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gerrit.omnirom.org / android_frameworks_native / 636f5240a78cc824eaa081e919dbec73894b4390 / . / libs / jpegrecoverymap / recoverymap.cpp
blob: a744d157fde0bec909beff07c012c9833ab59b2c [file] [log] [blame]
/*
* Copyright 2022 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <jpegrecoverymap/recoverymap.h>
#include <jpegrecoverymap/jpegencoder.h>
#include <jpegrecoverymap/jpegdecoder.h>
#include <jpegrecoverymap/recoverymapmath.h>
#include <jpegrecoverymap/recoverymaputils.h>
#include <image_io/jpeg/jpeg_marker.h>
#include <image_io/xml/xml_writer.h>
#include <image_io/jpeg/jpeg_info.h>
#include <image_io/jpeg/jpeg_scanner.h>
#include <image_io/jpeg/jpeg_info_builder.h>
#include <image_io/base/data_segment_data_source.h>
#include <utils/Log.h>
#include <memory>
#include <sstream>
#include <string>
#include <cmath>
using namespace std;
using namespace photos_editing_formats::image_io;
namespace android::recoverymap {
#define JPEGR_CHECK(x) \
{ \
status_t status = (x); \
if ((status) != NO_ERROR) { \
return status; \
} \
}
// The current JPEGR version that we encode to
static const uint32_t kJpegrVersion = 1;
// Map is quarter res / sixteenth size
static const size_t kMapDimensionScaleFactor = 4;
// JPEG compress quality (0 ~ 100) for recovery map
static const int kMapCompressQuality = 85;
// TODO: fill in st2086 metadata
static const st2086_metadata kSt2086Metadata = {
{0.0f, 0.0f},
{0.0f, 0.0f},
{0.0f, 0.0f},
{0.0f, 0.0f},
0,
1.0f,
};
/*
* Helper function used for generating XMP metadata.
*
* @param prefix The prefix part of the name.
* @param suffix The suffix part of the name.
* @return A name of the form "prefix:suffix".
*/
string Name(const string &prefix, const string &suffix) {
std::stringstream ss;
ss << prefix << ":" << suffix;
return ss.str();
}
/*
* Helper function used for writing data to destination.
*
* @param destination destination of the data to be written.
* @param source source of data being written.
* @param length length of the data to be written.
* @param position cursor in desitination where the data is to be written.
* @return status of succeed or error code.
*/
status_t Write(jr_compressed_ptr destination, const void* source, size_t length, int &position) {
if (position + length > destination->maxLength) {
return ERROR_JPEGR_BUFFER_TOO_SMALL;
}
memcpy((uint8_t*)destination->data + sizeof(uint8_t) * position, source, length);
position += length;
return NO_ERROR;
}
/* Encode API-0 */
status_t RecoveryMap::encodeJPEGR(jr_uncompressed_ptr uncompressed_p010_image,
jpegr_transfer_function hdr_tf,
jr_compressed_ptr dest,
int quality,
jr_exif_ptr /* exif */) {
if (uncompressed_p010_image == nullptr || dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
if (quality < 0 || quality > 100) {
return ERROR_JPEGR_INVALID_INPUT_TYPE;
}
jpegr_metadata metadata;
metadata.version = kJpegrVersion;
metadata.transferFunction = hdr_tf;
if (hdr_tf == JPEGR_TF_PQ) {
metadata.hdr10Metadata.st2086Metadata = kSt2086Metadata;
}
jpegr_uncompressed_struct uncompressed_yuv_420_image;
JPEGR_CHECK(toneMap(uncompressed_p010_image, &uncompressed_yuv_420_image));
jpegr_uncompressed_struct map;
JPEGR_CHECK(generateRecoveryMap(
&uncompressed_yuv_420_image, uncompressed_p010_image, &metadata, &map));
std::unique_ptr<uint8_t[]> map_data;
map_data.reset(reinterpret_cast<uint8_t*>(map.data));
jpegr_compressed_struct compressed_map;
compressed_map.maxLength = map.width * map.height;
unique_ptr<uint8_t[]> compressed_map_data = make_unique<uint8_t[]>(compressed_map.maxLength);
compressed_map.data = compressed_map_data.get();
JPEGR_CHECK(compressRecoveryMap(&map, &compressed_map));
