evbmips/ingenic/intr.c

1.3  macallan /*	$NetBSD: intr.c,v 1.3 2014/12/23 16:17:39 macallan Exp $ */
1.1  macallan
1.1  macallan /*-
1.1  macallan  * Copyright (c) 2014 Michael Lorenz
1.1  macallan  * All rights reserved.
1.1  macallan  *
1.1  macallan  * Redistribution and use in source and binary forms, with or without
1.1  macallan  * modification, are permitted provided that the following conditions
1.1  macallan  * are met:
1.1  macallan  * 1. Redistributions of source code must retain the above copyright
1.1  macallan  *    notice, this list of conditions and the following disclaimer.
1.1  macallan  * 2. Redistributions in binary form must reproduce the above copyright
1.1  macallan  *    notice, this list of conditions and the following disclaimer in the
1.1  macallan  *    documentation and/or other materials provided with the distribution.
1.1  macallan  *
1.1  macallan  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.1  macallan  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  macallan  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  macallan  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1  macallan  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  macallan  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  macallan  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  macallan  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  macallan  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  macallan  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  macallan  * POSSIBILITY OF SUCH DAMAGE.
1.1  macallan  */
1.1  macallan
1.1  macallan #include <sys/cdefs.h>
1.3  macallan __KERNEL_RCSID(0, "$NetBSD: intr.c,v 1.3 2014/12/23 16:17:39 macallan Exp $");
1.1  macallan
1.1  macallan #define __INTR_PRIVATE
1.1  macallan
1.1  macallan #include <sys/param.h>
1.1  macallan #include <sys/cpu.h>
1.1  macallan #include <sys/device.h>
1.1  macallan #include <sys/kernel.h>
1.1  macallan #include <sys/systm.h>
1.1  macallan #include <sys/timetc.h>
1.2  macallan #include <sys/bitops.h>
1.1  macallan
1.1  macallan #include <mips/locore.h>
1.1  macallan #include <machine/intr.h>
1.1  macallan
1.1  macallan #include <mips/ingenic/ingenic_regs.h>
1.1  macallan
1.2  macallan #include "opt_ingenic.h"
1.2  macallan
1.1  macallan extern void ingenic_clockintr(uint32_t);
1.1  macallan extern void ingenic_puts(const char *);
1.1  macallan
1.1  macallan /*
1.1  macallan  * This is a mask of bits to clear in the SR when we go to a
1.1  macallan  * given hardware interrupt priority level.
1.1  macallan  */
1.1  macallan static const struct ipl_sr_map ingenic_ipl_sr_map = {
1.1  macallan     .sr_bits = {
1.1  macallan 	[IPL_NONE] =		0,
1.1  macallan 	[IPL_SOFTCLOCK] =	MIPS_SOFT_INT_MASK_0,
1.1  macallan 	[IPL_SOFTNET] =		MIPS_SOFT_INT_MASK_0 | MIPS_SOFT_INT_MASK_1,
1.1  macallan 	[IPL_VM] =
1.1  macallan 	    MIPS_SOFT_INT_MASK_0 | MIPS_SOFT_INT_MASK_1 |
1.1  macallan 	    MIPS_INT_MASK_0 |
