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[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [services/] [gfx/] [mw/] [v2_0/] [src/] [engine/] [devdraw.c] - Rev 174
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/* * Copyright (c) 1999, 2000, 2001 Greg Haerr <greg@censoft.com> * Portions Copyright (c) 1991 David I. Bell * Permission is granted to use, distribute, or modify this source, * provided that this copyright notice remains intact. * * Device-independent mid level drawing and color routines. * * These routines do the necessary range checking, clipping, and cursor * overwriting checks, and then call the lower level device dependent * routines to actually do the drawing. The lower level routines are * only called when it is known that all the pixels to be drawn are * within the device area and are visible. */ /*#define NDEBUG*/ #include <stdio.h> #include <stdlib.h> #include <assert.h> #include "device.h" extern MWPIXELVAL gr_foreground; /* current foreground color */ extern MWPIXELVAL gr_background; /* current background color */ extern MWBOOL gr_usebg; /* TRUE if background drawn in pixmaps */ extern int gr_mode; /* drawing mode */ extern MWPALENTRY gr_palette[256]; /* current palette*/ extern int gr_firstuserpalentry;/* first user-changable palette entry*/ extern int gr_nextpalentry; /* next available palette entry*/ /*static*/ void drawpoint(PSD psd,MWCOORD x, MWCOORD y); /*static*/ void drawrow(PSD psd,MWCOORD x1,MWCOORD x2,MWCOORD y); static void drawcol(PSD psd,MWCOORD x,MWCOORD y1,MWCOORD y2); /* * Set the drawing mode for future calls. */ int GdSetMode(int mode) { int oldmode = gr_mode; gr_mode = mode; return oldmode; } /* * Set whether or not the background is used for drawing pixmaps and text. */ MWBOOL GdSetUseBackground(MWBOOL flag) { MWBOOL oldusebg = gr_usebg; gr_usebg = flag; return oldusebg; } /* * Set the foreground color for drawing. */ MWPIXELVAL GdSetForeground(MWPIXELVAL fg) { MWPIXELVAL oldfg = gr_foreground; gr_foreground = fg; return oldfg; } /* * Set the background color for bitmap and text backgrounds. */ MWPIXELVAL GdSetBackground(MWPIXELVAL bg) { MWPIXELVAL oldbg = gr_background; gr_background = bg; return oldbg; } /* * Draw a point using the current clipping region and foreground color. */ void GdPoint(PSD psd, MWCOORD x, MWCOORD y) { if (GdClipPoint(psd, x, y)) { psd->DrawPixel(psd, x, y, gr_foreground); GdFixCursor(psd); } } /* * Draw an arbitrary line using the current clipping region and foreground color * If bDrawLastPoint is FALSE, draw up to but not including point x2, y2. * * This routine is the only routine that adjusts coordinates for supporting * two different types of upper levels, those that draw the last point * in a line, and those that draw up to the last point. All other local * routines draw the last point. This gives this routine a bit more overhead, * but keeps overall complexity down. */ void GdLine(PSD psd, MWCOORD x1, MWCOORD y1, MWCOORD x2, MWCOORD y2, MWBOOL bDrawLastPoint) { int xdelta; /* width of rectangle around line */ int ydelta; /* height of rectangle around line */ int xinc; /* increment for moving x coordinate */ int yinc; /* increment for moving y coordinate */ int rem; /* current remainder */ MWCOORD temp; /* See if the line is horizontal or vertical. If so, then call * special routines. */ if (y1 == y2) { /* * Adjust coordinates if not drawing last point. Tricky. */ if(!bDrawLastPoint) { if (x1 > x2) { temp = x1; x1 = x2 + 1; x2 = temp; } else --x2; } /* call faster line drawing routine*/ drawrow(psd, x1, x2, y1); GdFixCursor(psd); return; } if (x1 == x2) { /* * Adjust coordinates if not drawing last point. Tricky. */ if(!bDrawLastPoint) { if (y1 > y2) { temp = y1; y1 = y2 + 1; y2 = temp; } else --y2; } /* call faster line drawing routine*/ drawcol(psd, x1, y1, y2); GdFixCursor(psd); return; } /* See if the line is either totally visible or totally invisible. If * so, then the line drawing is easy. */ switch (GdClipArea(psd, x1, y1, x2, y2)) { case CLIP_VISIBLE: /* * For size considerations, there's no low-level bresenham * line draw, so we've got to draw all non-vertical * and non-horizontal lines with per-point * clipping for the time being psd->Line(psd, x1, y1, x2, y2, gr_foreground); GdFixCursor(psd); return; */ break; case CLIP_INVISIBLE: return; } /* The line may be partially obscured. Do the draw line algorithm * checking each point against the clipping regions. */ xdelta = x2 - x1; ydelta = y2 - y1; if (xdelta < 0) xdelta = -xdelta; if (ydelta < 0) ydelta = -ydelta; xinc = (x2 > x1) ? 