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base: go:v1.1.56
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go:main go:renovate/major-go-dependencies go:cleue-v2 go:whitesource/configure go:cleue-switch-either-type go:cleue-bind go:cleue-add-with-resource go:cleue-support-chain-first-for-iooption go:cleue-add-uniq-to-array go:cleue-fix-compact-array go:cleue-fix-generic-order-in-chain-to go:cleue-add-sequence-array-par go:cleue-add-alt-to-iooption go:cleue-add-fromiooption go:cleue-fix-http-for-ioeither go:dependency-injection go:cleue-flip go:cleue-issue-77-2 go:issue-77 go:cleue-add-presentation go:cleue-add-asserts go:cleue-improve-with-lock go:cleue-add-mutex-to-io go:cleue-add-bool-package go:cleue-add-missing-FromIO go:cleue-add-flap-to-readerio go:cleue-add-flap-to-reader go:cleue-add-try-catch-for-single-value-return go:cleue-fix-flap-order go:cleue-add-FromReaderIO go:cleue-add-missing-chain-readeriok go:cleue-add-chain-first-to-readerio go:cleue-alternative-monoid-for-option go:cleue-add-flap go:sample-match go:cleue-add-missing-flatten-to-reader go:cleue-add-memoize-to-reader go:cleue-rioe-tests go:cleue-add-some-tweaks go:cleue-add-ioeither-sample-with-return-tuple go:cleue-some-benchmarking go:cleue-prefer-second-over-SK go:cleue-add-apply-monoid go:cleue-add-custom-type-sample go:cleue-add-traverse-with-index go:cleue-add-missing-functions go:cleue-add-missing-lenses go:cleue-implement-compact go:cleue-fix-order-of-generics-for-ChainOptionK go:cleue-mostly-adequate-more-samples go:cleue-mostly-adequate-capter10 go:cleue-request-builder-example go:cleue-mostly-adequate-fp-go go:cleue-add-cache go:cleue-sample-ioeither go:cleue-more-samples go:cleue-fix-build-break-1 go:cleue-add-disclaimer go:cleue-better-docs go:cleue-add-FoldMap go:cleue-fix-buildbreak go:cleue-add-FilterChain-operations go:cleue-implement-first-and-last go:cleue-add-some-more-itertools go:cleue-add-take go:cleue-add-zip go:cleue-implement-with-temp-file go:cleue-add-missing-methods go:cleue-add-more-generated-code go:cleue-more-iterator go:cleue-better-doc go:cleue-add-writer go:cleue-add-renovate go:cleue-auto-generate-traversal-for-readeroieither go:cleue-http-example go:cleue-fix-ap go:cleue-check-ap go:cleue-getting-started-docs go:cleue-add-doc go:cleue-initial-checkin
go:v1.1.83 go:v1.1.82 go:v1.1.81 go:v1.1.80 go:v1.1.79 go:v1.1.78 go:v1.1.77 go:v1.1.76 go:v1.1.75 go:v1.1.74 go:v1.1.73 go:v1.1.72 go:v1.1.71 go:v1.1.70 go:v1.1.69 go:v1.1.68 go:v1.1.67 go:v1.1.66 go:v1.1.65 go:v1.1.64 go:v1.1.63 go:v1.1.62 go:v1.1.61 go:v1.1.60 go:v1.1.59 go:v1.1.58 go:v1.1.57 go:v1.1.56 go:v1.1.55 go:v1.1.54 go:v1.1.53 go:v1.1.52 go:v1.1.51 go:v1.1.50 go:v1.1.49 go:v1.1.48 go:v1.1.47 go:v1.1.46 go:v1.1.45 go:v1.1.44 go:v1.1.43 go:v1.1.42 go:v1.1.41 go:v1.1.40 go:v1.1.39 go:v1.1.38 go:v1.1.37 go:v1.1.36 go:v1.1.35 go:v1.1.34 go:v1.1.33 go:v1.1.32 go:v1.1.31 go:v1.1.30 go:v1.1.29 go:v1.1.28 go:v1.1.27 go:v1.1.26 go:v1.1.25 go:v1.1.24 go:v1.1.23 go:v1.1.22 go:v1.1.21 go:v1.1.20 go:v1.1.19 go:v1.1.18 go:v1.1.17 go:v1.1.16 go:v1.1.15 go:v1.1.14 go:v1.1.13 go:v1.1.12 go:v1.1.11 go:v1.1.10 go:v1.1.9 go:v1.1.8 go:v1.1.7 go:v1.1.6 go:v1.1.5 go:v1.1.4 go:v1.1.3 go:v1.1.2 go:v1.1.1 go:v1.1.0 go:v1.0.155 go:v1.0.154 go:v1.0.153 go:v1.0.152 go:v1.0.151 go:v1.0.150 go:v1.0.149 go:v1.0.148 go:v1.0.147 go:v1.0.146 go:v1.0.145 go:v1.0.144 go:v1.0.143 go:v1.0.142 go:v1.0.141 go:v1.0.140 go:v1.0.139 go:v1.0.138 go:v1.0.137 go:v1.0.136 go:v1.0.135 go:v1.0.134 go:v1.0.133 go:v1.0.132 go:v1.0.131 go:v1.0.130 go:v1.0.129 go:v1.0.128 go:v1.0.127 go:v1.0.126 go:v1.0.125 go:v1.0.124 go:v1.0.123 go:v1.0.122 go:v1.0.121 go:v1.0.120 go:v1.0.119 go:v1.0.118 go:v1.0.117 go:v1.0.116 go:v1.0.115 go:v1.0.114 go:v1.0.113 go:v1.0.112 go:v1.0.111 go:v1.0.110 go:v1.0.109 go:v1.0.108 go:v1.0.107 go:v1.0.106 go:v1.0.105 go:v1.0.104 go:v1.0.103 go:v1.0.102 go:v1.0.101 go:v1.0.100 go:v1.0.99 go:v1.0.98 go:v1.0.97 go:v1.0.96 go:v1.0.95 go:v1.0.94 go:v1.0.93 go:v1.0.92 go:v1.0.91 go:v1.0.90 go:v1.0.89 go:v1.0.88 go:v1.0.87 go:v1.0.86 go:v1.0.85 go:v1.0.84 go:v1.0.83 go:v1.0.82 go:v1.0.81 go:v1.0.80 go:v1.0.79 go:v1.0.78 go:v1.0.77 go:v1.0.76 go:v1.0.75 go:v1.0.74 go:v1.0.73 go:v1.0.72 go:v1.0.71 go:v1.0.70 go:v1.0.69 go:v1.0.68 go:v1.0.67 go:v1.0.66 go:v1.0.65 go:v1.0.64 go:v1.0.63 go:v1.0.62 go:v1.0.61 go:v1.0.60 go:v1.0.59 go:v1.0.58 go:v1.0.57 go:v1.0.56 go:v1.0.55 go:v1.0.54 go:v1.0.53 go:v1.0.52 go:v1.0.51 go:v1.0.50 go:v1.0.49 go:v1.0.48 go:v1.0.47 go:v1.0.46 go:v1.0.45 go:v1.0.44 go:v1.0.43 go:v1.0.42 go:v1.0.41 go:v1.0.40 go:v1.0.39 go:v1.0.38 go:v1.0.37 go:v1.0.36 go:v1.0.35 go:v1.0.34 go:v1.0.33 go:v1.0.32 go:v1.0.31 go:v1.0.30 go:v1.0.29 go:v1.0.28 go:v1.0.27 go:v1.0.26 go:v1.0.25 go:v1.0.24 go:v1.0.23 go:v1.0.22 go:v1.0.21 go:v1.0.20 go:v1.0.19 go:v1.0.18 go:v1.0.17 go:v1.0.16 go:v1.0.15 go:v1.0.14 go:v1.0.13 go:v1.0.12 go:v1.0.11 go:v1.0.10 go:v1.0.9 go:v1.0.8 go:v1.0.7 go:v1.0.6 go:v1.0.5 go:v1.0.4 go:v1.0.3 go:v1.0.2 go:v1.0.1 go:v1.0.0
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compare: go:v1.1.82
Branches Tags
go:renovate/major-go-dependencies go:main go:cleue-v2 go:whitesource/configure go:cleue-switch-either-type go:cleue-bind go:cleue-add-with-resource go:cleue-support-chain-first-for-iooption go:cleue-add-uniq-to-array go:cleue-fix-compact-array go:cleue-fix-generic-order-in-chain-to go:cleue-add-sequence-array-par go:cleue-add-alt-to-iooption go:cleue-add-fromiooption go:cleue-fix-http-for-ioeither go:dependency-injection go:cleue-flip go:cleue-issue-77-2 go:issue-77 go:cleue-add-presentation go:cleue-add-asserts go:cleue-improve-with-lock go:cleue-add-mutex-to-io go:cleue-add-bool-package go:cleue-add-missing-FromIO go:cleue-add-flap-to-readerio go:cleue-add-flap-to-reader go:cleue-add-try-catch-for-single-value-return go:cleue-fix-flap-order go:cleue-add-FromReaderIO go:cleue-add-missing-chain-readeriok go:cleue-add-chain-first-to-readerio go:cleue-alternative-monoid-for-option go:cleue-add-flap go:sample-match go:cleue-add-missing-flatten-to-reader go:cleue-add-memoize-to-reader go:cleue-rioe-tests go:cleue-add-some-tweaks go:cleue-add-ioeither-sample-with-return-tuple go:cleue-some-benchmarking go:cleue-prefer-second-over-SK go:cleue-add-apply-monoid go:cleue-add-custom-type-sample go:cleue-add-traverse-with-index go:cleue-add-missing-functions go:cleue-add-missing-lenses go:cleue-implement-compact go:cleue-fix-order-of-generics-for-ChainOptionK go:cleue-mostly-adequate-more-samples go:cleue-mostly-adequate-capter10 go:cleue-request-builder-example go:cleue-mostly-adequate-fp-go go:cleue-add-cache go:cleue-sample-ioeither go:cleue-more-samples go:cleue-fix-build-break-1 go:cleue-add-disclaimer go:cleue-better-docs go:cleue-add-FoldMap go:cleue-fix-buildbreak go:cleue-add-FilterChain-operations go:cleue-implement-first-and-last go:cleue-add-some-more-itertools go:cleue-add-take go:cleue-add-zip go:cleue-implement-with-temp-file go:cleue-add-missing-methods go:cleue-add-more-generated-code go:cleue-more-iterator go:cleue-better-doc go:cleue-add-writer go:cleue-add-renovate go:cleue-auto-generate-traversal-for-readeroieither go:cleue-http-example go:cleue-fix-ap go:cleue-check-ap go:cleue-getting-started-docs go:cleue-add-doc go:cleue-initial-checkin
go:v1.1.83 go:v1.1.82 go:v1.1.81 go:v1.1.80 go:v1.1.79 go:v1.1.78 go:v1.1.77 go:v1.1.76 go:v1.1.75 go:v1.1.74 go:v1.1.73 go:v1.1.72 go:v1.1.71 go:v1.1.70 go:v1.1.69 go:v1.1.68 go:v1.1.67 go:v1.1.66 go:v1.1.65 go:v1.1.64 go:v1.1.63 go:v1.1.62 go:v1.1.61 go:v1.1.60 go:v1.1.59 go:v1.1.58 go:v1.1.57 go:v1.1.56 go:v1.1.55 go:v1.1.54 go:v1.1.53 go:v1.1.52 go:v1.1.51 go:v1.1.50 go:v1.1.49 go:v1.1.48 go:v1.1.47 go:v1.1.46 go:v1.1.45 go:v1.1.44 go:v1.1.43 go:v1.1.42 go:v1.1.41 go:v1.1.40 go:v1.1.39 go:v1.1.38 go:v1.1.37 go:v1.1.36 go:v1.1.35 go:v1.1.34 go:v1.1.33 go:v1.1.32 go:v1.1.31 go:v1.1.30 go:v1.1.29 go:v1.1.28 go:v1.1.27 go:v1.1.26 go:v1.1.25 go:v1.1.24 go:v1.1.23 go:v1.1.22 go:v1.1.21 go:v1.1.20 go:v1.1.19 go:v1.1.18 go:v1.1.17 go:v1.1.16 go:v1.1.15 go:v1.1.14 go:v1.1.13 go:v1.1.12 go:v1.1.11 go:v1.1.10 go:v1.1.9 go:v1.1.8 go:v1.1.7 go:v1.1.6 go:v1.1.5 go:v1.1.4 go:v1.1.3 go:v1.1.2 go:v1.1.1 go:v1.1.0 go:v1.0.155 go:v1.0.154 go:v1.0.153 go:v1.0.152 go:v1.0.151 go:v1.0.150 go:v1.0.149 go:v1.0.148 go:v1.0.147 go:v1.0.146 go:v1.0.145 go:v1.0.144 go:v1.0.143 go:v1.0.142 go:v1.0.141 go:v1.0.140 go:v1.0.139 go:v1.0.138 go:v1.0.137 go:v1.0.136 go:v1.0.135 go:v1.0.134 go:v1.0.133 go:v1.0.132 go:v1.0.131 go:v1.0.130 go:v1.0.129 go:v1.0.128 go:v1.0.127 go:v1.0.126 go:v1.0.125 go:v1.0.124 go:v1.0.123 go:v1.0.122 go:v1.0.121 go:v1.0.120 go:v1.0.119 go:v1.0.118 go:v1.0.117 go:v1.0.116 go:v1.0.115 go:v1.0.114 go:v1.0.113 go:v1.0.112 go:v1.0.111 go:v1.0.110 go:v1.0.109 go:v1.0.108 go:v1.0.107 go:v1.0.106 go:v1.0.105 go:v1.0.104 go:v1.0.103 go:v1.0.102 go:v1.0.101 go:v1.0.100 go:v1.0.99 go:v1.0.98 go:v1.0.97 go:v1.0.96 go:v1.0.95 go:v1.0.94 go:v1.0.93 go:v1.0.92 go:v1.0.91 go:v1.0.90 go:v1.0.89 go:v1.0.88 go:v1.0.87 go:v1.0.86 go:v1.0.85 go:v1.0.84 go:v1.0.83 go:v1.0.82 go:v1.0.81 go:v1.0.80 go:v1.0.79 go:v1.0.78 go:v1.0.77 go:v1.0.76 go:v1.0.75 go:v1.0.74 go:v1.0.73 go:v1.0.72 go:v1.0.71 go:v1.0.70 go:v1.0.69 go:v1.0.68 go:v1.0.67 go:v1.0.66 go:v1.0.65 go:v1.0.64 go:v1.0.63 go:v1.0.62 go:v1.0.61 go:v1.0.60 go:v1.0.59 go:v1.0.58 go:v1.0.57 go:v1.0.56 go:v1.0.55 go:v1.0.54 go:v1.0.53 go:v1.0.52 go:v1.0.51 go:v1.0.50 go:v1.0.49 go:v1.0.48 go:v1.0.47 go:v1.0.46 go:v1.0.45 go:v1.0.44 go:v1.0.43 go:v1.0.42 go:v1.0.41 go:v1.0.40 go:v1.0.39 go:v1.0.38 go:v1.0.37 go:v1.0.36 go:v1.0.35 go:v1.0.34 go:v1.0.33 go:v1.0.32 go:v1.0.31 go:v1.0.30 go:v1.0.29 go:v1.0.28 go:v1.0.27 go:v1.0.26 go:v1.0.25 go:v1.0.24 go:v1.0.23 go:v1.0.22 go:v1.0.21 go:v1.0.20 go:v1.0.19 go:v1.0.18 go:v1.0.17 go:v1.0.16 go:v1.0.15 go:v1.0.14 go:v1.0.13 go:v1.0.12 go:v1.0.11 go:v1.0.10 go:v1.0.9 go:v1.0.8 go:v1.0.7 go:v1.0.6 go:v1.0.5 go:v1.0.4 go:v1.0.3 go:v1.0.2 go:v1.0.1 go:v1.0.0

30 Commits
v1.1.56 ... v1.1.82

Author SHA1 Message Date
Dr. Carsten Leue
20398e67a9 fix: better doc and implementation of retry 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-17 15:58:11 +01:00
Dr. Carsten Leue
fceda15701 doc: improve docs 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-17 10:11:58 +01:00
Dr. Carsten Leue
4ebfcadabe fix: add better tests 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-16 14:03:01 +01:00
Dr. Carsten Leue
acb601fc01 fix: reuse some more code 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-15 16:30:40 +01:00
Dr. Carsten Leue
d17663f016 fix: better doc 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-15 11:16:09 +01:00
Dr. Carsten Leue
829365fc24 doc: improve docs 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-12 13:30:10 +01:00
Dr. Carsten Leue
64b5660b4e doc: remove some comments 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-12 12:35:53 +01:00
Dr. Carsten Leue
16e82d6a65 fix: better cancellation support 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-12 11:52:43 +01:00
Dr. Carsten Leue
0d40fdcebb fix: implement tail recursion 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-12 11:18:32 +01:00
Dr. Carsten Leue
6a4dfa2c93 fix: better doc 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-11 16:18:55 +01:00
Dr. Carsten Leue
a37f379a3c fix: semantic of MapTo and ChainTo and update tests 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-11 09:09:44 +01:00
Dr. Carsten Leue
ece0cd135d fix: add more tests and logging 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-10 18:23:19 +01:00
Dr. Carsten Leue
739b6a284c fix: better slog based logging 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-09 17:52:57 +01:00
Dr. Carsten Leue
ba10d8d314 doc: fix docs 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-09 13:00:03 +01:00
Dr. Carsten Leue
3d6c419185 fix: add better logging 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-09 12:49:44 +01:00
Dr. Carsten Leue
3f4b6292e4 fix: optimize Traverse 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-05 21:35:05 +01:00
Dr. Carsten Leue
b1704b6d26 fix: implement TraverseReader 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-05 17:51:13 +01:00
Dr. Carsten Leue
ffdfd218f8 fix: implement Flip for Reader 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-05 11:04:49 +01:00
Dr. Carsten Leue
34826d8c52 fix: Ask and add tests to retry 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-04 16:47:53 +01:00
Dr. Carsten Leue
24c0519cc7 fix: try to unify type signatures 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-04 16:31:21 +01:00
Dr. Carsten Leue
ff48d8953e fix: implement some missing methods in reader io 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-04 13:50:25 +01:00
Dr. Carsten Leue
d739c9b277 fix: add doc to readerio 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-12-03 18:13:59 +01:00
Dr. Carsten Leue
f0054431a5 fix: add logging to readerio 2025-12-03 18:07:06 +01:00
Carsten Leue
1a89ec3df7 fix: implement Sequence for Pair 
Signed-off-by: Carsten Leue <carsten.leue@de.ibm.com>
 2025-11-28 11:22:23 +01:00
Carsten Leue
f652a94c3a fix: add template based logger 
Signed-off-by: Carsten Leue <carsten.leue@de.ibm.com>
 2025-11-28 10:11:08 +01:00
Dr. Carsten Leue
774db88ca5 fix: add name to prism 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-11-27 13:26:36 +01:00
Dr. Carsten Leue
62a3365b20 fix: add conversion prisms for numbers 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-11-27 13:12:18 +01:00
Dr. Carsten Leue
d9a16a6771 fix: add reduce operations to readerioresult 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-11-26 17:00:10 +01:00
Dr. Carsten Leue
8949cc7dca fix: expose stats 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-11-26 13:44:40 +01:00
Dr. Carsten Leue
fa6b6caf22 fix: generic order for reader.Flap 
Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com>
 2025-11-26 12:53:13 +01:00
323 changed files with 55026 additions and 5056 deletions
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# Design Decisions
This document explains the key design decisions and principles behind fp-go's API design.
## Table of Contents
- [Data Last Principle](#data-last-principle)
- [Kleisli and Operator Types](#kleisli-and-operator-types)
- [Monadic Operations Comparison](#monadic-operations-comparison)
- [Type Parameter Ordering](#type-parameter-ordering)
- [Generic Type Aliases](#generic-type-aliases)
## Data Last Principle
fp-go follows the **"data last"** principle, where the data being operated on is always the last parameter in a function. This design choice enables powerful function composition and partial application patterns.
### What is "Data Last"?
In the "data last" style, functions are structured so that:
1. Configuration parameters come first
2. The data to be transformed comes last
This is the opposite of the traditional object-oriented style where the data (receiver) comes first.
### Why "Data Last"?
The "data last" principle enables:
1. **Natural Currying**: Functions can be partially applied to create specialized transformations
2. **Function Composition**: Operations can be composed before applying them to data
3. **Point-Free Style**: Write transformations without explicitly mentioning the data
4. **Reusability**: Create reusable transformation pipelines
### Examples
#### Basic Transformation
```go
// Data last style (fp-go)
double := array.Map(number.Mul(2))
result := double([]int{1, 2, 3}) // [2, 4, 6]
// Compare with data first style (traditional)
result := array.Map([]int{1, 2, 3}, number.Mul(2))
```
#### Function Composition
```go
import (
A "github.com/IBM/fp-go/v2/array"
F "github.com/IBM/fp-go/v2/function"
N "github.com/IBM/fp-go/v2/number"
)
// Create a pipeline of transformations
pipeline := F.Flow3(
A.Filter(func(x int) bool { return x > 0 }), // Keep positive numbers
A.Map(N.Mul(2)), // Double each number
A.Reduce(func(acc, x int) int { return acc + x }, 0), // Sum them up
)
// Apply the pipeline to different data
result1 := pipeline([]int{-1, 2, 3, -4, 5}) // (2 + 3 + 5) * 2 = 20
result2 := pipeline([]int{1, 2, 3}) // (1 + 2 + 3) * 2 = 12
```
#### Partial Application
```go
import (
O "github.com/IBM/fp-go/v2/option"
)
// Create specialized functions by partial application
getOrZero := O.GetOrElse(func() int { return 0 })
getOrEmpty := O.GetOrElse(func() string { return "" })
// Use them with different data
value1 := getOrZero(O.Some(42)) // 42
value2 := getOrZero(O.None[int]()) // 0
text1 := getOrEmpty(O.Some("hello")) // "hello"
text2 := getOrEmpty(O.None[string]()) // ""
```
#### Building Reusable Transformations
```go
import (
E "github.com/IBM/fp-go/v2/either"
O "github.com/IBM/fp-go/v2/option"
)
// Create a reusable validation pipeline
type User struct {
Name string
Email string
Age int
}
validateAge := E.FromPredicate(
func(u User) bool { return u.Age >= 18 },
func(u User) error { return errors.New("must be 18 or older") },
)
validateEmail := E.FromPredicate(
func(u User) bool { return strings.Contains(u.Email, "@") },
func(u User) error { return errors.New("invalid email") },
)
// Compose validators
validateUser := F.Flow2(
validateAge,
E.Chain(validateEmail),
)
// Apply to different users
result1 := validateUser(User{Name: "Alice", Email: "alice@example.com", Age: 25})
result2 := validateUser(User{Name: "Bob", Email: "invalid", Age: 30})
```
#### Monadic Operations
```go
import (
O "github.com/IBM/fp-go/v2/option"
)
// Data last enables clean monadic chains
parseAndDouble := F.Flow2(
O.FromPredicate(func(s string) bool { return s != "" }),
O.Chain(func(s string) O.Option[int] {
n, err := strconv.Atoi(s)
if err != nil {
return O.None[int]()
}
return O.Some(n * 2)
}),
)
result1 := parseAndDouble("21") // Some(42)
result2 := parseAndDouble("") // None
result3 := parseAndDouble("abc") // None
```
### Monadic vs Non-Monadic Forms
fp-go provides two forms for most operations:
1. **Curried form** (data last): Returns a function that can be composed
2. **Monadic form** (data first): Takes all parameters at once
```go
// Curried form - data last, returns a function
Map[A, B any](f func(A) B) func(Option[A]) Option[B]
// Monadic form - data first, direct execution
MonadMap[A, B any](fa Option[A], f func(A) B) Option[B]
```
**When to use each:**
- **Curried form**: When building pipelines, composing functions, or creating reusable transformations
- **Monadic form**: When you have all parameters available and want direct execution
```go
// Curried form - building a pipeline
transform := F.Flow3(
O.Map(strings.ToUpper),
O.Filter(func(s string) bool { return len(s) > 3 }),
O.GetOrElse(func() string { return "DEFAULT" }),
)
result := transform(O.Some("hello"))
// Monadic form - direct execution
result := O.MonadMap(O.Some("hello"), strings.ToUpper)
```
### Further Reading on Data-Last Pattern
The data-last currying pattern is well-documented in the functional programming community:
- [Mostly Adequate Guide - Ch. 4: Currying](https://mostly-adequate.gitbook.io/mostly-adequate-guide/ch04) - Excellent introduction with clear examples
- [Curry and Function Composition](https://medium.com/javascript-scene/curry-and-function-composition-2c208d774983) by Eric Elliott
- [fp-ts Issue #1238](https://github.com/gcanti/fp-ts/issues/1238) - Real-world examples of data-last refactoring
## Kleisli and Operator Types
fp-go uses consistent type aliases across all monads to make code more recognizable and composable. These types provide a common vocabulary that works across different monadic contexts.
### Type Definitions
```go
// Kleisli arrow - a function that returns a monadic value
type Kleisli[A, B any] = func(A) M[B]
// Operator - a function that transforms a monadic value
type Operator[A, B any] = func(M[A]) M[B]
```
Where `M` represents the specific monad (Option, Either, IO, etc.).
### Why These Types Matter
1. **Consistency**: The same type names appear across all monads
2. **Recognizability**: Experienced functional programmers immediately understand the intent
3. **Composability**: Functions with these types compose naturally
4. **Documentation**: Type signatures clearly communicate the operation's behavior
### Examples Across Monads
#### Option Monad
```go
// option/option.go
type Kleisli[A, B any] = func(A) Option[B]
type Operator[A, B any] = func(Option[A]) Option[B]
// Chain uses Kleisli
func Chain[A, B any](f Kleisli[A, B]) Operator[A, B]
// Map returns an Operator
func Map[A, B any](f func(A) B) Operator[A, B]
```
#### Either Monad
```go
// either/either.go
type Kleisli[E, A, B any] = func(A) Either[E, B]
type Operator[E, A, B any] = func(Either[E, A]) Either[E, B]
// Chain uses Kleisli
func Chain[E, A, B any](f Kleisli[E, A, B]) Operator[E, A, B]
// Map returns an Operator
func Map[E, A, B any](f func(A) B) Operator[E, A, B]
```
#### IO Monad
```go
// io/io.go
type Kleisli[A, B any] = func(A) IO[B]
type Operator[A, B any] = func(IO[A]) IO[B]
// Chain uses Kleisli
func Chain[A, B any](f Kleisli[A, B]) Operator[A, B]
// Map returns an Operator
func Map[A, B any](f func(A) B) Operator[A, B]
```
#### Array (List Monad)
```go
// array/array.go
type Kleisli[A, B any] = func(A) []B
type Operator[A, B any] = func([]A) []B
// Chain uses Kleisli
func Chain[A, B any](f Kleisli[A, B]) Operator[A, B]
// Map returns an Operator
func Map[A, B any](f func(A) B) Operator[A, B]
```
### Pattern Recognition
Once you learn these patterns in one monad, you can apply them to all monads:
```go
// The pattern is always the same, just the monad changes
// Option
validateAge := option.Chain(func(user User) option.Option[User] {
if user.Age >= 18 {
return option.Some(user)
}
return option.None[User]()
})
// Either
validateAge := either.Chain(func(user User) either.Either[error, User] {
if user.Age >= 18 {
return either.Right[error](user)
}
return either.Left[User](errors.New("too young"))
})
// IO
validateAge := io.Chain(func(user User) io.IO[User] {
return io.Of(user) // Always succeeds in IO
})
// Array
validateAge := array.Chain(func(user User) []User {
if user.Age >= 18 {
return []User{user}
}
return []User{} // Empty array = failure
})
```
### Composing Kleisli Arrows
Kleisli arrows compose naturally using monadic composition:
```go
import (
O "github.com/IBM/fp-go/v2/option"
F "github.com/IBM/fp-go/v2/function"
)
// Define Kleisli arrows
parseAge := func(s string) O.Option[int] {
n, err := strconv.Atoi(s)
if err != nil {
return O.None[int]()
}
return O.Some(n)
}
validateAge := func(age int) O.Option[int] {
if age >= 18 {
return O.Some(age)
}
return O.None[int]()
}
formatAge := func(age int) O.Option[string] {
return O.Some(fmt.Sprintf("Age: %d", age))
}
// Compose them using Flow and Chain
pipeline := F.Flow3(
parseAge,
O.Chain(validateAge),
O.Chain(formatAge),
)
result := pipeline("25") // Some("Age: 25")
result := pipeline("15") // None (too young)
result := pipeline("abc") // None (parse error)
```
### Building Reusable Operators
Operators can be created once and reused across your codebase:
```go
import (
E "github.com/IBM/fp-go/v2/either"
)
// Create reusable operators
type ValidationError struct {
Field string
Message string
}
// Reusable validation operators
validateNonEmpty := E.Chain(func(s string) E.Either[ValidationError, string] {
if s == "" {
return E.Left[string](ValidationError{
Field: "input",
Message: "cannot be empty",
})
}
return E.Right[ValidationError](s)
})
validateEmail := E.Chain(func(s string) E.Either[ValidationError, string] {
if !strings.Contains(s, "@") {
return E.Left[string](ValidationError{
Field: "email",
Message: "invalid format",
})
}
return E.Right[ValidationError](s)
})
// Compose operators
validateEmailInput := F.Flow2(
validateNonEmpty,
validateEmail,
)
// Use across your application
result1 := validateEmailInput(E.Right[ValidationError]("user@example.com"))
result2 := validateEmailInput(E.Right[ValidationError](""))
result3 := validateEmailInput(E.Right[ValidationError]("invalid"))
```
### Benefits of Consistent Naming
1. **Cross-monad understanding**: Learn once, apply everywhere
2. **Easier refactoring**: Changing monads requires minimal code changes
3. **Better tooling**: IDEs can provide better suggestions
4. **Team communication**: Shared vocabulary across the team
5. **Library integration**: Third-party libraries follow the same patterns
### Identity Monad - The Simplest Case
The Identity monad shows these types in their simplest form:
```go
// identity/doc.go
type Operator[A, B any] = func(A) B
// In Identity, there's no wrapping, so:
// - Kleisli[A, B] is just func(A) B
// - Operator[A, B] is just func(A) B
// They're the same because Identity adds no context
```
This demonstrates that these type aliases represent fundamental functional programming concepts, not just arbitrary naming conventions.
## Monadic Operations Comparison
fp-go's monadic operations are inspired by functional programming languages and libraries. Here's how they compare:
| fp-go | fp-ts | Haskell | Scala | Description |
|-------|-------|---------|-------|-------------|
| `Map` | `map` | `fmap` | `map` | Functor mapping - transforms the value inside a context |
| `Chain` | `chain` | `>>=` (bind) | `flatMap` | Monadic bind - chains computations that return wrapped values |
| `Ap` | `ap` | `<*>` | `ap` | Applicative apply - applies a wrapped function to a wrapped value |
| `Of` | `of` | `return`/`pure` | `pure` | Lifts a pure value into a monadic context |
| `Fold` | `fold` | `either` | `fold` | Eliminates the context by providing handlers for each case |
| `Filter` | `filter` | `mfilter` | `filter` | Keeps values that satisfy a predicate |
| `Flatten` | `flatten` | `join` | `flatten` | Removes one level of nesting |
| `ChainFirst` | `chainFirst` | `>>` (then) | `tap` | Chains for side effects, keeping the original value |
| `Alt` | `alt` | `<\|>` | `orElse` | Provides an alternative value if the first fails |
| `GetOrElse` | `getOrElse` | `fromMaybe` | `getOrElse` | Extracts the value or provides a default |
| `FromPredicate` | `fromPredicate` | `guard` | `filter` | Creates a monadic value based on a predicate |
| `Sequence` | `sequence` | `sequence` | `sequence` | Transforms a collection of effects into an effect of a collection |
| `Traverse` | `traverse` | `traverse` | `traverse` | Maps and sequences in one operation |
| `Reduce` | `reduce` | `foldl` | `foldLeft` | Folds a structure from left to right |
| `ReduceRight` | `reduceRight` | `foldr` | `foldRight` | Folds a structure from right to left |
### Key Differences from Other Languages
#### Naming Conventions
- **Go conventions**: fp-go uses PascalCase for exported functions (e.g., `Map`, `Chain`) following Go's naming conventions
- **Type parameters first**: Non-inferrable type parameters come first (e.g., `Ap[B, E, A any]`)
- **Monadic prefix**: Direct execution forms use the `Monad` prefix (e.g., `MonadMap`, `MonadChain`)
#### Type System
```go
// fp-go (explicit type parameters when needed)
result := option.Map(transform)(value)
result := option.Map[string, int](transform)(value) // explicit when inference fails
// Haskell (type inference)
result = fmap transform value
// Scala (type inference with method syntax)
result = value.map(transform)
// fp-ts (TypeScript type inference)
const result = pipe(value, map(transform))
```
#### Currying
```go
// fp-go - explicit currying with data last
double := array.Map(number.Mul(2))
result := double(numbers)
// Haskell - automatic currying
double = fmap (*2)
result = double numbers
// Scala - method syntax
result = numbers.map(_ * 2)
```
## Type Parameter Ordering
fp-go v2 uses a specific ordering for type parameters to maximize type inference:
### Rule: Non-Inferrable Parameters First
Type parameters that **cannot be inferred** from function arguments come first. This allows the Go compiler to infer as many types as possible.
```go
// Ap - B cannot be inferred from arguments, so it comes first
func Ap[B, E, A any](fa Either[E, A]) func(Either[E, func(A) B]) Either[E, B]
// Usage - only B needs to be specified
result := either.Ap[string](value)(funcInEither)
```
### Examples
```go
// Map - all types can be inferred from arguments
func Map[E, A, B any](f func(A) B) func(Either[E, A]) Either[E, B]
// Usage - no type parameters needed
result := either.Map(transform)(value)
// Chain - all types can be inferred
func Chain[E, A, B any](f func(A) Either[E, B]) func(Either[E, A]) Either[E, B]
// Usage - no type parameters needed
result := either.Chain(validator)(value)
// Of - E cannot be inferred, comes first
func Of[E, A any](value A) Either[E, A]
// Usage - only E needs to be specified
result := either.Of[error](42)
```
### Benefits
1. **Less verbose code**: Most operations don't require explicit type parameters
2. **Better IDE support**: Type inference provides better autocomplete
3. **Clearer intent**: Only specify types that can't be inferred
## Generic Type Aliases
fp-go v2 leverages Go 1.24's generic type aliases for cleaner type definitions:
```go
// V2 - using generic type alias (requires Go 1.24+)
type ReaderIOEither[R, E, A any] = RD.Reader[R, IOE.IOEither[E, A]]
// V1 - using type definition (Go 1.18+)
type ReaderIOEither[R, E, A any] RD.Reader[R, IOE.IOEither[E, A]]
```
### Benefits
1. **True aliases**: The type is interchangeable with its definition
2. **No namespace imports needed**: Can use types directly without package prefixes
3. **Simpler codebase**: Eliminates the need for `generic` subpackages
4. **Better composability**: Types compose more naturally
### Migration Pattern
```go
// Define project-wide aliases once
package types
import (
"github.com/IBM/fp-go/v2/option"
"github.com/IBM/fp-go/v2/result"
"github.com/IBM/fp-go/v2/ioresult"
)
type Option[A any] = option.Option[A]
type Result[A any] = result.Result[A]
type IOResult[A any] = ioresult.IOResult[A]
// Use throughout your codebase
package myapp
import "myproject/types"
func process(input string) types.Result[types.Option[int]] {
// implementation
}
```
---
For more information, see:
- [README.md](./README.md) - Overview and quick start
- [API Documentation](https://pkg.go.dev/github.com/IBM/fp-go/v2) - Complete API reference
- [Samples](./samples/) - Practical examples

212
v2/EXAMPLE_TESTS_PROGRESS.md Normal file
View File

@@ -0,0 +1,212 @@
# Example Tests Progress
This document tracks the progress of converting documentation examples into executable example test files.
## Overview
The codebase has 300+ documentation examples across many packages. This document tracks which packages have been completed and which still need work.
## Completed Packages
### Core Packages
- [x] **result** - Created `examples_bind_test.go`, `examples_curry_test.go`, `examples_apply_test.go`
- Files: `bind.go` (10 examples), `curry.go` (5 examples), `apply.go` (2 examples)
- Status: ✅ 17 tests passing
### Utility Packages
- [x] **pair** - Created `examples_test.go`
- Files: `pair.go` (14 examples)
- Status: ✅ 14 tests passing
- [x] **tuple** - Created `examples_test.go`
- Files: `tuple.go` (6 examples)
- Status: ✅ 6 tests passing
### Type Class Packages
- [x] **semigroup** - Created `examples_test.go`
- Files: `semigroup.go` (7 examples)
- Status: ✅ 7 tests passing
### Utility Packages (continued)
- [x] **predicate** - Created `examples_test.go`
- Files: `bool.go` (3 examples), `contramap.go` (1 example)
- Status: ✅ 4 tests passing
### Context Reader Packages
- [x] **idiomatic/context/readerresult** - Created `examples_reader_test.go`, `examples_bind_test.go`
- Files: `reader.go` (8 examples), `bind.go` (14 examples)
- Status: ✅ 22 tests passing
## Summary Statistics
- **Total Example Tests Created**: 74
- **Total Packages Completed**: 7 (result, pair, tuple, semigroup, predicate, idiomatic/context/readerresult)
- **All Tests Status**: ✅ PASSING
### Breakdown by Package
- **result**: 21 tests (bind: 10, curry: 5, apply: 2, array: 4)
- **pair**: 14 tests
- **tuple**: 6 tests
- **semigroup**: 7 tests
- **predicate**: 4 tests
- **idiomatic/context/readerresult**: 22 tests (reader: 8, bind: 14)
## Packages with Existing Examples
These packages already have some example test files:
- result (has `examples_create_test.go`, `examples_extract_test.go`)
- option (has `examples_create_test.go`, `examples_extract_test.go`)
- either (has `examples_create_test.go`, `examples_extract_test.go`)
- ioeither (has `examples_create_test.go`, `examples_do_test.go`, `examples_extract_test.go`)
- ioresult (has `examples_create_test.go`, `examples_do_test.go`, `examples_extract_test.go`)
- lazy (has `example_lazy_test.go`)
- array (has `examples_basic_test.go`, `examples_sort_test.go`, `example_any_test.go`, `example_find_test.go`)
- readerioeither (has `traverse_example_test.go`)
- context/readerioresult (has `flip_example_test.go`)
## Packages Needing Example Tests
### Core Packages (High Priority)
- [ ] **result** - Additional files need examples:
- `apply.go` (2 examples)
- `array.go` (7 examples)
- `core.go` (6 examples)
- `either.go` (26 examples)
- `eq.go` (2 examples)
- `functor.go` (1 example)
- [ ] **option** - Additional files need examples
- [ ] **either** - Additional files need examples
### Reader Packages (High Priority)
- [ ] **reader** - Many examples in:
- `array.go` (12 examples)
- `bind.go` (10 examples)
- `curry.go` (8 examples)
- `flip.go` (2 examples)
- `reader.go` (21 examples)
- [ ] **readeroption** - Examples in:
- `array.go` (3 examples)
- `bind.go` (7 examples)
- `curry.go` (5 examples)
- `flip.go` (2 examples)
- `from.go` (4 examples)
- `reader.go` (18 examples)
- `sequence.go` (4 examples)
- [ ] **readerresult** - Examples in:
- `array.go` (3 examples)
- `bind.go` (24 examples)
- `curry.go` (7 examples)
- `flip.go` (2 examples)
- `from.go` (4 examples)
- `monoid.go` (3 examples)
- [ ] **readereither** - Examples in:
- `array.go` (3 examples)
- `bind.go` (7 examples)
- `flip.go` (3 examples)
- [ ] **readerio** - Examples in:
- `array.go` (3 examples)
- `bind.go` (7 examples)
- `flip.go` (2 examples)
- `logging.go` (4 examples)
- `reader.go` (30 examples)
- [ ] **readerioeither** - Examples in:
- `bind.go` (7 examples)
- `flip.go` (1 example)
- [ ] **readerioresult** - Examples in:
- `array.go` (8 examples)
- `bind.go` (24 examples)
### State Packages
- [ ] **statereaderioeither** - Examples in:
- `bind.go` (5 examples)
- `resource.go` (1 example)
- `state.go` (13 examples)
### Utility Packages
- [ ] **lazy** - Additional examples in:
- `apply.go` (2 examples)
- `bind.go` (7 examples)
- `lazy.go` (10 examples)
- `sequence.go` (4 examples)
- `traverse.go` (2 examples)
- [ ] **pair** - Additional examples in:
- `monad.go` (12 examples)
- `pair.go` (remaining ~20 examples)
- [ ] **tuple** - Examples in:
- `tuple.go` (6 examples)
- [ ] **predicate** - Examples in:
- `bool.go` (3 examples)
- `contramap.go` (1 example)
- `monoid.go` (4 examples)
- [ ] **retry** - Examples in:
- `retry.go` (7 examples)
- [ ] **logging** - Examples in:
- `logger.go` (5 examples)
### Collection Packages
- [ ] **record** - Examples in:
- `bind.go` (3 examples)
### Type Class Packages
- [ ] **semigroup** - Examples in:
- `alt.go` (1 example)
- `apply.go` (1 example)
- `array.go` (4 examples)
- `semigroup.go` (7 examples)
- [ ] **ord** - Examples in:
- `ord.go` (1 example)
## Strategy for Completion
1. **Prioritize by usage**: Focus on core packages (result, option, either) first
2. **Group by package**: Complete all examples for one package before moving to next
3. **Test incrementally**: Run tests after each file to catch errors early
4. **Follow patterns**: Use existing example test files as templates
5. **Document as you go**: Update this file with progress
## Example Test File Template
```go
// Copyright header...
package packagename_test
import (
"fmt"
PKG "github.com/IBM/fp-go/v2/packagename"
)
func ExampleFunctionName() {
// Copy example from doc comment
// Ensure it compiles and produces correct output
fmt.Println(result)
// Output:
// expected output
}
```
## Notes
- Use `F.Constant1[error](defaultValue)` for GetOrElse in result package
- Use `F.Pipe1` instead of `F.Pipe2` when only one transformation
- Check function signatures carefully for type parameters
- Some functions like `BiMap` are capitalized differently than in docs
- **Prefer `R.Eitherize1(func)` over manual error handling** - converts `func(T) (R, error)` to `func(T) Result[R]`
- Example: Use `R.Eitherize1(strconv.Atoi)` instead of manual if/else error checking
- **Add Go documentation comments to all example functions** - Each example should have a comment explaining what it demonstrates
- **Idiomatic vs Non-Idiomatic packages**:
- Non-idiomatic (e.g., `result`): Uses `Result[A]` type (Either monad)
- Idiomatic (e.g., `idiomatic/result`): Uses `(A, error)` tuples (Go-style)
- Context readers use non-idiomatic `Result[A]` internally

3
v2/README.md
View File

@@ -61,6 +61,7 @@ package main
import (
"fmt"
"github.com/IBM/fp-go/v2/option"
N "github.com/IBM/fp-go/v2/number"
)
func main() {
@@ -145,6 +146,8 @@ func main() {
}
```
## ⚠️ Breaking Changes
### From V1 to V2
#### 1. Generic Type Aliases

86
v2/array/array.go
View File

@@ -536,3 +536,89 @@ func Flap[B, A any](a A) Operator[func(A) B, B] {
func Prepend[A any](head A) Operator[A, A] {
return G.Prepend[Operator[A, A]](head)
}
// Reverse returns a new slice with elements in reverse order.
// This function creates a new slice containing all elements from the input slice
// in reverse order, without modifying the original slice.
//
// Type Parameters:
// - A: The type of elements in the slice
//
// Parameters:
// - as: The input slice to reverse
//
// Returns:
// - A new slice with elements in reverse order
//
// Behavior:
// - Creates a new slice with the same length as the input
// - Copies elements from the input slice in reverse order
// - Does not modify the original slice
// - Returns an empty slice if the input is empty
// - Returns a single-element slice unchanged if input has one element
//
// Example:
//
// numbers := []int{1, 2, 3, 4, 5}
// reversed := array.Reverse(numbers)
// // reversed: []int{5, 4, 3, 2, 1}
// // numbers: []int{1, 2, 3, 4, 5} (unchanged)
//
// Example with strings:
//
// words := []string{"hello", "world", "foo", "bar"}
// reversed := array.Reverse(words)
// // reversed: []string{"bar", "foo", "world", "hello"}
//
// Example with empty slice:
//
// empty := []int{}
// reversed := array.Reverse(empty)
// // reversed: []int{} (empty slice)
//
// Example with single element:
//
// single := []string{"only"}
// reversed := array.Reverse(single)
// // reversed: []string{"only"}
//
// Use cases:
// - Reversing the order of elements for display or processing
// - Implementing stack-like behavior (LIFO)
// - Processing data in reverse chronological order
// - Reversing transformation pipelines
// - Creating palindrome checks
// - Implementing undo/redo functionality
//
// Example with processing in reverse:
//
// events := []string{"start", "middle", "end"}
// reversed := array.Reverse(events)
// // Process events in reverse order
// for _, event := range reversed {
// fmt.Println(event) // Prints: "end", "middle", "start"
// }
//
// Example with functional composition:
//
// numbers := []int{1, 2, 3, 4, 5}
// result := F.Pipe2(
// numbers,
// array.Map(N.Mul(2)),
// array.Reverse,
// )
// // result: []int{10, 8, 6, 4, 2}
//
// Performance:
// - Time complexity: O(n) where n is the length of the slice
// - Space complexity: O(n) for the new slice
// - Does not allocate if the input slice is empty
//
// Note: This function is immutable - it does not modify the original slice.
// If you need to reverse a slice in-place, consider using a different approach
// or modifying the slice directly.
//
//go:inline
func Reverse[A any](as []A) []A {
return G.Reverse(as)
}

260
v2/array/array_test.go
View File

@@ -22,6 +22,7 @@ import (
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/internal/utils"
N "github.com/IBM/fp-go/v2/number"
O "github.com/IBM/fp-go/v2/option"
S "github.com/IBM/fp-go/v2/string"
T "github.com/IBM/fp-go/v2/tuple"
@@ -214,3 +215,262 @@ func ExampleFoldMap() {
// Output: ABC
}
// TestReverse tests the Reverse function
func TestReverse(t *testing.T) {
t.Run("Reverse integers", func(t *testing.T) {
input := []int{1, 2, 3, 4, 5}
result := Reverse(input)
expected := []int{5, 4, 3, 2, 1}
assert.Equal(t, expected, result)
})
t.Run("Reverse strings", func(t *testing.T) {
input := []string{"hello", "world", "foo", "bar"}
result := Reverse(input)
expected := []string{"bar", "foo", "world", "hello"}
assert.Equal(t, expected, result)
})
t.Run("Reverse empty slice", func(t *testing.T) {
input := []int{}
result := Reverse(input)
assert.Equal(t, []int{}, result)
})
t.Run("Reverse single element", func(t *testing.T) {
input := []string{"only"}
result := Reverse(input)
assert.Equal(t, []string{"only"}, result)
})
t.Run("Reverse two elements", func(t *testing.T) {
input := []int{1, 2}
result := Reverse(input)
assert.Equal(t, []int{2, 1}, result)
})
t.Run("Does not modify original slice", func(t *testing.T) {
original := []int{1, 2, 3, 4, 5}
originalCopy := []int{1, 2, 3, 4, 5}
_ = Reverse(original)
assert.Equal(t, originalCopy, original)
})
t.Run("Reverse with floats", func(t *testing.T) {
input := []float64{1.1, 2.2, 3.3}
result := Reverse(input)
expected := []float64{3.3, 2.2, 1.1}
assert.Equal(t, expected, result)
})
t.Run("Reverse with structs", func(t *testing.T) {
type Person struct {
Name string
Age int
}
input := []Person{
{"Alice", 30},
{"Bob", 25},
{"Charlie", 35},
}
result := Reverse(input)
expected := []Person{
{"Charlie", 35},
{"Bob", 25},
{"Alice", 30},
}
assert.Equal(t, expected, result)
})
t.Run("Reverse with pointers", func(t *testing.T) {
a, b, c := 1, 2, 3
input := []*int{&a, &b, &c}
result := Reverse(input)
assert.Equal(t, []*int{&c, &b, &a}, result)
})
t.Run("Double reverse returns original order", func(t *testing.T) {
original := []int{1, 2, 3, 4, 5}
reversed := Reverse(original)
doubleReversed := Reverse(reversed)
assert.Equal(t, original, doubleReversed)
})
t.Run("Reverse with large slice", func(t *testing.T) {
input := MakeBy(1000, F.Identity[int])
result := Reverse(input)
// Check first and last elements
assert.Equal(t, 999, result[0])
assert.Equal(t, 0, result[999])
// Check length
assert.Equal(t, 1000, len(result))
})
t.Run("Reverse palindrome", func(t *testing.T) {
input := []int{1, 2, 3, 2, 1}
result := Reverse(input)
assert.Equal(t, input, result)
})
}
// TestReverseComposition tests Reverse with other array operations
func TestReverseComposition(t *testing.T) {
t.Run("Reverse after Map", func(t *testing.T) {
input := []int{1, 2, 3, 4, 5}
result := F.Pipe2(
input,
Map(N.Mul(2)),
Reverse[int],
)
expected := []int{10, 8, 6, 4, 2}
assert.Equal(t, expected, result)
})
t.Run("Map after Reverse", func(t *testing.T) {
input := []int{1, 2, 3, 4, 5}
result := F.Pipe2(
input,
Reverse[int],
Map(N.Mul(2)),
)
expected := []int{10, 8, 6, 4, 2}
assert.Equal(t, expected, result)
})
t.Run("Reverse with Filter", func(t *testing.T) {
input := []int{1, 2, 3, 4, 5, 6}
result := F.Pipe2(
input,
Filter(func(n int) bool { return n%2 == 0 }),
Reverse[int],
)
expected := []int{6, 4, 2}
assert.Equal(t, expected, result)
})
t.Run("Reverse with Reduce", func(t *testing.T) {
input := []string{"a", "b", "c"}
reversed := Reverse(input)
result := Reduce(func(acc, val string) string {
return acc + val
}, "")(reversed)
assert.Equal(t, "cba", result)
})
t.Run("Reverse with Flatten", func(t *testing.T) {
input := [][]int{{1, 2}, {3, 4}, {5, 6}}
result := F.Pipe2(
input,
Reverse[[]int],
Flatten[int],
)
expected := []int{5, 6, 3, 4, 1, 2}
assert.Equal(t, expected, result)
})
}
// TestReverseUseCases demonstrates practical use cases for Reverse
func TestReverseUseCases(t *testing.T) {
t.Run("Process events in reverse chronological order", func(t *testing.T) {
events := []string{"2024-01-01", "2024-01-02", "2024-01-03"}
reversed := Reverse(events)
// Most recent first
assert.Equal(t, "2024-01-03", reversed[0])
assert.Equal(t, "2024-01-01", reversed[2])
})
t.Run("Implement stack behavior (LIFO)", func(t *testing.T) {
stack := []int{1, 2, 3, 4, 5}
reversed := Reverse(stack)
// Pop from reversed (LIFO)
assert.Equal(t, 5, reversed[0])
assert.Equal(t, 4, reversed[1])
})
t.Run("Reverse string characters", func(t *testing.T) {
chars := []rune("hello")
reversed := Reverse(chars)
result := string(reversed)
assert.Equal(t, "olleh", result)
})
t.Run("Check palindrome", func(t *testing.T) {
word := []rune("racecar")
reversed := Reverse(word)
assert.Equal(t, word, reversed)
notPalindrome := []rune("hello")
reversedNot := Reverse(notPalindrome)
assert.NotEqual(t, notPalindrome, reversedNot)
})
t.Run("Reverse transformation pipeline", func(t *testing.T) {
// Apply transformations in reverse order
numbers := []int{1, 2, 3}
// Normal: add 10, then multiply by 2
normal := F.Pipe2(
numbers,
Map(N.Add(10)),
Map(N.Mul(2)),
)
// Reversed order of operations
reversed := F.Pipe2(
numbers,
Map(N.Mul(2)),
Map(N.Add(10)),
)
assert.NotEqual(t, normal, reversed)
assert.Equal(t, []int{22, 24, 26}, normal)
assert.Equal(t, []int{12, 14, 16}, reversed)
})
}
// TestReverseProperties tests mathematical properties of Reverse
func TestReverseProperties(t *testing.T) {
t.Run("Involution property: Reverse(Reverse(x)) == x", func(t *testing.T) {
testCases := [][]int{
{1, 2, 3, 4, 5},
{1},
{},
{1, 2},
{5, 4, 3, 2, 1},
}
for _, original := range testCases {
result := Reverse(Reverse(original))
assert.Equal(t, original, result)
}
})
t.Run("Length preservation: len(Reverse(x)) == len(x)", func(t *testing.T) {
testCases := [][]int{
{1, 2, 3, 4, 5},
{1},
{},
MakeBy(100, F.Identity[int]),
}
for _, input := range testCases {
result := Reverse(input)
assert.Equal(t, len(input), len(result))
}
})
t.Run("First element becomes last", func(t *testing.T) {
input := []int{1, 2, 3, 4, 5}
result := Reverse(input)
if len(input) > 0 {
assert.Equal(t, input[0], result[len(result)-1])
assert.Equal(t, input[len(input)-1], result[0])
}
})
}

2
v2/array/eq.go
View File

@@ -19,7 +19,7 @@ import (
E "github.com/IBM/fp-go/v2/eq"
)
func equals[T any](left []T, right []T, eq func(T, T) bool) bool {
func equals[T any](left, right []T, eq func(T, T) bool) bool {
if len(left) != len(right) {
return false
}

13
v2/array/generic/array.go
View File

@@ -140,22 +140,27 @@ func Empty[GA ~[]A, A any]() GA {
return array.Empty[GA]()
}
//go:inline
func UpsertAt[GA ~[]A, A any](a A) func(GA) GA {
return array.UpsertAt[GA](a)
}
//go:inline
func MonadMap[GA ~[]A, GB ~[]B, A, B any](as GA, f func(a A) B) GB {
return array.MonadMap[GA, GB](as, f)
}
//go:inline
func Map[GA ~[]A, GB ~[]B, A, B any](f func(a A) B) func(GA) GB {
return array.Map[GA, GB](f)
}
//go:inline
func MonadMapWithIndex[GA ~[]A, GB ~[]B, A, B any](as GA, f func(int, A) B) GB {
return array.MonadMapWithIndex[GA, GB](as, f)
}
//go:inline
func MapWithIndex[GA ~[]A, GB ~[]B, A, B any](f func(int, A) B) func(GA) GB {
return F.Bind2nd(MonadMapWithIndex[GA, GB, A, B], f)
}
@@ -297,7 +302,7 @@ func MatchLeft[AS ~[]A, A, B any](onEmpty func() B, onNonEmpty func(A, AS) B) fu
}
//go:inline
func Slice[AS ~[]A, A any](start int, end int) func(AS) AS {
func Slice[AS ~[]A, A any](start, end int) func(AS) AS {
return array.Slice[AS](start, end)
}
@@ -361,6 +366,12 @@ func Flap[FAB ~func(A) B, GFAB ~[]FAB, GB ~[]B, A, B any](a A) func(GFAB) GB {
return FC.Flap(Map[GFAB, GB], a)
}
//go:inline
func Prepend[ENDO ~func(AS) AS, AS []A, A any](head A) ENDO {
return array.Prepend[ENDO](head)
}
//go:inline
func Reverse[GT ~[]T, T any](as GT) GT {
return array.Reverse(as)
}

108
v2/array/nonempty/array.go
View File

@@ -18,14 +18,11 @@ package nonempty
import (
G "github.com/IBM/fp-go/v2/array/generic"
EM "github.com/IBM/fp-go/v2/endomorphism"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/internal/array"
"github.com/IBM/fp-go/v2/option"
S "github.com/IBM/fp-go/v2/semigroup"
)
// NonEmptyArray represents an array with at least one element
type NonEmptyArray[A any] []A
// Of constructs a single element array
func Of[A any](first A) NonEmptyArray[A] {
return G.Of[NonEmptyArray[A]](first)
@@ -44,20 +41,24 @@ func From[A any](first A, data ...A) NonEmptyArray[A] {
return buffer
}
//go:inline
func IsEmpty[A any](_ NonEmptyArray[A]) bool {
return false
}
//go:inline
func IsNonEmpty[A any](_ NonEmptyArray[A]) bool {
return true
}
//go:inline
func MonadMap[A, B any](as NonEmptyArray[A], f func(a A) B) NonEmptyArray[B] {
return G.MonadMap[NonEmptyArray[A], NonEmptyArray[B]](as, f)
}
func Map[A, B any](f func(a A) B) func(NonEmptyArray[A]) NonEmptyArray[B] {
return F.Bind2nd(MonadMap[A, B], f)
//go:inline
func Map[A, B any](f func(a A) B) Operator[A, B] {
return G.Map[NonEmptyArray[A], NonEmptyArray[B]](f)
}
func Reduce[A, B any](f func(B, A) B, initial B) func(NonEmptyArray[A]) B {
@@ -72,22 +73,27 @@ func ReduceRight[A, B any](f func(A, B) B, initial B) func(NonEmptyArray[A]) B {
}
}
//go:inline
func Tail[A any](as NonEmptyArray[A]) []A {
return as[1:]
}
//go:inline
func Head[A any](as NonEmptyArray[A]) A {
return as[0]
}
//go:inline
func First[A any](as NonEmptyArray[A]) A {
return as[0]
}
//go:inline
func Last[A any](as NonEmptyArray[A]) A {
return as[len(as)-1]
}
//go:inline
func Size[A any](as NonEmptyArray[A]) int {
return G.Size(as)
}
@@ -96,11 +102,11 @@ func Flatten[A any](mma NonEmptyArray[NonEmptyArray[A]]) NonEmptyArray[A] {
return G.Flatten(mma)
}
func MonadChain[A, B any](fa NonEmptyArray[A], f func(a A) NonEmptyArray[B]) NonEmptyArray[B] {
func MonadChain[A, B any](fa NonEmptyArray[A], f Kleisli[A, B]) NonEmptyArray[B] {
return G.MonadChain(fa, f)
}
func Chain[A, B any](f func(A) NonEmptyArray[B]) func(NonEmptyArray[A]) NonEmptyArray[B] {
func Chain[A, B any](f func(A) NonEmptyArray[B]) Operator[A, B] {
return G.Chain[NonEmptyArray[A]](f)
}
@@ -134,3 +140,89 @@ func Fold[A any](s S.Semigroup[A]) func(NonEmptyArray[A]) A {
func Prepend[A any](head A) EM.Endomorphism[NonEmptyArray[A]] {
return array.Prepend[EM.Endomorphism[NonEmptyArray[A]]](head)
}
// ToNonEmptyArray attempts to convert a regular slice into a NonEmptyArray.
// This function provides a safe way to create a NonEmptyArray from a slice that might be empty,
// returning an Option type to handle the case where the input slice is empty.
//
// Type Parameters:
// - A: The element type of the array
//
// Parameters:
// - as: A regular slice that may or may not be empty
//
// Returns:
// - Option[NonEmptyArray[A]]: Some(NonEmptyArray) if the input slice is non-empty, None if empty
//
// Behavior:
// - If the input slice is empty, returns None
// - If the input slice has at least one element, wraps it in Some and returns it as a NonEmptyArray
// - The conversion is a type cast, so no data is copied
//
// Example:
//
// // Convert non-empty slice
// numbers := []int{1, 2, 3}
// result := ToNonEmptyArray(numbers) // Some(NonEmptyArray[1, 2, 3])
//
// // Convert empty slice
// empty := []int{}
// result := ToNonEmptyArray(empty) // None
//
// // Use with Option methods
// numbers := []int{1, 2, 3}
// result := ToNonEmptyArray(numbers)
// if O.IsSome(result) {
// nea := O.GetOrElse(F.Constant(From(0)))(result)
// head := Head(nea) // 1
// }
//
// Use cases:
// - Safely converting user input or external data to NonEmptyArray
// - Validating that a collection has at least one element before processing
// - Converting results from functions that return regular slices
// - Ensuring type safety when working with collections that must not be empty
//
// Example with validation:
//
// func processItems(items []string) Option[string] {
// return F.Pipe2(
// items,
// ToNonEmptyArray[string],
// O.Map(func(nea NonEmptyArray[string]) string {
// return Head(nea) // Safe to get head since we know it's non-empty
// }),
// )
// }
//
// Example with error handling:
//
// items := []int{1, 2, 3}
// result := ToNonEmptyArray(items)
// switch {
// case O.IsSome(result):
// nea := O.GetOrElse(F.Constant(From(0)))(result)
// fmt.Println("First item:", Head(nea))
// case O.IsNone(result):
// fmt.Println("Array is empty")
// }
//
// Example with chaining:
//
// // Process only if non-empty
// result := F.Pipe3(
// []int{1, 2, 3},
// ToNonEmptyArray[int],
// O.Map(Map(func(x int) int { return x * 2 })),
// O.Map(Head[int]),
// ) // Some(2)
//
// Note: This function is particularly useful when working with APIs or functions
// that return regular slices but you need the type-level guarantee that the
// collection is non-empty for subsequent operations.
func ToNonEmptyArray[A any](as []A) Option[NonEmptyArray[A]] {
if G.IsEmpty(as) {
return option.None[NonEmptyArray[A]]()
}
return option.Some(NonEmptyArray[A](as))
}

370
v2/array/nonempty/array_test.go Normal file
View File

@@ -0,0 +1,370 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package nonempty
import (
"testing"
F "github.com/IBM/fp-go/v2/function"
O "github.com/IBM/fp-go/v2/option"
"github.com/stretchr/testify/assert"
)
// TestToNonEmptyArray tests the ToNonEmptyArray function
func TestToNonEmptyArray(t *testing.T) {
t.Run("Convert non-empty slice of integers", func(t *testing.T) {
input := []int{1, 2, 3}
result := ToNonEmptyArray(input)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From(0)))(result)
assert.Equal(t, 3, Size(nea))
assert.Equal(t, 1, Head(nea))
assert.Equal(t, 3, Last(nea))
})
t.Run("Convert empty slice returns None", func(t *testing.T) {
input := []int{}
result := ToNonEmptyArray(input)
assert.True(t, O.IsNone(result))
})
t.Run("Convert single element slice", func(t *testing.T) {
input := []string{"hello"}
result := ToNonEmptyArray(input)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From("")))(result)
assert.Equal(t, 1, Size(nea))
assert.Equal(t, "hello", Head(nea))
})
t.Run("Convert non-empty slice of strings", func(t *testing.T) {
input := []string{"a", "b", "c", "d"}
result := ToNonEmptyArray(input)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From("")))(result)
assert.Equal(t, 4, Size(nea))
assert.Equal(t, "a", Head(nea))
assert.Equal(t, "d", Last(nea))
})
t.Run("Convert nil slice returns None", func(t *testing.T) {
var input []int
result := ToNonEmptyArray(input)
assert.True(t, O.IsNone(result))
})
t.Run("Convert slice with struct elements", func(t *testing.T) {
type Person struct {
Name string
Age int
}
input := []Person{
{Name: "Alice", Age: 30},
{Name: "Bob", Age: 25},
}
result := ToNonEmptyArray(input)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From(Person{})))(result)
assert.Equal(t, 2, Size(nea))
assert.Equal(t, "Alice", Head(nea).Name)
})
t.Run("Convert slice with pointer elements", func(t *testing.T) {
val1, val2 := 10, 20
input := []*int{&val1, &val2}
result := ToNonEmptyArray(input)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From[*int](nil)))(result)
assert.Equal(t, 2, Size(nea))
assert.Equal(t, 10, *Head(nea))
})
t.Run("Convert large slice", func(t *testing.T) {
input := make([]int, 1000)
for i := range input {
input[i] = i
}
result := ToNonEmptyArray(input)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From(0)))(result)
assert.Equal(t, 1000, Size(nea))
assert.Equal(t, 0, Head(nea))
assert.Equal(t, 999, Last(nea))
})
t.Run("Convert slice with float64 elements", func(t *testing.T) {
input := []float64{1.5, 2.5, 3.5}
result := ToNonEmptyArray(input)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From(0.0)))(result)
assert.Equal(t, 3, Size(nea))
assert.Equal(t, 1.5, Head(nea))
})
t.Run("Convert slice with boolean elements", func(t *testing.T) {
input := []bool{true, false, true}
result := ToNonEmptyArray(input)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From(false)))(result)
assert.Equal(t, 3, Size(nea))
assert.True(t, Head(nea))
})
}
// TestToNonEmptyArrayWithOption tests ToNonEmptyArray with Option operations
func TestToNonEmptyArrayWithOption(t *testing.T) {
t.Run("Chain with Map to process elements", func(t *testing.T) {
input := []int{1, 2, 3}
result := F.Pipe2(
input,
ToNonEmptyArray[int],
O.Map(Map(func(x int) int { return x * 2 })),
)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From(0)))(result)
assert.Equal(t, 2, Head(nea))
assert.Equal(t, 6, Last(nea))
})
t.Run("Chain with Map to get head", func(t *testing.T) {
input := []string{"first", "second", "third"}
result := F.Pipe2(
input,
ToNonEmptyArray[string],
O.Map(Head[string]),
)
assert.True(t, O.IsSome(result))
value := O.GetOrElse(F.Constant(""))(result)
assert.Equal(t, "first", value)
})
t.Run("GetOrElse with default value for empty slice", func(t *testing.T) {
input := []int{}
defaultValue := From(42)
result := F.Pipe2(
input,
ToNonEmptyArray[int],
O.GetOrElse(F.Constant(defaultValue)),
)
assert.Equal(t, 1, Size(result))
assert.Equal(t, 42, Head(result))
})
t.Run("GetOrElse with default value for non-empty slice", func(t *testing.T) {
input := []int{1, 2, 3}
defaultValue := From(42)
result := F.Pipe2(
input,
ToNonEmptyArray[int],
O.GetOrElse(F.Constant(defaultValue)),
)
assert.Equal(t, 3, Size(result))
assert.Equal(t, 1, Head(result))
})
t.Run("Fold with Some case", func(t *testing.T) {
input := []int{1, 2, 3}
result := F.Pipe2(
input,
ToNonEmptyArray[int],
O.Fold(
F.Constant(0),
func(nea NonEmptyArray[int]) int { return Head(nea) },
),
)
assert.Equal(t, 1, result)
})
t.Run("Fold with None case", func(t *testing.T) {
input := []int{}
result := F.Pipe2(
input,
ToNonEmptyArray[int],
O.Fold(
F.Constant(-1),
func(nea NonEmptyArray[int]) int { return Head(nea) },
),
)
assert.Equal(t, -1, result)
})
}
// TestToNonEmptyArrayComposition tests composing ToNonEmptyArray with other operations
func TestToNonEmptyArrayComposition(t *testing.T) {
t.Run("Compose with filter-like operation", func(t *testing.T) {
input := []int{1, 2, 3, 4, 5}
// Filter even numbers then convert
filtered := []int{}
for _, x := range input {
if x%2 == 0 {
filtered = append(filtered, x)
}
}
result := ToNonEmptyArray(filtered)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From(0)))(result)
assert.Equal(t, 2, Size(nea))
assert.Equal(t, 2, Head(nea))
})
t.Run("Compose with map operation before conversion", func(t *testing.T) {
input := []int{1, 2, 3}
// Map then convert
mapped := make([]int, len(input))
for i, x := range input {
mapped[i] = x * 10
}
result := ToNonEmptyArray(mapped)
assert.True(t, O.IsSome(result))
nea := O.GetOrElse(F.Constant(From(0)))(result)
assert.Equal(t, 10, Head(nea))
assert.Equal(t, 30, Last(nea))
})
t.Run("Chain multiple Option operations", func(t *testing.T) {
input := []int{5, 10, 15}
result := F.Pipe3(
input,
ToNonEmptyArray[int],
O.Map(Map(func(x int) int { return x / 5 })),
O.Map(func(nea NonEmptyArray[int]) int {
return Head(nea) + Last(nea)
}),
)
assert.True(t, O.IsSome(result))
value := O.GetOrElse(F.Constant(0))(result)
assert.Equal(t, 4, value) // 1 + 3
})
}
// TestToNonEmptyArrayUseCases demonstrates practical use cases
func TestToNonEmptyArrayUseCases(t *testing.T) {
t.Run("Validate user input has at least one item", func(t *testing.T) {
// Simulate user input
userInput := []string{"item1", "item2"}
result := ToNonEmptyArray(userInput)
if O.IsSome(result) {
nea := O.GetOrElse(F.Constant(From("")))(result)
firstItem := Head(nea)
assert.Equal(t, "item1", firstItem)
} else {
t.Fatal("Expected Some but got None")
}
})
t.Run("Process only non-empty collections", func(t *testing.T) {
processItems := func(items []int) Option[int] {
return F.Pipe2(
items,
ToNonEmptyArray[int],
O.Map(func(nea NonEmptyArray[int]) int {
// Safe to use Head since we know it's non-empty
return Head(nea) * 2
}),
)
}
result1 := processItems([]int{5, 10, 15})
assert.True(t, O.IsSome(result1))
assert.Equal(t, 10, O.GetOrElse(F.Constant(0))(result1))
result2 := processItems([]int{})
assert.True(t, O.IsNone(result2))
})
t.Run("Convert API response to NonEmptyArray", func(t *testing.T) {
// Simulate API response
type APIResponse struct {
Items []string
}
response := APIResponse{Items: []string{"data1", "data2", "data3"}}
result := F.Pipe2(
response.Items,
ToNonEmptyArray[string],
O.Map(func(nea NonEmptyArray[string]) string {
return "First item: " + Head(nea)
}),
)
assert.True(t, O.IsSome(result))
message := O.GetOrElse(F.Constant("No items"))(result)
assert.Equal(t, "First item: data1", message)
})
t.Run("Ensure collection is non-empty before processing", func(t *testing.T) {
calculateAverage := func(numbers []float64) Option[float64] {
return F.Pipe2(
numbers,
ToNonEmptyArray[float64],
O.Map(func(nea NonEmptyArray[float64]) float64 {
sum := 0.0
for _, n := range nea {
sum += n
}
return sum / float64(Size(nea))
}),
)
}
result1 := calculateAverage([]float64{10.0, 20.0, 30.0})
assert.True(t, O.IsSome(result1))
assert.Equal(t, 20.0, O.GetOrElse(F.Constant(0.0))(result1))
result2 := calculateAverage([]float64{})
assert.True(t, O.IsNone(result2))
})
t.Run("Safe head extraction with type guarantee", func(t *testing.T) {
getFirstOrDefault := func(items []string, defaultValue string) string {
return F.Pipe2(
items,
ToNonEmptyArray[string],
O.Fold(
F.Constant(defaultValue),
Head[string],
),
)
}
result1 := getFirstOrDefault([]string{"a", "b", "c"}, "default")
assert.Equal(t, "a", result1)
result2 := getFirstOrDefault([]string{}, "default")
assert.Equal(t, "default", result2)
})
}

15
v2/array/nonempty/types.go Normal file
View File

@@ -0,0 +1,15 @@
package nonempty
import "github.com/IBM/fp-go/v2/option"
type (
// NonEmptyArray represents an array with at least one element
NonEmptyArray[A any] []A
Kleisli[A, B any] = func(A) NonEmptyArray[B]
Operator[A, B any] = Kleisli[NonEmptyArray[A], B]
Option[A any] = option.Option[A]
)

272
v2/assert/assert.go
View File

@@ -19,6 +19,58 @@
// allowing for composable and functional test assertions. Each assertion
// returns a Reader that takes a *testing.T and performs the assertion.
//
// # Data Last Principle
//
// This package follows the "data last" functional programming principle, where
// the data being operated on comes as the last parameter in a chain of function
// applications. This design enables several powerful functional programming patterns:
//
// 1. **Partial Application**: You can create reusable assertion functions by providing
// configuration parameters first, leaving the data and testing context for later.
//
// 2. **Function Composition**: Assertions can be composed and combined before being
// applied to actual data.
//
// 3. **Point-Free Style**: You can pass assertion functions around without immediately
// providing the data they operate on.
//
// The general pattern is:
//
// assert.Function(config)(data)(testingContext)
// ↑ ↑ ↑
// expected actual *testing.T (always last)
//
// For single-parameter assertions:
//
// assert.Function(data)(testingContext)
// ↑ ↑
// actual *testing.T (always last)
//
// Examples of "data last" in action:
//
// // Multi-parameter: expected value → actual value → testing context
// assert.Equal(42)(result)(t)
// assert.ArrayContains(3)(numbers)(t)
//
// // Single-parameter: data → testing context
// assert.NoError(err)(t)
// assert.ArrayNotEmpty(arr)(t)
//
// // Partial application - create reusable assertions
// isPositive := assert.That(func(n int) bool { return n > 0 })
// // Later, apply to different values:
// isPositive(42)(t) // Passes
// isPositive(-5)(t) // Fails
//
// // Composition - combine assertions before applying data
// validateUser := func(u User) assert.Reader {
// return assert.AllOf([]assert.Reader{
// assert.Equal("Alice")(u.Name),
// assert.That(func(age int) bool { return age >= 18 })(u.Age),
// })
// }
// validateUser(user)(t)
//
// The package supports:
// - Equality and inequality assertions
// - Collection assertions (arrays, maps, strings)
@@ -83,38 +135,108 @@ func wrap1[T any](wrapped func(t assert.TestingT, expected, actual any, msgAndAr
}
}
// NotEqual tests if the expected and the actual values are not equal
// NotEqual tests if the expected and the actual values are not equal.
