powerpc/booke/e500_intr.c

1.37      flxd /*	$NetBSD: e500_intr.c,v 1.37 2018/01/26 17:49:55 flxd Exp $	*/
 1.2      matt /*-
 1.2      matt  * Copyright (c) 2010, 2011 The NetBSD Foundation, Inc.
 1.2      matt  * All rights reserved.
 1.2      matt  *
 1.2      matt  * This code is derived from software contributed to The NetBSD Foundation
 1.2      matt  * by Raytheon BBN Technologies Corp and Defense Advanced Research Projects
 1.2      matt  * Agency and which was developed by Matt Thomas of 3am Software Foundry.
 1.2      matt  *
 1.2      matt  * This material is based upon work supported by the Defense Advanced Research
 1.2      matt  * Projects Agency and Space and Naval Warfare Systems Center, Pacific, under
 1.2      matt  * Contract No. N66001-09-C-2073.
 1.2      matt  * Approved for Public Release, Distribution Unlimited
 1.2      matt  *
 1.2      matt  * Redistribution and use in source and binary forms, with or without
 1.2      matt  * modification, are permitted provided that the following conditions
 1.2      matt  * are met:
 1.2      matt  * 1. Redistributions of source code must retain the above copyright
 1.2      matt  *    notice, this list of conditions and the following disclaimer.
 1.2      matt  * 2. Redistributions in binary form must reproduce the above copyright
 1.2      matt  *    notice, this list of conditions and the following disclaimer in the
 1.2      matt  *    documentation and/or other materials provided with the distribution.
 1.2      matt  *
 1.2      matt  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.2      matt  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.2      matt  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.2      matt  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.2      matt  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.2      matt  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.2      matt  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.2      matt  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.2      matt  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.2      matt  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.2      matt  * POSSIBILITY OF SUCH DAMAGE.
 1.2      matt  */
 1.2      matt
 1.3      matt #include "opt_mpc85xx.h"
1.31    nonaka #include "opt_multiprocessor.h"
1.31    nonaka #include "opt_ddb.h"
 1.3      matt
 1.2      matt #define __INTR_PRIVATE
 1.2      matt
1.15  dholland #include <sys/cdefs.h>
1.37      flxd __KERNEL_RCSID(0, "$NetBSD: e500_intr.c,v 1.37 2018/01/26 17:49:55 flxd Exp $");
1.15  dholland
 1.2      matt #include <sys/param.h>
 1.2      matt #include <sys/proc.h>
 1.2      matt #include <sys/intr.h>
 1.2      matt #include <sys/cpu.h>
 1.2      matt #include <sys/kmem.h>
 1.2      matt #include <sys/atomic.h>
 1.2      matt #include <sys/bus.h>
 1.8      matt #include <sys/xcall.h>
1.24     rmind #include <sys/ipi.h>
 1.8      matt #include <sys/bitops.h>
1.34    nonaka #include <sys/interrupt.h>
 1.2      matt
 1.2      matt #include <uvm/uvm_extern.h>
 1.2      matt
1.10      matt #ifdef __HAVE_FAST_SOFTINTS
1.10      matt #include <powerpc/softint.h>
1.10      matt #endif
1.10      matt
 1.2      matt #include <powerpc/spr.h>
 1.2      matt #include <powerpc/booke/spr.h>
 1.2      matt
 1.2      matt #include <powerpc/booke/cpuvar.h>
 1.2      matt #include <powerpc/booke/e500reg.h>
 1.2      matt #include <powerpc/booke/e500var.h>
 1.2      matt #include <powerpc/booke/openpicreg.h>
 1.2      matt
 1.2      matt #define	IPL2CTPR(ipl)		((ipl) + 15 - IPL_HIGH)
 1.2      matt #define CTPR2IPL(ctpr)		((ctpr) - (15 - IPL_HIGH))
 1.2      matt
 1.2      matt #define	IST_PERCPU_P(ist)	((ist) >= IST_TIMER)
 1.2      matt
 1.2      matt struct e500_intr_irq_info {
 1.2      matt 	bus_addr_t irq_vpr;
 1.2      matt 	bus_addr_t irq_dr;
 1.2      matt 	u_int irq_vector;
 1.2      matt };
 1.2      matt
 1.2      matt struct intr_source {
 1.2      matt 	int (*is_func)(void *);
 1.2      matt 	void *is_arg;
 1.2      matt 	int8_t is_ipl;
 1.2      matt 	uint8_t is_ist;
 1.2      matt 	uint8_t is_irq;
1.30    nonaka 	uint8_t is_refcnt;
 1.2      matt 	bus_size_t is_vpr;
 1.2      matt 	bus_size_t is_dr;
1.34    nonaka 	char is_source[INTRIDBUF];
1.34    nonaka 	char is_xname[INTRDEVNAMEBUF];
 1.2      matt };
 1.2      matt
 1.2      matt #define	INTR_SOURCE_INITIALIZER \
 1.2      matt 	{ .is_func = e500_intr_spurious, .is_arg = NULL, \
1.34    nonaka 	.is_irq = -1, .is_ipl = IPL_NONE, .is_ist = IST_NONE, \
1.34    nonaka 	.is_source = "", .is_xname = "", }
 1.2      matt
 1.2      matt struct e500_intr_name {
 1.2      matt 	uint8_t in_irq;
 1.2      matt 	const char in_name[15];
 1.2      matt };
 1.2      matt
 1.2      matt static const struct e500_intr_name e500_onchip_intr_names[] = {
 1.2      matt 	{ ISOURCE_L2, "l2" },
 1.2      matt 	{ ISOURCE_ECM, "ecm" },
 1.2      matt 	{ ISOURCE_DDR, "ddr" },
 1.2      matt 	{ ISOURCE_LBC, "lbc" },
 1.2      matt 	{ ISOURCE_DMA_CHAN1, "dma-chan1" },
 1.2      matt 	{ ISOURCE_DMA_CHAN2, "dma-chan2" },
 1.2      matt 	{ ISOURCE_DMA_CHAN3, "dma-chan3" },
 1.2      matt 	{ ISOURCE_DMA_CHAN4, "dma-chan4" },
 1.2      matt 	{ ISOURCE_PCI1, "pci1" },
 1.2      matt 	{ ISOURCE_PCIEX2, "pcie2" },
 1.2      matt 	{ ISOURCE_PCIEX	, "pcie1" },
 1.2      matt 	{ ISOURCE_PCIEX3, "pcie3" },
 1.3      matt 	{ ISOURCE_USB1, "usb1" },
 1.2      matt 	{ ISOURCE_ETSEC1_TX, "etsec1-tx" },
 1.2      matt 	{ ISOURCE_ETSEC1_RX, "etsec1-rx" },
 1.2      matt 	{ ISOURCE_ETSEC3_TX, "etsec3-tx" },
 1.2      matt 	{ ISOURCE_ETSEC3_RX, "etsec3-rx" },
 1.2      matt 	{ ISOURCE_ETSEC3_ERR, "etsec3-err" },
 1.2      matt 	{ ISOURCE_ETSEC1_ERR, "etsec1-err" },
 1.2      matt 	{ ISOURCE_ETSEC2_TX, "etsec2-tx" },
 1.2      matt 	{ ISOURCE_ETSEC2_RX, "etsec2-rx" },
 1.2      matt 	{ ISOURCE_ETSEC4_TX, "etsec4-tx" },
 1.2      matt 	{ ISOURCE_ETSEC4_RX, "etsec4-rx" },
 1.2      matt 	{ ISOURCE_ETSEC4_ERR, "etsec4-err" },
 1.2      matt 	{ ISOURCE_ETSEC2_ERR, "etsec2-err" },
 1.2      matt 	{ ISOURCE_DUART, "duart" },
 1.2      matt 	{ ISOURCE_I2C, "i2c" },
 1.2      matt 	{ ISOURCE_PERFMON, "perfmon" },
 1.2      matt 	{ ISOURCE_SECURITY1, "sec1" },
 1.3      matt 	{ ISOURCE_GPIO, "gpio" },
 1.2      matt 	{ ISOURCE_SRIO_EWPU, "srio-ewpu" },
 1.2      matt 	{ ISOURCE_SRIO_ODBELL, "srio-odbell" },
 1.2      matt 	{ ISOURCE_SRIO_IDBELL, "srio-idbell" },
 1.2      matt 	{ ISOURCE_SRIO_OMU1, "srio-omu1" },
 1.2      matt 	{ ISOURCE_SRIO_IMU1, "srio-imu1" },
 1.2      matt 	{ ISOURCE_SRIO_OMU2, "srio-omu2" },
 1.7      matt 	{ ISOURCE_SRIO_IMU2, "srio-imu2" },
 1.2      matt 	{ ISOURCE_SECURITY2, "sec2" },
 1.2      matt 	{ ISOURCE_SPI, "spi" },
 1.2      matt 	{ ISOURCE_ETSEC1_PTP, "etsec1-ptp" },
 1.3      matt 	{ ISOURCE_ETSEC2_PTP, "etsec2-ptp" },
 1.2      matt 	{ ISOURCE_ETSEC3_PTP, "etsec3-ptp" },
 1.3      matt 	{ ISOURCE_ETSEC4_PTP, "etsec4-ptp" },
 1.2      matt 	{ ISOURCE_ESDHC, "esdhc" },
 1.2      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.3      matt const struct e500_intr_name default_external_intr_names[] = {
 1.2      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.2      matt static const struct e500_intr_name e500_msigroup_intr_names[] = {
 1.2      matt 	{ 0, "msigroup0" },
 1.2      matt 	{ 1, "msigroup1" },
 1.2      matt 	{ 2, "msigroup2" },
 1.2      matt 	{ 3, "msigroup3" },
 1.2      matt 	{ 4, "msigroup4" },
 1.2      matt 	{ 5, "msigroup5" },
 1.2      matt 	{ 6, "msigroup6" },
 1.2      matt 	{ 7, "msigroup7" },
 1.2      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.2      matt static const struct e500_intr_name e500_timer_intr_names[] = {
 1.2      matt 	{ 0, "timer0" },
 1.2      matt 	{ 1, "timer1" },
 1.2      matt 	{ 2, "timer2" },
 1.2      matt 	{ 3, "timer3" },
 1.2      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.2      matt static const struct e500_intr_name e500_ipi_intr_names[] = {
 1.2      matt 	{ 0, "ipi0" },
 1.2      matt 	{ 1, "ipi1" },
 1.2      matt 	{ 2, "ipi2" },
 1.2      matt 	{ 3, "ipi3" },
 1.2      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.2      matt static const struct e500_intr_name e500_mi_intr_names[] = {
 1.2      matt 	{ 0, "mi0" },
 1.2      matt 	{ 1, "mi1" },
 1.2      matt 	{ 2, "mi2" },
 1.2      matt 	{ 3, "mi3" },
 1.2      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.2      matt struct e500_intr_info {
 1.2      matt 	u_int ii_external_sources;
 1.2      matt 	uint32_t ii_onchip_bitmap[2];
 1.2      matt 	u_int ii_onchip_sources;
 1.2      matt 	u_int ii_msigroup_sources;
 1.2      matt 	u_int ii_ipi_sources;			/* per-cpu */
 1.2      matt 	u_int ii_timer_sources;			/* per-cpu */
 1.2      matt 	u_int ii_mi_sources;			/* per-cpu */
 1.2      matt 	u_int ii_percpu_sources;
