~speedprog/mtg/mtg_card_detector.git

			@@ -1,18 +1,20 @@
			#include "image.h"
			#include "utils.h"
			#include "blas.h"
			#include "cuda.h"
			#include <stdio.h>
			#include <math.h>

			#define STB_IMAGE_IMPLEMENTATION
			#include "stb_image.h"
			#define STB_IMAGE_WRITE_IMPLEMENTATION
			#include "stb_image_write.h"

			#ifdef OPENCV
			#include "opencv2/highgui/highgui_c.h"
			#include "opencv2/imgproc/imgproc_c.h"
			#endif

			#define STB_IMAGE_IMPLEMENTATION
			#include "stb_image.h"
			#define STB_IMAGE_WRITE_IMPLEMENTATION
			#include "stb_image_write.h"

			int windows = 0;

			@@ -29,10 +31,66 @@
			return r;
			}

			void composite_image(image source, image dest, int dx, int dy)
			{
			int x,y,k;
			for(k = 0; k < source.c; ++k){
			for(y = 0; y < source.h; ++y){
			for(x = 0; x < source.w; ++x){
			float val = get_pixel(source, x, y, k);
			float val2 = get_pixel_extend(dest, dx+x, dy+y, k);
			set_pixel(dest, dx+x, dy+y, k, val * val2);
			}
			}
			}
			}

			image border_image(image a, int border)
			{
			image b = make_image(a.w + 2border, a.h + 2border, a.c);
			int x,y,k;
			for(k = 0; k < b.c; ++k){
			for(y = 0; y < b.h; ++y){
			for(x = 0; x < b.w; ++x){
			float val = get_pixel_extend(a, x - border, y - border, k);
			set_pixel(b, x, y, k, val);
			}
			}
			}
			return b;
			}

			image tile_images(image a, image b, int dx)
			{
			if(a.w == 0) return copy_image(b);
			image c = make_image(a.w + b.w + dx, (a.h > b.h) ? a.h : b.h, (a.c > b.c) ? a.c : b.c);
			fill_cpu(c.wc.hc.c, 1, c.data, 1);
			embed_image(a, c, 0, 0);
			composite_image(b, c, a.w + dx, 0);
			return c;
			}

			image get_label(image characters, char string)
			{
			image label = make_empty_image(0,0,0);
			while(*string){
			image l = characters[(int)*string];
			image n = tile_images(label, l, -4);
			free_image(label);
			label = n;
			++string;
			}
			image b = border_image(label, label.h*.25);
			free_image(label);
			return b;
			}

			void draw_label(image a, int r, int c, image label, const float *rgb)
			{
			float ratio = (float) label.w / label.h;
			int h = label.h;
			int h = a.h * .04;
			h = label.h;
			h = a.h * .06;
			int w = ratio * h;
			image rl = resize_image(label, w, h);
			if (r - h >= 0) r = r - h;
			@@ -106,7 +164,19 @@
			}
			}

			void draw_detections(image im, int num, float thresh, box boxes, float probs, char names, image labels, int classes)
			image *load_alphabet()
			{
			int i;
			image *alphabet = calloc(128, sizeof(image));
			for(i = 32; i < 127; ++i){
			char buff[256];
			sprintf(buff, "data/labels/%d.png", i);
			alphabet[i] = load_image_color(buff, 0, 0);
			}
			return alphabet;
			}

			void draw_detections(image im, int num, float thresh, box boxes, float probs, char names, image alphabet, int classes)
			{
			int i;

			@@ -114,13 +184,17 @@
			int class = max_index(probs[i], classes);
			float prob = probs[i][class];
			if(prob > thresh){
			int width = pow(prob, 1./2.)*10+1;
			printf("%s: %.2f\n", names[class], prob);
			int offset = class*17 % classes;
			float red = get_color(0,offset,classes);
			//int width = pow(prob, 1./2.)*30+1;
			int width = im.h * .012;
			printf("%s: %.0f%%\n", names[class], prob*100);
			int offset = class*1 % classes;
			float red = get_color(2,offset,classes);
			float green = get_color(1,offset,classes);
			float blue = get_color(2,offset,classes);
			float blue = get_color(0,offset,classes);
			float rgb[3];

