dev/acpi/acpi_cpu_pstate.c

1.34    jruoho /* $NetBSD: acpi_cpu_pstate.c,v 1.34 2010/10/28 04:27:40 jruoho Exp $ */
 1.1    jruoho
 1.1    jruoho /*-
 1.1    jruoho  * Copyright (c) 2010 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>
1.34    jruoho __KERNEL_RCSID(0, "$NetBSD: acpi_cpu_pstate.c,v 1.34 2010/10/28 04:27:40 jruoho Exp $");
 1.1    jruoho
 1.1    jruoho #include <sys/param.h>
 1.7    jruoho #include <sys/evcnt.h>
 1.1    jruoho #include <sys/kmem.h>
 1.1    jruoho #include <sys/once.h>
 1.1    jruoho
 1.1    jruoho #include <dev/acpi/acpireg.h>
 1.1    jruoho #include <dev/acpi/acpivar.h>
 1.1    jruoho #include <dev/acpi/acpi_cpu.h>
 1.1    jruoho
 1.1    jruoho #define _COMPONENT	 ACPI_BUS_COMPONENT
 1.1    jruoho ACPI_MODULE_NAME	 ("acpi_cpu_pstate")
 1.1    jruoho
 1.1    jruoho static void		 acpicpu_pstate_attach_print(struct acpicpu_softc *);
 1.7    jruoho static void		 acpicpu_pstate_attach_evcnt(struct acpicpu_softc *);
 1.7    jruoho static void		 acpicpu_pstate_detach_evcnt(struct acpicpu_softc *);
1.21    jruoho static ACPI_STATUS	 acpicpu_pstate_pss(struct acpicpu_softc *);
 1.1    jruoho static ACPI_STATUS	 acpicpu_pstate_pss_add(struct acpicpu_pstate *,
 1.1    jruoho 						ACPI_OBJECT *);
1.21    jruoho static ACPI_STATUS	 acpicpu_pstate_xpss(struct acpicpu_softc *);
1.21    jruoho static ACPI_STATUS	 acpicpu_pstate_xpss_add(struct acpicpu_pstate *,
1.21    jruoho 						 ACPI_OBJECT *);
 1.1    jruoho static ACPI_STATUS	 acpicpu_pstate_pct(struct acpicpu_softc *);
 1.1    jruoho static int		 acpicpu_pstate_max(struct acpicpu_softc *);
1.27    jruoho static int		 acpicpu_pstate_min(struct acpicpu_softc *);
 1.1    jruoho static void		 acpicpu_pstate_change(struct acpicpu_softc *);
1.28    jruoho static void		 acpicpu_pstate_reset(struct acpicpu_softc *);
 1.1    jruoho static void		 acpicpu_pstate_bios(void);
 1.1    jruoho
1.29    jruoho static uint32_t		 acpicpu_pstate_saved = 0;
1.25    jruoho
 1.1    jruoho void
 1.1    jruoho acpicpu_pstate_attach(device_t self)
 1.1    jruoho {
 1.1    jruoho 	struct acpicpu_softc *sc = device_private(self);
 1.3    jruoho 	const char *str;
1.27    jruoho 	ACPI_HANDLE tmp;
 1.1    jruoho 	ACPI_STATUS rv;
 1.1    jruoho
 1.1    jruoho 	rv = acpicpu_pstate_pss(sc);
 1.1    jruoho
 1.3    jruoho 	if (ACPI_FAILURE(rv)) {
 1.3    jruoho 		str = "_PSS";
 1.3    jruoho 		goto fail;
 1.3    jruoho 	}
 1.1    jruoho
1.21    jruoho 	/*
1.34    jruoho 	 * Append additional information from the
1.34    jruoho 	 * extended _PSS, if available. Note that
1.34    jruoho 	 * XPSS can not be used on Intel systems
1.34    jruoho 	 * that use either _PDC or _OSC.
1.21    jruoho 	 */
1.21    jruoho 	if (sc->sc_cap == 0) {
1.34    jruoho
1.21    jruoho 		rv = acpicpu_pstate_xpss(sc);
1.21    jruoho
1.21    jruoho 		if (ACPI_SUCCESS(rv))
1.21    jruoho 			sc->sc_flags |= ACPICPU_FLAG_P_XPSS;
1.21    jruoho 	}
1.21    jruoho
 1.1    jruoho 	rv = acpicpu_pstate_pct(sc);
 1.1    jruoho
 1.3    jruoho 	if (ACPI_FAILURE(rv)) {
 1.3    jruoho 		str = "_PCT";
 1.3    jruoho 		goto fail;
 1.3    jruoho 	}
 1.1    jruoho
1.24    jruoho 	/*
1.24    jruoho 	 * The ACPI 3.0 and 4.0 specifications mandate three
1.24    jruoho 	 * objects for P-states: _PSS, _PCT, and _PPC. A less
1.24    jruoho 	 * strict wording is however used in the earlier 2.0
1.24    jruoho 	 * standard, and some systems conforming to ACPI 2.0
1.24    jruoho 	 * do not have _PPC, the method for dynamic maximum.
1.24    jruoho 	 */
1.27    jruoho 	rv = AcpiGetHandle(sc->sc_node->ad_handle, "_PPC", &tmp);
1.27    jruoho
1.27    jruoho 	if (ACPI_FAILURE(rv))
1.27    jruoho 		aprint_debug_dev(self, "_PPC missing\n");
1.27    jruoho
1.30    jruoho 	/*
1.30    jruoho 	 * Employ the XPSS structure by filling
1.30    jruoho 	 * it with MD information required for FFH.
