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Uses integer arithmetics in SDL_ResampleAudio
- Avoids precision loss caused by large floating point numbers. - Adds unit test to test the signal-to-noise ratio and maximum error of resampler. - Code cleanup (cherry-picked from commit 20e17559e545c5d3cfe86c1c4772365e70090779)
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@ -181,13 +181,17 @@ static void SDLCALL SDL_ConvertMonoToStereo_SSE(SDL_AudioCVT *cvt, SDL_AudioForm
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#include "SDL_audio_resampler_filter.h"
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static int ResamplerPadding(const int inrate, const int outrate)
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static Sint32 ResamplerPadding(const Sint32 inrate, const Sint32 outrate)
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{
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/* This function uses integer arithmetics to avoid precision loss caused
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* by large floating point numbers. Sint32 is needed for the large number
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* multiplication. The integers are assumed to be non-negative so that
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* division rounds by truncation. */
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if (inrate == outrate) {
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return 0;
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}
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if (inrate > outrate) {
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return (int)SDL_ceilf(((float)(RESAMPLER_SAMPLES_PER_ZERO_CROSSING * inrate) / ((float)outrate)));
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return (RESAMPLER_SAMPLES_PER_ZERO_CROSSING * inrate + outrate - 1) / outrate;
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}
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return RESAMPLER_SAMPLES_PER_ZERO_CROSSING;
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}
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@ -198,65 +202,59 @@ static int SDL_ResampleAudio(const int chans, const int inrate, const int outrat
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const float *inbuf, const int inbuflen,
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float *outbuf, const int outbuflen)
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{
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/* !!! FIXME: this produces artifacts if we don't work at double precision, but this turns out to
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be a big performance hit. Until we can resolve this better, we force this to double
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for amd64 CPUs, which should be able to take the hit for now, vs small embedded
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things that might end up in a software fallback here. */
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/* Note that this used to be double, but it looks like we can get by with float in most cases at
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almost twice the speed on Intel processors, and orders of magnitude more
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on CPUs that need a software fallback for double calculations. */
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#if defined(_M_X64) || defined(__x86_64__)
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typedef double ResampleFloatType;
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#else
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typedef float ResampleFloatType;
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#endif
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const ResampleFloatType finrate = (ResampleFloatType)inrate;
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const ResampleFloatType ratio = ((float)outrate) / ((float)inrate);
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/* This function uses integer arithmetics to avoid precision loss caused
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* by large floating point numbers. For some operations, Sint32 or Sint64
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* are needed for the large number multiplications. The input integers are
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* assumed to be non-negative so that division rounds by truncation and
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* modulo is always non-negative. Note that the operator order is important
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* for these integer divisions. */
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const int paddinglen = ResamplerPadding(inrate, outrate);
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const int framelen = chans * (int)sizeof(float);
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const int inframes = inbuflen / framelen;
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const int wantedoutframes = (int)(inframes * ratio); /* outbuflen isn't total to write, it's total available. */
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/* outbuflen isn't total to write, it's total available. */
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const int wantedoutframes = ((Sint64)inframes) * outrate / inrate;
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const int maxoutframes = outbuflen / framelen;
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const int outframes = SDL_min(wantedoutframes, maxoutframes);
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ResampleFloatType outtime = 0.0f;
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float *dst = outbuf;
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int i, j, chan;
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for (i = 0; i < outframes; i++) {
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const int srcindex = (int)(outtime * inrate);
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const ResampleFloatType intime = ((ResampleFloatType)srcindex) / finrate;
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const ResampleFloatType innexttime = ((ResampleFloatType)(srcindex + 1)) / finrate;
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const ResampleFloatType indeltatime = innexttime - intime;
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const ResampleFloatType interpolation1 = (indeltatime == 0.0f) ? 1.0f : (1.0f - ((innexttime - outtime) / indeltatime));
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const int filterindex1 = (int)(interpolation1 * RESAMPLER_SAMPLES_PER_ZERO_CROSSING);
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const ResampleFloatType interpolation2 = 1.0f - interpolation1;
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const int filterindex2 = (int)(interpolation2 * RESAMPLER_SAMPLES_PER_ZERO_CROSSING);
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const int srcindex = ((Sint64)i) * inrate / outrate;
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/* Calculating the following way avoids subtraction or modulo of large
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* floats which have low result precision.
