1 /* 2 * CDDL HEADER START 3 * 4 * The contents of this file are subject to the terms of the 5 * Common Development and Distribution License (the "License"). 6 * You may not use this file except in compliance with the License. 7 * 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE 9 * or http://www.opensolaris.org/os/licensing. 10 * See the License for the specific language governing permissions 11 * and limitations under the License. 12 * 13 * When distributing Covered Code, include this CDDL HEADER in each 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE. 15 * If applicable, add the following below this CDDL HEADER, with the 16 * fields enclosed by brackets "[]" replaced with your own identifying 17 * information: Portions Copyright [yyyy] [name of copyright owner] 18 * 19 * CDDL HEADER END 20 */ 21 /* 22 * Copyright 2009 Sun Microsystems, Inc. All rights reserved. 23 * Use is subject to license terms. 24 */ 25 26 /* 27 * CPU Device driver. The driver is not DDI-compliant. 28 * 29 * The driver supports following features: 30 * - Power management. 31 */ 32 33 #include <sys/types.h> 34 #include <sys/param.h> 35 #include <sys/errno.h> 36 #include <sys/modctl.h> 37 #include <sys/kmem.h> 38 #include <sys/conf.h> 39 #include <sys/cmn_err.h> 40 #include <sys/stat.h> 41 #include <sys/debug.h> 42 #include <sys/systm.h> 43 #include <sys/ddi.h> 44 #include <sys/sunddi.h> 45 #include <sys/sdt.h> 46 47 #include <sys/machsystm.h> 48 #include <sys/x_call.h> 49 #include <sys/cpudrv_mach.h> 50 #include <sys/msacct.h> 51 52 /* 53 * CPU power management 54 * 55 * The supported power saving model is to slow down the CPU (on SPARC by 56 * dividing the CPU clock and on x86 by dropping down a P-state). 57 * Periodically we determine the amount of time the CPU is running 58 * idle thread and threads in user mode during the last quantum. If the idle 59 * thread was running less than its low water mark for current speed for 60 * number of consecutive sampling periods, or number of running threads in 61 * user mode are above its high water mark, we arrange to go to the higher 62 * speed. If the idle thread was running more than its high water mark without 63 * dropping a number of consecutive times below the mark, and number of threads 64 * running in user mode are below its low water mark, we arrange to go to the 65 * next lower speed. While going down, we go through all the speeds. While 66 * going up we go to the maximum speed to minimize impact on the user, but have 67 * provisions in the driver to go to other speeds. 68 * 69 * The driver does not have knowledge of a particular implementation of this 70 * scheme and will work with all CPUs supporting this model. On SPARC, the 71 * driver determines supported speeds by looking at 'clock-divisors' property 72 * created by OBP. On x86, the driver retrieves the supported speeds from 73 * ACPI. 74 */ 75 76 /* 77 * Configuration function prototypes and data structures 78 */ 79 static int cpudrv_attach(dev_info_t *dip, ddi_attach_cmd_t cmd); 80 static int cpudrv_detach(dev_info_t *dip, ddi_detach_cmd_t cmd); 81 static int cpudrv_power(dev_info_t *dip, int comp, int level); 82 83 struct dev_ops cpudrv_ops = { 84 DEVO_REV, /* rev */ 85 0, /* refcnt */ 86 nodev, /* getinfo */ 87 nulldev, /* identify */ 88 nulldev, /* probe */ 89 cpudrv_attach, /* attach */ 90 cpudrv_detach, /* detach */ 91 nodev, /* reset */ 92 (struct cb_ops *)NULL, /* cb_ops */ 93 (struct bus_ops *)NULL, /* bus_ops */ 94 cpudrv_power, /* power */ 95 ddi_quiesce_not_needed, /* quiesce */ 96 }; 97 98 static struct modldrv modldrv = { 99 &mod_driverops, /* modops */ 100 "CPU Driver", /* linkinfo */ 101 &cpudrv_ops, /* dev_ops */ 102 }; 103 104 static struct modlinkage modlinkage = { 105 MODREV_1, /* rev */ 106 &modldrv, /* linkage */ 107 NULL 108 }; 109 110 /* 111 * Function prototypes 112 */ 113 static int cpudrv_pm_init_power(cpudrv_devstate_t *cpudsp); 114 static void cpudrv_pm_free(cpudrv_devstate_t *cpudsp); 115 static int cpudrv_pm_comp_create(cpudrv_devstate_t *cpudsp); 116 static void cpudrv_pm_monitor_disp(void *arg); 117 static void cpudrv_pm_monitor(void *arg); 118 119 /* 120 * Driver global variables 121 */ 122 uint_t cpudrv_debug = 0; 123 void *cpudrv_state; 124 static uint_t cpudrv_pm_idle_hwm = CPUDRV_PM_IDLE_HWM; 125 static uint_t cpudrv_pm_idle_lwm = CPUDRV_PM_IDLE_LWM; 126 static uint_t cpudrv_pm_idle_buf_zone = CPUDRV_PM_IDLE_BUF_ZONE; 127 static uint_t cpudrv_pm_idle_bhwm_cnt_max = CPUDRV_PM_IDLE_BHWM_CNT_MAX; 128 static uint_t cpudrv_pm_idle_blwm_cnt_max = CPUDRV_PM_IDLE_BLWM_CNT_MAX; 129 static uint_t cpudrv_pm_user_hwm = CPUDRV_PM_USER_HWM; 130 131 /* 132 * cpudrv_direct_pm allows user applications to directly control the 133 * power state transitions (direct pm) without following the normal 134 * direct pm protocol. This is needed because the normal protocol 135 * requires that a device only be lowered when it is idle, and be 136 * brought up when it request to do so by calling pm_raise_power(). 