~speedprog/mtg/mtg_card_detector.git

			@@ -1,225 +1,269 @@
			#include "convolutional_layer.h"
			#include "utils.h"
			#include "im2col.h"
			#include "col2im.h"
			#include "blas.h"
			#include "gemm.h"
			#include <stdio.h>
			#include <time.h>

			int convolutional_out_height(convolutional_layer layer)
			{
			int h = layer.h;
			if (!layer.pad) h -= layer.size;
			else h -= 1;
			return h/layer.stride + 1;
			}

			int convolutional_out_width(convolutional_layer layer)
			{
			int w = layer.w;
			if (!layer.pad) w -= layer.size;
			else w -= 1;
			return w/layer.stride + 1;
			}

			image get_convolutional_image(convolutional_layer layer)
			{
			int h,w,c;
			if(layer.edge){
			h = (layer.h-1)/layer.stride + 1;
			w = (layer.w-1)/layer.stride + 1;
			}else{
			h = (layer.h - layer.size)/layer.stride+1;
			w = (layer.h - layer.size)/layer.stride+1;
			}
			h = convolutional_out_height(layer);
			w = convolutional_out_width(layer);
			c = layer.n;
			return double_to_image(h,w,c,layer.output);
			return float_to_image(h,w,c,layer.output);
			}

			image get_convolutional_delta(convolutional_layer layer)
			{
			int h,w,c;
			if(layer.edge){
			h = (layer.h-1)/layer.stride + 1;
			w = (layer.w-1)/layer.stride + 1;
			}else{
			h = (layer.h - layer.size)/layer.stride+1;
			w = (layer.h - layer.size)/layer.stride+1;
			}
			h = convolutional_out_height(layer);
			w = convolutional_out_width(layer);
			c = layer.n;
			return double_to_image(h,w,c,layer.delta);
			return float_to_image(h,w,c,layer.delta);
			}

			convolutional_layer *make_convolutional_layer(int h, int w, int c, int n, int size, int stride, ACTIVATION activation)
			convolutional_layer *make_convolutional_layer(int batch, int h, int w, int c, int n, int size, int stride, int pad, ACTIVATION activation, float learning_rate, float momentum, float decay)
			{
			int i;
			int out_h,out_w;
			size = 2*(size/2)+1; //HA! And you thought you'd use an even sized filter...
			convolutional_layer *layer = calloc(1, sizeof(convolutional_layer));

			layer->learning_rate = learning_rate;
			layer->momentum = momentum;
			layer->decay = decay;

			layer->h = h;
			layer->w = w;
			layer->c = c;
			layer->n = n;
			layer->edge = 1;
			layer->batch = batch;
			layer->stride = stride;
			layer->kernels = calloc(n, sizeof(image));
			layer->kernel_updates = calloc(n, sizeof(image));
			layer->kernel_momentum = calloc(n, sizeof(image));
			layer->biases = calloc(n, sizeof(double));
			layer->bias_updates = calloc(n, sizeof(double));
			layer->bias_momentum = calloc(n, sizeof(double));
			double scale = 2./(size*size);
			layer->size = size;
			layer->pad = pad;

			layer->filters = calloc(cnsize*size, sizeof(float));
			layer->filter_updates = calloc(cnsize*size, sizeof(float));

			layer->biases = calloc(n, sizeof(float));
			layer->bias_updates = calloc(n, sizeof(float));
			float scale = 1./sqrt(sizesizec);
			for(i = 0; i < cnsizesize; ++i) layer->filters[i] = scalerand_normal();
			for(i = 0; i < n; ++i){
			//layer->biases[i] = rand_normal()*scale + scale;
			layer->biases[i] = 0;
			layer->kernels[i] = make_random_kernel(size, c, scale);
			layer->kernel_updates[i] = make_random_kernel(size, c, 0);
			layer->kernel_momentum[i] = make_random_kernel(size, c, 0);
			layer->biases[i] = scale;
			}
			layer->size = 2*(size/2)+1;
			if(layer->edge){
			out_h = (layer->h-1)/layer->stride + 1;
			out_w = (layer->w-1)/layer->stride + 1;
			}else{
			out_h = (layer->h - layer->size)/layer->stride+1;
			out_w = (layer->h - layer->size)/layer->stride+1;
			}
			fprintf(stderr, "Convolutional Layer: %d x %d x %d image, %d filters -> %d x %d x %d image\n", h,w,c,n, out_h, out_w, n);
			layer->output = calloc(out_h * out_w * n, sizeof(double));
			layer->delta = calloc(out_h * out_w * n, sizeof(double));
			layer->upsampled = make_image(h,w,n);
			int out_h = convolutional_out_height(*layer);
			int out_w = convolutional_out_width(*layer);

