~speedprog/mtg/mtg_card_detector.git

			@@ -1,12 +1,32 @@
			#include "image.h"
			#include "utils.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"

			int windows = 0;

			void draw_box(image a, int x1, int y1, int x2, int y2)
			float colors[6][3] = { {1,0,1}, {0,0,1},{0,1,1},{0,1,0},{1,1,0},{1,0,0} };

			float get_color(int c, int x, int max)
			{
			int i, c;
			float ratio = ((float)x/max)*5;
			int i = floor(ratio);
			int j = ceil(ratio);
			ratio -= i;
			float r = (1-ratio) * colors[i][c] + ratio*colors[j][c];
			//printf("%f\n", r);
			return r;
			}

			void draw_box(image a, int x1, int y1, int x2, int y2, float r, float g, float b)
			{
			//normalize_image(a);
			int i;
			if(x1 < 0) x1 = 0;
			if(x1 >= a.w) x1 = a.w-1;
			if(x2 < 0) x2 = 0;
			@@ -17,30 +37,39 @@
			if(y2 < 0) y2 = 0;
			if(y2 >= a.h) y2 = a.h-1;

			for(c = 0; c < a.c; ++c){
			for(i = x1; i < x2; ++i){
			a.data[i + y1a.w + ca.w*a.h] = (c==0)?1:-1;
			a.data[i + y2a.w + ca.w*a.h] = (c==0)?1:-1;
			}
			for(i = x1; i < x2; ++i){
			a.data[i + y1a.w + 0a.w*a.h] = b;
			a.data[i + y2a.w + 0a.w*a.h] = b;

			a.data[i + y1a.w + 1a.w*a.h] = g;
			a.data[i + y2a.w + 1a.w*a.h] = g;

			a.data[i + y1a.w + 2a.w*a.h] = r;
			a.data[i + y2a.w + 2a.w*a.h] = r;
			}
			for(c = 0; c < a.c; ++c){
			for(i = y1; i < y2; ++i){
			a.data[x1 + ia.w + ca.w*a.h] = (c==0)?1:-1;
			a.data[x2 + ia.w + ca.w*a.h] = (c==0)?1:-1;
			}
			for(i = y1; i < y2; ++i){
			a.data[x1 + ia.w + 0a.w*a.h] = b;
			a.data[x2 + ia.w + 0a.w*a.h] = b;

			a.data[x1 + ia.w + 1a.w*a.h] = g;
			a.data[x2 + ia.w + 1a.w*a.h] = g;

			a.data[x1 + ia.w + 2a.w*a.h] = r;
			a.data[x2 + ia.w + 2a.w*a.h] = r;
			}
			}

			void jitter_image(image a, int h, int w, int dh, int dw)
			void flip_image(image a)
			{
			int i,j,k;
			for(k = 0; k < a.c; ++k){
			for(i = 0; i < h; ++i){
			for(j = 0; j < w; ++j){
			int src = j + dw + (i+dh)a.w + ka.w*a.h;
			int dst = j + iw + kw*h;
			//printf("%d %d\n", src, dst);
			a.data[dst] = a.data[src];
			for(i = 0; i < a.h; ++i){
			for(j = 0; j < a.w/2; ++j){
			int index = j + a.w(i + a.h(k));
			int flip = (a.w - j - 1) + a.w(i + a.h(k));
			float swap = a.data[flip];
			a.data[flip] = a.data[index];
			a.data[index] = swap;
			}
			}
			}
			@@ -49,7 +78,7 @@
			image image_distance(image a, image b)
			{
			int i,j;
			image dist = make_image(a.h, a.w, 1);
			image dist = make_image(a.w, a.h, 1);
			for(i = 0; i < a.c; ++i){
			for(j = 0; j < a.h*a.w; ++j){
			dist.data[j] += pow(a.data[ia.ha.w+j]-b.data[ia.ha.w+j],2);
			@@ -61,20 +90,14 @@
			return dist;
			}

			void subtract_image(image a, image b)
			void embed_image(image source, image dest, int dx, int dy)
			{
			int i;
			for(i = 0; i < a.ha.wa.c; ++i) a.data[i] -= b.data[i];
			}