137 * Ignoring this protocol is harmless for CPU (other than speed). 138 * Moreover it might be the case that CPU is never idle or wants 139 * to be at higher speed because of the addition CPU cycles required 140 * to run the user application. 141 * 142 * The driver will still report idle/busy status to the framework. Although 143 * framework will ignore this information for direct pm devices and not 144 * try to bring them down when idle, user applications can still use this 145 * information if they wants. 146 * 147 * In the future, provide an ioctl to control setting of this mode. In 148 * that case, this variable should move to the state structure and 149 * be protected by the lock in the state structure. 150 */ 151 int cpudrv_direct_pm = 0; 152 153 /* 154 * Arranges for the handler function to be called at the interval suitable 155 * for current speed. 156 */ 157 #define CPUDRV_PM_MONITOR_INIT(cpudsp) { \ 158 if (CPUDRV_PM_POWER_ENABLED(cpudsp)) { \ 159 ASSERT(mutex_owned(&(cpudsp)->lock)); \ 160 (cpudsp)->cpudrv_pm.timeout_id = \ 161 timeout(cpudrv_pm_monitor_disp, \ 162 (cpudsp), (((cpudsp)->cpudrv_pm.cur_spd == NULL) ? \ 163 CPUDRV_PM_QUANT_CNT_OTHR : \ 164 (cpudsp)->cpudrv_pm.cur_spd->quant_cnt)); \ 165 } \ 166 } 167 168 /* 169 * Arranges for the handler function not to be called back. 170 */ 171 #define CPUDRV_PM_MONITOR_FINI(cpudsp) { \ 172 timeout_id_t tmp_tid; \ 173 ASSERT(mutex_owned(&(cpudsp)->lock)); \ 174 tmp_tid = (cpudsp)->cpudrv_pm.timeout_id; \ 175 (cpudsp)->cpudrv_pm.timeout_id = 0; \ 176 mutex_exit(&(cpudsp)->lock); \ 177 if (tmp_tid != 0) { \ 178 (void) untimeout(tmp_tid); \ 179 mutex_enter(&(cpudsp)->cpudrv_pm.timeout_lock); \ 180 while ((cpudsp)->cpudrv_pm.timeout_count != 0) \ 181 cv_wait(&(cpudsp)->cpudrv_pm.timeout_cv, \ 182 &(cpudsp)->cpudrv_pm.timeout_lock); \ 183 mutex_exit(&(cpudsp)->cpudrv_pm.timeout_lock); \ 184 } \ 185 mutex_enter(&(cpudsp)->lock); \ 186 } 187 188 int 189 _init(void) 190 { 191 int error; 192 193 DPRINTF(D_INIT, (" _init: function called\n")); 194 if ((error = ddi_soft_state_init(&cpudrv_state, 195 sizeof (cpudrv_devstate_t), 0)) != 0) { 196 return (error); 197 } 198 199 if ((error = mod_install(&modlinkage)) != 0) { 200 ddi_soft_state_fini(&cpudrv_state); 201 } 202 203 /* 204 * Callbacks used by the PPM driver. 205 */ 206 CPUDRV_PM_SET_PPM_CALLBACKS(); 207 return (error); 208 } 209 210 int 211 _fini(void) 212 { 213 int error; 214 215 DPRINTF(D_FINI, (" _fini: function called\n")); 216 if ((error = mod_remove(&modlinkage)) == 0) { 217 ddi_soft_state_fini(&cpudrv_state); 218 } 219 220 return (error); 221 } 222 223 int 224 _info(struct modinfo *modinfop) 225 { 226 return (mod_info(&modlinkage, modinfop)); 227 } 228 229 /* 230 * Driver attach(9e) entry point. 231 */ 232 static int 233 cpudrv_attach(dev_info_t *dip, ddi_attach_cmd_t cmd) 234 { 235 int instance; 236 cpudrv_devstate_t *cpudsp; 237 extern pri_t maxclsyspri; 238 239 instance = ddi_get_instance(dip); 240 241 switch (cmd) { 242 case DDI_ATTACH: 243 DPRINTF(D_ATTACH, ("cpudrv_attach: instance %d: " 244 "DDI_ATTACH called\n", instance)); 245 if (CPUDRV_PM_DISABLED()) 246 return (DDI_FAILURE); 247 if (ddi_soft_state_zalloc(cpudrv_state, instance) != 248 DDI_SUCCESS) { 249 cmn_err(CE_WARN, "cpudrv_attach: instance %d: " 250 "can't allocate state", instance); 251 CPUDRV_PM_DISABLE(); 252 return (DDI_FAILURE); 253 } 254 if ((cpudsp = ddi_get_soft_state(cpudrv_state, instance)) == 255 NULL) { 256 cmn_err(CE_WARN, "cpudrv_attach: instance %d: " 257 "can't get state", instance); 258 ddi_soft_state_free(cpudrv_state, instance); 259 CPUDRV_PM_DISABLE(); 260 return (DDI_FAILURE); 261 } 262 cpudsp->dip = dip; 263 264 /* 265 * Find CPU number for this dev_info node. 266 */ 267 if (!cpudrv_pm_get_cpu_id(dip, &(cpudsp->cpu_id))) { 268 cmn_err(CE_WARN, "cpudrv_attach: instance %d: " 269 "can't convert dip to cpu_id", instance); 270 ddi_soft_state_free(cpudrv_state, instance); 271 CPUDRV_PM_DISABLE(); 272 return (DDI_FAILURE); 273 } 274 if (!cpudrv_mach_pm_init(cpudsp)) { 275 ddi_soft_state_free(cpudrv_state, instance); 276 CPUDRV_PM_DISABLE(); 277 return (DDI_FAILURE); 278 } 279 mutex_init(&cpudsp->lock, NULL, MUTEX_DRIVER, NULL); 280 if (CPUDRV_PM_POWER_ENABLED(cpudsp)) { 281 if (cpudrv_pm_init_power(cpudsp) != DDI_SUCCESS) { 282 CPUDRV_PM_DISABLE(); 283 cpudrv_pm_free(cpudsp); 284 ddi_soft_state_free(cpudrv_state, instance); 285 return (DDI_FAILURE); 286 } 287 if (cpudrv_pm_comp_create(cpudsp) != DDI_SUCCESS) { 288 CPUDRV_PM_DISABLE(); 289 cpudrv_pm_free(cpudsp); 290 ddi_soft_state_free(cpudrv_state, instance); 291 return (DDI_FAILURE); 292 } 293 if (ddi_prop_update_string(DDI_DEV_T_NONE, 294 dip, "pm-class", "CPU") != DDI_PROP_SUCCESS) { 295 CPUDRV_PM_DISABLE(); 296 cpudrv_pm_free(cpudsp); 297 ddi_soft_state_free(cpudrv_state, instance); 298 return (DDI_FAILURE); 299 } 300 301 /* 302 * Taskq is used to dispatch routine to monitor CPU 303 * activities. 