ImageConversion.cpp

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#include <vtfpp/ImageConversion.h>
 
#include <algorithm>
#include <bit>
#include <cmath>
#include <cstdlib>
#include <cstring>
#include <memory>
#include <span>
#include <string_view>
#include <unordered_map>
 
#ifdef SOURCEPP_BUILD_WITH_TBB
#include <execution>
#endif
 
#ifdef SOURCEPP_BUILD_WITH_THREADS
#include <future>
#endif
 
#include <Compressonator.h>
 
#define QOI_IMPLEMENTATION
#define QOI_NO_STDIO
#include <qoi.h>
 
#include <sourcepp/Macros.h>
#include <sourcepp/MathExtended.h>
 
#define STB_IMAGE_IMPLEMENTATION
#define STB_IMAGE_STATIC
#define STBI_NO_FAILURE_STRINGS
#define STBI_NO_STDIO
#include <stb_image.h>
 
#define STB_IMAGE_RESIZE_IMPLEMENTATION
#define STB_IMAGE_RESIZE_STATIC
#include <stb_image_resize2.h>
 
#define STB_IMAGE_WRITE_IMPLEMENTATION
#define STB_IMAGE_WRITE_STATIC
#define STBI_WRITE_NO_STDIO
#include <stb_image_write.h>
 
#define TINYEXR_IMPLEMENTATION 1
#ifdef SOURCEPP_BUILD_WITH_THREADS
#define TINYEXR_USE_THREAD 1
#else
#define TINYEXR_USE_THREAD 0
#endif
#include <tinyexr.h>
 
#include <webp/decode.h>
#include <webp/encode.h>
 
using namespace sourcepp;
using namespace vtfpp;
 
namespace {
 
[[nodiscard]] constexpr CMP_FORMAT imageFormatToCompressonatorFormat(ImageFormat format) {
    switch (format) {
        using enum ImageFormat;
        case RGBA8888:
        case UVWQ8888:
            return CMP_FORMAT_RGBA_8888;
        case ABGR8888:
            return CMP_FORMAT_ABGR_8888;
        case RGB888:
            return CMP_FORMAT_RGB_888;
        case BGR888:
            return CMP_FORMAT_BGR_888;
        case I8:
        case P8:
            return CMP_FORMAT_R_8;
        case ARGB8888:
            return CMP_FORMAT_ARGB_8888;
        case BGRA8888:
            return CMP_FORMAT_BGRA_8888;
        case DXT1:
        case DXT1_ONE_BIT_ALPHA:
            return CMP_FORMAT_DXT1;
        case DXT3:
            return CMP_FORMAT_DXT3;
        case DXT5:
            return CMP_FORMAT_DXT5;
        case UV88:
            return CMP_FORMAT_RG_8;
        case R16F:
            return CMP_FORMAT_R_16F;
        case RG1616F:
            return CMP_FORMAT_RG_16F;
        case RGBA16161616F:
            return CMP_FORMAT_RGBA_16F;
        case RGBA16161616:
            return CMP_FORMAT_RGBA_16;
        case R32F:
            return CMP_FORMAT_R_32F;
        case RG3232F:
            return CMP_FORMAT_RG_32F;
        case RGB323232F:
            return CMP_FORMAT_RGB_32F;
        case RGBA32323232F:
            return CMP_FORMAT_RGBA_32F;
        case ATI2N:
            return CMP_FORMAT_ATI2N;
        case ATI1N:
            return CMP_FORMAT_ATI1N;
        case RGBA1010102:
            return CMP_FORMAT_RGBA_1010102;
        case R8:
            return CMP_FORMAT_R_8;
        case BC7:
            return CMP_FORMAT_BC7;
        case BC6H:
            return CMP_FORMAT_BC6H_SF;
        case RGB565:
        case IA88:
        case A8:
        case RGB888_BLUESCREEN:
        case BGR888_BLUESCREEN:
        case BGRX8888:
        case BGR565:
        case BGRX5551:
        case BGRA4444:
        case BGRA5551:
        case UVLX8888:
        case EMPTY:
        case BGRA1010102:
        case RGBX8888:
        case CONSOLE_BGRX8888_LINEAR:
        case CONSOLE_RGBA8888_LINEAR:
        case CONSOLE_ABGR8888_LINEAR:
        case CONSOLE_ARGB8888_LINEAR:
        case CONSOLE_BGRA8888_LINEAR:
        case CONSOLE_RGB888_LINEAR:
        case CONSOLE_BGR888_LINEAR:
        case CONSOLE_BGRX5551_LINEAR:
        case CONSOLE_I8_LINEAR:
        case CONSOLE_RGBA16161616_LINEAR:
        case CONSOLE_BGRX8888_LE:
        case CONSOLE_BGRA8888_LE:
            return CMP_FORMAT_Unknown;
    }
    return CMP_FORMAT_Unknown;
}
 
[[nodiscard]] constexpr int imageFormatToSTBIRPixelLayout(ImageFormat format) {
    switch (format) {
        using enum ImageFormat;
        case RGBA8888:
        case UVWQ8888:
        case RGBA16161616:
        case RGBA16161616F:
        case RGBA32323232F:
            return STBIR_RGBA;
        case ABGR8888:
            return STBIR_ABGR;
        case RGB888:
        case RGB323232F:
            return STBIR_RGB;
        case BGR888:
            return STBIR_BGR;
        case I8:
        case P8:
        case R32F:
        case R16F:
        case R8:
            return STBIR_1CHANNEL;
        case ARGB8888:
            return STBIR_ARGB;
        case BGRA8888:
            return STBIR_BGRA;
        case UV88:
        case RG1616F:
        case RG3232F:
            return STBIR_2CHANNEL;
        case IA88:
            return STBIR_RA;
        // We want these to get converted to their respective container format before resize
        case DXT1:
        case DXT1_ONE_BIT_ALPHA:
        case DXT3:
        case DXT5:
        case ATI2N:
        case ATI1N:
        case BC7:
        case BC6H:
        case RGB565:
        case A8:
        case RGB888_BLUESCREEN:
        case BGR888_BLUESCREEN:
        case RGBX8888:
        case BGRX8888:
        case BGR565:
        case BGRX5551:
        case BGRA4444:
        case BGRA5551:
        case UVLX8888:
        case EMPTY:
        case RGBA1010102:
        case BGRA1010102:
        case CONSOLE_BGRX8888_LINEAR:
        case CONSOLE_RGBA8888_LINEAR:
        case CONSOLE_ABGR8888_LINEAR:
        case CONSOLE_ARGB8888_LINEAR:
        case CONSOLE_BGRA8888_LINEAR:
        case CONSOLE_RGB888_LINEAR:
        case CONSOLE_BGR888_LINEAR:
        case CONSOLE_BGRX5551_LINEAR:
        case CONSOLE_I8_LINEAR:
        case CONSOLE_RGBA16161616_LINEAR:
        case CONSOLE_BGRX8888_LE:
        case CONSOLE_BGRA8888_LE:
            break;
    }
    return -1;
}
 
[[nodiscard]] constexpr int imageFormatToSTBIRDataType(ImageFormat format, bool srgb = false) {
    switch (format) {
        using enum ImageFormat;
        case RGBA8888:
        case ABGR8888:
        case RGB888:
        case BGR888:
        case I8:
        case IA88:
        case P8:
        case A8:
        case RGB888_BLUESCREEN:
        case BGR888_BLUESCREEN:
        case ARGB8888:
        case BGRA8888:
        case BGRX8888:
        case UV88:
        case UVWQ8888:
        case UVLX8888:
        case RGBX8888:
        case R8:
            return srgb ? STBIR_TYPE_UINT8_SRGB : STBIR_TYPE_UINT8;
        case R16F:
        case RG1616F:
        case RGBA16161616F:
            return STBIR_TYPE_HALF_FLOAT;
        case RGBA16161616:
            return STBIR_TYPE_UINT16;
        case R32F:
        case RG3232F:
        case RGB323232F:
        case RGBA32323232F:
            return STBIR_TYPE_FLOAT;
        case RGB565:
        case BGR565:
        case BGRX5551:
        case BGRA4444:
        case DXT1_ONE_BIT_ALPHA:
        case BGRA5551:
        case DXT1:
        case DXT3:
        case DXT5:
        case EMPTY:
        case ATI2N:
        case ATI1N:
        case RGBA1010102:
        case BGRA1010102:
        case CONSOLE_BGRX8888_LINEAR:
        case CONSOLE_RGBA8888_LINEAR:
        case CONSOLE_ABGR8888_LINEAR:
        case CONSOLE_ARGB8888_LINEAR:
        case CONSOLE_BGRA8888_LINEAR:
        case CONSOLE_RGB888_LINEAR:
        case CONSOLE_BGR888_LINEAR:
        case CONSOLE_BGRX5551_LINEAR:
        case CONSOLE_I8_LINEAR:
        case CONSOLE_RGBA16161616_LINEAR:
        case CONSOLE_BGRX8888_LE:
        case CONSOLE_BGRA8888_LE:
        case BC7:
        case BC6H:
            break;
    }
    return -1;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataUsingCompressonator(std::span<const std::byte> imageData, ImageFormat oldFormat, ImageFormat newFormat, uint16_t width, uint16_t height) {
    if (imageData.empty()) {
        return {};
    }
 
    CMP_Texture srcTexture{};
    srcTexture.dwSize     = sizeof(srcTexture);
    srcTexture.dwWidth    = width;
    srcTexture.dwHeight   = height;
    srcTexture.dwPitch    = ImageFormatDetails::compressed(newFormat) ? 0 : width * (ImageFormatDetails::bpp(newFormat) / 8);
    srcTexture.format     = ::imageFormatToCompressonatorFormat(oldFormat);
    srcTexture.dwDataSize = imageData.size();
 
    srcTexture.pData = const_cast<CMP_BYTE*>(reinterpret_cast<const CMP_BYTE*>(imageData.data()));
 
    CMP_Texture destTexture{};
    destTexture.dwSize     = sizeof(destTexture);
    destTexture.dwWidth    = width;
    destTexture.dwHeight   = height;
    destTexture.dwPitch    = ImageFormatDetails::compressed(newFormat) ? 0 : width * (ImageFormatDetails::bpp(newFormat) / 8);
    destTexture.format     = ::imageFormatToCompressonatorFormat(newFormat);
    destTexture.dwDataSize = CMP_CalculateBufferSize(&destTexture);
 
    std::vector<std::byte> destData;
    destData.resize(destTexture.dwDataSize);
    destTexture.pData = reinterpret_cast<CMP_BYTE*>(destData.data());
 
    CMP_CompressOptions options{};
    options.dwSize        = sizeof(options);
    options.bDXT1UseAlpha = oldFormat == ImageFormat::DXT1_ONE_BIT_ALPHA || newFormat == ImageFormat::DXT1_ONE_BIT_ALPHA;
    options.dwnumThreads  = 0;
 
    if (CMP_ConvertTexture(&srcTexture, &destTexture, &options, nullptr) != CMP_OK) {
        return {};
    }
    return destData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataToRGBA8888(std::span<const std::byte> imageData, ImageFormat format) {
    using namespace ImageConversion;
 
    if (imageData.empty()) {
        return {};
    }
 
    if (format == ImageFormat::RGBA8888 || format == ImageFormat::UVWQ8888) {
        return {imageData.begin(), imageData.end()};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / (ImageFormatDetails::bpp(format) / 8) * sizeof(ImagePixel::RGBA8888));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA8888*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA8888)};
 
    #define VTFPP_REMAP_TO_8(value, shift) math::remap<uint8_t>((value), (1 << (shift)) - 1, (1 << 8) - 1)
 
    #define VTFPP_CONVERT_DETAIL(InputType, r, g, b, a, ...) \
        std::span<const ImagePixel::InputType> imageDataSpan{reinterpret_cast<const ImagePixel::InputType*>(imageData.data()), imageData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(__VA_ARGS__ __VA_OPT__(,) imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::InputType pixel) -> ImagePixel::RGBA8888 { \
            return {(r), (g), (b), (a)}; \
        })
#ifdef SOURCEPP_BUILD_WITH_TBB
    #define VTFPP_CONVERT(InputType, r, g, b, a) VTFPP_CONVERT_DETAIL(InputType, r, g, b, a, std::execution::par_unseq)
#else
    #define VTFPP_CONVERT(InputType, r, g, b, a) VTFPP_CONVERT_DETAIL(InputType, r, g, b, a)
#endif
    #define VTFPP_CASE_CONVERT_AND_BREAK(InputType, r, g, b, a) \
        case InputType: { VTFPP_CONVERT(InputType, r, g, b, a); } break
 
    switch (format) {
        using enum ImageFormat;
        VTFPP_CASE_CONVERT_AND_BREAK(ABGR8888,                pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(RGB888,                  pixel.r, pixel.g, pixel.b, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(RGB888_BLUESCREEN,       pixel.r, pixel.g, pixel.b, static_cast<uint8_t>((pixel.r == 0 && pixel.g == 0 && pixel.b == 0xff) ? 0 : 0xff));
        VTFPP_CASE_CONVERT_AND_BREAK(BGR888,                  pixel.r, pixel.g, pixel.b, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(BGR888_BLUESCREEN,       pixel.r, pixel.g, pixel.b, static_cast<uint8_t>((pixel.r == 0 && pixel.g == 0 && pixel.b == 0xff) ? 0 : 0xff));
        VTFPP_CASE_CONVERT_AND_BREAK(RGB565,                  VTFPP_REMAP_TO_8(pixel.r, 5), VTFPP_REMAP_TO_8(pixel.g, 6), VTFPP_REMAP_TO_8(pixel.b, 5), 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(P8,                      pixel.p, pixel.p, pixel.p, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(I8,                      pixel.i, pixel.i, pixel.i, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(IA88,                    pixel.i, pixel.i, pixel.i, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(A8,                      0,       0,       0,       pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(ARGB8888,                pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(BGRA8888,                pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(BGRX8888,                pixel.r, pixel.g, pixel.b, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(BGR565,                  VTFPP_REMAP_TO_8(pixel.r, 5), VTFPP_REMAP_TO_8(pixel.g, 6), VTFPP_REMAP_TO_8(pixel.b, 5), 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(BGRA5551,                VTFPP_REMAP_TO_8(pixel.r, 5), VTFPP_REMAP_TO_8(pixel.g, 5), VTFPP_REMAP_TO_8(pixel.b, 5), static_cast<uint8_t>(pixel.a * 0xff));
        VTFPP_CASE_CONVERT_AND_BREAK(BGRX5551,                VTFPP_REMAP_TO_8(pixel.r, 5), VTFPP_REMAP_TO_8(pixel.g, 5), VTFPP_REMAP_TO_8(pixel.b, 5), 1);
        VTFPP_CASE_CONVERT_AND_BREAK(BGRA4444,                VTFPP_REMAP_TO_8(pixel.r, 4), VTFPP_REMAP_TO_8(pixel.g, 4), VTFPP_REMAP_TO_8(pixel.b, 4), VTFPP_REMAP_TO_8(pixel.a, 4));
        VTFPP_CASE_CONVERT_AND_BREAK(UV88,                    pixel.u, pixel.v, 0,       0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(UVLX8888,                pixel.u, pixel.v, pixel.l, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(RGBX8888,                pixel.r, pixel.g, pixel.b, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRX8888_LINEAR, pixel.r, pixel.g, pixel.b, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_RGBA8888_LINEAR, pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_ABGR8888_LINEAR, pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_ARGB8888_LINEAR, pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRA8888_LINEAR, pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_RGB888_LINEAR,   pixel.r, pixel.g, pixel.b, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGR888_LINEAR,   pixel.r, pixel.g, pixel.b, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRX5551_LINEAR, VTFPP_REMAP_TO_8(pixel.r, 5), VTFPP_REMAP_TO_8(pixel.g, 5), VTFPP_REMAP_TO_8(pixel.b, 5), 1);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_I8_LINEAR,       pixel.i, pixel.i, pixel.i, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRX8888_LE,     pixel.r, pixel.g, pixel.b, 0xff);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRA8888_LE,     pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(R8,                      pixel.r, 0,       0,       0xff);
        default: SOURCEPP_DEBUG_BREAK; break;
    }
 
