/**
* Tests the collage code with the appropriate algorithm.
*/
void testCollage(DrawAlgorithm algorithm)
{
cout << "Testing collage:" << endl;
vector<PNG> layers = setupImages();
vector<Point> coords = setupPoints();
Collage collage(layers, coords);
double startTime = omp_get_wtime();
PNG* result = collage.draw(algorithm, true);
double endTime = omp_get_wtime();
double parallelTime = endTime - startTime;
cout << " - saving image" << endl;
result->writeToFile("collage.png");
cout << "Elapsed collage time: " << parallelTime << endl;
cout << "Checking correctness: ";
bool correct = collage.checkCorrectness(*result);
cout << (correct ? makeGreen("PASS") : makeRed("FAIL") + " (the images are different)") << endl;
delete result;
startTime = omp_get_wtime();
result = collage.draw(algorithm, false);
endTime = omp_get_wtime();
cout << "Speedup: " << (endTime - startTime) / parallelTime << endl;
delete result;
}
void testWaterfall()
{
cout << "[main]: " << __func__ << "()" << endl;
PNG in("in_05.png");
List<RGBAPixel> list = imageToList(in);
list.waterfall();
PNG out = listToImage(list, in.width(), in.height());
out.writeToFile("waterfall_01.png");
checkSoln(__func__, out, "soln_waterfall_01.png");
in.readFromFile("in_06.png");
list = imageToList(in);
list.waterfall();
out = listToImage(list, in.width(), in.height());
out.writeToFile("waterfall_02.png");
checkSoln(__func__, out, "soln_waterfall_02.png");
List<int> list3;
for (int i = 1; i <= 8; i++)
list3.insertBack(i);
list3.waterfall();
//cout << "[waterfall custom]: " << list3 << endl;
}
bool rx_save_png(Image& img, std::string filename, bool datapath) {
PNG png;
png_uint_32 type;
if(img.getPixelFormat() == RX_FMT_GRAY8) {
type = PNG_COLOR_TYPE_GRAY;
}
else if(img.getPixelFormat() == RX_FMT_RGB24) {
type = PNG_COLOR_TYPE_RGB;
}
else if(img.getPixelFormat() == RX_FMT_RGBA32) {
type = PNG_COLOR_TYPE_RGB_ALPHA;
}
else {
RX_ERROR(ERR_IMG_UNSUPPORTED_FORMAT);
return false;
}
png.setPixels(img.getPixels(), img.getWidth(), img.getHeight(), type);
png.save(filename, datapath);
return true;
}
/**
* Tests the image flipping code.
*/
void testFlip()
{
PNG image;
cout << "Testing in-place image flipper:" << endl;
image.readFromFile("images/03_2560x1680.png");
cout << " - flipping image" << endl;
double startTime = omp_get_wtime();
Flipper::flipParallel(image);
double endTime = omp_get_wtime();
double parallelTime = endTime - startTime;
cout << " - saving image" << endl;
image.writeToFile("flipped.png");
cout << "Elapsed flip time: " << parallelTime << endl;
cout << "Checking correctness: ";
bool correct = Flipper::checkCorrectness(image);
cout << (correct ? makeGreen("PASS") : makeRed("FAIL") + " (the images are different)") << endl;
startTime = omp_get_wtime();
Flipper::flipSerial(image);
endTime = omp_get_wtime();
cout << "Speedup: " << (endTime - startTime) / parallelTime << endl;
}
int main()
{
SquareMaze m;
m.makeMaze(TEST,TEST);
std::cout << "MakeMaze complete" << std::endl;
/*
for ( int i = 0; i < TEST; i++)
{
for ( int j = 0; j < TEST ; j++)
{
cout <<"RIGHT: "<< m.canTravel(i,j,RIGHT)<< " x: "<<i<<" y: "<<j<<endl;
cout <<"BOTTOM: "<< m.canTravel(i,j,BOTTOM)<< " x: "<<i<<" y: "<<j<<endl;
}
}
*/
PNG* unsolved = m.drawMaze();
unsolved->writeToFile("unsolved.png");
delete unsolved;
std::cout << "drawMaze complete" << std::endl;
vector<int> sol = m.solveMaze();
std::cout << "solveMaze complete" << std::endl;
PNG* solved = m.drawMazeWithSolution();
solved->writeToFile("solved.png");
delete solved;
std::cout << "drawMazeWithSolution complete" << std::endl;
return 0;
}
/**
* Tests the image shifting code
*/
void testShift()
{
// remove old frames
system("rm -rf frames 2> /dev/null");
PNG image;
cout << "Testing image shifter:" << endl;
image.readFromFile("images/08_1024x768.png");
