/* Functions for the X window system. Copyright (C) 1989, 92, 93, 94, 95, 96, 97, 98, 99, 2000, 01, 02, 03 Free Software Foundation. This file is part of GNU Emacs. GNU Emacs 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 2, or (at your option) any later version. GNU Emacs 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 GNU Emacs; see the file COPYING. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include #include #include #include #ifdef HAVE_UNISTD_H #include #endif /* This makes the fields of a Display accessible, in Xlib header files. */ #define XLIB_ILLEGAL_ACCESS #include "lisp.h" #include "xterm.h" #include "frame.h" #include "window.h" #include "buffer.h" #include "intervals.h" #include "dispextern.h" #include "keyboard.h" #include "blockinput.h" #include #include "charset.h" #include "coding.h" #include "fontset.h" #include "systime.h" #include "termhooks.h" #include "atimer.h" #ifdef HAVE_X_WINDOWS #include #include #include #ifndef VMS #if 1 /* Used to be #ifdef EMACS_BITMAP_FILES, but this should always work. */ #include "bitmaps/gray.xbm" #else #include #endif #else #include "[.bitmaps]gray.xbm" #endif #ifdef USE_GTK #include "gtkutil.h" #endif #ifdef USE_X_TOOLKIT #include #ifndef USE_MOTIF #include #include #endif /* USE_MOTIF */ #ifdef USG #undef USG /* ####KLUDGE for Solaris 2.2 and up */ #include #define USG #else #include #endif #include "widget.h" #include "../lwlib/lwlib.h" #ifdef USE_MOTIF #include #include #include #endif /* Do the EDITRES protocol if running X11R5 Exception: HP-UX (at least version A.09.05) has X11R5 without EditRes */ #if (XtSpecificationRelease >= 5) && !defined(NO_EDITRES) #define HACK_EDITRES extern void _XEditResCheckMessages (); #endif /* R5 + Athena */ /* Unique id counter for widgets created by the Lucid Widget Library. */ extern LWLIB_ID widget_id_tick; #ifdef USE_LUCID /* This is part of a kludge--see lwlib/xlwmenu.c. */ extern XFontStruct *xlwmenu_default_font; #endif extern void free_frame_menubar (); extern double atof (); #ifdef USE_MOTIF /* LessTif/Motif version info. */ static Lisp_Object Vmotif_version_string; #endif /* USE_MOTIF */ #endif /* USE_X_TOOLKIT */ #ifdef HAVE_X11R4 #define MAXREQUEST(dpy) (XMaxRequestSize (dpy)) #else #define MAXREQUEST(dpy) ((dpy)->max_request_size) #endif /* The gray bitmap `bitmaps/gray'. This is done because xterm.c uses it, and including `bitmaps/gray' more than once is a problem when config.h defines `static' as an empty replacement string. */ int gray_bitmap_width = gray_width; int gray_bitmap_height = gray_height; char *gray_bitmap_bits = gray_bits; /* Non-zero means we're allowed to display an hourglass cursor. */ int display_hourglass_p; /* The background and shape of the mouse pointer, and shape when not over text or in the modeline. */ Lisp_Object Vx_pointer_shape, Vx_nontext_pointer_shape, Vx_mode_pointer_shape; Lisp_Object Vx_hourglass_pointer_shape; /* The shape when over mouse-sensitive text. */ Lisp_Object Vx_sensitive_text_pointer_shape; /* If non-nil, the pointer shape to indicate that windows can be dragged horizontally. */ Lisp_Object Vx_window_horizontal_drag_shape; /* Color of chars displayed in cursor box. */ Lisp_Object Vx_cursor_fore_pixel; /* Nonzero if using X. */ static int x_in_use; /* Non nil if no window manager is in use. */ Lisp_Object Vx_no_window_manager; /* Search path for bitmap files. */ Lisp_Object Vx_bitmap_file_path; /* Regexp matching a font name whose width is the same as `PIXEL_SIZE'. */ Lisp_Object Vx_pixel_size_width_font_regexp; Lisp_Object Qnone; Lisp_Object Qsuppress_icon; Lisp_Object Qundefined_color; Lisp_Object Qcenter; Lisp_Object Qcompound_text, Qcancel_timer; /* In dispnew.c */ extern Lisp_Object Vwindow_system_version; /* The below are defined in frame.c. */ #if GLYPH_DEBUG int image_cache_refcount, dpyinfo_refcount; #endif /* Error if we are not connected to X. */ void check_x () { if (! x_in_use) error ("X windows are not in use or not initialized"); } /* Nonzero if we can use mouse menus. You should not call this unless HAVE_MENUS is defined. */ int have_menus_p () { return x_in_use; } /* Extract a frame as a FRAME_PTR, defaulting to the selected frame and checking validity for X. */ FRAME_PTR check_x_frame (frame) Lisp_Object frame; { FRAME_PTR f; if (NILP (frame)) frame = selected_frame; CHECK_LIVE_FRAME (frame); f = XFRAME (frame); if (! FRAME_X_P (f)) error ("Non-X frame used"); return f; } /* Let the user specify an X display with a frame. nil stands for the selected frame--or, if that is not an X frame, the first X display on the list. */ struct x_display_info * check_x_display_info (frame) Lisp_Object frame; { struct x_display_info *dpyinfo = NULL; if (NILP (frame)) { struct frame *sf = XFRAME (selected_frame); if (FRAME_X_P (sf) && FRAME_LIVE_P (sf)) dpyinfo = FRAME_X_DISPLAY_INFO (sf); else if (x_display_list != 0) dpyinfo = x_display_list; else error ("X windows are not in use or not initialized"); } else if (STRINGP (frame)) dpyinfo = x_display_info_for_name (frame); else { FRAME_PTR f = check_x_frame (frame); dpyinfo = FRAME_X_DISPLAY_INFO (f); } return dpyinfo; } /* Return the Emacs frame-object corresponding to an X window. It could be the frame's main window or an icon window. */ /* This function can be called during GC, so use GC_xxx type test macros. */ struct frame * x_window_to_frame (dpyinfo, wdesc) struct x_display_info *dpyinfo; int wdesc; { Lisp_Object tail, frame; struct frame *f; for (tail = Vframe_list; GC_CONSP (tail); tail = XCDR (tail)) { frame = XCAR (tail); if (!GC_FRAMEP (frame)) continue; f = XFRAME (frame); if (!FRAME_X_P (f) || FRAME_X_DISPLAY_INFO (f) != dpyinfo) continue; if (f->output_data.x->hourglass_window == wdesc) return f; #ifdef USE_X_TOOLKIT if ((f->output_data.x->edit_widget && XtWindow (f->output_data.x->edit_widget) == wdesc) /* A tooltip frame? */ || (!f->output_data.x->edit_widget && FRAME_X_WINDOW (f) == wdesc) || f->output_data.x->icon_desc == wdesc) return f; #else /* not USE_X_TOOLKIT */ #ifdef USE_GTK if (f->output_data.x->edit_widget) { GtkWidget *gwdesc = xg_win_to_widget (wdesc); struct x_output *x = f->output_data.x; if (gwdesc != 0 && gwdesc == x->edit_widget) return f; } #endif /* USE_GTK */ if (FRAME_X_WINDOW (f) == wdesc || f->output_data.x->icon_desc == wdesc) return f; #endif /* not USE_X_TOOLKIT */ } return 0; } #if defined (USE_X_TOOLKIT) || defined (USE_GTK) /* Like x_window_to_frame but also compares the window with the widget's windows. */ struct frame * x_any_window_to_frame (dpyinfo, wdesc) struct x_display_info *dpyinfo; int wdesc; { Lisp_Object tail, frame; struct frame *f, *found; struct x_output *x; found = NULL; for (tail = Vframe_list; GC_CONSP (tail) && !found; tail = XCDR (tail)) { frame = XCAR (tail); if (!GC_FRAMEP (frame)) continue; f = XFRAME (frame); if (FRAME_X_P (f) && FRAME_X_DISPLAY_INFO (f) == dpyinfo) { /* This frame matches if the window is any of its widgets. */ x = f->output_data.x; if (x->hourglass_window == wdesc) found = f; else if (x->widget) { #ifdef USE_GTK GtkWidget *gwdesc = xg_win_to_widget (wdesc); if (gwdesc != 0 && (gwdesc == x->widget || gwdesc == x->edit_widget || gwdesc == x->vbox_widget || gwdesc == x->menubar_widget)) found = f; #else if (wdesc == XtWindow (x->widget) || wdesc == XtWindow (x->column_widget) || wdesc == XtWindow (x->edit_widget)) found = f; /* Match if the window is this frame's menubar. */ else if (lw_window_is_in_menubar (wdesc, x->menubar_widget)) found = f; #endif } else if (FRAME_X_WINDOW (f) == wdesc) /* A tooltip frame. */ found = f; } } return found; } /* Likewise, but exclude the menu bar widget. */ struct frame * x_non_menubar_window_to_frame (dpyinfo, wdesc) struct x_display_info *dpyinfo; int wdesc; { Lisp_Object tail, frame; struct frame *f; struct x_output *x; for (tail = Vframe_list; GC_CONSP (tail); tail = XCDR (tail)) { frame = XCAR (tail); if (!GC_FRAMEP (frame)) continue; f = XFRAME (frame); if (!FRAME_X_P (f) || FRAME_X_DISPLAY_INFO (f) != dpyinfo) continue; x = f->output_data.x; /* This frame matches if the window is any of its widgets. */ if (x->hourglass_window == wdesc) return f; else if (x->widget) { #ifdef USE_GTK GtkWidget *gwdesc = xg_win_to_widget (wdesc); if (gwdesc != 0 && (gwdesc == x->widget || gwdesc == x->edit_widget || gwdesc == x->vbox_widget)) return f; #else if (wdesc == XtWindow (x->widget) || wdesc == XtWindow (x->column_widget) || wdesc == XtWindow (x->edit_widget)) return f; #endif } else if (FRAME_X_WINDOW (f) == wdesc) /* A tooltip frame. */ return f; } return 0; } /* Likewise, but consider only the menu bar widget. */ struct frame * x_menubar_window_to_frame (dpyinfo, wdesc) struct x_display_info *dpyinfo; int wdesc; { Lisp_Object tail, frame; struct frame *f; struct x_output *x; for (tail = Vframe_list; GC_CONSP (tail); tail = XCDR (tail)) { frame = XCAR (tail); if (!GC_FRAMEP (frame)) continue; f = XFRAME (frame); if (!FRAME_X_P (f) || FRAME_X_DISPLAY_INFO (f) != dpyinfo) continue; x = f->output_data.x; /* Match if the window is this frame's menubar. */ #ifdef USE_GTK if (x->menubar_widget) { GtkWidget *gwdesc = xg_win_to_widget (wdesc); int found = 0; BLOCK_INPUT; if (gwdesc != 0 && (gwdesc == x->menubar_widget || gtk_widget_get_parent (gwdesc) == x->menubar_widget)) found = 1; UNBLOCK_INPUT; if (found) return f; } #else if (x->menubar_widget && lw_window_is_in_menubar (wdesc, x->menubar_widget)) return f; #endif } return 0; } /* Return the frame whose principal (outermost) window is WDESC. If WDESC is some other (smaller) window, we return 0. */ struct frame * x_top_window_to_frame (dpyinfo, wdesc) struct x_display_info *dpyinfo; int wdesc; { Lisp_Object tail, frame; struct frame *f; struct x_output *x; for (tail = Vframe_list; GC_CONSP (tail); tail = XCDR (tail)) { frame = XCAR (tail); if (!GC_FRAMEP (frame)) continue; f = XFRAME (frame); if (!FRAME_X_P (f) || FRAME_X_DISPLAY_INFO (f) != dpyinfo) continue; x = f->output_data.x; if (x->widget) { /* This frame matches if the window is its topmost widget. */ #ifdef USE_GTK GtkWidget *gwdesc = xg_win_to_widget (wdesc); if (gwdesc == x->widget) return f; #else if (wdesc == XtWindow (x->widget)) return f; #if 0 /* I don't know why it did this, but it seems logically wrong, and it causes trouble for MapNotify events. */ /* Match if the window is this frame's menubar. */ if (x->menubar_widget && wdesc == XtWindow (x->menubar_widget)) return f; #endif #endif } else if (FRAME_X_WINDOW (f) == wdesc) /* Tooltip frame. */ return f; } return 0; } #endif /* USE_X_TOOLKIT || USE_GTK */ /* Code to deal with bitmaps. Bitmaps are referenced by their bitmap id, which is just an int that this section returns. Bitmaps are reference counted so they can be shared among frames. Bitmap indices are guaranteed to be > 0, so a negative number can be used to indicate no bitmap. If you use x_create_bitmap_from_data, then you must keep track of the bitmaps yourself. That is, creating a bitmap from the same data more than once will not be caught. */ /* Functions to access the contents of a bitmap, given an id. */ int x_bitmap_height (f, id) FRAME_PTR f; int id; { return FRAME_X_DISPLAY_INFO (f)->bitmaps[id - 1].height; } int x_bitmap_width (f, id) FRAME_PTR f; int id; { return FRAME_X_DISPLAY_INFO (f)->bitmaps[id - 1].width; } int x_bitmap_pixmap (f, id) FRAME_PTR f; int id; { return FRAME_X_DISPLAY_INFO (f)->bitmaps[id - 1].pixmap; } /* Allocate a new bitmap record. Returns index of new record. */ static int x_allocate_bitmap_record (f) FRAME_PTR f; { struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (f); int i; if (dpyinfo->bitmaps == NULL) { dpyinfo->bitmaps_size = 10; dpyinfo->bitmaps = (struct x_bitmap_record *) xmalloc (dpyinfo->bitmaps_size * sizeof (struct x_bitmap_record)); dpyinfo->bitmaps_last = 1; return 1; } if (dpyinfo->bitmaps_last < dpyinfo->bitmaps_size) return ++dpyinfo->bitmaps_last; for (i = 0; i < dpyinfo->bitmaps_size; ++i) if (dpyinfo->bitmaps[i].refcount == 0) return i + 1; dpyinfo->bitmaps_size *= 2; dpyinfo->bitmaps = (struct x_bitmap_record *) xrealloc (dpyinfo->bitmaps, dpyinfo->bitmaps_size * sizeof (struct x_bitmap_record)); return ++dpyinfo->bitmaps_last; } /* Add one reference to the reference count of the bitmap with id ID. */ void x_reference_bitmap (f, id) FRAME_PTR f; int id; { ++FRAME_X_DISPLAY_INFO (f)->bitmaps[id - 1].refcount; } /* Create a bitmap for frame F from a HEIGHT x WIDTH array of bits at BITS. */ int x_create_bitmap_from_data (f, bits, width, height) struct frame *f; char *bits; unsigned int width, height; { struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (f); Pixmap bitmap; int id; bitmap = XCreateBitmapFromData (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), bits, width, height); if (! bitmap) return -1; id = x_allocate_bitmap_record (f); dpyinfo->bitmaps[id - 1].pixmap = bitmap; dpyinfo->bitmaps[id - 1].file = NULL; dpyinfo->bitmaps[id - 1].refcount = 1; dpyinfo->bitmaps[id - 1].depth = 1; dpyinfo->bitmaps[id - 1].height = height; dpyinfo->bitmaps[id - 1].width = width; return id; } /* Create bitmap from file FILE for frame F. */ int x_create_bitmap_from_file (f, file) struct frame *f; Lisp_Object file; { struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (f); unsigned int width, height; Pixmap bitmap; int xhot, yhot, result, id; Lisp_Object found; int fd; char *filename; /* Look for an existing bitmap with the same name. */ for (id = 0; id < dpyinfo->bitmaps_last; ++id) { if (dpyinfo->bitmaps[id].refcount && dpyinfo->bitmaps[id].file && !strcmp (dpyinfo->bitmaps[id].file, (char *) SDATA (file))) { ++dpyinfo->bitmaps[id].refcount; return id + 1; } } /* Search bitmap-file-path for the file, if appropriate. */ fd = openp (Vx_bitmap_file_path, file, Qnil, &found, Qnil); if (fd < 0) return -1; emacs_close (fd); filename = (char *) SDATA (found); result = XReadBitmapFile (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), filename, &width, &height, &bitmap, &xhot, &yhot); if (result != BitmapSuccess) return -1; id = x_allocate_bitmap_record (f); dpyinfo->bitmaps[id - 1].pixmap = bitmap; dpyinfo->bitmaps[id - 1].refcount = 1; dpyinfo->bitmaps[id - 1].file = (char *) xmalloc (SBYTES (file) + 1); dpyinfo->bitmaps[id - 1].depth = 1; dpyinfo->bitmaps[id - 1].height = height; dpyinfo->bitmaps[id - 1].width = width; strcpy (dpyinfo->bitmaps[id - 1].file, SDATA (file)); return id; } /* Remove reference to bitmap with id number ID. */ void x_destroy_bitmap (f, id) FRAME_PTR f; int id; { struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (f); if (id > 0) { --dpyinfo->bitmaps[id - 1].refcount; if (dpyinfo->bitmaps[id - 1].refcount == 0) { BLOCK_INPUT; XFreePixmap (FRAME_X_DISPLAY (f), dpyinfo->bitmaps[id - 1].pixmap); if (dpyinfo->bitmaps[id - 1].file) { xfree (dpyinfo->bitmaps[id - 1].file); dpyinfo->bitmaps[id - 1].file = NULL; } UNBLOCK_INPUT; } } } /* Free all the bitmaps for the display specified by DPYINFO. */ static void x_destroy_all_bitmaps (dpyinfo) struct x_display_info *dpyinfo; { int i; for (i = 0; i < dpyinfo->bitmaps_last; i++) if (dpyinfo->bitmaps[i].refcount > 0) { XFreePixmap (dpyinfo->display, dpyinfo->bitmaps[i].pixmap); if (dpyinfo->bitmaps[i].file) xfree (dpyinfo->bitmaps[i].file); } dpyinfo->bitmaps_last = 0; } static Lisp_Object unwind_create_frame P_ ((Lisp_Object)); static Lisp_Object unwind_create_tip_frame P_ ((Lisp_Object)); static void x_disable_image P_ ((struct frame *, struct image *)); void x_set_foreground_color P_ ((struct frame *, Lisp_Object, Lisp_Object)); static void x_set_wait_for_wm P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_background_color P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_mouse_color P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_cursor_color P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_border_color P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_cursor_type P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_icon_type P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_icon_name P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_explicitly_set_name P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_menu_bar_lines P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_title P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_tool_bar_lines P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_scroll_bar_foreground P_ ((struct frame *, Lisp_Object, Lisp_Object)); void x_set_scroll_bar_background P_ ((struct frame *, Lisp_Object, Lisp_Object)); static Lisp_Object x_default_scroll_bar_color_parameter P_ ((struct frame *, Lisp_Object, Lisp_Object, char *, char *, int)); static void x_edge_detection P_ ((struct frame *, struct image *, Lisp_Object, Lisp_Object)); static void init_color_table P_ ((void)); static void free_color_table P_ ((void)); static unsigned long *colors_in_color_table P_ ((int *n)); static unsigned long lookup_rgb_color P_ ((struct frame *f, int r, int g, int b)); static unsigned long lookup_pixel_color P_ ((struct frame *f, unsigned long p)); /* Store the screen positions of frame F into XPTR and YPTR. These are the positions of the containing window manager window, not Emacs's own window. */ void x_real_positions (f, xptr, yptr) FRAME_PTR f; int *xptr, *yptr; { int win_x, win_y, outer_x, outer_y; int real_x = 0, real_y = 0; int had_errors = 0; Window win = f->output_data.x->parent_desc; int count; BLOCK_INPUT; count = x_catch_errors (FRAME_X_DISPLAY (f)); if (win == FRAME_X_DISPLAY_INFO (f)->root_window) win = FRAME_OUTER_WINDOW (f); /* This loop traverses up the containment tree until we hit the root window. Window managers may intersect many windows between our window and the root window. The window we find just before the root window should be the outer WM window. */ for (;;) { Window wm_window, rootw; Window *tmp_children; unsigned int tmp_nchildren; int success; success = XQueryTree (FRAME_X_DISPLAY (f), win, &rootw, &wm_window, &tmp_children, &tmp_nchildren); had_errors = x_had_errors_p (FRAME_X_DISPLAY (f)); /* Don't free tmp_children if XQueryTree failed. */ if (! success) break; XFree ((char *) tmp_children); if (wm_window == rootw || had_errors) break; win = wm_window; } if (! had_errors) { int ign; Window child, rootw; /* Get the real coordinates for the WM window upper left corner */ XGetGeometry (FRAME_X_DISPLAY (f), win, &rootw, &real_x, &real_y, &ign, &ign, &ign, &ign); /* Translate real coordinates to coordinates relative to our window. For our window, the upper left corner is 0, 0. Since the upper left corner of the WM window is outside our window, win_x and win_y will be negative: ------------------ ---> x | title | | ----------------- v y | | our window */ XTranslateCoordinates (FRAME_X_DISPLAY (f), /* From-window, to-window. */ FRAME_X_DISPLAY_INFO (f)->root_window, FRAME_X_WINDOW (f), /* From-position, to-position. */ real_x, real_y, &win_x, &win_y, /* Child of win. */ &child); if (FRAME_X_WINDOW (f) == FRAME_OUTER_WINDOW (f)) { outer_x = win_x; outer_y = win_y; } else { XTranslateCoordinates (FRAME_X_DISPLAY (f), /* From-window, to-window. */ FRAME_X_DISPLAY_INFO (f)->root_window, FRAME_OUTER_WINDOW (f), /* From-position, to-position. */ real_x, real_y, &outer_x, &outer_y, /* Child of win. */ &child); } had_errors = x_had_errors_p (FRAME_X_DISPLAY (f)); } x_uncatch_errors (FRAME_X_DISPLAY (f), count); UNBLOCK_INPUT; if (had_errors) return; f->x_pixels_diff = -win_x; f->y_pixels_diff = -win_y; FRAME_X_OUTPUT (f)->x_pixels_outer_diff = -outer_x; FRAME_X_OUTPUT (f)->y_pixels_outer_diff = -outer_y; *xptr = real_x; *yptr = real_y; } /* Gamma-correct COLOR on frame F. */ void gamma_correct (f, color) struct frame *f; XColor *color; { if (f->gamma) { color->red = pow (color->red / 65535.0, f->gamma) * 65535.0 + 0.5; color->green = pow (color->green / 65535.0, f->gamma) * 65535.0 + 0.5; color->blue = pow (color->blue / 65535.0, f->gamma) * 65535.0 + 0.5; } } /* Decide if color named COLOR_NAME is valid for use on frame F. If so, return the RGB values in COLOR. If ALLOC_P is non-zero, allocate the color. Value is zero if COLOR_NAME is invalid, or no color could be allocated. */ int x_defined_color (f, color_name, color, alloc_p) struct frame *f; char *color_name; XColor *color; int alloc_p; { int success_p; Display *dpy = FRAME_X_DISPLAY (f); Colormap cmap = FRAME_X_COLORMAP (f); BLOCK_INPUT; success_p = XParseColor (dpy, cmap, color_name, color); if (success_p && alloc_p) success_p = x_alloc_nearest_color (f, cmap, color); UNBLOCK_INPUT; return success_p; } /* Return the pixel color value for color COLOR_NAME on frame F. If F is a monochrome frame, return MONO_COLOR regardless of what ARG says. Signal an error if color can't be allocated. */ int x_decode_color (f, color_name, mono_color) FRAME_PTR f; Lisp_Object color_name; int mono_color; { XColor cdef; CHECK_STRING (color_name); #if 0 /* Don't do this. It's wrong when we're not using the default colormap, it makes freeing difficult, and it's probably not an important optimization. */ if (strcmp (SDATA (color_name), "black") == 0) return BLACK_PIX_DEFAULT (f); else if (strcmp (SDATA (color_name), "white") == 0) return WHITE_PIX_DEFAULT (f); #endif /* Return MONO_COLOR for monochrome frames. */ if (FRAME_X_DISPLAY_INFO (f)->n_planes == 1) return mono_color; /* x_defined_color is responsible for coping with failures by looking for a near-miss. */ if (x_defined_color (f, SDATA (color_name), &cdef, 1)) return cdef.pixel; Fsignal (Qerror, Fcons (build_string ("Undefined color"), Fcons (color_name, Qnil))); return 0; } /* Change the `wait-for-wm' frame parameter of frame F. OLD_VALUE is the previous value of that parameter, NEW_VALUE is the new value. See also the comment of wait_for_wm in struct x_output. */ static void x_set_wait_for_wm (f, new_value, old_value) struct frame *f; Lisp_Object new_value, old_value; { f->output_data.x->wait_for_wm = !NILP (new_value); } /* Functions called only from `x_set_frame_param' to set individual parameters. If FRAME_X_WINDOW (f) is 0, the frame is being created and its X-window does not exist yet. In that case, just record the parameter's new value in the standard place; do not attempt to change the window. */ void x_set_foreground_color (f, arg, oldval) struct frame *f; Lisp_Object arg, oldval; { struct x_output *x = f->output_data.x; unsigned long fg, old_fg; fg = x_decode_color (f, arg, BLACK_PIX_DEFAULT (f)); old_fg = x->foreground_pixel; x->foreground_pixel = fg; if (FRAME_X_WINDOW (f) != 0) { Display *dpy = FRAME_X_DISPLAY (f); BLOCK_INPUT; XSetForeground (dpy, x->normal_gc, fg); XSetBackground (dpy, x->reverse_gc, fg); if (x->cursor_pixel == old_fg) { unload_color (f, x->cursor_pixel); x->cursor_pixel = x_copy_color (f, fg); XSetBackground (dpy, x->cursor_gc, x->cursor_pixel); } UNBLOCK_INPUT; update_face_from_frame_parameter (f, Qforeground_color, arg); if (FRAME_VISIBLE_P (f)) redraw_frame (f); } unload_color (f, old_fg); } void x_set_background_color (f, arg, oldval) struct frame *f; Lisp_Object arg, oldval; { struct x_output *x = f->output_data.x; unsigned long bg; bg = x_decode_color (f, arg, WHITE_PIX_DEFAULT (f)); unload_color (f, x->background_pixel); x->background_pixel = bg; if (FRAME_X_WINDOW (f) != 0) { Display *dpy = FRAME_X_DISPLAY (f); BLOCK_INPUT; XSetBackground (dpy, x->normal_gc, bg); XSetForeground (dpy, x->reverse_gc, bg); XSetWindowBackground (dpy, FRAME_X_WINDOW (f), bg); XSetForeground (dpy, x->cursor_gc, bg); #ifdef USE_GTK xg_set_background_color (f, bg); #endif #ifndef USE_TOOLKIT_SCROLL_BARS /* Turns out to be annoying with toolkit scroll bars. */ { Lisp_Object bar; for (bar = FRAME_SCROLL_BARS (f); !NILP (bar); bar = XSCROLL_BAR (bar)->next) { Window window = SCROLL_BAR_X_WINDOW (XSCROLL_BAR (bar)); XSetWindowBackground (dpy, window, bg); } } #endif /* USE_TOOLKIT_SCROLL_BARS */ UNBLOCK_INPUT; update_face_from_frame_parameter (f, Qbackground_color, arg); if (FRAME_VISIBLE_P (f)) redraw_frame (f); } } void x_set_mouse_color (f, arg, oldval) struct frame *f; Lisp_Object arg, oldval; { struct x_output *x = f->output_data.x; Display *dpy = FRAME_X_DISPLAY (f); Cursor cursor, nontext_cursor, mode_cursor, hand_cursor; Cursor hourglass_cursor, horizontal_drag_cursor; int count; unsigned long pixel = x_decode_color (f, arg, BLACK_PIX_DEFAULT (f)); unsigned long mask_color = x->background_pixel; /* Don't let pointers be invisible. */ if (mask_color == pixel) { x_free_colors (f, &pixel, 1); pixel = x_copy_color (f, x->foreground_pixel); } unload_color (f, x->mouse_pixel); x->mouse_pixel = pixel; BLOCK_INPUT; /* It's not okay to crash if the user selects a screwy cursor. */ count = x_catch_errors (dpy); if (!NILP (Vx_pointer_shape)) { CHECK_NUMBER (Vx_pointer_shape); cursor = XCreateFontCursor (dpy, XINT (Vx_pointer_shape)); } else cursor = XCreateFontCursor (dpy, XC_xterm); x_check_errors (dpy, "bad text pointer cursor: %s"); if (!NILP (Vx_nontext_pointer_shape)) { CHECK_NUMBER (Vx_nontext_pointer_shape); nontext_cursor = XCreateFontCursor (dpy, XINT (Vx_nontext_pointer_shape)); } else nontext_cursor = XCreateFontCursor (dpy, XC_left_ptr); x_check_errors (dpy, "bad nontext pointer cursor: %s"); if (!NILP (Vx_hourglass_pointer_shape)) { CHECK_NUMBER (Vx_hourglass_pointer_shape); hourglass_cursor = XCreateFontCursor (dpy, XINT (Vx_hourglass_pointer_shape)); } else hourglass_cursor = XCreateFontCursor (dpy, XC_watch); x_check_errors (dpy, "bad hourglass pointer cursor: %s"); x_check_errors (dpy, "bad nontext pointer cursor: %s"); if (!NILP (Vx_mode_pointer_shape)) { CHECK_NUMBER (Vx_mode_pointer_shape); mode_cursor = XCreateFontCursor (dpy, XINT (Vx_mode_pointer_shape)); } else mode_cursor = XCreateFontCursor (dpy, XC_xterm); x_check_errors (dpy, "bad modeline pointer cursor: %s"); if (!NILP (Vx_sensitive_text_pointer_shape)) { CHECK_NUMBER (Vx_sensitive_text_pointer_shape); hand_cursor = XCreateFontCursor (dpy, XINT (Vx_sensitive_text_pointer_shape)); } else hand_cursor = XCreateFontCursor (dpy, XC_hand2); if (!NILP (Vx_window_horizontal_drag_shape)) { CHECK_NUMBER (Vx_window_horizontal_drag_shape); horizontal_drag_cursor = XCreateFontCursor (dpy, XINT (Vx_window_horizontal_drag_shape)); } else horizontal_drag_cursor = XCreateFontCursor (dpy, XC_sb_h_double_arrow); /* Check and report errors with the above calls. */ x_check_errors (dpy, "can't set cursor shape: %s"); x_uncatch_errors (dpy, count); { XColor fore_color, back_color; fore_color.pixel = x->mouse_pixel; x_query_color (f, &fore_color); back_color.pixel = mask_color; x_query_color (f, &back_color); XRecolorCursor (dpy, cursor, &fore_color, &back_color); XRecolorCursor (dpy, nontext_cursor, &fore_color, &back_color); XRecolorCursor (dpy, mode_cursor, &fore_color, &back_color); XRecolorCursor (dpy, hand_cursor, &fore_color, &back_color); XRecolorCursor (dpy, hourglass_cursor, &fore_color, &back_color); XRecolorCursor (dpy, horizontal_drag_cursor, &fore_color, &back_color); } if (FRAME_X_WINDOW (f) != 0) XDefineCursor (dpy, FRAME_X_WINDOW (f), cursor); if (cursor != x->text_cursor && x->text_cursor != 0) XFreeCursor (dpy, x->text_cursor); x->text_cursor = cursor; if (nontext_cursor != x->nontext_cursor && x->nontext_cursor != 0) XFreeCursor (dpy, x->nontext_cursor); x->nontext_cursor = nontext_cursor; if (hourglass_cursor != x->hourglass_cursor && x->hourglass_cursor != 0) XFreeCursor (dpy, x->hourglass_cursor); x->hourglass_cursor = hourglass_cursor; if (mode_cursor != x->modeline_cursor && x->modeline_cursor != 0) XFreeCursor (dpy, f->output_data.x->modeline_cursor); x->modeline_cursor = mode_cursor; if (hand_cursor != x->hand_cursor && x->hand_cursor != 0) XFreeCursor (dpy, x->hand_cursor); x->hand_cursor = hand_cursor; if (horizontal_drag_cursor != x->horizontal_drag_cursor && x->horizontal_drag_cursor != 0) XFreeCursor (dpy, x->horizontal_drag_cursor); x->horizontal_drag_cursor = horizontal_drag_cursor; XFlush (dpy); UNBLOCK_INPUT; update_face_from_frame_parameter (f, Qmouse_color, arg); } void x_set_cursor_color (f, arg, oldval) struct frame *f; Lisp_Object arg, oldval; { unsigned long fore_pixel, pixel; int fore_pixel_allocated_p = 0, pixel_allocated_p = 0; struct x_output *x = f->output_data.x; if (!NILP (Vx_cursor_fore_pixel)) { fore_pixel = x_decode_color (f, Vx_cursor_fore_pixel, WHITE_PIX_DEFAULT (f)); fore_pixel_allocated_p = 1; } else fore_pixel = x->background_pixel; pixel = x_decode_color (f, arg, BLACK_PIX_DEFAULT (f)); pixel_allocated_p = 1; /* Make sure that the cursor color differs from the background color. */ if (pixel == x->background_pixel) { if (pixel_allocated_p) { x_free_colors (f, &pixel, 1); pixel_allocated_p = 0; } pixel = x->mouse_pixel; if (pixel == fore_pixel) { if (fore_pixel_allocated_p) { x_free_colors (f, &fore_pixel, 1); fore_pixel_allocated_p = 0; } fore_pixel = x->background_pixel; } } unload_color (f, x->cursor_foreground_pixel); if (!fore_pixel_allocated_p) fore_pixel = x_copy_color (f, fore_pixel); x->cursor_foreground_pixel = fore_pixel; unload_color (f, x->cursor_pixel); if (!pixel_allocated_p) pixel = x_copy_color (f, pixel); x->cursor_pixel = pixel; if (FRAME_X_WINDOW (f) != 0) { BLOCK_INPUT; XSetBackground (FRAME_X_DISPLAY (f), x->cursor_gc, x->cursor_pixel); XSetForeground (FRAME_X_DISPLAY (f), x->cursor_gc, fore_pixel); UNBLOCK_INPUT; if (FRAME_VISIBLE_P (f)) { x_update_cursor (f, 0); x_update_cursor (f, 1); } } update_face_from_frame_parameter (f, Qcursor_color, arg); } /* Set the border-color of frame F to pixel value PIX. Note that this does not fully take effect if done before F has an x-window. */ void x_set_border_pixel (f, pix) struct frame *f; int pix; { unload_color (f, f->output_data.x->border_pixel); f->output_data.x->border_pixel = pix; if (FRAME_X_WINDOW (f) != 0 && f->border_width > 0) { BLOCK_INPUT; XSetWindowBorder (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), (unsigned long)pix); UNBLOCK_INPUT; if (FRAME_VISIBLE_P (f)) redraw_frame (f); } } /* Set the border-color of frame F to value described by ARG. ARG can be a string naming a color. The border-color is used for the border that is drawn by the X server. Note that this does not fully take effect if done before F has an x-window; it must be redone when the window is created. Note: this is done in two routines because of the way X10 works. Note: under X11, this is normally the province of the window manager, and so emacs' border colors may be overridden. */ void x_set_border_color (f, arg, oldval) struct frame *f; Lisp_Object arg, oldval; { int pix; CHECK_STRING (arg); pix = x_decode_color (f, arg, BLACK_PIX_DEFAULT (f)); x_set_border_pixel (f, pix); update_face_from_frame_parameter (f, Qborder_color, arg); } void x_set_cursor_type (f, arg, oldval) FRAME_PTR f; Lisp_Object arg, oldval; { set_frame_cursor_types (f, arg); /* Make sure the cursor gets redrawn. */ cursor_type_changed = 1; } void x_set_icon_type (f, arg, oldval) struct frame *f; Lisp_Object arg, oldval; { int result; if (STRINGP (arg)) { if (STRINGP (oldval) && EQ (Fstring_equal (oldval, arg), Qt)) return; } else if (!STRINGP (oldval) && EQ (oldval, Qnil) == EQ (arg, Qnil)) return; BLOCK_INPUT; if (NILP (arg)) result = x_text_icon (f, (char *) SDATA ((!NILP (f->icon_name) ? f->icon_name : f->name))); else result = x_bitmap_icon (f, arg); if (result) { UNBLOCK_INPUT; error ("No icon window available"); } XFlush (FRAME_X_DISPLAY (f)); UNBLOCK_INPUT; } void x_set_icon_name (f, arg, oldval) struct frame *f; Lisp_Object arg, oldval; { int result; if (STRINGP (arg)) { if (STRINGP (oldval) && EQ (Fstring_equal (oldval, arg), Qt)) return; } else if (!STRINGP (oldval) && EQ (oldval, Qnil) == EQ (arg, Qnil)) return; f->icon_name = arg; if (f->output_data.x->icon_bitmap != 0) return; BLOCK_INPUT; result = x_text_icon (f, (char *) SDATA ((!NILP (f->icon_name) ? f->icon_name : !NILP (f->title) ? f->title : f->name))); if (result) { UNBLOCK_INPUT; error ("No icon window available"); } XFlush (FRAME_X_DISPLAY (f)); UNBLOCK_INPUT; } void x_set_menu_bar_lines (f, value, oldval) struct frame *f; Lisp_Object value, oldval; { int nlines; #ifndef USE_X_TOOLKIT int olines = FRAME_MENU_BAR_LINES (f); #endif /* Right now, menu bars don't work properly in minibuf-only frames; most of the commands try to apply themselves to the minibuffer frame itself, and get an error because you can't switch buffers in or split the minibuffer window. */ if (FRAME_MINIBUF_ONLY_P (f)) return; if (INTEGERP (value)) nlines = XINT (value); else nlines = 0; /* Make sure we redisplay all windows in this frame. */ windows_or_buffers_changed++; #if defined (USE_X_TOOLKIT) || defined (USE_GTK) FRAME_MENU_BAR_LINES (f) = 0; if (nlines) { FRAME_EXTERNAL_MENU_BAR (f) = 1; if (FRAME_X_P (f) && f->output_data.x->menubar_widget == 0) /* Make sure next redisplay shows the menu bar. */ XWINDOW (FRAME_SELECTED_WINDOW (f))->update_mode_line = Qt; } else { if (FRAME_EXTERNAL_MENU_BAR (f) == 1) free_frame_menubar (f); FRAME_EXTERNAL_MENU_BAR (f) = 0; if (FRAME_X_P (f)) f->output_data.x->menubar_widget = 0; } #else /* not USE_X_TOOLKIT && not USE_GTK */ FRAME_MENU_BAR_LINES (f) = nlines; change_window_heights (f->root_window, nlines - olines); #endif /* not USE_X_TOOLKIT */ adjust_glyphs (f); } /* Set the number of lines used for the tool bar of frame F to VALUE. VALUE not an integer, or < 0 means set the lines to zero. OLDVAL is the old number of tool bar lines. This function changes the height of all windows on frame F to match the new tool bar height. The frame's height doesn't change. */ void x_set_tool_bar_lines (f, value, oldval) struct frame *f; Lisp_Object value, oldval; { int delta, nlines, root_height; Lisp_Object root_window; /* Treat tool bars like menu bars. */ if (FRAME_MINIBUF_ONLY_P (f)) return; /* Use VALUE only if an integer >= 0. */ if (INTEGERP (value) && XINT (value) >= 0) nlines = XFASTINT (value); else nlines = 0; #ifdef USE_GTK FRAME_TOOL_BAR_LINES (f) = 0; if (nlines) { FRAME_EXTERNAL_TOOL_BAR (f) = 1; if (FRAME_X_P (f) && f->output_data.x->toolbar_widget == 0) /* Make sure next redisplay shows the tool bar. */ XWINDOW (FRAME_SELECTED_WINDOW (f))->update_mode_line = Qt; update_frame_tool_bar (f); } else { if (FRAME_EXTERNAL_TOOL_BAR (f)) free_frame_tool_bar (f); FRAME_EXTERNAL_TOOL_BAR (f) = 0; } return; #endif /* Make sure we redisplay all windows in this frame. */ ++windows_or_buffers_changed; delta = nlines - FRAME_TOOL_BAR_LINES (f); /* Don't resize the tool-bar to more than we have room for. */ root_window = FRAME_ROOT_WINDOW (f); root_height = WINDOW_TOTAL_LINES (XWINDOW (root_window)); if (root_height - delta < 1) { delta = root_height - 1; nlines = FRAME_TOOL_BAR_LINES (f) + delta; } FRAME_TOOL_BAR_LINES (f) = nlines; change_window_heights (root_window, delta); adjust_glyphs (f); /* We also have to make sure that the internal border at the top of the frame, below the menu bar or tool bar, is redrawn when the tool bar disappears. This is so because the internal border is below the tool bar if one is displayed, but is below the menu bar if there isn't a tool bar. The tool bar draws into the area below the menu bar. */ if (FRAME_X_WINDOW (f) && FRAME_TOOL_BAR_LINES (f) == 0) { updating_frame = f; clear_frame (); clear_current_matrices (f); updating_frame = NULL; } /* If the tool bar gets smaller, the internal border below it has to be cleared. It was formerly part of the display of the larger tool bar, and updating windows won't clear it. */ if (delta < 0) { int height = FRAME_INTERNAL_BORDER_WIDTH (f); int width = FRAME_PIXEL_WIDTH (f); int y = nlines * FRAME_LINE_HEIGHT (f); BLOCK_INPUT; x_clear_area (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), 0, y, width, height, False); UNBLOCK_INPUT; if (WINDOWP (f->tool_bar_window)) clear_glyph_matrix (XWINDOW (f->tool_bar_window)->current_matrix); } } /* Set the foreground color for scroll bars on frame F to VALUE. VALUE should be a string, a color name. If it isn't a string or isn't a valid color name, do nothing. OLDVAL is the old value of the frame parameter. */ void x_set_scroll_bar_foreground (f, value, oldval) struct frame *f; Lisp_Object value, oldval; { unsigned long pixel; if (STRINGP (value)) pixel = x_decode_color (f, value, BLACK_PIX_DEFAULT (f)); else pixel = -1; if (f->output_data.x->scroll_bar_foreground_pixel != -1) unload_color (f, f->output_data.x->scroll_bar_foreground_pixel); f->output_data.x->scroll_bar_foreground_pixel = pixel; if (FRAME_X_WINDOW (f) && FRAME_VISIBLE_P (f)) { /* Remove all scroll bars because they have wrong colors. */ if (condemn_scroll_bars_hook) (*condemn_scroll_bars_hook) (f); if (judge_scroll_bars_hook) (*judge_scroll_bars_hook) (f); update_face_from_frame_parameter (f, Qscroll_bar_foreground, value); redraw_frame (f); } } /* Set the background color for scroll bars on frame F to VALUE VALUE should be a string, a color name. If it isn't a string or isn't a valid color name, do nothing. OLDVAL is the old value of the frame parameter. */ void x_set_scroll_bar_background (f, value, oldval) struct frame *f; Lisp_Object value, oldval; { unsigned long pixel; if (STRINGP (value)) pixel = x_decode_color (f, value, WHITE_PIX_DEFAULT (f)); else pixel = -1; if (f->output_data.x->scroll_bar_background_pixel != -1) unload_color (f, f->output_data.x->scroll_bar_background_pixel); #ifdef USE_TOOLKIT_SCROLL_BARS /* Scrollbar shadow colors. */ if (f->output_data.x->scroll_bar_top_shadow_pixel != -1) { unload_color (f, f->output_data.x->scroll_bar_top_shadow_pixel); f->output_data.x->scroll_bar_top_shadow_pixel = -1; } if (f->output_data.x->scroll_bar_bottom_shadow_pixel != -1) { unload_color (f, f->output_data.x->scroll_bar_bottom_shadow_pixel); f->output_data.x->scroll_bar_bottom_shadow_pixel = -1; } #endif /* USE_TOOLKIT_SCROLL_BARS */ f->output_data.x->scroll_bar_background_pixel = pixel; if (FRAME_X_WINDOW (f) && FRAME_VISIBLE_P (f)) { /* Remove all scroll bars because they have wrong colors. */ if (condemn_scroll_bars_hook) (*condemn_scroll_bars_hook) (f); if (judge_scroll_bars_hook) (*judge_scroll_bars_hook) (f); update_face_from_frame_parameter (f, Qscroll_bar_background, value); redraw_frame (f); } } /* Encode Lisp string STRING as a text in a format appropriate for XICCC (X Inter Client Communication Conventions). If STRING contains only ASCII characters, do no conversion and return the string data of STRING. Otherwise, encode the text by CODING_SYSTEM, and return a newly allocated memory area which should be freed by `xfree' by a caller. SELECTIONP non-zero means the string is being encoded for an X selection, so it is safe to run pre-write conversions (which may run Lisp code). Store the byte length of resulting text in *TEXT_BYTES. If the text contains only ASCII and Latin-1, store 1 in *STRING_P, which means that the `encoding' of the result can be `STRING'. Otherwise store 0 in *STRINGP, which means that the `encoding' of the result should be `COMPOUND_TEXT'. */ unsigned char * x_encode_text (string, coding_system, selectionp, text_bytes, stringp) Lisp_Object string, coding_system; int *text_bytes, *stringp; int selectionp; { unsigned char *str = SDATA (string); int chars = SCHARS (string); int bytes = SBYTES (string); int charset_info; int bufsize; unsigned char *buf; struct coding_system coding; extern Lisp_Object Qcompound_text_with_extensions; charset_info = find_charset_in_text (str, chars, bytes, NULL, Qnil); if (charset_info == 0) { /* No multibyte character in OBJ. We need not encode it. */ *text_bytes = bytes; *stringp = 1; return str; } setup_coding_system (coding_system, &coding); if (selectionp && SYMBOLP (coding.pre_write_conversion) && !NILP (Ffboundp (coding.pre_write_conversion))) { string = run_pre_post_conversion_on_str (string, &coding, 1); str = SDATA (string); chars = SCHARS (string); bytes = SBYTES (string); } coding.src_multibyte = 1; coding.dst_multibyte = 0; coding.mode |= CODING_MODE_LAST_BLOCK; if (coding.type == coding_type_iso2022) coding.flags |= CODING_FLAG_ISO_SAFE; /* We suppress producing escape sequences for composition. */ coding.composing = COMPOSITION_DISABLED; bufsize = encoding_buffer_size (&coding, bytes); buf = (unsigned char *) xmalloc (bufsize); encode_coding (&coding, str, buf, bytes, bufsize); *text_bytes = coding.produced; *stringp = (charset_info == 1 || (!EQ (coding_system, Qcompound_text) && !EQ (coding_system, Qcompound_text_with_extensions))); return buf; } /* Change the name of frame F to NAME. If NAME is nil, set F's name to x_id_name. If EXPLICIT is non-zero, that indicates that lisp code is setting the name; if NAME is a string, set F's name to NAME and set F->explicit_name; if NAME is Qnil, then clear F->explicit_name. If EXPLICIT is zero, that indicates that Emacs redisplay code is suggesting a new name, which lisp code should override; if F->explicit_name is set, ignore the new name; otherwise, set it. */ void x_set_name (f, name, explicit) struct frame *f; Lisp_Object name; int explicit; { /* Make sure that requests from lisp code override requests from Emacs redisplay code. */ if (explicit) { /* If we're switching from explicit to implicit, we had better update the mode lines and thereby update the title. */ if (f->explicit_name && NILP (name)) update_mode_lines = 1; f->explicit_name = ! NILP (name); } else if (f->explicit_name) return; /* If NAME is nil, set the name to the x_id_name. */ if (NILP (name)) { /* Check for no change needed in this very common case before we do any consing. */ if (!strcmp (FRAME_X_DISPLAY_INFO (f)->x_id_name, SDATA (f->name))) return; name = build_string (FRAME_X_DISPLAY_INFO (f)->x_id_name); } else CHECK_STRING (name); /* Don't change the name if it's already NAME. */ if (! NILP (Fstring_equal (name, f->name))) return; f->name = name; /* For setting the frame title, the title parameter should override the name parameter. */ if (! NILP (f->title)) name = f->title; if (FRAME_X_WINDOW (f)) { BLOCK_INPUT; #ifdef HAVE_X11R4 { XTextProperty text, icon; int bytes, stringp; Lisp_Object coding_system; /* Note: Encoding strategy We encode NAME by compound-text and use "COMPOUND-TEXT" in text.encoding. But, there are non-internationalized window managers which don't support that encoding. So, if NAME contains only ASCII and 8859-1 characters, encode it by iso-latin-1, and use "STRING" in text.encoding hoping that such window manager at least analize this format correctly, i.e. treat 8-bit bytes as 8859-1 characters. We may also be able to use "UTF8_STRING" in text.encoding in the feature which can encode all Unicode characters. But, for the moment, there's no way to know that the current window manager supports it or not. */ coding_system = Qcompound_text; text.value = x_encode_text (name, coding_system, 0, &bytes, &stringp); text.encoding = (stringp ? XA_STRING : FRAME_X_DISPLAY_INFO (f)->Xatom_COMPOUND_TEXT); text.format = 8; text.nitems = bytes; if (NILP (f->icon_name)) { icon = text; } else { /* See the above comment "Note: Encoding strategy". */ icon.value = x_encode_text (f->icon_name, coding_system, 0, &bytes, &stringp); icon.encoding = (stringp ? XA_STRING : FRAME_X_DISPLAY_INFO (f)->Xatom_COMPOUND_TEXT); icon.format = 8; icon.nitems = bytes; } #ifdef USE_GTK gtk_window_set_title (GTK_WINDOW (FRAME_GTK_OUTER_WIDGET (f)), SDATA (name)); #else /* not USE_GTK */ XSetWMName (FRAME_X_DISPLAY (f), FRAME_OUTER_WINDOW (f), &text); #endif /* not USE_GTK */ XSetWMIconName (FRAME_X_DISPLAY (f), FRAME_OUTER_WINDOW (f), &icon); if (!NILP (f->icon_name) && icon.value != (unsigned char *) SDATA (f->icon_name)) xfree (icon.value); if (text.value != (unsigned char *) SDATA (name)) xfree (text.value); } #else /* not HAVE_X11R4 */ XSetIconName (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), SDATA (name)); XStoreName (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), SDATA (name)); #endif /* not HAVE_X11R4 */ UNBLOCK_INPUT; } } /* This function should be called when the user's lisp code has specified a name for the frame; the name will override any set by the redisplay code. */ void x_explicitly_set_name (f, arg, oldval) FRAME_PTR f; Lisp_Object arg, oldval; { x_set_name (f, arg, 1); } /* This function should be called by Emacs redisplay code to set the name; names set this way will never override names set by the user's lisp code. */ void x_implicitly_set_name (f, arg, oldval) FRAME_PTR f; Lisp_Object arg, oldval; { x_set_name (f, arg, 0); } /* Change the title of frame F to NAME. If NAME is nil, use the frame name as the title. If EXPLICIT is non-zero, that indicates that lisp code is setting the name; if NAME is a string, set F's name to NAME and set F->explicit_name; if NAME is Qnil, then clear F->explicit_name. If EXPLICIT is zero, that indicates that Emacs redisplay code is suggesting a new name, which lisp code should override; if F->explicit_name is set, ignore the new name; otherwise, set it. */ void x_set_title (f, name, old_name) struct frame *f; Lisp_Object name, old_name; { /* Don't change the title if it's already NAME. */ if (EQ (name, f->title)) return; update_mode_lines = 1; f->title = name; if (NILP (name)) name = f->name; else CHECK_STRING (name); if (FRAME_X_WINDOW (f)) { BLOCK_INPUT; #ifdef HAVE_X11R4 { XTextProperty text, icon; int bytes, stringp; Lisp_Object coding_system; coding_system = Qcompound_text; /* See the comment "Note: Encoding strategy" in x_set_name. */ text.value = x_encode_text (name, coding_system, 0, &bytes, &stringp); text.encoding = (stringp ? XA_STRING : FRAME_X_DISPLAY_INFO (f)->Xatom_COMPOUND_TEXT); text.format = 8; text.nitems = bytes; if (NILP (f->icon_name)) { icon = text; } else { /* See the comment "Note: Encoding strategy" in x_set_name. */ icon.value = x_encode_text (f->icon_name, coding_system, 0, &bytes, &stringp); icon.encoding = (stringp ? XA_STRING : FRAME_X_DISPLAY_INFO (f)->Xatom_COMPOUND_TEXT); icon.format = 8; icon.nitems = bytes; } #ifdef USE_GTK gtk_window_set_title (GTK_WINDOW (FRAME_GTK_OUTER_WIDGET (f)), SDATA (name)); #else /* not USE_GTK */ XSetWMName (FRAME_X_DISPLAY (f), FRAME_OUTER_WINDOW (f), &text); #endif /* not USE_GTK */ XSetWMIconName (FRAME_X_DISPLAY (f), FRAME_OUTER_WINDOW (f), &icon); if (!NILP (f->icon_name) && icon.value != (unsigned char *) SDATA (f->icon_name)) xfree (icon.value); if (text.value != (unsigned char *) SDATA (name)) xfree (text.value); } #else /* not HAVE_X11R4 */ XSetIconName (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), SDATA (name)); XStoreName (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), SDATA (name)); #endif /* not HAVE_X11R4 */ UNBLOCK_INPUT; } } void x_set_scroll_bar_default_width (f) struct frame *f; { int wid = FRAME_COLUMN_WIDTH (f); #ifdef USE_TOOLKIT_SCROLL_BARS /* A minimum width of 14 doesn't look good for toolkit scroll bars. */ int width = 16 + 2 * VERTICAL_SCROLL_BAR_WIDTH_TRIM; FRAME_CONFIG_SCROLL_BAR_COLS (f) = (width + wid - 1) / wid; FRAME_CONFIG_SCROLL_BAR_WIDTH (f) = width; #else /* Make the actual width at least 14 pixels and a multiple of a character width. */ FRAME_CONFIG_SCROLL_BAR_COLS (f) = (14 + wid - 1) / wid; /* Use all of that space (aside from required margins) for the scroll bar. */ FRAME_CONFIG_SCROLL_BAR_WIDTH (f) = 0; #endif } /* Record in frame F the specified or default value according to ALIST of the parameter named PROP (a Lisp symbol). If no value is specified for PROP, look for an X default for XPROP on the frame named NAME. If that is not found either, use the value DEFLT. */ static Lisp_Object x_default_scroll_bar_color_parameter (f, alist, prop, xprop, xclass, foreground_p) struct frame *f; Lisp_Object alist; Lisp_Object prop; char *xprop; char *xclass; int foreground_p; { struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (f); Lisp_Object tem; tem = x_get_arg (dpyinfo, alist, prop, xprop, xclass, RES_TYPE_STRING); if (EQ (tem, Qunbound)) { #ifdef USE_TOOLKIT_SCROLL_BARS /* See if an X resource for the scroll bar color has been specified. */ tem = display_x_get_resource (dpyinfo, build_string (foreground_p ? "foreground" : "background"), empty_string, build_string ("verticalScrollBar"), empty_string); if (!STRINGP (tem)) { /* If nothing has been specified, scroll bars will use a toolkit-dependent default. Because these defaults are difficult to get at without actually creating a scroll bar, use nil to indicate that no color has been specified. */ tem = Qnil; } #else /* not USE_TOOLKIT_SCROLL_BARS */ tem = Qnil; #endif /* not USE_TOOLKIT_SCROLL_BARS */ } x_set_frame_parameters (f, Fcons (Fcons (prop, tem), Qnil)); return tem; } #if !defined (HAVE_X11R4) && !defined (HAVE_XSETWMPROTOCOLS) Status XSetWMProtocols (dpy, w, protocols, count) Display *dpy; Window w; Atom *protocols; int count; { Atom prop; prop = XInternAtom (dpy, "WM_PROTOCOLS", False); if (prop == None) return False; XChangeProperty (dpy, w, prop, XA_ATOM, 32, PropModeReplace, (unsigned char *) protocols, count); return True; } #endif /* not HAVE_X11R4 && not HAVE_XSETWMPROTOCOLS */ #ifdef USE_X_TOOLKIT /* If the WM_PROTOCOLS property does not already contain WM_TAKE_FOCUS, WM_DELETE_WINDOW, and WM_SAVE_YOURSELF, then add them. (They may already be present because of the toolkit (Motif adds some of them, for example, but Xt doesn't). */ static void hack_wm_protocols (f, widget) FRAME_PTR f; Widget widget; { Display *dpy = XtDisplay (widget); Window w = XtWindow (widget); int need_delete = 1; int need_focus = 1; int need_save = 1; BLOCK_INPUT; { Atom type, *atoms = 0; int format = 0; unsigned long nitems = 0; unsigned long bytes_after; if ((XGetWindowProperty (dpy, w, FRAME_X_DISPLAY_INFO (f)->Xatom_wm_protocols, (long)0, (long)100, False, XA_ATOM, &type, &format, &nitems, &bytes_after, (unsigned char **) &atoms) == Success) && format == 32 && type == XA_ATOM) while (nitems > 0) { nitems--; if (atoms[nitems] == FRAME_X_DISPLAY_INFO (f)->Xatom_wm_delete_window) need_delete = 0; else if (atoms[nitems] == FRAME_X_DISPLAY_INFO (f)->Xatom_wm_take_focus) need_focus = 0; else if (atoms[nitems] == FRAME_X_DISPLAY_INFO (f)->Xatom_wm_save_yourself) need_save = 0; } if (atoms) XFree ((char *) atoms); } { Atom props [10]; int count = 0; if (need_delete) props[count++] = FRAME_X_DISPLAY_INFO (f)->Xatom_wm_delete_window; if (need_focus) props[count++] = FRAME_X_DISPLAY_INFO (f)->Xatom_wm_take_focus; if (need_save) props[count++] = FRAME_X_DISPLAY_INFO (f)->Xatom_wm_save_yourself; if (count) XChangeProperty (dpy, w, FRAME_X_DISPLAY_INFO (f)->Xatom_wm_protocols, XA_ATOM, 32, PropModeAppend, (unsigned char *) props, count); } UNBLOCK_INPUT; } #endif /* Support routines for XIC (X Input Context). */ #ifdef HAVE_X_I18N static XFontSet xic_create_xfontset P_ ((struct frame *, char *)); static XIMStyle best_xim_style P_ ((XIMStyles *, XIMStyles *)); /* Supported XIM styles, ordered by preference. */ static XIMStyle supported_xim_styles[] = { XIMPreeditPosition | XIMStatusArea, XIMPreeditPosition | XIMStatusNothing, XIMPreeditPosition | XIMStatusNone, XIMPreeditNothing | XIMStatusArea, XIMPreeditNothing | XIMStatusNothing, XIMPreeditNothing | XIMStatusNone, XIMPreeditNone | XIMStatusArea, XIMPreeditNone | XIMStatusNothing, XIMPreeditNone | XIMStatusNone, 0, }; /* Create an X fontset on frame F with base font name BASE_FONTNAME.. */ static XFontSet xic_create_xfontset (f, base_fontname) struct frame *f; char *base_fontname; { XFontSet xfs; char **missing_list; int missing_count; char *def_string; xfs = XCreateFontSet (FRAME_X_DISPLAY (f), base_fontname, &missing_list, &missing_count, &def_string); if (missing_list) XFreeStringList (missing_list); /* No need to free def_string. */ return xfs; } /* Value is the best input style, given user preferences USER (already checked to be supported by Emacs), and styles supported by the input method XIM. */ static XIMStyle best_xim_style (user, xim) XIMStyles *user; XIMStyles *xim; { int i, j; for (i = 0; i < user->count_styles; ++i) for (j = 0; j < xim->count_styles; ++j) if (user->supported_styles[i] == xim->supported_styles[j]) return user->supported_styles[i]; /* Return the default style. */ return XIMPreeditNothing | XIMStatusNothing; } /* Create XIC for frame F. */ static XIMStyle xic_style; void create_frame_xic (f) struct frame *f; { XIM xim; XIC xic = NULL; XFontSet xfs = NULL; if (FRAME_XIC (f)) return; xim = FRAME_X_XIM (f); if (xim) { XRectangle s_area; XPoint spot; XVaNestedList preedit_attr; XVaNestedList status_attr; char *base_fontname; int fontset; s_area.x = 0; s_area.y = 0; s_area.width = 1; s_area.height = 1; spot.x = 0; spot.y = 1; /* Create X fontset. */ fontset = FRAME_FONTSET (f); if (fontset < 0) base_fontname = "-*-*-*-r-normal--14-*-*-*-*-*-*-*"; else { /* Determine the base fontname from the ASCII font name of FONTSET. */ char *ascii_font = (char *) SDATA (fontset_ascii (fontset)); char *p = ascii_font; int i; for (i = 0; *p; p++) if (*p == '-') i++; if (i != 14) /* As the font name doesn't conform to XLFD, we can't modify it to get a suitable base fontname for the frame. */ base_fontname = "-*-*-*-r-normal--14-*-*-*-*-*-*-*"; else { int len = strlen (ascii_font) + 1; char *p1 = NULL; for (i = 0, p = ascii_font; i < 8; p++) { if (*p == '-') { i++; if (i == 3) p1 = p + 1; } } base_fontname = (char *) alloca (len); bzero (base_fontname, len); strcpy (base_fontname, "-*-*-"); bcopy (p1, base_fontname + 5, p - p1); strcat (base_fontname, "*-*-*-*-*-*-*"); } } xfs = xic_create_xfontset (f, base_fontname); /* Determine XIC style. */ if (xic_style == 0) { XIMStyles supported_list; supported_list.count_styles = (sizeof supported_xim_styles / sizeof supported_xim_styles[0]); supported_list.supported_styles = supported_xim_styles; xic_style = best_xim_style (&supported_list, FRAME_X_XIM_STYLES (f)); } preedit_attr = XVaCreateNestedList (0, XNFontSet, xfs, XNForeground, FRAME_FOREGROUND_PIXEL (f), XNBackground, FRAME_BACKGROUND_PIXEL (f), (xic_style & XIMPreeditPosition ? XNSpotLocation : NULL), &spot, NULL); status_attr = XVaCreateNestedList (0, XNArea, &s_area, XNFontSet, xfs, XNForeground, FRAME_FOREGROUND_PIXEL (f), XNBackground, FRAME_BACKGROUND_PIXEL (f), NULL); xic = XCreateIC (xim, XNInputStyle, xic_style, XNClientWindow, FRAME_X_WINDOW(f), XNFocusWindow, FRAME_X_WINDOW(f), XNStatusAttributes, status_attr, XNPreeditAttributes, preedit_attr, NULL); XFree (preedit_attr); XFree (status_attr); } FRAME_XIC (f) = xic; FRAME_XIC_STYLE (f) = xic_style; FRAME_XIC_FONTSET (f) = xfs; } /* Destroy XIC and free XIC fontset of frame F, if any. */ void free_frame_xic (f) struct frame *f; { if (FRAME_XIC (f) == NULL) return; XDestroyIC (FRAME_XIC (f)); if (FRAME_XIC_FONTSET (f)) XFreeFontSet (FRAME_X_DISPLAY (f), FRAME_XIC_FONTSET (f)); FRAME_XIC (f) = NULL; FRAME_XIC_FONTSET (f) = NULL; } /* Place preedit area for XIC of window W's frame to specified pixel position X/Y. X and Y are relative to window W. */ void xic_set_preeditarea (w, x, y) struct window *w; int x, y; { struct frame *f = XFRAME (w->frame); XVaNestedList attr; XPoint spot; spot.x = WINDOW_TO_FRAME_PIXEL_X (w, x); spot.y = WINDOW_TO_FRAME_PIXEL_Y (w, y) + FONT_BASE (FRAME_FONT (f)); attr = XVaCreateNestedList (0, XNSpotLocation, &spot, NULL); XSetICValues (FRAME_XIC (f), XNPreeditAttributes, attr, NULL); XFree (attr); } /* Place status area for XIC in bottom right corner of frame F.. */ void xic_set_statusarea (f) struct frame *f; { XIC xic = FRAME_XIC (f); XVaNestedList attr; XRectangle area; XRectangle *needed; /* Negotiate geometry of status area. If input method has existing status area, use its current size. */ area.x = area.y = area.width = area.height = 0; attr = XVaCreateNestedList (0, XNAreaNeeded, &area, NULL); XSetICValues (xic, XNStatusAttributes, attr, NULL); XFree (attr); attr = XVaCreateNestedList (0, XNAreaNeeded, &needed, NULL); XGetICValues (xic, XNStatusAttributes, attr, NULL); XFree (attr); if (needed->width == 0) /* Use XNArea instead of XNAreaNeeded */ { attr = XVaCreateNestedList (0, XNArea, &needed, NULL); XGetICValues (xic, XNStatusAttributes, attr, NULL); XFree (attr); } area.width = needed->width; area.height = needed->height; area.x = FRAME_PIXEL_WIDTH (f) - area.width - FRAME_INTERNAL_BORDER_WIDTH (f); area.y = (FRAME_PIXEL_HEIGHT (f) - area.height - FRAME_MENUBAR_HEIGHT (f) - FRAME_TOOLBAR_HEIGHT (f) - FRAME_INTERNAL_BORDER_WIDTH (f)); XFree (needed); attr = XVaCreateNestedList (0, XNArea, &area, NULL); XSetICValues(xic, XNStatusAttributes, attr, NULL); XFree (attr); } /* Set X fontset for XIC of frame F, using base font name BASE_FONTNAME. Called when a new Emacs fontset is chosen. */ void xic_set_xfontset (f, base_fontname) struct frame *f; char *base_fontname; { XVaNestedList attr; XFontSet xfs; xfs = xic_create_xfontset (f, base_fontname); attr = XVaCreateNestedList (0, XNFontSet, xfs, NULL); if (FRAME_XIC_STYLE (f) & XIMPreeditPosition) XSetICValues (FRAME_XIC (f), XNPreeditAttributes, attr, NULL); if (FRAME_XIC_STYLE (f) & XIMStatusArea) XSetICValues (FRAME_XIC (f), XNStatusAttributes, attr, NULL); XFree (attr); if (FRAME_XIC_FONTSET (f)) XFreeFontSet (FRAME_X_DISPLAY (f), FRAME_XIC_FONTSET (f)); FRAME_XIC_FONTSET (f) = xfs; } #endif /* HAVE_X_I18N */ #ifdef USE_X_TOOLKIT /* Create and set up the X widget for frame F. */ static void x_window (f, window_prompting, minibuffer_only) struct frame *f; long window_prompting; int minibuffer_only; { XClassHint class_hints; XSetWindowAttributes attributes; unsigned long attribute_mask; Widget shell_widget; Widget pane_widget; Widget frame_widget; Arg al [25]; int ac; BLOCK_INPUT; /* Use the resource name as the top-level widget name for looking up resources. Make a non-Lisp copy for the window manager, so GC relocation won't bother it. Elsewhere we specify the window name for the window manager. */ { char *str = (char *) SDATA (Vx_resource_name); f->namebuf = (char *) xmalloc (strlen (str) + 1); strcpy (f->namebuf, str); } ac = 0; XtSetArg (al[ac], XtNallowShellResize, 1); ac++; XtSetArg (al[ac], XtNinput, 1); ac++; XtSetArg (al[ac], XtNmappedWhenManaged, 0); ac++; XtSetArg (al[ac], XtNborderWidth, f->border_width); ac++; XtSetArg (al[ac], XtNvisual, FRAME_X_VISUAL (f)); ac++; XtSetArg (al[ac], XtNdepth, FRAME_X_DISPLAY_INFO (f)->n_planes); ac++; XtSetArg (al[ac], XtNcolormap, FRAME_X_COLORMAP (f)); ac++; shell_widget = XtAppCreateShell (f->namebuf, EMACS_CLASS, applicationShellWidgetClass, FRAME_X_DISPLAY (f), al, ac); f->output_data.x->widget = shell_widget; /* maybe_set_screen_title_format (shell_widget); */ pane_widget = lw_create_widget ("main", "pane", widget_id_tick++, (widget_value *) NULL, shell_widget, False, (lw_callback) NULL, (lw_callback) NULL, (lw_callback) NULL, (lw_callback) NULL); ac = 0; XtSetArg (al[ac], XtNvisual, FRAME_X_VISUAL (f)); ac++; XtSetArg (al[ac], XtNdepth, FRAME_X_DISPLAY_INFO (f)->n_planes); ac++; XtSetArg (al[ac], XtNcolormap, FRAME_X_COLORMAP (f)); ac++; XtSetValues (pane_widget, al, ac); f->output_data.x->column_widget = pane_widget; /* mappedWhenManaged to false tells to the paned window to not map/unmap the emacs screen when changing menubar. This reduces flickering. */ ac = 0; XtSetArg (al[ac], XtNmappedWhenManaged, 0); ac++; XtSetArg (al[ac], XtNshowGrip, 0); ac++; XtSetArg (al[ac], XtNallowResize, 1); ac++; XtSetArg (al[ac], XtNresizeToPreferred, 1); ac++; XtSetArg (al[ac], XtNemacsFrame, f); ac++; XtSetArg (al[ac], XtNvisual, FRAME_X_VISUAL (f)); ac++; XtSetArg (al[ac], XtNdepth, FRAME_X_DISPLAY_INFO (f)->n_planes); ac++; XtSetArg (al[ac], XtNcolormap, FRAME_X_COLORMAP (f)); ac++; frame_widget = XtCreateWidget (f->namebuf, emacsFrameClass, pane_widget, al, ac); f->output_data.x->edit_widget = frame_widget; XtManageChild (frame_widget); /* Do some needed geometry management. */ { int len; char *tem, shell_position[32]; Arg al[2]; int ac = 0; int extra_borders = 0; int menubar_size = (f->output_data.x->menubar_widget ? (f->output_data.x->menubar_widget->core.height + f->output_data.x->menubar_widget->core.border_width) : 0); #if 0 /* Experimentally, we now get the right results for -geometry -0-0 without this. 24 Aug 96, rms. */ if (FRAME_EXTERNAL_MENU_BAR (f)) { Dimension ibw = 0; XtVaGetValues (pane_widget, XtNinternalBorderWidth, &ibw, NULL); menubar_size += ibw; } #endif f->output_data.x->menubar_height = menubar_size; #ifndef USE_LUCID /* Motif seems to need this amount added to the sizes specified for the shell widget. The Athena/Lucid widgets don't. Both conclusions reached experimentally. -- rms. */ XtVaGetValues (f->output_data.x->edit_widget, XtNinternalBorderWidth, &extra_borders, NULL); extra_borders *= 2; #endif /* Convert our geometry parameters into a geometry string and specify it. Note that we do not specify here whether the position is a user-specified or program-specified one. We pass that information later, in x_wm_set_size_hints. */ { int left = f->left_pos; int xneg = window_prompting & XNegative; int top = f->top_pos; int yneg = window_prompting & YNegative; if (xneg) left = -left; if (yneg) top = -top; if (window_prompting & USPosition) sprintf (shell_position, "=%dx%d%c%d%c%d", FRAME_PIXEL_WIDTH (f) + extra_borders, FRAME_PIXEL_HEIGHT (f) + menubar_size + extra_borders, (xneg ? '-' : '+'), left, (yneg ? '-' : '+'), top); else sprintf (shell_position, "=%dx%d", FRAME_PIXEL_WIDTH (f) + extra_borders, FRAME_PIXEL_HEIGHT (f) + menubar_size + extra_borders); } len = strlen (shell_position) + 1; /* We don't free this because we don't know whether it is safe to free it while the frame exists. It isn't worth the trouble of arranging to free it when the frame is deleted. */ tem = (char *) xmalloc (len); strncpy (tem, shell_position, len); XtSetArg (al[ac], XtNgeometry, tem); ac++; XtSetValues (shell_widget, al, ac); } XtManageChild (pane_widget); XtRealizeWidget (shell_widget); FRAME_X_WINDOW (f) = XtWindow (frame_widget); validate_x_resource_name (); class_hints.res_name = (char *) SDATA (Vx_resource_name); class_hints.res_class = (char *) SDATA (Vx_resource_class); XSetClassHint (FRAME_X_DISPLAY (f), XtWindow (shell_widget), &class_hints); #ifdef HAVE_X_I18N FRAME_XIC (f) = NULL; if (use_xim) create_frame_xic (f); #endif f->output_data.x->wm_hints.input = True; f->output_data.x->wm_hints.flags |= InputHint; XSetWMHints (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), &f->output_data.x->wm_hints); hack_wm_protocols (f, shell_widget); #ifdef HACK_EDITRES XtAddEventHandler (shell_widget, 0, True, _XEditResCheckMessages, 0); #endif /* Do a stupid property change to force the server to generate a PropertyNotify event so that the event_stream server timestamp will be initialized to something relevant to the time we created the window. */ XChangeProperty (XtDisplay (frame_widget), XtWindow (frame_widget), FRAME_X_DISPLAY_INFO (f)->Xatom_wm_protocols, XA_ATOM, 32, PropModeAppend, (unsigned char*) NULL, 0); /* Make all the standard events reach the Emacs frame. */ attributes.event_mask = STANDARD_EVENT_SET; #ifdef HAVE_X_I18N if (FRAME_XIC (f)) { /* XIM server might require some X events. */ unsigned long fevent = NoEventMask; XGetICValues(FRAME_XIC (f), XNFilterEvents, &fevent, NULL); attributes.event_mask |= fevent; } #endif /* HAVE_X_I18N */ attribute_mask = CWEventMask; XChangeWindowAttributes (XtDisplay (shell_widget), XtWindow (shell_widget), attribute_mask, &attributes); XtMapWidget (frame_widget); /* x_set_name normally ignores requests to set the name if the requested name is the same as the current name. This is the one place where that assumption isn't correct; f->name is set, but the X server hasn't been told. */ { Lisp_Object name; int explicit = f->explicit_name; f->explicit_name = 0; name = f->name; f->name = Qnil; x_set_name (f, name, explicit); } XDefineCursor (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), f->output_data.x->text_cursor); UNBLOCK_INPUT; /* This is a no-op, except under Motif. Make sure main areas are set to something reasonable, in case we get an error later. */ lw_set_main_areas (pane_widget, 0, frame_widget); } #else /* not USE_X_TOOLKIT */ #ifdef USE_GTK void x_window (f) FRAME_PTR f; { if (! xg_create_frame_widgets (f)) error ("Unable to create window"); #ifdef HAVE_X_I18N FRAME_XIC (f) = NULL; if (use_xim) { BLOCK_INPUT; create_frame_xic (f); if (FRAME_XIC (f)) { /* XIM server might require some X events. */ unsigned long fevent = NoEventMask; XGetICValues(FRAME_XIC (f), XNFilterEvents, &fevent, NULL); if (fevent != NoEventMask) { XSetWindowAttributes attributes; XWindowAttributes wattr; unsigned long attribute_mask; XGetWindowAttributes (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), &wattr); attributes.event_mask = wattr.your_event_mask | fevent; attribute_mask = CWEventMask; XChangeWindowAttributes (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), attribute_mask, &attributes); } } UNBLOCK_INPUT; } #endif } #else /*! USE_GTK */ /* Create and set up the X window for frame