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aomedia / libavif / refs/tags/v0.5.6 / . / src / read.c
blob: 5bbd6bfec16b5a2a741f79b049882bbdc0ccb290 [file] [log] [blame]
// Copyright 2019 Joe Drago. All rights reserved.
// SPDX-License-Identifier: BSD-2-Clause
#include "avif/internal.h"
#include <string.h>
// from the MIAF spec:
// ---
// Section 6.7
// "α is an alpha plane value, scaled into the range of 0 (fully transparent) to 1 (fully opaque), inclusive"
// ---
// Section 7.3.5.2
// "the sample values of the alpha plane divided by the maximum value (e.g. by 255 for 8-bit sample
// values) provides the multiplier to be used to obtain the intensity for the associated master image"
// ---
// The define AVIF_FIX_STUDIO_ALPHA detects when the alpha OBU is incorrectly using studio range
// and corrects it before returning the alpha pixels to the caller.
#define AVIF_FIX_STUDIO_ALPHA
#define AUXTYPE_SIZE 64
#define CONTENTTYPE_SIZE 64
#define MAX_COMPATIBLE_BRANDS 32
// class VisualSampleEntry(codingname) extends SampleEntry(codingname) {
// unsigned int(16) pre_defined = 0;
// const unsigned int(16) reserved = 0;
// unsigned int(32)[3] pre_defined = 0;
// unsigned int(16) width;
// unsigned int(16) height;
// template unsigned int(32) horizresolution = 0x00480000; // 72 dpi
// template unsigned int(32) vertresolution = 0x00480000; // 72 dpi
// const unsigned int(32) reserved = 0;
// template unsigned int(16) frame_count = 1;
// string[32] compressorname;
// template unsigned int(16) depth = 0x0018;
// int(16) pre_defined = -1;
// // other boxes from derived specifications
// CleanApertureBox clap; // optional
// PixelAspectRatioBox pasp; // optional
// }
static const size_t VISUALSAMPLEENTRY_SIZE = 78;
static const char xmpContentType[] = CONTENT_TYPE_XMP;
static const size_t xmpContentTypeSize = sizeof(xmpContentType);
// ---------------------------------------------------------------------------
// Box data structures
// ftyp
typedef struct avifFileType
{
uint8_t majorBrand[4];
uint32_t minorVersion;
uint8_t compatibleBrands[4 * MAX_COMPATIBLE_BRANDS];
int compatibleBrandsCount;
} avifFileType;
// ispe
typedef struct avifImageSpatialExtents
{
uint32_t width;
uint32_t height;
} avifImageSpatialExtents;
// auxC
typedef struct avifAuxiliaryType
{
char auxType[AUXTYPE_SIZE];
} avifAuxiliaryType;
// infe mime content_type
typedef struct avifContentType
{
char contentType[CONTENTTYPE_SIZE];
} avifContentType;
// colr
typedef struct avifColourInformationBox
{
avifProfileFormat format;
const uint8_t * icc;
size_t iccSize;
avifNclxColorProfile nclx;
} avifColourInformationBox;
// ---------------------------------------------------------------------------
// Top-level structures
// one "item" worth (all iref, iloc, iprp, etc refer to one of these)
typedef struct avifItem
{
uint32_t id;
uint8_t type[4];
uint32_t offset;
uint32_t size;
uint32_t idatID; // If non-zero, offset is relative to this idat box (iloc construction_method==1)
avifBool ispePresent;
avifImageSpatialExtents ispe;
avifBool auxCPresent;
avifAuxiliaryType auxC;
avifContentType contentType;
avifBool colrPresent;
avifColourInformationBox colr;
avifBool av1CPresent;
avifCodecConfigurationBox av1C;
uint32_t thumbnailForID; // if non-zero, this item is a thumbnail for Item #{thumbnailForID}
uint32_t auxForID; // if non-zero, this item is an auxC plane for Item #{auxForID}
uint32_t descForID; // if non-zero, this item is a content description for Item #{descForID}
} avifItem;
AVIF_ARRAY_DECLARE(avifItemArray, avifItem, item);
// Temporary storage for ipco contents until they can be associated and memcpy'd to an avifItem
typedef struct avifProperty
{
uint8_t type[4];
avifImageSpatialExtents ispe;
avifAuxiliaryType auxC;
avifColourInformationBox colr;
avifCodecConfigurationBox av1C;
} avifProperty;
AVIF_ARRAY_DECLARE(avifPropertyArray, avifProperty, prop);
// idat storage
typedef struct avifItemData
{
uint32_t id;
avifROData data;
} avifItemData;
AVIF_ARRAY_DECLARE(avifItemDataArray, avifItemData, idat);
// ---------------------------------------------------------------------------
// avifTrack
typedef struct avifSampleTableChunk
{
uint64_t offset;
} avifSampleTableChunk;
AVIF_ARRAY_DECLARE(avifSampleTableChunkArray, avifSampleTableChunk, chunk);
typedef struct avifSampleTableSampleToChunk
{
uint32_t firstChunk;
uint32_t samplesPerChunk;
uint32_t sampleDescriptionIndex;
} avifSampleTableSampleToChunk;
AVIF_ARRAY_DECLARE(avifSampleTableSampleToChunkArray, avifSampleTableSampleToChunk, sampleToChunk);
typedef struct avifSampleTableSampleSize
{
uint32_t size;
} avifSampleTableSampleSize;
AVIF_ARRAY_DECLARE(avifSampleTableSampleSizeArray, avifSampleTableSampleSize, sampleSize);
typedef struct avifSampleTableTimeToSample
{
uint32_t sampleCount;
uint32_t sampleDelta;
} avifSampleTableTimeToSample;
AVIF_ARRAY_DECLARE(avifSampleTableTimeToSampleArray, avifSampleTableTimeToSample, timeToSample);
typedef struct avifSyncSample
{
uint32_t sampleNumber;
} avifSyncSample;
AVIF_ARRAY_DECLARE(avifSyncSampleArray, avifSyncSample, syncSample);
typedef struct avifSampleDescription
{
uint8_t format[4];
avifBool av1CPresent;
avifCodecConfigurationBox av1C;
} avifSampleDescription;
AVIF_ARRAY_DECLARE(avifSampleDescriptionArray, avifSampleDescription, description);
typedef struct avifSampleTable
{
avifSampleTableChunkArray chunks;
avifSampleDescriptionArray sampleDescriptions;
avifSampleTableSampleToChunkArray sampleToChunks;
avifSampleTableSampleSizeArray sampleSizes;
avifSampleTableTimeToSampleArray timeToSamples;
avifSyncSampleArray syncSamples;
uint32_t allSamplesSize; // If this is non-zero, sampleSizes will be empty and all samples will be this size
} avifSampleTable;
static avifSampleTable * avifSampleTableCreate()
{
avifSampleTable * sampleTable = (avifSampleTable *)avifAlloc(sizeof(avifSampleTable));
memset(sampleTable, 0, sizeof(avifSampleTable));
avifArrayCreate(&sampleTable->chunks, sizeof(avifSampleTableChunk), 16);
avifArrayCreate(&sampleTable->sampleDescriptions, sizeof(avifSampleDescription), 2);
avifArrayCreate(&sampleTable->sampleToChunks, sizeof(avifSampleTableSampleToChunk), 16);
avifArrayCreate(&sampleTable->sampleSizes, sizeof(avifSampleTableSampleSize), 16);
avifArrayCreate(&sampleTable->timeToSamples, sizeof(avifSampleTableTimeToSample), 16);
avifArrayCreate(&sampleTable->syncSamples, sizeof(avifSyncSample), 16);
return sampleTable;
}
static void avifSampleTableDestroy(avifSampleTable * sampleTable)
{
avifArrayDestroy(&sampleTable->chunks);
avifArrayDestroy(&sampleTable->sampleDescriptions);
avifArrayDestroy(&sampleTable->sampleToChunks);
avifArrayDestroy(&sampleTable->sampleSizes);
avifArrayDestroy(&sampleTable->timeToSamples);
avifArrayDestroy(&sampleTable->syncSamples);
avifFree(sampleTable);
}
static uint32_t avifSampleTableGetImageDelta(avifSampleTable * sampleTable, int imageIndex)
{
int maxSampleIndex = 0;
for (uint32_t i = 0; i < sampleTable->timeToSamples.count; ++i) {
avifSampleTableTimeToSample * timeToSample = &sampleTable->timeToSamples.timeToSample[i];
maxSampleIndex += timeToSample->sampleCount;
if ((imageIndex < maxSampleIndex) || (i == (sampleTable->timeToSamples.count - 1))) {
return timeToSample->sampleDelta;
}
}
// TODO: fail here?
