av1/common/enums.h - aom - Git at Google

 /*
  * Copyright (c) 2016, Alliance for Open Media. All rights reserved
  *
  * This source code is subject to the terms of the BSD 2 Clause License and
  * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
  * was not distributed with this source code in the LICENSE file, you can
  * obtain it at www.aomedia.org/license/software. If the Alliance for Open
  * Media Patent License 1.0 was not distributed with this source code in the
  * PATENTS file, you can obtain it at www.aomedia.org/license/patent.
  */

 #ifndef AOM_AV1_COMMON_ENUMS_H_
 #define AOM_AV1_COMMON_ENUMS_H_

 #include "config/aom_config.h"

 #include "aom/aom_codec.h"
 #include "aom/aom_integer.h"
 #include "aom_dsp/txfm_common.h"
 #include "aom_ports/mem.h"

 #ifdef __cplusplus
 extern "C" {
 #endif

 /*! @file */

 /*!\cond */

 // Max superblock size
 #define MAX_SB_SIZE_LOG2 7
 #define MAX_SB_SIZE (1 << MAX_SB_SIZE_LOG2)
 #define MAX_SB_SQUARE (MAX_SB_SIZE * MAX_SB_SIZE)

 // Min superblock size
 #define MIN_SB_SIZE_LOG2 6

 // Pixels per Mode Info (MI) unit
 #define MI_SIZE_LOG2 2
 #define MI_SIZE (1 << MI_SIZE_LOG2)

 // MI-units per max superblock (MI Block - MIB)
 #define MAX_MIB_SIZE_LOG2 (MAX_SB_SIZE_LOG2 - MI_SIZE_LOG2)
 #define MAX_MIB_SIZE (1 << MAX_MIB_SIZE_LOG2)

 // MI-units per min superblock
 #define MIN_MIB_SIZE_LOG2 (MIN_SB_SIZE_LOG2 - MI_SIZE_LOG2)

 // Mask to extract MI offset within max MIB
 #define MAX_MIB_MASK (MAX_MIB_SIZE - 1)

 // Maximum number of tile rows and tile columns
 #define MAX_TILE_ROWS 64
 #define MAX_TILE_COLS 64

 #define MAX_VARTX_DEPTH 2

 #define MI_SIZE_64X64 (64 >> MI_SIZE_LOG2)
 #define MI_SIZE_128X128 (128 >> MI_SIZE_LOG2)

 #define MAX_PALETTE_SQUARE (64 * 64)
 // Maximum number of colors in a palette.
 #define PALETTE_MAX_SIZE 8
 // Minimum number of colors in a palette.
 #define PALETTE_MIN_SIZE 2

 #define FRAME_OFFSET_BITS 5
 #define MAX_FRAME_DISTANCE ((1 << FRAME_OFFSET_BITS) - 1)

 // 4 frame filter levels: y plane vertical, y plane horizontal,
 // u plane, and v plane
 #define FRAME_LF_COUNT 4
 #define DEFAULT_DELTA_LF_MULTI 0
 #define MAX_MODE_LF_DELTAS 2

 #define DIST_PRECISION_BITS 4
 #define DIST_PRECISION (1 << DIST_PRECISION_BITS)  // 16

 #define PROFILE_BITS 3
 // The following three profiles are currently defined.
 // Profile 0.  8-bit and 10-bit 4:2:0 and 4:0:0 only.
 // Profile 1.  8-bit and 10-bit 4:4:4
 // Profile 2.  8-bit and 10-bit 4:2:2
 //            12-bit  4:0:0, 4:2:2 and 4:4:4
 // Since we have three bits for the profiles, it can be extended later.
 enum {
   PROFILE_0,
   PROFILE_1,
   PROFILE_2,
   MAX_PROFILES,
 } SENUM1BYTE(BITSTREAM_PROFILE);

 #define OP_POINTS_CNT_MINUS_1_BITS 5
 #define OP_POINTS_IDC_BITS 12

 // Note: Some enums use the attribute 'packed' to use smallest possible integer
 // type, so that we can save memory when they are used in structs/arrays.

 typedef enum ATTRIBUTE_PACKED {
   BLOCK_4X4,
   BLOCK_4X8,
   BLOCK_8X4,
   BLOCK_8X8,
   BLOCK_8X16,
   BLOCK_16X8,
   BLOCK_16X16,
   BLOCK_16X32,
   BLOCK_32X16,
   BLOCK_32X32,
   BLOCK_32X64,
   BLOCK_64X32,
   BLOCK_64X64,
   BLOCK_64X128,
   BLOCK_128X64,
   BLOCK_128X128,
   BLOCK_4X16,
   BLOCK_16X4,
   BLOCK_8X32,
   BLOCK_32X8,
   BLOCK_16X64,
   BLOCK_64X16,
   BLOCK_SIZES_ALL,
   BLOCK_SIZES = BLOCK_4X16,
   BLOCK_INVALID = 255,
   BLOCK_LARGEST = (BLOCK_SIZES - 1)
 } BLOCK_SIZE;

 // 4X4, 8X8, 16X16, 32X32, 64X64, 128X128
 #define SQR_BLOCK_SIZES 6

 //  Partition types.  R: Recursive
 //
 //  NONE          HORZ          VERT          SPLIT
 //  +-------+     +-------+     +---+---+     +---+---+
 //  |       |     |       |     |   |   |     | R | R |
 //  |       |     +-------+     |   |   |     +---+---+
 //  |       |     |       |     |   |   |     | R | R |
 //  +-------+     +-------+     +---+---+     +---+---+
 //
 //  HORZ_A        HORZ_B        VERT_A        VERT_B
 //  +---+---+     +-------+     +---+---+     +---+---+
 //  |   |   |     |       |     |   |   |     |   |   |
 //  +---+---+     +---+---+     +---+   |     |   +---+
 //  |       |     |   |   |     |   |   |     |   |   |
 //  +-------+     +---+---+     +---+---+     +---+---+
 //
 //  HORZ_4        VERT_4
 //  +-----+       +-+-+-+
 //  +-----+       | | | |
 //  +-----+       | | | |
 //  +-----+       +-+-+-+
 enum {
   PARTITION_NONE,
   PARTITION_HORZ,
   PARTITION_VERT,
   PARTITION_SPLIT,
   PARTITION_HORZ_A,  // HORZ split and the top partition is split again
   PARTITION_HORZ_B,  // HORZ split and the bottom partition is split again
   PARTITION_VERT_A,  // VERT split and the left partition is split again
   PARTITION_VERT_B,  // VERT split and the right partition is split again
   PARTITION_HORZ_4,  // 4:1 horizontal partition
   PARTITION_VERT_4,  // 4:1 vertical partition
   EXT_PARTITION_TYPES,
   PARTITION_TYPES = PARTITION_SPLIT + 1,
   PARTITION_INVALID = 255
 } UENUM1BYTE(PARTITION_TYPE);

 typedef char PARTITION_CONTEXT;
 #define PARTITION_PLOFFSET 4  // number of probability models per block size
 #define PARTITION_BLOCK_SIZES 5
 #define PARTITION_CONTEXTS (PARTITION_BLOCK_SIZES * PARTITION_PLOFFSET)

 #define TX_SIZE_LUMA_MIN (TX_4X4)
 /* We don't need to code a transform size unless the allowed size is at least
    one more than the minimum. */
 #define TX_SIZE_CTX_MIN (TX_SIZE_LUMA_MIN + 1)