//
// This function follows the "data last" principle - you provide the expected value first,
// then the actual value, and finally the testing.T context.
//
// Example:
//
// func TestNotEqual(t *testing.T) {
// value := 42
// assert.NotEqual(10)(value)(t) // Passes: 42 != 10
// assert.NotEqual(42)(value)(t) // Fails: 42 == 42
// }
func NotEqual[T any](expected T) Kleisli[T] {
return wrap1(assert.NotEqual, expected)
}
// Equal tests if the expected and the actual values are equal
// Equal tests if the expected and the actual values are equal.
//
// This is one of the most commonly used assertions. It follows the "data last" principle -
// you provide the expected value first, then the actual value, and finally the testing.T context.
//
// Example:
//
// func TestEqual(t *testing.T) {
// result := 2 + 2
// assert.Equal(4)(result)(t) // Passes
//
// name := "Alice"
// assert.Equal("Alice")(name)(t) // Passes
//
// // Can be composed with other assertions
// user := User{Name: "Bob", Age: 30}
// assertions := assert.AllOf([]assert.Reader{
// assert.Equal("Bob")(user.Name),
// assert.Equal(30)(user.Age),
// })
// assertions(t)
// }
func Equal[T any](expected T) Kleisli[T] {
return wrap1(assert.Equal, expected)
}
// ArrayNotEmpty checks if an array is not empty
// ArrayNotEmpty checks if an array is not empty.
//
// Example:
//
// func TestArrayNotEmpty(t *testing.T) {
// numbers := []int{1, 2, 3}
// assert.ArrayNotEmpty(numbers)(t) // Passes
//
// empty := []int{}
// assert.ArrayNotEmpty(empty)(t) // Fails
// }
func ArrayNotEmpty[T any](arr []T) Reader {
return func(t *testing.T) bool {
return assert.NotEmpty(t, arr)
}
}
// RecordNotEmpty checks if an map is not empty
// RecordNotEmpty checks if a map is not empty.
//
// Example:
//
// func TestRecordNotEmpty(t *testing.T) {
// config := map[string]int{"timeout": 30, "retries": 3}
// assert.RecordNotEmpty(config)(t) // Passes
//
// empty := map[string]int{}
// assert.RecordNotEmpty(empty)(t) // Fails
// }
func RecordNotEmpty[K comparable, T any](mp map[K]T) Reader {
return func(t *testing.T) bool {
return assert.NotEmpty(t, mp)
}
}
// StringNotEmpty checks if a string is not empty
// StringNotEmpty checks if a string is not empty.
//
// Example:
//
// func TestStringNotEmpty(t *testing.T) {
// message := "Hello, World!"
// assert.StringNotEmpty(message)(t) // Passes
//
// empty := ""
// assert.StringNotEmpty(empty)(t) // Fails
// }
func StringNotEmpty(s string) Reader {
return func(t *testing.T) bool {
return assert.NotEmpty(t, s)
}
}
// ArrayLength tests if an array has the expected length
// ArrayLength tests if an array has the expected length.
//
// Example:
//
// func TestArrayLength(t *testing.T) {
// numbers := []int{1, 2, 3, 4, 5}
// assert.ArrayLength[int](5)(numbers)(t) // Passes
// assert.ArrayLength[int](3)(numbers)(t) // Fails
// }
func ArrayLength[T any](expected int) Kleisli[[]T] {
return func(actual []T) Reader {
return func(t *testing.T) bool {
@@ -123,7 +245,15 @@ func ArrayLength[T any](expected int) Kleisli[[]T] {
}
}
// RecordLength tests if a map has the expected length
// RecordLength tests if a map has the expected length.
//
// Example:
//
// func TestRecordLength(t *testing.T) {
// config := map[string]string{"host": "localhost", "port": "8080"}
// assert.RecordLength[string, string](2)(config)(t) // Passes
// assert.RecordLength[string, string](3)(config)(t) // Fails
// }
func RecordLength[K comparable, T any](expected int) Kleisli[map[K]T] {
return func(actual map[K]T) Reader {
return func(t *testing.T) bool {
@@ -132,7 +262,15 @@ func RecordLength[K comparable, T any](expected int) Kleisli[map[K]T] {
}
}
// StringLength tests if a string has the expected length
// StringLength tests if a string has the expected length.
//
// Example:
//
// func TestStringLength(t *testing.T) {
// message := "Hello"
// assert.StringLength[any, any](5)(message)(t) // Passes
// assert.StringLength[any, any](10)(message)(t) // Fails
// }
func StringLength[K comparable, T any](expected int) Kleisli[string] {
return func(actual string) Reader {
return func(t *testing.T) bool {
@@ -141,31 +279,93 @@ func StringLength[K comparable, T any](expected int) Kleisli[string] {
}
}
// NoError validates that there is no error
// NoError validates that there is no error.
//
// This is commonly used to assert that operations complete successfully.
//
// Example:
//
// func TestNoError(t *testing.T) {
// err := doSomething()
// assert.NoError(err)(t) // Passes if err is nil
//
// // Can be used with result types
// result := result.TryCatch(func() (int, error) {
// return 42, nil
// })
// assert.Success(result)(t) // Uses NoError internally
// }
func NoError(err error) Reader {
return func(t *testing.T) bool {
return assert.NoError(t, err)
}
}
// Error validates that there is an error
// Error validates that there is an error.
//
// This is used to assert that operations fail as expected.
//
// Example:
//
// func TestError(t *testing.T) {
// err := validateInput("")
// assert.Error(err)(t) // Passes if err is not nil
//
// err2 := validateInput("valid")
// assert.Error(err2)(t) // Fails if err2 is nil
// }
func Error(err error) Reader {
return func(t *testing.T) bool {
return assert.Error(t, err)
}
}
// Success checks if a [Result] represents success
// Success checks if a [Result] represents success.
//
// This is a convenience function for testing Result types from the fp-go library.
//
// Example:
//
// func TestSuccess(t *testing.T) {
// res := result.Of[int](42)
// assert.Success(res)(t) // Passes
//
// failedRes := result.Error[int](errors.New("failed"))
// assert.Success(failedRes)(t) // Fails
// }
func Success[T any](res Result[T]) Reader {
return NoError(result.ToError(res))
}
// Failure checks if a [Result] represents failure
// Failure checks if a [Result] represents failure.
//
// This is a convenience function for testing Result types from the fp-go library.
//
// Example:
//
// func TestFailure(t *testing.T) {
// res := result.Error[int](errors.New("something went wrong"))
// assert.Failure(res)(t) // Passes
//
// successRes := result.Of[int](42)
// assert.Failure(successRes)(t) // Fails
// }
func Failure[T any](res Result[T]) Reader {
return Error(result.ToError(res))
}
// ArrayContains tests if a value is contained in an array
// ArrayContains tests if a value is contained in an array.
//
// Example:
//
// func TestArrayContains(t *testing.T) {
// numbers := []int{1, 2, 3, 4, 5}
// assert.ArrayContains(3)(numbers)(t) // Passes
// assert.ArrayContains(10)(numbers)(t) // Fails
//
// names := []string{"Alice", "Bob", "Charlie"}
// assert.ArrayContains("Bob")(names)(t) // Passes
// }
func ArrayContains[T any](expected T) Kleisli[[]T] {
return func(actual []T) Reader {
return func(t *testing.T) bool {
@@ -174,7 +374,15 @@ func ArrayContains[T any](expected T) Kleisli[[]T] {
}
}
// ContainsKey tests if a key is contained in a map
// ContainsKey tests if a key is contained in a map.
//
// Example:
//
// func TestContainsKey(t *testing.T) {
// config := map[string]int{"timeout": 30, "retries": 3}
// assert.ContainsKey[int]("timeout")(config)(t) // Passes
// assert.ContainsKey[int]("maxSize")(config)(t) // Fails
// }
func ContainsKey[T any, K comparable](expected K) Kleisli[map[K]T] {
return func(actual map[K]T) Reader {
return func(t *testing.T) bool {
@@ -183,7 +391,15 @@ func ContainsKey[T any, K comparable](expected K) Kleisli[map[K]T] {
}
}
// NotContainsKey tests if a key is not contained in a map
// NotContainsKey tests if a key is not contained in a map.
//
// Example:
//
// func TestNotContainsKey(t *testing.T) {
// config := map[string]int{"timeout": 30, "retries": 3}
// assert.NotContainsKey[int]("maxSize")(config)(t) // Passes
// assert.NotContainsKey[int]("timeout")(config)(t) // Fails
// }
func NotContainsKey[T any, K comparable](expected K) Kleisli[map[K]T] {
return func(actual map[K]T) Reader {
return func(t *testing.T) bool {
@@ -192,7 +408,31 @@ func NotContainsKey[T any, K comparable](expected K) Kleisli[map[K]T] {
}
}
// That asserts that a particular predicate matches
// That asserts that a particular predicate matches.
//
// This is a powerful function that allows you to create custom assertions using predicates.
//
// Example:
//
// func TestThat(t *testing.T) {
// // Test if a number is positive
// isPositive := func(n int) bool { return n > 0 }
// assert.That(isPositive)(42)(t) // Passes
// assert.That(isPositive)(-5)(t) // Fails
//
// // Test if a string is uppercase
// isUppercase := func(s string) bool { return s == strings.ToUpper(s) }
// assert.That(isUppercase)("HELLO")(t) // Passes
// assert.That(isUppercase)("Hello")(t) // Fails
//
// // Can be combined with Local for property testing
// type User struct { Age int }
// ageIsAdult := assert.Local(func(u User) int { return u.Age })(
// assert.That(func(age int) bool { return age >= 18 }),
// )
// user := User{Age: 25}
// ageIsAdult(user)(t) // Passes
// }
func That[T any](pred Predicate[T]) Kleisli[T] {
return func(a T) Reader {
return func(t *testing.T) bool {

5
v2/assert/assert_test.go
View File

@@ -22,6 +22,7 @@ import (
"github.com/IBM/fp-go/v2/optics/prism"
"github.com/IBM/fp-go/v2/option"
"github.com/IBM/fp-go/v2/result"
S "github.com/IBM/fp-go/v2/string"
)
func TestEqual(t *testing.T) {
@@ -334,7 +335,7 @@ func TestThat(t *testing.T) {
})
t.Run("should work with string predicates", func(t *testing.T) {
startsWithH := func(s string) bool { return len(s) > 0 && s[0] == 'h' }
startsWithH := func(s string) bool { return S.IsNonEmpty(s) && s[0] == 'h' }
result := That(startsWithH)("hello")(t)
if !result {
t.Error("Expected That to pass for string predicate")
@@ -484,7 +485,7 @@ func TestLocal(t *testing.T) {
t.Run("should compose with other assertions", func(t *testing.T) {
// Create multiple focused assertions
nameNotEmpty := Local(func(u User) string { return u.Name })(
That(func(name string) bool { return len(name) > 0 }),
That(S.IsNonEmpty),
)
ageInRange := Local(func(u User) int { return u.Age })(
That(func(age int) bool { return age >= 18 && age <= 100 }),

235
v2/assert/example_test.go Normal file
View File

@@ -0,0 +1,235 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package assert_test
import (
"errors"
"strings"
"testing"
"github.com/IBM/fp-go/v2/assert"
"github.com/IBM/fp-go/v2/result"
)
// Example_basicAssertions demonstrates basic equality and inequality assertions
func Example_basicAssertions() {
// This would be in a real test function
var t *testing.T // placeholder for example
// Basic equality
value := 42
assert.Equal(42)(value)(t)
// String equality
name := "Alice"
assert.Equal("Alice")(name)(t)
// Inequality
assert.NotEqual(10)(value)(t)
}
// Example_arrayAssertions demonstrates array-related assertions
func Example_arrayAssertions() {
var t *testing.T // placeholder for example
numbers := []int{1, 2, 3, 4, 5}
// Check array is not empty
assert.ArrayNotEmpty(numbers)(t)
// Check array length
assert.ArrayLength[int](5)(numbers)(t)
// Check array contains a value
assert.ArrayContains(3)(numbers)(t)
}
// Example_mapAssertions demonstrates map-related assertions
func Example_mapAssertions() {
var t *testing.T // placeholder for example
config := map[string]int{
"timeout": 30,
"retries": 3,
"maxSize": 1000,
}
// Check map is not empty
assert.RecordNotEmpty(config)(t)
// Check map length
assert.RecordLength[string, int](3)(config)(t)
// Check map contains key
assert.ContainsKey[int]("timeout")(config)(t)
// Check map does not contain key
assert.NotContainsKey[int]("unknown")(config)(t)
}
// Example_errorAssertions demonstrates error-related assertions
func Example_errorAssertions() {
var t *testing.T // placeholder for example
// Assert no error
err := doSomethingSuccessful()
assert.NoError(err)(t)
// Assert error exists
err2 := doSomethingThatFails()
assert.Error(err2)(t)
}
// Example_resultAssertions demonstrates Result type assertions
func Example_resultAssertions() {
var t *testing.T // placeholder for example
// Assert success
successResult := result.Of[int](42)
assert.Success(successResult)(t)
// Assert failure
failureResult := result.Left[int](errors.New("something went wrong"))
assert.Failure(failureResult)(t)
}
// Example_predicateAssertions demonstrates custom predicate assertions
func Example_predicateAssertions() {
var t *testing.T // placeholder for example
// Test if a number is positive
isPositive := func(n int) bool { return n > 0 }
assert.That(isPositive)(42)(t)
// Test if a string is uppercase
isUppercase := func(s string) bool { return s == strings.ToUpper(s) }
assert.That(isUppercase)("HELLO")(t)
// Test if a number is even
isEven := func(n int) bool { return n%2 == 0 }
assert.That(isEven)(10)(t)
}
// Example_allOf demonstrates combining multiple assertions
func Example_allOf() {
var t *testing.T // placeholder for example
type User struct {
Name string
Age int
Active bool
}
user := User{Name: "Alice", Age: 30, Active: true}
// Combine multiple assertions
assertions := assert.AllOf([]assert.Reader{
assert.Equal("Alice")(user.Name),
assert.Equal(30)(user.Age),
assert.Equal(true)(user.Active),
})
assertions(t)
}
// Example_runAll demonstrates running named test cases
func Example_runAll() {
var t *testing.T // placeholder for example
testcases := map[string]assert.Reader{
"addition": assert.Equal(4)(2 + 2),
"multiplication": assert.Equal(6)(2 * 3),
"subtraction": assert.Equal(1)(3 - 2),
"division": assert.Equal(2)(10 / 5),
}
assert.RunAll(testcases)(t)
}
// Example_local demonstrates focusing assertions on specific properties
func Example_local() {
var t *testing.T // placeholder for example
type User struct {
Name string
Age int
}
// Create an assertion that checks if age is positive
ageIsPositive := assert.That(func(age int) bool { return age > 0 })
// Focus this assertion on the Age field of User
userAgeIsPositive := assert.Local(func(u User) int { return u.Age })(ageIsPositive)
// Now we can test the whole User object
user := User{Name: "Alice", Age: 30}
userAgeIsPositive(user)(t)
}
// Example_composableAssertions demonstrates building complex assertions
func Example_composableAssertions() {
var t *testing.T // placeholder for example
type Config struct {
Host string
Port int
Timeout int
Retries int
}
config := Config{
Host: "localhost",
Port: 8080,
Timeout: 30,
Retries: 3,
}
// Create focused assertions for each field
validHost := assert.Local(func(c Config) string { return c.Host })(
assert.StringNotEmpty,
)
validPort := assert.Local(func(c Config) int { return c.Port })(
assert.That(func(p int) bool { return p > 0 && p < 65536 }),
)
validTimeout := assert.Local(func(c Config) int { return c.Timeout })(
assert.That(func(t int) bool { return t > 0 }),
)
validRetries := assert.Local(func(c Config) int { return c.Retries })(
assert.That(func(r int) bool { return r >= 0 }),
)
// Combine all assertions
validConfig := assert.AllOf([]assert.Reader{
validHost(config),
validPort(config),
validTimeout(config),
validRetries(config),
})
validConfig(t)
}
// Helper functions for examples
func doSomethingSuccessful() error {
return nil
}
func doSomethingThatFails() error {
return errors.New("operation failed")
}

2
v2/builder/prism.go
View File

@@ -8,5 +8,5 @@ import (
// BuilderPrism createa a [Prism] that converts between a builder and its type
func BuilderPrism[T any, B Builder[T]](creator func(T) B) Prism[B, T] {
return prism.MakePrism(F.Flow2(B.Build, result.ToOption[T]), creator)
return prism.MakePrismWithName(F.Flow2(B.Build, result.ToOption[T]), creator, "BuilderPrism")
}

169
v2/cli/lens.go
View File

@@ -27,13 +27,15 @@ import (
"strings"
"text/template"
S "github.com/IBM/fp-go/v2/string"
C "github.com/urfave/cli/v2"
)
const (
keyLensDir = "dir"
keyVerbose = "verbose"
lensAnnotation = "fp-go:Lens"
keyLensDir = "dir"
keyVerbose = "verbose"
keyIncludeTestFile = "include-test-files"
lensAnnotation = "fp-go:Lens"
)
var (
@@ -49,6 +51,13 @@ var (
Value: false,
Usage: "Enable verbose output",
}
flagIncludeTestFiles = &C.BoolFlag{
Name: keyIncludeTestFile,
Aliases: []string{"t"},
Value: false,
Usage: "Include test files (*_test.go) when scanning for annotated types",
}
)
// structInfo holds information about a struct that needs lens generation
@@ -67,6 +76,7 @@ type fieldInfo struct {
BaseType string // TypeName without leading * for pointer types
IsOptional bool // true if field is a pointer or has json omitempty tag
IsComparable bool // true if the type is comparable (can use ==)
IsEmbedded bool // true if this field comes from an embedded struct
}
// templateData holds data for template rendering
@@ -80,12 +90,12 @@ const lensStructTemplate = `
type {{.Name}}Lenses{{.TypeParams}} struct {
// mandatory fields
{{- range .Fields}}
{{.Name}} L.Lens[{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{.Name}} __lens.Lens[{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{- end}}
// optional fields
{{- range .Fields}}
{{- if .IsComparable}}
{{.Name}}O LO.LensO[{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{.Name}}O __lens_option.LensO[{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{- end}}
{{- end}}
}
@@ -94,13 +104,24 @@ type {{.Name}}Lenses{{.TypeParams}} struct {
type {{.Name}}RefLenses{{.TypeParams}} struct {
// mandatory fields
{{- range .Fields}}
{{.Name}} L.Lens[*{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{.Name}} __lens.Lens[*{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{- end}}
// optional fields
{{- range .Fields}}
{{- if .IsComparable}}
{{.Name}}O LO.LensO[*{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{.Name}}O __lens_option.LensO[*{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{- end}}
{{- end}}
// prisms
{{- range .Fields}}
{{.Name}}P __prism.Prism[*{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{- end}}
}
// {{.Name}}Prisms provides prisms for accessing fields of {{.Name}}
type {{.Name}}Prisms{{.TypeParams}} struct {
{{- range .Fields}}
{{.Name}} __prism.Prism[{{$.Name}}{{$.TypeParamNames}}, {{.TypeName}}]
{{- end}}
}
`
@@ -110,15 +131,16 @@ const lensConstructorTemplate = `
func Make{{.Name}}Lenses{{.TypeParams}}() {{.Name}}Lenses{{.TypeParamNames}} {
// mandatory lenses
{{- range .Fields}}
lens{{.Name}} := L.MakeLens(
lens{{.Name}} := __lens.MakeLensWithName(
func(s {{$.Name}}{{$.TypeParamNames}}) {{.TypeName}} { return s.{{.Name}} },
func(s {{$.Name}}{{$.TypeParamNames}}, v {{.TypeName}}) {{$.Name}}{{$.TypeParamNames}} { s.{{.Name}} = v; return s },
"{{$.Name}}{{$.TypeParamNames}}.{{.Name}}",
)
{{- end}}
// optional lenses
{{- range .Fields}}
{{- if .IsComparable}}
lens{{.Name}}O := LO.FromIso[{{$.Name}}{{$.TypeParamNames}}](IO.FromZero[{{.TypeName}}]())(lens{{.Name}})
lens{{.Name}}O := __lens_option.FromIso[{{$.Name}}{{$.TypeParamNames}}](__iso_option.FromZero[{{.TypeName}}]())(lens{{.Name}})
{{- end}}
{{- end}}
return {{.Name}}Lenses{{.TypeParamNames}}{
@@ -140,21 +162,23 @@ func Make{{.Name}}RefLenses{{.TypeParams}}() {{.Name}}RefLenses{{.TypeParamNames
// mandatory lenses
{{- range .Fields}}
{{- if .IsComparable}}
lens{{.Name}} := L.MakeLensStrict(
lens{{.Name}} := __lens.MakeLensStrictWithName(
func(s *{{$.Name}}{{$.TypeParamNames}}) {{.TypeName}} { return s.{{.Name}} },
func(s *{{$.Name}}{{$.TypeParamNames}}, v {{.TypeName}}) *{{$.Name}}{{$.TypeParamNames}} { s.{{.Name}} = v; return s },
"(*{{$.Name}}{{$.TypeParamNames}}).{{.Name}}",
)
{{- else}}
lens{{.Name}} := L.MakeLensRef(
lens{{.Name}} := __lens.MakeLensRefWithName(
func(s *{{$.Name}}{{$.TypeParamNames}}) {{.TypeName}} { return s.{{.Name}} },
func(s *{{$.Name}}{{$.TypeParamNames}}, v {{.TypeName}}) *{{$.Name}}{{$.TypeParamNames}} { s.{{.Name}} = v; return s },
"(*{{$.Name}}{{$.TypeParamNames}}).{{.Name}}",
)
{{- end}}
{{- end}}
// optional lenses
{{- range .Fields}}
{{- if .IsComparable}}
lens{{.Name}}O := LO.FromIso[*{{$.Name}}{{$.TypeParamNames}}](IO.FromZero[{{.TypeName}}]())(lens{{.Name}})
lens{{.Name}}O := __lens_option.FromIso[*{{$.Name}}{{$.TypeParamNames}}](__iso_option.FromZero[{{.TypeName}}]())(lens{{.Name}})
{{- end}}
{{- end}}
return {{.Name}}RefLenses{{.TypeParamNames}}{
@@ -170,6 +194,47 @@ func Make{{.Name}}RefLenses{{.TypeParams}}() {{.Name}}RefLenses{{.TypeParamNames
{{- end}}
}
}
// Make{{.Name}}Prisms creates a new {{.Name}}Prisms with prisms for all fields
func Make{{.Name}}Prisms{{.TypeParams}}() {{.Name}}Prisms{{.TypeParamNames}} {
{{- range .Fields}}
{{- if .IsComparable}}
_fromNonZero{{.Name}} := __option.FromNonZero[{{.TypeName}}]()
_prism{{.Name}} := __prism.MakePrismWithName(
func(s {{$.Name}}{{$.TypeParamNames}}) __option.Option[{{.TypeName}}] { return _fromNonZero{{.Name}}(s.{{.Name}}) },
func(v {{.TypeName}}) {{$.Name}}{{$.TypeParamNames}} {
{{- if .IsEmbedded}}
var result {{$.Name}}{{$.TypeParamNames}}
result.{{.Name}} = v
return result
{{- else}}
return {{$.Name}}{{$.TypeParamNames}}{ {{.Name}}: v }
{{- end}}
},
"{{$.Name}}{{$.TypeParamNames}}.{{.Name}}",
)
{{- else}}
_prism{{.Name}} := __prism.MakePrismWithName(
func(s {{$.Name}}{{$.TypeParamNames}}) __option.Option[{{.TypeName}}] { return __option.Some(s.{{.Name}}) },
func(v {{.TypeName}}) {{$.Name}}{{$.TypeParamNames}} {
{{- if .IsEmbedded}}
var result {{$.Name}}{{$.TypeParamNames}}
result.{{.Name}} = v
return result
{{- else}}
return {{$.Name}}{{$.TypeParamNames}}{ {{.Name}}: v }
{{- end}}
},
"{{$.Name}}{{$.TypeParamNames}}.{{.Name}}",
)
{{- end}}
{{- end}}
return {{.Name}}Prisms{{.TypeParamNames}} {
{{- range .Fields}}
{{.Name}}: _prism{{.Name}},
{{- end}}
}
}
`
var (
@@ -439,7 +504,7 @@ func extractEmbeddedFields(embedType ast.Expr, fileImports map[string]string, fi
return results
}
if typeName == "" || typeIdent == nil {
if S.IsEmpty(typeName) || typeIdent == nil {
return results
}
@@ -494,6 +559,7 @@ func extractEmbeddedFields(embedType ast.Expr, fileImports map[string]string, fi
BaseType: baseType,
IsOptional: isOptional,
IsComparable: isComparable,
IsEmbedded: true,
},
fieldType: field.Type,
})
@@ -695,7 +761,7 @@ func parseFile(filename string) ([]structInfo, string, error) {
}
// generateLensHelpers scans a directory for Go files and generates lens code
func generateLensHelpers(dir, filename string, verbose bool) error {
func generateLensHelpers(dir, filename string, verbose, includeTestFiles bool) error {
// Get absolute path
absDir, err := filepath.Abs(dir)
if err != nil {
@@ -716,21 +782,34 @@ func generateLensHelpers(dir, filename string, verbose bool) error {
log.Printf("Found %d Go files", len(files))
}
// Parse all files and collect structs
var allStructs []structInfo
// Parse all files and collect structs, separating test and non-test files
var regularStructs []structInfo
var testStructs []structInfo
var packageName string
for _, file := range files {
// Skip generated files and test files
if strings.HasSuffix(file, "_test.go") || strings.Contains(file, "gen.go") {
baseName := filepath.Base(file)
// Skip generated lens files (both regular and test)
if strings.HasPrefix(baseName, "gen_lens") && strings.HasSuffix(baseName, ".go") {
if verbose {
log.Printf("Skipping file: %s", filepath.Base(file))
log.Printf("Skipping generated lens file: %s", baseName)
}
continue
}
isTestFile := strings.HasSuffix(file, "_test.go")
// Skip test files unless includeTestFiles is true
if isTestFile && !includeTestFiles {
if verbose {
log.Printf("Skipping test file: %s", baseName)
}
continue
}
if verbose {
log.Printf("Parsing file: %s", filepath.Base(file))
log.Printf("Parsing file: %s", baseName)
}
structs, pkg, err := parseFile(file)
@@ -740,27 +819,52 @@ func generateLensHelpers(dir, filename string, verbose bool) error {
}
if verbose && len(structs) > 0 {
log.Printf("Found %d annotated struct(s) in %s", len(structs), filepath.Base(file))
log.Printf("Found %d annotated struct(s) in %s", len(structs), baseName)
for _, s := range structs {
log.Printf(" - %s (%d fields)", s.Name, len(s.Fields))
}
}
if packageName == "" {
if S.IsEmpty(packageName) {
packageName = pkg
}
allStructs = append(allStructs, structs...)
// Separate structs based on source file type
if isTestFile {
testStructs = append(testStructs, structs...)
} else {
regularStructs = append(regularStructs, structs...)
}
}
if len(allStructs) == 0 {
if len(regularStructs) == 0 && len(testStructs) == 0 {
log.Printf("No structs with %s annotation found in %s", lensAnnotation, absDir)
return nil
}
// Generate regular lens file if there are regular structs
if len(regularStructs) > 0 {
if err := generateLensFile(absDir, filename, packageName, regularStructs, verbose); err != nil {
return err
}
}
// Generate test lens file if there are test structs
if len(testStructs) > 0 {
testFilename := strings.TrimSuffix(filename, ".go") + "_test.go"
if err := generateLensFile(absDir, testFilename, packageName, testStructs, verbose); err != nil {
return err
}
}
return nil
}
// generateLensFile generates a lens file for the given structs
func generateLensFile(absDir, filename, packageName string, structs []structInfo, verbose bool) error {
// Collect all unique imports from all structs
allImports := make(map[string]string) // import path -> alias
for _, s := range allStructs {
for _, s := range structs {
for importPath, alias := range s.Imports {
allImports[importPath] = alias
}
@@ -774,7 +878,7 @@ func generateLensHelpers(dir, filename string, verbose bool) error {
}
defer f.Close()
log.Printf("Generating lens code in [%s] for package [%s] with [%d] structs ...", outPath, packageName, len(allStructs))
log.Printf("Generating lens code in [%s] for package [%s] with [%d] structs ...", outPath, packageName, len(structs))
// Write header
writePackage(f, packageName)
@@ -782,10 +886,11 @@ func generateLensHelpers(dir, filename string, verbose bool) error {
// Write imports
f.WriteString("import (\n")
// Standard fp-go imports always needed
f.WriteString("\tL \"github.com/IBM/fp-go/v2/optics/lens\"\n")
f.WriteString("\tLO \"github.com/IBM/fp-go/v2/optics/lens/option\"\n")
// f.WriteString("\tO \"github.com/IBM/fp-go/v2/option\"\n")
f.WriteString("\tIO \"github.com/IBM/fp-go/v2/optics/iso/option\"\n")
f.WriteString("\t__lens \"github.com/IBM/fp-go/v2/optics/lens\"\n")
f.WriteString("\t__option \"github.com/IBM/fp-go/v2/option\"\n")
f.WriteString("\t__prism \"github.com/IBM/fp-go/v2/optics/prism\"\n")
f.WriteString("\t__lens_option \"github.com/IBM/fp-go/v2/optics/lens/option\"\n")
f.WriteString("\t__iso_option \"github.com/IBM/fp-go/v2/optics/iso/option\"\n")
// Add additional imports collected from field types
for importPath, alias := range allImports {
@@ -795,7 +900,7 @@ func generateLensHelpers(dir, filename string, verbose bool) error {
f.WriteString(")\n")
// Generate lens code for each struct using templates
for _, s := range allStructs {
for _, s := range structs {
var buf bytes.Buffer
// Generate struct type
@@ -827,12 +932,14 @@ func LensCommand() *C.Command {
flagLensDir,
flagFilename,
flagVerbose,
flagIncludeTestFiles,
},
Action: func(ctx *C.Context) error {
return generateLensHelpers(
ctx.String(keyLensDir),
ctx.String(keyFilename),
ctx.Bool(keyVerbose),
ctx.Bool(keyIncludeTestFile),
)
},
}

146
v2/cli/lens_test.go
View File

@@ -25,6 +25,7 @@ import (
"strings"
"testing"
S "github.com/IBM/fp-go/v2/string"
"github.com/stretchr/testify/assert"
"github.com/stretchr/testify/require"
)
@@ -60,7 +61,7 @@ func TestHasLensAnnotation(t *testing.T) {
for _, tt := range tests {
t.Run(tt.name, func(t *testing.T) {
var doc *ast.CommentGroup
if tt.comment != "" {
if S.IsNonEmpty(tt.comment) {
doc = &ast.CommentGroup{
List: []*ast.Comment{
{Text: tt.comment},
@@ -289,7 +290,7 @@ func TestHasOmitEmpty(t *testing.T) {
for _, tt := range tests {
t.Run(tt.name, func(t *testing.T) {
var tag *ast.BasicLit
if tt.tag != "" {
if S.IsNonEmpty(tt.tag) {
tag = &ast.BasicLit{
Value: tt.tag,
}
@@ -326,7 +327,7 @@ type Other struct {
}
`
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Parse the file
@@ -380,7 +381,7 @@ type Config struct {
}
`
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Parse the file
@@ -440,7 +441,7 @@ type TypeTest struct {
}
`
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Parse the file
@@ -514,16 +515,16 @@ func TestLensRefTemplatesWithComparable(t *testing.T) {
assert.Contains(t, constructorStr, "func MakeTestStructRefLenses() TestStructRefLenses")
// Name field - comparable, should use MakeLensStrict
assert.Contains(t, constructorStr, "lensName := L.MakeLensStrict(",
"comparable field Name should use MakeLensStrict in RefLenses")
assert.Contains(t, constructorStr, "lensName := __lens.MakeLensStrictWithName(",
"comparable field Name should use MakeLensStrictWithName in RefLenses")
// Age field - comparable, should use MakeLensStrict
assert.Contains(t, constructorStr, "lensAge := L.MakeLensStrict(",
"comparable field Age should use MakeLensStrict in RefLenses")
assert.Contains(t, constructorStr, "lensAge := __lens.MakeLensStrictWithName(",
"comparable field Age should use MakeLensStrictWithName in RefLenses")
// Data field - not comparable, should use MakeLensRef
assert.Contains(t, constructorStr, "lensData := L.MakeLensRef(",
"non-comparable field Data should use MakeLensRef in RefLenses")
assert.Contains(t, constructorStr, "lensData := __lens.MakeLensRefWithName(",
"non-comparable field Data should use MakeLensRefWithName in RefLenses")
}
@@ -542,12 +543,12 @@ type TestStruct struct {
`
testFile := filepath.Join(tmpDir, "test.go")
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Generate lens code
outputFile := "gen.go"
err = generateLensHelpers(tmpDir, outputFile, false)
err = generateLensHelpers(tmpDir, outputFile, false, false)
require.NoError(t, err)
// Verify the generated file exists
@@ -564,23 +565,23 @@ type TestStruct struct {
// Check for expected content in RefLenses
assert.Contains(t, contentStr, "MakeTestStructRefLenses")
// Name and Count are comparable, should use MakeLensStrict
assert.Contains(t, contentStr, "L.MakeLensStrict",
"comparable fields should use MakeLensStrict in RefLenses")
// Name and Count are comparable, should use MakeLensStrictWithName
assert.Contains(t, contentStr, "__lens.MakeLensStrictWithName",
"comparable fields should use MakeLensStrictWithName in RefLenses")
// Data is not comparable (slice), should use MakeLensRef
assert.Contains(t, contentStr, "L.MakeLensRef",
"non-comparable fields should use MakeLensRef in RefLenses")
// Data is not comparable (slice), should use MakeLensRefWithName
assert.Contains(t, contentStr, "__lens.MakeLensRefWithName",
"non-comparable fields should use MakeLensRefWithName in RefLenses")
// Verify the pattern appears for Name field (comparable)
namePattern := "lensName := L.MakeLensStrict("
namePattern := "lensName := __lens.MakeLensStrictWithName("
assert.Contains(t, contentStr, namePattern,
"Name field should use MakeLensStrict")
"Name field should use MakeLensStrictWithName")
// Verify the pattern appears for Data field (not comparable)
dataPattern := "lensData := L.MakeLensRef("
dataPattern := "lensData := __lens.MakeLensRefWithName("
assert.Contains(t, contentStr, dataPattern,
"Data field should use MakeLensRef")
"Data field should use MakeLensRefWithName")
}
func TestGenerateLensHelpers(t *testing.T) {
@@ -597,12 +598,12 @@ type TestStruct struct {
`
testFile := filepath.Join(tmpDir, "test.go")
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Generate lens code
outputFile := "gen.go"
err = generateLensHelpers(tmpDir, outputFile, false)
err = generateLensHelpers(tmpDir, outputFile, false, false)
require.NoError(t, err)
// Verify the generated file exists
@@ -621,9 +622,9 @@ type TestStruct struct {
assert.Contains(t, contentStr, "Code generated by go generate")
assert.Contains(t, contentStr, "TestStructLenses")
assert.Contains(t, contentStr, "MakeTestStructLenses")
assert.Contains(t, contentStr, "L.Lens[TestStruct, string]")
assert.Contains(t, contentStr, "LO.LensO[TestStruct, *int]")
assert.Contains(t, contentStr, "IO.FromZero")
assert.Contains(t, contentStr, "__lens.Lens[TestStruct, string]")
assert.Contains(t, contentStr, "__lens_option.LensO[TestStruct, *int]")
assert.Contains(t, contentStr, "__iso_option.FromZero")
}
func TestGenerateLensHelpersNoAnnotations(t *testing.T) {
@@ -639,12 +640,12 @@ type TestStruct struct {
`
testFile := filepath.Join(tmpDir, "test.go")
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Generate lens code (should not create file)
outputFile := "gen.go"
err = generateLensHelpers(tmpDir, outputFile, false)
err = generateLensHelpers(tmpDir, outputFile, false, false)
require.NoError(t, err)
// Verify the generated file does not exist
@@ -669,10 +670,10 @@ func TestLensTemplates(t *testing.T) {
structStr := structBuf.String()
assert.Contains(t, structStr, "type TestStructLenses struct")
assert.Contains(t, structStr, "Name L.Lens[TestStruct, string]")
assert.Contains(t, structStr, "NameO LO.LensO[TestStruct, string]")
assert.Contains(t, structStr, "Value L.Lens[TestStruct, *int]")
assert.Contains(t, structStr, "ValueO LO.LensO[TestStruct, *int]")
assert.Contains(t, structStr, "Name __lens.Lens[TestStruct, string]")
assert.Contains(t, structStr, "NameO __lens_option.LensO[TestStruct, string]")
assert.Contains(t, structStr, "Value __lens.Lens[TestStruct, *int]")
assert.Contains(t, structStr, "ValueO __lens_option.LensO[TestStruct, *int]")
// Test constructor template
var constructorBuf bytes.Buffer
@@ -686,7 +687,7 @@ func TestLensTemplates(t *testing.T) {
assert.Contains(t, constructorStr, "NameO: lensNameO,")
assert.Contains(t, constructorStr, "Value: lensValue,")
assert.Contains(t, constructorStr, "ValueO: lensValueO,")
assert.Contains(t, constructorStr, "IO.FromZero")
assert.Contains(t, constructorStr, "__iso_option.FromZero")
}
func TestLensTemplatesWithOmitEmpty(t *testing.T) {
@@ -707,14 +708,14 @@ func TestLensTemplatesWithOmitEmpty(t *testing.T) {
structStr := structBuf.String()
assert.Contains(t, structStr, "type ConfigStructLenses struct")
assert.Contains(t, structStr, "Name L.Lens[ConfigStruct, string]")
assert.Contains(t, structStr, "NameO LO.LensO[ConfigStruct, string]")
assert.Contains(t, structStr, "Value L.Lens[ConfigStruct, string]")
assert.Contains(t, structStr, "ValueO LO.LensO[ConfigStruct, string]", "comparable non-pointer with omitempty should have optional lens")
assert.Contains(t, structStr, "Count L.Lens[ConfigStruct, int]")
assert.Contains(t, structStr, "CountO LO.LensO[ConfigStruct, int]", "comparable non-pointer with omitempty should have optional lens")
assert.Contains(t, structStr, "Pointer L.Lens[ConfigStruct, *string]")
assert.Contains(t, structStr, "PointerO LO.LensO[ConfigStruct, *string]")
assert.Contains(t, structStr, "Name __lens.Lens[ConfigStruct, string]")
assert.Contains(t, structStr, "NameO __lens_option.LensO[ConfigStruct, string]")
assert.Contains(t, structStr, "Value __lens.Lens[ConfigStruct, string]")
assert.Contains(t, structStr, "ValueO __lens_option.LensO[ConfigStruct, string]", "comparable non-pointer with omitempty should have optional lens")
assert.Contains(t, structStr, "Count __lens.Lens[ConfigStruct, int]")
assert.Contains(t, structStr, "CountO __lens_option.LensO[ConfigStruct, int]", "comparable non-pointer with omitempty should have optional lens")
assert.Contains(t, structStr, "Pointer __lens.Lens[ConfigStruct, *string]")
assert.Contains(t, structStr, "PointerO __lens_option.LensO[ConfigStruct, *string]")
// Test constructor template
var constructorBuf bytes.Buffer
@@ -723,9 +724,9 @@ func TestLensTemplatesWithOmitEmpty(t *testing.T) {
constructorStr := constructorBuf.String()
assert.Contains(t, constructorStr, "func MakeConfigStructLenses() ConfigStructLenses")
assert.Contains(t, constructorStr, "IO.FromZero[string]()")
assert.Contains(t, constructorStr, "IO.FromZero[int]()")
assert.Contains(t, constructorStr, "IO.FromZero[*string]()")
assert.Contains(t, constructorStr, "__iso_option.FromZero[string]()")
assert.Contains(t, constructorStr, "__iso_option.FromZero[int]()")
assert.Contains(t, constructorStr, "__iso_option.FromZero[*string]()")
}
func TestLensCommandFlags(t *testing.T) {
@@ -737,9 +738,9 @@ func TestLensCommandFlags(t *testing.T) {
assert.Contains(t, strings.ToLower(cmd.Description), "lenso", "Description should mention LensO for optional lenses")
// Check flags
assert.Len(t, cmd.Flags, 3)
assert.Len(t, cmd.Flags, 4)
var hasDir, hasFilename, hasVerbose bool
var hasDir, hasFilename, hasVerbose, hasIncludeTestFiles bool
for _, flag := range cmd.Flags {
switch flag.Names()[0] {
case "dir":
@@ -748,12 +749,15 @@ func TestLensCommandFlags(t *testing.T) {
hasFilename = true
case "verbose":
hasVerbose = true
case "include-test-files":
hasIncludeTestFiles = true
}
}
assert.True(t, hasDir, "should have dir flag")
assert.True(t, hasFilename, "should have filename flag")
assert.True(t, hasVerbose, "should have verbose flag")
assert.True(t, hasIncludeTestFiles, "should have include-test-files flag")
}
func TestParseFileWithEmbeddedStruct(t *testing.T) {
@@ -776,7 +780,7 @@ type Extended struct {
}
`
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Parse the file
@@ -824,12 +828,12 @@ type Person struct {
`
testFile := filepath.Join(tmpDir, "test.go")
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Generate lens code
outputFile := "gen.go"
err = generateLensHelpers(tmpDir, outputFile, false)
err = generateLensHelpers(tmpDir, outputFile, false, false)
require.NoError(t, err)
// Verify the generated file exists
@@ -849,14 +853,14 @@ type Person struct {
assert.Contains(t, contentStr, "MakePersonLenses")
// Check that embedded fields are included
assert.Contains(t, contentStr, "Street L.Lens[Person, string]", "Should have lens for embedded Street field")
assert.Contains(t, contentStr, "City L.Lens[Person, string]", "Should have lens for embedded City field")
assert.Contains(t, contentStr, "Name L.Lens[Person, string]", "Should have lens for Name field")
assert.Contains(t, contentStr, "Age L.Lens[Person, int]", "Should have lens for Age field")
assert.Contains(t, contentStr, "Street __lens.Lens[Person, string]", "Should have lens for embedded Street field")
assert.Contains(t, contentStr, "City __lens.Lens[Person, string]", "Should have lens for embedded City field")
assert.Contains(t, contentStr, "Name __lens.Lens[Person, string]", "Should have lens for Name field")
assert.Contains(t, contentStr, "Age __lens.Lens[Person, int]", "Should have lens for Age field")
// Check that optional lenses are also generated for embedded fields
assert.Contains(t, contentStr, "StreetO LO.LensO[Person, string]")
assert.Contains(t, contentStr, "CityO LO.LensO[Person, string]")
assert.Contains(t, contentStr, "StreetO __lens_option.LensO[Person, string]")
assert.Contains(t, contentStr, "CityO __lens_option.LensO[Person, string]")
}
func TestParseFileWithPointerEmbeddedStruct(t *testing.T) {
@@ -880,7 +884,7 @@ type Document struct {
}
`
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Parse the file
@@ -922,7 +926,7 @@ type Container[T any] struct {
}
`
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Parse the file
@@ -960,7 +964,7 @@ type Pair[K comparable, V any] struct {
}
`
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Parse the file
@@ -998,12 +1002,12 @@ type Box[T any] struct {
`
testFile := filepath.Join(tmpDir, "test.go")
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Generate lens code
outputFile := "gen.go"
err = generateLensHelpers(tmpDir, outputFile, false)
err = generateLensHelpers(tmpDir, outputFile, false, false)
require.NoError(t, err)
// Verify the generated file exists
@@ -1025,14 +1029,14 @@ type Box[T any] struct {
assert.Contains(t, contentStr, "func MakeBoxRefLenses[T any]() BoxRefLenses[T]", "Should have generic ref constructor")
// Check that fields use the generic type parameter
assert.Contains(t, contentStr, "Content L.Lens[Box[T], T]", "Should have lens for generic Content field")
assert.Contains(t, contentStr, "Label L.Lens[Box[T], string]", "Should have lens for Label field")
assert.Contains(t, contentStr, "Content __lens.Lens[Box[T], T]", "Should have lens for generic Content field")
assert.Contains(t, contentStr, "Label __lens.Lens[Box[T], string]", "Should have lens for Label field")
// Check optional lenses - only for comparable types
// T any is not comparable, so ContentO should NOT be generated
assert.NotContains(t, contentStr, "ContentO LO.LensO[Box[T], T]", "T any is not comparable, should not have optional lens")
assert.NotContains(t, contentStr, "ContentO __lens_option.LensO[Box[T], T]", "T any is not comparable, should not have optional lens")
// string is comparable, so LabelO should be generated
assert.Contains(t, contentStr, "LabelO LO.LensO[Box[T], string]", "string is comparable, should have optional lens")
assert.Contains(t, contentStr, "LabelO __lens_option.LensO[Box[T], string]", "string is comparable, should have optional lens")
}
func TestGenerateLensHelpersWithComparableTypeParam(t *testing.T) {
@@ -1049,12 +1053,12 @@ type ComparableBox[T comparable] struct {
`
testFile := filepath.Join(tmpDir, "test.go")
err := os.WriteFile(testFile, []byte(testCode), 0644)
err := os.WriteFile(testFile, []byte(testCode), 0o644)
require.NoError(t, err)
// Generate lens code
outputFile := "gen.go"
err = generateLensHelpers(tmpDir, outputFile, false)
err = generateLensHelpers(tmpDir, outputFile, false, false)
require.NoError(t, err)
// Verify the generated file exists
@@ -1074,11 +1078,11 @@ type ComparableBox[T comparable] struct {
assert.Contains(t, contentStr, "type ComparableBoxRefLenses[T comparable] struct", "Should have generic ComparableBoxRefLenses type")
// Check that Key field (with comparable constraint) uses MakeLensStrict in RefLenses
assert.Contains(t, contentStr, "lensKey := L.MakeLensStrict(", "Key field with comparable constraint should use MakeLensStrict")
assert.Contains(t, contentStr, "lensKey := __lens.MakeLensStrictWithName(", "Key field with comparable constraint should use MakeLensStrictWithName")
// Check that Value field (string, always comparable) also uses MakeLensStrict
assert.Contains(t, contentStr, "lensValue := L.MakeLensStrict(", "Value field (string) should use MakeLensStrict")
assert.Contains(t, contentStr, "lensValue := __lens.MakeLensStrictWithName(", "Value field (string) should use MakeLensStrictWithName")
// Verify that MakeLensRef is NOT used (since both fields are comparable)
assert.NotContains(t, contentStr, "L.MakeLensRef(", "Should not use MakeLensRef when all fields are comparable")
assert.NotContains(t, contentStr, "__lens.MakeLensRefWithName(", "Should not use MakeLensRefWithName when all fields are comparable")
}

24
v2/cli/monad.go
View File

@@ -19,6 +19,8 @@ import (
"fmt"
"os"
"strings"
S "github.com/IBM/fp-go/v2/string"
)
// Deprecated:
@@ -176,7 +178,7 @@ func generateTraverseTuple1(
}
fmt.Fprintf(f, "F%d ~func(A%d) %s", j+1, j+1, hkt(fmt.Sprintf("T%d", j+1)))
}
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, ", %s", infix)
}
// types
@@ -209,7 +211,7 @@ func generateTraverseTuple1(
fmt.Fprintf(f, " return A.TraverseTuple%d(\n", i)
// map
fmt.Fprintf(f, " Map[")
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, "%s, T1,", infix)
} else {
fmt.Fprintf(f, "T1,")
@@ -231,7 +233,7 @@ func generateTraverseTuple1(
fmt.Fprintf(f, " ")
}
fmt.Fprintf(f, "%s", tuple)
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, ", %s", infix)
}
fmt.Fprintf(f, ", T%d],\n", j+1)
@@ -256,11 +258,11 @@ func generateSequenceTuple1(
fmt.Fprintf(f, "\n// SequenceTuple%d converts a [Tuple%d] of [%s] into an [%s].\n", i, i, hkt("T"), hkt(fmt.Sprintf("Tuple%d", i)))
fmt.Fprintf(f, "func SequenceTuple%d[", i)
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, "%s", infix)
}
for j := 0; j < i; j++ {
if infix != "" || j > 0 {
if S.IsNonEmpty(infix) || j > 0 {
fmt.Fprintf(f, ", ")
}
fmt.Fprintf(f, "T%d", j+1)
@@ -276,7 +278,7 @@ func generateSequenceTuple1(
fmt.Fprintf(f, " return A.SequenceTuple%d(\n", i)
// map
fmt.Fprintf(f, " Map[")
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, "%s, T1,", infix)
} else {
fmt.Fprintf(f, "T1,")
@@ -298,7 +300,7 @@ func generateSequenceTuple1(
fmt.Fprintf(f, " ")
}
fmt.Fprintf(f, "%s", tuple)
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, ", %s", infix)
}
fmt.Fprintf(f, ", T%d],\n", j+1)
@@ -319,11 +321,11 @@ func generateSequenceT1(
fmt.Fprintf(f, "\n// SequenceT%d converts %d parameters of [%s] into a [%s].\n", i, i, hkt("T"), hkt(fmt.Sprintf("Tuple%d", i)))
fmt.Fprintf(f, "func SequenceT%d[", i)
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, "%s", infix)
}
for j := 0; j < i; j++ {
if infix != "" || j > 0 {
if S.IsNonEmpty(infix) || j > 0 {
fmt.Fprintf(f, ", ")
}
fmt.Fprintf(f, "T%d", j+1)
@@ -339,7 +341,7 @@ func generateSequenceT1(
fmt.Fprintf(f, " return A.SequenceT%d(\n", i)
// map
fmt.Fprintf(f, " Map[")
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, "%s, T1,", infix)
} else {
fmt.Fprintf(f, "T1,")
@@ -361,7 +363,7 @@ func generateSequenceT1(
fmt.Fprintf(f, " ")
}
fmt.Fprintf(f, "%s", tuple)
if infix != "" {
if S.IsNonEmpty(infix) {
fmt.Fprintf(f, ", %s", infix)
}
fmt.Fprintf(f, ", T%d],\n", j+1)

177
v2/consumer/consumer.go Normal file
View File

@@ -0,0 +1,177 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package consumer
// Local transforms a Consumer by preprocessing its input through a function.
// This is the contravariant map operation for Consumers, analogous to reader.Local
// but operating on the input side rather than the output side.
//
// Given a Consumer[R1] that consumes values of type R1, and a function f that
// converts R2 to R1, Local creates a new Consumer[R2] that:
// 1. Takes a value of type R2
// 2. Applies f to convert it to R1
// 3. Passes the result to the original Consumer[R1]
//
// This is particularly useful for adapting consumers to work with different input types,
// similar to how reader.Local adapts readers to work with different environment types.
//
// Comparison with reader.Local:
// - reader.Local: Transforms the environment BEFORE passing it to a Reader (preprocessing input)
// - consumer.Local: Transforms the value BEFORE passing it to a Consumer (preprocessing input)
// - Both are contravariant operations on the input type
// - Reader produces output, Consumer performs side effects
//
// Type Parameters:
// - R2: The input type of the new Consumer (what you have)
// - R1: The input type of the original Consumer (what it expects)
//
// Parameters:
// - f: A function that converts R2 to R1 (preprocessing function)
//
// Returns:
// - An Operator that transforms Consumer[R1] into Consumer[R2]
//
// Example - Basic type adaptation:
//
// // Consumer that logs integers
// logInt := func(x int) {
// fmt.Printf("Value: %d\n", x)
// }
//
// // Adapt it to consume strings by parsing them first
// parseToInt := func(s string) int {
// n, _ := strconv.Atoi(s)
// return n
// }
//
// logString := consumer.Local(parseToInt)(logInt)
// logString("42") // Logs: "Value: 42"
//
// Example - Extracting fields from structs:
//
// type User struct {
// Name string
// Age int
// }
//
// // Consumer that logs names
// logName := func(name string) {
// fmt.Printf("Name: %s\n", name)
// }
//
// // Adapt it to consume User structs
// extractName := func(u User) string {
// return u.Name
// }
//
// logUser := consumer.Local(extractName)(logName)
// logUser(User{Name: "Alice", Age: 30}) // Logs: "Name: Alice"
//
// Example - Simplifying complex types:
//
// type DetailedConfig struct {
// Host string
// Port int
// Timeout time.Duration
// MaxRetry int
// }
//
// type SimpleConfig struct {
// Host string
// Port int
// }
//
// // Consumer that logs simple configs
// logSimple := func(c SimpleConfig) {
// fmt.Printf("Server: %s:%d\n", c.Host, c.Port)
// }
//
// // Adapt it to consume detailed configs
// simplify := func(d DetailedConfig) SimpleConfig {
// return SimpleConfig{Host: d.Host, Port: d.Port}
// }
//
// logDetailed := consumer.Local(simplify)(logSimple)
// logDetailed(DetailedConfig{
// Host: "localhost",
// Port: 8080,
// Timeout: time.Second,
// MaxRetry: 3,
// }) // Logs: "Server: localhost:8080"
//
// Example - Composing multiple transformations:
//
// type Response struct {
// StatusCode int
// Body string
// }
//
// // Consumer that logs status codes
// logStatus := func(code int) {
// fmt.Printf("Status: %d\n", code)
// }
//
// // Extract status code from response
// getStatus := func(r Response) int {
// return r.StatusCode
// }
//
// // Adapt to consume responses
// logResponse := consumer.Local(getStatus)(logStatus)
// logResponse(Response{StatusCode: 200, Body: "OK"}) // Logs: "Status: 200"
//
// Example - Using with multiple consumers:
//
// type Event struct {
// Type string
// Timestamp time.Time
// Data map[string]any
// }
//
// // Consumers for different aspects
// logType := func(t string) { fmt.Printf("Type: %s\n", t) }
// logTime := func(t time.Time) { fmt.Printf("Time: %v\n", t) }
//
// // Adapt them to consume events
// logEventType := consumer.Local(func(e Event) string { return e.Type })(logType)
// logEventTime := consumer.Local(func(e Event) time.Time { return e.Timestamp })(logTime)
//
// event := Event{Type: "UserLogin", Timestamp: time.Now(), Data: nil}
// logEventType(event) // Logs: "Type: UserLogin"
// logEventTime(event) // Logs: "Time: ..."
//
// Use Cases:
// - Type adaptation: Convert between different input types
// - Field extraction: Extract specific fields from complex structures
// - Data transformation: Preprocess data before consumption
// - Interface adaptation: Adapt consumers to work with different interfaces
// - Logging pipelines: Transform data before logging
// - Event handling: Extract relevant data from events before processing
//
// Relationship to Reader:
// Consumer is the dual of Reader in category theory:
// - Reader[R, A] = R -> A (produces output from environment)
// - Consumer[A] = A -> () (consumes input, produces side effects)
// - reader.Local transforms the environment before reading
// - consumer.Local transforms the input before consuming
// - Both are contravariant functors on their input type
func Local[R2, R1 any](f func(R2) R1) Operator[R1, R2] {
return func(c Consumer[R1]) Consumer[R2] {
return func(r2 R2) {
c(f(r2))
}
}
}

383
v2/consumer/consumer_test.go Normal file
View File

@@ -0,0 +1,383 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package consumer
import (
"strconv"
"testing"
"time"
"github.com/IBM/fp-go/v2/function"
"github.com/stretchr/testify/assert"
)
func TestLocal(t *testing.T) {
t.Run("basic type transformation", func(t *testing.T) {
var captured int
consumeInt := func(x int) {
captured = x
}
// Transform string to int before consuming
stringToInt := func(s string) int {
n, _ := strconv.Atoi(s)
return n
}
consumeString := Local(stringToInt)(consumeInt)
consumeString("42")
assert.Equal(t, 42, captured)
})
t.Run("field extraction from struct", func(t *testing.T) {
type User struct {
Name string
Age int
}
var capturedName string
consumeName := func(name string) {
capturedName = name
}
extractName := func(u User) string {
return u.Name
}
consumeUser := Local(extractName)(consumeName)
consumeUser(User{Name: "Alice", Age: 30})
assert.Equal(t, "Alice", capturedName)
})
t.Run("simplifying complex types", func(t *testing.T) {
type DetailedConfig struct {
Host string
Port int
Timeout time.Duration
MaxRetry int
}
type SimpleConfig struct {
Host string
Port int
}
var captured SimpleConfig
consumeSimple := func(c SimpleConfig) {
captured = c
}
simplify := func(d DetailedConfig) SimpleConfig {
return SimpleConfig{Host: d.Host, Port: d.Port}
}
consumeDetailed := Local(simplify)(consumeSimple)
consumeDetailed(DetailedConfig{
Host: "localhost",
Port: 8080,
Timeout: time.Second,
MaxRetry: 3,
})
assert.Equal(t, SimpleConfig{Host: "localhost", Port: 8080}, captured)
})
t.Run("multiple transformations", func(t *testing.T) {
type Response struct {
StatusCode int
Body string
}
var capturedStatus int
consumeStatus := func(code int) {
capturedStatus = code
}
getStatus := func(r Response) int {
return r.StatusCode
}
consumeResponse := Local(getStatus)(consumeStatus)
consumeResponse(Response{StatusCode: 200, Body: "OK"})
assert.Equal(t, 200, capturedStatus)
})
t.Run("chaining Local transformations", func(t *testing.T) {
type Level3 struct{ Value int }
type Level2 struct{ L3 Level3 }
type Level1 struct{ L2 Level2 }
var captured int
consumeInt := func(x int) {
captured = x
}
// Chain multiple Local transformations
extract3 := func(l3 Level3) int { return l3.Value }
extract2 := func(l2 Level2) Level3 { return l2.L3 }
extract1 := func(l1 Level1) Level2 { return l1.L2 }
// Compose the transformations
consumeLevel3 := Local(extract3)(consumeInt)
consumeLevel2 := Local(extract2)(consumeLevel3)
consumeLevel1 := Local(extract1)(consumeLevel2)
consumeLevel1(Level1{L2: Level2{L3: Level3{Value: 42}}})
assert.Equal(t, 42, captured)
})
t.Run("identity transformation", func(t *testing.T) {
var captured string
consumeString := func(s string) {
captured = s
}
identity := function.Identity[string]
consumeIdentity := Local(identity)(consumeString)
consumeIdentity("test")
assert.Equal(t, "test", captured)
})
t.Run("transformation with calculation", func(t *testing.T) {
type Rectangle struct {
Width int
Height int
}
var capturedArea int
consumeArea := func(area int) {
capturedArea = area
}
calculateArea := func(r Rectangle) int {
return r.Width * r.Height
}
consumeRectangle := Local(calculateArea)(consumeArea)
consumeRectangle(Rectangle{Width: 5, Height: 10})
assert.Equal(t, 50, capturedArea)
})
t.Run("multiple consumers with same transformation", func(t *testing.T) {
type Event struct {
Type string
Timestamp time.Time
}
var capturedType string
var capturedTime time.Time
consumeType := func(t string) {
capturedType = t
}
consumeTime := func(t time.Time) {
capturedTime = t
}
extractType := func(e Event) string { return e.Type }
extractTime := func(e Event) time.Time { return e.Timestamp }
consumeEventType := Local(extractType)(consumeType)
consumeEventTime := Local(extractTime)(consumeTime)
now := time.Now()
event := Event{Type: "UserLogin", Timestamp: now}
consumeEventType(event)
consumeEventTime(event)
assert.Equal(t, "UserLogin", capturedType)
assert.Equal(t, now, capturedTime)
})
t.Run("transformation with slice", func(t *testing.T) {
var captured int
consumeLength := func(n int) {
captured = n
}
getLength := func(s []string) int {
return len(s)
}
consumeSlice := Local(getLength)(consumeLength)
consumeSlice([]string{"a", "b", "c"})
assert.Equal(t, 3, captured)
})
t.Run("transformation with map", func(t *testing.T) {
var captured int
consumeCount := func(n int) {
captured = n
}
getCount := func(m map[string]int) int {
return len(m)
}
consumeMap := Local(getCount)(consumeCount)
consumeMap(map[string]int{"a": 1, "b": 2, "c": 3})
assert.Equal(t, 3, captured)
})
t.Run("transformation with pointer", func(t *testing.T) {
var captured int
consumeInt := func(x int) {
captured = x
}
dereference := func(p *int) int {
if p == nil {
return 0
}
return *p
}
consumePointer := Local(dereference)(consumeInt)
value := 42
consumePointer(&value)
assert.Equal(t, 42, captured)
consumePointer(nil)
assert.Equal(t, 0, captured)
})
t.Run("transformation with custom type", func(t *testing.T) {
type MyType struct {
Value string
}
var captured string
consumeString := func(s string) {
captured = s
}
extractValue := func(m MyType) string {
return m.Value
}
consumeMyType := Local(extractValue)(consumeString)
consumeMyType(MyType{Value: "test"})
assert.Equal(t, "test", captured)
})
t.Run("accumulation through multiple calls", func(t *testing.T) {
var sum int
accumulate := func(x int) {
sum += x
}
double := func(x int) int {
return x * 2
}
accumulateDoubled := Local(double)(accumulate)
accumulateDoubled(1)
accumulateDoubled(2)
accumulateDoubled(3)
assert.Equal(t, 12, sum) // (1*2) + (2*2) + (3*2) = 2 + 4 + 6 = 12
})
t.Run("transformation with error handling", func(t *testing.T) {
type Result struct {
Value int
Error error
}
var captured int
consumeInt := func(x int) {
captured = x
}
extractValue := func(r Result) int {
if r.Error != nil {
return -1
}
return r.Value
}
consumeResult := Local(extractValue)(consumeInt)
consumeResult(Result{Value: 42, Error: nil})
assert.Equal(t, 42, captured)
consumeResult(Result{Value: 100, Error: assert.AnError})
assert.Equal(t, -1, captured)
})
t.Run("transformation preserves consumer behavior", func(t *testing.T) {
callCount := 0
consumer := func(x int) {
callCount++
}
transform := func(s string) int {
n, _ := strconv.Atoi(s)
return n
}
transformedConsumer := Local(transform)(consumer)
transformedConsumer("1")
transformedConsumer("2")
transformedConsumer("3")
assert.Equal(t, 3, callCount)
})
t.Run("comparison with reader.Local behavior", func(t *testing.T) {
// This test demonstrates the dual nature of Consumer and Reader
// Consumer: transforms input before consumption (contravariant)
// Reader: transforms environment before reading (also contravariant on input)
type DetailedEnv struct {
Value int
Extra string
}
type SimpleEnv struct {
Value int
}
var captured int
consumeSimple := func(e SimpleEnv) {
captured = e.Value
}
simplify := func(d DetailedEnv) SimpleEnv {
return SimpleEnv{Value: d.Value}
}
consumeDetailed := Local(simplify)(consumeSimple)
consumeDetailed(DetailedEnv{Value: 42, Extra: "ignored"})
assert.Equal(t, 42, captured)
})
}

56
v2/consumer/types.go Normal file
View File

@@ -0,0 +1,56 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package consumer provides types and utilities for functions that consume values without returning results.
//
// A Consumer represents a side-effecting operation that accepts a value but produces no output.
// This is useful for operations like logging, printing, updating state, or any action where
// the return value is not needed.
package consumer
type (
// Consumer represents a function that accepts a value of type A and performs a side effect.
// It does not return any value, making it useful for operations where only the side effect matters,
// such as logging, printing, or updating external state.
//
// This is a fundamental concept in functional programming for handling side effects in a
// controlled manner. Consumers can be composed, chained, or used in higher-order functions
// to build complex side-effecting behaviors.
//
// Type Parameters:
// - A: The type of value consumed by the function
//
// Example:
//
// // A simple consumer that prints values
// var printInt Consumer[int] = func(x int) {
// fmt.Println(x)
// }
// printInt(42) // Prints: 42
//
// // A consumer that logs messages
// var logger Consumer[string] = func(msg string) {
// log.Println(msg)
// }
// logger("Hello, World!") // Logs: Hello, World!
//
// // Consumers can be used in functional pipelines
// var saveToDatabase Consumer[User] = func(user User) {
// db.Save(user)
// }
Consumer[A any] = func(A)
Operator[A, B any] = func(Consumer[A]) Consumer[B]
)

4
v2/context/ioresult/ioeither.go
View File

@@ -24,8 +24,8 @@ import (
// withContext wraps an existing IOEither and performs a context check for cancellation before delegating
func WithContext[A any](ctx context.Context, ma IOResult[A]) IOResult[A] {
return func() Result[A] {
if err := context.Cause(ctx); err != nil {
return result.Left[A](err)
if ctx.Err() != nil {
return result.Left[A](context.Cause(ctx))
}
return ma()
}

16
v2/context/readerio/bracket.go Normal file
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@@ -0,0 +1,16 @@
package readerio
import (
RIO "github.com/IBM/fp-go/v2/readerio"
)
//go:inline
func Bracket[
A, B, ANY any](
acquire ReaderIO[A],
use Kleisli[A, B],
release func(A, B) ReaderIO[ANY],
) ReaderIO[B] {
return RIO.Bracket(acquire, use, release)
}

13
v2/context/readerio/consumer.go Normal file
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package readerio
import "github.com/IBM/fp-go/v2/io"
//go:inline
func ChainConsumer[A any](c Consumer[A]) Operator[A, struct{}] {
return ChainIOK(io.FromConsumerK(c))
}
//go:inline
func ChainFirstConsumer[A any](c Consumer[A]) Operator[A, A] {
return ChainFirstIOK(io.FromConsumerK(c))
}

20
v2/context/readerio/flip.go Normal file
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package readerio
import (
"context"
"github.com/IBM/fp-go/v2/reader"
RIO "github.com/IBM/fp-go/v2/readerio"
)
//go:inline
func SequenceReader[R, A any](ma ReaderIO[Reader[R, A]]) Reader[R, ReaderIO[A]] {
return RIO.SequenceReader(ma)
}
//go:inline
func TraverseReader[R, A, B any](
f reader.Kleisli[R, A, B],
) func(ReaderIO[A]) Kleisli[R, B] {
return RIO.TraverseReader[context.Context](f)
}

29
v2/context/readerio/logging.go Normal file
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package readerio
import (
"context"
"log/slog"
"github.com/IBM/fp-go/v2/logging"
)
func SLogWithCallback[A any](
logLevel slog.Level,
cb func(context.Context) *slog.Logger,
message string) Kleisli[A, A] {
return func(a A) ReaderIO[A] {
return func(ctx context.Context) IO[A] {
// logger
logger := cb(ctx)
return func() A {
logger.LogAttrs(ctx, logLevel, message, slog.Any("value", a))
return a
}
}
}
}
//go:inline
func SLog[A any](message string) Kleisli[A, A] {
return SLogWithCallback[A](slog.LevelInfo, logging.GetLoggerFromContext, message)
}

769
v2/context/readerio/reader.go Normal file
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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerio
import (
"context"
"time"
"github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/reader"
RIO "github.com/IBM/fp-go/v2/readerio"
)
const (
// useParallel is the feature flag to control if we use the parallel or the sequential implementation of ap
useParallel = true
)
// MonadMap transforms the success value of a [ReaderIO] using the provided function.
// If the computation fails, the error is propagated unchanged.
//
// Parameters:
// - fa: The ReaderIO to transform
// - f: The transformation function
//
// Returns a new ReaderIO with the transformed value.
//
//go:inline
func MonadMap[A, B any](fa ReaderIO[A], f func(A) B) ReaderIO[B] {
return RIO.MonadMap(fa, f)
}
// Map transforms the success value of a [ReaderIO] using the provided function.
// This is the curried version of [MonadMap], useful for composition.
//
// Parameters:
// - f: The transformation function
//
// Returns a function that transforms a ReaderIO.
//
//go:inline
func Map[A, B any](f func(A) B) Operator[A, B] {
return RIO.Map[context.Context](f)
}
// MonadMapTo replaces the success value of a [ReaderIO] with a constant value.
// If the computation fails, the error is propagated unchanged.
//
// Parameters:
// - fa: The ReaderIO to transform
// - b: The constant value to use
//
// Returns a new ReaderIO with the constant value.
//
//go:inline
func MonadMapTo[A, B any](fa ReaderIO[A], b B) ReaderIO[B] {
return RIO.MonadMapTo(fa, b)
}
// MapTo replaces the success value of a [ReaderIO] with a constant value.
// This is the curried version of [MonadMapTo].
//
// Parameters:
// - b: The constant value to use
//
// Returns a function that transforms a ReaderIO.
//
//go:inline
func MapTo[A, B any](b B) Operator[A, B] {
return RIO.MapTo[context.Context, A](b)
}
// MonadChain sequences two [ReaderIO] computations, where the second depends on the result of the first.
// If the first computation fails, the second is not executed.
//
// Parameters:
// - ma: The first ReaderIO
// - f: Function that produces the second ReaderIO based on the first's result
//
// Returns a new ReaderIO representing the sequenced computation.
//
//go:inline
func MonadChain[A, B any](ma ReaderIO[A], f Kleisli[A, B]) ReaderIO[B] {
return RIO.MonadChain(ma, f)
}
// Chain sequences two [ReaderIO] computations, where the second depends on the result of the first.
// This is the curried version of [MonadChain], useful for composition.
//
// Parameters:
// - f: Function that produces the second ReaderIO based on the first's result
//
// Returns a function that sequences ReaderIO computations.
//
//go:inline
func Chain[A, B any](f Kleisli[A, B]) Operator[A, B] {
return RIO.Chain(f)
}
// MonadChainFirst sequences two [ReaderIO] computations but returns the result of the first.
// The second computation is executed for its side effects only.
//
// Parameters:
// - ma: The first ReaderIO
// - f: Function that produces the second ReaderIO
//
// Returns a ReaderIO with the result of the first computation.
//
//go:inline
func MonadChainFirst[A, B any](ma ReaderIO[A], f Kleisli[A, B]) ReaderIO[A] {
return RIO.MonadChainFirst(ma, f)
}
// MonadTap executes a side-effect computation but returns the original value.
// This is an alias for [MonadChainFirst] and is useful for operations like logging
// or validation that should not affect the main computation flow.
//
// Parameters:
// - ma: The ReaderIO to tap
// - f: Function that produces a side-effect ReaderIO
//
// Returns a ReaderIO with the original value after executing the side effect.
//
//go:inline
func MonadTap[A, B any](ma ReaderIO[A], f Kleisli[A, B]) ReaderIO[A] {
return RIO.MonadTap(ma, f)
}
// ChainFirst sequences two [ReaderIO] computations but returns the result of the first.
// This is the curried version of [MonadChainFirst].
//
// Parameters:
// - f: Function that produces the second ReaderIO
//
// Returns a function that sequences ReaderIO computations.
//
//go:inline
func ChainFirst[A, B any](f Kleisli[A, B]) Operator[A, A] {
return RIO.ChainFirst(f)
}
// Tap executes a side-effect computation but returns the original value.
// This is the curried version of [MonadTap], an alias for [ChainFirst].
//
// Parameters:
// - f: Function that produces a side-effect ReaderIO
//
// Returns a function that taps ReaderIO computations.
//
//go:inline
func Tap[A, B any](f Kleisli[A, B]) Operator[A, A] {
return RIO.Tap(f)
}
// Of creates a [ReaderIO] that always succeeds with the given value.
// This is the same as [Right] and represents the monadic return operation.
//
// Parameters:
// - a: The value to wrap
//
// Returns a ReaderIO that always succeeds with the given value.
//
//go:inline
func Of[A any](a A) ReaderIO[A] {
return RIO.Of[context.Context](a)
}
// MonadApPar implements parallel applicative application for [ReaderIO].
// It executes the function and value computations in parallel where possible,
// potentially improving performance for independent operations.
//
// Parameters:
// - fab: ReaderIO containing a function
// - fa: ReaderIO containing a value
//
// Returns a ReaderIO with the function applied to the value.
//
//go:inline
func MonadApPar[B, A any](fab ReaderIO[func(A) B], fa ReaderIO[A]) ReaderIO[B] {
return RIO.MonadApPar(fab, fa)
}
// MonadAp implements applicative application for [ReaderIO].
// By default, it uses parallel execution ([MonadApPar]) but can be configured to use
// sequential execution ([MonadApSeq]) via the useParallel constant.
//
// Parameters:
// - fab: ReaderIO containing a function
// - fa: ReaderIO containing a value
//
// Returns a ReaderIO with the function applied to the value.
