/* * Copyright (c) 2017 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "modules/audio_processing/aec3/adaptive_fir_filter.h" // Defines WEBRTC_ARCH_X86_FAMILY, used below. #include "rtc_base/system/arch.h" #if defined(WEBRTC_HAS_NEON) #include #endif #if defined(WEBRTC_ARCH_X86_FAMILY) #include #endif #include #include #include #include "modules/audio_processing/aec3/fft_data.h" #include "rtc_base/checks.h" namespace webrtc { namespace aec3 { // Computes and stores the frequency response of the filter. void ComputeFrequencyResponse( size_t num_partitions, const std::vector>& H, std::vector>* H2) { for (auto& H2_ch : *H2) { H2_ch.fill(0.f); } const size_t num_render_channels = H[0].size(); RTC_DCHECK_EQ(H.size(), H2->capacity()); for (size_t p = 0; p < num_partitions; ++p) { RTC_DCHECK_EQ(kFftLengthBy2Plus1, (*H2)[p].size()); for (size_t ch = 0; ch < num_render_channels; ++ch) { for (size_t j = 0; j < kFftLengthBy2Plus1; ++j) { float tmp = H[p][ch].re[j] * H[p][ch].re[j] + H[p][ch].im[j] * H[p][ch].im[j]; (*H2)[p][j] = std::max((*H2)[p][j], tmp); } } } } #if defined(WEBRTC_HAS_NEON) // Computes and stores the frequency response of the filter. void ComputeFrequencyResponse_Neon( size_t num_partitions, const std::vector>& H, std::vector>* H2) { for (auto& H2_ch : *H2) { H2_ch.fill(0.f); } const size_t num_render_channels = H[0].size(); RTC_DCHECK_EQ(H.size(), H2->capacity()); for (size_t p = 0; p < num_partitions; ++p) { RTC_DCHECK_EQ(kFftLengthBy2Plus1, (*H2)[p].size()); auto& H2_p = (*H2)[p]; for (size_t ch = 0; ch < num_render_channels; ++ch) { const FftData& H_p_ch = H[p][ch]; for (size_t j = 0; j < kFftLengthBy2; j += 4) { const float32x4_t re = vld1q_f32(&H_p_ch.re[j]); const float32x4_t im = vld1q_f32(&H_p_ch.im[j]); float32x4_t H2_new = vmulq_f32(re, re); H2_new = vmlaq_f32(H2_new, im, im); float32x4_t H2_p_j = vld1q_f32(&H2_p[j]); H2_p_j = vmaxq_f32(H2_p_j, H2_new); vst1q_f32(&H2_p[j], H2_p_j); } float H2_new = H_p_ch.re[kFftLengthBy2] * H_p_ch.re[kFftLengthBy2] + H_p_ch.im[kFftLengthBy2] * H_p_ch.im[kFftLengthBy2]; H2_p[kFftLengthBy2] = std::max(H2_p[kFftLengthBy2], H2_new); } } } #endif #if defined(WEBRTC_ARCH_X86_FAMILY) // Computes and stores the frequency response of the filter. void ComputeFrequencyResponse_Sse2( size_t num_partitions, const std::vector>& H, std::vector>* H2) { for (auto& H2_ch : *H2) { H2_ch.fill(0.f); } const size_t num_render_channels = H[0].size(); RTC_DCHECK_EQ(H.size(), H2->capacity()); // constexpr __mmmask8 kMaxMask = static_cast<__mmmask8>(256u); for (size_t p = 0; p < num_partitions; ++p) { RTC_DCHECK_EQ(kFftLengthBy2Plus1, (*H2)[p].size()); auto& H2_p = (*H2)[p]; for (size_t ch = 0; ch < num_render_channels; ++ch) { const FftData& H_p_ch = H[p][ch]; for (size_t j = 0; j < kFftLengthBy2; j += 4) { const __m128 re = _mm_loadu_ps(&H_p_ch.re[j]); const __m128 re2 = _mm_mul_ps(re, re); const __m128 im = _mm_loadu_ps(&H_p_ch.im[j]); const __m128 im2 = _mm_mul_ps(im, im); const __m128 H2_new = _mm_add_ps(re2, im2); __m128 H2_k_j = _mm_loadu_ps(&H2_p[j]); H2_k_j = _mm_max_ps(H2_k_j, H2_new); _mm_storeu_ps(&H2_p[j], H2_k_j); } float H2_new = H_p_ch.re[kFftLengthBy2] * H_p_ch.re[kFftLengthBy2] + H_p_ch.im[kFftLengthBy2] * H_p_ch.im[kFftLengthBy2]; H2_p[kFftLengthBy2] = std::max(H2_p[kFftLengthBy2], H2_new); } } } #endif // Adapts the filter partitions as H(t+1)=H(t)+G(t)*conj(X(t)). void AdaptPartitions(const RenderBuffer& render_buffer, const FftData& G, size_t num_partitions, std::vector>* H) { rtc::ArrayView> render_buffer_data = render_buffer.GetFftBuffer(); size_t index = render_buffer.Position(); const size_t num_render_channels = render_buffer_data[index].size(); for (size_t p = 0; p < num_partitions; ++p) { for (size_t ch = 0; ch < num_render_channels; ++ch) { const FftData& X_p_ch = render_buffer_data[index][ch]; FftData& H_p_ch = (*H)[p][ch]; for (size_t k = 0; k < kFftLengthBy2Plus1; ++k) { H_p_ch.re[k] += X_p_ch.re[k] * G.re[k] + X_p_ch.im[k] * G.im[k]; H_p_ch.im[k] += X_p_ch.re[k] * G.im[k] - X_p_ch.im[k] * G.re[k]; } } index = index < (render_buffer_data.size() - 1) ? index + 1 : 0; } } #if defined(WEBRTC_HAS_NEON) // Adapts the filter partitions. (Neon variant) void AdaptPartitions_Neon(const RenderBuffer& render_buffer, const FftData& G, size_t num_partitions, std::vector>* H) { rtc::ArrayView> render_buffer_data = render_buffer.GetFftBuffer(); const size_t num_render_channels = render_buffer_data[0].size(); const size_t lim1 = std::min( render_buffer_data.size() - render_buffer.Position(), num_partitions); const size_t lim2 = num_partitions; constexpr size_t kNumFourBinBands = kFftLengthBy2 / 4; size_t X_partition = render_buffer.Position(); size_t limit = lim1; size_t p = 0; do { for (; p < limit; ++p, ++X_partition) { for (size_t ch = 0; ch < num_render_channels; ++ch) { FftData& H_p_ch = (*H)[p][ch]; const FftData& X = render_buffer_data[X_partition][ch]; for (size_t k = 0, n = 0; n < kNumFourBinBands; ++n, k += 4) { const float32x4_t G_re = vld1q_f32(&G.re[k]); const float32x4_t G_im = vld1q_f32(&G.im[k]); const float32x4_t X_re = vld1q_f32(&X.re[k]); const float32x4_t X_im = vld1q_f32(&X.im[k]); const float32x4_t H_re = vld1q_f32(&H_p_ch.re[k]); const float32x4_t H_im = vld1q_f32(&H_p_ch.im[k]); const float32x4_t a = vmulq_f32(X_re, G_re); const float32x4_t e = vmlaq_f32(a, X_im, G_im); const float32x4_t c = vmulq_f32(X_re, G_im); const float32x4_t f = vmlsq_f32(c, X_im, G_re); const float32x4_t g = vaddq_f32(H_re, e); const float32x4_t h = vaddq_f32(H_im, f); vst1q_f32(&H_p_ch.re[k], g); vst1q_f32(&H_p_ch.im[k], h); } } } X_partition = 0; limit = lim2; } while (p < lim2); X_partition = render_buffer.Position(); limit = lim1; p = 0; do { for (; p < limit; ++p, ++X_partition) { for (size_t ch = 0; ch < num_render_channels; ++ch) { FftData& H_p_ch = (*H)[p][ch]; const FftData& X = render_buffer_data[X_partition][ch]; H_p_ch.re[kFftLengthBy2] += X.re[kFftLengthBy2] * G.re[kFftLengthBy2] + X.im[kFftLengthBy2] * G.im[kFftLengthBy2]; H_p_ch.im[kFftLengthBy2] += X.re[kFftLengthBy2] * G.im[kFftLengthBy2] - X.im[kFftLengthBy2] * G.re[kFftLengthBy2]; } } X_partition = 0; limit = lim2; } while (p < lim2); } #endif #if defined(WEBRTC_ARCH_X86_FAMILY) // Adapts the filter partitions. (SSE2 variant) void AdaptPartitions_Sse2(const RenderBuffer& render_buffer, const FftData& G, size_t