			layer->col_image = calloc(out_hout_wsizesizec, sizeof(float));
			layer->output = calloc(layer->batchout_h out_w * n, sizeof(float));
			layer->delta = calloc(layer->batchout_h out_w * n, sizeof(float));

			#ifdef GPU
			layer->filters_gpu = cuda_make_array(layer->filters, cnsize*size);
			layer->filter_updates_gpu = cuda_make_array(layer->filter_updates, cnsize*size);

			layer->biases_gpu = cuda_make_array(layer->biases, n);
			layer->bias_updates_gpu = cuda_make_array(layer->bias_updates, n);

			layer->col_image_gpu = cuda_make_array(layer->col_image, out_hout_wsizesizec);
			layer->delta_gpu = cuda_make_array(layer->delta, layer->batchout_hout_w*n);
			layer->output_gpu = cuda_make_array(layer->output, layer->batchout_hout_w*n);
			#endif
			layer->activation = activation;

			fprintf(stderr, "Convolutional Layer: %d x %d x %d image, %d filters -> %d x %d x %d image\n", h,w,c,n, out_h, out_w, n);

			return layer;
			}

			void forward_convolutional_layer(const convolutional_layer layer, double *in)
			void resize_convolutional_layer(convolutional_layer *layer, int h, int w, int c)
			{
			image input = double_to_image(layer.h, layer.w, layer.c, in);
			image output = get_convolutional_image(layer);
			int i,j;
			for(i = 0; i < layer.n; ++i){
			convolve(input, layer.kernels[i], layer.stride, i, output, layer.edge);
			}
			for(i = 0; i < output.c; ++i){
			for(j = 0; j < output.h*output.w; ++j){
			int index = ioutput.houtput.w + j;
			output.data[index] += layer.biases[i];
			output.data[index] = activate(output.data[index], layer.activation);
			}
			}
			layer->h = h;
			layer->w = w;
			layer->c = c;
			int out_h = convolutional_out_height(*layer);
			int out_w = convolutional_out_width(*layer);

			layer->col_image = realloc(layer->col_image,
			out_hout_wlayer->sizelayer->sizelayer->c*sizeof(float));
			layer->output = realloc(layer->output,
			layer->batchout_h out_w * layer->n*sizeof(float));
			layer->delta = realloc(layer->delta,
			layer->batchout_h out_w * layer->n*sizeof(float));
			}

			void backward_convolutional_layer(convolutional_layer layer, double input, double delta)
			void bias_output(const convolutional_layer layer)
			{
			int i;

			image in_delta = double_to_image(layer.h, layer.w, layer.c, delta);
			image out_delta = get_convolutional_delta(layer);
			zero_image(in_delta);

			for(i = 0; i < layer.n; ++i){
			back_convolve(in_delta, layer.kernels[i], layer.stride, i, out_delta, layer.edge);
			}
			}

			void backward_convolutional_layer2(convolutional_layer layer, double input, double delta)
			{
			image in_delta = double_to_image(layer.h, layer.w, layer.c, delta);
			image out_delta = get_convolutional_delta(layer);
			int i,j;
			for(i = 0; i < layer.n; ++i){
			rotate_image(layer.kernels[i]);
			}

			zero_image(in_delta);
			upsample_image(out_delta, layer.stride, layer.upsampled);
			for(j = 0; j < in_delta.c; ++j){
			int i,j,b;
			int out_h = convolutional_out_height(layer);
			int out_w = convolutional_out_width(layer);
			for(b = 0; b < layer.batch; ++b){
			for(i = 0; i < layer.n; ++i){
			two_d_convolve(layer.upsampled, i, layer.kernels[i], j, 1, in_delta, j, layer.edge);
			}
			}

