/* * Copyright (c) 2020, Alliance for Open Media. All rights reserved. * * This source code is subject to the terms of the BSD 2 Clause License and * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License * was not distributed with this source code in the LICENSE file, you can * obtain it at www.aomedia.org/license/software. If the Alliance for Open * Media Patent License 1.0 was not distributed with this source code in the * PATENTS file, you can obtain it at www.aomedia.org/license/patent. */ #include #include #include #include "aom_dsp/aom_dsp_common.h" #include "av1/common/av1_common_int.h" #include "av1/encoder/cnn.h" // This mask rearranges source pixels in the order shown below. // shuffle_src_layer0[0][8]: applied on source pixels 0 to 7. // shuffle_src_layer0[1][8]: applied on source pixels 7 to 14. // This shuffling is needed to process 3 5x5 blocks which need // source pixels in the following order. // 1st 5x5 block: source pixels needed are 0 to 4, // 2nd 5x5 block: source pixels needed are 4 to 8, // 3rd 5x5 block: source pixels needed are 8 to 12. // Source pixels are loaded like mentioned below. // load_src0 : 0, 1, 2, 3, 4, 5, 6, 7 // load_src1 : 7, 8, 9, 10, 11, 12, 13, 14 // After applying masks, source bytes will be in the order: // load_src0 : 0, 1, 2, 3, 4, 4, 5, 6 // consists 5 pixels needed for 1st 5x5 block and // first 3 pixels needed for 2nd 5x5 block. // load_src1 : 7, 8, 8, 9, 10, 11, 12, x // consists last 2 pixels needed for 2nd 5x5 block and // 5 pixels needed for 3rd 5x5 block. DECLARE_ALIGNED(32, static const uint32_t, shuffle_src_layer0[2][8]) = { { 0, 1, 2, 3, 4, 4, 5, 6 }, { 0, 1, 1, 2, 3, 4, 5, 0 } }; // This mask rearrange the weights to match shuffled source pixels order. DECLARE_ALIGNED(32, static const uint32_t, shuffle_weight_layer0[2][8]) = { { 0, 1, 2, 3, 4, 0, 1, 2 }, { 3, 4, 0, 1, 2, 3, 4, 0 } }; // Shuffle mask used to rearrange weights corresponding to layer 1 and layer 2. // For layer 1 and layer 2, convolution happens at 2x2 as filter_width and // filter_height are equal to 2. So rearranging the weights in the // order shown below to match source pixels. Basically this mask replicates // the weights across the width of 2. DECLARE_ALIGNED(32, static const uint32_t, shuffle_weight_layer_1_and_2[2][8]) = { { 0, 1, 0, 1, 0, 1, 0, 1 }, { 2, 3, 2, 3, 2, 3, 2, 3 } }; // After the stages of multiplication and accumulation, the output values // in the register will be jumbled. In order to store register into // output buffer in a proper way, the following mask is applied on output // register. DECLARE_ALIGNED(32, static const uint32_t, shuffle_output_layer_1_and_2[8]) = { 0, 1, 4, 5, 2, 3, 6, 7 }; // Load weights needed for layer 0 (for 5x5 block processing), // and fill the registers appropriately to match source pixel mapping. static inline void prepare_weights_for_5x5_convolve( const float *layer_config_weights, int off, float weight[5][8], const int cstep, __m256 *shuffle_weight, const __m256i weight_mask_0, const __m256i weight_mask_1) { for (int row = 0; row < 5; ++row) { for (int col = 0; col < 5; ++col) { weight[row][col] = layer_config_weights[off]; off += cstep; } } shuffle_weight[0] = _mm256_loadu_ps(weight[0]); shuffle_weight[1] = _mm256_loadu_ps(weight[1]); shuffle_weight[2] = _mm256_loadu_ps(weight[2]); shuffle_weight[3] = _mm256_loadu_ps(weight[3]); shuffle_weight[4] = _mm256_loadu_ps(weight[4]); shuffle_weight[0] = _mm256_permutevar8x32_ps(shuffle_weight[0], weight_mask_0); shuffle_weight[1] = _mm256_permutevar8x32_ps(shuffle_weight[1], weight_mask_0); shuffle_weight[2] = _mm256_permutevar8x32_ps(shuffle_weight[2], weight_mask_0); shuffle_weight[3] = _mm256_permutevar8x32_ps(shuffle_weight[3], weight_mask_0); shuffle_weight[4] = _mm256_permutevar8x32_ps(shuffle_weight[4], weight_mask_0); shuffle_weight[5] = _mm256_permutevar8x32_ps(shuffle_weight[0], weight_mask_1); shuffle_weight[6] = _mm256_permutevar8x32_ps(shuffle_weight[1], weight_mask_1); shuffle_weight[7] = _mm256_permutevar8x32_ps(shuffle_weight[2], weight_mask_1); shuffle_weight[8] = _mm256_permutevar8x32_ps(shuffle_weight[3], weight_mask_1); shuffle_weight[9] = _mm256_permutevar8x32_ps(shuffle_weight[4], weight_mask_1); } // For each row, loads source pixels 0 to 7(load_src_0), 7 to 14(load_src_1) and // arranges them appropriately to process 3 blocks. #define PERFORM_CONVOLVE_FOR_3_5X5_BLOCKS() \ do { \ for (int row = 0; row < 5; row++) { \ load_src_0 = _mm256_loadu_ps(input_ptr); \ load_src_1 = _mm256_loadu_ps(input_ptr + 7); \ load_src_0 = _mm256_permutevar8x32_ps(load_src_0, block0_1); \ load_src_1 = _mm256_permutevar8x32_ps(load_src_1, block1_2); \ load_src_0 = _mm256_mul_ps(load_src_0, shuffle_weight[0 + row]); \ load_src_1 = _mm256_mul_ps(load_src_1, shuffle_weight[5 + row]); \ accum_src_0 = _mm256_add_ps(load_src_0, accum_src_0); \ accum_src_1 = _mm256_add_ps(load_src_1, accum_src_1); \ input_ptr += in_stride; \ } \ } while (0) // Load masks needed for shuffling of output and weights. static inline void load_shuffle_masks_for_2x2_convolve(__m256i *output_mask, __m256i *weight_mask) { // Load shuffle buffer needed to sort the output. *output_mask = _mm256_load_si256((const __m256i *)shuffle_output_layer_1_and_2); // Load shuffle buffers needed for weight. weight_mask[0] = _mm256_load_si256((const __m256i *)shuffle_weight_layer_1_and_2[0]); weight_mask[1] = _mm256_load_si256((const __m256i *)shuffle_weight_layer_1_and_2[1]); } // Load weights needed for layer 1 and 2 (for 2x2 block processing), // and fill the registers appropriately to match source pixel mapping. static inline void prepare_weights_for_2x2_convolve( const float *layer_config_weights, int off, const int cstep, __m256 *shuffle_weight, __m256i *weight_mask) { // Weights needed for 2x2 block. float weight[4] = { 0 }; for (int i = 0; i < 4; ++i) { weight[i] = layer_config_weights[off]; off += cstep; } const __m256 weight_vec = _mm256_castps128_ps256(_mm_loadu_ps(weight)); shuffle_weight[0] = _mm256_permutevar8x32_ps(weight_vec, weight_mask[0]); shuffle_weight[1] = _mm256_permutevar8x32_ps(weight_vec, weight_mask[1]); } // Do convolution of one 5x5 block. #define PERFORM_CONVOLVE_FOR_1_5X5_BLOCK(w, accum0, in_stride) \ do { \ __m128 load_src[5]; \ load_src[0] = _mm_loadu_ps(input_ptr); \ last_column_sum += input_ptr[4] * weight[0][4]; \ input_ptr += in_stride; \ load_src[1] = _mm_loadu_ps(input_ptr); \ last_column_sum += input_ptr[4] * weight[1][4]; \ input_ptr += in_stride; \ load_src[2] = _mm_loadu_ps(input_ptr); \ last_column_sum += input_ptr[4] * weight[2][4]; \ input_ptr += in_stride; \ load_src[3] = _mm_loadu_ps(input_ptr); \ last_column_sum += input_ptr[4] * weight[3][4]; \ input_ptr += in_stride; \ load_src[4] = _mm_loadu_ps(input_ptr); \ last_column_sum += input_ptr[4] * weight[4][4]; \ \ load_src[0] = _mm_mul_ps(load_src[0], _mm256_castps256_ps128(w[0])); \ load_src[1] = _mm_mul_ps(load_src[1], _mm256_castps256_ps128(w[1])); \ load_src[2] = _mm_mul_ps(load_src[2], _mm256_castps256_ps128(w[2])); \ load_src[3] = _mm_mul_ps(load_src[3], _mm256_castps256_ps128(w[3])); \ load_src[4] = _mm_mul_ps(load_src[4], _mm256_castps256_ps128(w[4])); \ \ accum0 = _mm_add_ps(load_src[0], accum0); \ load_src[1] = _mm_add_ps(load_src[1], load_src[2]); \ load_src[3] = _mm_add_ps(load_src[3], load_src[4]); \ load_src[1] = _mm_add_ps(load_src[1], load_src[3]); \ accum0 = _mm_add_ps(accum0, load_src[1]); \ } while (0) // Do convolution on 8 horizontal 2x2 blocks. static inline void perform_convolve_for_8h_2x2_blocks( const float *input_ptr, int in_stride, __m256 *weight, __m256 *out_accum, __m256i shuffle_output_mask) { __m256 load_src[4]; // Load input into source registers. load_src[0] = _mm256_loadu_ps(input_ptr); load_src[1] = _mm256_loadu_ps(input_ptr + 8); load_src[2] = _mm256_loadu_ps(input_ptr + in_stride); load_src[3] = _mm256_loadu_ps(input_ptr + in_stride + 8); // Multiply the loaded input with corresponding weights. load_src[0] = _mm256_mul_ps(load_src[0], weight[0]); load_src[1] = _mm256_mul_ps(load_src[1], weight[0]); load_src[2] = _mm256_mul_ps(load_src[2], weight[1]); load_src[3] = _mm256_mul_ps(load_src[3], weight[1]); // Accumulate across 2x2 blocks. load_src[0] = _mm256_add_ps(load_src[0], load_src[2]); load_src[1] = _mm256_add_ps(load_src[1], load_src[3]); load_src[0] = _mm256_hadd_ps(load_src[0], load_src[1]); // Sort the output in order to store into output buffer. load_src[0] = _mm256_permutevar8x32_ps(load_src[0], shuffle_output_mask); *out_accum = _mm256_add_ps(*out_accum, load_src[0]); } // Do convolution on 8 (4 horizontal x 2 vertical) 2x2 blocks. static inline void perform_convolve_for_4hx2v_2x2_blocks( const float *input_ptr, int in_stride, __m256 *weight, __m256 *out_accum, __m256i shuffle_output_mask) { __m256 load_src[4]; // Load input into source registers. load_src[0] = _mm256_loadu_ps(input_ptr); load_src[1] = _mm256_loadu_ps(input_ptr + in_stride); load_src[2] = _mm256_loadu_ps(input_ptr + (in_stride * 2)); load_src[3] = _mm256_loadu_ps(input_ptr + (in_stride * 3)); // Multiply the loaded input with corresponding weights. load_src[0] = _mm256_mul_ps(load_src[0], weight[0]); load_src[1] = _mm256_mul_ps(load_src[1], weight[1]); load_src[2] = _mm256_mul_ps(load_src[2], weight[0]); load_src[3] = _mm256_mul_ps(load_src[3], weight[1]); // Accumulate across 2x2 blocks. load_src[0] = _mm256_add_ps(load_src[0], load_src[1]); load_src[2] = _mm256_add_ps(load_src[2], load_src[3]); load_src[0] = _mm256_hadd_ps(load_src[0], load_src[2]); // Sort the output in order to store into output buffer. load_src[0] = _mm256_permutevar8x32_ps(load_src[0], shuffle_output_mask); *out_accum = _mm256_add_ps(*out_accum, load_src[0]); } // AVX2 variant of av1_cnn_convolve_no_maxpool_padding_valid_c(), when // filter_width and filter_height are equal to 5. // CNN convolve parsing is based on av1_intra_mode_cnn_partition_cnn_config. // Based on the configuration set for each layer, the current encoder // always chooses the case of no_maxpool_padding_valid. // And also for layer 0 convolution happens at 5x5 level as the // filter_width and filter_height are set as 5. static void cnn_convolve_no_maxpool_padding_valid_5x5_avx2( const float **input, int in_width, int in_height, int in_stride, const CNN_LAYER_CONFIG *const layer_config, float **output, int out_stride, int start_idx, const int cstep, const int channel_step) { const int kFilterWidth = 5; const int kFilterHeight = 5; const int kSkipWidth = 4; const int kSkipHeight = 4; assert(layer_config->filter_width == kFilterWidth && layer_config->filter_height == kFilterHeight); assert(layer_config->skip_width == kSkipWidth && layer_config->skip_height == kSkipHeight); // Load shuffle buffers needed for source. const __m256i block0_1 = _mm256_load_si256((const __m256i *)shuffle_src_layer0[0]); const __m256i block1_2 = _mm256_load_si256((const __m256i *)shuffle_src_layer0[1]); // Load