~speedprog/mtg/mtg_card_detector.git

			@@ -1,3 +1,7 @@
			#include "cuda_runtime.h"
			#include "curand.h"
			#include "cublas_v2.h"

			extern "C" {
			#include "convolutional_layer.h"
			#include "gemm.h"
			@@ -8,6 +12,21 @@
			#include "cuda.h"
			}

			__global__ void binarize_filters_kernel(float filters, int n, int size, float binary)
			{
			int f = (blockIdx.x + blockIdx.ygridDim.x) blockDim.x + threadIdx.x;
			if (f >= n) return;
			int i = 0;
			float mean = 0;
			for(i = 0; i < size; ++i){
			mean += abs(filters[f*size + i]);
			}
			mean = mean / size;
			for(i = 0; i < size; ++i){
			binary[fsize + i] = (filters[fsize + i] > 0) ? mean : -mean;
			}
			}

			__global__ void scale_bias_kernel(float output, float biases, int n, int size)
			{
			int offset = blockIdx.x * blockDim.x + threadIdx.x;
			@@ -46,6 +65,12 @@
			}
			}

			void binarize_filters_gpu(float filters, int n, int size, float mean)
			{
			binarize_filters_kernel<<<cuda_gridsize(n), BLOCK>>>(filters, n, size, mean);
			check_error(cudaPeekAtLastError());
			}

			void backward_scale_gpu(float x_norm, float delta, int batch, int n, int size, float *scale_updates)
			{
			backward_scale_kernel<<<n, BLOCK>>>(x_norm, delta, batch, n, size, scale_updates);
			@@ -90,12 +115,59 @@
			}
			}

			__global__ void dot_kernel(float output, float scale, int batch, int n, int size, float delta)
			{
			int index = (blockIdx.x + blockIdx.ygridDim.x) blockDim.x + threadIdx.x;
			int f1 = index / n;
			int f2 = index % n;
			if (f2 <= f1) return;

			float sum = 0;
			float norm1 = 0;
			float norm2 = 0;
			int b, i;
			for(b = 0; b < batch; ++b){
			for(i = 0; i < size; ++i){
			int i1 = b * size * n + f1 * size + i;
			int i2 = b * size * n + f2 * size + i;
			sum += output[i1] * output[i2];
			norm1 += output[i1] * output[i1];
			norm2 += output[i2] * output[i2];
			}
			}
			norm1 = sqrt(norm1);
			norm2 = sqrt(norm2);
			float norm = norm1 * norm2;
			sum = sum / norm;
			for(b = 0; b < batch; ++b){
			for(i = 0; i < size; ++i){
			int i1 = b * size * n + f1 * size + i;
			int i2 = b * size * n + f2 * size + i;
			delta[i1] += - scale * sum * output[i2] / norm;
			delta[i2] += - scale * sum * output[i1] / norm;
			}
			}
			}

			void dot_error_gpu(layer l)
			{
			dot_kernel<<<cuda_gridsize(l.nl.n), BLOCK>>>(l.output_gpu, l.dot, l.batch, l.n, l.out_w l.out_h, l.delta_gpu);
			check_error(cudaPeekAtLastError());
			}

			void backward_bias_gpu(float bias_updates, float delta, int batch, int n, int size)
			{
			backward_bias_kernel<<<n, BLOCK>>>(bias_updates, delta, batch, n, size);
			check_error(cudaPeekAtLastError());
			}

			void swap_binary(convolutional_layer *l)
			{
			float *swap = l->filters_gpu;
			l->filters_gpu = l->binary_filters_gpu;
			l->binary_filters_gpu = swap;
			}

			void forward_convolutional_layer_gpu(convolutional_layer l, network_state state)
			{
			int i;
			@@ -105,6 +177,11 @@
			convolutional_out_width(l);

			fill_ongpu(l.outputs*l.batch, 0, l.output_gpu, 1);
			if(l.binary){
			binarize_filters_gpu(l.filters_gpu, l.n, l.cl.sizel.size, l.binary_filters_gpu);
			swap_binary(&l);
			}

