BasiliskII/src/adb.cpp

/*
 *  adb.cpp - ADB emulation (mouse/keyboard)
 *
 *  Basilisk II (C) Christian Bauer
 *
 *  This program is free software; you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation; either version 2 of the License, or
 *  (at your option) any later version.
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program; if not, write to the Free Software
 *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 */

/*
 *  SEE ALSO
 *    Inside Macintosh: Devices, chapter 5 "ADB Manager"
 *    Technote HW 01: "ADB - The Untold Story: Space Aliens Ate My Mouse"
 */

#include <stdlib.h>

#include "sysdeps.h"
#include "cpu_emulation.h"
#include "emul_op.h"
#include "main.h"
#include "prefs.h"
#include "video.h"
#include "adb.h"

#ifdef POWERPC_ROM
#include "thunks.h"
#endif

#define DEBUG 0
#include "debug.h"


// Global variables
static int mouse_x = 0, mouse_y = 0;                                                    // Mouse position
static int old_mouse_x = 0, old_mouse_y = 0;
static bool mouse_button[3] = {false, false, false};                    // Mouse button states
static bool old_mouse_button[3] = {false, false, false};
static bool relative_mouse = false;

static uint8 key_states[16];                            // Key states (Mac keycodes)
#define MATRIX(code) (key_states[code >> 3] & (1 << (~code & 7)))

// Keyboard event buffer (Mac keycodes with up/down flag)
const int KEY_BUFFER_SIZE = 16;
static uint8 key_buffer[KEY_BUFFER_SIZE];
static unsigned int key_read_ptr = 0, key_write_ptr = 0;

static uint8 mouse_reg_3[2] = {0x63, 0x01};     // Mouse ADB register 3

static uint8 key_reg_2[2] = {0xff, 0xff};       // Keyboard ADB register 2
static uint8 key_reg_3[2] = {0x62, 0x05};       // Keyboard ADB register 3

static uint8 m_keyboard_type = 0x05;

// ADB mouse motion lock (for platforms that use separate input thread)
static B2_mutex *mouse_lock;


/*
 *  Initialize ADB emulation
 */

void ADBInit(void)
{
        mouse_lock = B2_create_mutex();
        m_keyboard_type = (uint8)PrefsFindInt32("keyboardtype");
        key_reg_3[1] = m_keyboard_type;
}


/*
 *  Exit ADB emulation
 */

void ADBExit(void)
{
        if (mouse_lock) {
                B2_delete_mutex(mouse_lock);
                mouse_lock = NULL;
        }
}


/*
 *  ADBOp() replacement
 */

void ADBOp(uint8 op, uint8 *data)
{
        D(bug("ADBOp op %02x, data %02x %02x %02x\n", op, data[0], data[1], data[2]));

        // ADB reset?
        if ((op & 0x0f) == 0) {
                mouse_reg_3[0] = 0x63;
                mouse_reg_3[1] = 0x01;
                key_reg_2[0] = 0xff;
                key_reg_2[1] = 0xff;
                key_reg_3[0] = 0x62;
                key_reg_3[1] = m_keyboard_type;
                return;
        }

        // Cut op into fields
        uint8 adr = op >> 4;
        uint8 cmd = (op >> 2) & 3;
        uint8 reg = op & 3;

        // Check which device was addressed and act accordingly
        if (adr == (mouse_reg_3[0] & 0x0f)) {

                // Mouse
                if (cmd == 2) {

                        // Listen
                        switch (reg) {
                                case 3:         // Address/HandlerID
                                        if (data[2] == 0xfe)                    // Change address
                                                mouse_reg_3[0] = (mouse_reg_3[0] & 0xf0) | (data[1] & 0x0f);
                                        else if (data[2] == 1 || data[2] == 2 || data[2] == 4)  // Change device handler ID
                                                mouse_reg_3[1] = data[2];
                                        else if (data[2] == 0x00)               // Change address and enable bit
                                                mouse_reg_3[0] = (mouse_reg_3[0] & 0xd0) | (data[1] & 0x2f);
                                        break;
                        }