 1.2      matt 	const struct e500_intr_name *ii_external_intr_names;
 1.2      matt 	const struct e500_intr_name *ii_onchip_intr_names;
 1.2      matt 	u_int8_t ii_ist_vectors[IST_MAX+1];
 1.2      matt };
 1.2      matt
 1.3      matt static kmutex_t e500_intr_lock __cacheline_aligned;
 1.2      matt static struct e500_intr_info e500_intr_info;
 1.2      matt
 1.3      matt #define	INTR_INFO_DECL(lc_chip, UC_CHIP)				\
 1.3      matt static const struct e500_intr_info lc_chip##_intr_info = {		\
 1.3      matt 	.ii_external_sources = UC_CHIP ## _EXTERNALSOURCES,		\
 1.3      matt 	.ii_onchip_bitmap = UC_CHIP ## _ONCHIPBITMAP,			\
 1.3      matt 	.ii_onchip_sources = UC_CHIP ## _ONCHIPSOURCES,			\
 1.3      matt 	.ii_msigroup_sources = UC_CHIP ## _MSIGROUPSOURCES,		\
 1.3      matt 	.ii_timer_sources = UC_CHIP ## _TIMERSOURCES,			\
 1.3      matt 	.ii_ipi_sources = UC_CHIP ## _IPISOURCES,			\
 1.3      matt 	.ii_mi_sources = UC_CHIP ## _MISOURCES,				\
 1.3      matt 	.ii_percpu_sources = UC_CHIP ## _TIMERSOURCES			\
 1.3      matt 	    + UC_CHIP ## _IPISOURCES + UC_CHIP ## _MISOURCES, 		\
 1.3      matt 	.ii_external_intr_names = lc_chip ## _external_intr_names,	\
 1.3      matt 	.ii_onchip_intr_names = lc_chip ## _onchip_intr_names,		\
 1.3      matt 	.ii_ist_vectors = {						\
 1.3      matt 		[IST_NONE]		= ~0,				\
 1.3      matt 		[IST_EDGE]		= 0,				\
 1.3      matt 		[IST_LEVEL_LOW]		= 0,				\
 1.3      matt 		[IST_LEVEL_HIGH]	= 0,				\
1.11      matt 		[IST_PULSE]		= 0,				\
 1.3      matt 		[IST_ONCHIP]		= UC_CHIP ## _EXTERNALSOURCES,	\
 1.3      matt 		[IST_MSIGROUP]		= UC_CHIP ## _EXTERNALSOURCES	\
 1.3      matt 					    + UC_CHIP ## _ONCHIPSOURCES, \
 1.3      matt 		[IST_TIMER]		= UC_CHIP ## _EXTERNALSOURCES	\
 1.3      matt 					    + UC_CHIP ## _ONCHIPSOURCES	\
 1.3      matt 					    + UC_CHIP ## _MSIGROUPSOURCES, \
 1.3      matt 		[IST_IPI]		= UC_CHIP ## _EXTERNALSOURCES	\
 1.3      matt 					    + UC_CHIP ## _ONCHIPSOURCES	\
 1.3      matt 					    + UC_CHIP ## _MSIGROUPSOURCES \
 1.3      matt 					    + UC_CHIP ## _TIMERSOURCES,	\
 1.3      matt 		[IST_MI]		= UC_CHIP ## _EXTERNALSOURCES	\
 1.3      matt 					    + UC_CHIP ## _ONCHIPSOURCES	\
 1.3      matt 					    + UC_CHIP ## _MSIGROUPSOURCES \
 1.3      matt 					    + UC_CHIP ## _TIMERSOURCES	\
 1.3      matt 					    + UC_CHIP ## _IPISOURCES,	\
 1.3      matt 		[IST_MAX]		= UC_CHIP ## _EXTERNALSOURCES	\
 1.3      matt 					    + UC_CHIP ## _ONCHIPSOURCES	\
 1.3      matt 					    + UC_CHIP ## _MSIGROUPSOURCES \
 1.3      matt 					    + UC_CHIP ## _TIMERSOURCES	\
 1.3      matt 					    + UC_CHIP ## _IPISOURCES	\
 1.3      matt 					    + UC_CHIP ## _MISOURCES,	\
 1.3      matt 	},								\
 1.3      matt }
 1.3      matt
 1.3      matt #ifdef MPC8536
 1.3      matt #define	mpc8536_external_intr_names	default_external_intr_names
 1.3      matt const struct e500_intr_name mpc8536_onchip_intr_names[] = {
 1.3      matt 	{ ISOURCE_SATA2, "sata2" },
 1.3      matt 	{ ISOURCE_USB2, "usb2" },
 1.3      matt 	{ ISOURCE_USB3, "usb3" },
 1.3      matt 	{ ISOURCE_SATA1, "sata1" },
 1.3      matt 	{ 0, "" },
 1.3      matt };
 1.3      matt
 1.3      matt INTR_INFO_DECL(mpc8536, MPC8536);
 1.3      matt #endif
 1.3      matt
 1.3      matt #ifdef MPC8544
 1.3      matt #define	mpc8544_external_intr_names	default_external_intr_names
 1.3      matt const struct e500_intr_name mpc8544_onchip_intr_names[] = {
 1.3      matt 	{ 0, "" },
 1.3      matt };
 1.3      matt
 1.3      matt INTR_INFO_DECL(mpc8544, MPC8544);
 1.3      matt #endif
 1.3      matt #ifdef MPC8548
 1.3      matt #define	mpc8548_external_intr_names	default_external_intr_names
 1.3      matt const struct e500_intr_name mpc8548_onchip_intr_names[] = {
 1.3      matt 	{ ISOURCE_PCI1, "pci1" },
 1.3      matt 	{ ISOURCE_PCI2, "pci2" },
 1.3      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.3      matt INTR_INFO_DECL(mpc8548, MPC8548);
 1.3      matt #endif
 1.3      matt #ifdef MPC8555
 1.3      matt #define	mpc8555_external_intr_names	default_external_intr_names
 1.3      matt const struct e500_intr_name mpc8555_onchip_intr_names[] = {
 1.3      matt 	{ ISOURCE_PCI2, "pci2" },
 1.3      matt 	{ ISOURCE_CPM, "CPM" },
 1.3      matt 	{ 0, "" },
 1.3      matt };
 1.3      matt
 1.3      matt INTR_INFO_DECL(mpc8555, MPC8555);
 1.3      matt #endif
 1.3      matt #ifdef MPC8568
 1.3      matt #define	mpc8568_external_intr_names	default_external_intr_names
 1.3      matt const struct e500_intr_name mpc8568_onchip_intr_names[] = {
 1.3      matt 	{ ISOURCE_QEB_LOW, "QEB low" },
 1.3      matt 	{ ISOURCE_QEB_PORT, "QEB port" },
 1.3      matt 	{ ISOURCE_QEB_IECC, "QEB iram ecc" },
 1.3      matt 	{ ISOURCE_QEB_MUECC, "QEB ram ecc" },
 1.3      matt 	{ ISOURCE_TLU1, "tlu1" },
 1.3      matt 	{ ISOURCE_QEB_HIGH, "QEB high" },
 1.3      matt 	{ 0, "" },
 1.3      matt };
 1.3      matt
 1.3      matt INTR_INFO_DECL(mpc8568, MPC8568);
 1.3      matt #endif
 1.3      matt #ifdef MPC8572
 1.3      matt #define	mpc8572_external_intr_names	default_external_intr_names
 1.3      matt const struct e500_intr_name mpc8572_onchip_intr_names[] = {
 1.3      matt 	{ ISOURCE_PCIEX3_MPC8572, "pcie3" },
 1.3      matt 	{ ISOURCE_FEC, "fec" },
 1.3      matt 	{ ISOURCE_PME_GENERAL, "pme" },
 1.3      matt 	{ ISOURCE_TLU1, "tlu1" },
 1.3      matt 	{ ISOURCE_TLU2, "tlu2" },
 1.3      matt 	{ ISOURCE_PME_CHAN1, "pme-chan1" },
 1.3      matt 	{ ISOURCE_PME_CHAN2, "pme-chan2" },
 1.3      matt 	{ ISOURCE_PME_CHAN3, "pme-chan3" },
 1.3      matt 	{ ISOURCE_PME_CHAN4, "pme-chan4" },
 1.3      matt 	{ ISOURCE_DMA2_CHAN1, "dma2-chan1" },
 1.3      matt 	{ ISOURCE_DMA2_CHAN2, "dma2-chan2" },
 1.3      matt 	{ ISOURCE_DMA2_CHAN3, "dma2-chan3" },
 1.3      matt 	{ ISOURCE_DMA2_CHAN4, "dma2-chan4" },
 1.3      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.3      matt INTR_INFO_DECL(mpc8572, MPC8572);
 1.3      matt #endif
1.19      matt
1.19      matt #ifdef P1025
1.19      matt #define	p1025_external_intr_names	default_external_intr_names
1.19      matt const struct e500_intr_name p1025_onchip_intr_names[] = {
1.19      matt 	{ ISOURCE_PCIEX3_MPC8572, "pcie3" },
1.19      matt 	{ ISOURCE_ETSEC1_G1_TX, "etsec1-g1-tx" },
1.19      matt 	{ ISOURCE_ETSEC1_G1_RX, "etsec1-g1-rx" },
1.19      matt 	{ ISOURCE_ETSEC1_G1_ERR, "etsec1-g1-error" },
1.19      matt 	{ ISOURCE_ETSEC2_G1_TX, "etsec2-g1-tx" },
1.19      matt 	{ ISOURCE_ETSEC2_G1_RX, "etsec2-g1-rx" },
1.19      matt 	{ ISOURCE_ETSEC2_G1_ERR, "etsec2-g1-error" },
1.19      matt 	{ ISOURCE_ETSEC3_G1_TX, "etsec3-g1-tx" },
1.19      matt 	{ ISOURCE_ETSEC3_G1_RX, "etsec3-g1-rx" },
1.19      matt 	{ ISOURCE_ETSEC3_G1_ERR, "etsec3-g1-error" },
1.20      matt 	{ ISOURCE_QEB_MUECC, "qeb-low" },
1.20      matt 	{ ISOURCE_QEB_HIGH, "qeb-crit" },
1.19      matt 	{ ISOURCE_DMA2_CHAN1, "dma2-chan1" },
1.19      matt 	{ ISOURCE_DMA2_CHAN2, "dma2-chan2" },
1.19      matt 	{ ISOURCE_DMA2_CHAN3, "dma2-chan3" },
1.19      matt 	{ ISOURCE_DMA2_CHAN4, "dma2-chan4" },
1.19      matt 	{ 0, "" },
1.19      matt };
1.19      matt
1.19      matt INTR_INFO_DECL(p1025, P1025);
1.19      matt #endif
1.19      matt
 1.3      matt #ifdef P2020
 1.3      matt #define	p20x0_external_intr_names	default_external_intr_names
 1.3      matt const struct e500_intr_name p20x0_onchip_intr_names[] = {
 1.3      matt 	{ ISOURCE_PCIEX3_MPC8572, "pcie3" },
 1.3      matt 	{ ISOURCE_DMA2_CHAN1, "dma2-chan1" },
 1.3      matt 	{ ISOURCE_DMA2_CHAN2, "dma2-chan2" },
 1.3      matt 	{ ISOURCE_DMA2_CHAN3, "dma2-chan3" },
 1.3      matt 	{ ISOURCE_DMA2_CHAN4, "dma2-chan4" },
 1.3      matt 	{ 0, "" },
 1.2      matt };
 1.2      matt
 1.3      matt INTR_INFO_DECL(p20x0, P20x0);
 1.3      matt #endif
 1.3      matt
1.28    nonaka #ifdef P1023
1.28    nonaka #define	p1023_external_intr_names	default_external_intr_names
1.28    nonaka const struct e500_intr_name p1023_onchip_intr_names[] = {
1.28    nonaka 	{ ISOURCE_FMAN,            "fman" },
1.28    nonaka 	{ ISOURCE_MDIO,            "mdio" },
1.28    nonaka 	{ ISOURCE_QMAN0,           "qman0" },
1.28    nonaka 	{ ISOURCE_BMAN0,           "bman0" },
1.28    nonaka 	{ ISOURCE_QMAN1,           "qman1" },
1.28    nonaka 	{ ISOURCE_BMAN1,           "bman1" },
1.28    nonaka 	{ ISOURCE_QMAN2,           "qman2" },
1.28    nonaka 	{ ISOURCE_BMAN2,           "bman2" },
1.28    nonaka 	{ ISOURCE_SECURITY2_P1023, "sec2" },
1.28    nonaka 	{ ISOURCE_SEC_GENERAL,     "sec-general" },
1.28    nonaka 	{ ISOURCE_DMA2_CHAN1,      "dma2-chan1" },
1.28    nonaka 	{ ISOURCE_DMA2_CHAN2,      "dma2-chan2" },
1.28    nonaka 	{ ISOURCE_DMA2_CHAN3,      "dma2-chan3" },
1.28    nonaka 	{ ISOURCE_DMA2_CHAN4,      "dma2-chan4" },
1.28    nonaka 	{ 0, "" },
1.28    nonaka };
1.28    nonaka
1.28    nonaka INTR_INFO_DECL(p1023, P1023);
1.28    nonaka #endif