 // Maximum tx_size categories
 #define MAX_TX_CATS (TX_SIZES - TX_SIZE_CTX_MIN)
 #define MAX_TX_DEPTH 2

 #define MAX_TX_SIZE_LOG2 (6)
 #define MAX_TX_SIZE (1 << MAX_TX_SIZE_LOG2)
 #define MIN_TX_SIZE_LOG2 2
 #define MIN_TX_SIZE (1 << MIN_TX_SIZE_LOG2)
 #define MAX_TX_SQUARE (MAX_TX_SIZE * MAX_TX_SIZE)

 // Pad 4 extra columns to remove horizontal availability check.
 #define TX_PAD_HOR_LOG2 2
 #define TX_PAD_HOR 4
 // Pad 6 extra rows (2 on top and 4 on bottom) to remove vertical availability
 // check.
 #define TX_PAD_TOP 0
 #define TX_PAD_BOTTOM 4
 #define TX_PAD_VER (TX_PAD_TOP + TX_PAD_BOTTOM)
 // Pad 16 extra bytes to avoid reading overflow in SIMD optimization.
 #define TX_PAD_END 16
 #define TX_PAD_2D ((32 + TX_PAD_HOR) * (32 + TX_PAD_VER) + TX_PAD_END)

 // Number of maximum size transform blocks in the maximum size superblock
 #define MAX_TX_BLOCKS_IN_MAX_SB_LOG2 ((MAX_SB_SIZE_LOG2 - MAX_TX_SIZE_LOG2) * 2)
 #define MAX_TX_BLOCKS_IN_MAX_SB (1 << MAX_TX_BLOCKS_IN_MAX_SB_LOG2)

 // frame transform mode
 enum {
   ONLY_4X4,         // use only 4x4 transform
   TX_MODE_LARGEST,  // transform size is the largest possible for pu size
   TX_MODE_SELECT,   // transform specified for each block
   TX_MODES,
 } UENUM1BYTE(TX_MODE);

 // 1D tx types
 enum {
   DCT_1D,
   ADST_1D,
   FLIPADST_1D,
   IDTX_1D,
   TX_TYPES_1D,
 } UENUM1BYTE(TX_TYPE_1D);

 enum {
   REG_REG,
   REG_SMOOTH,
   REG_SHARP,
   SMOOTH_REG,
   SMOOTH_SMOOTH,
   SMOOTH_SHARP,
   SHARP_REG,
   SHARP_SMOOTH,
   SHARP_SHARP,
 } UENUM1BYTE(DUAL_FILTER_TYPE);

 #define EXT_TX_SIZES 4       // number of sizes that use extended transforms
 #define EXT_TX_SETS_INTER 4  // Sets of transform selections for INTER
 #define EXT_TX_SETS_INTRA 3  // Sets of transform selections for INTRA

 enum {
   AOM_LAST_FLAG = 1 << 0,
   AOM_LAST2_FLAG = 1 << 1,
   AOM_LAST3_FLAG = 1 << 2,
   AOM_GOLD_FLAG = 1 << 3,
   AOM_BWD_FLAG = 1 << 4,
   AOM_ALT2_FLAG = 1 << 5,
   AOM_ALT_FLAG = 1 << 6,
   AOM_REFFRAME_ALL = (1 << 7) - 1
 } UENUM1BYTE(AOM_REFFRAME);

 enum {
   UNIDIR_COMP_REFERENCE,
   BIDIR_COMP_REFERENCE,
   COMP_REFERENCE_TYPES,
 } UENUM1BYTE(COMP_REFERENCE_TYPE);

 enum { PLANE_TYPE_Y, PLANE_TYPE_UV, PLANE_TYPES } UENUM1BYTE(PLANE_TYPE);

 #define CFL_ALPHABET_SIZE_LOG2 4
 #define CFL_ALPHABET_SIZE (1 << CFL_ALPHABET_SIZE_LOG2)
 #define CFL_MAGS_SIZE ((2 << CFL_ALPHABET_SIZE_LOG2) + 1)
 #define CFL_INDEX_ZERO CFL_ALPHABET_SIZE
 #define CFL_IDX_U(idx) (idx >> CFL_ALPHABET_SIZE_LOG2)
 #define CFL_IDX_V(idx) (idx & (CFL_ALPHABET_SIZE - 1))

 enum { CFL_PRED_U, CFL_PRED_V, CFL_PRED_PLANES } UENUM1BYTE(CFL_PRED_TYPE);

 enum {
   CFL_SIGN_ZERO,
   CFL_SIGN_NEG,
   CFL_SIGN_POS,
   CFL_SIGNS
 } UENUM1BYTE(CFL_SIGN_TYPE);

 enum {
   CFL_DISALLOWED,
   CFL_ALLOWED,
   CFL_ALLOWED_TYPES
 } UENUM1BYTE(CFL_ALLOWED_TYPE);

 // CFL_SIGN_ZERO,CFL_SIGN_ZERO is invalid
 #define CFL_JOINT_SIGNS (CFL_SIGNS * CFL_SIGNS - 1)
 // CFL_SIGN_U is equivalent to (js + 1) / 3 for js in 0 to 8
 #define CFL_SIGN_U(js) (((js + 1) * 11) >> 5)
 // CFL_SIGN_V is equivalent to (js + 1) % 3 for js in 0 to 8
 #define CFL_SIGN_V(js) ((js + 1) - CFL_SIGNS * CFL_SIGN_U(js))

 // There is no context when the alpha for a given plane is zero.
 // So there are 2 fewer contexts than joint signs.
 #define CFL_ALPHA_CONTEXTS (CFL_JOINT_SIGNS + 1 - CFL_SIGNS)
 #define CFL_CONTEXT_U(js) (js + 1 - CFL_SIGNS)
 // Also, the contexts are symmetric under swapping the planes.
 #define CFL_CONTEXT_V(js) \
   (CFL_SIGN_V(js) * CFL_SIGNS + CFL_SIGN_U(js) - CFL_SIGNS)

 enum {
   PALETTE_MAP,
   COLOR_MAP_TYPES,
 } UENUM1BYTE(COLOR_MAP_TYPE);

 enum {
   TWO_COLORS,
   THREE_COLORS,
   FOUR_COLORS,
   FIVE_COLORS,
   SIX_COLORS,
   SEVEN_COLORS,
   EIGHT_COLORS,
   PALETTE_SIZES
 } UENUM1BYTE(PALETTE_SIZE);

 enum {
   PALETTE_COLOR_ONE,
   PALETTE_COLOR_TWO,
   PALETTE_COLOR_THREE,
   PALETTE_COLOR_FOUR,
   PALETTE_COLOR_FIVE,
   PALETTE_COLOR_SIX,
   PALETTE_COLOR_SEVEN,
   PALETTE_COLOR_EIGHT,
   PALETTE_COLORS
 } UENUM1BYTE(PALETTE_COLOR);

