/*************************************************************************

    This project implements a complete(!) JPEG (Recommendation ITU-T
    T.81 | ISO/IEC 10918-1) codec, plus a library that can be used to
    encode and decode JPEG streams. 
    It also implements ISO/IEC 18477 aka JPEG XT which is an extension
    towards intermediate, high-dynamic-range lossy and lossless coding
    of JPEG. In specific, it supports ISO/IEC 18477-3/-6/-7/-8 encoding.

    Note that only Profiles C and D of ISO/IEC 18477-7 are supported
    here. Check the JPEG XT reference software for a full implementation
    of ISO/IEC 18477-7.

    Copyright (C) 2012-2018 Thomas Richter, University of Stuttgart and
    Accusoft. (C) 2019-2020 Thomas Richter, Fraunhofer IIS.

    This program is available under two licenses, GPLv3 and the ITU
    Software licence Annex A Option 2, RAND conditions.

    For the full text of the GPU license option, see README.license.gpl.
    For the full text of the ITU license option, see README.license.itu.
    
    You may freely select between these two options.

    For the GPL option, please note the following:

    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 3 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, see <http://www.gnu.org/licenses/>.

*************************************************************************/
/*
**
** Basic control helper for requesting and releasing bitmap data.
**
** $Id: bitmapctrl.cpp,v 1.19 2020/08/31 07:50:44 thor Exp $
**
*/

/// Includes
#include "tools/environment.hpp"
#include "marker/frame.hpp"
#include "marker/scan.hpp"
#include "marker/component.hpp"
#include "control/bitmapctrl.hpp"
#include "interface/bitmaphook.hpp"
#include "codestream/rectanglerequest.hpp"
#include "std/string.hpp"
///

/// BitmapCtrl::BitmapCtrl
BitmapCtrl::BitmapCtrl(class Frame *frame)
  : BufferCtrl(frame->EnvironOf()), m_pFrame(frame), 
    m_ppBitmap(NULL), m_ppLDRBitmap(NULL), m_ppCTemp(NULL), m_pColorBuffer(NULL)
{
}
///

/// BitmapCtrl::BuildCommon
void BitmapCtrl::BuildCommon(void)
{
  m_ulPixelWidth  = m_pFrame->WidthOf();
  m_ulPixelHeight = m_pFrame->HeightOf();
  m_ucPixelType   = 0;
  m_ucCount       = m_pFrame->DepthOf();

  if (m_ppCTemp == NULL)
    m_ppCTemp     = (LONG **)m_pEnviron->AllocMem(m_ucCount * sizeof(LONG *));

  if (m_pColorBuffer == NULL)
    m_pColorBuffer = (LONG *)m_pEnviron->AllocMem(m_ucCount * 64 * sizeof(LONG));

  if (m_ppBitmap == NULL) {
    m_ppBitmap      = (struct ImageBitMap **)m_pEnviron->AllocMem(sizeof(struct ImageBitMap *) * m_ucCount);
    memset(m_ppBitmap,0,sizeof(struct ImageBitMap *) * m_ucCount);
    
    for(UBYTE i = 0;i < m_ucCount;i++) {
      m_ppBitmap[i] = new(m_pEnviron) struct ImageBitMap();
      m_ppCTemp[i]  = m_pColorBuffer + i * 64;
    }
  }
}
///

/// BitmapCtrl::~BitmapCtrl
BitmapCtrl::~BitmapCtrl(void)
{
  UBYTE i;

  if (m_ppCTemp)
    m_pEnviron->FreeMem(m_ppCTemp,m_ucCount * sizeof(LONG *));
  
  if (m_pColorBuffer)
    m_pEnviron->FreeMem(m_pColorBuffer,m_ucCount * 64 * sizeof(LONG));
  
  if (m_ppBitmap) {
    for(i = 0;i < m_ucCount;i++) {
      delete m_ppBitmap[i];
    }
    m_pEnviron->FreeMem(m_ppBitmap,sizeof(struct ImageBitMap *) * m_ucCount);
  }

  if (m_ppLDRBitmap) {
    for(i = 0;i < m_ucCount;i++) {
      delete m_ppLDRBitmap[i];
    }
    m_pEnviron->FreeMem(m_ppLDRBitmap,sizeof(struct ImageBitMap *) * m_ucCount);
  }
}
///