			void embed_image(image source, image dest, int h, int w)
			{
			int i,j,k;
			int x,y,k;
			for(k = 0; k < source.c; ++k){
			for(i = 0; i < source.h; ++i){
			for(j = 0; j < source.w; ++j){
			float val = get_pixel(source, i,j,k);
			set_pixel(dest, h+i, w+j, k, val);
			for(y = 0; y < source.h; ++y){
			for(x = 0; x < source.w; ++x){
			float val = get_pixel(source, x,y,k);
			set_pixel(dest, dx+x, dy+y, k, val);
			}
			}
			}
			@@ -84,20 +107,24 @@
			{
			int h = source.h;
			h = (h+border)*source.c - border;
			image dest = make_image(h, source.w, 1);
			image dest = make_image(source.w, h, 1);
			int i;
			for(i = 0; i < source.c; ++i){
			image layer = get_image_layer(source, i);
			int h_offset = i*(source.h+border);
			embed_image(layer, dest, h_offset, 0);
			embed_image(layer, dest, 0, h_offset);
			free_image(layer);
			}
			return dest;
			}

			void z_normalize_image(image p)
			void constrain_image(image im)
			{
			normalize_array(p.data, p.hp.wp.c);
			int i;
			for(i = 0; i < im.wim.him.c; ++i){
			if(im.data[i] < 0) im.data[i] = 0;
			if(im.data[i] > 1) im.data[i] = 1;
			}
			}

			void normalize_image(image p)
			@@ -129,24 +156,6 @@
			free(max);
			}

			float avg_image_layer(image m, int l)
			{
			int i;
			float sum = 0;
			for(i = 0; i < m.h*m.w; ++i){
			sum += m.data[lm.hm.w + i];
			}
			return sum/(m.h*m.w);
			}

			void threshold_image(image p, float t)
			{
			int i;
			for(i = 0; i < p.wp.hp.c; ++i){
			if(p.data[i] < t) p.data[i] = 0;
			}
			}

			image copy_image(image p)
			{
			image copy = p;
			@@ -155,12 +164,23 @@
			return copy;
			}


			void show_image(image p, char *name)
			void rgbgr_image(image im)
			{
			int i,j,k;
			int i;
			for(i = 0; i < im.w*im.h; ++i){
			float swap = im.data[i];
			im.data[i] = im.data[i+im.wim.h2];
			im.data[i+im.wim.h2] = swap;
			}
			}

			#ifdef OPENCV
			void show_image_cv(image p, char *name)
			{
			int x,y,k;
			image copy = copy_image(p);
			normalize_image(copy);
			rgbgr_image(copy);
			//normalize_image(copy);

			char buff[256];
			//sprintf(buff, "%s (%d)", name, windows);
			@@ -171,16 +191,16 @@
			cvNamedWindow(buff, CV_WINDOW_AUTOSIZE);
			//cvMoveWindow(buff, 100(windows%10) + 200(windows/10), 100*(windows%10));
			++windows;
			for(i = 0; i < p.h; ++i){
			for(j = 0; j < p.w; ++j){
			for(y = 0; y < p.h; ++y){
			for(x = 0; x < p.w; ++x){
			for(k= 0; k < p.c; ++k){
			disp->imageData[istep + jp.c + k] = (unsigned char)(get_pixel(copy,i,j,k)*255);
			disp->imageData[ystep + xp.c + k] = (unsigned char)(get_pixel(copy,x,y,k)*255);
			}
			}
			}
			free_image(copy);
			if(disp->height < 500 \|\| disp->width < 500 \|\| disp->height > 1000){
			int w = 500;
			if(disp->height < 448 \|\| disp->width < 448 \|\| disp->height > 1000){
			int w = 448;
			int h = w*p.h/p.w;
			if(h > 1000){
			h = 1000;
			@@ -188,18 +208,46 @@
			}
			IplImage *buffer = disp;
			disp = cvCreateImage(cvSize(w, h), buffer->depth, buffer->nChannels);
			cvResize(buffer, disp, CV_INTER_NN);
			cvResize(buffer, disp, CV_INTER_LINEAR);
			cvReleaseImage(&buffer);
			}
			cvShowImage(buff, disp);
			cvReleaseImage(&disp);
			}
			#endif

			void save_image(image p, char *name)
			void show_image(image p, char *name)
			{
			int i,j,k;
			#ifdef OPENCV
			show_image_cv(p, name);
			#else
			fprintf(stderr, "Not compiled with OpenCV, saving to %s.png instead\n", name);
			save_image(p, name);
			#endif
			}

			void save_image(image im, char *name)
			{
			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);
			if(!success) fprintf(stderr, "Failed to write image %s\n", buff);
			}

			/*
			void save_image_cv(image p, char *name)
			{
			int x,y,k;
			image copy = copy_image(p);
			normalize_image(copy);
			//normalize_image(copy);

			char buff[256];
			//sprintf(buff, "%s (%d)", name, windows);
			@@ -207,10 +255,10 @@