//
//go:inline
func MonadAp[B, A any](fab ReaderIO[func(A) B], fa ReaderIO[A]) ReaderIO[B] {
// dispatch to the configured version
if useParallel {
return MonadApPar(fab, fa)
}
return MonadApSeq(fab, fa)
}
// MonadApSeq implements sequential applicative application for [ReaderIO].
// It executes the function computation first, then the value computation.
//
// Parameters:
// - fab: ReaderIO containing a function
// - fa: ReaderIO containing a value
//
// Returns a ReaderIO with the function applied to the value.
//
//go:inline
func MonadApSeq[B, A any](fab ReaderIO[func(A) B], fa ReaderIO[A]) ReaderIO[B] {
return RIO.MonadApSeq(fab, fa)
}
// Ap applies a function wrapped in a [ReaderIO] to a value wrapped in a ReaderIO.
// This is the curried version of [MonadAp], using the default execution mode.
//
// Parameters:
// - fa: ReaderIO containing a value
//
// Returns a function that applies a ReaderIO function to the value.
//
//go:inline
func Ap[B, A any](fa ReaderIO[A]) Operator[func(A) B, B] {
return RIO.Ap[B](fa)
}
// ApSeq applies a function wrapped in a [ReaderIO] to a value sequentially.
// This is the curried version of [MonadApSeq].
//
// Parameters:
// - fa: ReaderIO containing a value
//
// Returns a function that applies a ReaderIO function to the value sequentially.
//
//go:inline
func ApSeq[B, A any](fa ReaderIO[A]) Operator[func(A) B, B] {
return function.Bind2nd(MonadApSeq[B, A], fa)
}
// ApPar applies a function wrapped in a [ReaderIO] to a value in parallel.
// This is the curried version of [MonadApPar].
//
// Parameters:
// - fa: ReaderIO containing a value
//
// Returns a function that applies a ReaderIO function to the value in parallel.
//
//go:inline
func ApPar[B, A any](fa ReaderIO[A]) Operator[func(A) B, B] {
return function.Bind2nd(MonadApPar[B, A], fa)
}
// Ask returns a [ReaderIO] that provides access to the context.
// This is useful for accessing the [context.Context] within a computation.
//
// Returns a ReaderIO that produces the context.
//
//go:inline
func Ask() ReaderIO[context.Context] {
return RIO.Ask[context.Context]()
}
// FromIO converts an [IO] into a [ReaderIO].
// The IO computation always succeeds, so it's wrapped in Right.
//
// Parameters:
// - t: The IO to convert
//
// Returns a ReaderIO that executes the IO and wraps the result in Right.
//
//go:inline
func FromIO[A any](t IO[A]) ReaderIO[A] {
return RIO.FromIO[context.Context](t)
}
// FromReader converts a [Reader] into a [ReaderIO].
// The Reader computation is lifted into the IO context, allowing it to be
// composed with other ReaderIO operations.
//
// Parameters:
// - t: The Reader to convert
//
// Returns a ReaderIO that executes the Reader and wraps the result in IO.
//
//go:inline
func FromReader[A any](t Reader[context.Context, A]) ReaderIO[A] {
return RIO.FromReader(t)
}
// FromLazy converts a [Lazy] computation into a [ReaderIO].
// The Lazy computation always succeeds, so it's wrapped in Right.
// This is an alias for [FromIO] since Lazy and IO have the same structure.
//
// Parameters:
// - t: The Lazy computation to convert
//
// Returns a ReaderIO that executes the Lazy computation and wraps the result in Right.
//
//go:inline
func FromLazy[A any](t Lazy[A]) ReaderIO[A] {
return RIO.FromIO[context.Context](t)
}
// MonadChainIOK chains a function that returns an [IO] into a [ReaderIO] computation.
// The IO computation always succeeds, so it's wrapped in Right.
//
// Parameters:
// - ma: The ReaderIO to chain from
// - f: Function that produces an IO
//
// Returns a new ReaderIO with the chained IO computation.
//
//go:inline
func MonadChainIOK[A, B any](ma ReaderIO[A], f func(A) IO[B]) ReaderIO[B] {
return RIO.MonadChainIOK(ma, f)
}
// ChainIOK chains a function that returns an [IO] into a [ReaderIO] computation.
// This is the curried version of [MonadChainIOK].
//
// Parameters:
// - f: Function that produces an IO
//
// Returns a function that chains the IO-returning function.
//
//go:inline
func ChainIOK[A, B any](f func(A) IO[B]) Operator[A, B] {
return RIO.ChainIOK[context.Context](f)
}
// MonadChainFirstIOK chains a function that returns an [IO] but keeps the original value.
// The IO computation is executed for its side effects only.
//
// Parameters:
// - ma: The ReaderIO to chain from
// - f: Function that produces an IO
//
// Returns a ReaderIO with the original value after executing the IO.
//
//go:inline
func MonadChainFirstIOK[A, B any](ma ReaderIO[A], f func(A) IO[B]) ReaderIO[A] {
return RIO.MonadChainFirstIOK(ma, f)
}
// MonadTapIOK chains a function that returns an [IO] but keeps the original value.
// This is an alias for [MonadChainFirstIOK] and is useful for side effects like logging.
//
// Parameters:
// - ma: The ReaderIO to tap
// - f: Function that produces an IO for side effects
//
// Returns a ReaderIO with the original value after executing the IO.
//
//go:inline
func MonadTapIOK[A, B any](ma ReaderIO[A], f func(A) IO[B]) ReaderIO[A] {
return RIO.MonadTapIOK(ma, f)
}
// ChainFirstIOK chains a function that returns an [IO] but keeps the original value.
// This is the curried version of [MonadChainFirstIOK].
//
// Parameters:
// - f: Function that produces an IO
//
// Returns a function that chains the IO-returning function.
//
//go:inline
func ChainFirstIOK[A, B any](f func(A) IO[B]) Operator[A, A] {
return RIO.ChainFirstIOK[context.Context](f)
}
// TapIOK chains a function that returns an [IO] but keeps the original value.
// This is the curried version of [MonadTapIOK], an alias for [ChainFirstIOK].
//
// Parameters:
// - f: Function that produces an IO for side effects
//
// Returns a function that taps with IO-returning functions.
//
//go:inline
func TapIOK[A, B any](f func(A) IO[B]) Operator[A, A] {
return RIO.TapIOK[context.Context](f)
}
// Defer creates a [ReaderIO] by lazily generating a new computation each time it's executed.
// This is useful for creating computations that should be re-evaluated on each execution.
//
// Parameters:
// - gen: Lazy generator function that produces a ReaderIO
//
// Returns a ReaderIO that generates a fresh computation on each execution.
//
//go:inline
func Defer[A any](gen Lazy[ReaderIO[A]]) ReaderIO[A] {
return RIO.Defer(gen)
}
// Memoize computes the value of the provided [ReaderIO] monad lazily but exactly once.
// The context used to compute the value is the context of the first call, so do not use this
// method if the value has a functional dependency on the content of the context.
//
// Parameters:
// - rdr: The ReaderIO to memoize
//
// Returns a ReaderIO that caches its result after the first execution.
//
//go:inline
func Memoize[A any](rdr ReaderIO[A]) ReaderIO[A] {
return RIO.Memoize(rdr)
}
// Flatten converts a nested [ReaderIO] into a flat [ReaderIO].
// This is equivalent to [MonadChain] with the identity function.
//
// Parameters:
// - rdr: The nested ReaderIO to flatten
//
// Returns a flattened ReaderIO.
//
//go:inline
func Flatten[A any](rdr ReaderIO[ReaderIO[A]]) ReaderIO[A] {
return RIO.Flatten(rdr)
}
// MonadFlap applies a value to a function wrapped in a [ReaderIO].
// This is the reverse of [MonadAp], useful in certain composition scenarios.
//
// Parameters:
// - fab: ReaderIO containing a function
// - a: The value to apply to the function
//
// Returns a ReaderIO with the function applied to the value.
//
//go:inline
func MonadFlap[B, A any](fab ReaderIO[func(A) B], a A) ReaderIO[B] {
return RIO.MonadFlap(fab, a)
}
// Flap applies a value to a function wrapped in a [ReaderIO].
// This is the curried version of [MonadFlap].
//
// Parameters:
// - a: The value to apply to the function
//
// Returns a function that applies the value to a ReaderIO function.
//
//go:inline
func Flap[B, A any](a A) Operator[func(A) B, B] {
return RIO.Flap[context.Context, B](a)
}
// MonadChainReaderK chains a [ReaderIO] with a function that returns a [Reader].
// The Reader is lifted into the ReaderIO context, allowing composition of
// Reader and ReaderIO operations.
//
// Parameters:
// - ma: The ReaderIO to chain from
// - f: Function that produces a Reader
//
// Returns a new ReaderIO with the chained Reader computation.
//
//go:inline
func MonadChainReaderK[A, B any](ma ReaderIO[A], f reader.Kleisli[context.Context, A, B]) ReaderIO[B] {
return RIO.MonadChainReaderK(ma, f)
}
// ChainReaderK chains a [ReaderIO] with a function that returns a [Reader].
// This is the curried version of [MonadChainReaderK].
//
// Parameters:
// - f: Function that produces a Reader
//
// Returns a function that chains Reader-returning functions.
//
//go:inline
func ChainReaderK[A, B any](f reader.Kleisli[context.Context, A, B]) Operator[A, B] {
return RIO.ChainReaderK(f)
}
// MonadChainFirstReaderK chains a function that returns a [Reader] but keeps the original value.
// The Reader computation is executed for its side effects only.
//
// Parameters:
// - ma: The ReaderIO to chain from
// - f: Function that produces a Reader
//
// Returns a ReaderIO with the original value after executing the Reader.
//
//go:inline
func MonadChainFirstReaderK[A, B any](ma ReaderIO[A], f reader.Kleisli[context.Context, A, B]) ReaderIO[A] {
return RIO.MonadChainFirstReaderK(ma, f)
}
// MonadTapReaderK chains a function that returns a [Reader] but keeps the original value.
// This is an alias for [MonadChainFirstReaderK] and is useful for side effects.
//
// Parameters:
// - ma: The ReaderIO to tap
// - f: Function that produces a Reader for side effects
//
// Returns a ReaderIO with the original value after executing the Reader.
//
//go:inline
func MonadTapReaderK[A, B any](ma ReaderIO[A], f reader.Kleisli[context.Context, A, B]) ReaderIO[A] {
return RIO.MonadTapReaderK(ma, f)
}
// ChainFirstReaderK chains a function that returns a [Reader] but keeps the original value.
// This is the curried version of [MonadChainFirstReaderK].
//
// Parameters:
// - f: Function that produces a Reader
//
// Returns a function that chains Reader-returning functions while preserving the original value.
//
//go:inline
func ChainFirstReaderK[A, B any](f reader.Kleisli[context.Context, A, B]) Operator[A, A] {
return RIO.ChainFirstReaderK(f)
}
// TapReaderK chains a function that returns a [Reader] but keeps the original value.
// This is the curried version of [MonadTapReaderK], an alias for [ChainFirstReaderK].
//
// Parameters:
// - f: Function that produces a Reader for side effects
//
// Returns a function that taps with Reader-returning functions.
//
//go:inline
func TapReaderK[A, B any](f reader.Kleisli[context.Context, A, B]) Operator[A, A] {
return RIO.TapReaderK(f)
}
// Read executes a [ReaderIO] with a given context, returning the resulting [IO].
// This is useful for providing the context dependency and obtaining an IO action
// that can be executed later.
//
// Parameters:
// - r: The context to provide to the ReaderIO
//
// Returns a function that converts a ReaderIO into an IO by applying the context.
//
//go:inline
func Read[A any](r context.Context) func(ReaderIO[A]) IO[A] {
return RIO.Read[A](r)
}
// Local transforms the context.Context environment before passing it to a ReaderIO computation.
//
// This is the Reader's local operation, which allows you to modify the environment
// for a specific computation without affecting the outer context. The transformation
// function receives the current context and returns a new context along with a
// cancel function. The cancel function is automatically called when the computation
// completes (via defer), ensuring proper cleanup of resources.
//
// This is useful for:
// - Adding timeouts or deadlines to specific operations
// - Adding context values for nested computations
// - Creating isolated context scopes
// - Implementing context-based dependency injection
//
// Type Parameters:
// - A: The value type of the ReaderIO
//
// Parameters:
// - f: A function that transforms the context and returns a cancel function
//
// Returns:
// - An Operator that runs the computation with the transformed context
//
// Example:
//
// import F "github.com/IBM/fp-go/v2/function"
//
// // Add a custom value to the context
// type key int
// const userKey key = 0
//
// addUser := readerio.Local[string](func(ctx context.Context) (context.Context, context.CancelFunc) {
// newCtx := context.WithValue(ctx, userKey, "Alice")
// return newCtx, func() {} // No-op cancel
// })
//
// getUser := readerio.FromReader(func(ctx context.Context) string {
// if user := ctx.Value(userKey); user != nil {
// return user.(string)
// }
// return "unknown"
// })
//
// result := F.Pipe1(
// getUser,
// addUser,
// )
// user := result(context.Background())() // Returns "Alice"
//
// Timeout Example:
//
// // Add a 5-second timeout to a specific operation
// withTimeout := readerio.Local[Data](func(ctx context.Context) (context.Context, context.CancelFunc) {
// return context.WithTimeout(ctx, 5*time.Second)
// })
//
// result := F.Pipe1(
// fetchData,
// withTimeout,
// )
func Local[A any](f func(context.Context) (context.Context, context.CancelFunc)) Operator[A, A] {
return func(rr ReaderIO[A]) ReaderIO[A] {
return func(ctx context.Context) IO[A] {
return func() A {
otherCtx, otherCancel := f(ctx)
defer otherCancel()
return rr(otherCtx)()
}
}
}
}
// WithTimeout adds a timeout to the context for a ReaderIO computation.
//
// This is a convenience wrapper around Local that uses context.WithTimeout.
// The computation must complete within the specified duration, or it will be
// cancelled. This is useful for ensuring operations don't run indefinitely
// and for implementing timeout-based error handling.
//
// The timeout is relative to when the ReaderIO is executed, not when
// WithTimeout is called. The cancel function is automatically called when
// the computation completes, ensuring proper cleanup.
//
// Type Parameters:
// - A: The value type of the ReaderIO
//
// Parameters:
// - timeout: The maximum duration for the computation
//
// Returns:
// - An Operator that runs the computation with a timeout
//
// Example:
//
// import (
// "time"
// F "github.com/IBM/fp-go/v2/function"
// )
//
// // Fetch data with a 5-second timeout
// fetchData := readerio.FromReader(func(ctx context.Context) Data {
// // Simulate slow operation
// select {
// case <-time.After(10 * time.Second):
// return Data{Value: "slow"}
// case <-ctx.Done():
// return Data{}
// }
// })
//
// result := F.Pipe1(
// fetchData,
// readerio.WithTimeout[Data](5*time.Second),
// )
// data := result(context.Background())() // Returns Data{} after 5s timeout
//
// Successful Example:
//
// quickFetch := readerio.Of(Data{Value: "quick"})
// result := F.Pipe1(
// quickFetch,
// readerio.WithTimeout[Data](5*time.Second),
// )
// data := result(context.Background())() // Returns Data{Value: "quick"}
func WithTimeout[A any](timeout time.Duration) Operator[A, A] {
return Local[A](func(ctx context.Context) (context.Context, context.CancelFunc) {
return context.WithTimeout(ctx, timeout)
})
}
// WithDeadline adds an absolute deadline to the context for a ReaderIO computation.
//
// This is a convenience wrapper around Local that uses context.WithDeadline.
// The computation must complete before the specified time, or it will be
// cancelled. This is useful for coordinating operations that must finish
// by a specific time, such as request deadlines or scheduled tasks.
//
// The deadline is an absolute time, unlike WithTimeout which uses a relative
// duration. The cancel function is automatically called when the computation
// completes, ensuring proper cleanup.
//
// Type Parameters:
// - A: The value type of the ReaderIO
//
// Parameters:
// - deadline: The absolute time by which the computation must complete
//
// Returns:
// - An Operator that runs the computation with a deadline
//
// Example:
//
// import (
// "time"
// F "github.com/IBM/fp-go/v2/function"
// )
//
// // Operation must complete by 3 PM
// deadline := time.Date(2024, 1, 1, 15, 0, 0, 0, time.UTC)
//
// fetchData := readerio.FromReader(func(ctx context.Context) Data {
// // Simulate operation
// select {
// case <-time.After(1 * time.Hour):
// return Data{Value: "done"}
// case <-ctx.Done():
// return Data{}
// }
// })
//
// result := F.Pipe1(
// fetchData,
// readerio.WithDeadline[Data](deadline),
// )
// data := result(context.Background())() // Returns Data{} if past deadline
//
// Combining with Parent Context:
//
// // If parent context already has a deadline, the earlier one takes precedence
// parentCtx, cancel := context.WithDeadline(context.Background(), time.Now().Add(1*time.Hour))
// defer cancel()
//
// laterDeadline := time.Now().Add(2 * time.Hour)
// result := F.Pipe1(
// fetchData,
// readerio.WithDeadline[Data](laterDeadline),
// )
// data := result(parentCtx)() // Will use parent's 1-hour deadline
func WithDeadline[A any](deadline time.Time) Operator[A, A] {
return Local[A](func(ctx context.Context) (context.Context, context.CancelFunc) {
return context.WithDeadline(ctx, deadline)
})
}
// Delay creates an operation that passes in the value after some delay
//
//go:inline
func Delay[A any](delay time.Duration) Operator[A, A] {
return RIO.Delay[context.Context, A](delay)
}
// After creates an operation that passes after the given [time.Time]
//
//go:inline
func After[R, E, A any](timestamp time.Time) Operator[A, A] {
return RIO.After[context.Context, A](timestamp)
}

502
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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerio
import (
"context"
"testing"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/internal/utils"
G "github.com/IBM/fp-go/v2/io"
N "github.com/IBM/fp-go/v2/number"
"github.com/IBM/fp-go/v2/reader"
"github.com/stretchr/testify/assert"
)
func TestMonadMap(t *testing.T) {
rio := Of(5)
doubled := MonadMap(rio, N.Mul(2))
result := doubled(context.Background())()
assert.Equal(t, 10, result)
}
func TestMap(t *testing.T) {
g := F.Pipe1(
Of(1),
Map(utils.Double),
)
assert.Equal(t, 2, g(context.Background())())
}
func TestMonadMapTo(t *testing.T) {
rio := Of(42)
replaced := MonadMapTo(rio, "constant")
result := replaced(context.Background())()
assert.Equal(t, "constant", result)
}
func TestMapTo(t *testing.T) {
result := F.Pipe1(
Of(42),
MapTo[int]("constant"),
)
assert.Equal(t, "constant", result(context.Background())())
}
func TestMonadChain(t *testing.T) {
rio1 := Of(5)
result := MonadChain(rio1, func(n int) ReaderIO[int] {
return Of(n * 3)
})
assert.Equal(t, 15, result(context.Background())())
}
func TestChain(t *testing.T) {
result := F.Pipe1(
Of(5),
Chain(func(n int) ReaderIO[int] {
return Of(n * 3)
}),
)
assert.Equal(t, 15, result(context.Background())())
}
func TestMonadChainFirst(t *testing.T) {
sideEffect := 0
rio := Of(42)
result := MonadChainFirst(rio, func(n int) ReaderIO[string] {
sideEffect = n
return Of("side effect")
})
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestChainFirst(t *testing.T) {
sideEffect := 0
result := F.Pipe1(
Of(42),
ChainFirst(func(n int) ReaderIO[string] {
sideEffect = n
return Of("side effect")
}),
)
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestMonadTap(t *testing.T) {
sideEffect := 0
rio := Of(42)
result := MonadTap(rio, func(n int) ReaderIO[func()] {
sideEffect = n
return Of(func() {})
})
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestTap(t *testing.T) {
sideEffect := 0
result := F.Pipe1(
Of(42),
Tap(func(n int) ReaderIO[func()] {
sideEffect = n
return Of(func() {})
}),
)
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestOf(t *testing.T) {
rio := Of(100)
result := rio(context.Background())()
assert.Equal(t, 100, result)
}
func TestMonadAp(t *testing.T) {
fabIO := Of(N.Mul(2))
faIO := Of(5)
result := MonadAp(fabIO, faIO)
assert.Equal(t, 10, result(context.Background())())
}
func TestAp(t *testing.T) {
g := F.Pipe1(
Of(utils.Double),
Ap[int](Of(1)),
)
assert.Equal(t, 2, g(context.Background())())
}
func TestMonadApSeq(t *testing.T) {
fabIO := Of(N.Add(10))
faIO := Of(5)
result := MonadApSeq(fabIO, faIO)
assert.Equal(t, 15, result(context.Background())())
}
func TestApSeq(t *testing.T) {
g := F.Pipe1(
Of(N.Add(10)),
ApSeq[int](Of(5)),
)
assert.Equal(t, 15, g(context.Background())())
}
func TestMonadApPar(t *testing.T) {
fabIO := Of(N.Add(10))
faIO := Of(5)
result := MonadApPar(fabIO, faIO)
assert.Equal(t, 15, result(context.Background())())
}
func TestApPar(t *testing.T) {
g := F.Pipe1(
Of(N.Add(10)),
ApPar[int](Of(5)),
)
assert.Equal(t, 15, g(context.Background())())
}
func TestAsk(t *testing.T) {
rio := Ask()
ctx := context.WithValue(context.Background(), "key", "value")
result := rio(ctx)()
assert.Equal(t, ctx, result)
}
func TestFromIO(t *testing.T) {
ioAction := G.Of(42)
rio := FromIO(ioAction)
result := rio(context.Background())()
assert.Equal(t, 42, result)
}
func TestFromReader(t *testing.T) {
rdr := func(ctx context.Context) int {
return 42
}
rio := FromReader(rdr)
result := rio(context.Background())()
assert.Equal(t, 42, result)
}
func TestFromLazy(t *testing.T) {
lazy := func() int { return 42 }
rio := FromLazy(lazy)
result := rio(context.Background())()
assert.Equal(t, 42, result)
}
func TestMonadChainIOK(t *testing.T) {
rio := Of(5)
result := MonadChainIOK(rio, func(n int) G.IO[int] {
return G.Of(n * 4)
})
assert.Equal(t, 20, result(context.Background())())
}
func TestChainIOK(t *testing.T) {
result := F.Pipe1(
Of(5),
ChainIOK(func(n int) G.IO[int] {
return G.Of(n * 4)
}),
)
assert.Equal(t, 20, result(context.Background())())
}
func TestMonadChainFirstIOK(t *testing.T) {
sideEffect := 0
rio := Of(42)
result := MonadChainFirstIOK(rio, func(n int) G.IO[string] {
sideEffect = n
return G.Of("side effect")
})
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestChainFirstIOK(t *testing.T) {
sideEffect := 0
result := F.Pipe1(
Of(42),
ChainFirstIOK(func(n int) G.IO[string] {
sideEffect = n
return G.Of("side effect")
}),
)
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestMonadTapIOK(t *testing.T) {
sideEffect := 0
rio := Of(42)
result := MonadTapIOK(rio, func(n int) G.IO[func()] {
sideEffect = n
return G.Of(func() {})
})
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestTapIOK(t *testing.T) {
sideEffect := 0
result := F.Pipe1(
Of(42),
TapIOK(func(n int) G.IO[func()] {
sideEffect = n
return G.Of(func() {})
}),
)
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestDefer(t *testing.T) {
counter := 0
rio := Defer(func() ReaderIO[int] {
counter++
return Of(counter)
})
result1 := rio(context.Background())()
result2 := rio(context.Background())()
assert.Equal(t, 1, result1)
assert.Equal(t, 2, result2)
}
func TestMemoize(t *testing.T) {
counter := 0
rio := Of(0)
memoized := Memoize(MonadMap(rio, func(int) int {
counter++
return counter
}))
result1 := memoized(context.Background())()
result2 := memoized(context.Background())()
assert.Equal(t, 1, result1)
assert.Equal(t, 1, result2) // Same value, memoized
}
func TestFlatten(t *testing.T) {
nested := Of(Of(42))
flattened := Flatten(nested)
result := flattened(context.Background())()
assert.Equal(t, 42, result)
}
func TestMonadFlap(t *testing.T) {
fabIO := Of(N.Mul(3))
result := MonadFlap(fabIO, 7)
assert.Equal(t, 21, result(context.Background())())
}
func TestFlap(t *testing.T) {
result := F.Pipe1(
Of(N.Mul(3)),
Flap[int](7),
)
assert.Equal(t, 21, result(context.Background())())
}
func TestMonadChainReaderK(t *testing.T) {
rio := Of(5)
result := MonadChainReaderK(rio, func(n int) reader.Reader[context.Context, int] {
return func(ctx context.Context) int { return n * 2 }
})
assert.Equal(t, 10, result(context.Background())())
}
func TestChainReaderK(t *testing.T) {
result := F.Pipe1(
Of(5),
ChainReaderK(func(n int) reader.Reader[context.Context, int] {
return func(ctx context.Context) int { return n * 2 }
}),
)
assert.Equal(t, 10, result(context.Background())())
}
func TestMonadChainFirstReaderK(t *testing.T) {
sideEffect := 0
rio := Of(42)
result := MonadChainFirstReaderK(rio, func(n int) reader.Reader[context.Context, string] {
return func(ctx context.Context) string {
sideEffect = n
return "side effect"
}
})
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestChainFirstReaderK(t *testing.T) {
sideEffect := 0
result := F.Pipe1(
Of(42),
ChainFirstReaderK(func(n int) reader.Reader[context.Context, string] {
return func(ctx context.Context) string {
sideEffect = n
return "side effect"
}
}),
)
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestMonadTapReaderK(t *testing.T) {
sideEffect := 0
rio := Of(42)
result := MonadTapReaderK(rio, func(n int) reader.Reader[context.Context, func()] {
return func(ctx context.Context) func() {
sideEffect = n
return func() {}
}
})
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestTapReaderK(t *testing.T) {
sideEffect := 0
result := F.Pipe1(
Of(42),
TapReaderK(func(n int) reader.Reader[context.Context, func()] {
return func(ctx context.Context) func() {
sideEffect = n
return func() {}
}
}),
)
value := result(context.Background())()
assert.Equal(t, 42, value)
assert.Equal(t, 42, sideEffect)
}
func TestRead(t *testing.T) {
rio := Of(42)
ctx := context.Background()
ioAction := Read[int](ctx)(rio)
result := ioAction()
assert.Equal(t, 42, result)
}
func TestComplexPipeline(t *testing.T) {
// Test a complex pipeline combining multiple operations
result := F.Pipe3(
Ask(),
Map(func(ctx context.Context) int { return 5 }),
Chain(func(n int) ReaderIO[int] {
return Of(n * 2)
}),
Map(N.Add(10)),
)
assert.Equal(t, 20, result(context.Background())()) // (5 * 2) + 10 = 20
}
func TestFromIOWithChain(t *testing.T) {
ioAction := G.Of(10)
result := F.Pipe1(
FromIO(ioAction),
Chain(func(n int) ReaderIO[int] {
return Of(n + 5)
}),
)
assert.Equal(t, 15, result(context.Background())())
}
func TestTapWithLogging(t *testing.T) {
// Simulate logging scenario
logged := []int{}
result := F.Pipe3(
Of(42),
Tap(func(n int) ReaderIO[func()] {
logged = append(logged, n)
return Of(func() {})
}),
Map(N.Mul(2)),
Tap(func(n int) ReaderIO[func()] {
logged = append(logged, n)
return Of(func() {})
}),
)
value := result(context.Background())()
assert.Equal(t, 84, value)
assert.Equal(t, []int{42, 84}, logged)
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerio
import (
"github.com/IBM/fp-go/v2/readerio"
)
//go:inline
func TailRec[A, B any](f Kleisli[A, Either[A, B]]) Kleisli[A, B] {
return readerio.TailRec(f)
}

41
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// Copyright (c) 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerio
import (
"github.com/IBM/fp-go/v2/retry"
RG "github.com/IBM/fp-go/v2/retry/generic"
)
//go:inline
func Retrying[A any](
policy retry.RetryPolicy,
action Kleisli[retry.RetryStatus, A],
check func(A) bool,
) ReaderIO[A] {
// get an implementation for the types
return RG.Retrying(
Chain[A, A],
Chain[retry.RetryStatus, A],
Of[A],
Of[retry.RetryStatus],
Delay[retry.RetryStatus],
policy,
action,
check,
)
}

75
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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerio
import (
"context"
"github.com/IBM/fp-go/v2/consumer"
"github.com/IBM/fp-go/v2/either"
"github.com/IBM/fp-go/v2/io"
"github.com/IBM/fp-go/v2/lazy"
"github.com/IBM/fp-go/v2/reader"
"github.com/IBM/fp-go/v2/readerio"
)
type (
// Lazy represents a deferred computation that produces a value of type A when executed.
// The computation is not executed until explicitly invoked.
Lazy[A any] = lazy.Lazy[A]
// IO represents a side-effectful computation that produces a value of type A.
// The computation is deferred and only executed when invoked.
//
// IO[A] is equivalent to func() A
IO[A any] = io.IO[A]
// Reader represents a computation that depends on a context of type R.
// This is used for dependency injection and accessing shared context.
//
// Reader[R, A] is equivalent to func(R) A
Reader[R, A any] = reader.Reader[R, A]
// ReaderIO represents a context-dependent computation that performs side effects.
// This is specialized to use [context.Context] as the context type.
//
// ReaderIO[A] is equivalent to func(context.Context) func() A
ReaderIO[A any] = readerio.ReaderIO[context.Context, A]
// Kleisli represents a Kleisli arrow for the ReaderIO monad.
// It is a function that takes a value of type A and returns a ReaderIO computation
// that produces a value of type B.
//
// Kleisli arrows are used for composing monadic computations and are fundamental
// to functional programming patterns involving effects and context.
//
// Kleisli[A, B] is equivalent to func(A) func(context.Context) func() B
Kleisli[A, B any] = reader.Reader[A, ReaderIO[B]]
// Operator represents a transformation from one ReaderIO computation to another.
// It takes a ReaderIO[A] and returns a ReaderIO[B], allowing for the composition
// of context-dependent, side-effectful computations.
//
// Operators are useful for building pipelines of ReaderIO computations where
// each step can depend on the previous computation's result.
//
// Operator[A, B] is equivalent to func(ReaderIO[A]) func(context.Context) func() B
Operator[A, B any] = Kleisli[ReaderIO[A], B]
Consumer[A any] = consumer.Consumer[A]
Either[E, A any] = either.Either[E, A]
)

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# Sequence Functions and Point-Free Style Programming
This document explains how the `Sequence*` functions in the `context/readerioresult` package enable point-free style programming and improve code composition.
## Table of Contents
1. [What is Point-Free Style?](#what-is-point-free-style)
2. [The Problem: Nested Function Application](#the-problem-nested-function-application)
3. [The Solution: Sequence Functions](#the-solution-sequence-functions)
4. [How Sequence Enables Point-Free Style](#how-sequence-enables-point-free-style)
5. [TraverseReader: Introducing Dependencies](#traversereader-introducing-dependencies)
6. [Practical Benefits](#practical-benefits)
7. [Examples](#examples)
8. [Comparison: With and Without Sequence](#comparison-with-and-without-sequence)
## What is Point-Free Style?
Point-free style (also called tacit programming) is a programming paradigm where function definitions don't explicitly mention their arguments. Instead, functions are composed using combinators and higher-order functions.
**Traditional style (with points):**
```go
func double(x int) int {
return x * 2
}
```
**Point-free style (without points):**
```go
var double = N.Mul(2)
```
The key benefit is that point-free style emphasizes **what** the function does (its transformation) rather than **how** it manipulates data.
## The Problem: Nested Function Application
In functional programming with monadic types like `ReaderIOResult`, we often have nested structures where we need to apply parameters in a specific order. Consider:
```go
type ReaderIOResult[A any] = func(context.Context) func() Either[error, A]
type Reader[R, A any] = func(R) A
// A computation that produces a Reader
type Computation = ReaderIOResult[Reader[Config, int]]
// Expands to: func(context.Context) func() Either[error, func(Config) int]
```
To use this, we must apply parameters in this order:
1. First, provide `context.Context`
2. Then, execute the IO effect (call the function)
3. Then, unwrap the `Either` to get the `Reader`
4. Finally, provide the `Config`
This creates several problems:
### Problem 1: Awkward Parameter Order
```go
computation := getComputation()
ctx := context.Background()
cfg := Config{Value: 42}
// Must apply in this specific order
result := computation(ctx)() // Get Either[error, Reader[Config, int]]
if reader, err := either.Unwrap(result); err == nil {
value := reader(cfg) // Finally apply Config
// use value
}
```
The `Config` parameter, which is often known early and stable, must be provided last. This prevents partial application and reuse.
### Problem 2: Cannot Partially Apply Dependencies
```go
// Want to do this: create a reusable computation with Config baked in
// But can't because Config comes last!
withConfig := computation(cfg) // ❌ Doesn't work - cfg comes last, not first
```
### Problem 3: Breaks Point-Free Composition
```go
// Want to compose like this:
var pipeline = F.Flow3(
getComputation,
applyConfig(cfg), // ❌ Can't do this - Config comes last
processResult,
)
```
## The Solution: Sequence Functions
The `Sequence*` functions solve this by "flipping" or "sequencing" the nested structure, changing the order in which parameters are applied.
### SequenceReader
```go
func SequenceReader[R, A any](
ma ReaderIOResult[Reader[R, A]]
) Kleisli[R, A]
```
**Type transformation:**
```
From: func(context.Context) func() Either[error, func(R) A]
To: func(R) func(context.Context) func() Either[error, A]
```
Now `R` (the Reader's environment) comes **first**, before `context.Context`!
### SequenceReaderIO
```go
func SequenceReaderIO[R, A any](
ma ReaderIOResult[ReaderIO[R, A]]
) Kleisli[R, A]
```
**Type transformation:**
```
From: func(context.Context) func() Either[error, func(R) func() A]
To: func(R) func(context.Context) func() Either[error, A]
```
### SequenceReaderResult
```go
func SequenceReaderResult[R, A any](
ma ReaderIOResult[ReaderResult[R, A]]
) Kleisli[R, A]
```
**Type transformation:**
```
From: func(context.Context) func() Either[error, func(R) Either[error, A]]
To: func(R) func(context.Context) func() Either[error, A]
```
## How Sequence Enables Point-Free Style
### 1. Partial Application
By moving the environment parameter first, we can partially apply it:
```go
type Config struct { Multiplier int }
computation := getComputation() // ReaderIOResult[Reader[Config, int]]
sequenced := SequenceReader[Config, int](computation)
// Partially apply Config
cfg := Config{Multiplier: 5}
withConfig := sequenced(cfg) // ✅ Now we have ReaderIOResult[int]
// Reuse with different contexts
result1 := withConfig(ctx1)()
result2 := withConfig(ctx2)()
```
### 2. Dependency Injection
Inject dependencies early in the pipeline:
```go
type Database struct { ConnectionString string }
makeQuery := func(ctx context.Context) func() Either[error, func(Database) string] {
// ... implementation
}
// Sequence to enable DI
queryWithDB := SequenceReader[Database, string](makeQuery)
// Inject database
db := Database{ConnectionString: "localhost:5432"}
query := queryWithDB(db) // ✅ Database injected
// Use query with any context
result := query(context.Background())()
```
### 3. Point-Free Composition
Build pipelines without mentioning intermediate values:
```go
var pipeline = F.Flow3(
getComputation, // ReaderIOResult[Reader[Config, int]]
SequenceReader[Config, int], // func(Config) ReaderIOResult[int]
applyConfig(cfg), // ReaderIOResult[int]
)
// Or with partial application:
var withConfig = F.Pipe1(
getComputation(),
SequenceReader[Config, int],
)
result := withConfig(cfg)(ctx)()
```
### 4. Reusable Computations
Create specialized versions of generic computations:
```go
// Generic computation
makeServiceInfo := func(ctx context.Context) func() Either[error, func(ServiceConfig) string] {
// ... implementation
}
sequenced := SequenceReader[ServiceConfig, string](makeServiceInfo)
// Create specialized versions
authService := sequenced(ServiceConfig{Name: "Auth", Version: "1.0"})
userService := sequenced(ServiceConfig{Name: "User", Version: "2.0"})
// Reuse across contexts
authInfo := authService(ctx)()
userInfo := userService(ctx)()
```
## TraverseReader: Introducing Dependencies
While `SequenceReader` flips the parameter order of an existing nested structure, `TraverseReader` allows you to **introduce** a new Reader dependency into an existing computation.
### Function Signature
```go
func TraverseReader[R, A, B any](
f reader.Kleisli[R, A, B],
) func(ReaderIOResult[A]) Kleisli[R, B]
```
**Type transformation:**
```
Input: ReaderIOResult[A] = func(context.Context) func() Either[error, A]
With: reader.Kleisli[R, A, B] = func(A) func(R) B
Output: Kleisli[R, B] = func(R) func(context.Context) func() Either[error, B]
```
### What It Does
`TraverseReader` takes:
1. A Reader-based transformation `f: func(A) func(R) B` that depends on environment `R`
2. Returns a function that transforms `ReaderIOResult[A]` into `Kleisli[R, B]`
This allows you to:
- Add environment dependencies to computations that don't have them yet
- Transform values within a ReaderIOResult using environment-dependent logic
- Build composable pipelines where transformations depend on configuration
### Key Difference from SequenceReader
- **SequenceReader**: Works with computations that **already contain** a Reader (`ReaderIOResult[Reader[R, A]]`)
- Flips the order so `R` comes first
- No transformation of the value itself
- **TraverseReader**: Works with computations that **don't have** a Reader yet (`ReaderIOResult[A]`)
- Introduces a new Reader dependency via a transformation function
- Transforms `A` to `B` using environment `R`
### Example: Adding Configuration to a Computation
```go
type Config struct {
Multiplier int
Prefix string
}
// Original computation that just produces an int
getValue := func(ctx context.Context) func() Either[error, int] {
return func() Either[error, int] {
return Right[error](10)
}
}
// A Reader-based transformation that depends on Config
formatWithConfig := func(n int) func(Config) string {
return func(cfg Config) string {
result := n * cfg.Multiplier
return fmt.Sprintf("%s: %d", cfg.Prefix, result)
}
}
// Use TraverseReader to introduce Config dependency
traversed := TraverseReader[Config, int, string](formatWithConfig)
withConfig := traversed(getValue)
// Now we can provide Config to get the final result
cfg := Config{Multiplier: 5, Prefix: "Result"}
ctx := context.Background()
result := withConfig(cfg)(ctx)() // Returns Right("Result: 50")
```
### Point-Free Composition with TraverseReader
```go
// Build a pipeline that introduces dependencies at each stage
var pipeline = F.Flow4(
loadValue, // ReaderIOResult[int]
TraverseReader(multiplyByConfig), // Kleisli[Config, int]
applyConfig(cfg), // ReaderIOResult[int]
Chain(TraverseReader(formatWithStyle)), // Introduce another dependency
)
```
### When to Use TraverseReader vs SequenceReader
**Use SequenceReader when:**
- Your computation already returns a Reader: `ReaderIOResult[Reader[R, A]]`
- You just want to flip the parameter order
- No transformation of the value is needed
```go
// Already have Reader[Config, int]
computation := getComputation() // ReaderIOResult[Reader[Config, int]]
sequenced := SequenceReader[Config, int](computation)
result := sequenced(cfg)(ctx)()
```
**Use TraverseReader when:**
- Your computation doesn't have a Reader yet: `ReaderIOResult[A]`
- You want to transform the value using environment-dependent logic
- You're introducing a new dependency into the pipeline
```go
// Have ReaderIOResult[int], want to add Config dependency
computation := getValue() // ReaderIOResult[int]
traversed := TraverseReader[Config, int, string](formatWithConfig)
withDep := traversed(computation)
result := withDep(cfg)(ctx)()
```
### Practical Example: Multi-Stage Processing
```go
type DatabaseConfig struct {
ConnectionString string
Timeout time.Duration
}
type FormattingConfig struct {
DateFormat string
Timezone string
}
// Stage 1: Load raw data (no dependencies yet)
loadData := func(ctx context.Context) func() Either[error, RawData] {
// ... implementation
}
// Stage 2: Process with database config
processWithDB := func(raw RawData) func(DatabaseConfig) ProcessedData {
return func(cfg DatabaseConfig) ProcessedData {
// Use cfg.ConnectionString, cfg.Timeout
return ProcessedData{/* ... */}
}
}
// Stage 3: Format with formatting config
formatData := func(processed ProcessedData) func(FormattingConfig) string {
return func(cfg FormattingConfig) string {
// Use cfg.DateFormat, cfg.Timezone
return "formatted result"
}
}
// Build pipeline introducing dependencies at each stage
var pipeline = F.Flow3(
loadData,
TraverseReader[DatabaseConfig, RawData, ProcessedData](processWithDB),
// Now we have Kleisli[DatabaseConfig, ProcessedData]
applyConfig(dbConfig),
// Now we have ReaderIOResult[ProcessedData]
TraverseReader[FormattingConfig, ProcessedData, string](formatData),
// Now we have Kleisli[FormattingConfig, string]
)
// Execute with both configs
result := pipeline(fmtConfig)(ctx)()
```
### Combining TraverseReader and SequenceReader
You can combine both functions in complex pipelines:
```go
// Start with nested Reader
computation := getComputation() // ReaderIOResult[Reader[Config, User]]
var pipeline = F.Flow4(
computation,
SequenceReader[Config, User], // Flip to get Kleisli[Config, User]
applyConfig(cfg), // Apply config, get ReaderIOResult[User]
TraverseReader(enrichWithDatabase), // Add database dependency
// Now have Kleisli[Database, EnrichedUser]
)
result := pipeline(db)(ctx)()
```
## Practical Benefits
### 1. **Improved Testability**
Inject test dependencies easily:
```go
// Production
prodDB := Database{ConnectionString: "prod:5432"}
prodQuery := queryWithDB(prodDB)
// Testing
testDB := Database{ConnectionString: "test:5432"}
testQuery := queryWithDB(testDB)
// Same computation, different dependencies
```
### 2. **Better Separation of Concerns**
Separate configuration from execution:
```go
// Configuration phase (pure, no effects)
cfg := loadConfig()
computation := sequenced(cfg)
// Execution phase (with effects)
result := computation(ctx)()
```
### 3. **Enhanced Composability**
Build complex pipelines from simple pieces:
```go
var processUser = F.Flow4(
loadUserConfig, // ReaderIOResult[Reader[Database, User]]
SequenceReader, // func(Database) ReaderIOResult[User]
applyDatabase(db), // ReaderIOResult[User]
Chain(validateUser), // ReaderIOResult[ValidatedUser]
)
```
### 4. **Reduced Boilerplate**
No need to manually thread parameters:
```go
// Without Sequence - manual threading
func processWithConfig(cfg Config) ReaderIOResult[Result] {
return func(ctx context.Context) func() Either[error, Result] {
return func() Either[error, Result] {
comp := getComputation()(ctx)()
if reader, err := either.Unwrap(comp); err == nil {
value := reader(cfg)
// ... more processing
}
// ... error handling
}
}
}
// With Sequence - point-free
var processWithConfig = F.Flow2(
getComputation,
SequenceReader[Config, Result],
)
```
## Examples
### Example 1: Database Query with Configuration
```go
type QueryConfig struct {
Timeout time.Duration
MaxRows int
}
type Database struct {
ConnectionString string
}
// Without Sequence
func executeQueryOld(cfg QueryConfig, db Database) ReaderIOResult[[]Row] {
return func(ctx context.Context) func() Either[error, []Row] {
return func() Either[error, []Row] {
// Must manually handle all parameters
// ...
}
}
}
// With Sequence
func makeQuery(ctx context.Context) func() Either[error, func(Database) []Row] {
return func() Either[error, func(Database) []Row] {
return Right[error](func(db Database) []Row {
// Implementation
return []Row{}
})
}
}
var executeQuery = F.Flow2(
makeQuery,
SequenceReader[Database, []Row],
)
// Usage
db := Database{ConnectionString: "localhost:5432"}
query := executeQuery(db)
result := query(ctx)()
```
### Example 2: Multi-Service Architecture
```go
type ServiceRegistry struct {
AuthService AuthService
UserService UserService
EmailService EmailService
}
// Create computations that depend on services
makeAuthCheck := func(ctx context.Context) func() Either[error, func(ServiceRegistry) bool] {
// ... implementation
}
makeSendEmail := func(ctx context.Context) func() Either[error, func(ServiceRegistry) error] {
// ... implementation
}
// Sequence them
authCheck := SequenceReader[ServiceRegistry, bool](makeAuthCheck)
sendEmail := SequenceReader[ServiceRegistry, error](makeSendEmail)
// Inject services once
registry := ServiceRegistry{ /* ... */ }
checkAuth := authCheck(registry)
sendMail := sendEmail(registry)
// Use with different contexts
if isAuth, _ := either.Unwrap(checkAuth(ctx1)()); isAuth {
sendMail(ctx2)()
}
```
### Example 3: Configuration-Driven Pipeline
```go
type PipelineConfig struct {
Stage1Config Stage1Config
Stage2Config Stage2Config
Stage3Config Stage3Config
}
// Define stages
stage1 := SequenceReader[Stage1Config, IntermediateResult1](makeStage1)
stage2 := SequenceReader[Stage2Config, IntermediateResult2](makeStage2)
stage3 := SequenceReader[Stage3Config, FinalResult](makeStage3)
// Build pipeline with configuration
func buildPipeline(cfg PipelineConfig) ReaderIOResult[FinalResult] {
return F.Pipe3(
stage1(cfg.Stage1Config),
Chain(func(r1 IntermediateResult1) ReaderIOResult[IntermediateResult2] {
return stage2(cfg.Stage2Config)
}),
Chain(func(r2 IntermediateResult2) ReaderIOResult[FinalResult] {
return stage3(cfg.Stage3Config)
}),
)
}
// Execute pipeline
cfg := loadPipelineConfig()
pipeline := buildPipeline(cfg)
result := pipeline(ctx)()
```
## Comparison: With and Without Sequence
### Without Sequence (Imperative Style)
```go
func processUser(userID string) ReaderIOResult[ProcessedUser] {
return func(ctx context.Context) func() Either[error, ProcessedUser] {
return func() Either[error, ProcessedUser] {
// Get database
dbComp := getDatabase()(ctx)()
if dbReader, err := either.Unwrap(dbComp); err != nil {
return Left[ProcessedUser](err)
}
db := dbReader(dbConfig)
// Get user
userComp := getUser(userID)(ctx)()
if userReader, err := either.Unwrap(userComp); err != nil {
return Left[ProcessedUser](err)
}
user := userReader(db)
// Process user
processComp := processUserData(user)(ctx)()
if processReader, err := either.Unwrap(processComp); err != nil {
return Left[ProcessedUser](err)
}
result := processReader(processingConfig)
return Right[error](result)
}
}
}
```
### With Sequence (Point-Free Style)
```go
var processUser = func(userID string) ReaderIOResult[ProcessedUser] {
return F.Pipe3(
getDatabase,
SequenceReader[DatabaseConfig, Database],
applyConfig(dbConfig),
Chain(func(db Database) ReaderIOResult[User] {
return F.Pipe2(
getUser(userID),
SequenceReader[Database, User],
applyDB(db),
)
}),
Chain(func(user User) ReaderIOResult[ProcessedUser] {
return F.Pipe2(
processUserData(user),
SequenceReader[ProcessingConfig, ProcessedUser],
applyConfig(processingConfig),
)
}),
)
}
```
## Key Takeaways
1. **Sequence functions flip parameter order** to enable partial application
2. **Dependencies come first**, making them easy to inject and test
3. **Point-free style** becomes natural and readable
4. **Composition** is enhanced through proper parameter ordering
5. **Reusability** increases as computations can be specialized early
6. **Testability** improves through easy dependency injection
7. **Separation of concerns** is clearer (configuration vs. execution)
## When to Use Sequence
Use `Sequence*` functions when:
- ✅ You want to partially apply environment/configuration parameters
- ✅ You're building reusable computations with injected dependencies
- ✅ You need to test with different dependency implementations
- ✅ You're composing complex pipelines in point-free style
- ✅ You want to separate configuration from execution
- ✅ You're working with nested Reader-like structures
Don't use `Sequence*` when:
- ❌ The original parameter order is already optimal
- ❌ You're not doing any composition or partial application
- ❌ The added abstraction doesn't provide value
- ❌ The code is simpler without it
## Conclusion
The `Sequence*` functions are powerful tools for enabling point-free style programming in Go. By flipping the parameter order of nested monadic structures, they make it easy to:
- Partially apply dependencies
- Build composable pipelines
- Improve testability
- Write more declarative code
While they add a layer of abstraction, the benefits in terms of code reusability, testability, and composability make them invaluable for functional programming in Go.

52
v2/context/readerioresult/bind.go
View File

@@ -18,14 +18,13 @@ package readerioresult
import (
"context"
"github.com/IBM/fp-go/v2/context/readerio"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/internal/apply"
"github.com/IBM/fp-go/v2/io"
"github.com/IBM/fp-go/v2/ioeither"
"github.com/IBM/fp-go/v2/ioresult"
L "github.com/IBM/fp-go/v2/optics/lens"
"github.com/IBM/fp-go/v2/reader"
"github.com/IBM/fp-go/v2/readerio"
RIOR "github.com/IBM/fp-go/v2/readerioresult"
"github.com/IBM/fp-go/v2/result"
)
@@ -96,7 +95,7 @@ func Bind[S1, S2, T any](
setter func(T) func(S1) S2,
f Kleisli[S1, T],
) Operator[S1, S2] {
return RIOR.Bind(setter, f)
return RIOR.Bind(setter, WithContextK(f))
}
// Let attaches the result of a computation to a context [S1] to produce a context [S2]
@@ -128,6 +127,13 @@ func BindTo[S1, T any](
return RIOR.BindTo[context.Context](setter)
}
//go:inline
func BindToP[S1, T any](
setter Prism[S1, T],
) Operator[T, S1] {
return BindTo(setter.ReverseGet)
}
// ApS attaches a value to a context [S1] to produce a context [S2] by considering
// the context and the value concurrently (using Applicative rather than Monad).
// This allows independent computations to be combined without one depending on the result of the other.
@@ -214,7 +220,7 @@ func ApS[S1, S2, T any](
//
//go:inline
func ApSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa ReaderIOResult[T],
) Operator[S, S] {
return ApS(lens.Set, fa)
@@ -253,10 +259,10 @@ func ApSL[S, T any](
//
//go:inline
func BindL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
f Kleisli[T, T],
) Operator[S, S] {
return RIOR.BindL(lens, f)
return RIOR.BindL(lens, WithContextK(f))
}
// LetL is a variant of Let that uses a lens to focus on a specific part of the context.
@@ -289,8 +295,8 @@ func BindL[S, T any](
//
//go:inline
func LetL[S, T any](
lens L.Lens[S, T],
f func(T) T,
lens Lens[S, T],
f Endomorphism[T],
) Operator[S, S] {
return RIOR.LetL[context.Context](lens, f)
}
@@ -322,7 +328,7 @@ func LetL[S, T any](
//
//go:inline
func LetToL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
b T,
) Operator[S, S] {
return RIOR.LetToL[context.Context](lens, b)
@@ -398,7 +404,7 @@ func BindReaderK[S1, S2, T any](
//go:inline
func BindReaderIOK[S1, S2, T any](
setter func(T) func(S1) S2,
f readerio.Kleisli[context.Context, S1, T],
f readerio.Kleisli[S1, T],
) Operator[S1, S2] {
return Bind(setter, F.Flow2(f, FromReaderIO[T]))
}
@@ -443,7 +449,7 @@ func BindResultK[S1, S2, T any](
//
//go:inline
func BindIOEitherKL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
f ioresult.Kleisli[T, T],
) Operator[S, S] {
return BindL(lens, F.Flow2(f, FromIOEither[T]))
@@ -458,7 +464,7 @@ func BindIOEitherKL[S, T any](
//
//go:inline
func BindIOResultKL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
f ioresult.Kleisli[T, T],
) Operator[S, S] {
return BindL(lens, F.Flow2(f, FromIOEither[T]))
@@ -474,7 +480,7 @@ func BindIOResultKL[S, T any](
//
//go:inline
func BindIOKL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
f io.Kleisli[T, T],
) Operator[S, S] {
return BindL(lens, F.Flow2(f, FromIO[T]))
@@ -490,7 +496,7 @@ func BindIOKL[S, T any](
//
//go:inline
func BindReaderKL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
f reader.Kleisli[context.Context, T, T],
) Operator[S, S] {
return BindL(lens, F.Flow2(f, FromReader[T]))
@@ -506,8 +512,8 @@ func BindReaderKL[S, T any](
//
//go:inline
func BindReaderIOKL[S, T any](
lens L.Lens[S, T],
f readerio.Kleisli[context.Context, T, T],
lens Lens[S, T],
f readerio.Kleisli[T, T],
) Operator[S, S] {
return BindL(lens, F.Flow2(f, FromReaderIO[T]))
}
@@ -627,7 +633,7 @@ func ApResultS[S1, S2, T any](
//
//go:inline
func ApIOEitherSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa IOResult[T],
) Operator[S, S] {
return F.Bind2nd(F.Flow2[ReaderIOResult[S], ioresult.Operator[S, S]], ioresult.ApSL(lens, fa))
@@ -642,7 +648,7 @@ func ApIOEitherSL[S, T any](
//
//go:inline
func ApIOResultSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa IOResult[T],
) Operator[S, S] {
return F.Bind2nd(F.Flow2[ReaderIOResult[S], ioresult.Operator[S, S]], ioresult.ApSL(lens, fa))
@@ -657,7 +663,7 @@ func ApIOResultSL[S, T any](
//
//go:inline
func ApIOSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa IO[T],
) Operator[S, S] {
return ApSL(lens, FromIO(fa))
@@ -672,7 +678,7 @@ func ApIOSL[S, T any](
//
//go:inline
func ApReaderSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa Reader[context.Context, T],
) Operator[S, S] {
return ApSL(lens, FromReader(fa))
@@ -687,7 +693,7 @@ func ApReaderSL[S, T any](
//
//go:inline
func ApReaderIOSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa ReaderIO[T],
) Operator[S, S] {
return ApSL(lens, FromReaderIO(fa))
@@ -702,7 +708,7 @@ func ApReaderIOSL[S, T any](
//
//go:inline
func ApEitherSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa Result[T],
) Operator[S, S] {
return ApSL(lens, FromEither(fa))
@@ -717,7 +723,7 @@ func ApEitherSL[S, T any](
//
//go:inline
func ApResultSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa Result[T],
) Operator[S, S] {
return ApSL(lens, FromResult(fa))

4
v2/context/readerioresult/bind_test.go
View File

@@ -203,9 +203,7 @@ func TestApS_EmptyState(t *testing.T) {
result := res(t.Context())()
assert.True(t, E.IsRight(result))
emptyOpt := E.ToOption(result)
assert.True(t, O.IsSome(emptyOpt))
empty, _ := O.Unwrap(emptyOpt)
assert.Equal(t, Empty{}, empty)
assert.Equal(t, O.Of(Empty{}), emptyOpt)
}
func TestApS_ChainedWithBind(t *testing.T) {

5
v2/context/readerioresult/bracket.go
View File

@@ -16,11 +16,14 @@
package readerioresult
import (
F "github.com/IBM/fp-go/v2/function"
RIOR "github.com/IBM/fp-go/v2/readerioresult"
)
// Bracket makes sure that a resource is cleaned up in the event of an error. The release action is called regardless of
// whether the body action returns and error or not.
//
//go:inline
func Bracket[
A, B, ANY any](
@@ -28,5 +31,5 @@ func Bracket[
use Kleisli[A, B],
release func(A, Either[B]) ReaderIOResult[ANY],
) ReaderIOResult[B] {
return RIOR.Bracket(acquire, use, release)
return RIOR.Bracket(acquire, F.Flow2(use, WithContext), release)
}

13
v2/context/readerioresult/cancel.go
View File

@@ -19,6 +19,7 @@ import (
"context"
CIOE "github.com/IBM/fp-go/v2/context/ioresult"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/ioeither"
)
@@ -34,9 +35,17 @@ import (
// Returns a ReaderIOResult that checks for cancellation before executing.
func WithContext[A any](ma ReaderIOResult[A]) ReaderIOResult[A] {
return func(ctx context.Context) IOEither[A] {
if err := context.Cause(ctx); err != nil {
return ioeither.Left[A](err)
if ctx.Err() != nil {
return ioeither.Left[A](context.Cause(ctx))
}
return CIOE.WithContext(ctx, ma(ctx))
}
}
//go:inline
func WithContextK[A, B any](f Kleisli[A, B]) Kleisli[A, B] {
return F.Flow2(
f,
WithContext,
)
}

13
v2/context/readerioresult/consumer.go Normal file
View File

@@ -0,0 +1,13 @@
package readerioresult
import "github.com/IBM/fp-go/v2/io"
//go:inline
func ChainConsumer[A any](c Consumer[A]) Operator[A, struct{}] {
return ChainIOK(io.FromConsumerK(c))
}
//go:inline
func ChainFirstConsumer[A any](c Consumer[A]) Operator[A, A] {
return ChainFirstIOK(io.FromConsumerK(c))
}

295
v2/context/readerioresult/flip.go Normal file
View File

@@ -0,0 +1,295 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerioresult
import (
"context"
"github.com/IBM/fp-go/v2/reader"
RIO "github.com/IBM/fp-go/v2/readerio"
RIOR "github.com/IBM/fp-go/v2/readerioresult"
RR "github.com/IBM/fp-go/v2/readerresult"
)
// SequenceReader transforms a ReaderIOResult containing a Reader into a function that
// takes the Reader's environment first, then returns a ReaderIOResult.
//
// This function "flips" or "sequences" the nested structure, changing the order in which
// parameters are applied. It's particularly useful for point-free style programming where
// you want to partially apply the inner Reader's environment before dealing with the
// outer context.
//
// Type transformation:
//
// From: ReaderIOResult[Reader[R, A]]
// = func(context.Context) func() Either[error, func(R) A]
//
// To: func(context.Context) func(R) IOResult[A]
// = func(context.Context) func(R) func() Either[error, A]
//
// This allows you to:
// 1. Provide the context.Context first
// 2. Then provide the Reader's environment R
// 3. Finally execute the IO effect to get Either[error, A]
//
// Point-free style benefits:
// - Enables partial application of the Reader environment
// - Facilitates composition of Reader-based computations
// - Allows building reusable computation pipelines
// - Supports dependency injection patterns where R represents dependencies
//
// Example:
//
// type Config struct {
// Timeout int
// }
//
// // A computation that produces a Reader based on context
// func getMultiplier(ctx context.Context) func() Either[error, func(Config) int] {
// return func() Either[error, func(Config) int] {
// return Right[error](func(cfg Config) int {
// return cfg.Timeout * 2
// })
// }
// }
//
// // Sequence it to apply Config first
// sequenced := SequenceReader[Config, int](getMultiplier)
//
// // Now we can partially apply the Config
// cfg := Config{Timeout: 30}
// ctx := context.Background()
// result := sequenced(ctx)(cfg)() // Returns Right(60)
//
// This is especially useful in point-free style when building computation pipelines:
//
// var pipeline = F.Flow3(
// loadConfig, // ReaderIOResult[Reader[Database, Config]]
// SequenceReader, // func(context.Context) func(Database) IOResult[Config]
// applyToDatabase(db), // IOResult[Config]
// )
//
//go:inline
func SequenceReader[R, A any](ma ReaderIOResult[Reader[R, A]]) Kleisli[R, A] {
return RIOR.SequenceReader(ma)
}
// SequenceReaderIO transforms a ReaderIOResult containing a ReaderIO into a function that
// takes the ReaderIO's environment first, then returns a ReaderIOResult.
//
// This is similar to SequenceReader but works with ReaderIO, which represents a computation
// that depends on an environment R and performs IO effects.
//
// Type transformation:
//
// From: ReaderIOResult[ReaderIO[R, A]]
// = func(context.Context) func() Either[error, func(R) func() A]
//
// To: func(context.Context) func(R) IOResult[A]
// = func(context.Context) func(R) func() Either[error, A]
//
// The key difference from SequenceReader is that the inner computation (ReaderIO) already
// performs IO effects, so the sequencing combines these effects properly.
//
// Point-free style benefits:
// - Enables composition of ReaderIO-based computations
// - Allows partial application of environment before IO execution
// - Facilitates building effect pipelines with dependency injection
// - Supports layered architecture where R represents service dependencies
//
// Example:
//
// type Database struct {
// ConnectionString string
// }
//
// // A computation that produces a ReaderIO based on context
// func getQuery(ctx context.Context) func() Either[error, func(Database) func() string] {
// return func() Either[error, func(Database) func() string] {
// return Right[error](func(db Database) func() string {
// return func() string {
// // Perform actual IO here
// return "Query result from " + db.ConnectionString
// }
// })
// }
// }
//
// // Sequence it to apply Database first
// sequenced := SequenceReaderIO[Database, string](getQuery)
//
// // Partially apply the Database
// db := Database{ConnectionString: "localhost:5432"}
// ctx := context.Background()
// result := sequenced(ctx)(db)() // Executes IO and returns Right("Query result...")
//
// In point-free style, this enables clean composition:
//
// var executeQuery = F.Flow3(
// prepareQuery, // ReaderIOResult[ReaderIO[Database, QueryResult]]
// SequenceReaderIO, // func(context.Context) func(Database) IOResult[QueryResult]
// withDatabase(db), // IOResult[QueryResult]
// )
//
//go:inline
func SequenceReaderIO[R, A any](ma ReaderIOResult[RIO.ReaderIO[R, A]]) Kleisli[R, A] {
return RIOR.SequenceReaderIO(ma)
}
// SequenceReaderResult transforms a ReaderIOResult containing a ReaderResult into a function
// that takes the ReaderResult's environment first, then returns a ReaderIOResult.
//
// This is similar to SequenceReader but works with ReaderResult, which represents a computation
// that depends on an environment R and can fail with an error.
//
// Type transformation:
//
// From: ReaderIOResult[ReaderResult[R, A]]
// = func(context.Context) func() Either[error, func(R) Either[error, A]]
//
// To: func(context.Context) func(R) IOResult[A]
// = func(context.Context) func(R) func() Either[error, A]
//
// The sequencing properly combines the error handling from both the outer ReaderIOResult
// and the inner ReaderResult, ensuring that errors from either level are propagated correctly.
//
// Point-free style benefits:
// - Enables composition of error-handling computations with dependency injection
// - Allows partial application of dependencies before error handling
// - Facilitates building validation pipelines with environment dependencies
// - Supports service-oriented architectures with proper error propagation
//
// Example:
//
// type Config struct {
// MaxRetries int
// }
//
// // A computation that produces a ReaderResult based on context
// func validateRetries(ctx context.Context) func() Either[error, func(Config) Either[error, int]] {
// return func() Either[error, func(Config) Either[error, int]] {
// return Right[error](func(cfg Config) Either[error, int] {
// if cfg.MaxRetries < 0 {
// return Left[int](errors.New("negative retries"))
// }
// return Right[error](cfg.MaxRetries)
// })
// }
// }
//
// // Sequence it to apply Config first
// sequenced := SequenceReaderResult[Config, int](validateRetries)
//
// // Partially apply the Config
// cfg := Config{MaxRetries: 3}
// ctx := context.Background()
// result := sequenced(ctx)(cfg)() // Returns Right(3)
//
// // With invalid config
// badCfg := Config{MaxRetries: -1}
// badResult := sequenced(ctx)(badCfg)() // Returns Left(error("negative retries"))
//
// In point-free style, this enables validation pipelines:
//
// var validateAndProcess = F.Flow4(
// loadConfig, // ReaderIOResult[ReaderResult[Config, Settings]]
// SequenceReaderResult, // func(context.Context) func(Config) IOResult[Settings]
// applyConfig(cfg), // IOResult[Settings]
// Chain(processSettings), // IOResult[Result]
// )
//
//go:inline
func SequenceReaderResult[R, A any](ma ReaderIOResult[RR.ReaderResult[R, A]]) Kleisli[R, A] {
return RIOR.SequenceReaderEither(ma)
}
// TraverseReader transforms a ReaderIOResult computation by applying a Reader-based function,
// effectively introducing a new environment dependency.
//
// This function takes a Reader-based transformation (Kleisli arrow) and returns a function that
// can transform a ReaderIOResult. The result allows you to provide the Reader's environment (R)
// first, which then produces a ReaderIOResult that depends on the context.
//
// Type transformation:
//
// From: ReaderIOResult[A]
// = func(context.Context) func() Either[error, A]
//
// With: reader.Kleisli[R, A, B]
// = func(A) func(R) B
//
// To: func(ReaderIOResult[A]) func(R) ReaderIOResult[B]
// = func(ReaderIOResult[A]) func(R) func(context.Context) func() Either[error, B]
//
// This enables:
// 1. Transforming values within a ReaderIOResult using environment-dependent logic
// 2. Introducing new environment dependencies into existing computations
// 3. Building composable pipelines where transformations depend on configuration or dependencies
// 4. Point-free style composition with Reader-based transformations
//
// Type Parameters:
// - R: The environment type that the Reader depends on
// - A: The input value type
// - B: The output value type
//
// Parameters:
// - f: A Reader-based Kleisli arrow that transforms A to B using environment R
//
// Returns:
// - A function that takes a ReaderIOResult[A] and returns a Kleisli[R, B],
// which is func(R) ReaderIOResult[B]
//
// The function preserves error handling and IO effects while adding the Reader environment dependency.
