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FFmpeg/tests/fate/filter-audio.mak

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FATE_AFILTER-$(call FILTERDEMDECENCMUX, ADELAY, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-adelay
fate-filter-adelay: tests/data/asynth-44100-2.wav
fate-filter-adelay: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-adelay: CMD = framecrc -i $(SRC) -af aresample,adelay=42,aresample
FATE_AFILTER-$(call FILTERDEMDECENCMUX, AECHO, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-aecho
fate-filter-aecho: tests/data/asynth-44100-2.wav
fate-filter-aecho: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-aecho: CMD = framecrc -i $(SRC) -af aresample,aecho=0.5:0.5:32:0.5,aresample
FATE_FILTER_AEMPHASIS += fate-filter-aemphasis-50fm
fate-filter-aemphasis-50fm: tests/data/asynth-44100-2.wav
fate-filter-aemphasis-50fm: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-aemphasis-50fm: CMD = framecrc -i $(SRC) -af aresample,aemphasis=1:5:reproduction:50fm,aresample
FATE_FILTER_AEMPHASIS += fate-filter-aemphasis-75kf
fate-filter-aemphasis-75kf: tests/data/asynth-44100-2.wav
fate-filter-aemphasis-75kf: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-aemphasis-75kf: CMD = framecrc -i $(SRC) -af aresample,aemphasis=2:8:reproduction:75kf,aresample
FATE_AFILTER-$(call FILTERDEMDECENCMUX, AEMPHASIS, WAV, PCM_S16LE, PCM_S16LE, WAV) += $(FATE_FILTER_AEMPHASIS)
FATE_FILTER_AFADE += fate-filter-afade-qsin
fate-filter-afade-qsin: tests/data/asynth-44100-2.wav
fate-filter-afade-qsin: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-afade-qsin: CMD = framecrc -i $(SRC) -af afade=t=in:ss=0:d=2:curve=qsin
FATE_FILTER_AFADE += fate-filter-afade-iqsin
fate-filter-afade-iqsin: tests/data/asynth-44100-2.wav
fate-filter-afade-iqsin: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-afade-iqsin: CMD = framecrc -i $(SRC) -af afade=t=in:ss=0:d=2:curve=iqsin
FATE_FILTER_AFADE += fate-filter-afade-esin
fate-filter-afade-esin: tests/data/asynth-44100-2.wav
fate-filter-afade-esin: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-afade-esin: CMD = framecrc -i $(SRC) -af afade=t=in:ss=0:d=2:curve=esin
FATE_FILTER_AFADE += fate-filter-afade-hsin
fate-filter-afade-hsin: tests/data/asynth-44100-2.wav
fate-filter-afade-hsin: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-afade-hsin: CMD = framecrc -i $(SRC) -af afade=t=in:ss=0:d=2:curve=hsin
FATE_FILTER_AFADE += fate-filter-afade-exp
fate-filter-afade-exp: tests/data/asynth-44100-2.wav
fate-filter-afade-exp: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-afade-exp: CMD = framecrc -i $(SRC) -af afade=t=in:ss=0:d=2:curve=exp
FATE_FILTER_AFADE += fate-filter-afade-log
fate-filter-afade-log: tests/data/asynth-44100-2.wav
fate-filter-afade-log: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-afade-log: CMD = framecrc -i $(SRC) -af afade=t=in:ss=1:d=2.5:curve=log
FATE_AFILTER-$(call FILTERDEMDECENCMUX, AFADE, WAV, PCM_S16LE, PCM_S16LE, WAV) += $(FATE_FILTER_AFADE)
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, ACROSSFADE, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-acrossfade
fate-filter-acrossfade: tests/data/asynth-44100-2.wav
fate-filter-acrossfade: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-acrossfade: SRC2 = $(TARGET_SAMPLES)/audio-reference/luckynight_2ch_44kHz_s16.wav
fate-filter-acrossfade: CMD = framecrc -i $(SRC) -i $(SRC2) -filter_complex acrossfade=d=2:c1=log:c2=exp
FATE_AFILTER-$(call FILTERDEMDECENCMUX, AFADE, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-agate
fate-filter-agate: tests/data/asynth-44100-2.wav
fate-filter-agate: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-agate: CMD = framecrc -i $(SRC) -af aresample,agate=level_in=10:range=0:threshold=1:ratio=1:attack=1:knee=1:makeup=4,aresample
FATE_AFILTER-$(call FILTERDEMDECENCMUX, AFADE, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-alimiter
fate-filter-alimiter: tests/data/asynth-44100-2.wav
fate-filter-alimiter: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-alimiter: CMD = framecrc -i $(SRC) -af aresample,alimiter=level_in=1:level_out=2:limit=0.2,aresample
FATE_AFILTER-$(call FILTERDEMDECENCMUX, AMERGE, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-amerge
fate-filter-amerge: tests/data/asynth-44100-1.wav
fate-filter-amerge: SRC = $(TARGET_PATH)/tests/data/asynth-44100-1.wav
fate-filter-amerge: CMD = framecrc -i $(SRC) -i $(SRC) -filter_complex "[0:a][1:a]amerge=inputs=2[aout]" -map "[aout]"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, APAD, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-apad
fate-filter-apad: tests/data/asynth-44100-2.wav
fate-filter-apad: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-apad: CMD = framecrc -i $(SRC) -af apad=pad_len=10
FATE_AFILTER-$(call FILTERDEMDECENCMUX, ANEQUALIZER, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-anequalizer
fate-filter-anequalizer: tests/data/asynth-44100-2.wav
fate-filter-anequalizer: tests/data/filtergraphs/anequalizer
fate-filter-anequalizer: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-anequalizer: CMD = framecrc -auto_conversion_filters -i $(SRC) -filter_complex_script $(TARGET_PATH)/tests/data/filtergraphs/anequalizer
FATE_AFILTER-$(call FILTERDEMDECENCMUX, ASETNSAMPLES, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-asetnsamples-pad
fate-filter-asetnsamples-pad: tests/data/asynth-44100-2.wav
fate-filter-asetnsamples-pad: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-asetnsamples-pad: CMD = framecrc -i $(SRC) -af asetnsamples=512:p=1
FATE_AFILTER-$(call FILTERDEMDECENCMUX, ASETNSAMPLES, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-asetnsamples-nopad
