/* * Device driver for Specialix range (SI/XIO) of serial line multiplexors. * * Copyright (C) 1990, 1992, 1998 Specialix International, * Copyright (C) 1993, Andy Rutter * Copyright (C) 1995, Peter Wemm * * Originally derived from: SunOS 4.x version * Ported from BSDI version to FreeBSD by Peter Wemm. * * 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 * notices, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notices, 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 by Andy Rutter of * Advanced Methods and Tools Ltd. based on original information * from Specialix International. * 4. Neither the name of Advanced Methods and Tools, nor Specialix * International may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY ``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 AUTHORS BE LIABLE. * * $Id: si.c,v 1.84 1999/05/08 07:02:31 phk Exp $ */ #ifndef lint static const char si_copyright1[] = "@(#) Copyright (C) Specialix International, 1990,1992,1998", si_copyright2[] = "@(#) Copyright (C) Andy Rutter 1993", si_copyright3[] = "@(#) Copyright (C) Peter Wemm 1995"; #endif /* not lint */ #include "opt_compat.h" #include "opt_debug_si.h" #include "opt_devfs.h" #include #include #if defined(COMPAT_43) || defined(COMPAT_SUNOS) #include #endif #include #include #include #include #include #include #include #include #ifdef DEVFS #include #endif /*DEVFS*/ #include #include #include #include #include #include #include #include #include #include "pci.h" #if NPCI > 0 #include #endif #include "eisa.h" #if NEISA > 0 #warning "Fix si eisa code! - newbus casualty" #undef NEISA #define NEISA 0 #endif #if NEISA > 0 #include #include #endif #include "si.h" /* * This device driver is designed to interface the Specialix International * SI, XIO and SX range of serial multiplexor cards to FreeBSD on an ISA, * EISA or PCI bus machine. * * The controller is interfaced to the host via dual port RAM * and an interrupt. * * The code for the Host 1 (very old ISA cards) has not been tested. */ #define POLL /* turn on poller to scan for lost interrupts */ #define REALPOLL /* on each poll, scan for work regardless */ #define POLLHZ (hz/10) /* 10 times per second */ #define SI_I_HIGH_WATER (TTYHOG - 2 * SI_BUFFERSIZE) #define INT_COUNT 25000 /* max of 125 ints per second */ #define JET_INT_COUNT 100 /* max of 100 ints per second */ #define RXINT_COUNT 1 /* one rxint per 10 milliseconds */ enum si_mctl { GET, SET, BIS, BIC }; static void si_command __P((struct si_port *, int, int)); static int si_modem __P((struct si_port *, enum si_mctl, int)); static void si_write_enable __P((struct si_port *, int)); static int si_Sioctl __P((dev_t, u_long, caddr_t, int, struct proc *)); static void si_start __P((struct tty *)); static timeout_t si_lstart; static void si_disc_optim __P((struct tty *tp, struct termios *t, struct si_port *pp)); static void sihardclose __P((struct si_port *pp)); static void sidtrwakeup __P((void *chan)); static int siparam __P((struct tty *, struct termios *)); static int siprobe __P((struct isa_device *id)); static int siattach __P((struct isa_device *id)); static void si_modem_state __P((struct si_port *pp, struct tty *tp, int hi_ip)); static void si_intr __P((int unit)); static char * si_modulename __P((int host_type, int uart_type)); struct isa_driver sidriver = { siprobe, siattach, "si" }; static u_long sipcieisacount = 0; #if NPCI > 0 static const char *sipciprobe __P((pcici_t, pcidi_t)); static void sipciattach __P((pcici_t, int)); static struct pci_device sipcidev = { "si", sipciprobe, sipciattach, &sipcieisacount, NULL, }; COMPAT_PCI_DRIVER (sipci, sipcidev); #endif #if NEISA > 0 static int si_eisa_probe __P((void)); static int si_eisa_attach __P((struct eisa_device *ed)); static struct eisa_driver si_eisa_driver = { "si", si_eisa_probe, si_eisa_attach, NULL, &sipcieisacount, }; DATA_SET(eisadriver_set, si_eisa_driver); #endif static d_open_t siopen; static d_close_t siclose; static d_read_t siread; static d_write_t siwrite; static d_ioctl_t siioctl; static d_stop_t sistop; static d_devtotty_t sidevtotty; #define CDEV_MAJOR 68 static struct cdevsw si_cdevsw = { siopen, siclose, siread, siwrite, siioctl, sistop, noreset, sidevtotty, ttpoll, nommap, NULL, "si", NULL, -1, nodump, nopsize, D_TTY, }; #ifdef SI_DEBUG /* use: ``options "SI_DEBUG"'' in your config file */ static void si_dprintf __P((struct si_port *pp, int flags, const char *fmt, ...)); static char *si_mctl2str __P((enum si_mctl cmd)); #define DPRINT(x) si_dprintf x #else #define DPRINT(x) /* void */ #endif static int si_Nports; static int si_Nmodules; static int si_debug = 0; /* data, not bss, so it's patchable */ SYSCTL_INT(_machdep, OID_AUTO, si_debug, CTLFLAG_RW, &si_debug, 0, ""); static struct tty *si_tty; /* where the firmware lives; defined in si2_z280.c and si3_t225.c */ /* old: si2_z280.c */ extern unsigned char si2_z280_download[]; extern unsigned short si2_z280_downloadaddr; extern int si2_z280_dsize; /* new: si3_t225.c */ extern unsigned char si3_t225_download[]; extern unsigned short si3_t225_downloadaddr; extern int si3_t225_dsize; extern unsigned char si3_t225_bootstrap[]; extern unsigned short si3_t225_bootloadaddr; extern int si3_t225_bsize; struct si_softc { int sc_type; /* adapter type */ char *sc_typename; /* adapter type string */ struct si_port *sc_ports; /* port structures for this card */ caddr_t sc_paddr; /* physical addr of iomem */ caddr_t sc_maddr; /* kvaddr of iomem */ int sc_nport; /* # ports on this card */ int sc_irq; /* copy of attach irq */ #if NEISA > 0 int sc_eisa_iobase; /* EISA io port address */ int sc_eisa_irq; /* EISA irq number */ #endif #ifdef DEVFS struct { void *ttya; void *cuaa; void *ttyl; void *cual; void *ttyi; void *cuai; } devfs_token[32]; /* what is the max per card? */ void *control_token; #endif }; static struct si_softc si_softc[NSI]; /* up to 4 elements */ #ifndef B2000 /* not standard, but the hardware knows it. */ # define B2000 2000 #endif static struct speedtab bdrates[] = { B75, CLK75, /* 0x0 */ B110, CLK110, /* 0x1 */ B150, CLK150, /* 0x3 */ B300, CLK300, /* 0x4 */ B600, CLK600, /* 0x5 */ B1200, CLK1200, /* 0x6 */ B2000, CLK2000, /* 0x7 */ B2400, CLK2400, /* 0x8 */ B4800, CLK4800, /* 0x9 */ B9600, CLK9600, /* 0xb */ B19200, CLK19200, /* 0xc */ B38400, CLK38400, /* 0x2 (out of order!) */ B57600, CLK57600, /* 0xd */ B115200, CLK110, /* 0x1 (dupe!, 110 baud on "si") */ -1, -1 }; /* populated with approx character/sec rates - translated at card * initialisation time to chars per tick of the clock */ static int done_chartimes = 0; static struct speedtab chartimes[] = { B75, 8, B110, 11, B150, 15, B300, 30, B600, 60, B1200, 120, B2000, 200, B2400, 240, B4800, 480, B9600, 960, B19200, 1920, B38400, 3840, B57600, 5760, B115200, 11520, -1, -1 }; static volatile int in_intr = 0; /* Inside interrupt handler? */ #ifdef POLL static int si_pollrate; /* in addition to irq */ static int si_realpoll; /* poll HW on timer */ SYSCTL_INT(_machdep, OID_AUTO, si_pollrate, CTLFLAG_RW, &si_pollrate, 0, ""); SYSCTL_INT(_machdep, OID_AUTO, si_realpoll, CTLFLAG_RW, &si_realpoll, 0, ""); static int init_finished = 0; static void si_poll __P((void *)); #endif /* * Array of adapter types and the corresponding RAM size. The order of * entries here MUST match the ordinal of the adapter type. */ static char *si_type[] = { "EMPTY", "SIHOST", "SIMCA", /* FreeBSD does not support Microchannel */ "SIHOST2", "SIEISA", "SIPCI", "SXPCI", "SXISA", }; #if NPCI > 0 static const char * sipciprobe(configid, deviceid) pcici_t configid; pcidi_t deviceid; { switch (deviceid) { case 0x400011cb: return("Specialix SI/XIO PCI host card"); break; case 0x200011cb: if (pci_conf_read(configid, SIJETSSIDREG) == 0x020011cb) return("Specialix SX PCI host card"); else return NULL; break; default: return NULL; } /*NOTREACHED*/ } void sipciattach(configid, unit) pcici_t configid; int unit; { struct isa_device id; vm_offset_t vaddr,paddr; u_long mapval = 0; /* shut up gcc, should not be needed */ switch ( pci_conf_read(configid, 0) >> 16 ) { case 0x4000: si_softc[unit].sc_type = SIPCI; mapval = SIPCIBADR; break; case 0x2000: si_softc[unit].sc_type = SIJETPCI; mapval = SIJETBADR; break; } if (!pci_map_mem(configid, mapval, &vaddr, &paddr)) { printf("si%d: couldn't map memory\n", unit); } /* * We're cheating here a little bit. The argument to an ISA * interrupt routine is the unit number. The argument to a * PCI interrupt handler is a void *, but we're simply going * to be lazy and hand it the unit number. */ if (!pci_map_int(configid, (pci_inthand_t *) si_intr, (void *)unit, &tty_imask)) { printf("si%d: couldn't map interrupt\n", unit); } si_softc[unit].sc_typename = si_type[si_softc[unit].sc_type]; /* * More cheating: We're going to dummy up a struct isa_device * and call the other attach routine. We don't really have to * fill in very much of the structure, since we filled in a * little of the soft state already. */ id.id_unit = unit; id.id_maddr = (caddr_t) vaddr; siattach(&id); } #endif #if NEISA > 0 static const char *si_eisa_match __P((eisa_id_t id)); static const char * si_eisa_match(id) eisa_id_t id; { if (id == SIEISADEVID) return ("Specialix SI/XIO EISA host card"); return (NULL); } static int si_eisa_probe(void) { struct eisa_device *ed = NULL; int count, irq; for (count=0; (ed = eisa_match_dev(ed, si_eisa_match)) != NULL; count++) { u_long port,maddr; port = (ed->ioconf.slot * EISA_SLOT_SIZE) + SIEISABASE; eisa_add_iospace(ed, port, SIEISAIOSIZE, RESVADDR_NONE); maddr = (inb(port+1) << 24) | (inb(port) << 16); irq = ((inb(port+2) >> 4) & 0xf); eisa_add_mspace(ed, maddr, SIEISA_MEMSIZE, RESVADDR_NONE); eisa_add_intr(ed, irq); eisa_registerdev(ed, &si_eisa_driver); count++; } return count; } static int si_eisa_attach(ed) struct eisa_device *ed; { struct isa_device id; resvaddr_t *maddr,*iospace; u_int irq; struct si_softc *sc; sc = &si_softc[ed->unit]; sc->sc_type = SIEISA; sc->sc_typename = si_type[sc->sc_type]; if ((iospace = ed->ioconf.ioaddrs.lh_first) == NULL) { printf("si%lu: no iospace??\n", ed->unit); return -1; } sc->sc_eisa_iobase = iospace->addr; irq = ((inb(iospace->addr + 2) >> 4) & 0xf); sc->sc_eisa_irq = irq; if ((maddr = ed->ioconf.maddrs.lh_first) == NULL) { printf("si%lu: where am I??\n", ed->unit); return -1; } eisa_reg_start(ed); if (eisa_reg_iospace(ed, iospace)) { printf("si%lu: failed to register iospace %p\n", ed->unit, (void *)iospace); return -1; } if (eisa_reg_mspace(ed, maddr)) { printf("si%lu: failed to register memspace %p\n", ed->unit, (void *)maddr); return -1; } /* * We're cheating here a little bit. The argument to an ISA * interrupt routine is the unit number. The argument to a * EISA interrupt handler is a void *, but we're simply going * to be lazy and hand it the unit number. */ if (eisa_reg_intr(ed, irq, (void (*)(void *)) si_intr, (void *)(intptr_t)(ed->unit), &tty_imask, 1)) { printf("si%lu: failed to register interrupt %d\n", ed->unit, irq); return -1; } eisa_reg_end(ed); if (eisa_enable_intr(ed, irq)) { return -1; } /* * More cheating: We're going to dummy up a struct isa_device * and call the other attach routine. We don't really have to * fill in very much of the structure, since we filled in a * little of the soft state already. */ id.id_unit = ed->unit; id.id_maddr = (caddr_t) pmap_mapdev(maddr->addr, SIEISA_MEMSIZE); return (siattach(&id)); } #endif /* Look for a valid board at the given mem addr */ static int siprobe(id) struct isa_device *id; { struct si_softc *sc; int type; u_int i, ramsize; volatile BYTE was, *ux; volatile unsigned char *maddr; unsigned char *paddr; si_pollrate = POLLHZ; /* default 10 per second */ #ifdef REALPOLL si_realpoll = 1; /* scan always */ #endif maddr = id->id_maddr; /* virtual address... */ paddr = (caddr_t)vtophys(id->id_maddr); /* physical address... */ DPRINT((0, DBG_AUTOBOOT, "si%d: probe at virtual=0x%x physical=0x%x\n", id->id_unit, id->id_maddr, paddr)); /* * this is a lie, but it's easier than trying to handle caching * and ram conflicts in the >1M and <16M region. */ if ((caddr_t)paddr < (caddr_t)IOM_BEGIN || (caddr_t)paddr >= (caddr_t)IOM_END) { printf("si%d: iomem (%p) out of range\n", id->id_unit, (void *)paddr); return(0); } if (id->id_unit >= NSI) { /* THIS IS IMPOSSIBLE */ return(0); } if (((u_int)paddr & 0x7fff) != 0) { DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: iomem (%x) not on 32k boundary\n", id->id_unit, paddr)); return(0); } if (si_softc[id->id_unit].sc_typename) { /* EISA or PCI has taken this unit, choose another */ for (i=0; i < NSI; i++) { if (si_softc[i].sc_typename == NULL) { id->id_unit = i; break; } } if (i >= NSI) { DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: cannot realloc unit\n", id->id_unit)); return (0); } } for (i=0; i < NSI; i++) { sc = &si_softc[i]; if ((caddr_t)sc->sc_paddr == (caddr_t)paddr) { DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: iomem (%x) already configured to si%d\n", id->id_unit, sc->sc_paddr, i)); return(0); } } /* Is there anything out there? (0x17 is just an arbitrary number) */ *maddr = 0x17; if (*maddr != 0x17) { DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: 0x17 check fail at phys 0x%x\n", id->id_unit, paddr)); fail: return(0); } /* * Let's look first for a JET ISA card, since that's pretty easy * * All jet hosts are supposed to have this string in the IDROM, * but it's not worth checking on self-IDing busses like PCI. */ { unsigned char *jet_chk_str = "JET HOST BY KEV#"; for (i = 0; i < strlen(jet_chk_str); i++) if (jet_chk_str[i] != *(maddr + SIJETIDSTR + 2 * i)) goto try_mk2; } DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: JET first check - 0x%x\n", id->id_unit, (*(maddr+SIJETIDBASE)))); if (*(maddr+SIJETIDBASE) != (SISPLXID&0xff)) goto try_mk2; DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: JET second check - 0x%x\n", id->id_unit, (*(maddr+SIJETIDBASE+2)))); if (*(maddr+SIJETIDBASE+2) != ((SISPLXID&0xff00)>>8)) goto try_mk2; /* It must be a Jet ISA or RIO card */ DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: JET id check - 0x%x\n", id->id_unit, (*(maddr+SIUNIQID)))); if ((*(maddr+SIUNIQID) & 0xf0) !=0x20) goto try_mk2; /* It must be a Jet ISA SI/XIO card */ *(maddr + SIJETCONFIG) = 0; type = SIJETISA; ramsize = SIJET_RAMSIZE; goto got_card; /* * OK, now to see if whatever responded is really an SI card. * Try for a MK II next (SIHOST2) */ try_mk2: for (i = SIPLSIG; i < SIPLSIG + 8; i++) if ((*(maddr+i) & 7) != (~(BYTE)i & 7)) goto try_mk1; /* It must be an SIHOST2 */ *(maddr + SIPLRESET) = 0; *(maddr + SIPLIRQCLR) = 0; *(maddr + SIPLIRQSET) = 0x10; type = SIHOST2; ramsize = SIHOST2_RAMSIZE; goto got_card; /* * Its not a MK II, so try for a MK I (SIHOST) */ try_mk1: *(maddr+SIRESET) = 0x0; /* reset the card */ *(maddr+SIINTCL) = 0x0; /* clear int */ *(maddr+SIRAM) = 0x17; if (*(maddr+SIRAM) != (BYTE)0x17) goto fail; *(maddr+0x7ff8) = 0x17; if (*(maddr+0x7ff8) != (BYTE)0x17) { DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: 0x17 check fail at phys 0x%x = 0x%x\n", id->id_unit, paddr+0x77f8, *(maddr+0x77f8))); goto fail; } /* It must be an SIHOST (maybe?) - there must be a better way XXX */ type = SIHOST; ramsize = SIHOST_RAMSIZE; got_card: DPRINT((0, DBG_AUTOBOOT, "si%d: found type %d card, try memory test\n", id->id_unit, type)); /* Try the acid test */ ux = maddr + SIRAM; for (i = 0; i < ramsize; i++, ux++) *ux = (BYTE)(i&0xff); ux = maddr + SIRAM; for (i = 0; i < ramsize; i++, ux++) { if ((was = *ux) != (BYTE)(i&0xff)) { DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: match fail at phys 0x%x, was %x should be %x\n", id->id_unit, paddr + i, was, i&0xff)); goto fail; } } /* clear out the RAM */ ux = maddr + SIRAM; for (i = 0; i < ramsize; i++) *ux++ = 0; ux = maddr + SIRAM; for (i = 0; i < ramsize; i++) { if ((was = *ux++) != 0) { DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: clear fail at phys 0x%x, was %x\n", id->id_unit, paddr + i, was)); goto fail; } } /* * Success, we've found a valid board, now fill in * the adapter structure. */ switch (type) { case SIHOST2: if ((id->id_irq & (IRQ11|IRQ12|IRQ15)) == 0) { bad_irq: DPRINT((0, DBG_AUTOBOOT|DBG_FAIL, "si%d: bad IRQ value - %d\n", id->id_unit, id->id_irq)); return(0); } id->id_msize = SIHOST2_MEMSIZE; break; case SIHOST: if ((id->id_irq & (IRQ11|IRQ12|IRQ15)) == 0) { goto bad_irq; } id->id_msize = SIHOST_MEMSIZE; break; case SIJETISA: if ((id->id_irq & (IRQ9|IRQ10|IRQ11|IRQ12|IRQ15)) == 0) { goto bad_irq; } id->id_msize = SIJETISA_MEMSIZE; break; case SIMCA: /* MCA */ default: printf("si%d: %s not supported\n", id->id_unit, si_type[type]); return(0); } id->id_intr = (inthand2_t *)si_intr; /* set here instead of config */ si_softc[id->id_unit].sc_type = type; si_softc[id->id_unit].sc_typename = si_type[type]; return(-1); /* -1 == found */ } /* * We have to make an 8 bit version of bcopy, since some cards can't * deal with 32 bit I/O */ #if 1 static void si_bcopy(const void *src, void *dst, size_t len) { while (len--) *(((u_char *)dst)++) = *(((u_char *)src)++); } #else #define si_bcopy bcopy #endif /* * Attach the device. Initialize the card. * * This routine also gets called by the EISA and PCI attach routines. * It presumes that the softstate for the unit has had had its type field * and the EISA specific stuff filled in, as well as the kernel virtual * base address and the unit number of the isa_device struct. */ static int siattach(id) struct isa_device *id; { int unit = id->id_unit; struct si_softc *sc = &si_softc[unit]; struct si_port *pp; volatile struct si_channel *ccbp; volatile struct si_reg *regp; volatile caddr_t maddr; struct si_module *modp; struct tty *tp; struct speedtab *spt; int nmodule, nport, x, y; int uart_type; DPRINT((0, DBG_AUTOBOOT, "si%d: siattach\n", id->id_unit)); sc->sc_paddr = (caddr_t)vtophys(id->id_maddr); sc->sc_maddr = id->id_maddr; sc->sc_irq = id->id_irq; DPRINT((0, DBG_AUTOBOOT, "si%d: type: %s paddr: %x maddr: %x\n", unit, sc->sc_typename, sc->sc_paddr, sc->sc_maddr)); sc->sc_ports = NULL; /* mark as uninitialised */ maddr = sc->sc_maddr; /* Stop the CPU first so it won't stomp around while we load */ switch (sc->sc_type) { #if NEISA > 0 case SIEISA: outb(sc->sc_eisa_iobase + 2, sc->sc_eisa_irq << 4); break; #endif #if NPCI > 0 case SIPCI: *(maddr+SIPCIRESET) = 0; break; case SIJETPCI: /* fall through to JET ISA */ #endif case SIJETISA: *(maddr+SIJETCONFIG) = 0; break; case SIHOST2: *(maddr+SIPLRESET) = 0; break; case SIHOST: *(maddr+SIRESET) = 0; break; default: /* this should never happen */ printf("si%d: unsupported configuration\n", unit); return 0; break; } /* OK, now lets download the download code */ if (SI_ISJET(sc->sc_type)) { DPRINT((0, DBG_DOWNLOAD, "si%d: jet_download: nbytes %d\n", id->id_unit, si3_t225_dsize)); si_bcopy(si3_t225_download, maddr + si3_t225_downloadaddr, si3_t225_dsize); DPRINT((0, DBG_DOWNLOAD, "si%d: jet_bootstrap: nbytes %d -> %x\n", id->id_unit, si3_t225_bsize, si3_t225_bootloadaddr)); si_bcopy(si3_t225_bootstrap, maddr + si3_t225_bootloadaddr, si3_t225_bsize); } else { DPRINT((0, DBG_DOWNLOAD, "si%d: si_download: nbytes %d\n", id->id_unit, si2_z280_dsize)); si_bcopy(si2_z280_download, maddr + si2_z280_downloadaddr, si2_z280_dsize); } /* Now start the CPU */ switch (sc->sc_type) { #if NEISA > 0 case SIEISA: /* modify the download code to tell it that it's on an EISA */ *(maddr + 0x42) = 1; outb(sc->sc_eisa_iobase + 2, (sc->sc_eisa_irq << 4) | 4); (void)inb(sc->sc_eisa_iobase + 3); /* reset interrupt */ break; #endif case SIPCI: /* modify the download code to tell it that it's on a PCI */ *(maddr+0x42) = 1; *(maddr+SIPCIRESET) = 1; *(maddr+SIPCIINTCL) = 0; break; case SIJETPCI: *(maddr+SIJETRESET) = 0; *(maddr+SIJETCONFIG) = SIJETBUSEN|SIJETIRQEN; break; case SIJETISA: *(maddr+SIJETRESET) = 0; switch (sc->sc_irq) { case IRQ9: *(maddr+SIJETCONFIG) = SIJETBUSEN|SIJETIRQEN|0x90; break; case IRQ10: *(maddr+SIJETCONFIG) = SIJETBUSEN|SIJETIRQEN|0xa0; break; case IRQ11: *(maddr+SIJETCONFIG) = SIJETBUSEN|SIJETIRQEN|0xb0; break; case IRQ12: *(maddr+SIJETCONFIG) = SIJETBUSEN|SIJETIRQEN|0xc0; break; case IRQ15: *(maddr+SIJETCONFIG) = SIJETBUSEN|SIJETIRQEN|0xf0; break; } break; case SIHOST: *(maddr+SIRESET_CL) = 0; *(maddr+SIINTCL_CL) = 0; break; case SIHOST2: *(maddr+SIPLRESET) = 0x10; switch (sc->sc_irq) { case IRQ11: *(maddr+SIPLIRQ11) = 0x10; break; case IRQ12: *(maddr+SIPLIRQ12) = 0x10; break; case IRQ15: *(maddr+SIPLIRQ15) = 0x10; break; } *(maddr+SIPLIRQCLR) = 0x10; break; default: /* this should _REALLY_ never happen */ printf("si%d: Uh, it was supported a second ago...