blob: cfd7e295ba33f5149ab45343a04e0daea624941f [file] [log] [blame]
// Copyright 2019 Joe Drago. All rights reserved.
// SPDX-License-Identifier: BSD-2-Clause
#include "avif/internal.h"
#if !defined(AVIF_LIBYUV_ENABLED)
// No libyuv!
avifResult avifImageRGBToYUVLibYUV(avifImage * image, const avifRGBImage * rgb)
{
(void)image;
(void)rgb;
return AVIF_RESULT_NOT_IMPLEMENTED;
}
avifResult avifImageYUVToRGBLibYUV(const avifImage * image, avifRGBImage * rgb, avifBool reformatAlpha, avifBool * alphaReformattedWithLibYUV)
{
(void)image;
(void)rgb;
(void)reformatAlpha;
*alphaReformattedWithLibYUV = AVIF_FALSE;
return AVIF_RESULT_NOT_IMPLEMENTED;
}
avifResult avifRGBImagePremultiplyAlphaLibYUV(avifRGBImage * rgb)
{
(void)rgb;
return AVIF_RESULT_NOT_IMPLEMENTED;
}
avifResult avifRGBImageUnpremultiplyAlphaLibYUV(avifRGBImage * rgb)
{
(void)rgb;
return AVIF_RESULT_NOT_IMPLEMENTED;
}
avifResult avifRGBImageToF16LibYUV(avifRGBImage * rgb)
{
(void)rgb;
return AVIF_RESULT_NOT_IMPLEMENTED;
}
unsigned int avifLibYUVVersion(void)
{
return 0;
}
#else
#include <assert.h>
#include <limits.h>
#include <string.h>
#if defined(__clang__)
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wstrict-prototypes" // "this function declaration is not a prototype"
// The newline at the end of libyuv/version.h was accidentally deleted in version 1792 and restored
// in version 1813:
// https://chromium-review.googlesource.com/c/libyuv/libyuv/+/3183182
// https://chromium-review.googlesource.com/c/libyuv/libyuv/+/3527834
#pragma clang diagnostic ignored "-Wnewline-eof" // "no newline at end of file"
#endif
#include <libyuv.h>
#if defined(__clang__)
#pragma clang diagnostic pop
#endif
// libyuv is a C++ library and defines custom types (struct, enum, etc) in the libyuv namespace when the libyuv header files are
// included by C++ code. When accessed from a C library like libavif, via a function pointer, this leads to signature mismatches
// in the CFI sanitizers since libyuv itself, compiled as C++ code, has the types within the namespace and the C code has the
// types without the namespace. The same thing happens with clang's undefined behavior sanitizer as well when invoked with
// -fsanitize=function. So we suppress both of these sanitizers in functions that call libyuv functions via a pointer.
// For a simpler example of this bug, please see: https://github.com/vigneshvg/cpp_c_potential_cfi_bug.
// For more details on clang's CFI see: https://clang.llvm.org/docs/ControlFlowIntegrity.html.
// For more details on clang's UBSan see: https://clang.llvm.org/docs/UndefinedBehaviorSanitizer.html
#if defined(__clang__)
#define IGNORE_CFI_ICALL __attribute__((no_sanitize("cfi-icall", "function")))
#else
#define IGNORE_CFI_ICALL
#endif
//--------------------------------------------------------------------------------------------------
// libyuv API availability management
// These defines are used to create a NULL reference to libyuv functions that
// did not exist prior to a particular version of libyuv.
// Versions prior to 1755 are considered too old and not used (see CMakeLists.txt).
#if LIBYUV_VERSION < 1844
// I444ToRGB24Matrix() and I422ToRGB24MatrixFilter() were added in libyuv version 1844.
//
// Note: Between the following two commits, libyuv version jumped from 1841 to 1844, down to 1843,
// and back to 1844. See https://chromium-review.googlesource.com/c/libyuv/libyuv/+/3906082 and
// https://chromium-review.googlesource.com/c/libyuv/libyuv/+/3906091.
#define I444ToRGB24Matrix NULL
#define I422ToRGB24MatrixFilter NULL
#endif
#if LIBYUV_VERSION < 1841
// I420ToRGB24MatrixFilter() was added in libyuv version 1841.
// See https://chromium-review.googlesource.com/c/libyuv/libyuv/+/3900298.
#define I420ToRGB24MatrixFilter NULL
#endif
#if LIBYUV_VERSION < 1840
#define ABGRToJ400 NULL
#endif
#if LIBYUV_VERSION < 1838
#define I422ToRGB565Matrix NULL
#endif
#if LIBYUV_VERSION < 1813
#define I422ToARGBMatrixFilter NULL
#define I420ToARGBMatrixFilter NULL
#define I210ToARGBMatrixFilter NULL
#define I010ToARGBMatrixFilter NULL
#define I420AlphaToARGBMatrixFilter NULL
#define I422AlphaToARGBMatrixFilter NULL
#define I010AlphaToARGBMatrixFilter NULL
#define I210AlphaToARGBMatrixFilter NULL
#endif
#if LIBYUV_VERSION < 1782
#define RAWToJ420 NULL
#endif
#if LIBYUV_VERSION < 1781
#define I012ToARGBMatrix NULL
#endif
#if LIBYUV_VERSION < 1780
#define I410ToARGBMatrix NULL
#define I410AlphaToARGBMatrix NULL
#define I210AlphaToARGBMatrix NULL
#define I010AlphaToARGBMatrix NULL
#endif
#if LIBYUV_VERSION < 1771
#define I422AlphaToARGBMatrix NULL
#define I444AlphaToARGBMatrix NULL
#endif
#if LIBYUV_VERSION < 1756
#define I400ToARGBMatrix NULL
#endif
// Two-step replacement for the conversions to 8-bit BT.601 YUV which are missing from libyuv.
static int avifReorderARGBThenConvertToYUV(int (*ReorderARGB)(const uint8_t *, int, uint8_t *, int, int, int),
int (*ConvertToYUV)(const uint8_t *, int, uint8_t *, int, uint8_t *, int, uint8_t *, int, int, int),
const uint8_t * src_abgr,
int src_stride_abgr,
uint8_t * dst_y,
int dst_stride_y,
uint8_t * dst_u,
int dst_stride_u,
uint8_t * dst_v,
int dst_stride_v,
avifPixelFormat dst_format,
int width,
int height)
{
// Only the vertically subsampled formats need to be processed by luma row pairs.
avifPixelFormatInfo format_info;
avifGetPixelFormatInfo(dst_format, &format_info);
const int min_num_rows = (format_info.chromaShiftY == 1) ? 2 : 1;
// A temporary buffer is needed to call ReorderARGB().
uint8_t * src_argb;
const int src_stride_argb = width * 4;
const int soft_allocation_limit = 16384; // Arbitrarily chosen trade-off between CPU and memory footprints.
int num_allocated_rows;
if ((height == 1) || ((int64_t)src_stride_argb * height <= soft_allocation_limit)) {
// Process the whole buffer in one go.
num_allocated_rows = height;
} else {
if ((int64_t)src_stride_argb * min_num_rows > INT_MAX) {
return -1;
}
// The last row of an odd number of RGB rows to be converted to vertically subsampled YUV is treated
// differently by libyuv, so make sure all steps but the last one process a multiple of min_num_rows rows.