return 1;
}
static avifBool avifSampleTableHasFormat(avifSampleTable * sampleTable, const char * format)
{
for (uint32_t i = 0; i < sampleTable->sampleDescriptions.count; ++i) {
if (!memcmp(sampleTable->sampleDescriptions.description[i].format, format, 4)) {
return AVIF_TRUE;
}
}
return AVIF_FALSE;
}
static uint32_t avifCodecConfigurationBoxGetDepth(avifCodecConfigurationBox * av1C)
{
if (av1C->twelveBit) {
return 12;
} else if (av1C->highBitdepth) {
return 10;
}
return 8;
}
static uint32_t avifSampleTableGetDepth(avifSampleTable * sampleTable)
{
for (uint32_t i = 0; i < sampleTable->sampleDescriptions.count; ++i) {
avifSampleDescription * description = &sampleTable->sampleDescriptions.description[i];
if (!memcmp(description->format, "av01", 4) && description->av1CPresent) {
return avifCodecConfigurationBoxGetDepth(&description->av1C);
}
}
return 0;
}
// one video track ("trak" contents)
typedef struct avifTrack
{
uint32_t id;
uint32_t auxForID; // if non-zero, this item is an auxC plane for Track #{auxForID}
uint32_t mediaTimescale;
uint64_t mediaDuration;
uint32_t width;
uint32_t height;
avifSampleTable * sampleTable;
} avifTrack;
AVIF_ARRAY_DECLARE(avifTrackArray, avifTrack, track);
// ---------------------------------------------------------------------------
// avifCodecDecodeInput
avifCodecDecodeInput * avifCodecDecodeInputCreate(void)
{
avifCodecDecodeInput * decodeInput = (avifCodecDecodeInput *)avifAlloc(sizeof(avifCodecDecodeInput));
memset(decodeInput, 0, sizeof(avifCodecDecodeInput));
avifArrayCreate(&decodeInput->samples, sizeof(avifSample), 1);
return decodeInput;
}
void avifCodecDecodeInputDestroy(avifCodecDecodeInput * decodeInput)
{
avifArrayDestroy(&decodeInput->samples);
avifFree(decodeInput);
}
static avifBool avifCodecDecodeInputGetSamples(avifCodecDecodeInput * decodeInput, avifSampleTable * sampleTable, avifROData * rawInput)
{
uint32_t sampleSizeIndex = 0;
for (uint32_t chunkIndex = 0; chunkIndex < sampleTable->chunks.count; ++chunkIndex) {
avifSampleTableChunk * chunk = &sampleTable->chunks.chunk[chunkIndex];
// First, figure out how many samples are in this chunk
uint32_t sampleCount = 0;
for (int sampleToChunkIndex = sampleTable->sampleToChunks.count - 1; sampleToChunkIndex >= 0; --sampleToChunkIndex) {
avifSampleTableSampleToChunk * sampleToChunk = &sampleTable->sampleToChunks.sampleToChunk[sampleToChunkIndex];
if (sampleToChunk->firstChunk <= (chunkIndex + 1)) {
sampleCount = sampleToChunk->samplesPerChunk;
break;
}
}
if (sampleCount == 0) {
// chunks with 0 samples are invalid
return AVIF_FALSE;
}
uint64_t sampleOffset = chunk->offset;
for (uint32_t sampleIndex = 0; sampleIndex < sampleCount; ++sampleIndex) {
uint32_t sampleSize = sampleTable->allSamplesSize;
if (sampleSize == 0) {
if (sampleSizeIndex >= sampleTable->sampleSizes.count) {
// We've run out of samples to sum
return AVIF_FALSE;
}
avifSampleTableSampleSize * sampleSizePtr = &sampleTable->sampleSizes.sampleSize[sampleSizeIndex];
sampleSize = sampleSizePtr->size;
}
avifSample * sample = (avifSample *)avifArrayPushPtr(&decodeInput->samples);
sample->data.data = rawInput->data + sampleOffset;
sample->data.size = sampleSize;
sample->sync = AVIF_FALSE; // to potentially be set to true following the outer loop
if (sampleOffset > (uint64_t)rawInput->size) {
return AVIF_FALSE;
}
sampleOffset += sampleSize;
++sampleSizeIndex;
}
}
// Mark appropriate samples as sync
for (uint32_t syncSampleIndex = 0; syncSampleIndex < sampleTable->syncSamples.count; ++syncSampleIndex) {
uint32_t frameIndex = sampleTable->syncSamples.syncSample[syncSampleIndex].sampleNumber - 1; // sampleNumber is 1-based
if (frameIndex < decodeInput->samples.count) {
decodeInput->samples.sample[frameIndex].sync = AVIF_TRUE;
}
}
// Assume frame 0 is sync, just in case the stss box is absent in the BMFF. (Unnecessary?)
if (decodeInput->samples.count > 0) {
decodeInput->samples.sample[0].sync = AVIF_TRUE;
}
return AVIF_TRUE;
}
// ---------------------------------------------------------------------------
// avifData
typedef struct avifData
{
avifFileType ftyp;
avifItemArray items;
avifPropertyArray properties;
avifItemDataArray idats;
avifTrackArray tracks;
avifROData rawInput;
avifCodecDecodeInput * colorInput;
avifCodecDecodeInput * alphaInput;
avifDecoderSource source;
avifSampleTable * sourceSampleTable; // NULL unless (source == AVIF_DECODER_SOURCE_TRACKS), owned by an avifTrack
uint32_t primaryItemID;
uint32_t metaBoxID; // Ever-incrementing ID for tracking which 'meta' box contains an idat, and which idat an iloc might refer to
struct avifCodec * codec[AVIF_CODEC_PLANES_COUNT];
} avifData;
static avifData * avifDataCreate()
{
avifData * data = (avifData *)avifAlloc(sizeof(avifData));
memset(data, 0, sizeof(avifData));
avifArrayCreate(&data->items, sizeof(avifItem), 8);
avifArrayCreate(&data->properties, sizeof(avifProperty), 16);
avifArrayCreate(&data->idats, sizeof(avifItemData), 1);
avifArrayCreate(&data->tracks, sizeof(avifTrack), 2);
return data;
}
static void avifDataResetCodec(avifData * data)
{
for (int i = 0; i < AVIF_CODEC_PLANES_COUNT; ++i) {
if (data->codec[i]) {
avifCodecDestroy(data->codec[i]);
data->codec[i] = NULL;
}
}
}
static void avifDataDestroy(avifData * data)
{
avifDataResetCodec(data);
avifArrayDestroy(&data->items);
avifArrayDestroy(&data->properties);
avifArrayDestroy(&data->idats);
for (uint32_t i = 0; i < data->tracks.count; ++i) {
if (data->tracks.track[i].sampleTable) {
avifSampleTableDestroy(data->tracks.track[i].sampleTable);
}
}
avifArrayDestroy(&data->tracks);
if (data->colorInput) {
avifCodecDecodeInputDestroy(data->colorInput);
}
if (data->alphaInput) {
avifCodecDecodeInputDestroy(data->alphaInput);
}
avifFree(data);
}
static avifItem * avifDataFindItem(avifData * data, uint32_t itemID)
{
if (itemID == 0) {
return NULL;
}
for (uint32_t i = 0; i < data->items.count; ++i) {
if (data->items.item[i].id == itemID) {
return &data->items.item[i];
}
}
avifItem * item = (avifItem *)avifArrayPushPtr(&data->items);
item->id = itemID;
return item;
}
static const uint8_t * avifDataCalcItemPtr(avifData * data, avifItem * item)
{
avifROData * offsetBuffer = NULL;
if (item->idatID == 0) {
// construction_method: file(0)
offsetBuffer = &data->rawInput;
} else {
// construction_method: idat(1)
// Find associated idat block
for (uint32_t i = 0; i < data->idats.count; ++i) {
if (data->idats.idat[i].id == item->idatID) {
offsetBuffer = &data->idats.idat[i].data;
break;
}
}
if (offsetBuffer == NULL) {
// no idat box was found in this meta box, bail out
return NULL;
}
}
if (item->offset > offsetBuffer->size) {
return NULL;
}
uint64_t offsetSize = (uint64_t)item->offset + (uint64_t)item->size;
if (offsetSize > (uint64_t)offsetBuffer->size) {
return NULL;
}
return offsetBuffer->data + item->offset;
}
// ---------------------------------------------------------------------------
// URN
static avifBool isAlphaURN(char * urn)
{
if (!strcmp(urn, URN_ALPHA0))
return AVIF_TRUE;
if (!strcmp(urn, URN_ALPHA1))
return AVIF_TRUE;
return AVIF_FALSE;
}
// ---------------------------------------------------------------------------
// BMFF Parsing
#define BEGIN_STREAM(VARNAME, PTR, SIZE) \
avifROStream VARNAME; \
avifROData VARNAME##_roData; \
VARNAME##_roData.data = PTR; \
VARNAME##_roData.size = SIZE; \
avifROStreamStart(&VARNAME, &VARNAME##_roData)
static avifBool avifParseItemLocationBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
uint8_t version;
uint8_t flags[3];
CHECK(avifROStreamReadVersionAndFlags(&s, &version, flags));
if (version > 2) {
return AVIF_FALSE;
}
uint8_t offsetSizeAndLengthSize;
