dev/acpi/acpi_cpu_cstate.c

1.6    jruoho /* $NetBSD: acpi_cpu_cstate.c,v 1.6 2010/07/23 05:32:02 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>
1.6    jruoho __KERNEL_RCSID(0, "$NetBSD: acpi_cpu_cstate.c,v 1.6 2010/07/23 05:32:02 jruoho Exp $");
1.1    jruoho
1.1    jruoho #include <sys/param.h>
1.1    jruoho #include <sys/cpu.h>
1.1    jruoho #include <sys/device.h>
1.1    jruoho #include <sys/kernel.h>
1.1    jruoho #include <sys/once.h>
1.1    jruoho #include <sys/timetc.h>
1.1    jruoho
1.1    jruoho #include <dev/pci/pcivar.h>
1.1    jruoho #include <dev/pci/pcidevs.h>
1.1    jruoho
1.4    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 #include <dev/acpi/acpi_timer.h>
1.1    jruoho
1.1    jruoho #include <machine/acpi_machdep.h>
1.1    jruoho
1.4    jruoho #define _COMPONENT	 ACPI_BUS_COMPONENT
1.4    jruoho ACPI_MODULE_NAME	 ("acpi_cpu_cstate")
1.4    jruoho
1.1    jruoho /*
1.1    jruoho  * This is AML_RESOURCE_GENERIC_REGISTER,
1.1    jruoho  * included here separately for convenience.
1.1    jruoho  */
1.1    jruoho struct acpicpu_reg {
1.1    jruoho 	uint8_t		 reg_desc;
1.1    jruoho 	uint16_t	 reg_reslen;
1.1    jruoho 	uint8_t		 reg_spaceid;
1.1    jruoho 	uint8_t		 reg_bitwidth;
1.1    jruoho 	uint8_t		 reg_bitoffset;
1.1    jruoho 	uint8_t		 reg_accesssize;
1.1    jruoho 	uint64_t	 reg_addr;
1.1    jruoho } __packed;
1.1    jruoho
1.1    jruoho static void		 acpicpu_cstate_attach_print(struct acpicpu_softc *);
1.1    jruoho static ACPI_STATUS	 acpicpu_cstate_cst(struct acpicpu_softc *);
1.1    jruoho static ACPI_STATUS	 acpicpu_cstate_cst_add(struct acpicpu_softc *,
1.1    jruoho 						ACPI_OBJECT *);
1.1    jruoho static void		 acpicpu_cstate_cst_bios(void);
1.1    jruoho static ACPI_STATUS	 acpicpu_cstate_csd(ACPI_HANDLE, struct acpicpu_csd *);
1.1    jruoho static void		 acpicpu_cstate_fadt(struct acpicpu_softc *);
1.1    jruoho static void		 acpicpu_cstate_quirks(struct acpicpu_softc *);
1.1    jruoho static int		 acpicpu_cstate_quirks_piix4(struct pci_attach_args *);
1.1    jruoho static int		 acpicpu_cstate_latency(struct acpicpu_softc *);
1.1    jruoho static bool		 acpicpu_cstate_bm_check(void);
1.1    jruoho static void		 acpicpu_cstate_idle_enter(struct acpicpu_softc *,int);
1.1    jruoho
1.1    jruoho extern kmutex_t		      acpicpu_mtx;
1.1    jruoho extern struct acpicpu_softc **acpicpu_sc;
1.1    jruoho extern int		      acpi_suspended;
1.1    jruoho
1.1    jruoho void
1.1    jruoho acpicpu_cstate_attach(device_t self)
1.1    jruoho {
1.1    jruoho 	struct acpicpu_softc *sc = device_private(self);
1.1    jruoho 	ACPI_STATUS rv;
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Either use the preferred _CST or resort to FADT.
