struct x264_t
{
/* encoder parameters */
x264_param_t param;
x264_t *thread[X264_THREAD_MAX+1];
x264_t *lookahead_thread[X264_LOOKAHEAD_THREAD_MAX];
int b_thread_active;
int i_thread_phase; /* which thread to use for the next frame */
int i_thread_idx; /* which thread this is */
int i_threadslice_start; /* first row in this thread slice */
int i_threadslice_end; /* row after the end of this thread slice */
int i_threadslice_pass; /* which pass of encoding we are on */
x264_threadpool_t *threadpool;
x264_threadpool_t *lookaheadpool;
x264_pthread_mutex_t mutex;
x264_pthread_cond_t cv;
/* bitstream output */
struct
{
int i_nal;
int i_nals_allocated;
x264_nal_t *nal;
int i_bitstream; /* size of p_bitstream */
uint8_t *p_bitstream; /* will hold data for all nal */
bs_t bs;
} out;
uint8_t *nal_buffer;
int nal_buffer_size;
/**** thread synchronization starts here ****/
/* frame number/poc */
int i_frame;
int i_frame_num;
int i_thread_frames; /* Number of different frames being encoded by threads;
* 1 when sliced-threads is on. */
int i_nal_type;
int i_nal_ref_idc;
int64_t i_disp_fields; /* Number of displayed fields (both coded and implied via pic_struct) */
int i_disp_fields_last_frame;
int64_t i_prev_duration; /* Duration of previous frame */
int64_t i_coded_fields; /* Number of coded fields (both coded and implied via pic_struct) */
int64_t i_cpb_delay; /* Equal to number of fields preceding this field
* since last buffering_period SEI */
int64_t i_coded_fields_lookahead; /* Use separate counters for lookahead */
int64_t i_cpb_delay_lookahead;
int64_t i_cpb_delay_pir_offset;
int64_t i_cpb_delay_pir_offset_next;
int b_queued_intra_refresh;
int64_t i_last_idr_pts;
int i_idr_pic_id;
/* quantization matrix for decoding, [cqm][qp%6][coef] */
int (*dequant4_mf[4])[16]; /* [4][6][16] */
int (*dequant8_mf[4])[64]; /* [4][6][64] */
/* quantization matrix for trellis, [cqm][qp][coef] */
int (*unquant4_mf[4])[16]; /* [4][52][16] */
int (*unquant8_mf[4])[64]; /* [4][52][64] */
/* quantization matrix for deadzone */
udctcoef (*quant4_mf[4])[16]; /* [4][52][16] */
udctcoef (*quant8_mf[4])[64]; /* [4][52][64] */
udctcoef (*quant4_bias[4])[16]; /* [4][52][16] */
udctcoef (*quant8_bias[4])[64]; /* [4][52][64] */
udctcoef (*quant4_bias0[4])[16]; /* [4][52][16] */
udctcoef (*quant8_bias0[4])[64]; /* [4][52][64] */
udctcoef (*nr_offset_emergency)[4][64];
/* mv/ref cost arrays. */
uint16_t *cost_mv[QP_MAX+1];
uint16_t *cost_mv_fpel[QP_MAX+1][4];
const uint8_t *chroma_qp_table; /* includes both the nonlinear luma->chroma mapping and chroma_qp_offset */
/* Slice header */
x264_slice_header_t sh;
/* SPS / PPS */
x264_sps_t sps[1];
x264_pps_t pps[1];
/* Slice header backup, for SEI_DEC_REF_PIC_MARKING */
int b_sh_backup;
x264_slice_header_t sh_backup;
/* cabac context */
x264_cabac_t cabac;
struct
{
/* Frames to be encoded (whose types have been decided) */
x264_frame_t **current;
/* Unused frames: 0 = fenc, 1 = fdec */
x264_frame_t **unused[2];
/* Unused blank frames (for duplicates) */
x264_frame_t **blank_unused;
/* frames used for reference + sentinels */
x264_frame_t *reference[X264_REF_MAX+2];
int i_last_keyframe; /* Frame number of the last keyframe */
int i_last_idr; /* Frame number of the last IDR (not RP)*/
int i_poc_last_open_gop; /* Poc of the I frame of the last open-gop. The value
* is only assigned during the period between that
* I frame and the next P or I frame, else -1 */
int i_input; /* Number of input frames already accepted */
int i_max_dpb; /* Number of frames allocated in the decoded picture buffer */
int i_max_ref0;
int i_max_ref1;
int i_delay; /* Number of frames buffered for B reordering */
int i_bframe_delay;
int64_t i_bframe_delay_time;
int64_t i_first_pts;
int64_t i_prev_reordered_pts[2];
int64_t i_largest_pts;
int64_t i_second_largest_pts;
int b_have_lowres; /* Whether 1/2 resolution luma planes are being used */
int b_have_sub8x8_esa;
} frames;
/* current frame being encoded */
x264_frame_t *fenc;
/* frame being reconstructed */
x264_frame_t *fdec;
/* references lists */
int i_ref[2];
x264_frame_t *fref[2][X264_REF_MAX+3];
x264_frame_t *fref_nearest[2];
int b_ref_reorder[2];
/* hrd */
int initial_cpb_removal_delay;
int initial_cpb_removal_delay_offset;
int64_t i_reordered_pts_delay;
/* Current MB DCT coeffs */
struct
{
ALIGNED_16( dctcoef luma16x16_dc[3][16] );
ALIGNED_16( dctcoef chroma_dc[2][8] );
// FIXME share memory?
