acpi_cpu_md.c revision 1.38.4.1
1 1.38.4.1 bouyer /* $NetBSD: acpi_cpu_md.c,v 1.38.4.1 2011/02/17 12:00:05 bouyer 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 1.38.4.1 bouyer __KERNEL_RCSID(0, "$NetBSD: acpi_cpu_md.c,v 1.38.4.1 2011/02/17 12:00:05 bouyer Exp $"); 31 1.1 jruoho 32 1.1 jruoho #include <sys/param.h> 33 1.1 jruoho #include <sys/bus.h> 34 1.1 jruoho #include <sys/kcore.h> 35 1.5 jruoho #include <sys/sysctl.h> 36 1.4 jruoho #include <sys/xcall.h> 37 1.1 jruoho 38 1.1 jruoho #include <x86/cpu.h> 39 1.5 jruoho #include <x86/cpufunc.h> 40 1.5 jruoho #include <x86/cputypes.h> 41 1.1 jruoho #include <x86/cpuvar.h> 42 1.5 jruoho #include <x86/cpu_msr.h> 43 1.1 jruoho #include <x86/machdep.h> 44 1.1 jruoho 45 1.1 jruoho #include <dev/acpi/acpica.h> 46 1.1 jruoho #include <dev/acpi/acpi_cpu.h> 47 1.1 jruoho 48 1.12 jruoho #include <dev/pci/pcivar.h> 49 1.12 jruoho #include <dev/pci/pcidevs.h> 50 1.12 jruoho 51 1.38 jruoho #include <machine/acpi_machdep.h> 52 1.38 jruoho 53 1.35 jruoho /* 54 1.35 jruoho * AMD C1E. 55 1.35 jruoho */ 56 1.35 jruoho #define MSR_CMPHALT 0xc0010055 57 1.35 jruoho 58 1.35 jruoho #define MSR_CMPHALT_SMI __BIT(27) 59 1.35 jruoho #define MSR_CMPHALT_C1E __BIT(28) 60 1.35 jruoho #define MSR_CMPHALT_BMSTS __BIT(29) 61 1.33 jruoho 62 1.32 jruoho /* 63 1.32 jruoho * AMD families 10h and 11h. 64 1.32 jruoho */ 65 1.32 jruoho #define MSR_10H_LIMIT 0xc0010061 66 1.32 jruoho #define MSR_10H_CONTROL 0xc0010062 67 1.32 jruoho #define MSR_10H_STATUS 0xc0010063 68 1.32 jruoho #define MSR_10H_CONFIG 0xc0010064 69 1.22 jruoho 70 1.32 jruoho /* 71 1.32 jruoho * AMD family 0Fh. 72 1.32 jruoho */ 73 1.32 jruoho #define MSR_0FH_CONTROL 0xc0010041 74 1.17 jruoho #define MSR_0FH_STATUS 0xc0010042 75 1.17 jruoho 76 1.32 jruoho #define MSR_0FH_STATUS_CFID __BITS( 0, 5) 77 1.32 jruoho #define MSR_0FH_STATUS_CVID __BITS(32, 36) 78 1.32 jruoho #define MSR_0FH_STATUS_PENDING __BITS(31, 31) 79 1.32 jruoho 80 1.32 jruoho #define MSR_0FH_CONTROL_FID __BITS( 0, 5) 81 1.32 jruoho #define MSR_0FH_CONTROL_VID __BITS( 8, 12) 82 1.32 jruoho #define MSR_0FH_CONTROL_CHG __BITS(16, 16) 83 1.32 jruoho #define MSR_0FH_CONTROL_CNT __BITS(32, 51) 84 1.32 jruoho 85 1.32 jruoho #define ACPI_0FH_STATUS_FID __BITS( 0, 5) 86 1.32 jruoho #define ACPI_0FH_STATUS_VID __BITS( 6, 10) 87 1.32 jruoho 88 1.32 jruoho #define ACPI_0FH_CONTROL_FID __BITS( 0, 5) 89 1.32 jruoho #define ACPI_0FH_CONTROL_VID __BITS( 6, 10) 90 1.32 jruoho #define ACPI_0FH_CONTROL_VST __BITS(11, 17) 91 1.32 jruoho #define ACPI_0FH_CONTROL_MVS __BITS(18, 19) 92 1.32 jruoho #define ACPI_0FH_CONTROL_PLL __BITS(20, 26) 93 1.32 jruoho #define ACPI_0FH_CONTROL_RVO __BITS(28, 29) 94 1.32 jruoho #define ACPI_0FH_CONTROL_IRT __BITS(30, 31) 95 1.32 jruoho 96 1.32 jruoho #define FID_TO_VCO_FID(fidd) (((fid) < 8) ? (8 + ((fid) << 1)) : (fid)) 97 1.17 jruoho 98 1.5 jruoho static char native_idle_text[16]; 99 1.5 jruoho void (*native_idle)(void) = NULL; 100 1.1 jruoho 101 1.12 jruoho static int acpicpu_md_quirks_piix4(struct pci_attach_args *); 102 1.19 jruoho static void acpicpu_md_pstate_status(void *, void *); 103 1.32 jruoho static int acpicpu_md_pstate_fidvid_get(struct acpicpu_softc *, 104 1.32 jruoho uint32_t *); 105 1.32 jruoho static int acpicpu_md_pstate_fidvid_set(struct acpicpu_pstate *); 106 1.32 jruoho static int acpicpu_md_pstate_fidvid_read(uint32_t *, uint32_t *); 107 1.32 jruoho static void acpicpu_md_pstate_fidvid_write(uint32_t, uint32_t, 108 1.32 jruoho uint32_t, uint32_t); 109 1.19 jruoho static void acpicpu_md_tstate_status(void *, void *); 110 1.19 jruoho static int acpicpu_md_pstate_sysctl_init(void); 111 1.5 jruoho static int acpicpu_md_pstate_sysctl_get(SYSCTLFN_PROTO); 112 1.5 jruoho static int acpicpu_md_pstate_sysctl_set(SYSCTLFN_PROTO); 113 1.5 jruoho static int acpicpu_md_pstate_sysctl_all(SYSCTLFN_PROTO); 114 1.5 jruoho 115 1.5 jruoho extern struct acpicpu_softc **acpicpu_sc; 116 1.35 jruoho static bool acpicpu_pstate_status = false; 117 1.19 jruoho static struct sysctllog *acpicpu_log = NULL; 118 1.1 jruoho 119 1.1 jruoho uint32_t 120 1.1 jruoho acpicpu_md_cap(void) 121 1.1 jruoho { 122 1.1 jruoho struct cpu_info *ci = curcpu(); 123 1.1 jruoho uint32_t val = 0; 124 1.1 jruoho 125 1.17 jruoho if (cpu_vendor != CPUVENDOR_IDT && 126 1.17 jruoho cpu_vendor != CPUVENDOR_INTEL) 127 1.1 jruoho return val; 128 1.1 jruoho 129 1.1 jruoho /* 130 1.1 jruoho * Basic SMP C-states (required for _CST). 131 1.1 jruoho */ 132 1.1 jruoho val |= ACPICPU_PDC_C_C1PT | ACPICPU_PDC_C_C2C3; 133 1.1 jruoho 134 1.1 jruoho /* 135 1.1 jruoho * If MONITOR/MWAIT is available, announce 136 1.1 jruoho * support for native instructions in all C-states. 