 // Note: All directional predictors must be between V_PRED and D67_PRED (both
 // inclusive).
 enum {
   DC_PRED,        // Average of above and left pixels
   V_PRED,         // Vertical
   H_PRED,         // Horizontal
   D45_PRED,       // Directional 45  degree
   D135_PRED,      // Directional 135 degree
   D113_PRED,      // Directional 113 degree
   D157_PRED,      // Directional 157 degree
   D203_PRED,      // Directional 203 degree
   D67_PRED,       // Directional 67  degree
   SMOOTH_PRED,    // Combination of horizontal and vertical interpolation
   SMOOTH_V_PRED,  // Vertical interpolation
   SMOOTH_H_PRED,  // Horizontal interpolation
   PAETH_PRED,     // Predict from the direction of smallest gradient
   NEARESTMV,
   NEARMV,
   GLOBALMV,
   NEWMV,
   // Compound ref compound modes
   NEAREST_NEARESTMV,
   NEAR_NEARMV,
   NEAREST_NEWMV,
   NEW_NEARESTMV,
   NEAR_NEWMV,
   NEW_NEARMV,
   GLOBAL_GLOBALMV,
   NEW_NEWMV,
   MB_MODE_COUNT,
   PRED_MODE_INVALID = MB_MODE_COUNT,
   INTRA_MODE_START = DC_PRED,
   INTRA_MODE_END = NEARESTMV,
   DIR_MODE_START = V_PRED,
   DIR_MODE_END = D67_PRED + 1,
   INTRA_MODE_NUM = INTRA_MODE_END - INTRA_MODE_START,
   SINGLE_INTER_MODE_START = NEARESTMV,
   SINGLE_INTER_MODE_END = NEAREST_NEARESTMV,
   SINGLE_INTER_MODE_NUM = SINGLE_INTER_MODE_END - SINGLE_INTER_MODE_START,
   COMP_INTER_MODE_START = NEAREST_NEARESTMV,
   COMP_INTER_MODE_END = MB_MODE_COUNT,
   COMP_INTER_MODE_NUM = COMP_INTER_MODE_END - COMP_INTER_MODE_START,
   INTER_MODE_START = NEARESTMV,
   INTER_MODE_END = MB_MODE_COUNT,
   INTRA_MODES = PAETH_PRED + 1,  // PAETH_PRED has to be the last intra mode.
   INTRA_INVALID = MB_MODE_COUNT  // For uv_mode in inter blocks
 } UENUM1BYTE(PREDICTION_MODE);

 // TODO(ltrudeau) Do we really want to pack this?
 // TODO(ltrudeau) Do we match with PREDICTION_MODE?
 enum {
   UV_DC_PRED,        // Average of above and left pixels
   UV_V_PRED,         // Vertical
   UV_H_PRED,         // Horizontal
   UV_D45_PRED,       // Directional 45  degree
   UV_D135_PRED,      // Directional 135 degree
   UV_D113_PRED,      // Directional 113 degree
   UV_D157_PRED,      // Directional 157 degree
   UV_D203_PRED,      // Directional 203 degree
   UV_D67_PRED,       // Directional 67  degree
   UV_SMOOTH_PRED,    // Combination of horizontal and vertical interpolation
   UV_SMOOTH_V_PRED,  // Vertical interpolation
   UV_SMOOTH_H_PRED,  // Horizontal interpolation
   UV_PAETH_PRED,     // Predict from the direction of smallest gradient
   UV_CFL_PRED,       // Chroma-from-Luma
   UV_INTRA_MODES,
   UV_MODE_INVALID,  // For uv_mode in inter blocks
 } UENUM1BYTE(UV_PREDICTION_MODE);

 // Number of top model rd to store for pruning y modes in intra mode decision
 #define TOP_INTRA_MODEL_COUNT 4
 // Total number of luma intra prediction modes (include both directional and
 // non-directional modes)
 // Because there are 8 directional modes, each has additional 6 delta angles.
 #define LUMA_MODE_COUNT (PAETH_PRED - DC_PRED + 1 + 6 * 8)

 enum {
   SIMPLE_TRANSLATION,
   OBMC_CAUSAL,    // 2-sided OBMC
   WARPED_CAUSAL,  // 2-sided WARPED
   MOTION_MODES
 } UENUM1BYTE(MOTION_MODE);

 enum {
   II_DC_PRED,
   II_V_PRED,
   II_H_PRED,
   II_SMOOTH_PRED,
   INTERINTRA_MODES
 } UENUM1BYTE(INTERINTRA_MODE);

 enum {
   COMPOUND_AVERAGE,
   COMPOUND_DISTWTD,
   COMPOUND_WEDGE,
   COMPOUND_DIFFWTD,
   COMPOUND_TYPES,
   MASKED_COMPOUND_TYPES = 2,
 } UENUM1BYTE(COMPOUND_TYPE);

 enum {
   FILTER_DC_PRED,
   FILTER_V_PRED,
   FILTER_H_PRED,
   FILTER_D157_PRED,
   FILTER_PAETH_PRED,
   FILTER_INTRA_MODES,
 } UENUM1BYTE(FILTER_INTRA_MODE);

 enum {
   SEQ_LEVEL_2_0,
   SEQ_LEVEL_2_1,
   SEQ_LEVEL_2_2,
   SEQ_LEVEL_2_3,
   SEQ_LEVEL_3_0,
   SEQ_LEVEL_3_1,
   SEQ_LEVEL_3_2,
   SEQ_LEVEL_3_3,
   SEQ_LEVEL_4_0,
   SEQ_LEVEL_4_1,
   SEQ_LEVEL_4_2,
   SEQ_LEVEL_4_3,
   SEQ_LEVEL_5_0,
   SEQ_LEVEL_5_1,
   SEQ_LEVEL_5_2,
   SEQ_LEVEL_5_3,
   SEQ_LEVEL_6_0,
   SEQ_LEVEL_6_1,
   SEQ_LEVEL_6_2,
   SEQ_LEVEL_6_3,
   SEQ_LEVEL_7_0,
   SEQ_LEVEL_7_1,
   SEQ_LEVEL_7_2,
   SEQ_LEVEL_7_3,
   SEQ_LEVEL_8_0,
   SEQ_LEVEL_8_1,
   SEQ_LEVEL_8_2,
   SEQ_LEVEL_8_3,
   SEQ_LEVELS,
   SEQ_LEVEL_MAX = 31,
   SEQ_LEVEL_KEEP_STATS = 32,
 } UENUM1BYTE(AV1_LEVEL);

 #define LEVEL_BITS 5

 #define DIRECTIONAL_MODES 8
 #define MAX_ANGLE_DELTA 3
 #define ANGLE_STEP 3

 #define INTER_MODES (1 + NEWMV - NEARESTMV)

 #define INTER_COMPOUND_MODES (1 + NEW_NEWMV - NEAREST_NEARESTMV)

 #define SKIP_CONTEXTS 3
 #define SKIP_MODE_CONTEXTS 3

 #define COMP_INDEX_CONTEXTS 6
 #define COMP_GROUP_IDX_CONTEXTS 6

 #define NMV_CONTEXTS 3

 #define NEWMV_MODE_CONTEXTS 6
 #define GLOBALMV_MODE_CONTEXTS 2
 #define REFMV_MODE_CONTEXTS 6
 #define DRL_MODE_CONTEXTS 3

 #define GLOBALMV_OFFSET 3
 #define REFMV_OFFSET 4

 #define NEWMV_CTX_MASK ((1 << GLOBALMV_OFFSET) - 1)
 #define GLOBALMV_CTX_MASK ((1 << (REFMV_OFFSET - GLOBALMV_OFFSET)) - 1)
 #define REFMV_CTX_MASK ((1 << (8 - REFMV_OFFSET)) - 1)