fate-filter-asetnsamples-nopad: tests/data/asynth-44100-2.wav
fate-filter-asetnsamples-nopad: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-asetnsamples-nopad: CMD = framecrc -i $(SRC) -af asetnsamples=512:p=0
FATE_AFILTER-$(call FILTERDEMDECENCMUX, ASETRATE, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-asetrate
fate-filter-asetrate: tests/data/asynth-44100-2.wav
fate-filter-asetrate: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-asetrate: CMD = framecrc -i $(SRC) -frames:a 20 -af asetrate=20000
FATE_AFILTER-$(call FILTERDEMDECENCMUX, CHORUS, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-chorus
fate-filter-chorus: tests/data/asynth-22050-1.wav
fate-filter-chorus: SRC = $(TARGET_PATH)/tests/data/asynth-22050-1.wav
fate-filter-chorus: CMD = framecrc -i $(SRC) -frames:a 10 -af aresample,chorus=0.050001:0.050002:64:0.050001:0.025003:2.00004,aresample
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FATE_AFILTER-$(call FILTERDEMDECENCMUX, CRYSTALIZER, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-crystalizer
fate-filter-crystalizer: tests/data/asynth-44100-2.wav
fate-filter-crystalizer: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-crystalizer: CMD = framecrc -i $(SRC) -af aresample,crystalizer=2:0,crystalizer=-2:0,aresample
FATE_AFILTER-$(call FILTERDEMDECENCMUX, DCSHIFT, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-dcshift
fate-filter-dcshift: tests/data/asynth-44100-2.wav
fate-filter-dcshift: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-dcshift: CMD = framecrc -i $(SRC) -frames:a 20 -af aresample,dcshift=shift=0.25:limitergain=0.05,aresample
FATE_AFILTER-$(call FILTERDEMDECENCMUX, EARWAX, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-earwax
fate-filter-earwax: tests/data/asynth-44100-2.wav
fate-filter-earwax: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-earwax: CMD = framecrc -i $(SRC) -frames:a 20 -af aresample,earwax,aresample
FATE_AFILTER-$(call FILTERDEMDECENCMUX, EXTRASTEREO, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-extrastereo
fate-filter-extrastereo: tests/data/asynth-44100-2.wav
fate-filter-extrastereo: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-extrastereo: CMD = framecrc -i $(SRC) -frames:a 20 -af aresample,extrastereo=m=2,aresample
FATE_AFILTER-$(call FILTERDEMDECENCMUX, FIREQUALIZER ATRIM VOLUME, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-firequalizer
fate-filter-firequalizer: tests/data/asynth-44100-2.wav
fate-filter-firequalizer: tests/data/filtergraphs/firequalizer
fate-filter-firequalizer: REF = tests/data/asynth-44100-2.wav
fate-filter-firequalizer: CMD = ffmpeg -auto_conversion_filters -i $(TARGET_PATH)/tests/data/asynth-44100-2.wav -filter_script $(TARGET_PATH)/tests/data/filtergraphs/firequalizer -f wav -c:a pcm_s16le -
fate-filter-firequalizer: CMP = oneoff
fate-filter-firequalizer: CMP_UNIT = s16
fate-filter-firequalizer: SIZE_TOLERANCE = 1058400 - 1097208
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-mono1
fate-filter-pan-mono1: tests/data/asynth-44100-2.wav
fate-filter-pan-mono1: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-pan-mono1: CMD = framecrc -ss 3.14 -i $(SRC) -frames:a 20 -filter:a "pan=mono|FC=FL"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-mono2
fate-filter-pan-mono2: tests/data/asynth-44100-2.wav
fate-filter-pan-mono2: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-pan-mono2: CMD = framecrc -ss 3.14 -i $(SRC) -frames:a 20 -filter:a "pan=1C|c0=c0+c1"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-stereo1
fate-filter-pan-stereo1: tests/data/asynth-44100-3.wav
fate-filter-pan-stereo1: SRC = $(TARGET_PATH)/tests/data/asynth-44100-3.wav
fate-filter-pan-stereo1: CMD = framecrc -ss 3.14 -i $(SRC) -frames:a 20 -filter:a "pan=2c|FL=FR|FR=FL"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-stereo2
fate-filter-pan-stereo2: tests/data/asynth-44100-3.wav
fate-filter-pan-stereo2: SRC = $(TARGET_PATH)/tests/data/asynth-44100-3.wav
fate-filter-pan-stereo2: CMD = framecrc -ss 3.14 -i $(SRC) -frames:a 20 -filter:a "pan=stereo|c0=c0-c2|c1=c1-c2"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-stereo3
fate-filter-pan-stereo3: tests/data/asynth-44100-2.wav
fate-filter-pan-stereo3: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-pan-stereo3: CMD = framecrc -ss 3.14 -i $(SRC) -frames:a 20 -filter:a "pan=FL+FR|FL<3*c0+2*c1|FR<2*c0+3*c1"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-stereo4
fate-filter-pan-stereo4: tests/data/asynth-44100-2.wav
fate-filter-pan-stereo4: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-pan-stereo4: CMD = framecrc -ss 3.14 -guess_layout_max 0 -i $(SRC) -frames:a 20 -filter:a "pan=2C|c0=c0-0.5*c1|c1=c1+0.5*c0"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-upmix1
fate-filter-pan-upmix1: tests/data/asynth-44100-2.wav
fate-filter-pan-upmix1: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-pan-upmix1: CMD = framecrc -ss 3.14 -guess_layout_max 0 -i $(SRC) -frames:a 20 -filter:a "pan=4C|c0=c0-0.5*c1|c1=c1+0.5*c0|c2=0*c0|c3=0*c0"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-upmix2
fate-filter-pan-upmix2: tests/data/asynth-44100-4.wav
fate-filter-pan-upmix2: SRC = $(TARGET_PATH)/tests/data/asynth-44100-4.wav
fate-filter-pan-upmix2: CMD = framecrc -ss 3.14 -i $(SRC) -frames:a 20 -filter:a "pan=9C|c0=c0-c1|c1=c2+c3|c2=c0+c1|c3=c2-c3|c4=c1-c0|c5=c3+c2|c6=c1+c0|c7=c3-c2|c8=c0-c3"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-downmix1
fate-filter-pan-downmix1: tests/data/asynth-44100-4.wav
fate-filter-pan-downmix1: SRC = $(TARGET_PATH)/tests/data/asynth-44100-4.wav
fate-filter-pan-downmix1: CMD = framecrc -ss 3.14 -i $(SRC) -frames:a 20 -filter:a "pan=2c|FL<FL+0.5*FC+0.6*BL+0.6*SL|FR<FR+0.5*FC+0.6*BR+0.6*SR"