    #undef VTFPP_CASE_CONVERT_AND_BREAK
    #undef VTFPP_CONVERT
    #undef VTFPP_CONVERT_DETAIL
    #undef VTFPP_REMAP_TO_8
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA8888(std::span<const std::byte> imageData, ImageFormat format) {
    using namespace ImageConversion;
 
    if (imageData.empty()) {
        return {};
    }
 
    if (format == ImageFormat::RGBA8888) {
        return {imageData.begin(), imageData.end()};
    }
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA8888*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA8888)};
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA8888) * (ImageFormatDetails::bpp(format) / 8));
 
    #define VTFPP_REMAP_FROM_8(value, shift) math::remap<uint8_t>((value), (1 << 8) - 1, (1 << (shift)) - 1)
 
#ifdef SOURCEPP_BUILD_WITH_TBB
    #define VTFPP_CONVERT(InputType, ...) \
        std::span<ImagePixel::InputType> newDataSpan{reinterpret_cast<ImagePixel::InputType*>(newData.data()), newData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(std::execution::par_unseq, imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA8888 pixel) -> ImagePixel::InputType { \
            return __VA_ARGS__; \
        })
#else
    #define VTFPP_CONVERT(InputType, ...) \
        std::span<ImagePixel::InputType> newDataSpan{reinterpret_cast<ImagePixel::InputType*>(newData.data()), newData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA8888 pixel) -> ImagePixel::InputType { \
            return __VA_ARGS__; \
        })
#endif
    #define VTFPP_CASE_CONVERT_AND_BREAK(InputType, ...) \
        case InputType: { VTFPP_CONVERT(InputType, __VA_ARGS__); } break
 
    switch (format) {
        using enum ImageFormat;
        VTFPP_CASE_CONVERT_AND_BREAK(ABGR8888,                {pixel.a, pixel.b, pixel.g, pixel.r});
        VTFPP_CASE_CONVERT_AND_BREAK(RGB888,                  {pixel.r, pixel.g, pixel.b});
        VTFPP_CASE_CONVERT_AND_BREAK(RGB888_BLUESCREEN,       pixel.a == 0xff ? ImagePixel::RGB888_BLUESCREEN{pixel.r, pixel.g, pixel.b} : ImagePixel::RGB888_BLUESCREEN{0, 0, 0xff});
        VTFPP_CASE_CONVERT_AND_BREAK(BGR888,                  {pixel.b, pixel.g, pixel.r});
        VTFPP_CASE_CONVERT_AND_BREAK(BGR888_BLUESCREEN,       pixel.a == 0xff ? ImagePixel::BGR888_BLUESCREEN{pixel.b, pixel.g, pixel.r} : ImagePixel::BGR888_BLUESCREEN{0xff, 0, 0});
        VTFPP_CASE_CONVERT_AND_BREAK(RGB565,                  {VTFPP_REMAP_FROM_8(pixel.r, 5), VTFPP_REMAP_FROM_8(pixel.g, 6), VTFPP_REMAP_FROM_8(pixel.b, 5)});
        VTFPP_CASE_CONVERT_AND_BREAK(P8,                      {pixel.r});
        VTFPP_CASE_CONVERT_AND_BREAK(I8,                      {pixel.r});
        VTFPP_CASE_CONVERT_AND_BREAK(IA88,                    {pixel.r, pixel.a});
        VTFPP_CASE_CONVERT_AND_BREAK(A8,                      {pixel.a});
        VTFPP_CASE_CONVERT_AND_BREAK(ARGB8888,                {pixel.a, pixel.r, pixel.g, pixel.b});
        VTFPP_CASE_CONVERT_AND_BREAK(BGRA8888,                {pixel.b, pixel.g, pixel.r, pixel.a});
        VTFPP_CASE_CONVERT_AND_BREAK(BGRX8888,                {pixel.b, pixel.g, pixel.r, 0xff});
        VTFPP_CASE_CONVERT_AND_BREAK(BGR565,                  {VTFPP_REMAP_FROM_8(pixel.b, 5), VTFPP_REMAP_FROM_8(pixel.g, 6), VTFPP_REMAP_FROM_8(pixel.r, 5)});
        VTFPP_CASE_CONVERT_AND_BREAK(BGRA5551,                {VTFPP_REMAP_FROM_8(pixel.b, 5), VTFPP_REMAP_FROM_8(pixel.g, 5), VTFPP_REMAP_FROM_8(pixel.r, 5), static_cast<uint8_t>(pixel.a < 0xff ? 1 : 0)});
        VTFPP_CASE_CONVERT_AND_BREAK(BGRX5551,                {VTFPP_REMAP_FROM_8(pixel.b, 5), VTFPP_REMAP_FROM_8(pixel.g, 5), VTFPP_REMAP_FROM_8(pixel.r, 5), 1});
        VTFPP_CASE_CONVERT_AND_BREAK(BGRA4444,                {VTFPP_REMAP_FROM_8(pixel.b, 4), VTFPP_REMAP_FROM_8(pixel.g, 4), VTFPP_REMAP_FROM_8(pixel.r, 4), VTFPP_REMAP_FROM_8(pixel.a, 4)});
        VTFPP_CASE_CONVERT_AND_BREAK(UV88,                    {pixel.r, pixel.g});
        VTFPP_CASE_CONVERT_AND_BREAK(UVLX8888,                {pixel.r, pixel.g, pixel.b});
        VTFPP_CASE_CONVERT_AND_BREAK(RGBX8888,                {pixel.r, pixel.g, pixel.b, 0xff});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRX8888_LINEAR, {pixel.b, pixel.g, pixel.r, 0xff});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_RGBA8888_LINEAR, {pixel.r, pixel.g, pixel.b, pixel.a});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_ABGR8888_LINEAR, {pixel.a, pixel.b, pixel.g, pixel.r});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_ARGB8888_LINEAR, {pixel.a, pixel.r, pixel.g, pixel.b});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRA8888_LINEAR, {pixel.b, pixel.g, pixel.r, pixel.a});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_RGB888_LINEAR,   {pixel.r, pixel.g, pixel.b});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGR888_LINEAR,   {pixel.b, pixel.g, pixel.r});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRX5551_LINEAR, {VTFPP_REMAP_FROM_8(pixel.b, 5), VTFPP_REMAP_FROM_8(pixel.g, 5), VTFPP_REMAP_FROM_8(pixel.r, 5), 1});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_I8_LINEAR,       {pixel.r});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRX8888_LE,     {pixel.b, pixel.g, pixel.r, 0xff});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_BGRA8888_LE,     {pixel.b, pixel.g, pixel.r, pixel.a});
        VTFPP_CASE_CONVERT_AND_BREAK(R8,                      {pixel.r});
        default: SOURCEPP_DEBUG_BREAK; break;
    }
 
    #undef VTFPP_CASE_CONVERT_AND_BREAK
    #undef VTFPP_CONVERT
    #undef VTFPP_REMAP_FROM_8
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataToRGBA16161616(std::span<const std::byte> imageData, ImageFormat format) {
    using namespace ImageConversion;
 
    if (imageData.empty()) {
        return {};
    }
 
    if (format == ImageFormat::RGBA16161616) {
        return {imageData.begin(), imageData.end()};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / (ImageFormatDetails::bpp(format) / 8) * sizeof(ImagePixel::RGBA16161616));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA16161616*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA16161616)};
 
    #define VTFPP_REMAP_TO_16(value, shift) math::remap<uint16_t>((value), (1 << (shift)) - 1, (1 << 16) - 1)
 
    #define VTFPP_CONVERT_DETAIL(InputType, r, g, b, a, ...) \
        std::span<const ImagePixel::InputType> imageDataSpan{reinterpret_cast<const ImagePixel::InputType*>(imageData.data()), imageData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(__VA_ARGS__ __VA_OPT__(,) imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::InputType pixel) -> ImagePixel::RGBA16161616 { \
            return { static_cast<uint16_t>(r), static_cast<uint16_t>(g), static_cast<uint16_t>(b), static_cast<uint16_t>(a) }; \
        })
#ifdef SOURCEPP_BUILD_WITH_TBB
    #define VTFPP_CONVERT(InputType, r, g, b, a) VTFPP_CONVERT_DETAIL(InputType, r, g, b, a, std::execution::par_unseq)
#else
    #define VTFPP_CONVERT(InputType, r, g, b, a) VTFPP_CONVERT_DETAIL(InputType, r, g, b, a)
#endif
    #define VTFPP_CASE_CONVERT_AND_BREAK(InputType, r, g, b, a) \
        case InputType: { VTFPP_CONVERT(InputType, r, g, b, a); } break
 
    #define VTFPP_CONVERT_REMAP(InputType, r, g, b, a) \
        do { \
            if constexpr (ImageFormatDetails::alpha(ImageFormat::InputType) > 1) { \
                VTFPP_CONVERT(InputType, \
                        VTFPP_REMAP_TO_16((r), ImageFormatDetails::red(ImageFormat::InputType)), \
                        VTFPP_REMAP_TO_16((g), ImageFormatDetails::green(ImageFormat::InputType)), \
                        VTFPP_REMAP_TO_16((b), ImageFormatDetails::blue(ImageFormat::InputType)), \
                        VTFPP_REMAP_TO_16((a), ImageFormatDetails::alpha(ImageFormat::InputType))); \
            } else if constexpr (ImageFormatDetails::alpha(ImageFormat::InputType) == 1) { \
                VTFPP_CONVERT(InputType, \
                        VTFPP_REMAP_TO_16((r), ImageFormatDetails::red(ImageFormat::InputType)), \
                        VTFPP_REMAP_TO_16((g), ImageFormatDetails::green(ImageFormat::InputType)), \
                        VTFPP_REMAP_TO_16((b), ImageFormatDetails::blue(ImageFormat::InputType)), \
                        (a) * 0xff); \
            } else { \
                VTFPP_CONVERT(InputType, \
                        VTFPP_REMAP_TO_16((r), ImageFormatDetails::red(ImageFormat::InputType)), \
                        VTFPP_REMAP_TO_16((g), ImageFormatDetails::green(ImageFormat::InputType)), \
                        VTFPP_REMAP_TO_16((b), ImageFormatDetails::blue(ImageFormat::InputType)), \
                        (a)); \
            } \
        } while (false)
    #define VTFPP_CASE_CONVERT_REMAP_AND_BREAK(InputType, r, g, b, a) \
        case InputType: { VTFPP_CONVERT_REMAP(InputType, r, g, b, a); } \
        break
 
    switch (format) {
        using enum ImageFormat;
        VTFPP_CASE_CONVERT_REMAP_AND_BREAK(RGBA1010102,           pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_REMAP_AND_BREAK(BGRA1010102,           pixel.r, pixel.g, pixel.b, pixel.a);
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_RGBA16161616_LINEAR, pixel.r, pixel.g, pixel.b, pixel.a);
        default: SOURCEPP_DEBUG_BREAK; break;
    }
 
    #undef VTFPP_CASE_CONVERT_REMAP_AND_BREAK
    #undef VTFPP_CONVERT_REMAP
    #undef VTFPP_CASE_CONVERT_AND_BREAK
    #undef VTFPP_CONVERT
    #undef VTFPP_CONVERT_DETAIL
    #undef VTFPP_REMAP_TO_16
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA16161616(std::span<const std::byte> imageData, ImageFormat format) {
    using namespace ImageConversion;
 
    if (imageData.empty()) {
        return {};
    }
 
    if (format == ImageFormat::RGBA16161616) {
        return {imageData.begin(), imageData.end()};
    }
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA16161616*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA16161616)};
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA16161616) * (ImageFormatDetails::bpp(format) / 8));
 
    #define VTFPP_REMAP_FROM_16(value, shift) static_cast<uint8_t>(math::remap<uint16_t>((value), (1 << 16) - 1, (1 << (shift)) - 1))
 