			IplImage *disp = cvCreateImage(cvSize(p.w,p.h), IPL_DEPTH_8U, p.c);
			int step = disp->widthStep;
			for(i = 0; i < p.h; ++i){
			for(j = 0; j < p.w; ++j){
			for(y = 0; y < p.h; ++y){
			for(x = 0; x < p.w; ++x){
			for(k= 0; k < p.c; ++k){
			disp->imageData[istep + jp.c + k] = (unsigned char)(get_pixel(copy,i,j,k)*255);
			disp->imageData[ystep + xp.c + k] = (unsigned char)(get_pixel(copy,x,y,k)*255);
			}
			}
			}
			@@ -218,6 +266,7 @@
			cvSaveImage(buff, disp,0);
			cvReleaseImage(&disp);
			}
			*/

			void show_image_layers(image p, char *name)
			{
			@@ -238,7 +287,7 @@
			free_image(c);
			}

			image make_empty_image(int h, int w, int c)
			image make_empty_image(int w, int h, int c)
			{
			image out;
			out.data = 0;
			@@ -248,63 +297,37 @@
			return out;
			}

			image make_image(int h, int w, int c)
			image make_image(int w, int h, int c)
			{
			image out = make_empty_image(h,w,c);
			image out = make_empty_image(w,h,c);
			out.data = calloc(hwc, sizeof(float));
			return out;
			}

			image float_to_image(int h, int w, int c, float *data)
			image float_to_image(int w, int h, int c, float *data)
			{
			image out = make_empty_image(h,w,c);
			image out = make_empty_image(w,h,c);
			out.data = data;
			return out;
			}

			void zero_image(image m)
			image rotate_image(image im, float rad)
			{
			memset(m.data, 0, m.hm.wm.c*sizeof(float));
			}

			void zero_channel(image m, int c)
			{
			memset(&(m.data[cm.hm.w]), 0, m.hm.wsizeof(float));
			}

			void rotate_image(image m)
			{
			int i,j;
			for(j = 0; j < m.c; ++j){
			for(i = 0; i < m.h*m.w/2; ++i){
			float swap = m.data[jm.hm.w + i];
			m.data[jm.hm.w + i] = m.data[jm.hm.w + (m.h*m.w-1 - i)];
			m.data[jm.hm.w + (m.h*m.w-1 - i)] = swap;
			}
			}
			}

			image make_random_image(int h, int w, int c)
			{
			image out = make_image(h,w,c);
			int i;
			for(i = 0; i < hwc; ++i){
			out.data[i] = rand_normal();
			//out.data[i] = rand()%3;
			}
			return out;
			}

			void add_into_image(image src, image dest, int h, int w)
			{
			int i,j,k;
			for(k = 0; k < src.c; ++k){
			for(i = 0; i < src.h; ++i){
			for(j = 0; j < src.w; ++j){
			add_pixel(dest, h+i, w+j, k, get_pixel(src, i, j, k));
			int x, y, c;
			float cx = im.w/2.;
			float cy = im.h/2.;
			image rot = make_image(im.w, im.h, im.c);
			for(c = 0; c < im.c; ++c){
			for(y = 0; y < im.h; ++y){
			for(x = 0; x < im.w; ++x){
			float rx = cos(rad)(x-cx) - sin(rad)(y-cy) + cx;
			float ry = sin(rad)(x-cx) + cos(rad)(y-cy) + cy;
			float val = billinear_interpolate(im, rx, ry, c);
			set_pixel(rot, x, y, c, val);
			}
			}
			}
			return rot;
			}

			void translate_image(image m, float s)
			@@ -319,123 +342,267 @@
			for(i = 0; i < m.hm.wm.c; ++i) m.data[i] *= s;
			}

			image make_random_kernel(int size, int c, float scale)
			image crop_image(image im, int dx, int dy, int w, int h)
			{
			int pad;
			if((pad=(size%2==0))) ++size;
			image out = make_random_image(size,size,c);
			scale_image(out, scale);
			int i,k;
			if(pad){
			for(k = 0; k < out.c; ++k){
			for(i = 0; i < size; ++i) {
			set_pixel(out, i, 0, k, 0);
			set_pixel(out, 0, i, k, 0);
			image cropped = make_image(w, h, im.c);
			int i, j, k;
			for(k = 0; k < im.c; ++k){
			for(j = 0; j < h; ++j){
			for(i = 0; i < w; ++i){
			int r = j + dy;
			int c = i + dx;
			float val = 0;
			if (r >= 0 && r < im.h && c >= 0 && c < im.w) {
			val = get_pixel(im, c, r, k);
			}
			set_pixel(cropped, i, j, k, val);
			}
			}
			}
			return out;
			return cropped;
			}

