x86/acpi/acpi_cpu_md.c

1.57    jruoho /* $NetBSD: acpi_cpu_md.c,v 1.57 2011/03/24 11:52:53 jruoho Exp $ */
 1.1    jruoho
 1.1    jruoho /*-
1.41    jruoho  * Copyright (c) 2010, 2011 Jukka Ruohonen <jruohonen (at) iki.fi>
 1.1    jruoho  * All rights reserved.
 1.1    jruoho  *
 1.1    jruoho  * Redistribution and use in source and binary forms, with or without
 1.1    jruoho  * modification, are permitted provided that the following conditions
 1.1    jruoho  * are met:
 1.1    jruoho  *
 1.1    jruoho  * 1. Redistributions of source code must retain the above copyright
 1.1    jruoho  *    notice, this list of conditions and the following disclaimer.
 1.1    jruoho  * 2. Redistributions in binary form must reproduce the above copyright
 1.1    jruoho  *    notice, this list of conditions and the following disclaimer in the
 1.1    jruoho  *    documentation and/or other materials provided with the distribution.
 1.1    jruoho  *
 1.1    jruoho  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
 1.1    jruoho  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 1.1    jruoho  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 1.1    jruoho  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
 1.1    jruoho  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 1.1    jruoho  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 1.1    jruoho  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1    jruoho  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 1.1    jruoho  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1    jruoho  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1    jruoho  * SUCH DAMAGE.
 1.1    jruoho  */
 1.1    jruoho #include <sys/cdefs.h>
1.57    jruoho __KERNEL_RCSID(0, "$NetBSD: acpi_cpu_md.c,v 1.57 2011/03/24 11:52:53 jruoho Exp $");
 1.1    jruoho
 1.1    jruoho #include <sys/param.h>
 1.1    jruoho #include <sys/bus.h>
1.48    jruoho #include <sys/device.h>
 1.1    jruoho #include <sys/kcore.h>
 1.5    jruoho #include <sys/sysctl.h>
 1.4    jruoho #include <sys/xcall.h>
 1.1    jruoho
 1.1    jruoho #include <x86/cpu.h>
 1.5    jruoho #include <x86/cpufunc.h>
 1.5    jruoho #include <x86/cputypes.h>
 1.1    jruoho #include <x86/cpuvar.h>
 1.5    jruoho #include <x86/cpu_msr.h>
 1.1    jruoho #include <x86/machdep.h>
 1.1    jruoho
 1.1    jruoho #include <dev/acpi/acpica.h>
 1.1    jruoho #include <dev/acpi/acpi_cpu.h>
 1.1    jruoho
1.12    jruoho #include <dev/pci/pcivar.h>
1.12    jruoho #include <dev/pci/pcidevs.h>
1.12    jruoho
1.38    jruoho #include <machine/acpi_machdep.h>
1.38    jruoho
1.35    jruoho /*
1.55    jruoho  * Intel IA32_MISC_ENABLE.
1.55    jruoho  */
1.55    jruoho #define MSR_MISC_ENABLE_EST	__BIT(16)
1.55    jruoho #define MSR_MISC_ENABLE_TURBO	__BIT(38)
1.55    jruoho
1.55    jruoho /*
1.35    jruoho  * AMD C1E.
1.35    jruoho  */
1.35    jruoho #define MSR_CMPHALT		0xc0010055
1.35    jruoho
1.35    jruoho #define MSR_CMPHALT_SMI		__BIT(27)
1.35    jruoho #define MSR_CMPHALT_C1E		__BIT(28)
1.35    jruoho #define MSR_CMPHALT_BMSTS	__BIT(29)
1.33    jruoho
1.32    jruoho /*
1.40  jmcneill  * AMD families 10h, 11h, and 14h
1.32    jruoho  */
1.32    jruoho #define MSR_10H_LIMIT		0xc0010061
1.32    jruoho #define MSR_10H_CONTROL		0xc0010062
1.32    jruoho #define MSR_10H_STATUS		0xc0010063
1.32    jruoho #define MSR_10H_CONFIG		0xc0010064
1.22    jruoho
1.32    jruoho /*
1.32    jruoho  * AMD family 0Fh.
1.32    jruoho  */
1.32    jruoho #define MSR_0FH_CONTROL		0xc0010041
1.17    jruoho #define MSR_0FH_STATUS		0xc0010042
1.17    jruoho
1.32    jruoho #define MSR_0FH_STATUS_CFID	__BITS( 0,  5)
1.32    jruoho #define MSR_0FH_STATUS_CVID	__BITS(32, 36)
1.32    jruoho #define MSR_0FH_STATUS_PENDING	__BITS(31, 31)
1.32    jruoho
1.32    jruoho #define MSR_0FH_CONTROL_FID	__BITS( 0,  5)
1.32    jruoho #define MSR_0FH_CONTROL_VID	__BITS( 8, 12)
1.32    jruoho #define MSR_0FH_CONTROL_CHG	__BITS(16, 16)
1.32    jruoho #define MSR_0FH_CONTROL_CNT	__BITS(32, 51)
1.32    jruoho
1.32    jruoho #define ACPI_0FH_STATUS_FID	__BITS( 0,  5)
1.32    jruoho #define ACPI_0FH_STATUS_VID	__BITS( 6, 10)
1.32    jruoho
1.32    jruoho #define ACPI_0FH_CONTROL_FID	__BITS( 0,  5)
1.32    jruoho #define ACPI_0FH_CONTROL_VID	__BITS( 6, 10)
1.32    jruoho #define ACPI_0FH_CONTROL_VST	__BITS(11, 17)
1.32    jruoho #define ACPI_0FH_CONTROL_MVS	__BITS(18, 19)
1.32    jruoho #define ACPI_0FH_CONTROL_PLL	__BITS(20, 26)
1.32    jruoho #define ACPI_0FH_CONTROL_RVO	__BITS(28, 29)
1.32    jruoho #define ACPI_0FH_CONTROL_IRT	__BITS(30, 31)
1.32    jruoho
1.32    jruoho #define FID_TO_VCO_FID(fidd)	(((fid) < 8) ? (8 + ((fid) << 1)) : (fid))
1.17    jruoho
 1.5    jruoho static char	  native_idle_text[16];
 1.5    jruoho void		(*native_idle)(void) = NULL;
 1.1    jruoho
1.43    jruoho static int	 acpicpu_md_quirk_piix4(struct pci_attach_args *);
1.56    jruoho static void	 acpicpu_md_pstate_hwf_reset(void *, void *);
1.32    jruoho static int	 acpicpu_md_pstate_fidvid_get(struct acpicpu_softc *,
1.32    jruoho                                               uint32_t *);
1.32    jruoho static int	 acpicpu_md_pstate_fidvid_set(struct acpicpu_pstate *);
1.32    jruoho static int	 acpicpu_md_pstate_fidvid_read(uint32_t *, uint32_t *);
1.32    jruoho static void	 acpicpu_md_pstate_fidvid_write(uint32_t, uint32_t,
1.32    jruoho 					        uint32_t, uint32_t);
1.19    jruoho static int	 acpicpu_md_pstate_sysctl_init(void);
 1.5    jruoho static int	 acpicpu_md_pstate_sysctl_get(SYSCTLFN_PROTO);
 1.5    jruoho static int	 acpicpu_md_pstate_sysctl_set(SYSCTLFN_PROTO);
 1.5    jruoho static int	 acpicpu_md_pstate_sysctl_all(SYSCTLFN_PROTO);
 1.5    jruoho
 1.5    jruoho extern struct acpicpu_softc **acpicpu_sc;
1.19    jruoho static struct sysctllog *acpicpu_log = NULL;
 1.1    jruoho
1.48    jruoho struct cpu_info *
1.48    jruoho acpicpu_md_match(device_t parent, cfdata_t match, void *aux)
1.48    jruoho {
1.48    jruoho 	struct cpufeature_attach_args *cfaa = aux;
1.48    jruoho
1.48    jruoho 	if (strcmp(cfaa->name, "frequency") != 0)
1.48    jruoho 		return NULL;
1.48    jruoho
1.48    jruoho 	return cfaa->ci;
1.48    jruoho }
1.48    jruoho
1.48    jruoho struct cpu_info *
1.48    jruoho acpicpu_md_attach(device_t parent, device_t self, void *aux)
1.48    jruoho {
1.48    jruoho 	struct cpufeature_attach_args *cfaa = aux;
1.48    jruoho
1.48    jruoho 	return cfaa->ci;
1.48    jruoho }
1.48    jruoho
 1.1    jruoho uint32_t
 1.1    jruoho acpicpu_md_cap(void)
 1.1    jruoho {
 1.1    jruoho 	struct cpu_info *ci = curcpu();
1.44    jruoho 	uint32_t regs[4];
 1.1    jruoho 	uint32_t val = 0;
 1.1    jruoho
1.17    jruoho 	if (cpu_vendor != CPUVENDOR_IDT &&
1.17    jruoho 	    cpu_vendor != CPUVENDOR_INTEL)
 1.1    jruoho 		return val;
 1.1    jruoho
 1.1    jruoho 	/*
1.47    jruoho 	 * Basic SMP C-states (required for e.g. _CST).
