/* $OpenBSD: vme.c,v 1.4 1996/06/11 10:15:26 deraadt Exp $ */ /* * Copyright (c) 1995 Theo de Raadt * All rights reserved. * * 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. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed under OpenBSD by * Theo de Raadt for Willowglen Singapore. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * 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. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "pcc.h" #include "mc.h" #include "pcctwo.h" #if NPCC > 0 #include #endif #if NMC > 0 #include #endif #if NPCCTWO > 0 #include #endif int vmematch __P((struct device *, void *, void *)); void vmeattach __P((struct device *, struct device *, void *)); int vme1chip_init __P((struct vmesoftc *sc)); int vme2chip_init __P((struct vmesoftc *sc)); u_long vme2chip_map __P((u_long base, int len, int dwidth)); int vme2abort __P((struct frame *frame)); static int vmebustype; struct cfattach vme_ca = { sizeof(struct vmesoftc), vmematch, vmeattach }; struct cfdriver vme_cd = { NULL, "vme", DV_DULL, 0 }; int vmematch(parent, cf, args) struct device *parent; void *cf; void *args; { struct confargs *ca = args; #if NMC > 0 if (ca->ca_bustype == BUS_MC) { struct mcreg *mc = (struct mcreg *)ca->ca_master; if (mc->mc_ver & MC_VER_NOVME) return (0); } #endif return (1); } /* * Returns a physical address mapping for a VME address & length. * Note: on some hardware it is not possible to create certain * mappings, ie. the MVME147 cannot do 32 bit accesses to VME bus * addresses from 0 to physmem. */ void * vmepmap(sc, vmeaddr, len, bustype) struct vmesoftc *sc; void *vmeaddr; int len; int bustype; { u_int32_t base = (u_int32_t)vmeaddr; len = roundup(len, NBPG); switch (vmebustype) { #if NPCC > 0 case BUS_PCC: switch (bustype) { case BUS_VMES: printf("base %8x/%8x len %8x\n", vmeaddr, base, len); if (base > VME1_A16BASE && (base+len - VME1_A16BASE) < VME1_A16D16LEN) { base = base - VME1_A16BASE + VME1_A16D16BASE; printf("vmes1: base = %8x\n", base); /* 1:1 */ } else if (base > VME1_A32D16BASE && base+len < VME1_A16BASE) { /* 1:1 mapped */ printf("vmes2: base = %8x\n", base); } else { printf("%s: cannot map pa %x len %x\n", sc->sc_dev.dv_xname, base, len); return (NULL); } break; case BUS_VMEL: if (base >= physmem && (base+len) < VME1_A32D32LEN) base = base + VME1_A32D32BASE; else if (base+len < VME1_A32D16LEN) /* HACK! */ base = base + VME1_A32D16BASE; else { printf("%s: cannot map pa %x len %x\n", sc->sc_dev.dv_xname, base, len); return (NULL); } break; } break; #endif #if NMC > 0 || NPCCTWO > 0 case BUS_MC: case BUS_PCCTWO: switch (bustype) { case BUS_VMES: if (base > VME2_A16BASE && (base+len-VME2_A16BASE) < VME2_A16D16LEN) base = base - VME2_A16BASE + VME2_A16D16BASE; else if (base > VME2_A24BASE && (base+len-VME2_A24BASE) < VME2_A24D16LEN) base = base - VME2_A24BASE + VME2_A24D16BASE; else if ((base+len) < VME2_A32D16LEN) base = base + VME2_A32D16BASE; else { base = vme2chip_map(base, len, 16); if (base == NULL) return (NULL); } break; case BUS_VMEL: #if 0 if (base > VME2_A16BASE && (base+len-VME2_A16BASE) < VME2_A16D32LEN) base = base - VME2_A16BASE + VME2_A16D32BASE; #endif base = vme2chip_map(base, len, 32); if (base == NULL) return (NULL); break; } break; #endif } return ((void *)base); } /* if successful, returns the va of a vme bus mapping */ void * vmemap(sc, vmeaddr, len, bustype) struct vmesoftc *sc; void *vmeaddr; int len; int bustype; { void *pa, *va; pa = vmepmap(sc, vmeaddr, len, bustype); if (pa == NULL) return (NULL); va = mapiodev(pa, len); return (va); } void vmeunmap(va, len) void *va; int len; { unmapiodev(va, len); } int vmerw(sc, uio, flags, bus) struct vmesoftc *sc; struct uio *uio; int flags; int bus; { register vm_offset_t o, v; register int c; register struct iovec *iov; void *vme; int error = 0; while (uio->uio_resid > 0 && error == 0) { iov = uio->uio_iov; if (iov->iov_len == 0) { uio->uio_iov++; uio->uio_iovcnt--; if (uio->uio_iovcnt < 0) panic("vmerw"); continue; } v = uio->uio_offset; c = min(iov->iov_len, MAXPHYS); if ((v & PGOFSET) + c > NBPG) /* max NBPG at a time */ c = NBPG - (v & PGOFSET); if (c == 0) return (0); vme = vmemap(sc, (void *)(v & ~PGOFSET), NBPG, BUS_VMES); if (vme == NULL) { error = EFAULT; /* XXX? */ continue; } error = uiomove((void *)vme + (v & PGOFSET), c, uio); vmeunmap(vme, NBPG); } return (error); } int vmeprint(args, bus) void *args; char *bus; { struct confargs *ca = args; printf(" offset 0x%x", ca->ca_offset); if (ca->ca_vec > 0) printf(" vec %d", ca->ca_vec); if (ca->ca_ipl > 0) printf(" ipl %d", ca->ca_ipl); return (UNCONF); } int vmescan(parent, child, args, bustype) struct device *parent; void *child, *args; int bustype; { struct cfdata *cf = child; struct vmesoftc *sc = (struct vmesoftc *)parent; struct confargs *ca = args; struct confargs oca; if (parent->dv_cfdata->cf_driver->cd_indirect) { printf(" indirect devices not supported\n"); return 0; } bzero(&oca, sizeof oca); oca.ca_bustype = bustype; oca.ca_paddr = (void *)cf->cf_loc[0]; oca.ca_len = cf->cf_loc[1]; oca.ca_vec = cf->cf_loc[2]; oca.ca_ipl = cf->cf_loc[3]; if (oca.ca_ipl > 0 && oca.ca_vec == -1) oca.ca_vec = intr_findvec(255, 0); if (oca.ca_len == -1) oca.ca_len = 4096; oca.ca_offset = (u_int)oca.ca_paddr; printf("pa=%8x len=%8x vec=%d ipl=%d\n", oca.ca_paddr, oca.ca_len, oca.ca_vec, oca.ca_ipl); oca.ca_vaddr = vmemap(sc, oca.ca_paddr, oca.ca_len, oca.ca_bustype); if (!oca.ca_vaddr) oca.ca_vaddr = (void *)-1; printf("va=%8x\n", oca.ca_vaddr); oca.ca_master = (void *)sc; oca.ca_name = cf->cf_driver->cd_name; if ((*cf->cf_attach->ca_match)(parent, cf, &oca) == 0) { if (oca.ca_vaddr != (void *)-1) vmeunmap(oca.ca_vaddr, oca.ca_len); return (0); } /* * If match works, the driver is responsible for * vmunmap()ing if it does not need the mapping. */ config_attach(parent, cf, &oca, vmeprint); return (1); } void vmeattach(parent, self, args) struct device *parent, *self; void *args; { struct vmesoftc *sc = (struct vmesoftc *)self; struct confargs *ca = args; struct vme1reg *vme1; struct vme2reg *vme2; int scon; sc->sc_vaddr = ca->ca_vaddr; vmebustype = ca->ca_bustype; switch (ca->ca_bustype) { #if