/* $OpenBSD: ts102.c,v 1.21 2015/03/28 19:07:08 miod Exp $ */ /* * Copyright (c) 2003, 2004, Miodrag Vallat. * * 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 PCMCIA controller found in Tadpole SPARCbook 3 series * notebooks. * * Based on the information provided in the SPARCbook 3 Technical Reference * Manual (s3gxtrmb.pdf), chapter 7. A few ramblings against this document * and/or the chip itself are scattered across this file. * * Implementation notes: * * - The TS102 exports its PCMCIA windows as SBus memory ranges: 64MB for * the common memory window, and 16MB for the attribute and I/O windows. * * Mapping the whole windows would consume 192MB of address space, which * is much more that what the iospace can offer. * * A best-effort solution would be to map the windows on demand. However, * due to the way mapdev() works, the va used for the mappings would be * lost after unmapping (although using an extent to register iospace memory * usage would fix this). So, instead, we will do a fixed mapping of a subset * of each window upon attach - this is similar to what the stp4020 driver * does. * * - IPL for the cards interrupt handlers are not respected. See the stp4020 * driver source for comments about this. * * Endianness farce: * * - The documentation pretends that the endianness settings only affect the * common memory window. Gee, thanks a lot. What about other windows, then? * As a result, this driver runs with endianness conversions turned off. * * - One of the little-endian SBus and big-endian PCMCIA flags has the reverse * meaning, actually. To achieve a ``no endianness conversion'' status, * one has to be set and the other unset. It does not matter which one, * though. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define TS102_NUM_SLOTS 2 /* * Memory ranges */ #define TS102_RANGE_COMMON 0 #define TS102_RANGE_ATTR 1 #define TS102_RANGE_IO 2 #define TS102_RANGE_CNT 3 #define TS102_NUM_RANGES (TS102_RANGE_CNT * TS102_NUM_SLOTS) #define TS102_ARBITRARY_MAP_SIZE (1 * 1024 * 1024) struct tslot_softc; /* * Per-slot data */ struct tslot_data { struct tslot_softc *td_parent; struct device *td_pcmcia; volatile u_int8_t *td_regs; struct rom_reg td_rr; vaddr_t td_space[TS102_RANGE_CNT]; /* Interrupt handler */ int (*td_intr)(void *); void *td_intrarg; void *td_softintr; /* Socket status */ int td_slot; int td_status; #define TS_CARD 0x0001 }; struct tslot_softc { struct device sc_dev; struct intrhand sc_ih; pcmcia_chipset_tag_t sc_pct; struct proc *sc_thread; /* event thread */ unsigned int sc_events; /* sockets with pending events */ struct tslot_data sc_slot[TS102_NUM_SLOTS]; }; void tslot_attach(struct device *, struct device *, void *); void tslot_create_event_thread(void *); void tslot_event_thread(void *); int tslot_intr(void *); void tslot_intr_disestablish(pcmcia_chipset_handle_t, void *); void tslot_intr_dispatch(void *); void *tslot_intr_establish(pcmcia_chipset_handle_t, struct pcmcia_function *, int, int (*)(void *), void *, char *); const char *tslot_intr_string(pcmcia_chipset_handle_t, void *); int tslot_io_alloc(pcmcia_chipset_handle_t, bus_addr_t, bus_size_t, bus_size_t, struct pcmcia_io_handle *); void tslot_io_free(pcmcia_chipset_handle_t, struct