1.1    jruoho 	 */
1.1    jruoho 	rv = acpicpu_cstate_cst(sc);
1.1    jruoho
1.1    jruoho 	switch (rv) {
1.1    jruoho
1.1    jruoho 	case AE_OK:
1.6    jruoho 		sc->sc_flags |= ACPICPU_FLAG_C_CST;
1.1    jruoho 		acpicpu_cstate_cst_bios();
1.1    jruoho 		break;
1.1    jruoho
1.1    jruoho 	default:
1.6    jruoho 		sc->sc_flags |= ACPICPU_FLAG_C_FADT;
1.1    jruoho 		acpicpu_cstate_fadt(sc);
1.1    jruoho 		break;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	acpicpu_cstate_quirks(sc);
1.1    jruoho 	acpicpu_cstate_attach_print(sc);
1.1    jruoho }
1.1    jruoho
1.1    jruoho void
1.1    jruoho acpicpu_cstate_attach_print(struct acpicpu_softc *sc)
1.1    jruoho {
1.1    jruoho 	struct acpicpu_cstate *cs;
1.1    jruoho 	struct acpicpu_csd csd;
1.1    jruoho 	const char *method;
1.1    jruoho 	ACPI_STATUS rv;
1.1    jruoho 	int i;
1.1    jruoho
1.1    jruoho 	(void)memset(&csd, 0, sizeof(struct acpicpu_csd));
1.1    jruoho
1.1    jruoho 	rv = acpicpu_cstate_csd(sc->sc_node->ad_handle, &csd);
1.1    jruoho
1.1    jruoho 	if (ACPI_SUCCESS(rv)) {
1.1    jruoho 		aprint_debug_dev(sc->sc_dev, "C%u:  _CSD, "
1.1    jruoho 		    "domain 0x%02x / 0x%02x, type 0x%02x\n",
1.1    jruoho 		    csd.csd_index, csd.csd_domain,
1.1    jruoho 		    csd.csd_ncpu, csd.csd_coord);
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	aprint_debug_dev(sc->sc_dev, "Cx: %5s",
1.1    jruoho 	    (sc->sc_flags & ACPICPU_FLAG_C_FADT) != 0 ? "FADT" : "_CST");
1.1    jruoho
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_BM) != 0)
1.1    jruoho 		aprint_debug(", BM control");
1.1    jruoho
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_ARB) != 0)
1.1    jruoho 		aprint_debug(", BM arbitration");
1.1    jruoho
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_C1E) != 0)
1.1    jruoho 		aprint_debug(", C1E");
1.1    jruoho
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_NOC3) != 0)
1.1    jruoho 		aprint_debug(", C3 disabled (quirk)");
1.1    jruoho
1.1    jruoho 	aprint_debug("\n");
1.1    jruoho
1.1    jruoho 	for (i = 0; i < ACPI_C_STATE_COUNT; i++) {
1.1    jruoho
1.1    jruoho 		cs = &sc->sc_cstate[i];
1.1    jruoho
1.1    jruoho 		if (cs->cs_method == 0)
1.1    jruoho 			continue;
1.1    jruoho
1.1    jruoho 		switch (cs->cs_method) {
1.1    jruoho
1.1    jruoho 		case ACPICPU_C_STATE_HALT:
1.1    jruoho 			method = "HALT";
1.1    jruoho 			break;
1.1    jruoho
1.1    jruoho 		case ACPICPU_C_STATE_FFH:
1.1    jruoho 			method = "FFH";
1.1    jruoho 			break;
1.1    jruoho
1.1    jruoho 		case ACPICPU_C_STATE_SYSIO:
1.1    jruoho 			method = "SYSIO";
1.1    jruoho 			break;
1.1    jruoho
1.1    jruoho 		default:
1.1    jruoho 			panic("NOTREACHED");
1.1    jruoho 		}
1.1    jruoho
1.1    jruoho 		aprint_debug_dev(sc->sc_dev, "C%d: %5s, "
1.1    jruoho 		    "latency %4u, power %4u, addr 0x%06x\n", i, method,
1.1    jruoho 		    cs->cs_latency, cs->cs_power, (uint32_t)cs->cs_addr);
1.1    jruoho 	}
1.1    jruoho }
1.1    jruoho
1.1    jruoho int
1.1    jruoho acpicpu_cstate_detach(device_t self)
1.1    jruoho {
1.1    jruoho 	static ONCE_DECL(once_detach);
1.1    jruoho
1.1    jruoho 	return RUN_ONCE(&once_detach, acpicpu_md_idle_stop);
1.1    jruoho }
1.1    jruoho
1.1    jruoho int
1.1    jruoho acpicpu_cstate_start(device_t self)
1.1    jruoho {
1.1    jruoho 	struct acpicpu_softc *sc = device_private(self);
1.1    jruoho 	static ONCE_DECL(once_start);
1.1    jruoho 	static ONCE_DECL(once_save);
1.1    jruoho 	int rv;
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Save the existing idle-mechanism and claim the idle_loop(9).
1.1    jruoho 	 * This should be called after all ACPI CPUs have been attached.