// Try to process the highest multiple of min_num_rows rows possible in a single step without
// allocating more than soft_allocation_limit, unless min_num_rows rows need more than that.
num_allocated_rows = AVIF_MAX(1, soft_allocation_limit / (src_stride_argb * min_num_rows)) * min_num_rows;
}
src_argb = (uint8_t *)avifAlloc(num_allocated_rows * src_stride_argb);
if (!src_argb) {
return -1;
}
for (int y = 0; y < height; y += num_allocated_rows) {
const int num_rows = AVIF_MIN(num_allocated_rows, height - y);
if (ReorderARGB(src_abgr, src_stride_abgr, src_argb, src_stride_argb, width, num_rows) ||
ConvertToYUV(src_argb, src_stride_argb, dst_y, dst_stride_y, dst_u, dst_stride_u, dst_v, dst_stride_v, width, num_rows)) {
avifFree(src_argb);
return -1;
}
src_abgr += (size_t)num_rows * src_stride_abgr;
dst_y += (size_t)num_rows * dst_stride_y;
// Either chroma is not vertically subsampled, num_rows is even, or this is the last iteration.
dst_u += (size_t)(num_rows >> format_info.chromaShiftY) * dst_stride_u;
dst_v += (size_t)(num_rows >> format_info.chromaShiftY) * dst_stride_v;
}
avifFree(src_argb);
return 0;
}
#define AVIF_DEFINE_CONVERSION(NAME, REORDER_ARGB, CONVERT_TO_YUV, YUV_FORMAT) \
static int NAME(const uint8_t * src_abgr, \
int src_stride_abgr, \
uint8_t * dst_y, \
int dst_stride_y, \
uint8_t * dst_u, \
int dst_stride_u, \
uint8_t * dst_v, \
int dst_stride_v, \
int width, \
int height) \
{ \
return avifReorderARGBThenConvertToYUV(REORDER_ARGB, \
CONVERT_TO_YUV, \
src_abgr, \
src_stride_abgr, \
dst_y, \
dst_stride_y, \
dst_u, \
dst_stride_u, \
dst_v, \
dst_stride_v, \
YUV_FORMAT, \
width, \
height); \
}
#if LIBYUV_VERSION < 1840
// AVIF_RGB_FORMAT_RGBA
AVIF_DEFINE_CONVERSION(ABGRToJ422, ABGRToARGB, ARGBToJ422, AVIF_PIXEL_FORMAT_YUV422)
AVIF_DEFINE_CONVERSION(ABGRToJ420, ABGRToARGB, ARGBToJ420, AVIF_PIXEL_FORMAT_YUV420)
#endif
// These are not yet implemented in libyuv so they cannot be guarded by a version check.
// The "avif" prefix avoids any redefinition if they are available in libyuv one day.
// AVIF_RGB_FORMAT_RGB
AVIF_DEFINE_CONVERSION(avifRAWToI444, RAWToARGB, ARGBToI444, AVIF_PIXEL_FORMAT_YUV444)
AVIF_DEFINE_CONVERSION(avifRAWToI422, RAWToARGB, ARGBToI422, AVIF_PIXEL_FORMAT_YUV422)
AVIF_DEFINE_CONVERSION(avifRAWToJ422, RAWToARGB, ARGBToJ422, AVIF_PIXEL_FORMAT_YUV422)
// AVIF_RGB_FORMAT_RGBA
AVIF_DEFINE_CONVERSION(avifABGRToI444, ABGRToARGB, ARGBToI444, AVIF_PIXEL_FORMAT_YUV444)
AVIF_DEFINE_CONVERSION(avifABGRToI422, ABGRToARGB, ARGBToI422, AVIF_PIXEL_FORMAT_YUV422)
// AVIF_RGB_FORMAT_ARGB
AVIF_DEFINE_CONVERSION(avifBGRAToI444, BGRAToARGB, ARGBToI444, AVIF_PIXEL_FORMAT_YUV444)
AVIF_DEFINE_CONVERSION(avifBGRAToI422, BGRAToARGB, ARGBToI422, AVIF_PIXEL_FORMAT_YUV422)
AVIF_DEFINE_CONVERSION(avifBGRAToJ422, BGRAToARGB, ARGBToJ422, AVIF_PIXEL_FORMAT_YUV422)
AVIF_DEFINE_CONVERSION(avifBGRAToJ420, BGRAToARGB, ARGBToJ420, AVIF_PIXEL_FORMAT_YUV420)
// AVIF_RGB_FORMAT_BGR
AVIF_DEFINE_CONVERSION(avifRGB24ToI444, RGB24ToARGB, ARGBToI444, AVIF_PIXEL_FORMAT_YUV444)
AVIF_DEFINE_CONVERSION(avifRGB24ToI422, RGB24ToARGB, ARGBToI422, AVIF_PIXEL_FORMAT_YUV422)
AVIF_DEFINE_CONVERSION(avifRGB24ToJ422, RGB24ToARGB, ARGBToJ422, AVIF_PIXEL_FORMAT_YUV422)
// AVIF_RGB_FORMAT_ABGR
AVIF_DEFINE_CONVERSION(avifRGBAToI444, RGBAToARGB, ARGBToI444, AVIF_PIXEL_FORMAT_YUV444)
AVIF_DEFINE_CONVERSION(avifRGBAToI422, RGBAToARGB, ARGBToI422, AVIF_PIXEL_FORMAT_YUV422)
AVIF_DEFINE_CONVERSION(avifRGBAToJ422, RGBAToARGB, ARGBToJ422, AVIF_PIXEL_FORMAT_YUV422)
AVIF_DEFINE_CONVERSION(avifRGBAToJ420, RGBAToARGB, ARGBToJ420, AVIF_PIXEL_FORMAT_YUV420)
//--------------------------------------------------------------------------------------------------
// RGB to YUV
static avifResult avifImageRGBToYUVLibYUV8bpc(avifImage * image, const avifRGBImage * rgb);
avifResult avifImageRGBToYUVLibYUV(avifImage * image, const avifRGBImage * rgb)
{
// The width, height, and stride parameters of libyuv functions are all of the int type.
