mirror of
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555 lines
15 KiB
Diff
555 lines
15 KiB
Diff
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diff -ur fltk-1.3.2.org/FL/Fl_Image.H fltk-1.3.2/FL/Fl_Image.H
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--- fltk-1.3.2.org/FL/Fl_Image.H 2012-11-09 17:02:08.000000000 +0100
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+++ fltk-1.3.2/FL/Fl_Image.H 2013-01-16 14:40:51.543230638 +0100
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@@ -26,6 +26,7 @@
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#include <stdlib.h>
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class Fl_Widget;
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+class Fl_Pixmap;
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struct Fl_Menu_Item;
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struct Fl_Label;
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@@ -203,6 +204,7 @@
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*/
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Fl_RGB_Image(const uchar *bits, int W, int H, int D=3, int LD=0) :
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Fl_Image(W,H,D), array(bits), alloc_array(0), id_(0), mask_(0) {data((const char **)&array, 1); ld(LD);}
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+ Fl_RGB_Image(const Fl_Pixmap *pxm, Fl_Color bg=FL_GRAY);
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virtual ~Fl_RGB_Image();
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virtual Fl_Image *copy(int W, int H);
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Fl_Image *copy() { return copy(w(), h()); }
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diff -ur fltk-1.3.2.org/src/fl_draw_pixmap.cxx fltk-1.3.2/src/fl_draw_pixmap.cxx
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--- fltk-1.3.2.org/src/fl_draw_pixmap.cxx 2012-04-22 05:09:31.000000000 +0200
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+++ fltk-1.3.2/src/fl_draw_pixmap.cxx 2013-01-16 14:40:51.542230588 +0100
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@@ -58,99 +58,6 @@
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return 1;
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}
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-#ifdef U64
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-
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-// The callback from fl_draw_image to get a row of data passes this:
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-struct pixmap_data {
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- int w, h;
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- const uchar*const* data;
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- union {
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- U64 colors[256];
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- U64* byte1[256];
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- };
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-};
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-
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-// callback for 1 byte per pixel:
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-static void cb1(void*v, int x, int y, int w, uchar* buf) {
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- pixmap_data& d = *(pixmap_data*)v;
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- const uchar* p = d.data[y]+x;
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- U64* q = (U64*)buf;
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- for (int X=w; X>0; X-=2, p += 2) {
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- if (X>1) {
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-# if WORDS_BIGENDIAN
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- *q++ = (d.colors[p[0]]<<32) | d.colors[p[1]];
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-# else
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- *q++ = (d.colors[p[1]]<<32) | d.colors[p[0]];
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-# endif
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- } else {
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-# if WORDS_BIGENDIAN
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- *q++ = d.colors[p[0]]<<32;
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-# else
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- *q++ = d.colors[p[0]];
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-# endif
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- }
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- }
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-}
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-
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-// callback for 2 bytes per pixel:
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-static void cb2(void*v, int x, int y, int w, uchar* buf) {
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- pixmap_data& d = *(pixmap_data*)v;
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- const uchar* p = d.data[y]+2*x;
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- U64* q = (U64*)buf;
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- for (int X=w; X>0; X-=2) {
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- U64* colors = d.byte1[*p++];
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- int index = *p++;
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- if (X>1) {
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- U64* colors1 = d.byte1[*p++];
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- int index1 = *p++;
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-# if WORDS_BIGENDIAN
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- *q++ = (colors[index]<<32) | colors1[index1];
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-# else
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- *q++ = (colors1[index1]<<32) | colors[index];
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-# endif
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- } else {
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-# if WORDS_BIGENDIAN
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- *q++ = colors[index]<<32;
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-# else
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- *q++ = colors[index];
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-# endif
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- }
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- }
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-}
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-
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-#else // U32
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-
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-// The callback from fl_draw_image to get a row of data passes this:
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-struct pixmap_data {
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- int w, h;
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- const uchar*const* data;
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- union {
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- U32 colors[256];
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- U32* byte1[256];
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- };
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-};
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-
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-// callback for 1 byte per pixel:
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-static void cb1(void*v, int x, int y, int w, uchar* buf) {
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- pixmap_data& d = *(pixmap_data*)v;
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- const uchar* p = d.data[y]+x;
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- U32* q = (U32*)buf;
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- for (int X=w; X--;) *q++ = d.colors[*p++];
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-}
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-
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-// callback for 2 bytes per pixel:
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-static void cb2(void*v, int x, int y, int w, uchar* buf) {
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- pixmap_data& d = *(pixmap_data*)v;
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- const uchar* p = d.data[y]+2*x;
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- U32* q = (U32*)buf;
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- for (int X=w; X--;) {
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- U32* colors = d.byte1[*p++];
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- *q++ = colors[*p++];
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- }
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-}
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-
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-#endif // U64 else U32
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-
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uchar **fl_mask_bitmap; // if non-zero, create bitmap and store pointer here
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/**
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@@ -200,34 +107,33 @@
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}
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#endif
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-/**
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- Draw XPM image data, with the top-left corner at the given position.