JpegEncoder jpeg_encoder;
// TODO: determine ICC data based on color gamut information
if (!jpeg_encoder.compressImage(uncompressed_yuv_420_image.data,
uncompressed_yuv_420_image.width,
uncompressed_yuv_420_image.height, quality, nullptr, 0)) {
return ERROR_JPEGR_ENCODE_ERROR;
}
jpegr_compressed_struct jpeg;
jpeg.data = jpeg_encoder.getCompressedImagePtr();
jpeg.length = jpeg_encoder.getCompressedImageSize();
JPEGR_CHECK(appendRecoveryMap(&jpeg, &compressed_map, &metadata, dest));
return NO_ERROR;
}
/* Encode API-1 */
status_t RecoveryMap::encodeJPEGR(jr_uncompressed_ptr uncompressed_p010_image,
jr_uncompressed_ptr uncompressed_yuv_420_image,
jpegr_transfer_function hdr_tf,
jr_compressed_ptr dest,
int quality,
jr_exif_ptr /* exif */) {
if (uncompressed_p010_image == nullptr
|| uncompressed_yuv_420_image == nullptr
|| dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
if (quality < 0 || quality > 100) {
return ERROR_JPEGR_INVALID_INPUT_TYPE;
}
if (uncompressed_p010_image->width != uncompressed_yuv_420_image->width
|| uncompressed_p010_image->height != uncompressed_yuv_420_image->height) {
return ERROR_JPEGR_RESOLUTION_MISMATCH;
}
jpegr_metadata metadata;
metadata.version = kJpegrVersion;
metadata.transferFunction = hdr_tf;
if (hdr_tf == JPEGR_TF_PQ) {
metadata.hdr10Metadata.st2086Metadata = kSt2086Metadata;
}
jpegr_uncompressed_struct map;
JPEGR_CHECK(generateRecoveryMap(
uncompressed_yuv_420_image, uncompressed_p010_image, &metadata, &map));
std::unique_ptr<uint8_t[]> map_data;
map_data.reset(reinterpret_cast<uint8_t*>(map.data));
jpegr_compressed_struct compressed_map;
compressed_map.maxLength = map.width * map.height;
unique_ptr<uint8_t[]> compressed_map_data = make_unique<uint8_t[]>(compressed_map.maxLength);
compressed_map.data = compressed_map_data.get();
JPEGR_CHECK(compressRecoveryMap(&map, &compressed_map));
JpegEncoder jpeg_encoder;
// TODO: determine ICC data based on color gamut information
if (!jpeg_encoder.compressImage(uncompressed_yuv_420_image->data,
uncompressed_yuv_420_image->width,
uncompressed_yuv_420_image->height, quality, nullptr, 0)) {
return ERROR_JPEGR_ENCODE_ERROR;
}
jpegr_compressed_struct jpeg;
jpeg.data = jpeg_encoder.getCompressedImagePtr();
jpeg.length = jpeg_encoder.getCompressedImageSize();
JPEGR_CHECK(appendRecoveryMap(&jpeg, &compressed_map, &metadata, dest));
return NO_ERROR;
}
/* Encode API-2 */
status_t RecoveryMap::encodeJPEGR(jr_uncompressed_ptr uncompressed_p010_image,
jr_uncompressed_ptr uncompressed_yuv_420_image,
jr_compressed_ptr compressed_jpeg_image,
jpegr_transfer_function hdr_tf,
jr_compressed_ptr dest) {
if (uncompressed_p010_image == nullptr
|| uncompressed_yuv_420_image == nullptr
|| compressed_jpeg_image == nullptr
|| dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
if (uncompressed_p010_image->width != uncompressed_yuv_420_image->width
|| uncompressed_p010_image->height != uncompressed_yuv_420_image->height) {
return ERROR_JPEGR_RESOLUTION_MISMATCH;
}
jpegr_metadata metadata;
metadata.version = kJpegrVersion;
metadata.transferFunction = hdr_tf;
if (hdr_tf == JPEGR_TF_PQ) {
metadata.hdr10Metadata.st2086Metadata = kSt2086Metadata;
}
jpegr_uncompressed_struct map;
JPEGR_CHECK(generateRecoveryMap(
uncompressed_yuv_420_image, uncompressed_p010_image, &metadata, &map));
std::unique_ptr<uint8_t[]> map_data;
map_data.reset(reinterpret_cast<uint8_t*>(map.data));
jpegr_compressed_struct compressed_map;
compressed_map.maxLength = map.width * map.height;
unique_ptr<uint8_t[]> compressed_map_data = make_unique<uint8_t[]>(compressed_map.maxLength);
compressed_map.data = compressed_map_data.get();
JPEGR_CHECK(compressRecoveryMap(&map, &compressed_map));