304 */ 305 cpudsp->cpudrv_pm.tq = taskq_create_instance( 306 "cpudrv_pm_monitor", 307 ddi_get_instance(dip), CPUDRV_PM_TASKQ_THREADS, 308 (maxclsyspri - 1), CPUDRV_PM_TASKQ_MIN, 309 CPUDRV_PM_TASKQ_MAX, 310 TASKQ_PREPOPULATE|TASKQ_CPR_SAFE); 311 312 mutex_init(&cpudsp->cpudrv_pm.timeout_lock, NULL, 313 MUTEX_DRIVER, NULL); 314 cv_init(&cpudsp->cpudrv_pm.timeout_cv, NULL, 315 CV_DEFAULT, NULL); 316 317 /* 318 * Driver needs to assume that CPU is running at 319 * unknown speed at DDI_ATTACH and switch it to the 320 * needed speed. We assume that initial needed speed 321 * is full speed for us. 322 */ 323 /* 324 * We need to take the lock because cpudrv_pm_monitor() 325 * will start running in parallel with attach(). 326 */ 327 mutex_enter(&cpudsp->lock); 328 cpudsp->cpudrv_pm.cur_spd = NULL; 329 cpudsp->cpudrv_pm.pm_started = B_FALSE; 330 /* 331 * We don't call pm_raise_power() directly from attach 332 * because driver attach for a slave CPU node can 333 * happen before the CPU is even initialized. We just 334 * start the monitoring system which understands 335 * unknown speed and moves CPU to top speed when it 336 * has been initialized. 337 */ 338 CPUDRV_PM_MONITOR_INIT(cpudsp); 339 mutex_exit(&cpudsp->lock); 340 341 } 342 343 CPUDRV_PM_INSTALL_MAX_CHANGE_HANDLER(cpudsp, dip); 344 345 ddi_report_dev(dip); 346 return (DDI_SUCCESS); 347 348 case DDI_RESUME: 349 DPRINTF(D_ATTACH, ("cpudrv_attach: instance %d: " 350 "DDI_RESUME called\n", instance)); 351 352 cpudsp = ddi_get_soft_state(cpudrv_state, instance); 353 ASSERT(cpudsp != NULL); 354 355 /* 356 * Nothing to do for resume, if not doing active PM. 357 */ 358 if (!CPUDRV_PM_POWER_ENABLED(cpudsp)) 359 return (DDI_SUCCESS); 360 361 mutex_enter(&cpudsp->lock); 362 /* 363 * Driver needs to assume that CPU is running at unknown speed 364 * at DDI_RESUME and switch it to the needed speed. We assume 365 * that the needed speed is full speed for us. 366 */ 367 cpudsp->cpudrv_pm.cur_spd = NULL; 368 CPUDRV_PM_MONITOR_INIT(cpudsp); 369 mutex_exit(&cpudsp->lock); 370 CPUDRV_PM_REDEFINE_TOPSPEED(dip); 371 return (DDI_SUCCESS); 372 373 default: 374 return (DDI_FAILURE); 375 } 376 } 377 378 /* 379 * Driver detach(9e) entry point. 380 */ 381 static int 382 cpudrv_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) 383 { 384 int instance; 385 cpudrv_devstate_t *cpudsp; 386 cpudrv_pm_t *cpupm; 387 388 instance = ddi_get_instance(dip); 389 390 switch (cmd) { 391 case DDI_DETACH: 392 DPRINTF(D_DETACH, ("cpudrv_detach: instance %d: " 393 "DDI_DETACH called\n", instance)); 394 /* 395 * If the only thing supported by the driver is power 396 * management, we can in future enhance the driver and 397 * framework that loads it to unload the driver when 398 * user has disabled CPU power management. 399 */ 400 return (DDI_FAILURE); 401 402 case DDI_SUSPEND: 403 DPRINTF(D_DETACH, ("cpudrv_detach: instance %d: " 404 "DDI_SUSPEND called\n", instance)); 405 406 cpudsp = ddi_get_soft_state(cpudrv_state, instance); 407 ASSERT(cpudsp != NULL); 408 409 /* 410 * Nothing to do for suspend, if not doing active PM. 411 */ 412 if (!CPUDRV_PM_POWER_ENABLED(cpudsp)) 413 return (DDI_SUCCESS); 414 415 /* 416 * During a checkpoint-resume sequence, framework will 417 * stop interrupts to quiesce kernel activity. This will 418 * leave our monitoring system ineffective. Handle this 419 * by stopping our monitoring system and bringing CPU 420 * to full speed. In case we are in special direct pm 421 * mode, we leave the CPU at whatever speed it is. This 422 * is harmless other than speed. 423 */ 424 mutex_enter(&cpudsp->lock); 425 cpupm = &(cpudsp->cpudrv_pm); 426 427 DPRINTF(D_DETACH, ("cpudrv_detach: instance %d: DDI_SUSPEND - " 428 "cur_spd %d, topspeed %d\n", instance, 429 cpupm->cur_spd->pm_level, 430 CPUDRV_PM_TOPSPEED(cpupm)->pm_level)); 431 432 CPUDRV_PM_MONITOR_FINI(cpudsp); 433 434 if (!cpudrv_direct_pm && (cpupm->cur_spd != 435 CPUDRV_PM_TOPSPEED(cpupm))) { 436 if (cpupm->pm_busycnt < 1) { 437 if ((pm_busy_component(dip, CPUDRV_PM_COMP_NUM) 438 == DDI_SUCCESS)) { 439 cpupm->pm_busycnt++; 440 } else { 441 CPUDRV_PM_MONITOR_INIT(cpudsp); 442 mutex_exit(&cpudsp->lock); 443 cmn_err(CE_WARN, "cpudrv_detach: " 444 "instance %d: can't busy CPU " 445 "component", instance); 446 return (DDI_FAILURE); 447 } 448 } 449 mutex_exit(&cpudsp->lock); 450 if (pm_raise_power(dip, CPUDRV_PM_COMP_NUM, 451 CPUDRV_PM_TOPSPEED(cpupm)->pm_level) != 452 DDI_SUCCESS) { 453 mutex_enter(&cpudsp->lock); 454 CPUDRV_PM_MONITOR_INIT(cpudsp); 455 mutex_exit(&cpudsp->lock); 456 cmn_err(CE_WARN, "cpudrv_detach: instance %d: " 457 "can't raise CPU power level to %d", 458 instance, 459 CPUDRV_PM_TOPSPEED(cpupm)->pm_level); 460 return (DDI_FAILURE); 461 } else { 462 return (DDI_SUCCESS); 463 } 464 } else { 465 mutex_exit(&cpudsp->lock); 466 return (DDI_SUCCESS); 467 } 468 469 default: 470 return (DDI_FAILURE); 471 } 472 } 473 474 /* 475 * Driver power(9e) entry point. 