NPCC > 0 case BUS_PCC: vme1 = (struct vme1reg *)sc->sc_vaddr; scon = (vme1->vme1_scon & VME1_SCON_SWITCH); printf(": %sscon\n", scon ? "" : "not "); vme1chip_init(sc); break; #endif #if NMC > 0 || NPCCTWO > 0 case BUS_MC: case BUS_PCCTWO: vme2 = (struct vme2reg *)sc->sc_vaddr; scon = (vme2->vme2_tctl & VME2_TCTL_SCON); printf(": %sscon\n", scon ? "" : "not "); vme2chip_init(sc); break; #endif } while (config_found(self, NULL, NULL)) ; } /* * On the VMEbus, only one cpu may be configured to respond to any * particular vme ipl. Therefore, it wouldn't make sense to globally * enable all the interrupts all the time -- it would not be possible * to put two cpu's and one vme card into a single cage. Rather, we * enable each vme interrupt only when we are attaching a device that * uses it. This makes it easier (though not trivial) to put two cpu * cards in one VME cage, and both can have some limited access to vme * interrupts (just can't share the same irq). * Obviously no check is made to see if another cpu is using that * interrupt. If you share you will lose. */ int vmeintr_establish(vec, ih) int vec; struct intrhand *ih; { struct vmesoftc *sc = (struct vmesoftc *) vme_cd.cd_devs[0]; #if NPCC > 0 struct vme1reg *vme1; #endif #if NMC > 0 || NPCCTWO > 0 struct vme2reg *vme2; #endif int x; x = (intr_establish(vec, ih)); switch (vmebustype) { #if NPCC > 0 case BUS_PCC: vme1 = (struct vme1reg *)sc->sc_vaddr; vme1->vme1_irqen = vme1->vme1_irqen | VME1_IRQ_VME(ih->ih_ipl); break; #endif #if NMC > 0 || NPCCTWO > 0 case BUS_MC: case BUS_PCCTWO: vme2 = (struct vme2reg *)sc->sc_vaddr; vme2->vme2_irqen = vme2->vme2_irqen | VME2_IRQ_VME(ih->ih_ipl); break; #endif } return (x); } #if defined(MVME147) int vme1chip_init(sc) struct vmesoftc *sc; { struct vme1reg *vme1 = (struct vme1reg *)sc->sc_vaddr; vme1->vme1_scon &= ~VME1_SCON_SYSFAIL; /* XXX doesn't work */ } #endif #if defined(MVME162) || defined(MVME167) || defined(MVME177) /* * make local addresses 1G-2G correspond to VME addresses 3G-4G, * as D32 */ #define VME2_D32STARTPHYS (1*1024*1024*1024UL) #define VME2_D32ENDPHYS (2*1024*1024*1024UL) #define VME2_D32STARTVME (3*1024*1024*1024UL) #define VME2_D32BITSVME (3*1024*1024*1024UL) /* * make local addresses 3G-3.75G correspond to VME addresses 3G-3.75G, * as D16 */ #define VME2_D16STARTPHYS (3*1024*1024*1024UL) #define VME2_D16ENDPHYS (3*1024*1024*1024UL + 768*1024*1024UL) /* * XXX what AM bits should be used for the D32/D16 mappings? */ int vme2chip_init(sc) struct vmesoftc *sc; { struct vme2reg *vme2 = (struct vme2reg *)sc->sc_vaddr; u_long ctl; /* turn off SYSFAIL LED */ vme2->vme2_tctl &= ~VME2_TCTL_SYSFAIL; ctl = vme2->vme2_masterctl; #if 0 /* unused decoders 1 & 2 */ printf("%s: phys 0x%08x-0x%08x to VMExxx 0x%08x-0x%08x\n", sc->sc_dev.dv_xname, vme2->vme2_master1 << 16, vme2->vme2_master1 & 0xffff0000, vme2->vme2_master1 << 16, vme2->vme2_master1 & 0xffff0000); printf("%s: phys 0x%08x-0x%08x to VMExxx 0x%08x-0x%08x\n", sc->sc_dev.dv_xname, vme2->vme2_master2 << 16, vme2->vme2_master2 & 0xffff0000, vme2->vme2_master2 << 