			//width = prob*20+2;

			rgb[0] = red;
			rgb[1] = green;
			rgb[2] = blue;
			@@ -137,11 +211,50 @@
			if(bot > im.h-1) bot = im.h-1;

			draw_box_width(im, left, top, right, bot, width, red, green, blue);
			if (labels) draw_label(im, top + width, left, labels[class], rgb);
			if (alphabet) {
			image label = get_label(alphabet, names[class]);
			draw_label(im, top + width, left, label, rgb);
			}
			}
			}
			}

			void transpose_image(image im)
			{
			assert(im.w == im.h);
			int n, m;
			int c;
			for(c = 0; c < im.c; ++c){
			for(n = 0; n < im.w-1; ++n){
			for(m = n + 1; m < im.w; ++m){
			float swap = im.data[m + im.w(n + im.hc)];
			im.data[m + im.w(n + im.hc)] = im.data[n + im.w(m + im.hc)];
			im.data[n + im.w(m + im.hc)] = swap;
			}
			}
			}
			}

			void rotate_image_cw(image im, int times)
			{
			assert(im.w == im.h);
			times = (times + 400) % 4;
			int i, x, y, c;
			int n = im.w;
			for(i = 0; i < times; ++i){
			for(c = 0; c < im.c; ++c){
			for(x = 0; x < n/2; ++x){
			for(y = 0; y < (n-1)/2 + 1; ++y){
			float temp = im.data[y + im.w(x + im.hc)];
			im.data[y + im.w(x + im.hc)] = im.data[n-1-x + im.w(y + im.hc)];
			im.data[n-1-x + im.w(y + im.hc)] = im.data[n-1-y + im.w(n-1-x + im.hc)];
			im.data[n-1-y + im.w(n-1-x + im.hc)] = im.data[x + im.w(n-1-y + im.hc)];
			im.data[x + im.w(n-1-y + im.hc)] = temp;
			}
			}
			}
			}
			}

			void flip_image(image a)
			{
			@@ -213,6 +326,26 @@

			void normalize_image(image p)
			{
			int i;
			float min = 9999999;
			float max = -999999;

			for(i = 0; i < p.hp.wp.c; ++i){
			float v = p.data[i];
			if(v < min) min = v;
			if(v > max) max = v;
			}
			if(max - min < .000000001){
			min = 0;
			max = 1;
			}
			for(i = 0; i < p.cp.wp.h; ++i){
			p.data[i] = (p.data[i] - min)/(max-min);
			}
			}

			void normalize_image2(image p)
			{
			float *min = calloc(p.c, sizeof(float));
			float *max = calloc(p.c, sizeof(float));
			int i,j;
			@@ -285,7 +418,6 @@
			}
			free_image(copy);
			if(0){
			//if(disp->height < 448 \|\| disp->width < 448 \|\| disp->height > 1000){
			int w = 448;
			int h = w*p.h/p.w;
			if(h > 1000){
			@@ -312,28 +444,67 @@
			#endif
			}

			void save_image(image im, const char *name)
			#ifdef OPENCV

			image ipl_to_image(IplImage* src)
			{
			char buff[256];
			//sprintf(buff, "%s (%d)", name, windows);
			sprintf(buff, "%s.png", name);
			unsigned char data = calloc(im.wim.h*im.c, sizeof(char));
			int i,k;
			for(k = 0; k < im.c; ++k){
			for(i = 0; i < im.w*im.h; ++i){
			data[iim.c+k] = (unsigned char) (255im.data[i + kim.wim.h]);
			unsigned char data = (unsigned char )src->imageData;
			int h = src->height;
			int w = src->width;
			int c = src->nChannels;
			int step = src->widthStep;
			image out = make_image(w, h, c);
			int i, j, k, count=0;;

			for(k= 0; k < c; ++k){
			for(i = 0; i < h; ++i){
			for(j = 0; j < w; ++j){
			out.data[count++] = data[istep + jc + k]/255.;
			}
			}
			}
			int success = stbi_write_png(buff, im.w, im.h, im.c, data, im.w*im.c);
			free(data);
			if(!success) fprintf(stderr, "Failed to write image %s\n", buff);
			return out;
			}