476 * 477 * Driver's notion of current power is set *only* in power(9e) entry point 478 * after actual power change operation has been successfully completed. 479 */ 480 /* ARGSUSED */ 481 static int 482 cpudrv_power(dev_info_t *dip, int comp, int level) 483 { 484 int instance; 485 cpudrv_devstate_t *cpudsp; 486 cpudrv_pm_t *cpupm; 487 cpudrv_pm_spd_t *new_spd; 488 boolean_t is_ready; 489 int ret; 490 491 instance = ddi_get_instance(dip); 492 493 DPRINTF(D_POWER, ("cpudrv_power: instance %d: level %d\n", 494 instance, level)); 495 if ((cpudsp = ddi_get_soft_state(cpudrv_state, instance)) == NULL) { 496 cmn_err(CE_WARN, "cpudrv_power: instance %d: can't get state", 497 instance); 498 return (DDI_FAILURE); 499 } 500 501 mutex_enter(&cpudsp->lock); 502 cpupm = &(cpudsp->cpudrv_pm); 503 504 /* 505 * In normal operation, we fail if we are busy and request is 506 * to lower the power level. We let this go through if the driver 507 * is in special direct pm mode. On x86, we also let this through 508 * if the change is due to a request to govern the max speed. 509 */ 510 if (!cpudrv_direct_pm && (cpupm->pm_busycnt >= 1) && 511 !cpudrv_pm_is_governor_thread(cpupm)) { 512 if ((cpupm->cur_spd != NULL) && 513 (level < cpupm->cur_spd->pm_level)) { 514 mutex_exit(&cpudsp->lock); 515 return (DDI_FAILURE); 516 } 517 } 518 519 for (new_spd = cpupm->head_spd; new_spd; new_spd = new_spd->down_spd) { 520 if (new_spd->pm_level == level) 521 break; 522 } 523 if (!new_spd) { 524 CPUDRV_PM_RESET_GOVERNOR_THREAD(cpupm); 525 mutex_exit(&cpudsp->lock); 526 cmn_err(CE_WARN, "cpudrv_power: instance %d: " 527 "can't locate new CPU speed", instance); 528 return (DDI_FAILURE); 529 } 530 531 /* 532 * We currently refuse to power manage if the CPU is not ready to 533 * take cross calls (cross calls fail silently if CPU is not ready 534 * for it). 535 * 536 * Additionally, for x86 platforms we cannot power manage 537 * any one instance, until all instances have been initialized. 538 * That's because we don't know what the CPU domains look like 539 * until all instances have been initialized. 540 */ 541 is_ready = CPUDRV_PM_XCALL_IS_READY(cpudsp->cpu_id); 542 if (!is_ready) { 543 DPRINTF(D_POWER, ("cpudrv_power: instance %d: " 544 "CPU not ready for x-calls\n", instance)); 545 } else if (!(is_ready = cpudrv_pm_power_ready())) { 546 DPRINTF(D_POWER, ("cpudrv_power: instance %d: " 547 "waiting for all CPUs to be power manageable\n", instance)); 548 } 549 if (!is_ready) { 550 CPUDRV_PM_RESET_GOVERNOR_THREAD(cpupm); 551 mutex_exit(&cpudsp->lock); 552 return (DDI_FAILURE); 553 } 554 555 /* 556 * Execute CPU specific routine on the requested CPU to change its 557 * speed to normal-speed/divisor. 558 */ 559 if ((ret = cpudrv_pm_change_speed(cpudsp, new_spd)) != DDI_SUCCESS) { 560 cmn_err(CE_WARN, "cpudrv_power: cpudrv_pm_change_speed() " 561 "return = %d", ret); 562 mutex_exit(&cpudsp->lock); 563 return (DDI_FAILURE); 564 } 565 566 /* 567 * DTrace probe point for CPU speed change transition 568 */ 569 DTRACE_PROBE3(cpu__change__speed, cpudrv_devstate_t *, cpudsp, 570 cpudrv_pm_t *, cpupm, cpudrv_pm_spd_t *, new_spd); 571 572 /* 573 * Reset idle threshold time for the new power level. 574 */ 575 if ((cpupm->cur_spd != NULL) && (level < cpupm->cur_spd->pm_level)) { 576 if (pm_idle_component(dip, CPUDRV_PM_COMP_NUM) == 577 DDI_SUCCESS) { 578 if (cpupm->pm_busycnt >= 1) 579 cpupm->pm_busycnt--; 580 } else 581 cmn_err(CE_WARN, "cpudrv_power: instance %d: can't " 582 "idle CPU component", ddi_get_instance(dip)); 583 } 584 /* 585 * Reset various parameters because we are now running at new speed. 586 */ 587 cpupm->lastquan_mstate[CMS_IDLE] = 0; 588 cpupm->lastquan_mstate[CMS_SYSTEM] = 0; 589 cpupm->lastquan_mstate[CMS_USER] = 0; 590 cpupm->lastquan_ticks = 0; 591 cpupm->cur_spd = new_spd; 592 CPUDRV_PM_RESET_GOVERNOR_THREAD(cpupm); 593 mutex_exit(&cpudsp->lock); 594 595 return (DDI_SUCCESS); 596 } 597 598 /* 599 * Initialize the field that will be used for reporting 600 * the supported_frequencies_Hz cpu_info kstat. 