cout << " - shifting image" << endl;
double startTime = omp_get_wtime();
animation anim = Shifter::shiftParallel(image);
double endTime = omp_get_wtime();
double parallelTime = endTime - startTime;
cout << " - saving image" << endl;
anim.write("shifted.gif");
cout << "Elapsed shifting time: " << parallelTime << endl;
cout << "Checking correctness: ";
bool correct = Shifter::checkCorrectness();
cout << (correct ? makeGreen("PASS") : makeRed("FAIL") + " (the images are different)") << endl;
// remove old frames
system("rm -rf frames 2> /dev/null");
// calculate speedup
startTime = omp_get_wtime();
anim = Shifter::shiftSerial(image);
endTime = omp_get_wtime();
cout << "Speedup: " << (endTime - startTime) / parallelTime << endl;
}
void Terrain::loadHeightMap(string filename, int res_x, int res_y)
{
PNG inputFile;
inputFile.load(filename);
dim_x = inputFile.width;
dim_y = inputFile.height;
unsigned char * data = inputFile.getData();
int size = dim_x*dim_y;
float * originalHeightMap = new float[size];
int i,x,y;
for (i=0; i<size; i++){
originalHeightMap[i] = 256*data[2*i]+data[2*i + 1];
}
// recalculate to the given resolution (use linear interpolation...)
size = res_x*res_y;
heightMap = new float[size];
float step_x = float(dim_x)/float(res_x);
float step_y = float(dim_y)/float(res_y);
for(x=0; x<res_x; x++)
{
for(y=0; y<res_y; y++)
{
heightMap[x*res_y + y] = getHeightAt(originalHeightMap, dim_x, dim_y, float(x*step_x), float(y*step_y));
}
}
SAFE_DELETE_ARRAY_PTR(originalHeightMap);
}
void testReverseNth()
{
cout << "[main]: " << __func__ << "()" << endl;
PNG in("in_03.png");
/*
List<int> test;
for (int i = 1; i <= 11; i++)
{
test.insertBack(i);
}
cout<<test<<endl;
test.reverseNth(3);
cout<<test<<endl;
*/
List<RGBAPixel> list = imageToList(in);
list.reverseNth(in.height() * 20);
PNG out = listToImage(list, in.width(), in.height());
out.writeToFile("reverseNth_01.png");
checkSoln(__func__, out, "soln_reverseNth_01.png");
in.readFromFile("in_04.png");
list = imageToList(in);
list.reverseNth(in.height() * 61);
out = listToImage(list, in.width(), in.height());
out.writeToFile("reverseNth_02.png");
checkSoln(__func__, out, "soln_reverseNth_02.png");
}
void testWaterfall()
{
List<double> li;
cout<<li<<endl;
li.waterfall();
cout<<li<<endl;
cout << "[main]: " << __func__ << "()" << endl;
PNG in("in_05.png");
List<RGBAPixel> list = imageToList(in);
list.waterfall();
PNG out = listToImage(list, in.width(), in.height());
out.writeToFile("waterfall_01.png");
checkSoln(__func__, out, "soln_waterfall_01.png");
in.readFromFile("in_06.png");
list = imageToList(in);
list.waterfall();
out = listToImage(list, in.width(), in.height());
out.writeToFile("waterfall_02.png");
checkSoln(__func__, out, "soln_waterfall_02.png");
}
int main(int argc, char* argv[])
{
const int canvas_width = 128;
const int canvas_height = 128;
PNG canvas;
canvas.resize(canvas_width, canvas_height);
const RGBAPixel triangle_color = color::ORANGE;
Shape* triangle = new Triangle(triangle_color,
Vector2(32, 32),
Vector2(64, 64),
Vector2(32, 64));
triangle->draw(&canvas);
canvas.writeToFile("test_destructor.png");
/* TODO: Why is this leaking memory? Triangle does have a valid destructor!?
* Can you stop it from leaking WITHOUT changing triangle's type from a
* Shape pointer to a Triangle pointer type? */
delete triangle;
triangle = NULL;
return 0;
}
/**
* This function brightens a rectangle of a PNG, increasing the components
* (red, green, blue) of each pixel by the given amount. You must account
* for potential overflow issues (color components can only store numbers
* between 0 and 255). If you attempt to store a value greater than 255
* into a color component, the result will wrap around (and you won't be
* able to check if it was greater than 255).