CHECK(avifROStreamRead(&s, &offsetSizeAndLengthSize, 1));
uint8_t offsetSize = (offsetSizeAndLengthSize >> 4) & 0xf; // unsigned int(4) offset_size;
uint8_t lengthSize = (offsetSizeAndLengthSize >> 0) & 0xf; // unsigned int(4) length_size;
uint8_t baseOffsetSizeAndIndexSize;
CHECK(avifROStreamRead(&s, &baseOffsetSizeAndIndexSize, 1));
uint8_t baseOffsetSize = (baseOffsetSizeAndIndexSize >> 4) & 0xf; // unsigned int(4) base_offset_size;
uint8_t indexSize = 0;
if ((version == 1) || (version == 2)) {
indexSize = baseOffsetSizeAndIndexSize & 0xf; // unsigned int(4) index_size;
if (indexSize != 0) {
// extent_index unsupported
return AVIF_FALSE;
}
}
uint16_t tmp16;
uint32_t itemCount;
if (version < 2) {
CHECK(avifROStreamReadU16(&s, &tmp16)); // unsigned int(16) item_count;
itemCount = tmp16;
} else {
CHECK(avifROStreamReadU32(&s, &itemCount)); // unsigned int(32) item_count;
}
for (uint32_t i = 0; i < itemCount; ++i) {
uint32_t itemID;
uint32_t idatID = 0;
if (version < 2) {
CHECK(avifROStreamReadU16(&s, &tmp16)); // unsigned int(16) item_ID;
itemID = tmp16;
} else {
CHECK(avifROStreamReadU32(&s, &itemID)); // unsigned int(32) item_ID;
}
if ((version == 1) || (version == 2)) {
uint8_t ignored;
uint8_t constructionMethod;
CHECK(avifROStreamRead(&s, &ignored, 1)); // unsigned int(12) reserved = 0;
CHECK(avifROStreamRead(&s, &constructionMethod, 1)); // unsigned int(4) construction_method;
constructionMethod = constructionMethod & 0xf;
if ((constructionMethod != 0 /* file */) && (constructionMethod != 1 /* idat */)) {
// construction method item(2) unsupported
return AVIF_FALSE;
}
if (constructionMethod == 1) {
idatID = data->metaBoxID;
}
}
uint16_t dataReferenceIndex; // unsigned int(16) data_ref rence_index;
CHECK(avifROStreamReadU16(&s, &dataReferenceIndex)); //
uint64_t baseOffset; // unsigned int(base_offset_size*8) base_offset;
CHECK(avifROStreamReadUX8(&s, &baseOffset, baseOffsetSize)); //
uint16_t extentCount; // unsigned int(16) extent_count;
CHECK(avifROStreamReadU16(&s, &extentCount)); //
if (extentCount == 1) {
// If extent_index is ever supported, this spec must be implemented here:
// :: if (((version == 1) || (version == 2)) && (index_size > 0)) {
// :: unsigned int(index_size*8) extent_index;
// :: }
uint64_t extentOffset; // unsigned int(offset_size*8) extent_offset;
CHECK(avifROStreamReadUX8(&s, &extentOffset, offsetSize));
uint64_t extentLength; // unsigned int(offset_size*8) extent_length;
CHECK(avifROStreamReadUX8(&s, &extentLength, lengthSize));
avifItem * item = avifDataFindItem(data, itemID);
if (!item) {
return AVIF_FALSE;
}
item->id = itemID;
item->offset = (uint32_t)(baseOffset + extentOffset);
item->size = (uint32_t)extentLength;
item->idatID = idatID;
} else {
// TODO: support more than one extent
return AVIF_FALSE;
}
}
return AVIF_TRUE;
}
static avifBool avifParseImageSpatialExtentsProperty(avifData * data, const uint8_t * raw, size_t rawLen, int propertyIndex)
{
BEGIN_STREAM(s, raw, rawLen);
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
CHECK(avifROStreamReadU32(&s, &data->properties.prop[propertyIndex].ispe.width));
CHECK(avifROStreamReadU32(&s, &data->properties.prop[propertyIndex].ispe.height));
return AVIF_TRUE;
}
static avifBool avifParseAuxiliaryTypeProperty(avifData * data, const uint8_t * raw, size_t rawLen, int propertyIndex)
{
BEGIN_STREAM(s, raw, rawLen);
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
CHECK(avifROStreamReadString(&s, data->properties.prop[propertyIndex].auxC.auxType, AUXTYPE_SIZE));
return AVIF_TRUE;
}
static avifBool avifParseColourInformationBox(avifData * data, const uint8_t * raw, size_t rawLen, int propertyIndex)
{
BEGIN_STREAM(s, raw, rawLen);
data->properties.prop[propertyIndex].colr.format = AVIF_PROFILE_FORMAT_NONE;
uint8_t colourType[4]; // unsigned int(32) colour_type;
CHECK(avifROStreamRead(&s, colourType, 4));
if (!memcmp(colourType, "rICC", 4) || !memcmp(colourType, "prof", 4)) {
data->properties.prop[propertyIndex].colr.format = AVIF_PROFILE_FORMAT_ICC;
data->properties.prop[propertyIndex].colr.icc = avifROStreamCurrent(&s);
data->properties.prop[propertyIndex].colr.iccSize = avifROStreamRemainingBytes(&s);
} else if (!memcmp(colourType, "nclx", 4)) {
// unsigned int(16) colour_primaries;
CHECK(avifROStreamReadU16(&s, &data->properties.prop[propertyIndex].colr.nclx.colourPrimaries));
// unsigned int(16) transfer_characteristics;
CHECK(avifROStreamReadU16(&s, &data->properties.prop[propertyIndex].colr.nclx.transferCharacteristics));
// unsigned int(16) matrix_coefficients;
CHECK(avifROStreamReadU16(&s, &data->properties.prop[propertyIndex].colr.nclx.matrixCoefficients));
// unsigned int(1) full_range_flag;
// unsigned int(7) reserved = 0;
CHECK(avifROStreamRead(&s, &data->properties.prop[propertyIndex].colr.nclx.fullRangeFlag, 1));
data->properties.prop[propertyIndex].colr.nclx.fullRangeFlag |= 0x80;
data->properties.prop[propertyIndex].colr.format = AVIF_PROFILE_FORMAT_NCLX;
}
return AVIF_TRUE;
}
static avifBool avifParseAV1CodecConfigurationBox(const uint8_t * raw, size_t rawLen, avifCodecConfigurationBox * av1C)
{
BEGIN_STREAM(s, raw, rawLen);
uint8_t markerAndVersion = 0;
CHECK(avifROStreamRead(&s, &markerAndVersion, 1));
uint8_t seqProfileAndIndex = 0;
CHECK(avifROStreamRead(&s, &seqProfileAndIndex, 1));
uint8_t rawFlags = 0;
CHECK(avifROStreamRead(&s, &rawFlags, 1));
if (markerAndVersion != 0x81) {
// Marker and version must both == 1
return AVIF_FALSE;
}
av1C->seqProfile = (seqProfileAndIndex >> 5) & 0x7; // unsigned int (3) seq_profile;
av1C->seqLevelIdx0 = (seqProfileAndIndex >> 0) & 0x1f; // unsigned int (5) seq_level_idx_0;
av1C->seqTier0 = (rawFlags >> 7) & 0x1; // unsigned int (1) seq_tier_0;
av1C->highBitdepth = (rawFlags >> 6) & 0x1; // unsigned int (1) high_bitdepth;
av1C->twelveBit = (rawFlags >> 5) & 0x1; // unsigned int (1) twelve_bit;
av1C->monochrome = (rawFlags >> 4) & 0x1; // unsigned int (1) monochrome;
av1C->chromaSubsamplingX = (rawFlags >> 3) & 0x1; // unsigned int (1) chroma_subsampling_x;
av1C->chromaSubsamplingY = (rawFlags >> 2) & 0x1; // unsigned int (1) chroma_subsampling_y;
av1C->chromaSamplePosition = (rawFlags >> 0) & 0x3; // unsigned int (2) chroma_sample_position;
return AVIF_TRUE;
}
static avifBool avifParseAV1CodecConfigurationBoxProperty(avifData * data, const uint8_t * raw, size_t rawLen, int propertyIndex)
{
return avifParseAV1CodecConfigurationBox(raw, rawLen, &data->properties.prop[propertyIndex].av1C);
}
static avifBool avifParseItemPropertyContainerBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
int propertyIndex = avifArrayPushIndex(&data->properties);
memcpy(data->properties.prop[propertyIndex].type, header.type, 4);
if (!memcmp(header.type, "ispe", 4)) {
CHECK(avifParseImageSpatialExtentsProperty(data, avifROStreamCurrent(&s), header.size, propertyIndex));
}
if (!memcmp(header.type, "auxC", 4)) {
CHECK(avifParseAuxiliaryTypeProperty(data, avifROStreamCurrent(&s), header.size, propertyIndex));
}
if (!memcmp(header.type, "colr", 4)) {
CHECK(avifParseColourInformationBox(data, avifROStreamCurrent(&s), header.size, propertyIndex));
}
if (!memcmp(header.type, "av1C", 4)) {
CHECK(avifParseAV1CodecConfigurationBoxProperty(data, avifROStreamCurrent(&s), header.size, propertyIndex));
}
CHECK(avifROStreamSkip(&s, header.size));
}
return AVIF_TRUE;
}
static avifBool avifParseItemPropertyAssociation(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
uint8_t version;
uint8_t flags[3];
CHECK(avifROStreamReadVersionAndFlags(&s, &version, flags));
avifBool propertyIndexIsU16 = (flags[2] & 0x1) ? AVIF_TRUE : AVIF_FALSE; // is flags[2] correct?
