/* Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved. 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. */ /* conv conv_bn conv_add conv_relu conv_bn_relu conv_add_relu conv_add_bn_relu */ #include "cl_common.h" __kernel void conv_3x3(__private const int global_size_dim0, __private const int global_size_dim1, __private const int global_size_dim2, __read_only image2d_t input_image, __read_only image2d_t filter, #ifdef BIASE __read_only image2d_t bias, #endif #ifdef BATCH_NORM __read_only image2d_t new_scale, __read_only image2d_t new_biase, #endif __write_only image2d_t output_image, __private const int stride, __private const int offset, __private const int input_c, __private const int dilation, __private const int input_width,/* of one block */ __private const int input_height,/* of one block */ __private const int output_width, __private const int output_height) { const int out_c = get_global_id(0); const int out_w = get_global_id(1); const int out_nh = get_global_id(2); if (out_c >= global_size_dim0 || out_w >= global_size_dim1 || out_nh >= global_size_dim2) { return; } int2 stride_xy; stride_xy.x = stride; stride_xy.y = stride; int2 ouput_pos_in_one_block; ouput_pos_in_one_block.x = out_w; ouput_pos_in_one_block.y = out_nh; const sampler_t sampler = CLK_NORMALIZED_COORDS_TRUE | CLK_ADDRESS_CLAMP | CLK_FILTER_NEAREST; int2 in_pos_in_one_block; in_pos_in_one_block.x = ouput_pos_in_one_block.x * stride + offset; in_pos_in_one_block.y = ouput_pos_in_one_block.y * stride + offset; #ifdef BIASE half4 output = read_imageh(bias, sampler, (int2)(out_c, 0)); #else half4 output = 0.0f; #endif half4 input[9]; for (int i = 0; i < input_c; ++i) { int2 pos_in = (int2)(i * input_width + in_pos_in_one_block.x, in_pos_in_one_block.y); input[0] = select(read_imageh(input_image, sampler, (int2)(pos_in.x - dilation, pos_in.y - dilation)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x - dilation < 0 || in_pos_in_one_block.y - dilation < 0 || in_pos_in_one_block.x - dilation >= input_width || in_pos_in_one_block.y - dilation >= input_height) << 15)); input[1] = select(read_imageh(input_image, sampler, (int2)(pos_in.x, pos_in.y - dilation)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x < 0 || in_pos_in_one_block.y - dilation < 0 || in_pos_in_one_block.x >= input_width || in_pos_in_one_block.y - dilation >= input_height) << 15)); input[2] = select(read_imageh(input_image, sampler, (int2)(pos_in.x + dilation, pos_in.y - dilation)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x + dilation < 0 || in_pos_in_one_block.y - dilation < 0 || in_pos_in_one_block.x + dilation >= input_width || in_pos_in_one_block.y - dilation >= input_height) << 15)); input[3] = select(read_imageh(input_image, sampler, (int2)(pos_in.x - dilation, pos_in.y)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x - dilation < 0 || in_pos_in_one_block.y < 0 || in_pos_in_one_block.x - dilation >= input_width || in_pos_in_one_block.y >= input_height) << 15)); input[4] = select(read_imageh(input_image, sampler, (int2)(pos_in.x, pos_in.y)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x < 0 || in_pos_in_one_block.y < 0 || in_pos_in_one_block.x >= input_width || in_pos_in_one_block.y >= input_height) << 15)); input[5] = select(read_imageh(input_image, sampler, (int2)(pos_in.x + dilation, pos_in.y)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x + dilation < 0 || in_pos_in_one_block.y < 0 || in_pos_in_one_block.x + dilation >= input_width || in_pos_in_one_block.y >= input_height) << 15)); input[6] = select(read_imageh(input_image, sampler, (int2)(pos_in.x - dilation, pos_in.y + dilation)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x - dilation < 0 || in_pos_in_one_block.y + dilation < 0 || in_pos_in_one_block.x - dilation >= input_width || in_pos_in_one_block.y + dilation >= input_height) << 15)); input[7] = select(read_imageh(input_image, sampler, (int2)(pos_in.x, pos_in.y + dilation)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x < 0 || in_pos_in_one_block.y + dilation < 0 || in_pos_in_one_block.x >= input_width || in_pos_in_one_block.y + dilation >= input_height) << 15)); input[8] = select(read_imageh(input_image, sampler, (int2)(pos_in.x + dilation, pos_in.y + dilation)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x + dilation < 0 || in_pos_in_one_block.y + dilation < 0 || in_pos_in_one_block.x + dilation >= input_width || in_pos_in_one_block.y + dilation >= input_height) << 15)); for (int j = 0; j < 9; ++j) { int2 pos_of_weight; pos_of_weight.x = i * 3 + j % 3; pos_of_weight.y = out_c * 4 * 3 + 0 * 3 + j / 3; half4 weight_x = read_imageh(filter, sampler, pos_of_weight); output.x += dot(input[j], weight_x); pos_of_weight.y = out_c * 4 * 3 + 1 * 3 + j / 3; half4 weight_y = read_imageh(filter, sampler, pos_of_weight); output.y += dot(input[j], weight_y); pos_of_weight.y = out_c * 4 * 3 + 2 * 3 + j / 3; half4 weight_z = read_imageh(filter, sampler, pos_of_weight); output.z += dot(input[j], weight_z); pos_of_weight.y = out_c * 4 * 3 + 3 * 3 + j / 3; half4 weight_w = read_imageh(filter, sampler, pos_of_weight); output.w += dot(input[j], weight_w); } } #ifdef BATCH_NORM output = output * read_imageh(new_scale, sampler, (int2)(out_c, 0)) + read_imageh(new_biase, sampler, (int2)(out_c, 0)); #endif #ifdef RELU output = activation(output); #endif write_imageh(output_image, (int2)(out_c * global_size_dim1 + out_w, out_nh), output); } __kernel void depth_conv_3x3(__private const int global_size_dim0, __private const int global_size_dim1, __private const int global_size_dim2, __read_only image2d_t input, __read_only image2d_t filter, #ifdef BIASE __read_only image2d_t bias, #endif #ifdef BATCH_NORM __read_only image2d_t new_scale, __read_only image2d_t new_biase, #endif __write_only image2d_t output_image, __private const int stride, __private const int offset, __private const int input_c, __private const int dilation, __private const int input_width,/* of one block */ __private const int input_height, /* of one block */ __private const int output_width, __private const int output_height) { const int out_c = get_global_id(0); const int out_w = get_global_id(1); const int out_nh = get_global_id(2); int2 output_pos = (int2)(out_c * global_size_dim1 + out_w, out_nh); const sampler_t sampler = CLK_NORMALIZED_COORDS_TRUE | CLK_ADDRESS_CLAMP | CLK_FILTER_NEAREST; const int batch_index = out_nh / output_height; const int out_nh_in_one_batch = out_nh % output_height; int2 stride_xy = (int2)(stride, stride); int2 ouput_pos_in_one_block = (int2)(out_w, out_nh_in_one_batch); int2 in_pos_in_one_block = ouput_pos_in_one_block * stride_xy + (int2)(offset, offset); #ifdef BIASE half4 output = read_imageh(bias, sampler, (int2)(out_c, 0)); #else half4 output = 0.0f; #endif const int filter_width = 3; const int filter_height = 3; int2 pos_in_input_block = (int2)(out_c * input_width, batch_index * input_height); int2 pos_in_filter_block = (int2)(out_c * filter_width, batch_index * filter_height); int filter_x = pos_in_filter_block.x ; int filter_y = pos_in_filter_block.y ; half4 inputs[9]; inputs[0] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x - 1, pos_in_input_block.y + in_pos_in_one_block.y - 1)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x - 1 < 0 || in_pos_in_one_block.y - 1 < 0 || in_pos_in_one_block.x - 1 >= input_width || in_pos_in_one_block.y - 1 >= input_height) << 15)); inputs[1] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x, pos_in_input_block.y + in_pos_in_one_block.y - 1)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x < 0 || in_pos_in_one_block.y - 1 < 0 || in_pos_in_one_block.x >= input_width || in_pos_in_one_block.y - 1 >= input_height) << 15)); inputs[2] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x + 1, pos_in_input_block.y + in_pos_in_one_block.y - 1)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x + 1 < 0 || in_pos_in_one_block.y - 1 < 0 || in_pos_in_one_block.x + 1 >= input_width || in_pos_in_one_block.y - 1 >= input_height) << 15)); inputs[3] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x - 1, pos_in_input_block.y + in_pos_in_one_block.y)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x - 1 < 0 || in_pos_in_one_block.y < 0 || in_pos_in_one_block.x - 1 >= input_width || in_pos_in_one_block.y >= input_height) << 15)); /* if (output_pos.x == 112 && output_pos.y == 0) { half4 input1 = inputs[3]; float4 in = (float4)(input1.x, input1.y, input1.z, input1.w); printf(" input4 3 - %v4hlf \n", in); printf(" --- %d ---\n", in_pos_in_one_block.x - 1); } */ inputs[4] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x, pos_in_input_block.y + in_pos_in_one_block.y)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x < 0 || in_pos_in_one_block.y < 0 || in_pos_in_one_block.x >= input_width || in_pos_in_one_block.y >= input_height) << 15)); inputs[5] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x + 1, pos_in_input_block.y + in_pos_in_one_block.y)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x + 1 < 0 || in_pos_in_one_block.y < 0 || in_pos_in_one_block.x + 1 >= input_width || in_pos_in_one_block.y >= input_height) << 15)); inputs[6] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x - 1, pos_in_input_block.y + in_pos_in_one_block.y + 1)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x - 1 < 0 || in_pos_in_one_block.y + 1 < 0 || in_pos_in_one_block.x - 1 >= input_width || in_pos_in_one_block.y + 1 >= input_height) << 15)); inputs[7] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x, pos_in_input_block.y + in_pos_in_one_block.y + 1)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x < 0 || in_pos_in_one_block.y + 1 < 0 || in_pos_in_one_block.x >= input_width || in_pos_in_one_block.y + 1 >= input_height) << 15)); inputs[8] = select(read_imageh(input, sampler, (int2)(pos_in_input_block.x + in_pos_in_one_block.x + 1, pos_in_input_block.y + in_pos_in_one_block.y + 1)), (half4)(0.0f), (ushort4)((in_pos_in_one_block.x + 1 < 0 || in_pos_in_one_block.y + 1 < 0 || in_pos_in_one_block.x + 1 >= input_width || in_pos_in_one_block.y + 1 >= input_height) << 15)); half4 filters[9]; filters[0] = read_imageh(filter, sampler,(int2)(filter_x,filter_y)); filters[1] = read_imageh(filter, sampler,(int2)(filter_x + 1,filter_y)); filters[2] = read_imageh(filter, sampler,(int2)(filter_x + 2,filter_y)); filters[3] = read_imageh(filter, sampler,(int2)(filter_x,filter_y + 1)); filters[4] = read_imageh(filter, sampler,(int2)(filter_x + 1,filter_y + 1)); filters[5] = read_imageh(filter, sampler,(int2)(filter_x + 2,filter_y + 1)); filters[6] = read_imageh(filter, sampler,(int2)(filter_x,filter_y + 2)); filters[7] = read_imageh(filter, sampler,(int2)(filter_x + 1,filter_y + 2)); filters[8] = read_imageh(filter, sampler,(int2)(filter_x + 2,filter_y + 2)); for(int i = 0 ;i < 9 ; i++){ output += inputs[i] * filters[i]; } #ifdef BATCH_NORM output = output * read_imageh(new_scale, sampler, (int2)(out_c, 0)) + read_imageh(new_biase, sampler, (int2)(out_c, 0)); #endif #ifdef RELU output = activation(output); #endif /* if (output_pos.x == 112 && output_pos.y == 0) { for (int i = 0; i < 9; ++i) { half4 input1 = inputs[i]; float4 in = (float4)(input1.x, input1.y, input1.z, input1.w); printf(" input4 %d - %v4hlf \n", i, in); } float4 out = (float4)(output.x, output.y, output.z, output.w); printf(" depth wise output output4 = %v4hlf \n", out); printf(" pos_in_input_block -x %d \n ", pos_in_input_block.x); printf(" pos_in_input_block -y %d \n ", pos_in_input_block.y); printf(" in_pos_in_one_block - x %d \n", in_pos_in_one_block.x); printf(" in_pos_in_one_block - y %d \n", in_pos_in_one_block.y); } */ write_imageh(output_image, output_pos, output); } __kernel void conv_1x1(__private const int global_size_dim0, __private const int global_size_dim1, __private const int global_size_dim2, __read_only image2d_t input_image, __read_only image2d_t filter, #ifdef BIASE __read_only image2d_t bias, #endif #ifdef BATCH_NORM __read_only image2d_t new_scale, __read_only image2d_t new_biase, #endif __write_only image2d_t output_image, __private const int stride, __private const int offset, __private const int input_c, __private const int dilation, __private const int input_width,/* of one block */ __private const int input_height,/* of one block */ __private const int output_width, __private const int output_height) { const int out_c = get_global_id(0); const int out_w = get_global_id(1); const int out_nh = get_global_id(2); const sampler_t sampler = CLK_NORMALIZED_COORDS_TRUE | CLK_ADDRESS_CLAMP | CLK_FILTER_NEAREST; const uint kernelHXW = 1; int2 stride_xy = (int2)(stride, stride); int2 ouput_pos_in_one_block = (int2)(out_w, out_nh); int2 in_pos_in_one_block = ouput_pos_in_one_block * stride_xy + (int2)(offset, offset); #ifdef BIASE half4 output = read_imageh(bias, sampler, (int2)(out_c, 0)); #else half4 output = 0.0f; #endif for (int i = 0; i < input_c; ++i) { int2 pos_in = (int2)(i * input_width + in_pos_in_one_block.x, in_pos_in_one_block.y); half4 input = read_imageh(input_image, sampler, pos_in); half4 weight0 = read_imageh(filter, sampler, (int2)(out_c, i * 4 + 0)); half4 weight1 = read_imageh(filter, sampler, (int2)(out_c, i * 4 + 1)); half4 weight2 = read_imageh(filter, sampler, (int2)(out_c, i * 4 + 2)); half4 weight3 = read_imageh(filter, sampler, (int2)(out_c, i * 4 + 3)); /* output.x = dot(input, weight0); output.y = dot(input, weight1); output.z = dot(input, weight2); output.w = dot(input, weight3); */ output = mad(input.x, weight0, output); output = mad(input.y, weight1, output); output = mad(input.z, weight2, output); output = mad(input.w, weight3, output); } #ifdef BATCH_NORM output = output * read_imageh(new_scale, sampler, (int2)(out_c, 0)) + read_imageh(new_biase, sampler, (int2)(out_c, 0)); #endif #ifdef RELU output = activation(output); #endif int2 output_pos = (int2)(out_c * global_size_dim1 + out_w, out_nh); write_imageh(output_image, output_pos, output); } /* __kernel void conv_1x1_4(__private const int global_size_dim0, __private const int global_size_dim1, __private const int global_size_dim2, __read_only image2d_t input_image, __read_only image2d_t filter, #ifdef BIASE __read_only image2d_t bias, #endif #ifdef BATCH_NORM __read_only image2d_t new_scale, __read_only image2d_t new_biase, #endif __write_only image2d_t output_image, __private const int stride, __private const int offset, __private const int input_c, __private const int dilation, __private const int input_width, __private const int input_height, __private const int output_width, __private const int output_height) { const int out_c = get_global_id(0) * 4; const int out_w = get_global_id(1); const int out_nh = get_global_id(2); const sampler_t sampler = CLK_NORMALIZED_COORDS_TRUE | CLK_ADDRESS_CLAMP | CLK_FILTER_NEAREST; int2 stride_xy = (int2)(stride, stride); int2 ouput_pos_in_one_block = (int2)(out_w, out_nh); int2 in_pos_in_one_block = ouput_pos_in_one_block * stride_xy + (int2)(offset, offset); #ifdef BIASE half4 output0 = read_imageh(bias, sampler, (int2)(out_c, 0)); half4 output1 = read_imageh(bias, sampler, (int2)(out_c + 1, 0)); half4 output2 = read_imageh(bias, sampler, (int2)(out_c + 2, 0)); half4 output3 = read_imageh(bias, sampler, (int2)(out_c + 3, 0)); #else half4 output0 = 0.0f; half4 output1 = 0.0f; half4 output2 = 0.0f; half4 output3 = 0.0f; #endif for (int i = 0; i < input_c; ++i) { int2 pos_in = (int2)(i * input_width + in_pos_in_one_block.x, in_pos_in_one_block.y); half4 input = read_imageh(input_image, sampler, pos_in); half4 weight0_0 = read_imageh(filter, sampler, (int2)(out_c, i * 4 + 0)); half4 weight0_1 = read_imageh(filter, sampler, (int2)(out_c, i * 4 + 1)); half4 weight0_2 = read_imageh(filter, sampler, (int2)(out_c, i * 4 + 2)); half4 weight0_3 = read_imageh(filter, sampler, (int2)(out_c, i * 4 + 3)); output0 = mad(input.x, weight0_0, output0); output0 = mad(input.y, weight0_1, output0); output0 = mad(input.z, weight0_2, output0); output0 = mad(input.w, weight0_3, output0); half4 weight1_0 = read_imageh(filter, sampler, (int2)(out_c + 1, i * 4 + 0)); half4 weight1_1 = read_imageh(filter, sampler, (int2)(out_c + 1, i * 4 + 1)); half4 weight1_2 = read_imageh(filter, sampler, (int2)(out_c + 1, i * 4 + 2)); half4 weight1_3 = read_imageh(filter, sampler, (int2)(out_c + 1, i * 4 + 3)); output1 = mad(input.x, weight1_0, output1); output1 = mad(input.y, weight1_1, output1); output1 = mad(input.z, weight1_2, output1); output1 = mad(input.w, weight1_3, output1); half4 weight2_0 = read_imageh(filter, sampler, (int2)(out_c + 2, i * 4 + 0)); half4 weight2_1 = read_imageh(filter, sampler, (int2)(out_c + 2, i * 4 + 1)); half4 weight2_2 = read_imageh(filter, sampler, (int2)(out_c + 2, i * 4 + 2)); half4 weight2_3 = read_imageh(filter, sampler, (int2)(out_c + 2, i * 4 + 3)); output2 = mad(input.x, weight2_0, output2); output2 = mad(input.y, weight2_1, output2); output2 = mad(input.z, weight2_2, output2); output2 = mad(input.w, weight2_3, output2); half4 weight3_0 = read_imageh(filter, sampler, (int2)(out_c + 3, i * 4 + 0)); half4 weight3_1 = read_imageh(filter, sampler, (int2)(out_c + 3, i * 4 + 1)); half4 weight3_2 = read_imageh(filter, sampler, (int2)(out_c + 3, i * 4 + 2)); half4 weight3_3 = read_imageh(filter, sampler, (int2)(out_c + 3, i * 4 + 3)); output3 = mad(input.x, weight3_0, output3); output3 = mad(input.y, weight3_1, output3); output3 = mad(input.z, weight3_2, output3); output3 = mad(input.w, weight3_3, output3); } #ifdef BATCH_NORM output0 = output0 * read_imageh(new_scale, sampler, (int2)(out_c + 0, 0)) + read_imageh(new_biase, sampler, (int2)(out_c + 0, 0)); output1 = output1 * read_imageh(new_scale, sampler, (int2)(out_c + 1, 0)) + read_imageh(new_biase, sampler, (int2)(out_c + 1, 0)); output2 = output2 * read_imageh(new_scale, sampler, (int2)(out_c + 2, 0)) + read_imageh(new_biase, sampler, (int2)(out_c + 2, 0)); output3 = output3 * read_imageh(new_scale, sampler, (int2)(out_c + 3, 0)) + read_imageh(new_biase, sampler, (int2)(out_c + 3, 0)); #endif #ifdef RELU output0 = activation(output0); output1 = activation(output1); output2 = activation(output2); output3 = activation(output3); #endif int2 output_pos0 = (int2)(out_c * global_size_dim1 + out_w, out_nh); write_imageh(output_image, output_pos0, output0); int2 output_pos1 = (int2)((out_c + 1) * global_size_dim1 + out_w, out_nh); write_imageh(output_image, output_pos1, output1); int2 output_pos2 = (int2)((out_c + 2) * global_size_dim1 + out_w, out_nh); write_imageh(output_image, output_pos2, output2); int2 output_pos3 = (int2)((out_c + 3) * global_size_dim1 + out_w, out_nh); write_imageh(output_image, output_pos3, output3); } */