 1.1    jruoho 	 */
 1.1    jruoho 	val |= ACPICPU_PDC_C_C1PT | ACPICPU_PDC_C_C2C3;
 1.1    jruoho
1.47    jruoho 	/*
1.47    jruoho 	 * Claim to support dependency coordination.
1.47    jruoho 	 */
1.47    jruoho 	val |= ACPICPU_PDC_P_SW | ACPICPU_PDC_C_SW | ACPICPU_PDC_T_SW;
1.47    jruoho
 1.1    jruoho         /*
 1.1    jruoho 	 * If MONITOR/MWAIT is available, announce
 1.1    jruoho 	 * support for native instructions in all C-states.
 1.1    jruoho 	 */
 1.1    jruoho         if ((ci->ci_feat_val[1] & CPUID2_MONITOR) != 0)
 1.1    jruoho 		val |= ACPICPU_PDC_C_C1_FFH | ACPICPU_PDC_C_C2C3_FFH;
 1.1    jruoho
 1.5    jruoho 	/*
1.10    jruoho 	 * Set native P- and T-states, if available.
 1.5    jruoho 	 */
 1.5    jruoho         if ((ci->ci_feat_val[1] & CPUID2_EST) != 0)
 1.5    jruoho 		val |= ACPICPU_PDC_P_FFH;
 1.5    jruoho
1.10    jruoho 	if ((ci->ci_feat_val[0] & CPUID_ACPI) != 0)
1.10    jruoho 		val |= ACPICPU_PDC_T_FFH;
1.10    jruoho
1.44    jruoho 	/*
1.44    jruoho 	 * Declare support for APERF and MPERF.
1.44    jruoho 	 */
1.44    jruoho 	if (cpuid_level >= 0x06) {
1.44    jruoho
1.44    jruoho 		x86_cpuid(0x00000006, regs);
1.44    jruoho
1.44    jruoho 		if ((regs[2] & CPUID_DSPM_HWF) != 0)
1.53    jruoho 			val |= ACPICPU_PDC_P_HWF;
1.44    jruoho 	}
1.44    jruoho
 1.1    jruoho 	return val;
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho uint32_t
1.43    jruoho acpicpu_md_flags(void)
 1.1    jruoho {
 1.1    jruoho 	struct cpu_info *ci = curcpu();
1.12    jruoho 	struct pci_attach_args pa;
1.18    jruoho 	uint32_t family, val = 0;
1.21    jruoho 	uint32_t regs[4];
 1.1    jruoho
1.38    jruoho 	if (acpi_md_ncpus() == 1)
 1.1    jruoho 		val |= ACPICPU_FLAG_C_BM;
 1.1    jruoho
 1.1    jruoho 	if ((ci->ci_feat_val[1] & CPUID2_MONITOR) != 0)
 1.5    jruoho 		val |= ACPICPU_FLAG_C_FFH;
 1.1    jruoho
1.39    jruoho 	/*
1.39    jruoho 	 * By default, assume that the local APIC timer
1.39    jruoho 	 * as well as TSC are stalled during C3 sleep.
1.39    jruoho 	 */
1.25    jruoho 	val |= ACPICPU_FLAG_C_APIC | ACPICPU_FLAG_C_TSC;
1.22    jruoho
 1.1    jruoho 	switch (cpu_vendor) {
 1.1    jruoho
1.17    jruoho 	case CPUVENDOR_IDT:
1.22    jruoho
1.22    jruoho 		if ((ci->ci_feat_val[1] & CPUID2_EST) != 0)
1.22    jruoho 			val |= ACPICPU_FLAG_P_FFH;
1.22    jruoho
1.22    jruoho 		if ((ci->ci_feat_val[0] & CPUID_ACPI) != 0)
1.22    jruoho 			val |= ACPICPU_FLAG_T_FFH;
1.22    jruoho
1.22    jruoho 		break;
1.22    jruoho
 1.1    jruoho 	case CPUVENDOR_INTEL:
1.17    jruoho
1.39    jruoho 		/*
1.39    jruoho 		 * Bus master control and arbitration should be
1.39    jruoho 		 * available on all supported Intel CPUs (to be
1.39    jruoho 		 * sure, this is double-checked later from the
1.39    jruoho 		 * firmware data). These flags imply that it is
1.39    jruoho 		 * not necessary to flush caches before C3 state.
1.39    jruoho 		 */
1.22    jruoho 		val |= ACPICPU_FLAG_C_BM | ACPICPU_FLAG_C_ARB;
1.22    jruoho
1.39    jruoho 		/*
1.39    jruoho 		 * Check if we can use "native", MSR-based,
1.39    jruoho 		 * access. If not, we have to resort to I/O.
1.39    jruoho 		 */
 1.5    jruoho 		if ((ci->ci_feat_val[1] & CPUID2_EST) != 0)
 1.5    jruoho 			val |= ACPICPU_FLAG_P_FFH;
 1.5    jruoho
1.10    jruoho 		if ((ci->ci_feat_val[0] & CPUID_ACPI) != 0)
1.10    jruoho 			val |= ACPICPU_FLAG_T_FFH;
1.10    jruoho
1.22    jruoho 		/*
1.25    jruoho 		 * Check whether MSR_APERF, MSR_MPERF, and Turbo
1.25    jruoho 		 * Boost are available. Also see if we might have
1.25    jruoho 		 * an invariant local APIC timer ("ARAT").
1.23    jruoho 		 */
1.23    jruoho 		if (cpuid_level >= 0x06) {
1.23    jruoho
1.44    jruoho 			x86_cpuid(0x00000006, regs);
1.23    jruoho
1.34    jruoho 			if ((regs[2] & CPUID_DSPM_HWF) != 0)
1.53    jruoho 				val |= ACPICPU_FLAG_P_HWF;
1.23    jruoho
1.34    jruoho 			if ((regs[0] & CPUID_DSPM_IDA) != 0)
1.24    jruoho 				val |= ACPICPU_FLAG_P_TURBO;
1.25    jruoho
1.34    jruoho 			if ((regs[0] & CPUID_DSPM_ARAT) != 0)
1.25    jruoho 				val &= ~ACPICPU_FLAG_C_APIC;
1.23    jruoho 		}
1.23    jruoho
1.23    jruoho 		/*
1.22    jruoho 		 * Detect whether TSC is invariant. If it is not,
1.22    jruoho 		 * we keep the flag to note that TSC will not run
1.22    jruoho 		 * at constant rate. Depending on the CPU, this may
1.22    jruoho 		 * affect P- and T-state changes, but especially
1.22    jruoho 		 * relevant are C-states; with variant TSC, states
1.24    jruoho 		 * larger than C1 may completely stop the counter.