#ifdef SOURCEPP_BUILD_WITH_TBB
    #define VTFPP_CONVERT(InputType, ...) \
        std::span<ImagePixel::InputType> newDataSpan{reinterpret_cast<ImagePixel::InputType*>(newData.data()), newData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(std::execution::par_unseq, imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA16161616 pixel) -> ImagePixel::InputType { \
            return __VA_ARGS__; \
        })
#else
    #define VTFPP_CONVERT(InputType, ...) \
        std::span<ImagePixel::InputType> newDataSpan{reinterpret_cast<ImagePixel::InputType*>(newData.data()), newData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA16161616 pixel) -> ImagePixel::InputType { \
            return __VA_ARGS__; \
        })
#endif
    #define VTFPP_CASE_CONVERT_AND_BREAK(InputType, ...) \
        case InputType: { VTFPP_CONVERT(InputType, __VA_ARGS__); } break
 
    switch (format) {
        using enum ImageFormat;
        VTFPP_CASE_CONVERT_AND_BREAK(RGBA1010102,                 {VTFPP_REMAP_FROM_16(pixel.r, 10), VTFPP_REMAP_FROM_16(pixel.g, 10), VTFPP_REMAP_FROM_16(pixel.b, 10), VTFPP_REMAP_FROM_16(pixel.a, 2)});
        VTFPP_CASE_CONVERT_AND_BREAK(BGRA1010102,                 {VTFPP_REMAP_FROM_16(pixel.b, 10), VTFPP_REMAP_FROM_16(pixel.g, 10), VTFPP_REMAP_FROM_16(pixel.r, 10), VTFPP_REMAP_FROM_16(pixel.a, 2)});
        VTFPP_CASE_CONVERT_AND_BREAK(CONSOLE_RGBA16161616_LINEAR, {pixel.r, pixel.g, pixel.b, pixel.a});
        default: SOURCEPP_DEBUG_BREAK; break;
    }
 
    #undef VTFPP_CASE_CONVERT_AND_BREAK
    #undef VTFPP_CONVERT
    #undef VTFPP_REMAP_FROM_16
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataToRGBA32323232F(std::span<const std::byte> imageData, ImageFormat format) {
    if (imageData.empty()) {
        return {};
    }
 
    if (format == ImageFormat::RGBA32323232F) {
        return {imageData.begin(), imageData.end()};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / (ImageFormatDetails::bpp(format) / 8) * sizeof(ImagePixel::RGBA32323232F));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA32323232F*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA32323232F)};
 
    #define VTFPP_CONVERT_DETAIL(InputType, r, g, b, a, ...) \
        std::span<const ImagePixel::InputType> imageDataSpan{reinterpret_cast<const ImagePixel::InputType*>(imageData.data()), imageData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(__VA_ARGS__ __VA_OPT__(,) imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::InputType pixel) -> ImagePixel::RGBA32323232F { return {(r), (g), (b), (a)}; })
#ifdef SOURCEPP_BUILD_WITH_TBB
    #define VTFPP_CONVERT(InputType, r, g, b, a) VTFPP_CONVERT_DETAIL(InputType, r, g, b, a, std::execution::par_unseq)
#else
    #define VTFPP_CONVERT(InputType, r, g, b, a) VTFPP_CONVERT_DETAIL(InputType, r, g, b, a)
#endif
    #define VTFPP_CASE_CONVERT_AND_BREAK(InputType, r, g, b, a) \
        case InputType: { VTFPP_CONVERT(InputType, r, g, b, a); } break
 
    switch (format) {
        using enum ImageFormat;
        VTFPP_CASE_CONVERT_AND_BREAK(R32F,          pixel.r, 0.f,     0.f,     1.f);
        VTFPP_CASE_CONVERT_AND_BREAK(RG3232F,       pixel.r, pixel.g, 0.f,     1.f);
        VTFPP_CASE_CONVERT_AND_BREAK(RGB323232F,    pixel.r, pixel.g, pixel.b, 1.f);
        VTFPP_CASE_CONVERT_AND_BREAK(R16F,          pixel.r, 0.f,     0.f,     1.f);
        VTFPP_CASE_CONVERT_AND_BREAK(RG1616F,       pixel.r, pixel.g, 0.f,     1.f);
        VTFPP_CASE_CONVERT_AND_BREAK(RGBA16161616F, pixel.r, pixel.g, pixel.b, pixel.a);
        default: SOURCEPP_DEBUG_BREAK; break;
    }
 
    #undef VTFPP_CASE_CONVERT_AND_BREAK
    #undef VTFPP_CONVERT
    #undef VTFPP_CONVERT_DETAIL
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA32323232F(std::span<const std::byte> imageData, ImageFormat format) {
    using namespace ImageConversion;
 
    if (imageData.empty()) {
        return {};
    }
 
    if (format == ImageFormat::RGBA32323232F) {
        return {imageData.begin(), imageData.end()};
    }
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA32323232F*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA32323232F)};
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA32323232F) * (ImageFormatDetails::bpp(format) / 8));
 
#ifdef SOURCEPP_BUILD_WITH_TBB
    #define VTFPP_CONVERT(InputType, ...) \
        std::span<ImagePixel::InputType> newDataSpan{reinterpret_cast<ImagePixel::InputType*>(newData.data()), newData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(std::execution::par_unseq, imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA32323232F pixel) -> ImagePixel::InputType { \
            return __VA_ARGS__; \
        })
#else
    #define VTFPP_CONVERT(InputType, ...) \
        std::span<ImagePixel::InputType> newDataSpan{reinterpret_cast<ImagePixel::InputType*>(newData.data()), newData.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA32323232F pixel) -> ImagePixel::InputType { \
            return __VA_ARGS__; \
        })
#endif
    #define VTFPP_CASE_CONVERT_AND_BREAK(InputType, ...) \
        case InputType: { VTFPP_CONVERT(InputType, __VA_ARGS__); } break
 
    switch (format) {
        using enum ImageFormat;
        VTFPP_CASE_CONVERT_AND_BREAK(R32F,          {pixel.r});
        VTFPP_CASE_CONVERT_AND_BREAK(RG3232F,       {pixel.r, pixel.g});
        VTFPP_CASE_CONVERT_AND_BREAK(RGB323232F,    {pixel.r, pixel.g, pixel.b});
        VTFPP_CASE_CONVERT_AND_BREAK(R16F,          {half{pixel.r}});
        VTFPP_CASE_CONVERT_AND_BREAK(RG1616F,       {half{pixel.r}, half{pixel.g}});
        VTFPP_CASE_CONVERT_AND_BREAK(RGBA16161616F, {half{pixel.r}, half{pixel.g}, half{pixel.b}, half{pixel.a}});
        default: SOURCEPP_DEBUG_BREAK; break;
    }
 
    #undef VTFPP_CASE_CONVERT_AND_BREAK
    #undef VTFPP_CONVERT
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA8888ToRGBA32323232F(std::span<const std::byte> imageData) {
    if (imageData.empty()) {
        return {};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA8888) * sizeof(ImagePixel::RGBA32323232F));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA32323232F*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA32323232F)};
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA8888*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA8888)};
    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
            std::execution::par_unseq,
#endif
            imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA8888 pixel) -> ImagePixel::RGBA32323232F {
        return {
            static_cast<float>(pixel.r) / static_cast<float>((1 << 8) - 1),
            static_cast<float>(pixel.g) / static_cast<float>((1 << 8) - 1),
            static_cast<float>(pixel.b) / static_cast<float>((1 << 8) - 1),
            static_cast<float>(pixel.a) / static_cast<float>((1 << 8) - 1),
        };
    });
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA32323232FToRGBA8888(std::span<const std::byte> imageData) {
    if (imageData.empty()) {
        return {};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA32323232F) * sizeof(ImagePixel::RGBA8888));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA8888*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA8888)};
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA32323232F*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA32323232F)};
    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
            std::execution::par_unseq,
#endif
            imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA32323232F pixel) -> ImagePixel::RGBA8888 {
        return {
            static_cast<uint8_t>(std::clamp(pixel.r, 0.f, 1.f) * ((1 << 8) - 1)),
            static_cast<uint8_t>(std::clamp(pixel.g, 0.f, 1.f) * ((1 << 8) - 1)),
            static_cast<uint8_t>(std::clamp(pixel.b, 0.f, 1.f) * ((1 << 8) - 1)),
            static_cast<uint8_t>(std::clamp(pixel.a, 0.f, 1.f) * ((1 << 8) - 1)),
        };
    });
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA8888ToRGBA16161616(std::span<const std::byte> imageData) {
    if (imageData.empty()) {
        return {};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA8888) * sizeof(ImagePixel::RGBA16161616));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA16161616*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA16161616)};
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA8888*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA8888)};
    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
            std::execution::par_unseq,
#endif
            imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA8888 pixel) -> ImagePixel::RGBA16161616 {
        return {
            math::remap<uint16_t>(pixel.r, (1 << 8) - 1, (1 << 16) - 1),
            math::remap<uint16_t>(pixel.g, (1 << 8) - 1, (1 << 16) - 1),
            math::remap<uint16_t>(pixel.b, (1 << 8) - 1, (1 << 16) - 1),
            math::remap<uint16_t>(pixel.a, (1 << 8) - 1, (1 << 16) - 1),
        };
    });
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA16161616ToRGBA8888(std::span<const std::byte> imageData) {
    if (imageData.empty()) {
        return {};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA16161616) * sizeof(ImagePixel::RGBA8888));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA8888*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA8888)};
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA16161616*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA16161616)};
    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
            std::execution::par_unseq,
#endif
            imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA16161616 pixel) -> ImagePixel::RGBA8888 {
        return {
            static_cast<uint8_t>(math::remap<uint16_t>(pixel.r, (1 << 16) - 1, (1 << 8) - 1)),
            static_cast<uint8_t>(math::remap<uint16_t>(pixel.g, (1 << 16) - 1, (1 << 8) - 1)),
            static_cast<uint8_t>(math::remap<uint16_t>(pixel.b, (1 << 16) - 1, (1 << 8) - 1)),
            static_cast<uint8_t>(math::remap<uint16_t>(pixel.a, (1 << 16) - 1, (1 << 8) - 1)),
        };
    });
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA32323232FToRGBA16161616(std::span<const std::byte> imageData) {
    if (imageData.empty()) {
        return {};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA32323232F) * sizeof(ImagePixel::RGBA16161616));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA16161616*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA16161616)};
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA32323232F*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA32323232F)};
    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
            std::execution::par_unseq,
#endif
            imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA32323232F pixel) -> ImagePixel::RGBA16161616 {
        return {
            static_cast<uint16_t>(std::clamp(pixel.r, 0.f, 1.f) * ((1 << 16) - 1)),
            static_cast<uint16_t>(std::clamp(pixel.g, 0.f, 1.f) * ((1 << 16) - 1)),
            static_cast<uint16_t>(std::clamp(pixel.b, 0.f, 1.f) * ((1 << 16) - 1)),
            static_cast<uint16_t>(std::clamp(pixel.a, 0.f, 1.f) * ((1 << 16) - 1)),
        };
    });
 
    return newData;
}
 
[[nodiscard]] std::vector<std::byte> convertImageDataFromRGBA16161616ToRGBA32323232F(std::span<const std::byte> imageData) {
    if (imageData.empty()) {
        return {};
    }
 
    std::vector<std::byte> newData;
    newData.resize(imageData.size() / sizeof(ImagePixel::RGBA16161616) * sizeof(ImagePixel::RGBA32323232F));
    std::span newDataSpan{reinterpret_cast<ImagePixel::RGBA32323232F*>(newData.data()), newData.size() / sizeof(ImagePixel::RGBA32323232F)};
 
    std::span imageDataSpan{reinterpret_cast<const ImagePixel::RGBA16161616*>(imageData.data()), imageData.size() / sizeof(ImagePixel::RGBA16161616)};
    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
            std::execution::par_unseq,
#endif
            imageDataSpan.begin(), imageDataSpan.end(), newDataSpan.begin(), [](ImagePixel::RGBA16161616 pixel) -> ImagePixel::RGBA32323232F {
        return {
            static_cast<float>(pixel.r) / static_cast<float>((1 << 16) - 1),
            static_cast<float>(pixel.g) / static_cast<float>((1 << 16) - 1),
            static_cast<float>(pixel.b) / static_cast<float>((1 << 16) - 1),
            static_cast<float>(pixel.a) / static_cast<float>((1 << 16) - 1),
        };
    });
 
    return newData;
}
 
} // namespace
 
std::vector<std::byte> ImageConversion::convertImageDataToFormat(std::span<const std::byte> imageData, ImageFormat oldFormat, ImageFormat newFormat, uint16_t width, uint16_t height) {
    if (imageData.empty() || oldFormat == ImageFormat::EMPTY) {
        return {};
    }
 
    if (oldFormat == newFormat) {
        return {imageData.begin(), imageData.end()};
    }
 
    std::vector<std::byte> newData;
 
    const ImageFormat intermediaryOldFormat = ImageFormatDetails::containerFormat(oldFormat);
    if (ImageFormatDetails::compressed(oldFormat)) {
        newData = ::convertImageDataUsingCompressonator(imageData, oldFormat, intermediaryOldFormat, width, height);
    } else {
        switch (intermediaryOldFormat) {
            case ImageFormat::RGBA8888:      newData = ::convertImageDataToRGBA8888(imageData, oldFormat);      break;
            case ImageFormat::RGBA16161616:  newData = ::convertImageDataToRGBA16161616(imageData, oldFormat);  break;
            case ImageFormat::RGBA32323232F: newData = ::convertImageDataToRGBA32323232F(imageData, oldFormat); break;
            default:                         return {};
        }
    }
 
    if (intermediaryOldFormat == newFormat) {
        return newData;
    }
 
    const ImageFormat intermediaryNewFormat = ImageFormatDetails::containerFormat(newFormat);
    if (intermediaryOldFormat != intermediaryNewFormat) {
        if (intermediaryOldFormat == ImageFormat::RGBA8888) {
            if (intermediaryNewFormat == ImageFormat::RGBA16161616) {
                newData = ::convertImageDataFromRGBA8888ToRGBA16161616(newData);
            } else if (intermediaryNewFormat == ImageFormat::RGBA32323232F) {
                newData = ::convertImageDataFromRGBA8888ToRGBA32323232F(newData);
            } else {
                return {};
            }
        } else if (intermediaryOldFormat == ImageFormat::RGBA16161616) {
            if (intermediaryNewFormat == ImageFormat::RGBA8888) {
                newData = ::convertImageDataFromRGBA16161616ToRGBA8888(newData);
            } else if (intermediaryNewFormat == ImageFormat::RGBA32323232F) {
                newData = ::convertImageDataFromRGBA16161616ToRGBA32323232F(newData);
            } else {
                return {};
            }
        } else if (intermediaryOldFormat == ImageFormat::RGBA32323232F) {
            if (intermediaryNewFormat == ImageFormat::RGBA8888) {
                newData = ::convertImageDataFromRGBA32323232FToRGBA8888(newData);
            } else if (intermediaryNewFormat == ImageFormat::RGBA16161616) {
                newData = ::convertImageDataFromRGBA32323232FToRGBA16161616(newData);
            } else {
                return {};
            }
        } else {
            return {};
        }
    }
 