1.30    jruoho 	 */
1.30    jruoho 	rv = acpicpu_md_pstate_pss(sc);
1.30    jruoho
1.30    jruoho 	if (rv != 0) {
1.30    jruoho 		rv = AE_SUPPORT;
1.30    jruoho 		goto fail;
1.30    jruoho 	}
1.30    jruoho
 1.1    jruoho 	sc->sc_flags |= ACPICPU_FLAG_P;
 1.1    jruoho
 1.1    jruoho 	acpicpu_pstate_bios();
1.28    jruoho 	acpicpu_pstate_reset(sc);
 1.7    jruoho 	acpicpu_pstate_attach_evcnt(sc);
 1.1    jruoho 	acpicpu_pstate_attach_print(sc);
 1.3    jruoho
 1.3    jruoho 	return;
 1.3    jruoho
 1.3    jruoho fail:
1.15    jruoho 	switch (rv) {
1.15    jruoho
1.15    jruoho 	case AE_NOT_FOUND:
1.15    jruoho 		return;
1.15    jruoho
1.15    jruoho 	case AE_SUPPORT:
1.15    jruoho 		aprint_verbose_dev(sc->sc_dev, "P-states not supported\n");
1.15    jruoho 		return;
1.15    jruoho
1.15    jruoho 	default:
1.15    jruoho 		aprint_error_dev(sc->sc_dev, "failed to evaluate "
1.15    jruoho 		    "%s: %s\n", str, AcpiFormatException(rv));
1.15    jruoho 	}
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho static void
 1.1    jruoho acpicpu_pstate_attach_print(struct acpicpu_softc *sc)
 1.1    jruoho {
 1.1    jruoho 	const uint8_t method = sc->sc_pstate_control.reg_spaceid;
 1.1    jruoho 	struct acpicpu_pstate *ps;
1.12    jruoho 	static bool once = false;
 1.1    jruoho 	const char *str;
 1.1    jruoho 	uint32_t i;
 1.1    jruoho
1.12    jruoho 	if (once != false)
1.12    jruoho 		return;
1.12    jruoho
 1.8    jruoho 	str = (method != ACPI_ADR_SPACE_SYSTEM_IO) ? "FFH" : "I/O";
 1.1    jruoho
 1.1    jruoho 	for (i = 0; i < sc->sc_pstate_count; i++) {
 1.1    jruoho
 1.1    jruoho 		ps = &sc->sc_pstate[i];
 1.1    jruoho
 1.1    jruoho 		if (ps->ps_freq == 0)
 1.1    jruoho 			continue;
 1.1    jruoho
 1.8    jruoho 		aprint_debug_dev(sc->sc_dev, "P%d: %3s, "
1.15    jruoho 		    "lat %3u us, pow %5u mW, %4u MHz\n", i, str,
1.15    jruoho 		    ps->ps_latency, ps->ps_power, ps->ps_freq);
 1.1    jruoho 	}
1.12    jruoho
1.12    jruoho 	once = true;
 1.1    jruoho }
 1.1    jruoho
 1.7    jruoho static void
 1.7    jruoho acpicpu_pstate_attach_evcnt(struct acpicpu_softc *sc)
 1.7    jruoho {
 1.7    jruoho 	struct acpicpu_pstate *ps;
 1.7    jruoho 	uint32_t i;
 1.7    jruoho
 1.7    jruoho 	for (i = 0; i < sc->sc_pstate_count; i++) {
 1.7    jruoho
 1.7    jruoho 		ps = &sc->sc_pstate[i];
 1.7    jruoho
 1.7    jruoho 		if (ps->ps_freq == 0)
 1.7    jruoho 			continue;
 1.7    jruoho
 1.7    jruoho 		(void)snprintf(ps->ps_name, sizeof(ps->ps_name),
 1.7    jruoho 		    "P%u (%u MHz)", i, ps->ps_freq);
 1.7    jruoho
 1.7    jruoho 		evcnt_attach_dynamic(&ps->ps_evcnt, EVCNT_TYPE_MISC,
 1.7    jruoho 		    NULL, device_xname(sc->sc_dev), ps->ps_name);
 1.7    jruoho 	}
 1.7    jruoho }
 1.7    jruoho
 1.1    jruoho int
 1.1    jruoho acpicpu_pstate_detach(device_t self)
 1.1    jruoho {
 1.1    jruoho 	struct acpicpu_softc *sc = device_private(self);
 1.1    jruoho 	static ONCE_DECL(once_detach);
 1.1    jruoho 	size_t size;
 1.1    jruoho 	int rv;
 1.1    jruoho
 1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_P) == 0)
 1.1    jruoho 		return 0;
 1.1    jruoho
 1.1    jruoho 	rv = RUN_ONCE(&once_detach, acpicpu_md_pstate_stop);
 1.1    jruoho
 1.1    jruoho 	if (rv != 0)
 1.1    jruoho 		return rv;
 1.1    jruoho
 1.1    jruoho 	size = sc->sc_pstate_count * sizeof(*sc->sc_pstate);
 1.1    jruoho
 1.1    jruoho 	if (sc->sc_pstate != NULL)
 1.1    jruoho 		kmem_free(sc->sc_pstate, size);
 1.1    jruoho
 1.1    jruoho 	sc->sc_flags &= ~ACPICPU_FLAG_P;
 1.7    jruoho 	acpicpu_pstate_detach_evcnt(sc);
 1.1    jruoho
 1.1    jruoho 	return 0;
 1.1    jruoho }
 1.1    jruoho
 1.7    jruoho static void
 1.7    jruoho acpicpu_pstate_detach_evcnt(struct acpicpu_softc *sc)
 1.7    jruoho {
 1.7    jruoho 	struct acpicpu_pstate *ps;
 1.7    jruoho 	uint32_t i;
 1.7    jruoho
 1.7    jruoho 	for (i = 0; i < sc->sc_pstate_count; i++) {
 1.7    jruoho
 1.7    jruoho 		ps = &sc->sc_pstate[i];
 1.7    jruoho
 1.7    jruoho 		if (ps->ps_freq != 0)
 1.7    jruoho 			evcnt_detach(&ps->ps_evcnt);
 1.7    jruoho 	}
 1.7    jruoho }
 1.7    jruoho
1.24    jruoho void
 1.1    jruoho acpicpu_pstate_start(device_t self)
 1.1    jruoho {
 1.1    jruoho 	struct acpicpu_softc *sc = device_private(self);
1.25    jruoho 	struct acpicpu_pstate *ps;
1.25    jruoho 	uint32_t i;
1.24    jruoho 	int rv;
 1.1    jruoho
1.24    jruoho 	rv = acpicpu_md_pstate_start();
1.24    jruoho
1.25    jruoho 	if (rv != 0)
1.25    jruoho 		goto fail;
1.25    jruoho
1.25    jruoho 	/*
1.27    jruoho 	 * Initialize the state to P0.
