#include #include "cuda/modulated_deform_im2col_cuda.h" #include "cuda/deform_psroi_pooling_cuda.h" extern THCState *state; // author: Charles Shang // https://github.com/torch/cunn/blob/master/lib/THCUNN/generic/SpatialConvolutionMM.cu void modulated_deform_conv_cuda_forward(THCudaTensor *input, THCudaTensor *weight, THCudaTensor *bias, THCudaTensor *ones, THCudaTensor *offset, THCudaTensor *mask, THCudaTensor *output, THCudaTensor *columns, int kernel_h, int kernel_w, const int stride_h, const int stride_w, const int pad_h, const int pad_w, const int dilation_h, const int dilation_w, const int deformable_group) { THCAssertSameGPU(THCudaTensor_checkGPU(state, 8, input, weight, bias, ones, offset, mask, output, columns)); THArgCheck(THCudaTensor_isContiguous(state, input), 1, "input tensor has to be contiguous"); THArgCheck(THCudaTensor_isContiguous(state, weight), 2, "weight tensor has to be contiguous"); const int batch = THCudaTensor_size(state, input, 0); const int channels = THCudaTensor_size(state, input, 1); const int height = THCudaTensor_size(state, input, 2); const int width = THCudaTensor_size(state, input, 3); const int channels_out = THCudaTensor_size(state, weight, 0); const int channels_kernel = THCudaTensor_size(state, weight, 1); const int kernel_h_ = THCudaTensor_size(state, weight, 2); const int kernel_w_ = THCudaTensor_size(state, weight, 3); if (kernel_h_ != kernel_h || kernel_w_ != kernel_w) THError("Input shape and kernel shape wont match: (%d x %d vs %d x %d).", kernel_h_, kernel_w, kernel_h_, kernel_w_); if (channels != channels_kernel) THError("Input shape and kernel channels wont match: (%d vs %d).", channels, channels_kernel); const int height_out = (height + 2 * pad_h - (dilation_h * (kernel_h - 1) + 1)) / stride_h + 1; const int width_out = (width + 2 * pad_w - (dilation_w * (kernel_w - 1) + 1)) / stride_w + 1; if (THCudaTensor_nDimension(state, ones) != 2 || THCudaTensor_size(state, ones, 0) * THCudaTensor_size(state, ones, 1) < height_out * width_out) { // Resize plane and fill with ones... THCudaTensor_resize2d(state, ones, height_out, width_out); THCudaTensor_fill(state, ones, 1); } // resize output THCudaTensor_resize4d(state, output, batch, channels_out, height_out, width_out); // resize temporary columns THCudaTensor_resize2d(state, columns, channels * kernel_h * kernel_w, 1 * height_out * width_out); THCudaTensor *input_n = THCudaTensor_new(state); THCudaTensor *offset_n = THCudaTensor_new(state); THCudaTensor *mask_n = THCudaTensor_new(state); THCudaTensor *output_n = THCudaTensor_new(state); for (int b = 0; b < batch; b++) { THCudaTensor_select(state, input_n, input, 0, b); THCudaTensor_select(state, offset_n, offset, 0, b); THCudaTensor_select(state, mask_n, mask, 0, b); THCudaTensor_select(state, output_n, output, 0, b); // Do Bias first: // M,N,K are dims of matrix A and B // (see http://docs.nvidia.com/cuda/cublas/#cublas-lt-t-gt-gemm) // (N x 1) (1 x M) long m_ = channels_out; long n_ = height_out * width_out; long k_ = 1; THCudaBlas_Sgemm(state, 't', 'n', n_, m_, k_, 1.0f, THCudaTensor_data(state, ones), k_, THCudaTensor_data(state, bias), k_, 0.0f, THCudaTensor_data(state, output_n), n_); modulated_deformable_im2col_cuda(THCState_getCurrentStream(state), THCudaTensor_data(state, input_n), THCudaTensor_data(state, offset_n), THCudaTensor_data(state, mask_n), 1, channels, height, width, height_out, width_out, kernel_h, kernel_w, pad_h, pad_w, stride_h, stride_w, dilation_h, dilation_w, deformable_group, THCudaTensor_data(state, columns)); //(k * m) x (m * n) // Y = WC long m = channels_out; long n = height_out * width_out; long k = channels * kernel_h * kernel_w; THCudaBlas_Sgemm(state, 'n', 'n', n, m, k, 1.0f, THCudaTensor_data(state, columns), n, THCudaTensor_data(state, weight), k, 1.0f, THCudaTensor_data(state, output_n), n); } THCudaTensor_free(state, input_n); THCudaTensor_free(state, offset_n); THCudaTensor_free(state, mask_n); THCudaTensor_free(state, output_n); } void modulated_deform_conv_cuda_backward(THCudaTensor *input, THCudaTensor *weight, THCudaTensor *bias, THCudaTensor *ones, THCudaTensor *offset, THCudaTensor *mask, THCudaTensor *columns, THCudaTensor *grad_input, THCudaTensor *grad_weight, THCudaTensor *grad_bias, THCudaTensor *grad_offset, THCudaTensor *grad_mask, THCudaTensor *grad_output, int kernel_h, int kernel_w, int stride_h, int stride_w, int pad_h, int pad_w, int dilation_h, int dilation_w, int deformable_group) { THCAssertSameGPU(THCudaTensor_checkGPU(state, 13, input, weight, bias, ones, offset, mask, columns, grad_input, grad_weight, grad_bias, grad_offset, grad_mask, grad_output)); THArgCheck(THCudaTensor_isContiguous(state, input), 1, "input tensor has to be contiguous"); THArgCheck(THCudaTensor_isContiguous(state, weight), 2, "weight tensor has to be contiguous"); const int batch = THCudaTensor_size(state, input, 0); const int channels = THCudaTensor_size(state, input, 1); const int height = THCudaTensor_size(state, input, 2); const int width = THCudaTensor_size(state, input, 3); const int channels_out = THCudaTensor_size(state, weight, 0); const int channels_kernel = THCudaTensor_size(state, weight, 1); const int kernel_h_ = THCudaTensor_size(state, weight, 2); const int kernel_w_ = THCudaTensor_size(state, weight, 3); if (kernel_h_ != kernel_h || kernel_w_ != kernel_w) THError("Input shape and kernel shape wont match: (%d x %d vs %d x %d).", kernel_h_, kernel_w, kernel_h_, kernel_w_); if (channels != channels_kernel) THError("Input shape and kernel channels wont match: (%d vs %d).", channels, channels_kernel); const int height_out = (height + 2 * pad_h - (dilation_h * (kernel_h - 1) + 1)) / stride_h + 1; const int width_out = (width + 2 * pad_w - (dilation_w * (kernel_w - 1) + 1)) / stride_w + 1; if (THCudaTensor_nDimension(state, ones) != 2 || THCudaTensor_size(state, ones, 0) * THCudaTensor_size(state, ones, 1) < height_out * width_out) { // Resize plane and fill with ones... THCudaTensor_resize2d(state, ones, height_out, width_out); THCudaTensor_fill(state, ones, 1.0f); } THCudaTensor_resize4d(state, grad_input, batch, channels, height, width); THCudaTensor_resize2d(state, columns, channels * kernel_h * kernel_w, height_out * width_out); THCudaTensor *input_n = THCudaTensor_new(state); THCudaTensor *offset_n = THCudaTensor_new(state); THCudaTensor *mask_n = THCudaTensor_new(state); THCudaTensor *grad_output_n = THCudaTensor_new(state); THCudaTensor *grad_input_n = THCudaTensor_new(state); THCudaTensor *grad_offset_n = THCudaTensor_new(state); THCudaTensor *grad_mask_n = THCudaTensor_new(state); for (int b = 0; b < batch; b++) { THCudaTensor_select(state, input_n, input, 0, b); THCudaTensor_select(state, offset_n, offset, 0, b); THCudaTensor_select(state, mask_n, mask, 0, b); THCudaTensor_select(state, grad_output_n, grad_output, 0, b); THCudaTensor_select(state, grad_input_n, grad_input, 0, b); THCudaTensor_select(state, grad_offset_n, grad_offset, 0, b); THCudaTensor_select(state, grad_mask_n, grad_mask, 0, b); long m = channels * kernel_h * kernel_w; long n = height_out * width_out; long k = channels_out; THCudaBlas_Sgemm(state, 'n', 't', n, m, k, 1.0f, THCudaTensor_data(state, grad_output_n), n, THCudaTensor_data(state, weight), m, 0.0f, THCudaTensor_data(state, columns), n); // gradient w.r.t. input coordinate data modulated_deformable_col2im_coord_cuda(THCState_getCurrentStream(state), THCudaTensor_data(state, columns), THCudaTensor_data(state, input_n), THCudaTensor_data(state, offset_n), THCudaTensor_data(state, mask_n), 1, channels, height, width, height_out, width_out, kernel_h, kernel_w, pad_h, pad_w, stride_h, stride_w, dilation_h, dilation_w, deformable_group, THCudaTensor_data(state, grad_offset_n), THCudaTensor_data(state, grad_mask_n)); // gradient w.r.t. input data modulated_deformable_col2im_cuda(THCState_getCurrentStream(state), THCudaTensor_data(state, columns), THCudaTensor_data(state, offset_n), THCudaTensor_data(state, mask_n), 1, channels, height, width, height_out, width_out, kernel_h, kernel_w, pad_h, pad_w, stride_h, stride_w, dilation_h, dilation_w, deformable_group, THCudaTensor_data(state, grad_input_n)); // gradient w.r.t. weight, dWeight should accumulate across the batch and group modulated_deformable_im2col_cuda(THCState_getCurrentStream(state), THCudaTensor_data(state, input_n), THCudaTensor_data(state, offset_n), THCudaTensor_data(state, mask_n), 