PPMImage PPMImage::resize(int out_rows, int out_columns)const{
PPMImage output = PPMImage(magic, meta, out_rows, out_columns);
for (int r=0; r < out_rows; r++){
for (int c=0; c < out_columns; c++){
// Convert r,c into old style coordinates
float r_real = (float)r / out_rows * rows;
float c_real = (float)c / out_columns * columns;
int r_0 = floor(r_real);
int r_1 = ceil(r_real);
int c_0 = floor(c_real);
int c_1 = ceil(c_real);
float r_d = r_real - r_0;
float c_d = c_real - c_0;
/* tl--t------tr
* | | |
* |---p------|
* | | |
* | | |
* | | |
* bl--b------br */
float tl, tr, bl, br;
float t, b, R, G, B;
tl = (*this)[r_0][c_0].r;
tr = (*this)[r_0][c_1].r;
bl = (*this)[r_1][c_0].r;
br = (*this)[r_1][c_1].r;
t = tr + (tr - tl)*c_d;
b = br + (br - bl)*c_d;
R = b + (b - t)*r_d;
tl = (*this)[r_0][c_0].g;
tr = (*this)[r_0][c_1].g;
bl = (*this)[r_1][c_0].g;
br = (*this)[r_1][c_1].g;
t = tr + (tr - tl)*c_d;
b = br + (br - bl)*c_d;
G = b + (b - t)*r_d;
tl = (*this)[r_0][c_0].b;
tr = (*this)[r_0][c_1].b;
bl = (*this)[r_1][c_0].b;
br = (*this)[r_1][c_1].b;
t = tr + (tr - tl)*c_d;
b = br + (br - bl)*c_d;
B = b + (b - t)*r_d;
output[r][c] = RGBPixel(R,G,B);
// r / rows * this->rows() same for cols
// find the 4 vals adjacent and the distances from each
// Do a weighted sum (possibly split into x and y separately)
// Set output[r][c] = val;
}
}
return output;
}
RGBImageView* visualize(const T &src )
{
typedef typename T::value_type value_type;
int x,y;
RGBImageData* dest_data = new RGBImageData(src.size(), src.origin());
RGBImageView* dest = new RGBImageView(*dest_data);
RGBPixel blackval = black(*dest);
RGBPixel whiteval = white(*dest);
for (y = 0; y < (int)src.nrows(); y++)
for (x = 0; x < (int)src.ncols(); x++) {
switch (src.get(Point(x,y))) {
case (1) :
dest->set(Point(x,y),blackval);
break; // black, music
case (2) :
dest->set(Point(x,y),RGBPixel(228, 228, 228));
break; // light grey, border
case (4) :
dest->set(Point(x,y),RGBPixel(0, 127, 0));
break; // dark green, ornate letter
case (8) :
dest->set(Point(x,y),RGBPixel(0, 255, 0));
break; // light green, text in staff
case (16) :
dest->set(Point(x,y),RGBPixel(255, 127, 0));
break; // orange, lyrics
case (32) :
dest->set(Point(x,y),RGBPixel(255, 227, 0));
break; // yellow, title
case (64) :
dest->set(Point(x,y),RGBPixel(0, 0, 255));
break; // blue, UNUSED
case (128) :
dest->set(Point(x,y),RGBPixel(255, 0, 255));
break; // magenta, UNUSED
default :
dest->set(Point(x,y),whiteval);
}
}
return dest;
}
PPMImage PPMImage::convolve(const PixelGrid<MonoPixel> kernel)const{
std::cout << "Convolving" << std::endl;
PPMImage conv(magic, meta, rows-kernel.rows+1, columns-kernel.columns+1);
// std::cout << conv.rows << ' ' << conv.columns << std::endl;
for (int r = kernel.rows-1; r < rows; r++){
for (int c = kernel.columns-1; c < columns; c++){
float red = 0;
float green = 0;
float blue = 0;
for (int x = 0; x < kernel.rows; x++){
for (int y = 0; y < kernel.columns; y++){
red += kernel[x][y].i * (*this)[r-x][c-y].r;
green += kernel[x][y].i * (*this)[r-x][c-y].g;
blue += kernel[x][y].i * (*this)[r-x][c-y].b;
}
}
conv[r-kernel.rows+1][c-kernel.columns+1] = RGBPixel(red, green, blue);
}
}
// std::cout << "end of convolution" << std::endl;
return conv;
}