pcmcia_io_handle *); int tslot_io_map(pcmcia_chipset_handle_t, int, bus_addr_t, bus_size_t, struct pcmcia_io_handle *, int *); void tslot_io_unmap(pcmcia_chipset_handle_t, int); int tslot_match(struct device *, void *, void *); int tslot_mem_alloc(pcmcia_chipset_handle_t, bus_size_t, struct pcmcia_mem_handle *); void tslot_mem_free(pcmcia_chipset_handle_t, struct pcmcia_mem_handle *); int tslot_mem_map(pcmcia_chipset_handle_t, int, bus_addr_t, bus_size_t, struct pcmcia_mem_handle *, bus_size_t *, int *); void tslot_mem_unmap(pcmcia_chipset_handle_t, int); int tslot_print(void *, const char *); void tslot_queue_event(struct tslot_softc *, int); void tslot_reset(struct tslot_data *, u_int32_t); void tslot_slot_disable(pcmcia_chipset_handle_t); void tslot_slot_enable(pcmcia_chipset_handle_t); void tslot_slot_intr(struct tslot_data *, int); struct cfattach tslot_ca = { sizeof(struct tslot_softc), tslot_match, tslot_attach }; struct cfdriver tslot_cd = { NULL, "tslot", DV_DULL }; /* * PCMCIA chipset methods */ struct pcmcia_chip_functions tslot_functions = { tslot_mem_alloc, tslot_mem_free, tslot_mem_map, tslot_mem_unmap, tslot_io_alloc, tslot_io_free, tslot_io_map, tslot_io_unmap, tslot_intr_establish, tslot_intr_disestablish, tslot_intr_string, tslot_slot_enable, tslot_slot_disable }; #define TSLOT_READ(slot, offset) \ *(volatile u_int16_t *)((slot)->td_regs + (offset)) #define TSLOT_WRITE(slot, offset, value) \ *(volatile u_int16_t *)((slot)->td_regs + (offset)) = (value) /* * Attachment and initialization */ int tslot_match(struct device *parent, void *vcf, void *aux) { struct confargs *ca = aux; return (strcmp("ts102", ca->ca_ra.ra_name) == 0); } void tslot_attach(struct device *parent, struct device *self, void *args) { struct confargs *ca = args; struct tslot_softc *sc = (struct tslot_softc *)self; struct romaux *ra; struct rom_range ranges[TS102_NUM_RANGES], *range; struct tslot_data *td; volatile u_int8_t *regs; int node, nranges, slot, rnum; ra = &ca->ca_ra; node = ra->ra_node; regs = mapiodev(&ra->ra_reg[0], 0, ra->ra_len); /* * Find memory ranges */ nranges = getproplen(node, "ranges") / sizeof(struct rom_range); if (nranges < TS102_NUM_RANGES) { printf(": expected %d memory ranges, got %d\n", TS102_NUM_RANGES, nranges); return; } getprop(node, "ranges", ranges, sizeof ranges); /* * Ranges being relative to this sbus slot, turn them into absolute * addresses. */ for (rnum = 0; rnum < TS102_NUM_RANGES; rnum++) { ranges[rnum].poffset -= TS102_OFFSET_REGISTERS; } sc->sc_ih.ih_fun = tslot_intr; sc->sc_ih.ih_arg = sc; intr_establish(ra->ra_intr[0].int_pri, &sc->sc_ih, -1, self->dv_xname); printf(" pri %d", ra->ra_intr[0].int_pri); printf(": %d slots\n", TS102_NUM_SLOTS); /* * Setup asynchronous event handler */ sc->sc_events = 0; kthread_create_deferred(tslot_create_event_thread, sc); sc->sc_pct = (pcmcia_chipset_tag_t)&tslot_functions; /* * Setup slots */ for (slot = 0; slot < TS102_NUM_SLOTS; slot++) { td = &sc->sc_slot[slot]; for (rnum = 0; rnum < TS102_RANGE_CNT; rnum++) { range = ranges + (slot * TS102_RANGE_CNT + rnum); td->td_rr = ra->ra_reg[0]; td->td_rr.rr_iospace = range->pspace; td->td_rr.rr_paddr = (void *) ((u_int32_t)td->td_rr.rr_paddr + range->poffset); td->td_space[rnum] = (vaddr_t)mapiodev(&td->td_rr, 0, TS102_ARBITRARY_MAP_SIZE); } td->td_parent = sc; td->td_regs = regs + slot * (TS102_REG_CARD_B_INT - TS102_REG_CARD_A_INT); td->td_slot = slot; SET_TAG_LITTLE_ENDIAN(&td->td_rr); tslot_reset(td, TS102_ARBITRARY_MAP_SIZE); } } void tslot_reset(struct tslot_data *td, u_int32_t iosize) { struct pcmciabus_attach_args paa; int ctl, status; paa.paa_busname = "pcmcia"; paa.pct = (pcmcia_chipset_tag_t)td->td_parent->sc_pct; paa.pch = (pcmcia_chipset_handle_t)td; paa.iobase = 0; paa.iosize = iosize; td->td_pcmcia = config_found(&td->td_parent->sc_dev, &paa, tslot_print); if (td->td_pcmcia == NULL) { /* * If no pcmcia attachment, power down the slot. */ tslot_slot_disable((pcmcia_chipset_handle_t)td); return; } /* * Initialize the slot */ ctl = TSLOT_READ(td, TS102_REG_CARD_A_CTL); /* force low addresses */ ctl &= ~(TS102_CARD_CTL_AA_MASK | TS102_CARD_CTL_IA_MASK); /* Put SBus and PCMCIA in their respective endian mode */ ctl |= TS102_CARD_CTL_SBLE; /* this is not what it looks like! */ ctl &= ~TS102_CARD_CTL_PCMBE; /* disable read ahead and address increment */ ctl &= ~TS102_CARD_CTL_RAHD; ctl |= TS102_CARD_CTL_INCDIS; /* power on */ ctl &= ~TS102_CARD_CTL_PWRD; TSLOT_WRITE(td, TS102_REG_CARD_A_CTL, ctl); /* * Enable interrupt upon insertion/removal */ TSLOT_WRITE(td, TS102_REG_CARD_A_INT, TS102_CARD_INT_MASK_CARDDETECT_STATUS); status = TSLOT_READ(td, TS102_REG_CARD_A_STS); if (status & TS102_CARD_STS_PRES) { tadpole_set_pcmcia(td->td_slot, 1); td->td_status = TS_CARD; pcmcia_card_attach(td->td_pcmcia); } else { tadpole_set_pcmcia(td->td_slot, 0); td->td_status = 0; } } /* XXX there ought to be a common function for this... */ int tslot_print(void *aux, const char *description) { struct pcmciabus_attach_args *paa = aux; struct tslot_data *td = (struct tslot_data *)paa->pch; printf(" socket %d", td->td_slot); return (UNCONF); } /* * PCMCIA Helpers */ int tslot_io_alloc(pcmcia_chipset_handle_t pch, bus_addr_t start, bus_size_t size, bus_size_t align, struct pcmcia_io_handle *pih) { struct tslot_data *td = (struct tslot_data *)pch; #ifdef TSLOT_DEBUG printf("[io alloc %x-%x]", start, size); #endif pih->iot = &td->td_rr; pih->ioh = (bus_space_handle_t)(td->td_space[TS102_RANGE_IO]); pih->addr = start; pih->size = size; pih->flags = 0; return (0); } void tslot_io_free(pcmcia_chipset_handle_t pch, struct pcmcia_io_handle *pih) { #ifdef TSLOT_DEBUG printf("[io free %x-%x]", pih->start, pih->size); #endif } int tslot_io_map(pcmcia_chipset_handle_t pch, int width, bus_addr_t offset, bus_size_t size, struct pcmcia_io_handle *pih, int *windowp) { struct tslot_data *td = (struct tslot_data *)pch; #ifdef TSLOT_DEBUG printf("[io map %x-%x", offset, size); #endif pih->iot = &td->td_rr; bus_space_subregion(&td->td_rr, td->td_space[TS102_RANGE_IO], offset, size, &pih->ioh); *windowp = TS102_RANGE_IO; #ifdef TSLOT_DEBUG printf("->%p/%x]", pih->ioh, size); #endif return (0); } void tslot_io_unmap(pcmcia_chipset_handle_t pch, int win) { #ifdef TSLOT_DEBUG printf("[io unmap]"); #endif } int tslot_mem_alloc(pcmcia_chipset_handle_t pch, bus_size_t size, struct pcmcia_mem_handle *pmh) { struct tslot_data *td = (struct