~speedprog/mtg/mtg_card_detector.git

			@@ -1,72 +1,423 @@
			int detection_out_height(detection_layer layer)
			#include "detection_layer.h"
			#include "activations.h"
			#include "softmax_layer.h"
			#include "blas.h"
			#include "cuda.h"
			#include "utils.h"
			#include <stdio.h>
			#include <string.h>
			#include <stdlib.h>

			int get_detection_layer_locations(detection_layer l)
			{
			return layer.size + layer.h*layer.stride;
			return l.inputs / (l.classes+l.coords+l.joint+(l.background \|\| l.objectness));
			}

			int detection_out_width(detection_layer layer)
			int get_detection_layer_output_size(detection_layer l)
			{
			return layer.size + layer.w*layer.stride;
			return get_detection_layer_locations(l)*((l.background \|\| l.objectness) + l.classes + l.coords);
			}

			detection_layer *make_detection_layer(int batch, int h, int w, int c, int n, int size, int stride, ACTIVATION activation)
			detection_layer make_detection_layer(int batch, int inputs, int classes, int coords, int joint, int rescore, int background, int objectness)
			{
			int i;
			size = 2*(size/2)+1; //HA! And you thought you'd use an even sized filter...
			detection_layer *layer = calloc(1, sizeof(detection_layer));
			layer->h = h;
			layer->w = w;
			layer->c = c;
			layer->n = n;
			layer->batch = batch;
			layer->stride = stride;
			layer->size = size;
			assert(c%n == 0);
			detection_layer l = {0};
			l.type = DETECTION;

			l.batch = batch;
			l.inputs = inputs;
			l.classes = classes;
			l.coords = coords;
			l.rescore = rescore;
			l.objectness = objectness;
			l.joint = joint;
			l.cost = calloc(1, sizeof(float));
			l.does_cost=1;
			l.background = background;
			int outputs = get_detection_layer_output_size(l);
			l.outputs = outputs;
			l.output = calloc(batch*outputs, sizeof(float));
			l.delta = calloc(batch*outputs, sizeof(float));
			#ifdef GPU
			l.output_gpu = cuda_make_array(0, batch*outputs);
			l.delta_gpu = cuda_make_array(0, batch*outputs);
			#endif

			layer->filters = calloc(csizesize, sizeof(float));
			layer->filter_updates = calloc(csizesize, sizeof(float));
			layer->filter_momentum = calloc(csizesize, sizeof(float));

			float scale = 1./(sizesizec);
			for(i = 0; i < cnsizesize; ++i) layer->filters[i] = scale(rand_uniform());

			int out_h = detection_out_height(*layer);
			int out_w = detection_out_width(*layer);

			layer->output = calloc(layer->batch * out_h * out_w * n, sizeof(float));
			layer->delta = calloc(layer->batch * out_h * out_w * n, sizeof(float));

			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);
			fprintf(stderr, "Detection Layer\n");
			srand(0);

			return layer;
			return l;
			}

			void forward_detection_layer(const detection_layer layer, float *in)
			typedef struct{
			float dx, dy, dw, dh;
			} dbox;

			dbox derivative(box a, box b)
			{
			int out_h = detection_out_height(layer);
			int out_w = detection_out_width(layer);
			int i,j,fh, fw,c;
			memset(layer.output, 0, layer->batchlayer->nout_hout_wsizeof(float));
			for(c = 0; c < layer.c; ++c){
			for(i = 0; i < layer.h; ++i){
			for(j = 0; j < layer.w; ++j){
			float val = layer->input[j+(i + clayer.h)layer.w];
			for(fh = 0; fh < layer.size; ++fh){
			for(fw = 0; fw < layer.size; ++fw){
			int h = i*layer.stride + fh;
			int w = j*layer.stride + fw;
			layer.output[w+(h+c/nout_h)out_w] += vallayer->filters[fw+(fh+clayer.size)*layer.size];
			}
			dbox d;
			d.dx = 0;
			d.dw = 0;
			float l1 = a.x - a.w/2;
			float l2 = b.x - b.w/2;
			if (l1 > l2){
			d.dx -= 1;
			d.dw += .5;
			}
			float r1 = a.x + a.w/2;
			float r2 = b.x + b.w/2;
			if(r1 < r2){
			d.dx += 1;
			d.dw += .5;
			}
			if (l1 > r2) {
			d.dx = -1;
			d.dw = 0;
			}
			if (r1 < l2){
			d.dx = 1;
			d.dw = 0;
			}