1, channels, height, width, height_out, width_out, kernel_h, kernel_w, pad_h, pad_w, stride_h, stride_w, dilation_h, dilation_w, deformable_group, THCudaTensor_data(state, columns)); long m_ = channels_out; long n_ = channels * kernel_h * kernel_w; long k_ = height_out * width_out; THCudaBlas_Sgemm(state, 't', 'n', n_, m_, k_, 1.0f, THCudaTensor_data(state, columns), k_, THCudaTensor_data(state, grad_output_n), k_, 1.0f, THCudaTensor_data(state, grad_weight), n_); // gradient w.r.t. bias // long m_ = channels_out; // long k__ = height_out * width_out; THCudaBlas_Sgemv(state, 't', k_, m_, 1.0f, THCudaTensor_data(state, grad_output_n), k_, THCudaTensor_data(state, ones), 1, 1.0f, THCudaTensor_data(state, grad_bias), 1); } THCudaTensor_free(state, input_n); THCudaTensor_free(state, offset_n); THCudaTensor_free(state, mask_n); THCudaTensor_free(state, grad_output_n); THCudaTensor_free(state, grad_input_n); THCudaTensor_free(state, grad_offset_n); THCudaTensor_free(state, grad_mask_n); } void deform_psroi_pooling_cuda_forward(THCudaTensor * input, THCudaTensor * bbox, THCudaTensor * trans, THCudaTensor * out, THCudaTensor * top_count, const int no_trans, const float spatial_scale, const int output_dim, const int group_size, const int pooled_size, const int part_size, const int sample_per_part, const float trans_std) { THArgCheck(THCudaTensor_isContiguous(state, input), 1, "input tensor has to be contiguous"); THCAssertSameGPU(THCudaTensor_checkGPU(state, 5, input, bbox, trans, out, top_count)); const int batch = THCudaTensor_size(state, input, 0); const int channels = THCudaTensor_size(state, input, 1); const int height = THCudaTensor_size(state, input, 2); const int width = THCudaTensor_size(state, input, 3); const int channels_trans = no_trans? 2 : THCudaTensor_size(state, trans, 1); const int num_bbox = THCudaTensor_size(state, bbox, 0); if (num_bbox != THCudaTensor_size(state, out, 0)) THError("Output shape and bbox number wont match: (%d vs %d).", THCudaTensor_size(state, out, 0), num_bbox); DeformablePSROIPoolForward(THCState_getCurrentStream(state), THCudaTensor_data(state, input), THCudaTensor_data(state, bbox), THCudaTensor_data(state, trans), THCudaTensor_data(state, out), THCudaTensor_data(state, top_count), batch, channels, height, width, num_bbox, channels_trans, no_trans, spatial_scale, output_dim, group_size, pooled_size, part_size, sample_per_part, trans_std); } void deform_psroi_pooling_cuda_backward(THCudaTensor * out_grad, THCudaTensor * input, THCudaTensor * bbox, THCudaTensor * trans, THCudaTensor * top_count, THCudaTensor * input_grad, THCudaTensor * trans_grad, const int no_trans, const float spatial_scale, const int output_dim, const int group_size, const int pooled_size, const int part_size, const int sample_per_part, const float trans_std) { THArgCheck(THCudaTensor_isContiguous(state, out_grad), 0, "out_grad tensor has to be contiguous"); THArgCheck(THCudaTensor_isContiguous(state, input), 1, "input tensor has to be contiguous"); THCAssertSameGPU(THCudaTensor_checkGPU(state, 7, input, bbox, trans, out_grad, top_count, input_grad, trans_grad)); const int batch = THCudaTensor_size(state, input, 0); const int channels = THCudaTensor_size(state, input, 1); const int height = THCudaTensor_size(state, input, 2); const int width = THCudaTensor_size(state, input, 3); const int channels_trans = no_trans? 2 : THCudaTensor_size(state, trans, 1); const int num_bbox = THCudaTensor_size(state, bbox, 0); if (num_bbox != THCudaTensor_size(state, out_grad, 0)) THError("Output shape and bbox number wont match: (%d vs %d).", THCudaTensor_size(state, out_grad, 0), num_bbox); DeformablePSROIPoolBackwardAcc(THCState_getCurrentStream(state), THCudaTensor_data(state, out_grad), THCudaTensor_data(state, input), THCudaTensor_data(state, bbox), THCudaTensor_data(state, trans), THCudaTensor_data(state, top_count), THCudaTensor_data(state, input_grad), THCudaTensor_data(state, trans_grad), batch, channels, height, width, num_bbox, channels_trans, no_trans, spatial_scale, output_dim, group_size, pooled_size, part_size, sample_per_part, trans_std); }