F. */ void x_window (f) struct frame *f; { XClassHint class_hints; XSetWindowAttributes attributes; unsigned long attribute_mask; attributes.background_pixel = f->output_data.x->background_pixel; attributes.border_pixel = f->output_data.x->border_pixel; attributes.bit_gravity = StaticGravity; attributes.backing_store = NotUseful; attributes.save_under = True; attributes.event_mask = STANDARD_EVENT_SET; attributes.colormap = FRAME_X_COLORMAP (f); attribute_mask = (CWBackPixel | CWBorderPixel | CWBitGravity | CWEventMask | CWColormap); BLOCK_INPUT; FRAME_X_WINDOW (f) = XCreateWindow (FRAME_X_DISPLAY (f), f->output_data.x->parent_desc, f->left_pos, f->top_pos, FRAME_PIXEL_WIDTH (f), FRAME_PIXEL_HEIGHT (f), f->border_width, CopyFromParent, /* depth */ InputOutput, /* class */ FRAME_X_VISUAL (f), attribute_mask, &attributes); #ifdef HAVE_X_I18N if (use_xim) { create_frame_xic (f); if (FRAME_XIC (f)) { /* XIM server might require some X events. */ unsigned long fevent = NoEventMask; XGetICValues(FRAME_XIC (f), XNFilterEvents, &fevent, NULL); attributes.event_mask |= fevent; attribute_mask = CWEventMask; XChangeWindowAttributes (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), attribute_mask, &attributes); } } #endif /* HAVE_X_I18N */ validate_x_resource_name (); class_hints.res_name = (char *) SDATA (Vx_resource_name); class_hints.res_class = (char *) SDATA (Vx_resource_class); XSetClassHint (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), &class_hints); /* The menubar is part of the ordinary display; it does not count in addition to the height of the window. */ f->output_data.x->menubar_height = 0; /* This indicates that we use the "Passive Input" input model. Unless we do this, we don't get the Focus{In,Out} events that we need to draw the cursor correctly. Accursed bureaucrats. XWhipsAndChains (FRAME_X_DISPLAY (f), IronMaiden, &TheRack); */ f->output_data.x->wm_hints.input = True; f->output_data.x->wm_hints.flags |= InputHint; XSetWMHints (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), &f->output_data.x->wm_hints); f->output_data.x->wm_hints.icon_pixmap = None; /* Request "save yourself" and "delete window" commands from wm. */ { Atom protocols[2]; protocols[0] = FRAME_X_DISPLAY_INFO (f)->Xatom_wm_delete_window; protocols[1] = FRAME_X_DISPLAY_INFO (f)->Xatom_wm_save_yourself; XSetWMProtocols (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), protocols, 2); } /* x_set_name normally ignores requests to set the name if the requested name is the same as the current name. This is the one place where that assumption isn't correct; f->name is set, but the X server hasn't been told. */ { Lisp_Object name; int explicit = f->explicit_name; f->explicit_name = 0; name = f->name; f->name = Qnil; x_set_name (f, name, explicit); } XDefineCursor (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), f->output_data.x->text_cursor); UNBLOCK_INPUT; if (FRAME_X_WINDOW (f) == 0) error ("Unable to create window"); } #endif /* not USE_GTK */ #endif /* not USE_X_TOOLKIT */ /* Handle the icon stuff for this window. Perhaps later we might want an x_set_icon_position which can be called interactively as well. */ static void x_icon (f, parms) struct frame *f; Lisp_Object parms; { Lisp_Object icon_x, icon_y; struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (f); /* Set the position of the icon. Note that twm groups all icons in an icon window. */ icon_x = x_frame_get_and_record_arg (f, parms, Qicon_left, 0, 0, RES_TYPE_NUMBER); icon_y = x_frame_get_and_record_arg (f, parms, Qicon_top, 0, 0, RES_TYPE_NUMBER); if (!EQ (icon_x, Qunbound) && !EQ (icon_y, Qunbound)) { CHECK_NUMBER (icon_x); CHECK_NUMBER (icon_y); } else if (!EQ (icon_x, Qunbound) || !EQ (icon_y, Qunbound)) error ("Both left and top icon corners of icon must be specified"); BLOCK_INPUT; if (! EQ (icon_x, Qunbound)) x_wm_set_icon_position (f, XINT (icon_x), XINT (icon_y)); /* Start up iconic or window? */ x_wm_set_window_state (f, (EQ (x_get_arg (dpyinfo, parms, Qvisibility, 0, 0, RES_TYPE_SYMBOL), Qicon) ? IconicState : NormalState)); x_text_icon (f, (char *) SDATA ((!NILP (f->icon_name) ? f->icon_name : f->name))); UNBLOCK_INPUT; } /* Make the GCs needed for this window, setting the background, border and mouse colors; also create the mouse cursor and the gray border tile. */ static char cursor_bits[] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; static void x_make_gc (f) struct frame *f; { XGCValues gc_values; BLOCK_INPUT; /* Create the GCs of this frame. Note that many default values are used. */ /* Normal video */ gc_values.font = FRAME_FONT (f)->fid; gc_values.foreground = f->output_data.x->foreground_pixel; gc_values.background = f->output_data.x->background_pixel; gc_values.line_width = 0; /* Means 1 using fast algorithm. */ f->output_data.x->normal_gc = XCreateGC (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), GCLineWidth | GCFont | GCForeground | GCBackground, &gc_values); /* Reverse video style. */ gc_values.foreground = f->output_data.x->background_pixel; gc_values.background = f->output_data.x->foreground_pixel; f->output_data.x->reverse_gc = XCreateGC (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), GCFont | GCForeground | GCBackground | GCLineWidth, &gc_values); /* Cursor has cursor-color background, background-color foreground. */ gc_values.foreground = f->output_data.x->background_pixel; gc_values.background = f->output_data.x->cursor_pixel; gc_values.fill_style = FillOpaqueStippled; gc_values.stipple = XCreateBitmapFromData (FRAME_X_DISPLAY (f), FRAME_X_DISPLAY_INFO (f)->root_window, cursor_bits, 16, 16); f->output_data.x->cursor_gc = XCreateGC (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), (GCFont | GCForeground | GCBackground | GCFillStyle /* | GCStipple */ | GCLineWidth), &gc_values); /* Reliefs. */ f->output_data.x->white_relief.gc = 0; f->output_data.x->black_relief.gc = 0; /* Create the gray border tile used when the pointer is not in the frame. Since this depends on the frame's pixel values, this must be done on a per-frame basis. */ f->output_data.x->border_tile = (XCreatePixmapFromBitmapData (FRAME_X_DISPLAY (f), FRAME_X_DISPLAY_INFO (f)->root_window, gray_bits, gray_width, gray_height, f->output_data.x->foreground_pixel, f->output_data.x->background_pixel, DefaultDepth (FRAME_X_DISPLAY (f), FRAME_X_SCREEN_NUMBER (f)))); UNBLOCK_INPUT; } /* Free what was was allocated in x_make_gc. */ void x_free_gcs (f) struct frame *f; { Display *dpy = FRAME_X_DISPLAY (f); BLOCK_INPUT; if (f->output_data.x->normal_gc) { XFreeGC (dpy, f->output_data.x->normal_gc); f->output_data.x->normal_gc = 0; } if (f->output_data.x->reverse_gc) { XFreeGC (dpy, f->output_data.x->reverse_gc); f->output_data.x->reverse_gc = 0; } if (f->output_data.x->cursor_gc) { XFreeGC (dpy, f->output_data.x->cursor_gc); f->output_data.x->cursor_gc = 0; } if (f->output_data.x->border_tile) { XFreePixmap (dpy, f->output_data.x->border_tile); f->output_data.x->border_tile = 0; } UNBLOCK_INPUT; } /* Handler for signals raised during x_create_frame and x_create_top_frame. FRAME is the frame which is partially constructed. */ static Lisp_Object unwind_create_frame (frame) Lisp_Object frame; { struct frame *f = XFRAME (frame); /* If frame is ``official'', nothing to do. */ if (!CONSP (Vframe_list) || !EQ (XCAR (Vframe_list), frame)) { #if GLYPH_DEBUG struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (f); #endif x_free_frame_resources (f); /* Check that reference counts are indeed correct. */ xassert (dpyinfo->reference_count == dpyinfo_refcount); xassert (dpyinfo->image_cache->refcount == image_cache_refcount); return Qt; } return Qnil; } DEFUN ("x-create-frame", Fx_create_frame, Sx_create_frame, 1, 1, 0, doc: /* Make a new X window, which is called a "frame" in Emacs terms. Returns an Emacs frame object. ALIST is an alist of frame parameters. If the parameters specify that the frame should not have a minibuffer, and do not specify a specific minibuffer window to use, then `default-minibuffer-frame' must be a frame whose minibuffer can be shared by the new frame. This function is an internal primitive--use `make-frame' instead. */) (parms) Lisp_Object parms; { struct frame *f; Lisp_Object frame, tem; Lisp_Object name; int minibuffer_only = 0; long window_prompting = 0; int width, height; int count = SPECPDL_INDEX (); struct gcpro gcpro1, gcpro2, gcpro3, gcpro4; Lisp_Object display; struct x_display_info *dpyinfo = NULL; Lisp_Object parent; struct kboard *kb; check_x (); /* Use this general default value to start with until we know if this frame has a specified name. */ Vx_resource_name = Vinvocation_name; display = x_get_arg (dpyinfo, parms, Qdisplay, 0, 0, RES_TYPE_STRING); if (EQ (display, Qunbound)) display = Qnil; dpyinfo = check_x_display_info (display); #ifdef MULTI_KBOARD kb = dpyinfo->kboard; #else kb = &the_only_kboard; #endif name = x_get_arg (dpyinfo, parms, Qname, "name", "Name", RES_TYPE_STRING); if (!STRINGP (name) && ! EQ (name, Qunbound) && ! NILP (name)) error ("Invalid frame name--not a string or nil"); if (STRINGP (name)) Vx_resource_name = name; /* See if parent window is specified. */ parent = x_get_arg (dpyinfo, parms, Qparent_id, NULL, NULL, RES_TYPE_NUMBER); if (EQ (parent, Qunbound)) parent = Qnil; if (! NILP (parent)) CHECK_NUMBER (parent); /* make_frame_without_minibuffer can run Lisp code and garbage collect. */ /* No need to protect DISPLAY because that's not used after passing it to make_frame_without_minibuffer. */ frame = Qnil; GCPRO4 (parms, parent, name, frame); tem = x_get_arg (dpyinfo, parms, Qminibuffer, "minibuffer", "Minibuffer", RES_TYPE_SYMBOL); if (EQ (tem, Qnone) || NILP (tem)) f = make_frame_without_minibuffer (Qnil, kb, display); else if (EQ (tem, Qonly)) { f = make_minibuffer_frame (); minibuffer_only = 1; } else if (WINDOWP (tem)) f = make_frame_without_minibuffer (tem, kb, display); else f = make_frame (1); XSETFRAME (frame, f); /* Note that X Windows does support scroll bars. */ FRAME_CAN_HAVE_SCROLL_BARS (f) = 1; f->output_method = output_x_window; f->output_data.x = (struct x_output *) xmalloc (sizeof (struct x_output)); bzero (f->output_data.x, sizeof (struct x_output)); f->output_data.x->icon_bitmap = -1; FRAME_FONTSET (f) = -1; f->output_data.x->scroll_bar_foreground_pixel = -1; f->output_data.x->scroll_bar_background_pixel = -1; #ifdef USE_TOOLKIT_SCROLL_BARS f->output_data.x->scroll_bar_top_shadow_pixel = -1; f->output_data.x->scroll_bar_bottom_shadow_pixel = -1; #endif /* USE_TOOLKIT_SCROLL_BARS */ record_unwind_protect (unwind_create_frame, frame); f->icon_name = x_get_arg (dpyinfo, parms, Qicon_name, "iconName", "Title", RES_TYPE_STRING); if (! STRINGP (f->icon_name)) f->icon_name = Qnil; FRAME_X_DISPLAY_INFO (f) = dpyinfo; #if GLYPH_DEBUG image_cache_refcount = FRAME_X_IMAGE_CACHE (f)->refcount; dpyinfo_refcount = dpyinfo->reference_count; #endif /* GLYPH_DEBUG */ #ifdef MULTI_KBOARD FRAME_KBOARD (f) = kb; #endif /* These colors will be set anyway later, but it's important to get the color reference counts right, so initialize them! */ { Lisp_Object black; struct gcpro gcpro1; /* Function x_decode_color can signal an error. Make sure to initialize color slots so that we won't try to free colors we haven't allocated. */ f->output_data.x->foreground_pixel = -1; f->output_data.x->background_pixel = -1; f->output_data.x->cursor_pixel = -1; f->output_data.x->cursor_foreground_pixel = -1; f->output_data.x->border_pixel = -1; f->output_data.x->mouse_pixel = -1; black = build_string ("black"); GCPRO1 (black); f->output_data.x->foreground_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->background_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->cursor_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->cursor_foreground_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->border_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->mouse_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); UNGCPRO; } /* Specify the parent under which to make this X window. */ if (!NILP (parent)) { f->output_data.x->parent_desc = (Window) XFASTINT (parent); f->output_data.x->explicit_parent = 1; } else { f->output_data.x->parent_desc = FRAME_X_DISPLAY_INFO (f)->root_window; f->output_data.x->explicit_parent = 0; } /* Set the name; the functions to which we pass f expect the name to be set. */ if (EQ (name, Qunbound) || NILP (name)) { f->name = build_string (dpyinfo->x_id_name); f->explicit_name = 0; } else { f->name = name; f->explicit_name = 1; /* use the frame's title when getting resources for this frame. */ specbind (Qx_resource_name, name); } /* Extract the window parameters from the supplied values that are needed to determine window geometry. */ { Lisp_Object font; font = x_get_arg (dpyinfo, parms, Qfont, "font", "Font", RES_TYPE_STRING); BLOCK_INPUT; /* First, try whatever font the caller has specified. */ if (STRINGP (font)) { tem = Fquery_fontset (font, Qnil); if (STRINGP (tem)) font = x_new_fontset (f, SDATA (tem)); else font = x_new_font (f, SDATA (font)); } /* Try out a font which we hope has bold and italic variations. */ if (!STRINGP (font)) font = x_new_font (f, "-adobe-courier-medium-r-*-*-*-120-*-*-*-*-iso8859-1"); if (!STRINGP (font)) font = x_new_font (f, "-misc-fixed-medium-r-normal-*-*-140-*-*-c-*-iso8859-1"); if (! STRINGP (font)) font = x_new_font (f, "-*-*-medium-r-normal-*-*-140-*-*-c-*-iso8859-1"); if (! STRINGP (font)) /* This was formerly the first thing tried, but it finds too many fonts and takes too long. */ font = x_new_font (f, "-*-*-medium-r-*-*-*-*-*-*-c-*-iso8859-1"); /* If those didn't work, look for something which will at least work. */ if (! STRINGP (font)) font = x_new_font (f, "-*-fixed-*-*-*-*-*-140-*-*-c-*-iso8859-1"); UNBLOCK_INPUT; if (! STRINGP (font)) font = build_string ("fixed"); x_default_parameter (f, parms, Qfont, font, "font", "Font", RES_TYPE_STRING); } #ifdef USE_LUCID /* Prevent lwlib/xlwmenu.c from crashing because of a bug whereby it fails to get any font. */ xlwmenu_default_font = FRAME_FONT (f); #endif x_default_parameter (f, parms, Qborder_width, make_number (2), "borderWidth", "BorderWidth", RES_TYPE_NUMBER); /* This defaults to 1 in order to match xterm. We recognize either internalBorderWidth or internalBorder (which is what xterm calls it). */ if (NILP (Fassq (Qinternal_border_width, parms))) { Lisp_Object value; value = x_get_arg (dpyinfo, parms, Qinternal_border_width, "internalBorder", "internalBorder", RES_TYPE_NUMBER); if (! EQ (value, Qunbound)) parms = Fcons (Fcons (Qinternal_border_width, value), parms); } x_default_parameter (f, parms, Qinternal_border_width, make_number (1), "internalBorderWidth", "internalBorderWidth", RES_TYPE_NUMBER); x_default_parameter (f, parms, Qvertical_scroll_bars, Qleft, "verticalScrollBars", "ScrollBars", RES_TYPE_SYMBOL); /* Also do the stuff which must be set before the window exists. */ x_default_parameter (f, parms, Qforeground_color, build_string ("black"), "foreground", "Foreground", RES_TYPE_STRING); x_default_parameter (f, parms, Qbackground_color, build_string ("white"), "background", "Background", RES_TYPE_STRING); x_default_parameter (f, parms, Qmouse_color, build_string ("black"), "pointerColor", "Foreground", RES_TYPE_STRING); x_default_parameter (f, parms, Qcursor_color, build_string ("black"), "cursorColor", "Foreground", RES_TYPE_STRING); x_default_parameter (f, parms, Qborder_color, build_string ("black"), "borderColor", "BorderColor", RES_TYPE_STRING); x_default_parameter (f, parms, Qscreen_gamma, Qnil, "screenGamma", "ScreenGamma", RES_TYPE_FLOAT); x_default_parameter (f, parms, Qline_spacing, Qnil, "lineSpacing", "LineSpacing", RES_TYPE_NUMBER); x_default_parameter (f, parms, Qleft_fringe, Qnil, "leftFringe", "LeftFringe", RES_TYPE_NUMBER); x_default_parameter (f, parms, Qright_fringe, Qnil, "rightFringe", "RightFringe", RES_TYPE_NUMBER); x_default_scroll_bar_color_parameter (f, parms, Qscroll_bar_foreground, "scrollBarForeground", "ScrollBarForeground", 1); x_default_scroll_bar_color_parameter (f, parms, Qscroll_bar_background, "scrollBarBackground", "ScrollBarBackground", 0); /* Init faces before x_default_parameter is called for scroll-bar parameters because that function calls x_set_scroll_bar_width, which calls change_frame_size, which calls Fset_window_buffer, which runs hooks, which call Fvertical_motion. At the end, we end up in init_iterator with a null face cache, which should not happen. */ init_frame_faces (f); x_default_parameter (f, parms, Qmenu_bar_lines, make_number (1), "menuBar", "MenuBar", RES_TYPE_NUMBER); x_default_parameter (f, parms, Qtool_bar_lines, make_number (1), "toolBar", "ToolBar", RES_TYPE_NUMBER); x_default_parameter (f, parms, Qbuffer_predicate, Qnil, "bufferPredicate", "BufferPredicate", RES_TYPE_SYMBOL); x_default_parameter (f, parms, Qtitle, Qnil, "title", "Title", RES_TYPE_STRING); x_default_parameter (f, parms, Qwait_for_wm, Qt, "waitForWM", "WaitForWM", RES_TYPE_BOOLEAN); x_default_parameter (f, parms, Qfullscreen, Qnil, "fullscreen", "Fullscreen", RES_TYPE_SYMBOL); f->output_data.x->parent_desc = FRAME_X_DISPLAY_INFO (f)->root_window; /* Compute the size of the X window. */ window_prompting = x_figure_window_size (f, parms, 1); tem = x_get_arg (dpyinfo, parms, Qunsplittable, 0, 0, RES_TYPE_BOOLEAN); f->no_split = minibuffer_only || EQ (tem, Qt); /* Create the X widget or window. */ #ifdef USE_X_TOOLKIT x_window (f, window_prompting, minibuffer_only); #else x_window (f); #endif x_icon (f, parms); x_make_gc (f); /* Now consider the frame official. */ FRAME_X_DISPLAY_INFO (f)->reference_count++; Vframe_list = Fcons (frame, Vframe_list); /* We need to do this after creating the X window, so that the icon-creation functions can say whose icon they're describing. */ x_default_parameter (f, parms, Qicon_type, Qnil, "bitmapIcon", "BitmapIcon", RES_TYPE_SYMBOL); x_default_parameter (f, parms, Qauto_raise, Qnil, "autoRaise", "AutoRaiseLower", RES_TYPE_BOOLEAN); x_default_parameter (f, parms, Qauto_lower, Qnil, "autoLower", "AutoRaiseLower", RES_TYPE_BOOLEAN); x_default_parameter (f, parms, Qcursor_type, Qbox, "cursorType", "CursorType", RES_TYPE_SYMBOL); x_default_parameter (f, parms, Qscroll_bar_width, Qnil, "scrollBarWidth", "ScrollBarWidth", RES_TYPE_NUMBER); /* Dimensions, especially FRAME_LINES (f), must be done via change_frame_size. Change will not be effected unless different from the current FRAME_LINES (f). */ width = FRAME_COLS (f); height = FRAME_LINES (f); SET_FRAME_COLS (f, 0); FRAME_LINES (f) = 0; change_frame_size (f, height, width, 1, 0, 0); #if defined (USE_X_TOOLKIT) || defined (USE_GTK) /* Create the menu bar. */ if (!minibuffer_only && FRAME_EXTERNAL_MENU_BAR (f)) { /* If this signals an error, we haven't set size hints for the frame and we didn't make it visible. */ initialize_frame_menubar (f); #ifndef USE_GTK /* This is a no-op, except under Motif where it arranges the main window for the widgets on it. */ lw_set_main_areas (f->output_data.x->column_widget, f->output_data.x->menubar_widget, f->output_data.x->edit_widget); #endif /* not USE_GTK */ } #endif /* USE_X_TOOLKIT || USE_GTK */ /* Tell the server what size and position, etc, we want, and how badly we want them. This should be done after we have the menu bar so that its size can be taken into account. */ BLOCK_INPUT; x_wm_set_size_hint (f, window_prompting, 0); UNBLOCK_INPUT; /* Make the window appear on the frame and enable display, unless the caller says not to. However, with explicit parent, Emacs cannot control visibility, so don't try. */ if (! f->output_data.x->explicit_parent) { Lisp_Object visibility; visibility = x_get_arg (dpyinfo, parms, Qvisibility, 0, 0, RES_TYPE_SYMBOL); if (EQ (visibility, Qunbound)) visibility = Qt; if (EQ (visibility, Qicon)) x_iconify_frame (f); else if (! NILP (visibility)) x_make_frame_visible (f); else /* Must have been Qnil. */ ; } UNGCPRO; /* Make sure windows on this frame appear in calls to next-window and similar functions. */ Vwindow_list = Qnil; return unbind_to (count, frame); } /* FRAME is used only to get a handle on the X display. We don't pass the display info directly because we're called from frame.c, which doesn't know about that structure. */ Lisp_Object x_get_focus_frame (frame) struct frame *frame; { struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (frame); Lisp_Object xfocus; if (! dpyinfo->x_focus_frame) return Qnil; XSETFRAME (xfocus, dpyinfo->x_focus_frame); return xfocus; } /* In certain situations, when the window manager follows a click-to-focus policy, there seems to be no way around calling XSetInputFocus to give another frame the input focus . In an ideal world, XSetInputFocus should generally be avoided so that applications don't interfere with the window manager's focus policy. But I think it's okay to use when it's clearly done following a user-command. */ DEFUN ("x-focus-frame", Fx_focus_frame, Sx_focus_frame, 1, 1, 0, doc: /* Set the input focus to FRAME. FRAME nil means use the selected frame. */) (frame) Lisp_Object frame; { struct frame *f = check_x_frame (frame); Display *dpy = FRAME_X_DISPLAY (f); int count; BLOCK_INPUT; count = x_catch_errors (dpy); XSetInputFocus (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), RevertToParent, CurrentTime); x_uncatch_errors (dpy, count); UNBLOCK_INPUT; return Qnil; } DEFUN ("xw-color-defined-p", Fxw_color_defined_p, Sxw_color_defined_p, 1, 2, 0, doc: /* Internal function called by `color-defined-p', which see. */) (color, frame) Lisp_Object color, frame; { XColor foo; FRAME_PTR f = check_x_frame (frame); CHECK_STRING (color); if (x_defined_color (f, SDATA (color), &foo, 0)) return Qt; else return Qnil; } DEFUN ("xw-color-values", Fxw_color_values, Sxw_color_values, 1, 2, 0, doc: /* Internal function called by `color-values', which see. */) (color, frame) Lisp_Object color, frame; { XColor foo; FRAME_PTR f = check_x_frame (frame); CHECK_STRING (color); if (x_defined_color (f, SDATA (color), &foo, 0)) { Lisp_Object rgb[3]; rgb[0] = make_number (foo.red); rgb[1] = make_number (foo.green); rgb[2] = make_number (foo.blue); return Flist (3, rgb); } else return Qnil; } DEFUN ("xw-display-color-p", Fxw_display_color_p, Sxw_display_color_p, 0, 1, 0, doc: /* Internal function called by `display-color-p', which see. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); if (dpyinfo->n_planes <= 2) return Qnil; switch (dpyinfo->visual->class) { case StaticColor: case PseudoColor: case TrueColor: case DirectColor: return Qt; default: return Qnil; } } DEFUN ("x-display-grayscale-p", Fx_display_grayscale_p, Sx_display_grayscale_p, 0, 1, 0, doc: /* Return t if the X display supports shades of gray. Note that color displays do support shades of gray. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); if (dpyinfo->n_planes <= 1) return Qnil; switch (dpyinfo->visual->class) { case StaticColor: case PseudoColor: case TrueColor: case DirectColor: case StaticGray: case GrayScale: return Qt; default: return Qnil; } } DEFUN ("x-display-pixel-width", Fx_display_pixel_width, Sx_display_pixel_width, 0, 1, 0, doc: /* Returns the width in pixels of the X display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); return make_number (dpyinfo->width); } DEFUN ("x-display-pixel-height", Fx_display_pixel_height, Sx_display_pixel_height, 0, 1, 0, doc: /* Returns the height in pixels of the X display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); return make_number (dpyinfo->height); } DEFUN ("x-display-planes", Fx_display_planes, Sx_display_planes, 0, 1, 0, doc: /* Returns the number of bitplanes of the X display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); return make_number (dpyinfo->n_planes); } DEFUN ("x-display-color-cells", Fx_display_color_cells, Sx_display_color_cells, 0, 1, 0, doc: /* Returns the number of color cells of the X display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); return make_number (DisplayCells (dpyinfo->display, XScreenNumberOfScreen (dpyinfo->screen))); } DEFUN ("x-server-max-request-size", Fx_server_max_request_size, Sx_server_max_request_size, 0, 1, 0, doc: /* Returns the maximum request size of the X server of display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); return make_number (MAXREQUEST (dpyinfo->display)); } DEFUN ("x-server-vendor", Fx_server_vendor, Sx_server_vendor, 0, 1, 0, doc: /* Returns the vendor ID string of the X server of display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); char *vendor = ServerVendor (dpyinfo->display); if (! vendor) vendor = ""; return build_string (vendor); } DEFUN ("x-server-version", Fx_server_version, Sx_server_version, 0, 1, 0, doc: /* Returns the version numbers of the X server of display DISPLAY. The value is a list of three integers: the major and minor version numbers of the X Protocol in use, and the vendor-specific release number. See also the function `x-server-vendor'. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); Display *dpy = dpyinfo->display; return Fcons (make_number (ProtocolVersion (dpy)), Fcons (make_number (ProtocolRevision (dpy)), Fcons (make_number (VendorRelease (dpy)), Qnil))); } DEFUN ("x-display-screens", Fx_display_screens, Sx_display_screens, 0, 1, 0, doc: /* Return the number of screens on the X server of display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); return make_number (ScreenCount (dpyinfo->display)); } DEFUN ("x-display-mm-height", Fx_display_mm_height, Sx_display_mm_height, 0, 1, 0, doc: /* Return the height in millimeters of the X display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); return make_number (HeightMMOfScreen (dpyinfo->screen)); } DEFUN ("x-display-mm-width", Fx_display_mm_width, Sx_display_mm_width, 0, 1, 0, doc: /* Return the width in millimeters of the X display DISPLAY. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); return make_number (WidthMMOfScreen (dpyinfo->screen)); } DEFUN ("x-display-backing-store", Fx_display_backing_store, Sx_display_backing_store, 0, 1, 0, doc: /* Returns an indication of whether X display DISPLAY does backing store. The value may be `always', `when-mapped', or `not-useful'. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); Lisp_Object result; switch (DoesBackingStore (dpyinfo->screen)) { case Always: result = intern ("always"); break; case WhenMapped: result = intern ("when-mapped"); break; case NotUseful: result = intern ("not-useful"); break; default: error ("Strange value for BackingStore parameter of screen"); result = Qnil; } return result; } DEFUN ("x-display-visual-class", Fx_display_visual_class, Sx_display_visual_class, 0, 1, 0, doc: /* Return the visual class of the X display DISPLAY. The value is one of the symbols `static-gray', `gray-scale', `static-color', `pseudo-color', `true-color', or `direct-color'. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); Lisp_Object result; switch (dpyinfo->visual->class) { case StaticGray: result = intern ("static-gray"); break; case GrayScale: result = intern ("gray-scale"); break; case StaticColor: result = intern ("static-color"); break; case PseudoColor: result = intern ("pseudo-color"); break; case TrueColor: result = intern ("true-color"); break; case DirectColor: result = intern ("direct-color"); break; default: error ("Display has an unknown visual class"); result = Qnil; } return result; } DEFUN ("x-display-save-under", Fx_display_save_under, Sx_display_save_under, 0, 1, 0, doc: /* Returns t if the X display DISPLAY supports the save-under feature. The optional argument DISPLAY specifies which display to ask about. DISPLAY should be either a frame or a display name (a string). If omitted or nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); if (DoesSaveUnders (dpyinfo->screen) == True) return Qt; else return Qnil; } int x_pixel_width (f) register struct frame *f; { return FRAME_PIXEL_WIDTH (f); } int x_pixel_height (f) register struct frame *f; { return FRAME_PIXEL_HEIGHT (f); } int x_char_width (f) register struct frame *f; { return FRAME_COLUMN_WIDTH (f); } int x_char_height (f) register struct frame *f; { return FRAME_LINE_HEIGHT (f); } int x_screen_planes (f) register struct frame *f; { return FRAME_X_DISPLAY_INFO (f)->n_planes; } /************************************************************************ X Displays ************************************************************************/ /* Mapping visual names to visuals. */ static struct visual_class { char *name; int class; } visual_classes[] = { {"StaticGray", StaticGray}, {"GrayScale", GrayScale}, {"StaticColor", StaticColor}, {"PseudoColor", PseudoColor}, {"TrueColor", TrueColor}, {"DirectColor", DirectColor}, {NULL, 0} }; #ifndef HAVE_XSCREENNUMBEROFSCREEN /* Value is the screen number of screen SCR. This is a substitute for the X function with the same name when that doesn't exist. */ int XScreenNumberOfScreen (scr) register Screen *scr; { Display *dpy = scr->display; int i; for (i = 0; i < dpy->nscreens; ++i) if (scr == dpy->screens + i) break; return i; } #endif /* not HAVE_XSCREENNUMBEROFSCREEN */ /* Select the visual that should be used on display DPYINFO. Set members of DPYINFO appropriately. Called from x_term_init. */ void select_visual (dpyinfo) struct x_display_info *dpyinfo; { Display *dpy = dpyinfo->display; Screen *screen = dpyinfo->screen; Lisp_Object value; /* See if a visual is specified. */ value = display_x_get_resource (dpyinfo, build_string ("visualClass"), build_string ("VisualClass"), Qnil, Qnil); if (STRINGP (value)) { /* VALUE should be of the form CLASS-DEPTH, where CLASS is one of `PseudoColor', `TrueColor' etc. and DEPTH is the color depth, a decimal number. NAME is compared with case ignored. */ char *s = (char *) alloca (SBYTES (value) + 1); char *dash; int i, class = -1; XVisualInfo vinfo; strcpy (s, SDATA (value)); dash = index (s, '-'); if (dash) { dpyinfo->n_planes = atoi (dash + 1); *dash = '\0'; } else /* We won't find a matching visual with depth 0, so that an error will be printed below. */ dpyinfo->n_planes = 0; /* Determine the visual class. */ for (i = 0; visual_classes[i].name; ++i) if (xstricmp (s, visual_classes[i].name) == 0) { class = visual_classes[i].class; break; } /* Look up a matching visual for the specified class. */ if (class == -1 || !XMatchVisualInfo (dpy, XScreenNumberOfScreen (screen), dpyinfo->n_planes, class, &vinfo)) fatal ("Invalid visual specification `%s'", SDATA (value)); dpyinfo->visual = vinfo.visual; } else { int n_visuals; XVisualInfo *vinfo, vinfo_template; dpyinfo->visual = DefaultVisualOfScreen (screen); #ifdef HAVE_X11R4 vinfo_template.visualid = XVisualIDFromVisual (dpyinfo->visual); #else vinfo_template.visualid = dpyinfo->visual->visualid; #endif vinfo_template.screen = XScreenNumberOfScreen (screen); vinfo = XGetVisualInfo (dpy, VisualIDMask | VisualScreenMask, &vinfo_template, &n_visuals); if (n_visuals != 1) fatal ("Can't get proper X visual info"); dpyinfo->n_planes = vinfo->depth; XFree ((char *) vinfo); } } /* Return the X display structure for the display named NAME. Open a new connection if necessary. */ struct x_display_info * x_display_info_for_name (name) Lisp_Object name; { Lisp_Object names; struct x_display_info *dpyinfo; CHECK_STRING (name); if (! EQ (Vwindow_system, intern ("x"))) error ("Not using X Windows"); for (dpyinfo = x_display_list, names = x_display_name_list; dpyinfo; dpyinfo = dpyinfo->next, names = XCDR (names)) { Lisp_Object tem; tem = Fstring_equal (XCAR (XCAR (names)), name); if (!NILP (tem)) return dpyinfo; } /* Use this general default value to start with. */ Vx_resource_name = Vinvocation_name; validate_x_resource_name (); dpyinfo = x_term_init (name, (char *)0, (char *) SDATA (Vx_resource_name)); if (dpyinfo == 0) error ("Cannot connect to X server %s", SDATA (name)); x_in_use = 1; XSETFASTINT (Vwindow_system_version, 11); return dpyinfo; } DEFUN ("x-open-connection", Fx_open_connection, Sx_open_connection, 1, 3, 0, doc: /* Open a connection to an X server. DISPLAY is the name of the display to connect to. Optional second arg XRM-STRING is a string of resources in xrdb format. If the optional third arg MUST-SUCCEED is non-nil, terminate Emacs if we can't open the connection. */) (display, xrm_string, must_succeed) Lisp_Object display, xrm_string, must_succeed; { unsigned char *xrm_option; struct x_display_info *dpyinfo; CHECK_STRING (display); if (! NILP (xrm_string)) CHECK_STRING (xrm_string); if (! EQ (Vwindow_system, intern ("x"))) error ("Not using X Windows"); if (! NILP (xrm_string)) xrm_option = (unsigned char *) SDATA (xrm_string); else xrm_option = (unsigned char *) 0; validate_x_resource_name (); /* This is what opens the connection and sets x_current_display. This also initializes many symbols, such as those used for input. */ dpyinfo = x_term_init (display, xrm_option, (char *) SDATA (Vx_resource_name)); if (dpyinfo == 0) { if (!NILP (must_succeed)) fatal ("Cannot connect to X server %s.