acpi_cpu_pstate.c revision 1.29
1 1.29 jruoho /* $NetBSD: acpi_cpu_pstate.c,v 1.29 2010/08/17 10:57:30 jruoho Exp $ */ 2 1.1 jruoho 3 1.1 jruoho /*- 4 1.1 jruoho * Copyright (c) 2010 Jukka Ruohonen <jruohonen (at) iki.fi> 5 1.1 jruoho * All rights reserved. 6 1.1 jruoho * 7 1.1 jruoho * Redistribution and use in source and binary forms, with or without 8 1.1 jruoho * modification, are permitted provided that the following conditions 9 1.1 jruoho * are met: 10 1.1 jruoho * 11 1.1 jruoho * 1. Redistributions of source code must retain the above copyright 12 1.1 jruoho * notice, this list of conditions and the following disclaimer. 13 1.1 jruoho * 2. Redistributions in binary form must reproduce the above copyright 14 1.1 jruoho * notice, this list of conditions and the following disclaimer in the 15 1.1 jruoho * documentation and/or other materials provided with the distribution. 16 1.1 jruoho * 17 1.1 jruoho * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND 18 1.1 jruoho * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 19 1.1 jruoho * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 20 1.1 jruoho * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE 21 1.1 jruoho * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 22 1.1 jruoho * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 23 1.1 jruoho * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 24 1.1 jruoho * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 25 1.1 jruoho * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 26 1.1 jruoho * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 27 1.1 jruoho * SUCH DAMAGE. 28 1.1 jruoho */ 29 1.1 jruoho #include <sys/cdefs.h> 30 1.29 jruoho __KERNEL_RCSID(0, "$NetBSD: acpi_cpu_pstate.c,v 1.29 2010/08/17 10:57:30 jruoho Exp $"); 31 1.1 jruoho 32 1.1 jruoho #include <sys/param.h> 33 1.7 jruoho #include <sys/evcnt.h> 34 1.1 jruoho #include <sys/kmem.h> 35 1.1 jruoho #include <sys/once.h> 36 1.1 jruoho 37 1.1 jruoho #include <dev/acpi/acpireg.h> 38 1.1 jruoho #include <dev/acpi/acpivar.h> 39 1.1 jruoho #include <dev/acpi/acpi_cpu.h> 40 1.1 jruoho 41 1.1 jruoho #define _COMPONENT ACPI_BUS_COMPONENT 42 1.1 jruoho ACPI_MODULE_NAME ("acpi_cpu_pstate") 43 1.1 jruoho 44 1.1 jruoho static void acpicpu_pstate_attach_print(struct acpicpu_softc *); 45 1.7 jruoho static void acpicpu_pstate_attach_evcnt(struct acpicpu_softc *); 46 1.7 jruoho static void acpicpu_pstate_detach_evcnt(struct acpicpu_softc *); 47 1.21 jruoho static ACPI_STATUS acpicpu_pstate_pss(struct acpicpu_softc *); 48 1.1 jruoho static ACPI_STATUS acpicpu_pstate_pss_add(struct acpicpu_pstate *, 49 1.1 jruoho ACPI_OBJECT *); 50 1.21 jruoho static ACPI_STATUS acpicpu_pstate_xpss(struct acpicpu_softc *); 51 1.21 jruoho static ACPI_STATUS acpicpu_pstate_xpss_add(struct acpicpu_pstate *, 52 1.21 jruoho ACPI_OBJECT *); 53 1.1 jruoho static ACPI_STATUS acpicpu_pstate_pct(struct acpicpu_softc *); 54 1.1 jruoho static int acpicpu_pstate_max(struct acpicpu_softc *); 55 1.27 jruoho static int acpicpu_pstate_min(struct acpicpu_softc *); 56 1.1 jruoho static void acpicpu_pstate_change(struct acpicpu_softc *); 57 1.28 jruoho static void acpicpu_pstate_reset(struct acpicpu_softc *); 58 1.1 jruoho static void acpicpu_pstate_bios(void); 59 1.1 jruoho 60 1.29 jruoho static uint32_t acpicpu_pstate_saved = 0; 61 1.25 jruoho 62 1.1 jruoho void 63 1.1 jruoho acpicpu_pstate_attach(device_t self) 64 1.1 jruoho { 65 1.1 jruoho struct acpicpu_softc *sc = device_private(self); 66 1.3 jruoho const char *str; 67 1.27 jruoho ACPI_HANDLE tmp; 68 1.1 jruoho ACPI_STATUS rv; 69 1.1 jruoho 70 1.1 jruoho rv = acpicpu_pstate_pss(sc); 71 1.1 jruoho 72 1.3 jruoho if (ACPI_FAILURE(rv)) { 73 1.3 jruoho str = "_PSS"; 74 1.3 jruoho goto fail; 75 1.3 jruoho } 76 1.1 jruoho 77 1.21 jruoho /* 78 1.21 jruoho * Check the availability of extended _PSS. 79 1.21 jruoho * If present, this will override the data. 80 1.21 jruoho * Note that XPSS can not be used on Intel 81 1.21 jruoho * systems where _PDC or _OSC may be used. 82 1.21 jruoho */ 83 1.21 jruoho if (sc->sc_cap == 0) { 84 1.21 jruoho 85 1.21 jruoho rv = acpicpu_pstate_xpss(sc); 86 1.21 jruoho 87 1.21 jruoho if (ACPI_SUCCESS(rv)) 88 1.21 jruoho sc->sc_flags |= ACPICPU_FLAG_P_XPSS; 89 1.21 jruoho 90 1.21 jruoho if (ACPI_FAILURE(rv) && rv != AE_NOT_FOUND) { 91 1.21 jruoho str = "XPSS"; 92 1.21 jruoho goto fail; 93 1.21 jruoho } 94 1.21 jruoho } 95 1.21 jruoho 96 1.1 jruoho rv = acpicpu_pstate_pct(sc); 97 1.1 jruoho 98 1.3 jruoho if (ACPI_FAILURE(rv)) { 99 1.3 jruoho str = "_PCT"; 100 1.3 jruoho goto fail; 101 1.3 jruoho } 102 1.1 jruoho 103 1.24 jruoho /* 104 1.24 jruoho * The ACPI 3.0 and 4.0 specifications mandate three 105 1.24 jruoho * objects for P-states: _PSS, _PCT, and _PPC. A less 106 1.24 jruoho * strict wording is however used in the earlier 2.0 107 1.24 jruoho * standard, and some systems conforming to ACPI 2.0 108 1.24 jruoho * do not have _PPC, the method for dynamic maximum. 