                } else if (cmd == 3) {

                        // Talk
                        switch (reg) {
                                case 1:         // Extended mouse protocol
                                        data[0] = 8;
                                        data[1] = 'a';                          // Identifier
                                        data[2] = 'p';
                                        data[3] = 'p';
                                        data[4] = 'l';
                                        data[5] = 300 >> 8;                     // Resolution (dpi)
                                        data[6] = 300 & 0xff;
                                        data[7] = 1;                            // Class (mouse)
                                        data[8] = 3;                            // Number of buttons
                                        break;
                                case 3:         // Address/HandlerID
                                        data[0] = 2;
                                        data[1] = mouse_reg_3[0] & 0xf0 | (rand() & 0x0f);
                                        data[2] = mouse_reg_3[1];
                                        break;
                                default:
                                        data[0] = 0;
                                        break;
                        }
                }
                D(bug(" mouse reg 3 %02x%02x\n", mouse_reg_3[0], mouse_reg_3[1]));

        } else if (adr == (key_reg_3[0] & 0x0f)) {

                // Keyboard
                if (cmd == 2) {

                        // Listen
                        switch (reg) {
                                case 2:         // LEDs/Modifiers
                                        key_reg_2[0] = data[1];
                                        key_reg_2[1] = data[2];
                                        break;
                                case 3:         // Address/HandlerID
                                        if (data[2] == 0xfe)                    // Change address
                                                        key_reg_3[0] = (key_reg_3[0] & 0xf0) | (data[1] & 0x0f);
                                        else if (data[2] == 0x00)               // Change address and enable bit
                                                key_reg_3[0] = (key_reg_3[0] & 0xd0) | (data[1] & 0x2f);
                                        break;
                        }

                } else if (cmd == 3) {

                        // Talk
                        switch (reg) {
                                case 2: {       // LEDs/Modifiers
                                        uint8 reg2hi = 0xff;
                                        uint8 reg2lo = key_reg_2[1] | 0xf8;
                                        if (MATRIX(0x6b))       // Scroll Lock
                                                reg2lo &= ~0x40;
                                        if (MATRIX(0x47))       // Num Lock
                                                reg2lo &= ~0x80;
                                        if (MATRIX(0x37))       // Command
                                                reg2hi &= ~0x01;
                                        if (MATRIX(0x3a))       // Option
                                                reg2hi &= ~0x02;
                                        if (MATRIX(0x38))       // Shift
                                                reg2hi &= ~0x04;
                                        if (MATRIX(0x36))       // Control
                                                reg2hi &= ~0x08;
                                        if (MATRIX(0x39))       // Caps Lock
                                                reg2hi &= ~0x20;
                                        if (MATRIX(0x75))       // Delete
                                                reg2hi &= ~0x40;
                                        data[0] = 2;
                                        data[1] = reg2hi;
                                        data[2] = reg2lo;
                                        break;
                                }
                                case 3:         // Address/HandlerID
                                        data[0] = 2;
                                        data[1] = key_reg_3[0] & 0xf0 | (rand() & 0x0f);
                                        data[2] = key_reg_3[1];
                                        break;
                                default:
                                        data[0] = 0;
                                        break;
                        }
                }
                D(bug(" keyboard reg 3 %02x%02x\n", key_reg_3[0], key_reg_3[1]));

        } else                                                                                          // Unknown address
                if (cmd == 3)
                        data[0] = 0;                                                            // Talk: 0 bytes of data
}


/*
 *  Mouse was moved (x/y are absolute or relative, depending on ADBSetRelMouseMode())
 */

void ADBMouseMoved(int x, int y)
{
        B2_lock_mutex(mouse_lock);
        if (relative_mouse) {
                mouse_x += x; mouse_y += y;
        } else {
                mouse_x = x; mouse_y = y;
        }
        B2_unlock_mutex(mouse_lock);
        SetInterruptFlag(INTFLAG_ADB);
        TriggerInterrupt();
}


/* 
 *  Mouse button pressed
 */

void ADBMouseDown(int button)
{
        mouse_button[button] = true;
        SetInterruptFlag(INTFLAG_ADB);
        TriggerInterrupt();
}


/*
 *  Mouse button released
 */

void ADBMouseUp(int button)
{
        mouse_button[button] = false;
        SetInterruptFlag(INTFLAG_ADB);
        TriggerInterrupt();
}


