path: root/src/drivers/Quartz/Fl_Quartz_Graphics_Driver_image.cxx

//
// "$Id$"
//
// MacOS image drawing code for the Fast Light Tool Kit (FLTK).
//
// Copyright 1998-2012 by Bill Spitzak and others.
//
// This library is free software. Distribution and use rights are outlined in
// the file "COPYING" which should have been included with this file.  If this
// file is missing or damaged, see the license at:
//
//     http://www.fltk.org/COPYING.php
//
// Please report all bugs and problems on the following page:
//
//     http://www.fltk.org/str.php
//

#include "../../config_lib.h"
#ifdef FL_CFG_GFX_QUARTZ

#include "Fl_Quartz_Graphics_Driver.h"

#include <config.h>
#include <FL/Fl.H>
#include <FL/fl_draw.H>
#include <FL/Fl_Printer.H>
#include <FL/x.H>

#define MAXBUFFER 0x40000 // 256k

static void dataReleaseCB(void *info, const void *data, size_t size)
{
  delete[] (uchar *)data;
}

/*
 * draw an image based on the input parameters
 *
 * buf:       image source data
 * X, Y:      position (in buffer?!)
 * W, H:      size of picture (in pixel?)
 * delta:     distance from pixel to pixel in buf in bytes
 * linedelta: distance from line to line in buf in bytes
 * mono:      if set, pixel is one byte - if zero, pixel is 3 byte
 * cb:        callback to copy image data into (RGB?) buffer
 *   buf:       pointer to first byte in image source
 *   x, y:      position in buffer
 *   w:         width (in bytes?)
 *   dst:       destination buffer
 * userdata:  ?
 */
static void innards(const uchar *buf, int X, int Y, int W, int H,
		    int delta, int linedelta, int mono,
		    Fl_Draw_Image_Cb cb, void* userdata)
{
  if (!linedelta) linedelta = W*delta;

  const void *array = buf;
  uchar *tmpBuf = 0;
  if (cb || Fl_Surface_Device::surface() != Fl_Display_Device::display_device()) {
    tmpBuf = new uchar[ H*W*delta ];
    if (cb) {
      for (int i=0; i<H; i++) {
	cb(userdata, 0, i, W, tmpBuf+i*W*delta);
      }
    } else {
      uchar *p = tmpBuf;
      for (int i=0; i<H; i++) {
	memcpy(p, buf+i*linedelta, W*delta);
	p += W*delta;
	}
    }
    array = (void*)tmpBuf;
    linedelta = W*delta;
  }
  // create an image context
  CGColorSpaceRef   lut = 0;
  if (delta<=2) 
    lut = CGColorSpaceCreateDeviceGray();
  else
    lut = CGColorSpaceCreateDeviceRGB();
  // a release callback is necessary when the fl_gc is a print context because the image data
  // must be kept until the page is closed. Thus tmpBuf can't be deleted here. It's too early.
  CGDataProviderRef src = CGDataProviderCreateWithData( 0L, array, linedelta*H, 
						       tmpBuf ? dataReleaseCB : NULL
						       );
  CGImageRef        img = CGImageCreate( W, H, 8, 8*delta, linedelta,
                            lut, delta&1?kCGImageAlphaNone:kCGImageAlphaNoneSkipLast,
                            //lut, delta&1?kCGImageAlphaNone:kCGImageAlphaLast,
                            src, 0L, false, kCGRenderingIntentDefault);
  // draw the image into the destination context
  if (img) {
    CGRect rect = CGRectMake( X, Y,  W, H);
    Fl_X::q_begin_image(rect, 0, 0, W, H);
    CGContextDrawImage(fl_gc, rect, img);
    Fl_X::q_end_image();
    // release all allocated resources
    CGImageRelease(img);
  }
  CGColorSpaceRelease(lut);
  CGDataProviderRelease(src);
  if (img) return; // else fall through to slow mode
  // following the very save (and very slow) way to write the image into the give port
  CGContextSetShouldAntialias(fl_gc, false);
  if ( cb )
  {
    uchar *tmpBuf = new uchar[ W*4 ];
    for ( int i=0; i<H; i++ )
    {
      uchar *src = tmpBuf;
      cb( userdata, 0, i, W, tmpBuf );
      for ( int j=0; j<W; j++ )
      {
        if ( mono )
          { fl_color( src[0], src[0], src[0] ); }
        else
          { fl_color( src[0], src[1], src[2] ); }
        CGContextMoveToPoint(fl_gc, X+j, Y+i);
        CGContextAddLineToPoint(fl_gc, X+j, Y+i);
        CGContextStrokePath(fl_gc);
        src+=delta;
      }
    }
    delete[] tmpBuf;
  }
  else
  {
    for ( int i=0; i<H; i++ )
    {
      const uchar *src = buf+i*linedelta;
      for ( int j=0; j<W; j++ )
      {
        if ( mono )
          fl_color( src[0], src[0], src[0] );
        else
          fl_color( src[0], src[1], src[2] );
        CGContextMoveToPoint(fl_gc, X+j, Y+i);
        CGContextAddLineToPoint(fl_gc, X+j, Y+i);
        CGContextStrokePath(fl_gc);
        src += delta;
      }
    }
  }
  CGContextSetShouldAntialias(fl_gc, true);
}

