forked from mirror/libbpg
1488 lines
68 KiB
C
1488 lines
68 KiB
C
/*****************************************************************************
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* Copyright (C) 2013 x265 project
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*
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* Authors: Steve Borho <steve@borho.org>
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02111, USA.
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*
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* This program is also available under a commercial proprietary license.
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* For more information, contact us at license @ x265.com.
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*****************************************************************************/
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#ifndef X265_H
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#define X265_H
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#include <stdint.h>
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#include "x265_config.h"
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#ifdef __cplusplus
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extern "C" {
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#endif
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/* x265_encoder:
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* opaque handler for encoder */
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typedef struct x265_encoder x265_encoder;
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/* Application developers planning to link against a shared library version of
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* libx265 from a Microsoft Visual Studio or similar development environment
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* will need to define X265_API_IMPORTS before including this header.
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* This clause does not apply to MinGW, similar development environments, or non
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* Windows platforms. */
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#ifdef X265_API_IMPORTS
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#define X265_API __declspec(dllimport)
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#else
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#define X265_API
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#endif
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typedef enum
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{
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NAL_UNIT_CODED_SLICE_TRAIL_N = 0,
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NAL_UNIT_CODED_SLICE_TRAIL_R,
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NAL_UNIT_CODED_SLICE_TSA_N,
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NAL_UNIT_CODED_SLICE_TLA_R,
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NAL_UNIT_CODED_SLICE_STSA_N,
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NAL_UNIT_CODED_SLICE_STSA_R,
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NAL_UNIT_CODED_SLICE_RADL_N,
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NAL_UNIT_CODED_SLICE_RADL_R,
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NAL_UNIT_CODED_SLICE_RASL_N,
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NAL_UNIT_CODED_SLICE_RASL_R,
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NAL_UNIT_CODED_SLICE_BLA_W_LP = 16,
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NAL_UNIT_CODED_SLICE_BLA_W_RADL,
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NAL_UNIT_CODED_SLICE_BLA_N_LP,
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NAL_UNIT_CODED_SLICE_IDR_W_RADL,
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NAL_UNIT_CODED_SLICE_IDR_N_LP,
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NAL_UNIT_CODED_SLICE_CRA,
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NAL_UNIT_VPS = 32,
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NAL_UNIT_SPS,
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NAL_UNIT_PPS,
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NAL_UNIT_ACCESS_UNIT_DELIMITER,
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NAL_UNIT_EOS,
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NAL_UNIT_EOB,
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NAL_UNIT_FILLER_DATA,
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NAL_UNIT_PREFIX_SEI,
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NAL_UNIT_SUFFIX_SEI,
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NAL_UNIT_INVALID = 64,
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} NalUnitType;
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/* The data within the payload is already NAL-encapsulated; the type is merely
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* in the struct for easy access by the calling application. All data returned
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* in an x265_nal, including the data in payload, is no longer valid after the
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* next call to x265_encoder_encode. Thus it must be used or copied before
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* calling x265_encoder_encode again. */
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typedef struct x265_nal
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{
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uint32_t type; /* NalUnitType */
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uint32_t sizeBytes; /* size in bytes */
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uint8_t* payload;
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} x265_nal;
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/* Stores all analysis data for a single frame */
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typedef struct x265_analysis_data
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{
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void* interData;
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void* intraData;
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uint32_t frameRecordSize;
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uint32_t poc;
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uint32_t sliceType;
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uint32_t numCUsInFrame;
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uint32_t numPartitions;
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} x265_analysis_data;
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/* cu statistics */
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typedef struct x265_cu_stats
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{
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double percentSkipCu[4]; // Percentage of skip cu in all depths
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double percentMergeCu[4]; // Percentage of merge cu in all depths
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double percentIntraDistribution[4][3]; // Percentage of DC, Planar, Angular intra modes in all depths
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double percentInterDistribution[4][3]; // Percentage of 2Nx2N inter, rect and amp in all depths
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double percentIntraNxN; // Percentage of 4x4 cu
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/* All the above values will add up to 100%. */
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} x265_cu_stats;
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/* Frame level statistics */
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typedef struct x265_frame_stats
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{
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double qp;
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double rateFactor;
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double psnrY;
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double psnrU;
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double psnrV;
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double psnr;
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double ssim;
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double decideWaitTime;
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double row0WaitTime;
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double wallTime;
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double refWaitWallTime;
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double totalCTUTime;
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double stallTime;
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double avgWPP;
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double avgLumaDistortion;
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double avgChromaDistortion;
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double avgPsyEnergy;
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double avgResEnergy;
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double avgLumaLevel;
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uint64_t bits;
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int encoderOrder;
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int poc;
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int countRowBlocks;
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int list0POC[16];
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int list1POC[16];
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uint16_t maxLumaLevel;
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char sliceType;
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int bScenecut;
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x265_cu_stats cuStats;
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} x265_frame_stats;
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/* Used to pass pictures into the encoder, and to get picture data back out of
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* the encoder. The input and output semantics are different */
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typedef struct x265_picture
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{
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/* presentation time stamp: user-specified, returned on output */
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int64_t pts;
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/* display time stamp: ignored on input, copied from reordered pts. Returned
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* on output */
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int64_t dts;
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/* force quantizer for != X265_QP_AUTO */
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/* The value provided on input is returned with the same picture (POC) on
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* output */
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void* userData;
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/* Must be specified on input pictures, the number of planes is determined
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* by the colorSpace value */
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void* planes[3];
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/* Stride is the number of bytes between row starts */
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int stride[3];
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/* Must be specified on input pictures. x265_picture_init() will set it to
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* the encoder's internal bit depth, but this field must describe the depth
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* of the input pictures. Must be between 8 and 16. Values larger than 8
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* imply 16bits per input sample. If input bit depth is larger than the
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* internal bit depth, the encoder will down-shift pixels. Input samples
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* larger than 8bits will be masked to internal bit depth. On output the
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* bitDepth will be the internal encoder bit depth */
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int bitDepth;
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/* Must be specified on input pictures: X265_TYPE_AUTO or other.
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* x265_picture_init() sets this to auto, returned on output */
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int sliceType;
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/* Ignored on input, set to picture count, returned on output */
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int poc;
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/* Must be specified on input pictures: X265_CSP_I420 or other. It must
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* match the internal color space of the encoder. x265_picture_init() will
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* initialize this value to the internal color space */
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int colorSpace;
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/* Force the slice base QP for this picture within the encoder. Set to 0
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* to allow the encoder to determine base QP */
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int forceqp;
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/* If param.analysisMode is X265_ANALYSIS_OFF this field is ignored on input
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* and output. Else the user must call x265_alloc_analysis_data() to
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* allocate analysis buffers for every picture passed to the encoder.
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*
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* On input when param.analysisMode is X265_ANALYSIS_LOAD and analysisData
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* member pointers are valid, the encoder will use the data stored here to
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* reduce encoder work.
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*
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* On output when param.analysisMode is X265_ANALYSIS_SAVE and analysisData
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* member pointers are valid, the encoder will write output analysis into
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* this data structure */
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x265_analysis_data analysisData;
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/* An array of quantizer offsets to be applied to this image during encoding.
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* These are added on top of the decisions made by rateControl.