if (image->width > INT_MAX || image->height > INT_MAX || image->yuvRowBytes[AVIF_CHAN_Y] > INT_MAX || rgb->rowBytes > INT_MAX) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
if ((image->depth == 8) && (rgb->depth == 8)) {
return avifImageRGBToYUVLibYUV8bpc(image, rgb);
}
// This function didn't do anything; use the built-in conversion.
return AVIF_RESULT_NOT_IMPLEMENTED;
}
avifResult avifImageRGBToYUVLibYUV8bpc(avifImage * image, const avifRGBImage * rgb)
{
assert((image->depth == 8) && (rgb->depth == 8));
// libavif uses byte-order when describing pixel formats, such that the R in RGBA is the lowest address,
// similar to PNG. libyuv orders in word-order, so libavif's RGBA would be referred to in libyuv as ABGR.
// libyuv only handles BT.601 for RGB to YUV, and not all range/order/subsampling combinations.
// BT.470BG has the same coefficients as BT.601.
if ((image->matrixCoefficients == AVIF_MATRIX_COEFFICIENTS_BT470BG) || (image->matrixCoefficients == AVIF_MATRIX_COEFFICIENTS_BT601)) {
if (image->yuvFormat == AVIF_PIXEL_FORMAT_YUV400) {
// Lookup table for RGB To Y (monochrome).
typedef int (*RGBtoY)(const uint8_t *, int, uint8_t *, int, int, int);
// First dimension is for avifRange.
RGBtoY lutRgbToY[2][AVIF_RGB_FORMAT_COUNT] = { // AVIF_RANGE_LIMITED
{
// // AVIF_RGB_FORMAT_
NULL, // RGB
NULL, // RGBA
NULL, // ARGB
NULL, // BGR
ARGBToI400, // BGRA
NULL, // ABGR
NULL, // RGB_565
},
// AVIF_RANGE_FULL
{
// // AVIF_RGB_FORMAT_
RAWToJ400, // RGB
ABGRToJ400, // RGBA
NULL, // ARGB
RGB24ToJ400, // BGR
ARGBToJ400, // BGRA
RGBAToJ400, // ABGR
NULL // RGB_565
}
};
RGBtoY rgbToY = lutRgbToY[image->yuvRange][rgb->format];
if (rgbToY != NULL) {
if (rgbToY(rgb->pixels,
rgb->rowBytes,
image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y],
image->width,
image->height) != 0) {
return AVIF_RESULT_REFORMAT_FAILED;
}
return AVIF_RESULT_OK;
}
} else {
// Lookup table for RGB To YUV Matrix (average filter).
typedef int (*RGBtoYUV)(const uint8_t *, int, uint8_t *, int, uint8_t *, int, uint8_t *, int, int, int);
// First dimension is for avifRange.
RGBtoYUV lutRgbToYuv[2][AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// AVIF_RANGE_LIMITED
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, avifRAWToI444, avifRAWToI422, RAWToI420, NULL }, // RGB
{ NULL, avifABGRToI444, avifABGRToI422, ABGRToI420, NULL }, // RGBA
{ NULL, avifBGRAToI444, avifBGRAToI422, BGRAToI420, NULL }, // ARGB
{ NULL, avifRGB24ToI444, avifRGB24ToI422, RGB24ToI420, NULL }, // BGR
{ NULL, ARGBToI444, ARGBToI422, ARGBToI420, NULL }, // BGRA
{ NULL, avifRGBAToI444, avifRGBAToI422, RGBAToI420, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL } // RGB_565
},
// AVIF_RANGE_FULL
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, avifRAWToJ422, RAWToJ420, NULL }, // RGB
{ NULL, NULL, ABGRToJ422, ABGRToJ420, NULL }, // RGBA
{ NULL, NULL, avifBGRAToJ422, avifBGRAToJ420, NULL }, // ARGB
{ NULL, NULL, avifRGB24ToJ422, RGB24ToJ420, NULL }, // BGR
{ NULL, NULL, ARGBToJ422, ARGBToJ420, NULL }, // BGRA
{ NULL, NULL, avifRGBAToJ422, avifRGBAToJ420, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL } // RGB_565
}
};
RGBtoYUV rgbToYuv = lutRgbToYuv[image->yuvRange][rgb->format][image->yuvFormat];
if (rgbToYuv != NULL) {
if (rgbToYuv(rgb->pixels,
rgb->rowBytes,
image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y],
image->yuvPlanes[AVIF_CHAN_U],
image->yuvRowBytes[AVIF_CHAN_U],
image->yuvPlanes[AVIF_CHAN_V],
image->yuvRowBytes[AVIF_CHAN_V],
image->width,
image->height) != 0) {
return AVIF_RESULT_REFORMAT_FAILED;
}
return AVIF_RESULT_OK;
}
}
}
// TODO: Use SplitRGBPlane() for AVIF_MATRIX_COEFFICIENTS_IDENTITY if faster than the built-in implementation
return AVIF_RESULT_NOT_IMPLEMENTED;
}
//--------------------------------------------------------------------------------------------------
// YUV to RGB
// Note about the libyuv look up tables used for YUV-to-RGB conversion:
// libavif uses byte-order when describing pixel formats, such that the R in RGBA is the lowest address, similar to PNG. libyuv
// orders in word-order, so libavif's RGBA would be referred to in libyuv as ABGR. In addition, swapping U and V in any of the
// calls, along with using the Yvu matrix instead of Yuv matrix, swaps B and R in these orderings as well.