1.25    jruoho 	 */
1.25    jruoho 	for (i = 0, rv = ENXIO; i < sc->sc_pstate_count; i++) {
1.25    jruoho
1.25    jruoho 		ps = &sc->sc_pstate[i];
1.25    jruoho
1.25    jruoho 		if (ps->ps_freq != 0) {
1.25    jruoho 			sc->sc_cold = false;
1.25    jruoho 			rv = acpicpu_pstate_set(sc, ps->ps_freq);
1.25    jruoho 			break;
1.25    jruoho 		}
1.25    jruoho 	}
1.25    jruoho
1.25    jruoho 	if (rv != 0)
1.25    jruoho 		goto fail;
1.25    jruoho
1.25    jruoho 	return;
 1.1    jruoho
1.25    jruoho fail:
1.24    jruoho 	sc->sc_flags &= ~ACPICPU_FLAG_P;
1.32    jruoho
1.32    jruoho 	if (rv == EEXIST) {
1.32    jruoho 		aprint_error_dev(self, "driver conflicts with existing one\n");
1.32    jruoho 		return;
1.32    jruoho 	}
1.32    jruoho
1.24    jruoho 	aprint_error_dev(self, "failed to start P-states (err %d)\n", rv);
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho bool
 1.1    jruoho acpicpu_pstate_suspend(device_t self)
 1.1    jruoho {
1.25    jruoho 	struct acpicpu_softc *sc = device_private(self);
1.25    jruoho 	struct acpicpu_pstate *ps = NULL;
1.25    jruoho 	int32_t i;
1.25    jruoho
1.29    jruoho 	mutex_enter(&sc->sc_mtx);
1.28    jruoho 	acpicpu_pstate_reset(sc);
1.29    jruoho 	mutex_exit(&sc->sc_mtx);
1.28    jruoho
1.25    jruoho 	if (acpicpu_pstate_saved != 0)
1.25    jruoho 		return true;
1.25    jruoho
1.25    jruoho 	/*
1.25    jruoho 	 * Following design notes for Windows, we set the highest
1.25    jruoho 	 * P-state when entering any of the system sleep states.
1.25    jruoho 	 * When resuming, the saved P-state will be restored.
1.25    jruoho 	 *
1.25    jruoho 	 *	Microsoft Corporation: Windows Native Processor
1.25    jruoho 	 *	Performance Control. Version 1.1a, November, 2002.
1.25    jruoho 	 */
1.25    jruoho 	for (i = sc->sc_pstate_count - 1; i >= 0; i--) {
1.25    jruoho
1.25    jruoho 		if (sc->sc_pstate[i].ps_freq != 0) {
1.25    jruoho 			ps = &sc->sc_pstate[i];
1.25    jruoho 			break;
1.25    jruoho 		}
1.25    jruoho 	}
1.25    jruoho
1.25    jruoho 	if (__predict_false(ps == NULL))
1.25    jruoho 		return true;
1.25    jruoho
1.25    jruoho 	mutex_enter(&sc->sc_mtx);
1.25    jruoho 	acpicpu_pstate_saved = sc->sc_pstate_current;
1.25    jruoho 	mutex_exit(&sc->sc_mtx);
1.25    jruoho
1.25    jruoho 	if (acpicpu_pstate_saved == ps->ps_freq)
1.25    jruoho 		return true;
1.25    jruoho
1.25    jruoho 	(void)acpicpu_pstate_set(sc, ps->ps_freq);
 1.1    jruoho
 1.1    jruoho 	return true;
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho bool
 1.1    jruoho acpicpu_pstate_resume(device_t self)
 1.1    jruoho {
1.25    jruoho 	struct acpicpu_softc *sc = device_private(self);
1.25    jruoho
1.25    jruoho 	if (acpicpu_pstate_saved != 0) {
1.25    jruoho 		(void)acpicpu_pstate_set(sc, acpicpu_pstate_saved);
1.25    jruoho 		acpicpu_pstate_saved = 0;
1.25    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	return true;
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho void
 1.1    jruoho acpicpu_pstate_callback(void *aux)
 1.1    jruoho {
 1.1    jruoho 	struct acpicpu_softc *sc;
 1.1    jruoho 	device_t self = aux;
 1.1    jruoho 	uint32_t old, new;
 1.1    jruoho
 1.1    jruoho 	sc = device_private(self);
 1.1    jruoho
 1.1    jruoho 	mutex_enter(&sc->sc_mtx);
 1.1    jruoho 	old = sc->sc_pstate_max;
 1.1    jruoho 	acpicpu_pstate_change(sc);
 1.1    jruoho 	new = sc->sc_pstate_max;
 1.1    jruoho 	mutex_exit(&sc->sc_mtx);
 1.1    jruoho
 1.1    jruoho 	if (old != new) {
 1.1    jruoho
1.14    jruoho 		aprint_debug_dev(sc->sc_dev, "maximum frequency "
1.14    jruoho 		    "changed from P%u (%u MHz) to P%u (%u MHz)\n",
1.14    jruoho 		    old, sc->sc_pstate[old].ps_freq, new,
1.14    jruoho 		    sc->sc_pstate[sc->sc_pstate_max].ps_freq);
1.14    jruoho #if 0
 1.1    jruoho 		/*
 1.1    jruoho 		 * If the maximum changed, proactively
 1.1    jruoho 		 * raise or lower the target frequency.