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* interpolation1
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* = (i / outrate * inrate) - floor(i / outrate * inrate)
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* = mod(i / outrate * inrate, 1)
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* = mod(i * inrate, outrate) / outrate */
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const int srcfraction = ((Sint64)i) * inrate % outrate;
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const float interpolation1 = ((float)srcfraction) / ((float)outrate);
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const int filterindex1 = ((Sint32)srcfraction) * RESAMPLER_SAMPLES_PER_ZERO_CROSSING / outrate;
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const float interpolation2 = 1.0f - interpolation1;
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const int filterindex2 = ((Sint32)(outrate - srcfraction)) * RESAMPLER_SAMPLES_PER_ZERO_CROSSING / outrate;
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for (chan = 0; chan < chans; chan++) {
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float outsample = 0.0f;
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/* do this twice to calculate the sample, once for the "left wing" and then same for the right. */
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for (j = 0; (filterindex1 + (j * RESAMPLER_SAMPLES_PER_ZERO_CROSSING)) < RESAMPLER_FILTER_SIZE; j++) {
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const int filt_ind = filterindex1 + j * RESAMPLER_SAMPLES_PER_ZERO_CROSSING;
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const int srcframe = srcindex - j;
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/* !!! FIXME: we can bubble this conditional out of here by doing a pre loop. */
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const float insample = (srcframe < 0) ? lpadding[((paddinglen + srcframe) * chans) + chan] : inbuf[(srcframe * chans) + chan];
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outsample += (float) (insample * (ResamplerFilter[filterindex1 + (j * RESAMPLER_SAMPLES_PER_ZERO_CROSSING)] + (interpolation1 * ResamplerFilterDifference[filterindex1 + (j * RESAMPLER_SAMPLES_PER_ZERO_CROSSING)])));
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outsample += (float) (insample * (ResamplerFilter[filt_ind] + (interpolation1 * ResamplerFilterDifference[filt_ind])));
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}
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/* Do the right wing! */
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for (j = 0; (filterindex2 + (j * RESAMPLER_SAMPLES_PER_ZERO_CROSSING)) < RESAMPLER_FILTER_SIZE; j++) {
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const int jsamples = j * RESAMPLER_SAMPLES_PER_ZERO_CROSSING;
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const int filt_ind = filterindex2 + j * RESAMPLER_SAMPLES_PER_ZERO_CROSSING;
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const int srcframe = srcindex + 1 + j;
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/* !!! FIXME: we can bubble this conditional out of here by doing a post loop. */
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const float insample = (srcframe >= inframes) ? rpadding[((srcframe - inframes) * chans) + chan] : inbuf[(srcframe * chans) + chan];
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outsample += (float) (insample * (ResamplerFilter[filterindex2 + jsamples] + (interpolation2 * ResamplerFilterDifference[filterindex2 + jsamples])));
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outsample += (float) (insample * (ResamplerFilter[filt_ind] + (interpolation2 * ResamplerFilterDifference[filt_ind])));
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}
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*(dst++) = outsample;
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}
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outtime = ((ResampleFloatType)i) / ((ResampleFloatType)outrate);
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}
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return outframes * chans * sizeof(float);
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@ -8,6 +8,7 @@
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#define _CRT_SECURE_NO_WARNINGS
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#endif
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#include <math.h>
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#include <stdio.h>
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#include <string.h>
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@ -965,6 +966,119 @@ int audio_openCloseAudioDeviceConnected()
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return TEST_COMPLETED;
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}
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static double sine_wave_sample(const Sint64 idx, const Sint64 rate, const Sint64 freq, const double phase)
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{
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/* Using integer modulo to avoid precision loss caused by large floating
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* point numbers. Sint64 is needed for the large integer multiplication.
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* The integers are assumed to be non-negative so that modulo is always
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* non-negative.
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* sin(i / rate * freq * 2 * M_PI + phase)
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* = sin(mod(i / rate * freq, 1) * 2 * M_PI + phase)
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* = sin(mod(i * freq, rate) / rate * 2 * M_PI + phase) */
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return SDL_sin(((double) (idx * freq % rate)) / ((double) rate) * (M_PI * 2) + phase);
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}
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/**
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* \brief Check signal-to-noise ratio and maximum error of audio resampling.