601 */ 602 static void 603 set_supp_freqs(cpu_t *cp, cpudrv_pm_t *cpupm) 604 { 605 char *supp_freqs; 606 char *sfptr; 607 uint64_t *speeds; 608 cpudrv_pm_spd_t *spd; 609 int i; 610 #define UINT64_MAX_STRING (sizeof ("18446744073709551615")) 611 612 speeds = kmem_zalloc(cpupm->num_spd * sizeof (uint64_t), KM_SLEEP); 613 for (i = cpupm->num_spd - 1, spd = cpupm->head_spd; spd; 614 i--, spd = spd->down_spd) { 615 speeds[i] = 616 CPUDRV_PM_SPEED_HZ(cp->cpu_type_info.pi_clock, spd->speed); 617 } 618 619 supp_freqs = kmem_zalloc((UINT64_MAX_STRING * cpupm->num_spd), 620 KM_SLEEP); 621 sfptr = supp_freqs; 622 for (i = 0; i < cpupm->num_spd; i++) { 623 if (i == cpupm->num_spd - 1) { 624 (void) sprintf(sfptr, "%"PRIu64, speeds[i]); 625 } else { 626 (void) sprintf(sfptr, "%"PRIu64":", speeds[i]); 627 sfptr = supp_freqs + strlen(supp_freqs); 628 } 629 } 630 cpu_set_supp_freqs(cp, supp_freqs); 631 kmem_free(supp_freqs, (UINT64_MAX_STRING * cpupm->num_spd)); 632 kmem_free(speeds, cpupm->num_spd * sizeof (uint64_t)); 633 } 634 635 /* 636 * Initialize power management data. 637 */ 638 static int 639 cpudrv_pm_init_power(cpudrv_devstate_t *cpudsp) 640 { 641 cpudrv_pm_t *cpupm = &(cpudsp->cpudrv_pm); 642 cpudrv_pm_spd_t *cur_spd; 643 cpudrv_pm_spd_t *prev_spd = NULL; 644 int *speeds; 645 uint_t nspeeds; 646 int idle_cnt_percent; 647 int user_cnt_percent; 648 int i; 649 650 CPUDRV_PM_GET_SPEEDS(cpudsp, speeds, nspeeds); 651 if (nspeeds < 2) { 652 /* Need at least two speeds to power manage */ 653 CPUDRV_PM_FREE_SPEEDS(speeds, nspeeds); 654 return (DDI_FAILURE); 655 } 656 cpupm->num_spd = nspeeds; 657 658 /* 659 * Calculate the watermarks and other parameters based on the 660 * supplied speeds. 661 * 662 * One of the basic assumption is that for X amount of CPU work, 663 * if CPU is slowed down by a factor of N, the time it takes to 664 * do the same work will be N * X. 665 * 666 * The driver declares that a CPU is idle and ready for slowed down, 667 * if amount of idle thread is more than the current speed idle_hwm 668 * without dropping below idle_hwm a number of consecutive sampling 669 * intervals and number of running threads in user mode are below 670 * user_lwm. We want to set the current user_lwm such that if we 671 * just switched to the next slower speed with no change in real work 672 * load, the amount of user threads at the slower speed will be such 673 * that it falls below the slower speed's user_hwm. If we didn't do 674 * that then we will just come back to the higher speed as soon as we 675 * go down even with no change in work load. 676 * The user_hwm is a fixed precentage and not calculated dynamically. 677 * 678 * We bring the CPU up if idle thread at current speed is less than 679 * the current speed idle_lwm for a number of consecutive sampling 680 * intervals or user threads are above the user_hwm for the current 681 * speed. 682 */ 683 for (i = 0; i < nspeeds; i++) { 684 cur_spd = kmem_zalloc(sizeof (cpudrv_pm_spd_t), KM_SLEEP); 685 cur_spd->speed = speeds[i]; 686 if (i == 0) { /* normal speed */ 687 cpupm->head_spd = cur_spd; 688 CPUDRV_PM_TOPSPEED(cpupm) = cur_spd; 689 cur_spd->quant_cnt = CPUDRV_PM_QUANT_CNT_NORMAL; 690 cur_spd->idle_hwm = 691 (cpudrv_pm_idle_hwm * cur_spd->quant_cnt) / 100; 692 /* can't speed anymore */ 693 cur_spd->idle_lwm = 0; 694 cur_spd->user_hwm = UINT_MAX; 695 } else { 696 cur_spd->quant_cnt = CPUDRV_PM_QUANT_CNT_OTHR; 697 ASSERT(prev_spd != NULL); 698 prev_spd->down_spd = cur_spd; 699 cur_spd->up_spd = cpupm->head_spd; 700 701 /* 702 * Let's assume CPU is considered idle at full speed 703 * when it is spending I% of time in running the idle 704 * thread. At full speed, CPU will be busy (100 - I) % 705 * of times. This % of busyness increases by factor of 706 * N as CPU slows down. CPU that is idle I% of times 707 * in full speed, it is idle (100 - ((100 - I) * N)) % 708 * of times in N speed. The idle_lwm is a fixed 709 * percentage. A large value of N may result in 710 * idle_hwm to go below idle_lwm. We need to make sure 711 * that there is at least a buffer zone seperation 712 * between the idle_lwm and idle_hwm values. 713 */ 714 idle_cnt_percent = CPUDRV_PM_IDLE_CNT_PERCENT( 715 cpudrv_pm_idle_hwm, speeds, i); 716 idle_cnt_percent = max(idle_cnt_percent, 717 (cpudrv_pm_idle_lwm + cpudrv_pm_idle_buf_zone)); 718 cur_spd->idle_hwm = 719 (idle_cnt_percent * cur_spd->quant_cnt) / 100; 720 cur_spd->idle_lwm = 721 (cpudrv_pm_idle_lwm * cur_spd->quant_cnt) / 100; 722 723 /* 724 * The lwm for user threads are determined such that 725 * if CPU slows down, the load of work in the 726 * new speed would still keep the CPU at or below the 727 * user_hwm in the new speed. This is to prevent 728 * the quick jump back up to higher speed. 