1 : -1; yinc = (y2 > y1) ? 1 : -1; if (GdClipPoint(psd, x1, y1)) psd->DrawPixel(psd, x1, y1, gr_foreground); if (xdelta >= ydelta) { rem = xdelta / 2; for(;;) { if(!bDrawLastPoint && x1 == x2) break; x1 += xinc; rem += ydelta; if (rem >= xdelta) { rem -= xdelta; y1 += yinc; } if (GdClipPoint(psd, x1, y1)) psd->DrawPixel(psd, x1, y1, gr_foreground); if(bDrawLastPoint && x1 == x2) break; } } else { rem = ydelta / 2; for(;;) { if(!bDrawLastPoint && y1 == y2) break; y1 += yinc; rem += xdelta; if (rem >= ydelta) { rem -= ydelta; x1 += xinc; } if (GdClipPoint(psd, x1, y1)) psd->DrawPixel(psd, x1, y1, gr_foreground); if(bDrawLastPoint && y1 == y2) break; } } GdFixCursor(psd); } /* Draw a point in the foreground color, applying clipping if necessary*/ /*static*/ void drawpoint(PSD psd, MWCOORD x, MWCOORD y) { if (GdClipPoint(psd, x, y)) psd->DrawPixel(psd, x, y, gr_foreground); } /* Draw a horizontal line from x1 to and including x2 in the * foreground color, applying clipping if necessary. */ /*static*/ void drawrow(PSD psd, MWCOORD x1, MWCOORD x2, MWCOORD y) { MWCOORD temp; /* reverse endpoints if necessary*/ if (x1 > x2) { temp = x1; x1 = x2; x2 = temp; } /* clip to physical device*/ if (x1 < 0) x1 = 0; if (x2 >= psd->xvirtres) x2 = psd->xvirtres - 1; /* check cursor intersect once for whole line*/ GdCheckCursor(psd, x1, y, x2, y); while (x1 <= x2) { if (GdClipPoint(psd, x1, y)) { temp = MWMIN(clipmaxx, x2); psd->DrawHorzLine(psd, x1, temp, y, gr_foreground); } else temp = MWMIN(clipmaxx, x2); x1 = temp + 1; } } /* Draw a vertical line from y1 to and including y2 in the * foreground color, applying clipping if necessary. */ static void drawcol(PSD psd, MWCOORD x,MWCOORD y1,MWCOORD y2) { MWCOORD temp; /* reverse endpoints if necessary*/ if (y1 > y2) { temp = y1; y1 = y2; y2 = temp; } /* clip to physical device*/ if (y1 < 0) y1 = 0; if (y2 >= psd->yvirtres) y2 = psd->yvirtres - 1; /* check cursor intersect once for whole line*/ GdCheckCursor(psd, x, y1, x, y2); while (y1 <= y2) { if (GdClipPoint(psd, x, y1)) { temp = MWMIN(clipmaxy, y2); psd->DrawVertLine(psd, x, y1, temp, gr_foreground); } else temp = MWMIN(clipmaxy, y2); y1 = temp + 1; } } /* Draw a rectangle in the foreground color, applying clipping if necessary. * This is careful to not draw points multiple times in case the rectangle * is being drawn using XOR. */ void GdRect(PSD psd, MWCOORD x, MWCOORD y, MWCOORD width, MWCOORD height) { MWCOORD maxx; MWCOORD maxy; if (width <= 0 || height <= 0) return; maxx = x + width - 1; maxy = y + height - 1; drawrow(psd, x, maxx, y); if (height > 1) drawrow(psd, x, maxx, maxy); if (height < 3) return; y++; maxy--; drawcol(psd, x, y, maxy); if (width > 1) drawcol(psd, maxx, y, maxy); GdFixCursor(psd); } /* Draw a filled in rectangle in the foreground color, applying * clipping if necessary. */ void GdFillRect(PSD psd, MWCOORD x1, MWCOORD y1, MWCOORD width, MWCOORD height) { MWCOORD x2 = x1+width-1; MWCOORD y2 = y1+height-1; if (width <= 0 || height <= 0) return; /* See if the rectangle is either totally visible or totally * invisible. If so, then the rectangle drawing is easy. */ switch (GdClipArea(psd, x1, y1, x2, y2)) { case CLIP_VISIBLE: psd->FillRect(psd, x1, y1, x2, y2, gr_foreground); GdFixCursor(psd); return; case CLIP_INVISIBLE: return; } /* The rectangle may be partially obstructed. So do it line by line. */ while (y1 <= y2) drawrow(psd, x1, x2, y1++); GdFixCursor(psd); } /* * Draw a rectangular area using the current clipping region and the * specified bit map. This differs from rectangle drawing in that the * rectangle is drawn using the foreground color and possibly the background * color as determined by the bit map. Each row of bits is aligned to the * next bitmap word boundary (so there is padding at the end of the row). * The background bit values are only written if the gr_usebg flag * is set. */ void GdBitmap(PSD psd, MWCOORD x, MWCOORD y, MWCOORD