//
// Example:
//
// type Config struct {
// Multiplier int
// }
//
// // A Reader-based transformation that depends on Config
// multiply := func(x int) func(Config) int {
// return func(cfg Config) int {
// return x * cfg.Multiplier
// }
// }
//
// // Original computation that produces an int
// computation := Right[int](10)
//
// // Apply TraverseReader to introduce Config dependency
// traversed := TraverseReader[Config, int, int](multiply)
// result := traversed(computation)
//
// // Now we can provide the Config to get the final result
// cfg := Config{Multiplier: 5}
// ctx := context.Background()
// finalResult := result(cfg)(ctx)() // Returns Right(50)
//
// In point-free style, this enables clean composition:
//
// var pipeline = F.Flow3(
// loadValue, // ReaderIOResult[int]
// TraverseReader(multiplyByConfig), // func(Config) ReaderIOResult[int]
// applyConfig(cfg), // ReaderIOResult[int]
// )
//
//go:inline
func TraverseReader[R, A, B any](
f reader.Kleisli[R, A, B],
) func(ReaderIOResult[A]) Kleisli[R, B] {
return RIOR.TraverseReader[context.Context](f)
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerioresult_test
import (
"context"
"fmt"
RIOE "github.com/IBM/fp-go/v2/context/readerioresult"
"github.com/IBM/fp-go/v2/either"
F "github.com/IBM/fp-go/v2/function"
)
// Example_sequenceReader_basicUsage demonstrates the basic usage of SequenceReader
// to flip the parameter order, enabling point-free style programming.
func Example_sequenceReader_basicUsage() {
type Config struct {
Multiplier int
}
// A computation that produces a Reader based on context
getComputation := func(ctx context.Context) func() either.Either[error, func(Config) int] {
return func() either.Either[error, func(Config) int] {
// This could check context for cancellation, deadlines, etc.
return either.Right[error](func(cfg Config) int {
return cfg.Multiplier * 10
})
}
}
// Sequence it to flip the parameter order
// Now Config comes first, then context
sequenced := RIOE.SequenceReader(getComputation)
// Partially apply the Config - this is the key benefit for point-free style
cfg := Config{Multiplier: 5}
withConfig := sequenced(cfg)
// Now we have a ReaderIOResult[int] that can be used with any context
ctx := context.Background()
result := withConfig(ctx)()
if value, err := either.Unwrap(result); err == nil {
fmt.Println(value)
}
// Output: 50
}
// Example_sequenceReader_dependencyInjection demonstrates how SequenceReader
// enables clean dependency injection patterns in point-free style.
func Example_sequenceReader_dependencyInjection() {
// Define our dependencies
type Database struct {
ConnectionString string
}
type UserService struct {
db Database
}
// A function that creates a computation requiring a Database
makeQuery := func(ctx context.Context) func() either.Either[error, func(Database) string] {
return func() either.Either[error, func(Database) string] {
return either.Right[error](func(db Database) string {
return fmt.Sprintf("Querying %s", db.ConnectionString)
})
}
}
// Sequence to enable dependency injection
queryWithDB := RIOE.SequenceReader(makeQuery)
// Inject the database dependency
db := Database{ConnectionString: "localhost:5432"}
query := queryWithDB(db)
// Execute with context
ctx := context.Background()
result := query(ctx)()
if value, err := either.Unwrap(result); err == nil {
fmt.Println(value)
}
// Output: Querying localhost:5432
}
// Example_sequenceReader_pointFreeComposition demonstrates how SequenceReader
// enables point-free style composition of computations.
func Example_sequenceReader_pointFreeComposition() {
type Config struct {
BaseValue int
}
// Step 1: Create a computation that produces a Reader
step1 := func(ctx context.Context) func() either.Either[error, func(Config) int] {
return func() either.Either[error, func(Config) int] {
return either.Right[error](func(cfg Config) int {
return cfg.BaseValue * 2
})
}
}
// Step 2: Sequence it to enable partial application
sequenced := RIOE.SequenceReader(step1)
// Step 3: Build a pipeline using point-free style
// Partially apply the config
cfg := Config{BaseValue: 10}
// Create a reusable computation with the config baked in
computation := F.Pipe1(
sequenced(cfg),
RIOE.Map(func(x int) int { return x + 5 }),
)
// Execute the pipeline
ctx := context.Background()
result := computation(ctx)()
if value, err := either.Unwrap(result); err == nil {
fmt.Println(value)
}
// Output: 25
}
// Example_sequenceReader_multipleEnvironments demonstrates using SequenceReader
// to work with multiple environment types in a clean, composable way.
func Example_sequenceReader_multipleEnvironments() {
type DatabaseConfig struct {
Host string
Port int
}
type APIConfig struct {
Endpoint string
APIKey string
}
// Function that needs DatabaseConfig
getDatabaseURL := func(ctx context.Context) func() either.Either[error, func(DatabaseConfig) string] {
return func() either.Either[error, func(DatabaseConfig) string] {
return either.Right[error](func(cfg DatabaseConfig) string {
return fmt.Sprintf("%s:%d", cfg.Host, cfg.Port)
})
}
}
// Function that needs APIConfig
getAPIURL := func(ctx context.Context) func() either.Either[error, func(APIConfig) string] {
return func() either.Either[error, func(APIConfig) string] {
return either.Right[error](func(cfg APIConfig) string {
return cfg.Endpoint
})
}
}
// Sequence both to enable partial application
withDBConfig := RIOE.SequenceReader(getDatabaseURL)
withAPIConfig := RIOE.SequenceReader(getAPIURL)
// Partially apply different configs
dbCfg := DatabaseConfig{Host: "localhost", Port: 5432}
apiCfg := APIConfig{Endpoint: "https://api.example.com", APIKey: "secret"}
dbQuery := withDBConfig(dbCfg)
apiQuery := withAPIConfig(apiCfg)
// Execute both with the same context
ctx := context.Background()
dbResult := dbQuery(ctx)()
apiResult := apiQuery(ctx)()
if dbURL, err := either.Unwrap(dbResult); err == nil {
fmt.Println("Database:", dbURL)
}
if apiURL, err := either.Unwrap(apiResult); err == nil {
fmt.Println("API:", apiURL)
}
// Output:
// Database: localhost:5432
// API: https://api.example.com
}
// Example_sequenceReaderResult_errorHandling demonstrates how SequenceReaderResult
// enables point-free style with proper error handling at multiple levels.
func Example_sequenceReaderResult_errorHandling() {
type ValidationConfig struct {
MinValue int
MaxValue int
}
// A computation that can fail at both outer and inner levels
makeValidator := func(ctx context.Context) func() either.Either[error, func(context.Context) either.Either[error, int]] {
return func() either.Either[error, func(context.Context) either.Either[error, int]] {
// Outer level: check context
if ctx.Err() != nil {
return either.Left[func(context.Context) either.Either[error, int]](ctx.Err())
}
// Return inner computation
return either.Right[error](func(innerCtx context.Context) either.Either[error, int] {
// Inner level: perform validation
value := 42
if value < 0 {
return either.Left[int](fmt.Errorf("value too small: %d", value))
}
if value > 100 {
return either.Left[int](fmt.Errorf("value too large: %d", value))
}
return either.Right[error](value)
})
}
}
// Sequence to enable point-free composition
sequenced := RIOE.SequenceReaderResult(makeValidator)
// Build a pipeline with error handling
ctx := context.Background()
pipeline := F.Pipe2(
sequenced(ctx),
RIOE.Map(func(x int) int { return x * 2 }),
RIOE.Chain(func(x int) RIOE.ReaderIOResult[string] {
return RIOE.Of(fmt.Sprintf("Result: %d", x))
}),
)
result := pipeline(ctx)()
if value, err := either.Unwrap(result); err == nil {
fmt.Println(value)
}
// Output: Result: 84
}
// Example_sequenceReader_partialApplication demonstrates the power of partial
// application enabled by SequenceReader for building reusable computations.
func Example_sequenceReader_partialApplication() {
type ServiceConfig struct {
ServiceName string
Version string
}
// Create a computation factory
makeServiceInfo := func(ctx context.Context) func() either.Either[error, func(ServiceConfig) string] {
return func() either.Either[error, func(ServiceConfig) string] {
return either.Right[error](func(cfg ServiceConfig) string {
return fmt.Sprintf("%s v%s", cfg.ServiceName, cfg.Version)
})
}
}
// Sequence it
sequenced := RIOE.SequenceReader(makeServiceInfo)
// Create multiple service configurations
authConfig := ServiceConfig{ServiceName: "AuthService", Version: "1.0.0"}
userConfig := ServiceConfig{ServiceName: "UserService", Version: "2.1.0"}
// Partially apply each config to create specialized computations
getAuthInfo := sequenced(authConfig)
getUserInfo := sequenced(userConfig)
// These can now be reused across different contexts
ctx := context.Background()
authResult := getAuthInfo(ctx)()
userResult := getUserInfo(ctx)()
if auth, err := either.Unwrap(authResult); err == nil {
fmt.Println(auth)
}
if user, err := either.Unwrap(userResult); err == nil {
fmt.Println(user)
}
// Output:
// AuthService v1.0.0
// UserService v2.1.0
}
// Example_sequenceReader_testingBenefits demonstrates how SequenceReader
// makes testing easier by allowing you to inject test dependencies.
func Example_sequenceReader_testingBenefits() {
// Simple logger that collects messages
type SimpleLogger struct {
Messages []string
}
// A computation that depends on a logger (using the struct directly)
makeLoggingOperation := func(ctx context.Context) func() either.Either[error, func(*SimpleLogger) string] {
return func() either.Either[error, func(*SimpleLogger) string] {
return either.Right[error](func(logger *SimpleLogger) string {
logger.Messages = append(logger.Messages, "Operation started")
result := "Success"
logger.Messages = append(logger.Messages, fmt.Sprintf("Operation completed: %s", result))
return result
})
}
}
// Sequence to enable dependency injection
sequenced := RIOE.SequenceReader(makeLoggingOperation)
// Inject a test logger
testLogger := &SimpleLogger{Messages: []string{}}
operation := sequenced(testLogger)
// Execute
ctx := context.Background()
result := operation(ctx)()
if value, err := either.Unwrap(result); err == nil {
fmt.Println("Result:", value)
fmt.Println("Logs:", len(testLogger.Messages))
}
// Output:
// Result: Success
// Logs: 2
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerioresult
import (
"context"
"errors"
"fmt"
"testing"
"github.com/IBM/fp-go/v2/either"
"github.com/stretchr/testify/assert"
)
func TestSequenceReader(t *testing.T) {
t.Run("flips parameter order for simple types", func(t *testing.T) {
// Original: ReaderIOResult[Reader[string, int]]
// = func(context.Context) func() Either[error, func(string) int]
original := func(ctx context.Context) func() Either[Reader[string, int]] {
return func() Either[Reader[string, int]] {
return either.Right[error](func(s string) int {
return 10 + len(s)
})
}
}
// Sequenced: func(string) func(context.Context) IOResult[int]
// The Reader environment (string) is now the first parameter
sequenced := SequenceReader(original)
ctx := context.Background()
// Test original
result1 := original(ctx)()
assert.True(t, either.IsRight(result1))
innerFunc1, _ := either.Unwrap(result1)
value1 := innerFunc1("hello")
assert.Equal(t, 15, value1)
// Test sequenced - note the flipped order: string first, then context
result2 := sequenced("hello")(ctx)()
assert.True(t, either.IsRight(result2))
value2, _ := either.Unwrap(result2)
assert.Equal(t, 15, value2)
})
t.Run("flips parameter order for struct types", func(t *testing.T) {
type Database struct {
ConnectionString string
}
// Original: ReaderIOResult[Reader[Database, string]]
query := func(ctx context.Context) func() Either[Reader[Database, string]] {
return func() Either[Reader[Database, string]] {
if ctx.Err() != nil {
return either.Left[Reader[Database, string]](ctx.Err())
}
return either.Right[error](func(db Database) string {
return fmt.Sprintf("Query on %s", db.ConnectionString)
})
}
}
db := Database{ConnectionString: "localhost:5432"}
ctx := context.Background()
expected := "Query on localhost:5432"
// Sequence it
sequenced := SequenceReader(query)
// Test original with valid inputs
result1 := query(ctx)()
assert.True(t, either.IsRight(result1))
innerFunc1, _ := either.Unwrap(result1)
value1 := innerFunc1(db)
assert.Equal(t, expected, value1)
// Test sequenced with valid inputs - Database first, then context
result2 := sequenced(db)(ctx)()
assert.True(t, either.IsRight(result2))
value2, _ := either.Unwrap(result2)
assert.Equal(t, expected, value2)
})
t.Run("preserves outer error", func(t *testing.T) {
expectedError := errors.New("outer error")
// Original that fails at outer level
original := func(ctx context.Context) func() Either[Reader[string, int]] {
return func() Either[Reader[string, int]] {
return either.Left[Reader[string, int]](expectedError)
}
}
ctx := context.Background()
// Test original with error
result1 := original(ctx)()
assert.True(t, either.IsLeft(result1))
_, err1 := either.Unwrap(result1)
assert.Equal(t, expectedError, err1)
// Test sequenced - the outer error is preserved
sequenced := SequenceReader(original)
result2 := sequenced("test")(ctx)()
assert.True(t, either.IsLeft(result2))
_, err2 := either.Unwrap(result2)
assert.Equal(t, expectedError, err2)
})
t.Run("preserves computation logic", func(t *testing.T) {
// Original function
original := func(ctx context.Context) func() Either[Reader[string, int]] {
return func() Either[Reader[string, int]] {
return either.Right[error](func(s string) int {
return 3 * len(s)
})
}
}
ctx := context.Background()
// Sequence
sequenced := SequenceReader(original)
// Test that sequence produces correct results
result1 := original(ctx)()
innerFunc1, _ := either.Unwrap(result1)
value1 := innerFunc1("test")
result2 := sequenced("test")(ctx)()
value2, _ := either.Unwrap(result2)
assert.Equal(t, value1, value2)
assert.Equal(t, 12, value2) // 3 * 4
})
t.Run("works with zero values", func(t *testing.T) {
original := func(ctx context.Context) func() Either[Reader[string, int]] {
return func() Either[Reader[string, int]] {
return either.Right[error](func(s string) int {
return len(s)
})
}
}
ctx := context.Background()
sequenced := SequenceReader(original)
// Test with zero values
result1 := original(ctx)()
innerFunc1, _ := either.Unwrap(result1)
value1 := innerFunc1("")
assert.Equal(t, 0, value1)
result2 := sequenced("")(ctx)()
value2, _ := either.Unwrap(result2)
assert.Equal(t, 0, value2)
})
t.Run("respects context cancellation", func(t *testing.T) {
original := func(ctx context.Context) func() Either[Reader[string, int]] {
return func() Either[Reader[string, int]] {
if ctx.Err() != nil {
return either.Left[Reader[string, int]](ctx.Err())
}
return either.Right[error](func(s string) int {
return len(s)
})
}
}
ctx, cancel := context.WithCancel(context.Background())
cancel()
sequenced := SequenceReader(original)
result := sequenced("test")(ctx)()
assert.True(t, either.IsLeft(result))
_, err := either.Unwrap(result)
assert.Equal(t, context.Canceled, err)
})
t.Run("enables point-free style with partial application", func(t *testing.T) {
type Config struct {
Multiplier int
}
// Original computation
original := func(ctx context.Context) func() Either[Reader[Config, int]] {
return func() Either[Reader[Config, int]] {
return either.Right[error](func(cfg Config) int {
return cfg.Multiplier * 10
})
}
}
// Sequence to enable partial application
sequenced := SequenceReader(original)
// Partially apply the Config
cfg := Config{Multiplier: 5}
withConfig := sequenced(cfg)
// Now we have a ReaderIOResult[int] that can be used in different contexts
ctx1 := context.Background()
result1 := withConfig(ctx1)()
assert.True(t, either.IsRight(result1))
value1, _ := either.Unwrap(result1)
assert.Equal(t, 50, value1)
// Can reuse with different context
ctx2 := context.Background()
result2 := withConfig(ctx2)()
assert.True(t, either.IsRight(result2))
value2, _ := either.Unwrap(result2)
assert.Equal(t, 50, value2)
})
}
func TestSequenceReaderIO(t *testing.T) {
t.Run("flips parameter order for simple types", func(t *testing.T) {
// Original: ReaderIOResult[ReaderIO[int]]
// = func(context.Context) func() Either[error, func(context.Context) func() int]
original := func(ctx context.Context) func() Either[ReaderIO[int]] {
return func() Either[ReaderIO[int]] {
return either.Right[error](func(innerCtx context.Context) func() int {
return func() int {
return 20
}
})
}
}
ctx := context.Background()
sequenced := SequenceReaderIO(original)
// Test original
result1 := original(ctx)()
assert.True(t, either.IsRight(result1))
innerFunc1, _ := either.Unwrap(result1)
value1 := innerFunc1(ctx)()
assert.Equal(t, 20, value1)
// Test sequenced - context first, then context again for inner ReaderIO
result2 := sequenced(ctx)(ctx)()
assert.True(t, either.IsRight(result2))
value2, _ := either.Unwrap(result2)
assert.Equal(t, 20, value2)
})
t.Run("preserves outer error", func(t *testing.T) {
expectedError := errors.New("outer error")
// Original that fails at outer level
original := func(ctx context.Context) func() Either[ReaderIO[int]] {
return func() Either[ReaderIO[int]] {
return either.Left[ReaderIO[int]](expectedError)
}
}
ctx := context.Background()
// Test original with error
result1 := original(ctx)()
assert.True(t, either.IsLeft(result1))
_, err1 := either.Unwrap(result1)
assert.Equal(t, expectedError, err1)
// Test sequenced - the outer error is preserved
sequenced := SequenceReaderIO(original)
result2 := sequenced(ctx)(ctx)()
assert.True(t, either.IsLeft(result2))
_, err2 := either.Unwrap(result2)
assert.Equal(t, expectedError, err2)
})
t.Run("respects context cancellation in outer context", func(t *testing.T) {
original := func(ctx context.Context) func() Either[ReaderIO[int]] {
return func() Either[ReaderIO[int]] {
if ctx.Err() != nil {
return either.Left[ReaderIO[int]](ctx.Err())
}
return either.Right[error](func(innerCtx context.Context) func() int {
return func() int {
return 20
}
})
}
}
ctx, cancel := context.WithCancel(context.Background())
cancel()
sequenced := SequenceReaderIO(original)
result := sequenced(ctx)(ctx)()
assert.True(t, either.IsLeft(result))
_, err := either.Unwrap(result)
assert.Equal(t, context.Canceled, err)
})
}
func TestSequenceReaderResult(t *testing.T) {
t.Run("flips parameter order for simple types", func(t *testing.T) {
// Original: ReaderIOResult[ReaderResult[int]]
// = func(context.Context) func() Either[error, func(context.Context) Either[error, int]]
original := func(ctx context.Context) func() Either[ReaderResult[int]] {
return func() Either[ReaderResult[int]] {
return either.Right[error](func(innerCtx context.Context) Either[int] {
return either.Right[error](20)
})
}
}
ctx := context.Background()
sequenced := SequenceReaderResult(original)
// Test original
result1 := original(ctx)()
assert.True(t, either.IsRight(result1))
innerFunc1, _ := either.Unwrap(result1)
innerResult1 := innerFunc1(ctx)
assert.True(t, either.IsRight(innerResult1))
value1, _ := either.Unwrap(innerResult1)
assert.Equal(t, 20, value1)
// Test sequenced
result2 := sequenced(ctx)(ctx)()
assert.True(t, either.IsRight(result2))
value2, _ := either.Unwrap(result2)
assert.Equal(t, 20, value2)
})
t.Run("preserves outer error", func(t *testing.T) {
expectedError := errors.New("outer error")
// Original that fails at outer level
original := func(ctx context.Context) func() Either[ReaderResult[int]] {
return func() Either[ReaderResult[int]] {
return either.Left[ReaderResult[int]](expectedError)
}
}
ctx := context.Background()
// Test original with error
result1 := original(ctx)()
assert.True(t, either.IsLeft(result1))
_, err1 := either.Unwrap(result1)
assert.Equal(t, expectedError, err1)
// Test sequenced - the outer error is preserved
sequenced := SequenceReaderResult(original)
result2 := sequenced(ctx)(ctx)()
assert.True(t, either.IsLeft(result2))
_, err2 := either.Unwrap(result2)
assert.Equal(t, expectedError, err2)
})
t.Run("preserves inner error", func(t *testing.T) {
expectedError := errors.New("inner error")
// Original that fails at inner level
original := func(ctx context.Context) func() Either[ReaderResult[int]] {
return func() Either[ReaderResult[int]] {
return either.Right[error](func(innerCtx context.Context) Either[int] {
return either.Left[int](expectedError)
})
}
}
ctx := context.Background()
// Test original with inner error
result1 := original(ctx)()
assert.True(t, either.IsRight(result1))
innerFunc1, _ := either.Unwrap(result1)
innerResult1 := innerFunc1(ctx)
assert.True(t, either.IsLeft(innerResult1))
_, innerErr1 := either.Unwrap(innerResult1)
assert.Equal(t, expectedError, innerErr1)
// Test sequenced with inner error
sequenced := SequenceReaderResult(original)
result2 := sequenced(ctx)(ctx)()
assert.True(t, either.IsLeft(result2))
_, innerErr2 := either.Unwrap(result2)
assert.Equal(t, expectedError, innerErr2)
})
t.Run("handles errors at different levels", func(t *testing.T) {
// Original that can fail at both levels
makeOriginal := func(x int) ReaderIOResult[ReaderResult[int]] {
return func(ctx context.Context) func() Either[ReaderResult[int]] {
return func() Either[ReaderResult[int]] {
if x < -10 {
return either.Left[ReaderResult[int]](errors.New("outer: too negative"))
}
return either.Right[error](func(innerCtx context.Context) Either[int] {
if x < 0 {
return either.Left[int](errors.New("inner: negative value"))
}
return either.Right[error](x * 2)
})
}
}
}
ctx := context.Background()
// Test outer error
sequenced1 := SequenceReaderResult(makeOriginal(-20))
result1 := sequenced1(ctx)(ctx)()
assert.True(t, either.IsLeft(result1))
_, err1 := either.Unwrap(result1)
assert.Contains(t, err1.Error(), "outer")
// Test inner error
sequenced2 := SequenceReaderResult(makeOriginal(-5))
result2 := sequenced2(ctx)(ctx)()
assert.True(t, either.IsLeft(result2))
_, err2 := either.Unwrap(result2)
assert.Contains(t, err2.Error(), "inner")
// Test success
sequenced3 := SequenceReaderResult(makeOriginal(10))
result3 := sequenced3(ctx)(ctx)()
assert.True(t, either.IsRight(result3))
value3, _ := either.Unwrap(result3)
assert.Equal(t, 20, value3)
})
t.Run("respects context cancellation", func(t *testing.T) {
original := func(ctx context.Context) func() Either[ReaderResult[int]] {
return func() Either[ReaderResult[int]] {
if ctx.Err() != nil {
return either.Left[ReaderResult[int]](ctx.Err())
}
return either.Right[error](func(innerCtx context.Context) Either[int] {
if innerCtx.Err() != nil {
return either.Left[int](innerCtx.Err())
}
return either.Right[error](20)
})
}
}
ctx, cancel := context.WithCancel(context.Background())
cancel()
sequenced := SequenceReaderResult(original)
result := sequenced(ctx)(ctx)()
assert.True(t, either.IsLeft(result))
_, err := either.Unwrap(result)
assert.Equal(t, context.Canceled, err)
})
}
func TestSequenceEdgeCases(t *testing.T) {
t.Run("works with empty struct", func(t *testing.T) {
type Empty struct{}
original := func(ctx context.Context) func() Either[Reader[Empty, int]] {
return func() Either[Reader[Empty, int]] {
return either.Right[error](func(e Empty) int {
return 20
})
}
}
ctx := context.Background()
empty := Empty{}
sequenced := SequenceReader(original)
result1 := original(ctx)()
innerFunc1, _ := either.Unwrap(result1)
value1 := innerFunc1(empty)
assert.Equal(t, 20, value1)
result2 := sequenced(empty)(ctx)()
value2, _ := either.Unwrap(result2)
assert.Equal(t, 20, value2)
})
t.Run("works with pointer types", func(t *testing.T) {
type Data struct {
Value int
}
original := func(ctx context.Context) func() Either[Reader[*Data, int]] {
return func() Either[Reader[*Data, int]] {
return either.Right[error](func(d *Data) int {
if d == nil {
return 42
}
return 42 + d.Value
})
}
}
ctx := context.Background()
data := &Data{Value: 100}
sequenced := SequenceReader(original)
// Test with non-nil pointer
result1 := original(ctx)()
innerFunc1, _ := either.Unwrap(result1)
value1 := innerFunc1(data)
assert.Equal(t, 142, value1)
result2 := sequenced(data)(ctx)()
value2, _ := either.Unwrap(result2)
assert.Equal(t, 142, value2)
// Test with nil pointer
result3 := sequenced(nil)(ctx)()
value3, _ := either.Unwrap(result3)
assert.Equal(t, 42, value3)
})
t.Run("maintains referential transparency", func(t *testing.T) {
// The same inputs should always produce the same outputs
original := func(ctx context.Context) func() Either[Reader[string, int]] {
return func() Either[Reader[string, int]] {
return either.Right[error](func(s string) int {
return 10 + len(s)
})
}
}
ctx := context.Background()
sequenced := SequenceReader(original)
// Call multiple times with same inputs
for range 5 {
result1 := original(ctx)()
innerFunc1, _ := either.Unwrap(result1)
value1 := innerFunc1("hello")
assert.Equal(t, 15, value1)
result2 := sequenced("hello")(ctx)()
value2, _ := either.Unwrap(result2)
assert.Equal(t, 15, value2)
}
})
}
func TestTraverseReader(t *testing.T) {
t.Run("basic transformation with Reader dependency", func(t *testing.T) {
type Config struct {
Multiplier int
}
// Original computation
original := Right(10)
// Reader-based transformation
multiply := func(x int) Reader[Config, int] {
return func(cfg Config) int {
return x * cfg.Multiplier
}
}
// Apply TraverseReader
traversed := TraverseReader(multiply)
result := traversed(original)
// Provide Config and execute
cfg := Config{Multiplier: 5}
ctx := context.Background()
finalResult := result(cfg)(ctx)()
assert.True(t, either.IsRight(finalResult))
value, _ := either.Unwrap(finalResult)
assert.Equal(t, 50, value)
})
t.Run("preserves outer error", func(t *testing.T) {
type Config struct {
Multiplier int
}
expectedError := errors.New("computation failed")
// Original computation that fails
original := Left[int](expectedError)
// Reader-based transformation (won't be called)
multiply := func(x int) Reader[Config, int] {
return func(cfg Config) int {
return x * cfg.Multiplier
}
}
// Apply TraverseReader
traversed := TraverseReader(multiply)
result := traversed(original)
// Provide Config and execute
cfg := Config{Multiplier: 5}
ctx := context.Background()
finalResult := result(cfg)(ctx)()
assert.True(t, either.IsLeft(finalResult))
_, err := either.Unwrap(finalResult)
assert.Equal(t, expectedError, err)
})
t.Run("works with different types", func(t *testing.T) {
type Database struct {
Prefix string
}
// Original computation producing an int
original := Right(42)
// Reader-based transformation: int -> string using Database
format := func(x int) func(Database) string {
return func(db Database) string {
return fmt.Sprintf("%s:%d", db.Prefix, x)
}
}
// Apply TraverseReader
traversed := TraverseReader(format)
result := traversed(original)
// Provide Database and execute
db := Database{Prefix: "ID"}
ctx := context.Background()
finalResult := result(db)(ctx)()
assert.True(t, either.IsRight(finalResult))
value, _ := either.Unwrap(finalResult)
assert.Equal(t, "ID:42", value)
})
t.Run("works with struct environments", func(t *testing.T) {
type Settings struct {
Prefix string
Suffix string
}
// Original computation
original := Right("value")
// Reader-based transformation using Settings
decorate := func(s string) func(Settings) string {
return func(settings Settings) string {
return settings.Prefix + s + settings.Suffix
}
}
// Apply TraverseReader
traversed := TraverseReader(decorate)
result := traversed(original)
// Provide Settings and execute
settings := Settings{Prefix: "[", Suffix: "]"}
ctx := context.Background()
finalResult := result(settings)(ctx)()
assert.True(t, either.IsRight(finalResult))
value, _ := either.Unwrap(finalResult)
assert.Equal(t, "[value]", value)
})
t.Run("enables partial application", func(t *testing.T) {
type Config struct {
Factor int
}
// Original computation
original := Right(10)
// Reader-based transformation
scale := func(x int) Reader[Config, int] {
return func(cfg Config) int {
return x * cfg.Factor
}
}
// Apply TraverseReader
traversed := TraverseReader(scale)
result := traversed(original)
// Partially apply Config
cfg := Config{Factor: 3}
withConfig := result(cfg)
// Can now use with different contexts
ctx1 := context.Background()
finalResult1 := withConfig(ctx1)()
assert.True(t, either.IsRight(finalResult1))
value1, _ := either.Unwrap(finalResult1)
assert.Equal(t, 30, value1)
// Reuse with different context
ctx2 := context.Background()
finalResult2 := withConfig(ctx2)()
assert.True(t, either.IsRight(finalResult2))
value2, _ := either.Unwrap(finalResult2)
assert.Equal(t, 30, value2)
})
t.Run("respects context cancellation", func(t *testing.T) {
type Config struct {
Value int
}
// Original computation that checks context
original := func(ctx context.Context) func() Either[int] {
return func() Either[int] {
if ctx.Err() != nil {
return either.Left[int](ctx.Err())
}
return either.Right[error](10)
}
}
// Reader-based transformation
multiply := func(x int) Reader[Config, int] {
return func(cfg Config) int {
return x * cfg.Value
}
}
// Apply TraverseReader
traversed := TraverseReader(multiply)
result := traversed(original)
// Use canceled context
ctx, cancel := context.WithCancel(context.Background())
cancel()
cfg := Config{Value: 5}
finalResult := result(cfg)(ctx)()
assert.True(t, either.IsLeft(finalResult))
_, err := either.Unwrap(finalResult)
assert.Equal(t, context.Canceled, err)
})
t.Run("works with zero values", func(t *testing.T) {
type Config struct {
Offset int
}
// Original computation with zero value
original := Right(0)
// Reader-based transformation
add := func(x int) Reader[Config, int] {
return func(cfg Config) int {
return x + cfg.Offset
}
}
// Apply TraverseReader
traversed := TraverseReader(add)
result := traversed(original)
// Provide Config with zero offset
cfg := Config{Offset: 0}
ctx := context.Background()
finalResult := result(cfg)(ctx)()
assert.True(t, either.IsRight(finalResult))
value, _ := either.Unwrap(finalResult)
assert.Equal(t, 0, value)
})
t.Run("chains multiple transformations", func(t *testing.T) {
type Config struct {
Multiplier int
}
// Original computation
original := Right(5)
// First Reader-based transformation
multiply := func(x int) Reader[Config, int] {
return func(cfg Config) int {
return x * cfg.Multiplier
}
}
// Apply TraverseReader
traversed := TraverseReader(multiply)
result := traversed(original)
// Provide Config and execute
cfg := Config{Multiplier: 4}
ctx := context.Background()
finalResult := result(cfg)(ctx)()
assert.True(t, either.IsRight(finalResult))
value, _ := either.Unwrap(finalResult)
assert.Equal(t, 20, value) // 5 * 4 = 20
})
t.Run("works with complex Reader logic", func(t *testing.T) {
type ValidationRules struct {
MinValue int
MaxValue int
}
// Original computation
original := Right(50)
// Reader-based transformation with validation logic
validate := func(x int) func(ValidationRules) int {
return func(rules ValidationRules) int {
if x < rules.MinValue {
return rules.MinValue
}
if x > rules.MaxValue {
return rules.MaxValue
}
return x
}
}
// Apply TraverseReader
traversed := TraverseReader(validate)
result := traversed(original)
// Test with value within range
rules1 := ValidationRules{MinValue: 0, MaxValue: 100}
ctx := context.Background()
finalResult1 := result(rules1)(ctx)()
assert.True(t, either.IsRight(finalResult1))
value1, _ := either.Unwrap(finalResult1)
assert.Equal(t, 50, value1)
// Test with value above max
rules2 := ValidationRules{MinValue: 0, MaxValue: 30}
finalResult2 := result(rules2)(ctx)()
assert.True(t, either.IsRight(finalResult2))
value2, _ := either.Unwrap(finalResult2)
assert.Equal(t, 30, value2) // Clamped to max
// Test with value below min
rules3 := ValidationRules{MinValue: 60, MaxValue: 100}
finalResult3 := result(rules3)(ctx)()
assert.True(t, either.IsRight(finalResult3))
value3, _ := either.Unwrap(finalResult3)
assert.Equal(t, 60, value3) // Clamped to min
})
}

14
v2/context/readerioresult/http/request.go
View File

@@ -73,7 +73,7 @@ type (
// It wraps a standard http.Client and provides functional HTTP operations.
client struct {
delegate *http.Client
doIOE func(*http.Request) IOE.IOEither[error, *http.Response]
doIOE IOE.Kleisli[error, *http.Request, *http.Response]
}
)
@@ -158,7 +158,7 @@ func MakeClient(httpClient *http.Client) Client {
// request := MakeGetRequest("https://api.example.com/data")
// fullResp := ReadFullResponse(client)(request)
// result := fullResp(context.Background())()
func ReadFullResponse(client Client) func(Requester) RIOE.ReaderIOResult[H.FullResponse] {
func ReadFullResponse(client Client) RIOE.Kleisli[Requester, H.FullResponse] {
return func(req Requester) RIOE.ReaderIOResult[H.FullResponse] {
return F.Flow3(
client.Do(req),
@@ -195,7 +195,7 @@ func ReadFullResponse(client Client) func(Requester) RIOE.ReaderIOResult[H.FullR
// request := MakeGetRequest("https://api.example.com/data")
// readBytes := ReadAll(client)
// result := readBytes(request)(context.Background())()
func ReadAll(client Client) func(Requester) RIOE.ReaderIOResult[[]byte] {
func ReadAll(client Client) RIOE.Kleisli[Requester, []byte] {
return F.Flow2(
ReadFullResponse(client),
RIOE.Map(H.Body),
@@ -219,7 +219,7 @@ func ReadAll(client Client) func(Requester) RIOE.ReaderIOResult[[]byte] {
// request := MakeGetRequest("https://api.example.com/text")
// readText := ReadText(client)
// result := readText(request)(context.Background())()
func ReadText(client Client) func(Requester) RIOE.ReaderIOResult[string] {
func ReadText(client Client) RIOE.Kleisli[Requester, string] {
return F.Flow2(
ReadAll(client),
RIOE.Map(B.ToString),
@@ -231,7 +231,7 @@ func ReadText(client Client) func(Requester) RIOE.ReaderIOResult[string] {
// Deprecated: Use [ReadJSON] instead. This function is kept for backward compatibility
// but will be removed in a future version. The capitalized version follows Go naming
// conventions for acronyms.
func ReadJson[A any](client Client) func(Requester) RIOE.ReaderIOResult[A] {
func ReadJson[A any](client Client) RIOE.Kleisli[Requester, A] {
return ReadJSON[A](client)
}
@@ -242,7 +242,7 @@ func ReadJson[A any](client Client) func(Requester) RIOE.ReaderIOResult[A] {
// 3. Reads the response body as bytes
//
// This function is used internally by ReadJSON to ensure proper JSON response handling.
func readJSON(client Client) func(Requester) RIOE.ReaderIOResult[[]byte] {
func readJSON(client Client) RIOE.Kleisli[Requester, []byte] {
return F.Flow3(
ReadFullResponse(client),
RIOE.ChainFirstEitherK(F.Flow2(
@@ -278,7 +278,7 @@ func readJSON(client Client) func(Requester) RIOE.ReaderIOResult[[]byte] {
// request := MakeGetRequest("https://api.example.com/user/1")
// readUser := ReadJSON[User](client)
// result := readUser(request)(context.Background())()
func ReadJSON[A any](client Client) func(Requester) RIOE.ReaderIOResult[A] {
func ReadJSON[A any](client Client) RIOE.Kleisli[Requester, A] {
return F.Flow2(
readJSON(client),
RIOE.ChainEitherK(J.Unmarshal[A]),

732
v2/context/readerioresult/logging.go Normal file
View File

@@ -0,0 +1,732 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package readerioresult provides logging utilities for ReaderIOResult computations.
// It includes functions for entry/exit logging with timing, correlation IDs, and context management.
package readerioresult
import (
"context"
"log/slog"
"sync/atomic"
"time"
"github.com/IBM/fp-go/v2/context/readerio"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/io"
"github.com/IBM/fp-go/v2/logging"
"github.com/IBM/fp-go/v2/option"
"github.com/IBM/fp-go/v2/reader"
"github.com/IBM/fp-go/v2/result"
)
type (
// loggingContextKeyType is the type used as a key for storing logging information in context.Context
loggingContextKeyType int
// LoggingID is a unique identifier assigned to each logged operation for correlation
LoggingID uint64
// loggingContext holds the logging state for a computation, including timing,
// correlation ID, logger instance, and whether logging is enabled.
loggingContext struct {
contextID LoggingID // Unique identifier for this logged operation
startTime time.Time // When the operation started (for duration calculation)
logger *slog.Logger // The logger instance to use for this operation
isEnabled bool // Whether logging is enabled for this operation
}
)
var (
// loggingContextKey is the singleton key used to store/retrieve logging data from context
loggingContextKey loggingContextKeyType
// loggingCounter is an atomic counter that generates unique LoggingIDs
loggingCounter atomic.Uint64
loggingContextValue = F.Bind2nd(context.Context.Value, any(loggingContextKey))
withLoggingContextValue = F.Bind2of3(context.WithValue)(any(loggingContextKey))
// getLoggingContext retrieves the logging information (start time and ID) from the context.
// It returns a Pair containing the start time and the logging ID.
// This function assumes the context contains logging information; it will panic if not present.
getLoggingContext = F.Flow3(
loggingContextValue,
option.ToType[loggingContext],
option.GetOrElse(getDefaultLoggingContext),
)
)
// getDefaultLoggingContext returns a default logging context with the global logger.
// This is used when no logging context is found in the context.Context.
func getDefaultLoggingContext() loggingContext {
return loggingContext{
logger: logging.GetLogger(),
}
}
// withLoggingContext creates an endomorphism that adds a logging context to a context.Context.
// This is used internally to store logging state in the context for retrieval by nested operations.
//
// Parameters:
// - lctx: The logging context to store
//
// Returns:
// - An endomorphism that adds the logging context to a context.Context
func withLoggingContext(lctx loggingContext) Endomorphism[context.Context] {
return F.Bind2nd(withLoggingContextValue, any(lctx))
}
// LogEntryExitF creates a customizable operator that wraps a ReaderIOResult computation with entry/exit callbacks.
//
// This is a more flexible version of LogEntryExit that allows you to provide custom callbacks for
// entry and exit events. The onEntry callback receives the current context and can return a modified
// context (e.g., with additional logging information). The onExit callback receives the computation
// result and can perform custom logging, metrics collection, or cleanup.
//
// The function uses the bracket pattern to ensure that:
// - The onEntry callback is executed before the computation starts
// - The computation runs with the context returned by onEntry
// - The onExit callback is executed after the computation completes (success or failure)
// - The original result is preserved and returned unchanged
// - Cleanup happens even if the computation fails
//
// Type Parameters:
// - A: The success type of the ReaderIOResult
// - ANY: The return type of the onExit callback (typically any)
//
// Parameters:
// - onEntry: A ReaderIO that receives the current context and returns a (possibly modified) context.
// This is executed before the computation starts. Use this for logging entry, adding context values,
// starting timers, or initialization logic.
// - onExit: A Kleisli function that receives the Result[A] and returns a ReaderIO[ANY].
// This is executed after the computation completes, regardless of success or failure.
// Use this for logging exit, recording metrics, cleanup, or finalization logic.
//
// Returns:
// - An Operator that wraps the ReaderIOResult computation with the custom entry/exit callbacks
//
// Example with custom context modification:
//
// type RequestID string
//
// logOp := LogEntryExitF[User, any](
// func(ctx context.Context) IO[context.Context] {
// return func() context.Context {
// reqID := RequestID(uuid.New().String())
// log.Printf("[%s] Starting operation", reqID)
// return context.WithValue(ctx, "requestID", reqID)
// }
// },
// func(res Result[User]) ReaderIO[any] {
// return func(ctx context.Context) IO[any] {
// return func() any {
// reqID := ctx.Value("requestID").(RequestID)
// return F.Pipe1(
// res,
// result.Fold(
// func(err error) any {
// log.Printf("[%s] Operation failed: %v", reqID, err)
// return nil
// },
// func(_ User) any {
// log.Printf("[%s] Operation succeeded", reqID)
// return nil
// },
// ),
// )
// }
// }
// },
// )
//
// wrapped := logOp(fetchUser(123))
//
// Example with metrics collection:
//
// import "github.com/prometheus/client_golang/prometheus"
//
// metricsOp := LogEntryExitF[Response, any](
// func(ctx context.Context) IO[context.Context] {
// return func() context.Context {
// requestCount.WithLabelValues("api_call", "started").Inc()
// return context.WithValue(ctx, "startTime", time.Now())
// }
// },
// func(res Result[Response]) ReaderIO[any] {
// return func(ctx context.Context) IO[any] {
// return func() any {
// startTime := ctx.Value("startTime").(time.Time)
// duration := time.Since(startTime).Seconds()
//
// return F.Pipe1(
// res,
// result.Fold(
// func(err error) any {
// requestCount.WithLabelValues("api_call", "error").Inc()
// requestDuration.WithLabelValues("api_call", "error").Observe(duration)
// return nil
// },
// func(_ Response) any {
// requestCount.WithLabelValues("api_call", "success").Inc()
// requestDuration.WithLabelValues("api_call", "success").Observe(duration)
// return nil
// },
// ),
// )
// }
// }
// },
// )
//
// Use Cases:
// - Custom context modification: Adding request IDs, trace IDs, or other context values
// - Structured logging: Integration with zap, logrus, or other structured loggers
// - Metrics collection: Recording operation durations, success/failure rates
// - Distributed tracing: OpenTelemetry, Jaeger integration
// - Custom monitoring: Application-specific monitoring and alerting
//
// Note: LogEntryExit is implemented using LogEntryExitF with standard logging and context management.
// Use LogEntryExitF when you need more control over the entry/exit behavior or context modification.
func LogEntryExitF[A, ANY any](
onEntry ReaderIO[context.Context],
onExit readerio.Kleisli[Result[A], ANY],
) Operator[A, A] {
bracket := F.Bind13of3(readerio.Bracket[context.Context, Result[A], ANY])(onEntry, func(newCtx context.Context, res Result[A]) ReaderIO[ANY] {
return readerio.FromIO(onExit(res)(newCtx)) // Get the exit callback for this result
})
return func(src ReaderIOResult[A]) ReaderIOResult[A] {
return bracket(F.Flow2(
src,
FromIOResult,
))
}
}
// onEntry creates a ReaderIO that handles the entry logging for an operation.
// It generates a unique logging ID, captures the start time, and logs the entry message.
// The logging context is stored in the context.Context for later retrieval.
//
// Parameters:
// - logLevel: The slog.Level to use for logging (e.g., slog.LevelInfo, slog.LevelDebug)
// - cb: Callback function to retrieve the logger from the context
// - nameAttr: The slog.Attr containing the operation name
//
// Returns:
// - A ReaderIO that prepares the context with logging information and logs the entry
func onEntry(
logLevel slog.Level,
cb func(context.Context) *slog.Logger,
nameAttr slog.Attr,
) ReaderIO[context.Context] {
return func(ctx context.Context) IO[context.Context] {
// logger
logger := cb(ctx)
return func() context.Context {
// check if the logger is enabled
if logger.Enabled(ctx, logLevel) {
// Generate unique logging ID and capture start time
contextID := LoggingID(loggingCounter.Add(1))
startTime := time.Now()
newLogger := logger.With("ID", contextID)
// log using ID
newLogger.LogAttrs(ctx, logLevel, "[entering]", nameAttr)
withCtx := withLoggingContext(loggingContext{
contextID: contextID,
startTime: startTime,
logger: newLogger,
isEnabled: true,
})
withLogger := logging.WithLogger(newLogger)
return withCtx(withLogger(ctx))
}
// logging disabled
withCtx := withLoggingContext(loggingContext{
logger: logger,
isEnabled: false,
})
return withCtx(ctx)
}
}
}
// onExitAny creates a Kleisli function that handles exit logging for an operation.
// It logs either success or error based on the Result, including the operation duration.
// Only logs if logging was enabled during entry (checked via loggingContext.isEnabled).
//
// Parameters:
// - logLevel: The slog.Level to use for logging
// - nameAttr: The slog.Attr containing the operation name
//
// Returns:
// - A Kleisli function that logs the exit/error and returns nil
func onExitAny(
logLevel slog.Level,
nameAttr slog.Attr,
) readerio.Kleisli[Result[any], any] {
return func(res Result[any]) ReaderIO[any] {
return func(ctx context.Context) IO[any] {
value := getLoggingContext(ctx)
if value.isEnabled {
return func() any {
// Retrieve logging information from context
durationAttr := slog.Duration("duration", time.Since(value.startTime))
// Log error with ID and duration
onError := func(err error) any {
value.logger.LogAttrs(ctx, logLevel, "[throwing]",
nameAttr,
durationAttr,
slog.Any("error", err))
return nil
}
// Log success with ID and duration
onSuccess := func(_ any) any {
value.logger.LogAttrs(ctx, logLevel, "[exiting ]", nameAttr, durationAttr)
return nil
}
return F.Pipe1(
res,
result.Fold(onError, onSuccess),
)
}
}
// nothing to do
return io.Of[any](nil)
}
}
}
// LogEntryExitWithCallback creates an operator that logs entry and exit of a ReaderIOResult computation
// using a custom logger callback and log level. This provides more control than LogEntryExit.
//
// This function allows you to:
// - Use a custom log level (Debug, Info, Warn, Error)
// - Retrieve the logger from the context using a custom callback
// - Control whether logging is enabled based on the logger's configuration
//
// Type Parameters:
// - A: The success type of the ReaderIOResult
//
// Parameters:
// - logLevel: The slog.Level to use for all log messages (entry, exit, error)
// - cb: Callback function to retrieve the *slog.Logger from the context
// - name: A descriptive name for the operation
//
// Returns:
// - An Operator that wraps the ReaderIOResult with customizable logging
//
// Example with custom log level:
//
// // Log at debug level
// debugOp := LogEntryExitWithCallback[User](
// slog.LevelDebug,
// logging.GetLoggerFromContext,
// "fetchUser",
// )
// result := debugOp(fetchUser(123))
//
// Example with custom logger callback:
//
// type loggerKey int
// const myLoggerKey loggerKey = 0
//
// getMyLogger := func(ctx context.Context) *slog.Logger {
// if logger := ctx.Value(myLoggerKey); logger != nil {
// return logger.(*slog.Logger)
// }
// return slog.Default()
// }
//
// customOp := LogEntryExitWithCallback[Data](
// slog.LevelInfo,
// getMyLogger,
// "processData",
// )
func LogEntryExitWithCallback[A any](
logLevel slog.Level,
cb func(context.Context) *slog.Logger,
name string) Operator[A, A] {
nameAttr := slog.String("name", name)
return LogEntryExitF(
onEntry(logLevel, cb, nameAttr),
F.Flow2(
result.MapTo[A, any](nil),
onExitAny(logLevel, nameAttr),
),
)
}
// LogEntryExit creates an operator that logs the entry and exit of a ReaderIOResult computation with timing and correlation IDs.
//
// This function wraps a ReaderIOResult computation with automatic logging that tracks:
// - Entry: Logs when the computation starts with "[entering <id>] <name>"
// - Exit: Logs when the computation completes successfully with "[exiting <id>] <name> [duration]"
// - Error: Logs when the computation fails with "[throwing <id>] <name> [duration]: <error>"
//
// Each logged operation is assigned a unique LoggingID (a monotonically increasing counter) that
// appears in all log messages for that operation. This ID enables correlation of entry and exit
// logs, even when multiple operations are running concurrently or are interleaved.
//
// The logging information (start time and ID) is stored in the context and can be retrieved using
// getLoggingContext or getLoggingID. This allows nested operations to access the parent operation's
// logging information.
//
// Type Parameters:
// - A: The success type of the ReaderIOResult
//
// Parameters:
// - name: A descriptive name for the computation, used in log messages to identify the operation
//
// Returns:
// - An Operator that wraps the ReaderIOResult computation with entry/exit logging
//
// The function uses the bracket pattern to ensure that:
// - Entry is logged before the computation starts
// - A unique LoggingID is assigned and stored in the context
// - Exit/error is logged after the computation completes, regardless of success or failure
// - Timing is accurate, measuring from entry to exit
// - The original result is preserved and returned unchanged
//
// Log Format:
// - Entry: "[entering <id>] <name>"
// - Success: "[exiting <id>] <name> [<duration>s]"
// - Error: "[throwing <id>] <name> [<duration>s]: <error>"
//
// Example with successful computation:
//
// fetchUser := func(id int) ReaderIOResult[User] {
// return Of(User{ID: id, Name: "Alice"})
// }
//
// // Wrap with logging
// loggedFetch := LogEntryExit[User]("fetchUser")(fetchUser(123))
//
// // Execute
// result := loggedFetch(context.Background())()
// // Logs:
// // [entering 1] fetchUser
// // [exiting 1] fetchUser [0.1s]
//
// Example with error:
//
// failingOp := func() ReaderIOResult[string] {
// return Left[string](errors.New("connection timeout"))
// }
//
// logged := LogEntryExit[string]("failingOp")(failingOp())
// result := logged(context.Background())()
// // Logs:
// // [entering 2] failingOp
// // [throwing 2] failingOp [0.0s]: connection timeout
//
// Example with nested operations:
//
// fetchOrders := func(userID int) ReaderIOResult[[]Order] {
// return Of([]Order{{ID: 1}})
// }
//
// pipeline := F.Pipe3(
// fetchUser(123),
// LogEntryExit[User]("fetchUser"),
// Chain(func(user User) ReaderIOResult[[]Order] {
// return fetchOrders(user.ID)
// }),
// LogEntryExit[[]Order]("fetchOrders"),
// )
//
// result := pipeline(context.Background())()
// // Logs:
// // [entering 3] fetchUser
// // [exiting 3] fetchUser [0.1s]
// // [entering 4] fetchOrders
// // [exiting 4] fetchOrders [0.2s]
//
// Example with concurrent operations:
//
// // Multiple operations can run concurrently, each with unique IDs
// op1 := LogEntryExit[Data]("operation1")(fetchData(1))
// op2 := LogEntryExit[Data]("operation2")(fetchData(2))
//
// go op1(context.Background())()
// go op2(context.Background())()
// // Logs (order may vary):
// // [entering 5] operation1
// // [entering 6] operation2
// // [exiting 5] operation1 [0.1s]
// // [exiting 6] operation2 [0.2s]
// // The IDs allow correlation even when logs are interleaved
//
// Use Cases:
// - Debugging: Track execution flow through complex ReaderIOResult chains with correlation IDs
// - Performance monitoring: Identify slow operations with timing information
// - Production logging: Monitor critical operations with unique identifiers
// - Concurrent operations: Correlate logs from multiple concurrent operations
// - Nested operations: Track parent-child relationships in operation hierarchies
// - Troubleshooting: Quickly identify where errors occur and correlate with entry logs
//
//go:inline
func LogEntryExit[A any](name string) Operator[A, A] {
return LogEntryExitWithCallback[A](slog.LevelInfo, logging.GetLoggerFromContext, name)
}
func curriedLog(
logLevel slog.Level,
cb func(context.Context) *slog.Logger,
message string) func(slog.Attr) func(context.Context) func() struct{} {
return F.Curry2(func(a slog.Attr, ctx context.Context) func() struct{} {
logger := cb(ctx)
return func() struct{} {
logger.LogAttrs(ctx, logLevel, message, a)
return struct{}{}
}
})
}
// SLogWithCallback creates a Kleisli arrow that logs a Result value (success or error) with a custom logger and log level.
//
// This function logs both successful values and errors, making it useful for debugging and monitoring
// Result values as they flow through a computation. Unlike TapSLog which only logs successful values,
// SLogWithCallback logs the Result regardless of whether it contains a value or an error.
//
// The logged output includes:
// - For success: The message with the value as a structured "value" attribute
// - For error: The message with the error as a structured "error" attribute
//
// The Result is passed through unchanged after logging.
//
// Type Parameters:
// - A: The success type of the Result
//
// Parameters:
// - logLevel: The slog.Level to use for logging (e.g., slog.LevelInfo, slog.LevelDebug)
// - cb: Callback function to retrieve the *slog.Logger from the context
// - message: A descriptive message to include in the log entry
//
// Returns:
// - A Kleisli arrow that logs the Result (value or error) and returns it unchanged
//
// Example with custom log level:
//
// debugLog := SLogWithCallback[User](
// slog.LevelDebug,
// logging.GetLoggerFromContext,
// "User result",
// )
//
// pipeline := F.Pipe2(
// fetchUser(123),
// Chain(debugLog),
// Map(func(u User) string { return u.Name }),
// )
//
// Example with custom logger:
//
// type loggerKey int
// const myLoggerKey loggerKey = 0
//
// getMyLogger := func(ctx context.Context) *slog.Logger {
// if logger := ctx.Value(myLoggerKey); logger != nil {
// return logger.(*slog.Logger)
// }
// return slog.Default()
// }
//
// customLog := SLogWithCallback[Data](
// slog.LevelWarn,
// getMyLogger,
// "Data processing result",
// )
//
// Use Cases:
// - Debugging: Log both successful and failed Results in a pipeline
// - Error tracking: Monitor error occurrences with custom log levels
// - Custom logging: Use application-specific loggers and log levels
// - Conditional logging: Enable/disable logging based on logger configuration
func SLogWithCallback[A any](
logLevel slog.Level,
cb func(context.Context) *slog.Logger,
message string) Kleisli[Result[A], A] {
return F.Pipe1(
F.Flow2(
// create the attribute to log depending on the condition
result.ToSLogAttr[A](),
// create an `IO` that logs the attribute
curriedLog(logLevel, cb, message),
),
// preserve the original context
reader.Chain(reader.Sequence(readerio.MapTo[struct{}, Result[A]])),
)
}
// SLog creates a Kleisli arrow that logs a Result value (success or error) with a message.
//
// This function logs both successful values and errors at Info level using the logger from the context.
// It's a convenience wrapper around SLogWithCallback with standard settings.
//
// The logged output includes:
// - For success: The message with the value as a structured "value" attribute
// - For error: The message with the error as a structured "error" attribute
//
// The Result is passed through unchanged after logging, making this function transparent in the
// computation pipeline.
//
// Type Parameters:
// - A: The success type of the Result
//
// Parameters:
// - message: A descriptive message to include in the log entry
//
// Returns:
// - A Kleisli arrow that logs the Result (value or error) and returns it unchanged
//
// Example with successful Result:
//
// pipeline := F.Pipe2(
// fetchUser(123),
// Chain(SLog[User]("Fetched user")),
// Map(func(u User) string { return u.Name }),
// )
//
// result := pipeline(context.Background())()
// // If successful, logs: "Fetched user" value={ID:123 Name:"Alice"}
// // If error, logs: "Fetched user" error="user not found"
//
// Example in error handling pipeline:
//
// pipeline := F.Pipe3(
// fetchData(id),
// Chain(SLog[Data]("Data fetched")),
// Chain(validateData),
// Chain(SLog[Data]("Data validated")),
// Chain(processData),
// )
//
// // Logs each step, including errors:
// // "Data fetched" value={...} or error="..."
// // "Data validated" value={...} or error="..."
//
// Use Cases:
// - Debugging: Track both successful and failed Results in a pipeline
// - Error monitoring: Log errors as they occur in the computation
// - Flow tracking: See the progression of Results through a pipeline
// - Troubleshooting: Identify where errors are introduced or propagated
//
// Note: This function logs the Result itself (which may contain an error), not just successful values.
// For logging only successful values, use TapSLog instead.
//
//go:inline
func SLog[A any](message string) Kleisli[Result[A], A] {
return SLogWithCallback[A](slog.LevelInfo, logging.GetLoggerFromContext, message)
}
// TapSLog creates an operator that logs only successful values with a message and passes them through unchanged.
//
// This function is useful for debugging and monitoring values as they flow through a ReaderIOResult
// computation chain. Unlike SLog which logs both successes and errors, TapSLog only logs when the
// computation is successful. If the computation contains an error, no logging occurs and the error
// is propagated unchanged.
//
// The logged output includes:
// - The provided message
// - The value being passed through (as a structured "value" attribute)
//
// Type Parameters:
// - A: The type of the value to log and pass through
//
// Parameters:
// - message: A descriptive message to include in the log entry
//
// Returns:
// - An Operator that logs successful values and returns them unchanged
//
// Example with simple value logging:
//
// fetchUser := func(id int) ReaderIOResult[User] {
// return Of(User{ID: id, Name: "Alice"})
// }
//
// pipeline := F.Pipe2(
// fetchUser(123),
// TapSLog[User]("Fetched user"),
// Map(func(u User) string { return u.Name }),
// )
//
// result := pipeline(context.Background())()
// // Logs: "Fetched user" value={ID:123 Name:"Alice"}
// // Returns: result.Of("Alice")
//
// Example in a processing pipeline:
//
// processOrder := F.Pipe4(
// fetchOrder(orderId),
// TapSLog[Order]("Order fetched"),
// Chain(validateOrder),
// TapSLog[Order]("Order validated"),
// Chain(processPayment),
// TapSLog[Payment]("Payment processed"),
// )
//
// result := processOrder(context.Background())()
// // Logs each successful step with the intermediate values
// // If any step fails, subsequent TapSLog calls don't log
//
// Example with error handling:
//
// pipeline := F.Pipe3(
// fetchData(id),
// TapSLog[Data]("Data fetched"),
// Chain(func(d Data) ReaderIOResult[Result] {
// if d.IsValid() {
// return Of(processData(d))
// }
// return Left[Result](errors.New("invalid data"))
// }),
// TapSLog[Result]("Data processed"),
// )
//
// // If fetchData succeeds: logs "Data fetched" with the data
// // If processing succeeds: logs "Data processed" with the result
// // If processing fails: "Data processed" is NOT logged (error propagates)
//
// Use Cases:
// - Debugging: Inspect intermediate successful values in a computation pipeline
// - Monitoring: Track successful data flow through complex operations
// - Troubleshooting: Identify where successful computations stop (last logged value before error)
// - Auditing: Log important successful values for compliance or security
// - Development: Understand data transformations during development
//
// Note: This function only logs successful values. Errors are silently propagated without logging.
// For logging both successes and errors, use SLog instead.
//
//go:inline
func TapSLog[A any](message string) Operator[A, A] {
return readerio.ChainFirst(SLog[A](message))
}

662
v2/context/readerioresult/logging_test.go Normal file
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@@ -0,0 +1,662 @@
package readerioresult
import (
"bytes"
"context"
"errors"
"log/slog"
"strconv"
"strings"
"testing"
"time"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/logging"
N "github.com/IBM/fp-go/v2/number"
"github.com/IBM/fp-go/v2/result"
S "github.com/IBM/fp-go/v2/string"
"github.com/stretchr/testify/assert"
)
// TestLoggingContext tests basic nested logging with correlation IDs
func TestLoggingContext(t *testing.T) {
data := F.Pipe2(
Of("Sample"),
LogEntryExit[string]("TestLoggingContext1"),
LogEntryExit[string]("TestLoggingContext2"),
)
assert.Equal(t, result.Of("Sample"), data(context.Background())())
}
// TestLogEntryExitSuccess tests successful operation logging
func TestLogEntryExitSuccess(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
operation := F.Pipe1(
Of("success value"),
LogEntryExit[string]("TestOperation"),
)
res := operation(context.Background())()
assert.Equal(t, result.Of("success value"), res)
logOutput := buf.String()
assert.Contains(t, logOutput, "[entering]")
assert.Contains(t, logOutput, "[exiting ]")
assert.Contains(t, logOutput, "TestOperation")
assert.Contains(t, logOutput, "ID=")
assert.Contains(t, logOutput, "duration=")
}
// TestLogEntryExitError tests error operation logging
func TestLogEntryExitError(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
testErr := errors.New("test error")
operation := F.Pipe1(
Left[string](testErr),
LogEntryExit[string]("FailingOperation"),
)
res := operation(context.Background())()
assert.True(t, result.IsLeft(res))
logOutput := buf.String()
assert.Contains(t, logOutput, "[entering]")
assert.Contains(t, logOutput, "[throwing]")
assert.Contains(t, logOutput, "FailingOperation")
assert.Contains(t, logOutput, "test error")
assert.Contains(t, logOutput, "ID=")
assert.Contains(t, logOutput, "duration=")
}
// TestLogEntryExitNested tests nested operations with different IDs
func TestLogEntryExitNested(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
innerOp := F.Pipe1(
Of("inner"),
LogEntryExit[string]("InnerOp"),
)
outerOp := F.Pipe2(
Of("outer"),
LogEntryExit[string]("OuterOp"),
Chain(func(s string) ReaderIOResult[string] {
return innerOp
}),
)
res := outerOp(context.Background())()
assert.True(t, result.IsRight(res))
logOutput := buf.String()
// Should have two different IDs
assert.Contains(t, logOutput, "OuterOp")
assert.Contains(t, logOutput, "InnerOp")
// Count entering and exiting logs
enterCount := strings.Count(logOutput, "[entering]")
exitCount := strings.Count(logOutput, "[exiting ]")
assert.Equal(t, 2, enterCount, "Should have 2 entering logs")
assert.Equal(t, 2, exitCount, "Should have 2 exiting logs")
}
// TestLogEntryExitWithCallback tests custom log level and callback
func TestLogEntryExitWithCallback(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelDebug,
}))
customCallback := func(ctx context.Context) *slog.Logger {
return logger
}
operation := F.Pipe1(
Of(42),
LogEntryExitWithCallback[int](slog.LevelDebug, customCallback, "DebugOperation"),
)
res := operation(context.Background())()
assert.Equal(t, result.Of(42), res)
logOutput := buf.String()
assert.Contains(t, logOutput, "[entering]")
assert.Contains(t, logOutput, "[exiting ]")
assert.Contains(t, logOutput, "DebugOperation")
assert.Contains(t, logOutput, "level=DEBUG")
}
// TestLogEntryExitDisabled tests that logging can be disabled
func TestLogEntryExitDisabled(t *testing.T) {
var buf bytes.Buffer
// Create logger with level that disables info logs
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelError, // Only log errors
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
operation := F.Pipe1(
Of("value"),
LogEntryExit[string]("DisabledOperation"),
)
res := operation(context.Background())()
assert.True(t, result.IsRight(res))
// Should have no logs since level is ERROR
logOutput := buf.String()
assert.Empty(t, logOutput, "Should have no logs when logging is disabled")
}
// TestLogEntryExitF tests custom entry/exit callbacks
func TestLogEntryExitF(t *testing.T) {
var entryCount, exitCount int
onEntry := func(ctx context.Context) IO[context.Context] {
return func() context.Context {
entryCount++
return ctx
}
}
onExit := func(res Result[string]) ReaderIO[any] {
return func(ctx context.Context) IO[any] {
return func() any {
exitCount++
return nil
}
}
}
operation := F.Pipe1(
Of("test"),
LogEntryExitF(onEntry, onExit),
)
res := operation(context.Background())()
assert.True(t, result.IsRight(res))
assert.Equal(t, 1, entryCount, "Entry callback should be called once")
assert.Equal(t, 1, exitCount, "Exit callback should be called once")
}
// TestLogEntryExitFWithError tests custom callbacks with error
func TestLogEntryExitFWithError(t *testing.T) {
var entryCount, exitCount int
var capturedError error
onEntry := func(ctx context.Context) IO[context.Context] {
return func() context.Context {
entryCount++
return ctx
}
}
onExit := func(res Result[string]) ReaderIO[any] {
return func(ctx context.Context) IO[any] {
return func() any {
exitCount++
if result.IsLeft(res) {
_, capturedError = result.Unwrap(res)
}
return nil
}
}
}
testErr := errors.New("custom error")
operation := F.Pipe1(
Left[string](testErr),
LogEntryExitF(onEntry, onExit),
)
res := operation(context.Background())()
assert.True(t, result.IsLeft(res))
assert.Equal(t, 1, entryCount, "Entry callback should be called once")
assert.Equal(t, 1, exitCount, "Exit callback should be called once")
assert.Equal(t, testErr, capturedError, "Should capture the error")
}
// TestLoggingIDUniqueness tests that logging IDs are unique
func TestLoggingIDUniqueness(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
// Run multiple operations
for i := range 5 {
op := F.Pipe1(
Of(i),
LogEntryExit[int]("Operation"),
)
op(context.Background())()
}
logOutput := buf.String()
// Extract all IDs and verify they're unique
lines := strings.Split(logOutput, "\n")
ids := make(map[string]bool)
for _, line := range lines {
if strings.Contains(line, "ID=") {
// Extract ID value
parts := strings.Split(line, "ID=")
if len(parts) > 1 {
idPart := strings.Fields(parts[1])[0]
ids[idPart] = true
}
}
}
// Should have 5 unique IDs (one per operation)
assert.GreaterOrEqual(t, len(ids), 5, "Should have at least 5 unique IDs")
}
// TestLogEntryExitWithContextLogger tests using logger from context
func TestLogEntryExitWithContextLogger(t *testing.T) {
var buf bytes.Buffer
contextLogger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
ctx := logging.WithLogger(contextLogger)(context.Background())
operation := F.Pipe1(
Of("context value"),
LogEntryExit[string]("ContextOperation"),
)
res := operation(ctx)()
assert.True(t, result.IsRight(res))
logOutput := buf.String()
assert.Contains(t, logOutput, "[entering]")
assert.Contains(t, logOutput, "[exiting ]")
assert.Contains(t, logOutput, "ContextOperation")
}
// TestLogEntryExitTiming tests that duration is captured
func TestLogEntryExitTiming(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
// Operation with delay
slowOp := func(ctx context.Context) IOResult[string] {
return func() Result[string] {
time.Sleep(10 * time.Millisecond)
return result.Of("done")
}
}
operation := F.Pipe1(
slowOp,
LogEntryExit[string]("SlowOperation"),
)
res := operation(context.Background())()
assert.True(t, result.IsRight(res))
logOutput := buf.String()
assert.Contains(t, logOutput, "duration=")
// Verify duration is present in exit log
lines := strings.Split(logOutput, "\n")
var foundDuration bool
for _, line := range lines {
if strings.Contains(line, "[exiting ]") && strings.Contains(line, "duration=") {
foundDuration = true
break
}
}
assert.True(t, foundDuration, "Exit log should contain duration")
}
// TestLogEntryExitChainedOperations tests complex chained operations
func TestLogEntryExitChainedOperations(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
step1 := F.Pipe1(
Of(1),
LogEntryExit[int]("Step1"),
)
step2 := F.Flow3(
N.Mul(2),
Of,
LogEntryExit[int]("Step2"),
)
step3 := F.Flow3(
strconv.Itoa,
Of,
LogEntryExit[string]("Step3"),
)
pipeline := F.Pipe1(
step1,
Chain(F.Flow2(
step2,
Chain(step3),
)),
)
res := pipeline(context.Background())()
assert.Equal(t, result.Of("2"), res)
logOutput := buf.String()
assert.Contains(t, logOutput, "Step1")
assert.Contains(t, logOutput, "Step2")
assert.Contains(t, logOutput, "Step3")
// Verify all steps completed
assert.Equal(t, 3, strings.Count(logOutput, "[entering]"))
assert.Equal(t, 3, strings.Count(logOutput, "[exiting ]"))
}
// TestTapSLog tests basic TapSLog functionality
func TestTapSLog(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
operation := F.Pipe2(
Of(42),
TapSLog[int]("Processing value"),
Map(N.Mul(2)),
)
res := operation(context.Background())()
assert.Equal(t, result.Of(84), res)
logOutput := buf.String()
assert.Contains(t, logOutput, "Processing value")
assert.Contains(t, logOutput, "value=42")
}
// TestTapSLogInPipeline tests TapSLog in a multi-step pipeline
func TestTapSLogInPipeline(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
step1 := F.Pipe2(
Of("hello"),
TapSLog[string]("Step 1: Initial value"),
Map(func(s string) string { return s + " world" }),
)
step2 := F.Pipe2(
step1,
TapSLog[string]("Step 2: After concatenation"),
Map(S.Size),
)
pipeline := F.Pipe1(
step2,
TapSLog[int]("Step 3: Final length"),
)
res := pipeline(context.Background())()
assert.Equal(t, result.Of(11), res)
logOutput := buf.String()
assert.Contains(t, logOutput, "Step 1: Initial value")
assert.Contains(t, logOutput, "value=hello")
assert.Contains(t, logOutput, "Step 2: After concatenation")
assert.Contains(t, logOutput, `value="hello world"`)
assert.Contains(t, logOutput, "Step 3: Final length")
assert.Contains(t, logOutput, "value=11")
}
// TestTapSLogWithError tests that TapSLog logs errors (via SLog)
func TestTapSLogWithError(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
testErr := errors.New("computation failed")
pipeline := F.Pipe2(
Left[int](testErr),
TapSLog[int]("Error logged"),
Map(N.Mul(2)),
)
res := pipeline(context.Background())()
assert.True(t, result.IsLeft(res))
logOutput := buf.String()
// TapSLog uses SLog internally, which logs both successes and errors
assert.Contains(t, logOutput, "Error logged")
assert.Contains(t, logOutput, "error")
assert.Contains(t, logOutput, "computation failed")
}
// TestTapSLogWithStruct tests TapSLog with structured data
func TestTapSLogWithStruct(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
type User struct {
ID int
Name string
}
user := User{ID: 123, Name: "Alice"}
operation := F.Pipe2(
Of(user),
TapSLog[User]("User data"),
Map(func(u User) string { return u.Name }),
)
res := operation(context.Background())()
assert.Equal(t, result.Of("Alice"), res)
logOutput := buf.String()
assert.Contains(t, logOutput, "User data")
assert.Contains(t, logOutput, "ID:123")
assert.Contains(t, logOutput, "Name:Alice")
}
// TestTapSLogDisabled tests that TapSLog respects logger level
func TestTapSLogDisabled(t *testing.T) {
var buf bytes.Buffer
// Create logger with level that disables info logs
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelError, // Only log errors
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
operation := F.Pipe2(
Of(42),
TapSLog[int]("This should not be logged"),
Map(N.Mul(2)),
)
res := operation(context.Background())()
assert.Equal(t, result.Of(84), res)
// Should have no logs since level is ERROR
logOutput := buf.String()
assert.Empty(t, logOutput, "Should have no logs when logging is disabled")
}
// TestTapSLogWithContextLogger tests TapSLog using logger from context
func TestTapSLogWithContextLogger(t *testing.T) {
var buf bytes.Buffer
contextLogger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
ctx := logging.WithLogger(contextLogger)(context.Background())
operation := F.Pipe2(
Of("test value"),
TapSLog[string]("Context logger test"),
Map(S.Size),
)
res := operation(ctx)()
assert.Equal(t, result.Of(10), res)
logOutput := buf.String()
assert.Contains(t, logOutput, "Context logger test")
assert.Contains(t, logOutput, `value="test value"`)
}
// TestSLogLogsSuccessValue tests that SLog logs successful Result values
func TestSLogLogsSuccessValue(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
// Create a Result and log it
res1 := result.Of(42)
logged := SLog[int]("Result value")(res1)(ctx)()
assert.Equal(t, result.Of(42), logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "Result value")
assert.Contains(t, logOutput, "value=42")
}
// TestSLogLogsErrorValue tests that SLog logs error Result values
func TestSLogLogsErrorValue(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
testErr := errors.New("test error")
// Create an error Result and log it
res1 := result.Left[int](testErr)
logged := SLog[int]("Result value")(res1)(ctx)()
assert.True(t, result.IsLeft(logged))
logOutput := buf.String()
assert.Contains(t, logOutput, "Result value")
assert.Contains(t, logOutput, "error")
assert.Contains(t, logOutput, "test error")
}
// TestSLogWithCallbackCustomLevel tests SLogWithCallback with custom log level
func TestSLogWithCallbackCustomLevel(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelDebug,
}))
customCallback := func(ctx context.Context) *slog.Logger {
return logger
}
ctx := context.Background()
// Create a Result and log it with custom callback
res1 := result.Of(42)
logged := SLogWithCallback[int](slog.LevelDebug, customCallback, "Debug result")(res1)(ctx)()
assert.Equal(t, result.Of(42), logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "Debug result")
assert.Contains(t, logOutput, "value=42")
assert.Contains(t, logOutput, "level=DEBUG")
}
// TestSLogWithCallbackLogsError tests SLogWithCallback logs errors
func TestSLogWithCallbackLogsError(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelWarn,
}))
customCallback := func(ctx context.Context) *slog.Logger {
return logger
}
ctx := context.Background()
testErr := errors.New("warning error")
// Create an error Result and log it with custom callback
res1 := result.Left[int](testErr)
logged := SLogWithCallback[int](slog.LevelWarn, customCallback, "Warning result")(res1)(ctx)()
assert.True(t, result.IsLeft(logged))
logOutput := buf.String()
assert.Contains(t, logOutput, "Warning result")
assert.Contains(t, logOutput, "error")
assert.Contains(t, logOutput, "warning error")
assert.Contains(t, logOutput, "level=WARN")
}

289
v2/context/readerioresult/reader.go
View File

@@ -19,6 +19,7 @@ import (
"context"
"time"
"github.com/IBM/fp-go/v2/context/readerio"
"github.com/IBM/fp-go/v2/context/readerresult"
"github.com/IBM/fp-go/v2/either"
"github.com/IBM/fp-go/v2/errors"
@@ -26,10 +27,11 @@ import (
"github.com/IBM/fp-go/v2/io"
"github.com/IBM/fp-go/v2/ioeither"
"github.com/IBM/fp-go/v2/ioresult"
"github.com/IBM/fp-go/v2/option"
"github.com/IBM/fp-go/v2/reader"
"github.com/IBM/fp-go/v2/readerio"
RIOR "github.com/IBM/fp-go/v2/readerioresult"
"github.com/IBM/fp-go/v2/readeroption"
"github.com/IBM/fp-go/v2/result"
)
const (
@@ -150,7 +152,7 @@ func MapTo[A, B any](b B) Operator[A, B] {
//
//go:inline
func MonadChain[A, B any](ma ReaderIOResult[A], f Kleisli[A, B]) ReaderIOResult[B] {
return RIOR.MonadChain(ma, f)
return RIOR.MonadChain(ma, WithContextK(f))
}
// Chain sequences two [ReaderIOResult] computations, where the second depends on the result of the first.
@@ -163,7 +165,7 @@ func MonadChain[A, B any](ma ReaderIOResult[A], f Kleisli[A, B]) ReaderIOResult[
//
//go:inline
func Chain[A, B any](f Kleisli[A, B]) Operator[A, B] {
return RIOR.Chain(f)
return RIOR.Chain(WithContextK(f))
}
// MonadChainFirst sequences two [ReaderIOResult] computations but returns the result of the first.
@@ -177,12 +179,12 @@ func Chain[A, B any](f Kleisli[A, B]) Operator[A, B] {
//
//go:inline
func MonadChainFirst[A, B any](ma ReaderIOResult[A], f Kleisli[A, B]) ReaderIOResult[A] {
return RIOR.MonadChainFirst(ma, f)
return RIOR.MonadChainFirst(ma, WithContextK(f))
}
//go:inline
func MonadTap[A, B any](ma ReaderIOResult[A], f Kleisli[A, B]) ReaderIOResult[A] {
return RIOR.MonadTap(ma, f)
return RIOR.MonadTap(ma, WithContextK(f))
}
// ChainFirst sequences two [ReaderIOResult] computations but returns the result of the first.
@@ -195,12 +197,12 @@ func MonadTap[A, B any](ma ReaderIOResult[A], f Kleisli[A, B]) ReaderIOResult[A]
//
//go:inline
func ChainFirst[A, B any](f Kleisli[A, B]) Operator[A, A] {
return RIOR.ChainFirst(f)
return RIOR.ChainFirst(WithContextK(f))
}
//go:inline
func Tap[A, B any](f Kleisli[A, B]) Operator[A, A] {
return RIOR.Tap(f)
return RIOR.Tap(WithContextK(f))
}
// Of creates a [ReaderIOResult] that always succeeds with the given value.
@@ -243,14 +245,14 @@ func MonadApPar[B, A any](fab ReaderIOResult[func(A) B], fa ReaderIOResult[A]) R
return func(ctx context.Context) IOResult[B] {
// quick check for cancellation
if err := context.Cause(ctx); err != nil {
return ioeither.Left[B](err)
if ctx.Err() != nil {
return ioeither.Left[B](context.Cause(ctx))
}
return func() Result[B] {
// quick check for cancellation
if err := context.Cause(ctx); err != nil {
return either.Left[B](err)
if ctx.Err() != nil {
return either.Left[B](context.Cause(ctx))
}
// create sub-contexts for fa and fab, so they can cancel one other
@@ -382,7 +384,7 @@ func Ask() ReaderIOResult[context.Context] {
// Returns a new ReaderIOResult with the chained computation.
//
//go:inline
func MonadChainEitherK[A, B any](ma ReaderIOResult[A], f func(A) Either[B]) ReaderIOResult[B] {
func MonadChainEitherK[A, B any](ma ReaderIOResult[A], f either.Kleisli[error, A, B]) ReaderIOResult[B] {
return RIOR.MonadChainEitherK(ma, f)
}
@@ -395,7 +397,12 @@ func MonadChainEitherK[A, B any](ma ReaderIOResult[A], f func(A) Either[B]) Read
// Returns a function that chains the Either-returning function.
//
//go:inline
func ChainEitherK[A, B any](f func(A) Either[B]) Operator[A, B] {
func ChainEitherK[A, B any](f either.Kleisli[error, A, B]) Operator[A, B] {
return RIOR.ChainEitherK[context.Context](f)
}
//go:inline
func ChainResultK[A, B any](f either.Kleisli[error, A, B]) Operator[A, B] {
return RIOR.ChainEitherK[context.Context](f)
}
@@ -409,12 +416,12 @@ func ChainEitherK[A, B any](f func(A) Either[B]) Operator[A, B] {
// Returns a ReaderIOResult with the original value if both computations succeed.
//
//go:inline
func MonadChainFirstEitherK[A, B any](ma ReaderIOResult[A], f func(A) Either[B]) ReaderIOResult[A] {
func MonadChainFirstEitherK[A, B any](ma ReaderIOResult[A], f either.Kleisli[error, A, B]) ReaderIOResult[A] {
return RIOR.MonadChainFirstEitherK(ma, f)
}
//go:inline
func MonadTapEitherK[A, B any](ma ReaderIOResult[A], f func(A) Either[B]) ReaderIOResult[A] {
func MonadTapEitherK[A, B any](ma ReaderIOResult[A], f either.Kleisli[error, A, B]) ReaderIOResult[A] {
return RIOR.MonadTapEitherK(ma, f)
}
@@ -427,12 +434,12 @@ func MonadTapEitherK[A, B any](ma ReaderIOResult[A], f func(A) Either[B]) Reader
// Returns a function that chains the Either-returning function.
//
//go:inline
func ChainFirstEitherK[A, B any](f func(A) Either[B]) Operator[A, A] {
func ChainFirstEitherK[A, B any](f either.Kleisli[error, A, B]) Operator[A, A] {
return RIOR.ChainFirstEitherK[context.Context](f)
}
//go:inline
func TapEitherK[A, B any](f func(A) Either[B]) Operator[A, A] {
func TapEitherK[A, B any](f either.Kleisli[error, A, B]) Operator[A, A] {
return RIOR.TapEitherK[context.Context](f)
}
@@ -445,7 +452,7 @@ func TapEitherK[A, B any](f func(A) Either[B]) Operator[A, A] {
// Returns a function that chains Option-returning functions into ReaderIOResult.
//
//go:inline
func ChainOptionK[A, B any](onNone func() error) func(func(A) Option[B]) Operator[A, B] {
func ChainOptionK[A, B any](onNone func() error) func(option.Kleisli[A, B]) Operator[A, B] {
return RIOR.ChainOptionK[context.Context, A, B](onNone)
}
@@ -527,7 +534,7 @@ func Never[A any]() ReaderIOResult[A] {
// Returns a new ReaderIOResult with the chained IO computation.