729 */ 730 cur_spd->user_hwm = (cpudrv_pm_user_hwm * 731 cur_spd->quant_cnt) / 100; 732 user_cnt_percent = CPUDRV_PM_USER_CNT_PERCENT( 733 cpudrv_pm_user_hwm, speeds, i); 734 prev_spd->user_lwm = 735 (user_cnt_percent * prev_spd->quant_cnt) / 100; 736 } 737 prev_spd = cur_spd; 738 } 739 /* Slowest speed. Can't slow down anymore */ 740 cur_spd->idle_hwm = UINT_MAX; 741 cur_spd->user_lwm = -1; 742 #ifdef DEBUG 743 DPRINTF(D_PM_INIT, ("cpudrv_pm_init: instance %d: head_spd spd %d, " 744 "num_spd %d\n", ddi_get_instance(cpudsp->dip), 745 cpupm->head_spd->speed, cpupm->num_spd)); 746 for (cur_spd = cpupm->head_spd; cur_spd; cur_spd = cur_spd->down_spd) { 747 DPRINTF(D_PM_INIT, ("cpudrv_pm_init: instance %d: speed %d, " 748 "down_spd spd %d, idle_hwm %d, user_lwm %d, " 749 "up_spd spd %d, idle_lwm %d, user_hwm %d, " 750 "quant_cnt %d\n", ddi_get_instance(cpudsp->dip), 751 cur_spd->speed, 752 (cur_spd->down_spd ? cur_spd->down_spd->speed : 0), 753 cur_spd->idle_hwm, cur_spd->user_lwm, 754 (cur_spd->up_spd ? cur_spd->up_spd->speed : 0), 755 cur_spd->idle_lwm, cur_spd->user_hwm, 756 cur_spd->quant_cnt)); 757 } 758 #endif /* DEBUG */ 759 CPUDRV_PM_FREE_SPEEDS(speeds, nspeeds); 760 return (DDI_SUCCESS); 761 } 762 763 /* 764 * Free CPU power management data. 765 */ 766 static void 767 cpudrv_pm_free(cpudrv_devstate_t *cpudsp) 768 { 769 cpudrv_pm_t *cpupm = &(cpudsp->cpudrv_pm); 770 cpudrv_pm_spd_t *cur_spd, *next_spd; 771 772 cur_spd = cpupm->head_spd; 773 while (cur_spd) { 774 next_spd = cur_spd->down_spd; 775 kmem_free(cur_spd, sizeof (cpudrv_pm_spd_t)); 776 cur_spd = next_spd; 777 } 778 bzero(cpupm, sizeof (cpudrv_pm_t)); 779 cpudrv_mach_pm_free(cpudsp); 780 } 781 782 /* 783 * Create pm-components property. 784 */ 785 static int 786 cpudrv_pm_comp_create(cpudrv_devstate_t *cpudsp) 787 { 788 cpudrv_pm_t *cpupm = &(cpudsp->cpudrv_pm); 789 cpudrv_pm_spd_t *cur_spd; 790 char **pmc; 791 int size; 792 char name[] = "NAME=CPU Speed"; 793 int i, j; 794 uint_t comp_spd; 795 int result = DDI_FAILURE; 796 797 pmc = kmem_zalloc((cpupm->num_spd + 1) * sizeof (char *), KM_SLEEP); 798 size = CPUDRV_PM_COMP_SIZE(); 799 if (cpupm->num_spd > CPUDRV_PM_COMP_MAX_VAL) { 800 cmn_err(CE_WARN, "cpudrv_pm_comp_create: instance %d: " 801 "number of speeds exceeded limits", 802 ddi_get_instance(cpudsp->dip)); 803 kmem_free(pmc, (cpupm->num_spd + 1) * sizeof (char *)); 804 return (result); 805 } 806 807 for (i = cpupm->num_spd, cur_spd = cpupm->head_spd; i > 0; 808 i--, cur_spd = cur_spd->down_spd) { 809 cur_spd->pm_level = i; 810 pmc[i] = kmem_zalloc((size * sizeof (char)), KM_SLEEP); 811 comp_spd = CPUDRV_PM_COMP_SPEED(cpupm, cur_spd); 812 if (comp_spd > CPUDRV_PM_COMP_MAX_VAL) { 813 cmn_err(CE_WARN, "cpudrv_pm_comp_create: " 814 "instance %d: speed exceeded limits", 815 ddi_get_instance(cpudsp->dip)); 816 for (j = cpupm->num_spd; j >= i; j--) { 817 kmem_free(pmc[j], size * sizeof (char)); 818 } 819 kmem_free(pmc, (cpupm->num_spd + 1) * 820 sizeof (char *)); 821 return (result); 822 } 823 CPUDRV_PM_COMP_SPRINT(pmc[i], cpupm, cur_spd, comp_spd) 824 DPRINTF(D_PM_COMP_CREATE, ("cpudrv_pm_comp_create: " 825 "instance %d: pm-components power level %d string '%s'\n", 826 ddi_get_instance(cpudsp->dip), i, pmc[i])); 827 } 828 pmc[0] = kmem_zalloc(sizeof (name), KM_SLEEP); 829 (void) strcat(pmc[0], name); 830 DPRINTF(D_PM_COMP_CREATE, ("cpudrv_pm_comp_create: instance %d: " 831 "pm-components component name '%s'\n", 832 ddi_get_instance(cpudsp->dip), pmc[0])); 833 834 if (ddi_prop_update_string_array(DDI_DEV_T_NONE, cpudsp->dip, 835 "pm-components", pmc, cpupm->num_spd + 1) == DDI_PROP_SUCCESS) { 836 result = DDI_SUCCESS; 837 } else { 838 cmn_err(CE_WARN, "cpudrv_pm_comp_create: instance %d: " 839 "can't create pm-components property", 840 ddi_get_instance(cpudsp->dip)); 841 } 842 843 for (i = cpupm->num_spd; i > 0; i--) { 844 kmem_free(pmc[i], size * sizeof (char)); 845 } 846 kmem_free(pmc[0], sizeof (name)); 847 kmem_free(pmc, (cpupm->num_spd + 1) * sizeof (char *)); 848 return (result); 849 } 850 851 /* 852 * Mark a component idle. 853 */ 854 #define CPUDRV_PM_MONITOR_PM_IDLE_COMP(dip, cpupm) { \ 855 if ((cpupm)->pm_busycnt >= 1) { \ 856 if (pm_idle_component((dip), CPUDRV_PM_COMP_NUM) == \ 857 DDI_SUCCESS) { \ 858 DPRINTF(D_PM_MONITOR, ("cpudrv_pm_monitor: " \ 859 "instance %d: pm_idle_component called\n", \ 860 ddi_get_instance((dip)))); \ 861 (cpupm)->pm_busycnt--; \ 862 } else { \ 863 cmn_err(CE_WARN, "cpudrv_pm_monitor: instance %d: " \ 864 "can't idle CPU component", \ 865 ddi_get_instance((dip))); \ 866 } \ 867 } \ 868 } 869 870 /* 871 * Marks a component busy in both PM framework and driver state structure. 872 */ 873 #define CPUDRV_PM_MONITOR_PM_BUSY_COMP(dip, cpupm) { \ 874 if ((cpupm)->pm_busycnt < 1) { \ 875 if (pm_busy_component((dip), CPUDRV_PM_COMP_NUM) == \ 876 DDI_SUCCESS) { \ 877 DPRINTF(D_PM_MONITOR, ("cpudrv_pm_monitor: " \ 878 "instance %d: pm_busy_component called\n", \ 879 ddi_get_instance((dip)))); \ 880 (cpupm)->pm_busycnt++; \ 881 } else { \ 882 cmn_err(CE_WARN, "cpudrv_pm_monitor: instance %d: " \ 883 "can't busy CPU component", \ 884 ddi_get_instance((dip))); \ 885 } \ 886 } \ 887 } 888 889 /* 890 * Marks a component busy and calls pm_raise_power(). 