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Commit Graph

44 Commits

Author SHA1 Message Date
Andreas Rheinhardt
1a7efafd33 avutil/tx: Use proper deallocator
May fix the FATE failures on x64 Windows here:
https://fate.ffmpeg.org/report.cgi?slot=x86_64-msvc17-windows-native&time=20221125130443

Reviewed-by: Lynne <dev@lynne.ee>
Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@outlook.com>
2022-11-25 15:54:33 +01:00
Lynne
7f019e7758
lavu/tx: add length decomposition function
Rather than using a list of lengths supported, this goes a step beyond
and uses all registered codelets to come up with a good decomposition.
2022-11-24 15:58:34 +01:00
Lynne
87bae6b018
lavu/tx: refactor to explicitly track and convert lookup table order
Necessary for generalizing PFAs.
2022-11-24 15:58:34 +01:00
Lynne
1c8d77a2bf
lavu/tx: refactor and separate codelet list and prio code 2022-11-24 15:58:33 +01:00
Lynne
958b3760b5
lavu/tx: improve transform tree logging
Now prints the actual codelet size used, as well as the number of
allowed factors.
2022-11-24 15:58:33 +01:00
Lynne
6ddd10c3e2
lavu/tx: allow codelets to specify a minimum number of matching factors 2022-11-24 15:58:33 +01:00
Lynne
dd77e61182
lavu/tx: add ff_tx_clear_ctx()
This function allows implementations to clean up a context after
successfully initializing subcontexts.
2022-11-24 15:58:32 +01:00
Lynne
45bd4bf79f
lavu/tx: generalize single-factor transforms
Not that useful, but it gives us fast small odd-length transforms.
2022-11-24 15:58:28 +01:00
James Almer
d5c7970a27 avutil/tx: use a lower log level for the debug messages
The amount of lines printed is too high for the verbose level, and the debug
level is a better fit for their content.

Signed-off-by: James Almer <jamrial@gmail.com>
2022-11-08 14:08:05 -03:00
Lynne
e7a987d7c9
lavu/tx: remove special -1 inverted lookup mode
It was somewhat hacky and unnecessary.
2022-09-23 12:35:28 +02:00
Lynne
8c283e8fe6
lavu/tx: propagate the codelet flags into the context
The field is documented as a combination of both.
2022-09-10 02:37:11 +02:00
Lynne
4537d9554d
x86/tx_float: implement inverse MDCT AVX2 assembly
This commit implements an iMDCT in pure assembly.

This is capable of processing any mod-8 transforms, rather than just
power of two, but since power of two is all we have assembly for
currently, that's what's supported.
It would really benefit if we could somehow use the C code to decide
which function to jump into, but exposing function labels from assebly
into C is anything but easy.
The post-transform loop could probably be improved.

This was somewhat annoying to write, as we must support arbitrary
strides during runtime. There's a fast branch for stride == 4 bytes
and a slower one which uses vgatherdps.

Zen 3 benchmarks for stride == 4 for old (av_imdct_half) vs new (av_tx):

128pt:
   2811 decicycles in         av_tx (imdct),16775916 runs,   1300 skips
   3082 decicycles in         av_imdct_half,16776751 runs,    465 skips

256pt:
   4920 decicycles in         av_tx (imdct),16775820 runs,   1396 skips
   5378 decicycles in         av_imdct_half,16776411 runs,    805 skips

512pt:
   9668 decicycles in         av_tx (imdct),16775774 runs,   1442 skips
  10626 decicycles in         av_imdct_half,16775647 runs,   1569 skips

1024pt:
  19812 decicycles in         av_tx (imdct),16777144 runs,     72 skips
  23036 decicycles in         av_imdct_half,16777167 runs,     49 skips
2022-09-06 04:21:46 +02:00
Lynne
2425d5cd7e
x86/tx_float: add support for calling assembly functions from assembly
Needed for the next patch.
We get this for the extremely small cost of a branch on _ns functions,
which wouldn't be used anyway with assembly.
2022-09-06 04:21:41 +02:00
Lynne
f932b89ea3
lavu/tx: implement aarch64 NEON SIMD FFT
The fastest fast Fourier transform in not just the west, but the world,
now for the most popular toy ISA.