uint32_t entryCount;
CHECK(avifROStreamReadU32(&s, &entryCount));
for (uint32_t entryIndex = 0; entryIndex < entryCount; ++entryIndex) {
unsigned int itemID;
if (version < 1) {
uint16_t tmp;
CHECK(avifROStreamReadU16(&s, &tmp));
itemID = tmp;
} else {
CHECK(avifROStreamReadU32(&s, &itemID));
}
uint8_t associationCount;
CHECK(avifROStreamRead(&s, &associationCount, 1));
for (uint8_t associationIndex = 0; associationIndex < associationCount; ++associationIndex) {
// avifBool essential = AVIF_FALSE; // currently unused
uint16_t propertyIndex = 0;
if (propertyIndexIsU16) {
CHECK(avifROStreamReadU16(&s, &propertyIndex));
// essential = (propertyIndex & 0x8000) ? AVIF_TRUE : AVIF_FALSE;
propertyIndex &= 0x7fff;
} else {
uint8_t tmp;
CHECK(avifROStreamRead(&s, &tmp, 1));
// essential = (tmp & 0x80) ? AVIF_TRUE : AVIF_FALSE;
propertyIndex = tmp & 0x7f;
}
if (propertyIndex == 0) {
// Not associated with any item
continue;
}
--propertyIndex; // 1-indexed
if (propertyIndex >= data->properties.count) {
return AVIF_FALSE;
}
avifItem * item = avifDataFindItem(data, itemID);
if (!item) {
return AVIF_FALSE;
}
// Associate property with item
avifProperty * prop = &data->properties.prop[propertyIndex];
if (!memcmp(prop->type, "ispe", 4)) {
item->ispePresent = AVIF_TRUE;
memcpy(&item->ispe, &prop->ispe, sizeof(avifImageSpatialExtents));
} else if (!memcmp(prop->type, "auxC", 4)) {
item->auxCPresent = AVIF_TRUE;
memcpy(&item->auxC, &prop->auxC, sizeof(avifAuxiliaryType));
} else if (!memcmp(prop->type, "colr", 4)) {
item->colrPresent = AVIF_TRUE;
memcpy(&item->colr, &prop->colr, sizeof(avifColourInformationBox));
} else if (!memcmp(prop->type, "av1C", 4)) {
item->av1CPresent = AVIF_TRUE;
memcpy(&item->av1C, &prop->av1C, sizeof(avifCodecConfigurationBox));
}
}
}
return AVIF_TRUE;
}
static avifBool avifParsePrimaryItemBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
if (data->primaryItemID > 0) {
// Illegal to have multiple pitm boxes, bail out
return AVIF_FALSE;
}
BEGIN_STREAM(s, raw, rawLen);
uint8_t version;
CHECK(avifROStreamReadVersionAndFlags(&s, &version, NULL));
if (version == 0) {
uint16_t tmp16;
CHECK(avifROStreamReadU16(&s, &tmp16)); // unsigned int(16) item_ID;
data->primaryItemID = tmp16;
} else {
CHECK(avifROStreamReadU32(&s, &data->primaryItemID)); // unsigned int(32) item_ID;
}
return AVIF_TRUE;
}
static avifBool avifParseItemDataBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
uint32_t idatID = data->metaBoxID;
// Check to see if we've already seen an idat box for this meta box. If so, bail out
for (uint32_t i = 0; i < data->idats.count; ++i) {
if (data->idats.idat[i].id == idatID) {
return AVIF_FALSE;
}
}
int index = avifArrayPushIndex(&data->idats);
avifItemData * idat = &data->idats.idat[index];
idat->id = idatID;
idat->data.data = raw;
idat->data.size = rawLen;
return AVIF_TRUE;
}
static avifBool avifParseItemPropertiesBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
avifBoxHeader ipcoHeader;
CHECK(avifROStreamReadBoxHeader(&s, &ipcoHeader));
if (memcmp(ipcoHeader.type, "ipco", 4) != 0) {
return AVIF_FALSE;
}
// Read all item properties inside of ItemPropertyContainerBox
CHECK(avifParseItemPropertyContainerBox(data, avifROStreamCurrent(&s), ipcoHeader.size));
CHECK(avifROStreamSkip(&s, ipcoHeader.size));
// Now read all ItemPropertyAssociation until the end of the box, and make associations
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader ipmaHeader;
CHECK(avifROStreamReadBoxHeader(&s, &ipmaHeader));
if (!memcmp(ipmaHeader.type, "ipma", 4)) {
CHECK(avifParseItemPropertyAssociation(data, avifROStreamCurrent(&s), ipmaHeader.size));
} else {
// These must all be type ipma
return AVIF_FALSE;
}
CHECK(avifROStreamSkip(&s, ipmaHeader.size));
}
return AVIF_TRUE;
}
static avifBool avifParseItemInfoEntry(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
CHECK(avifROStreamReadAndEnforceVersion(&s, 2)); // TODO: support version > 2? 2+ is required for item_type
uint16_t itemID; // unsigned int(16) item_ID;
CHECK(avifROStreamReadU16(&s, &itemID)); //
uint16_t itemProtectionIndex; // unsigned int(16) item_protection_index;
CHECK(avifROStreamReadU16(&s, &itemProtectionIndex)); //
uint8_t itemType[4]; // unsigned int(32) item_type;
CHECK(avifROStreamRead(&s, itemType, 4)); //
avifContentType contentType;
if (!memcmp(itemType, "mime", 4)) {
CHECK(avifROStreamReadString(&s, NULL, 0)); // string item_name; (skipped)
CHECK(avifROStreamReadString(&s, contentType.contentType, CONTENTTYPE_SIZE)); // string content_type;
} else {
memset(&contentType, 0, sizeof(contentType));
}
avifItem * item = avifDataFindItem(data, itemID);
if (!item) {
return AVIF_FALSE;
}
memcpy(item->type, itemType, sizeof(itemType));
memcpy(&item->contentType, &contentType, sizeof(contentType));
return AVIF_TRUE;
}
static avifBool avifParseItemInfoBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
uint8_t version;
CHECK(avifROStreamReadVersionAndFlags(&s, &version, NULL));
uint32_t entryCount;
if (version == 0) {
uint16_t tmp;
CHECK(avifROStreamReadU16(&s, &tmp)); // unsigned int(16) entry_count;
entryCount = tmp;
} else if (version == 1) {
CHECK(avifROStreamReadU32(&s, &entryCount)); // unsigned int(32) entry_count;
} else {
return AVIF_FALSE;
}
for (uint32_t entryIndex = 0; entryIndex < entryCount; ++entryIndex) {
avifBoxHeader infeHeader;
CHECK(avifROStreamReadBoxHeader(&s, &infeHeader));
if (!memcmp(infeHeader.type, "infe", 4)) {
CHECK(avifParseItemInfoEntry(data, avifROStreamCurrent(&s), infeHeader.size));
} else {
// These must all be type ipma
return AVIF_FALSE;
}
CHECK(avifROStreamSkip(&s, infeHeader.size));
}
return AVIF_TRUE;
}
static avifBool avifParseItemReferenceBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
uint8_t version;
CHECK(avifROStreamReadVersionAndFlags(&s, &version, NULL));
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader irefHeader;
CHECK(avifROStreamReadBoxHeader(&s, &irefHeader));
uint32_t fromID = 0;
if (version == 0) {
uint16_t tmp;
CHECK(avifROStreamReadU16(&s, &tmp)); // unsigned int(16) from_item_ID;
fromID = tmp;
} else if (version == 1) {
CHECK(avifROStreamReadU32(&s, &fromID)); // unsigned int(32) from_item_ID;
} else {
// unsupported iref version, skip it
break;
}
uint16_t referenceCount = 0;
CHECK(avifROStreamReadU16(&s, &referenceCount)); // unsigned int(16) reference_count;
for (uint16_t refIndex = 0; refIndex < referenceCount; ++refIndex) {
uint32_t toID = 0;
if (version == 0) {
uint16_t tmp;
CHECK(avifROStreamReadU16(&s, &tmp)); // unsigned int(16) to_item_ID;
toID = tmp;
} else if (version == 1) {
CHECK(avifROStreamReadU32(&s, &toID)); // unsigned int(32) to_item_ID;
} else {
// unsupported iref version, skip it
break;
}
// Read this reference as "{fromID} is a {irefType} for {toID}"
if (fromID && toID) {
avifItem * item = avifDataFindItem(data, fromID);
if (!item) {
return AVIF_FALSE;
}
if (!memcmp(irefHeader.type, "thmb", 4)) {
item->thumbnailForID = toID;
}
if (!memcmp(irefHeader.type, "auxl", 4)) {
item->auxForID = toID;
}
if (!memcmp(irefHeader.type, "cdsc", 4)) {
item->descForID = toID;
}
}
}
}
return AVIF_TRUE;
}
static avifBool avifParseMetaBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
++data->metaBoxID; // for tracking idat
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (!memcmp(header.type, "iloc", 4)) {
CHECK(avifParseItemLocationBox(data, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "pitm", 4)) {