//
//go:inline
func MonadChainIOK[A, B any](ma ReaderIOResult[A], f func(A) IO[B]) ReaderIOResult[B] {
func MonadChainIOK[A, B any](ma ReaderIOResult[A], f io.Kleisli[A, B]) ReaderIOResult[B] {
return RIOR.MonadChainIOK(ma, f)
}
@@ -540,7 +547,7 @@ func MonadChainIOK[A, B any](ma ReaderIOResult[A], f func(A) IO[B]) ReaderIOResu
// Returns a function that chains the IO-returning function.
//
//go:inline
func ChainIOK[A, B any](f func(A) IO[B]) Operator[A, B] {
func ChainIOK[A, B any](f io.Kleisli[A, B]) Operator[A, B] {
return RIOR.ChainIOK[context.Context](f)
}
@@ -554,12 +561,12 @@ func ChainIOK[A, B any](f func(A) IO[B]) Operator[A, B] {
// Returns a ReaderIOResult with the original value after executing the IO.
//
//go:inline
func MonadChainFirstIOK[A, B any](ma ReaderIOResult[A], f func(A) IO[B]) ReaderIOResult[A] {
func MonadChainFirstIOK[A, B any](ma ReaderIOResult[A], f io.Kleisli[A, B]) ReaderIOResult[A] {
return RIOR.MonadChainFirstIOK(ma, f)
}
//go:inline
func MonadTapIOK[A, B any](ma ReaderIOResult[A], f func(A) IO[B]) ReaderIOResult[A] {
func MonadTapIOK[A, B any](ma ReaderIOResult[A], f io.Kleisli[A, B]) ReaderIOResult[A] {
return RIOR.MonadTapIOK(ma, f)
}
@@ -572,12 +579,12 @@ func MonadTapIOK[A, B any](ma ReaderIOResult[A], f func(A) IO[B]) ReaderIOResult
// Returns a function that chains the IO-returning function.
//
//go:inline
func ChainFirstIOK[A, B any](f func(A) IO[B]) Operator[A, A] {
func ChainFirstIOK[A, B any](f io.Kleisli[A, B]) Operator[A, A] {
return RIOR.ChainFirstIOK[context.Context](f)
}
//go:inline
func TapIOK[A, B any](f func(A) IO[B]) Operator[A, A] {
func TapIOK[A, B any](f io.Kleisli[A, B]) Operator[A, A] {
return RIOR.TapIOK[context.Context](f)
}
@@ -590,7 +597,7 @@ func TapIOK[A, B any](f func(A) IO[B]) Operator[A, A] {
// Returns a function that chains the IOResult-returning function.
//
//go:inline
func ChainIOEitherK[A, B any](f func(A) IOResult[B]) Operator[A, B] {
func ChainIOEitherK[A, B any](f ioresult.Kleisli[A, B]) Operator[A, B] {
return RIOR.ChainIOEitherK[context.Context](f)
}
@@ -753,7 +760,7 @@ func Flap[B, A any](a A) Operator[func(A) B, B] {
//
//go:inline
func Fold[A, B any](onLeft Kleisli[error, B], onRight Kleisli[A, B]) Operator[A, B] {
return RIOR.Fold(onLeft, onRight)
return RIOR.Fold(function.Flow2(onLeft, WithContext), function.Flow2(onRight, WithContext))
}
// GetOrElse extracts the value from a [ReaderIOResult], providing a default via a function if it fails.
@@ -765,7 +772,7 @@ func Fold[A, B any](onLeft Kleisli[error, B], onRight Kleisli[A, B]) Operator[A,
// Returns a function that converts a ReaderIOResult to a ReaderIO.
//
//go:inline
func GetOrElse[A any](onLeft func(error) ReaderIO[A]) func(ReaderIOResult[A]) ReaderIO[A] {
func GetOrElse[A any](onLeft readerio.Kleisli[error, A]) func(ReaderIOResult[A]) ReaderIO[A] {
return RIOR.GetOrElse(onLeft)
}
@@ -858,32 +865,32 @@ func TapReaderResultK[A, B any](f readerresult.Kleisli[A, B]) Operator[A, A] {
}
//go:inline
func MonadChainReaderIOK[A, B any](ma ReaderIOResult[A], f readerio.Kleisli[context.Context, A, B]) ReaderIOResult[B] {
func MonadChainReaderIOK[A, B any](ma ReaderIOResult[A], f readerio.Kleisli[A, B]) ReaderIOResult[B] {
return RIOR.MonadChainReaderIOK(ma, f)
}
//go:inline
func ChainReaderIOK[A, B any](f readerio.Kleisli[context.Context, A, B]) Operator[A, B] {
func ChainReaderIOK[A, B any](f readerio.Kleisli[A, B]) Operator[A, B] {
return RIOR.ChainReaderIOK(f)
}
//go:inline
func MonadChainFirstReaderIOK[A, B any](ma ReaderIOResult[A], f readerio.Kleisli[context.Context, A, B]) ReaderIOResult[A] {
func MonadChainFirstReaderIOK[A, B any](ma ReaderIOResult[A], f readerio.Kleisli[A, B]) ReaderIOResult[A] {
return RIOR.MonadChainFirstReaderIOK(ma, f)
}
//go:inline
func MonadTapReaderIOK[A, B any](ma ReaderIOResult[A], f readerio.Kleisli[context.Context, A, B]) ReaderIOResult[A] {
func MonadTapReaderIOK[A, B any](ma ReaderIOResult[A], f readerio.Kleisli[A, B]) ReaderIOResult[A] {
return RIOR.MonadTapReaderIOK(ma, f)
}
//go:inline
func ChainFirstReaderIOK[A, B any](f readerio.Kleisli[context.Context, A, B]) Operator[A, A] {
func ChainFirstReaderIOK[A, B any](f readerio.Kleisli[A, B]) Operator[A, A] {
return RIOR.ChainFirstReaderIOK(f)
}
//go:inline
func TapReaderIOK[A, B any](f readerio.Kleisli[context.Context, A, B]) Operator[A, A] {
func TapReaderIOK[A, B any](f readerio.Kleisli[A, B]) Operator[A, A] {
return RIOR.TapReaderIOK(f)
}
@@ -913,15 +920,15 @@ func Read[A any](r context.Context) func(ReaderIOResult[A]) IOResult[A] {
//
//go:inline
func MonadChainLeft[A any](fa ReaderIOResult[A], f Kleisli[error, A]) ReaderIOResult[A] {
return RIOR.MonadChainLeft(fa, f)
return RIOR.MonadChainLeft(fa, WithContextK(f))
}
// ChainLeft is the curried version of [MonadChainLeft].
// It returns a function that chains a computation on the left (error) side of a [ReaderIOResult].
//
//go:inline
func ChainLeft[A any](f Kleisli[error, A]) func(ReaderIOResult[A]) ReaderIOResult[A] {
return RIOR.ChainLeft(f)
func ChainLeft[A any](f Kleisli[error, A]) Operator[A, A] {
return RIOR.ChainLeft(WithContextK(f))
}
// MonadChainFirstLeft chains a computation on the left (error) side but always returns the original error.
@@ -934,12 +941,12 @@ func ChainLeft[A any](f Kleisli[error, A]) func(ReaderIOResult[A]) ReaderIOResul
//
//go:inline
func MonadChainFirstLeft[A, B any](ma ReaderIOResult[A], f Kleisli[error, B]) ReaderIOResult[A] {
return RIOR.MonadChainFirstLeft(ma, f)
return RIOR.MonadChainFirstLeft(ma, WithContextK(f))
}
//go:inline
func MonadTapLeft[A, B any](ma ReaderIOResult[A], f Kleisli[error, B]) ReaderIOResult[A] {
return RIOR.MonadTapLeft(ma, f)
return RIOR.MonadTapLeft(ma, WithContextK(f))
}
// ChainFirstLeft is the curried version of [MonadChainFirstLeft].
@@ -951,10 +958,212 @@ func MonadTapLeft[A, B any](ma ReaderIOResult[A], f Kleisli[error, B]) ReaderIOR
//
//go:inline
func ChainFirstLeft[A, B any](f Kleisli[error, B]) Operator[A, A] {
return RIOR.ChainFirstLeft[A](f)
return RIOR.ChainFirstLeft[A](WithContextK(f))
}
//go:inline
func TapLeft[A, B any](f Kleisli[error, B]) Operator[A, A] {
return RIOR.TapLeft[A](f)
return RIOR.TapLeft[A](WithContextK(f))
}
// Local transforms the context.Context environment before passing it to a ReaderIOResult computation.
//
// This is the Reader's local operation, which allows you to modify the environment
// for a specific computation without affecting the outer context. The transformation
// function receives the current context and returns a new context along with a
// cancel function. The cancel function is automatically called when the computation
// completes (via defer), ensuring proper cleanup of resources.
//
// The function checks for context cancellation before applying the transformation,
// returning an error immediately if the context is already cancelled.
//
// This is useful for:
// - Adding timeouts or deadlines to specific operations
// - Adding context values for nested computations
// - Creating isolated context scopes
// - Implementing context-based dependency injection
//
// Type Parameters:
// - A: The value type of the ReaderIOResult
//
// Parameters:
// - f: A function that transforms the context and returns a cancel function
//
// Returns:
// - An Operator that runs the computation with the transformed context
//
// Example:
//
// import F "github.com/IBM/fp-go/v2/function"
//
// // Add a custom value to the context
// type key int
// const userKey key = 0
//
// addUser := readerioresult.Local[string](func(ctx context.Context) (context.Context, context.CancelFunc) {
// newCtx := context.WithValue(ctx, userKey, "Alice")
// return newCtx, func() {} // No-op cancel
// })
//
// getUser := readerioresult.FromReader(func(ctx context.Context) string {
// if user := ctx.Value(userKey); user != nil {
// return user.(string)
// }
// return "unknown"
// })
//
// result := F.Pipe1(
// getUser,
// addUser,
// )
// value, err := result(context.Background())() // Returns ("Alice", nil)
//
// Timeout Example:
//
// // Add a 5-second timeout to a specific operation
// withTimeout := readerioresult.Local[Data](func(ctx context.Context) (context.Context, context.CancelFunc) {
// return context.WithTimeout(ctx, 5*time.Second)
// })
//
// result := F.Pipe1(
// fetchData,
// withTimeout,
// )
func Local[A any](f func(context.Context) (context.Context, context.CancelFunc)) Operator[A, A] {
return func(rr ReaderIOResult[A]) ReaderIOResult[A] {
return func(ctx context.Context) IOResult[A] {
return func() Result[A] {
if ctx.Err() != nil {
return result.Left[A](context.Cause(ctx))
}
otherCtx, otherCancel := f(ctx)
defer otherCancel()
return rr(otherCtx)()
}
}
}
}
// WithTimeout adds a timeout to the context for a ReaderIOResult computation.
//
// This is a convenience wrapper around Local that uses context.WithTimeout.
// The computation must complete within the specified duration, or it will be
// cancelled. This is useful for ensuring operations don't run indefinitely
// and for implementing timeout-based error handling.
//
// The timeout is relative to when the ReaderIOResult is executed, not when
// WithTimeout is called. The cancel function is automatically called when
// the computation completes, ensuring proper cleanup. If the timeout expires,
// the computation will receive a context.DeadlineExceeded error.
//
// Type Parameters:
// - A: The value type of the ReaderIOResult
//
// Parameters:
// - timeout: The maximum duration for the computation
//
// Returns:
// - An Operator that runs the computation with a timeout
//
// Example:
//
// import (
// "time"
// F "github.com/IBM/fp-go/v2/function"
// )
//
// // Fetch data with a 5-second timeout
// fetchData := readerioresult.FromReader(func(ctx context.Context) Data {
// // Simulate slow operation
// select {
// case <-time.After(10 * time.Second):
// return Data{Value: "slow"}
// case <-ctx.Done():
// return Data{}
// }
// })
//
// result := F.Pipe1(
// fetchData,
// readerioresult.WithTimeout[Data](5*time.Second),
// )
// value, err := result(context.Background())() // Returns (Data{}, context.DeadlineExceeded) after 5s
//
// Successful Example:
//
// quickFetch := readerioresult.Right(Data{Value: "quick"})
// result := F.Pipe1(
// quickFetch,
// readerioresult.WithTimeout[Data](5*time.Second),
// )
// value, err := result(context.Background())() // Returns (Data{Value: "quick"}, nil)
func WithTimeout[A any](timeout time.Duration) Operator[A, A] {
return Local[A](func(ctx context.Context) (context.Context, context.CancelFunc) {
return context.WithTimeout(ctx, timeout)
})
}
// WithDeadline adds an absolute deadline to the context for a ReaderIOResult computation.
//
// This is a convenience wrapper around Local that uses context.WithDeadline.
// The computation must complete before the specified time, or it will be
// cancelled. This is useful for coordinating operations that must finish
// by a specific time, such as request deadlines or scheduled tasks.
//
// The deadline is an absolute time, unlike WithTimeout which uses a relative
// duration. The cancel function is automatically called when the computation
// completes, ensuring proper cleanup. If the deadline passes, the computation
// will receive a context.DeadlineExceeded error.
//
// Type Parameters:
// - A: The value type of the ReaderIOResult
//
// Parameters:
// - deadline: The absolute time by which the computation must complete
//
// Returns:
// - An Operator that runs the computation with a deadline
//
// Example:
//
// import (
// "time"
// F "github.com/IBM/fp-go/v2/function"
// )
//
// // Operation must complete by 3 PM
// deadline := time.Date(2024, 1, 1, 15, 0, 0, 0, time.UTC)
//
// fetchData := readerioresult.FromReader(func(ctx context.Context) Data {
// // Simulate operation
// select {
// case <-time.After(1 * time.Hour):
// return Data{Value: "done"}
// case <-ctx.Done():
// return Data{}
// }
// })
//
// result := F.Pipe1(
// fetchData,
// readerioresult.WithDeadline[Data](deadline),
// )
// value, err := result(context.Background())() // Returns (Data{}, context.DeadlineExceeded) if past deadline
//
// Combining with Parent Context:
//
// // If parent context already has a deadline, the earlier one takes precedence
// parentCtx, cancel := context.WithDeadline(context.Background(), time.Now().Add(1*time.Hour))
// defer cancel()
//
// laterDeadline := time.Now().Add(2 * time.Hour)
// result := F.Pipe1(
// fetchData,
// readerioresult.WithDeadline[Data](laterDeadline),
// )
// value, err := result(parentCtx)() // Will use parent's 1-hour deadline
func WithDeadline[A any](deadline time.Time) Operator[A, A] {
return Local[A](func(ctx context.Context) (context.Context, context.CancelFunc) {
return context.WithDeadline(ctx, deadline)
})
}

14
v2/context/readerioresult/reader_extended_test.go
View File

@@ -567,15 +567,13 @@ func TestMemoize(t *testing.T) {
res1 := computation(context.Background())()
assert.True(t, E.IsRight(res1))
val1 := E.ToOption(res1)
v1, _ := O.Unwrap(val1)
assert.Equal(t, 1, v1)
assert.Equal(t, O.Of(1), val1)
// Second execution should return cached value
res2 := computation(context.Background())()
assert.True(t, E.IsRight(res2))
val2 := E.ToOption(res2)
v2, _ := O.Unwrap(val2)
assert.Equal(t, 1, v2)
assert.Equal(t, O.Of(1), val2)
// Counter should only be incremented once
assert.Equal(t, 1, counter)
@@ -739,9 +737,7 @@ func TestTraverseArray(t *testing.T) {
res := result(context.Background())()
assert.True(t, E.IsRight(res))
arrOpt := E.ToOption(res)
assert.True(t, O.IsSome(arrOpt))
resultArr, _ := O.Unwrap(arrOpt)
assert.Equal(t, []int{2, 4, 6}, resultArr)
assert.Equal(t, O.Of([]int{2, 4, 6}), arrOpt)
})
t.Run("TraverseArray with error", func(t *testing.T) {
@@ -765,9 +761,7 @@ func TestSequenceArray(t *testing.T) {
res := result(context.Background())()
assert.True(t, E.IsRight(res))
arrOpt := E.ToOption(res)
assert.True(t, O.IsSome(arrOpt))
resultArr, _ := O.Unwrap(arrOpt)
assert.Equal(t, []int{1, 2, 3}, resultArr)
assert.Equal(t, O.Of([]int{1, 2, 3}), arrOpt)
}
func TestTraverseRecord(t *testing.T) {

184
v2/context/readerioresult/rec.go Normal file
View File

@@ -0,0 +1,184 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerioresult
import (
"github.com/IBM/fp-go/v2/either"
F "github.com/IBM/fp-go/v2/function"
RIOR "github.com/IBM/fp-go/v2/readerioresult"
)
// TailRec implements stack-safe tail recursion for the context-aware ReaderIOResult monad.
//
// This function enables recursive computations that combine four powerful concepts:
// - Context awareness: Automatic cancellation checking via [context.Context]
// - Environment dependency (Reader aspect): Access to configuration, context, or dependencies
// - Side effects (IO aspect): Logging, file I/O, network calls, etc.
// - Error handling (Either aspect): Computations that can fail with an error
//
// The function uses an iterative loop to execute the recursion, making it safe for deep
// or unbounded recursion without risking stack overflow. Additionally, it integrates
// context cancellation checking through [WithContext], ensuring that recursive computations
// can be cancelled gracefully.
//
// # How It Works
//
// TailRec takes a Kleisli arrow that returns Either[A, B]:
// - Left(A): Continue recursion with the new state A
// - Right(B): Terminate recursion successfully and return the final result B
//
// The function wraps each iteration with [WithContext] to ensure context cancellation
// is checked before each recursive step. If the context is cancelled, the recursion
// terminates early with a context cancellation error.
//
// # Type Parameters
//
// - A: The state type that changes during recursion
// - B: The final result type when recursion terminates successfully
//
// # Parameters
//
// - f: A Kleisli arrow (A => ReaderIOResult[Either[A, B]]) that:
// - Takes the current state A
// - Returns a ReaderIOResult that depends on [context.Context]
// - Can fail with error (Left in the outer Either)
// - Produces Either[A, B] to control recursion flow (Right in the outer Either)
//
// # Returns
//
// A Kleisli arrow (A => ReaderIOResult[B]) that:
// - Takes an initial state A
// - Returns a ReaderIOResult that requires [context.Context]
// - Can fail with error or context cancellation
// - Produces the final result B after recursion completes
//
// # Context Cancellation
//
// Unlike the base [readerioresult.TailRec], this version automatically integrates
// context cancellation checking:
// - Each recursive iteration checks if the context is cancelled
// - If cancelled, recursion terminates immediately with a cancellation error
// - This prevents runaway recursive computations in cancelled contexts
// - Enables responsive cancellation for long-running recursive operations
//
// # Use Cases
//
// 1. Cancellable recursive algorithms:
// - Tree traversals that can be cancelled mid-operation
// - Graph algorithms with timeout requirements
// - Recursive parsers that respect cancellation
//
// 2. Long-running recursive computations:
// - File system traversals with cancellation support
// - Network operations with timeout handling
// - Database operations with connection timeout awareness
//
// 3. Interactive recursive operations:
// - User-initiated operations that can be cancelled
// - Background tasks with cancellation support
// - Streaming operations with graceful shutdown
//
// # Example: Cancellable Countdown
//
// countdownStep := func(n int) readerioresult.ReaderIOResult[either.Either[int, string]] {
// return func(ctx context.Context) ioeither.IOEither[error, either.Either[int, string]] {
// return func() either.Either[error, either.Either[int, string]] {
// if n <= 0 {
// return either.Right[error](either.Right[int]("Done!"))
// }
// // Simulate some work
// time.Sleep(100 * time.Millisecond)
// return either.Right[error](either.Left[string](n - 1))
// }
// }
// }
//
// countdown := readerioresult.TailRec(countdownStep)
//
// // With cancellation
// ctx, cancel := context.WithTimeout(context.Background(), 500*time.Millisecond)
// defer cancel()
// result := countdown(10)(ctx)() // Will be cancelled after ~500ms
//
// # Example: Cancellable File Processing
//
// type ProcessState struct {
// files []string
// processed []string
// }
//
// processStep := func(state ProcessState) readerioresult.ReaderIOResult[either.Either[ProcessState, []string]] {
// return func(ctx context.Context) ioeither.IOEither[error, either.Either[ProcessState, []string]] {
// return func() either.Either[error, either.Either[ProcessState, []string]] {
// if len(state.files) == 0 {
// return either.Right[error](either.Right[ProcessState](state.processed))
// }
//
// file := state.files[0]
// // Process file (this could be cancelled via context)
// if err := processFileWithContext(ctx, file); err != nil {
// return either.Left[either.Either[ProcessState, []string]](err)
// }
//
// return either.Right[error](either.Left[[]string](ProcessState{
// files: state.files[1:],
// processed: append(state.processed, file),
// }))
// }
// }
// }
//
// processFiles := readerioresult.TailRec(processStep)
// ctx, cancel := context.WithCancel(context.Background())
//
// // Can be cancelled at any point during processing
// go func() {
// time.Sleep(2 * time.Second)
// cancel() // Cancel after 2 seconds
// }()
//
// result := processFiles(ProcessState{files: manyFiles})(ctx)()
//
// # Stack Safety
//
// The iterative implementation ensures that even deeply recursive computations
// (thousands or millions of iterations) will not cause stack overflow, while
// still respecting context cancellation:
//
// // Safe for very large inputs with cancellation support
// largeCountdown := readerioresult.TailRec(countdownStep)
// ctx := context.Background()
// result := largeCountdown(1000000)(ctx)() // Safe, no stack overflow
//
// # Performance Considerations
//
// - Each iteration includes context cancellation checking overhead
// - Context checking happens before each recursive step
// - For performance-critical code, consider the cancellation checking cost
// - The [WithContext] wrapper adds minimal overhead for cancellation safety
//
// # See Also
//
// - [readerioresult.TailRec]: Base tail recursion without automatic context checking
// - [WithContext]: Context cancellation wrapper used internally
// - [Chain]: For sequencing ReaderIOResult computations
// - [Ask]: For accessing the context
// - [Left]/[Right]: For creating error/success values
//
//go:inline
func TailRec[A, B any](f Kleisli[A, either.Either[A, B]]) Kleisli[A, B] {
return RIOR.TailRec(F.Flow2(f, WithContext))
}

433
v2/context/readerioresult/rec_test.go Normal file
View File

@@ -0,0 +1,433 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerioresult
import (
"context"
"errors"
"fmt"
"sync/atomic"
"testing"
"time"
A "github.com/IBM/fp-go/v2/array"
E "github.com/IBM/fp-go/v2/either"
"github.com/stretchr/testify/assert"
"github.com/stretchr/testify/require"
)
func TestTailRec_BasicRecursion(t *testing.T) {
// Test basic countdown recursion
countdownStep := func(n int) ReaderIOResult[E.Either[int, string]] {
return func(ctx context.Context) IOEither[E.Either[int, string]] {
return func() Either[E.Either[int, string]] {
if n <= 0 {
return E.Right[error](E.Right[int]("Done!"))
}
return E.Right[error](E.Left[string](n - 1))
}
}
}
countdown := TailRec(countdownStep)
result := countdown(5)(context.Background())()
assert.Equal(t, E.Of[error]("Done!"), result)
}
func TestTailRec_FactorialRecursion(t *testing.T) {
// Test factorial computation using tail recursion
type FactorialState struct {
n int
acc int
}
factorialStep := func(state FactorialState) ReaderIOResult[E.Either[FactorialState, int]] {
return func(ctx context.Context) IOEither[E.Either[FactorialState, int]] {
return func() Either[E.Either[FactorialState, int]] {
if state.n <= 1 {
return E.Right[error](E.Right[FactorialState](state.acc))
}
return E.Right[error](E.Left[int](FactorialState{
n: state.n - 1,
acc: state.acc * state.n,
}))
}
}
}
factorial := TailRec(factorialStep)
result := factorial(FactorialState{n: 5, acc: 1})(context.Background())()
assert.Equal(t, E.Of[error](120), result) // 5! = 120
}
func TestTailRec_ErrorHandling(t *testing.T) {
// Test that errors are properly propagated
testErr := errors.New("computation error")
errorStep := func(n int) ReaderIOResult[E.Either[int, string]] {
return func(ctx context.Context) IOEither[E.Either[int, string]] {
return func() Either[E.Either[int, string]] {
if n == 3 {
return E.Left[E.Either[int, string]](testErr)
}
if n <= 0 {
return E.Right[error](E.Right[int]("Done!"))
}
return E.Right[error](E.Left[string](n - 1))
}
}
}
errorRecursion := TailRec(errorStep)
result := errorRecursion(5)(context.Background())()
assert.True(t, E.IsLeft(result))
err := E.ToError(result)
assert.Equal(t, testErr, err)
}
func TestTailRec_ContextCancellation(t *testing.T) {
// Test that recursion gets cancelled early when context is canceled
var iterationCount int32
slowStep := func(n int) ReaderIOResult[E.Either[int, string]] {
return func(ctx context.Context) IOEither[E.Either[int, string]] {
return func() Either[E.Either[int, string]] {
atomic.AddInt32(&iterationCount, 1)
// Simulate some work
time.Sleep(50 * time.Millisecond)
if n <= 0 {
return E.Right[error](E.Right[int]("Done!"))
}
return E.Right[error](E.Left[string](n - 1))
}
}
}
slowRecursion := TailRec(slowStep)
// Create a context that will be cancelled after 100ms
ctx, cancel := context.WithTimeout(context.Background(), 100*time.Millisecond)
defer cancel()
start := time.Now()
result := slowRecursion(10)(ctx)()
elapsed := time.Since(start)
// Should be cancelled and return an error
assert.True(t, E.IsLeft(result))
// Should complete quickly due to cancellation (much less than 10 * 50ms = 500ms)
assert.Less(t, elapsed, 200*time.Millisecond)
// Should have executed only a few iterations before cancellation
iterations := atomic.LoadInt32(&iterationCount)
assert.Less(t, iterations, int32(5), "Should have been cancelled before completing all iterations")
}
func TestTailRec_ImmediateCancellation(t *testing.T) {
// Test with an already cancelled context
countdownStep := func(n int) ReaderIOResult[E.Either[int, string]] {
return func(ctx context.Context) IOEither[E.Either[int, string]] {
return func() Either[E.Either[int, string]] {
if n <= 0 {
return E.Right[error](E.Right[int]("Done!"))
}
return E.Right[error](E.Left[string](n - 1))
}
}
}
countdown := TailRec(countdownStep)
// Create an already cancelled context
ctx, cancel := context.WithCancel(context.Background())
cancel()
result := countdown(5)(ctx)()
// Should immediately return a cancellation error
assert.True(t, E.IsLeft(result))
err := E.ToError(result)
assert.Equal(t, context.Canceled, err)
}
func TestTailRec_StackSafety(t *testing.T) {
// Test that deep recursion doesn't cause stack overflow
const largeN = 10000
countdownStep := func(n int) ReaderIOResult[E.Either[int, int]] {
return func(ctx context.Context) IOEither[E.Either[int, int]] {
return func() Either[E.Either[int, int]] {
if n <= 0 {
return E.Right[error](E.Right[int](0))
}
return E.Right[error](E.Left[int](n - 1))
}
}
}
countdown := TailRec(countdownStep)
result := countdown(largeN)(context.Background())()
assert.Equal(t, E.Of[error](0), result)
}
func TestTailRec_StackSafetyWithCancellation(t *testing.T) {
// Test stack safety with cancellation after many iterations
const largeN = 100000
var iterationCount int32
countdownStep := func(n int) ReaderIOResult[E.Either[int, int]] {
return func(ctx context.Context) IOEither[E.Either[int, int]] {
return func() Either[E.Either[int, int]] {
atomic.AddInt32(&iterationCount, 1)
// Add a small delay every 1000 iterations to make cancellation more likely
if n%1000 == 0 {
time.Sleep(1 * time.Millisecond)
}
if n <= 0 {
return E.Right[error](E.Right[int](0))
}
return E.Right[error](E.Left[int](n - 1))
}
}
}
countdown := TailRec(countdownStep)
// Cancel after 50ms to allow some iterations but not all
ctx, cancel := context.WithTimeout(context.Background(), 50*time.Millisecond)
defer cancel()
result := countdown(largeN)(ctx)()
// Should be cancelled (or completed if very fast)
// The key is that it doesn't cause a stack overflow
iterations := atomic.LoadInt32(&iterationCount)
assert.Greater(t, iterations, int32(0))
// If it was cancelled, verify it didn't complete all iterations
if E.IsLeft(result) {
assert.Less(t, iterations, int32(largeN))
}
}
func TestTailRec_ComplexState(t *testing.T) {
// Test with more complex state management
type ProcessState struct {
items []string
processed []string
errors []error
}
processStep := func(state ProcessState) ReaderIOResult[E.Either[ProcessState, []string]] {
return func(ctx context.Context) IOEither[E.Either[ProcessState, []string]] {
return func() Either[E.Either[ProcessState, []string]] {
if A.IsEmpty(state.items) {
return E.Right[error](E.Right[ProcessState](state.processed))
}
item := state.items[0]
// Simulate processing that might fail for certain items
if item == "error-item" {
return E.Left[E.Either[ProcessState, []string]](
fmt.Errorf("failed to process item: %s", item))
}
return E.Right[error](E.Left[[]string](ProcessState{
items: state.items[1:],
processed: append(state.processed, item),
errors: state.errors,
}))
}
}
}
processItems := TailRec(processStep)
t.Run("successful processing", func(t *testing.T) {
initialState := ProcessState{
items: []string{"item1", "item2", "item3"},
processed: []string{},
errors: []error{},
}
result := processItems(initialState)(context.Background())()
assert.Equal(t, E.Of[error]([]string{"item1", "item2", "item3"}), result)
})
t.Run("processing with error", func(t *testing.T) {
initialState := ProcessState{
items: []string{"item1", "error-item", "item3"},
processed: []string{},
errors: []error{},
}
result := processItems(initialState)(context.Background())()
assert.True(t, E.IsLeft(result))
err := E.ToError(result)
assert.Contains(t, err.Error(), "failed to process item: error-item")
})
}
func TestTailRec_CancellationDuringProcessing(t *testing.T) {
// Test cancellation during a realistic processing scenario
type FileProcessState struct {
files []string
processed int
}
var processedCount int32
processFileStep := func(state FileProcessState) ReaderIOResult[E.Either[FileProcessState, int]] {
return func(ctx context.Context) IOEither[E.Either[FileProcessState, int]] {
return func() Either[E.Either[FileProcessState, int]] {
if A.IsEmpty(state.files) {
return E.Right[error](E.Right[FileProcessState](state.processed))
}
// Simulate file processing time
time.Sleep(20 * time.Millisecond)
atomic.AddInt32(&processedCount, 1)
return E.Right[error](E.Left[int](FileProcessState{
files: state.files[1:],
processed: state.processed + 1,
}))
}
}
}
processFiles := TailRec(processFileStep)
// Create many files to process
files := make([]string, 20)
for i := range files {
files[i] = fmt.Sprintf("file%d.txt", i)
}
initialState := FileProcessState{
files: files,
processed: 0,
}
// Cancel after 100ms (should allow ~5 files to be processed)
ctx, cancel := context.WithTimeout(context.Background(), 100*time.Millisecond)
defer cancel()
start := time.Now()
result := processFiles(initialState)(ctx)()
elapsed := time.Since(start)
// Should be cancelled
assert.True(t, E.IsLeft(result))
// Should complete quickly due to cancellation
assert.Less(t, elapsed, 150*time.Millisecond)
// Should have processed some but not all files
processed := atomic.LoadInt32(&processedCount)
assert.Greater(t, processed, int32(0))
assert.Less(t, processed, int32(20))
}
func TestTailRec_ZeroIterations(t *testing.T) {
// Test case where recursion terminates immediately
immediateStep := func(n int) ReaderIOResult[E.Either[int, string]] {
return func(ctx context.Context) IOEither[E.Either[int, string]] {
return func() Either[E.Either[int, string]] {
return E.Right[error](E.Right[int]("immediate"))
}
}
}
immediate := TailRec(immediateStep)
result := immediate(100)(context.Background())()
assert.Equal(t, E.Of[error]("immediate"), result)
}
func TestTailRec_ContextWithDeadline(t *testing.T) {
// Test with context deadline
var iterationCount int32
slowStep := func(n int) ReaderIOResult[E.Either[int, string]] {
return func(ctx context.Context) IOEither[E.Either[int, string]] {
return func() Either[E.Either[int, string]] {
atomic.AddInt32(&iterationCount, 1)
time.Sleep(30 * time.Millisecond)
if n <= 0 {
return E.Right[error](E.Right[int]("Done!"))
}
return E.Right[error](E.Left[string](n - 1))
}
}
}
slowRecursion := TailRec(slowStep)
// Set deadline 80ms from now
ctx, cancel := context.WithDeadline(context.Background(), time.Now().Add(80*time.Millisecond))
defer cancel()
result := slowRecursion(10)(ctx)()
// Should be cancelled due to deadline
assert.True(t, E.IsLeft(result))
// Should have executed only a few iterations
iterations := atomic.LoadInt32(&iterationCount)
assert.Greater(t, iterations, int32(0))
assert.Less(t, iterations, int32(5))
}
func TestTailRec_ContextWithValue(t *testing.T) {
// Test that context values are preserved through recursion
type contextKey string
const testKey contextKey = "test"
valueStep := func(n int) ReaderIOResult[E.Either[int, string]] {
return func(ctx context.Context) IOEither[E.Either[int, string]] {
return func() Either[E.Either[int, string]] {
value := ctx.Value(testKey)
require.NotNil(t, value)
assert.Equal(t, "test-value", value.(string))
if n <= 0 {
return E.Right[error](E.Right[int]("Done!"))
}
return E.Right[error](E.Left[string](n - 1))
}
}
}
valueRecursion := TailRec(valueStep)
ctx := context.WithValue(context.Background(), testKey, "test-value")
result := valueRecursion(3)(ctx)()
assert.Equal(t, E.Of[error]("Done!"), result)
}

112
v2/context/readerioresult/resource.go
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@@ -16,7 +16,11 @@
package readerioresult
import (
"context"
"io"
RIOR "github.com/IBM/fp-go/v2/readerioresult"
"github.com/IBM/fp-go/v2/result"
)
// WithResource constructs a function that creates a resource, then operates on it and then releases the resource.
@@ -55,3 +59,111 @@ import (
func WithResource[A, R, ANY any](onCreate ReaderIOResult[R], onRelease Kleisli[R, ANY]) Kleisli[Kleisli[R, A], A] {
return RIOR.WithResource[A](onCreate, onRelease)
}
// onClose is a helper function that creates a ReaderIOResult for closing an io.Closer resource.
// It safely calls the Close() method and handles any errors that may occur during closing.
//
// Type Parameters:
// - A: Must implement io.Closer interface
//
// Parameters:
// - a: The resource to close
//
// Returns:
// - ReaderIOResult[any]: A computation that closes the resource and returns nil on success
//
// The function ignores the context parameter since closing operations typically don't need context.
// Any error from Close() is captured and returned as a Result error.
func onClose[A io.Closer](a A) ReaderIOResult[any] {
return func(_ context.Context) IOResult[any] {
return func() Result[any] {
return result.TryCatchError[any](nil, a.Close())
}
}
}
// WithCloser creates a resource management function specifically for io.Closer resources.
// This is a specialized version of WithResource that automatically handles closing of resources
// that implement the io.Closer interface.
//
// The function ensures that:
// - The resource is created using the onCreate function
// - The resource is automatically closed when the operation completes (success or failure)
// - Any errors during closing are properly handled
// - The resource is closed even if the main operation fails or the context is canceled
//
// Type Parameters:
// - B: The type of value returned by the resource-using function
// - A: The type of resource that implements io.Closer
//
// Parameters:
// - onCreate: ReaderIOResult that creates the io.Closer resource
//
// Returns:
// - A function that takes a resource-using function and returns a ReaderIOResult[B]
//
// Example with file operations:
//
// openFile := func(filename string) ReaderIOResult[*os.File] {
// return TryCatch(func(ctx context.Context) func() (*os.File, error) {
// return func() (*os.File, error) {
// return os.Open(filename)
// }
// })
// }
//
// fileReader := WithCloser(openFile("data.txt"))
// result := fileReader(func(f *os.File) ReaderIOResult[string] {
// return TryCatch(func(ctx context.Context) func() (string, error) {
// return func() (string, error) {
// data, err := io.ReadAll(f)
// return string(data), err
// }
// })
// })
//
// Example with HTTP response:
//
// httpGet := func(url string) ReaderIOResult[*http.Response] {
// return TryCatch(func(ctx context.Context) func() (*http.Response, error) {
// return func() (*http.Response, error) {
// return http.Get(url)
// }
// })
// }
//
// responseReader := WithCloser(httpGet("https://api.example.com/data"))
// result := responseReader(func(resp *http.Response) ReaderIOResult[[]byte] {
// return TryCatch(func(ctx context.Context) func() ([]byte, error) {
// return func() ([]byte, error) {
// return io.ReadAll(resp.Body)
// }
// })
// })
//
// Example with database connection:
//
// openDB := func(dsn string) ReaderIOResult[*sql.DB] {
// return TryCatch(func(ctx context.Context) func() (*sql.DB, error) {
// return func() (*sql.DB, error) {
// return sql.Open("postgres", dsn)
// }
// })
// }
//
// dbQuery := WithCloser(openDB("postgres://..."))
// result := dbQuery(func(db *sql.DB) ReaderIOResult[[]User] {
// return TryCatch(func(ctx context.Context) func() ([]User, error) {
// return func() ([]User, error) {
// rows, err := db.QueryContext(ctx, "SELECT * FROM users")
// if err != nil {
// return nil, err
// }
// defer rows.Close()
// return scanUsers(rows)
// }
// })
// })
func WithCloser[B any, A io.Closer](onCreate ReaderIOResult[A]) Kleisli[Kleisli[A, B], B] {
return WithResource[B](onCreate, onClose[A])
}

179
v2/context/readerioresult/retry.go Normal file
View File

@@ -0,0 +1,179 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache LicensVersion 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerioresult
import (
"context"
"time"
RIO "github.com/IBM/fp-go/v2/context/readerio"
R "github.com/IBM/fp-go/v2/retry"
RG "github.com/IBM/fp-go/v2/retry/generic"
)
// Retrying retries a ReaderIOResult computation according to a retry policy with context awareness.
//
// This function implements a retry mechanism for operations that depend on a [context.Context],
// perform side effects (IO), and can fail (Result). It respects context cancellation, meaning
// that if the context is cancelled during retry delays, the operation will stop immediately
// and return the cancellation error.
//
// The retry loop will continue until one of the following occurs:
// - The action succeeds and the check function returns false (no retry needed)
// - The retry policy returns None (retry limit reached)
// - The check function returns false (indicating success or a non-retryable failure)
// - The context is cancelled (returns context.Canceled or context.DeadlineExceeded)
//
// Parameters:
//
// - policy: A RetryPolicy that determines when and how long to wait between retries.
// The policy receives a RetryStatus on each iteration and returns an optional delay.
// If it returns None, retrying stops. Common policies include LimitRetries,
// ExponentialBackoff, and CapDelay from the retry package.
//
// - action: A Kleisli arrow that takes a RetryStatus and returns a ReaderIOResult[A].
// This function is called on each retry attempt and receives information about the
// current retry state (iteration number, cumulative delay, etc.). The action depends
// on a context.Context and produces a Result[A]. The context passed to the action
// will be the same context used for retry delays, so cancellation is properly propagated.
//
// - check: A predicate function that examines the Result[A] and returns true if the
// operation should be retried, or false if it should stop. This allows you to
// distinguish between retryable failures (e.g., network timeouts) and permanent
// failures (e.g., invalid input). Note that context cancellation errors will
// automatically stop retrying regardless of this function's return value.
//
// Returns:
//
// A ReaderIOResult[A] that, when executed with a context, will perform the retry
// logic with context cancellation support and return the final result.
//
// Type Parameters:
// - A: The type of the success value
//
// Context Cancellation:
//
// The retry mechanism respects context cancellation in two ways:
// 1. During retry delays: If the context is cancelled while waiting between retries,
// the operation stops immediately and returns the context error.
// 2. During action execution: If the action itself checks the context and returns
// an error due to cancellation, the retry loop will stop (assuming the check
// function doesn't force a retry on context errors).
//
// Example:
//
// // Create a retry policy: exponential backoff with a cap, limited to 5 retries
// policy := M.Concat(
// retry.LimitRetries(5),
// retry.CapDelay(10*time.Second, retry.ExponentialBackoff(100*time.Millisecond)),
// )(retry.Monoid)
//
// // Action that fetches data, with retry status information
// fetchData := func(status retry.RetryStatus) ReaderIOResult[string] {
// return func(ctx context.Context) IOResult[string] {
// return func() Result[string] {
// // Check if context is cancelled
// if ctx.Err() != nil {
// return result.Left[string](ctx.Err())
// }
// // Simulate an HTTP request that might fail
// if status.IterNumber < 3 {
// return result.Left[string](fmt.Errorf("temporary error"))
// }
// return result.Of("success")
// }
// }
// }
//
// // Check function: retry on any error except context cancellation
// shouldRetry := func(r Result[string]) bool {
// return result.IsLeft(r) && !errors.Is(result.GetLeft(r), context.Canceled)
// }
//
// // Create the retrying computation
// retryingFetch := Retrying(policy, fetchData, shouldRetry)
//
// // Execute with a cancellable context
// ctx, cancel := context.WithTimeout(context.Background(), 5*time.Second)
// defer cancel()
// ioResult := retryingFetch(ctx)
// finalResult := ioResult()
//
// See also:
// - retry.RetryPolicy for available retry policies
// - retry.RetryStatus for information passed to the action
// - context.Context for context cancellation semantics
//
//go:inline
func Retrying[A any](
policy R.RetryPolicy,
action Kleisli[R.RetryStatus, A],
check func(Result[A]) bool,
) ReaderIOResult[A] {
// delayWithCancel implements a context-aware delay mechanism for retry operations.
// It creates a timeout context that will be cancelled when either:
// 1. The delay duration expires (normal case), or
// 2. The parent context is cancelled (early termination)
//
// The function waits on timeoutCtx.Done(), which will be signaled in either case:
// - If the delay expires, timeoutCtx is cancelled by the timeout
// - If the parent ctx is cancelled, timeoutCtx inherits the cancellation
//
// After the wait completes, we dispatch to the next action by calling ri(ctx)().
// This works correctly because the action is wrapped in WithContextK, which handles
// context cancellation by checking ctx.Err() and returning an appropriate error
// (context.Canceled or context.DeadlineExceeded) when the context is cancelled.
//
// This design ensures that:
// - Retry delays respect context cancellation and terminate immediately
// - The cancellation error propagates correctly through the retry chain
// - No unnecessary delays occur when the context is already cancelled
delayWithCancel := func(delay time.Duration) RIO.Operator[R.RetryStatus, R.RetryStatus] {
return func(ri ReaderIO[R.RetryStatus]) ReaderIO[R.RetryStatus] {
return func(ctx context.Context) IO[R.RetryStatus] {
return func() R.RetryStatus {
// Create a timeout context that will be cancelled when either:
// - The delay duration expires, or
// - The parent context is cancelled
timeoutCtx, cancelTimeout := context.WithTimeout(ctx, delay)
defer cancelTimeout()
// Wait for either the timeout or parent context cancellation
<-timeoutCtx.Done()
// Dispatch to the next action with the original context.
// WithContextK will handle context cancellation correctly.
return ri(ctx)()
}
}
}
}
// get an implementation for the types
return RG.Retrying(
RIO.Chain[Result[A], Result[A]],
RIO.Chain[R.RetryStatus, Result[A]],
RIO.Of[Result[A]],
RIO.Of[R.RetryStatus],
delayWithCancel,
policy,
WithContextK(action),
check,
)
}

511
v2/context/readerioresult/retry_test.go Normal file
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@@ -0,0 +1,511 @@
// Copyright (c) 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerioresult
import (
"context"
"errors"
"fmt"
"testing"
"time"
"github.com/IBM/fp-go/v2/result"
R "github.com/IBM/fp-go/v2/retry"
"github.com/stretchr/testify/assert"
)
// Helper function to create a test retry policy
func testRetryPolicy() R.RetryPolicy {
return R.Monoid.Concat(
R.LimitRetries(5),
R.CapDelay(1*time.Second, R.ExponentialBackoff(10*time.Millisecond)),
)
}
// TestRetrying_SuccessOnFirstAttempt tests that Retrying succeeds immediately
// when the action succeeds on the first attempt.
func TestRetrying_SuccessOnFirstAttempt(t *testing.T) {
policy := testRetryPolicy()
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
return result.Of("success")
}
}
}
check := func(r Result[string]) bool {
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
ctx := t.Context()
res := retrying(ctx)()
assert.Equal(t, result.Of("success"), res)
}
// TestRetrying_SuccessAfterRetries tests that Retrying eventually succeeds
// after a few failed attempts.
func TestRetrying_SuccessAfterRetries(t *testing.T) {
policy := testRetryPolicy()
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
// Fail on first 3 attempts, succeed on 4th
if status.IterNumber < 3 {
return result.Left[string](fmt.Errorf("attempt %d failed", status.IterNumber))
}
return result.Of(fmt.Sprintf("success on attempt %d", status.IterNumber))
}
}
}
check := func(r Result[string]) bool {
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
ctx := t.Context()
res := retrying(ctx)()
assert.Equal(t, result.Of("success on attempt 3"), res)
}
// TestRetrying_ExhaustsRetries tests that Retrying stops after the retry limit
// is reached and returns the last error.
func TestRetrying_ExhaustsRetries(t *testing.T) {
policy := R.LimitRetries(3)
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
return result.Left[string](fmt.Errorf("attempt %d failed", status.IterNumber))
}
}
}
check := func(r Result[string]) bool {
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
ctx := t.Context()
res := retrying(ctx)()
assert.True(t, result.IsLeft(res))
assert.Equal(t, result.Left[string](fmt.Errorf("attempt 3 failed")), res)
}
// TestRetrying_ActionChecksContextCancellation tests that actions can check
// the context and return early if it's cancelled.
func TestRetrying_ActionChecksContextCancellation(t *testing.T) {
policy := R.LimitRetries(10)
attemptCount := 0
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
attemptCount++
// Check context at the start of the action
if ctx.Err() != nil {
return result.Left[string](ctx.Err())
}
// Simulate work that might take time
time.Sleep(10 * time.Millisecond)
// Check context again after work
if ctx.Err() != nil {
return result.Left[string](ctx.Err())
}
// Always fail to trigger retries
return result.Left[string](fmt.Errorf("attempt %d failed", status.IterNumber))
}
}
}
check := func(r Result[string]) bool {
// Don't retry on context errors
val, err := result.Unwrap(r)
_ = val
if err != nil && (errors.Is(err, context.Canceled) || errors.Is(err, context.DeadlineExceeded)) {
return false
}
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
// Create a context that we'll cancel after a short time
ctx, cancel := context.WithCancel(t.Context())
// Start the retry operation in a goroutine
resultChan := make(chan Result[string], 1)
go func() {
res := retrying(ctx)()
resultChan <- res
}()
// Cancel the context after allowing a couple attempts
time.Sleep(50 * time.Millisecond)
cancel()
// Wait for the result
res := <-resultChan
// Should have stopped due to context cancellation
assert.True(t, result.IsLeft(res))
// Should have stopped early (not all 10 attempts)
assert.Less(t, attemptCount, 10, "Should stop retrying when action detects context cancellation")
// The error should be related to context cancellation or an early attempt
val, err := result.Unwrap(res)
_ = val
assert.Error(t, err)
}
// TestRetrying_ContextCancelledBeforeStart tests that if the context is already
// cancelled before starting, the operation fails immediately.
func TestRetrying_ContextCancelledBeforeStart(t *testing.T) {
policy := testRetryPolicy()
attemptCount := 0
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
attemptCount++
// Check context before doing work
if ctx.Err() != nil {
return result.Left[string](ctx.Err())
}
return result.Left[string](fmt.Errorf("attempt %d failed", status.IterNumber))
}
}
}
check := func(r Result[string]) bool {
// Don't retry on context errors
val, err := result.Unwrap(r)
_ = val
if err != nil && errors.Is(err, context.Canceled) {
return false
}
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
// Create an already-cancelled context
ctx, cancel := context.WithCancel(t.Context())
cancel()
res := retrying(ctx)()
assert.True(t, result.IsLeft(res))
val, err := result.Unwrap(res)
_ = val
assert.True(t, errors.Is(err, context.Canceled))
// Should have attempted at most once
assert.LessOrEqual(t, attemptCount, 1)
}
// TestRetrying_ContextTimeoutInAction tests that actions respect context deadlines.
func TestRetrying_ContextTimeoutInAction(t *testing.T) {
policy := R.LimitRetries(10)
attemptCount := 0
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
attemptCount++
// Check context before doing work
if ctx.Err() != nil {
return result.Left[string](ctx.Err())
}
// Simulate some work
time.Sleep(50 * time.Millisecond)
// Check context after work
if ctx.Err() != nil {
return result.Left[string](ctx.Err())
}
// Always fail to trigger retries
return result.Left[string](fmt.Errorf("attempt %d failed", status.IterNumber))
}
}
}
check := func(r Result[string]) bool {
// Don't retry on context errors
val, err := result.Unwrap(r)
_ = val
if err != nil && (errors.Is(err, context.Canceled) || errors.Is(err, context.DeadlineExceeded)) {
return false
}
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
// Create a context with a short timeout
ctx, cancel := context.WithTimeout(t.Context(), 150*time.Millisecond)
defer cancel()
startTime := time.Now()
res := retrying(ctx)()
elapsed := time.Since(startTime)
assert.True(t, result.IsLeft(res))
// Should have stopped before completing all 10 retries
assert.Less(t, attemptCount, 10, "Should stop retrying when action detects context timeout")
// Should have stopped around the timeout duration
assert.Less(t, elapsed, 500*time.Millisecond, "Should stop soon after timeout")
}
// TestRetrying_CheckFunctionStopsRetry tests that the check function can
// stop retrying even when errors occur.
func TestRetrying_CheckFunctionStopsRetry(t *testing.T) {
policy := testRetryPolicy()
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
if status.IterNumber == 0 {
return result.Left[string](fmt.Errorf("retryable error"))
}
return result.Left[string](fmt.Errorf("permanent error"))
}
}
}
// Only retry on "retryable error"
check := func(r Result[string]) bool {
return result.IsLeft(r) && result.Fold(
func(err error) bool { return err.Error() == "retryable error" },
func(string) bool { return false },
)(r)
}
retrying := Retrying(policy, action, check)
ctx := t.Context()
res := retrying(ctx)()
assert.Equal(t, result.Left[string](fmt.Errorf("permanent error")), res)
}
// TestRetrying_ExponentialBackoff tests that exponential backoff is applied.
func TestRetrying_ExponentialBackoff(t *testing.T) {
// Use a policy with measurable delays
policy := R.Monoid.Concat(
R.LimitRetries(3),
R.ExponentialBackoff(50*time.Millisecond),
)
startTime := time.Now()
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
if status.IterNumber < 2 {
return result.Left[string](fmt.Errorf("retry"))
}
return result.Of("success")
}
}
}
check := func(r Result[string]) bool {
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
ctx := t.Context()
res := retrying(ctx)()
elapsed := time.Since(startTime)
assert.Equal(t, result.Of("success"), res)
// With exponential backoff starting at 50ms:
// Iteration 0: no delay
// Iteration 1: 50ms delay
// Iteration 2: 100ms delay
// Total should be at least 150ms
assert.GreaterOrEqual(t, elapsed, 150*time.Millisecond)
}
// TestRetrying_ContextValuePropagation tests that context values are properly
// propagated through the retry mechanism.
func TestRetrying_ContextValuePropagation(t *testing.T) {
policy := R.LimitRetries(2)
type contextKey string
const requestIDKey contextKey = "requestID"
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
// Extract value from context
requestID, ok := ctx.Value(requestIDKey).(string)
if !ok {
return result.Left[string](fmt.Errorf("missing request ID"))
}
if status.IterNumber < 1 {
return result.Left[string](fmt.Errorf("retry needed"))
}
return result.Of(fmt.Sprintf("processed request %s", requestID))
}
}
}
check := func(r Result[string]) bool {
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
// Create context with a value
ctx := context.WithValue(t.Context(), requestIDKey, "12345")
res := retrying(ctx)()
assert.Equal(t, result.Of("processed request 12345"), res)
}
// TestRetrying_RetryStatusProgression tests that the RetryStatus is properly
// updated on each iteration.
func TestRetrying_RetryStatusProgression(t *testing.T) {
policy := testRetryPolicy()
var iterations []uint
action := func(status R.RetryStatus) ReaderIOResult[int] {
return func(ctx context.Context) IOResult[int] {
return func() Result[int] {
iterations = append(iterations, status.IterNumber)
if status.IterNumber < 3 {
return result.Left[int](fmt.Errorf("retry"))
}
return result.Of(int(status.IterNumber))
}
}
}
check := func(r Result[int]) bool {
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
ctx := t.Context()
res := retrying(ctx)()
assert.Equal(t, result.Of(3), res)
// Should have attempted iterations 0, 1, 2, 3
assert.Equal(t, []uint{0, 1, 2, 3}, iterations)
}
// TestRetrying_ContextCancelledDuringDelay tests that the retry operation
// stops immediately when the context is cancelled during a retry delay,
// even if there are still retries remaining according to the policy.
func TestRetrying_ContextCancelledDuringDelay(t *testing.T) {
// Use a policy with significant delays to ensure we can cancel during the delay
policy := R.Monoid.Concat(
R.LimitRetries(10),
R.ConstantDelay(200*time.Millisecond),
)
attemptCount := 0
action := func(status R.RetryStatus) ReaderIOResult[string] {
return func(ctx context.Context) IOResult[string] {
return func() Result[string] {
attemptCount++
// Always fail to trigger retries
return result.Left[string](fmt.Errorf("attempt %d failed", status.IterNumber))
}
}
}
// Always retry on errors (don't check for context cancellation in check function)
check := func(r Result[string]) bool {
return result.IsLeft(r)
}
retrying := Retrying(policy, action, check)
// Create a context that we'll cancel during the retry delay
ctx, cancel := context.WithCancel(t.Context())
// Start the retry operation in a goroutine
resultChan := make(chan Result[string], 1)
startTime := time.Now()
go func() {
res := retrying(ctx)()
resultChan <- res
}()
// Wait for the first attempt to complete and the delay to start
time.Sleep(50 * time.Millisecond)
// Cancel the context during the retry delay
cancel()
// Wait for the result
res := <-resultChan
elapsed := time.Since(startTime)
// Should have stopped due to context cancellation
assert.True(t, result.IsLeft(res))
// Should have attempted only once or twice (not all 10 attempts)
// because the context was cancelled during the delay
assert.LessOrEqual(t, attemptCount, 2, "Should stop retrying when context is cancelled during delay")
// Should have stopped quickly after cancellation, not waiting for all delays
// With 10 retries and 200ms delays, it would take ~2 seconds without cancellation
// With cancellation during first delay, it should complete in well under 500ms
assert.Less(t, elapsed, 500*time.Millisecond, "Should stop immediately when context is cancelled during delay")
// When context is cancelled during the delay, the retry mechanism
// detects the cancellation and returns a context error
val, err := result.Unwrap(res)
_ = val
assert.Error(t, err)
// The error should be a context cancellation error since cancellation
// happened during the delay between retries
assert.True(t, errors.Is(err, context.Canceled), "Should return context.Canceled when cancelled during delay")
}

21
v2/context/readerioresult/traverse.go
View File

@@ -18,6 +18,7 @@ package readerioresult
import (
"github.com/IBM/fp-go/v2/array"
"github.com/IBM/fp-go/v2/function"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/internal/record"
)
@@ -34,7 +35,7 @@ func TraverseArray[A, B any](f Kleisli[A, B]) Kleisli[[]A, []B] {
Map[[]B, func(B) []B],
Ap[[]B, B],
f,
F.Flow2(f, WithContext),
)
}
@@ -78,7 +79,7 @@ func TraverseRecord[K comparable, A, B any](f Kleisli[A, B]) Kleisli[map[K]A, ma
Map[map[K]B, func(B) map[K]B],
Ap[map[K]B, B],
f,
F.Flow2(f, WithContext),
)
}
@@ -123,7 +124,7 @@ func MonadTraverseArraySeq[A, B any](as []A, f Kleisli[A, B]) ReaderIOResult[[]B
Map[[]B, func(B) []B],
ApSeq[[]B, B],
as,
f,
F.Flow2(f, WithContext),
)
}
@@ -139,7 +140,7 @@ func TraverseArraySeq[A, B any](f Kleisli[A, B]) Kleisli[[]A, []B] {
Of[[]B],
Map[[]B, func(B) []B],
ApSeq[[]B, B],
f,
F.Flow2(f, WithContext),
)
}
@@ -171,7 +172,7 @@ func MonadTraverseRecordSeq[K comparable, A, B any](as map[K]A, f Kleisli[A, B])
Map[map[K]B, func(B) map[K]B],
ApSeq[map[K]B, B],
as,
f,
F.Flow2(f, WithContext),
)
}
@@ -182,7 +183,7 @@ func TraverseRecordSeq[K comparable, A, B any](f Kleisli[A, B]) Kleisli[map[K]A,
Map[map[K]B, func(B) map[K]B],
ApSeq[map[K]B, B],
f,
F.Flow2(f, WithContext),
)
}
@@ -216,7 +217,7 @@ func MonadTraverseArrayPar[A, B any](as []A, f Kleisli[A, B]) ReaderIOResult[[]B
Map[[]B, func(B) []B],
ApPar[[]B, B],
as,
f,
F.Flow2(f, WithContext),
)
}
@@ -232,7 +233,7 @@ func TraverseArrayPar[A, B any](f Kleisli[A, B]) Kleisli[[]A, []B] {
Of[[]B],
Map[[]B, func(B) []B],
ApPar[[]B, B],
f,
F.Flow2(f, WithContext),
)
}
@@ -264,7 +265,7 @@ func TraverseRecordPar[K comparable, A, B any](f Kleisli[A, B]) Kleisli[map[K]A,
Map[map[K]B, func(B) map[K]B],
ApPar[map[K]B, B],
f,
F.Flow2(f, WithContext),
)
}
@@ -286,7 +287,7 @@ func MonadTraverseRecordPar[K comparable, A, B any](as map[K]A, f Kleisli[A, B])
Map[map[K]B, func(B) map[K]B],
ApPar[map[K]B, B],
as,
f,
F.Flow2(f, WithContext),
)
}

11
v2/context/readerioresult/type.go
View File

@@ -18,12 +18,16 @@ package readerioresult
import (
"context"
"github.com/IBM/fp-go/v2/consumer"
"github.com/IBM/fp-go/v2/context/ioresult"
"github.com/IBM/fp-go/v2/context/readerresult"
"github.com/IBM/fp-go/v2/either"
"github.com/IBM/fp-go/v2/endomorphism"
"github.com/IBM/fp-go/v2/io"
"github.com/IBM/fp-go/v2/ioeither"
"github.com/IBM/fp-go/v2/lazy"
"github.com/IBM/fp-go/v2/optics/lens"
"github.com/IBM/fp-go/v2/optics/prism"
"github.com/IBM/fp-go/v2/option"
"github.com/IBM/fp-go/v2/reader"
"github.com/IBM/fp-go/v2/readereither"
@@ -126,4 +130,11 @@ type (
ReaderResult[A any] = readerresult.ReaderResult[A]
ReaderEither[R, E, A any] = readereither.ReaderEither[R, E, A]
ReaderOption[R, A any] = readeroption.ReaderOption[R, A]
Endomorphism[A any] = endomorphism.Endomorphism[A]
Consumer[A any] = consumer.Consumer[A]
Prism[S, T any] = prism.Prism[S, T]
Lens[S, T any] = lens.Lens[S, T]
)

7
v2/context/readerresult/array.go
View File

@@ -15,11 +15,14 @@
package readerresult
import "github.com/IBM/fp-go/v2/readereither"
import (
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/readereither"
)
// TraverseArray transforms an array
func TraverseArray[A, B any](f Kleisli[A, B]) Kleisli[[]A, []B] {
return readereither.TraverseArray(f)
return readereither.TraverseArray(F.Flow2(f, WithContext))
}
// TraverseArrayWithIndex transforms an array

89
v2/context/readerresult/bind.go
View File

@@ -17,7 +17,6 @@ package readerresult
import (
F "github.com/IBM/fp-go/v2/function"
L "github.com/IBM/fp-go/v2/optics/lens"
G "github.com/IBM/fp-go/v2/readereither/generic"
)
@@ -31,16 +30,26 @@ import (
// TenantID string
// }
// result := readereither.Do(State{})
//
//go:inline
func Do[S any](
empty S,
) ReaderResult[S] {
return G.Do[ReaderResult[S]](empty)
}
// Bind attaches the result of a computation to a context [S1] to produce a context [S2].
// Bind attaches the result of an EFFECTFUL computation to a context [S1] to produce a context [S2].
// This enables sequential composition where each step can depend on the results of previous steps
// and access the context.Context from the environment.
//
// IMPORTANT: Bind is for EFFECTFUL FUNCTIONS that depend on context.Context.
// The function parameter takes state and returns a ReaderResult[T], which is effectful because
// it depends on context.Context (can be cancelled, has deadlines, carries values).
//
// For PURE FUNCTIONS (side-effect free), use:
// - BindResultK: For pure functions with errors (State -> (Value, error))
// - Let: For pure functions without errors (State -> Value)
//
// The setter function takes the result of the computation and returns a function that
// updates the context from S1 to S2.
//
@@ -78,14 +87,27 @@ func Do[S any](
// },
// ),
// )
//
//go:inline
func Bind[S1, S2, T any](
setter func(T) func(S1) S2,
f Kleisli[S1, T],
) Kleisli[ReaderResult[S1], S2] {
return G.Bind[ReaderResult[S1], ReaderResult[S2]](setter, f)
return G.Bind[ReaderResult[S1], ReaderResult[S2]](setter, F.Flow2(f, WithContext))
}
// Let attaches the result of a computation to a context [S1] to produce a context [S2]
// Let attaches the result of a PURE computation to a context [S1] to produce a context [S2].
//
// IMPORTANT: Let is for PURE FUNCTIONS (side-effect free) that don't depend on context.Context.
// The function parameter takes state and returns a value directly, with no errors or effects.
//
// For EFFECTFUL FUNCTIONS (that need context.Context), use:
// - Bind: For effectful ReaderResult computations (State -> ReaderResult[Value])
//
// For PURE FUNCTIONS with error handling, use:
// - BindResultK: For pure functions with errors (State -> (Value, error))
//
//go:inline
func Let[S1, S2, T any](
setter func(T) func(S1) S2,
f func(S1) T,
@@ -93,7 +115,10 @@ func Let[S1, S2, T any](
return G.Let[ReaderResult[S1], ReaderResult[S2]](setter, f)
}
// LetTo attaches the a value to a context [S1] to produce a context [S2]
// LetTo attaches a constant value to a context [S1] to produce a context [S2].
// This is a PURE operation (side-effect free) that simply sets a field to a constant value.
//
//go:inline
func LetTo[S1, S2, T any](
setter func(T) func(S1) S2,
b T,
@@ -102,15 +127,27 @@ func LetTo[S1, S2, T any](
}
// BindTo initializes a new state [S1] from a value [T]
//
//go:inline
func BindTo[S1, T any](
setter func(T) S1,
) Kleisli[ReaderResult[T], S1] {
) Operator[T, S1] {
return G.BindTo[ReaderResult[S1], ReaderResult[T]](setter)
}
//go:inline
func BindToP[S1, T any](
setter Prism[S1, T],
) Operator[T, S1] {
return BindTo(setter.ReverseGet)
}
// ApS attaches a value to a context [S1] to produce a context [S2] by considering
// the context and the value concurrently (using Applicative rather than Monad).
// This allows independent computations to be combined without one depending on the result of the other.
// This allows independent EFFECTFUL computations to be combined without one depending on the result of the other.
//
// IMPORTANT: ApS is for EFFECTFUL FUNCTIONS that depend on context.Context.
// The ReaderResult parameter is effectful because it depends on context.Context.
//
// Unlike Bind, which sequences operations, ApS can be used when operations are independent
// and can conceptually run in parallel.
@@ -145,6 +182,8 @@ func BindTo[S1, T any](
// getTenantID,
// ),
// )
//
//go:inline
func ApS[S1, S2, T any](
setter func(T) func(S1) S2,
fa ReaderResult[T],
@@ -183,17 +222,24 @@ func ApS[S1, S2, T any](
// readereither.Do(Person{Name: "Alice", Age: 25}),
// readereither.ApSL(ageLens, getAge),
// )
//
//go:inline
func ApSL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
fa ReaderResult[T],
) Kleisli[ReaderResult[S], S] {
return ApS(lens.Set, fa)
}
// BindL is a variant of Bind that uses a lens to focus on a specific field in the state.
// It combines the lens-based field access with monadic composition, allowing you to:
// It combines the lens-based field access with monadic composition for EFFECTFUL computations.
//
// IMPORTANT: BindL is for EFFECTFUL FUNCTIONS that depend on context.Context.
// The function parameter returns a ReaderResult, which is effectful.
//
// It allows you to:
// 1. Extract a field value using the lens
// 2. Use that value in a computation that may fail
// 2. Use that value in an effectful computation that may fail
// 3. Update the field with the result
//
// Parameters:
@@ -227,15 +273,20 @@ func ApSL[S, T any](
// readereither.Of[error](Counter{Value: 42}),
// readereither.BindL(valueLens, increment),
// )
//
//go:inline
func BindL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
f Kleisli[T, T],
) Kleisli[ReaderResult[S], S] {
return Bind(lens.Set, F.Flow2(lens.Get, f))
return Bind(lens.Set, F.Flow2(lens.Get, F.Flow2(f, WithContext)))
}
// LetL is a variant of Let that uses a lens to focus on a specific field in the state.
// It applies a pure transformation to the focused field without any effects.
// It applies a PURE transformation to the focused field without any effects.
//
// IMPORTANT: LetL is for PURE FUNCTIONS (side-effect free) that don't depend on context.Context.
// The function parameter is a pure endomorphism (T -> T) with no errors or effects.
//
// Parameters:
// - lens: A lens that focuses on a field of type T within state S
@@ -262,15 +313,17 @@ func BindL[S, T any](
// readereither.LetL(valueLens, double),
// )
// // result when executed will be Right(Counter{Value: 42})
//
//go:inline
func LetL[S, T any](
lens L.Lens[S, T],
f func(T) T,
lens Lens[S, T],
f Endomorphism[T],
) Kleisli[ReaderResult[S], S] {
return Let(lens.Set, F.Flow2(lens.Get, f))
}
// LetToL is a variant of LetTo that uses a lens to focus on a specific field in the state.
// It sets the focused field to a constant value.
// It sets the focused field to a constant value. This is a PURE operation (side-effect free).
//
// Parameters:
// - lens: A lens that focuses on a field of type T within state S
@@ -296,8 +349,10 @@ func LetL[S, T any](
// readereither.LetToL(debugLens, false),
// )
// // result when executed will be Right(Config{Debug: false, Timeout: 30})
//
//go:inline
func LetToL[S, T any](
lens L.Lens[S, T],
lens Lens[S, T],
b T,
) Kleisli[ReaderResult[S], S] {
return LetTo(lens.Set, b)

13
v2/context/readerresult/cancel.go
View File

@@ -19,14 +19,23 @@ import (
"context"
E "github.com/IBM/fp-go/v2/either"
F "github.com/IBM/fp-go/v2/function"
)
// withContext wraps an existing ReaderResult and performs a context check for cancellation before deletating
func WithContext[A any](ma ReaderResult[A]) ReaderResult[A] {
return func(ctx context.Context) E.Either[error, A] {
if err := context.Cause(ctx); err != nil {
return E.Left[A](err)
if ctx.Err() != nil {
return E.Left[A](context.Cause(ctx))
}
return ma(ctx)
}
}
//go:inline
func WithContextK[A, B any](f Kleisli[A, B]) Kleisli[A, B] {
return F.Flow2(
f,
WithContext,
)
}

154
v2/context/readerresult/flip.go Normal file
View File

@@ -0,0 +1,154 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"github.com/IBM/fp-go/v2/reader"
RR "github.com/IBM/fp-go/v2/readerresult"
)
// SequenceReader swaps the order of environment parameters when the inner computation is a Reader.
//
// This function is specialized for the context.Context-based ReaderResult monad. It takes a
// ReaderResult that produces a Reader and returns a reader.Kleisli that produces Results.
// The context.Context is implicitly used as the outer environment type.
//
// Type Parameters:
// - R: The inner environment type (becomes outer after flip)
// - A: The success value type
//
// Parameters:
// - ma: A ReaderResult that takes context.Context and may produce a Reader[R, A]
//
// Returns:
// - A reader.Kleisli[context.Context, R, Result[A]], which is func(context.Context) func(R) Result[A]
//
// The function preserves error handling from the outer ReaderResult layer. If the outer
// computation fails, the error is propagated to the inner Result.
//
// Note: This is an inline wrapper around readerresult.SequenceReader, specialized for
// context.Context as the outer environment type.
//
// Example:
//
// type Database struct {
// ConnectionString string
// }
//
// // Original: takes context, may fail, produces Reader[Database, string]
// original := func(ctx context.Context) result.Result[reader.Reader[Database, string]] {
// if ctx.Err() != nil {
// return result.Error[reader.Reader[Database, string]](ctx.Err())
// }
// return result.Ok[error](func(db Database) string {
// return fmt.Sprintf("Query on %s", db.ConnectionString)
// })
// }
//
// // Sequenced: takes context first, then Database
// sequenced := SequenceReader(original)
//
// ctx := context.Background()
// db := Database{ConnectionString: "localhost:5432"}
//
// // Apply context first to get a function that takes database
// dbReader := sequenced(ctx)
// // Then apply database to get the final result
// result := dbReader(db)
// // result is Result[string]
//
// Use Cases:
// - Dependency injection: Flip parameter order to inject context first, then dependencies
// - Testing: Separate context handling from business logic for easier testing
// - Composition: Enable point-free style by fixing the context parameter first
//
//go:inline
func SequenceReader[R, A any](ma ReaderResult[Reader[R, A]]) reader.Kleisli[context.Context, R, Result[A]] {
return RR.SequenceReader(ma)
}
// TraverseReader transforms a value using a Reader function and swaps environment parameter order.
//
// This function combines mapping and parameter flipping in a single operation. It takes a
// Reader function (pure computation without error handling) and returns a function that:
// 1. Maps a ReaderResult[A] to ReaderResult[B] using the provided Reader function
// 2. Flips the parameter order so R comes before context.Context
//
// Type Parameters:
// - R: The inner environment type (becomes outer after flip)
// - A: The input value type
// - B: The output value type
//
// Parameters:
// - f: A reader.Kleisli[R, A, B], which is func(R) func(A) B - a pure Reader function
//
// Returns:
// - A function that takes ReaderResult[A] and returns Kleisli[R, B]
// - Kleisli[R, B] is func(R) ReaderResult[B], which is func(R) func(context.Context) Result[B]
//
// The function preserves error handling from the input ReaderResult. If the input computation
// fails, the error is propagated without applying the transformation function.
//
// Note: This is a wrapper around readerresult.TraverseReader, specialized for context.Context.
//
// Example:
//
// type Config struct {
// MaxRetries int
// }
//
// // A pure Reader function that depends on Config
// formatMessage := func(cfg Config) func(int) string {
// return func(value int) string {
// return fmt.Sprintf("Value: %d, MaxRetries: %d", value, cfg.MaxRetries)
// }
// }
//
// // Original computation that may fail
// computation := func(ctx context.Context) result.Result[int] {
// if ctx.Err() != nil {
// return result.Error[int](ctx.Err())
// }
// return result.Ok[error](42)
// }
//
// // Create a traversal that applies formatMessage and flips parameters
// traverse := TraverseReader[Config, int, string](formatMessage)
//
// // Apply to the computation
// flipped := traverse(computation)
//
// // Now we can provide Config first, then context
// cfg := Config{MaxRetries: 3}
// ctx := context.Background()
//
// result := flipped(cfg)(ctx)
// // result is Result[string] containing "Value: 42, MaxRetries: 3"
//
// Use Cases:
// - Dependency injection: Inject configuration/dependencies before context
// - Testing: Separate pure business logic from context handling
// - Composition: Build pipelines where dependencies are fixed before execution
// - Point-free style: Enable partial application by fixing dependencies first
//
//go:inline
func TraverseReader[R, A, B any](
f reader.Kleisli[R, A, B],
) func(ReaderResult[A]) Kleisli[R, B] {
return RR.TraverseReader[context.Context](f)
}

215
v2/context/readerresult/logging.go Normal file
View File

@@ -0,0 +1,215 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package readerresult provides logging utilities for the ReaderResult monad,
// which combines the Reader monad (for dependency injection via context.Context)
// with the Result monad (for error handling).