    if (intermediaryNewFormat == newFormat) {
        return newData;
    }
 
    if (ImageFormatDetails::compressed(newFormat)) {
        newData = ::convertImageDataUsingCompressonator(newData, intermediaryNewFormat, newFormat, width, height);
    } else {
        switch (intermediaryNewFormat) {
            case ImageFormat::RGBA8888:      newData = ::convertImageDataFromRGBA8888(newData, newFormat);      break;
            case ImageFormat::RGBA16161616:  newData = ::convertImageDataFromRGBA16161616(newData, newFormat);  break;
            case ImageFormat::RGBA32323232F: newData = ::convertImageDataFromRGBA32323232F(newData, newFormat); break;
            default:                         return {};
        }
    }
 
    return newData;
}
 
std::vector<std::byte> ImageConversion::convertSeveralImageDataToFormat(std::span<const std::byte> imageData, ImageFormat oldFormat, ImageFormat newFormat, uint8_t mipCount, uint16_t frameCount, uint8_t faceCount, uint16_t width, uint16_t height, uint16_t sliceCount) {
    if (imageData.empty() || oldFormat == ImageFormat::EMPTY) {
        return {};
    }
 
    if (oldFormat == newFormat) {
        return {imageData.begin(), imageData.end()};
    }
 
    std::vector<std::byte> out(ImageFormatDetails::getDataLength(newFormat, mipCount, frameCount, faceCount, width, height, sliceCount));
    for(int mip = mipCount - 1; mip >= 0; mip--) {
        for (int frame = 0; frame < frameCount; frame++) {
            for (int face = 0; face < faceCount; face++) {
                for (int slice = 0; slice < sliceCount; slice++) {
                    if (uint32_t oldOffset, oldLength; ImageFormatDetails::getDataPosition(oldOffset, oldLength, oldFormat, mip, mipCount, frame, frameCount, face, faceCount, width, height, slice, sliceCount)) {
                        const auto convertedImageData = ImageConversion::convertImageDataToFormat({imageData.data() + oldOffset, oldLength}, oldFormat, newFormat, ImageDimensions::getMipDim(mip, width), ImageDimensions::getMipDim(mip, height));
                        if (uint32_t newOffset, newLength; ImageFormatDetails::getDataPosition(newOffset, newLength, newFormat, mip, mipCount, frame, frameCount, face, faceCount, width, height, slice, sliceCount) && newLength == convertedImageData.size()) {
                            std::memcpy(out.data() + newOffset, convertedImageData.data(), newLength);
                        }
                    }
                }
            }
        }
    }
    return out;
}
 
std::array<std::vector<std::byte>, 6> ImageConversion::convertHDRIToCubeMap(std::span<const std::byte> imageData, ImageFormat format, uint16_t width, uint16_t height, uint16_t resolution, bool bilinear) {
    if (imageData.empty() || format == ImageFormat::EMPTY) {
        return {};
    }
 
    if (!resolution) {
        resolution = height;
    }
 
    std::span<const float> imageDataRGBA32323232F{reinterpret_cast<const float*>(imageData.data()), reinterpret_cast<const float*>(imageData.data() + imageData.size())};
 
    std::vector<std::byte> possiblyConvertedDataOrEmptyDontUseMeDirectly;
    if (format != ImageFormat::RGBA32323232F) {
        possiblyConvertedDataOrEmptyDontUseMeDirectly = convertImageDataToFormat(imageData, format, ImageFormat::RGBA32323232F, width, height);
        imageDataRGBA32323232F = {reinterpret_cast<const float*>(possiblyConvertedDataOrEmptyDontUseMeDirectly.data()), reinterpret_cast<const float*>(possiblyConvertedDataOrEmptyDontUseMeDirectly.data() + possiblyConvertedDataOrEmptyDontUseMeDirectly.size())};
    }
 
    // For each face, contains the 3d starting point (corresponding to left bottom pixel), right direction,
    // and up direction in 3d space, corresponding to pixel x,y coordinates of each face
    static constexpr std::array<std::array<math::Vec3f, 3>, 6> startRightUp = {{
        {{{ 1.0f, -1.0f, -1.0f}, { 0.0f, 1.0f,  0.0f}, {-1.0f, 0.0f,  0.0f}}}, // front
        {{{ 1.0f,  1.0f,  1.0f}, { 0.0f,-1.0f,  0.0f}, {-1.0f, 0.0f,  0.0f}}}, // back
        {{{ 1.0f,  1.0f,  1.0f}, { 0.0f, 0.0f, -1.0f}, { 0.0f,-1.0f,  0.0f}}}, // right
        {{{-1.0f, -1.0f,  1.0f}, { 0.0f, 0.0f, -1.0f}, { 0.0f, 1.0f,  0.0f}}}, // left
        {{{ 1.0f, -1.0f,  1.0f}, { 0.0f, 0.0f, -1.0f}, {-1.0f, 0.0f,  0.0f}}}, // up
        {{{ 1.0f,  1.0f, -1.0f}, { 0.0f, 0.0f,  1.0f}, {-1.0f, 0.0f,  0.0f}}}, // down
    }};
 
    std::array<std::vector<std::byte>, 6> faceData;
 
#ifdef SOURCEPP_BUILD_WITH_THREADS
    const auto faceExtraction = [&](int i) {
#else
    for (int i = 0; i < faceData.size(); i++) {
#endif
        const auto start = startRightUp[i][0];
        const auto right = startRightUp[i][1];
        const auto up    = startRightUp[i][2];
 
        faceData[i].resize(resolution * resolution * sizeof(ImagePixel::RGBA32323232F));
        std::span<float> face{reinterpret_cast<float*>(faceData[i].data()), reinterpret_cast<float*>(faceData[i].data() + faceData[i].size())};
 
        for (int row = 0; row < resolution; row++) {
            for (int col = 0; col < resolution; col++) {
                math::Vec3f pixelDirection3d{
                    start[0] + (static_cast<float>(col) * 2.f + 0.5f) / static_cast<float>(resolution) * right[0] + (static_cast<float>(row) * 2.f + 0.5f) / static_cast<float>(resolution) * up[0],
                    start[1] + (static_cast<float>(col) * 2.f + 0.5f) / static_cast<float>(resolution) * right[1] + (static_cast<float>(row) * 2.f + 0.5f) / static_cast<float>(resolution) * up[1],
                    start[2] + (static_cast<float>(col) * 2.f + 0.5f) / static_cast<float>(resolution) * right[2] + (static_cast<float>(row) * 2.f + 0.5f) / static_cast<float>(resolution) * up[2],
                };
                float azimuth = std::atan2(pixelDirection3d[0], -pixelDirection3d[2]) + math::pi_f32; // add pi to move range to 0-360 deg
                float elevation = std::atan(pixelDirection3d[1] / std::sqrt(pixelDirection3d[0] * pixelDirection3d[0] + pixelDirection3d[2] * pixelDirection3d[2])) + math::pi_f32 / 2.f;
                float colHdri = (azimuth / math::pi_f32 / 2.f) * static_cast<float>(width); // add pi to azimuth to move range to 0-360 deg
                float rowHdri = (elevation / math::pi_f32) * static_cast<float>(height);
                if (!bilinear) {
                    int colNearest = std::clamp(static_cast<int>(colHdri), 0, width - 1);
                    int rowNearest = std::clamp(static_cast<int>(rowHdri), 0, height - 1);
                    face[col * 4 + resolution * row * 4 + 0] = imageDataRGBA32323232F[colNearest * 4 + width * rowNearest * 4 + 0];
                    face[col * 4 + resolution * row * 4 + 1] = imageDataRGBA32323232F[colNearest * 4 + width * rowNearest * 4 + 1];
                    face[col * 4 + resolution * row * 4 + 2] = imageDataRGBA32323232F[colNearest * 4 + width * rowNearest * 4 + 2];
                    face[col * 4 + resolution * row * 4 + 3] = imageDataRGBA32323232F[colNearest * 4 + width * rowNearest * 4 + 3];
                } else {
                    float intCol, intRow;
                    // factor gives the contribution of the next column, while the contribution of intCol is 1 - factor
                    float factorCol = std::modf(colHdri - 0.5f, &intCol);
                    float factorRow = std::modf(rowHdri - 0.5f, &intRow);
                    int low_idx_row = static_cast<int>(intRow);
                    int low_idx_column = static_cast<int>(intCol);
                    int high_idx_column;
                    if (factorCol < 0.f) {
                        // modf can only give a negative value if the azimuth falls in the first pixel, left of the
                        // center, so we have to mix with the pixel on the opposite side of the panoramic image
                        high_idx_column = width - 1;
                    } else if (low_idx_column == width - 1) {
                        // if we are in the right-most pixel, and fall right of the center, mix with the left-most pixel
                        high_idx_column = 0;
                    } else {
                        high_idx_column = low_idx_column + 1;
                    }
                    int high_idx_row;
                    if (factorRow < 0.f || low_idx_row == height - 1) {
                        high_idx_row = low_idx_row;
                        factorRow = 0.f;
                    } else {
                        high_idx_row = low_idx_row + 1;
                    }
                    factorCol = std::abs(factorCol);
                    factorRow = std::abs(factorRow);
                    float f1 = (1 - factorRow) * (1 - factorCol);
                    float f2 = factorRow * (1 - factorCol);
                    float f3 = (1 - factorRow) * factorCol;
                    float f4 = factorRow * factorCol;
                    for (int j = 0; j < 4; j++) {
                        face[col * 4 + resolution * row * 4 + j] =
                            imageDataRGBA32323232F[low_idx_column  * 4 + width * low_idx_row  * 4 + j] * f1 +
                            imageDataRGBA32323232F[low_idx_column  * 4 + width * high_idx_row * 4 + j] * f2 +
                            imageDataRGBA32323232F[high_idx_column * 4 + width * low_idx_row  * 4 + j] * f3 +
                            imageDataRGBA32323232F[high_idx_column * 4 + width * high_idx_row * 4 + j] * f4;
                    }
                }
            }
        }
        if (format != ImageFormat::RGBA32323232F) {
            faceData[i] = convertImageDataToFormat(faceData[i], ImageFormat::RGBA32323232F, format, resolution, resolution);
        }
    }
#ifdef SOURCEPP_BUILD_WITH_THREADS
    ;
    std::array<std::future<void>, 6> faceFutures{
        std::async(std::launch::async, faceExtraction, 0),
        std::async(std::launch::async, faceExtraction, 1),
        std::async(std::launch::async, faceExtraction, 2),
        std::async(std::launch::async, faceExtraction, 3),
        std::async(std::launch::async, faceExtraction, 4),
        std::async(std::launch::async, faceExtraction, 5),
    };
    for (auto& future : faceFutures) {
        future.get();
    }
#endif
 
    return faceData;
}
 
ImageConversion::FileFormat ImageConversion::getDefaultFileFormatForImageFormat(ImageFormat format) {
    using enum FileFormat;
    return ImageFormatDetails::decimal(format) ? EXR : PNG;
}
 
std::vector<std::byte> ImageConversion::convertImageDataToFile(std::span<const std::byte> imageData, ImageFormat format, uint16_t width, uint16_t height, FileFormat fileFormat) {
    if (imageData.empty() || format == ImageFormat::EMPTY) {
        return {};
    }
    std::vector<std::byte> out;
    auto stbWriteFunc = [](void* out_, void* data, int size) {
        std::copy_n(static_cast<std::byte*>(data), size, std::back_inserter(*static_cast<std::vector<std::byte>*>(out_)));
    };
 
    if (fileFormat == FileFormat::DEFAULT) {
        fileFormat = getDefaultFileFormatForImageFormat(format);
    }
    switch (fileFormat) {
        case FileFormat::PNG: {
            if (format == ImageFormat::RGB888) {
                stbi_write_png_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGB888), imageData.data(), 0);
            } else if (format == ImageFormat::RGBA8888) {
                stbi_write_png_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGBA8888), imageData.data(), 0);
            } else if (ImageFormatDetails::opaque(format)) {
                const auto rgb = convertImageDataToFormat(imageData, format, ImageFormat::RGB888, width, height);
                stbi_write_png_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGB888), rgb.data(), 0);
            } else {
                const auto rgba = convertImageDataToFormat(imageData, format, ImageFormat::RGBA8888, width, height);
                stbi_write_png_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGBA8888), rgba.data(), 0);
            }
            break;
        }
        case FileFormat::JPG: {
            if (format == ImageFormat::RGB888) {
                stbi_write_jpg_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGB888), imageData.data(), 95);
            } else {
                const auto rgb = convertImageDataToFormat(imageData, format, ImageFormat::RGB888, width, height);
                stbi_write_jpg_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGB888), rgb.data(), 95);
            }
            break;
        }
        case FileFormat::BMP: {
            if (format == ImageFormat::RGB888) {
                stbi_write_bmp_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGB888), imageData.data());
            } else if (format == ImageFormat::RGBA8888) {
                stbi_write_bmp_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGBA8888), imageData.data());
            } else if (ImageFormatDetails::opaque(format)) {
                const auto rgb = convertImageDataToFormat(imageData, format, ImageFormat::RGB888, width, height);
                stbi_write_bmp_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGB888), rgb.data());
            } else {
                const auto rgba = convertImageDataToFormat(imageData, format, ImageFormat::RGBA8888, width, height);
                stbi_write_bmp_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGBA8888), rgba.data());
            }
            break;
        }
        case FileFormat::TGA: {
            if (format == ImageFormat::RGB888) {
                stbi_write_tga_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGB888), imageData.data());
            } else if (format == ImageFormat::RGBA8888) {
                stbi_write_tga_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGBA8888), imageData.data());
            } else if (ImageFormatDetails::opaque(format)) {
                const auto rgb = convertImageDataToFormat(imageData, format, ImageFormat::RGB888, width, height);
                stbi_write_tga_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGB888), rgb.data());
            } else {
                const auto rgba = convertImageDataToFormat(imageData, format, ImageFormat::RGBA8888, width, height);
                stbi_write_tga_to_func(stbWriteFunc, &out, width, height, sizeof(ImagePixel::RGBA8888), rgba.data());
            }
            break;
        }
        case FileFormat::WEBP: {
            WebPConfig config;
            WebPConfigInit(&config);
            WebPConfigPreset(&config, WEBP_PRESET_DRAWING, 75.f);
            WebPConfigLosslessPreset(&config, 6);
 