/*
 *  Set mouse mode (absolute or relative)
 */

void ADBSetRelMouseMode(bool relative)
{
        if (relative_mouse != relative) {
                relative_mouse = relative;
                mouse_x = mouse_y = 0;
        }
}


/*
 *  Key pressed ("code" is the Mac key code)
 */

void ADBKeyDown(int code)
{
        // Add keycode to buffer
        key_buffer[key_write_ptr] = code;
        key_write_ptr = (key_write_ptr + 1) % KEY_BUFFER_SIZE;

        // Set key in matrix
        key_states[code >> 3] |= (1 << (~code & 7));

        // Trigger interrupt
        SetInterruptFlag(INTFLAG_ADB);
        TriggerInterrupt();
}


/*
 *  Key released ("code" is the Mac key code)
 */

void ADBKeyUp(int code)
{
        // Add keycode to buffer
        key_buffer[key_write_ptr] = code | 0x80;        // Key-up flag
        key_write_ptr = (key_write_ptr + 1) % KEY_BUFFER_SIZE;

        // Clear key in matrix
        key_states[code >> 3] &= ~(1 << (~code & 7));

        // Trigger interrupt
        SetInterruptFlag(INTFLAG_ADB);
        TriggerInterrupt();
}


/*
 *  ADB interrupt function (executed as part of 60Hz interrupt)
 */

void ADBInterrupt(void)
{
        M68kRegisters r;

        // Return if ADB is not initialized
        uint32 adb_base = ReadMacInt32(0xcf8);
        if (!adb_base || adb_base == 0xffffffff)
                return;
        uint32 tmp_data = adb_base + 0x163;     // Temporary storage for faked ADB data

        // Get mouse state
        B2_lock_mutex(mouse_lock);
        int mx = mouse_x;
        int my = mouse_y;
        if (relative_mouse)
                mouse_x = mouse_y = 0;
        int mb[3] = {mouse_button[0], mouse_button[1], mouse_button[2]};
        B2_unlock_mutex(mouse_lock);

        uint32 key_base = adb_base + 4;
        uint32 mouse_base = adb_base + 16;

        if (relative_mouse) {

                // Mouse movement (relative) and buttons
                if (mx != 0 || my != 0 || mb[0] != old_mouse_button[0] || mb[1] != old_mouse_button[1] || mb[2] != old_mouse_button[2]) {

                        // Call mouse ADB handler
                        if (mouse_reg_3[1] == 4) {
                                // Extended mouse protocol
                                WriteMacInt8(tmp_data, 3);
                                WriteMacInt8(tmp_data + 1, (my & 0x7f) | (mb[0] ? 0 : 0x80));
                                WriteMacInt8(tmp_data + 2, (mx & 0x7f) | (mb[1] ? 0 : 0x80));
                                WriteMacInt8(tmp_data + 3, ((my >> 3) & 0x70) | ((mx >> 7) & 0x07) | (mb[2] ? 0x08 : 0x88));
                        } else {
                                // 100/200 dpi mode
                                WriteMacInt8(tmp_data, 2);
                                WriteMacInt8(tmp_data + 1, (my & 0x7f) | (mb[0] ? 0 : 0x80));
                                WriteMacInt8(tmp_data + 2, (mx & 0x7f) | (mb[1] ? 0 : 0x80));
                        }       
                        r.a[0] = tmp_data;
                        r.a[1] = ReadMacInt32(mouse_base);
                        r.a[2] = ReadMacInt32(mouse_base + 4);
                        r.a[3] = adb_base;
                        r.d[0] = (mouse_reg_3[0] << 4) | 0x0c;  // Talk 0
                        Execute68k(r.a[1], &r);

                        old_mouse_button[0] = mb[0];
                        old_mouse_button[1] = mb[1];
                        old_mouse_button[2] = mb[2];
                }