//
// The logging functions in this package allow you to log Result values (both
// successes and errors) while preserving the functional composition style.
package readerresult
import (
"context"
"log/slog"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/logging"
"github.com/IBM/fp-go/v2/reader"
"github.com/IBM/fp-go/v2/result"
)
// curriedLog creates a curried logging function that takes an slog.Attr and a context,
// then logs the attribute with the specified log level and message.
//
// This is an internal helper function used to create the logging pipeline in a
// point-free style. The currying allows for partial application in functional
// composition.
//
// Parameters:
// - logLevel: The slog.Level at which to log (e.g., LevelInfo, LevelError)
// - cb: A callback function that retrieves a logger from the context
// - message: The log message to display
//
// Returns:
// - A curried function that takes an slog.Attr, then a context, and performs logging
func curriedLog(
logLevel slog.Level,
cb func(context.Context) *slog.Logger,
message string) func(slog.Attr) Reader[context.Context, struct{}] {
return F.Curry2(func(a slog.Attr, ctx context.Context) struct{} {
cb(ctx).LogAttrs(ctx, logLevel, message, a)
return struct{}{}
})
}
// SLogWithCallback creates a Kleisli arrow that logs a Result value using a custom
// logger callback and log level. The Result value is logged and then returned unchanged,
// making this function suitable for use in functional pipelines.
//
// This function logs both successful values and errors:
// - Success values are logged with the key "value"
// - Error values are logged with the key "error"
//
// The logging is performed as a side effect while preserving the Result value,
// allowing it to be used in the middle of a computation pipeline without
// interrupting the flow.
//
// Type Parameters:
// - A: The type of the success value in the Result
//
// Parameters:
// - logLevel: The slog.Level at which to log (e.g., LevelInfo, LevelDebug, LevelError)
// - cb: A callback function that retrieves a *slog.Logger from the context
// - message: The log message to display
//
// Returns:
// - A Kleisli arrow that takes a Result[A] and returns a ReaderResult[A]
// The returned ReaderResult, when executed with a context, logs the Result
// and returns it unchanged
//
// Example:
//
// type User struct {
// ID int
// Name string
// }
//
// // Custom logger callback
// getLogger := func(ctx context.Context) *slog.Logger {
// return slog.Default()
// }
//
// // Create a logging function for debug level
// logDebug := SLogWithCallback[User](slog.LevelDebug, getLogger, "User data")
//
// // Use in a pipeline
// ctx := context.Background()
// user := result.Of(User{ID: 123, Name: "Alice"})
// logged := logDebug(user)(ctx) // Logs: level=DEBUG msg="User data" value={ID:123 Name:Alice}
// // logged still contains the User value
//
// Example with error:
//
// err := errors.New("user not found")
// userResult := result.Left[User](err)
// logged := logDebug(userResult)(ctx) // Logs: level=DEBUG msg="User data" error="user not found"
// // logged still contains the error
func SLogWithCallback[A any](
logLevel slog.Level,
cb func(context.Context) *slog.Logger,
message string) Kleisli[Result[A], A] {
return F.Pipe1(
F.Flow2(
result.ToSLogAttr[A](),
curriedLog(logLevel, cb, message),
),
reader.Chain(reader.Sequence(F.Flow2( // this flow is basically the `MapTo` function with side effects
reader.Of[struct{}, Result[A]],
reader.Map[context.Context, struct{}, Result[A]],
))),
)
}
// SLog creates a Kleisli arrow that logs a Result value at INFO level using the
// logger from the context. This is a convenience function that uses SLogWithCallback
// with default settings.
//
// The Result value is logged and then returned unchanged, making this function
// suitable for use in functional pipelines for debugging or monitoring purposes.
//
// This function logs both successful values and errors:
// - Success values are logged with the key "value"
// - Error values are logged with the key "error"
//
// Type Parameters:
// - A: The type of the success value in the Result
//
// Parameters:
// - message: The log message to display
//
// Returns:
// - A Kleisli arrow that takes a Result[A] and returns a ReaderResult[A]
// The returned ReaderResult, when executed with a context, logs the Result
// at INFO level and returns it unchanged
//
// Example - Logging a successful computation:
//
// ctx := context.Background()
//
// // Simple value logging
// res := result.Of(42)
// logged := SLog[int]("Processing number")(res)(ctx)
// // Logs: level=INFO msg="Processing number" value=42
// // logged == result.Of(42)
//
// Example - Logging in a pipeline:
//
// type User struct {
// ID int
// Name string
// }
//
// fetchUser := func(id int) result.Result[User] {
// return result.Of(User{ID: id, Name: "Alice"})
// }
//
// processUser := func(user User) result.Result[string] {
// return result.Of(fmt.Sprintf("Processed: %s", user.Name))
// }
//
// ctx := context.Background()
//
// // Log at each step
// userResult := fetchUser(123)
// logged1 := SLog[User]("Fetched user")(userResult)(ctx)
// // Logs: level=INFO msg="Fetched user" value={ID:123 Name:Alice}
//
// processed := result.Chain(processUser)(logged1)
// logged2 := SLog[string]("Processed user")(processed)(ctx)
// // Logs: level=INFO msg="Processed user" value="Processed: Alice"
//
// Example - Logging errors:
//
// err := errors.New("database connection failed")
// errResult := result.Left[User](err)
// logged := SLog[User]("Database operation")(errResult)(ctx)
// // Logs: level=INFO msg="Database operation" error="database connection failed"
// // logged still contains the error
//
// Example - Using with context logger:
//
// // Set up a custom logger in the context
// logger := slog.New(slog.NewJSONHandler(os.Stdout, nil))
// ctx := logging.WithLogger(logger)(context.Background())
//
// res := result.Of("important data")
// logged := SLog[string]("Critical operation")(res)(ctx)
// // Uses the logger from context to log the message
//
// Note: The function uses logging.GetLoggerFromContext to retrieve the logger,
// which falls back to the global logger if no logger is found in the context.
//
//go:inline
func SLog[A any](message string) Kleisli[Result[A], A] {
return SLogWithCallback[A](slog.LevelInfo, logging.GetLoggerFromContext, message)
}
//go:inline
func TapSLog[A any](message string) Operator[A, A] {
return reader.Chain(SLog[A](message))
}

302
v2/context/readerresult/logging_test.go Normal file
View File

@@ -0,0 +1,302 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"bytes"
"context"
"errors"
"log/slog"
"testing"
"github.com/IBM/fp-go/v2/logging"
N "github.com/IBM/fp-go/v2/number"
"github.com/IBM/fp-go/v2/result"
"github.com/stretchr/testify/assert"
)
// TestSLogLogsSuccessValue tests that SLog logs successful Result values
func TestSLogLogsSuccessValue(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
// Create a Result and log it
res1 := result.Of(42)
logged := SLog[int]("Result value")(res1)(ctx)
assert.Equal(t, result.Of(42), logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "Result value")
assert.Contains(t, logOutput, "value=42")
}
// TestSLogLogsErrorValue tests that SLog logs error Result values
func TestSLogLogsErrorValue(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
testErr := errors.New("test error")
// Create an error Result and log it
res1 := result.Left[int](testErr)
logged := SLog[int]("Result value")(res1)(ctx)
assert.Equal(t, res1, logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "Result value")
assert.Contains(t, logOutput, "error")
assert.Contains(t, logOutput, "test error")
}
// TestSLogInPipeline tests SLog in a functional pipeline
func TestSLogInPipeline(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
// SLog takes a Result[A] and returns ReaderResult[A]
// So we need to start with a Result, apply SLog, then execute with context
res1 := result.Of(10)
logged := SLog[int]("Initial value")(res1)(ctx)
assert.Equal(t, result.Of(10), logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "Initial value")
assert.Contains(t, logOutput, "value=10")
}
// TestSLogWithContextLogger tests SLog using logger from context
func TestSLogWithContextLogger(t *testing.T) {
var buf bytes.Buffer
contextLogger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
ctx := logging.WithLogger(contextLogger)(context.Background())
res1 := result.Of("test value")
logged := SLog[string]("Context logger test")(res1)(ctx)
assert.Equal(t, result.Of("test value"), logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "Context logger test")
assert.Contains(t, logOutput, `value="test value"`)
}
// TestSLogDisabled tests that SLog respects logger level
func TestSLogDisabled(t *testing.T) {
var buf bytes.Buffer
// Create logger with level that disables info logs
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelError, // Only log errors
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
res1 := result.Of(42)
logged := SLog[int]("This should not be logged")(res1)(ctx)
assert.Equal(t, result.Of(42), logged)
// Should have no logs since level is ERROR
logOutput := buf.String()
assert.Empty(t, logOutput, "Should have no logs when logging is disabled")
}
// TestSLogWithStruct tests SLog with structured data
func TestSLogWithStruct(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
type User struct {
ID int
Name string
}
ctx := context.Background()
user := User{ID: 123, Name: "Alice"}
res1 := result.Of(user)
logged := SLog[User]("User data")(res1)(ctx)
assert.Equal(t, result.Of(user), logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "User data")
assert.Contains(t, logOutput, "ID:123")
assert.Contains(t, logOutput, "Name:Alice")
}
// TestSLogWithCallbackCustomLevel tests SLogWithCallback with custom log level
func TestSLogWithCallbackCustomLevel(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelDebug,
}))
customCallback := func(ctx context.Context) *slog.Logger {
return logger
}
ctx := context.Background()
// Create a Result and log it with custom callback
res1 := result.Of(42)
logged := SLogWithCallback[int](slog.LevelDebug, customCallback, "Debug result")(res1)(ctx)
assert.Equal(t, result.Of(42), logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "Debug result")
assert.Contains(t, logOutput, "value=42")
assert.Contains(t, logOutput, "level=DEBUG")
}
// TestSLogWithCallbackLogsError tests SLogWithCallback logs errors
func TestSLogWithCallbackLogsError(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelWarn,
}))
customCallback := func(ctx context.Context) *slog.Logger {
return logger
}
ctx := context.Background()
testErr := errors.New("warning error")
// Create an error Result and log it with custom callback
res1 := result.Left[int](testErr)
logged := SLogWithCallback[int](slog.LevelWarn, customCallback, "Warning result")(res1)(ctx)
assert.Equal(t, res1, logged)
logOutput := buf.String()
assert.Contains(t, logOutput, "Warning result")
assert.Contains(t, logOutput, "error")
assert.Contains(t, logOutput, "warning error")
assert.Contains(t, logOutput, "level=WARN")
}
// TestSLogChainedOperations tests SLog in chained operations
func TestSLogChainedOperations(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
// First log step 1
res1 := result.Of(5)
logged1 := SLog[int]("Step 1")(res1)(ctx)
// Then log step 2 with doubled value
res2 := result.Map(N.Mul(2))(logged1)
logged2 := SLog[int]("Step 2")(res2)(ctx)
assert.Equal(t, result.Of(10), logged2)
logOutput := buf.String()
assert.Contains(t, logOutput, "Step 1")
assert.Contains(t, logOutput, "value=5")
assert.Contains(t, logOutput, "Step 2")
assert.Contains(t, logOutput, "value=10")
}
// TestSLogPreservesError tests that SLog preserves error through the pipeline
func TestSLogPreservesError(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
testErr := errors.New("original error")
res1 := result.Left[int](testErr)
logged := SLog[int]("Logging error")(res1)(ctx)
// Apply map to verify error is preserved
res2 := result.Map(N.Mul(2))(logged)
assert.Equal(t, res1, res2)
logOutput := buf.String()
assert.Contains(t, logOutput, "Logging error")
assert.Contains(t, logOutput, "original error")
}
// TestSLogMultipleValues tests logging multiple different values
func TestSLogMultipleValues(t *testing.T) {
var buf bytes.Buffer
logger := slog.New(slog.NewTextHandler(&buf, &slog.HandlerOptions{
Level: slog.LevelInfo,
}))
oldLogger := logging.SetLogger(logger)
defer logging.SetLogger(oldLogger)
ctx := context.Background()
// Test with different types
intRes := SLog[int]("Integer")(result.Of(42))(ctx)
assert.Equal(t, result.Of(42), intRes)
strRes := SLog[string]("String")(result.Of("hello"))(ctx)
assert.Equal(t, result.Of("hello"), strRes)
boolRes := SLog[bool]("Boolean")(result.Of(true))(ctx)
assert.Equal(t, result.Of(true), boolRes)
logOutput := buf.String()
assert.Contains(t, logOutput, "Integer")
assert.Contains(t, logOutput, "value=42")
assert.Contains(t, logOutput, "String")
assert.Contains(t, logOutput, "value=hello")
assert.Contains(t, logOutput, "Boolean")
assert.Contains(t, logOutput, "value=true")
}

210
v2/context/readerresult/reader.go
View File

@@ -18,9 +18,17 @@ package readerresult
import (
"context"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/internal/chain"
"github.com/IBM/fp-go/v2/option"
"github.com/IBM/fp-go/v2/reader"
"github.com/IBM/fp-go/v2/readereither"
)
func FromReader[A any](r Reader[context.Context, A]) ReaderResult[A] {
return readereither.FromReader[error](r)
}
func FromEither[A any](e Either[A]) ReaderResult[A] {
return readereither.FromEither[context.Context](e)
}
@@ -42,11 +50,11 @@ func Map[A, B any](f func(A) B) Operator[A, B] {
}
func MonadChain[A, B any](ma ReaderResult[A], f Kleisli[A, B]) ReaderResult[B] {
return readereither.MonadChain(ma, f)
return readereither.MonadChain(ma, F.Flow2(f, WithContext))
}
func Chain[A, B any](f Kleisli[A, B]) Operator[A, B] {
return readereither.Chain(f)
return readereither.Chain(F.Flow2(f, WithContext))
}
func Of[A any](a A) ReaderResult[A] {
@@ -66,7 +74,7 @@ func FromPredicate[A any](pred func(A) bool, onFalse func(A) error) Kleisli[A, A
}
func OrElse[A any](onLeft Kleisli[error, A]) Kleisli[ReaderResult[A], A] {
return readereither.OrElse(onLeft)
return readereither.OrElse(F.Flow2(onLeft, WithContext))
}
func Ask() ReaderResult[context.Context] {
@@ -81,7 +89,7 @@ func ChainEitherK[A, B any](f func(A) Either[B]) func(ma ReaderResult[A]) Reader
return readereither.ChainEitherK[context.Context](f)
}
func ChainOptionK[A, B any](onNone func() error) func(func(A) Option[B]) Operator[A, B] {
func ChainOptionK[A, B any](onNone func() error) func(option.Kleisli[A, B]) Operator[A, B] {
return readereither.ChainOptionK[context.Context, A, B](onNone)
}
@@ -97,3 +105,197 @@ func Flap[B, A any](a A) Operator[func(A) B, B] {
func Read[A any](r context.Context) func(ReaderResult[A]) Result[A] {
return readereither.Read[error, A](r)
}
// MonadMapTo executes a ReaderResult computation, discards its success value, and returns a constant value.
// This is the monadic version that takes both the ReaderResult and the constant value as parameters.
//
// IMPORTANT: ReaderResult represents a side-effectful computation because it depends on context.Context,
// which is effectful (can be cancelled, has deadlines, carries values). For this reason, MonadMapTo WILL
// execute the original ReaderResult to allow any side effects to occur, then discard the success result
// and return the constant value. If the original computation fails, the error is preserved.
//
// Type Parameters:
// - A: The success type of the first ReaderResult (will be discarded if successful)
// - B: The type of the constant value to return on success
//
// Parameters:
// - ma: The ReaderResult to execute (side effects will occur, success value discarded)
// - b: The constant value to return if ma succeeds
//
// Returns:
// - A ReaderResult that executes ma, preserves errors, but replaces success values with b
//
// Example:
//
// type Config struct { Counter int }
// increment := func(ctx context.Context) result.Result[int] {
// // Side effect: log the operation
// fmt.Println("incrementing")
// return result.Of(5)
// }
// r := readerresult.MonadMapTo(increment, "done")
// result := r(context.Background()) // Prints "incrementing", returns Right("done")
//
//go:inline
func MonadMapTo[A, B any](ma ReaderResult[A], b B) ReaderResult[B] {
return MonadMap(ma, reader.Of[A](b))
}
// MapTo creates an operator that executes a ReaderResult computation, discards its success value,
// and returns a constant value. This is the curried version where the constant value is provided first,
// returning a function that can be applied to any ReaderResult.
//
// IMPORTANT: ReaderResult represents a side-effectful computation because it depends on context.Context,
// which is effectful (can be cancelled, has deadlines, carries values). For this reason, MapTo WILL
// execute the input ReaderResult to allow any side effects to occur, then discard the success result
// and return the constant value. If the computation fails, the error is preserved.
//
// Type Parameters:
// - A: The success type of the input ReaderResult (will be discarded if successful)
// - B: The type of the constant value to return on success
//
// Parameters:
// - b: The constant value to return on success
//
// Returns:
// - An Operator that executes a ReaderResult[A], preserves errors, but replaces success with b
//
// Example:
//
// logStep := func(ctx context.Context) result.Result[int] {
// fmt.Println("step executed")
// return result.Of(42)
// }
// toDone := readerresult.MapTo[int, string]("done")
// pipeline := toDone(logStep)
// result := pipeline(context.Background()) // Prints "step executed", returns Right("done")
//
// Example - In a functional pipeline:
//
// step1 := func(ctx context.Context) result.Result[int] {
// fmt.Println("processing")
// return result.Of(1)
// }
// pipeline := F.Pipe1(
// step1,
// readerresult.MapTo[int, string]("complete"),
// )
// output := pipeline(context.Background()) // Prints "processing", returns Right("complete")
//
//go:inline
func MapTo[A, B any](b B) Operator[A, B] {
return Map(reader.Of[A](b))
}
// MonadChainTo sequences two ReaderResult computations where the second ignores the first's success value.
// This is the monadic version that takes both ReaderResults as parameters.
//
// IMPORTANT: ReaderResult represents a side-effectful computation because it depends on context.Context,
// which is effectful (can be cancelled, has deadlines, carries values). For this reason, MonadChainTo WILL
// execute the first ReaderResult to allow any side effects to occur, then discard the success result and
// execute the second ReaderResult with the same context. If the first computation fails, the error is
// returned immediately without executing the second computation.
//
// Type Parameters:
// - A: The success type of the first ReaderResult (will be discarded if successful)
// - B: The success type of the second ReaderResult
//
// Parameters:
// - ma: The first ReaderResult to execute (side effects will occur, success value discarded)
// - b: The second ReaderResult to execute if ma succeeds
//
// Returns:
// - A ReaderResult that executes ma, then b if ma succeeds, returning b's result
//
// Example:
//
// logStart := func(ctx context.Context) result.Result[int] {
// fmt.Println("starting")
// return result.Of(1)
// }
// logEnd := func(ctx context.Context) result.Result[string] {
// fmt.Println("ending")
// return result.Of("done")
// }
// r := readerresult.MonadChainTo(logStart, logEnd)
// result := r(context.Background()) // Prints "starting" then "ending", returns Right("done")
//
//go:inline
func MonadChainTo[A, B any](ma ReaderResult[A], b ReaderResult[B]) ReaderResult[B] {
return MonadChain(ma, reader.Of[A](b))
}
// ChainTo creates an operator that sequences two ReaderResult computations where the second ignores
// the first's success value. This is the curried version where the second ReaderResult is provided first,
// returning a function that can be applied to any first ReaderResult.
//
// IMPORTANT: ReaderResult represents a side-effectful computation because it depends on context.Context,
// which is effectful (can be cancelled, has deadlines, carries values). For this reason, ChainTo WILL
// execute the first ReaderResult to allow any side effects to occur, then discard the success result and
// execute the second ReaderResult with the same context. If the first computation fails, the error is
// returned immediately without executing the second computation.
//
// Type Parameters:
// - A: The success type of the first ReaderResult (will be discarded if successful)
// - B: The success type of the second ReaderResult
//
// Parameters:
// - b: The second ReaderResult to execute after the first succeeds
//
// Returns:
// - An Operator that executes the first ReaderResult, then b if successful
//
// Example:
//
// logEnd := func(ctx context.Context) result.Result[string] {
// fmt.Println("ending")
// return result.Of("done")
// }
// thenLogEnd := readerresult.ChainTo[int, string](logEnd)
//
// logStart := func(ctx context.Context) result.Result[int] {
// fmt.Println("starting")
// return result.Of(1)
// }
// pipeline := thenLogEnd(logStart)
// result := pipeline(context.Background()) // Prints "starting" then "ending", returns Right("done")
//
// Example - In a functional pipeline:
//
// step1 := func(ctx context.Context) result.Result[int] {
// fmt.Println("step 1")
// return result.Of(1)
// }
// step2 := func(ctx context.Context) result.Result[string] {
// fmt.Println("step 2")
// return result.Of("complete")
// }
// pipeline := F.Pipe1(
// step1,
// readerresult.ChainTo[int, string](step2),
// )
// output := pipeline(context.Background()) // Prints "step 1" then "step 2", returns Right("complete")
//
//go:inline
func ChainTo[A, B any](b ReaderResult[B]) Operator[A, B] {
return Chain(reader.Of[A](b))
}
//go:inline
func MonadChainFirst[A, B any](ma ReaderResult[A], f Kleisli[A, B]) ReaderResult[A] {
return chain.MonadChainFirst(
MonadChain,
MonadMap,
ma,
F.Flow2(f, WithContext),
)
}
//go:inline
func ChainFirst[A, B any](f Kleisli[A, B]) Operator[A, A] {
return chain.ChainFirst(
Chain,
Map,
F.Flow2(f, WithContext),
)
}

315
v2/context/readerresult/reader_test.go Normal file
View File

@@ -0,0 +1,315 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"testing"
E "github.com/IBM/fp-go/v2/either"
F "github.com/IBM/fp-go/v2/function"
"github.com/stretchr/testify/assert"
)
func TestMapTo(t *testing.T) {
t.Run("executes original reader and returns constant value on success", func(t *testing.T) {
executed := false
originalReader := func(ctx context.Context) E.Either[error, int] {
executed = true
return E.Of[error](42)
}
// Apply MapTo operator
toDone := MapTo[int]("done")
resultReader := toDone(originalReader)
// Execute the resulting reader
result := resultReader(context.Background())
// Verify the constant value is returned
assert.Equal(t, E.Of[error]("done"), result)
// Verify the original reader WAS executed (side effect occurred)
assert.True(t, executed, "original reader should be executed to allow side effects")
})
t.Run("executes reader in functional pipeline", func(t *testing.T) {
executed := false
step1 := func(ctx context.Context) E.Either[error, int] {
executed = true
return E.Of[error](100)
}
pipeline := F.Pipe1(
step1,
MapTo[int]("complete"),
)
result := pipeline(context.Background())
assert.Equal(t, E.Of[error]("complete"), result)
assert.True(t, executed, "original reader should be executed in pipeline")
})
t.Run("executes reader with side effects", func(t *testing.T) {
sideEffectOccurred := false
readerWithSideEffect := func(ctx context.Context) E.Either[error, int] {
sideEffectOccurred = true
return E.Of[error](42)
}
resultReader := MapTo[int](true)(readerWithSideEffect)
result := resultReader(context.Background())
assert.Equal(t, E.Of[error](true), result)
assert.True(t, sideEffectOccurred, "side effect should occur")
})
t.Run("preserves errors from original reader", func(t *testing.T) {
executed := false
testErr := assert.AnError
failingReader := func(ctx context.Context) E.Either[error, int] {
executed = true
return E.Left[int](testErr)
}
resultReader := MapTo[int]("done")(failingReader)
result := resultReader(context.Background())
assert.Equal(t, E.Left[string](testErr), result)
assert.True(t, executed, "failing reader should still be executed")
})
}
func TestMonadMapTo(t *testing.T) {
t.Run("executes original reader and returns constant value on success", func(t *testing.T) {
executed := false
originalReader := func(ctx context.Context) E.Either[error, int] {
executed = true
return E.Of[error](42)
}
// Apply MonadMapTo
resultReader := MonadMapTo(originalReader, "done")
// Execute the resulting reader
result := resultReader(context.Background())
// Verify the constant value is returned
assert.Equal(t, E.Of[error]("done"), result)
// Verify the original reader WAS executed (side effect occurred)
assert.True(t, executed, "original reader should be executed to allow side effects")
})
t.Run("executes complex computation with side effects", func(t *testing.T) {
computationExecuted := false
complexReader := func(ctx context.Context) E.Either[error, string] {
computationExecuted = true
return E.Of[error]("complex result")
}
resultReader := MonadMapTo(complexReader, 42)
result := resultReader(context.Background())
assert.Equal(t, E.Of[error](42), result)
assert.True(t, computationExecuted, "complex computation should be executed")
})
t.Run("preserves errors from original reader", func(t *testing.T) {
executed := false
testErr := assert.AnError
failingReader := func(ctx context.Context) E.Either[error, []string] {
executed = true
return E.Left[[]string](testErr)
}
resultReader := MonadMapTo(failingReader, 99)
result := resultReader(context.Background())
assert.Equal(t, E.Left[int](testErr), result)
assert.True(t, executed, "failing reader should still be executed")
})
}
func TestChainTo(t *testing.T) {
t.Run("executes first reader then second reader on success", func(t *testing.T) {
firstExecuted := false
secondExecuted := false
firstReader := func(ctx context.Context) E.Either[error, int] {
firstExecuted = true
return E.Of[error](42)
}
secondReader := func(ctx context.Context) E.Either[error, string] {
secondExecuted = true
return E.Of[error]("result")
}
// Apply ChainTo operator
thenSecond := ChainTo[int](secondReader)
resultReader := thenSecond(firstReader)
// Execute the resulting reader
result := resultReader(context.Background())
// Verify the second reader's result is returned
assert.Equal(t, E.Of[error]("result"), result)
// Verify both readers were executed
assert.True(t, firstExecuted, "first reader should be executed")
assert.True(t, secondExecuted, "second reader should be executed")
})
t.Run("executes both readers in functional pipeline", func(t *testing.T) {
firstExecuted := false
secondExecuted := false
step1 := func(ctx context.Context) E.Either[error, int] {
firstExecuted = true
return E.Of[error](100)
}
step2 := func(ctx context.Context) E.Either[error, string] {
secondExecuted = true
return E.Of[error]("complete")
}
pipeline := F.Pipe1(
step1,
ChainTo[int](step2),
)
result := pipeline(context.Background())
assert.Equal(t, E.Of[error]("complete"), result)
assert.True(t, firstExecuted, "first reader should be executed in pipeline")
assert.True(t, secondExecuted, "second reader should be executed in pipeline")
})
t.Run("executes first reader with side effects", func(t *testing.T) {
sideEffectOccurred := false
readerWithSideEffect := func(ctx context.Context) E.Either[error, int] {
sideEffectOccurred = true
return E.Of[error](42)
}
secondReader := func(ctx context.Context) E.Either[error, bool] {
return E.Of[error](true)
}
resultReader := ChainTo[int](secondReader)(readerWithSideEffect)
result := resultReader(context.Background())
assert.Equal(t, E.Of[error](true), result)
assert.True(t, sideEffectOccurred, "side effect should occur in first reader")
})
t.Run("preserves error from first reader without executing second", func(t *testing.T) {
firstExecuted := false
secondExecuted := false
testErr := assert.AnError
failingReader := func(ctx context.Context) E.Either[error, int] {
firstExecuted = true
return E.Left[int](testErr)
}
secondReader := func(ctx context.Context) E.Either[error, string] {
secondExecuted = true
return E.Of[error]("result")
}
resultReader := ChainTo[int](secondReader)(failingReader)
result := resultReader(context.Background())
assert.Equal(t, E.Left[string](testErr), result)
assert.True(t, firstExecuted, "first reader should be executed")
assert.False(t, secondExecuted, "second reader should not be executed on error")
})
}
func TestMonadChainTo(t *testing.T) {
t.Run("executes first reader then second reader on success", func(t *testing.T) {
firstExecuted := false
secondExecuted := false
firstReader := func(ctx context.Context) E.Either[error, int] {
firstExecuted = true
return E.Of[error](42)
}
secondReader := func(ctx context.Context) E.Either[error, string] {
secondExecuted = true
return E.Of[error]("result")
}
// Apply MonadChainTo
resultReader := MonadChainTo(firstReader, secondReader)
// Execute the resulting reader
result := resultReader(context.Background())
// Verify the second reader's result is returned
assert.Equal(t, E.Of[error]("result"), result)
// Verify both readers were executed
assert.True(t, firstExecuted, "first reader should be executed")
assert.True(t, secondExecuted, "second reader should be executed")
})
t.Run("executes complex first computation with side effects", func(t *testing.T) {
firstExecuted := false
secondExecuted := false
complexFirstReader := func(ctx context.Context) E.Either[error, []int] {
firstExecuted = true
return E.Of[error]([]int{1, 2, 3})
}
secondReader := func(ctx context.Context) E.Either[error, string] {
secondExecuted = true
return E.Of[error]("done")
}
resultReader := MonadChainTo(complexFirstReader, secondReader)
result := resultReader(context.Background())
assert.Equal(t, E.Of[error]("done"), result)
assert.True(t, firstExecuted, "complex first computation should be executed")
assert.True(t, secondExecuted, "second reader should be executed")
})
t.Run("preserves error from first reader without executing second", func(t *testing.T) {
firstExecuted := false
secondExecuted := false
testErr := assert.AnError
failingReader := func(ctx context.Context) E.Either[error, map[string]int] {
firstExecuted = true
return E.Left[map[string]int](testErr)
}
secondReader := func(ctx context.Context) E.Either[error, float64] {
secondExecuted = true
return E.Of[error](3.14)
}
resultReader := MonadChainTo(failingReader, secondReader)
result := resultReader(context.Background())
assert.Equal(t, E.Left[float64](testErr), result)
assert.True(t, firstExecuted, "first reader should be executed")
assert.False(t, secondExecuted, "second reader should not be executed on error")
})
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package readerresult implements a specialization of the Reader monad assuming a golang context as the context of the monad and a standard golang error
package readerresult
import (
"context"
"github.com/IBM/fp-go/v2/either"
"github.com/IBM/fp-go/v2/result"
)
// TailRec implements tail-recursive computation for ReaderResult with context cancellation support.
//
// TailRec takes a Kleisli function that returns Either[A, B] and converts it into a stack-safe,
// tail-recursive computation. The function repeatedly applies the Kleisli until it produces a Right value.
//
// The implementation includes a short-circuit mechanism that checks for context cancellation on each
// iteration. If the context is canceled (ctx.Err() != nil), the computation immediately returns a
// Left result containing the context's cause error, preventing unnecessary computation.
//
// Type Parameters:
// - A: The input type for the recursive step
// - B: The final result type
//
// Parameters:
// - f: A Kleisli function that takes an A and returns a ReaderResult containing Either[A, B].
// When the result is Left[B](a), recursion continues with the new value 'a'.
// When the result is Right[A](b), recursion terminates with the final value 'b'.
//
// Returns:
// - A Kleisli function that performs the tail-recursive computation in a stack-safe manner.
//
// Behavior:
// - On each iteration, checks if the context has been canceled (short circuit)
// - If canceled, returns result.Left[B](context.Cause(ctx))
// - If the step returns Left[B](error), propagates the error
// - If the step returns Right[A](Left[B](a)), continues recursion with new value 'a'
// - If the step returns Right[A](Right[A](b)), terminates with success value 'b'
//
// Example - Factorial computation with context:
//
// type State struct {
// n int
// acc int
// }
//
// factorialStep := func(state State) ReaderResult[either.Either[State, int]] {
// return func(ctx context.Context) result.Result[either.Either[State, int]] {
// if state.n <= 0 {
// return result.Of(either.Right[State](state.acc))
// }
// return result.Of(either.Left[int](State{state.n - 1, state.acc * state.n}))
// }
// }
//
// factorial := TailRec(factorialStep)
// result := factorial(State{5, 1})(ctx) // Returns result.Of(120)
//
// Example - Context cancellation:
//
// ctx, cancel := context.WithCancel(context.Background())
// cancel() // Cancel immediately
//
// computation := TailRec(someStep)
// result := computation(initialValue)(ctx)
// // Returns result.Left[B](context.Cause(ctx)) without executing any steps
//
//go:inline
func TailRec[A, B any](f Kleisli[A, either.Either[A, B]]) Kleisli[A, B] {
return func(a A) ReaderResult[B] {
initialReader := f(a)
return func(ctx context.Context) Result[B] {
rdr := initialReader
for {
// short circuit
if ctx.Err() != nil {
return result.Left[B](context.Cause(ctx))
}
current := rdr(ctx)
rec, e := either.Unwrap(current)
if either.IsLeft(current) {
return result.Left[B](e)
}
b, a := either.Unwrap(rec)
if either.IsRight(rec) {
return result.Of(b)
}
rdr = f(a)
}
}
}
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"errors"
"fmt"
"testing"
"time"
A "github.com/IBM/fp-go/v2/array"
E "github.com/IBM/fp-go/v2/either"
R "github.com/IBM/fp-go/v2/result"
"github.com/stretchr/testify/assert"
)
// TestTailRecFactorial tests factorial computation with context
func TestTailRecFactorial(t *testing.T) {
type State struct {
n int
acc int
}
factorialStep := func(state State) ReaderResult[E.Either[State, int]] {
return func(ctx context.Context) Result[E.Either[State, int]] {
if state.n <= 0 {
return R.Of(E.Right[State](state.acc))
}
return R.Of(E.Left[int](State{state.n - 1, state.acc * state.n}))
}
}
factorial := TailRec(factorialStep)
result := factorial(State{5, 1})(context.Background())
assert.Equal(t, R.Of(120), result)
}
// TestTailRecFibonacci tests Fibonacci computation
func TestTailRecFibonacci(t *testing.T) {
type State struct {
n int
prev int
curr int
}
fibStep := func(state State) ReaderResult[E.Either[State, int]] {
return func(ctx context.Context) Result[E.Either[State, int]] {
if state.n <= 0 {
return R.Of(E.Right[State](state.curr))
}
return R.Of(E.Left[int](State{state.n - 1, state.curr, state.prev + state.curr}))
}
}
fib := TailRec(fibStep)
result := fib(State{10, 0, 1})(context.Background())
assert.Equal(t, R.Of(89), result) // 10th Fibonacci number
}
// TestTailRecCountdown tests countdown computation
func TestTailRecCountdown(t *testing.T) {
countdownStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
countdown := TailRec(countdownStep)
result := countdown(10)(context.Background())
assert.Equal(t, R.Of(0), result)
}
// TestTailRecImmediateTermination tests immediate termination (Right on first call)
func TestTailRecImmediateTermination(t *testing.T) {
immediateStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
return R.Of(E.Right[int](n * 2))
}
}
immediate := TailRec(immediateStep)
result := immediate(42)(context.Background())
assert.Equal(t, R.Of(84), result)
}
// TestTailRecStackSafety tests that TailRec handles large iterations without stack overflow
func TestTailRecStackSafety(t *testing.T) {
countdownStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
countdown := TailRec(countdownStep)
result := countdown(10000)(context.Background())
assert.Equal(t, R.Of(0), result)
}
// TestTailRecSumList tests summing a list
func TestTailRecSumList(t *testing.T) {
type State struct {
list []int
sum int
}
sumStep := func(state State) ReaderResult[E.Either[State, int]] {
return func(ctx context.Context) Result[E.Either[State, int]] {
if A.IsEmpty(state.list) {
return R.Of(E.Right[State](state.sum))
}
return R.Of(E.Left[int](State{state.list[1:], state.sum + state.list[0]}))
}
}
sumList := TailRec(sumStep)
result := sumList(State{[]int{1, 2, 3, 4, 5}, 0})(context.Background())
assert.Equal(t, R.Of(15), result)
}
// TestTailRecCollatzConjecture tests the Collatz conjecture
func TestTailRecCollatzConjecture(t *testing.T) {
collatzStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
if n <= 1 {
return R.Of(E.Right[int](n))
}
if n%2 == 0 {
return R.Of(E.Left[int](n / 2))
}
return R.Of(E.Left[int](3*n + 1))
}
}
collatz := TailRec(collatzStep)
result := collatz(10)(context.Background())
assert.Equal(t, R.Of(1), result)
}
// TestTailRecGCD tests greatest common divisor
func TestTailRecGCD(t *testing.T) {
type State struct {
a int
b int
}
gcdStep := func(state State) ReaderResult[E.Either[State, int]] {
return func(ctx context.Context) Result[E.Either[State, int]] {
if state.b == 0 {
return R.Of(E.Right[State](state.a))
}
return R.Of(E.Left[int](State{state.b, state.a % state.b}))
}
}
gcd := TailRec(gcdStep)
result := gcd(State{48, 18})(context.Background())
assert.Equal(t, R.Of(6), result)
}
// TestTailRecErrorPropagation tests that errors are properly propagated
func TestTailRecErrorPropagation(t *testing.T) {
expectedErr := errors.New("computation error")
errorStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
if n == 5 {
return R.Left[E.Either[int, int]](expectedErr)
}
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
computation := TailRec(errorStep)
result := computation(10)(context.Background())
assert.True(t, R.IsLeft(result))
_, err := R.Unwrap(result)
assert.Equal(t, expectedErr, err)
}
// TestTailRecContextCancellationImmediate tests short circuit when context is already canceled
func TestTailRecContextCancellationImmediate(t *testing.T) {
ctx, cancel := context.WithCancel(context.Background())
cancel() // Cancel immediately before execution
stepExecuted := false
countdownStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
stepExecuted = true
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
countdown := TailRec(countdownStep)
result := countdown(10)(ctx)
// Should short circuit without executing any steps
assert.False(t, stepExecuted, "Step should not be executed when context is already canceled")
assert.True(t, R.IsLeft(result))
_, err := R.Unwrap(result)
assert.Equal(t, context.Canceled, err)
}
// TestTailRecContextCancellationDuringExecution tests short circuit when context is canceled during execution
func TestTailRecContextCancellationDuringExecution(t *testing.T) {
ctx, cancel := context.WithCancel(context.Background())
executionCount := 0
countdownStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
executionCount++
// Cancel after 3 iterations
if executionCount == 3 {
cancel()
}
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
countdown := TailRec(countdownStep)
result := countdown(100)(ctx)
// Should stop after cancellation
assert.True(t, R.IsLeft(result))
assert.LessOrEqual(t, executionCount, 4, "Should stop shortly after cancellation")
_, err := R.Unwrap(result)
assert.Equal(t, context.Canceled, err)
}
// TestTailRecContextWithTimeout tests behavior with timeout context
func TestTailRecContextWithTimeout(t *testing.T) {
ctx, cancel := context.WithTimeout(context.Background(), 50*time.Millisecond)
defer cancel()
executionCount := 0
slowStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
executionCount++
// Simulate slow computation
time.Sleep(20 * time.Millisecond)
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
computation := TailRec(slowStep)
result := computation(100)(ctx)
// Should timeout and return error
assert.True(t, R.IsLeft(result))
assert.Less(t, executionCount, 100, "Should not complete all iterations due to timeout")
_, err := R.Unwrap(result)
assert.Equal(t, context.DeadlineExceeded, err)
}
// TestTailRecContextWithCause tests that context.Cause is properly returned
func TestTailRecContextWithCause(t *testing.T) {
customErr := errors.New("custom cancellation reason")
ctx, cancel := context.WithCancelCause(context.Background())
cancel(customErr)
countdownStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
countdown := TailRec(countdownStep)
result := countdown(10)(ctx)
assert.True(t, R.IsLeft(result))
_, err := R.Unwrap(result)
assert.Equal(t, customErr, err)
}
// TestTailRecContextCancellationMultipleIterations tests that cancellation is checked on each iteration
func TestTailRecContextCancellationMultipleIterations(t *testing.T) {
ctx, cancel := context.WithCancel(context.Background())
executionCount := 0
maxExecutions := 5
countdownStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
executionCount++
if executionCount == maxExecutions {
cancel()
}
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
countdown := TailRec(countdownStep)
result := countdown(1000)(ctx)
// Should detect cancellation on next iteration check
assert.True(t, R.IsLeft(result))
// Should stop within 1-2 iterations after cancellation
assert.LessOrEqual(t, executionCount, maxExecutions+2)
_, err := R.Unwrap(result)
assert.Equal(t, context.Canceled, err)
}
// TestTailRecContextNotCanceled tests normal execution when context is not canceled
func TestTailRecContextNotCanceled(t *testing.T) {
ctx := context.Background()
executionCount := 0
countdownStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
executionCount++
if n <= 0 {
return R.Of(E.Right[int](n))
}
return R.Of(E.Left[int](n - 1))
}
}
countdown := TailRec(countdownStep)
result := countdown(10)(ctx)
assert.Equal(t, 11, executionCount) // 10, 9, 8, ..., 1, 0
assert.Equal(t, R.Of(0), result)
}
// TestTailRecPowerOfTwo tests computing power of 2
func TestTailRecPowerOfTwo(t *testing.T) {
type State struct {
exponent int
result int
target int
}
powerStep := func(state State) ReaderResult[E.Either[State, int]] {
return func(ctx context.Context) Result[E.Either[State, int]] {
if state.exponent >= state.target {
return R.Of(E.Right[State](state.result))
}
return R.Of(E.Left[int](State{state.exponent + 1, state.result * 2, state.target}))
}
}
power := TailRec(powerStep)
result := power(State{0, 1, 10})(context.Background())
assert.Equal(t, R.Of(1024), result) // 2^10
}
// TestTailRecFindInRange tests finding a value in a range
func TestTailRecFindInRange(t *testing.T) {
type State struct {
current int
max int
target int
}
findStep := func(state State) ReaderResult[E.Either[State, int]] {
return func(ctx context.Context) Result[E.Either[State, int]] {
if state.current >= state.max {
return R.Of(E.Right[State](-1)) // Not found
}
if state.current == state.target {
return R.Of(E.Right[State](state.current)) // Found
}
return R.Of(E.Left[int](State{state.current + 1, state.max, state.target}))
}
}
find := TailRec(findStep)
result := find(State{0, 100, 42})(context.Background())
assert.Equal(t, R.Of(42), result)
}
// TestTailRecFindNotInRange tests finding a value not in range
func TestTailRecFindNotInRange(t *testing.T) {
type State struct {
current int
max int
target int
}
findStep := func(state State) ReaderResult[E.Either[State, int]] {
return func(ctx context.Context) Result[E.Either[State, int]] {
if state.current >= state.max {
return R.Of(E.Right[State](-1)) // Not found
}
if state.current == state.target {
return R.Of(E.Right[State](state.current)) // Found
}
return R.Of(E.Left[int](State{state.current + 1, state.max, state.target}))
}
}
find := TailRec(findStep)
result := find(State{0, 100, 200})(context.Background())
assert.Equal(t, R.Of(-1), result)
}
// TestTailRecWithContextValue tests that context values are accessible
func TestTailRecWithContextValue(t *testing.T) {
type contextKey string
const multiplierKey contextKey = "multiplier"
ctx := context.WithValue(context.Background(), multiplierKey, 3)
countdownStep := func(n int) ReaderResult[E.Either[int, int]] {
return func(ctx context.Context) Result[E.Either[int, int]] {
if n <= 0 {
multiplier := ctx.Value(multiplierKey).(int)
return R.Of(E.Right[int](n * multiplier))
}
return R.Of(E.Left[int](n - 1))
}
}
countdown := TailRec(countdownStep)
result := countdown(5)(ctx)
assert.Equal(t, R.Of(0), result) // 0 * 3 = 0
}
// TestTailRecComplexState tests with complex state structure
func TestTailRecComplexState(t *testing.T) {
type ComplexState struct {
counter int
sum int
product int
completed bool
}
complexStep := func(state ComplexState) ReaderResult[E.Either[ComplexState, string]] {
return func(ctx context.Context) Result[E.Either[ComplexState, string]] {
if state.counter <= 0 || state.completed {
result := fmt.Sprintf("sum=%d, product=%d", state.sum, state.product)
return R.Of(E.Right[ComplexState](result))
}
newState := ComplexState{
counter: state.counter - 1,
sum: state.sum + state.counter,
product: state.product * state.counter,
completed: state.counter == 1,
}
return R.Of(E.Left[string](newState))
}
}
computation := TailRec(complexStep)
result := computation(ComplexState{5, 0, 1, false})(context.Background())
assert.Equal(t, R.Of("sum=15, product=120"), result)
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache LicensVersion 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"time"
RD "github.com/IBM/fp-go/v2/reader"
R "github.com/IBM/fp-go/v2/retry"
RG "github.com/IBM/fp-go/v2/retry/generic"
)
//go:inline
func Retrying[A any](
policy R.RetryPolicy,
action Kleisli[R.RetryStatus, A],
check func(Result[A]) bool,
) ReaderResult[A] {
// delayWithCancel implements a context-aware delay mechanism for retry operations.
// It creates a timeout context that will be cancelled when either:
// 1. The delay duration expires (normal case), or
// 2. The parent context is cancelled (early termination)
//
// The function waits on timeoutCtx.Done(), which will be signaled in either case:
// - If the delay expires, timeoutCtx is cancelled by the timeout
// - If the parent ctx is cancelled, timeoutCtx inherits the cancellation
//
// After the wait completes, we dispatch to the next action by calling ri(ctx)().
// This works correctly because the action is wrapped in WithContextK, which handles
// context cancellation by checking ctx.Err() and returning an appropriate error
// (context.Canceled or context.DeadlineExceeded) when the context is cancelled.
//
// This design ensures that:
// - Retry delays respect context cancellation and terminate immediately
// - The cancellation error propagates correctly through the retry chain
// - No unnecessary delays occur when the context is already cancelled
delayWithCancel := func(delay time.Duration) RD.Operator[context.Context, R.RetryStatus, R.RetryStatus] {
return func(ri Reader[context.Context, R.RetryStatus]) Reader[context.Context, R.RetryStatus] {
return func(ctx context.Context) R.RetryStatus {
// Create a timeout context that will be cancelled when either:
// - The delay duration expires, or
// - The parent context is cancelled
timeoutCtx, cancelTimeout := context.WithTimeout(ctx, delay)
defer cancelTimeout()
// Wait for either the timeout or parent context cancellation
<-timeoutCtx.Done()
// Dispatch to the next action with the original context.
// WithContextK will handle context cancellation correctly.
return ri(ctx)
}
}
}
// get an implementation for the types
return RG.Retrying(
RD.Chain[context.Context, Result[A], Result[A]],
RD.Chain[context.Context, R.RetryStatus, Result[A]],
RD.Of[context.Context, Result[A]],
RD.Of[context.Context, R.RetryStatus],
delayWithCancel,
policy,
WithContextK(action),
check,
)
}

43
v2/context/readerresult/type.go
View File

@@ -13,13 +13,40 @@
// See the License for the specific language governing permissions and
// limitations under the License.
// package readerresult implements a specialization of the Reader monad assuming a golang context as the context of the monad and a standard golang error
// Package readerresult implements a specialization of the Reader monad assuming a golang context as the context of the monad and a standard golang error.
//
// # Pure vs Effectful Functions
//
// This package distinguishes between pure (side-effect free) and effectful (side-effectful) functions:
//
// EFFECTFUL FUNCTIONS (depend on context.Context):
// - ReaderResult[A]: func(context.Context) (A, error) - Effectful computation that needs context
// - These functions are effectful because context.Context is effectful (can be cancelled, has deadlines, carries values)
// - Use for: operations that need cancellation, timeouts, context values, or any context-dependent behavior
// - Examples: database queries, HTTP requests, operations that respect cancellation
//
// PURE FUNCTIONS (side-effect free):
// - func(State) (Value, error) - Pure computation that only depends on state, not context
// - func(State) Value - Pure transformation without errors
// - These functions are pure because they only read from their input state and don't depend on external context
// - Use for: parsing, validation, calculations, data transformations that don't need context
// - Examples: JSON parsing, input validation, mathematical computations
//
// The package provides different bind operations for each:
// - Bind: For effectful ReaderResult computations (State -> ReaderResult[Value])
// - BindResultK: For pure functions with errors (State -> (Value, error))
// - Let: For pure functions without errors (State -> Value)
// - BindReaderK: For context-dependent pure functions (State -> Reader[Context, Value])
// - BindEitherK: For pure Result/Either values (State -> Result[Value])
package readerresult
import (
"context"
"github.com/IBM/fp-go/v2/either"
"github.com/IBM/fp-go/v2/endomorphism"
"github.com/IBM/fp-go/v2/optics/lens"
"github.com/IBM/fp-go/v2/optics/prism"
"github.com/IBM/fp-go/v2/option"
"github.com/IBM/fp-go/v2/reader"
"github.com/IBM/fp-go/v2/readereither"
@@ -27,12 +54,16 @@ import (
)
type (
Option[A any] = option.Option[A]
Either[A any] = either.Either[error, A]
Result[A any] = result.Result[A]
Option[A any] = option.Option[A]
Either[A any] = either.Either[error, A]
Result[A any] = result.Result[A]
Reader[R, A any] = reader.Reader[R, A]
// ReaderResult is a specialization of the Reader monad for the typical golang scenario
ReaderResult[A any] = readereither.ReaderEither[context.Context, error, A]
Kleisli[A, B any] = reader.Reader[A, ReaderResult[B]]
Operator[A, B any] = Kleisli[ReaderResult[A], B]
Kleisli[A, B any] = reader.Reader[A, ReaderResult[B]]
Operator[A, B any] = Kleisli[ReaderResult[A], B]
Endomorphism[A any] = endomorphism.Endomorphism[A]
Prism[S, T any] = prism.Prism[S, T]
Lens[S, T any] = lens.Lens[S, T]
)

9917
v2/coverage.out
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File diff suppressed because it is too large Load Diff

4
v2/di/token.go
View File

@@ -103,11 +103,11 @@ func (t *token[T]) Unerase(val any) Result[T] {
func (t *token[T]) ProviderFactory() Option[DIE.ProviderFactory] {
return t.base.providerFactory
}
func makeTokenBase(name string, id string, typ int, providerFactory Option[DIE.ProviderFactory]) *tokenBase {
func makeTokenBase(name, id string, typ int, providerFactory Option[DIE.ProviderFactory]) *tokenBase {
return &tokenBase{name, id, typ, providerFactory}
}
func makeToken[T any](name string, id string, typ int, unerase func(val any) Result[T], providerFactory Option[DIE.ProviderFactory]) Dependency[T] {
func makeToken[T any](name, id string, typ int, unerase func(val any) Result[T], providerFactory Option[DIE.ProviderFactory]) Dependency[T] {
return &token[T]{makeTokenBase(name, id, typ, providerFactory), unerase}
}

4
v2/either/array.go
View File

@@ -75,7 +75,7 @@ func TraverseArray[E, A, B any](f Kleisli[E, A, B]) Kleisli[E, []A, []B] {
// Example:
//
// validate := func(i int, s string) either.Either[error, string] {
// if len(s) > 0 {
// if S.IsNonEmpty(s) {
// return either.Right[error](fmt.Sprintf("%d:%s", i, s))
// }
// return either.Left[string](fmt.Errorf("empty at index %d", i))
@@ -105,7 +105,7 @@ func TraverseArrayWithIndexG[GA ~[]A, GB ~[]B, E, A, B any](f func(int, A) Eithe
// Example:
//
// validate := func(i int, s string) either.Either[error, string] {
// if len(s) > 0 {
// if S.IsNonEmpty(s) {
// return either.Right[error](fmt.Sprintf("%d:%s", i, s))
// }
// return either.Left[string](fmt.Errorf("empty at index %d", i))

2
v2/either/curry.go
View File

@@ -34,7 +34,7 @@ func Curry0[R any](f func() (R, error)) func() Either[error, R] {
//
// Example:
//
// parse := func(s string) (int, error) { return strconv.Atoi(s) }
// parse := strconv.Atoi
// curried := either.Curry1(parse)
// result := curried("42") // Right(42)
func Curry1[T1, R any](f func(T1) (R, error)) func(T1) Either[error, R] {

15
v2/either/doc.go
View File

@@ -19,6 +19,21 @@
// - Left represents an error or failure case (type E)
// - Right represents a success case (type A)
//
// # Fantasy Land Specification
//
// This implementation corresponds to the Fantasy Land Either type:
// https://github.com/fantasyland/fantasy-land#either
//
// Implemented Fantasy Land algebras:
// - Functor: https://github.com/fantasyland/fantasy-land#functor
// - Bifunctor: https://github.com/fantasyland/fantasy-land#bifunctor
// - Apply: https://github.com/fantasyland/fantasy-land#apply
// - Applicative: https://github.com/fantasyland/fantasy-land#applicative
// - Chain: https://github.com/fantasyland/fantasy-land#chain
// - Monad: https://github.com/fantasyland/fantasy-land#monad
// - Alt: https://github.com/fantasyland/fantasy-land#alt
// - Foldable: https://github.com/fantasyland/fantasy-land#foldable
//
// # Core Concepts
//
// The Either type is a discriminated union that can hold either a Left value (typically an error)

11
v2/either/either_coverage_test.go
View File

@@ -22,8 +22,9 @@ import (
"testing"
F "github.com/IBM/fp-go/v2/function"
M "github.com/IBM/fp-go/v2/monoid"
N "github.com/IBM/fp-go/v2/number"
O "github.com/IBM/fp-go/v2/option"
S "github.com/IBM/fp-go/v2/string"
"github.com/stretchr/testify/assert"
)
@@ -305,7 +306,7 @@ func TestTraverseArray(t *testing.T) {
// Test TraverseArrayWithIndex
func TestTraverseArrayWithIndex(t *testing.T) {
validate := func(i int, s string) Either[error, string] {
if len(s) > 0 {
if S.IsNonEmpty(s) {
return Right[error](fmt.Sprintf("%d:%s", i, s))
}
return Left[string](fmt.Errorf("empty at index %d", i))
@@ -334,7 +335,7 @@ func TestTraverseRecord(t *testing.T) {
// Test TraverseRecordWithIndex
func TestTraverseRecordWithIndex(t *testing.T) {
validate := func(k string, v string) Either[error, string] {
if len(v) > 0 {
if S.IsNonEmpty(v) {
return Right[error](k + ":" + v)
}
return Left[string](fmt.Errorf("empty value for key %s", k))
@@ -373,7 +374,7 @@ func TestCurry0(t *testing.T) {
}
func TestCurry1(t *testing.T) {
parse := func(s string) (int, error) { return strconv.Atoi(s) }
parse := strconv.Atoi
curried := Curry1(parse)
result := curried("42")
assert.Equal(t, Right[error](42), result)
@@ -645,7 +646,7 @@ func TestAltSemigroup(t *testing.T) {
// Test AlternativeMonoid
func TestAlternativeMonoid(t *testing.T) {
intAdd := M.MakeMonoid(func(a, b int) int { return a + b }, 0)
intAdd := N.MonoidSum[int]()
m := AlternativeMonoid[error](intAdd)
result := m.Concat(Right[error](1), Right[error](2))

8
v2/either/either_test.go
View File

@@ -22,7 +22,6 @@ import (
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/internal/utils"
IO "github.com/IBM/fp-go/v2/io"
O "github.com/IBM/fp-go/v2/option"
S "github.com/IBM/fp-go/v2/string"
"github.com/stretchr/testify/assert"
@@ -120,10 +119,3 @@ func TestStringer(t *testing.T) {
var s fmt.Stringer = &e
assert.Equal(t, exp, s.String())
}
func TestFromIO(t *testing.T) {
f := IO.Of("abc")
e := FromIO[error](f)
assert.Equal(t, Right[error]("abc"), e)
}

96
v2/either/logger.go
View File

@@ -17,11 +17,19 @@ package either
import (
"log"
"log/slog"
F "github.com/IBM/fp-go/v2/function"
L "github.com/IBM/fp-go/v2/logging"
)
var (
// slogError creates a slog.Attr with key "error" for logging error values
slogError = F.Bind1st(slog.Any, "error")
// slogValue creates a slog.Attr with key "value" for logging success values
slogValue = F.Bind1st(slog.Any, "value")
)
func _log[E, A any](left func(string, ...any), right func(string, ...any), prefix string) Operator[E, A, A] {
return Fold(
func(e E) Either[E, A] {
@@ -62,3 +70,91 @@ func Logger[E, A any](loggers ...*log.Logger) func(string) Operator[E, A, A] {
}
}
}
// ToSLogAttr converts an Either value to a structured logging attribute (slog.Attr).
//
// This function creates a converter that transforms Either values into slog.Attr for use
// with Go's structured logging (log/slog). It maps:
// - Left values to an "error" attribute
// - Right values to a "value" attribute
//
// This is particularly useful when integrating Either-based error handling with structured
// logging systems, allowing you to log both successful values and errors in a consistent,
// structured format.
//
// Type Parameters:
// - E: The Left (error) type of the Either
// - A: The Right (success) type of the Either
//
// Returns:
// - A function that converts Either[E, A] to slog.Attr
//
// Example with Left (error):
//
// converter := either.ToSLogAttr[error, int]()
// leftValue := either.Left[int](errors.New("connection failed"))
// attr := converter(leftValue)
// // attr is: slog.Any("error", errors.New("connection failed"))
//
// logger.LogAttrs(ctx, slog.LevelError, "Operation failed", attr)
// // Logs: {"level":"error","msg":"Operation failed","error":"connection failed"}
//
// Example with Right (success):
//
// converter := either.ToSLogAttr[error, User]()
// rightValue := either.Right[error](User{ID: 123, Name: "Alice"})
// attr := converter(rightValue)
// // attr is: slog.Any("value", User{ID: 123, Name: "Alice"})
//
// logger.LogAttrs(ctx, slog.LevelInfo, "User fetched", attr)
// // Logs: {"level":"info","msg":"User fetched","value":{"ID":123,"Name":"Alice"}}
//
// Example in a pipeline with structured logging:
//
// toAttr := either.ToSLogAttr[error, Data]()
//
// result := F.Pipe2(
// fetchData(id),
// either.Map(processData),
// either.Map(validateData),
// )
//
// attr := toAttr(result)
// logger.LogAttrs(ctx, slog.LevelInfo, "Data processing complete", attr)
// // Logs success: {"level":"info","msg":"Data processing complete","value":{...}}
// // Or error: {"level":"info","msg":"Data processing complete","error":"validation failed"}
//
// Example with custom log levels based on Either:
//
// toAttr := either.ToSLogAttr[error, Response]()
// result := callAPI(endpoint)
//
// level := either.Fold(
// func(error) slog.Level { return slog.LevelError },
// func(Response) slog.Level { return slog.LevelInfo },
// )(result)
//
// logger.LogAttrs(ctx, level, "API call completed", toAttr(result))
//
// Use Cases:
// - Structured logging: Convert Either results to structured log attributes
// - Error tracking: Log errors with consistent "error" key in structured logs
// - Success monitoring: Log successful values with consistent "value" key
// - Observability: Integrate Either-based error handling with logging systems
// - Debugging: Inspect Either values in logs with proper structure
// - Metrics: Extract Either values for metrics collection in logging pipelines
//
// Note: The returned slog.Attr uses "error" for Left values and "value" for Right values.
// These keys are consistent with common structured logging conventions.
func ToSLogAttr[E, A any]() func(Either[E, A]) slog.Attr {
return Fold(
F.Flow2(
F.ToAny[E],
slogError,
),
F.Flow2(
F.ToAny[A],
slogValue,
),
)
}

139
v2/either/logger_test.go
View File

@@ -16,9 +16,12 @@
package either
import (
"errors"
"log/slog"
"testing"
F "github.com/IBM/fp-go/v2/function"
N "github.com/IBM/fp-go/v2/number"
"github.com/stretchr/testify/assert"
)
@@ -35,3 +38,139 @@ func TestLogger(t *testing.T) {
assert.Equal(t, r, res)
}
func TestToSLogAttr_Left(t *testing.T) {
// Test with Left (error) value
converter := ToSLogAttr[error, int]()
testErr := errors.New("test error")
leftValue := Left[int](testErr)
attr := converter(leftValue)
// Verify the attribute has the correct key
assert.Equal(t, "error", attr.Key)
// Verify the attribute value is the error
assert.Equal(t, testErr, attr.Value.Any())
}
func TestToSLogAttr_Right(t *testing.T) {
// Test with Right (success) value
converter := ToSLogAttr[error, string]()
rightValue := Right[error]("success value")
attr := converter(rightValue)
// Verify the attribute has the correct key
assert.Equal(t, "value", attr.Key)
// Verify the attribute value is the success value
assert.Equal(t, "success value", attr.Value.Any())
}
func TestToSLogAttr_LeftWithCustomType(t *testing.T) {
// Test with custom error type
type CustomError struct {
Code int
Message string
}
converter := ToSLogAttr[CustomError, string]()
customErr := CustomError{Code: 404, Message: "not found"}
leftValue := Left[string](customErr)
attr := converter(leftValue)
assert.Equal(t, "error", attr.Key)
assert.Equal(t, customErr, attr.Value.Any())
}
func TestToSLogAttr_RightWithCustomType(t *testing.T) {
// Test with custom success type
type User struct {
ID int
Name string
}
converter := ToSLogAttr[error, User]()
user := User{ID: 123, Name: "Alice"}
rightValue := Right[error](user)
attr := converter(rightValue)
assert.Equal(t, "value", attr.Key)
assert.Equal(t, user, attr.Value.Any())
}
func TestToSLogAttr_InPipeline(t *testing.T) {
// Test ToSLogAttr in a functional pipeline
converter := ToSLogAttr[error, int]()
// Test with successful pipeline
successResult := F.Pipe2(
Right[error](10),
Map[error](N.Mul(2)),
converter,
)
assert.Equal(t, "value", successResult.Key)
// slog.Any converts int to int64
assert.Equal(t, int64(20), successResult.Value.Any())
// Test with failed pipeline
testErr := errors.New("computation failed")
failureResult := F.Pipe2(
Left[int](testErr),
Map[error](N.Mul(2)),
converter,
)
assert.Equal(t, "error", failureResult.Key)
assert.Equal(t, testErr, failureResult.Value.Any())
}
func TestToSLogAttr_WithNilError(t *testing.T) {
// Test with nil error (edge case)
converter := ToSLogAttr[error, string]()
var nilErr error = nil
leftValue := Left[string](nilErr)
attr := converter(leftValue)
assert.Equal(t, "error", attr.Key)
assert.Nil(t, attr.Value.Any())
}
func TestToSLogAttr_WithZeroValue(t *testing.T) {
// Test with zero value of success type
converter := ToSLogAttr[error, int]()
rightValue := Right[error](0)
attr := converter(rightValue)
assert.Equal(t, "value", attr.Key)
// slog.Any converts int to int64
assert.Equal(t, int64(0), attr.Value.Any())
}
func TestToSLogAttr_WithEmptyString(t *testing.T) {
// Test with empty string as success value
converter := ToSLogAttr[error, string]()
rightValue := Right[error]("")
attr := converter(rightValue)
assert.Equal(t, "value", attr.Key)
assert.Equal(t, "", attr.Value.Any())
}
func TestToSLogAttr_AttributeKind(t *testing.T) {
// Verify that the returned attribute has the correct Kind
converter := ToSLogAttr[error, string]()
leftAttr := converter(Left[string](errors.New("error")))
// Errors are stored as KindAny (which has value 0)
assert.Equal(t, slog.KindAny, leftAttr.Value.Kind())
rightAttr := converter(Right[error]("value"))
// Strings have KindString
assert.Equal(t, slog.KindString, rightAttr.Value.Kind())
}

34
v2/either/rec.go Normal file
View File

@@ -0,0 +1,34 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package either
//go:inline
func TailRec[E, A, B any](f Kleisli[E, A, Either[A, B]]) Kleisli[E, A, B] {
return func(a A) Either[E, B] {
current := f(a)
for {
rec, e := Unwrap(current)
if IsLeft(current) {
return Left[B](e)
}
b, a := Unwrap(rec)
if IsRight(rec) {
return Right[E](b)
}
current = f(a)
}
}
}

6
v2/endomorphism/endo.go
View File

@@ -41,7 +41,7 @@ import (
// increment := N.Add(1)
// result := endomorphism.MonadAp(double, increment) // Composes: double ∘ increment
// // result(5) = double(increment(5)) = double(6) = 12
func MonadAp[A any](fab Endomorphism[A], fa Endomorphism[A]) Endomorphism[A] {
func MonadAp[A any](fab, fa Endomorphism[A]) Endomorphism[A] {
return MonadCompose(fab, fa)
}
@@ -225,7 +225,7 @@ func Map[A any](f Endomorphism[A]) Operator[A] {
// // Compare with MonadCompose which executes RIGHT-TO-LEFT:
// composed := endomorphism.MonadCompose(increment, double)
// result2 := composed(5) // (5 * 2) + 1 = 11 (same result, different parameter order)
func MonadChain[A any](ma Endomorphism[A], f Endomorphism[A]) Endomorphism[A] {
func MonadChain[A any](ma, f Endomorphism[A]) Endomorphism[A] {
return function.Flow2(ma, f)
}
@@ -247,7 +247,7 @@ func MonadChain[A any](ma Endomorphism[A], f Endomorphism[A]) Endomorphism[A] {
// log := func(x int) int { fmt.Println(x); return x }
// chained := endomorphism.MonadChainFirst(double, log)
// result := chained(5) // Prints 10, returns 10
func MonadChainFirst[A any](ma Endomorphism[A], f Endomorphism[A]) Endomorphism[A] {
func MonadChainFirst[A any](ma, f Endomorphism[A]) Endomorphism[A] {
return func(a A) A {
result := ma(a)
f(result) // Apply f for its effect

72
v2/endomorphism/from.go
View File

@@ -1,3 +1,18 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package endomorphism
import (
@@ -5,6 +20,63 @@ import (
S "github.com/IBM/fp-go/v2/semigroup"
)
// FromSemigroup converts a semigroup into a Kleisli arrow for endomorphisms.
//
// This function takes a semigroup and returns a Kleisli arrow that, when given
// a value of type A, produces an endomorphism that concatenates that value with
// other values using the semigroup's Concat operation.
//
// The resulting Kleisli arrow has the signature: func(A) Endomorphism[A]
// When called with a value 'x', it returns an endomorphism that concatenates
// 'x' with its input using the semigroup's binary operation.
//
// # Data Last Principle
//
// FromSemigroup follows the "data last" principle by using function.Bind2of2,
// which binds the second parameter of the semigroup's Concat operation.
// This means that for a semigroup with Concat(a, b), calling FromSemigroup(s)(x)
// creates an endomorphism that computes Concat(input, x), where the input data
// comes first and the bound value 'x' comes last.
//
// For example, with string concatenation:
// - Semigroup.Concat("Hello", "World") = "HelloWorld"
// - FromSemigroup(semigroup)("World") creates: func(input) = Concat(input, "World")
// - Applying it: endomorphism("Hello") = Concat("Hello", "World") = "HelloWorld"
//
// This is particularly useful for creating endomorphisms from associative operations
// like string concatenation, number addition, list concatenation, etc.
//
// Parameters:
// - s: A semigroup providing the Concat operation for type A
//
// Returns:
// - A Kleisli arrow that converts values of type A into endomorphisms
//
// Example:
//
// import (
// "github.com/IBM/fp-go/v2/endomorphism"
// "github.com/IBM/fp-go/v2/semigroup"
// )
//
// // Create a semigroup for integer addition
// addSemigroup := semigroup.MakeSemigroup(func(a, b int) int {
// return a + b
// })
//
// // Convert it to a Kleisli arrow
// addKleisli := endomorphism.FromSemigroup(addSemigroup)
//
// // Use the Kleisli arrow to create an endomorphism that adds 5
// // This follows "data last": the input data comes first, 5 comes last
// addFive := addKleisli(5)
//
// // Apply the endomorphism: Concat(10, 5) = 10 + 5 = 15
// result := addFive(10) // result is 15
//
// The function uses function.Bind2of2 to partially apply the semigroup's Concat
// operation, effectively currying it to create the desired Kleisli arrow while
// maintaining the "data last" principle.
func FromSemigroup[A any](s S.Semigroup[A]) Kleisli[A] {
return function.Bind2of2(s.Concat)
}

439
v2/endomorphism/from_test.go Normal file
View File

@@ -0,0 +1,439 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package endomorphism
import (
"testing"
S "github.com/IBM/fp-go/v2/semigroup"
"github.com/stretchr/testify/assert"
)
// TestFromSemigroup tests the FromSemigroup function with various semigroups
func TestFromSemigroup(t *testing.T) {
t.Run("integer addition semigroup", func(t *testing.T) {
// Create a semigroup for integer addition
addSemigroup := S.MakeSemigroup(func(a, b int) int {
return a + b
})
// Convert to Kleisli arrow
addKleisli := FromSemigroup(addSemigroup)
// Create an endomorphism that adds 5
addFive := addKleisli(5)
// Test the endomorphism
assert.Equal(t, 15, addFive(10), "addFive(10) should equal 15")
assert.Equal(t, 5, addFive(0), "addFive(0) should equal 5")
assert.Equal(t, -5, addFive(-10), "addFive(-10) should equal -5")
})
t.Run("integer multiplication semigroup", func(t *testing.T) {
// Create a semigroup for integer multiplication
mulSemigroup := S.MakeSemigroup(func(a, b int) int {
return a * b
})
// Convert to Kleisli arrow
mulKleisli := FromSemigroup(mulSemigroup)
// Create an endomorphism that multiplies by 3
multiplyByThree := mulKleisli(3)
// Test the endomorphism
assert.Equal(t, 15, multiplyByThree(5), "multiplyByThree(5) should equal 15")
assert.Equal(t, 0, multiplyByThree(0), "multiplyByThree(0) should equal 0")
assert.Equal(t, -9, multiplyByThree(-3), "multiplyByThree(-3) should equal -9")
})
t.Run("string concatenation semigroup", func(t *testing.T) {
// Create a semigroup for string concatenation
concatSemigroup := S.MakeSemigroup(func(a, b string) string {
return a + b
})
// Convert to Kleisli arrow
concatKleisli := FromSemigroup(concatSemigroup)
// Create an endomorphism that appends "Hello, " (input is on the left)
appendHello := concatKleisli("Hello, ")
// Test the endomorphism - input is concatenated on the left, "Hello, " on the right
assert.Equal(t, "WorldHello, ", appendHello("World"), "appendHello('World') should equal 'WorldHello, '")
assert.Equal(t, "Hello, ", appendHello(""), "appendHello('') should equal 'Hello, '")
assert.Equal(t, "GoHello, ", appendHello("Go"), "appendHello('Go') should equal 'GoHello, '")
})
t.Run("slice concatenation semigroup", func(t *testing.T) {
// Create a semigroup for slice concatenation
sliceSemigroup := S.MakeSemigroup(func(a, b []int) []int {
result := make([]int, len(a)+len(b))
copy(result, a)
copy(result[len(a):], b)
return result
})
// Convert to Kleisli arrow
sliceKleisli := FromSemigroup(sliceSemigroup)
// Create an endomorphism that appends [1, 2] (input is on the left)
appendOneTwo := sliceKleisli([]int{1, 2})
// Test the endomorphism - input is concatenated on the left, [1,2] on the right
result1 := appendOneTwo([]int{3, 4, 5})
assert.Equal(t, []int{3, 4, 5, 1, 2}, result1, "appendOneTwo([3,4,5]) should equal [3,4,5,1,2]")
result2 := appendOneTwo([]int{})
assert.Equal(t, []int{1, 2}, result2, "appendOneTwo([]) should equal [1,2]")
result3 := appendOneTwo([]int{10})
assert.Equal(t, []int{10, 1, 2}, result3, "appendOneTwo([10]) should equal [10,1,2]")
})
t.Run("max semigroup", func(t *testing.T) {
// Create a semigroup for max operation
maxSemigroup := S.MakeSemigroup(func(a, b int) int {
if a > b {
return a
}
return b
})
// Convert to Kleisli arrow
maxKleisli := FromSemigroup(maxSemigroup)
// Create an endomorphism that takes max with 10
maxWithTen := maxKleisli(10)
// Test the endomorphism
assert.Equal(t, 15, maxWithTen(15), "maxWithTen(15) should equal 15")
assert.Equal(t, 10, maxWithTen(5), "maxWithTen(5) should equal 10")
assert.Equal(t, 10, maxWithTen(10), "maxWithTen(10) should equal 10")
assert.Equal(t, 10, maxWithTen(-5), "maxWithTen(-5) should equal 10")
})
t.Run("min semigroup", func(t *testing.T) {
// Create a semigroup for min operation
minSemigroup := S.MakeSemigroup(func(a, b int) int {
if a < b {
return a
}
return b
})
// Convert to Kleisli arrow
minKleisli := FromSemigroup(minSemigroup)
// Create an endomorphism that takes min with 10
minWithTen := minKleisli(10)
// Test the endomorphism
assert.Equal(t, 5, minWithTen(5), "minWithTen(5) should equal 5")
assert.Equal(t, 10, minWithTen(15), "minWithTen(15) should equal 10")
assert.Equal(t, 10, minWithTen(10), "minWithTen(10) should equal 10")
assert.Equal(t, -5, minWithTen(-5), "minWithTen(-5) should equal -5")
})
}
// TestFromSemigroupComposition tests that endomorphisms created from semigroups can be composed
func TestFromSemigroupComposition(t *testing.T) {
t.Run("compose addition endomorphisms", func(t *testing.T) {
// Create a semigroup for integer addition
addSemigroup := S.MakeSemigroup(func(a, b int) int {
return a + b
})
addKleisli := FromSemigroup(addSemigroup)
// Create two endomorphisms
addFive := addKleisli(5)
addTen := addKleisli(10)
// Compose them (RIGHT-TO-LEFT execution)
composed := MonadCompose(addFive, addTen)
// Test composition: addTen first, then addFive
result := composed(3) // 3 + 10 = 13, then 13 + 5 = 18
assert.Equal(t, 18, result, "composed addition should work correctly")
})
t.Run("compose string endomorphisms", func(t *testing.T) {
// Create a semigroup for string concatenation
concatSemigroup := S.MakeSemigroup(func(a, b string) string {
return a + b
})
concatKleisli := FromSemigroup(concatSemigroup)
// Create two endomorphisms
appendHello := concatKleisli("Hello, ")
appendExclamation := concatKleisli("!")