\n\ Check the DISPLAY environment variable or use `-d'.\n\ Also use the `xauth' program to verify that you have the proper\n\ authorization information needed to connect the X server.\n\ An insecure way to solve the problem may be to use `xhost'.\n", SDATA (display)); else error ("Cannot connect to X server %s", SDATA (display)); } x_in_use = 1; XSETFASTINT (Vwindow_system_version, 11); return Qnil; } DEFUN ("x-close-connection", Fx_close_connection, Sx_close_connection, 1, 1, 0, doc: /* Close the connection to DISPLAY's X server. For DISPLAY, specify either a frame or a display name (a string). If DISPLAY is nil, that stands for the selected frame's display. */) (display) Lisp_Object display; { struct x_display_info *dpyinfo = check_x_display_info (display); int i; if (dpyinfo->reference_count > 0) error ("Display still has frames on it"); BLOCK_INPUT; /* Free the fonts in the font table. */ for (i = 0; i < dpyinfo->n_fonts; i++) if (dpyinfo->font_table[i].name) { if (dpyinfo->font_table[i].name != dpyinfo->font_table[i].full_name) xfree (dpyinfo->font_table[i].full_name); xfree (dpyinfo->font_table[i].name); XFreeFont (dpyinfo->display, dpyinfo->font_table[i].font); } x_destroy_all_bitmaps (dpyinfo); XSetCloseDownMode (dpyinfo->display, DestroyAll); #ifdef USE_X_TOOLKIT XtCloseDisplay (dpyinfo->display); #else XCloseDisplay (dpyinfo->display); #endif x_delete_display (dpyinfo); UNBLOCK_INPUT; return Qnil; } DEFUN ("x-display-list", Fx_display_list, Sx_display_list, 0, 0, 0, doc: /* Return the list of display names that Emacs has connections to. */) () { Lisp_Object tail, result; result = Qnil; for (tail = x_display_name_list; ! NILP (tail); tail = XCDR (tail)) result = Fcons (XCAR (XCAR (tail)), result); return result; } DEFUN ("x-synchronize", Fx_synchronize, Sx_synchronize, 1, 2, 0, doc: /* If ON is non-nil, report X errors as soon as the erring request is made. If ON is nil, allow buffering of requests. Turning on synchronization prohibits the Xlib routines from buffering requests and seriously degrades performance, but makes debugging much easier. The optional second argument DISPLAY specifies which display to act on. DISPLAY should be either a frame or a display name (a string). If DISPLAY is omitted or nil, that stands for the selected frame's display. */) (on, display) Lisp_Object display, on; { struct x_display_info *dpyinfo = check_x_display_info (display); XSynchronize (dpyinfo->display, !EQ (on, Qnil)); return Qnil; } /* Wait for responses to all X commands issued so far for frame F. */ void x_sync (f) FRAME_PTR f; { BLOCK_INPUT; XSync (FRAME_X_DISPLAY (f), False); UNBLOCK_INPUT; } /*********************************************************************** Image types ***********************************************************************/ /* Value is the number of elements of vector VECTOR. */ #define DIM(VECTOR) (sizeof (VECTOR) / sizeof *(VECTOR)) /* List of supported image types. Use define_image_type to add new types. Use lookup_image_type to find a type for a given symbol. */ static struct image_type *image_types; /* The symbol `image' which is the car of the lists used to represent images in Lisp. */ extern Lisp_Object Qimage; /* The symbol `xbm' which is used as the type symbol for XBM images. */ Lisp_Object Qxbm; /* Keywords. */ extern Lisp_Object QCwidth, QCheight, QCforeground, QCbackground, QCfile; extern Lisp_Object QCdata, QCtype; Lisp_Object QCascent, QCmargin, QCrelief; Lisp_Object QCconversion, QCcolor_symbols, QCheuristic_mask; Lisp_Object QCindex, QCmatrix, QCcolor_adjustment, QCmask; /* Other symbols. */ Lisp_Object Qlaplace, Qemboss, Qedge_detection, Qheuristic; /* Time in seconds after which images should be removed from the cache if not displayed. */ Lisp_Object Vimage_cache_eviction_delay; /* Function prototypes. */ static void define_image_type P_ ((struct image_type *type)); static struct image_type *lookup_image_type P_ ((Lisp_Object symbol)); static void image_error P_ ((char *format, Lisp_Object, Lisp_Object)); static void x_laplace P_ ((struct frame *, struct image *)); static void x_emboss P_ ((struct frame *, struct image *)); static int x_build_heuristic_mask P_ ((struct frame *, struct image *, Lisp_Object)); /* Define a new image type from TYPE. This adds a copy of TYPE to image_types and adds the symbol *TYPE->type to Vimage_types. */ static void define_image_type (type) struct image_type *type; { /* Make a copy of TYPE to avoid a bus error in a dumped Emacs. The initialized data segment is read-only. */ struct image_type *p = (struct image_type *) xmalloc (sizeof *p); bcopy (type, p, sizeof *p); p->next = image_types; image_types = p; Vimage_types = Fcons (*p->type, Vimage_types); } /* Look up image type SYMBOL, and return a pointer to its image_type structure. Value is null if SYMBOL is not a known image type. */ static INLINE struct image_type * lookup_image_type (symbol) Lisp_Object symbol; { struct image_type *type; for (type = image_types; type; type = type->next) if (EQ (symbol, *type->type)) break; return type; } /* Value is non-zero if OBJECT is a valid Lisp image specification. A valid image specification is a list whose car is the symbol `image', and whose rest is a property list. The property list must contain a value for key `:type'. That value must be the name of a supported image type. The rest of the property list depends on the image type. */ int valid_image_p (object) Lisp_Object object; { int valid_p = 0; if (CONSP (object) && EQ (XCAR (object), Qimage)) { Lisp_Object tem; for (tem = XCDR (object); CONSP (tem); tem = XCDR (tem)) if (EQ (XCAR (tem), QCtype)) { tem = XCDR (tem); if (CONSP (tem) && SYMBOLP (XCAR (tem))) { struct image_type *type; type = lookup_image_type (XCAR (tem)); if (type) valid_p = type->valid_p (object); } break; } } return valid_p; } /* Log error message with format string FORMAT and argument ARG. Signaling an error, e.g. when an image cannot be loaded, is not a good idea because this would interrupt redisplay, and the error message display would lead to another redisplay. This function therefore simply displays a message. */ static void image_error (format, arg1, arg2) char *format; Lisp_Object arg1, arg2; { add_to_log (format, arg1, arg2); } /*********************************************************************** Image specifications ***********************************************************************/ enum image_value_type { IMAGE_DONT_CHECK_VALUE_TYPE, IMAGE_STRING_VALUE, IMAGE_STRING_OR_NIL_VALUE, IMAGE_SYMBOL_VALUE, IMAGE_POSITIVE_INTEGER_VALUE, IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, IMAGE_NON_NEGATIVE_INTEGER_VALUE, IMAGE_ASCENT_VALUE, IMAGE_INTEGER_VALUE, IMAGE_FUNCTION_VALUE, IMAGE_NUMBER_VALUE, IMAGE_BOOL_VALUE }; /* Structure used when parsing image specifications. */ struct image_keyword { /* Name of keyword. */ char *name; /* The type of value allowed. */ enum image_value_type type; /* Non-zero means key must be present. */ int mandatory_p; /* Used to recognize duplicate keywords in a property list. */ int count; /* The value that was found. */ Lisp_Object value; }; static int parse_image_spec P_ ((Lisp_Object, struct image_keyword *, int, Lisp_Object)); static Lisp_Object image_spec_value P_ ((Lisp_Object, Lisp_Object, int *)); /* Parse image spec SPEC according to KEYWORDS. A valid image spec has the format (image KEYWORD VALUE ...). One of the keyword/ value pairs must be `:type TYPE'. KEYWORDS is a vector of image_keywords structures of size NKEYWORDS describing other allowed keyword/value pairs. Value is non-zero if SPEC is valid. */ static int parse_image_spec (spec, keywords, nkeywords, type) Lisp_Object spec; struct image_keyword *keywords; int nkeywords; Lisp_Object type; { int i; Lisp_Object plist; if (!CONSP (spec) || !EQ (XCAR (spec), Qimage)) return 0; plist = XCDR (spec); while (CONSP (plist)) { Lisp_Object key, value; /* First element of a pair must be a symbol. */ key = XCAR (plist); plist = XCDR (plist); if (!SYMBOLP (key)) return 0; /* There must follow a value. */ if (!CONSP (plist)) return 0; value = XCAR (plist); plist = XCDR (plist); /* Find key in KEYWORDS. Error if not found. */ for (i = 0; i < nkeywords; ++i) if (strcmp (keywords[i].name, SDATA (SYMBOL_NAME (key))) == 0) break; if (i == nkeywords) continue; /* Record that we recognized the keyword. If a keywords was found more than once, it's an error. */ keywords[i].value = value; ++keywords[i].count; if (keywords[i].count > 1) return 0; /* Check type of value against allowed type. */ switch (keywords[i].type) { case IMAGE_STRING_VALUE: if (!STRINGP (value)) return 0; break; case IMAGE_STRING_OR_NIL_VALUE: if (!STRINGP (value) && !NILP (value)) return 0; break; case IMAGE_SYMBOL_VALUE: if (!SYMBOLP (value)) return 0; break; case IMAGE_POSITIVE_INTEGER_VALUE: if (!INTEGERP (value) || XINT (value) <= 0) return 0; break; case IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR: if (INTEGERP (value) && XINT (value) >= 0) break; if (CONSP (value) && INTEGERP (XCAR (value)) && INTEGERP (XCDR (value)) && XINT (XCAR (value)) >= 0 && XINT (XCDR (value)) >= 0) break; return 0; case IMAGE_ASCENT_VALUE: if (SYMBOLP (value) && EQ (value, Qcenter)) break; else if (INTEGERP (value) && XINT (value) >= 0 && XINT (value) <= 100) break; return 0; case IMAGE_NON_NEGATIVE_INTEGER_VALUE: if (!INTEGERP (value) || XINT (value) < 0) return 0; break; case IMAGE_DONT_CHECK_VALUE_TYPE: break; case IMAGE_FUNCTION_VALUE: value = indirect_function (value); if (SUBRP (value) || COMPILEDP (value) || (CONSP (value) && EQ (XCAR (value), Qlambda))) break; return 0; case IMAGE_NUMBER_VALUE: if (!INTEGERP (value) && !FLOATP (value)) return 0; break; case IMAGE_INTEGER_VALUE: if (!INTEGERP (value)) return 0; break; case IMAGE_BOOL_VALUE: if (!NILP (value) && !EQ (value, Qt)) return 0; break; default: abort (); break; } if (EQ (key, QCtype) && !EQ (type, value)) return 0; } /* Check that all mandatory fields are present. */ for (i = 0; i < nkeywords; ++i) if (keywords[i].mandatory_p && keywords[i].count == 0) return 0; return NILP (plist); } /* Return the value of KEY in image specification SPEC. Value is nil if KEY is not present in SPEC. if FOUND is not null, set *FOUND to 1 if KEY was found in SPEC, set it to 0 otherwise. */ static Lisp_Object image_spec_value (spec, key, found) Lisp_Object spec, key; int *found; { Lisp_Object tail; xassert (valid_image_p (spec)); for (tail = XCDR (spec); CONSP (tail) && CONSP (XCDR (tail)); tail = XCDR (XCDR (tail))) { if (EQ (XCAR (tail), key)) { if (found) *found = 1; return XCAR (XCDR (tail)); } } if (found) *found = 0; return Qnil; } DEFUN ("image-size", Fimage_size, Simage_size, 1, 3, 0, doc: /* Return the size of image SPEC as pair (WIDTH . HEIGHT). PIXELS non-nil means return the size in pixels, otherwise return the size in canonical character units. FRAME is the frame on which the image will be displayed. FRAME nil or omitted means use the selected frame. */) (spec, pixels, frame) Lisp_Object spec, pixels, frame; { Lisp_Object size; size = Qnil; if (valid_image_p (spec)) { struct frame *f = check_x_frame (frame); int id = lookup_image (f, spec); struct image *img = IMAGE_FROM_ID (f, id); int width = img->width + 2 * img->hmargin; int height = img->height + 2 * img->vmargin; if (NILP (pixels)) size = Fcons (make_float ((double) width / FRAME_COLUMN_WIDTH (f)), make_float ((double) height / FRAME_LINE_HEIGHT (f))); else size = Fcons (make_number (width), make_number (height)); } else error ("Invalid image specification"); return size; } DEFUN ("image-mask-p", Fimage_mask_p, Simage_mask_p, 1, 2, 0, doc: /* Return t if image SPEC has a mask bitmap. FRAME is the frame on which the image will be displayed. FRAME nil or omitted means use the selected frame. */) (spec, frame) Lisp_Object spec, frame; { Lisp_Object mask; mask = Qnil; if (valid_image_p (spec)) { struct frame *f = check_x_frame (frame); int id = lookup_image (f, spec); struct image *img = IMAGE_FROM_ID (f, id); if (img->mask) mask = Qt; } else error ("Invalid image specification"); return mask; } /*********************************************************************** Image type independent image structures ***********************************************************************/ static struct image *make_image P_ ((Lisp_Object spec, unsigned hash)); static void free_image P_ ((struct frame *f, struct image *img)); /* Allocate and return a new image structure for image specification SPEC. SPEC has a hash value of HASH. */ static struct image * make_image (spec, hash) Lisp_Object spec; unsigned hash; { struct image *img = (struct image *) xmalloc (sizeof *img); xassert (valid_image_p (spec)); bzero (img, sizeof *img); img->type = lookup_image_type (image_spec_value (spec, QCtype, NULL)); xassert (img->type != NULL); img->spec = spec; img->data.lisp_val = Qnil; img->ascent = DEFAULT_IMAGE_ASCENT; img->hash = hash; return img; } /* Free image IMG which was used on frame F, including its resources. */ static void free_image (f, img) struct frame *f; struct image *img; { if (img) { struct image_cache *c = FRAME_X_IMAGE_CACHE (f); /* Remove IMG from the hash table of its cache. */ if (img->prev) img->prev->next = img->next; else c->buckets[img->hash % IMAGE_CACHE_BUCKETS_SIZE] = img->next; if (img->next) img->next->prev = img->prev; c->images[img->id] = NULL; /* Free resources, then free IMG. */ img->type->free (f, img); xfree (img); } } /* Prepare image IMG for display on frame F. Must be called before drawing an image. */ void prepare_image_for_display (f, img) struct frame *f; struct image *img; { EMACS_TIME t; /* We're about to display IMG, so set its timestamp to `now'. */ EMACS_GET_TIME (t); img->timestamp = EMACS_SECS (t); /* If IMG doesn't have a pixmap yet, load it now, using the image type dependent loader function. */ if (img->pixmap == None && !img->load_failed_p) img->load_failed_p = img->type->load (f, img) == 0; } /* Value is the number of pixels for the ascent of image IMG when drawn in face FACE. */ int image_ascent (img, face) struct image *img; struct face *face; { int height = img->height + img->vmargin; int ascent; if (img->ascent == CENTERED_IMAGE_ASCENT) { if (face->font) /* This expression is arranged so that if the image can't be exactly centered, it will be moved slightly up. This is because a typical font is `top-heavy' (due to the presence uppercase letters), so the image placement should err towards being top-heavy too. It also just generally looks better. */ ascent = (height + face->font->ascent - face->font->descent + 1) / 2; else ascent = height / 2; } else ascent = height * img->ascent / 100.0; return ascent; } /* Image background colors. */ static unsigned long four_corners_best (ximg, width, height) XImage *ximg; unsigned long width, height; { unsigned long corners[4], best; int i, best_count; /* Get the colors at the corners of ximg. */ corners[0] = XGetPixel (ximg, 0, 0); corners[1] = XGetPixel (ximg, width - 1, 0); corners[2] = XGetPixel (ximg, width - 1, height - 1); corners[3] = XGetPixel (ximg, 0, height - 1); /* Choose the most frequently found color as background. */ for (i = best_count = 0; i < 4; ++i) { int j, n; for (j = n = 0; j < 4; ++j) if (corners[i] == corners[j]) ++n; if (n > best_count) best = corners[i], best_count = n; } return best; } /* Return the `background' field of IMG. If IMG doesn't have one yet, it is guessed heuristically. If non-zero, XIMG is an existing XImage object to use for the heuristic. */ unsigned long image_background (img, f, ximg) struct image *img; struct frame *f; XImage *ximg; { if (! img->background_valid) /* IMG doesn't have a background yet, try to guess a reasonable value. */ { int free_ximg = !ximg; if (! ximg) ximg = XGetImage (FRAME_X_DISPLAY (f), img->pixmap, 0, 0, img->width, img->height, ~0, ZPixmap); img->background = four_corners_best (ximg, img->width, img->height); if (free_ximg) XDestroyImage (ximg); img->background_valid = 1; } return img->background; } /* Return the `background_transparent' field of IMG. If IMG doesn't have one yet, it is guessed heuristically. If non-zero, MASK is an existing XImage object to use for the heuristic. */ int image_background_transparent (img, f, mask) struct image *img; struct frame *f; XImage *mask; { if (! img->background_transparent_valid) /* IMG doesn't have a background yet, try to guess a reasonable value. */ { if (img->mask) { int free_mask = !mask; if (! mask) mask = XGetImage (FRAME_X_DISPLAY (f), img->mask, 0, 0, img->width, img->height, ~0, ZPixmap); img->background_transparent = !four_corners_best (mask, img->width, img->height); if (free_mask) XDestroyImage (mask); } else img->background_transparent = 0; img->background_transparent_valid = 1; } return img->background_transparent; } /*********************************************************************** Helper functions for X image types ***********************************************************************/ static void x_clear_image_1 P_ ((struct frame *, struct image *, int, int, int)); static void x_clear_image P_ ((struct frame *f, struct image *img)); static unsigned long x_alloc_image_color P_ ((struct frame *f, struct image *img, Lisp_Object color_name, unsigned long dflt)); /* Clear X resources of image IMG on frame F. PIXMAP_P non-zero means free the pixmap if any. MASK_P non-zero means clear the mask pixmap if any. COLORS_P non-zero means free colors allocated for the image, if any. */ static void x_clear_image_1 (f, img, pixmap_p, mask_p, colors_p) struct frame *f; struct image *img; int pixmap_p, mask_p, colors_p; { if (pixmap_p && img->pixmap) { XFreePixmap (FRAME_X_DISPLAY (f), img->pixmap); img->pixmap = None; img->background_valid = 0; } if (mask_p && img->mask) { XFreePixmap (FRAME_X_DISPLAY (f), img->mask); img->mask = None; img->background_transparent_valid = 0; } if (colors_p && img->ncolors) { x_free_colors (f, img->colors, img->ncolors); xfree (img->colors); img->colors = NULL; img->ncolors = 0; } } /* Free X resources of image IMG which is used on frame F. */ static void x_clear_image (f, img) struct frame *f; struct image *img; { BLOCK_INPUT; x_clear_image_1 (f, img, 1, 1, 1); UNBLOCK_INPUT; } /* Allocate color COLOR_NAME for image IMG on frame F. If color cannot be allocated, use DFLT. Add a newly allocated color to IMG->colors, so that it can be freed again. Value is the pixel color. */ static unsigned long x_alloc_image_color (f, img, color_name, dflt) struct frame *f; struct image *img; Lisp_Object color_name; unsigned long dflt; { XColor color; unsigned long result; xassert (STRINGP (color_name)); if (x_defined_color (f, SDATA (color_name), &color, 1)) { /* This isn't called frequently so we get away with simply reallocating the color vector to the needed size, here. */ ++img->ncolors; img->colors = (unsigned long *) xrealloc (img->colors, img->ncolors * sizeof *img->colors); img->colors[img->ncolors - 1] = color.pixel; result = color.pixel; } else result = dflt; return result; } /*********************************************************************** Image Cache ***********************************************************************/ static void cache_image P_ ((struct frame *f, struct image *img)); static void postprocess_image P_ ((struct frame *, struct image *)); /* Return a new, initialized image cache that is allocated from the heap. Call free_image_cache to free an image cache. */ struct image_cache * make_image_cache () { struct image_cache *c = (struct image_cache *) xmalloc (sizeof *c); int size; bzero (c, sizeof *c); c->size = 50; c->images = (struct image **) xmalloc (c->size * sizeof *c->images); size = IMAGE_CACHE_BUCKETS_SIZE * sizeof *c->buckets; c->buckets = (struct image **) xmalloc (size); bzero (c->buckets, size); return c; } /* Free image cache of frame F. Be aware that X frames share images caches. */ void free_image_cache (f) struct frame *f; { struct image_cache *c = FRAME_X_IMAGE_CACHE (f); if (c) { int i; /* Cache should not be referenced by any frame when freed. */ xassert (c->refcount == 0); for (i = 0; i < c->used; ++i) free_image (f, c->images[i]); xfree (c->images); xfree (c->buckets); xfree (c); FRAME_X_IMAGE_CACHE (f) = NULL; } } /* Clear image cache of frame F. FORCE_P non-zero means free all images. FORCE_P zero means clear only images that haven't been displayed for some time. Should be called from time to time to reduce the number of loaded images. If image-eviction-seconds is non-nil, this frees images in the cache which weren't displayed for at least that many seconds. */ void clear_image_cache (f, force_p) struct frame *f; int force_p; { struct image_cache *c = FRAME_X_IMAGE_CACHE (f); if (c && INTEGERP (Vimage_cache_eviction_delay)) { EMACS_TIME t; unsigned long old; int i, nfreed; EMACS_GET_TIME (t); old = EMACS_SECS (t) - XFASTINT (Vimage_cache_eviction_delay); /* Block input so that we won't be interrupted by a SIGIO while being in an inconsistent state. */ BLOCK_INPUT; for (i = nfreed = 0; i < c->used; ++i) { struct image *img = c->images[i]; if (img != NULL && (force_p || img->timestamp < old)) { free_image (f, img); ++nfreed; } } /* We may be clearing the image cache because, for example, Emacs was iconified for a longer period of time. In that case, current matrices may still contain references to images freed above. So, clear these matrices. */ if (nfreed) { Lisp_Object tail, frame; FOR_EACH_FRAME (tail, frame) { struct frame *f = XFRAME (frame); if (FRAME_X_P (f) && FRAME_X_IMAGE_CACHE (f) == c) clear_current_matrices (f); } ++windows_or_buffers_changed; } UNBLOCK_INPUT; } } DEFUN ("clear-image-cache", Fclear_image_cache, Sclear_image_cache, 0, 1, 0, doc: /* Clear the image cache of FRAME. FRAME nil or omitted means use the selected frame. FRAME t means clear the image caches of all frames. */) (frame) Lisp_Object frame; { if (EQ (frame, Qt)) { Lisp_Object tail; FOR_EACH_FRAME (tail, frame) if (FRAME_X_P (XFRAME (frame))) clear_image_cache (XFRAME (frame), 1); } else clear_image_cache (check_x_frame (frame), 1); return Qnil; } /* Compute masks and transform image IMG on frame F, as specified by the image's specification, */ static void postprocess_image (f, img) struct frame *f; struct image *img; { /* Manipulation of the image's mask. */ if (img->pixmap) { Lisp_Object conversion, spec; Lisp_Object mask; spec = img->spec; /* `:heuristic-mask t' `:mask heuristic' means build a mask heuristically. `:heuristic-mask (R G B)' `:mask (heuristic (R G B))' means build a mask from color (R G B) in the image. `:mask nil' means remove a mask, if any. */ mask = image_spec_value (spec, QCheuristic_mask, NULL); if (!NILP (mask)) x_build_heuristic_mask (f, img, mask); else { int found_p; mask = image_spec_value (spec, QCmask, &found_p); if (EQ (mask, Qheuristic)) x_build_heuristic_mask (f, img, Qt); else if (CONSP (mask) && EQ (XCAR (mask), Qheuristic)) { if (CONSP (XCDR (mask))) x_build_heuristic_mask (f, img, XCAR (XCDR (mask))); else x_build_heuristic_mask (f, img, XCDR (mask)); } else if (NILP (mask) && found_p && img->mask) { XFreePixmap (FRAME_X_DISPLAY (f), img->mask); img->mask = None; } } /* Should we apply an image transformation algorithm? */ conversion = image_spec_value (spec, QCconversion, NULL); if (EQ (conversion, Qdisabled)) x_disable_image (f, img); else if (EQ (conversion, Qlaplace)) x_laplace (f, img); else if (EQ (conversion, Qemboss)) x_emboss (f, img); else if (CONSP (conversion) && EQ (XCAR (conversion), Qedge_detection)) { Lisp_Object tem; tem = XCDR (conversion); if (CONSP (tem)) x_edge_detection (f, img, Fplist_get (tem, QCmatrix), Fplist_get (tem, QCcolor_adjustment)); } } } /* Return the id of image with Lisp specification SPEC on frame F. SPEC must be a valid Lisp image specification (see valid_image_p). */ int lookup_image (f, spec) struct frame *f; Lisp_Object spec; { struct image_cache *c = FRAME_X_IMAGE_CACHE (f); struct image *img; int i; unsigned hash; struct gcpro gcpro1; EMACS_TIME now; /* F must be a window-system frame, and SPEC must be a valid image specification. */ xassert (FRAME_WINDOW_P (f)); xassert (valid_image_p (spec)); GCPRO1 (spec); /* Look up SPEC in the hash table of the image cache. */ hash = sxhash (spec, 0); i = hash % IMAGE_CACHE_BUCKETS_SIZE; for (img = c->buckets[i]; img; img = img->next) if (img->hash == hash && !NILP (Fequal (img->spec, spec))) break; /* If not found, create a new image and cache it. */ if (img == NULL) { extern Lisp_Object Qpostscript; BLOCK_INPUT; img = make_image (spec, hash); cache_image (f, img); img->load_failed_p = img->type->load (f, img) == 0; /* If we can't load the image, and we don't have a width and height, use some arbitrary width and height so that we can draw a rectangle for it. */ if (img->load_failed_p) { Lisp_Object value; value = image_spec_value (spec, QCwidth, NULL); img->width = (INTEGERP (value) ? XFASTINT (value) : DEFAULT_IMAGE_WIDTH); value = image_spec_value (spec, QCheight, NULL); img->height = (INTEGERP (value) ? XFASTINT (value) : DEFAULT_IMAGE_HEIGHT); } else { /* Handle image type independent image attributes `:ascent ASCENT', `:margin MARGIN', `:relief RELIEF', `:background COLOR'. */ Lisp_Object ascent, margin, relief, bg; ascent = image_spec_value (spec, QCascent, NULL); if (INTEGERP (ascent)) img->ascent = XFASTINT (ascent); else if (EQ (ascent, Qcenter)) img->ascent = CENTERED_IMAGE_ASCENT; margin = image_spec_value (spec, QCmargin, NULL); if (INTEGERP (margin) && XINT (margin) >= 0) img->vmargin = img->hmargin = XFASTINT (margin); else if (CONSP (margin) && INTEGERP (XCAR (margin)) && INTEGERP (XCDR (margin))) { if (XINT (XCAR (margin)) > 0) img->hmargin = XFASTINT (XCAR (margin)); if (XINT (XCDR (margin)) > 0) img->vmargin = XFASTINT (XCDR (margin)); } relief = image_spec_value (spec, QCrelief, NULL); if (INTEGERP (relief)) { img->relief = XINT (relief); img->hmargin += abs (img->relief); img->vmargin += abs (img->relief); } if (! img->background_valid) { bg = image_spec_value (img->spec, QCbackground, NULL); if (!NILP (bg)) { img->background = x_alloc_image_color (f, img, bg, FRAME_BACKGROUND_PIXEL (f)); img->background_valid = 1; } } /* Do image transformations and compute masks, unless we don't have the image yet. */ if (!EQ (*img->type->type, Qpostscript)) postprocess_image (f, img); } UNBLOCK_INPUT; xassert (!interrupt_input_blocked); } /* We're using IMG, so set its timestamp to `now'. */ EMACS_GET_TIME (now); img->timestamp = EMACS_SECS (now); UNGCPRO; /* Value is the image id. */ return img->id; } /* Cache image IMG in the image cache of frame F. */ static void cache_image (f, img) struct frame *f; struct image *img; { struct image_cache *c = FRAME_X_IMAGE_CACHE (f); int i; /* Find a free slot in c->images. */ for (i = 0; i < c->used; ++i) if (c->images[i] == NULL) break; /* If no free slot found, maybe enlarge c->images. */ if (i == c->used && c->used == c->size) { c->size *= 2; c->images = (struct image **) xrealloc (c->images, c->size * sizeof *c->images); } /* Add IMG to c->images, and assign IMG an id. */ c->images[i] = img; img->id = i; if (i == c->used) ++c->used; /* Add IMG to the cache's hash table. */ i = img->hash % IMAGE_CACHE_BUCKETS_SIZE; img->next = c->buckets[i]; if (img->next) img->next->prev = img; img->prev = NULL; c->buckets[i] = img; } /* Call FN on every image in the image cache of frame F. Used to mark Lisp Objects in the image cache. */ void forall_images_in_image_cache (f, fn) struct frame *f; void (*fn) P_ ((struct image *img)); { if (FRAME_LIVE_P (f) && FRAME_X_P (f)) { struct image_cache *c = FRAME_X_IMAGE_CACHE (f); if (c) { int i; for (i = 0; i < c->used; ++i) if (c->images[i]) fn (c->images[i]); } } } /*********************************************************************** X support code ***********************************************************************/ static int x_create_x_image_and_pixmap P_ ((struct frame *, int, int, int, XImage **, Pixmap *)); static void x_destroy_x_image P_ ((XImage *)); static void x_put_x_image P_ ((struct frame *, XImage *, Pixmap, int, int)); /* Create an XImage and a pixmap of size WIDTH x HEIGHT for use on frame F. Set *XIMG and *PIXMAP to the XImage and Pixmap created. Set (*XIMG)->data to a raster of WIDTH x HEIGHT pixels allocated via xmalloc. Print error messages via image_error if an error occurs. Value is non-zero if successful. */ static int x_create_x_image_and_pixmap (f, width, height, depth, ximg, pixmap) struct frame *f; int width, height, depth; XImage **ximg; Pixmap *pixmap; { Display *display = FRAME_X_DISPLAY (f); Screen *screen = FRAME_X_SCREEN (f); Window window = FRAME_X_WINDOW (f); xassert (interrupt_input_blocked); if (depth <= 0) depth = DefaultDepthOfScreen (screen); *ximg = XCreateImage (display, DefaultVisualOfScreen (screen), depth, ZPixmap, 0, NULL, width, height, depth > 16 ? 32 : depth > 8 ? 16 : 8, 0); if (*ximg == NULL) { image_error ("Unable to allocate X image", Qnil, Qnil); return 0; } /* Allocate image raster. */ (*ximg)->data = (char *) xmalloc ((*ximg)->bytes_per_line * height); /* Allocate a pixmap of the same size. */ *pixmap = XCreatePixmap (display, window, width, height, depth); if (*pixmap == None) { x_destroy_x_image (*ximg); *ximg = NULL; image_error ("Unable to create X pixmap", Qnil, Qnil); return 0; } return 1; } /* Destroy XImage XIMG. Free XIMG->data. */ static void x_destroy_x_image (ximg) XImage *ximg; { xassert (interrupt_input_blocked); if (ximg) { xfree (ximg->data); ximg->data = NULL; XDestroyImage (ximg); } } /* Put XImage XIMG into pixmap PIXMAP on frame F. WIDTH and HEIGHT are width and height of both the image and pixmap. */ static void x_put_x_image (f, ximg, pixmap, width, height) struct frame *f; XImage *ximg; Pixmap pixmap; int width, height; { GC gc; xassert (interrupt_input_blocked); gc = XCreateGC (FRAME_X_DISPLAY (f), pixmap, 0, NULL); XPutImage (FRAME_X_DISPLAY (f), pixmap, gc, ximg, 0, 0, 0, 0, width, height); XFreeGC (FRAME_X_DISPLAY (f), gc); } /*********************************************************************** File Handling ***********************************************************************/ static Lisp_Object x_find_image_file P_ ((Lisp_Object)); static char *slurp_file P_ ((char *, int *)); /* Find image file FILE. Look in data-directory, then x-bitmap-file-path. Value is the full name of the file found, or nil if not found. */ static Lisp_Object x_find_image_file (file) Lisp_Object file; { Lisp_Object file_found, search_path; struct gcpro gcpro1, gcpro2; int fd; file_found = Qnil; search_path = Fcons (Vdata_directory, Vx_bitmap_file_path); GCPRO2 (file_found, search_path); /* Try to find FILE in data-directory, then x-bitmap-file-path. */ fd = openp (search_path, file, Qnil, &file_found, Qnil); if (fd == -1) file_found = Qnil; else close (fd); UNGCPRO; return file_found; } /* Read FILE into memory. Value is a pointer to a buffer allocated with xmalloc holding FILE's contents. Value is null if an error occurred. *SIZE is set to the size of the file. */ static char * slurp_file (file, size) char *file; int *size; { FILE *fp = NULL; char *buf = NULL; struct stat st; if (stat (file, &st) == 0 && (fp = fopen (file, "r")) != NULL && (buf = (char *) xmalloc (st.st_size), fread (buf, 1, st.st_size, fp) == st.st_size)) { *size = st.st_size; fclose (fp); } else { if (fp) fclose (fp); if (buf) { xfree (buf); buf = NULL; } } return buf; } /*********************************************************************** XBM images ***********************************************************************/ static int xbm_scan P_ ((char **, char *, char *, int *)); static int xbm_load P_ ((struct frame *f, struct image *img)); static int xbm_load_image P_ ((struct frame *f, struct image *img, char *, char *)); static int xbm_image_p P_ ((Lisp_Object object)); static int xbm_read_bitmap_data P_ ((char *, char *, int *, int *, unsigned char **)); static int xbm_file_p P_ ((Lisp_Object)); /* Indices of image specification fields in xbm_format, below. */ enum xbm_keyword_index { XBM_TYPE, XBM_FILE, XBM_WIDTH, XBM_HEIGHT, XBM_DATA, XBM_FOREGROUND, XBM_BACKGROUND, XBM_ASCENT, XBM_MARGIN, XBM_RELIEF, XBM_ALGORITHM, XBM_HEURISTIC_MASK, XBM_MASK, XBM_LAST }; /* Vector of image_keyword structures describing the format of valid XBM image specifications. */ static struct image_keyword xbm_format[XBM_LAST] = { {":type", IMAGE_SYMBOL_VALUE, 1}, {":file", IMAGE_STRING_VALUE, 0}, {":width", IMAGE_POSITIVE_INTEGER_VALUE, 0}, {":height", IMAGE_POSITIVE_INTEGER_VALUE, 0}, {":data", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":foreground", IMAGE_STRING_OR_NIL_VALUE, 0}, {":background", IMAGE_STRING_OR_NIL_VALUE, 0}, {":ascent", IMAGE_ASCENT_VALUE, 0}, {":margin", IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, 0}, {":relief", IMAGE_INTEGER_VALUE, 0}, {":conversion", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":heuristic-mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0} }; /* Structure describing the image type XBM. */ static struct image_type xbm_type = { &Qxbm, xbm_image_p, xbm_load, x_clear_image, NULL }; /* Tokens returned from xbm_scan. */ enum xbm_token { XBM_TK_IDENT = 256, XBM_TK_NUMBER }; /* Return non-zero if OBJECT is a valid XBM-type image specification. A valid specification is a list starting with the symbol `image' The rest of the list is a property list which must contain an entry `:type xbm.. If the specification specifies a file to load, it must contain an entry `:file FILENAME' where FILENAME is a string. If the specification is for a bitmap loaded from memory it must contain `:width WIDTH', `:height HEIGHT', and `:data DATA', where WIDTH and HEIGHT are integers > 0. DATA may be: 1. a string large enough to hold the bitmap data, i.e. it must have a size >= (WIDTH + 7) / 8 * HEIGHT 2. a bool-vector of size >= WIDTH * HEIGHT 3. a vector of strings or bool-vectors, one for each line of the bitmap. 