 #define COMP_NEWMV_CTXS 5
 #define INTER_MODE_CONTEXTS 8

 #define DELTA_Q_SMALL 3
 #define DELTA_Q_PROBS (DELTA_Q_SMALL)
 #define DEFAULT_DELTA_Q_RES_PERCEPTUAL 4
 #define DEFAULT_DELTA_Q_RES_OBJECTIVE 4
 #define DEFAULT_DELTA_Q_RES_DUCKY_ENCODE 4

 #define DELTA_LF_SMALL 3
 #define DELTA_LF_PROBS (DELTA_LF_SMALL)
 #define DEFAULT_DELTA_LF_RES 2

 /* Segment Feature Masks */
 #define MAX_MV_REF_CANDIDATES 2

 #define MAX_REF_MV_STACK_SIZE 8
 #define USABLE_REF_MV_STACK_SIZE 4
 #define REF_CAT_LEVEL 640

 #define INTRA_INTER_CONTEXTS 4
 #define COMP_INTER_CONTEXTS 5
 #define REF_CONTEXTS 3

 #define COMP_REF_TYPE_CONTEXTS 5
 #define UNI_COMP_REF_CONTEXTS 3

 #define TXFM_PARTITION_CONTEXTS ((TX_SIZES - TX_8X8) * 6 - 3)
 typedef uint8_t TXFM_CONTEXT;

 // An enum for single reference types (and some derived values).
 enum {
   NONE_FRAME = -1,
   INTRA_FRAME,
   LAST_FRAME,
   LAST2_FRAME,
   LAST3_FRAME,
   GOLDEN_FRAME,
   BWDREF_FRAME,
   ALTREF2_FRAME,
   ALTREF_FRAME,
   REF_FRAMES,

   // Extra/scratch reference frame. It may be:
   // - used to update the ALTREF2_FRAME ref (see lshift_bwd_ref_frames()), or
   // - updated from ALTREF2_FRAME ref (see rshift_bwd_ref_frames()).
   EXTREF_FRAME = REF_FRAMES,

   // Number of inter (non-intra) reference types.
   INTER_REFS_PER_FRAME = ALTREF_FRAME - LAST_FRAME + 1,

   // Number of forward (aka past) reference types.
   FWD_REFS = GOLDEN_FRAME - LAST_FRAME + 1,

   // Number of backward (aka future) reference types.
   BWD_REFS = ALTREF_FRAME - BWDREF_FRAME + 1,

   SINGLE_REFS = FWD_REFS + BWD_REFS,
 };

 #define REF_FRAMES_LOG2 3

 // REF_FRAMES for the cm->ref_frame_map array, 1 scratch frame for the new
 // frame in cm->cur_frame, INTER_REFS_PER_FRAME for scaled references on the
 // encoder in the cpi->scaled_ref_buf array.
 // The encoder uses FRAME_BUFFERS only in GOOD and REALTIME encoding modes.
 // The decoder also uses FRAME_BUFFERS.
 #define FRAME_BUFFERS (REF_FRAMES + 1 + INTER_REFS_PER_FRAME)

 // During allintra encoding, one reference frame buffer is free to be used again
 // only after another frame buffer is stored as the reference frame. Hence, it
 // is necessary and sufficient to maintain only two reference frame buffers in
 // this case.
 #define FRAME_BUFFERS_ALLINTRA 2

 #define FWD_RF_OFFSET(ref) (ref - LAST_FRAME)
 #define BWD_RF_OFFSET(ref) (ref - BWDREF_FRAME)

 // Select all the decoded frame buffer slots
 #define SELECT_ALL_BUF_SLOTS 0xFF

 enum {
   LAST_LAST2_FRAMES,      // { LAST_FRAME, LAST2_FRAME }
   LAST_LAST3_FRAMES,      // { LAST_FRAME, LAST3_FRAME }
   LAST_GOLDEN_FRAMES,     // { LAST_FRAME, GOLDEN_FRAME }
   BWDREF_ALTREF_FRAMES,   // { BWDREF_FRAME, ALTREF_FRAME }
   LAST2_LAST3_FRAMES,     // { LAST2_FRAME, LAST3_FRAME }
   LAST2_GOLDEN_FRAMES,    // { LAST2_FRAME, GOLDEN_FRAME }
   LAST3_GOLDEN_FRAMES,    // { LAST3_FRAME, GOLDEN_FRAME }
   BWDREF_ALTREF2_FRAMES,  // { BWDREF_FRAME, ALTREF2_FRAME }
   ALTREF2_ALTREF_FRAMES,  // { ALTREF2_FRAME, ALTREF_FRAME }
   TOTAL_UNIDIR_COMP_REFS,
   // NOTE: UNIDIR_COMP_REFS is the number of uni-directional reference pairs
   //       that are explicitly signaled.
   UNIDIR_COMP_REFS = BWDREF_ALTREF_FRAMES + 1,
 } UENUM1BYTE(UNIDIR_COMP_REF);

 #define TOTAL_COMP_REFS (FWD_REFS * BWD_REFS + TOTAL_UNIDIR_COMP_REFS)

 #define COMP_REFS (FWD_REFS * BWD_REFS + UNIDIR_COMP_REFS)

 // NOTE: A limited number of unidirectional reference pairs can be signalled for
 //       compound prediction. The use of skip mode, on the other hand, makes it
 //       possible to have a reference pair not listed for explicit signaling.
 #define MODE_CTX_REF_FRAMES (REF_FRAMES + TOTAL_COMP_REFS)

 // Note: It includes single and compound references. So, it can take values from
 // NONE_FRAME to (MODE_CTX_REF_FRAMES - 1). Hence, it is not defined as an enum.
 typedef int8_t MV_REFERENCE_FRAME;

 /*!\endcond */

 /*!\enum RestorationType
  * \brief This enumeration defines various restoration types supported
  */
 typedef enum {
   RESTORE_NONE,       /**< No restoration */
   RESTORE_WIENER,     /**< Separable Wiener restoration */
   RESTORE_SGRPROJ,    /**< Selfguided restoration */
   RESTORE_SWITCHABLE, /**< Switchable restoration */
   RESTORE_SWITCHABLE_TYPES = RESTORE_SWITCHABLE, /**< Num Switchable types */
   RESTORE_TYPES = 4,                             /**< Num Restore types */
 } RestorationType;

 /*!\cond */
 // Picture prediction structures (0-13 are predefined) in scalability metadata.
 enum {
   SCALABILITY_L1T2 = 0,
   SCALABILITY_L1T3 = 1,
   SCALABILITY_L2T1 = 2,
   SCALABILITY_L2T2 = 3,
   SCALABILITY_L2T3 = 4,
   SCALABILITY_S2T1 = 5,
   SCALABILITY_S2T2 = 6,
   SCALABILITY_S2T3 = 7,
   SCALABILITY_L2T1h = 8,
   SCALABILITY_L2T2h = 9,
   SCALABILITY_L2T3h = 10,
   SCALABILITY_S2T1h = 11,
   SCALABILITY_S2T2h = 12,
   SCALABILITY_S2T3h = 13,
   SCALABILITY_SS = 14
 } UENUM1BYTE(SCALABILITY_STRUCTURES);

 #define SUPERRES_SCALE_BITS 3
 #define SUPERRES_SCALE_DENOMINATOR_MIN (SCALE_NUMERATOR + 1)

 // In large_scale_tile coding, external references are used.
 #define MAX_EXTERNAL_REFERENCES 128
 #define MAX_TILES 512