109 1.24 jruoho */ 110 1.27 jruoho rv = AcpiGetHandle(sc->sc_node->ad_handle, "_PPC", &tmp); 111 1.27 jruoho 112 1.27 jruoho if (ACPI_FAILURE(rv)) 113 1.27 jruoho aprint_debug_dev(self, "_PPC missing\n"); 114 1.27 jruoho 115 1.1 jruoho sc->sc_flags |= ACPICPU_FLAG_P; 116 1.1 jruoho 117 1.1 jruoho acpicpu_pstate_bios(); 118 1.28 jruoho acpicpu_pstate_reset(sc); 119 1.7 jruoho acpicpu_pstate_attach_evcnt(sc); 120 1.1 jruoho acpicpu_pstate_attach_print(sc); 121 1.3 jruoho 122 1.3 jruoho return; 123 1.3 jruoho 124 1.3 jruoho fail: 125 1.15 jruoho switch (rv) { 126 1.15 jruoho 127 1.15 jruoho case AE_NOT_FOUND: 128 1.15 jruoho return; 129 1.15 jruoho 130 1.15 jruoho case AE_SUPPORT: 131 1.15 jruoho aprint_verbose_dev(sc->sc_dev, "P-states not supported\n"); 132 1.15 jruoho return; 133 1.15 jruoho 134 1.15 jruoho default: 135 1.15 jruoho aprint_error_dev(sc->sc_dev, "failed to evaluate " 136 1.15 jruoho "%s: %s\n", str, AcpiFormatException(rv)); 137 1.15 jruoho } 138 1.1 jruoho } 139 1.1 jruoho 140 1.1 jruoho static void 141 1.1 jruoho acpicpu_pstate_attach_print(struct acpicpu_softc *sc) 142 1.1 jruoho { 143 1.1 jruoho const uint8_t method = sc->sc_pstate_control.reg_spaceid; 144 1.1 jruoho struct acpicpu_pstate *ps; 145 1.12 jruoho static bool once = false; 146 1.1 jruoho const char *str; 147 1.1 jruoho uint32_t i; 148 1.1 jruoho 149 1.12 jruoho if (once != false) 150 1.12 jruoho return; 151 1.12 jruoho 152 1.8 jruoho str = (method != ACPI_ADR_SPACE_SYSTEM_IO) ? "FFH" : "I/O"; 153 1.1 jruoho 154 1.1 jruoho for (i = 0; i < sc->sc_pstate_count; i++) { 155 1.1 jruoho 156 1.1 jruoho ps = &sc->sc_pstate[i]; 157 1.1 jruoho 158 1.1 jruoho if (ps->ps_freq == 0) 159 1.1 jruoho continue; 160 1.1 jruoho 161 1.8 jruoho aprint_debug_dev(sc->sc_dev, "P%d: %3s, " 162 1.15 jruoho "lat %3u us, pow %5u mW, %4u MHz\n", i, str, 163 1.15 jruoho ps->ps_latency, ps->ps_power, ps->ps_freq); 164 1.1 jruoho } 165 1.12 jruoho 166 1.12 jruoho once = true; 167 1.1 jruoho } 168 1.1 jruoho 169 1.7 jruoho static void 170 1.7 jruoho acpicpu_pstate_attach_evcnt(struct acpicpu_softc *sc) 171 1.7 jruoho { 172 1.7 jruoho struct acpicpu_pstate *ps; 173 1.7 jruoho uint32_t i; 174 1.7 jruoho 175 1.7 jruoho for (i = 0; i < sc->sc_pstate_count; i++) { 176 1.7 jruoho 177 1.7 jruoho ps = &sc->sc_pstate[i]; 178 1.7 jruoho 179 1.7 jruoho if (ps->ps_freq == 0) 180 1.7 jruoho continue; 181 1.7 jruoho 182 1.7 jruoho (void)snprintf(ps->ps_name, sizeof(ps->ps_name), 183 1.7 jruoho "P%u (%u MHz)", i, ps->ps_freq); 184 1.7 jruoho 185 1.7 jruoho evcnt_attach_dynamic(&ps->ps_evcnt, EVCNT_TYPE_MISC, 186 1.7 jruoho NULL, device_xname(sc->sc_dev), ps->ps_name); 187 1.7 jruoho } 188 1.7 jruoho } 189 1.7 jruoho 190 1.1 jruoho int 191 1.1 jruoho acpicpu_pstate_detach(device_t self) 192 1.1 jruoho { 193 1.1 jruoho struct acpicpu_softc *sc = device_private(self); 194 1.1 jruoho static ONCE_DECL(once_detach); 195 1.1 jruoho size_t size; 196 1.1 jruoho int rv; 197 1.1 jruoho 198 1.1 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P) == 0) 199 1.1 jruoho return 0; 200 1.1 jruoho 201 1.1 jruoho rv = RUN_ONCE(&once_detach, acpicpu_md_pstate_stop); 202 1.1 jruoho 203 1.1 jruoho if (rv != 0) 204 1.1 jruoho return rv; 205 1.1 jruoho 206 1.1 jruoho size = sc->sc_pstate_count * sizeof(*sc->sc_pstate); 207 1.1 jruoho 208 1.1 jruoho if (sc->sc_pstate != NULL) 209 1.1 jruoho kmem_free(sc->sc_pstate, size); 210 1.1 jruoho 211 1.1 jruoho sc->sc_flags &= ~ACPICPU_FLAG_P; 212 1.7 jruoho acpicpu_pstate_detach_evcnt(sc); 213 1.1 jruoho 214 1.1 jruoho return 0; 215 1.1 jruoho } 216 1.1 jruoho 217 1.7 jruoho static void 218 1.7 jruoho acpicpu_pstate_detach_evcnt(struct acpicpu_softc *sc) 219 1.7 jruoho { 220 1.7 jruoho struct acpicpu_pstate *ps; 221 1.7 jruoho uint32_t i; 222 1.7 jruoho 223 1.7 jruoho for (i = 0; i < sc->sc_pstate_count; i++) { 224 1.7 jruoho 225 1.7 jruoho ps = &sc->sc_pstate[i]; 226 1.7 jruoho 227 1.7 jruoho if (ps->ps_freq != 0) 228 1.7 jruoho evcnt_detach(&ps->ps_evcnt); 229 1.7 jruoho } 230 1.7 jruoho } 231 1.7 jruoho 232 1.24 jruoho void 233 1.1 jruoho acpicpu_pstate_start(device_t self) 234 1.1 jruoho { 235 1.1 jruoho struct acpicpu_softc *sc = device_private(self); 236 1.25 jruoho struct acpicpu_pstate *ps; 237 1.25 jruoho uint32_t i; 238 1.24 jruoho int rv; 239 1.1 jruoho 240 1.24 jruoho rv = acpicpu_md_pstate_start(); 241 1.24 jruoho 242 1.25 jruoho if (rv != 0) 243 1.25 jruoho goto fail; 244 1.25 jruoho 245 1.25 jruoho /* 246 1.27 jruoho * Initialize the state to P0. 