source: SHVCSoftware/trunk/source/Lib/TLibCommon/TComPrediction.cpp @ 1164

Last change on this file since 1164 was 906, checked in by seregin, 10 years ago

merge SHM-dev

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1/* The copyright in this software is being made available under the BSD
2 * License, included below. This software may be subject to other third party
3 * and contributor rights, including patent rights, and no such rights are
4 * granted under this license. 
5 *
6 * Copyright (c) 2010-2014, ITU/ISO/IEC
7 * All rights reserved.
8 *
9 * Redistribution and use in source and binary forms, with or without
10 * modification, are permitted provided that the following conditions are met:
11 *
12 *  * Redistributions of source code must retain the above copyright notice,
13 *    this list of conditions and the following disclaimer.
14 *  * Redistributions in binary form must reproduce the above copyright notice,
15 *    this list of conditions and the following disclaimer in the documentation
16 *    and/or other materials provided with the distribution.
17 *  * Neither the name of the ITU/ISO/IEC nor the names of its contributors may
18 *    be used to endorse or promote products derived from this software without
19 *    specific prior written permission.
20 *
21 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
22 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
23 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
24 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS
25 * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
26 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
27 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
28 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
29 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
30 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
31 * THE POSSIBILITY OF SUCH DAMAGE.
32 */
33
34/** \file     TComPrediction.cpp
35    \brief    prediction class
36*/
37
38#include <memory.h>
39#include "TComPrediction.h"
40
41//! \ingroup TLibCommon
42//! \{
43
44// ====================================================================================================================
45// Constructor / destructor / initialize
46// ====================================================================================================================
47
48TComPrediction::TComPrediction()
49: m_pLumaRecBuffer(0)
50, m_iLumaRecStride(0)
51{
52  m_piYuvExt = NULL;
53}
54
55TComPrediction::~TComPrediction()
56{
57 
58  delete[] m_piYuvExt;
59
60  m_acYuvPred[0].destroy();
61  m_acYuvPred[1].destroy();
62
63  m_cYuvPredTemp.destroy();
64
65  if( m_pLumaRecBuffer )
66  {
67    delete [] m_pLumaRecBuffer;
68  }
69 
70  Int i, j;
71  for (i = 0; i < 4; i++)
72  {
73    for (j = 0; j < 4; j++)
74    {
75      m_filteredBlock[i][j].destroy();
76    }
77    m_filteredBlockTmp[i].destroy();
78  }
79}
80
81Void TComPrediction::initTempBuff()
82{
83  if( m_piYuvExt == NULL )
84  {
85    Int extWidth  = MAX_CU_SIZE + 16; 
86    Int extHeight = MAX_CU_SIZE + 1;
87    Int i, j;
88    for (i = 0; i < 4; i++)
89    {
90      m_filteredBlockTmp[i].create(extWidth, extHeight + 7);
91      for (j = 0; j < 4; j++)
92      {
93        m_filteredBlock[i][j].create(extWidth, extHeight);
94      }
95    }
96    m_iYuvExtHeight  = ((MAX_CU_SIZE + 2) << 4);
97    m_iYuvExtStride = ((MAX_CU_SIZE  + 8) << 4);
98    m_piYuvExt = new Int[ m_iYuvExtStride * m_iYuvExtHeight ];
99
100    // new structure
101    m_acYuvPred[0] .create( MAX_CU_SIZE, MAX_CU_SIZE );
102    m_acYuvPred[1] .create( MAX_CU_SIZE, MAX_CU_SIZE );
103
104    m_cYuvPredTemp.create( MAX_CU_SIZE, MAX_CU_SIZE );
105  }
106
107  if (m_iLumaRecStride != (MAX_CU_SIZE>>1) + 1)
108  {
109    m_iLumaRecStride =  (MAX_CU_SIZE>>1) + 1;
110    if (!m_pLumaRecBuffer)
111    {
112      m_pLumaRecBuffer = new Pel[ m_iLumaRecStride * m_iLumaRecStride ];
113    }
114  }
115}
116
117// ====================================================================================================================
118// Public member functions
119// ====================================================================================================================
120
121// Function for calculating DC value of the reference samples used in Intra prediction
122Pel TComPrediction::predIntraGetPredValDC( Int* pSrc, Int iSrcStride, UInt iWidth, UInt iHeight, Bool bAbove, Bool bLeft )
123{
124  assert(iWidth > 0 && iHeight > 0);
125  Int iInd, iSum = 0;
126  Pel pDcVal;
127
128  if (bAbove)
129  {
130    for (iInd = 0;iInd < iWidth;iInd++)
131    {
132      iSum += pSrc[iInd-iSrcStride];
133    }
134  }
135  if (bLeft)
136  {
137    for (iInd = 0;iInd < iHeight;iInd++)
138    {
139      iSum += pSrc[iInd*iSrcStride-1];
140    }
141  }
142
143  if (bAbove && bLeft)
144  {
145    pDcVal = (iSum + iWidth) / (iWidth + iHeight);
146  }
147  else if (bAbove)
148  {
149    pDcVal = (iSum + iWidth/2) / iWidth;
150  }
151  else if (bLeft)
152  {
153    pDcVal = (iSum + iHeight/2) / iHeight;
154  }
155  else
156  {
157    pDcVal = pSrc[-1]; // Default DC value already calculated and placed in the prediction array if no neighbors are available
158  }
159 
160  return pDcVal;
161}
162
163// Function for deriving the angular Intra predictions
164
165/** Function for deriving the simplified angular intra predictions.
