gstreamer/subprojects/gst-plugins-bad/gst-libs/gst/codecparsers/gstav1parser.h

1887 lines
87 KiB
C

/*
* gstav1parser.h
*
* Copyright (C) 2018 Georg Ottinger
* Copyright (C) 2019-2020 Intel Corporation
* Author: Georg Ottinger<g.ottinger@gmx.at>
* Author: Junyan He<junyan.he@hotmail.com>
* Author: Victor Jaquez <vjaquez@igalia.com>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the
* Free Software Foundation, Inc., 51 Franklin St, Fifth Floor,
* Boston, MA 02110-1301, USA.
*/
#ifndef __GST_AV1_PARSER_H__
#define __GST_AV1_PARSER_H__
#ifndef GST_USE_UNSTABLE_API
#warning "The AV1 parsing library is unstable API and may change in future."
#warning "You can define GST_USE_UNSTABLE_API to avoid this warning."
#endif
#include <gst/gst.h>
#include <gst/codecparsers/codecparsers-prelude.h>
G_BEGIN_DECLS
#define GST_AV1_MAX_NUM_TEMPORAL_LAYERS 8
#define GST_AV1_MAX_NUM_SPATIAL_LAYERS 4
#define GST_AV1_MAX_TILE_WIDTH 4096
#define GST_AV1_MAX_TILE_AREA (4096 * 2304)
#define GST_AV1_TOTAL_REFS_PER_FRAME 8
#define GST_AV1_MAX_SEGMENTS 8
#define GST_AV1_SEG_LVL_MAX 8
#define GST_AV1_MAX_TILE_COLS 64
#define GST_AV1_MAX_TILE_ROWS 64
#define GST_AV1_REFS_PER_FRAME 7
#define GST_AV1_PRIMARY_REF_NONE 7
#define GST_AV1_SUPERRES_NUM 8
#define GST_AV1_SUPERRES_DENOM_MIN 9
#define GST_AV1_SUPERRES_DENOM_BITS 3
#define GST_AV1_MAX_LOOP_FILTER 63
#define GST_AV1_GM_ABS_TRANS_BITS 12
#define GST_AV1_GM_ABS_TRANS_ONLY_BITS 9
#define GST_AV1_GM_ABS_ALPHA_BITS 12
#define GST_AV1_GM_ALPHA_PREC_BITS 15
#define GST_AV1_GM_TRANS_PREC_BITS 6
#define GST_AV1_GM_TRANS_ONLY_PREC_BITS 3
#define GST_AV1_WARPEDMODEL_PREC_BITS 16
#define GST_AV1_WARP_PARAM_REDUCE_BITS 6
#define GST_AV1_SELECT_SCREEN_CONTENT_TOOLS 2
#define GST_AV1_SELECT_INTEGER_MV 2
#define GST_AV1_RESTORATION_TILESIZE_MAX 256
#define GST_AV1_SEG_LVL_ALT_Q 0
#define GST_AV1_SEG_LVL_REF_FRAME 5
/* Following defines are derived from the spec, but not mentioned by
* this particular name in the spec */
#define GST_AV1_CDEF_MAX (1 << 3)
#define GST_AV1_MAX_TILE_COUNT 512
#define GST_AV1_MAX_OPERATING_POINTS \
(GST_AV1_MAX_NUM_TEMPORAL_LAYERS * GST_AV1_MAX_NUM_SPATIAL_LAYERS)
#define GST_AV1_MAX_TEMPORAL_GROUP_SIZE 255
#define GST_AV1_MAX_TEMPORAL_GROUP_REFERENCES 7
#define GST_AV1_MAX_NUM_Y_POINTS 16
#define GST_AV1_MAX_NUM_CB_POINTS 16
#define GST_AV1_MAX_NUM_CR_POINTS 16
#define GST_AV1_MAX_NUM_POS_LUMA 25
#define GST_AV1_MAX_NUM_PLANES 3
#define GST_AV1_DIV_LUT_PREC_BITS 14
#define GST_AV1_DIV_LUT_BITS 8
#define GST_AV1_DIV_LUT_NUM (1 << GST_AV1_DIV_LUT_BITS)
typedef struct _GstAV1Parser GstAV1Parser;
typedef struct _GstAV1ParserState GstAV1ParserState;
typedef struct _GstAV1OBUHeader GstAV1OBUHeader;
typedef struct _GstAV1OBU GstAV1OBU;
typedef struct _GstAV1SequenceHeaderOBU GstAV1SequenceHeaderOBU;
typedef struct _GstAV1MetadataOBU GstAV1MetadataOBU;
typedef struct _GstAV1FrameHeaderOBU GstAV1FrameHeaderOBU;
typedef struct _GstAV1TileListOBU GstAV1TileListOBU;
typedef struct _GstAV1TileListOBUEntry GstAV1TileListOBUEntry;
typedef struct _GstAV1TileGroupOBU GstAV1TileGroupOBU;
typedef struct _GstAV1TileGroupOBUEntry GstAV1TileGroupOBUEntry;
typedef struct _GstAV1FrameOBU GstAV1FrameOBU;
typedef struct _GstAV1OperatingPoint GstAV1OperatingPoint;
typedef struct _GstAV1DecoderModelInfo GstAV1DecoderModelInfo;
typedef struct _GstAV1TimingInfo GstAV1TimingInfo;
typedef struct _GstAV1ColorConfig GstAV1ColorConfig;
typedef struct _GstAV1MetadataITUT_T35 GstAV1MetadataITUT_T35;
typedef struct _GstAV1MetadataHdrCll GstAV1MetadataHdrCll;
typedef struct _GstAV1MetadataHdrMdcv GstAV1MetadataHdrMdcv;
typedef struct _GstAV1MetadataScalability GstAV1MetadataScalability;
typedef struct _GstAV1MetadataTimecode GstAV1MetadataTimecode;
typedef struct _GstAV1LoopFilterParams GstAV1LoopFilterParams;
typedef struct _GstAV1QuantizationParams GstAV1QuantizationParams;
typedef struct _GstAV1SegmenationParams GstAV1SegmenationParams;
typedef struct _GstAV1TileInfo GstAV1TileInfo;
typedef struct _GstAV1CDEFParams GstAV1CDEFParams;
typedef struct _GstAV1LoopRestorationParams GstAV1LoopRestorationParams;
typedef struct _GstAV1GlobalMotionParams GstAV1GlobalMotionParams;
typedef struct _GstAV1FilmGrainParams GstAV1FilmGrainParams;
typedef struct _GstAV1ReferenceFrameInfo GstAV1ReferenceFrameInfo;
typedef struct _GstAV1ReferenceFrameInfoEntry GstAV1ReferenceFrameInfoEntry;
/**
* GstAV1ParserResult:
* @GST_AV1_PARSER_OK: successful return
* @GST_AV1_PARSER_NO_MORE_DATA: the parser needs more data for one OBU
* @GST_AV1_PARSER_DROP: no need to handle this OBU, skip it
* @GST_AV1_PARSER_BITSTREAM_ERROR: stream error, for example, include invalid bits
* @GST_AV1_PARSER_MISSING_OBU_REFERENCE: no reference, for example, no sequence found
* @GST_AV1_PARSER_INVALID_OPERATION: something like invalid parameters
*
* Defines the result of parser process
*/
typedef enum {
GST_AV1_PARSER_OK = 0,
GST_AV1_PARSER_NO_MORE_DATA = 1,
GST_AV1_PARSER_DROP = 2,
GST_AV1_PARSER_BITSTREAM_ERROR = 3,
GST_AV1_PARSER_MISSING_OBU_REFERENCE = 4,
GST_AV1_PARSER_INVALID_OPERATION = 5,
} GstAV1ParserResult;
/**
* GstAV1Profile:
* @GST_AV1_PROFILE_0: 8-bit and 10-bit 4:2:0 and 4:0:0 only.
* @GST_AV1_PROFILE_1: 8-bit and 10-bit 4:4:4.
* @GST_AV1_PROFILE_2: 8-bit and 10-bit 4:2:2, 12-bit 4:0:0 4:2:2 and 4:4:4
* @GST_AV1_PROFILE_UNDEFINED: unknow AV1 profile (Since: 1.20)
*
* Defines the AV1 profiles
*/
/**
* GST_AV1_PROFILE_UNDEFINED:
*
* unknow AV1 profile
*
* Since: 1.20
*/
typedef enum {
GST_AV1_PROFILE_0 = 0,
GST_AV1_PROFILE_1 = 1,
GST_AV1_PROFILE_2 = 2,
GST_AV1_PROFILE_UNDEFINED,
} GstAV1Profile;
/**
* GstAV1OBUType:
* @GST_AV1_OBU_RESERVED_0: Reserved 0
* @GST_AV1_OBU_SEQUENCE_HEADER: Sequence Header OBU
* @GST_AV1_OBU_TEMPORAL_DELIMITER: Temporal Delimiter OBU
* @GST_AV1_OBU_FRAME_HEADER: Frame Header OBU
* @GST_AV1_OBU_TILE_GROUP: Tile Group OBU
* @GST_AV1_OBU_METADATA: Metadata OBU
* @GST_AV1_OBU_FRAME: Frame OBU (includes Frame Header and one Tile Group)
* @GST_AV1_OBU_REDUNDANT_FRAME_HEADER: Redundant Frame Header OBU
* @GST_AV1_OBU_TILE_LIST: Tile LIst OBU
* @GST_AV1_OBU_RESERVED_9: Reserved 9
* @GST_AV1_OBU_RESERVED_10: Reserved 10
* @GST_AV1_OBU_RESERVED_11: Reserved 11
* @GST_AV1_OBU_RESERVED_12: Reserved 12
* @GST_AV1_OBU_RESERVED_13: Reserved 13
* @GST_AV1_OBU_RESERVED_14: Reserved 14
* @GST_AV1_OBU_PADDING: Padding
*
* Defines all the possible OBU types
*/
typedef enum {
GST_AV1_OBU_RESERVED_0 = 0,
GST_AV1_OBU_SEQUENCE_HEADER = 1,
GST_AV1_OBU_TEMPORAL_DELIMITER = 2,
GST_AV1_OBU_FRAME_HEADER = 3,
GST_AV1_OBU_TILE_GROUP = 4,
GST_AV1_OBU_METADATA = 5,
GST_AV1_OBU_FRAME = 6,
GST_AV1_OBU_REDUNDANT_FRAME_HEADER = 7,
GST_AV1_OBU_TILE_LIST = 8,
GST_AV1_OBU_RESERVED_9 = 9,
GST_AV1_OBU_RESERVED_10 = 10,
GST_AV1_OBU_RESERVED_11 = 11,
GST_AV1_OBU_RESERVED_12 = 12,
GST_AV1_OBU_RESERVED_13 = 13,
GST_AV1_OBU_RESERVED_14 = 14,
GST_AV1_OBU_PADDING = 15,
} GstAV1OBUType;
/**
* GstAV1SeqLevels:
* @GST_AV1_SEQ_LEVEL_2_0: Level 2.0
* @GST_AV1_SEQ_LEVEL_2_1: Level 2.1
* @GST_AV1_SEQ_LEVEL_2_2: Level 2.2
* @GST_AV1_SEQ_LEVEL_2_3: Level 2.3
* @GST_AV1_SEQ_LEVEL_3_0: Level 3.0
* @GST_AV1_SEQ_LEVEL_3_1: Level 3.1
* @GST_AV1_SEQ_LEVEL_3_2: Level 3.2
* @GST_AV1_SEQ_LEVEL_3_3: Level 3.3
* @GST_AV1_SEQ_LEVEL_4_0: Level 4.0
* @GST_AV1_SEQ_LEVEL_4_1: Level 4.1
* @GST_AV1_SEQ_LEVEL_4_2: Level 4.2
* @GST_AV1_SEQ_LEVEL_4_3: Level 4.3
* @GST_AV1_SEQ_LEVEL_5_0: Level 5.0
* @GST_AV1_SEQ_LEVEL_5_1: Level 5.1