width, MWCOORD height, MWIMAGEBITS *imagebits) { MWCOORD minx; MWCOORD maxx; MWPIXELVAL savecolor; /* saved foreground color */ MWIMAGEBITS bitvalue = 0; /* bitmap word value */ int bitcount; /* number of bits left in bitmap word */ switch (GdClipArea(psd, x, y, x + width - 1, y + height - 1)) { case CLIP_VISIBLE: /* * For size considerations, there's no low-level bitmap * draw so we've got to draw everything with per-point * clipping for the time being. if (gr_usebg) psd->FillRect(psd, x, y, x + width - 1, y + height - 1, gr_background); psd->DrawBitmap(psd, x, y, width, height, imagebits, gr_foreground); return; */ break; case CLIP_INVISIBLE: return; } /* The rectangle is partially visible, so must do clipping. First * fill a rectangle in the background color if necessary. */ if (gr_usebg) { savecolor = gr_foreground; gr_foreground = gr_background; /* note: change to fillrect*/ GdFillRect(psd, x, y, width, height); gr_foreground = savecolor; } minx = x; maxx = x + width - 1; bitcount = 0; while (height > 0) { if (bitcount <= 0) { bitcount = MWIMAGE_BITSPERIMAGE; bitvalue = *imagebits++; } if (MWIMAGE_TESTBIT(bitvalue) && GdClipPoint(psd, x, y)) psd->DrawPixel(psd, x, y, gr_foreground); bitvalue = MWIMAGE_SHIFTBIT(bitvalue); bitcount--; if (x++ == maxx) { x = minx; y++; height--; bitcount = 0; } } GdFixCursor(psd); } /* * Return true if color is in palette */ MWBOOL GdColorInPalette(MWCOLORVAL cr,MWPALENTRY *palette,int palsize) { int i; for(i=0; i<palsize; ++i) if(GETPALENTRY(palette, i) == cr) return TRUE; return FALSE; } /* * Create a MWPIXELVAL conversion table between the passed palette * and the in-use palette. The system palette is loaded/merged according * to fLoadType. */ void GdMakePaletteConversionTable(PSD psd,MWPALENTRY *palette,int palsize, MWPIXELVAL *convtable,int fLoadType) { int i; MWCOLORVAL cr; int newsize, nextentry; MWPALENTRY newpal[256]; /* * Check for load palette completely, or add colors * from passed palette to system palette until full. */ if(psd->pixtype == MWPF_PALETTE) { switch(fLoadType) { case LOADPALETTE: /* Load palette from beginning with image's palette. * First palette entries are Microwindows colors * and not changed. */ GdSetPalette(psd, gr_firstuserpalentry, palsize, palette); break; case MERGEPALETTE: /* get system palette*/ for(i=0; i<(int)psd->ncolors; ++i) newpal[i] = gr_palette[i]; /* merge passed palette into system palette*/ newsize = 0; nextentry = gr_nextpalentry; /* if color missing and there's room, add it*/ for(i=0; i<palsize && nextentry < (int)psd->ncolors; ++i) { cr = GETPALENTRY(palette, i); if(!GdColorInPalette(cr, newpal, nextentry)) { newpal[nextentry++] = palette[i]; ++newsize; } } /* set the new palette if any color was added*/ if(newsize) { GdSetPalette(psd, gr_nextpalentry, newsize, &newpal[gr_nextpalentry]); gr_nextpalentry += newsize; } break; } } /* * Build conversion table from inuse system palette and * passed palette. This will load RGB values directly * if running truecolor, otherwise it will find the * nearest color from the inuse palette. * FIXME: tag the conversion table to the bitmap image */ for(i=0; i<palsize; ++i) { cr = GETPALENTRY(palette, i); convtable[i] = GdFindColor(cr); } } /* * Draw a color bitmap image in 1, 4, 8, 24 or 32 bits per pixel. The * Microwindows color image format is DWORD padded bytes, with * the upper bits corresponding to the left side (identical to * the MS Windows format). This format is currently different * than the MWIMAGEBITS format, which uses word-padded bits * for monochrome display only, where the upper bits in the word * correspond with the left side. */ void GdDrawImage(PSD psd, MWCOORD x, MWCOORD y, PMWIMAGEHDR pimage) { MWCOORD minx; MWCOORD maxx; MWUCHAR bitvalue = 0; int bitcount; MWUCHAR *imagebits; MWCOORD height, width; MWPIXELVAL pixel; int clip; int extra, linesize; int rgborder; MWCOLORVAL cr; MWCOORD yoff; unsigned long transcolor; MWPIXELVAL convtable[256]; height = pimage->height; width = pimage->width; /* determine if entire image is clipped out, save clipresult for later*/ clip = GdClipArea(psd, x, y, x + width - 1, y + height - 1); if(clip == CLIP_INVISIBLE) return; transcolor = pimage->transcolor; /* * Merge the images's palette and build a