~speedprog/mtg/mtg_card_detector.git

			@@ -1,6 +1,7 @@
			#include "cost_layer.h"
			#include "utils.h"
			#include "mini_blas.h"
			#include "cuda.h"
			#include "blas.h"
			#include <math.h>
			#include <string.h>
			#include <stdlib.h>
			@@ -9,8 +10,9 @@
			COST_TYPE get_cost_type(char *s)
			{
			if (strcmp(s, "sse")==0) return SSE;
			if (strcmp(s, "detection")==0) return DETECTION;
			fprintf(stderr, "Couldn't find activation function %s, going with SSE\n", s);
			if (strcmp(s, "masked")==0) return MASKED;
			if (strcmp(s, "smooth")==0) return SMOOTH;
			fprintf(stderr, "Couldn't find cost type %s, going with SSE\n", s);
			return SSE;
			}

			@@ -19,98 +21,128 @@
			switch(a){
			case SSE:
			return "sse";
			case DETECTION:
			return "detection";
			case MASKED:
			return "masked";
			case SMOOTH:
			return "smooth";
			}
			return "sse";
			}

			cost_layer *make_cost_layer(int batch, int inputs, COST_TYPE type)
			cost_layer make_cost_layer(int batch, int inputs, COST_TYPE cost_type, float scale)
			{
			fprintf(stderr, "Cost Layer: %d inputs\n", inputs);
			cost_layer *layer = calloc(1, sizeof(cost_layer));
			layer->batch = batch;
			layer->inputs = inputs;
			layer->type = type;
			layer->delta = calloc(inputs*batch, sizeof(float));
			layer->output = calloc(1, sizeof(float));
			fprintf(stderr, "cost %4d\n", inputs);
			cost_layer l = {0};
			l.type = COST;

			l.scale = scale;
			l.batch = batch;
			l.inputs = inputs;
			l.outputs = inputs;
			l.cost_type = cost_type;
			l.delta = calloc(inputs*batch, sizeof(float));
			l.output = calloc(inputs*batch, sizeof(float));
			l.cost = calloc(1, sizeof(float));

			l.forward = forward_cost_layer;
			l.backward = backward_cost_layer;
			#ifdef GPU
			layer->delta_cl = cl_make_array(layer->delta, inputs*batch);
			l.forward_gpu = forward_cost_layer_gpu;
			l.backward_gpu = backward_cost_layer_gpu;

			l.delta_gpu = cuda_make_array(l.output, inputs*batch);
			l.output_gpu = cuda_make_array(l.delta, inputs*batch);
			#endif
			return layer;
			return l;
			}

			void forward_cost_layer(cost_layer layer, float input, float truth)
			void resize_cost_layer(cost_layer *l, int inputs)
			{
			if (!truth) return;
			copy_cpu(layer.batch*layer.inputs, truth, 1, layer.delta, 1);
			axpy_cpu(layer.batch*layer.inputs, -1, input, 1, layer.delta, 1);
			if(layer.type == DETECTION){
			l->inputs = inputs;
			l->outputs = inputs;
			l->delta = realloc(l->delta, inputsl->batchsizeof(float));
			l->output = realloc(l->output, inputsl->batchsizeof(float));
			#ifdef GPU
			cuda_free(l->delta_gpu);
			cuda_free(l->output_gpu);
			l->delta_gpu = cuda_make_array(l->delta, inputs*l->batch);
			l->output_gpu = cuda_make_array(l->output, inputs*l->batch);
			#endif
			}

			void forward_cost_layer(cost_layer l, network_state state)
			{
			if (!state.truth) return;
			if(l.cost_type == MASKED){
			int i;
			for(i = 0; i < layer.batch*layer.inputs; ++i){
			if((i%5) && !truth[(i/5)*5]) layer.delta[i] = 0;
			for(i = 0; i < l.batch*l.inputs; ++i){
			if(state.truth[i] == SECRET_NUM) state.input[i] = SECRET_NUM;
			}
			}
			(layer.output) = dot_cpu(layer.batchlayer.inputs, layer.delta, 1, layer.delta, 1);
			//printf("cost: %f\n", *layer.output);
			if(l.cost_type == SMOOTH){
			smooth_l1_cpu(l.batch*l.inputs, state.input, state.truth, l.delta, l.output);
			} else {
			l2_cpu(l.batch*l.inputs, state.input, state.truth, l.delta, l.output);
			}
			l.cost[0] = sum_array(l.output, l.batch*l.inputs);
			}

			void backward_cost_layer(const cost_layer layer, float input, float delta)
			void backward_cost_layer(const cost_layer l, network_state state)
			{
			copy_cpu(layer.batch*layer.inputs, layer.delta, 1, delta, 1);
			axpy_cpu(l.batch*l.inputs, l.scale, l.delta, 1, state.delta, 1);
			}

