[ViewVC] Diff of: cebix/BasiliskII/src/Unix/video

Comparing BasiliskII/src/Unix/video_x.cpp (file contents):
Revision 1.22 by cebix, 2000-10-08T18:41:35Z vs.
Revision 1.55 by cebix, 2001-07-06T22:37:23Z

#	Line 1 \| Line 1
1		/*
2		* video_x.cpp - Video/graphics emulation, X11 specific stuff
3		*
4	<	* Basilisk II (C) 1997-2000 Christian Bauer
4	>	* Basilisk II (C) 1997-2001 Christian Bauer
5		*
6		* This program is free software; you can redistribute it and/or modify
7		* it under the terms of the GNU General Public License as published by
#	Line 24 \| Line 24
24		* Ctrl-Tab = suspend DGA mode
25		* Ctrl-Esc = emergency quit
26		* Ctrl-F1 = mount floppy
27	+	* Ctrl-F5 = grab mouse (in windowed mode)
28		*/
29
30		#include "sysdeps.h"
#	Line 36 \| Line 37
37		#include <sys/shm.h>
38		#include <errno.h>
39
40	+	#include <algorithm>
41	+
42	+	#ifndef NO_STD_NAMESPACE
43	+	using std::sort;
44	+	#endif
45	+
46		#ifdef HAVE_PTHREADS
47		# include <pthread.h>
48		#endif
#	Line 52 \| Line 59
59		# include <sys/mman.h>
60		#endif
61
55	–	#ifdef ENABLE_VOSF
56	–	# include <math.h> // log()
57	–	# include <unistd.h>
58	–	# include <signal.h>
59	–	# include <fcntl.h>
60	–	# include <sys/mman.h>
61	–	#endif
62	–
62		#include "cpu_emulation.h"
63		#include "main.h"
64		#include "adb.h"
#	Line 80 \| Line 79 \| enum {
79
80		// Constants
81		const char KEYCODE_FILE_NAME[] = DATADIR "/keycodes";
82	<	const char FBDEVICES_FILE_NAME[] = DATADIR "/fbdevices";
82	>
83	>	static const int win_eventmask = KeyPressMask \| KeyReleaseMask \| ButtonPressMask \| ButtonReleaseMask \| PointerMotionMask \| ExposureMask \| StructureNotifyMask;
84	>	static const int dga_eventmask = KeyPressMask \| KeyReleaseMask \| ButtonPressMask \| ButtonReleaseMask \| PointerMotionMask \| StructureNotifyMask;
85
86
87		// Global variables
88		static int32 frame_skip; // Prefs items
89	<	static int16 mouse_wheel_mode = 1;
90	<	static int16 mouse_wheel_lines = 3;
89	>	static int16 mouse_wheel_mode;
90	>	static int16 mouse_wheel_lines;
91
92		static int display_type = DISPLAY_WINDOW; // See enum above
93		static bool local_X11; // Flag: X server running on local machine?
94	<	static uint8 *the_buffer; // Mac frame buffer
94	>	static uint8 *the_buffer = NULL; // Mac frame buffer (where MacOS draws into)
95	>	static uint8 *the_buffer_copy = NULL; // Copy of Mac frame buffer (for refreshed modes)
96
95	–	#ifdef HAVE_PTHREADS
97		static bool redraw_thread_active = false; // Flag: Redraw thread installed
98	<	static volatile bool redraw_thread_cancel = false; // Flag: Cancel Redraw thread
98	>	#ifdef HAVE_PTHREADS
99	>	static volatile bool redraw_thread_cancel; // Flag: Cancel Redraw thread
100		static pthread_t redraw_thread; // Redraw thread
101		#endif
102
103		static bool has_dga = false; // Flag: Video DGA capable
104		static bool has_vidmode = false; // Flag: VidMode extension available
105
106	+	#ifdef ENABLE_VOSF
107	+	static bool use_vosf = true; // Flag: VOSF enabled
108	+	#else
109	+	static const bool use_vosf = false; // VOSF not possible
110	+	#endif
111	+
112		static bool ctrl_down = false; // Flag: Ctrl key pressed
113		static bool caps_on = false; // Flag: Caps Lock on
114		static bool quit_full_screen = false; // Flag: DGA close requested from redraw thread
#	Line 114 \| Line 122 \| static int keycode_table[256]; // X
122
123		// X11 variables
124		static int screen; // Screen number
125	<	static int xdepth; // Depth of X screen
126	<	static int depth; // Depth of Mac frame buffer
127	<	static Window rootwin, the_win; // Root window and our window
120	<	static XVisualInfo visualInfo;
121	<	static Visual *vis;
122	<	static Colormap cmap[2]; // Two colormaps (DGA) for 8-bit mode
125	>	static Window rootwin; // Root window and our window
126	>	static int num_depths = 0; // Number of available X depths
127	>	static int *avail_depths = NULL; // List of available X depths
128		static XColor black, white;
129		static unsigned long black_pixel, white_pixel;
130		static int eventmask;
126	–	static const int win_eventmask = KeyPressMask \| KeyReleaseMask \| ButtonPressMask \| ButtonReleaseMask \| PointerMotionMask \| EnterWindowMask \| ExposureMask;
127	–	static const int dga_eventmask = KeyPressMask \| KeyReleaseMask \| ButtonPressMask \| ButtonReleaseMask \| PointerMotionMask;
131
132	<	static XColor palette[256]; // Color palette for 8-bit mode
133	<	static bool palette_changed = false; // Flag: Palette changed, redraw thread must set new colors
134	<	#ifdef HAVE_PTHREADS
135	<	static pthread_mutex_t palette_lock = PTHREAD_MUTEX_INITIALIZER; // Mutex to protect palette
133	<	#endif
132	>	static int xdepth; // Depth of X screen
133	>	static XVisualInfo visualInfo;
134	>	static Visual *vis;
135	>	static int color_class;
136
137	<	// Variables for window mode
136	<	static GC the_gc;
137	<	static XImage *img = NULL;
138	<	static XShmSegmentInfo shminfo;
139	<	static Cursor mac_cursor;
140	<	static uint8 *the_buffer_copy = NULL; // Copy of Mac frame buffer
141	<	static bool have_shm = false; // Flag: SHM extensions available
142	<	static bool updt_box[17][17]; // Flag for Update
143	<	static int nr_boxes;
144	<	static const int sm_uptd[] = {4,1,6,3,0,5,2,7};
145	<	static int sm_no_boxes[] = {1,8,32,64,128,300};
137	>	static int rshift, rloss, gshift, gloss, bshift, bloss; // Pixel format of DirectColor/TrueColor modes
138
139	<	// Variables for XF86 DGA mode
148	<	static int current_dga_cmap; // Number (0 or 1) of currently installed DGA colormap
149	<	static Window suspend_win; // "Suspend" window
150	<	static void *fb_save = NULL; // Saved frame buffer for suspend
151	<	#ifdef HAVE_PTHREADS
152	<	static pthread_mutex_t frame_buffer_lock = PTHREAD_MUTEX_INITIALIZER; // Mutex to protect frame buffer
153	<	#endif
139	>	static Colormap cmap[2] = {0, 0}; // Colormaps for indexed modes (DGA needs two of them)
140
141	<	// Variables for fbdev DGA mode
142	<	const char FBDEVICE_FILE_NAME[] = "/dev/fb";
143	<	static int fbdev_fd;
141	>	static XColor palette[256]; // Color palette to be used as CLUT and gamma table
142	>	static bool palette_changed = false; // Flag: Palette changed, redraw thread must set new colors
143	>
144	>	#ifdef ENABLE_FBDEV_DGA
145	>	static int fbdev_fd = -1;
146	>	#endif
147
148		#ifdef ENABLE_XF86_VIDMODE
149	<	// Variables for XF86 VidMode support
161	<	static XF86VidModeModeInfo **x_video_modes; // Array of all available modes
149	>	static XF86VidModeModeInfo **x_video_modes = NULL; // Array of all available modes
150		static int num_x_video_modes;
151		#endif
152
153	<	#ifdef ENABLE_VOSF
154	<	static bool use_vosf = true; // Flag: VOSF enabled
153	>	// Mutex to protect palette
154	>	#ifdef HAVE_PTHREADS
155	>	static pthread_mutex_t palette_lock = PTHREAD_MUTEX_INITIALIZER;
156	>	#define LOCK_PALETTE pthread_mutex_lock(&palette_lock)
157	>	#define UNLOCK_PALETTE pthread_mutex_unlock(&palette_lock)
158		#else
159	<	static const bool use_vosf = false; // Flag: VOSF enabled
160	<	#endif
170	<
171	<	#ifdef ENABLE_VOSF
172	<	static uint8 * the_host_buffer; // Host frame buffer in VOSF mode
173	<	static uint32 the_buffer_size; // Size of allocated the_buffer
159	>	#define LOCK_PALETTE
160	>	#define UNLOCK_PALETTE
161		#endif
162
163	<	#ifdef ENABLE_VOSF
177	<	// Variables for Video on SEGV support (taken from the Win32 port)
178	<	struct ScreenPageInfo {
179	<	int top, bottom; // Mapping between this virtual page and Mac scanlines
180	<	};
181	<
182	<	struct ScreenInfo {
183	<	uint32 memBase; // Real start address
184	<	uint32 memStart; // Start address aligned to page boundary
185	<	uint32 memEnd; // Address of one-past-the-end of the screen
186	<	uint32 memLength; // Length of the memory addressed by the screen pages
187	<
188	<	uint32 pageSize; // Size of a page
189	<	int pageBits; // Shift count to get the page number
190	<	uint32 pageCount; // Number of pages allocated to the screen
191	<
192	<	uint8 * dirtyPages; // Table of flags set if page was altered
193	<	ScreenPageInfo * pageInfo; // Table of mappings page -> Mac scanlines
194	<	};
195	<
196	<	static ScreenInfo mainBuffer;
197	<
198	<	#define PFLAG_SET(page) mainBuffer.dirtyPages[page] = 1
199	<	#define PFLAG_CLEAR(page) mainBuffer.dirtyPages[page] = 0
200	<	#define PFLAG_ISSET(page) mainBuffer.dirtyPages[page]
201	<	#define PFLAG_ISCLEAR(page) (mainBuffer.dirtyPages[page] == 0)
202	<	#ifdef UNALIGNED_PROFITABLE
203	<	# define PFLAG_ISCLEAR_4(page) (((uint32 )(mainBuffer.dirtyPages + page)) == 0)
204	<	#else
205	<	# define PFLAG_ISCLEAR_4(page) \
206	<	(mainBuffer.dirtyPages[page ] == 0) \
207	<	&& (mainBuffer.dirtyPages[page+1] == 0) \
208	<	&& (mainBuffer.dirtyPages[page+2] == 0) \
209	<	&& (mainBuffer.dirtyPages[page+3] == 0)
210	<	#endif
211	<	#define PFLAG_CLEAR_ALL memset(mainBuffer.dirtyPages, 0, mainBuffer.pageCount)
212	<	#define PFLAG_SET_ALL memset(mainBuffer.dirtyPages, 1, mainBuffer.pageCount)
213	<
214	<	static int zero_fd = -1;
215	<	static bool Screen_fault_handler_init();
216	<	static struct sigaction vosf_sa;
217	<
163	>	// Mutex to protect frame buffer
164		#ifdef HAVE_PTHREADS
165	<	static pthread_mutex_t Screen_draw_lock = PTHREAD_MUTEX_INITIALIZER; // Mutex to protect frame buffer (dirtyPages in fact)
165	>	static pthread_mutex_t frame_buffer_lock = PTHREAD_MUTEX_INITIALIZER;
166	>	#define LOCK_FRAME_BUFFER pthread_mutex_lock(&frame_buffer_lock);
167	>	#define UNLOCK_FRAME_BUFFER pthread_mutex_unlock(&frame_buffer_lock);
168	>	#else
169	>	#define LOCK_FRAME_BUFFER
170	>	#define UNLOCK_FRAME_BUFFER
171		#endif
172
173	<	#endif
173	>	// Variables for non-VOSF incremental refresh
174	>	static const int sm_uptd[] = {4,1,6,3,0,5,2,7};
175	>	static int sm_no_boxes[] = {1,8,32,64,128,300};
176	>	static bool updt_box[17][17];
177	>	static int nr_boxes;
178
179	<	// VideoRefresh function
180	<	void VideoRefreshInit(void);
179	>	// Video refresh function
180	>	static void VideoRefreshInit(void);
181		static void (*video_refresh)(void);
182
183	+
184		// Prototypes
185		static void redraw_func(void arg);
186	<	static int event2keycode(XKeyEvent *ev);
231	<
186	>	static int event2keycode(XKeyEvent &ev);
187
188		// From main_unix.cpp
189		extern char *x_display_name;
#	Line 237 \| Line 192 \| *extern Display x_display;**
192		// From sys_unix.cpp
193		extern void SysMountFirstFloppy(void);
194
240	–	#ifdef ENABLE_VOSF
241	–	# include "video_vosf.h"
242	–	#endif
243	–
195
196		/*
197	<	* Initialization
197	>	* Utility functions
198		*/
199
200	<	// Set VideoMonitor according to video mode
201	<	void set_video_monitor(int width, int height, int bytes_per_row, bool native_byte_order)
200	>	// Map RGB color to pixel value (this only works in TrueColor/DirectColor visuals)
201	>	static inline uint32 map_rgb(uint8 red, uint8 green, uint8 blue)
202		{
203	<	#if !REAL_ADDRESSING && !DIRECT_ADDRESSING
204	<	int layout = FLAYOUT_DIRECT;
203	>	return ((red >> rloss) << rshift) \| ((green >> gloss) << gshift) \| ((blue >> bloss) << bshift);
204	>	}
205	>
206	>	// Do we have a visual for handling the specified Mac depth? If so, set the
207	>	// global variables "xdepth", "visualInfo", "vis" and "color_class".