CHECK(avifParsePrimaryItemBox(data, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "idat", 4)) {
CHECK(avifParseItemDataBox(data, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "iprp", 4)) {
CHECK(avifParseItemPropertiesBox(data, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "iinf", 4)) {
CHECK(avifParseItemInfoBox(data, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "iref", 4)) {
CHECK(avifParseItemReferenceBox(data, avifROStreamCurrent(&s), header.size));
}
CHECK(avifROStreamSkip(&s, header.size));
}
return AVIF_TRUE;
}
static avifBool avifParseTrackHeaderBox(avifData * data, avifTrack * track, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
uint8_t version;
uint8_t flags[3];
CHECK(avifROStreamReadVersionAndFlags(&s, &version, flags));
uint32_t ignored32, trackID;
uint64_t ignored64;
if (version == 1) {
CHECK(avifROStreamReadU64(&s, &ignored64)); // unsigned int(64) creation_time;
CHECK(avifROStreamReadU64(&s, &ignored64)); // unsigned int(64) modification_time;
CHECK(avifROStreamReadU32(&s, &trackID)); // unsigned int(32) track_ID;
CHECK(avifROStreamReadU32(&s, &ignored32)); // const unsigned int(32) reserved = 0;
CHECK(avifROStreamReadU64(&s, &ignored64)); // unsigned int(64) duration;
} else if (version == 0) {
CHECK(avifROStreamReadU32(&s, &ignored32)); // unsigned int(32) creation_time;
CHECK(avifROStreamReadU32(&s, &ignored32)); // unsigned int(32) modification_time;
CHECK(avifROStreamReadU32(&s, &trackID)); // unsigned int(32) track_ID;
CHECK(avifROStreamReadU32(&s, &ignored32)); // const unsigned int(32) reserved = 0;
CHECK(avifROStreamReadU32(&s, &ignored32)); // unsigned int(32) duration;
} else {
// Unsupported version
return AVIF_FALSE;
}
// Skipping the following 52 bytes here:
// ------------------------------------
// const unsigned int(32)[2] reserved = 0;
// template int(16) layer = 0;
// template int(16) alternate_group = 0;
// template int(16) volume = {if track_is_audio 0x0100 else 0};
// const unsigned int(16) reserved = 0;
// template int(32)[9] matrix= { 0x00010000,0,0,0,0x00010000,0,0,0,0x40000000 }; // unity matrix
CHECK(avifROStreamSkip(&s, 52));
uint32_t width, height;
CHECK(avifROStreamReadU32(&s, &width)); // unsigned int(32) width;
CHECK(avifROStreamReadU32(&s, &height)); // unsigned int(32) height;
track->width = width >> 16;
track->height = height >> 16;
// TODO: support scaling based on width/height track header info?
track->id = trackID;
return AVIF_TRUE;
}
static avifBool avifParseMediaHeaderBox(avifData * data, avifTrack * track, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
uint8_t version;
uint8_t flags[3];
CHECK(avifROStreamReadVersionAndFlags(&s, &version, flags));
uint32_t ignored32, mediaTimescale, mediaDuration32;
uint64_t ignored64, mediaDuration64;
if (version == 1) {
CHECK(avifROStreamReadU64(&s, &ignored64)); // unsigned int(64) creation_time;
CHECK(avifROStreamReadU64(&s, &ignored64)); // unsigned int(64) modification_time;
CHECK(avifROStreamReadU32(&s, &mediaTimescale)); // unsigned int(32) timescale;
CHECK(avifROStreamReadU64(&s, &mediaDuration64)); // unsigned int(64) duration;
track->mediaDuration = mediaDuration64;
} else if (version == 0) {
CHECK(avifROStreamReadU32(&s, &ignored32)); // unsigned int(32) creation_time;
CHECK(avifROStreamReadU32(&s, &ignored32)); // unsigned int(32) modification_time;
CHECK(avifROStreamReadU32(&s, &mediaTimescale)); // unsigned int(32) timescale;
CHECK(avifROStreamReadU32(&s, &mediaDuration32)); // unsigned int(32) duration;
track->mediaDuration = (uint64_t)mediaDuration32;
} else {
// Unsupported version
return AVIF_FALSE;
}
track->mediaTimescale = mediaTimescale;
return AVIF_TRUE;
}
static avifBool avifParseChunkOffsetBox(avifData * data, avifSampleTable * sampleTable, avifBool largeOffsets, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
uint32_t entryCount;
CHECK(avifROStreamReadU32(&s, &entryCount)); // unsigned int(32) entry_count;
for (uint32_t i = 0; i < entryCount; ++i) {
uint64_t offset;
if (largeOffsets) {
CHECK(avifROStreamReadU64(&s, &offset)); // unsigned int(32) chunk_offset;
} else {
uint32_t offset32;
CHECK(avifROStreamReadU32(&s, &offset32)); // unsigned int(32) chunk_offset;
offset = (uint64_t)offset32;
}
avifSampleTableChunk * chunk = (avifSampleTableChunk *)avifArrayPushPtr(&sampleTable->chunks);
chunk->offset = offset;
}
return AVIF_TRUE;
}
static avifBool avifParseSampleToChunkBox(avifData * data, avifSampleTable * sampleTable, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
uint32_t entryCount;
CHECK(avifROStreamReadU32(&s, &entryCount)); // unsigned int(32) entry_count;
for (uint32_t i = 0; i < entryCount; ++i) {
avifSampleTableSampleToChunk * sampleToChunk = (avifSampleTableSampleToChunk *)avifArrayPushPtr(&sampleTable->sampleToChunks);
CHECK(avifROStreamReadU32(&s, &sampleToChunk->firstChunk)); // unsigned int(32) first_chunk;
CHECK(avifROStreamReadU32(&s, &sampleToChunk->samplesPerChunk)); // unsigned int(32) samples_per_chunk;
CHECK(avifROStreamReadU32(&s, &sampleToChunk->sampleDescriptionIndex)); // unsigned int(32) sample_description_index;
}
return AVIF_TRUE;
}
static avifBool avifParseSampleSizeBox(avifData * data, avifSampleTable * sampleTable, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
uint32_t allSamplesSize, sampleCount;
CHECK(avifROStreamReadU32(&s, &allSamplesSize)); // unsigned int(32) sample_size;
CHECK(avifROStreamReadU32(&s, &sampleCount)); // unsigned int(32) sample_count;
if (allSamplesSize > 0) {
sampleTable->allSamplesSize = allSamplesSize;
} else {
for (uint32_t i = 0; i < sampleCount; ++i) {
avifSampleTableSampleSize * sampleSize = (avifSampleTableSampleSize *)avifArrayPushPtr(&sampleTable->sampleSizes);
CHECK(avifROStreamReadU32(&s, &sampleSize->size)); // unsigned int(32) entry_size;
}
}
return AVIF_TRUE;
}
static avifBool avifParseSyncSampleBox(avifData * data, avifSampleTable * sampleTable, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
uint32_t entryCount;
CHECK(avifROStreamReadU32(&s, &entryCount)); // unsigned int(32) entry_count;
for (uint32_t i = 0; i < entryCount; ++i) {
uint32_t sampleNumber = 0;
CHECK(avifROStreamReadU32(&s, &sampleNumber)); // unsigned int(32) sample_number;
avifSyncSample * syncSample = (avifSyncSample *)avifArrayPushPtr(&sampleTable->syncSamples);
syncSample->sampleNumber = sampleNumber;
}
return AVIF_TRUE;
}
static avifBool avifParseTimeToSampleBox(avifData * data, avifSampleTable * sampleTable, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
uint32_t entryCount;
CHECK(avifROStreamReadU32(&s, &entryCount)); // unsigned int(32) entry_count;
for (uint32_t i = 0; i < entryCount; ++i) {
avifSampleTableTimeToSample * timeToSample = (avifSampleTableTimeToSample *)avifArrayPushPtr(&sampleTable->timeToSamples);
CHECK(avifROStreamReadU32(&s, &timeToSample->sampleCount)); // unsigned int(32) sample_count;
CHECK(avifROStreamReadU32(&s, &timeToSample->sampleDelta)); // unsigned int(32) sample_delta;
}
return AVIF_TRUE;
}
static avifBool avifParseSampleDescriptionBox(avifData * data, avifSampleTable * sampleTable, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
CHECK(avifROStreamReadAndEnforceVersion(&s, 0));
uint32_t entryCount;
CHECK(avifROStreamReadU32(&s, &entryCount)); // unsigned int(32) entry_count;
for (uint32_t i = 0; i < entryCount; ++i) {
avifBoxHeader sampleEntryHeader;
CHECK(avifROStreamReadBoxHeader(&s, &sampleEntryHeader));