On a high level, it follows the design of the AVX2 version closely,
with the exception that the input is slightly less permuted as we don't have
to do lane switching with the input on double 4pt and 8pt.

On a low level, the lack of subadd/addsub instructions REALLY penalizes
any attempt at writing an FFT. That single register matters a lot,
and reloading it simply takes unacceptably long.
In x86 land, vendors would've noticed developers need this.
In ARM land, you get a badly designed complex multiplication instruction
we cannot use, that's not present on 95% of devices. Because only
compilers matter, right?

Future optimization options are very few, perhaps better register
management to use more ld1/st1s.

All timings below are in cycles:
A53:
Length | C           | New (lavu)  | Old (lavc)  | FFTW
------ |-------------|-------------|-------------|-----
4      |         842 | 420         | 1210        | 1460
8      |        1538 | 1020        | 1850        | 2520
16     |        3717 | 1900        | 3700        | 3990
32     |        9156 | 4070        | 8289        | 8860
64     |       21160 | 9931        | 18600       | 19625
128    |       49180 | 23278       | 41922       | 41922
256    |      112073 | 53876       | 93202       | 101092
512    |      252864 | 122884      | 205897      | 207868
1024   |      560512 | 278322      | 458071      | 453053
2048   |     1295402 | 775835      | 1038205     | 1020265
4096   |     3281263 | 2021221     | 2409718     | 2577554
8192   |     8577845 | 4780526     | 5673041     | 6802722

Apple M1
New  - Total for len 512 reps 2097152 = 1.459141 s
Old  - Total for len 512 reps 2097152 = 2.251344 s
FFTW - Total for len 512 reps 2097152 = 1.868429 s

New  - Total for len 1024 reps 4194304 = 6.490080 s
Old  - Total for len 1024 reps 4194304 = 9.604949 s
FFTW - Total for len 1024 reps 4194304 = 7.889281 s

New  - Total for len 16384 reps 262144 = 10.374001 s
Old  - Total for len 16384 reps 262144 = 15.266713 s
FFTW - Total for len 16384 reps 262144 = 12.341745 s

New  - Total for len 65536 reps 8192 = 1.769812 s
Old  - Total for len 65536 reps 8192 = 4.209413 s
FFTW - Total for len 65536 reps 8192 = 3.012365 s

New  - Total for len 131072 reps 4096 = 1.942836 s
Old  - Segfaults
FFTW - Total for len 131072 reps 4096 = 3.713713 s

Thanks to wbs for some simplifications, assembler fixes and a review
and to jannau for giving it a look.
2022-08-25 17:40:28 +02:00
Andreas Rheinhardt
0bb0c26799 avutil/mem_internal: Fix headers
Including avassert.h is unnecessary since commit
786be70e28.

Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@outlook.com>
2022-08-24 03:43:52 +02:00
Lynne
ae66a9db7b
lavu/tx: optimize and simplify inverse MDCTs
Convert the input from a scatter to a gather instead,
which is faster and better for SIMD.
Also, add a pre-shuffled exptab version to avoid
gathering there at all. This doubles the exptab size,
but the speedup makes it worth it. In SIMD, the
exptab will likely be purged to a higher cache
anyway because of the FFT in the middle, and
the amount of loads stays identical.

For a 960-point inverse MDCT, the speedup is 10%.