*
* @param original A PNG object which holds the image data to be modified.
* @param amount The integer amount by which to increase each pixel's
* components.
*
* @return The brightened image.
*/
PNG brighten(PNG original, int amount)
{
/// You can assume amount is positive.
for (size_t yi = 0; yi < original.height(); yi++)
{
for (size_t xi = 0; xi < original.width(); xi++)
{
/// Your code here!
int blue = original(xi, yi)->blue;
int green = original(xi, yi)->green;
int red = original(xi, yi)->red;
if(red+amount<255)
original(xi,yi)->red= red+amount;
else
original(xi,yi)->red= 255;
if(blue+amount<255)
original(xi,yi)->blue= blue+amount;
else
original(xi,yi)->blue= 255;
if(green+amount<255)
original(xi,yi)->green= green+amount;
else
original(xi,yi)->green= 255;
}
}
return original;
}
/**
* Removes an RGB color component from the PNG.
* THIS FUNCTION IS GRADED.
* @todo - parallelize removeColor()
* @param source - the original PNG
* @param color - the color to remove
* @return - a PNG object with an RGB component taken out
* of each pixel (if color parameter is valid)
*/
PNG ImageTools::removeColor(const PNG & source, const Color & color)
{
int width = source.width();
int height = source.height();
PNG output(width, height);
#pragma omp parallel for
for(int i = 0; i < width; ++i)
{
for(int j = 0; j < height; ++j)
{
*output(i, j) = *source(i, j);
switch(color)
{
case RED:
output(i,j)->red=0;
break;
case GREEN:
output(i,j)->green=0;
break;
case BLUE:
output(i,j)->blue=0;
break;
}
}
}
return output;
}
/**
* Makes an animation of an image shifting to the left
* @param toShift - the image to be shifted
* @return - an animation of the image being shifted
*/
animation Shifter::shiftParallel(const PNG & toShift)
{
PNG image = toShift;
animation anim;
int width = image.width();
int height = image.height();
int shiftAmount = 32;
// shift image to the left by 32 pixels each iteration
for(int destCol = 0; destCol < width; destCol += 32)
{
for(int x = 0; x < width - 32; ++x)
{
#pragma omp parallel for
for(int y = 0; y < height; ++y)
{
*image(x, y) = *image(x + 32, y);
}
}
if(destCol % shiftAmount == 0)
{
anim.addFrame(image);
}
}
return anim;
}
void makePhotoMosaic(const string & inFile, const string & tileDir, int numTiles, int pixelsPerTile, const string & outFile)
{
PNG inImage(inFile);
SourceImage source(inImage, numTiles);
vector<TileImage> tiles = getTiles(tileDir);
if (tiles.empty())
{
cerr << "ERROR: No tile images found in " << tileDir << endl;
exit(2);
}
MosaicCanvas::enableOutput = true;
MosaicCanvas * mosaic = mapTiles(source, tiles);
cerr << endl;
if (mosaic == NULL)
{
cerr << "ERROR: Mosaic generation failed" << endl;
exit(3);
}
PNG result = mosaic->drawMosaic(pixelsPerTile);
cerr << "Saving Output Image... ";
result.writeToFile(outFile);
cerr << "Done" << endl;
delete mosaic;
}
/**
* This function brightens a rectangle of a PNG, increasing the components
* (red, green, blue) of each pixel by the given amount. You must account
* for potential overflow issues (color components can only store numbers
* between 0 and 255). If you attempt to store a value greater than 255
* into a color component, the result will wrap around (and you won't be
* able to check if it was greater than 255).
*
* @param original A PNG object which holds the image data to be modified.
* @param amount The integer amount by which to increase each pixel's
* components.
*
* @return The brightened image.
*/
PNG brighten(PNG original, int amount)
{
/// You can assume amount is positive.
for (size_t yi = 0; yi < original.height(); yi++)
{
for (size_t xi = 0; xi < original.width(); xi++)
{
size_t r = original(xi, yi) -> red;
size_t g = original(xi, yi) -> green;
size_t b = original(xi, yi) -> blue;
r = r + amount;
g = g + amount;
b = b + amount;
if(r > 255){
r = 255;
}
if(g > 255){
g = 255;
}
if(b > 255){
b = 255;
}
original(xi, yi) ->red = r;
original(xi, yi) ->green = g;
original(xi, yi) ->blue = b;
/// Your code here!