			for(i = 0; i < layer.n; ++i){
			rotate_image(layer.kernels[i]);
			}
			}

			void gradient_delta_convolutional_layer(convolutional_layer layer)
			{
			int i;
			image out_delta = get_convolutional_delta(layer);
			image out_image = get_convolutional_image(layer);
			for(i = 0; i < out_image.hout_image.wout_image.c; ++i){
			out_delta.data[i] *= gradient(out_image.data[i], layer.activation);
			}
			}

			void learn_convolutional_layer(convolutional_layer layer, double *input)
			{
			int i;
			image in_image = double_to_image(layer.h, layer.w, layer.c, input);
			image out_delta = get_convolutional_delta(layer);
			gradient_delta_convolutional_layer(layer);
			for(i = 0; i < layer.n; ++i){
			kernel_update(in_image, layer.kernel_updates[i], layer.stride, i, out_delta, layer.edge);
			layer.bias_updates[i] += avg_image_layer(out_delta, i);
			}
			}

			void update_convolutional_layer(convolutional_layer layer, double step, double momentum, double decay)
			{
			int i,j;
			for(i = 0; i < layer.n; ++i){
			layer.bias_momentum[i] = step*(layer.bias_updates[i])
			+ momentum*layer.bias_momentum[i];
			layer.biases[i] += layer.bias_momentum[i];
			layer.bias_updates[i] = 0;
			int pixels = layer.kernels[i].hlayer.kernels[i].wlayer.kernels[i].c;
			for(j = 0; j < pixels; ++j){
			layer.kernel_momentum[i].data[j] = step(layer.kernel_updates[i].data[j] - decaylayer.kernels[i].data[j])
			+ momentum*layer.kernel_momentum[i].data[j];
			layer.kernels[i].data[j] += layer.kernel_momentum[i].data[j];
			}
			zero_image(layer.kernel_updates[i]);
			}
			}

			void visualize_convolutional_filters(convolutional_layer layer, char *window)
			{
			int color = 1;
			int border = 1;
			int h,w,c;
			int size = layer.size;
			h = size;
			w = (size + border) * layer.n - border;
			c = layer.kernels[0].c;
			if(c != 3 \|\| !color){
			h = (h+border)*c - border;
			c = 1;
			}

			image filters = make_image(h,w,c);
			int i,j;
			for(i = 0; i < layer.n; ++i){
			int w_offset = i*(size+border);
			image k = layer.kernels[i];
			image copy = copy_image(k);
			normalize_image(copy);
			for(j = 0; j < k.c; ++j){
			set_pixel(copy,0,0,j,layer.biases[i]);
			}
			if(c == 3 && color){
			embed_image(copy, filters, 0, w_offset);
			}
			else{
			for(j = 0; j < k.c; ++j){
			int h_offset = j*(size+border);
			image layer = get_image_layer(k, j);
			embed_image(layer, filters, h_offset, w_offset);
			free_image(layer);
			for(j = 0; j < out_h*out_w; ++j){
			layer.output[(blayer.n + i)out_h*out_w + j] = layer.biases[i];
			}
			}
			free_image(copy);
			}
			image delta = get_convolutional_delta(layer);
			image dc = collapse_image_layers(delta, 1);
			char buff[256];
			sprintf(buff, "%s: Delta", window);
			show_image(dc, buff);
			free_image(dc);
			show_image(filters, window);
			free_image(filters);
			}

			void visualize_convolutional_layer(convolutional_layer layer)
			void forward_convolutional_layer(const convolutional_layer layer, float *in)
			{
			int out_h = convolutional_out_height(layer);
			int out_w = convolutional_out_width(layer);
			int i;
			char buff[256];
			for(i = 0; i < layer.n; ++i){
			image k = layer.kernels[i];
			sprintf(buff, "Kernel %d", i);
			if(k.c <= 3) show_image(k, buff);
			else show_image_layers(k, buff);

			bias_output(layer);

			int m = layer.n;
			int k = layer.sizelayer.sizelayer.c;
			int n = out_h*out_w;

			float *a = layer.filters;
			float *b = layer.col_image;
			float *c = layer.output;

			for(i = 0; i < layer.batch; ++i){
			im2col_cpu(in, layer.c, layer.h, layer.w,
			layer.size, layer.stride, layer.pad, b);
			gemm(0,0,m,n,k,1,a,k,b,n,1,c,n);
			c += n*m;
			in += layer.clayer.hlayer.w;
			}
			activate_array(layer.output, mnlayer.batch, layer.activation);
			}