ALIGNED_16( dctcoef luma8x8[12][64] );
ALIGNED_16( dctcoef luma4x4[16*3][16] );
} dct;
/* MB table and cache for current frame/mb */
struct
{
int i_mb_width;
int i_mb_height;
int i_mb_count; /* number of mbs in a frame */
/* Chroma subsampling */
int chroma_h_shift;
int chroma_v_shift;
/* Strides */
int i_mb_stride;
int i_b8_stride;
int i_b4_stride;
int left_b8[2];
int left_b4[2];
/* Current index */
int i_mb_x;
int i_mb_y;
int i_mb_xy;
int i_b8_xy;
int i_b4_xy;
/* Search parameters */
int i_me_method;
int i_subpel_refine;
int b_chroma_me;
int b_trellis;
int b_noise_reduction;
int b_dct_decimate;
int i_psy_rd; /* Psy RD strength--fixed point value*/
int i_psy_trellis; /* Psy trellis strength--fixed point value*/
int b_interlaced;
int b_adaptive_mbaff; /* MBAFF+subme 0 requires non-adaptive MBAFF i.e. all field mbs */
/* Allowed qpel MV range to stay within the picture + emulated edge pixels */
int mv_min[2];
int mv_max[2];
int mv_miny_row[3]; /* 0 == top progressive, 1 == bot progressive, 2 == interlaced */
int mv_maxy_row[3];
/* Subpel MV range for motion search.
* same mv_min/max but includes levels' i_mv_range. */
int mv_min_spel[2];
int mv_max_spel[2];
int mv_miny_spel_row[3];
int mv_maxy_spel_row[3];
/* Fullpel MV range for motion search */
int mv_min_fpel[2];
int mv_max_fpel[2];
int mv_miny_fpel_row[3];
int mv_maxy_fpel_row[3];
/* neighboring MBs */
unsigned int i_neighbour;
unsigned int i_neighbour8[4]; /* neighbours of each 8x8 or 4x4 block that are available */
unsigned int i_neighbour4[16]; /* at the time the block is coded */
unsigned int i_neighbour_intra; /* for constrained intra pred */
unsigned int i_neighbour_frame; /* ignoring slice boundaries */
int i_mb_type_top;
int i_mb_type_left[2];
int i_mb_type_topleft;
int i_mb_type_topright;
int i_mb_prev_xy;
int i_mb_left_xy[2];
int i_mb_top_xy;
int i_mb_topleft_xy;
int i_mb_topright_xy;
int i_mb_top_y;
int i_mb_topleft_y;
int i_mb_topright_y;
const x264_left_table_t *left_index_table;
int i_mb_top_mbpair_xy;
int topleft_partition;
int b_allow_skip;
int field_decoding_flag;
/**** thread synchronization ends here ****/
/* subsequent variables are either thread-local or constant,
* and won't be copied from one thread to another */
/* mb table */
int8_t *type; /* mb type */
uint8_t *partition; /* mb partition */
int8_t *qp; /* mb qp */
int16_t *cbp; /* mb cbp: 0x0?: luma, 0x?0: chroma, 0x100: luma dc, 0x0200 and 0x0400: chroma dc (all set for PCM)*/
int8_t (*intra4x4_pred_mode)[8]; /* intra4x4 pred mode. for non I4x4 set to I_PRED_4x4_DC(2) */
/* actually has only 7 entries; set to 8 for write-combining optimizations */
uint8_t (*non_zero_count)[16*3]; /* nzc. for I_PCM set to 16 */
int8_t *chroma_pred_mode; /* chroma_pred_mode. cabac only. for non intra I_PRED_CHROMA_DC(0) */
int16_t (*mv[2])[2]; /* mb mv. set to 0 for intra mb */
uint8_t (*mvd[2])[8][2]; /* absolute value of mb mv difference with predict, clipped to [0,33]. set to 0 if intra. cabac only */
int8_t *ref[2]; /* mb ref. set to -1 if non used (intra or Lx only) */
int16_t (*mvr[2][X264_REF_MAX*2])[2];/* 16x16 mv for each possible ref */