208	>	static bool find_visual_for_depth(video_depth depth)
209	>	{
210	>	D(bug("have_visual_for_depth(%d)\n", 1 << depth));
211	>
212	>	// Calculate minimum and maximum supported X depth
213	>	int min_depth = 1, max_depth = 32;
214		switch (depth) {
215	<	case 1:
216	<	layout = FLAYOUT_DIRECT;
215	>	case VDEPTH_1BIT: // 1-bit works always
216	>	min_depth = 1;
217	>	max_depth = 32;
218		break;
219	<	case 8:
220	<	layout = FLAYOUT_DIRECT;
219	>	#ifdef ENABLE_VOSF
220	>	case VDEPTH_2BIT:
221	>	case VDEPTH_4BIT: // VOSF blitters can convert 2/4/8-bit -> 8/16/32-bit
222	>	case VDEPTH_8BIT:
223	>	min_depth = 8;
224	>	max_depth = 32;
225		break;
226	<	case 15:
227	<	layout = FLAYOUT_HOST_555;
226	>	#else
227	>	case VDEPTH_2BIT:
228	>	case VDEPTH_4BIT: // 2/4-bit requires VOSF blitters
229	>	return false;
230	>	case VDEPTH_8BIT: // 8-bit without VOSF requires an 8-bit visual
231	>	min_depth = 8;
232	>	max_depth = 8;
233		break;
234	<	case 16:
235	<	layout = FLAYOUT_HOST_565;
234	>	#endif
235	>	case VDEPTH_16BIT: // 16-bit requires a 15/16-bit visual
236	>	min_depth = 15;
237	>	max_depth = 16;
238		break;
239	<	case 24:
240	<	case 32:
241	<	layout = FLAYOUT_HOST_888;
239	>	case VDEPTH_32BIT: // 32-bit requires a 24/32-bit visual
240	>	min_depth = 24;
241	>	max_depth = 32;
242		break;
243		}
244	+	D(bug(" minimum required X depth is %d, maximum supported X depth is %d\n", min_depth, max_depth));
245	+
246	+	// Try to find a visual for one of the color depths
247	+	bool visual_found = false;
248	+	for (int i=0; i<num_depths && !visual_found; i++) {
249	+
250	+	xdepth = avail_depths[i];
251	+	D(bug(" trying to find visual for depth %d\n", xdepth));
252	+	if (xdepth < min_depth \|\| xdepth > max_depth)
253	+	continue;
254	+
255	+	// Determine best color class for this depth
256	+	switch (xdepth) {
257	+	case 1: // Try StaticGray or StaticColor
258	+	if (XMatchVisualInfo(x_display, screen, xdepth, StaticGray, &visualInfo)
259	+	\|\| XMatchVisualInfo(x_display, screen, xdepth, StaticColor, &visualInfo))
260	+	visual_found = true;
261	+	break;
262	+	case 8: // Need PseudoColor
263	+	if (XMatchVisualInfo(x_display, screen, xdepth, PseudoColor, &visualInfo))
264	+	visual_found = true;
265	+	break;
266	+	case 15:
267	+	case 16:
268	+	case 24:
269	+	case 32: // Try DirectColor first, as this will allow gamma correction
270	+	if (XMatchVisualInfo(x_display, screen, xdepth, DirectColor, &visualInfo)
271	+	\|\| XMatchVisualInfo(x_display, screen, xdepth, TrueColor, &visualInfo))
272	+	visual_found = true;
273	+	break;
274	+	default:
275	+	D(bug(" not a supported depth\n"));
276	+	break;
277	+	}
278	+	}
279	+	if (!visual_found)
280	+	return false;
281	+
282	+	// Visual was found
283	+	vis = visualInfo.visual;
284	+	color_class = visualInfo.c_class;
285	+	D(bug(" found visual ID 0x%02x, depth %d, class ", visualInfo.visualid, xdepth));
286	+	#if DEBUG
287	+	switch (color_class) {
288	+	case StaticGray: D(bug("StaticGray\n")); break;
289	+	case GrayScale: D(bug("GrayScale\n")); break;
290	+	case StaticColor: D(bug("StaticColor\n")); break;
291	+	case PseudoColor: D(bug("PseudoColor\n")); break;
292	+	case TrueColor: D(bug("TrueColor\n")); break;
293	+	case DirectColor: D(bug("DirectColor\n")); break;
294	+	}
295	+	#endif
296	+	}
297	+
298	+	// Add mode to list of supported modes
299	+	static void add_mode(uint32 width, uint32 height, uint32 resolution_id, uint32 bytes_per_row, video_depth depth)
300	+	{
301	+	video_mode mode;
302	+	mode.x = width;
303	+	mode.y = height;
304	+	mode.resolution_id = resolution_id;
305	+	mode.bytes_per_row = bytes_per_row;
306	+	mode.depth = depth;
307	+	VideoModes.push_back(mode);
308	+	}
309	+
310	+	// Add standard list of windowed modes for given color depth
311	+	static void add_window_modes(video_depth depth)
312	+	{
313	+	add_mode(512, 384, 0x80, TrivialBytesPerRow(512, depth), depth);
314	+	add_mode(640, 480, 0x81, TrivialBytesPerRow(640, depth), depth);
315	+	add_mode(800, 600, 0x82, TrivialBytesPerRow(800, depth), depth);
316	+	add_mode(1024, 768, 0x83, TrivialBytesPerRow(1024, depth), depth);
317	+	add_mode(1152, 870, 0x84, TrivialBytesPerRow(1152, depth), depth);
318	+	add_mode(1280, 1024, 0x85, TrivialBytesPerRow(1280, depth), depth);
319	+	add_mode(1600, 1200, 0x86, TrivialBytesPerRow(1600, depth), depth);
320	+	}
321	+
322	+	// Set Mac frame layout and base address (uses the_buffer/MacFrameBaseMac)
323	+	static void set_mac_frame_buffer(video_depth depth, bool native_byte_order)
324	+	{
325	+	#if !REAL_ADDRESSING && !DIRECT_ADDRESSING
326	+	int layout = FLAYOUT_DIRECT;
327	+	if (depth == VDEPTH_16BIT)
328	+	layout = (xdepth == 15) ? FLAYOUT_HOST_555 : FLAYOUT_HOST_565;
329	+	else if (depth == VDEPTH_32BIT)
330	+	layout = (xdepth == 24) ? FLAYOUT_HOST_888 : FLAYOUT_DIRECT;
331		if (native_byte_order)
332		MacFrameLayout = layout;
333		else
334		MacFrameLayout = FLAYOUT_DIRECT;
335	+	VideoMonitor.mac_frame_base = MacFrameBaseMac;
336	+
337	+	// Set variables used by UAE memory banking
338	+	MacFrameBaseHost = the_buffer;
339	+	MacFrameSize = VideoMonitor.mode.bytes_per_row * VideoMonitor.mode.y;
340	+	InitFrameBufferMapping();
341	+	#else
342	+	VideoMonitor.mac_frame_base = Host2MacAddr(the_buffer);
343		#endif
344	<	switch (depth) {
345	<	case 1:
346	<	VideoMonitor.mode = VMODE_1BIT;
347	<	break;
348	<	case 8:
349	<	VideoMonitor.mode = VMODE_8BIT;
350	<	break;
351	<	case 15:
352	<	VideoMonitor.mode = VMODE_16BIT;
353	<	break;
354	<	case 16:
355	<	VideoMonitor.mode = VMODE_16BIT;
356	<	break;
357	<	case 24:
358	<	case 32:
359	<	VideoMonitor.mode = VMODE_32BIT;
360	<	break;
344	>	D(bug("VideoMonitor.mac_frame_base = %08x\n", VideoMonitor.mac_frame_base));
345	>	}
346	>
347	>	// Set window name and class
348	>	static void set_window_name(Window w, int name)
349	>	{
350	>	const char *str = GetString(name);
351	>	XStoreName(x_display, w, str);
352	>	XSetIconName(x_display, w, str);
353	>
354	>	XClassHint *hints;
355	>	hints = XAllocClassHint();
356	>	if (hints) {
357	>	hints->res_name = "BasiliskII";
358	>	hints->res_class = "BasiliskII";
359	>	XSetClassHint(x_display, w, hints);
360	>	XFree(hints);
361		}
362	<	VideoMonitor.x = width;
363	<	VideoMonitor.y = height;
364	<	VideoMonitor.bytes_per_row = bytes_per_row;
362	>	}
363	>
364	>	// Set window input focus flag
365	>	static void set_window_focus(Window w)
366	>	{
367	>	XWMHints *hints = XAllocWMHints();
368	>	if (hints) {
369	>	hints->input = True;
370	>	hints->initial_state = NormalState;
371	>	hints->flags = InputHint \| StateHint;
372	>	XSetWMHints(x_display, w, hints);
373	>	XFree(hints);
374	>	}
375	>	}
376	>
377	>	// Set WM_DELETE_WINDOW protocol on window (preventing it from being destroyed by the WM when clicking on the "close" widget)
378	>	static Atom WM_DELETE_WINDOW = (Atom)0;
379	>	static void set_window_delete_protocol(Window w)
380	>	{
381	>	WM_DELETE_WINDOW = XInternAtom(x_display, "WM_DELETE_WINDOW", false);
382	>	XSetWMProtocols(x_display, w, &WM_DELETE_WINDOW, 1);
383	>	}
384	>
385	>	// Wait until window is mapped/unmapped
386	>	void wait_mapped(Window w)
387	>	{
388	>	XEvent e;
389	>	do {
390	>	XMaskEvent(x_display, StructureNotifyMask, &e);
391	>	} while ((e.type != MapNotify) \|\| (e.xmap.event != w));
392	>	}
393	>
394	>	void wait_unmapped(Window w)
395	>	{
396	>	XEvent e;
397	>	do {
398	>	XMaskEvent(x_display, StructureNotifyMask, &e);
399	>	} while ((e.type != UnmapNotify) \|\| (e.xmap.event != w));
400		}
401
402		// Trap SHM errors
#	Line 310 \| Line 412 \| *static int error_handler(Display d, XEr**
412		return old_error_handler(d, e);
413		}
414
415	<	// Init window mode
416	<	static bool init_window(int width, int height)
415	>
416	>	/*
417	>	* Display "driver" classes
418	>	*/
419	>
420	>	class driver_base {
421	>	public:
422	>	driver_base();
423	>	virtual ~driver_base();
424	>
425	>	virtual void update_palette(void);
426	>	virtual void suspend(void) {}
427	>	virtual void resume(void) {}
428	>	virtual void toggle_mouse_grab(void) {}
429	>	virtual void mouse_moved(int x, int y) { ADBMouseMoved(x, y); }
430	>
431	>	virtual void grab_mouse(void) {}
432	>	virtual void ungrab_mouse(void) {}
433	>
434	>	public:
435	>	bool init_ok; // Initialization succeeded (we can't use exceptions because of -fomit-frame-pointer)
436	>	Window w; // The window we draw into
437	>	};
438	>
439	>	class driver_window;
440	>	static void update_display_window_vosf(driver_window *drv);
441	>	static void update_display_dynamic(int ticker, driver_window *drv);
442	>	static void update_display_static(driver_window *drv);
443	>
444	>	class driver_window : public driver_base {
445	>	friend void update_display_window_vosf(driver_window *drv);
446	>	friend void update_display_dynamic(int ticker, driver_window *drv);
447	>	friend void update_display_static(driver_window *drv);
448	>
449	>	public:
450	>	driver_window(const video_mode &mode);
451	>	~driver_window();
452	>
453	>	void toggle_mouse_grab(void);
454	>	void mouse_moved(int x, int y);
455	>
456	>	void grab_mouse(void);
457	>	void ungrab_mouse(void);
458	>
459	>	private:
460	>	GC gc;
461	>	XImage *img;
462	>	bool have_shm; // Flag: SHM extensions available
463	>	XShmSegmentInfo shminfo;
464	>	Cursor mac_cursor;
465	>	bool mouse_grabbed; // Flag: mouse pointer grabbed, using relative mouse mode
466	>	int mouse_last_x, mouse_last_y; // Last mouse position (for relative mode)
467	>	};
468	>
469	>	static driver_base *drv = NULL; // Pointer to currently used driver object
470	>
471	>	#ifdef ENABLE_VOSF
472	>	# include "video_vosf.h"
473	>	#endif
474	>
475	>	driver_base::driver_base()
476	>	: init_ok(false), w(0)
477	>	{
478	>	the_buffer = NULL;
479	>	the_buffer_copy = NULL;
480	>	}
481	>
482	>	driver_base::~driver_base()
483	>	{
484	>	ungrab_mouse();
485	>
486	>	if (w) {
487	>	XUnmapWindow(x_display, w);
488	>	wait_unmapped(w);
489	>	XDestroyWindow(x_display, w);
490	>	}
491	>
492	>	XFlush(x_display);
493	>	XSync(x_display, false);
494	>
495	>	// Free frame buffer(s)
496	>	if (!use_vosf) {
497	>	if (the_buffer) {
498	>	free(the_buffer);
499	>	the_buffer = NULL;
500	>	}
501	>	if (the_buffer_copy) {
502	>	free(the_buffer_copy);
503	>	the_buffer_copy = NULL;
504	>	}
505	>	}
506	>	#ifdef ENABLE_VOSF
507	>	else {
508	>	if (the_host_buffer) {
509	>	free(the_host_buffer);
510	>	the_host_buffer = NULL;
511	>	}
512	>	if (the_buffer != (uint8 *)VM_MAP_FAILED) {
513	>	vm_release(the_buffer, the_buffer_size);
514	>	the_buffer = NULL;
515	>	}
516	>	if (the_buffer_copy != (uint8 *)VM_MAP_FAILED) {
517	>	vm_release(the_buffer_copy, the_buffer_size);
518	>	the_buffer_copy = NULL;
519	>	}
520	>	}
521	>	#endif
522	>	}
523	>
524	>	// Palette has changed
525	>	void driver_base::update_palette(void)
526	>	{
527	>	if (cmap[0] && cmap[1]) {
528	>	int num = vis->map_entries;
529	>	if (!IsDirectMode(VideoMonitor.mode) && color_class == DirectColor)
530	>	return; // Indexed mode on true color screen, don't set CLUT
531	>	XStoreColors(x_display, cmap[0], palette, num);
532	>	XStoreColors(x_display, cmap[1], palette, num);
533	>	}
534	>	XSync(x_display, false);
535	>	}
536	>
537	>
538	>	/*
539	>	* Windowed display driver
540	>	*/
541	>
542	>	// Open display
543	>	driver_window::driver_window(const video_mode &mode)
544	>	: gc(0), img(NULL), have_shm(false), mouse_grabbed(false), mac_cursor(0)
545		{
546	+	int width = mode.x, height = mode.y;
547		int aligned_width = (width + 15) & ~15;
548		int aligned_height = (height + 15) & ~15;
549
550		// Set absolute mouse mode
551	<	ADBSetRelMouseMode(false);
321	<
322	<	// Read frame skip prefs
323	<	frame_skip = PrefsFindInt32("frameskip");
551	>	ADBSetRelMouseMode(mouse_grabbed);
552
553		// Create window
554		XSetWindowAttributes wattr;
555		wattr.event_mask = eventmask = win_eventmask;
556		wattr.background_pixel = black_pixel;
557	<	wattr.border_pixel = black_pixel;
558	<	wattr.backing_store = NotUseful;
559	<	wattr.save_under = false;
332	<	wattr.backing_planes = xdepth;
557	>	wattr.colormap = (mode.depth == VDEPTH_1BIT && color_class == PseudoColor ? DefaultColormap(x_display, screen) : cmap[0]);
558	>	w = XCreateWindow(x_display, rootwin, 0, 0, width, height, 0, xdepth,
559	>	InputOutput, vis, CWEventMask \| CWBackPixel \| (color_class == PseudoColor \|\| color_class == DirectColor ? CWColormap : 0), &wattr);
560
561	<	XSync(x_display, false);
562	<	the_win = XCreateWindow(x_display, rootwin, 0, 0, width, height, 0, xdepth,
336	<	InputOutput, vis, CWEventMask \| CWBackPixel \| CWBorderPixel \|
337	<	CWBackingStore \| CWBackingPlanes, &wattr);
338	<	XSync(x_display, false);
339	<	XStoreName(x_display, the_win, GetString(STR_WINDOW_TITLE));
