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1 | /* |
1 | /* |
2 | * Copyright (C) 2006 Josef Cejka |
2 | * Copyright (C) 2006 Josef Cejka |
3 | * All rights reserved. |
3 | * All rights reserved. |
4 | * |
4 | * |
5 | * Redistribution and use in source and binary forms, with or without |
5 | * Redistribution and use in source and binary forms, with or without |
6 | * modification, are permitted provided that the following conditions |
6 | * modification, are permitted provided that the following conditions |
7 | * are met: |
7 | * are met: |
8 | * |
8 | * |
9 | * - Redistributions of source code must retain the above copyright |
9 | * - Redistributions of source code must retain the above copyright |
10 | * notice, this list of conditions and the following disclaimer. |
10 | * notice, this list of conditions and the following disclaimer. |
11 | * - Redistributions in binary form must reproduce the above copyright |
11 | * - Redistributions in binary form must reproduce the above copyright |
12 | * notice, this list of conditions and the following disclaimer in the |
12 | * notice, this list of conditions and the following disclaimer in the |
13 | * documentation and/or other materials provided with the distribution. |
13 | * documentation and/or other materials provided with the distribution. |
14 | * - The name of the author may not be used to endorse or promote products |
14 | * - The name of the author may not be used to endorse or promote products |
15 | * derived from this software without specific prior written permission. |
15 | * derived from this software without specific prior written permission. |
16 | * |
16 | * |
17 | * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR |
17 | * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR |
18 | * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES |
18 | * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES |
19 | * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. |
19 | * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. |
20 | * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, |
20 | * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, |
21 | * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT |
21 | * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT |
22 | * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
22 | * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
23 | * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
23 | * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
24 | * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
24 | * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
25 | * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF |
25 | * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF |
26 | * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
26 | * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
27 | */ |
27 | */ |
28 | 28 | ||
29 | #include <arch/kbd.h> |
29 | #include <arch/kbd.h> |
30 | #include <ipc/ipc.h> |
30 | #include <ipc/ipc.h> |
31 | #include <sysinfo.h> |
31 | #include <sysinfo.h> |
32 | 32 | ||
33 | 33 | ||