1.1  macallan 	    MIPS_INT_MASK_3 |
1.1  macallan 	    MIPS_INT_MASK_4 |
1.1  macallan 	    MIPS_INT_MASK_5,
1.1  macallan 	[IPL_SCHED] =
1.1  macallan 	    MIPS_SOFT_INT_MASK_0 | MIPS_SOFT_INT_MASK_1 |
1.1  macallan 	    MIPS_INT_MASK_0 |
1.1  macallan 	    MIPS_INT_MASK_1 |
1.1  macallan 	    MIPS_INT_MASK_2 |
1.1  macallan 	    MIPS_INT_MASK_3 |
1.1  macallan 	    MIPS_INT_MASK_4 |
1.1  macallan 	    MIPS_INT_MASK_5,
1.1  macallan 	[IPL_DDB] =		MIPS_INT_MASK,
1.1  macallan 	[IPL_HIGH] =            MIPS_INT_MASK,
1.1  macallan     },
1.1  macallan };
1.1  macallan
1.2  macallan #define NINTR 64
1.2  macallan
1.2  macallan /* some timer channels share interrupts, couldn't find any others */
1.2  macallan struct intrhand {
1.2  macallan 	struct evcnt ih_count;
1.2  macallan 	int (*ih_func)(void *);
1.2  macallan 	void *ih_arg;
1.2  macallan 	int ih_ipl;
1.2  macallan };
1.2  macallan
1.2  macallan struct intrhand intrs[NINTR];
1.2  macallan
1.2  macallan void ingenic_irq(int);
1.2  macallan
1.1  macallan void
1.1  macallan evbmips_intr_init(void)
1.1  macallan {
1.1  macallan 	uint32_t reg;
1.2  macallan 	int i;
1.2  macallan 	char irqstr[8];
1.1  macallan
1.1  macallan 	ipl_sr_map = ingenic_ipl_sr_map;
1.1  macallan
1.2  macallan 	/* zero all handlers */
1.2  macallan 	for (i = 0; i < NINTR; i++) {
1.2  macallan 		intrs[i].ih_func = NULL;
1.2  macallan 		intrs[i].ih_arg = NULL;
1.2  macallan 		snprintf(irqstr, sizeof(irqstr), "irq %d", i);
1.2  macallan 		evcnt_attach_dynamic(&intrs[i].ih_count, EVCNT_TYPE_INTR,
1.2  macallan 		    NULL, "PIC", irqstr);
1.2  macallan 	}
1.2  macallan
1.1  macallan 	/* mask all peripheral IRQs */
1.1  macallan 	writereg(JZ_ICMR0, 0xffffffff);
1.1  macallan 	writereg(JZ_ICMR1, 0xffffffff);
1.1  macallan
1.2  macallan 	/* allow peripheral interrupts to core 0 only */
1.1  macallan 	reg = MFC0(12, 4);	/* reset entry and interrupts */
1.1  macallan 	reg &= 0xffff0000;
1.1  macallan 	reg |= REIM_IRQ0_M | REIM_MIRQ0_M | REIM_MIRQ1_M;
1.1  macallan 	MTC0(reg, 12, 4);
1.1  macallan }
1.1  macallan
1.1  macallan void
1.1  macallan evbmips_iointr(int ipl, vaddr_t pc, uint32_t ipending)
1.1  macallan {
1.1  macallan 	uint32_t id;
1.3  macallan #ifdef INGENIC_INTR_DEBUG
1.1  macallan 	char buffer[256];
1.1  macallan
1.2  macallan 	snprintf(buffer, 256, "pending: %08x CR %08x\n", ipending,
1.2  macallan 	    MFC0(MIPS_COP_0_CAUSE, 0));
1.1  macallan 	ingenic_puts(buffer);
1.1  macallan #endif
1.1  macallan 	/* see which core we're on */
1.1  macallan 	id = MFC0(15, 1) & 7;
1.1  macallan
1.1  macallan 	/*
1.1  macallan 	 * XXX
1.1  macallan 	 * the manual counts the softint bits as INT0 and INT1, out headers
1.1  macallan 	 * don't so everything here looks off by two
1.1  macallan 	 */
1.1  macallan 	if (ipending & MIPS_INT_MASK_1) {
1.1  macallan 		/*
1.1  macallan 		 * this is a mailbox interrupt / IPI
1.1  macallan 		 * for now just print the message and clear it
1.1  macallan 		 */