JPEGR_CHECK(appendRecoveryMap(compressed_jpeg_image, &compressed_map, &metadata, dest));
return NO_ERROR;
}
/* Encode API-3 */
status_t RecoveryMap::encodeJPEGR(jr_uncompressed_ptr uncompressed_p010_image,
jr_compressed_ptr compressed_jpeg_image,
jpegr_transfer_function hdr_tf,
jr_compressed_ptr dest) {
if (uncompressed_p010_image == nullptr
|| compressed_jpeg_image == nullptr
|| dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
JpegDecoder jpeg_decoder;
if (!jpeg_decoder.decompressImage(compressed_jpeg_image->data, compressed_jpeg_image->length)) {
return ERROR_JPEGR_DECODE_ERROR;
}
jpegr_uncompressed_struct uncompressed_yuv_420_image;
uncompressed_yuv_420_image.data = jpeg_decoder.getDecompressedImagePtr();
uncompressed_yuv_420_image.width = jpeg_decoder.getDecompressedImageWidth();
uncompressed_yuv_420_image.height = jpeg_decoder.getDecompressedImageHeight();
uncompressed_yuv_420_image.colorGamut = compressed_jpeg_image->colorGamut;
if (uncompressed_p010_image->width != uncompressed_yuv_420_image.width
|| uncompressed_p010_image->height != uncompressed_yuv_420_image.height) {
return ERROR_JPEGR_RESOLUTION_MISMATCH;
}
jpegr_metadata metadata;
metadata.version = kJpegrVersion;
metadata.transferFunction = hdr_tf;
if (hdr_tf == JPEGR_TF_PQ) {
metadata.hdr10Metadata.st2086Metadata = kSt2086Metadata;
}
jpegr_uncompressed_struct map;
JPEGR_CHECK(generateRecoveryMap(
&uncompressed_yuv_420_image, uncompressed_p010_image, &metadata, &map));
std::unique_ptr<uint8_t[]> map_data;
map_data.reset(reinterpret_cast<uint8_t*>(map.data));
jpegr_compressed_struct compressed_map;
compressed_map.maxLength = map.width * map.height;
unique_ptr<uint8_t[]> compressed_map_data = make_unique<uint8_t[]>(compressed_map.maxLength);
compressed_map.data = compressed_map_data.get();
JPEGR_CHECK(compressRecoveryMap(&map, &compressed_map));
JPEGR_CHECK(appendRecoveryMap(compressed_jpeg_image, &compressed_map, &metadata, dest));
return NO_ERROR;
}
status_t RecoveryMap::getJPEGRInfo(jr_compressed_ptr compressed_jpegr_image,
jr_info_ptr jpegr_info) {
if (compressed_jpegr_image == nullptr || jpegr_info == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
jpegr_compressed_struct primary_image, recovery_map;
JPEGR_CHECK(extractPrimaryImageAndRecoveryMap(compressed_jpegr_image,
&primary_image, &recovery_map));
JpegDecoder jpeg_decoder;
if (!jpeg_decoder.getCompressedImageParameters(primary_image.data, primary_image.length,
&jpegr_info->width, &jpegr_info->height,
jpegr_info->iccData, jpegr_info->exifData)) {
return ERROR_JPEGR_DECODE_ERROR;
}
return NO_ERROR;
}
/* Decode API */
status_t RecoveryMap::decodeJPEGR(jr_compressed_ptr compressed_jpegr_image,
jr_uncompressed_ptr dest,
jr_exif_ptr exif,
bool request_sdr) {
if (compressed_jpegr_image == nullptr || dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
// TODO: fill EXIF data
(void) exif;
jpegr_compressed_struct compressed_map;
jpegr_metadata metadata;
JPEGR_CHECK(extractRecoveryMap(compressed_jpegr_image, &compressed_map));
jpegr_uncompressed_struct map;
JPEGR_CHECK(decompressRecoveryMap(&compressed_map, &map));
JpegDecoder jpeg_decoder;
if (!jpeg_decoder.decompressImage(compressed_jpegr_image->data, compressed_jpegr_image->length)) {
return ERROR_JPEGR_DECODE_ERROR;
}
jpegr_uncompressed_struct uncompressed_yuv_420_image;
uncompressed_yuv_420_image.data = jpeg_decoder.getDecompressedImagePtr();
uncompressed_yuv_420_image.width = jpeg_decoder.getDecompressedImageWidth();
uncompressed_yuv_420_image.height = jpeg_decoder.getDecompressedImageHeight();
if (!getMetadataFromXMP(static_cast<uint8_t*>(jpeg_decoder.getXMPPtr()),
jpeg_decoder.getXMPSize(), &metadata)) {
return ERROR_JPEGR_DECODE_ERROR;