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* Adaptive quantization must be enabled to use this feature. These quantizer
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* offsets should be given for each 16x16 block. Behavior if quant
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* offsets differ between encoding passes is undefined. */
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float *quantOffsets;
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/* Frame level statistics */
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x265_frame_stats frameData;
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} x265_picture;
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typedef enum
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{
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X265_DIA_SEARCH,
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X265_HEX_SEARCH,
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X265_UMH_SEARCH,
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X265_STAR_SEARCH,
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X265_FULL_SEARCH
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} X265_ME_METHODS;
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/* CPU flags */
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/* x86 */
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#define X265_CPU_CMOV 0x0000001
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#define X265_CPU_MMX 0x0000002
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#define X265_CPU_MMX2 0x0000004 /* MMX2 aka MMXEXT aka ISSE */
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#define X265_CPU_MMXEXT X265_CPU_MMX2
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#define X265_CPU_SSE 0x0000008
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#define X265_CPU_SSE2 0x0000010
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#define X265_CPU_SSE3 0x0000020
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#define X265_CPU_SSSE3 0x0000040
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#define X265_CPU_SSE4 0x0000080 /* SSE4.1 */
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#define X265_CPU_SSE42 0x0000100 /* SSE4.2 */
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#define X265_CPU_LZCNT 0x0000200 /* Phenom support for "leading zero count" instruction. */
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#define X265_CPU_AVX 0x0000400 /* AVX support: requires OS support even if YMM registers aren't used. */
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#define X265_CPU_XOP 0x0000800 /* AMD XOP */
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#define X265_CPU_FMA4 0x0001000 /* AMD FMA4 */
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#define X265_CPU_AVX2 0x0002000 /* AVX2 */
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#define X265_CPU_FMA3 0x0004000 /* Intel FMA3 */
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#define X265_CPU_BMI1 0x0008000 /* BMI1 */
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#define X265_CPU_BMI2 0x0010000 /* BMI2 */
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/* x86 modifiers */
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#define X265_CPU_CACHELINE_32 0x0020000 /* avoid memory loads that span the border between two cachelines */
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#define X265_CPU_CACHELINE_64 0x0040000 /* 32/64 is the size of a cacheline in bytes */
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#define X265_CPU_SSE2_IS_SLOW 0x0080000 /* avoid most SSE2 functions on Athlon64 */
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#define X265_CPU_SSE2_IS_FAST 0x0100000 /* a few functions are only faster on Core2 and Phenom */
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#define X265_CPU_SLOW_SHUFFLE 0x0200000 /* The Conroe has a slow shuffle unit (relative to overall SSE performance) */
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#define X265_CPU_STACK_MOD4 0x0400000 /* if stack is only mod4 and not mod16 */
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#define X265_CPU_SLOW_CTZ 0x0800000 /* BSR/BSF x86 instructions are really slow on some CPUs */
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#define X265_CPU_SLOW_ATOM 0x1000000 /* The Atom is terrible: slow SSE unaligned loads, slow
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* SIMD multiplies, slow SIMD variable shifts, slow pshufb,
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* cacheline split penalties -- gather everything here that
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* isn't shared by other CPUs to avoid making half a dozen
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* new SLOW flags. */
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#define X265_CPU_SLOW_PSHUFB 0x2000000 /* such as on the Intel Atom */
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#define X265_CPU_SLOW_PALIGNR 0x4000000 /* such as on the AMD Bobcat */
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/* ARM */
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#define X265_CPU_ARMV6 0x0000001
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#define X265_CPU_NEON 0x0000002 /* ARM NEON */
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#define X265_CPU_FAST_NEON_MRC 0x0000004 /* Transfer from NEON to ARM register is fast (Cortex-A9) */
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#define X265_MAX_SUBPEL_LEVEL 7
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/* Log level */
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#define X265_LOG_NONE (-1)
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#define X265_LOG_ERROR 0
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#define X265_LOG_WARNING 1
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#define X265_LOG_INFO 2
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#define X265_LOG_DEBUG 3
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#define X265_LOG_FULL 4
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#define X265_B_ADAPT_NONE 0
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#define X265_B_ADAPT_FAST 1
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#define X265_B_ADAPT_TRELLIS 2
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#define X265_REF_LIMIT_DEPTH 1
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#define X265_REF_LIMIT_CU 2
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#define X265_BFRAME_MAX 16
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#define X265_MAX_FRAME_THREADS 16
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#define X265_TYPE_AUTO 0x0000 /* Let x265 choose the right type */
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#define X265_TYPE_IDR 0x0001
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#define X265_TYPE_I 0x0002
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#define X265_TYPE_P 0x0003
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#define X265_TYPE_BREF 0x0004 /* Non-disposable B-frame */
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#define X265_TYPE_B 0x0005
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#define IS_X265_TYPE_I(x) ((x) == X265_TYPE_I || (x) == X265_TYPE_IDR)
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#define IS_X265_TYPE_B(x) ((x) == X265_TYPE_B || (x) == X265_TYPE_BREF)
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#define X265_QP_AUTO 0
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#define X265_AQ_NONE 0
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#define X265_AQ_VARIANCE 1
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#define X265_AQ_AUTO_VARIANCE 2
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#define X265_AQ_AUTO_VARIANCE_BIASED 3
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/* NOTE! For this release only X265_CSP_I420 and X265_CSP_I444 are supported */
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/* Supported internal color space types (according to semantics of chroma_format_idc) */
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#define X265_CSP_I400 0 /* yuv 4:0:0 planar */
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#define X265_CSP_I420 1 /* yuv 4:2:0 planar */
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#define X265_CSP_I422 2 /* yuv 4:2:2 planar */
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#define X265_CSP_I444 3 /* yuv 4:4:4 planar */
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#define X265_CSP_COUNT 4 /* Number of supported internal color spaces */
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/* These color spaces will eventually be supported as input pictures. The pictures will
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* be converted to the appropriate planar color spaces at ingest */
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#define X265_CSP_NV12 4 /* yuv 4:2:0, with one y plane and one packed u+v */
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#define X265_CSP_NV16 5 /* yuv 4:2:2, with one y plane and one packed u+v */
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/* Interleaved color-spaces may eventually be supported as input pictures */
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#define X265_CSP_BGR 6 /* packed bgr 24bits */
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#define X265_CSP_BGRA 7 /* packed bgr 32bits */
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#define X265_CSP_RGB 8 /* packed rgb 24bits */
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#define X265_CSP_MAX 9 /* end of list */
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#define X265_EXTENDED_SAR 255 /* aspect ratio explicitly specified as width:height */
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/* Analysis options */
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#define X265_ANALYSIS_OFF 0
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#define X265_ANALYSIS_SAVE 1
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#define X265_ANALYSIS_LOAD 2
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typedef struct x265_cli_csp
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{
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int planes;
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int width[3];
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int height[3];
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} x265_cli_csp;
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static const x265_cli_csp x265_cli_csps[] =
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{
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{ 1, { 0, 0, 0 }, { 0, 0, 0 } }, /* i400 */
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{ 3, { 0, 1, 1 }, { 0, 1, 1 } }, /* i420 */
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{ 3, { 0, 1, 1 }, { 0, 0, 0 } }, /* i422 */
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{ 3, { 0, 0, 0 }, { 0, 0, 0 } }, /* i444 */
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{ 2, { 0, 0 }, { 0, 1 } }, /* nv12 */
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{ 2, { 0, 0 }, { 0, 0 } }, /* nv16 */
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};
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/* rate tolerance method */
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typedef enum
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{
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X265_RC_ABR,
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X265_RC_CQP,
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X265_RC_CRF
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} X265_RC_METHODS;
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/* slice type statistics */
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typedef struct x265_sliceType_stats
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{
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double avgQp;
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double bitrate;
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double psnrY;
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double psnrU;
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double psnrV;
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double ssim;
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uint32_t numPics;
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} x265_sliceType_stats;
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||
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||
/* Output statistics from encoder */
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||
typedef struct x265_stats
|
||
{
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||
double globalPsnrY;
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||
double globalPsnrU;
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||
double globalPsnrV;
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||
double globalPsnr;
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||
double globalSsim;
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||
double elapsedEncodeTime; /* wall time since encoder was opened */
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||
double elapsedVideoTime; /* encoded picture count / frame rate */
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||
double bitrate; /* accBits / elapsed video time */
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uint64_t accBits; /* total bits output thus far */
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uint32_t encodedPictureCount; /* number of output pictures thus far */
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||
uint32_t totalWPFrames; /* number of uni-directional weighted frames used */
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x265_sliceType_stats statsI; /* statistics of I slice */
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||
x265_sliceType_stats statsP; /* statistics of P slice */
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||
x265_sliceType_stats statsB; /* statistics of B slice */
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||
uint16_t maxCLL; /* maximum content light level */
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||
uint16_t maxFALL; /* maximum frame average light level */
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||
} x265_stats;
|
||
|
||
/* String values accepted by x265_param_parse() (and CLI) for various parameters */
|
||
static const char * const x265_motion_est_names[] = { "dia", "hex", "umh", "star", "full", 0 };
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||
static const char * const x265_source_csp_names[] = { "i400", "i420", "i422", "i444", "nv12", "nv16", 0 };
|
||
static const char * const x265_video_format_names[] = { "component", "pal", "ntsc", "secam", "mac", "undef", 0 };
|
||
static const char * const x265_fullrange_names[] = { "limited", "full", 0 };
|
||
static const char * const x265_colorprim_names[] = { "", "bt709", "undef", "", "bt470m", "bt470bg", "smpte170m", "smpte240m", "film", "bt2020", 0 };
|
||
static const char * const x265_transfer_names[] = { "", "bt709", "undef", "", "bt470m", "bt470bg", "smpte170m", "smpte240m", "linear", "log100",
|
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"log316", "iec61966-2-4", "bt1361e", "iec61966-2-1", "bt2020-10", "bt2020-12",
|
||
"smpte-st-2084", "smpte-st-428", "arib-std-b67", 0 };
|
||
static const char * const x265_colmatrix_names[] = { "GBR", "bt709", "undef", "", "fcc", "bt470bg", "smpte170m", "smpte240m",
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"YCgCo", "bt2020nc", "bt2020c", 0 };
|
||
static const char * const x265_sar_names[] = { "undef", "1:1", "12:11", "10:11", "16:11", "40:33", "24:11", "20:11",
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"32:11", "80:33", "18:11", "15:11", "64:33", "160:99", "4:3", "3:2", "2:1", 0 };
|
||
static const char * const x265_interlace_names[] = { "prog", "tff", "bff", 0 };
|
||
static const char * const x265_analysis_names[] = { "off", "save", "load", 0 };
|
||
|
||
/* Zones: override ratecontrol for specific sections of the video.