//
// libavif format libyuv Func UV matrix (and UV argument ordering)
// -------------------- ------------- ------------------------------------
// For 8-bit YUV:
// AVIF_RGB_FORMAT_RGB *ToRGB24Matrix matrixYVU
// AVIF_RGB_FORMAT_RGBA *ToARGBMatrix matrixYVU
// AVIF_RGB_FORMAT_ARGB *ToRGBAMatrix matrixYVU
// AVIF_RGB_FORMAT_BGR *ToRGB24Matrix matrixYUV
// AVIF_RGB_FORMAT_BGRA *ToARGBMatrix matrixYUV
// AVIF_RGB_FORMAT_ABGR *ToRGBAMatrix matrixYUV
// AVIF_RGB_FORMAT_RGB_565 *ToRGB565Matrix matrixYUV
//
// For 10-bit and 12-bit YUV:
// AVIF_RGB_FORMAT_RGB n/a n/a
// AVIF_RGB_FORMAT_RGBA *ToARGBMatrix matrixYVU
// AVIF_RGB_FORMAT_ARGB n/a n/a
// AVIF_RGB_FORMAT_BGR n/a n/a
// AVIF_RGB_FORMAT_BGRA *ToARGBMatrix matrixYUV
// AVIF_RGB_FORMAT_ABGR n/a n/a
// AVIF_RGB_FORMAT_RGB_565 n/a n/a
// Lookup table for isYVU. If the entry in this table is AVIF_TRUE, then it
// means that we are using a libyuv function with R and B channels swapped,
// which requires U and V planes also be swapped.
static const avifBool lutIsYVU[AVIF_RGB_FORMAT_COUNT] = {
// // AVIF_RGB_FORMAT_
AVIF_TRUE, // RGB
AVIF_TRUE, // RGBA
AVIF_TRUE, // ARGB
AVIF_FALSE, // BGR
AVIF_FALSE, // BGRA
AVIF_FALSE, // ABGR
AVIF_FALSE, // RGB_565
};
typedef int (*YUV400ToRGBMatrix)(const uint8_t *, int, uint8_t *, int, const struct YuvConstants *, int, int);
typedef int (*YUVToRGBMatrixFilter)(const uint8_t *,
int,
const uint8_t *,
int,
const uint8_t *,
int,
uint8_t *,
int,
const struct YuvConstants *,
int,
int,
enum FilterMode);
typedef int (*YUVAToRGBMatrixFilter)(const uint8_t *,
int,
const uint8_t *,
int,
const uint8_t *,
int,
const uint8_t *,
int,
uint8_t *,
int,
const struct YuvConstants *,
int,
int,
int,
enum FilterMode);
typedef int (*YUVToRGBMatrix)(const uint8_t *, int, const uint8_t *, int, const uint8_t *, int, uint8_t *, int, const struct YuvConstants *, int, int);
typedef int (*YUVAToRGBMatrix)(const uint8_t *,
int,
const uint8_t *,
int,
const uint8_t *,
int,
const uint8_t *,
int,
uint8_t *,
int,
const struct YuvConstants *,
int,
int,
int);
typedef int (*YUVToRGBMatrixFilterHighBitDepth)(const uint16_t *,
int,
const uint16_t *,
int,
const uint16_t *,
int,
uint8_t *,
int,
const struct YuvConstants *,
int,
int,
enum FilterMode);
typedef int (*YUVAToRGBMatrixFilterHighBitDepth)(const uint16_t *,
int,
const uint16_t *,
int,
const uint16_t *,
int,
const uint16_t *,
int,
uint8_t *,
int,
const struct YuvConstants *,
int,
int,
int,
enum FilterMode);
typedef int (*YUVToRGBMatrixHighBitDepth)(const uint16_t *,
int,
const uint16_t *,
int,
const uint16_t *,
int,
uint8_t *,
int,
const struct YuvConstants *,
int,
int);
typedef int (*YUVAToRGBMatrixHighBitDepth)(const uint16_t *,
int,
const uint16_t *,
int,
const uint16_t *,
int,
const uint16_t *,
int,
uint8_t *,
int,
const struct YuvConstants *,
int,
int,
int);
// At most one pointer in this struct will be not-NULL.
typedef struct
{
YUV400ToRGBMatrix yuv400ToRgbMatrix;
YUVToRGBMatrixFilter yuvToRgbMatrixFilter;
YUVAToRGBMatrixFilter yuvaToRgbMatrixFilter;
YUVToRGBMatrix yuvToRgbMatrix;
YUVAToRGBMatrix yuvaToRgbMatrix;
YUVToRGBMatrixFilterHighBitDepth yuvToRgbMatrixFilterHighBitDepth;
YUVAToRGBMatrixFilterHighBitDepth yuvaToRgbMatrixFilterHighBitDepth;
YUVToRGBMatrixHighBitDepth yuvToRgbMatrixHighBitDepth;
YUVAToRGBMatrixHighBitDepth yuvaToRgbMatrixHighBitDepth;
} LibyuvConversionFunction;
// Only allow nearest-neighbor filter if explicitly specified or left as default.
static avifBool nearestNeighborFilterAllowed(int chromaUpsampling)
{
return chromaUpsampling != AVIF_CHROMA_UPSAMPLING_BILINEAR && chromaUpsampling != AVIF_CHROMA_UPSAMPLING_BEST_QUALITY;
}
// Returns AVIF_TRUE if the given yuvFormat and yuvDepth can be converted to 8-bit RGB using libyuv, AVIF_FALSE otherwise. When
// AVIF_TRUE is returned, exactly one function pointers will be populated with the appropriate conversion function. If
// alphaPreferred is set to AVIF_TRUE, then a function that can also copy the alpha channel will be preferred if available.
static avifBool getLibYUVConversionFunction(avifPixelFormat yuvFormat,
int yuvDepth,
avifRGBImage * rgb,
avifBool alphaPreferred,
LibyuvConversionFunction * lcf)
{
// Lookup table for 8-bit YUV400 to 8-bit RGB Matrix.
static const YUV400ToRGBMatrix lutYuv400ToRgbMatrix[AVIF_RGB_FORMAT_COUNT] = {
// // AVIF_RGB_FORMAT_
NULL, // RGB
I400ToARGBMatrix, // RGBA
NULL, // ARGB
NULL, // BGR
I400ToARGBMatrix, // BGRA
NULL, // ABGR
NULL, // RGB_565
};
// Lookup table for 8-bit YUV To 8-bit RGB Matrix (with filter).
static const YUVToRGBMatrixFilter lutYuvToRgbMatrixFilter[AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, I422ToRGB24MatrixFilter, I420ToRGB24MatrixFilter, NULL }, // RGB
{ NULL, NULL, I422ToARGBMatrixFilter, I420ToARGBMatrixFilter, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, I422ToRGB24MatrixFilter, I420ToRGB24MatrixFilter, NULL }, // BGR
{ NULL, NULL, I422ToARGBMatrixFilter, I420ToARGBMatrixFilter, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
};
// Lookup table for 8-bit YUVA To 8-bit RGB Matrix (with filter).
static const YUVAToRGBMatrixFilter lutYuvaToRgbMatrixFilter[AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, NULL, I422AlphaToARGBMatrixFilter, I420AlphaToARGBMatrixFilter, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, NULL, I422AlphaToARGBMatrixFilter, I420AlphaToARGBMatrixFilter, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
};
// Lookup table for 8-bit YUV To 8-bit RGB Matrix (4:4:4 or nearest-neighbor filter).