avifSampleDescription * description = (avifSampleDescription *)avifArrayPushPtr(&sampleTable->sampleDescriptions);
memcpy(description->format, sampleEntryHeader.type, sizeof(description->format));
size_t remainingBytes = avifROStreamRemainingBytes(&s);
if (!memcmp(description->format, "av01", 4) && (remainingBytes > VISUALSAMPLEENTRY_SIZE)) {
BEGIN_STREAM(av01Stream, avifROStreamCurrent(&s) + VISUALSAMPLEENTRY_SIZE, remainingBytes - VISUALSAMPLEENTRY_SIZE);
while (avifROStreamHasBytesLeft(&av01Stream, 1)) {
avifBoxHeader av01ChildHeader;
CHECK(avifROStreamReadBoxHeader(&av01Stream, &av01ChildHeader));
if (!memcmp(av01ChildHeader.type, "av1C", 4)) {
CHECK(avifParseAV1CodecConfigurationBox(avifROStreamCurrent(&av01Stream), av01ChildHeader.size, &description->av1C));
description->av1CPresent = AVIF_TRUE;
}
CHECK(avifROStreamSkip(&av01Stream, av01ChildHeader.size));
}
}
CHECK(avifROStreamSkip(&s, sampleEntryHeader.size));
}
return AVIF_TRUE;
}
static avifBool avifParseSampleTableBox(avifData * data, avifTrack * track, const uint8_t * raw, size_t rawLen)
{
if (track->sampleTable) {
// A TrackBox may only have one SampleTable
return AVIF_FALSE;
}
track->sampleTable = avifSampleTableCreate();
BEGIN_STREAM(s, raw, rawLen);
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (!memcmp(header.type, "stco", 4)) {
CHECK(avifParseChunkOffsetBox(data, track->sampleTable, AVIF_FALSE, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "co64", 4)) {
CHECK(avifParseChunkOffsetBox(data, track->sampleTable, AVIF_TRUE, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "stsc", 4)) {
CHECK(avifParseSampleToChunkBox(data, track->sampleTable, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "stsz", 4)) {
CHECK(avifParseSampleSizeBox(data, track->sampleTable, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "stss", 4)) {
CHECK(avifParseSyncSampleBox(data, track->sampleTable, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "stts", 4)) {
CHECK(avifParseTimeToSampleBox(data, track->sampleTable, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "stsd", 4)) {
CHECK(avifParseSampleDescriptionBox(data, track->sampleTable, avifROStreamCurrent(&s), header.size));
}
CHECK(avifROStreamSkip(&s, header.size));
}
return AVIF_TRUE;
}
static avifBool avifParseMediaInformationBox(avifData * data, avifTrack * track, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (!memcmp(header.type, "stbl", 4)) {
CHECK(avifParseSampleTableBox(data, track, avifROStreamCurrent(&s), header.size));
}
CHECK(avifROStreamSkip(&s, header.size));
}
return AVIF_TRUE;
}
static avifBool avifParseMediaBox(avifData * data, avifTrack * track, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (!memcmp(header.type, "mdhd", 4)) {
CHECK(avifParseMediaHeaderBox(data, track, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "minf", 4)) {
CHECK(avifParseMediaInformationBox(data, track, avifROStreamCurrent(&s), header.size));
}
CHECK(avifROStreamSkip(&s, header.size));
}
return AVIF_TRUE;
}
static avifBool avifTrackReferenceBox(avifData * data, avifTrack * track, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
(void)data;
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (!memcmp(header.type, "auxl", 4)) {
uint32_t toID;
CHECK(avifROStreamReadU32(&s, &toID)); // unsigned int(32) track_IDs[]
CHECK(avifROStreamSkip(&s, header.size - sizeof(uint32_t))); // just take the first one
track->auxForID = toID;
} else {
CHECK(avifROStreamSkip(&s, header.size));
}
}
return AVIF_TRUE;
}
static avifBool avifParseTrackBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
avifTrack * track = (avifTrack *)avifArrayPushPtr(&data->tracks);
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (!memcmp(header.type, "tkhd", 4)) {
CHECK(avifParseTrackHeaderBox(data, track, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "mdia", 4)) {
CHECK(avifParseMediaBox(data, track, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "tref", 4)) {
CHECK(avifTrackReferenceBox(data, track, avifROStreamCurrent(&s), header.size));
}
CHECK(avifROStreamSkip(&s, header.size));
}
return AVIF_TRUE;
}
static avifBool avifParseMoovBox(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (!memcmp(header.type, "trak", 4)) {
CHECK(avifParseTrackBox(data, avifROStreamCurrent(&s), header.size));
}
CHECK(avifROStreamSkip(&s, header.size));
}
return AVIF_TRUE;
}
static avifBool avifParseFileTypeBox(avifFileType * ftyp, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
CHECK(avifROStreamRead(&s, ftyp->majorBrand, 4));
CHECK(avifROStreamReadU32(&s, &ftyp->minorVersion));
size_t compatibleBrandsBytes = avifROStreamRemainingBytes(&s);
if ((compatibleBrandsBytes % 4) != 0) {
return AVIF_FALSE;
}
if (compatibleBrandsBytes > (4 * MAX_COMPATIBLE_BRANDS)) {
// TODO: stop clamping and resize this
compatibleBrandsBytes = (4 * MAX_COMPATIBLE_BRANDS);
}
CHECK(avifROStreamRead(&s, ftyp->compatibleBrands, compatibleBrandsBytes));
ftyp->compatibleBrandsCount = (int)compatibleBrandsBytes / 4;
return AVIF_TRUE;
}
static avifBool avifParse(avifData * data, const uint8_t * raw, size_t rawLen)
{
BEGIN_STREAM(s, raw, rawLen);
while (avifROStreamHasBytesLeft(&s, 1)) {
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (!memcmp(header.type, "ftyp", 4)) {
CHECK(avifParseFileTypeBox(&data->ftyp, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "meta", 4)) {
CHECK(avifParseMetaBox(data, avifROStreamCurrent(&s), header.size));
} else if (!memcmp(header.type, "moov", 4)) {
CHECK(avifParseMoovBox(data, avifROStreamCurrent(&s), header.size));
}
CHECK(avifROStreamSkip(&s, header.size));
}
return AVIF_TRUE;
}
// ---------------------------------------------------------------------------
static avifBool avifFileTypeIsCompatible(avifFileType * ftyp)
{
avifBool avifCompatible = (memcmp(ftyp->majorBrand, "avif", 4) == 0) ? AVIF_TRUE : AVIF_FALSE;
if (!avifCompatible) {
avifCompatible = (memcmp(ftyp->majorBrand, "avis", 4) == 0) ? AVIF_TRUE : AVIF_FALSE;
}
if (!avifCompatible) {
avifCompatible = (memcmp(ftyp->majorBrand, "av01", 4) == 0) ? AVIF_TRUE : AVIF_FALSE;
}
if (!avifCompatible) {
for (int compatibleBrandIndex = 0; compatibleBrandIndex < ftyp->compatibleBrandsCount; ++compatibleBrandIndex) {
uint8_t * compatibleBrand = &ftyp->compatibleBrands[4 * compatibleBrandIndex];
if (!memcmp(compatibleBrand, "avif", 4)) {
avifCompatible = AVIF_TRUE;
break;
}
if (!memcmp(compatibleBrand, "avis", 4)) {
avifCompatible = AVIF_TRUE;
break;
}
if (!memcmp(compatibleBrand, "av01", 4)) {
avifCompatible = AVIF_TRUE;
break;
}
}
}
return avifCompatible;
}
avifBool avifPeekCompatibleFileType(avifROData * input)
{
BEGIN_STREAM(s, input->data, input->size);
avifBoxHeader header;
CHECK(avifROStreamReadBoxHeader(&s, &header));
if (memcmp(header.type, "ftyp", 4) != 0) {
return AVIF_FALSE;
}
avifFileType ftyp;
memset(&ftyp, 0, sizeof(avifFileType));
avifBool parsed = avifParseFileTypeBox(&ftyp, avifROStreamCurrent(&s), header.size);
if (!parsed) {
return AVIF_FALSE;
}
return avifFileTypeIsCompatible(&ftyp);
}
// ---------------------------------------------------------------------------
avifDecoder * avifDecoderCreate(void)
{
avifDecoder * decoder = (avifDecoder *)avifAlloc(sizeof(avifDecoder));
memset(decoder, 0, sizeof(avifDecoder));
return decoder;
}
static void avifDecoderCleanup(avifDecoder * decoder)
{
if (decoder->data) {
avifDataDestroy(decoder->data);
decoder->data = NULL;
}