			// Returns a new image that is a cropped version (rectangular cut-out)
			// of the original image.
			IplImage* cropImage(const IplImage *img, const CvRect region)
			float three_way_max(float a, float b, float c)
			{
			IplImage *imageCropped;
			CvSize size;

			if (img->width <= 0 \|\| img->height <= 0
			\|\| region.width <= 0 \|\| region.height <= 0) {
			//cerr << "ERROR in cropImage(): invalid dimensions." << endl;
			exit(1);
			}

			if (img->depth != IPL_DEPTH_8U) {
			//cerr << "ERROR in cropImage(): image depth is not 8." << endl;
			exit(1);
			}

			// Set the desired region of interest.
			cvSetImageROI((IplImage*)img, region);
			// Copy region of interest into a new iplImage and return it.
			size.width = region.width;
			size.height = region.height;
			imageCropped = cvCreateImage(size, IPL_DEPTH_8U, img->nChannels);
			cvCopy(img, imageCropped,NULL); // Copy just the region.

			return imageCropped;
			return (a > b) ? ( (a > c) ? a : c) : ( (b > c) ? b : c) ;
			}

			// Creates a new image copy that is of a desired size. The aspect ratio will
			// be kept constant if 'keepAspectRatio' is true, by cropping undesired parts
			// so that only pixels of the original image are shown, instead of adding
			// extra blank space.
			// Remember to free the new image later.
			IplImage* resizeImage(const IplImage *origImg, int newHeight, int newWidth,
			int keepAspectRatio)
			float three_way_min(float a, float b, float c)
			{
			IplImage *outImg = 0;
			int origWidth = 0;
			int origHeight = 0;
			if (origImg) {
			origWidth = origImg->width;
			origHeight = origImg->height;
			}
			if (newWidth <= 0 \|\| newHeight <= 0 \|\| origImg == 0
			\|\| origWidth <= 0 \|\| origHeight <= 0) {
			//cerr << "ERROR: Bad desired image size of " << newWidth
			// << "x" << newHeight << " in resizeImage().\n";
			exit(1);
			}

			if (keepAspectRatio) {
			// Resize the image without changing its aspect ratio,
			// by cropping off the edges and enlarging the middle section.
			CvRect r;
			// input aspect ratio
			float origAspect = (origWidth / (float)origHeight);
			// output aspect ratio
			float newAspect = (newWidth / (float)newHeight);
			// crop width to be origHeight * newAspect
			if (origAspect > newAspect) {
			int tw = (origHeight * newWidth) / newHeight;
			r = cvRect((origWidth - tw)/2, 0, tw, origHeight);
			}
			else { // crop height to be origWidth / newAspect
			int th = (origWidth * newHeight) / newWidth;
			r = cvRect(0, (origHeight - th)/2, origWidth, th);
			}
			IplImage *croppedImg = cropImage(origImg, r);

			// Call this function again, with the new aspect ratio image.
			// Will do a scaled image resize with the correct aspect ratio.
			outImg = resizeImage(croppedImg, newHeight, newWidth, 0);
			cvReleaseImage( &croppedImg );
			}
			else {

			// Scale the image to the new dimensions,
			// even if the aspect ratio will be changed.
			outImg = cvCreateImage(cvSize(newWidth, newHeight),
			origImg->depth, origImg->nChannels);
			if (newWidth > origImg->width && newHeight > origImg->height) {
			// Make the image larger
			cvResetImageROI((IplImage*)origImg);
			// CV_INTER_LINEAR: good at enlarging.
			// CV_INTER_CUBIC: good at enlarging.
			cvResize(origImg, outImg, CV_INTER_LINEAR);
			}
			else {
			// Make the image smaller
			cvResetImageROI((IplImage*)origImg);
			// CV_INTER_AREA: good at shrinking (decimation) only.
			cvResize(origImg, outImg, CV_INTER_AREA);
			}

			}
			return outImg;
			return (a < b) ? ( (a < c) ? a : c) : ( (b < c) ? b : c) ;
			}