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- \see fl_draw_pixmap(char* const* data, int x, int y, Fl_Color bg)
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- */
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-int fl_draw_pixmap(const char*const* cdata, int x, int y, Fl_Color bg) {
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- pixmap_data d;
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- if (!fl_measure_pixmap(cdata, d.w, d.h)) return 0;
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+int fl_convert_pixmap(const char*const* cdata, uchar* out, Fl_Color bg) {
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+ int w, h;
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const uchar*const* data = (const uchar*const*)(cdata+1);
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int transparent_index = -1;
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+
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+ if (!fl_measure_pixmap(cdata, w, h))
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+ return 0;
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+
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+ if ((chars_per_pixel < 1) || (chars_per_pixel > 2))
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+ return 0;
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+
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+ uchar colors[1<<(chars_per_pixel*8)][4];
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+
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#ifdef WIN32
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uchar *transparent_c = (uchar *)0; // such that transparent_c[0,1,2] are the RGB of the transparent color
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color_count = 0;
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used_colors = (uchar *)malloc(abs(ncolors)*3*sizeof(uchar));
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#endif
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- if (ncolors < 0) { // FLTK (non standard) compressed colormap
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+ if (ncolors < 0) {
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+ // FLTK (non standard) compressed colormap
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ncolors = -ncolors;
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const uchar *p = *data++;
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// if first color is ' ' it is transparent (put it later to make
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// it not be transparent):
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if (*p == ' ') {
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- uchar* c = (uchar*)&d.colors[(int)' '];
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-#ifdef U64
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- *(U64*)c = 0;
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-# if WORDS_BIGENDIAN
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- c += 4;
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-# endif
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-#endif
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+ uchar* c = colors[(int)' '];
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transparent_index = ' ';
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Fl::get_color(bg, c[0], c[1], c[2]); c[3] = 0;
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#ifdef WIN32
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@@ -238,13 +144,7 @@
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}
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// read all the rest of the colors:
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for (int i=0; i < ncolors; i++) {
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- uchar* c = (uchar*)&d.colors[*p++];
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-#ifdef U64
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- *(U64*)c = 0;
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-# if WORDS_BIGENDIAN
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- c += 4;
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-# endif
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-#endif
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+ uchar* c = colors[*p++];
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#ifdef WIN32
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used_colors[3*color_count] = *p;
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used_colors[3*color_count+1] = *(p+1);
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@@ -254,69 +154,44 @@
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*c++ = *p++;
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*c++ = *p++;
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*c++ = *p++;
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-#ifdef __APPLE_QUARTZ__
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*c = 255;
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-#else
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- *c = 0;
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-#endif
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}
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- } else { // normal XPM colormap with names
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- if (chars_per_pixel>1) memset(d.byte1, 0, sizeof(d.byte1));
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+ } else {
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+ // normal XPM colormap with names
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for (int i=0; i<ncolors; i++) {
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const uchar *p = *data++;
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// the first 1 or 2 characters are the color index:
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int ind = *p++;
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uchar* c;
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- if (chars_per_pixel>1) {
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-#ifdef U64
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- U64* colors = d.byte1[ind];
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- if (!colors) colors = d.byte1[ind] = new U64[256];
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-#else
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- U32* colors = d.byte1[ind];
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- if (!colors) colors = d.byte1[ind] = new U32[256];
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-#endif
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- c = (uchar*)&colors[*p];
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- ind = (ind<<8)|*p++;
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- } else {
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- c = (uchar *)&d.colors[ind];