/// BitmapCtrl::ClipToImage
// Clip a rectangle to the image region
void BitmapCtrl::ClipToImage(RectAngle<LONG> &rect) const
{
  if (rect.ra_MinX < 0)
    rect.ra_MinX = 0;
  if (rect.ra_MaxX >= LONG(m_ulPixelWidth))
    rect.ra_MaxX = m_ulPixelWidth  - 1;
  if (rect.ra_MinY < 0)
    rect.ra_MinY = 0;
  if (m_ulPixelHeight && rect.ra_MaxY >= LONG(m_ulPixelHeight))
    rect.ra_MaxY = m_ulPixelHeight - 1;
}
///

/// BitmapCtrl::RequestUserData
// Request data from the user through the indicated bitmap hook
// for the given rectangle. The rectangle is first clipped to
// range (as appropriate, if the height is already known) and
// then the desired n'th component of the scan (not the component
// index) is requested.
void BitmapCtrl::RequestUserData(class BitMapHook *bmh,const RectAngle<LONG> &r,UBYTE comp,bool alpha)
{
  assert(comp < m_ucCount && bmh);

  if (alpha) {
    bmh->RequestClientAlpha(r,m_ppBitmap[comp],m_pFrame->ComponentOf(comp));
  } else {
    bmh->RequestClientData(r,m_ppBitmap[comp],m_pFrame->ComponentOf(comp));
  }

  if (m_ucPixelType == 0) { // Not yet defined
    m_ucPixelType = m_ppBitmap[comp]->ibm_ucPixelType;
  } else if (m_ppBitmap[comp]->ibm_ucPixelType) {
    if (m_ucPixelType != m_ppBitmap[comp]->ibm_ucPixelType) {
      JPG_THROW(INVALID_PARAMETER,"BitmapCtrl::RequestUserData","pixel types must be consistent across components");
    }
  }

  //
  // Now check whether the user supplies a dedicated LDR part.
  if (!alpha && bmh->providesLDRImage()) {
    // Need to build the LDR image layout?
    if (m_ppLDRBitmap == NULL) { 
      m_ppLDRBitmap    = (struct ImageBitMap **)m_pEnviron->AllocMem(sizeof(struct ImageBitMap *) * m_ucCount);
      memset(m_ppLDRBitmap,0,sizeof(struct ImageBitMap *) * m_ucCount);
    
      for(UBYTE i = 0;i < m_ucCount;i++) {
        m_ppLDRBitmap[i] = new(m_pEnviron) struct ImageBitMap();
      }
    }
    bmh->RequestLDRData(r,m_ppLDRBitmap[comp],m_pFrame->ComponentOf(comp));
  }
}
///

/// BitmapCtrl::ReleaseUserData
// Release the user data again through the bitmap hook.
void BitmapCtrl::ReleaseUserData(class BitMapHook *bmh,const RectAngle<LONG> &r,UBYTE comp,bool alpha)
{
  assert(comp < 4 && bmh);
  
  // If we have LDR bitmaps, release this one first as it was requested last.
  if (m_ppLDRBitmap && !alpha) {
    bmh->ReleaseLDRData(r,m_ppLDRBitmap[comp],m_pFrame->ComponentOf(comp));
  }