			#ifdef OPENCV
			void save_image_jpg(image p, char *name)
			image load_image_cv(char *filename, int channels)
			{
			IplImage* src = 0;
			int flag = -1;
			if (channels == 0) flag = -1;
			else if (channels == 1) flag = 0;
			else if (channels == 3) flag = 1;
			else {
			fprintf(stderr, "OpenCV can't force load with %d channels\n", channels);
			}

			if( (src = cvLoadImage(filename, flag)) == 0 )
			{
			fprintf(stderr, "Cannot load image \"%s\"\n", filename);
			char buff[256];
			sprintf(buff, "echo %s >> bad.list", filename);
			system(buff);
			return make_image(10,10,3);
			//exit(0);
			}
			image out = ipl_to_image(src);
			cvReleaseImage(&src);
			rgbgr_image(out);
			return out;
			}

			image get_image_from_stream(CvCapture *cap)
			{
			IplImage* src = cvQueryFrame(cap);
			if (!src) return make_empty_image(0,0,0);
			image im = ipl_to_image(src);
			rgbgr_image(im);
			return im;
			}

			void save_image_jpg(image p, const char *name)
			{
			image copy = copy_image(p);
			rgbgr_image(copy);
			if(p.c == 3) rgbgr_image(copy);
			int x,y,k;

			char buff[256];
			@@ -354,6 +525,28 @@
			}
			#endif

			void save_image(image im, const char *name)
			{
			#ifdef OPENCV
			save_image_jpg(im, name);
			#else
			char buff[256];
			//sprintf(buff, "%s (%d)", name, windows);
			sprintf(buff, "%s.png", name);
			unsigned char data = calloc(im.wim.h*im.c, sizeof(char));
			int i,k;
			for(k = 0; k < im.c; ++k){
			for(i = 0; i < im.w*im.h; ++i){
			data[iim.c+k] = (unsigned char) (255im.data[i + kim.wim.h]);
			}
			}
			int success = stbi_write_png(buff, im.w, im.h, im.c, data, im.w*im.c);
			free(data);
			if(!success) fprintf(stderr, "Failed to write image %s\n", buff);
			#endif
			}


			void show_image_layers(image p, char *name)
			{
			int i;
			@@ -390,6 +583,17 @@
			return out;
			}

			image make_random_image(int w, int h, int c)
			{
			image out = make_empty_image(w,h,c);
			out.data = calloc(hwc, sizeof(float));
			int i;
			for(i = 0; i < whc; ++i){
			out.data[i] = (rand_normal() * .25) + .5;
			}
			return out;
			}

			image float_to_image(int w, int h, int c, float *data)
			{
			image out = make_empty_image(w,h,c);
			@@ -397,6 +601,26 @@
			return out;
			}


			image rotate_crop_image(image im, float rad, float s, int w, int h, float dx, float dy, float aspect)
			{
			int x, y, c;
			float cx = im.w/2.;
			float cy = im.h/2.;
			image rot = make_image(w, h, im.c);
			for(c = 0; c < im.c; ++c){
			for(y = 0; y < h; ++y){
			for(x = 0; x < w; ++x){
			float rx = cos(rad)((x - w/2.)/saspect + dx/saspect) - sin(rad)((y - h/2.)/s + dy/s) + cx;
			float ry = sin(rad)((x - w/2.)/saspect + dx/saspect) + cos(rad)((y - h/2.)/s + dy/s) + cy;
			float val = bilinear_interpolate(im, rx, ry, c);
			set_pixel(rot, x, y, c, val);
			}
			}
			}
			return rot;
			}

			image rotate_image(image im, float rad)
			{
			int x, y, c;
			@@ -438,6 +662,8 @@
			int r = j + dy;
			int c = i + dx;
			float val = 0;
			r = constrain_int(r, 0, im.h-1);
			c = constrain_int(c, 0, im.w-1);
			if (r >= 0 && r < im.h && c >= 0 && c < im.w) {
			val = get_pixel(im, c, r, k);
			}
			@@ -448,6 +674,118 @@
			return cropped;
			}