num_partitions, std::vector>* H) { rtc::ArrayView> render_buffer_data = render_buffer.GetFftBuffer(); const size_t num_render_channels = render_buffer_data[0].size(); const size_t lim1 = std::min( render_buffer_data.size() - render_buffer.Position(), num_partitions); const size_t lim2 = num_partitions; constexpr size_t kNumFourBinBands = kFftLengthBy2 / 4; size_t X_partition = render_buffer.Position(); size_t limit = lim1; size_t p = 0; do { for (; p < limit; ++p, ++X_partition) { for (size_t ch = 0; ch < num_render_channels; ++ch) { FftData& H_p_ch = (*H)[p][ch]; const FftData& X = render_buffer_data[X_partition][ch]; for (size_t k = 0, n = 0; n < kNumFourBinBands; ++n, k += 4) { const __m128 G_re = _mm_loadu_ps(&G.re[k]); const __m128 G_im = _mm_loadu_ps(&G.im[k]); const __m128 X_re = _mm_loadu_ps(&X.re[k]); const __m128 X_im = _mm_loadu_ps(&X.im[k]); const __m128 H_re = _mm_loadu_ps(&H_p_ch.re[k]); const __m128 H_im = _mm_loadu_ps(&H_p_ch.im[k]); const __m128 a = _mm_mul_ps(X_re, G_re); const __m128 b = _mm_mul_ps(X_im, G_im); const __m128 c = _mm_mul_ps(X_re, G_im); const __m128 d = _mm_mul_ps(X_im, G_re); const __m128 e = _mm_add_ps(a, b); const __m128 f = _mm_sub_ps(c, d); const __m128 g = _mm_add_ps(H_re, e); const __m128 h = _mm_add_ps(H_im, f); _mm_storeu_ps(&H_p_ch.re[k], g); _mm_storeu_ps(&H_p_ch.im[k], h); } } } X_partition = 0; limit = lim2; } while (p < lim2); X_partition = render_buffer.Position(); limit = lim1; p = 0; do { for (; p < limit; ++p, ++X_partition) { for (size_t ch = 0; ch < num_render_channels; ++ch) { FftData& H_p_ch = (*H)[p][ch]; const FftData& X = render_buffer_data[X_partition][ch]; H_p_ch.re[kFftLengthBy2] += X.re[kFftLengthBy2] * G.re[kFftLengthBy2] + X.im[kFftLengthBy2] * G.im[kFftLengthBy2]; H_p_ch.im[kFftLengthBy2] += X.re[kFftLengthBy2] * G.im[kFftLengthBy2] - X.im[kFftLengthBy2] * G.re[kFftLengthBy2]; } } X_partition = 0; limit = lim2; } while (p < lim2); } #endif // Produces the filter output. void ApplyFilter(const RenderBuffer& render_buffer, size_t num_partitions, const std::vector>& H, FftData* S) { S->re.fill(0.f); S->im.fill(0.f); rtc::ArrayView> render_buffer_data = render_buffer.GetFftBuffer(); size_t index = render_buffer.Position(); const size_t num_render_channels = render_buffer_data[index].size(); for (size_t p = 0; p < num_partitions; ++p) { RTC_DCHECK_EQ(num_render_channels, H[p].size()); for (size_t ch = 0; ch < num_render_channels; ++ch) { const FftData& X_p_ch = render_buffer_data[index][ch]; const FftData& H_p_ch = H[p][ch]; for (size_t k = 0; k < kFftLengthBy2Plus1; ++k) { S->re[k] += X_p_ch.re[k] * H_p_ch.re[k] - X_p_ch.im[k] * H_p_ch.im[k]; S->im[k] += X_p_ch.re[k] * H_p_ch.im[k] + X_p_ch.im[k] * H_p_ch.re[k]; } } index = index < (render_buffer_data.size() - 1) ? index + 1 : 0; } } #if defined(WEBRTC_HAS_NEON) // Produces the filter output (Neon variant). void ApplyFilter_Neon(const RenderBuffer& render_buffer, size_t num_partitions, const std::vector>& H, FftData* S) { // const RenderBuffer& render_buffer, // rtc::ArrayView H, // FftData* S) { RTC_DCHECK_GE(H.size(), H.size() - 1); S->Clear(); rtc::ArrayView> render_buffer_data = render_buffer.GetFftBuffer(); const