1.22    jruoho 		 */
1.22    jruoho 		x86_cpuid(0x80000000, regs);
1.22    jruoho
1.22    jruoho 		if (regs[0] >= 0x80000007) {
1.22    jruoho
1.22    jruoho 			x86_cpuid(0x80000007, regs);
1.22    jruoho
1.32    jruoho 			if ((regs[3] & __BIT(8)) != 0)
1.22    jruoho 				val &= ~ACPICPU_FLAG_C_TSC;
1.22    jruoho 		}
1.22    jruoho
1.17    jruoho 		break;
1.12    jruoho
1.17    jruoho 	case CPUVENDOR_AMD:
1.17    jruoho
1.32    jruoho 		x86_cpuid(0x80000000, regs);
1.32    jruoho
1.32    jruoho 		if (regs[0] < 0x80000007)
1.32    jruoho 			break;
1.32    jruoho
1.32    jruoho 		x86_cpuid(0x80000007, regs);
1.32    jruoho
1.18    jruoho 		family = CPUID2FAMILY(ci->ci_signature);
1.18    jruoho
1.18    jruoho 		if (family == 0xf)
1.18    jruoho 			family += CPUID2EXTFAMILY(ci->ci_signature);
1.18    jruoho
1.32    jruoho     		switch (family) {
 1.1    jruoho
1.22    jruoho 		case 0x0f:
1.32    jruoho
1.45    jruoho 			/*
1.45    jruoho 			 * Evaluate support for the "FID/VID
1.45    jruoho 			 * algorithm" also used by powernow(4).
1.45    jruoho 			 */
1.32    jruoho 			if ((regs[3] & CPUID_APM_FID) == 0)
1.32    jruoho 				break;
1.32    jruoho
1.32    jruoho 			if ((regs[3] & CPUID_APM_VID) == 0)
1.32    jruoho 				break;
1.32    jruoho
1.32    jruoho 			val |= ACPICPU_FLAG_P_FFH | ACPICPU_FLAG_P_FIDVID;
1.32    jruoho 			break;
1.32    jruoho
1.17    jruoho 		case 0x10:
1.17    jruoho 		case 0x11:
1.40  jmcneill 			val |= ACPICPU_FLAG_C_C1E;
1.40  jmcneill 			/* FALLTHROUGH */
1.40  jmcneill
1.40  jmcneill 		case 0x14: /* AMD Fusion */
 1.1    jruoho
1.42    jruoho 			/*
1.42    jruoho 			 * Like with Intel, detect invariant TSC,
1.42    jruoho 			 * MSR-based P-states, and AMD's "turbo"
1.42    jruoho 			 * (Core Performance Boost), respectively.
1.42    jruoho 			 */
1.22    jruoho 			if ((regs[3] & CPUID_APM_TSC) != 0)
1.22    jruoho 				val &= ~ACPICPU_FLAG_C_TSC;
1.22    jruoho
1.21    jruoho 			if ((regs[3] & CPUID_APM_HWP) != 0)
1.17    jruoho 				val |= ACPICPU_FLAG_P_FFH;
1.21    jruoho
1.21    jruoho 			if ((regs[3] & CPUID_APM_CPB) != 0)
1.21    jruoho 				val |= ACPICPU_FLAG_P_TURBO;
1.35    jruoho
1.42    jruoho 			/*
1.42    jruoho 			 * Also check for APERF and MPERF,
1.42    jruoho 			 * first available in the family 10h.
1.42    jruoho 			 */
1.42    jruoho 			if (cpuid_level >= 0x06) {
1.42    jruoho
1.42    jruoho 				x86_cpuid(0x00000006, regs);
1.42    jruoho
1.44    jruoho 				if ((regs[2] & CPUID_DSPM_HWF) != 0)
1.53    jruoho 					val |= ACPICPU_FLAG_P_HWF;
1.42    jruoho 			}
1.42    jruoho
1.35    jruoho 			break;
1.17    jruoho 		}
 1.1    jruoho
 1.1    jruoho 		break;
 1.1    jruoho 	}
 1.1    jruoho
1.12    jruoho 	/*
1.12    jruoho 	 * There are several erratums for PIIX4.
1.12    jruoho 	 */
1.43    jruoho 	if (pci_find_device(&pa, acpicpu_md_quirk_piix4) != 0)
1.12    jruoho 		val |= ACPICPU_FLAG_PIIX4;
1.12    jruoho
 1.1    jruoho 	return val;
 1.1    jruoho }
 1.1    jruoho
1.12    jruoho static int
1.43    jruoho acpicpu_md_quirk_piix4(struct pci_attach_args *pa)
1.12    jruoho {
1.12    jruoho
1.12    jruoho 	/*
1.12    jruoho 	 * XXX: The pci_find_device(9) function only
1.12    jruoho 	 *	deals with attached devices. Change this
1.12    jruoho 	 *	to use something like pci_device_foreach().
1.12    jruoho 	 */
1.12    jruoho 	if (PCI_VENDOR(pa->pa_id) != PCI_VENDOR_INTEL)
1.12    jruoho 		return 0;
1.12    jruoho
1.12    jruoho 	if (PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_INTEL_82371AB_ISA ||
1.12    jruoho 	    PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_INTEL_82440MX_PMC)
1.12    jruoho 		return 1;
1.12    jruoho
1.12    jruoho 	return 0;
1.12    jruoho }
1.12    jruoho
1.35    jruoho void
1.43    jruoho acpicpu_md_quirk_c1e(void)
1.35    jruoho {
1.35    jruoho 	const uint64_t c1e = MSR_CMPHALT_SMI | MSR_CMPHALT_C1E;
1.35    jruoho 	uint64_t val;
1.35    jruoho
1.35    jruoho 	val = rdmsr(MSR_CMPHALT);
1.35    jruoho
1.35    jruoho 	if ((val & c1e) != 0)
1.35    jruoho 		wrmsr(MSR_CMPHALT, val & ~c1e);
1.35    jruoho }
1.35    jruoho
 1.1    jruoho int
1.43    jruoho acpicpu_md_cstate_start(struct acpicpu_softc *sc)
 1.1    jruoho {
 1.1    jruoho 	const size_t size = sizeof(native_idle_text);
1.31    jruoho 	struct acpicpu_cstate *cs;
1.31    jruoho 	bool ipi = false;
1.31    jruoho 	int i;
 1.1    jruoho
1.45    jruoho 	/*
1.45    jruoho 	 * Save the cpu_idle(9) loop used by default.