// Compose them (RIGHT-TO-LEFT execution)
composed := MonadCompose(appendHello, appendExclamation)
// Test composition: appendExclamation first, then appendHello
// "World" + "!" = "World!", then "World!" + "Hello, " = "World!Hello, "
result := composed("World")
assert.Equal(t, "World!Hello, ", result, "composed string operations should work correctly")
})
}
// TestFromSemigroupWithMonoid tests using FromSemigroup-created endomorphisms with monoid operations
func TestFromSemigroupWithMonoid(t *testing.T) {
t.Run("monoid concat with addition endomorphisms", func(t *testing.T) {
// Create a semigroup for integer addition
addSemigroup := S.MakeSemigroup(func(a, b int) int {
return a + b
})
addKleisli := FromSemigroup(addSemigroup)
// Create multiple endomorphisms
addOne := addKleisli(1)
addTwo := addKleisli(2)
addThree := addKleisli(3)
// Use monoid to combine them
monoid := Monoid[int]()
combined := monoid.Concat(monoid.Concat(addOne, addTwo), addThree)
// Test: RIGHT-TO-LEFT execution: addThree, then addTwo, then addOne
result := combined(10) // 10 + 3 = 13, 13 + 2 = 15, 15 + 1 = 16
assert.Equal(t, 16, result, "monoid combination should work correctly")
})
}
// TestFromSemigroupAssociativity tests that the semigroup associativity is preserved
func TestFromSemigroupAssociativity(t *testing.T) {
t.Run("addition associativity", func(t *testing.T) {
// Create a semigroup for integer addition
addSemigroup := S.MakeSemigroup(func(a, b int) int {
return a + b
})
addKleisli := FromSemigroup(addSemigroup)
// Create three endomorphisms
addTwo := addKleisli(2)
addThree := addKleisli(3)
addFive := addKleisli(5)
// Test associativity: (a . b) . c = a . (b . c)
left := MonadCompose(MonadCompose(addTwo, addThree), addFive)
right := MonadCompose(addTwo, MonadCompose(addThree, addFive))
testValue := 10
assert.Equal(t, left(testValue), right(testValue), "composition should be associative")
// Both should equal: 10 + 5 + 3 + 2 = 20
assert.Equal(t, 20, left(testValue), "left composition should equal 20")
assert.Equal(t, 20, right(testValue), "right composition should equal 20")
})
t.Run("string concatenation associativity", func(t *testing.T) {
// Create a semigroup for string concatenation
concatSemigroup := S.MakeSemigroup(func(a, b string) string {
return a + b
})
concatKleisli := FromSemigroup(concatSemigroup)
// Create three endomorphisms
appendA := concatKleisli("A")
appendB := concatKleisli("B")
appendC := concatKleisli("C")
// Test associativity: (a . b) . c = a . (b . c)
left := MonadCompose(MonadCompose(appendA, appendB), appendC)
right := MonadCompose(appendA, MonadCompose(appendB, appendC))
testValue := "X"
assert.Equal(t, left(testValue), right(testValue), "string composition should be associative")
// Both should equal: "X" + "C" + "B" + "A" = "XCBA" (RIGHT-TO-LEFT composition)
assert.Equal(t, "XCBA", left(testValue), "left composition should equal 'XCBA'")
assert.Equal(t, "XCBA", right(testValue), "right composition should equal 'XCBA'")
})
}
// TestFromSemigroupEdgeCases tests edge cases and boundary conditions
func TestFromSemigroupEdgeCases(t *testing.T) {
t.Run("zero values", func(t *testing.T) {
// Test with addition and zero
addSemigroup := S.MakeSemigroup(func(a, b int) int {
return a + b
})
addKleisli := FromSemigroup(addSemigroup)
addZero := addKleisli(0)
assert.Equal(t, 5, addZero(5), "adding zero should not change the value")
assert.Equal(t, 0, addZero(0), "adding zero to zero should be zero")
assert.Equal(t, -3, addZero(-3), "adding zero to negative should not change")
})
t.Run("empty string", func(t *testing.T) {
// Test with string concatenation and empty string
concatSemigroup := S.MakeSemigroup(func(a, b string) string {
return a + b
})
concatKleisli := FromSemigroup(concatSemigroup)
prependEmpty := concatKleisli("")
assert.Equal(t, "hello", prependEmpty("hello"), "prepending empty string should not change")
assert.Equal(t, "", prependEmpty(""), "prepending empty to empty should be empty")
})
t.Run("empty slice", func(t *testing.T) {
// Test with slice concatenation and empty slice
sliceSemigroup := S.MakeSemigroup(func(a, b []int) []int {
result := make([]int, len(a)+len(b))
copy(result, a)
copy(result[len(a):], b)
return result
})
sliceKleisli := FromSemigroup(sliceSemigroup)
prependEmpty := sliceKleisli([]int{})
result := prependEmpty([]int{1, 2, 3})
assert.Equal(t, []int{1, 2, 3}, result, "prepending empty slice should not change")
emptyResult := prependEmpty([]int{})
assert.Equal(t, []int{}, emptyResult, "prepending empty to empty should be empty")
})
}
// TestFromSemigroupDataLastPrinciple explicitly tests that FromSemigroup follows the "data last" principle
func TestFromSemigroupDataLastPrinciple(t *testing.T) {
t.Run("data last with string concatenation", func(t *testing.T) {
// Create a semigroup for string concatenation
// Concat(a, b) = a + b
concatSemigroup := S.MakeSemigroup(func(a, b string) string {
return a + b
})
// FromSemigroup uses Bind2of2, which binds the second parameter
// So FromSemigroup(s)(x) creates: func(input) = Concat(input, x)
// This is "data last" - the input data comes first, bound value comes last
kleisli := FromSemigroup(concatSemigroup)
// Bind "World" as the second parameter
appendWorld := kleisli("World")
// When we call appendWorld("Hello"), it computes Concat("Hello", "World")
// The input "Hello" is the first parameter (data), "World" is the second (bound value)
result := appendWorld("Hello")
assert.Equal(t, "HelloWorld", result, "Data last: Concat(input='Hello', bound='World') = 'HelloWorld'")
// Verify with different input
result2 := appendWorld("Goodbye")
assert.Equal(t, "GoodbyeWorld", result2, "Data last: Concat(input='Goodbye', bound='World') = 'GoodbyeWorld'")
})
t.Run("data last with integer addition", func(t *testing.T) {
// Create a semigroup for integer addition
// Concat(a, b) = a + b
addSemigroup := S.MakeSemigroup(func(a, b int) int {
return a + b
})
// FromSemigroup binds the second parameter
// So FromSemigroup(s)(5) creates: func(input) = Concat(input, 5) = input + 5
kleisli := FromSemigroup(addSemigroup)
// Bind 5 as the second parameter
addFive := kleisli(5)
// When we call addFive(10), it computes Concat(10, 5) = 10 + 5 = 15
// The input 10 is the first parameter (data), 5 is the second (bound value)
result := addFive(10)
assert.Equal(t, 15, result, "Data last: Concat(input=10, bound=5) = 15")
})
t.Run("data last with non-commutative operation", func(t *testing.T) {
// Create a semigroup for a non-commutative operation to clearly show order
// Concat(a, b) = a - b (subtraction is not commutative)
subSemigroup := S.MakeSemigroup(func(a, b int) int {
return a - b
})
// FromSemigroup binds the second parameter
// So FromSemigroup(s)(5) creates: func(input) = Concat(input, 5) = input - 5
kleisli := FromSemigroup(subSemigroup)
// Bind 5 as the second parameter
subtractFive := kleisli(5)
// When we call subtractFive(10), it computes Concat(10, 5) = 10 - 5 = 5
// The input 10 is the first parameter (data), 5 is the second (bound value)
result := subtractFive(10)
assert.Equal(t, 5, result, "Data last: Concat(input=10, bound=5) = 10 - 5 = 5")
// If it were "data first" (binding first parameter), we would get:
// Concat(5, 10) = 5 - 10 = -5, which is NOT what we get
assert.NotEqual(t, -5, result, "Not data first: result is NOT Concat(bound=5, input=10) = 5 - 10 = -5")
})
t.Run("data last with list concatenation", func(t *testing.T) {
// Create a semigroup for list concatenation
// Concat(a, b) = a ++ b
listSemigroup := S.MakeSemigroup(func(a, b []int) []int {
result := make([]int, len(a)+len(b))
copy(result, a)
copy(result[len(a):], b)
return result
})
// FromSemigroup binds the second parameter
// So FromSemigroup(s)([3,4]) creates: func(input) = Concat(input, [3,4])
kleisli := FromSemigroup(listSemigroup)
// Bind [3, 4] as the second parameter
appendThreeFour := kleisli([]int{3, 4})
// When we call appendThreeFour([1,2]), it computes Concat([1,2], [3,4]) = [1,2,3,4]
// The input [1,2] is the first parameter (data), [3,4] is the second (bound value)
result := appendThreeFour([]int{1, 2})
assert.Equal(t, []int{1, 2, 3, 4}, result, "Data last: Concat(input=[1,2], bound=[3,4]) = [1,2,3,4]")
})
}
// BenchmarkFromSemigroup benchmarks the FromSemigroup function
func BenchmarkFromSemigroup(b *testing.B) {
addSemigroup := S.MakeSemigroup(func(a, b int) int {
return a + b
})
addKleisli := FromSemigroup(addSemigroup)
addFive := addKleisli(5)
b.ResetTimer()
for b.Loop() {
_ = addFive(10)
}
}
// BenchmarkFromSemigroupComposition benchmarks composed endomorphisms from semigroups
func BenchmarkFromSemigroupComposition(b *testing.B) {
addSemigroup := S.MakeSemigroup(func(a, b int) int {
return a + b
})
addKleisli := FromSemigroup(addSemigroup)
addFive := addKleisli(5)
addTen := addKleisli(10)
composed := MonadCompose(addFive, addTen)
b.ResetTimer()
for b.Loop() {
_ = composed(3)
}
}

8
v2/eq/eq_test.go
View File

@@ -72,9 +72,7 @@ func TestFromStrictEquals(t *testing.T) {
func TestFromEquals(t *testing.T) {
t.Run("case-insensitive string equality", func(t *testing.T) {
caseInsensitiveEq := FromEquals(func(a, b string) bool {
return strings.EqualFold(a, b)
})
caseInsensitiveEq := FromEquals(strings.EqualFold)
assert.True(t, caseInsensitiveEq.Equals("hello", "HELLO"))
assert.True(t, caseInsensitiveEq.Equals("Hello", "hello"))
@@ -243,9 +241,7 @@ func TestContramap(t *testing.T) {
})
t.Run("case-insensitive name comparison", func(t *testing.T) {
caseInsensitiveEq := FromEquals(func(a, b string) bool {
return strings.EqualFold(a, b)
})
caseInsensitiveEq := FromEquals(strings.EqualFold)
personEqByNameCI := Contramap(func(p Person) string {
return p.Name

23
v2/function/function.go
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@@ -53,7 +53,10 @@ func Identity[A any](a A) A {
//
// getMessage := Constant("Hello")
// msg := getMessage() // "Hello"
//
//go:inline
func Constant[A any](a A) func() A {
//go:inline
return func() A {
return a
}
@@ -81,7 +84,10 @@ func Constant[A any](a A) func() A {
//
// defaultName := Constant1[int, string]("Unknown")
// name := defaultName(42) // "Unknown"
//
//go:inline
func Constant1[B, A any](a A) func(B) A {
//go:inline
return func(_ B) A {
return a
}
@@ -107,7 +113,10 @@ func Constant1[B, A any](a A) func(B) A {
//
// alwaysTrue := Constant2[int, string, bool](true)
// result := alwaysTrue(42, "test") // true
//
//go:inline
func Constant2[B, C, A any](a A) func(B, C) A {
//go:inline
return func(_ B, _ C) A {
return a
}
@@ -128,6 +137,8 @@ func Constant2[B, C, A any](a A) func(B, C) A {
//
// value := 42
// IsNil(&value) // false
//
//go:inline
func IsNil[A any](a *A) bool {
return a == nil
}
@@ -149,6 +160,8 @@ func IsNil[A any](a *A) bool {
//
// value := 42
// IsNonNil(&value) // true
//
//go:inline
func IsNonNil[A any](a *A) bool {
return a != nil
}
@@ -207,6 +220,8 @@ func Swap[T1, T2, R any](f func(T1, T2) R) func(T2, T1) R {
//
// result := First(42, "hello") // 42
// result := First(true, 100) // true
//
//go:inline
func First[T1, T2 any](t1 T1, _ T2) T1 {
return t1
}
@@ -231,6 +246,14 @@ func First[T1, T2 any](t1 T1, _ T2) T1 {
//
// result := Second(42, "hello") // "hello"
// result := Second(true, 100) // 100
//
//go:inline
func Second[T1, T2 any](_ T1, t2 T2) T2 {
return t2
}
// Zero returns the zero value of the given type.
func Zero[A comparable]() A {
var zero A
return zero
}

4
v2/function/gen.go
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@@ -117,9 +117,13 @@ func Nullary2[F1 ~func() T1, F2 ~func(T1) T2, T1, T2 any](f1 F1, f2 F2) func() T
// Curry2 takes a function with 2 parameters and returns a cascade of functions each taking only one parameter.
// The inverse function is [Uncurry2]
//go:inline
func Curry2[FCT ~func(T0, T1) T2, T0, T1, T2 any](f FCT) func(T0) func(T1) T2 {
//go:inline
return func(t0 T0) func(t1 T1) T2 {
//go:inline
return func(t1 T1) T2 {
//go:inline
return f(t0, t1)
}
}

4
v2/function/ternary.go
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@@ -36,7 +36,7 @@ package function
// Example:
//
// isPositive := func(n int) bool { return n > 0 }
// double := func(n int) int { return n * 2 }
// double := N.Mul(2)
// negate := func(n int) int { return -n }
//
// transform := Ternary(isPositive, double, negate)
@@ -51,7 +51,7 @@ package function
// )
// result := classify(5) // "positive"
// result2 := classify(-3) // "non-positive"
func Ternary[A, B any](pred func(A) bool, onTrue func(A) B, onFalse func(A) B) func(A) B {
func Ternary[A, B any](pred func(A) bool, onTrue, onFalse func(A) B) func(A) B {
return func(a A) B {
if pred(a) {
return onTrue(a)

6
v2/http/builder/builder.go
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@@ -246,7 +246,7 @@ func (builder *Builder) GetTargetURL() Result[string] {
parseQuery,
result.Map(F.Flow2(
F.Curry2(FM.ValuesMonoid.Concat)(builder.GetQuery()),
(url.Values).Encode,
url.Values.Encode,
)),
),
),
@@ -351,13 +351,13 @@ func Header(name string) Lens[*Builder, Option[string]] {
LZ.Map(delHeader(name)),
)
return L.MakeLens(get, func(b *Builder, value Option[string]) *Builder {
return L.MakeLensWithName(get, func(b *Builder, value Option[string]) *Builder {
cpy := b.clone()
return F.Pipe1(
value,
O.Fold(del(cpy), set(cpy)),
)
})
}, fmt.Sprintf("HttpHeader[%s]", name))
}
// WithHeader creates a [Endomorphism] for a certain header

22
v2/identity/doc.go
View File

@@ -16,6 +16,18 @@
/*
Package identity implements the Identity monad, the simplest possible monad.
# Fantasy Land Specification
This implementation corresponds to the Fantasy Land Identity type:
https://github.com/fantasyland/fantasy-land
Implemented Fantasy Land algebras:
- Functor: https://github.com/fantasyland/fantasy-land#functor
- Apply: https://github.com/fantasyland/fantasy-land#apply
- Applicative: https://github.com/fantasyland/fantasy-land#applicative
- Chain: https://github.com/fantasyland/fantasy-land#chain
- Monad: https://github.com/fantasyland/fantasy-land#monad
# Overview
The Identity monad is a trivial monad that simply wraps a value without adding
@@ -107,8 +119,8 @@ Chain for sequential composition:
// Chain multiple operations
result := F.Pipe2(
10,
identity.Chain(func(n int) int { return n * 2 }),
identity.Chain(func(n int) int { return n + 5 }),
identity.Chain(N.Mul(2)),
identity.Chain(N.Add(5)),
)
// result is 25
@@ -177,8 +189,8 @@ Convert tuples of Identity values:
// Traverse with transformation
tuple := T.MakeTuple2(1, 2)
result := identity.TraverseTuple2(
func(n int) int { return n * 2 },
func(n int) int { return n * 3 },
N.Mul(2),
N.Mul(3),
)(tuple)
// result is T.Tuple2[int, int]{2, 6}
@@ -211,7 +223,7 @@ Example of generic code:
) M {
return F.Pipe2(
monad.Of(value),
monad.Map(func(n int) int { return n * 2 }),
monad.Map(N.Mul(2)),
monad.Map(func(n int) string { return fmt.Sprintf("%d", n) }),
)
}

127
v2/identity/identity_test.go
View File

@@ -17,10 +17,13 @@ package identity
import (
"fmt"
"strconv"
"testing"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/internal/utils"
N "github.com/IBM/fp-go/v2/number"
S "github.com/IBM/fp-go/v2/string"
T "github.com/IBM/fp-go/v2/tuple"
"github.com/stretchr/testify/assert"
)
@@ -51,17 +54,15 @@ func TestMap(t *testing.T) {
})
t.Run("transforms string", func(t *testing.T) {
result := F.Pipe1("hello", Map(func(s string) int {
return len(s)
}))
result := F.Pipe1("hello", Map(S.Size))
assert.Equal(t, 5, result)
})
t.Run("chains multiple maps", func(t *testing.T) {
result := F.Pipe2(
5,
Map(func(n int) int { return n * 2 }),
Map(func(n int) int { return n + 3 }),
Map(N.Mul(2)),
Map(N.Add(3)),
)
assert.Equal(t, 13, result)
})
@@ -69,14 +70,12 @@ func TestMap(t *testing.T) {
func TestMonadMap(t *testing.T) {
t.Run("transforms value", func(t *testing.T) {
result := MonadMap(10, func(n int) int { return n * 3 })
result := MonadMap(10, N.Mul(3))
assert.Equal(t, 30, result)
})
t.Run("changes type", func(t *testing.T) {
result := MonadMap(42, func(n int) string {
return fmt.Sprintf("Number: %d", n)
})
result := MonadMap(42, S.Format[int]("Number: %d"))
assert.Equal(t, "Number: 42", result)
})
}
@@ -109,23 +108,21 @@ func TestChain(t *testing.T) {
t.Run("chains multiple operations", func(t *testing.T) {
result := F.Pipe2(
10,
Chain(func(n int) int { return n * 2 }),
Chain(func(n int) int { return n + 5 }),
Chain(N.Mul(2)),
Chain(N.Add(5)),
)
assert.Equal(t, 25, result)
})
t.Run("changes type", func(t *testing.T) {
result := F.Pipe1(5, Chain(func(n int) string {
return fmt.Sprintf("Value: %d", n)
}))
result := F.Pipe1(5, Chain(S.Format[int]("Value: %d")))
assert.Equal(t, "Value: 5", result)
})
}
func TestMonadChain(t *testing.T) {
t.Run("chains computation", func(t *testing.T) {
result := MonadChain(7, func(n int) int { return n * 7 })
result := MonadChain(7, N.Mul(7))
assert.Equal(t, 49, result)
})
}
@@ -148,7 +145,7 @@ func TestChainFirst(t *testing.T) {
result := F.Pipe2(
10,
ChainFirst(func(n int) string { return "ignored" }),
Map(func(n int) int { return n * 2 }),
Map(N.Mul(2)),
)
assert.Equal(t, 20, result)
})
@@ -156,9 +153,7 @@ func TestChainFirst(t *testing.T) {
func TestMonadChainFirst(t *testing.T) {
t.Run("keeps original value", func(t *testing.T) {
result := MonadChainFirst(100, func(n int) string {
return fmt.Sprintf("%d", n)
})
result := MonadChainFirst(100, strconv.Itoa)
assert.Equal(t, 100, result)
})
}
@@ -170,17 +165,13 @@ func TestAp(t *testing.T) {
})
t.Run("applies curried function", func(t *testing.T) {
add := func(a int) func(int) int {
return func(b int) int { return a + b }
}
add := N.Add[int]
result := F.Pipe1(add(10), Ap[int](5))
assert.Equal(t, 15, result)
})
t.Run("changes type", func(t *testing.T) {
toString := func(n int) string {
return fmt.Sprintf("Number: %d", n)
}
toString := S.Format[int]("Number: %d")
result := F.Pipe1(toString, Ap[string](42))
assert.Equal(t, "Number: 42", result)
})
@@ -188,22 +179,22 @@ func TestAp(t *testing.T) {
func TestMonadAp(t *testing.T) {
t.Run("applies function to value", func(t *testing.T) {
result := MonadAp(func(n int) int { return n * 3 }, 7)
result := MonadAp(N.Mul(3), 7)
assert.Equal(t, 21, result)
})
}
func TestFlap(t *testing.T) {
t.Run("flips application", func(t *testing.T) {
double := func(n int) int { return n * 2 }
double := N.Mul(2)
result := F.Pipe1(double, Flap[int](5))
assert.Equal(t, 10, result)
})
t.Run("with multiple functions", func(t *testing.T) {
funcs := []func(int) int{
func(n int) int { return n * 2 },
func(n int) int { return n + 10 },
N.Mul(2),
N.Add(10),
func(n int) int { return n * n },
}
@@ -218,9 +209,7 @@ func TestFlap(t *testing.T) {
func TestMonadFlap(t *testing.T) {
t.Run("applies value to function", func(t *testing.T) {
result := MonadFlap(func(n int) string {
return fmt.Sprintf("Value: %d", n)
}, 42)
result := MonadFlap(S.Format[int]("Value: %d"), 42)
assert.Equal(t, "Value: 42", result)
})
}
@@ -391,8 +380,8 @@ func TestTraverseTuple(t *testing.T) {
t.Run("TraverseTuple2", func(t *testing.T) {
tuple := T.MakeTuple2(1, 2)
result := TraverseTuple2(
func(n int) int { return n * 2 },
func(n int) int { return n * 3 },
N.Mul(2),
N.Mul(3),
)(tuple)
assert.Equal(t, T.MakeTuple2(2, 6), result)
})
@@ -400,7 +389,7 @@ func TestTraverseTuple(t *testing.T) {
t.Run("TraverseTuple3", func(t *testing.T) {
tuple := T.MakeTuple3(1, 2, 3)
result := TraverseTuple3(
func(n int) int { return n + 10 },
N.Add(10),
func(n int) int { return n + 20 },
func(n int) int { return n + 30 },
)(tuple)
@@ -426,15 +415,11 @@ func TestMonad(t *testing.T) {
assert.Equal(t, 42, value)
// Test Map
mapped := m.Map(func(n int) string {
return fmt.Sprintf("Number: %d", n)
})(value)
mapped := m.Map(S.Format[int]("Number: %d"))(value)
assert.Equal(t, "Number: 42", mapped)
// Test Chain
chained := m.Chain(func(n int) string {
return fmt.Sprintf("Value: %d", n)
})(value)
chained := m.Chain(S.Format[int]("Value: %d"))(value)
assert.Equal(t, "Value: 42", chained)
// Test Ap
@@ -450,7 +435,7 @@ func TestMonadLaws(t *testing.T) {
t.Run("left identity", func(t *testing.T) {
// Of(a).Chain(f) === f(a)
a := 42
f := func(n int) int { return n * 2 }
f := N.Mul(2)
left := F.Pipe1(Of(a), Chain(f))
right := f(a)
@@ -470,8 +455,8 @@ func TestMonadLaws(t *testing.T) {
t.Run("associativity", func(t *testing.T) {
// m.Chain(f).Chain(g) === m.Chain(x => f(x).Chain(g))
m := 5
f := func(n int) int { return n * 2 }
g := func(n int) int { return n + 10 }
f := N.Mul(2)
g := N.Add(10)
left := F.Pipe2(m, Chain(f), Chain(g))
right := F.Pipe1(m, Chain(func(x int) int {
@@ -496,8 +481,8 @@ func TestFunctorLaws(t *testing.T) {
t.Run("composition", func(t *testing.T) {
// Map(f).Map(g) === Map(g ∘ f)
value := 5
f := func(n int) int { return n * 2 }
g := func(n int) int { return n + 10 }
f := N.Mul(2)
g := N.Add(10)
left := F.Pipe2(value, Map(f), Map(g))
right := F.Pipe1(value, Map(F.Flow2(f, g)))
@@ -541,7 +526,7 @@ func TestTraverseTuple4(t *testing.T) {
t.Run("traverses tuple4", func(t *testing.T) {
tuple := T.MakeTuple4(1, 2, 3, 4)
result := TraverseTuple4(
func(n int) int { return n + 10 },
N.Add(10),
func(n int) int { return n + 20 },
func(n int) int { return n + 30 },
func(n int) int { return n + 40 },
@@ -570,8 +555,8 @@ func TestTraverseTuple5(t *testing.T) {
tuple := T.MakeTuple5(1, 2, 3, 4, 5)
result := TraverseTuple5(
func(n int) int { return n * 1 },
func(n int) int { return n * 2 },
func(n int) int { return n * 3 },
N.Mul(2),
N.Mul(3),
func(n int) int { return n * 4 },
func(n int) int { return n * 5 },
)(tuple)
@@ -598,11 +583,11 @@ func TestTraverseTuple6(t *testing.T) {
t.Run("traverses tuple6", func(t *testing.T) {
tuple := T.MakeTuple6(1, 2, 3, 4, 5, 6)
result := TraverseTuple6(
func(n int) int { return n + 1 },
N.Add(1),
func(n int) int { return n + 2 },
func(n int) int { return n + 3 },
N.Add(3),
func(n int) int { return n + 4 },
func(n int) int { return n + 5 },
N.Add(5),
func(n int) int { return n + 6 },
)(tuple)
assert.Equal(t, T.MakeTuple6(2, 4, 6, 8, 10, 12), result)
@@ -691,15 +676,15 @@ func TestTraverseTuple9(t *testing.T) {
t.Run("traverses tuple9", func(t *testing.T) {
tuple := T.MakeTuple9(1, 2, 3, 4, 5, 6, 7, 8, 9)
result := TraverseTuple9(
func(n int) int { return n + 1 },
func(n int) int { return n + 1 },
func(n int) int { return n + 1 },
func(n int) int { return n + 1 },
func(n int) int { return n + 1 },
func(n int) int { return n + 1 },
func(n int) int { return n + 1 },
func(n int) int { return n + 1 },
func(n int) int { return n + 1 },
N.Add(1),
N.Add(1),
N.Add(1),
N.Add(1),
N.Add(1),
N.Add(1),
N.Add(1),
N.Add(1),
N.Add(1),
)(tuple)
assert.Equal(t, T.MakeTuple9(2, 3, 4, 5, 6, 7, 8, 9, 10), result)
})
@@ -724,16 +709,16 @@ func TestTraverseTuple10(t *testing.T) {
t.Run("traverses tuple10", func(t *testing.T) {
tuple := T.MakeTuple10(1, 2, 3, 4, 5, 6, 7, 8, 9, 10)
result := TraverseTuple10(
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
func(n int) int { return n * 2 },
N.Mul(2),
N.Mul(2),
N.Mul(2),
N.Mul(2),
N.Mul(2),
N.Mul(2),
N.Mul(2),
N.Mul(2),
N.Mul(2),
N.Mul(2),
)(tuple)
assert.Equal(t, T.MakeTuple10(2, 4, 6, 8, 10, 12, 14, 16, 18, 20), result)
})

1033
v2/idiomatic/context/readerresult/README.md Normal file
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75
v2/idiomatic/context/readerresult/array.go Normal file
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@@ -0,0 +1,75 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
RR "github.com/IBM/fp-go/v2/idiomatic/readerresult"
)
// TraverseArray applies a ReaderResult-returning function to each element of an array,
// collecting the results. If any element fails, the entire operation fails with the first error.
//
// Example:
//
// parseUser := func(id int) readerresult.ReaderResult[DB, User] { ... }
// ids := []int{1, 2, 3}
// result := readerresult.TraverseArray[DB](parseUser)(ids)
// // result(db) returns ([]User, nil) with all users or (nil, error) on first error
//
//go:inline
func TraverseArray[A, B any](f Kleisli[A, B]) Kleisli[[]A, []B] {
return RR.TraverseArray(f)
}
//go:inline
func MonadTraverseArray[A, B any](as []A, f Kleisli[A, B]) ReaderResult[[]B] {
return RR.MonadTraverseArray(as, f)
}
// TraverseArrayWithIndex is like TraverseArray but the function also receives the element's index.
// This is useful when the transformation depends on the position in the array.
//
// Example:
//
// processItem := func(idx int, item string) readerresult.ReaderResult[Config, int] {
// return readerresult.Of[Config](idx + len(item))
// }
// items := []string{"a", "bb", "ccc"}
// result := readerresult.TraverseArrayWithIndex[Config](processItem)(items)
//
//go:inline
func TraverseArrayWithIndex[A, B any](f func(int, A) ReaderResult[B]) Kleisli[[]A, []B] {
return RR.TraverseArrayWithIndex(f)
}
// SequenceArray converts an array of ReaderResult values into a single ReaderResult of an array.
// If any element fails, the entire operation fails with the first error encountered.
// All computations share the same environment.
//
// Example:
//
// readers := []readerresult.ReaderResult[Config, int]{
// readerresult.Of[Config](1),
// readerresult.Of[Config](2),
// readerresult.Of[Config](3),
// }
// result := readerresult.SequenceArray(readers)
// // result(cfg) returns ([]int{1, 2, 3}, nil)
//
//go:inline
func SequenceArray[A any](ma []ReaderResult[A]) ReaderResult[[]A] {
return RR.SequenceArray(ma)
}

456
v2/idiomatic/context/readerresult/bind.go Normal file
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@@ -0,0 +1,456 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
RR "github.com/IBM/fp-go/v2/idiomatic/readerresult"
"github.com/IBM/fp-go/v2/idiomatic/result"
AP "github.com/IBM/fp-go/v2/internal/apply"
C "github.com/IBM/fp-go/v2/internal/chain"
"github.com/IBM/fp-go/v2/reader"
RES "github.com/IBM/fp-go/v2/result"
)
// Do initializes a do-notation context with an empty state.
//
// This is the starting point for do-notation style composition, which allows
// imperative-style sequencing of ReaderResult computations while maintaining
// functional purity.
//
// Type Parameters:
// - S: The state type
//
// Parameters:
// - empty: The initial empty state
//
// Returns:
// - A ReaderResult[S] containing the initial state
//
//go:inline
func Do[S any](
empty S,
) ReaderResult[S] {
return RR.Do[context.Context](empty)
}
// Bind sequences an EFFECTFUL ReaderResult computation and updates the state with its result.
//
// IMPORTANT: Bind is for EFFECTFUL FUNCTIONS that depend on context.Context.
// The Kleisli parameter (State -> ReaderResult[T]) is effectful because ReaderResult
// depends on context.Context (can be cancelled, has deadlines, carries values).
//
// For PURE FUNCTIONS (side-effect free), use:
// - BindResultK: For pure functions with errors (State -> (Value, error))
// - Let: For pure functions without errors (State -> Value)
//
// This is the core operation for do-notation, allowing you to chain computations
// where each step can depend on the accumulated state and update it with new values.
//
// Type Parameters:
// - S1: The input state type
// - S2: The output state type
// - T: The type of value produced by the computation
//
// Parameters:
// - setter: A function that takes the computation result and returns a state updater
// - f: A Kleisli arrow that produces the next effectful computation based on current state
//
// Returns:
// - An Operator that transforms ReaderResult[S1] to ReaderResult[S2]
//
//go:inline
func Bind[S1, S2, T any](
setter func(T) func(S1) S2,
f Kleisli[S1, T],
) Operator[S1, S2] {
return C.Bind(
Chain[S1, S2],
Map[T, S2],
setter,
WithContextK(f),
)
}
// Let attaches the result of a PURE computation to a state.
//
// IMPORTANT: Let is for PURE FUNCTIONS (side-effect free) that don't depend on context.Context.
// The function parameter (State -> Value) is pure - it only reads from state with no effects.
//
// For EFFECTFUL FUNCTIONS (that need context.Context), use:
// - Bind: For effectful ReaderResult computations (State -> ReaderResult[Value])
//
// For PURE FUNCTIONS with error handling, use:
// - BindResultK: For pure functions with errors (State -> (Value, error))
//
// Unlike Bind, Let works with pure functions (not ReaderResult computations).
// This is useful for deriving values from the current state without performing
// any effects.
//
// Type Parameters:
// - S1: The input state type
// - S2: The output state type
// - T: The type of value computed
//
// Parameters:
// - setter: A function that takes the computed value and returns a state updater
// - f: A pure function that computes a value from the current state
//
// Returns:
// - An Operator that transforms ReaderResult[S1] to ReaderResult[S2]
//
//go:inline
func Let[S1, S2, T any](
setter func(T) func(S1) S2,
f func(S1) T,
) Operator[S1, S2] {
return RR.Let[context.Context](setter, f)
}
// LetTo attaches a constant value to a state.
// This is a PURE operation (side-effect free).
//
// This is a simplified version of Let for when you want to add a constant
// value to the state without computing it.
//
// Type Parameters:
// - S1: The input state type
// - S2: The output state type
// - T: The type of the constant value
//
// Parameters:
// - setter: A function that takes the constant and returns a state updater
// - b: The constant value to attach
//
// Returns:
// - An Operator that transforms ReaderResult[S1] to ReaderResult[S2]
//
//go:inline
func LetTo[S1, S2, T any](
setter func(T) func(S1) S2,
b T,
) Operator[S1, S2] {
return RR.LetTo[context.Context](setter, b)
}
// BindTo initializes do-notation by binding a value to a state.
//
// This is typically used as the first operation after a computation to
// start building up a state structure.
//
// Type Parameters:
// - S1: The state type to create
// - T: The type of the initial value
//
// Parameters:
// - setter: A function that creates the initial state from a value
//
// Returns:
// - An Operator that transforms ReaderResult[T] to ReaderResult[S1]
//
//go:inline
func BindTo[S1, T any](
setter func(T) S1,
) Operator[T, S1] {
return RR.BindTo[context.Context](setter)
}
// BindToP initializes do-notation by binding a value to a state using a Prism.
//
// This is a variant of BindTo that uses a prism instead of a setter function.
// Prisms are useful for working with sum types and optional values.
//
// Type Parameters:
// - S1: The state type to create
// - T: The type of the initial value
//
// Parameters:
// - setter: A prism that can construct the state from a value
//
// Returns:
// - An Operator that transforms ReaderResult[T] to ReaderResult[S1]
//
//go:inline
func BindToP[S1, T any](
setter Prism[S1, T],
) Operator[T, S1] {
return BindTo(setter.ReverseGet)
}
// ApS attaches a value to a context using applicative style.
//
// IMPORTANT: ApS is for EFFECTFUL FUNCTIONS that depend on context.Context.
// The ReaderResult parameter is effectful because it depends on context.Context.
//
// Unlike Bind (which sequences operations), ApS can be used when operations are
// independent and can conceptually run in parallel.
//
// Type Parameters:
// - S1: The input state type
// - S2: The output state type
// - T: The type of value produced by the computation
//
// Parameters:
// - setter: A function that takes the computation result and returns a state updater
// - fa: An effectful ReaderResult computation
//
// Returns:
// - An Operator that transforms ReaderResult[S1] to ReaderResult[S2]
//
//go:inline
func ApS[S1, S2, T any](
setter func(T) func(S1) S2,
fa ReaderResult[T],
) Operator[S1, S2] {
return AP.ApS(
Ap[S2, T],
Map[S1, func(T) S2],
setter,
fa,
)
}
// ApSL is a variant of ApS that uses a lens to focus on a specific field in the state.
//
// IMPORTANT: ApSL is for EFFECTFUL FUNCTIONS that depend on context.Context.
// The ReaderResult parameter is effectful because it depends on context.Context.
//
// Instead of providing a setter function, you provide a lens that knows how to get and set
// the field. This is more convenient when working with nested structures.
//
// Type Parameters:
// - S: The state type
// - T: The type of the field to update
//
// Parameters:
// - lens: A lens that focuses on a field of type T within state S
// - fa: An effectful ReaderResult computation that produces a value of type T
//
// Returns:
// - An Operator that transforms ReaderResult[S] to ReaderResult[S]
//
//go:inline
func ApSL[S, T any](
lens Lens[S, T],
fa ReaderResult[T],
) Operator[S, S] {
return ApS(lens.Set, fa)
}
// BindL is a variant of Bind that uses a lens to focus on a specific field in the state.
//
// IMPORTANT: BindL is for EFFECTFUL FUNCTIONS that depend on context.Context.
// The Kleisli parameter returns a ReaderResult, which is effectful.
//
// It combines lens-based field access with monadic composition, allowing you to:
// 1. Extract a field value using the lens
// 2. Use that value in an effectful computation that may fail
// 3. Update the field with the result
//
// Type Parameters:
// - S: The state type
// - T: The type of the field to update
//
// Parameters:
// - lens: A lens that focuses on a field of type T within state S
// - f: An effectful Kleisli arrow that transforms the field value
//
// Returns:
// - An Operator that transforms ReaderResult[S] to ReaderResult[S]
//
//go:inline
func BindL[S, T any](
lens Lens[S, T],
f Kleisli[T, T],
) Operator[S, S] {
return RR.BindL(lens, WithContextK(f))
}
// LetL is a variant of Let that uses a lens to focus on a specific field in the state.
//
// IMPORTANT: LetL is for PURE FUNCTIONS (side-effect free) that don't depend on context.Context.
// The endomorphism parameter is a pure function (T -> T) with no errors or effects.
//
// It applies a pure transformation to the focused field without any effects.
//
// Type Parameters:
// - S: The state type
// - T: The type of the field to update
//
// Parameters:
// - lens: A lens that focuses on a field of type T within state S
// - f: A pure endomorphism that transforms the field value
//
// Returns:
// - An Operator that transforms ReaderResult[S] to ReaderResult[S]
//
//go:inline
func LetL[S, T any](
lens Lens[S, T],
f Endomorphism[T],
) Operator[S, S] {
return RR.LetL[context.Context](lens, f)
}
// LetToL is a variant of LetTo that uses a lens to focus on a specific field in the state.
//
// IMPORTANT: LetToL is for setting constant values. This is a PURE operation (side-effect free).
//
// It sets the focused field to a constant value.
//
// Type Parameters:
// - S: The state type
// - T: The type of the field to update
//
// Parameters:
// - lens: A lens that focuses on a field of type T within state S
// - b: The constant value to set
//
// Returns:
// - An Operator that transforms ReaderResult[S] to ReaderResult[S]
//
//go:inline
func LetToL[S, T any](
lens Lens[S, T],
b T,
) Operator[S, S] {
return RR.LetToL[context.Context](lens, b)
}
// BindReaderK binds a Reader computation (context-dependent but error-free) into the do-notation chain.
//
// IMPORTANT: This is for functions that depend on context.Context but don't return errors.
// The Reader[Context, T] is effectful because it depends on context.Context.
// Use this when you need context values but the operation cannot fail.
//
//go:inline
func BindReaderK[S1, S2, T any](
setter func(T) func(S1) S2,
f reader.Kleisli[context.Context, S1, T],
) Operator[S1, S2] {
return RR.BindReaderK(setter, f)
}
// BindEitherK binds a Result (Either) computation into the do-notation chain.
//
// IMPORTANT: This is for PURE FUNCTIONS (side-effect free) that return Result[T].
// The function (State -> Result[T]) is pure - it only depends on state, not context.
// Use this for pure error-handling logic that doesn't need context.
//
//go:inline
func BindEitherK[S1, S2, T any](
setter func(T) func(S1) S2,
f RES.Kleisli[S1, T],
) Operator[S1, S2] {
return RR.BindEitherK[context.Context](setter, f)
}
// BindResultK binds an idiomatic Go function (returning value and error) into the do-notation chain.
//
// IMPORTANT: This is for PURE FUNCTIONS (side-effect free) that return (Value, error).
// The function (State -> (Value, error)) is pure - it only depends on state, not context.
// Use this for pure computations with error handling that don't need context.
//
// For EFFECTFUL FUNCTIONS (that need context.Context), use Bind instead.
//
//go:inline
func BindResultK[S1, S2, T any](
setter func(T) func(S1) S2,
f result.Kleisli[S1, T],
) Operator[S1, S2] {
return RR.BindResultK[context.Context](setter, f)
}
// BindToReader converts a Reader computation into a ReaderResult and binds it to create an initial state.
//
// IMPORTANT: Reader[Context, T] is EFFECTFUL because it depends on context.Context.
// Use this when you have a context-dependent computation that cannot fail.
//
//go:inline
func BindToReader[
S1, T any](
setter func(T) S1,
) func(Reader[context.Context, T]) ReaderResult[S1] {
return RR.BindToReader[context.Context](setter)
}
// BindToEither converts a Result (Either) into a ReaderResult and binds it to create an initial state.
//
// IMPORTANT: Result[T] is PURE (side-effect free) - it doesn't depend on context.
// Use this to lift pure error-handling values into the ReaderResult context.
//
//go:inline
func BindToEither[
S1, T any](
setter func(T) S1,
) func(Result[T]) ReaderResult[S1] {
return RR.BindToEither[context.Context](setter)
}
// BindToResult converts an idiomatic Go tuple (value, error) into a ReaderResult and binds it to create an initial state.
//
// IMPORTANT: The (Value, error) tuple is PURE (side-effect free) - it doesn't depend on context.
// Use this to lift pure Go error-handling results into the ReaderResult context.
//
//go:inline
func BindToResult[
S1, T any](
setter func(T) S1,
) func(T, error) ReaderResult[S1] {
return RR.BindToResult[context.Context](setter)
}
// ApReaderS applies a Reader computation in applicative style, combining it with the current state.
//
// IMPORTANT: Reader[Context, T] is EFFECTFUL because it depends on context.Context.
// Use this for context-dependent operations that cannot fail.
//
//go:inline
func ApReaderS[
S1, S2, T any](
setter func(T) func(S1) S2,
fa Reader[context.Context, T],
) Operator[S1, S2] {
return RR.ApReaderS(setter, fa)
}
// ApResultS applies an idiomatic Go tuple (value, error) in applicative style.
//
// IMPORTANT: The (Value, error) tuple is PURE (side-effect free) - it doesn't depend on context.
// Use this for pure Go error-handling results.
//
//go:inline
func ApResultS[
S1, S2, T any](
setter func(T) func(S1) S2,
) func(T, error) Operator[S1, S2] {
return RR.ApResultS[context.Context](setter)
}
// ApEitherS applies a Result (Either) in applicative style, combining it with the current state.
//
// IMPORTANT: Result[T] is PURE (side-effect free) - it doesn't depend on context.
// Use this for pure error-handling values.
//
//go:inline
func ApEitherS[
S1, S2, T any](
setter func(T) func(S1) S2,
fa Result[T],
) Operator[S1, S2] {
return RR.ApEitherS[context.Context](setter, fa)
}

627
v2/idiomatic/context/readerresult/bind_test.go Normal file
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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"errors"
"testing"
F "github.com/IBM/fp-go/v2/function"
N "github.com/IBM/fp-go/v2/number"
"github.com/IBM/fp-go/v2/reader"
RES "github.com/IBM/fp-go/v2/result"
"github.com/stretchr/testify/assert"
)
func TestDoInit(t *testing.T) {
initial := SimpleState{Value: 42}
result := Do(initial)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, initial, state)
}
func TestBind(t *testing.T) {
t.Run("successful bind", func(t *testing.T) {
// Effectful function that depends on context
fetchValue := func(s SimpleState) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return s.Value * 2, nil
}
}
result := F.Pipe1(
Do(SimpleState{Value: 21}),
Bind(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
fetchValue,
),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
})
t.Run("bind with error", func(t *testing.T) {
fetchValue := func(s SimpleState) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return 0, errors.New("fetch failed")
}
}
result := F.Pipe1(
Do(SimpleState{Value: 21}),
Bind(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
fetchValue,
),
)
_, err := result(context.Background())
assert.Error(t, err)
assert.Equal(t, "fetch failed", err.Error())
})
}
func TestLet(t *testing.T) {
// Pure function that doesn't depend on context
double := func(s SimpleState) int {
return s.Value * 2
}
result := F.Pipe1(
Do(SimpleState{Value: 21}),
Let(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
double,
),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
}
func TestLetTo(t *testing.T) {
result := F.Pipe1(
Do(SimpleState{}),
LetTo(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
100,
),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 100, state.Value)
}
func TestBindToInit(t *testing.T) {
getValue := func(ctx context.Context) (int, error) {
return 42, nil
}
result := F.Pipe1(
getValue,
BindTo(func(v int) SimpleState {
return SimpleState{Value: v}
}),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
}
func TestApS(t *testing.T) {
t.Run("successful ApS", func(t *testing.T) {
getValue := func(ctx context.Context) (int, error) {
return 100, nil
}
result := F.Pipe1(
Do(SimpleState{Value: 42}),
ApS(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
getValue,
),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 100, state.Value)
})
t.Run("ApS with error", func(t *testing.T) {
getValue := func(ctx context.Context) (int, error) {
return 0, errors.New("failed")
}
result := F.Pipe1(
Do(SimpleState{Value: 42}),
ApS(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
getValue,
),
)
_, err := result(context.Background())
assert.Error(t, err)
})
}
func TestApSL(t *testing.T) {
lenses := MakeSimpleStateLenses()
getValue := func(ctx context.Context) (int, error) {
return 100, nil
}
result := F.Pipe1(
Do(SimpleState{Value: 42}),
ApSL(lenses.Value, getValue),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 100, state.Value)
}
func TestBindL(t *testing.T) {
lenses := MakeSimpleStateLenses()
// Effectful function
increment := func(v int) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return v + 1, nil
}
}
result := F.Pipe1(
Do(SimpleState{Value: 41}),
BindL(lenses.Value, increment),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
}
func TestLetL(t *testing.T) {
lenses := MakeSimpleStateLenses()
result := F.Pipe1(
Do(SimpleState{Value: 21}),
LetL(lenses.Value, N.Mul(2)),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
}
func TestLetToL(t *testing.T) {
lenses := MakeSimpleStateLenses()
result := F.Pipe1(
Do(SimpleState{}),
LetToL(lenses.Value, 42),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
}
func TestBindReaderK(t *testing.T) {
t.Run("successful BindReaderK", func(t *testing.T) {
// Context-dependent function that doesn't return error
getFromContext := func(s SimpleState) reader.Reader[context.Context, int] {
return func(ctx context.Context) int {
if val := ctx.Value("multiplier"); val != nil {
return s.Value * val.(int)
}
return s.Value
}
}
result := F.Pipe1(
Do(SimpleState{Value: 21}),
BindReaderK(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
getFromContext,
),
)
ctx := context.WithValue(context.Background(), "multiplier", 2)
state, err := result(ctx)
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
})
}
func TestBindEitherK(t *testing.T) {
t.Run("successful BindEitherK", func(t *testing.T) {
// Pure function returning Result
validate := func(s SimpleState) RES.Result[int] {
if s.Value > 0 {
return RES.Of(s.Value * 2)
}
return RES.Left[int](errors.New("value must be positive"))
}
result := F.Pipe1(
Do(SimpleState{Value: 21}),
BindEitherK(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
validate,
),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
})
t.Run("BindEitherK with error", func(t *testing.T) {
validate := func(s SimpleState) RES.Result[int] {
return RES.Left[int](errors.New("validation failed"))
}
result := F.Pipe1(
Do(SimpleState{Value: 21}),
BindEitherK(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
validate,
),
)
_, err := result(context.Background())
assert.Error(t, err)
assert.Equal(t, "validation failed", err.Error())
})
}
func TestBindResultK(t *testing.T) {
t.Run("successful BindResultK", func(t *testing.T) {
// Pure function returning (value, error)
parse := func(s SimpleState) (int, error) {
return s.Value * 2, nil
}
result := F.Pipe1(
Do(SimpleState{Value: 21}),
BindResultK(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
parse,
),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
})
t.Run("BindResultK with error", func(t *testing.T) {
parse := func(s SimpleState) (int, error) {
return 0, errors.New("parse failed")
}
result := F.Pipe1(
Do(SimpleState{Value: 21}),
BindResultK(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
parse,
),
)
_, err := result(context.Background())
assert.Error(t, err)
assert.Equal(t, "parse failed", err.Error())
})
}
func TestBindToReader(t *testing.T) {
getFromContext := func(ctx context.Context) int {
if val := ctx.Value("value"); val != nil {
return val.(int)
}
return 0
}
result := F.Pipe1(
getFromContext,
BindToReader(func(v int) SimpleState {
return SimpleState{Value: v}
}),
)
ctx := context.WithValue(context.Background(), "value", 42)
state, err := result(ctx)
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
}
func TestBindToEither(t *testing.T) {
t.Run("successful BindToEither", func(t *testing.T) {
resultValue := RES.Of(42)
result := F.Pipe1(
resultValue,
BindToEither(func(v int) SimpleState {
return SimpleState{Value: v}
}),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
})
t.Run("BindToEither with error", func(t *testing.T) {
resultValue := RES.Left[int](errors.New("failed"))
result := F.Pipe1(
resultValue,
BindToEither(func(v int) SimpleState {
return SimpleState{Value: v}
}),
)
_, err := result(context.Background())
assert.Error(t, err)
})
}
func TestBindToResult(t *testing.T) {
t.Run("successful BindToResult", func(t *testing.T) {
value, err := 42, error(nil)
result := F.Pipe1(
BindToResult(func(v int) SimpleState {
return SimpleState{Value: v}
}),
func(f func(int, error) ReaderResult[SimpleState]) ReaderResult[SimpleState] {
return f(value, err)
},
)
state, resultErr := result(context.Background())
assert.NoError(t, resultErr)
assert.Equal(t, 42, state.Value)
})
t.Run("BindToResult with error", func(t *testing.T) {
value, err := 0, errors.New("failed")
result := F.Pipe1(
BindToResult(func(v int) SimpleState {
return SimpleState{Value: v}
}),
func(f func(int, error) ReaderResult[SimpleState]) ReaderResult[SimpleState] {
return f(value, err)
},
)
_, resultErr := result(context.Background())
assert.Error(t, resultErr)
})
}
func TestApReaderS(t *testing.T) {
getFromContext := func(ctx context.Context) int {
if val := ctx.Value("value"); val != nil {
return val.(int)
}
return 0
}
result := F.Pipe1(
Do(SimpleState{}),
ApReaderS(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
getFromContext,
),
)
ctx := context.WithValue(context.Background(), "value", 42)
state, err := result(ctx)
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
}
func TestApResultS(t *testing.T) {
t.Run("successful ApResultS", func(t *testing.T) {
value, err := 42, error(nil)
result := F.Pipe1(
Do(SimpleState{}),
func(rr ReaderResult[SimpleState]) ReaderResult[SimpleState] {
return F.Pipe1(
rr,
ApResultS(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
)(value, err),
)
},
)
state, resultErr := result(context.Background())
assert.NoError(t, resultErr)
assert.Equal(t, 42, state.Value)
})
t.Run("ApResultS with error", func(t *testing.T) {
value, err := 0, errors.New("failed")
result := F.Pipe1(
Do(SimpleState{}),
func(rr ReaderResult[SimpleState]) ReaderResult[SimpleState] {
return F.Pipe1(
rr,
ApResultS(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
)(value, err),
)
},
)
_, resultErr := result(context.Background())
assert.Error(t, resultErr)
})
}
func TestApEitherS(t *testing.T) {
t.Run("successful ApEitherS", func(t *testing.T) {
resultValue := RES.Of(42)
result := F.Pipe1(
Do(SimpleState{}),
ApEitherS(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
resultValue,
),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
})
t.Run("ApEitherS with error", func(t *testing.T) {
resultValue := RES.Left[int](errors.New("failed"))
result := F.Pipe1(
Do(SimpleState{}),
ApEitherS(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
resultValue,
),
)
_, err := result(context.Background())
assert.Error(t, err)
})
}
func TestComplexPipeline(t *testing.T) {
lenses := MakeSimpleStateLenses()
// Complex pipeline combining multiple operations
result := F.Pipe3(
Do(SimpleState{}),
LetToL(lenses.Value, 10),
LetL(lenses.Value, N.Mul(2)),
BindResultK(
func(v int) func(SimpleState) SimpleState {
return func(s SimpleState) SimpleState {
s.Value = v
return s
}
},
func(s SimpleState) (int, error) {
return s.Value + 22, nil
},
),
)
state, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 42, state.Value)
}

409
v2/idiomatic/context/readerresult/bracket.go Normal file
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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"io"
RR "github.com/IBM/fp-go/v2/idiomatic/readerresult"
)
// Bracket ensures safe resource management with guaranteed cleanup in the ReaderResult monad.
//
// This function implements the bracket pattern (also known as try-with-resources or RAII)
// for ReaderResult computations. It guarantees that the release action is called regardless
// of whether the use action succeeds or fails, making it ideal for managing resources like
// file handles, database connections, network sockets, or locks.
//
// The execution flow is:
// 1. Acquire the resource (lazily evaluated)
// 2. Use the resource with the provided function
// 3. Release the resource with access to: the resource, the result (if successful), and any error
//
// The release function is always called, even if:
// - The acquire action fails (release is not called in this case)
// - The use action fails (release receives the error)
// - The use action succeeds (release receives nil error)
//
// Type Parameters:
// - A: The type of the acquired resource
// - B: The type of the result produced by using the resource
// - ANY: The type returned by the release action (typically ignored)
//
// Parameters:
// - acquire: Lazy computation that acquires the resource
// - use: Function that uses the resource to produce a result
// - release: Function that releases the resource, receiving the resource, result, and any error
//
// Returns:
// - A ReaderResult[B] that safely manages the resource lifecycle
//
// Example - File handling:
//
// import (
// "context"
// "os"
// )
//
// readFile := readerresult.Bracket(
// // Acquire: Open file
// func() readerresult.ReaderResult[*os.File] {
// return func(ctx context.Context) (*os.File, error) {
// return os.Open("data.txt")
// }
// },
// // Use: Read file contents
// func(file *os.File) readerresult.ReaderResult[string] {
// return func(ctx context.Context) (string, error) {
// data, err := io.ReadAll(file)
// return string(data), err
// }
// },
// // Release: Close file (always called)
// func(file *os.File, content string, err error) readerresult.ReaderResult[any] {
// return func(ctx context.Context) (any, error) {
// return nil, file.Close()
// }
// },
// )
//
// content, err := readFile(context.Background())
//
// Example - Database connection:
//
// queryDB := readerresult.Bracket(
// // Acquire: Open connection
// func() readerresult.ReaderResult[*sql.DB] {
// return func(ctx context.Context) (*sql.DB, error) {
// return sql.Open("postgres", connString)
// }
// },
// // Use: Execute query
// func(db *sql.DB) readerresult.ReaderResult[[]User] {
// return func(ctx context.Context) ([]User, error) {
// return queryUsers(ctx, db)
// }
// },
// // Release: Close connection (always called)
// func(db *sql.DB, users []User, err error) readerresult.ReaderResult[any] {
// return func(ctx context.Context) (any, error) {
// return nil, db.Close()
// }
// },
// )
//
// Example - Lock management:
//
// withLock := readerresult.Bracket(
// // Acquire: Lock mutex
// func() readerresult.ReaderResult[*sync.Mutex] {
// return func(ctx context.Context) (*sync.Mutex, error) {
// mu.Lock()
// return mu, nil
// }
// },
// // Use: Perform critical section work
// func(mu *sync.Mutex) readerresult.ReaderResult[int] {
// return func(ctx context.Context) (int, error) {
// return performCriticalWork(ctx)
// }
// },
// // Release: Unlock mutex (always called)
// func(mu *sync.Mutex, result int, err error) readerresult.ReaderResult[any] {
// return func(ctx context.Context) (any, error) {
// mu.Unlock()
// return nil, nil
// }
// },
// )
//
//go:inline
func Bracket[
A, B, ANY any](
acquire Lazy[ReaderResult[A]],
use Kleisli[A, B],
release func(A, B, error) ReaderResult[ANY],
) ReaderResult[B] {
return RR.Bracket(acquire, WithContextK(use), release)
}
// WithResource creates a higher-order function for resource management with automatic cleanup.
//
// This function provides a more composable alternative to Bracket by creating a function
// that takes a resource-using function and automatically handles resource acquisition and
// release. This is particularly useful when you want to reuse the same resource management
// pattern with different operations.
//
// The pattern is:
// 1. Create a resource manager with onCreate and onRelease
// 2. Apply it to different use functions as needed
// 3. Each application ensures proper resource cleanup
//
// This is useful for:
// - Creating reusable resource management patterns
// - Building resource pools or factories
// - Composing resource-dependent operations
// - Abstracting resource lifecycle management
//
// Type Parameters:
// - B: The type of the result produced by using the resource
// - A: The type of the acquired resource
// - ANY: The type returned by the release action (typically ignored)
//
// Parameters:
// - onCreate: Lazy computation that creates/acquires the resource
// - onRelease: Function that releases the resource (receives the resource)
//
// Returns:
// - A Kleisli arrow that takes a resource-using function and returns a ReaderResult[B]
// with automatic resource management
//
// Example - Reusable database connection manager:
//
// import (
// "context"
// "database/sql"
// )
//
// // Create a reusable DB connection manager
// withDB := readerresult.WithResource(
// // onCreate: Acquire connection
// func() readerresult.ReaderResult[*sql.DB] {
// return func(ctx context.Context) (*sql.DB, error) {
// return sql.Open("postgres", connString)
// }
// },
// // onRelease: Close connection
// func(db *sql.DB) readerresult.ReaderResult[any] {
// return func(ctx context.Context) (any, error) {
// return nil, db.Close()
// }
// },
// )
//
// // Use the manager with different operations
// getUsers := withDB(func(db *sql.DB) readerresult.ReaderResult[[]User] {
// return func(ctx context.Context) ([]User, error) {
// return queryUsers(ctx, db)
// }
// })
//
// getOrders := withDB(func(db *sql.DB) readerresult.ReaderResult[[]Order] {
// return func(ctx context.Context) ([]Order, error) {
// return queryOrders(ctx, db)
// }
// })
//
// // Both operations automatically manage the connection
// users, err := getUsers(context.Background())
// orders, err := getOrders(context.Background())
//
// Example - File operations manager:
//
// withFile := readerresult.WithResource(
// func() readerresult.ReaderResult[*os.File] {
// return func(ctx context.Context) (*os.File, error) {
// return os.Open("config.json")
// }
// },
// func(file *os.File) readerresult.ReaderResult[any] {
// return func(ctx context.Context) (any, error) {
// return nil, file.Close()
// }
// },
// )
//
// // Different operations on the same file
// readConfig := withFile(func(file *os.File) readerresult.ReaderResult[Config] {
// return func(ctx context.Context) (Config, error) {
// return parseConfig(file)
// }
// })
//
// validateConfig := withFile(func(file *os.File) readerresult.ReaderResult[bool] {
// return func(ctx context.Context) (bool, error) {
// return validateConfigFile(file)
// }
// })
//
// Example - Composing with other operations:
//
// import F "github.com/IBM/fp-go/v2/function"
//
// // Create a pipeline with automatic resource management
// processData := F.Pipe2(
// loadData,
// withDB(func(db *sql.DB) readerresult.ReaderResult[Result] {
// return saveToDatabase(db)
// }),
// readerresult.Map(formatResult),
// )
//
//go:inline
func WithResource[B, A, ANY any](
onCreate Lazy[ReaderResult[A]],
onRelease Kleisli[A, ANY],
) Kleisli[Kleisli[A, B], B] {
return WithContextK(RR.WithResource[B](onCreate, onRelease))
}
// onClose is a helper function that creates a ReaderResult that closes an io.Closer.
// This is used internally by WithCloser to provide automatic cleanup for resources
// that implement the io.Closer interface.
func onClose[A io.Closer](a A) ReaderResult[struct{}] {
return func(_ context.Context) (struct{}, error) {
return struct{}{}, a.Close()
}
}
// WithCloser creates a higher-order function for managing resources that implement io.Closer.
//
// This is a specialized version of WithResource that automatically handles cleanup for any
// resource implementing the io.Closer interface (such as files, network connections, HTTP
// response bodies, etc.). It eliminates the need to manually specify the release function,
// making it more convenient for common Go resources.
//
// The function automatically calls Close() on the resource when the operation completes,
// regardless of success or failure. This ensures proper resource cleanup following Go's
// standard io.Closer pattern.
//
// Type Parameters:
// - B: The type of the result produced by using the resource
// - A: The type of the resource, which must implement io.Closer
//
// Parameters:
// - onCreate: Lazy computation that creates/acquires the io.Closer resource
//
// Returns:
// - A Kleisli arrow that takes a resource-using function and returns a ReaderResult[B]
// with automatic Close() cleanup
//
// Example - File operations:
//
// import (
// "context"
// "os"
// "io"
// )
//
// // Create a reusable file manager
// withFile := readerresult.WithCloser(
// func() readerresult.ReaderResult[*os.File] {
// return func(ctx context.Context) (*os.File, error) {
// return os.Open("data.txt")
// }
// },
// )
//
// // Use with different operations - Close() is automatic
// readContent := withFile(func(file *os.File) readerresult.ReaderResult[string] {
// return func(ctx context.Context) (string, error) {
// data, err := io.ReadAll(file)
// return string(data), err
// }
// })
//
// getSize := withFile(func(file *os.File) readerresult.ReaderResult[int64] {
// return func(ctx context.Context) (int64, error) {
// info, err := file.Stat()
// if err != nil {
// return 0, err
// }
// return info.Size(), nil
// }
// })
//
// content, err := readContent(context.Background())
// size, err := getSize(context.Background())
//
// Example - HTTP response body:
//
// import "net/http"
//
// withResponse := readerresult.WithCloser(
// func() readerresult.ReaderResult[*http.Response] {
// return func(ctx context.Context) (*http.Response, error) {
// return http.Get("https://api.example.com/data")
// }
// },
// )
//
// // Body is automatically closed after use
// parseJSON := withResponse(func(resp *http.Response) readerresult.ReaderResult[Data] {
// return func(ctx context.Context) (Data, error) {
// var data Data
// err := json.NewDecoder(resp.Body).Decode(&data)
// return data, err
// }
// })
//
// Example - Multiple file operations:
//
// // Read from one file, write to another
// copyFile := func(src, dst string) readerresult.ReaderResult[int64] {
// withSrc := readerresult.WithCloser(
// func() readerresult.ReaderResult[*os.File] {
// return func(ctx context.Context) (*os.File, error) {
// return os.Open(src)
// }
// },
// )
//
// withDst := readerresult.WithCloser(
// func() readerresult.ReaderResult[*os.File] {
// return func(ctx context.Context) (*os.File, error) {
// return os.Create(dst)
// }
// },
// )
//
// return withSrc(func(srcFile *os.File) readerresult.ReaderResult[int64] {
// return withDst(func(dstFile *os.File) readerresult.ReaderResult[int64] {
// return func(ctx context.Context) (int64, error) {
// return io.Copy(dstFile, srcFile)
// }
// })
// })
// }
//
// Example - Network connection:
//
// import "net"
//
// withConn := readerresult.WithCloser(
// func() readerresult.ReaderResult[net.Conn] {
// return func(ctx context.Context) (net.Conn, error) {
// return net.Dial("tcp", "localhost:8080")
// }
// },
// )
//
// sendData := withConn(func(conn net.Conn) readerresult.ReaderResult[int] {
// return func(ctx context.Context) (int, error) {
// return conn.Write([]byte("Hello, World!"))
// }
// })
//
// Note: WithCloser is a convenience wrapper around WithResource that automatically
// provides the Close() cleanup function. For resources that don't implement io.Closer
// or require custom cleanup logic, use WithResource or Bracket instead.
//
//go:inline
func WithCloser[B any, A io.Closer](onCreate Lazy[ReaderResult[A]]) Kleisli[Kleisli[A, B], B] {
return WithResource[B](onCreate, onClose[A])
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"errors"
"io"
"strings"
"sync"
"testing"
"github.com/stretchr/testify/assert"
)
// mockResource simulates a resource that needs cleanup
type mockResource struct {
id int
closed bool
closeMu sync.Mutex
closeErr error
}
func (m *mockResource) Close() error {
m.closeMu.Lock()
defer m.closeMu.Unlock()
m.closed = true
return m.closeErr
}
func (m *mockResource) IsClosed() bool {
m.closeMu.Lock()
defer m.closeMu.Unlock()
return m.closed
}
// mockCloser implements io.Closer for testing WithCloser
type mockCloser struct {
*mockResource
}
func TestBracketExtended(t *testing.T) {
t.Run("successful acquire, use, and release with real resource", func(t *testing.T) {
resource := &mockResource{id: 1}
released := false
result := Bracket(
// Acquire
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return resource, nil
}
},
// Use
func(r *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return r.id * 2, nil
}
},
// Release
func(r *mockResource, result int, err error) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
released = true
assert.Equal(t, 2, result)
assert.NoError(t, err)
return nil, r.Close()
}
},
)
value, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 2, value)
assert.True(t, released)
assert.True(t, resource.IsClosed())
})
t.Run("acquire fails - release not called", func(t *testing.T) {
acquireErr := errors.New("acquire failed")
released := false
result := Bracket(
// Acquire fails
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return nil, acquireErr
}
},
// Use (should not be called)
func(r *mockResource) ReaderResult[int] {
t.Fatal("use should not be called when acquire fails")
return func(ctx context.Context) (int, error) {
return 0, nil
}
},
// Release (should not be called)
func(r *mockResource, result int, err error) ReaderResult[any] {
released = true
return func(ctx context.Context) (any, error) {
return nil, nil
}
},
)
_, err := result(context.Background())
assert.Error(t, err)
assert.Equal(t, acquireErr, err)
assert.False(t, released)
})
t.Run("use fails - release still called", func(t *testing.T) {
resource := &mockResource{id: 1}
useErr := errors.New("use failed")
released := false
result := Bracket(
// Acquire
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return resource, nil
}
},
// Use fails
func(r *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return 0, useErr
}
},
// Release (should still be called)
func(r *mockResource, result int, err error) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
released = true
assert.Equal(t, 0, result)
assert.Equal(t, useErr, err)
return nil, r.Close()
}
},
)
_, err := result(context.Background())
assert.Error(t, err)
assert.Equal(t, useErr, err)
assert.True(t, released)
assert.True(t, resource.IsClosed())
})
t.Run("release fails - error propagated", func(t *testing.T) {
resource := &mockResource{id: 1, closeErr: errors.New("close failed")}
released := false
result := Bracket(
// Acquire
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return resource, nil
}
},
// Use succeeds
func(r *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return r.id * 2, nil
}
},
// Release fails
func(r *mockResource, result int, err error) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
released = true
return nil, r.Close()
}
},
)
_, err := result(context.Background())
assert.Error(t, err)
assert.Equal(t, "close failed", err.Error())
assert.True(t, released)
assert.True(t, resource.IsClosed())
})
t.Run("both use and release fail - use error takes precedence", func(t *testing.T) {
resource := &mockResource{id: 1, closeErr: errors.New("close failed")}
useErr := errors.New("use failed")
released := false
result := Bracket(
// Acquire
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return resource, nil
}
},
// Use fails
func(r *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return 0, useErr
}
},
// Release also fails
func(r *mockResource, result int, err error) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
released = true
assert.Equal(t, useErr, err)
return nil, r.Close()
}
},
)
_, err := result(context.Background())
assert.Error(t, err)
// The use error should be returned
assert.Equal(t, useErr, err)
assert.True(t, released)
assert.True(t, resource.IsClosed())
})
t.Run("context cancellation during use", func(t *testing.T) {
resource := &mockResource{id: 1}
released := false
result := Bracket(
// Acquire
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return resource, nil
}
},
// Use checks context
func(r *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
select {
case <-ctx.Done():
return 0, ctx.Err()
default:
return r.id * 2, nil
}
}
},
// Release
func(r *mockResource, result int, err error) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
released = true
return nil, r.Close()
}
},
)
ctx, cancel := context.WithCancel(context.Background())
cancel() // Cancel immediately
_, err := result(ctx)
assert.Error(t, err)
assert.Equal(t, context.Canceled, err)
assert.True(t, released)
assert.True(t, resource.IsClosed())
})
}
func TestWithResource(t *testing.T) {
t.Run("reusable resource manager - successful operations", func(t *testing.T) {
resource := &mockResource{id: 42}
createCount := 0
releaseCount := 0
withResource := WithResource[int](
// onCreate
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
createCount++
return resource, nil
}
},
// onRelease
func(r *mockResource) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
releaseCount++
return nil, r.Close()
}
},
)
// First operation
operation1 := withResource(func(r *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return r.id * 2, nil
}
})
result1, err1 := operation1(context.Background())
assert.NoError(t, err1)
assert.Equal(t, 84, result1)
assert.Equal(t, 1, createCount)
assert.Equal(t, 1, releaseCount)
// Reset for second operation
resource.closed = false
// Second operation with same resource manager
operation2 := withResource(func(r *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return r.id + 10, nil
}
})
result2, err2 := operation2(context.Background())
assert.NoError(t, err2)
assert.Equal(t, 52, result2)
assert.Equal(t, 2, createCount)
assert.Equal(t, 2, releaseCount)
})
t.Run("resource manager with failing operation", func(t *testing.T) {
resource := &mockResource{id: 42}
releaseCount := 0
opErr := errors.New("operation failed")
withResource := WithResource[int](
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return resource, nil
}
},
func(r *mockResource) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
releaseCount++
return nil, r.Close()
}
},
)
operation := withResource(func(r *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return 0, opErr
}
})
_, err := operation(context.Background())
assert.Error(t, err)
assert.Equal(t, opErr, err)
assert.Equal(t, 1, releaseCount)
assert.True(t, resource.IsClosed())
})
t.Run("nested resource managers", func(t *testing.T) {
resource1 := &mockResource{id: 1}
resource2 := &mockResource{id: 2}
withResource1 := WithResource[int](
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return resource1, nil
}
},
func(r *mockResource) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
return nil, r.Close()
}
},
)
withResource2 := WithResource[int](
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return resource2, nil
}
},
func(r *mockResource) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
return nil, r.Close()
}
},
)
// Nest the resource managers
operation := withResource1(func(r1 *mockResource) ReaderResult[int] {
return withResource2(func(r2 *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return r1.id + r2.id, nil
}
})
})
result, err := operation(context.Background())
assert.NoError(t, err)
assert.Equal(t, 3, result)
assert.True(t, resource1.IsClosed())
assert.True(t, resource2.IsClosed())
})
}
func TestWithCloser(t *testing.T) {
t.Run("successful operation with io.Closer", func(t *testing.T) {
resource := &mockCloser{mockResource: &mockResource{id: 100}}
withCloser := WithCloser[string](
func() ReaderResult[*mockCloser] {
return func(ctx context.Context) (*mockCloser, error) {
return resource, nil
}
},
)
operation := withCloser(func(r *mockCloser) ReaderResult[string] {
return func(ctx context.Context) (string, error) {
return "success", nil
}
})
result, err := operation(context.Background())
assert.NoError(t, err)
assert.Equal(t, "success", result)
assert.True(t, resource.IsClosed())
})
t.Run("operation fails but closer still called", func(t *testing.T) {
resource := &mockCloser{mockResource: &mockResource{id: 100}}
opErr := errors.New("operation failed")
withCloser := WithCloser[string](
func() ReaderResult[*mockCloser] {
return func(ctx context.Context) (*mockCloser, error) {
return resource, nil
}
},
)
operation := withCloser(func(r *mockCloser) ReaderResult[string] {
return func(ctx context.Context) (string, error) {
return "", opErr
}
})
_, err := operation(context.Background())
assert.Error(t, err)
assert.Equal(t, opErr, err)
assert.True(t, resource.IsClosed())
})
t.Run("closer fails", func(t *testing.T) {
closeErr := errors.New("close failed")
resource := &mockCloser{mockResource: &mockResource{id: 100, closeErr: closeErr}}
withCloser := WithCloser[string](
func() ReaderResult[*mockCloser] {
return func(ctx context.Context) (*mockCloser, error) {
return resource, nil
}
},
)
operation := withCloser(func(r *mockCloser) ReaderResult[string] {
return func(ctx context.Context) (string, error) {
return "success", nil
}
})
_, err := operation(context.Background())
assert.Error(t, err)
assert.Equal(t, closeErr, err)
assert.True(t, resource.IsClosed())
})
t.Run("with strings.Reader (real io.Closer)", func(t *testing.T) {
content := "Hello, World!"
withReader := WithCloser[string](
func() ReaderResult[io.ReadCloser] {
return func(ctx context.Context) (io.ReadCloser, error) {
return io.NopCloser(strings.NewReader(content)), nil
}
},
)
operation := withReader(func(r io.ReadCloser) ReaderResult[string] {
return func(ctx context.Context) (string, error) {
data, err := io.ReadAll(r)
return string(data), err
}
})
result, err := operation(context.Background())
assert.NoError(t, err)
assert.Equal(t, content, result)
})
t.Run("multiple operations with same closer", func(t *testing.T) {
createCount := 0
withCloser := WithCloser[int](
func() ReaderResult[*mockCloser] {
return func(ctx context.Context) (*mockCloser, error) {
createCount++
return &mockCloser{mockResource: &mockResource{id: createCount}}, nil
}
},
)
// First operation
op1 := withCloser(func(r *mockCloser) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return r.id * 10, nil
}
})
result1, err1 := op1(context.Background())
assert.NoError(t, err1)
assert.Equal(t, 10, result1)
// Second operation
op2 := withCloser(func(r *mockCloser) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return r.id * 20, nil
}
})
result2, err2 := op2(context.Background())
assert.NoError(t, err2)
assert.Equal(t, 40, result2)
assert.Equal(t, 2, createCount)
})
}
func TestOnClose(t *testing.T) {
t.Run("onClose helper function", func(t *testing.T) {
resource := &mockCloser{mockResource: &mockResource{id: 1}}
closeFunc := onClose(resource)
_, err := closeFunc(context.Background())
assert.NoError(t, err)
assert.True(t, resource.IsClosed())
})
t.Run("onClose with error", func(t *testing.T) {
closeErr := errors.New("close error")
resource := &mockCloser{mockResource: &mockResource{id: 1, closeErr: closeErr}}
closeFunc := onClose(resource)
_, err := closeFunc(context.Background())
assert.Error(t, err)
assert.Equal(t, closeErr, err)
assert.True(t, resource.IsClosed())
})
}
// Integration test combining multiple bracket patterns
func TestBracketIntegration(t *testing.T) {
t.Run("complex resource management scenario", func(t *testing.T) {
// Simulate a scenario with multiple resources
db := &mockResource{id: 1}
cache := &mockResource{id: 2}
logger := &mockResource{id: 3}
result := Bracket(
// Acquire DB
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return db, nil
}
},
// Use DB to get cache and logger
func(dbRes *mockResource) ReaderResult[int] {
return Bracket(
// Acquire cache
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return cache, nil
}
},
// Use cache to get logger
func(cacheRes *mockResource) ReaderResult[int] {
return Bracket(
// Acquire logger
func() ReaderResult[*mockResource] {
return func(ctx context.Context) (*mockResource, error) {
return logger, nil
}
},
// Use all resources
func(logRes *mockResource) ReaderResult[int] {
return func(ctx context.Context) (int, error) {
return dbRes.id + cacheRes.id + logRes.id, nil
}
},
// Release logger
func(logRes *mockResource, result int, err error) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
return nil, logRes.Close()
}
},
)
},
// Release cache
func(cacheRes *mockResource, result int, err error) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
return nil, cacheRes.Close()
}
},
)
},
// Release DB
func(dbRes *mockResource, result int, err error) ReaderResult[any] {
return func(ctx context.Context) (any, error) {
return nil, dbRes.Close()
}
},
)
value, err := result(context.Background())
assert.NoError(t, err)
assert.Equal(t, 6, value) // 1 + 2 + 3
assert.True(t, db.IsClosed())
assert.True(t, cache.IsClosed())
assert.True(t, logger.IsClosed())
})
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
F "github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/idiomatic/result"
)
// WithContext wraps an existing ReaderResult and performs a context check for cancellation before delegating
// to the underlying computation.