4. A string containing an in-memory XBM file. WIDTH and HEIGHT may not be specified in this case because they are defined in the XBM file. Both the file and data forms may contain the additional entries `:background COLOR' and `:foreground COLOR'. If not present, foreground and background of the frame on which the image is displayed is used. */ static int xbm_image_p (object) Lisp_Object object; { struct image_keyword kw[XBM_LAST]; bcopy (xbm_format, kw, sizeof kw); if (!parse_image_spec (object, kw, XBM_LAST, Qxbm)) return 0; xassert (EQ (kw[XBM_TYPE].value, Qxbm)); if (kw[XBM_FILE].count) { if (kw[XBM_WIDTH].count || kw[XBM_HEIGHT].count || kw[XBM_DATA].count) return 0; } else if (kw[XBM_DATA].count && xbm_file_p (kw[XBM_DATA].value)) { /* In-memory XBM file. */ if (kw[XBM_WIDTH].count || kw[XBM_HEIGHT].count || kw[XBM_FILE].count) return 0; } else { Lisp_Object data; int width, height; /* Entries for `:width', `:height' and `:data' must be present. */ if (!kw[XBM_WIDTH].count || !kw[XBM_HEIGHT].count || !kw[XBM_DATA].count) return 0; data = kw[XBM_DATA].value; width = XFASTINT (kw[XBM_WIDTH].value); height = XFASTINT (kw[XBM_HEIGHT].value); /* Check type of data, and width and height against contents of data. */ if (VECTORP (data)) { int i; /* Number of elements of the vector must be >= height. */ if (XVECTOR (data)->size < height) return 0; /* Each string or bool-vector in data must be large enough for one line of the image. */ for (i = 0; i < height; ++i) { Lisp_Object elt = XVECTOR (data)->contents[i]; if (STRINGP (elt)) { if (SCHARS (elt) < (width + BITS_PER_CHAR - 1) / BITS_PER_CHAR) return 0; } else if (BOOL_VECTOR_P (elt)) { if (XBOOL_VECTOR (elt)->size < width) return 0; } else return 0; } } else if (STRINGP (data)) { if (SCHARS (data) < (width + BITS_PER_CHAR - 1) / BITS_PER_CHAR * height) return 0; } else if (BOOL_VECTOR_P (data)) { if (XBOOL_VECTOR (data)->size < width * height) return 0; } else return 0; } return 1; } /* Scan a bitmap file. FP is the stream to read from. Value is either an enumerator from enum xbm_token, or a character for a single-character token, or 0 at end of file. If scanning an identifier, store the lexeme of the identifier in SVAL. If scanning a number, store its value in *IVAL. */ static int xbm_scan (s, end, sval, ival) char **s, *end; char *sval; int *ival; { int c; loop: /* Skip white space. */ while (*s < end && (c = *(*s)++, isspace (c))) ; if (*s >= end) c = 0; else if (isdigit (c)) { int value = 0, digit; if (c == '0' && *s < end) { c = *(*s)++; if (c == 'x' || c == 'X') { while (*s < end) { c = *(*s)++; if (isdigit (c)) digit = c - '0'; else if (c >= 'a' && c <= 'f') digit = c - 'a' + 10; else if (c >= 'A' && c <= 'F') digit = c - 'A' + 10; else break; value = 16 * value + digit; } } else if (isdigit (c)) { value = c - '0'; while (*s < end && (c = *(*s)++, isdigit (c))) value = 8 * value + c - '0'; } } else { value = c - '0'; while (*s < end && (c = *(*s)++, isdigit (c))) value = 10 * value + c - '0'; } if (*s < end) *s = *s - 1; *ival = value; c = XBM_TK_NUMBER; } else if (isalpha (c) || c == '_') { *sval++ = c; while (*s < end && (c = *(*s)++, (isalnum (c) || c == '_'))) *sval++ = c; *sval = 0; if (*s < end) *s = *s - 1; c = XBM_TK_IDENT; } else if (c == '/' && **s == '*') { /* C-style comment. */ ++*s; while (**s && (**s != '*' || *(*s + 1) != '/')) ++*s; if (**s) { *s += 2; goto loop; } } return c; } /* Replacement for XReadBitmapFileData which isn't available under old X versions. CONTENTS is a pointer to a buffer to parse; END is the buffer's end. Set *WIDTH and *HEIGHT to the width and height of the image. Return in *DATA the bitmap data allocated with xmalloc. Value is non-zero if successful. DATA null means just test if CONTENTS looks like an in-memory XBM file. */ static int xbm_read_bitmap_data (contents, end, width, height, data) char *contents, *end; int *width, *height; unsigned char **data; { char *s = contents; char buffer[BUFSIZ]; int padding_p = 0; int v10 = 0; int bytes_per_line, i, nbytes; unsigned char *p; int value; int LA1; #define match() \ LA1 = xbm_scan (&s, end, buffer, &value) #define expect(TOKEN) \ if (LA1 != (TOKEN)) \ goto failure; \ else \ match () #define expect_ident(IDENT) \ if (LA1 == XBM_TK_IDENT && strcmp (buffer, (IDENT)) == 0) \ match (); \ else \ goto failure *width = *height = -1; if (data) *data = NULL; LA1 = xbm_scan (&s, end, buffer, &value); /* Parse defines for width, height and hot-spots. */ while (LA1 == '#') { match (); expect_ident ("define"); expect (XBM_TK_IDENT); if (LA1 == XBM_TK_NUMBER); { char *p = strrchr (buffer, '_'); p = p ? p + 1 : buffer; if (strcmp (p, "width") == 0) *width = value; else if (strcmp (p, "height") == 0) *height = value; } expect (XBM_TK_NUMBER); } if (*width < 0 || *height < 0) goto failure; else if (data == NULL) goto success; /* Parse bits. Must start with `static'. */ expect_ident ("static"); if (LA1 == XBM_TK_IDENT) { if (strcmp (buffer, "unsigned") == 0) { match (); expect_ident ("char"); } else if (strcmp (buffer, "short") == 0) { match (); v10 = 1; if (*width % 16 && *width % 16 < 9) padding_p = 1; } else if (strcmp (buffer, "char") == 0) match (); else goto failure; } else goto failure; expect (XBM_TK_IDENT); expect ('['); expect (']'); expect ('='); expect ('{'); bytes_per_line = (*width + 7) / 8 + padding_p; nbytes = bytes_per_line * *height; p = *data = (char *) xmalloc (nbytes); if (v10) { for (i = 0; i < nbytes; i += 2) { int val = value; expect (XBM_TK_NUMBER); *p++ = val; if (!padding_p || ((i + 2) % bytes_per_line)) *p++ = value >> 8; if (LA1 == ',' || LA1 == '}') match (); else goto failure; } } else { for (i = 0; i < nbytes; ++i) { int val = value; expect (XBM_TK_NUMBER); *p++ = val; if (LA1 == ',' || LA1 == '}') match (); else goto failure; } } success: return 1; failure: if (data && *data) { xfree (*data); *data = NULL; } return 0; #undef match #undef expect #undef expect_ident } /* Load XBM image IMG which will be displayed on frame F from buffer CONTENTS. END is the end of the buffer. Value is non-zero if successful. */ static int xbm_load_image (f, img, contents, end) struct frame *f; struct image *img; char *contents, *end; { int rc; unsigned char *data; int success_p = 0; rc = xbm_read_bitmap_data (contents, end, &img->width, &img->height, &data); if (rc) { int depth = DefaultDepthOfScreen (FRAME_X_SCREEN (f)); unsigned long foreground = FRAME_FOREGROUND_PIXEL (f); unsigned long background = FRAME_BACKGROUND_PIXEL (f); Lisp_Object value; xassert (img->width > 0 && img->height > 0); /* Get foreground and background colors, maybe allocate colors. */ value = image_spec_value (img->spec, QCforeground, NULL); if (!NILP (value)) foreground = x_alloc_image_color (f, img, value, foreground); value = image_spec_value (img->spec, QCbackground, NULL); if (!NILP (value)) { background = x_alloc_image_color (f, img, value, background); img->background = background; img->background_valid = 1; } img->pixmap = XCreatePixmapFromBitmapData (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), data, img->width, img->height, foreground, background, depth); xfree (data); if (img->pixmap == None) { x_clear_image (f, img); image_error ("Unable to create X pixmap for `%s'", img->spec, Qnil); } else success_p = 1; } else image_error ("Error loading XBM image `%s'", img->spec, Qnil); return success_p; } /* Value is non-zero if DATA looks like an in-memory XBM file. */ static int xbm_file_p (data) Lisp_Object data; { int w, h; return (STRINGP (data) && xbm_read_bitmap_data (SDATA (data), (SDATA (data) + SBYTES (data)), &w, &h, NULL)); } /* Fill image IMG which is used on frame F with pixmap data. Value is non-zero if successful. */ static int xbm_load (f, img) struct frame *f; struct image *img; { int success_p = 0; Lisp_Object file_name; xassert (xbm_image_p (img->spec)); /* If IMG->spec specifies a file name, create a non-file spec from it. */ file_name = image_spec_value (img->spec, QCfile, NULL); if (STRINGP (file_name)) { Lisp_Object file; char *contents; int size; struct gcpro gcpro1; file = x_find_image_file (file_name); GCPRO1 (file); if (!STRINGP (file)) { image_error ("Cannot find image file `%s'", file_name, Qnil); UNGCPRO; return 0; } contents = slurp_file (SDATA (file), &size); if (contents == NULL) { image_error ("Error loading XBM image `%s'", img->spec, Qnil); UNGCPRO; return 0; } success_p = xbm_load_image (f, img, contents, contents + size); UNGCPRO; } else { struct image_keyword fmt[XBM_LAST]; Lisp_Object data; int depth; unsigned long foreground = FRAME_FOREGROUND_PIXEL (f); unsigned long background = FRAME_BACKGROUND_PIXEL (f); char *bits; int parsed_p; int in_memory_file_p = 0; /* See if data looks like an in-memory XBM file. */ data = image_spec_value (img->spec, QCdata, NULL); in_memory_file_p = xbm_file_p (data); /* Parse the image specification. */ bcopy (xbm_format, fmt, sizeof fmt); parsed_p = parse_image_spec (img->spec, fmt, XBM_LAST, Qxbm); xassert (parsed_p); /* Get specified width, and height. */ if (!in_memory_file_p) { img->width = XFASTINT (fmt[XBM_WIDTH].value); img->height = XFASTINT (fmt[XBM_HEIGHT].value); xassert (img->width > 0 && img->height > 0); } /* Get foreground and background colors, maybe allocate colors. */ if (fmt[XBM_FOREGROUND].count && STRINGP (fmt[XBM_FOREGROUND].value)) foreground = x_alloc_image_color (f, img, fmt[XBM_FOREGROUND].value, foreground); if (fmt[XBM_BACKGROUND].count && STRINGP (fmt[XBM_BACKGROUND].value)) background = x_alloc_image_color (f, img, fmt[XBM_BACKGROUND].value, background); if (in_memory_file_p) success_p = xbm_load_image (f, img, SDATA (data), (SDATA (data) + SBYTES (data))); else { if (VECTORP (data)) { int i; char *p; int nbytes = (img->width + BITS_PER_CHAR - 1) / BITS_PER_CHAR; p = bits = (char *) alloca (nbytes * img->height); for (i = 0; i < img->height; ++i, p += nbytes) { Lisp_Object line = XVECTOR (data)->contents[i]; if (STRINGP (line)) bcopy (SDATA (line), p, nbytes); else bcopy (XBOOL_VECTOR (line)->data, p, nbytes); } } else if (STRINGP (data)) bits = SDATA (data); else bits = XBOOL_VECTOR (data)->data; /* Create the pixmap. */ depth = DefaultDepthOfScreen (FRAME_X_SCREEN (f)); img->pixmap = XCreatePixmapFromBitmapData (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), bits, img->width, img->height, foreground, background, depth); if (img->pixmap) success_p = 1; else { image_error ("Unable to create pixmap for XBM image `%s'", img->spec, Qnil); x_clear_image (f, img); } } } return success_p; } /*********************************************************************** XPM images ***********************************************************************/ #if HAVE_XPM static int xpm_image_p P_ ((Lisp_Object object)); static int xpm_load P_ ((struct frame *f, struct image *img)); static int xpm_valid_color_symbols_p P_ ((Lisp_Object)); #include "X11/xpm.h" /* The symbol `xpm' identifying XPM-format images. */ Lisp_Object Qxpm; /* Indices of image specification fields in xpm_format, below. */ enum xpm_keyword_index { XPM_TYPE, XPM_FILE, XPM_DATA, XPM_ASCENT, XPM_MARGIN, XPM_RELIEF, XPM_ALGORITHM, XPM_HEURISTIC_MASK, XPM_MASK, XPM_COLOR_SYMBOLS, XPM_BACKGROUND, XPM_LAST }; /* Vector of image_keyword structures describing the format of valid XPM image specifications. */ static struct image_keyword xpm_format[XPM_LAST] = { {":type", IMAGE_SYMBOL_VALUE, 1}, {":file", IMAGE_STRING_VALUE, 0}, {":data", IMAGE_STRING_VALUE, 0}, {":ascent", IMAGE_ASCENT_VALUE, 0}, {":margin", IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, 0}, {":relief", IMAGE_INTEGER_VALUE, 0}, {":conversion", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":heuristic-mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":color-symbols", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":background", IMAGE_STRING_OR_NIL_VALUE, 0} }; /* Structure describing the image type XBM. */ static struct image_type xpm_type = { &Qxpm, xpm_image_p, xpm_load, x_clear_image, NULL }; /* Define ALLOC_XPM_COLORS if we can use Emacs' own color allocation functions for allocating image colors. Our own functions handle color allocation failures more gracefully than the ones on the XPM lib. */ #if defined XpmAllocColor && defined XpmFreeColors && defined XpmColorClosure #define ALLOC_XPM_COLORS #endif #ifdef ALLOC_XPM_COLORS static void xpm_init_color_cache P_ ((struct frame *, XpmAttributes *)); static void xpm_free_color_cache P_ ((void)); static int xpm_lookup_color P_ ((struct frame *, char *, XColor *)); static int xpm_color_bucket P_ ((char *)); static struct xpm_cached_color *xpm_cache_color P_ ((struct frame *, char *, XColor *, int)); /* An entry in a hash table used to cache color definitions of named colors. This cache is necessary to speed up XPM image loading in case we do color allocations ourselves. Without it, we would need a call to XParseColor per pixel in the image. */ struct xpm_cached_color { /* Next in collision chain. */ struct xpm_cached_color *next; /* Color definition (RGB and pixel color). */ XColor color; /* Color name. */ char name[1]; }; /* The hash table used for the color cache, and its bucket vector size. */ #define XPM_COLOR_CACHE_BUCKETS 1001 struct xpm_cached_color **xpm_color_cache; /* Initialize the color cache. */ static void xpm_init_color_cache (f, attrs) struct frame *f; XpmAttributes *attrs; { size_t nbytes = XPM_COLOR_CACHE_BUCKETS * sizeof *xpm_color_cache; xpm_color_cache = (struct xpm_cached_color **) xmalloc (nbytes); memset (xpm_color_cache, 0, nbytes); init_color_table (); if (attrs->valuemask & XpmColorSymbols) { int i; XColor color; for (i = 0; i < attrs->numsymbols; ++i) if (XParseColor (FRAME_X_DISPLAY (f), FRAME_X_COLORMAP (f), attrs->colorsymbols[i].value, &color)) { color.pixel = lookup_rgb_color (f, color.red, color.green, color.blue); xpm_cache_color (f, attrs->colorsymbols[i].name, &color, -1); } } } /* Free the color cache. */ static void xpm_free_color_cache () { struct xpm_cached_color *p, *next; int i; for (i = 0; i < XPM_COLOR_CACHE_BUCKETS; ++i) for (p = xpm_color_cache[i]; p; p = next) { next = p->next; xfree (p); } xfree (xpm_color_cache); xpm_color_cache = NULL; free_color_table (); } /* Return the bucket index for color named COLOR_NAME in the color cache. */ static int xpm_color_bucket (color_name) char *color_name; { unsigned h = 0; char *s; for (s = color_name; *s; ++s) h = (h << 2) ^ *s; return h %= XPM_COLOR_CACHE_BUCKETS; } /* On frame F, cache values COLOR for color with name COLOR_NAME. BUCKET, if >= 0, is a precomputed bucket index. Value is the cache entry added. */ static struct xpm_cached_color * xpm_cache_color (f, color_name, color, bucket) struct frame *f; char *color_name; XColor *color; int bucket; { size_t nbytes; struct xpm_cached_color *p; if (bucket < 0) bucket = xpm_color_bucket (color_name); nbytes = sizeof *p + strlen (color_name); p = (struct xpm_cached_color *) xmalloc (nbytes); strcpy (p->name, color_name); p->color = *color; p->next = xpm_color_cache[bucket]; xpm_color_cache[bucket] = p; return p; } /* Look up color COLOR_NAME for frame F in the color cache. If found, return the cached definition in *COLOR. Otherwise, make a new entry in the cache and allocate the color. Value is zero if color allocation failed. */ static int xpm_lookup_color (f, color_name, color) struct frame *f; char *color_name; XColor *color; { struct xpm_cached_color *p; int h = xpm_color_bucket (color_name); for (p = xpm_color_cache[h]; p; p = p->next) if (strcmp (p->name, color_name) == 0) break; if (p != NULL) *color = p->color; else if (XParseColor (FRAME_X_DISPLAY (f), FRAME_X_COLORMAP (f), color_name, color)) { color->pixel = lookup_rgb_color (f, color->red, color->green, color->blue); p = xpm_cache_color (f, color_name, color, h); } /* You get `opaque' at least from ImageMagick converting pbm to xpm with transparency, and it's useful. */ else if (strcmp ("opaque", color_name) == 0) { bzero (color, sizeof (XColor)); /* Is this necessary/correct? */ color->pixel = FRAME_FOREGROUND_PIXEL (f); p = xpm_cache_color (f, color_name, color, h); } return p != NULL; } /* Callback for allocating color COLOR_NAME. Called from the XPM lib. CLOSURE is a pointer to the frame on which we allocate the color. Return in *COLOR the allocated color. Value is non-zero if successful. */ static int xpm_alloc_color (dpy, cmap, color_name, color, closure) Display *dpy; Colormap cmap; char *color_name; XColor *color; void *closure; { return xpm_lookup_color ((struct frame *) closure, color_name, color); } /* Callback for freeing NPIXELS colors contained in PIXELS. CLOSURE is a pointer to the frame on which we allocate the color. Value is non-zero if successful. */ static int xpm_free_colors (dpy, cmap, pixels, npixels, closure) Display *dpy; Colormap cmap; Pixel *pixels; int npixels; void *closure; { return 1; } #endif /* ALLOC_XPM_COLORS */ /* Value is non-zero if COLOR_SYMBOLS is a valid color symbols list for XPM images. Such a list must consist of conses whose car and cdr are strings. */ static int xpm_valid_color_symbols_p (color_symbols) Lisp_Object color_symbols; { while (CONSP (color_symbols)) { Lisp_Object sym = XCAR (color_symbols); if (!CONSP (sym) || !STRINGP (XCAR (sym)) || !STRINGP (XCDR (sym))) break; color_symbols = XCDR (color_symbols); } return NILP (color_symbols); } /* Value is non-zero if OBJECT is a valid XPM image specification. */ static int xpm_image_p (object) Lisp_Object object; { struct image_keyword fmt[XPM_LAST]; bcopy (xpm_format, fmt, sizeof fmt); return (parse_image_spec (object, fmt, XPM_LAST, Qxpm) /* Either `:file' or `:data' must be present. */ && fmt[XPM_FILE].count + fmt[XPM_DATA].count == 1 /* Either no `:color-symbols' or it's a list of conses whose car and cdr are strings. */ && (fmt[XPM_COLOR_SYMBOLS].count == 0 || xpm_valid_color_symbols_p (fmt[XPM_COLOR_SYMBOLS].value))); } /* Load image IMG which will be displayed on frame F. Value is non-zero if successful. */ static int xpm_load (f, img) struct frame *f; struct image *img; { int rc; XpmAttributes attrs; Lisp_Object specified_file, color_symbols; /* Configure the XPM lib. Use the visual of frame F. Allocate close colors. Return colors allocated. */ bzero (&attrs, sizeof attrs); attrs.visual = FRAME_X_VISUAL (f); attrs.colormap = FRAME_X_COLORMAP (f); attrs.valuemask |= XpmVisual; attrs.valuemask |= XpmColormap; #ifdef ALLOC_XPM_COLORS /* Allocate colors with our own functions which handle failing color allocation more gracefully. */ attrs.color_closure = f; attrs.alloc_color = xpm_alloc_color; attrs.free_colors = xpm_free_colors; attrs.valuemask |= XpmAllocColor | XpmFreeColors | XpmColorClosure; #else /* not ALLOC_XPM_COLORS */ /* Let the XPM lib allocate colors. */ attrs.valuemask |= XpmReturnAllocPixels; #ifdef XpmAllocCloseColors attrs.alloc_close_colors = 1; attrs.valuemask |= XpmAllocCloseColors; #else /* not XpmAllocCloseColors */ attrs.closeness = 600; attrs.valuemask |= XpmCloseness; #endif /* not XpmAllocCloseColors */ #endif /* ALLOC_XPM_COLORS */ /* If image specification contains symbolic color definitions, add these to `attrs'. */ color_symbols = image_spec_value (img->spec, QCcolor_symbols, NULL); if (CONSP (color_symbols)) { Lisp_Object tail; XpmColorSymbol *xpm_syms; int i, size; attrs.valuemask |= XpmColorSymbols; /* Count number of symbols. */ attrs.numsymbols = 0; for (tail = color_symbols; CONSP (tail); tail = XCDR (tail)) ++attrs.numsymbols; /* Allocate an XpmColorSymbol array. */ size = attrs.numsymbols * sizeof *xpm_syms; xpm_syms = (XpmColorSymbol *) alloca (size); bzero (xpm_syms, size); attrs.colorsymbols = xpm_syms; /* Fill the color symbol array. */ for (tail = color_symbols, i = 0; CONSP (tail); ++i, tail = XCDR (tail)) { Lisp_Object name = XCAR (XCAR (tail)); Lisp_Object color = XCDR (XCAR (tail)); xpm_syms[i].name = (char *) alloca (SCHARS (name) + 1); strcpy (xpm_syms[i].name, SDATA (name)); xpm_syms[i].value = (char *) alloca (SCHARS (color) + 1); strcpy (xpm_syms[i].value, SDATA (color)); } } /* Create a pixmap for the image, either from a file, or from a string buffer containing data in the same format as an XPM file. */ #ifdef ALLOC_XPM_COLORS xpm_init_color_cache (f, &attrs); #endif specified_file = image_spec_value (img->spec, QCfile, NULL); if (STRINGP (specified_file)) { Lisp_Object file = x_find_image_file (specified_file); if (!STRINGP (file)) { image_error ("Cannot find image file `%s'", specified_file, Qnil); return 0; } rc = XpmReadFileToPixmap (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), SDATA (file), &img->pixmap, &img->mask, &attrs); } else { Lisp_Object buffer = image_spec_value (img->spec, QCdata, NULL); rc = XpmCreatePixmapFromBuffer (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), SDATA (buffer), &img->pixmap, &img->mask, &attrs); } if (rc == XpmSuccess) { #ifdef ALLOC_XPM_COLORS img->colors = colors_in_color_table (&img->ncolors); #else /* not ALLOC_XPM_COLORS */ int i; img->ncolors = attrs.nalloc_pixels; img->colors = (unsigned long *) xmalloc (img->ncolors * sizeof *img->colors); for (i = 0; i < attrs.nalloc_pixels; ++i) { img->colors[i] = attrs.alloc_pixels[i]; #ifdef DEBUG_X_COLORS register_color (img->colors[i]); #endif } #endif /* not ALLOC_XPM_COLORS */ img->width = attrs.width; img->height = attrs.height; xassert (img->width > 0 && img->height > 0); /* The call to XpmFreeAttributes below frees attrs.alloc_pixels. */ XpmFreeAttributes (&attrs); } else { switch (rc) { case XpmOpenFailed: image_error ("Error opening XPM file (%s)", img->spec, Qnil); break; case XpmFileInvalid: image_error ("Invalid XPM file (%s)", img->spec, Qnil); break; case XpmNoMemory: image_error ("Out of memory (%s)", img->spec, Qnil); break; case XpmColorFailed: image_error ("Color allocation error (%s)", img->spec, Qnil); break; default: image_error ("Unknown error (%s)", img->spec, Qnil); break; } } #ifdef ALLOC_XPM_COLORS xpm_free_color_cache (); #endif return rc == XpmSuccess; } #endif /* HAVE_XPM != 0 */ /*********************************************************************** Color table ***********************************************************************/ /* An entry in the color table mapping an RGB color to a pixel color. */ struct ct_color { int r, g, b; unsigned long pixel; /* Next in color table collision list. */ struct ct_color *next; }; /* The bucket vector size to use. Must be prime. */ #define CT_SIZE 101 /* Value is a hash of the RGB color given by R, G, and B. */ #define CT_HASH_RGB(R, G, B) (((R) << 16) ^ ((G) << 8) ^ (B)) /* The color hash table. */ struct ct_color **ct_table; /* Number of entries in the color table. */ int ct_colors_allocated; /* Initialize the color table. */ static void init_color_table () { int size = CT_SIZE * sizeof (*ct_table); ct_table = (struct ct_color **) xmalloc (size); bzero (ct_table, size); ct_colors_allocated = 0; } /* Free memory associated with the color table. */ static void free_color_table () { int i; struct ct_color *p, *next; for (i = 0; i < CT_SIZE; ++i) for (p = ct_table[i]; p; p = next) { next = p->next; xfree (p); } xfree (ct_table); ct_table = NULL; } /* Value is a pixel color for RGB color R, G, B on frame F. If an entry for that color already is in the color table, return the pixel color of that entry. Otherwise, allocate a new color for R, G, B, and make an entry in the color table. */ static unsigned long lookup_rgb_color (f, r, g, b) struct frame *f; int r, g, b; { unsigned hash = CT_HASH_RGB (r, g, b); int i = hash % CT_SIZE; struct ct_color *p; for (p = ct_table[i]; p; p = p->next) if (p->r == r && p->g == g && p->b == b) break; if (p == NULL) { XColor color; Colormap cmap; int rc; color.red = r; color.green = g; color.blue = b; cmap = FRAME_X_COLORMAP (f); rc = x_alloc_nearest_color (f, cmap, &color); if (rc) { ++ct_colors_allocated; p = (struct ct_color *) xmalloc (sizeof *p); p->r = r; p->g = g; p->b = b; p->pixel = color.pixel; p->next = ct_table[i]; ct_table[i] = p; } else return FRAME_FOREGROUND_PIXEL (f); } return p->pixel; } /* Look up pixel color PIXEL which is used on frame F in the color table. If not already present, allocate it. Value is PIXEL. */ static unsigned long lookup_pixel_color (f, pixel) struct frame *f; unsigned long pixel; { int i = pixel % CT_SIZE; struct ct_color *p; for (p = ct_table[i]; p; p = p->next) if (p->pixel == pixel) break; if (p == NULL) { XColor color; Colormap cmap; int rc; cmap = FRAME_X_COLORMAP (f); color.pixel = pixel; x_query_color (f, &color); rc = x_alloc_nearest_color (f, cmap, &color); if (rc) { ++ct_colors_allocated; p = (struct ct_color *) xmalloc (sizeof *p); p->r = color.red; p->g = color.green; p->b = color.blue; p->pixel = pixel; p->next = ct_table[i]; ct_table[i] = p; } else return FRAME_FOREGROUND_PIXEL (f); } return p->pixel; } /* Value is a vector of all pixel colors contained in the color table, allocated via xmalloc. Set *N to the number of colors. */ static unsigned long * colors_in_color_table (n) int *n; { int i, j; struct ct_color *p; unsigned long *colors; if (ct_colors_allocated == 0) { *n = 0; colors = NULL; } else { colors = (unsigned long *) xmalloc (ct_colors_allocated * sizeof *colors); *n = ct_colors_allocated; for (i = j = 0; i < CT_SIZE; ++i) for (p = ct_table[i]; p; p = p->next) colors[j++] = p->pixel; } return colors; } /*********************************************************************** Algorithms ***********************************************************************/ static XColor *x_to_xcolors P_ ((struct frame *, struct image *, int)); static void x_from_xcolors P_ ((struct frame *, struct image *, XColor *)); static void x_detect_edges P_ ((struct frame *, struct image *, int[9], int)); /* Non-zero means draw a cross on images having `:conversion disabled'. */ int cross_disabled_images; /* Edge detection matrices for different edge-detection strategies. */ static int emboss_matrix[9] = { /* x - 1 x x + 1 */ 2, -1, 0, /* y - 1 */ -1, 0, 1, /* y */ 0, 1, -2 /* y + 1 */ }; static int laplace_matrix[9] = { /* x - 1 x x + 1 */ 1, 0, 0, /* y - 1 */ 0, 0, 0, /* y */ 0, 0, -1 /* y + 1 */ }; /* Value is the intensity of the color whose red/green/blue values are R, G, and B. */ #define COLOR_INTENSITY(R, G, B) ((2 * (R) + 3 * (G) + (B)) / 6) /* On frame F, return an array of XColor structures describing image IMG->pixmap. Each XColor structure has its pixel color set. RGB_P non-zero means also fill the red/green/blue members of the XColor structures. Value is a pointer to the array of XColors structures, allocated with xmalloc; it must be freed by the caller. */ static XColor * x_to_xcolors (f, img, rgb_p) struct frame *f; struct image *img; int rgb_p; { int x, y; XColor *colors, *p; XImage *ximg; colors = (XColor *) xmalloc (img->width * img->height * sizeof *colors); /* Get the X image IMG->pixmap. */ ximg = XGetImage (FRAME_X_DISPLAY (f), img->pixmap, 0, 0, img->width, img->height, ~0, ZPixmap); /* Fill the `pixel' members of the XColor array. I wished there were an easy and portable way to circumvent XGetPixel. */ p = colors; for (y = 0; y < img->height; ++y) { XColor *row = p; for (x = 0; x < img->width; ++x, ++p) p->pixel = XGetPixel (ximg, x, y); if (rgb_p) x_query_colors (f, row, img->width); } XDestroyImage (ximg); return colors; } /* Create IMG->pixmap from an array COLORS of XColor structures, whose RGB members are set. F is the frame on which this all happens. COLORS will be freed; an existing IMG->pixmap will be freed, too. */ static void x_from_xcolors (f, img, colors) struct frame *f; struct image *img; XColor *colors; { int x, y; XImage *oimg; Pixmap pixmap; XColor *p; init_color_table (); x_create_x_image_and_pixmap (f, img->width, img->height, 0, &oimg, &pixmap); p = colors; for (y = 0; y < img->height; ++y) for (x = 0; x < img->width; ++x, ++p) { unsigned long pixel; pixel = lookup_rgb_color (f, p->red, p->green, p->blue); XPutPixel (oimg, x, y, pixel); } xfree (colors); x_clear_image_1 (f, img, 1, 0, 1); x_put_x_image (f, oimg, pixmap, img->width, img->height); x_destroy_x_image (oimg); img->pixmap = pixmap; img->colors = colors_in_color_table (&img->ncolors); free_color_table (); } /* On frame F, perform edge-detection on image IMG. MATRIX is a nine-element array specifying the transformation matrix. See emboss_matrix for an example. COLOR_ADJUST is a color adjustment added to each pixel of the outgoing image. */ static void x_detect_edges (f, img, matrix, color_adjust) struct frame *f; struct image *img; int matrix[9], color_adjust; { XColor *colors = x_to_xcolors (f, img, 1); XColor *new, *p; int x, y, i, sum; for (i = sum = 0; i < 9; ++i) sum += abs (matrix[i]); #define COLOR(A, X, Y) ((A) + (Y) * img->width + (X)) new = (XColor *) xmalloc (img->width * img->height * sizeof *new); for (y = 0; y < img->height; ++y) { p = COLOR (new, 0, y); p->red = p->green = p->blue = 0xffff/2; p = COLOR (new, img->width - 1, y); p->red = p->green = p->blue = 0xffff/2; } for (x = 1; x < img->width - 1; ++x) { p = COLOR (new, x, 0); p->red = p->green = p->blue = 0xffff/2; p = COLOR (new, x, img->height - 1); p->red = p->green = p->blue = 0xffff/2; } for (y = 1; y < img->height - 1; ++y) { p = COLOR (new, 1, y); for (x = 1; x < img->width - 1; ++x, ++p) { int r, g, b, y1, x1; r = g = b = i = 0; for (y1 = y - 1; y1 < y + 2; ++y1) for (x1 = x - 1; x1 < x + 2; ++x1, ++i) if (matrix[i]) { XColor *t = COLOR (colors, x1, y1); r += matrix[i] * t->red; g += matrix[i] * t->green; b += matrix[i] * t->blue; } r = (r / sum + color_adjust) & 0xffff; g = (g / sum + color_adjust) & 0xffff; b = (b / sum + color_adjust) & 0xffff; p->red = p->green = p->blue = COLOR_INTENSITY (r, g, b); } } xfree (colors); x_from_xcolors (f, img, new); #undef COLOR } /* Perform the pre-defined `emboss' edge-detection on image IMG on frame F. */ static void x_emboss (f, img) struct frame *f; struct image *img; { x_detect_edges (f, img, emboss_matrix, 0xffff / 2); } /* Perform the pre-defined `laplace' edge-detection on image IMG on frame F. */ static void x_laplace (f, img) struct frame *f; struct image *img; { x_detect_edges (f, img, laplace_matrix, 45000); } /* Perform edge-detection on image IMG on frame F, with specified transformation matrix MATRIX and color-adjustment COLOR_ADJUST. MATRIX must be either - a list of at least 9 numbers in row-major form - a