1.45    jruoho 	 */
 1.1    jruoho 	x86_cpu_idle_get(&native_idle, native_idle_text, size);
1.31    jruoho
1.31    jruoho 	for (i = 0; i < ACPI_C_STATE_COUNT; i++) {
1.31    jruoho
1.31    jruoho 		cs = &sc->sc_cstate[i];
1.31    jruoho
1.31    jruoho 		if (cs->cs_method == ACPICPU_C_STATE_HALT) {
1.31    jruoho 			ipi = true;
1.31    jruoho 			break;
1.31    jruoho 		}
1.31    jruoho 	}
1.31    jruoho
1.31    jruoho 	x86_cpu_idle_set(acpicpu_cstate_idle, "acpi", ipi);
 1.1    jruoho
 1.1    jruoho 	return 0;
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho int
1.43    jruoho acpicpu_md_cstate_stop(void)
 1.1    jruoho {
 1.4    jruoho 	uint64_t xc;
1.31    jruoho 	bool ipi;
 1.1    jruoho
1.31    jruoho 	ipi = (native_idle != x86_cpu_idle_halt) ? false : true;
1.31    jruoho 	x86_cpu_idle_set(native_idle, native_idle_text, ipi);
 1.1    jruoho
 1.4    jruoho 	/*
 1.4    jruoho 	 * Run a cross-call to ensure that all CPUs are
 1.4    jruoho 	 * out from the ACPI idle-loop before detachment.
 1.4    jruoho 	 */
 1.4    jruoho 	xc = xc_broadcast(0, (xcfunc_t)nullop, NULL, NULL);
 1.4    jruoho 	xc_wait(xc);
 1.1    jruoho
 1.1    jruoho 	return 0;
 1.1    jruoho }
 1.1    jruoho
 1.3    jruoho /*
1.31    jruoho  * Called with interrupts disabled.
1.31    jruoho  * Caller should enable interrupts after return.
 1.3    jruoho  */
 1.1    jruoho void
1.43    jruoho acpicpu_md_cstate_enter(int method, int state)
 1.1    jruoho {
 1.3    jruoho 	struct cpu_info *ci = curcpu();
 1.1    jruoho
 1.1    jruoho 	switch (method) {
 1.1    jruoho
 1.1    jruoho 	case ACPICPU_C_STATE_FFH:
 1.3    jruoho
 1.3    jruoho 		x86_enable_intr();
 1.3    jruoho 		x86_monitor(&ci->ci_want_resched, 0, 0);
 1.3    jruoho
1.31    jruoho 		if (__predict_false(ci->ci_want_resched != 0))
 1.3    jruoho 			return;
 1.3    jruoho
 1.1    jruoho 		x86_mwait((state - 1) << 4, 0);
 1.1    jruoho 		break;
 1.1    jruoho
 1.1    jruoho 	case ACPICPU_C_STATE_HALT:
 1.3    jruoho
1.31    jruoho 		if (__predict_false(ci->ci_want_resched != 0))
 1.3    jruoho 			return;
 1.3    jruoho
 1.1    jruoho 		x86_stihlt();
 1.1    jruoho 		break;
 1.1    jruoho 	}
 1.1    jruoho }
 1.5    jruoho
 1.5    jruoho int
1.41    jruoho acpicpu_md_pstate_start(struct acpicpu_softc *sc)
 1.5    jruoho {
1.57    jruoho 	uint64_t xc;
1.57    jruoho
1.57    jruoho 	/*
1.57    jruoho 	 * Reset the APERF and MPERF counters.
1.57    jruoho 	 */
1.57    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_P_HWF) != 0) {
1.57    jruoho 		xc = xc_broadcast(0, acpicpu_md_pstate_hwf_reset, NULL, NULL);
1.57    jruoho 		xc_wait(xc);
1.57    jruoho 	}
1.57    jruoho
1.19    jruoho 	return acpicpu_md_pstate_sysctl_init();
 1.5    jruoho }
 1.5    jruoho
 1.5    jruoho int
 1.5    jruoho acpicpu_md_pstate_stop(void)
 1.5    jruoho {
1.19    jruoho 	if (acpicpu_log != NULL)
1.19    jruoho 		sysctl_teardown(&acpicpu_log);
 1.5    jruoho
 1.5    jruoho 	return 0;
 1.5    jruoho }
 1.5    jruoho
 1.5    jruoho int
1.55    jruoho acpicpu_md_pstate_init(struct acpicpu_softc *sc)
 1.5    jruoho {
1.56    jruoho 	struct cpu_info *ci = sc->sc_ci;
1.15    jruoho 	struct acpicpu_pstate *ps, msr;
1.18    jruoho 	uint32_t family, i = 0;
1.57    jruoho 	uint64_t val;
1.13    jruoho
1.15    jruoho 	(void)memset(&msr, 0, sizeof(struct acpicpu_pstate));
1.13    jruoho
 1.5    jruoho 	switch (cpu_vendor) {
 1.5    jruoho
1.17    jruoho 	case CPUVENDOR_IDT:
 1.5    jruoho 	case CPUVENDOR_INTEL:
1.33    jruoho
1.33    jruoho 		/*
1.55    jruoho 		 * Make sure EST is enabled.
1.55    jruoho 		 */
1.55    jruoho 		if ((sc->sc_flags & ACPICPU_FLAG_P_FFH) != 0) {
1.55    jruoho
1.55    jruoho 			val = rdmsr(MSR_MISC_ENABLE);
1.55    jruoho
1.55    jruoho 			if ((val & MSR_MISC_ENABLE_EST) == 0) {
1.55    jruoho
1.55    jruoho 				val |= MSR_MISC_ENABLE_EST;
1.55    jruoho 				wrmsr(MSR_MISC_ENABLE, val);
1.55    jruoho 				val = rdmsr(MSR_MISC_ENABLE);
1.55    jruoho
1.55    jruoho 				if ((val & MSR_MISC_ENABLE_EST) == 0)
1.55    jruoho 					return ENOTTY;
1.55    jruoho 			}
1.55    jruoho 		}
1.55    jruoho
1.55    jruoho 		/*
1.33    jruoho 		 * If the so-called Turbo Boost is present,
1.33    jruoho 		 * the P0-state is always the "turbo state".
1.51    jruoho 		 * It is shown as the P1 frequency + 1 MHz.
1.33    jruoho 		 *
1.33    jruoho 		 * For discussion, see:
1.33    jruoho 		 *
1.33    jruoho 		 *	Intel Corporation: Intel Turbo Boost Technology
1.33    jruoho 		 *	in Intel Core(tm) Microarchitectures (Nehalem)
1.33    jruoho 		 *	Based Processors. White Paper, November 2008.
1.33    jruoho 		 */
1.55    jruoho 		if (sc->sc_pstate_count >= 2 &&
1.52    jruoho 		   (sc->sc_flags & ACPICPU_FLAG_P_TURBO) != 0) {
1.51    jruoho
1.51    jruoho 			ps = &sc->sc_pstate[0];
1.51    jruoho
1.51    jruoho 			if (ps->ps_freq == sc->sc_pstate[1].ps_freq + 1)
1.51    jruoho 				ps->ps_flags |= ACPICPU_FLAG_P_TURBO;
1.51    jruoho 		}
1.33    jruoho
1.15    jruoho 		msr.ps_control_addr = MSR_PERF_CTL;
1.15    jruoho 		msr.ps_control_mask = __BITS(0, 15);
1.15    jruoho
1.15    jruoho 		msr.ps_status_addr  = MSR_PERF_STATUS;
1.15    jruoho 		msr.ps_status_mask  = __BITS(0, 15);
1.13    jruoho 		break;
1.13    jruoho
1.13    jruoho 	case CPUVENDOR_AMD:
1.13    jruoho
1.33    jruoho 		if ((sc->sc_flags & ACPICPU_FLAG_P_FIDVID) != 0)
1.33    jruoho 			msr.ps_flags |= ACPICPU_FLAG_P_FIDVID;
1.33    jruoho
1.18    jruoho 		family = CPUID2FAMILY(ci->ci_signature);
1.18    jruoho
1.18    jruoho 		if (family == 0xf)
1.18    jruoho 			family += CPUID2EXTFAMILY(ci->ci_signature);
1.18    jruoho
1.18    jruoho 		switch (family) {
1.17    jruoho
1.32    jruoho 		case 0x0f:
1.32    jruoho 			msr.ps_control_addr = MSR_0FH_CONTROL;
1.32    jruoho 			msr.ps_status_addr  = MSR_0FH_STATUS;
1.32    jruoho 			break;
1.32    jruoho
1.17    jruoho 		case 0x10:
1.17    jruoho 		case 0x11:
1.40  jmcneill 		case 0x14: /* AMD Fusion */
1.17    jruoho 			msr.ps_control_addr = MSR_10H_CONTROL;
1.17    jruoho 			msr.ps_control_mask = __BITS(0, 2);
1.17    jruoho
1.17    jruoho 			msr.ps_status_addr  = MSR_10H_STATUS;
1.17    jruoho 			msr.ps_status_mask  = __BITS(0, 2);
1.17    jruoho 			break;
1.17    jruoho
1.17    jruoho 		default:
1.55    jruoho 			/*
1.55    jruoho 			 * If we have an unknown AMD CPU, rely on XPSS.