if (decoder->image) {
avifImageDestroy(decoder->image);
decoder->image = NULL;
}
}
void avifDecoderDestroy(avifDecoder * decoder)
{
avifDecoderCleanup(decoder);
avifFree(decoder);
}
avifResult avifDecoderSetSource(avifDecoder * decoder, avifDecoderSource source)
{
decoder->requestedSource = source;
return avifDecoderReset(decoder);
}
avifResult avifDecoderParse(avifDecoder * decoder, avifROData * rawInput)
{
// Cleanup anything lingering in the decoder
avifDecoderCleanup(decoder);
// -----------------------------------------------------------------------
// Parse BMFF boxes
decoder->data = avifDataCreate();
// Shallow copy, on purpose
memcpy(&decoder->data->rawInput, rawInput, sizeof(avifROData));
if (!avifParse(decoder->data, decoder->data->rawInput.data, decoder->data->rawInput.size)) {
return AVIF_RESULT_BMFF_PARSE_FAILED;
}
avifBool avifCompatible = avifFileTypeIsCompatible(&decoder->data->ftyp);
if (!avifCompatible) {
return AVIF_RESULT_INVALID_FTYP;
}
// Sanity check items
for (uint32_t itemIndex = 0; itemIndex < decoder->data->items.count; ++itemIndex) {
avifItem * item = &decoder->data->items.item[itemIndex];
const uint8_t * p = avifDataCalcItemPtr(decoder->data, item);
if (p == NULL) {
return AVIF_RESULT_BMFF_PARSE_FAILED;
}
}
// Sanity check tracks
for (uint32_t trackIndex = 0; trackIndex < decoder->data->tracks.count; ++trackIndex) {
avifTrack * track = &decoder->data->tracks.track[trackIndex];
if (!track->sampleTable) {
continue;
}
for (uint32_t chunkIndex = 0; chunkIndex < track->sampleTable->chunks.count; ++chunkIndex) {
avifSampleTableChunk * chunk = &track->sampleTable->chunks.chunk[chunkIndex];
if (chunk->offset > decoder->data->rawInput.size) {
return AVIF_RESULT_BMFF_PARSE_FAILED;
}
}
}
return avifDecoderReset(decoder);
}
static avifCodec * avifCodecCreateInternal(avifCodecChoice choice, avifCodecDecodeInput * decodeInput)
{
avifCodec * codec = avifCodecCreate(choice, AVIF_CODEC_FLAG_CAN_DECODE);
if (codec) {
codec->decodeInput = decodeInput;
}
return codec;
}
static avifResult avifDecoderFlush(avifDecoder * decoder)
{
avifDataResetCodec(decoder->data);
decoder->data->codec[AVIF_CODEC_PLANES_COLOR] = avifCodecCreateInternal(decoder->codecChoice, decoder->data->colorInput);
if (!decoder->data->codec[AVIF_CODEC_PLANES_COLOR]) {
return AVIF_RESULT_NO_CODEC_AVAILABLE;
}
if (!decoder->data->codec[AVIF_CODEC_PLANES_COLOR]->open(decoder->data->codec[AVIF_CODEC_PLANES_COLOR], decoder->imageIndex + 1)) {
return AVIF_RESULT_DECODE_COLOR_FAILED;
}
if (decoder->data->alphaInput) {
decoder->data->codec[AVIF_CODEC_PLANES_ALPHA] = avifCodecCreateInternal(decoder->codecChoice, decoder->data->alphaInput);
if (!decoder->data->codec[AVIF_CODEC_PLANES_ALPHA]) {
return AVIF_RESULT_NO_CODEC_AVAILABLE;
}
if (!decoder->data->codec[AVIF_CODEC_PLANES_ALPHA]->open(decoder->data->codec[AVIF_CODEC_PLANES_ALPHA], decoder->imageIndex + 1)) {
return AVIF_RESULT_DECODE_ALPHA_FAILED;
}
}
return AVIF_RESULT_OK;
}
avifResult avifDecoderReset(avifDecoder * decoder)
{
avifData * data = decoder->data;
if (!data) {
// Nothing to reset.
return AVIF_RESULT_OK;
}
avifDataResetCodec(data);
if (!decoder->image) {
decoder->image = avifImageCreateEmpty();
}
if (data->colorInput) {
avifCodecDecodeInputDestroy(data->colorInput);
data->colorInput = NULL;
}
if (data->alphaInput) {
avifCodecDecodeInputDestroy(data->alphaInput);
data->alphaInput = NULL;
}
memset(&decoder->ioStats, 0, sizeof(decoder->ioStats));
// -----------------------------------------------------------------------
// Build decode input
data->sourceSampleTable = NULL; // Reset
if (decoder->requestedSource == AVIF_DECODER_SOURCE_AUTO) {
if (data->tracks.count > 0) {
data->source = AVIF_DECODER_SOURCE_TRACKS;
} else {
data->source = AVIF_DECODER_SOURCE_PRIMARY_ITEM;
}
} else {
data->source = decoder->requestedSource;
}
if (data->source == AVIF_DECODER_SOURCE_TRACKS) {
avifTrack * colorTrack = NULL;
avifTrack * alphaTrack = NULL;
// Find primary track - this probably needs some better detection
uint32_t colorTrackIndex = 0;
for (; colorTrackIndex < decoder->data->tracks.count; ++colorTrackIndex) {
avifTrack * track = &decoder->data->tracks.track[colorTrackIndex];
if (!track->sampleTable) {
continue;
}
if (!track->sampleTable->chunks.count) {
continue;
}
if (!avifSampleTableHasFormat(track->sampleTable, "av01")) {
continue;
}
if (track->auxForID != 0) {
continue;
}
// Found one!
break;
}
if (colorTrackIndex == decoder->data->tracks.count) {
return AVIF_RESULT_NO_CONTENT;
}
colorTrack = &decoder->data->tracks.track[colorTrackIndex];
uint32_t alphaTrackIndex = 0;
for (; alphaTrackIndex < decoder->data->tracks.count; ++alphaTrackIndex) {
avifTrack * track = &decoder->data->tracks.track[alphaTrackIndex];
if (!track->sampleTable) {
continue;
}
if (!track->sampleTable->chunks.count) {
continue;
}
if (!avifSampleTableHasFormat(track->sampleTable, "av01")) {
continue;
}
if (track->auxForID == colorTrack->id) {
// Found it!
break;
}
}
if (alphaTrackIndex != decoder->data->tracks.count) {
alphaTrack = &decoder->data->tracks.track[alphaTrackIndex];
}
// TODO: We must get color profile information from somewhere; likely the color OBU as a fallback
data->colorInput = avifCodecDecodeInputCreate();
if (!avifCodecDecodeInputGetSamples(data->colorInput, colorTrack->sampleTable, &decoder->data->rawInput)) {
return AVIF_RESULT_BMFF_PARSE_FAILED;
}
if (alphaTrack) {
data->alphaInput = avifCodecDecodeInputCreate();
if (!avifCodecDecodeInputGetSamples(data->alphaInput, alphaTrack->sampleTable, &decoder->data->rawInput)) {
return AVIF_RESULT_BMFF_PARSE_FAILED;
}
data->alphaInput->alpha = AVIF_TRUE;
}
// Stash off sample table for future timing information
data->sourceSampleTable = colorTrack->sampleTable;
// Image sequence timing
decoder->imageIndex = -1;
decoder->imageCount = data->colorInput->samples.count;
decoder->timescale = colorTrack->mediaTimescale;
decoder->durationInTimescales = colorTrack->mediaDuration;
if (colorTrack->mediaTimescale) {
decoder->duration = (double)decoder->durationInTimescales / (double)colorTrack->mediaTimescale;
} else {
decoder->duration = 0;
}
memset(&decoder->imageTiming, 0, sizeof(decoder->imageTiming)); // to be set in avifDecoderNextImage()
decoder->containerWidth = colorTrack->width;
decoder->containerHeight = colorTrack->height;
decoder->containerDepth = avifSampleTableGetDepth(colorTrack->sampleTable);
} else {
// Create from items
avifROData colorOBU = AVIF_DATA_EMPTY;
avifROData alphaOBU = AVIF_DATA_EMPTY;
avifROData exifData = AVIF_DATA_EMPTY;
avifROData xmpData = AVIF_DATA_EMPTY;
avifItem * colorOBUItem = NULL;
// Find the colorOBU (primary) item
for (uint32_t itemIndex = 0; itemIndex < data->items.count; ++itemIndex) {
avifItem * item = &data->items.item[itemIndex];
if (!item->id || !item->size) {
break;
}
if (memcmp(item->type, "av01", 4)) {
// probably exif or some other data
continue;
}
if (item->thumbnailForID != 0) {
// It's a thumbnail, skip it
continue;
}
if ((data->primaryItemID > 0) && (item->id != data->primaryItemID)) {
// a primary item ID was specified, require it
continue;
}
colorOBUItem = item;
colorOBU.data = avifDataCalcItemPtr(data, item);
colorOBU.size = item->size;
break;
}
if (colorOBUItem) {
// Find the alphaOBU item, if any
for (uint32_t itemIndex = 0; itemIndex < data->items.count; ++itemIndex) {
avifItem * item = &data->items.item[itemIndex];
if (!item->id || !item->size) {
break;
}