}
if (request_sdr) {
memcpy(dest->data, uncompressed_yuv_420_image.data,
uncompressed_yuv_420_image.width*uncompressed_yuv_420_image.height *3 / 2);
dest->width = uncompressed_yuv_420_image.width;
dest->height = uncompressed_yuv_420_image.height;
} else {
JPEGR_CHECK(applyRecoveryMap(&uncompressed_yuv_420_image, &map, &metadata, dest));
}
return NO_ERROR;
}
status_t RecoveryMap::decompressRecoveryMap(jr_compressed_ptr compressed_recovery_map,
jr_uncompressed_ptr dest) {
if (compressed_recovery_map == nullptr || dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
JpegDecoder jpeg_decoder;
if (!jpeg_decoder.decompressImage(compressed_recovery_map->data,
compressed_recovery_map->length)) {
return ERROR_JPEGR_DECODE_ERROR;
}
dest->data = jpeg_decoder.getDecompressedImagePtr();
dest->width = jpeg_decoder.getDecompressedImageWidth();
dest->height = jpeg_decoder.getDecompressedImageHeight();
return NO_ERROR;
}
status_t RecoveryMap::compressRecoveryMap(jr_uncompressed_ptr uncompressed_recovery_map,
jr_compressed_ptr dest) {
if (uncompressed_recovery_map == nullptr || dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
// TODO: should we have ICC data for the map?
JpegEncoder jpeg_encoder;
if (!jpeg_encoder.compressImage(uncompressed_recovery_map->data,
uncompressed_recovery_map->width,
uncompressed_recovery_map->height,
kMapCompressQuality,
nullptr,
0,
true /* isSingleChannel */)) {
return ERROR_JPEGR_ENCODE_ERROR;
}
if (dest->maxLength < jpeg_encoder.getCompressedImageSize()) {
return ERROR_JPEGR_BUFFER_TOO_SMALL;
}
memcpy(dest->data, jpeg_encoder.getCompressedImagePtr(), jpeg_encoder.getCompressedImageSize());
dest->length = jpeg_encoder.getCompressedImageSize();
dest->colorGamut = JPEGR_COLORGAMUT_UNSPECIFIED;
return NO_ERROR;
}
status_t RecoveryMap::generateRecoveryMap(jr_uncompressed_ptr uncompressed_yuv_420_image,
jr_uncompressed_ptr uncompressed_p010_image,
jr_metadata_ptr metadata,
jr_uncompressed_ptr dest) {
if (uncompressed_yuv_420_image == nullptr
|| uncompressed_p010_image == nullptr
|| metadata == nullptr
|| dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
if (uncompressed_yuv_420_image->width != uncompressed_p010_image->width
|| uncompressed_yuv_420_image->height != uncompressed_p010_image->height) {
return ERROR_JPEGR_RESOLUTION_MISMATCH;
}
if (uncompressed_yuv_420_image->colorGamut == JPEGR_COLORGAMUT_UNSPECIFIED
|| uncompressed_p010_image->colorGamut == JPEGR_COLORGAMUT_UNSPECIFIED) {
return ERROR_JPEGR_INVALID_COLORGAMUT;
}
size_t image_width = uncompressed_yuv_420_image->width;
size_t image_height = uncompressed_yuv_420_image->height;
size_t map_width = image_width / kMapDimensionScaleFactor;
size_t map_height = image_height / kMapDimensionScaleFactor;
dest->width = map_width;
dest->height = map_height;
dest->colorGamut = JPEGR_COLORGAMUT_UNSPECIFIED;
dest->data = new uint8_t[map_width * map_height];
std::unique_ptr<uint8_t[]> map_data;
map_data.reset(reinterpret_cast<uint8_t*>(dest->data));
ColorTransformFn hdrInvOetf = nullptr;
switch (metadata->transferFunction) {
case JPEGR_TF_HLG:
hdrInvOetf = hlgInvOetf;
break;
case JPEGR_TF_PQ:
hdrInvOetf = pqInvOetf;
break;
}
ColorTransformFn hdrGamutConversionFn = getHdrConversionFn(
uncompressed_yuv_420_image->colorGamut, uncompressed_p010_image->colorGamut);
ColorCalculationFn luminanceFn = nullptr;
switch (uncompressed_yuv_420_image->colorGamut) {
case JPEGR_COLORGAMUT_BT709:
luminanceFn = srgbLuminance;
break;
case JPEGR_COLORGAMUT_P3:
luminanceFn = p3Luminance;
break;
case JPEGR_COLORGAMUT_BT2100:
luminanceFn = bt2100Luminance;
break;
case JPEGR_COLORGAMUT_UNSPECIFIED:
// Should be impossible to hit after input validation.
