/* $OpenBSD: mkbc.c,v 1.9 2009/10/26 18:00:06 miod Exp $ */ /* * Copyright (c) 2006, 2007, Joel Sing * 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. * * 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 MIND, * 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. */ /* * Derived from sys/dev/ic/pckbc.c under the following terms: * $NetBSD: pckbc.c,v 1.5 2000/06/09 04:58:35 soda Exp $ */ /* * Copyright (c) 1998 * Matthias Drochner. 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. * * 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 Moosehead PS/2 Controllers (mkbc) * * There are actually two separate controllers attached to the macebus. * However in the interest of reusing code, we want to act like a pckbc(4) * so that we can directly attach pckbd(4) and pms(4). As a result, we make * each controller look like a "slot" and combine them into a single device. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "mkbcreg.h" const char *mkbc_slot_names[] = { "kbd", "mouse" }; #define KBC_DEVCMD_ACK 0xfa #define KBC_DEVCMD_RESEND 0xfe #define KBD_DELAY DELAY(8) struct mkbc_softc { struct pckbc_softc sc_pckbc; bus_space_tag_t iot; bus_space_handle_t ioh; }; int mkbc_match(struct device *, void *, void *); void mkbc_attach(struct device *, struct device *, void *); struct cfattach mkbc_ca = { sizeof(struct mkbc_softc), mkbc_match, mkbc_attach }; struct cfdriver mkbc_cd = { NULL, "mkbc", DV_DULL }; /* Descriptor for one device command. */ struct pckbc_devcmd { TAILQ_ENTRY(pckbc_devcmd) next; int flags; #define KBC_CMDFLAG_SYNC 1 /* Give descriptor back to caller. */ #define KBC_CMDFLAG_SLOW 2 u_char cmd[4]; int cmdlen, cmdidx, retries; u_char response[4]; int status, responselen, responseidx; }; /* Data per slave device. */ struct pckbc_slotdata { int polling; /* Don't read data port in interrupt handler. */ TAILQ_HEAD(, pckbc_devcmd) cmdqueue; /* Active commands. */ TAILQ_HEAD(, pckbc_devcmd) freequeue; /* Free commands. */ #define NCMD 5 struct pckbc_devcmd cmds[NCMD]; bus_space_handle_t ioh; }; #define CMD_IN_QUEUE(q) (TAILQ_FIRST(&(q)->cmdqueue) != NULL) static int mkbc_console; static struct pckbc_slotdata mkbc_cons_slotdata; struct pckbc_internal mkbc_consdata; void mkbc_start(struct pckbc_internal *, pckbc_slot_t); int mkbc_attach_slot(struct mkbc_softc *, pckbc_slot_t); void mkbc_init_slotdata(struct pckbc_slotdata *); int mkbc_submatch(struct device *, void *, void *); int mkbcprint(void *, const char *); int mkbcintr(void *); int mkbcintr_internal(struct pckbc_internal *, struct pckbc_softc *); void mkbc_cleanqueue(struct pckbc_slotdata *); void mkbc_cleanup(void *); void mkbc_poll(void *); int mkbc_cmdresponse(struct pckbc_internal *, pckbc_slot_t, u_char); int mkbc_poll_read(bus_space_tag_t, bus_space_handle_t); int mkbc_poll_write(bus_space_tag_t, bus_space_handle_t, int); int mkbc_match(struct device *parent, void *cf, void *aux) { return 1; } void mkbc_init_slotdata(struct pckbc_slotdata *q) { int i; TAILQ_INIT(&q->cmdqueue); TAILQ_INIT(&q->freequeue); for (i = 0; i < NCMD; i++) { TAILQ_INSERT_TAIL(&q->freequeue, &(q->cmds[i]), next); } q->polling = 0; } int mkbcprint(void *aux, const char *pnp) { struct pckbc_attach_args *pa = aux; if (!pnp) printf(" (%s slot)", mkbc_slot_names[pa->pa_slot]); return (QUIET); } int mkbc_submatch(struct device *parent, void *match, void *aux) { struct cfdata *cf = match; struct pckbc_attach_args *pa = aux; if (cf->cf_loc[PCKBCCF_SLOT] != PCKBCCF_SLOT_DEFAULT && cf->cf_loc[PCKBCCF_SLOT] != pa->pa_slot) return (0); return ((*cf->cf_attach->ca_match)(parent, cf, aux)); } int mkbc_attach_slot(struct mkbc_softc *msc, pckbc_slot_t slot) { struct pckbc_softc *sc = &msc->sc_pckbc; struct pckbc_internal *t = sc->id; struct pckbc_attach_args pa; bus_space_handle_t ioh; int found; if (!t->t_slotdata[slot]) { t->t_slotdata[slot] = malloc(sizeof(struct pckbc_slotdata), M_DEVBUF, M_NOWAIT); if (t->t_slotdata[slot] == NULL) { printf("Failed to allocate slot data!\n"); return 0; } mkbc_init_slotdata(t->t_slotdata[slot]); /* Map subregion of bus space for this "slot". */ if (bus_space_subregion(msc->iot, msc->ioh, MKBC_PORTSIZE * slot, MKBC_PORTSIZE, &ioh)) { printf("Unable to map slot subregion!\n"); return 0; } t->t_slotdata[slot]->ioh = ioh; /* Initialise controller. */ bus_space_write_8(msc->iot, ioh, MKBC_CONTROL, MKBC_CONTROL_TX_CLOCK_DISABLE | MKBC_CONTROL_RESET); delay(100); /* 100us */ /* Enable controller. */ bus_space_write_8(t->t_iot, t->t_slotdata[slot]->ioh, MKBC_CONTROL, MKBC_CONTROL_RX_CLOCK_ENABLE | MKBC_CONTROL_TX_ENABLE); } pa.pa_tag = t; pa.pa_slot = slot; found = (config_found_sm((struct device *)msc, &pa, mkbcprint, mkbc_submatch) != NULL); return (found); } void mkbc_attach(struct device *parent, struct device *self, void *aux) { struct mkbc_softc *msc = (void*)self; struct macebus_attach_args *maa = aux; struct pckbc_softc *sc = &msc->sc_pckbc; struct pckbc_internal *t; if (mkbc_console == 0) { /* Setup bus space mapping. */ msc->iot = maa->maa_iot; if (bus_space_map(msc->iot, maa->maa_baseaddr, MKBC_PORTSIZE * 2, 0, &msc->ioh)) { printf(": unable to map bus space!\n"); return; } /* Setup pckbc_internal structure. */ t = malloc(sizeof(struct pckbc_internal), M_DEVBUF, M_WAITOK | M_ZERO); t->t_iot = msc->iot; t->t_ioh_d = NULL; t->t_ioh_c = NULL; t->t_addr = maa->maa_baseaddr; t->t_sc = (struct pckbc_softc *)msc; sc->id = t; timeout_set(&t->t_cleanup, mkbc_cleanup, t); timeout_set(&t->t_poll, mkbc_poll, t); } else { /* Things have already been setup in mkbc_cnattach. */ msc->iot = mkbc_consdata.t_iot; msc->ioh = mkbc_consdata.t_ioh_d; mkbc_consdata.t_sc = (struct pckbc_softc *)msc; sc->id = &mkbc_consdata; } /* Establish interrupt handler. */ if (macebus_intr_establish(maa->maa_intr, maa->maa_mace_intr, IST_EDGE, IPL_TTY, mkbcintr, msc, sc->sc_dv.dv_xname)) printf("\n"); else printf(": unable to establish interrupt\n"); /* * Attach "slots" - technically these are separate controllers * in the same bus space, however we want to act like pckbc(4) so * that we can attach pckbd(4) and pms(4). */ mkbc_attach_slot(msc, PCKBC_KBD_SLOT); mkbc_attach_slot(msc, PCKBC_AUX_SLOT); } int mkbcintr(void *vsc) { struct mkbc_softc *msc = (struct mkbc_softc *)vsc; struct pckbc_softc *sc = &msc->sc_pckbc; struct pckbc_internal *t = sc->id; return mkbcintr_internal(t, sc); } int mkbcintr_internal(struct pckbc_internal *t, struct pckbc_softc *sc) { pckbc_slot_t slot; struct pckbc_slotdata *q; int served = 0; u_int64_t stat; u_int64_t data; /* Reschedule timeout further into the idle times. */ if (timeout_pending(&t->t_poll)) timeout_add_sec(&t->t_poll, 1); /* * Need to check both "slots" since interrupt could be from * either controller. */ slot = PCKBC_KBD_SLOT; q = t->t_slotdata[slot]; for(;;) { if (!q) { printf("mkbcintr: no kbd slot data!\n"); break; } stat = bus_space_read_8(t->t_iot, q->ioh, MKBC_STATUS); if (!(stat & MKBC_STATUS_RX_FULL)) break; served = 1; if (q->polling) break; /* pckbc_poll_data() will get it */ KBD_DELAY; data = bus_space_read_8(t->t_iot, q->ioh, MKBC_RX_PORT) & 0xff; if (CMD_IN_QUEUE(q) && mkbc_cmdresponse(t, slot, data)) continue; if (sc->inputhandler[slot]) (*sc->inputhandler[slot])(sc->inputarg[slot], data); #ifdef MKBCDEBUG else printf("mkbcintr: slot %d lost %d\n", slot, data); #endif } /* Mouse controller/slot. */ slot = PCKBC_AUX_SLOT; q = t->t_slotdata[slot]; for(;;) { if (!q) { printf("mkbcintr: no mouse slot data!\n"); break; } stat = bus_space_read_8(t->t_iot, q->ioh, MKBC_STATUS); if (!(stat & MKBC_STATUS_RX_FULL)) break; served = 1; if (q->polling) break; /* pckbc_poll_data() will get it. */ KBD_DELAY; data = bus_space_read_8(t->t_iot, q->ioh, MKBC_RX_PORT) & 0xff; if (CMD_IN_QUEUE(q) && mkbc_cmdresponse(t, slot, data)) continue; if (sc->inputhandler[slot]) (*sc->inputhandler[slot])(sc->inputarg[slot], data); #ifdef MKBCDEBUG else printf("mkbcintr: slot %d lost %d\n", slot, data); #endif } return (served); } int mkbc_poll_write(bus_space_tag_t iot, bus_space_handle_t ioh, int val) { int timeout = 10000; u_int64_t stat; /* Attempt to write a value to the controller. */ while (timeout--) { stat = bus_space_read_8(iot, ioh, MKBC_STATUS); if (stat & MKBC_STATUS_TX_EMPTY) { bus_space_write_8(iot, ioh, MKBC_TX_PORT, val & 0xff); return 0; } delay(50); } return -1; } int mkbc_poll_read(bus_space_tag_t iot, bus_space_handle_t ioh) { int timeout = 10000; u_int64_t stat, val; /* Poll input from controller. */ while (timeout--) { stat = bus_space_read_8(iot, ioh, MKBC_STATUS); if (stat & MKBC_STATUS_RX_FULL) { val = bus_space_read_8(iot, ioh, MKBC_RX_PORT); return val & 0xff; } delay(50); } return -1; } /* * Pass command to device, poll for ACK and data. * to be called at spltty() */ static void mkbc_poll_cmd(struct pckbc_internal *t, pckbc_slot_t slot, struct pckbc_devcmd *cmd) { bus_space_tag_t iot = t->t_iot; bus_space_handle_t ioh = t->t_slotdata[slot]->ioh; int i, c = 0; while (cmd->cmdidx < cmd->cmdlen) { if (mkbc_poll_write(iot, ioh, cmd->cmd[cmd->cmdidx]) == -1) { printf("mkbc_poll_cmd: send error\n"); cmd->status = EIO; return; } for (i = 10; i; i--) { /* 1s ??? */ c = mkbc_poll_read(iot, ioh); if (c != -1) break; } if (c == KBC_DEVCMD_ACK) { cmd->cmdidx++; continue; } if (c == KBC_DEVCMD_RESEND) { #ifdef MKBCDEBUG printf("mkbc_cmd: RESEND\n"); #endif if (cmd->retries++ < 5) continue; else { #ifdef MKBCDEBUG printf("mkbc: cmd failed\n"); #endif cmd->status = EIO; return; } } if (c == -1) { #ifdef MKBCDEBUG printf("mkbc_cmd: timeout\n"); #endif cmd->status = EIO; return; } #ifdef MKBCDEBUG printf("mkbc_cmd: lost 0x%x\n", c); #endif } while (cmd->responseidx < cmd->responselen) { if (cmd->flags & KBC_CMDFLAG_SLOW) i = 100; /* 10s ??? */ else i = 10; /* 1s ??? */ while (i--) { c = mkbc_poll_read(iot, ioh); if (c != -1) break; } if (c == -1) { #ifdef MKBCDEBUG printf("mkbc_poll_cmd: no data\n"); #endif cmd->status = ETIMEDOUT; return; } else cmd->response[cmd->responseidx++] = c; } } /* * Clean up a command queue, throw away everything. */ void mkbc_cleanqueue(struct pckbc_slotdata *q) { struct pckbc_devcmd *cmd; #ifdef MKBCDEBUG int i; #endif while ((cmd = TAILQ_FIRST(&q->cmdqueue))) { TAILQ_REMOVE(&q->cmdqueue, cmd, next); #ifdef MKBCDEBUG printf("mkbc_cleanqueue: removing"); for (i = 0; i < cmd->cmdlen; i++) printf(" %02x", cmd->cmd[i]); printf("\n"); #endif TAILQ_INSERT_TAIL(&q->freequeue, cmd, next); } } /* * Timeout error handler: clean queues and data port. * XXX could be less invasive. */ void mkbc_cleanup(void *self) { struct pckbc_internal *t = self; int s; printf("mkbc: command timeout\n"); s = spltty(); if (t->t_slotdata[PCKBC_KBD_SLOT]) mkbc_cleanqueue(t->t_slotdata[PCKBC_KBD_SLOT]); if (t->t_slotdata[PCKBC_AUX_SLOT]) mkbc_cleanqueue(t->t_slotdata[PCKBC_AUX_SLOT]); while (mkbc_poll_read(t->t_iot, t->t_slotdata[PCKBC_KBD_SLOT]->ioh) != -1) ; while (mkbc_poll_read(t->t_iot, t->t_slotdata[PCKBC_AUX_SLOT]->ioh) != -1) ; /* Reset KBC? */ splx(s); } /* * Pass command to device during normal operation. * to be called at spltty() */ void mkbc_start(struct pckbc_internal *t, pckbc_slot_t slot) { struct pckbc_slotdata *q = t->t_slotdata[slot]; struct pckbc_devcmd *cmd = TAILQ_FIRST(&q->cmdqueue); if (q->polling) { do { mkbc_poll_cmd(t, slot, cmd); if (cmd->status) printf("mkbc_start: command error\n"); TAILQ_REMOVE(&q->cmdqueue, cmd, next); if (cmd->flags & KBC_CMDFLAG_SYNC) wakeup(cmd); else { timeout_del(&t->t_cleanup); TAILQ_INSERT_TAIL(&q->freequeue, cmd, next); } cmd = TAILQ_FIRST(&q->cmdqueue); } while (cmd); return; } if (mkbc_poll_write(t->t_iot, t->t_slotdata[slot]->ioh, cmd->cmd[cmd->cmdidx])) { printf("mkbc_start: send error\n"); /* XXX what now? */ return; } } /* * Handle command responses coming in asynchronously, * return nonzero if valid response. * to be called at spltty() */ int mkbc_cmdresponse(struct pckbc_internal *t, pckbc_slot_t slot, u_char data) { struct pckbc_slotdata *q = t->t_slotdata[slot]; struct pckbc_devcmd *cmd = TAILQ_FIRST(&q->cmdqueue); #ifdef DIAGNOSTIC if (!cmd) panic("mkbc_cmdresponse: no active command"); #endif if (cmd->cmdidx < cmd->cmdlen) { if (data != KBC_DEVCMD_ACK && data != KBC_DEVCMD_RESEND) return (0); if (data == KBC_DEVCMD_RESEND) { if (cmd->retries++ < 5) { /* try again last command */ goto restart; } else { #ifdef MKBCDEBUG printf("mkbc: cmd failed\n"); #endif cmd->status = EIO; /* dequeue */ } } else { if (++cmd->cmdidx < cmd->cmdlen) goto restart; if (cmd->responselen) return (1); /* else dequeue */ } } else if (cmd->responseidx < cmd->responselen) { cmd->response[cmd->responseidx++] = data; if (cmd->responseidx < cmd->responselen) return (1); /* else dequeue */ } else return (0); /* dequeue: */ TAILQ_REMOVE(&q->cmdqueue, cmd, next); if (cmd->flags & KBC_CMDFLAG_SYNC) wakeup(cmd); else { timeout_del(&t->t_cleanup); TAILQ_INSERT_TAIL(&q->freequeue, cmd, next); } if (!CMD_IN_QUEUE(q)) return (1); restart: mkbc_start(t, slot); return (1); } /* * Interfaces to act like pckbc(4). */ int pckbc_xt_translation(pckbc_tag_t self, pckbc_slot_t slot, int on) { /* Translation isn't supported... */ return 0; } /* For use in autoconfiguration. */ int pckbc_poll_cmd(pckbc_tag_t self, pckbc_slot_t slot, u_char *cmd, int len, int responselen, u_char *respbuf, int slow) { struct pckbc_devcmd nc; int s; if ((len > 4) || (responselen > 4)) return (EINVAL); bzero(&nc, sizeof(nc)); bcopy(cmd, nc.cmd, len); nc.cmdlen = len; nc.responselen = responselen; nc.flags = (slow ? KBC_CMDFLAG_SLOW : 0); s = spltty(); mkbc_poll_cmd(self, slot, &nc); splx(s); if (nc.status == 0 && respbuf) bcopy(nc.response, respbuf, responselen); return (nc.status); } void pckbc_flush(pckbc_tag_t self, pckbc_slot_t slot) { /* Read any data and discard. */ struct pckbc_internal *t = self; (void) mkbc_poll_read(t->t_iot, t->t_slotdata[slot]->ioh); } /* * Put command into the device's command queue, return zero or errno. */ int pckbc_enqueue_cmd(pckbc_tag_t self, pckbc_slot_t slot, u_char *cmd, int len, int responselen, int sync, u_char *respbuf) { struct pckbc_internal *t = self; struct pckbc_slotdata *q = t->t_slotdata[slot]; struct pckbc_devcmd *nc; int s, isactive, res = 0; if ((len > 4) || (responselen > 4)) return (EINVAL); s = spltty(); nc = TAILQ_FIRST(&q->freequeue); if (nc) { TAILQ_REMOVE(&q->freequeue, nc, next); } splx(s); if (!nc) return (ENOMEM); bzero(nc, sizeof(*nc)); bcopy(cmd, nc->cmd, len); nc->cmdlen = len; nc->responselen = responselen; nc->flags = (sync ? KBC_CMDFLAG_SYNC : 0); s = spltty(); if (q->polling && sync) { /* * XXX We should poll until the queue is empty. * But we don't come here normally, so make * it simple and throw away everything. */ mkbc_cleanqueue(q); } isactive = CMD_IN_QUEUE(q); TAILQ_INSERT_TAIL(&q->cmdqueue, nc, next); if (!isactive) mkbc_start(t, slot); if (q->polling) res = (sync ? nc->status : 0); else if (sync) { if ((res = tsleep(nc, 0, "kbccmd", 1*hz))) { TAILQ_REMOVE(&q->cmdqueue, nc, next); mkbc_cleanup(t); } else res = nc->status; } else timeout_add_sec(&t->t_cleanup, 1); if (sync) { if (respbuf) bcopy(nc->response, respbuf, responselen); TAILQ_INSERT_TAIL(&q->freequeue, nc, next); } splx(s); return (res); } int pckbc_poll_data(pckbc_tag_t self, pckbc_slot_t slot) { struct pckbc_internal *t = self; struct pckbc_slotdata *q = t->t_slotdata[slot]; int c; c = mkbc_poll_read(t->t_iot, q->ioh); if (c != -1 && q && CMD_IN_QUEUE(q)) { /* We jumped into a running command - try to deliver the response. */ if (mkbc_cmdresponse(t, slot, c)) return (-1); } return (c); } void