			for(i = 0; i < l.batch; ++i){
			im2col_ongpu(state.input + il.cl.h*l.w, l.c, l.h, l.w, l.size, l.stride, l.pad, l.col_image_gpu);
			float * a = l.filters_gpu;
			@@ -113,19 +190,16 @@
			gemm_ongpu(0,0,m,n,k,1.,a,k,b,n,1.,c+imn,n);
			}

			if(l.batch_normalize){
			if(state.train){
			fast_mean_gpu(l.output_gpu, l.batch, l.n, l.out_h*l.out_w, l.spatial_mean_gpu, l.mean_gpu);
			fast_variance_gpu(l.output_gpu, l.mean_gpu, l.batch, l.n, l.out_h*l.out_w, l.spatial_variance_gpu, l.variance_gpu);
			if (l.batch_normalize) {
			if (state.train) {
			fast_mean_gpu(l.output_gpu, l.batch, l.n, l.out_h*l.out_w, l.mean_gpu);
			fast_variance_gpu(l.output_gpu, l.mean_gpu, l.batch, l.n, l.out_h*l.out_w, l.variance_gpu);

			scal_ongpu(l.n, .95, l.rolling_mean_gpu, 1);
			axpy_ongpu(l.n, .05, l.mean_gpu, 1, l.rolling_mean_gpu, 1);
			scal_ongpu(l.n, .95, l.rolling_variance_gpu, 1);
			axpy_ongpu(l.n, .05, l.variance_gpu, 1, l.rolling_variance_gpu, 1);

			// cuda_pull_array(l.variance_gpu, l.mean, l.n);
			// printf("%f\n", l.mean[0]);

			copy_ongpu(l.outputs*l.batch, l.output_gpu, 1, l.x_gpu, 1);
			normalize_gpu(l.output_gpu, l.mean_gpu, l.variance_gpu, l.batch, l.n, l.out_h*l.out_w);
			copy_ongpu(l.outputs*l.batch, l.output_gpu, 1, l.x_norm_gpu, 1);
			@@ -138,6 +212,8 @@
			add_bias_gpu(l.output_gpu, l.biases_gpu, l.batch, l.n, n);

			activate_array_ongpu(l.output_gpu, mnl.batch, l.activation);
			if(l.dot > 0) dot_error_gpu(l);
			if(l.binary) swap_binary(&l);
			}

			void backward_convolutional_layer_gpu(convolutional_layer l, network_state state)
			@@ -157,8 +233,8 @@

			scale_bias_gpu(l.delta_gpu, l.scales_gpu, l.batch, l.n, l.out_h*l.out_w);

			fast_mean_delta_gpu(l.delta_gpu, l.variance_gpu, l.batch, l.n, l.out_w*l.out_h, l.spatial_mean_delta_gpu, l.mean_delta_gpu);
			fast_variance_delta_gpu(l.x_gpu, l.delta_gpu, l.mean_gpu, l.variance_gpu, l.batch, l.n, l.out_w*l.out_h, l.spatial_variance_delta_gpu, l.variance_delta_gpu);
			fast_mean_delta_gpu(l.delta_gpu, l.variance_gpu, l.batch, l.n, l.out_w*l.out_h, l.mean_delta_gpu);
			fast_variance_delta_gpu(l.x_gpu, l.delta_gpu, l.mean_gpu, l.variance_gpu, l.batch, l.n, l.out_w*l.out_h, l.variance_delta_gpu);
			normalize_delta_gpu(l.x_gpu, l.mean_gpu, l.variance_gpu, l.mean_delta_gpu, l.variance_delta_gpu, l.batch, l.n, l.out_w*l.out_h, l.delta_gpu);
			}

			@@ -171,6 +247,7 @@
			gemm_ongpu(0,1,m,n,k,1,a + imk,k,b,k,1,c,n);

			if(state.delta){
			if(l.binary) swap_binary(&l);
			float * a = l.filters_gpu;
			float * b = l.delta_gpu;
			float * c = l.col_image_gpu;
			@@ -178,6 +255,7 @@
			gemm_ongpu(1,0,n,k,m,1,a,n,b + ikm,k,0,c,k);

			col2im_ongpu(l.col_image_gpu, l.c, l.h, l.w, l.size, l.stride, l.pad, state.delta + il.cl.h*l.w);
			if(l.binary) swap_binary(&l);
			}
			}
			}