247 1.25 jruoho */ 248 1.25 jruoho for (i = 0, rv = ENXIO; i < sc->sc_pstate_count; i++) { 249 1.25 jruoho 250 1.25 jruoho ps = &sc->sc_pstate[i]; 251 1.25 jruoho 252 1.25 jruoho if (ps->ps_freq != 0) { 253 1.25 jruoho sc->sc_cold = false; 254 1.25 jruoho rv = acpicpu_pstate_set(sc, ps->ps_freq); 255 1.25 jruoho break; 256 1.25 jruoho } 257 1.25 jruoho } 258 1.25 jruoho 259 1.25 jruoho if (rv != 0) 260 1.25 jruoho goto fail; 261 1.25 jruoho 262 1.25 jruoho return; 263 1.1 jruoho 264 1.25 jruoho fail: 265 1.24 jruoho sc->sc_flags &= ~ACPICPU_FLAG_P; 266 1.24 jruoho aprint_error_dev(self, "failed to start P-states (err %d)\n", rv); 267 1.1 jruoho } 268 1.1 jruoho 269 1.1 jruoho bool 270 1.1 jruoho acpicpu_pstate_suspend(device_t self) 271 1.1 jruoho { 272 1.25 jruoho struct acpicpu_softc *sc = device_private(self); 273 1.25 jruoho struct acpicpu_pstate *ps = NULL; 274 1.25 jruoho int32_t i; 275 1.25 jruoho 276 1.29 jruoho mutex_enter(&sc->sc_mtx); 277 1.28 jruoho acpicpu_pstate_reset(sc); 278 1.29 jruoho mutex_exit(&sc->sc_mtx); 279 1.28 jruoho 280 1.25 jruoho if (acpicpu_pstate_saved != 0) 281 1.25 jruoho return true; 282 1.25 jruoho 283 1.25 jruoho /* 284 1.25 jruoho * Following design notes for Windows, we set the highest 285 1.25 jruoho * P-state when entering any of the system sleep states. 286 1.25 jruoho * When resuming, the saved P-state will be restored. 287 1.25 jruoho * 288 1.25 jruoho * Microsoft Corporation: Windows Native Processor 289 1.25 jruoho * Performance Control. Version 1.1a, November, 2002. 290 1.25 jruoho */ 291 1.25 jruoho for (i = sc->sc_pstate_count - 1; i >= 0; i--) { 292 1.25 jruoho 293 1.25 jruoho if (sc->sc_pstate[i].ps_freq != 0) { 294 1.25 jruoho ps = &sc->sc_pstate[i]; 295 1.25 jruoho break; 296 1.25 jruoho } 297 1.25 jruoho } 298 1.25 jruoho 299 1.25 jruoho if (__predict_false(ps == NULL)) 300 1.25 jruoho return true; 301 1.25 jruoho 302 1.25 jruoho mutex_enter(&sc->sc_mtx); 303 1.25 jruoho acpicpu_pstate_saved = sc->sc_pstate_current; 304 1.25 jruoho mutex_exit(&sc->sc_mtx); 305 1.25 jruoho 306 1.25 jruoho if (acpicpu_pstate_saved == ps->ps_freq) 307 1.25 jruoho return true; 308 1.25 jruoho 309 1.25 jruoho (void)acpicpu_pstate_set(sc, ps->ps_freq); 310 1.1 jruoho 311 1.1 jruoho return true; 312 1.1 jruoho } 313 1.1 jruoho 314 1.1 jruoho bool 315 1.1 jruoho acpicpu_pstate_resume(device_t self) 316 1.1 jruoho { 317 1.25 jruoho struct acpicpu_softc *sc = device_private(self); 318 1.25 jruoho 319 1.25 jruoho if (acpicpu_pstate_saved != 0) { 320 1.25 jruoho (void)acpicpu_pstate_set(sc, acpicpu_pstate_saved); 321 1.25 jruoho acpicpu_pstate_saved = 0; 322 1.25 jruoho } 323 1.1 jruoho 324 1.1 jruoho return true; 325 1.1 jruoho } 326 1.1 jruoho 327 1.1 jruoho void 328 1.1 jruoho acpicpu_pstate_callback(void *aux) 329 1.1 jruoho { 330 1.1 jruoho struct acpicpu_softc *sc; 331 1.1 jruoho device_t self = aux; 332 1.1 jruoho uint32_t old, new; 333 1.1 jruoho 334 1.1 jruoho sc = device_private(self); 335 1.1 jruoho 336 1.1 jruoho mutex_enter(&sc->sc_mtx); 337 1.1 jruoho old = sc->sc_pstate_max; 338 1.1 jruoho acpicpu_pstate_change(sc); 339 1.1 jruoho new = sc->sc_pstate_max; 340 1.1 jruoho mutex_exit(&sc->sc_mtx); 341 1.1 jruoho 342 1.1 jruoho if (old != new) { 343 1.1 jruoho 344 1.14 jruoho aprint_debug_dev(sc->sc_dev, "maximum frequency " 345 1.14 jruoho "changed from P%u (%u MHz) to P%u (%u MHz)\n", 346 1.14 jruoho old, sc->sc_pstate[old].ps_freq, new, 347 1.14 jruoho sc->sc_pstate[sc->sc_pstate_max].ps_freq); 348 1.14 jruoho #if 0 349 1.1 jruoho /* 350 1.1 jruoho * If the maximum changed, proactively 351 1.1 jruoho * raise or lower the target frequency. 