pm_direct.c revision 1.42
1 1.42 nat /* $NetBSD: pm_direct.c,v 1.42 2025/05/12 00:28:07 nat Exp $ */ 2 1.1 scottr 3 1.1 scottr /* 4 1.40 nat * Copyright (c) 2024, 2025 Nathanial Sloss <nathanialsloss (at) yahoo.com.au> 5 1.33 nat * All rights reserved. 6 1.33 nat * 7 1.1 scottr * Copyright (C) 1997 Takashi Hamada 8 1.1 scottr * All rights reserved. 9 1.1 scottr * 10 1.1 scottr * Redistribution and use in source and binary forms, with or without 11 1.1 scottr * modification, are permitted provided that the following conditions 12 1.1 scottr * are met: 13 1.1 scottr * 1. Redistributions of source code must retain the above copyright 14 1.1 scottr * notice, this list of conditions and the following disclaimer. 15 1.1 scottr * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 scottr * notice, this list of conditions and the following disclaimer in the 17 1.1 scottr * documentation and/or other materials provided with the distribution. 18 1.1 scottr * 3. All advertising materials mentioning features or use of this software 19 1.1 scottr * must display the following acknowledgement: 20 1.5 scottr * This product includes software developed by Takashi Hamada 21 1.1 scottr * 4. The name of the author may not be used to endorse or promote products 22 1.1 scottr * derived from this software without specific prior written permission. 23 1.1 scottr * 24 1.1 scottr * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 25 1.1 scottr * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 26 1.1 scottr * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 27 1.1 scottr * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 28 1.1 scottr * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 29 1.1 scottr * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 30 1.1 scottr * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 31 1.1 scottr * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 32 1.1 scottr * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE 33 1.1 scottr * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 34 1.1 scottr */ 35 1.5 scottr /* From: pm_direct.c 1.3 03/18/98 Takashi Hamada */ 36 1.22 lukem 37 1.22 lukem #include <sys/cdefs.h> 38 1.42 nat __KERNEL_RCSID(0, "$NetBSD: pm_direct.c,v 1.42 2025/05/12 00:28:07 nat Exp $"); 39 1.1 scottr 40 1.3 scottr #include "opt_adb.h" 41 1.3 scottr 42 1.3 scottr #ifdef DEBUG 43 1.3 scottr #ifndef ADB_DEBUG 44 1.3 scottr #define ADB_DEBUG 45 1.3 scottr #endif 46 1.3 scottr #endif 47 1.1 scottr 48 1.1 scottr /* #define PM_GRAB_SI 1 */ 49 1.1 scottr 50 1.1 scottr #include <sys/types.h> 51 1.40 nat #include <sys/kthread.h> 52 1.40 nat #include <sys/proc.h> 53 1.38 nat #include <sys/mutex.h> 54 1.3 scottr #include <sys/systm.h> 55 1.1 scottr 56 1.35 nat #include <dev/sysmon/sysmonvar.h> 57 1.35 nat 58 1.1 scottr #include <machine/viareg.h> 59 1.1 scottr #include <machine/param.h> 60 1.1 scottr #include <machine/cpu.h> 61 1.1 scottr #include <machine/adbsys.h> 62 1.1 scottr 63 1.2 scottr #include <mac68k/mac68k/macrom.h> 64 1.2 scottr #include <mac68k/dev/adbvar.h> 65 1.2 scottr #include <mac68k/dev/pm_direct.h> 66 1.1 scottr 67 1.1 scottr /* hardware dependent values */ 68 1.1 scottr extern u_short ADBDelay; 69 1.1 scottr extern u_int32_t HwCfgFlags3; 70 1.1 scottr extern struct mac68k_machine_S mac68k_machine; 71 1.1 scottr 72 1.1 scottr 73 1.1 scottr /* useful macros */ 74 1.1 scottr #define PM_SR() via_reg(VIA1, vSR) 75 1.1 scottr #define PM_VIA_INTR_ENABLE() via_reg(VIA1, vIER) = 0x90 76 1.1 scottr #define PM_VIA_INTR_DISABLE() via_reg(VIA1, vIER) = 0x10 77 1.1 scottr #define PM_VIA_CLR_INTR() via_reg(VIA1, vIFR) = 0x90 78 1.1 scottr #define PM_SET_STATE_ACKON() via_reg(VIA2, vBufB) |= 0x04 79 1.1 scottr #define PM_SET_STATE_ACKOFF() via_reg(VIA2, vBufB) &= ~0x04 80 1.4 scottr #define PM_IS_ON (0x02 == (via_reg(VIA2, vBufB) & 0x02)) 81 1.4 scottr #define PM_IS_OFF (0x00 == (via_reg(VIA2, vBufB) & 0x02)) 82 1.1 scottr 83 1.4 scottr /* 84 1.4 scottr * Variables for internal use 85 1.1 scottr */ 86 1.1 scottr int pmHardware = PM_HW_UNKNOWN; 87 1.1 scottr u_short pm_existent_ADB_devices = 0x0; /* each bit expresses the existent ADB device */ 88 1.1 scottr u_int pm_LCD_brightness = 0x0; 89 1.1 scottr u_int pm_LCD_contrast = 0x0; 90 1.1 scottr u_int pm_counter = 0; /* clock count */ 91 1.35 nat struct sysmon_pswitch pbutton; 92 1.1 scottr 93 1.1 scottr /* these values shows that number of data returned after 'send' cmd is sent */ 94 1.1 scottr char pm_send_cmd_type[] = { 95 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 96 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 97 1.4 scottr 0x01, 0x01, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 98 1.4 scottr 0x00, 0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0x00, 99 1.4 scottr 0xff, 0x00, 0x02, 0x01, 0x01, 0xff, 0xff, 0xff, 100 1.4 scottr 0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 101 1.4 scottr 0x04, 0x14, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 102 1.4 scottr 0x00, 0x00, 0x02, 0xff, 0xff, 0xff, 0xff, 0xff, 103 1.4 scottr 0x01, 0x01, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 104 1.4 scottr 0x00, 0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 105 1.4 scottr 0x01, 0x00, 0x02, 0x02, 0xff, 0x01, 0x03, 0x01, 106 1.4 scottr 0x00, 0x01, 0x00, 0x00, 0x00, 0xff, 0xff, 0xff, 107 1.4 scottr 0x02, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 108 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0xff, 0xff, 109 1.4 scottr 0x01, 0x01, 0x01, 0xff, 0xff, 0xff, 0xff, 0xff, 110 1.4 scottr 0x00, 0x00, 0xff, 0xff, 0xff, 0xff, 0x04, 0x04, 111 1.4 scottr 0x04, 0xff, 0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 112 1.4 scottr 0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 113 1.4 scottr 0x01, 0x02, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 114 1.4 scottr 0x00, 0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 