size_t num_render_channels = render_buffer_data[0].size(); const size_t lim1 = std::min( render_buffer_data.size() - render_buffer.Position(), num_partitions); const size_t lim2 = num_partitions; constexpr size_t kNumFourBinBands = kFftLengthBy2 / 4; size_t X_partition = render_buffer.Position(); size_t p = 0; size_t limit = lim1; do { for (; p < limit; ++p, ++X_partition) { for (size_t ch = 0; ch < num_render_channels; ++ch) { const FftData& H_p_ch = H[p][ch]; const FftData& X = render_buffer_data[X_partition][ch]; for (size_t k = 0, n = 0; n < kNumFourBinBands; ++n, k += 4) { const float32x4_t X_re = vld1q_f32(&X.re[k]); const float32x4_t X_im = vld1q_f32(&X.im[k]); const float32x4_t H_re = vld1q_f32(&H_p_ch.re[k]); const float32x4_t H_im = vld1q_f32(&H_p_ch.im[k]); const float32x4_t S_re = vld1q_f32(&S->re[k]); const float32x4_t S_im = vld1q_f32(&S->im[k]); const float32x4_t a = vmulq_f32(X_re, H_re); const float32x4_t e = vmlsq_f32(a, X_im, H_im); const float32x4_t c = vmulq_f32(X_re, H_im); const float32x4_t f = vmlaq_f32(c, X_im, H_re); const float32x4_t g = vaddq_f32(S_re, e); const float32x4_t h = vaddq_f32(S_im, f); vst1q_f32(&S->re[k], g); vst1q_f32(&S->im[k], h); } } } limit = lim2; X_partition = 0; } while (p < lim2); X_partition = render_buffer.Position(); p = 0; limit = lim1; do { for (; p < limit; ++p, ++X_partition) { for (size_t ch = 0; ch < num_render_channels; ++ch) { const FftData& H_p_ch = H[p][ch]; const FftData& X = render_buffer_data[X_partition][ch]; S->re[kFftLengthBy2] += X.re[kFftLengthBy2] * H_p_ch.re[kFftLengthBy2] - X.im[kFftLengthBy2] * H_p_ch.im[kFftLengthBy2]; S->im[kFftLengthBy2] += X.re[kFftLengthBy2] * H_p_ch.im[kFftLengthBy2] + X.im[kFftLengthBy2] * H_p_ch.re[kFftLengthBy2]; } } limit = lim2; X_partition = 0; } while (p < lim2); } #endif #if defined(WEBRTC_ARCH_X86_FAMILY) // Produces the filter output (SSE2 variant). void ApplyFilter_Sse2(const RenderBuffer& render_buffer, size_t num_partitions, const std::vector>& H, FftData* S) { // const RenderBuffer& render_buffer, // rtc::ArrayView H, // FftData* S) { RTC_DCHECK_GE(H.size(), H.size() - 1); S->re.fill(0.f); S->im.fill(0.f); rtc::ArrayView> render_buffer_data = render_buffer.GetFftBuffer(); const size_t num_render_channels = render_buffer_data[0].size(); const size_t lim1 = std::min( render_buffer_data.size() - render_buffer.Position(), num_partitions); const size_t lim2 = num_partitions; constexpr size_t kNumFourBinBands = kFftLengthBy2 / 4; size_t X_partition = render_buffer.Position(); size_t p = 0; size_t limit = lim1; do { for (; p < limit; ++p, ++X_partition) { for (size_t ch = 0; ch < num_render_channels; ++ch) { const FftData& H_p_ch = H[p][ch]; const FftData& X = render_buffer_data[X_partition][ch]; for (size_t k = 0, n = 0; n < kNumFourBinBands; ++n, k += 4) { const __m128 X_re = _mm_loadu_ps(&X.re[k]); const __m128 X_im = _mm_loadu_ps(&X.im[k]); const __m128 H_re = _mm_loadu_ps(&H_p_ch.re[k]); const __m128 H_im = _mm_loadu_ps(&H_p_ch.im[k]); const __m128 S_re = _mm_loadu_ps(&S->re[k]); const __m128 S_im = _mm_loadu_ps(&S->im[k]); const __m128 a = _mm_mul_ps(X_re, H_re); const __m128 b = _mm_mul_ps(X_im, H_im); const __m128 c = _mm_mul_ps(X_re, H_im); const __m128 d = _mm_mul_ps(X_im, H_re); const __m128 e = _mm_sub_ps(a, b); const __m128 f = _mm_add_ps(c, d); const __m128 g = _mm_add_ps(S_re, e); const __m128 h = _mm_add_ps(S_im, f); _mm_storeu_ps(&S->re[k], g); _mm_storeu_ps(&S->im[k], h); } } } limit = lim2; X_partition = 0; } while (p < lim2); X_partition = render_buffer.Position(); p = 0; limit = lim1; do { for (; p < limit; ++p, ++X_partition) { for (size_t ch = 0; ch < num_render_channels; ++ch) { const FftData& H_p_ch = H[p][ch]; const FftData& X = render_buffer_data[X_partition][ch]; S->re[kFftLengthBy2] += X.re[kFftLengthBy2] * H_p_ch.re[kFftLengthBy2] - X.im[kFftLengthBy2] * H_p_ch.im[kFftLengthBy2]; S->im[kFftLengthBy2] += X.re[kFftLengthBy2] * H_p_ch.im[kFftLengthBy2] + X.im[kFftLengthBy2] * H_p_ch.re[kFftLengthBy2]; } } limit = lim2; X_partition = 0; } while (p < lim2); } #endif } // namespace aec3 namespace { // Ensures that the newly added filter partitions after a size increase are set // to zero. void ZeroFilter(size_t old_size, size_t new_size, std::vector>* H) { RTC_DCHECK_GE(H->size(), old_size); RTC_DCHECK_GE(H->size(), new_size); for (size_t p = old_size; p < new_size; ++p) { RTC_DCHECK_EQ((*H)[p].size(), (*H)[0].size()); for (size_t ch = 0; ch < (*H)[0].size(); ++ch) { (*H)[p][ch].Clear(); } } } } // namespace AdaptiveFirFilter::AdaptiveFirFilter(size_t max_size_partitions, size_t initial_size_partitions, size_t size_change_duration_blocks, size_t num_render_channels, Aec3Optimization optimization, ApmDataDumper* data_dumper) : data_dumper_(data_dumper), fft_(), optimization_(optimization), num_render_channels_(num_render_channels), max_size_partitions_(max_size_partitions), size_change_duration_blocks_( static_cast(size_change_duration_blocks)), current_size_partitions_(initial_size_partitions), target_size_partitions_(initial_size_partitions), old_target_size_partitions_(initial_size_partitions), H_(max_size_partitions_, std::vector(num_render_channels_)) { RTC_DCHECK(data_dumper_); RTC_DCHECK_GE(max_size_partitions, initial_size_partitions); RTC_DCHECK_LT(0, size_change_duration_blocks_); one_by_size_change_duration_blocks_ = 1.f / size_change_duration_blocks_; ZeroFilter(0, max_size_partitions_, &H_); SetSizePartitions(current_size_partitions_, true); } AdaptiveFirFilter::~AdaptiveFirFilter() = default; void AdaptiveFirFilter::HandleEchoPathChange() { // TODO(peah): Check the value and purpose of the code below. ZeroFilter(current_size_partitions_, max_size_partitions_, &H_); } void AdaptiveFirFilter::SetSizePartitions(size_t size, bool immediate_effect) { RTC_DCHECK_EQ(max_size_partitions_, H_.capacity()); RTC_DCHECK_LE(size, max_size_partitions_); target_size_partitions_ = std::min(max_size_partitions_, size); if (immediate_effect) { size_t old_size_partitions_ = current_size_partitions_; current_size_partitions_ = old_target_size_partitions_ = target_size_partitions_; ZeroFilter(old_size_partitions_, current_size_partitions_, &H_); partition_to_constrain_ = std::min(partition_to_constrain_, current_size_partitions_ - 1); size_change_counter_ = 0; } else { size_change_counter_ = size_change_duration_blocks_; } } void AdaptiveFirFilter::UpdateSize() { RTC_DCHECK_GE(size_change_duration_blocks_, size_change_counter_); size_t old_size_partitions_ = current_size_partitions_; if (size_change_counter_ > 0) { --size_change_counter_; auto average = [](float from, float to, float from_weight) { return from * from_weight + to * (1.f - from_weight); }; float change_factor = size_change_counter_ * one_by_size_change_duration_blocks_; current_size_partitions_ = average(old_target_size_partitions_, target_size_partitions_, change_factor); partition_to_constrain_ = std::min(partition_to_constrain_, current_size_partitions_ - 1); } else { current_size_partitions_ = old_target_size_partitions_ = target_size_partitions_; } ZeroFilter(old_size_partitions_, current_size_partitions_, &H_); RTC_DCHECK_LE(0, size_change_counter_); } void AdaptiveFirFilter::Filter(const RenderBuffer& render_buffer, FftData* S) const { RTC_DCHECK(S); switch (optimization_) { #if defined(WEBRTC_ARCH_X86_FAMILY) case Aec3Optimization::kSse2: aec3::ApplyFilter_Sse2(render_buffer, current_size_partitions_, H_, S); break; case Aec3Optimization::kAvx2: aec3::ApplyFilter_Avx2(render_buffer, current_size_partitions_, H_, S); break; #endif #if defined(WEBRTC_HAS_NEON) case Aec3Optimization::kNeon: aec3::ApplyFilter_Neon(render_buffer, current_size_partitions_, H_, S); break; #endif default: aec3::ApplyFilter(render_buffer, current_size_partitions_, H_, S); } } void AdaptiveFirFilter::Adapt(const RenderBuffer& render_buffer, const FftData& G) { // Adapt the filter and update the filter size. AdaptAndUpdateSize(render_buffer, G); // Constrain the filter partitions in a cyclic manner. Constrain(); } void AdaptiveFirFilter::Adapt(const RenderBuffer& render_buffer, const FftData& G, std::vector* impulse_response) { // Adapt the filter and update the filter size. AdaptAndUpdateSize(render_buffer, G); // Constrain the filter partitions in a cyclic manner. ConstrainAndUpdateImpulseResponse(impulse_response); } void AdaptiveFirFilter::ComputeFrequencyResponse( std::vector>* H2) const { RTC_DCHECK_GE(max_size_partitions_, H2->capacity()); H2->resize(current_size_partitions_); switch (optimization_) { #if defined(WEBRTC_ARCH_X86_FAMILY) case Aec3Optimization::kSse2: aec3::ComputeFrequencyResponse_Sse2(current_size_partitions_, H_, H2); break; case Aec3Optimization::kAvx2: aec3::ComputeFrequencyResponse_Avx2(current_size_partitions_, H_, H2); break; #endif #if defined(WEBRTC_HAS_NEON) case Aec3Optimization::kNeon: aec3::ComputeFrequencyResponse_Neon(current_size_partitions_, H_, H2); break; #endif default: aec3::ComputeFrequencyResponse(current_size_partitions_, H_, H2); } } void AdaptiveFirFilter::AdaptAndUpdateSize(const RenderBuffer& render_buffer, const FftData& G) { // Update the filter size if needed. UpdateSize(); // Adapt the filter. switch (optimization_) { #if defined(WEBRTC_ARCH_X86_FAMILY) case Aec3Optimization::kSse2: aec3::AdaptPartitions_Sse2(render_buffer, G, current_size_partitions_, &H_); break; case Aec3Optimization::kAvx2: aec3::AdaptPartitions_Avx2(render_buffer, G, current_size_partitions_, &H_); break; #endif #if