* @GST_AV1_SEQ_LEVEL_5_2: Level 5.2
* @GST_AV1_SEQ_LEVEL_5_3: Level 5.3
* @GST_AV1_SEQ_LEVEL_6_0: Level 6.0
* @GST_AV1_SEQ_LEVEL_6_1: Level 6.1
* @GST_AV1_SEQ_LEVEL_6_2: Level 6.2
* @GST_AV1_SEQ_LEVEL_6_3: Level 6.3
* @GST_AV1_SEQ_LEVEL_7_0: Level 7.0
* @GST_AV1_SEQ_LEVEL_7_1: Level 7.1
* @GST_AV1_SEQ_LEVEL_7_2: Level 7.2
* @GST_AV1_SEQ_LEVEL_7_3: Level 7.3
* @GST_AV1_SEQ_LEVELS: all valid levels
* @GST_AV1_SEQ_LEVEL_MAX: Maximum parameters
*
* Defines all the possible OBU types
*/
typedef enum {
GST_AV1_SEQ_LEVEL_2_0 = 0,
GST_AV1_SEQ_LEVEL_2_1 = 1,
GST_AV1_SEQ_LEVEL_2_2 = 2,
GST_AV1_SEQ_LEVEL_2_3 = 3,
GST_AV1_SEQ_LEVEL_3_0 = 4,
GST_AV1_SEQ_LEVEL_3_1 = 5,
GST_AV1_SEQ_LEVEL_3_2 = 6,
GST_AV1_SEQ_LEVEL_3_3 = 7,
GST_AV1_SEQ_LEVEL_4_0 = 8,
GST_AV1_SEQ_LEVEL_4_1 = 9,
GST_AV1_SEQ_LEVEL_4_2 = 10,
GST_AV1_SEQ_LEVEL_4_3 = 11,
GST_AV1_SEQ_LEVEL_5_0 = 12,
GST_AV1_SEQ_LEVEL_5_1 = 13,
GST_AV1_SEQ_LEVEL_5_2 = 14,
GST_AV1_SEQ_LEVEL_5_3 = 15,
GST_AV1_SEQ_LEVEL_6_0 = 16,
GST_AV1_SEQ_LEVEL_6_1 = 17,
GST_AV1_SEQ_LEVEL_6_2 = 18,
GST_AV1_SEQ_LEVEL_6_3 = 19,
GST_AV1_SEQ_LEVEL_7_0 = 20,
GST_AV1_SEQ_LEVEL_7_1 = 21,
GST_AV1_SEQ_LEVEL_7_2 = 22,
GST_AV1_SEQ_LEVEL_7_3 = 23,
GST_AV1_SEQ_LEVELS,
GST_AV1_SEQ_LEVEL_MAX = 31
} GstAV1SeqLevels;
/**
* GstAV1MetadataType:
* @GST_AV1_METADATA_TYPE_RESERVED_0: Reserved 0
* @GST_AV1_METADATA_TYPE_HDR_CLL: Metadata high dynamic range content
* light level semantics
* @GST_AV1_METADATA_TYPE_HDR_MDCV: Metadata high dynamic range mastering
* display color volume semantics
* @GST_AV1_METADATA_TYPE_SCALABILITY: Metadata scalability semantics
* @GST_AV1_METADATA_TYPE_ITUT_T35: Metadata ITUT T35 semantics
* @GST_AV1_METADATA_TYPE_TIMECODE: Timecode semantics
*/
typedef enum {
GST_AV1_METADATA_TYPE_RESERVED_0 = 0,
GST_AV1_METADATA_TYPE_HDR_CLL = 1,
GST_AV1_METADATA_TYPE_HDR_MDCV = 2,
GST_AV1_METADATA_TYPE_SCALABILITY = 3,
GST_AV1_METADATA_TYPE_ITUT_T35 = 4,
GST_AV1_METADATA_TYPE_TIMECODE = 5,
} GstAV1MetadataType;
/**
* GstAV1ScalabilityModes:
* @GST_AV1_SCALABILITY_L1T2: 1 spatial layer, 2 temporal layers
* @GST_AV1_SCALABILITY_L1T3: 1 spatial layer, 3 temporal layers
* @GST_AV1_SCALABILITY_L2T1: 2 spatial layer (ratio 2:1), 1 temporal layer,
* inter-layer dependency
* @GST_AV1_SCALABILITY_L2T2: 2 spatial layer (ratio 2:1), 2 temporal layer,
* inter-layer dependency
* @GST_AV1_SCALABILITY_L2T3: 2 spatial layer (ratio 2:1), 3 temporal layer,
* inter-layer dependency
* @GST_AV1_SCALABILITY_S2T1: 2 spatial layer (ratio 2:1), 1 temporal layer
* @GST_AV1_SCALABILITY_S2T2: 2 spatial layer (ratio 2:1), 2 temporal layer
* @GST_AV1_SCALABILITY_S2T3: 2 spatial layer (ratio 2:1), 3 temporal layer
* @GST_AV1_SCALABILITY_L2T1h: 2 spatial layer (ratio 1.5:1), 1 temporal layer,
* inter-layer dependency
* @GST_AV1_SCALABILITY_L2T2h: 2 spatial layer (ratio 1.5:1), 2 temporal layer,
* inter-layer dependency
* @GST_AV1_SCALABILITY_L2T3h: 2 spatial layer (ratio 1.5:1), 3 temporal layer,
* inter-layer dependency
* @GST_AV1_SCALABILITY_S2T1h: 2 spatial layer (ratio 1.5:1), 1 temporal layer
* @GST_AV1_SCALABILITY_S2T2h: 2 spatial layer (ratio 1.5:1), 2 temporal layer
* @GST_AV1_SCALABILITY_S2T3h: 2 spatial layer (ratio 1.5:1), 3 temporal layer
* @GST_AV1_SCALABILITY_SS: Use scalability structure #GstAV1MetadataScalability
*/
typedef enum {
GST_AV1_SCALABILITY_L1T2 = 0,
GST_AV1_SCALABILITY_L1T3 = 1,
GST_AV1_SCALABILITY_L2T1 = 2,
GST_AV1_SCALABILITY_L2T2 = 3,
GST_AV1_SCALABILITY_L2T3 = 4,
GST_AV1_SCALABILITY_S2T1 = 5,
GST_AV1_SCALABILITY_S2T2 = 6,
GST_AV1_SCALABILITY_S2T3 = 7,
GST_AV1_SCALABILITY_L2T1h = 8,
GST_AV1_SCALABILITY_L2T2h = 9,
GST_AV1_SCALABILITY_L2T3h = 10,
GST_AV1_SCALABILITY_S2T1h = 11,
GST_AV1_SCALABILITY_S2T2h = 12,
GST_AV1_SCALABILITY_S2T3h = 13,
GST_AV1_SCALABILITY_SS = 14,
} GstAV1ScalabilityModes;
/**
* GstAV1ColorPrimaries:
* @GST_AV1_CP_BT_709: BT.709
* @GST_AV1_CP_UNSPECIFIED: Unspecified
* @GST_AV1_CP_BT_470_M: BT.470 System M (historical)
* @GST_AV1_CP_BT_470_B_G:BT.470 System B, G (historical),
* @GST_AV1_CP_BT_601: BT.601
* @GST_AV1_CP_SMPTE_240: SMPTE 240
* @GST_AV1_CP_GENERIC_FILM: Generic film (color filters using illuminant C,
* @GST_AV1_CP_BT_2020: BT.2020, BT.2100,
* @GST_AV1_CP_XYZ: SMPTE 428 (CIE 1921 XYZ),
* @GST_AV1_CP_SMPTE_431: SMPTE RP 431-2
* @GST_AV1_CP_SMPTE_432: SMPTE EG 432-1
* @GST_AV1_CP_EBU_3213: EBU Tech. 3213-E
*/
typedef enum {
GST_AV1_CP_BT_709 = 1,
GST_AV1_CP_UNSPECIFIED = 2,
GST_AV1_CP_BT_470_M = 4,
GST_AV1_CP_BT_470_B_G = 5,
GST_AV1_CP_BT_601 = 6,
GST_AV1_CP_SMPTE_240 = 7,
GST_AV1_CP_GENERIC_FILM = 8,
GST_AV1_CP_BT_2020 = 9,
GST_AV1_CP_XYZ = 10,
GST_AV1_CP_SMPTE_431 = 11,
GST_AV1_CP_SMPTE_432 = 12,
GST_AV1_CP_EBU_3213 = 22,
} GstAV1ColorPrimaries;
/**
* GstAV1TransferCharacteristics:
* @GST_AV1_TC_RESERVED_0: For future use
* @GST_AV1_TC_BT_709: BT.709
* @GST_AV1_TC_UNSPECIFIED: Unspecified
* @GST_AV1_TC_RESERVED_3: For future use
* @GST_AV1_TC_BT_470_M: BT.470 System M (historical)
* @GST_AV1_TC_BT_470_B_G: BT.470 System B, G (historical)
* @GST_AV1_TC_BT_601: BT.601
* @GST_AV1_TC_SMPTE_240: SMPTE 240 M
* @GST_AV1_TC_LINEAR: Linear
* @GST_AV1_TC_LOG_100: Logarithmic (100 : 1 range)
* @GST_AV1_TC_LOG_100_SQRT10: Logarithmic (100 * Sqrt(10) : 1 range)
* @GST_AV1_TC_IEC_61966: IEC 61966-2-4
* @GST_AV1_TC_BT_1361: BT.1361
* @GST_AV1_TC_SRGB: sRGB or sYCC
* @GST_AV1_TC_BT_2020_10_BIT: BT.2020 10-bit systems
* @GST_AV1_TC_BT_2020_12_BIT: BT.2020 12-bit systems
* @GST_AV1_TC_SMPTE_2084: SMPTE ST 2084, ITU BT.2100 PQ
* @GST_AV1_TC_SMPTE_428: SMPTE ST 428
* @GST_AV1_TC_HLG: BT.2100 HLG, ARIB STD-B67
*/
typedef enum {
GST_AV1_TC_RESERVED_0 = 0,
GST_AV1_TC_BT_709 = 1,
GST_AV1_TC_UNSPECIFIED = 2,
GST_AV1_TC_RESERVED_3 = 3,
GST_AV1_TC_BT_470_M = 4,
GST_AV1_TC_BT_470_B_G = 5,
GST_AV1_TC_BT_601 = 6,
GST_AV1_TC_SMPTE_240 = 7,
GST_AV1_TC_LINEAR = 8,
GST_AV1_TC_LOG_100 = 9,
GST_AV1_TC_LOG_100_SQRT10 = 10,
GST_AV1_TC_IEC_61966 = 11,
GST_AV1_TC_BT_1361 = 12,
GST_AV1_TC_SRGB = 13,
GST_AV1_TC_BT_2020_10_BIT = 14,
GST_AV1_TC_BT_2020_12_BIT = 15,
GST_AV1_TC_SMPTE_2084 = 16,
GST_AV1_TC_SMPTE_428 = 17,
GST_AV1_TC_HLG = 18,
} GstAV1TransferCharacteristics;
/**
* GstAV1MatrixCoefficients:
* @GST_AV1_MC_IDENTITY: Identity matrix
* @GST_AV1_MC_BT_709: BT.709
* @GST_AV1_MC_UNSPECIFIED: Unspecified
* @GST_AV1_MC_RESERVED_3: For future use
* @GST_AV1_MC_FCC: US FCC 73.628
* @GST_AV1_MC_BT_470_B_G: BT.470 System B, G (historical)
* @GST_AV1_MC_BT_601: BT.601
* @GST_AV1_MC_SMPTE_240: SMPTE 240 M
* @GST_AV1_MC_SMPTE_YCGCO: YCgCo
* @GST_AV1_MC_BT_2020_NCL: BT.2020 non-constant luminance, BT.2100 YCbCr
* @GST_AV1_MC_BT_2020_CL: BT.2020 constant luminance
* @GST_AV1_MC_SMPTE_2085: SMPTE ST 2085 YDzDx
* @GST_AV1_MC_CHROMAT_NCL: Chromaticity-derived non-constant luminance
* @GST_AV1_MC_CHROMAT_CL: Chromaticity-derived constant luminancw
* @GST_AV1_MC_ICTCP: BT.2100 ICtCp
*/
typedef enum {
GST_AV1_MC_IDENTITY = 0,
GST_AV1_MC_BT_709 = 1,
GST_AV1_MC_UNSPECIFIED = 2,
GST_AV1_MC_RESERVED_3 = 3,
GST_AV1_MC_FCC = 4,
GST_AV1_MC_BT_470_B_G = 5,
GST_AV1_MC_BT_601 = 6,
GST_AV1_MC_SMPTE_240 = 7,
GST_AV1_MC_SMPTE_YCGCO = 8,
GST_AV1_MC_BT_2020_NCL = 9,
GST_AV1_MC_BT_2020_CL = 10,
GST_AV1_MC_SMPTE_2085 = 11,
GST_AV1_MC_CHROMAT_NCL = 12,
GST_AV1_MC_CHROMAT_CL = 13,
GST_AV1_MC_ICTCP = 14,
} GstAV1MatrixCoefficients;
/**
* GstAV1ChromaSamplePositions:
* @GST_AV1_CSP_UNKNOWN: Unknown (in this case the source video transfer
* function must be signaled outside the AV1 bitstream).
