/*!
 *************************************************************************************
 * \file 
 *      erc_do_i.c
 *
 * \brief
 *      Intra (I) frame error concealment algorithms for decoder
 *
 *  \author
 *      - Ari Hourunranta                <ari.hourunranta@nokia.com>
 *      - Viktor Varsa                     <viktor.varsa@nokia.com>
 *      - Ye-Kui Wang                   <wyk@ieee.org>
 *
 *************************************************************************************
 */

#include <stdlib.h>
#include "global.h"
#include "erc_do.h"

static void concealBlocks( int lastColumn, int lastRow, int comp, frame *recfr, int32 picSizeX, int *condition );
static void pixMeanInterpolateBlock( byte *src[], byte *block, int blockSize, int frameWidth );

/*!
 ************************************************************************
 * \brief
 *      The main function for Intra frame concealment.
 *      Calls "concealBlocks" for each color component (Y,U,V) seperately
 * \return
 *      0, if the concealment was not successful and simple concealment should be used
 *      1, otherwise (even if none of the blocks were concealed)
 * \param recfr
 *      Reconstructed frame buffer
 * \param picSizeX
 *      Width of the frame in pixels
 * \param picSizeY
 *      Height of the frame in pixels
 * \param errorVar   
 *      Variables for error concealment
 ************************************************************************
 */
int ercConcealIntraFrame( frame *recfr, int32 picSizeX, int32 picSizeY, ercVariables_t *errorVar ) 
{
  int lastColumn = 0, lastRow = 0;
  
  /* if concealment is on */
  if ( errorVar && errorVar->concealment ) 
  {
    /* if there are segments to be concealed */
    if ( errorVar->nOfCorruptedSegments ) 
    { 
      /* Y */
      lastRow = (int) (picSizeY>>3);
      lastColumn = (int) (picSizeX>>3);
      concealBlocks( lastColumn, lastRow, 0, recfr, picSizeX, errorVar->yCondition );
      
      /* U (dimensions halved compared to Y) */
      lastRow = (int) (picSizeY>>4);
      lastColumn = (int) (picSizeX>>4);
      concealBlocks( lastColumn, lastRow, 1, recfr, picSizeX, errorVar->uCondition );
      
      /* V ( dimensions equal to U ) */
      concealBlocks( lastColumn, lastRow, 2, recfr, picSizeX, errorVar->vCondition );
    }
    return 1;
  }
  else
    return 0;
}

/*!
 ************************************************************************
 * \brief
 *      Conceals the MB at position (row, column) using pixels from predBlocks[]
 *      using pixMeanInterpolateBlock()
 * \param currFrame
 *      current frame
 * \param row
 *      y coordinate in blocks
 * \param column
 *      x coordinate in blocks
 * \param predBlocks[]   
 *      list of neighboring source blocks (numbering 0 to 7, 1 means: use the neighbor)
 * \param frameWidth
 *      width of frame in pixels
 * \param mbWidthInBlocks
 *      2 for Y, 1 for U/V components
 ************************************************************************
 */
void ercPixConcealIMB(byte *currFrame, int row, int column, int predBlocks[], int frameWidth, int mbWidthInBlocks) 
{
   byte *src[8]={NULL,NULL,NULL,NULL,NULL,NULL,NULL,NULL};
   byte *currBlock = NULL;

   /* collect the reliable neighboring blocks */
   if (predBlocks[0])
      src[0] = currFrame + (row-mbWidthInBlocks)*frameWidth*8 + (column+mbWidthInBlocks)*8;
   if (predBlocks[1])
      src[1] = currFrame + (row-mbWidthInBlocks)*frameWidth*8 + (column-mbWidthInBlocks)*8;
   if (predBlocks[2])
      src[2] = currFrame + (row+mbWidthInBlocks)*frameWidth*8 + (column-mbWidthInBlocks)*8;
   if (predBlocks[3])
      src[3] = currFrame + (row+mbWidthInBlocks)*frameWidth*8 + (column+mbWidthInBlocks)*8;
   if (predBlocks[4])
      src[4] = currFrame + (row-mbWidthInBlocks)*frameWidth*8 + column*8;
   if (predBlocks[5])
      src[5] = currFrame + row*frameWidth*8 + (column-mbWidthInBlocks)*8;
   if (predBlocks[6])
      src[6] = currFrame + (row+mbWidthInBlocks)*frameWidth*8 + column*8;
   if (predBlocks[7])
      src[7] = currFrame + row*frameWidth*8 + (column+mbWidthInBlocks)*8;
   
   currBlock = currFrame + row*frameWidth*8 + column*8;
   pixMeanInterpolateBlock( src, currBlock, mbWidthInBlocks*8, frameWidth );