166 * \param pSrc pointer to reconstructed sample array
167 * \param srcStride the stride of the reconstructed sample array
168 * \param rpDst reference to pointer for the prediction sample array
169 * \param dstStride the stride of the prediction sample array
170 * \param width the width of the block
171 * \param height the height of the block
172 * \param dirMode the intra prediction mode index
173 * \param blkAboveAvailable boolean indication if the block above is available
174 * \param blkLeftAvailable boolean indication if the block to the left is available
175 *
176 * This function derives the prediction samples for the angular mode based on the prediction direction indicated by
177 * the prediction mode index. The prediction direction is given by the displacement of the bottom row of the block and
178 * the reference row above the block in the case of vertical prediction or displacement of the rightmost column
179 * of the block and reference column left from the block in the case of the horizontal prediction. The displacement
180 * is signalled at 1/32 pixel accuracy. When projection of the predicted pixel falls inbetween reference samples,
181 * the predicted value for the pixel is linearly interpolated from the reference samples. All reference samples are taken
182 * from the extended main reference.
183 */
184Void TComPrediction::xPredIntraAng(Int bitDepth, Int* pSrc, Int srcStride, Pel*& rpDst, Int dstStride, UInt width, UInt height, UInt dirMode, Bool blkAboveAvailable, Bool blkLeftAvailable, Bool bFilter )
185{
186  Int k,l;
187  Int blkSize        = width;
188  Pel* pDst          = rpDst;
189
190  // Map the mode index to main prediction direction and angle
191  assert( dirMode > 0 ); //no planar
192  Bool modeDC        = dirMode < 2;
193  Bool modeHor       = !modeDC && (dirMode < 18);
194  Bool modeVer       = !modeDC && !modeHor;
195  Int intraPredAngle = modeVer ? (Int)dirMode - VER_IDX : modeHor ? -((Int)dirMode - HOR_IDX) : 0;
196  Int absAng         = abs(intraPredAngle);
197  Int signAng        = intraPredAngle < 0 ? -1 : 1;
198
199  // Set bitshifts and scale the angle parameter to block size
200  Int angTable[9]    = {0,    2,    5,   9,  13,  17,  21,  26,  32};
201  Int invAngTable[9] = {0, 4096, 1638, 910, 630, 482, 390, 315, 256}; // (256 * 32) / Angle
202  Int invAngle       = invAngTable[absAng];
203  absAng             = angTable[absAng];
204  intraPredAngle     = signAng * absAng;
205
206  // Do the DC prediction
207  if (modeDC)
208  {
209    Pel dcval = predIntraGetPredValDC(pSrc, srcStride, width, height, blkAboveAvailable, blkLeftAvailable);
210
211    for (k=0;k<blkSize;k++)
212    {
213      for (l=0;l<blkSize;l++)
214      {
215        pDst[k*dstStride+l] = dcval;
216      }
217    }
218  }
219
220  // Do angular predictions
221  else
222  {
223    Pel* refMain;
224    Pel* refSide;
225    Pel  refAbove[2*MAX_CU_SIZE+1];
226    Pel  refLeft[2*MAX_CU_SIZE+1];
227
228    // Initialise the Main and Left reference array.
229    if (intraPredAngle < 0)
230    {
231      for (k=0;k<blkSize+1;k++)
232      {
233        refAbove[k+blkSize-1] = pSrc[k-srcStride-1];
234      }
235      for (k=0;k<blkSize+1;k++)
236      {
237        refLeft[k+blkSize-1] = pSrc[(k-1)*srcStride-1];
238      }
239      refMain = (modeVer ? refAbove : refLeft) + (blkSize-1);
240      refSide = (modeVer ? refLeft : refAbove) + (blkSize-1);
241
242      // Extend the Main reference to the left.