34 | #define MSIM_KEY_F1 0x504f1bL |
34 | #define MSIM_KEY_F1 0x504f1bL |
35 | #define MSIM_KEY_F2 0x514f1bL |
35 | #define MSIM_KEY_F2 0x514f1bL |
36 | #define MSIM_KEY_F3 0x524f1bL |
36 | #define MSIM_KEY_F3 0x524f1bL |
37 | #define MSIM_KEY_F4 0x534f1bL |
37 | #define MSIM_KEY_F4 0x534f1bL |
38 | #define MSIM_KEY_F5 0x35315b1bL |
38 | #define MSIM_KEY_F5 0x35315b1bL |
39 | #define MSIM_KEY_F6 0x37315b1bL |
39 | #define MSIM_KEY_F6 0x37315b1bL |
40 | #define MSIM_KEY_F7 0x38315b1bL |
40 | #define MSIM_KEY_F7 0x38315b1bL |
41 | #define MSIM_KEY_F8 0x39315b1bL |
41 | #define MSIM_KEY_F8 0x39315b1bL |
42 | #define MSIM_KEY_F9 0x30325b1bL |
42 | #define MSIM_KEY_F9 0x30325b1bL |
43 | #define MSIM_KEY_F10 0x31325b1bL |
43 | #define MSIM_KEY_F10 0x31325b1bL |
44 | #define MSIM_KEY_F11 0x33325b1bL |
44 | #define MSIM_KEY_F11 0x33325b1bL |
45 | #define MSIM_KEY_F12 0x34325b1bL |
45 | #define MSIM_KEY_F12 0x34325b1bL |
46 | 46 | ||
47 | 47 | ||
48 | #define GXEMUL_KEY_F1 0x504f5b1bL |
48 | #define GXEMUL_KEY_F1 0x504f5b1bL |
49 | #define GXEMUL_KEY_F2 0x514f5b1bL |
49 | #define GXEMUL_KEY_F2 0x514f5b1bL |
50 | #define GXEMUL_KEY_F3 0x524f5b1bL |
50 | #define GXEMUL_KEY_F3 0x524f5b1bL |
51 | #define GXEMUL_KEY_F4 0x534f5b1bL |
51 | #define GXEMUL_KEY_F4 0x534f5b1bL |
52 | #define GXEMUL_KEY_F5 0x35315b1bL |
52 | #define GXEMUL_KEY_F5 0x35315b1bL |
53 | #define GXEMUL_KEY_F6 0x37315b1bL |
53 | #define GXEMUL_KEY_F6 0x37315b1bL |
54 | #define GXEMUL_KEY_F7 0x38315b1bL |
54 | #define GXEMUL_KEY_F7 0x38315b1bL |
55 | #define GXEMUL_KEY_F8 0x39315b1bL |
55 | #define GXEMUL_KEY_F8 0x39315b1bL |
56 | #define GXEMUL_KEY_F9 0x38325b1bL |
56 | #define GXEMUL_KEY_F9 0x38325b1bL |
57 | #define GXEMUL_KEY_F10 0x39325b1bL |
57 | #define GXEMUL_KEY_F10 0x39325b1bL |
58 | #define GXEMUL_KEY_F11 0x33325b1bL |
58 | #define GXEMUL_KEY_F11 0x33325b1bL |
59 | #define GXEMUL_KEY_F12 0x34325b1bL |
59 | #define GXEMUL_KEY_F12 0x34325b1bL |
60 | 60 | ||
61 | 61 | ||
62 | #define FUNCTION_KEYS 0x100 |
62 | #define FUNCTION_KEYS 0x100 |
63 | 63 | ||
64 | 64 | ||
65 | irq_cmd_t msim_cmds[1] = { |
65 | irq_cmd_t msim_cmds[1] = { |
66 | { CMD_MEM_READ_1, (void *)0xB0000000, 0 } |
66 | { CMD_MEM_READ_1, (void *)0xB0000000, 0 } |
67 | }; |
67 | }; |
68 | 68 | ||
69 | irq_code_t msim_kbd = { |
69 | irq_code_t msim_kbd = { |
70 | 1, |
70 | 1, |
71 | msim_cmds |
71 | msim_cmds |
72 | }; |
72 | }; |
73 | 73 | ||
74 | static int msim,gxemul; |
74 | static int msim,gxemul; |
75 | 75 | ||
76 | int kbd_arch_init(void) |
76 | int kbd_arch_init(void) |
77 | { |
77 | { |
78 | ipc_register_irq(2, &msim_kbd); |
78 | ipc_register_irq(2, &msim_kbd); |
79 | msim=sysinfo_value("machine.msim"); |
79 | msim=sysinfo_value("machine.msim"); |
80 | gxemul=sysinfo_value("machine.lgxemul"); |
80 | gxemul=sysinfo_value("machine.lgxemul"); |
81 | return 1; |
81 | return 1; |
82 | } |
82 | } |
83 | 83 | ||
84 | 84 | ||
85 | //* |
85 | //* |
86 | //* |
86 | //* |
87 | //* Please preserve this code (it can be used to determine scancodes) |
87 | //* Please preserve this code (it can be used to determine scancodes) |
88 | //* |
88 | //* |