1.1    jruoho 	 */
1.1    jruoho 	rv = RUN_ONCE(&once_save, acpicpu_md_idle_init);
1.1    jruoho
1.1    jruoho 	if (rv != 0)
1.1    jruoho 		return rv;
1.1    jruoho
1.5  christos 	rv = RUN_ONCE(&once_start, acpicpu_md_idle_start);
1.6    jruoho
1.5  christos 	if (rv == 0)
1.6    jruoho 		sc->sc_flags |= ACPICPU_FLAG_C;
1.6    jruoho
1.5  christos 	return rv;
1.1    jruoho }
1.1    jruoho
1.1    jruoho bool
1.1    jruoho acpicpu_cstate_suspend(device_t self)
1.1    jruoho {
1.1    jruoho
1.1    jruoho 	return true;
1.1    jruoho }
1.1    jruoho
1.1    jruoho bool
1.1    jruoho acpicpu_cstate_resume(device_t self)
1.1    jruoho {
1.1    jruoho 	static const ACPI_OSD_EXEC_CALLBACK func = acpicpu_cstate_callback;
1.1    jruoho 	struct acpicpu_softc *sc = device_private(self);
1.1    jruoho
1.1    jruoho 	KASSERT((sc->sc_flags & ACPICPU_FLAG_C) != 0);
1.1    jruoho
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_CST) != 0)
1.1    jruoho 		(void)AcpiOsExecute(OSL_NOTIFY_HANDLER, func, sc->sc_dev);
1.1    jruoho
1.1    jruoho 	return true;
1.1    jruoho }
1.1    jruoho
1.1    jruoho void
1.1    jruoho acpicpu_cstate_callback(void *aux)
1.1    jruoho {
1.1    jruoho 	struct acpicpu_softc *sc;
1.1    jruoho 	device_t self = aux;
1.1    jruoho
1.1    jruoho 	sc = device_private(self);
1.1    jruoho
1.1    jruoho 	KASSERT((sc->sc_flags & ACPICPU_FLAG_C) != 0);
1.1    jruoho
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_FADT) != 0) {
1.1    jruoho 		KASSERT((sc->sc_flags & ACPICPU_FLAG_C_CST) == 0);
1.1    jruoho 		return;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	(void)acpicpu_md_idle_stop();
1.1    jruoho 	(void)acpicpu_cstate_cst(sc);
1.1    jruoho 	(void)acpicpu_md_idle_start();
1.1    jruoho }
1.1    jruoho
1.1    jruoho static ACPI_STATUS
1.1    jruoho acpicpu_cstate_cst(struct acpicpu_softc *sc)
1.1    jruoho {
1.1    jruoho 	ACPI_OBJECT *elm, *obj;
1.1    jruoho 	ACPI_BUFFER buf;
1.1    jruoho 	ACPI_STATUS rv;
1.1    jruoho 	uint32_t i, n;
1.1    jruoho 	uint8_t count;
1.1    jruoho
1.1    jruoho 	rv = acpi_eval_struct(sc->sc_node->ad_handle, "_CST", &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 	elm = obj->Package.Elements;
1.1    jruoho
1.1    jruoho 	if (elm[0].Type != ACPI_TYPE_INTEGER) {
1.1    jruoho 		rv = AE_TYPE;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	n = elm[0].Integer.Value;
1.1    jruoho
1.1    jruoho 	if (n != obj->Package.Count - 1) {
1.1    jruoho 		rv = AE_BAD_VALUE;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	if (n > ACPI_C_STATES_MAX) {
1.1    jruoho 		rv = AE_LIMIT;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	(void)memset(sc->sc_cstate, 0,
1.1    jruoho 	    sizeof(*sc->sc_cstate) * ACPI_C_STATE_COUNT);
1.1    jruoho
1.3    jruoho 	CTASSERT(ACPI_STATE_C0 == 0 && ACPI_STATE_C1 == 1);
1.3    jruoho 	CTASSERT(ACPI_STATE_C2 == 2 && ACPI_STATE_C3 == 3);
1.3    jruoho
1.1    jruoho 	for (count = 0, i = 1; i <= n; i++) {
1.1    jruoho
1.1    jruoho 		elm = &obj->Package.Elements[i];
1.1    jruoho 		rv = acpicpu_cstate_cst_add(sc, elm);
1.1    jruoho
1.1    jruoho 		if (ACPI_SUCCESS(rv))
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 	if (ACPI_FAILURE(rv))
1.1    jruoho 		aprint_error_dev(sc->sc_dev, "failed to evaluate "
1.1    jruoho 		    "_CST: %s\n", AcpiFormatException(rv));
1.1    jruoho
1.1    jruoho 	return rv;
1.1    jruoho }
1.1    jruoho
1.1    jruoho static ACPI_STATUS
1.1    jruoho acpicpu_cstate_cst_add(struct acpicpu_softc *sc, ACPI_OBJECT *elm)
1.1    jruoho {
1.1    jruoho 	const struct acpicpu_object *ao = &sc->sc_object;
1.1    jruoho 	struct acpicpu_cstate *cs = sc->sc_cstate;
1.1    jruoho 	struct acpicpu_cstate state;
1.1    jruoho 	struct acpicpu_reg *reg;
1.1    jruoho 	ACPI_STATUS rv = AE_OK;
1.1    jruoho 	ACPI_OBJECT *obj;
1.1    jruoho 	uint32_t type;
1.1    jruoho
1.1    jruoho 	(void)memset(&state, 0, sizeof(*cs));
1.1    jruoho
1.1    jruoho 	if (elm->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 (elm->Package.Count != 4) {
1.1    jruoho 		rv = AE_LIMIT;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Type.