|
||
* If zones overlap, whichever comes later in the list takes precedence. */
|
||
typedef struct x265_zone
|
||
{
|
||
int startFrame, endFrame; /* range of frame numbers */
|
||
int bForceQp; /* whether to use qp vs bitrate factor */
|
||
int qp;
|
||
float bitrateFactor;
|
||
} x265_zone;
|
||
|
||
/* x265 input parameters
|
||
*
|
||
* For version safety you may use x265_param_alloc/free() to manage the
|
||
* allocation of x265_param instances, and x265_param_parse() to assign values
|
||
* by name. By never dereferencing param fields in your own code you can treat
|
||
* x265_param as an opaque data structure */
|
||
typedef struct x265_param
|
||
{
|
||
/* x265_param_default() will auto-detect this cpu capability bitmap. it is
|
||
* recommended to not change this value unless you know the cpu detection is
|
||
* somehow flawed on your target hardware. The asm function tables are
|
||
* process global, the first encoder configures them for all encoders */
|
||
int cpuid;
|
||
|
||
/*== Parallelism Features ==*/
|
||
|
||
/* Number of concurrently encoded frames between 1 and X265_MAX_FRAME_THREADS
|
||
* or 0 for auto-detection. By default x265 will use a number of frame
|
||
* threads empirically determined to be optimal for your CPU core count,
|
||
* between 2 and 6. Using more than one frame thread causes motion search
|
||
* in the down direction to be clamped but otherwise encode behavior is
|
||
* unaffected. With CQP rate control the output bitstream is deterministic
|
||
* for all values of frameNumThreads greater than 1. All other forms of
|
||
* rate-control can be negatively impacted by increases to the number of
|
||
* frame threads because the extra concurrency adds uncertainty to the
|
||
* bitrate estimations. Frame parallelism is generally limited by the the
|
||
* is generally limited by the the number of CU rows
|
||
*
|
||
* When thread pools are used, each frame thread is assigned to a single
|
||
* pool and the frame thread itself is given the node affinity of its pool.
|
||
* But when no thread pools are used no node affinity is assigned. */
|
||
int frameNumThreads;
|
||
|
||
/* Comma seperated list of threads per NUMA node. If "none", then no worker
|
||
* pools are created and only frame parallelism is possible. If NULL or ""
|
||
* (default) x265 will use all available threads on each NUMA node.
|
||
*
|
||
* '+' is a special value indicating all cores detected on the node
|
||
* '*' is a special value indicating all cores detected on the node and all
|
||
* remaining nodes.
|
||
* '-' is a special value indicating no cores on the node, same as '0'
|
||
*
|
||
* example strings for a 4-node system:
|
||
* "" - default, unspecified, all numa nodes are used for thread pools
|
||
* "*" - same as default
|
||
* "none" - no thread pools are created, only frame parallelism possible
|
||
* "-" - same as "none"
|
||
* "10" - allocate one pool, using up to 10 cores on node 0
|
||
* "-,+" - allocate one pool, using all cores on node 1
|
||
* "+,-,+" - allocate two pools, using all cores on nodes 0 and 2
|
||
* "+,-,+,-" - allocate two pools, using all cores on nodes 0 and 2
|
||
* "-,*" - allocate three pools, using all cores on nodes 1, 2 and 3
|
||
* "8,8,8,8" - allocate four pools with up to 8 threads in each pool
|
||
*
|
||
* The total number of threads will be determined by the number of threads
|
||
* assigned to all nodes. The worker threads will each be given affinity for
|
||
* their node, they will not be allowed to migrate between nodes, but they
|
||
* will be allowed to move between CPU cores within their node.
|
||
*
|
||
* If the three pool features: bEnableWavefront, bDistributeModeAnalysis and
|
||
* bDistributeMotionEstimation are all disabled, then numaPools is ignored
|
||
* and no thread pools are created.
|
||
*
|
||
* If "none" is specified, then all three of the thread pool features are
|
||
* implicitly disabled.
|
||
*
|
||
* Multiple thread pools will be allocated for any NUMA node with more than
|
||
* 64 logical CPU cores. But any given thread pool will always use at most
|
||
* one NUMA node.
|
||
*
|
||
* Frame encoders are distributed between the available thread pools, and
|
||
* the encoder will never generate more thread pools than frameNumThreads */
|
||
const char* numaPools;
|
||
|
||
/* Enable wavefront parallel processing, greatly increases parallelism for
|
||
* less than 1% compression efficiency loss. Requires a thread pool, enabled
|
||
* by default */
|
||
int bEnableWavefront;
|
||
|
||
/* Use multiple threads to measure CU mode costs. Recommended for many core
|
||
* CPUs. On RD levels less than 5, it may not offload enough work to warrant
|
||
* the overhead. It is useful with the slow preset since it has the
|
||
* rectangular predictions enabled. At RD level 5 and 6 (preset slower and
|
||
* below), this feature should be an unambiguous win if you have CPU
|
||
* cores available for work. Default disabled */
|
||
int bDistributeModeAnalysis;
|
||
|
||
/* Use multiple threads to perform motion estimation to (ME to one reference
|
||
* per thread). Recommended for many core CPUs. The more references the more
|
||
* motion searches there will be to distribute. This option is often not a
|
||
* win, particularly in video sequences with low motion. Default disabled */
|
||
int bDistributeMotionEstimation;
|
||
|
||
/*== Logging Features ==*/
|
||
|
||
/* Enable analysis and logging distribution of CUs. Now deprecated */
|
||
int bLogCuStats;
|
||
|
||
/* Enable the measurement and reporting of PSNR. Default is enabled */
|
||
int bEnablePsnr;
|
||
|
||
/* Enable the measurement and reporting of SSIM. Default is disabled */
|
||
int bEnableSsim;
|
||
|
||
/* The level of logging detail emitted by the encoder. X265_LOG_NONE to
|
||
* X265_LOG_FULL, default is X265_LOG_INFO */
|
||
int logLevel;
|
||
|
||
/* Filename of CSV log. Now deprecated */
|
||
const char* csvfn;
|
||
|
||
/*== Internal Picture Specification ==*/
|
||
|
||
/* Internal encoder bit depth. If x265 was compiled to use 8bit pixels
|
||
* (HIGH_BIT_DEPTH=0), this field must be 8, else this field must be 10.
|
||
* Future builds may support 12bit pixels. */
|
||
int internalBitDepth;
|
||
|
||
/* Color space of internal pictures, must match color space of input
|
||
* pictures */
|
||
int internalCsp;
|
||
|
||
/* Numerator and denominator of frame rate */
|
||
uint32_t fpsNum;
|
||
uint32_t fpsDenom;
|
||
|
||
/* Width (in pixels) of the source pictures. If this width is not an even
|
||
* multiple of 4, the encoder will pad the pictures internally to meet this
|
||
* minimum requirement. All valid HEVC widths are supported */
|
||
int sourceWidth;
|
||
|
||
/* Height (in pixels) of the source pictures. If this height is not an even
|
||
* multiple of 4, the encoder will pad the pictures internally to meet this
|
||
* minimum requirement. All valid HEVC heights are supported */
|
||
int sourceHeight;
|
||
|
||
/* Interlace type of source pictures. 0 - progressive pictures (default).
|
||
* 1 - top field first, 2 - bottom field first. HEVC encodes interlaced
|
||
* content as fields, they must be provided to the encoder in the correct
|
||
* temporal order */
|
||
int interlaceMode;
|
||
|
||
/* Total Number of frames to be encoded, calculated from the user input
|
||
* (--frames) and (--seek). In case, the input is read from a pipe, this can
|
||
* remain as 0. It is later used in 2 pass RateControl, hence storing the
|
||
* value in param */
|
||
int totalFrames;
|
||
|
||
/*== Profile / Tier / Level ==*/
|
||
|
||
/* Note: the profile is specified by x265_param_apply_profile() */
|
||
|
||
/* Minimum decoder requirement level. Defaults to 0, which implies auto-
|
||
* detection by the encoder. If specified, the encoder will attempt to bring
|
||
* the encode specifications within that specified level. If the encoder is
|
||
* unable to reach the level it issues a warning and emits the actual
|
||
* decoder requirement. If the requested requirement level is higher than
|
||
* the actual level, the actual requirement level is signaled. The value is
|
||
* an specified as an integer with the level times 10, for example level
|
||
* "5.1" is specified as 51, and level "5.0" is specified as 50. */
|
||
int levelIdc;
|
||
|
||
/* if levelIdc is specified (non-zero) this flag will differentiate between
|
||
* Main (0) and High (1) tier. Default is Main tier (0) */
|
||
int bHighTier;
|
||
|
||
/* The maximum number of L0 references a P or B slice may use. This
|
||
* influences the size of the decoded picture buffer. The higher this
|
||
* number, the more reference frames there will be available for motion
|
||
* search, improving compression efficiency of most video at a cost of
|
||
* performance. Value must be between 1 and 16, default is 3 */
|
||
int maxNumReferences;
|
||
|
||
/* Allow libx265 to emit HEVC bitstreams which do not meet strict level
|
||
* requirements. Defaults to false */
|
||
int bAllowNonConformance;
|
||
|
||
/*== Bitstream Options ==*/
|
||
|
||
/* Flag indicating whether VPS, SPS and PPS headers should be output with
|
||
* each keyframe. Default false */
|
||
int bRepeatHeaders;
|
||
|
||
/* Flag indicating whether the encoder should generate start codes (Annex B
|
||
* format) or length (file format) before NAL units. Default true, Annex B.