115 1.4 scottr 0x02, 0x02, 0x02, 0x04, 0xff, 0x00, 0xff, 0xff, 116 1.4 scottr 0x01, 0x01, 0x03, 0x02, 0xff, 0xff, 0xff, 0xff, 117 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 118 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 119 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 120 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 121 1.4 scottr 0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 122 1.4 scottr 0x01, 0x01, 0xff, 0xff, 0x00, 0x00, 0xff, 0xff, 123 1.4 scottr 0xff, 0x04, 0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 124 1.4 scottr 0x03, 0xff, 0x00, 0xff, 0x00, 0xff, 0xff, 0x00, 125 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 126 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff 127 1.1 scottr }; 128 1.1 scottr 129 1.1 scottr /* these values shows that number of data returned after 'receive' cmd is sent */ 130 1.1 scottr char pm_receive_cmd_type[] = { 131 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 132 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 133 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 134 1.4 scottr 0x02, 0x02, 0xff, 0xff, 0xff, 0xff, 0xff, 0x00, 135 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 136 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 137 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 138 1.4 scottr 0x05, 0x15, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 139 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 140 1.4 scottr 0x02, 0x02, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 141 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 142 1.4 scottr 0x02, 0x00, 0x03, 0x03, 0xff, 0xff, 0xff, 0xff, 143 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 144 1.4 scottr 0x04, 0x04, 0x03, 0x09, 0xff, 0xff, 0xff, 0xff, 145 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 146 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x01, 0x01, 147 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 148 1.4 scottr 0x06, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 149 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 150 1.4 scottr 0x02, 0x02, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 151 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 152 1.4 scottr 0x02, 0x00, 0x00, 0x00, 0xff, 0xff, 0xff, 0xff, 153 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 154 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 155 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 156 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 157 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 158 1.4 scottr 0x02, 0x02, 0xff, 0xff, 0x02, 0xff, 0xff, 0xff, 159 1.4 scottr 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 160 1.4 scottr 0xff, 0xff, 0x02, 0xff, 0xff, 0xff, 0xff, 0x00, 161 1.4 scottr 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 162 1.4 scottr 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 163 1.1 scottr }; 164 1.1 scottr 165 1.1 scottr 166 1.38 nat /* Spin mutex to seriaize powermanager requests. */ 167 1.38 nat kmutex_t pm_mutex; 168 1.38 nat 169 1.1 scottr /* 170 1.1 scottr * Define the private functions 171 1.1 scottr */ 172 1.1 scottr 173 1.1 scottr /* for debugging */ 174 1.3 scottr #ifdef ADB_DEBUG 175 1.25 christos void pm_printerr(const char *, int, int, char *); 176 1.1 scottr #endif 177 1.1 scottr 178 1.23 chs int pm_wait_busy(int); 179 1.23 chs int pm_wait_free(int); 180 1.1 scottr 181 1.1 scottr /* these functions are for the PB1XX series */ 182 1.23 chs int pm_receive_pm1(u_char *); 183 1.23 chs int pm_send_pm1(u_char, int); 184 1.23 chs int pm_pmgrop_pm1(PMData *); 185 1.23 chs void pm_intr_pm1(void *); 186 1.40 nat void brightness_slider(void *); /* brightness slider thread */ 187 1.1 scottr 188 1.1 scottr /* these functions are for the PB Duo series and the PB 5XX series */ 189 1.23 chs int pm_receive_pm2(u_char *); 190 1.23 chs int pm_send_pm2(u_char); 191 1.23 chs int pm_pmgrop_pm2(PMData *); 192 1.23 chs void pm_intr_pm2(void *); 193 1.1 scottr 194 1.1 scottr /* this function is MRG-Based (for testing) */ 195 1.23 chs int pm_pmgrop_mrg(PMData *); 196 1.1 scottr 197 1.1 scottr /* these functions are called from adb_direct.c */ 198 1.23 chs void pm_setup_adb(void); 199 1.23 chs void pm_check_adb_devices(int); 200 1.23 chs void pm_intr(void *); 201 1.23 chs int pm_adb_op(u_char *, void *, void *, int); 202 1.23 chs void pm_hw_setup(void); 203 1.1 scottr 204 1.1 scottr /* these functions also use the variables of adb_direct.c */ 205 1.23 chs void pm_adb_get_TALK_result(PMData *); 206 1.23 chs void pm_adb_get_ADB_data(PMData *); 207 1.23 chs void pm_adb_poll_next_device_pm1(PMData *); 208 1.1 scottr 209 1.1 scottr 210 1.1 scottr /* 211 1.1 scottr * These variables are in adb_direct.c. 212 1.1 scottr */ 213 1.1 scottr extern u_char *adbBuffer; /* pointer to user data area */ 214 1.1 scottr extern void *adbCompRout; /* pointer to the completion routine */ 215 1.1 scottr extern void *adbCompData; /* pointer to the completion routine data */ 216 1.1 scottr extern int adbWaiting; /* waiting for return data from the device */ 217 1.1 scottr extern int adbWaitingCmd; /* ADB command we are waiting for */ 218 1.1 scottr extern int adbStarting; /* doing ADB reinit, so do "polling" differently */ 219 1.1 scottr 220 1.5 scottr #define ADB_MAX_MSG_LENGTH 16 221 1.5 scottr #define ADB_MAX_HDR_LENGTH 8 222 1.5 scottr struct adbCommand { 223 1.5 scottr u_char header[ADB_MAX_HDR_LENGTH]; /* not used yet */ 224 1.5 scottr u_char data[ADB_MAX_MSG_LENGTH]; /* packet data only */ 225 1.5 scottr u_char *saveBuf; /* where to save result */ 226 1.5 scottr u_char *compRout; /* completion routine pointer */ 227 1.5 scottr u_char *compData; /* completion routine data pointer */ 228 1.5 scottr u_int cmd; /* the original command for this data */ 229 1.5 scottr