243      Int invAngleSum    = 128;       // rounding for (shift by 8)
244      for (k=-1; k>blkSize*intraPredAngle>>5; k--)
245      {
246        invAngleSum += invAngle;
247        refMain[k] = refSide[invAngleSum>>8];
248      }
249    }
250    else
251    {
252      for (k=0;k<2*blkSize+1;k++)
253      {
254        refAbove[k] = pSrc[k-srcStride-1];
255      }
256      for (k=0;k<2*blkSize+1;k++)
257      {
258        refLeft[k] = pSrc[(k-1)*srcStride-1];
259      }
260      refMain = modeVer ? refAbove : refLeft;
261      refSide = modeVer ? refLeft  : refAbove;
262    }
263
264    if (intraPredAngle == 0)
265    {
266      for (k=0;k<blkSize;k++)
267      {
268        for (l=0;l<blkSize;l++)
269        {
270          pDst[k*dstStride+l] = refMain[l+1];
271        }
272      }
273
274      if ( bFilter )
275      {
276        for (k=0;k<blkSize;k++)
277        {
278          pDst[k*dstStride] = Clip3(0, (1<<bitDepth)-1, pDst[k*dstStride] + (( refSide[k+1] - refSide[0] ) >> 1) );
279        }
280      }
281    }
282    else
283    {
284      Int deltaPos=0;
285      Int deltaInt;
286      Int deltaFract;
287      Int refMainIndex;
288
289      for (k=0;k<blkSize;k++)
290      {
291        deltaPos += intraPredAngle;
292        deltaInt   = deltaPos >> 5;
293        deltaFract = deltaPos & (32 - 1);
294
295        if (deltaFract)
296        {
297          // Do linear filtering
298          for (l=0;l<blkSize;l++)
299          {
300            refMainIndex        = l+deltaInt+1;
301            pDst[k*dstStride+l] = (Pel) ( ((32-deltaFract)*refMain[refMainIndex]+deltaFract*refMain[refMainIndex+1]+16) >> 5 );
302          }
303        }
304        else
305        {
306          // Just copy the integer samples
307          for (l=0;l<blkSize;l++)
308          {
309            pDst[k*dstStride+l] = refMain[l+deltaInt+1];
310          }
311        }
312      }
313    }
314
315    // Flip the block if this is the horizontal mode
316    if (modeHor)
317    {
318      Pel  tmp;
319      for (k=0;k<blkSize-1;k++)
320      {
321        for (l=k+1;l<blkSize;l++)
322        {
323          tmp                 = pDst[k*dstStride+l];
324          pDst[k*dstStride+l] = pDst[l*dstStride+k];
325          pDst[l*dstStride+k] = tmp;
326        }
327      }
328    }
329  }
330}
331
332Void TComPrediction::predIntraLumaAng(TComPattern* pcTComPattern, UInt uiDirMode, Pel* piPred, UInt uiStride, Int iWidth, Int iHeight, Bool bAbove, Bool bLeft )
333{
334  Pel *pDst = piPred;
335  Int *ptrSrc;
336
337  assert( g_aucConvertToBit[ iWidth ] >= 0 ); //   4x  4
338  assert( g_aucConvertToBit[ iWidth ] <= 5 ); // 128x128
339  assert( iWidth == iHeight  );
340
341  ptrSrc = pcTComPattern->getPredictorPtr( uiDirMode, g_aucConvertToBit[ iWidth ] + 2, m_piYuvExt );
342
343  // get starting pixel in block
344  Int sw = 2 * iWidth + 1;
345
346  // Create the prediction
347  if ( uiDirMode == PLANAR_IDX )
348  {
349    xPredIntraPlanar( ptrSrc+sw+1, sw, pDst, uiStride, iWidth, iHeight );
350  }
351  else
352  {
353    if ( (iWidth > 16) || (iHeight > 16) )
354    {
355      xPredIntraAng(g_bitDepthY, ptrSrc+sw+1, sw, pDst, uiStride, iWidth, iHeight, uiDirMode, bAbove, bLeft, false );
356    }
357    else
358    {
359      xPredIntraAng(g_bitDepthY, ptrSrc+sw+1, sw, pDst, uiStride, iWidth, iHeight, uiDirMode, bAbove, bLeft, true );
360
361      if( (uiDirMode == DC_IDX ) && bAbove && bLeft )
362      {
363        xDCPredFiltering( ptrSrc+sw+1, sw, pDst, uiStride, iWidth, iHeight);
364      }
365    }
366  }
367}
368
369// Angular chroma
370Void TComPrediction::predIntraChromaAng( Int* piSrc, UInt uiDirMode, Pel* piPred, UInt uiStride, Int iWidth, Int iHeight, Bool bAbove, Bool bLeft )
371{
372  Pel *pDst = piPred;
373  Int *ptrSrc = piSrc;
374
375  // get starting pixel in block
376  Int sw = 2 * iWidth + 1;
377
378  if ( uiDirMode == PLANAR_IDX )
379  {
380    xPredIntraPlanar( ptrSrc+sw+1, sw, pDst, uiStride, iWidth, iHeight );
381  }
382  else
383  {
384    // Create the prediction
385    xPredIntraAng(g_bitDepthC, ptrSrc+sw+1, sw, pDst, uiStride, iWidth, iHeight, uiDirMode, bAbove, bLeft, false );
386  }
387}
388
389/** Function for checking identical motion.