1.1    jruoho 	 */
1.1    jruoho 	obj = &elm->Package.Elements[1];
1.1    jruoho
1.1    jruoho 	if (obj->Type != ACPI_TYPE_INTEGER) {
1.1    jruoho 		rv = AE_TYPE;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	type = obj->Integer.Value;
1.1    jruoho
1.3    jruoho 	if (type < ACPI_STATE_C1 || type > ACPI_STATE_C3) {
1.3    jruoho 		rv = AE_TYPE;
1.3    jruoho 		goto out;
1.3    jruoho 	}
1.3    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Latency.
1.1    jruoho 	 */
1.1    jruoho 	obj = &elm->Package.Elements[2];
1.1    jruoho
1.1    jruoho 	if (obj->Type != ACPI_TYPE_INTEGER) {
1.1    jruoho 		rv = AE_TYPE;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	state.cs_latency = obj->Integer.Value;
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Power.
1.1    jruoho 	 */
1.1    jruoho 	obj = &elm->Package.Elements[3];
1.1    jruoho
1.1    jruoho 	if (obj->Type != ACPI_TYPE_INTEGER) {
1.1    jruoho 		rv = AE_TYPE;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	state.cs_power = obj->Integer.Value;
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Register.
1.1    jruoho 	 */
1.1    jruoho 	obj = &elm->Package.Elements[0];
1.1    jruoho
1.1    jruoho 	if (obj->Type != ACPI_TYPE_BUFFER) {
1.1    jruoho 		rv = AE_TYPE;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * "When specifically directed by the CPU manufacturer, the
1.1    jruoho 	 *  system firmware may define an interface as functional
1.1    jruoho 	 *  fixed hardware by supplying a special address space
1.1    jruoho 	 *  identifier, FfixedHW (0x7F), in the address space ID
1.1    jruoho 	 *  field for register definitions (ACPI 3.0, p. 46)".
1.1    jruoho 	 */
1.1    jruoho 	reg = (struct acpicpu_reg *)obj->Buffer.Pointer;
1.1    jruoho
1.1    jruoho 	switch (reg->reg_spaceid) {
1.1    jruoho
1.1    jruoho 	case ACPI_ADR_SPACE_SYSTEM_IO:
1.1    jruoho 		state.cs_method = ACPICPU_C_STATE_SYSIO;
1.1    jruoho
1.1    jruoho 		if (reg->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 		if (reg->reg_bitwidth != 8) {
1.1    jruoho 			rv = AE_AML_BAD_RESOURCE_LENGTH;
1.1    jruoho 			goto out;
1.1    jruoho 		}
1.1    jruoho
1.3    jruoho 		/*
1.3    jruoho 		 * Check only that the address is in the mapped space.
1.3    jruoho 		 * Systems are allowed to change it when operating
1.3    jruoho 		 * with _CST (see ACPI 4.0, pp. 94-95). For instance,
1.3    jruoho 		 * the offset of P_LVL3 may change depending on whether
1.3    jruoho 		 * acpiacad(4) is connected or disconnected.