 1.1    jruoho 		 */
1.25    jruoho 		(void)acpicpu_pstate_set(sc, sc->sc_pstate[new].ps_freq);
 1.1    jruoho
1.14    jruoho #endif
 1.1    jruoho 	}
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho ACPI_STATUS
 1.1    jruoho acpicpu_pstate_pss(struct acpicpu_softc *sc)
 1.1    jruoho {
 1.1    jruoho 	struct acpicpu_pstate *ps;
 1.1    jruoho 	ACPI_OBJECT *obj;
 1.1    jruoho 	ACPI_BUFFER buf;
 1.1    jruoho 	ACPI_STATUS rv;
 1.1    jruoho 	uint32_t count;
 1.1    jruoho 	uint32_t i, j;
 1.1    jruoho
 1.1    jruoho 	rv = acpi_eval_struct(sc->sc_node->ad_handle, "_PSS", &buf);
 1.1    jruoho
 1.1    jruoho 	if (ACPI_FAILURE(rv))
 1.1    jruoho 		return rv;
 1.1    jruoho
 1.1    jruoho 	obj = buf.Pointer;
 1.1    jruoho
 1.1    jruoho 	if (obj->Type != ACPI_TYPE_PACKAGE) {
 1.1    jruoho 		rv = AE_TYPE;
 1.1    jruoho 		goto out;
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	sc->sc_pstate_count = obj->Package.Count;
 1.1    jruoho
 1.1    jruoho 	if (sc->sc_pstate_count == 0) {
 1.1    jruoho 		rv = AE_NOT_EXIST;
 1.1    jruoho 		goto out;
 1.1    jruoho 	}
 1.1    jruoho
 1.9    jruoho 	if (sc->sc_pstate_count > ACPICPU_P_STATE_MAX) {
 1.1    jruoho 		rv = AE_LIMIT;
 1.1    jruoho 		goto out;
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	sc->sc_pstate = kmem_zalloc(sc->sc_pstate_count *
 1.1    jruoho 	    sizeof(struct acpicpu_pstate), KM_SLEEP);
 1.1    jruoho
 1.1    jruoho 	if (sc->sc_pstate == NULL) {
 1.1    jruoho 		rv = AE_NO_MEMORY;
 1.1    jruoho 		goto out;
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	for (count = i = 0; i < sc->sc_pstate_count; i++) {
 1.1    jruoho
 1.1    jruoho 		ps = &sc->sc_pstate[i];
 1.1    jruoho 		rv = acpicpu_pstate_pss_add(ps, &obj->Package.Elements[i]);
 1.1    jruoho
1.13    jruoho 		if (ACPI_FAILURE(rv)) {
1.13    jruoho 			ps->ps_freq = 0;
 1.1    jruoho 			continue;
1.13    jruoho 		}
 1.1    jruoho
 1.1    jruoho 		for (j = 0; j < i; j++) {
 1.1    jruoho
 1.1    jruoho 			if (ps->ps_freq >= sc->sc_pstate[j].ps_freq) {
 1.1    jruoho 				ps->ps_freq = 0;
 1.1    jruoho 				break;
 1.1    jruoho 			}
 1.1    jruoho 		}
 1.1    jruoho
 1.1    jruoho 		if (ps->ps_freq != 0)
 1.1    jruoho 			count++;
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	rv = (count != 0) ? AE_OK : AE_NOT_EXIST;
 1.1    jruoho
 1.1    jruoho out:
 1.1    jruoho 	if (buf.Pointer != NULL)
 1.1    jruoho 		ACPI_FREE(buf.Pointer);
 1.1    jruoho
 1.1    jruoho 	return rv;
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho static ACPI_STATUS
 1.1    jruoho acpicpu_pstate_pss_add(struct acpicpu_pstate *ps, ACPI_OBJECT *obj)
 1.1    jruoho {
 1.1    jruoho 	ACPI_OBJECT *elm;
 1.1    jruoho 	int i;
 1.1    jruoho
 1.1    jruoho 	if (obj->Type != ACPI_TYPE_PACKAGE)
 1.1    jruoho 		return AE_TYPE;
 1.1    jruoho
 1.1    jruoho 	if (obj->Package.Count != 6)
 1.1    jruoho 		return AE_BAD_DATA;
 1.1    jruoho
 1.1    jruoho 	elm = obj->Package.Elements;
 1.1    jruoho
 1.1    jruoho 	for (i = 0; i < 6; i++) {
 1.1    jruoho
 1.1    jruoho 		if (elm[i].Type != ACPI_TYPE_INTEGER)
 1.1    jruoho 			return AE_TYPE;
 1.1    jruoho
 1.1    jruoho 		if (elm[i].Integer.Value > UINT32_MAX)
 1.1    jruoho 			return AE_AML_NUMERIC_OVERFLOW;
 1.1    jruoho 	}
 1.1    jruoho
1.21    jruoho 	ps->ps_freq       = elm[0].Integer.Value;
1.21    jruoho 	ps->ps_power      = elm[1].Integer.Value;
1.21    jruoho 	ps->ps_latency    = elm[2].Integer.Value;
1.21    jruoho 	ps->ps_latency_bm = elm[3].Integer.Value;
1.21    jruoho 	ps->ps_control    = elm[4].Integer.Value;
1.21    jruoho 	ps->ps_status     = elm[5].Integer.Value;
 1.1    jruoho
1.13    jruoho 	if (ps->ps_freq == 0 || ps->ps_freq > 9999)
1.13    jruoho 		return AE_BAD_DECIMAL_CONSTANT;
1.13    jruoho
 1.1    jruoho 	/*
 1.1    jruoho 	 * The latency is typically around 10 usec
 1.1    jruoho 	 * on Intel CPUs. Use that as the minimum.
 1.1    jruoho 	 */
 1.1    jruoho 	if (ps->ps_latency < 10)
 1.1    jruoho 		ps->ps_latency = 10;
 1.1    jruoho
 1.1    jruoho 	return AE_OK;
 1.1    jruoho }
 1.1    jruoho
1.21    jruoho static ACPI_STATUS
1.21    jruoho acpicpu_pstate_xpss(struct acpicpu_softc *sc)
1.21    jruoho {
1.34    jruoho 	struct acpicpu_pstate *ps;
1.21    jruoho 	ACPI_OBJECT *obj;
1.21    jruoho 	ACPI_BUFFER buf;
1.21    jruoho 	ACPI_STATUS rv;
1.34    jruoho 	uint32_t i = 0;
1.21    jruoho
1.21    jruoho 	rv = acpi_eval_struct(sc->sc_node->ad_handle, "XPSS", &buf);
1.21    jruoho
1.21    jruoho 	if (ACPI_FAILURE(rv))
1.21    jruoho 		return rv;
1.21    jruoho
1.21    jruoho 	obj = buf.Pointer;
1.21    jruoho
1.21    jruoho 	if (obj->Type != ACPI_TYPE_PACKAGE) {
1.21    jruoho 		rv = AE_TYPE;
1.21    jruoho 		goto out;
1.21    jruoho 	}
1.21    jruoho
1.34    jruoho 	if (obj->Package.Count != sc->sc_pstate_count) {
1.21    jruoho 		rv = AE_LIMIT;
1.21    jruoho 		goto out;
1.21    jruoho 	}
1.21    jruoho
1.34    jruoho 	while (i < sc->sc_pstate_count) {
1.21    jruoho
1.34    jruoho 		ps = &sc->sc_pstate[i];
1.34    jruoho 		acpicpu_pstate_xpss_add(ps, &obj->Package.Elements[i]);
1.21    jruoho
1.34    jruoho 		i++;
1.33  jmcneill 	}
1.21    jruoho
1.21    jruoho out:
1.21    jruoho 	if (buf.Pointer != NULL)
1.21    jruoho 		ACPI_FREE(buf.Pointer);
1.21    jruoho
1.21    jruoho 	return rv;
1.21    jruoho }
1.21    jruoho
1.21    jruoho static ACPI_STATUS
1.21    jruoho acpicpu_pstate_xpss_add(struct acpicpu_pstate *ps, ACPI_OBJECT *obj)
1.21    jruoho {
1.21    jruoho 	ACPI_OBJECT *elm;
1.21    jruoho 	int i;
1.21    jruoho
1.21    jruoho 	if (obj->Type != ACPI_TYPE_PACKAGE)
1.21    jruoho 		return AE_TYPE;
1.21    jruoho
1.21    jruoho 	if (obj->Package.Count != 8)
1.21    jruoho 		return AE_BAD_DATA;
1.21    jruoho
1.21    jruoho 	elm = obj->Package.Elements;
1.21    jruoho
1.21    jruoho 	for (i = 0; i < 4; i++) {
1.21    jruoho
1.21    jruoho 		if (elm[i].Type != ACPI_TYPE_INTEGER)
1.21    jruoho 			return AE_TYPE;
1.21    jruoho
1.21    jruoho 		if (elm[i].Integer.Value > UINT32_MAX)
1.21    jruoho 			return AE_AML_NUMERIC_OVERFLOW;
1.21    jruoho 	}
1.21    jruoho
1.21    jruoho 	for (; i < 8; i++) {
1.21    jruoho
1.21    jruoho 		if (elm[i].Type != ACPI_TYPE_BUFFER)
1.21    jruoho 			return AE_TYPE;
1.21    jruoho
1.33  jmcneill 		if (elm[i].Buffer.Length != 8)
1.21    jruoho 			return AE_LIMIT;
1.21    jruoho 	}
1.21    jruoho
1.34    jruoho 	/*
1.34    jruoho 	 * Only overwrite the elements that were
1.34    jruoho 	 * not available from the conventional _PSS.