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- }
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+ if (chars_per_pixel>1)
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+ ind = (ind<<8)|*p++;
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+ c = colors[ind];
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// look for "c word", or last word if none:
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const uchar *previous_word = p;
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for (;;) {
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- while (*p && isspace(*p)) p++;
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- uchar what = *p++;
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- while (*p && !isspace(*p)) p++;
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- while (*p && isspace(*p)) p++;
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- if (!*p) {p = previous_word; break;}
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- if (what == 'c') break;
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- previous_word = p;
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- while (*p && !isspace(*p)) p++;
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+ while (*p && isspace(*p)) p++;
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+ uchar what = *p++;
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+ while (*p && !isspace(*p)) p++;
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+ while (*p && isspace(*p)) p++;
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+ if (!*p) {p = previous_word; break;}
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+ if (what == 'c') break;
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+ previous_word = p;
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+ while (*p && !isspace(*p)) p++;
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}
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-#ifdef U64
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- *(U64*)c = 0;
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-# if WORDS_BIGENDIAN
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- c += 4;
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-# endif
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-#endif
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-#ifdef __APPLE_QUARTZ__
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- c[3] = 255;
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-#endif
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int parse = fl_parse_color((const char*)p, c[0], c[1], c[2]);
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+ c[3] = 255;
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if (parse) {
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#ifdef WIN32
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- used_colors[3*color_count] = c[0];
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- used_colors[3*color_count+1] = c[1];
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- used_colors[3*color_count+2] = c[2];
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- color_count++;
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+ used_colors[3*color_count] = c[0];
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+ used_colors[3*color_count+1] = c[1];
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+ used_colors[3*color_count+2] = c[2];
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+ color_count++;
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#endif
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- }
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- else {
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+ } else {
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// assume "None" or "#transparent" for any errors
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- // "bg" should be transparent...
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- Fl::get_color(bg, c[0], c[1], c[2]);
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-#ifdef __APPLE_QUARTZ__
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+ // "bg" should be transparent...
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+ Fl::get_color(bg, c[0], c[1], c[2]);
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c[3] = 0;
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-#endif
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transparent_index = ind;
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#ifdef WIN32
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transparent_c = c;
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@@ -324,7 +199,6 @@
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}
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}
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}
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- d.data = data;
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#ifdef WIN32
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if (transparent_c) {
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make_unused_color(transparent_c[0], transparent_c[1], transparent_c[2]);
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@@ -334,77 +208,76 @@
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make_unused_color(r, g, b);
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}
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#endif
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+
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+ U32 *q = (U32*)out;
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+ for (int Y = 0; Y < h; Y++) {
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+ const uchar* p = data[Y];
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+ if (chars_per_pixel <= 1) {
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+ for (int X = 0; X < w; X++)
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+ memcpy(q++, colors[*p++], 4);
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+ } else {
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+ for (int X = 0; X < w; X++) {
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+ int ind = (*p++)<<8;
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+ ind |= *p++;
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+ memcpy(q++, colors[ind], 4);
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+ }
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+ }
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+ }
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+ return 1;
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+}
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+
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+/**
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+ Draw XPM image data, with the top-left corner at the given position.