|
||
* Muxers should set this to the correct value */
|
||
int bAnnexB;
|
||
|
||
/* Flag indicating whether the encoder should emit an Access Unit Delimiter
|
||
* NAL at the start of every access unit. Default false */
|
||
int bEnableAccessUnitDelimiters;
|
||
|
||
/* Enables the buffering period SEI and picture timing SEI to signal the HRD
|
||
* parameters. Default is disabled */
|
||
int bEmitHRDSEI;
|
||
|
||
/* Enables the emission of a user data SEI with the stream headers which
|
||
* describes the encoder version, build info, and parameters. This is
|
||
* very helpful for debugging, but may interfere with regression tests.
|
||
* Default enabled */
|
||
int bEmitInfoSEI;
|
||
|
||
/* Enable the generation of SEI messages for each encoded frame containing
|
||
* the hashes of the three reconstructed picture planes. Most decoders will
|
||
* validate those hashes against the reconstructed images it generates and
|
||
* report any mismatches. This is essentially a debugging feature. Hash
|
||
* types are MD5(1), CRC(2), Checksum(3). Default is 0, none */
|
||
int decodedPictureHashSEI;
|
||
|
||
/* Enable Temporal Sub Layers while encoding, signals NAL units of coded
|
||
* slices with their temporalId. Output bitstreams can be extracted either
|
||
* at the base temporal layer (layer 0) with roughly half the frame rate or
|
||
* at a higher temporal layer (layer 1) that decodes all the frames in the
|
||
* sequence. */
|
||
int bEnableTemporalSubLayers;
|
||
|
||
/*== GOP structure and slice type decisions (lookahead) ==*/
|
||
|
||
/* Enable open GOP - meaning I slices are not necessarily IDR and thus frames
|
||
* encoded after an I slice may reference frames encoded prior to the I
|
||
* frame which have remained in the decoded picture buffer. Open GOP
|
||
* generally has better compression efficiency and negligible encoder
|
||
* performance impact, but the use case may preclude it. Default true */
|
||
int bOpenGOP;
|
||
|
||
/* Scene cuts closer together than this are coded as I, not IDR. */
|
||
int keyframeMin;
|
||
|
||
/* Maximum keyframe distance or intra period in number of frames. If 0 or 1,
|
||
* all frames are I frames. A negative value is casted to MAX_INT internally
|
||
* which effectively makes frame 0 the only I frame. Default is 250 */
|
||
int keyframeMax;
|
||
|
||
/* Maximum consecutive B frames that can be emitted by the lookahead. When
|
||
* b-adapt is 0 and keyframMax is greater than bframes, the lookahead emits
|
||
* a fixed pattern of `bframes` B frames between each P. With b-adapt 1 the
|
||
* lookahead ignores the value of bframes for the most part. With b-adapt 2
|
||
* the value of bframes determines the search (POC) distance performed in
|
||
* both directions, quadratically increasing the compute load of the
|
||
* lookahead. The higher the value, the more B frames the lookahead may
|
||
* possibly use consecutively, usually improving compression. Default is 3,
|
||
* maximum is 16 */
|
||
int bframes;
|
||
|
||
/* Sets the operating mode of the lookahead. With b-adapt 0, the GOP
|
||
* structure is fixed based on the values of keyframeMax and bframes.
|
||
* With b-adapt 1 a light lookahead is used to chose B frame placement.
|
||
* With b-adapt 2 (trellis) a viterbi B path selection is performed */
|
||
int bFrameAdaptive;
|
||
|
||
/* When enabled, the encoder will use the B frame in the middle of each
|
||
* mini-GOP larger than 2 B frames as a motion reference for the surrounding
|
||
* B frames. This improves compression efficiency for a small performance
|
||
* penalty. Referenced B frames are treated somewhere between a B and a P
|
||
* frame by rate control. Default is enabled. */
|
||
int bBPyramid;
|
||
|
||
/* A value which is added to the cost estimate of B frames in the lookahead.
|
||
* It may be a positive value (making B frames appear more expensive, which
|
||
* causes the lookahead to chose more P frames) or negative, which makes the
|
||
* lookahead chose more B frames. Default is 0, there are no limits */
|
||
int bFrameBias;
|
||
|
||
/* The number of frames that must be queued in the lookahead before it may
|
||
* make slice decisions. Increasing this value directly increases the encode
|
||
* latency. The longer the queue the more optimally the lookahead may make
|
||
* slice decisions, particularly with b-adapt 2. When cu-tree is enabled,
|
||
* the length of the queue linearly increases the effectiveness of the
|
||
* cu-tree analysis. Default is 40 frames, maximum is 250 */
|
||
int lookaheadDepth;
|
||
|
||
/* Use multiple worker threads to measure the estimated cost of each frame
|
||
* within the lookahead. When bFrameAdaptive is 2, most frame cost estimates
|
||
* will be performed in batch mode, many cost estimates at the same time,
|
||
* and lookaheadSlices is ignored for batched estimates. The effect on
|
||
* performance can be quite small. The higher this parameter, the less
|
||
* accurate the frame costs will be (since context is lost across slice
|
||
* boundaries) which will result in less accurate B-frame and scene-cut
|
||
* decisions. Default is 0 - disabled. 1 is the same as 0. Max 16 */
|
||
int lookaheadSlices;
|
||
|
||
/* An arbitrary threshold which determines how aggressively the lookahead
|
||
* should detect scene cuts. The default (40) is recommended. */
|
||
int scenecutThreshold;
|
||
|
||
/*== Coding Unit (CU) definitions ==*/
|
||
|
||
/* Maximum CU width and height in pixels. The size must be 64, 32, or 16.
|
||
* The higher the size, the more efficiently x265 can encode areas of low
|
||
* complexity, greatly improving compression efficiency at large
|
||
* resolutions. The smaller the size, the more effective wavefront and
|
||
* frame parallelism will become because of the increase in rows. default 64
|
||
* All encoders within the same process must use the same maxCUSize, until
|
||
* all encoders are closed and x265_cleanup() is called to reset the value. */
|
||
uint32_t maxCUSize;
|
||
|
||
/* Minimum CU width and height in pixels. The size must be 64, 32, 16, or
|
||
* 8. Default 8. All encoders within the same process must use the same
|
||
* minCUSize. */
|
||
uint32_t minCUSize;
|
||
|
||
/* Enable rectangular motion prediction partitions (vertical and
|
||
* horizontal), available at all CU depths from 64x64 to 8x8. Default is
|
||
* disabled */
|
||
int bEnableRectInter;
|
||
|
||
/* Enable asymmetrical motion predictions. At CU depths 64, 32, and 16, it
|
||
* is possible to use 25%/75% split partitions in the up, down, right, left
|
||
* directions. For some material this can improve compression efficiency at
|
||
* the cost of extra analysis. bEnableRectInter must be enabled for this
|
||
* feature to be used. Default disabled */
|
||
int bEnableAMP;
|
||
|
||
/*== Residual Quadtree Transform Unit (TU) definitions ==*/
|
||
|
||
/* Maximum TU width and height in pixels. The size must be 32, 16, 8 or 4.
|
||
* The larger the size the more efficiently the residual can be compressed
|
||
* by the DCT transforms, at the expense of more computation */
|
||
uint32_t maxTUSize;
|
||
|
||
/* The additional depth the residual quad-tree is allowed to recurse beyond
|
||
* the coding quad-tree, for inter coded blocks. This must be between 1 and
|
||
* 4. The higher the value the more efficiently the residual can be
|
||
* compressed by the DCT transforms, at the expense of much more compute */
|
||
uint32_t tuQTMaxInterDepth;
|
||
|
||
/* The additional depth the residual quad-tree is allowed to recurse beyond
|
||
* the coding quad-tree, for intra coded blocks. This must be between 1 and
|
||
* 4. The higher the value the more efficiently the residual can be
|
||
* compressed by the DCT transforms, at the expense of much more compute */
|
||
uint32_t tuQTMaxIntraDepth;
|
||
|
||
/* Set the amount of rate-distortion analysis to use within quant. 0 implies
|
||
* no rate-distortion optimization. At level 1 rate-distortion cost is used to
|
||
* find optimal rounding values for each level (and allows psy-rdoq to be
|
||
* enabled). At level 2 rate-distortion cost is used to make decimate decisions
|
||
* on each 4x4 coding group (including the cost of signaling the group within
|
||
* the group bitmap). Psy-rdoq is less effective at preserving energy when
|
||
* RDOQ is at level 2 */
|
||
int rdoqLevel;
|
||
|
||
/* Enable the implicit signaling of the sign bit of the last coefficient of
|
||
* each transform unit. This saves one bit per TU at the expense of figuring
|
||
* out which coefficient can be toggled with the least distortion.