			int best_3d_shift_r(image a, image b, int min, int max)
			{
			if(min == max) return min;
			int mid = floor((min + max) / 2.);
			image c1 = crop_image(b, 0, mid, b.w, b.h);
			image c2 = crop_image(b, 0, mid+1, b.w, b.h);
			float d1 = dist_array(c1.data, a.data, a.wa.ha.c, 10);
			float d2 = dist_array(c2.data, a.data, a.wa.ha.c, 10);
			free_image(c1);
			free_image(c2);
			if(d1 < d2) return best_3d_shift_r(a, b, min, mid);
			else return best_3d_shift_r(a, b, mid+1, max);
			}

			int best_3d_shift(image a, image b, int min, int max)
			{
			int i;
			int best = 0;
			float best_distance = FLT_MAX;
			for(i = min; i <= max; i += 2){
			image c = crop_image(b, 0, i, b.w, b.h);
			float d = dist_array(c.data, a.data, a.wa.ha.c, 100);
			if(d < best_distance){
			best_distance = d;
			best = i;
			}
			printf("%d %f\n", i, d);
			free_image(c);
			}
			return best;
			}

			void composite_3d(char f1, char f2, char *out, int delta)
			{
			if(!out) out = "out";
			image a = load_image(f1, 0,0,0);
			image b = load_image(f2, 0,0,0);
			int shift = best_3d_shift_r(a, b, -a.h/100, a.h/100);

			image c1 = crop_image(b, 10, shift, b.w, b.h);
			float d1 = dist_array(c1.data, a.data, a.wa.ha.c, 100);
			image c2 = crop_image(b, -10, shift, b.w, b.h);
			float d2 = dist_array(c2.data, a.data, a.wa.ha.c, 100);

			if(d2 < d1 && 0){
			image swap = a;
			a = b;
			b = swap;
			shift = -shift;
			printf("swapped, %d\n", shift);
			}
			else{
			printf("%d\n", shift);
			}

			image c = crop_image(b, delta, shift, a.w, a.h);
			int i;
			for(i = 0; i < c.w*c.h; ++i){
			c.data[i] = a.data[i];
			}
			#ifdef OPENCV
			save_image_jpg(c, out);
			#else
			save_image(c, out);
			#endif
			}

			image resize_min(image im, int min)
			{
			int w = im.w;
			int h = im.h;
			if(w < h){
			h = (h * min) / w;
			w = min;
			} else {
			w = (w * min) / h;
			h = min;
			}
			if(w == im.w && h == im.h) return im;
			image resized = resize_image(im, w, h);
			return resized;
			}

			image random_crop_image(image im, int w, int h)
			{
			int dx = rand_int(0, im.w - w);
			int dy = rand_int(0, im.h - h);
			image crop = crop_image(im, dx, dy, w, h);
			return crop;
			}

			image random_augment_image(image im, float angle, float aspect, int low, int high, int size)
			{
			aspect = rand_scale(aspect);
			int r = rand_int(low, high);
			int min = (im.h < im.waspect) ? im.h : im.waspect;
			float scale = (float)r / min;

			float rad = rand_uniform(-angle, angle) * TWO_PI / 360.;

			float dx = (im.w*scale/aspect - size) / 2.;
			float dy = (im.h*scale - size) / 2.;
			if(dx < 0) dx = 0;
			if(dy < 0) dy = 0;
			dx = rand_uniform(-dx, dx);
			dy = rand_uniform(-dy, dy);

			image crop = rotate_crop_image(im, rad, scale, size, size, dx, dy, aspect);

			return crop;
			}

			float three_way_max(float a, float b, float c)
			{
			return (a > b) ? ( (a > c) ? a : c) : ( (b > c) ? b : c) ;
			@@ -476,7 +814,7 @@
			v = max;
			if(max == 0){
			s = 0;
			h = -1;
			h = 0;
			}else{
			s = delta/max;
			if(r == max){
			@@ -487,6 +825,7 @@
			h = 4 + (r - g) / delta;
			}
			if (h < 0) h += 6;
			h = h/6.;
			}
			set_pixel(im, i, j, 0, h);
			set_pixel(im, i, j, 1, s);
			@@ -504,7 +843,7 @@
			float f, p, q, t;
			for(j = 0; j < im.h; ++j){
			for(i = 0; i < im.w; ++i){
			h = get_pixel(im, i , j, 0);
			h = 6 * get_pixel(im, i , j, 0);
			s = get_pixel(im, i , j, 1);
			v = get_pixel(im, i , j, 2);
			if (s == 0) {
			@@ -591,6 +930,29 @@
			}
			}

