// // "$Id: fl_draw_pixmap.cxx 7659 2010-07-01 13:21:32Z manolo $" // // Pixmap drawing code for the Fast Light Tool Kit (FLTK). // // Copyright 1998-2009 by Bill Spitzak and others. // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Library General Public // License as published by the Free Software Foundation; either // version 2 of the License, or (at your option) any later version. // // This library 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 // Library General Public License for more details. // // You should have received a copy of the GNU Library General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 // USA. // // Please report all bugs and problems on the following page: // // http://www.fltk.org/str.php // // Implemented without using the xpm library (which I can't use because // it interferes with the color cube used by fl_draw_image). // Current implementation is cheap and slow, and works best on a full-color // display. Transparency is not handled, and colors are dithered to // the color cube. Color index is achieved by adding the id // characters together! Also mallocs a lot of temporary memory! // Notice that there is no pixmap file interface. This is on purpose, // as I want to discourage programs that require support files to work. // All data needed by a program ui should be compiled in!!! #include #include #include #include #include "flstring.h" static int ncolors, chars_per_pixel; /** Get the dimensions of a pixmap. An XPM image contains the dimensions in its data. This function returns te width and height. \param[in] data pointer to XPM image data. \param[out] w,h width and height of image \returns non-zero if the dimensions were parsed OK \returns 0 if there were any problems */ int fl_measure_pixmap(/*const*/ char* const* data, int &w, int &h) { return fl_measure_pixmap((const char*const*)data,w,h); } /** Get the dimensions of a pixmap. \see fl_measure_pixmap(char* const* data, int &w, int &h) */ int fl_measure_pixmap(const char * const *cdata, int &w, int &h) { int i = sscanf(cdata[0],"%d%d%d%d",&w,&h,&ncolors,&chars_per_pixel); if (i<4 || w<=0 || h<=0 || chars_per_pixel!=1 && chars_per_pixel!=2) return w=0; return 1; } #ifdef U64 // The callback from fl_draw_image to get a row of data passes this: struct pixmap_data { int w, h; const uchar*const* data; union { U64 colors[256]; U64* byte1[256]; }; }; // callback for 1 byte per pixel: static void cb1(void*v, int x, int y, int w, uchar* buf) { pixmap_data& d = *(pixmap_data*)v; const uchar* p = d.data[y]+x; U64* q = (U64*)buf; for (int X=w; X>0; X-=2, p += 2) { if (X>1) { # if WORDS_BIGENDIAN *q++ = (d.colors[p[0]]<<32) | d.colors[p[1]]; # else *q++ = (d.colors[p[1]]<<32) | d.colors[p[0]]; # endif } else { # if WORDS_BIGENDIAN *q++ = d.colors[p[0]]<<32; # else *q++ = d.colors[p[0]]; # endif } } } // callback for 2 bytes per pixel: static void cb2(void*v, int x, int y, int w, uchar* buf) { pixmap_data& d = *(pixmap_data*)v; const uchar* p = d.data[y]+2*x; U64* q = (U64*)buf; for (int X=w; X>0; X-=2) { U64* colors = d.byte1[*p++]; int index = *p++; if (X>1) { U64* colors1 = d.byte1[*p++]; int index1 = *p++; # if WORDS_BIGENDIAN *q++ = (colors[index]<<32) | colors1[index1]; # else *q++ = (colors1[index1]<<32) | colors[index]; # endif } else { # if WORDS_BIGENDIAN *q++ = colors[index]<<32; # else *q++ = colors[index]; # endif } } } #else // U32 // The callback from fl_draw_image to get a row of data passes this: struct pixmap_data { int w, h; const uchar*const* data; union { U32 