apps/avifgainmaputil/swapbase_command.cc - libavif - Git at Google

 // Copyright 2023 Google LLC
 // SPDX-License-Identifier: BSD-2-Clause

 #include "swapbase_command.h"

 #include "avif/avif_cxx.h"
 #include "imageio.h"

 namespace avif {

 avifResult ChangeBase(const avifImage& image, int depth,
                       avifPixelFormat yuvFormat, avifImage* swapped) {
   if (image.gainMap == nullptr || image.gainMap->image == nullptr) {
     return AVIF_RESULT_INVALID_ARGUMENT;
   }

   // Copy all metadata (no planes).
   avifResult result = avifImageCopy(swapped, &image, /*planes=*/0);
   if (result != AVIF_RESULT_OK) {
     return result;
   }
   swapped->depth = depth;
   swapped->yuvFormat = yuvFormat;

   const float headroom =
       static_cast<double>(image.gainMap->metadata.alternateHdrHeadroomN) /
       image.gainMap->metadata.alternateHdrHeadroomD;
   const bool tone_mapping_to_sdr = (headroom == 0.0f);

   swapped->colorPrimaries = image.gainMap->altColorPrimaries;
   if (swapped->colorPrimaries == AVIF_COLOR_PRIMARIES_UNSPECIFIED) {
     // Default to the same primaries as the base image if unspecified.
     swapped->colorPrimaries = image.colorPrimaries;
   }

   swapped->transferCharacteristics = image.gainMap->altTransferCharacteristics;
   if (swapped->transferCharacteristics ==
       AVIF_TRANSFER_CHARACTERISTICS_UNSPECIFIED) {
     // Default to PQ for HDR and sRGB for SDR if unspecified.
     const avifTransferCharacteristics transfer_characteristics =
         tone_mapping_to_sdr ? AVIF_TRANSFER_CHARACTERISTICS_SRGB
                             : AVIF_TRANSFER_CHARACTERISTICS_PQ;
     swapped->transferCharacteristics = transfer_characteristics;
   }

   swapped->matrixCoefficients = image.gainMap->altMatrixCoefficients;
   if (swapped->matrixCoefficients == AVIF_MATRIX_COEFFICIENTS_UNSPECIFIED) {
     // Default to the same matrix as the base image if unspecified.
     swapped->matrixCoefficients = image.matrixCoefficients;
   }

   avifRGBImage swapped_rgb;
   avifRGBImageSetDefaults(&swapped_rgb, swapped);

   avifContentLightLevelInformationBox clli = image.gainMap->image->clli;
   const bool compute_clli =
       !tone_mapping_to_sdr && clli.maxCLL == 0 && clli.maxPALL == 0;

   avifDiagnostics diag;
   result = avifImageApplyGainMap(&image, image.gainMap, headroom,
                                  swapped->colorPrimaries,
                                  swapped->transferCharacteristics, &swapped_rgb,
                                  (compute_clli ? &clli : nullptr), &diag);
   if (result != AVIF_RESULT_OK) {
     std::cout << "Failed to tone map image: " << avifResultToString(result)
               << " (" << diag.error << ")\n";
     return result;
   }
   result = avifImageRGBToYUV(swapped, &swapped_rgb);
   if (result != AVIF_RESULT_OK) {
     std::cerr << "Failed to convert to YUV: " << avifResultToString(result)
               << "\n";
     return result;
   }

   swapped->clli = clli;
   // Copy the gain map's planes.
   result = avifImageCopy(swapped->gainMap->image, image.gainMap->image,
                          AVIF_PLANES_YUV);
   if (result != AVIF_RESULT_OK) {
     return result;
   }

   // Fill in the information on the alternate image
   result =
       avifRWDataSet(&swapped->gainMap->altICC, image.icc.data, image.icc.size);
   if (result != AVIF_RESULT_OK) {
     return result;
   }
   swapped->gainMap->altColorPrimaries = image.colorPrimaries;
   swapped->gainMap->altTransferCharacteristics = image.transferCharacteristics;
   swapped->gainMap->altMatrixCoefficients = image.matrixCoefficients;
   swapped->gainMap->altYUVRange = image.yuvRange;
   swapped->gainMap->altDepth = image.depth;
   swapped->gainMap->altPlaneCount =
       (image.yuvFormat == AVIF_PIXEL_FORMAT_YUV400) ? 1 : 3;
   swapped->gainMap->altCLLI = image.clli;