This makes it possible to write sane and fast SIMD
versions of inverse MDCTs.
2022-08-16 01:22:38 +02:00
Lynne
805e8d1921
lavu/tx: make slow ISA extension penalties smarter
Instead of having a fixed -64 prio penalty, make the penalties
more granular.
As the prio is based on the register size in bits, decrementing
it by 129 makes AVX SLOW functions be avoided in favor of any
SSE versions.
2022-05-21 02:10:14 +02:00
Lynne
04cc7a5548
lavu/tx: wrap missed string in NULL_IF_CONFIG_SMALL
It's the only one that isn't defined through the macros used elsewhere.
2022-02-07 04:23:31 +01:00
Lynne
eac4c3574b
lavu/tx: disable debugging information when CONFIG_SMALL 2022-02-07 03:56:47 +01:00
Lynne
7e35e0224c
lavu/tx: do not unconditionally free subcontexts if initialization fails
If a codelet initializes 2 subtransforms, and the second one fails,
the failure would free all subcontexts.
Instead, if there are subcontexts still left, don't free the array.
If all initializations fail, the init() function will return,
and reset_ctx() from the previous step will clean up all contained
subtransforms.
2022-01-29 01:02:37 +01:00
Lynne
265731f201
lavu/tx: reset subcontext pointer if initialization fails
Thanks to mkver for pointing this out.
2022-01-29 00:53:35 +01:00
Lynne
95f02e43e1
lavu/tx: print debug info even if no transforms are found 2022-01-28 08:28:02 +01:00
Steven Liu
9887ec3e9b avutil/tx: add null pointer check after av_mallocz
Fix CID: 1497863
there will get null pointer in attempt to initialize each if alloc memory failed.

Signed-off-by: Steven Liu <liuqi05@kuaishou.com>
2022-01-28 08:27:48 +01:00
Steven Liu
f0044d886f avutil/tx: remove deadcode of the control flow
Fix CID: 1497864
The control flow should return ENOSYS if nb_cd_matches is 0 at before
and the ret equal AVERROR(ENOMEM) or goto end label, so remove the last
control flow if (ret >= 0) before end label.

Signed-off-by: Steven Liu <liuqi05@kuaishou.com>
2022-01-28 08:27:46 +01:00
Lynne
008c131d68
lavu/tx: clean up CPU flags check
Just makes it more readable.
2022-01-27 02:18:06 +01:00
Lynne
9787005846
x86/tx_float: do not build tx_float_init.c if x86 assembly is disabled
This broke builds with --disable-mmx, which also disabled assembly
entirely, but ARCH_X86 was still true, so the init file tried to find
assembly that didn't exist.
Instead of checking for architecture, check if external x86 assembly
is enabled.
2022-01-27 02:17:46 +01:00
Lynne
6c8e841824
lavu/tx: do not mix declarations and code 2022-01-26 04:55:23 +01:00
Lynne
af94ab7c7c
lavu/tx: add an RDFT implementation
RDFTs are full of conventions that vary between implementations.
What I've gone for here is what's most common between
both fftw, avcodec's rdft and what we use, the equivalent of
which is DFT_R2C for forward and IDFT_C2R for inverse. The
other 2 conventions (IDFT_R2C and DFT_C2R) were not used at
all in our code, and their names are also not appropriate.
If there's a use for either, we can easily add a flag which
would just flip the sign on one exptab.

For some unknown reason, possibly to allow reusing FFT's exp tables,
av_rdft's C2R output is 0.5x lower than what it should be to ensure
a proper back-and-forth conversion.
This code outputs its real samples at the correct level, which
matches FFTW's level, and allows the user to change the level
and insert arbitrary multiplies for free by setting the scale option.
2022-01-26 04:12:46 +01:00
Lynne
ef4bd81615
lavu/tx: rewrite internal code as a tree-based codelet constructor
This commit rewrites the internal transform code into a constructor
that stitches transforms (codelets).
This allows for transforms to reuse arbitrary parts of other
transforms, and allows transforms to be stacked onto one
another (such as a full iMDCT using a half-iMDCT which in turn
uses an FFT). It also permits for each step to be individually
replaced by assembly or a custom implementation (such as an ASIC).
2022-01-26 04:12:44 +01:00
James Almer
35331aa266 avutil/tx: add a return at the end of non-void functions
Fixes compilation with GCC 11 when configured with --disable-optimizations