static const YUVToRGBMatrix lutYuvToRgbMatrix[AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, I444ToRGB24Matrix, NULL, I420ToRGB24Matrix, NULL }, // RGB
{ NULL, I444ToARGBMatrix, I422ToARGBMatrix, I420ToARGBMatrix, NULL }, // RGBA
{ NULL, NULL, I422ToRGBAMatrix, I420ToRGBAMatrix, NULL }, // ARGB
{ NULL, I444ToRGB24Matrix, NULL, I420ToRGB24Matrix, NULL }, // BGR
{ NULL, I444ToARGBMatrix, I422ToARGBMatrix, I420ToARGBMatrix, NULL }, // BGRA
{ NULL, NULL, I422ToRGBAMatrix, I420ToRGBAMatrix, NULL }, // ABGR
{ NULL, NULL, I422ToRGB565Matrix, I420ToRGB565Matrix, NULL }, // RGB_565
};
// Lookup table for 8-bit YUVA To 8-bit RGB Matrix (4:4:4 or nearest-neighbor filter).
static const YUVAToRGBMatrix lutYuvaToRgbMatrix[AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, I444AlphaToARGBMatrix, I422AlphaToARGBMatrix, I420AlphaToARGBMatrix, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, I444AlphaToARGBMatrix, I422AlphaToARGBMatrix, I420AlphaToARGBMatrix, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
};
// Lookup table for YUV To RGB Matrix (with filter). First dimension is for the YUV bit depth.
static const YUVToRGBMatrixFilterHighBitDepth lutYuvToRgbMatrixFilterHighBitDepth[2][AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// 10bpc
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, NULL, I210ToARGBMatrixFilter, I010ToARGBMatrixFilter, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, NULL, I210ToARGBMatrixFilter, I010ToARGBMatrixFilter, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
},
// 12bpc
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, NULL, NULL, NULL, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, NULL, NULL, NULL, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
},
};
// Lookup table for YUVA To RGB Matrix (with filter). First dimension is for the YUV bit depth.
static const YUVAToRGBMatrixFilterHighBitDepth lutYuvaToRgbMatrixFilterHighBitDepth[2][AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// 10bpc
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, NULL, I210AlphaToARGBMatrixFilter, I010AlphaToARGBMatrixFilter, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, NULL, I210AlphaToARGBMatrixFilter, I010AlphaToARGBMatrixFilter, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
},
// 12bpc
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, NULL, NULL, NULL, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, NULL, NULL, NULL, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
},
};
// Lookup table for YUV To RGB Matrix (4:4:4 or nearest-neighbor filter). First dimension is for the YUV bit depth.
static const YUVToRGBMatrixHighBitDepth lutYuvToRgbMatrixHighBitDepth[2][AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// 10bpc
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, I410ToARGBMatrix, I210ToARGBMatrix, I010ToARGBMatrix, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, I410ToARGBMatrix, I210ToARGBMatrix, I010ToARGBMatrix, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
},
// 12bpc
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, NULL, NULL, I012ToARGBMatrix, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, NULL, NULL, I012ToARGBMatrix, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
},
};
// Lookup table for YUVA To RGB Matrix (4:4:4 or nearest-neighbor filter). First dimension is for the YUV bit depth.
static const YUVAToRGBMatrixHighBitDepth lutYuvaToRgbMatrixHighBitDepth[2][AVIF_RGB_FORMAT_COUNT][AVIF_PIXEL_FORMAT_COUNT] = {
// 10bpc
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, I410AlphaToARGBMatrix, I210AlphaToARGBMatrix, I010AlphaToARGBMatrix, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, I410AlphaToARGBMatrix, I210AlphaToARGBMatrix, I010AlphaToARGBMatrix, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
},
// 12bpc
{
// { NONE, YUV444, YUV422, YUV420, YUV400 } // AVIF_RGB_FORMAT_
{ NULL, NULL, NULL, NULL, NULL }, // RGB
{ NULL, NULL, NULL, NULL, NULL }, // RGBA
{ NULL, NULL, NULL, NULL, NULL }, // ARGB
{ NULL, NULL, NULL, NULL, NULL }, // BGR
{ NULL, NULL, NULL, NULL, NULL }, // BGRA
{ NULL, NULL, NULL, NULL, NULL }, // ABGR
{ NULL, NULL, NULL, NULL, NULL }, // RGB_565
},
};
memset(lcf, 0, sizeof(*lcf));
assert(rgb->depth == 8);
if (yuvDepth > 8) {
assert(yuvDepth == 10 || yuvDepth == 12);
int depthIndex = (yuvDepth == 10) ? 0 : 1;
if (yuvFormat != AVIF_PIXEL_FORMAT_YUV444) {
if (alphaPreferred) {
lcf->yuvaToRgbMatrixFilterHighBitDepth = lutYuvaToRgbMatrixFilterHighBitDepth[depthIndex][rgb->format][yuvFormat];
if (lcf->yuvaToRgbMatrixFilterHighBitDepth != NULL) {
return AVIF_TRUE;
}
}
lcf->yuvToRgbMatrixFilterHighBitDepth = lutYuvToRgbMatrixFilterHighBitDepth[depthIndex][rgb->format][yuvFormat];
if (lcf->yuvToRgbMatrixFilterHighBitDepth != NULL) {
return AVIF_TRUE;
}
}
if (yuvFormat == AVIF_PIXEL_FORMAT_YUV444 || nearestNeighborFilterAllowed(rgb->chromaUpsampling)) {
if (alphaPreferred) {
lcf->yuvaToRgbMatrixHighBitDepth = lutYuvaToRgbMatrixHighBitDepth[depthIndex][rgb->format][yuvFormat];
if (lcf->yuvaToRgbMatrixHighBitDepth != NULL) {
return AVIF_TRUE;
}
}
lcf->yuvToRgbMatrixHighBitDepth = lutYuvToRgbMatrixHighBitDepth[depthIndex][rgb->format][yuvFormat];
if (lcf->yuvToRgbMatrixHighBitDepth != NULL) {
return AVIF_TRUE;
}
}
// Fallthrough is intentional. No high bitdepth libyuv function was found. Check if there is an 8-bit libyuv function which
// can used with a downshift.