u_int unsol; /* 1 if packet was unsolicited */ 230 1.5 scottr u_int ack_only; /* 1 for no special processing */ 231 1.5 scottr }; 232 1.23 chs extern void adb_pass_up(struct adbCommand *); 233 1.5 scottr 234 1.3 scottr #ifdef ADB_DEBUG 235 1.1 scottr /* 236 1.1 scottr * This function dumps contents of the PMData 237 1.1 scottr */ 238 1.1 scottr void 239 1.25 christos pm_printerr(const char *ttl, int rval, int num, char *data) 240 1.1 scottr { 241 1.1 scottr int i; 242 1.1 scottr 243 1.4 scottr printf("pm: %s:%04x %02x ", ttl, rval, num); 244 1.4 scottr for (i = 0; i < num; i++) 245 1.4 scottr printf("%02x ", data[i]); 246 1.4 scottr printf("\n"); 247 1.1 scottr } 248 1.1 scottr #endif 249 1.1 scottr 250 1.1 scottr 251 1.1 scottr 252 1.1 scottr /* 253 1.1 scottr * Check the hardware type of the Power Manager 254 1.1 scottr */ 255 1.1 scottr void 256 1.23 chs pm_setup_adb(void) 257 1.1 scottr { 258 1.38 nat mutex_init(&pm_mutex, MUTEX_DEFAULT, IPL_HIGH); 259 1.1 scottr switch (mac68k_machine.machineid) { 260 1.1 scottr case MACH_MACPB140: 261 1.1 scottr case MACH_MACPB145: 262 1.1 scottr case MACH_MACPB160: 263 1.1 scottr case MACH_MACPB165: 264 1.1 scottr case MACH_MACPB165C: 265 1.1 scottr case MACH_MACPB170: 266 1.1 scottr case MACH_MACPB180: 267 1.1 scottr case MACH_MACPB180C: 268 1.1 scottr pmHardware = PM_HW_PB1XX; 269 1.35 nat 270 1.35 nat memset(&pbutton, 0, sizeof(struct sysmon_pswitch)); 271 1.35 nat pbutton.smpsw_name = "PB"; 272 1.35 nat pbutton.smpsw_type = PSWITCH_TYPE_POWER; 273 1.35 nat if (sysmon_pswitch_register(&pbutton) != 0) 274 1.35 nat printf("Unable to register soft power\n"); 275 1.40 nat kthread_create(PRI_NONE, KTHREAD_MPSAFE, NULL, 276 1.40 nat brightness_slider, NULL, NULL, "britethrd"); 277 1.1 scottr break; 278 1.19 shiba case MACH_MACPB150: 279 1.1 scottr case MACH_MACPB210: 280 1.1 scottr case MACH_MACPB230: 281 1.1 scottr case MACH_MACPB250: 282 1.1 scottr case MACH_MACPB270: 283 1.1 scottr case MACH_MACPB280: 284 1.1 scottr case MACH_MACPB280C: 285 1.1 scottr case MACH_MACPB500: 286 1.21 shiba case MACH_MACPB190: 287 1.21 shiba case MACH_MACPB190CS: 288 1.1 scottr pmHardware = PM_HW_PB5XX; 289 1.35 nat #if notyet 290 1.35 nat memset(&pbutton, 0, sizeof(struct sysmon_pswitch)); 291 1.35 nat pbutton.smpsw_name = "PB"; 292 1.35 nat pbutton.smpsw_type = PSWITCH_TYPE_POWER; 293 1.35 nat if (sysmon_pswitch_register(&pbutton) != 0) 294 1.35 nat printf("Unable to register soft power\n"); 295 1.35 nat #endif 296 1.1 scottr break; 297 1.1 scottr default: 298 1.1 scottr break; 299 1.1 scottr } 300 1.1 scottr } 301 1.1 scottr 302 1.1 scottr 303 1.1 scottr /* 304 1.1 scottr * Check the existent ADB devices 305 1.1 scottr */ 306 1.1 scottr void 307 1.23 chs pm_check_adb_devices(int id) 308 1.1 scottr { 309 1.1 scottr u_short ed = 0x1; 310 1.1 scottr 311 1.1 scottr ed <<= id; 312 1.1 scottr pm_existent_ADB_devices |= ed; 313 1.1 scottr } 314 1.1 scottr 315 1.1 scottr 316 1.1 scottr /* 317 1.1 scottr * Wait until PM IC is busy 318 1.1 scottr */ 319 1.1 scottr int 320 1.24 jmc pm_wait_busy(int xdelay) 321 1.1 scottr { 322 1.4 scottr while (PM_IS_ON) { 323 1.1 scottr #ifdef PM_GRAB_SI 324 1.15 scottr (void)intr_dispatch(0x70); /* grab any serial interrupts */ 325 1.1 scottr #endif 326 1.24 jmc if ((--xdelay) < 0) 327 1.5 scottr return 1; /* timeout */ 328 1.1 scottr } 329 1.5 scottr return 0; 330 1.1 scottr } 331 1.1 scottr 332 1.1 scottr 333 1.1 scottr /* 334 1.1 scottr * Wait until PM IC is free 335 1.1 scottr */ 336 1.1 scottr int 337 1.24 jmc pm_wait_free(int xdelay) 338 1.1 scottr { 339 1.4 scottr while (PM_IS_OFF) { 340 1.1 scottr #ifdef PM_GRAB_SI 341 1.15 scottr (void)intr_dispatch(0x70); /* grab any serial interrupts */ 342 1.1 scottr #endif 343 1.24 jmc if ((--xdelay) < 0) 344 1.5 scottr return 0; /* timeout */ 345 1.1 scottr } 346 1.5 scottr return 1; 347 1.1 scottr } 348 1.1 scottr 349 1.1 scottr 350 1.1 scottr 351 1.1 scottr /* 352 1.1 scottr * Functions for the PB1XX series 353 1.1 scottr */ 354 1.1 scottr 355 1.1 scottr /* 356 1.1 scottr * Receive data from PM for the PB1XX series 357 1.1 scottr */ 358 1.1 scottr int 359 1.23 chs pm_receive_pm1(u_char *data) 360 1.1 scottr { 361 1.1 scottr int rval = 0xffffcd34; 362 1.1 scottr 363 1.1 scottr via_reg(VIA2, vDirA) = 0x00; 364 1.1 scottr 365 1.4 scottr switch (1) { 366 1.1 scottr default: 367 1.4 scottr if (pm_wait_busy(0x40) != 0) 368 1.1 scottr break; /* timeout */ 369 1.1 scottr 370 1.1 scottr PM_SET_STATE_ACKOFF(); 371 1.1 scottr *data = via_reg(VIA2, 0x200); 372 1.1 scottr 373 1.1 scottr rval = 0xffffcd33; 374 1.4 scottr if (pm_wait_free(0x40) == 0) 375 1.1 scottr break; /* timeout */ 376 1.1 scottr 377 1.1 scottr rval = 0x00; 378 1.1 scottr break; 379 1.1 scottr } 380 1.1 scottr 381 1.1 scottr PM_SET_STATE_ACKON(); 382 1.1 scottr via_reg(VIA2, vDirA) = 0x00; 383 1.1 scottr 384 1.5 scottr return rval; 385 1.1 scottr } 386 1.1 scottr 387 1.1 scottr 388 1.1 scottr 389 1.1 scottr /* 390 1.1 scottr * Send data to PM for the PB1XX series 391 1.1 scottr */ 392 1.1 scottr int 393 1.23 chs pm_send_pm1(u_char data, int timo) 394 1.1 scottr { 395 1.4 scottr int rval; 396 1.1 scottr 397 1.1 scottr via_reg(VIA2, vDirA) = 0xff; 398 1.1 scottr via_reg(VIA2, 0x200) = data; 399 1.1 scottr 400 1.1 scottr PM_SET_STATE_ACKOFF(); 401 1.14 scottr #if 0 402 1.14 scottr if (pm_wait_busy(0x400) == 0) { 403 1.14 scottr #else 404 1.14 scottr if (pm_wait_busy(timo) == 0) { 405 1.14 scottr #endif 406 1.1 scottr PM_SET_STATE_ACKON(); 407 1.14 scottr if (pm_wait_free(0x40) != 0) 408 1.14 scottr rval = 0x0; 409 1.14 scottr else 410 1.14 scottr rval = 0xffffcd35; 411 1.14 scottr } else { 412 1.14 scottr rval = 0xffffcd36; 413 1.1 scottr } 414 1.1 scottr 415 1.1 scottr PM_SET_STATE_ACKON(); 416 1.1 scottr via_reg(VIA2, vDirA) = 0x00; 417 1.1 scottr 418 1.5 scottr return rval; 419 1.1 scottr } 420 1.1 scottr 421 1.1 scottr 422 