Signed-off-by: James Almer <jamrial@gmail.com>
2021-08-06 21:22:49 -03:00
Michael Niedermayer
85b883429f avutil/tx: avoid negative left shifts
Fixes: left shift of negative value -1
Fixes: 33736/clusterfuzz-testcase-minimized-ffmpeg_AV_CODEC_ID_SIREN_fuzzer-6657785795313664

Found-by: continuous fuzzing process https://github.com/google/oss-fuzz/tree/master/projects/ffmpeg
Signed-off-by: Michael Niedermayer <michael@niedermayer.cc>
2021-06-18 18:58:25 +02:00
Lynne
119a3f7e8d
lavu/x86: add FFT assembly
This commit adds a pure x86 assembly SIMD version of the FFT in libavutil/tx.
The design of this pure assembly FFT is pretty unconventional.

On the lowest level, instead of splitting the complex numbers into
real and imaginary parts, we keep complex numbers together but split
them in terms of parity. This saves a number of shuffles in each transform,
but more importantly, it splits each transform into two independent
paths, which we process using separate registers in parallel.
This allows us to keep all units saturated and lets us use all available
registers to avoid dependencies.
Moreover, it allows us to double the granularity of our per-load permutation,
skipping many expensive lookups and allowing us to use just 4 loads per register,
rather than 8, or in case FMA3 (and by extension, AVX2), use the vgatherdpd
instruction, which is at least as fast as 4 separate loads on old hardware,
and quite a bit faster on modern CPUs).

Higher up, we go for a bottom-up construction of large transforms, foregoing
the traditional per-transform call-return recursion chains. Instead, we always
start at the bottom-most basis transform (in this case, a 32-point transform),
and continue constructing larger and larger transforms until we return to the
top-most transform.
This way, we only touch the stack 3 times per a complete target transform:
once for the 1/2 length transform and two times for the 1/4 length transform.

The combination algorithm we use is a standard Split-Radix algorithm,
as used in our C code. Although a version with less operations exists
(Steven G. Johnson and Matteo Frigo's "A modified split-radix FFT with fewer
arithmetic operations", IEEE Trans. Signal Process. 55 (1), 111–119 (2007),
which is the one FFTW uses), it only has 2% less operations and requires at least 4x
the binary code (due to it needing 4 different paths to do a single transform).
That version also has other issues which prevent it from being implemented
with SIMD code as efficiently, which makes it lose the marginal gains it offered,
and cannot be performed bottom-up, requiring many recursive call-return chains,
whose overhead adds up.

We go through a lot of effort to minimize load/stores by keeping as much in
registers in between construcring transforms. This saves us around 32 cycles,
on paper, but in reality a lot more due to load/store aliasing (a load from a
memory location cannot be issued while there's a store pending, and there are
only so many (2 for Zen 3) load/store units in a CPU).
Also, we interleave coefficients during the last stage to save on a store+load
per register.

Each of the smallest, basis transforms (4, 8 and 16-point in our case)
has been extremely optimized. Our 8-point transform is barely 20 instructions
in total, beating our old implementation 8-point transform by 1 instruction.
Our 2x8-point transform is 23 instructions, beating our old implementation by
6 instruction and needing 50% less cycles. Our 16-point transform's combination
code takes slightly more instructions than our old implementation, but makes up
for it by requiring a lot less arithmetic operations.

Overall, the transform was optimized for the timings of Zen 3, which at the
time of writing has the most IPC from all documented CPUs. Shuffles were
preferred over arithmetic operations due to their 1/0.5 latency/throughput.