void Fl_Quartz_Graphics_Driver::draw_image(const uchar* buf, int x, int y, int w, int h, int d, int l){
  innards(buf,x,y,w,h,d,l,(d<3&&d>-3),0,0);
}
void Fl_Quartz_Graphics_Driver::draw_image(Fl_Draw_Image_Cb cb, void* data,
		   int x, int y, int w, int h,int d) {
  innards(0,x,y,w,h,d,0,(d<3&&d>-3),cb,data);
}
void Fl_Quartz_Graphics_Driver::draw_image_mono(const uchar* buf, int x, int y, int w, int h, int d, int l){
  innards(buf,x,y,w,h,d,l,1,0,0);
}
void Fl_Quartz_Graphics_Driver::draw_image_mono(Fl_Draw_Image_Cb cb, void* data,
		   int x, int y, int w, int h,int d) {
  innards(0,x,y,w,h,d,0,1,cb,data);
}

void fl_rectf(int x, int y, int w, int h, uchar r, uchar g, uchar b) {
  fl_color(r,g,b);
  fl_rectf(x,y,w,h);
}

void Fl_Quartz_Graphics_Driver::draw(Fl_Bitmap *bm, int XP, int YP, int WP, int HP, int cx, int cy) {
  int X, Y, W, H;
  if (bm->start(XP, YP, WP, HP, cx, cy, X, Y, W, H)) {
    return;
  }
  if (bm->id_ && fl_gc) {
    CGRect rect = { { (CGFloat)X, (CGFloat)Y }, { (CGFloat)W, (CGFloat)H } };
    Fl_X::q_begin_image(rect, cx, cy, bm->w(), bm->h());
    CGContextDrawImage(fl_gc, rect, (CGImageRef)bm->id_);
    Fl_X::q_end_image();
  }
}

static void imgProviderReleaseData (void *info, const void *data, size_t size)
{
  if (!info || *(bool*)info) delete[] (unsigned char *)data;
  delete (bool*)info;
}

static int start(Fl_RGB_Image *img, int XP, int YP, int WP, int HP, int w, int h, int &cx, int &cy,
                 int &X, int &Y, int &W, int &H)
{
  // account for current clip region (faster on Irix):
  fl_clip_box(XP,YP,WP,HP,X,Y,W,H);
  cx += X-XP; cy += Y-YP;
  // clip the box down to the size of image, quit if empty:
  if (cx < 0) {W += cx; X -= cx; cx = 0;}
  if (cx+W > w) W = w-cx;
  if (W <= 0) return 1;
  if (cy < 0) {H += cy; Y -= cy; cy = 0;}
  if (cy+H > h) H = h-cy;
  if (H <= 0) return 1;
  return 0;
}