1.1 scottr /* 423 1.1 scottr * My PMgrOp routine for the PB1XX series 424 1.1 scottr */ 425 1.1 scottr int 426 1.23 chs pm_pmgrop_pm1(PMData *pmdata) 427 1.1 scottr { 428 1.4 scottr int i; 429 1.4 scottr int s = 0x81815963; 430 1.4 scottr u_char via1_vIER, via1_vDirA; 431 1.4 scottr int rval = 0; 432 1.4 scottr int num_pm_data = 0; 433 1.36 riastrad u_char pm_cmd; 434 1.4 scottr u_char pm_data; 435 1.4 scottr u_char *pm_buf; 436 1.1 scottr 437 1.38 nat mutex_spin_enter(&pm_mutex); 438 1.38 nat 439 1.32 andvar /* disable all interrupts but PM */ 440 1.1 scottr via1_vIER = via_reg(VIA1, vIER); 441 1.1 scottr PM_VIA_INTR_DISABLE(); 442 1.1 scottr 443 1.1 scottr via1_vDirA = via_reg(VIA1, vDirA); 444 1.1 scottr 445 1.4 scottr switch (pmdata->command) { 446 1.1 scottr default: 447 1.4 scottr for (i = 0; i < 7; i++) { 448 1.36 riastrad via_reg(VIA2, vDirA) = 0x00; 449 1.1 scottr 450 1.1 scottr /* wait until PM is free */ 451 1.4 scottr if (pm_wait_free(ADBDelay) == 0) { /* timeout */ 452 1.1 scottr via_reg(VIA2, vDirA) = 0x00; 453 1.1 scottr /* restore formar value */ 454 1.1 scottr via_reg(VIA1, vDirA) = via1_vDirA; 455 1.1 scottr via_reg(VIA1, vIER) = via1_vIER; 456 1.38 nat mutex_spin_exit(&pm_mutex); 457 1.5 scottr return 0xffffcd38; 458 1.1 scottr } 459 1.1 scottr 460 1.4 scottr switch (mac68k_machine.machineid) { 461 1.1 scottr case MACH_MACPB160: 462 1.1 scottr case MACH_MACPB165: 463 1.1 scottr case MACH_MACPB165C: 464 1.8 scottr case MACH_MACPB170: 465 1.1 scottr case MACH_MACPB180: 466 1.1 scottr case MACH_MACPB180C: 467 1.1 scottr { 468 1.24 jmc int xdelay = ADBDelay * 16; 469 1.1 scottr 470 1.1 scottr via_reg(VIA2, vDirA) = 0x00; 471 1.24 jmc while ((via_reg(VIA2, 0x200) == 0x7f) && (xdelay >= 0)) 472 1.24 jmc xdelay--; 473 1.1 scottr 474 1.24 jmc if (xdelay < 0) { /* timeout */ 475 1.1 scottr via_reg(VIA2, vDirA) = 0x00; 476 1.1 scottr /* restore formar value */ 477 1.1 scottr via_reg(VIA1, vIER) = via1_vIER; 478 1.38 nat mutex_spin_exit(&pm_mutex); 479 1.5 scottr return 0xffffcd38; 480 1.1 scottr } 481 1.1 scottr } 482 1.1 scottr } /* end switch */ 483 1.1 scottr 484 1.4 scottr s = splhigh(); 485 1.1 scottr 486 1.1 scottr via1_vDirA = via_reg(VIA1, vDirA); 487 1.1 scottr via_reg(VIA1, vDirA) &= 0x7f; 488 1.1 scottr 489 1.1 scottr pm_cmd = (u_char)(pmdata->command & 0xff); 490 1.4 scottr if ((rval = pm_send_pm1(pm_cmd, ADBDelay * 8)) == 0) 491 1.4 scottr break; /* send command succeeded */ 492 1.1 scottr 493 1.1 scottr via_reg(VIA1, vDirA) = via1_vDirA; 494 1.1 scottr splx(s); 495 1.1 scottr } /* end for */ 496 1.1 scottr 497 1.1 scottr /* failed to send a command */ 498 1.1 scottr if (i == 7) { 499 1.1 scottr via_reg(VIA2, vDirA) = 0x00; 500 1.1 scottr /* restore formar value */ 501 1.1 scottr via_reg(VIA1, vDirA) = via1_vDirA; 502 1.1 scottr via_reg(VIA1, vIER) = via1_vIER; 503 1.13 scottr if (s != 0x81815963) 504 1.13 scottr splx(s); 505 1.38 nat mutex_spin_exit(&pm_mutex); 506 1.13 scottr return 0xffffcd38; 507 1.1 scottr } 508 1.1 scottr 509 1.1 scottr /* send # of PM data */ 510 1.1 scottr num_pm_data = pmdata->num_data; 511 1.4 scottr if ((rval = pm_send_pm1((u_char)(num_pm_data & 0xff), ADBDelay * 8)) != 0) 512 1.1 scottr break; /* timeout */ 513 1.1 scottr 514 1.1 scottr /* send PM data */ 515 1.1 scottr pm_buf = (u_char *)pmdata->s_buf; 516 1.4 scottr for (i = 0; i < num_pm_data; i++) 517 1.4 scottr if ((rval = pm_send_pm1(pm_buf[i], ADBDelay * 8)) != 0) 518 1.4 scottr break; /* timeout */ 519 1.1 scottr if ((i != num_pm_data) && (num_pm_data != 0)) 520 1.4 scottr break; /* timeout */ 521 1.1 scottr 522 1.1 scottr /* Will PM IC return data? */ 523 1.1 scottr if ((pm_cmd & 0x08) == 0) { 524 1.1 scottr rval = 0; 525 1.4 scottr break; /* no returned data */ 526 1.1 scottr } 527 1.1 scottr 528 1.1 scottr rval = 0xffffcd37; 529 1.4 scottr if (pm_wait_busy(ADBDelay) != 0) 530 1.1 scottr break; /* timeout */ 531 1.1 scottr 532 1.1 scottr /* receive PM command */ 533 1.4 scottr if ((rval = pm_receive_pm1(&pm_data)) != 0) 534 1.1 scottr break; 535 1.1 scottr 536 1.1 scottr pmdata->command = pm_data; 537 1.1 scottr 538 1.1 scottr /* receive number of PM data */ 539 1.4 scottr if ((rval = pm_receive_pm1(&pm_data)) != 0) 540 1.4 scottr break; /* timeout */ 541 1.1 scottr num_pm_data = pm_data; 542 1.1 scottr pmdata->num_data = num_pm_data; 543 1.1 scottr 544 1.1 scottr /* receive PM data */ 545 1.1 scottr pm_buf = (u_char *)pmdata->r_buf; 546 1.4 scottr for (i = 0; i < num_pm_data; i++) { 547 1.4 scottr if ((rval = pm_receive_pm1(&pm_data)) != 0) 548 1.12 scottr break; /* timeout */ 549 1.1 scottr pm_buf[i] = pm_data; 550 1.1 scottr } 551 1.1 scottr 552 1.1 scottr rval = 0; 553 1.1 scottr } 554 1.1 scottr 555 1.36 riastrad via_reg(VIA2, vDirA) = 0x00; 556 1.1 scottr 557 1.1 scottr /* restore formar value */ 558 1.1 scottr via_reg(VIA1, vDirA) = via1_vDirA; 559 1.1 scottr via_reg(VIA1, vIER) = via1_vIER; 560 1.1 scottr if (s != 0x81815963) 561 1.1 scottr splx(s); 562 1.1 scottr 563 1.38 nat mutex_spin_exit(&pm_mutex); 564 1.38 nat 565 1.5 scottr return rval; 566 1.1 scottr } 567 1.1 scottr 568 1.1 scottr 569 1.1 scottr /* 570 1.5 scottr * My PM interrupt routine for PB1XX series 571 1.1 scottr */ 572 1.1 scottr void 573 1.23 chs pm_intr_pm1(void *arg) 574 1.1 scottr { 575 1.4 scottr int s; 576 1.4 scottr int rval; 577 1.4 scottr PMData pmdata; 578 1.1 scottr 579 1.1 scottr s = splhigh(); 580 1.1 scottr 581 1.1 scottr PM_VIA_CLR_INTR(); /* clear VIA1 interrupt */ 582 1.1 scottr 583 1.30 andvar /* ask PM what happened */ 584 1.1 scottr pmdata.command = 0x78; 585 1.1 scottr pmdata.num_data = 0; 586 1.1 scottr pmdata.data[0] = pmdata.data[1] = 0; 587 1.1 scottr pmdata.s_buf = &pmdata.data[2]; 588 1.1 scottr pmdata.r_buf = &pmdata.data[2]; 589 1.4 scottr rval = pm_pmgrop_pm1(&pmdata); 590 1.1 scottr if (rval != 0) { 591 1.3 scottr #ifdef ADB_DEBUG 592 1.3 scottr if (adb_debug) 