 /*!\endcond */

 #ifdef __cplusplus
 }  // extern "C"
 #endif

 #endif  // AOM_AV1_COMMON_ENUMS_H_
	/*
	* Copyright (c) 2016, Alliance for Open Media. All rights reserved
	*
	* This source code is subject to the terms of the BSD 2 Clause License and
	* the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
	* was not distributed with this source code in the LICENSE file, you can
	* obtain it at www.aomedia.org/license/software. If the Alliance for Open
	* Media Patent License 1.0 was not distributed with this source code in the
	* PATENTS file, you can obtain it at www.aomedia.org/license/patent.
	*/

	#ifndef AOM_AV1_COMMON_ENUMS_H_
	#define AOM_AV1_COMMON_ENUMS_H_

	#include "config/aom_config.h"

	#include "aom/aom_codec.h"
	#include "aom/aom_integer.h"
	#include "aom_dsp/txfm_common.h"
	#include "aom_ports/mem.h"

	#ifdef __cplusplus
	extern "C" {
	#endif

	/! @file /

	/!\cond /

	// Max superblock size
	#define MAX_SB_SIZE_LOG2 7
	#define MAX_SB_SIZE (1 << MAX_SB_SIZE_LOG2)
	#define MAX_SB_SQUARE (MAX_SB_SIZE * MAX_SB_SIZE)

	// Min superblock size
	#define MIN_SB_SIZE_LOG2 6

	// Pixels per Mode Info (MI) unit
	#define MI_SIZE_LOG2 2
	#define MI_SIZE (1 << MI_SIZE_LOG2)

	// MI-units per max superblock (MI Block - MIB)
	#define MAX_MIB_SIZE_LOG2 (MAX_SB_SIZE_LOG2 - MI_SIZE_LOG2)
	#define MAX_MIB_SIZE (1 << MAX_MIB_SIZE_LOG2)

	// MI-units per min superblock
	#define MIN_MIB_SIZE_LOG2 (MIN_SB_SIZE_LOG2 - MI_SIZE_LOG2)

	// Mask to extract MI offset within max MIB
	#define MAX_MIB_MASK (MAX_MIB_SIZE - 1)

	// Maximum number of tile rows and tile columns
	#define MAX_TILE_ROWS 64
	#define MAX_TILE_COLS 64

	#define MAX_VARTX_DEPTH 2

	#define MI_SIZE_64X64 (64 >> MI_SIZE_LOG2)
	#define MI_SIZE_128X128 (128 >> MI_SIZE_LOG2)

	#define MAX_PALETTE_SQUARE (64 * 64)
	// Maximum number of colors in a palette.
	#define PALETTE_MAX_SIZE 8
	// Minimum number of colors in a palette.
	#define PALETTE_MIN_SIZE 2

	#define FRAME_OFFSET_BITS 5
	#define MAX_FRAME_DISTANCE ((1 << FRAME_OFFSET_BITS) - 1)

	// 4 frame filter levels: y plane vertical, y plane horizontal,
	// u plane, and v plane
	#define FRAME_LF_COUNT 4
	#define DEFAULT_DELTA_LF_MULTI 0
	#define MAX_MODE_LF_DELTAS 2

	#define DIST_PRECISION_BITS 4
	#define DIST_PRECISION (1 << DIST_PRECISION_BITS) // 16

	#define PROFILE_BITS 3
	// The following three profiles are currently defined.
	// Profile 0. 8-bit and 10-bit 4:2:0 and 4:0:0 only.
	// Profile 1. 8-bit and 10-bit 4:4:4
	// Profile 2. 8-bit and 10-bit 4:2:2
	// 12-bit 4:0:0, 4:2:2 and 4:4:4
	// Since we have three bits for the profiles, it can be extended later.
	enum {
	PROFILE_0,
	PROFILE_1,
	PROFILE_2,
	MAX_PROFILES,
	} SENUM1BYTE(BITSTREAM_PROFILE);

	#define OP_POINTS_CNT_MINUS_1_BITS 5
	#define OP_POINTS_IDC_BITS 12

	// Note: Some enums use the attribute 'packed' to use smallest possible integer
	// type, so that we can save memory when they are used in structs/arrays.

	typedef enum ATTRIBUTE_PACKED {
	BLOCK_4X4,
	BLOCK_4X8,
	BLOCK_8X4,
	BLOCK_8X8,
	BLOCK_8X16,
	BLOCK_16X8,
	BLOCK_16X16,
	BLOCK_16X32,
	BLOCK_32X16,
	BLOCK_32X32,
	BLOCK_32X64,
	BLOCK_64X32,
	BLOCK_64X64,
	BLOCK_64X128,
	BLOCK_128X64,
	BLOCK_128X128,
	BLOCK_4X16,
	BLOCK_16X4,
	BLOCK_8X32,
	BLOCK_32X8,
	BLOCK_16X64,
	BLOCK_64X16,
	BLOCK_SIZES_ALL,
	BLOCK_SIZES = BLOCK_4X16,
	BLOCK_INVALID = 255,
	BLOCK_LARGEST = (BLOCK_SIZES - 1)
	} BLOCK_SIZE;

	// 4X4, 8X8, 16X16, 32X32, 64X64, 128X128
	#define SQR_BLOCK_SIZES 6

	// Partition types. R: Recursive
	//
	// NONE HORZ VERT SPLIT
	// +-------+ +-------+ +---+---+ +---+---+
	// \| \| \| \| \| \| \| \| R \| R \|
	// \| \| +-------+ \| \| \| +---+---+
	// \| \| \| \| \| \| \| \| R \| R \|
	// +-------+ +-------+ +---+---+ +---+---+
	//
	// HORZ_A HORZ_B VERT_A VERT_B
	// +---+---+ +-------+ +---+---+ +---+---+
	// \| \| \| \| \| \| \| \| \| \| \|
	// +---+---+ +---+---+ +---+ \| \| +---+
	// \| \| \| \| \| \| \| \| \| \| \|
	// +-------+ +---+---+ +---+---+ +---+---+
	//
	// HORZ_4 VERT_4
	// +-----+ +-+-+-+
	// +-----+ \| \| \| \|
	// +-----+ \| \| \| \|
	// +-----+ +-+-+-+
	enum {
	PARTITION_NONE,
	PARTITION_HORZ,
	PARTITION_VERT,
	PARTITION_SPLIT,
	PARTITION_HORZ_A, // HORZ split and the top partition is split again
	PARTITION_HORZ_B, // HORZ split and the bottom partition is split again
	PARTITION_VERT_A, // VERT split and the left partition is split again
	PARTITION_VERT_B, // VERT split and the right partition is split again
	PARTITION_HORZ_4, // 4:1 horizontal partition
	PARTITION_VERT_4, // 4:1 vertical partition
	EXT_PARTITION_TYPES,
	PARTITION_TYPES = PARTITION_SPLIT + 1,
	PARTITION_INVALID = 255
	} UENUM1BYTE(PARTITION_TYPE);

	typedef char PARTITION_CONTEXT;
	#define PARTITION_PLOFFSET 4 // number of probability models per block size
	#define PARTITION_BLOCK_SIZES 5
	#define PARTITION_CONTEXTS (PARTITION_BLOCK_SIZES * PARTITION_PLOFFSET)

	#define TX_SIZE_LUMA_MIN (TX_4X4)
	/* We don't need to code a transform size unless the allowed size is at least
	one more than the minimum. */
	#define TX_SIZE_CTX_MIN (TX_SIZE_LUMA_MIN + 1)