1.28    nonaka
 1.2      matt static const char ist_names[][12] = {
 1.2      matt 	[IST_NONE] = "none",
 1.2      matt 	[IST_EDGE] = "edge",
 1.2      matt 	[IST_LEVEL_LOW] = "level-",
 1.2      matt 	[IST_LEVEL_HIGH] = "level+",
1.11      matt 	[IST_PULSE] = "pulse",
 1.2      matt 	[IST_MSI] = "msi",
 1.2      matt 	[IST_ONCHIP] = "onchip",
 1.2      matt 	[IST_MSIGROUP] = "msigroup",
 1.2      matt 	[IST_TIMER] = "timer",
 1.2      matt 	[IST_IPI] = "ipi",
 1.2      matt 	[IST_MI] = "msgint",
 1.2      matt };
 1.2      matt
 1.2      matt static struct intr_source *e500_intr_sources;
 1.2      matt static const struct intr_source *e500_intr_last_source;
 1.2      matt
1.34    nonaka static void 	*e500_intr_establish(int, int, int, int (*)(void *), void *,
1.34    nonaka 		    const char *);
 1.2      matt static void 	e500_intr_disestablish(void *);
 1.8      matt static void 	e500_intr_cpu_attach(struct cpu_info *ci);
 1.8      matt static void 	e500_intr_cpu_hatch(struct cpu_info *ci);
 1.8      matt static void	e500_intr_cpu_send_ipi(cpuid_t, uintptr_t);
 1.2      matt static void 	e500_intr_init(void);
1.32    nonaka static void 	e500_intr_init_precpu(void);
1.23  christos static const char *e500_intr_string(int, int, char *, size_t);
1.11      matt static const char *e500_intr_typename(int);
 1.2      matt static void 	e500_critintr(struct trapframe *tf);
 1.2      matt static void 	e500_decrintr(struct trapframe *tf);
 1.2      matt static void 	e500_extintr(struct trapframe *tf);
 1.2      matt static void 	e500_fitintr(struct trapframe *tf);
 1.2      matt static void 	e500_wdogintr(struct trapframe *tf);
 1.2      matt static void	e500_spl0(void);
 1.2      matt static int 	e500_splraise(int);
 1.2      matt static void 	e500_splx(int);
1.34    nonaka static const char *e500_intr_all_name_lookup(int, int);
 1.2      matt
 1.2      matt const struct intrsw e500_intrsw = {
 1.2      matt 	.intrsw_establish = e500_intr_establish,
 1.2      matt 	.intrsw_disestablish = e500_intr_disestablish,
 1.2      matt 	.intrsw_init = e500_intr_init,
 1.8      matt 	.intrsw_cpu_attach = e500_intr_cpu_attach,
 1.8      matt 	.intrsw_cpu_hatch = e500_intr_cpu_hatch,
 1.8      matt 	.intrsw_cpu_send_ipi = e500_intr_cpu_send_ipi,
 1.2      matt 	.intrsw_string = e500_intr_string,
1.11      matt 	.intrsw_typename = e500_intr_typename,
 1.2      matt
 1.2      matt 	.intrsw_critintr = e500_critintr,
 1.2      matt 	.intrsw_decrintr = e500_decrintr,
 1.2      matt 	.intrsw_extintr = e500_extintr,
 1.2      matt 	.intrsw_fitintr = e500_fitintr,
 1.2      matt 	.intrsw_wdogintr = e500_wdogintr,
 1.2      matt
 1.2      matt 	.intrsw_splraise = e500_splraise,
 1.2      matt 	.intrsw_splx = e500_splx,
 1.2      matt 	.intrsw_spl0 = e500_spl0,
 1.2      matt
 1.2      matt #ifdef __HAVE_FAST_SOFTINTS
1.10      matt 	.intrsw_softint_init_md = powerpc_softint_init_md,
1.10      matt 	.intrsw_softint_trigger = powerpc_softint_trigger,
 1.2      matt #endif
 1.2      matt };
 1.2      matt
1.21      matt static bool wdog_barked;
1.21      matt
 1.2      matt static inline uint32_t
 1.2      matt openpic_read(struct cpu_softc *cpu, bus_size_t offset)
 1.2      matt {
 1.2      matt
 1.2      matt 	return bus_space_read_4(cpu->cpu_bst, cpu->cpu_bsh,
 1.2      matt 	    OPENPIC_BASE + offset);
 1.2      matt }
 1.2      matt
 1.2      matt static inline void
 1.2      matt openpic_write(struct cpu_softc *cpu, bus_size_t offset, uint32_t val)
 1.2      matt {
 1.2      matt
 1.2      matt 	return bus_space_write_4(cpu->cpu_bst, cpu->cpu_bsh,
 1.2      matt 	    OPENPIC_BASE + offset, val);
 1.2      matt }
 1.2      matt
 1.2      matt static const char *
 1.2      matt e500_intr_external_name_lookup(int irq)
 1.2      matt {
 1.2      matt 	prop_array_t extirqs = board_info_get_object("external-irqs");
 1.2      matt 	prop_string_t irqname = prop_array_get(extirqs, irq);
 1.2      matt 	KASSERT(irqname != NULL);
 1.2      matt 	KASSERT(prop_object_type(irqname) == PROP_TYPE_STRING);
 1.2      matt
 1.2      matt 	return prop_string_cstring_nocopy(irqname);
 1.2      matt }
 1.2      matt
 1.2      matt static const char *
 1.2      matt e500_intr_name_lookup(const struct e500_intr_name *names, int irq)
 1.2      matt {
 1.2      matt 	for (; names->in_name[0] != '\0'; names++) {
 1.2      matt 		if (names->in_irq == irq)
 1.2      matt 			return names->in_name;
 1.2      matt 	}
 1.2      matt
 1.2      matt 	return NULL;
 1.2      matt }
 1.2      matt
 1.2      matt static const char *
 1.2      matt e500_intr_onchip_name_lookup(int irq)
 1.2      matt {
 1.2      matt 	const char *name;
 1.2      matt
 1.5      matt 	name = e500_intr_name_lookup(e500_intr_info.ii_onchip_intr_names, irq);
 1.5      matt 	if (name == NULL)
 1.5      matt 	       name = e500_intr_name_lookup(e500_onchip_intr_names, irq);
 1.2      matt
 1.5      matt 	return name;
 1.2      matt }
 1.2      matt
 1.2      matt static inline void
 1.2      matt e500_splset(struct cpu_info *ci, int ipl)
 1.2      matt {
 1.2      matt 	struct cpu_softc * const cpu = ci->ci_softc;
1.13      matt
 1.2      matt 	KASSERT((curlwp->l_pflag & LP_INTR) == 0 || ipl != IPL_NONE);
1.13      matt 	const u_int ctpr = IPL2CTPR(ipl);
1.12      matt 	KASSERT(openpic_read(cpu, OPENPIC_CTPR) == IPL2CTPR(ci->ci_cpl));
 1.2      matt 	openpic_write(cpu, OPENPIC_CTPR, ctpr);
 1.2      matt 	KASSERT(openpic_read(cpu, OPENPIC_CTPR) == ctpr);
1.21      matt #ifdef DIAGNOSTIC
1.21      matt 	cpu->cpu_spl_tb[ipl][ci->ci_cpl] = mftb();
1.21      matt #endif
 1.2      matt 	ci->ci_cpl = ipl;
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_spl0(void)
 1.2      matt {
1.12      matt 	wrtee(0);
1.12      matt
 1.2      matt 	struct cpu_info * const ci = curcpu();
 1.2      matt
 1.2      matt #ifdef __HAVE_FAST_SOFTINTS
 1.2      matt 	if (__predict_false(ci->ci_data.cpu_softints != 0)) {
 1.2      matt 		e500_splset(ci, IPL_HIGH);
1.21      matt 		wrtee(PSL_EE);
1.10      matt 		powerpc_softint(ci, IPL_NONE,
 1.8      matt 		    (vaddr_t)__builtin_return_address(0));
1.21      matt 		wrtee(0);
 1.2      matt 	}
 1.2      matt #endif /* __HAVE_FAST_SOFTINTS */
 1.2      matt 	e500_splset(ci, IPL_NONE);
 1.2      matt
 1.2      matt 	wrtee(PSL_EE);
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_splx(int ipl)
 1.2      matt {
 1.2      matt 	struct cpu_info * const ci = curcpu();
 1.2      matt 	const int old_ipl = ci->ci_cpl;
 1.2      matt
1.18      matt 	/* if we paniced because of watchdog, PSL_CE will be clear.  */
1.21      matt 	KASSERT(wdog_barked || (mfmsr() & PSL_CE));
 1.2      matt
 1.2      matt 	if (ipl == old_ipl)
 1.2      matt 		return;
 1.2      matt
 1.2      matt 	if (__predict_false(ipl > old_ipl)) {
 1.2      matt 		printf("%s: %p: cpl=%u: ignoring splx(%u) to raise ipl\n",
 1.2      matt 		    __func__, __builtin_return_address(0), old_ipl, ipl);
 1.2      matt 		if (old_ipl == IPL_NONE)
 1.2      matt 			Debugger();
 1.2      matt 	}
 1.2      matt
 1.2      matt 	// const
 1.2      matt 	register_t msr = wrtee(0);
 1.2      matt #ifdef __HAVE_FAST_SOFTINTS
1.17      matt 	const u_int softints = ci->ci_data.cpu_softints & (IPL_SOFTMASK << ipl);
 1.2      matt 	if (__predict_false(softints != 0)) {
 1.2      matt 		e500_splset(ci, IPL_HIGH);
1.21      matt 		wrtee(msr);
1.10      matt 		powerpc_softint(ci, ipl,
 1.8      matt 		    (vaddr_t)__builtin_return_address(0));
1.21      matt 		wrtee(0);
 1.2      matt 	}
 1.2      matt #endif /* __HAVE_FAST_SOFTINTS */
 1.2      matt 	e500_splset(ci, ipl);
 1.2      matt #if 1
 1.2      matt 	if (ipl < IPL_VM && old_ipl >= IPL_VM)
 1.2      matt 		msr = PSL_EE;
 1.2      matt #endif
 1.2      matt 	wrtee(msr);
 1.2      matt }
 1.2      matt
 1.2      matt static int
 1.2      matt e500_splraise(int ipl)
 1.2      matt {
 1.2      matt 	struct cpu_info * const ci = curcpu();
 1.2      matt 	const int old_ipl = ci->ci_cpl;
 1.2      matt
1.18      matt 	/* if we paniced because of watchdog, PSL_CE will be clear.  */
1.21      matt 	KASSERT(wdog_barked || (mfmsr() & PSL_CE));
 1.2      matt
 1.2      matt 	if (old_ipl < ipl) {
 1.2      matt 		//const
 1.2      matt 		register_t msr = wrtee(0);
 1.2      matt 		e500_splset(ci, ipl);
1.21      matt #if 0
 1.2      matt 		if (old_ipl < IPL_VM && ipl >= IPL_VM)
 1.2      matt 			msr = 0;
 1.2      matt #endif
 1.2      matt 		wrtee(msr);
 1.2      matt 	} else if (ipl == IPL_NONE) {
 1.2      matt 		panic("%s: %p: cpl=%u: attempt to splraise(IPL_NONE)",
 1.2      matt 		    __func__, __builtin_return_address(0), old_ipl);
 1.2      matt #if 0
 1.2      matt 	} else if (old_ipl > ipl) {
 1.2      matt 		printf("%s: %p: cpl=%u: ignoring splraise(%u) to lower ipl\n",
 1.2      matt 		    __func__, __builtin_return_address(0), old_ipl, ipl);