1.34    jruoho 	 */
1.34    jruoho 	if (ps->ps_freq == 0)
1.34    jruoho 		ps->ps_freq = elm[0].Integer.Value;
1.34    jruoho
1.34    jruoho 	if (ps->ps_power == 0)
1.34    jruoho 		ps->ps_power = elm[1].Integer.Value;
1.34    jruoho
1.34    jruoho 	if (ps->ps_latency == 0)
1.34    jruoho 		ps->ps_latency = elm[2].Integer.Value;
1.34    jruoho
1.34    jruoho 	if (ps->ps_latency_bm == 0)
1.34    jruoho 		ps->ps_latency_bm = elm[3].Integer.Value;
1.34    jruoho
1.34    jruoho 	if (ps->ps_control == 0)
1.34    jruoho 		ps->ps_control = ACPI_GET64(elm[4].Buffer.Pointer);
1.34    jruoho
1.34    jruoho 	if (ps->ps_status == 0)
1.34    jruoho 		ps->ps_status = ACPI_GET64(elm[5].Buffer.Pointer);
1.21    jruoho
1.34    jruoho 	if (ps->ps_control_mask == 0)
1.34    jruoho 		ps->ps_control_mask = ACPI_GET64(elm[6].Buffer.Pointer);
1.21    jruoho
1.34    jruoho 	if (ps->ps_status_mask == 0)
1.34    jruoho 		ps->ps_status_mask = ACPI_GET64(elm[7].Buffer.Pointer);
1.21    jruoho
1.21    jruoho 	/*
1.21    jruoho 	 * The latency is often defined to be
1.21    jruoho 	 * zero on AMD systems. Raise that to 1.
1.21    jruoho 	 */
1.21    jruoho 	if (ps->ps_latency == 0)
1.21    jruoho 		ps->ps_latency = 1;
1.21    jruoho
1.21    jruoho 	ps->ps_flags |= ACPICPU_FLAG_P_XPSS;
1.21    jruoho
1.34    jruoho 	if (ps->ps_freq > 9999)
1.34    jruoho 		return AE_BAD_DECIMAL_CONSTANT;
1.34    jruoho
1.21    jruoho 	return AE_OK;
1.21    jruoho }
1.21    jruoho
 1.1    jruoho ACPI_STATUS
 1.1    jruoho acpicpu_pstate_pct(struct acpicpu_softc *sc)
 1.1    jruoho {
 1.1    jruoho 	static const size_t size = sizeof(struct acpicpu_reg);
 1.1    jruoho 	struct acpicpu_reg *reg[2];
1.21    jruoho 	struct acpicpu_pstate *ps;
 1.1    jruoho 	ACPI_OBJECT *elm, *obj;
 1.1    jruoho 	ACPI_BUFFER buf;
 1.1    jruoho 	ACPI_STATUS rv;
 1.1    jruoho 	uint8_t width;
1.21    jruoho 	uint32_t i;
 1.1    jruoho
 1.1    jruoho 	rv = acpi_eval_struct(sc->sc_node->ad_handle, "_PCT", &buf);
 1.1    jruoho
 1.1    jruoho 	if (ACPI_FAILURE(rv))
 1.1    jruoho 		return rv;
 1.1    jruoho
 1.1    jruoho 	obj = buf.Pointer;
 1.1    jruoho
 1.1    jruoho 	if (obj->Type != ACPI_TYPE_PACKAGE) {
 1.1    jruoho 		rv = AE_TYPE;
 1.1    jruoho 		goto out;
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	if (obj->Package.Count != 2) {
 1.1    jruoho 		rv = AE_LIMIT;
 1.1    jruoho 		goto out;
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	for (i = 0; i < 2; i++) {
 1.1    jruoho
 1.1    jruoho 		elm = &obj->Package.Elements[i];
 1.1    jruoho
 1.1    jruoho 		if (elm->Type != ACPI_TYPE_BUFFER) {
 1.1    jruoho 			rv = AE_TYPE;
 1.1    jruoho 			goto out;
 1.1    jruoho 		}
 1.1    jruoho
 1.1    jruoho 		if (size > elm->Buffer.Length) {
 1.1    jruoho 			rv = AE_AML_BAD_RESOURCE_LENGTH;
 1.1    jruoho 			goto out;
 1.1    jruoho 		}
 1.1    jruoho
 1.1    jruoho 		reg[i] = (struct acpicpu_reg *)elm->Buffer.Pointer;
 1.1    jruoho
 1.1    jruoho 		switch (reg[i]->reg_spaceid) {
 1.1    jruoho
 1.1    jruoho 		case ACPI_ADR_SPACE_SYSTEM_IO:
 1.1    jruoho
 1.1    jruoho 			if (reg[i]->reg_addr == 0) {
 1.1    jruoho 				rv = AE_AML_ILLEGAL_ADDRESS;
 1.1    jruoho 				goto out;
 1.1    jruoho 			}
 1.1    jruoho
 1.1    jruoho 			width = reg[i]->reg_bitwidth;
 1.1    jruoho
1.10    jruoho 			if (width + reg[i]->reg_bitoffset > 32) {
1.10    jruoho 				rv = AE_AML_BAD_RESOURCE_VALUE;
1.10    jruoho 				goto out;
1.10    jruoho 			}
1.10    jruoho
 1.1    jruoho 			if (width != 8 && width != 16 && width != 32) {
 1.4    jruoho 				rv = AE_AML_BAD_RESOURCE_VALUE;
 1.1    jruoho 				goto out;
 1.1    jruoho 			}
 1.1    jruoho
 1.1    jruoho 			break;
 1.1    jruoho
 1.1    jruoho 		case ACPI_ADR_SPACE_FIXED_HARDWARE:
 1.1    jruoho
1.21    jruoho 			if ((sc->sc_flags & ACPICPU_FLAG_P_XPSS) != 0) {