			d.dy = 0;
			d.dh = 0;
			float t1 = a.y - a.h/2;
			float t2 = b.y - b.h/2;
			if (t1 > t2){
			d.dy -= 1;
			d.dh += .5;
			}
			float b1 = a.y + a.h/2;
			float b2 = b.y + b.h/2;
			if(b1 < b2){
			d.dy += 1;
			d.dh += .5;
			}
			if (t1 > b2) {
			d.dy = -1;
			d.dh = 0;
			}
			if (b1 < t2){
			d.dy = 1;
			d.dh = 0;
			}
			return d;
			}

			float overlap(float x1, float w1, float x2, float w2)
			{
			float l1 = x1 - w1/2;
			float l2 = x2 - w2/2;
			float left = l1 > l2 ? l1 : l2;
			float r1 = x1 + w1/2;
			float r2 = x2 + w2/2;
			float right = r1 < r2 ? r1 : r2;
			return right - left;
			}

			float box_intersection(box a, box b)
			{
			float w = overlap(a.x, a.w, b.x, b.w);
			float h = overlap(a.y, a.h, b.y, b.h);
			if(w < 0 \|\| h < 0) return 0;
			float area = w*h;
			return area;
			}

			float box_union(box a, box b)
			{
			float i = box_intersection(a, b);
			float u = a.wa.h + b.wb.h - i;
			return u;
			}

			float box_iou(box a, box b)
			{
			return box_intersection(a, b)/box_union(a, b);
			}

			dbox dintersect(box a, box b)
			{
			float w = overlap(a.x, a.w, b.x, b.w);
			float h = overlap(a.y, a.h, b.y, b.h);
			dbox dover = derivative(a, b);
			dbox di;

			di.dw = dover.dw*h;
			di.dx = dover.dx*h;
			di.dh = dover.dh*w;
			di.dy = dover.dy*w;

			return di;
			}

			dbox dunion(box a, box b)
			{
			dbox du;

			dbox di = dintersect(a, b);
			du.dw = a.h - di.dw;
			du.dh = a.w - di.dh;
			du.dx = -di.dx;
			du.dy = -di.dy;

			return du;
			}

			dbox diou(box a, box b);

			void test_dunion()
			{
			box a = {0, 0, 1, 1};
			box dxa= {0+.0001, 0, 1, 1};
			box dya= {0, 0+.0001, 1, 1};
			box dwa= {0, 0, 1+.0001, 1};
			box dha= {0, 0, 1, 1+.0001};

			box b = {.5, .5, .2, .2};
			dbox di = dunion(a,b);
			printf("Union: %f %f %f %f\n", di.dx, di.dy, di.dw, di.dh);
			float inter = box_union(a, b);
			float xinter = box_union(dxa, b);
			float yinter = box_union(dya, b);
			float winter = box_union(dwa, b);
			float hinter = box_union(dha, b);
			xinter = (xinter - inter)/(.0001);
			yinter = (yinter - inter)/(.0001);
			winter = (winter - inter)/(.0001);
			hinter = (hinter - inter)/(.0001);
			printf("Union Manual %f %f %f %f\n", xinter, yinter, winter, hinter);
			}
			void test_dintersect()
			{
			box a = {0, 0, 1, 1};
			box dxa= {0+.0001, 0, 1, 1};
			box dya= {0, 0+.0001, 1, 1};
			box dwa= {0, 0, 1+.0001, 1};
			box dha= {0, 0, 1, 1+.0001};

			box b = {.5, .5, .2, .2};
			dbox di = dintersect(a,b);
			printf("Inter: %f %f %f %f\n", di.dx, di.dy, di.dw, di.dh);
			float inter = box_intersection(a, b);
			float xinter = box_intersection(dxa, b);
			float yinter = box_intersection(dya, b);
			float winter = box_intersection(dwa, b);
			float hinter = box_intersection(dha, b);
			xinter = (xinter - inter)/(.0001);
			yinter = (yinter - inter)/(.0001);
			winter = (winter - inter)/(.0001);
			hinter = (hinter - inter)/(.0001);
			printf("Inter Manual %f %f %f %f\n", xinter, yinter, winter, hinter);
			}