int8_t *skipbp; /* block pattern for SKIP or DIRECT (sub)mbs. B-frames + cabac only */
int8_t *mb_transform_size; /* transform_size_8x8_flag of each mb */
uint16_t *slice_table; /* sh->first_mb of the slice that the indexed mb is part of
* NOTE: this will fail on resolutions above 2^16 MBs... */
uint8_t *field;
/* buffer for weighted versions of the reference frames */
pixel *p_weight_buf[X264_REF_MAX];
/* current value */
int i_type;
int i_partition;
ALIGNED_4( uint8_t i_sub_partition[4] );
int b_transform_8x8;
int i_cbp_luma;
int i_cbp_chroma;
int i_intra16x16_pred_mode;
int i_chroma_pred_mode;
/* skip flags for i4x4 and i8x8
* 0 = encode as normal.
* 1 (non-RD only) = the DCT is still in h->dct, restore fdec and skip reconstruction.
* 2 (RD only) = the DCT has since been overwritten by RD; restore that too. */
int i_skip_intra;
/* skip flag for motion compensation */
/* if we've already done MC, we don't need to do it again */
int b_skip_mc;
/* set to true if we are re-encoding a macroblock. */
int b_reencode_mb;
int ip_offset; /* Used by PIR to offset the quantizer of intra-refresh blocks. */
int b_deblock_rdo;
int b_overflow; /* If CAVLC had a level code overflow during bitstream writing. */
struct
{
/* space for p_fenc and p_fdec */
#define FENC_STRIDE 16
#define FDEC_STRIDE 32
ALIGNED_16( pixel fenc_buf[48*FENC_STRIDE] );
ALIGNED_16( pixel fdec_buf[52*FDEC_STRIDE] );
/* i4x4 and i8x8 backup data, for skipping the encode stage when possible */
ALIGNED_16( pixel i4x4_fdec_buf[16*16] );
ALIGNED_16( pixel i8x8_fdec_buf[16*16] );
ALIGNED_16( dctcoef i8x8_dct_buf[3][64] );
ALIGNED_16( dctcoef i4x4_dct_buf[15][16] );
uint32_t i4x4_nnz_buf[4];
uint32_t i8x8_nnz_buf[4];
int i4x4_cbp;
int i8x8_cbp;
/* Psy trellis DCT data */
ALIGNED_16( dctcoef fenc_dct8[4][64] );
ALIGNED_16( dctcoef fenc_dct4[16][16] );
/* Psy RD SATD/SA8D scores cache */
ALIGNED_16( uint64_t fenc_hadamard_cache[9] );
ALIGNED_16( uint32_t fenc_satd_cache[32] );
/* pointer over mb of the frame to be compressed */
pixel *p_fenc[3]; /* y,u,v */
/* pointer to the actual source frame, not a block copy */
pixel *p_fenc_plane[3];
/* pointer over mb of the frame to be reconstructed */
pixel *p_fdec[3];
/* pointer over mb of the references */
int i_fref[2];
/* [12]: yN, yH, yV, yHV, (NV12 ? uv : I444 ? (uN, uH, uV, uHV, vN, ...)) */
pixel *p_fref[2][X264_REF_MAX*2][12];
pixel *p_fref_w[X264_REF_MAX*2]; /* weighted fullpel luma */
uint16_t *p_integral[2][X264_REF_MAX];
/* fref stride */
int i_stride[3];
} pic;
/* cache */
struct
{
/* real intra4x4_pred_mode if I_4X4 or I_8X8, I_PRED_4x4_DC if mb available, -1 if not */
ALIGNED_8( int8_t intra4x4_pred_mode[X264_SCAN8_LUMA_SIZE] );
/* i_non_zero_count if available else 0x80 */
ALIGNED_16( uint8_t non_zero_count[X264_SCAN8_SIZE] );
/* -1 if unused, -2 if unavailable */
ALIGNED_4( int8_t ref[2][X264_SCAN8_LUMA_SIZE] );
/* 0 if not available */
ALIGNED_16( int16_t mv[2][X264_SCAN8_LUMA_SIZE][2] );
ALIGNED_8( uint8_t mvd[2][X264_SCAN8_LUMA_SIZE][2] );
/* 1 if SKIP or DIRECT. set only for B-frames + CABAC */