340	<	XMapRaised(x_display, the_win);
341	<	XSync(x_display, false);
561	>	// Set window name/class
562	>	set_window_name(w, STR_WINDOW_TITLE);
563
564	<	// Set colormap
565	<	if (depth == 8) {
566	<	XSetWindowColormap(x_display, the_win, cmap[0]);
567	<	XSetWMColormapWindows(x_display, the_win, &the_win, 1);
568	<	}
564	>	// Indicate that we want keyboard input
565	>	set_window_focus(w);
566	>
567	>	// Set delete protocol property
568	>	set_window_delete_protocol(w);
569
570		// Make window unresizable
571	<	XSizeHints *hints;
572	<	if ((hints = XAllocSizeHints()) != NULL) {
573	<	hints->min_width = width;
574	<	hints->max_width = width;
575	<	hints->min_height = height;
576	<	hints->max_height = height;
577	<	hints->flags = PMinSize \| PMaxSize;
578	<	XSetWMNormalHints(x_display, the_win, hints);
579	<	XFree((char *)hints);
571	>	{
572	>	XSizeHints *hints = XAllocSizeHints();
573	>	if (hints) {
574	>	hints->min_width = width;
575	>	hints->max_width = width;
576	>	hints->min_height = height;
577	>	hints->max_height = height;
578	>	hints->flags = PMinSize \| PMaxSize;
579	>	XSetWMNormalHints(x_display, w, hints);
580	>	XFree(hints);
581	>	}
582		}
583
584	+	// Show window
585	+	XMapWindow(x_display, w);
586	+	wait_mapped(w);
587	+
588	+	// 1-bit mode is big-endian; if the X server is little-endian, we can't
589	+	// use SHM because that doesn't allow changing the image byte order
590	+	bool need_msb_image = (mode.depth == VDEPTH_1BIT && XImageByteOrder(x_display) == LSBFirst);
591	+
592		// Try to create and attach SHM image
593	<	have_shm = false;
363	<	if (depth != 1 && local_X11 && XShmQueryExtension(x_display)) {
593	>	if (local_X11 && !need_msb_image && XShmQueryExtension(x_display)) {
594
595		// Create SHM image ("height + 2" for safety)
596	<	img = XShmCreateImage(x_display, vis, depth, depth == 1 ? XYBitmap : ZPixmap, 0, &shminfo, width, height);
596	>	img = XShmCreateImage(x_display, vis, mode.depth == VDEPTH_1BIT ? 1 : xdepth, mode.depth == VDEPTH_1BIT ? XYBitmap : ZPixmap, 0, &shminfo, width, height);
597		shminfo.shmid = shmget(IPC_PRIVATE, (aligned_height + 2) * img->bytes_per_line, IPC_CREAT \| 0777);
598		the_buffer_copy = (uint8 *)shmat(shminfo.shmid, 0, 0);
599		shminfo.shmaddr = img->data = (char *)the_buffer_copy;
#	Line 378 \| Line 608 \| static bool init_window(int width, int h
608		if (shm_error) {
609		shmdt(shminfo.shmaddr);
610		XDestroyImage(img);
611	+	img = NULL;
612		shminfo.shmid = -1;
613		} else {
614		have_shm = true;
#	Line 387 \| Line 618 \| static bool init_window(int width, int h
618
619		// Create normal X image if SHM doesn't work ("height + 2" for safety)
620		if (!have_shm) {
621	<	int bytes_per_row = aligned_width;
391	<	switch (depth) {
392	<	case 1:
393	<	bytes_per_row /= 8;
394	<	break;
395	<	case 15:
396	<	case 16:
397	<	bytes_per_row *= 2;
398	<	break;
399	<	case 24:
400	<	case 32:
401	<	bytes_per_row *= 4;
402	<	break;
403	<	}
621	>	int bytes_per_row = (mode.depth == VDEPTH_1BIT ? aligned_width/8 : TrivialBytesPerRow(aligned_width, DepthModeForPixelDepth(xdepth)));
622		the_buffer_copy = (uint8 )malloc((aligned_height + 2) bytes_per_row);
623	<	img = XCreateImage(x_display, vis, depth, depth == 1 ? XYBitmap : ZPixmap, 0, (char *)the_buffer_copy, aligned_width, aligned_height, 32, bytes_per_row);
623	>	img = XCreateImage(x_display, vis, mode.depth == VDEPTH_1BIT ? 1 : xdepth, mode.depth == VDEPTH_1BIT ? XYBitmap : ZPixmap, 0, (char *)the_buffer_copy, aligned_width, aligned_height, 32, bytes_per_row);
624		}
625
626	<	// 1-Bit mode is big-endian
409	<	if (depth == 1) {
626	>	if (need_msb_image) {
627		img->byte_order = MSBFirst;
628		img->bitmap_bit_order = MSBFirst;
629		}
630
631		#ifdef ENABLE_VOSF
632	<	// Allocate a page-aligned chunk of memory for frame buffer
416	<	the_buffer_size = align_on_page_boundary((aligned_height + 2) * img->bytes_per_line);
632	>	// Allocate memory for frame buffer (SIZE is extended to page-boundary)
633		the_host_buffer = the_buffer_copy;
634	<
635	<	the_buffer_copy = (uint8 *)allocate_framebuffer(the_buffer_size);
636	<	memset(the_buffer_copy, 0, the_buffer_size);
637	<
422	<	the_buffer = (uint8 *)allocate_framebuffer(the_buffer_size);
423	<	memset(the_buffer, 0, the_buffer_size);
634	>	the_buffer_size = page_extend((aligned_height + 2) * img->bytes_per_line);
635	>	the_buffer_copy = (uint8 *)vm_acquire(the_buffer_size);
636	>	the_buffer = (uint8 *)vm_acquire(the_buffer_size);
637	>	D(bug("the_buffer = %p, the_buffer_copy = %p, the_host_buffer = %p\n", the_buffer, the_buffer_copy, the_host_buffer));
638		#else
639		// Allocate memory for frame buffer
640		the_buffer = (uint8 )malloc((aligned_height + 2) img->bytes_per_line);
641	+	D(bug("the_buffer = %p, the_buffer_copy = %p\n", the_buffer, the_buffer_copy));
642		#endif
643
644		// Create GC
645	<	the_gc = XCreateGC(x_display, the_win, 0, 0);
646	<	XSetState(x_display, the_gc, black_pixel, white_pixel, GXcopy, AllPlanes);
645	>	gc = XCreateGC(x_display, w, 0, 0);
646	>	XSetState(x_display, gc, black_pixel, white_pixel, GXcopy, AllPlanes);
647
648		// Create no_cursor
649		mac_cursor = XCreatePixmapCursor(x_display,
650	<	XCreatePixmap(x_display, the_win, 1, 1, 1),
651	<	XCreatePixmap(x_display, the_win, 1, 1, 1),
650	>	XCreatePixmap(x_display, w, 1, 1, 1),
651	>	XCreatePixmap(x_display, w, 1, 1, 1),
652		&black, &white, 0, 0);
653	<	XDefineCursor(x_display, the_win, mac_cursor);
653	>	XDefineCursor(x_display, w, mac_cursor);
654
655	<	// Set VideoMonitor
655	>	// Init blitting routines
656		bool native_byte_order;
657		#ifdef WORDS_BIGENDIAN
658	<	native_byte_order = (img->bitmap_bit_order == MSBFirst);
658	>	native_byte_order = (XImageByteOrder(x_display) == MSBFirst);
659		#else
660	<	native_byte_order = (img->bitmap_bit_order == LSBFirst);
660	>	native_byte_order = (XImageByteOrder(x_display) == LSBFirst);
661		#endif
662		#ifdef ENABLE_VOSF
663	<	do_update_framebuffer = GET_FBCOPY_FUNC(depth, native_byte_order, DISPLAY_WINDOW);
663	>	Screen_blitter_init(&visualInfo, native_byte_order, mode.depth);
664		#endif
665	<	set_video_monitor(width, height, img->bytes_per_line, native_byte_order);
666	<
667	<	#if REAL_ADDRESSING \|\| DIRECT_ADDRESSING
668	<	VideoMonitor.mac_frame_base = Host2MacAddr(the_buffer);
665	>
666	>	// Set VideoMonitor
667	>	VideoMonitor.mode = mode;
668	>	set_mac_frame_buffer(mode.depth, native_byte_order);
669	>
670	>	// Everything went well
671	>	init_ok = true;
672	>	}
673	>
674	>	// Close display
675	>	driver_window::~driver_window()
676	>	{
677	>	if (have_shm) {
678	>	XShmDetach(x_display, &shminfo);
679	>	#ifdef ENABLE_VOSF
680	>	the_host_buffer = NULL; // don't free() in driver_base dtor
681		#else
682	<	VideoMonitor.mac_frame_base = MacFrameBaseMac;
682	>	the_buffer_copy = NULL; // don't free() in driver_base dtor
683		#endif
684	<	return true;
684	>	}
685	>	if (img)
686	>	XDestroyImage(img);
687	>	if (have_shm) {
688	>	shmdt(shminfo.shmaddr);
689	>	shmctl(shminfo.shmid, IPC_RMID, 0);
690	>	}
691	>	if (gc)
692	>	XFreeGC(x_display, gc);
693	>	}
694	>
695	>	// Toggle mouse grab
696	>	void driver_window::toggle_mouse_grab(void)
697	>	{
698	>	if (mouse_grabbed)
699	>	ungrab_mouse();
700	>	else
701	>	grab_mouse();
702	>	}
703	>
704	>	// Grab mouse, switch to relative mouse mode
705	>	void driver_window::grab_mouse(void)
706	>	{
707	>	int result;
708	>	for (int i=0; i<10; i++) {
709	>	result = XGrabPointer(x_display, w, True, 0,
710	>	GrabModeAsync, GrabModeAsync, w, None, CurrentTime);
711	>	if (result != AlreadyGrabbed)
712	>	break;
713	>	Delay_usec(100000);
714	>	}
715	>	if (result == GrabSuccess) {
716	>	ADBSetRelMouseMode(mouse_grabbed = true);
717	>	XStoreName(x_display, w, GetString(STR_WINDOW_TITLE_GRABBED));
718	>	XSync(x_display, false);
719	>	}
720	>	}
721	>
722	>	// Ungrab mouse, switch to absolute mouse mode
723	>	void driver_window::ungrab_mouse(void)
724	>	{
725	>	if (mouse_grabbed) {
726	>	XUngrabPointer(x_display, CurrentTime);
727	>	XStoreName(x_display, w, GetString(STR_WINDOW_TITLE));
728	>	ADBSetRelMouseMode(mouse_grabbed = false);
729	>	}
730	>	}
731	>
732	>	// Mouse moved
733	>	void driver_window::mouse_moved(int x, int y)
734	>	{
735	>	if (!mouse_grabbed) {
736	>	mouse_last_x = x; mouse_last_y = y;
737	>	ADBMouseMoved(x, y);
738	>	return;
739	>	}
740	>
741	>	// Warped mouse motion (this code is taken from SDL)
742	>
743	>	// Post first mouse event
744	>	int width = VideoMonitor.mode.x, height = VideoMonitor.mode.y;
745	>	int delta_x = x - mouse_last_x, delta_y = y - mouse_last_y;
746	>	mouse_last_x = x; mouse_last_y = y;
747	>	ADBMouseMoved(delta_x, delta_y);
748	>
749	>	// Only warp the pointer when it has reached the edge
750	>	const int MOUSE_FUDGE_FACTOR = 8;
751	>	if (x < MOUSE_FUDGE_FACTOR \|\| x > (width - MOUSE_FUDGE_FACTOR)
752	>	\|\| y < MOUSE_FUDGE_FACTOR \|\| y > (height - MOUSE_FUDGE_FACTOR)) {
753	>	XEvent event;
754	>	while (XCheckTypedEvent(x_display, MotionNotify, &event)) {
755	>	delta_x = x - mouse_last_x; delta_y = y - mouse_last_y;
756	>	mouse_last_x = x; mouse_last_y = y;
757	>	ADBMouseMoved(delta_x, delta_y);
758	>	}
759	>	mouse_last_x = width/2;
760	>	mouse_last_y = height/2;
761	>	XWarpPointer(x_display, None, w, 0, 0, 0, 0, mouse_last_x, mouse_last_y);
762	>	for (int i=0; i<10; i++) {
763	>	XMaskEvent(x_display, PointerMotionMask, &event);
764	>	if (event.xmotion.x > (mouse_last_x - MOUSE_FUDGE_FACTOR)
765	>	&& event.xmotion.x < (mouse_last_x + MOUSE_FUDGE_FACTOR)
766	>	&& event.xmotion.y > (mouse_last_y - MOUSE_FUDGE_FACTOR)
767	>	&& event.xmotion.y < (mouse_last_y + MOUSE_FUDGE_FACTOR))
768	>	break;
769	>	}
770	>	}
771	>	}
772	>
773	>
774	>	#if defined(ENABLE_XF86_DGA) \|\| defined(ENABLE_FBDEV_DGA)
775	>	/*
776	>	* DGA display driver base class
777	>	*/
778	>
779	>	class driver_dga : public driver_base {
780	>	public:
781	>	driver_dga();
782	>	~driver_dga();
783	>
784	>	void suspend(void);
785	>	void resume(void);
786	>
787	>	private:
788	>	Window suspend_win; // "Suspend" information window
789	>	void *fb_save; // Saved frame buffer for suspend/resume
790	>	};
791	>
792	>	driver_dga::driver_dga()
793	>	: suspend_win(0), fb_save(NULL)
794	>	{
795	>	}
796	>
797	>	driver_dga::~driver_dga()
798	>	{
799	>	XUngrabPointer(x_display, CurrentTime);
800	>	XUngrabKeyboard(x_display, CurrentTime);
801	>	}
802	>
803	>	// Suspend emulation
804	>	void driver_dga::suspend(void)
805	>	{
806	>	// Release ctrl key
807	>	ADBKeyUp(0x36);
808	>	ctrl_down = false;
809	>
810	>	// Lock frame buffer (this will stop the MacOS thread)
811	>	LOCK_FRAME_BUFFER;
812	>
813	>	// Save frame buffer
814	>	fb_save = malloc(VideoMonitor.mode.y * VideoMonitor.mode.bytes_per_row);
815	>	if (fb_save)
816	>	memcpy(fb_save, the_buffer, VideoMonitor.mode.y * VideoMonitor.mode.bytes_per_row);
817	>
818	>	// Close full screen display
819	>	#ifdef ENABLE_XF86_DGA
820	>	XF86DGADirectVideo(x_display, screen, 0);
821	>	#endif
822	>	XUngrabPointer(x_display, CurrentTime);
823	>	XUngrabKeyboard(x_display, CurrentTime);
824	>	XUnmapWindow(x_display, w);
825	>	wait_unmapped(w);
826	>
827	>	// Open "suspend" window
828	>	XSetWindowAttributes wattr;
829	>	wattr.event_mask = KeyPressMask;
830	>	wattr.background_pixel = black_pixel;
831	>
832	>	suspend_win = XCreateWindow(x_display, rootwin, 0, 0, 512, 1, 0, xdepth,
833	>	InputOutput, vis, CWEventMask \| CWBackPixel, &wattr);
834	>	set_window_name(suspend_win, STR_SUSPEND_WINDOW_TITLE);
835	>	set_window_focus(suspend_win);
836	>	XMapWindow(x_display, suspend_win);
837	>	emul_suspended = true;
838		}
839
840	<	// Init fbdev DGA display
841	<	static bool init_fbdev_dga(char *in_fb_name)
840	>	// Resume emulation
841	>	void driver_dga::resume(void)
842		{
843	+	// Close "suspend" window
844	+	XDestroyWindow(x_display, suspend_win);
845	+	XSync(x_display, false);
846	+
847	+	// Reopen full screen display
848	+	XMapRaised(x_display, w);
849	+	wait_mapped(w);
850	+	XWarpPointer(x_display, None, rootwin, 0, 0, 0, 0, 0, 0);
851	+	XGrabKeyboard(x_display, rootwin, True, GrabModeAsync, GrabModeAsync, CurrentTime);
852	+	XGrabPointer(x_display, rootwin, True, PointerMotionMask \| ButtonPressMask \| ButtonReleaseMask, GrabModeAsync, GrabModeAsync, None, None, CurrentTime);
853	+	#ifdef ENABLE_XF86_DGA
854	+	XF86DGADirectVideo(x_display, screen, XF86DGADirectGraphics \| XF86DGADirectKeyb \| XF86DGADirectMouse);
855	+	XF86DGASetViewPort(x_display, screen, 0, 0);
856	+	#endif
857	+	XSync(x_display, false);
858	+
859	+	// the_buffer already contains the data to restore. i.e. since a temporary
860	+	// frame buffer is used when VOSF is actually used, fb_save is therefore
861	+	// not necessary.