137 1.1 jruoho */ 138 1.1 jruoho if ((ci->ci_feat_val[1] & CPUID2_MONITOR) != 0) 139 1.1 jruoho val |= ACPICPU_PDC_C_C1_FFH | ACPICPU_PDC_C_C2C3_FFH; 140 1.1 jruoho 141 1.5 jruoho /* 142 1.10 jruoho * Set native P- and T-states, if available. 143 1.5 jruoho */ 144 1.5 jruoho if ((ci->ci_feat_val[1] & CPUID2_EST) != 0) 145 1.5 jruoho val |= ACPICPU_PDC_P_FFH; 146 1.5 jruoho 147 1.10 jruoho if ((ci->ci_feat_val[0] & CPUID_ACPI) != 0) 148 1.10 jruoho val |= ACPICPU_PDC_T_FFH; 149 1.10 jruoho 150 1.1 jruoho return val; 151 1.1 jruoho } 152 1.1 jruoho 153 1.1 jruoho uint32_t 154 1.1 jruoho acpicpu_md_quirks(void) 155 1.1 jruoho { 156 1.1 jruoho struct cpu_info *ci = curcpu(); 157 1.12 jruoho struct pci_attach_args pa; 158 1.18 jruoho uint32_t family, val = 0; 159 1.21 jruoho uint32_t regs[4]; 160 1.1 jruoho 161 1.38 jruoho if (acpi_md_ncpus() == 1) 162 1.1 jruoho val |= ACPICPU_FLAG_C_BM; 163 1.1 jruoho 164 1.1 jruoho if ((ci->ci_feat_val[1] & CPUID2_MONITOR) != 0) 165 1.5 jruoho val |= ACPICPU_FLAG_C_FFH; 166 1.1 jruoho 167 1.38.4.1 bouyer /* 168 1.38.4.1 bouyer * By default, assume that the local APIC timer 169 1.38.4.1 bouyer * as well as TSC are stalled during C3 sleep. 170 1.38.4.1 bouyer */ 171 1.25 jruoho val |= ACPICPU_FLAG_C_APIC | ACPICPU_FLAG_C_TSC; 172 1.22 jruoho 173 1.1 jruoho switch (cpu_vendor) { 174 1.1 jruoho 175 1.17 jruoho case CPUVENDOR_IDT: 176 1.22 jruoho 177 1.22 jruoho if ((ci->ci_feat_val[1] & CPUID2_EST) != 0) 178 1.22 jruoho val |= ACPICPU_FLAG_P_FFH; 179 1.22 jruoho 180 1.22 jruoho if ((ci->ci_feat_val[0] & CPUID_ACPI) != 0) 181 1.22 jruoho val |= ACPICPU_FLAG_T_FFH; 182 1.22 jruoho 183 1.22 jruoho break; 184 1.22 jruoho 185 1.1 jruoho case CPUVENDOR_INTEL: 186 1.17 jruoho 187 1.38.4.1 bouyer /* 188 1.38.4.1 bouyer * Bus master control and arbitration should be 189 1.38.4.1 bouyer * available on all supported Intel CPUs (to be 190 1.38.4.1 bouyer * sure, this is double-checked later from the 191 1.38.4.1 bouyer * firmware data). These flags imply that it is 192 1.38.4.1 bouyer * not necessary to flush caches before C3 state. 193 1.38.4.1 bouyer */ 194 1.22 jruoho val |= ACPICPU_FLAG_C_BM | ACPICPU_FLAG_C_ARB; 195 1.22 jruoho 196 1.38.4.1 bouyer /* 197 1.38.4.1 bouyer * Check if we can use "native", MSR-based, 198 1.38.4.1 bouyer * access. If not, we have to resort to I/O. 199 1.38.4.1 bouyer */ 200 1.5 jruoho if ((ci->ci_feat_val[1] & CPUID2_EST) != 0) 201 1.5 jruoho val |= ACPICPU_FLAG_P_FFH; 202 1.5 jruoho 203 1.10 jruoho if ((ci->ci_feat_val[0] & CPUID_ACPI) != 0) 204 1.10 jruoho val |= ACPICPU_FLAG_T_FFH; 205 1.10 jruoho 206 1.22 jruoho /* 207 1.25 jruoho * Check whether MSR_APERF, MSR_MPERF, and Turbo 208 1.25 jruoho * Boost are available. Also see if we might have 209 1.25 jruoho * an invariant local APIC timer ("ARAT"). 210 1.23 jruoho */ 211 1.23 jruoho if (cpuid_level >= 0x06) { 212 1.23 jruoho 213 1.23 jruoho x86_cpuid(0x06, regs); 214 1.23 jruoho 215 1.34 jruoho if ((regs[2] & CPUID_DSPM_HWF) != 0) 216 1.23 jruoho val |= ACPICPU_FLAG_P_HW; 217 1.23 jruoho 218 1.34 jruoho if ((regs[0] & CPUID_DSPM_IDA) != 0) 219 1.24 jruoho val |= ACPICPU_FLAG_P_TURBO; 220 1.25 jruoho 221 1.34 jruoho if ((regs[0] & CPUID_DSPM_ARAT) != 0) 222 1.25 jruoho val &= ~ACPICPU_FLAG_C_APIC; 223 1.23 jruoho } 224 1.23 jruoho 225 1.23 jruoho /* 226 1.22 jruoho * Detect whether TSC is invariant. If it is not, 227 1.22 jruoho * we keep the flag to note that TSC will not run 228 1.22 jruoho * at constant rate. Depending on the CPU, this may 229 1.22 jruoho * affect P- and T-state changes, but especially 230 1.22 jruoho * relevant are C-states; with variant TSC, states 231 1.24 jruoho * larger than C1 may completely stop the counter. 232 1.22 jruoho */ 233 1.22 jruoho x86_cpuid(0x80000000, regs); 234 1.22 jruoho 235 1.22 jruoho if (regs[0] >= 0x80000007) { 236 1.22 jruoho 237 1.22 jruoho x86_cpuid(0x80000007, regs); 238 1.22 jruoho 239 1.32 jruoho if ((regs[3] & __BIT(8)) != 0) 240 1.22 jruoho val &= ~ACPICPU_FLAG_C_TSC; 241 1.22 jruoho } 242 1.22 jruoho 243 1.17 jruoho break; 244 1.12 jruoho 245 1.17 jruoho case CPUVENDOR_AMD: 246 1.17 jruoho 247 1.32 jruoho x86_cpuid(0x80000000, regs); 248 1.32 jruoho 249 1.32 jruoho if (regs[0] < 0x80000007) 250 1.32 jruoho break; 251 1.32 jruoho 252 1.32 jruoho x86_cpuid(0x80000007, regs); 253 1.32 jruoho 254 1.18 jruoho family = CPUID2FAMILY(ci->ci_signature); 255 1.18 jruoho 256 1.18 jruoho if (family == 0xf) 257 1.18 jruoho family += CPUID2EXTFAMILY(ci->ci_signature); 258 1.18 jruoho 259 1.32 jruoho switch (family) { 260 1.1 jruoho 261 1.22 jruoho case 0x0f: 262 1.32 jruoho 263 1.32 