shuffle buffers needed for weight. const __m256i weight_mask_0 = _mm256_load_si256((const __m256i *)shuffle_weight_layer0[0]); const __m256i weight_mask_1 = _mm256_load_si256((const __m256i *)shuffle_weight_layer0[1]); // Width needs to be moved to go to next iteration of processing 3 5x5 blocks. const int kSkipWidthForNextIter = kSkipWidth * 3; // Minimum width required to process 3 5x5 blocks at a time. // min width (for processing 3 5x5 block) = 2*skip_width + filter_width // Here, skip_width specifies how much width we should move while processing // next block convolution and filter_width specifies for how many pixels // filter needs to be applied. const int kMinWidthFor3_5x5Blocks = (kSkipWidth * 2) + kFilterWidth; for (int i = start_idx; i < layer_config->out_channels; i += channel_step) { const float out_ch_bias = layer_config->bias[i]; for (int k = 0; k < layer_config->in_channels; ++k) { __m256 shuffle_weight[10]; // Weights needed are 5x5, for SIMD purpose made this array as 5x8. float weight[5][8] = { { 0 } }; int off = k * layer_config->out_channels + i; // In layer 0, the convolution process happens at 5x5. // The weights needed for 5x5 block are same across the in-channels, // which is why the load of weights happens once for each in-channel. prepare_weights_for_5x5_convolve(layer_config->weights, off, weight, cstep, shuffle_weight, weight_mask_0, weight_mask_1); for (int h = 0, u = 0; h < in_height - kFilterHeight + 1; h += kSkipHeight, ++u) { const int out_h = u * out_stride; int v = 0; int w = 0; int rem_width = in_width; // Processing 3 5x5 blocks at a time, if sufficient width is present. while (rem_width >= kMinWidthFor3_5x5Blocks) { __m256 load_src_0, load_src_1; __m256 accum_src_0 = _mm256_setzero_ps(); __m256 accum_src_1 = _mm256_setzero_ps(); const float *input_ptr = &input[k][h * in_stride + w]; PERFORM_CONVOLVE_FOR_3_5X5_BLOCKS(); // Accumulate across column. __m256 accum = _mm256_hadd_ps(accum_src_0, accum_src_1); __m128 tmp_reg_0 = _mm256_extractf128_ps(accum_src_0, 1); __m128 tmp_reg_1 = _mm256_extractf128_ps(accum_src_1, 1); __m128 accum_l = _mm256_castps256_ps128(accum); __m128 accum_h = _mm256_extractf128_ps(accum, 1); __m128 tmp_reg_2 = _mm_add_ps(accum_l, tmp_reg_0); __m128 tmp_reg_3 = _mm_add_ps(tmp_reg_0, accum_h); __m128 tmp_reg_4 = _mm_add_ps(tmp_reg_1, accum_h); // 1st 5x5 block output. output[i][out_h + v] = out_ch_bias + _mm_cvtss_f32(tmp_reg_2) + _mm_cvtss_f32(_mm_shuffle_ps(accum_l, accum_l, 1)); // 2nd 5x5 block output. output[i][out_h + v + 1] = out_ch_bias + _mm_cvtss_f32(_mm_shuffle_ps(tmp_reg_3, tmp_reg_3, 1)) + _mm_cvtss_f32(_mm_shuffle_ps(accum_l, accum_l, 2)); // 3rd 5x5 block output. output[i][out_h + v + 2] = out_ch_bias + _mm_cvtss_f32(_mm_shuffle_ps(tmp_reg_4, tmp_reg_4, 2)) + _mm_cvtss_f32(_mm_shuffle_ps(accum_l, accum_l, 3)); v += 3; w += kSkipWidthForNextIter; rem_width -= kSkipWidthForNextIter; } // Process remaining blocks as single 5x5 block at a time. while (rem_width >= kFilterWidth) { float last_column_sum = 0; __m128 accum = _mm_setzero_ps(); const float *input_ptr = &input[k][h * in_stride + w]; PERFORM_CONVOLVE_FOR_1_5X5_BLOCK(shuffle_weight, accum, in_stride); // Accumulate across column. accum = _mm_hadd_ps(accum, accum); output[i][out_h + v] = out_ch_bias + last_column_sum + _mm_cvtss_f32(accum) + _mm_cvtss_f32(_mm_shuffle_ps(accum, accum, 1)); v += 1; w += kSkipWidth; rem_width -= kSkipWidth; } } } } } // AVX2 implementation for layer 1. static inline void cnn_convolve_no_maxpool_padding_valid_layer1_avx2( const float **input, int in_stride, const CNN_LAYER_CONFIG *const layer_config, float **output, int