593 1.3 scottr printf("pm: PM is not ready. error code=%08x\n", rval); 594 1.1 scottr #endif 595 1.1 scottr splx(s); 596 1.31 nat return; 597 1.1 scottr } 598 1.1 scottr 599 1.1 scottr if ((pmdata.data[2] & 0x10) == 0x10) { 600 1.4 scottr if ((pmdata.data[2] & 0x0f) == 0) { 601 1.4 scottr /* ADB data that were requested by TALK command */ 602 1.1 scottr pm_adb_get_TALK_result(&pmdata); 603 1.4 scottr } else if ((pmdata.data[2] & 0x08) == 0x8) { 604 1.4 scottr /* PM is requesting to poll */ 605 1.1 scottr pm_adb_poll_next_device_pm1(&pmdata); 606 1.4 scottr } else if ((pmdata.data[2] & 0x04) == 0x4) { 607 1.4 scottr /* ADB device event */ 608 1.1 scottr pm_adb_get_ADB_data(&pmdata); 609 1.1 scottr } 610 1.35 nat } else if ((pmdata.num_data == 0x1) && (pmdata.data[0] == 0)) { 611 1.35 nat /* PowerBook 160/180 Power button. */ 612 1.35 nat sysmon_pswitch_event(&pbutton, PSWITCH_EVENT_PRESSED); 613 1.1 scottr } else { 614 1.3 scottr #ifdef ADB_DEBUG 615 1.3 scottr if (adb_debug) 616 1.3 scottr pm_printerr("driver does not supported this event.", 617 1.3 scottr rval, pmdata.num_data, pmdata.data); 618 1.1 scottr #endif 619 1.1 scottr } 620 1.1 scottr 621 1.1 scottr splx(s); 622 1.1 scottr } 623 1.1 scottr 624 1.40 nat void 625 1.40 nat brightness_slider(void *arg) 626 1.40 nat { 627 1.40 nat int s; 628 1.40 nat int rval; 629 1.40 nat PMData pmdata; 630 1.40 nat 631 1.40 nat for (;;) { 632 1.41 nat kpause("brslider", false, hz / 4, NULL); 633 1.40 nat 634 1.40 nat s = splhigh(); 635 1.40 nat 636 1.40 nat pmdata.command = 0x49; 637 1.40 nat pmdata.num_data = 0; 638 1.40 nat pmdata.data[0] = pmdata.data[1] = 0; 639 1.40 nat pmdata.s_buf = &pmdata.data[0]; 640 1.40 nat pmdata.r_buf = &pmdata.data[0]; 641 1.40 nat rval = pm_pmgrop_pm1(&pmdata); 642 1.40 nat if (rval != 0) { 643 1.40 nat #ifdef ADB_DEBUG 644 1.40 nat if (adb_debug) { 645 1.40 nat printf("pm: PM is not ready. " 646 1.40 nat "error code=%08x\n", rval); 647 1.40 nat } 648 1.40 nat #endif 649 1.40 nat splx(s); 650 1.40 nat continue; 651 1.40 nat } 652 1.1 scottr 653 1.40 nat if (((uint8_t)pmdata.data[0] / 8) != pm_LCD_brightness) { 654 1.40 nat pm_LCD_brightness = (uint8_t)pmdata.data[0] / 8; 655 1.40 nat pm_LCD_brightness = 656 1.40 nat pm_set_brightness(pm_LCD_brightness); 657 1.40 nat } 658 1.40 nat 659 1.40 nat splx(s); 660 1.40 nat } 661 1.40 nat } 662 1.1 scottr 663 1.1 scottr /* 664 1.1 scottr * Functions for the PB Duo series and the PB 5XX series 665 1.1 scottr */ 666 1.1 scottr 667 1.1 scottr /* 668 1.1 scottr * Receive data from PM for the PB Duo series and the PB 5XX series 669 1.1 scottr */ 670 1.1 scottr int 671 1.23 chs pm_receive_pm2(u_char *data) 672 1.1 scottr { 673 1.4 scottr int rval; 674 1.1 scottr 675 1.1 scottr rval = 0xffffcd34; 676 1.1 scottr 677 1.4 scottr switch (1) { 678 1.1 scottr default: 679 1.1 scottr /* set VIA SR to input mode */ 680 1.1 scottr via_reg(VIA1, vACR) |= 0x0c; 681 1.1 scottr via_reg(VIA1, vACR) &= ~0x10; 682 1.29 martin PM_SR(); 683 1.1 scottr 684 1.1 scottr PM_SET_STATE_ACKOFF(); 685 1.1 scottr if (pm_wait_busy((int)ADBDelay*32) != 0) 686 1.1 scottr break; /* timeout */ 687 1.1 scottr 688 1.1 scottr PM_SET_STATE_ACKON(); 689 1.1 scottr rval = 0xffffcd33; 690 1.1 scottr if (pm_wait_free((int)ADBDelay*32) == 0) 691 1.1 scottr break; /* timeout */ 692 1.1 scottr 693 1.1 scottr *data = PM_SR(); 694 1.1 scottr rval = 0; 695 1.1 scottr 696 1.1 scottr break; 697 1.1 scottr } 698 1.1 scottr 699 1.1 scottr PM_SET_STATE_ACKON(); 700 1.1 scottr via_reg(VIA1, vACR) |= 0x1c; 701 1.1 scottr 702 1.5 scottr return rval; 703 1.36 riastrad } 704 1.1 scottr 705 1.1 scottr 706 1.1 scottr 707 1.1 scottr /* 708 1.1 scottr * Send data to PM for the PB Duo series and the PB 5XX series 709 1.1 scottr */ 710 1.1 scottr int 711 1.23 chs pm_send_pm2(u_char data) 712 1.1 scottr { 713 1.4 scottr int rval; 714 1.1 scottr 715 1.1 scottr via_reg(VIA1, vACR) |= 0x1c; 716 1.1 scottr PM_SR() = data; 717 1.1 scottr 718 1.1 scottr PM_SET_STATE_ACKOFF(); 719 1.14 scottr if (pm_wait_busy((int)ADBDelay*32) == 0) { 720 1.1 scottr PM_SET_STATE_ACKON(); 721 1.14 scottr if (pm_wait_free((int)ADBDelay*32) != 0) 722 1.14 scottr rval = 0; 723 1.14 scottr else 724 1.14 scottr rval = 0xffffcd35; 725 1.14 scottr } else { 726 1.14 scottr rval = 0xffffcd36; 727 1.1 scottr } 728 1.1 scottr 729 1.1 scottr PM_SET_STATE_ACKON(); 730 1.1 scottr via_reg(VIA1, vACR) |= 0x1c; 731 1.1 scottr 732 1.5 scottr return rval; 733 1.1 scottr } 734 1.1 scottr 735 1.1 scottr 736 1.1 scottr 737 1.1 scottr /* 738 1.1 scottr * My PMgrOp routine for the PB Duo series and the PB 5XX series 739 1.1 scottr */ 740 1.1 scottr int 741 1.23 chs pm_pmgrop_pm2(PMData *pmdata) 742 1.1 scottr { 743 1.4 scottr int i; 744 1.4 scottr int s; 745 1.4 scottr u_char via1_vIER; 746 1.4 scottr int rval = 0; 747 1.4 scottr int num_pm_data = 0; 748 1.36 riastrad u_char pm_cmd; 749 1.4 scottr short pm_num_rx_data; 750 1.4 scottr u_char pm_data; 751 1.4 scottr u_char *pm_buf; 752 1.1 scottr 753 1.38 nat mutex_spin_enter(&pm_mutex); 754 1.4 scottr s = splhigh(); 755 1.1 scottr 756 1.32 andvar /* disable all interrupts but PM */ 757 1.1 scottr via1_vIER = 0x10; 758 1.1 scottr via1_vIER &= via_reg(VIA1, vIER); 759 1.1 scottr via_reg(VIA1, vIER) = via1_vIER; 760 1.1 scottr if (via1_vIER != 0x0) 761 1.1 scottr via1_vIER |= 0x80; 762 1.1 scottr 763 1.4 scottr switch (pmdata->command) { 764 1.1 scottr default: 765 1.1 scottr /* wait until PM is free */ 766 1.1 scottr pm_cmd = (u_char)(pmdata->command & 0xff); 767 1.1 scottr rval = 0xcd38; 768 1.4 scottr if (pm_wait_free(ADBDelay * 4) == 0) 769 1.1 scottr break; /* timeout */ 770 1.1 scottr 771 1.36 riastrad if (HwCfgFlags3 & 0x00200000) { 772 1.4 scottr /* PB 160, PB 165(c), PB 180(c)? */ 773 1.24 jmc int xdelay = ADBDelay * 16; 774 1.1 scottr 775 1.1 scottr via_reg(VIA2, vDirA) = 0x00; 776 1.4 scottr while ((via_reg(VIA2, 