   // Swap base and alternate in the gain map metadata.
   avifGainMapMetadata& metadata = swapped->gainMap->metadata;
   metadata.backwardDirection = !metadata.backwardDirection;
   metadata.useBaseColorSpace = !metadata.useBaseColorSpace;
   std::swap(metadata.baseHdrHeadroomN, metadata.alternateHdrHeadroomN);
   std::swap(metadata.baseHdrHeadroomD, metadata.alternateHdrHeadroomD);
   for (int c = 0; c < 3; ++c) {
     std::swap(metadata.baseOffsetN, metadata.alternateOffsetN);
     std::swap(metadata.baseOffsetD, metadata.alternateOffsetD);
   }

   return AVIF_RESULT_OK;
 }

 SwapBaseCommand::SwapBaseCommand()
     : ProgramCommand(
           "swapbase",
           "Swaps the base and alternate images (e.g. if the base image is SDR "
           "and the alternate is HDR, makes the base HDR). The alternate image "
           "is the result ot fully applying the gain map.") {
   argparse_.add_argument(arg_input_filename_, "input_filename");
   argparse_.add_argument(arg_output_filename_, "output_filename");
   arg_image_read_.Init(argparse_);
   arg_image_encode_.Init(argparse_, /*can_have_alpha=*/true);
   argparse_.add_argument(arg_gain_map_quality_, "--qgain-map")
       .help("Quality for the gain map (0-100, where 100 is lossless)")
       .default_value("60");
 }

 avifResult SwapBaseCommand::Run() {
   DecoderPtr decoder(avifDecoderCreate());
   if (decoder == NULL) {
     return AVIF_RESULT_OUT_OF_MEMORY;
   }
   decoder->enableParsingGainMapMetadata = true;
   decoder->enableDecodingGainMap = true;
   avifResult result = ReadAvif(decoder.get(), arg_input_filename_,
                                arg_image_read_.ignore_profile);
   if (result != AVIF_RESULT_OK) {
     return result;
   }

   const avifImage* image = decoder->image;
   if (image->gainMap == nullptr || image->gainMap->image == nullptr) {
     std::cerr << "Input image " << arg_input_filename_
               << " does not contain a gain map\n";
     return AVIF_RESULT_INVALID_ARGUMENT;
   }

   int depth = arg_image_read_.depth;
   if (depth == 0) {
     depth = image->gainMap->altDepth;
   }
   if (depth == 0) {
     // Default to the max depth between the base image and the gain map/
     depth = std::max(image->depth, image->gainMap->image->depth);
   }

   avifPixelFormat pixel_format =
       (avifPixelFormat)arg_image_read_.pixel_format.value();
   if (pixel_format == AVIF_PIXEL_FORMAT_NONE) {
     pixel_format = (image->gainMap->altPlaneCount == 1)
                        ? AVIF_PIXEL_FORMAT_YUV420
                        : AVIF_PIXEL_FORMAT_YUV444;
   }

   ImagePtr new_base(avifImageCreateEmpty());
   if (new_base == nullptr) {
     return AVIF_RESULT_OUT_OF_MEMORY;
   }
   result = ChangeBase(*image, depth, pixel_format, new_base.get());
   if (result != AVIF_RESULT_OK) {
     return result;
   }

   EncoderPtr encoder(avifEncoderCreate());
   if (encoder == nullptr) {
     return AVIF_RESULT_OUT_OF_MEMORY;
   }
   encoder->quality = arg_image_encode_.quality;
   encoder->qualityAlpha = arg_image_encode_.quality_alpha;
   encoder->qualityGainMap = arg_gain_map_quality_;
   encoder->speed = arg_image_encode_.speed;
   result = WriteAvif(new_base.get(), encoder.get(), arg_output_filename_);
   if (result != AVIF_RESULT_OK) {
     std::cout << "Failed to encode image: " << avifResultToString(result)
               << " (" << encoder->diag.error << ")\n";
     return result;
   }

   return AVIF_RESULT_OK;
 }

 }  // namespace avif
	// Copyright 2023 Google LLC
	// SPDX-License-Identifier: BSD-2-Clause