* @GST_AV1_CSP_VERTICAL: Horizontally co-located with (0, 0) luma sample,
* vertical position in the middle between two luma samples.
* @GST_AV1_CSP_COLOCATED: co-located with (0, 0) luma sample.
* @GST_AV1_CSP_RESERVED: For future use.
*/
typedef enum {
GST_AV1_CSP_UNKNOWN = 0,
GST_AV1_CSP_VERTICAL = 1,
GST_AV1_CSP_COLOCATED = 2,
GST_AV1_CSP_RESERVED = 3,
} GstAV1ChromaSamplePositions;
/**
* GstAV1FrameType:
* @GST_AV1_KEY_FRAME: Key Frame
* @GST_AV1_INTER_FRAME: InterFrame
* @GST_AV1_INTRA_ONLY_FRAME: Intra-Only Frame
* @GST_AV1_SWITCH_FRAME: Switch Frame
*/
typedef enum {
GST_AV1_KEY_FRAME = 0,
GST_AV1_INTER_FRAME = 1,
GST_AV1_INTRA_ONLY_FRAME = 2,
GST_AV1_SWITCH_FRAME = 3,
} GstAV1FrameType;
/**
* GstAV1InterpolationFilter:
* @GST_AV1_INTERPOLATION_FILTER_EIGHTTAP: Eighttap
* @GST_AV1_INTERPOLATION_FILTER_EIGHTTAP_SMOOTH: Eighttap Smooth
* @GST_AV1_INTERPOLATION_FILTER_EIGHTTAP_SHARP: Eighttap Sharp
* @GST_AV1_INTERPOLATION_FILTER_BILINEAR: Bilinear
* @GST_AV1_INTERPOLATION_FILTER_SWITCHABLE: Filter is swichtable
*/
typedef enum {
GST_AV1_INTERPOLATION_FILTER_EIGHTTAP = 0,
GST_AV1_INTERPOLATION_FILTER_EIGHTTAP_SMOOTH = 1,
GST_AV1_INTERPOLATION_FILTER_EIGHTTAP_SHARP = 2,
GST_AV1_INTERPOLATION_FILTER_BILINEAR = 3,
GST_AV1_INTERPOLATION_FILTER_SWITCHABLE = 4,
} GstAV1InterpolationFilter;
/**
* GstAV1TXModes:
* @GST_AV1_TX_MODE_ONLY_4x4: the inverse transform will use only 4x4 transforms.
* @GST_AV1_TX_MODE_LARGEST: the inverse transform will use the largest transform
* size that fits inside the block.
* @GST_AV1_TX_MODE_SELECT: the choice of transform size is specified explicitly
* for each block.
*/
typedef enum {
GST_AV1_TX_MODE_ONLY_4x4 = 0,
GST_AV1_TX_MODE_LARGEST = 1,
GST_AV1_TX_MODE_SELECT = 2,
} GstAV1TXModes;
/**
* GstAV1FrameRestorationType:
* @GST_AV1_FRAME_RESTORE_NONE: no filtering is applied
* @GST_AV1_FRAME_RESTORE_WIENER: Wiener filter process is invoked
* @GST_AV1_FRAME_RESTORE_SGRPROJ: self guided filter proces is invoked
* @GST_AV1_FRAME_RESTORE_SWITCHABLE: restoration filter is swichtable
*/
typedef enum {
GST_AV1_FRAME_RESTORE_NONE = 0,
GST_AV1_FRAME_RESTORE_WIENER = 1,
GST_AV1_FRAME_RESTORE_SGRPROJ = 2,
GST_AV1_FRAME_RESTORE_SWITCHABLE = 3,
} GstAV1FrameRestorationType;
/**
* GstAV1ReferenceFrame:
* @GST_AV1_REF_INTRA_FRAME: Intra Frame Reference
* @GST_AV1_REF_LAST_FRAME: Last Reference Frame
* @GST_AV1_REF_LAST2_FRAME: Last2 Reference Frame
* @GST_AV1_REF_LAST3_FRAME: Last3 Reference Frame
* @GST_AV1_REF_GOLDEN_FRAME: Golden Reference Frame
* @GST_AV1_REF_BWDREF_FRAME: BWD Reference Frame
* @GST_AV1_REF_ALTREF2_FRAME: Alternative2 Reference Frame
* @GST_AV1_REF_ALTREF_FRAME: Alternative Reference Frame
* @GST_AV1_NUM_REF_FRAMES: Total Reference Frame Number
*/
typedef enum {
GST_AV1_REF_INTRA_FRAME = 0,
GST_AV1_REF_LAST_FRAME = 1,
GST_AV1_REF_LAST2_FRAME = 2,
GST_AV1_REF_LAST3_FRAME = 3,
GST_AV1_REF_GOLDEN_FRAME = 4,
GST_AV1_REF_BWDREF_FRAME = 5,
GST_AV1_REF_ALTREF2_FRAME = 6,
GST_AV1_REF_ALTREF_FRAME = 7,
GST_AV1_NUM_REF_FRAMES
} GstAV1ReferenceFrame;
/**
* GstAV1WarpModelType:
* @GST_AV1_WARP_MODEL_IDENTITY: Warp model is just an identity transform
* @GST_AV1_WARP_MODEL_TRANSLATION: Warp model is a pure translation
* @GST_AV1_WARP_MODEL_ROTZOOM: Warp model is a rotation + symmetric zoom
* + translation
* @GST_AV1_WARP_MODEL_AFFINE: Warp model is a general affine transform
*/
typedef enum {
GST_AV1_WARP_MODEL_IDENTITY = 0,
GST_AV1_WARP_MODEL_TRANSLATION = 1,
GST_AV1_WARP_MODEL_ROTZOOM = 2,
GST_AV1_WARP_MODEL_AFFINE = 3,
} GstAV1WarpModelType;
/**
* GstAV1OBUHeader:
* @obu_type: the type of data structure contained in the OBU payload.
* @obu_extention_flag: indicates if OBU header extention is present.
* @obu_has_size_field: equal to 1 indicates that the obu_size syntax element will be
* present. @obu_has_size_field equal to 0 indicates that the @obu_size syntax element
* will not be present.
* @obu_temporal_id: specifies the temporal level of the data contained in the OBU.
* @obu_spatial_id: specifies the spatial level of the data contained in the OBU.
*
* Collect info for OBU header and OBU extension header if
* obu_extension_flag == 1.
*/
struct _GstAV1OBUHeader {
GstAV1OBUType obu_type;
gboolean obu_extention_flag;
gboolean obu_has_size_field;
guint8 obu_temporal_id;
guint8 obu_spatial_id;
};
/**
* GstAV1OBU:
* @header: a #GstAV1OBUHeader OBU Header
* @obu_type: the type of data structure contained in the OBU payload.
* @data: references the current data chunk that holds the OBU
* @obu_size: size of the OBU, not include header size
*
* It is the general representation of AV1 OBU (Open Bitstream
* Unit). One OBU include its header and payload.
*/
struct _GstAV1OBU {
GstAV1OBUHeader header;
GstAV1OBUType obu_type;
guint8 *data;
guint32 obu_size;
};
/**
* GstAV1OperatingPoint:
* @seq_level_idx: specifies the level that the coded video sequence conforms to.
* @seq_tier: specifies the tier that the coded video sequence conforms to.
* @idc: contains a bitmask that indicates which spatial and temporal layers should be
* decoded. Bit k is equal to 1 if temporal layer k should be decoded (for k between
* 0 and 7). Bit j+8 is equal to 1 if spatial layer j should be decoded (for j between
* 0 and 3).
* @decoder_model_present_for_this_op: equal to one indicates that there is a decoder model
* associated with this operating point. @decoder_model_present_for_this_op equal to zero
* indicates that there is not a decoder model associated.
* @decoder_buffer_delay: specifies the time interval between the arrival of the first bit
* in the smoothing buffer and the subsequent removal of the data that belongs to the
* first coded frame for operating point op, measured in units of 1/90000 seconds. The
* length of @decoder_buffer_delay is specified by @buffer_delay_length_minus_1 + 1, in bits.
* @encoder_buffer_delay: specifies, in combination with @decoder_buffer_delay syntax element,
* the first bit arrival time of frames to be decoded to the smoothing buffer.
* @encoder_buffer_delay is measured in units of 1/90000 seconds. For a video sequence that
* includes one or more random access points the sum of @decoder_buffer_delay and
* @encoder_buffer_delay shall be kept constant.
* @low_delay_mode_flag: equal to 1 indicates that the smoothing buffer operates in low-delay
* mode for operating point op. In low-delay mode late decode times and buffer underflow
* are both permitted. @low_delay_mode_flag equal to 0 indicates that the smoothing buffer
* operates in strict mode, where buffer underflow is not allowed.
* @initial_display_delay_present_for_this_op: equal to 1 indicates that
* @initial_display_delay_minus_1 is specified for this operating. 0 indicates that
* @initial_display_delay_minus_1 is not specified for this operating point.
* @initial_display_delay_minus_1: plus 1 specifies, for operating point i, the number of
* decoded frames that should be present in the buffer pool before the first presentable
* frame is displayed. This will ensure that all presentable frames in the sequence can
* be decoded at or before the time that they are scheduled for display.
*/
struct _GstAV1OperatingPoint {
guint8 seq_level_idx;
guint8 seq_tier;
guint16 idc;
gboolean decoder_model_present_for_this_op;
guint8 decoder_buffer_delay;
guint8 encoder_buffer_delay;
gboolean low_delay_mode_flag;
gboolean initial_display_delay_present_for_this_op;
guint8 initial_display_delay_minus_1;
};
/**
* GstAV1DecoderModelInfo:
* @buffer_delay_length_minus_1: plus 1 specifies the length of the
* @decoder_buffer_delay and the @encoder_buffer_delay syntax elements,
* in bits.
* @num_units_in_decoding_tick: is the number of time units of a decoding clock
* operating at the frequency @time_scale Hz that corresponds to one increment
* of a clock tick counter.
* @buffer_removal_time_length_minus_1: plus 1 specifies the length of the
* @buffer_removal_time syntax element, in bits.
* @frame_presentation_time_length_minus_1: plus 1 specifies the length of the
* @frame_presentation_time syntax element, in bits.
*/
struct _GstAV1DecoderModelInfo {
guint8 buffer_delay_length_minus_1;
guint32 num_units_in_decoding_tick;
guint8 buffer_removal_time_length_minus_1;
guint8 frame_presentation_time_length_minus_1;
};
/**
* GstAV1TimingInfo:
* @num_units_in_display_tick: is the number of time units of a clock operating at the
* frequency @time_scale Hz that corresponds to one increment of a clock tick counter.
* A clock tick, in seconds, is equal to num_units_in_display_tick divided by time_scale.
* It is a requirement of bitstream conformance that num_units_in_display_tick is greater
* than 0.
* @time_scale: is the number of time units that pass in one second. It is a requirement of
* bitstream conformance that @time_scale is greater than 0.
* @equal_picture_interval: equal to 1 indicates that pictures should be displayed according
* to their output order with the number of ticks between two consecutive pictures (without
* dropping frames) specified by @num_ticks_per_picture_minus_1 + 1. @equal_picture_interval
* equal to 0 indicates that the interval between two consecutive pictures is not specified.
* @num_ticks_per_picture_minus_1: plus 1 specifies the number of clock ticks corresponding
* to output time between two consecutive pictures in the output order. It is a requirement
* of bitstream conformance that the value of @num_ticks_per_picture_minus_1 shall be in the
* range of 0 to (1 << 32) - 2, inclusive.
*/
struct _GstAV1TimingInfo {
guint32 num_units_in_display_tick;
guint32 time_scale;
gboolean equal_picture_interval;
guint32 num_ticks_per_picture_minus_1;
};
/**
* GstAV1ColorConfig:
* @high_bitdepth: syntax element which, together with @seq_profile, determine the bit depth.
