evbarm/ifpga/ifpga_intr.c

1.9      matt /*	$NetBSD: ifpga_intr.c,v 1.9 2010/12/20 00:25:31 matt Exp $	*/
1.1  rearnsha
1.1  rearnsha /*
1.1  rearnsha  * Copyright (c) 2001, 2002 Wasabi Systems, Inc.
1.1  rearnsha  * All rights reserved.
1.1  rearnsha  *
1.1  rearnsha  * Written by Jason R. Thorpe for Wasabi Systems, Inc.
1.1  rearnsha  *
1.1  rearnsha  * Redistribution and use in source and binary forms, with or without
1.1  rearnsha  * modification, are permitted provided that the following conditions
1.1  rearnsha  * are met:
1.1  rearnsha  * 1. Redistributions of source code must retain the above copyright
1.1  rearnsha  *    notice, this list of conditions and the following disclaimer.
1.1  rearnsha  * 2. Redistributions in binary form must reproduce the above copyright
1.1  rearnsha  *    notice, this list of conditions and the following disclaimer in the
1.1  rearnsha  *    documentation and/or other materials provided with the distribution.
1.1  rearnsha  * 3. All advertising materials mentioning features or use of this software
1.1  rearnsha  *    must display the following acknowledgement:
1.1  rearnsha  *	This product includes software developed for the NetBSD Project by
1.1  rearnsha  *	Wasabi Systems, Inc.
1.1  rearnsha  * 4. The name of Wasabi Systems, Inc. may not be used to endorse
1.1  rearnsha  *    or promote products derived from this software without specific prior
1.1  rearnsha  *    written permission.
1.1  rearnsha  *
1.1  rearnsha  * THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND
1.1  rearnsha  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  rearnsha  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  rearnsha  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL WASABI SYSTEMS, INC
1.1  rearnsha  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  rearnsha  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  rearnsha  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  rearnsha  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  rearnsha  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  rearnsha  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  rearnsha  * POSSIBILITY OF SUCH DAMAGE.
1.1  rearnsha  */
1.1  rearnsha
1.1  rearnsha #ifndef EVBARM_SPL_NOINLINE
1.1  rearnsha #define	EVBARM_SPL_NOINLINE
1.1  rearnsha #endif
1.1  rearnsha
1.1  rearnsha /*
1.1  rearnsha  * Interrupt support for the Integrator FPGA.
1.1  rearnsha  */
1.1  rearnsha
1.1  rearnsha #include <sys/param.h>
1.1  rearnsha #include <sys/systm.h>
1.1  rearnsha #include <sys/malloc.h>
1.6        ad #include <sys/bus.h>
1.6        ad #include <sys/intr.h>
1.1  rearnsha
1.1  rearnsha #include <arm/cpufunc.h>
1.1  rearnsha
1.1  rearnsha #include <evbarm/ifpga/ifpgareg.h>
1.1  rearnsha #include <evbarm/ifpga/ifpgavar.h>
1.1  rearnsha
1.1  rearnsha /* Interrupt handler queues. */
1.1  rearnsha struct intrq intrq[NIRQ];
1.1  rearnsha
1.1  rearnsha /* Interrupts to mask at each level. */
1.1  rearnsha int ifpga_imask[NIPL];
1.1  rearnsha
1.1  rearnsha /* Interrupts pending. */
1.3     perry volatile int ifpga_ipending;
1.1  rearnsha
1.1  rearnsha /* Software copy of the IRQs we have enabled. */
1.3     perry volatile uint32_t intr_enabled;
1.1  rearnsha
1.1  rearnsha /* Mask if interrupts steered to FIQs. */
1.1  rearnsha uint32_t intr_steer;
1.1  rearnsha
1.1  rearnsha /*
1.1  rearnsha  * Interrupt bit names.