89 | int to_hex(int v) |
89 | int to_hex(int v) |
90 | { |
90 | { |
91 | return "0123456789ABCDEF"[v]; |
91 | return "0123456789ABCDEF"[v]; |
92 | } |
92 | } |
93 | //*/ |
93 | //*/ |
94 | 94 | ||
95 | static int kbd_arch_process_msim(keybuffer_t *keybuffer, int scan_code) |
95 | static int kbd_arch_process_msim(keybuffer_t *keybuffer, int scan_code) |
96 | { |
96 | { |
97 | 97 | ||
98 | static unsigned long buf=0; |
98 | static unsigned long buf=0; |
99 | static int count=0; |
99 | static int count=0; |
100 | 100 | ||
101 | 101 | ||
102 | //* Please preserve this code (it can be used to determine scancodes) |
102 | //* Please preserve this code (it can be used to determine scancodes) |
103 | //* |
103 | //* |
104 | //keybuffer_push(keybuffer, to_hex((scan_code>>4)&0xf)); |
104 | //keybuffer_push(keybuffer, to_hex((scan_code>>4)&0xf)); |
105 | //keybuffer_push(keybuffer, to_hex(scan_code&0xf)); |
105 | //keybuffer_push(keybuffer, to_hex(scan_code&0xf)); |
106 | //keybuffer_push(keybuffer, ' '); |
106 | //keybuffer_push(keybuffer, ' '); |
107 | //keybuffer_push(keybuffer, ' '); |
107 | //keybuffer_push(keybuffer, ' '); |
108 | //*/ |
108 | //*/ |
109 | //return 1; |
109 | //return 1; |
110 | 110 | ||
111 | 111 | ||
112 | if(scan_code==0x7e) |
112 | if(scan_code==0x7e) |
113 | { |
113 | { |
114 | switch (buf){ |
114 | switch (buf){ |
115 | case MSIM_KEY_F5: |
115 | case MSIM_KEY_F5: |
116 | keybuffer_push(keybuffer,FUNCTION_KEYS | 5 ); |
116 | keybuffer_push(keybuffer,FUNCTION_KEYS | 5 ); |
117 | buf=count=0; |
117 | buf=count=0; |
118 | return 1; |
118 | return 1; |
119 | case MSIM_KEY_F6: |
119 | case MSIM_KEY_F6: |
120 | keybuffer_push(keybuffer,FUNCTION_KEYS | 6 ); |
120 | keybuffer_push(keybuffer,FUNCTION_KEYS | 6 ); |
121 | buf=count=0; |
121 | buf=count=0; |
122 | return 1; |
122 | return 1; |
123 | case MSIM_KEY_F7: |
123 | case MSIM_KEY_F7: |
124 | keybuffer_push(keybuffer,FUNCTION_KEYS | 7 ); |
124 | keybuffer_push(keybuffer,FUNCTION_KEYS | 7 ); |
125 | buf=count=0; |
125 | buf=count=0; |
126 | return 1; |
126 | return 1; |
127 | case MSIM_KEY_F8: |
127 | case MSIM_KEY_F8: |
128 | keybuffer_push(keybuffer,FUNCTION_KEYS | 8 ); |
128 | keybuffer_push(keybuffer,FUNCTION_KEYS | 8 ); |
129 | buf=count=0; |
129 | buf=count=0; |
130 | return 1; |
130 | return 1; |
131 | 131 | ||
132 | case MSIM_KEY_F9: |
132 | case MSIM_KEY_F9: |
133 | keybuffer_push(keybuffer,FUNCTION_KEYS | 9 ); |
133 | keybuffer_push(keybuffer,FUNCTION_KEYS | 9 ); |
134 | buf=count=0; |
134 | buf=count=0; |
135 | return 1; |
135 | return 1; |
136 | case MSIM_KEY_F10: |
136 | case MSIM_KEY_F10: |
137 | keybuffer_push(keybuffer,FUNCTION_KEYS | 10 ); |
137 | keybuffer_push(keybuffer,FUNCTION_KEYS | 10 ); |
138 | buf=count=0; |
138 | buf=count=0; |
139 | return 1; |
139 | return 1; |
140 | 140 | ||
141 | case MSIM_KEY_F11: |
141 | case MSIM_KEY_F11: |
142 | keybuffer_push(keybuffer,FUNCTION_KEYS | 11 ); |
142 | keybuffer_push(keybuffer,FUNCTION_KEYS | 11 ); |
143 | buf=count=0; |
143 | buf=count=0; |
144 | return 1; |
144 | return 1; |
145 | case MSIM_KEY_F12: |
145 | case MSIM_KEY_F12: |
146 | keybuffer_push(keybuffer,FUNCTION_KEYS | 12 ); |