return ERROR_JPEGR_INVALID_COLORGAMUT;
}
float hdr_y_nits_max = 0.0f;
double hdr_y_nits_avg = 0.0f;
for (size_t y = 0; y < image_height; ++y) {
for (size_t x = 0; x < image_width; ++x) {
Color hdr_yuv_gamma = getP010Pixel(uncompressed_p010_image, x, y);
Color hdr_rgb_gamma = bt2100YuvToRgb(hdr_yuv_gamma);
Color hdr_rgb = hdrInvOetf(hdr_rgb_gamma);
hdr_rgb = hdrGamutConversionFn(hdr_rgb);
float hdr_y_nits = luminanceFn(hdr_rgb);
hdr_y_nits_avg += hdr_y_nits;
if (hdr_y_nits > hdr_y_nits_max) {
hdr_y_nits_max = hdr_y_nits;
}
}
}
hdr_y_nits_avg /= image_width * image_height;
metadata->rangeScalingFactor = hdr_y_nits_max / kSdrWhiteNits;
if (metadata->transferFunction == JPEGR_TF_PQ) {
metadata->hdr10Metadata.maxFALL = hdr_y_nits_avg;
metadata->hdr10Metadata.maxCLL = hdr_y_nits_max;
}
for (size_t y = 0; y < map_height; ++y) {
for (size_t x = 0; x < map_width; ++x) {
Color sdr_yuv_gamma = sampleYuv420(uncompressed_yuv_420_image,
kMapDimensionScaleFactor, x, y);
Color sdr_rgb_gamma = srgbYuvToRgb(sdr_yuv_gamma);
Color sdr_rgb = srgbInvOetf(sdr_rgb_gamma);
float sdr_y_nits = luminanceFn(sdr_rgb);
Color hdr_yuv_gamma = sampleP010(uncompressed_p010_image, kMapDimensionScaleFactor, x, y);
Color hdr_rgb_gamma = bt2100YuvToRgb(hdr_yuv_gamma);
Color hdr_rgb = hdrInvOetf(hdr_rgb_gamma);
hdr_rgb = hdrGamutConversionFn(hdr_rgb);
float hdr_y_nits = luminanceFn(hdr_rgb);
size_t pixel_idx = x + y * map_width;
reinterpret_cast<uint8_t*>(dest->data)[pixel_idx] =
encodeRecovery(sdr_y_nits, hdr_y_nits, metadata->rangeScalingFactor);
}
}
map_data.release();
return NO_ERROR;
}
status_t RecoveryMap::applyRecoveryMap(jr_uncompressed_ptr uncompressed_yuv_420_image,
jr_uncompressed_ptr uncompressed_recovery_map,
jr_metadata_ptr metadata,
jr_uncompressed_ptr dest) {
if (uncompressed_yuv_420_image == nullptr
|| uncompressed_recovery_map == nullptr
|| metadata == nullptr
|| dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
size_t width = uncompressed_yuv_420_image->width;
size_t height = uncompressed_yuv_420_image->height;
dest->width = width;
dest->height = height;
size_t pixel_count = width * height;
ColorTransformFn hdrOetf = nullptr;
switch (metadata->transferFunction) {
case JPEGR_TF_HLG:
hdrOetf = hlgOetf;
break;
case JPEGR_TF_PQ:
hdrOetf = pqOetf;
break;
}
for (size_t y = 0; y < height; ++y) {
for (size_t x = 0; x < width; ++x) {
Color yuv_gamma_sdr = getYuv420Pixel(uncompressed_yuv_420_image, x, y);
Color rgb_gamma_sdr = srgbYuvToRgb(yuv_gamma_sdr);
Color rgb_sdr = srgbInvOetf(rgb_gamma_sdr);
// TODO: determine map scaling factor based on actual map dims
float recovery = sampleMap(uncompressed_recovery_map, kMapDimensionScaleFactor, x, y);
Color rgb_hdr = applyRecovery(rgb_sdr, recovery, metadata->rangeScalingFactor);
Color rgb_gamma_hdr = hdrOetf(rgb_hdr);
uint32_t rgba1010102 = colorToRgba1010102(rgb_gamma_hdr);
size_t pixel_idx = x + y * width;
reinterpret_cast<uint32_t*>(dest->data)[pixel_idx] = rgba1010102;
}
}
return NO_ERROR;
}
status_t RecoveryMap::extractPrimaryImageAndRecoveryMap(jr_compressed_ptr compressed_jpegr_image,
jr_compressed_ptr primary_image,
jr_compressed_ptr recovery_map) {