0x200) == 0x07) && 777 1.24 jmc (xdelay >= 0)) 778 1.24 jmc xdelay--; 779 1.1 scottr 780 1.24 jmc if (xdelay < 0) { 781 1.1 scottr rval = 0xffffcd38; 782 1.1 scottr break; /* timeout */ 783 1.1 scottr } 784 1.1 scottr } 785 1.1 scottr 786 1.1 scottr /* send PM command */ 787 1.4 scottr if ((rval = pm_send_pm2((u_char)(pm_cmd & 0xff)))) 788 1.1 scottr break; /* timeout */ 789 1.1 scottr 790 1.1 scottr /* send number of PM data */ 791 1.1 scottr num_pm_data = pmdata->num_data; 792 1.1 scottr if (HwCfgFlags3 & 0x00020000) { /* PB Duo, PB 5XX */ 793 1.1 scottr if (pm_send_cmd_type[pm_cmd] < 0) { 794 1.4 scottr if ((rval = pm_send_pm2((u_char)(num_pm_data & 0xff))) != 0) 795 1.1 scottr break; /* timeout */ 796 1.1 scottr pmdata->command = 0; 797 1.1 scottr } 798 1.1 scottr } else { /* PB 1XX series ? */ 799 1.4 scottr if ((rval = pm_send_pm2((u_char)(num_pm_data & 0xff))) != 0) 800 1.1 scottr break; /* timeout */ 801 1.36 riastrad } 802 1.1 scottr /* send PM data */ 803 1.1 scottr pm_buf = (u_char *)pmdata->s_buf; 804 1.4 scottr for (i = 0 ; i < num_pm_data; i++) 805 1.4 scottr if ((rval = pm_send_pm2(pm_buf[i])) != 0) 806 1.1 scottr break; /* timeout */ 807 1.1 scottr if (i != num_pm_data) 808 1.1 scottr break; /* timeout */ 809 1.1 scottr 810 1.1 scottr 811 1.1 scottr /* check if PM will send me data */ 812 1.1 scottr pm_num_rx_data = pm_receive_cmd_type[pm_cmd]; 813 1.1 scottr pmdata->num_data = pm_num_rx_data; 814 1.1 scottr if (pm_num_rx_data == 0) { 815 1.1 scottr rval = 0; 816 1.1 scottr break; /* no return data */ 817 1.1 scottr } 818 1.1 scottr 819 1.1 scottr /* receive PM command */ 820 1.1 scottr pm_data = pmdata->command; 821 1.1 scottr if (HwCfgFlags3 & 0x00020000) { /* PB Duo, PB 5XX */ 822 1.1 scottr pm_num_rx_data--; 823 1.1 scottr if (pm_num_rx_data == 0) 824 1.4 scottr if ((rval = pm_receive_pm2(&pm_data)) != 0) { 825 1.1 scottr rval = 0xffffcd37; 826 1.1 scottr break; 827 1.1 scottr } 828 1.1 scottr pmdata->command = pm_data; 829 1.1 scottr } else { /* PB 1XX series ? */ 830 1.4 scottr if ((rval = pm_receive_pm2(&pm_data)) != 0) { 831 1.1 scottr rval = 0xffffcd37; 832 1.1 scottr break; 833 1.1 scottr } 834 1.1 scottr pmdata->command = pm_data; 835 1.1 scottr } 836 1.1 scottr 837 1.1 scottr /* receive number of PM data */ 838 1.1 scottr if (HwCfgFlags3 & 0x00020000) { /* PB Duo, PB 5XX */ 839 1.1 scottr if (pm_num_rx_data < 0) { 840 1.4 scottr if ((rval = pm_receive_pm2(&pm_data)) != 0) 841 1.1 scottr break; /* timeout */ 842 1.1 scottr num_pm_data = pm_data; 843 1.1 scottr } else 844 1.1 scottr num_pm_data = pm_num_rx_data; 845 1.1 scottr pmdata->num_data = num_pm_data; 846 1.1 scottr } else { /* PB 1XX serias ? */ 847 1.4 scottr if ((rval = pm_receive_pm2(&pm_data)) != 0) 848 1.1 scottr break; /* timeout */ 849 1.1 scottr num_pm_data = pm_data; 850 1.1 scottr pmdata->num_data = num_pm_data; 851 1.1 scottr } 852 1.1 scottr 853 1.1 scottr /* receive PM data */ 854 1.1 scottr pm_buf = (u_char *)pmdata->r_buf; 855 1.4 scottr for (i = 0; i < num_pm_data; i++) { 856 1.4 scottr if ((rval = pm_receive_pm2(&pm_data)) != 0) 857 1.1 scottr break; /* timeout */ 858 1.1 scottr pm_buf[i] = pm_data; 859 1.1 scottr } 860 1.1 scottr 861 1.1 scottr rval = 0; 862 1.1 scottr } 863 1.1 scottr 864 1.1 scottr /* restore former value */ 865 1.1 scottr via_reg(VIA1, vIER) = via1_vIER; 866 1.1 scottr splx(s); 867 1.1 scottr 868 1.38 nat mutex_spin_exit(&pm_mutex); 869 1.5 scottr return rval; 870 1.1 scottr } 871 1.1 scottr 872 1.1 scottr 873 1.1 scottr /* 874 1.1 scottr * My PM interrupt routine for the PB Duo series and the PB 5XX series 875 1.1 scottr */ 876 1.1 scottr void 877 1.23 chs pm_intr_pm2(void *arg) 878 1.1 scottr { 879 1.4 scottr int s; 880 1.4 scottr int rval; 881 1.4 scottr PMData pmdata; 882 1.1 scottr 883 1.1 scottr s = splhigh(); 884 1.1 scottr 885 1.4 scottr PM_VIA_CLR_INTR(); /* clear VIA1 interrupt */ 886 1.30 andvar /* ask PM what happened */ 887 1.1 scottr pmdata.command = 0x78; 888 1.1 scottr pmdata.num_data = 0; 889 1.1 scottr pmdata.s_buf = &pmdata.data[2]; 890 1.1 scottr pmdata.r_buf = &pmdata.data[2]; 891 1.4 scottr rval = pm_pmgrop_pm2(&pmdata); 892 1.1 scottr if (rval != 0) { 893 1.3 scottr #ifdef ADB_DEBUG 894 1.3 scottr if (adb_debug) 895 1.3 scottr printf("pm: PM is not ready. error code: %08x\n", rval); 896 1.1 scottr #endif 897 1.1 scottr splx(s); 898 1.31 nat return; 899 1.1 scottr } 900 1.1 scottr 901 1.4 scottr switch ((u_int)(pmdata.data[2] & 0xff)) { 902 1.4 scottr case 0x00: /* 1 sec interrupt? */ 903 1.1 scottr break; 904 1.4 scottr case 0x80: /* 1 sec interrupt? */ 905 1.1 scottr pm_counter++; 906 1.1 scottr break; 907 1.37 nat case 0x08: /* Brightness/Contrast button on LCD panel */ 908 1.1 scottr /* get brightness and contrast of the LCD */ 909 1.1 scottr pm_LCD_brightness = (u_int)pmdata.data[3] & 0xff; 910 1.1 scottr pm_LCD_contrast = (u_int)pmdata.data[4] & 0xff; 911 1.1 scottr /* 912 1.4 scottr pm_printerr("#08", rval, pmdata.num_data, pmdata.data); 913 1.1 scottr pmdata.command = 0x33; 914 1.1 scottr pmdata.num_data = 1; 915 1.1 scottr pmdata.s_buf = pmdata.data; 916 1.1 scottr pmdata.r_buf = pmdata.data; 917 1.1 scottr pmdata.data[0] = pm_LCD_contrast; 918 1.4 scottr rval = pm_pmgrop_pm2(&pmdata); 919 1.4 scottr pm_printerr("#33", rval, pmdata.num_data, pmdata.data); 920 1.1 scottr */ 921 1.33 nat pm_LCD_brightness = 922 1.33 nat pm_set_brightness(pm_LCD_brightness); 923 1.1 scottr break; 924 1.4 scottr case 0x10: /* ADB data that were requested by TALK command */ 925 1.1 scottr case 0x14: 926 1.1 scottr pm_adb_get_TALK_result(&pmdata); 927 1.1 scottr break; 928 1.4 scottr case 0x16: /* ADB device event */ 929 1.1 scottr case 0x18: 930 1.1 scottr case 0x1e: 931 1.1 scottr pm_adb_get_ADB_data(&pmdata); 932 1.1 scottr break; 933 1.1 scottr default: 934 1.3 scottr #ifdef ADB_DEBUG 935 1.3 scottr if (adb_debug) 936 1.3 scottr pm_printerr("driver