 1.2      matt #endif
 1.2      matt 	}
 1.2      matt
 1.2      matt 	return old_ipl;
 1.2      matt }
 1.2      matt
 1.2      matt static int
 1.2      matt e500_intr_spurious(void *arg)
 1.2      matt {
 1.2      matt 	return 0;
 1.2      matt }
 1.2      matt
 1.2      matt static bool
 1.2      matt e500_intr_irq_info_get(struct cpu_info *ci, u_int irq, int ipl, int ist,
 1.2      matt 	struct e500_intr_irq_info *ii)
 1.2      matt {
 1.2      matt 	const struct e500_intr_info * const info = &e500_intr_info;
 1.2      matt 	bool ok;
 1.2      matt
 1.2      matt #if DEBUG > 2
 1.2      matt 	printf("%s(%p,irq=%u,ipl=%u,ist=%u,%p)\n", __func__, ci, irq, ipl, ist, ii);
 1.2      matt #endif
 1.2      matt
 1.2      matt 	if (ipl < IPL_VM || ipl > IPL_HIGH) {
 1.2      matt #if DEBUG > 2
 1.2      matt 		printf("%s:%d ipl=%u\n", __func__, __LINE__, ipl);
 1.2      matt #endif
 1.2      matt 		return false;
 1.2      matt 	}
 1.2      matt
 1.2      matt 	if (ist <= IST_NONE || ist >= IST_MAX) {
 1.2      matt #if DEBUG > 2
 1.2      matt 		printf("%s:%d ist=%u\n", __func__, __LINE__, ist);
 1.2      matt #endif
 1.2      matt 		return false;
 1.2      matt 	}
 1.2      matt
 1.2      matt 	ii->irq_vector = irq + info->ii_ist_vectors[ist];
 1.8      matt 	if (IST_PERCPU_P(ist) && ist != IST_IPI)
 1.2      matt 		ii->irq_vector += ci->ci_cpuid * info->ii_percpu_sources;
 1.2      matt
 1.2      matt 	switch (ist) {
 1.2      matt 	default:
 1.2      matt 		ii->irq_vpr = OPENPIC_EIVPR(irq);
 1.2      matt 		ii->irq_dr  = OPENPIC_EIDR(irq);
 1.2      matt 		ok = irq < info->ii_external_sources
 1.2      matt 		    && (ist == IST_EDGE
 1.2      matt 			|| ist == IST_LEVEL_LOW
 1.2      matt 			|| ist == IST_LEVEL_HIGH);
 1.2      matt 		break;
1.11      matt 	case IST_PULSE:
1.11      matt 		ok = false;
1.11      matt 		break;
 1.2      matt 	case IST_ONCHIP:
 1.2      matt 		ii->irq_vpr = OPENPIC_IIVPR(irq);
 1.2      matt 		ii->irq_dr  = OPENPIC_IIDR(irq);
 1.2      matt 		ok = irq < 32 * __arraycount(info->ii_onchip_bitmap);
 1.2      matt #if DEBUG > 2
 1.2      matt 		printf("%s: irq=%u: ok=%u\n", __func__, irq, ok);
 1.2      matt #endif
 1.2      matt 		ok = ok && (info->ii_onchip_bitmap[irq/32] & (1 << (irq & 31)));
 1.2      matt #if DEBUG > 2
 1.2      matt 		printf("%s: %08x%08x -> %08x%08x: ok=%u\n", __func__,
 1.2      matt 		    irq < 32 ? 0 : (1 << irq), irq < 32 ? (1 << irq) : 0,
 1.2      matt 		    info->ii_onchip_bitmap[1], info->ii_onchip_bitmap[0],
 1.2      matt 		    ok);
 1.2      matt #endif
 1.2      matt 		break;
 1.2      matt 	case IST_MSIGROUP:
 1.2      matt 		ii->irq_vpr = OPENPIC_MSIVPR(irq);
 1.2      matt 		ii->irq_dr  = OPENPIC_MSIDR(irq);
 1.2      matt 		ok = irq < info->ii_msigroup_sources
 1.2      matt 		    && ipl == IPL_VM;
 1.2      matt 		break;
 1.2      matt 	case IST_TIMER:
 1.2      matt 		ii->irq_vpr = OPENPIC_GTVPR(ci->ci_cpuid, irq);
 1.2      matt 		ii->irq_dr  = OPENPIC_GTDR(ci->ci_cpuid, irq);
 1.2      matt 		ok = irq < info->ii_timer_sources;
 1.2      matt #if DEBUG > 2
 1.2      matt 		printf("%s: IST_TIMER irq=%u: ok=%u\n", __func__, irq, ok);
 1.2      matt #endif
 1.2      matt 		break;
 1.2      matt 	case IST_IPI:
 1.2      matt 		ii->irq_vpr = OPENPIC_IPIVPR(irq);
 1.2      matt 		ii->irq_dr  = OPENPIC_IPIDR(irq);
 1.2      matt 		ok = irq < info->ii_ipi_sources;
 1.2      matt 		break;
 1.2      matt 	case IST_MI:
 1.2      matt 		ii->irq_vpr = OPENPIC_MIVPR(irq);
 1.2      matt 		ii->irq_dr  = OPENPIC_MIDR(irq);
 1.2      matt 		ok = irq < info->ii_mi_sources;
 1.2      matt 		break;
 1.2      matt 	}
 1.2      matt
 1.2      matt 	return ok;
 1.2      matt }
 1.2      matt
 1.2      matt static const char *
1.23  christos e500_intr_string(int irq, int ist, char *buf, size_t len)
 1.2      matt {
 1.2      matt 	struct cpu_info * const ci = curcpu();
 1.2      matt 	struct cpu_softc * const cpu = ci->ci_softc;
 1.2      matt 	struct e500_intr_irq_info ii;
 1.2      matt
 1.2      matt 	if (!e500_intr_irq_info_get(ci, irq, IPL_VM, ist, &ii))
 1.2      matt 		return NULL;
 1.2      matt
1.23  christos 	strlcpy(buf, cpu->cpu_evcnt_intrs[ii.irq_vector].ev_name, len);
1.23  christos 	return buf;
 1.2      matt }
 1.2      matt
1.11      matt __CTASSERT(__arraycount(ist_names) == IST_MAX);
1.11      matt
1.11      matt static const char *
1.11      matt e500_intr_typename(int ist)
1.11      matt {
1.11      matt 	if (IST_NONE <= ist && ist < IST_MAX)
1.11      matt 		return ist_names[ist];
1.11      matt
1.11      matt 	return NULL;
1.11      matt }
1.11      matt
 1.2      matt static void *
 1.2      matt e500_intr_cpu_establish(struct cpu_info *ci, int irq, int ipl, int ist,
1.34    nonaka 	int (*handler)(void *), void *arg, const char *xname)
 1.2      matt {
 1.2      matt 	struct cpu_softc * const cpu = ci->ci_softc;
 1.2      matt 	struct e500_intr_irq_info ii;
 1.2      matt
 1.2      matt 	KASSERT(ipl >= IPL_VM && ipl <= IPL_HIGH);
 1.2      matt 	KASSERT(ist > IST_NONE && ist < IST_MAX && ist != IST_MSI);
 1.2      matt
 1.2      matt 	if (!e500_intr_irq_info_get(ci, irq, ipl, ist, &ii)) {
 1.2      matt 		printf("%s: e500_intr_irq_info_get(%p,%u,%u,%u,%p) failed\n",
 1.2      matt 		    __func__, ci, irq, ipl, ist, &ii);
 1.2      matt 		return NULL;
 1.2      matt 	}
 1.2      matt
1.34    nonaka 	if (xname == NULL) {
1.34    nonaka 		xname = e500_intr_all_name_lookup(irq, ist);
1.34    nonaka 		if (xname == NULL)
1.34    nonaka 			xname = "unknown";
1.34    nonaka 	}
1.34    nonaka
 1.2      matt 	struct intr_source * const is = &e500_intr_sources[ii.irq_vector];
 1.2      matt 	mutex_enter(&e500_intr_lock);
1.25    nonaka 	if (is->is_ipl != IPL_NONE) {
1.30    nonaka 		/* XXX IPI0 is shared by all CPU. */
1.30    nonaka 		if (is->is_ist != IST_IPI ||
1.30    nonaka 		    is->is_irq != irq ||
1.30    nonaka 		    is->is_ipl != ipl ||
1.30    nonaka 		    is->is_ist != ist ||
1.30    nonaka 		    is->is_func != handler ||
1.30    nonaka 		    is->is_arg != arg) {
1.30    nonaka 			mutex_exit(&e500_intr_lock);
1.30    nonaka 			return NULL;
1.30    nonaka 		}
1.25    nonaka 	}
 1.2      matt
 1.2      matt 	is->is_func = handler;
 1.2      matt 	is->is_arg = arg;
 1.2      matt 	is->is_ipl = ipl;
 1.2      matt 	is->is_ist = ist;
 1.2      matt 	is->is_irq = irq;
1.30    nonaka 	is->is_refcnt++;
 1.2      matt 	is->is_vpr = ii.irq_vpr;
 1.2      matt 	is->is_dr = ii.irq_dr;
1.34    nonaka 	switch (ist) {
1.34    nonaka 	case IST_EDGE:
1.34    nonaka 	case IST_LEVEL_LOW:
1.34    nonaka 	case IST_LEVEL_HIGH:
1.34    nonaka 		snprintf(is->is_source, sizeof(is->is_source), "extirq %d",
1.34    nonaka 		    irq);
1.34    nonaka 		break;
1.34    nonaka 	case IST_ONCHIP:
1.34    nonaka 		snprintf(is->is_source, sizeof(is->is_source), "irq %d", irq);
1.34    nonaka 		break;
1.34    nonaka 	case IST_MSIGROUP:
1.34    nonaka 		snprintf(is->is_source, sizeof(is->is_source), "msigroup %d",
1.34    nonaka 		    irq);
1.34    nonaka 		break;
1.34    nonaka 	case IST_TIMER:
1.34    nonaka 		snprintf(is->is_source, sizeof(is->is_source), "timer %d", irq);
1.34    nonaka 		break;
1.34    nonaka 	case IST_IPI:
1.34    nonaka 		snprintf(is->is_source, sizeof(is->is_source), "ipi %d", irq);
1.34    nonaka 		break;
1.34    nonaka 	case IST_MI:
1.34    nonaka 		snprintf(is->is_source, sizeof(is->is_source), "mi %d", irq);
1.34    nonaka 		break;
1.34    nonaka 	case IST_PULSE:
1.34    nonaka 	default:
1.34    nonaka 		panic("%s: invalid ist (%d)\n", __func__, ist);
1.34    nonaka 	}
1.34    nonaka 	strlcpy(is->is_xname, xname, sizeof(is->is_xname));
 1.2      matt
 1.2      matt 	uint32_t vpr = VPR_PRIORITY_MAKE(IPL2CTPR(ipl))
 1.2      matt 	    | VPR_VECTOR_MAKE(((ii.irq_vector + 1) << 4) | ipl)
 1.2      matt 	    | (ist == IST_LEVEL_LOW
 1.2      matt 		? VPR_LEVEL_LOW
 1.2      matt 		: (ist == IST_LEVEL_HIGH
 1.2      matt 		    ? VPR_LEVEL_HIGH
 1.2      matt 		    : (ist == IST_ONCHIP
 1.2      matt 		      ? VPR_P_HIGH
 1.2      matt 		      : 0)));
 1.2      matt
 1.2      matt 	/*
 1.2      matt 	 * All interrupts go to the primary except per-cpu interrupts which get
 1.2      matt 	 * routed to the appropriate cpu.
 1.2      matt 	 */
 1.8      matt 	uint32_t dr = openpic_read(cpu, ii.irq_dr);
 1.8      matt
 1.8      matt 	dr |= 1 << (IST_PERCPU_P(ist) ? ci->ci_cpuid : 0);
 1.2      matt
 1.2      matt 	/*
 1.2      matt 	 * Update the vector/priority and destination registers keeping the
 1.2      matt 	 * interrupt masked.
 1.2      matt 	 */
 1.2      matt 	const register_t msr = wrtee(0);	/* disable interrupts */
 1.2      matt 	openpic_write(cpu, ii.irq_vpr, vpr | VPR_MSK);
 1.2      matt 	openpic_write(cpu, ii.irq_dr, dr);
 1.2      matt
 1.2      matt 	/*
 1.2      matt 	 * Now unmask the interrupt.