}

/*!
 ************************************************************************
 * \brief
 *      This function checks the neighbours of a Macroblock for usability in
 *      concealment. First the OK Macroblocks are marked, and if there is not 
 *      enough of them, then the CONCEALED ones as well.
 *      A "1" in the the output array means reliable, a "0" non reliable MB.
 *      The block order in "predBlocks":
 *              1 4 0
 *              5 x 7
 *              2 6 3   
 *      i.e., corners first.
 * \return
 *      Number of useable neighbour Macroblocks for concealment.
 * \param predBlocks[] 
 *      Array for indicating the valid neighbor blocks
 * \param currRow 
 *      Current block row in the frame
 * \param currColumn    
 *      Current block column in the frame
 * \param condition    
 *      The block condition (ok, lost) table
 * \param maxRow      
 *      Number of block rows in the frame
 * \param maxColumn   
 *      Number of block columns in the frame
 * \param step          
 *      Number of blocks belonging to a MB, when counting
 *      in vertical/horizontal direction. (Y:2 U,V:1)
 * \param fNoCornerNeigh 
 *      No corner neighbours are considered
 ************************************************************************
 */
int ercCollect8PredBlocks( int predBlocks[], int currRow, int currColumn, int *condition, 
                          int maxRow, int maxColumn, int step, byte fNoCornerNeigh )
{
  int srcCounter = 0, srcCountMin = (fNoCornerNeigh ? 2 : 4),
    threshold = ERC_BLOCK_CONCEALED;
  
  memset( predBlocks, 0, 8*sizeof(int) );
  
  /* collect the reliable neighboring blocks */
  do 
  {
    srcCounter = 0;
    /* Top */
    if (currRow > 0 && condition[ (currRow-1)*maxColumn + currColumn ] >= threshold ) 
    {                           //ERC_BLOCK_OK (3) or ERC_BLOCK_CONCEALED (2)
      predBlocks[4] = condition[ (currRow-1)*maxColumn + currColumn ];
      srcCounter++;
    }
    /* Bottom */
    if ( currRow < (maxRow-step) && condition[ (currRow+step)*maxColumn + currColumn ] >= threshold ) 
    {
      predBlocks[6] = condition[ (currRow+step)*maxColumn + currColumn ];
      srcCounter++;
    }
    
    if ( currColumn > 0 ) 
    {
      /* Left */
      if ( condition[ currRow*maxColumn + currColumn - 1 ] >= threshold ) 
      {
        predBlocks[5] = condition[ currRow*maxColumn + currColumn - 1 ];
        srcCounter++;
      }
      
      if ( !fNoCornerNeigh ) 
      {
        /* Top-Left */
        if ( currRow > 0 && condition[ (currRow-1)*maxColumn + currColumn - 1 ] >= threshold ) 
        {
          predBlocks[1] = condition[ (currRow-1)*maxColumn + currColumn - 1 ];
          srcCounter++;
        }
        /* Bottom-Left */
        if ( currRow < (maxRow-step) && condition[ (currRow+step)*maxColumn + currColumn - 1 ] >= threshold ) 
        {
          predBlocks[2] = condition[ (currRow+step)*maxColumn + currColumn - 1 ];
          srcCounter++;
        }
      }
    }
    
    if ( currColumn < (maxColumn-step) ) 
    {
      /* Right */
      if ( condition[ currRow*maxColumn+currColumn + step ] >= threshold ) 
      {
        predBlocks[7] = condition[ currRow*maxColumn+currColumn + step ];
        srcCounter++;
      }
      
      if ( !fNoCornerNeigh ) 
      {
        /* Top-Right */
        if ( currRow > 0 && condition[ (currRow-1)*maxColumn + currColumn + step ] >= threshold ) 
        {
          predBlocks[0] = condition[ (currRow-1)*maxColumn + currColumn + step ];
          srcCounter++;
        }
        /* Bottom-Right */
        if ( currRow < (maxRow-step) && condition[ (currRow+step)*maxColumn + currColumn + step ] >= threshold ) 
        {
          predBlocks[3] = condition[ (currRow+step)*maxColumn + currColumn + step ];
          srcCounter++;
        }
      }
    }
    /* prepare for the next round */
    threshold--;
    if (threshold < ERC_BLOCK_CONCEALED)
      break;
  } while ( srcCounter < srcCountMin);
  
  return srcCounter;
}

/*!
 ************************************************************************
 * \brief
 *      collects prediction blocks only from the current column
 * \return
 *      Number of useable neighbour Macroblocks for concealment.
 * \param predBlocks[] 
 *      Array for indicating the valid neighbor blocks
 * \param currRow 
 *      Current block row in the frame
 * \param currColumn    
 *      Current block column in the frame
 * \param condition    
 *      The block condition (ok, lost) table
 * \param maxRow      
 *      Number of block rows in the frame
 * \param maxColumn   
 *      Number of block columns in the frame
 * \param step          
 *      Number of blocks belonging to a MB, when counting
 *      in vertical/horizontal direction. (Y:2 U,V:1)
 ************************************************************************
 */
int ercCollectColumnBlocks( int predBlocks[], int currRow, int currColumn, int *condition, int maxRow, int maxColumn, int step )
{
  int srcCounter = 0, threshold = ERC_BLOCK_CORRUPTED;
  
  memset( predBlocks, 0, 8*sizeof(int) );
  
  /* in this case, row > 0 and row < 17 */
  if ( condition[ (currRow-1)*maxColumn + currColumn ] > threshold ) 
  {
    predBlocks[4] = 1;
    srcCounter++;
  }