FATE_AFILTER-$(call FILTERDEMDECENCMUX, PAN, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-pan-downmix2
fate-filter-pan-downmix2: tests/data/asynth-44100-11.wav
fate-filter-pan-downmix2: SRC = $(TARGET_PATH)/tests/data/asynth-44100-11.wav
fate-filter-pan-downmix2: CMD = framecrc -ss 3.14 -i $(SRC) -frames:a 20 -filter:a "pan=5C|c0=0.7*c0+0.7*c10|c1=c9|c2=c8|c3=c7|c4=c6"
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FATE_AFILTER-$(call ALLYES, LAVFI_INDEV, AEVALSRC_FILTER SILENCEREMOVE_FILTER) += fate-filter-silenceremove
fate-filter-silenceremove: CMD = framecrc -auto_conversion_filters -f lavfi -i "aevalsrc=between(t\,1\,2)+between(t\,4\,5)+between(t\,7\,9):d=10:n=8192,silenceremove=start_periods=0:start_duration=0:start_threshold=0:stop_periods=-1:stop_duration=0:stop_threshold=-90dB:window=0:detection=peak"
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, STEREOTOOLS, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-stereotools
fate-filter-stereotools: SRC = $(TARGET_SAMPLES)/audio-reference/luckynight_2ch_44kHz_s16.wav
fate-filter-stereotools: CMD = framecrc -i $(SRC) -frames:a 20 -af aresample,stereotools=mlev=0.015625,aresample
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, TREMOLO, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-tremolo
fate-filter-tremolo: tests/data/asynth-44100-2.wav
fate-filter-tremolo: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-tremolo: CMD = ffmpeg -auto_conversion_filters -i $(SRC) -frames:a 20 -af tremolo -f wav -f s16le -
fate-filter-tremolo: REF = $(SAMPLES)/filter/tremolo.pcm
fate-filter-tremolo: CMP = oneoff
fate-filter-tremolo: CMP_UNIT = s16
FATE_AFILTER-$(call FILTERDEMDECENCMUX, COMPAND, WAV, PCM_S16LE, PCM_S16LE, WAV) += fate-filter-compand
fate-filter-compand: tests/data/asynth-44100-2.wav
fate-filter-compand: tests/data/filtergraphs/compand
fate-filter-compand: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-compand: CMD = framecrc -auto_conversion_filters -i $(SRC) -frames:a 20 -filter_complex_script $(TARGET_PATH)/tests/data/filtergraphs/compand
tests/data/hls-list.m3u8: TAG = GEN
tests/data/hls-list.m3u8: ffmpeg$(PROGSSUF)$(EXESUF) | tests/data
$(M)$(TARGET_EXEC) $(TARGET_PATH)/$< -nostdin \
-f lavfi -i "aevalsrc=cos(2*PI*t)*sin(2*PI*(440+4*t)*t):d=20" -f segment -segment_time 10 -map 0 -flags +bitexact -codec:a mp2fixed \
-segment_list $(TARGET_PATH)/$@ -y $(TARGET_PATH)/tests/data/hls-out-%03d.ts 2>/dev/null
FATE_AFILTER-$(call ALLYES, HLS_DEMUXER MPEGTS_MUXER MPEGTS_DEMUXER AEVALSRC_FILTER LAVFI_INDEV MP2FIXED_ENCODER) += fate-filter-hls
fate-filter-hls: tests/data/hls-list.m3u8
fate-filter-hls: CMD = framecrc -flags +bitexact -i $(TARGET_PATH)/tests/data/hls-list.m3u8 -af aresample
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tests/data/hls-list-append.m3u8: TAG = GEN
tests/data/hls-list-append.m3u8: ffmpeg$(PROGSSUF)$(EXESUF) | tests/data
$(M)$(TARGET_EXEC) $(TARGET_PATH)/$< -nostdin \
-f lavfi -i "aevalsrc=cos(2*PI*t)*sin(2*PI*(440+4*t)*t):d=20" -f segment -segment_time 10 -map 0 -flags +bitexact -codec:a mp2fixed \
-segment_list $(TARGET_PATH)/$@ -y $(TARGET_PATH)/tests/data/hls-append-out-%03d.ts 2>/dev/null; \
$(TARGET_EXEC) $(TARGET_PATH)/$< -nostdin \
-f lavfi -i "aevalsrc=cos(2*PI*t)*sin(2*PI*(440+4*t)*t):d=20" -f hls -hls_time 10 -map 0 -flags +bitexact \
-hls_flags append_list -codec:a mp2fixed -hls_segment_filename $(TARGET_PATH)/tests/data/hls-append-out-%03d.ts \
$(TARGET_PATH)/tests/data/hls-list-append.m3u8 2>/dev/null
FATE_AFILTER-$(call ALLYES, HLS_DEMUXER MPEGTS_MUXER MPEGTS_DEMUXER AEVALSRC_FILTER LAVFI_INDEV MP2FIXED_ENCODER) += fate-filter-hls-append
fate-filter-hls-append: tests/data/hls-list-append.m3u8
fate-filter-hls-append: CMD = framecrc -flags +bitexact -i $(TARGET_PATH)/tests/data/hls-list-append.m3u8 -af asetpts=N*23,aresample
FATE_AMIX += fate-filter-amix-simple
fate-filter-amix-simple: CMD = ffmpeg -auto_conversion_filters -filter_complex amix -i $(SRC) -ss 3 -i $(SRC1) -f f32le -
fate-filter-amix-simple: REF = $(SAMPLES)/filter/amix_simple.pcm
FATE_AMIX += fate-filter-amix-first
fate-filter-amix-first: CMD = ffmpeg -auto_conversion_filters -filter_complex amix=duration=first -ss 4 -i $(SRC) -i $(SRC1) -f f32le -
fate-filter-amix-first: REF = $(SAMPLES)/filter/amix_first.pcm
FATE_AMIX += fate-filter-amix-transition
fate-filter-amix-transition: tests/data/asynth-44100-2-3.wav
fate-filter-amix-transition: SRC2 = $(TARGET_PATH)/tests/data/asynth-44100-2-3.wav
fate-filter-amix-transition: CMD = ffmpeg -auto_conversion_filters -filter_complex amix=inputs=3:dropout_transition=0.5 -i $(SRC) -ss 2 -i $(SRC1) -ss 4 -i $(SRC2) -f f32le -
fate-filter-amix-transition: REF = $(SAMPLES)/filter/amix_transition.pcm
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, AMIX, WAV, PCM_S16LE, PCM_F32LE, PCM_F32LE) += $(FATE_AMIX)
$(FATE_AMIX): tests/data/asynth-44100-2.wav tests/data/asynth-44100-2-2.wav
$(FATE_AMIX): SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
$(FATE_AMIX): SRC1 = $(TARGET_PATH)/tests/data/asynth-44100-2-2.wav
$(FATE_AMIX): CMP = oneoff
$(FATE_AMIX): CMP_UNIT = f32
FATE_AFILTER_SAMPLES-$(CONFIG_ARESAMPLE_FILTER) += fate-filter-aresample
fate-filter-aresample: SRC = $(TARGET_SAMPLES)/nellymoser/nellymoser-discont.flv
fate-filter-aresample: CMD = pcm -analyzeduration 10000000 -i $(SRC) -af aresample=min_comp=0.001:min_hard_comp=0.1:first_pts=0
fate-filter-aresample: CMP = oneoff
fate-filter-aresample: REF = $(SAMPLES)/nellymoser/nellymoser-discont.pcm
2013-04-02 20:30:11 +03:00
FATE_ATRIM += fate-filter-atrim-duration
fate-filter-atrim-duration: CMD = framecrc -i $(SRC) -af atrim=start=0.1:duration=0.01
FATE_ATRIM += fate-filter-atrim-mixed