1.55    jruoho 			 */
1.17    jruoho 			if ((sc->sc_flags & ACPICPU_FLAG_P_XPSS) == 0)
1.17    jruoho 				return EOPNOTSUPP;
1.17    jruoho 		}
1.13    jruoho
1.13    jruoho 		break;
1.13    jruoho
1.13    jruoho 	default:
1.13    jruoho 		return ENODEV;
1.13    jruoho 	}
 1.5    jruoho
1.26    jruoho 	/*
1.26    jruoho 	 * Fill the P-state structures with MSR addresses that are
1.27    jruoho 	 * known to be correct. If we do not know the addresses,
1.27    jruoho 	 * leave the values intact. If a vendor uses XPSS, we do
1.39    jruoho 	 * not necessarily need to do anything to support new CPUs.
1.26    jruoho 	 */
1.15    jruoho 	while (i < sc->sc_pstate_count) {
1.15    jruoho
1.15    jruoho 		ps = &sc->sc_pstate[i];
1.15    jruoho
1.32    jruoho 		if (msr.ps_flags != 0)
1.32    jruoho 			ps->ps_flags |= msr.ps_flags;
1.32    jruoho
1.27    jruoho 		if (msr.ps_status_addr != 0)
1.15    jruoho 			ps->ps_status_addr = msr.ps_status_addr;
1.15    jruoho
1.27    jruoho 		if (msr.ps_status_mask != 0)
1.15    jruoho 			ps->ps_status_mask = msr.ps_status_mask;
1.15    jruoho
1.27    jruoho 		if (msr.ps_control_addr != 0)
1.15    jruoho 			ps->ps_control_addr = msr.ps_control_addr;
1.15    jruoho
1.27    jruoho 		if (msr.ps_control_mask != 0)
1.15    jruoho 			ps->ps_control_mask = msr.ps_control_mask;
1.15    jruoho
1.15    jruoho 		i++;
1.15    jruoho 	}
1.15    jruoho
1.15    jruoho 	return 0;
1.15    jruoho }
1.15    jruoho
1.55    jruoho /*
1.55    jruoho  * Read the IA32_APERF and IA32_MPERF counters. The first
1.55    jruoho  * increments at the rate of the fixed maximum frequency
1.55    jruoho  * configured during the boot, whereas APERF counts at the
1.55    jruoho  * rate of the actual frequency. Note that the MSRs must be
1.55    jruoho  * read without delay, and that only the ratio between
1.55    jruoho  * IA32_APERF and IA32_MPERF is architecturally defined.
1.55    jruoho  *
1.55    jruoho  * The function thus returns the percentage of the actual
1.55    jruoho  * frequency in terms of the maximum frequency of the calling
1.55    jruoho  * CPU since the last call. A value zero implies an error.
1.55    jruoho  *
1.55    jruoho  * For further details, refer to:
1.55    jruoho  *
1.55    jruoho  *	Intel Corporation: Intel 64 and IA-32 Architectures
1.55    jruoho  *	Software Developer's Manual. Section 13.2, Volume 3A:
1.55    jruoho  *	System Programming Guide, Part 1. July, 2008.
1.55    jruoho  *
1.55    jruoho  *	Advanced Micro Devices: BIOS and Kernel Developer's
1.55    jruoho  *	Guide (BKDG) for AMD Family 10h Processors. Section
1.55    jruoho  *	2.4.5, Revision 3.48, April 2010.
1.55    jruoho  */
1.41    jruoho uint8_t
1.56    jruoho acpicpu_md_pstate_hwf(struct cpu_info *ci)
1.41    jruoho {
1.55    jruoho 	struct acpicpu_softc *sc;
1.41    jruoho 	uint64_t aperf, mperf;
1.55    jruoho 	uint8_t rv = 0;
1.55    jruoho
1.55    jruoho 	sc = acpicpu_sc[ci->ci_acpiid];
1.41    jruoho
1.55    jruoho 	if (__predict_false(sc == NULL))
1.50    jruoho 		return 0;
1.50    jruoho
1.53    jruoho 	if (__predict_false((sc->sc_flags & ACPICPU_FLAG_P_HWF) == 0))
1.50    jruoho 		return 0;
1.41    jruoho
1.41    jruoho 	aperf = sc->sc_pstate_aperf;
1.41    jruoho 	mperf = sc->sc_pstate_mperf;
1.41    jruoho
1.56    jruoho 	x86_disable_intr();
1.56    jruoho
1.50    jruoho 	sc->sc_pstate_aperf = rdmsr(MSR_APERF);
1.50    jruoho 	sc->sc_pstate_mperf = rdmsr(MSR_MPERF);
1.41    jruoho
1.56    jruoho 	x86_enable_intr();
1.56    jruoho
1.41    jruoho 	aperf = sc->sc_pstate_aperf - aperf;
1.41    jruoho 	mperf = sc->sc_pstate_mperf - mperf;
1.41    jruoho
1.41    jruoho 	if (__predict_true(mperf != 0))
1.41    jruoho 		rv = (aperf * 100) / mperf;
1.41    jruoho
1.41    jruoho 	return rv;
1.41    jruoho }
1.41    jruoho
1.41    jruoho static void
1.56    jruoho acpicpu_md_pstate_hwf_reset(void *arg1, void *arg2)
1.41    jruoho {
1.56    jruoho 	struct cpu_info *ci = curcpu();
1.55    jruoho 	struct acpicpu_softc *sc;
1.41    jruoho
1.55    jruoho 	sc = acpicpu_sc[ci->ci_acpiid];
1.41    jruoho
1.55    jruoho 	if (__predict_false(sc == NULL))
1.55    jruoho 		return;
1.46    jruoho
1.56    jruoho 	x86_disable_intr();
1.46    jruoho
1.55    jruoho 	wrmsr(MSR_APERF, 0);
1.55    jruoho 	wrmsr(MSR_MPERF, 0);
1.41    jruoho
1.56    jruoho 	x86_enable_intr();
1.56    jruoho
1.41    jruoho 	sc->sc_pstate_aperf = 0;
1.41    jruoho 	sc->sc_pstate_mperf = 0;
1.41    jruoho }
1.41    jruoho
1.15    jruoho int
1.15    jruoho acpicpu_md_pstate_get(struct acpicpu_softc *sc, uint32_t *freq)
1.15    jruoho {
1.15    jruoho 	struct acpicpu_pstate *ps = NULL;
1.15    jruoho 	uint64_t val;
1.15    jruoho 	uint32_t i;
1.15    jruoho
1.32    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_P_FIDVID) != 0)
1.32    jruoho 		return acpicpu_md_pstate_fidvid_get(sc, freq);
1.32    jruoho
1.49    jruoho 	/*
1.49    jruoho 	 * Pick any P-state for the status address.