}
if (yuvFormat == AVIF_PIXEL_FORMAT_YUV400) {
lcf->yuv400ToRgbMatrix = lutYuv400ToRgbMatrix[rgb->format];
return lcf->yuv400ToRgbMatrix != NULL;
}
if (yuvFormat != AVIF_PIXEL_FORMAT_YUV444) {
if (alphaPreferred) {
lcf->yuvaToRgbMatrixFilter = lutYuvaToRgbMatrixFilter[rgb->format][yuvFormat];
if (lcf->yuvaToRgbMatrixFilter != NULL) {
return AVIF_TRUE;
}
}
lcf->yuvToRgbMatrixFilter = lutYuvToRgbMatrixFilter[rgb->format][yuvFormat];
if (lcf->yuvToRgbMatrixFilter != NULL) {
return AVIF_TRUE;
}
if (!nearestNeighborFilterAllowed(rgb->chromaUpsampling)) {
return AVIF_FALSE;
}
}
if (alphaPreferred) {
lcf->yuvaToRgbMatrix = lutYuvaToRgbMatrix[rgb->format][yuvFormat];
if (lcf->yuvaToRgbMatrix != NULL) {
return AVIF_TRUE;
}
}
lcf->yuvToRgbMatrix = lutYuvToRgbMatrix[rgb->format][yuvFormat];
return lcf->yuvToRgbMatrix != NULL;
}
static void getLibYUVConstants(const avifImage * image, const struct YuvConstants ** matrixYUV, const struct YuvConstants ** matrixYVU)
{
// Allow the identity matrix to be used with YUV 4:0:0. Replace the identity matrix with
// MatrixCoefficients 6 (BT.601).
const avifBool yuv400WithIdentityMatrix = (image->yuvFormat == AVIF_PIXEL_FORMAT_YUV400) &&
(image->matrixCoefficients == AVIF_MATRIX_COEFFICIENTS_IDENTITY);
const avifMatrixCoefficients matrixCoefficients = yuv400WithIdentityMatrix ? AVIF_MATRIX_COEFFICIENTS_BT601 : image->matrixCoefficients;
if (image->yuvRange == AVIF_RANGE_FULL) {
switch (matrixCoefficients) {
// BT.709 full range YuvConstants were added in libyuv version 1772.
// See https://chromium-review.googlesource.com/c/libyuv/libyuv/+/2646472.
case AVIF_MATRIX_COEFFICIENTS_BT709:
#if LIBYUV_VERSION >= 1772
*matrixYUV = &kYuvF709Constants;
*matrixYVU = &kYvuF709Constants;
#endif
break;
case AVIF_MATRIX_COEFFICIENTS_BT470BG:
case AVIF_MATRIX_COEFFICIENTS_BT601:
case AVIF_MATRIX_COEFFICIENTS_UNSPECIFIED:
*matrixYUV = &kYuvJPEGConstants;
*matrixYVU = &kYvuJPEGConstants;
break;
// BT.2020 full range YuvConstants were added in libyuv version 1775.
// See https://chromium-review.googlesource.com/c/libyuv/libyuv/+/2678859.
case AVIF_MATRIX_COEFFICIENTS_BT2020_NCL:
#if LIBYUV_VERSION >= 1775
*matrixYUV = &kYuvV2020Constants;
*matrixYVU = &kYvuV2020Constants;
#endif
break;
case AVIF_MATRIX_COEFFICIENTS_CHROMA_DERIVED_NCL:
switch (image->colorPrimaries) {
case AVIF_COLOR_PRIMARIES_BT709:
case AVIF_COLOR_PRIMARIES_UNSPECIFIED:
#if LIBYUV_VERSION >= 1772
*matrixYUV = &kYuvF709Constants;
*matrixYVU = &kYvuF709Constants;
#endif
break;
case AVIF_COLOR_PRIMARIES_BT470BG:
case AVIF_COLOR_PRIMARIES_BT601:
*matrixYUV = &kYuvJPEGConstants;
*matrixYVU = &kYvuJPEGConstants;
break;
case AVIF_COLOR_PRIMARIES_BT2020:
#if LIBYUV_VERSION >= 1775
*matrixYUV = &kYuvV2020Constants;
*matrixYVU = &kYvuV2020Constants;
#endif
break;
case AVIF_COLOR_PRIMARIES_UNKNOWN:
case AVIF_COLOR_PRIMARIES_BT470M:
case AVIF_COLOR_PRIMARIES_SMPTE240:
case AVIF_COLOR_PRIMARIES_GENERIC_FILM:
case AVIF_COLOR_PRIMARIES_XYZ:
case AVIF_COLOR_PRIMARIES_SMPTE431:
case AVIF_COLOR_PRIMARIES_SMPTE432:
case AVIF_COLOR_PRIMARIES_EBU3213:
break;
}
break;
case AVIF_MATRIX_COEFFICIENTS_IDENTITY:
case AVIF_MATRIX_COEFFICIENTS_FCC:
case AVIF_MATRIX_COEFFICIENTS_SMPTE240:
case AVIF_MATRIX_COEFFICIENTS_YCGCO:
case AVIF_MATRIX_COEFFICIENTS_BT2020_CL:
case AVIF_MATRIX_COEFFICIENTS_SMPTE2085:
case AVIF_MATRIX_COEFFICIENTS_CHROMA_DERIVED_CL:
case AVIF_MATRIX_COEFFICIENTS_ICTCP:
break;
}
} else { // image->yuvRange == AVIF_RANGE_LIMITED
switch (matrixCoefficients) {
case AVIF_MATRIX_COEFFICIENTS_BT709:
*matrixYUV = &kYuvH709Constants;
*matrixYVU = &kYvuH709Constants;
break;
case AVIF_MATRIX_COEFFICIENTS_BT470BG:
case AVIF_MATRIX_COEFFICIENTS_BT601:
case AVIF_MATRIX_COEFFICIENTS_UNSPECIFIED:
*matrixYUV = &kYuvI601Constants;
*matrixYVU = &kYvuI601Constants;
break;
case AVIF_MATRIX_COEFFICIENTS_BT2020_NCL:
*matrixYUV = &kYuv2020Constants;
*matrixYVU = &kYvu2020Constants;
break;
case AVIF_MATRIX_COEFFICIENTS_CHROMA_DERIVED_NCL:
switch (image->colorPrimaries) {
case AVIF_COLOR_PRIMARIES_BT709:
case AVIF_COLOR_PRIMARIES_UNSPECIFIED:
*matrixYUV = &kYuvH709Constants;
*matrixYVU = &kYvuH709Constants;
break;
case AVIF_COLOR_PRIMARIES_BT470BG:
case AVIF_COLOR_PRIMARIES_BT601:
*matrixYUV = &kYuvI601Constants;
*matrixYVU = &kYvuI601Constants;
break;
case AVIF_COLOR_PRIMARIES_BT2020:
*matrixYUV = &kYuv2020Constants;
*matrixYVU = &kYvu2020Constants;
break;
case AVIF_COLOR_PRIMARIES_UNKNOWN:
case AVIF_COLOR_PRIMARIES_BT470M:
case AVIF_COLOR_PRIMARIES_SMPTE240:
case AVIF_COLOR_PRIMARIES_GENERIC_FILM:
case AVIF_COLOR_PRIMARIES_XYZ:
case AVIF_COLOR_PRIMARIES_SMPTE431:
case AVIF_COLOR_PRIMARIES_SMPTE432:
case AVIF_COLOR_PRIMARIES_EBU3213:
break;
}
break;
case AVIF_MATRIX_COEFFICIENTS_IDENTITY:
case AVIF_MATRIX_COEFFICIENTS_FCC:
case AVIF_MATRIX_COEFFICIENTS_SMPTE240:
case AVIF_MATRIX_COEFFICIENTS_YCGCO:
case AVIF_MATRIX_COEFFICIENTS_BT2020_CL:
case AVIF_MATRIX_COEFFICIENTS_SMPTE2085:
case AVIF_MATRIX_COEFFICIENTS_CHROMA_DERIVED_CL:
case AVIF_MATRIX_COEFFICIENTS_ICTCP:
break;
}
}
}
static avifResult avifImageDownshiftTo8bpc(const avifImage * image, avifImage * image8, avifBool downshiftAlpha)
{
avifImageSetDefaults(image8);
avifImageCopyNoAlloc(image8, image);
image8->depth = 8;
// downshiftAlpha will be true only if the image has an alpha plane. So it is safe to pass AVIF_PLANES_ALL here in that case.