jruoho if ((regs[3] & CPUID_APM_FID) == 0) 264 1.32 jruoho break; 265 1.32 jruoho 266 1.32 jruoho if ((regs[3] & CPUID_APM_VID) == 0) 267 1.32 jruoho break; 268 1.32 jruoho 269 1.32 jruoho val |= ACPICPU_FLAG_P_FFH | ACPICPU_FLAG_P_FIDVID; 270 1.32 jruoho break; 271 1.32 jruoho 272 1.17 jruoho case 0x10: 273 1.17 jruoho case 0x11: 274 1.1 jruoho 275 1.22 jruoho if ((regs[3] & CPUID_APM_TSC) != 0) 276 1.22 jruoho val &= ~ACPICPU_FLAG_C_TSC; 277 1.22 jruoho 278 1.21 jruoho if ((regs[3] & CPUID_APM_HWP) != 0) 279 1.17 jruoho val |= ACPICPU_FLAG_P_FFH; 280 1.21 jruoho 281 1.21 jruoho if ((regs[3] & CPUID_APM_CPB) != 0) 282 1.21 jruoho val |= ACPICPU_FLAG_P_TURBO; 283 1.35 jruoho 284 1.35 jruoho val |= ACPICPU_FLAG_C_C1E; 285 1.35 jruoho break; 286 1.17 jruoho } 287 1.1 jruoho 288 1.1 jruoho break; 289 1.1 jruoho } 290 1.1 jruoho 291 1.12 jruoho /* 292 1.12 jruoho * There are several erratums for PIIX4. 293 1.12 jruoho */ 294 1.12 jruoho if (pci_find_device(&pa, acpicpu_md_quirks_piix4) != 0) 295 1.12 jruoho val |= ACPICPU_FLAG_PIIX4; 296 1.12 jruoho 297 1.1 jruoho return val; 298 1.1 jruoho } 299 1.1 jruoho 300 1.12 jruoho static int 301 1.12 jruoho acpicpu_md_quirks_piix4(struct pci_attach_args *pa) 302 1.12 jruoho { 303 1.12 jruoho 304 1.12 jruoho /* 305 1.12 jruoho * XXX: The pci_find_device(9) function only 306 1.12 jruoho * deals with attached devices. Change this 307 1.12 jruoho * to use something like pci_device_foreach(). 308 1.12 jruoho */ 309 1.12 jruoho if (PCI_VENDOR(pa->pa_id) != PCI_VENDOR_INTEL) 310 1.12 jruoho return 0; 311 1.12 jruoho 312 1.12 jruoho if (PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_INTEL_82371AB_ISA || 313 1.12 jruoho PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_INTEL_82440MX_PMC) 314 1.12 jruoho return 1; 315 1.12 jruoho 316 1.12 jruoho return 0; 317 1.12 jruoho } 318 1.12 jruoho 319 1.35 jruoho void 320 1.35 jruoho acpicpu_md_quirks_c1e(void) 321 1.35 jruoho { 322 1.35 jruoho const uint64_t c1e = MSR_CMPHALT_SMI | MSR_CMPHALT_C1E; 323 1.35 jruoho uint64_t val; 324 1.35 jruoho 325 1.35 jruoho val = rdmsr(MSR_CMPHALT); 326 1.35 jruoho 327 1.35 jruoho if ((val & c1e) != 0) 328 1.35 jruoho wrmsr(MSR_CMPHALT, val & ~c1e); 329 1.35 jruoho } 330 1.35 jruoho 331 1.1 jruoho int 332 1.31 jruoho acpicpu_md_idle_start(struct acpicpu_softc *sc) 333 1.1 jruoho { 334 1.1 jruoho const size_t size = sizeof(native_idle_text); 335 1.31 jruoho struct acpicpu_cstate *cs; 336 1.31 jruoho bool ipi = false; 337 1.31 jruoho int i; 338 1.1 jruoho 339 1.1 jruoho x86_cpu_idle_get(&native_idle, native_idle_text, size); 340 1.31 jruoho 341 1.31 jruoho for (i = 0; i < ACPI_C_STATE_COUNT; i++) { 342 1.31 jruoho 343 1.31 jruoho cs = &sc->sc_cstate[i]; 344 1.31 jruoho 345 1.31 jruoho if (cs->cs_method == ACPICPU_C_STATE_HALT) { 346 1.31 jruoho ipi = true; 347 1.31 jruoho break; 348 1.31 jruoho } 349 1.31 jruoho } 350 1.31 jruoho 351 1.31 jruoho x86_cpu_idle_set(acpicpu_cstate_idle, "acpi", ipi); 352 1.1 jruoho 353 1.1 jruoho return 0; 354 1.1 jruoho } 355 1.1 jruoho 356 1.1 jruoho int 357 1.1 jruoho acpicpu_md_idle_stop(void) 358 1.1 jruoho { 359 1.4 jruoho uint64_t xc; 360 1.31 jruoho bool ipi; 361 1.1 jruoho 362 1.31 jruoho ipi = (native_idle != x86_cpu_idle_halt) ? false : true; 363 1.31 jruoho x86_cpu_idle_set(native_idle, native_idle_text, ipi); 364 1.1 jruoho 365 1.4 jruoho /* 366 1.4 jruoho * Run a cross-call to ensure that all CPUs are 367 1.4 jruoho * out from the ACPI idle-loop before detachment. 368 1.4 jruoho */ 369 1.4 jruoho xc = xc_broadcast(0, (xcfunc_t)nullop, NULL, NULL); 370 1.4 jruoho xc_wait(xc); 371 1.1 jruoho 372 1.1 jruoho return 0; 373 1.1 jruoho } 374 1.1 jruoho 375 1.3 jruoho /* 376 1.31 jruoho * Called with interrupts disabled. 377 1.31 jruoho * Caller should enable interrupts after return. 378 1.3 jruoho */ 379 1.1 jruoho void 380 1.1 jruoho acpicpu_md_idle_enter(int method, int state) 381 1.1 jruoho { 382 1.3 jruoho struct cpu_info *ci = curcpu(); 383 1.1 jruoho 384 1.1 jruoho switch (method) { 385 1.1 jruoho 386 1.1 jruoho case ACPICPU_C_STATE_FFH: 387 1.3 jruoho 388 1.3 jruoho x86_enable_intr(); 389 1.3 jruoho x86_monitor(&ci->ci_want_resched, 0, 0); 390 1.3 jruoho 391 1.31 jruoho if (__predict_false(ci->ci_want_resched != 0)) 392 1.3 jruoho return; 393 1.3 jruoho 394 1.1 jruoho x86_mwait((state - 1) << 4, 0); 395 1.1 jruoho break; 396 1.1 jruoho 397 1.1 jruoho case ACPICPU_C_STATE_HALT: 398 1.3 jruoho 399 1.31 jruoho if (__predict_false(ci->ci_want_resched != 0)) 400 1.3 jruoho return; 401 1.3 jruoho 402 1.1 jruoho x86_stihlt(); 403 1.1 jruoho break; 404 1.1 jruoho } 405 1.1 jruoho } 406 1.5 jruoho 407 1.5 