			void test_box()
			{
			test_dintersect();
			test_dunion();
			box a = {0, 0, 1, 1};
			box dxa= {0+.00001, 0, 1, 1};
			box dya= {0, 0+.00001, 1, 1};
			box dwa= {0, 0, 1+.00001, 1};
			box dha= {0, 0, 1, 1+.00001};

			box b = {.5, 0, .2, .2};

			float iou = box_iou(a,b);
			iou = (1-iou)*(1-iou);
			printf("%f\n", iou);
			dbox d = diou(a, b);
			printf("%f %f %f %f\n", d.dx, d.dy, d.dw, d.dh);

			float xiou = box_iou(dxa, b);
			float yiou = box_iou(dya, b);
			float wiou = box_iou(dwa, b);
			float hiou = box_iou(dha, b);
			xiou = ((1-xiou)*(1-xiou) - iou)/(.00001);
			yiou = ((1-yiou)*(1-yiou) - iou)/(.00001);
			wiou = ((1-wiou)*(1-wiou) - iou)/(.00001);
			hiou = ((1-hiou)*(1-hiou) - iou)/(.00001);
			printf("manual %f %f %f %f\n", xiou, yiou, wiou, hiou);
			}

			dbox diou(box a, box b)
			{
			float u = box_union(a,b);
			float i = box_intersection(a,b);
			dbox di = dintersect(a,b);
			dbox du = dunion(a,b);
			dbox dd = {0,0,0,0};

			if(i <= 0 \|\| 1) {
			dd.dx = b.x - a.x;
			dd.dy = b.y - a.y;
			dd.dw = b.w - a.w;
			dd.dh = b.h - a.h;
			return dd;
			}

			dd.dx = 2pow((1-(i/u)),1)(di.dxu - du.dxi)/(u*u);
			dd.dy = 2pow((1-(i/u)),1)(di.dyu - du.dyi)/(u*u);
			dd.dw = 2pow((1-(i/u)),1)(di.dwu - du.dwi)/(u*u);
			dd.dh = 2pow((1-(i/u)),1)(di.dhu - du.dhi)/(u*u);
			return dd;
			}

			void forward_detection_layer(const detection_layer l, network_state state)
			{
			int in_i = 0;
			int out_i = 0;
			int locations = get_detection_layer_locations(l);
			int i,j;
			for(i = 0; i < l.batch*locations; ++i){
			int mask = (!state.truth \|\| state.truth[out_i + (l.background \|\| l.objectness) + l.classes + 2]);
			float scale = 1;
			if(l.joint) scale = state.input[in_i++];
			else if(l.objectness){
			l.output[out_i++] = 1-state.input[in_i++];
			scale = mask;
			}
			else if(l.background) l.output[out_i++] = scale*state.input[in_i++];

			for(j = 0; j < l.classes; ++j){
			l.output[out_i++] = scale*state.input[in_i++];
			}
			if(l.objectness){

			}else if(l.background){
			softmax_array(l.output + out_i - l.classes-l.background, l.classes+l.background, l.output + out_i - l.classes-l.background);
			activate_array(state.input+in_i, l.coords, LOGISTIC);
			}
			for(j = 0; j < l.coords; ++j){
			l.output[out_i++] = mask*state.input[in_i++];
			}
			}
			float avg_iou = 0;
			int count = 0;
			if(l.does_cost && state.train){
			*(l.cost) = 0;
			int size = get_detection_layer_output_size(l) * l.batch;
			memset(l.delta, 0, size * sizeof(float));
			for (i = 0; i < l.batch*locations; ++i) {
			int classes = l.objectness+l.classes;
			int offset = i*(classes+l.coords);
			for (j = offset; j < offset+classes; ++j) {
			*(l.cost) += pow(state.truth[j] - l.output[j], 2);
			l.delta[j] = state.truth[j] - l.output[j];
			}

			box truth;
			truth.x = state.truth[j+0]/7;
			truth.y = state.truth[j+1]/7;
			truth.w = pow(state.truth[j+2], 2);
			truth.h = pow(state.truth[j+3], 2);
			box out;
			out.x = l.output[j+0]/7;
			out.y = l.output[j+1]/7;
			out.w = pow(l.output[j+2], 2);
			out.h = pow(l.output[j+3], 2);

			if(!(truth.w*truth.h)) continue;
			float iou = box_iou(out, truth);
			avg_iou += iou;
			++count;
			dbox delta = diou(out, truth);

			l.delta[j+0] = 10 * delta.dx/7;
			l.delta[j+1] = 10 * delta.dy/7;
			l.delta[j+2] = 10 * delta.dw * 2 * sqrt(out.w);
			l.delta[j+3] = 10 * delta.dh * 2 * sqrt(out.h);