146 | keybuffer_push(keybuffer,FUNCTION_KEYS | 12 ); |
147 | buf=count=0; |
147 | buf=count=0; |
148 | return 1; |
148 | return 1; |
149 | default: |
149 | default: |
150 | keybuffer_push(keybuffer, buf & 0xff ); |
150 | keybuffer_push(keybuffer, buf & 0xff ); |
151 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
151 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
152 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
152 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
153 | keybuffer_push(keybuffer, (buf >> 24) &0xff ); |
153 | keybuffer_push(keybuffer, (buf >> 24) &0xff ); |
154 | keybuffer_push(keybuffer, scan_code ); |
154 | keybuffer_push(keybuffer, scan_code ); |
155 | buf=count=0; |
155 | buf=count=0; |
156 | return 1; |
156 | return 1; |
157 | 157 | ||
158 | } |
158 | } |
159 | } |
159 | } |
160 | 160 | ||
161 | buf|=((unsigned long) scan_code)<<(8*(count++)); |
161 | buf|=((unsigned long) scan_code)<<(8*(count++)); |
162 | 162 | ||
163 | 163 | ||
164 | if((buf & 0xff)!= (MSIM_KEY_F1 & 0xff)) { |
164 | if((buf & 0xff)!= (MSIM_KEY_F1 & 0xff)) { |
165 | 165 | ||
166 | keybuffer_push(keybuffer,buf ); |
166 | keybuffer_push(keybuffer,buf ); |
167 | buf=count=0; |
167 | buf=count=0; |
168 | return 1; |
168 | return 1; |
169 | } |
169 | } |
170 | 170 | ||
171 | if ( count <= 1 ) |
171 | if ( count <= 1 ) |
172 | return 1; |
172 | return 1; |
173 | 173 | ||
174 | if( (buf & 0xffff) != (MSIM_KEY_F1 & 0xffff) |
174 | if( (buf & 0xffff) != (MSIM_KEY_F1 & 0xffff) |
175 | && (buf & 0xffff) != (MSIM_KEY_F5 & 0xffff) ) { |
175 | && (buf & 0xffff) != (MSIM_KEY_F5 & 0xffff) ) { |
176 | 176 | ||
177 | keybuffer_push(keybuffer, buf & 0xff ); |
177 | keybuffer_push(keybuffer, buf & 0xff ); |
178 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
178 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
179 | buf=count=0; |
179 | buf=count=0; |
180 | return 1; |
180 | return 1; |
181 | } |
181 | } |
182 | 182 | ||
183 | if ( count <= 2) |
183 | if ( count <= 2) |
184 | return 1; |
184 | return 1; |
185 | 185 | ||
186 | switch (buf){ |
186 | switch (buf){ |
187 | case MSIM_KEY_F1: |
187 | case MSIM_KEY_F1: |
188 | keybuffer_push(keybuffer,FUNCTION_KEYS | 1 ); |
188 | keybuffer_push(keybuffer,FUNCTION_KEYS | 1 ); |
189 | buf=count=0; |
189 | buf=count=0; |
190 | return 1; |
190 | return 1; |
191 | case MSIM_KEY_F2: |
191 | case MSIM_KEY_F2: |
192 | keybuffer_push(keybuffer,FUNCTION_KEYS | 2 ); |
192 | keybuffer_push(keybuffer,FUNCTION_KEYS | 2 ); |
193 | buf=count=0; |
193 | buf=count=0; |
194 | return 1; |
194 | return 1; |
195 | case MSIM_KEY_F3: |
195 | case MSIM_KEY_F3: |
196 | keybuffer_push(keybuffer,FUNCTION_KEYS | 3 ); |
196 | keybuffer_push(keybuffer,FUNCTION_KEYS | 3 ); |
197 | buf=count=0; |
197 | buf=count=0; |
198 | return 1; |
198 | return 1; |
199 | case MSIM_KEY_F4: |
199 | case MSIM_KEY_F4: |
200 | keybuffer_push(keybuffer,FUNCTION_KEYS | 4 ); |
200 | keybuffer_push(keybuffer,FUNCTION_KEYS | 4 ); |
201 | buf=count=0; |
201 | buf=count=0; |
202 | return 1; |
202 | return 1; |
203 | } |
203 | } |
204 | 204 | ||
205 | 205 | ||