1.21    jruoho
1.21    jruoho 				if (reg[i]->reg_bitwidth != 64) {
1.21    jruoho 					rv = AE_AML_BAD_RESOURCE_VALUE;
1.21    jruoho 					goto out;
1.21    jruoho 				}
1.21    jruoho
1.21    jruoho 				if (reg[i]->reg_bitoffset != 0) {
1.21    jruoho 					rv = AE_AML_BAD_RESOURCE_VALUE;
1.21    jruoho 					goto out;
1.21    jruoho 				}
1.21    jruoho
1.21    jruoho 				break;
1.21    jruoho 			}
1.21    jruoho
 1.1    jruoho 			if ((sc->sc_flags & ACPICPU_FLAG_P_FFH) == 0) {
 1.4    jruoho 				rv = AE_SUPPORT;
 1.1    jruoho 				goto out;
 1.1    jruoho 			}
 1.1    jruoho
 1.1    jruoho 			break;
 1.1    jruoho
 1.1    jruoho 		default:
 1.1    jruoho 			rv = AE_AML_INVALID_SPACE_ID;
 1.1    jruoho 			goto out;
 1.1    jruoho 		}
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	if (reg[0]->reg_spaceid != reg[1]->reg_spaceid) {
 1.1    jruoho 		rv = AE_AML_INVALID_SPACE_ID;
 1.1    jruoho 		goto out;
 1.1    jruoho 	}
 1.1    jruoho
1.15    jruoho 	(void)memcpy(&sc->sc_pstate_control, reg[0], size);
1.15    jruoho 	(void)memcpy(&sc->sc_pstate_status,  reg[1], size);
 1.1    jruoho
1.22    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_P_XPSS) == 0)
1.22    jruoho 		goto out;
1.22    jruoho
1.22    jruoho 	/*
1.22    jruoho 	 * In XPSS the control address can not be zero,
1.26    jruoho 	 * but the status address may be. In this case,
1.26    jruoho 	 * comparable to T-states, we can ignore the status
1.22    jruoho 	 * check during the P-state (FFH) transition.
1.22    jruoho 	 */
1.22    jruoho 	if (sc->sc_pstate_control.reg_addr == 0) {
1.23  jmcneill 		rv = AE_AML_BAD_RESOURCE_LENGTH;
1.22    jruoho 		goto out;
1.22    jruoho 	}
1.22    jruoho
1.21    jruoho 	/*
1.21    jruoho 	 * If XPSS is present, copy the MSR addresses
1.21    jruoho 	 * to the P-state structures for convenience.
1.21    jruoho 	 */
1.21    jruoho 	for (i = 0; i < sc->sc_pstate_count; i++) {
1.21    jruoho
1.21    jruoho 		ps = &sc->sc_pstate[i];
1.21    jruoho
1.21    jruoho 		if (ps->ps_freq == 0)
1.21    jruoho 			continue;
1.21    jruoho
1.21    jruoho 		ps->ps_status_addr  = sc->sc_pstate_status.reg_addr;
1.21    jruoho 		ps->ps_control_addr = sc->sc_pstate_control.reg_addr;
1.21    jruoho 	}
1.21    jruoho
 1.1    jruoho out:
 1.1    jruoho 	if (buf.Pointer != NULL)
 1.1    jruoho 		ACPI_FREE(buf.Pointer);
 1.1    jruoho
 1.1    jruoho 	return rv;
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho static int
 1.1    jruoho acpicpu_pstate_max(struct acpicpu_softc *sc)
 1.1    jruoho {
 1.1    jruoho 	ACPI_INTEGER val;
 1.1    jruoho 	ACPI_STATUS rv;
 1.1    jruoho
 1.1    jruoho 	/*
 1.1    jruoho 	 * Evaluate the currently highest P-state that can be used.
 1.1    jruoho 	 * If available, we can use either this state or any lower
 1.1    jruoho 	 * power (i.e. higher numbered) state from the _PSS object.
1.27    jruoho 	 * Note that the return value must match the _OST parameter.
 1.1    jruoho 	 */
 1.1    jruoho 	rv = acpi_eval_integer(sc->sc_node->ad_handle, "_PPC", &val);
 1.1    jruoho
1.27    jruoho 	if (ACPI_SUCCESS(rv) && val < sc->sc_pstate_count) {
1.27    jruoho
1.27    jruoho 		if (sc->sc_pstate[val].ps_freq != 0) {
1.27    jruoho 			sc->sc_pstate_max = val;
1.27    jruoho 			return 0;
1.27    jruoho 		}
1.27    jruoho 	}
1.27    jruoho
1.27    jruoho 	return 1;
1.27    jruoho }
1.27    jruoho
1.27    jruoho static int
1.27    jruoho acpicpu_pstate_min(struct acpicpu_softc *sc)
1.27    jruoho {
1.27    jruoho 	ACPI_INTEGER val;
1.27    jruoho 	ACPI_STATUS rv;
 1.1    jruoho
1.27    jruoho 	/*
1.27    jruoho 	 * The _PDL object defines the minimum when passive cooling
1.27    jruoho 	 * is being performed. If available, we can use the returned
1.27    jruoho 	 * state or any higher power (i.e. lower numbered) state.