1.1  macallan 		uint32_t reg;
1.1  macallan
1.1  macallan 		/* read pending IPIs */
1.1  macallan 		reg = MFC0(12, 3);
1.1  macallan 		if (id == 0) {
1.1  macallan 			if (reg & CS_MIRQ0_P) {
1.1  macallan
1.3  macallan #ifdef INGENIC_INTR_DEBUG
1.2  macallan 				snprintf(buffer, 256,
1.2  macallan 				    "IPI for core 0, msg %08x\n",
1.1  macallan 				    MFC0(CP0_CORE_MBOX, 0));
1.1  macallan 				ingenic_puts(buffer);
1.1  macallan #endif
1.1  macallan 				reg &= (~CS_MIRQ0_P);
1.1  macallan 				/* clear it */
1.1  macallan 				MTC0(reg, 12, 3);
1.1  macallan 			}
1.1  macallan 		} else if (id == 1) {
1.1  macallan 			if (reg & CS_MIRQ1_P) {
1.3  macallan #ifdef INGENIC_INTR_DEBUG
1.2  macallan 				snprintf(buffer, 256,
1.2  macallan 				    "IPI for core 1, msg %08x\n",
1.1  macallan 				    MFC0(CP0_CORE_MBOX, 1));
1.1  macallan 				ingenic_puts(buffer);
1.1  macallan #endif
1.1  macallan 				reg &= ( 7 - CS_MIRQ1_P);
1.1  macallan 				/* clear it */
1.1  macallan 				MTC0(reg, 12, 3);
1.1  macallan 			}
1.1  macallan 		}
1.1  macallan 	}
1.1  macallan 	if (ipending & MIPS_INT_MASK_2) {
1.1  macallan 		/* this is a timer interrupt */
1.1  macallan 		ingenic_clockintr(id);
1.1  macallan 		ingenic_puts("INT2\n");
1.1  macallan 	}
1.1  macallan 	if (ipending & MIPS_INT_MASK_0) {
1.1  macallan 		/* peripheral interrupt */
1.1  macallan
1.1  macallan 		/*
1.1  macallan 		 * XXX
1.1  macallan 		 * OS timer interrupts are supposed to show up as INT2 as well
1.1  macallan 		 * but I haven't seen them there so for now we just weed them
1.1  macallan 		 * out right here.
1.1  macallan 		 * The idea is to allow peripheral interrupts on both cores but
1.1  macallan 		 * block INT0 on core1 so it would see only timer interrupts
1.1  macallan 		 * and IPIs. If that doesn't work we'll have to send an IPI to
1.1  macallan 		 * core1 for each timer tick.
1.1  macallan 		 */
1.2  macallan 		if (readreg(JZ_ICPR0) & 0x08000000) {
1.1  macallan 			ingenic_clockintr(id);
1.2  macallan 		}
1.2  macallan 		ingenic_irq(ipl);
1.1  macallan 		KASSERT(id == 0);
1.1  macallan 	}
1.1  macallan }
1.2  macallan
1.2  macallan void
1.2  macallan ingenic_irq(int ipl)
1.2  macallan {
1.2  macallan 	uint32_t irql, irqh, mask;
1.2  macallan 	int bit, idx;
1.3  macallan #ifdef INGENIC_INTR_DEBUG
1.3  macallan 	char buffer[16];
1.3  macallan #endif
1.2  macallan
1.2  macallan 	irql = readreg(JZ_ICPR0);
1.3  macallan #ifdef INGENIC_INTR_DEBUG
1.3  macallan 	if (irql != 0) {
1.3  macallan 		snprintf(buffer, 16, " il%08x", irql);
1.3  macallan 		ingenic_puts(buffer);
1.3  macallan 	}
1.3  macallan #endif
1.2  macallan 	bit = ffs32(irql);
1.2  macallan 	while (bit != 0) {
1.2  macallan 		idx = bit - 1;
1.2  macallan 		mask = 1 << idx;
1.2  macallan 		if (intrs[idx].ih_func != NULL) {
1.2  macallan 			if (intrs[idx].ih_ipl == IPL_VM)
1.2  macallan 				KERNEL_LOCK(1, NULL);
1.2  macallan 			intrs[idx].ih_func(intrs[idx].ih_arg);
1.2  macallan 			if (intrs[idx].ih_ipl == IPL_VM)