        } else {

                // Update mouse position (absolute)
                if (mx != old_mouse_x || my != old_mouse_y) {
#ifdef POWERPC_ROM
                        static const uint8 proc_template[] = {
                                0x2f, 0x08,             // move.l a0,-(sp)
                                0x2f, 0x00,             // move.l d0,-(sp)
                                0x2f, 0x01,             // move.l d1,-(sp)
                                0x70, 0x01,             // moveq #1,d0 (MoveTo)
                                0xaa, 0xdb,             // CursorDeviceDispatch
                                M68K_RTS >> 8, M68K_RTS & 0xff
                        };
                        BUILD_SHEEPSHAVER_PROCEDURE(proc);
                        r.a[0] = ReadMacInt32(mouse_base + 4);
                        r.d[0] = mx;
                        r.d[1] = my;
                        Execute68k(proc, &r);
#else
                        WriteMacInt16(0x82a, mx);
                        WriteMacInt16(0x828, my);
                        WriteMacInt16(0x82e, mx);
                        WriteMacInt16(0x82c, my);
                        WriteMacInt8(0x8ce, ReadMacInt8(0x8cf));        // CrsrCouple -> CrsrNew
#endif
                        old_mouse_x = mx;
                        old_mouse_y = my;
                }

                // Send mouse button events
                if (mb[0] != old_mouse_button[0] || mb[1] != old_mouse_button[1] || mb[2] != old_mouse_button[2]) {
                        uint32 mouse_base = adb_base + 16;

                        // Call mouse ADB handler
                        if (mouse_reg_3[1] == 4) {
                                // Extended mouse protocol
                                WriteMacInt8(tmp_data, 3);
                                WriteMacInt8(tmp_data + 1, mb[0] ? 0 : 0x80);
                                WriteMacInt8(tmp_data + 2, mb[1] ? 0 : 0x80);
                                WriteMacInt8(tmp_data + 3, mb[2] ? 0x08 : 0x88);
                        } else {
                                // 100/200 dpi mode
                                WriteMacInt8(tmp_data, 2);
                                WriteMacInt8(tmp_data + 1, mb[0] ? 0 : 0x80);
                                WriteMacInt8(tmp_data + 2, mb[1] ? 0 : 0x80);
                        }
                        r.a[0] = tmp_data;
                        r.a[1] = ReadMacInt32(mouse_base);
                        r.a[2] = ReadMacInt32(mouse_base + 4);
                        r.a[3] = adb_base;
                        r.d[0] = (mouse_reg_3[0] << 4) | 0x0c;  // Talk 0
                        Execute68k(r.a[1], &r);

                        old_mouse_button[0] = mb[0];
                        old_mouse_button[1] = mb[1];
                        old_mouse_button[2] = mb[2];
                }
        }

        // Process accumulated keyboard events
        while (key_read_ptr != key_write_ptr) {

                // Read keyboard event
                uint8 mac_code = key_buffer[key_read_ptr];
                key_read_ptr = (key_read_ptr + 1) % KEY_BUFFER_SIZE;

                // Call keyboard ADB handler
                WriteMacInt8(tmp_data, 2);
                WriteMacInt8(tmp_data + 1, mac_code);
                WriteMacInt8(tmp_data + 2, mac_code == 0x7f ? 0x7f : 0xff);     // Power key is special
                r.a[0] = tmp_data;
                r.a[1] = ReadMacInt32(key_base);
                r.a[2] = ReadMacInt32(key_base + 4);
                r.a[3] = adb_base;
                r.d[0] = (key_reg_3[0] << 4) | 0x0c;    // Talk 0
                Execute68k(r.a[1], &r);
        }