1.49    jruoho 	*/
1.15    jruoho 	for (i = 0; i < sc->sc_pstate_count; i++) {
1.15    jruoho
1.15    jruoho 		ps = &sc->sc_pstate[i];
1.15    jruoho
1.32    jruoho 		if (__predict_true(ps->ps_freq != 0))
1.15    jruoho 			break;
1.15    jruoho 	}
1.15    jruoho
1.15    jruoho 	if (__predict_false(ps == NULL))
1.17    jruoho 		return ENODEV;
1.15    jruoho
1.28    jruoho 	if (__predict_false(ps->ps_status_addr == 0))
1.13    jruoho 		return EINVAL;
 1.5    jruoho
1.13    jruoho 	val = rdmsr(ps->ps_status_addr);
 1.5    jruoho
1.28    jruoho 	if (__predict_true(ps->ps_status_mask != 0))
1.13    jruoho 		val = val & ps->ps_status_mask;
 1.5    jruoho
1.49    jruoho 	/*
1.49    jruoho 	 * Search for the value from known P-states.
1.49    jruoho 	 */
1.13    jruoho 	for (i = 0; i < sc->sc_pstate_count; i++) {
 1.5    jruoho
1.13    jruoho 		ps = &sc->sc_pstate[i];
 1.5    jruoho
1.32    jruoho 		if (__predict_false(ps->ps_freq == 0))
1.13    jruoho 			continue;
 1.5    jruoho
1.29    jruoho 		if (val == ps->ps_status) {
1.13    jruoho 			*freq = ps->ps_freq;
1.13    jruoho 			return 0;
1.13    jruoho 		}
 1.5    jruoho 	}
 1.5    jruoho
1.13    jruoho 	return EIO;
 1.5    jruoho }
 1.5    jruoho
 1.5    jruoho int
 1.5    jruoho acpicpu_md_pstate_set(struct acpicpu_pstate *ps)
 1.5    jruoho {
1.54    jruoho 	uint64_t val = 0;
 1.5    jruoho
1.37    jruoho 	if (__predict_false(ps->ps_control_addr == 0))
1.37    jruoho 		return EINVAL;
1.37    jruoho
1.32    jruoho 	if ((ps->ps_flags & ACPICPU_FLAG_P_FIDVID) != 0)
1.32    jruoho 		return acpicpu_md_pstate_fidvid_set(ps);
1.32    jruoho
1.54    jruoho 	/*
1.54    jruoho 	 * If the mask is set, do a read-modify-write.
1.54    jruoho 	 */
1.54    jruoho 	if (__predict_true(ps->ps_control_mask != 0)) {
1.54    jruoho 		val = rdmsr(ps->ps_control_addr);
1.54    jruoho 		val &= ~ps->ps_control_mask;
1.54    jruoho 	}
 1.5    jruoho
1.54    jruoho 	val |= ps->ps_control;
1.13    jruoho
1.49    jruoho 	wrmsr(ps->ps_control_addr, val);
1.49    jruoho 	DELAY(ps->ps_latency);
1.14    jruoho
1.49    jruoho 	return 0;
 1.5    jruoho }
1.10    jruoho
1.32    jruoho static int
1.32    jruoho acpicpu_md_pstate_fidvid_get(struct acpicpu_softc *sc, uint32_t *freq)
1.32    jruoho {
1.32    jruoho 	struct acpicpu_pstate *ps;
1.32    jruoho 	uint32_t fid, i, vid;
1.32    jruoho 	uint32_t cfid, cvid;
1.32    jruoho 	int rv;
1.32    jruoho
1.32    jruoho 	/*
1.32    jruoho 	 * AMD family 0Fh needs special treatment.
1.32    jruoho 	 * While it wants to use ACPI, it does not
1.32    jruoho 	 * comply with the ACPI specifications.
1.32    jruoho 	 */
1.32    jruoho 	rv = acpicpu_md_pstate_fidvid_read(&cfid, &cvid);
1.32    jruoho
1.32    jruoho 	if (rv != 0)
1.32    jruoho 		return rv;
1.32    jruoho
1.32    jruoho 	for (i = 0; i < sc->sc_pstate_count; i++) {
1.32    jruoho
1.32    jruoho 		ps = &sc->sc_pstate[i];
1.32    jruoho
1.32    jruoho 		if (__predict_false(ps->ps_freq == 0))
1.32    jruoho 			continue;
1.32    jruoho
1.32    jruoho 		fid = __SHIFTOUT(ps->ps_status, ACPI_0FH_STATUS_FID);
1.32    jruoho 		vid = __SHIFTOUT(ps->ps_status, ACPI_0FH_STATUS_VID);
1.32    jruoho
1.32    jruoho 		if (cfid == fid && cvid == vid) {
1.32    jruoho 			*freq = ps->ps_freq;
1.32    jruoho 			return 0;
1.32    jruoho 		}
1.32    jruoho 	}
1.32    jruoho
1.32    jruoho 	return EIO;
1.32    jruoho }
1.32    jruoho
1.32    jruoho static int
1.32    jruoho acpicpu_md_pstate_fidvid_set(struct acpicpu_pstate *ps)
1.32    jruoho {
1.32    jruoho 	const uint64_t ctrl = ps->ps_control;
1.32    jruoho 	uint32_t cfid, cvid, fid, i, irt;
1.32    jruoho 	uint32_t pll, vco_cfid, vco_fid;
1.32    jruoho 	uint32_t val, vid, vst;
1.32    jruoho 	int rv;
1.32    jruoho
1.32    jruoho 	rv = acpicpu_md_pstate_fidvid_read(&cfid, &cvid);
1.32    jruoho
1.32    jruoho 	if (rv != 0)
1.32    jruoho 		return rv;
1.32    jruoho
1.32    jruoho 	fid = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_FID);
1.32    jruoho 	vid = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_VID);
1.32    jruoho 	irt = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_IRT);
1.32    jruoho 	vst = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_VST);
1.32    jruoho 	pll = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_PLL);
1.32    jruoho
1.32    jruoho 	vst = vst * 20;
1.32    jruoho 	pll = pll * 1000 / 5;
1.32    jruoho 	irt = 10 * __BIT(irt);
1.32    jruoho
1.32    jruoho 	/*
1.32    jruoho 	 * Phase 1.
1.32    jruoho 	 */
1.32    jruoho 	while (cvid > vid) {
1.32    jruoho
1.32    jruoho 		val = 1 << __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_MVS);
1.32    jruoho 		val = (val > cvid) ? 0 : cvid - val;
1.32    jruoho
1.32    jruoho 		acpicpu_md_pstate_fidvid_write(cfid, val, 1, vst);
1.32    jruoho 		rv = acpicpu_md_pstate_fidvid_read(NULL, &cvid);
1.32    jruoho
1.32    jruoho 		if (rv != 0)
1.32    jruoho 			return rv;
1.32    jruoho 	}
1.32    jruoho
1.32    jruoho 	i = __SHIFTOUT(ctrl, ACPI_0FH_CONTROL_RVO);
1.32    jruoho
1.32    jruoho 	for (; i > 0 && cvid > 0; --i) {
1.32    jruoho
1.32    jruoho 		acpicpu_md_pstate_fidvid_write(cfid, cvid - 1, 1, vst);
1.32    jruoho 		rv = acpicpu_md_pstate_fidvid_read(NULL, &cvid);
1.32    jruoho
1.32    jruoho 		if (rv != 0)
1.32    jruoho 			return rv;
1.32    jruoho 	}
1.32    jruoho
1.32    jruoho 	/*
1.32    jruoho 	 * Phase 2.