}
}
return original;
}
void checkSoln(string test, PNG out, string soln_file)
{
PNG soln;
soln.readFromFile(soln_file.c_str());
if (!(soln == out))
cerr << "[" << test << "]: Image does not match " << soln_file << endl;
}
int main(int argc, char* argv[])
{
const int canvas_width = 128;
const int canvas_height = 128;
PNG canvas;
canvas.resize(canvas_width, canvas_height);
Vector2 rectangle_center(canvas_width / 2, canvas_height / 2);
const int rectangle_width = canvas_width / 4;
const int rectangle_height = canvas_height / 4;
Rectangle* rectangle = new Rectangle(rectangle_center,
color::BLUE,
rectangle_width,
rectangle_height);
rectangle->draw(&canvas);
const int rectangle_perimeter = rectangle->perimeter();
cout << "Rectangle's Perimeter = " << rectangle_perimeter << endl;
const int rectangle_area = rectangle->area();
cout << "Rectangle's Area = " << rectangle_area << endl;
/* But we can treat a Rectangle just like a Shape using a Shape pointer */
Shape* shape = rectangle;
const int shape_perimeter = shape->perimeter();
cout << "Shape's Perimeter = " << shape_perimeter << endl;
const int shape_area = shape->area();
cout << "Shape' Area = " << shape_area << endl;
/* TODO: For some reason the shape's area and perimeter is different from
* triangle's area and perimeter even though they are pointing to the same
* object! Can you this this so they are the same WITHOUT changing the
* shape's type from a Shape pointer to a Triangle pointer? */
if (rectangle_perimeter == shape_perimeter)
{
cout << "The Perimeters are the same!" << endl;
} else
{
cout << "The Perimeters are NOT the same." << endl;
}
if (rectangle_area == shape_area)
{
cout << "The Areas are the same!" << endl;
} else
{
cout << "The Areas are NOT the same." << endl;
}
canvas.writeToFile("test_virtual.png");
delete rectangle;
return 0;
}
bool CTdata::loadFromFiles(const char * filename, int cnt, int scaleX, int scaleY, int scaleZ){
int divide = 2;
int chars = 0;
scX = scaleX;
scY = scaleY;
scZ = scaleZ/divide;
char filen [50];
unsigned char * rawData;
PNG ctfile;
int width=0, height=0, width2, height2;
int x,y,z;
float val;
for(z=0; z<cnt; z++){
sprintf(filen, filename, z+1);
ctfile.clear();
if (!ctfile.load(filen)){
return false;
}
rawData = ctfile.getData();
height = ctfile.height;
width = ctfile.width;
width2 = width/float(divide);
height2 = height/float(divide);
if (data==NULL){
data = new float[cnt*width2*height2]; //data = new float[cnt*width*height];
}
for (y=0; y<height2; y++){ //height
for (x=0; x<width2; x++){ //width
// 2x 8-bit to 1x 16-bit
val = 256*rawData[(2*y*width + 2*x)*divide]+rawData[(2*y*width + 2*x)*divide + 1]; //val = 256*rawData[2*y*width + 2*x]+rawData[2*y*width + 2*x + 1];
// save in array
data[z*height2*width2 + y*width2 +(width2-1-x)] = val; //data[z*width*height + y*width +x] = val;
}
}
BACKSPACE(chars);
chars = printf("LOADING CT images: %03i %%",((z+1)*100)/cnt);
}
dimX = width2;
dimY = height2;
dimZ = cnt;
szX = dimX * scX;
szY = dimY * scY;
szZ = dimZ * scZ;
center.x = szX/2.0;
center.y = szY/2.0;
center.z = szZ/2.0;
// backspace...