 1.2      matt 	 */
 1.2      matt 	openpic_write(cpu, ii.irq_vpr, vpr);
 1.2      matt
 1.2      matt 	wrtee(msr);				/* re-enable interrupts */
 1.2      matt
 1.2      matt 	mutex_exit(&e500_intr_lock);
 1.2      matt
 1.2      matt 	return is;
 1.2      matt }
 1.2      matt
 1.2      matt static void *
1.34    nonaka e500_intr_establish(int irq, int ipl, int ist, int (*handler)(void *),
1.34    nonaka     void *arg, const char *xname)
 1.2      matt {
1.34    nonaka 	return e500_intr_cpu_establish(curcpu(), irq, ipl, ist, handler, arg,
1.34    nonaka 	    xname);
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_intr_disestablish(void *vis)
 1.2      matt {
 1.2      matt 	struct cpu_softc * const cpu = curcpu()->ci_softc;
 1.2      matt 	struct intr_source * const is = vis;
 1.2      matt 	struct e500_intr_irq_info ii;
 1.2      matt
 1.2      matt 	KASSERT(e500_intr_sources <= is);
 1.2      matt 	KASSERT(is < e500_intr_last_source);
 1.2      matt 	KASSERT(!cpu_intr_p());
 1.2      matt
 1.2      matt 	bool ok = e500_intr_irq_info_get(curcpu(), is->is_irq, is->is_ipl,
 1.2      matt 	    is->is_ist, &ii);
 1.2      matt 	(void)ok;	/* appease gcc */
 1.2      matt 	KASSERT(ok);
 1.2      matt 	KASSERT(is - e500_intr_sources == ii.irq_vector);
 1.2      matt
 1.2      matt 	mutex_enter(&e500_intr_lock);
1.30    nonaka
1.30    nonaka 	if (is->is_refcnt-- > 1) {
1.30    nonaka 		mutex_exit(&e500_intr_lock);
1.30    nonaka 		return;
1.30    nonaka 	}
1.30    nonaka
 1.2      matt 	/*
 1.2      matt 	 * Mask the source using the mask (MSK) bit in the vector/priority reg.
 1.2      matt 	 */
 1.2      matt 	uint32_t vpr = openpic_read(cpu, ii.irq_vpr);
 1.2      matt 	openpic_write(cpu, ii.irq_vpr, VPR_MSK | vpr);
 1.2      matt
 1.2      matt 	/*
 1.2      matt 	 * Wait for the Activity (A) bit for the source to be cleared.
 1.2      matt 	 */
 1.2      matt 	while (openpic_read(cpu, ii.irq_vpr) & VPR_A)
 1.2      matt 		;
 1.2      matt
 1.2      matt 	/*
 1.2      matt 	 * Now the source can be modified.
 1.2      matt 	 */
 1.2      matt 	openpic_write(cpu, ii.irq_dr, 0);		/* stop delivery */
 1.2      matt 	openpic_write(cpu, ii.irq_vpr, VPR_MSK);	/* mask/reset it */
 1.2      matt
 1.2      matt 	*is = (struct intr_source)INTR_SOURCE_INITIALIZER;
 1.2      matt
 1.2      matt 	mutex_exit(&e500_intr_lock);
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_critintr(struct trapframe *tf)
 1.2      matt {
 1.2      matt 	panic("%s: srr0/srr1=%#lx/%#lx", __func__, tf->tf_srr0, tf->tf_srr1);
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_decrintr(struct trapframe *tf)
 1.2      matt {
 1.2      matt 	panic("%s: srr0/srr1=%#lx/%#lx", __func__, tf->tf_srr0, tf->tf_srr1);
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_fitintr(struct trapframe *tf)
 1.2      matt {
 1.2      matt 	panic("%s: srr0/srr1=%#lx/%#lx", __func__, tf->tf_srr0, tf->tf_srr1);
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_wdogintr(struct trapframe *tf)
 1.2      matt {
1.21      matt 	struct cpu_info * const ci = curcpu();
 1.2      matt 	mtspr(SPR_TSR, TSR_ENW|TSR_WIS);
1.21      matt 	wdog_barked = true;
1.21      matt 	dump_splhist(ci, NULL);
1.21      matt 	dump_trapframe(tf, NULL);
1.21      matt 	panic("%s: tf=%p tb=%"PRId64" srr0/srr1=%#lx/%#lx"
1.21      matt 	    " cpl=%d idepth=%d, mtxcount=%d",
1.21      matt 	    __func__, tf, mftb(), tf->tf_srr0, tf->tf_srr1,
1.21      matt 	    ci->ci_cpl, ci->ci_idepth, ci->ci_mtx_count);
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_extintr(struct trapframe *tf)
 1.2      matt {
 1.2      matt 	struct cpu_info * const ci = curcpu();
 1.2      matt 	struct cpu_softc * const cpu = ci->ci_softc;
 1.2      matt 	const int old_ipl = ci->ci_cpl;
 1.2      matt
1.18      matt 	/* if we paniced because of watchdog, PSL_CE will be clear.  */
1.21      matt 	KASSERT(wdog_barked || (mfmsr() & PSL_CE));
 1.2      matt
 1.2      matt #if 0
 1.2      matt //	printf("%s(%p): idepth=%d enter\n", __func__, tf, ci->ci_idepth);
 1.2      matt 	if ((register_t)tf >= (register_t)curlwp->l_addr + USPACE
 1.2      matt 	    || (register_t)tf < (register_t)curlwp->l_addr + NBPG) {
 1.2      matt 		printf("%s(entry): pid %d.%d (%s): srr0/srr1=%#lx/%#lx: invalid tf addr %p\n",
 1.2      matt 		    __func__, curlwp->l_proc->p_pid, curlwp->l_lid,
 1.2      matt 		    curlwp->l_proc->p_comm, tf->tf_srr0, tf->tf_srr1, tf);
 1.2      matt 	}
 1.2      matt #endif
 1.2      matt
 1.2      matt
 1.2      matt 	ci->ci_data.cpu_nintr++;
 1.2      matt 	tf->tf_cf.cf_idepth = ci->ci_idepth++;
 1.2      matt 	cpu->cpu_pcpls[ci->ci_idepth] = old_ipl;
 1.2      matt #if 1
 1.2      matt 	if (mfmsr() & PSL_EE)
 1.2      matt 		panic("%s(%p): MSR[EE] is on (%#lx)!", __func__, tf, mfmsr());
 1.2      matt 	if (old_ipl == IPL_HIGH
 1.2      matt 	    || IPL2CTPR(old_ipl) != openpic_read(cpu, OPENPIC_CTPR))
 1.2      matt 		panic("%s(%p): old_ipl(%u) == IPL_HIGH(%u) "
 1.2      matt 		    "|| old_ipl + %u != OPENPIC_CTPR (%u)",
 1.2      matt 		    __func__, tf, old_ipl, IPL_HIGH,
 1.2      matt 		    15 - IPL_HIGH, openpic_read(cpu, OPENPIC_CTPR));
 1.2      matt #else
 1.2      matt 	if (old_ipl >= IPL_VM)
 1.2      matt 		panic("%s(%p): old_ipl(%u) >= IPL_VM(%u) CTPR=%u",
 1.2      matt 		    __func__, tf, old_ipl, IPL_VM, openpic_read(cpu, OPENPIC_CTPR));
 1.2      matt #endif
 1.2      matt
 1.2      matt 	for (;;) {
 1.2      matt 		/*
 1.2      matt 		 * Find out the pending interrupt.
 1.2      matt 		 */
1.21      matt 		KASSERTMSG((mfmsr() & PSL_EE) == 0,
1.21      matt 		    "%s(%p): MSR[EE] left on (%#lx)!", __func__, tf, mfmsr());
 1.2      matt 		if (IPL2CTPR(old_ipl) != openpic_read(cpu, OPENPIC_CTPR))
 1.2      matt 			panic("%s(%p): %d: old_ipl(%u) + %u != OPENPIC_CTPR (%u)",
 1.2      matt 			    __func__, tf, __LINE__, old_ipl,
 1.2      matt 			    15 - IPL_HIGH, openpic_read(cpu, OPENPIC_CTPR));
 1.2      matt 		const uint32_t iack = openpic_read(cpu, OPENPIC_IACK);
 1.6    dyoung #ifdef DIAGNOSTIC
 1.2      matt 		const int ipl = iack & 0xf;
 1.6    dyoung #endif
 1.2      matt 		const int irq = (iack >> 4) - 1;
 1.2      matt #if 0
 1.2      matt 		printf("%s: iack=%d ipl=%d irq=%d <%s>\n",
 1.2      matt 		    __func__, iack, ipl, irq,
 1.2      matt 		    (iack != IRQ_SPURIOUS ?
 1.2      matt 			cpu->cpu_evcnt_intrs[irq].ev_name : "spurious"));
 1.2      matt #endif
 1.2      matt 		if (IPL2CTPR(old_ipl) != openpic_read(cpu, OPENPIC_CTPR))
 1.2      matt 			panic("%s(%p): %d: old_ipl(%u) + %u != OPENPIC_CTPR (%u)",
 1.2      matt 			    __func__, tf, __LINE__, old_ipl,
 1.2      matt 			    15 - IPL_HIGH, openpic_read(cpu, OPENPIC_CTPR));
 1.2      matt 		if (iack == IRQ_SPURIOUS)
 1.2      matt 			break;
 1.2      matt
 1.2      matt 		struct intr_source * const is = &e500_intr_sources[irq];
 1.2      matt 		if (__predict_true(is < e500_intr_last_source)) {
 1.2      matt 			/*
 1.2      matt 			 * Timer interrupts get their argument overriden with
 1.2      matt 			 * the pointer to the trapframe.
 1.2      matt 			 */
1.22      matt 			KASSERTMSG(is->is_ipl == ipl,
1.22      matt 			    "iack %#x: is %p: irq %d ipl %d != iack ipl %d",
1.22      matt 			    iack, is, irq, is->is_ipl, ipl);
 1.2      matt 			void *arg = (is->is_ist == IST_TIMER ? tf : is->is_arg);
 1.2      matt 			if (is->is_ipl <= old_ipl)
 1.2      matt 				panic("%s(%p): %s (%u): is->is_ipl (%u) <= old_ipl (%u)\n",
 1.2      matt 				    __func__, tf,
 1.2      matt 				    cpu->cpu_evcnt_intrs[irq].ev_name, irq,
 1.2      matt 				    is->is_ipl, old_ipl);
 1.2      matt 			KASSERT(is->is_ipl > old_ipl);
 1.2      matt 			e500_splset(ci, is->is_ipl);	/* change IPL */
 1.2      matt 			if (__predict_false(is->is_func == NULL)) {
 1.2      matt 				aprint_error_dev(ci->ci_dev,
 1.2      matt 				    "interrupt from unestablished irq %d\n",
 1.2      matt 				    irq);
 1.2      matt 			} else {
 1.2      matt 				int (*func)(void *) = is->is_func;
 1.2      matt 				wrtee(PSL_EE);
 1.2      matt 				int rv = (*func)(arg);
 1.2      matt 				wrtee(0);
 1.2      matt #if DEBUG > 2
 1.2      matt 				printf("%s: %s handler %p(%p) returned %d\n",
 1.2      matt 				    __func__,
 1.2      matt 				    cpu->cpu_evcnt_intrs[irq].ev_name,
 1.2      matt 				    func, arg, rv);
 1.2      matt #endif
 1.2      matt 				if (rv == 0)
 1.2      matt 					cpu->cpu_evcnt_spurious_intr.ev_count++;
 1.2      matt 			}
 1.2      matt 			e500_splset(ci, old_ipl);	/* restore IPL */
 1.2      matt 			cpu->cpu_evcnt_intrs[irq].ev_count++;
 1.2      matt 		} else {
 1.2      matt 			aprint_error_dev(ci->ci_dev,
 1.2      matt 			    "interrupt from illegal irq %d\n", irq);
 1.2      matt 			cpu->cpu_evcnt_spurious_intr.ev_count++;
 1.2      matt 		}
 1.2      matt 		/*
 1.2      matt 		 * If this is a nested interrupt, simply ack it and exit
 1.2      matt 		 * because the loop we interrupted will complete looking
 1.2      matt 		 * for interrupts.
 1.2      matt 		 */
1.21      matt 		KASSERTMSG((mfmsr() & PSL_EE) == 0,
1.21      matt 		    "%s(%p): MSR[EE] left on (%#lx)!", __func__, tf, mfmsr());
 1.2      matt 		if (IPL2CTPR(old_ipl) != openpic_read(cpu, OPENPIC_CTPR))
 1.2      matt 			panic("%s(%p): %d: old_ipl(%u) + %u != OPENPIC_CTPR (%u)",
 1.2      matt 			    __func__, tf, __LINE__, old_ipl,
 1.2      matt 			    15 - IPL_HIGH, openpic_read(cpu, OPENPIC_CTPR));
 1.2      matt
 1.2      matt 		openpic_write(cpu, OPENPIC_EOI, 0);
 1.2      matt 		if (IPL2CTPR(old_ipl) != openpic_read(cpu, OPENPIC_CTPR))
 1.2      matt 			panic("%s(%p): %d: old_ipl(%u) + %u != OPENPIC_CTPR (%u)",
 1.2      matt 			    __func__, tf, __LINE__, old_ipl,
 1.2      matt 			    15 - IPL_HIGH, openpic_read(cpu, OPENPIC_CTPR));
 1.2      matt 		if (ci->ci_idepth > 0)
 1.2      matt 			break;
 1.2      matt 	}
 1.2      matt
 1.2      matt 	ci->ci_idepth--;
 1.2      matt
 1.2      matt #ifdef __HAVE_FAST_SOFTINTS
 1.2      matt 	/*
 1.2      matt 	 * Before exiting, deal with any softints that need to be dealt with.