862	+	#ifdef ENABLE_VOSF
863	+	if (use_vosf) {
864	+	LOCK_VOSF;
865	+	PFLAG_SET_ALL;
866	+	UNLOCK_VOSF;
867	+	memset(the_buffer_copy, 0, VideoMonitor.mode.bytes_per_row * VideoMonitor.mode.y);
868	+	}
869	+	#endif
870	+
871	+	// Restore frame buffer
872	+	if (fb_save) {
873	+	#ifdef ENABLE_VOSF
874	+	// Don't copy fb_save to the temporary frame buffer in VOSF mode
875	+	if (!use_vosf)
876	+	#endif
877	+	memcpy(the_buffer, fb_save, VideoMonitor.mode.y * VideoMonitor.mode.bytes_per_row);
878	+	free(fb_save);
879	+	fb_save = NULL;
880	+	}
881	+
882	+	// Unlock frame buffer (and continue MacOS thread)
883	+	UNLOCK_FRAME_BUFFER;
884	+	emul_suspended = false;
885	+	}
886	+	#endif
887	+
888	+
889		#ifdef ENABLE_FBDEV_DGA
890	+	/*
891	+	* fbdev DGA display driver
892	+	*/
893	+
894	+	const char FBDEVICES_FILE_NAME[] = DATADIR "/fbdevices";
895	+	const char FBDEVICE_FILE_NAME[] = "/dev/fb";
896	+
897	+	class driver_fbdev : public driver_dga {
898	+	public:
899	+	driver_fbdev(const video_mode &mode);
900	+	~driver_fbdev();
901	+	};
902	+
903	+	// Open display
904	+	driver_fbdev::driver_fbdev(const video_mode &mode)
905	+	{
906	+	int width = mode.x, height = mode.y;
907	+
908	+	// Set absolute mouse mode
909	+	ADBSetRelMouseMode(false);
910	+
911		// Find the maximum depth available
912		int ndepths, max_depth(0);
913		int *depths = XListDepths(x_display, screen, &ndepths);
914		if (depths == NULL) {
915		printf("FATAL: Could not determine the maximal depth available\n");
916	<	return false;
916	>	return;
917		} else {
918		while (ndepths-- > 0) {
919		if (depths[ndepths] > max_depth)
#	Line 483 \| Line 930 \| *static bool init_fbdev_dga(char in_fb_n**
930		char str[256];
931		sprintf(str, GetString(STR_NO_FBDEVICE_FILE_ERR), fbd_path ? fbd_path : FBDEVICES_FILE_NAME, strerror(errno));
932		ErrorAlert(str);
933	<	return false;
933	>	return;
934		}
935
936		int fb_depth; // supported depth
#	Line 503 \| Line 950 \| *static bool init_fbdev_dga(char in_fb_n**
950		continue;
951
952		if ((sscanf(line, "%19s %d %x", &fb_name, &fb_depth, &fb_offset) == 3)
953	<	&& (strcmp(fb_name, in_fb_name) == 0) && (fb_depth == max_depth)) {
953	>	&& (strcmp(fb_name, fb_name) == 0) && (fb_depth == max_depth)) {
954		device_found = true;
955		break;
956		}
#	Line 515 \| Line 962 \| *static bool init_fbdev_dga(char in_fb_n**
962		// Frame buffer name not found ? Then, display warning
963		if (!device_found) {
964		char str[256];
965	<	sprintf(str, GetString(STR_FBDEV_NAME_ERR), in_fb_name, max_depth);
965	>	sprintf(str, GetString(STR_FBDEV_NAME_ERR), fb_name, max_depth);
966		ErrorAlert(str);
967	<	return false;
967	>	return;
968		}
969
523	–	int width = DisplayWidth(x_display, screen);
524	–	int height = DisplayHeight(x_display, screen);
525	–	depth = fb_depth; // max_depth
526	–
527	–	// Set relative mouse mode
528	–	ADBSetRelMouseMode(false);
529	–
970		// Create window
971		XSetWindowAttributes wattr;
972	<	wattr.override_redirect = True;
973	<	wattr.backing_store = NotUseful;
974	<	wattr.background_pixel = white_pixel;
975	<	wattr.border_pixel = black_pixel;
536	<	wattr.event_mask = eventmask = dga_eventmask;
972	>	wattr.event_mask = eventmask = dga_eventmask;
973	>	wattr.background_pixel = white_pixel;
974	>	wattr.override_redirect = True;
975	>	wattr.colormap = cmap[0];
976
977	<	XSync(x_display, false);
539	<	the_win = XCreateWindow(x_display, rootwin,
977	>	w = XCreateWindow(x_display, rootwin,
978		0, 0, width, height,
979		0, xdepth, InputOutput, vis,
980	<	CWEventMask\|CWBackPixel\|CWBorderPixel\|CWOverrideRedirect\|CWBackingStore,
980	>	CWEventMask \| CWBackPixel \| CWOverrideRedirect \| (fb_depth <= 8 ? CWColormap : 0),
981		&wattr);
982	<	XSync(x_display, false);
983	<	XMapRaised(x_display, the_win);
984	<	XSync(x_display, false);
982	>
983	>	// Set window name/class
984	>	set_window_name(w, STR_WINDOW_TITLE);
985	>
986	>	// Indicate that we want keyboard input
987	>	set_window_focus(w);
988	>
989	>	// Show window
990	>	XMapRaised(x_display, w);
991	>	wait_mapped(w);
992
993		// Grab mouse and keyboard
994	<	XGrabKeyboard(x_display, the_win, True,
994	>	XGrabKeyboard(x_display, w, True,
995		GrabModeAsync, GrabModeAsync, CurrentTime);
996	<	XGrabPointer(x_display, the_win, True,
996	>	XGrabPointer(x_display, w, True,
997		PointerMotionMask \| ButtonPressMask \| ButtonReleaseMask,
998	<	GrabModeAsync, GrabModeAsync, the_win, None, CurrentTime);
554	<
555	<	// Set colormap
556	<	if (depth == 8) {
557	<	XSetWindowColormap(x_display, the_win, cmap[0]);
558	<	XSetWMColormapWindows(x_display, the_win, &the_win, 1);
559	<	}
998	>	GrabModeAsync, GrabModeAsync, w, None, CurrentTime);
999
1000	<	// Set VideoMonitor
1001	<	int bytes_per_row = width;
563	<	switch (depth) {
564	<	case 1:
565	<	bytes_per_row = ((width \| 7) & ~7) >> 3;
566	<	break;
567	<	case 15:
568	<	case 16:
569	<	bytes_per_row *= 2;
570	<	break;
571	<	case 24:
572	<	case 32:
573	<	bytes_per_row *= 4;
574	<	break;
575	<	}
1000	>	// Calculate bytes per row
1001	>	int bytes_per_row = TrivialBytesPerRow(mode.x, mode.depth);
1002
1003	+	// Map frame buffer
1004		if ((the_buffer = (uint8 ) mmap(NULL, height bytes_per_row, PROT_READ \| PROT_WRITE, MAP_PRIVATE, fbdev_fd, fb_offset)) == MAP_FAILED) {
1005		if ((the_buffer = (uint8 ) mmap(NULL, height bytes_per_row, PROT_READ \| PROT_WRITE, MAP_SHARED, fbdev_fd, fb_offset)) == MAP_FAILED) {
1006		char str[256];
1007		sprintf(str, GetString(STR_FBDEV_MMAP_ERR), strerror(errno));
1008		ErrorAlert(str);
1009	<	return false;
1009	>	return;
1010		}
1011		}
1012
1013	+	#if ENABLE_VOSF
1014		#if REAL_ADDRESSING \|\| DIRECT_ADDRESSING
1015	<	// If the blit function is null, i.e. just a copy of the buffer,
1016	<	// we first try to avoid the allocation of a temporary frame buffer
1017	<	use_vosf = true;
590	<	do_update_framebuffer = GET_FBCOPY_FUNC(depth, true, DISPLAY_DGA);
591	<	if (do_update_framebuffer == FBCOPY_FUNC(fbcopy_raw))
592	<	use_vosf = false;
1015	>	// Screen_blitter_init() returns TRUE if VOSF is mandatory
1016	>	// i.e. the framebuffer update function is not Blit_Copy_Raw
1017	>	use_vosf = Screen_blitter_init(&visualInfo, true, mode.depth);
1018
1019		if (use_vosf) {
1020	<	the_host_buffer = the_buffer;
1021	<	the_buffer_size = align_on_page_boundary((height + 2) * bytes_per_row);
1022	<	the_buffer_copy = (uint8 *)malloc(the_buffer_size);
1023	<	memset(the_buffer_copy, 0, the_buffer_size);
1024	<	the_buffer = (uint8 *)allocate_framebuffer(the_buffer_size);
600	<	memset(the_buffer, 0, the_buffer_size);
1020	>	// Allocate memory for frame buffer (SIZE is extended to page-boundary)
1021	>	the_host_buffer = the_buffer;
1022	>	the_buffer_size = page_extend((height + 2) * bytes_per_row);
1023	>	the_buffer_copy = (uint8 *)vm_acquire(the_buffer_size);
1024	>	the_buffer = (uint8 *)vm_acquire(the_buffer_size);
1025		}
602	–	#elif ENABLE_VOSF
603	–	use_vosf = false;
604	–	#endif
605	–
606	–	set_video_monitor(width, height, bytes_per_row, true);
607	–	#if REAL_ADDRESSING \|\| DIRECT_ADDRESSING
608	–	VideoMonitor.mac_frame_base = Host2MacAddr(the_buffer);
1026		#else
1027	<	VideoMonitor.mac_frame_base = MacFrameBaseMac;
1027	>	use_vosf = false;
1028		#endif
612	–	return true;
613	–	#else
614	–	ErrorAlert("Basilisk II has been compiled with fbdev DGA support disabled.");
615	–	return false;
1029		#endif
1030	+
1031	+	// Set VideoMonitor
1032	+	VideoModes[0].bytes_per_row = bytes_per_row;
1033	+	VideoModes[0].depth = DepthModeForPixelDepth(fb_depth);
1034	+	VideoMonitor.mode = mode;
1035	+	set_mac_frame_buffer(mode.depth, true);
1036	+
1037	+	// Everything went well
1038	+	init_ok = true;
1039		}
1040
1041	<	// Init XF86 DGA display
1042	<	static bool init_xf86_dga(int width, int height)
1041	>	// Close display
1042	>	driver_fbdev::~driver_fbdev()
1043		{
1044	+	}
1045	+	#endif
1046	+
1047	+
1048		#ifdef ENABLE_XF86_DGA
1049	+	/*
1050	+	* XFree86 DGA display driver
1051	+	*/
1052	+
1053	+	class driver_xf86dga : public driver_dga {
1054	+	public:
1055	+	driver_xf86dga(const video_mode &mode);
1056	+	~driver_xf86dga();
1057	+
1058	+	void update_palette(void);
1059	+	void resume(void);
1060	+
1061	+	private:
1062	+	int current_dga_cmap; // Number (0 or 1) of currently installed DGA colormap
1063	+	};
1064	+
1065	+	// Open display
1066	+	driver_xf86dga::driver_xf86dga(const video_mode &mode)
1067	+	: current_dga_cmap(0)
1068	+	{
1069	+	int width = mode.x, height = mode.y;
1070	+
1071		// Set relative mouse mode
1072		ADBSetRelMouseMode(true);
1073
#	Line 635 \| Line 1083 \| static bool init_xf86_dga(int width, int
1083		}
1084		XF86VidModeSwitchToMode(x_display, screen, x_video_modes[best]);
1085		XF86VidModeSetViewPort(x_display, screen, 0, 0);
1086	+	XSync(x_display, false);
1087		}
1088		#endif
1089
1090		// Create window
1091		XSetWindowAttributes wattr;
1092		wattr.event_mask = eventmask = dga_eventmask;
644	–	wattr.border_pixel = black_pixel;
1093		wattr.override_redirect = True;
1094
1095	<	XSync(x_display, false);
1096	<	the_win = XCreateWindow(x_display, rootwin, 0, 0, width, height, 0, xdepth,
1097	<	InputOutput, vis, CWEventMask \| CWBorderPixel \| CWOverrideRedirect, &wattr);
1098	<	XSync(x_display, false);
1099	<	XStoreName(x_display, the_win, GetString(STR_WINDOW_TITLE));
1100	<	XMapRaised(x_display, the_win);
1101	<	XSync(x_display, false);
1095	>	w = XCreateWindow(x_display, rootwin, 0, 0, width, height, 0, xdepth,
1096	>	InputOutput, vis, CWEventMask \| CWOverrideRedirect, &wattr);
1097	>
1098	>	// Set window name/class
1099	>	set_window_name(w, STR_WINDOW_TITLE);
1100	>
1101	>	// Indicate that we want keyboard input
1102	>	set_window_focus(w);
1103	>
1104	>	// Show window
1105	>	XMapRaised(x_display, w);
1106	>	wait_mapped(w);
1107
1108		// Establish direct screen connection
1109	<	XMoveResizeWindow(x_display, the_win, 0, 0, width, height);
1109	>	XMoveResizeWindow(x_display, w, 0, 0, width, height);
1110		XWarpPointer(x_display, None, rootwin, 0, 0, 0, 0, 0, 0);
1111		XGrabKeyboard(x_display, rootwin, True, GrabModeAsync, GrabModeAsync, CurrentTime);
1112		XGrabPointer(x_display, rootwin, True, PointerMotionMask \| ButtonPressMask \| ButtonReleaseMask, GrabModeAsync, GrabModeAsync, None, None, CurrentTime);
#	Line 665 \| Line 1118 \| static bool init_xf86_dga(int width, int
1118		XF86DGASetVidPage(x_display, screen, 0);
1119
1120		// Set colormap
1121	<	if (depth == 8) {
1122	<	XSetWindowColormap(x_display, the_win, cmap[current_dga_cmap = 0]);
670	<	XSetWMColormapWindows(x_display, the_win, &the_win, 1);
1121	>	if (!IsDirectMode(mode)) {
1122	>	XSetWindowColormap(x_display, w, cmap[current_dga_cmap = 0]);
1123		XF86DGAInstallColormap(x_display, screen, cmap[current_dga_cmap]);
1124		}
1125	+	XSync(x_display, false);
1126
1127	<	// Set VideoMonitor
1128	<	int bytes_per_row = (v_width + 7) & ~7;
1129	<	switch (depth) {
677	<	case 1:
678	<	bytes_per_row /= 8;
679	<	break;
680	<	case 15:
681	<	case 16:
682	<	bytes_per_row *= 2;
683	<	break;
684	<	case 24:
685	<	case 32:
686	<	bytes_per_row *= 4;
687	<	break;
688	<	}
689	<
1127	>	// Init blitting routines
1128	>	int bytes_per_row = TrivialBytesPerRow((v_width + 7) & ~7, mode.depth);
1129	>	#ifdef VIDEO_VOSF
1130		#if REAL_ADDRESSING \|\| DIRECT_ADDRESSING
1131	<	// If the blit function is null, i.e. just a copy of the buffer,
1132	<	// we first try to avoid the allocation of a temporary frame buffer
1133	<	use_vosf = true;
694	<	do_update_framebuffer = GET_FBCOPY_FUNC(depth, true, DISPLAY_DGA);
695	<	if (do_update_framebuffer == FBCOPY_FUNC(fbcopy_raw))
696	<	use_vosf = false;
1131	>	// Screen_blitter_init() returns TRUE if VOSF is mandatory
1132	>	// i.e. the framebuffer update function is not Blit_Copy_Raw
1133	>	use_vosf = Screen_blitter_init(&visualInfo, true, mode.depth);
1134
1135		if (use_vosf) {
1136	<	the_host_buffer = the_buffer;
1137	<	the_buffer_size = align_on_page_boundary((height + 2) * bytes_per_row);
1138	<	the_buffer_copy = (uint8 *)malloc(the_buffer_size);
1139	<	memset(the_buffer_copy, 0, the_buffer_size);
1140	<	the_buffer = (uint8 *)allocate_framebuffer(the_buffer_size);
704	<	memset(the_buffer, 0, the_buffer_size);
1136	>	// Allocate memory for frame buffer (SIZE is extended to page-boundary)
1137	>	the_host_buffer = the_buffer;
1138	>	the_buffer_size = page_extend((height + 2) * bytes_per_row);
1139	>	the_buffer_copy = (uint8 *)vm_acquire(the_buffer_size);
1140	>	the_buffer = (uint8 *)vm_acquire(the_buffer_size);
1141		}
1142	<	#elif defined(ENABLE_VOSF)
707	<	// The UAE memory handlers will already handle color conversion, if needed.