            WebPPicture pic;
            if (!WebPPictureInit(&pic)) {
                return {};
            }
            pic.width = width;
            pic.height = height;
            if (!WebPPictureAlloc(&pic)) {
                return {};
            }
 
            if (format == ImageFormat::RGB888) {
                WebPPictureImportRGB(&pic, reinterpret_cast<const uint8_t*>(imageData.data()), static_cast<int>(width * sizeof(ImagePixel::RGB888)));
            } else if (format == ImageFormat::RGBA8888) {
                WebPPictureImportRGBA(&pic, reinterpret_cast<const uint8_t*>(imageData.data()), static_cast<int>(width * sizeof(ImagePixel::RGBA8888)));
            } else if (ImageFormatDetails::opaque(format)) {
                const auto rgb = convertImageDataToFormat(imageData, format, ImageFormat::RGB888, width, height);
                WebPPictureImportRGB(&pic, reinterpret_cast<const uint8_t*>(rgb.data()), static_cast<int>(width * sizeof(ImagePixel::RGB888)));
            } else {
                const auto rgba = convertImageDataToFormat(imageData, format, ImageFormat::RGBA8888, width, height);
                WebPPictureImportRGBA(&pic, reinterpret_cast<const uint8_t*>(rgba.data()), static_cast<int>(width * sizeof(ImagePixel::RGBA8888)));
            }
 
            WebPMemoryWriter writer;
            WebPMemoryWriterInit(&writer);
            pic.writer = &WebPMemoryWrite;
            pic.custom_ptr = &writer;
 
            int ok = WebPEncode(&config, &pic);
            WebPPictureFree(&pic);
            if (!ok) {
                WebPMemoryWriterClear(&writer);
                return {};
            }
 
            if (writer.mem && writer.size) {
                out.resize(writer.size);
                std::memcpy(out.data(), writer.mem, writer.size);
            }
            WebPMemoryWriterClear(&writer);
            break;
        }
        case FileFormat::QOI: {
            qoi_desc descriptor{
                .width = width,
                .height = height,
                .channels = 0,
                .colorspace = QOI_SRGB,
            };
            void* qoiData = nullptr;
            int qoiDataLen = 0;
            if (format == ImageFormat::RGB888) {
                descriptor.channels = 3;
                qoiData = qoi_encode(imageData.data(), &descriptor, &qoiDataLen);
            } else if (format == ImageFormat::RGBA8888) {
                descriptor.channels = 4;
                qoiData = qoi_encode(imageData.data(), &descriptor, &qoiDataLen);
            } else if (ImageFormatDetails::opaque(format)) {
                const auto rgb = convertImageDataToFormat(imageData, format, ImageFormat::RGB888, width, height);
                descriptor.channels = 3;
                qoiData = qoi_encode(rgb.data(), &descriptor, &qoiDataLen);
            } else {
                const auto rgba = convertImageDataToFormat(imageData, format, ImageFormat::RGBA8888, width, height);
                descriptor.channels = 4;
                qoiData = qoi_encode(rgba.data(), &descriptor, &qoiDataLen);
            }
            if (qoiData && qoiDataLen) {
                out.resize(qoiDataLen);
                std::memcpy(out.data(), qoiData, qoiDataLen);
            }
            std::free(qoiData);
            break;
        }
        case FileFormat::HDR: {
            if (format == ImageFormat::RGB323232F) {
                stbi_write_hdr_to_func(stbWriteFunc, &out, width, height, ImageFormatDetails::bpp(ImageFormat::RGB323232F) / (8 * sizeof(float)), reinterpret_cast<const float*>(imageData.data()));
            } else {
                const auto hdr = convertImageDataToFormat(imageData, format, ImageFormat::RGB323232F, width, height);
                stbi_write_hdr_to_func(stbWriteFunc, &out, width, height, ImageFormatDetails::bpp(ImageFormat::RGB323232F) / (8 * sizeof(float)), reinterpret_cast<const float*>(hdr.data()));
            }
            break;
        }
        case FileFormat::EXR: {
            EXRHeader header;
            InitEXRHeader(&header);
 
            std::vector<std::byte> rawData;
            if (!ImageFormatDetails::decimal(format) || ImageFormatDetails::compressed(format)) {
                if (ImageFormatDetails::transparent(format)) {
                    rawData = convertImageDataToFormat(imageData, format, ImageFormat::RGBA32323232F, width, height);
                    format = ImageFormat::RGBA32323232F;
                } else {
                    rawData = convertImageDataToFormat(imageData, format, ImageFormat::RGB323232F, width, height);
                    format = ImageFormat::RGB323232F;
                }
            } else {
                rawData = {imageData.begin(), imageData.end()};
            }
 
            header.num_channels = (ImageFormatDetails::red(format) > 0) + (ImageFormatDetails::green(format) > 0) + (ImageFormatDetails::blue(format) > 0) + (ImageFormatDetails::alpha(format) > 0);
            header.channels = static_cast<EXRChannelInfo*>(std::malloc(header.num_channels * sizeof(EXRChannelInfo)));
            header.pixel_types = static_cast<int*>(malloc(header.num_channels * sizeof(int)));
            header.requested_pixel_types = static_cast<int*>(malloc(header.num_channels * sizeof(int)));
 
            switch (header.num_channels) {
                case 4:
                    header.channels[0].name[0] = 'A';
                    header.channels[1].name[0] = 'B';
                    header.channels[2].name[0] = 'G';
                    header.channels[3].name[0] = 'R';
                    break;
                case 3:
                    header.channels[0].name[0] = 'B';
                    header.channels[1].name[0] = 'G';
                    header.channels[2].name[0] = 'R';
                    break;
                case 2:
                    header.channels[0].name[0] = 'G';
                    header.channels[1].name[0] = 'R';
                    break;
                case 1:
                    header.channels[0].name[0] = 'R';
                    break;
                default:
                    FreeEXRHeader(&header);
                    return {};
            }
            for (int i = 0; i < header.num_channels; i++) {
                header.channels[i].name[1] = '\0';
            }
 
            int pixelType = (ImageFormatDetails::red(format) / 8) == sizeof(half) ? TINYEXR_PIXELTYPE_HALF : TINYEXR_PIXELTYPE_FLOAT;
            for (int i = 0; i < header.num_channels; i++) {
                header.pixel_types[i] = pixelType;
                header.requested_pixel_types[i] = pixelType;
            }
 
            std::vector<std::vector<std::byte>> images(header.num_channels);
            std::vector<void*> imagePtrs(header.num_channels);
            switch (header.num_channels) {
                case 4:
                    if (pixelType == TINYEXR_PIXELTYPE_HALF) {
                        images[0] = extractChannelFromImageData(imageData, &ImagePixel::RGBA16161616F::a);
                        images[1] = extractChannelFromImageData(imageData, &ImagePixel::RGBA16161616F::b);
                        images[2] = extractChannelFromImageData(imageData, &ImagePixel::RGBA16161616F::g);
                        images[3] = extractChannelFromImageData(imageData, &ImagePixel::RGBA16161616F::r);
                    } else {
                        images[0] = extractChannelFromImageData(imageData, &ImagePixel::RGBA32323232F::a);
                        images[1] = extractChannelFromImageData(imageData, &ImagePixel::RGBA32323232F::b);
                        images[2] = extractChannelFromImageData(imageData, &ImagePixel::RGBA32323232F::g);
                        images[3] = extractChannelFromImageData(imageData, &ImagePixel::RGBA32323232F::r);
                    }
                    break;
                case 3:
                    if (pixelType == TINYEXR_PIXELTYPE_HALF) {
                        // We should not be here!
                        FreeEXRHeader(&header);
                        return {};
                    }
                    images[0] = extractChannelFromImageData(imageData, &ImagePixel::RGB323232F::b);
                    images[1] = extractChannelFromImageData(imageData, &ImagePixel::RGB323232F::g);
                    images[2] = extractChannelFromImageData(imageData, &ImagePixel::RGB323232F::r);
                    break;
                case 2:
                    if (pixelType == TINYEXR_PIXELTYPE_HALF) {
                        images[0] = extractChannelFromImageData(imageData, &ImagePixel::RG1616F::g);
                        images[1] = extractChannelFromImageData(imageData, &ImagePixel::RG1616F::r);
                    } else {
                        images[0] = extractChannelFromImageData(imageData, &ImagePixel::RG3232F::g);
                        images[1] = extractChannelFromImageData(imageData, &ImagePixel::RG3232F::r);
                    }
                    break;
                case 1:
                    images[0] = rawData;
                    break;
                default:
                    FreeEXRHeader(&header);
                    return {};
            }
            for (int i = 0; i < header.num_channels; i++) {
                imagePtrs[i] = images[i].data();
            }
 
            EXRImage image;
            InitEXRImage(&image);
            image.width = width;
            image.height = height;
            image.images = reinterpret_cast<unsigned char**>(imagePtrs.data());
            image.num_channels = header.num_channels;
 
            unsigned char* data = nullptr;
            const char* err = nullptr;
 
            size_t size = SaveEXRImageToMemory(&image, &header, &data, &err);
            if (err) {
                FreeEXRErrorMessage(err);
                FreeEXRHeader(&header);
                return {};
            }
            if (data) {
                out = {reinterpret_cast<std::byte*>(data), reinterpret_cast<std::byte*>(data) + size};
                std::free(data);
            }
 
            FreeEXRHeader(&header);
            break;
        }
        case FileFormat::DEFAULT:
            break;
    }
    return out;
}
 
namespace {
 
template<typename T>
using stb_ptr = std::unique_ptr<T, void(*)(void*)>;
 
} // namespace
 
std::vector<std::byte> ImageConversion::convertFileToImageData(std::span<const std::byte> fileData, ImageFormat& format, int& width, int& height, int& frameCount) {
    stbi_convert_iphone_png_to_rgb(true);
 
    format = ImageFormat::EMPTY;
    width = 0;
    height = 0;
    int channels = 0;
    frameCount = 1;
 
    // EXR
    if (EXRVersion version; ParseEXRVersionFromMemory(&version, reinterpret_cast<const unsigned char*>(fileData.data()), fileData.size()) == TINYEXR_SUCCESS) {
        if (version.multipart || version.non_image) {
            return {};
        }
 
        EXRHeader header;
        InitEXRHeader(&header);
        const char* err = nullptr;
        if (ParseEXRHeaderFromMemory(&header, &version, reinterpret_cast<const unsigned char*>(fileData.data()), fileData.size(), &err) != TINYEXR_SUCCESS) {
            FreeEXRErrorMessage(err);
            return {};
        }
 
        // Sanity check
        if (header.num_channels < 1) {
            FreeEXRHeader(&header);
            return {};
        }
 
        // Define the channel names we support (RGBA, greyscale)
        std::unordered_map<std::string_view, int> channelIndices{{"R", -1}, {"G",  -1}, {"B",  -1}, {"A", -1}, {"Y", -1}};
 
        // Get channel type (EXR supports different types per channel, we do not)
        // Rather than bailing we ask EXR to convert the lowest precision data
        auto channelType = header.pixel_types[0];
        for (int i = 1; i < header.num_channels; i++) {
            // UINT -> HALF -> FLOAT
            if (header.pixel_types[i] > channelType && channelIndices.contains(header.channels[i].name)) {
                channelType = header.pixel_types[i];
            }
        }
        // requested_pixel_types field only supports floats
        if (channelType == TINYEXR_PIXELTYPE_UINT) {
            channelType = TINYEXR_PIXELTYPE_HALF;
        }
 
        // Determine proper format to use
        for (int i = 0; i < header.num_channels; i++) {
            if (channelIndices.contains(header.channels[i].name)) {
                channelIndices[header.channels[i].name] = i;
            }
        }
        if (channelIndices["Y"] >= 0) {
            if (channelIndices["A"] >= 0) {
                format = channelType == TINYEXR_PIXELTYPE_HALF ? ImageFormat::RGBA16161616F : ImageFormat::RGBA32323232F;
            } else {
                if (channelType == TINYEXR_PIXELTYPE_HALF) {
                    // VTF has no RGB161616F
                    channelType = TINYEXR_PIXELTYPE_FLOAT;
                }
                format = ImageFormat::RGB323232F;
            }
            channelIndices["R"] = channelIndices["Y"];
            channelIndices["G"] = channelIndices["Y"];
            channelIndices["B"] = channelIndices["Y"];
        } else if (channelIndices["A"] >= 0) {
            format = channelType == TINYEXR_PIXELTYPE_HALF ? ImageFormat::RGBA16161616F : ImageFormat::RGBA32323232F;
        } else if (channelIndices["B"] >= 0) {
            if (channelType == TINYEXR_PIXELTYPE_HALF) {
                // VTF has no RGB161616F
                channelType = TINYEXR_PIXELTYPE_FLOAT;
            }
            format = ImageFormat::RGB323232F;
        } else if (channelIndices["G"] >= 0) {
            format = channelType == TINYEXR_PIXELTYPE_HALF ? ImageFormat::RG1616F : ImageFormat::RG3232F;
        } else if (channelIndices["R"] >= 0) {
            format = channelType == TINYEXR_PIXELTYPE_HALF ? ImageFormat::R16F : ImageFormat::R32F;
        } else {
            FreeEXRHeader(&header);
            return {};
        }
 
        // Now that channelType has stopped changing, we can set it properly
        for (int i = 0; i < header.num_channels; i++) {
            if (header.pixel_types[i] != channelType && channelIndices.contains(header.channels[i].name)) {
                header.requested_pixel_types[i] = channelType;
            }
        }
 
        EXRImage image;
        InitEXRImage(&image);
        if (LoadEXRImageFromMemory(&image, &header, reinterpret_cast<const unsigned char*>(fileData.data()), fileData.size(), &err) != TINYEXR_SUCCESS) {
            FreeEXRErrorMessage(err);
            FreeEXRHeader(&header);
            return {};
        }
 
        width = image.width;
        height = image.height;
 