 1.2      matt 	 */
1.17      matt 	const u_int softints = ci->ci_data.cpu_softints & (IPL_SOFTMASK << old_ipl);
 1.2      matt 	if (__predict_false(softints != 0)) {
 1.2      matt 		KASSERT(old_ipl < IPL_VM);
 1.2      matt 		e500_splset(ci, IPL_HIGH);	/* pop to high */
1.21      matt 		wrtee(PSL_EE);			/* reenable interrupts */
1.10      matt 		powerpc_softint(ci, old_ipl,	/* deal with them */
 1.8      matt 		    tf->tf_srr0);
1.21      matt 		wrtee(0);			/* disable interrupts */
 1.2      matt 		e500_splset(ci, old_ipl);	/* and drop back */
 1.2      matt 	}
 1.2      matt #endif /* __HAVE_FAST_SOFTINTS */
 1.2      matt 	KASSERT(ci->ci_cpl == old_ipl);
 1.2      matt
1.13      matt 	/*
1.13      matt 	 * If we interrupted while power-saving and we need to exit idle,
1.13      matt 	 * we need to clear PSL_POW so we won't go back into power-saving.
1.13      matt 	 */
1.13      matt 	if (__predict_false(tf->tf_srr1 & PSL_POW) && ci->ci_want_resched)
1.13      matt 		tf->tf_srr1 &= ~PSL_POW;
1.13      matt
 1.2      matt //	printf("%s(%p): idepth=%d exit\n", __func__, tf, ci->ci_idepth);
 1.2      matt }
 1.2      matt
 1.2      matt static void
 1.2      matt e500_intr_init(void)
 1.2      matt {
 1.2      matt 	struct cpu_info * const ci = curcpu();
 1.2      matt 	struct cpu_softc * const cpu = ci->ci_softc;
 1.2      matt 	const uint32_t frr = openpic_read(cpu, OPENPIC_FRR);
 1.2      matt 	const u_int nirq = FRR_NIRQ_GET(frr) + 1;
 1.2      matt //	const u_int ncpu = FRR_NCPU_GET(frr) + 1;
 1.2      matt 	struct intr_source *is;
 1.2      matt 	struct e500_intr_info * const ii = &e500_intr_info;
 1.2      matt
 1.4      matt 	const uint16_t svr = (mfspr(SPR_SVR) & ~0x80000) >> 16;
 1.3      matt 	switch (svr) {
 1.3      matt #ifdef MPC8536
 1.3      matt 	case SVR_MPC8536v1 >> 16:
 1.3      matt 		*ii = mpc8536_intr_info;
 1.3      matt 		break;
 1.3      matt #endif
 1.3      matt #ifdef MPC8544
 1.3      matt 	case SVR_MPC8544v1 >> 16:
 1.3      matt 		*ii = mpc8544_intr_info;
 1.3      matt 		break;
 1.3      matt #endif
 1.3      matt #ifdef MPC8548
 1.3      matt 	case SVR_MPC8543v1 >> 16:
 1.3      matt 	case SVR_MPC8548v1 >> 16:
 1.2      matt 		*ii = mpc8548_intr_info;
 1.2      matt 		break;
 1.3      matt #endif
 1.3      matt #ifdef MPC8555
 1.3      matt 	case SVR_MPC8541v1 >> 16:
 1.3      matt 	case SVR_MPC8555v1 >> 16:
 1.3      matt 		*ii = mpc8555_intr_info;
 1.3      matt 		break;
 1.3      matt #endif
 1.3      matt #ifdef MPC8568
 1.3      matt 	case SVR_MPC8568v1 >> 16:
 1.3      matt 		*ii = mpc8568_intr_info;
 1.2      matt 		break;
 1.3      matt #endif
 1.3      matt #ifdef MPC8572
 1.3      matt 	case SVR_MPC8572v1 >> 16:
 1.2      matt 		*ii = mpc8572_intr_info;
 1.2      matt 		break;
 1.3      matt #endif
1.28    nonaka #ifdef P1023
1.28    nonaka 	case SVR_P1017v1 >> 16:
1.28    nonaka 	case SVR_P1023v1 >> 16:
1.28    nonaka 		*ii = p1023_intr_info;
1.28    nonaka 		break;
1.28    nonaka #endif
1.19      matt #ifdef P1025
1.19      matt 	case SVR_P1016v1 >> 16:
1.19      matt 	case SVR_P1025v1 >> 16:
1.19      matt 		*ii = p1025_intr_info;
1.19      matt 		break;
1.19      matt #endif
 1.3      matt #ifdef P2020
 1.3      matt 	case SVR_P2010v2 >> 16:
 1.3      matt 	case SVR_P2020v2 >> 16:
 1.3      matt 		*ii = p20x0_intr_info;
 1.3      matt 		break;
 1.3      matt #endif
 1.2      matt 	default:
1.37      flxd 		panic("%s: don't know how to deal with SVR %#jx",
1.37      flxd 		    __func__, (uintmax_t)mfspr(SPR_SVR));
 1.2      matt 	}
 1.2      matt
 1.2      matt 	/*
1.29    nonaka 	 * Initialize interrupt handler lock
1.29    nonaka 	 */
1.29    nonaka 	mutex_init(&e500_intr_lock, MUTEX_DEFAULT, IPL_HIGH);
1.29    nonaka
1.29    nonaka 	/*
 1.2      matt 	 * We need to be in mixed mode.
 1.2      matt 	 */
 1.2      matt 	openpic_write(cpu, OPENPIC_GCR, GCR_M);
 1.2      matt
 1.2      matt 	/*
 1.2      matt 	 * Make we and the openpic both agree about the current SPL level.
 1.2      matt 	 */
 1.2      matt 	e500_splset(ci, ci->ci_cpl);
 1.2      matt
 1.2      matt 	/*
 1.2      matt 	 * Allow the required number of interrupt sources.
 1.2      matt 	 */
 1.2      matt 	is = kmem_zalloc(nirq * sizeof(*is), KM_SLEEP);
 1.2      matt 	e500_intr_sources = is;
 1.2      matt 	e500_intr_last_source = is + nirq;
 1.2      matt
 1.2      matt 	/*
 1.2      matt 	 * Initialize all the external interrupts as active low.
 1.2      matt 	 */
 1.2      matt 	for (u_int irq = 0; irq < e500_intr_info.ii_external_sources; irq++) {
 1.2      matt 		openpic_write(cpu, OPENPIC_EIVPR(irq),
 1.2      matt 		    VPR_VECTOR_MAKE(irq) | VPR_LEVEL_LOW);
 1.2      matt 	}
 1.2      matt }
 1.2      matt
 1.2      matt static void
1.32    nonaka e500_intr_init_precpu(void)
1.32    nonaka {
1.32    nonaka 	struct cpu_info const *ci = curcpu();
1.32    nonaka 	struct cpu_softc * const cpu = ci->ci_softc;
1.32    nonaka 	bus_addr_t dr;
1.32    nonaka
1.32    nonaka 	/*
1.32    nonaka 	 * timer's DR is set to be delivered to cpu0 as initial value.
1.32    nonaka 	 */
1.32    nonaka 	for (u_int irq = 0; irq < e500_intr_info.ii_timer_sources; irq++) {
1.32    nonaka 		dr = OPENPIC_GTDR(ci->ci_cpuid, irq);
1.32    nonaka 		openpic_write(cpu, dr, 0);	/* stop delivery */
1.32    nonaka 	}
1.32    nonaka }
1.32    nonaka
1.32    nonaka static void
 1.9      matt e500_idlespin(void)
 1.9      matt {
 1.9      matt 	KASSERTMSG(curcpu()->ci_cpl == IPL_NONE,
1.16       jym 	    "%s: cpu%u: ci_cpl (%d) != 0", __func__, cpu_number(),
1.16       jym 	     curcpu()->ci_cpl);
 1.9      matt 	KASSERTMSG(CTPR2IPL(openpic_read(curcpu()->ci_softc, OPENPIC_CTPR)) == IPL_NONE,
1.16       jym 	    "%s: cpu%u: CTPR (%d) != IPL_NONE", __func__, cpu_number(),
1.16       jym 	     CTPR2IPL(openpic_read(curcpu()->ci_softc, OPENPIC_CTPR)));
 1.9      matt 	KASSERT(mfmsr() & PSL_EE);
1.13      matt
1.13      matt 	if (powersave > 0)
1.13      matt 		mtmsr(mfmsr() | PSL_POW);
 1.9      matt }
 1.9      matt
 1.9      matt static void
 1.8      matt e500_intr_cpu_attach(struct cpu_info *ci)
 1.2      matt {
 1.2      matt 	struct cpu_softc * const cpu = ci->ci_softc;
 1.2      matt 	const char * const xname = device_xname(ci->ci_dev);
 1.2      matt
 1.2      matt 	const u_int32_t frr = openpic_read(cpu, OPENPIC_FRR);
 1.2      matt 	const u_int nirq = FRR_NIRQ_GET(frr) + 1;
 1.2      matt //	const u_int ncpu = FRR_NCPU_GET(frr) + 1;
 1.2      matt
 1.2      matt 	const struct e500_intr_info * const info = &e500_intr_info;
 1.2      matt
 1.2      matt 	cpu->cpu_clock_gtbcr = OPENPIC_GTBCR(ci->ci_cpuid, E500_CLOCK_TIMER);
 1.2      matt
 1.2      matt 	cpu->cpu_evcnt_intrs =
 1.2      matt 	    kmem_zalloc(nirq * sizeof(cpu->cpu_evcnt_intrs[0]), KM_SLEEP);
 1.2      matt
 1.2      matt 	struct evcnt *evcnt = cpu->cpu_evcnt_intrs;
 1.2      matt 	for (size_t j = 0; j < info->ii_external_sources; j++, evcnt++) {
 1.2      matt 		const char *name = e500_intr_external_name_lookup(j);
 1.2      matt 		evcnt_attach_dynamic(evcnt, EVCNT_TYPE_INTR, NULL, xname, name);
 1.2      matt 	}
 1.2      matt 	KASSERT(evcnt == cpu->cpu_evcnt_intrs + info->ii_ist_vectors[IST_ONCHIP]);
 1.2      matt 	for (size_t j = 0; j < info->ii_onchip_sources; j++, evcnt++) {
 1.5      matt 		if (info->ii_onchip_bitmap[j / 32] & __BIT(j & 31)) {
 1.5      matt 			const char *name = e500_intr_onchip_name_lookup(j);
 1.5      matt 			if (name != NULL) {
 1.5      matt 				evcnt_attach_dynamic(evcnt, EVCNT_TYPE_INTR,
 1.5      matt 				    NULL, xname, name);
 1.5      matt #ifdef DIAGNOSTIC
 1.5      matt 			} else {
 1.5      matt 				printf("%s: missing evcnt for onchip irq %zu\n",
 1.5      matt 				    __func__, j);
 1.5      matt #endif
 1.5      matt 			}
 1.2      matt 		}
 1.2      matt 	}
 1.2      matt
 1.2      matt 	KASSERT(evcnt == cpu->cpu_evcnt_intrs + info->ii_ist_vectors[IST_MSIGROUP]);
 1.2      matt 	for (size_t j = 0; j < info->ii_msigroup_sources; j++, evcnt++) {
 1.2      matt 		evcnt_attach_dynamic(evcnt, EVCNT_TYPE_INTR,
 1.2      matt 		    NULL, xname, e500_msigroup_intr_names[j].in_name);
 1.2      matt 	}
 1.2      matt
 1.2      matt 	KASSERT(evcnt == cpu->cpu_evcnt_intrs + info->ii_ist_vectors[IST_TIMER]);
 1.2      matt 	evcnt += ci->ci_cpuid * info->ii_percpu_sources;
 1.2      matt 	for (size_t j = 0; j < info->ii_timer_sources; j++, evcnt++) {
 1.2      matt 		evcnt_attach_dynamic(evcnt, EVCNT_TYPE_INTR,
 1.2      matt 		    NULL, xname, e500_timer_intr_names[j].in_name);
 1.2      matt 	}
 1.2      matt
 1.2      matt 	for (size_t j = 0; j < info->ii_ipi_sources; j++, evcnt++) {
 1.2      matt 		evcnt_attach_dynamic(evcnt, EVCNT_TYPE_INTR,
 1.2      matt 		    NULL, xname, e500_ipi_intr_names[j].in_name);
 1.2      matt 	}
 1.2      matt