	// Maximum tx_size categories
	#define MAX_TX_CATS (TX_SIZES - TX_SIZE_CTX_MIN)
	#define MAX_TX_DEPTH 2

	#define MAX_TX_SIZE_LOG2 (6)
	#define MAX_TX_SIZE (1 << MAX_TX_SIZE_LOG2)
	#define MIN_TX_SIZE_LOG2 2
	#define MIN_TX_SIZE (1 << MIN_TX_SIZE_LOG2)
	#define MAX_TX_SQUARE (MAX_TX_SIZE * MAX_TX_SIZE)

	// Pad 4 extra columns to remove horizontal availability check.
	#define TX_PAD_HOR_LOG2 2
	#define TX_PAD_HOR 4
	// Pad 6 extra rows (2 on top and 4 on bottom) to remove vertical availability
	// check.
	#define TX_PAD_TOP 0
	#define TX_PAD_BOTTOM 4
	#define TX_PAD_VER (TX_PAD_TOP + TX_PAD_BOTTOM)
	// Pad 16 extra bytes to avoid reading overflow in SIMD optimization.
	#define TX_PAD_END 16
	#define TX_PAD_2D ((32 + TX_PAD_HOR) * (32 + TX_PAD_VER) + TX_PAD_END)

	// Number of maximum size transform blocks in the maximum size superblock
	#define MAX_TX_BLOCKS_IN_MAX_SB_LOG2 ((MAX_SB_SIZE_LOG2 - MAX_TX_SIZE_LOG2) * 2)
	#define MAX_TX_BLOCKS_IN_MAX_SB (1 << MAX_TX_BLOCKS_IN_MAX_SB_LOG2)

	// frame transform mode
	enum {
	ONLY_4X4, // use only 4x4 transform
	TX_MODE_LARGEST, // transform size is the largest possible for pu size
	TX_MODE_SELECT, // transform specified for each block
	TX_MODES,
	} UENUM1BYTE(TX_MODE);

	// 1D tx types
	enum {
	DCT_1D,
	ADST_1D,
	FLIPADST_1D,
	IDTX_1D,
	TX_TYPES_1D,
	} UENUM1BYTE(TX_TYPE_1D);

	enum {
	REG_REG,
	REG_SMOOTH,
	REG_SHARP,
	SMOOTH_REG,
	SMOOTH_SMOOTH,
	SMOOTH_SHARP,
	SHARP_REG,
	SHARP_SMOOTH,
	SHARP_SHARP,
	} UENUM1BYTE(DUAL_FILTER_TYPE);

	#define EXT_TX_SIZES 4 // number of sizes that use extended transforms
	#define EXT_TX_SETS_INTER 4 // Sets of transform selections for INTER
	#define EXT_TX_SETS_INTRA 3 // Sets of transform selections for INTRA

	enum {
	AOM_LAST_FLAG = 1 << 0,
	AOM_LAST2_FLAG = 1 << 1,
	AOM_LAST3_FLAG = 1 << 2,
	AOM_GOLD_FLAG = 1 << 3,
	AOM_BWD_FLAG = 1 << 4,
	AOM_ALT2_FLAG = 1 << 5,
	AOM_ALT_FLAG = 1 << 6,
	AOM_REFFRAME_ALL = (1 << 7) - 1
	} UENUM1BYTE(AOM_REFFRAME);

	enum {
	UNIDIR_COMP_REFERENCE,
	BIDIR_COMP_REFERENCE,
	COMP_REFERENCE_TYPES,
	} UENUM1BYTE(COMP_REFERENCE_TYPE);

	enum { PLANE_TYPE_Y, PLANE_TYPE_UV, PLANE_TYPES } UENUM1BYTE(PLANE_TYPE);

	#define CFL_ALPHABET_SIZE_LOG2 4
	#define CFL_ALPHABET_SIZE (1 << CFL_ALPHABET_SIZE_LOG2)
	#define CFL_MAGS_SIZE ((2 << CFL_ALPHABET_SIZE_LOG2) + 1)
	#define CFL_INDEX_ZERO CFL_ALPHABET_SIZE
	#define CFL_IDX_U(idx) (idx >> CFL_ALPHABET_SIZE_LOG2)
	#define CFL_IDX_V(idx) (idx & (CFL_ALPHABET_SIZE - 1))

	enum { CFL_PRED_U, CFL_PRED_V, CFL_PRED_PLANES } UENUM1BYTE(CFL_PRED_TYPE);

	enum {
	CFL_SIGN_ZERO,
	CFL_SIGN_NEG,
	CFL_SIGN_POS,
	CFL_SIGNS
	} UENUM1BYTE(CFL_SIGN_TYPE);

	enum {
	CFL_DISALLOWED,
	CFL_ALLOWED,
	CFL_ALLOWED_TYPES
	} UENUM1BYTE(CFL_ALLOWED_TYPE);

	// CFL_SIGN_ZERO,CFL_SIGN_ZERO is invalid
	#define CFL_JOINT_SIGNS (CFL_SIGNS * CFL_SIGNS - 1)
	// CFL_SIGN_U is equivalent to (js + 1) / 3 for js in 0 to 8
	#define CFL_SIGN_U(js) (((js + 1) * 11) >> 5)
	// CFL_SIGN_V is equivalent to (js + 1) % 3 for js in 0 to 8
	#define CFL_SIGN_V(js) ((js + 1) - CFL_SIGNS * CFL_SIGN_U(js))

	// There is no context when the alpha for a given plane is zero.
	// So there are 2 fewer contexts than joint signs.
	#define CFL_ALPHA_CONTEXTS (CFL_JOINT_SIGNS + 1 - CFL_SIGNS)
	#define CFL_CONTEXT_U(js) (js + 1 - CFL_SIGNS)
	// Also, the contexts are symmetric under swapping the planes.
	#define CFL_CONTEXT_V(js) \
	(CFL_SIGN_V(js) * CFL_SIGNS + CFL_SIGN_U(js) - CFL_SIGNS)

	enum {
	PALETTE_MAP,
	COLOR_MAP_TYPES,
	} UENUM1BYTE(COLOR_MAP_TYPE);

	enum {
	TWO_COLORS,
	THREE_COLORS,
	FOUR_COLORS,
	FIVE_COLORS,
	SIX_COLORS,
	SEVEN_COLORS,
	EIGHT_COLORS,
	PALETTE_SIZES
	} UENUM1BYTE(PALETTE_SIZE);

	enum {
	PALETTE_COLOR_ONE,
	PALETTE_COLOR_TWO,
	PALETTE_COLOR_THREE,
	PALETTE_COLOR_FOUR,
	PALETTE_COLOR_FIVE,
	PALETTE_COLOR_SIX,
	PALETTE_COLOR_SEVEN,
	PALETTE_COLOR_EIGHT,
	PALETTE_COLORS
	} UENUM1BYTE(PALETTE_COLOR);

