/* $OpenBSD: asc_ioasic.c,v 1.4 1998/05/18 00:25:08 millert Exp $ */ /* $NetBSD: asc_ioasic.c,v 1.12 1998/01/12 09:51:30 thorpej Exp $ */ /* * Copyright 1996 The Board of Trustees of The Leland Stanford * Junior University. All Rights Reserved. * * Permission to use, copy, modify, and distribute this * software and its documentation for any purpose and without * fee is hereby granted, provided that the above copyright * notice appear in all copies. Stanford University * makes no representations about the suitability of this * software for any purpose. It is provided "as is" without * express or implied warranty. * */ #define USE_CACHED_BUFFER 0 #include #include #include #include #include #include #include /* XXX */ #include /* XXX */ #include /* XXX */ #include #include #include /* bus, cache consistency, etc */ /*XXX*/ #include /* XXX ioasic register defs? */ #include /* XXX ioasic register defs? */ #include extern int pmax_boardtype; extern vm_offset_t kvtophys __P((vm_offset_t)); /* * Autoconfiguration data for config. */ int asc_ioasic_match __P((struct device *, void *, void *)); void asc_ioasic_attach __P((struct device *, struct device *, void *)); struct cfattach asc_ioasic_ca = { sizeof(struct asc_softc), asc_ioasic_match, asc_ioasic_attach }; #ifdef notdef extern struct cfdriver asc_cd; #endif /* * DMA callback declarations */ #ifdef ASC_IOASIC_BOUNCE extern u_long asc_iomem; #endif static int asic_dma_start __P((asc_softc_t asc, State *state, caddr_t cp, int flag, int len, int off)); static void asic_dma_end __P((asc_softc_t asc, State *state, int flag)); int asc_ioasic_match(parent, match, aux) struct device *parent; void *match; void *aux; { struct ioasicdev_attach_args *d = aux; void *ascaddr; if (strncmp(d->iada_modname, "asc", TC_ROM_LLEN) && strncmp(d->iada_modname, "PMAZ-AA ", TC_ROM_LLEN)) return (0); /* probe for chip */ ascaddr = (void*)d->iada_addr; if (tc_badaddr(ascaddr + ASC_OFFSET_53C94)) return (0); return (1); } void asc_ioasic_attach(parent, self, aux) struct device *parent; struct device *self; void *aux; { register struct ioasicdev_attach_args *d = aux; register asc_softc_t asc = (asc_softc_t) self; #ifdef ASC_IOASIC_BOUNCE u_char *buff; int i; #endif void *ascaddr; int unit; ascaddr = (void*)MIPS_PHYS_TO_KSEG1(d->iada_addr); unit = asc->sc_dev.dv_unit; /* * Initialize hw descriptor, cache some pointers */ asc->regs = (asc_regmap_t *)(ascaddr + ASC_OFFSET_53C94); /* * Set up machine dependencies. * (1) how to do dma * (2) timing based on turbochannel frequency */ #ifdef ASC_IOASIC_BOUNCE #if USE_CACHED_BUFFER /* XXX Use cached address for DMA buffer to increase raw read speed */ buff = (u_char *)MIPS_PHYS_TO_KSEG0(asc_iomem); #else buff = (u_char *)MIPS_PHYS_TO_KSEG1(asc_iomem); #endif /* USE_CACHED_BUFFER */ /* * Statically partition the DMA buffer between targets. * This way we will eventually be able to attach/detach * drives on-fly. And 18k/target is plenty for normal use. */ /* * Give each target its own DMA buffer region. * We may want to try ping ponging buffers later. */ for (i = 0; i < ASC_NCMD; i++) asc->st[i].dmaBufAddr = buff + 8192 * i; #endif /* ASC_IOASIC_BOUNCE */ *((volatile int *)IOASIC_REG_SCSI_DMAPTR(ioasic_base)) = -1; *((volatile int *)IOASIC_REG_SCSI_DMANPTR(ioasic_base)) = -1; *((volatile int *)IOASIC_REG_SCSI_SCR(ioasic_base)) = 0; asc->dma_start = asic_dma_start; asc->dma_end = asic_dma_end; /* digital meters show IOASIC 53c94s are clocked at approx 25MHz */ ascattach(asc, ASC_SPEED_25_MHZ); /* tie pseudo-slot to device */ ioasic_intr_establish(parent, d->iada_cookie, TC_IPL_BIO, asc_intr, asc); } /* * DMA handling routines. For a turbochannel device, just set the dmar. * For the I/O ASIC, handle the actual DMA interface. */ static int asic_dma_start(asc, state, cp, flag, len, off) asc_softc_t asc; State *state; caddr_t cp; int flag; int len; int off; { register volatile u_int *ssr = (volatile u_int *) IOASIC_REG_CSR(ioasic_base); u_int phys, nphys; /* stop DMA engine first */ *ssr &= ~IOASIC_CSR_DMAEN_SCSI; *((volatile int *)IOASIC_REG_SCSI_SCR(ioasic_base)) = 