//
// If the context has been cancelled (ctx.Err() != nil), it immediately returns an error containing the
// cancellation cause without executing the wrapped computation. Otherwise, it delegates to the original
// ReaderResult.
//
// This is useful for adding cancellation checks to computations that may not check the context themselves,
// ensuring that cancelled operations fail fast.
//
// Example:
//
// // A computation that might take a long time
// slowComputation := func(ctx context.Context) (int, error) {
// time.Sleep(5 * time.Second)
// return 42, nil
// }
//
// // Wrap it to check for cancellation before execution
// safeSlow := readerresult.WithContext(slowComputation)
//
// // If context is already cancelled, this returns immediately
// ctx, cancel := context.WithCancel(context.Background())
// cancel() // Cancel immediately
// result, err := safeSlow(ctx) // Returns error immediately without sleeping
func WithContext[A any](ma ReaderResult[A]) ReaderResult[A] {
return func(ctx context.Context) (A, error) {
if ctx.Err() != nil {
return result.Left[A](context.Cause(ctx))
}
return ma(ctx)
}
}
// WithContextK wraps a Kleisli arrow (a function that returns a ReaderResult) with context cancellation checking.
//
// This is the Kleisli arrow version of WithContext. It takes a function A -> ReaderResult[B] and returns
// a new function that performs the same transformation but with an added context cancellation check before
// executing the resulting ReaderResult.
//
// A Kleisli arrow is a function that takes a value and returns a monadic computation. In this case,
// Kleisli[A, B] = func(A) ReaderResult[B], which represents a function from A to a context-dependent
// computation that may fail.
//
// WithContextK is particularly useful when composing operations with Chain/Bind, as it ensures that
// each step in the composition checks for cancellation before proceeding.
//
// Parameters:
// - f: A Kleisli arrow (function from A to ReaderResult[B])
//
// Returns:
// - A new Kleisli arrow that wraps the result of f with context cancellation checking
//
// Example:
//
// // A function that fetches user details
// fetchUserDetails := func(userID int) readerresult.ReaderResult[UserDetails] {
// return func(ctx context.Context) (UserDetails, error) {
// // Fetch from database...
// return details, nil
// }
// }
//
// // Wrap it to ensure cancellation is checked before each execution
// safeFetchDetails := readerresult.WithContextK(fetchUserDetails)
//
// // Use in a composition chain
// pipeline := F.Pipe2(
// getUser(42),
// readerresult.Chain(safeFetchDetails), // Checks cancellation before fetching details
// )
//
// // If context is cancelled between getUser and fetchUserDetails,
// // the details fetch will not execute
// ctx, cancel := context.WithTimeout(context.Background(), 100*time.Millisecond)
// defer cancel()
// result, err := pipeline(ctx)
//
// Use Cases:
// - Adding cancellation checks to composed operations
// - Ensuring long-running pipelines respect context cancellation
// - Wrapping third-party functions that don't check context themselves
// - Creating fail-fast behavior in complex operation chains
func WithContextK[A, B any](f Kleisli[A, B]) Kleisli[A, B] {
return F.Flow2(
f,
WithContext,
)
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
RR "github.com/IBM/fp-go/v2/idiomatic/readerresult"
)
// Curry0 converts a function that takes context.Context and returns (A, error) into a ReaderResult[A].
//
// This is useful for lifting existing functions that follow Go's context-first convention
// into the ReaderResult monad.
//
// Type Parameters:
// - A: The return value type
//
// Parameters:
// - f: A function that takes context.Context and returns (A, error)
//
// Returns:
// - A ReaderResult[A] that wraps the function
//
// Example:
//
// func getConfig(ctx context.Context) (Config, error) {
// // ... implementation
// return config, nil
// }
// rr := readerresult.Curry0(getConfig)
// config, err := rr(ctx)
//
//go:inline
func Curry0[A any](f func(context.Context) (A, error)) ReaderResult[A] {
return RR.Curry0(f)
}
// Curry1 converts a function with one parameter into a curried ReaderResult-returning function.
//
// The context.Context parameter is handled by the ReaderResult, allowing you to partially
// apply the business parameter before providing the context.
//
// Type Parameters:
// - T1: The first parameter type
// - A: The return value type
//
// Parameters:
// - f: A function that takes (context.Context, T1) and returns (A, error)
//
// Returns:
// - A curried function that takes T1 and returns ReaderResult[A]
//
// Example:
//
// func getUser(ctx context.Context, id int) (User, error) {
// // ... implementation
// return user, nil
// }
// getUserRR := readerresult.Curry1(getUser)
// rr := getUserRR(42) // Partially applied
// user, err := rr(ctx) // Execute with context
//
//go:inline
func Curry1[T1, A any](f func(context.Context, T1) (A, error)) func(T1) ReaderResult[A] {
return RR.Curry1(f)
}
// Curry2 converts a function with two parameters into a curried ReaderResult-returning function.
//
// The context.Context parameter is handled by the ReaderResult, allowing you to partially
// apply the business parameters before providing the context.
//
// Type Parameters:
// - T1: The first parameter type
// - T2: The second parameter type
// - A: The return value type
//
// Parameters:
// - f: A function that takes (context.Context, T1, T2) and returns (A, error)
//
// Returns:
// - A curried function that takes T1, then T2, and returns ReaderResult[A]
//
// Example:
//
// func updateUser(ctx context.Context, id int, name string) (User, error) {
// // ... implementation
// return user, nil
// }
// updateUserRR := readerresult.Curry2(updateUser)
// rr := updateUserRR(42)("Alice") // Partially applied
// user, err := rr(ctx) // Execute with context
//
//go:inline
func Curry2[T1, T2, A any](f func(context.Context, T1, T2) (A, error)) func(T1) func(T2) ReaderResult[A] {
return RR.Curry2(f)
}
// Curry3 converts a function with three parameters into a curried ReaderResult-returning function.
//
// The context.Context parameter is handled by the ReaderResult, allowing you to partially
// apply the business parameters before providing the context.
//
// Type Parameters:
// - T1: The first parameter type
// - T2: The second parameter type
// - T3: The third parameter type
// - A: The return value type
//
// Parameters:
// - f: A function that takes (context.Context, T1, T2, T3) and returns (A, error)
//
// Returns:
// - A curried function that takes T1, then T2, then T3, and returns ReaderResult[A]
//
// Example:
//
// func createPost(ctx context.Context, userID int, title string, body string) (Post, error) {
// // ... implementation
// return post, nil
// }
// createPostRR := readerresult.Curry3(createPost)
// rr := createPostRR(42)("Title")("Body") // Partially applied
// post, err := rr(ctx) // Execute with context
//
//go:inline
func Curry3[T1, T2, T3, A any](f func(context.Context, T1, T2, T3) (A, error)) func(T1) func(T2) func(T3) ReaderResult[A] {
return RR.Curry3(f)
}
// Uncurry1 converts a curried ReaderResult function back to a standard Go function.
//
// This is the inverse of Curry1, useful when you need to call curried functions
// in a traditional Go style.
//
// Type Parameters:
// - T1: The parameter type
// - A: The return value type
//
// Parameters:
// - f: A curried function that takes T1 and returns ReaderResult[A]
//
// Returns:
// - A function that takes (context.Context, T1) and returns (A, error)
//
// Example:
//
// curriedFn := func(id int) readerresult.ReaderResult[User] { ... }
// normalFn := readerresult.Uncurry1(curriedFn)
// user, err := normalFn(ctx, 42)
//
//go:inline
func Uncurry1[T1, A any](f func(T1) ReaderResult[A]) func(context.Context, T1) (A, error) {
return RR.Uncurry1(f)
}
// Uncurry2 converts a curried ReaderResult function with two parameters back to a standard Go function.
//
// This is the inverse of Curry2.
//
// Type Parameters:
// - T1: The first parameter type
// - T2: The second parameter type
// - A: The return value type
//
// Parameters:
// - f: A curried function that takes T1, then T2, and returns ReaderResult[A]
//
// Returns:
// - A function that takes (context.Context, T1, T2) and returns (A, error)
//
//go:inline
func Uncurry2[T1, T2, A any](f func(T1) func(T2) ReaderResult[A]) func(context.Context, T1, T2) (A, error) {
return RR.Uncurry2(f)
}
// Uncurry3 converts a curried ReaderResult function with three parameters back to a standard Go function.
//
// This is the inverse of Curry3.
//
// Type Parameters:
// - T1: The first parameter type
// - T2: The second parameter type
// - T3: The third parameter type
// - A: The return value type
//
// Parameters:
// - f: A curried function that takes T1, then T2, then T3, and returns ReaderResult[A]
//
// Returns:
// - A function that takes (context.Context, T1, T2, T3) and returns (A, error)
//
//go:inline
func Uncurry3[T1, T2, T3, A any](f func(T1) func(T2) func(T3) ReaderResult[A]) func(context.Context, T1, T2, T3) (A, error) {
return RR.Uncurry3(f)
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package readerresult provides a ReaderResult monad specialized for context.Context.
//
// A ReaderResult[A] represents an effectful computation that:
// - Takes a context.Context as input
// - May fail with an error (Result aspect, which is Either[error, A])
// - Returns a value of type A on success
//
// The type is defined as: ReaderResult[A any] = func(context.Context) (A, error)
//
// This is equivalent to Reader[context.Context, Result[A]] or Reader[context.Context, Either[error, A]],
// but specialized to always use context.Context as the environment type.
//
// # Effectful Computations with Context
//
// ReaderResult is particularly well-suited for representing effectful computations in Go. An effectful
// computation is one that:
//
// - Performs side effects (I/O, network calls, database operations, etc.)
// - May fail with an error
// - Requires contextual information (cancellation, deadlines, request-scoped values)
//
// By using context.Context as the fixed environment type, ReaderResult[A] provides:
//
// 1. Cancellation propagation - operations can be cancelled via context
// 2. Deadline/timeout handling - operations respect context deadlines
// 3. Request-scoped values - access to request metadata, trace IDs, etc.
// 4. Functional composition - chain effectful operations while maintaining context
// 5. Error handling - explicit error propagation through the Result type
//
// This pattern is idiomatic in Go, where functions performing I/O conventionally accept
// context.Context as their first parameter: func(ctx context.Context, ...) (Result, error).
// ReaderResult preserves this convention while enabling functional composition.
//
// Example of an effectful computation:
//
// // An effectful operation that queries a database
// func fetchUser(ctx context.Context, id int) (User, error) {
// // ctx provides cancellation, deadlines, and request context
// row := db.QueryRowContext(ctx, "SELECT * FROM users WHERE id = ?", id)
// var user User
// err := row.Scan(&user.ID, &user.Name)
// return user, err
// }
//
// // Lift into ReaderResult for functional composition
// getUser := readerresult.Curry1(fetchUser)
//
// // Compose multiple effectful operations
// pipeline := F.Pipe2(
// getUser(42), // ReaderResult[User]
// readerresult.Chain(func(user User) readerresult.ReaderResult[[]Post] {
// return getPosts(user.ID) // Another effectful operation
// }),
// )
//
// // Execute with a context (e.g., from an HTTP request)
// ctx := r.Context() // HTTP request context
// posts, err := pipeline(ctx)
//
// # Use Cases
//
// ReaderResult is particularly useful for:
//
// 1. Effectful computations with context - operations that perform I/O and need cancellation/deadlines
// 2. Functional error handling - compose operations that depend on context and may error
// 3. Testing - easily mock context-dependent operations
// 4. HTTP handlers - chain request processing operations with proper context propagation
//
// # Composition
//
// ReaderResult provides several ways to compose computations:
//
// 1. Map - transform successful values
// 2. Chain (FlatMap) - sequence dependent operations
// 3. Ap - combine independent computations
// 4. Do-notation - imperative-style composition with Bind
//
// # Do-Notation Example
//
// type State struct {
// User User
// Posts []Post
// }
//
// result := F.Pipe2(
// readerresult.Do(State{}),
// readerresult.Bind(
// func(user User) func(State) State {
// return func(s State) State { s.User = user; return s }
// },
// func(s State) readerresult.ReaderResult[User] {
// return getUser(42)
// },
// ),
// readerresult.Bind(
// func(posts []Post) func(State) State {
// return func(s State) State { s.Posts = posts; return s }
// },
// func(s State) readerresult.ReaderResult[[]Post] {
// return getPosts(s.User.ID)
// },
// ),
// )
//
// # Currying Functions with Context
//
// The Curry functions enable partial application of function parameters while deferring
// the context.Context parameter until execution time.
//
// When you curry a function like func(context.Context, T1, T2) (A, error), the context.Context
// becomes the last argument to be applied, even though it appears first in the original function
// signature. This is intentional and follows Go's context-first convention while enabling
// functional composition patterns.
//
// Why context.Context is the last curried argument:
//
// - In Go, context conventionally comes first: func(ctx context.Context, params...) (Result, error)
// - In curried form: Curry2(f)(param1)(param2) returns ReaderResult[A]
// - The ReaderResult is then applied to ctx: Curry2(f)(param1)(param2)(ctx)
// - This allows partial application of business parameters before providing the context
//
// Example with database operations:
//
// // Database operations following Go conventions (context first)
// func fetchUser(ctx context.Context, db *sql.DB, id int) (User, error) {
// row := db.QueryRowContext(ctx, "SELECT * FROM users WHERE id = ?", id)
// var user User
// err := row.Scan(&user.ID, &user.Name)
// return user, err
// }
//
// func updateUser(ctx context.Context, db *sql.DB, id int, name string) (User, error) {
// _, err := db.ExecContext(ctx, "UPDATE users SET name = ? WHERE id = ?", name, id)
// if err != nil {
// return User{}, err
// }
// return fetchUser(ctx, db, id)
// }
//
// // Curry these into composable operations
// getUser := readerresult.Curry2(fetchUser)
// updateUserName := readerresult.Curry3(updateUser)
//
// // Compose operations with partial application
// pipeline := F.Pipe2(
// getUser(db)(42), // ReaderResult[User] - db and id applied, waiting for ctx
// readerresult.Chain(func(user User) readerresult.ReaderResult[User] {
// newName := user.Name + " (updated)"
// return updateUserName(db)(user.ID)(newName) // Waiting for ctx
// }),
// )
//
// // Execute by providing the context
// ctx := context.Background()
// updatedUser, err := pipeline(ctx)
//
// The key insight is that currying creates a chain where:
// 1. Business parameters are applied first: getUser(db)(42)
// 2. This returns a ReaderResult[User] that waits for the context
// 3. Multiple operations can be composed before providing the context
// 4. Finally, the context is provided to execute everything: pipeline(ctx)
//
// This pattern is particularly useful for:
// - Creating reusable operation pipelines independent of specific contexts
// - Testing with different contexts (with timeouts, cancellation, etc.)
// - Composing operations that share the same context
// - Deferring context creation until execution time
//
// # Error Handling
//
// ReaderResult provides several functions for error handling:
//
// - Left/Right - create failed/successful values
// - GetOrElse - provide a default value for errors
// - OrElse - recover from errors with an alternative computation
// - Fold - handle both success and failure cases
// - ChainEitherK - lift result.Result computations into ReaderResult
//
// # Relationship to Other Monads
//
// ReaderResult is related to several other monads in this library:
//
// - Reader[context.Context, A] - ReaderResult without error handling
// - Result[A] (Either[error, A]) - error handling without context dependency
// - IOResult[A] - similar to ReaderResult but without explicit context parameter
// - ReaderIOResult[R, A] - generic version that allows custom environment type R
//
// # Performance Note
//
// ReaderResult is a zero-cost abstraction - it compiles to a simple function type
// with no runtime overhead beyond the underlying computation.
package readerresult

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"fmt"
F "github.com/IBM/fp-go/v2/function"
N "github.com/IBM/fp-go/v2/number"
"github.com/IBM/fp-go/v2/optics/lens"
RES "github.com/IBM/fp-go/v2/result"
)
// Post represents a blog post
// fp-go:Lens
type Post struct {
ID int
UserID int
Title string
}
// State represents accumulated state in do-notation
// fp-go:Lens
type State struct {
User User
Posts []Post
FullName string
Status string
}
// getUser simulates fetching a user by ID
func getUser(id int) ReaderResult[User] {
return func(ctx context.Context) (User, error) {
return User{ID: id, Name: "Alice"}, nil
}
}
// getPosts simulates fetching posts for a user
func getPosts(userID int) ReaderResult[[]Post] {
return func(ctx context.Context) ([]Post, error) {
return []Post{
{ID: 1, UserID: userID, Title: "First Post"},
{ID: 2, UserID: userID, Title: "Second Post"},
}, nil
}
}
// fp-go:Lens
type SimpleState struct {
Value int
}
// ExampleDo demonstrates initializing a do-notation context with an empty state.
// This is the starting point for do-notation style composition, which allows
// imperative-style sequencing of ReaderResult computations while maintaining
// functional purity.
//
// Step-by-step breakdown:
//
// 1. Do(SimpleState{}) - Initialize the do-notation chain with an empty SimpleState.
// This creates a ReaderResult that, when executed, will return the initial state.
// The state acts as an accumulator that will be threaded through subsequent operations.
//
// 2. LetToL(simpleStateLenses.Value, 42) - Set the Value field to the constant 42.
// LetToL uses a lens to focus on a specific field in the state and assign a constant value.
// The "L" suffix indicates this is the lens-based version of LetTo.
// After this step, state.Value = 42.
//
// 3. LetL(simpleStateLenses.Value, N.Add(8)) - Transform the Value field by adding 8.
// LetL uses a lens to focus on a field and apply a transformation function to it.
// N.Add(8) creates a function that adds 8 to its input.
// After this step, state.Value = 42 + 8 = 50.
//
// 4. result(context.Background()) - Execute the composed ReaderResult computation.
// This runs the entire chain with the provided context and returns the final state
// and any error that occurred during execution.
//
// The key insight: Do-notation allows you to build complex stateful computations
// in a declarative, pipeline style while maintaining immutability and composability.
func ExampleDo() {
simpleStateLenses := MakeSimpleStateLenses()
result := F.Pipe2(
Do(SimpleState{}),
LetToL(
simpleStateLenses.Value,
42,
),
LetL(
simpleStateLenses.Value,
N.Add(8),
),
)
state, err := result(context.Background())
fmt.Printf("Value: %d, Error: %v\n", state.Value, err)
// Output: Value: 50, Error: <nil>
}
// ExampleBind demonstrates sequencing a ReaderResult computation and updating
// the state with its result. This is the core operation for do-notation,
// allowing you to chain computations where each step can depend on the
// accumulated state and update it with new values.
//
// Step-by-step breakdown:
//
// 1. Setup lenses for accessing nested state fields:
//
// - userLenses: Provides lenses for User fields (ID, Name)
//
// - stateLenses: Provides lenses for State fields (User, Posts, FullName, Status)
//
// - userIdLens: A composed lens that focuses on state.User.ID
// Created by composing stateLenses.User with userLenses.ID
//
// 2. Do(State{}) - Initialize the do-notation chain with an empty State.
// This creates the initial ReaderResult that will accumulate data through
// subsequent operations.
//
// 3. ApSL(stateLenses.User, getUser(42)) - Fetch user and store in state.User field.
// ApSL (Applicative Set Lens) executes the getUser(42) ReaderResult computation
// and uses the lens to set the result into state.User.
// After this step: state.User = User{ID: 42, Name: "Alice"}
//
// 4. Bind(stateLenses.Posts.Set, F.Flow2(userIdLens.Get, getPosts)) - Fetch posts
// based on the user ID from state and store them in state.Posts.
//
// Breaking down the Bind operation:
// a) First parameter: stateLenses.Posts.Set - A setter function that will update
// the Posts field in the state with the result of the computation.
//
// b) Second parameter: F.Flow2(userIdLens.Get, getPosts) - A composed function that:
//
// - Takes the current state as input
//
// - Extracts the user ID using userIdLens.Get (gets state.User.ID)
//
// - Passes the user ID to getPosts, which returns a ReaderResult[[]Post]
//
// - The result is then set into state.Posts using the setter
//
// After this step: state.Posts = [{ID: 1, UserID: 42, ...}, {ID: 2, UserID: 42, ...}]
//
// 5. result(context.Background()) - Execute the entire computation chain.
// This runs all the ReaderResult operations in sequence, threading the context
// through each step and accumulating the state.
//
// Key concepts demonstrated:
// - Lens composition: Building complex accessors from simple ones
// - Sequential effects: Each step can depend on previous results
// - State accumulation: Building up a complex state object step by step
// - Context threading: The context.Context flows through all operations
// - Error handling: Any error in the chain short-circuits execution
func ExampleBind() {
userLenses := MakeUserLenses()
stateLenses := MakeStateLenses()
userIdLens := F.Pipe1(
stateLenses.User,
lens.Compose[State](userLenses.ID),
)
result := F.Pipe2(
Do(State{}),
ApSL(
stateLenses.User,
getUser(42),
),
Bind(
stateLenses.Posts.Set,
F.Flow2(
userIdLens.Get,
getPosts,
),
),
)
state, err := result(context.Background())
fmt.Printf("User: %s, Posts: %d, Error: %v\n", state.User.Name, len(state.Posts), err)
// Output: User: Alice, Posts: 2, Error: <nil>
}
// fp-go:Lens
type NameState struct {
FirstName string
LastName string
FullName string
}
// ExampleLet demonstrates attaching the result of a pure computation to a state.
// Unlike Bind, Let works with pure functions (not ReaderResult computations).
// This is useful for deriving values from the current state without performing
// any effects.
//
// Step-by-step breakdown:
//
// 1. nameStateLenses := MakeNameStateLenses() - Create lenses for accessing NameState fields.
// Lenses provide a functional way to get and set nested fields in immutable data structures.
// This gives us lenses for FirstName, LastName, and FullName fields.
//
// 2. Do(NameState{FirstName: "John", LastName: "Doe"}) - Initialize the do-notation
// chain with a NameState containing first and last names.
// Initial state: {FirstName: "John", LastName: "Doe", FullName: ""}
//
// 3. Let(nameStateLenses.FullName.Set, func(s NameState) string {...}) - Compute a
// derived value from the current state and update the state with it.
//
// Let takes two parameters:
//
// a) First parameter: nameStateLenses.FullName.Set
// This is a setter function (from the lens) that takes a value and returns a
// function to update the FullName field in the state. The lens-based setter
// ensures immutable updates.
//
// b) Second parameter: func(s NameState) string
// This is a pure "getter" or "computation" function that derives a value from
// the current state. Here it concatenates FirstName and LastName with a space.
// This function has no side effects - it just computes a value.
//
// The Let operation flow:
// - Takes the current state: {FirstName: "John", LastName: "Doe", FullName: ""}
// - Calls the computation function: "John" + " " + "Doe" = "John Doe"
// - Passes "John Doe" to the setter (nameStateLenses.FullName.Set)
// - The setter creates a new state with FullName updated
// After this step: {FirstName: "John", LastName: "Doe", FullName: "John Doe"}
//
// 4. Map(nameStateLenses.FullName.Get) - Transform the final state to extract just
// the FullName field using the lens getter. This changes the result type from
// ReaderResult[NameState] to ReaderResult[string].
//
// 5. result(context.Background()) - Execute the computation chain and return the
// final extracted value ("John Doe") and any error.
//
// Key differences between Let and Bind:
// - Let: Works with pure functions (State -> Value), no effects or errors
// - Bind: Works with effectful computations (State -> ReaderResult[Value])
// - Let: Used for deriving/computing values from existing state
// - Bind: Used for operations that may fail, need context, or have side effects
//
// Use Let when you need to:
// - Compute derived values from existing state fields
// - Transform or combine state values without side effects
// - Add computed fields to your state for later use in the pipeline
// - Perform pure calculations that don't require context or error handling
func ExampleLet() {
nameStateLenses := MakeNameStateLenses()
result := F.Pipe2(
Do(NameState{FirstName: "John", LastName: "Doe"}),
Let(nameStateLenses.FullName.Set,
func(s NameState) string {
return s.FirstName + " " + s.LastName
},
),
Map(nameStateLenses.FullName.Get),
)
fullName, err := result(context.Background())
fmt.Printf("Full Name: %s, Error: %v\n", fullName, err)
// Output: Full Name: John Doe, Error: <nil>
}
// fp-go:Lens
type StatusState struct {
Status string
}
// ExampleLetTo demonstrates attaching a constant value to a state.
// This is a simplified version of Let for when you want to add a constant
// value to the state without computing it.
//
// Step-by-step breakdown:
//
// 1. statusStateLenses := MakeStatusStateLenses() - Create lenses for accessing
// StatusState fields. This provides functional accessors (getters and setters)
// for the Status field.
//
// 2. Do(StatusState{}) - Initialize the do-notation chain with an empty StatusState.
// Initial state: {Status: ""}
//
// 3. LetToL(statusStateLenses.Status, "active") - Set the Status field to the
// constant value "active".
//
// LetToL is the lens-based version of LetTo and takes two parameters:
//
// a) First parameter: statusStateLenses.Status
// This is a lens that focuses on the Status field. The lens provides both
// a getter and setter for the field, enabling immutable updates.
//
// b) Second parameter: "active"
// This is the constant value to assign to the Status field. Unlike Let,
// which takes a function to compute the value, LetToL directly takes the
// value itself.
//
// The LetToL operation:
// - Takes the constant value "active"
// - Uses the lens setter to create a new state with Status = "active"
// - Returns the updated state
// After this step: {Status: "active"}
//
// 4. Map(statusStateLenses.Status.Get) - Transform the final state to extract
// just the Status field using the lens getter. This changes the result type
// from ReaderResult[StatusState] to ReaderResult[string].
//
// 5. result(context.Background()) - Execute the computation chain and return
// the final extracted value ("active") and any error.
//
// Comparison of state-setting operations:
// - LetToL: Set a field to a constant value using a lens (simplest)
// - LetL: Transform a field using a function and a lens
// - Let: Compute a value from state and update using a custom setter
// - Bind: Execute an effectful computation and update state with the result
//
// Use LetToL when you need to:
// - Set a field to a known constant value
// - Initialize state fields with default values
// - Update configuration or status flags
// - Assign literal values without any computation
//
// LetToL is the most straightforward way to set a constant value in do-notation,
// combining the simplicity of LetTo with the power of lenses for type-safe,
// immutable field updates.
func ExampleLetTo() {
statusStateLenses := MakeStatusStateLenses()
result := F.Pipe2(
Do(StatusState{}),
LetToL(
statusStateLenses.Status,
"active",
),
Map(statusStateLenses.Status.Get),
)
status, err := result(context.Background())
fmt.Printf("Status: %s, Error: %v\n", status, err)
// Output: Status: active, Error: <nil>
}
// fp-go:Lens
type UserState struct {
User User
}
// ExampleBindTo demonstrates initializing do-notation by binding a value to a state.
// This is typically used as the first operation after a computation to
// start building up a state structure.
func ExampleBindTo() {
userStatePrisms := MakeUserStatePrisms()
result := F.Pipe1(
getUser(42),
BindToP(userStatePrisms.User),
)
state, err := result(context.Background())
fmt.Printf("User: %s, Error: %v\n", state.User.Name, err)
// Output: User: Alice, Error: <nil>
}
// fp-go:Lens
type ConfigState struct {
Config string
}
// ExampleBindReaderK demonstrates binding a Reader computation (context-dependent
// but error-free) into a ReaderResult do-notation chain.
func ExampleBindReaderK() {
configStateLenses := MakeConfigStateLenses()
// A Reader that extracts a value from context
getConfig := func(ctx context.Context) string {
if val := ctx.Value("config"); val != nil {
return val.(string)
}
return "default"
}
result := F.Pipe1(
Do(ConfigState{}),
BindReaderK(configStateLenses.Config.Set,
func(s ConfigState) Reader[context.Context, string] {
return getConfig
},
),
)
ctx := context.WithValue(context.Background(), "config", "production")
state, err := result(ctx)
fmt.Printf("Config: %s, Error: %v\n", state.Config, err)
// Output: Config: production, Error: <nil>
}
// fp-go:Lens
type NumberState struct {
Number int
}
// ExampleBindEitherK demonstrates binding a Result (Either) computation into
// a ReaderResult do-notation chain. This is useful for integrating pure
// error-handling logic that doesn't need context.
func ExampleBindEitherK() {
numberStateLenses := MakeNumberStateLenses()
// A pure function that returns a Result
parseNumber := func(s NumberState) RES.Result[int] {
return RES.Of(42)
}
result := F.Pipe1(
Do(NumberState{}),
BindEitherK(
numberStateLenses.Number.Set,
parseNumber,
),
)
state, err := result(context.Background())
fmt.Printf("Number: %d, Error: %v\n", state.Number, err)
// Output: Number: 42, Error: <nil>
}
// fp-go:Lens
type DataState struct {
Data string
}
// ExampleBindResultK demonstrates binding an idiomatic Go function (returning
// value and error) into a ReaderResult do-notation chain. This is particularly
// useful for integrating existing Go code that follows the standard (value, error)
// return pattern into functional pipelines.
//
// Step-by-step breakdown:
//
// 1. dataStateLenses := MakeDataStateLenses() - Create lenses for accessing
// DataState fields. This provides functional accessors (getters and setters)
// for the Data field, enabling type-safe, immutable field updates.
//
// 2. fetchData := func(s DataState) (string, error) - Define an idiomatic Go
// function that takes the current state and returns a tuple of (value, error).
//
// IMPORTANT: This function represents a PURE READER COMPOSITION - it reads from
// the state and performs computations that don't require a context.Context.
// This is suitable for:
// - Pure computations that may fail (parsing, validation, calculations)
// - Operations that only depend on the state, not external context
// - Stateless transformations with error handling
// - Synchronous operations that don't need cancellation or timeouts
//
// For EFFECTFUL COMPOSITION (operations that need context), use the full
// ReaderResult type instead: func(context.Context) (Value, error)
// Use ReaderResult when you need:
// - Context cancellation or timeouts
// - Context values (request IDs, trace IDs, etc.)
// - Operations that depend on external context state
// - Async operations that should respect context lifecycle
//
// In this example, fetchData always succeeds with "fetched data", but in real
// code it might perform pure operations like:
// - Parsing or validating data from the state
// - Performing calculations that could fail
// - Calling pure functions from external libraries
// - Data transformations that don't require context
//
// 3. Do(DataState{}) - Initialize the do-notation chain with an empty DataState.
// This creates the initial ReaderResult that will accumulate data through
// subsequent operations.
// Initial state: {Data: ""}
//
// 4. BindResultK(dataStateLenses.Data.Set, fetchData) - Bind the idiomatic Go
// function into the ReaderResult chain.
//
// BindResultK takes two parameters:
//
// a) First parameter: dataStateLenses.Data.Set
// This is a setter function from the lens that will update the Data field
// with the result of the computation. The lens ensures immutable updates.
//
// b) Second parameter: fetchData
// This is the idiomatic Go function (State -> (Value, error)) that will be
// lifted into the ReaderResult context.
//
// The BindResultK operation flow:
// - Takes the current state: {Data: ""}
// - Calls fetchData with the state: fetchData(DataState{})
// - Gets the result tuple: ("fetched data", nil)
// - If error is not nil, short-circuits the chain and returns the error
// - If error is nil, uses the setter to update state.Data with "fetched data"
// - Returns the updated state: {Data: "fetched data"}
// After this step: {Data: "fetched data"}
//
// 5. result(context.Background()) - Execute the computation chain with a context.
// Even though fetchData doesn't use the context, the ReaderResult still needs
// one to maintain the uniform interface. This runs all operations in sequence
// and returns the final state and any error.
//
// Key concepts demonstrated:
// - Integration of idiomatic Go code: BindResultK bridges functional and imperative styles
// - Error propagation: Errors from the Go function automatically propagate through the chain
// - State transformation: The result updates the state using lens-based setters
// - Context independence: The function doesn't need context but still works in ReaderResult
//
// Comparison with other bind operations:
// - BindResultK: For idiomatic Go functions (State -> (Value, error))
// - Bind: For full ReaderResult computations (State -> ReaderResult[Value])
// - BindEitherK: For pure Result/Either values (State -> Result[Value])
// - BindReaderK: For context-dependent functions (State -> Reader[Context, Value])
//
// Use BindResultK when you need to:
// - Integrate existing Go code that returns (value, error)
// - Call functions that may fail but don't need context
// - Perform stateful computations with standard Go error handling
// - Bridge between functional pipelines and imperative Go code
// - Work with libraries that follow Go conventions
//
// Real-world example scenarios:
// - Parsing JSON from a state field: func(s State) (ParsedData, error)
// - Validating user input: func(s State) (ValidatedInput, error)
// - Performing calculations: func(s State) (Result, error)
// - Calling third-party libraries: func(s State) (APIResponse, error)
func ExampleBindResultK() {
dataStateLenses := MakeDataStateLenses()
// An idiomatic Go function returning (value, error)
fetchData := func(s DataState) (string, error) {
return "fetched data", nil
}
result := F.Pipe1(
Do(DataState{}),
BindResultK(
dataStateLenses.Data.Set,
fetchData,
),
)
state, err := result(context.Background())
fmt.Printf("Data: %s, Error: %v\n", state.Data, err)
// Output: Data: fetched data, Error: <nil>
}
// fp-go:Lens
type RequestState struct {
RequestID string
}
// ExampleBindToReader demonstrates converting a Reader computation into a
// ReaderResult and binding it to create an initial state.
func ExampleBindToReader() {
// A Reader that extracts request ID from context
getRequestID := func(ctx context.Context) string {
if val := ctx.Value("requestID"); val != nil {
return val.(string)
}
return "unknown"
}
result := F.Pipe1(
getRequestID,
BindToReader(func(id string) RequestState {
return RequestState{RequestID: id}
}),
)
ctx := context.WithValue(context.Background(), "requestID", "req-123")
state, err := result(ctx)
fmt.Printf("Request ID: %s, Error: %v\n", state.RequestID, err)
// Output: Request ID: req-123, Error: <nil>
}
// fp-go:Lens
type ValueState struct {
Value int
}
// ExampleBindToEither demonstrates converting a Result (Either) into a
// ReaderResult and binding it to create an initial state.
func ExampleBindToEither() {
// A Result value
resultValue := RES.Of(100)
result := F.Pipe1(
resultValue,
BindToEither(func(v int) ValueState {
return ValueState{Value: v}
}),
)
state, err := result(context.Background())
fmt.Printf("Value: %d, Error: %v\n", state.Value, err)
// Output: Value: 100, Error: <nil>
}
// fp-go:Lens
type ResultState struct {
Result string
}
// ExampleBindToResult demonstrates converting an idiomatic Go tuple (value, error)
// into a ReaderResult and binding it to create an initial state.
func ExampleBindToResult() {
// Simulate an idiomatic Go function result
value, err := "success", error(nil)
result := F.Pipe1(
BindToResult(func(v string) ResultState {
return ResultState{Result: v}
}),
func(f func(string, error) ReaderResult[ResultState]) ReaderResult[ResultState] {
return f(value, err)
},
)
state, resultErr := result(context.Background())
fmt.Printf("Result: %s, Error: %v\n", state.Result, resultErr)
// Output: Result: success, Error: <nil>
}
// fp-go:Lens
type EnvState struct {
Environment string
}
// ExampleApReaderS demonstrates applying a Reader computation in applicative style,
// combining it with the current state in a do-notation chain.
func ExampleApReaderS() {
// A Reader that gets environment from context
getEnv := func(ctx context.Context) string {
if val := ctx.Value("env"); val != nil {
return val.(string)
}
return "development"
}
result := F.Pipe1(
Do(EnvState{}),
ApReaderS(
func(env string) Endomorphism[EnvState] {
return func(s EnvState) EnvState {
s.Environment = env
return s
}
},
getEnv,
),
)
ctx := context.WithValue(context.Background(), "env", "staging")
state, err := result(ctx)
fmt.Printf("Environment: %s, Error: %v\n", state.Environment, err)
// Output: Environment: staging, Error: <nil>
}
// fp-go:Lens
type ScoreState struct {
Score int
}
// ExampleApEitherS demonstrates applying a Result (Either) in applicative style,
// combining it with the current state in a do-notation chain.
func ExampleApEitherS() {
// A Result value
scoreResult := RES.Of(95)
result := F.Pipe1(
Do(ScoreState{}),
ApEitherS(
func(score int) Endomorphism[ScoreState] {
return func(s ScoreState) ScoreState {
s.Score = score
return s
}
},
scoreResult,
),
)
state, err := result(context.Background())
fmt.Printf("Score: %d, Error: %v\n", state.Score, err)
// Output: Score: 95, Error: <nil>
}
// fp-go:Lens
type MessageState struct {
Message string
}
// ExampleApResultS demonstrates applying an idiomatic Go tuple (value, error)
// in applicative style, combining it with the current state in a do-notation chain.
func ExampleApResultS() {
// Simulate an idiomatic Go function result
value, err := "Hello, World!", error(nil)
result := F.Pipe1(
Do(MessageState{}),
func(rr ReaderResult[MessageState]) ReaderResult[MessageState] {
return F.Pipe1(
rr,
ApResultS(
func(msg string) Endomorphism[MessageState] {
return func(s MessageState) MessageState {
s.Message = msg
return s
}
},
)(value, err),
)
},
)
state, resultErr := result(context.Background())
fmt.Printf("Message: %s, Error: %v\n", state.Message, resultErr)
// Output: Message: Hello, World!, Error: <nil>
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"errors"
"fmt"
RES "github.com/IBM/fp-go/v2/result"
)
// ExampleFromEither demonstrates lifting a Result (Either) into a
// The resulting ReaderResult ignores the context and returns the Result value.
func ExampleFromEither() {
res := RES.Of(42)
rr := FromEither(res)
value, err := rr(context.Background())
fmt.Println(value, err)
// Output:
// 42 <nil>
}
// ExampleFromResult demonstrates creating a ReaderResult from a Go-style (value, error) tuple.
// This is useful for converting standard Go error handling into the ReaderResult monad.
func ExampleFromResult() {
rr := FromResult(42, nil)
value, err := rr(context.Background())
fmt.Println(value, err)
// Output:
// 42 <nil>
}
// ExampleFromResult_error demonstrates creating a ReaderResult from an error case.
// The resulting ReaderResult will propagate the error when executed.
func ExampleFromResult_error() {
rr := FromResult(0, errors.New("failed"))
value, err := rr(context.Background())
fmt.Println(value, err != nil)
// Output:
// 0 true
}
// ExampleLeft demonstrates creating a ReaderResult that always fails with an error.
// This is the error constructor for ReaderResult, analogous to Either's Left.
func ExampleLeft() {
rr := Left[int](errors.New("failed"))
value, err := rr(context.Background())
fmt.Println(value, err != nil)
// Output:
// 0 true
}
// ExampleRight demonstrates creating a ReaderResult that always succeeds with a value.
// This is the success constructor for ReaderResult, analogous to Either's Right.
func ExampleRight() {
rr := Right(42)
value, err := rr(context.Background())
fmt.Println(value, err)
// Output:
// 42 <nil>
}
// ExampleOf demonstrates the monadic return/pure operation for
// It creates a ReaderResult that always succeeds with the given value.
func ExampleOf() {
rr := Of(42)
value, err := rr(context.Background())
fmt.Println(value, err)
// Output:
// 42 <nil>
}
// ExampleAsk demonstrates getting the context.Context environment.
// This returns a ReaderResult that provides access to the context itself.
func ExampleAsk() {
rr := Ask()
ctx := context.Background()
value, err := rr(ctx)
fmt.Println(value == ctx, err)
// Output:
// true <nil>
}
// ExampleAsks demonstrates extracting a value from the context using a function.
// This is useful for accessing configuration or other data stored in the context.
func ExampleAsks() {
type Config struct {
Port int
}
getPort := Asks(func(ctx context.Context) int {
// In real code, extract config from context
return 8080
})
value, err := getPort(context.Background())
fmt.Println(value, err)
// Output:
// 8080 <nil>
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
RR "github.com/IBM/fp-go/v2/idiomatic/readerresult"
"github.com/IBM/fp-go/v2/reader"
)
// SequenceReader swaps the order of nested environment parameters when the inner type is a Reader.
//
// It transforms ReaderResult[Reader[R, A]] into a function that takes context.Context first,
// then R, and returns (A, error). This is useful when you have a ReaderResult computation
// that produces a Reader, and you want to sequence the environment dependencies.
//
// Type Parameters:
// - R: The inner Reader's environment type
// - A: The final result type
//
// Parameters:
// - ma: A ReaderResult that produces a Reader[R, A]
//
// Returns:
// - A Kleisli arrow that takes context.Context and R to produce (A, error)
//
// Example:
//
// type Config struct {
// DatabaseURL string
// }
//
// // Returns a ReaderResult that produces a Reader
// getDBReader := func(ctx context.Context) (reader.Reader[Config, string], error) {
// return func(cfg Config) string {
// return cfg.DatabaseURL
// }, nil
// }
//
// // Sequence the environments: context.Context -> Config -> string
// sequenced := readerresult.SequenceReader[Config, string](getDBReader)
// result, err := sequenced(ctx)(config)
//
//go:inline
func SequenceReader[R, A any](ma ReaderResult[Reader[R, A]]) Kleisli[R, A] {
return WithContextK(RR.SequenceReader(ma))
}
// TraverseReader combines SequenceReader with a Kleisli arrow transformation.
//
// It takes a Reader Kleisli arrow (a function from A to Reader[R, B]) and returns
// a function that transforms ReaderResult[A] into a Kleisli arrow from context.Context
// and R to B. This is useful for transforming values within a ReaderResult while
// introducing an additional Reader dependency.
//
// Type Parameters:
// - R: The Reader's environment type
// - A: The input type
// - B: The output type
//
// Parameters:
// - f: A Kleisli arrow that transforms A into Reader[R, B]
//
// Returns:
// - A function that transforms ReaderResult[A] into a Kleisli arrow from context.Context and R to B
//
// Example:
//
// type Config struct {
// Multiplier int
// }
//
// // A Kleisli arrow that uses Config to transform int to string
// formatWithConfig := func(n int) reader.Reader[Config, string] {
// return func(cfg Config) string {
// return fmt.Sprintf("Value: %d", n * cfg.Multiplier)
// }
// }
//
// // Create a ReaderResult[int]
// getValue := readerresult.Of[int](42)
//
// // Traverse: transform the int using the Reader Kleisli arrow
// traversed := readerresult.TraverseReader[Config](formatWithConfig)(getValue)
// result, err := traversed(ctx)(Config{Multiplier: 2})
// // result == "Value: 84"
//
//go:inline
func TraverseReader[R, A, B any](
f reader.Kleisli[R, A, B],
) func(ReaderResult[A]) Kleisli[R, B] {
return RR.TraverseReader[context.Context](f)
}

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
RR "github.com/IBM/fp-go/v2/idiomatic/readerresult"
)
// From0 converts a context-taking function into a thunk that returns a ReaderResult.
//
// Unlike Curry0 which returns a ReaderResult directly, From0 returns a function
// that when called produces a ReaderResult. This is useful for lazy evaluation.
//
// Type Parameters:
// - A: The return value type
//
// Parameters:
// - f: A function that takes context.Context and returns (A, error)
//
// Returns:
// - A thunk (function with no parameters) that returns ReaderResult[A]
//
// Example:
//
// func getConfig(ctx context.Context) (Config, error) {
// return Config{Port: 8080}, nil
// }
// thunk := readerresult.From0(getConfig)
// rr := thunk() // Create the ReaderResult
// config, err := rr(ctx) // Execute it
//
//go:inline
func From0[A any](f func(context.Context) (A, error)) func() ReaderResult[A] {
return RR.From0(f)
}
// From1 converts a function with one parameter into an uncurried ReaderResult-returning function.
//
// Unlike Curry1 which returns a curried function, From1 returns a function that takes
// all parameters at once (except context). This is more convenient for direct calls.
//
// Type Parameters:
// - T1: The parameter type
// - A: The return value type
//
// Parameters:
// - f: A function that takes (context.Context, T1) and returns (A, error)
//
// Returns:
// - A function that takes T1 and returns ReaderResult[A]
//
// Example:
//
// func getUser(ctx context.Context, id int) (User, error) {
// return User{ID: id}, nil
// }
// getUserRR := readerresult.From1(getUser)
// rr := getUserRR(42)
// user, err := rr(ctx)
//
//go:inline
func From1[T1, A any](f func(context.Context, T1) (A, error)) func(T1) ReaderResult[A] {
return RR.From1(f)
}
// From2 converts a function with two parameters into an uncurried ReaderResult-returning function.
//
// Type Parameters:
// - T1: The first parameter type
// - T2: The second parameter type
// - A: The return value type
//
// Parameters:
// - f: A function that takes (context.Context, T1, T2) and returns (A, error)
//
// Returns:
// - A function that takes (T1, T2) and returns ReaderResult[A]
//
// Example:
//
// func updateUser(ctx context.Context, id int, name string) (User, error) {
// return User{ID: id, Name: name}, nil
// }
// updateUserRR := readerresult.From2(updateUser)
// rr := updateUserRR(42, "Alice")
// user, err := rr(ctx)
//
//go:inline
func From2[T1, T2, A any](f func(context.Context, T1, T2) (A, error)) func(T1, T2) ReaderResult[A] {
return RR.From2(f)
}
// From3 converts a function with three parameters into an uncurried ReaderResult-returning function.
//
// Type Parameters:
// - T1: The first parameter type
// - T2: The second parameter type
// - T3: The third parameter type
// - A: The return value type
//
// Parameters:
// - f: A function that takes (context.Context, T1, T2, T3) and returns (A, error)
//
// Returns:
// - A function that takes (T1, T2, T3) and returns ReaderResult[A]
//
// Example:
//
// func createPost(ctx context.Context, userID int, title, body string) (Post, error) {
// return Post{UserID: userID, Title: title, Body: body}, nil
// }
// createPostRR := readerresult.From3(createPost)
// rr := createPostRR(42, "Title", "Body")
// post, err := rr(ctx)
//
//go:inline
func From3[T1, T2, T3, A any](f func(context.Context, T1, T2, T3) (A, error)) func(T1, T2, T3) ReaderResult[A] {
return RR.From3(f)
}

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package readerresult
//go:generate go run ../../../main.go lens --dir . --filename gen_lens.go

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// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
RR "github.com/IBM/fp-go/v2/idiomatic/readerresult"
M "github.com/IBM/fp-go/v2/monoid"
)
// AlternativeMonoid creates a Monoid for ReaderResult using the Alternative semantics.
//
// The Alternative semantics means that the monoid operation tries the first computation,
// and if it fails, tries the second one. The empty element is a computation that always fails.
// The inner values are combined using the provided monoid when both computations succeed.
//
// Type Parameters:
// - A: The value type
//
// Parameters:
// - m: A Monoid[A] for combining successful values
//
// Returns:
// - A Monoid[ReaderResult[A]] with Alternative semantics
//
// Example:
//
// import "github.com/IBM/fp-go/v2/monoid"
//
// // Monoid for integers with addition
// intMonoid := monoid.MonoidSum[int]()
// rrMonoid := readerresult.AlternativeMonoid(intMonoid)
//
// rr1 := readerresult.Right(10)
// rr2 := readerresult.Right(20)
// combined := rrMonoid.Concat(rr1, rr2)
// value, err := combined(ctx) // Returns (30, nil)
//
//go:inline
func AlternativeMonoid[A any](m M.Monoid[A]) Monoid[A] {
return RR.AlternativeMonoid[context.Context](m)
}
// AltMonoid creates a Monoid for ReaderResult using Alt semantics with a custom zero.
//
// The Alt semantics means that the monoid operation tries the first computation,
// and if it fails, tries the second one. The provided zero is used as the empty element.
//
// Type Parameters:
// - A: The value type
//
// Parameters:
// - zero: A lazy ReaderResult[A] to use as the empty element
//
// Returns:
// - A Monoid[ReaderResult[A]] with Alt semantics
//
// Example:
//
// zero := func() readerresult.ReaderResult[int] {
// return readerresult.Left[int](errors.New("empty"))
// }
// rrMonoid := readerresult.AltMonoid(zero)
//
// rr1 := readerresult.Left[int](errors.New("failed"))
// rr2 := readerresult.Right(42)
// combined := rrMonoid.Concat(rr1, rr2)
// value, err := combined(ctx) // Returns (42, nil) - uses second on first failure
//
//go:inline
func AltMonoid[A any](zero Lazy[ReaderResult[A]]) Monoid[A] {
return RR.AltMonoid(zero)
}
// ApplicativeMonoid creates a Monoid for ReaderResult using Applicative semantics.
//
// The Applicative semantics means that both computations are executed independently,
// and their results are combined using the provided monoid. If either fails, the
// entire operation fails.
//
// Type Parameters:
// - A: The value type
//
// Parameters:
// - m: A Monoid[A] for combining successful values
//
// Returns:
// - A Monoid[ReaderResult[A]] with Applicative semantics
//
// Example:
//
// import "github.com/IBM/fp-go/v2/monoid"
//
// // Monoid for integers with addition
// intMonoid := monoid.MonoidSum[int]()
// rrMonoid := readerresult.ApplicativeMonoid(intMonoid)
//
// rr1 := readerresult.Right(10)
// rr2 := readerresult.Right(20)
// combined := rrMonoid.Concat(rr1, rr2)
// value, err := combined(ctx) // Returns (30, nil)
//
//go:inline
func ApplicativeMonoid[A any](m M.Monoid[A]) Monoid[A] {
return RR.ApplicativeMonoid[context.Context](m)
}

692
v2/idiomatic/context/readerresult/reader.go Normal file
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@@ -0,0 +1,692 @@
// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package readerresult
import (
"context"
"sync"
"time"
RS "github.com/IBM/fp-go/v2/context/readerresult"
"github.com/IBM/fp-go/v2/either"
"github.com/IBM/fp-go/v2/function"
"github.com/IBM/fp-go/v2/idiomatic/option"
RR "github.com/IBM/fp-go/v2/idiomatic/readerresult"
"github.com/IBM/fp-go/v2/idiomatic/result"
"github.com/IBM/fp-go/v2/reader"
RES "github.com/IBM/fp-go/v2/result"
)
// FromEither lifts a Result (Either[error, A]) into a ReaderResult.
//
// The resulting ReaderResult ignores the context.Context environment and simply
// returns the Result value. This is useful for converting existing Result values
// into the ReaderResult monad for composition with other ReaderResult operations.
//
// Type Parameters:
// - A: The success value type
//
// Parameters:
// - e: A Result[A] (Either[error, A]) to lift
//
// Returns:
// - A ReaderResult[A] that ignores the context and returns the Result
//
//go:inline
func FromEither[A any](e Result[A]) ReaderResult[A] {
return RR.FromEither[context.Context](e)
}
// FromResult creates a ReaderResult from a Go-style (value, error) tuple.
//
// This is a convenience function for converting standard Go error handling
// into the ReaderResult monad. The resulting ReaderResult ignores the context.
//
// Type Parameters:
// - A: The value type
//
// Parameters:
// - a: The value
// - err: The error (nil for success)
//
// Returns:
// - A ReaderResult[A] that returns the given value and error
//
//go:inline
func FromResult[A any](a A, err error) ReaderResult[A] {
return RR.FromResult[context.Context](a, err)
}
//go:inline
func RightReader[A any](rdr Reader[context.Context, A]) ReaderResult[A] {
return RR.RightReader(rdr)
}
//go:inline
func LeftReader[A, R any](l Reader[context.Context, error]) ReaderResult[A] {
return RR.LeftReader[A](l)
}
// Left creates a ReaderResult that always fails with the given error.
//
// This is the error constructor for ReaderResult, analogous to Either's Left.
// The resulting computation ignores the context and immediately returns the error.
//
// Type Parameters:
// - A: The success type (for type inference)
//
// Parameters:
// - err: The error to return
//
// Returns:
// - A ReaderResult[A] that always fails with the given error
//
//go:inline
func Left[A any](err error) ReaderResult[A] {
return RR.Left[context.Context, A](err)
}
// Right creates a ReaderResult that always succeeds with the given value.
//
// This is the success constructor for ReaderResult, analogous to Either's Right.
// The resulting computation ignores the context and immediately returns the value.
//
// Type Parameters:
// - A: The value type
//
// Parameters:
// - a: The value to return
//
// Returns:
// - A ReaderResult[A] that always succeeds with the given value
//
//go:inline
func Right[A any](a A) ReaderResult[A] {
return RR.Right[context.Context](a)
}
// FromReader lifts a Reader into a ReaderResult that always succeeds.
//
// The Reader computation is executed and its result is wrapped in a successful Result.
// This is useful for incorporating Reader computations into ReaderResult pipelines.
//
// Type Parameters:
// - A: The value type
//
// Parameters:
// - r: A Reader[context.Context, A] to lift
//
// Returns:
// - A ReaderResult[A] that executes the Reader and always succeeds
//
//go:inline
func FromReader[A any](r Reader[context.Context, A]) ReaderResult[A] {
return RR.FromReader(r)
}
//go:inline
func FromReaderResult[A any](r RS.ReaderResult[A]) ReaderResult[A] {
return func(ctx context.Context) (A, error) {
return either.Unwrap(r(ctx))
}
}
//go:inline
func ToReaderResult[A any](r ReaderResult[A]) RS.ReaderResult[A] {
return func(ctx context.Context) Result[A] {
return either.TryCatchError(r(ctx))
}
}
// MonadMap transforms the success value of a ReaderResult using the given function.
//
// If the ReaderResult fails, the error is propagated unchanged. This is the
// Functor's map operation for ReaderResult.
//
// Type Parameters:
// - A: The input value type
// - B: The output value type
//
// Parameters:
// - fa: The ReaderResult to transform
// - f: The transformation function
//
// Returns:
// - A ReaderResult[B] with the transformed value
//
//go:inline
func MonadMap[A, B any](fa ReaderResult[A], f func(A) B) ReaderResult[B] {
return RR.MonadMap(fa, f)
}
// Map is the curried version of MonadMap, useful for function composition.
//
// It returns an Operator that can be used in pipelines with F.Pipe.
//
// Type Parameters:
// - A: The input value type
// - B: The output value type
//
// Parameters:
// - f: The transformation function
//
// Returns:
// - An Operator that transforms ReaderResult[A] to ReaderResult[B]
//
//go:inline
func Map[A, B any](f func(A) B) Operator[A, B] {
return RR.Map[context.Context](f)
}
// MonadChain sequences two ReaderResult computations where the second depends on the first.
//
// This is the monadic bind operation (flatMap). If the first computation fails,
// the error is propagated and the second computation is not executed. Both
// computations share the same context.Context environment.
//
// Type Parameters:
// - A: The input value type
// - B: The output value type
//
// Parameters:
// - ma: The first ReaderResult computation
// - f: A Kleisli arrow that produces the second computation based on the first's result
//
// Returns:
// - A ReaderResult[B] representing the sequenced computation
//
//go:inline
func MonadChain[A, B any](ma ReaderResult[A], f Kleisli[A, B]) ReaderResult[B] {
return RR.MonadChain(ma, WithContextK(f))
}
// Chain is the curried version of MonadChain, useful for function composition.
//
// It returns an Operator that can be used in pipelines with F.Pipe.
//
// Type Parameters:
// - A: The input value type
// - B: The output value type
//
// Parameters:
// - f: A Kleisli arrow for the second computation
//
// Returns:
// - An Operator that chains ReaderResult computations
//
//go:inline
func Chain[A, B any](f Kleisli[A, B]) Operator[A, B] {
return RR.Chain(WithContextK(f))
}
// Of creates a ReaderResult that always succeeds with the given value.
//
// This is an alias for Right and represents the Applicative's pure/return operation.
// The resulting computation ignores the context and immediately returns the value.
//
// Type Parameters:
// - A: The value type
//
// Parameters:
// - a: The value to wrap
//
// Returns:
// - A ReaderResult[A] that always succeeds with the given value
//
//go:inline
func Of[A any](a A) ReaderResult[A] {
return RR.Of[context.Context](a)
}
// MonadAp applies a function wrapped in a ReaderResult to a value wrapped in a ReaderResult.
//
// This is the Applicative's ap operation. Both computations are executed concurrently
// using goroutines, and the context is shared between them. If either computation fails,
// the entire operation fails. If the context is cancelled, the operation is aborted.
//
// The concurrent execution allows for parallel independent computations, which can
// improve performance when both operations involve I/O or other blocking operations.
//
// Type Parameters:
// - B: The result type after applying the function
// - A: The input type to the function
//
// Parameters:
// - fab: A ReaderResult containing a function from A to B
// - fa: A ReaderResult containing a value of type A
//
// Returns:
// - A ReaderResult[B] that applies the function to the value
//
// Example:
//
// // Create a function wrapped in ReaderResult
// addTen := readerresult.Right(func(n int) int {
// return n + 10
// })
//
// // Create a value wrapped in ReaderResult
// value := readerresult.Right(32)
//
// // Apply the function to the value
// result := readerresult.MonadAp(addTen, value)
// output, err := result(ctx) // Returns (42, nil)
//
// Error Handling:
//
// // If the function fails
// failedFn := readerresult.Left[func(int) int](errors.New("function error"))
// result := readerresult.MonadAp(failedFn, value)
// _, err := result(ctx) // Returns function error
//
// // If the value fails
// failedValue := readerresult.Left[int](errors.New("value error"))
// result := readerresult.MonadAp(addTen, failedValue)
// _, err := result(ctx) // Returns value error
//
// Context Cancellation:
//
// ctx, cancel := context.WithCancel(context.Background())
// cancel() // Cancel immediately
// result := readerresult.MonadAp(addTen, value)
// _, err := result(ctx) // Returns context cancellation error
func MonadAp[B, A any](fab ReaderResult[func(A) B], fa ReaderResult[A]) ReaderResult[B] {
return func(ctx context.Context) (B, error) {
if ctx.Err() != nil {
return result.Left[B](context.Cause(ctx))
}
var wg sync.WaitGroup
wg.Add(1)
cancelCtx, cancelFct := context.WithCancel(ctx)
defer cancelFct()
var a A
var aerr error
go func() {
defer wg.Done()
a, aerr = fa(cancelCtx)
if aerr != nil {
cancelFct()
}
}()
ab, aberr := fab(cancelCtx)
if aberr != nil {
cancelFct()
wg.Wait()
return result.Left[B](aberr)
}
wg.Wait()
if aerr != nil {
return result.Left[B](aerr)
}
return result.Of(ab(a))
}
}
// Ap is the curried version of MonadAp, useful for function composition.
//
// It fixes the value argument and returns an Operator that can be applied
// to a ReaderResult containing a function. This is particularly useful in
// pipelines where you want to apply a fixed value to various functions.
//
// Type Parameters:
// - B: The result type after applying the function
// - A: The input type to the function
//
// Parameters:
// - fa: A ReaderResult containing a value of type A
//
// Returns:
// - An Operator that applies the value to a function wrapped in ReaderResult
//
// Example:
//
// import F "github.com/IBM/fp-go/v2/function"
//
// value := readerresult.Right(32)
// addTen := readerresult.Right(N.Add(10))
//
// result := F.Pipe1(
// addTen,
// readerresult.Ap[int](value),
// )
// output, err := result(ctx) // Returns (42, nil)
//
//go:inline
func Ap[B, A any](fa ReaderResult[A]) Operator[func(A) B, B] {
return function.Bind2nd(MonadAp[B, A], fa)
}
//go:inline
func FromPredicate[A any](pred func(A) bool, onFalse func(A) error) Kleisli[A, A] {
return WithContextK(RR.FromPredicate[context.Context](pred, onFalse))
}
//go:inline
func Fold[A, B any](onLeft reader.Kleisli[context.Context, error, B], onRight reader.Kleisli[context.Context, A, B]) func(ReaderResult[A]) Reader[context.Context, B] {
return RR.Fold(onLeft, onRight)
}
//go:inline
func GetOrElse[A any](onLeft reader.Kleisli[context.Context, error, A]) func(ReaderResult[A]) Reader[context.Context, A] {
return RR.GetOrElse(onLeft)
}
//go:inline
func OrElse[A any](onLeft Kleisli[error, A]) Operator[A, A] {
return RR.OrElse(WithContextK(onLeft))
}
//go:inline
func OrLeft[A any](onLeft reader.Kleisli[context.Context, error, error]) Operator[A, A] {
return RR.OrLeft[A](onLeft)
}
// Ask retrieves the current context.Context environment.
//
// This is the Reader's ask operation, which provides access to the environment.
// It always succeeds and returns the context that was passed in.
//
// Returns:
// - A ReaderResult[context.Context] that returns the environment
//
//go:inline
func Ask() ReaderResult[context.Context] {
return RR.Ask[context.Context]()
}
// Asks extracts a value from the context.Context environment using a Reader function.
//
// This is useful for accessing specific parts of the environment. The Reader
// function is applied to the context, and the result is wrapped in a successful ReaderResult.
//
// Type Parameters:
// - A: The extracted value type
//
// Parameters:
// - r: A Reader function that extracts a value from the context
//
// Returns:
// - A ReaderResult[A] that extracts and returns the value
//
//go:inline
func Asks[A any](r Reader[context.Context, A]) ReaderResult[A] {
return RR.Asks(r)
}
//go:inline
func MonadChainEitherK[A, B any](ma ReaderResult[A], f RES.Kleisli[A, B]) ReaderResult[B] {
return RR.MonadChainEitherK(ma, f)
}
//go:inline
func ChainEitherK[A, B any](f RES.Kleisli[A, B]) Operator[A, B] {
return RR.ChainEitherK[context.Context](f)
}
//go:inline
func MonadChainReaderK[A, B any](ma ReaderResult[A], f result.Kleisli[A, B]) ReaderResult[B] {
return RR.MonadChainReaderK(ma, f)
}
//go:inline
func ChainReaderK[A, B any](f result.Kleisli[A, B]) Operator[A, B] {
return RR.ChainReaderK[context.Context](f)
}
//go:inline
func ChainOptionK[A, B any](onNone Lazy[error]) func(option.Kleisli[A, B]) Operator[A, B] {
return RR.ChainOptionK[context.Context, A, B](onNone)
}
// Flatten removes one level of ReaderResult nesting.
//
// This is equivalent to Chain with the identity function. It's useful when you have
// a ReaderResult that produces another ReaderResult and want to collapse them into one.
//
// Type Parameters:
// - A: The inner value type
//
// Parameters:
// - mma: A nested ReaderResult[ReaderResult[A]]
//
// Returns:
// - A flattened ReaderResult[A]
//
//go:inline
func Flatten[A any](mma ReaderResult[ReaderResult[A]]) ReaderResult[A] {
return RR.Flatten(mma)
}
//go:inline
func MonadBiMap[A, B any](fa ReaderResult[A], f Endomorphism[error], g func(A) B) ReaderResult[B] {
return RR.MonadBiMap(fa, f, g)
}
//go:inline
func BiMap[A, B any](f Endomorphism[error], g func(A) B) Operator[A, B] {
return RR.BiMap[context.Context](f, g)
}
// Read executes a ReaderResult by providing it with a context.Context.
//
// This is the elimination form for ReaderResult - it "runs" the computation
// by supplying the required environment, producing a (value, error) tuple.
//
// Type Parameters:
// - A: The result value type
//
// Parameters:
// - ctx: The context.Context environment to provide
//
// Returns:
// - A function that executes a ReaderResult[A] and returns (A, error)
//
//go:inline
func Read[A any](ctx context.Context) func(ReaderResult[A]) (A, error) {
return RR.Read[A](ctx)
}
//go:inline
func MonadFlap[A, B any](fab ReaderResult[func(A) B], a A) ReaderResult[B] {
return RR.MonadFlap(fab, a)
}
//go:inline
func Flap[B, A any](a A) Operator[func(A) B, B] {
return RR.Flap[context.Context, B](a)
}
//go:inline
func MonadMapLeft[A any](fa ReaderResult[A], f Endomorphism[error]) ReaderResult[A] {
return RR.MonadMapLeft(fa, f)
}
//go:inline
func MapLeft[A any](f Endomorphism[error]) Operator[A, A] {
return RR.MapLeft[context.Context, A](f)
}
//go:inline
func MonadAlt[A any](first ReaderResult[A], second Lazy[ReaderResult[A]]) ReaderResult[A] {
return RR.MonadAlt(first, second)
}
//go:inline
func Alt[A any](second Lazy[ReaderResult[A]]) Operator[A, A] {
return RR.Alt(second)
}
// Local transforms the context.Context environment before passing it to a ReaderResult computation.
//
// This is the Reader's local operation, which allows you to modify the environment
// for a specific computation without affecting the outer context. The transformation
// function receives the current context and returns a new context along with a
// cancel function. The cancel function is automatically called when the computation
// completes (via defer), ensuring proper cleanup of resources.
//
// This is useful for:
// - Adding timeouts or deadlines to specific operations
// - Adding context values for nested computations
// - Creating isolated context scopes
// - Implementing context-based dependency injection
//
// Type Parameters:
// - A: The value type of the ReaderResult
//
// Parameters:
// - f: A function that transforms the context and returns a cancel function
//
// Returns:
// - An Operator that runs the computation with the transformed context
//
// Example:
//
// import F "github.com/IBM/fp-go/v2/function"
//
// // Add a custom value to the context
// type key int
// const userKey key = 0
//
// addUser := readerresult.Local[string](func(ctx context.Context) (context.Context, context.CancelFunc) {
// newCtx := context.WithValue(ctx, userKey, "Alice")
// return newCtx, func() {} // No-op cancel
// })
//
// getUser := readerresult.Asks(func(ctx context.Context) string {
// return ctx.Value(userKey).(string)
// })
//
// result := F.Pipe1(
// getUser,
// addUser,
// )
// user, err := result(context.Background()) // Returns ("Alice", nil)
//
// Timeout Example:
//
// // Add a 5-second timeout to a specific operation
// withTimeout := readerresult.Local[Data](func(ctx context.Context) (context.Context, context.CancelFunc) {
// return context.WithTimeout(ctx, 5*time.Second)
// })
//
// result := F.Pipe1(
// fetchData,
// withTimeout,
// )
func Local[A any](f func(context.Context) (context.Context, context.CancelFunc)) Operator[A, A] {
return func(rr ReaderResult[A]) ReaderResult[A] {
return func(ctx context.Context) (A, error) {
if ctx.Err() != nil {
return result.Left[A](context.Cause(ctx))
}
otherCtx, otherCancel := f(ctx)
defer otherCancel()
return rr(otherCtx)
}
}
}
// WithTimeout adds a timeout to the context for a ReaderResult computation.
//
// This is a convenience wrapper around Local that uses context.WithTimeout.
// The computation must complete within the specified duration, or it will be
// cancelled. This is useful for ensuring operations don't run indefinitely
// and for implementing timeout-based error handling.
//
// The timeout is relative to when the ReaderResult is executed, not when
// WithTimeout is called. The cancel function is automatically called when
// the computation completes, ensuring proper cleanup.
//
// Type Parameters:
// - A: The value type of the ReaderResult
//
// Parameters:
// - timeout: The maximum duration for the computation
//
// Returns:
// - An Operator that runs the computation with a timeout
//
// Example:
//
// import (
// "time"
// F "github.com/IBM/fp-go/v2/function"
// )
//
// // Fetch data with a 5-second timeout
// fetchData := readerresult.FromReader(func(ctx context.Context) Data {
// // Simulate slow operation
// select {
// case <-time.After(10 * time.Second):
// return Data{Value: "slow"}
// case <-ctx.Done():
// return Data{}
// }
// })
//
// result := F.Pipe1(
// fetchData,
// readerresult.WithTimeout[Data](5*time.Second),
// )
// _, err := result(context.Background()) // Returns context.DeadlineExceeded after 5s
//
// Successful Example:
//
// quickFetch := readerresult.Right(Data{Value: "quick"})
// result := F.Pipe1(
// quickFetch,
// readerresult.WithTimeout[Data](5*time.Second),
// )
// data, err := result(context.Background()) // Returns (Data{Value: "quick"}, nil)
func WithTimeout[A any](timeout time.Duration) Operator[A, A] {
return Local[A](func(ctx context.Context) (context.Context, context.CancelFunc) {
return context.WithTimeout(ctx, timeout)
})
}
// WithDeadline adds an absolute deadline to the context for a ReaderResult computation.
//
// This is a convenience wrapper around Local that uses context.WithDeadline.
// The computation must complete before the specified time, or it will be
// cancelled. This is useful for coordinating operations that must finish
// by a specific time, such as request deadlines or scheduled tasks.
//
// The deadline is an absolute time, unlike WithTimeout which uses a relative
// duration. The cancel function is automatically called when the computation
// completes, ensuring proper cleanup.
//
// Type Parameters:
// - A: The value type of the ReaderResult
//
// Parameters:
// - deadline: The absolute time by which the computation must complete
//
// Returns:
// - An Operator that runs the computation with a deadline
func WithDeadline[A any](deadline time.Time) Operator[A, A] {
return Local[A](func(ctx context.Context) (context.Context, context.CancelFunc) {
return context.WithDeadline(ctx, deadline)
})
}

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