        // Clear temporary data
        WriteMacInt32(tmp_data, 0);
        WriteMacInt32(tmp_data + 4, 0);
}
Revision:	1.17
Committed:	2010-02-21T09:55:36Z (14 years, 2 months ago) by cebix
Branch:	MAIN
CVS Tags:	HEAD
Changes since 1.16:	+2 -2 lines
Log Message:	fixed compiler warnings
#	Content
1	/*
2	* adb.cpp - ADB emulation (mouse/keyboard)
3	*
4	* Basilisk II (C) 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
8	* the Free Software Foundation; either version 2 of the License, or
9	* (at your option) any later version.
10	*
11	* This program is distributed in the hope that it will be useful,
12	* but WITHOUT ANY WARRANTY; without even the implied warranty of
13	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14	* GNU General Public License for more details.
15	*
16	* You should have received a copy of the GNU General Public License
17	* along with this program; if not, write to the Free Software
18	* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
19	*/
20
21	/*
22	* SEE ALSO
23	* Inside Macintosh: Devices, chapter 5 "ADB Manager"
24	* Technote HW 01: "ADB - The Untold Story: Space Aliens Ate My Mouse"
25	*/
26
27	#include <stdlib.h>
28
29	#include "sysdeps.h"
30	#include "cpu_emulation.h"
31	#include "emul_op.h"
32	#include "main.h"
33	#include "prefs.h"
34	#include "video.h"
35	#include "adb.h"
36
37	#ifdef POWERPC_ROM
38	#include "thunks.h"
39	#endif
40
41	#define DEBUG 0
42	#include "debug.h"
43
44
45	// Global variables
46	static int mouse_x = 0, mouse_y = 0; // Mouse position
47	static int old_mouse_x = 0, old_mouse_y = 0;
48	static bool mouse_button[3] = {false, false, false}; // Mouse button states
49	static bool old_mouse_button[3] = {false, false, false};
50	static bool relative_mouse = false;
51
52	static uint8 key_states[16]; // Key states (Mac keycodes)
53	#define MATRIX(code) (key_states[code >> 3] & (1 << (~code & 7)))
54
55	// Keyboard event buffer (Mac keycodes with up/down flag)
56	const int KEY_BUFFER_SIZE = 16;
57	static uint8 key_buffer[KEY_BUFFER_SIZE];
58	static unsigned int key_read_ptr = 0, key_write_ptr = 0;
59
60	static uint8 mouse_reg_3[2] = {0x63, 0x01}; // Mouse ADB register 3
61
62	static uint8 key_reg_2[2] = {0xff, 0xff}; // Keyboard ADB register 2
63	static uint8 key_reg_3[2] = {0x62, 0x05}; // Keyboard ADB register 3
64
65	static uint8 m_keyboard_type = 0x05;
66
67	// ADB mouse motion lock (for platforms that use separate input thread)
68	static B2_mutex *mouse_lock;
69
70
71	/*
72	* Initialize ADB emulation
73	*/
74
75	void ADBInit(void)
76	{
77	mouse_lock = B2_create_mutex();
78	m_keyboard_type = (uint8)PrefsFindInt32("keyboardtype");
79	key_reg_3[1] = m_keyboard_type;
80	}
81
82
83	/*
84	* Exit ADB emulation
85	*/
86
87	void ADBExit(void)
88	{
89	if (mouse_lock) {
90	B2_delete_mutex(mouse_lock);
91	mouse_lock = NULL;
92	}
93	}
94
95
96	/*
97	* ADBOp() replacement
98	*/
99
100	void ADBOp(uint8 op, uint8 *data)
101	{
102	D(bug("ADBOp op %02x, data %02x %02x %02x\n", op, data[0], data[1], data[2]));
103
104	// ADB reset?
105	if ((op & 0x0f) == 0) {