* @twelve_bit: is syntax elements which, together with @seq_profile and @high_bitdepth,
* determines the bit depth.
* @mono_chrome: equal to 1 indicates that the video does not contain U and V color planes.
* @mono_chrome equal to 0 indicates that the video contains Y, U, and V color planes.
* @color_description_present_flag: equal to 1 specifies that color_primaries,
* @transfer_characteristics, and @matrix_coefficients are present.
* @color_description_present_flag equal to 0 specifies that @color_primaries,
* @transfer_characteristics and @matrix_coefficients are not present.
* @color_primaries: is an integer that is defined by the "Color primaries" section of
* ISO/IEC 23091-4/ITU-T H.273.
* @transfer_characteristics: is an integer that is defined by the "Transfer characteristics"
* section of ISO/IEC 23091-4/ITU-T H.273.
* @matrix_coefficients: is an integer that is defined by the "Matrix coefficients" section
* of ISO/IEC 23091-4/ITU-T H.273.
* @color_range: is a binary value that is associated with the VideoFullRangeFlag variable
* specified in ISO/IEC 23091-4/ITU-T H.273. color range equal to 0 shall be referred to
* as the studio swing representation and color range equal to 1 shall be referred to as
* the full swing representation for all intents relating to this specification.
* @subsampling_x, @subsampling_y: specify the chroma subsampling format. If
* @matrix_coefficients is equal to GST_AV1_MC_IDENTITY, it is a requirement of bitstream
* conformance that @subsampling_x is equal to 0 and @subsampling_y is equal to 0.
* @chroma_sample_position specifies the sample position for subsampled streams:
* @separate_uv_delta_q: equal to 1 indicates that the U and V planes may have separate
* delta quantizer values. @separate_uv_delta_q equal to 0 indicates that the U and V
* planes will share the same delta quantizer value.
*/
struct _GstAV1ColorConfig {
gboolean high_bitdepth;
gboolean twelve_bit;
gboolean mono_chrome;
gboolean color_description_present_flag;
GstAV1ColorPrimaries color_primaries;
GstAV1TransferCharacteristics transfer_characteristics;
GstAV1MatrixCoefficients matrix_coefficients;
gboolean color_range;
guint8 subsampling_x;
guint8 subsampling_y;
GstAV1ChromaSamplePositions chroma_sample_position;
gboolean separate_uv_delta_q;
};
/**
* GstAV1SequenceHeaderOBU:
* @seq_profile: specifies the features that can be used in the coded video sequence
* @still_picture: equal to 1 specifies that the bitstream contains only one coded frame.
* @reduced_still_picture_header: specifies that the syntax elements not needed by a still
* picture are omitted.
* @frame_width_bits_minus_1: specifies the number of bits minus 1 used for transmitting
* the frame width syntax elements.
* @frame_height_bits_minus_1: specifies the number of bits minus 1 used for transmitting
* the frame height syntax elements.
* @max_frame_width_minus_1: specifies the maximum frame width minus 1 for the frames
* represented by this sequenceheader.
* @max_frame_height_minus_1: specifies the maximum frame height minus 1 for the frames
* represented by this sequenceheader.
* @frame_id_numbers_present_flag: specifies whether frame id numbers are present in the bitstream.
* @delta_frame_id_length_minus_2: specifies the number of bits minus 2 used to encode
* delta_frame_id syntax elements.
* @additional_frame_id_length_minus_1: is used to calculate the number of bits used to
* encode the frame_id syntax element.
* @use_128x128_superblock: when equal to 1, indicates that superblocks contain 128x128 luma
* samples. When equal to 0, it indicates that superblocks contain 64x64 luma samples.
* (The number of contained chroma samples depends on @subsampling_x and @subsampling_y).
* @enable_filter_intra: equal to 1 specifies that the @use_filter_intra syntax element may
* be present. @enable_filter_intra equal to 0 specifies that the @use_filter_intra syntax
* element will not be present.
* @enable_intra_edge_filter: specifies whether the intra edge filtering process should be enabled.
* @enable_interintra_compound: equal to 1 specifies that the mode info for inter blocks may
* contain the syntax element interintra. @enable_interintra_compound equal to 0 specifies
* that the syntax element interintra will not be present.
* @enable_masked_compound: equal to 1 specifies that the mode info for inter blocks may
* contain the syntax element @compound_type. @enable_masked_compound equal to 0 specifies
* that the syntax element @compound_type will not be present.
* @enable_warped_motion: equal to 1 indicates that the allow_warped_motion syntax element
* may be present. @enable_warped_motion equal to 0 indicates that the @allow_warped_motion
* syntax element will not be present.
* @enable_order_hint: equal to 1 indicates that tools based on the values of order hints
* may be used. @enable_order_hint equal to 0 indicates that tools based on order hints
* are disabled.
* @enable_dual_filter: equal to 1 indicates that the inter prediction filter type may be
* specified independently in the horizontal and vertical directions. If the flag is equal
* to 0, only one filter type may be specified, which is then used in both directions.
* @enable_jnt_comp: equal to 1 indicates that the distance weights process may be used
* for inter prediction.
* @enable_ref_frame_mvs: equal to 1 indicates that the @use_ref_frame_mvs syntax element
* may be present. @enable_ref_frame_mvs equal to 0 indicates that the @use_ref_frame_mvs
* syntax element will not be present.
* @seq_choose_screen_content_tools: equal to 0 indicates that the @seq_force_screen_content_tools
* syntax element will be present. @seq_choose_screen_content_tools equal to 1 indicates
* that @seq_force_screen_content_tools should be set equal to SELECT_SCREEN_CONTENT_TOOLS.
* @seq_force_screen_content_tools: equal to SELECT_SCREEN_CONTENT_TOOLS indicates that the
* @allow_screen_content_tools syntax element will be present in the frame header. Otherwise,
* @seq_force_screen_content_tools contains the value for @allow_screen_content_tools.
* @seq_choose_integer_mv: equal to 0 indicates that the seq_force_integer_mv syntax element
* will be present. @seq_choose_integer_mv equal to 1 indicates that @seq_force_integer_mv
* should be set equal to SELECT_INTEGER_MV.
* @seq_force_integer_mv: equal to SELECT_INTEGER_MV indicates that the @force_integer_mv
* syntax element will be present in the frame header (providing allow_screen_content_tools
* is equal to 1). Otherwise, @seq_force_integer_mv contains the value for @force_integer_mv.
* @order_hint_bits_minus_1: is used to compute OrderHintBits.
* @enable_superres: equal to 1 specifies that the use_superres syntax element will be present
* in the uncompressed header. enable_superres equal to 0 specifies that the use_superres
* syntax element will not be present (instead use_superres will be set to 0 in the
* uncompressed header without being read).
* @enable_cdef: equal to 1 specifies that cdef filtering may be enabled. enable_cdef equal
* to 0 specifies that cdef filtering is disabled.
* @enable_restoration: equal to 1 specifies that loop restoration filtering may be enabled.
* enable_restoration equal to 0 specifies that loop restoration filtering is disabled.
* @film_grain_params_present: specifies whether film grain parameters are present in the bitstream.
* @operating_points_cnt_minus_1: indicates the number of operating points minus 1 present
* in this bitstream.
* @operating_points: specifies the corresponding operating point for a set of operating
* parameters.
* @decoder_model_info_present_flag: specifies whether the decoder model info is present in
* the bitstream.
* @decoder_model_info: holds information about the decoder model.
* @initial_display_delay_present_flag: specifies whether initial display delay information
* is present in the bitstream or not.
* @timing_info_present_flag: specifies whether timing info is present in the bitstream.
* @timing_info: holds the timing information.
* @color_config: hold the color configuration.
* @order_hint_bits: specifies the number of bits used for the order_hint syntax element.
* @bit_depth: the bit depth of the stream.
* @num_planes: the YUV plane number.
*/
struct _GstAV1SequenceHeaderOBU {
GstAV1Profile seq_profile;
gboolean still_picture;
guint8 reduced_still_picture_header;
guint8 frame_width_bits_minus_1;
guint8 frame_height_bits_minus_1;
guint16 max_frame_width_minus_1;
guint16 max_frame_height_minus_1;
gboolean frame_id_numbers_present_flag;
guint8 delta_frame_id_length_minus_2;
guint8 additional_frame_id_length_minus_1;
gboolean use_128x128_superblock;
gboolean enable_filter_intra;
gboolean enable_intra_edge_filter;
gboolean enable_interintra_compound;
gboolean enable_masked_compound;
gboolean enable_warped_motion;
gboolean enable_order_hint;
gboolean enable_dual_filter;
gboolean enable_jnt_comp;
gboolean enable_ref_frame_mvs;
gboolean seq_choose_screen_content_tools;
guint8 seq_force_screen_content_tools;
gboolean seq_choose_integer_mv;
guint8 seq_force_integer_mv;
gint8 order_hint_bits_minus_1;
gboolean enable_superres;
gboolean enable_cdef;
gboolean enable_restoration;
guint8 film_grain_params_present;
guint8 operating_points_cnt_minus_1;
GstAV1OperatingPoint operating_points[GST_AV1_MAX_OPERATING_POINTS];
gboolean decoder_model_info_present_flag;
GstAV1DecoderModelInfo decoder_model_info;
guint8 initial_display_delay_present_flag;
gboolean timing_info_present_flag;
GstAV1TimingInfo timing_info;
GstAV1ColorConfig color_config;
/* Global var calculated by sequence */
guint8 order_hint_bits; /* OrderHintBits */
guint8 bit_depth; /* BitDepth */
guint8 num_planes; /* NumPlanes */
};
/**
* GstAV1MetadataITUT_T35:
* @itu_t_t35_country_code: shall be a byte having a value specified as a country code by
* Annex A of Recommendation ITU-T T.35.
* @itu_t_t35_country_code_extension_byte: shall be a byte having a value specified as a
* country code by Annex B of Recommendation ITU-T T.35.
* @itu_t_t35_payload_bytes: shall be bytes containing data registered as specified in
* Recommendation ITU-T T.35.
*/
struct _GstAV1MetadataITUT_T35 {
guint8 itu_t_t35_country_code;
guint8 itu_t_t35_country_code_extention_byte;
/* itu_t_t35_payload_bytes - not specified at this spec */
guint8 *itu_t_t35_payload_bytes;
};
/**
* GstAV1MetadataHdrCll:
* @max_cll: specifies the maximum content light level as specified in CEA-861.3, Appendix A.
* @max_fall: specifies the maximum frame-average light level as specified in CEA-861.3, Appendix A.
*
* High Dynamic Range content light level syntax metadata.
*/
struct _GstAV1MetadataHdrCll {
guint16 max_cll;
guint16 max_fall;
};
/**
* GstAV1MetadataHdrMdcv:
* @primary_chromaticity_x: specifies a 0.16 fixed-point X chromaticity coordinate as
* defined by CIE 1931, where i = 0,1,2 specifies Red, Green, Blue respectively.
* @primary_chromaticity_y: specifies a 0.16 fixed-point Y chromaticity coordinate as
* defined by CIE 1931, where i = 0,1,2 specifies Red, Green, Blue respectively.
* @white_point_chromaticity_x: specifies a 0.16 fixed-point white X chromaticity coordinate
* as defined by CIE 1931.
* @white_point_chromaticity_y: specifies a 0.16 fixed-point white Y chromaticity coordinate
* as defined by CIE 1931.
* @luminance_max: is a 24.8 fixed-point maximum luminance, represented in candelas per
* square meter.
* @luminance_min: is a 18.14 fixed-point minimum luminance, represented in candelas per
* square meter.
*
* High Dynamic Range mastering display color volume metadata.
*/
struct _GstAV1MetadataHdrMdcv {
guint16 primary_chromaticity_x[3];
guint16 primary_chromaticity_y[3];
guint16 white_point_chromaticity_x;
guint16 white_point_chromaticity_y;
guint32 luminance_max;
guint32 luminance_min;
};
/**
* GstAV1MetadataScalability:
* @scalability_mode_idc: indicates the picture prediction structure of the bitstream.
* @spatial_layers_cnt_minus_1: indicates the number of spatial layers present in the video
* sequence minus one.
* @spatial_layer_description_present_flag: indicates when set to 1 that the
* spatial_layer_ref_id is present for each of the (@spatial_layers_cnt_minus_1 + 1) layers,
* or that it is not present when set to 0.