|
||
* Default is enabled */
|
||
int bEnableSignHiding;
|
||
|
||
/* Allow intra coded blocks to be encoded directly as residual without the
|
||
* DCT transform, when this improves efficiency. Checking whether the block
|
||
* will benefit from this option incurs a performance penalty. Default is
|
||
* disabled */
|
||
int bEnableTransformSkip;
|
||
|
||
/* An integer value in range of 0 to 2000, which denotes strength of noise
|
||
* reduction in intra CUs. 0 means disabled */
|
||
int noiseReductionIntra;
|
||
|
||
/* An integer value in range of 0 to 2000, which denotes strength of noise
|
||
* reduction in inter CUs. 0 means disabled */
|
||
int noiseReductionInter;
|
||
|
||
/* Quantization scaling lists. HEVC supports 6 quantization scaling lists to
|
||
* be defined; one each for Y, Cb, Cr for intra prediction and one each for
|
||
* inter prediction.
|
||
*
|
||
* - NULL and "off" will disable quant scaling (default)
|
||
* - "default" will enable the HEVC default scaling lists, which
|
||
* do not need to be signaled since they are specified
|
||
* - all other strings indicate a filename containing custom scaling lists
|
||
* in the HM format. The encode will fail if the file is not parsed
|
||
* correctly. Custom lists must be signaled in the SPS. */
|
||
const char *scalingLists;
|
||
|
||
/*== Intra Coding Tools ==*/
|
||
|
||
/* Enable constrained intra prediction. This causes intra prediction to
|
||
* input samples that were inter predicted. For some use cases this is
|
||
* believed to me more robust to stream errors, but it has a compression
|
||
* penalty on P and (particularly) B slices. Defaults to disabled */
|
||
int bEnableConstrainedIntra;
|
||
|
||
/* Enable strong intra smoothing for 32x32 blocks where the reference
|
||
* samples are flat. It may or may not improve compression efficiency,
|
||
* depending on your source material. Defaults to disabled */
|
||
int bEnableStrongIntraSmoothing;
|
||
|
||
/*== Inter Coding Tools ==*/
|
||
|
||
/* The maximum number of merge candidates that are considered during inter
|
||
* analysis. This number (between 1 and 5) is signaled in the stream
|
||
* headers and determines the number of bits required to signal a merge so
|
||
* it can have significant trade-offs. The smaller this number the higher
|
||
* the performance but the less compression efficiency. Default is 3 */
|
||
uint32_t maxNumMergeCand;
|
||
|
||
/* Limit the motion references used for each search based on the results of
|
||
* previous motion searches already performed for the same CU: If 0 all
|
||
* references are always searched. If X265_REF_LIMIT_CU all motion searches
|
||
* will restrict themselves to the references selected by the 2Nx2N search
|
||
* at the same depth. If X265_REF_LIMIT_DEPTH the 2Nx2N motion search will
|
||
* only use references that were selected by the best motion searches of the
|
||
* 4 split CUs at the next lower CU depth. The two flags may be combined */
|
||
uint32_t limitReferences;
|
||
|
||
/* ME search method (DIA, HEX, UMH, STAR, FULL). The search patterns
|
||
* (methods) are sorted in increasing complexity, with diamond being the
|
||
* simplest and fastest and full being the slowest. DIA, HEX, and UMH were
|
||
* adapted from x264 directly. STAR is an adaption of the HEVC reference
|
||
* encoder's three step search, while full is a naive exhaustive search. The
|
||
* default is the star search, it has a good balance of performance and
|
||
* compression efficiency */
|
||
int searchMethod;
|
||
|
||
/* A value between 0 and X265_MAX_SUBPEL_LEVEL which adjusts the amount of
|
||
* effort performed during sub-pel refine. Default is 5 */
|
||
int subpelRefine;
|
||
|
||
/* The maximum distance from the motion prediction that the full pel motion
|
||
* search is allowed to progress before terminating. This value can have an
|
||
* effect on frame parallelism, as referenced frames must be at least this
|
||
* many rows of reconstructed pixels ahead of the referencee at all times.
|
||
* (When considering reference lag, the motion prediction must be ignored
|
||
* because it cannot be known ahead of time). Default is 60, which is the
|
||
* default max CU size (64) minus the luma HPEL half-filter length (4). If a
|
||
* smaller CU size is used, the search range should be similarly reduced */
|
||
int searchRange;
|
||
|
||
/* Enable availability of temporal motion vector for AMVP, default is enabled */
|
||
int bEnableTemporalMvp;
|
||
|
||
/* Enable weighted prediction in P slices. This enables weighting analysis
|
||
* in the lookahead, which influences slice decisions, and enables weighting
|
||
* analysis in the main encoder which allows P reference samples to have a
|
||
* weight function applied to them prior to using them for motion
|
||
* compensation. In video which has lighting changes, it can give a large
|
||
* improvement in compression efficiency. Default is enabled */
|
||
int bEnableWeightedPred;
|
||
|
||
/* Enable weighted prediction in B slices. Default is disabled */
|
||
int bEnableWeightedBiPred;
|
||
|
||
/*== Loop Filters ==*/
|
||
|
||
/* Enable the deblocking loop filter, which improves visual quality by
|
||
* reducing blocking effects at block edges, particularly at lower bitrates
|
||
* or higher QP. When enabled it adds another CU row of reference lag,
|
||
* reducing frame parallelism effectiveness. Default is enabled */
|
||
int bEnableLoopFilter;
|
||
|
||
/* deblocking filter tC offset [-6, 6] -6 light filter, 6 strong.
|
||
* This is the coded div2 value, actual offset is doubled at use */
|
||
int deblockingFilterTCOffset;
|
||
|
||
/* deblocking filter Beta offset [-6, 6] -6 light filter, 6 strong
|
||
* This is the coded div2 value, actual offset is doubled at use */
|
||
int deblockingFilterBetaOffset;
|
||
|
||
/* Enable the Sample Adaptive Offset loop filter, which reduces distortion
|
||
* effects by adjusting reconstructed sample values based on histogram
|
||
* analysis to better approximate the original samples. When enabled it adds
|
||
* a CU row of reference lag, reducing frame parallelism effectiveness.
|
||
* Default is enabled */
|
||
int bEnableSAO;
|
||
|
||
/* Note: when deblocking and SAO are both enabled, the loop filter CU lag is
|
||
* only one row, as they operate in series on the same row. */
|
||
|
||
/* Select the method in which SAO deals with deblocking boundary pixels. If
|
||
* disabled the right and bottom boundary areas are skipped. If enabled,
|
||
* non-deblocked pixels are used entirely. Default is disabled */
|
||
int bSaoNonDeblocked;
|
||
|
||
/*== Analysis tools ==*/
|
||
|
||
/* A value between X265_NO_RDO_NO_RDOQ and X265_RDO_LEVEL which determines
|
||
* the level of rate distortion optimizations to perform during mode
|
||
* decisions and quantization. The more RDO the better the compression
|
||
* efficiency at a major cost of performance. Default is no RDO (0) */
|
||
int rdLevel;
|
||
|
||
/* Enable early skip decisions to avoid intra and inter analysis in likely
|
||
* skip blocks. Default is disabled */
|
||
int bEnableEarlySkip;
|
||
|
||
/* Use a faster search method to find the best intra mode. Default is 0 */
|
||
int bEnableFastIntra;
|
||
|
||
/* Enable a faster determination of whether skipping the DCT transform will
|
||
* be beneficial. Slight performance gain for some compression loss. Default
|
||
* is enabled */
|
||
int bEnableTSkipFast;
|
||
|
||
/* The CU Lossless flag, when enabled, compares the rate-distortion costs
|
||
* for normal and lossless encoding, and chooses the best mode for each CU.
|
||
* If lossless mode is chosen, the cu-transquant-bypass flag is set for that
|
||
* CU */
|
||
int bCULossless;
|
||
|
||
/* Specify whether to attempt to encode intra modes in B frames. By default
|
||
* enabled, but only applicable for the presets which use rdLevel 5 or 6
|
||
* (veryslow and placebo). All other presets will not try intra in B frames
|
||
* regardless of this setting */
|
||
int bIntraInBFrames;
|
||
|
||
/* Apply an optional penalty to the estimated cost of 32x32 intra blocks in
|
||
* non-intra slices. 0 is disabled, 1 enables a small penalty, and 2 enables
|
||
* a full penalty. This favors inter-coding and its low bitrate over
|
||
* potential increases in distortion, but usually improves performance.
|
||
* Default is 0 */
|
||
int rdPenalty;
|
||
|
||
/* Psycho-visual rate-distortion strength. Only has an effect in presets
|
||
* which use RDO. It makes mode decision favor options which preserve the
|
||
* energy of the source, at the cost of lost compression. The value must
|
||
* be between 0 and 2.0, 1.0 is typical. Default 0.3 */
|
||
double psyRd;
|
||
|
||
/* Strength of psycho-visual optimizations in quantization. Only has an
|
||
* effect in presets which use RDOQ (rd-levels 4 and 5). The value must be
|
||
* between 0 and 50, 1.0 is typical. Default 1.0 */
|
||
double psyRdoq;
|
||
|
||
/* If X265_ANALYSIS_SAVE, write per-frame analysis information into analysis
|
||
* buffers. if X265_ANALYSIS_LOAD, read analysis information into analysis
|
||
* buffer and use this analysis information to reduce the amount of work
|
||
* the encoder must perform. Default X265_ANALYSIS_OFF */
|
||
int analysisMode;
|
||
|
||
/* Filename for analysisMode save/load. Default name is "x265_analysis.dat" */
|
||
const char* analysisFileName;
|
||
|
||
/*== Rate Control ==*/
|
||
|
||
/* The lossless flag enables true lossless coding, bypassing scaling,
|
||
* transform, quantization and in-loop filter processes. This is used for
|
||
* ultra-high bitrates with zero loss of quality. It implies no rate control */
|
||
int bLossless;
|
||
|
||
/* Generally a small signed integer which offsets the QP used to quantize
|
||
* the Cb chroma residual (delta from luma QP specified by rate-control).