colors[256]; U32* byte1[256]; }; }; // callback for 1 byte per pixel: static void cb1(void*v, int x, int y, int w, uchar* buf) { pixmap_data& d = *(pixmap_data*)v; const uchar* p = d.data[y]+x; U32* q = (U32*)buf; for (int X=w; X--;) *q++ = d.colors[*p++]; } // callback for 2 bytes per pixel: static void cb2(void*v, int x, int y, int w, uchar* buf) { pixmap_data& d = *(pixmap_data*)v; const uchar* p = d.data[y]+2*x; U32* q = (U32*)buf; for (int X=w; X--;) { U32* colors = d.byte1[*p++]; *q++ = colors[*p++]; } } #endif // U64 else U32 uchar **fl_mask_bitmap; // if non-zero, create bitmap and store pointer here /** Draw XPM image data, with the top-left corner at the given position. The image is dithered on 8-bit displays so you won't lose color space for programs displaying both images and pixmaps. \param[in] data pointer to XPM image data \param[in] x,y position of top-left corner \param[in] bg background color \returns 0 if there was any error decoding the XPM data. */ int fl_draw_pixmap(/*const*/ char* const* data, int x,int y,Fl_Color bg) { return fl_draw_pixmap((const char*const*)data,x,y,bg); } #ifdef WIN32 // to compute an unused color to be used for the pixmap background FL_EXPORT UINT win_pixmap_bg_color; // the RGB() of the pixmap background color static int color_count; // # of non-transparent colors used in pixmap static uchar *used_colors; // used_colors[3*i+j] j=0,1,2 are the RGB values of the ith used color static void make_unused_color(uchar &r, uchar &g, uchar &b) // makes an RGB triplet different from all the colors used in the pixmap // and compute win_pixmap_bg_color from this triplet { int i; r = 2; g = 3; b = 4; while (1) { for ( i = 0; i < color_count; i++) { if(used_colors[3*i] == r && used_colors[3*i+1] == g && used_colors[3*i+2] == b) break; } if (i >= color_count) { free(used_colors); win_pixmap_bg_color = RGB(r, g, b); return; } if (r < 255) r++; else { r = 0; if (g < 255) g++; else { g = 0; b++; } } } } #endif /** Draw XPM image data, with the top-left corner at the given position. \see fl_draw_pixmap(char* const* data, int x, int y, Fl_Color bg) */ int fl_draw_pixmap(const char*const* cdata, int x, int y, Fl_Color bg) { pixmap_data d; if (!fl_measure_pixmap(cdata, d.w, d.h)) return 0; const uchar*const* data = (const uchar*const*)(cdata+1); int transparent_index = -1; uchar *transparent_c = (uchar *)0; // such that transparent_c[0,1,2] are the RGB of the transparent color #ifdef WIN32 color_count = 0; used_colors = (uchar *)malloc(abs(ncolors)*3*sizeof(uchar)); #endif if (ncolors < 0) { // FLTK (non standard) compressed colormap ncolors = -ncolors; const uchar *p = *data++; // if first color is ' ' it is transparent (put it later to make // it not be transparent): if (*p == ' ') { uchar* c = (uchar*)&d.colors[(int)' ']; #ifdef U64 *(U64*)c = 0; # if WORDS_BIGENDIAN c += 4; # endif #endif transparent_index = ' '; Fl::get_color(bg, c[0], c[1], c[2]); c[3] = 0; transparent_c = c; p += 4; ncolors--; } // read all the rest of the colors: for (int i=0; i < ncolors; i++) { uchar* c = (uchar*)&d.colors[*p++]; #ifdef U64 *(U64*)c = 0; # if WORDS_BIGENDIAN c += 4; # endif #endif #ifdef WIN32 used_colors[3*color_count] = *p; used_colors[3*color_count+1] = *(p+1); used_colors[3*color_count+2] = *(p+2); color_count++; #endif *c++ = *p++; *c++ = *p++; *c++ = *p++; #ifdef __APPLE_QUARTZ__ *c = 255; #else *c = 0; #endif } } else { // normal XPM colormap with names if (chars_per_pixel>1) memset(d.byte1, 0, sizeof(d.byte1)); for (int i=0; i1) { #ifdef U64 U64* colors = d.byte1[ind]; if (!colors) colors = d.byte1[ind] = new U64[256]; #else U32* colors = d.byte1[ind]; if (!colors) colors = d.byte1[ind] = new U32[256]; #endif c = (uchar*)&colors[*p]; ind = (ind<<8)|*p++; } else { c = (uchar *)&d.colors[ind]; } // look for "c word", or last word if none: const uchar *previous_word = p; for (;;) { while (*p && isspace(*p)) p++; uchar what = *p++; while (*p && !isspace(*p)) p++; while (*p && isspace(*p)) p++; if (!