1142	>	#else
1143		use_vosf = false;
1144		#endif
710	–
711	–	set_video_monitor(width, height, bytes_per_row, true);
712	–	#if REAL_ADDRESSING \|\| DIRECT_ADDRESSING
713	–	VideoMonitor.mac_frame_base = Host2MacAddr(the_buffer);
714	–	// MacFrameLayout = FLAYOUT_DIRECT;
715	–	#else
716	–	VideoMonitor.mac_frame_base = MacFrameBaseMac;
1145		#endif
1146	<	return true;
1147	<	#else
1148	<	ErrorAlert("Basilisk II has been compiled with XF86 DGA support disabled.");
1149	<	return false;
1146	>
1147	>	// Set VideoMonitor
1148	>	const_cast<video_mode *>(&mode)->bytes_per_row = bytes_per_row;
1149	>	VideoMonitor.mode = mode;
1150	>	set_mac_frame_buffer(mode.depth, true);
1151	>
1152	>	// Everything went well
1153	>	init_ok = true;
1154	>	}
1155	>
1156	>	// Close display
1157	>	driver_xf86dga::~driver_xf86dga()
1158	>	{
1159	>	XF86DGADirectVideo(x_display, screen, 0);
1160	>	#ifdef ENABLE_XF86_VIDMODE
1161	>	if (has_vidmode)
1162	>	XF86VidModeSwitchToMode(x_display, screen, x_video_modes[0]);
1163		#endif
1164		}
1165
1166	+	// Palette has changed
1167	+	void driver_xf86dga::update_palette(void)
1168	+	{
1169	+	driver_dga::update_palette();
1170	+	current_dga_cmap ^= 1;
1171	+	if (!IsDirectMode(VideoMonitor.mode) && cmap[current_dga_cmap])
1172	+	XF86DGAInstallColormap(x_display, screen, cmap[current_dga_cmap]);
1173	+	}
1174	+
1175	+	// Resume emulation
1176	+	void driver_xf86dga::resume(void)
1177	+	{
1178	+	driver_dga::resume();
1179	+	if (!IsDirectMode(VideoMonitor.mode))
1180	+	XF86DGAInstallColormap(x_display, screen, cmap[current_dga_cmap]);
1181	+	}
1182	+	#endif
1183	+
1184	+
1185	+	/*
1186	+	* Initialization
1187	+	*/
1188	+
1189		// Init keycode translation table
1190		static void keycode_init(void)
1191		{
#	Line 787 \| Line 1251 \| static void keycode_init(void)
1251		}
1252		}
1253
1254	<	bool VideoInitBuffer()
1254	>	// Open display for specified mode
1255	>	static bool video_open(const video_mode &mode)
1256		{
1257	<	#ifdef ENABLE_VOSF
1258	<	if (use_vosf) {
1259	<	const uint32 page_size = getpagesize();
1260	<	const uint32 page_mask = page_size - 1;
1261	<
797	<	mainBuffer.memBase = (uint32) the_buffer;
798	<	// Align the frame buffer on page boundary
799	<	mainBuffer.memStart = (uint32)((((unsigned long) the_buffer) + page_mask) & ~page_mask);
800	<	mainBuffer.memLength = the_buffer_size;
801	<	mainBuffer.memEnd = mainBuffer.memStart + mainBuffer.memLength;
802	<
803	<	mainBuffer.pageSize = page_size;
804	<	mainBuffer.pageCount = (mainBuffer.memLength + page_mask)/mainBuffer.pageSize;
805	<	mainBuffer.pageBits = int( log(mainBuffer.pageSize) / log(2.0) );
806	<
807	<	if (mainBuffer.dirtyPages != 0)
808	<	free(mainBuffer.dirtyPages);
1257	>	// Find best available X visual
1258	>	if (!find_visual_for_depth(mode.depth)) {
1259	>	ErrorAlert(STR_NO_XVISUAL_ERR);
1260	>	return false;
1261	>	}
1262
1263	<	mainBuffer.dirtyPages = (uint8 *) malloc(mainBuffer.pageCount);
1263	>	// Create color maps
1264	>	if (color_class == PseudoColor \|\| color_class == DirectColor) {
1265	>	cmap[0] = XCreateColormap(x_display, rootwin, vis, AllocAll);
1266	>	cmap[1] = XCreateColormap(x_display, rootwin, vis, AllocAll);
1267	>	}
1268
1269	<	if (mainBuffer.pageInfo != 0)
1270	<	free(mainBuffer.pageInfo);
1269	>	// Find pixel format of direct modes
1270	>	if (color_class == DirectColor \|\| color_class == TrueColor) {
1271	>	rshift = gshift = bshift = 0;
1272	>	rloss = gloss = bloss = 8;
1273	>	uint32 mask;
1274	>	for (mask=vis->red_mask; !(mask&1); mask>>=1)
1275	>	++rshift;
1276	>	for (; mask&1; mask>>=1)
1277	>	--rloss;
1278	>	for (mask=vis->green_mask; !(mask&1); mask>>=1)
1279	>	++gshift;
1280	>	for (; mask&1; mask>>=1)
1281	>	--gloss;
1282	>	for (mask=vis->blue_mask; !(mask&1); mask>>=1)
1283	>	++bshift;
1284	>	for (; mask&1; mask>>=1)
1285	>	--bloss;
1286	>	}
1287	>
1288	>	// Preset palette pixel values for gamma table
1289	>	if (color_class == DirectColor) {
1290	>	int num = vis->map_entries;
1291	>	for (int i=0; i<num; i++) {
1292	>	int c = (i * 256) / num;
1293	>	palette[i].pixel = map_rgb(c, c, c);
1294	>	}
1295	>	}
1296
1297	<	mainBuffer.pageInfo = (ScreenPageInfo ) malloc(mainBuffer.pageCount sizeof(ScreenPageInfo));
1297	>	// Load gray ramp to color map
1298	>	int num = (color_class == DirectColor ? vis->map_entries : 256);
1299	>	for (int i=0; i<num; i++) {
1300	>	int c = (i * 256) / num;
1301	>	palette[i].red = c * 0x0101;
1302	>	palette[i].green = c * 0x0101;
1303	>	palette[i].blue = c * 0x0101;
1304	>	if (color_class == PseudoColor)
1305	>	palette[i].pixel = i;
1306	>	palette[i].flags = DoRed \| DoGreen \| DoBlue;
1307	>	}
1308	>	if (cmap[0] && cmap[1]) {
1309	>	XStoreColors(x_display, cmap[0], palette, num);
1310	>	XStoreColors(x_display, cmap[1], palette, num);
1311	>	}
1312
1313	<	if ((mainBuffer.dirtyPages == 0) \|\| (mainBuffer.pageInfo == 0))
1314	<	return false;
1313	>	#ifdef ENABLE_VOSF
1314	>	// Load gray ramp to 8->16/32 expand map
1315	>	if (!IsDirectMode(mode) && (color_class == TrueColor \|\| color_class == DirectColor))
1316	>	for (int i=0; i<256; i++)
1317	>	ExpandMap[i] = map_rgb(i, i, i);
1318	>	#endif
1319
1320	<	PFLAG_CLEAR_ALL;
1320	>	// Create display driver object of requested type
1321	>	switch (display_type) {
1322	>	case DISPLAY_WINDOW:
1323	>	drv = new driver_window(mode);
1324	>	break;
1325	>	#ifdef ENABLE_FBDEV_DGA
1326	>	case DISPLAY_DGA:
1327	>	drv = new driver_fbdev(mode);
1328	>	break;
1329	>	#endif
1330	>	#ifdef ENABLE_XF86_DGA
1331	>	case DISPLAY_DGA:
1332	>	drv = new driver_xf86dga(mode);
1333	>	break;
1334	>	#endif
1335	>	}
1336	>	if (drv == NULL)
1337	>	return false;
1338	>	if (!drv->init_ok) {
1339	>	delete drv;
1340	>	drv = NULL;
1341	>	return false;
1342	>	}
1343
1344	<	uint32 a = 0;
1345	<	for (int i = 0; i < mainBuffer.pageCount; i++) {
1346	<	int y1 = a / VideoMonitor.bytes_per_row;
1347	<	if (y1 >= VideoMonitor.y)
1348	<	y1 = VideoMonitor.y - 1;
1349	<
828	<	int y2 = (a + mainBuffer.pageSize) / VideoMonitor.bytes_per_row;
829	<	if (y2 >= VideoMonitor.y)
830	<	y2 = VideoMonitor.y - 1;
831	<
832	<	mainBuffer.pageInfo[i].top = y1;
833	<	mainBuffer.pageInfo[i].bottom = y2;
834	<
835	<	a += mainBuffer.pageSize;
836	<	if (a > mainBuffer.memLength)
837	<	a = mainBuffer.memLength;
1344	>	#ifdef ENABLE_VOSF
1345	>	if (use_vosf) {
1346	>	// Initialize the mainBuffer structure
1347	>	if (!video_init_buffer()) {
1348	>	ErrorAlert(STR_VOSF_INIT_ERR);
1349	>	return false;
1350		}
1351	<
1352	<	// We can now write-protect the frame buffer
1353	<	if (mprotect((caddr_t)mainBuffer.memStart, mainBuffer.memLength, PROT_READ) != 0)
1351	>
1352	>	// Initialize the handler for SIGSEGV
1353	>	if (!sigsegv_install_handler(screen_fault_handler)) {
1354	>	ErrorAlert("Could not initialize Video on SEGV signals");
1355		return false;
1356	+	}
1357	+	}
1358	+	#endif
1359	+
1360	+	// Initialize VideoRefresh function
1361	+	VideoRefreshInit();
1362	+
1363	+	// Lock down frame buffer
1364	+	XSync(x_display, false);
1365	+	LOCK_FRAME_BUFFER;
1366	+
1367	+	// Start redraw/input thread
1368	+	#ifdef HAVE_PTHREADS
1369	+	redraw_thread_cancel = false;
1370	+	redraw_thread_active = (pthread_create(&redraw_thread, NULL, redraw_func, NULL) == 0);
1371	+	if (!redraw_thread_active) {
1372	+	printf("FATAL: cannot create redraw thread\n");
1373	+	return false;
1374		}
1375	+	#else
1376	+	redraw_thread_active = true;
1377		#endif
1378	+
1379		return true;
1380		}
1381
1382		bool VideoInit(bool classic)
1383		{
1384	+	classic_mode = classic;
1385	+
1386		#ifdef ENABLE_VOSF
851	–	// Open /dev/zero
852	–	zero_fd = open("/dev/zero", O_RDWR);
853	–	if (zero_fd < 0) {
854	–	char str[256];
855	–	sprintf(str, GetString(STR_NO_DEV_ZERO_ERR), strerror(errno));
856	–	ErrorAlert(str);
857	–	return false;
858	–	}
859	–
1387		// Zero the mainBuffer structure
1388	<	mainBuffer.dirtyPages = 0;
1389	<	mainBuffer.pageInfo = 0;
1388	>	mainBuffer.dirtyPages = NULL;
1389	>	mainBuffer.pageInfo = NULL;
1390		#endif
1391
1392		// Check if X server runs on local machine
#	Line 870 \| Line 1397 \| bool VideoInit(bool classic)
1397		keycode_init();
1398
1399		// Read prefs
1400	<	mouse_wheel_mode = PrefsFindInt16("mousewheelmode");
1401	<	mouse_wheel_lines = PrefsFindInt16("mousewheellines");
1400	>	frame_skip = PrefsFindInt32("frameskip");
1401	>	mouse_wheel_mode = PrefsFindInt32("mousewheelmode");
1402	>	mouse_wheel_lines = PrefsFindInt32("mousewheellines");
1403
1404		// Find screen and root window
1405		screen = XDefaultScreen(x_display);
1406		rootwin = XRootWindow(x_display, screen);
1407	<
1408	<	// Get screen depth
1409	<	xdepth = DefaultDepth(x_display, screen);
1407	>
1408	>	// Get sorted list of available depths
1409	>	avail_depths = XListDepths(x_display, screen, &num_depths);
1410	>	if (avail_depths == NULL) {
1411	>	ErrorAlert(STR_UNSUPP_DEPTH_ERR);
1412	>	return false;
1413	>	}
1414	>	sort(avail_depths, avail_depths + num_depths);
1415
1416		#ifdef ENABLE_FBDEV_DGA
1417		// Frame buffer name
1418		char fb_name[20];
1419
1420	<	// Could do fbdev dga ?
1420	>	// Could do fbdev DGA?
1421		if ((fbdev_fd = open(FBDEVICE_FILE_NAME, O_RDWR)) != -1)
1422		has_dga = true;
1423		else
#	Line 918 \| Line 1451 \| bool VideoInit(bool classic)
1451		black_pixel = BlackPixel(x_display, screen);
1452		white_pixel = WhitePixel(x_display, screen);
1453
921	–	// Get appropriate visual
922	–	int color_class;
923	–	switch (xdepth) {
924	–	case 1:
925	–	color_class = StaticGray;
926	–	break;
927	–	case 8:
928	–	color_class = PseudoColor;
929	–	break;
930	–	case 15:
931	–	case 16:
932	–	case 24:
933	–	case 32:
934	–	color_class = TrueColor;
935	–	break;
936	–	default:
937	–	ErrorAlert(GetString(STR_UNSUPP_DEPTH_ERR));
938	–	return false;
939	–	}
940	–	if (!XMatchVisualInfo(x_display, screen, xdepth, color_class, &visualInfo)) {
941	–	ErrorAlert(GetString(STR_NO_XVISUAL_ERR));
942	–	return false;
943	–	}
944	–	if (visualInfo.depth != xdepth) {
945	–	ErrorAlert(GetString(STR_NO_XVISUAL_ERR));
946	–	return false;
947	–	}
948	–	vis = visualInfo.visual;
949	–
950	–	// Mac screen depth is always 1 bit in Classic mode, but follows X depth otherwise
951	–	classic_mode = classic;
952	–	if (classic)
953	–	depth = 1;
954	–	else
955	–	depth = xdepth;
956	–
957	–	// Create color maps for 8 bit mode
958	–	if (depth == 8) {
959	–	cmap[0] = XCreateColormap(x_display, rootwin, vis, AllocAll);
960	–	cmap[1] = XCreateColormap(x_display, rootwin, vis, AllocAll);
961	–	XInstallColormap(x_display, cmap[0]);
962	–	XInstallColormap(x_display, cmap[1]);
963	–	}
964	–
1454		// Get screen mode from preferences
1455		const char *mode_str;
1456	<	if (classic)
1456	>	if (classic_mode)
1457		mode_str = "win/512/342";
1458		else
1459		mode_str = PrefsFindString("screen");
1460
1461	<	// Determine type and mode
1462	<	int width = 512, height = 384;
1461	>	// Determine display type and default dimensions
1462	>	int default_width = 512, default_height = 384;
1463		display_type = DISPLAY_WINDOW;
1464		if (mode_str) {
1465	<	if (sscanf(mode_str, "win/%d/%d", &width, &height) == 2)
1465	>	if (sscanf(mode_str, "win/%d/%d", &default_width, &default_height) == 2) {
1466		display_type = DISPLAY_WINDOW;
1467		#ifdef ENABLE_FBDEV_DGA
1468	<	else if (has_dga && sscanf(mode_str, "dga/%19s", fb_name) == 1) {
1469	<	#else
1470	<	else if (has_dga && sscanf(mode_str, "dga/%d/%d", &width, &height) == 2) {
1468	>	} else if (has_dga && sscanf(mode_str, "dga/%19s", fb_name) == 1) {
1469	>	display_type = DISPLAY_DGA;
1470	>	default_width = -1; default_height = -1; // use entire screen
1471		#endif
1472	+	#ifdef ENABLE_XF86_DGA
1473	+	} else if (has_dga && sscanf(mode_str, "dga/%d/%d", &default_width, &default_height) == 2) {
1474		display_type = DISPLAY_DGA;
1475	<	if (width > DisplayWidth(x_display, screen))
1476	<	width = DisplayWidth(x_display, screen);
986	<	if (height > DisplayHeight(x_display, screen))
987	<	height = DisplayHeight(x_display, screen);
988	<	}
989	<	if (width <= 0)
990	<	width = DisplayWidth(x_display, screen);
991	<	if (height <= 0)
992	<	height = DisplayHeight(x_display, screen);
1475	>	#endif
1476	>	}
1477		}
1478	<
1479	<	// Initialize according to display type
1480	<	switch (display_type) {
1481	<	case DISPLAY_WINDOW:
1482	<	if (!init_window(width, height))
1483	<	return false;
1478	>	if (default_width <= 0)
1479	>	default_width = DisplayWidth(x_display, screen);
1480	>	else if (default_width > DisplayWidth(x_display, screen))
1481	>	default_width = DisplayWidth(x_display, screen);
1482	>	if (default_height <= 0)
1483	>	default_height = DisplayHeight(x_display, screen);
1484	>	else if (default_height > DisplayHeight(x_display, screen))
1485	>	default_height = DisplayHeight(x_display, screen);
1486	>
1487	>	// Mac screen depth follows X depth
1488	>	video_depth default_depth = VDEPTH_1BIT;
1489	>	switch (DefaultDepth(x_display, screen)) {
1490	>	case 8:
1491	>	default_depth = VDEPTH_8BIT;
1492		break;
1493	<	case DISPLAY_DGA:
1494	<	#ifdef ENABLE_FBDEV_DGA
1495	<	if (!init_fbdev_dga(fb_name))
1496	<	#else
1497	<	if (!init_xf86_dga(width, height))
1006	<	#endif
1007	<	return false;
1493	>	case 15: case 16:
1494	>	default_depth = VDEPTH_16BIT;
1495	>	break;
1496	>	case 24: case 32:
1497	>	default_depth = VDEPTH_32BIT;
1498		break;
1499		}
1500
1501	<	#ifdef HAVE_PTHREADS
1502	<	// Lock down frame buffer
1503	<	pthread_mutex_lock(&frame_buffer_lock);
1504	<	#endif
1505	<
1506	<	#if !REAL_ADDRESSING && !DIRECT_ADDRESSING
1507	<	// Set variables for UAE memory mapping
1508	<	MacFrameBaseHost = the_buffer;
1509	<	MacFrameSize = VideoMonitor.bytes_per_row * VideoMonitor.y;
1020	<
1021	<	// No special frame buffer in Classic mode (frame buffer is in Mac RAM)
1022	<	if (classic)
1023	<	MacFrameLayout = FLAYOUT_NONE;
1024	<	#endif
1025	<
1026	<	#ifdef ENABLE_VOSF
1027	<	if (use_vosf) {
1028	<	// Initialize the mainBuffer structure
1029	<	if (!VideoInitBuffer()) {
1030	<	// TODO: STR_VOSF_INIT_ERR ?