void Fl_Quartz_Graphics_Driver::draw(Fl_RGB_Image *img, int XP, int YP, int WP, int HP, int cx, int cy) {
  int X, Y, W, H;
  // Don't draw an empty image...
  if (!img->d() || !img->array) {
    img->draw_empty(XP, YP);
    return;
  }
  if (start(img, XP, YP, WP, HP, img->w(), img->h(), cx, cy, X, Y, W, H)) {
    return;
  }
  if (!img->id_) {
    CGColorSpaceRef lut = img->d()<=2 ? CGColorSpaceCreateDeviceGray() : CGColorSpaceCreateDeviceRGB();
    int ld = img->ld();
    if (!ld) ld = img->w() * img->d();
    // If img->alloc_array == 0, the CGImage data provider must not release the image data.
    // If img->alloc_array != 0, the CGImage data provider will take responsibilty of deleting RGB image data after use:
    // when the CGImage is deallocated, the release callback of its data provider
    // (imgProviderReleaseData) is called and can delete the RGB image data.
    // If the CGImage is printed, it is not deallocated until after the end of the page,
    // therefore, with img->alloc_array != 0, the RGB image can be safely deleted any time after return from this function.
    // The previously unused mask_ member allows to make sure the RGB image data is not deleted by Fl_RGB_Image::uncache().
    if (img->alloc_array) img->mask_ = new bool(true);
    CGDataProviderRef src = CGDataProviderCreateWithData(img->mask_, img->array, ld * img->h(),
                                                         img->alloc_array?imgProviderReleaseData:NULL);
    img->id_ = CGImageCreate(img->w(), img->h(), 8, img->d()*8, ld,
                             lut, (img->d()&1)?kCGImageAlphaNone:kCGImageAlphaLast,
                             src, 0L, false, kCGRenderingIntentDefault);
    CGColorSpaceRelease(lut);
    CGDataProviderRelease(src);
  }
  if (img->id_ && fl_gc) {
    if (!img->alloc_array && has_feature(PRINTER) && !CGImageGetShouldInterpolate((CGImageRef)img->id_)) {
      // When printing, the image data is used when the page is completed, that is, after return from this function.
      // If the image has alloc_array = 0, we must protect against image data being freed before it is used:
      // we duplicate the image data and have it deleted after use by the release-callback of the CGImage data provider
      Fl_RGB_Image* img2 = (Fl_RGB_Image*)img->copy();
      img2->alloc_array = 0;
      const uchar *img_bytes = img2->array;
      int ld = img2->ld();
      if (!ld) ld = img2->w() * img2->d();
      delete img2;
      img->uncache();
      CGColorSpaceRef lut = img->d()<=2 ? CGColorSpaceCreateDeviceGray() : CGColorSpaceCreateDeviceRGB();
      CGDataProviderRef src = CGDataProviderCreateWithData( NULL, img_bytes, ld * img->h(), imgProviderReleaseData);
      img->id_ = CGImageCreate(img->w(), img->h(), 8, img->d()*8, ld,
                               lut, (img->d()&1)?kCGImageAlphaNone:kCGImageAlphaLast,
                               src, 0L, true, kCGRenderingIntentDefault);
      CGColorSpaceRelease(lut);
      CGDataProviderRelease(src);
    }
    CGRect rect = CGRectMake(X, Y, W, H);
    Fl_X::q_begin_image(rect, cx, cy, img->w(), img->h());
    CGContextDrawImage(fl_gc, rect, (CGImageRef)img->id_);
    Fl_X::q_end_image();
  }
}

int Fl_Quartz_Graphics_Driver::draw_scaled(Fl_Image *img, int XP, int YP, int WP, int HP) {
  int X, Y, W, H;
  fl_clip_box(XP,YP,WP,HP,X,Y,W,H); // X,Y,W,H will give the unclipped area of XP,YP,WP,HP
  if (W == 0 || H == 0) return 1;
  fl_push_no_clip(); // remove the FLTK clip that can't be rescaled
  CGContextSaveGState(fl_gc);
  CGContextClipToRect(fl_gc, CGRectMake(X, Y, W, H)); // this clip path will be rescaled & translated
  CGContextTranslateCTM(fl_gc, XP, YP);
  CGContextScaleCTM(fl_gc, float(WP)/img->w(), float(HP)/img->h());
  img->draw(0, 0, img->w(), img->h(), 0, 0);
  CGContextRestoreGState(fl_gc);
  fl_pop_clip(); // restore FLTK's clip
  return 1;
}

void Fl_Quartz_Graphics_Driver::draw(Fl_Pixmap *pxm, int XP, int YP, int WP, int HP, int cx, int cy) {
  int X, Y, W, H;
  if (pxm->prepare(XP, YP, WP, HP, cx, cy, X, Y, W, H)) return;
  copy_offscreen(X, Y, W, H, (Fl_Offscreen)pxm->id_, cx, cy);
}

Fl_Bitmask Fl_Quartz_Graphics_Driver::create_bitmask(int w, int h, const uchar *array) {
  static uchar reverse[16] =    /* Bit reversal lookup table */
  { 0x00, 0x88, 0x44, 0xcc, 0x22, 0xaa, 0x66, 0xee,
    0x11, 0x99, 0x55, 0xdd, 0x33, 0xbb, 0x77, 0xff };
  int rowBytes = (w+7)>>3 ;
  uchar *bmask = (uchar*)malloc(rowBytes*h), *dst = bmask;
  const uchar *src = array;
  for ( int i=rowBytes*h; i>0; i--,src++ ) {
    *dst++ = ((reverse[*src & 0x0f] & 0xf0) | (reverse[(*src >> 4) & 0x0f] & 0x0f))^0xff;
  }
  CGDataProviderRef srcp = CGDataProviderCreateWithData( 0L, bmask, rowBytes*h, 0L);
  CGImageRef id_ = CGImageMaskCreate( w, h, 1, 1, rowBytes, srcp, 0L, false);
  CGDataProviderRelease(srcp);
  return (Fl_Bitmask)id_;
}

void Fl_Quartz_Graphics_Driver::delete_bitmask(Fl_Bitmask bm) {
  if (bm) CGImageRelease((CGImageRef)bm);
}



#endif // FL_CFG_GFX_QUARTZ

//
// End of "$Id$".
//