16, vme2->vme2_master2 & 0xffff0000); #endif /* setup a D16 space */ vme2->vme2_master3 = ((VME2_D16ENDPHYS-1) & 0xffff0000) | (VME2_D16STARTPHYS >> 16); ctl &= ~(VME2_MASTERCTL_ALL << VME2_MASTERCTL_3SHIFT); ctl |= (VME2_MASTERCTL_AM32SP | VME2_MASTERCTL_D16) << VME2_MASTERCTL_3SHIFT; #if 0 printf("%s: phys 0x%08x-0x%08x to VMED16 0x%08x-0x%08x\n", sc->sc_dev.dv_xname, VME2_D16STARTPHYS, VME2_D16ENDPHYS-1, VME2_D16STARTPHYS, VME2_D16ENDPHYS-1); #endif /* setup a D32 space */ vme2->vme2_master4 = ((VME2_D32ENDPHYS-1) & 0xffff0000) | (VME2_D32STARTPHYS >> 16); vme2->vme2_master4mod = (VME2_D32STARTVME & 0xffff0000) | (VME2_D32BITSVME >> 16); ctl &= ~(VME2_MASTERCTL_ALL << VME2_MASTERCTL_4SHIFT); ctl |= (VME2_MASTERCTL_AM32SP) << VME2_MASTERCTL_4SHIFT; #if 0 printf("%s: phys 0x%08x-0x%08x to VMED32 0x%08x-0x%08x\n", sc->sc_dev.dv_xname, VME2_D32STARTPHYS, VME2_D32ENDPHYS-1, VME2_D32STARTVME, VME2_D32STARTVME | ~VME2_D32BITSVME); #endif vme2->vme2_masterctl = ctl; ctl = vme2->vme2_gcsrctl; /* enable A16 short IO map decoder (0xffffxxxx) */ ctl &= ~(VME2_GCSRCTL_I1EN | VME2_GCSRCTL_I1D16 | VME2_GCSRCTL_I1WP | VME2_GCSRCTL_I1SU); ctl |= VME2_GCSRCTL_I1EN | VME2_GCSRCTL_I1D16 | VME2_GCSRCTL_I1SU; /* enable A24D16 (0xf0xxxxxx) and A32D16 (0xf[1-e]xxxxxx) decoders */ ctl &= ~(VME2_GCSRCTL_I2EN | VME2_GCSRCTL_I2WP | VME2_GCSRCTL_I2SU | VME2_GCSRCTL_I2PD); ctl |= VME2_GCSRCTL_I2EN | VME2_GCSRCTL_I2SU | VME2_GCSRCTL_I2PD; /* map decoders 3 & 4 which were just configured */ ctl &= ~(VME2_GCSRCTL_MDEN4 | VME2_GCSRCTL_MDEN3 | VME2_GCSRCTL_MDEN1 | VME2_GCSRCTL_MDEN2); ctl |= VME2_GCSRCTL_MDEN4 | VME2_GCSRCTL_MDEN3; vme2->vme2_gcsrctl = ctl; /* * Map the VME irq levels to the cpu levels 1:1. * This is rather inflexible, but much easier. */ vme2->vme2_irql4 = (7 << VME2_IRQL4_VME7SHIFT) | (6 << VME2_IRQL4_VME6SHIFT) | (5 << VME2_IRQL4_VME5SHIFT) | (4 << VME2_IRQL4_VME4SHIFT) | (3 << VME2_IRQL4_VME3SHIFT) | (2 << VME2_IRQL4_VME2SHIFT) | (1 << VME2_IRQL4_VME1SHIFT); #if NPCCTWO > 0 if (vmebustype == BUS_PCCTWO) { sc->sc_abih.ih_fn = vme2abort; sc->sc_abih.ih_arg = 0; sc->sc_abih.ih_ipl = 7; sc->sc_abih.ih_wantframe = 1; intr_establish(110, &sc->sc_abih); /* XXX 110 */ vme2->vme2_irqen |= VME2_IRQ_AB; } #endif } /* * A32 accesses on the MVME1[67]x require setting up mappings in * the VME2 chip. * XXX VME address must be between 2G and 4G * XXX We only support D32 at the moment.. */ u_long vme2chip_map(base, len, dwidth) u_long base; int len, dwidth; { switch (dwidth) { case 16: if (base < VME2_D16STARTPHYS || base + (u_long)len > VME2_D16ENDPHYS) return (NULL); return (base); case 32: if (base < VME2_D32STARTVME) return (NULL); return (base - VME2_D32STARTVME + VME2_D32STARTPHYS); } } #if NPCCTWO > 0 int vme2abort(frame) struct frame *frame; { struct vmesoftc *sc = (struct vmesoftc *)vme_cd.cd_devs[0]; struct vme2reg *vme2 = (struct vme2reg *)sc->sc_vaddr; if (vme2->vme2_irqstat & VME2_IRQ_AB == 0) { printf("%s: vme2chip irq not set\n", sc->sc_dev.dv_xname); return (0); } vme2->vme2_irqclr = VME2_IRQ_AB; nmihand(frame); return (1); } #endif #endif