1.3    jruoho 		 */
1.3    jruoho 		if (reg->reg_addr > ao->ao_pblkaddr + ao->ao_pblklen) {
1.3    jruoho 			rv = AE_BAD_ADDRESS;
1.3    jruoho 			goto out;
1.3    jruoho 		}
1.3    jruoho
1.3    jruoho 		state.cs_addr = reg->reg_addr;
1.1    jruoho 		break;
1.1    jruoho
1.1    jruoho 	case ACPI_ADR_SPACE_FIXED_HARDWARE:
1.1    jruoho 		state.cs_method = ACPICPU_C_STATE_FFH;
1.1    jruoho
1.1    jruoho 		switch (type) {
1.1    jruoho
1.1    jruoho 		case ACPI_STATE_C1:
1.1    jruoho
1.1    jruoho 			if ((sc->sc_flags & ACPICPU_FLAG_C_MWAIT) == 0)
1.1    jruoho 				state.cs_method = ACPICPU_C_STATE_HALT;
1.1    jruoho
1.1    jruoho 			break;
1.1    jruoho
1.1    jruoho 		default:
1.1    jruoho
1.1    jruoho 			if ((sc->sc_flags & ACPICPU_FLAG_C_MWAIT) == 0) {
1.1    jruoho 				rv = AE_AML_BAD_RESOURCE_VALUE;
1.1    jruoho 				goto out;
1.1    jruoho 			}
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
1.3    jruoho 	if (cs[type].cs_method != 0) {
1.1    jruoho 		rv = AE_ALREADY_EXISTS;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho #ifndef ACPICPU_ENABLE_C3
1.1    jruoho 	/*
1.1    jruoho 	 * XXX: The local APIC timer (as well as TSC) is typically
1.1    jruoho 	 *	stopped in C3, causing the timer interrupt to fire
1.1    jruoho 	 *	haphazardly, depending on how long the system slept.
1.1    jruoho 	 *	For now, we disable the C3 state unconditionally.
1.1    jruoho 	 */
1.3    jruoho 	if (type == ACPI_STATE_C3) {
1.1    jruoho 		sc->sc_flags |= ACPICPU_FLAG_C_NOC3;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho #endif
1.1    jruoho
1.3    jruoho 	cs[type].cs_addr = state.cs_addr;
1.3    jruoho 	cs[type].cs_power = state.cs_power;
1.3    jruoho 	cs[type].cs_latency = state.cs_latency;
1.3    jruoho 	cs[type].cs_method = state.cs_method;
1.1    jruoho
1.1    jruoho out:
1.1    jruoho 	if (ACPI_FAILURE(rv))
1.1    jruoho 		aprint_verbose_dev(sc->sc_dev,
1.1    jruoho 		    "invalid _CST: %s\n", AcpiFormatException(rv));
1.1    jruoho
1.1    jruoho 	return rv;
1.1    jruoho }
1.1    jruoho
1.1    jruoho static void
1.1    jruoho acpicpu_cstate_cst_bios(void)
1.1    jruoho {
1.1    jruoho 	const uint8_t val = AcpiGbl_FADT.CstControl;
1.1    jruoho 	const uint32_t addr = AcpiGbl_FADT.SmiCommand;
1.1    jruoho
1.1    jruoho 	if (addr == 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 static ACPI_STATUS
1.1    jruoho acpicpu_cstate_csd(ACPI_HANDLE hdl, struct acpicpu_csd *csd)
1.1    jruoho {
1.1    jruoho 	ACPI_OBJECT *elm, *obj;
1.1    jruoho 	ACPI_BUFFER buf;
1.1    jruoho 	ACPI_STATUS rv;
1.1    jruoho 	int i, n;
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Query the optional _CSD for heuristics.
1.1    jruoho 	 */
1.1    jruoho 	rv = acpi_eval_struct(hdl, "_CSD", &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 	n = obj->Package.Count;
1.1    jruoho
1.1    jruoho 	if (n != 6) {
1.1    jruoho 		rv = AE_LIMIT;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	elm = obj->Package.Elements;
1.1    jruoho
1.1    jruoho 	for (i = 0; i < n; i++) {
1.1    jruoho
1.1    jruoho 		if (elm[i].Type != ACPI_TYPE_INTEGER) {
1.1    jruoho 			rv = AE_TYPE;
1.1    jruoho 			goto out;
1.1    jruoho 		}
1.1    jruoho
1.1    jruoho 		KDASSERT((uint64_t)elm[i].Integer.Value <= UINT32_MAX);
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	if (elm[0].Integer.Value != 6 || elm[1].Integer.Value != 0) {
1.1    jruoho 		rv = AE_BAD_DATA;
1.1    jruoho 		goto out;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	csd->csd_domain = elm[2].Integer.Value;
1.1    jruoho 	csd->csd_coord  = elm[3].Integer.Value;
1.1    jruoho 	csd->csd_ncpu   = elm[4].Integer.Value;
1.1    jruoho 	csd->csd_index  = elm[5].Integer.Value;
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 void
1.1    jruoho acpicpu_cstate_fadt(struct acpicpu_softc *sc)
1.1    jruoho {
1.1    jruoho 	struct acpicpu_cstate *cs = sc->sc_cstate;
1.1    jruoho
1.1    jruoho 	(void)memset(cs, 0, sizeof(*cs) * ACPI_C_STATE_COUNT);
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * All x86 processors should support C1 (a.k.a. HALT).
