(***********************************************************************) (* *) (* Objective Caml *) (* *) (* Xavier Leroy, projet Cristal, INRIA Rocquencourt *) (* *) (* Copyright 1996 Institut National de Recherche en Informatique et *) (* en Automatique. All rights reserved. This file is distributed *) (* under the terms of the GNU Library General Public License. *) (* *) (***********************************************************************) (* $Id$ *) exception Graphic_failure of string (* Initializations *) let _ = Callback.register_exception "Graphics.Graphic_failure" (Graphic_failure "") external raw_open_graph: string -> unit = "gr_open_graph" external raw_close_graph: unit -> unit = "gr_close_graph" external sigio_signal: unit -> int = "gr_sigio_signal" external sigio_handler: int -> unit = "gr_sigio_handler" let unix_open_graph arg = Sys.set_signal (sigio_signal()) (Sys.Signal_handle sigio_handler); raw_open_graph arg let unix_close_graph () = Sys.set_signal (sigio_signal()) Sys.Signal_ignore; raw_close_graph () let (open_graph, close_graph) = match Sys.os_type with | "Unix" -> (unix_open_graph, unix_close_graph) | "Win32" -> (raw_open_graph, raw_close_graph) | "MacOS" -> (raw_open_graph, raw_close_graph) | _ -> invalid_arg ("Graphics: unknown OS type: " ^ Sys.os_type) external set_window_title : string -> unit = "gr_set_window_title" external clear_graph : unit -> unit = "gr_clear_graph" external size_x : unit -> int = "gr_size_x" external size_y : unit -> int = "gr_size_y" (* Double-buffering *) external display_mode : bool -> unit = "gr_display_mode" external remember_mode : bool -> unit = "gr_remember_mode" external synchronize : unit -> unit = "gr_synchronize" let auto_synchronize = function | true -> display_mode true; remember_mode true; synchronize () | false -> display_mode false; remember_mode true ;; (* Colors *) type color = int let rgb r g b = (r lsl 16) + (g lsl 8) + b external set_color : color -> unit = "gr_set_color" let black = 0x000000 and white = 0xFFFFFF and red = 0xFF0000 and green = 0x00FF00 and blue = 0x0000FF and yellow = 0xFFFF00 and cyan = 0x00FFFF and magenta = 0xFF00FF let background = white and foreground = black (* Drawing *) external plot : int -> int -> unit = "gr_plot" let plots points = for i = 0 to Array.length points - 1 do let (x, y) = points.(i) in plot x y; done ;; external point_color : int -> int -> color = "gr_point_color" external moveto : int -> int -> unit = "gr_moveto" external current_x : unit -> int = "gr_current_x" external current_y : unit -> int = "gr_current_y" let current_point () = current_x (), current_y () external lineto : int -> int -> unit = "gr_lineto" let rlineto x y = lineto (current_x () + x) (current_y () + y) let rmoveto x y = moveto (current_x () + x) (current_y () + y) external draw_rect : int -> int -> int -> int -> unit = "gr_draw_rect" let draw_poly, draw_poly_line = let dodraw close_flag points = if Array.length points > 0 then begin let (savex, savey) = current_point () in moveto (fst points.(0)) (snd points.(0)); for i = 1 to Array.length points - 1 do let (x, y) = points.(i) in lineto x y; done; if close_flag then lineto (fst points.(0)) (snd points.(0)); moveto savex savey; end; in dodraw true, dodraw false ;; let draw_segments segs = let (savex, savey) = current_point () in for i = 0 to Array.length segs - 1 do let (x1, y1, x2, y2) = segs.(i) in moveto x1 y1; lineto x2 y2; done; moveto savex savey; ;; external draw_arc : int -> int -> int -> int -> int -> int -> unit = "gr_draw_arc" "gr_draw_arc_nat" let draw_ellipse x y rx ry = draw_arc x y rx ry 0 360 let draw_circle x y r = draw_arc x y r r 0 360 external set_line_width : int -> unit = "gr_set_line_width" external fill_rect : int -> int -> int -> int -> unit = "gr_fill_rect" external fill_poly : (int * int) array -> unit = "gr_fill_poly" external fill_arc : int -> int -> int -> int -> int -> int -> unit = "gr_fill_arc" "gr_fill_arc_nat" let fill_ellipse x y rx ry = fill_arc x y rx ry 0 360 let fill_circle x y r = fill_arc x y r r 0 360 (* Text *) external draw_char : char -> unit = "gr_draw_char" external draw_string : string -> unit = "gr_draw_string" external set_font : string -> unit = "gr_set_font" external set_text_size : int -> unit = "gr_set_text_size" external text_size : string -> int * int = "gr_text_size" (* Images *) type image let transp = -1 external make_image : color array array -> image = "gr_make_image" external dump_image : image -> color array array = "gr_dump_image" external draw_image : image -> int -> int -> unit = "gr_draw_image" external create_image : int -> int -> image = "gr_create_image" external blit_image : image -> int -> int -> unit = "gr_blit_image" let get_image x y w h = let image = create_image w h in blit_image image x y; image (* Events *) type status = { mouse_x : int; mouse_y : int; button : bool; keypressed : bool; key : char } type event = Button_down | Button_up | Key_pressed | Mouse_motion | Poll external wait_next_event : event list -> status = "gr_wait_event" let mouse_pos () = let e = wait_next_event [Poll] in (e.mouse_x, e.mouse_y) let button_down () = let e = wait_next_event [Poll] in e.button let read_key () = let e = wait_next_event [Key_pressed] in e.key let key_pressed () = let e = wait_next_event [Poll] in e.keypressed (*** Sound *) external sound : int -> int -> unit = "gr_sound" (* Splines *) let add (x1, y1) (x2, y2) = (x1 +. x2, y1 +. y2) and sub (x1, y1) (x2, y2) = (x1 -. x2, y1 -. y2) and middle (x1, y1) (x2, y2) = ((x1 +. x2) /. 2.0, (y1 +. y2) /. 2.0) and area (x1, y1) (x2, y2) = abs_float (x1 *. y2 -. x2 *. y1) and norm (x1, y1) = sqrt (x1 *. x1 +. y1 *. y1);; let test a b c d = let v = sub d a in let s = norm v in area v (sub a b) < s && area v (sub a c) < s;; let spline a b c d = let rec spl accu a b c d = if test a b c d then d :: accu else let a' = middle a b and o = middle b c in let b' = middle a' o and d' = middle c d in let c' = middle o d' in let i = middle b' c' in spl (spl accu a a' b' i) i c' d' d in spl [a] a b c d;; let curveto b c (x, y as d) = let float_point (x, y) = float_of_int x, float_of_int y in let round f = int_of_float (f +. 0.5) in let int_point (x, y) = round x, round y in let points = spline (float_point (current_point ())) (float_point b) (float_point c) (float_point d) in draw_poly_line (Array.of_list (List.map int_point points)); moveto x y;;