1.1  rearnsha  */
1.7      matt const char * const ifpga_irqnames[] = {
1.1  rearnsha 	"soft",		/* 0 */
1.1  rearnsha 	"uart 0",	/* 1 */
1.1  rearnsha 	"uart 1",	/* 2 */
1.1  rearnsha 	"kbd",		/* 3 */
1.1  rearnsha 	"mouse",	/* 4 */
1.1  rearnsha 	"tmr 0",	/* 5 */
1.1  rearnsha 	"tmr 1 hard",	/* 6 */
1.1  rearnsha 	"tmr 2 stat",	/* 7 */
1.1  rearnsha 	"rtc",		/* 8 */
1.1  rearnsha 	"exp 0",	/* 9 */
1.1  rearnsha 	"exp 1",	/* 10 */
1.1  rearnsha 	"exp 2",	/* 11 */
1.1  rearnsha 	"exp 3",	/* 12 */
1.1  rearnsha 	"pci 0",	/* 13 */
1.1  rearnsha 	"pci 1",	/* 14 */
1.1  rearnsha 	"pci 2",	/* 15 */
1.1  rearnsha 	"pci 3",	/* 16 */
1.1  rearnsha 	"V3 br",	/* 17 */
1.1  rearnsha 	"deg",		/* 18 */
1.1  rearnsha 	"enum",		/* 19 */
1.1  rearnsha 	"pci lb",	/* 20 */
1.1  rearnsha 	"autoPC",	/* 21 */
1.1  rearnsha 	"irq 22",	/* 22 */
1.1  rearnsha 	"irq 23",	/* 23 */
1.1  rearnsha 	"irq 24",	/* 24 */
1.1  rearnsha 	"irq 25",	/* 25 */
1.1  rearnsha 	"irq 26",	/* 26 */
1.1  rearnsha 	"irq 27",	/* 27 */
1.1  rearnsha 	"irq 28",	/* 28 */
1.1  rearnsha 	"irq 29",	/* 29 */
1.1  rearnsha 	"irq 30",	/* 30 */
1.1  rearnsha 	"irq 31",	/* 31 */
1.1  rearnsha };
1.1  rearnsha
1.1  rearnsha void	ifpga_intr_dispatch(struct clockframe *frame);
1.1  rearnsha
1.1  rearnsha extern struct ifpga_softc *ifpga_sc;
1.1  rearnsha
1.3     perry static inline uint32_t
1.1  rearnsha ifpga_iintsrc_read(void)
1.1  rearnsha {
1.1  rearnsha 	return bus_space_read_4(ifpga_sc->sc_iot, ifpga_sc->sc_irq_ioh,
1.1  rearnsha 	    IFPGA_INTR_STATUS);
1.1  rearnsha }
1.1  rearnsha
1.3     perry static inline void
1.1  rearnsha ifpga_enable_irq(int irq)
1.1  rearnsha {
1.1  rearnsha
1.1  rearnsha 	intr_enabled |= (1U << irq);
1.1  rearnsha 	ifpga_set_intrmask();
1.1  rearnsha }
1.1  rearnsha
1.3     perry static inline void
1.1  rearnsha ifpga_disable_irq(int irq)
1.1  rearnsha {
1.1  rearnsha
1.1  rearnsha 	intr_enabled &= ~(1U << irq);
1.1  rearnsha 	ifpga_set_intrmask();
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha /*
1.1  rearnsha  * NOTE: This routine must be called with interrupts disabled in the CPSR.
1.1  rearnsha  */
1.1  rearnsha static void
1.1  rearnsha ifpga_intr_calculate_masks(void)
1.1  rearnsha {
1.1  rearnsha 	struct intrq *iq;
1.1  rearnsha 	struct intrhand *ih;
1.1  rearnsha 	int irq, ipl;
1.1  rearnsha
1.1  rearnsha 	/* First, figure out which IPLs each IRQ has. */
1.1  rearnsha 	for (irq = 0; irq < NIRQ; irq++) {
1.1  rearnsha 		int levels = 0;
1.1  rearnsha 		iq = &intrq[irq];
1.1  rearnsha 		ifpga_disable_irq(irq);
1.1  rearnsha 		for (ih = TAILQ_FIRST(&iq->iq_list); ih != NULL;
1.1  rearnsha 		     ih = TAILQ_NEXT(ih, ih_list))
1.1  rearnsha 			levels |= (1U << ih->ih_ipl);
1.1  rearnsha 		iq->iq_levels = levels;
1.1  rearnsha 	}
1.1  rearnsha
1.1  rearnsha 	/* Next, figure out which IRQs are used by each IPL. */
1.1  rearnsha 	for (ipl = 0; ipl < NIPL; ipl++) {
1.1  rearnsha 		int irqs = 0;
1.1  rearnsha 		for (irq = 0; irq < NIRQ; irq++) {
1.1  rearnsha 			if (intrq[irq].iq_levels & (1U << ipl))
1.1  rearnsha 				irqs |= (1U << irq);
1.1  rearnsha 		}
1.1  rearnsha 		ifpga_imask[ipl] = irqs;
1.1  rearnsha 	}
1.1  rearnsha
1.7      matt 	KASSERT(ifpga_imask[IPL_NONE] == 0);
1.1  rearnsha
1.1  rearnsha 	/*
1.5       wiz 	 * Enforce a hierarchy that gives "slow" device (or devices with
1.1  rearnsha 	 * limited input buffer space/"real-time" requirements) a better
1.1  rearnsha 	 * chance at not dropping data.