	#include "swapbase_command.h"

	#include "avif/avif_cxx.h"
	#include "imageio.h"

	namespace avif {

	avifResult ChangeBase(const avifImage& image, int depth,
	avifPixelFormat yuvFormat, avifImage* swapped) {
	if (image.gainMap == nullptr \|\| image.gainMap->image == nullptr) {
	return AVIF_RESULT_INVALID_ARGUMENT;
	}

	// Copy all metadata (no planes).
	avifResult result = avifImageCopy(swapped, &image, /planes=/0);
	if (result != AVIF_RESULT_OK) {
	return result;
	}
	swapped->depth = depth;
	swapped->yuvFormat = yuvFormat;

	const float headroom =
	static_cast<double>(image.gainMap->metadata.alternateHdrHeadroomN) /
	image.gainMap->metadata.alternateHdrHeadroomD;
	const bool tone_mapping_to_sdr = (headroom == 0.0f);

	swapped->colorPrimaries = image.gainMap->altColorPrimaries;
	if (swapped->colorPrimaries == AVIF_COLOR_PRIMARIES_UNSPECIFIED) {
	// Default to the same primaries as the base image if unspecified.
	swapped->colorPrimaries = image.colorPrimaries;
	}

	swapped->transferCharacteristics = image.gainMap->altTransferCharacteristics;
	if (swapped->transferCharacteristics ==
	AVIF_TRANSFER_CHARACTERISTICS_UNSPECIFIED) {
	// Default to PQ for HDR and sRGB for SDR if unspecified.
	const avifTransferCharacteristics transfer_characteristics =
	tone_mapping_to_sdr ? AVIF_TRANSFER_CHARACTERISTICS_SRGB
	: AVIF_TRANSFER_CHARACTERISTICS_PQ;
	swapped->transferCharacteristics = transfer_characteristics;
	}

	swapped->matrixCoefficients = image.gainMap->altMatrixCoefficients;
	if (swapped->matrixCoefficients == AVIF_MATRIX_COEFFICIENTS_UNSPECIFIED) {
	// Default to the same matrix as the base image if unspecified.
	swapped->matrixCoefficients = image.matrixCoefficients;
	}

	avifRGBImage swapped_rgb;
	avifRGBImageSetDefaults(&swapped_rgb, swapped);

	avifContentLightLevelInformationBox clli = image.gainMap->image->clli;
	const bool compute_clli =
	!tone_mapping_to_sdr && clli.maxCLL == 0 && clli.maxPALL == 0;

	avifDiagnostics diag;
	result = avifImageApplyGainMap(&image, image.gainMap, headroom,
	swapped->colorPrimaries,
	swapped->transferCharacteristics, &swapped_rgb,
	(compute_clli ? &clli : nullptr), &diag);
	if (result != AVIF_RESULT_OK) {
	std::cout << "Failed to tone map image: " << avifResultToString(result)
	<< " (" << diag.error << ")\n";
	return result;
	}
	result = avifImageRGBToYUV(swapped, &swapped_rgb);
	if (result != AVIF_RESULT_OK) {
	std::cerr << "Failed to convert to YUV: " << avifResultToString(result)
	<< "\n";
	return result;
	}

	swapped->clli = clli;
	// Copy the gain map's planes.
	result = avifImageCopy(swapped->gainMap->image, image.gainMap->image,
	AVIF_PLANES_YUV);
	if (result != AVIF_RESULT_OK) {
	return result;
	}

	// Fill in the information on the alternate image
	result =
	avifRWDataSet(&swapped->gainMap->altICC, image.icc.data, image.icc.size);
	if (result != AVIF_RESULT_OK) {
	return result;
	}
	swapped->gainMap->altColorPrimaries = image.colorPrimaries;
	swapped->gainMap->altTransferCharacteristics = image.transferCharacteristics;
	swapped->gainMap->altMatrixCoefficients = image.matrixCoefficients;
	swapped->gainMap->altYUVRange = image.yuvRange;
	swapped->gainMap->altDepth = image.depth;
	swapped->gainMap->altPlaneCount =
	(image.yuvFormat == AVIF_PIXEL_FORMAT_YUV400) ? 1 : 3;
	swapped->gainMap->altCLLI = image.clli;

