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/*
* imhistmatch
*
* histogram matching in scilab
*
*/
// Created by Samiran Roy, mail: samiranroy@cse.iitb.ac.in
// An implementation of imhistmatch method
// Usage:
// 1) imhistmatch(image,referenceimage)
// 2) imhistmatch(image,referenceimage,outputbins)
// Known Changes from Matlab:
/*
* Default number of bins is 256 - for both input and output
*/
#include <numeric>
#include "opencv2/core/core.hpp"
#include "opencv2/highgui/highgui.hpp"
#include "opencv2/opencv.hpp"
#include <iostream>
using namespace cv;
using namespace std;
extern "C" {
#include "api_scilab.h"
#include "Scierror.h"
#include "BOOL.h"
#include <localization.h>
#include "sciprint.h"
#include "../common.h"
// Matches the input image histogram with the reference image histogram,
// returning the output in n bins
Mat match(Mat image, Mat ref, int bins) {
Mat dst, hist;
Mat input_image = Mat::zeros(image.size(), CV_8U);
Mat refhist;
int inputbins = 256;
Mat cdf = Mat(inputbins, 1, CV_8U, cvScalar(0));
Mat refcdf = Mat(bins, 1, CV_8U, cvScalar(0));
// Calculating histogram of image
image.convertTo(dst, CV_8U, 1, 0);
calcHist(&dst, 1, 0, Mat(), hist, 1, &inputbins, 0);
// Calculating histogram of reference image
ref.convertTo(dst, CV_8U, 1, 0);
calcHist(&dst, 1, 0, Mat(), refhist, 1, &bins, 0);
hist.copyTo(cdf);
refhist.copyTo(refcdf);
// calculate cdf
for (int h = 1; h < inputbins; h++) {
float binVal = hist.at<float>(h, 0);
cdf.at<float>(h, 0) = cdf.at<float>(h, 0) + cdf.at<float>(h - 1, 0);
}
// normalize histogram
for (int h = 0; h < inputbins; h++) {
cdf.at<float>(h, 0) = cdf.at<float>(h, 0) / cdf.at<float>(inputbins - 1, 0);
}
// for reference image
// calculate cdf
for (int h = 1; h < bins; h++) {
float binVal = refhist.at<float>(h, 0);
refcdf.at<float>(h, 0) =
refcdf.at<float>(h, 0) + refcdf.at<float>(h - 1, 0);
}
// normalize histogram
for (int h = 0; h < bins; h++) {
refcdf.at<float>(h, 0) =
refcdf.at<float>(h, 0) / refcdf.at<float>(bins - 1, 0);
}
// for( int h = 0; h < bins; h++ )
// {
// sciprint("%f\n",refcdf.at<float>(h,0));
// }
// sciprint("\n");
// for( int h = 0; h < bins; h++ )
// {
// sciprint("%f\n",cdf.at<float>(h,0));
// }
float observed_cdf, minval;
float minindex;
for (int i = 0; i < input_image.rows; i++)
for (int j = 0; j < input_image.cols; j++) {
observed_cdf = cdf.at<float>(image.at<uchar>(i, j), 0);
minval = 1000; // will be overwritten
for (int h = 0; h < bins; h++) {
if ((abs(refcdf.at<float>(h, 0) - observed_cdf)) < minval) {
minval = abs(refcdf.at<float>(h, 0) - observed_cdf);
minindex = h;
}
// sciprint("%d\n",minindex);
}
input_image.at<uchar>(i, j) = minindex;
}
transpose(input_image, input_image);
return input_image;
}
int opencv_imhistmatch(char *fname, unsigned long fname_len) {
SciErr sciErr;
int intErr = 0;
int *piAddr = NULL;
int *piAddrNew = NULL;
int *piAddr2 = NULL;
int *piAddr3 = NULL;
double num_bins = 256; // default number of bins for histogram calculation
// checking input argument
CheckInputArgument(pvApiCtx, 2, 3);
CheckOutputArgument(pvApiCtx, 1, 1);
// Get the number of input arguments
int inputarg = *getNbInputArgument(pvApiCtx);
// get input matrix
Mat image, new_image, r, g, b;
retrieveImage(image, 1);
Mat ref;
retrieveImage(ref, 2);
int case1 = 0;
if (image.channels() == 1)
{
if (ref.channels() != 1) {
sciprint(
"If A is a grayscale image, the ref image must also be grayscale\n");
return 0;
} else {
case1 = 1;
}
}
else if (image.channels() == 3)
{
if (ref.channels() == 1) {
case1 = 2;
}
if (ref.channels() == 3) {
case1 = 3;
}
}
else {
sciprint("Invalid Image\n");
return 0;
}
if (!((image.channels() == 3) || (image.channels() == 1))) {
sciprint("Invalid Image\n");
return 0;
}
if (!((ref.channels() == 3) || (ref.channels() == 1))) {
sciprint("Invalid Reference Image\n");
return 0;
}
if (inputarg == 3) {
// Get the number of bins for histogram calculation
sciErr = getVarAddressFromPosition(pvApiCtx, 3, &piAddr3);
if (sciErr.iErr) {
printError(&sciErr, 0);
return 0;
}
intErr = getScalarDouble(pvApiCtx, piAddr3, &num_bins);
if (sciErr.iErr) {
return intErr;
}
if (num_bins < 1) {
sciprint("Invalid number of histogram bins\n");
return 0;
}
}
int bins = (int)num_bins;
if (case1 == 1) {
new_image = match(image, ref, bins);
}
else if (case1 == 2) {
Mat rgb[3];
split(image, rgb);
r = match(rgb[0], ref, bins);
g = match(rgb[1], ref, bins);
b = match(rgb[2], ref, bins);
vector<Mat> channels;
channels.push_back(r);
channels.push_back(g);
channels.push_back(b);
merge(channels, new_image);
transpose(new_image, new_image);
}
else if (case1 == 3) {
Mat rgb[3];
Mat rgbref[3];
split(ref, rgbref);
split(image, rgb);
r = match(rgb[0], rgbref[0], bins);
g = match(rgb[1], rgbref[1], bins);
b = match(rgb[2], rgbref[2], bins);
vector<Mat> channels;
channels.push_back(r);
channels.push_back(g);
channels.push_back(b);
merge(channels, new_image);
transpose(new_image, new_image);
}
// Normalizing the final image
cv::normalize(new_image, new_image, 0, 255, NORM_MINMAX, CV_8U);
// sciprint("\n");
// for (int i = 0; i < new_image.rows; i++) {
// for (int j = 0; j < new_image.cols; j++) {
// sciprint(" %i ", new_image.at<uchar>(i,j));
// }
// sciprint("\n");
// }
int temp = nbInputArgument(pvApiCtx) + 1;
string tempstring = type2str(new_image.type());
char *checker;
checker = (char *)malloc(tempstring.size() + 1);
memcpy(checker, tempstring.c_str(), tempstring.size() + 1);
returnImage(checker, new_image, 1);
free(checker);
// Assigning the list as the Output Variable
AssignOutputVariable(pvApiCtx, 1) = nbInputArgument(pvApiCtx) + 1;
// Returning the Output Variables as arguments to the Scilab environment
ReturnArguments(pvApiCtx);
return 0;
}
/* ==================================================================== */
}
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