390 * \param TComDataCU* pcCU
391 * \param UInt PartAddr
392 */
393Bool TComPrediction::xCheckIdenticalMotion ( TComDataCU* pcCU, UInt PartAddr )
394{
395  if( pcCU->getSlice()->isInterB() && !pcCU->getSlice()->getPPS()->getWPBiPred() )
396  {
397    if( pcCU->getCUMvField(REF_PIC_LIST_0)->getRefIdx(PartAddr) >= 0 && pcCU->getCUMvField(REF_PIC_LIST_1)->getRefIdx(PartAddr) >= 0)
398    {
399      Int RefPOCL0 = pcCU->getSlice()->getRefPic(REF_PIC_LIST_0, pcCU->getCUMvField(REF_PIC_LIST_0)->getRefIdx(PartAddr))->getPOC();
400      Int RefPOCL1 = pcCU->getSlice()->getRefPic(REF_PIC_LIST_1, pcCU->getCUMvField(REF_PIC_LIST_1)->getRefIdx(PartAddr))->getPOC();
401      if(RefPOCL0 == RefPOCL1 && pcCU->getCUMvField(REF_PIC_LIST_0)->getMv(PartAddr) == pcCU->getCUMvField(REF_PIC_LIST_1)->getMv(PartAddr))
402      {
403        return true;
404      }
405    }
406  }
407  return false;
408}
409
410
411Void TComPrediction::motionCompensation ( TComDataCU* pcCU, TComYuv* pcYuvPred, RefPicList eRefPicList, Int iPartIdx )
412{
413  Int         iWidth;
414  Int         iHeight;
415  UInt        uiPartAddr;
416
417  if ( iPartIdx >= 0 )
418  {
419    pcCU->getPartIndexAndSize( iPartIdx, uiPartAddr, iWidth, iHeight );
420    if ( eRefPicList != REF_PIC_LIST_X )
421    {
422      if( pcCU->getSlice()->getPPS()->getUseWP())
423      {
424        xPredInterUni (pcCU, uiPartAddr, iWidth, iHeight, eRefPicList, pcYuvPred, true );
425      }
426      else
427      {
428        xPredInterUni (pcCU, uiPartAddr, iWidth, iHeight, eRefPicList, pcYuvPred );
429      }
430      if ( pcCU->getSlice()->getPPS()->getUseWP() )
431      {
432        xWeightedPredictionUni( pcCU, pcYuvPred, uiPartAddr, iWidth, iHeight, eRefPicList, pcYuvPred );
433      }
434    }
435    else
436    {
437      if ( xCheckIdenticalMotion( pcCU, uiPartAddr ) )
438      {
439        xPredInterUni (pcCU, uiPartAddr, iWidth, iHeight, REF_PIC_LIST_0, pcYuvPred );
440      }
441      else
442      {
443        xPredInterBi  (pcCU, uiPartAddr, iWidth, iHeight, pcYuvPred );
444      }
445    }
446    return;
447  }
448
449  for ( iPartIdx = 0; iPartIdx < pcCU->getNumPartitions(); iPartIdx++ )
450  {
451    pcCU->getPartIndexAndSize( iPartIdx, uiPartAddr, iWidth, iHeight );
452
453    if ( eRefPicList != REF_PIC_LIST_X )
454    {
455      if( pcCU->getSlice()->getPPS()->getUseWP())
456      {
457        xPredInterUni (pcCU, uiPartAddr, iWidth, iHeight, eRefPicList, pcYuvPred, true );
458      }
459      else
460      {
461        xPredInterUni (pcCU, uiPartAddr, iWidth, iHeight, eRefPicList, pcYuvPred );
462      }
463      if ( pcCU->getSlice()->getPPS()->getUseWP() )
464      {
465        xWeightedPredictionUni( pcCU, pcYuvPred, uiPartAddr, iWidth, iHeight, eRefPicList, pcYuvPred );
466      }
467    }
468    else
469    {
470      if ( xCheckIdenticalMotion( pcCU, uiPartAddr ) )
471      {
472        xPredInterUni (pcCU, uiPartAddr, iWidth, iHeight, REF_PIC_LIST_0, pcYuvPred );
473      }
474      else
475      {
476        xPredInterBi  (pcCU, uiPartAddr, iWidth, iHeight, pcYuvPred );
477      }
478    }
479  }
480  return;
481}
482
483Void TComPrediction::xPredInterUni ( TComDataCU* pcCU, UInt uiPartAddr, Int iWidth, Int iHeight, RefPicList eRefPicList, TComYuv*& rpcYuvPred, Bool bi )