1.32    jruoho 	 */
1.32    jruoho 	if (cfid != fid) {
1.32    jruoho
1.32    jruoho 		vco_fid  = FID_TO_VCO_FID(fid);
1.32    jruoho 		vco_cfid = FID_TO_VCO_FID(cfid);
1.32    jruoho
1.32    jruoho 		while (abs(vco_fid - vco_cfid) > 2) {
1.32    jruoho
1.32    jruoho 			if (fid <= cfid)
1.32    jruoho 				val = cfid - 2;
1.32    jruoho 			else {
1.32    jruoho 				val = (cfid > 6) ? cfid + 2 :
1.32    jruoho 				    FID_TO_VCO_FID(cfid) + 2;
1.32    jruoho 			}
1.32    jruoho
1.32    jruoho 			acpicpu_md_pstate_fidvid_write(val, cvid, pll, irt);
1.32    jruoho 			rv = acpicpu_md_pstate_fidvid_read(&cfid, NULL);
1.32    jruoho
1.32    jruoho 			if (rv != 0)
1.32    jruoho 				return rv;
1.32    jruoho
1.32    jruoho 			vco_cfid = FID_TO_VCO_FID(cfid);
1.32    jruoho 		}
1.32    jruoho
1.32    jruoho 		acpicpu_md_pstate_fidvid_write(fid, cvid, pll, irt);
1.32    jruoho 		rv = acpicpu_md_pstate_fidvid_read(&cfid, NULL);
1.32    jruoho
1.32    jruoho 		if (rv != 0)
1.32    jruoho 			return rv;
1.32    jruoho 	}
1.32    jruoho
1.32    jruoho 	/*
1.32    jruoho 	 * Phase 3.
1.32    jruoho 	 */
1.32    jruoho 	if (cvid != vid) {
1.32    jruoho
1.32    jruoho 		acpicpu_md_pstate_fidvid_write(cfid, vid, 1, vst);
1.32    jruoho 		rv = acpicpu_md_pstate_fidvid_read(NULL, &cvid);
1.32    jruoho
1.32    jruoho 		if (rv != 0)
1.32    jruoho 			return rv;
1.32    jruoho 	}
1.32    jruoho
1.32    jruoho 	if (cfid != fid || cvid != vid)
1.32    jruoho 		return EIO;
1.32    jruoho
1.32    jruoho 	return 0;
1.32    jruoho }
1.32    jruoho
1.32    jruoho static int
1.32    jruoho acpicpu_md_pstate_fidvid_read(uint32_t *cfid, uint32_t *cvid)
1.32    jruoho {
1.32    jruoho 	int i = ACPICPU_P_STATE_RETRY * 100;
1.32    jruoho 	uint64_t val;
1.32    jruoho
1.32    jruoho 	do {
1.32    jruoho 		val = rdmsr(MSR_0FH_STATUS);
1.32    jruoho
1.32    jruoho 	} while (__SHIFTOUT(val, MSR_0FH_STATUS_PENDING) != 0 && --i >= 0);
1.32    jruoho
1.32    jruoho 	if (i == 0)
1.32    jruoho 		return EAGAIN;
1.32    jruoho
1.32    jruoho 	if (cfid != NULL)
1.32    jruoho 		*cfid = __SHIFTOUT(val, MSR_0FH_STATUS_CFID);
1.32    jruoho
1.32    jruoho 	if (cvid != NULL)
1.32    jruoho 		*cvid = __SHIFTOUT(val, MSR_0FH_STATUS_CVID);
1.32    jruoho
1.32    jruoho 	return 0;
1.32    jruoho }
1.32    jruoho
1.32    jruoho static void
1.32    jruoho acpicpu_md_pstate_fidvid_write(uint32_t fid,
1.32    jruoho     uint32_t vid, uint32_t cnt, uint32_t tmo)
1.32    jruoho {
1.49    jruoho 	uint64_t val = 0;
1.32    jruoho
1.49    jruoho 	val |= __SHIFTIN(fid, MSR_0FH_CONTROL_FID);
1.49    jruoho 	val |= __SHIFTIN(vid, MSR_0FH_CONTROL_VID);
1.49    jruoho 	val |= __SHIFTIN(cnt, MSR_0FH_CONTROL_CNT);
1.49    jruoho 	val |= __SHIFTIN(0x1, MSR_0FH_CONTROL_CHG);
1.32    jruoho
1.49    jruoho 	wrmsr(MSR_0FH_CONTROL, val);
1.32    jruoho 	DELAY(tmo);
1.32    jruoho }
1.32    jruoho
1.10    jruoho int
1.10    jruoho acpicpu_md_tstate_get(struct acpicpu_softc *sc, uint32_t *percent)
1.10    jruoho {
1.10    jruoho 	struct acpicpu_tstate *ts;
1.14    jruoho 	uint64_t val;
1.10    jruoho 	uint32_t i;
1.10    jruoho
1.14    jruoho 	val = rdmsr(MSR_THERM_CONTROL);
1.10    jruoho
1.10    jruoho 	for (i = 0; i < sc->sc_tstate_count; i++) {
1.10    jruoho
1.10    jruoho 		ts = &sc->sc_tstate[i];
1.10    jruoho
1.10    jruoho 		if (ts->ts_percent == 0)
1.10    jruoho 			continue;
1.10    jruoho
1.29    jruoho 		if (val == ts->ts_status) {
1.10    jruoho 			*percent = ts->ts_percent;
1.10    jruoho 			return 0;
1.10    jruoho 		}
1.10    jruoho 	}
1.10    jruoho
1.10    jruoho 	return EIO;
1.10    jruoho }
1.10    jruoho
1.10    jruoho int
1.10    jruoho acpicpu_md_tstate_set(struct acpicpu_tstate *ts)
1.10    jruoho {
1.49    jruoho 	uint64_t val;
1.49    jruoho 	uint8_t i;
1.10    jruoho
1.49    jruoho 	val = ts->ts_control;
1.49    jruoho 	val = val & __BITS(1, 4);
1.10    jruoho
1.49    jruoho 	wrmsr(MSR_THERM_CONTROL, val);
1.10    jruoho
1.30    jruoho 	if (ts->ts_status == 0) {
1.30    jruoho 		DELAY(ts->ts_latency);
1.10    jruoho 		return 0;
1.30    jruoho 	}
1.10    jruoho
1.10    jruoho 	for (i = val = 0; i < ACPICPU_T_STATE_RETRY; i++) {
1.10    jruoho
1.14    jruoho 		val = rdmsr(MSR_THERM_CONTROL);
1.10    jruoho
1.29    jruoho 		if (val == ts->ts_status)
1.49    jruoho 			return 0;
1.10    jruoho
1.10    jruoho 		DELAY(ts->ts_latency);
1.10    jruoho 	}
1.10    jruoho
1.49    jruoho 	return EAGAIN;
1.10    jruoho }
1.19    jruoho
1.19    jruoho /*
1.19    jruoho  * A kludge for backwards compatibility.