if (compressed_jpegr_image == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
MessageHandler msg_handler;
std::shared_ptr<DataSegment> seg =
DataSegment::Create(DataRange(0, compressed_jpegr_image->length),
static_cast<const uint8_t*>(compressed_jpegr_image->data),
DataSegment::BufferDispositionPolicy::kDontDelete);
DataSegmentDataSource data_source(seg);
JpegInfoBuilder jpeg_info_builder;
jpeg_info_builder.SetImageLimit(2);
JpegScanner jpeg_scanner(&msg_handler);
jpeg_scanner.Run(&data_source, &jpeg_info_builder);
data_source.Reset();
if (jpeg_scanner.HasError()) {
return ERROR_JPEGR_INVALID_INPUT_TYPE;
}
const auto& jpeg_info = jpeg_info_builder.GetInfo();
const auto& image_ranges = jpeg_info.GetImageRanges();
if (image_ranges.empty()) {
return ERROR_JPEGR_INVALID_INPUT_TYPE;
}
if (image_ranges.size() != 2) {
// Must be 2 JPEG Images
return ERROR_JPEGR_INVALID_INPUT_TYPE;
}
if (primary_image != nullptr) {
primary_image->data = static_cast<uint8_t*>(compressed_jpegr_image->data) +
image_ranges[0].GetBegin();
primary_image->length = image_ranges[0].GetLength();
}
if (recovery_map != nullptr) {
recovery_map->data = static_cast<uint8_t*>(compressed_jpegr_image->data) +
image_ranges[1].GetBegin();
recovery_map->length = image_ranges[1].GetLength();
}
return NO_ERROR;
}
status_t RecoveryMap::extractRecoveryMap(jr_compressed_ptr compressed_jpegr_image,
jr_compressed_ptr dest) {
if (compressed_jpegr_image == nullptr || dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
return extractPrimaryImageAndRecoveryMap(compressed_jpegr_image, nullptr, dest);
}
status_t RecoveryMap::appendRecoveryMap(jr_compressed_ptr compressed_jpeg_image,
jr_compressed_ptr compressed_recovery_map,
jr_metadata_ptr metadata,
jr_compressed_ptr dest) {
if (compressed_jpeg_image == nullptr
|| compressed_recovery_map == nullptr
|| metadata == nullptr
|| dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
const string xmp = generateXmp(compressed_recovery_map->length, *metadata);
const string nameSpace = "http://ns.adobe.com/xap/1.0/\0";
const int nameSpaceLength = nameSpace.size() + 1; // need to count the null terminator
// 2 bytes: APP1 sign (ff e1)
// 29 bytes: length of name space "http://ns.adobe.com/xap/1.0/\0",
// x bytes: length of xmp packet
const int length = 3 + nameSpaceLength + xmp.size();
const uint8_t lengthH = ((length >> 8) & 0xff);
const uint8_t lengthL = (length & 0xff);
int pos = 0;
// JPEG/R structure:
// SOI (ff d8)
// APP1 (ff e1)
// 2 bytes of length (2 + 29 + length of xmp packet)
// name space ("http://ns.adobe.com/xap/1.0/\0")
// xmp
// primary image (without the first two bytes, the SOI sign)
// secondary image (the recovery map)
JPEGR_CHECK(Write(dest, &photos_editing_formats::image_io::JpegMarker::kStart, 1, pos));
JPEGR_CHECK(Write(dest, &photos_editing_formats::image_io::JpegMarker::kSOI, 1, pos));
JPEGR_CHECK(Write(dest, &photos_editing_formats::image_io::JpegMarker::kStart, 1, pos));
JPEGR_CHECK(Write(dest, &photos_editing_formats::image_io::JpegMarker::kAPP1, 1, pos));
JPEGR_CHECK(Write(dest, &lengthH, 1, pos));
JPEGR_CHECK(Write(dest, &lengthL, 1, pos));