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*
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* \sa https://wiki.libsdl.org/SDL_BuildAudioCVT
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* \sa https://wiki.libsdl.org/SDL_ConvertAudio
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*/
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int audio_resampleLoss()
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{
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/* Note: always test long input time (>= 5s from experience) in some test
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* cases because an improper implementation may suffer from low resampling
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* precision with long input due to e.g. doing subtraction with large floats. */
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struct test_spec_t {
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int time;
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int freq;
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double phase;
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int rate_in;
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int rate_out;
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double signal_to_noise;
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double max_error;
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} test_specs[] = {
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{ 50, 440, 0, 44100, 48000, 60, 0.0025 },
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{ 50, 5000, M_PI / 2, 20000, 10000, 65, 0.0010 },
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{ 0 }
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};
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int spec_idx = 0;
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for (spec_idx = 0; test_specs[spec_idx].time > 0; ++spec_idx) {
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const struct test_spec_t *spec = &test_specs[spec_idx];
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const int frames_in = spec->time * spec->rate_in;
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const int frames_target = spec->time * spec->rate_out;
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const int len_in = frames_in * (int)sizeof(float);
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const int len_target = frames_target * (int)sizeof(float);
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Uint64 tick_beg = 0;
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Uint64 tick_end = 0;
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SDL_AudioCVT cvt;
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int i = 0;
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int ret = 0;
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double max_error = 0;
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double sum_squared_error = 0;
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double sum_squared_value = 0;
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double signal_to_noise = 0;
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SDLTest_AssertPass("Test resampling of %i s %i Hz %f phase sine wave from sampling rate of %i Hz to %i Hz",
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spec->time, spec->freq, spec->phase, spec->rate_in, spec->rate_out);
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ret = SDL_BuildAudioCVT(&cvt, AUDIO_F32, 1, spec->rate_in, AUDIO_F32, 1, spec->rate_out);
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SDLTest_AssertPass("Call to SDL_BuildAudioCVT(&cvt, AUDIO_F32, 1, %i, AUDIO_F32, 1, %i)", spec->rate_in, spec->rate_out);
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SDLTest_AssertCheck(ret == 1, "Expected SDL_BuildAudioCVT to succeed and conversion to be needed.");
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if (ret != 1) {
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return TEST_ABORTED;
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}
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cvt.buf = (Uint8 *)SDL_malloc(len_in * cvt.len_mult);
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SDLTest_AssertCheck(cvt.buf != NULL, "Expected input buffer to be created.");
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if (cvt.buf == NULL) {
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return TEST_ABORTED;
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}
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cvt.len = len_in;
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for (i = 0; i < frames_in; ++i) {
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*(((float *) cvt.buf) + i) = (float)sine_wave_sample(i, spec->rate_in, spec->freq, spec->phase);
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}
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tick_beg = SDL_GetPerformanceCounter();
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ret = SDL_ConvertAudio(&cvt);
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tick_end = SDL_GetPerformanceCounter();
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SDLTest_AssertPass("Call to SDL_ConvertAudio(&cvt)");
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SDLTest_AssertCheck(ret == 0, "Expected SDL_ConvertAudio to succeed.");
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SDLTest_AssertCheck(cvt.len_cvt == len_target, "Expected output length %i, got %i.", len_target, cvt.len_cvt);
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if (ret != 0 || cvt.len_cvt != len_target) {
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SDL_free(cvt.buf);
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return TEST_ABORTED;
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}
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SDLTest_Log("Resampling used %f seconds.", ((double) (tick_end - tick_beg)) / SDL_GetPerformanceFrequency());
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for (i = 0; i < frames_target; ++i) {
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const float output = *(((float *) cvt.buf) + i);
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const double target = sine_wave_sample(i, spec->rate_out, spec->freq, spec->phase);
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const double error = SDL_fabs(target - output);
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max_error = SDL_max(max_error, error);
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sum_squared_error += error * error;
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sum_squared_value += target * target;
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}
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SDL_free(cvt.buf);
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signal_to_noise = 10 * SDL_log10(sum_squared_value / sum_squared_error); /* decibel */
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SDLTest_AssertCheck(isfinite(sum_squared_value), "Sum of squared target should be finite.");
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SDLTest_AssertCheck(isfinite(sum_squared_error), "Sum of squared error should be finite.");
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/* Infinity is theoretically possible when there is very little to no noise */
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SDLTest_AssertCheck(!isnan(signal_to_noise), "Signal-to-noise ratio should not be NaN.");
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SDLTest_AssertCheck(isfinite(max_error), "Maximum conversion error should be finite.");
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SDLTest_AssertCheck(signal_to_noise >= spec->signal_to_noise, "Conversion signal-to-noise ratio %f dB should be no less than %f dB.",
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signal_to_noise, spec->signal_to_noise);
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SDLTest_AssertCheck(max_error <= spec->max_error, "Maximum conversion error %f should be no more than %f.",
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max_error, spec->max_error);
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}
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return TEST_COMPLETED;
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}
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/* ================= Test Case References ================== */
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/* Audio test cases */
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@ -1033,11 +1147,15 @@ static const SDLTest_TestCaseReference audioTest15 = {
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(SDLTest_TestCaseFp)audio_pauseUnpauseAudio, "audio_pauseUnpauseAudio", "Pause and Unpause audio for various audio specs while testing callback.", TEST_ENABLED
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};
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static const SDLTest_TestCaseReference audioTest16 = {
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(SDLTest_TestCaseFp)audio_resampleLoss, "audio_resampleLoss", "Check signal-to-noise ratio and maximum error of audio resampling.", TEST_ENABLED
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};
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/* Sequence of Audio test cases */
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static const SDLTest_TestCaseReference *audioTests[] = {
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&audioTest1, &audioTest2, &audioTest3, &audioTest4, &audioTest5, &audioTest6,
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&audioTest7, &audioTest8, &audioTest9, &audioTest10, &audioTest11,
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&audioTest12, &audioTest13, &audioTest14, &audioTest15, NULL
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&audioTest12, &audioTest13, &audioTest14, &audioTest15, &audioTest16, NULL
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};
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/* Audio test suite (global) */
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