libbpg/x265/source/encoder/ratecontrol.h
2015-10-27 11:46:00 +01:00

267 lines
9.5 KiB
C++

/*****************************************************************************
* Copyright (C) 2013 x265 project
*
* Authors: Sumalatha Polureddy <sumalatha@multicorewareinc.com>
* Aarthi Priya Thirumalai <aarthi@multicorewareinc.com>
* Xun Xu, PPLive Corporation <xunxu@pptv.com>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02111, USA.
*
* This program is also available under a commercial proprietary license.
* For more information, contact us at license @ x265.com.
*****************************************************************************/
#ifndef X265_RATECONTROL_H
#define X265_RATECONTROL_H
#include "common.h"
#include "sei.h"
namespace X265_NS {
// encoder namespace
class Encoder;
class Frame;
class SEIBufferingPeriod;
struct SPS;
#define BASE_FRAME_DURATION 0.04
/* Arbitrary limitations as a sanity check. */
#define MAX_FRAME_DURATION 1.00
#define MIN_FRAME_DURATION 0.01
#define MIN_AMORTIZE_FRAME 10
#define MIN_AMORTIZE_FRACTION 0.2
#define CLIP_DURATION(f) x265_clip3(MIN_FRAME_DURATION, MAX_FRAME_DURATION, f)
struct Predictor
{
double coeff;
double count;
double decay;
double offset;
};
struct HRDTiming
{
double cpbInitialAT;
double cpbFinalAT;
double dpbOutputTime;
double cpbRemovalTime;
};
struct RateControlEntry
{
Predictor rowPreds[3][2];
Predictor* rowPred[2];
int64_t lastSatd; /* Contains the picture cost of the previous frame, required for resetAbr and VBV */
int64_t leadingNoBSatd;
int64_t rowTotalBits; /* update cplxrsum and totalbits at the end of 2 rows */
double blurredComplexity;
double qpaRc;
double qpAq;
double qRceq;
double frameSizePlanned; /* frame Size decided by RateCotrol before encoding the frame */
double bufferRate;
double movingAvgSum;
double rowCplxrSum;
double qpNoVbv;
double bufferFill;
double frameDuration;
double clippedDuration;
double frameSizeEstimated; /* hold frameSize, updated from cu level vbv rc */
double frameSizeMaximum; /* max frame Size according to minCR restrictions and level of the video */
int sliceType;
int bframes;
int poc;
int encodeOrder;
bool bLastMiniGopBFrame;
bool isActive;
double amortizeFrames;
double amortizeFraction;
/* Required in 2-pass rate control */
uint64_t expectedBits; /* total expected bits up to the current frame (current one excluded) */
double iCuCount;
double pCuCount;
double skipCuCount;
double expectedVbv;
double qScale;
double newQScale;
double newQp;
int mvBits;
int miscBits;
int coeffBits;
bool keptAsRef;
SEIPictureTiming *picTimingSEI;
HRDTiming *hrdTiming;
};
class RateControl
{
public:
x265_param* m_param;
Slice* m_curSlice; /* all info about the current frame */
SliceType m_sliceType; /* Current frame type */
int m_ncu; /* number of CUs in a frame */
int m_qp; /* updated qp for current frame */
bool m_isAbr;
bool m_isVbv;
bool m_isCbr;
bool m_singleFrameVbv;
bool m_isAbrReset;
int m_lastAbrResetPoc;
double m_rateTolerance;
double m_frameDuration; /* current frame duration in seconds */
double m_bitrate;
double m_rateFactorConstant;
double m_bufferSize;
double m_bufferFillFinal; /* real buffer as of the last finished frame */
double m_bufferFill; /* planned buffer, if all in-progress frames hit their bit budget */
double m_bufferRate; /* # of bits added to buffer_fill after each frame */
double m_vbvMaxRate; /* in kbps */
double m_rateFactorMaxIncrement; /* Don't allow RF above (CRF + this value). */
double m_rateFactorMaxDecrement; /* don't allow RF below (this value). */
Predictor m_pred[4]; /* Slice predictors to preidct bits for each Slice type - I,P,Bref and B */
int64_t m_leadingNoBSatd;
int m_predType; /* Type of slice predictors to be used - depends on the slice type */
double m_ipOffset;
double m_pbOffset;
int64_t m_bframeBits;
int64_t m_currentSatd;
int m_qpConstant[3];
int m_lastNonBPictType;
int m_framesDone; /* # of frames passed through RateCotrol already */
double m_cplxrSum; /* sum of bits*qscale/rceq */