0; #ifndef ASC_IOASIC_BOUNCE /* restrict len to the maximum the IOASIC can transfer */ if (len > ((caddr_t)mips_trunc_page(cp + NBPG * 2) - cp)) len = (caddr_t)mips_trunc_page(cp + NBPG * 2) - cp; /* If R4K, writeback and invalidate the buffer */ if (CPUISMIPS3) mips3_HitFlushDCache((vm_offset_t)cp, len); /* Get physical address of buffer start, no next phys addr */ phys = (u_int)kvtophys((vm_offset_t)cp); nphys = -1; /* Compute 2nd DMA pointer only if next page is part of this I/O */ if ((NBPG - (phys & (NBPG - 1))) < len) { cp = (caddr_t)mips_trunc_page(cp + NBPG); nphys = (u_int)kvtophys((vm_offset_t)cp); } /* If not R4K, need to invalidate cache lines for both physical segments */ if (!CPUISMIPS3 && flag == ASCDMA_READ) { MachFlushDCache(MIPS_PHYS_TO_KSEG0(phys), nphys == 0xffffffff ? len : NBPG - (phys & (NBPG - 1))); if (nphys != 0xffffffff) MachFlushDCache(MIPS_PHYS_TO_KSEG0(nphys), NBPG); /* XXX */ } #else /* ASC_IOASIC_BOUNCE */ /* restrict len to the maximum the IOASIC can transfer */ if (len > ((caddr_t)mips_trunc_page(state->dmaBufAddr + off + NBPG * 2) - (caddr_t)(state->dmaBufAddr + off))) len = (caddr_t)mips_trunc_page(state->dmaBufAddr + off + NBPG * 2) - (caddr_t)(state->dmaBufAddr + off); if (flag == ASCDMA_WRITE) bcopy(cp, state->dmaBufAddr + off, len); cp = state->dmaBufAddr + off; #if USE_CACHED_BUFFER #ifdef MIPS3 /* If R4K, need to writeback the bounce buffer */ if (CPUISMIPS3) mips3_HitFlushDCache((vm_offset_t)cp, len); #endif /* MIPS3 */ phys = MIPS_KSEG0_TO_PHYS(cp); cp = (caddr_t)mips_trunc_page(cp + NBPG); nphys = MIPS_KSEG0_TO_PHYS(cp); #else phys = MIPS_KSEG1_TO_PHYS(cp); cp = (caddr_t)mips_trunc_page(cp + NBPG); nphys = MIPS_KSEG1_TO_PHYS(cp); #endif /* USE_CACHED_BUFFER */ #endif /* ASC_IOASIC_BOUNCE */ #ifdef notyet asc->dma_next = cp; asc->dma_xfer = state->dmalen - (nphys - phys); #endif *(volatile int *)IOASIC_REG_SCSI_DMAPTR(ioasic_base) = IOASIC_DMA_ADDR(phys); *(volatile int *)IOASIC_REG_SCSI_DMANPTR(ioasic_base) = IOASIC_DMA_ADDR(nphys); if (flag == ASCDMA_READ) *ssr |= IOASIC_CSR_SCSI_DIR | IOASIC_CSR_DMAEN_SCSI; else *ssr = (*ssr & ~IOASIC_CSR_SCSI_DIR) | IOASIC_CSR_DMAEN_SCSI; wbflush(); return (len); } static void asic_dma_end(asc, state, flag) asc_softc_t asc; State *state; int flag; { register volatile u_int *ssr = (volatile u_int *) IOASIC_REG_CSR(ioasic_base); register volatile u_int *dmap = (volatile u_int *) IOASIC_REG_SCSI_DMAPTR(ioasic_base); register u_short *to; register int w; int nb; *ssr &= ~IOASIC_CSR_DMAEN_SCSI; #if USE_CACHED_BUFFER /* XXX - Should uncached address always be used? */ to = (u_short *)MIPS_PHYS_TO_KSEG0(*dmap >> 3); #else to = (u_short *)MIPS_PHYS_TO_KSEG1(*dmap >> 3); #endif *dmap = -1; *((volatile int *)IOASIC_REG_SCSI_DMANPTR(ioasic_base)) = -1; wbflush(); if (flag == ASCDMA_READ) { #if !defined(ASC_IOASIC_BOUNCE) && USE_CACHED_BUFFER /* Invalidate cache for the buffer */ #ifdef MIPS3 if (CPUISMIPS3) MachFlushDCache(MIPS_KSEG1_TO_PHYS(state->dmaBufAddr), state->dmalen); else #endif /* MIPS3 */ MachFlushDCache(MIPS_PHYS_TO_KSEG0( MIPS_KSEG1_TO_PHYS(state->dmaBufAddr)), state->dmalen); #endif /* USE_CACHED_BUFFER */ if ( (nb = *((int *)IOASIC_REG_SCSI_SCR(ioasic_base))) != 0) { /* pick up last upto6 bytes, sigh. */ /* Last byte really xferred is.. */ w = *(int *)IOASIC_REG_SCSI_SDR0(ioasic_base); *to++ = w; if (--nb > 0) { w >>= 16; *to++ = w; } if (--nb > 0) { w = *(int *)IOASIC_REG_SCSI_SDR1(ioasic_base); *to++ = w; } } #ifdef ASC_IOASIC_BOUNCE bcopy(state->dmaBufAddr, state->buf, state->dmalen); #endif } } #ifdef notdef /* * Called by asic_intr() for scsi dma pointer update interrupts. */ void asc_dma_intr() { asc_softc_t asc = &asc_cd.cd_devs[0]; /*XXX*/ u_int next_phys; asc->dma_xfer -= NBPG; if (asc->dma_xfer <= -NBPG) { volatile u_int *ssr = (volatile u_int *) IOASIC_REG_CSR(ioasic_base); *ssr &= ~IOASIC_CSR_DMAEN_SCSI; } else { asc->dma_next += NBPG; next_phys = MIPS_KSEG0_TO_PHYS(asc->dma_next); } *(volatile int *)IOASIC_REG_SCSI_DMANPTR(ioasic_base) = IOASIC_DMA_ADDR(next_phys); wbflush(); } #endif /*notdef*/