fate-filter-atrim-mixed: CMD = framecrc -i $(SRC) -af atrim=start=0.05:start_sample=1025:end=0.1:end_sample=4411
FATE_ATRIM += fate-filter-atrim-samples
fate-filter-atrim-samples: CMD = framecrc -i $(SRC) -af atrim=start_sample=26:end_sample=80
FATE_ATRIM += fate-filter-atrim-time
fate-filter-atrim-time: CMD = framecrc -i $(SRC) -af atrim=0.1:0.2
$(FATE_ATRIM): tests/data/asynth-44100-2.wav
$(FATE_ATRIM): SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
FATE_AFILTER-$(call FILTERDEMDECENCMUX, ATRIM, WAV, PCM_S16LE, PCM_S16LE, WAV) += $(FATE_ATRIM)
2013-04-02 20:30:11 +03:00
FATE_FILTER_CHANNELMAP += fate-filter-channelmap-one-int
fate-filter-channelmap-one-int: tests/data/filtergraphs/channelmap_one_int
fate-filter-channelmap-one-int: SRC = $(TARGET_PATH)/tests/data/asynth-44100-6.wav
fate-filter-channelmap-one-int: tests/data/asynth-44100-6.wav
fate-filter-channelmap-one-int: CMD = md5 -auto_conversion_filters -i $(SRC) -filter_complex_script $(TARGET_PATH)/tests/data/filtergraphs/channelmap_one_int -f wav -fflags +bitexact
fate-filter-channelmap-one-int: CMP = oneline
fate-filter-channelmap-one-int: REF = 8cfe553d65ed4696756d8c1b824fcdd3
FATE_FILTER_CHANNELMAP += fate-filter-channelmap-one-str
fate-filter-channelmap-one-str: tests/data/filtergraphs/channelmap_one_str
fate-filter-channelmap-one-str: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-channelmap-one-str: tests/data/asynth-44100-2.wav
fate-filter-channelmap-one-str: CMD = md5 -auto_conversion_filters -i $(SRC) -filter_complex_script $(TARGET_PATH)/tests/data/filtergraphs/channelmap_one_str -f wav -fflags +bitexact
fate-filter-channelmap-one-str: CMP = oneline
fate-filter-channelmap-one-str: REF = 0ea3052e482c95d5d3bd9da6dac1b5fa
FATE_AFILTER-$(call FILTERDEMDECENCMUX, CHANNELMAP, WAV, PCM_S16LE, PCM_S16LE, WAV) += $(FATE_FILTER_CHANNELMAP)
FATE_AFILTER-$(call FILTERDEMDECENCMUX, CHANNELSPLIT, WAV, PCM_S16LE, PCM_S16LE, PCM_S16LE) += fate-filter-channelsplit
fate-filter-channelsplit: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-channelsplit: tests/data/asynth-44100-2.wav
fate-filter-channelsplit: CMD = md5 -auto_conversion_filters -i $(SRC) -filter_complex channelsplit -f s16le
fate-filter-channelsplit: CMP = oneline
fate-filter-channelsplit: REF = d92988d0fe2dd92236763f47b07ab597
FATE_AFILTER-$(call FILTERDEMDECENCMUX, JOIN, WAV, PCM_S16LE, PCM_S16LE, PCM_S16LE) += fate-filter-join
fate-filter-join: SRC1 = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-join: SRC2 = $(TARGET_PATH)/tests/data/asynth-44100-3.wav
fate-filter-join: tests/data/asynth-44100-2.wav tests/data/asynth-44100-3.wav
fate-filter-join: CMD = md5 -auto_conversion_filters -i $(SRC1) -i $(SRC2) -filter_complex join=channel_layout=5c -f s16le
fate-filter-join: CMP = oneline
fate-filter-join: REF = 88b0d24a64717ba8635b29e8dac6ecd8
FATE_AFILTER-$(call ALLYES, WAV_DEMUXER PCM_S16LE_DECODER PCM_S16LE_ENCODER PCM_S16LE_MUXER APERMS_FILTER VOLUME_FILTER) += fate-filter-volume
fate-filter-volume: SRC = $(TARGET_PATH)/tests/data/asynth-44100-2.wav
fate-filter-volume: tests/data/asynth-44100-2.wav
fate-filter-volume: CMD = md5 -i $(SRC) -af aperms=random,volume=precision=fixed:volume=0.5 -f s16le
fate-filter-volume: CMP = oneline
fate-filter-volume: REF = 4d6ba75ef3e32d305d066b9bc771d6f4
# hdcd-mix.flac is a mix of three different sources which are interesting for various reasons:
# first 5 seconds uses packet format A and max LLE of -7.0db
# second 5 seconds uses packet format B and has a gain mismatch between channels
# last 10 seconds is not HDCD but has a coincidental HDCD packet, it needs to be 10 seconds because it also tests the cdt expiration
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-mix
fate-filter-hdcd-mix: SRC = $(TARGET_SAMPLES)/filter/hdcd-mix.flac
fate-filter-hdcd-mix: CMD = md5 -i $(SRC) -af hdcd -f s24le
fate-filter-hdcd-mix: CMP = oneline
avcodec/flac_parser: Fix off-by-one error The flac parser uses a fifo to buffer its data. Consequently, when searching for sync codes of flac packets, one needs to take care of the possibility of wraparound. This is done by using an optimized start code search that works on each of the continuous buffers separately and by explicitly checking whether the last pre-wrap byte and the first post-wrap byte constitute a valid sync code. Moreover, the last MAX_FRAME_HEADER_SIZE - 1 bytes ought not to be searched for (the start of) a sync code because a header that might be found in this region might not be completely available. These bytes ought to be searched lateron when more data is available or when flushing. Unfortunately there was an off-by-one error in the calculation of the length to search of the post-wrap buffer: It was too large, because the calculation was based on the amount of bytes available in the fifo from the last pre-wrap byte onwards. This meant that a header might be parsed twice (once prematurely and once regularly when more data is available); it could also mean that an invalid header will be treated as valid (namely if the length of said invalid header is MAX_FRAME_HEADER_SIZE and the invalid byte that will be treated as the last byte of this potential header happens to be the right CRC-8). Should a header be parsed twice, the second instance will be the best child of the first instance; the first instance's score will be FLAC_HEADER_BASE_SCORE - FLAC_HEADER_CHANGED_PENALTY ( = 3) higher than the second instance's score. So the frame belonging to the first instance will be output and it will be done as a zero length frame (the difference of the header's offset and the child's offset). This has serious consequences when flushing, as returning a zero length buffer signals to the caller that no more data will be output; consequently the last frames not yet output will be dropped. Furthermore, a "sample/frame number mismatch in adjacent frames" warning got output when returning the zero-length frame belonging to the first header, because the child's sample/frame number of course didn't match the expected sample frame/number given its parent. filter/hdcd-mix.flac from the FATE-suite was affected by this (the last frame was omitted) which is the reason why several FATE-tests needed to be updated. Fixes ticket #5937. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2019-10-06 07:01:15 +02:00