1031	<	ErrorAlert("Could not initialize Video on SEGV signals");
1032	<	return false;
1501	>	// Construct list of supported modes
1502	>	if (display_type == DISPLAY_WINDOW) {
1503	>	if (classic)
1504	>	add_mode(512, 342, 0x80, 64, VDEPTH_1BIT);
1505	>	else {
1506	>	for (unsigned d=VDEPTH_1BIT; d<=VDEPTH_32BIT; d++) {
1507	>	if (find_visual_for_depth(video_depth(d)))
1508	>	add_window_modes(video_depth(d));
1509	>	}
1510		}
1511	+	} else
1512	+	add_mode(default_width, default_height, 0x80, TrivialBytesPerRow(default_width, default_depth), default_depth);
1513	+	if (VideoModes.empty()) {
1514	+	ErrorAlert(STR_NO_XVISUAL_ERR);
1515	+	return false;
1516	+	}
1517	+	video_init_depth_list();
1518
1519	<	// Initialize the handler for SIGSEGV
1520	<	if (!Screen_fault_handler_init()) {
1521	<	// TODO: STR_VOSF_INIT_ERR ?
1522	<	ErrorAlert("Could not initialize Video on SEGV signals");
1523	<	return false;
1524	<	}
1519	>	#if DEBUG
1520	>	D(bug("Available video modes:\n"));
1521	>	vector<video_mode>::const_iterator i = VideoModes.begin(), end = VideoModes.end();
1522	>	while (i != end) {
1523	>	int bits = 1 << i->depth;
1524	>	if (bits == 16)
1525	>	bits = 15;
1526	>	else if (bits == 32)
1527	>	bits = 24;
1528	>	D(bug(" %dx%d (ID %02x), %d colors\n", i->x, i->y, i->resolution_id, 1 << bits));
1529	>	++i;
1530		}
1531		#endif
1043	–
1044	–	// Initialize VideoRefresh function
1045	–	VideoRefreshInit();
1046	–
1047	–	XSync(x_display, false);
1532
1533	<	#ifdef HAVE_PTHREADS
1534	<	// Start redraw/input thread
1535	<	redraw_thread_active = (pthread_create(&redraw_thread, NULL, redraw_func, NULL) == 0);
1536	<	if (!redraw_thread_active) {
1537	<	printf("FATAL: cannot create redraw thread\n");
1538	<	return false;
1533	>	// Find requested default mode and open display
1534	>	if (VideoModes.size() == 1)
1535	>	return video_open(VideoModes[0]);
1536	>	else {
1537	>	// Find mode with specified dimensions
1538	>	std::vector<video_mode>::const_iterator i, end = VideoModes.end();
1539	>	for (i = VideoModes.begin(); i != end; ++i) {
1540	>	if (i->x == default_width && i->y == default_height && i->depth == default_depth)
1541	>	return video_open(*i);
1542	>	}
1543	>	return video_open(VideoModes[0]);
1544		}
1056	–	#endif
1057	–	return true;
1545		}
1546
1547
#	Line 1062 \| Line 1549 \| bool VideoInit(bool classic)
1549		* Deinitialization
1550		*/
1551
1552	<	void VideoExit(void)
1552	>	// Close display
1553	>	static void video_close(void)
1554		{
1067	–	#ifdef HAVE_PTHREADS
1555		// Stop redraw thread
1556	+	#ifdef HAVE_PTHREADS
1557		if (redraw_thread_active) {
1558		redraw_thread_cancel = true;
1559		#ifdef HAVE_PTHREAD_CANCEL
1560		pthread_cancel(redraw_thread);
1561		#endif
1562		pthread_join(redraw_thread, NULL);
1075	–	redraw_thread_active = false;
1563		}
1564		#endif
1565	+	redraw_thread_active = false;
1566
1079	–	#ifdef HAVE_PTHREADS
1567		// Unlock frame buffer
1568	<	pthread_mutex_unlock(&frame_buffer_lock);
1569	<	#endif
1083	<
1084	<	// Close window and server connection
1085	<	if (x_display != NULL) {
1086	<	XSync(x_display, false);
1087	<
1088	<	#ifdef ENABLE_XF86_DGA
1089	<	if (display_type == DISPLAY_DGA) {
1090	<	XF86DGADirectVideo(x_display, screen, 0);
1091	<	XUngrabPointer(x_display, CurrentTime);
1092	<	XUngrabKeyboard(x_display, CurrentTime);
1093	<	}
1094	<	#endif
1095	<
1096	<	#ifdef ENABLE_XF86_VIDMODE
1097	<	if (has_vidmode && display_type == DISPLAY_DGA)
1098	<	XF86VidModeSwitchToMode(x_display, screen, x_video_modes[0]);
1099	<	#endif
1100	<
1101	<	#ifdef ENABLE_FBDEV_DGA
1102	<	if (display_type == DISPLAY_DGA) {
1103	<	XUngrabPointer(x_display, CurrentTime);
1104	<	XUngrabKeyboard(x_display, CurrentTime);
1105	<	close(fbdev_fd);
1106	<	}
1107	<	#endif
1108	<
1109	<	XFlush(x_display);
1110	<	XSync(x_display, false);
1111	<	if (depth == 8) {
1112	<	XFreeColormap(x_display, cmap[0]);
1113	<	XFreeColormap(x_display, cmap[1]);
1114	<	}
1115	<
1116	<	if (!use_vosf) {
1117	<	if (the_buffer) {
1118	<	free(the_buffer);
1119	<	the_buffer = NULL;
1120	<	}
1568	>	UNLOCK_FRAME_BUFFER;
1569	>	XSync(x_display, false);
1570
1122	–	if (!have_shm && the_buffer_copy) {
1123	–	free(the_buffer_copy);
1124	–	the_buffer_copy = NULL;
1125	–	}
1126	–	}
1127	–	#ifdef ENABLE_VOSF
1128	–	else {
1129	–	if (the_buffer != (uint8 *)MAP_FAILED) {
1130	–	munmap((caddr_t)the_buffer, the_buffer_size);
1131	–	the_buffer = 0;
1132	–	}
1133	–
1134	–	if (the_buffer_copy != (uint8 *)MAP_FAILED) {
1135	–	munmap((caddr_t)the_buffer_copy, the_buffer_size);
1136	–	the_buffer_copy = 0;
1137	–	}
1138	–	}
1139	–	#endif
1140	–	}
1141	–
1571		#ifdef ENABLE_VOSF
1572	+	// Deinitialize VOSF
1573		if (use_vosf) {
1144	–	// Clear mainBuffer data
1574		if (mainBuffer.pageInfo) {
1575		free(mainBuffer.pageInfo);
1576	<	mainBuffer.pageInfo = 0;
1576	>	mainBuffer.pageInfo = NULL;
1577		}
1149	–
1578		if (mainBuffer.dirtyPages) {
1579		free(mainBuffer.dirtyPages);
1580	<	mainBuffer.dirtyPages = 0;
1580	>	mainBuffer.dirtyPages = NULL;
1581		}
1582		}
1583	+	#endif
1584	+
1585	+	// Close display
1586	+	delete drv;
1587	+	drv = NULL;
1588	+
1589	+	// Free colormaps
1590	+	if (cmap[0]) {
1591	+	XFreeColormap(x_display, cmap[0]);
1592	+	cmap[0] = 0;
1593	+	}
1594	+	if (cmap[1]) {
1595	+	XFreeColormap(x_display, cmap[1]);
1596	+	cmap[1] = 0;
1597	+	}
1598	+	}
1599	+
1600	+	void VideoExit(void)
1601	+	{
1602	+	// Close display
1603	+	video_close();
1604	+
1605	+	#ifdef ENABLE_XF86_VIDMODE
1606	+	// Free video mode list
1607	+	if (x_video_modes) {
1608	+	XFree(x_video_modes);
1609	+	x_video_modes = NULL;
1610	+	}
1611	+	#endif
1612
1613	<	// Close /dev/zero
1614	<	if (zero_fd > 0)
1615	<	close(zero_fd);
1613	>	#ifdef ENABLE_FBDEV_DGA
1614	>	// Close framebuffer device
1615	>	if (fbdev_fd >= 0) {
1616	>	close(fbdev_fd);
1617	>	fbdev_fd = -1;
1618	>	}
1619		#endif
1620	+
1621	+	// Free depth list
1622	+	if (avail_depths) {
1623	+	XFree(avail_depths);
1624	+	avail_depths = NULL;
1625	+	}
1626		}
1627
1628
#	Line 1167 \| Line 1633 \| void VideoExit(void)
1633		void VideoQuitFullScreen(void)
1634		{
1635		D(bug("VideoQuitFullScreen()\n"));
1636	<	if (display_type == DISPLAY_DGA)
1171	<	quit_full_screen = true;
1636	>	quit_full_screen = true;
1637		}
1638
1639
#	Line 1182 \| Line 1647 \| void VideoInterrupt(void)
1647		if (emerg_quit)
1648		QuitEmulator();
1649
1185	–	#ifdef HAVE_PTHREADS
1650		// Temporarily give up frame buffer lock (this is the point where
1651		// we are suspended when the user presses Ctrl-Tab)
1652	<	pthread_mutex_unlock(&frame_buffer_lock);
1653	<	pthread_mutex_lock(&frame_buffer_lock);
1190	<	#endif
1652	>	UNLOCK_FRAME_BUFFER;
1653	>	LOCK_FRAME_BUFFER;
1654		}
1655
1656
#	Line 1195 \| Line 1658 \| void VideoInterrupt(void)
1658		* Set palette
1659		*/
1660
1661	<	void video_set_palette(uint8 *pal)
1661	>	void video_set_palette(uint8 *pal, int num_in)
1662		{
1663	<	#ifdef HAVE_PTHREDS
1201	<	pthread_mutex_lock(&palette_lock);
1202	<	#endif
1663	>	LOCK_PALETTE;
1664
1665		// Convert colors to XColor array
1666	<	for (int i=0; i<256; i++) {
1667	<	palette[i].pixel = i;
1668	<	palette[i].red = pal[i3] 0x0101;
1669	<	palette[i].green = pal[i3+1] 0x0101;
1670	<	palette[i].blue = pal[i3+2] 0x0101;
1671	<	palette[i].flags = DoRed \| DoGreen \| DoBlue;
1666	>	int num_out = 256;
1667	>	bool stretch = false;
1668	>	if (IsDirectMode(VideoMonitor.mode)) {
1669	>	// If X is in 565 mode we have to stretch the gamma table from 32 to 64 entries
1670	>	num_out = vis->map_entries;
1671	>	stretch = true;
1672	>	}
1673	>	XColor *p = palette;
1674	>	for (int i=0; i<num_out; i++) {
1675	>	int c = (stretch ? (i * num_in) / num_out : i);
1676	>	p->red = pal[c3 + 0] 0x0101;
1677	>	p->green = pal[c3 + 1] 0x0101;
1678	>	p->blue = pal[c3 + 2] 0x0101;
1679	>	if (color_class == PseudoColor)
1680	>	p->pixel = i;
1681	>	p->flags = DoRed \| DoGreen \| DoBlue;
1682	>	p++;
1683		}
1684
1685	+	#ifdef ENABLE_VOSF
1686	+	// Recalculate pixel color expansion map
1687	+	if (!IsDirectMode(VideoMonitor.mode) && (color_class == TrueColor \|\| color_class == DirectColor)) {
1688	+	for (int i=0; i<256; i++) {
1689	+	int c = i & (num_in-1); // If there are less than 256 colors, we repeat the first entries (this makes color expansion easier)
1690	+	ExpandMap[i] = map_rgb(pal[c3+0], pal[c3+1], pal[c*3+2]);
1691	+	}
1692	+
1693	+	// We have to redraw everything because the interpretation of pixel values changed
1694	+	LOCK_VOSF;
1695	+	PFLAG_SET_ALL;
1696	+	UNLOCK_VOSF;
1697	+	memset(the_buffer_copy, 0, VideoMonitor.mode.bytes_per_row * VideoMonitor.mode.y);
1698	+	}
1699	+	#endif
1700	+
1701		// Tell redraw thread to change palette
1702		palette_changed = true;
1703
1704	<	#ifdef HAVE_PTHREADS
1217	<	pthread_mutex_unlock(&palette_lock);
1218	<	#endif
1704	>	UNLOCK_PALETTE;
1705		}
1706
1707
1708		/*
1709	<	* Suspend/resume emulator
1709	>	* Switch video mode
1710		*/
1711
1712	<	#if defined(ENABLE_XF86_DGA) \|\| defined(ENABLE_FBDEV_DGA)
1227	<	static void suspend_emul(void)
1228	<	{
1229	<	if (display_type == DISPLAY_DGA) {
1230	<	// Release ctrl key
1231	<	ADBKeyUp(0x36);
1232	<	ctrl_down = false;
1233	<
1234	<	#ifdef HAVE_PTHREADS
1235	<	// Lock frame buffer (this will stop the MacOS thread)
1236	<	pthread_mutex_lock(&frame_buffer_lock);
1237	<	#endif
1238	<
1239	<	// Save frame buffer
1240	<	fb_save = malloc(VideoMonitor.y * VideoMonitor.bytes_per_row);
1241	<	if (fb_save)
1242	<	memcpy(fb_save, the_buffer, VideoMonitor.y * VideoMonitor.bytes_per_row);
1243	<
1244	<	// Close full screen display
1245	<	#ifdef ENABLE_XF86_DGA
1246	<	XF86DGADirectVideo(x_display, screen, 0);
1247	<	#endif
1248	<	XUngrabPointer(x_display, CurrentTime);
1249	<	XUngrabKeyboard(x_display, CurrentTime);
1250	<	XUnmapWindow(x_display, the_win);
1251	<	XSync(x_display, false);
1252	<
1253	<	// Open "suspend" window
1254	<	XSetWindowAttributes wattr;
1255	<	wattr.event_mask = KeyPressMask;
1256	<	wattr.background_pixel = black_pixel;
1257	<	wattr.border_pixel = black_pixel;
1258	<	wattr.backing_store = Always;
1259	<	wattr.backing_planes = xdepth;
1260	<	wattr.colormap = DefaultColormap(x_display, screen);
1261	<
1262	<	XSync(x_display, false);
1263	<	suspend_win = XCreateWindow(x_display, rootwin, 0, 0, 512, 1, 0, xdepth,
1264	<	InputOutput, vis, CWEventMask \| CWBackPixel \| CWBorderPixel \|
1265	<	CWBackingStore \| CWBackingPlanes \| (xdepth == 8 ? CWColormap : 0), &wattr);
1266	<	XSync(x_display, false);
1267	<	XStoreName(x_display, suspend_win, GetString(STR_SUSPEND_WINDOW_TITLE));
1268	<	XMapRaised(x_display, suspend_win);
1269	<	XSync(x_display, false);
1270	<	emul_suspended = true;
1271	<	}
1272	<	}
1273	<
1274	<	static void resume_emul(void)
1712	>	void video_switch_to_mode(const video_mode &mode)
1713		{
1714	<	// Close "suspend" window
1715	<	XDestroyWindow(x_display, suspend_win);
1716	<	XSync(x_display, false);
1714	>	// Close and reopen display
1715	>	video_close();
1716	>	video_open(mode);
1717
1718	<	// Reopen full screen display
1719	<	XMapRaised(x_display, the_win);
1720	<	XWarpPointer(x_display, None, rootwin, 0, 0, 0, 0, 0, 0);
1283	<	XSync(x_display, false);
1284	<	XGrabKeyboard(x_display, rootwin, 1, GrabModeAsync, GrabModeAsync, CurrentTime);
1285	<	XGrabPointer(x_display, rootwin, 1, PointerMotionMask \| ButtonPressMask \| ButtonReleaseMask, GrabModeAsync, GrabModeAsync, None, None, CurrentTime);
1286	<	#ifdef ENABLE_XF86_DGA
1287	<	XF86DGADirectVideo(x_display, screen, XF86DGADirectGraphics \| XF86DGADirectKeyb \| XF86DGADirectMouse);
1288	<	XF86DGASetViewPort(x_display, screen, 0, 0);
1289	<	#endif
1290	<	XSync(x_display, false);
1291	<
1292	<	// the_buffer already contains the data to restore. i.e. since a temporary
1293	<	// frame buffer is used when VOSF is actually used, fb_save is therefore
1294	<	// not necessary.