vector of at least 9 numbers COLOR_ADJUST nil means use a default; otherwise it must be a number. */ static void x_edge_detection (f, img, matrix, color_adjust) struct frame *f; struct image *img; Lisp_Object matrix, color_adjust; { int i = 0; int trans[9]; if (CONSP (matrix)) { for (i = 0; i < 9 && CONSP (matrix) && NUMBERP (XCAR (matrix)); ++i, matrix = XCDR (matrix)) trans[i] = XFLOATINT (XCAR (matrix)); } else if (VECTORP (matrix) && ASIZE (matrix) >= 9) { for (i = 0; i < 9 && NUMBERP (AREF (matrix, i)); ++i) trans[i] = XFLOATINT (AREF (matrix, i)); } if (NILP (color_adjust)) color_adjust = make_number (0xffff / 2); if (i == 9 && NUMBERP (color_adjust)) x_detect_edges (f, img, trans, (int) XFLOATINT (color_adjust)); } /* Transform image IMG on frame F so that it looks disabled. */ static void x_disable_image (f, img) struct frame *f; struct image *img; { struct x_display_info *dpyinfo = FRAME_X_DISPLAY_INFO (f); if (dpyinfo->n_planes >= 2) { /* Color (or grayscale). Convert to gray, and equalize. Just drawing such images with a stipple can look very odd, so we're using this method instead. */ XColor *colors = x_to_xcolors (f, img, 1); XColor *p, *end; const int h = 15000; const int l = 30000; for (p = colors, end = colors + img->width * img->height; p < end; ++p) { int i = COLOR_INTENSITY (p->red, p->green, p->blue); int i2 = (0xffff - h - l) * i / 0xffff + l; p->red = p->green = p->blue = i2; } x_from_xcolors (f, img, colors); } /* Draw a cross over the disabled image, if we must or if we should. */ if (dpyinfo->n_planes < 2 || cross_disabled_images) { Display *dpy = FRAME_X_DISPLAY (f); GC gc; gc = XCreateGC (dpy, img->pixmap, 0, NULL); XSetForeground (dpy, gc, BLACK_PIX_DEFAULT (f)); XDrawLine (dpy, img->pixmap, gc, 0, 0, img->width - 1, img->height - 1); XDrawLine (dpy, img->pixmap, gc, 0, img->height - 1, img->width - 1, 0); XFreeGC (dpy, gc); if (img->mask) { gc = XCreateGC (dpy, img->mask, 0, NULL); XSetForeground (dpy, gc, WHITE_PIX_DEFAULT (f)); XDrawLine (dpy, img->mask, gc, 0, 0, img->width - 1, img->height - 1); XDrawLine (dpy, img->mask, gc, 0, img->height - 1, img->width - 1, 0); XFreeGC (dpy, gc); } } } /* Build a mask for image IMG which is used on frame F. FILE is the name of an image file, for error messages. HOW determines how to determine the background color of IMG. If it is a list '(R G B)', with R, G, and B being integers >= 0, take that as the color of the background. Otherwise, determine the background color of IMG heuristically. Value is non-zero if successful. */ static int x_build_heuristic_mask (f, img, how) struct frame *f; struct image *img; Lisp_Object how; { Display *dpy = FRAME_X_DISPLAY (f); XImage *ximg, *mask_img; int x, y, rc, use_img_background; unsigned long bg = 0; if (img->mask) { XFreePixmap (FRAME_X_DISPLAY (f), img->mask); img->mask = None; img->background_transparent_valid = 0; } /* Create an image and pixmap serving as mask. */ rc = x_create_x_image_and_pixmap (f, img->width, img->height, 1, &mask_img, &img->mask); if (!rc) return 0; /* Get the X image of IMG->pixmap. */ ximg = XGetImage (dpy, img->pixmap, 0, 0, img->width, img->height, ~0, ZPixmap); /* Determine the background color of ximg. If HOW is `(R G B)' take that as color. Otherwise, use the image's background color. */ use_img_background = 1; if (CONSP (how)) { int rgb[3], i; for (i = 0; i < 3 && CONSP (how) && NATNUMP (XCAR (how)); ++i) { rgb[i] = XFASTINT (XCAR (how)) & 0xffff; how = XCDR (how); } if (i == 3 && NILP (how)) { char color_name[30]; sprintf (color_name, "#%04x%04x%04x", rgb[0], rgb[1], rgb[2]); bg = x_alloc_image_color (f, img, build_string (color_name), 0); use_img_background = 0; } } if (use_img_background) bg = four_corners_best (ximg, img->width, img->height); /* Set all bits in mask_img to 1 whose color in ximg is different from the background color bg. */ for (y = 0; y < img->height; ++y) for (x = 0; x < img->width; ++x) XPutPixel (mask_img, x, y, XGetPixel (ximg, x, y) != bg); /* Fill in the background_transparent field while we have the mask handy. */ image_background_transparent (img, f, mask_img); /* Put mask_img into img->mask. */ x_put_x_image (f, mask_img, img->mask, img->width, img->height); x_destroy_x_image (mask_img); XDestroyImage (ximg); return 1; } /*********************************************************************** PBM (mono, gray, color) ***********************************************************************/ static int pbm_image_p P_ ((Lisp_Object object)); static int pbm_load P_ ((struct frame *f, struct image *img)); static int pbm_scan_number P_ ((unsigned char **, unsigned char *)); /* The symbol `pbm' identifying images of this type. */ Lisp_Object Qpbm; /* Indices of image specification fields in gs_format, below. */ enum pbm_keyword_index { PBM_TYPE, PBM_FILE, PBM_DATA, PBM_ASCENT, PBM_MARGIN, PBM_RELIEF, PBM_ALGORITHM, PBM_HEURISTIC_MASK, PBM_MASK, PBM_FOREGROUND, PBM_BACKGROUND, PBM_LAST }; /* Vector of image_keyword structures describing the format of valid user-defined image specifications. */ static struct image_keyword pbm_format[PBM_LAST] = { {":type", IMAGE_SYMBOL_VALUE, 1}, {":file", IMAGE_STRING_VALUE, 0}, {":data", IMAGE_STRING_VALUE, 0}, {":ascent", IMAGE_ASCENT_VALUE, 0}, {":margin", IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, 0}, {":relief", IMAGE_INTEGER_VALUE, 0}, {":conversion", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":heuristic-mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":foreground", IMAGE_STRING_OR_NIL_VALUE, 0}, {":background", IMAGE_STRING_OR_NIL_VALUE, 0} }; /* Structure describing the image type `pbm'. */ static struct image_type pbm_type = { &Qpbm, pbm_image_p, pbm_load, x_clear_image, NULL }; /* Return non-zero if OBJECT is a valid PBM image specification. */ static int pbm_image_p (object) Lisp_Object object; { struct image_keyword fmt[PBM_LAST]; bcopy (pbm_format, fmt, sizeof fmt); if (!parse_image_spec (object, fmt, PBM_LAST, Qpbm)) return 0; /* Must specify either :data or :file. */ return fmt[PBM_DATA].count + fmt[PBM_FILE].count == 1; } /* Scan a decimal number from *S and return it. Advance *S while reading the number. END is the end of the string. Value is -1 at end of input. */ static int pbm_scan_number (s, end) unsigned char **s, *end; { int c = 0, val = -1; while (*s < end) { /* Skip white-space. */ while (*s < end && (c = *(*s)++, isspace (c))) ; if (c == '#') { /* Skip comment to end of line. */ while (*s < end && (c = *(*s)++, c != '\n')) ; } else if (isdigit (c)) { /* Read decimal number. */ val = c - '0'; while (*s < end && (c = *(*s)++, isdigit (c))) val = 10 * val + c - '0'; break; } else break; } return val; } /* Load PBM image IMG for use on frame F. */ static int pbm_load (f, img) struct frame *f; struct image *img; { int raw_p, x, y; int width, height, max_color_idx = 0; XImage *ximg; Lisp_Object file, specified_file; enum {PBM_MONO, PBM_GRAY, PBM_COLOR} type; struct gcpro gcpro1; unsigned char *contents = NULL; unsigned char *end, *p; int size; specified_file = image_spec_value (img->spec, QCfile, NULL); file = Qnil; GCPRO1 (file); if (STRINGP (specified_file)) { file = x_find_image_file (specified_file); if (!STRINGP (file)) { image_error ("Cannot find image file `%s'", specified_file, Qnil); UNGCPRO; return 0; } contents = slurp_file (SDATA (file), &size); if (contents == NULL) { image_error ("Error reading `%s'", file, Qnil); UNGCPRO; return 0; } p = contents; end = contents + size; } else { Lisp_Object data; data = image_spec_value (img->spec, QCdata, NULL); p = SDATA (data); end = p + SBYTES (data); } /* Check magic number. */ if (end - p < 2 || *p++ != 'P') { image_error ("Not a PBM image: `%s'", img->spec, Qnil); error: xfree (contents); UNGCPRO; return 0; } switch (*p++) { case '1': raw_p = 0, type = PBM_MONO; break; case '2': raw_p = 0, type = PBM_GRAY; break; case '3': raw_p = 0, type = PBM_COLOR; break; case '4': raw_p = 1, type = PBM_MONO; break; case '5': raw_p = 1, type = PBM_GRAY; break; case '6': raw_p = 1, type = PBM_COLOR; break; default: image_error ("Not a PBM image: `%s'", img->spec, Qnil); goto error; } /* Read width, height, maximum color-component. Characters starting with `#' up to the end of a line are ignored. */ width = pbm_scan_number (&p, end); height = pbm_scan_number (&p, end); if (type != PBM_MONO) { max_color_idx = pbm_scan_number (&p, end); if (raw_p && max_color_idx > 255) max_color_idx = 255; } if (width < 0 || height < 0 || (type != PBM_MONO && max_color_idx < 0)) goto error; if (!x_create_x_image_and_pixmap (f, width, height, 0, &ximg, &img->pixmap)) goto error; /* Initialize the color hash table. */ init_color_table (); if (type == PBM_MONO) { int c = 0, g; struct image_keyword fmt[PBM_LAST]; unsigned long fg = FRAME_FOREGROUND_PIXEL (f); unsigned long bg = FRAME_BACKGROUND_PIXEL (f); /* Parse the image specification. */ bcopy (pbm_format, fmt, sizeof fmt); parse_image_spec (img->spec, fmt, PBM_LAST, Qpbm); /* Get foreground and background colors, maybe allocate colors. */ if (fmt[PBM_FOREGROUND].count && STRINGP (fmt[PBM_FOREGROUND].value)) fg = x_alloc_image_color (f, img, fmt[PBM_FOREGROUND].value, fg); if (fmt[PBM_BACKGROUND].count && STRINGP (fmt[PBM_BACKGROUND].value)) { bg = x_alloc_image_color (f, img, fmt[PBM_BACKGROUND].value, bg); img->background = bg; img->background_valid = 1; } for (y = 0; y < height; ++y) for (x = 0; x < width; ++x) { if (raw_p) { if ((x & 7) == 0) c = *p++; g = c & 0x80; c <<= 1; } else g = pbm_scan_number (&p, end); XPutPixel (ximg, x, y, g ? fg : bg); } } else { for (y = 0; y < height; ++y) for (x = 0; x < width; ++x) { int r, g, b; if (type == PBM_GRAY) r = g = b = raw_p ? *p++ : pbm_scan_number (&p, end); else if (raw_p) { r = *p++; g = *p++; b = *p++; } else { r = pbm_scan_number (&p, end); g = pbm_scan_number (&p, end); b = pbm_scan_number (&p, end); } if (r < 0 || g < 0 || b < 0) { xfree (ximg->data); ximg->data = NULL; XDestroyImage (ximg); image_error ("Invalid pixel value in image `%s'", img->spec, Qnil); goto error; } /* RGB values are now in the range 0..max_color_idx. Scale this to the range 0..0xffff supported by X. */ r = (double) r * 65535 / max_color_idx; g = (double) g * 65535 / max_color_idx; b = (double) b * 65535 / max_color_idx; XPutPixel (ximg, x, y, lookup_rgb_color (f, r, g, b)); } } /* Store in IMG->colors the colors allocated for the image, and free the color table. */ img->colors = colors_in_color_table (&img->ncolors); free_color_table (); /* Maybe fill in the background field while we have ximg handy. */ if (NILP (image_spec_value (img->spec, QCbackground, NULL))) IMAGE_BACKGROUND (img, f, ximg); /* Put the image into a pixmap. */ x_put_x_image (f, ximg, img->pixmap, width, height); x_destroy_x_image (ximg); img->width = width; img->height = height; UNGCPRO; xfree (contents); return 1; } /*********************************************************************** PNG ***********************************************************************/ #if HAVE_PNG #include /* Function prototypes. */ static int png_image_p P_ ((Lisp_Object object)); static int png_load P_ ((struct frame *f, struct image *img)); /* The symbol `png' identifying images of this type. */ Lisp_Object Qpng; /* Indices of image specification fields in png_format, below. */ enum png_keyword_index { PNG_TYPE, PNG_DATA, PNG_FILE, PNG_ASCENT, PNG_MARGIN, PNG_RELIEF, PNG_ALGORITHM, PNG_HEURISTIC_MASK, PNG_MASK, PNG_BACKGROUND, PNG_LAST }; /* Vector of image_keyword structures describing the format of valid user-defined image specifications. */ static struct image_keyword png_format[PNG_LAST] = { {":type", IMAGE_SYMBOL_VALUE, 1}, {":data", IMAGE_STRING_VALUE, 0}, {":file", IMAGE_STRING_VALUE, 0}, {":ascent", IMAGE_ASCENT_VALUE, 0}, {":margin", IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, 0}, {":relief", IMAGE_INTEGER_VALUE, 0}, {":conversion", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":heuristic-mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":background", IMAGE_STRING_OR_NIL_VALUE, 0} }; /* Structure describing the image type `png'. */ static struct image_type png_type = { &Qpng, png_image_p, png_load, x_clear_image, NULL }; /* Return non-zero if OBJECT is a valid PNG image specification. */ static int png_image_p (object) Lisp_Object object; { struct image_keyword fmt[PNG_LAST]; bcopy (png_format, fmt, sizeof fmt); if (!parse_image_spec (object, fmt, PNG_LAST, Qpng)) return 0; /* Must specify either the :data or :file keyword. */ return fmt[PNG_FILE].count + fmt[PNG_DATA].count == 1; } /* Error and warning handlers installed when the PNG library is initialized. */ static void my_png_error (png_ptr, msg) png_struct *png_ptr; char *msg; { xassert (png_ptr != NULL); image_error ("PNG error: %s", build_string (msg), Qnil); longjmp (png_ptr->jmpbuf, 1); } static void my_png_warning (png_ptr, msg) png_struct *png_ptr; char *msg; { xassert (png_ptr != NULL); image_error ("PNG warning: %s", build_string (msg), Qnil); } /* Memory source for PNG decoding. */ struct png_memory_storage { unsigned char *bytes; /* The data */ size_t len; /* How big is it? */ int index; /* Where are we? */ }; /* Function set as reader function when reading PNG image from memory. PNG_PTR is a pointer to the PNG control structure. Copy LENGTH bytes from the input to DATA. */ static void png_read_from_memory (png_ptr, data, length) png_structp png_ptr; png_bytep data; png_size_t length; { struct png_memory_storage *tbr = (struct png_memory_storage *) png_get_io_ptr (png_ptr); if (length > tbr->len - tbr->index) png_error (png_ptr, "Read error"); bcopy (tbr->bytes + tbr->index, data, length); tbr->index = tbr->index + length; } /* Load PNG image IMG for use on frame F. Value is non-zero if successful. */ static int png_load (f, img) struct frame *f; struct image *img; { Lisp_Object file, specified_file; Lisp_Object specified_data; int x, y, i; XImage *ximg, *mask_img = NULL; struct gcpro gcpro1; png_struct *png_ptr = NULL; png_info *info_ptr = NULL, *end_info = NULL; FILE *volatile fp = NULL; png_byte sig[8]; png_byte * volatile pixels = NULL; png_byte ** volatile rows = NULL; png_uint_32 width, height; int bit_depth, color_type, interlace_type; png_byte channels; png_uint_32 row_bytes; int transparent_p; double screen_gamma; struct png_memory_storage tbr; /* Data to be read */ /* Find out what file to load. */ specified_file = image_spec_value (img->spec, QCfile, NULL); specified_data = image_spec_value (img->spec, QCdata, NULL); file = Qnil; GCPRO1 (file); if (NILP (specified_data)) { file = x_find_image_file (specified_file); if (!STRINGP (file)) { image_error ("Cannot find image file `%s'", specified_file, Qnil); UNGCPRO; return 0; } /* Open the image file. */ fp = fopen (SDATA (file), "rb"); if (!fp) { image_error ("Cannot open image file `%s'", file, Qnil); UNGCPRO; fclose (fp); return 0; } /* Check PNG signature. */ if (fread (sig, 1, sizeof sig, fp) != sizeof sig || !png_check_sig (sig, sizeof sig)) { image_error ("Not a PNG file: `%s'", file, Qnil); UNGCPRO; fclose (fp); return 0; } } else { /* Read from memory. */ tbr.bytes = SDATA (specified_data); tbr.len = SBYTES (specified_data); tbr.index = 0; /* Check PNG signature. */ if (tbr.len < sizeof sig || !png_check_sig (tbr.bytes, sizeof sig)) { image_error ("Not a PNG image: `%s'", img->spec, Qnil); UNGCPRO; return 0; } /* Need to skip past the signature. */ tbr.bytes += sizeof (sig); } /* Initialize read and info structs for PNG lib. */ png_ptr = png_create_read_struct (PNG_LIBPNG_VER_STRING, NULL, my_png_error, my_png_warning); if (!png_ptr) { if (fp) fclose (fp); UNGCPRO; return 0; } info_ptr = png_create_info_struct (png_ptr); if (!info_ptr) { png_destroy_read_struct (&png_ptr, NULL, NULL); if (fp) fclose (fp); UNGCPRO; return 0; } end_info = png_create_info_struct (png_ptr); if (!end_info) { png_destroy_read_struct (&png_ptr, &info_ptr, NULL); if (fp) fclose (fp); UNGCPRO; return 0; } /* Set error jump-back. We come back here when the PNG library detects an error. */ if (setjmp (png_ptr->jmpbuf)) { error: if (png_ptr) png_destroy_read_struct (&png_ptr, &info_ptr, &end_info); xfree (pixels); xfree (rows); if (fp) fclose (fp); UNGCPRO; return 0; } /* Read image info. */ if (!NILP (specified_data)) png_set_read_fn (png_ptr, (void *) &tbr, png_read_from_memory); else png_init_io (png_ptr, fp); png_set_sig_bytes (png_ptr, sizeof sig); png_read_info (png_ptr, info_ptr); png_get_IHDR (png_ptr, info_ptr, &width, &height, &bit_depth, &color_type, &interlace_type, NULL, NULL); /* If image contains simply transparency data, we prefer to construct a clipping mask. */ if (png_get_valid (png_ptr, info_ptr, PNG_INFO_tRNS)) transparent_p = 1; else transparent_p = 0; /* This function is easier to write if we only have to handle one data format: RGB or RGBA with 8 bits per channel. Let's transform other formats into that format. */ /* Strip more than 8 bits per channel. */ if (bit_depth == 16) png_set_strip_16 (png_ptr); /* Expand data to 24 bit RGB, or 8 bit grayscale, with alpha channel if available. */ png_set_expand (png_ptr); /* Convert grayscale images to RGB. */ if (color_type == PNG_COLOR_TYPE_GRAY || color_type == PNG_COLOR_TYPE_GRAY_ALPHA) png_set_gray_to_rgb (png_ptr); screen_gamma = (f->gamma ? 1 / f->gamma / 0.45455 : 2.2); #if 0 /* Avoid double gamma correction for PNG images. */ { /* Tell the PNG lib to handle gamma correction for us. */ int intent; double image_gamma; #if defined(PNG_READ_sRGB_SUPPORTED) || defined(PNG_WRITE_sRGB_SUPPORTED) if (png_get_sRGB (png_ptr, info_ptr, &intent)) /* The libpng documentation says this is right in this case. */ png_set_gamma (png_ptr, screen_gamma, 0.45455); else #endif if (png_get_gAMA (png_ptr, info_ptr, &image_gamma)) /* Image contains gamma information. */ png_set_gamma (png_ptr, screen_gamma, image_gamma); else /* Use the standard default for the image gamma. */ png_set_gamma (png_ptr, screen_gamma, 0.45455); } #endif /* if 0 */ /* Handle alpha channel by combining the image with a background color. Do this only if a real alpha channel is supplied. For simple transparency, we prefer a clipping mask. */ if (!transparent_p) { png_color_16 *image_bg; Lisp_Object specified_bg = image_spec_value (img->spec, QCbackground, NULL); if (STRINGP (specified_bg)) /* The user specified `:background', use that. */ { XColor color; if (x_defined_color (f, SDATA (specified_bg), &color, 0)) { png_color_16 user_bg; bzero (&user_bg, sizeof user_bg); user_bg.red = color.red; user_bg.green = color.green; user_bg.blue = color.blue; png_set_background (png_ptr, &user_bg, PNG_BACKGROUND_GAMMA_SCREEN, 0, 1.0); } } else if (png_get_bKGD (png_ptr, info_ptr, &image_bg)) /* Image contains a background color with which to combine the image. */ png_set_background (png_ptr, image_bg, PNG_BACKGROUND_GAMMA_FILE, 1, 1.0); else { /* Image does not contain a background color with which to combine the image data via an alpha channel. Use the frame's background instead. */ XColor color; Colormap cmap; png_color_16 frame_background; cmap = FRAME_X_COLORMAP (f); color.pixel = FRAME_BACKGROUND_PIXEL (f); x_query_color (f, &color); bzero (&frame_background, sizeof frame_background); frame_background.red = color.red; frame_background.green = color.green; frame_background.blue = color.blue; png_set_background (png_ptr, &frame_background, PNG_BACKGROUND_GAMMA_SCREEN, 0, 1.0); } } /* Update info structure. */ png_read_update_info (png_ptr, info_ptr); /* Get number of channels. Valid values are 1 for grayscale images and images with a palette, 2 for grayscale images with transparency information (alpha channel), 3 for RGB images, and 4 for RGB images with alpha channel, i.e. RGBA. If conversions above were sufficient we should only have 3 or 4 channels here. */ channels = png_get_channels (png_ptr, info_ptr); xassert (channels == 3 || channels == 4); /* Number of bytes needed for one row of the image. */ row_bytes = png_get_rowbytes (png_ptr, info_ptr); /* Allocate memory for the image. */ pixels = (png_byte *) xmalloc (row_bytes * height * sizeof *pixels); rows = (png_byte **) xmalloc (height * sizeof *rows); for (i = 0; i < height; ++i) rows[i] = pixels + i * row_bytes; /* Read the entire image. */ png_read_image (png_ptr, rows); png_read_end (png_ptr, info_ptr); if (fp) { fclose (fp); fp = NULL; } /* Create the X image and pixmap. */ if (!x_create_x_image_and_pixmap (f, width, height, 0, &ximg, &img->pixmap)) goto error; /* Create an image and pixmap serving as mask if the PNG image contains an alpha channel. */ if (channels == 4 && !transparent_p && !x_create_x_image_and_pixmap (f, width, height, 1, &mask_img, &img->mask)) { x_destroy_x_image (ximg); XFreePixmap (FRAME_X_DISPLAY (f), img->pixmap); img->pixmap = None; goto error; } /* Fill the X image and mask from PNG data. */ init_color_table (); for (y = 0; y < height; ++y) { png_byte *p = rows[y]; for (x = 0; x < width; ++x) { unsigned r, g, b; r = *p++ << 8; g = *p++ << 8; b = *p++ << 8; XPutPixel (ximg, x, y, lookup_rgb_color (f, r, g, b)); /* An alpha channel, aka mask channel, associates variable transparency with an image. Where other image formats support binary transparency---fully transparent or fully opaque---PNG allows up to 254 levels of partial transparency. The PNG library implements partial transparency by combining the image with a specified background color. I'm not sure how to handle this here nicely: because the background on which the image is displayed may change, for real alpha channel support, it would be necessary to create a new image for each possible background. What I'm doing now is that a mask is created if we have boolean transparency information. Otherwise I'm using the frame's background color to combine the image with. */ if (channels == 4) { if (mask_img) XPutPixel (mask_img, x, y, *p > 0); ++p; } } } if (NILP (image_spec_value (img->spec, QCbackground, NULL))) /* Set IMG's background color from the PNG image, unless the user overrode it. */ { png_color_16 *bg; if (png_get_bKGD (png_ptr, info_ptr, &bg)) { img->background = lookup_rgb_color (f, bg->red, bg->green, bg->blue); img->background_valid = 1; } } /* Remember colors allocated for this image. */ img->colors = colors_in_color_table (&img->ncolors); free_color_table (); /* Clean up. */ png_destroy_read_struct (&png_ptr, &info_ptr, &end_info); xfree (rows); xfree (pixels); img->width = width; img->height = height; /* Maybe fill in the background field while we have ximg handy. */ IMAGE_BACKGROUND (img, f, ximg); /* Put the image into the pixmap, then free the X image and its buffer. */ x_put_x_image (f, ximg, img->pixmap, width, height); x_destroy_x_image (ximg); /* Same for the mask. */ if (mask_img) { /* Fill in the background_transparent field while we have the mask handy. */ image_background_transparent (img, f, mask_img); x_put_x_image (f, mask_img, img->mask, img->width, img->height); x_destroy_x_image (mask_img); } UNGCPRO; return 1; } #endif /* HAVE_PNG != 0 */ /*********************************************************************** JPEG ***********************************************************************/ #if HAVE_JPEG /* Work around a warning about HAVE_STDLIB_H being redefined in jconfig.h. */ #ifdef HAVE_STDLIB_H #define HAVE_STDLIB_H_1 #undef HAVE_STDLIB_H #endif /* HAVE_STLIB_H */ #include #include #include #ifdef HAVE_STLIB_H_1 #define HAVE_STDLIB_H 1 #endif static int jpeg_image_p P_ ((Lisp_Object object)); static int jpeg_load P_ ((struct frame *f, struct image *img)); /* The symbol `jpeg' identifying images of this type. */ Lisp_Object Qjpeg; /* Indices of image specification fields in gs_format, below. */ enum jpeg_keyword_index { JPEG_TYPE, JPEG_DATA, JPEG_FILE, JPEG_ASCENT, JPEG_MARGIN, JPEG_RELIEF, JPEG_ALGORITHM, JPEG_HEURISTIC_MASK, JPEG_MASK, JPEG_BACKGROUND, JPEG_LAST }; /* Vector of image_keyword structures describing the format of valid user-defined image specifications. */ static struct image_keyword jpeg_format[JPEG_LAST] = { {":type", IMAGE_SYMBOL_VALUE, 1}, {":data", IMAGE_STRING_VALUE, 0}, {":file", IMAGE_STRING_VALUE, 0}, {":ascent", IMAGE_ASCENT_VALUE, 0}, {":margin", IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, 0}, {":relief", IMAGE_INTEGER_VALUE, 0}, {":conversions", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":heuristic-mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":background", IMAGE_STRING_OR_NIL_VALUE, 0} }; /* Structure describing the image type `jpeg'. */ static struct image_type jpeg_type = { &Qjpeg, jpeg_image_p, jpeg_load, x_clear_image, NULL }; /* Return non-zero if OBJECT is a valid JPEG image specification. */ static int jpeg_image_p (object) Lisp_Object object; { struct image_keyword fmt[JPEG_LAST]; bcopy (jpeg_format, fmt, sizeof fmt); if (!parse_image_spec (object, fmt, JPEG_LAST, Qjpeg)) return 0; /* Must specify either the :data or :file keyword. */ return fmt[JPEG_FILE].count + fmt[JPEG_DATA].count == 1; } struct my_jpeg_error_mgr { struct jpeg_error_mgr pub; jmp_buf setjmp_buffer; }; static void my_error_exit (cinfo) j_common_ptr cinfo; { struct my_jpeg_error_mgr *mgr = (struct my_jpeg_error_mgr *) cinfo->err; longjmp (mgr->setjmp_buffer, 1); } /* Init source method for JPEG data source manager. Called by jpeg_read_header() before any data is actually read. See libjpeg.doc from the JPEG lib distribution. */ static void our_init_source (cinfo) j_decompress_ptr cinfo; { } /* Fill input buffer method for JPEG data source manager. Called whenever more data is needed. We read the whole image in one step, so this only adds a fake end of input marker at the end. */ static boolean our_fill_input_buffer (cinfo) j_decompress_ptr cinfo; { /* Insert a fake EOI marker. */ struct jpeg_source_mgr *src = cinfo->src; static JOCTET buffer[2]; buffer[0] = (JOCTET) 0xFF; buffer[1] = (JOCTET) JPEG_EOI; src->next_input_byte = buffer; src->bytes_in_buffer = 2; return TRUE; } /* Method to skip over NUM_BYTES bytes in the image data. CINFO->src is the JPEG data source manager. */ static void our_skip_input_data (cinfo, num_bytes) j_decompress_ptr cinfo; long num_bytes; { struct jpeg_source_mgr *src = (struct jpeg_source_mgr *) cinfo->src; if (src) { if (num_bytes > src->bytes_in_buffer) ERREXIT (cinfo, JERR_INPUT_EOF); src->bytes_in_buffer -= num_bytes; src->next_input_byte += num_bytes; } } /* Method to terminate data source. Called by jpeg_finish_decompress() after all data has been processed. */ static void our_term_source (cinfo) j_decompress_ptr cinfo; { } /* Set up the JPEG lib for reading an image from DATA which contains LEN bytes. CINFO is the decompression info structure created for reading the image. */ static void jpeg_memory_src (cinfo, data, len) j_decompress_ptr cinfo; JOCTET *data; unsigned int len; { struct jpeg_source_mgr *src; if (cinfo->src == NULL) { /* First time for this JPEG object? */ cinfo->src = (struct jpeg_source_mgr *) (*cinfo->mem->alloc_small) ((j_common_ptr) cinfo, JPOOL_PERMANENT, sizeof (struct jpeg_source_mgr)); src = (struct jpeg_source_mgr *) cinfo->src; src->next_input_byte = data; } src = (struct jpeg_source_mgr *) cinfo->src; src->init_source = our_init_source; src->fill_input_buffer = our_fill_input_buffer; src->skip_input_data = our_skip_input_data; src->resync_to_restart = jpeg_resync_to_restart; /* Use default method. */ src->term_source = our_term_source; src->bytes_in_buffer = len; src->next_input_byte = data; } /* Load image IMG for use on frame F. Patterned after example.c from the JPEG lib. */ static int jpeg_load (f, img) struct frame *f; struct image *img; { struct jpeg_decompress_struct cinfo; struct my_jpeg_error_mgr mgr; Lisp_Object file, specified_file; Lisp_Object specified_data; FILE * volatile fp = NULL; JSAMPARRAY buffer; int row_stride, x, y; XImage *ximg = NULL; int rc; unsigned long *colors; int width, height; struct gcpro gcpro1; /* Open the JPEG file. */ specified_file = image_spec_value (img->spec, QCfile, NULL); specified_data = image_spec_value (img->spec, QCdata, NULL); file = Qnil; GCPRO1 (file); if (NILP (specified_data)) { file = x_find_image_file (specified_file); if (!STRINGP (file)) { image_error ("Cannot find image file `%s'", specified_file, Qnil); UNGCPRO; return 0; } fp = fopen (SDATA (file), "r"); if (fp == NULL) { image_error ("Cannot open `%s'", file, Qnil); UNGCPRO; return 0; } } /* Customize libjpeg's error handling to call my_error_exit when an error is detected. This function will perform a longjmp. */ cinfo.err = jpeg_std_error (&mgr.pub); mgr.pub.error_exit = my_error_exit; if ((rc = setjmp (mgr.setjmp_buffer)) != 0) { if (rc == 1) { /* Called from my_error_exit. Display a JPEG error. */ char buffer[JMSG_LENGTH_MAX]; cinfo.err->format_message ((j_common_ptr) &cinfo, buffer); image_error ("Error reading JPEG image `%s': %s", img->spec, build_string (buffer)); } /* Close the input file and destroy the JPEG object. */ if (fp) fclose ((FILE *) fp); jpeg_destroy_decompress (&cinfo); /* If we already have an XImage, free that. */ x_destroy_x_image (ximg); /* Free pixmap and colors. */ x_clear_image (f, img); UNGCPRO; return 0; } /* Create the JPEG decompression object. Let it read from fp. Read the JPEG image header. */ jpeg_create_decompress (&cinfo); if (NILP (specified_data)) jpeg_stdio_src (&cinfo, (FILE *) fp); else jpeg_memory_src (&cinfo, SDATA (specified_data), SBYTES (specified_data)); jpeg_read_header (&cinfo, TRUE); /* Customize decompression so that color quantization will be used. Start decompression. */ cinfo.quantize_colors = TRUE; jpeg_start_decompress (&cinfo); width = img->width = cinfo.output_width; height = img->height = cinfo.output_height; /* Create X image and pixmap. */ if (!x_create_x_image_and_pixmap (f, width, height, 0, &ximg, &img->pixmap)) longjmp (mgr.setjmp_buffer, 2); /* Allocate colors. When color quantization is used, cinfo.actual_number_of_colors has been set with the number of colors generated, and cinfo.colormap is a two-dimensional array of color indices in the range 0..cinfo.actual_number_of_colors. No more than 255 colors will be generated. */ { int i, ir, ig, ib; if (cinfo.out_color_components > 2) ir = 0, ig = 1, ib = 2; else if (cinfo.out_color_components > 1) ir = 0, ig = 1, ib = 0; else ir = 0, ig = 0, ib = 0; /* Use the color table mechanism because it handles colors that cannot be allocated nicely. Such colors will be replaced with a default color, and we don't have to care about which colors can be freed safely, and which can't. */ init_color_table (); colors = (unsigned long *) alloca (cinfo.actual_number_of_colors * sizeof *colors); for (i = 0; i < cinfo.actual_number_of_colors; ++i) { /* Multiply RGB values with 255 because X expects RGB values in the range 0..0xffff. */ int r = cinfo.colormap[ir][i] << 8; int g = cinfo.colormap[ig][i] << 8; int b = cinfo.colormap[ib][i] << 8; colors[i] = lookup_rgb_color (f, r, g, b); } /* Remember those colors actually allocated. */ img->colors = colors_in_color_table (&img->ncolors); free_color_table (); } /* Read pixels. */ row_stride = width * cinfo.output_components; buffer = cinfo.mem->alloc_sarray ((j_common_ptr) &cinfo, JPOOL_IMAGE, row_stride, 1); for (y = 0; y < height; ++y) { jpeg_read_scanlines (&cinfo, buffer, 1); for (x = 0; x < cinfo.output_width; ++x) XPutPixel (ximg, x, y, colors[buffer[0][x]]); } /* Clean up. */ jpeg_finish_decompress (&cinfo); jpeg_destroy_decompress (&cinfo); if (fp) fclose ((FILE *) fp); /* Maybe fill in the background field while we have ximg handy. */ if (NILP (image_spec_value (img->spec, QCbackground, NULL))) IMAGE_BACKGROUND (img, f, ximg); /* Put the image into the pixmap. */ x_put_x_image (f, ximg, img->pixmap, width, height); x_destroy_x_image (ximg); UNGCPRO; return 1; } #endif /* HAVE_JPEG */ /*********************************************************************** TIFF ***********************************************************************/ #if HAVE_TIFF #include static int tiff_image_p P_ ((Lisp_Object object)); static int tiff_load P_ ((struct frame *f, struct image *img)); /* The symbol `tiff' identifying images of this type. */ Lisp_Object Qtiff; /* Indices of image specification fields in tiff_format, below. */ enum tiff_keyword_index { TIFF_TYPE, TIFF_DATA, TIFF_FILE, TIFF_ASCENT, TIFF_MARGIN, TIFF_RELIEF, TIFF_ALGORITHM, TIFF_HEURISTIC_MASK, TIFF_MASK, TIFF_BACKGROUND, TIFF_LAST }; /* Vector of image_keyword structures