palette index conversion table. */ if (pimage->bpp <= 8) { if(!pimage->palette) { /* for jpeg's without a palette*/ for(yoff=0; yoff<pimage->palsize; ++yoff) convtable[yoff] = yoff; } else GdMakePaletteConversionTable(psd, pimage->palette, pimage->palsize, convtable, MERGEPALETTE); /* The following is no longer used. One reason is that it required */ /* the transparent color to be unique, which was unnessecary */ /* convert transcolor to converted palette index for speed*/ /* if (transcolor != -1L) transcolor = (unsigned long) convtable[transcolor]; */ } minx = x; maxx = x + width - 1; imagebits = pimage->imagebits; /* check for bottom-up image*/ if(pimage->compression & MWIMAGE_UPSIDEDOWN) { y += height - 1; yoff = -1; } else yoff = 1; #define PIX2BYTES(n) (((n)+7)/8) /* imagebits are dword aligned*/ switch(pimage->bpp) { default: case 8: linesize = width; break; case 32: linesize = width*4; break; case 24: linesize = width*3; break; case 4: linesize = PIX2BYTES(width<<2); break; case 1: linesize = PIX2BYTES(width); break; } extra = pimage->pitch - linesize; /* 24bpp RGB rather than BGR byte order?*/ rgborder = pimage->compression & MWIMAGE_RGB; bitcount = 0; while(height > 0) { unsigned long trans = 0; if (bitcount <= 0) { bitcount = sizeof(MWUCHAR) * 8; bitvalue = *imagebits++; } switch(pimage->bpp) { case 24: case 32: cr = rgborder? MWRGB(bitvalue, imagebits[0], imagebits[1]): MWRGB(imagebits[1], imagebits[0], bitvalue); /* Include the upper bits for transcolor stuff */ if (imagebits[2]) /* FIXME: 24bpp error*/ trans = cr | 0x01000000L; if (pimage->bpp == 32) imagebits += 3; else imagebits += 2; bitcount = 0; /* handle transparent color*/ if (transcolor == trans) goto next; switch(psd->pixtype) { case MWPF_PALETTE: default: pixel = GdFindColor(cr); break; case MWPF_TRUECOLOR0888: case MWPF_TRUECOLOR888: pixel = COLOR2PIXEL888(cr); break; case MWPF_TRUECOLOR565: pixel = COLOR2PIXEL565(cr); break; case MWPF_TRUECOLOR555: pixel = COLOR2PIXEL555(cr); break; case MWPF_TRUECOLOR332: pixel = COLOR2PIXEL332(cr); break; } break; default: case 8: bitcount = 0; if (bitvalue == transcolor) goto next; pixel = convtable[bitvalue]; break; case 4: if (((bitvalue & 0xf0) >> 4) == transcolor) { bitvalue <<= 4; bitcount -= 4; goto next; } pixel = convtable[(bitvalue & 0xf0) >> 4]; bitvalue <<= 4; bitcount -= 4; break; case 1: --bitcount; if (((bitvalue & 0x80) ? 1 : 0) == transcolor) { bitvalue <<= 1; goto next; } pixel = convtable[(bitvalue & 0x80)? 1: 0]; bitvalue <<= 1; break; } /* if((unsigned long)pixel != transcolor &&*/ if (clip == CLIP_VISIBLE || GdClipPoint(psd, x, y)) psd->DrawPixel(psd, x, y, pixel); #if 0 /* fix: use clipmaxx to clip quicker*/ else if(clip != CLIP_VISIBLE && !clipresult && x > clipmaxx) { x = maxx; } #endif next: if(x++ == maxx) { x = minx; y += yoff; height--; bitcount = 0; imagebits += extra; } } GdFixCursor(psd); } /* * Read a rectangular area of the screen. * The color table is indexed row by row. */ void GdReadArea(PSD psd, MWCOORD x, MWCOORD y, MWCOORD width, MWCOORD height, MWPIXELVAL *pixels) { MWCOORD row; MWCOORD col; if (width <= 0 || height <= 0) return; GdCheckCursor(psd, x, y, x+width-1, y+height-1); for (row = y; row < height+y; row++) for (col = x; col < width+x; col++) if (row < 0 || row >= psd->yvirtres || col < 0 || col >= psd->xvirtres) *pixels++ = 0; else *pixels++ = psd->ReadPixel(psd, col, row); GdFixCursor(psd); } /* Draw a rectangle of color values, clipping if necessary. * If a color matches the background color, * then that pixel is only drawn if the gr_usebg flag is set. * * The pixels are packed according to pixtype: * * pixtype array of * MWPF_RGB MWCOLORVAL (unsigned long) * MWPF_PIXELVAL MWPIXELVAL (compile-time dependent) * MWPF_PALETTE unsigned char * MWPF_TRUECOLOR0888 unsigned long * MWPF_TRUECOLOR888 packed struct {char r,char g,char b} (24 bits) * MWPF_TRUECOLOR565 unsigned short * MWPF_TRUECOLOR555 unsigned short * MWPF_TRUECOLOR332 unsigned char * * NOTE: Currently, no translation is performed if the pixtype * is not MWPF_RGB. Pixtype is only then used to determine the * packed size of the pixel data, and is then stored unmodified * in a MWPIXELVAL and passed to the screen driver. Virtually, * this means there's only three