	// Note: All directional predictors must be between V_PRED and D67_PRED (both
	// inclusive).
	enum {
	DC_PRED, // Average of above and left pixels
	V_PRED, // Vertical
	H_PRED, // Horizontal
	D45_PRED, // Directional 45 degree
	D135_PRED, // Directional 135 degree
	D113_PRED, // Directional 113 degree
	D157_PRED, // Directional 157 degree
	D203_PRED, // Directional 203 degree
	D67_PRED, // Directional 67 degree
	SMOOTH_PRED, // Combination of horizontal and vertical interpolation
	SMOOTH_V_PRED, // Vertical interpolation
	SMOOTH_H_PRED, // Horizontal interpolation
	PAETH_PRED, // Predict from the direction of smallest gradient
	NEARESTMV,
	NEARMV,
	GLOBALMV,
	NEWMV,
	// Compound ref compound modes
	NEAREST_NEARESTMV,
	NEAR_NEARMV,
	NEAREST_NEWMV,
	NEW_NEARESTMV,
	NEAR_NEWMV,
	NEW_NEARMV,
	GLOBAL_GLOBALMV,
	NEW_NEWMV,
	MB_MODE_COUNT,
	PRED_MODE_INVALID = MB_MODE_COUNT,
	INTRA_MODE_START = DC_PRED,
	INTRA_MODE_END = NEARESTMV,
	DIR_MODE_START = V_PRED,
	DIR_MODE_END = D67_PRED + 1,
	INTRA_MODE_NUM = INTRA_MODE_END - INTRA_MODE_START,
	SINGLE_INTER_MODE_START = NEARESTMV,
	SINGLE_INTER_MODE_END = NEAREST_NEARESTMV,
	SINGLE_INTER_MODE_NUM = SINGLE_INTER_MODE_END - SINGLE_INTER_MODE_START,
	COMP_INTER_MODE_START = NEAREST_NEARESTMV,
	COMP_INTER_MODE_END = MB_MODE_COUNT,
	COMP_INTER_MODE_NUM = COMP_INTER_MODE_END - COMP_INTER_MODE_START,
	INTER_MODE_START = NEARESTMV,
	INTER_MODE_END = MB_MODE_COUNT,
	INTRA_MODES = PAETH_PRED + 1, // PAETH_PRED has to be the last intra mode.
	INTRA_INVALID = MB_MODE_COUNT // For uv_mode in inter blocks
	} UENUM1BYTE(PREDICTION_MODE);

	// TODO(ltrudeau) Do we really want to pack this?
	// TODO(ltrudeau) Do we match with PREDICTION_MODE?
	enum {
	UV_DC_PRED, // Average of above and left pixels
	UV_V_PRED, // Vertical
	UV_H_PRED, // Horizontal
	UV_D45_PRED, // Directional 45 degree
	UV_D135_PRED, // Directional 135 degree
	UV_D113_PRED, // Directional 113 degree
	UV_D157_PRED, // Directional 157 degree
	UV_D203_PRED, // Directional 203 degree
	UV_D67_PRED, // Directional 67 degree
	UV_SMOOTH_PRED, // Combination of horizontal and vertical interpolation
	UV_SMOOTH_V_PRED, // Vertical interpolation
	UV_SMOOTH_H_PRED, // Horizontal interpolation
	UV_PAETH_PRED, // Predict from the direction of smallest gradient
	UV_CFL_PRED, // Chroma-from-Luma
	UV_INTRA_MODES,
	UV_MODE_INVALID, // For uv_mode in inter blocks
	} UENUM1BYTE(UV_PREDICTION_MODE);

	// Number of top model rd to store for pruning y modes in intra mode decision
	#define TOP_INTRA_MODEL_COUNT 4
	// Total number of luma intra prediction modes (include both directional and
	// non-directional modes)
	// Because there are 8 directional modes, each has additional 6 delta angles.
	#define LUMA_MODE_COUNT (PAETH_PRED - DC_PRED + 1 + 6 * 8)

	enum {
	SIMPLE_TRANSLATION,
	OBMC_CAUSAL, // 2-sided OBMC
	WARPED_CAUSAL, // 2-sided WARPED
	MOTION_MODES
	} UENUM1BYTE(MOTION_MODE);

	enum {
	II_DC_PRED,
	II_V_PRED,
	II_H_PRED,
	II_SMOOTH_PRED,
	INTERINTRA_MODES
	} UENUM1BYTE(INTERINTRA_MODE);

	enum {
	COMPOUND_AVERAGE,
	COMPOUND_DISTWTD,
	COMPOUND_WEDGE,
	COMPOUND_DIFFWTD,
	COMPOUND_TYPES,
	MASKED_COMPOUND_TYPES = 2,
	} UENUM1BYTE(COMPOUND_TYPE);

	enum {
	FILTER_DC_PRED,
	FILTER_V_PRED,
	FILTER_H_PRED,
	FILTER_D157_PRED,
	FILTER_PAETH_PRED,
	FILTER_INTRA_MODES,
	} UENUM1BYTE(FILTER_INTRA_MODE);

	enum {
	SEQ_LEVEL_2_0,
	SEQ_LEVEL_2_1,
	SEQ_LEVEL_2_2,
	SEQ_LEVEL_2_3,
	SEQ_LEVEL_3_0,
	SEQ_LEVEL_3_1,
	SEQ_LEVEL_3_2,
	SEQ_LEVEL_3_3,
	SEQ_LEVEL_4_0,
	SEQ_LEVEL_4_1,
	SEQ_LEVEL_4_2,
	SEQ_LEVEL_4_3,
	SEQ_LEVEL_5_0,
	SEQ_LEVEL_5_1,
	SEQ_LEVEL_5_2,
	SEQ_LEVEL_5_3,
	SEQ_LEVEL_6_0,
	SEQ_LEVEL_6_1,
	SEQ_LEVEL_6_2,
	SEQ_LEVEL_6_3,
	SEQ_LEVEL_7_0,
	SEQ_LEVEL_7_1,
	SEQ_LEVEL_7_2,
	SEQ_LEVEL_7_3,
	SEQ_LEVEL_8_0,
	SEQ_LEVEL_8_1,
	SEQ_LEVEL_8_2,
	SEQ_LEVEL_8_3,
	SEQ_LEVELS,
	SEQ_LEVEL_MAX = 31,
	SEQ_LEVEL_KEEP_STATS = 32,
	} UENUM1BYTE(AV1_LEVEL);

	#define LEVEL_BITS 5

	#define DIRECTIONAL_MODES 8
	#define MAX_ANGLE_DELTA 3
	#define ANGLE_STEP 3

	#define INTER_MODES (1 + NEWMV - NEARESTMV)

	#define INTER_COMPOUND_MODES (1 + NEW_NEWMV - NEAREST_NEARESTMV)

	#define SKIP_CONTEXTS 3
	#define SKIP_MODE_CONTEXTS 3

	#define COMP_INDEX_CONTEXTS 6
	#define COMP_GROUP_IDX_CONTEXTS 6

	#define NMV_CONTEXTS 3

	#define NEWMV_MODE_CONTEXTS 6
	#define GLOBALMV_MODE_CONTEXTS 2
	#define REFMV_MODE_CONTEXTS 6
	#define DRL_MODE_CONTEXTS 3

	#define GLOBALMV_OFFSET 3
	#define REFMV_OFFSET 4

	#define NEWMV_CTX_MASK ((1 << GLOBALMV_OFFSET) - 1)
	#define GLOBALMV_CTX_MASK ((1 << (REFMV_OFFSET - GLOBALMV_OFFSET)) - 1)
	#define REFMV_CTX_MASK ((1 << (8 - REFMV_OFFSET)) - 1)