			void translate_image_channel(image im, int c, float v)
			{
			int i, j;
			for(j = 0; j < im.h; ++j){
			for(i = 0; i < im.w; ++i){
			float pix = get_pixel(im, i, j, c);
			pix = pix+v;
			set_pixel(im, i, j, c, pix);
			}
			}
			}

			image binarize_image(image im)
			{
			image c = copy_image(im);
			int i;
			for(i = 0; i < im.w * im.h * im.c; ++i){
			if(c.data[i] > .5) c.data[i] = 1;
			else c.data[i] = 0;
			}
			return c;
			}

			void saturate_image(image im, float sat)
			{
			rgb_to_hsv(im);
			@@ -599,6 +961,19 @@
			constrain_image(im);
			}

			void hue_image(image im, float hue)
			{
			rgb_to_hsv(im);
			int i;
			for(i = 0; i < im.w*im.h; ++i){
			im.data[i] = im.data[i] + hue;
			if (im.data[i] > 1) im.data[i] -= 1;
			if (im.data[i] < 0) im.data[i] += 1;
			}
			hsv_to_rgb(im);
			constrain_image(im);
			}

			void exposure_image(image im, float sat)
			{
			rgb_to_hsv(im);
			@@ -607,6 +982,29 @@
			constrain_image(im);
			}

			void distort_image(image im, float hue, float sat, float val)
			{
			rgb_to_hsv(im);
			scale_image_channel(im, 1, sat);
			scale_image_channel(im, 2, val);
			int i;
			for(i = 0; i < im.w*im.h; ++i){
			im.data[i] = im.data[i] + hue;
			if (im.data[i] > 1) im.data[i] -= 1;
			if (im.data[i] < 0) im.data[i] += 1;
			}
			hsv_to_rgb(im);
			constrain_image(im);
			}

			void random_distort_image(image im, float hue, float saturation, float exposure)
			{
			float dhue = rand_uniform(-hue, hue);
			float dsat = rand_scale(saturation);
			float dexp = rand_scale(exposure);
			distort_image(im, dhue, dsat, dexp);
			}

			void saturate_exposure_image(image im, float sat, float exposure)
			{
			rgb_to_hsv(im);
			@@ -616,23 +1014,6 @@
			constrain_image(im);
			}

			/*
			image saturate_image(image im, float sat)
			{
			image gray = grayscale_image(im);
			image blend = blend_image(im, gray, sat);
			free_image(gray);
			constrain_image(blend);
			return blend;
			}

			image brightness_image(image im, float b)
			{
			image bright = make_image(im.w, im.h, im.c);
			return bright;
			}
			*/

			float bilinear_interpolate(image im, float x, float y, int c)
			{
			int ix = (int) floorf(x);
			@@ -692,85 +1073,56 @@
			return resized;
			}


			void test_resize(char *filename)
			{
			image im = load_image(filename, 0,0, 3);
			float mag = mag_array(im.data, im.wim.him.c);
			printf("L2 Norm: %f\n", mag);
			image gray = grayscale_image(im);

			image sat2 = copy_image(im);
			saturate_image(sat2, 2);
			image c1 = copy_image(im);
			image c2 = copy_image(im);
			image c3 = copy_image(im);
			image c4 = copy_image(im);
			distort_image(c1, .1, 1.5, 1.5);
			distort_image(c2, -.1, .66666, .66666);
			distort_image(c3, .1, 1.5, .66666);
			distort_image(c4, .1, .66666, 1.5);

			image sat5 = copy_image(im);
			saturate_image(sat5, .5);

			image exp2 = copy_image(im);
			exposure_image(exp2, 2);

			image exp5 = copy_image(im);
			exposure_image(exp5, .5);

			image r = resize_image(im, im.w/2, im.h/2);