1.27    jruoho 	 */
1.27    jruoho 	rv = acpi_eval_integer(sc->sc_node->ad_handle, "_PDL", &val);
 1.1    jruoho
1.27    jruoho 	if (ACPI_SUCCESS(rv) && val < sc->sc_pstate_count) {
 1.1    jruoho
1.27    jruoho 		if (sc->sc_pstate[val].ps_freq == 0)
1.27    jruoho 			return 1;
 1.1    jruoho
1.27    jruoho 		if (val >= sc->sc_pstate_max) {
1.27    jruoho 			sc->sc_pstate_min = val;
1.27    jruoho 			return 0;
1.27    jruoho 		}
1.27    jruoho 	}
 1.1    jruoho
1.27    jruoho 	return 1;
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho static void
 1.1    jruoho acpicpu_pstate_change(struct acpicpu_softc *sc)
 1.1    jruoho {
1.27    jruoho 	static ACPI_STATUS rv = AE_OK;
 1.1    jruoho 	ACPI_OBJECT_LIST arg;
 1.1    jruoho 	ACPI_OBJECT obj[2];
 1.1    jruoho
1.28    jruoho 	acpicpu_pstate_reset(sc);
1.27    jruoho
 1.1    jruoho 	arg.Count = 2;
 1.1    jruoho 	arg.Pointer = obj;
 1.1    jruoho
 1.1    jruoho 	obj[0].Type = ACPI_TYPE_INTEGER;
 1.1    jruoho 	obj[1].Type = ACPI_TYPE_INTEGER;
 1.1    jruoho
 1.1    jruoho 	obj[0].Integer.Value = ACPICPU_P_NOTIFY;
 1.1    jruoho 	obj[1].Integer.Value = acpicpu_pstate_max(sc);
 1.1    jruoho
1.27    jruoho 	if (sc->sc_passive != false)
1.27    jruoho 		(void)acpicpu_pstate_min(sc);
1.27    jruoho
1.27    jruoho 	if (ACPI_FAILURE(rv))
1.27    jruoho 		return;
1.27    jruoho
1.27    jruoho 	rv = AcpiEvaluateObject(sc->sc_node->ad_handle, "_OST", &arg, NULL);
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho static void
1.28    jruoho acpicpu_pstate_reset(struct acpicpu_softc *sc)
1.28    jruoho {
1.28    jruoho
1.28    jruoho 	sc->sc_pstate_max = 0;
1.28    jruoho 	sc->sc_pstate_min = sc->sc_pstate_count - 1;
1.28    jruoho
1.28    jruoho }
1.28    jruoho
1.28    jruoho static void
 1.1    jruoho acpicpu_pstate_bios(void)
 1.1    jruoho {
 1.1    jruoho 	const uint8_t val = AcpiGbl_FADT.PstateControl;
 1.1    jruoho 	const uint32_t addr = AcpiGbl_FADT.SmiCommand;
 1.1    jruoho
1.19    jruoho 	if (addr == 0 || val == 0)
 1.1    jruoho 		return;
 1.1    jruoho
 1.1    jruoho 	(void)AcpiOsWritePort(addr, val, 8);
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho int
 1.1    jruoho acpicpu_pstate_get(struct acpicpu_softc *sc, uint32_t *freq)
 1.1    jruoho {
 1.1    jruoho 	const uint8_t method = sc->sc_pstate_control.reg_spaceid;
 1.1    jruoho 	struct acpicpu_pstate *ps = NULL;
 1.1    jruoho 	uint32_t i, val = 0;
 1.1    jruoho 	uint64_t addr;
 1.1    jruoho 	uint8_t width;
 1.1    jruoho 	int rv;
 1.1    jruoho
1.11    jruoho 	if (sc->sc_cold != false) {
1.11    jruoho 		rv = EBUSY;
1.11    jruoho 		goto fail;
1.11    jruoho 	}
1.11    jruoho
 1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_P) == 0) {
 1.1    jruoho 		rv = ENODEV;
 1.1    jruoho 		goto fail;
 1.1    jruoho 	}
 1.1    jruoho
1.14    jruoho 	mutex_enter(&sc->sc_mtx);
1.14    jruoho
 1.1    jruoho 	if (sc->sc_pstate_current != ACPICPU_P_STATE_UNKNOWN) {
 1.1    jruoho 		*freq = sc->sc_pstate_current;
1.14    jruoho 		mutex_exit(&sc->sc_mtx);
 1.1    jruoho 		return 0;
 1.1    jruoho 	}
 1.1    jruoho
1.14    jruoho 	mutex_exit(&sc->sc_mtx);
1.14    jruoho
 1.1    jruoho 	switch (method) {
 1.1    jruoho
 1.1    jruoho 	case ACPI_ADR_SPACE_FIXED_HARDWARE:
 1.1    jruoho
 1.1    jruoho 		rv = acpicpu_md_pstate_get(sc, freq);
 1.1    jruoho
 1.1    jruoho 		if (rv != 0)
 1.1    jruoho 			goto fail;
 1.1    jruoho
 1.1    jruoho 		break;
 1.1    jruoho
 1.1    jruoho 	case ACPI_ADR_SPACE_SYSTEM_IO:
 1.1    jruoho
 1.1    jruoho 		addr  = sc->sc_pstate_status.reg_addr;
 1.1    jruoho 		width = sc->sc_pstate_status.reg_bitwidth;
 1.1    jruoho
 1.1    jruoho 		(void)AcpiOsReadPort(addr, &val, width);
 1.1    jruoho
 1.1    jruoho 		if (val == 0) {
 1.1    jruoho 			rv = EIO;
 1.1    jruoho 			goto fail;
 1.1    jruoho 		}
 1.1    jruoho
 1.5    jruoho 		for (i = 0; i < sc->sc_pstate_count; i++) {
 1.1    jruoho
 1.1    jruoho 			if (sc->sc_pstate[i].ps_freq == 0)
 1.1    jruoho 				continue;
 1.1    jruoho
 1.1    jruoho 			if (val == sc->sc_pstate[i].ps_status) {
 1.1    jruoho 				ps = &sc->sc_pstate[i];
 1.1    jruoho 				break;
 1.1    jruoho 			}
 1.1    jruoho 		}
 1.1    jruoho
1.15    jruoho 		if (__predict_false(ps == NULL)) {
 1.1    jruoho 			rv = EIO;
 1.1    jruoho 			goto fail;