206 | if( (buf & 0xffffff) != (MSIM_KEY_F5 & 0xffffff) |
206 | if( (buf & 0xffffff) != (MSIM_KEY_F5 & 0xffffff) |
207 | && (buf & 0xffffff) != (MSIM_KEY_F9 & 0xffffff) ) { |
207 | && (buf & 0xffffff) != (MSIM_KEY_F9 & 0xffffff) ) { |
208 | 208 | ||
209 | keybuffer_push(keybuffer, buf & 0xff ); |
209 | keybuffer_push(keybuffer, buf & 0xff ); |
210 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
210 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
211 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
211 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
212 | buf=count=0; |
212 | buf=count=0; |
213 | return 1; |
213 | return 1; |
214 | } |
214 | } |
215 | 215 | ||
216 | if ( count <= 3 ) |
216 | if ( count <= 3 ) |
217 | return 1; |
217 | return 1; |
218 | 218 | ||
219 | 219 | ||
220 | 220 | ||
221 | 221 | ||
222 | switch (buf){ |
222 | switch (buf){ |
223 | case MSIM_KEY_F5: |
223 | case MSIM_KEY_F5: |
224 | case MSIM_KEY_F6: |
224 | case MSIM_KEY_F6: |
225 | case MSIM_KEY_F7: |
225 | case MSIM_KEY_F7: |
226 | case MSIM_KEY_F8: |
226 | case MSIM_KEY_F8: |
227 | case MSIM_KEY_F9: |
227 | case MSIM_KEY_F9: |
228 | case MSIM_KEY_F10: |
228 | case MSIM_KEY_F10: |
229 | case MSIM_KEY_F11: |
229 | case MSIM_KEY_F11: |
230 | case MSIM_KEY_F12: |
230 | case MSIM_KEY_F12: |
231 | return 1; |
231 | return 1; |
232 | default: |
232 | default: |
233 | keybuffer_push(keybuffer, buf & 0xff ); |
233 | keybuffer_push(keybuffer, buf & 0xff ); |
234 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
234 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
235 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
235 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
236 | keybuffer_push(keybuffer, (buf >> 24) &0xff ); |
236 | keybuffer_push(keybuffer, (buf >> 24) &0xff ); |
237 | buf=count=0; |
237 | buf=count=0; |
238 | return 1; |
238 | return 1; |
239 | 239 | ||
240 | } |
240 | } |
241 | return 1; |
241 | return 1; |
242 | } |
242 | } |
243 | 243 | ||
244 | 244 | ||
245 | 245 | ||
246 | static int kbd_arch_process_gxemul(keybuffer_t *keybuffer, int scan_code) |
246 | static int kbd_arch_process_gxemul(keybuffer_t *keybuffer, int scan_code) |
247 | { |
247 | { |
248 | 248 | ||
249 | static unsigned long buf=0; |
249 | static unsigned long buf=0; |
250 | static int count=0; |
250 | static int count=0; |
251 | 251 | ||
252 | 252 | ||
253 | //* Please preserve this code (it can be used to determine scancodes) |
253 | //* Please preserve this code (it can be used to determine scancodes) |
254 | //* |
254 | //* |
255 | //keybuffer_push(keybuffer, to_hex((scan_code>>4)&0xf)); |
255 | //keybuffer_push(keybuffer, to_hex((scan_code>>4)&0xf)); |
256 | //keybuffer_push(keybuffer, to_hex(scan_code&0xf)); |
256 | //keybuffer_push(keybuffer, to_hex(scan_code&0xf)); |
257 | //keybuffer_push(keybuffer, ' '); |
257 | //keybuffer_push(keybuffer, ' '); |
258 | //keybuffer_push(keybuffer, ' '); |
258 | //keybuffer_push(keybuffer, ' '); |
259 | //*/ |
259 | //*/ |
260 | //return 1; |
260 | //return 1; |
261 | 261 | ||
- | 262 | ||
- | 263 | if ( scan_code == '\r' ) |
|
- | 264 | scan_code = '\n' ; |
