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196 lines
5.9 KiB
C++
196 lines
5.9 KiB
C++
// Copyright 2019 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include <algorithm>
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#include <cmath>
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#include "testing/gtest/include/gtest/gtest-death-test.h"
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#include "testing/gtest/include/gtest/gtest.h"
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#include "third_party/pffft/src/fftpack.h"
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#include "third_party/pffft/src/pffft.h"
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namespace pffft {
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namespace test {
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namespace {
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static constexpr int kFftSizes[] = {
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16, 32, 64, 96, 128, 160, 192, 256, 288, 384, 5 * 96, 512,
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576, 5 * 128, 800, 864, 1024, 2048, 2592, 4000, 4096, 12000, 36864};
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double frand() {
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return rand() / (double)RAND_MAX;
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}
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void PffftValidate(int fft_size, bool complex_fft) {
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PFFFT_Setup* pffft_status =
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pffft_new_setup(fft_size, complex_fft ? PFFFT_COMPLEX : PFFFT_REAL);
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ASSERT_TRUE(pffft_status) << "FFT size (" << fft_size << ") not supported.";
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int num_floats = fft_size * (complex_fft ? 2 : 1);
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int num_bytes = num_floats * sizeof(float);
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float* ref = static_cast<float*>(pffft_aligned_malloc(num_bytes));
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float* in = static_cast<float*>(pffft_aligned_malloc(num_bytes));
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float* out = static_cast<float*>(pffft_aligned_malloc(num_bytes));
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float* tmp = static_cast<float*>(pffft_aligned_malloc(num_bytes));
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float* tmp2 = static_cast<float*>(pffft_aligned_malloc(num_bytes));
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for (int pass = 0; pass < 2; ++pass) {
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SCOPED_TRACE(pass);
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float ref_max = 0;
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int k;
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// Compute reference solution with FFTPACK.
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if (pass == 0) {
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float* fftpack_buff =
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static_cast<float*>(malloc(2 * num_bytes + 15 * sizeof(float)));
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for (k = 0; k < num_floats; ++k) {
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ref[k] = in[k] = frand() * 2 - 1;
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out[k] = 1e30;
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}
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if (!complex_fft) {
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rffti(fft_size, fftpack_buff);
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rfftf(fft_size, ref, fftpack_buff);
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// Use our ordering for real FFTs instead of the one of fftpack.
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{
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float refN = ref[fft_size - 1];
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for (k = fft_size - 2; k >= 1; --k)
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ref[k + 1] = ref[k];
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ref[1] = refN;
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}
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} else {
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cffti(fft_size, fftpack_buff);
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cfftf(fft_size, ref, fftpack_buff);
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}
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free(fftpack_buff);
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}
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for (k = 0; k < num_floats; ++k) {
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ref_max = std::max(ref_max, fabs(ref[k]));
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}
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// Pass 0: non canonical ordering of transform coefficients.
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if (pass == 0) {
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// Test forward transform, with different input / output.
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pffft_transform(pffft_status, in, tmp, nullptr, PFFFT_FORWARD);
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memcpy(tmp2, tmp, num_bytes);
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memcpy(tmp, in, num_bytes);
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pffft_transform(pffft_status, tmp, tmp, nullptr, PFFFT_FORWARD);
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for (k = 0; k < num_floats; ++k) {
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SCOPED_TRACE(k);
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EXPECT_EQ(tmp2[k], tmp[k]);
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}
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// Test reordering.
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pffft_zreorder(pffft_status, tmp, out, PFFFT_FORWARD);
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pffft_zreorder(pffft_status, out, tmp, PFFFT_BACKWARD);
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for (k = 0; k < num_floats; ++k) {
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SCOPED_TRACE(k);
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EXPECT_EQ(tmp2[k], tmp[k]);
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}
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pffft_zreorder(pffft_status, tmp, out, PFFFT_FORWARD);
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} else {
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// Pass 1: canonical ordering of transform coefficients.
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pffft_transform_ordered(pffft_status, in, tmp, nullptr, PFFFT_FORWARD);
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memcpy(tmp2, tmp, num_bytes);
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memcpy(tmp, in, num_bytes);
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pffft_transform_ordered(pffft_status, tmp, tmp, nullptr, PFFFT_FORWARD);
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for (k = 0; k < num_floats; ++k) {
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SCOPED_TRACE(k);
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EXPECT_EQ(tmp2[k], tmp[k]);
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}
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memcpy(out, tmp, num_bytes);
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}
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{
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for (k = 0; k < num_floats; ++k) {
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SCOPED_TRACE(k);
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EXPECT_NEAR(ref[k], out[k], 1e-3 * ref_max) << "Forward FFT mismatch";
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}
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if (pass == 0) {
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pffft_transform(pffft_status, tmp, out, nullptr, PFFFT_BACKWARD);
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} else {
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pffft_transform_ordered(pffft_status, tmp, out, nullptr,
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PFFFT_BACKWARD);
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}
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memcpy(tmp2, out, num_bytes);
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memcpy(out, tmp, num_bytes);
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if (pass == 0) {
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pffft_transform(pffft_status, out, out, nullptr, PFFFT_BACKWARD);
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} else {
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pffft_transform_ordered(pffft_status, out, out, nullptr,
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PFFFT_BACKWARD);
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}
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for (k = 0; k < num_floats; ++k) {
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assert(tmp2[k] == out[k]);
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out[k] *= 1.f / fft_size;
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}
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for (k = 0; k < num_floats; ++k) {
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SCOPED_TRACE(k);
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EXPECT_NEAR(in[k], out[k], 1e-3 * ref_max) << "Reverse FFT mismatch";
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}
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}
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// Quick test of the circular convolution in FFT domain.
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{
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float conv_err = 0, conv_max = 0;
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pffft_zreorder(pffft_status, ref, tmp, PFFFT_FORWARD);
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memset(out, 0, num_bytes);
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pffft_zconvolve_accumulate(pffft_status, ref, ref, out, 1.0);
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pffft_zreorder(pffft_status, out, tmp2, PFFFT_FORWARD);
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for (k = 0; k < num_floats; k += 2) {
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float ar = tmp[k], ai = tmp[k + 1];
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if (complex_fft || k > 0) {
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tmp[k] = ar * ar - ai * ai;
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tmp[k + 1] = 2 * ar * ai;
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} else {
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tmp[0] = ar * ar;
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tmp[1] = ai * ai;
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}
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}
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for (k = 0; k < num_floats; ++k) {
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float d = fabs(tmp[k] - tmp2[k]), e = fabs(tmp[k]);
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if (d > conv_err)
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conv_err = d;
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if (e > conv_max)
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conv_max = e;
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}
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EXPECT_LT(conv_err, 1e-5 * conv_max) << "zconvolve error";
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}
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}
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pffft_destroy_setup(pffft_status);
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pffft_aligned_free(ref);
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pffft_aligned_free(in);
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pffft_aligned_free(out);
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pffft_aligned_free(tmp);
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pffft_aligned_free(tmp2);
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}
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} // namespace
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TEST(PffftTest, ValidateReal) {
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for (int fft_size : kFftSizes) {
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SCOPED_TRACE(fft_size);
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if (fft_size == 16) {
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continue;
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}
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PffftValidate(fft_size, /*complex_fft=*/false);
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}
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}
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TEST(PffftTest, ValidateComplex) {
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for (int fft_size : kFftSizes) {
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SCOPED_TRACE(fft_size);
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PffftValidate(fft_size, /*complex_fft=*/true);
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}
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}
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} // namespace test
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} // namespace pffft
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