1.1    jruoho 	 */
1.1    jruoho 	if ((AcpiGbl_FADT.Flags & ACPI_FADT_C1_SUPPORTED) != 0)
1.1    jruoho 		cs[ACPI_STATE_C1].cs_method = ACPICPU_C_STATE_HALT;
1.1    jruoho
1.1    jruoho 	if ((acpicpu_md_cpus_running() > 1) &&
1.1    jruoho 	    (AcpiGbl_FADT.Flags & ACPI_FADT_C2_MP_SUPPORTED) == 0)
1.1    jruoho 		return;
1.1    jruoho
1.1    jruoho 	cs[ACPI_STATE_C2].cs_method = ACPICPU_C_STATE_SYSIO;
1.1    jruoho 	cs[ACPI_STATE_C3].cs_method = ACPICPU_C_STATE_SYSIO;
1.1    jruoho
1.1    jruoho 	cs[ACPI_STATE_C2].cs_latency = AcpiGbl_FADT.C2Latency;
1.1    jruoho 	cs[ACPI_STATE_C3].cs_latency = AcpiGbl_FADT.C3Latency;
1.1    jruoho
1.1    jruoho 	cs[ACPI_STATE_C2].cs_addr = sc->sc_object.ao_pblkaddr + 4;
1.1    jruoho 	cs[ACPI_STATE_C3].cs_addr = sc->sc_object.ao_pblkaddr + 5;
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * The P_BLK length should always be 6. If it
1.1    jruoho 	 * is not, reduce functionality accordingly.
1.1    jruoho 	 * Sanity check also FADT's latency levels.
1.1    jruoho 	 */
1.1    jruoho 	if (sc->sc_object.ao_pblklen < 5)
1.1    jruoho 		cs[ACPI_STATE_C2].cs_method = 0;
1.1    jruoho
1.1    jruoho 	if (sc->sc_object.ao_pblklen < 6)
1.1    jruoho 		cs[ACPI_STATE_C3].cs_method = 0;
1.1    jruoho
1.3    jruoho 	CTASSERT(ACPICPU_C_C2_LATENCY_MAX == 100);
1.3    jruoho 	CTASSERT(ACPICPU_C_C3_LATENCY_MAX == 1000);
1.3    jruoho
1.1    jruoho 	if (AcpiGbl_FADT.C2Latency > ACPICPU_C_C2_LATENCY_MAX)
1.1    jruoho 		cs[ACPI_STATE_C2].cs_method = 0;
1.1    jruoho
1.1    jruoho 	if (AcpiGbl_FADT.C3Latency > ACPICPU_C_C3_LATENCY_MAX)
1.1    jruoho 		cs[ACPI_STATE_C3].cs_method = 0;
1.1    jruoho
1.1    jruoho #ifndef ACPICPU_ENABLE_C3
1.1    jruoho 	cs[ACPI_STATE_C3].cs_method = 0;
1.1    jruoho 	sc->sc_flags |= ACPICPU_FLAG_C_NOC3;	/* XXX. */
1.1    jruoho #endif
1.1    jruoho }
1.1    jruoho
1.1    jruoho static void
1.1    jruoho acpicpu_cstate_quirks(struct acpicpu_softc *sc)
1.1    jruoho {
1.1    jruoho 	const uint32_t reg = AcpiGbl_FADT.Pm2ControlBlock;
1.1    jruoho 	const uint32_t len = AcpiGbl_FADT.Pm2ControlLength;
1.1    jruoho 	struct pci_attach_args pa;
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Check bus master arbitration.
1.1    jruoho 	 */
1.1    jruoho 	if (reg != 0 && len != 0)
1.1    jruoho 		sc->sc_flags |= ACPICPU_FLAG_C_ARB;
1.1    jruoho 	else {
1.1    jruoho 		/*
1.1    jruoho 		 * Disable C3 entirely if WBINVD is not present.
1.1    jruoho 		 */
1.1    jruoho 		if ((AcpiGbl_FADT.Flags & ACPI_FADT_WBINVD) == 0)
1.1    jruoho 			sc->sc_flags |= ACPICPU_FLAG_C_NOC3;
1.1    jruoho 		else {
1.1    jruoho 			/*
1.1    jruoho 			 * If WBINVD is present, but not functioning
1.1    jruoho 			 * properly according to FADT, flush all CPU
1.1    jruoho 			 * caches before entering the C3 state.
