/* $OpenBSD: openpic.c,v 1.20 2004/12/24 22:50:30 miod Exp $ */ /*- * Copyright (c) 1995 Per Fogelstrom * Copyright (c) 1993, 1994 Charles M. Hannum. * Copyright (c) 1990 The Regents of the University of California. * All rights reserved. * * This code is derived from software contributed to Berkeley by * William Jolitz and Don Ahn. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * @(#)isa.c 7.2 (Berkeley) 5/12/91 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define ICU_LEN 32 #define LEGAL_IRQ(x) ((x >= 0) && (x < ICU_LEN)) #define IO_ICU1 (isaspace_va + 0x20) #define IO_ICU2 (isaspace_va + 0xa0) #define IO_ELCR1 (isaspace_va + 0x4d0) #define IO_ELCR2 (isaspace_va + 0x4d1) #define IRQ_SLAVE 2 #define ICU_OFFSET 0 #define PIC_OFFSET 16 #define PIC_SPURIOUS 0xff unsigned char icu1_val = 0xff; unsigned char icu2_val = 0xff; unsigned char elcr1_val = 0x00; unsigned char elcr2_val = 0x00; int intrtype[ICU_LEN], intrmask[ICU_LEN], intrlevel[ICU_LEN]; struct intrhand *intrhand[ICU_LEN]; int hwirq[ICU_LEN], virq[ICU_LEN]; unsigned int imen = 0xffffffff; int virq_max; int fakeintr(void *); const char *intr_typename(int type); void intr_calculatemasks(void); static __inline int cntlzw(int x); int mapirq(int irq); void openpic_enable_irq_mask(int irq_mask); #define HWIRQ_MAX 27 #define HWIRQ_MASK 0x0fffffff static __inline u_int openpic_read(int); static __inline void openpic_write(int, u_int); void openpic_enable_irq(int, int); void openpic_disable_irq(int); void openpic_init(void); void openpic_set_priority(int, int); static __inline int openpic_iack(int); static __inline void openpic_eoi(int); void openpic_initirq(int, int, int); void i8259_init(void); int i8259_intr(void); void i8259_enable_irq(int, int); void i8259_disable_irq(int); void i8259_eoi(int); void *i8259_intr_establish(void *, int, int, int, int (*)(void *), void *, char *); void i8259_set_irq_mask(void); struct openpic_softc { struct device sc_dev; }; int openpic_match(struct device *parent, void *cf, void *aux); void openpic_attach(struct device *, struct device *, void *); void openpic_do_pending_int(void); void ext_intr_openpic(void); struct cfattach openpic_ca = { sizeof(struct openpic_softc), openpic_match, openpic_attach }; struct cfdriver openpic_cd = { NULL, "openpic", DV_DULL }; /* * ISA IRQ for PCI IRQ to MPIC IRQ routing. * From MVME2600APG tables 5.2 and 5.3 */ const struct pci_route { int pci; int openpic; } pci_routes[] = { { 10, 2 }, { 11, 5 }, { 14, 3 }, { 15, 4 }, { 0, 0 } }; int openpic_match(parent, cf, aux) struct device *parent; void *cf; void *aux; { /* We must be a child of the raven device */ if (strcmp(parent->dv_cfdata->cf_driver->cd_name, "raven") != 0) return (0); /* If there is a raven, then there is a mpic! */ return 1; } u_int8_t *interrupt_reg; typedef void (void_f) (void); extern void_f *pending_int_f; int abort_switch (void *arg); int i8259_dummy(void *arg); typedef int mac_intr_handle_t; typedef void *(intr_establish_t)(void *, int, int, int, int (*)(void *), void *, char *); typedef void (intr_disestablish_t)(void *, void *); vaddr_t openpic_base; extern vaddr_t isaspace_va; void * openpic_intr_establish(void *, int, int, int, int (*)(void *), void *, char *); void openpic_intr_disestablish(void *, void *); void openpic_collect_preconf_intr(void); void openpic_attach(parent, self, aux) struct device *parent, *self; void *aux; { extern intr_establish_t *intr_establish_func; extern intr_disestablish_t *intr_disestablish_func; if ((openpic_base = (vaddr_t)mapiodev(MPCIC_BASE, MPCIC_SIZE)) == NULL) { printf(": can't map MPCIC!