\n", unit); return 0; } DELAY(1000000); /* wait around for a second */ regp = (struct si_reg *)maddr; y = 0; /* wait max of 5 sec for init OK */ while (regp->initstat == 0 && y++ < 10) { DELAY(500000); } switch (regp->initstat) { case 0: printf("si%d: startup timeout - aborting\n", unit); sc->sc_type = SIEMPTY; return 0; case 1: if (SI_ISJET(sc->sc_type)) { /* set throttle to 100 times per second */ regp->int_count = JET_INT_COUNT; /* rx_intr_count is a NOP in Jet */ } else { /* set throttle to 125 times per second */ regp->int_count = INT_COUNT; /* rx intr max of 25 times per second */ regp->rx_int_count = RXINT_COUNT; } regp->int_pending = 0; /* no intr pending */ regp->int_scounter = 0; /* reset counter */ break; case 0xff: /* * No modules found, so give up on this one. */ printf("si%d: %s - no ports found\n", unit, si_type[sc->sc_type]); return 0; default: printf("si%d: download code version error - initstat %x\n", unit, regp->initstat); return 0; } /* * First time around the ports just count them in order * to allocate some memory. */ nport = 0; modp = (struct si_module *)(maddr + 0x80); for (;;) { DPRINT((0, DBG_DOWNLOAD, "si%d: ccb addr 0x%x\n", unit, modp)); switch (modp->sm_type) { case TA4: DPRINT((0, DBG_DOWNLOAD, "si%d: Found old TA4 module, 4 ports\n", unit)); x = 4; break; case TA8: DPRINT((0, DBG_DOWNLOAD, "si%d: Found old TA8 module, 8 ports\n", unit)); x = 8; break; case TA4_ASIC: DPRINT((0, DBG_DOWNLOAD, "si%d: Found ASIC TA4 module, 4 ports\n", unit)); x = 4; break; case TA8_ASIC: DPRINT((0, DBG_DOWNLOAD, "si%d: Found ASIC TA8 module, 8 ports\n", unit)); x = 8; break; case MTA: DPRINT((0, DBG_DOWNLOAD, "si%d: Found CD1400 module, 8 ports\n", unit)); x = 8; break; case SXDC: DPRINT((0, DBG_DOWNLOAD, "si%d: Found SXDC module, 8 ports\n", unit)); x = 8; break; default: printf("si%d: unknown module type %d\n", unit, modp->sm_type); goto try_next; } /* this was limited in firmware and is also a driver issue */ if ((nport + x) > SI_MAXPORTPERCARD) { printf("si%d: extra ports ignored\n", unit); goto try_next; } nport += x; si_Nports += x; si_Nmodules++; try_next: if (modp->sm_next == 0) break; modp = (struct si_module *) (maddr + (unsigned)(modp->sm_next & 0x7fff)); } sc->sc_ports = (struct si_port *)malloc(sizeof(struct si_port) * nport, M_DEVBUF, M_NOWAIT); if (sc->sc_ports == 0) { mem_fail: printf("si%d: fail to malloc memory for port structs\n", unit); return 0; } bzero(sc->sc_ports, sizeof(struct si_port) * nport); sc->sc_nport = nport; /* * allocate tty structures for ports */ tp = (struct tty *)malloc(sizeof(*tp) * nport, M_DEVBUF, M_NOWAIT); if (tp == 0) goto mem_fail; bzero(tp, sizeof(*tp) * nport); si_tty = tp; /* * Scan round the ports again, this time initialising. */ pp = sc->sc_ports; nmodule = 0; modp = (struct si_module *)(maddr + 0x80); uart_type = 1000; /* arbitary, > uchar_max */ for (;;) { switch (modp->sm_type) { case TA4: nport = 4; break; case TA8: nport = 8; break; case TA4_ASIC: nport = 4; break; case TA8_ASIC: nport = 8; break; case MTA: nport = 8; break; case SXDC: nport = 8; break; default: goto try_next2; } nmodule++; ccbp = (struct si_channel *)((char *)modp + 0x100); if (uart_type == 1000) uart_type = ccbp->type; else if (uart_type != ccbp->type) printf("si%d: Warning: module %d mismatch! (%d%s != %d%s)\n", unit, nmodule, ccbp->type, si_modulename(sc->sc_type, ccbp->type), uart_type, si_modulename(sc->sc_type, uart_type)); for (x = 0; x < nport; x++, pp++, ccbp++) { pp->sp_ccb = ccbp; /* save the address */ pp->sp_tty = tp++; pp->sp_pend = IDLE_CLOSE; pp->sp_state = 0; /* internal flag */ pp->sp_dtr_wait = 3 * hz; pp->sp_iin.c_iflag = TTYDEF_IFLAG; pp->sp_iin.c_oflag = TTYDEF_OFLAG; pp->sp_iin.c_cflag = TTYDEF_CFLAG; pp->sp_iin.c_lflag = TTYDEF_LFLAG; termioschars(&pp->sp_iin); pp->sp_iin.c_ispeed = pp->sp_iin.c_ospeed = TTYDEF_SPEED;; pp->sp_iout = pp->sp_iin; } try_next2: if (modp->sm_next == 0) { printf("si%d: card: %s, ports: %d, modules: %d, type: %d%s\n", unit, sc->sc_typename, sc->sc_nport, nmodule, uart_type, si_modulename(sc->sc_type, uart_type)); break; } modp = (struct si_module *) (maddr + (unsigned)(modp->sm_next & 0x7fff)); } if (done_chartimes == 0) { for (spt = chartimes ; spt->sp_speed != -1; spt++) { if ((spt->sp_code /= hz) == 0) spt->sp_code = 1; } done_chartimes = 1; } #ifdef DEVFS /* path name devsw minor type uid gid perm*/ for ( x = 0; x < sc->sc_nport; x++ ) { /* sync with the manuals that start at 1 */ y = x + 1 + id->id_unit * (1 << SI_CARDSHIFT); sc->devfs_token[x].ttya = devfs_add_devswf( &si_cdevsw, x, DV_CHR, 0, 0, 0600, "ttyA%02d", y); sc->devfs_token[x].cuaa = devfs_add_devswf( &si_cdevsw, x + 0x00080, DV_CHR, 0, 0, 0600, "cuaA%02d", y); sc->devfs_token[x].ttyi = devfs_add_devswf( &si_cdevsw, x + 0x10000, DV_CHR, 0, 0, 0600, "ttyiA%02d", y); sc->devfs_token[x].cuai = devfs_add_devswf( &si_cdevsw, x + 0x10080, DV_CHR, 0, 0, 0600, "cuaiA%02d", y); sc->devfs_token[x].ttyl = devfs_add_devswf( &si_cdevsw, x + 0x20000, DV_CHR, 0, 0, 0600, "ttylA%02d", y); sc->devfs_token[x].cual = devfs_add_devswf( &si_cdevsw, x + 0x20080, DV_CHR, 0, 0, 0600, "cualA%02d", y); } sc->control_token = devfs_add_devswf(&si_cdevsw, 0x40000, DV_CHR, 0, 0, 0600, "si_control"); #endif return (1); } static int siopen(dev, flag, mode, p) dev_t dev; int flag, mode; struct proc *p; { int oldspl, error; int card, port; register struct si_softc *sc; register struct tty *tp; volatile struct si_channel *ccbp; struct si_port *pp; int mynor = minor(dev); /* quickly let in /dev/si_control */ if (IS_CONTROLDEV(mynor)) { if ((error = suser(p))) return(error); return(0); } card = SI_CARD(mynor); if (card >= NSI) return (ENXIO); sc = &si_softc[card]; if (sc->sc_type == SIEMPTY) { DPRINT((0, DBG_OPEN|DBG_FAIL, "si%d: type %s??\n", card, sc->sc_typename)); return(ENXIO); } port = SI_PORT(mynor); if (port >= sc->sc_nport) { DPRINT((0, DBG_OPEN|DBG_FAIL, "si%d: nports %d\n", card, sc->sc_nport)); return(ENXIO); } #ifdef POLL /* * We've now got a device, so start the poller. */ if (init_finished == 0) { timeout(si_poll, (caddr_t)0L, si_pollrate); init_finished = 1; } #endif /* initial/lock device */ if (IS_STATE(mynor)) { return(0); } pp = sc->sc_ports + port; tp = pp->sp_tty; /* the "real" tty */ ccbp = pp->sp_ccb; /* Find control block */ DPRINT((pp, DBG_ENTRY|DBG_OPEN, "siopen(%x,%x,%x,%x)\n", dev, flag, mode, p)); oldspl = spltty(); /* Keep others out */ error = 0; open_top: while (pp->sp_state & SS_DTR_OFF) { error = tsleep(&pp->sp_dtr_wait, TTIPRI|PCATCH, "sidtr", 0); if (error != 0) goto out; } if (tp->t_state & TS_ISOPEN) { /* * The device is open, so everything has been initialised. * handle conflicts. */ if (IS_CALLOUT(mynor)) { if (!pp->sp_active_out) { error = EBUSY; goto out; } } else { if (pp->sp_active_out) { if (flag & O_NONBLOCK) { error = EBUSY; goto out; } error = tsleep(&pp->sp_active_out, TTIPRI|PCATCH, "sibi", 0); if (error != 0) goto out; goto open_top; } } if (tp->t_state & TS_XCLUDE && suser(p)) { DPRINT((pp, DBG_OPEN|DBG_FAIL, "already open and EXCLUSIVE set\n")); error = EBUSY; goto out; } } else { /* * The device isn't open, so there are no conflicts. * Initialize it. Avoid sleep... :-) */ DPRINT((pp, DBG_OPEN, "first open\n")); tp->t_oproc = si_start; tp->t_param = siparam; tp->t_dev = dev; tp->t_termios = mynor & SI_CALLOUT_MASK ? pp->sp_iout : pp->sp_iin; (void) si_modem(pp, SET, TIOCM_DTR|TIOCM_RTS); ++pp->sp_wopeners; /* in case of sleep in siparam */ error = siparam(tp, &tp->t_termios); --pp->sp_wopeners; if (error != 0) goto out; /* XXX: we should goto_top if siparam slept */ /* set initial DCD state */ pp->sp_last_hi_ip = ccbp->hi_ip; if ((pp->sp_last_hi_ip & IP_DCD) || IS_CALLOUT(mynor)) { (*linesw[tp->t_line].l_modem)(tp, 1); } } /* whoops! we beat the close! */ if (pp->sp_state & SS_CLOSING) { /* try and stop it from proceeding to bash the hardware */ pp->sp_state &= ~SS_CLOSING; } /* * Wait for DCD if necessary */ if (!(tp->t_state & TS_CARR_ON) && !IS_CALLOUT(mynor) && !(tp->t_cflag & CLOCAL) && !(flag & O_NONBLOCK)) { ++pp->sp_wopeners; DPRINT((pp, DBG_OPEN, "sleeping for carrier\n")); error = tsleep(TSA_CARR_ON(tp), TTIPRI|PCATCH, "sidcd", 0); --pp->sp_wopeners; if (error != 0) goto out; goto open_top; } error = (*linesw[tp->t_line].l_open)(dev, tp); si_disc_optim(tp, &tp->t_termios, pp); if (tp->t_state & TS_ISOPEN && IS_CALLOUT(mynor)) pp->sp_active_out = TRUE; pp->sp_state |= SS_OPEN; /* made it! */ out: splx(oldspl); DPRINT((pp, DBG_OPEN, "leaving siopen\n")); if (!