484{
485  Int         iRefIdx     = pcCU->getCUMvField( eRefPicList )->getRefIdx( uiPartAddr );           assert (iRefIdx >= 0);
486  TComMv      cMv         = pcCU->getCUMvField( eRefPicList )->getMv( uiPartAddr );
487  pcCU->clipMv(cMv);
488
489#if SVC_EXTENSION
490  if( pcCU->getLayerId() > 0 )
491  {
492    TComPic* refPic = pcCU->getSlice()->getRefPic(eRefPicList, iRefIdx);
493
494    if( refPic->isILR(pcCU->getLayerId()) )
495    {
496      // It is a requirement of bitstream conformance that when the reference picture represented by the variable refIdxLX is an inter-layer reference picture,
497      // VpsInterLayerSamplePredictionEnabled[ LayerIdxInVps[ currLayerId ] ][ LayerIdxInVps[ rLId ] ] shall be equal to 1, where rLId is set equal to nuh_layer_id of the inter-layer picture
498      assert( pcCU->getSlice()->getVPS()->isSamplePredictionType( pcCU->getLayerId(), refPic->getLayerId() ) );
499
500#if REF_IDX_ME_ZEROMV
501      // It is a requirement of bitstream conformance that the variables mvLX[ 0 ] and mvLX[ 1 ] shall be equal to 0 if the value of refIdxLX corresponds to an inter-layer reference picture.
502      assert( cMv.getHor() == 0 && cMv.getVer() == 0 );
503#endif
504    }
505
506  }
507#endif
508
509  xPredInterLumaBlk  ( pcCU, pcCU->getSlice()->getRefPic( eRefPicList, iRefIdx )->getPicYuvRec(), uiPartAddr, &cMv, iWidth, iHeight, rpcYuvPred, bi );
510  xPredInterChromaBlk( pcCU, pcCU->getSlice()->getRefPic( eRefPicList, iRefIdx )->getPicYuvRec(), uiPartAddr, &cMv, iWidth, iHeight, rpcYuvPred, bi );
511}
512
513Void TComPrediction::xPredInterBi ( TComDataCU* pcCU, UInt uiPartAddr, Int iWidth, Int iHeight, TComYuv*& rpcYuvPred )
514{
515  TComYuv* pcMbYuv;
516  Int      iRefIdx[2] = {-1, -1};
517
518  for ( Int iRefList = 0; iRefList < 2; iRefList++ )
519  {
520    RefPicList eRefPicList = (iRefList ? REF_PIC_LIST_1 : REF_PIC_LIST_0);
521    iRefIdx[iRefList] = pcCU->getCUMvField( eRefPicList )->getRefIdx( uiPartAddr );
522
523    if ( iRefIdx[iRefList] < 0 )
524    {
525      continue;
526    }
527
528    assert( iRefIdx[iRefList] < pcCU->getSlice()->getNumRefIdx(eRefPicList) );
529
530    pcMbYuv = &m_acYuvPred[iRefList];
531    if( pcCU->getCUMvField( REF_PIC_LIST_0 )->getRefIdx( uiPartAddr ) >= 0 && pcCU->getCUMvField( REF_PIC_LIST_1 )->getRefIdx( uiPartAddr ) >= 0 )
532    {
533      xPredInterUni ( pcCU, uiPartAddr, iWidth, iHeight, eRefPicList, pcMbYuv, true );
534    }
535    else
536    {
537      if ( ( pcCU->getSlice()->getPPS()->getUseWP()       && pcCU->getSlice()->getSliceType() == P_SLICE ) || 
538           ( pcCU->getSlice()->getPPS()->getWPBiPred() && pcCU->getSlice()->getSliceType() == B_SLICE ) )
539      {
540        xPredInterUni ( pcCU, uiPartAddr, iWidth, iHeight, eRefPicList, pcMbYuv, true );
541      }
542      else
543      {
544        xPredInterUni ( pcCU, uiPartAddr, iWidth, iHeight, eRefPicList, pcMbYuv );
545      }
546    }
547  }
548
549  if ( pcCU->getSlice()->getPPS()->getWPBiPred() && pcCU->getSlice()->getSliceType() == B_SLICE  )
550  {
551    xWeightedPredictionBi( pcCU, &m_acYuvPred[0], &m_acYuvPred[1], iRefIdx[0], iRefIdx[1], uiPartAddr, iWidth, iHeight, rpcYuvPred );
552  } 