JPEGR_CHECK(Write(dest, (void*)nameSpace.c_str(), nameSpaceLength, pos));
JPEGR_CHECK(Write(dest, (void*)xmp.c_str(), xmp.size(), pos));
JPEGR_CHECK(Write(dest,
(uint8_t*)compressed_jpeg_image->data + 2, compressed_jpeg_image->length - 2, pos));
JPEGR_CHECK(Write(dest, compressed_recovery_map->data, compressed_recovery_map->length, pos));
dest->length = pos;
return NO_ERROR;
}
string RecoveryMap::generateXmp(int secondary_image_length, jpegr_metadata& metadata) {
const string kContainerPrefix = "GContainer";
const string kContainerUri = "http://ns.google.com/photos/1.0/container/";
const string kItemPrefix = "Item";
const string kRecoveryMap = "RecoveryMap";
const string kDirectory = "Directory";
const string kImageJpeg = "image/jpeg";
const string kItem = "Item";
const string kLength = "Length";
const string kMime = "Mime";
const string kPrimary = "Primary";
const string kSemantic = "Semantic";
const string kVersion = "Version";
const string kConDir = Name(kContainerPrefix, kDirectory);
const string kContainerItem = Name(kContainerPrefix, kItem);
const string kItemLength = Name(kItemPrefix, kLength);
const string kItemMime = Name(kItemPrefix, kMime);
const string kItemSemantic = Name(kItemPrefix, kSemantic);
const vector<string> kConDirSeq({kConDir, string("rdf:Seq")});
const vector<string> kLiItem({string("rdf:li"), kContainerItem});
std::stringstream ss;
photos_editing_formats::image_io::XmlWriter writer(ss);
writer.StartWritingElement("x:xmpmeta");
writer.WriteXmlns("x", "adobe:ns:meta/");
writer.WriteAttributeNameAndValue("x:xmptk", "Adobe XMP Core 5.1.2");
writer.StartWritingElement("rdf:RDF");
writer.WriteXmlns("rdf", "http://www.w3.org/1999/02/22-rdf-syntax-ns#");
writer.StartWritingElement("rdf:Description");
writer.WriteXmlns(kContainerPrefix, kContainerUri);
writer.WriteElementAndContent(Name(kContainerPrefix, kVersion), metadata.version);
writer.WriteElementAndContent(Name(kContainerPrefix, "rangeScalingFactor"),
metadata.rangeScalingFactor);
// TODO: determine structure for hdr10 metadata
// TODO: write rest of metadata
writer.StartWritingElements(kConDirSeq);
size_t item_depth = writer.StartWritingElements(kLiItem);
writer.WriteAttributeNameAndValue(kItemSemantic, kPrimary);
writer.WriteAttributeNameAndValue(kItemMime, kImageJpeg);
writer.FinishWritingElementsToDepth(item_depth);
writer.StartWritingElements(kLiItem);
writer.WriteAttributeNameAndValue(kItemSemantic, kRecoveryMap);
writer.WriteAttributeNameAndValue(kItemMime, kImageJpeg);
writer.WriteAttributeNameAndValue(kItemLength, secondary_image_length);
writer.FinishWriting();
return ss.str();
}
status_t RecoveryMap::toneMap(jr_uncompressed_ptr uncompressed_p010_image,
jr_uncompressed_ptr dest) {
if (uncompressed_p010_image == nullptr || dest == nullptr) {
return ERROR_JPEGR_INVALID_NULL_PTR;
}
dest->width = uncompressed_p010_image->width;
dest->height = uncompressed_p010_image->height;
unique_ptr<uint8_t[]> dest_data = make_unique<uint8_t[]>(dest->width * dest->height * 3 / 2);
dest->data = dest_data.get();
// TODO: Tone map algorighm here.
return NO_ERROR;
}
} // namespace android::recoverymap