\n"); return; } /* the ICU area in isa space already mapped */ printf(": version 0x%x", openpic_read(OPENPIC_FEATURE) & 0xFF); i8259_init(); openpic_init(); pending_int_f = openpic_do_pending_int; intr_establish_func = i8259_intr_establish; intr_disestablish_func = openpic_intr_disestablish; openpic_collect_preconf_intr(); /* * i8259 interrupts are chained to openpic interrupt #0 */ openpic_intr_establish(parent, 0x00, IST_LEVEL, IPL_HIGH, i8259_dummy, NULL, "8259 Interrupt"); i8259_intr_establish(parent, 0x08, IST_EDGE, IPL_HIGH, abort_switch, NULL, "abort button"); printf("\n"); } void openpic_collect_preconf_intr() { int i; for (i = 0; i < ppc_configed_intr_cnt; i++) { #ifdef DEBUG printf("\n\t%s irq %d level %d fun %x arg %x", ppc_configed_intr[i].ih_what, ppc_configed_intr[i].ih_irq, ppc_configed_intr[i].ih_level, ppc_configed_intr[i].ih_fun, ppc_configed_intr[i].ih_arg); #endif openpic_intr_establish(NULL, ppc_configed_intr[i].ih_irq, IST_LEVEL, ppc_configed_intr[i].ih_level, ppc_configed_intr[i].ih_fun, ppc_configed_intr[i].ih_arg, ppc_configed_intr[i].ih_what); } } int abort_switch(void *arg) { #ifdef DDB if (db_console) Debugger(); #else printf("Abort button pressed, debugger not available.\n"); #endif return 1; } int i8259_dummy(void *arg) { /* All the 8259 handling happens in ext_intr_openpic(), actually. */ return 1; } int fakeintr(arg) void *arg; { return 0; } /* * Register an ISA interrupt handler. */ void * i8259_intr_establish(lcv, irq, type, level, ih_fun, ih_arg, what) void * lcv; int irq; int type; int level; int (*ih_fun)(void *); void *ih_arg; char *what; { struct intrhand **p, *q, *ih; static struct intrhand fakehand; fakehand.ih_next = NULL; fakehand.ih_fun = fakeintr; #if 0 printf("i8259_intr_establish, %d, %s", irq, (type == IST_EDGE) ? "EDGE":"LEVEL")); #endif irq = mapirq(irq + ICU_OFFSET); /* no point in sleeping unless someone can free memory. */ ih = malloc(sizeof *ih, M_DEVBUF, cold ? M_NOWAIT : M_WAITOK); if (ih == NULL) panic("i8259_intr_establish: can't malloc handler info"); if (!LEGAL_IRQ(irq) || type == IST_NONE) panic("i8259_intr_establish: bogus irq or type"); switch (intrtype[irq]) { case IST_EDGE: case IST_LEVEL: if (type == intrtype[irq]) break; case IST_PULSE: if (type != IST_NONE) panic("intr_establish: can't share %s with %s", intr_typename(intrtype[irq]), intr_typename(type)); break; } /* * Figure out where to put the handler. * This is O(N^2), but we want to preserve the order, and N is * generally small. */ for (p = &intrhand[irq]; (q = *p) != NULL; p = &q->ih_next) ; /* * Actually install a fake handler momentarily, since we might be doing * this with interrupts enabled and don't want the real routine called * until masking is set up. */ fakehand.ih_level = level; *p = &fakehand; intr_calculatemasks(); /* * Poke the real handler in now. */ ih->ih_fun = ih_fun; ih->ih_arg = ih_arg; ih->ih_next = NULL; ih->ih_level = level; ih->ih_irq = irq; ih->ih_what = what; evcount_attach(&ih->ih_count, what, (void *)&ih->ih_irq, &evcount_intr); *p = ih; return (ih); } /* * Register a PCI interrupt handler. */ void * openpic_intr_establish(lcv, irq, type, level, ih_fun, ih_arg, what) void * lcv; int irq; int type; int level; int (*ih_fun)(void *); void *ih_arg; char *what; { struct intrhand **p, *q, *ih; static struct intrhand fakehand; const struct pci_route *pr; fakehand.ih_next = NULL; fakehand.ih_fun = fakeintr; for (pr = pci_routes; pr->pci != 0; pr++) if (pr->pci == irq) { irq = pr->openpic; break; } irq = mapirq(irq + PIC_OFFSET); /* no point in sleeping unless someone can free memory. */ ih = malloc(sizeof *ih, M_DEVBUF, cold ? M_NOWAIT : M_WAITOK); if (ih == NULL) panic("intr_establish: can't malloc handler info"); if (!LEGAL_IRQ(irq) || type == IST_NONE) panic("intr_establish: bogus irq or type"); switch (intrtype[irq]) { case IST_EDGE: case IST_LEVEL: if (type == intrtype[irq]) break; case IST_PULSE: if (type != IST_NONE) panic("intr_establish: can't share %s with %s", intr_typename(intrtype[irq]), intr_typename(type)); break; } /* * Figure out where to put the handler. * This is O(N^2), but we want to preserve the order, and N is * generally small. */ for (p = &intrhand[irq]; (q = *p) != NULL; p = &q->ih_next) ; /* * Actually install a fake handler momentarily, since we might be doing * this with interrupts enabled and don't want the real routine called * until masking is set up. */ fakehand.ih_level = level; *p = &fakehand; intr_calculatemasks(); /* * Poke the real handler in now. */ ih->ih_fun = ih_fun; ih->ih_arg = ih_arg; ih->ih_next = NULL; ih->ih_level = level; ih->ih_irq = irq; ih->ih_what = what; evcount_attach(&ih->ih_count, what, (void *)&ih->ih_irq, &evcount_intr); *p = ih; return (ih); } /* * Deregister an interrupt handler. */ void openpic_intr_disestablish(lcp, arg) void *lcp; void *arg; { struct intrhand *ih = arg; int irq = ih->ih_irq; struct intrhand **p, *q; if (!LEGAL_IRQ(irq)) panic("intr_disestablish: bogus irq"); /* * Remove the handler from the chain. * This is O(n^2), too. */ for (p = &intrhand[irq]; (q = *p) != NULL && q != ih; p = &q->ih_next) ; if (q) *p = q->ih_next; else panic("intr_disestablish: handler not registered"); evcount_detach(&ih->ih_count); free((void *)ih, M_DEVBUF); intr_calculatemasks(); if (intrhand[irq] == NULL) intrtype[irq] = IST_NONE; } const char * intr_typename(type) int type; { switch (type) { case IST_NONE : return ("none"); case IST_PULSE: return ("pulsed"); case IST_EDGE: return ("edge-triggered"); case IST_LEVEL: return ("level-triggered"); #ifdef DIAGNOSTIC default: panic("intr_typename: invalid type %d", type); #endif } } /* * Recalculate the interrupt masks from scratch. * We could code special registry and deregistry versions of this function that * would be faster, but the code would be nastier, and we don't expect this to * happen very much anyway. */ void intr_calculatemasks() { int irq, hirq, level, levels; struct intrhand *q; int irqs; /* First, figure out which levels each IRQ uses. */ for (irq = 0; irq < ICU_LEN; irq++) { levels = 0; for (q = intrhand[irq]; q; q = q->ih_next) levels |= 1 << q->ih_level; intrlevel[irq] = levels; } /* Then figure out which IRQs use each level. */ for (level = IPL_NONE; level < IPL_NUM; level++) { irqs = 0; for (irq = 0; irq < ICU_LEN; irq++) if (intrlevel[irq] & (1 << level)) irqs |= 1 << irq; imask[level] = irqs | SINT_MASK; } /* * There are tty, network and disk drivers that use free() at interrupt * time, so imp > (tty | net | bio). * * Enforce a hierarchy that gives slow devices a better chance