/* Spa * * Copyright © 2019 Wim Taymans * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ #include "config.h" #include #include #include #include #include #include #include #include "test-helper.h" #include "fmt-ops.c" #define N_SAMPLES 253 #define N_CHANNELS 11 static uint32_t cpu_flags; static uint8_t samp_in[N_SAMPLES * 8]; static uint8_t samp_out[N_SAMPLES * 8]; static uint8_t temp_in[N_SAMPLES * N_CHANNELS * 8]; static uint8_t temp_out[N_SAMPLES * N_CHANNELS * 8]; static void compare_mem(int i, int j, const void *m1, const void *m2, size_t size) { int res = memcmp(m1, m2, size); if (res != 0) { fprintf(stderr, "%d %d %zd:\n", i, j, size); spa_debug_mem(0, m1, size); spa_debug_mem(0, m2, size); } spa_assert_se(res == 0); } static void run_test(const char *name, const void *in, size_t in_size, const void *out, size_t out_size, size_t n_samples, bool in_packed, bool out_packed, convert_func_t func) { const void *ip[N_CHANNELS]; void *tp[N_CHANNELS]; int i, j; const uint8_t *in8 = in, *out8 = out; struct convert conv; conv.n_channels = N_CHANNELS; for (j = 0; j < N_SAMPLES; j++) { memcpy(&samp_in[j * in_size], &in8[(j % n_samples) * in_size], in_size); memcpy(&samp_out[j * out_size], &out8[(j % n_samples) * out_size], out_size); } for (j = 0; j < N_CHANNELS; j++) ip[j] = samp_in; if (in_packed) { tp[0] = temp_in; switch(in_size) { case 1: conv_8d_to_8_c(&conv, tp, ip, N_SAMPLES); break; case 2: conv_16d_to_16_c(&conv, tp, ip, N_SAMPLES); break; case 3: conv_24d_to_24_c(&conv, tp, ip, N_SAMPLES); break; case 4: conv_32d_to_32_c(&conv, tp, ip, N_SAMPLES); break; case 8: conv_64d_to_64_c(&conv, tp, ip, N_SAMPLES); break; default: fprintf(stderr, "unknown size %zd\n", in_size); return; } ip[0] = temp_in; } spa_zero(temp_out); for (j = 0; j < N_CHANNELS; j++) tp[j] = &temp_out[j * N_SAMPLES * out_size]; fprintf(stderr, "test %s:\n", name); func(&conv, tp, ip, N_SAMPLES); if (out_packed) { const uint8_t *d = tp[0], *s = samp_out; for (i = 0; i < N_SAMPLES; i++) { for (j = 0; j < N_CHANNELS; j++) { compare_mem(i, j, d, s, out_size); d += out_size; } s += out_size; } } else { for (j = 0; j < N_CHANNELS; j++) { compare_mem(0, j, tp[j], samp_out, N_SAMPLES * out_size); } } } static void test_f32_s8(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/160.f, 1.0f/256.f, -1.0f/160.f, -1.0f/256.f }; static const int8_t out[] = { 0, 127, -128, 64, 192, 127, -128, 1, 0, -1, 0 }; run_test("test_f32_s8", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_s8_c); run_test("test_f32d_s8", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s8_c); run_test("test_f32_s8d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_f32_to_s8d_c); run_test("test_f32d_s8d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_f32d_to_s8d_c); } static void test_s8_f32(void) { static const int8_t in[] = { 0, 127, -128, 64, 192, }; static const float out[] = { 0.0f, 0.9921875f, -1.0f, 0.5f, -0.5f, }; run_test("test_s8_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_s8_to_f32_c); run_test("test_s8d_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_s8d_to_f32_c); run_test("test_s8_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s8_to_f32d_c); run_test("test_s8d_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_s8d_to_f32d_c); } static void test_f32_u8(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/160.f, 1.0f/256.f, -1.0f/160.f, -1.0f/256.f }; static const uint8_t out[] = { 128, 255, 0, 192, 64, 255, 0, 129, 128, 127, 128 }; run_test("test_f32_u8", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_u8_c); run_test("test_f32d_u8", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_u8_c); run_test("test_f32_u8d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_f32_to_u8d_c); run_test("test_f32d_u8d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_f32d_to_u8d_c); } static void test_u8_f32(void) { static const uint8_t in[] = { 128, 255, 0, 192, 64, }; static const float out[] = { 0.0f, 0.9921875f, -1.0f, 0.5f, -0.5f, }; run_test("test_u8_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_u8_to_f32_c); run_test("test_u8d_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_u8d_to_f32_c); run_test("test_u8_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_u8_to_f32d_c); run_test("test_u8d_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_u8d_to_f32d_c); } static void test_f32_u16(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/49152.f, 1.0f/65536.f, -1.0f/49152.f, -1.0f/65536.f }; static const uint16_t out[] = { 32768, 65535, 0, 49152, 16384, 65535, 0, 32769, 32768, 32767, 32768 }; run_test("test_f32_u16", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_u16_c); run_test("test_f32d_u16", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_u16_c); } static void test_u16_f32(void) { static const uint16_t in[] = { 32768, 65535, 0, 49152, 16384, }; static const float out[] = { 0.0f, 0.999969482422f, -1.0f, 0.5f, -0.5f }; run_test("test_u16_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_u16_to_f32d_c); run_test("test_u16_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_u16_to_f32_c); } static void test_f32_s16(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/49152.f, 1.0f/65536.f, -1.0f/49152.f, -1.0f/65536.f }; static const int16_t out[] = { 0, 32767, -32768, 16384, -16384, 32767, -32768, 1, 0, -1, 0 }; run_test("test_f32_s16", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_s16_c); run_test("test_f32d_s16", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s16_c); run_test("test_f32_s16d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_f32_to_s16d_c); run_test("test_f32d_s16d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_f32d_to_s16d_c); #if defined(HAVE_SSE2) if (cpu_flags & SPA_CPU_FLAG_SSE2) { run_test("test_f32_s16_sse2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_s16_sse2); run_test("test_f32d_s16_sse2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s16_sse2); run_test("test_f32d_s16d_sse2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_f32d_to_s16d_sse2); } #endif #if defined(HAVE_AVX2) if (cpu_flags & SPA_CPU_FLAG_AVX2) { run_test("test_f32d_s16_avx2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s16_avx2); } #endif #if defined(HAVE_NEON) if (cpu_flags & SPA_CPU_FLAG_NEON) { run_test("test_f32d_s16_neon", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s16_neon); } #endif } static void test_s16_f32(void) { static const int16_t in[] = { 0, 32767, -32768, 16384, -16384, }; static const float out[] = { 0.0f, 0.999969482422f, -1.0f, 0.5f, -0.5f }; run_test("test_s16_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s16_to_f32d_c); run_test("test_s16d_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_s16d_to_f32_c); run_test("test_s16_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_s16_to_f32_c); run_test("test_s16d_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_s16d_to_f32d_c); #if defined(HAVE_SSE2) if (cpu_flags & SPA_CPU_FLAG_SSE2) { run_test("test_s16_f32d_sse2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s16_to_f32d_sse2); } #endif #if defined(HAVE_AVX2) if (cpu_flags & SPA_CPU_FLAG_AVX2) { run_test("test_s16_f32d_avx2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s16_to_f32d_avx2); } #endif #if defined(HAVE_NEON) if (cpu_flags & SPA_CPU_FLAG_NEON) { run_test("test_s16_f32d_neon", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s16_to_f32d_neon); } #endif } static void test_f32_u32(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/0xa00000, 1.0f/0x1000000, -1.0f/0xa00000, -1.0f/0x1000000 }; static const uint32_t out[] = { 0x80000000, 0xffffff00, 0x0, 0xc0000000, 0x40000000, 0xffffff00, 0x0, 0x80000100, 0x80000000, 0x7fffff00, 0x80000000 }; run_test("test_f32_u32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_u32_c); run_test("test_f32d_u32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_u32_c); } static void test_u32_f32(void) { static const uint32_t in[] = { 0x80000000, 0xffffff00, 0x0, 0xc0000000, 0x40000000 }; static const float out[] = { 0.0f, 0.999999880791f, -1.0f, 0.5f, -0.5f, }; run_test("test_u32_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_u32_to_f32d_c); run_test("test_u32_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_u32_to_f32_c); } static void test_f32_s32(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/0xa00000, 1.0f/0x1000000, -1.0f/0xa00000, -1.0f/0x1000000 }; static const int32_t out[] = { 0, 0x7fffff00, 0x80000000, 0x40000000, 0xc0000000, 0x7fffff00, 0x80000000, 0x00000100, 0x00000000, 0xffffff00, 0x00000000 }; run_test("test_f32_s32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_s32_c); run_test("test_f32d_s32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s32_c); run_test("test_f32_s32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_f32_to_s32d_c); run_test("test_f32d_s32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_f32d_to_s32d_c); #if defined(HAVE_SSE2) if (cpu_flags & SPA_CPU_FLAG_SSE2) { run_test("test_f32d_s32_sse2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s32_sse2); } #endif #if defined(HAVE_AVX2) if (cpu_flags & SPA_CPU_FLAG_AVX2) { run_test("test_f32d_s32_avx2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s32_avx2); } #endif } static void test_s32_f32(void) { static const int32_t in[] = { 0, 0x7fffff00, 0x80000000, 0x40000000, 0xc0000000 }; static const float out[] = { 0.0f, 0.999999880791, -1.0f, 0.5, -0.5, }; run_test("test_s32_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s32_to_f32d_c); run_test("test_s32d_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_s32d_to_f32_c); run_test("test_s32_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_s32_to_f32_c); run_test("test_s32d_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_s32d_to_f32d_c); #if defined(HAVE_SSE2) if (cpu_flags & SPA_CPU_FLAG_SSE2) { run_test("test_s32_f32d_sse2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s32_to_f32d_sse2); } #endif #if defined(HAVE_AVX2) if (cpu_flags & SPA_CPU_FLAG_AVX2) { run_test("test_s32_f32d_avx2", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s32_to_f32d_avx2); } #endif } static void test_f32_u24(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/0xa00000, 1.0f/0x1000000, -1.0f/0xa00000, -1.0f/0x1000000 }; static const uint24_t out[] = { U32_TO_U24(0x00800000), U32_TO_U24(0xffffff), U32_TO_U24(0x000000), U32_TO_U24(0xc00000), U32_TO_U24(0x400000), U32_TO_U24(0xffffff), U32_TO_U24(0x000000), U32_TO_U24(0x800001), U32_TO_U24(0x800000), U32_TO_U24(0x7fffff), U32_TO_U24(0x800000) }; run_test("test_f32_u24", in, sizeof(in[0]), out, 3, SPA_N_ELEMENTS(in), true, true, conv_f32_to_u24_c); run_test("test_f32d_u24", in, sizeof(in[0]), out, 3, SPA_N_ELEMENTS(in), false, true, conv_f32d_to_u24_c); } static void test_u24_f32(void) { static const uint24_t