pckbc_set_inputhandler(pckbc_tag_t self, pckbc_slot_t slot, pckbc_inputfcn func, void *arg, char *name) { struct pckbc_internal *t = (struct pckbc_internal *)self; struct pckbc_softc *sc = t->t_sc; if (slot >= PCKBC_NSLOTS) panic("mkbc_set_inputhandler: bad slot %d", slot); sc->inputhandler[slot] = func; sc->inputarg[slot] = arg; sc->subname[slot] = name; if (mkbc_console && slot == PCKBC_KBD_SLOT) timeout_add_sec(&t->t_poll, 1); } void pckbc_slot_enable(pckbc_tag_t self, pckbc_slot_t slot, int on) { struct pckbc_internal *t = (struct pckbc_internal *)self; /* * Should we also enable/disable the controller?? * If we did then none of the poll_ functions would work... */ if (on) { /* Enable controller interrupts. */ bus_space_write_8(t->t_iot, t->t_slotdata[slot]->ioh, MKBC_CONTROL, MKBC_CONTROL_RX_CLOCK_ENABLE | MKBC_CONTROL_TX_ENABLE | MKBC_CONTROL_RX_INT_ENABLE); } else { /* Disable controller interrupts. */ bus_space_write_8(t->t_iot, t->t_slotdata[slot]->ioh, MKBC_CONTROL, MKBC_CONTROL_RX_CLOCK_ENABLE | MKBC_CONTROL_TX_ENABLE); } if (slot == PCKBC_KBD_SLOT) { if (on) timeout_add_sec(&t->t_poll, 1); else timeout_del(&t->t_poll); } } void pckbc_set_poll(pckbc_tag_t self, pckbc_slot_t slot, int on) { struct pckbc_internal *t = (struct pckbc_internal *)self; t->t_slotdata[slot]->polling = on; if (!on) { int s; /* * If disabling polling on a device that's been configured, * make sure there are no bytes left in the FIFO, holding up * the interrupt line. Otherwise we won't get any further * interrupts. */ if (t->t_sc) { s = spltty(); mkbcintr(t->t_sc); splx(s); } } } int mkbc_cnattach(bus_space_tag_t iot, bus_addr_t addr, pckbc_slot_t slot) { bus_space_handle_t ioh, slot_ioh; int res = 0; /* Ensure that we're on an O2. */ if (sys_config.system_type != SGI_O2) return (ENXIO); if (bus_space_map(iot, addr, MKBC_PORTSIZE * 2, 0, &ioh)) return (ENXIO); mkbc_consdata.t_addr = addr; mkbc_consdata.t_iot = iot; mkbc_consdata.t_ioh_d = ioh; /* Map subregion of bus space for this "slot". */ if (bus_space_subregion(iot, ioh, MKBC_PORTSIZE * slot, MKBC_PORTSIZE, &slot_ioh)) { bus_space_unmap(iot, ioh, MKBC_PORTSIZE * 2); return (ENXIO); } mkbc_cons_slotdata.ioh = slot_ioh; mkbc_init_slotdata(&mkbc_cons_slotdata); mkbc_consdata.t_slotdata[slot] = &mkbc_cons_slotdata; /* Initialise controller. */ bus_space_write_8(iot, slot_ioh, MKBC_CONTROL, MKBC_CONTROL_TX_CLOCK_DISABLE | MKBC_CONTROL_RESET); delay(100); /* 100us */ /* Enable controller. */ bus_space_write_8(iot, slot_ioh, MKBC_CONTROL, MKBC_CONTROL_RX_CLOCK_ENABLE | MKBC_CONTROL_TX_ENABLE | MKBC_CONTROL_RX_INT_ENABLE); timeout_set(&mkbc_consdata.t_cleanup, mkbc_cleanup, &mkbc_consdata); timeout_set(&mkbc_consdata.t_poll, mkbc_poll, &mkbc_consdata); /* Flush input buffer. */ (void) mkbc_poll_read(iot, slot_ioh); res = pckbd_cnattach(&mkbc_consdata, slot); if (res) { bus_space_unmap(iot, ioh, MKBC_PORTSIZE * 2); } else { mkbc_console = 1; } return (res); } void mkbc_poll(void *self) { struct pckbc_internal *t = self; int s; s = spltty(); (void)mkbcintr_internal(t, t->t_sc); timeout_add_sec(&t->t_poll, 1); splx(s); }