reasonable options for client * programs: (1) pass all data as RGB MWCOLORVALs, (2) pass * data as unpacked 32-bit MWPIXELVALs in the format the current * screen driver is running, or (3) pass data as packed values * in the format the screen driver is running. Options 2 and 3 * are identical except for the packing structure. */ void GdArea(PSD psd, MWCOORD x, MWCOORD y, MWCOORD width, MWCOORD height, void *pixels, int pixtype) { unsigned char *PIXELS = pixels; /* for ANSI compilers, can't use void*/ long cellstodo; /* remaining number of cells */ long count; /* number of cells of same color */ long cc; /* current cell count */ long rows; /* number of complete rows */ MWCOORD minx; /* minimum x value */ MWCOORD maxx; /* maximum x value */ MWPIXELVAL savecolor; /* saved foreground color */ MWBOOL dodraw; /* TRUE if draw these points */ MWCOLORVAL rgbcolor = 0L; int pixsize; unsigned char r, g, b; minx = x; maxx = x + width - 1; /* Set up area clipping, and just return if nothing is visible */ if ( GdClipArea(psd, minx, y, maxx, y + height - 1) == CLIP_INVISIBLE ) return; /* psd->DrawArea driver call temp removed, doesn't work with new blit routines*/ #if 0000 { driver_gc_t hwgc; int px1, px2, py1, py2, pw, ph, rx1, rx2, ry1, ry2; #if DYNAMICREGIONS MWRECT *prc; extern MWCLIPREGION *clipregion; #else MWCLIPRECT *prc; extern MWCLIPRECT cliprects[]; extern int clipcount; #endif #if HAVE_T1LIB_SUPPORT | HAVE_FREETYPE_SUPPORT /* can't use drawarea driver in 16 bpp mode yet with font routines*/ goto fallback; #endif if ( !(psd->flags & PSF_HAVEOP_COPY) ) goto fallback; #if DYNAMICREGIONS prc = clipregion->rects; count = clipregion->numRects; #else prc = cliprects; count = clipcount; #endif hwgc.pixels = PIXELS; hwgc.src_linelen = width; hwgc.gr_usebg = gr_usebg; hwgc.bg_color = gr_background; while ( count-- > 0 ) { #if DYNAMICREGIONS rx1 = prc->left; ry1 = prc->top; rx2 = prc->right; ry2 = prc->bottom; #else /* New clip-code by Morten */ rx1 = prc->x; ry1 = prc->y; rx2 = prc->x + prc->width; ry2 = prc->y + prc->height; #endif /* Check if this rect intersects with the one we draw */ px1 = x; py1 = y; px2 = x + width; py2 = y + height; if ( px1 < rx1 ) px1 = rx1; if ( py1 < ry1 ) py1 = ry1; if ( px2 > rx2 ) px2 = rx2; if ( py2 > ry2 ) py2 = ry2; pw = px2 - px1; ph = py2 - py1; if ( pw > 0 && ph > 0 ) { hwgc.dstx = px1; hwgc.dsty = py1; hwgc.dstw = pw; hwgc.dsth = ph; hwgc.srcx = px1 - x; hwgc.srcy = py1 - y; GdCheckCursor(psd,px1,py1,px1+pw-1,py1+ph-1); psd->DrawArea(psd,&hwgc,PSDOP_COPY); } prc++; } GdFixCursor(psd); return; fallback: } #endif /* if 0000 temp removed*/ /* Calculate size of packed pixels*/ switch(pixtype) { case MWPF_RGB: pixsize = sizeof(MWCOLORVAL); break; case MWPF_PIXELVAL: pixsize = sizeof(MWPIXELVAL); break; case MWPF_PALETTE: case MWPF_TRUECOLOR332: pixsize = sizeof(unsigned char); break; case MWPF_TRUECOLOR0888: pixsize = sizeof(unsigned long); break; case MWPF_TRUECOLOR888: pixsize = 3; break; case MWPF_TRUECOLOR565: case MWPF_TRUECOLOR555: pixsize = sizeof(unsigned short); break; default: return; } savecolor = gr_foreground; cellstodo = (long)width * height; while (cellstodo > 0) { /* read the pixel value from the pixtype*/ switch(pixtype) { case MWPF_RGB: rgbcolor = *(MWCOLORVAL *)PIXELS; PIXELS += sizeof(MWCOLORVAL); gr_foreground = GdFindColor(rgbcolor); break; case MWPF_PIXELVAL: gr_foreground = *(MWPIXELVAL *)PIXELS; PIXELS += sizeof(MWPIXELVAL); break; case MWPF_PALETTE: case MWPF_TRUECOLOR332: gr_foreground = *PIXELS++; break; case MWPF_TRUECOLOR0888: gr_foreground = *(unsigned long *)PIXELS; PIXELS += sizeof(unsigned long); break; case MWPF_TRUECOLOR888: r = *PIXELS++; g = *PIXELS++; b = *PIXELS++; gr_foreground = (MWPIXELVAL)MWRGB(r, g, b); break; case MWPF_TRUECOLOR565: case MWPF_TRUECOLOR555: gr_foreground = *(unsigned short *)PIXELS; PIXELS += sizeof(unsigned short); break; } dodraw = (gr_usebg || (gr_foreground != gr_background)); count = 1; --cellstodo; /* See how many of the adjacent remaining points have the * same color as the next point. * * NOTE: Yes, with the addition of the pixel unpacking, * it's almost slower to look ahead than to just draw * the pixel... FIXME */ while (cellstodo > 0) { switch(pixtype) { case MWPF_RGB: if(rgbcolor != *(MWCOLORVAL *)PIXELS) goto breakwhile; PIXELS += sizeof(MWCOLORVAL); break; case MWPF_PIXELVAL: if(gr_foreground != *(MWPIXELVAL *)PIXELS) goto breakwhile; PIXELS += sizeof(MWPIXELVAL); break; case MWPF_PALETTE: case MWPF_TRUECOLOR332: if(gr_foreground != *(unsigned char *)PIXELS) goto breakwhile; ++PIXELS; break; case MWPF_TRUECOLOR0888: if(gr_foreground != *(unsigned long *)PIXELS) goto breakwhile; PIXELS += sizeof(unsigned long); break; case MWPF_TRUECOLOR888: r = *(unsigned char *)PIXELS; g = *(unsigned char *)(PIXELS + 1); b = *(unsigned char *)(PIXELS + 2); if(gr_foreground != (MWPIXELVAL)MWRGB(r, g, b)) goto breakwhile; PIXELS += 3; break; case MWPF_TRUECOLOR565: case MWPF_TRUECOLOR555: if(gr_foreground != *(unsigned short *)PIXELS) goto breakwhile; PIXELS += sizeof(unsigned short); break; } ++count; --cellstodo; } breakwhile: /* If there is only one point with this color, then draw it * by itself. */ if (count == 1) { if (dodraw) drawpoint(psd, x, y); if (++x > maxx) { x = minx; y++; } continue; } /* There are multiple points with the same color. If we are * not at the start of a row of the rectangle, then draw this * first row specially. */ if (x != minx) { cc = count; if (x + cc - 1 > maxx) cc = maxx - x + 1; if (dodraw) drawrow(psd, x, x + cc - 1, y); count -= cc; x += cc; if (x > maxx) { x = minx; y++; } } /* Now the x value is at the beginning of a row if there are * any points left to be drawn. Draw all the complete rows * with one call. */ rows = count / width; if (rows > 0) { if (dodraw) { /* note: change to fillrect, (parm types changed)*/ /*GdFillRect(psd, x, y, maxx, y + rows - 1);*/ GdFillRect(psd, x, y, maxx - x + 1, rows); } count %= width; y += rows; } /* If there is a final partial row of pixels left to be * drawn, then do that. */ if (count > 0) { if (dodraw) drawrow(psd, x, x + count - 1, y); x += count; } } gr_foreground = savecolor; GdFixCursor(psd); } #if NOTYET /* Copy a rectangular area from one screen area to another. * This bypasses clipping. */ void GdCopyArea(PSD psd, MWCOORD srcx, MWCOORD srcy, MWCOORD width, MWCOORD height, MWCOORD destx, MWCOORD desty) { if (width <= 0 || height <= 0) return; if (srcx == destx && srcy == desty) return; GdCheckCursor(psd, srcx, srcy, srcx + width - 1, srcy + height - 1); GdCheckCursor(psd, destx, desty, destx + width - 1, desty + height - 1); psd->CopyArea(psd, srcx, srcy, width, height, destx, desty); GdFixCursor(psd); } #endif /* Copy source rectangle of pixels to destination rectangle quickly*/ void GdBlit(PSD dstpsd, MWCOORD dstx, MWCOORD dsty, MWCOORD width, MWCOORD height, PSD srcpsd, MWCOORD srcx, MWCOORD srcy, long rop) { int rx1, rx2, ry1, ry2; int px1, px2, py1, py2; int pw, ph; int count; #if DYNAMICREGIONS MWRECT * prc; extern MWCLIPREGION *clipregion; #else MWCLIPRECT * prc; extern MWCLIPRECT cliprects[]; extern int clipcount; #endif /*FIXME: compare bpp's and convert if necessary*/ assert(dstpsd->planes == srcpsd->planes); assert(dstpsd->bpp == srcpsd->bpp); /* temporary assert() until rotation blits completed*/ assert(dstpsd->portrait == srcpsd->portrait); /* clip blit rectangle to source screen/bitmap size*/ /* we must do this because there isn't any source clipping setup*/ if(srcx < 0) { width += srcx; dstx -= srcx; srcx = 0; } if(srcy < 0) { height += srcy; dsty -= srcy; srcy = 0; } if(srcx+width > srcpsd->xvirtres) width = srcpsd->xvirtres - srcx; if(srcy+height > srcpsd->yvirtres) height = srcpsd->yvirtres - srcy; switch(GdClipArea(dstpsd, dstx, dsty, dstx+width-1, dsty+height-1)) { case CLIP_VISIBLE: /* check cursor in src region*/ GdCheckCursor(dstpsd, srcx, srcy, srcx+width-1, srcy+height-1); dstpsd->Blit(dstpsd, dstx, dsty, width, height, srcpsd, srcx, srcy, rop); GdFixCursor(dstpsd); return; case CLIP_INVISIBLE: return; } /* Partly clipped, we'll blit using destination clip * rectangles, and offset the blit accordingly. * Since the destination is already clipped, we * only need to clip the source here. */ #if DYNAMICREGIONS prc = clipregion->rects; count = clipregion->numRects; #else prc = cliprects; count = clipcount; #endif while(--count >= 0) { #if DYNAMICREGIONS rx1 = prc->left; ry1 = prc->top; rx2 = prc->right; ry2 = prc->bottom; #else rx1 = prc->x; ry1 = prc->y; rx2 = prc->x + prc->width; ry2 = prc->y + prc->height; #endif /* Check: does this rect intersect the one we want to draw? */ px1 = dstx; py1 = dsty; px2 = dstx + width; py2 = dsty + height; if (px1 < rx1) px1 = rx1; if (py1 < ry1) py1 = ry1; if (px2 > rx2) px2 = rx2; if (py2 > ry2) py2 = ry2; pw = px2 - px1; ph = py2 - py1; if(pw > 0 && ph > 0) { /* check cursor in dest and src regions*/ GdCheckCursor(dstpsd, px1, py1, px2-1, py2-1); GdCheckCursor(dstpsd, srcx, srcy, srcx+width, srcy+height); dstpsd->Blit(dstpsd, px1, py1, pw, ph, srcpsd, srcx + (px1-dstx), srcy + (py1-dsty), rop); } ++prc; } GdFixCursor(dstpsd); } /* experimental globals for ratio bug when src != 0*/ int g_row_inc, g_col_inc; /* Stretch source rectangle of pixels to destination rectangle quickly*/ void GdStretchBlit(PSD dstpsd, MWCOORD dstx, MWCOORD dsty, MWCOORD dstw, MWCOORD dsth, PSD srcpsd, MWCOORD srcx, MWCOORD srcy, MWCOORD srcw, MWCOORD srch, long rop) { int count; #if DYNAMICREGIONS MWRECT * prc; extern MWCLIPREGION *clipregion; #else MWCLIPRECT * prc; extern MWCLIPRECT cliprects[]; extern int clipcount; #endif g_row_inc = g_col_inc = 0; /* check for driver stretch blit implementation*/ if (!dstpsd->StretchBlit) return; /*FIXME: compare bpp's and convert if necessary*/ assert(dstpsd->planes == srcpsd->planes); assert(dstpsd->bpp == srcpsd->bpp); /* clip blit rectangle to source screen/bitmap size*/ /* we must do this because there isn't any source clipping setup*/ if(srcx < 0) { srcw += srcx; /*dstx -= srcx;*/ srcx = 0; } if(srcy < 0) { srch += srcy; /*dsty -= srcy;*/ srcy = 0; } if(srcx+srcw > srcpsd->xvirtres) srcw = srcpsd->xvirtres - srcx; if(srcy+srch > srcpsd->yvirtres) srch = srcpsd->yvirtres - srcy; /* temp dest clipping for partially visible case*/ if(dstx+dstw > dstpsd->xvirtres) dstw = dstpsd->xvirtres - dstx; if(dsty+dsth > dstpsd->yvirtres) dsth = dstpsd->yvirtres - dsty; switch(GdClipArea(dstpsd, dstx, dsty, dstx+dstw-1, dsty+dsth-1)) { case CLIP_VISIBLE: /* check cursor in src region*/ GdCheckCursor(dstpsd, srcx, srcy, srcx+srcw-1, srcy+srch-1); dstpsd->StretchBlit(dstpsd, dstx, dsty, dstw, dsth, srcpsd, srcx, srcy, srcw, srch, rop); GdFixCursor(dstpsd); return; case CLIP_INVISIBLE: return; } /* Partly clipped, we'll blit using destination clip * rectangles, and offset the blit accordingly. * Since the destination is already clipped, we * only need to clip the source here. */ #if DYNAMICREGIONS prc = clipregion->rects; count = clipregion->numRects; #else prc = cliprects; count = clipcount; #endif while(--count >= 0) { int rx1, rx2, ry1, ry2; int px1, px2, py1, py2; int pw, ph; int sx, sy, sw, sh; #if DYNAMICREGIONS rx1 = prc->left; ry1 = prc->top; rx2 = prc->right; ry2 = prc->bottom; #else rx1 = prc->x; ry1 = prc->y; rx2 = prc->x + prc->width; ry2 = prc->y + prc->height; #endif /* Check: does this rect intersect the one we want to draw? */ px1 = dstx; py1 = dsty; px2 = dstx + dstw; py2 = dsty + dsth; if (px1 < rx1) px1 = rx1; if (py1 < ry1) py1 = ry1; if (px2 > rx2) px2 = rx2; if (py2 > ry2) py2 = ry2; pw = px2 - px1; ph = py2 - py1; if(pw > 0 && ph > 0) { /* calc proper src/dst offset for stretch rect*/ g_row_inc = (srch << 16) / dsth; g_col_inc = (srcw << 16) / dstw; sw = pw * srcw / dstw; sh = ph * srch / dsth; if (sw > 0 && sh > 0) { sx = srcx + (px1-dstx) * srcw / dstw; sy = srcy + (py1-dsty) * srch / dsth; /*printf("P %d,%d,%d,%d %d,%d\n", sx, sy, sw, sh, g_row_inc, g_col_inc);*/ /* check cursor in dest and src regions*/ GdCheckCursor(dstpsd, px1, py1, px2-1, py2-1); GdCheckCursor(dstpsd, srcx, srcy, srcx+srcw, srcy+srch); dstpsd->StretchBlit(dstpsd, px1, py1, pw, ph, srcpsd, sx, sy, sw, sh, rop); } } ++prc; } GdFixCursor(dstpsd); } /* * Calculate size and linelen of memory gc. * If bpp or planes is 0, use passed psd's bpp/planes. * Note: linelen is calculated to be DWORD aligned for speed * for bpp <= 8. Linelen is converted to bytelen for bpp > 8. */ int GdCalcMemGCAlloc(PSD psd, unsigned int width, unsigned int height, int planes, int bpp, int *psize, int *plinelen) { int bytelen, linelen, tmp; if(!planes) planes = psd->planes; if(!bpp) bpp = psd->bpp; /* * swap width and height in left/right portrait modes, * so imagesize is calculated properly */ if(psd->portrait & (MWPORTRAIT_LEFT|MWPORTRAIT_RIGHT)) { tmp = width; width = height; height = tmp; } /* * use bpp and planes to create size and linelen. * linelen is in bytes for bpp 1, 2, 4, 8, and pixels for bpp 16,24,32. */ if(planes == 1) { switch(bpp) { case 1: linelen = (width+7)/8; bytelen = linelen = (linelen+3) & ~3; break; case 2: linelen = (width+3)/4; bytelen = linelen = (linelen+3) & ~3; break; case 4: linelen = (width+1)/2; bytelen = linelen = (linelen+3) & ~3; break; case 8: bytelen = linelen = (width+3) & ~3; break; case 16: linelen = width; bytelen = width * 2; break; case 24: linelen = width; bytelen = width * 3; break; case 32: linelen = width; bytelen = width * 4; break; default: return 0; } } else if(planes == 4) { /* FIXME assumes VGA 4 planes 4bpp*/ /* we use 4bpp linear for memdc format*/ linelen = (width+1)/2; linelen = (linelen+3) & ~3; bytelen = linelen; } else { *psize = *plinelen = 0; return 0; } *plinelen = linelen; *psize = bytelen * height; return 1; } /* Translate a rectangle of color values * * The pixels are packed according to inpixtype/outpixtype: * * pixtype array of * MWPF_RGB MWCOLORVAL (unsigned long) * MWPF_PIXELVAL MWPIXELVAL (compile-time dependent) * MWPF_PALETTE unsigned char * MWPF_TRUECOLOR0888 unsigned long * MWPF_TRUECOLOR888 packed struct {char r,char g,char b} (24 bits) * MWPF_TRUECOLOR565 unsigned short * MWPF_TRUECOLOR555 unsigned short * MWPF_TRUECOLOR332 unsigned char */ void GdTranslateArea(MWCOORD width, MWCOORD height, void *in, int inpixtype, MWCOORD inpitch, void *out, int outpixtype, int outpitch) { unsigned char * inbuf = in; unsigned char * outbuf = out; unsigned long pixelval; MWCOLORVAL colorval; MWCOORD x, y; unsigned char r, g, b; extern MWPALENTRY gr_palette[256]; int gr_palsize = 256; /* FIXME*/ for(y=0; y<height; ++y) { for(x=0; x<width; ++x) { /* read pixel value and convert to BGR colorval (0x00BBGGRR)*/ switch (inpixtype) { case MWPF_RGB: colorval = *(MWCOLORVAL *)inbuf; inbuf += sizeof(MWCOLORVAL); break; case MWPF_PIXELVAL: pixelval = *(MWPIXELVAL *)inbuf; inbuf += sizeof(MWPIXELVAL); /* convert based on compile-time MWPIXEL_FORMAT*/ #if MWPIXEL_FORMAT == MWPF_PALETTE colorval = GETPALENTRY(gr_palette, pixelval); #else colorval = PIXELVALTOCOLORVAL(pixelval); #endif break; case MWPF_PALETTE: pixelval = *inbuf++; colorval = GETPALENTRY(gr_palette, pixelval); break; case MWPF_TRUECOLOR332: pixelval = *inbuf++; colorval = PIXEL332TOCOLORVAL(pixelval); break; case MWPF_TRUECOLOR0888: pixelval = *(unsigned long *)inbuf; colorval = PIXEL888TOCOLORVAL(pixelval); inbuf += sizeof(unsigned long); break; case MWPF_TRUECOLOR888: r = *inbuf++; g = *inbuf++; b = *inbuf++; colorval = (MWPIXELVAL)MWRGB(r, g, b); break; case MWPF_TRUECOLOR565: pixelval = *(unsigned short *)inbuf; colorval = PIXEL565TOCOLORVAL(pixelval); inbuf += sizeof(unsigned short); break; case MWPF_TRUECOLOR555: pixelval = *(unsigned short *)inbuf; colorval = PIXEL555TOCOLORVAL(pixelval); inbuf += sizeof(unsigned short); break; default: return; } /* convert from BGR colorval to desired output pixel format*/ switch (outpixtype) { case MWPF_RGB: *(MWCOLORVAL *)outbuf = colorval; outbuf += sizeof(MWCOLORVAL); break; case MWPF_PIXELVAL: /* convert based on compile-time MWPIXEL_FORMAT*/ #if MWPIXEL_FORMAT == MWPF_PALETTE *(MWPIXELVAL *)outbuf = GdFindNearestColor(gr_palette, gr_palsize, colorval); #else *(MWPIXELVAL *)outbuf = COLORVALTOPIXELVAL(colorval); #endif outbuf += sizeof(MWPIXELVAL); break; case MWPF_PALETTE: *outbuf++ = GdFindNearestColor(gr_palette, gr_palsize, colorval); break; case MWPF_TRUECOLOR332: *outbuf++ = COLOR2PIXEL332(colorval); break; case MWPF_TRUECOLOR0888: *(unsigned long *)outbuf = COLOR2PIXEL888(colorval); outbuf += sizeof(unsigned long); break; case MWPF_TRUECOLOR888: *outbuf++ = REDVALUE(colorval); *outbuf++ = GREENVALUE(colorval); *outbuf++ = BLUEVALUE(colorval); break; case MWPF_TRUECOLOR565: *(unsigned short *)outbuf = COLOR2PIXEL565(colorval); outbuf += sizeof(unsigned short); break; case MWPF_TRUECOLOR555: *(unsigned short *)outbuf = COLOR2PIXEL555(colorval); outbuf += sizeof(unsigned short); break; } } /* adjust line widths, if necessary*/ if(inpitch > width) inbuf += inpitch - width; if(outpitch > width) outbuf += outpitch - width; } }