fate-filter-hdcd-mix: REF = 77443573e0bd3532de52a8bc0e825da7
# output will be different because of the gain mismatch in the second and third parts
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-mix-psoff
fate-filter-hdcd-mix-psoff: SRC = $(TARGET_SAMPLES)/filter/hdcd-mix.flac
fate-filter-hdcd-mix-psoff: CMD = md5 -i $(SRC) -af hdcd=process_stereo=false -f s24le
fate-filter-hdcd-mix-psoff: CMP = oneline
avcodec/flac_parser: Fix off-by-one error The flac parser uses a fifo to buffer its data. Consequently, when searching for sync codes of flac packets, one needs to take care of the possibility of wraparound. This is done by using an optimized start code search that works on each of the continuous buffers separately and by explicitly checking whether the last pre-wrap byte and the first post-wrap byte constitute a valid sync code. Moreover, the last MAX_FRAME_HEADER_SIZE - 1 bytes ought not to be searched for (the start of) a sync code because a header that might be found in this region might not be completely available. These bytes ought to be searched lateron when more data is available or when flushing. Unfortunately there was an off-by-one error in the calculation of the length to search of the post-wrap buffer: It was too large, because the calculation was based on the amount of bytes available in the fifo from the last pre-wrap byte onwards. This meant that a header might be parsed twice (once prematurely and once regularly when more data is available); it could also mean that an invalid header will be treated as valid (namely if the length of said invalid header is MAX_FRAME_HEADER_SIZE and the invalid byte that will be treated as the last byte of this potential header happens to be the right CRC-8). Should a header be parsed twice, the second instance will be the best child of the first instance; the first instance's score will be FLAC_HEADER_BASE_SCORE - FLAC_HEADER_CHANGED_PENALTY ( = 3) higher than the second instance's score. So the frame belonging to the first instance will be output and it will be done as a zero length frame (the difference of the header's offset and the child's offset). This has serious consequences when flushing, as returning a zero length buffer signals to the caller that no more data will be output; consequently the last frames not yet output will be dropped. Furthermore, a "sample/frame number mismatch in adjacent frames" warning got output when returning the zero-length frame belonging to the first header, because the child's sample/frame number of course didn't match the expected sample frame/number given its parent. filter/hdcd-mix.flac from the FATE-suite was affected by this (the last frame was omitted) which is the reason why several FATE-tests needed to be updated. Fixes ticket #5937. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2019-10-06 07:01:15 +02:00
fate-filter-hdcd-mix-psoff: REF = 89e57885917a436b30855db4d478cefb
# test the different analyze modes
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-analyze-pe
fate-filter-hdcd-analyze-pe: SRC = $(TARGET_SAMPLES)/filter/hdcd-mix.flac
fate-filter-hdcd-analyze-pe: CMD = md5 -i $(SRC) -af hdcd=analyze_mode=pe -f s24le
fate-filter-hdcd-analyze-pe: CMP = oneline
avcodec/flac_parser: Fix off-by-one error The flac parser uses a fifo to buffer its data. Consequently, when searching for sync codes of flac packets, one needs to take care of the possibility of wraparound. This is done by using an optimized start code search that works on each of the continuous buffers separately and by explicitly checking whether the last pre-wrap byte and the first post-wrap byte constitute a valid sync code. Moreover, the last MAX_FRAME_HEADER_SIZE - 1 bytes ought not to be searched for (the start of) a sync code because a header that might be found in this region might not be completely available. These bytes ought to be searched lateron when more data is available or when flushing. Unfortunately there was an off-by-one error in the calculation of the length to search of the post-wrap buffer: It was too large, because the calculation was based on the amount of bytes available in the fifo from the last pre-wrap byte onwards. This meant that a header might be parsed twice (once prematurely and once regularly when more data is available); it could also mean that an invalid header will be treated as valid (namely if the length of said invalid header is MAX_FRAME_HEADER_SIZE and the invalid byte that will be treated as the last byte of this potential header happens to be the right CRC-8). Should a header be parsed twice, the second instance will be the best child of the first instance; the first instance's score will be FLAC_HEADER_BASE_SCORE - FLAC_HEADER_CHANGED_PENALTY ( = 3) higher than the second instance's score. So the frame belonging to the first instance will be output and it will be done as a zero length frame (the difference of the header's offset and the child's offset). This has serious consequences when flushing, as returning a zero length buffer signals to the caller that no more data will be output; consequently the last frames not yet output will be dropped. Furthermore, a "sample/frame number mismatch in adjacent frames" warning got output when returning the zero-length frame belonging to the first header, because the child's sample/frame number of course didn't match the expected sample frame/number given its parent. filter/hdcd-mix.flac from the FATE-suite was affected by this (the last frame was omitted) which is the reason why several FATE-tests needed to be updated. Fixes ticket #5937. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2019-10-06 07:01:15 +02:00