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+ \see fl_draw_pixmap(char* const* data, int x, int y, Fl_Color bg)
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+ */
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+int fl_draw_pixmap(const char*const* cdata, int x, int y, Fl_Color bg) {
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+ int w, h;
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+
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+ if (!fl_measure_pixmap(cdata, w, h))
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+ return 0;
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+
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+ uchar buffer[w*h*4];
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+
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+ if (!fl_convert_pixmap(cdata, buffer, bg))
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+ return 0;
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+
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+ // FIXME: Hack until fl_draw_image() supports alpha properly
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#ifdef __APPLE_QUARTZ__
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if (Fl_Surface_Device::surface() == Fl_Display_Device::display_device()) {
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- U32 *array = new U32[d.w * d.h], *q = array;
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- for (int Y = 0; Y < d.h; Y++) {
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- const uchar* p = data[Y];
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- if (chars_per_pixel <= 1) {
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- for (int X = 0; X < d.w; X++) {
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- *q++ = d.colors[*p++];
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- }
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- } else {
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- for (int X = 0; X < d.w; X++) {
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- U32* colors = (U32*)d.byte1[*p++];
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- *q++ = colors[*p++];
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- }
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- }
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- }
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- Fl_RGB_Image* rgb = new Fl_RGB_Image((uchar*)array, d.w, d.h, 4);
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+ Fl_RGB_Image* rgb = new Fl_RGB_Image(buffer, w, h, 4);
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rgb->draw(x, y);
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delete rgb;
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- delete[] array;
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- }
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- else {
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+ } else {
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#endif // __APPLE_QUARTZ__
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-
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// build the mask bitmap used by Fl_Pixmap:
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- if (fl_mask_bitmap && transparent_index >= 0) {
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- int W = (d.w+7)/8;
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- uchar* bitmap = new uchar[W * d.h];
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+ if (fl_mask_bitmap) {
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+ int W = (w+7)/8;
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+ uchar* bitmap = new uchar[W * h];
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*fl_mask_bitmap = bitmap;
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- for (int Y = 0; Y < d.h; Y++) {
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- const uchar* p = data[Y];
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- if (chars_per_pixel <= 1) {
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- int dw = d.w;
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- for (int X = 0; X < W; X++) {
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- uchar b = (dw-->0 && *p++ != transparent_index);
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- if (dw-->0 && *p++ != transparent_index) b |= 2;
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- if (dw-->0 && *p++ != transparent_index) b |= 4;
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- if (dw-->0 && *p++ != transparent_index) b |= 8;
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- if (dw-->0 && *p++ != transparent_index) b |= 16;
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- if (dw-->0 && *p++ != transparent_index) b |= 32;
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- if (dw-->0 && *p++ != transparent_index) b |= 64;
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- if (dw-->0 && *p++ != transparent_index) b |= 128;
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+ const uchar *p = &buffer[3];
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+ uchar b = 0;
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+ for (int Y = 0; Y < h; Y++) {
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+ b = 0;
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+ for (int X = 0, bit = 1; X < w; X++, p += 4) {
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+ if (*p > 127) b |= bit;
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+ bit <<= 1;
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+ if (bit > 0x80 || X == w-1) {
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*bitmap++ = b;
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- }
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- } else {
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- uchar b = 0, bit = 1;
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||
|
- 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;
|
||
|
+ bit = 1;
|
||
|
+ b = 0;
|
||
|
}
|
||
|
}
|
||
|
-
|
||
|
- if (bit > 1) *bitmap++ = b;
|
||
|
}
|
||
|
- }
|
||
|
+
|
||
|
}
|
||
|
|
||
|
- fl_draw_image(chars_per_pixel==1 ? cb1 : cb2, &d, x, y, d.w, d.h, 4);
|
||
|
+ fl_draw_image(buffer, x, y, w, h, 4);
|
||
|
+
|
||
|
#ifdef __APPLE_QUARTZ__
|
||
|
}
|
||
|
#endif
|
||
|
|
||
|
- if (chars_per_pixel > 1) for (int i = 0; i < 256; i++) delete[] d.byte1[i];
|
||
|
return 1;
|
||
|
}
|
||
|
|
||
|
diff -ur fltk-1.3.2.org/src/Fl_Image.cxx fltk-1.3.2/src/Fl_Image.cxx
|
||
|
--- fltk-1.3.2.org/src/Fl_Image.cxx 2012-11-09 17:02:08.000000000 +0100
|
||
|
+++ fltk-1.3.2/src/Fl_Image.cxx 2013-01-16 14:41:38.404162795 +0100
|
||
|
@@ -165,7 +165,22 @@
|
||
|
//
|
||
|
size_t Fl_RGB_Image::max_size_ = ~((size_t)0);
|
||
|
|
||
|
-/** The destructor free all memory and server resources that are used by the image. */
|
||
|
+int fl_convert_pixmap(const char*const* cdata, uchar* out, Fl_Color bg);
|
||
|
+
|
||
|
+/** The constructor creates a new RGBA image from the specified Fl_Pixmap.