ALIGNED_4( int8_t skip[X264_SCAN8_LUMA_SIZE] );
ALIGNED_4( int16_t direct_mv[2][4][2] );
ALIGNED_4( int8_t direct_ref[2][4] );
int direct_partition;
ALIGNED_4( int16_t pskip_mv[2] );
/* number of neighbors (top and left) that used 8x8 dct */
int i_neighbour_transform_size;
int i_neighbour_skip;
/* neighbor CBPs */
int i_cbp_top;
int i_cbp_left;
/* extra data required for mbaff in mv prediction */
int16_t topright_mv[2][3][2];
int8_t topright_ref[2][3];
/* current mb deblock strength */
uint8_t (*deblock_strength)[8][4];
} cache;
/* */
int i_qp; /* current qp */
int i_chroma_qp;
int i_last_qp; /* last qp */
int i_last_dqp; /* last delta qp */
int b_variable_qp; /* whether qp is allowed to vary per macroblock */
int b_lossless;
int b_direct_auto_read; /* take stats for --direct auto from the 2pass log */
int b_direct_auto_write; /* analyse direct modes, to use and/or save */
/* lambda values */
int i_trellis_lambda2[2][2]; /* [luma,chroma][inter,intra] */
int i_psy_rd_lambda;
int i_chroma_lambda2_offset;
/* B_direct and weighted prediction */
int16_t dist_scale_factor_buf[2][2][X264_REF_MAX*2][4];
int16_t (*dist_scale_factor)[4];
int8_t bipred_weight_buf[2][2][X264_REF_MAX*2][4];
int8_t (*bipred_weight)[4];
/* maps fref1[0]'s ref indices into the current list0 */
#define map_col_to_list0(col) h->mb.map_col_to_list0[(col)+2]
int8_t map_col_to_list0[X264_REF_MAX+2];
int ref_blind_dupe; /* The index of the blind reference frame duplicate. */
int8_t deblock_ref_table[X264_REF_MAX*2+2];
#define deblock_ref_table(x) h->mb.deblock_ref_table[(x)+2]
} mb;
/* rate control encoding only */
x264_ratecontrol_t *rc;
/* stats */
struct
{
/* Current frame stats */
x264_frame_stat_t frame;
/* Cumulated stats */
/* per slice info */
int i_frame_count[3];
int64_t i_frame_size[3];
double f_frame_qp[3];
int i_consecutive_bframes[X264_BFRAME_MAX+1];
/* */
double f_ssd_global[3];
double f_psnr_average[3];
double f_psnr_mean_y[3];
double f_psnr_mean_u[3];
double f_psnr_mean_v[3];
double f_ssim_mean_y[3];
double f_frame_duration[3];
/* */
int64_t i_mb_count[3][19];
int64_t i_mb_partition[2][17];
int64_t i_mb_count_8x8dct[2];
int64_t i_mb_count_ref[2][2][X264_REF_MAX*2];
int64_t i_mb_cbp[6];
int64_t i_mb_pred_mode[4][13];
int64_t i_mb_field[3];
/* */
int i_direct_score[2];
int i_direct_frames[2];
/* num p-frames weighted */
int i_wpred[2];
} stat;
/* 0 = luma 4x4, 1 = luma 8x8, 2 = chroma 4x4, 3 = chroma 8x8 */
udctcoef (*nr_offset)[64];
uint32_t (*nr_residual_sum)[64];
uint32_t *nr_count;
ALIGNED_16( udctcoef nr_offset_denoise[4][64] );
ALIGNED_16( uint32_t nr_residual_sum_buf[2][4][64] );
uint32_t nr_count_buf[2][4];
uint8_t luma2chroma_pixel[7]; /* Subsampled pixel size */
/* Buffers that are allocated per-thread even in sliced threads. */
void *scratch_buffer; /* for any temporary storage that doesn't want repeated malloc */
void *scratch_buffer2; /* if the first one's already in use */
pixel *intra_border_backup[5][3]; /* bottom pixels of the previous mb row, used for intra prediction after the framebuffer has been deblocked */
/* Deblock strength values are stored for each 4x4 partition. In MBAFF