fate-filter-hdcd-analyze-pe: REF = 2d839d8a1cf73b10a566ce3d4cfaa79e
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-analyze-lle
fate-filter-hdcd-analyze-lle: SRC = $(TARGET_SAMPLES)/filter/hdcd-mix.flac
fate-filter-hdcd-analyze-lle: CMD = md5 -i $(SRC) -af hdcd=analyze_mode=lle -f s24le
fate-filter-hdcd-analyze-lle: CMP = oneline
avcodec/flac_parser: Fix off-by-one error The flac parser uses a fifo to buffer its data. Consequently, when searching for sync codes of flac packets, one needs to take care of the possibility of wraparound. This is done by using an optimized start code search that works on each of the continuous buffers separately and by explicitly checking whether the last pre-wrap byte and the first post-wrap byte constitute a valid sync code. Moreover, the last MAX_FRAME_HEADER_SIZE - 1 bytes ought not to be searched for (the start of) a sync code because a header that might be found in this region might not be completely available. These bytes ought to be searched lateron when more data is available or when flushing. Unfortunately there was an off-by-one error in the calculation of the length to search of the post-wrap buffer: It was too large, because the calculation was based on the amount of bytes available in the fifo from the last pre-wrap byte onwards. This meant that a header might be parsed twice (once prematurely and once regularly when more data is available); it could also mean that an invalid header will be treated as valid (namely if the length of said invalid header is MAX_FRAME_HEADER_SIZE and the invalid byte that will be treated as the last byte of this potential header happens to be the right CRC-8). Should a header be parsed twice, the second instance will be the best child of the first instance; the first instance's score will be FLAC_HEADER_BASE_SCORE - FLAC_HEADER_CHANGED_PENALTY ( = 3) higher than the second instance's score. So the frame belonging to the first instance will be output and it will be done as a zero length frame (the difference of the header's offset and the child's offset). This has serious consequences when flushing, as returning a zero length buffer signals to the caller that no more data will be output; consequently the last frames not yet output will be dropped. Furthermore, a "sample/frame number mismatch in adjacent frames" warning got output when returning the zero-length frame belonging to the first header, because the child's sample/frame number of course didn't match the expected sample frame/number given its parent. filter/hdcd-mix.flac from the FATE-suite was affected by this (the last frame was omitted) which is the reason why several FATE-tests needed to be updated. Fixes ticket #5937. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2019-10-06 07:01:15 +02:00
fate-filter-hdcd-analyze-lle: REF = b4b185332b7025c191062f49a2c015f1
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-analyze-cdt
fate-filter-hdcd-analyze-cdt: SRC = $(TARGET_SAMPLES)/filter/hdcd-mix.flac
fate-filter-hdcd-analyze-cdt: CMD = md5 -i $(SRC) -af hdcd=analyze_mode=cdt -f s24le
fate-filter-hdcd-analyze-cdt: CMP = oneline
avcodec/flac_parser: Fix off-by-one error The flac parser uses a fifo to buffer its data. Consequently, when searching for sync codes of flac packets, one needs to take care of the possibility of wraparound. This is done by using an optimized start code search that works on each of the continuous buffers separately and by explicitly checking whether the last pre-wrap byte and the first post-wrap byte constitute a valid sync code. Moreover, the last MAX_FRAME_HEADER_SIZE - 1 bytes ought not to be searched for (the start of) a sync code because a header that might be found in this region might not be completely available. These bytes ought to be searched lateron when more data is available or when flushing. Unfortunately there was an off-by-one error in the calculation of the length to search of the post-wrap buffer: It was too large, because the calculation was based on the amount of bytes available in the fifo from the last pre-wrap byte onwards. This meant that a header might be parsed twice (once prematurely and once regularly when more data is available); it could also mean that an invalid header will be treated as valid (namely if the length of said invalid header is MAX_FRAME_HEADER_SIZE and the invalid byte that will be treated as the last byte of this potential header happens to be the right CRC-8). Should a header be parsed twice, the second instance will be the best child of the first instance; the first instance's score will be FLAC_HEADER_BASE_SCORE - FLAC_HEADER_CHANGED_PENALTY ( = 3) higher than the second instance's score. So the frame belonging to the first instance will be output and it will be done as a zero length frame (the difference of the header's offset and the child's offset). This has serious consequences when flushing, as returning a zero length buffer signals to the caller that no more data will be output; consequently the last frames not yet output will be dropped. Furthermore, a "sample/frame number mismatch in adjacent frames" warning got output when returning the zero-length frame belonging to the first header, because the child's sample/frame number of course didn't match the expected sample frame/number given its parent. filter/hdcd-mix.flac from the FATE-suite was affected by this (the last frame was omitted) which is the reason why several FATE-tests needed to be updated. Fixes ticket #5937. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2019-10-06 07:01:15 +02:00