1.2  macallan 				KERNEL_UNLOCK_ONE(NULL);
1.2  macallan 			intrs[idx].ih_count.ev_count++;
1.2  macallan 		} else {
1.3  macallan 			/* spurious interrupt, mask it */
1.2  macallan 			writereg(JZ_ICMSR0, mask);
1.2  macallan 		}
1.2  macallan 		irql &= ~mask;
1.2  macallan 		bit = ffs32(irql);
1.2  macallan 	}
1.2  macallan
1.2  macallan 	irqh = readreg(JZ_ICPR1);
1.3  macallan #ifdef INGENIC_INTR_DEBUG
1.3  macallan 	if (irqh != 0) {
1.3  macallan 		snprintf(buffer, 16, " ih%08x", irqh);
1.3  macallan 		ingenic_puts(buffer);
1.3  macallan 	}
1.3  macallan #endif
1.2  macallan 	bit = ffs32(irqh);
1.2  macallan 	while (bit != 0) {
1.2  macallan 		idx = bit - 1;
1.2  macallan 		mask = 1 << idx;
1.2  macallan 		idx += 32;
1.2  macallan 		if (intrs[idx].ih_func != NULL) {
1.2  macallan 			if (intrs[idx].ih_ipl == IPL_VM)
1.2  macallan 				KERNEL_LOCK(1, NULL);
1.2  macallan 			intrs[idx].ih_func(intrs[idx].ih_arg);
1.2  macallan 			if (intrs[idx].ih_ipl == IPL_VM)
1.2  macallan 				KERNEL_UNLOCK_ONE(NULL);
1.2  macallan 			intrs[idx].ih_count.ev_count++;
1.2  macallan 		} else {
1.3  macallan 			/* spurious interrupt, mask it */
1.2  macallan 			writereg(JZ_ICMSR1, mask);
1.2  macallan 		}
1.2  macallan 		irqh &= ~mask;
1.2  macallan 		bit = ffs32(irqh);
1.2  macallan 	}
1.2  macallan
1.2  macallan }
1.2  macallan
1.2  macallan void *
1.2  macallan evbmips_intr_establish(int irq, int (*func)(void *), void *arg)
1.2  macallan {
1.2  macallan 	int s;
1.2  macallan
1.2  macallan 	if ((irq < 0) || (irq >= NINTR)) {
1.2  macallan 		aprint_error("%s: invalid irq %d\n", __func__, irq);
1.2  macallan 		return NULL;
1.2  macallan 	}
1.2  macallan
1.2  macallan 	s = splhigh();	/* XXX probably needs a mutex */
1.2  macallan 	intrs[irq].ih_func = func;
1.2  macallan 	intrs[irq].ih_arg = arg;
1.2  macallan 	intrs[irq].ih_ipl = IPL_VM;
1.2  macallan
1.2  macallan 	/* now enable the IRQ */
1.2  macallan 	if (irq >= 32) {
1.2  macallan 		writereg(JZ_ICMCR1, 1 << (irq - 32));
1.2  macallan 	} else
1.2  macallan 		writereg(JZ_ICMCR0, 1 << irq);
1.2  macallan
1.2  macallan 	splx(s);
1.2  macallan
1.2  macallan 	return ((void *)(irq + 1));
1.2  macallan }
1.2  macallan
1.2  macallan void
1.2  macallan evbmips_intr_disestablish(void *cookie)
1.2  macallan {
1.2  macallan 	int irq = ((int)cookie) - 1;
1.2  macallan 	int s;
1.2  macallan
1.2  macallan 	if ((irq < 0) || (irq >= NINTR)) {
1.2  macallan 		aprint_error("%s: invalid irq %d\n", __func__, irq);
1.2  macallan 		return;
1.2  macallan 	}
1.2  macallan
1.2  macallan 	s = splhigh();
1.2  macallan
1.2  macallan 	/* disable the IRQ */
1.2  macallan 	if (irq >= 32) {
1.2  macallan 		writereg(JZ_ICMSR1, 1 << (irq - 32));
1.2  macallan 	} else
1.2  macallan 		writereg(JZ_ICMSR0, 1 << irq);
1.2  macallan
1.2  macallan 	intrs[irq].ih_func = NULL;
1.2  macallan 	intrs[irq].ih_arg = NULL;
1.2  macallan 	intrs[irq].ih_ipl = 0;
1.2  macallan
1.2  macallan 	splx(s);
1.2  macallan }