1.1  rearnsha 	 */
1.8      matt 	ifpga_imask[IPL_VM] |= 0;
1.6        ad 	ifpga_imask[IPL_SCHED] |= ifpga_imask[IPL_VM];
1.6        ad 	ifpga_imask[IPL_HIGH] |= ifpga_imask[IPL_SCHED];
1.1  rearnsha
1.1  rearnsha 	/*
1.1  rearnsha 	 * Now compute which IRQs must be blocked when servicing any
1.1  rearnsha 	 * given IRQ.
1.1  rearnsha 	 */
1.1  rearnsha 	for (irq = 0; irq < NIRQ; irq++) {
1.1  rearnsha 		int irqs = (1U << irq);
1.1  rearnsha 		iq = &intrq[irq];
1.1  rearnsha 		if (TAILQ_FIRST(&iq->iq_list) != NULL)
1.1  rearnsha 			ifpga_enable_irq(irq);
1.1  rearnsha 		for (ih = TAILQ_FIRST(&iq->iq_list); ih != NULL;
1.1  rearnsha 		     ih = TAILQ_NEXT(ih, ih_list))
1.1  rearnsha 			irqs |= ifpga_imask[ih->ih_ipl];
1.1  rearnsha 		iq->iq_mask = irqs;
1.1  rearnsha 	}
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha void
1.1  rearnsha splx(int new)
1.1  rearnsha {
1.1  rearnsha
1.1  rearnsha 	ifpga_splx(new);
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha int
1.1  rearnsha _spllower(int ipl)
1.1  rearnsha {
1.1  rearnsha
1.1  rearnsha 	return (ifpga_spllower(ipl));
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha int
1.1  rearnsha _splraise(int ipl)
1.1  rearnsha {
1.1  rearnsha
1.1  rearnsha 	return (ifpga_splraise(ipl));
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha /*
1.1  rearnsha  * ifpga_intr_init:
1.1  rearnsha  *
1.1  rearnsha  *	Initialize the rest of the interrupt subsystem, making it
1.1  rearnsha  *	ready to handle interrupts from devices.
1.1  rearnsha  */
1.1  rearnsha void
1.1  rearnsha ifpga_intr_init(void)
1.1  rearnsha {
1.1  rearnsha 	struct intrq *iq;
1.1  rearnsha 	int i;
1.1  rearnsha
1.1  rearnsha 	intr_enabled = 0;
1.1  rearnsha
1.1  rearnsha 	for (i = 0; i < NIRQ; i++) {
1.1  rearnsha 		iq = &intrq[i];
1.1  rearnsha 		TAILQ_INIT(&iq->iq_list);
1.1  rearnsha
1.1  rearnsha 		evcnt_attach_dynamic(&iq->iq_ev, EVCNT_TYPE_INTR,
1.1  rearnsha 		    NULL, "ifpga", ifpga_irqnames[i]);
1.1  rearnsha 	}
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha void
1.1  rearnsha ifpga_intr_postinit(void)
1.1  rearnsha {
1.1  rearnsha 	ifpga_intr_calculate_masks();
1.1  rearnsha
1.1  rearnsha 	/* Enable IRQs (don't yet use FIQs). */
1.1  rearnsha 	enable_interrupts(I32_bit);
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha void *
1.1  rearnsha ifpga_intr_establish(int irq, int ipl, int (*func)(void *), void *arg)
1.1  rearnsha {
1.1  rearnsha 	struct intrq *iq;
1.1  rearnsha 	struct intrhand *ih;
1.1  rearnsha 	u_int oldirqstate;
1.1  rearnsha
1.1  rearnsha 	if (irq < 0 || irq > NIRQ)
1.1  rearnsha 		panic("ifpga_intr_establish: IRQ %d out of range", irq);
1.1  rearnsha
1.1  rearnsha 	ih = malloc(sizeof(*ih), M_DEVBUF, M_NOWAIT);
1.1  rearnsha 	if (ih == NULL)
1.1  rearnsha 		return (NULL);
1.1  rearnsha
1.1  rearnsha 	ih->ih_func = func;
1.1  rearnsha 	ih->ih_arg = arg;
1.1  rearnsha 	ih->ih_ipl = ipl;
1.1  rearnsha 	ih->ih_irq = irq;
1.1  rearnsha
1.1  rearnsha 	iq = &intrq[irq];
1.1  rearnsha
1.1  rearnsha 	/* All IOP321 interrupts are level-triggered. */
1.1  rearnsha 	iq->iq_ist = IST_LEVEL;
1.1  rearnsha