On average, this code is 30% faster than our old libavcodec implementation.
It's able to trade blows with the previously-untouchable FFTW on small transforms,
and due to its tiny size and better prediction, outdoes FFTW on larger transforms
by 11% on the largest currently supported size.
2021-04-24 17:19:18 +02:00
Lynne
1978b143eb
checkasm: add av_tx FFT SIMD testing code
This sadly required making changes to the code itself,
due to the same context needing to be reused for both versions.
The lookup table had to be duplicated for both versions.
2021-04-24 17:19:17 +02:00
Lynne
ff71671d88
lavu/tx: add parity revtab generator version
This will be used for SIMD support.
2021-04-24 17:17:30 +02:00
Lynne
aa910a7ecd
lavu/tx: minor code style improvements and additional comments 2021-04-24 17:17:15 +02:00
Lynne
8e94b7cff0
lavu/tx: invert permutation lookups
out[lut[i]] = in[i] lookups were 4.04 times(!) slower than
out[i] = in[lut[i]] lookups for an out-of-place FFT of length 4096.

The permutes remain unchanged for anything but out-of-place monolithic
FFT, as those benefit quite a lot from the current order (it means
there's only 1 lookup necessary to add to an offset, rather than
a full gather).

The code was based around non-power-of-two FFTs, so this wasn't
benchmarked early on.
2021-02-27 04:21:05 +01:00
Lynne
9ddaf0c9f0
lavu/tx: simplify in-place permute search function 2021-02-27 04:21:03 +01:00
Andreas Rheinhardt
c7c7aa85b7 avutil/tx: Fix declaration after statement
Reviewed-by: Paul B Mahol <onemda@gmail.com>
Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2021-02-22 10:03:32 +01:00
Lynne
5ca40d6d94
lavu/tx: support in-place FFT transforms
This commit adds support for in-place FFT transforms. Since our
internal transforms were all in-place anyway, this only changes
the permutation on the input.

Unfortunately, research papers were of no help here. All focused
on dry hardware implementations, where permutes are free, or on
software implementations where binary bloat is of no concern so
storing dozen times the transforms for each permutation and version
is not considered bad practice.
Still, for a pure C implementation, it's only around 28% slower
than the multi-megabyte FFTW3 in unaligned mode.

Unlike a closed permutation like with PFA, split-radix FFT bit-reversals
contain multiple NOPs, multiple simple swaps, and a few chained swaps,
so regular single-loop single-state permute loops were not possible.
Instead, we filter out parts of the input indices which are redundant.
This allows for a single branch, and with some clever AVX512 asm,
could possibly be SIMD'd without refactoring.

The inplace_idx array is guaranteed to never be larger than the
revtab array, and in practice only requires around log2(len) entries.

The power-of-two MDCTs can be done in-place as well. And it's
possible to eliminate a copy in the compound MDCTs too, however
it'll be slower than doing them out of place, and we'd need to dirty
the input array.
2021-02-21 17:05:16 +01:00
Lynne
e8f054b095 lavu/tx: implement 32 bit fixed point FFT and MDCT
Required minimal changes to the code so made sense to implement.
FFT and MDCT tested, the output of both was properly rounded.
Fun fact: the non-power-of-two fixed-point FFT and MDCT are the fastest ever
non-power-of-two fixed-point FFT and MDCT written.
This can replace the power of two integer MDCTs in aac and ac3 if the
MIPS optimizations are ported across.
Unfortunately the ac3 encoder uses a 16-bit fixed point forward transform,
unlike the encoder which uses a 32bit inverse transform, so some modifications
might be required there.

