// Quantise in-place transformed coefficients (without LL subband prediction)
const Picture quantise_transform_np(const Picture& transform,
const int qIndex,
const Array1D& qMatrix) {
Picture result(transform.format());
result.y(quantise_transform_np(transform.y(), qIndex, qMatrix));
result.c1(quantise_transform_np(transform.c1(), qIndex, qMatrix));
result.c2(quantise_transform_np(transform.c2(), qIndex, qMatrix));
return result;
}
const Picture inverse_quantise_transform_np(const Picture& qCoeffs,
const int qIndex,
const Array1D& qMatrix) {
Picture result(qCoeffs.format());
result.y(inverse_quantise_transform_np(qCoeffs.y(), qIndex, qMatrix));
result.c1(inverse_quantise_transform_np(qCoeffs.c1(), qIndex, qMatrix));
result.c2(inverse_quantise_transform_np(qCoeffs.c2(), qIndex, qMatrix));
return result;
}
// Quantise in-place transformed coefficients of a whole picture as slices
// Using LL (DC) subband prediction
// Uses a quantisation matrix
const Picture quantise_transform(const Picture& transform,
const Array2D& qIndices,
const Array1D& qMatrix) {
Picture result(transform.format());
result.y(quantise_transform(transform.y(), qIndices, qMatrix));
result.c1(quantise_transform(transform.c1(), qIndices, qMatrix));
result.c2(quantise_transform(transform.c2(), qIndices, qMatrix));
return result;
}
const long long yss_for_slice(const Picture &inPicture,
const int qIndex,
const Array1D& qMatrix) {
Picture trialSlice = quantise_transform_np(inPicture, qIndex, qMatrix);
Picture restoredSlice = inverse_quantise_transform_np(trialSlice, qIndex, qMatrix);
Array2D yDiff(restoredSlice.format().lumaShape());
std::transform(inPicture.y().data(), inPicture.y().data()+inPicture.y().num_elements(),
restoredSlice.y().data(),
yDiff.data(),
std::minus<int>() );
std::transform(yDiff.data(), yDiff.data()+yDiff.num_elements(),
yDiff.data(),
yDiff.data(),
std::multiplies<int>() );
return std::accumulate(yDiff.data(), yDiff.data()+yDiff.num_elements(), 0LL);
}