1.1  rearnsha 	oldirqstate = disable_interrupts(I32_bit);
1.1  rearnsha
1.1  rearnsha 	TAILQ_INSERT_TAIL(&iq->iq_list, ih, ih_list);
1.1  rearnsha
1.1  rearnsha 	ifpga_intr_calculate_masks();
1.1  rearnsha
1.1  rearnsha 	restore_interrupts(oldirqstate);
1.1  rearnsha
1.1  rearnsha 	return (ih);
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha void
1.1  rearnsha ifpga_intr_disestablish(void *cookie)
1.1  rearnsha {
1.1  rearnsha 	struct intrhand *ih = cookie;
1.1  rearnsha 	struct intrq *iq = &intrq[ih->ih_irq];
1.1  rearnsha 	int oldirqstate;
1.1  rearnsha
1.1  rearnsha 	oldirqstate = disable_interrupts(I32_bit);
1.1  rearnsha
1.1  rearnsha 	TAILQ_REMOVE(&iq->iq_list, ih, ih_list);
1.1  rearnsha
1.1  rearnsha 	ifpga_intr_calculate_masks();
1.1  rearnsha
1.1  rearnsha 	restore_interrupts(oldirqstate);
1.1  rearnsha }
1.1  rearnsha
1.1  rearnsha void
1.1  rearnsha ifpga_intr_dispatch(struct clockframe *frame)
1.1  rearnsha {
1.1  rearnsha 	struct intrq *iq;
1.1  rearnsha 	struct intrhand *ih;
1.1  rearnsha 	int oldirqstate, pcpl, irq, ibit, hwpend;
1.8      matt 	struct cpu_info * const ci = curcpu();
1.1  rearnsha
1.8      matt 	pcpl = ci->ci_cpl;
1.1  rearnsha
1.1  rearnsha 	hwpend = ifpga_iintsrc_read();
1.1  rearnsha
1.1  rearnsha 	/*
1.1  rearnsha 	 * Disable all the interrupts that are pending.  We will
1.1  rearnsha 	 * reenable them once they are processed and not masked.
1.1  rearnsha 	 */
1.1  rearnsha 	intr_enabled &= ~hwpend;
1.1  rearnsha 	ifpga_set_intrmask();
1.1  rearnsha
1.1  rearnsha 	/* Wait for these interrupts to be suppressed.  */
1.1  rearnsha 	while ((ifpga_iintsrc_read() & hwpend) != 0)
1.1  rearnsha 	    ;
1.1  rearnsha
1.1  rearnsha 	while (hwpend != 0) {
1.1  rearnsha 		irq = ffs(hwpend) - 1;
1.1  rearnsha 		ibit = (1U << irq);
1.1  rearnsha
1.1  rearnsha 		hwpend &= ~ibit;
1.1  rearnsha
1.1  rearnsha 		if (pcpl & ibit) {
1.1  rearnsha 			/*
1.1  rearnsha 			 * IRQ is masked; mark it as pending and check
1.1  rearnsha 			 * the next one.  Note: the IRQ is already disabled.
1.1  rearnsha 			 */
1.1  rearnsha 			ifpga_ipending |= ibit;
1.1  rearnsha 			continue;
1.1  rearnsha 		}
1.1  rearnsha
1.1  rearnsha 		ifpga_ipending &= ~ibit;
1.1  rearnsha
1.1  rearnsha 		iq = &intrq[irq];
1.1  rearnsha 		iq->iq_ev.ev_count++;
1.9      matt 		ci->ci_data.cpu_nintr++;
1.8      matt 		ci->ci_cpl |= iq->iq_mask;
1.1  rearnsha 		oldirqstate = enable_interrupts(I32_bit);
1.1  rearnsha 		for (ih = TAILQ_FIRST(&iq->iq_list); ih != NULL;
1.1  rearnsha 		     ih = TAILQ_NEXT(ih, ih_list)) {
1.1  rearnsha 			(void) (*ih->ih_func)(ih->ih_arg ? ih->ih_arg : frame);
1.1  rearnsha 		}
1.1  rearnsha 		restore_interrupts(oldirqstate);
1.8      matt 		ci->ci_cpl = pcpl;
1.1  rearnsha
1.1  rearnsha 		hwpend |= (ifpga_ipending & IFPGA_INTR_HWMASK) & ~pcpl;
1.1  rearnsha
1.1  rearnsha 		/* Re-enable this interrupt now that's it's cleared. */
1.1  rearnsha 		intr_enabled |= ibit;
1.1  rearnsha 		ifpga_set_intrmask();
1.1  rearnsha 	}
1.1  rearnsha
1.7      matt #ifdef __HAVE_FAST_SOFTINTS
1.8      matt 	cpu_dosoftints();
1.7      matt #endif
1.1  rearnsha }