352 1.1 jruoho */ 353 1.25 jruoho (void)acpicpu_pstate_set(sc, sc->sc_pstate[new].ps_freq); 354 1.1 jruoho 355 1.14 jruoho #endif 356 1.1 jruoho } 357 1.1 jruoho } 358 1.1 jruoho 359 1.1 jruoho ACPI_STATUS 360 1.1 jruoho acpicpu_pstate_pss(struct acpicpu_softc *sc) 361 1.1 jruoho { 362 1.1 jruoho struct acpicpu_pstate *ps; 363 1.1 jruoho ACPI_OBJECT *obj; 364 1.1 jruoho ACPI_BUFFER buf; 365 1.1 jruoho ACPI_STATUS rv; 366 1.1 jruoho uint32_t count; 367 1.1 jruoho uint32_t i, j; 368 1.1 jruoho 369 1.1 jruoho rv = acpi_eval_struct(sc->sc_node->ad_handle, "_PSS", &buf); 370 1.1 jruoho 371 1.1 jruoho if (ACPI_FAILURE(rv)) 372 1.1 jruoho return rv; 373 1.1 jruoho 374 1.1 jruoho obj = buf.Pointer; 375 1.1 jruoho 376 1.1 jruoho if (obj->Type != ACPI_TYPE_PACKAGE) { 377 1.1 jruoho rv = AE_TYPE; 378 1.1 jruoho goto out; 379 1.1 jruoho } 380 1.1 jruoho 381 1.1 jruoho sc->sc_pstate_count = obj->Package.Count; 382 1.1 jruoho 383 1.1 jruoho if (sc->sc_pstate_count == 0) { 384 1.1 jruoho rv = AE_NOT_EXIST; 385 1.1 jruoho goto out; 386 1.1 jruoho } 387 1.1 jruoho 388 1.9 jruoho if (sc->sc_pstate_count > ACPICPU_P_STATE_MAX) { 389 1.1 jruoho rv = AE_LIMIT; 390 1.1 jruoho goto out; 391 1.1 jruoho } 392 1.1 jruoho 393 1.1 jruoho sc->sc_pstate = kmem_zalloc(sc->sc_pstate_count * 394 1.1 jruoho sizeof(struct acpicpu_pstate), KM_SLEEP); 395 1.1 jruoho 396 1.1 jruoho if (sc->sc_pstate == NULL) { 397 1.1 jruoho rv = AE_NO_MEMORY; 398 1.1 jruoho goto out; 399 1.1 jruoho } 400 1.1 jruoho 401 1.1 jruoho for (count = i = 0; i < sc->sc_pstate_count; i++) { 402 1.1 jruoho 403 1.1 jruoho ps = &sc->sc_pstate[i]; 404 1.1 jruoho rv = acpicpu_pstate_pss_add(ps, &obj->Package.Elements[i]); 405 1.1 jruoho 406 1.13 jruoho if (ACPI_FAILURE(rv)) { 407 1.13 jruoho ps->ps_freq = 0; 408 1.1 jruoho continue; 409 1.13 jruoho } 410 1.1 jruoho 411 1.1 jruoho for (j = 0; j < i; j++) { 412 1.1 jruoho 413 1.1 jruoho if (ps->ps_freq >= sc->sc_pstate[j].ps_freq) { 414 1.1 jruoho ps->ps_freq = 0; 415 1.1 jruoho break; 416 1.1 jruoho } 417 1.1 jruoho } 418 1.1 jruoho 419 1.1 jruoho if (ps->ps_freq != 0) 420 1.1 jruoho count++; 421 1.1 jruoho } 422 1.1 jruoho 423 1.1 jruoho rv = (count != 0) ? AE_OK : AE_NOT_EXIST; 424 1.1 jruoho 425 1.1 jruoho out: 426 1.1 jruoho if (buf.Pointer != NULL) 427 1.1 jruoho ACPI_FREE(buf.Pointer); 428 1.1 jruoho 429 1.1 jruoho return rv; 430 1.1 jruoho } 431 1.1 jruoho 432 1.1 jruoho static ACPI_STATUS 433 1.1 jruoho acpicpu_pstate_pss_add(struct acpicpu_pstate *ps, ACPI_OBJECT *obj) 434 1.1 jruoho { 435 1.1 jruoho ACPI_OBJECT *elm; 436 1.1 jruoho int i; 437 1.1 jruoho 438 1.1 jruoho if (obj->Type != ACPI_TYPE_PACKAGE) 439 1.1 jruoho return AE_TYPE; 440 1.1 jruoho 441 1.1 jruoho if (obj->Package.Count != 6) 442 1.1 jruoho return AE_BAD_DATA; 443 1.1 jruoho 444 1.1 jruoho elm = obj->Package.Elements; 445 1.1 jruoho 446 1.1 jruoho for (i = 0; i < 6; i++) { 447 1.1 jruoho 448 1.1 jruoho if (elm[i].Type != ACPI_TYPE_INTEGER) 449 1.1 jruoho return AE_TYPE; 450 1.1 jruoho 451 1.1 jruoho if (elm[i].Integer.Value > UINT32_MAX) 452 1.1 jruoho return AE_AML_NUMERIC_OVERFLOW; 453 1.1 jruoho } 454 1.1 jruoho 455 1.21 jruoho ps->ps_freq = elm[0].Integer.Value; 456 1.21 jruoho ps->ps_power = elm[1].Integer.Value; 457 1.21 jruoho ps->ps_latency = elm[2].Integer.Value; 458 1.21 jruoho ps->ps_latency_bm = elm[3].Integer.Value; 459 1.21 jruoho ps->ps_control = elm[4].Integer.Value; 460 1.21 jruoho ps->ps_status = elm[5].Integer.Value; 461 1.1 jruoho 462 1.13 jruoho if (ps->ps_freq == 0 || ps->ps_freq > 9999) 463 1.13 jruoho return AE_BAD_DECIMAL_CONSTANT; 464 1.13 jruoho 465 1.1 jruoho /* 466 1.1 jruoho * The latency is typically around 10 usec 467 1.1 jruoho * on Intel CPUs. Use that as the minimum. 468 1.1 jruoho */ 469 1.1 jruoho if (ps->ps_latency < 10) 470 1.1 jruoho ps->ps_latency = 10; 471 1.1 jruoho 472 1.1 jruoho return AE_OK; 473 1.1 jruoho } 474 1.1 jruoho 475 1.21 jruoho static ACPI_STATUS 476 1.21 jruoho acpicpu_pstate_xpss(struct acpicpu_softc *sc) 477 1.21 jruoho { 478 1.21 jruoho static const size_t size = sizeof(struct acpicpu_pstate); 479 1.21 jruoho struct acpicpu_pstate *ps; 480 1.21 jruoho ACPI_OBJECT *obj; 481 1.21 jruoho ACPI_BUFFER buf; 482 1.21 jruoho ACPI_STATUS rv; 483 1.21 jruoho uint32_t count; 484 1.21 jruoho uint32_t i, j; 485 1.21 jruoho 486 1.21 jruoho rv = acpi_eval_struct(sc->sc_node->ad_handle, "XPSS", &buf); 487 1.21 jruoho 488 1.21 jruoho if (ACPI_FAILURE(rv)) 489 1.21 jruoho return rv; 490 1.21 jruoho 491 1.21 jruoho obj = buf.Pointer; 492 1.21 jruoho 493 1.21 jruoho if (obj->Type != ACPI_TYPE_PACKAGE) { 494 1.21 jruoho rv = AE_TYPE; 495 1.21 jruoho goto out; 496 1.21 jruoho } 497 1.21 jruoho 498 1.21 jruoho count = obj->Package.Count; 499 1.21 jruoho 500 1.21 jruoho if (count == 0) { 501 1.21 jruoho rv = AE_NOT_EXIST; 502 1.21 jruoho goto out; 