in[] = { U32_TO_U24(0x00800000), U32_TO_U24(0xffffff), U32_TO_U24(0x000000), U32_TO_U24(0xc00000), U32_TO_U24(0x400000) }; static const float out[] = { 0.0f, 0.999999880791f, -1.0f, 0.5, -0.5, }; run_test("test_u24_f32d", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_u24_to_f32d_c); run_test("test_u24_f32", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_u24_to_f32_c); } static void test_f32_s24(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/0xa00000, 1.0f/0x1000000, -1.0f/0xa00000, -1.0f/0x1000000 }; static const int24_t out[] = { S32_TO_S24(0), S32_TO_S24(0x7fffff), S32_TO_S24(0xff800000), S32_TO_S24(0x400000), S32_TO_S24(0xc00000), S32_TO_S24(0x7fffff), S32_TO_S24(0xff800000), S32_TO_S24(0x000001), S32_TO_S24(0x000000), S32_TO_S24(0xffffffff), S32_TO_S24(0x000000) }; run_test("test_f32_s24", in, sizeof(in[0]), out, 3, SPA_N_ELEMENTS(in), true, true, conv_f32_to_s24_c); run_test("test_f32d_s24", in, sizeof(in[0]), out, 3, SPA_N_ELEMENTS(in), false, true, conv_f32d_to_s24_c); run_test("test_f32_s24d", in, sizeof(in[0]), out, 3, SPA_N_ELEMENTS(in), true, false, conv_f32_to_s24d_c); run_test("test_f32d_s24d", in, sizeof(in[0]), out, 3, SPA_N_ELEMENTS(in), false, false, conv_f32d_to_s24d_c); } static void test_s24_f32(void) { static const int24_t in[] = { S32_TO_S24(0), S32_TO_S24(0x7fffff), S32_TO_S24(0xff800000), S32_TO_S24(0x400000), S32_TO_S24(0xc00000) }; static const float out[] = { 0.0f, 0.999999880791f, -1.0f, 0.5f, -0.5f, }; run_test("test_s24_f32d", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s24_to_f32d_c); run_test("test_s24d_f32", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_s24d_to_f32_c); run_test("test_s24_f32", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_s24_to_f32_c); run_test("test_s24d_f32d", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_s24d_to_f32d_c); #if defined(HAVE_SSE2) if (cpu_flags & SPA_CPU_FLAG_SSE2) { run_test("test_s24_f32d_sse2", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s24_to_f32d_sse2); } #endif #if defined(HAVE_SSSE3) if (cpu_flags & SPA_CPU_FLAG_SSSE3) { run_test("test_s24_f32d_ssse3", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s24_to_f32d_ssse3); } #endif #if defined(HAVE_SSE41) if (cpu_flags & SPA_CPU_FLAG_SSE41) { run_test("test_s24_f32d_sse41", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s24_to_f32d_sse41); } #endif #if defined(HAVE_AVX2) if (cpu_flags & SPA_CPU_FLAG_AVX2) { run_test("test_s24_f32d_avx2", in, 3, out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s24_to_f32d_avx2); } #endif } static void test_f32_u24_32(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/0xa00000, 1.0f/0x1000000, -1.0f/0xa00000, -1.0f/0x1000000 }; static const uint32_t out[] = { 0x800000, 0xffffff, 0x0, 0xc00000, 0x400000, 0xffffff, 0x000000, 0x800001, 0x800000, 0x7fffff, 0x800000 }; run_test("test_f32_u24_32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_u24_32_c); run_test("test_f32d_u24_32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_u24_32_c); } static void test_u24_32_f32(void) { static const uint32_t in[] = { 0x800000, 0xffffff, 0x0, 0xc00000, 0x400000, 0x11000000 }; static const float out[] = { 0.0f, 0.999999880791f, -1.0f, 0.5f, -0.5f, -1.0f }; run_test("test_u24_32_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_u24_32_to_f32d_c); run_test("test_u24_32_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_u24_32_to_f32_c); } static void test_f32_s24_32(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f, 1.0f/0xa00000, 1.0f/0x1000000, -1.0f/0xa00000, -1.0f/0x1000000 }; static const int32_t out[] = { 0, 0x7fffff, 0xff800000, 0x400000, 