1.19    jruoho  */
1.19    jruoho static int
1.19    jruoho acpicpu_md_pstate_sysctl_init(void)
1.19    jruoho {
1.19    jruoho 	const struct sysctlnode	*fnode, *mnode, *rnode;
1.19    jruoho 	const char *str;
1.19    jruoho 	int rv;
1.19    jruoho
1.19    jruoho 	switch (cpu_vendor) {
1.19    jruoho
1.19    jruoho 	case CPUVENDOR_IDT:
1.19    jruoho 	case CPUVENDOR_INTEL:
1.19    jruoho 		str = "est";
1.19    jruoho 		break;
1.19    jruoho
1.19    jruoho 	case CPUVENDOR_AMD:
1.19    jruoho 		str = "powernow";
1.19    jruoho 		break;
1.19    jruoho
1.19    jruoho 	default:
1.19    jruoho 		return ENODEV;
1.19    jruoho 	}
1.19    jruoho
1.19    jruoho
1.19    jruoho 	rv = sysctl_createv(&acpicpu_log, 0, NULL, &rnode,
1.19    jruoho 	    CTLFLAG_PERMANENT, CTLTYPE_NODE, "machdep", NULL,
1.19    jruoho 	    NULL, 0, NULL, 0, CTL_MACHDEP, CTL_EOL);
1.19    jruoho
1.19    jruoho 	if (rv != 0)
1.19    jruoho 		goto fail;
1.19    jruoho
1.19    jruoho 	rv = sysctl_createv(&acpicpu_log, 0, &rnode, &mnode,
1.19    jruoho 	    0, CTLTYPE_NODE, str, NULL,
1.19    jruoho 	    NULL, 0, NULL, 0, CTL_CREATE, CTL_EOL);
1.19    jruoho
1.19    jruoho 	if (rv != 0)
1.19    jruoho 		goto fail;
1.19    jruoho
1.19    jruoho 	rv = sysctl_createv(&acpicpu_log, 0, &mnode, &fnode,
1.19    jruoho 	    0, CTLTYPE_NODE, "frequency", NULL,
1.19    jruoho 	    NULL, 0, NULL, 0, CTL_CREATE, CTL_EOL);
1.19    jruoho
1.19    jruoho 	if (rv != 0)
1.19    jruoho 		goto fail;
1.19    jruoho
1.19    jruoho 	rv = sysctl_createv(&acpicpu_log, 0, &fnode, &rnode,
1.19    jruoho 	    CTLFLAG_READWRITE, CTLTYPE_INT, "target", NULL,
1.19    jruoho 	    acpicpu_md_pstate_sysctl_set, 0, NULL, 0, CTL_CREATE, CTL_EOL);
1.19    jruoho
1.19    jruoho 	if (rv != 0)
1.19    jruoho 		goto fail;
1.19    jruoho
1.19    jruoho 	rv = sysctl_createv(&acpicpu_log, 0, &fnode, &rnode,
1.19    jruoho 	    CTLFLAG_READONLY, CTLTYPE_INT, "current", NULL,
1.19    jruoho 	    acpicpu_md_pstate_sysctl_get, 0, NULL, 0, CTL_CREATE, CTL_EOL);
1.19    jruoho
1.19    jruoho 	if (rv != 0)
1.19    jruoho 		goto fail;
1.19    jruoho
1.19    jruoho 	rv = sysctl_createv(&acpicpu_log, 0, &fnode, &rnode,
1.19    jruoho 	    CTLFLAG_READONLY, CTLTYPE_STRING, "available", NULL,
1.19    jruoho 	    acpicpu_md_pstate_sysctl_all, 0, NULL, 0, CTL_CREATE, CTL_EOL);
1.19    jruoho
1.19    jruoho 	if (rv != 0)
1.19    jruoho 		goto fail;
1.19    jruoho
1.19    jruoho 	return 0;
1.19    jruoho
1.19    jruoho fail:
1.19    jruoho 	if (acpicpu_log != NULL) {
1.19    jruoho 		sysctl_teardown(&acpicpu_log);
1.19    jruoho 		acpicpu_log = NULL;
1.19    jruoho 	}
1.19    jruoho
1.19    jruoho 	return rv;
1.19    jruoho }
1.19    jruoho
1.19    jruoho static int
1.19    jruoho acpicpu_md_pstate_sysctl_get(SYSCTLFN_ARGS)
1.19    jruoho {
1.19    jruoho 	struct cpu_info *ci = curcpu();
1.19    jruoho 	struct sysctlnode node;
1.19    jruoho 	uint32_t freq;
1.19    jruoho 	int err;
1.19    jruoho
1.49    jruoho 	err = acpicpu_pstate_get(ci, &freq);
1.19    jruoho
1.19    jruoho 	if (err != 0)
1.19    jruoho 		return err;
1.19    jruoho
1.19    jruoho 	node = *rnode;
1.19    jruoho 	node.sysctl_data = &freq;
1.19    jruoho
1.19    jruoho 	err = sysctl_lookup(SYSCTLFN_CALL(&node));
1.19    jruoho
1.19    jruoho 	if (err != 0 || newp == NULL)
1.19    jruoho 		return err;
1.19    jruoho
1.19    jruoho 	return 0;
1.19    jruoho }
1.19    jruoho
1.19    jruoho static int
1.19    jruoho acpicpu_md_pstate_sysctl_set(SYSCTLFN_ARGS)
1.19    jruoho {
1.19    jruoho 	struct cpu_info *ci = curcpu();
1.19    jruoho 	struct sysctlnode node;
1.19    jruoho 	uint32_t freq;
1.19    jruoho 	int err;
1.19    jruoho
1.49    jruoho 	err = acpicpu_pstate_get(ci, &freq);
1.19    jruoho
1.19    jruoho 	if (err != 0)
1.19    jruoho 		return err;
1.19    jruoho
1.19    jruoho 	node = *rnode;
1.19    jruoho 	node.sysctl_data = &freq;
1.19    jruoho
1.19    jruoho 	err = sysctl_lookup(SYSCTLFN_CALL(&node));
1.19    jruoho
1.19    jruoho 	if (err != 0 || newp == NULL)
1.19    jruoho 		return err;
1.19    jruoho
1.49    jruoho 	acpicpu_pstate_set(ci, freq);
1.19    jruoho
1.19    jruoho 	return 0;
1.19    jruoho }
1.19    jruoho
1.19    jruoho static int
1.19    jruoho acpicpu_md_pstate_sysctl_all(SYSCTLFN_ARGS)
1.19    jruoho {
1.19    jruoho 	struct cpu_info *ci = curcpu();
1.19    jruoho 	struct acpicpu_softc *sc;
1.19    jruoho 	struct sysctlnode node;
1.19    jruoho 	char buf[1024];
1.19    jruoho 	size_t len;
1.19    jruoho 	uint32_t i;
1.19    jruoho 	int err;
1.19    jruoho
1.19    jruoho 	sc = acpicpu_sc[ci->ci_acpiid];
1.19    jruoho
1.19    jruoho 	if (sc == NULL)
1.19    jruoho 		return ENXIO;
1.19    jruoho
1.19    jruoho 	(void)memset(&buf, 0, sizeof(buf));
1.19    jruoho
1.19    jruoho 	mutex_enter(&sc->sc_mtx);
1.19    jruoho
1.19    jruoho 	for (len = 0, i = sc->sc_pstate_max; i < sc->sc_pstate_count; i++) {
1.19    jruoho
1.19    jruoho 		if (sc->sc_pstate[i].ps_freq == 0)
1.19    jruoho 			continue;
1.19    jruoho
1.19    jruoho 		len += snprintf(buf + len, sizeof(buf) - len, "%u%s",
1.19    jruoho 		    sc->sc_pstate[i].ps_freq,
1.19    jruoho 		    i < (sc->sc_pstate_count - 1) ? " " : "");
1.19    jruoho 	}
1.19    jruoho
1.19    jruoho 	mutex_exit(&sc->sc_mtx);
1.19    jruoho
1.19    jruoho 	node = *rnode;
1.19    jruoho 	node.sysctl_data = buf;
1.19    jruoho
1.19    jruoho 	err = sysctl_lookup(SYSCTLFN_CALL(&node));
1.19    jruoho
1.19    jruoho 	if (err != 0 || newp == NULL)
1.19    jruoho 		return err;
1.19    jruoho
1.19    jruoho 	return 0;
1.19    jruoho }
1.19    jruoho