	// Swap base and alternate in the gain map metadata.
	avifGainMapMetadata& metadata = swapped->gainMap->metadata;
	metadata.backwardDirection = !metadata.backwardDirection;
	metadata.useBaseColorSpace = !metadata.useBaseColorSpace;
	std::swap(metadata.baseHdrHeadroomN, metadata.alternateHdrHeadroomN);
	std::swap(metadata.baseHdrHeadroomD, metadata.alternateHdrHeadroomD);
	for (int c = 0; c < 3; ++c) {
	std::swap(metadata.baseOffsetN, metadata.alternateOffsetN);
	std::swap(metadata.baseOffsetD, metadata.alternateOffsetD);
	}

	return AVIF_RESULT_OK;
	}

	SwapBaseCommand::SwapBaseCommand()
	: ProgramCommand(
	"swapbase",
	"Swaps the base and alternate images (e.g. if the base image is SDR "
	"and the alternate is HDR, makes the base HDR). The alternate image "
	"is the result ot fully applying the gain map.") {
	argparse_.add_argument(arg_input_filename_, "input_filename");
	argparse_.add_argument(arg_output_filename_, "output_filename");
	arg_image_read_.Init(argparse_);
	arg_image_encode_.Init(argparse_, /can_have_alpha=/true);
	argparse_.add_argument(arg_gain_map_quality_, "--qgain-map")
	.help("Quality for the gain map (0-100, where 100 is lossless)")
	.default_value("60");
	}

	avifResult SwapBaseCommand::Run() {
	DecoderPtr decoder(avifDecoderCreate());
	if (decoder == NULL) {
	return AVIF_RESULT_OUT_OF_MEMORY;
	}
	decoder->enableParsingGainMapMetadata = true;
	decoder->enableDecodingGainMap = true;
	avifResult result = ReadAvif(decoder.get(), arg_input_filename_,
	arg_image_read_.ignore_profile);
	if (result != AVIF_RESULT_OK) {
	return result;
	}

	const avifImage* image = decoder->image;
	if (image->gainMap == nullptr \|\| image->gainMap->image == nullptr) {
	std::cerr << "Input image " << arg_input_filename_
	<< " does not contain a gain map\n";
	return AVIF_RESULT_INVALID_ARGUMENT;
	}

	int depth = arg_image_read_.depth;
	if (depth == 0) {
	depth = image->gainMap->altDepth;
	}
	if (depth == 0) {
	// Default to the max depth between the base image and the gain map/
	depth = std::max(image->depth, image->gainMap->image->depth);
	}

	avifPixelFormat pixel_format =
	(avifPixelFormat)arg_image_read_.pixel_format.value();
	if (pixel_format == AVIF_PIXEL_FORMAT_NONE) {
	pixel_format = (image->gainMap->altPlaneCount == 1)
	? AVIF_PIXEL_FORMAT_YUV420
	: AVIF_PIXEL_FORMAT_YUV444;
	}

	ImagePtr new_base(avifImageCreateEmpty());
	if (new_base == nullptr) {
	return AVIF_RESULT_OUT_OF_MEMORY;
	}
	result = ChangeBase(*image, depth, pixel_format, new_base.get());
	if (result != AVIF_RESULT_OK) {
	return result;
	}

	EncoderPtr encoder(avifEncoderCreate());
	if (encoder == nullptr) {
	return AVIF_RESULT_OUT_OF_MEMORY;
	}
	encoder->quality = arg_image_encode_.quality;
	encoder->qualityAlpha = arg_image_encode_.quality_alpha;
	encoder->qualityGainMap = arg_gain_map_quality_;
	encoder->speed = arg_image_encode_.speed;
	result = WriteAvif(new_base.get(), encoder.get(), arg_output_filename_);
	if (result != AVIF_RESULT_OK) {
	std::cout << "Failed to encode image: " << avifResultToString(result)
	<< " (" << encoder->diag.error << ")\n";
	return result;
	}

	return AVIF_RESULT_OK;
	}

	} // namespace avif