 1.2      matt 	for (size_t j = 0; j < info->ii_mi_sources; j++, evcnt++) {
 1.2      matt 		evcnt_attach_dynamic(evcnt, EVCNT_TYPE_INTR,
 1.2      matt 		    NULL, xname, e500_mi_intr_names[j].in_name);
 1.2      matt 	}
 1.9      matt
 1.9      matt 	ci->ci_idlespin = e500_idlespin;
 1.8      matt }
 1.8      matt
 1.8      matt static void
 1.8      matt e500_intr_cpu_send_ipi(cpuid_t target, uint32_t ipimsg)
 1.8      matt {
 1.8      matt 	struct cpu_info * const ci = curcpu();
 1.8      matt 	struct cpu_softc * const cpu = ci->ci_softc;
 1.8      matt 	uint32_t dstmask;
 1.8      matt
1.14      matt 	if (target >= CPU_MAXNUM) {
 1.8      matt 		CPU_INFO_ITERATOR cii;
 1.8      matt 		struct cpu_info *dst_ci;
 1.8      matt
 1.8      matt 		KASSERT(target == IPI_DST_NOTME || target == IPI_DST_ALL);
 1.8      matt
 1.8      matt 		dstmask = 0;
 1.8      matt 		for (CPU_INFO_FOREACH(cii, dst_ci)) {
 1.8      matt 			if (target == IPI_DST_ALL || ci != dst_ci) {
 1.8      matt 				dstmask |= 1 << cpu_index(ci);
 1.8      matt 				if (ipimsg)
 1.8      matt 					atomic_or_32(&dst_ci->ci_pending_ipis,
 1.8      matt 					    ipimsg);
 1.8      matt 			}
 1.8      matt 		}
 1.8      matt 	} else {
 1.8      matt 		struct cpu_info * const dst_ci = cpu_lookup(target);
1.14      matt 		KASSERT(dst_ci != NULL);
1.14      matt 		KASSERTMSG(target == cpu_index(dst_ci),
1.16       jym 		    "%s: target (%lu) != cpu_index(cpu%u)",
1.16       jym 		     __func__, target, cpu_index(dst_ci));
 1.8      matt 		dstmask = (1 << target);
 1.8      matt 		if (ipimsg)
 1.8      matt 			atomic_or_32(&dst_ci->ci_pending_ipis, ipimsg);
 1.8      matt 	}
 1.8      matt
1.27    nonaka 	openpic_write(cpu, OPENPIC_IPIDR(0), dstmask);
 1.8      matt }
 1.8      matt
 1.8      matt typedef void (*ipifunc_t)(void);
 1.8      matt
1.33  jmcneill #ifdef __HAVE_PREEMPTION
 1.8      matt static void
 1.8      matt e500_ipi_kpreempt(void)
 1.8      matt {
1.10      matt 	poowerpc_softint_trigger(1 << IPL_NONE);
 1.8      matt }
 1.8      matt #endif
 1.8      matt
1.31    nonaka static void
1.31    nonaka e500_ipi_suspend(void)
1.31    nonaka {
1.31    nonaka
1.31    nonaka #ifdef MULTIPROCESSOR
1.31    nonaka 	cpu_pause(NULL);
1.31    nonaka #endif	/* MULTIPROCESSOR */
1.31    nonaka }
1.31    nonaka
 1.8      matt static const ipifunc_t e500_ipifuncs[] = {
 1.8      matt 	[ilog2(IPI_XCALL)] =	xc_ipi_handler,
1.24     rmind 	[ilog2(IPI_GENERIC)] =	ipi_cpu_handler,
 1.8      matt 	[ilog2(IPI_HALT)] =	e500_ipi_halt,
 1.8      matt #ifdef __HAVE_PREEMPTION
 1.8      matt 	[ilog2(IPI_KPREEMPT)] =	e500_ipi_kpreempt,
 1.8      matt #endif
 1.8      matt 	[ilog2(IPI_TLB1SYNC)] =	e500_tlb1_sync,
1.31    nonaka 	[ilog2(IPI_SUSPEND)] =	e500_ipi_suspend,
 1.8      matt };
 1.8      matt
 1.8      matt static int
 1.8      matt e500_ipi_intr(void *v)
 1.8      matt {
 1.8      matt 	struct cpu_info * const ci = curcpu();
 1.8      matt
 1.8      matt 	ci->ci_ev_ipi.ev_count++;
 1.8      matt
 1.8      matt 	uint32_t pending_ipis = atomic_swap_32(&ci->ci_pending_ipis, 0);
 1.8      matt 	for (u_int ipi = 31; pending_ipis != 0; ipi--, pending_ipis <<= 1) {
 1.8      matt 		const u_int bits = __builtin_clz(pending_ipis);
 1.8      matt 		ipi -= bits;
 1.8      matt 		pending_ipis <<= bits;
 1.8      matt 		KASSERT(e500_ipifuncs[ipi] != NULL);
 1.8      matt 		(*e500_ipifuncs[ipi])();
 1.8      matt 	}
 1.8      matt
 1.8      matt 	return 1;
 1.8      matt }
 1.2      matt
 1.8      matt static void
 1.8      matt e500_intr_cpu_hatch(struct cpu_info *ci)
 1.8      matt {
1.34    nonaka 	char iname[INTRIDBUF];
1.32    nonaka
1.32    nonaka 	/* Initialize percpu interupts. */
1.32    nonaka 	e500_intr_init_precpu();
1.32    nonaka
 1.2      matt 	/*
 1.8      matt 	 * Establish clock interrupt for this CPU.
 1.2      matt 	 */
1.34    nonaka 	snprintf(iname, sizeof(iname), "%s clock", device_xname(ci->ci_dev));
 1.2      matt 	if (e500_intr_cpu_establish(ci, E500_CLOCK_TIMER, IPL_CLOCK, IST_TIMER,
1.34    nonaka 	    e500_clock_intr, NULL, iname) == NULL)
 1.2      matt 		panic("%s: failed to establish clock interrupt!", __func__);
 1.2      matt
 1.2      matt 	/*
 1.8      matt 	 * Establish the IPI interrupts for this CPU.
 1.8      matt 	 */
1.27    nonaka 	if (e500_intr_cpu_establish(ci, 0, IPL_VM, IST_IPI, e500_ipi_intr,
1.34    nonaka 	    NULL, "ipi") == NULL)
 1.8      matt 		panic("%s: failed to establish ipi interrupt!", __func__);
 1.8      matt
 1.8      matt 	/*
 1.2      matt 	 * Enable watchdog interrupts.
 1.2      matt 	 */
 1.2      matt 	uint32_t tcr = mfspr(SPR_TCR);
 1.2      matt 	tcr |= TCR_WIE;
 1.2      matt 	mtspr(SPR_TCR, tcr);
 1.2      matt }
1.34    nonaka
1.34    nonaka static const char *
1.34    nonaka e500_intr_all_name_lookup(int irq, int ist)
1.34    nonaka {
1.34    nonaka 	const struct e500_intr_info * const info = &e500_intr_info;
1.34    nonaka
1.34    nonaka 	switch (ist) {
1.34    nonaka 	default:
1.34    nonaka 		if (irq < info->ii_external_sources &&
1.34    nonaka 		    (ist == IST_EDGE ||
1.34    nonaka 		     ist == IST_LEVEL_LOW ||
1.34    nonaka 		     ist == IST_LEVEL_HIGH))
1.34    nonaka 			return e500_intr_name_lookup(
1.34    nonaka 			    info->ii_external_intr_names, irq);
1.34    nonaka 		break;
1.34    nonaka
1.34    nonaka 	case IST_PULSE:
1.34    nonaka 		break;
1.34    nonaka
1.34    nonaka 	case IST_ONCHIP:
1.34    nonaka 		if (irq < info->ii_onchip_sources)
1.34    nonaka 			return e500_intr_onchip_name_lookup(irq);
1.34    nonaka 		break;
1.34    nonaka
1.34    nonaka 	case IST_MSIGROUP:
1.34    nonaka 		if (irq < info->ii_msigroup_sources)
1.34    nonaka 			return e500_intr_name_lookup(e500_msigroup_intr_names,
1.34    nonaka 			    irq);
1.34    nonaka 		break;
1.34    nonaka
1.34    nonaka 	case IST_TIMER:
1.34    nonaka 		if (irq < info->ii_timer_sources)
1.34    nonaka 			return e500_intr_name_lookup(e500_timer_intr_names,
1.34    nonaka 			    irq);
1.34    nonaka 		break;
1.34    nonaka
1.34    nonaka 	case IST_IPI:
1.34    nonaka 		if (irq < info->ii_ipi_sources)
1.34    nonaka 			return e500_intr_name_lookup(e500_ipi_intr_names, irq);
1.34    nonaka 		break;
1.34    nonaka
1.34    nonaka 	case IST_MI:
1.34    nonaka 		if (irq < info->ii_mi_sources)
1.34    nonaka 			return e500_intr_name_lookup(e500_mi_intr_names, irq);
1.34    nonaka 		break;
1.34    nonaka 	}
1.34    nonaka
1.34    nonaka 	return NULL;
1.34    nonaka }
1.34    nonaka
1.34    nonaka static void
1.34    nonaka e500_intr_get_affinity(struct intr_source *is, kcpuset_t *cpuset)
1.34    nonaka {
1.34    nonaka 	struct cpu_info * const ci = curcpu();
1.34    nonaka 	struct cpu_softc * const cpu = ci->ci_softc;
1.34    nonaka 	struct e500_intr_irq_info ii;
1.34    nonaka
1.34    nonaka 	kcpuset_zero(cpuset);
1.34    nonaka
1.34    nonaka 	if (is->is_ipl != IPL_NONE && !IST_PERCPU_P(is->is_ist)) {
1.34    nonaka 		if (e500_intr_irq_info_get(ci, is->is_irq, is->is_ipl,
1.34    nonaka 		    is->is_ist, &ii)) {
1.34    nonaka 			uint32_t dr = openpic_read(cpu, ii.irq_dr);
1.34    nonaka 			while (dr != 0) {
1.34    nonaka 				u_int n = ffs(dr);
1.34    nonaka 				if (n-- == 0)
1.34    nonaka 					break;
1.34    nonaka 				dr &= ~(1 << n);
1.34    nonaka 				kcpuset_set(cpuset, n);
1.34    nonaka 			}
1.34    nonaka 		}
1.34    nonaka 	}
1.34    nonaka }
1.34    nonaka
1.34    nonaka static int
1.34    nonaka e500_intr_set_affinity(struct intr_source *is, const kcpuset_t *cpuset)
1.34    nonaka {
1.34    nonaka 	struct cpu_info * const ci = curcpu();
1.34    nonaka 	struct cpu_softc * const cpu = ci->ci_softc;
1.34    nonaka 	struct e500_intr_irq_info ii;
1.34    nonaka 	uint32_t ecpuset, tcpuset;
1.34    nonaka
1.34    nonaka 	KASSERT(mutex_owned(&cpu_lock));
1.34    nonaka 	KASSERT(mutex_owned(&e500_intr_lock));
1.34    nonaka 	KASSERT(!kcpuset_iszero(cpuset));
1.34    nonaka
1.34    nonaka 	kcpuset_export_u32(cpuset, &ecpuset, sizeof(ecpuset));
1.34    nonaka 	tcpuset = ecpuset;
1.34    nonaka 	while (tcpuset != 0) {
1.34    nonaka 		u_int cpu_idx = ffs(tcpuset);
1.34    nonaka 		if (cpu_idx-- == 0)
1.34    nonaka 			break;
1.34    nonaka
1.34    nonaka 		tcpuset &= ~(1 << cpu_idx);
1.34    nonaka 		struct cpu_info * const newci = cpu_lookup(cpu_idx);
1.34    nonaka 		if (newci == NULL)
1.34    nonaka 			return EINVAL;
1.34    nonaka 		if ((newci->ci_schedstate.spc_flags & SPCF_NOINTR) != 0)
1.34    nonaka 			return EINVAL;
1.34    nonaka 	}
1.34    nonaka
1.34    nonaka 	if (!e500_intr_irq_info_get(ci, is->is_irq, is->is_ipl, is->is_ist,
1.34    nonaka 	    &ii))
1.34    nonaka 		return ENXIO;
1.34    nonaka
1.34    nonaka 	/*
1.34    nonaka 	 * Update the vector/priority and destination registers keeping the
1.34    nonaka 	 * interrupt masked.