*p) {p = previous_word; break;} if (what == 'c') break; previous_word = p; while (*p && !isspace(*p)) p++; } #ifdef U64 *(U64*)c = 0; # if WORDS_BIGENDIAN c += 4; # endif #endif #ifdef __APPLE_QUARTZ__ c[3] = 255; #endif int parse = fl_parse_color((const char*)p, c[0], c[1], c[2]); if (parse) { #ifdef WIN32 used_colors[3*color_count] = c[0]; used_colors[3*color_count+1] = c[1]; used_colors[3*color_count+2] = c[2]; color_count++; #endif } else { // assume "None" or "#transparent" for any errors // "bg" should be transparent... Fl::get_color(bg, c[0], c[1], c[2]); #ifdef __APPLE_QUARTZ__ c[3] = 0; #endif transparent_index = ind; transparent_c = c; } } } d.data = data; #ifdef WIN32 if (transparent_c) { make_unused_color(transparent_c[0], transparent_c[1], transparent_c[2]); } else { uchar r, g, b; make_unused_color(r, g, b); } #endif #ifdef __APPLE_QUARTZ__ if (fl_graphics_driver->type() == Fl_Quartz_Graphics_Driver::device_type ) { bool transparent = (transparent_index>=0); transparent = true; U32 *array = new U32[d.w * d.h], *q = array; for (int Y = 0; Y < d.h; Y++) { const uchar* p = data[Y]; if (chars_per_pixel <= 1) { for (int X = 0; X < d.w; X++) { *q++ = d.colors[*p++]; } } else { for (int X = 0; X < d.w; X++) { U32* colors = (U32*)d.byte1[*p++]; *q++ = colors[*p++]; } } } CGColorSpaceRef lut = CGColorSpaceCreateDeviceRGB(); CGDataProviderRef src = CGDataProviderCreateWithData( 0L, array, d.w * d.h * 4, 0L); CGImageRef img = CGImageCreate(d.w, d.h, 8, 4*8, 4*d.w, lut, transparent?kCGImageAlphaLast:kCGImageAlphaNoneSkipLast, src, 0L, false, kCGRenderingIntentDefault); CGColorSpaceRelease(lut); CGDataProviderRelease(src); CGRect rect = { { x, y} , { d.w, d.h } }; Fl_X::q_begin_image(rect, 0, 0, d.w, d.h); CGContextDrawImage(fl_gc, rect, img); Fl_X::q_end_image(); CGImageRelease(img); delete array; } else { #endif // __APPLE_QUARTZ__ // build the mask bitmap used by Fl_Pixmap: if (fl_mask_bitmap && transparent_index >= 0) { int W = (d.w+7)/8; uchar* bitmap = new uchar[W * d.h]; *fl_mask_bitmap = bitmap; for (int Y = 0; Y < d.h; Y++) { const uchar* p = data[Y]; if (chars_per_pixel <= 1) { int dw = d.w; for (int X = 0; X < W; X++) { uchar b = (dw-->0 && *p++ != transparent_index); if (dw-->0 && *p++ != transparent_index) b |= 2; if (dw-->0 && *p++ != transparent_index) b |= 4; if (dw-->0 && *p++ != transparent_index) b |= 8; if (dw-->0 && *p++ != transparent_index) b |= 16; if (dw-->0 && *p++ != transparent_index) b |= 32; if (dw-->0 && *p++ != transparent_index) b |= 64; if (dw-->0 && *p++ != transparent_index) b |= 128; *bitmap++ = b; } } else { uchar b = 0, bit = 1; for (int X = 0; X < d.w; X++) { int ind = *p++; ind = (ind<<8) | (*p++); if (ind != transparent_index) b |= bit; if (bit < 128) bit <<= 1; else { *bitmap++ = b; b = 0; bit = 1; } } if (bit > 1) *bitmap++ = b; } } } fl_draw_image(chars_per_pixel==1 ? cb1 : cb2, &d, x, y, d.w, d.h, 4); #ifdef __APPLE_QUARTZ__ } #endif if (chars_per_pixel > 1) for (int i = 0; i < 256; i++) delete[] d.byte1[i]; return 1; } // // End of "$Id: fl_draw_pixmap.cxx 7659 2010-07-01 13:21:32Z manolo $". //