106	mouse_reg_3[0] = 0x63;
107	mouse_reg_3[1] = 0x01;
108	key_reg_2[0] = 0xff;
109	key_reg_2[1] = 0xff;
110	key_reg_3[0] = 0x62;
111	key_reg_3[1] = m_keyboard_type;
112	return;
113	}
114
115	// Cut op into fields
116	uint8 adr = op >> 4;
117	uint8 cmd = (op >> 2) & 3;
118	uint8 reg = op & 3;
119
120	// Check which device was addressed and act accordingly
121	if (adr == (mouse_reg_3[0] & 0x0f)) {
122
123	// Mouse
124	if (cmd == 2) {
125
126	// Listen
127	switch (reg) {
128	case 3: // Address/HandlerID
129	if (data[2] == 0xfe) // Change address
130	mouse_reg_3[0] = (mouse_reg_3[0] & 0xf0) \| (data[1] & 0x0f);
131	else if (data[2] == 1 \|\| data[2] == 2 \|\| data[2] == 4) // Change device handler ID
132	mouse_reg_3[1] = data[2];
133	else if (data[2] == 0x00) // Change address and enable bit
134	mouse_reg_3[0] = (mouse_reg_3[0] & 0xd0) \| (data[1] & 0x2f);
135	break;
136	}
137
138	} else if (cmd == 3) {
139
140	// Talk
141	switch (reg) {
142	case 1: // Extended mouse protocol
143	data[0] = 8;
144	data[1] = 'a'; // Identifier
145	data[2] = 'p';
146	data[3] = 'p';
147	data[4] = 'l';
148	data[5] = 300 >> 8; // Resolution (dpi)
149	data[6] = 300 & 0xff;
150	data[7] = 1; // Class (mouse)
151	data[8] = 3; // Number of buttons
152	break;
153	case 3: // Address/HandlerID
154	data[0] = 2;
155	data[1] = mouse_reg_3[0] & 0xf0 \| (rand() & 0x0f);
156	data[2] = mouse_reg_3[1];
157	break;
158	default:
159	data[0] = 0;
160	break;
161	}
162	}
163	D(bug(" mouse reg 3 %02x%02x\n", mouse_reg_3[0], mouse_reg_3[1]));
164
165	} else if (adr == (key_reg_3[0] & 0x0f)) {
166
167	// Keyboard
168	if (cmd == 2) {
169
170	// Listen
171	switch (reg) {
172	case 2: // LEDs/Modifiers
173	key_reg_2[0] = data[1];
174	key_reg_2[1] = data[2];
175	break;
176	case 3: // Address/HandlerID
177	if (data[2] == 0xfe) // Change address
178	key_reg_3[0] = (key_reg_3[0] & 0xf0) \| (data[1] & 0x0f);
179	else if (data[2] == 0x00) // Change address and enable bit
180	key_reg_3[0] = (key_reg_3[0] & 0xd0) \| (data[1] & 0x2f);
181	break;
182	}
183
184	} else if (cmd == 3) {
185
186	// Talk
187	switch (reg) {
188	case 2: { // LEDs/Modifiers
189	uint8 reg2hi = 0xff;
190	uint8 reg2lo = key_reg_2[1] \| 0xf8;
191	if (MATRIX(0x6b)) // Scroll Lock
192	reg2lo &= ~0x40;
193	if (MATRIX(0x47)) // Num Lock
194	reg2lo &= ~0x80;
195	if (MATRIX(0x37)) // Command
196	reg2hi &= ~0x01;
197	if (MATRIX(0x3a)) // Option
198	reg2hi &= ~0x02;
199	if (MATRIX(0x38)) // Shift
200	reg2hi &= ~0x04;
201	if (MATRIX(0x36)) // Control
202	reg2hi &= ~0x08;
203	if (MATRIX(0x39)) // Caps Lock
204	reg2hi &= ~0x20;
205	if (MATRIX(0x75)) // Delete
206	reg2hi &= ~0x40;
207	data[0] = 2;
208	data[1] = reg2hi;
209	data[2] = reg2lo;
210	break;
211	}
212	case 3: // Address/HandlerID
213	data[0] = 2;
214	data[1] = key_reg_3[0] & 0xf0 \| (rand() & 0x0f);
215	data[2] = key_reg_3[1];
216	break;
217	default:
218	data[0] = 0;
219	break;
220	}
221	}
222	D(bug(" keyboard reg 3 %02x%02x\n", key_reg_3[0], key_reg_3[1]));
223
224	} else // Unknown address
225	if (cmd == 3)
226	data[0] = 0; // Talk: 0 bytes of data
227	}
228
229
230	/*