at not * dropping data. */ imask[IPL_NET] |= imask[IPL_BIO]; imask[IPL_TTY] |= imask[IPL_NET]; imask[IPL_IMP] |= imask[IPL_TTY]; imask[IPL_CLOCK] |= imask[IPL_IMP] | SPL_CLOCK; /* * These are pseudo-levels. */ imask[IPL_NONE] = 0x00000000; imask[IPL_HIGH] = 0xffffffff; /* And eventually calculate the complete masks. */ for (irq = 0; irq < ICU_LEN; irq++) { irqs = 1 << irq; for (q = intrhand[irq]; q; q = q->ih_next) irqs |= imask[q->ih_level]; intrmask[irq] = irqs | SINT_MASK; } /* Lastly, determine which IRQs are actually in use. */ irqs = 0; for (irq = 0; irq < ICU_LEN; irq++) { hirq = hwirq[irq]; if (hirq < 0) continue; if (intrhand[irq]) { irqs |= 1 << irq; if (hirq >= PIC_OFFSET) openpic_enable_irq(hirq, intrtype[irq]); else i8259_enable_irq(hirq, intrtype[irq]); } else { if (hirq >= PIC_OFFSET) openpic_disable_irq(hirq); else i8259_disable_irq(hirq); } } /* always enable the chained 8259 interrupt */ i8259_enable_irq(IRQ_SLAVE, IST_EDGE); imen = ~irqs; i8259_set_irq_mask(); } /* * Map 64 irqs into 32 (bits). */ int mapirq(irq) int irq; { int v; #ifdef DIAGNOSTIC if (irq < 0 || irq >= ICU_LEN) panic("invalid irq"); #endif virq_max++; v = virq_max; if (v > HWIRQ_MAX) panic("virq overflow"); hwirq[v] = irq; virq[irq] = v; #ifdef DEBUG printf("mapirq %x to %x\n", irq, v); #endif return v; } /* * Count leading zeros. */ static __inline int cntlzw(x) int x; { int a; __asm __volatile ("cntlzw %0,%1" : "=r"(a) : "r"(x)); return a; } void openpic_do_pending_int() { struct intrhand *ih; int irq; int pcpl; int hwpend; int s; static int processing; if (processing) return; processing = 1; pcpl = splhigh(); /* Turn off all */ s = ppc_intr_disable(); hwpend = ipending & ~pcpl; /* Do now unmasked pendings */ imen &= ~hwpend; openpic_enable_irq_mask(~imen); hwpend &= HWIRQ_MASK; while (hwpend) { irq = 31 - cntlzw(hwpend); hwpend &= ~(1L << irq); ih = intrhand[irq]; while (ih) { if ((*ih->ih_fun)(ih->ih_arg)) ih->ih_count.ec_count++; ih = ih->ih_next; } } do { if ((ipending & SINT_CLOCK) & ~pcpl) { ipending &= ~SINT_CLOCK; softclock(); } if ((ipending & SINT_NET) & ~pcpl) { extern int netisr; int pisr = netisr; netisr = 0; ipending &= ~SINT_NET; softnet(pisr); } #if 0 if ((ipending & SINT_TTY) & ~pcpl) { ipending &= ~SINT_TTY; softtty(); } #endif } while (ipending & (SINT_NET|SINT_CLOCK/*|SINT_TTY*/) & ~cpl); ipending &= pcpl; cpl = pcpl; /* Don't use splx... we are here already! */ #if 0 i8259_set_irq_mask(); #endif ppc_intr_enable(s); processing = 0; } u_int openpic_read(reg) int reg; { char *addr = (void *)(openpic_base + reg); return in32rb(addr); } void openpic_write(reg, val) int reg; u_int val; { char *addr = (void *)(openpic_base + reg); out32rb(addr, val); } void openpic_enable_irq_mask(irq_mask) int irq_mask; { int irq, hirq; for (irq = 0; irq <= virq_max; irq++) { hirq = hwirq[irq]; if (hirq < 0) continue; if (irq_mask & (1 << irq)) { if (hirq >= PIC_OFFSET) openpic_enable_irq(hirq, intrtype[irq]); else i8259_enable_irq(hirq, intrtype[irq]); } else { if (hirq >= PIC_OFFSET) openpic_disable_irq(hirq); else i8259_disable_irq(hirq); } } i8259_set_irq_mask(); } void openpic_enable_irq(irq, type) int irq; int type; { u_int x, isrc; #ifdef DIAGNOSTIC /* skip invalid irqs */ if (irq < PIC_OFFSET) panic("openpic_enable_irq: invalid irq %x", irq); #endif irq -= PIC_OFFSET; x = openpic_read(OPENPIC_SRC_VECTOR(irq)); isrc = x & ~(OPENPIC_IMASK | OPENPIC_SENSE_LEVEL | OPENPIC_POLARITY_POSITIVE | OPENPIC_ACTIVITY); if (irq == 0) isrc |= OPENPIC_POLARITY_POSITIVE; if (type == IST_LEVEL) isrc |= OPENPIC_SENSE_LEVEL; else isrc |= OPENPIC_SENSE_EDGE; /* Ack all pending interrupts if this one is pending. */ while (x & OPENPIC_ACTIVITY) { (void)openpic_iack(0); openpic_eoi(0); x = openpic_read(OPENPIC_SRC_VECTOR(irq)); } if (x != isrc) openpic_write(OPENPIC_SRC_VECTOR(irq), isrc); } void openpic_disable_irq(irq) int irq; { u_int x; /* skip invalid irqs */ if (irq >= PIC_OFFSET) irq -= PIC_OFFSET; x = openpic_read(OPENPIC_SRC_VECTOR(irq)); x |= OPENPIC_IMASK; openpic_write(OPENPIC_SRC_VECTOR(irq), x); } void i8259_set_irq_mask(void) { if (icu2_val != 0xff) { /* Turn on the second IC */ icu1_val &= ~(1 << IRQ_SLAVE); } else { icu1_val |= (1 << IRQ_SLAVE); } outb(IO_ICU1 + 1, icu1_val); outb(IO_ICU2 + 1, icu2_val); outb(IO_ELCR1, elcr1_val); outb(IO_ELCR2, elcr2_val); } void i8259_disable_irq(irq) int irq; { #ifdef DIAGNOSTIC /* skip invalid irqs */ if (irq < 0 || irq >= PIC_OFFSET) panic("i8259_disable_irq: invalid irq %x", irq); #endif if (irq < 8) { icu1_val |= 1 << irq; elcr1_val &= ~(1 << irq); } else { irq -= 8; icu2_val |= 1 << irq; elcr2_val &= ~(1 << irq); } } void i8259_enable_irq(irq, type) int irq, type; { #ifdef DIAGNOSTIC /* skip invalid irqs */ if (irq < 0 || irq >= PIC_OFFSET) panic("i8259_enable_irq: invalid irq %x", irq); #endif if (irq < 8) { icu1_val &= ~(1 << irq); if (type == IST_LEVEL) elcr1_val |= (1 << irq); else elcr1_val &= ~(1 << irq); } else { irq -= 8; icu2_val &= ~(1 << irq); if (type == IST_LEVEL) elcr2_val |= (1 << irq); else elcr2_val &= ~(1 << irq); } } void i8259_eoi(int irq) { #ifdef DIAGNOSTIC /* skip invalid irqs */ if (irq < 0 || irq >= PIC_OFFSET) panic("i8259_eoi: invalid irq %x", irq); #endif if (irq < 8) outb(IO_ICU1, 0x60 | irq); else { outb(IO_ICU2, 0x60 | (irq - 8)); /* * Do not ack on the master unless there are no * other interrupts pending on the slave * controller! */ outb(IO_ICU2, 0x0b); if (inb(IO_ICU2) == 0) outb(IO_ICU1, 0x60 | IRQ_SLAVE); } } void openpic_set_priority(cpu, pri) int cpu, pri; { u_int x; x = openpic_read(OPENPIC_CPU_PRIORITY(cpu)); x &= ~OPENPIC_CPU_PRIORITY_MASK; x |= pri; openpic_write(OPENPIC_CPU_PRIORITY(cpu), x); } int openpic_iack(cpu) int cpu; { return openpic_read(OPENPIC_IACK(cpu)) & OPENPIC_VECTOR_MASK; } void openpic_eoi(cpu) int cpu; { openpic_write(OPENPIC_EOI(cpu), 0); openpic_read(OPENPIC_EOI(cpu)); } void i8259_init(void) { /* initialize 8259's */ outb(IO_ICU1, 0x11); /* reset; program device, four bytes */ outb(IO_ICU1+1, ICU_OFFSET); /* starting at this vector index */ outb(IO_ICU1+1, 1 << IRQ_SLAVE); /* slave on line 2 */ outb(IO_ICU1+1, 1); /* 8086 mode */ outb(IO_ICU1+1, 0xff); /* leave interrupts masked */ /* init interrupt controller 2 */ outb(IO_ICU2, 0x11); /* reset; program device, four bytes */ outb(IO_ICU2+1, ICU_OFFSET+8); /* staring at this vector index */ outb(IO_ICU2+1, IRQ_SLAVE); outb(IO_ICU2+1, 1); /* 8086 mode */ outb(IO_ICU2+1, 0xff); /* leave interrupts masked */ } int i8259_intr(void) { int irq; /* * Perform an interrupt acknowledge cycle on controller 1 */ outb(IO_ICU1, 0x0c); irq = inb(IO_ICU1) & 7; if (irq == IRQ_SLAVE) { /* * Interrupt is cascaded so perform interrupt * acknowledge on controller 2 */ outb(IO_ICU2, 0x0c); irq = (inb(IO_ICU2) & 7) + 8; if (irq == 15) { outb(IO_ICU2, 0x0b); if ((inb(IO_ICU2) & 0x80) == 0) { #ifdef DIAGNOSTIC printf("spurious interrupt on ICU2\n"); #endif return PIC_SPURIOUS; } } } else if (irq == 7) { /* * This may be a spurious interrupt * * Read the interrupt status register. If the most * significant bit is not set then there is no valid * interrupt */ outb(IO_ICU1, 0x0b); if ((inb(IO_ICU1) & 0x80) == 0) { #ifdef DIAGNOSTIC printf("spurious interrupt on ICU1\n"); #endif return PIC_SPURIOUS; } } return (ICU_OFFSET + irq); } void ext_intr_openpic() { int irq, realirq; int r_imen; int pcpl, ocpl; struct intrhand *ih; pcpl = cpl; realirq = openpic_iack(0); while (realirq != PIC_SPURIOUS) { if (realirq == 0x00) { /* * Interrupt from the PCI/ISA bridge. PCI interrupts * are shadowed on the ISA PIC for compatibility with * MVME1600, so simply handle the ISA PIC. */ realirq = i8259_intr(); openpic_eoi(0); if (realirq == PIC_SPURIOUS) break; } else { realirq += PIC_OFFSET; } irq = virq[realirq]; /* XXX check range */ r_imen = 1 << irq; if ((pcpl & r_imen) != 0) { ipending |= r_imen; /* Masked! Mark this as pending */ if (realirq >= PIC_OFFSET) { openpic_disable_irq(realirq); openpic_eoi(0); } else { i8259_disable_irq(realirq); i8259_set_irq_mask(); i8259_eoi(realirq); } } else { if (realirq >= PIC_OFFSET) { openpic_disable_irq(realirq); } else { i8259_disable_irq(realirq); i8259_set_irq_mask(); } ocpl = splraise(intrmask[irq]); ih = intrhand[irq]; while (ih) { if ((*ih->ih_fun)(ih->ih_arg)) ih->ih_count.ec_count++; ih = ih->ih_next; } uvmexp.intrs++; __asm__ volatile("":::"memory"); cpl = ocpl; __asm__ volatile("":::"memory"); if (realirq >= PIC_OFFSET) { openpic_eoi(0); openpic_enable_irq(realirq, intrtype[irq]); } else { i8259_eoi(realirq); i8259_enable_irq(realirq, intrtype[irq]); i8259_set_irq_mask(); } } realirq = openpic_iack(0); } ppc_intr_enable(1); splx(pcpl); /* Process pendings. */ } void openpic_initirq(int irq, int pol, int sense) { u_int x; x = (irq & OPENPIC_VECTOR_MASK); x |= OPENPIC_IMASK; x |= (pol ? OPENPIC_POLARITY_POSITIVE : OPENPIC_POLARITY_NEGATIVE); x |= (sense ? OPENPIC_SENSE_LEVEL : OPENPIC_SENSE_EDGE); x |= 8 << OPENPIC_PRIORITY_SHIFT; openpic_write(OPENPIC_SRC_VECTOR(irq), x); } void openpic_init() { int irq; u_int x; /* disable all interrupts and init hwirq[] */ for (irq = 0; irq < ICU_LEN; irq++) { hwirq[irq] = -1; intrtype[irq] = IST_NONE; intrmask[irq] = 0; intrlevel[irq] = 0; intrhand[irq] = NULL; openpic_write(OPENPIC_SRC_VECTOR(irq), OPENPIC_IMASK); } openpic_set_priority(0, 15); /* we don't need 8259 pass through mode */ x = openpic_read(OPENPIC_CONFIG); x |= OPENPIC_CONFIG_8259_PASSTHRU_DISABLE; openpic_write(OPENPIC_CONFIG, x); /* send all interrupts to cpu 0 */ for (irq = 0; irq < ICU_LEN; irq++) openpic_write(OPENPIC_SRC_DEST(irq), CPU(0)); /* special case for intr src 0 */ openpic_initirq(0, 1, 0); for (irq = 1; irq < ICU_LEN; irq++) { openpic_initirq(irq, 0, 1); } /* XXX set spurious intr vector */ #if 0 openpic_write(OPENPIC_SPURIOUS_VECTOR, 0xFF); #endif /* unmask interrupts for cpu 0 */ openpic_set_priority(0, 0); /* clear all pending interrunts */ /* < ICU_LEN ? */ for (irq = 0; irq < PIC_OFFSET; irq++) { openpic_iack(0); openpic_eoi(0); } for (irq = 0; irq < PIC_OFFSET; irq++) { /* < ICU_LEN ? */ i8259_disable_irq(irq); openpic_disable_irq(irq); } i8259_set_irq_mask(); install_extint(ext_intr_openpic); }