553  else if ( pcCU->getSlice()->getPPS()->getUseWP() && pcCU->getSlice()->getSliceType() == P_SLICE )
554  {
555    xWeightedPredictionUni( pcCU, &m_acYuvPred[0], uiPartAddr, iWidth, iHeight, REF_PIC_LIST_0, rpcYuvPred ); 
556  }
557  else
558  {
559    xWeightedAverage( &m_acYuvPred[0], &m_acYuvPred[1], iRefIdx[0], iRefIdx[1], uiPartAddr, iWidth, iHeight, rpcYuvPred );
560  }
561}
562
563/**
564 * \brief Generate motion-compensated luma block
565 *
566 * \param cu       Pointer to current CU
567 * \param refPic   Pointer to reference picture
568 * \param partAddr Address of block within CU
569 * \param mv       Motion vector
570 * \param width    Width of block
571 * \param height   Height of block
572 * \param dstPic   Pointer to destination picture
573 * \param bi       Flag indicating whether bipred is used
574 */
575Void TComPrediction::xPredInterLumaBlk( TComDataCU *cu, TComPicYuv *refPic, UInt partAddr, TComMv *mv, Int width, Int height, TComYuv *&dstPic, Bool bi )
576{
577  Int refStride = refPic->getStride(); 
578  Int refOffset = ( mv->getHor() >> 2 ) + ( mv->getVer() >> 2 ) * refStride;
579  Pel *ref      = refPic->getLumaAddr( cu->getAddr(), cu->getZorderIdxInCU() + partAddr ) + refOffset;
580 
581  Int dstStride = dstPic->getStride();
582  Pel *dst      = dstPic->getLumaAddr( partAddr );
583 
584  Int xFrac = mv->getHor() & 0x3;
585  Int yFrac = mv->getVer() & 0x3;
586
587  if ( yFrac == 0 )
588  {
589    m_if.filterHorLuma( ref, refStride, dst, dstStride, width, height, xFrac,       !bi );
590  }
591  else if ( xFrac == 0 )
592  {
593    m_if.filterVerLuma( ref, refStride, dst, dstStride, width, height, yFrac, true, !bi );
594  }
595  else
596  {
597    Int tmpStride = m_filteredBlockTmp[0].getStride();
598    Short *tmp    = m_filteredBlockTmp[0].getLumaAddr();
599
600    Int filterSize = NTAPS_LUMA;
601    Int halfFilterSize = ( filterSize >> 1 );
602
603    m_if.filterHorLuma(ref - (halfFilterSize-1)*refStride, refStride, tmp, tmpStride, width, height+filterSize-1, xFrac, false     );
604    m_if.filterVerLuma(tmp + (halfFilterSize-1)*tmpStride, tmpStride, dst, dstStride, width, height,              yFrac, false, !bi);   
605  }
606}
607
608/**
609 * \brief Generate motion-compensated chroma block
610 *
611 * \param cu       Pointer to current CU
612 * \param refPic   Pointer to reference picture
613 * \param partAddr Address of block within CU
614 * \param mv       Motion vector
615 * \param width    Width of block
616 * \param height   Height of block
617 * \param dstPic   Pointer to destination picture
618 * \param bi       Flag indicating whether bipred is used
619 */
620Void TComPrediction::xPredInterChromaBlk( TComDataCU *cu, TComPicYuv *refPic, UInt partAddr, TComMv *mv, Int width, Int height, TComYuv *&dstPic, Bool bi )
621{
622  Int     refStride  = refPic->getCStride();
623  Int     dstStride  = dstPic->getCStride();
624 
625  Int     refOffset  = (mv->getHor() >> 3) + (mv->getVer() >> 3) * refStride;
626 
627  Pel*    refCb     = refPic->getCbAddr( cu->getAddr(), cu->getZorderIdxInCU() + partAddr ) + refOffset;
628  Pel*    refCr     = refPic->getCrAddr( cu->getAddr(), cu->getZorderIdxInCU() + partAddr ) + refOffset;
629 
630  Pel* dstCb = dstPic->getCbAddr( partAddr );
631  Pel* dstCr = dstPic->getCrAddr( partAddr );
632 