			// http://www.cs.rit.edu/~ncs/color/t_convert.html
			void rgb_to_hsv(image im)
			{
			assert(im.c == 3);
			int i, j;
			float r, g, b;
			float h, s, v;
			for(j = 0; j < im.h; ++j){
			for(i = 0; i < im.w; ++i){
			r = get_pixel(im, i , j, 0);
			g = get_pixel(im, i , j, 1);
			b = get_pixel(im, i , j, 2);
			float max = three_way_max(r,g,b);
			float min = three_way_min(r,g,b);
			float delta = max - min;
			v = max;
			if(max == 0){
			s = 0;
			h = -1;
			}else{
			s = delta/max;
			if(r == max){
			h = (g - b) / delta;
			} else if (g == max) {
			h = 2 + (b - r) / delta;
			} else {
			h = 4 + (r - g) / delta;
			}
			if (h < 0) h += 6;
			}
			set_pixel(im, i, j, 0, h);
			set_pixel(im, i, j, 1, s);
			set_pixel(im, i, j, 2, v);
			}
			}
			}

			void hsv_to_rgb(image im)
			{
			assert(im.c == 3);
			int i, j;
			float r, g, b;
			float h, s, v;
			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);
			s = get_pixel(im, i , j, 1);
			v = get_pixel(im, i , j, 2);
			if (s == 0) {
			r = g = b = v;
			} else {
			int index = floor(h);
			f = h - index;
			p = v*(1-s);
			q = v(1-sf);
			t = v(1-s(1-f));
			if(index == 0){
			r = v; g = t; b = p;
			} else if(index == 1){
			r = q; g = v; b = p;
			} else if(index == 2){
			r = p; g = v; b = t;
			} else if(index == 3){
			r = p; g = q; b = v;
			} else if(index == 4){
			r = t; g = p; b = v;
			} else {
			r = v; g = p; b = q;
			}
			}
			set_pixel(im, i, j, 0, r);
			set_pixel(im, i, j, 1, g);
			set_pixel(im, i, j, 2, b);
			}
			}
			}

			image grayscale_image(image im)
			{
			assert(im.c == 3);
			int i, j, k;
			image gray = make_image(im.w, im.h, im.c);
			float scale[] = {0.587, 0.299, 0.114};
			for(k = 0; k < im.c; ++k){
			for(j = 0; j < im.h; ++j){
			for(i = 0; i < im.w; ++i){
			gray.data[i+im.wj] += scale[k]get_pixel(im, i, j, k);
			}
			}
			}
			memcpy(gray.data + im.wim.h1, gray.data, sizeof(float)im.wim.h);
			memcpy(gray.data + im.wim.h2, gray.data, sizeof(float)im.wim.h);
			return gray;
			}

			image blend_image(image fore, image back, float alpha)
			{
			assert(fore.w == back.w && fore.h == back.h && fore.c == back.c);
			image blend = make_image(fore.w, fore.h, fore.c);
			int i, j, k;
			for(k = 0; k < fore.c; ++k){
			for(j = 0; j < fore.h; ++j){
			for(i = 0; i < fore.w; ++i){
			float val = alpha * get_pixel(fore, i, j, k) +
			(1 - alpha)* get_pixel(back, i, j, k);
			set_pixel(blend, i, j, k, val);
			}
			}
			}
			return blend;
			}

			void scale_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);
			}
			}
			}

			void saturate_image(image im, float sat)
			{
			rgb_to_hsv(im);
			scale_image_channel(im, 1, sat);
			hsv_to_rgb(im);
			constrain_image(im);
			}

			void exposure_image(image im, float sat)
			{
			rgb_to_hsv(im);
			scale_image_channel(im, 2, sat);
			hsv_to_rgb(im);
			constrain_image(im);
			}

			void saturate_exposure_image(image im, float sat, float exposure)
			{
			rgb_to_hsv(im);
			scale_image_channel(im, 1, sat);
			scale_image_channel(im, 2, exposure);
			hsv_to_rgb(im);
			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 billinear_interpolate(image im, float x, float y, int c)
			{
			int ix = (int) floorf(x);
			int iy = (int) floorf(y);

			float dx = x - ix;
			float dy = y - iy;

			float val = (1-dy) * (1-dx) * get_pixel_extend(im, ix, iy, c) +
			dy * (1-dx) * get_pixel_extend(im, ix, iy+1, c) +
			(1-dy) * dx * get_pixel_extend(im, ix+1, iy, c) +
			dy * dx * get_pixel_extend(im, ix+1, iy+1, c);
			return val;
			}