tslot_data *)pch; #ifdef TSLOT_DEBUG printf("[mem alloc %x]", size); #endif pmh->memt = &td->td_rr; pmh->size = round_page(size); pmh->addr = 0; pmh->mhandle = 0; pmh->realsize = 0; /* nothing so far! */ return (0); } void tslot_mem_free(pcmcia_chipset_handle_t pch, struct pcmcia_mem_handle *pmh) { #ifdef TSLOT_DEBUG printf("[mem free %x]", pmh->size); #endif } int tslot_mem_map(pcmcia_chipset_handle_t pch, int kind, bus_addr_t addr, bus_size_t size, struct pcmcia_mem_handle *pmh, bus_size_t *offsetp, int *windowp) { struct tslot_data *td = (struct tslot_data *)pch; int slot; slot = kind & PCMCIA_MEM_ATTR ? TS102_RANGE_ATTR : TS102_RANGE_COMMON; #ifdef TSLOT_DEBUG printf("[mem map %d %x-%x", slot, addr, size); #endif addr += pmh->addr; pmh->memt = &td->td_rr; bus_space_subregion(&td->td_rr, td->td_space[slot], addr, size, &pmh->memh); pmh->realsize = TS102_ARBITRARY_MAP_SIZE - addr; *offsetp = 0; *windowp = slot; #ifdef TSLOT_DEBUG printf("->%p/%x]", pmh->memh, size); #endif return (0); } void tslot_mem_unmap(pcmcia_chipset_handle_t pch, int win) { #ifdef TSLOT_DEBUG printf("[mem unmap %d]", win); #endif } void tslot_slot_disable(pcmcia_chipset_handle_t pch) { struct tslot_data *td = (struct tslot_data *)pch; #ifdef TSLOT_DEBUG printf("%s: disable slot %d\n", td->td_parent->sc_dev.dv_xname, td->td_slot); #endif /* * Disable card access. */ TSLOT_WRITE(td, TS102_REG_CARD_A_STS, TSLOT_READ(td, TS102_REG_CARD_A_STS) & ~TS102_CARD_STS_ACEN); /* * Disable interrupts, except for insertion. */ TSLOT_WRITE(td, TS102_REG_CARD_A_INT, TS102_CARD_INT_MASK_CARDDETECT_STATUS); } void tslot_slot_enable(pcmcia_chipset_handle_t pch) { struct tslot_data *td = (struct tslot_data *)pch; int status, intr, i; #ifdef TSLOT_DEBUG printf("%s: enable slot %d\n", td->td_parent->sc_dev.dv_xname, td->td_slot); #endif /* Power down the socket to reset it */ status = TSLOT_READ(td, TS102_REG_CARD_A_STS); TSLOT_WRITE(td, TS102_REG_CARD_A_STS, status | TS102_CARD_STS_VCCEN); /* * wait 300ms until power fails (Tpf). Then, wait 100ms since we * are changing Vcc (Toff). */ DELAY((300 + 100) * 1000); /* * Power on the card if not already done, and enable card access */ status |= TS102_CARD_STS_ACEN; status &= ~TS102_CARD_STS_VCCEN; TSLOT_WRITE(td, TS102_REG_CARD_A_STS, status); /* * wait 100ms until power raise (Tpr) and 20ms to become * stable (Tsu(Vcc)). */ DELAY((100 + 20) * 1000); status &= ~TS102_CARD_STS_VPP1_MASK; status |= TS102_CARD_STS_VPP1_VCC; TSLOT_WRITE(td, TS102_REG_CARD_A_STS, status); /* * hold RESET at least 20us. */ intr = TSLOT_READ(td, TS102_REG_CARD_A_INT); TSLOT_WRITE(td, TS102_REG_CARD_A_INT, TS102_CARD_INT_SOFT_RESET); DELAY(20); TSLOT_WRITE(td, TS102_REG_CARD_A_INT, intr); /* wait 20ms as per pc card standard (r2.01) section 4.3.6 */ DELAY(20 * 1000); /* We need level-triggered interrupts for PC Card hardware */ TSLOT_WRITE(td, TS102_REG_CARD_A_STS, TSLOT_READ(td, TS102_REG_CARD_A_STS) | TS102_CARD_STS_LVL); /* * Wait until the card is unbusy. If it is still busy after 3 seconds, * give up. We could enable card interrupts and wait for the interrupt * to happen when BUSY is released, but the interrupt could also be * triggered by the card itself if it's an I/O card, so