/* $OpenBSD: fga.c,v 1.15 2006/02/22 22:32:12 miod Exp $ */ /* * Copyright (c) 1999 Jason L. Wright (jason@thought.net) * All rights reserved. * * This software was developed by Jason L. Wright under contract with * RTMX Incorporated (http://www.rtmx.com). * * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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. */ /* * Driver for the Force Gate Array 5000 (VME/SBus bridge) found * on FORCE CPU-5V boards. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* for SBUS_BURST_* */ #include #include #include int fgamatch(struct device *, void *, void *); void fgaattach(struct device *, struct device *, void *); int fvmematch(struct device *, void *, void *); void fvmeattach(struct device *, struct device *, void *); int fgaprint(void *, const char *); int fvmeprint(void *, const char *); int fvmescan(struct device *parent, void *, void *); struct fga_softc { struct device sc_dev; /* base device */ int sc_node; /* prom node */ struct fga_regs *sc_regs; /* registers */ struct intrhand sc_ih1; /* level 1 handler */ struct intrhand sc_ih2; /* level 2 handler */ struct intrhand sc_ih3; /* level 3 handler */ struct intrhand sc_ih4; /* level 4 handler */ struct intrhand sc_ih5; /* level 5 handler */ struct intrhand sc_ih6; /* level 6 handler */ struct intrhand sc_ih7; /* level 7 handler */ struct intrhand **sc_vmevec; /* vectored handlers */ #ifdef DDB int sc_abort; /* abort switch enabled? */ #endif int sc_nrange; /* number of sbus ranges */ struct rom_range *sc_range; /* sbus range data */ u_int8_t sc_established; /* which hw intrs installed */ }; int fgaopen(dev_t, int, int, struct proc *); int fgaclose(dev_t, int, int, struct proc *); int fgaioctl(dev_t, u_long, caddr_t, int, struct proc *); int fga_vmerangemap(struct fga_softc *, u_int32_t, u_int32_t, int, int, u_int32_t, struct confargs *); int fga_intr_establish(struct fga_softc *, int, int, struct intrhand *, const char *); int fga_hwintr_establish(struct fga_softc *, u_int8_t); int fga_hwintr1(void *); int fga_hwintr2(void *); int fga_hwintr3(void *); int fga_hwintr4(void *); int fga_hwintr5(void *); int fga_hwintr6(void *); int fga_hwintr7(void *); int fga_intrvec(struct fga_softc *, int); struct cfattach fga_ca = { sizeof (struct fga_softc), fgamatch, fgaattach }; struct cfdriver fga_cd = { NULL, "fga", DV_DULL }; struct fvme_softc { struct device sc_dv; u_int32_t sc_vmeoffset; /* vme range offset */ u_int32_t sc_len; /* length of range */ u_int32_t sc_sbusoffset; /* sbus phys address */ u_int32_t sc_type; /* amcode type */ }; struct cfattach fvme_ca = { sizeof (struct fvme_softc), fvmematch, fvmeattach }; struct cfdriver fvme_cd = { NULL, "fvme", DV_DULL }; int fgamatch(parent, vcf, aux) struct device *parent; void *vcf, *aux; { struct confargs *ca = aux; struct romaux *ra = &ca->ca_ra; if (strcmp("VME", ra->ra_name)) return (0); return (1); } void fgaattach(parent, self, aux) struct device *parent, *self; void *aux; { struct confargs *ca = aux, oca; struct fga_softc *sc = (struct fga_softc *)self; char *s; int i, rlen; if (sc->sc_dev.dv_unit > 0) { printf(" unsupported\n"); return; } /* map registers */ if (ca->ca_ra.ra_nreg != 1) { printf(": expected 1 register, got %d\n", ca->ca_ra.ra_nreg); return; } sc->sc_regs = mapiodev(&(ca->ca_ra.ra_reg[0]), 0, ca->ca_ra.ra_reg[0].rr_len); sc->sc_node = ca->ca_ra.ra_node; i = opennode("/iommu/sbus"); if (i == 0) { printf(": no iommu or sbus found, unconfigured\n"); return; } rlen = getproplen(i, "ranges"); sc->sc_range = (struct rom_range *)malloc(rlen, M_DEVBUF, M_NOWAIT); if (sc->sc_range == NULL) { printf(": PROM ranges too large: %d\n", rlen); return; } sc->sc_nrange = rlen / sizeof(struct rom_range); (void)getprop(i, "ranges", sc->sc_range, rlen); s = getpropstring(sc->sc_node, "model"); printf(": model %s id %c%c%c\n", s, sc->sc_regs->id[0], sc->sc_regs->id[1], sc->sc_regs->id[2]); /* * The prom leaves at least one of the ranges "on", so make sure * they are all off. */ for (i = 0; i < 16; i++) sc->sc_regs->vme_range[i] |= VME_RANGE_DECEN; sc->sc_regs->sbus_ssel[0] &= ~(SBUS_SSEL_Y); sc->sc_regs->sbus_ssel[0] |= SBUS_SSEL_Y_SLOT4; sc->sc_regs->sbus_ssel[1] &= ~(SBUS_SSEL_X | SBUS_SSEL_Y); sc->sc_regs->sbus_ssel[1] |= SBUS_SSEL_X_SLOT5 | SBUS_SSEL_Y_SLOT5; sc->sc_regs->sbus_ssel[2] &= ~(SBUS_SSEL_X | SBUS_SSEL_Y); sc->sc_regs->sbus_ssel[2] |= SBUS_SSEL_X_SLOT5 | SBUS_SSEL_Y_SLOT1; sc->sc_regs->sbus_ssel[3] &= ~(SBUS_SSEL_X | SBUS_SSEL_Y); sc->sc_regs->sbus_ssel[3] |= SBUS_SSEL_X_SLOT1 | SBUS_SSEL_Y_SLOT1; /* * Map and attach vme<->sbus master ranges */ fga_vmerangemap(sc, 0xf0000000, 0x10000000, VME_MASTER_CAP_D32 | VME_MASTER_CAP_A32, 1, 0, &oca); fga_vmerangemap(sc, 0xf0000000, 0x10000000, VME_MASTER_CAP_D16 | VME_MASTER_CAP_A32, 4, 0, &oca); fga_vmerangemap(sc, 0x00000000, 0x01000000, VME_MASTER_CAP_D16 | VME_MASTER_CAP_A24, 5, 0xe000000, &oca); fga_vmerangemap(sc, 0x00000000, 0x00010000, VME_MASTER_CAP_D8 | VME_MASTER_CAP_A16, 5, 0x0ffc0000, &oca); fga_vmerangemap(sc, 0x00000000, 0x00010000, VME_MASTER_CAP_D16 | VME_MASTER_CAP_A16, 5, 0x0ffd0000, &oca); fga_vmerangemap(sc, 0x00000000, 0x00010000, VME_MASTER_CAP_D32 | VME_MASTER_CAP_A16, 5, 0x0ffe0000, &oca); #ifdef DDB s = getpropstring(optionsnode, "abort-ena?"); if (s && strcmp(s, "true") == 0) { sc->sc_abort = 1; fga_hwintr_establish(sc, IRQ_MAP_SINT7); sc->sc_regs->abort_irq_map &= ~IRQ_MAP_INT_MASK; sc->sc_regs->abort_irq_map |= IRQ_MAP_SINT7; sc->sc_regs->abort_irq_map &= ~IRQ_MAP_ENABLE; } #endif } int fgaprint(args, name) void *args; const char *name; { struct confargs *ca = args; if (name) printf("%s at %s", ca->ca_ra.ra_name, name); printf(" slot %d addr 0x%x", ca->ca_slot, ca->ca_offset); return (UNCONF); } /* * Map a region of VME space to a sbus slot/offset. */ int fga_vmerangemap(sc, vmebase, vmelen, vmecap, sbusslot, sbusoffset, oca) struct fga_softc *sc; u_int32_t vmebase, vmelen; int vmecap; int sbusslot; u_int32_t sbusoffset; struct confargs *oca; { struct fga_regs *regs = sc->sc_regs; u_int32_t rval; u_int8_t sval; int range, i, srange; for (i = 0; i < FVME_MAX_RANGES; i++) { if (regs->vme_range[i] & VME_RANGE_DECEN) break; } if (i == FVME_MAX_RANGES) return (-1); range = i; for (srange = 0; srange < sc->sc_nrange; srange++) { if (sbusslot == sc->sc_range[srange].cspace) break; } if (srange == sc->sc_nrange) return (-1); bzero(oca, sizeof(*oca)); oca->ca_bustype = BUS_FGA; oca->ca_slot = sbusslot; oca->ca_offset = sc->sc_range[srange].poffset | sbusoffset; oca->ca_ra.ra_name = "fvme"; oca->ca_ra.ra_nreg = 2; oca->ca_ra.ra_reg[0].rr_len = vmelen; oca->ca_ra.ra_reg[0].rr_paddr = (void *)(sc->sc_range[srange].poffset | sbusoffset); oca->ca_ra.ra_reg[0].rr_iospace = sbusslot; oca->ca_ra.ra_reg[1].rr_iospace = vmecap; oca->ca_ra.ra_reg[1].rr_paddr = (void *)vmebase; oca->ca_ra.ra_reg[1].rr_len = vmelen; /* 1. Setup slot select register for this range. */ switch (sbusslot) { case 1: sval = SBUS_SSEL_Y_SLOT1; break; case 2: sval = SBUS_SSEL_Y_SLOT2; break; case 3: sval = SBUS_SSEL_Y_SLOT3; break; case 4: sval = SBUS_SSEL_Y_SLOT4; break; case 5: sval = SBUS_SSEL_Y_SLOT5; break; default: return (-1); } if (range & 1) { regs->sbus_ssel[range >> 1] &= ~SBUS_SSEL_Y; regs->sbus_ssel[range >> 1] |= sval; } else { regs->sbus_ssel[range >> 1] &= ~SBUS_SSEL_X; regs->sbus_ssel[range >> 1] |= sval << 4; } /* 2. Setup and enable the VME master range. */ rval = regs->vme_range[range]; rval &= ~(VME_RANGE_VMAE | VME_RANGE_VMAT); rval |= (vmebase >> 13) & (VME_RANGE_VMAE | VME_RANGE_VMAT); rval &= ~VME_RANGE_VMRCC; rval |= ((sbusoffset << 4) | (vmelen << 3)) & VME_RANGE_VMRCC; rval &= ~VME_RANGE_DECEN; regs->vme_range[range] = rval; /* 3. Setup addr/data capabilities for the range. */ regs->vme_master_cap[range] &= ~(VME_MASTER_CAP_DATA | VME_MASTER_CAP_ADDR); regs->vme_master_cap[range] |= vmecap; (void)config_found(&sc->sc_dev, oca, fgaprint); return (0); } int fga_hwintr1(v) void *v; { struct fga_softc *sc = v; struct fga_regs *regs = sc->sc_regs; u_int32_t bits = 0, stat; int r = 0, s; s = splhigh(); stat = regs->intr_stat; splx(s); if ((stat & INTR_STAT_VMEIRQ1) == 0) { bits |= INTR_STAT_VMEIRQ1; r |= fga_intrvec(sc, regs->viack_emu1); } s = splhigh(); regs->intr_stat &= ~bits; splx(s); return (r); } int fga_hwintr2(v) void *v; { struct fga_softc *sc = v; struct fga_regs *regs = sc->sc_regs; int r = 0; if ((regs->intr_stat & INTR_STAT_VMEIRQ2) == 0) r |= fga_intrvec(sc, regs->viack_emu2); return (r); } int fga_hwintr3(v) void *v; { struct fga_softc *sc = v; struct fga_regs *regs = sc->sc_regs; int r = 0; /* vme irq 3 */ if ((regs->intr_stat & INTR_STAT_VMEIRQ3) == 0) r |= fga_intrvec(sc, regs->viack_emu3); return (r); } int fga_hwintr4(v) void *v; { struct fga_softc *sc = v; struct fga_regs *regs = sc->sc_regs; int r = 0; if ((regs->intr_stat & INTR_STAT_VMEIRQ4) == 0) r |= fga_intrvec(sc, regs->viack_emu4); return (r); } int fga_hwintr5(v) void *v; { struct fga_softc *sc = v; struct fga_regs *regs = sc->sc_regs; int r = 0; if ((regs->intr_stat & INTR_STAT_VMEIRQ5) == 0) r |= fga_intrvec(sc, regs->viack_emu5); return (r); } int fga_hwintr6(v) void *v; { struct fga_softc *sc = v; struct fga_regs *regs = sc->sc_regs; int r = 0; if ((regs->intr_stat & INTR_STAT_VMEIRQ6) == 0) r |= fga_intrvec(sc, regs->viack_emu6); return (r); } int fga_hwintr7(v) void *v; { struct fga_softc *sc = v; struct fga_regs *regs = sc->sc_regs; int r = 0, s; u_int32_t bits = 0, stat; s = splhigh(); stat = regs->intr_stat; splx(s); #ifdef DDB if (sc->sc_abort && (stat & INTR_STAT_ABORT) == 0) { bits |= INTR_STAT_ABORT; r |= 1; Debugger(); } #endif if ((regs->intr_stat & INTR_STAT_VMEIRQ7) == 0) { bits |= INTR_STAT_VMEIRQ7; r |= fga_intrvec(sc, regs->viack_emu7); } s = splhigh(); regs->intr_stat &= ~bits; splx(s); return (r); } /* * Handle a VME vectored interrupt. */ int fga_intrvec(sc, vec) struct fga_softc *sc; u_int8_t vec; { struct intrhand *ih; int r, s = 0; if (sc->sc_vmevec == NULL) return (0); for (ih = sc->sc_vmevec[vec]; ih; ih = ih->ih_next) { r = (*ih->ih_fun)(ih->ih_arg); if (r > 0) { ih->ih_count.ec_count++; return (r); } s |= r; } return (s); } /* * Establish a VME level/vector interrupt. */ int fga_intr_establish(sc, vec, level, ih, name) struct fga_softc *sc; int vec, level; struct intrhand *ih; const char *name; { struct intrhand *ihs; const u_int8_t level_to_sint[] = { IRQ_MAP_INT, IRQ_MAP_SINT1, IRQ_MAP_SINT2, IRQ_MAP_SINT3, IRQ_MAP_SINT4, IRQ_MAP_SINT5, IRQ_MAP_SINT6, IRQ_MAP_SINT7 }; const u_int8_t level_to_irqmap[] = {0xff, 6, 5, 4, 3, 2, 1, 0}; #ifdef DIAGNOSTIC if (level < 1 || level > 7) panic("fga_level"); #endif /* setup vector handler */ if (sc->sc_vmevec == NULL) { sc->sc_vmevec = (struct intrhand **)malloc(256 * sizeof(struct intrhand *), M_DEVBUF, M_NOWAIT); if (sc->sc_vmevec == NULL) panic("fga_addirq"); bzero(sc->sc_vmevec, 256 * sizeof(struct intrhand *)); } if (sc->sc_vmevec[vec] == NULL) sc->sc_vmevec[vec] = ih; else { ihs = sc->sc_vmevec[vec]; while (ihs->ih_next) ihs = ihs->ih_next; ih->ih_next = ih; } ih->ih_vec = level; evcount_attach(&ih->ih_count, name, &ih->ih_vec, &evcount_intr); /* setup hardware handler */ fga_hwintr_establish(sc, level_to_sint[level]); /* setup/enable vme -> sbus irq mapping */ sc->sc_regs->virq_map[level_to_irqmap[level]] &= ~IRQ_MAP_INT_MASK; sc->sc_regs->virq_map[level_to_irqmap[level]] |= level_to_sint[level]; sc->sc_regs->virq_map[level_to_irqmap[level]] &= ~IRQ_MAP_ENABLE; return (0); } /* * Establish a hardware interrupt, making sure we're not there already. */ int fga_hwintr_establish(sc, sint) struct fga_softc *sc; u_int8_t sint; { const int sint_to_pri[] = {0, 2, 3, 5, 6, 7, 8, 9}; if (sc->sc_established & (1 << sint)) return (0); switch (sint) { case 1: sc->sc_ih1.ih_fun = fga_hwintr1; sc->sc_ih1.ih_arg = sc; intr_establish(sint_to_pri[sint], &sc->sc_ih1, -1, NULL); break; case 2: sc->sc_ih2.ih_fun = fga_hwintr2; sc->sc_ih2.ih_arg = sc; intr_establish(sint_to_pri[sint], &sc->sc_ih2, -1, NULL); break; case 3: sc->sc_ih3.ih_fun = fga_hwintr3; sc->sc_ih3.ih_arg = sc; intr_establish(sint_to_pri[sint], &sc->sc_ih3, -1, NULL); break; case 4: sc->sc_ih4.ih_fun = fga_hwintr4; sc->sc_ih4.ih_arg = sc; intr_establish(sint_to_pri[sint], &sc->sc_ih4, -1, NULL); break; case 5: sc->sc_ih5.ih_fun = fga_hwintr5; sc->sc_ih5.ih_arg = sc; intr_establish(sint_to_pri[sint], &sc->sc_ih5, -1, NULL); break; case 6: sc->sc_ih6.ih_fun = fga_hwintr6; sc->sc_ih6.ih_arg = sc; intr_establish(sint_to_pri[sint], &sc->sc_ih6, -1, NULL); break; case 7: sc->sc_ih7.ih_fun = fga_hwintr7; sc->sc_ih7.ih_arg = sc; intr_establish(sint_to_pri[sint], &sc->sc_ih7, -1, NULL); break; #ifdef DIAGNOSTIC default: panic("fga_sint"); #endif } sc->sc_established |= 1 << sint; return (0); } int fgaopen(dev, flags, mode, p) dev_t dev; int flags, mode; struct proc *p; { struct fga_softc *sc; if (fga_cd.cd_ndevs == 0) return (ENXIO); sc = fga_cd.cd_devs[0]; if (sc == NULL) return (ENXIO); return (0); } int fgaclose(dev, flags, mode, p) dev_t dev; int flags, mode; struct proc *p; { return (0); } int fgaioctl(dev, cmd, data, flags, p) dev_t dev; u_long cmd; caddr_t data; int flags; struct proc *p; { struct fga_softc *sc = fga_cd.cd_devs[0]; struct fga_sem *fsem = (struct fga_sem *)data; int error = 0; switch (cmd) { case FGAIOCSEM: if (fsem->fgasem_num >= 48) { error = ENOENT; break; } sc->sc_regs->sem[fsem->fgasem_num] = 0xff; break; case FGAIOGSEM: if (fsem->fgasem_num >= 48) { error = ENOENT; break; } fsem->fgasem_val = (sc->sc_regs->sem[fsem->fgasem_num] & MBOX_SEM) ? 0 : 1; break; case FGAIOCMBX: if (fsem->fgasem_num >= 16) { error = ENOENT; break; } sc->sc_regs->mbox[fsem->fgasem_num] = 0xff; break; case FGAIOGMBX: if (fsem->fgasem_num >= 16) { error = ENOENT; break; } fsem->fgasem_val = sc->sc_regs->mbox[fsem->fgasem_num] ? 