			// #wikipedia
			image resize_image(image im, int w, int h)
			{
			image resized = make_image(w, h, im.c);
			int r, c, k;
			float w_scale = (float)(im.w - 1) / (w - 1);
			float h_scale = (float)(im.h - 1) / (h - 1);
			for(k = 0; k < im.c; ++k){
			for(r = 0; r < h; ++r){
			for(c = 0; c < w; ++c){
			float sx = c*w_scale;
			float sy = r*h_scale;
			float val = billinear_interpolate(im, sx, sy, k);
			set_pixel(resized, c, r, k, val);
			}
			}
			}
			return resized;
			}

			void test_resize(char *filename)
			{
			image im = load_image(filename, 0,0, 3);
			image gray = grayscale_image(im);

			image sat2 = copy_image(im);
			saturate_image(sat2, 2);

			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);

			show_image(im, "Original");
			show_image(gray, "Gray");
			show_image(sat2, "Saturation-2");
			show_image(sat5, "Saturation-.5");
			show_image(exp2, "Exposure-2");
			show_image(exp5, "Exposure-.5");
			#ifdef OPENCV
			cvWaitKey(0);
			#endif
			}

			#ifdef OPENCV
			image ipl_to_image(IplImage* src)
			{
			unsigned char data = (unsigned char )src->imageData;
			@@ -443,261 +610,113 @@
			int w = src->width;
			int c = src->nChannels;
			int step = src->widthStep;
			image out = make_image(h,w,c);
			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];
			out.data[count++] = data[istep + jc + k]/255.;
			}
			}
			}
			return out;
			}

			image load_image_color(char *filename, int h, int w)
			image load_image_cv(char *filename, int channels)
			{
			IplImage* src = 0;
			if( (src = cvLoadImage(filename, 1)) == 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 file image %s\n", filename);
			exit(0);
			}
			if(h && w && (src->height != h \|\| src->width != w)){
			//printf("Resized!\n");
			IplImage *resized = resizeImage(src, h, w, 0);
			cvReleaseImage(&src);
			src = resized;
			}
			image out = ipl_to_image(src);
			cvReleaseImage(&src);
			rgbgr_image(out);
			return out;
			}

			image load_image(char *filename, int h, int w)
			#endif


			image load_image_stb(char *filename, int channels)
			{
			IplImage* src = 0;
			if( (src = cvLoadImage(filename,-1)) == 0 )
			{
			printf("Cannot load file image %s\n", filename);
			int w, h, c;
			unsigned char *data = stbi_load(filename, &w, &h, &c, channels);
			if (!data) {
			fprintf(stderr, "Cannot load file image %s\nSTB Reason: %s\n", filename, stbi_failure_reason());
			exit(0);
			}
			if(h && w ){
			IplImage *resized = resizeImage(src, h, w, 0);
			cvReleaseImage(&src);
			src = resized;
			if(channels) c = channels;
			int i,j,k;
			image im = make_image(w, h, c);
			for(k = 0; k < c; ++k){
			for(j = 0; j < h; ++j){
			for(i = 0; i < w; ++i){
			int dst_index = i + wj + wh*k;
			int src_index = k + ci + cw*j;
			im.data[dst_index] = (float)data[src_index]/255.;
			}
			}
			}
			image out = ipl_to_image(src);
			cvReleaseImage(&src);
			free(data);
			return im;
			}

			image load_image(char *filename, int w, int h, int c)
			{
			#ifdef OPENCV
			image out = load_image_cv(filename, c);
			#else
			image out = load_image_stb(filename, c);
			#endif

			if((h && w) && (h != out.h \|\| w != out.w)){
			image resized = resize_image(out, w, h);
			free_image(out);
			out = resized;
			}
			return out;
			}

			image load_image_color(char *filename, int w, int h)
			{
			return load_image(filename, w, h, 3);
			}

			image get_image_layer(image m, int l)
			{
			image out = make_image(m.h, m.w, 1);
			image out = make_image(m.w, m.h, 1);
			int i;
			for(i = 0; i < m.h*m.w; ++i){
			out.data[i] = m.data[i+lm.hm.w];
			}
			return out;
			}
			image get_sub_image(image m, int h, int w, int dh, int dw)
			{
			image out = make_image(dh, dw, m.c);
			int i,j,k;
			for(k = 0; k < out.c; ++k){
			for(i = 0; i < dh; ++i){
			for(j = 0; j < dw; ++j){
			float val = get_pixel(m, h+i, w+j, k);
			set_pixel(out, i, j, k, val);
			}
			}
			}
			return out;
			}