|
||
* Default is 0, which is recommended */
|
||
int cbQpOffset;
|
||
|
||
/* Generally a small signed integer which offsets the QP used to quantize
|
||
* the Cr chroma residual (delta from luma QP specified by rate-control).
|
||
* Default is 0, which is recommended */
|
||
int crQpOffset;
|
||
|
||
struct
|
||
{
|
||
/* Explicit mode of rate-control, necessary for API users. It must
|
||
* be one of the X265_RC_METHODS enum values. */
|
||
int rateControlMode;
|
||
|
||
/* Base QP to use for Constant QP rate control. Adaptive QP may alter
|
||
* the QP used for each block. If a QP is specified on the command line
|
||
* CQP rate control is implied. Default: 32 */
|
||
int qp;
|
||
|
||
/* target bitrate for Average BitRate (ABR) rate control. If a non- zero
|
||
* bitrate is specified on the command line, ABR is implied. Default 0 */
|
||
int bitrate;
|
||
|
||
/* qComp sets the quantizer curve compression factor. It weights the frame
|
||
* quantizer based on the complexity of residual (measured by lookahead).
|
||
* Default value is 0.6. Increasing it to 1 will effectively generate CQP */
|
||
double qCompress;
|
||
|
||
/* QP offset between I/P and P/B frames. Default ipfactor: 1.4
|
||
* Default pbFactor: 1.3 */
|
||
double ipFactor;
|
||
double pbFactor;
|
||
|
||
/* Ratefactor constant: targets a certain constant "quality".
|
||
* Acceptable values between 0 and 51. Default value: 28 */
|
||
double rfConstant;
|
||
|
||
/* Max QP difference between frames. Default: 4 */
|
||
int qpStep;
|
||
|
||
/* Enable adaptive quantization. This mode distributes available bits between all
|
||
* CTUs of a frame, assigning more bits to low complexity areas. Turning
|
||
* this ON will usually affect PSNR negatively, however SSIM and visual quality
|
||
* generally improves. Default: X265_AQ_VARIANCE */
|
||
int aqMode;
|
||
|
||
/* Sets the strength of AQ bias towards low detail CTUs. Valid only if
|
||
* AQ is enabled. Default value: 1.0. Acceptable values between 0.0 and 3.0 */
|
||
double aqStrength;
|
||
|
||
/* Sets the maximum rate the VBV buffer should be assumed to refill at
|
||
* Default is zero */
|
||
int vbvMaxBitrate;
|
||
|
||
/* Sets the size of the VBV buffer in kilobits. Default is zero */
|
||
int vbvBufferSize;
|
||
|
||
/* Sets how full the VBV buffer must be before playback starts. If it is less than
|
||
* 1, then the initial fill is vbv-init * vbvBufferSize. Otherwise, it is
|
||
* interpreted as the initial fill in kbits. Default is 0.9 */
|
||
double vbvBufferInit;
|
||
|
||
/* Enable CUTree rate-control. This keeps track of the CUs that propagate temporally
|
||
* across frames and assigns more bits to these CUs. Improves encode efficiency.
|
||
* Default: enabled */
|
||
int cuTree;
|
||
|
||
/* In CRF mode, maximum CRF as caused by VBV. 0 implies no limit */
|
||
double rfConstantMax;
|
||
|
||
/* In CRF mode, minimum CRF as caused by VBV */
|
||
double rfConstantMin;
|
||
|
||
/* Multi-pass encoding */
|
||
/* Enable writing the stats in a multi-pass encode to the stat output file */
|
||
int bStatWrite;
|
||
|
||
/* Enable loading data from the stat input file in a multi pass encode */
|
||
int bStatRead;
|
||
|
||
/* Filename of the 2pass output/input stats file, if unspecified the
|
||
* encoder will default to using x265_2pass.log */
|
||
const char* statFileName;
|
||
|
||
/* temporally blur quants */
|
||
double qblur;
|
||
|
||
/* temporally blur complexity */
|
||
double complexityBlur;
|
||
|
||
/* Enable slow and a more detailed first pass encode in multi pass rate control */
|
||
int bEnableSlowFirstPass;
|
||
|
||
/* rate-control overrides */
|
||
int zoneCount;
|
||
x265_zone* zones;
|
||
|
||
/* specify a text file which contains MAX_MAX_QP + 1 floating point
|
||
* values to be copied into x265_lambda_tab and a second set of
|
||
* MAX_MAX_QP + 1 floating point values for x265_lambda2_tab. All values
|
||
* are separated by comma, space or newline. Text after a hash (#) is
|
||
* ignored. The lambda tables are process-global, so these new lambda
|
||
* values will affect all encoders in the same process */
|
||
const char* lambdaFileName;
|
||
|
||
/* Enable stricter conditions to check bitrate deviations in CBR mode. May compromise
|
||
* quality to maintain bitrate adherence */
|
||
int bStrictCbr;
|
||
|
||
/* Enable adaptive quantization at CU granularity. This parameter specifies
|
||
* the minimum CU size at which QP can be adjusted, i.e. Quantization Group
|
||
* (QG) size. Allowed values are 64, 32, 16 provided it falls within the
|
||
* inclusuve range [maxCUSize, minCUSize]. Experimental, default: maxCUSize*/
|
||
uint32_t qgSize;
|
||
} rc;
|
||
|
||
/*== Video Usability Information ==*/
|
||
struct
|
||
{
|
||
/* Aspect ratio idc to be added to the VUI. The default is 0 indicating
|
||
* the apsect ratio is unspecified. If set to X265_EXTENDED_SAR then
|
||
* sarWidth and sarHeight must also be set */
|
||
int aspectRatioIdc;
|
||
|
||
/* Sample Aspect Ratio width in arbitrary units to be added to the VUI
|
||
* only if aspectRatioIdc is set to X265_EXTENDED_SAR. This is the width
|
||
* of an individual pixel. If this is set then sarHeight must also be set */
|
||
int sarWidth;
|
||
|
||
/* Sample Aspect Ratio height in arbitrary units to be added to the VUI.
|
||
* only if aspectRatioIdc is set to X265_EXTENDED_SAR. This is the width
|
||
* of an individual pixel. If this is set then sarWidth must also be set */
|
||
int sarHeight;
|
||
|
||
/* Enable overscan info present flag in the VUI. If this is set then
|
||
* bEnabledOverscanAppropriateFlag will be added to the VUI. The default
|
||
* is false */
|
||
int bEnableOverscanInfoPresentFlag;
|
||
|
||
/* Enable overscan appropriate flag. The status of this flag is added
|
||
* to the VUI only if bEnableOverscanInfoPresentFlag is set. If this
|
||
* flag is set then cropped decoded pictures may be output for display.