1.1    jruoho 			 */
1.1    jruoho 			if ((AcpiGbl_FADT.Flags & ACPI_FADT_WBINVD_FLUSH) == 0)
1.1    jruoho 				sc->sc_flags &= ~ACPICPU_FLAG_C_BM;
1.1    jruoho 		}
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * There are several erratums for PIIX4.
1.1    jruoho 	 */
1.1    jruoho 	if (pci_find_device(&pa, acpicpu_cstate_quirks_piix4) != 0)
1.1    jruoho 		sc->sc_flags |= ACPICPU_FLAG_C_NOC3;
1.1    jruoho
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_NOC3) != 0)
1.1    jruoho 		sc->sc_cstate[ACPI_STATE_C3].cs_method = 0;
1.1    jruoho }
1.1    jruoho
1.1    jruoho static int
1.1    jruoho acpicpu_cstate_quirks_piix4(struct pci_attach_args *pa)
1.1    jruoho {
1.1    jruoho
1.1    jruoho 	if (PCI_VENDOR(pa->pa_id) != PCI_VENDOR_INTEL)
1.1    jruoho 		return 0;
1.1    jruoho
1.1    jruoho 	if (PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_INTEL_82371AB_ISA ||
1.1    jruoho 	    PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_INTEL_82440MX_PMC)
1.1    jruoho 		return 1;
1.1    jruoho
1.1    jruoho 	return 0;
1.1    jruoho }
1.1    jruoho
1.1    jruoho static int
1.1    jruoho acpicpu_cstate_latency(struct acpicpu_softc *sc)
1.1    jruoho {
1.1    jruoho 	static const uint32_t cs_factor = 3;
1.1    jruoho 	struct acpicpu_cstate *cs;
1.1    jruoho 	int i;
1.1    jruoho
1.1    jruoho 	for (i = ACPI_STATE_C3; i > 0; i--) {
1.1    jruoho
1.1    jruoho 		cs = &sc->sc_cstate[i];
1.1    jruoho
1.1    jruoho 		if (__predict_false(cs->cs_method == 0))
1.1    jruoho 			continue;
1.1    jruoho
1.1    jruoho 		/*
1.1    jruoho 		 * Choose a state if we have previously slept
1.1    jruoho 		 * longer than the worst case latency of the
1.1    jruoho 		 * state times an arbitrary multiplier.
1.1    jruoho 		 */
1.1    jruoho 		if (sc->sc_sleep > cs->cs_latency * cs_factor)
1.1    jruoho 			return i;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	return ACPI_STATE_C1;
1.1    jruoho }
1.1    jruoho
1.1    jruoho /*
1.1    jruoho  * The main idle loop.
1.1    jruoho  */
1.1    jruoho void
1.1    jruoho acpicpu_cstate_idle(void)
1.1    jruoho {
1.1    jruoho         struct cpu_info *ci = curcpu();
1.1    jruoho 	struct acpicpu_softc *sc;
1.1    jruoho 	int state;
1.1    jruoho
1.1    jruoho 	if (__predict_false(ci->ci_want_resched) != 0)
1.1    jruoho 		return;
1.1    jruoho
1.1    jruoho 	KASSERT(acpicpu_sc != NULL);
1.1    jruoho 	KASSERT(ci->ci_cpuid < maxcpus);
1.1    jruoho 	KASSERT(ci->ci_ilevel == IPL_NONE);
1.1    jruoho
1.1    jruoho 	if (__predict_false(acpi_suspended != 0)) {
1.1    jruoho 		acpicpu_md_idle_enter(0, 0);
1.1    jruoho 		return;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	sc = acpicpu_sc[ci->ci_cpuid];
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * If all CPUs do not have an ACPI counterpart,
1.1    jruoho 	 * the softc may be NULL. In this case use C1.
1.1    jruoho 	 */
1.1    jruoho 	if (__predict_false(sc == NULL)) {
1.1    jruoho 		acpicpu_md_idle_enter(0, 0);
1.1    jruoho 		return;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	acpi_md_OsDisableInterrupt();
1.1    jruoho 	state = acpicpu_cstate_latency(sc);
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Check for bus master activity. Note that
1.1    jruoho 	 * particularly usb(4) causes high activity,
1.1    jruoho 	 * which may prevent the use of C3 states.