jruoho int 408 1.5 jruoho acpicpu_md_pstate_start(void) 409 1.5 jruoho { 410 1.20 jruoho const uint64_t est = __BIT(16); 411 1.20 jruoho uint64_t val; 412 1.20 jruoho 413 1.20 jruoho switch (cpu_vendor) { 414 1.20 jruoho 415 1.20 jruoho case CPUVENDOR_IDT: 416 1.20 jruoho case CPUVENDOR_INTEL: 417 1.20 jruoho 418 1.20 jruoho val = rdmsr(MSR_MISC_ENABLE); 419 1.20 jruoho 420 1.20 jruoho if ((val & est) == 0) { 421 1.20 jruoho 422 1.20 jruoho val |= est; 423 1.20 jruoho 424 1.20 jruoho wrmsr(MSR_MISC_ENABLE, val); 425 1.20 jruoho val = rdmsr(MSR_MISC_ENABLE); 426 1.20 jruoho 427 1.20 jruoho if ((val & est) == 0) 428 1.20 jruoho return ENOTTY; 429 1.20 jruoho } 430 1.20 jruoho } 431 1.9 jruoho 432 1.19 jruoho return acpicpu_md_pstate_sysctl_init(); 433 1.5 jruoho } 434 1.5 jruoho 435 1.5 jruoho int 436 1.5 jruoho acpicpu_md_pstate_stop(void) 437 1.5 jruoho { 438 1.5 jruoho 439 1.19 jruoho if (acpicpu_log != NULL) 440 1.19 jruoho sysctl_teardown(&acpicpu_log); 441 1.5 jruoho 442 1.5 jruoho return 0; 443 1.5 jruoho } 444 1.5 jruoho 445 1.5 jruoho int 446 1.15 jruoho acpicpu_md_pstate_pss(struct acpicpu_softc *sc) 447 1.5 jruoho { 448 1.15 jruoho struct acpicpu_pstate *ps, msr; 449 1.17 jruoho struct cpu_info *ci = curcpu(); 450 1.18 jruoho uint32_t family, i = 0; 451 1.13 jruoho 452 1.15 jruoho (void)memset(&msr, 0, sizeof(struct acpicpu_pstate)); 453 1.13 jruoho 454 1.5 jruoho switch (cpu_vendor) { 455 1.5 jruoho 456 1.17 jruoho case CPUVENDOR_IDT: 457 1.5 jruoho case CPUVENDOR_INTEL: 458 1.33 jruoho 459 1.33 jruoho /* 460 1.33 jruoho * If the so-called Turbo Boost is present, 461 1.33 jruoho * the P0-state is always the "turbo state". 462 1.33 jruoho * 463 1.33 jruoho * For discussion, see: 464 1.33 jruoho * 465 1.33 jruoho * Intel Corporation: Intel Turbo Boost Technology 466 1.33 jruoho * in Intel Core(tm) Microarchitectures (Nehalem) 467 1.33 jruoho * Based Processors. White Paper, November 2008. 468 1.33 jruoho */ 469 1.33 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P_TURBO) != 0) 470 1.33 jruoho sc->sc_pstate[0].ps_flags |= ACPICPU_FLAG_P_TURBO; 471 1.33 jruoho 472 1.15 jruoho msr.ps_control_addr = MSR_PERF_CTL; 473 1.15 jruoho msr.ps_control_mask = __BITS(0, 15); 474 1.15 jruoho 475 1.15 jruoho msr.ps_status_addr = MSR_PERF_STATUS; 476 1.15 jruoho msr.ps_status_mask = __BITS(0, 15); 477 1.13 jruoho break; 478 1.13 jruoho 479 1.13 jruoho case CPUVENDOR_AMD: 480 1.13 jruoho 481 1.33 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P_FIDVID) != 0) 482 1.33 jruoho msr.ps_flags |= ACPICPU_FLAG_P_FIDVID; 483 1.33 jruoho 484 1.18 jruoho family = CPUID2FAMILY(ci->ci_signature); 485 1.18 jruoho 486 1.18 jruoho if (family == 0xf) 487 1.18 jruoho family += CPUID2EXTFAMILY(ci->ci_signature); 488 1.18 jruoho 489 1.18 jruoho switch (family) { 490 1.17 jruoho 491 1.32 jruoho case 0x0f: 492 1.32 jruoho msr.ps_control_addr = MSR_0FH_CONTROL; 493 1.32 jruoho msr.ps_status_addr = MSR_0FH_STATUS; 494 1.32 jruoho break; 495 1.32 jruoho 496 1.17 jruoho case 0x10: 497 1.17 jruoho case 0x11: 498 1.17 jruoho msr.ps_control_addr = MSR_10H_CONTROL; 499 1.17 jruoho msr.ps_control_mask = __BITS(0, 2); 500 1.17 jruoho 501 1.17 jruoho msr.ps_status_addr = MSR_10H_STATUS; 502 1.17 jruoho msr.ps_status_mask = __BITS(0, 2); 503 1.17 jruoho break; 504 1.17 jruoho 505 1.17 jruoho default: 506 1.17 jruoho 507 1.17 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P_XPSS) == 0) 508 1.17 jruoho return EOPNOTSUPP; 509 1.17 jruoho } 510 1.13 jruoho 511 1.13 jruoho break; 512 1.13 jruoho 513 1.13 jruoho default: 514 1.13 jruoho return ENODEV; 515 1.13 jruoho } 516 1.5 jruoho 517 1.26 jruoho /* 518 1.26 jruoho * Fill the P-state structures with MSR addresses that are 519 1.27 jruoho * known to be correct. If we do not know the addresses, 520 1.27 jruoho * leave the values intact. If a vendor uses XPSS, we do 521 1.38.4.1 bouyer * not necessarily need to do anything to support new CPUs. 522 1.26 jruoho */ 523 1.15 jruoho while (i < sc->sc_pstate_count) { 524 1.15 jruoho 525 1.15 jruoho ps = &sc->sc_pstate[i]; 526 1.15 jruoho 527 1.32 jruoho if (msr.ps_flags != 0) 528 1.32 jruoho ps->ps_flags |= msr.ps_flags; 529 1.32 jruoho 530 1.27 jruoho if (msr.ps_status_addr != 0) 531 1.15 jruoho ps->ps_status_addr = msr.ps_status_addr; 532 1.15 jruoho 533 1.27 jruoho if (msr.ps_status_mask != 0) 534 1.15 jruoho ps->ps_status_mask = msr.ps_status_mask; 535 1.15 jruoho 536 1.27 jruoho if (msr.ps_control_addr != 0) 537 1.15 jruoho ps->ps_control_addr = msr.ps_control_addr; 538 1.15 jruoho 539 1.27 jruoho if (msr.ps_control_mask != 0) 540 1.15 jruoho ps->ps_control_mask = msr.ps_control_mask; 541 1.15 