503 1.21 jruoho } 504 1.21 jruoho 505 1.21 jruoho if (count > ACPICPU_P_STATE_MAX) { 506 1.21 jruoho rv = AE_LIMIT; 507 1.21 jruoho goto out; 508 1.21 jruoho } 509 1.21 jruoho 510 1.21 jruoho if (sc->sc_pstate != NULL) 511 1.21 jruoho kmem_free(sc->sc_pstate, sc->sc_pstate_count * size); 512 1.21 jruoho 513 1.21 jruoho sc->sc_pstate = kmem_zalloc(count * size, KM_SLEEP); 514 1.21 jruoho 515 1.21 jruoho if (sc->sc_pstate == NULL) { 516 1.21 jruoho rv = AE_NO_MEMORY; 517 1.21 jruoho goto out; 518 1.21 jruoho } 519 1.21 jruoho 520 1.21 jruoho sc->sc_pstate_count = count; 521 1.21 jruoho 522 1.21 jruoho for (count = i = 0; i < sc->sc_pstate_count; i++) { 523 1.21 jruoho 524 1.21 jruoho ps = &sc->sc_pstate[i]; 525 1.21 jruoho rv = acpicpu_pstate_xpss_add(ps, &obj->Package.Elements[i]); 526 1.21 jruoho 527 1.21 jruoho if (ACPI_FAILURE(rv)) { 528 1.21 jruoho ps->ps_freq = 0; 529 1.21 jruoho continue; 530 1.21 jruoho } 531 1.21 jruoho 532 1.21 jruoho for (j = 0; j < i; j++) { 533 1.21 jruoho 534 1.21 jruoho if (ps->ps_freq >= sc->sc_pstate[j].ps_freq) { 535 1.21 jruoho ps->ps_freq = 0; 536 1.21 jruoho break; 537 1.21 jruoho } 538 1.21 jruoho } 539 1.21 jruoho 540 1.21 jruoho if (ps->ps_freq != 0) 541 1.21 jruoho count++; 542 1.21 jruoho } 543 1.21 jruoho 544 1.21 jruoho rv = (count != 0) ? AE_OK : AE_NOT_EXIST; 545 1.21 jruoho 546 1.21 jruoho out: 547 1.21 jruoho if (buf.Pointer != NULL) 548 1.21 jruoho ACPI_FREE(buf.Pointer); 549 1.21 jruoho 550 1.21 jruoho return rv; 551 1.21 jruoho } 552 1.21 jruoho 553 1.21 jruoho static ACPI_STATUS 554 1.21 jruoho acpicpu_pstate_xpss_add(struct acpicpu_pstate *ps, ACPI_OBJECT *obj) 555 1.21 jruoho { 556 1.21 jruoho static const size_t size = sizeof(uint64_t); 557 1.21 jruoho ACPI_OBJECT *elm; 558 1.21 jruoho int i; 559 1.21 jruoho 560 1.21 jruoho if (obj->Type != ACPI_TYPE_PACKAGE) 561 1.21 jruoho return AE_TYPE; 562 1.21 jruoho 563 1.21 jruoho if (obj->Package.Count != 8) 564 1.21 jruoho return AE_BAD_DATA; 565 1.21 jruoho 566 1.21 jruoho elm = obj->Package.Elements; 567 1.21 jruoho 568 1.21 jruoho for (i = 0; i < 4; i++) { 569 1.21 jruoho 570 1.21 jruoho if (elm[i].Type != ACPI_TYPE_INTEGER) 571 1.21 jruoho return AE_TYPE; 572 1.21 jruoho 573 1.21 jruoho if (elm[i].Integer.Value > UINT32_MAX) 574 1.21 jruoho return AE_AML_NUMERIC_OVERFLOW; 575 1.21 jruoho } 576 1.21 jruoho 577 1.21 jruoho for (; i < 8; i++) { 578 1.21 jruoho 579 1.21 jruoho if (elm[i].Type != ACPI_TYPE_BUFFER) 580 1.21 jruoho return AE_TYPE; 581 1.21 jruoho 582 1.21 jruoho if (elm[i].Buffer.Length > size) 583 1.21 jruoho return AE_LIMIT; 584 1.21 jruoho } 585 1.21 jruoho 586 1.21 jruoho ps->ps_freq = elm[0].Integer.Value; 587 1.21 jruoho ps->ps_power = elm[1].Integer.Value; 588 1.21 jruoho ps->ps_latency = elm[2].Integer.Value; 589 1.21 jruoho ps->ps_latency_bm = elm[3].Integer.Value; 590 1.21 jruoho 591 1.21 jruoho if (ps->ps_freq == 0 || ps->ps_freq > 9999) 592 1.21 jruoho return AE_BAD_DECIMAL_CONSTANT; 593 1.21 jruoho 594 1.21 jruoho (void)memcpy(&ps->ps_control, elm[4].Buffer.Pointer, size); 595 1.21 jruoho (void)memcpy(&ps->ps_status, elm[5].Buffer.Pointer, size); 596 1.21 jruoho 597 1.21 jruoho (void)memcpy(&ps->ps_control_mask, elm[6].Buffer.Pointer, size); 598 1.21 jruoho (void)memcpy(&ps->ps_status_mask, elm[7].Buffer.Pointer, size); 599 1.21 jruoho 600 1.21 jruoho /* 601 1.21 jruoho * The latency is often defined to be 602 1.21 jruoho * zero on AMD systems. Raise that to 1. 603 1.21 jruoho */ 604 1.21 jruoho if (ps->ps_latency == 0) 605 1.21 jruoho ps->ps_latency = 1; 606 1.21 jruoho 607 1.21 jruoho ps->ps_flags |= ACPICPU_FLAG_P_XPSS; 608 1.21 jruoho 609 1.21 jruoho return AE_OK; 610 1.21 jruoho } 611 1.21 jruoho 612 1.1 jruoho ACPI_STATUS 613 1.1 jruoho acpicpu_pstate_pct(struct acpicpu_softc *sc) 614 1.1 jruoho { 615 1.1 jruoho static const size_t size = sizeof(struct acpicpu_reg); 616 1.1 jruoho struct acpicpu_reg *reg[2]; 617 1.21 jruoho struct acpicpu_pstate *ps; 618 1.1 jruoho ACPI_OBJECT *elm, *obj; 619 1.1 jruoho ACPI_BUFFER buf; 620 1.1 jruoho ACPI_STATUS rv; 621 1.1 jruoho uint8_t width; 622 1.21 jruoho uint32_t i; 623 1.1 jruoho 624 1.1 jruoho rv = acpi_eval_struct(sc->sc_node->ad_handle, "_PCT", &buf); 625 1.1 jruoho 626 1.1 jruoho if (ACPI_FAILURE(rv)) 627 1.1 jruoho return rv; 628 1.1 jruoho 629 1.1 jruoho obj = buf.Pointer; 630 1.1 jruoho 631 1.1 jruoho if (obj->Type != ACPI_TYPE_PACKAGE) { 632 1.1 jruoho rv = AE_TYPE; 633 1.1 jruoho goto out; 634 1.1 jruoho } 635 1.1 jruoho 