* @spatial_layer_dimensions_present_flag: indicates when set to 1 that the
* @spatial_layer_max_width and @spatial_layer_max_height parameters are present for each of
* the (@spatial_layers_cnt_minus_1 + 1) layers, or that it they are not present when set to 0.
* @temporal_group_description_present_flag: indicates when set to 1 that the temporal
* dependency information is present, or that it is not when set to 0.
* @spatial_layer_max_width: specifies the maximum frame width for the frames with
* @spatial_id equal to i. This number must not be larger than @max_frame_width_minus_1 + 1.
* @spatial_layer_max_height: specifies the maximum frame height for the frames with
* @spatial_id equal to i. This number must not be larger than @max_frame_height_minus_1 + 1.
* @spatial_layer_ref_id: specifies the @spatial_id value of the frame within the current
* temporal unit that the frame of layer i uses for reference. If no frame within the
* current temporal unit is used for reference the value must be equal to 255.
* @temporal_group_size: indicates the number of pictures in a temporal picture group. If the
* @temporal_group_size is greater than 0, then the scalability structure data allows the
* inter-picture temporal dependency structure of the video sequence to be specified. If the
* @temporal_group_size is greater than 0, then for @temporal_group_size pictures in the
* temporal group, each picture's temporal layer id (@temporal_id), switch up points
* (@temporal_group_temporal_switching_up_point_flag and
* @temporal_group_spatial_switching_up_point_flag), and the reference picture indices
* (@temporal_group_ref_pic_diff) are specified. The first picture specified in a temporal
* group must have @temporal_id equal to 0. If the parameter @temporal_group_size is not
* present or set to 0, then either there is only one temporal layer or there is no fixed
* inter-picture temporal dependency present going forward in the video sequence. Note that
* for a given picture, all frames follow the same inter-picture temporal dependency
* structure. However, the frame rate of each layer can be different from each other. The
* specified dependency structure in the scalability structure data must be for the highest
* frame rate layer.
* @temporal_group_temporal_id: specifies the temporal_id value for the i-th picture in
* the temporal group.
* @temporal_group_temporal_switching_up_point_flag: is set to 1 if subsequent (in decoding
* order) pictures with a @temporal_id higher than @temporal_group_temporal_id[i] do not
* depend on any picture preceding the current picture (in coding order) with @temporal_id
* higher than @temporal_group_temporal_id[ i ].
* @temporal_group_spatial_switching_up_point_flag: is set to 1 if spatial layers of the
* current picture in the temporal group (i.e., pictures with a spatial_id higher than zero)
* do not depend on any picture preceding the current picture in the temporal group.
* @temporal_group_ref_cnt: indicates the number of reference pictures used by the i-th
* picture in the temporal group.
* @temporal_group_ref_pic_diff: indicates, for the i-th picture in the temporal group,
* the temporal distance between the i-th picture and the j-th reference picture used by
* the i-th picture. The temporal distance is measured in frames, counting only frames of
* identical @spatial_id values.
*
* The scalability metadata OBU is intended for use by intermediate
* processing entities that may perform selective layer elimination.
*/
struct _GstAV1MetadataScalability {
GstAV1ScalabilityModes scalability_mode_idc;
guint8 spatial_layers_cnt_minus_1;
gboolean spatial_layer_dimensions_present_flag;
gboolean spatial_layer_description_present_flag;
gboolean temporal_group_description_present_flag;
guint16 spatial_layer_max_width[GST_AV1_MAX_NUM_SPATIAL_LAYERS];
guint16 spatial_layer_max_height[GST_AV1_MAX_NUM_SPATIAL_LAYERS];
guint8 spatial_layer_ref_id[GST_AV1_MAX_NUM_SPATIAL_LAYERS];
guint8 temporal_group_size;
guint8 temporal_group_temporal_id[GST_AV1_MAX_TEMPORAL_GROUP_SIZE];
guint8 temporal_group_temporal_switching_up_point_flag[GST_AV1_MAX_TEMPORAL_GROUP_SIZE];
guint8 temporal_group_spatial_switching_up_point_flag[GST_AV1_MAX_TEMPORAL_GROUP_SIZE];
guint8 temporal_group_ref_cnt[GST_AV1_MAX_TEMPORAL_GROUP_SIZE];
guint8 temporal_group_ref_pic_diff[GST_AV1_MAX_TEMPORAL_GROUP_SIZE]
[GST_AV1_MAX_TEMPORAL_GROUP_REFERENCES];
};
/**
* GstAV1MetadataTimecode:
* @counting_type: specifies the method of dropping values of the n_frames syntax element as
* specified in AV1 Spec 6.1.1. @counting_type should be the same for all pictures in the
* coded video sequence.
* @full_timestamp_flag: equal to 1 indicates that the the @seconds_value, @minutes_value,
* @hours_value syntax elements will be present. @full_timestamp_flag equal to 0 indicates
* that there are flags to control the presence of these syntax elements.
* @discontinuity_flag: equal to 0 indicates that the difference between the current value
* of clockTimestamp and the value of clockTimestamp computed from the previous set of
* timestamp syntax elements in output order can be interpreted as the time difference
* between the times of origin or capture of the associated frames or fields.
* @discontinuity_flag equal to 1 indicates that the difference between the current value of
* clockTimestamp and the value of clockTimestamp computed from the previous set of clock
* timestamp syntax elements in output order should not be interpreted as the time difference
* between the times of origin or capture of the associated frames or fields.
* @cnt_dropped_flag: specifies the skipping of one or more values of @n_frames using the
* counting method specified by counting_type.
* @n_frames: is used to compute clockTimestamp. When @timing_info_present_flag is equal to 1,
* @n_frames shall be less than maxFps, where maxFps is specified by
* maxFps = ceil( time_scale / ( 2 * @num_units_in_display_tick ) ).
* @seconds_flag: equal to 1 specifies that @seconds_value and @minutes_flag are present when
* @full_timestamp_flag is equal to 0. @seconds_flag equal to 0 specifies that @seconds_value
* and @minutes_flag are not present.
* @seconds_value: is used to compute clockTimestamp and shall be in the range of 0 to 59.
* When @seconds_value is not present, its value is inferred to be equal to the value of
* @seconds_value for the previous set of clock timestamp syntax elements in decoding order,
* and it is required that such a previous @seconds_value shall have been present.
* @minutes_flag: equal to 1 specifies that @minutes_value and @hours_flag are present when
* @full_timestamp_flag is equal to 0 and @seconds_flag is equal to 1. @minutes_flag equal to 0
* specifies that @minutes_value and @hours_flag are not present.
* @minutes_value: specifies the value of mm used to compute clockTimestamp and shall be in
* the range of 0 to 59, inclusive. When minutes_value is not present, its value is inferred
* to be equal to the value of @minutes_value for the previous set of clock timestamp syntax
* elements in decoding order, and it is required that such a previous @minutes_value shall
* have been present.
* @hours_flag: equal to 1 specifies that @hours_value is present when @full_timestamp_flag is
* equal to 0 and @seconds_flag is equal to 1 and @minutes_flag is equal to 1.
* @hours_value: is used to compute clockTimestamp and shall be in the range of 0 to 23,
* inclusive. When @hours_value is not present, its value is inferred to be equal to the
* value of @hours_value for the previous set of clock timestamp syntax elements in decoding
* order, and it is required that such a previous @hours_value shall have been present.
* @time_offset_length: greater than 0 specifies the length in bits of the @time_offset_value
* syntax element. @time_offset_length equal to 0 specifies that the @time_offset_value syntax
* element is not present. @time_offset_length should be the same for all pictures in the
* coded video sequence.
* @time_offset_value: is used to compute clockTimestamp. The number of bits used to represent
* @time_offset_value is equal to @time_offset_length. When @time_offset_value is not present,
* its value is inferred to be equal to 0.
*/
struct _GstAV1MetadataTimecode {
guint8 counting_type; /* candidate for sperate Type GstAV1TimecodeCountingType */
gboolean full_timestamp_flag;
gboolean discontinuity_flag;
gboolean cnt_dropped_flag;
guint8 n_frames;
gboolean seconds_flag;
guint8 seconds_value;
gboolean minutes_flag;
guint8 minutes_value;
gboolean hours_flag;
guint8 hours_value;
guint8 time_offset_length;
guint32 time_offset_value;
};
/**
* GstAV1MetadataOBU:
* @metadata_type: type of metadata
* @itut_t35: ITUT T35 metadata
* @hdrcll: high dynamic range content light level metadata
* @hdrcmdcv: high dynamic range mastering display color volume metadata_type
* @scalability: Scalability metadata
* @timecode: Timecode metadata
*/
struct _GstAV1MetadataOBU {
GstAV1MetadataType metadata_type;
union {
GstAV1MetadataITUT_T35 itut_t35;
GstAV1MetadataHdrCll hdr_cll;
GstAV1MetadataHdrMdcv hdr_mdcv;
GstAV1MetadataScalability scalability;
GstAV1MetadataTimecode timecode;
};
};
/**
* GstAV1LoopFilterParams:
* @loop_filter_level: is an array containing loop filter strength values. Different loop
* filter strength values from the array are used depending on the image plane being
* filtered, and the edge direction (vertical or horizontal) being filtered.
* @loop_filter_sharpness: indicates the sharpness level. The @loop_filter_level and
* @loop_filter_sharpness together determine when a block edge is filtered, and by how much
* the filtering can change the sample values. The loop filter process is described in AV1
* Bitstream Spec. section 7.14.
* @loop_filter_delta_enabled: equal to 1 means that the filter level depends on the mode and
* reference frame used to predict a block. @loop_filter_delta_enabled equal to 0 means that
* the filter level does not depend on the mode and reference frame.
* @loop_filter_delta_update: equal to 1 means that the bitstream contains additional syntax
* elements that specify which mode and reference frame deltas are to be updated.
* @loop_filter_delta_update equal to 0 means that these syntax elements are not present.
* @loop_filter_ref_deltas: contains the adjustment needed for the filter level based on
* the chosen reference frame. If this syntax element is not present in the bitstream,
* it maintains its previous value.
* @loop_filter_mode_deltas: contains the adjustment needed for the filter level based on
* the chosen mode. If this syntax element is not present in the bitstream, it maintains
* its previous value.
* @delta_lf_present: specifies whether loop filter delta values are present in the bitstream.
* @delta_lf_res: specifies the left shift which should be applied to decoded loop filter
* delta values.
* @delta_lf_multi: equal to 1 specifies that separate loop filter deltas are sent for
* horizontal luma edges, vertical luma edges, the U edges, and the V edges. @delta_lf_multi
* equal to 0 specifies that the same loop filter delta is used for all edges.
*/
struct _GstAV1LoopFilterParams {
guint8 loop_filter_level[4];
guint8 loop_filter_sharpness;
gboolean loop_filter_delta_enabled;
gboolean loop_filter_delta_update;
gint8 loop_filter_ref_deltas[GST_AV1_TOTAL_REFS_PER_FRAME];
gint8 loop_filter_mode_deltas[2];
gboolean delta_lf_present;
guint8 delta_lf_res;
guint8 delta_lf_multi;
};
/**
* GstAV1QuantizationParams:
* @base_q_idx: indicates the base frame qindex. This is used for Y AC coefficients and as
* the base value for the other quantizers.
* @diff_uv_delta: equal to 1 indicates that the U and V delta quantizer values are coded
* separately. @diff_uv_delta equal to 0 indicates that the U and V delta quantizer values
* share a common value.
* @using_qmatrix: specifies that the quantizer matrix will be used to compute quantizers.
* @qm_y: specifies the level in the quantizer matrix that should be used for luma plane decoding.
* @qm_u: specifies the level in the quantizer matrix that should be used for chroma U plane decoding.
* @qm_v: specifies the level in the quantizer matrix that should be used for chroma V plane decoding.
* @delta_q_present: specifies whether quantizer index delta values are present in the bitstream.
* @delta_q_res: specifies the left shift which should be applied to decoded quantizer index
* delta values.
* @delta_q_y_dc: indicates the Y DC quantizer relative to base_q_idx.
* @delta_q_u_dc: indicates the U DC quantizer relative to base_q_idx.
* @delta_q_u_ac: indicates the U AC quantizer relative to base_q_idx.
* @delta_q_v_dc: indicates the V DC quantizer relative to base_q_idx.
* @delta_q_v_ac: indicates the V AC quantizer relative to base_q_idx.