jruoho 542 1.15 jruoho i++; 543 1.15 jruoho } 544 1.15 jruoho 545 1.15 jruoho return 0; 546 1.15 jruoho } 547 1.15 jruoho 548 1.15 jruoho int 549 1.15 jruoho acpicpu_md_pstate_get(struct acpicpu_softc *sc, uint32_t *freq) 550 1.15 jruoho { 551 1.15 jruoho struct acpicpu_pstate *ps = NULL; 552 1.15 jruoho uint64_t val; 553 1.15 jruoho uint32_t i; 554 1.15 jruoho 555 1.32 jruoho if ((sc->sc_flags & ACPICPU_FLAG_P_FIDVID) != 0) 556 1.32 jruoho return acpicpu_md_pstate_fidvid_get(sc, freq); 557 1.32 jruoho 558 1.15 jruoho for (i = 0; i < sc->sc_pstate_count; i++) { 559 1.15 jruoho 560 1.15 jruoho ps = &sc->sc_pstate[i]; 561 1.15 jruoho 562 1.32 jruoho if (__predict_true(ps->ps_freq != 0)) 563 1.15 jruoho break; 564 1.15 jruoho } 565 1.15 jruoho 566 1.15 jruoho if (__predict_false(ps == NULL)) 567 1.17 jruoho return ENODEV; 568 1.15 jruoho 569 1.28 jruoho if (__predict_false(ps->ps_status_addr == 0)) 570 1.13 jruoho return EINVAL; 571 1.5 jruoho 572 1.13 jruoho val = rdmsr(ps->ps_status_addr); 573 1.5 jruoho 574 1.28 jruoho if (__predict_true(ps->ps_status_mask != 0)) 575 1.13 jruoho val = val & ps->ps_status_mask; 576 1.5 jruoho 577 1.13 jruoho for (i = 0; i < sc->sc_pstate_count; i++) { 578 1.5 jruoho 579 1.13 jruoho ps = &sc->sc_pstate[i]; 580 1.5 jruoho 581 1.32 jruoho if (__predict_false(ps->ps_freq == 0)) 582 1.13 jruoho continue; 583 1.5 jruoho 584 1.29 jruoho if (val == ps->ps_status) { 585 1.13 jruoho *freq = ps->ps_freq; 586 1.13 jruoho return 0; 587 1.13 jruoho } 588 1.5 jruoho } 589 1.5 jruoho 590 1.13 jruoho return EIO; 591 1.5 jruoho } 592 1.5 jruoho 593 1.5 jruoho int 594 1.5 jruoho acpicpu_md_pstate_set(struct acpicpu_pstate *ps) 595 1.5 jruoho { 596 1.5 jruoho struct msr_rw_info msr; 597 1.14 jruoho uint64_t xc; 598 1.14 jruoho int rv = 0; 599 1.5 jruoho 600 1.37 jruoho if (__predict_false(ps->ps_control_addr == 0)) 601 1.37 jruoho return EINVAL; 602 1.37 jruoho 603 1.32 jruoho if ((ps->ps_flags & ACPICPU_FLAG_P_FIDVID) != 0) 604 1.32 jruoho return acpicpu_md_pstate_fidvid_set(ps); 605 1.32 jruoho 606 1.13 jruoho msr.msr_read = false; 607 1.13 jruoho msr.msr_type = ps->ps_control_addr; 608 1.13 jruoho msr.msr_value = ps->ps_control; 609 1.13 jruoho 610 1.24 jruoho if (__predict_true(ps->ps_control_mask != 0)) { 611 1.13 jruoho msr.msr_mask = ps->ps_control_mask; 612 1.13 jruoho msr.msr_read = true; 613 1.13 jruoho } 614 1.13 jruoho 615 1.5 jruoho xc = xc_broadcast(0, (xcfunc_t)x86_msr_xcall, &msr, NULL); 616 1.5 jruoho xc_wait(xc); 617 1.5 jruoho 618 1.36 jruoho /* 619 1.36 jruoho * Due several problems, we bypass the 620 1.36 jruoho * relatively expensive status check. 621 1.36 jruoho */ 622 1.36 jruoho if (acpicpu_pstate_status != true) { 623 1.33 jruoho DELAY(ps->ps_latency); 624 1.33 jruoho return 0; 625 1.33 jruoho } 626 1.13 jruoho 627 1.14 jruoho xc = xc_broadcast(0, (xcfunc_t)acpicpu_md_pstate_status, ps, &rv); 628 1.14 jruoho xc_wait(xc); 629 1.14 jruoho 630 1.14 jruoho return rv; 631 1.14 jruoho } 632 1.14 jruoho 633 1.14 jruoho static void 634 1.14 jruoho acpicpu_md_pstate_status(void *arg1, void *arg2) 635 1.14 jruoho { 636 1.14 jruoho struct acpicpu_pstate *ps = arg1; 637 1.14 jruoho uint64_t val; 638 1.14 jruoho int i; 639 1.14 jruoho 640 1.5 jruoho for (i = val = 0; i < ACPICPU_P_STATE_RETRY; i++) { 641 1.5 jruoho 642 1.13 jruoho val = rdmsr(ps->ps_status_addr); 643 1.13 jruoho 644 1.24 jruoho if (__predict_true(ps->ps_status_mask != 0)) 645 1.13 jruoho val = val & ps->ps_status_mask; 646 1.5 jruoho 647 1.29 jruoho if (val == ps->ps_status) 648 1.14 jruoho return; 649 1.5 jruoho 650 1.5 jruoho DELAY(ps->ps_latency); 651 1.5 jruoho } 652 1.5 jruoho 653 1.14 jruoho *(uintptr_t *)arg2 = EAGAIN; 654 1.5 jruoho } 655 1.10 jruoho 656 1.32 jruoho static int 657 1.32 jruoho acpicpu_md_pstate_fidvid_get(struct acpicpu_softc *sc, uint32_t *freq) 658 1.32 jruoho { 659 1.32 jruoho struct acpicpu_pstate *ps; 660 1.32 jruoho uint32_t fid, i, vid; 661 1.32 jruoho uint32_t cfid, cvid; 662 1.32 jruoho int rv; 663 1.32 jruoho 664 1.32 jruoho /* 665 1.32 jruoho * AMD family 0Fh needs special treatment. 666 1.32 jruoho * While it wants to use ACPI, it does not 667 1.32 jruoho * comply with the ACPI specifications. 