        // Merge channel data into a single buffer
        std::vector<std::byte> combinedChannels(width * height * (ImageFormatDetails::bpp(format) / 8));
        const auto populateBuffer = [
            hasRed=ImageFormatDetails::red(format) > 0,
            hasGreen=ImageFormatDetails::green(format) > 0,
            hasBlue=ImageFormatDetails::blue(format) > 0,
            hasAlpha=ImageFormatDetails::alpha(format) > 0,
            width,
            height,
            &header,
            r=channelIndices["R"],
            g=channelIndices["G"],
            b=channelIndices["B"],
            a=channelIndices["A"],
            &image,
            &combinedChannels
        ]<typename C> {
            const auto channelCount = hasRed + hasGreen + hasBlue + hasAlpha;
            std::span out{reinterpret_cast<C*>(combinedChannels.data()), combinedChannels.size() / sizeof(C)};
            if (header.tiled) {
                for (int t = 0; t < image.num_tiles; t++) {
                    auto** src = reinterpret_cast<C**>(image.tiles[t].images);
                    for (int j = 0; j < header.tile_size_y; j++) {
                        for (int i = 0; i < header.tile_size_x; i++) {
                            const auto ii = static_cast<uint64_t>(image.tiles[t].offset_x) * header.tile_size_x + i;
                            const auto jj = static_cast<uint64_t>(image.tiles[t].offset_y) * header.tile_size_y + j;
                            const auto idx = ii + jj * image.width;
 
                            if (ii >= image.width || jj >= image.height) {
                                continue;
                            }
 
                            const auto srcIdx = j * static_cast<uint64_t>(header.tile_size_x) + i;
                            if (r >= 0)        out[idx * channelCount + 0] = src[r][srcIdx];
                            else if (hasRed)   out[idx * channelCount + 0] = 0.f;
                            if (g >= 0)        out[idx * channelCount + 1] = src[g][srcIdx];
                            else if (hasGreen) out[idx * channelCount + 1] = 0.f;
                            if (b >= 0)        out[idx * channelCount + 2] = src[b][srcIdx];
                            else if (hasBlue)  out[idx * channelCount + 2] = 0.f;
                            if (a >= 0)        out[idx * channelCount + 3] = src[a][srcIdx];
                            else if (hasAlpha) out[idx * channelCount + 3] = 1.f;
                        }
                    }
                }
            } else {
                auto** src = reinterpret_cast<C**>(image.images);
                for (uint64_t i = 0; i < width * height; i++) {
                    if (r >= 0)        out[i * channelCount + 0] = src[r][i];
                    else if (hasRed)   out[i * channelCount + 0] = 0.f;
                    if (g >= 0)        out[i * channelCount + 1] = src[g][i];
                    else if (hasGreen) out[i * channelCount + 1] = 0.f;
                    if (b >= 0)        out[i * channelCount + 2] = src[b][i];
                    else if (hasBlue)  out[i * channelCount + 2] = 0.f;
                    if (a >= 0)        out[i * channelCount + 3] = src[a][i];
                    else if (hasAlpha) out[i * channelCount + 3] = 1.f;
                }
            }
        };
        if (channelType == TINYEXR_PIXELTYPE_HALF) {
            populateBuffer.operator()<half>();
        } else {
            populateBuffer.operator()<float>();
        }
 
        FreeEXRImage(&image);
        FreeEXRHeader(&header);
        return combinedChannels;
    }
 
    // HDR
    if (stbi_is_hdr_from_memory(reinterpret_cast<const stbi_uc*>(fileData.data()), static_cast<int>(fileData.size()))) {
        const ::stb_ptr<float> stbImage{
            stbi_loadf_from_memory(reinterpret_cast<const stbi_uc*>(fileData.data()), static_cast<int>(fileData.size()), &width, &height, &channels, 0),
            &stbi_image_free,
        };
        if (!stbImage) {
            return {};
        }
        switch (channels) {
            case 1:  format = ImageFormat::R32F;          break;
            case 2:  format = ImageFormat::RG3232F;       break;
            case 3:  format = ImageFormat::RGB323232F;    break;
            case 4:  format = ImageFormat::RGBA32323232F; break;
            default: return {};
        }
        return {reinterpret_cast<std::byte*>(stbImage.get()), reinterpret_cast<std::byte*>(stbImage.get()) + ImageFormatDetails::getDataLength(format, width, height)};
    }
 
    // WebP
    if (WebPBitstreamFeatures features; fileData.size() > 12 && static_cast<char>(fileData[8]) == 'W' && static_cast<char>(fileData[9]) == 'E' && static_cast<char>(fileData[10]) == 'B' && static_cast<char>(fileData[11]) == 'P' && WebPGetFeatures(reinterpret_cast<const uint8_t*>(fileData.data()), fileData.size(), &features) == VP8_STATUS_OK) {
        width = features.width;
        height = features.height;
        // We don't process animated WebP right now
        frameCount = 1;
 
        std::vector<std::byte> out;
        if (features.has_alpha) {
            format = ImageFormat::RGBA8888;
            out.resize(width * height * (ImageFormatDetails::bpp(format) / 8));
            if (!WebPDecodeRGBAInto(reinterpret_cast<const uint8_t*>(fileData.data()), fileData.size(), reinterpret_cast<uint8_t*>(out.data()), out.size(), width * (ImageFormatDetails::bpp(format) / 8))) {
                return {};
            }
        } else {
            format = ImageFormat::RGB888;
            out.resize(width * height * (ImageFormatDetails::bpp(format) / 8));
            if (!WebPDecodeRGBInto(reinterpret_cast<const uint8_t*>(fileData.data()), fileData.size(), reinterpret_cast<uint8_t*>(out.data()), out.size(), width * (ImageFormatDetails::bpp(format) / 8))) {
                return {};
            }
        }
        return out;
    }
 
    // GIF
    if (fileData.size() > 3 && static_cast<char>(fileData[0]) == 'G' && static_cast<char>(fileData[1]) == 'I' && static_cast<char>(fileData[2]) == 'F') {
        const ::stb_ptr<stbi_uc> stbImage{
            stbi_load_gif_from_memory(reinterpret_cast<const stbi_uc*>(fileData.data()), static_cast<int>(fileData.size()), nullptr, &width, &height, &frameCount, &channels, 0),
            &stbi_image_free,
        };
        if (!stbImage || !frameCount) {
            return {};
        }
        switch (channels) {
            case 1:  format = ImageFormat::I8;       break;
            case 2:  format = ImageFormat::UV88;     break;
            case 3:  format = ImageFormat::RGB888;   break;
            case 4:  format = ImageFormat::RGBA8888; break;
            default: return {};
        }
        return {reinterpret_cast<std::byte*>(stbImage.get()), reinterpret_cast<std::byte*>(stbImage.get() + (ImageFormatDetails::getDataLength(format, width, height) * frameCount))};
    }
 
    // APNG
    {
        stbi__context s;
        stbi__start_mem(&s, reinterpret_cast<const stbi_uc*>(fileData.data()), static_cast<int>(fileData.size()));
        if (stbi__png_test(&s)) {
            // We know it's a PNG, but is it an APNG? You'll have to scroll past the decoder to find out!
            const auto apngDecoder = [&format, &width, &height, &frameCount]<typename P>(const auto& stbImage, std::size_t dirOffset) -> std::vector<std::byte> {
                auto* dir = reinterpret_cast<stbi__apng_directory*>(stbImage.get() + dirOffset);
                if (dir->type != STBI__STRUCTURE_TYPE_APNG_DIRECTORY) {
                    return {}; // Malformed
                }
 
                format = P::FORMAT;
                frameCount = static_cast<int>(dir->num_frames);
 
                static constexpr auto calcPixelOffset = [](uint32_t offsetX, uint32_t offsetY, uint32_t width) {
                    return ((offsetY * width) + offsetX) * sizeof(P);
                };
 
                // Where dst is a full frame and src is a subregion
                static constexpr auto copyImageData = [](std::span<std::byte> dst, uint32_t dstWidth, uint32_t dstHeight, std::span<const std::byte> src, uint32_t srcWidth, uint32_t srcHeight, uint32_t srcOffsetX, uint32_t srcOffsetY) {
                    for (uint32_t y = 0; y < srcHeight; y++) {
                        std::copy(
#ifdef SOURCEPP_BUILD_WITH_TBB
                            std::execution::unseq,
#endif
                            src.data() + calcPixelOffset(         0,              y, srcWidth),
                            src.data() + calcPixelOffset(  srcWidth,              y, srcWidth),
                            dst.data() + calcPixelOffset(srcOffsetX, srcOffsetY + y, dstWidth));
                    }
                };
 
                // Where dst and src are the same size and we are copying a subregion
                static constexpr auto copyImageSubRectData = [](std::span<std::byte> dst, std::span<const std::byte> src, uint32_t imgWidth, uint32_t imgHeight, uint32_t subWidth, uint32_t subHeight, uint32_t subOffsetX, uint32_t subOffsetY) {
                    for (uint32_t y = subOffsetY; y < subOffsetY + subHeight; y++) {
                        std::copy(
#ifdef SOURCEPP_BUILD_WITH_TBB
                            std::execution::unseq,
#endif
                            src.data() + calcPixelOffset(subOffsetX,            y, imgWidth),
                            src.data() + calcPixelOffset(subOffsetX + subWidth, y, imgWidth),
                            dst.data() + calcPixelOffset(subOffsetX,            y, imgWidth));
                    }
                };
 
                static constexpr auto clearImageData = [](std::span<std::byte> dst, uint32_t dstWidth, uint32_t dstHeight, uint32_t clrWidth, uint32_t clrHeight, uint32_t clrOffsetX, uint32_t clrOffsetY) {
                    for (uint32_t y = 0; y < clrHeight; y++) {
                        std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
                            std::execution::unseq,
#endif
                            dst.data() + calcPixelOffset(clrOffsetX, clrOffsetY + y, dstWidth),
                            dst.data() + calcPixelOffset(clrOffsetX, clrOffsetY + y, dstWidth) + (clrWidth * sizeof(P)),
                            dst.data() + calcPixelOffset(clrOffsetX, clrOffsetY + y, dstWidth),
                            [](std::byte) { return std::byte{0}; });
                    }
                };
 
                static constexpr auto overlayImageData = [](std::span<std::byte> dst, uint32_t dstWidth, uint32_t dstHeight, std::span<const std::byte> src, uint32_t srcWidth, uint32_t srcHeight, uint32_t srcOffsetX, uint32_t srcOffsetY) {
                    for (uint32_t y = 0; y < srcHeight; y++) {
                        const auto* sp = reinterpret_cast<const uint8_t*>(src.data() + calcPixelOffset(0, y, srcWidth));
                        auto* dp = reinterpret_cast<uint8_t*>(dst.data() + calcPixelOffset(srcOffsetX, srcOffsetY + y, dstWidth));
                        for (uint32_t x = 0; x < srcWidth; x++, sp += 4, dp += 4) {
                            if (sp[3] == 0) {
                                continue;
                            } else if ((sp[3] == 0xff) || (dp[3] == 0)) {
                                std::copy(sp, sp + sizeof(P), dp);
                            } else {
                                int u = sp[3] * 0xff;
                                int v = (0xff - sp[3]) * dp[3];
                                int al = u + v;
                                dp[0] = (sp[0] * u + dp[0] * v) / al;
                                dp[1] = (sp[1] * u + dp[1] * v) / al;
                                dp[2] = (sp[2] * u + dp[2] * v) / al;
                                dp[3] = al / 0xff;
                            }
                        }
                    }
                };
 
                // https://wiki.mozilla.org/APNG_Specification
                const uint64_t fullFrameSize = sizeof(P) * width * height;
                uint64_t currentFrameSize = 0;
                std::vector<std::byte> out(fullFrameSize * frameCount);
                uint64_t srcFrameOffset = 0;
                uint64_t dstFrameOffset = 0;
                for (uint32_t i = 0; i < dir->num_frames; i++) {
                    const auto& frame = dir->frames[i];
                    currentFrameSize = sizeof(P) * frame.width * frame.height;
 
                    // If the parameters are perfect we can memcpy all the data in
                    if (frame.width == width && frame.height == height && frame.x_offset == 0 && frame.y_offset == 0 && frame.blend_op == STBI_APNG_blend_op_source) {
                        std::memcpy(out.data() + dstFrameOffset, stbImage.get() + srcFrameOffset, fullFrameSize);
                    } else {
                        // Check the blend op
                        if (frame.blend_op == STBI_APNG_blend_op_source || (i == 0 && frame.blend_op == STBI_APNG_blend_op_over)) {
                            copyImageData({out.data() + dstFrameOffset, out.data() + dstFrameOffset + fullFrameSize}, width, height, {reinterpret_cast<const std::byte*>(stbImage.get() + srcFrameOffset), reinterpret_cast<const std::byte*>(stbImage.get() + srcFrameOffset + currentFrameSize)}, frame.width, frame.height, frame.x_offset, frame.y_offset);
                        } else if (frame.blend_op == STBI_APNG_blend_op_over) {
                            overlayImageData({out.data() + dstFrameOffset, out.data() + dstFrameOffset + fullFrameSize}, width, height, {reinterpret_cast<const std::byte*>(stbImage.get() + srcFrameOffset), reinterpret_cast<const std::byte*>(stbImage.get() + srcFrameOffset + currentFrameSize)}, frame.width, frame.height, frame.x_offset, frame.y_offset);
                        } else {
                            return {}; // Malformed
                        }
                    }
 
                    dstFrameOffset += fullFrameSize;
                    srcFrameOffset += currentFrameSize;
 
                    // Bail here if this is the last frame
                    if (i == dir->num_frames - 1) {
                        continue;
                    }
 
                    // Copy over this frame to the next one
                    copyImageData({out.data() + dstFrameOffset, out.data() + dstFrameOffset + fullFrameSize}, width, height, {out.data() + dstFrameOffset - fullFrameSize, out.data() + dstFrameOffset}, width, height, 0, 0);
 