BACKSPACE(chars);
printf("LOADING CT images (%i) DONE\n", cnt);
return true;
}
int main()
{
PNG oldImage;
oldImage.readFromFile("in.png");
size_t vertical = oldImage.height();
size_t horizontal = oldImage.width();
/*
* have initialized newImage just so that the pixels are accessable
*/
PNG newImage;
newImage.readFromFile("in.png");
/*
* we will flip the image horizontally and vertically to rotate it by 180 degrees
*/
for (size_t x = 0; x < oldImage.width(); x++)
{
for (size_t y = 0; y < oldImage.height(); y++)
{
newImage(horizontal-x-1, vertical-y-1)->red = oldImage(x,y)->red;
newImage(horizontal-x-1, vertical-y-1)->green = oldImage(x,y)->green;
newImage(horizontal-x-1, vertical-y-1)->blue = oldImage(x,y)->blue;
}
}
newImage.writeToFile("out.png");
}
GLuint OpenGLInterface::LoadTextureFromPNG( const char* fileName, unsigned int tex )
{
PNG pngFile;
if( pngFile.Load( fileName ) )
{
tex = CreateTextureFromImageData( pngFile.GetData(), pngFile.GetWidth(), pngFile.GetHeight(), pngFile.GetHasAlpha(), tex );
}
return tex;
}
void testReverse()
{
cout << "[main]: " << __func__ << "()" << endl;
PNG in("in_02.png");
List<RGBAPixel> list = imageToList(in);
list.reverse();
PNG out = listToImage(list, in.width(), in.height());
out.writeToFile("reverse.png");
checkSoln(__func__, out, "soln_reverse.png");
}
List<RGBAPixel> imageToList(PNG const & img)
{
List<RGBAPixel> list;
for (int i = 0; i < img.width(); i++)
{
for (int j = 0; j < img.height(); j++)
{
list.insertFront(*img(i,j));
}
}
return list;
}
/**
* This function accepts a PNG object, two integer coordinates and a color, and
* proceeds to draw a horizontal line across the image at the y coordinate and
* a vertical line down the image at the x coordinage using the given color.
* The modified PNG is then returned.
*
* @param original A PNG object which holds the image data to be modified.
* @param centerX The center x coordinate of the crosshair which is to be drawn.
* @param centerY The center y coordinate of the crosshair which is to be drawn.
* @param color The color of the lines to be drawn.
*
* @return The image on which a crosshair has been drawn.
*/
PNG drawCrosshairs(PNG original, int centerX, int centerY, RGBAPixel color)
{
/// This function is already written for you so you can see how to
/// interact with our PNG class.
for (size_t x = 0; x < original.width(); x++)
*original(x, centerY) = color;
for (size_t y = 0; y < original.height(); y++)
*original(centerX, y) = color;
return original;
}
void testSolidFill( const Filler & filler, const string & outputFile ) {
PNG img;
img.readFromFile( SOLIDTESTIMAGE );
RGBAPixel px( 70, 50, 13 );
animation anim;
if( filler == DFS )
anim = filler::dfs::fillSolid( img, SOLIDX, SOLIDY, px, SOLIDTOLERANCE, SOLIDFRAMEFREQ );
else
anim = filler::bfs::fillSolid( img, SOLIDX, SOLIDY, px, SOLIDTOLERANCE, SOLIDFRAMEFREQ );
anim.write( outputFile );
cout << "\tWrote " << outputFile << endl;
}
void testGridFill( const Filler & filler, const string & outputFile ) {
PNG img;
img.readFromFile( GRIDTESTIMAGE );
RGBAPixel px( 70, 25, 70 );
animation anim;
if( filler == DFS )
anim = filler::dfs::fillGrid( img, GRIDX, GRIDY, px, GRIDGRIDSPACING, GRIDTOLERANCE, GRIDFRAMEFREQ );
else
anim = filler::bfs::fillGrid( img, GRIDX, GRIDY, px, GRIDGRIDSPACING, GRIDTOLERANCE, GRIDFRAMEFREQ );
anim.write( outputFile );
cout << "\tWrote " << outputFile << endl;
}
/**
* This function blends, or averages, two PNGs together. That is, each pixel in
* the returned image consists of the averaged components (red, green, blue) of
* the two input images.
*
* @param firstImage The first of the two PNGs to be averaged together.
* @param secondImage The second of the two PNGs to be averaged together.
*
* @return The averaged image.
*/
PNG blendImages(PNG firstImage, PNG secondImage)
{
for (size_t yi = 0; yi < firstImage.height(); yi++)
{
for (size_t xi = 0; xi < firstImage.width(); xi++)
{
firstImage(xi, yi)->green =(firstImage(xi, yi)->green+secondImage(xi, yi)->green)/2;
firstImage(xi, yi)->red =(firstImage(xi, yi)->red+secondImage(xi, yi)->red)/2;
firstImage(xi, yi)->blue =(firstImage(xi, yi)->blue+secondImage(xi, yi)->blue)/2;
}
}
return firstImage;
}
/**
* Simply parses the command line args and runs the appropriate functions.