better poll * here. */ for (i = 30000; i != 0; i--) { status = TSLOT_READ(td, TS102_REG_CARD_A_STS); /* If the card has been removed, abort */ if ((status & TS102_CARD_STS_PRES) == 0) { tslot_slot_disable(pch); return; } if (status & TS102_CARD_STS_RDY) break; else DELAY(100); } if (i == 0) { printf("%s: slot %d still busy after 3 seconds, status 0x%x\n", td->td_parent->sc_dev.dv_xname, td->td_slot, TSLOT_READ(td, TS102_REG_CARD_A_STS)); return; } /* * Enable the card interrupts if this is an I/O card. * Note that the TS102_CARD_STS_IO bit in the status register will * never get set, despite what the documentation says! */ if (pcmcia_card_gettype(td->td_pcmcia) == PCMCIA_IFTYPE_IO) { TSLOT_WRITE(td, TS102_REG_CARD_A_STS, TSLOT_READ(td, TS102_REG_CARD_A_STS) | TS102_CARD_STS_IO); TSLOT_WRITE(td, TS102_REG_CARD_A_INT, TS102_CARD_INT_MASK_CARDDETECT_STATUS | TS102_CARD_INT_MASK_IRQ); } } /* * Event management */ void tslot_create_event_thread(void *v) { struct tslot_softc *sc = v; const char *name = sc->sc_dev.dv_xname; if (kthread_create(tslot_event_thread, sc, &sc->sc_thread, name) != 0) { panic("%s: unable to create event kthread", name); } } void tslot_event_thread(void *v) { struct tslot_softc *sc = v; struct tslot_data *td; int s, status; unsigned int socket; for (;;) { s = splhigh(); if ((socket = ffs(sc->sc_events)) == 0) { splx(s); tsleep(&sc->sc_events, PWAIT, "tslot_event", 0); continue; } socket--; sc->sc_events &= ~(1 << socket); splx(s); if (socket >= TS102_NUM_SLOTS) { #ifdef DEBUG printf("%s: invalid slot number %d\n", sc->sc_dev.dv_xname, te->te_slot); #endif continue; } td = &sc->sc_slot[socket]; status = TSLOT_READ(td, TS102_REG_CARD_A_STS); if (status & TS102_CARD_STS_PRES) { /* Card insertion */ if ((td->td_status & TS_CARD) == 0) { td->td_status |= TS_CARD; tadpole_set_pcmcia(td->td_slot, 1); pcmcia_card_attach(td->td_pcmcia); } } else { /* Card removal */ if ((td->td_status & TS_CARD) != 0) { td->td_status &= ~TS_CARD; tadpole_set_pcmcia(td->td_slot, 0); pcmcia_card_detach(td->td_pcmcia, DETACH_FORCE); } } } } /* * Interrupt handling */ int tslot_intr(void *v) { struct tslot_softc *sc = v; struct tslot_data *td; int intregs[TS102_NUM_SLOTS], *intreg; int i, rc = 0; int s; /* protect hardware access against soft interrupts */ s = splhigh(); /* * Scan slots, and acknowledge the interrupt if necessary first */ for (i = 0; i < TS102_NUM_SLOTS; i++) { td = &sc->sc_slot[i]; intreg = &intregs[i]; *intreg = TSLOT_READ(td, TS102_REG_CARD_A_INT); /* * Acknowledge all interrupt situations at once, even if they * did not occur. */ if ((*intreg & (TS102_CARD_INT_STATUS_IRQ | TS102_CARD_INT_STATUS_WP_STATUS_CHANGED | TS102_CARD_INT_STATUS_BATTERY_STATUS_CHANGED | TS102_CARD_INT_STATUS_CARDDETECT_STATUS_CHANGED)) != 0) { rc = 1; TSLOT_WRITE(td, TS102_REG_CARD_A_INT, *intreg | TS102_CARD_INT_RQST_IRQ | TS102_CARD_INT_RQST_WP_STATUS_CHANGED | TS102_CARD_INT_RQST_BATTERY_STATUS_CHANGED | TS102_CARD_INT_RQST_CARDDETECT_STATUS_CHANGED); } } /* * Invoke the interrupt handler for each slot */ for (i = 0; i < TS102_NUM_SLOTS; i++) { td = &sc->sc_slot[i]; intreg = &intregs[i]; if ((*intreg & (TS102_CARD_INT_STATUS_IRQ | TS102_CARD_INT_STATUS_WP_STATUS_CHANGED | TS102_CARD_INT_STATUS_BATTERY_STATUS_CHANGED | TS102_CARD_INT_STATUS_CARDDETECT_STATUS_CHANGED)) != 0) tslot_slot_intr(td, *intreg); } splx(s); return (rc); } void tslot_queue_event(struct tslot_softc *sc, int slot) { int s; s = splhigh(); sc->sc_events |= (1 << slot); splx(s); wakeup(&sc->sc_events); } void tslot_slot_intr(struct tslot_data *td, int intreg) { struct tslot_softc *sc = td->td_parent; int status, sockstat; status = TSLOT_READ(td, TS102_REG_CARD_A_STS); #ifdef TSLOT_DEBUG printf("%s: interrupt on socket %d ir %x sts %x\n", sc->sc_dev.dv_xname, td->td_slot, intreg, status); #endif sockstat = td->td_status; /* * The TS102 queues interrupt requests, and may trigger an interrupt * for a condition the driver does not want to receive anymore (for * example, after a card gets removed). * Thus, only proceed if the driver is currently allowing a particular * condition. */ if ((intreg & TS102_CARD_INT_STATUS_CARDDETECT_STATUS_CHANGED) != 0 && (intreg & TS102_CARD_INT_MASK_CARDDETECT_STATUS) != 0) { tslot_queue_event(sc, td->td_slot); #ifdef TSLOT_DEBUG printf("%s: slot %d status changed from %d to %d\n", sc->sc_dev.dv_xname, td->td_slot, sockstat, td->td_status); #endif /* * Ignore extra interrupt bits, they are part of the change. */ return; } if ((intreg & TS102_CARD_INT_STATUS_IRQ) != 0 && (intreg & TS102_CARD_INT_MASK_IRQ) != 0) { /* ignore interrupts if we have a pending state change */ if (sc->sc_events & (1 << td->td_slot)) return; if ((sockstat & TS_CARD) == 0) { printf("%s: spurious interrupt on slot %d isr %x\n", sc->sc_dev.dv_xname, td->td_slot, intreg); return; } if (td->td_softintr != NULL) { /* * Disable this sbus interrupt, until the * softintr handler had a chance to run. */ TSLOT_WRITE(td, TS102_REG_CARD_A_INT, TSLOT_READ(td, TS102_REG_CARD_A_INT) & ~TS102_CARD_INT_MASK_IRQ); softintr_schedule(td->td_softintr); } } } /* * Software interrupt called to invoke the real driver interrupt handler. */ void tslot_intr_dispatch(void *arg) { struct tslot_data *td = (struct tslot_data *)arg; int s; /* invoke driver handler */ td->td_intr(td->td_intrarg); /* enable SBUS interrupts for PCMCIA interrupts again */ s = splhigh(); TSLOT_WRITE(td, TS102_REG_CARD_A_INT, TSLOT_READ(td, TS102_REG_CARD_A_INT) | TS102_CARD_INT_MASK_IRQ); splx(s); } void tslot_intr_disestablish(pcmcia_chipset_handle_t pch, void *ih) { struct tslot_data *td = (struct tslot_data *)pch; if (td->td_softintr != NULL) { softintr_disestablish(td->td_softintr); td->td_softintr = NULL; } td->td_intr = NULL; td->td_intrarg = NULL; } const char * tslot_intr_string(pcmcia_chipset_handle_t pch, void *ih) { if (ih == NULL) return ("couldn't establish interrupt"); else return (""); /* nothing for now */ } void * tslot_intr_establish(pcmcia_chipset_handle_t pch, struct pcmcia_function *pf, int ipl, int (*handler)(void *), void *arg, char *xname) { struct tslot_data *td = (struct tslot_data *)pch; /* * Note that this code relies on softintr_establish() to be * used with real, hardware ipl values. All platforms with * SBus support support this. */ td->td_intr = handler; td->td_intrarg = arg; td->td_softintr = softintr_establish(ipl, tslot_intr_dispatch, td); return td->td_softintr != NULL ? td : NULL; }