			float get_pixel(image m, int x, int y, int c)
			{
			assert(x < m.h && y < m.w && c < m.c);
			return m.data[cm.hm.w + x*m.w + y];
			assert(x < m.w && y < m.h && c < m.c);
			return m.data[cm.hm.w + y*m.w + x];
			}
			float get_pixel_extend(image m, int x, int y, int c)
			{
			if(x < 0 \|\| x >= m.h \|\| y < 0 \|\| y >= m.w \|\| c < 0 \|\| c >= m.c) return 0;
			if(x < 0 \|\| x >= m.w \|\| y < 0 \|\| y >= m.h \|\| 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)
			{
			assert(x < m.h && y < m.w && c < m.c);
			m.data[cm.hm.w + x*m.w + y] = val;
			}
			void set_pixel_extend(image m, int x, int y, int c, float val)
			{
			if(x < 0 \|\| x >= m.h \|\| y < 0 \|\| y >= m.w \|\| c < 0 \|\| c >= m.c) return;
			set_pixel(m, x, y, c, val);
			}

			void add_pixel(image m, int x, int y, int c, float val)
			{
			assert(x < m.h && y < m.w && c < m.c);
			m.data[cm.hm.w + x*m.w + y] += val;
			}

			void add_pixel_extend(image m, int x, int y, int c, float val)
			{
			if(x < 0 \|\| x >= m.h \|\| y < 0 \|\| y >= m.w \|\| c < 0 \|\| c >= m.c) return;
			add_pixel(m, x, y, c, val);
			}

			void two_d_convolve(image m, int mc, image kernel, int kc, int stride, image out, int oc, int edge)
			{
			int x,y,i,j;
			int xstart, xend, ystart, yend;
			if(edge){
			xstart = ystart = 0;
			xend = m.h;
			yend = m.w;
			}else{
			xstart = kernel.h/2;
			ystart = kernel.w/2;
			xend = m.h-kernel.h/2;
			yend = m.w - kernel.w/2;
			}
			for(x = xstart; x < xend; x += stride){
			for(y = ystart; y < yend; y += stride){
			float sum = 0;
			for(i = 0; i < kernel.h; ++i){
			for(j = 0; j < kernel.w; ++j){
			sum += get_pixel(kernel, i, j, kc)*get_pixel_extend(m, x+i-kernel.h/2, y+j-kernel.w/2, mc);
			}
			}
			add_pixel(out, (x-xstart)/stride, (y-ystart)/stride, oc, sum);
			}
			}
			}

			float single_convolve(image m, image kernel, int x, int y)
			{
			float sum = 0;
			int i, j, k;
			for(i = 0; i < kernel.h; ++i){
			for(j = 0; j < kernel.w; ++j){
			for(k = 0; k < kernel.c; ++k){
			sum += get_pixel(kernel, i, j, k)*get_pixel_extend(m, x+i-kernel.h/2, y+j-kernel.w/2, k);
			}
			}
			}
			return sum;
			}

			void convolve(image m, image kernel, int stride, int channel, image out, int edge)
			{
			assert(m.c == kernel.c);
			int i;
			zero_channel(out, channel);
			for(i = 0; i < m.c; ++i){
			two_d_convolve(m, i, kernel, i, stride, out, channel, edge);
			}
			/*
			int j;
			for(i = 0; i < m.h; i += stride){
			for(j = 0; j < m.w; j += stride){
			float val = single_convolve(m, kernel, i, j);
			set_pixel(out, i/stride, j/stride, channel, val);
			}
			}
			*/
			}

			void upsample_image(image m, int stride, image out)
			{
			int i,j,k;
			zero_image(out);
			for(k = 0; k < m.c; ++k){
			for(i = 0; i < m.h; ++i){
			for(j = 0; j< m.w; ++j){
			float val = get_pixel(m, i, j, k);
			set_pixel(out, istride, jstride, k, val);
			}
			}
			}
			}

			void single_update(image m, image update, int x, int y, float error)
			{
			int i, j, k;
			for(i = 0; i < update.h; ++i){
			for(j = 0; j < update.w; ++j){
			for(k = 0; k < update.c; ++k){
			float val = get_pixel_extend(m, x+i-update.h/2, y+j-update.w/2, k);
			add_pixel(update, i, j, k, val*error);
			}
			}
			}
			}