The 3-point FFT is somewhat less accurate than it otherwise could be,
having minor rounding errors with bigger transforms. However, this
could be improved later, and the way its currently written is the way one
would write assembly for it.
Similar rounding errors can also be found throughout the power of two FFTs
as well, though those are more difficult to correct.
Despite this, the integer transforms are more than accurate enough.
2020-02-13 17:10:34 +00:00
Lynne
42e2319ba9 lavu/tx: add support for double precision FFT and MDCT
Simply moves and templates the actual transforms to support an
additional data type.
Unlike the float version, which is equal or better than libfftw3f,
double precision output is bit identical with libfftw3.
2019-08-02 01:19:52 +01:00
Ruiling Song
65646db8e8 avutil/tx: should check against (*ctx)
ctx is a pointer to pointer here.

Signed-off-by: Ruiling Song <ruiling.song@intel.com>
2019-05-16 18:25:31 -03:00
Lynne
6044534964 avutil/tx: fix forward compound non-mod-15 based MDCTs
There was a hardcoded value left. Wasn't caught earlier as no code uses
compound forward mod-3/5 MDCTs yet.
2019-05-16 17:31:53 +01:00
Lynne
b79b29ddb1 libavutil: add an FFT & MDCT implementation
This commit adds a new API to libavutil to allow for arbitrary transformations
on various types of data.
This is a partly new implementation, with the power of two transforms taken
from libavcodec/fft_template, the 5 and 15-point FFT taken from mdct15, while
the 3-point FFT was written from scratch.
The (i)mdct folding code is taken from mdct15 as well, as the mdct_template
code was somewhat old, messy and not easy to separate.

A notable feature of this implementation is that it allows for 3xM and 5xM
based transforms, where M is a power of two, e.g. 384, 640, 768, 1280, etc.
AC-4 uses 3xM transforms while Siren uses 5xM transforms, so the code will
allow for decoding of such streams.
A non-exaustive list of supported sizes:
4, 8, 12, 16, 20, 24, 32, 40, 48, 60, 64, 80, 96, 120, 128, 160, 192, 240,
256, 320, 384, 480, 512, 640, 768, 960, 1024, 1280, 1536, 1920, 2048, 2560...

The API was designed such that it allows for not only 1D transforms but also
2D transforms of certain block sizes. This was partly on accident as the stride
argument is required for Opus MDCTs, but can be used in the context of a 2D
transform as well.
Also, various data types would be implemented eventually as well, such as
"double" and "int32_t".

Some performance comparisons with libfftw3f (SIMD disabled for both):
120:
  22353 decicycles in     fftwf_execute,     1024 runs,      0 skips
  21836 decicycles in compound_fft_15x8,     1024 runs,      0 skips

128:
  22003 decicycles in       fftwf_execute,   1024 runs,      0 skips
  23132 decicycles in monolithic_fft_ptwo,   1024 runs,      0 skips

384:
  75939 decicycles in      fftwf_execute,    1024 runs,      0 skips
  73973 decicycles in compound_fft_3x128,    1024 runs,      0 skips

640:
 104354 decicycles in       fftwf_execute,   1024 runs,      0 skips
 149518 decicycles in compound_fft_5x128,    1024 runs,      0 skips

768:
 109323 decicycles in      fftwf_execute,    1024 runs,      0 skips
 164096 decicycles in compound_fft_3x256,    1024 runs,      0 skips

960:
 186210 decicycles in      fftwf_execute,    1024 runs,      0 skips
 215256 decicycles in compound_fft_15x64,    1024 runs,      0 skips

1024:
 163464 decicycles in       fftwf_execute,   1024 runs,      0 skips
 199686 decicycles in monolithic_fft_ptwo,   1024 runs,      0 skips

With SIMD we should be faster than fftw for 15xM transforms as our fft15 SIMD
is around 2x faster than theirs, even if our ptwo SIMD is slightly slower.

The goal is to remove the libavcodec/mdct15 code and deprecate the
libavcodec/avfft interface once aarch64 and x86 SIMD code has been ported.
New code throughout the project should use this API.

The implementation passes fate when used in Opus, AAC and Vorbis, and the output
is identical with ATRAC9 as well.
2019-05-15 17:39:59 +01:00