I am trying to implement bicubic image interpolation. I have only pasted relevant sections of the code. I have skipped the code dealing with loading the image into a buffer and reading pixels from them etc. I am reasonably sure my math is correct. However, I seem to be having terrible artifacts in the output.

All the action happens in the resize method.

Am hoping that experienced graphics programmers may be able to share their hunches as to what I could be doing wrong.

The following are the input and output images that I get when resizing the input to twice its width and height.

```
double Interpolator::interpolate(const double p0, const double p1, const double p2, const double p3, const double x){
return (-0.5f*p0+1.5f*p1-1.5f*p2+0.5*p3)*pow(x,3)+
(p0-2.5f*p1+2.f*p2-0.5f*p3)*pow(x,2)+
(-0.5f*p0+0.5f*p2)*x+
p1;
}
bool Image::equals(double a, double b, double threshold){
if(fabs(a-b)<=threshold)
return true;
return false;
}
void Image::interpolate(const Pixel p[], double offset, Pixel& result){
result.r = Interpolator::interpolate(p[0].r,p[1].r,p[2].r,p[3].r,offset);
result.g = Interpolator::interpolate(p[0].g,p[1].g,p[2].g,p[3].g,offset);
result.b = Interpolator::interpolate(p[0].b,p[1].b,p[2].b,p[3].b,offset);
result.a = Interpolator::interpolate(p[0].a,p[1].a,p[2].a,p[3].a,offset);
}
void Image::getSamplingCoords(const int nearest,
const int max,
int coords[]){
coords[0] = nearest-1;
if(coords[0]<0)
coords[0] = nearest;
coords[1] = nearest;
coords[2] = nearest+1;
if(coords[2]>=max)
coords[2] = nearest;
coords[3] = nearest+2;
//The following check should not be necessary
//since this is never expected to occur. Nevertheless...
if(coords[3]>=max)
coords[3] = nearest;
}
void Image::interpolateAlongY(int x, int y, int yMax, double yOffset, Pixel& result){
if(equals(yOffset,0.f,ERROR_THRESHOLD)){
//No interpolation required
getPixel(x,y,result);
return;
}
int yCoords[4];
getSamplingCoords(y, yMax, yCoords);
Pixel interpolants[4];
for(int i=0; i<4; ++i){
getPixel(x, yCoords[i], interpolants[i]);
}
interpolate(interpolants, y, result);
}
void Image::resize(const int newWidth, const int newHeight){
//Ensure that we have a valid buffer already
if(buffer==NULL){
printf("ERROR: Must load an image before resizing it!");
assert(false);
}
//We first need to create a new buffer with the new dimensions
unsigned char* newBuffer = new unsigned char[newWidth*newHeight*channelCount];
for(int j=0; j<newHeight; ++j){
for(int i=0; i<newWidth; ++i){
size_t newIndexOffset = (j*newWidth+i)*channelCount;
//For this pixel in the target image we
//a) Find the nearest pixel in the source image
//b) Find the offset from the aforementioned nearest pixel
int xNear,yNear;
double xOffset,yOffset;
double x = ((double)width/(double)newWidth)*i;
double y = ((double)height/(double)newHeight)*j;
xNear = floor(x);
yNear = floor(y);
xOffset = x-xNear;
yOffset = y-yNear;
//If offset is 0, we don't need any interpolation
//we simply need to sample the source pixel and proceed
// if(equals(xOffset,0.f,ERROR_THRESHOLD) && equals(yOffset,0.f,ERROR_THRESHOLD)){
// Pixel result;
// getPixel(xNear, yNear, result);
// *(newBuffer+newIndexOffset) = result.r;
// *(newBuffer+newIndexOffset+1) = result.g;
// *(newBuffer+newIndexOffset+2) = result.b;
// if(channelCount==4)
// *(buffer+newIndexOffset+3) = result.a;
// continue;
// }
//We make a check that xNear and yNear obtained above
//are always smaller than the edge pixels at the extremeties
if(xNear>=width || yNear>=height){
printf("ERROR: Nearest pixel computation error!");
assert(false);
}
//Next we find four pixels along the x direction around this
//nearest pixel
int xCoords[4];
getSamplingCoords(xNear,width,xCoords);
//For each of these sampling xCoords, we interpolate 4 nearest points
//along Y direction
Pixel yInterps[4];
for(int k=0; k<4; k++){
interpolateAlongY(xCoords[k], yNear, height, yOffset, yInterps[k]);
}
//Finally, the resultant pixel is a cubic interpolation
//on the 4 obtained pixels above
Pixel result;
if(equals(xOffset,0.f,ERROR_THRESHOLD)){
result.r = yInterps[0].r;
result.g = yInterps[0].g;
result.b = yInterps[0].b;
result.a = yInterps[0].a;
}else{
interpolate(yInterps, xOffset, result);
}
*(newBuffer+newIndexOffset) = result.r;
*(newBuffer+newIndexOffset+1) = result.g;
*(newBuffer+newIndexOffset+2) = result.b;
if(channelCount==4)
*(newBuffer+newIndexOffset+3) = result.a;
}
}
//Now we can deallocate the memory of our current buffer
delete [] buffer;
//Reassign our newly sampled buffer to our own
buffer = newBuffer;
//Reset our image dimensions
height = newHeight;
width = newWidth;
}
```