891 */ 892 #define CPUDRV_PM_MONITOR_PM_BUSY_AND_RAISE(dip, cpudsp, cpupm, new_level) { \ 893 /* \ 894 * Mark driver and PM framework busy first so framework doesn't try \ 895 * to bring CPU to lower speed when we need to be at higher speed. \ 896 */ \ 897 CPUDRV_PM_MONITOR_PM_BUSY_COMP((dip), (cpupm)); \ 898 mutex_exit(&(cpudsp)->lock); \ 899 DPRINTF(D_PM_MONITOR, ("cpudrv_pm_monitor: instance %d: " \ 900 "pm_raise_power called to %d\n", ddi_get_instance((dip)), \ 901 (new_level))); \ 902 if (pm_raise_power((dip), CPUDRV_PM_COMP_NUM, (new_level)) != \ 903 DDI_SUCCESS) { \ 904 cmn_err(CE_WARN, "cpudrv_pm_monitor: instance %d: can't " \ 905 "raise CPU power level", ddi_get_instance((dip))); \ 906 } \ 907 mutex_enter(&(cpudsp)->lock); \ 908 } 909 910 /* 911 * In order to monitor a CPU, we need to hold cpu_lock to access CPU 912 * statistics. Holding cpu_lock is not allowed from a callout routine. 913 * We dispatch a taskq to do that job. 914 */ 915 static void 916 cpudrv_pm_monitor_disp(void *arg) 917 { 918 cpudrv_devstate_t *cpudsp = (cpudrv_devstate_t *)arg; 919 920 /* 921 * We are here because the last task has scheduled a timeout. 922 * The queue should be empty at this time. 923 */ 924 mutex_enter(&cpudsp->cpudrv_pm.timeout_lock); 925 if (!taskq_dispatch(cpudsp->cpudrv_pm.tq, cpudrv_pm_monitor, arg, 926 TQ_NOSLEEP)) { 927 mutex_exit(&cpudsp->cpudrv_pm.timeout_lock); 928 DPRINTF(D_PM_MONITOR, ("cpudrv_pm_monitor_disp: failed to " 929 "dispatch the cpudrv_pm_monitor taskq\n")); 930 mutex_enter(&cpudsp->lock); 931 CPUDRV_PM_MONITOR_INIT(cpudsp); 932 mutex_exit(&cpudsp->lock); 933 return; 934 } 935 cpudsp->cpudrv_pm.timeout_count++; 936 mutex_exit(&cpudsp->cpudrv_pm.timeout_lock); 937 } 938 939 /* 940 * Monitors each CPU for the amount of time idle thread was running in the 941 * last quantum and arranges for the CPU to go to the lower or higher speed. 942 * Called at the time interval appropriate for the current speed. The 943 * time interval for normal speed is CPUDRV_PM_QUANT_CNT_NORMAL. The time 944 * interval for other speeds (including unknown speed) is 945 * CPUDRV_PM_QUANT_CNT_OTHR. 946 */ 947 static void 948 cpudrv_pm_monitor(void *arg) 949 { 950 cpudrv_devstate_t *cpudsp = (cpudrv_devstate_t *)arg; 951 cpudrv_pm_t *cpupm; 952 cpudrv_pm_spd_t *cur_spd, *new_spd; 953 cpu_t *cp; 954 dev_info_t *dip; 955 uint_t idle_cnt, user_cnt, system_cnt; 956 clock_t ticks; 957 uint_t tick_cnt; 958 hrtime_t msnsecs[NCMSTATES]; 959 boolean_t is_ready; 960 961 #define GET_CPU_MSTATE_CNT(state, cnt) \ 962 msnsecs[state] = NSEC_TO_TICK(msnsecs[state]); \ 963 if (cpupm->lastquan_mstate[state] > msnsecs[state]) \ 964 msnsecs[state] = cpupm->lastquan_mstate[state]; \ 965 cnt = msnsecs[state] - cpupm->lastquan_mstate[state]; \ 966 cpupm->lastquan_mstate[state] = msnsecs[state] 967 968 mutex_enter(&cpudsp->lock); 969 cpupm = &(cpudsp->cpudrv_pm); 970 if (cpupm->timeout_id == 0) { 971 mutex_exit(&cpudsp->lock); 972 goto do_return; 973 } 974 cur_spd = cpupm->cur_spd; 975 dip = cpudsp->dip; 976 977 /* 978 * We assume that a CPU is initialized and has a valid cpu_t 979 * structure, if it is ready for cross calls. If this changes, 980 * additional checks might be needed. 981 * 982 * Additionally, for x86 platforms we cannot power manage 983 * any one instance, until all instances have been initialized. 984 * That's because we don't know what the CPU domains look like 985 * until all instances have been initialized. 986 */ 987 is_ready = CPUDRV_PM_XCALL_IS_READY(cpudsp->cpu_id); 988 if (!is_ready) { 989 DPRINTF(D_PM_MONITOR, ("cpudrv_pm_monitor: instance %d: " 990 "CPU not ready for x-calls\n", ddi_get_instance(dip))); 991 } else if (!(is_ready = cpudrv_pm_power_ready())) { 992 DPRINTF(D_PM_MONITOR, ("cpudrv_pm_monitor: instance %d: " 993 "waiting for all CPUs to be power manageable\n", 994 ddi_get_instance(dip))); 995 } 996 if (!is_ready) { 997 /* 998 * Make sure that we are busy so that framework doesn't 999 * try to bring us down in this situation. 1000 */ 1001 CPUDRV_PM_MONITOR_PM_BUSY_COMP(dip, cpupm); 1002 CPUDRV_PM_MONITOR_INIT(cpudsp); 1003 mutex_exit(&cpudsp->lock); 1004 goto do_return; 1005 } 1006 1007 /* 1008 * Make sure that we are still not at unknown power level. 1009 */ 1010 if (cur_spd == NULL) { 1011 DPRINTF(D_PM_MONITOR, ("cpudrv_pm_monitor: instance %d: " 1012 "cur_spd is unknown\n", ddi_get_instance(dip))); 1013 CPUDRV_PM_MONITOR_PM_BUSY_AND_RAISE(dip, cpudsp, cpupm, 1014 CPUDRV_PM_TOPSPEED(cpupm)->pm_level); 1015 /* 1016 * We just changed the speed. Wait till at least next 1017 * call to this routine before proceeding ahead. 