636 1.1 jruoho if (obj->Package.Count != 2) { 637 1.1 jruoho rv = AE_LIMIT; 638 1.1 jruoho goto out; 639 1.1 jruoho } 640 1.1 jruoho 641 1.1 jruoho for (i = 0; i < 2; i++) { 642 1.1 jruoho 643 1.1 jruoho elm = &obj->Package.Elements[i]; 644 1.1 jruoho 645 1.1 jruoho if (elm->Type != ACPI_TYPE_BUFFER) { 646 1.1 jruoho rv = AE_TYPE; 647 1.1 jruoho goto out; 648 1.1 jruoho } 649 1.1 jruoho 650 1.1 jruoho if (size > elm->Buffer.Length) { 651 1.1 jruoho rv = AE_AML_BAD_RESOURCE_LENGTH; 652 1.1 jruoho goto out; 653 1.1 jruoho } 654 1.1 jruoho 655 1.1 jruoho reg[i] = (struct acpicpu_reg *)elm->Buffer.Pointer; 656 1.1 jruoho 657 1.1 jruoho switch (reg[i]->reg_spaceid) { 658 1.1 jruoho 659 1.1 jruoho case ACPI_ADR_SPACE_SYSTEM_IO: 660 1.1 jruoho 661 1.1 jruoho if (reg[i]->reg_addr == 0) { 662 1.1 jruoho rv = AE_AML_ILLEGAL_ADDRESS; 663 1.1 jruoho goto out; 664 1.1 jruoho } 665 1.1 jruoho 666 1.1 jruoho width = reg[i]->reg_bitwidth; 667 1.1 jruoho 668 1.10 jruoho if (width + reg[i]->reg_bitoffset > 32) { 669 1.10 jruoho rv = AE_AML_BAD_RESOURCE_VALUE; 670 1.10 jruoho goto out; 671 1.10 jruoho } 672 1.10 jruoho 673 1.1 jruoho if (width != 8 && width != 16 && width != 32) { 674 1.4 jruoho rv = AE_AML_BAD_RESOURCE_VALUE; 675 1.1 jruoho goto out; 676 1.1 jruoho } 677 1.1 jruoho 678 1.1 jruoho break; 679 1.1 jruoho 680 1.1 jruoho case ACPI_ADR_SPACE_FIXED_HARDWARE: 681 1.1 jruoho 682 1.21 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P_XPSS) != 0) { 683 1.21 jruoho 684 1.21 jruoho if (reg[i]->reg_bitwidth != 64) { 685 1.21 jruoho rv = AE_AML_BAD_RESOURCE_VALUE; 686 1.21 jruoho goto out; 687 1.21 jruoho } 688 1.21 jruoho 689 1.21 jruoho if (reg[i]->reg_bitoffset != 0) { 690 1.21 jruoho rv = AE_AML_BAD_RESOURCE_VALUE; 691 1.21 jruoho goto out; 692 1.21 jruoho } 693 1.21 jruoho 694 1.21 jruoho break; 695 1.21 jruoho } 696 1.21 jruoho 697 1.1 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P_FFH) == 0) { 698 1.4 jruoho rv = AE_SUPPORT; 699 1.1 jruoho goto out; 700 1.1 jruoho } 701 1.1 jruoho 702 1.1 jruoho break; 703 1.1 jruoho 704 1.1 jruoho default: 705 1.1 jruoho rv = AE_AML_INVALID_SPACE_ID; 706 1.1 jruoho goto out; 707 1.1 jruoho } 708 1.1 jruoho } 709 1.1 jruoho 710 1.1 jruoho if (reg[0]->reg_spaceid != reg[1]->reg_spaceid) { 711 1.1 jruoho rv = AE_AML_INVALID_SPACE_ID; 712 1.1 jruoho goto out; 713 1.1 jruoho } 714 1.1 jruoho 715 1.15 jruoho (void)memcpy(&sc->sc_pstate_control, reg[0], size); 716 1.15 jruoho (void)memcpy(&sc->sc_pstate_status, reg[1], size); 717 1.1 jruoho 718 1.22 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P_XPSS) == 0) 719 1.22 jruoho goto out; 720 1.22 jruoho 721 1.22 jruoho /* 722 1.22 jruoho * In XPSS the control address can not be zero, 723 1.26 jruoho * but the status address may be. In this case, 724 1.26 jruoho * comparable to T-states, we can ignore the status 725 1.22 jruoho * check during the P-state (FFH) transition. 726 1.22 jruoho */ 727 1.22 jruoho if (sc->sc_pstate_control.reg_addr == 0) { 728 1.23 jmcneill rv = AE_AML_BAD_RESOURCE_LENGTH; 729 1.22 jruoho goto out; 730 1.22 jruoho } 731 1.22 jruoho 732 1.21 jruoho /* 733 1.21 jruoho * If XPSS is present, copy the MSR addresses 734 1.21 jruoho * to the P-state structures for convenience. 735 1.21 jruoho */ 736 1.21 jruoho for (i = 0; i < sc->sc_pstate_count; i++) { 737 1.21 jruoho 738 1.21 jruoho ps = &sc->sc_pstate[i]; 739 1.21 jruoho 740 1.21 jruoho if (ps->ps_freq == 0) 741 1.21 jruoho continue; 742 1.21 jruoho 743 1.21 jruoho ps->ps_status_addr = sc->sc_pstate_status.reg_addr; 744 1.21 jruoho ps->ps_control_addr = sc->sc_pstate_control.reg_addr; 745 1.21 jruoho } 746 1.21 jruoho 747 1.1 jruoho out: 748 1.1 jruoho if (buf.Pointer != NULL) 749 1.1 jruoho ACPI_FREE(buf.Pointer); 750 1.1 jruoho 751 1.1 jruoho return rv; 752 1.1 jruoho } 753 1.1 jruoho 754 1.1 jruoho static int 755 1.1 jruoho acpicpu_pstate_max(struct acpicpu_softc *sc) 756 1.1 jruoho { 757 1.1 jruoho ACPI_INTEGER val; 758 1.1 jruoho ACPI_STATUS rv; 759 1.1 jruoho 760 1.1 jruoho /* 761 1.1 jruoho * Evaluate the currently highest P-state that can be used. 762 1.1 jruoho * If available, we can use either this state or any lower 763 1.1 jruoho * power (i.e. higher numbered) state from the _PSS object. 764 1.27 jruoho * Note that the return value must match the _OST parameter. 