assert(!downshiftAlpha || image->alphaPlane);
AVIF_CHECKRES(avifImageAllocatePlanes(image8, downshiftAlpha ? AVIF_PLANES_ALL : AVIF_PLANES_YUV));
// 16384 for 10-bit and 4096 for 12-bit.
const int scale = 1 << (24 - image->depth);
for (int plane = AVIF_CHAN_Y; plane <= (downshiftAlpha ? AVIF_CHAN_A : AVIF_CHAN_V); ++plane) {
const uint32_t planeWidth = avifImagePlaneWidth(image, plane);
if (planeWidth == 0) {
continue;
}
Convert16To8Plane((const uint16_t *)avifImagePlane(image, plane),
avifImagePlaneRowBytes(image, plane) / 2,
avifImagePlane(image8, plane),
avifImagePlaneRowBytes(image8, plane),
scale,
planeWidth,
avifImagePlaneHeight(image, plane));
}
return AVIF_RESULT_OK;
}
IGNORE_CFI_ICALL avifResult avifImageYUVToRGBLibYUV(const avifImage * image, avifRGBImage * rgb, avifBool reformatAlpha, avifBool * alphaReformattedWithLibYUV)
{
*alphaReformattedWithLibYUV = AVIF_FALSE;
// The width, height, and stride parameters of libyuv functions are all of the int type.
if (image->width > INT_MAX || image->height > INT_MAX || image->yuvRowBytes[AVIF_CHAN_Y] > INT_MAX || rgb->rowBytes > INT_MAX) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
if (rgb->depth != 8 || (image->depth != 8 && image->depth != 10 && image->depth != 12)) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
// Find the correct libyuv YuvConstants, based on range and CP/MC
const struct YuvConstants * matrixYUV = NULL;
const struct YuvConstants * matrixYVU = NULL;
getLibYUVConstants(image, &matrixYUV, &matrixYVU);
if (!matrixYVU) {
// No YuvConstants exist for the current image; use the built-in YUV conversion
return AVIF_RESULT_NOT_IMPLEMENTED;
}
LibyuvConversionFunction lcf;
const avifBool alphaPreferred = reformatAlpha && image->alphaPlane && image->alphaRowBytes;
if (!getLibYUVConversionFunction(image->yuvFormat, image->depth, rgb, alphaPreferred, &lcf)) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
if (!image->alphaPlane || !image->alphaRowBytes) {
// If the image does not have an alpha plane, then libyuv always prefills the output RGB image with opaque alpha values.
*alphaReformattedWithLibYUV = AVIF_TRUE;
}
avifBool isYVU = lutIsYVU[rgb->format];
const struct YuvConstants * matrix = isYVU ? matrixYVU : matrixYUV;
int libyuvResult = -1;
int uPlaneIndex = isYVU ? AVIF_CHAN_V : AVIF_CHAN_U;
int vPlaneIndex = isYVU ? AVIF_CHAN_U : AVIF_CHAN_V;
const enum FilterMode filter =
((rgb->chromaUpsampling == AVIF_CHROMA_UPSAMPLING_FASTEST) || (rgb->chromaUpsampling == AVIF_CHROMA_UPSAMPLING_NEAREST))
? kFilterNone
: kFilterBilinear;
if (lcf.yuvToRgbMatrixFilterHighBitDepth != NULL) {
libyuvResult = lcf.yuvToRgbMatrixFilterHighBitDepth((const uint16_t *)image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y] / 2,
(const uint16_t *)image->yuvPlanes[uPlaneIndex],
image->yuvRowBytes[uPlaneIndex] / 2,
(const uint16_t *)image->yuvPlanes[vPlaneIndex],
image->yuvRowBytes[vPlaneIndex] / 2,
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height,
filter);
} else if (lcf.yuvaToRgbMatrixFilterHighBitDepth != NULL) {
libyuvResult = lcf.yuvaToRgbMatrixFilterHighBitDepth((const uint16_t *)image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y] / 2,
(const uint16_t *)image->yuvPlanes[uPlaneIndex],
image->yuvRowBytes[uPlaneIndex] / 2,
(const uint16_t *)image->yuvPlanes[vPlaneIndex],
image->yuvRowBytes[vPlaneIndex] / 2,
(const uint16_t *)image->alphaPlane,
image->alphaRowBytes / 2,
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height,
/*attenuate=*/0,
filter);
*alphaReformattedWithLibYUV = AVIF_TRUE;
} else if (lcf.yuvToRgbMatrixHighBitDepth != NULL) {
libyuvResult = lcf.yuvToRgbMatrixHighBitDepth((const uint16_t *)image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y] / 2,
(const uint16_t *)image->yuvPlanes[uPlaneIndex],
image->yuvRowBytes[uPlaneIndex] / 2,
(const uint16_t *)image->yuvPlanes[vPlaneIndex],
image->yuvRowBytes[vPlaneIndex] / 2,
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height);
} else if (lcf.yuvaToRgbMatrixHighBitDepth != NULL) {
libyuvResult = lcf.yuvaToRgbMatrixHighBitDepth((const uint16_t *)image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y] / 2,
(const uint16_t *)image->yuvPlanes[uPlaneIndex],
image->yuvRowBytes[uPlaneIndex] / 2,
(const uint16_t *)image->yuvPlanes[vPlaneIndex],
image->yuvRowBytes[vPlaneIndex] / 2,
(const uint16_t *)image->alphaPlane,
image->alphaRowBytes / 2,
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height,
/*attentuate=*/0);
*alphaReformattedWithLibYUV = AVIF_TRUE;
} else {
avifImage image8;
avifBool inputIsHighBitDepth = image->depth > 8;
if (inputIsHighBitDepth) {
const avifBool downshiftAlpha = (lcf.yuvaToRgbMatrixFilter != NULL || lcf.yuvaToRgbMatrix != NULL);
AVIF_CHECKRES(avifImageDownshiftTo8bpc(image, &image8, downshiftAlpha));