633  Int     xFrac  = mv->getHor() & 0x7;
634  Int     yFrac  = mv->getVer() & 0x7;
635  UInt    cxWidth  = width  >> 1;
636  UInt    cxHeight = height >> 1;
637 
638  Int     extStride = m_filteredBlockTmp[0].getStride();
639  Short*  extY      = m_filteredBlockTmp[0].getLumaAddr();
640 
641  Int filterSize = NTAPS_CHROMA;
642 
643  Int halfFilterSize = (filterSize>>1);
644 
645  if ( yFrac == 0 )
646  {
647    m_if.filterHorChroma(refCb, refStride, dstCb,  dstStride, cxWidth, cxHeight, xFrac, !bi);   
648    m_if.filterHorChroma(refCr, refStride, dstCr,  dstStride, cxWidth, cxHeight, xFrac, !bi);   
649  }
650  else if ( xFrac == 0 )
651  {
652    m_if.filterVerChroma(refCb, refStride, dstCb, dstStride, cxWidth, cxHeight, yFrac, true, !bi);   
653    m_if.filterVerChroma(refCr, refStride, dstCr, dstStride, cxWidth, cxHeight, yFrac, true, !bi);   
654  }
655  else
656  {
657    m_if.filterHorChroma(refCb - (halfFilterSize-1)*refStride, refStride, extY,  extStride, cxWidth, cxHeight+filterSize-1, xFrac, false);
658    m_if.filterVerChroma(extY  + (halfFilterSize-1)*extStride, extStride, dstCb, dstStride, cxWidth, cxHeight  , yFrac, false, !bi);
659   
660    m_if.filterHorChroma(refCr - (halfFilterSize-1)*refStride, refStride, extY,  extStride, cxWidth, cxHeight+filterSize-1, xFrac, false);
661    m_if.filterVerChroma(extY  + (halfFilterSize-1)*extStride, extStride, dstCr, dstStride, cxWidth, cxHeight  , yFrac, false, !bi);   
662  }
663}
664
665Void TComPrediction::xWeightedAverage( TComYuv* pcYuvSrc0, TComYuv* pcYuvSrc1, Int iRefIdx0, Int iRefIdx1, UInt uiPartIdx, Int iWidth, Int iHeight, TComYuv*& rpcYuvDst )
666{
667  if( iRefIdx0 >= 0 && iRefIdx1 >= 0 )
668  {
669    rpcYuvDst->addAvg( pcYuvSrc0, pcYuvSrc1, uiPartIdx, iWidth, iHeight );
670  }
671  else if ( iRefIdx0 >= 0 && iRefIdx1 <  0 )
672  {
673    pcYuvSrc0->copyPartToPartYuv( rpcYuvDst, uiPartIdx, iWidth, iHeight );
674  }
675  else if ( iRefIdx0 <  0 && iRefIdx1 >= 0 )
676  {
677    pcYuvSrc1->copyPartToPartYuv( rpcYuvDst, uiPartIdx, iWidth, iHeight );
678  }
679}
680
681// AMVP
682Void TComPrediction::getMvPredAMVP( TComDataCU* pcCU, UInt uiPartIdx, UInt uiPartAddr, RefPicList eRefPicList, TComMv& rcMvPred )
683{
684  AMVPInfo* pcAMVPInfo = pcCU->getCUMvField(eRefPicList)->getAMVPInfo();
685  if( pcAMVPInfo->iN <= 1 )
686  {
687    rcMvPred = pcAMVPInfo->m_acMvCand[0];
688
689    pcCU->setMVPIdxSubParts( 0, eRefPicList, uiPartAddr, uiPartIdx, pcCU->getDepth(uiPartAddr));
690    pcCU->setMVPNumSubParts( pcAMVPInfo->iN, eRefPicList, uiPartAddr, uiPartIdx, pcCU->getDepth(uiPartAddr));
691    return;
692  }
693
694  assert(pcCU->getMVPIdx(eRefPicList,uiPartAddr) >= 0);
695  rcMvPred = pcAMVPInfo->m_acMvCand[pcCU->getMVPIdx(eRefPicList,uiPartAddr)];
696  return;
697}
698
699/** Function for deriving planar intra prediction.
700 * \param pSrc pointer to reconstructed sample array
701 * \param srcStride the stride of the reconstructed sample array
702 * \param rpDst reference to pointer for the prediction sample array
703 * \param dstStride the stride of the prediction sample array
704 * \param width the width of the block
705 * \param height the height of the block
706 *
707 * This function derives the prediction samples for planar mode (intra coding).