			void kernel_update(image m, image update, int stride, int channel, image out, int edge)
			{
			assert(m.c == update.c);
			zero_image(update);
			int i, j, istart, jstart, iend, jend;
			if(edge){
			istart = jstart = 0;
			iend = m.h;
			jend = m.w;
			}else{
			istart = update.h/2;
			jstart = update.w/2;
			iend = m.h-update.h/2;
			jend = m.w - update.w/2;
			}
			for(i = istart; i < iend; i += stride){
			for(j = jstart; j < jend; j += stride){
			float error = get_pixel(out, (i-istart)/stride, (j-jstart)/stride, channel);
			single_update(m, update, i, j, error);
			}
			}
			/*
			for(i = 0; i < update.hupdate.wupdate.c; ++i){
			update.data[i] /= (m.h/stride)*(m.w/stride);
			}
			*/
			}

			void single_back_convolve(image m, image kernel, int x, int y, float val)
			{
			int i, j, k;
			for(i = 0; i < kernel.h; ++i){
			for(j = 0; j < kernel.w; ++j){
			for(k = 0; k < kernel.c; ++k){
			float pval = get_pixel(kernel, i, j, k) * val;
			add_pixel_extend(m, x+i-kernel.h/2, y+j-kernel.w/2, k, pval);
			}
			}
			}
			}

			void back_convolve(image m, image kernel, int stride, int channel, image out, int edge)
			{
			assert(m.c == kernel.c);
			int i, j, istart, jstart, iend, jend;
			if(edge){
			istart = jstart = 0;
			iend = m.h;
			jend = m.w;
			}else{
			istart = kernel.h/2;
			jstart = kernel.w/2;
			iend = m.h-kernel.h/2;
			jend = m.w - kernel.w/2;
			}
			for(i = istart; i < iend; i += stride){
			for(j = jstart; j < jend; j += stride){
			float val = get_pixel(out, (i-istart)/stride, (j-jstart)/stride, channel);
			single_back_convolve(m, kernel, i, j, val);
			}
			}
			assert(x < m.w && y < m.h && c < m.c);
			m.data[cm.hm.w + y*m.w + x] = val;
			}

			void print_image(image m)
			@@ -730,20 +749,20 @@
			c = 1;
			}

			image filters = make_image(h,w,c);
			image filters = make_image(w, h, c);
			int i,j;
			for(i = 0; i < n; ++i){
			int h_offset = i*(ims[0].h+border);
			image copy = copy_image(ims[i]);
			//normalize_image(copy);
			if(c == 3 && color){
			embed_image(copy, filters, h_offset, 0);
			embed_image(copy, filters, 0, h_offset);
			}
			else{
			for(j = 0; j < copy.c; ++j){
			int w_offset = j*(ims[0].w+border);
			image layer = get_image_layer(copy, j);
			embed_image(layer, filters, h_offset, w_offset);
			embed_image(layer, filters, w_offset, h_offset);
			free_image(layer);
			}
			}
			@@ -766,20 +785,20 @@
			c = 1;
			}

			image filters = make_image(h,w,c);
			image filters = make_image(w, h, c);
			int i,j;
			for(i = 0; i < n; ++i){
			int w_offset = i*(size+border);
			image copy = copy_image(ims[i]);
			//normalize_image(copy);
			if(c == 3 && color){
			embed_image(copy, filters, 0, w_offset);
			embed_image(copy, filters, w_offset, 0);
			}
			else{
			for(j = 0; j < copy.c; ++j){
			int h_offset = j*(size+border);
			image layer = get_image_layer(copy, j);
			embed_image(layer, filters, h_offset, w_offset);
			embed_image(layer, filters, w_offset, h_offset);
			free_image(layer);
			}
			}
			@@ -796,43 +815,6 @@
			free_image(m);
			}

			image grid_images(image **ims, int h, int w)
			{
			int i;
			image *rows = calloc(h, sizeof(image));
			for(i = 0; i < h; ++i){
			rows[i] = collapse_images_horz(ims[i], w);
			}
			image out = collapse_images_vert(rows, h);
			for(i = 0; i < h; ++i){
			free_image(rows[i]);
			}
			free(rows);
			return out;
			}

			void test_grid()
			{
			int i,j;
			int num = 3;
			int topk = 3;
			image *vizs = calloc(num, sizeof(image));
			for(i = 0; i < num; ++i){
			vizs[i] = calloc(topk, sizeof(image));
			for(j = 0; j < topk; ++j) vizs[i][j] = make_image(3,3,3);
			}
			image grid = grid_images(vizs, num, topk);
			save_image(grid, "Test Grid");
			free_image(grid);
			}

			void show_images_grid(image *ims, int h, int w, char window)
			{
			image out = grid_images(ims, h, w);
			show_image(out, window);
			free_image(out);
			}

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