1018 */ 1019 CPUDRV_PM_MONITOR_INIT(cpudsp); 1020 mutex_exit(&cpudsp->lock); 1021 goto do_return; 1022 } 1023 1024 mutex_enter(&cpu_lock); 1025 if ((cp = cpu_get(cpudsp->cpu_id)) == NULL) { 1026 mutex_exit(&cpu_lock); 1027 CPUDRV_PM_MONITOR_INIT(cpudsp); 1028 mutex_exit(&cpudsp->lock); 1029 cmn_err(CE_WARN, "cpudrv_pm_monitor: instance %d: can't get " 1030 "cpu_t", ddi_get_instance(dip)); 1031 goto do_return; 1032 } 1033 1034 if (!cpupm->pm_started) { 1035 cpupm->pm_started = B_TRUE; 1036 set_supp_freqs(cp, cpupm); 1037 } 1038 1039 get_cpu_mstate(cp, msnsecs); 1040 GET_CPU_MSTATE_CNT(CMS_IDLE, idle_cnt); 1041 GET_CPU_MSTATE_CNT(CMS_USER, user_cnt); 1042 GET_CPU_MSTATE_CNT(CMS_SYSTEM, system_cnt); 1043 1044 /* 1045 * We can't do anything when we have just switched to a state 1046 * because there is no valid timestamp. 1047 */ 1048 if (cpupm->lastquan_ticks == 0) { 1049 cpupm->lastquan_ticks = NSEC_TO_TICK(gethrtime()); 1050 mutex_exit(&cpu_lock); 1051 CPUDRV_PM_MONITOR_INIT(cpudsp); 1052 mutex_exit(&cpudsp->lock); 1053 goto do_return; 1054 } 1055 1056 /* 1057 * Various watermarks are based on this routine being called back 1058 * exactly at the requested period. This is not guaranteed 1059 * because this routine is called from a taskq that is dispatched 1060 * from a timeout routine. Handle this by finding out how many 1061 * ticks have elapsed since the last call and adjusting 1062 * the idle_cnt based on the delay added to the requested period 1063 * by timeout and taskq. 1064 */ 1065 ticks = NSEC_TO_TICK(gethrtime()); 1066 tick_cnt = ticks - cpupm->lastquan_ticks; 1067 ASSERT(tick_cnt != 0); 1068 cpupm->lastquan_ticks = ticks; 1069 mutex_exit(&cpu_lock); 1070 /* 1071 * Time taken between recording the current counts and 1072 * arranging the next call of this routine is an error in our 1073 * calculation. We minimize the error by calling 1074 * CPUDRV_PM_MONITOR_INIT() here instead of end of this routine. 1075 */ 1076 CPUDRV_PM_MONITOR_INIT(cpudsp); 1077 DPRINTF(D_PM_MONITOR_VERBOSE, ("cpudrv_pm_monitor: instance %d: " 1078 "idle count %d, user count %d, system count %d, pm_level %d, " 1079 "pm_busycnt %d\n", ddi_get_instance(dip), idle_cnt, user_cnt, 1080 system_cnt, cur_spd->pm_level, cpupm->pm_busycnt)); 1081 1082 #ifdef DEBUG 1083 /* 1084 * Notify that timeout and taskq has caused delays and we need to 1085 * scale our parameters accordingly. 1086 * 1087 * To get accurate result, don't turn on other DPRINTFs with 1088 * the following DPRINTF. PROM calls generated by other 1089 * DPRINTFs changes the timing. 1090 */ 1091 if (tick_cnt > cur_spd->quant_cnt) { 1092 DPRINTF(D_PM_MONITOR_DELAY, ("cpudrv_pm_monitor: instance %d: " 1093 "tick count %d > quantum_count %u\n", 1094 ddi_get_instance(dip), tick_cnt, cur_spd->quant_cnt)); 1095 } 1096 #endif /* DEBUG */ 1097 1098 /* 1099 * Adjust counts based on the delay added by timeout and taskq. 1100 */ 1101 idle_cnt = (idle_cnt * cur_spd->quant_cnt) / tick_cnt; 1102 user_cnt = (user_cnt * cur_spd->quant_cnt) / tick_cnt; 1103 1104 if ((user_cnt > cur_spd->user_hwm) || (idle_cnt < cur_spd->idle_lwm && 1105 cur_spd->idle_blwm_cnt >= cpudrv_pm_idle_blwm_cnt_max)) { 1106 cur_spd->idle_blwm_cnt = 0; 1107 cur_spd->idle_bhwm_cnt = 0; 1108 /* 1109 * In normal situation, arrange to go to next higher speed. 1110 * If we are running in special direct pm mode, we just stay 1111 * at the current speed. 1112 */ 1113 if (cur_spd == cur_spd->up_spd || cpudrv_direct_pm) { 1114 CPUDRV_PM_MONITOR_PM_BUSY_COMP(dip, cpupm); 1115 } else { 1116 new_spd = cur_spd->up_spd; 1117 CPUDRV_PM_MONITOR_PM_BUSY_AND_RAISE(dip, cpudsp, cpupm, 1118 new_spd->pm_level); 1119 } 1120 } else if ((user_cnt <= cur_spd->user_lwm) && 1121 (idle_cnt >= cur_spd->idle_hwm) || !CPU_ACTIVE(cp)) { 1122 cur_spd->idle_blwm_cnt = 0; 1123 cur_spd->idle_bhwm_cnt = 0; 1124 /* 1125 * Arrange to go to next lower speed by informing our idle 1126 * status to the power management framework. 1127 */ 1128 CPUDRV_PM_MONITOR_PM_IDLE_COMP(dip, cpupm); 1129 } else { 1130 /* 1131 * If we are between the idle water marks and have not 1132 * been here enough consecutive times to be considered 1133 * busy, just increment the count and return. 1134 */ 1135 if ((idle_cnt < cur_spd->idle_hwm) && 1136 (idle_cnt >= cur_spd->idle_lwm) && 1137 (cur_spd->idle_bhwm_cnt < cpudrv_pm_idle_bhwm_cnt_max)) { 1138 cur_spd->idle_blwm_cnt = 0; 1139 cur_spd->idle_bhwm_cnt++; 1140 mutex_exit(&cpudsp->lock); 1141 goto do_return; 1142 } 1143 if (idle_cnt < cur_spd->idle_lwm) { 1144 cur_spd->idle_blwm_cnt++; 1145 cur_spd->idle_bhwm_cnt = 0; 1146 } 1147 /* 1148 * Arranges to stay at the current speed. 1149 */ 1150 CPUDRV_PM_MONITOR_PM_BUSY_COMP(dip, cpupm); 1151 } 1152 mutex_exit(&cpudsp->lock); 1153 do_return: 1154 mutex_enter(&cpupm->timeout_lock); 1155 ASSERT(cpupm->timeout_count > 0); 1156 cpupm->timeout_count--; 1157 cv_signal(&cpupm->timeout_cv); 1158 mutex_exit(&cpupm->timeout_lock); 1159 } 1160