fate-filter-hdcd-analyze-cdt: REF = afa6577675c63e87da3edbd442b7b6e2
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-analyze-tgm
fate-filter-hdcd-analyze-tgm: SRC = $(TARGET_SAMPLES)/filter/hdcd-mix.flac
fate-filter-hdcd-analyze-tgm: CMD = md5 -i $(SRC) -af hdcd=analyze_mode=tgm -f s24le
fate-filter-hdcd-analyze-tgm: CMP = oneline
avcodec/flac_parser: Fix off-by-one error The flac parser uses a fifo to buffer its data. Consequently, when searching for sync codes of flac packets, one needs to take care of the possibility of wraparound. This is done by using an optimized start code search that works on each of the continuous buffers separately and by explicitly checking whether the last pre-wrap byte and the first post-wrap byte constitute a valid sync code. Moreover, the last MAX_FRAME_HEADER_SIZE - 1 bytes ought not to be searched for (the start of) a sync code because a header that might be found in this region might not be completely available. These bytes ought to be searched lateron when more data is available or when flushing. Unfortunately there was an off-by-one error in the calculation of the length to search of the post-wrap buffer: It was too large, because the calculation was based on the amount of bytes available in the fifo from the last pre-wrap byte onwards. This meant that a header might be parsed twice (once prematurely and once regularly when more data is available); it could also mean that an invalid header will be treated as valid (namely if the length of said invalid header is MAX_FRAME_HEADER_SIZE and the invalid byte that will be treated as the last byte of this potential header happens to be the right CRC-8). Should a header be parsed twice, the second instance will be the best child of the first instance; the first instance's score will be FLAC_HEADER_BASE_SCORE - FLAC_HEADER_CHANGED_PENALTY ( = 3) higher than the second instance's score. So the frame belonging to the first instance will be output and it will be done as a zero length frame (the difference of the header's offset and the child's offset). This has serious consequences when flushing, as returning a zero length buffer signals to the caller that no more data will be output; consequently the last frames not yet output will be dropped. Furthermore, a "sample/frame number mismatch in adjacent frames" warning got output when returning the zero-length frame belonging to the first header, because the child's sample/frame number of course didn't match the expected sample frame/number given its parent. filter/hdcd-mix.flac from the FATE-suite was affected by this (the last frame was omitted) which is the reason why several FATE-tests needed to be updated. Fixes ticket #5937. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2019-10-06 07:01:15 +02:00
fate-filter-hdcd-analyze-tgm: REF = 285f0fd2249b4903cd5e1ad5ce004219
# the two additional analyze modes from libhdcd
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-analyze-ltgm
fate-filter-hdcd-analyze-ltgm: SRC = $(TARGET_SAMPLES)/filter/hdcd-mix.flac
fate-filter-hdcd-analyze-ltgm: CMD = md5 -i $(SRC) -af hdcd=analyze_mode=lle:process_stereo=false -f s24le
fate-filter-hdcd-analyze-ltgm: CMP = oneline
avcodec/flac_parser: Fix off-by-one error The flac parser uses a fifo to buffer its data. Consequently, when searching for sync codes of flac packets, one needs to take care of the possibility of wraparound. This is done by using an optimized start code search that works on each of the continuous buffers separately and by explicitly checking whether the last pre-wrap byte and the first post-wrap byte constitute a valid sync code. Moreover, the last MAX_FRAME_HEADER_SIZE - 1 bytes ought not to be searched for (the start of) a sync code because a header that might be found in this region might not be completely available. These bytes ought to be searched lateron when more data is available or when flushing. Unfortunately there was an off-by-one error in the calculation of the length to search of the post-wrap buffer: It was too large, because the calculation was based on the amount of bytes available in the fifo from the last pre-wrap byte onwards. This meant that a header might be parsed twice (once prematurely and once regularly when more data is available); it could also mean that an invalid header will be treated as valid (namely if the length of said invalid header is MAX_FRAME_HEADER_SIZE and the invalid byte that will be treated as the last byte of this potential header happens to be the right CRC-8). Should a header be parsed twice, the second instance will be the best child of the first instance; the first instance's score will be FLAC_HEADER_BASE_SCORE - FLAC_HEADER_CHANGED_PENALTY ( = 3) higher than the second instance's score. So the frame belonging to the first instance will be output and it will be done as a zero length frame (the difference of the header's offset and the child's offset). This has serious consequences when flushing, as returning a zero length buffer signals to the caller that no more data will be output; consequently the last frames not yet output will be dropped. Furthermore, a "sample/frame number mismatch in adjacent frames" warning got output when returning the zero-length frame belonging to the first header, because the child's sample/frame number of course didn't match the expected sample frame/number given its parent. filter/hdcd-mix.flac from the FATE-suite was affected by this (the last frame was omitted) which is the reason why several FATE-tests needed to be updated. Fixes ticket #5937. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2019-10-06 07:01:15 +02:00
