/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserve. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ #pragma once #include #include "paddle/fluid/operators/math/detail/activation_functions.h" #include "paddle/fluid/operators/math/gru_compute.h" namespace paddle { namespace operators { namespace math { namespace detail { #ifndef __NVCC__ template void hl_naive_gru_forward_reset_output(OpResetOutput op_reset_output, T *gate_value, T *reset_output_value, T *prev_output_value, int frame_size, ActivationType active_gate) { T r_value_update_gate; T r_value_reset_gate; T r_value_reset_output; T r_prev_out = 0; T *update_gate = gate_value; T *reset_gate = gate_value + frame_size; for (int i = 0; i < frame_size; i++) { r_value_update_gate = update_gate[i]; r_value_reset_gate = reset_gate[i]; if (prev_output_value) { r_prev_out = prev_output_value[i]; } op_reset_output(r_value_update_gate, r_value_reset_gate, r_prev_out, r_value_reset_output, active_gate); update_gate[i] = r_value_update_gate; reset_gate[i] = r_value_reset_gate; reset_output_value[i] = r_value_reset_output; } } template void hl_naive_gru_forward_final_output(OpFinalOutput op_final_output, T *gate_value, T *prev_output_value, T *output_value, int frame_size, ActivationType active_node) { T r_value_update_gate; T r_value_frame_state; T r_prev_out = 0; T r_output; T *update_gate = gate_value; T *frame_state = gate_value + frame_size * 2; for (int i = 0; i < frame_size; i++) { r_value_update_gate = update_gate[i]; r_value_frame_state = frame_state[i]; if (prev_output_value) { r_prev_out = prev_output_value[i]; } op_final_output(r_value_update_gate, r_value_frame_state, r_prev_out, r_output, active_node); frame_state[i] = r_value_frame_state; output_value[i] = r_output; } } template void hl_avx_gru_forward_reset_output(OpResetOutput op_reset_output, T *gate_value, T *reset_output_value, T *prev_output_value, int frame_size, ActivationType active_gate) { #ifdef __AVX__ __m256 r_value_update_gate; __m256 r_value_reset_gate; __m256 r_value_reset_output; __m256 r_prev_out = _mm256_set1_ps(0.0f); __m256 *update_gate = (__m256 *)gate_value; __m256 *reset_gate = (__m256 *)(gate_value + frame_size); for (int i = 0; i < frame_size / 8; i++) { r_value_update_gate = update_gate[i]; r_value_reset_gate = reset_gate[i]; if (prev_output_value) { r_prev_out = ((__m256 *)prev_output_value)[i]; } op_reset_output(r_value_update_gate, r_value_reset_gate, r_prev_out, r_value_reset_output, active_gate); update_gate[i] = r_value_update_gate; reset_gate[i] = r_value_reset_gate; ((__m256 *)reset_output_value)[i] = r_value_reset_output; } #endif } template void hl_avx_gru_forward_final_output(OpFinalOutput op_final_output, T *gate_value, T *prev_output_value, T *output_value, int frame_size, ActivationType active_node) { #ifdef __AVX__ __m256 r_value_update_gate; __m256 r_value_frame_state; __m256 r_prev_out = _mm256_set1_ps(0.0f); __m256 r_output; __m256 *update_gate = (__m256 *)gate_value; __m256 *frame_state = (__m256 *)(gate_value + frame_size * 2); for (int i = 0; i < frame_size / 8; i++) { r_value_update_gate = update_gate[i]; r_value_frame_state = frame_state[i]; if (prev_output_value) { r_prev_out = ((__m256 *)prev_output_value)[i]; } op_final_output(r_value_update_gate, r_value_frame_state, r_prev_out, r_output, active_node); frame_state[i] = r_value_frame_state; ((__m256 *)output_value)[i] = r_output; } #endif } template inline void forward_reset_output(OpResetOutput op_reset_output, GRUMetaValue value, int frame_size, int batch_size, ActivationType active_gate) { for (int b = 0; b < batch_size; b++) { if (OpResetOutput::avx && !