668 1.32 jruoho */ 669 1.32 jruoho rv = acpicpu_md_pstate_fidvid_read(&cfid, &cvid); 670 1.32 jruoho 671 1.32 jruoho if (rv != 0) 672 1.32 jruoho return rv; 673 1.32 jruoho 674 1.32 jruoho for (i = 0; i < sc->sc_pstate_count; i++) { 675 1.32 jruoho 676 1.32 jruoho ps = &sc->sc_pstate[i]; 677 1.32 jruoho 678 1.32 jruoho if (__predict_false(ps->ps_freq == 0)) 679 1.32 jruoho continue; 680 1.32 jruoho 681 1.32 jruoho fid = __SHIFTOUT(ps->ps_status, ACPI_0FH_STATUS_FID); 682 1.32 jruoho vid = __SHIFTOUT(ps->ps_status, ACPI_0FH_STATUS_VID); 683 1.32 jruoho 684 1.32 jruoho if (cfid == fid && cvid == vid) { 685 1.32 jruoho *freq = ps->ps_freq; 686 1.32 jruoho return 0; 687 1.32 jruoho } 688 1.32 jruoho } 689 1.32 jruoho 690 1.32 jruoho return EIO; 691 1.32 jruoho } 692 1.32 jruoho 693 1.32 jruoho static int 694 1.32 jruoho acpicpu_md_pstate_fidvid_set(struct acpicpu_pstate *ps) 695 1.32 jruoho { 696 1.32 jruoho const uint64_t ctrl = ps->ps_control; 697 1.32 jruoho uint32_t cfid, cvid, fid, i, irt; 698 1.32 jruoho uint32_t pll, vco_cfid, vco_fid; 699 1.32 jruoho uint32_t val, vid, vst; 700 1.32 jruoho int rv; 701 1.32 jruoho 702 1.32 jruoho rv = acpicpu_md_pstate_fidvid_read(&cfid, &cvid); 703 1.32 jruoho 704 1.32 jruoho if (rv != 0) 705 1.32 jruoho return rv; 706 1.32 jruoho 707 1.32 jruoho fid = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_FID); 708 1.32 jruoho vid = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_VID); 709 1.32 jruoho irt = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_IRT); 710 1.32 jruoho vst = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_VST); 711 1.32 jruoho pll = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_PLL); 712 1.32 jruoho 713 1.32 jruoho vst = vst * 20; 714 1.32 jruoho pll = pll * 1000 / 5; 715 1.32 jruoho irt = 10 * __BIT(irt); 716 1.32 jruoho 717 1.32 jruoho /* 718 1.32 jruoho * Phase 1. 719 1.32 jruoho */ 720 1.32 jruoho while (cvid > vid) { 721 1.32 jruoho 722 1.32 jruoho val = 1 << __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_MVS); 723 1.32 jruoho val = (val > cvid) ? 0 : cvid - val; 724 1.32 jruoho 725 1.32 jruoho acpicpu_md_pstate_fidvid_write(cfid, val, 1, vst); 726 1.32 jruoho rv = acpicpu_md_pstate_fidvid_read(NULL, &cvid); 727 1.32 jruoho 728 1.32 jruoho if (rv != 0) 729 1.32 jruoho return rv; 730 1.32 jruoho } 731 1.32 jruoho 732 1.32 jruoho i = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_RVO); 733 1.32 jruoho 734 1.32 jruoho for (; i > 0 && cvid > 0; --i) { 735 1.32 jruoho 736 1.32 jruoho acpicpu_md_pstate_fidvid_write(cfid, cvid - 1, 1, vst); 737 1.32 jruoho rv = acpicpu_md_pstate_fidvid_read(NULL, &cvid); 738 1.32 jruoho 739 1.32 jruoho if (rv != 0) 740 1.32 jruoho return rv; 741 1.32 jruoho } 742 1.32 jruoho 743 1.32 jruoho /* 744 1.32 jruoho * Phase 2. 745 1.32 jruoho */ 746 1.32 jruoho if (cfid != fid) { 747 1.32 jruoho 748 1.32 jruoho vco_fid = FID_TO_VCO_FID(fid); 749 1.32 jruoho vco_cfid = FID_TO_VCO_FID(cfid); 750 1.32 jruoho 751 1.32 jruoho while (abs(vco_fid - vco_cfid) > 2) { 752 1.32 jruoho 753 1.32 jruoho if (fid <= cfid) 754 1.32 jruoho val = cfid - 2; 755 1.32 jruoho else { 756 1.32 jruoho val = (cfid > 6) ? cfid + 2 : 757 1.32 jruoho FID_TO_VCO_FID(cfid) + 2; 758 1.32 jruoho } 759 1.32 jruoho 760 1.32 jruoho acpicpu_md_pstate_fidvid_write(val, cvid, pll, irt); 761 1.32 jruoho rv = acpicpu_md_pstate_fidvid_read(&cfid, NULL); 762 1.32 jruoho 763 1.32 jruoho if (rv != 0) 764 1.32 jruoho return rv; 765 1.32 jruoho 766 1.32 jruoho vco_cfid = FID_TO_VCO_FID(cfid); 767 1.32 jruoho } 768 1.32 jruoho 769 1.32 jruoho acpicpu_md_pstate_fidvid_write(fid, cvid, pll, irt); 770 1.32 jruoho rv = acpicpu_md_pstate_fidvid_read(&cfid, NULL); 771 1.32 jruoho 772 1.32 jruoho if (rv != 0) 773 1.32 jruoho return rv; 774 1.32 jruoho } 775 1.32 jruoho 776 1.32 jruoho /* 777 1.32 jruoho * Phase 3. 778 1.32 jruoho */ 779 1.32 jruoho if (cvid != vid) { 780 1.32 jruoho 781 1.32 jruoho acpicpu_md_pstate_fidvid_write(cfid, vid, 1, vst); 782 1.32 jruoho rv = acpicpu_md_pstate_fidvid_read(NULL, &cvid); 783 1.32 jruoho 784 1.32 jruoho if (rv != 0) 785 1.32 jruoho return rv; 786 1.32 jruoho } 787 1.32 jruoho 788 1.32 jruoho if (cfid != fid || cvid != vid) 789 1.32 jruoho return EIO; 790 1.32 jruoho 791 1.32 jruoho return 0; 792 1.32 jruoho } 793 1.32 jruoho 794 1.32 jruoho static int 795 1.32 jruoho acpicpu_md_pstate_fidvid_read(uint32_t *cfid, uint32_t *cvid) 796 1.32 jruoho { 797 1.32 jruoho int i = ACPICPU_P_STATE_RETRY * 100; 798 1.32 jruoho uint64_t val; 799 1.32 jruoho 800 1.32 jruoho do { 801 1.32 jruoho val = rdmsr(MSR_0FH_STATUS); 802 1.32 jruoho 803 1.32 jruoho } while (__SHIFTOUT(val, MSR_0FH_STATUS_PENDING) != 0 && --i >= 0); 804 1.32 jruoho 805 1.32 jruoho if (i == 0) 806 1.32 jruoho return EAGAIN; 807 1.32 jruoho 808 1.32 jruoho if (cfid != NULL) 809 1.32 jruoho *cfid = __SHIFTOUT(val, MSR_0FH_STATUS_CFID); 810 1.32 jruoho 811 1.32 jruoho if (cvid != NULL) 812 1.32 jruoho *cvid = __SHIFTOUT(val, MSR_0FH_STATUS_CVID); 813 1.32 jruoho 814 1.32 jruoho return 0; 815 1.32 jruoho } 816 1.32 jruoho 817 1.32 jruoho static