fate-filter-hdcd-analyze-ltgm: REF = 404dc2301ea97e9f96c3d6d2ebcfeaa5
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-analyze-pel
fate-filter-hdcd-analyze-pel: SRC = $(TARGET_SAMPLES)/filter/hdcd-mix.flac
fate-filter-hdcd-analyze-pel: CMD = md5 -i $(SRC) -af hdcd=analyze_mode=pe:force_pe=true -f s24le
fate-filter-hdcd-analyze-pel: CMP = oneline
avcodec/flac_parser: Fix off-by-one error The flac parser uses a fifo to buffer its data. Consequently, when searching for sync codes of flac packets, one needs to take care of the possibility of wraparound. This is done by using an optimized start code search that works on each of the continuous buffers separately and by explicitly checking whether the last pre-wrap byte and the first post-wrap byte constitute a valid sync code. Moreover, the last MAX_FRAME_HEADER_SIZE - 1 bytes ought not to be searched for (the start of) a sync code because a header that might be found in this region might not be completely available. These bytes ought to be searched lateron when more data is available or when flushing. Unfortunately there was an off-by-one error in the calculation of the length to search of the post-wrap buffer: It was too large, because the calculation was based on the amount of bytes available in the fifo from the last pre-wrap byte onwards. This meant that a header might be parsed twice (once prematurely and once regularly when more data is available); it could also mean that an invalid header will be treated as valid (namely if the length of said invalid header is MAX_FRAME_HEADER_SIZE and the invalid byte that will be treated as the last byte of this potential header happens to be the right CRC-8). Should a header be parsed twice, the second instance will be the best child of the first instance; the first instance's score will be FLAC_HEADER_BASE_SCORE - FLAC_HEADER_CHANGED_PENALTY ( = 3) higher than the second instance's score. So the frame belonging to the first instance will be output and it will be done as a zero length frame (the difference of the header's offset and the child's offset). This has serious consequences when flushing, as returning a zero length buffer signals to the caller that no more data will be output; consequently the last frames not yet output will be dropped. Furthermore, a "sample/frame number mismatch in adjacent frames" warning got output when returning the zero-length frame belonging to the first header, because the child's sample/frame number of course didn't match the expected sample frame/number given its parent. filter/hdcd-mix.flac from the FATE-suite was affected by this (the last frame was omitted) which is the reason why several FATE-tests needed to be updated. Fixes ticket #5937. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2019-10-06 07:01:15 +02:00
fate-filter-hdcd-analyze-pel: REF = 9342983208ec1a7f2b3e332ac4dcb723
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-false-positive
fate-filter-hdcd-false-positive: SRC = $(TARGET_SAMPLES)/filter/hdcd-false-positive.flac
fate-filter-hdcd-false-positive: CMD = md5 -i $(SRC) -af hdcd -f s24le
fate-filter-hdcd-false-positive: CMP = grep
fate-filter-hdcd-false-positive: REF = HDCD detected: no
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-detect-errors
fate-filter-hdcd-detect-errors: SRC = $(TARGET_SAMPLES)/filter/hdcd-encoding-errors.flac
fate-filter-hdcd-detect-errors: CMD = md5 -i $(SRC) -af hdcd -f s24le
fate-filter-hdcd-detect-errors: CMP = grep
fate-filter-hdcd-detect-errors: REF = detectable errors: [1-9]
# 20bit HDCD
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, FLAC, FLAC, PCM_S32LE, PCM_S32LE) += fate-filter-hdcd-20bit
fate-filter-hdcd-20bit: SRC = $(TARGET_SAMPLES)/filter/hdcd-fake20bit.flac
fate-filter-hdcd-20bit: CMD = md5 -i $(SRC) -af hdcd=bits_per_sample=20 -f s32le
fate-filter-hdcd-20bit: CMP = oneline
fate-filter-hdcd-20bit: REF = 365ded883a4a92483b15b69babc81390
# non-hdcd tests of different input formats for code coverage
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, WAV, PCM_S16LE, PCM_S24LE, PCM_S24LE) += fate-filter-hdcd-mono
fate-filter-hdcd-mono: SRC = $(TARGET_SAMPLES)/audiomatch/tones_44100_mono.wav
fate-filter-hdcd-mono: CMD = md5 -i $(SRC) -af hdcd -f s24le
fate-filter-hdcd-mono: CMP = oneline
fate-filter-hdcd-mono: REF = f51b114b20728e6a463a9491c643d166
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, WV, WAVPACK, PCM_S32LE, PCM_S32LE) += fate-filter-hdcd-s16p
fate-filter-hdcd-s16p: SRC = $(TARGET_SAMPLES)/wavpack/lossless/16bit-partial.wv
fate-filter-hdcd-s16p: CMD = md5 -i $(SRC) -af hdcd -f s32le
fate-filter-hdcd-s16p: CMP = oneline
fate-filter-hdcd-s16p: REF = 4e767f436b891ac59810a8b2b1d7e96b
FATE_AFILTER_SAMPLES-$(call FILTERDEMDECENCMUX, HDCD, WV, WAVPACK, PCM_S32LE, PCM_S32LE) += fate-filter-hdcd-s32p
fate-filter-hdcd-s32p: SRC = $(TARGET_SAMPLES)/wavpack/lossless/24bit-partial.wv
fate-filter-hdcd-s32p: CMD = md5 -i $(SRC) -af hdcd -f s32le
fate-filter-hdcd-s32p: CMP = oneline
fate-filter-hdcd-s32p: REF = 0c5513e83eedaa10ab6fac9ddc173cf5
FATE_AFILTER-yes += fate-filter-formats
fate-filter-formats: libavfilter/tests/formats$(EXESUF)
fate-filter-formats: CMD = run libavfilter/tests/formats$(EXESUF)
FATE_SAMPLES_AVCONV += $(FATE_AFILTER_SAMPLES-yes)
FATE_FFMPEG += $(FATE_AFILTER-yes)
fate-afilter: $(FATE_AFILTER-yes) $(FATE_AFILTER_SAMPLES-yes)