			void learn_bias_convolutional_layer(convolutional_layer layer)
			{
			float alpha = 1./layer.batch;
			int i,b;
			int size = convolutional_out_height(layer)
			*convolutional_out_width(layer);
			for(b = 0; b < layer.batch; ++b){
			for(i = 0; i < layer.n; ++i){
			layer.bias_updates[i] += alpha * sum_array(layer.delta+size(i+blayer.n), size);
			}
			}
			}

			void backward_convolutional_layer(convolutional_layer layer, float in, float delta)
			{
			float alpha = 1./layer.batch;
			int i;
			int m = layer.n;
			int n = layer.sizelayer.sizelayer.c;
			int k = convolutional_out_height(layer)*
			convolutional_out_width(layer);

			gradient_array(layer.output, mklayer.batch, layer.activation, layer.delta);

			learn_bias_convolutional_layer(layer);

			if(delta) memset(delta, 0, layer.batchlayer.hlayer.wlayer.csizeof(float));

			for(i = 0; i < layer.batch; ++i){
			float a = layer.delta + im*k;
			float *b = layer.col_image;
			float *c = layer.filter_updates;

			float im = in+ilayer.clayer.hlayer.w;

			im2col_cpu(im, layer.c, layer.h, layer.w,
			layer.size, layer.stride, layer.pad, b);
			gemm(0,1,m,n,k,alpha,a,k,b,k,1,c,n);

			if(delta){
			a = layer.filters;
			b = layer.delta + imk;
			c = layer.col_image;

			gemm(1,0,n,k,m,1,a,n,b,k,0,c,k);

			col2im_cpu(layer.col_image, layer.c, layer.h, layer.w, layer.size, layer.stride, layer.pad, delta+ilayer.clayer.h*layer.w);
			}
			}
			}

			void update_convolutional_layer(convolutional_layer layer)
			{
			int size = layer.sizelayer.sizelayer.c*layer.n;
			axpy_cpu(layer.n, layer.learning_rate, layer.bias_updates, 1, layer.biases, 1);
			scal_cpu(layer.n, layer.momentum, layer.bias_updates, 1);

			axpy_cpu(size, -layer.decay, layer.filters, 1, layer.filter_updates, 1);
			axpy_cpu(size, layer.learning_rate, layer.filter_updates, 1, layer.filters, 1);
			scal_cpu(size, layer.momentum, layer.filter_updates, 1);
			}


			image get_convolutional_filter(convolutional_layer layer, int i)
			{
			int h = layer.size;
			int w = layer.size;
			int c = layer.c;
			return float_to_image(h,w,c,layer.filters+ihw*c);
			}

			image weighted_sum_filters(convolutional_layer layer, image prev_filters)
			{
			image *filters = calloc(layer.n, sizeof(image));
			int i,j,k,c;
			if(!prev_filters){
			for(i = 0; i < layer.n; ++i){
			filters[i] = copy_image(get_convolutional_filter(layer, i));
			}
			}
			else{
			image base = prev_filters[0];
			for(i = 0; i < layer.n; ++i){
			image filter = get_convolutional_filter(layer, i);
			filters[i] = make_image(base.h, base.w, base.c);
			for(j = 0; j < layer.size; ++j){
			for(k = 0; k < layer.size; ++k){
			for(c = 0; c < layer.c; ++c){
			float weight = get_pixel(filter, j, k, c);
			image prev_filter = copy_image(prev_filters[c]);
			scale_image(prev_filter, weight);
			add_into_image(prev_filter, filters[i], 0,0);
			free_image(prev_filter);
			}
			}
			}
			}
			}
			return filters;
			}

			image visualize_convolutional_layer(convolutional_layer layer, char window, image *prev_filters)
			{
			image *single_filters = weighted_sum_filters(layer, 0);
			show_images(single_filters, layer.n, window);

			image delta = get_convolutional_image(layer);
			image dc = collapse_image_layers(delta, 1);
			char buff[256];
			sprintf(buff, "%s: Output", window);
			//show_image(dc, buff);
			//save_image(dc, buff);
			free_image(dc);
			return single_filters;
			}