void 818 1.32 jruoho acpicpu_md_pstate_fidvid_write(uint32_t fid, 819 1.32 jruoho uint32_t vid, uint32_t cnt, uint32_t tmo) 820 1.32 jruoho { 821 1.32 jruoho struct msr_rw_info msr; 822 1.32 jruoho uint64_t xc; 823 1.32 jruoho 824 1.32 jruoho msr.msr_read = false; 825 1.32 jruoho msr.msr_type = MSR_0FH_CONTROL; 826 1.32 jruoho msr.msr_value = 0; 827 1.32 jruoho 828 1.32 jruoho msr.msr_value |= __SHIFTIN(fid, MSR_0FH_CONTROL_FID); 829 1.32 jruoho msr.msr_value |= __SHIFTIN(vid, MSR_0FH_CONTROL_VID); 830 1.32 jruoho msr.msr_value |= __SHIFTIN(cnt, MSR_0FH_CONTROL_CNT); 831 1.32 jruoho msr.msr_value |= __SHIFTIN(0x1, MSR_0FH_CONTROL_CHG); 832 1.32 jruoho 833 1.32 jruoho xc = xc_broadcast(0, (xcfunc_t)x86_msr_xcall, &msr, NULL); 834 1.32 jruoho xc_wait(xc); 835 1.32 jruoho 836 1.32 jruoho DELAY(tmo); 837 1.32 jruoho } 838 1.32 jruoho 839 1.10 jruoho int 840 1.10 jruoho acpicpu_md_tstate_get(struct acpicpu_softc *sc, uint32_t *percent) 841 1.10 jruoho { 842 1.10 jruoho struct acpicpu_tstate *ts; 843 1.14 jruoho uint64_t val; 844 1.10 jruoho uint32_t i; 845 1.10 jruoho 846 1.14 jruoho val = rdmsr(MSR_THERM_CONTROL); 847 1.10 jruoho 848 1.10 jruoho for (i = 0; i < sc->sc_tstate_count; i++) { 849 1.10 jruoho 850 1.10 jruoho ts = &sc->sc_tstate[i]; 851 1.10 jruoho 852 1.10 jruoho if (ts->ts_percent == 0) 853 1.10 jruoho continue; 854 1.10 jruoho 855 1.29 jruoho if (val == ts->ts_status) { 856 1.10 jruoho *percent = ts->ts_percent; 857 1.10 jruoho return 0; 858 1.10 jruoho } 859 1.10 jruoho } 860 1.10 jruoho 861 1.10 jruoho return EIO; 862 1.10 jruoho } 863 1.10 jruoho 864 1.10 jruoho int 865 1.10 jruoho acpicpu_md_tstate_set(struct acpicpu_tstate *ts) 866 1.10 jruoho { 867 1.10 jruoho struct msr_rw_info msr; 868 1.14 jruoho uint64_t xc; 869 1.14 jruoho int rv = 0; 870 1.10 jruoho 871 1.14 jruoho msr.msr_read = true; 872 1.14 jruoho msr.msr_type = MSR_THERM_CONTROL; 873 1.14 jruoho msr.msr_value = ts->ts_control; 874 1.14 jruoho msr.msr_mask = __BITS(1, 4); 875 1.10 jruoho 876 1.10 jruoho xc = xc_broadcast(0, (xcfunc_t)x86_msr_xcall, &msr, NULL); 877 1.10 jruoho xc_wait(xc); 878 1.10 jruoho 879 1.30 jruoho if (ts->ts_status == 0) { 880 1.30 jruoho DELAY(ts->ts_latency); 881 1.10 jruoho return 0; 882 1.30 jruoho } 883 1.10 jruoho 884 1.14 jruoho xc = xc_broadcast(0, (xcfunc_t)acpicpu_md_tstate_status, ts, &rv); 885 1.14 jruoho xc_wait(xc); 886 1.14 jruoho 887 1.14 jruoho return rv; 888 1.14 jruoho } 889 1.14 jruoho 890 1.14 jruoho static void 891 1.14 jruoho acpicpu_md_tstate_status(void *arg1, void *arg2) 892 1.14 jruoho { 893 1.14 jruoho struct acpicpu_tstate *ts = arg1; 894 1.14 jruoho uint64_t val; 895 1.14 jruoho int i; 896 1.14 jruoho 897 1.10 jruoho for (i = val = 0; i < ACPICPU_T_STATE_RETRY; i++) { 898 1.10 jruoho 899 1.14 jruoho val = rdmsr(MSR_THERM_CONTROL); 900 1.10 jruoho 901 1.29 jruoho if (val == ts->ts_status) 902 1.14 jruoho return; 903 1.10 jruoho 904 1.10 jruoho DELAY(ts->ts_latency); 905 1.10 jruoho } 906 1.10 jruoho 907 1.14 jruoho *(uintptr_t *)arg2 = EAGAIN; 908 1.10 jruoho } 909 1.19 jruoho 910 1.19 jruoho /* 911 1.19 jruoho * A kludge for backwards compatibility. 912 1.19 jruoho */ 913 1.19 jruoho static int 914 1.19 jruoho acpicpu_md_pstate_sysctl_init(void) 915 1.19 jruoho { 916 1.19 jruoho const struct sysctlnode *fnode, *mnode, *rnode; 917 1.19 jruoho const char *str; 918 1.19 jruoho int rv; 919 1.19 jruoho 920 1.19 jruoho switch (cpu_vendor) { 921 1.19 jruoho 922 1.19 jruoho case CPUVENDOR_IDT: 923 1.19 jruoho case CPUVENDOR_INTEL: 924 1.19 jruoho str = "est"; 925 1.19 jruoho break; 926 1.19 jruoho 927 1.19 jruoho case CPUVENDOR_AMD: 928 1.19 jruoho str = "powernow"; 929 1.19 jruoho break; 930 1.19 jruoho 931 1.19 jruoho default: 932 1.19 jruoho return ENODEV; 933 1.19 jruoho } 934 1.19 jruoho 935 1.19 jruoho 936 1.19 jruoho rv = sysctl_createv(&acpicpu_log, 0, NULL, &rnode, 937 1.19 jruoho CTLFLAG_PERMANENT, CTLTYPE_NODE, "machdep", NULL, 938 1.19 jruoho NULL, 0, NULL, 0, CTL_MACHDEP, CTL_EOL); 939 1.19 jruoho 940 1.19 jruoho if (rv != 0) 941 1.19 jruoho goto fail; 942 1.19 jruoho 943 1.19 jruoho rv = sysctl_createv(&acpicpu_log, 0, &rnode, &mnode, 944 1.19 jruoho 0, CTLTYPE_NODE, str, NULL, 945 1.19 jruoho NULL, 0, NULL, 0, CTL_CREATE, CTL_EOL); 946 1.19 jruoho 947 1.19 jruoho if (rv != 0) 948 1.19 jruoho goto fail; 949 1.19 jruoho 950 1.19 jruoho rv = sysctl_createv(&acpicpu_log, 0, &mnode, &fnode, 951 1.19 jruoho 0, CTLTYPE_NODE, "frequency", NULL, 952 1.19 jruoho NULL, 0, NULL, 0, CTL_CREATE, CTL_EOL); 953 1.19 jruoho 954 1.19 jruoho if (rv != 0) 955 1.19 jruoho goto fail; 956 1.19 jruoho 957 1.19 jruoho rv = sysctl_createv(&acpicpu_log, 