 1.1    jruoho 		}
 1.1    jruoho
 1.1    jruoho 		*freq = ps->ps_freq;
 1.1    jruoho 		break;
 1.1    jruoho
 1.1    jruoho 	default:
 1.1    jruoho 		rv = ENOTTY;
 1.1    jruoho 		goto fail;
 1.1    jruoho 	}
 1.1    jruoho
1.14    jruoho 	mutex_enter(&sc->sc_mtx);
 1.1    jruoho 	sc->sc_pstate_current = *freq;
1.14    jruoho 	mutex_exit(&sc->sc_mtx);
 1.1    jruoho
 1.1    jruoho 	return 0;
 1.1    jruoho
 1.1    jruoho fail:
 1.1    jruoho 	aprint_error_dev(sc->sc_dev, "failed "
 1.1    jruoho 	    "to get frequency (err %d)\n", rv);
 1.1    jruoho
1.14    jruoho 	mutex_enter(&sc->sc_mtx);
 1.1    jruoho 	*freq = sc->sc_pstate_current = ACPICPU_P_STATE_UNKNOWN;
1.14    jruoho 	mutex_exit(&sc->sc_mtx);
 1.1    jruoho
 1.1    jruoho 	return rv;
 1.1    jruoho }
 1.1    jruoho
 1.1    jruoho int
 1.1    jruoho acpicpu_pstate_set(struct acpicpu_softc *sc, uint32_t freq)
 1.1    jruoho {
 1.1    jruoho 	const uint8_t method = sc->sc_pstate_control.reg_spaceid;
 1.1    jruoho 	struct acpicpu_pstate *ps = NULL;
 1.1    jruoho 	uint32_t i, val;
 1.1    jruoho 	uint64_t addr;
 1.1    jruoho 	uint8_t width;
 1.1    jruoho 	int rv;
 1.1    jruoho
1.11    jruoho 	if (sc->sc_cold != false) {
1.11    jruoho 		rv = EBUSY;
1.11    jruoho 		goto fail;
1.11    jruoho 	}
1.11    jruoho
 1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_P) == 0) {
 1.1    jruoho 		rv = ENODEV;
 1.1    jruoho 		goto fail;
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	mutex_enter(&sc->sc_mtx);
 1.1    jruoho
1.31    jruoho 	if (sc->sc_pstate_current == freq) {
1.31    jruoho 		mutex_exit(&sc->sc_mtx);
1.31    jruoho 		return 0;
1.31    jruoho 	}
1.31    jruoho
1.27    jruoho 	for (i = sc->sc_pstate_max; i <= sc->sc_pstate_min; i++) {
 1.1    jruoho
 1.1    jruoho 		if (sc->sc_pstate[i].ps_freq == 0)
 1.1    jruoho 			continue;
 1.1    jruoho
 1.1    jruoho 		if (sc->sc_pstate[i].ps_freq == freq) {
 1.1    jruoho 			ps = &sc->sc_pstate[i];
 1.1    jruoho 			break;
 1.1    jruoho 		}
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	mutex_exit(&sc->sc_mtx);
 1.1    jruoho
1.15    jruoho 	if (__predict_false(ps == NULL)) {
 1.1    jruoho 		rv = EINVAL;
 1.1    jruoho 		goto fail;
 1.1    jruoho 	}
 1.1    jruoho
 1.1    jruoho 	switch (method) {
 1.1    jruoho
 1.1    jruoho 	case ACPI_ADR_SPACE_FIXED_HARDWARE:
 1.1    jruoho
 1.1    jruoho 		rv = acpicpu_md_pstate_set(ps);
 1.1    jruoho
 1.1    jruoho 		if (rv != 0)
 1.1    jruoho 			goto fail;
 1.1    jruoho
 1.1    jruoho 		break;
 1.1    jruoho
 1.1    jruoho 	case ACPI_ADR_SPACE_SYSTEM_IO:
 1.1    jruoho
 1.1    jruoho 		addr  = sc->sc_pstate_control.reg_addr;
 1.1    jruoho 		width = sc->sc_pstate_control.reg_bitwidth;
 1.1    jruoho
 1.1    jruoho 		(void)AcpiOsWritePort(addr, ps->ps_control, width);
 1.1    jruoho
 1.1    jruoho 		addr  = sc->sc_pstate_status.reg_addr;
 1.1    jruoho 		width = sc->sc_pstate_status.reg_bitwidth;
 1.1    jruoho
 1.1    jruoho 		/*
 1.1    jruoho 		 * Some systems take longer to respond
 1.1    jruoho 		 * than the reported worst-case latency.
 1.1    jruoho 		 */
 1.1    jruoho 		for (i = val = 0; i < ACPICPU_P_STATE_RETRY; i++) {
 1.1    jruoho
 1.1    jruoho 			(void)AcpiOsReadPort(addr, &val, width);
 1.1    jruoho
 1.1    jruoho 			if (val == ps->ps_status)
 1.1    jruoho 				break;
 1.1    jruoho
 1.1    jruoho 			DELAY(ps->ps_latency);
 1.1    jruoho 		}
 1.1    jruoho
 1.1    jruoho 		if (i == ACPICPU_P_STATE_RETRY) {
 1.1    jruoho 			rv = EAGAIN;
 1.1    jruoho 			goto fail;
 1.1    jruoho 		}
 1.1    jruoho
 1.1    jruoho 		break;
 1.1    jruoho
 1.1    jruoho 	default:
 1.1    jruoho 		rv = ENOTTY;
 1.1    jruoho 		goto fail;
 1.1    jruoho 	}
 1.1    jruoho
1.16    jruoho 	mutex_enter(&sc->sc_mtx);
 1.7    jruoho 	ps->ps_evcnt.ev_count++;
 1.1    jruoho 	sc->sc_pstate_current = freq;
1.14    jruoho 	mutex_exit(&sc->sc_mtx);
 1.1    jruoho
 1.1    jruoho 	return 0;
 1.1    jruoho
 1.1    jruoho fail:
 1.1    jruoho 	aprint_error_dev(sc->sc_dev, "failed to set "
 1.1    jruoho 	    "frequency to %u (err %d)\n", freq, rv);
 1.1    jruoho
1.14    jruoho 	mutex_enter(&sc->sc_mtx);
 1.1    jruoho 	sc->sc_pstate_current = ACPICPU_P_STATE_UNKNOWN;
1.14    jruoho 	mutex_exit(&sc->sc_mtx);
 1.1    jruoho
 1.1    jruoho 	return rv;
 1.1    jruoho }