*/
int main(int argc, char* argv[]){
if(argc != 5)
{
cerr << endl;
cerr << "Please run as " << argv[0] << " numThreads operation imageName saveFile" << endl;
cerr << " numThreads number of threads to use (if #pragma omp... is encountered)" << endl;
cerr << " operation \"flip\" or \"remove\"" << endl;
cerr << " imageName for example, \"images/01_8182x4096.png\"" << endl;
cerr << " saveFile \"yes\" (if you want to save output), \"no\" otherwise" << endl;
cerr << endl;
return 1;
}
// set the number of thread for the program to use (the first argument)
omp_set_num_threads(atoi(argv[1]));
// read the parameter PNG from file
string filename(argv[3]);
PNG img(filename);
PNG output;
cout << "Performing operation..." << endl;
double start = omp_get_wtime();
double end;
if(argv[2][0] == 'f')
{
output = ImageTools::verticalFlip(img);
end = omp_get_wtime();
if(argv[4][0] == 'y')
{
cout << "Saving image..." << endl;
output.writeToFile("flipped.png");
}
}
else
{
Color color = GREEN;
output = ImageTools::removeColor(img, color);
end = omp_get_wtime();
if(argv[4][0] == 'y')
{
cout << "Saving image..." << endl;
output.writeToFile("removed.png");
}
}
cout << "Total processed pixels: " << img.height() * img.width() << endl;
cout << "Time: " << end - start << " seconds" << endl;
return 0;
}
int main()
{
// Load in.png
PNG * original = new PNG;
original -> readFromFile("in.png");
int width = original->width();
int height = original->height();
cout << "width=" << width << " height=" << height << endl;
// Create out.png
PNG * output;
output = setupOutput(width, height);
// Loud our favorite color to color the outline
RGBAPixel * myPixel = myFavoriteColor(192);
// Go over the whole image, and if a pixel differs from that to its upper
// left, color it my favorite color in the output
for (int y = 1; y < height; y++)
{
for (int x = 1; x < width; x++)
{
// Calculate the pixel difference
RGBAPixel * prev = (*original)(x - 1, y - 1);
RGBAPixel * curr = (*original)(x, y);
int diff = abs(curr->red - prev->red ) +
abs(curr->green - prev->green) +
abs(curr->blue - prev->blue );
// If the pixel is an edge pixel,
// color the output pixel with my favorite color
RGBAPixel * currOutPixel = (*output)(x,y);
if (diff > 100) {
currOutPixel->blue = myPixel->blue;
currOutPixel->red = myPixel->red;
currOutPixel->green = myPixel->green;
}
}
}
// Save the output file
output->writeToFile("out.png");
// Clean up memory
delete myPixel;
delete output;
delete original;
return 0;
}
/**
* This function brightens a rectangle of a PNG, increasing the components
* (red, green, blue) of each pixel by the given amount. You must account
* for potential overflow issues (color components can only store numbers
* between 0 and 255). If you attempt to store a value greater than 255
* into a color component, the result will wrap around (and you won't be
* able to check if it was greater than 255).
*
* @param original A PNG object which holds the image data to be modified.
* @param amount The integer amount by which to increase each pixel's
* components.
*
* @return The brightened image.
*/
PNG brighten(PNG original, int amount)
{
/// You can assume amount is positive.
for (size_t yi = 0; yi < original.height(); yi++)
{
for (size_t xi = 0; xi < original.width(); xi++)
{
/// Your code here!
//original(xi,yi)->red = 0;
//original(xi,yi)->blue = 0;
}
}
return original;
}
bool rx_load_png(Image& img, std::string filename, bool datapath) {
PNG png;
if(!png.load(filename, datapath)) {
return false;
}
switch(png.getColorType()) {
case PNG_COLOR_TYPE_GRAY: {
img.setPixelFormat(RX_FMT_GRAY8);
break;
}
case PNG_COLOR_TYPE_RGB: {
img.setPixelFormat(RX_FMT_RGB24);
break;
}
case PNG_COLOR_TYPE_RGB_ALPHA: {
img.setPixelFormat(RX_FMT_RGBA32);
break;
}
default: {
RX_ERROR(PNG_ERR_UNSUPPORTED_FORMAT);
return false;
}
}
img.setWidth(png.getWidth());
img.setHeight(png.getHeight());
return img.copyPixels(png.getPixels(), png.getWidth(), png.getHeight(), img.getPixelFormat());
}