0, &fnode, &rnode, 958 1.19 jruoho CTLFLAG_READWRITE, CTLTYPE_INT, "target", NULL, 959 1.19 jruoho acpicpu_md_pstate_sysctl_set, 0, NULL, 0, CTL_CREATE, CTL_EOL); 960 1.19 jruoho 961 1.19 jruoho if (rv != 0) 962 1.19 jruoho goto fail; 963 1.19 jruoho 964 1.19 jruoho rv = sysctl_createv(&acpicpu_log, 0, &fnode, &rnode, 965 1.19 jruoho CTLFLAG_READONLY, CTLTYPE_INT, "current", NULL, 966 1.19 jruoho acpicpu_md_pstate_sysctl_get, 0, NULL, 0, CTL_CREATE, CTL_EOL); 967 1.19 jruoho 968 1.19 jruoho if (rv != 0) 969 1.19 jruoho goto fail; 970 1.19 jruoho 971 1.19 jruoho rv = sysctl_createv(&acpicpu_log, 0, &fnode, &rnode, 972 1.19 jruoho CTLFLAG_READONLY, CTLTYPE_STRING, "available", NULL, 973 1.19 jruoho acpicpu_md_pstate_sysctl_all, 0, NULL, 0, CTL_CREATE, CTL_EOL); 974 1.19 jruoho 975 1.19 jruoho if (rv != 0) 976 1.19 jruoho goto fail; 977 1.19 jruoho 978 1.19 jruoho return 0; 979 1.19 jruoho 980 1.19 jruoho fail: 981 1.19 jruoho if (acpicpu_log != NULL) { 982 1.19 jruoho sysctl_teardown(&acpicpu_log); 983 1.19 jruoho acpicpu_log = NULL; 984 1.19 jruoho } 985 1.19 jruoho 986 1.19 jruoho return rv; 987 1.19 jruoho } 988 1.19 jruoho 989 1.19 jruoho static int 990 1.19 jruoho acpicpu_md_pstate_sysctl_get(SYSCTLFN_ARGS) 991 1.19 jruoho { 992 1.19 jruoho struct cpu_info *ci = curcpu(); 993 1.19 jruoho struct acpicpu_softc *sc; 994 1.19 jruoho struct sysctlnode node; 995 1.19 jruoho uint32_t freq; 996 1.19 jruoho int err; 997 1.19 jruoho 998 1.19 jruoho sc = acpicpu_sc[ci->ci_acpiid]; 999 1.19 jruoho 1000 1.19 jruoho if (sc == NULL) 1001 1.19 jruoho return ENXIO; 1002 1.19 jruoho 1003 1.19 jruoho err = acpicpu_pstate_get(sc, &freq); 1004 1.19 jruoho 1005 1.19 jruoho if (err != 0) 1006 1.19 jruoho return err; 1007 1.19 jruoho 1008 1.19 jruoho node = *rnode; 1009 1.19 jruoho node.sysctl_data = &freq; 1010 1.19 jruoho 1011 1.19 jruoho err = sysctl_lookup(SYSCTLFN_CALL(&node)); 1012 1.19 jruoho 1013 1.19 jruoho if (err != 0 || newp == NULL) 1014 1.19 jruoho return err; 1015 1.19 jruoho 1016 1.19 jruoho return 0; 1017 1.19 jruoho } 1018 1.19 jruoho 1019 1.19 jruoho static int 1020 1.19 jruoho acpicpu_md_pstate_sysctl_set(SYSCTLFN_ARGS) 1021 1.19 jruoho { 1022 1.19 jruoho struct cpu_info *ci = curcpu(); 1023 1.19 jruoho struct acpicpu_softc *sc; 1024 1.19 jruoho struct sysctlnode node; 1025 1.19 jruoho uint32_t freq; 1026 1.19 jruoho int err; 1027 1.19 jruoho 1028 1.19 jruoho sc = acpicpu_sc[ci->ci_acpiid]; 1029 1.19 jruoho 1030 1.19 jruoho if (sc == NULL) 1031 1.19 jruoho return ENXIO; 1032 1.19 jruoho 1033 1.19 jruoho err = acpicpu_pstate_get(sc, &freq); 1034 1.19 jruoho 1035 1.19 jruoho if (err != 0) 1036 1.19 jruoho return err; 1037 1.19 jruoho 1038 1.19 jruoho node = *rnode; 1039 1.19 jruoho node.sysctl_data = &freq; 1040 1.19 jruoho 1041 1.19 jruoho err = sysctl_lookup(SYSCTLFN_CALL(&node)); 1042 1.19 jruoho 1043 1.19 jruoho if (err != 0 || newp == NULL) 1044 1.19 jruoho return err; 1045 1.19 jruoho 1046 1.19 jruoho err = acpicpu_pstate_set(sc, freq); 1047 1.19 jruoho 1048 1.19 jruoho if (err != 0) 1049 1.19 jruoho return err; 1050 1.19 jruoho 1051 1.19 jruoho return 0; 1052 1.19 jruoho } 1053 1.19 jruoho 1054 1.19 jruoho static int 1055 1.19 jruoho acpicpu_md_pstate_sysctl_all(SYSCTLFN_ARGS) 1056 1.19 jruoho { 1057 1.19 jruoho struct cpu_info *ci = curcpu(); 1058 1.19 jruoho struct acpicpu_softc *sc; 1059 1.19 jruoho struct sysctlnode node; 1060 1.19 jruoho char buf[1024]; 1061 1.19 jruoho size_t len; 1062 1.19 jruoho uint32_t i; 1063 1.19 jruoho int err; 1064 1.19 jruoho 1065 1.19 jruoho sc = acpicpu_sc[ci->ci_acpiid]; 1066 1.19 jruoho 1067 1.19 jruoho if (sc == NULL) 1068 1.19 jruoho return ENXIO; 1069 1.19 jruoho 1070 1.19 jruoho (void)memset(&buf, 0, sizeof(buf)); 1071 1.19 jruoho 1072 1.19 jruoho mutex_enter(&sc->sc_mtx); 1073 1.19 jruoho 1074 1.19 jruoho for (len = 0, i = sc->sc_pstate_max; i < sc->sc_pstate_count; i++) { 1075 1.19 jruoho 1076 1.19 jruoho if (sc->sc_pstate[i].ps_freq == 0) 1077 1.19 jruoho continue; 1078 1.19 jruoho 1079 1.19 jruoho len += snprintf(buf + len, sizeof(buf) - len, "%u%s", 1080 1.19 jruoho sc->sc_pstate[i].ps_freq, 1081 1.19 jruoho i < (sc->sc_pstate_count - 1) ? " " : ""); 1082 1.19 jruoho } 1083 1.19 jruoho 1084 1.19 jruoho mutex_exit(&sc->sc_mtx); 1085 1.19 jruoho 1086 1.19 jruoho node = *rnode; 1087 1.19 jruoho node.sysctl_data = buf; 1088 1.19 jruoho 1089 1.19 jruoho err = sysctl_lookup(SYSCTLFN_CALL(&node)); 1090 1.19 jruoho 1091 1.19 jruoho if (err != 0 || newp == NULL) 1092 1.19 jruoho return err; 1093 1.19 jruoho 1094 1.19 jruoho return 0; 1095 1.19 jruoho } 1096 1.19 jruoho 1097
Indexes created Tue Sep 30 20:09:53 GMT 2025