			image black = make_image(im.w, im.h, im.c);
			shortcut_cpu(black.data, im.w, im.h, im.c, 1, 2, r.data, 1, r.c);

			show_image(im, "Original");
			show_image(im, "Original");
			show_image(gray, "Gray");
			show_image(black, "Black");
			show_image(sat2, "Saturation-2");
			show_image(sat5, "Saturation-.5");
			show_image(exp2, "Exposure-2");
			show_image(exp5, "Exposure-.5");
			show_image(c1, "C1");
			show_image(c2, "C2");
			show_image(c3, "C3");
			show_image(c4, "C4");
			#ifdef OPENCV
			cvWaitKey(0);
			while(1){
			image aug = random_augment_image(im, 0, 320, 448, 320, .75);
			show_image(aug, "aug");
			free_image(aug);


			float exposure = 1.15;
			float saturation = 1.15;
			float hue = .05;

			image c = copy_image(im);

			float dexp = rand_scale(exposure);
			float dsat = rand_scale(saturation);
			float dhue = rand_uniform(-hue, hue);

			distort_image(c, dhue, dsat, dexp);
			show_image(c, "rand");
			printf("%f %f %f\n", dhue, dsat, dexp);
			free_image(c);
			cvWaitKey(0);
			}
			#endif
			}

			#ifdef OPENCV
			image ipl_to_image(IplImage* src)
			{
			unsigned char data = (unsigned char )src->imageData;
			int h = src->height;
			int w = src->width;
			int c = src->nChannels;
			int step = src->widthStep;
			image out = make_image(w, h, c);
			int i, j, k, count=0;;

			for(k= 0; k < c; ++k){
			for(i = 0; i < h; ++i){
			for(j = 0; j < w; ++j){
			out.data[count++] = data[istep + jc + k]/255.;
			}
			}
			}
			return out;
			}

			image load_image_cv(char *filename, int channels)
			{
			IplImage* src = 0;
			int flag = -1;
			if (channels == 0) flag = -1;
			else if (channels == 1) flag = 0;
			else if (channels == 3) flag = 1;
			else {
			fprintf(stderr, "OpenCV can't force load with %d channels\n", channels);
			}

			if( (src = cvLoadImage(filename, flag)) == 0 )
			{
			printf("Cannot load image \"%s\"\n", filename);
			exit(0);
			}
			image out = ipl_to_image(src);
			cvReleaseImage(&src);
			rgbgr_image(out);
			return out;
			}

			#endif


			image load_image_stb(char *filename, int channels)
			{
			@@ -834,11 +1186,16 @@
			}
			float get_pixel_extend(image m, int x, int y, int c)
			{
			if(x < 0 \|\| x >= m.w \|\| y < 0 \|\| y >= m.h \|\| c < 0 \|\| c >= m.c) return 0;
			if(x < 0) x = 0;
			if(x >= m.w) x = m.w-1;
			if(y < 0) y = 0;
			if(y >= m.h) y = m.h-1;
			if(c < 0 \|\| c >= m.c) return 0;
			return get_pixel(m, x, y, c);
			}
			void set_pixel(image m, int x, int y, int c, float val)
			{
			if (x < 0 \|\| y < 0 \|\| c < 0 \|\| x >= m.w \|\| y >= m.h \|\| c >= m.c) return;
			assert(x < m.w && y < m.h && c < m.c);
			m.data[cm.hm.w + y*m.w + x] = val;
			}
			@@ -936,6 +1293,14 @@
			return filters;
			}

			void show_image_normalized(image im, const char *name)
			{
			image c = copy_image(im);
			normalize_image(c);
			show_image(c, name);
			free_image(c);
			}

			void show_images(image ims, int n, char window)
			{
			image m = collapse_images_vert(ims, n);
			@@ -949,14 +1314,14 @@
			image sized = resize_image(m, w, h);
			*/
			normalize_image(m);
			image sized = resize_image(m, m.w, m.h);
			save_image(sized, window);
			show_image(sized, window);
			free_image(sized);
			save_image(m, window);
			show_image(m, window);
			free_image(m);
			}

			void free_image(image m)
			{
			free(m.data);
			if(m.data){
			free(m.data);
			}
			}