does not supported this event.", 937 1.3 scottr pmdata.data[2], pmdata.num_data, 938 1.3 scottr pmdata.data); 939 1.1 scottr #endif 940 1.1 scottr break; 941 1.1 scottr } 942 1.1 scottr 943 1.1 scottr splx(s); 944 1.1 scottr } 945 1.1 scottr 946 1.1 scottr 947 1.1 scottr /* 948 1.1 scottr * MRG-based PMgrOp routine 949 1.1 scottr */ 950 1.1 scottr int 951 1.23 chs pm_pmgrop_mrg(PMData *pmdata) 952 1.1 scottr { 953 1.1 scottr u_int32_t rval=0; 954 1.1 scottr 955 1.27 perry __asm volatile( 956 1.20 thorpej " movl %1,%%a0 \n" 957 1.20 thorpej " .word 0xa085 \n" 958 1.20 thorpej " movl %%d0,%0" 959 1.1 scottr : "=g" (rval) 960 1.1 scottr : "g" (pmdata) 961 1.18 chs : "a0","d0"); 962 1.1 scottr 963 1.1 scottr return rval; 964 1.1 scottr } 965 1.1 scottr 966 1.1 scottr 967 1.1 scottr /* 968 1.1 scottr * My PMgrOp routine 969 1.1 scottr */ 970 1.1 scottr int 971 1.23 chs pmgrop(PMData *pmdata) 972 1.1 scottr { 973 1.4 scottr switch (pmHardware) { 974 1.1 scottr case PM_HW_PB1XX: 975 1.4 scottr return (pm_pmgrop_pm1(pmdata)); 976 1.1 scottr break; 977 1.1 scottr case PM_HW_PB5XX: 978 1.4 scottr return (pm_pmgrop_pm2(pmdata)); 979 1.1 scottr break; 980 1.1 scottr default: 981 1.4 scottr /* return (pmgrop_mrg(pmdata)); */ 982 1.5 scottr return 1; 983 1.1 scottr } 984 1.1 scottr } 985 1.1 scottr 986 1.1 scottr 987 1.1 scottr /* 988 1.1 scottr * My PM interrupt routine 989 1.1 scottr */ 990 1.1 scottr void 991 1.23 chs pm_intr(void *arg) 992 1.1 scottr { 993 1.4 scottr switch (pmHardware) { 994 1.1 scottr case PM_HW_PB1XX: 995 1.9 briggs pm_intr_pm1(arg); 996 1.1 scottr break; 997 1.1 scottr case PM_HW_PB5XX: 998 1.9 briggs pm_intr_pm2(arg); 999 1.1 scottr break; 1000 1.1 scottr default: 1001 1.1 scottr break; 1002 1.1 scottr } 1003 1.1 scottr } 1004 1.1 scottr 1005 1.1 scottr 1006 1.9 briggs void 1007 1.23 chs pm_hw_setup(void) 1008 1.9 briggs { 1009 1.9 briggs switch (pmHardware) { 1010 1.9 briggs case PM_HW_PB1XX: 1011 1.9 briggs via1_register_irq(4, pm_intr_pm1, (void *)0); 1012 1.9 briggs PM_VIA_CLR_INTR(); 1013 1.9 briggs break; 1014 1.9 briggs case PM_HW_PB5XX: 1015 1.9 briggs via1_register_irq(4, pm_intr_pm2, (void *)0); 1016 1.9 briggs PM_VIA_CLR_INTR(); 1017 1.9 briggs break; 1018 1.9 briggs default: 1019 1.9 briggs break; 1020 1.9 briggs } 1021 1.9 briggs } 1022 1.9 briggs 1023 1.1 scottr 1024 1.1 scottr /* 1025 1.1 scottr * Synchronous ADBOp routine for the Power Manager 1026 1.1 scottr */ 1027 1.1 scottr int 1028 1.23 chs pm_adb_op(u_char *buffer, void *compRout, void *data, int command) 1029 1.1 scottr { 1030 1.5 scottr int i; 1031 1.4 scottr int s; 1032 1.4 scottr int rval; 1033 1.24 jmc int xdelay; 1034 1.4 scottr PMData pmdata; 1035 1.5 scottr struct adbCommand packet; 1036 1.1 scottr 1037 1.1 scottr if (adbWaiting == 1) 1038 1.5 scottr return 1; 1039 1.1 scottr 1040 1.1 scottr s = splhigh(); 1041 1.1 scottr via_reg(VIA1, vIER) = 0x10; 1042 1.1 scottr 1043 1.1 scottr adbBuffer = buffer; 1044 1.1 scottr adbCompRout = compRout; 1045 1.1 scottr adbCompData = data; 1046 1.1 scottr 1047 1.1 scottr pmdata.command = 0x20; 1048 1.1 scottr pmdata.s_buf = pmdata.data; 1049 1.1 scottr pmdata.r_buf = pmdata.data; 1050 1.1 scottr 1051 1.1 scottr if ((command & 0xc) == 0x8) { /* if the command is LISTEN, add number of ADB data to number of PM data */ 1052 1.1 scottr if (buffer != (u_char *)0) 1053 1.1 scottr pmdata.num_data = buffer[0] + 3; 1054 1.1 scottr } else { 1055 1.1 scottr pmdata.num_data = 3; 1056 1.1 scottr } 1057 1.1 scottr 1058 1.1 scottr pmdata.data[0] = (u_char)(command & 0xff); 1059 1.1 scottr pmdata.data[1] = 0; 1060 1.1 scottr if ((command & 0xc) == 0x8) { /* if the command is LISTEN, copy ADB data to PM buffer */ 1061 1.1 scottr if ((buffer != (u_char *)0) && (buffer[0] <= 24)) { 1062 1.1 scottr pmdata.data[2] = buffer[0]; /* number of data */ 1063 1.4 scottr for (i = 0; i < buffer[0]; i++) 1064 1.1 scottr pmdata.data[3 + i] = buffer[1 + i]; 1065 1.1 scottr } else 1066 1.1 scottr pmdata.data[2] = 0; 1067 1.1 scottr } else 1068 1.1 scottr pmdata.data[2] = 0; 1069 1.1 scottr 1070 1.5 scottr if ((command & 0xc) != 0xc) { /* if the command is not TALK */ 1071 1.9 briggs /* set up stuff fNULLor adb_pass_up */ 1072 1.5 scottr packet.data[0] = 1 + pmdata.data[2]; 1073 1.5 scottr packet.data[1] = command; 1074 1.5 scottr for (i = 0; i < pmdata.data[2]; i++) 1075 1.5 scottr packet.data[i+2] = pmdata.data[i+3]; 1076 1.5 scottr packet.saveBuf = adbBuffer; 1077 1.5 scottr packet.compRout = adbCompRout; 1078 1.5 scottr packet.compData = adbCompData; 1079 1.5 scottr packet.cmd = command; 1080 1.5 scottr packet.unsol = 0; 1081 1.5 scottr packet.ack_only = 1; 1082 1.10 scottr adb_polling = 1; 1083 1.5 scottr adb_pass_up(&packet); 1084 1.10 scottr adb_polling = 0; 1085 1.5 scottr } 1086 1.5 scottr 1087 1.4 scottr rval = pmgrop(&pmdata); 1088 1.12 scottr if (rval != 0) { 1089 1.12 scottr splx(s); 1090 1.5 scottr return 1; 1091 1.12 scottr } 1092 1.1 scottr 1093 1.5 scottr adbWaiting = 1; 1094 1.5 scottr adbWaitingCmd = command; 1095 1.1 scottr 1096 1.1 scottr PM_VIA_INTR_ENABLE(); 1097 1.1 scottr 1098 1.17 wiz /* wait until the PM interrupt has occurred */ 1099 1.24 jmc xdelay = 0x80000; 1100 1.4 scottr while (adbWaiting == 1) { 1101 1.15 scottr switch (mac68k_machine.machineid) { 1102 1.19 shiba case MACH_MACPB150: 1103 1.15 scottr case MACH_MACPB210: 1104 1.15 scottr case MACH_MACPB230: /* daishi tested with Duo230 */ 1105 1.15 scottr case MACH_MACPB250: 1106 1.15 scottr case MACH_MACPB270: 1107 1.15 scottr case MACH_MACPB280: 1108 1.15 scottr case MACH_MACPB280C: 1109 1.21 shiba case MACH_MACPB190: 1110 1.21 shiba case MACH_MACPB190CS: 1111 1.9 briggs pm_intr((void *)0); 1112 1.15 scottr break; 1113 1.15 scottr default: 1114 1.15 scottr if ((via_reg(VIA1, vIFR) & 0x10) == 0x10) 1115 1.15 scottr pm_intr((void *)0); 1116 1.15 scottr break; 1117 1.15 scottr } 1118 1.1 scottr #ifdef PM_GRAB_SI 1119 1.15 scottr (void)intr_dispatch(0x70); /* grab any serial interrupts */ 1120 1.1 scottr #endif 1121 1.24 jmc if ((--xdelay) < 0) { 1122 1.12 scottr splx(s); 1123 1.5 scottr return 1; 1124 1.12 scottr } 1125 1.1 scottr } 1126 1.1 scottr 1127 1.4 scottr /* this command enables the interrupt by operating ADB devices */ 1128 1.5 scottr if (HwCfgFlags3 & 0x00020000) { /* PB Duo series, PB 5XX series */ 1129 1.1 scottr pmdata.command = 0x20; 1130 1.1 scottr pmdata.num_data = 4; 1131 1.1 scottr pmdata.s_buf = pmdata.data; 1132 1.1 scottr pmdata.r_buf = pmdata.data; 1133 1.36 riastrad pmdata.data[0] = 0x00; 1134 1.1 scottr pmdata.data[1] = 0x86; /* magic spell for awaking the PM */ 1135 1.36 riastrad pmdata.data[2] = 0x00; 1136 1.1 scottr pmdata.data[3] = 0x0c; /* each bit may express the existent ADB device */ 1137 1.5 scottr } else { /* PB 1XX series */ 1138 1.1 scottr pmdata.command = 0x20; 1139 1.1 scottr pmdata.num_data = 3; 1140 1.1 scottr pmdata.s_buf = pmdata.data; 1141 1.1 scottr pmdata.r_buf = pmdata.data; 1142 1.1 scottr pmdata.data[0] = (u_char)(command & 0xf0) | 0xc; 1143 1.1 scottr pmdata.data[1] = 0x04; 1144 1.1 scottr pmdata.data[2] = 0x00; 1145 1.1 scottr } 1146 1.4 scottr rval = pmgrop(&pmdata); 1147 1.1 scottr 1148 1.1 scottr splx(s); 1149 1.5 scottr return rval; 1150 1.1 scottr } 1151 1.1 scottr 1152 1.1 scottr 1153 1.1 scottr void 1154 1.23 chs pm_adb_get_TALK_result(PMData *pmdata) 1155 1.1 scottr { 1156 1.1 scottr int i; 1157 1.5 scottr struct adbCommand packet; 1158 1.1 scottr 1159 1.5 scottr /* set up data for adb_pass_up */ 1160 1.5 scottr packet.data[0] = pmdata->num_data-1; 1161 1.5 scottr packet.data[1] = pmdata->data[3]; 1162 1.5 scottr for (i = 0; i <packet.data[0]-1; i++) 1163 1.5 scottr packet.data[i+2] = pmdata->data[i+4]; 1164 1.5 scottr 1165 1.5 scottr packet.saveBuf = adbBuffer; 1166 1.5 scottr packet.compRout = adbCompRout; 1167 1.5 scottr packet.compData = adbCompData; 1168 1.5 scottr packet.unsol = 0; 1169 1.5 scottr packet.ack_only = 0; 1170 1.10 scottr adb_polling = 1; 1171 1.5 scottr adb_pass_up(&packet); 1172 1.10 scottr adb_polling = 0; 1173 1.5 scottr 1174 1.5 scottr adbWaiting = 0; 1175 1.5 scottr adbBuffer = (long)0; 1176 1.5 scottr adbCompRout = (long)0; 1177 1.5 scottr adbCompData = (long)0; 1178 1.1 scottr } 1179 1.1 scottr 1180 1.1 scottr 1181 1.1 scottr void 1182 1.23 chs pm_adb_get_ADB_data(PMData *pmdata) 1183 1.1 scottr { 1184 1.1 scottr int i; 1185 1.5 scottr struct adbCommand packet; 1186 1.1 scottr 1187 1.5 scottr /* set up data for adb_pass_up */ 1188 1.5 scottr packet.data[0] = pmdata->num_data-1; /* number of raw data */ 1189 1.5 scottr packet.data[1] = pmdata->data[3]; /* ADB command */ 1190 1.5 scottr for (i = 0; i <packet.data[0]-1; i++) 1191 1.5 scottr packet.data[i+2] = pmdata->data[i+4]; 1192 1.5 scottr packet.unsol = 1; 1193 1.5 scottr packet.ack_only = 0; 1194 1.5 scottr adb_pass_up(&packet); 1195 1.1 scottr } 1196 1.1 scottr 1197 1.1 scottr 1198 1.1 scottr void 1199 1.23 chs pm_adb_poll_next_device_pm1(PMData *pmdata) 1200 1.1 scottr { 1201 1.1 scottr int i; 1202 1.1 scottr int ndid; 1203 1.1 scottr u_short bendid = 0x1; 1204 1.1 scottr PMData tmp_pmdata; 1205 1.1 scottr 1206 1.1 scottr /* find another existent ADB device to poll */ 1207 1.4 scottr for (i = 1; i < 16; i++) { 1208 1.11 scottr ndid = (ADB_CMDADDR(pmdata->data[3]) + i) & 0xf; 1209 1.1 scottr bendid <<= ndid; 1210 1.1 scottr if ((pm_existent_ADB_devices & bendid) != 0) 1211 1.1 scottr break; 1212 1.1 scottr } 1213 1.1 scottr 1214 1.1 scottr /* poll the other device */ 1215 1.1 scottr tmp_pmdata.command = 0x20; 1216 1.1 scottr tmp_pmdata.num_data = 3; 1217 1.1 scottr tmp_pmdata.s_buf = tmp_pmdata.data; 1218 1.1 scottr tmp_pmdata.r_buf = tmp_pmdata.data; 1219 1.1 scottr tmp_pmdata.data[0] = (u_char)(ndid << 4) | 0xc; 1220 1.1 scottr tmp_pmdata.data[1] = 0x04; /* magic spell for awaking the PM */ 1221 1.1 scottr tmp_pmdata.data[2] = 0x00; 1222 1.29 martin pmgrop(&tmp_pmdata); 1223 1.1 scottr } 1224 1.34 nat 1225 1.36 riastrad void 1226 1.34 nat pm_poweroff(void) 1227 1.34 nat { 1228 1.34 nat PMData pmdata; 1229 1.34 nat int attempt = 3; 1230 1.34 nat 1231 1.34 nat while (pmHardware == PM_HW_PB1XX && attempt > 0) { 1232 1.39 nat pmdata.command = 0xef; 1233 1.34 nat pmdata.num_data = 0; 1234 1.34 nat pmdata.data[0] = pmdata.data[1] = 0; 1235 1.34 nat pmdata.s_buf = &pmdata.data[2]; 1236 1.34 nat pmdata.r_buf = &pmdata.data[2]; 1237 1.34 nat (void)pm_pmgrop_pm1(&pmdata); 1238 1.34 nat attempt--; 1239 1.36 riastrad } 1240 1.34 nat 1241 1.34 nat return; 1242 1.34 nat } 1243 1.34 nat 1244 1.33 nat u_int 1245 1.33 nat pm_set_brightness(u_int brightness) 1246 1.33 nat { 1247 1.33 nat PMData pmdata; 1248 1.33 nat 1249 1.33 nat pmdata.num_data = 1; 1250 1.33 nat pmdata.s_buf = pmdata.data; 1251 1.33 nat pmdata.r_buf = pmdata.data; 1252 1.33 nat 1253 1.33 nat switch (pmHardware) { 1254 1.33 nat case PM_HW_PB5XX: 1255 1.33 nat /* this is an experimental code */ 1256 1.33 nat pmdata.command = 0x41; 1257 1.37 nat if ((int)brightness < 0) 1258 1.37 nat brightness = 0; 1259 1.37 nat if ((int)brightness > 31) 1260 1.37 nat brightness = 31; 1261 1.37 nat pmdata.data[0] = (31 - brightness) * 23 / 10 + 37; 1262 1.33 nat (void)pm_pmgrop_pm2(&pmdata); 1263 1.33 nat break; 1264 1.33 nat case PM_HW_PB1XX: 1265 1.33 nat /* this is an experimental code also */ 1266 1.33 nat pmdata.command = 0x40; 1267 1.33 nat if ((int)brightness < 0) 1268 1.33 nat brightness = 0; 1269 1.33 nat if ((int)brightness > 31) 1270 1.33 nat brightness = 31; 1271 1.33 nat pmdata.data[0] = 31 - brightness; 1272 1.33 nat (void)pm_pmgrop_pm1(&pmdata); 1273 1.33 nat break; 1274 1.33 nat default: 1275 1.33 nat 1276 1.33 nat return 0; 1277 1.33 nat break; 1278 1.33 nat } 1279 1.33 nat 1280 1.33 nat return brightness; 1281 1.33 nat } 1282
Indexes created Thu Oct 02 14:10:14 GMT 2025