231	* Mouse was moved (x/y are absolute or relative, depending on ADBSetRelMouseMode())
232	*/
233
234	void ADBMouseMoved(int x, int y)
235	{
236	B2_lock_mutex(mouse_lock);
237	if (relative_mouse) {
238	mouse_x += x; mouse_y += y;
239	} else {
240	mouse_x = x; mouse_y = y;
241	}
242	B2_unlock_mutex(mouse_lock);
243	SetInterruptFlag(INTFLAG_ADB);
244	TriggerInterrupt();
245	}
246
247
248	/*
249	* Mouse button pressed
250	*/
251
252	void ADBMouseDown(int button)
253	{
254	mouse_button[button] = true;
255	SetInterruptFlag(INTFLAG_ADB);
256	TriggerInterrupt();
257	}
258
259
260	/*
261	* Mouse button released
262	*/
263
264	void ADBMouseUp(int button)
265	{
266	mouse_button[button] = false;
267	SetInterruptFlag(INTFLAG_ADB);
268	TriggerInterrupt();
269	}
270
271
272	/*
273	* Set mouse mode (absolute or relative)
274	*/
275
276	void ADBSetRelMouseMode(bool relative)
277	{
278	if (relative_mouse != relative) {
279	relative_mouse = relative;
280	mouse_x = mouse_y = 0;
281	}
282	}
283
284
285	/*
286	* Key pressed ("code" is the Mac key code)
287	*/
288
289	void ADBKeyDown(int code)
290	{
291	// Add keycode to buffer
292	key_buffer[key_write_ptr] = code;
293	key_write_ptr = (key_write_ptr + 1) % KEY_BUFFER_SIZE;
294
295	// Set key in matrix
296	key_states[code >> 3] \|= (1 << (~code & 7));
297
298	// Trigger interrupt
299	SetInterruptFlag(INTFLAG_ADB);
300	TriggerInterrupt();
301	}
302
303
304	/*
305	* Key released ("code" is the Mac key code)
306	*/
307
308	void ADBKeyUp(int code)
309	{
310	// Add keycode to buffer
311	key_buffer[key_write_ptr] = code \| 0x80; // Key-up flag
312	key_write_ptr = (key_write_ptr + 1) % KEY_BUFFER_SIZE;
313
314	// Clear key in matrix
315	key_states[code >> 3] &= ~(1 << (~code & 7));
316
317	// Trigger interrupt
318	SetInterruptFlag(INTFLAG_ADB);
319	TriggerInterrupt();
320	}
321
322
323	/*
324	* ADB interrupt function (executed as part of 60Hz interrupt)
325	*/
326
327	void ADBInterrupt(void)
328	{
329	M68kRegisters r;
330
331	// Return if ADB is not initialized
332	uint32 adb_base = ReadMacInt32(0xcf8);
333	if (!adb_base \|\| adb_base == 0xffffffff)
334	return;
335	uint32 tmp_data = adb_base + 0x163; // Temporary storage for faked ADB data
336
337	// Get mouse state
338	B2_lock_mutex(mouse_lock);
339	int mx = mouse_x;
340	int my = mouse_y;
341	if (relative_mouse)
342	mouse_x = mouse_y = 0;
343	int mb[3] = {mouse_button[0], mouse_button[1], mouse_button[2]};
344	B2_unlock_mutex(mouse_lock);
345
346	uint32 key_base = adb_base + 4;
347	uint32 mouse_base = adb_base + 16;
348
349	if (relative_mouse) {
350
351	// Mouse movement (relative) and buttons
352	if (mx != 0 \|\| my != 0 \|\| mb[0] != old_mouse_button[0] \|\| mb[1] != old_mouse_button[1] \|\| mb[2] != old_mouse_button[2]) {
353
354	// Call mouse ADB handler
355	if (mouse_reg_3[1] == 4) {
356	// Extended mouse protocol
357	WriteMacInt8(tmp_data, 3);
358	WriteMacInt8(tmp_data + 1, (my & 0x7f) \| (mb[0] ? 0 : 0x80));
359	WriteMacInt8(tmp_data + 2, (mx & 0x7f) \| (mb[1] ? 0 : 0x80));
360	WriteMacInt8(tmp_data + 3, ((my >> 3) & 0x70) \| ((mx >> 7) & 0x07) \| (mb[2] ? 0x08 : 0x88));