1295	<	#ifdef ENABLE_VOSF
1296	<	if (use_vosf) {
1297	<	#ifdef HAVE_PTHREADS
1298	<	pthread_mutex_lock(&Screen_draw_lock);
1299	<	#endif
1300	<	PFLAG_SET_ALL;
1301	<	#ifdef HAVE_PTHREADS
1302	<	pthread_mutex_unlock(&Screen_draw_lock);
1303	<	#endif
1304	<	memset(the_buffer_copy, 0, VideoMonitor.bytes_per_row * VideoMonitor.y);
1305	<	}
1306	<	#endif
1307	<
1308	<	// Restore frame buffer
1309	<	if (fb_save) {
1310	<	#ifdef ENABLE_VOSF
1311	<	// Don't copy fb_save to the temporary frame buffer in VOSF mode
1312	<	if (!use_vosf)
1313	<	#endif
1314	<	memcpy(the_buffer, fb_save, VideoMonitor.y * VideoMonitor.bytes_per_row);
1315	<	free(fb_save);
1316	<	fb_save = NULL;
1718	>	if (drv == NULL) {
1719	>	ErrorAlert(STR_OPEN_WINDOW_ERR);
1720	>	QuitEmulator();
1721		}
1318	–
1319	–	#ifdef ENABLE_XF86_DGA
1320	–	if (depth == 8)
1321	–	XF86DGAInstallColormap(x_display, screen, cmap[current_dga_cmap]);
1322	–	#endif
1323	–
1324	–	#ifdef HAVE_PTHREADS
1325	–	// Unlock frame buffer (and continue MacOS thread)
1326	–	pthread_mutex_unlock(&frame_buffer_lock);
1327	–	emul_suspended = false;
1328	–	#endif
1722		}
1330	–	#endif
1723
1724
1725		/*
1726	<	* Translate key event to Mac keycode
1726	>	* Translate key event to Mac keycode, returns -1 if no keycode was found
1727	>	* and -2 if the key was recognized as a hotkey
1728		*/
1729
1730	<	static int kc_decode(KeySym ks)
1730	>	static int kc_decode(KeySym ks, bool key_down)
1731		{
1732		switch (ks) {
1733		case XK_A: case XK_a: return 0x00;
#	Line 1387 \| Line 1780 \| static int kc_decode(KeySym ks)
1780		case XK_period: case XK_greater: return 0x2f;
1781		case XK_slash: case XK_question: return 0x2c;
1782
1783	<	#if defined(ENABLE_XF86_DGA) \|\| defined(ENABLE_FBDEV_DGA)
1391	<	case XK_Tab: if (ctrl_down) {suspend_emul(); return -1;} else return 0x30;
1392	<	#else
1393	<	case XK_Tab: return 0x30;
1394	<	#endif
1783	>	case XK_Tab: if (ctrl_down) {if (key_down) drv->suspend(); return -2;} else return 0x30;
1784		case XK_Return: return 0x24;
1785		case XK_space: return 0x31;
1786		case XK_BackSpace: return 0x33;
#	Line 1425 \| Line 1814 \| static int kc_decode(KeySym ks)
1814		case XK_Left: return 0x3b;
1815		case XK_Right: return 0x3c;
1816
1817	<	case XK_Escape: if (ctrl_down) {quit_full_screen = true; emerg_quit = true; return -1;} else return 0x35;
1817	>	case XK_Escape: if (ctrl_down) {if (key_down) { quit_full_screen = true; emerg_quit = true; } return -2;} else return 0x35;
1818
1819	<	case XK_F1: if (ctrl_down) {SysMountFirstFloppy(); return -1;} else return 0x7a;
1819	>	case XK_F1: if (ctrl_down) {if (key_down) SysMountFirstFloppy(); return -2;} else return 0x7a;
1820		case XK_F2: return 0x78;
1821		case XK_F3: return 0x63;
1822		case XK_F4: return 0x76;
1823	<	case XK_F5: return 0x60;
1823	>	case XK_F5: if (ctrl_down) {if (key_down) drv->toggle_mouse_grab(); return -2;} else return 0x60;
1824		case XK_F6: return 0x61;
1825		case XK_F7: return 0x62;
1826		case XK_F8: return 0x64;
#	Line 1479 \| Line 1868 \| static int kc_decode(KeySym ks)
1868		return -1;
1869		}
1870
1871	<	static int event2keycode(XKeyEvent *ev)
1871	>	static int event2keycode(XKeyEvent &ev, bool key_down)
1872		{
1873		KeySym ks;
1485	–	int as;
1874		int i = 0;
1875
1876		do {
1877	<	ks = XLookupKeysym(ev, i++);
1878	<	as = kc_decode(ks);
1879	<	if (as != -1)
1877	>	ks = XLookupKeysym(&ev, i++);
1878	>	int as = kc_decode(ks, key_down);
1879	>	if (as >= 0)
1880	>	return as;
1881	>	if (as == -2)
1882		return as;
1883		} while (ks != NoSymbol);
1884
#	Line 1502 \| Line 1892 \| *static int event2keycode(XKeyEvent ev)**
1892
1893		static void handle_events(void)
1894		{
1895	<	XEvent event;
1896	<	for (;;) {
1897	<	if (!XCheckMaskEvent(x_display, eventmask, &event))
1508	<	break;
1895	>	while (XPending(x_display)) {
1896	>	XEvent event;
1897	>	XNextEvent(x_display, &event);
1898
1899		switch (event.type) {
1900		// Mouse button
1901		case ButtonPress: {
1902	<	unsigned int button = ((XButtonEvent *)&event)->button;
1902	>	unsigned int button = event.xbutton.button;
1903		if (button < 4)
1904		ADBMouseDown(button - 1);
1905		else if (button < 6) { // Wheel mouse
#	Line 1529 \| Line 1918 \| static void handle_events(void)
1918		break;
1919		}
1920		case ButtonRelease: {
1921	<	unsigned int button = ((XButtonEvent *)&event)->button;
1921	>	unsigned int button = event.xbutton.button;
1922		if (button < 4)
1923		ADBMouseUp(button - 1);
1924		break;
1925		}
1926
1927		// Mouse moved
1539	–	case EnterNotify:
1540	–	ADBMouseMoved(((XMotionEvent )&event)->x, ((XMotionEvent )&event)->y);
1541	–	break;
1928		case MotionNotify:
1929	<	ADBMouseMoved(((XMotionEvent )&event)->x, ((XMotionEvent )&event)->y);
1929	>	drv->mouse_moved(event.xmotion.x, event.xmotion.y);
1930		break;
1931
1932		// Keyboard
1933		case KeyPress: {
1934	<	int code;
1934	>	int code = -1;
1935		if (use_keycodes) {
1936	<	event2keycode((XKeyEvent *)&event); // This is called to process the hotkeys
1937	<	code = keycode_table[((XKeyEvent *)&event)->keycode & 0xff];
1936	>	if (event2keycode(event.xkey, true) != -2) // This is called to process the hotkeys
1937	>	code = keycode_table[event.xkey.keycode & 0xff];
1938		} else
1939	<	code = event2keycode((XKeyEvent *)&event);
1940	<	if (code != -1) {
1939	>	code = event2keycode(event.xkey, true);
1940	>	if (code >= 0) {
1941		if (!emul_suspended) {
1942		if (code == 0x39) { // Caps Lock pressed
1943		if (caps_on) {
#	Line 1566 \| Line 1952 \| static void handle_events(void)
1952		if (code == 0x36)
1953		ctrl_down = true;
1954		} else {
1569	–	#if defined(ENABLE_XF86_DGA) \|\| defined(ENABLE_FBDEV_DGA)
1955		if (code == 0x31)
1956	<	resume_emul(); // Space wakes us up
1572	<	#endif
1956	>	drv->resume(); // Space wakes us up
1957		}
1958		}
1959		break;
1960		}
1961		case KeyRelease: {
1962	<	int code;
1962	>	int code = -1;
1963		if (use_keycodes) {
1964	<	event2keycode((XKeyEvent *)&event); // This is called to process the hotkeys
1965	<	code = keycode_table[((XKeyEvent *)&event)->keycode & 0xff];
1964	>	if (event2keycode(event.xkey, false) != -2) // This is called to process the hotkeys
1965	>	code = keycode_table[event.xkey.keycode & 0xff];
1966		} else
1967	<	code = event2keycode((XKeyEvent *)&event);
1968	<	if (code != -1 && code != 0x39) { // Don't propagate Caps Lock releases
1967	>	code = event2keycode(event.xkey, false);
1968	>	if (code >= 0 && code != 0x39) { // Don't propagate Caps Lock releases
1969		ADBKeyUp(code);
1970		if (code == 0x36)
1971		ctrl_down = false;
#	Line 1594 \| Line 1978 \| static void handle_events(void)
1978		if (display_type == DISPLAY_WINDOW) {
1979		#ifdef ENABLE_VOSF
1980		if (use_vosf) { // VOSF refresh
1981	<	#ifdef HAVE_PTHREADS
1598	<	pthread_mutex_lock(&Screen_draw_lock);
1599	<	#endif
1981	>	LOCK_VOSF;
1982		PFLAG_SET_ALL;
1983	<	#ifdef HAVE_PTHREADS
1984	<	pthread_mutex_unlock(&Screen_draw_lock);
1603	<	#endif
1604	<	memset(the_buffer_copy, 0, VideoMonitor.bytes_per_row * VideoMonitor.y);
1983	>	UNLOCK_VOSF;
1984	>	memset(the_buffer_copy, 0, VideoMonitor.mode.bytes_per_row * VideoMonitor.mode.y);
1985		}
1986		else
1987		#endif
#	Line 1612 \| Line 1992 \| static void handle_events(void)
1992		updt_box[x1][y1] = true;
1993		nr_boxes = 16 * 16;
1994		} else // Static refresh
1995	<	memset(the_buffer_copy, 0, VideoMonitor.bytes_per_row * VideoMonitor.y);
1995	>	memset(the_buffer_copy, 0, VideoMonitor.mode.bytes_per_row * VideoMonitor.mode.y);
1996	>	}
1997	>	break;
1998	>
1999	>	// Window "close" widget clicked
2000	>	case ClientMessage:
2001	>	if (event.xclient.format == 32 && event.xclient.data.l[0] == WM_DELETE_WINDOW) {
2002	>	ADBKeyDown(0x7f); // Power key
2003	>	ADBKeyUp(0x7f);
2004		}
2005		break;
2006		}
#	Line 1625 \| Line 2013 \| static void handle_events(void)
2013		*/
2014
2015		// Dynamic display update (variable frame rate for each box)
2016	<	static void update_display_dynamic(int ticker)
2016	>	static void update_display_dynamic(int ticker, driver_window *drv)
2017		{
2018		int y1, y2, y2s, y2a, i, x1, xm, xmo, ymo, yo, yi, yil, xi;
2019		int xil = 0;
2020		int rxm = 0, rxmo = 0;
2021	<	int bytes_per_row = VideoMonitor.bytes_per_row;
2022	<	int bytes_per_pixel = VideoMonitor.bytes_per_row / VideoMonitor.x;
2023	<	int rx = VideoMonitor.bytes_per_row / 16;
2024	<	int ry = VideoMonitor.y / 16;
2021	>	int bytes_per_row = VideoMonitor.mode.bytes_per_row;
2022	>	int bytes_per_pixel = VideoMonitor.mode.bytes_per_row / VideoMonitor.mode.x;
2023	>	int rx = VideoMonitor.mode.bytes_per_row / 16;
2024	>	int ry = VideoMonitor.mode.y / 16;
2025		int max_box;
2026
2027		y2s = sm_uptd[ticker % 8];
#	Line 1687 \| Line 2075 \| static void update_display_dynamic(int t
2075		i = (yi * bytes_per_row) + xi;
2076		for (y2=0; y2 < yil; y2++, i += bytes_per_row)
2077		memcpy(&the_buffer_copy[i], &the_buffer[i], xil);
2078	<	if (depth == 1) {
2079	<	if (have_shm)
2080	<	XShmPutImage(x_display, the_win, the_gc, img, xi * 8, yi, xi * 8, yi, xil * 8, yil, 0);
2078	>	if (VideoMonitor.mode.depth == VDEPTH_1BIT) {
2079	>	if (drv->have_shm)
2080	>	XShmPutImage(x_display, drv->w, drv->gc, drv->img, xi * 8, yi, xi * 8, yi, xil * 8, yil, 0);
2081		else
2082	<	XPutImage(x_display, the_win, the_gc, img, xi * 8, yi, xi * 8, yi, xil * 8, yil);
2082	>	XPutImage(x_display, drv->w, drv->gc, drv->img, xi * 8, yi, xi * 8, yi, xil * 8, yil);
2083		} else {
2084	<	if (have_shm)
2085	<	XShmPutImage(x_display, the_win, the_gc, img, xi / bytes_per_pixel, yi, xi / bytes_per_pixel, yi, xil / bytes_per_pixel, yil, 0);
2084	>	if (drv->have_shm)
2085	>	XShmPutImage(x_display, drv->w, drv->gc, drv->img, xi / bytes_per_pixel, yi, xi / bytes_per_pixel, yi, xil / bytes_per_pixel, yil, 0);
2086		else
2087	<	XPutImage(x_display, the_win, the_gc, img, xi / bytes_per_pixel, yi, xi / bytes_per_pixel, yi, xil / bytes_per_pixel, yil);
2087	>	XPutImage(x_display, drv->w, drv->gc, drv->img, xi / bytes_per_pixel, yi, xi / bytes_per_pixel, yi, xil / bytes_per_pixel, yil);
2088		}
2089		xil = 0;
2090		}
#	Line 1715 \| Line 2103 \| static void update_display_dynamic(int t
2103		}
2104
2105		// Static display update (fixed frame rate, but incremental)
2106	<	static void update_display_static(void)
2106	>	static void update_display_static(driver_window *drv)
2107		{
2108		// Incremental update code
2109		int wide = 0, high = 0, x1, x2, y1, y2, i, j;
2110	<	int bytes_per_row = VideoMonitor.bytes_per_row;
2111	<	int bytes_per_pixel = VideoMonitor.bytes_per_row / VideoMonitor.x;
2110	>	int bytes_per_row = VideoMonitor.mode.bytes_per_row;
2111	>	int bytes_per_pixel = VideoMonitor.mode.bytes_per_row / VideoMonitor.mode.x;
2112		uint8 p, p2;
2113
2114		// Check for first line from top and first line from bottom that have changed
2115		y1 = 0;
2116	<	for (j=0; j<VideoMonitor.y; j++) {
2116	>	for (j=0; j<VideoMonitor.mode.y; j++) {
2117		if (memcmp(&the_buffer[j * bytes_per_row], &the_buffer_copy[j * bytes_per_row], bytes_per_row)) {
2118		y1 = j;
2119		break;
2120		}
2121		}
2122		y2 = y1 - 1;
2123	<	for (j=VideoMonitor.y-1; j>=y1; j--) {
2123	>	for (j=VideoMonitor.mode.y-1; j>=y1; j--) {
2124		if (memcmp(&the_buffer[j * bytes_per_row], &the_buffer_copy[j * bytes_per_row], bytes_per_row)) {
2125		y2 = j;
2126		break;
#	Line 1742 \| Line 2130 \| static void update_display_static(void)
2130
2131		// Check for first column from left and first column from right that have changed
2132		if (high) {
2133	<	if (depth == 1) {
2134	<	x1 = VideoMonitor.x;
2133	>	if (VideoMonitor.mode.depth == VDEPTH_1BIT) {
2134	>	x1 = VideoMonitor.mode.x - 1;
2135		for (j=y1; j<=y2; j++) {
2136		p = &the_buffer[j * bytes_per_row];
2137		p2 = &the_buffer_copy[j * bytes_per_row];
#	Line 1761 \| Line 2149 \| static void update_display_static(void)
2149		p2 = &the_buffer_copy[j * bytes_per_row];
2150		p += bytes_per_row;
2151		p2 += bytes_per_row;
2152	<	for (i=(VideoMonitor.x>>3); i>(x2>>3); i--) {
2152	>	for (i=(VideoMonitor.mode.x>>3); i>(x2>>3); i--) {
2153		p--; p2--;
2154		if (p != p2) {
2155	<	x2 = i << 3;
2155	>	x2 = (i << 3) + 7;
2156		break;
2157		}
2158		}
2159		}
2160	<	wide = x2 - x1;
2160	>	wide = x2 - x1 + 1;
2161
2162		// Update copy of the_buffer
2163		if (high && wide) {
#	Line 1780 \| Line 2168 \| static void update_display_static(void)
2168		}
2169
2170		} else {
2171	<	x1 = VideoMonitor.x;
2171	>	x1 = VideoMonitor.mode.x;
2172		for (j=y1; j<=y2; j++) {
2173		p = &the_buffer[j * bytes_per_row];
2174		p2 = &the_buffer_copy[j * bytes_per_row];
#	Line 1798 \| Line 2186 \| static void update_display_static(void)
2186		p2 = &the_buffer_copy[j * bytes_per_row];
2187		p += bytes_per_row;
2188		p2 += bytes_per_row;
2189	<	for (i=VideoMonitor.xbytes_per_pixel; i>x2bytes_per_pixel; i--) {
2189	>	for (i=VideoMonitor.mode.xbytes_per_pixel; i>x2bytes_per_pixel; i--) {
2190		p--;
2191		p2--;
2192		if (p != p2) {
#	Line 1821 \| Line 2209 \| static void update_display_static(void)
2209
2210		// Refresh display
2211		if (high && wide) {
2212	<	if (have_shm)
2213	<	XShmPutImage(x_display, the_win, the_gc, img, x1, y1, x1, y1, wide, high, 0);
2212	>	if (drv->have_shm)
2213	>	XShmPutImage(x_display, drv->w, drv->gc, drv->img, x1, y1, x1, y1, wide, high, 0);
2214		else
2215	<	XPutImage(x_display, the_win, the_gc, img, x1, y1, x1, y1, wide, high);
2215	>	XPutImage(x_display, drv->w, drv->gc, drv->img, x1, y1, x1, y1, wide, high);
2216		}
2217		}
2218
#	Line 1833 \| Line 2221 \| static void update_display_static(void)
2221		* Screen refresh functions
2222		*/
2223
2224	<	// The specialisations hereunder are meant to enable VOSF with DGA in direct
2225	<	// addressing mode in case the address spaces (RAM, ROM, FrameBuffer) could
2226	<	// not get mapped correctly with respect to the predetermined host frame
2227	<	// buffer base address.