			*(l.cost) += pow((1-iou), 2);
			l.delta[j+0] = 4 * (state.truth[j+0] - l.output[j+0]);
			l.delta[j+1] = 4 * (state.truth[j+1] - l.output[j+1]);
			l.delta[j+2] = 4 * (state.truth[j+2] - l.output[j+2]);
			l.delta[j+3] = 4 * (state.truth[j+3] - l.output[j+3]);
			if(l.rescore){
			for (j = offset; j < offset+classes; ++j) {
			if(state.truth[j]) state.truth[j] = iou;
			l.delta[j] = state.truth[j] - l.output[j];
			}
			}
			}
			printf("Avg IOU: %f\n", avg_iou/count);
			}
			}

			void backward_detection_layer(const detection_layer layer, float *delta)
			void backward_detection_layer(const detection_layer l, network_state state)
			{
			int locations = get_detection_layer_locations(l);
			int i,j;
			int in_i = 0;
			int out_i = 0;
			for(i = 0; i < l.batch*locations; ++i){
			float scale = 1;
			float latent_delta = 0;
			if(l.joint) scale = state.input[in_i++];
			else if (l.objectness) state.delta[in_i++] = -l.delta[out_i++];
			else if (l.background) state.delta[in_i++] = scale*l.delta[out_i++];
			for(j = 0; j < l.classes; ++j){
			latent_delta += state.input[in_i]*l.delta[out_i];
			state.delta[in_i++] = scale*l.delta[out_i++];
			}

			if (l.objectness) {

			}else if (l.background) gradient_array(l.output + out_i, l.coords, LOGISTIC, l.delta + out_i);
			for(j = 0; j < l.coords; ++j){
			state.delta[in_i++] = l.delta[out_i++];
			}
			if(l.joint) state.delta[in_i-l.coords-l.classes-l.joint] = latent_delta;
			}
			}

			#ifdef GPU

			void forward_detection_layer_gpu(const detection_layer l, network_state state)
			{
			int outputs = get_detection_layer_output_size(l);
			float in_cpu = calloc(l.batchl.inputs, sizeof(float));
			float *truth_cpu = 0;
			if(state.truth){
			truth_cpu = calloc(l.batch*outputs, sizeof(float));
			cuda_pull_array(state.truth, truth_cpu, l.batch*outputs);
			}
			cuda_pull_array(state.input, in_cpu, l.batch*l.inputs);
			network_state cpu_state;
			cpu_state.train = state.train;
			cpu_state.truth = truth_cpu;
			cpu_state.input = in_cpu;
			forward_detection_layer(l, cpu_state);
			cuda_push_array(l.output_gpu, l.output, l.batch*outputs);
			cuda_push_array(l.delta_gpu, l.delta, l.batch*outputs);
			free(cpu_state.input);
			if(cpu_state.truth) free(cpu_state.truth);
			}

			void backward_detection_layer_gpu(detection_layer l, network_state state)
			{
			int outputs = get_detection_layer_output_size(l);

			float in_cpu = calloc(l.batchl.inputs, sizeof(float));
			float delta_cpu = calloc(l.batchl.inputs, sizeof(float));
			float *truth_cpu = 0;
			if(state.truth){
			truth_cpu = calloc(l.batch*outputs, sizeof(float));
			cuda_pull_array(state.truth, truth_cpu, l.batch*outputs);
			}
			network_state cpu_state;
			cpu_state.train = state.train;
			cpu_state.input = in_cpu;
			cpu_state.truth = truth_cpu;
			cpu_state.delta = delta_cpu;

			cuda_pull_array(state.input, in_cpu, l.batch*l.inputs);
			cuda_pull_array(l.delta_gpu, l.delta, l.batch*outputs);
			backward_detection_layer(l, cpu_state);
			cuda_push_array(state.delta, delta_cpu, l.batch*l.inputs);

			free(in_cpu);
			free(delta_cpu);
			}
			#endif