765 1.1 jruoho */ 766 1.1 jruoho rv = acpi_eval_integer(sc->sc_node->ad_handle, "_PPC", &val); 767 1.1 jruoho 768 1.27 jruoho if (ACPI_SUCCESS(rv) && val < sc->sc_pstate_count) { 769 1.27 jruoho 770 1.27 jruoho if (sc->sc_pstate[val].ps_freq != 0) { 771 1.27 jruoho sc->sc_pstate_max = val; 772 1.27 jruoho return 0; 773 1.27 jruoho } 774 1.27 jruoho } 775 1.27 jruoho 776 1.27 jruoho return 1; 777 1.27 jruoho } 778 1.27 jruoho 779 1.27 jruoho static int 780 1.27 jruoho acpicpu_pstate_min(struct acpicpu_softc *sc) 781 1.27 jruoho { 782 1.27 jruoho ACPI_INTEGER val; 783 1.27 jruoho ACPI_STATUS rv; 784 1.1 jruoho 785 1.27 jruoho /* 786 1.27 jruoho * The _PDL object defines the minimum when passive cooling 787 1.27 jruoho * is being performed. If available, we can use the returned 788 1.27 jruoho * state or any higher power (i.e. lower numbered) state. 789 1.27 jruoho */ 790 1.27 jruoho rv = acpi_eval_integer(sc->sc_node->ad_handle, "_PDL", &val); 791 1.1 jruoho 792 1.27 jruoho if (ACPI_SUCCESS(rv) && val < sc->sc_pstate_count) { 793 1.1 jruoho 794 1.27 jruoho if (sc->sc_pstate[val].ps_freq == 0) 795 1.27 jruoho return 1; 796 1.1 jruoho 797 1.27 jruoho if (val >= sc->sc_pstate_max) { 798 1.27 jruoho sc->sc_pstate_min = val; 799 1.27 jruoho return 0; 800 1.27 jruoho } 801 1.27 jruoho } 802 1.1 jruoho 803 1.27 jruoho return 1; 804 1.1 jruoho } 805 1.1 jruoho 806 1.1 jruoho static void 807 1.1 jruoho acpicpu_pstate_change(struct acpicpu_softc *sc) 808 1.1 jruoho { 809 1.27 jruoho static ACPI_STATUS rv = AE_OK; 810 1.1 jruoho ACPI_OBJECT_LIST arg; 811 1.1 jruoho ACPI_OBJECT obj[2]; 812 1.1 jruoho 813 1.28 jruoho acpicpu_pstate_reset(sc); 814 1.27 jruoho 815 1.1 jruoho arg.Count = 2; 816 1.1 jruoho arg.Pointer = obj; 817 1.1 jruoho 818 1.1 jruoho obj[0].Type = ACPI_TYPE_INTEGER; 819 1.1 jruoho obj[1].Type = ACPI_TYPE_INTEGER; 820 1.1 jruoho 821 1.1 jruoho obj[0].Integer.Value = ACPICPU_P_NOTIFY; 822 1.1 jruoho obj[1].Integer.Value = acpicpu_pstate_max(sc); 823 1.1 jruoho 824 1.27 jruoho if (sc->sc_passive != false) 825 1.27 jruoho (void)acpicpu_pstate_min(sc); 826 1.27 jruoho 827 1.27 jruoho if (ACPI_FAILURE(rv)) 828 1.27 jruoho return; 829 1.27 jruoho 830 1.27 jruoho rv = AcpiEvaluateObject(sc->sc_node->ad_handle, "_OST", &arg, NULL); 831 1.1 jruoho } 832 1.1 jruoho 833 1.1 jruoho static void 834 1.28 jruoho acpicpu_pstate_reset(struct acpicpu_softc *sc) 835 1.28 jruoho { 836 1.28 jruoho 837 1.28 jruoho sc->sc_pstate_max = 0; 838 1.28 jruoho sc->sc_pstate_min = sc->sc_pstate_count - 1; 839 1.28 jruoho 840 1.28 jruoho } 841 1.28 jruoho 842 1.28 jruoho static void 843 1.1 jruoho acpicpu_pstate_bios(void) 844 1.1 jruoho { 845 1.1 jruoho const uint8_t val = AcpiGbl_FADT.PstateControl; 846 1.1 jruoho const uint32_t addr = AcpiGbl_FADT.SmiCommand; 847 1.1 jruoho 848 1.19 jruoho if (addr == 0 || val == 0) 849 1.1 jruoho return; 850 1.1 jruoho 851 1.1 jruoho (void)AcpiOsWritePort(addr, val, 8); 852 1.1 jruoho } 853 1.1 jruoho 854 1.1 jruoho int 855 1.1 jruoho acpicpu_pstate_get(struct acpicpu_softc *sc, uint32_t *freq) 856 1.1 jruoho { 857 1.1 jruoho const uint8_t method = sc->sc_pstate_control.reg_spaceid; 858 1.1 jruoho struct acpicpu_pstate *ps = NULL; 859 1.1 jruoho uint32_t i, val = 0; 860 1.1 jruoho uint64_t addr; 861 1.1 jruoho uint8_t width; 862 1.1 jruoho int rv; 863 1.1 jruoho 864 1.11 jruoho if (sc->sc_cold != false) { 865 1.11 jruoho rv = EBUSY; 866 1.11 jruoho goto fail; 867 1.11 jruoho } 868 1.11 jruoho 869 1.1 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P) == 0) { 870 1.1 jruoho rv = ENODEV; 871 1.1 jruoho goto fail; 872 1.1 jruoho } 873 1.1 jruoho 874 1.14 jruoho mutex_enter(&sc->sc_mtx); 875 1.14 jruoho 876 1.1 jruoho if (sc->sc_pstate_current != ACPICPU_P_STATE_UNKNOWN) { 877 1.1 jruoho *freq = sc->sc_pstate_current; 878 1.14 jruoho mutex_exit(&sc->sc_mtx); 879 1.1 jruoho return 0; 880 1.1 jruoho } 881 1.1 jruoho 882 1.14 jruoho mutex_exit(&sc->sc_mtx); 883 1.14 jruoho 884 1.1 jruoho switch (method) { 885 1.1 jruoho 886 1.1 jruoho case ACPI_ADR_SPACE_FIXED_HARDWARE: 887 1.1 jruoho 888 1.1 jruoho rv = acpicpu_md_pstate_get(sc, freq); 889 1.1 jruoho 890 1.1 jruoho if (rv != 0) 891 1.1 jruoho goto fail; 892 1.1 jruoho 893 1.1 jruoho break; 894 1.1 jruoho 895 1.1 jruoho case ACPI_ADR_SPACE_SYSTEM_IO: 896 1.1 jruoho 897 1.1 jruoho addr = sc->sc_pstate_status.reg_addr; 898 1.1 jruoho width = sc->sc_pstate_status.reg_bitwidth; 899 1.1 jruoho 900 1.1 jruoho (void)AcpiOsReadPort(addr, &val, width); 901 1.1 jruoho 902 1.1 jruoho if (val == 0) { 903 1.1 jruoho rv = EIO; 904 1.1 jruoho goto fail; 905 1.1 jruoho } 906 1.1 jruoho 907 1.5 jruoho for (i = 0; i < sc->sc_pstate_count; i++) { 