|
||
* The default is false */
|
||
int bEnableOverscanAppropriateFlag;
|
||
|
||
/* Video signal type present flag of the VUI. If this is set then
|
||
* videoFormat, bEnableVideoFullRangeFlag and
|
||
* bEnableColorDescriptionPresentFlag will be added to the VUI. The
|
||
* default is false */
|
||
int bEnableVideoSignalTypePresentFlag;
|
||
|
||
/* Video format of the source video. 0 = component, 1 = PAL, 2 = NTSC,
|
||
* 3 = SECAM, 4 = MAC, 5 = unspecified video format is the default */
|
||
int videoFormat;
|
||
|
||
/* Video full range flag indicates the black level and range of the luma
|
||
* and chroma signals as derived from E′Y, E′PB, and E′PR or E′R, E′G,
|
||
* and E′B real-valued component signals. The default is false */
|
||
int bEnableVideoFullRangeFlag;
|
||
|
||
/* Color description present flag in the VUI. If this is set then
|
||
* color_primaries, transfer_characteristics and matrix_coeffs are to be
|
||
* added to the VUI. The default is false */
|
||
int bEnableColorDescriptionPresentFlag;
|
||
|
||
/* Color primaries holds the chromacity coordinates of the source
|
||
* primaries. The default is 2 */
|
||
int colorPrimaries;
|
||
|
||
/* Transfer characteristics indicates the opto-electronic transfer
|
||
* characteristic of the source picture. The default is 2 */
|
||
int transferCharacteristics;
|
||
|
||
/* Matrix coefficients used to derive the luma and chroma signals from
|
||
* the red, blue and green primaries. The default is 2 */
|
||
int matrixCoeffs;
|
||
|
||
/* Chroma location info present flag adds chroma_sample_loc_type_top_field and
|
||
* chroma_sample_loc_type_bottom_field to the VUI. The default is false */
|
||
int bEnableChromaLocInfoPresentFlag;
|
||
|
||
/* Chroma sample location type top field holds the chroma location in
|
||
* the top field. The default is 0 */
|
||
int chromaSampleLocTypeTopField;
|
||
|
||
/* Chroma sample location type bottom field holds the chroma location in
|
||
* the bottom field. The default is 0 */
|
||
int chromaSampleLocTypeBottomField;
|
||
|
||
/* Default display window flag adds def_disp_win_left_offset,
|
||
* def_disp_win_right_offset, def_disp_win_top_offset and
|
||
* def_disp_win_bottom_offset to the VUI. The default is false */
|
||
int bEnableDefaultDisplayWindowFlag;
|
||
|
||
/* Default display window left offset holds the left offset with the
|
||
* conformance cropping window to further crop the displayed window */
|
||
int defDispWinLeftOffset;
|
||
|
||
/* Default display window right offset holds the right offset with the
|
||
* conformance cropping window to further crop the displayed window */
|
||
int defDispWinRightOffset;
|
||
|
||
/* Default display window top offset holds the top offset with the
|
||
* conformance cropping window to further crop the displayed window */
|
||
int defDispWinTopOffset;
|
||
|
||
/* Default display window bottom offset holds the bottom offset with the
|
||
* conformance cropping window to further crop the displayed window */
|
||
int defDispWinBottomOffset;
|
||
} vui;
|
||
|
||
/* SMPTE ST 2086 mastering display color volume SEI info, specified as a
|
||
* string which is parsed when the stream header SEI are emitted. The string
|
||
* format is "G(%hu,%hu)B(%hu,%hu)R(%hu,%hu)WP(%hu,%hu)L(%u,%u)" where %hu
|
||
* are unsigned 16bit integers and %u are unsigned 32bit integers. The SEI
|
||
* includes X,Y display primaries for RGB channels, white point X,Y and
|
||
* max,min luminance values. */
|
||
const char* masteringDisplayColorVolume;
|
||
|
||
/* Maximum Content light level(MaxCLL), specified as integer that indicates the
|
||
* maximum pixel intensity level in units of 1 candela per square metre of the
|
||
* bitstream. x265 will also calculate MaxCLL programmatically from the input
|
||
* pixel values and set in the Content light level info SEI */
|
||
uint16_t maxCLL;
|
||
|
||
/* Maximum Frame Average Light Level(MaxFALL), specified as integer that indicates
|
||
* the maximum frame average intensity level in units of 1 candela per square
|
||
* metre of the bitstream. x265 will also calculate MaxFALL programmatically
|
||
* from the input pixel values and set in the Content light level info SEI */
|
||
uint16_t maxFALL;
|
||
|
||
/* Minimum luma level of input source picture, specified as a integer which
|
||
* would automatically increase any luma values below the specified --min-luma
|
||
* value to that value. */
|
||
uint16_t minLuma;
|
||
|
||
/* Maximum luma level of input source picture, specified as a integer which
|
||
* would automatically decrease any luma values above the specified --max-luma
|
||
* value to that value. */
|
||
uint16_t maxLuma;
|
||
|
||
} x265_param;
|
||
|
||
/* x265_param_alloc:
|
||
* Allocates an x265_param instance. The returned param structure is not
|
||
* special in any way, but using this method together with x265_param_free()
|
||
* and x265_param_parse() to set values by name allows the application to treat
|
||
* x265_param as an opaque data struct for version safety */
|
||
x265_param *x265_param_alloc(void);
|
||
|
||
/* x265_param_free:
|
||
* Use x265_param_free() to release storage for an x265_param instance
|
||
* allocated by x265_param_alloc() */
|
||
void x265_param_free(x265_param *);
|
||
|
||
/* x265_param_default:
|
||
* Initialize an x265_param structure to default values */
|
||
void x265_param_default(x265_param *param);
|
||
|
||
/* x265_param_parse:
|
||
* set one parameter by name.
|
||
* returns 0 on success, or returns one of the following errors.
|
||
* note: BAD_VALUE occurs only if it can't even parse the value,
|
||
* numerical range is not checked until x265_encoder_open().
|
||
* value=NULL means "true" for boolean options, but is a BAD_VALUE for non-booleans. */
|
||
#define X265_PARAM_BAD_NAME (-1)
|
||
#define X265_PARAM_BAD_VALUE (-2)
|
||
int x265_param_parse(x265_param *p, const char *name, const char *value);
|
||
|
||
static const char * const x265_profile_names[] = {
|
||
/* HEVC v1 */
|
||
"main", "main10", "mainstillpicture", /* alias */ "msp",
|
||
|
||
/* HEVC v2 (Range Extensions) */
|
||
"main-intra", "main10-intra",
|
||
"main444-8", "main444-intra", "main444-stillpicture",
|
||
|
||
"main422-10", "main422-10-intra",
|
||
"main444-10", "main444-10-intra",
|
||
|
||
"main12", "main12-intra",
|
||
"main422-12", "main422-12-intra",
|
||
"main444-12", "main444-12-intra",
|
||
|
||
"main444-16-intra", "main444-16-stillpicture", /* Not Supported! */
|
||
0
|
||
};
|
||
|
||
/* x265_param_apply_profile:
|
||
* Applies the restrictions of the given profile. (one of x265_profile_names)
|
||
* (can be NULL, in which case the function will do nothing)
|
||
* Note: the detected profile can be lower than the one specified to this
|
||
* function. This function will force the encoder parameters to fit within
|
||
* the specified profile, or fail if that is impossible.
|
||
* returns 0 on success, negative on failure (e.g. invalid profile name). */
|
||
int x265_param_apply_profile(x265_param *, const char *profile);
|
||
|
||
/* x265_param_default_preset:
|
||
* The same as x265_param_default, but also use the passed preset and tune
|
||
* to modify the default settings.
|
||
* (either can be NULL, which implies no preset or no tune, respectively)
|
||
*
|
||
* Currently available presets are, ordered from fastest to slowest: */
|
||
static const char * const x265_preset_names[] = { "ultrafast", "superfast", "veryfast", "faster", "fast", "medium", "slow", "slower", "veryslow", "placebo", 0 };
|
||
|
||
/* The presets can also be indexed numerically, as in:
|
||
* x265_param_default_preset( ¶m, "3", ... )
|
||
* with ultrafast mapping to "0" and placebo mapping to "9". This mapping may
|
||
* of course change if new presets are added in between, but will always be
|
||
* ordered from fastest to slowest.
|
||
*
|
||
* Warning: the speed of these presets scales dramatically. Ultrafast is a full
|
||
* 100 times faster than placebo!
|
||
*
|
||
* Currently available tunings are: */
|
||
static const char * const x265_tune_names[] = { "psnr", "ssim", "grain", "zerolatency", "fastdecode", 0 };
|
||
|
||
/* returns 0 on success, negative on failure (e.g. invalid preset/tune name). */
|
||
int x265_param_default_preset(x265_param *, const char *preset, const char *tune);
|
||
|
||
/* x265_picture_alloc:
|
||
* Allocates an x265_picture instance. The returned picture structure is not
|
||
* special in any way, but using this method together with x265_picture_free()
|
||
* and x265_picture_init() allows some version safety. New picture fields will
|
||
* always be added to the end of x265_picture */
|
||
x265_picture *x265_picture_alloc(void);
|
||
|
||
/* x265_picture_free:
|
||
* Use x265_picture_free() to release storage for an x265_picture instance
|
||
* allocated by x265_picture_alloc() */
|
||
void x265_picture_free(x265_picture *);
|
||
|
||
/* x265_picture_init:
|
||
* Initialize an x265_picture structure to default values. It sets the pixel
|
||
* depth and color space to the encoder's internal values and sets the slice
|
||
* type to auto - so the lookahead will determine slice type. */
|
||
void x265_picture_init(x265_param *param, x265_picture *pic);
|
||
|
||
/* x265_max_bit_depth:
|
||
* Specifies the numer of bits per pixel that x265 uses internally to
|
||
* represent a pixel, and the bit depth of the output bitstream.
|
||
* param->internalBitDepth must be set to this value. x265_max_bit_depth
|
||
* will be 8 for default builds, 10 for HIGH_BIT_DEPTH builds. */
|
||
X265_API extern const int x265_max_bit_depth;
|
||
|
||
/* x265_version_str:
|
||
* A static string containing the version of this compiled x265 library */
|
||
X265_API extern const char *x265_version_str;
|
||
|
||
/* x265_build_info:
|
||
* A static string describing the compiler and target architecture */
|
||
X265_API extern const char *x265_build_info_str;
|
||
|
||
/* Force a link error in the case of linking against an incompatible API version.
|
||
* Glue #defines exist to force correct macro expansion; the final output of the macro
|
||
* is x265_encoder_open_##X265_BUILD (for purposes of dlopen). */
|
||
#define x265_encoder_glue1(x, y) x ## y
|
||
#define x265_encoder_glue2(x, y) x265_encoder_glue1(x, y)
|
||
#define x265_encoder_open x265_encoder_glue2(x265_encoder_open_, X265_BUILD)
|
||
|
||
/* x265_encoder_open:
|
||
* create a new encoder handler, all parameters from x265_param are copied */
|
||
x265_encoder* x265_encoder_open(x265_param *);
|
||
|
||
/* x265_encoder_parameters:
|
||
* copies the current internal set of parameters to the pointer provided
|
||
* by the caller. useful when the calling application needs to know
|
||
* how x265_encoder_open has changed the parameters.