*/
struct _GstAV1QuantizationParams {
guint8 base_q_idx;
gboolean diff_uv_delta;
gboolean using_qmatrix;
guint8 qm_y;
guint8 qm_u;
guint8 qm_v;
gboolean delta_q_present;
guint8 delta_q_res;
gint8 delta_q_y_dc; /* DeltaQYDc */
gint8 delta_q_u_dc; /* DeltaQUDc */
gint8 delta_q_u_ac; /* DeltaQUAc */
gint8 delta_q_v_dc; /* DeltaQVDc */
gint8 delta_q_v_ac; /* DeltaQVAc */
};
/**
* GstAV1SegmenationParams:
* @segmentation_enabled: equal to 1 indicates that this frame makes use of the segmentation
* tool; @segmentation_enabled equal to 0 indicates that the frame does not use segmentation.
* @segmentation_update_map: equal to 1 indicates that the segmentation map are updated during
* the decoding of this frame. @segmentation_update_map equal to 0 means that the segmentation
* map from the previous frame is used.
* @segmentation_temporal_update: equal to 1 indicates that the updates to the segmentation map
* are coded relative to the existing segmentation map. @segmentation_temporal_update equal to
* 0 indicates that the new segmentation map is coded without reference to the existing
* segmentation map.
* @segmentation_update_data: equal to 1 indicates that new parameters are about to be
* specified for each segment. @segmentation_update_data equal to 0 indicates that the
* segmentation parameters should keep their existing values.
* @feature_enabled: set to 1 when the feature of segmentation is enabled.
* @feature_data: the value of according segmentation feature.
* @seg_id_pre_skip: equal to 1 indicates that the segment id will be read before the skip
* syntax element. @seg_id_pre_skip equal to 0 indicates that the skip syntax element will be
* read first.
* @last_active_seg_id: indicates the highest numbered segment id that has some enabled feature.
* This is used when decoding the segment id to only decode choices corresponding to used
* segments.
*/
struct _GstAV1SegmenationParams {
gboolean segmentation_enabled;
guint8 segmentation_update_map;
guint8 segmentation_temporal_update;
guint8 segmentation_update_data;
gint8 feature_enabled[GST_AV1_MAX_SEGMENTS][GST_AV1_SEG_LVL_MAX]; /* FeatureEnabled */
gint16 feature_data[GST_AV1_MAX_SEGMENTS][GST_AV1_SEG_LVL_MAX]; /* FeatureData */
guint8 seg_id_pre_skip; /* SegIdPreSkip */
guint8 last_active_seg_id; /* LastActiveSegId */
};
/**
* GstAV1TileInfo:
* @uniform_tile_spacing_flag: equal to 1 means that the tiles are uniformly spaced across the
* frame. (In other words, all tiles are the same size except for the ones at the right and
* bottom edge which can be smaller.) @uniform_tile_spacing_flag equal to 0 means that the
* tile sizes are coded.
* @increment_tile_rows_log2: is used to compute @tile_rows_log2.
* @width_in_sbs_minus_1: specifies the width of a tile minus 1 in units of superblocks.
* @height_in_sbs_minus_1: specifies the height of a tile minus 1 in units of superblocks.
* @tile_size_bytes_minus_1: is used to compute @tile_size_bytes
* @context_update_tile_id: specifies which tile to use for the CDF update.
* @mi_col_starts: is an array specifying the start column (in units of 4x4 luma samples) for
* each tile across the image.
* @mi_row_starts: is an array specifying the start row (in units of 4x4 luma samples) for
* each tile down the image.
* @tile_cols_log2: specifies the base 2 logarithm of the desired number of tiles across the frame.
* @tile_cols: specifies the number of tiles across the frame. It is a requirement of bitstream
* conformance that @tile_cols is less than or equal to GST_AV1_MAX_TILE_COLS.
* @tile_rows_log2: specifies the base 2 logarithm of the desired number of tiles down the frame.
* @tile_rows: specifies the number of tiles down the frame. It is a requirement of bitstream
* conformance that @tile_rows is less than or equal to GST_AV1_MAX_TILE_ROWS.
* @tile_size_bytes: specifies the number of bytes needed to code each tile size.
*/
struct _GstAV1TileInfo {
guint8 uniform_tile_spacing_flag;
gint increment_tile_rows_log2;
gint width_in_sbs_minus_1[GST_AV1_MAX_TILE_COLS];
gint height_in_sbs_minus_1[GST_AV1_MAX_TILE_ROWS];
gint tile_size_bytes_minus_1;
guint8 context_update_tile_id;
guint32 mi_col_starts[GST_AV1_MAX_TILE_COLS + 1]; /* MiColStarts */
guint32 mi_row_starts[GST_AV1_MAX_TILE_ROWS + 1]; /* MiRowStarts */
guint8 tile_cols_log2; /* TileColsLog2 */
guint8 tile_cols; /* TileCols */
guint8 tile_rows_log2; /* TileRowsLog2 */
guint8 tile_rows; /* TileRows */
guint8 tile_size_bytes; /* TileSizeBytes */
};
/**
* GstAV1CDEFParams:
* @cdef_damping: controls the amount of damping in the deringing filter.
* @cdef_bits: specifies the number of bits needed to specify which CDEF filter to apply.
* @cdef_y_pri_strength: specify the strength of the primary filter (Y component)
* @cdef_uv_pri_strength: specify the strength of the primary filter (UV components).
* @cdef_y_sec_strength: specify the strength of the secondary filter (Y component).
* @cdef_uv_sec_strength: specify the strength of the secondary filter (UV components).
*
* Parameters of Constrained Directional Enhancement Filter (CDEF).
*/
struct _GstAV1CDEFParams {
guint8 cdef_damping;
guint8 cdef_bits;
guint8 cdef_y_pri_strength[GST_AV1_CDEF_MAX];
guint8 cdef_y_sec_strength[GST_AV1_CDEF_MAX];
guint8 cdef_uv_pri_strength[GST_AV1_CDEF_MAX];
guint8 cdef_uv_sec_strength[GST_AV1_CDEF_MAX];
};
/**
* GstAV1LoopRestorationParams:
* @lr_unit_shift: specifies if the luma restoration size should be halved.
* @lr_uv_shift: is only present for 4:2:0 formats and specifies if the chroma size should be
* half the luma size.
* @frame_restoration_type: specifies the type of restoration used for each plane.
* @loop_restoration_size: specifies the size of loop restoration units in units of samples in
* the current plane.
* @uses_lr: indicates if any plane uses loop restoration.
*/
struct _GstAV1LoopRestorationParams {
guint8 lr_unit_shift;
gboolean lr_uv_shift;
GstAV1FrameRestorationType frame_restoration_type[GST_AV1_MAX_NUM_PLANES]; /* FrameRestorationType */
guint32 loop_restoration_size[GST_AV1_MAX_NUM_PLANES]; /* LoopRestorationSize */
guint8 uses_lr; /* UsesLr */
};
/**
* GstAV1GlobalMotionParams:
* @is_global: specifies whether global motion parameters are present for a particular
* reference frame.
* @is_rot_zoom: specifies whether a particular reference frame uses rotation and zoom
* global motion.
* @is_translation: specifies whether a particular reference frame uses translation
* global motion.
* @gm_params: is set equal to SavedGmParams[ frame_to_show_map_idx ][ ref ][ j ] for
* ref = LAST_FRAME..ALTREF_FRAME, for j = 0..5.
* @gm_type: specifying the type of global motion.
* @invalid: whether this global motion parameters is invalid. (Since: 1.20)
*/
/**
* _GstAV1GlobalMotionParams.invalid:
*
* whether this global motion parameters is invalid.
*
* Since: 1.20
*/
struct _GstAV1GlobalMotionParams {
gboolean is_global[GST_AV1_NUM_REF_FRAMES];
gboolean is_rot_zoom[GST_AV1_NUM_REF_FRAMES];
gboolean is_translation[GST_AV1_NUM_REF_FRAMES];
gint32 gm_params[GST_AV1_NUM_REF_FRAMES][6];
GstAV1WarpModelType gm_type[GST_AV1_NUM_REF_FRAMES]; /* GmType */
gboolean invalid[GST_AV1_NUM_REF_FRAMES];
};
/**
* GstAV1FilmGrainParams:
* @apply_grain: equal to 1 specifies that film grain should be added to this frame.
* apply_grain equal to 0 specifies that film grain should not be added.
* @grain_seed: specifies the starting value for the pseudo-random numbers used during film
* grain synthesis.
* @update_grain: equal to 1 means that a new set of parameters should be sent. @update_grain
* equal to 0 means that the previous set of parameters should be used.
* @film_grain_params_ref_idx: indicates which reference frame contains the film grain
* parameters to be used for this frame.
* @num_y_points: specifies the number of points for the piece-wise linear scaling function
* of the luma component. It is a requirement of bitstream conformance that @num_y_points is
* less than or equal to 14.
* @point_y_value: represents the x (luma value) coordinate for the i-th point of the
* piecewise linear scaling function for luma component. The values are signaled on the
* scale of 0..255. (In case of 10 bit video, these values correspond to luma values divided
* by 4. In case of 12 bit video, these values correspond to luma values divided by 16.)
* If i is greater than 0, it is a r equirement of bitstream conformance that
* @point_y_value[ i ] is greater than @point_y_value[ i - 1 ] (this ensures the x coordinates
* are specified in increasing order).
* @point_y_scaling: represents the scaling (output) value for the i-th point of the
* piecewise linear scaling function for luma component.
* @chroma_scaling_from_luma: specifies that the chroma scaling is inferred from the luma scaling.
* @num_cb_points: specifies the number of points for the piece-wise linear scaling function
* of the cb component. It is a requirement of bitstream conformance that @num_cb_points is
* less than or equal to 10.
* @point_cb_value: represents the x coordinate for the i-th point of the piece-wise linear
* scaling function for cb component. The values are signaled on the scale of 0..255. If i
* is greater than 0, it is a requirement of bitstream conformance that point_cb_value[ i ]
* is greater than point_cb_value[ i - 1 ].
* @point_cb_scaling: represents the scaling (output) value for the i-th point of the
* piecewise linear scaling function for cb component.
* @num_cr_points: specifies represents the number of points for the piece-wise linear scaling
* function of the cr component. It is a requirement of bitstream conformance that
* num_cr_points is less than or equal to 10. If subsampling_x is equal to 1 and
* @subsampling_y is equal to 1 and num_cb_points is equal to 0, it is a requirement of
* bitstream conformance that num_cr_points is equal to 0. If @subsampling_x is equal to 1
* and @subsampling_y is equal to 1 and @num_cb_points is not equal to 0, it is a requirement
* of bitstream conformance that @num_cr_points is not equal to 0.
* @point_cr_value: represents the x coordinate for the i-th point of the piece-wise linear
* scaling function for cr component. The values are signaled on the scale of 0..255. If i
* is greater than 0, it is a requirement of bitstream conformance that @point_cr_value[ i ]
* is greater than @point_cr_value[ i - 1 ].
* @point_cr_scaling: represents the scaling (output) value for the i-th point of the
* piecewise linear scaling function for cr component.
* @grain_scaling_minus_8: represents the shift - 8 applied to the values of the chroma
* component. The @grain_scaling_minus_8 can take values of 0..3 and determines the range and
* quantization step of the standard deviation of film grain.
* @ar_coeff_lag: specifies the number of auto-regressive coefficients for luma and chroma.
* @ar_coeffs_y_plus_128: specifies auto-regressive coefficients used for the Y plane.
* @ar_coeffs_cb_plus_128: specifies auto-regressive coefficients used for the U plane.
* @ar_coeffs_cr_plus_128: specifies auto-regressive coefficients used for the V plane.
* @ar_coeff_shift_minus_6: specifies the range of the auto-regressive coefficients. Values
* of 0, 1, 2, and 3 correspond to the ranges for auto-regressive coefficients of [-2, 2),
* [-1, 1), [-0.5, 0.5) and [-0.25, 0.25) respectively.
* @grain_scale_shift: specifies how much the Gaussian random numbers should be scaled down
* during the grain synthesis process.
* @cb_mult: represents a multiplier for the cb component used in derivation of the input
* index to the cb component scaling function.
* @cb_luma_mult: represents a multiplier for the average luma component used in derivation
* of the input index to the cb component scaling function.
* @cb_offset: represents an offset used in derivation of the input index to the cb component
* scaling function.
* @cr_mult: represents a multiplier for the cr component used in derivation of the input
* index to the cr component scaling function.
* @cr_luma_mult: represents a multiplier for the average luma component used in derivation
* of the input index to the cr component scaling function.