708 */
709Void TComPrediction::xPredIntraPlanar( Int* pSrc, Int srcStride, Pel* rpDst, Int dstStride, UInt width, UInt height )
710{
711  assert(width == height);
712
713  Int k, l, bottomLeft, topRight;
714  Int horPred;
715  Int leftColumn[MAX_CU_SIZE+1], topRow[MAX_CU_SIZE+1], bottomRow[MAX_CU_SIZE], rightColumn[MAX_CU_SIZE];
716  UInt blkSize = width;
717  UInt offset2D = width;
718  UInt shift1D = g_aucConvertToBit[ width ] + 2;
719  UInt shift2D = shift1D + 1;
720
721  // Get left and above reference column and row
722  for(k=0;k<blkSize+1;k++)
723  {
724    topRow[k] = pSrc[k-srcStride];
725    leftColumn[k] = pSrc[k*srcStride-1];
726  }
727
728  // Prepare intermediate variables used in interpolation
729  bottomLeft = leftColumn[blkSize];
730  topRight   = topRow[blkSize];
731  for (k=0;k<blkSize;k++)
732  {
733    bottomRow[k]   = bottomLeft - topRow[k];
734    rightColumn[k] = topRight   - leftColumn[k];
735    topRow[k]      <<= shift1D;
736    leftColumn[k]  <<= shift1D;
737  }
738
739  // Generate prediction signal
740  for (k=0;k<blkSize;k++)
741  {
742    horPred = leftColumn[k] + offset2D;
743    for (l=0;l<blkSize;l++)
744    {
745      horPred += rightColumn[k];
746      topRow[l] += bottomRow[l];
747      rpDst[k*dstStride+l] = ( (horPred + topRow[l]) >> shift2D );
748    }
749  }
750}
751
752/** Function for filtering intra DC predictor.
753 * \param pSrc pointer to reconstructed sample array
754 * \param iSrcStride the stride of the reconstructed sample array
755 * \param rpDst reference to pointer for the prediction sample array
756 * \param iDstStride the stride of the prediction sample array
757 * \param iWidth the width of the block
758 * \param iHeight the height of the block
759 *
760 * This function performs filtering left and top edges of the prediction samples for DC mode (intra coding).
761 */
762Void TComPrediction::xDCPredFiltering( Int* pSrc, Int iSrcStride, Pel*& rpDst, Int iDstStride, Int iWidth, Int iHeight )
763{
764  Pel* pDst = rpDst;
765  Int x, y, iDstStride2, iSrcStride2;
766
767  // boundary pixels processing
768  pDst[0] = (Pel)((pSrc[-iSrcStride] + pSrc[-1] + 2 * pDst[0] + 2) >> 2);
769
770  for ( x = 1; x < iWidth; x++ )
771  {
772    pDst[x] = (Pel)((pSrc[x - iSrcStride] +  3 * pDst[x] + 2) >> 2);
773  }
774
775  for ( y = 1, iDstStride2 = iDstStride, iSrcStride2 = iSrcStride-1; y < iHeight; y++, iDstStride2+=iDstStride, iSrcStride2+=iSrcStride )
776  {
777    pDst[iDstStride2] = (Pel)((pSrc[iSrcStride2] + 3 * pDst[iDstStride2] + 2) >> 2);
778  }
779
780  return;
781}
782
783#if SVC_EXTENSION
784#if O0215_PHASE_ALIGNMENT
785#if O0194_JOINT_US_BITSHIFT
786Void TComPrediction::upsampleBasePic( TComSlice* currSlice, UInt refLayerIdc, TComPicYuv* pcUsPic, TComPicYuv* pcBasePic, TComPicYuv* pcTempPic, Bool phaseAlignFlag )
787{
788  m_cUsf.upsampleBasePic( currSlice, refLayerIdc, pcUsPic, pcBasePic, pcTempPic, phaseAlignFlag );
789}
790#else
791Void TComPrediction::upsampleBasePic( UInt refLayerIdc, TComPicYuv* pcUsPic, TComPicYuv* pcBasePic, TComPicYuv* pcTempPic, const Window window, Bool phaseAlignFlag )
792{
793  m_cUsf.upsampleBasePic( refLayerIdc, pcUsPic, pcBasePic, pcTempPic, window, phaseAlignFlag );
794}
795#endif
796#else
797#if O0194_JOINT_US_BITSHIFT
798#if REF_REGION_OFFSET
799Void TComPrediction::upsampleBasePic( UInt refLayerIdc, TComPicYuv* pcUsPic, TComPicYuv* pcBasePic, TComPicYuv* pcTempPic, const Window window, const Window altRefWindow )
800{
801  m_cUsf.upsampleBasePic( refLayerIdc, pcUsPic, pcBasePic, pcTempPic, window, altRefWindow );
802}
803#else
804Void TComPrediction::upsampleBasePic( TComSlice* currSlice, UInt refLayerIdc, TComPicYuv* pcUsPic, TComPicYuv* pcBasePic, TComPicYuv* pcTempPic, const Window window)
805{
806  m_cUsf.upsampleBasePic( refLayerIdc, pcUsPic, pcBasePic, pcTempPic, window);
807}
808#endif
809#else
810Void TComPrediction::upsampleBasePic( UInt refLayerIdc, TComPicYuv* pcUsPic, TComPicYuv* pcBasePic, TComPicYuv* pcTempPic, const Window window)
811{
812  m_cUsf.upsampleBasePic( refLayerIdc, pcUsPic, pcBasePic, pcTempPic, window);
813}
814#endif
815#endif
816#endif //SVC_EXTENSION
817//! \}
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