  //
  // Now for the HDR part, or the only part.
  if (alpha) {
    bmh->ReleaseClientAlpha(r,m_ppBitmap[comp],m_pFrame->ComponentOf(comp));
  } else {
    bmh->ReleaseClientData(r,m_ppBitmap[comp],m_pFrame->ComponentOf(comp));
  }

  m_ucPixelType = 0;
}
///

/// BitmapCtrl::ExtractBitmap
// Extract the region of the bitmap covering the indicated rectangle
void BitmapCtrl::ExtractBitmap(struct ImageBitMap *ibm,const RectAngle<LONG> &rect,UBYTE i)
{
  assert(i < m_ucCount);
  
  ibm->ExtractBitMap(m_ppBitmap[i],rect);
}
///

/// BitmapCtrl::ExtractLDRBitmap
// Extract a region from the LDR data.
void BitmapCtrl::ExtractLDRBitmap(struct ImageBitMap *ibm,const RectAngle<LONG> &rect,UBYTE i)
{
  assert(i < m_ucCount);
  assert(m_ppLDRBitmap);

  ibm->ExtractBitMap(m_ppLDRBitmap[i],rect);
}
///

/// BitmapCtrl::ResetBitmaps
// Ensure that unused bitmaps are cleared so we do overwrite memory that is
// not requested.
void BitmapCtrl::ResetBitmaps(void)
{
  UBYTE i;
  
  for(i = 0;i < m_ucCount;i++) {
    m_ppBitmap[i]->ibm_pData          = NULL;
    m_ppBitmap[i]->ibm_ucPixelType    = 0;
    m_ppBitmap[i]->ibm_cBytesPerPixel = 0;
    m_ppBitmap[i]->ibm_lBytesPerRow   = 0;
  }
}
///

/// BitmapCtrl::ReleaseUserDataFromEncoding 
// Release user data after encoding.
void BitmapCtrl::ReleaseUserDataFromEncoding(class BitMapHook *bmh,const RectAngle<LONG> &region,bool alpha)
{
  int i;
  
  for(i = 0;i < m_ucCount;i++) {
    ReleaseUserData(bmh,region,i,alpha);
  }
}
///

/// BitmapCtrl::ReleaseUserDataFromDecoding
// Release user data after decoding.
void BitmapCtrl::ReleaseUserDataFromDecoding(class BitMapHook *bmh,const struct RectangleRequest *rr,bool alpha)
{
  int i;
  
  for(i = rr->rr_usFirstComponent;i <=rr->rr_usLastComponent;i++) {
    ReleaseUserData(bmh,rr->rr_Request,i,alpha);
  }
}
///

/// BitmapCtrl::CropDecodingRegion
// First step of a region decoder: Find the region that can be provided in the next step.
void BitmapCtrl::CropDecodingRegion(RectAngle<LONG> &region,const struct RectangleRequest *)
{
  // The easy case
  ClipToImage(region);
}
///

/// BitmapCtrl::SubsampledRegion
// Compute the subsampled rectangle in case we are not upsampling from the
// region in the rectangle request.
void BitmapCtrl::SubsampledRegion(RectAngle<LONG> &rect,const struct RectangleRequest *rr) const
{
  if (rr->rr_bUpsampling == false) {
    class Component *comp;
    UBYTE subx,suby;
    //
    if (rr->rr_bColorTrafo)
      JPG_THROW(INVALID_PARAMETER,"BitmapCtrl::SubsampledRegion","cannot color transform non-upsampled data");
    if (rr->rr_usFirstComponent != rr->rr_usLastComponent)
      JPG_THROW(INVALID_PARAMETER,"BitmapCtrl::SubsampledRegion","if upsampling is disabled, components can only be reconstructed one by one");
    //
    comp = m_pFrame->ComponentOf(rr->rr_usFirstComponent);
    subx = comp->SubXOf();
    suby = comp->SubYOf();
    //
    rect.ra_MinX = (rect.ra_MinX + subx - 1) / subx;
    rect.ra_MaxX = (rect.ra_MaxX + subx    ) / subx - 1;
    rect.ra_MinY = (rect.ra_MinY + suby - 1) / suby;
    rect.ra_MaxY = (rect.ra_MaxY + suby    ) / suby - 1;
  }
}
///