* there are four extra values that need to be stored, located in [4][i]. */
uint8_t (*deblock_strength[2])[2][8][4];
/* CPU functions dependents */
x264_predict_t predict_16x16[4+3];
x264_predict8x8_t predict_8x8[9+3];
x264_predict_t predict_4x4[9+3];
x264_predict_t predict_chroma[4+3];
x264_predict_t predict_8x8c[4+3];
x264_predict_t predict_8x16c[4+3];
x264_predict_8x8_filter_t predict_8x8_filter;
x264_pixel_function_t pixf;
x264_mc_functions_t mc;
x264_dct_function_t dctf;
x264_zigzag_function_t zigzagf;
x264_zigzag_function_t zigzagf_interlaced;
x264_zigzag_function_t zigzagf_progressive;
x264_quant_function_t quantf;
x264_deblock_function_t loopf;
x264_bitstream_function_t bsf;
#if HAVE_VISUALIZE
struct visualize_t *visualize;
#endif
x264_lookahead_t *lookahead;
};
typedef struct
{
int i_id;
int i_profile_idc;
int i_level_idc;
int b_constraint_set0;
int b_constraint_set1;
int b_constraint_set2;
int b_constraint_set3;
int i_log2_max_frame_num;
int i_poc_type;
/* poc 0 */
int i_log2_max_poc_lsb;
int i_num_ref_frames;
int b_gaps_in_frame_num_value_allowed;
int i_mb_width;
int i_mb_height;
int b_frame_mbs_only;
int b_mb_adaptive_frame_field;
int b_direct8x8_inference;
int b_crop;
struct
{
int i_left;
int i_right;
int i_top;
int i_bottom;
} crop;
int b_vui;
struct
{
int b_aspect_ratio_info_present;
int i_sar_width;
int i_sar_height;
int b_overscan_info_present;
int b_overscan_info;
int b_signal_type_present;
int i_vidformat;
int b_fullrange;
int b_color_description_present;
int i_colorprim;
int i_transfer;
int i_colmatrix;
int b_chroma_loc_info_present;
int i_chroma_loc_top;
int i_chroma_loc_bottom;
int b_timing_info_present;
uint32_t i_num_units_in_tick;
uint32_t i_time_scale;
int b_fixed_frame_rate;
int b_nal_hrd_parameters_present;
int b_vcl_hrd_parameters_present;
struct
{
int i_cpb_cnt;
int i_bit_rate_scale;
int i_cpb_size_scale;
int i_bit_rate_value;
int i_cpb_size_value;
int i_bit_rate_unscaled;
int i_cpb_size_unscaled;
int b_cbr_hrd;
int i_initial_cpb_removal_delay_length;
int i_cpb_removal_delay_length;
int i_dpb_output_delay_length;
int i_time_offset_length;
} hrd;
int b_pic_struct_present;
int b_bitstream_restriction;
int b_motion_vectors_over_pic_boundaries;
int i_max_bytes_per_pic_denom;
int i_max_bits_per_mb_denom;
int i_log2_max_mv_length_horizontal;
int i_log2_max_mv_length_vertical;
int i_num_reorder_frames;
int i_max_dec_frame_buffering;
/* FIXME to complete */
} vui;
int b_qpprime_y_zero_transform_bypass;
int i_chroma_format_idc;
} x264_sps_t;
typedef struct
{
int i_id;
int i_sps_id;
int b_cabac;
int b_pic_order;
int i_num_slice_groups;
int i_num_ref_idx_l0_default_active;
int i_num_ref_idx_l1_default_active;
int b_weighted_pred;
int b_weighted_bipred;
int i_pic_init_qp;
int i_pic_init_qs;
int i_chroma_qp_index_offset;
int b_deblocking_filter_control;
int b_constrained_intra_pred;
int b_redundant_pic_cnt;
int b_transform_8x8_mode;
int i_cqm_preset;
const uint8_t *scaling_list[8]; /* could be 12, but we don't allow separate Cb/Cr lists */
} x264_pps_t;
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