if (memcmp(item->type, "av01", 4)) {
// probably exif or some other data
continue;
}
if (item->thumbnailForID != 0) {
// It's a thumbnail, skip it
continue;
}
if (isAlphaURN(item->auxC.auxType) && (item->auxForID == colorOBUItem->id)) {
alphaOBU.data = avifDataCalcItemPtr(data, item);
alphaOBU.size = item->size;
break;
}
}
// Find Exif and/or XMP metadata, if any
for (uint32_t itemIndex = 0; itemIndex < data->items.count; ++itemIndex) {
avifItem * item = &data->items.item[itemIndex];
if (!item->id || !item->size) {
break;
}
if (item->descForID != colorOBUItem->id) {
// Not a content description (metadata) for the colorOBU, skip it
continue;
}
if (!memcmp(item->type, "Exif", 4)) {
// Advance past Annex A.2.1's header
const uint8_t * boxPtr = avifDataCalcItemPtr(data, item);
BEGIN_STREAM(exifBoxStream, boxPtr, item->size);
uint32_t exifTiffHeaderOffset;
CHECK(avifROStreamReadU32(&exifBoxStream, &exifTiffHeaderOffset)); // unsigned int(32) exif_tiff_header_offset;
exifData.data = avifROStreamCurrent(&exifBoxStream);
exifData.size = avifROStreamRemainingBytes(&exifBoxStream);
}
if (!memcmp(item->type, "mime", 4) && !memcmp(item->contentType.contentType, xmpContentType, xmpContentTypeSize)) {
xmpData.data = avifDataCalcItemPtr(data, item);
xmpData.size = item->size;
}
}
}
if (colorOBU.size == 0) {
return AVIF_RESULT_NO_AV1_ITEMS_FOUND;
}
if (colorOBUItem->colrPresent) {
if (colorOBUItem->colr.format == AVIF_PROFILE_FORMAT_ICC) {
avifImageSetProfileICC(decoder->image, colorOBUItem->colr.icc, colorOBUItem->colr.iccSize);
} else if (colorOBUItem->colr.format == AVIF_PROFILE_FORMAT_NCLX) {
avifImageSetProfileNCLX(decoder->image, &colorOBUItem->colr.nclx);
}
}
if (exifData.data && exifData.size) {
avifImageSetMetadataExif(decoder->image, exifData.data, exifData.size);
}
if (xmpData.data && xmpData.size) {
avifImageSetMetadataXMP(decoder->image, xmpData.data, xmpData.size);
}
data->colorInput = avifCodecDecodeInputCreate();
avifSample * colorSample = (avifSample *)avifArrayPushPtr(&data->colorInput->samples);
memcpy(&colorSample->data, &colorOBU, sizeof(avifROData));
colorSample->sync = AVIF_TRUE;
if (alphaOBU.size > 0) {
data->alphaInput = avifCodecDecodeInputCreate();
avifSample * alphaSample = (avifSample *)avifArrayPushPtr(&data->alphaInput->samples);
memcpy(&alphaSample->data, &alphaOBU, sizeof(avifROData));
alphaSample->sync = AVIF_TRUE;
data->alphaInput->alpha = AVIF_TRUE;
}
// Set all counts and timing to safe-but-uninteresting values
decoder->imageIndex = -1;
decoder->imageCount = 1;
decoder->imageTiming.timescale = 1;
decoder->imageTiming.pts = 0;
decoder->imageTiming.ptsInTimescales = 0;
decoder->imageTiming.duration = 1;
decoder->imageTiming.durationInTimescales = 1;
decoder->timescale = 1;
decoder->duration = 1;
decoder->durationInTimescales = 1;
decoder->ioStats.colorOBUSize = colorOBU.size;
decoder->ioStats.alphaOBUSize = alphaOBU.size;
if (colorOBUItem->ispePresent) {
decoder->containerWidth = colorOBUItem->ispe.width;
decoder->containerHeight = colorOBUItem->ispe.height;
} else {
decoder->containerWidth = 0;
decoder->containerHeight = 0;
}
if (colorOBUItem->av1CPresent) {
decoder->containerDepth = avifCodecConfigurationBoxGetDepth(&colorOBUItem->av1C);
} else {
decoder->containerDepth = 0;
}
}
return avifDecoderFlush(decoder);
}
avifResult avifDecoderNextImage(avifDecoder * decoder)
{
avifCodec * colorCodec = decoder->data->codec[AVIF_CODEC_PLANES_COLOR];
if (!colorCodec->getNextImage(colorCodec, decoder->image)) {
if (decoder->image->width) {
// We've sent at least one image, but we've run out now.
return AVIF_RESULT_NO_IMAGES_REMAINING;
}
return AVIF_RESULT_DECODE_COLOR_FAILED;
}
avifCodec * alphaCodec = decoder->data->codec[AVIF_CODEC_PLANES_ALPHA];
if (alphaCodec) {
if (!alphaCodec->getNextImage(alphaCodec, decoder->image)) {
return AVIF_RESULT_DECODE_ALPHA_FAILED;
}
} else {
avifImageFreePlanes(decoder->image, AVIF_PLANES_A);
}
#if defined(AVIF_FIX_STUDIO_ALPHA)
if (alphaCodec && alphaCodec->alphaLimitedRange(alphaCodec)) {
// Naughty! Alpha planes are supposed to be full range. Correct that here.
avifImageCopyDecoderAlpha(decoder->image);
if (avifImageUsesU16(decoder->image)) {
for (uint32_t j = 0; j < decoder->image->height; ++j) {
for (uint32_t i = 0; i < decoder->image->height; ++i) {
uint16_t * alpha = (uint16_t *)&decoder->image->alphaPlane[(i * 2) + (j * decoder->image->alphaRowBytes)];
*alpha = (uint16_t)avifLimitedToFullY(decoder->image->depth, *alpha);
}
}
} else {
for (uint32_t j = 0; j < decoder->image->height; ++j) {
for (uint32_t i = 0; i < decoder->image->height; ++i) {
uint8_t * alpha = &decoder->image->alphaPlane[i + (j * decoder->image->alphaRowBytes)];
*alpha = (uint8_t)avifLimitedToFullY(decoder->image->depth, *alpha);
}
}
}
}
#endif
++decoder->imageIndex;
if (decoder->data->sourceSampleTable) {
// Decoding from a track! Provide timing information.
decoder->imageTiming.timescale = decoder->timescale;
decoder->imageTiming.ptsInTimescales = 0;
for (int imageIndex = 0; imageIndex < decoder->imageIndex; ++imageIndex) {
decoder->imageTiming.ptsInTimescales += avifSampleTableGetImageDelta(decoder->data->sourceSampleTable, imageIndex);
}
decoder->imageTiming.durationInTimescales = avifSampleTableGetImageDelta(decoder->data->sourceSampleTable, decoder->imageIndex);
if (decoder->imageTiming.timescale > 0) {
decoder->imageTiming.pts = (double)decoder->imageTiming.ptsInTimescales / (double)decoder->imageTiming.timescale;
decoder->imageTiming.duration = (double)decoder->imageTiming.durationInTimescales / (double)decoder->imageTiming.timescale;
} else {
decoder->imageTiming.pts = 0.0;
decoder->imageTiming.duration = 0.0;
}
}
return AVIF_RESULT_OK;
}
avifResult avifDecoderNthImage(avifDecoder * decoder, uint32_t frameIndex)
{
int requestedIndex = (int)frameIndex;
if (requestedIndex == decoder->imageIndex) {
// We're here already, nothing to do
return AVIF_RESULT_OK;
}
if (requestedIndex == (decoder->imageIndex + 1)) {
// it's just the next image, nothing special here
return avifDecoderNextImage(decoder);
}
if (requestedIndex >= decoder->imageCount) {
// Impossible index
return AVIF_RESULT_NO_IMAGES_REMAINING;
}
// If we get here, a decoder flush is necessary
decoder->imageIndex = ((int)avifDecoderNearestKeyframe(decoder, frameIndex)) - 1; // prepare to read nearest keyframe
avifDecoderFlush(decoder);
for (;;) {
avifResult result = avifDecoderNextImage(decoder);
if (result != AVIF_RESULT_OK) {
return result;
}
if (requestedIndex == decoder->imageIndex) {
break;
}
}
return AVIF_RESULT_OK;
}
avifBool avifDecoderIsKeyframe(avifDecoder * decoder, uint32_t frameIndex)
{
if (decoder->data->colorInput) {
if (frameIndex < decoder->data->colorInput->samples.count) {
return decoder->data->colorInput->samples.sample[frameIndex].sync;
}
}
return AVIF_FALSE;
}
uint32_t avifDecoderNearestKeyframe(avifDecoder * decoder, uint32_t frameIndex)
{
for (; frameIndex != 0; --frameIndex) {
if (avifDecoderIsKeyframe(decoder, frameIndex)) {
break;
}
}
return frameIndex;
}
avifResult avifDecoderRead(avifDecoder * decoder, avifImage * image, avifROData * input)
{
avifResult result = avifDecoderParse(decoder, input);
if (result != AVIF_RESULT_OK) {
return result;
}
result = avifDecoderNextImage(decoder);
if (result != AVIF_RESULT_OK) {
return result;
}
if (!decoder->image) {
return AVIF_RESULT_NO_IMAGES_REMAINING;
}
avifImageCopy(image, decoder->image);
return AVIF_RESULT_OK;
}