|
- | 265 | ||
262 | buf|=((unsigned long) scan_code)<<(8*(count++)); |
266 | buf|=((unsigned long) scan_code)<<(8*(count++)); |
263 | 267 | ||
264 | 268 | ||
265 | if((buf & 0xff)!= (GXEMUL_KEY_F1 & 0xff)) { |
269 | if((buf & 0xff)!= (GXEMUL_KEY_F1 & 0xff)) { |
266 | 270 | ||
267 | keybuffer_push(keybuffer,buf ); |
271 | keybuffer_push(keybuffer,buf ); |
268 | buf=count=0; |
272 | buf=count=0; |
269 | return 1; |
273 | return 1; |
270 | } |
274 | } |
271 | 275 | ||
272 | if ( count <= 1 ) |
276 | if ( count <= 1 ) |
273 | return 1; |
277 | return 1; |
274 | 278 | ||
275 | if( (buf & 0xffff) != (GXEMUL_KEY_F1 & 0xffff) ) { |
279 | if( (buf & 0xffff) != (GXEMUL_KEY_F1 & 0xffff) ) { |
276 | 280 | ||
277 | keybuffer_push(keybuffer, buf & 0xff ); |
281 | keybuffer_push(keybuffer, buf & 0xff ); |
278 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
282 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
279 | buf=count=0; |
283 | buf=count=0; |
280 | return 1; |
284 | return 1; |
281 | } |
285 | } |
282 | 286 | ||
283 | if ( count <= 2) |
287 | if ( count <= 2) |
284 | return 1; |
288 | return 1; |
285 | 289 | ||
286 | 290 | ||
287 | if( (buf & 0xffffff) != (GXEMUL_KEY_F1 & 0xffffff) |
291 | if( (buf & 0xffffff) != (GXEMUL_KEY_F1 & 0xffffff) |
288 | && (buf & 0xffffff) != (GXEMUL_KEY_F5 & 0xffffff) |
292 | && (buf & 0xffffff) != (GXEMUL_KEY_F5 & 0xffffff) |
289 | && (buf & 0xffffff) != (GXEMUL_KEY_F9 & 0xffffff) ) { |
293 | && (buf & 0xffffff) != (GXEMUL_KEY_F9 & 0xffffff) ) { |
290 | 294 | ||
291 | keybuffer_push(keybuffer, buf & 0xff ); |
295 | keybuffer_push(keybuffer, buf & 0xff ); |
292 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
296 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
293 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
297 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
294 | buf=count=0; |
298 | buf=count=0; |
295 | return 1; |
299 | return 1; |
296 | } |
300 | } |
297 | 301 | ||
298 | if ( count <= 3 ) |
302 | if ( count <= 3 ) |
299 | return 1; |
303 | return 1; |
300 | 304 | ||
301 | 305 | ||
302 | switch (buf){ |
306 | switch (buf){ |
303 | 307 | ||
304 | case GXEMUL_KEY_F1: |
308 | case GXEMUL_KEY_F1: |
305 | keybuffer_push(keybuffer,FUNCTION_KEYS | 1 ); |
309 | keybuffer_push(keybuffer,FUNCTION_KEYS | 1 ); |
306 | buf=count=0; |
310 | buf=count=0; |
307 | return 1; |
311 | return 1; |
308 | case GXEMUL_KEY_F2: |
312 | case GXEMUL_KEY_F2: |
309 | keybuffer_push(keybuffer,FUNCTION_KEYS | 2 ); |
313 | keybuffer_push(keybuffer,FUNCTION_KEYS | 2 ); |
310 | buf=count=0; |
314 | buf=count=0; |
311 | return 1; |
315 | return 1; |
312 | case GXEMUL_KEY_F3: |
316 | case GXEMUL_KEY_F3: |
313 | keybuffer_push(keybuffer,FUNCTION_KEYS | 3 ); |
317 | keybuffer_push(keybuffer,FUNCTION_KEYS | 3 ); |
314 | buf=count=0; |
318 | buf=count=0; |
315 | return 1; |
319 | return 1; |
316 | case GXEMUL_KEY_F4: |
320 | case GXEMUL_KEY_F4: |
317 | keybuffer_push(keybuffer,FUNCTION_KEYS | 4 ); |
321 | keybuffer_push(keybuffer,FUNCTION_KEYS | 4 ); |
318 | buf=count=0; |
322 | buf=count=0; |
319 | return 1; |
323 | return 1; |
320 | case GXEMUL_KEY_F5: |