1.1    jruoho 	 */
1.1    jruoho 	if (acpicpu_cstate_bm_check() != false) {
1.1    jruoho
1.1    jruoho 		state--;
1.1    jruoho
1.1    jruoho 		if (__predict_false(sc->sc_cstate[state].cs_method == 0))
1.1    jruoho 			state = ACPI_STATE_C1;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	KASSERT(state != ACPI_STATE_C0);
1.1    jruoho
1.1    jruoho 	if (state != ACPI_STATE_C3) {
1.1    jruoho 		acpicpu_cstate_idle_enter(sc, state);
1.1    jruoho 		return;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * On all recent (Intel) CPUs caches are shared
1.1    jruoho 	 * by CPUs and bus master control is required to
1.1    jruoho 	 * keep these coherent while in C3. Flushing the
1.1    jruoho 	 * CPU caches is only the last resort.
1.1    jruoho 	 */
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_BM) == 0)
1.1    jruoho 		ACPI_FLUSH_CPU_CACHE();
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Some chipsets may not return back to C0
1.1    jruoho 	 * from C3 if bus master wake is not enabled.
1.1    jruoho 	 */
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_BM) != 0)
1.1    jruoho 		(void)AcpiWriteBitRegister(ACPI_BITREG_BUS_MASTER_RLD, 1);
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * It may be necessary to disable bus master arbitration
1.1    jruoho 	 * to ensure that bus master cycles do not occur while
1.1    jruoho 	 * sleeping in C3 (see ACPI 4.0, section 8.1.4).
1.1    jruoho 	 */
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_ARB) != 0)
1.1    jruoho 		(void)AcpiWriteBitRegister(ACPI_BITREG_ARB_DISABLE, 1);
1.1    jruoho
1.1    jruoho 	acpicpu_cstate_idle_enter(sc, state);
1.1    jruoho
1.1    jruoho 	/*
1.1    jruoho 	 * Disable bus master wake and re-enable the arbiter.
1.1    jruoho 	 */
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_BM) != 0)
1.1    jruoho 		(void)AcpiWriteBitRegister(ACPI_BITREG_BUS_MASTER_RLD, 0);
1.1    jruoho
1.1    jruoho 	if ((sc->sc_flags & ACPICPU_FLAG_C_ARB) != 0)
1.1    jruoho 		(void)AcpiWriteBitRegister(ACPI_BITREG_ARB_DISABLE, 0);
1.1    jruoho }
1.1    jruoho
1.1    jruoho static void
1.1    jruoho acpicpu_cstate_idle_enter(struct acpicpu_softc *sc, int state)
1.1    jruoho {
1.1    jruoho 	struct acpicpu_cstate *cs = &sc->sc_cstate[state];
1.1    jruoho 	uint32_t end, start, val;
1.1    jruoho
1.1    jruoho 	start = acpitimer_read_safe(NULL);
1.1    jruoho
1.1    jruoho 	switch (cs->cs_method) {
1.1    jruoho
1.1    jruoho 	case ACPICPU_C_STATE_FFH:
1.1    jruoho 	case ACPICPU_C_STATE_HALT:
1.1    jruoho 		acpicpu_md_idle_enter(cs->cs_method, state);
1.1    jruoho 		break;
1.1    jruoho
1.1    jruoho 	case ACPICPU_C_STATE_SYSIO:
1.1    jruoho 		(void)AcpiOsReadPort(cs->cs_addr, &val, 8);
1.1    jruoho 		break;
1.1    jruoho
1.1    jruoho 	default:
1.1    jruoho 		acpicpu_md_idle_enter(0, 0);
1.1    jruoho 		break;
1.1    jruoho 	}
1.1    jruoho
1.1    jruoho 	cs->cs_stat++;
1.1    jruoho
1.1    jruoho 	end = acpitimer_read_safe(NULL);
1.1    jruoho 	sc->sc_sleep = hztoms(acpitimer_delta(end, start)) * 1000;
1.1    jruoho
1.1    jruoho 	acpi_md_OsEnableInterrupt();
1.1    jruoho }
1.1    jruoho
1.1    jruoho static bool
1.1    jruoho acpicpu_cstate_bm_check(void)
1.1    jruoho {
1.1    jruoho 	uint32_t val = 0;
1.1    jruoho 	ACPI_STATUS rv;
1.1    jruoho
1.1    jruoho 	rv = AcpiReadBitRegister(ACPI_BITREG_BUS_MASTER_STATUS, &val);
1.1    jruoho
1.1    jruoho 	if (ACPI_FAILURE(rv) || val == 0)
1.1    jruoho 		return false;
1.1    jruoho
1.1    jruoho 	(void)AcpiWriteBitRegister(ACPI_BITREG_BUS_MASTER_STATUS, 1);
1.1    jruoho
1.1    jruoho 	return true;
1.1    jruoho }