|
||
|
+
|
||
|
+ The RGBA image is built fully opaque except for the transparent area
|
||
|
+ of the pixmap that is assigned the \par bg color with full transparency */
|
||
|
+Fl_RGB_Image::Fl_RGB_Image(const Fl_Pixmap *pxm, Fl_Color bg):
|
||
|
+ Fl_Image(pxm->w(), pxm->h(), 4), id_(0), mask_(0)
|
||
|
+{
|
||
|
+ array = new uchar[w() * h() * d()];
|
||
|
+ alloc_array = 1;
|
||
|
+ fl_convert_pixmap(pxm->data(), (uchar*)array, bg);
|
||
|
+ data((const char **)&array, 1);
|
||
|
+}
|
||
|
+
|
||
|
+/** The destructor frees all memory and server resources that are used by the image. */
|
||
|
Fl_RGB_Image::~Fl_RGB_Image() {
|
||
|
uncache();
|
||
|
if (alloc_array) delete[] (uchar *)array;
|
||
|
diff -ur fltk-1.3.2.org/src/ps_image.cxx fltk-1.3.2/src/ps_image.cxx
|
||
|
--- fltk-1.3.2.org/src/ps_image.cxx 2011-07-19 06:49:30.000000000 +0200
|
||
|
+++ fltk-1.3.2/src/ps_image.cxx 2013-01-16 14:40:51.541228080 +0100
|
||
|
@@ -185,72 +185,38 @@
|
||
|
|
||
|
extern uchar **fl_mask_bitmap;
|
||
|
|
||
|
+struct callback_data {
|
||
|
+ const uchar *data;
|
||
|
+ int D, LD;
|
||
|
+};
|
||
|
|
||
|
-void Fl_PostScript_Graphics_Driver::draw_image(const uchar *data, int ix, int iy, int iw, int ih, int D, int LD) {
|
||
|
- double x = ix, y = iy, w = iw, h = ih;
|
||
|
|
||
|
- if (D<3){ //mono
|
||
|
- draw_image_mono(data, ix, iy, iw, ih, D, LD);
|
||
|
- return;
|
||
|
- }
|
||
|
+static void draw_image_cb(void *data, int x, int y, int w, uchar *buf) {
|
||
|
+ struct callback_data *cb_data;
|
||
|
+ const uchar *curdata;
|
||
|
|
||
|
+ cb_data = (struct callback_data*)data;
|
||
|
+ curdata = cb_data->data + x*cb_data->D + y*cb_data->LD;
|
||
|
|
||
|
- int i,j, k;
|
||
|
+ memcpy(buf, curdata, w*cb_data->D);
|
||
|
+}
|
||
|
|
||
|
- fprintf(output,"save\n");
|
||
|
|
||
|
- const char * interpol;
|
||
|
- if (lang_level_>1){
|
||
|
- if (interpolate_)
|
||
|
- interpol="true";
|
||
|
- else
|
||
|
- interpol="false";
|
||
|
- if (mask && lang_level_>2)
|
||
|
- fprintf(output, "%g %g %g %g %i %i %i %i %s CIM\n", x , y+h , w , -h , iw , ih, mx, my, interpol);
|
||
|
- else
|
||
|
- fprintf(output, "%g %g %g %g %i %i %s CII\n", x , y+h , w , -h , iw , ih, interpol);
|
||
|