0xffc00000, 0x7fffff, 0xff800000, 0x000001, 0x000000, 0xffffffff, 0x000000 }; run_test("test_f32_s24_32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_s24_32_c); run_test("test_f32d_s24_32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_s24_32_c); run_test("test_f32_s24_32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_f32_to_s24_32d_c); run_test("test_f32d_s24_32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_f32d_to_s24_32d_c); } static void test_s24_32_f32(void) { static const int32_t in[] = { 0, 0x7fffff, 0xff800000, 0x400000, 0xffc00000, 0x66800000 }; static const float out[] = { 0.0f, 0.999999880791f, -1.0f, 0.5f, -0.5f, -1.0f }; run_test("test_s24_32_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_s24_32_to_f32d_c); run_test("test_s24_32d_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_s24_32d_to_f32_c); run_test("test_s24_32_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_s24_32_to_f32_c); run_test("test_s24_32d_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_s24_32d_to_f32d_c); } static void test_f64_f32(void) { static const double in[] = { 0.0, 1.0, -1.0, 0.5, -0.5, }; static const float out[] = { 0.0, 1.0, -1.0, 0.5, -0.5, }; run_test("test_f64_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_f64_to_f32d_c); run_test("test_f64d_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f64d_to_f32_c); run_test("test_f64_f32", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f64_to_f32_c); run_test("test_f64d_f32d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_f64d_to_f32d_c); } static void test_f32_f64(void) { static const float in[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f }; static const double out[] = { 0.0f, 1.0f, -1.0f, 0.5f, -0.5f, 1.1f, -1.1f }; run_test("test_f32_f64", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, true, conv_f32_to_f64_c); run_test("test_f32d_f64", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, true, conv_f32d_to_f64_c); run_test("test_f32_f64d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), true, false, conv_f32_to_f64d_c); run_test("test_f32d_f64d", in, sizeof(in[0]), out, sizeof(out[0]), SPA_N_ELEMENTS(out), false, false, conv_f32d_to_f64d_c); } static void test_lossless_s8(void) { int8_t i; fprintf(stderr, "test %s:\n", __func__); for (i = S8_MIN; i < S8_MAX; i+=1) { float v = S8_TO_F32(i); int8_t t = F32_TO_S8(v); spa_assert_se(i == t); } } static void test_lossless_u8(void) { uint8_t i; fprintf(stderr, "test %s:\n", __func__); for (i = U8_MIN; i < U8_MAX; i+=1) { float v = U8_TO_F32(i); uint8_t t = F32_TO_U8(v); spa_assert_se(i == t); } } static void test_lossless_s16(void) { int16_t i; fprintf(stderr, "test %s:\n", __func__); for (i = S16_MIN; i < S16_MAX; i+=3) { float v = S16_TO_F32(i); int16_t t = F32_TO_S16(v); spa_assert_se(i == t); } } static void test_lossless_u16(void) { uint32_t i; fprintf(stderr, "test %s:\n", __func__); for (i = U16_MIN; i < U16_MAX; i+=3) { float v = U16_TO_F32(i); uint16_t t = F32_TO_U16(v); spa_assert_se(i == t); } } static void test_lossless_s24(void) { int32_t i; fprintf(stderr, "test %s:\n", __func__); for (i = S24_MIN; i < S24_MAX; i+=13) { float v = S24_TO_F32(s32_to_s24(i)); int32_t t = s24_to_s32(F32_TO_S24(v)); spa_assert_se(i == t); } } static void test_lossless_u24(void) { uint32_t i; fprintf(stderr, "test %s:\n", __func__); for (i = U24_MIN; i < U24_MAX; i+=11) { float v = U24_TO_F32(u32_to_u24(i)); uint32_t t = u24_to_u32(F32_TO_U24(v)); spa_assert_se(i == t); } } static void test_lossless_s32(void) { int32_t i; fprintf(stderr, "test %s:\n", __func__); for (i = S32_MIN; i < S32_MAX; i+=255) { float v = S32_TO_F32(i); int32_t t = F32_TO_S32(v); spa_assert_se(SPA_ABS(i - t) <= 256); } } static void test_lossless_u32(void) { uint32_t i; fprintf(stderr, "test %s:\n", __func__); for (i = U32_MIN; i < U32_MAX; i+=255) { float v = U32_TO_F32(i); uint32_t t = F32_TO_U32(v); spa_assert_se(i > t ? (i - t) <= 256 : (t - i) <= 256); } } static void test_swaps(void) { { uint24_t v = U32_TO_U24(0x123456); uint24_t t = U32_TO_U24(0x563412); uint24_t s = bswap_u24(v); spa_assert_se(memcmp(&s, &t, sizeof(t)) == 0); } { int24_t v = S32_TO_S24(0xfffe1dc0); int24_t t = S32_TO_S24(0xffc01dfe); int24_t s = bswap_s24(v); spa_assert_se(memcmp(&s, &t, sizeof(t)) == 0); } { int24_t v = S32_TO_S24(0x123456); int24_t t = S32_TO_S24(0x563412); int24_t s = bswap_s24(v); spa_assert_se(memcmp(&s, &t, sizeof(t)) == 0); } } static void run_test_noise(uint32_t fmt, uint32_t noise, uint32_t flags) { struct convert conv; const void *ip[N_CHANNELS]; void *op[N_CHANNELS]; uint32_t i, range; bool all_zero; spa_zero(conv); conv.noise_bits = noise; conv.src_fmt = SPA_AUDIO_FORMAT_F32P; conv.dst_fmt = fmt; conv.n_channels = 2; conv.rate = 44100; conv.cpu_flags = flags; spa_assert_se(convert_init(&conv) == 0); fprintf(stderr, "test noise %s:\n", conv.func_name); memset(samp_in, 0, sizeof(samp_in)); for (i = 0; i < conv.n_channels; i++) { ip[i] = samp_in; op[i] = samp_out; } convert_process(&conv, op, ip, N_SAMPLES); range = 1 << conv.noise_bits; all_zero = true; for (i = 0; i < conv.n_channels * N_SAMPLES; i++) { switch (fmt) { case SPA_AUDIO_FORMAT_S8: { int8_t *d = (int8_t *)samp_out; if (d[i] != 0) all_zero = false; spa_assert_se(SPA_ABS(d[i] - 0) <= (int8_t)range); break; } case SPA_AUDIO_FORMAT_U8: { uint8_t *d = (uint8_t *)samp_out; if (d[i] != 0x80) all_zero = false; spa_assert_se((int8_t)SPA_ABS(d[i] - 0x80) <= (int8_t)(range<<1)); break; } case SPA_AUDIO_FORMAT_S16: { int16_t *d = (int16_t *)samp_out; if (d[i] != 0) all_zero = false; spa_assert_se(SPA_ABS(d[i] - 0) <= (int16_t)range); break; } case SPA_AUDIO_FORMAT_S24: { int24_t *d = (int24_t *)samp_out; int32_t t = s24_to_s32(d[i]); if (t != 0) all_zero = false; spa_assert_se(SPA_ABS(t - 0) <= (int32_t)range); break; } case SPA_AUDIO_FORMAT_S32: { int32_t *d = (int32_t *)samp_out; if (d[i] != 0) all_zero = false; spa_assert_se(SPA_ABS(d[i] - 0) <= (int32_t)(range << 8)); break; } default: spa_assert_not_reached(); break; } } spa_assert_se(all_zero == false); convert_free(&conv); } static void test_noise(void) { run_test_noise(SPA_AUDIO_FORMAT_S8, 1, 0); run_test_noise(SPA_AUDIO_FORMAT_S8, 2, 0); run_test_noise(SPA_AUDIO_FORMAT_U8, 1, 0); run_test_noise(SPA_AUDIO_FORMAT_U8, 2, 0); run_test_noise(SPA_AUDIO_FORMAT_S16, 1, 0); run_test_noise(SPA_AUDIO_FORMAT_S16, 2, 0); run_test_noise(SPA_AUDIO_FORMAT_S24, 1, 0); run_test_noise(SPA_AUDIO_FORMAT_S24, 2, 0); run_test_noise(SPA_AUDIO_FORMAT_S32, 1, 0); run_test_noise(SPA_AUDIO_FORMAT_S32, 2, 0); } int main(int argc, char *argv[]) { cpu_flags = get_cpu_flags(); printf("got CPU flags %d\n", cpu_flags); test_f32_s8(); test_s8_f32(); test_f32_u8(); test_u8_f32(); test_f32_u16(); test_u16_f32(); test_f32_s16(); test_s16_f32(); test_f32_u32(); test_u32_f32(); test_f32_s32(); test_s32_f32(); test_f32_u24(); test_u24_f32(); test_f32_s24(); test_s24_f32(); test_f32_u24_32(); test_u24_32_f32(); test_f32_s24_32(); test_s24_32_f32(); test_f32_f64(); test_f64_f32(); test_lossless_s8(); test_lossless_u8(); test_lossless_s16(); test_lossless_u16(); test_lossless_s24(); test_lossless_u24(); test_lossless_s32(); test_lossless_u32(); test_swaps(); test_noise(); return 0; }