describing the format of valid user-defined image specifications. */ static struct image_keyword tiff_format[TIFF_LAST] = { {":type", IMAGE_SYMBOL_VALUE, 1}, {":data", IMAGE_STRING_VALUE, 0}, {":file", IMAGE_STRING_VALUE, 0}, {":ascent", IMAGE_ASCENT_VALUE, 0}, {":margin", IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, 0}, {":relief", IMAGE_INTEGER_VALUE, 0}, {":conversions", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":heuristic-mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":background", IMAGE_STRING_OR_NIL_VALUE, 0} }; /* Structure describing the image type `tiff'. */ static struct image_type tiff_type = { &Qtiff, tiff_image_p, tiff_load, x_clear_image, NULL }; /* Return non-zero if OBJECT is a valid TIFF image specification. */ static int tiff_image_p (object) Lisp_Object object; { struct image_keyword fmt[TIFF_LAST]; bcopy (tiff_format, fmt, sizeof fmt); if (!parse_image_spec (object, fmt, TIFF_LAST, Qtiff)) return 0; /* Must specify either the :data or :file keyword. */ return fmt[TIFF_FILE].count + fmt[TIFF_DATA].count == 1; } /* Reading from a memory buffer for TIFF images Based on the PNG memory source, but we have to provide a lot of extra functions. Blah. We really only need to implement read and seek, but I am not convinced that the TIFF library is smart enough not to destroy itself if we only hand it the function pointers we need to override. */ typedef struct { unsigned char *bytes; size_t len; int index; } tiff_memory_source; static size_t tiff_read_from_memory (data, buf, size) thandle_t data; tdata_t buf; tsize_t size; { tiff_memory_source *src = (tiff_memory_source *) data; if (size > src->len - src->index) return (size_t) -1; bcopy (src->bytes + src->index, buf, size); src->index += size; return size; } static size_t tiff_write_from_memory (data, buf, size) thandle_t data; tdata_t buf; tsize_t size; { return (size_t) -1; } static toff_t tiff_seek_in_memory (data, off, whence) thandle_t data; toff_t off; int whence; { tiff_memory_source *src = (tiff_memory_source *) data; int idx; switch (whence) { case SEEK_SET: /* Go from beginning of source. */ idx = off; break; case SEEK_END: /* Go from end of source. */ idx = src->len + off; break; case SEEK_CUR: /* Go from current position. */ idx = src->index + off; break; default: /* Invalid `whence'. */ return -1; } if (idx > src->len || idx < 0) return -1; src->index = idx; return src->index; } static int tiff_close_memory (data) thandle_t data; { /* NOOP */ return 0; } static int tiff_mmap_memory (data, pbase, psize) thandle_t data; tdata_t *pbase; toff_t *psize; { /* It is already _IN_ memory. */ return 0; } static void tiff_unmap_memory (data, base, size) thandle_t data; tdata_t base; toff_t size; { /* We don't need to do this. */ } static toff_t tiff_size_of_memory (data) thandle_t data; { return ((tiff_memory_source *) data)->len; } static void tiff_error_handler (title, format, ap) const char *title, *format; va_list ap; { char buf[512]; int len; len = sprintf (buf, "TIFF error: %s ", title); vsprintf (buf + len, format, ap); add_to_log (buf, Qnil, Qnil); } static void tiff_warning_handler (title, format, ap) const char *title, *format; va_list ap; { char buf[512]; int len; len = sprintf (buf, "TIFF warning: %s ", title); vsprintf (buf + len, format, ap); add_to_log (buf, Qnil, Qnil); } /* Load TIFF image IMG for use on frame F. Value is non-zero if successful. */ static int tiff_load (f, img) struct frame *f; struct image *img; { Lisp_Object file, specified_file; Lisp_Object specified_data; TIFF *tiff; int width, height, x, y; uint32 *buf; int rc; XImage *ximg; struct gcpro gcpro1; tiff_memory_source memsrc; specified_file = image_spec_value (img->spec, QCfile, NULL); specified_data = image_spec_value (img->spec, QCdata, NULL); file = Qnil; GCPRO1 (file); TIFFSetErrorHandler (tiff_error_handler); TIFFSetWarningHandler (tiff_warning_handler); if (NILP (specified_data)) { /* Read from a file */ file = x_find_image_file (specified_file); if (!STRINGP (file)) { image_error ("Cannot find image file `%s'", file, Qnil); UNGCPRO; return 0; } /* Try to open the image file. */ tiff = TIFFOpen (SDATA (file), "r"); if (tiff == NULL) { image_error ("Cannot open `%s'", file, Qnil); UNGCPRO; return 0; } } else { /* Memory source! */ memsrc.bytes = SDATA (specified_data); memsrc.len = SBYTES (specified_data); memsrc.index = 0; tiff = TIFFClientOpen ("memory_source", "r", &memsrc, (TIFFReadWriteProc) tiff_read_from_memory, (TIFFReadWriteProc) tiff_write_from_memory, tiff_seek_in_memory, tiff_close_memory, tiff_size_of_memory, tiff_mmap_memory, tiff_unmap_memory); if (!tiff) { image_error ("Cannot open memory source for `%s'", img->spec, Qnil); UNGCPRO; return 0; } } /* Get width and height of the image, and allocate a raster buffer of width x height 32-bit values. */ TIFFGetField (tiff, TIFFTAG_IMAGEWIDTH, &width); TIFFGetField (tiff, TIFFTAG_IMAGELENGTH, &height); buf = (uint32 *) xmalloc (width * height * sizeof *buf); rc = TIFFReadRGBAImage (tiff, width, height, buf, 0); TIFFClose (tiff); if (!rc) { image_error ("Error reading TIFF image `%s'", img->spec, Qnil); xfree (buf); UNGCPRO; return 0; } /* Create the X image and pixmap. */ if (!x_create_x_image_and_pixmap (f, width, height, 0, &ximg, &img->pixmap)) { xfree (buf); UNGCPRO; return 0; } /* Initialize the color table. */ init_color_table (); /* Process the pixel raster. Origin is in the lower-left corner. */ for (y = 0; y < height; ++y) { uint32 *row = buf + y * width; for (x = 0; x < width; ++x) { uint32 abgr = row[x]; int r = TIFFGetR (abgr) << 8; int g = TIFFGetG (abgr) << 8; int b = TIFFGetB (abgr) << 8; XPutPixel (ximg, x, height - 1 - y, lookup_rgb_color (f, r, g, b)); } } /* Remember the colors allocated for the image. Free the color table. */ img->colors = colors_in_color_table (&img->ncolors); free_color_table (); img->width = width; img->height = height; /* Maybe fill in the background field while we have ximg handy. */ if (NILP (image_spec_value (img->spec, QCbackground, NULL))) IMAGE_BACKGROUND (img, f, ximg); /* Put the image into the pixmap, then free the X image and its buffer. */ x_put_x_image (f, ximg, img->pixmap, width, height); x_destroy_x_image (ximg); xfree (buf); UNGCPRO; return 1; } #endif /* HAVE_TIFF != 0 */ /*********************************************************************** GIF ***********************************************************************/ #if HAVE_GIF #include static int gif_image_p P_ ((Lisp_Object object)); static int gif_load P_ ((struct frame *f, struct image *img)); /* The symbol `gif' identifying images of this type. */ Lisp_Object Qgif; /* Indices of image specification fields in gif_format, below. */ enum gif_keyword_index { GIF_TYPE, GIF_DATA, GIF_FILE, GIF_ASCENT, GIF_MARGIN, GIF_RELIEF, GIF_ALGORITHM, GIF_HEURISTIC_MASK, GIF_MASK, GIF_IMAGE, GIF_BACKGROUND, GIF_LAST }; /* Vector of image_keyword structures describing the format of valid user-defined image specifications. */ static struct image_keyword gif_format[GIF_LAST] = { {":type", IMAGE_SYMBOL_VALUE, 1}, {":data", IMAGE_STRING_VALUE, 0}, {":file", IMAGE_STRING_VALUE, 0}, {":ascent", IMAGE_ASCENT_VALUE, 0}, {":margin", IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, 0}, {":relief", IMAGE_INTEGER_VALUE, 0}, {":conversion", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":heuristic-mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":image", IMAGE_NON_NEGATIVE_INTEGER_VALUE, 0}, {":background", IMAGE_STRING_OR_NIL_VALUE, 0} }; /* Structure describing the image type `gif'. */ static struct image_type gif_type = { &Qgif, gif_image_p, gif_load, x_clear_image, NULL }; /* Return non-zero if OBJECT is a valid GIF image specification. */ static int gif_image_p (object) Lisp_Object object; { struct image_keyword fmt[GIF_LAST]; bcopy (gif_format, fmt, sizeof fmt); if (!parse_image_spec (object, fmt, GIF_LAST, Qgif)) return 0; /* Must specify either the :data or :file keyword. */ return fmt[GIF_FILE].count + fmt[GIF_DATA].count == 1; } /* Reading a GIF image from memory Based on the PNG memory stuff to a certain extent. */ typedef struct { unsigned char *bytes; size_t len; int index; } gif_memory_source; /* Make the current memory source available to gif_read_from_memory. It's done this way because not all versions of libungif support a UserData field in the GifFileType structure. */ static gif_memory_source *current_gif_memory_src; static int gif_read_from_memory (file, buf, len) GifFileType *file; GifByteType *buf; int len; { gif_memory_source *src = current_gif_memory_src; if (len > src->len - src->index) return -1; bcopy (src->bytes + src->index, buf, len); src->index += len; return len; } /* Load GIF image IMG for use on frame F. Value is non-zero if successful. */ static int gif_load (f, img) struct frame *f; struct image *img; { Lisp_Object file, specified_file; Lisp_Object specified_data; int rc, width, height, x, y, i; XImage *ximg; ColorMapObject *gif_color_map; unsigned long pixel_colors[256]; GifFileType *gif; struct gcpro gcpro1; Lisp_Object image; int ino, image_left, image_top, image_width, image_height; gif_memory_source memsrc; unsigned char *raster; specified_file = image_spec_value (img->spec, QCfile, NULL); specified_data = image_spec_value (img->spec, QCdata, NULL); file = Qnil; GCPRO1 (file); if (NILP (specified_data)) { file = x_find_image_file (specified_file); if (!STRINGP (file)) { image_error ("Cannot find image file `%s'", specified_file, Qnil); UNGCPRO; return 0; } /* Open the GIF file. */ gif = DGifOpenFileName (SDATA (file)); if (gif == NULL) { image_error ("Cannot open `%s'", file, Qnil); UNGCPRO; return 0; } } else { /* Read from memory! */ current_gif_memory_src = &memsrc; memsrc.bytes = SDATA (specified_data); memsrc.len = SBYTES (specified_data); memsrc.index = 0; gif = DGifOpen(&memsrc, gif_read_from_memory); if (!gif) { image_error ("Cannot open memory source `%s'", img->spec, Qnil); UNGCPRO; return 0; } } /* Read entire contents. */ rc = DGifSlurp (gif); if (rc == GIF_ERROR) { image_error ("Error reading `%s'", img->spec, Qnil); DGifCloseFile (gif); UNGCPRO; return 0; } image = image_spec_value (img->spec, QCindex, NULL); ino = INTEGERP (image) ? XFASTINT (image) : 0; if (ino >= gif->ImageCount) { image_error ("Invalid image number `%s' in image `%s'", image, img->spec); DGifCloseFile (gif); UNGCPRO; return 0; } width = img->width = max (gif->SWidth, gif->Image.Left + gif->Image.Width); height = img->height = max (gif->SHeight, gif->Image.Top + gif->Image.Height); /* Create the X image and pixmap. */ if (!x_create_x_image_and_pixmap (f, width, height, 0, &ximg, &img->pixmap)) { DGifCloseFile (gif); UNGCPRO; return 0; } /* Allocate colors. */ gif_color_map = gif->SavedImages[ino].ImageDesc.ColorMap; if (!gif_color_map) gif_color_map = gif->SColorMap; init_color_table (); bzero (pixel_colors, sizeof pixel_colors); for (i = 0; i < gif_color_map->ColorCount; ++i) { int r = gif_color_map->Colors[i].Red << 8; int g = gif_color_map->Colors[i].Green << 8; int b = gif_color_map->Colors[i].Blue << 8; pixel_colors[i] = lookup_rgb_color (f, r, g, b); } img->colors = colors_in_color_table (&img->ncolors); free_color_table (); /* Clear the part of the screen image that are not covered by the image from the GIF file. Full animated GIF support requires more than can be done here (see the gif89 spec, disposal methods). Let's simply assume that the part not covered by a sub-image is in the frame's background color. */ image_top = gif->SavedImages[ino].ImageDesc.Top; image_left = gif->SavedImages[ino].ImageDesc.Left; image_width = gif->SavedImages[ino].ImageDesc.Width; image_height = gif->SavedImages[ino].ImageDesc.Height; for (y = 0; y < image_top; ++y) for (x = 0; x < width; ++x) XPutPixel (ximg, x, y, FRAME_BACKGROUND_PIXEL (f)); for (y = image_top + image_height; y < height; ++y) for (x = 0; x < width; ++x) XPutPixel (ximg, x, y, FRAME_BACKGROUND_PIXEL (f)); for (y = image_top; y < image_top + image_height; ++y) { for (x = 0; x < image_left; ++x) XPutPixel (ximg, x, y, FRAME_BACKGROUND_PIXEL (f)); for (x = image_left + image_width; x < width; ++x) XPutPixel (ximg, x, y, FRAME_BACKGROUND_PIXEL (f)); } /* Read the GIF image into the X image. We use a local variable `raster' here because RasterBits below is a char *, and invites problems with bytes >= 0x80. */ raster = (unsigned char *) gif->SavedImages[ino].RasterBits; if (gif->SavedImages[ino].ImageDesc.Interlace) { static int interlace_start[] = {0, 4, 2, 1}; static int interlace_increment[] = {8, 8, 4, 2}; int pass; int row = interlace_start[0]; pass = 0; for (y = 0; y < image_height; y++) { if (row >= image_height) { row = interlace_start[++pass]; while (row >= image_height) row = interlace_start[++pass]; } for (x = 0; x < image_width; x++) { int i = raster[(y * image_width) + x]; XPutPixel (ximg, x + image_left, row + image_top, pixel_colors[i]); } row += interlace_increment[pass]; } } else { for (y = 0; y < image_height; ++y) for (x = 0; x < image_width; ++x) { int i = raster[y * image_width + x]; XPutPixel (ximg, x + image_left, y + image_top, pixel_colors[i]); } } DGifCloseFile (gif); /* Maybe fill in the background field while we have ximg handy. */ if (NILP (image_spec_value (img->spec, QCbackground, NULL))) IMAGE_BACKGROUND (img, f, ximg); /* Put the image into the pixmap, then free the X image and its buffer. */ x_put_x_image (f, ximg, img->pixmap, width, height); x_destroy_x_image (ximg); UNGCPRO; return 1; } #endif /* HAVE_GIF != 0 */ /*********************************************************************** Ghostscript ***********************************************************************/ static int gs_image_p P_ ((Lisp_Object object)); static int gs_load P_ ((struct frame *f, struct image *img)); static void gs_clear_image P_ ((struct frame *f, struct image *img)); /* The symbol `postscript' identifying images of this type. */ Lisp_Object Qpostscript; /* Keyword symbols. */ Lisp_Object QCloader, QCbounding_box, QCpt_width, QCpt_height; /* Indices of image specification fields in gs_format, below. */ enum gs_keyword_index { GS_TYPE, GS_PT_WIDTH, GS_PT_HEIGHT, GS_FILE, GS_LOADER, GS_BOUNDING_BOX, GS_ASCENT, GS_MARGIN, GS_RELIEF, GS_ALGORITHM, GS_HEURISTIC_MASK, GS_MASK, GS_BACKGROUND, GS_LAST }; /* Vector of image_keyword structures describing the format of valid user-defined image specifications. */ static struct image_keyword gs_format[GS_LAST] = { {":type", IMAGE_SYMBOL_VALUE, 1}, {":pt-width", IMAGE_POSITIVE_INTEGER_VALUE, 1}, {":pt-height", IMAGE_POSITIVE_INTEGER_VALUE, 1}, {":file", IMAGE_STRING_VALUE, 1}, {":loader", IMAGE_FUNCTION_VALUE, 0}, {":bounding-box", IMAGE_DONT_CHECK_VALUE_TYPE, 1}, {":ascent", IMAGE_ASCENT_VALUE, 0}, {":margin", IMAGE_POSITIVE_INTEGER_VALUE_OR_PAIR, 0}, {":relief", IMAGE_INTEGER_VALUE, 0}, {":conversion", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":heuristic-mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":mask", IMAGE_DONT_CHECK_VALUE_TYPE, 0}, {":background", IMAGE_STRING_OR_NIL_VALUE, 0} }; /* Structure describing the image type `ghostscript'. */ static struct image_type gs_type = { &Qpostscript, gs_image_p, gs_load, gs_clear_image, NULL }; /* Free X resources of Ghostscript image IMG which is used on frame F. */ static void gs_clear_image (f, img) struct frame *f; struct image *img; { /* IMG->data.ptr_val may contain a recorded colormap. */ xfree (img->data.ptr_val); x_clear_image (f, img); } /* Return non-zero if OBJECT is a valid Ghostscript image specification. */ static int gs_image_p (object) Lisp_Object object; { struct image_keyword fmt[GS_LAST]; Lisp_Object tem; int i; bcopy (gs_format, fmt, sizeof fmt); if (!parse_image_spec (object, fmt, GS_LAST, Qpostscript)) return 0; /* Bounding box must be a list or vector containing 4 integers. */ tem = fmt[GS_BOUNDING_BOX].value; if (CONSP (tem)) { for (i = 0; i < 4; ++i, tem = XCDR (tem)) if (!CONSP (tem) || !INTEGERP (XCAR (tem))) return 0; if (!NILP (tem)) return 0; } else if (VECTORP (tem)) { if (XVECTOR (tem)->size != 4) return 0; for (i = 0; i < 4; ++i) if (!INTEGERP (XVECTOR (tem)->contents[i])) return 0; } else return 0; return 1; } /* Load Ghostscript image IMG for use on frame F. Value is non-zero if successful. */ static int gs_load (f, img) struct frame *f; struct image *img; { char buffer[100]; Lisp_Object window_and_pixmap_id = Qnil, loader, pt_height, pt_width; struct gcpro gcpro1, gcpro2; Lisp_Object frame; double in_width, in_height; Lisp_Object pixel_colors = Qnil; /* Compute pixel size of pixmap needed from the given size in the image specification. Sizes in the specification are in pt. 1 pt = 1/72 in, xdpi and ydpi are stored in the frame's X display info. */ pt_width = image_spec_value (img->spec, QCpt_width, NULL); in_width = XFASTINT (pt_width) / 72.0; img->width = in_width * FRAME_X_DISPLAY_INFO (f)->resx; pt_height = image_spec_value (img->spec, QCpt_height, NULL); in_height = XFASTINT (pt_height) / 72.0; img->height = in_height * FRAME_X_DISPLAY_INFO (f)->resy; /* Create the pixmap. */ xassert (img->pixmap == None); img->pixmap = XCreatePixmap (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), img->width, img->height, DefaultDepthOfScreen (FRAME_X_SCREEN (f))); if (!img->pixmap) { image_error ("Unable to create pixmap for `%s'", img->spec, Qnil); return 0; } /* Call the loader to fill the pixmap. It returns a process object if successful. We do not record_unwind_protect here because other places in redisplay like calling window scroll functions don't either. Let the Lisp loader use `unwind-protect' instead. */ GCPRO2 (window_and_pixmap_id, pixel_colors); sprintf (buffer, "%lu %lu", (unsigned long) FRAME_X_WINDOW (f), (unsigned long) img->pixmap); window_and_pixmap_id = build_string (buffer); sprintf (buffer, "%lu %lu", FRAME_FOREGROUND_PIXEL (f), FRAME_BACKGROUND_PIXEL (f)); pixel_colors = build_string (buffer); XSETFRAME (frame, f); loader = image_spec_value (img->spec, QCloader, NULL); if (NILP (loader)) loader = intern ("gs-load-image"); img->data.lisp_val = call6 (loader, frame, img->spec, make_number (img->width), make_number (img->height), window_and_pixmap_id, pixel_colors); UNGCPRO; return PROCESSP (img->data.lisp_val); } /* Kill the Ghostscript process that was started to fill PIXMAP on frame F. Called from XTread_socket when receiving an event telling Emacs that Ghostscript has finished drawing. */ void x_kill_gs_process (pixmap, f) Pixmap pixmap; struct frame *f; { struct image_cache *c = FRAME_X_IMAGE_CACHE (f); int class, i; struct image *img; /* Find the image containing PIXMAP. */ for (i = 0; i < c->used; ++i) if (c->images[i]->pixmap == pixmap) break; /* Should someone in between have cleared the image cache, for instance, give up. */ if (i == c->used) return; /* Kill the GS process. We should have found PIXMAP in the image cache and its image should contain a process object. */ img = c->images[i]; xassert (PROCESSP (img->data.lisp_val)); Fkill_process (img->data.lisp_val, Qnil); img->data.lisp_val = Qnil; /* On displays with a mutable colormap, figure out the colors allocated for the image by looking at the pixels of an XImage for img->pixmap. */ class = FRAME_X_VISUAL (f)->class; if (class != StaticColor && class != StaticGray && class != TrueColor) { XImage *ximg; BLOCK_INPUT; /* Try to get an XImage for img->pixmep. */ ximg = XGetImage (FRAME_X_DISPLAY (f), img->pixmap, 0, 0, img->width, img->height, ~0, ZPixmap); if (ximg) { int x, y; /* Initialize the color table. */ init_color_table (); /* For each pixel of the image, look its color up in the color table. After having done so, the color table will contain an entry for each color used by the image. */ for (y = 0; y < img->height; ++y) for (x = 0; x < img->width; ++x) { unsigned long pixel = XGetPixel (ximg, x, y); lookup_pixel_color (f, pixel); } /* Record colors in the image. Free color table and XImage. */ img->colors = colors_in_color_table (&img->ncolors); free_color_table (); XDestroyImage (ximg); #if 0 /* This doesn't seem to be the case. If we free the colors here, we get a BadAccess later in x_clear_image when freeing the colors. */ /* We have allocated colors once, but Ghostscript has also allocated colors on behalf of us. So, to get the reference counts right, free them once. */ if (img->ncolors) x_free_colors (f, img->colors, img->ncolors); #endif } else image_error ("Cannot get X image of `%s'; colors will not be freed", img->spec, Qnil); UNBLOCK_INPUT; } /* Now that we have the pixmap, compute mask and transform the image if requested. */ BLOCK_INPUT; postprocess_image (f, img); UNBLOCK_INPUT; } /*********************************************************************** Window properties ***********************************************************************/ DEFUN ("x-change-window-property", Fx_change_window_property, Sx_change_window_property, 2, 3, 0, doc: /* Change window property PROP to VALUE on the X window of FRAME. PROP and VALUE must be strings. FRAME nil or omitted means use the selected frame. Value is VALUE. */) (prop, value, frame) Lisp_Object frame, prop, value; { struct frame *f = check_x_frame (frame); Atom prop_atom; CHECK_STRING (prop); CHECK_STRING (value); BLOCK_INPUT; prop_atom = XInternAtom (FRAME_X_DISPLAY (f), SDATA (prop), False); XChangeProperty (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), prop_atom, XA_STRING, 8, PropModeReplace, SDATA (value), SCHARS (value)); /* Make sure the property is set when we return. */ XFlush (FRAME_X_DISPLAY (f)); UNBLOCK_INPUT; return value; } DEFUN ("x-delete-window-property", Fx_delete_window_property, Sx_delete_window_property, 1, 2, 0, doc: /* Remove window property PROP from X window of FRAME. FRAME nil or omitted means use the selected frame. Value is PROP. */) (prop, frame) Lisp_Object prop, frame; { struct frame *f = check_x_frame (frame); Atom prop_atom; CHECK_STRING (prop); BLOCK_INPUT; prop_atom = XInternAtom (FRAME_X_DISPLAY (f), SDATA (prop), False); XDeleteProperty (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), prop_atom); /* Make sure the property is removed when we return. */ XFlush (FRAME_X_DISPLAY (f)); UNBLOCK_INPUT; return prop; } DEFUN ("x-window-property", Fx_window_property, Sx_window_property, 1, 2, 0, doc: /* Value is the value of window property PROP on FRAME. If FRAME is nil or omitted, use the selected frame. Value is nil if FRAME hasn't a property with name PROP or if PROP has no string value. */) (prop, frame) Lisp_Object prop, frame; { struct frame *f = check_x_frame (frame); Atom prop_atom; int rc; Lisp_Object prop_value = Qnil; char *tmp_data = NULL; Atom actual_type; int actual_format; unsigned long actual_size, bytes_remaining; CHECK_STRING (prop); BLOCK_INPUT; prop_atom = XInternAtom (FRAME_X_DISPLAY (f), SDATA (prop), False); rc = XGetWindowProperty (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), prop_atom, 0, 0, False, XA_STRING, &actual_type, &actual_format, &actual_size, &bytes_remaining, (unsigned char **) &tmp_data); if (rc == Success) { int size = bytes_remaining; XFree (tmp_data); tmp_data = NULL; rc = XGetWindowProperty (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), prop_atom, 0, bytes_remaining, False, XA_STRING, &actual_type, &actual_format, &actual_size, &bytes_remaining, (unsigned char **) &tmp_data); if (rc == Success && tmp_data) prop_value = make_string (tmp_data, size); XFree (tmp_data); } UNBLOCK_INPUT; return prop_value; } /*********************************************************************** Busy cursor ***********************************************************************/ /* If non-null, an asynchronous timer that, when it expires, displays an hourglass cursor on all frames. */ static struct atimer *hourglass_atimer; /* Non-zero means an hourglass cursor is currently shown. */ static int hourglass_shown_p; /* Number of seconds to wait before displaying an hourglass cursor. */ static Lisp_Object Vhourglass_delay; /* Default number of seconds to wait before displaying an hourglass cursor. */ #define DEFAULT_HOURGLASS_DELAY 1 /* Function prototypes. */ static void show_hourglass P_ ((struct atimer *)); static void hide_hourglass P_ ((void)); /* Cancel a currently active hourglass timer, and start a new one. */ void start_hourglass () { EMACS_TIME delay; int secs, usecs = 0; cancel_hourglass (); if (INTEGERP (Vhourglass_delay) && XINT (Vhourglass_delay) > 0) secs = XFASTINT (Vhourglass_delay); else if (FLOATP (Vhourglass_delay) && XFLOAT_DATA (Vhourglass_delay) > 0) { Lisp_Object tem; tem = Ftruncate (Vhourglass_delay, Qnil); secs = XFASTINT (tem); usecs = (XFLOAT_DATA (Vhourglass_delay) - secs) * 1000000; } else secs = DEFAULT_HOURGLASS_DELAY; EMACS_SET_SECS_USECS (delay, secs, usecs); hourglass_atimer = start_atimer (ATIMER_RELATIVE, delay, show_hourglass, NULL); } /* Cancel the hourglass cursor timer if active, hide a busy cursor if shown. */ void cancel_hourglass () { if (hourglass_atimer) { cancel_atimer (hourglass_atimer); hourglass_atimer = NULL; } if (hourglass_shown_p) hide_hourglass (); } /* Timer function of hourglass_atimer. TIMER is equal to hourglass_atimer. Display an hourglass pointer on all frames by mapping the frames' hourglass_window. Set the hourglass_p flag in the frames' output_data.x structure to indicate that an hourglass cursor is shown on the frames. */ static void show_hourglass (timer) struct atimer *timer; { /* The timer implementation will cancel this timer automatically after this function has run. Set hourglass_atimer to null so that we know the timer doesn't have to be canceled. */ hourglass_atimer = NULL; if (!hourglass_shown_p) { Lisp_Object rest, frame; BLOCK_INPUT; FOR_EACH_FRAME (rest, frame) { struct frame *f = XFRAME (frame); if (FRAME_LIVE_P (f) && FRAME_X_P (f) && FRAME_X_DISPLAY (f)) { Display *dpy = FRAME_X_DISPLAY (f); #ifdef USE_X_TOOLKIT if (f->output_data.x->widget) #else if (FRAME_OUTER_WINDOW (f)) #endif { f->output_data.x->hourglass_p = 1; if (!f->output_data.x->hourglass_window) { unsigned long mask = CWCursor; XSetWindowAttributes attrs; attrs.cursor = f->output_data.x->hourglass_cursor; f->output_data.x->hourglass_window = XCreateWindow (dpy, FRAME_OUTER_WINDOW (f), 0, 0, 32000, 32000, 0, 0, InputOnly, CopyFromParent, mask, &attrs); } XMapRaised (dpy, f->output_data.x->hourglass_window); XFlush (dpy); } } } hourglass_shown_p = 1; UNBLOCK_INPUT; } } /* Hide the hourglass pointer on all frames, if it is currently shown. */ static void hide_hourglass () { if (hourglass_shown_p) { Lisp_Object rest, frame; BLOCK_INPUT; FOR_EACH_FRAME (rest, frame) { struct frame *f = XFRAME (frame); if (FRAME_X_P (f) /* Watch out for newly created frames. */ && f->output_data.x->hourglass_window) { XUnmapWindow (FRAME_X_DISPLAY (f), f->output_data.x->hourglass_window); /* Sync here because XTread_socket looks at the hourglass_p flag that is reset to zero below. */ XSync (FRAME_X_DISPLAY (f), False); f->output_data.x->hourglass_p = 0; } } hourglass_shown_p = 0; UNBLOCK_INPUT; } } /*********************************************************************** Tool tips ***********************************************************************/ static Lisp_Object x_create_tip_frame P_ ((struct x_display_info *, Lisp_Object, Lisp_Object)); static void compute_tip_xy P_ ((struct frame *, Lisp_Object, Lisp_Object, Lisp_Object, int, int, int *, int *)); /* The frame of a currently visible tooltip. */ Lisp_Object tip_frame; /* If non-nil, a timer started that hides the last tooltip when it fires. */ Lisp_Object tip_timer; Window tip_window; /* If non-nil, a vector of 3 elements containing the last args with which x-show-tip was called. See there. */ Lisp_Object last_show_tip_args; /* Maximum size for tooltips; a cons (COLUMNS . ROWS). */ Lisp_Object Vx_max_tooltip_size; static Lisp_Object unwind_create_tip_frame (frame) Lisp_Object frame; { Lisp_Object deleted; deleted = unwind_create_frame (frame); if (EQ (deleted, Qt)) { tip_window = None; tip_frame = Qnil; } return deleted; } /* Create a frame for a tooltip on the display described by DPYINFO. PARMS is a list of frame parameters. TEXT is the string to display in the tip frame. Value is the frame. Note that functions called here, esp. x_default_parameter can signal errors, for instance when a specified color name is undefined. We have to make sure that we're in a consistent state when this happens. */ static Lisp_Object x_create_tip_frame (dpyinfo, parms, text) struct x_display_info *dpyinfo; Lisp_Object parms, text; { struct frame *f; Lisp_Object frame, tem; Lisp_Object name; long window_prompting = 0; int width, height; int count = SPECPDL_INDEX (); struct gcpro gcpro1, gcpro2, gcpro3; struct kboard *kb; int face_change_count_before = face_change_count; Lisp_Object buffer; struct buffer *old_buffer; check_x (); /* Use this general default value to start with until we know if this frame has a specified name. */ Vx_resource_name = Vinvocation_name; #ifdef MULTI_KBOARD kb = dpyinfo->kboard; #else kb = &the_only_kboard; #endif /* Get the name of the frame to use for resource lookup. */ name = x_get_arg (dpyinfo, parms, Qname, "name", "Name", RES_TYPE_STRING); if (!STRINGP (name) && !EQ (name, Qunbound) && !NILP (name)) error ("Invalid frame name--not a string or nil"); Vx_resource_name = name; frame = Qnil; GCPRO3 (parms, name, frame); f = make_frame (1); XSETFRAME (frame, f); buffer = Fget_buffer_create (build_string (" *tip*")); Fset_window_buffer (FRAME_ROOT_WINDOW (f), buffer, Qnil); old_buffer = current_buffer; set_buffer_internal_1 (XBUFFER (buffer)); current_buffer->truncate_lines = Qnil; Ferase_buffer (); Finsert (1, &text); set_buffer_internal_1 (old_buffer); FRAME_CAN_HAVE_SCROLL_BARS (f) = 0; record_unwind_protect (unwind_create_tip_frame, frame); /* By setting the output method, we're essentially saying that the frame is live, as per FRAME_LIVE_P. If we get a signal from this point on, x_destroy_window might screw up reference counts etc. */ f->output_method = output_x_window; f->output_data.x = (struct x_output *) xmalloc (sizeof (struct x_output)); bzero (f->output_data.x, sizeof (struct x_output)); f->output_data.x->icon_bitmap = -1; FRAME_FONTSET (f) = -1; f->output_data.x->scroll_bar_foreground_pixel = -1; f->output_data.x->scroll_bar_background_pixel = -1; #ifdef USE_TOOLKIT_SCROLL_BARS f->output_data.x->scroll_bar_top_shadow_pixel = -1; f->output_data.x->scroll_bar_bottom_shadow_pixel = -1; #endif /* USE_TOOLKIT_SCROLL_BARS */ f->icon_name = Qnil; FRAME_X_DISPLAY_INFO (f) = dpyinfo; #if GLYPH_DEBUG image_cache_refcount = FRAME_X_IMAGE_CACHE (f)->refcount; dpyinfo_refcount = dpyinfo->reference_count; #endif /* GLYPH_DEBUG */ #ifdef MULTI_KBOARD FRAME_KBOARD (f) = kb; #endif f->output_data.x->parent_desc = FRAME_X_DISPLAY_INFO (f)->root_window; f->output_data.x->explicit_parent = 0; /* These colors will be set anyway later, but it's important to get the color reference counts right, so initialize them! */ { Lisp_Object black; struct gcpro gcpro1; black = build_string ("black"); GCPRO1 (black); f->output_data.x->foreground_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->background_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->cursor_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->cursor_foreground_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->border_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); f->output_data.x->mouse_pixel = x_decode_color (f, black, BLACK_PIX_DEFAULT (f)); UNGCPRO; } /* Set the name; the functions to which we pass f expect the name to be set. */ if (EQ (name, Qunbound) || NILP (name)) { f->name = build_string (dpyinfo->x_id_name); f->explicit_name = 0; } else { f->name = name; f->explicit_name = 1; /* use the frame's title when getting resources for this frame. */ specbind (Qx_resource_name, name); } /* Extract the window parameters from the supplied values that are needed to determine window geometry. */ { Lisp_Object font; font = x_get_arg (dpyinfo, parms, Qfont, "font", "Font", RES_TYPE_STRING); BLOCK_INPUT; /* First, try whatever font the caller has specified. */ if (STRINGP (font)) { tem = Fquery_fontset (font, Qnil); if (STRINGP (tem)) font = x_new_fontset (f, SDATA (tem)); else font = x_new_font (f, SDATA (font)); } /* Try out a font which we hope has bold and italic variations. */ if (!STRINGP (font)) font = x_new_font (f, "-adobe-courier-medium-r-*-*-*-120-*-*-*-*-iso8859-1"); if (!STRINGP (font)) font = x_new_font (f, "-misc-fixed-medium-r-normal-*-*-140-*-*-c-*-iso8859-1"); if (! STRINGP (font)) font = x_new_font (f, "-*-*-medium-r-normal-*-*-140-*-*-c-*-iso8859-1"); if (! STRINGP (font)) /* This was formerly the first thing tried, but it finds too many fonts and takes too long. */ font = x_new_font (f, "-*-*-medium-r-*-*-*-*-*-*-c-*-iso8859-1"); /* If those didn't work, look for something which will at least work. */ if (! STRINGP (font)) font = x_new_font (f, "-*-fixed-*-*-*-*-*-140-*-*-c-*-iso8859-1"); UNBLOCK_INPUT; if (! STRINGP (font)) font = build_string ("fixed"); x_default_parameter (f, parms, Qfont, font, "font", "Font", RES_TYPE_STRING); } x_default_parameter (f, parms, Qborder_width, make_number (2), "borderWidth", "BorderWidth", RES_TYPE_NUMBER); /* This defaults to 2 in order to match xterm. We recognize either internalBorderWidth or internalBorder (which is what xterm calls it). */ if (NILP (Fassq (Qinternal_border_width, parms))) { Lisp_Object value; value = x_get_arg (dpyinfo, parms, Qinternal_border_width, "internalBorder", "internalBorder", RES_TYPE_NUMBER); if (! EQ (value, Qunbound)) parms = Fcons (Fcons (Qinternal_border_width, value), parms); } x_default_parameter (f, parms, Qinternal_border_width, make_number (1), "internalBorderWidth", "internalBorderWidth", RES_TYPE_NUMBER); /* Also do the stuff which must be set before the window exists. */ x_default_parameter (f, parms, Qforeground_color, build_string ("black"), "foreground", "Foreground", RES_TYPE_STRING); x_default_parameter (f, parms, Qbackground_color, build_string ("white"), "background", "Background", RES_TYPE_STRING); x_default_parameter (f, parms, Qmouse_color, build_string ("black"), "pointerColor", "Foreground", RES_TYPE_STRING); x_default_parameter (f, parms, Qcursor_color, build_string ("black"), "cursorColor", "Foreground", RES_TYPE_STRING); x_default_parameter (f, parms, Qborder_color, build_string ("black"), "borderColor", "BorderColor", RES_TYPE_STRING); /* Init faces before x_default_parameter is called for scroll-bar parameters because that function calls x_set_scroll_bar_width, which calls change_frame_size, which calls Fset_window_buffer, which runs hooks, which call Fvertical_motion. At the end, we end up in init_iterator with a null face cache, which should not happen. */ init_frame_faces (f); f->output_data.x->parent_desc = FRAME_X_DISPLAY_INFO (f)->root_window; window_prompting = x_figure_window_size (f, parms, 0); { XSetWindowAttributes attrs; unsigned long mask; BLOCK_INPUT; mask = CWBackPixel | CWOverrideRedirect | CWEventMask; if (DoesSaveUnders (dpyinfo->screen)) mask |= CWSaveUnder; /* Window managers look at the override-redirect flag to determine whether or net to give windows a decoration (Xlib spec, chapter 3.2.8). */ attrs.override_redirect = True; attrs.save_under = True; attrs.background_pixel = FRAME_BACKGROUND_PIXEL (f); /* Arrange for getting MapNotify and UnmapNotify events. */ attrs.event_mask = StructureNotifyMask; tip_window = FRAME_X_WINDOW (f) = XCreateWindow (FRAME_X_DISPLAY (f), FRAME_X_DISPLAY_INFO (f)->root_window, /* x, y, width, height */ 0, 0, 1, 1, /* Border. */ 1, CopyFromParent, InputOutput, CopyFromParent, mask, &attrs); UNBLOCK_INPUT; } x_make_gc (f); x_default_parameter (f, parms, Qauto_raise, Qnil, "autoRaise", "AutoRaiseLower", RES_TYPE_BOOLEAN); x_default_parameter (f, parms, Qauto_lower, Qnil, "autoLower", "AutoRaiseLower", RES_TYPE_BOOLEAN); x_default_parameter (f, parms, Qcursor_type, Qbox, "cursorType", "CursorType", RES_TYPE_SYMBOL); /* Dimensions, especially FRAME_LINES (f), must be done via change_frame_size. Change will not be effected unless different from the current FRAME_LINES (f). */ width = FRAME_COLS (f); height = FRAME_LINES (f); SET_FRAME_COLS (f, 0); FRAME_LINES (f) = 0; change_frame_size (f, height, width, 1, 0, 0); /* Add `tooltip' frame parameter's default value. */ if (NILP (Fframe_parameter (frame, intern ("tooltip")))) Fmodify_frame_parameters (frame, Fcons (Fcons (intern ("tooltip"), Qt), Qnil)); /* Set up faces after all frame parameters are known. This call also merges in face attributes specified for new frames. Frame parameters may be changed if .Xdefaults contains specifications for the default font. For example, if there is an `Emacs.default.attributeBackground: pink', the `background-color' attribute of the frame get's set, which let's the internal border of the tooltip frame appear in pink. Prevent this. */ { Lisp_Object bg = Fframe_parameter (frame, Qbackground_color); /* Set tip_frame here, so that */ tip_frame = frame; call1 (Qface_set_after_frame_default, frame); if (!EQ (bg, Fframe_parameter (frame, Qbackground_color))) Fmodify_frame_parameters (frame, Fcons (Fcons (Qbackground_color, bg), Qnil)); } f->no_split = 1; UNGCPRO; /* It is now ok to make the frame official even if we get an error below. And the frame needs to be on Vframe_list or making it visible won't work. */ Vframe_list = Fcons (frame, Vframe_list); /* Now that the frame is official, it counts as a reference to its display. */ FRAME_X_DISPLAY_INFO (f)->reference_count++; /* Setting attributes of faces of the tooltip frame from resources and similar will increment face_change_count, which leads to the clearing of all current matrices. Since this isn't necessary here, avoid it by resetting face_change_count to the value it had before we created the tip frame. */ face_change_count = face_change_count_before; /* Discard the unwind_protect. */ return unbind_to (count, frame); } /* Compute where to display tip frame F. PARMS is the list of frame parameters for F. DX and DY are specified offsets from the current location of the mouse. WIDTH and HEIGHT are the width and height of the tooltip. Return coordinates relative to the root window of the display in *ROOT_X, and *ROOT_Y. */ static void compute_tip_xy (f, parms, dx, dy, width, height, root_x, root_y) struct frame *f; Lisp_Object parms, dx, dy; int width, height; int *root_x, *root_y; { Lisp_Object left, top; int win_x, win_y; Window root, child; unsigned pmask; /* User-specified position? */ left = Fcdr (Fassq (Qleft, parms)); top = Fcdr (Fassq (Qtop, parms)); /* Move the tooltip window where the mouse pointer is. Resize and show it. */ if (!INTEGERP (left) || !INTEGERP (top)) { BLOCK_INPUT; XQueryPointer (FRAME_X_DISPLAY (f), FRAME_X_DISPLAY_INFO (f)->root_window, &root, &child, root_x, root_y, &win_x, &win_y, &pmask); UNBLOCK_INPUT; } if (INTEGERP (top)) *root_y = XINT (top); else if (*root_y + XINT (dy) - height < 0) *root_y -= XINT (dy); else { *root_y -= height; *root_y += XINT (dy); } if (INTEGERP (left)) *root_x = XINT (left); else if (*root_x + XINT (dx) + width <= FRAME_X_DISPLAY_INFO (f)->width) /* It fits to the right of the pointer. */ *root_x += XINT (dx); else if (width + XINT (dx) <= *root_x) /* It fits to the left of the pointer. */ *root_x -= width + XINT (dx); else /* Put it left-justified on the screen--it ought to fit that way. */ *root_x = 0; } DEFUN ("x-show-tip", Fx_show_tip, Sx_show_tip, 1, 6, 0, doc: /* Show STRING in a "tooltip" window on frame FRAME. A tooltip window is a small X window displaying a string. FRAME nil or omitted means use the selected frame. PARMS is an optional list of frame parameters which can be used to change the tooltip's appearance. Automatically hide the tooltip after TIMEOUT seconds. TIMEOUT nil means use the default timeout of 5 seconds. If the list of frame parameters PARAMS contains a `left' parameters, the tooltip is displayed at that x-position. Otherwise it is displayed at the mouse position, with offset DX added (default is 5 if DX isn't specified). Likewise for the y-position; if a `top' frame parameter is specified, it determines the y-position of the tooltip window, otherwise it is displayed at the mouse position, with offset DY added (default is -10). A tooltip's maximum size is specified by `x-max-tooltip-size'. Text larger than the specified size is clipped. */) (string, frame, parms, timeout, dx, dy) Lisp_Object string, frame, parms, timeout, dx, dy; { struct frame *f; struct window *w; int root_x, root_y; struct buffer *old_buffer; struct text_pos pos; int i, width, height; struct gcpro gcpro1, gcpro2, gcpro3, gcpro4; int old_windows_or_buffers_changed = windows_or_buffers_changed; int count = SPECPDL_INDEX (); specbind (Qinhibit_redisplay, Qt); GCPRO4 (string, parms, frame, timeout); CHECK_STRING (string); f = check_x_frame (frame); if (NILP (timeout)) timeout = make_number (5); else CHECK_NATNUM (timeout); if (NILP (dx)) dx = make_number (5); else CHECK_NUMBER (dx); if (NILP (dy)) dy = make_number (-10); else CHECK_NUMBER (dy); if (NILP (last_show_tip_args)) last_show_tip_args = Fmake_vector (make_number (3), Qnil); if (!NILP (tip_frame)) { Lisp_Object last_string = AREF (last_show_tip_args, 0); Lisp_Object last_frame = AREF (last_show_tip_args, 1); Lisp_Object last_parms = AREF (last_show_tip_args, 2); if (EQ (frame, last_frame) && !NILP (Fequal (last_string, string)) && !NILP (Fequal (last_parms, parms))) { struct frame *f = XFRAME (tip_frame); /* Only DX and DY have changed. */ if (!NILP (tip_timer)) { Lisp_Object timer = tip_timer; tip_timer = Qnil; call1 (Qcancel_timer, timer); } BLOCK_INPUT; compute_tip_xy (f, parms, dx, dy, FRAME_PIXEL_WIDTH (f), FRAME_PIXEL_HEIGHT (f), &root_x, &root_y); XMoveWindow (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), root_x, root_y); UNBLOCK_INPUT; goto start_timer; } } /* Hide a previous tip, if any. */ Fx_hide_tip (); ASET (last_show_tip_args, 0, string); ASET (last_show_tip_args, 1, frame); ASET (last_show_tip_args, 2, parms); /* Add default values to frame parameters. */ if (NILP (Fassq (Qname, parms))) parms = Fcons (Fcons (Qname, build_string ("tooltip")), parms); if (NILP (Fassq (Qinternal_border_width, parms))) parms = Fcons (Fcons (Qinternal_border_width, make_number (3)), parms); if (NILP (Fassq (Qborder_width, parms))) parms = Fcons (Fcons (Qborder_width, make_number (1)), parms); if (NILP (Fassq (Qborder_color, parms))) parms = Fcons (Fcons (Qborder_color, build_string ("lightyellow")), parms); if (NILP (Fassq (Qbackground_color, parms))) parms = Fcons (Fcons (Qbackground_color, build_string ("lightyellow")), parms); /* Create a frame for the tooltip, and record it in the global variable tip_frame. */ frame = x_create_tip_frame (FRAME_X_DISPLAY_INFO (f), parms, string); f = XFRAME (frame); /* Set up the frame's root window. */ w = XWINDOW (FRAME_ROOT_WINDOW (f)); w->left_col = w->top_line = make_number (0); if (CONSP (Vx_max_tooltip_size) && INTEGERP (XCAR (Vx_max_tooltip_size)) && XINT (XCAR (Vx_max_tooltip_size)) > 0 && INTEGERP (XCDR (Vx_max_tooltip_size)) && XINT (XCDR (Vx_max_tooltip_size)) > 0) { w->total_cols = XCAR (Vx_max_tooltip_size); w->total_lines = XCDR (Vx_max_tooltip_size); } else { w->total_cols = make_number (80); w->total_lines = make_number (40); } FRAME_TOTAL_COLS (f) = XINT (w->total_cols); adjust_glyphs (f); w->pseudo_window_p = 1; /* Display the tooltip text in a temporary buffer. */ old_buffer = current_buffer; set_buffer_internal_1 (XBUFFER (XWINDOW (FRAME_ROOT_WINDOW (f))->buffer)); current_buffer->truncate_lines = Qnil; clear_glyph_matrix (w->desired_matrix); clear_glyph_matrix (w->current_matrix); SET_TEXT_POS (pos, BEGV, BEGV_BYTE); try_window (FRAME_ROOT_WINDOW (f), pos); /* Compute width and height of the tooltip. */ width = height = 0; for (i = 0; i < w->desired_matrix->nrows; ++i) { struct glyph_row *row = &w->desired_matrix->rows[i]; struct glyph *last; int row_width; /* Stop at the first empty row at the end. */ if (!row->enabled_p || !row->displays_text_p) break; /* Let the row go over the full width of the frame. */ row->full_width_p = 1; /* There's a glyph at the end of rows that is used to place the cursor there. Don't include the width of this glyph. */ if (row->used[TEXT_AREA]) { last = &row->glyphs[TEXT_AREA][row->used[TEXT_AREA] - 1]; row_width = row->pixel_width - last->pixel_width; } else row_width = row->pixel_width; height += row->height; width = max (width, row_width); } /* Add the frame's internal border to the width and height the X window should have. */ height += 2 * FRAME_INTERNAL_BORDER_WIDTH (f); width += 2 * FRAME_INTERNAL_BORDER_WIDTH (f); /* Move the tooltip window where the mouse pointer is. Resize and show it. */ compute_tip_xy (f, parms, dx, dy, width, height, &root_x, &root_y); BLOCK_INPUT; XMoveResizeWindow (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f), root_x, root_y, width, height); XMapRaised (FRAME_X_DISPLAY (f), FRAME_X_WINDOW (f)); UNBLOCK_INPUT; /* Draw into the window. */ w->must_be_updated_p = 1; update_single_window (w, 1); /* Restore original current buffer. */ set_buffer_internal_1 (old_buffer); windows_or_buffers_changed = old_windows_or_buffers_changed; start_timer: /* Let the tip disappear after timeout seconds. */ tip_timer = call3 (intern ("run-at-time"), timeout, Qnil, intern ("x-hide-tip")); UNGCPRO; return unbind_to (count, Qnil); } DEFUN ("x-hide-tip", Fx_hide_tip, Sx_hide_tip, 0, 0, 0, doc: /* Hide the current tooltip window, if there is any. Value is t if tooltip was open, nil otherwise. */) () { int count; Lisp_Object deleted, frame, timer; struct gcpro gcpro1, gcpro2; /* Return quickly if nothing to do. */ if (NILP (tip_timer) && NILP (tip_frame)) return Qnil; frame = tip_frame; timer = tip_timer; GCPRO2 (frame, timer); tip_frame = tip_timer = deleted = Qnil; count = SPECPDL_INDEX (); specbind (Qinhibit_redisplay, Qt); specbind (Qinhibit_quit, Qt); if (!NILP (timer)) call1 (Qcancel_timer, timer); if (FRAMEP (frame)) { Fdelete_frame (frame, Qnil); deleted = Qt; #ifdef USE_LUCID /* Bloodcurdling hack alert: The Lucid menu bar widget's redisplay procedure is not called when a tip frame over menu items is unmapped. Redisplay the menu manually... */ { struct frame *f = SELECTED_FRAME (); Widget w = f->output_data.x->menubar_widget; extern void xlwmenu_redisplay P_ ((Widget)); if (!DoesSaveUnders (FRAME_X_DISPLAY_INFO (f)->screen) && w != NULL) { BLOCK_INPUT; xlwmenu_redisplay (w); UNBLOCK_INPUT; } } #endif /* USE_LUCID */ } UNGCPRO; return unbind_to (count, deleted); } /*********************************************************************** File selection dialog ***********************************************************************/ #ifdef USE_MOTIF /* Callback for "OK" and "Cancel" on file selection dialog. */ static void file_dialog_cb (widget, client_data, call_data) Widget widget; XtPointer call_data, client_data; { int *result = (int *) client_data; XmAnyCallbackStruct *cb = (XmAnyCallbackStruct *) call_data; *result = cb->reason; } /* Callback for unmapping a file selection dialog. This is used to capture the case where a dialog is closed via a window manager's closer button, for example. Using a XmNdestroyCallback didn't work in this case. */ static void file_dialog_unmap_cb (widget, client_data, call_data) Widget widget; XtPointer call_data, client_data; { int *result = (int *) client_data; *result = XmCR_CANCEL; } DEFUN ("x-file-dialog", Fx_file_dialog, Sx_file_dialog, 2, 4, 0, doc: /* Read file name, prompting with PROMPT in directory DIR. Use a file selection dialog. Select DEFAULT-FILENAME in the dialog's file selection box, if specified. Don't let the user enter a file name in the file selection dialog's entry field, if MUSTMATCH is non-nil. */) (prompt, dir, default_filename, mustmatch) Lisp_Object prompt, dir, default_filename, mustmatch; { int result; struct frame *f = SELECTED_FRAME (); Lisp_Object file = Qnil; Widget dialog, text, list, help; Arg al[10]; int ac = 0; extern XtAppContext Xt_app_con; XmString dir_xmstring, pattern_xmstring; int count = SPECPDL_INDEX (); struct gcpro gcpro1, gcpro2, gcpro3, gcpro4, gcpro5; GCPRO5 (prompt, dir, default_filename, mustmatch, file); CHECK_STRING (prompt); CHECK_STRING (dir); /* Prevent redisplay. */ specbind (Qinhibit_redisplay, Qt); BLOCK_INPUT; /* Create the dialog with PROMPT as title, using DIR as initial directory and using "*" as pattern. */ dir = Fexpand_file_name (dir, Qnil); dir_xmstring = XmStringCreateLocalized (SDATA (dir)); pattern_xmstring = XmStringCreateLocalized ("*"); XtSetArg (al[ac], XmNtitle, SDATA (prompt)); ++ac; XtSetArg (al[ac], XmNdirectory, dir_xmstring); ++ac; XtSetArg (al[ac], XmNpattern, pattern_xmstring); ++ac; XtSetArg (al[ac], XmNresizePolicy, XmRESIZE_GROW); ++ac; XtSetArg (al[ac], XmNdialogStyle, XmDIALOG_APPLICATION_MODAL); ++ac; dialog = XmCreateFileSelectionDialog (f->output_data.x->widget, "fsb", al, ac); XmStringFree (dir_xmstring); XmStringFree (pattern_xmstring); /* Add callbacks for OK and Cancel. */ XtAddCallback (dialog, XmNokCallback, file_dialog_cb, (XtPointer) &result); XtAddCallback (dialog, XmNcancelCallback, file_dialog_cb, (XtPointer) &result); XtAddCallback (dialog, XmNunmapCallback, file_dialog_unmap_cb, (XtPointer) &result); /* Disable the help button since we can't display help. */ help = XmFileSelectionBoxGetChild (dialog, XmDIALOG_HELP_BUTTON); XtSetSensitive (help, False); /* Mark OK button as default. */ XtVaSetValues (XmFileSelectionBoxGetChild (dialog, XmDIALOG_OK_BUTTON), XmNshowAsDefault, True, NULL); /* If MUSTMATCH is non-nil, disable the file entry field of the dialog, so that the user must select a file from the files list box. We can't remove it because we wouldn't have a way to get at the result file name, then. */ text = XmFileSelectionBoxGetChild (dialog, XmDIALOG_TEXT); if (!NILP (mustmatch)) { Widget label; label = XmFileSelectionBoxGetChild (dialog, XmDIALOG_SELECTION_LABEL); XtSetSensitive (text, False); XtSetSensitive (label, False); } /* Manage the dialog, so that list boxes get filled. */ XtManageChild (dialog); /* Select DEFAULT_FILENAME in the files list box. DEFAULT_FILENAME must include the path for this to work. */ list = XmFileSelectionBoxGetChild (dialog, XmDIALOG_LIST); if (STRINGP (default_filename)) { XmString default_xmstring; int item_pos; default_xmstring = XmStringCreateLocalized (SDATA (default_filename)); if (!XmListItemExists (list, default_xmstring)) { /* Add a new item if DEFAULT_FILENAME is not in the list. */ XmListAddItem (list, default_xmstring, 0); item_pos = 0; } else item_pos = XmListItemPos (list, default_xmstring); XmStringFree (default_xmstring); /* Select the item and scroll it into view. */ XmListSelectPos (list, item_pos, True); XmListSetPos (list, item_pos); } /* Process events until the user presses Cancel or OK. */ result = 0; while (result == 0) { XEvent event; XtAppNextEvent (Xt_app_con, &event); (void) x_dispatch_event (&event, FRAME_X_DISPLAY (f) ); } /* Get the result. */ if (result == XmCR_OK) { XmString text; String data; XtVaGetValues (dialog, XmNtextString, &text, NULL); XmStringGetLtoR (text, XmFONTLIST_DEFAULT_TAG, &data); XmStringFree (text); file = build_string (data); XtFree (data); } else file = Qnil; /* Clean up. */ XtUnmanageChild (dialog); XtDestroyWidget (dialog); UNBLOCK_INPUT; UNGCPRO; /* Make "Cancel" equivalent to C-g. */ if (NILP (file)) Fsignal (Qquit, Qnil); return unbind_to (count, file); } #endif /* USE_MOTIF */ #ifdef USE_GTK DEFUN ("x-file-dialog", Fx_file_dialog, Sx_file_dialog, 2, 4, 0, "Read file name, prompting with PROMPT in directory DIR.\n\ Use a file selection dialog.\n\ Select DEFAULT-FILENAME in the dialog's file selection box, if\n\ specified. Don't let the user enter a file name in the file\n\ selection dialog's entry field, if MUSTMATCH is non-nil.") (prompt, dir, default_filename, mustmatch) Lisp_Object prompt, dir, default_filename, mustmatch; { FRAME_PTR f = SELECTED_FRAME (); char *fn; Lisp_Object file = Qnil; int count = specpdl_ptr - specpdl; struct gcpro gcpro1, gcpro2, gcpro3, gcpro4, gcpro5; char *cdef_file; char *cprompt; GCPRO5 (prompt, dir, default_filename, mustmatch, file); CHECK_STRING (prompt); CHECK_STRING (dir); /* Prevent redisplay. */ specbind (Qinhibit_redisplay, Qt); BLOCK_INPUT; if (STRINGP (default_filename)) cdef_file = SDATA (default_filename); else cdef_file = SDATA (dir); fn = xg_get_file_name (f, SDATA (prompt), cdef_file, ! NILP (mustmatch)); if (fn) { file = build_string (fn); xfree (fn); } UNBLOCK_INPUT; UNGCPRO; /* Make "Cancel" equivalent to C-g. */ if (NILP (file)) Fsignal (Qquit, Qnil); return unbind_to (count, file); } #endif /* USE_GTK */ /*********************************************************************** Keyboard ***********************************************************************/ #ifdef HAVE_XKBGETKEYBOARD #include #include #endif DEFUN ("x-backspace-delete-keys-p", Fx_backspace_delete_keys_p, Sx_backspace_delete_keys_p, 0, 1, 0, doc: /* Check if both Backspace and Delete keys are on the keyboard of FRAME. FRAME nil means use the selected frame. Value is t if we know that both keys are present, and are mapped to the usual X keysyms. */) (frame) Lisp_Object frame; { #ifdef HAVE_XKBGETKEYBOARD XkbDescPtr kb; struct frame *f = check_x_frame (frame); Display *dpy = FRAME_X_DISPLAY (f); Lisp_Object have_keys; int major, minor, op, event, error; BLOCK_INPUT; /* Check library version in case we're dynamically linked. */ major = XkbMajorVersion; minor = XkbMinorVersion; if (!XkbLibraryVersion (&major, &minor)) { UNBLOCK_INPUT; return Qnil; } /* Check that the server supports XKB. */ major = XkbMajorVersion; minor = XkbMinorVersion; if (!XkbQueryExtension (dpy, &op, &event, &error, &major, &minor)) { UNBLOCK_INPUT; return Qnil; } have_keys = Qnil; kb = XkbGetMap (dpy, XkbAllMapComponentsMask, XkbUseCoreKbd); if (kb) { int delete_keycode = 0, backspace_keycode = 0, i; if (XkbGetNames (dpy, XkbAllNamesMask, kb) == Success) { for (i = kb->min_key_code; (i < kb->max_key_code && (delete_keycode == 0 || backspace_keycode == 0)); ++i) { /* The XKB symbolic key names can be seen most easily in the PS file generated by `xkbprint -label name $DISPLAY'. */ if (bcmp ("DELE", kb->names->keys[i].name, 4) == 0) delete_keycode = i; else if (bcmp ("BKSP", kb->names->keys[i].name, 4) == 0) backspace_keycode = i; } XkbFreeNames (kb, 0, True); } XkbFreeClientMap (kb, 0, True); if (delete_keycode && backspace_keycode && XKeysymToKeycode (dpy, XK_Delete) == delete_keycode && XKeysymToKeycode (dpy, XK_BackSpace) == backspace_keycode) have_keys = Qt; } UNBLOCK_INPUT; return have_keys; #else /* not HAVE_XKBGETKEYBOARD */ return Qnil; #endif /* not HAVE_XKBGETKEYBOARD */ } /*********************************************************************** Initialization ***********************************************************************/ /* Keep this list in the same order as frame_parms in frame.c. Use 0 for unsupported frame parameters. */ frame_parm_handler x_frame_parm_handlers[] = { x_set_autoraise, x_set_autolower, x_set_background_color, x_set_border_color, x_set_border_width, x_set_cursor_color, x_set_cursor_type, x_set_font, x_set_foreground_color, x_set_icon_name, x_set_icon_type, x_set_internal_border_width, x_set_menu_bar_lines, x_set_mouse_color, x_explicitly_set_name, x_set_scroll_bar_width, x_set_title, x_set_unsplittable, x_set_vertical_scroll_bars, x_set_visibility, x_set_tool_bar_lines, x_set_scroll_bar_foreground, x_set_scroll_bar_background, x_set_screen_gamma, x_set_line_spacing, x_set_fringe_width, x_set_fringe_width, x_set_wait_for_wm, x_set_fullscreen, }; void syms_of_xfns () { /* This is zero if not using X windows. */ x_in_use = 0; /* The section below is built by the lisp expression at the top of the file, just above where these variables are declared. */ /*&&& init symbols here &&&*/ Qnone = intern ("none"); staticpro (&Qnone); Qsuppress_icon = intern ("suppress-icon"); staticpro (&Qsuppress_icon); Qundefined_color = intern ("undefined-color"); staticpro (&Qundefined_color); Qcenter = intern ("center"); staticpro (&Qcenter); Qcompound_text = intern ("compound-text"); staticpro (&Qcompound_text); Qcancel_timer = intern ("cancel-timer"); staticpro (&Qcancel_timer); /* This is the end of symbol initialization. */ /* Text property `display' should be nonsticky by default. */ Vtext_property_default_nonsticky = Fcons (Fcons (Qdisplay, Qt), Vtext_property_default_nonsticky); Qlaplace = intern ("laplace"); staticpro (&Qlaplace); Qemboss = intern ("emboss"); staticpro (&Qemboss); Qedge_detection = intern ("edge-detection"); staticpro (&Qedge_detection); Qheuristic = intern ("heuristic"); staticpro (&Qheuristic); QCmatrix = intern (":matrix"); staticpro (&QCmatrix); QCcolor_adjustment = intern (":color-adjustment"); staticpro (&QCcolor_adjustment); QCmask = intern (":mask"); staticpro (&QCmask); Fput (Qundefined_color, Qerror_conditions, Fcons (Qundefined_color, Fcons (Qerror, Qnil))); Fput (Qundefined_color, Qerror_message, build_string ("Undefined color")); DEFVAR_BOOL ("cross-disabled-images", &cross_disabled_images, doc: /* Non-nil means always draw a cross over disabled images. Disabled images are those having an `:conversion disabled' property. A cross is always drawn on black & white displays. */); cross_disabled_images = 0; DEFVAR_LISP ("x-bitmap-file-path", &Vx_bitmap_file_path, doc: /* List of directories to search for window system bitmap files. */); Vx_bitmap_file_path = decode_env_path ((char *) 0, PATH_BITMAPS); DEFVAR_LISP ("x-pointer-shape", &Vx_pointer_shape, doc: /* The shape of the pointer when over text. Changing the value does not affect existing frames unless you set the mouse color. */); Vx_pointer_shape = Qnil; #if 0 /* This doesn't really do anything. */ DEFVAR_LISP ("x-nontext-pointer-shape", &Vx_nontext_pointer_shape, doc: /* The shape of the pointer when not over text. This variable takes effect when you create a new frame or when you set the mouse color. */); #endif Vx_nontext_pointer_shape = Qnil; DEFVAR_LISP ("x-hourglass-pointer-shape", &Vx_hourglass_pointer_shape, doc: /* The shape of the pointer when Emacs is busy. This variable takes effect when you create a new frame or when you set the mouse color. */); Vx_hourglass_pointer_shape = Qnil; DEFVAR_BOOL ("display-hourglass", &display_hourglass_p, doc: /* Non-zero means Emacs displays an hourglass pointer on window systems. */); display_hourglass_p = 1; DEFVAR_LISP ("hourglass-delay", &Vhourglass_delay, doc: /* *Seconds to wait before displaying an hourglass pointer. Value must be an integer or float. */); Vhourglass_delay = make_number (DEFAULT_HOURGLASS_DELAY); #if 0 /* This doesn't really do anything. */ DEFVAR_LISP ("x-mode-pointer-shape", &Vx_mode_pointer_shape, doc: /* The shape of the pointer when over the mode line. This variable takes effect when you create a new frame or when you set the mouse color. */); #endif Vx_mode_pointer_shape = Qnil; DEFVAR_LISP ("x-sensitive-text-pointer-shape", &Vx_sensitive_text_pointer_shape, doc: /* The shape of the pointer when over mouse-sensitive text. This variable takes effect when you create a new frame or when you set the mouse color. */); Vx_sensitive_text_pointer_shape = Qnil; DEFVAR_LISP ("x-window-horizontal-drag-cursor", &Vx_window_horizontal_drag_shape, doc: /* Pointer shape to use for indicating a window can be dragged horizontally. This variable takes effect when you create a new frame or when you set the mouse color. */); Vx_window_horizontal_drag_shape = Qnil; DEFVAR_LISP ("x-cursor-fore-pixel", &Vx_cursor_fore_pixel, doc: /* A string indicating the foreground color of the cursor box. */); Vx_cursor_fore_pixel = Qnil; DEFVAR_LISP ("x-max-tooltip-size", &Vx_max_tooltip_size, doc: /* Maximum size for tooltips. Value is a pair (COLUMNS . ROWS). Text larger than this is clipped. */); Vx_max_tooltip_size = Fcons (make_number (80), make_number (40)); DEFVAR_LISP ("x-no-window-manager", &Vx_no_window_manager, doc: /* Non-nil if no X window manager is in use. Emacs doesn't try to figure this out; this is always nil unless you set it to something else. */); /* We don't have any way to find this out, so set it to nil and maybe the user would like to set it to t. */ Vx_no_window_manager = Qnil; DEFVAR_LISP ("x-pixel-size-width-font-regexp", &Vx_pixel_size_width_font_regexp, doc: /* Regexp matching a font name whose width is the same as `PIXEL_SIZE'. Since Emacs gets width of a font matching with this regexp from PIXEL_SIZE field of the name, font finding mechanism gets faster for such a font. This is especially effective for such large fonts as Chinese, Japanese, and Korean. */); Vx_pixel_size_width_font_regexp = Qnil; DEFVAR_LISP ("image-cache-eviction-delay", &Vimage_cache_eviction_delay, doc: /* Time after which cached images are removed from the cache. When an image has not been displayed this many seconds, remove it from the image cache. Value must be an integer or nil with nil meaning don't clear the cache. */); Vimage_cache_eviction_delay = make_number (30 * 60); #ifdef USE_X_TOOLKIT Fprovide (intern ("x-toolkit"), Qnil); #ifdef USE_MOTIF Fprovide (intern ("motif"), Qnil); DEFVAR_LISP ("motif-version-string", &Vmotif_version_string, doc: /* Version info for LessTif/Motif. */); Vmotif_version_string = build_string (XmVERSION_STRING); #endif /* USE_MOTIF */ #endif /* USE_X_TOOLKIT */ /* X window properties. */ defsubr (&Sx_change_window_property); defsubr (&Sx_delete_window_property); defsubr (&Sx_window_property); defsubr (&Sxw_display_color_p); defsubr (&Sx_display_grayscale_p); defsubr (&Sxw_color_defined_p); defsubr (&Sxw_color_values); defsubr (&Sx_server_max_request_size); defsubr (&Sx_server_vendor); defsubr (&Sx_server_version); defsubr (&Sx_display_pixel_width); defsubr (&Sx_display_pixel_height); defsubr (&Sx_display_mm_width); defsubr (&Sx_display_mm_height); defsubr (&Sx_display_screens); defsubr (&Sx_display_planes); defsubr (&Sx_display_color_cells); defsubr (&Sx_display_visual_class); defsubr (&Sx_display_backing_store); defsubr (&Sx_display_save_under); defsubr (&Sx_create_frame); defsubr (&Sx_open_connection); defsubr (&Sx_close_connection); defsubr (&Sx_display_list); defsubr (&Sx_synchronize); defsubr (&Sx_focus_frame); defsubr (&Sx_backspace_delete_keys_p); /* Setting callback functions for fontset handler. */ get_font_info_func = x_get_font_info; #if 0 /* This function pointer doesn't seem to be used anywhere. And the pointer assigned has the wrong type, anyway. */ list_fonts_func = x_list_fonts; #endif load_font_func = x_load_font; find_ccl_program_func = x_find_ccl_program; query_font_func = x_query_font; set_frame_fontset_func = x_set_font; check_window_system_func = check_x; /* Images. */ Qxbm = intern ("xbm"); staticpro (&Qxbm); QCconversion = intern (":conversion"); staticpro (&QCconversion); QCheuristic_mask = intern (":heuristic-mask"); staticpro (&QCheuristic_mask); QCcolor_symbols = intern (":color-symbols"); staticpro (&QCcolor_symbols); QCascent = intern (":ascent"); staticpro (&QCascent); QCmargin = intern (":margin"); staticpro (&QCmargin); QCrelief = intern (":relief"); staticpro (&QCrelief); Qpostscript = intern ("postscript"); staticpro (&Qpostscript); QCloader = intern (":loader"); staticpro (&QCloader); QCbounding_box = intern (":bounding-box"); staticpro (&QCbounding_box); QCpt_width = intern (":pt-width"); staticpro (&QCpt_width); QCpt_height = intern (":pt-height"); staticpro (&QCpt_height); QCindex = intern (":index"); staticpro (&QCindex); Qpbm = intern ("pbm"); staticpro (&Qpbm); #if HAVE_XPM Qxpm = intern ("xpm"); staticpro (&Qxpm); #endif #if HAVE_JPEG Qjpeg = intern ("jpeg"); staticpro (&Qjpeg); #endif #if HAVE_TIFF Qtiff = intern ("tiff"); staticpro (&Qtiff); #endif #if HAVE_GIF Qgif = intern ("gif"); staticpro (&Qgif); #endif #if HAVE_PNG Qpng = intern ("png"); staticpro (&Qpng); #endif defsubr (&Sclear_image_cache); defsubr (&Simage_size); defsubr (&Simage_mask_p); hourglass_atimer = NULL; hourglass_shown_p = 0; defsubr (&Sx_show_tip); defsubr (&Sx_hide_tip); tip_timer = Qnil; staticpro (&tip_timer); tip_frame = Qnil; staticpro (&tip_frame); last_show_tip_args = Qnil; staticpro (&last_show_tip_args); #ifdef USE_MOTIF defsubr (&Sx_file_dialog); #endif } void init_xfns () { image_types = NULL; Vimage_types = Qnil; define_image_type (&xbm_type); define_image_type (&gs_type); define_image_type (&pbm_type); #if HAVE_XPM define_image_type (&xpm_type); #endif #if HAVE_JPEG define_image_type (&jpeg_type); #endif #if HAVE_TIFF define_image_type (&tiff_type); #endif #if HAVE_GIF define_image_type (&gif_type); #endif #if HAVE_PNG define_image_type (&png_type); #endif } #endif /* HAVE_X_WINDOWS */