                    // Check the dispose op to see what to do about the frame's region for the next frame, if there is one
                    if (frame.dispose_op == STBI_APNG_dispose_op_background || (i == 0 && frame.dispose_op == STBI_APNG_dispose_op_previous)) {
                        clearImageData({out.data() + dstFrameOffset, out.data() + dstFrameOffset + fullFrameSize}, width, height, frame.width, frame.height, frame.x_offset, frame.y_offset);
                    } else if (frame.dispose_op == STBI_APNG_dispose_op_previous) {
                        copyImageSubRectData({out.data() + dstFrameOffset, out.data() + dstFrameOffset + fullFrameSize}, {out.data() + dstFrameOffset - fullFrameSize, out.data() + dstFrameOffset}, width, height, frame.width, frame.height, frame.x_offset, frame.y_offset);
                    } else if (frame.dispose_op != STBI_APNG_dispose_op_none) {
                        return {}; // Malformed
                    }
                }
#if 0
                // Debug code from https://gist.github.com/jcredmond/9ef711b406e42a250daa3797ce96fd26
 
                static const char *dispose_ops[] = {
                    "STBI_APNG_dispose_op_none", // leave the old frame
                    "STBI_APNG_dispose_op_background", // clear frame's region to black transparent
                    "STBI_APNG_dispose_op_previous", // frame's region should be reverted to prior frame before adding new one - if first frame, clear region to black transparent
                };
 
                static const char *blend_ops[] = {
                    "STBI_APNG_blend_op_source", // all color, including alpha, overwrites prior image
                    "STBI_APNG_blend_op_over", // composited onto the output buffer with algorithm
                };
 
                fprintf(stderr, "dir_offset                       : %zu\n", dirOffset);
                fprintf(stderr, "dir.type                         : %.*s\n", 4, (unsigned char *) &dir->type);
                fprintf(stderr, "dir.num_frames                   : %u\n", dir->num_frames);
                fprintf(stderr, "dir.default_image_is_first_frame : %s\n",
                        dir->default_image_is_first_frame ? "yes" : "no");
                fprintf(stderr, "dir.num_plays                    : %u\n", dir->num_plays);
 
                for (int i = 0; i < dir->num_frames; ++i) {
                    stbi__apng_frame_directory_entry *frame = &dir->frames[i];
 
                    fprintf(stderr, "frame         : %u\n", i);
                    fprintf(stderr, "   width      : %u\n", frame->width);
                    fprintf(stderr, "   height     : %u\n", frame->height);
                    fprintf(stderr, "   x_offset   : %u\n", frame->x_offset);
                    fprintf(stderr, "   y_offset   : %u\n", frame->y_offset);
                    fprintf(stderr, "   delay_num  : %u\n", frame->delay_num);
                    fprintf(stderr, "   delay_den  : %u\n", frame->delay_den);
                    fprintf(stderr, "   dispose_op : %s\n", dispose_ops[frame->dispose_op]);
                    fprintf(stderr, "   blend_op   : %s\n", blend_ops[frame->blend_op]);
                }
#endif
                return out;
            };
 
            std::size_t dirOffset = 0;
            if (stbi__png_is16(&s)) {
                const ::stb_ptr<stbi_us> stbImage{
                    stbi__apng_load_16bit(&s, &width, &height, &channels, STBI_rgb_alpha, &dirOffset),
                    &stbi_image_free,
                };
                if (stbImage && dirOffset) {
                    return apngDecoder.template operator()<ImagePixel::RGBA16161616>(stbImage, dirOffset);
                }
            } else {
                const ::stb_ptr<stbi_uc> stbImage{
                    stbi__apng_load_8bit(&s, &width, &height, &channels, STBI_rgb_alpha, &dirOffset),
                    &stbi_image_free,
                };
                if (stbImage && dirOffset) {
                    return apngDecoder.template operator()<ImagePixel::RGBA8888>(stbImage, dirOffset);
                }
            }
        }
    }
 
    // QOI header
    if (fileData.size() >= 26 && *reinterpret_cast<const uint32_t*>(fileData.data()) == parser::binary::makeFourCC("fioq")) {
        qoi_desc descriptor;
        const ::stb_ptr<std::byte> qoiImage{
            static_cast<std::byte*>(qoi_decode(fileData.data(), fileData.size(), &descriptor, 0)),
            &std::free,
        };
        if (!qoiImage) {
            return {};
        }
        width = descriptor.width;
        height = descriptor.height;
        channels = descriptor.channels;
        switch (channels) {
            case 3:  format = ImageFormat::RGB888;   break;
            case 4:  format = ImageFormat::RGBA8888; break;
            default: return {};
        }
        return {qoiImage.get(), qoiImage.get() + ImageFormatDetails::getDataLength(format, width, height)};
    }
 
    // 16-bit single-frame image
    if (stbi_is_16_bit_from_memory(reinterpret_cast<const stbi_uc*>(fileData.data()), static_cast<int>(fileData.size()))) {
        const ::stb_ptr<stbi_us> stbImage{
            stbi_load_16_from_memory(reinterpret_cast<const stbi_uc*>(fileData.data()), static_cast<int>(fileData.size()), &width, &height, &channels, 0),
            &stbi_image_free,
        };
        if (!stbImage) {
            return {};
        }
        if (channels == 4) {
            format = ImageFormat::RGBA16161616;
        } else if (channels >= 1 && channels < 4) {
            // There are no other 16-bit integer formats in Source, so we have to do a conversion here
            format = ImageFormat::RGBA16161616;
            std::vector<std::byte> out(ImageFormatDetails::getDataLength(format, width, height));
            std::span<ImagePixel::RGBA16161616> outPixels{reinterpret_cast<ImagePixel::RGBA16161616*>(out.data()), out.size() / sizeof(ImagePixel::RGBA16161616)};
            switch (channels) {
                case 1: {
                    std::span<uint16_t> inPixels{reinterpret_cast<uint16_t*>(stbImage.get()), outPixels.size()};
                    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
                        std::execution::par_unseq,
#endif
                        inPixels.begin(), inPixels.end(), outPixels.begin(), [](uint16_t pixel) -> ImagePixel::RGBA16161616 {
                        return {pixel, 0, 0, 0xffff};
                    });
                    return out;
                }
                case 2: {
                    struct RG1616 {
                        uint16_t r;
                        uint16_t g;
                    };
                    std::span<RG1616> inPixels{reinterpret_cast<RG1616*>(stbImage.get()), outPixels.size()};
                    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
                        std::execution::par_unseq,
#endif
                        inPixels.begin(), inPixels.end(), outPixels.begin(), [](RG1616 pixel) -> ImagePixel::RGBA16161616 {
                        return {pixel.r, pixel.g, 0, 0xffff};
                    });
                    return out;
                }
                case 3: {
                    struct RGB161616 {
                        uint16_t r;
                        uint16_t g;
                        uint16_t b;
                    };
                    std::span<RGB161616> inPixels{reinterpret_cast<RGB161616*>(stbImage.get()), outPixels.size()};
                    std::transform(
#ifdef SOURCEPP_BUILD_WITH_TBB
                        std::execution::par_unseq,
#endif
                        inPixels.begin(), inPixels.end(), outPixels.begin(), [](RGB161616 pixel) -> ImagePixel::RGBA16161616 {
                        return {pixel.r, pixel.g, pixel.b, 0xffff};
                    });
                    return out;
                }
                default:
                    return {};
            }
        } else {
            return {};
        }
        return {reinterpret_cast<std::byte*>(stbImage.get()), reinterpret_cast<std::byte*>(stbImage.get()) + ImageFormatDetails::getDataLength(format, width, height)};
    }
 
    // 8-bit or less single frame image
    const ::stb_ptr<stbi_uc> stbImage{
        stbi_load_from_memory(reinterpret_cast<const stbi_uc*>(fileData.data()), static_cast<int>(fileData.size()), &width, &height, &channels, 0),
        &stbi_image_free,
    };
    if (!stbImage) {
        return {};
    }
    switch (channels) {
        case 1:  format = ImageFormat::I8;       break;
        case 2:  format = ImageFormat::UV88;     break;
        case 3:  format = ImageFormat::RGB888;   break;
        case 4:  format = ImageFormat::RGBA8888; break;
        default: return {};
    }
    return {reinterpret_cast<std::byte*>(stbImage.get()), reinterpret_cast<std::byte*>(stbImage.get()) + ImageFormatDetails::getDataLength(format, width, height)};
}
 
uint16_t ImageConversion::getResizedDim(uint16_t n, ResizeMethod method) {
    switch (method) {
        case ResizeMethod::NONE:                 break;
        case ResizeMethod::POWER_OF_TWO_BIGGER:  return std::bit_ceil(n);
        case ResizeMethod::POWER_OF_TWO_SMALLER: return std::bit_floor(n);
        case ResizeMethod::POWER_OF_TWO_NEAREST: return math::nearestPowerOf2(n);
    }
    return n;
}
 
void ImageConversion::setResizedDims(uint16_t& width, ResizeMethod widthResize, uint16_t& height, ResizeMethod heightResize) {
    width = getResizedDim(width, widthResize);
    height = getResizedDim(height, heightResize);
}
 
std::vector<std::byte> ImageConversion::resizeImageData(std::span<const std::byte> imageData, ImageFormat format, uint16_t width, uint16_t newWidth, uint16_t height, uint16_t newHeight, bool srgb, ResizeFilter filter, ResizeEdge edge) {
    if (imageData.empty() || format == ImageFormat::EMPTY) {
        return {};
    }
 
    STBIR_RESIZE resize;
    const auto setEdgeModesAndFiltersAndDoResize = [edge, filter, &resize] {
        stbir_set_edgemodes(&resize, static_cast<stbir_edge>(edge), static_cast<stbir_edge>(edge));
        switch (filter) {
            case ResizeFilter::DEFAULT:
            case ResizeFilter::BOX:
            case ResizeFilter::BILINEAR:
            case ResizeFilter::CUBIC_BSPLINE:
            case ResizeFilter::CATMULL_ROM:
            case ResizeFilter::MITCHELL:
            case ResizeFilter::POINT_SAMPLE: {
                stbir_set_filters(&resize, static_cast<stbir_filter>(filter), static_cast<stbir_filter>(filter));
                break;
            }
            case ResizeFilter::KAISER: {
                static constexpr auto KAISER_BETA = [](float s) {
                    if (s >= 1.f) {
                        return 5.f;
                    }
                    if (s >= 0.5f) {
                        return 6.5f;
                    }
                    return 8.f;
                };
                static constexpr auto KAISER_FILTER = [](float x, float s, void*) -> float {
                    if (x < -1.f || x > 1.f) {
                        return 0.f;
                    }
                    return static_cast<float>(math::kaiserWindow(x * s, KAISER_BETA(s)));
                };
                static constexpr auto KAISER_SUPPORT = [](float s, void*) -> float {
                    float baseSupport = KAISER_BETA(s) / 2.f;
                    if (s > 1.f) {
                        return std::max(2.f, baseSupport - 0.5f);
                    }
                    return std::max(3.f, baseSupport);
                };
                stbir_set_filter_callbacks(&resize, KAISER_FILTER, KAISER_SUPPORT, KAISER_FILTER, KAISER_SUPPORT);
                break;
            }
            case ResizeFilter::NICE: {
                static constexpr auto SINC = [](float x) -> float {
                    if (x == 0.f) return 1.f;
                    const float a = x * math::pi_f32;
                    return sinf(a) / a;
                };
                static constexpr auto NICE_FILTER = [](float x, float, void*) -> float {
                    if (x >= 3.f || x <= -3.f) return 0.f;
                    return SINC(x) * SINC(x / 3.f);
                };
                // Normally you would max(1, invScale), but stb is weird and immediately un-scales the result when downsampling.
                // See stb_image_resize2.h L2977 (stbir__get_filter_pixel_width)
                static constexpr auto NICE_SUPPORT = [](float invScale, void*) -> float {
                    return invScale * 3.f;
                };
                stbir_set_filter_callbacks(&resize, NICE_FILTER, NICE_SUPPORT, NICE_FILTER, NICE_SUPPORT);
                break;
            }
        }
        stbir_resize_extended(&resize);
    };
 
    const auto pixelLayout = ::imageFormatToSTBIRPixelLayout(format);
    if (pixelLayout == -1) {
        const auto containerFormat = ImageFormatDetails::containerFormat(format);
        const auto in = convertImageDataToFormat(imageData, format, containerFormat, width, height);
        std::vector<std::byte> intermediary(ImageFormatDetails::getDataLength(containerFormat, newWidth, newHeight));
        stbir_resize_init(&resize, in.data(), width, height, ImageFormatDetails::bpp(containerFormat) / 8 * width, intermediary.data(), newWidth, newHeight, ImageFormatDetails::bpp(containerFormat) / 8 * newWidth, static_cast<stbir_pixel_layout>(::imageFormatToSTBIRPixelLayout(containerFormat)), static_cast<stbir_datatype>(::imageFormatToSTBIRDataType(containerFormat, srgb)));
        setEdgeModesAndFiltersAndDoResize();
        return convertImageDataToFormat(intermediary, containerFormat, format, newWidth, newHeight);
    }
    std::vector<std::byte> out(ImageFormatDetails::getDataLength(format, newWidth, newHeight));
    stbir_resize_init(&resize, imageData.data(), width, height, ImageFormatDetails::bpp(format) / 8 * width, out.data(), newWidth, newHeight, ImageFormatDetails::bpp(format) / 8 * newWidth, static_cast<stbir_pixel_layout>(pixelLayout), static_cast<stbir_datatype>(::imageFormatToSTBIRDataType(format, srgb)));
    setEdgeModesAndFiltersAndDoResize();
    return out;
}
 
std::vector<std::byte> ImageConversion::resizeImageDataStrict(std::span<const std::byte> imageData, ImageFormat format, uint16_t width, uint16_t newWidth, uint16_t& widthOut, ResizeMethod widthResize, uint16_t height, uint16_t newHeight, uint16_t& heightOut, ResizeMethod heightResize, bool srgb, ResizeFilter filter, ResizeEdge edge) {
    if (imageData.empty() || format == ImageFormat::EMPTY) {
        return {};
    }
    widthOut = getResizedDim(newWidth, widthResize);
    heightOut = getResizedDim(newHeight, heightResize);
    return resizeImageData(imageData, format, width, widthOut, height, heightOut, srgb, filter, edge);
}
 
// NOLINTNEXTLINE(*-no-recursion)
std::vector<std::byte> ImageConversion::cropImageData(std::span<const std::byte> imageData, ImageFormat format, uint16_t width, uint16_t newWidth, uint16_t xOffset, uint16_t height, uint16_t newHeight, uint16_t yOffset) {
    if (imageData.empty() || format == ImageFormat::EMPTY || xOffset + newWidth >= width || yOffset + newHeight >= height) {
        return {};
    }
    if (ImageFormatDetails::compressed(format)) {
        // This is horrible but what can you do?
        const auto container = ImageFormatDetails::containerFormat(format);
        return convertImageDataToFormat(cropImageData(convertImageDataToFormat(imageData, format, container, width, height), container, width, newWidth, xOffset, height, newHeight, yOffset), container, format, newWidth, newHeight);
    }
 
    const auto pixelSize = ImageFormatDetails::bpp(format) / 8;
    std::vector<std::byte> out(pixelSize * newWidth * newHeight);
    for (uint16_t y = yOffset; y < yOffset + newHeight; y++) {
        std::memcpy(out.data() + (((y - yOffset) * newWidth) * pixelSize), imageData.data() + (((y * width) + xOffset) * pixelSize), newWidth * pixelSize);
    }
    return out;
}
 