* @cr_offset: represents an offset used in derivation of the input index to the cr component
* scaling function.
* @overlap_flag: equal to 1 indicates that the overlap between film grain blocks shall be
* applied. overlap_flag equal to 0 indicates that the overlap between film grain blocks
* shall not be applied.
* @clip_to_restricted_range: equal to 1 indicates that clipping to the restricted (studio)
* range shall be applied to the sample values after adding the film grain (see the
* semantics for color_range for an explanation of studio swing). clip_to_restricted_range
* equal to 0 indicates that clipping to the full range shall be applied to the sample
* values after adding the film grain.
*/
struct _GstAV1FilmGrainParams {
gboolean apply_grain;
guint16 grain_seed;
gboolean update_grain;
guint8 film_grain_params_ref_idx;
guint8 num_y_points;
guint8 point_y_value[GST_AV1_MAX_NUM_Y_POINTS];
guint8 point_y_scaling[GST_AV1_MAX_NUM_Y_POINTS];
guint8 chroma_scaling_from_luma;
guint8 num_cb_points;
guint8 point_cb_value[GST_AV1_MAX_NUM_CB_POINTS];
guint8 point_cb_scaling[GST_AV1_MAX_NUM_CB_POINTS];
guint8 num_cr_points;
guint8 point_cr_value[GST_AV1_MAX_NUM_CR_POINTS];
guint8 point_cr_scaling[GST_AV1_MAX_NUM_CR_POINTS];
guint8 grain_scaling_minus_8;
guint8 ar_coeff_lag;
guint8 ar_coeffs_y_plus_128[GST_AV1_MAX_NUM_POS_LUMA];
guint8 ar_coeffs_cb_plus_128[GST_AV1_MAX_NUM_POS_LUMA];
guint8 ar_coeffs_cr_plus_128[GST_AV1_MAX_NUM_POS_LUMA];
guint8 ar_coeff_shift_minus_6;
guint8 grain_scale_shift;
guint8 cb_mult;
guint8 cb_luma_mult;
guint16 cb_offset;
guint8 cr_mult;
guint8 cr_luma_mult;
guint16 cr_offset;
gboolean overlap_flag;
gboolean clip_to_restricted_range;
};
/**
* GstAV1FrameHeaderOBU:
* @show_existing_frame: equal to 1, indicates the frame indexed by @frame_to_show_map_idx is
* to be output; @show_existing_frame equal to 0 indicates that further processing is required.
* If @obu_type is equal to %GST_AV1_OBU_FRAME, it is a requirement of bitstream conformance that
* @show_existing_frame is equal to 0.
* @frame_to_show_map_idx: specifies the frame to be output. It is only available if
* @show_existing_frame is 1.
* @frame_presentation_time: specifies the presentation time of the frame in clock ticks
* DispCT counted from the removal time of the last frame with frame_type equal to KEY_FRAME
* for the operating point that is being decoded. The syntax element is signaled as a fixed
* length unsigned integer with a length in bits given by
* @frame_presentation_time_length_minus_1 + 1. The @frame_presentation_time is the remainder
* of a modulo 1 << (@frame_presentation_time_length_minus_1 + 1) counter.
* @tu_presentation_delay: is a syntax element used by the decoder model. It does not affect
* the decoding process.
* @display_frame_id: provides the frame id number for the frame to output. It is a requirement
* of bitstream conformance that whenever @display_frame_id is read, the value matches
* @ref_frame_id[ @frame_to_show_map_idx ] (the value of @current_frame_id at the time that the
* frame indexed by @frame_to_show_map_idx was stored), and that
* @ref_valid[ @frame_to_show_map_idx ] is equal to 1. It is a requirement of bitstream
* conformance that the number of bits needed to read @display_frame_id does not exceed 16.
* This is equivalent to the constraint that idLen <= 16
* @frame_type: specifies the type of the frame.
* @show_frame: equal to 1 specifies that this frame should be immediately output once decoded.
* show_frame equal to 0 specifies that this frame should not be immediately output. (It may
* be output later if a later uncompressed header uses @show_existing_frame equal to 1).
* @showable_frame: equal to 1 specifies that the frame may be output using the
* @show_existing_frame mechanism. showable_frame equal to 0 specifies that this frame will
* not be output using the @show_existing_frame mechanism. It is a requirement of bitstream
* conformance that when @show_existing_frame is used to show a previous frame, that the
* value of @showable_frame for the previous frame was equal to 1. It is a requirement of
* bitstream conformance that a particular showable frame is output via the
* @show_existing_frame mechanism at most once.
* @error_resilient_mode: equal to 1 indicates that error resilient mode is enabled;
* @error_resilient_mode equal to 0 indicates that error resilient mode is disabled.
* @disable_cdf_update: specifies whether the CDF update in the symbol decoding process should
* be disabled.
* @allow_screen_content_tools: equal to 1 indicates that intra blocks may use palette encoding;
* @allow_screen_content_tools equal to 0 indicates that palette encoding is never used.
* @force_integer_mv: equal to 1 specifies that motion vectors will always be integers.
* @force_integer_mv equal to 0 specifies that motion vectors can contain fractional bits.
* @current_frame_id: specifies the frame id number for the current frame. Frame id numbers
* are additional information that do not affect the decoding process, but provide decoders
* with a way of detecting missing reference frames so that appropriate action can be taken.
* @frame_size_override_flag: equal to 0 specifies that the frame size is equal to the size in
* the sequence header. @frame_size_override_flag equal to 1 specifies that the frame size
* will either be specified as the size of one of the reference frames, or computed from the
* @frame_width_minus_1 and @frame_height_minus_1 syntax elements.
* @order_hint: is used to compute order_hint.
* @primary_ref_frame: specifies which reference frame contains the CDF values and other state
* that should be loaded at the start of the frame.
* @buffer_removal_time_present_flag: equal to 1 specifies that @buffer_removal_time is present
* in the bitstream. @buffer_removal_time_present_flag equal to 0 specifies that
* @buffer_removal_time is not present in the bitstream.
* @buffer_removal_time: specifies the frame removal time in units of DecCT clock ticks
* counted from the removal time of the last frame with frame_type equal to KEY_FRAME for
* operating point opNum. @buffer_removal_time is signaled as a fixed length unsigned integer
* with a length in bits given by @buffer_removal_time_length_minus_1 + 1. @buffer_removal_time
* is the remainder of a modulo 1 << ( @buffer_removal_time_length_minus_1 + 1 ) counter.
* @refresh_frame_flags: contains a bitmask that specifies which reference frame slots will be
* updated with the current frame after it is decoded. If @frame_type is equal to
* %GST_AV1_INTRA_ONLY_FRAME, it is a requirement of bitstream conformance that
* @refresh_frame_flags is not equal to 0xff.
* @ref_order_hint: specifies the expected output order hint for each reference buffer.
* @allow_intrabc: equal to 1 indicates that intra block copy may be used in this frame.
* allow_intrabc equal to 0 indicates that intra block copy is not allowed in this frame.
* @frame_refs_short_signaling: equal to 1 indicates that only two reference frames are
* explicitly signaled. frame_refs_short_signaling equal to 0 indicates that all reference
* frames are explicitly signaled.
* @last_frame_idx: specifies the reference frame to use for LAST_FRAME.
* @gold_frame_idx: specifies the reference frame to use for GOLDEN_FRAME.
* @ref_frame_idx[i]: specifies which reference frames are used by inter frames.
* @delta_frame_id_minus_1 is used to calculate @delta_frame_id.
* @allow_high_precision_mv: equal to 0 specifies that motion vectors are specified to quarter
* pel precision; @allow_high_precision_mv equal to 1 specifies that motion vectors are
* specified to eighth pel precision.
* @is_motion_mode_switchable: equal to 0 specifies that only the SIMPLE motion mode will be used.
* @use_ref_frame_mvs: equal to 1 specifies that motion vector information from a previous
* frame can be used when decoding the current frame. @use_ref_frame_mvs equal to 0 specifies
* that this information will not be used.
* @disable_frame_end_update_cdf: equal to 1 indicates that the end of frame CDF update is
* disabled; @disable_frame_end_update_cdf equal to 0 indicates that the end of frame CDF
* update is enabled.
* @allow_warped_motion: equal to 1 indicates that the syntax element @motion_mode may be
* present. @allow_warped_motion equal to 0 indicates that the syntax element motion_mode
* will not be present (this means that LOCALWARP cannot be signaled if @allow_warped_motion
* is equal to 0).
* @reduced_tx_set: equal to 1 specifies that the frame is restricted to a reduced subset of
* the full set of transform types.
* @render_and_frame_size_different: equal to 0 means that the render width and height are
* inferred from the frame width and height. @render_and_frame_size_different equal to 1
* means that the render width and height are explicitly coded in the bitstream.
* @use_superres: equal to 0 indicates that no upscaling is needed. @use_superres equal to 1
* indicates that upscaling is needed.
* @is_filter_switchable: equal to 1 indicates that the filter selection is signaled at the
* block level; @is_filter_switchable equal to 0 indicates that the filter selection is
* signaled at the frame level.
* @interpolation_filter: a #GstAV1InterpolationFilter that specifies the filter selection used
* for performing inter prediction.
* @loop_filter_params: a #GstAV1LoopFilterParams holding the loop filter parameters.
* @quantization_params: a #GstAV1QuantizationParams holding the quantization parameters.
* @segmentation_params: a #GstAV1SegmenationParams holding the segementation parameters.
* @tile_info: a #GstAV1TileInfo holding the tile info.
* @cdef_params: a #GstAV1CDEFParams holding the CDEF paramters.
* @loop_restoration_params: a #GstAV1LoopRestorationParams holding the loop restoration parameters.
* @tx_mode_select: is used to compute TxMode.
* @skip_mode_present: equal to 1 specifies that the syntax element @skip_mode will be coded
* in the bitstream. @skip_mode_present equal to 0 specifies that @skip_mode will not be used
* for this frame.
* @reference_select: equal to 1 specifies that the mode info for inter blocks contains the
* syntax element comp_mode that indicates whether to use single or compound reference
* prediction. Reference_select equal to 0 specifies that all interblocks will use single
* prediction.
* @global_motion_params: a #GstAV1GlobalMotionParams holding the global motion parameters.
* @film_grain_params: a #GstAV1FilmGrainParams holding the Film Grain parameters.
* @superres_denom: is the denominator of a fraction that specifies the ratio between the
* superblock width before and after upscaling.
* @frame_is_intra: if equal to 0 indicating that this frame may use inter prediction.
* @order_hints: specifies the expected output order for each reference frame.
* @ref_frame_sign_bias: specifies the intended direction of the motion vector in time for
* each reference frame.
* @coded_lossless: is a variable that is equal to 1 when all segments use lossless encoding.
* @all_lossless: is a variable that is equal to 1 when @coded_lossless is equal to 1 and
* @frame_width is equal to @upscaled_width. This indicates that the frame is fully lossless
* at the upscaled resolution.
* @lossless_array: whether the segmentation is lossless.
* @seg_qm_Level: the segmentation's qm level.
* @upscaled_width: the upscaled width.
* @frame_width: the frame width.
* @frame_height: the frame height.
* @render_width: the frame width to be rendered.
* @render_height: the frame height to be rendered.
* @tx_mode: specifies how the transform size is determined.
* @skip_mode_frame: specifies the frames to use for compound prediction when @skip_mode is 1.