defined(WEBRTC_HAS_NEON) case Aec3Optimization::kNeon: aec3::AdaptPartitions_Neon(render_buffer, G, current_size_partitions_, &H_); break; #endif default: aec3::AdaptPartitions(render_buffer, G, current_size_partitions_, &H_); } } // Constrains the partition of the frequency domain filter to be limited in // time via setting the relevant time-domain coefficients to zero and updates // the corresponding values in an externally stored impulse response estimate. void AdaptiveFirFilter::ConstrainAndUpdateImpulseResponse( std::vector* impulse_response) { RTC_DCHECK_EQ(GetTimeDomainLength(max_size_partitions_), impulse_response->capacity()); impulse_response->resize(GetTimeDomainLength(current_size_partitions_)); std::array h; impulse_response->resize(GetTimeDomainLength(current_size_partitions_)); std::fill( impulse_response->begin() + partition_to_constrain_ * kFftLengthBy2, impulse_response->begin() + (partition_to_constrain_ + 1) * kFftLengthBy2, 0.f); for (size_t ch = 0; ch < num_render_channels_; ++ch) { fft_.Ifft(H_[partition_to_constrain_][ch], &h); static constexpr float kScale = 1.0f / kFftLengthBy2; std::for_each(h.begin(), h.begin() + kFftLengthBy2, [](float& a) { a *= kScale; }); std::fill(h.begin() + kFftLengthBy2, h.end(), 0.f); if (ch == 0) { std::copy( h.begin(), h.begin() + kFftLengthBy2, impulse_response->begin() + partition_to_constrain_ * kFftLengthBy2); } else { for (size_t k = 0, j = partition_to_constrain_ * kFftLengthBy2; k < kFftLengthBy2; ++k, ++j) { if (fabsf((*impulse_response)[j]) < fabsf(h[k])) { (*impulse_response)[j] = h[k]; } } } fft_.Fft(&h, &H_[partition_to_constrain_][ch]); } partition_to_constrain_ = partition_to_constrain_ < (current_size_partitions_ - 1) ? partition_to_constrain_ + 1 : 0; } // Constrains the a partiton of the frequency domain filter to be limited in // time via setting the relevant time-domain coefficients to zero. void AdaptiveFirFilter::Constrain() { std::array h; for (size_t ch = 0; ch < num_render_channels_; ++ch) { fft_.Ifft(H_[partition_to_constrain_][ch], &h); static constexpr float kScale = 1.0f / kFftLengthBy2; std::for_each(h.begin(), h.begin() + kFftLengthBy2, [](float& a) { a *= kScale; }); std::fill(h.begin() + kFftLengthBy2, h.end(), 0.f); fft_.Fft(&h, &H_[partition_to_constrain_][ch]); } partition_to_constrain_ = partition_to_constrain_ < (current_size_partitions_ - 1) ? partition_to_constrain_ + 1 : 0; } void AdaptiveFirFilter::ScaleFilter(float factor) { for (auto& H_p : H_) { for (auto& H_p_ch : H_p) { for (auto& re : H_p_ch.re) { re *= factor; } for (auto& im : H_p_ch.im) { im *= factor; } } } } // Set the filter coefficients. void AdaptiveFirFilter::SetFilter(size_t num_partitions, const std::vector>& H) { const size_t min_num_partitions = std::min(current_size_partitions_, num_partitions); for (size_t p = 0; p < min_num_partitions; ++p) { RTC_DCHECK_EQ(H_[p].size(), H[p].size()); RTC_DCHECK_EQ(num_render_channels_, H_[p].size()); for (size_t ch = 0; ch < num_render_channels_; ++ch) { std::copy(H[p][ch].re.begin(), H[p][ch].re.end(), H_[p][ch].re.begin()); std::copy(H[p][ch].im.begin(), H[p][ch].im.end(), H_[p][ch].im.begin()); } } } } // namespace webrtc