// NOLINTNEXTLINE(*-no-recursion)
std::vector<std::byte> ImageConversion::gammaCorrectImageData(std::span<const std::byte> imageData, ImageFormat format, uint16_t width, uint16_t height, float gamma) {
    if (imageData.empty() || format == ImageFormat::EMPTY) {
        return {};
    }
    if (gamma == 1.f || ImageFormatDetails::large(format) || ImageFormatDetails::console(format) || format == ImageFormat::P8 || format == ImageFormat::A8 || format == ImageFormat::UV88 || format == ImageFormat::UVLX8888 || format == ImageFormat::UVWQ8888) {
        // No gamma correction for you! You are supposed to be linear! Or specialized...
        return {imageData.begin(), imageData.end()};
    }
    if (ImageFormatDetails::compressed(format)) {
        // This is horrible but what can you do?
        const auto container = ImageFormatDetails::containerFormat(format);
        return convertImageDataToFormat(gammaCorrectImageData(convertImageDataToFormat(imageData, format, container, width, height), container, width, height, gamma), container, format, width, height);
    }
 
    static constexpr auto calculateGammaLUT = [](float gamma_, uint8_t channelSize) -> std::array<uint8_t, 256> {
        const auto maxSize = static_cast<float>((1 << channelSize) - 1);
        std::array<uint8_t, 256> gammaLUT{};
        for (int i = 0; i < gammaLUT.size(); i++) {
            gammaLUT[i] = static_cast<uint8_t>(std::clamp(std::pow((static_cast<float>(i) + 0.5f) / maxSize, gamma_) * maxSize - 0.5f, 0.f, maxSize));
        }
        return gammaLUT;
    };
 
    #define VTFPP_CREATE_GAMMA_LUTS(InputType) \
        std::unordered_map<uint8_t, std::array<uint8_t, 256>> gammaLUTs; \
        if constexpr (ImageFormatDetails::red(ImageFormat::InputType) > 0) { \
            if (!gammaLUTs.contains(ImageFormatDetails::red(ImageFormat::InputType))) { \
                gammaLUTs[ImageFormatDetails::red(ImageFormat::InputType)] = calculateGammaLUT(gamma, ImageFormatDetails::red(ImageFormat::InputType)); \
            } \
        } \
        if constexpr (ImageFormatDetails::green(ImageFormat::InputType) > 0) { \
            if (!gammaLUTs.contains(ImageFormatDetails::green(ImageFormat::InputType))) { \
                gammaLUTs[ImageFormatDetails::green(ImageFormat::InputType)] = calculateGammaLUT(gamma, ImageFormatDetails::green(ImageFormat::InputType)); \
            } \
        } \
        if constexpr (ImageFormatDetails::blue(ImageFormat::InputType) > 0) { \
            if (!gammaLUTs.contains(ImageFormatDetails::blue(ImageFormat::InputType))) { \
                gammaLUTs[ImageFormatDetails::blue(ImageFormat::InputType)] = calculateGammaLUT(gamma, ImageFormatDetails::blue(ImageFormat::InputType)); \
            } \
        }
 
    #define VTFPP_APPLY_GAMMA_RED(value) \
        static_cast<decltype(value)>(gammaLUTs.at(ImageFormatDetails::red(PIXEL_TYPE::FORMAT))[value])
 
    #define VTFPP_APPLY_GAMMA_GREEN(value) \
        static_cast<decltype(value)>(gammaLUTs.at(ImageFormatDetails::green(PIXEL_TYPE::FORMAT))[value])
 
    #define VTFPP_APPLY_GAMMA_BLUE(value) \
        static_cast<decltype(value)>(gammaLUTs.at(ImageFormatDetails::blue(PIXEL_TYPE::FORMAT))[value])
 
    std::vector<std::byte> out(imageData.size());
 
#ifdef SOURCEPP_BUILD_WITH_TBB
    #define VTFPP_GAMMA_CORRECT(InputType, ...) \
        std::span imageDataSpan{reinterpret_cast<const ImagePixel::InputType*>(imageData.data()), imageData.size() / sizeof(ImagePixel::InputType)}; \
        std::span outSpan{reinterpret_cast<ImagePixel::InputType*>(out.data()), out.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(std::execution::par_unseq, imageDataSpan.begin(), imageDataSpan.end(), outSpan.begin(), [gammaLUTs](ImagePixel::InputType pixel) -> ImagePixel::InputType { \
            using PIXEL_TYPE = ImagePixel::InputType; \
            return __VA_ARGS__; \
        })
#else
    #define VTFPP_GAMMA_CORRECT(InputType, ...) \
        std::span imageDataSpan{reinterpret_cast<const ImagePixel::InputType*>(imageData.data()), imageData.size() / sizeof(ImagePixel::InputType)}; \
        std::span outSpan{reinterpret_cast<ImagePixel::InputType*>(out.data()), out.size() / sizeof(ImagePixel::InputType)}; \
        std::transform(imageDataSpan.begin(), imageDataSpan.end(), outSpan.begin(), [gammaLUTs](ImagePixel::InputType pixel) -> ImagePixel::InputType { \
            using PIXEL_TYPE = ImagePixel::InputType; \
            return __VA_ARGS__; \
        })
#endif
    #define VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(InputType, ...) \
        case InputType: { VTFPP_CREATE_GAMMA_LUTS(InputType) VTFPP_GAMMA_CORRECT(InputType, __VA_ARGS__); } break
 
    switch (format) {
        using enum ImageFormat;
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(ABGR8888,          {pixel.a,                         VTFPP_APPLY_GAMMA_BLUE(pixel.b),  VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(RGB888,            {VTFPP_APPLY_GAMMA_RED(pixel.r),  VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_BLUE(pixel.b)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(RGB888_BLUESCREEN, pixel.r == 0 && pixel.g == 0 && pixel.b == 0xff ? ImagePixel::RGB888_BLUESCREEN{0, 0, 0xff} : ImagePixel::RGB888_BLUESCREEN{VTFPP_APPLY_GAMMA_RED(pixel.r), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_BLUE(pixel.b)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(BGR888,            {VTFPP_APPLY_GAMMA_BLUE(pixel.b), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(BGR888_BLUESCREEN, pixel.r == 0 && pixel.g == 0 && pixel.b == 0xff ? ImagePixel::BGR888_BLUESCREEN{0, 0, 0xff} : ImagePixel::BGR888_BLUESCREEN{VTFPP_APPLY_GAMMA_BLUE(pixel.b), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(RGB565,            {VTFPP_APPLY_GAMMA_RED(pixel.r),  VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_BLUE(pixel.b)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(I8,                {VTFPP_APPLY_GAMMA_RED(pixel.i)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(IA88,              {VTFPP_APPLY_GAMMA_RED(pixel.i),  pixel.a});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(ARGB8888,          {pixel.a,                         VTFPP_APPLY_GAMMA_RED(pixel.r),   VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_BLUE(pixel.b)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(BGRA8888,          {VTFPP_APPLY_GAMMA_BLUE(pixel.b), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r),   pixel.a});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(BGRX8888,          {VTFPP_APPLY_GAMMA_BLUE(pixel.b), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r),   0xff});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(BGR565,            {VTFPP_APPLY_GAMMA_BLUE(pixel.b), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r)});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(BGRA5551,          {VTFPP_APPLY_GAMMA_BLUE(pixel.b), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r),   pixel.a});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(BGRX5551,          {VTFPP_APPLY_GAMMA_BLUE(pixel.b), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r),   1});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(BGRA4444,          {VTFPP_APPLY_GAMMA_BLUE(pixel.b), VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_RED(pixel.r),   pixel.a});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(RGBX8888,          {VTFPP_APPLY_GAMMA_RED(pixel.r),  VTFPP_APPLY_GAMMA_GREEN(pixel.g), VTFPP_APPLY_GAMMA_BLUE(pixel.b),  0xff});
        VTFPP_CASE_GAMMA_CORRECT_AND_BREAK(R8,                {VTFPP_APPLY_GAMMA_RED(pixel.r)});
        default: SOURCEPP_DEBUG_BREAK; break;
    }
 
    #undef VTFPP_CASE_GAMMA_CORRECT_AND_BREAK
    #undef VTFPP_GAMMA_CORRECT
    #undef VTFPP_APPLY_GAMMA_BLUE
    #undef VTFPP_APPLY_GAMMA_GREEN
    #undef VTFPP_APPLY_GAMMA_RED
    #undef VTFPP_CREATE_GAMMA_LUTS
 
    return out;
}
 
// NOLINTNEXTLINE(*-no-recursion)
std::vector<std::byte> ImageConversion::invertGreenChannelForImageData(std::span<const std::byte> imageData, ImageFormat format, uint16_t width, uint16_t height) {
    if (imageData.empty() || format == ImageFormat::EMPTY || ImageFormatDetails::decompressedGreen(format) == 0) {
        return {};
    }
    if (ImageFormatDetails::compressed(format)) {
        // This is horrible but what can you do?
        const auto container = ImageFormatDetails::containerFormat(format);
        return convertImageDataToFormat(invertGreenChannelForImageData(convertImageDataToFormat(imageData, format, container, width, height), container, width, height), container, format, width, height);
    }
 
    #define VTFPP_INVERT_GREEN(PixelType, ChannelName, ...) \
        static constexpr auto channelSize = ImageFormatDetails::green(ImagePixel::PixelType::FORMAT); \
        std::span imageDataSpan{reinterpret_cast<const ImagePixel::PixelType*>(imageData.data()), imageData.size() / sizeof(ImagePixel::PixelType)}; \
        std::span outSpan{reinterpret_cast<ImagePixel::PixelType*>(out.data()), out.size() / sizeof(ImagePixel::PixelType)}; \
        std::transform(__VA_ARGS__ __VA_OPT__(,) imageDataSpan.begin(), imageDataSpan.end(), outSpan.begin(), [](ImagePixel::PixelType pixel) -> ImagePixel::PixelType { \
            if constexpr (std::same_as<decltype(pixel.ChannelName), float> || std::same_as<decltype(pixel.ChannelName), half>) { \
                pixel.ChannelName = static_cast<decltype(pixel.ChannelName)>(static_cast<float>(static_cast<uint64_t>(1) << channelSize) - 1.f - static_cast<float>(pixel.ChannelName)); \
            } else { \
                if constexpr (channelSize >= sizeof(uint32_t) * 8) { \
                    pixel.ChannelName = static_cast<decltype(pixel.ChannelName)>((static_cast<uint64_t>(1) << channelSize) - 1 - static_cast<uint32_t>(pixel.ChannelName)); \
                } else { \
                    pixel.ChannelName = static_cast<decltype(pixel.ChannelName)>(static_cast<uint32_t>(1 << channelSize) - 1 - static_cast<uint32_t>(pixel.ChannelName)); \
                } \
            } \
            return pixel; \
        })
#ifdef SOURCEPP_BUILD_WITH_TBB
    #define VTFPP_INVERT_GREEN_CASE(PixelType) \
        case ImageFormat::PixelType: { VTFPP_INVERT_GREEN(PixelType, g, std::execution::par_unseq); break; }
    #define VTFPP_INVERT_GREEN_CASE_CA_OVERRIDE(PixelType, ChannelName) \
        case ImageFormat::PixelType: { VTFPP_INVERT_GREEN(PixelType, ChannelName, std::execution::par_unseq); break; }
#else
    #define VTFPP_INVERT_GREEN_CASE(PixelType) \
        case ImageFormat::PixelType: { VTFPP_INVERT_GREEN(PixelType, g); } break
    #define VTFPP_INVERT_GREEN_CASE_CA_OVERRIDE(PixelType, ChannelName) \
        case ImageFormat::PixelType: { VTFPP_INVERT_GREEN(PixelType, ChannelName); } break
#endif
 
    std::vector<std::byte> out(imageData.size());
    switch (format) {
        VTFPP_INVERT_GREEN_CASE(RGBA8888);
        VTFPP_INVERT_GREEN_CASE(ABGR8888);
        VTFPP_INVERT_GREEN_CASE(RGB888);
        VTFPP_INVERT_GREEN_CASE(BGR888);
        VTFPP_INVERT_GREEN_CASE(RGB565);
        VTFPP_INVERT_GREEN_CASE(RGB888_BLUESCREEN);
        VTFPP_INVERT_GREEN_CASE(BGR888_BLUESCREEN);
        VTFPP_INVERT_GREEN_CASE(ARGB8888);
        VTFPP_INVERT_GREEN_CASE(BGRA8888);
        VTFPP_INVERT_GREEN_CASE(BGRX8888);
        VTFPP_INVERT_GREEN_CASE(BGR565);
        VTFPP_INVERT_GREEN_CASE(BGRX5551);
        VTFPP_INVERT_GREEN_CASE(BGRA4444);
        VTFPP_INVERT_GREEN_CASE(BGRA5551);
        VTFPP_INVERT_GREEN_CASE_CA_OVERRIDE(UV88, v);
        VTFPP_INVERT_GREEN_CASE_CA_OVERRIDE(UVWQ8888, v);
        VTFPP_INVERT_GREEN_CASE(RGBA16161616F);
        VTFPP_INVERT_GREEN_CASE(RGBA16161616);
        VTFPP_INVERT_GREEN_CASE_CA_OVERRIDE(UVLX8888, v);
        VTFPP_INVERT_GREEN_CASE(RGB323232F);
        VTFPP_INVERT_GREEN_CASE(RGBA32323232F);
        VTFPP_INVERT_GREEN_CASE(RG1616F);
        VTFPP_INVERT_GREEN_CASE(RG3232F);
        VTFPP_INVERT_GREEN_CASE(RGBX8888);
        VTFPP_INVERT_GREEN_CASE(RGBA1010102);
        VTFPP_INVERT_GREEN_CASE(BGRA1010102);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_BGRX8888_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_RGBA8888_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_ABGR8888_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_ARGB8888_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_BGRA8888_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_RGB888_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_BGR888_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_BGRX5551_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_RGBA16161616_LINEAR);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_BGRX8888_LE);
        VTFPP_INVERT_GREEN_CASE(CONSOLE_BGRA8888_LE);
        default: SOURCEPP_DEBUG_BREAK; break;
    }
 
    #undef VTFPP_INVERT_GREEN_CASE_CA_OVERRIDE
    #undef VTFPP_INVERT_GREEN_CASE
    #undef VTFPP_INVERT_GREEN
 
    return out;
}