* @expected_frame_id: specifies the frame id for each frame used for reference. (Since: 1.24)
* @ref_global_motion_params: specifies the global motion parameters of the reference. (Since: 1.24)
*/
struct _GstAV1FrameHeaderOBU {
gboolean show_existing_frame;
gint8 frame_to_show_map_idx;
guint32 frame_presentation_time;
guint32 tu_presentation_delay;
guint32 display_frame_id;
GstAV1FrameType frame_type;
gboolean show_frame;
gboolean showable_frame;
gboolean error_resilient_mode;
gboolean disable_cdf_update;
guint8 allow_screen_content_tools;
gboolean force_integer_mv;
guint32 current_frame_id;
gboolean frame_size_override_flag;
guint32 order_hint;
guint8 primary_ref_frame;
gboolean buffer_removal_time_present_flag;
guint32 buffer_removal_time[GST_AV1_MAX_OPERATING_POINTS];
guint8 refresh_frame_flags;
guint32 ref_order_hint[GST_AV1_NUM_REF_FRAMES];
gboolean allow_intrabc;
gboolean frame_refs_short_signaling;
gint8 last_frame_idx;
gint8 gold_frame_idx;
gint8 ref_frame_idx[GST_AV1_REFS_PER_FRAME];
gboolean allow_high_precision_mv;
gboolean is_motion_mode_switchable;
gboolean use_ref_frame_mvs;
gboolean disable_frame_end_update_cdf;
gboolean allow_warped_motion;
gboolean reduced_tx_set;
gboolean render_and_frame_size_different;
gboolean use_superres;
gboolean is_filter_switchable;
GstAV1InterpolationFilter interpolation_filter;
GstAV1LoopFilterParams loop_filter_params;
GstAV1QuantizationParams quantization_params;
GstAV1SegmenationParams segmentation_params;
GstAV1TileInfo tile_info;
GstAV1CDEFParams cdef_params;
GstAV1LoopRestorationParams loop_restoration_params;
gboolean tx_mode_select;
gboolean skip_mode_present;
gboolean reference_select;
GstAV1GlobalMotionParams global_motion_params;
GstAV1FilmGrainParams film_grain_params;
/* Global vars set by frame header */
guint32 superres_denom; /* SuperresDenom */
guint8 frame_is_intra; /* FrameIsIntra */
guint32 order_hints[GST_AV1_NUM_REF_FRAMES]; /* OrderHints */
guint32 ref_frame_sign_bias[GST_AV1_NUM_REF_FRAMES]; /* RefFrameSignBias */
guint8 coded_lossless; /* CodedLossless */
guint8 all_lossless; /* AllLossless */
guint8 lossless_array[GST_AV1_MAX_SEGMENTS]; /* LosslessArray */
guint8 seg_qm_Level[3][GST_AV1_MAX_SEGMENTS]; /* SegQMLevel */
guint32 upscaled_width; /* UpscaledWidth */
guint32 frame_width; /* FrameWidth */
guint32 frame_height; /* FrameHeight */
guint32 render_width; /* RenderWidth */
guint32 render_height; /* RenderHeight */
GstAV1TXModes tx_mode; /* TxMode */
guint8 skip_mode_frame[2]; /* SkipModeFrame */
/**
* _GstAV1FrameHeaderOBU.expected_frame_id:
*
* Specifies the frames to use for compound prediction.
*
* Since: 1.24
*/
gint32 expected_frame_id[GST_AV1_REFS_PER_FRAME];
/**
* _GstAV1FrameHeaderOBU.ref_global_motion_params:
*
* Specifies the global motion parameters of the reference.
*
* Since: 1.24
*/
GstAV1GlobalMotionParams ref_global_motion_params;
};
/**
* GstAV1ReferenceFrameInfoEntry:
*
*/
struct _GstAV1ReferenceFrameInfoEntry {
gboolean ref_valid; /* RefValid */
guint32 ref_frame_id; /* RefFrameId */
guint32 ref_upscaled_width; /* RefUpscaledWidth */
guint32 ref_frame_width; /* RefFrameWidth */
guint32 ref_frame_height; /* RefFrameHeight */
guint32 ref_render_width; /* RefRenderWidth */
guint32 ref_render_height; /* RefRenderHeight */
guint32 ref_mi_cols; /* RefMiCols */
guint32 ref_mi_rows; /* RefMiRows */
GstAV1FrameType ref_frame_type; /* RefFrameType */
guint8 ref_subsampling_x; /* RefSubsamplingX */
guint8 ref_subsampling_y; /* RefSubsamplingY */
guint8 ref_bit_depth; /* RefBitDepth */
guint32 ref_order_hint; /* RefOrderHint */
GstAV1SegmenationParams ref_segmentation_params;
GstAV1GlobalMotionParams ref_global_motion_params;
GstAV1LoopFilterParams ref_lf_params;
GstAV1FilmGrainParams ref_film_grain_params;
GstAV1TileInfo ref_tile_info;
};
/**
* GstAV1ReferenceFrameInfo:
*
* All the info related to a reference frames.
*/
struct _GstAV1ReferenceFrameInfo {
GstAV1ReferenceFrameInfoEntry entry[GST_AV1_NUM_REF_FRAMES];
};
/**
* GstAV1TileListOBUEntry:
*
*/
struct _GstAV1TileListOBUEntry {
gint8 anchor_frame_idx;
guint8 anchor_tile_row;
guint8 anchor_tile_col;
guint16 tile_data_size_minus_1;
/* Just refer to obu's data, invalid after OBU data released */
guint8 *coded_tile_data;
};
/**
* GstAV1TileListOBU:
* @output_frame_width_in_tiles_minus_1: plus one is the width of the output frame, in tile units.
* @output_frame_height_in_tiles_minus_1: plus one is the height of the output frame, in tile units.
* @tile_count_minus_1: plus one is the number of @tile_list_entry in the list. It is a requirement
* of bitstream conformance that @tile_count_minus_1 is less than or equal to 511.
* @anchor_frame_idx: is the index into an array AnchorFrames of the frames that the tile uses
* for prediction. The AnchorFrames array is provided by external means and may change for
* each tile list OBU. The process for creating the AnchorFrames array is outside of the
* scope of this specification. It is a requirement of bitstream conformance that
* @anchor_frame_idx is less than or equal to 127.
* @anchor_tile_row: the row coordinate of the tile in the frame that it belongs, in tile
* units. It is a requirement of bitstream conformance that @anchor_tile_row is less than @tile_rows.
* @anchor_tile_col: is the column coordinate of the tile in the frame that it belongs, in tile
* units. It is a requirement of bitstream conformance that @anchor_tile_col is less than @tile_cols.
* @tile_data_size_minus_1: plus one is the size of the coded tile data, @coded_tile_data, in bytes.
* @coded_tile_data: are the @tile_data_size_minus_1 + 1 bytes of the coded tile.
*/
struct _GstAV1TileListOBU {
guint8 output_frame_width_in_tiles_minus_1;
guint8 output_frame_height_in_tiles_minus_1;
guint16 tile_count_minus_1;
GstAV1TileListOBUEntry entry[GST_AV1_MAX_TILE_COUNT];
};
/**
* GstAV1TileGroupOBUEntry:
*
*/
struct _GstAV1TileGroupOBUEntry {
guint32 tile_offset; /* Tile data offset from the OBU data. */
guint32 tile_size; /* Data size of this tile */
guint32 tile_row; /* tileRow */
guint32 tile_col; /* tileCol */
/* global varialbes */
guint32 mi_row_start; /* MiRowStart */
guint32 mi_row_end; /* MiRowEnd */
guint32 mi_col_start; /* MiColStart */
guint32 mi_col_end; /* MiColEnd */
};
/**
* GstAV1TileGroupOBU:
* @tile_start_and_end_present_flag: specifies whether @tg_start and @tg_end are present
* in the bitstream. If @tg_start and @tg_end are not present in the bitstream, this
* tile group covers the entire frame. If @obu_type is equal to %GST_AV1_OBU_FRAME, it is a
* requirement of bitstream conformance that the value of @tile_start_and_end_present_flag
* is equal to 0.
* @tg_start: specifies the zero-based index of the first tile in the current tile group.
* It is a requirement of bitstream conformance that the value of @tg_start is equal to
* the value of TileNum at the point that tile_group_obu is invoked.
* @tg_end: specifies the zero-based index of the last tile in the current tile group.
* It is a requirement of bitstream conformance that the value of tg_end is greater
* than or equal to tg_start. It is a requirement of bitstream conformance that the
* value of tg_end for the last tile group in each frame is equal to num_tiles-1.
* @tile_offset: Offset from the OBU data, the real data start of this tile.
* @tg_size: Data size of this tile.
* @tile_row: Tile index in row.
* @tile_col: Tile index in column.
* @mi_row_start: start position in mi rows
* @mi_row_end: end position in mi rows
* @mi_col_start: start position in mi cols
* @mi_col_end: end position in mi cols
* @num_tiles: specifies the total number of tiles in the frame.
*/
struct _GstAV1TileGroupOBU {
gboolean tile_start_and_end_present_flag;
guint8 tg_start;
guint8 tg_end;
GstAV1TileGroupOBUEntry entry[GST_AV1_MAX_TILE_COUNT];
guint32 num_tiles; /* NumTiles */
};
/**
* GstAV1FrameOBU:
* @frame_header: a #GstAV1FrameHeaderOBU holding frame_header data.
* @tile_group: a #GstAV1TileGroupOBU holding tile_group data.
*/
struct _GstAV1FrameOBU {
GstAV1TileGroupOBU tile_group;
GstAV1FrameHeaderOBU frame_header;
};
/**
* GstAV1ParserState:
*
*/
struct _GstAV1ParserState {
guint32 operating_point; /* Set by choose_operating_point() */
guint8 seen_frame_header; /* SeenFrameHeader */
guint32 operating_point_idc; /* OperatingPointIdc */
gboolean sequence_changed; /* Received a new sequence */
gboolean begin_first_frame; /* already find the first frame */
/* frame */
guint32 upscaled_width; /* UpscaledWidth */
guint32 frame_width; /* FrameWidth */
guint32 frame_height; /* FrameHeight */
guint32 mi_cols; /* MiCols */
guint32 mi_rows; /* MiRows */
guint32 render_width; /* RenderWidth */
guint32 render_height; /* RenderHeight */
guint32 prev_frame_id; /* PrevFrameID */
guint32 current_frame_id; /* the current frame ID */
GstAV1ReferenceFrameInfo ref_info; /* RefInfo */
guint32 mi_col_starts[GST_AV1_MAX_TILE_COLS + 1]; /* MiColStarts */
guint32 mi_row_starts[GST_AV1_MAX_TILE_ROWS + 1]; /* MiRowStarts */
guint8 tile_cols_log2; /* TileColsLog2 */
guint8 tile_cols; /* TileCols */
guint8 tile_rows_log2; /* TileRowsLog2 */
guint8 tile_rows; /* TileRows */
guint8 tile_size_bytes; /* TileSizeBytes */
};
/**
* GstAV1Parser:
*
* #GstAV1Parser opaque structure
*
* Instantiante it with gst_av1_parser_new() and destroy it with
* gst_av1_parser_free()
*/
struct _GstAV1Parser
{
/*< private >*/
GstAV1ParserState state;
gboolean annex_b;
guint32 temporal_unit_size;
/* consumed of this temporal unit */
guint32 temporal_unit_consumed;
guint32 frame_unit_size;
/* consumed of this frame unit */
guint32 frame_unit_consumed;
GstAV1SequenceHeaderOBU *seq_header;
};
GST_CODEC_PARSERS_API
void
gst_av1_parser_reset (GstAV1Parser * parser, gboolean annex_b);
GST_CODEC_PARSERS_API
void
gst_av1_parser_reset_annex_b (GstAV1Parser * parser);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_identify_one_obu (GstAV1Parser * parser, const guint8 * data,
guint32 size, GstAV1OBU * obu, guint32 * consumed);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_parse_sequence_header_obu (GstAV1Parser * parser,
GstAV1OBU * obu, GstAV1SequenceHeaderOBU * seq_header);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_parse_temporal_delimiter_obu (GstAV1Parser * parser,
GstAV1OBU * obu);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_parse_metadata_obu (GstAV1Parser * parser, GstAV1OBU * obu,
GstAV1MetadataOBU * metadata);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_parse_tile_list_obu (GstAV1Parser * parser, GstAV1OBU * obu,
GstAV1TileListOBU * tile_list);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_parse_tile_group_obu (GstAV1Parser * parser, GstAV1OBU * obu,
GstAV1TileGroupOBU * tile_group);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_parse_frame_header_obu (GstAV1Parser * parser, GstAV1OBU * obu,
GstAV1FrameHeaderOBU * frame_header);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_parse_frame_obu (GstAV1Parser * parser, GstAV1OBU * obu,
GstAV1FrameOBU * frame);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_reference_frame_update (GstAV1Parser * parser,
GstAV1FrameHeaderOBU * frame_header);
GST_CODEC_PARSERS_API
GstAV1ParserResult
gst_av1_parser_set_operating_point (GstAV1Parser * parser,
gint32 operating_point);
GST_CODEC_PARSERS_API
GstAV1Parser * gst_av1_parser_new (void);
GST_CODEC_PARSERS_API
void gst_av1_parser_free (GstAV1Parser * parser);
G_END_DECLS
#endif /* __GST_AV1_PARSER_H__ */