2228	<	//
1841	<	// Hmm, in other words, when in direct addressing mode and DGA is requested,
1842	<	// we first try to "triple allocate" the address spaces according to the real
1843	<	// host frame buffer address. Then, if it fails, we will use a temporary
1844	<	// frame buffer thus making the real host frame buffer updated when pages
1845	<	// of the temp frame buffer are altered.
1846	<	//
1847	<	// As a side effect, a little speed gain in screen updates could be noticed
1848	<	// for other modes than DGA.
1849	<	//
1850	<	// The following two functions below are inline so that a clever compiler
1851	<	// could specialise the code according to the current screen depth and
1852	<	// display type. A more clever compiler would the job by itself though...
1853	<	// (update_display_vosf is inlined as well)
2224	>	// We suggest the compiler to inline the next two functions so that it
2225	>	// may specialise the code according to the current screen depth and
2226	>	// display type. A clever compiler would do that job by itself though...
2227	>
2228	>	// NOTE: update_display_vosf is inlined too
2229
2230		static inline void possibly_quit_dga_mode()
2231		{
2232	<	#if defined(ENABLE_XF86_DGA) \|\| defined(ENABLE_FBDEV_DGA)
2233	<	// Quit DGA mode if requested
2232	>	// Quit DGA mode if requested (something terrible has happened and we
2233	>	// want to give control back to the user)
2234		if (quit_full_screen) {
2235		quit_full_screen = false;
2236	<	#ifdef ENABLE_XF86_DGA
2237	<	XF86DGADirectVideo(x_display, screen, 0);
1863	<	#endif
1864	<	XUngrabPointer(x_display, CurrentTime);
1865	<	XUngrabKeyboard(x_display, CurrentTime);
1866	<	XUnmapWindow(x_display, the_win);
1867	<	XSync(x_display, false);
2236	>	delete drv;
2237	>	drv = NULL;
2238		}
1869	–	#endif
2239		}
2240
2241	<	static inline void handle_palette_changes(int depth, int display_type)
2241	>	static inline void possibly_ungrab_mouse()
2242		{
2243	<	#ifdef HAVE_PTHREADS
2244	<	pthread_mutex_lock(&palette_lock);
2245	<	#endif
2243	>	// Ungrab mouse if requested (something terrible has happened and we
2244	>	// want to give control back to the user)
2245	>	if (quit_full_screen) {
2246	>	quit_full_screen = false;
2247	>	if (drv)
2248	>	drv->ungrab_mouse();
2249	>	}
2250	>	}
2251	>
2252	>	static inline void handle_palette_changes(void)
2253	>	{
2254	>	LOCK_PALETTE;
2255	>
2256		if (palette_changed) {
2257		palette_changed = false;
2258	<	if (depth == 8) {
1880	<	XStoreColors(x_display, cmap[0], palette, 256);
1881	<	XStoreColors(x_display, cmap[1], palette, 256);
1882	<
1883	<	#ifdef ENABLE_XF86_DGA
1884	<	if (display_type == DISPLAY_DGA) {
1885	<	current_dga_cmap ^= 1;
1886	<	XF86DGAInstallColormap(x_display, screen, cmap[current_dga_cmap]);
1887	<	}
1888	<	#endif
1889	<	}
2258	>	drv->update_palette();
2259		}
2260	<	#ifdef HAVE_PTHREADS
2261	<	pthread_mutex_unlock(&palette_lock);
1893	<	#endif
2260	>
2261	>	UNLOCK_PALETTE;
2262		}
2263
2264		static void video_refresh_dga(void)
#	Line 1902 \| Line 2270 \| static void video_refresh_dga(void)
2270		handle_events();
2271
2272		// Handle palette changes
2273	<	handle_palette_changes(depth, DISPLAY_DGA);
2273	>	handle_palette_changes();
2274		}
2275
2276	+	#ifdef ENABLE_VOSF
2277		#if REAL_ADDRESSING \|\| DIRECT_ADDRESSING
2278		static void video_refresh_dga_vosf(void)
2279		{
#	Line 1915 \| Line 2284 \| static void video_refresh_dga_vosf(void)
2284		handle_events();
2285
2286		// Handle palette changes
2287	<	handle_palette_changes(depth, DISPLAY_DGA);
2287	>	handle_palette_changes();
2288
2289		// Update display (VOSF variant)
2290		static int tick_counter = 0;
2291		if (++tick_counter >= frame_skip) {
2292		tick_counter = 0;
2293	<	#ifdef HAVE_PTHREADS
2294	<	pthread_mutex_lock(&Screen_draw_lock);
2295	<	#endif
2296	<	update_display_dga_vosf();
2297	<	#ifdef HAVE_PTHREADS
1929	<	pthread_mutex_unlock(&Screen_draw_lock);
1930	<	#endif
2293	>	if (mainBuffer.dirty) {
2294	>	LOCK_VOSF;
2295	>	update_display_dga_vosf();
2296	>	UNLOCK_VOSF;
2297	>	}
2298		}
2299		}
2300		#endif
2301
1935	–	#ifdef ENABLE_VOSF
2302		static void video_refresh_window_vosf(void)
2303		{
2304	<	// Quit DGA mode if requested
2305	<	possibly_quit_dga_mode();
2304	>	// Ungrab mouse if requested
2305	>	possibly_ungrab_mouse();
2306
2307		// Handle X events
2308		handle_events();
2309
2310		// Handle palette changes
2311	<	handle_palette_changes(depth, DISPLAY_WINDOW);
2311	>	handle_palette_changes();
2312
2313		// Update display (VOSF variant)
2314		static int tick_counter = 0;
2315		if (++tick_counter >= frame_skip) {
2316		tick_counter = 0;
2317	<	#ifdef HAVE_PTHREADS
2318	<	pthread_mutex_lock(&Screen_draw_lock);
2319	<	#endif
2320	<	update_display_window_vosf();
2321	<	#ifdef HAVE_PTHREADS
2322	<	pthread_mutex_unlock(&Screen_draw_lock);
1957	<	#endif
2317	>	if (mainBuffer.dirty) {
2318	>	LOCK_VOSF;
2319	>	update_display_window_vosf(static_cast<driver_window *>(drv));
2320	>	UNLOCK_VOSF;
2321	>	XSync(x_display, false); // Let the server catch up
2322	>	}
2323		}
2324		}
2325	<	#endif
2325	>	#endif // def ENABLE_VOSF
2326
2327		static void video_refresh_window_static(void)
2328		{
2329	+	// Ungrab mouse if requested
2330	+	possibly_ungrab_mouse();
2331	+
2332		// Handle X events
2333		handle_events();
2334
2335		// Handle_palette changes
2336	<	handle_palette_changes(depth, DISPLAY_WINDOW);
2336	>	handle_palette_changes();
2337
2338		// Update display (static variant)
2339		static int tick_counter = 0;
2340		if (++tick_counter >= frame_skip) {
2341		tick_counter = 0;
2342	<	update_display_static();
2342	>	update_display_static(static_cast<driver_window *>(drv));
2343		}
2344		}
2345
2346		static void video_refresh_window_dynamic(void)
2347		{
2348	+	// Ungrab mouse if requested
2349	+	possibly_ungrab_mouse();
2350	+
2351		// Handle X events
2352		handle_events();
2353
2354		// Handle_palette changes
2355	<	handle_palette_changes(depth, DISPLAY_WINDOW);
2355	>	handle_palette_changes();
2356
2357		// Update display (dynamic variant)
2358		static int tick_counter = 0;
2359		tick_counter++;
2360	<	update_display_dynamic(tick_counter);
2360	>	update_display_dynamic(tick_counter, static_cast<driver_window *>(drv));
2361		}
2362
2363
#	Line 1994 \| Line 2365 \| static void video_refresh_window_dynamic
2365		* Thread for screen refresh, input handling etc.
2366		*/
2367
2368	<	void VideoRefreshInit(void)
2368	>	static void VideoRefreshInit(void)
2369		{
2370		// TODO: set up specialised 8bpp VideoRefresh handlers ?
2371		if (display_type == DISPLAY_DGA) {
2372	<	#if REAL_ADDRESSING \|\| DIRECT_ADDRESSING
2372	>	#if ENABLE_VOSF && (REAL_ADDRESSING \|\| DIRECT_ADDRESSING)
2373		if (use_vosf)
2374		video_refresh = video_refresh_dga_vosf;
2375		else
#	Line 2020 \| Line 2391 \| void VideoRefreshInit(void)
2391
2392		void VideoRefresh(void)
2393		{
2394	<	// TODO: make main_unix/VideoRefresh call directly video_refresh() ?
2395	<	video_refresh();
2396	<	}
2397	<
2027	<	#if 0
2028	<	void VideoRefresh(void)
2029	<	{
2030	<	#if defined(ENABLE_XF86_DGA) \|\| defined(ENABLE_FBDEV_DGA)
2031	<	// Quit DGA mode if requested
2032	<	if (quit_full_screen) {
2033	<	quit_full_screen = false;
2034	<	if (display_type == DISPLAY_DGA) {
2035	<	#ifdef ENABLE_XF86_DGA
2036	<	XF86DGADirectVideo(x_display, screen, 0);
2037	<	#endif
2038	<	XUngrabPointer(x_display, CurrentTime);
2039	<	XUngrabKeyboard(x_display, CurrentTime);
2040	<	XUnmapWindow(x_display, the_win);
2041	<	XSync(x_display, false);
2042	<	}
2043	<	}
2044	<	#endif
2045	<
2046	<	// Handle X events
2047	<	handle_events();
2048	<
2049	<	// Handle palette changes
2050	<	#ifdef HAVE_PTHREADS
2051	<	pthread_mutex_lock(&palette_lock);
2052	<	#endif
2053	<	if (palette_changed) {
2054	<	palette_changed = false;
2055	<	if (depth == 8) {
2056	<	XStoreColors(x_display, cmap[0], palette, 256);
2057	<	XStoreColors(x_display, cmap[1], palette, 256);
2058	<
2059	<	#ifdef ENABLE_XF86_DGA
2060	<	if (display_type == DISPLAY_DGA) {
2061	<	current_dga_cmap ^= 1;
2062	<	XF86DGAInstallColormap(x_display, screen, cmap[current_dga_cmap]);
2063	<	}
2064	<	#endif
2065	<	}
2066	<	}
2067	<	#ifdef HAVE_PTHREADS
2068	<	pthread_mutex_unlock(&palette_lock);
2069	<	#endif
2070	<
2071	<	// In window mode, update display
2072	<	static int tick_counter = 0;
2073	<	if (display_type == DISPLAY_WINDOW) {
2074	<	tick_counter++;
2075	<	if (frame_skip == 0)
2076	<	update_display_dynamic(tick_counter);
2077	<	else if (tick_counter >= frame_skip) {
2078	<	tick_counter = 0;
2079	<	update_display_static();
2080	<	}
2081	<	}
2394	>	// We need to check redraw_thread_active to inhibit refreshed during
2395	>	// mode changes on non-threaded platforms
2396	>	if (redraw_thread_active)
2397	>	video_refresh();
2398		}
2083	–	#endif
2399
2400		#ifdef HAVE_PTHREADS
2401		static void redraw_func(void arg)
#	Line 2089 \| Line 2404 \| *static void redraw_func(void arg)*
2404		int64 ticks = 0;
2405		uint64 next = GetTicks_usec();
2406		while (!redraw_thread_cancel) {
2092	–	// VideoRefresh();
2407		video_refresh();
2408		next += 16667;
2409		int64 delay = next - GetTicks_usec();
#	Line 2100 \| Line 2414 \| *static void redraw_func(void arg)*
2414		ticks++;
2415		}
2416		uint64 end = GetTicks_usec();
2417	<	printf("%Ld ticks in %Ld usec = %Ld ticks/sec\n", ticks, end - start, (end - start) / ticks);
2417	>	// printf("%Ld ticks in %Ld usec = %Ld ticks/sec\n", ticks, end - start, ticks * 1000000 / (end - start));
2418		return NULL;
2419		}
2420		#endif

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Comparing BasiliskII/src/Unix/video_x.cpp (file contents): Revision 1.22 by cebix, 2000-10-08T18:41:35Z vs. Revision 1.55 by cebix, 2001-07-06T22:37:23Z

Diff Legend

Comparing BasiliskII/src/Unix/video_x.cpp (file contents):
Revision 1.22 by cebix, 2000-10-08T18:41:35Z vs.
Revision 1.55 by cebix, 2001-07-06T22:37:23Z