0 : 1; break; default: error = EINVAL; } return (error); } int fvmematch(parent, vcf, aux) struct device *parent; void *vcf, *aux; { struct confargs *ca = aux; struct romaux *ra = &ca->ca_ra; if (strcmp("fvme", ra->ra_name) || ca->ca_bustype != BUS_FGA) return (0); return (1); } const struct fvme_types { int data_cap; int addr_cap; const char *name; int bustype; } fvme_types[] = { {0, 0, "a16d8", BUS_FGA_A16D8}, {0, 1, "a24d8", BUS_FGA_A24D8}, {0, 2, "a32d8", BUS_FGA_A32D8}, {1, 0, "a16d16", BUS_FGA_A16D16}, {1, 1, "a24d16", BUS_FGA_A24D16}, {1, 2, "a32d16", BUS_FGA_A32D16}, {2, 0, "a16d32", BUS_FGA_A16D32}, {2, 1, "a24d32", BUS_FGA_A24D32}, {2, 2, "a32d32", BUS_FGA_A32D32}, {3, 0, "a16blt", -1}, {3, 1, "a24blt", -1}, {3, 2, "a32blt", -1}, {4, 0, "a16mblt", -1}, {4, 1, "a24mblt", -1}, {4, 2, "a32mblt", -1}, {-1, -1, "", -1}, }; void fvmeattach(parent, self, aux) struct device *parent, *self; void *aux; { struct confargs *ca = aux; const struct fvme_types *p; int dtype, atype; atype = (ca->ca_ra.ra_reg[1].rr_iospace & VME_MASTER_CAP_ADDR) >> 2; dtype = (ca->ca_ra.ra_reg[1].rr_iospace & VME_MASTER_CAP_DATA) >> 5; for (p = fvme_types; p->data_cap != -1; p++) { if (p->data_cap == dtype && p->addr_cap == atype) break; } if (p->data_cap == -1) { printf(" unknown addr/data capability\n"); return; } printf(": %s", p->name); if (p->bustype == -1) { printf(" unsupported\n"); return; } ca->ca_ra.ra_reg[1].rr_iospace = p->bustype; printf(" offset 0x%x len 0x%x\n", ca->ca_ra.ra_reg[1].rr_paddr, ca->ca_ra.ra_reg[1].rr_len); (void)config_search(fvmescan, self, aux); } int fvmescan(parent, child, aux) struct device *parent; void *child, *aux; { struct cfdata *cf = child; struct confargs *ca = aux, oca; int plen, paddr; if (cf->cf_loc[0] == -1) return (0); if ((unsigned)cf->cf_loc[0] < (unsigned)ca->ca_ra.ra_reg[1].rr_paddr) return (0); paddr = cf->cf_loc[0] - (int)ca->ca_ra.ra_reg[1].rr_paddr; paddr = (int)ca->ca_ra.ra_reg[0].rr_paddr + paddr; plen = cf->cf_loc[0] - (int)ca->ca_ra.ra_reg[1].rr_paddr; plen = ca->ca_ra.ra_reg[1].rr_len - plen; oca.ca_bustype = ca->ca_ra.ra_reg[1].rr_iospace; oca.ca_offset = cf->cf_loc[0]; oca.ca_ra.ra_nintr = 1; oca.ca_ra.ra_intr[0].int_pri = cf->cf_loc[1]; oca.ca_ra.ra_intr[0].int_vec = cf->cf_loc[2]; oca.ca_ra.ra_name = cf->cf_driver->cd_name; oca.ca_ra.ra_nreg = 1; oca.ca_ra.ra_reg[0].rr_paddr = (void *)paddr; oca.ca_ra.ra_reg[0].rr_iospace = ca->ca_ra.ra_reg[0].rr_iospace; oca.ca_ra.ra_reg[0].rr_len = plen; oca.ca_ra.ra_reg[0].rr_paddr = mapdev(&oca.ca_ra.ra_reg[0], TMPMAP_VA, 0, NBPG); if ((*cf->cf_attach->ca_match)(parent, cf, &oca) == 0) { bus_untmp(); return (0); } bus_untmp(); oca.ca_ra.ra_reg[0].rr_paddr = (void *)paddr; config_attach(parent, cf, &oca, fvmeprint); return (1); } int fvmeprint(args, name) void *args; const char *name; { struct confargs *ca = args; if (name) printf("%s at %s", ca->ca_ra.ra_name, name); printf(" addr 0x%x", ca->ca_offset); return (UNCONF); } int fvmeintrestablish(dsc, vec, level, ih, name) struct device *dsc; int vec, level; struct intrhand *ih; const char *name; { struct fga_softc *fsc = (struct fga_softc *)dsc->dv_parent; return (fga_intr_establish(fsc, vec, level, ih, name)); }