	#define COMP_NEWMV_CTXS 5
	#define INTER_MODE_CONTEXTS 8

	#define DELTA_Q_SMALL 3
	#define DELTA_Q_PROBS (DELTA_Q_SMALL)
	#define DEFAULT_DELTA_Q_RES_PERCEPTUAL 4
	#define DEFAULT_DELTA_Q_RES_OBJECTIVE 4
	#define DEFAULT_DELTA_Q_RES_DUCKY_ENCODE 4

	#define DELTA_LF_SMALL 3
	#define DELTA_LF_PROBS (DELTA_LF_SMALL)
	#define DEFAULT_DELTA_LF_RES 2

	/* Segment Feature Masks */
	#define MAX_MV_REF_CANDIDATES 2

	#define MAX_REF_MV_STACK_SIZE 8
	#define USABLE_REF_MV_STACK_SIZE 4
	#define REF_CAT_LEVEL 640

	#define INTRA_INTER_CONTEXTS 4
	#define COMP_INTER_CONTEXTS 5
	#define REF_CONTEXTS 3

	#define COMP_REF_TYPE_CONTEXTS 5
	#define UNI_COMP_REF_CONTEXTS 3

	#define TXFM_PARTITION_CONTEXTS ((TX_SIZES - TX_8X8) * 6 - 3)
	typedef uint8_t TXFM_CONTEXT;

	// An enum for single reference types (and some derived values).
	enum {
	NONE_FRAME = -1,
	INTRA_FRAME,
	LAST_FRAME,
	LAST2_FRAME,
	LAST3_FRAME,
	GOLDEN_FRAME,
	BWDREF_FRAME,
	ALTREF2_FRAME,
	ALTREF_FRAME,
	REF_FRAMES,

	// Extra/scratch reference frame. It may be:
	// - used to update the ALTREF2_FRAME ref (see lshift_bwd_ref_frames()), or
	// - updated from ALTREF2_FRAME ref (see rshift_bwd_ref_frames()).
	EXTREF_FRAME = REF_FRAMES,

	// Number of inter (non-intra) reference types.
	INTER_REFS_PER_FRAME = ALTREF_FRAME - LAST_FRAME + 1,

	// Number of forward (aka past) reference types.
	FWD_REFS = GOLDEN_FRAME - LAST_FRAME + 1,

	// Number of backward (aka future) reference types.
	BWD_REFS = ALTREF_FRAME - BWDREF_FRAME + 1,

	SINGLE_REFS = FWD_REFS + BWD_REFS,
	};

	#define REF_FRAMES_LOG2 3

	// REF_FRAMES for the cm->ref_frame_map array, 1 scratch frame for the new
	// frame in cm->cur_frame, INTER_REFS_PER_FRAME for scaled references on the
	// encoder in the cpi->scaled_ref_buf array.
	// The encoder uses FRAME_BUFFERS only in GOOD and REALTIME encoding modes.
	// The decoder also uses FRAME_BUFFERS.
	#define FRAME_BUFFERS (REF_FRAMES + 1 + INTER_REFS_PER_FRAME)

	// During allintra encoding, one reference frame buffer is free to be used again
	// only after another frame buffer is stored as the reference frame. Hence, it
	// is necessary and sufficient to maintain only two reference frame buffers in
	// this case.
	#define FRAME_BUFFERS_ALLINTRA 2

	#define FWD_RF_OFFSET(ref) (ref - LAST_FRAME)
	#define BWD_RF_OFFSET(ref) (ref - BWDREF_FRAME)

	// Select all the decoded frame buffer slots
	#define SELECT_ALL_BUF_SLOTS 0xFF

	enum {
	LAST_LAST2_FRAMES, // { LAST_FRAME, LAST2_FRAME }
	LAST_LAST3_FRAMES, // { LAST_FRAME, LAST3_FRAME }
	LAST_GOLDEN_FRAMES, // { LAST_FRAME, GOLDEN_FRAME }
	BWDREF_ALTREF_FRAMES, // { BWDREF_FRAME, ALTREF_FRAME }
	LAST2_LAST3_FRAMES, // { LAST2_FRAME, LAST3_FRAME }
	LAST2_GOLDEN_FRAMES, // { LAST2_FRAME, GOLDEN_FRAME }
	LAST3_GOLDEN_FRAMES, // { LAST3_FRAME, GOLDEN_FRAME }
	BWDREF_ALTREF2_FRAMES, // { BWDREF_FRAME, ALTREF2_FRAME }
	ALTREF2_ALTREF_FRAMES, // { ALTREF2_FRAME, ALTREF_FRAME }
	TOTAL_UNIDIR_COMP_REFS,
	// NOTE: UNIDIR_COMP_REFS is the number of uni-directional reference pairs
	// that are explicitly signaled.
	UNIDIR_COMP_REFS = BWDREF_ALTREF_FRAMES + 1,
	} UENUM1BYTE(UNIDIR_COMP_REF);

	#define TOTAL_COMP_REFS (FWD_REFS * BWD_REFS + TOTAL_UNIDIR_COMP_REFS)

	#define COMP_REFS (FWD_REFS * BWD_REFS + UNIDIR_COMP_REFS)

	// NOTE: A limited number of unidirectional reference pairs can be signalled for
	// compound prediction. The use of skip mode, on the other hand, makes it
	// possible to have a reference pair not listed for explicit signaling.
	#define MODE_CTX_REF_FRAMES (REF_FRAMES + TOTAL_COMP_REFS)

	// Note: It includes single and compound references. So, it can take values from
	// NONE_FRAME to (MODE_CTX_REF_FRAMES - 1). Hence, it is not defined as an enum.
	typedef int8_t MV_REFERENCE_FRAME;

	/!\endcond /

	/*!\enum RestorationType
	* \brief This enumeration defines various restoration types supported
	*/
	typedef enum {
	RESTORE_NONE, /*< No restoration /
	RESTORE_WIENER, /*< Separable Wiener restoration /
	RESTORE_SGRPROJ, /*< Selfguided restoration /
	RESTORE_SWITCHABLE, /*< Switchable restoration /
	RESTORE_SWITCHABLE_TYPES = RESTORE_SWITCHABLE, /*< Num Switchable types /
	RESTORE_TYPES = 4, /*< Num Restore types /
	} RestorationType;

	/!\cond /
	// Picture prediction structures (0-13 are predefined) in scalability metadata.
	enum {
	SCALABILITY_L1T2 = 0,
	SCALABILITY_L1T3 = 1,
	SCALABILITY_L2T1 = 2,
	SCALABILITY_L2T2 = 3,
	SCALABILITY_L2T3 = 4,
	SCALABILITY_S2T1 = 5,
	SCALABILITY_S2T2 = 6,
	SCALABILITY_S2T3 = 7,
	SCALABILITY_L2T1h = 8,
	SCALABILITY_L2T2h = 9,
	SCALABILITY_L2T3h = 10,
	SCALABILITY_S2T1h = 11,
	SCALABILITY_S2T2h = 12,
	SCALABILITY_S2T3h = 13,
	SCALABILITY_SS = 14
	} UENUM1BYTE(SCALABILITY_STRUCTURES);

	#define SUPERRES_SCALE_BITS 3
	#define SUPERRES_SCALE_DENOMINATOR_MIN (SCALE_NUMERATOR + 1)

	// In large_scale_tile coding, external references are used.
	#define MAX_EXTERNAL_REFERENCES 128
	#define MAX_TILES 512

	/!\endcond /

	#ifdef __cplusplus
	} // extern "C"
	#endif

	#endif // AOM_AV1_COMMON_ENUMS_H_