- } else
|
||
|
- fprintf(output , "%g %g %g %g %i %i CI", x , y+h , w , -h , iw , ih);
|
||
|
+void Fl_PostScript_Graphics_Driver::draw_image(const uchar *data, int ix, int iy, int iw, int ih, int D, int LD) {
|
||
|
+ if (D<3){ //mono
|
||
|
+ draw_image_mono(data, ix, iy, iw, ih, D, LD);
|
||
|
+ return;
|
||
|
+ }
|
||
|
|
||
|
+ struct callback_data cb_data;
|
||
|
|
||
|
if (!LD) LD = iw*D;
|
||
|
- uchar *curmask=mask;
|
||
|
-
|
||
|
- for (j=0; j<ih;j++){
|
||
|
- if (mask){
|
||
|
-
|
||
|
- for (k=0;k<my/ih;k++){
|
||
|
- for (i=0; i<((mx+7)/8);i++){
|
||
|
- if (!(i%80)) fprintf(output, "\n");
|
||
|
- fprintf(output, "%.2x",swap_byte(*curmask));
|
||
|
- curmask++;
|
||
|
- }
|
||
|
- fprintf(output,"\n");
|
||
|
- }
|
||
|
- }
|
||
|
- const uchar *curdata=data+j*LD;
|
||
|
- for (i=0 ; i<iw ; i++) {
|
||
|
- uchar r = curdata[0];
|
||
|
- uchar g = curdata[1];
|
||
|
- uchar b = curdata[2];
|
||
|
- if (lang_level_<3 && D>3) { //can do mixing using bg_* colors)
|
||
|
- unsigned int a2 = curdata[3]; //must be int
|
||
|
- unsigned int a = 255-a2;
|
||
|
- r = (a2 * r + bg_r * a)/255;
|
||
|
- g = (a2 * g + bg_g * a)/255;
|
||
|
- b = (a2 * b + bg_b * a)/255;
|
||
|
- }
|
||
|
- if (!(i%40)) fprintf(output, "\n");
|
||
|
- fprintf(output, "%.2x%.2x%.2x", r, g, b);
|
||
|
- curdata +=D;
|
||
|
- }
|
||
|
- fprintf(output,"\n");
|
||
|
-
|
||
|
- }
|
||
|
-
|
||
|
- fprintf(output," >\nrestore\n" );
|
||
|
|
||
|
+ cb_data.data = data;
|
||
|
+ cb_data.D = D;
|
||
|
+ cb_data.LD = LD;
|
||
|
|
||
|
+ draw_image(draw_image_cb, &cb_data, ix, iy, iw, ih, D);
|
||
|
}
|
||
|
|
||
|
void Fl_PostScript_Graphics_Driver::draw_image(Fl_Draw_Image_Cb call, void *data, int ix, int iy, int iw, int ih, int D) {
|
||
|
@@ -325,6 +291,14 @@
|
||
|
uchar g = curdata[1];
|
||
|
uchar b = curdata[2];
|
||
|
|
||
|
+ if (lang_level_<3 && D>3) { //can do mixing using bg_* colors)
|
||
|
+ unsigned int a2 = curdata[3]; //must be int
|
||
|
+ unsigned int a = 255-a2;
|
||
|
+ r = (a2 * r + bg_r * a)/255;
|
||
|
+ g = (a2 * g + bg_g * a)/255;
|
||
|
+ b = (a2 * b + bg_b * a)/255;
|
||
|
+ }
|
||
|
+
|
||
|
if (!(i%40)) fputs("\n", output);
|
||
|
fprintf(output, "%.2x%.2x%.2x", r, g, b);
|
||
|
|