361	} else {
362	// 100/200 dpi mode
363	WriteMacInt8(tmp_data, 2);
364	WriteMacInt8(tmp_data + 1, (my & 0x7f) \| (mb[0] ? 0 : 0x80));
365	WriteMacInt8(tmp_data + 2, (mx & 0x7f) \| (mb[1] ? 0 : 0x80));
366	}
367	r.a[0] = tmp_data;
368	r.a[1] = ReadMacInt32(mouse_base);
369	r.a[2] = ReadMacInt32(mouse_base + 4);
370	r.a[3] = adb_base;
371	r.d[0] = (mouse_reg_3[0] << 4) \| 0x0c; // Talk 0
372	Execute68k(r.a[1], &r);
373
374	old_mouse_button[0] = mb[0];
375	old_mouse_button[1] = mb[1];
376	old_mouse_button[2] = mb[2];
377	}
378
379	} else {
380
381	// Update mouse position (absolute)
382	if (mx != old_mouse_x \|\| my != old_mouse_y) {
383	#ifdef POWERPC_ROM
384	static const uint8 proc_template[] = {
385	0x2f, 0x08, // move.l a0,-(sp)
386	0x2f, 0x00, // move.l d0,-(sp)
387	0x2f, 0x01, // move.l d1,-(sp)
388	0x70, 0x01, // moveq #1,d0 (MoveTo)
389	0xaa, 0xdb, // CursorDeviceDispatch
390	M68K_RTS >> 8, M68K_RTS & 0xff
391	};
392	BUILD_SHEEPSHAVER_PROCEDURE(proc);
393	r.a[0] = ReadMacInt32(mouse_base + 4);
394	r.d[0] = mx;
395	r.d[1] = my;
396	Execute68k(proc, &r);
397	#else
398	WriteMacInt16(0x82a, mx);
399	WriteMacInt16(0x828, my);
400	WriteMacInt16(0x82e, mx);
401	WriteMacInt16(0x82c, my);
402	WriteMacInt8(0x8ce, ReadMacInt8(0x8cf)); // CrsrCouple -> CrsrNew
403	#endif
404	old_mouse_x = mx;
405	old_mouse_y = my;
406	}
407
408	// Send mouse button events
409	if (mb[0] != old_mouse_button[0] \|\| mb[1] != old_mouse_button[1] \|\| mb[2] != old_mouse_button[2]) {
410	uint32 mouse_base = adb_base + 16;
411
412	// Call mouse ADB handler
413	if (mouse_reg_3[1] == 4) {
414	// Extended mouse protocol
415	WriteMacInt8(tmp_data, 3);
416	WriteMacInt8(tmp_data + 1, mb[0] ? 0 : 0x80);
417	WriteMacInt8(tmp_data + 2, mb[1] ? 0 : 0x80);
418	WriteMacInt8(tmp_data + 3, mb[2] ? 0x08 : 0x88);
419	} else {
420	// 100/200 dpi mode
421	WriteMacInt8(tmp_data, 2);
422	WriteMacInt8(tmp_data + 1, mb[0] ? 0 : 0x80);
423	WriteMacInt8(tmp_data + 2, mb[1] ? 0 : 0x80);
424	}
425	r.a[0] = tmp_data;
426	r.a[1] = ReadMacInt32(mouse_base);
427	r.a[2] = ReadMacInt32(mouse_base + 4);
428	r.a[3] = adb_base;
429	r.d[0] = (mouse_reg_3[0] << 4) \| 0x0c; // Talk 0
430	Execute68k(r.a[1], &r);
431
432	old_mouse_button[0] = mb[0];
433	old_mouse_button[1] = mb[1];
434	old_mouse_button[2] = mb[2];
435	}
436	}
437
438	// Process accumulated keyboard events
439	while (key_read_ptr != key_write_ptr) {
440
441	// Read keyboard event
442	uint8 mac_code = key_buffer[key_read_ptr];
443	key_read_ptr = (key_read_ptr + 1) % KEY_BUFFER_SIZE;
444
445	// Call keyboard ADB handler
446	WriteMacInt8(tmp_data, 2);
447	WriteMacInt8(tmp_data + 1, mac_code);
448	WriteMacInt8(tmp_data + 2, mac_code == 0x7f ? 0x7f : 0xff); // Power key is special
449	r.a[0] = tmp_data;
450	r.a[1] = ReadMacInt32(key_base);
451	r.a[2] = ReadMacInt32(key_base + 4);
452	r.a[3] = adb_base;
453	r.d[0] = (key_reg_3[0] << 4) \| 0x0c; // Talk 0
454	Execute68k(r.a[1], &r);
455	}
456
457	// Clear temporary data
458	WriteMacInt32(tmp_data, 0);
459	WriteMacInt32(tmp_data + 4, 0);
460	}