image = &image8;
}
if (lcf.yuv400ToRgbMatrix != NULL) {
libyuvResult = lcf.yuv400ToRgbMatrix(image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y],
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height);
} else if (lcf.yuvToRgbMatrixFilter != NULL) {
libyuvResult = lcf.yuvToRgbMatrixFilter(image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y],
image->yuvPlanes[uPlaneIndex],
image->yuvRowBytes[uPlaneIndex],
image->yuvPlanes[vPlaneIndex],
image->yuvRowBytes[vPlaneIndex],
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height,
filter);
} else if (lcf.yuvaToRgbMatrixFilter != NULL) {
libyuvResult = lcf.yuvaToRgbMatrixFilter(image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y],
image->yuvPlanes[uPlaneIndex],
image->yuvRowBytes[uPlaneIndex],
image->yuvPlanes[vPlaneIndex],
image->yuvRowBytes[vPlaneIndex],
image->alphaPlane,
image->alphaRowBytes,
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height,
/*attenuate=*/0,
filter);
*alphaReformattedWithLibYUV = AVIF_TRUE;
} else if (lcf.yuvToRgbMatrix != NULL) {
libyuvResult = lcf.yuvToRgbMatrix(image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y],
image->yuvPlanes[uPlaneIndex],
image->yuvRowBytes[uPlaneIndex],
image->yuvPlanes[vPlaneIndex],
image->yuvRowBytes[vPlaneIndex],
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height);
} else if (lcf.yuvaToRgbMatrix != NULL) {
libyuvResult = lcf.yuvaToRgbMatrix(image->yuvPlanes[AVIF_CHAN_Y],
image->yuvRowBytes[AVIF_CHAN_Y],
image->yuvPlanes[uPlaneIndex],
image->yuvRowBytes[uPlaneIndex],
image->yuvPlanes[vPlaneIndex],
image->yuvRowBytes[vPlaneIndex],
image->alphaPlane,
image->alphaRowBytes,
rgb->pixels,
rgb->rowBytes,
matrix,
image->width,
image->height,
/*attenuate=*/0);
*alphaReformattedWithLibYUV = AVIF_TRUE;
}
if (inputIsHighBitDepth) {
avifImageFreePlanes(&image8, AVIF_PLANES_ALL);
image = NULL;
}
}
return (libyuvResult != 0) ? AVIF_RESULT_REFORMAT_FAILED : AVIF_RESULT_OK;
}
//--------------------------------------------------------------------------------------------------
avifResult avifRGBImagePremultiplyAlphaLibYUV(avifRGBImage * rgb)
{
// See if the current settings can be accomplished with libyuv, and use it (if possible).
// The width, height, and stride parameters of libyuv functions are all of the int type.
if (rgb->width > INT_MAX || rgb->height > INT_MAX || rgb->rowBytes > INT_MAX) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
if (rgb->depth != 8) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
// libavif uses byte-order when describing pixel formats, such that the R in RGBA is the lowest address,
// similar to PNG. libyuv orders in word-order, so libavif's RGBA would be referred to in libyuv as ABGR.
// Order of RGB doesn't matter here.
if (rgb->format == AVIF_RGB_FORMAT_RGBA || rgb->format == AVIF_RGB_FORMAT_BGRA) {
if (ARGBAttenuate(rgb->pixels, rgb->rowBytes, rgb->pixels, rgb->rowBytes, rgb->width, rgb->height) != 0) {
return AVIF_RESULT_REFORMAT_FAILED;
}
return AVIF_RESULT_OK;
}
return AVIF_RESULT_NOT_IMPLEMENTED;
}
avifResult avifRGBImageUnpremultiplyAlphaLibYUV(avifRGBImage * rgb)
{
// See if the current settings can be accomplished with libyuv, and use it (if possible).
// The width, height, and stride parameters of libyuv functions are all of the int type.
if (rgb->width > INT_MAX || rgb->height > INT_MAX || rgb->rowBytes > INT_MAX) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
if (rgb->depth != 8) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
// libavif uses byte-order when describing pixel formats, such that the R in RGBA is the lowest address,
// similar to PNG. libyuv orders in word-order, so libavif's RGBA would be referred to in libyuv as ABGR.
if (rgb->format == AVIF_RGB_FORMAT_RGBA || rgb->format == AVIF_RGB_FORMAT_BGRA) {
if (ARGBUnattenuate(rgb->pixels, rgb->rowBytes, rgb->pixels, rgb->rowBytes, rgb->width, rgb->height) != 0) {
return AVIF_RESULT_REFORMAT_FAILED;
}
return AVIF_RESULT_OK;
}
return AVIF_RESULT_NOT_IMPLEMENTED;
}
avifResult avifRGBImageToF16LibYUV(avifRGBImage * rgb)
{
// The width, height, and stride parameters of libyuv functions are all of the int type.
if (rgb->width > INT_MAX || rgb->height > INT_MAX || rgb->rowBytes > INT_MAX) {
return AVIF_RESULT_NOT_IMPLEMENTED;
}
const float scale = 1.0f / ((1 << rgb->depth) - 1);
// Note: HalfFloatPlane requires the stride to be in bytes.
const int result = HalfFloatPlane((const uint16_t *)rgb->pixels,
rgb->rowBytes,
(uint16_t *)rgb->pixels,
rgb->rowBytes,
scale,
rgb->width * avifRGBFormatChannelCount(rgb->format),
rgb->height);
return (result == 0) ? AVIF_RESULT_OK : AVIF_RESULT_INVALID_ARGUMENT;
}
unsigned int avifLibYUVVersion(void)
{
return (unsigned int)LIBYUV_VERSION;
}
#endif