1.34    nonaka 	 */
1.34    nonaka 	const register_t msr = wrtee(0);	/* disable interrupts */
1.34    nonaka
1.34    nonaka 	uint32_t vpr = openpic_read(cpu, ii.irq_vpr);
1.34    nonaka 	openpic_write(cpu, ii.irq_vpr, vpr | VPR_MSK);
1.34    nonaka
1.34    nonaka 	/*
1.34    nonaka 	 * Wait for the Activity (A) bit for the source to be cleared.
1.34    nonaka 	 */
1.34    nonaka 	while (openpic_read(cpu, ii.irq_vpr) & VPR_A)
1.34    nonaka 		continue;
1.34    nonaka
1.34    nonaka 	/*
1.34    nonaka 	 * Update destination register
1.34    nonaka 	 */
1.34    nonaka 	openpic_write(cpu, ii.irq_dr, ecpuset);
1.34    nonaka
1.34    nonaka 	/*
1.34    nonaka 	 * Now unmask the interrupt.
1.34    nonaka 	 */
1.34    nonaka 	openpic_write(cpu, ii.irq_vpr, vpr);
1.34    nonaka
1.34    nonaka 	wrtee(msr);				/* re-enable interrupts */
1.34    nonaka
1.34    nonaka 	return 0;
1.34    nonaka }
1.34    nonaka
1.34    nonaka static bool
1.34    nonaka e500_intr_is_affinity_intrsource(struct intr_source *is,
1.34    nonaka     const kcpuset_t *cpuset)
1.34    nonaka {
1.34    nonaka 	struct cpu_info * const ci = curcpu();
1.34    nonaka 	struct cpu_softc * const cpu = ci->ci_softc;
1.34    nonaka 	struct e500_intr_irq_info ii;
1.34    nonaka 	bool result = false;
1.34    nonaka
1.34    nonaka 	if (is->is_ipl != IPL_NONE && !IST_PERCPU_P(is->is_ist)) {
1.34    nonaka 		if (e500_intr_irq_info_get(ci, is->is_irq, is->is_ipl,
1.34    nonaka 		    is->is_ist, &ii)) {
1.34    nonaka 			uint32_t dr = openpic_read(cpu, ii.irq_dr);
1.34    nonaka 			while (dr != 0 && !result) {
1.34    nonaka 				u_int n = ffs(dr);
1.34    nonaka 				if (n-- == 0)
1.34    nonaka 					break;
1.34    nonaka 				dr &= ~(1 << n);
1.34    nonaka 				result = kcpuset_isset(cpuset, n);
1.34    nonaka 			}
1.34    nonaka 		}
1.34    nonaka 	}
1.34    nonaka 	return result;
1.34    nonaka }
1.34    nonaka
1.34    nonaka static struct intr_source *
1.34    nonaka e500_intr_get_source(const char *intrid)
1.34    nonaka {
1.34    nonaka 	struct intr_source *is;
1.34    nonaka
1.34    nonaka 	mutex_enter(&e500_intr_lock);
1.34    nonaka 	for (is = e500_intr_sources; is < e500_intr_last_source; ++is) {
1.34    nonaka 		if (is->is_source[0] == '\0')
1.34    nonaka 			continue;
1.34    nonaka
1.34    nonaka 		if (!strncmp(intrid, is->is_source, sizeof(is->is_source) - 1))
1.34    nonaka 			break;
1.34    nonaka 	}
1.34    nonaka 	if (is == e500_intr_last_source)
1.34    nonaka 		is = NULL;
1.34    nonaka 	mutex_exit(&e500_intr_lock);
1.34    nonaka 	return is;
1.34    nonaka }
1.34    nonaka
1.34    nonaka uint64_t
1.34    nonaka interrupt_get_count(const char *intrid, u_int cpu_idx)
1.34    nonaka {
1.34    nonaka 	struct cpu_info * const ci = cpu_lookup(cpu_idx);
1.34    nonaka 	struct cpu_softc * const cpu = ci->ci_softc;
1.34    nonaka 	struct intr_source *is;
1.34    nonaka 	struct e500_intr_irq_info ii;
1.34    nonaka
1.34    nonaka 	is = e500_intr_get_source(intrid);
1.34    nonaka 	if (is == NULL)
1.34    nonaka 		return 0;
1.34    nonaka
1.34    nonaka 	if (e500_intr_irq_info_get(ci, is->is_irq, is->is_ipl, is->is_ist, &ii))
1.34    nonaka 		return cpu->cpu_evcnt_intrs[ii.irq_vector].ev_count;
1.34    nonaka 	return 0;
1.34    nonaka }
1.34    nonaka
1.34    nonaka void
1.34    nonaka interrupt_get_assigned(const char *intrid, kcpuset_t *cpuset)
1.34    nonaka {
1.34    nonaka 	struct intr_source *is;
1.34    nonaka
1.34    nonaka 	kcpuset_zero(cpuset);
1.34    nonaka
1.34    nonaka 	is = e500_intr_get_source(intrid);
1.34    nonaka 	if (is == NULL)
1.34    nonaka 		return;
1.34    nonaka
1.34    nonaka 	mutex_enter(&e500_intr_lock);
1.34    nonaka 	e500_intr_get_affinity(is, cpuset);
1.34    nonaka 	mutex_exit(&e500_intr_lock);
1.34    nonaka }
1.34    nonaka
1.34    nonaka void
1.34    nonaka interrupt_get_available(kcpuset_t *cpuset)
1.34    nonaka {
1.34    nonaka 	CPU_INFO_ITERATOR cii;
1.34    nonaka 	struct cpu_info *ci;
1.34    nonaka
1.34    nonaka 	kcpuset_zero(cpuset);
1.34    nonaka
1.34    nonaka 	mutex_enter(&cpu_lock);
1.34    nonaka 	for (CPU_INFO_FOREACH(cii, ci)) {
1.34    nonaka 		if ((ci->ci_schedstate.spc_flags & SPCF_NOINTR) == 0)
1.34    nonaka 			kcpuset_set(cpuset, cpu_index(ci));
1.34    nonaka 	}
1.34    nonaka 	mutex_exit(&cpu_lock);
1.34    nonaka }
1.34    nonaka
1.34    nonaka void
1.34    nonaka interrupt_get_devname(const char *intrid, char *buf, size_t len)
1.34    nonaka {
1.34    nonaka 	struct intr_source *is;
1.34    nonaka
1.34    nonaka 	if (len == 0)
1.34    nonaka 		return;
1.34    nonaka
1.34    nonaka 	buf[0] = '\0';
1.34    nonaka
1.34    nonaka 	is = e500_intr_get_source(intrid);
1.34    nonaka 	if (is != NULL)
1.34    nonaka 		strlcpy(buf, is->is_xname, len);
1.34    nonaka }
1.34    nonaka
1.34    nonaka struct intrids_handler *
1.34    nonaka interrupt_construct_intrids(const kcpuset_t *cpuset)
1.34    nonaka {
1.34    nonaka 	struct intr_source *is;
1.34    nonaka 	struct intrids_handler *ii_handler;
1.34    nonaka 	intrid_t *ids;
1.34    nonaka 	int i, n;
1.34    nonaka
1.34    nonaka 	if (kcpuset_iszero(cpuset))
1.34    nonaka 		return NULL;
1.34    nonaka
1.34    nonaka 	n = 0;
1.34    nonaka 	mutex_enter(&e500_intr_lock);
1.34    nonaka 	for (is = e500_intr_sources; is < e500_intr_last_source; ++is) {
1.34    nonaka 		if (e500_intr_is_affinity_intrsource(is, cpuset))
1.34    nonaka 			++n;
1.34    nonaka 	}
1.34    nonaka 	mutex_exit(&e500_intr_lock);
1.34    nonaka
1.34    nonaka 	const size_t alloc_size = sizeof(int) + sizeof(intrid_t) * n;
1.34    nonaka 	ii_handler = kmem_zalloc(alloc_size, KM_SLEEP);
1.34    nonaka 	ii_handler->iih_nids = n;
1.34    nonaka 	if (n == 0)
1.34    nonaka 		return ii_handler;
1.34    nonaka
1.34    nonaka 	ids = ii_handler->iih_intrids;
1.34    nonaka 	mutex_enter(&e500_intr_lock);
1.34    nonaka 	for (i = 0, is = e500_intr_sources;
1.34    nonaka 	     i < n && is < e500_intr_last_source;
1.34    nonaka 	     ++is) {
1.34    nonaka 		if (!e500_intr_is_affinity_intrsource(is, cpuset))
1.34    nonaka 			continue;
1.34    nonaka
1.34    nonaka 		if (is->is_source[0] != '\0') {
1.34    nonaka 			strlcpy(ids[i], is->is_source, sizeof(ids[0]));
1.34    nonaka 			++i;
1.34    nonaka 		}
1.34    nonaka 	}
1.34    nonaka 	mutex_exit(&e500_intr_lock);
1.34    nonaka
1.34    nonaka 	return ii_handler;
1.34    nonaka }
1.34    nonaka
1.34    nonaka void
1.34    nonaka interrupt_destruct_intrids(struct intrids_handler *ii_handler)
1.34    nonaka {
1.34    nonaka 	size_t iih_size;
1.34    nonaka
1.34    nonaka 	if (ii_handler == NULL)
1.34    nonaka 		return;
1.34    nonaka
1.34    nonaka 	iih_size = sizeof(int) + sizeof(intrid_t) * ii_handler->iih_nids;
1.34    nonaka 	kmem_free(ii_handler, iih_size);
1.34    nonaka }
1.34    nonaka
1.34    nonaka static int
1.34    nonaka interrupt_distribute_locked(struct intr_source *is, const kcpuset_t *newset,
1.34    nonaka     kcpuset_t *oldset)
1.34    nonaka {
1.34    nonaka 	int error;
1.34    nonaka
1.34    nonaka 	KASSERT(mutex_owned(&cpu_lock));
1.34    nonaka
1.34    nonaka 	if (is->is_ipl == IPL_NONE || IST_PERCPU_P(is->is_ist))
1.34    nonaka 		return EINVAL;
1.34    nonaka
1.34    nonaka 	mutex_enter(&e500_intr_lock);
1.34    nonaka 	if (oldset != NULL)
1.34    nonaka 		e500_intr_get_affinity(is, oldset);
1.34    nonaka 	error = e500_intr_set_affinity(is, newset);
1.34    nonaka 	mutex_exit(&e500_intr_lock);
1.34    nonaka
1.34    nonaka 	return error;
1.34    nonaka }
1.34    nonaka
1.34    nonaka int
1.34    nonaka interrupt_distribute(void *ich, const kcpuset_t *newset, kcpuset_t *oldset)
1.34    nonaka {
1.34    nonaka 	int error;
1.34    nonaka
1.34    nonaka 	mutex_enter(&cpu_lock);
1.34    nonaka 	error = interrupt_distribute_locked(ich, newset, oldset);
1.34    nonaka 	mutex_exit(&cpu_lock);
1.34    nonaka
1.34    nonaka 	return error;
1.34    nonaka }
1.34    nonaka
1.34    nonaka int
1.34    nonaka interrupt_distribute_handler(const char *intrid, const kcpuset_t *newset,
1.34    nonaka     kcpuset_t *oldset)
1.34    nonaka {
1.34    nonaka 	struct intr_source *is;
1.34    nonaka 	int error;
1.34    nonaka
1.34    nonaka 	is = e500_intr_get_source(intrid);
1.34    nonaka 	if (is != NULL) {
1.34    nonaka 		mutex_enter(&cpu_lock);
1.34    nonaka 		error = interrupt_distribute_locked(is, newset, oldset);
1.34    nonaka 		mutex_exit(&cpu_lock);
1.34    nonaka 	} else
1.34    nonaka 		error = ENOENT;
1.34    nonaka
1.34    nonaka 	return error;
1.34    nonaka }