908 1.1 jruoho 909 1.1 jruoho if (sc->sc_pstate[i].ps_freq == 0) 910 1.1 jruoho continue; 911 1.1 jruoho 912 1.1 jruoho if (val == sc->sc_pstate[i].ps_status) { 913 1.1 jruoho ps = &sc->sc_pstate[i]; 914 1.1 jruoho break; 915 1.1 jruoho } 916 1.1 jruoho } 917 1.1 jruoho 918 1.15 jruoho if (__predict_false(ps == NULL)) { 919 1.1 jruoho rv = EIO; 920 1.1 jruoho goto fail; 921 1.1 jruoho } 922 1.1 jruoho 923 1.1 jruoho *freq = ps->ps_freq; 924 1.1 jruoho break; 925 1.1 jruoho 926 1.1 jruoho default: 927 1.1 jruoho rv = ENOTTY; 928 1.1 jruoho goto fail; 929 1.1 jruoho } 930 1.1 jruoho 931 1.14 jruoho mutex_enter(&sc->sc_mtx); 932 1.1 jruoho sc->sc_pstate_current = *freq; 933 1.14 jruoho mutex_exit(&sc->sc_mtx); 934 1.1 jruoho 935 1.1 jruoho return 0; 936 1.1 jruoho 937 1.1 jruoho fail: 938 1.1 jruoho aprint_error_dev(sc->sc_dev, "failed " 939 1.1 jruoho "to get frequency (err %d)\n", rv); 940 1.1 jruoho 941 1.14 jruoho mutex_enter(&sc->sc_mtx); 942 1.1 jruoho *freq = sc->sc_pstate_current = ACPICPU_P_STATE_UNKNOWN; 943 1.14 jruoho mutex_exit(&sc->sc_mtx); 944 1.1 jruoho 945 1.1 jruoho return rv; 946 1.1 jruoho } 947 1.1 jruoho 948 1.1 jruoho int 949 1.1 jruoho acpicpu_pstate_set(struct acpicpu_softc *sc, uint32_t freq) 950 1.1 jruoho { 951 1.1 jruoho const uint8_t method = sc->sc_pstate_control.reg_spaceid; 952 1.1 jruoho struct acpicpu_pstate *ps = NULL; 953 1.1 jruoho uint32_t i, val; 954 1.1 jruoho uint64_t addr; 955 1.1 jruoho uint8_t width; 956 1.1 jruoho int rv; 957 1.1 jruoho 958 1.11 jruoho if (sc->sc_cold != false) { 959 1.11 jruoho rv = EBUSY; 960 1.11 jruoho goto fail; 961 1.11 jruoho } 962 1.11 jruoho 963 1.1 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P) == 0) { 964 1.1 jruoho rv = ENODEV; 965 1.1 jruoho goto fail; 966 1.1 jruoho } 967 1.1 jruoho 968 1.1 jruoho mutex_enter(&sc->sc_mtx); 969 1.1 jruoho 970 1.27 jruoho for (i = sc->sc_pstate_max; i <= sc->sc_pstate_min; i++) { 971 1.1 jruoho 972 1.1 jruoho if (sc->sc_pstate[i].ps_freq == 0) 973 1.1 jruoho continue; 974 1.1 jruoho 975 1.1 jruoho if (sc->sc_pstate[i].ps_freq == freq) { 976 1.1 jruoho ps = &sc->sc_pstate[i]; 977 1.1 jruoho break; 978 1.1 jruoho } 979 1.1 jruoho } 980 1.1 jruoho 981 1.1 jruoho mutex_exit(&sc->sc_mtx); 982 1.1 jruoho 983 1.15 jruoho if (__predict_false(ps == NULL)) { 984 1.1 jruoho rv = EINVAL; 985 1.1 jruoho goto fail; 986 1.1 jruoho } 987 1.1 jruoho 988 1.1 jruoho switch (method) { 989 1.1 jruoho 990 1.1 jruoho case ACPI_ADR_SPACE_FIXED_HARDWARE: 991 1.1 jruoho 992 1.1 jruoho rv = acpicpu_md_pstate_set(ps); 993 1.1 jruoho 994 1.1 jruoho if (rv != 0) 995 1.1 jruoho goto fail; 996 1.1 jruoho 997 1.1 jruoho break; 998 1.1 jruoho 999 1.1 jruoho case ACPI_ADR_SPACE_SYSTEM_IO: 1000 1.1 jruoho 1001 1.1 jruoho addr = sc->sc_pstate_control.reg_addr; 1002 1.1 jruoho width = sc->sc_pstate_control.reg_bitwidth; 1003 1.1 jruoho 1004 1.1 jruoho (void)AcpiOsWritePort(addr, ps->ps_control, width); 1005 1.1 jruoho 1006 1.1 jruoho addr = sc->sc_pstate_status.reg_addr; 1007 1.1 jruoho width = sc->sc_pstate_status.reg_bitwidth; 1008 1.1 jruoho 1009 1.1 jruoho /* 1010 1.1 jruoho * Some systems take longer to respond 1011 1.1 jruoho * than the reported worst-case latency. 1012 1.1 jruoho */ 1013 1.1 jruoho for (i = val = 0; i < ACPICPU_P_STATE_RETRY; i++) { 1014 1.1 jruoho 1015 1.1 jruoho (void)AcpiOsReadPort(addr, &val, width); 1016 1.1 jruoho 1017 1.1 jruoho if (val == ps->ps_status) 1018 1.1 jruoho break; 1019 1.1 jruoho 1020 1.1 jruoho DELAY(ps->ps_latency); 1021 1.1 jruoho } 1022 1.1 jruoho 1023 1.1 jruoho if (i == ACPICPU_P_STATE_RETRY) { 1024 1.1 jruoho rv = EAGAIN; 1025 1.1 jruoho goto fail; 1026 1.1 jruoho } 1027 1.1 jruoho 1028 1.1 jruoho break; 1029 1.1 jruoho 1030 1.1 jruoho default: 1031 1.1 jruoho rv = ENOTTY; 1032 1.1 jruoho goto fail; 1033 1.1 jruoho } 1034 1.1 jruoho 1035 1.16 jruoho mutex_enter(&sc->sc_mtx); 1036 1.7 jruoho ps->ps_evcnt.ev_count++; 1037 1.1 jruoho sc->sc_pstate_current = freq; 1038 1.14 jruoho mutex_exit(&sc->sc_mtx); 1039 1.1 jruoho 1040 1.1 jruoho return 0; 1041 1.1 jruoho 1042 1.1 jruoho fail: 1043 1.1 jruoho aprint_error_dev(sc->sc_dev, "failed to set " 1044 1.1 jruoho "frequency to %u (err %d)\n", freq, rv); 1045 1.1 jruoho 1046 1.14 jruoho mutex_enter(&sc->sc_mtx); 1047 1.1 jruoho sc->sc_pstate_current = ACPICPU_P_STATE_UNKNOWN; 1048 1.14 jruoho mutex_exit(&sc->sc_mtx); 1049 1.1 jruoho 1050 1.1 jruoho return rv; 1051 1.1 jruoho } 1052
Indexes created Tue Sep 30 20:09:53 GMT 2025