|
||
* note that the data accessible through pointers in the returned param struct
|
||
* (e.g. filenames) should not be modified by the calling application. */
|
||
void x265_encoder_parameters(x265_encoder *, x265_param *);
|
||
|
||
/* x265_encoder_headers:
|
||
* return the SPS and PPS that will be used for the whole stream.
|
||
* *pi_nal is the number of NAL units outputted in pp_nal.
|
||
* returns negative on error, total byte size of payload data on success
|
||
* the payloads of all output NALs are guaranteed to be sequential in memory. */
|
||
int x265_encoder_headers(x265_encoder *, x265_nal **pp_nal, uint32_t *pi_nal);
|
||
|
||
/* x265_encoder_encode:
|
||
* encode one picture.
|
||
* *pi_nal is the number of NAL units outputted in pp_nal.
|
||
* returns negative on error, 1 if a picture and access unit were output,
|
||
* or zero if the encoder pipeline is still filling or is empty after flushing.
|
||
* the payloads of all output NALs are guaranteed to be sequential in memory.
|
||
* To flush the encoder and retrieve delayed output pictures, pass pic_in as NULL.
|
||
* Once flushing has begun, all subsequent calls must pass pic_in as NULL. */
|
||
int x265_encoder_encode(x265_encoder *encoder, x265_nal **pp_nal, uint32_t *pi_nal, x265_picture *pic_in, x265_picture *pic_out);
|
||
|
||
/* x265_encoder_reconfig:
|
||
* various parameters from x265_param are copied.
|
||
* this takes effect immediately, on whichever frame is encoded next;
|
||
* returns 0 on success, negative on parameter validation error.
|
||
*
|
||
* not all parameters can be changed; see the actual function for a
|
||
* detailed breakdown. since not all parameters can be changed, moving
|
||
* from preset to preset may not always fully copy all relevant parameters,
|
||
* but should still work usably in practice. however, more so than for
|
||
* other presets, many of the speed shortcuts used in ultrafast cannot be
|
||
* switched out of; using reconfig to switch between ultrafast and other
|
||
* presets is not recommended without a more fine-grained breakdown of
|
||
* parameters to take this into account. */
|
||
int x265_encoder_reconfig(x265_encoder *, x265_param *);
|
||
|
||
/* x265_encoder_get_stats:
|
||
* returns encoder statistics */
|
||
void x265_encoder_get_stats(x265_encoder *encoder, x265_stats *, uint32_t statsSizeBytes);
|
||
|
||
/* x265_encoder_log:
|
||
* This function is deprecated */
|
||
void x265_encoder_log(x265_encoder *encoder, int argc, char **argv);
|
||
|
||
/* x265_encoder_close:
|
||
* close an encoder handler */
|
||
void x265_encoder_close(x265_encoder *);
|
||
|
||
/* x265_cleanup:
|
||
* release library static allocations, reset configured CTU size */
|
||
void x265_cleanup(void);
|
||
|
||
#define X265_MAJOR_VERSION 1
|
||
|
||
/* === Multi-lib API ===
|
||
* By using this method to gain access to the libx265 interfaces, you allow run-
|
||
* time selection between various available libx265 libraries based on the
|
||
* encoder parameters. The most likely use case is to choose between Main and
|
||
* Main10 builds of libx265. */
|
||
|
||
typedef struct x265_api
|
||
{
|
||
int api_major_version; /* X265_MAJOR_VERSION */
|
||
int api_build_number; /* X265_BUILD (soname) */
|
||
int sizeof_param; /* sizeof(x265_param) */
|
||
int sizeof_picture; /* sizeof(x265_picture) */
|
||
int sizeof_analysis_data; /* sizeof(x265_analysis_data) */
|
||
int sizeof_zone; /* sizeof(x265_zone) */
|
||
int sizeof_stats; /* sizeof(x265_stats) */
|
||
|
||
int bit_depth;
|
||
const char* version_str;
|
||
const char* build_info_str;
|
||
|
||
/* libx265 public API functions, documented above with x265_ prefixes */
|
||
x265_param* (*param_alloc)(void);
|
||
void (*param_free)(x265_param*);
|
||
void (*param_default)(x265_param*);
|
||
int (*param_parse)(x265_param*, const char*, const char*);
|
||
int (*param_apply_profile)(x265_param*, const char*);
|
||
int (*param_default_preset)(x265_param*, const char*, const char *);
|
||
x265_picture* (*picture_alloc)(void);
|
||
void (*picture_free)(x265_picture*);
|
||
void (*picture_init)(x265_param*, x265_picture*);
|
||
x265_encoder* (*encoder_open)(x265_param*);
|
||
void (*encoder_parameters)(x265_encoder*, x265_param*);
|
||
int (*encoder_reconfig)(x265_encoder*, x265_param*);
|
||
int (*encoder_headers)(x265_encoder*, x265_nal**, uint32_t*);
|
||
int (*encoder_encode)(x265_encoder*, x265_nal**, uint32_t*, x265_picture*, x265_picture*);
|
||
void (*encoder_get_stats)(x265_encoder*, x265_stats*, uint32_t);
|
||
void (*encoder_log)(x265_encoder*, int, char**);
|
||
void (*encoder_close)(x265_encoder*);
|
||
void (*cleanup)(void);
|
||
|
||
int sizeof_frame_stats; /* sizeof(x265_frame_stats) */
|
||
/* add new pointers to the end, or increment X265_MAJOR_VERSION */
|
||
} x265_api;
|
||
|
||
/* Force a link error in the case of linking against an incompatible API version.
|
||
* Glue #defines exist to force correct macro expansion; the final output of the macro
|
||
* is x265_api_get_##X265_BUILD (for purposes of dlopen). */
|
||
#define x265_api_glue1(x, y) x ## y
|
||
#define x265_api_glue2(x, y) x265_api_glue1(x, y)
|
||
#define x265_api_get x265_api_glue2(x265_api_get_, X265_BUILD)
|
||
|
||
/* x265_api_get:
|
||
* Retrieve the programming interface for a linked x265 library.
|
||
* May return NULL if no library is available that supports the
|
||
* requested bit depth. If bitDepth is 0 the function is guarunteed
|
||
* to return a non-NULL x265_api pointer, from the linked libx265.
|
||
*
|
||
* If the requested bitDepth is not supported by the linked libx265,
|
||
* it will attempt to dynamically bind x265_api_get() from a shared
|
||
* library with an appropriate name:
|
||
* 8bit: libx265_main.so
|
||
* 10bit: libx265_main10.so
|
||
* Obviously the shared library file extension is platform specific */
|
||
const x265_api* x265_api_get(int bitDepth);
|
||
|
||
/* x265_api_query:
|
||
* Retrieve the programming interface for a linked x265 library, like
|
||
* x265_api_get(), except this function accepts X265_BUILD as the second
|
||
* argument rather than using the build number as part of the function name.
|
||
* Applications which dynamically link to libx265 can use this interface to
|
||
* query the library API and achieve a relative amount of version skew
|
||
* flexibility. The function may return NULL if the library determines that
|
||
* the apiVersion that your application was compiled against is not compatible
|
||
* with the library you have linked with.
|
||
*
|
||
* api_major_version will be incremented any time non-backward compatible
|
||
* changes are made to any public structures or functions. If
|
||
* api_major_version does not match X265_MAJOR_VERSION from the x265.h your
|
||
* application compiled against, your application must not use the returned
|
||
* x265_api pointer.
|
||
*
|
||
* Users of this API *must* also validate the sizes of any structures which
|
||
* are not treated as opaque in application code. For instance, if your
|
||
* application dereferences a x265_param pointer, then it must check that
|
||
* api->sizeof_param matches the sizeof(x265_param) that your application
|
||
* compiled with. */
|
||
const x265_api* x265_api_query(int bitDepth, int apiVersion, int* err);
|
||
|
||
#define X265_API_QUERY_ERR_NONE 0 /* returned API pointer is non-NULL */
|
||
#define X265_API_QUERY_ERR_VER_REFUSED 1 /* incompatible version skew */
|
||
#define X265_API_QUERY_ERR_LIB_NOT_FOUND 2 /* libx265_main10 not found, for ex */
|
||
#define X265_API_QUERY_ERR_FUNC_NOT_FOUND 3 /* unable to bind x265_api_query */
|
||
#define X265_API_QUERY_ERR_WRONG_BITDEPTH 4 /* libx265_main10 not 10bit, for ex */
|
||
|
||
static const char * const x265_api_query_errnames[] = {
|
||
"api queried from libx265",
|
||
"libx265 version is not compatible with this application",
|
||
"unable to bind a libx265 with requested bit depth",
|
||
"unable to bind x265_api_query from libx265",
|
||
"libx265 has an invalid bitdepth"
|
||
};
|
||
|
||
#ifdef __cplusplus
|
||
}
|
||
#endif
|
||
|
||
#endif // X265_H
|