#pragma once namespace nall { image::image(const image& source) { operator=(source); } image::image(image&& source) { operator=(forward(source)); } image::image(bool endian, unsigned depth, uint64_t alphaMask, uint64_t redMask, uint64_t greenMask, uint64_t blueMask) { _endian = endian; _depth = depth; _alpha = {alphaMask, bitDepth(alphaMask), bitShift(alphaMask)}; _red = {redMask, bitDepth(redMask), bitShift(redMask )}; _green = {greenMask, bitDepth(greenMask), bitShift(greenMask)}; _blue = {blueMask, bitDepth(blueMask), bitShift(blueMask )}; } image::image(const string& filename) { load(filename); } image::image(const vector& buffer) { auto data = buffer.data(); auto size = buffer.size(); if(0); else if(data[0] == 'B' && data[1] == 'M') loadBMP(data, size); else if(data[1] == 'P' && data[2] == 'N' && data[3] == 'G') loadPNG(data, size); } image::image(const uint8_t* data, unsigned size) { if(0); else if(data[0] == 'B' && data[1] == 'M') loadBMP(data, size); else if(data[1] == 'P' && data[2] == 'N' && data[3] == 'G') loadPNG(data, size); } image::image() { } image::~image() { free(); } auto image::operator=(const image& source) -> image& { if(this == &source) return *this; free(); _width = source._width; _height = source._height; _endian = source._endian; _depth = source._depth; _alpha = source._alpha; _red = source._red; _green = source._green; _blue = source._blue; _data = allocate(_width, _height, stride()); memory::copy(_data, source._data, source.size()); return *this; } auto image::operator=(image&& source) -> image& { if(this == &source) return *this; free(); _width = source._width; _height = source._height; _endian = source._endian; _depth = source._depth; _alpha = source._alpha; _red = source._red; _green = source._green; _blue = source._blue; _data = source._data; source._data = nullptr; return *this; } image::operator bool() const { return _data && _width && _height; } auto image::operator==(const image& source) const -> bool { if(_width != source._width) return false; if(_height != source._height) return false; if(_endian != source._endian) return false; if(_depth != source._depth) return false; if(_alpha != source._alpha) return false; if(_red != source._red) return false; if(_green != source._green) return false; if(_blue != source._blue) return false; return memory::compare(_data, source._data, size()) == 0; } auto image::operator!=(const image& source) const -> bool { return !operator==(source); } auto image::read(const uint8_t* data) const -> uint64_t { uint64_t result = 0; if(_endian == 0) { for(signed n = stride() - 1; n >= 0; n--) result = (result << 8) | data[n]; } else { for(signed n = 0; n < stride(); n++) result = (result << 8) | data[n]; } return result; } auto image::write(uint8_t* data, uint64_t value) const -> void { if(_endian == 0) { for(signed n = 0; n < stride(); n++) { data[n] = value; value >>= 8; } } else { for(signed n = stride() - 1; n >= 0; n--) { data[n] = value; value >>= 8; } } } auto image::free() -> void { if(_data) delete[] _data; _data = nullptr; } auto image::load(const string& filename) -> bool { if(loadBMP(filename) == true) return true; if(loadPNG(filename) == true) return true; return false; } auto image::allocate(unsigned width, unsigned height) -> void { if(_data && _width == width && _height == height) return; free(); _width = width; _height = height; _data = allocate(_width, _height, stride()); } auto image::allocate(unsigned width, unsigned height, unsigned stride) -> uint8_t* { //allocate 1x1 larger than requested; so that linear interpolation does not require bounds-checking unsigned size = width * height * stride; unsigned padding = width * stride + stride; auto data = new uint8_t[size + padding]; memory::fill(data + size, padding); return data; } }