			#ifdef GPU

			cl_kernel get_mask_kernel()
			void pull_cost_layer(cost_layer l)
			{
			static int init = 0;
			static cl_kernel kernel;
			if(!init){
			kernel = get_kernel("src/axpy.cl", "mask", 0);
			init = 1;
			}
			return kernel;
			cuda_pull_array(l.delta_gpu, l.delta, l.batch*l.inputs);
			}

			void mask_ongpu(int n, cl_mem x, cl_mem mask, int mod)
			void push_cost_layer(cost_layer l)
			{
			cl_kernel kernel = get_mask_kernel();
			cl_command_queue queue = cl.queue;

			cl_uint i = 0;
			cl.error = clSetKernelArg(kernel, i++, sizeof(n), (void*) &n);
			cl.error = clSetKernelArg(kernel, i++, sizeof(x), (void*) &x);
			cl.error = clSetKernelArg(kernel, i++, sizeof(mask), (void*) &mask);
			cl.error = clSetKernelArg(kernel, i++, sizeof(mod), (void*) &mod);
			check_error(cl);

			const size_t global_size[] = {n};

			cl.error = clEnqueueNDRangeKernel(queue, kernel, 1, 0, global_size, 0, 0, 0, 0);
			check_error(cl);

			cuda_push_array(l.delta_gpu, l.delta, l.batch*l.inputs);
			}

			void forward_cost_layer_gpu(cost_layer layer, cl_mem input, cl_mem truth)
			int float_abs_compare (const void * a, const void * b)
			{
			if (!truth) return;
			float fa = (const float) a;
			if(fa < 0) fa = -fa;
			float fb = (const float) b;
			if(fb < 0) fb = -fb;
			return (fa > fb) - (fa < fb);
			}

			copy_ongpu(layer.batch*layer.inputs, truth, 1, layer.delta_cl, 1);
			axpy_ongpu(layer.batch*layer.inputs, -1, input, 1, layer.delta_cl, 1);

			if(layer.type==DETECTION){
			mask_ongpu(layer.inputs*layer.batch, layer.delta_cl, truth, 5);
			void forward_cost_layer_gpu(cost_layer l, network_state state)
			{
			if (!state.truth) return;
			if (l.cost_type == MASKED) {
			mask_ongpu(l.batch*l.inputs, state.input, SECRET_NUM, state.truth);
			}

			cl_read_array(layer.delta_cl, layer.delta, layer.batch*layer.inputs);
			(layer.output) = dot_cpu(layer.batchlayer.inputs, layer.delta, 1, layer.delta, 1);
			//printf("cost: %f\n", *layer.output);
			if(l.cost_type == SMOOTH){
			smooth_l1_gpu(l.batch*l.inputs, state.input, state.truth, l.delta_gpu, l.output_gpu);
			} else {
			l2_gpu(l.batch*l.inputs, state.input, state.truth, l.delta_gpu, l.output_gpu);
			}

			if(l.ratio){
			cuda_pull_array(l.delta_gpu, l.delta, l.batch*l.inputs);
			qsort(l.delta, l.batch*l.inputs, sizeof(float), float_abs_compare);
			int n = (1-l.ratio) * l.batch*l.inputs;
			float thresh = l.delta[n];
			thresh = 0;
			printf("%f\n", thresh);
			supp_ongpu(l.batch*l.inputs, thresh, l.delta_gpu, 1);
			}

			cuda_pull_array(l.output_gpu, l.output, l.batch*l.inputs);
			l.cost[0] = sum_array(l.output, l.batch*l.inputs);
			}

			void backward_cost_layer_gpu(const cost_layer layer, cl_mem input, cl_mem delta)
			void backward_cost_layer_gpu(const cost_layer l, network_state state)
			{
			copy_ongpu(layer.batch*layer.inputs, layer.delta_cl, 1, delta, 1);
			axpy_ongpu(l.batch*l.inputs, l.scale, l.delta_gpu, 1, state.delta, 1);
			}
			#endif