out_stride, int start_idx, const int cstep, const int channel_step) { __m256i weight_mask[2]; __m256i shuffle_output_mask; load_shuffle_masks_for_2x2_convolve(&shuffle_output_mask, weight_mask); const int kInHeight = 16; const int kFilterHeight = 2; const int kSkipHeight = 2; for (int i = start_idx; i < layer_config->out_channels; i += channel_step) { __m256 bias_reg = _mm256_set1_ps(layer_config->bias[i]); // out_accum registers are used to store the 2x2 convolve outputs // (calculated over input block size), which are accumulated across the // in_channels. As per the design, each iteration of for loop processes 8 // (horizontal) 2x2 blocks and stores in corresponding out_accum register // (as input size is 16x16, a total of 64 2x2 blocks are present and 8 // out_accum registers are enough to store the outputs). // Hence for loops corresponding to 'j' and 'h', below, run over the number // of out_accum registers. __m256 out_accum[8]; for (int j = 0; j < 8; ++j) out_accum[j] = bias_reg; for (int k = 0; k < layer_config->in_channels; ++k) { __m256 shuffle_weight[2]; int off = k * layer_config->out_channels + i; // In layer 1, the convolution process happens at 2x2. // The weights needed for 2x2 block are same across the in-channels, // which is why the load of weights happens once for each in-channel. prepare_weights_for_2x2_convolve(layer_config->weights, off, cstep, shuffle_weight, weight_mask); for (int h = 0, u = 0; h < kInHeight - kFilterHeight + 1; h += kSkipHeight, ++u) { const float *input_ptr = &input[k][h * in_stride]; perform_convolve_for_8h_2x2_blocks(input_ptr, in_stride, shuffle_weight, &out_accum[u], shuffle_output_mask); } } // Store output of layer 1. for (int j = 0; j < 8; ++j) { _mm256_storeu_ps(&output[i][j * out_stride], out_accum[j]); } } } // AVX2 implementation for layer 2. static inline void cnn_convolve_no_maxpool_padding_valid_layer2_avx2( const float **input, int in_stride, const CNN_LAYER_CONFIG *const layer_config, float **output, int out_stride, int start_idx, const int cstep, const int channel_step) { __m256i weight_mask[2]; __m256i shuffle_output_mask; load_shuffle_masks_for_2x2_convolve(&shuffle_output_mask, weight_mask); const int kInHeight = 8; const int kFilterHeight = 2; const int kSkipHeight = 2; for (int i = start_idx; i < layer_config->out_channels; i += channel_step) { __m256 bias_reg = _mm256_set1_ps(layer_config->bias[i]); // out_accum registers are used to store the 2x2 convolve outputs // (calculated over input block size), which are accumulated across the // in_channels. As per the design, each iteration of for loop processes 8 // (4 horizontal x 2 vertical) 2x2 blocks and stores in corresponding // out_accum register (as input size is 8x8, a total of 16 2x2 blocks are // present and 2 out_accum registers are enough to store the outputs). // Hence for loops corresponding to 'j' and 'h', below, run over the number // of out_accum registers. __m256 out_accum[2]; // Height needs to be moved to go to next iteration of processing // while processing 2 2x2 blocks vertically. const int kSkipHeightForNextIter = kSkipHeight * 2; for (int j = 0; j < 2; ++j) out_accum[j] = bias_reg; for (int k = 0; k < layer_config->in_channels; ++k) { __m256 shuffle_weight[2]; int off = k * layer_config->out_channels + i; // In layer 2, the convolution process happens at 2x2. // The weights needed for 2x2 block are same across the in-channels, // which is why the load of weights happens once for each in-channel. prepare_weights_for_2x2_convolve(layer_config->weights, off, cstep, shuffle_weight, weight_mask); for (int h = 0, u = 0; h < kInHeight - kFilterHeight + 1; h += kSkipHeightForNextIter, ++u) { const float *input_ptr = &input[k][h * in_stride]; perform_convolve_for_4hx2v_2x2_blocks(input_ptr, in_stride, shuffle_weight, &out_accum[u], shuffle_output_mask); } } // Store output of layer 2. for (int j = 0; j < 2; ++j) { _mm256_storeu_ps(&output[i][j * out_stride * 2], out_accum[j]); } } } // AVX2 variant of av1_cnn_convolve_no_maxpool_padding_valid_c(), when // filter_width and filter_height are equal to 2. // As per the layer config set by av1_intra_mode_cnn_partition_cnn_config, // the filter_width and filter_height are equal to 2 for layer >= 1. So // convolution happens at 2x2 for layer >= 1. static void cnn_convolve_no_maxpool_padding_valid_2x2_avx2( const float **input, int in_width, int in_height, int in_stride, const CNN_LAYER_CONFIG *const layer_config, float **output, int out_stride, int start_idx, const int cstep, const int channel_step) { assert(layer_config->filter_width == 2 && layer_config->filter_height == 2); assert(layer_config->skip_width == 2 && layer_config->skip_height == 2); if (in_width == 16 && in_height == 16) { // This case of in_width and in_height equal to 16 corresponds to layer 1. // The output size of this layer is 8x8. cnn_convolve_no_maxpool_padding_valid_layer1_avx2( input, in_stride, layer_config, output, out_stride, start_idx, cstep, channel_step); } else if (in_width == 8 && in_height == 8) { // This case of in_width and in_height equal to 8 corresponds to layer 2. // The output size of this layer is 4x4. cnn_convolve_no_maxpool_padding_valid_layer2_avx2( input, in_stride, layer_config, output, out_stride, start_idx, cstep, channel_step); } else { // For layer equal to 3 and 4, the input is of size 4x4 and 2x2 // respectively. Implementing SIMD for these cases might not be optimal, // which is why we call C path for layer >= 3. av1_cnn_convolve_no_maxpool_padding_valid_c( input, in_width, in_height, in_stride, layer_config, output, out_stride, start_idx, cstep, channel_step); } } // AVX2 variant of av1_cnn_convolve_no_maxpool_padding_valid_c(). // As per the current encoder, av1_cnn_convolve function gets called for // block size equal to 64x64. av1_cnn_convolve() uses layer config values // set by av1_intra_mode_cnn_partition_cnn_config. The following are a few // details related to each layer's config parameters. // Layer_Number in_size out_size filter_wd filter_ht skip_wd skip_ht // 0 64x64 16x16 5 5 4 4 // 1 16x16 8x8 2 2 2 2 // 2 8x8 4x4 2 2 2 2 // 3 4x4 2x2 2 2 2 2 // 4 2x2 1x1 2 2 2 2 // Here, // filter_wd = filter_width and filter_ht = filter_height, // skip_wd = skip_width and skip_ht = skip_height. void av1_cnn_convolve_no_maxpool_padding_valid_avx2( const float **input, int in_width, int in_height, int in_stride, const CNN_LAYER_CONFIG *layer_config, float **output, int out_stride, int start_idx, int cstep, int channel_step) { if (layer_config->filter_width == 5 && layer_config->filter_height == 5 && layer_config->skip_width == 4 && layer_config->skip_height == 4) { cnn_convolve_no_maxpool_padding_valid_5x5_avx2( input, in_width, in_height, in_stride, layer_config, output, out_stride, start_idx, cstep, channel_step); } else if (layer_config->filter_width == 2 && layer_config->filter_height == 2 && layer_config->skip_width == 2 && layer_config->skip_height == 2) { cnn_convolve_no_maxpool_padding_valid_2x2_avx2( input, in_width, in_height, in_stride, layer_config, output, out_stride, start_idx, cstep, channel_step); } else { av1_cnn_convolve_no_maxpool_padding_valid_c( input, in_width, in_height, in_stride, layer_config, output, out_stride, start_idx, cstep, channel_step); } }