double m_wantedBitsWindow; /* target bitrate * window */
double m_accumPQp; /* for determining I-frame quant */
double m_accumPNorm;
double m_lastQScaleFor[3]; /* last qscale for a specific pict type, used for max_diff & ipb factor stuff */
double m_lstep;
double m_shortTermCplxSum;
double m_shortTermCplxCount;
double m_lastRceq;
double m_qCompress;
int64_t m_totalBits; /* total bits used for already encoded frames (after ammortization) */
int64_t m_encodedBits; /* bits used for encoded frames (without ammortization) */
double m_fps;
int64_t m_satdCostWindow[50];
int64_t m_encodedBitsWindow[50];
int m_sliderPos;
/* To detect a pattern of low detailed static frames in single pass ABR using satdcosts */
int64_t m_lastBsliceSatdCost;
int m_numBframesInPattern;
bool m_isPatternPresent;
bool m_isSceneTransition;
/* a common variable on which rateControlStart, rateControlEnd and rateControUpdateStats waits to
* sync the calls to these functions. For example
* -F2:
* rceStart 10
* rceUpdate 10
* rceEnd 9
* rceStart 11
* rceUpdate 11
* rceEnd 10
* rceStart 12
* rceUpdate 12
* rceEnd 11 */
ThreadSafeInteger m_startEndOrder;
int m_finalFrameCount; /* set when encoder begins flushing */
bool m_bTerminated; /* set true when encoder is closing */
/* hrd stuff */
SEIBufferingPeriod m_bufPeriodSEI;
double m_nominalRemovalTime;
double m_prevCpbFinalAT;
/* 2 pass */
bool m_2pass;
int m_numEntries;
FILE* m_statFileOut;
FILE* m_cutreeStatFileOut;
FILE* m_cutreeStatFileIn;
double m_lastAccumPNorm;
double m_expectedBitsSum; /* sum of qscale2bits after rceq, ratefactor, and overflow, only includes finished frames */
int64_t m_predictedBits;
RateControlEntry* m_rce2Pass;
struct
{
uint16_t *qpBuffer[2]; /* Global buffers for converting MB-tree quantizer data. */
int qpBufPos; /* In order to handle pyramid reordering, QP buffer acts as a stack.
* This value is the current position (0 or 1). */
} m_cuTreeStats;
RateControl(x265_param& p);
bool init(const SPS& sps);
void initHRD(SPS& sps);
void setFinalFrameCount(int count);
void terminate(); /* un-block all waiting functions so encoder may close */
void destroy();
// to be called for each curFrame to process RateControl and set QP
int rateControlStart(Frame* curFrame, RateControlEntry* rce, Encoder* enc);
void rateControlUpdateStats(RateControlEntry* rce);
int rateControlEnd(Frame* curFrame, int64_t bits, RateControlEntry* rce);
int rowDiagonalVbvRateControl(Frame* curFrame, uint32_t row, RateControlEntry* rce, double& qpVbv);
int rateControlSliceType(int frameNum);
bool cuTreeReadFor2Pass(Frame* curFrame);
void hrdFullness(SEIBufferingPeriod* sei);
int writeRateControlFrameStats(Frame* curFrame, RateControlEntry* rce);
protected:
static const int s_slidingWindowFrames;
static const char* s_defaultStatFileName;
double m_amortizeFraction;
int m_amortizeFrames;
int m_residualFrames;
int m_partialResidualFrames;
int m_residualCost;
int m_partialResidualCost;
x265_zone* getZone();
double getQScale(RateControlEntry *rce, double rateFactor);
double rateEstimateQscale(Frame* pic, RateControlEntry *rce); // main logic for calculating QP based on ABR
double tuneAbrQScaleFromFeedback(double qScale);
void accumPQpUpdate();
int getPredictorType(int lowresSliceType, int sliceType);
void updateVbv(int64_t bits, RateControlEntry* rce);
void updatePredictor(Predictor *p, double q, double var, double bits);
double clipQscale(Frame* pic, RateControlEntry* rce, double q);
void updateVbvPlan(Encoder* enc);
double predictSize(Predictor *p, double q, double var);
void checkAndResetABR(RateControlEntry* rce, bool isFrameDone);
double predictRowsSizeSum(Frame* pic, RateControlEntry* rce, double qpm, int32_t& encodedBits);
bool initPass2();
double getDiffLimitedQScale(RateControlEntry *rce, double q);
double countExpectedBits();
bool vbv2Pass(uint64_t allAvailableBits);
bool findUnderflow(double *fills, int *t0, int *t1, int over);
bool fixUnderflow(int t0, int t1, double adjustment, double qscaleMin, double qscaleMax);
};
}
#endif // ifndef X265_RATECONTROL_H