(frame_size & (8 - 1)) && (sizeof(T) == 4)) { hl_avx_gru_forward_reset_output( op_reset_output, value.gate_value, value.reset_output_value, value.prev_out_value, frame_size, active_gate); } else { hl_naive_gru_forward_reset_output( op_reset_output, value.gate_value, value.reset_output_value, value.prev_out_value, frame_size, active_gate); } value.gate_value += frame_size * 3; value.reset_output_value += frame_size; if (value.prev_out_value) { value.prev_out_value += frame_size; } } } template inline void forward_final_output(OpFinalOutput op_final_output, GRUMetaValue value, int frame_size, int batch_size, ActivationType active_node) { for (int b = 0; b < batch_size; b++) { if (OpFinalOutput::avx && !(frame_size & (8 - 1)) && (sizeof(T) == 4)) { hl_avx_gru_forward_final_output(op_final_output, value.gate_value, value.prev_out_value, value.output_value, frame_size, active_node); } else { hl_naive_gru_forward_final_output( op_final_output, value.gate_value, value.prev_out_value, value.output_value, frame_size, active_node); } value.gate_value += frame_size * 3; value.output_value += frame_size; if (value.prev_out_value) { value.prev_out_value += frame_size; } } } template void hl_naive_gru_backward_state_grad(OpStateGrad op_state_grad, T *gate_value, T *gate_grad, T *prev_out_value, T *prev_out_grad, T *output_grad, int frame_size, ActivationType active_node) { T r_update_gate_value; T r_update_gate_grad; T r_frame_state_value; T r_frame_state_grad; T r_out_grad; T r_prev_out_value = 0; T r_prev_out_grad = 0; T *update_gate_value = gate_value; T *update_gate_grad = gate_grad; T *frame_state_value = gate_value + frame_size * 2; T *frame_state_grad = gate_grad + frame_size * 2; for (int i = 0; i < frame_size; i++) { r_update_gate_value = update_gate_value[i]; r_frame_state_value = frame_state_value[i]; r_out_grad = output_grad[i]; if (prev_out_value) { r_prev_out_value = prev_out_value[i]; } if (prev_out_grad) { r_prev_out_grad = prev_out_grad[i]; } op_state_grad(r_update_gate_value, r_update_gate_grad, r_frame_state_value, r_frame_state_grad, r_prev_out_value, r_prev_out_grad, r_out_grad, active_node); update_gate_grad[i] = r_update_gate_grad; frame_state_grad[i] = r_frame_state_grad; if (prev_out_grad) { prev_out_grad[i] = r_prev_out_grad; } } } template void hl_naive_gru_backward_reset_grad(OpResetGrad op_reset_grad, T *gate_value, T *gate_grad, T *prev_out_value, T *prev_out_grad, T *reset_output_grad, int frame_size, ActivationType active_gate) { T r_update_gate_value; T r_update_gate_grad; T r_reset_gate_value; T r_reset_gate_grad; T r_reset_output_grad = 0; T r_prev_out_value = 0; T r_prev_out_grad = 0; T *update_gate_value = gate_value; T *update_gate_grad = gate_grad; T *reset_gate_value = gate_value + frame_size; T *reset_gate_grad = gate_grad + frame_size; for (int i = 0; i < frame_size; i++) { r_update_gate_value = update_gate_value[i]; r_update_gate_grad = update_gate_grad[i]; r_reset_gate_value = reset_gate_value[i]; if (prev_out_value && prev_out_grad) { r_reset_output_grad = reset_output_grad[i]; } if (prev_out_value) { r_prev_out_value = prev_out_value[i]; } if (prev_out_grad) { r_prev_out_grad = prev_out_grad[i]; } op_reset_grad(r_update_gate_value, r_update_gate_grad, r_reset_gate_value, r_reset_gate_grad, r_prev_out_value, r_prev_out_grad, r_reset_output_grad, active_gate); update_gate_grad[i] = r_update_gate_grad; reset_gate_grad[i] = r_reset_gate_grad; if (prev_out_grad) { prev_out_grad[i] = r_prev_out_grad; } } } template void hl_avx_gru_backward_state_grad(OpStateGrad op_state_grad, T *gate_value, T *gate_grad, T *prev_out_value, T *prev_out_grad, T *output_grad, int frame_size, ActivationType active_node) { #ifdef __AVX__ __m256 r_update_gate_value; __m256 r_update_gate_grad; __m256 r_frame_state_value; __m256 r_frame_state_grad; __m256 r_out_grad; __m256 r_prev_out_value = _mm256_set1_ps(0.0f); __m256 r_prev_out_grad = _mm256_set1_ps(0.0f); __m256 *update_gate_value = (__m256 *)gate_value; __m256 *update_gate_grad = (__m256 *)gate_grad; __m256 *frame_state_value = (__m256 *)(gate_value + frame_size * 2); __m256 *frame_state_grad = (__m256 *)(gate_grad + frame_size * 2); for (int i = 0; i < frame_size / 8; i++) { r_update_gate_value = update_gate_value[i]; r_frame_state_value = frame_state_value[i]; r_out_grad = ((__m256 *)output_grad)[i]; if (prev_out_value) { r_prev_out_value = ((__m256 *)prev_out_value)[i]; } if (prev_out_grad) { r_prev_out_grad = ((__m256 *)prev_out_grad)[i]; } op_state_grad(r_update_gate_value, r_update_gate_grad, r_frame_state_value, r_frame_state_grad, r_prev_out_value, r_prev_out_grad, r_out_grad, active_node); update_gate_grad[i] = r_update_gate_grad; frame_state_grad[i] = r_frame_state_grad; if (prev_out_grad) { ((__m256 *)prev_out_grad)[i] = r_prev_out_grad; } } #endif } template void hl_avx_gru_backward_reset_grad(OpResetGrad op_reset_grad, T *gate_value, T *gate_grad, T *prev_out_value, T *prev_out_grad, T *reset_output_grad, int frame_size, ActivationType active_gate) { #ifdef __AVX__ __m256 r_update_gate_value; __m256 r_update_gate_grad; __m256 r_reset_gate_value; __m256 r_reset_gate_grad; __m256 r_reset_output_grad = _mm256_set1_ps(0.0f); __m256 r_prev_out_value = _mm256_set1_ps(0.0f); __m256 r_prev_out_grad = _mm256_set1_ps(0.0f); __m256 *update_gate_value = (__m256 *)gate_value; __m256 *update_gate_grad = (__m256 *)gate_grad; __m256 *reset_gate_value = (__m256 *)(gate_value + frame_size); __m256 *reset_gate_grad = (__m256 *)(gate_grad + frame_size); for (int i = 0; i < frame_size / 8; i++) { r_update_gate_value = update_gate_value[i]; r_update_gate_grad = update_gate_grad[i]; r_reset_gate_value = reset_gate_value[i]; if (prev_out_value && prev_out_grad) { r_reset_output_grad = ((__m256 *)reset_output_grad)[i]; } if (prev_out_value) { r_prev_out_value = ((__m256 *)prev_out_value)[i]; } if (prev_out_grad) { r_prev_out_grad = ((__m256 *)prev_out_grad)[i]; } op_reset_grad(r_update_gate_value, r_update_gate_grad, r_reset_gate_value, r_reset_gate_grad, r_prev_out_value, r_prev_out_grad, r_reset_output_grad, active_gate); update_gate_grad[i] = r_update_gate_grad; reset_gate_grad[i] = r_reset_gate_grad; if (prev_out_grad) { ((__m256 *)prev_out_grad)[i] = r_prev_out_grad; } } #endif } template inline void backward_state_grad(OpStateGrad op_state_grad, GRUMetaValue value, GRUMetaGrad grad, int frame_size, int batch_size, ActivationType active_node) { for (int b = 0; b < batch_size; b++) { if (OpStateGrad::avx && !(frame_size & (8 - 1)) && (sizeof(T) == 4)) { hl_avx_gru_backward_state_grad( op_state_grad, value.gate_value, grad.gate_grad, value.prev_out_value, grad.prev_out_grad, grad.output_grad, frame_size, active_node); } else { hl_naive_gru_backward_state_grad( op_state_grad, value.gate_value, grad.gate_grad, value.prev_out_value, grad.prev_out_grad, grad.output_grad, frame_size, active_node); } value.gate_value += frame_size * 3; if (value.prev_out_value) { value.prev_out_value += frame_size; } grad.gate_grad += frame_size * 3; grad.output_grad += frame_size; if (grad.prev_out_grad) { grad.prev_out_grad += frame_size; } } } template inline void backward_reset_grad(OpResetGrad op_reset_grad, GRUMetaValue value, GRUMetaGrad grad, int frame_size, int batch_size, ActivationType active_gate) { for (int b = 0; b < batch_size; b++) { if (OpResetGrad::avx && !(frame_size & (8 - 1)) && (sizeof(T) == 4)) { hl_avx_gru_backward_reset_grad( op_reset_grad, value.gate_value, grad.gate_grad, value.prev_out_value, grad.prev_out_grad, grad.reset_output_grad, frame_size, active_gate); } else { hl_naive_gru_backward_reset_grad( op_reset_grad, value.gate_value, grad.gate_grad, value.prev_out_value, grad.prev_out_grad, grad.reset_output_grad, frame_size, active_gate); } value.gate_value += frame_size * 3; if (value.prev_out_value) { value.prev_out_value += frame_size; } grad.gate_grad += frame_size * 3; grad.reset_output_grad += frame_size; if (grad.prev_out_grad) { grad.prev_out_grad += frame_size; } } } #endif } // namespace detail } // namespace math } // namespace operators } // namespace paddle