324 | case GXEMUL_KEY_F5: |
321 | keybuffer_push(keybuffer,FUNCTION_KEYS | 5 ); |
325 | keybuffer_push(keybuffer,FUNCTION_KEYS | 5 ); |
322 | buf=count=0; |
326 | buf=count=0; |
323 | return 1; |
327 | return 1; |
324 | case GXEMUL_KEY_F6: |
328 | case GXEMUL_KEY_F6: |
325 | keybuffer_push(keybuffer,FUNCTION_KEYS | 6 ); |
329 | keybuffer_push(keybuffer,FUNCTION_KEYS | 6 ); |
326 | buf=count=0; |
330 | buf=count=0; |
327 | return 1; |
331 | return 1; |
328 | case GXEMUL_KEY_F7: |
332 | case GXEMUL_KEY_F7: |
329 | keybuffer_push(keybuffer,FUNCTION_KEYS | 7 ); |
333 | keybuffer_push(keybuffer,FUNCTION_KEYS | 7 ); |
330 | buf=count=0; |
334 | buf=count=0; |
331 | return 1; |
335 | return 1; |
332 | case GXEMUL_KEY_F8: |
336 | case GXEMUL_KEY_F8: |
333 | keybuffer_push(keybuffer,FUNCTION_KEYS | 8 ); |
337 | keybuffer_push(keybuffer,FUNCTION_KEYS | 8 ); |
334 | buf=count=0; |
338 | buf=count=0; |
335 | return 1; |
339 | return 1; |
336 | case GXEMUL_KEY_F9: |
340 | case GXEMUL_KEY_F9: |
337 | keybuffer_push(keybuffer,FUNCTION_KEYS | 9 ); |
341 | keybuffer_push(keybuffer,FUNCTION_KEYS | 9 ); |
338 | buf=count=0; |
342 | buf=count=0; |
339 | return 1; |
343 | return 1; |
340 | case GXEMUL_KEY_F10: |
344 | case GXEMUL_KEY_F10: |
341 | keybuffer_push(keybuffer,FUNCTION_KEYS | 10 ); |
345 | keybuffer_push(keybuffer,FUNCTION_KEYS | 10 ); |
342 | buf=count=0; |
346 | buf=count=0; |
343 | return 1; |
347 | return 1; |
344 | case GXEMUL_KEY_F11: |
348 | case GXEMUL_KEY_F11: |
345 | keybuffer_push(keybuffer,FUNCTION_KEYS | 11 ); |
349 | keybuffer_push(keybuffer,FUNCTION_KEYS | 11 ); |
346 | buf=count=0; |
350 | buf=count=0; |
347 | return 1; |
351 | return 1; |
348 | case GXEMUL_KEY_F12: |
352 | case GXEMUL_KEY_F12: |
349 | keybuffer_push(keybuffer,FUNCTION_KEYS | 12 ); |
353 | keybuffer_push(keybuffer,FUNCTION_KEYS | 12 ); |
350 | buf=count=0; |
354 | buf=count=0; |
351 | return 1; |
355 | return 1; |
352 | 356 | ||
353 | default: |
357 | default: |
354 | keybuffer_push(keybuffer, buf & 0xff ); |
358 | keybuffer_push(keybuffer, buf & 0xff ); |
355 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
359 | keybuffer_push(keybuffer, (buf >> 8) &0xff ); |
356 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
360 | keybuffer_push(keybuffer, (buf >> 16) &0xff ); |
357 | keybuffer_push(keybuffer, (buf >> 24) &0xff ); |
361 | keybuffer_push(keybuffer, (buf >> 24) &0xff ); |
358 | buf=count=0; |
362 | buf=count=0; |
359 | return 1; |
363 | return 1; |
360 | 364 | ||
361 | } |
365 | } |
362 | return 1; |
366 | return 1; |
363 | } |
367 | } |
364 | 368 | ||
365 | int kbd_arch_process(keybuffer_t *keybuffer, int scan_code) |
369 | int kbd_arch_process(keybuffer_t *keybuffer, int scan_code) |
366 | { |
370 | { |
367 | if(msim) return kbd_arch_process_msim(keybuffer, scan_code); |
371 | if(msim) return kbd_arch_process_msim(keybuffer, scan_code); |
368 | if(gxemul) return kbd_arch_process_gxemul(keybuffer, scan_code); |
372 | if(gxemul) return kbd_arch_process_gxemul(keybuffer, scan_code); |
369 | 373 | ||
370 | return 0; |
374 | return 0; |
371 | } |
375 | } |
372 | 376 | ||
373 | 377 |