(tp->t_state & TS_ISOPEN) && pp->sp_wopeners == 0) sihardclose(pp); return(error); } static int siclose(dev, flag, mode, p) dev_t dev; int flag, mode; struct proc *p; { register struct si_port *pp; register struct tty *tp; int oldspl; int error = 0; int mynor = minor(dev); if (IS_SPECIAL(mynor)) return(0); oldspl = spltty(); pp = MINOR2PP(mynor); tp = pp->sp_tty; DPRINT((pp, DBG_ENTRY|DBG_CLOSE, "siclose(%x,%x,%x,%x) sp_state:%x\n", dev, flag, mode, p, pp->sp_state)); /* did we sleep and loose a race? */ if (pp->sp_state & SS_CLOSING) { /* error = ESOMETING? */ goto out; } /* begin race detection.. */ pp->sp_state |= SS_CLOSING; si_write_enable(pp, 0); /* block writes for ttywait() */ /* THIS MAY SLEEP IN TTYWAIT!!! */ (*linesw[tp->t_line].l_close)(tp, flag); si_write_enable(pp, 1); /* did we sleep and somebody started another open? */ if (!(pp->sp_state & SS_CLOSING)) { /* error = ESOMETING? */ goto out; } /* ok. we are now still on the right track.. nuke the hardware */ if (pp->sp_state & SS_LSTART) { untimeout(si_lstart, (caddr_t)pp, pp->lstart_ch); pp->sp_state &= ~SS_LSTART; } sistop(tp, FREAD | FWRITE); sihardclose(pp); ttyclose(tp); pp->sp_state &= ~SS_OPEN; out: DPRINT((pp, DBG_CLOSE|DBG_EXIT, "close done, returning\n")); splx(oldspl); return(error); } static void sihardclose(pp) struct si_port *pp; { int oldspl; struct tty *tp; volatile struct si_channel *ccbp; oldspl = spltty(); tp = pp->sp_tty; ccbp = pp->sp_ccb; /* Find control block */ if (tp->t_cflag & HUPCL || (!pp->sp_active_out && !(ccbp->hi_ip & IP_DCD) && !(pp->sp_iin.c_cflag && CLOCAL)) || !(tp->t_state & TS_ISOPEN)) { (void) si_modem(pp, BIC, TIOCM_DTR|TIOCM_RTS); (void) si_command(pp, FCLOSE, SI_NOWAIT); if (pp->sp_dtr_wait != 0) { timeout(sidtrwakeup, pp, pp->sp_dtr_wait); pp->sp_state |= SS_DTR_OFF; } } pp->sp_active_out = FALSE; wakeup((caddr_t)&pp->sp_active_out); wakeup(TSA_CARR_ON(tp)); splx(oldspl); } /* * called at splsoftclock()... */ static void sidtrwakeup(chan) void *chan; { struct si_port *pp; int oldspl; oldspl = spltty(); pp = (struct si_port *)chan; pp->sp_state &= ~SS_DTR_OFF; wakeup(&pp->sp_dtr_wait); splx(oldspl); } /* * User level stuff - read and write */ static int siread(dev, uio, flag) register dev_t dev; struct uio *uio; int flag; { register struct tty *tp; int mynor = minor(dev); if (IS_SPECIAL(mynor)) { DPRINT((0, DBG_ENTRY|DBG_FAIL|DBG_READ, "siread(CONTROLDEV!!)\n")); return(ENODEV); } tp = MINOR2TP(mynor); DPRINT((TP2PP(tp), DBG_ENTRY|DBG_READ, "siread(%x,%x,%x)\n", dev, uio, flag)); return ((*linesw[tp->t_line].l_read)(tp, uio, flag)); } static int siwrite(dev, uio, flag) dev_t dev; struct uio *uio; int flag; { register struct si_port *pp; register struct tty *tp; int error = 0; int mynor = minor(dev); int oldspl; if (IS_SPECIAL(mynor)) { DPRINT((0, DBG_ENTRY|DBG_FAIL|DBG_WRITE, "siwrite(CONTROLDEV!!)\n")); return(ENODEV); } pp = MINOR2PP(mynor); tp = pp->sp_tty; DPRINT((pp, DBG_WRITE, "siwrite(%x,%x,%x)\n", dev, uio, flag)); oldspl = spltty(); /* * If writes are currently blocked, wait on the "real" tty */ while (pp->sp_state & SS_BLOCKWRITE) { pp->sp_state |= SS_WAITWRITE; DPRINT((pp, DBG_WRITE, "in siwrite, wait for SS_BLOCKWRITE to clear\n")); if ((error = ttysleep(tp, (caddr_t)pp, TTOPRI|PCATCH, "siwrite", tp->t_timeout))) { if (error == EWOULDBLOCK) error = EIO; goto out; } } error = (*linesw[tp->t_line].l_write)(tp, uio, flag); out: splx(oldspl); return (error); } static struct tty * sidevtotty(dev_t dev) { struct si_port *pp; int mynor = minor(dev); struct si_softc *sc = &si_softc[SI_CARD(mynor)]; if (IS_SPECIAL(mynor)) return(NULL); if (SI_PORT(mynor) >= sc->sc_nport) return(NULL); pp = MINOR2PP(mynor); return (pp->sp_tty); } static int siioctl(dev, cmd, data, flag, p) dev_t dev; u_long cmd; caddr_t data; int flag; struct proc *p; { struct si_port *pp; register struct tty *tp; int error; int mynor = minor(dev); int oldspl; int blocked = 0; #if defined(COMPAT_43) u_long oldcmd; struct termios term; #endif if (IS_SI_IOCTL(cmd)) return(si_Sioctl(dev, cmd, data, flag, p)); pp = MINOR2PP(mynor); tp = pp->sp_tty; DPRINT((pp, DBG_ENTRY|DBG_IOCTL, "siioctl(%x,%lx,%x,%x)\n", dev, cmd, data, flag)); if (IS_STATE(mynor)) { struct termios *ct; switch (mynor & SI_STATE_MASK) { case SI_INIT_STATE_MASK: ct = IS_CALLOUT(mynor) ? &pp->sp_iout : &pp->sp_iin; break; case SI_LOCK_STATE_MASK: ct = IS_CALLOUT(mynor) ? &pp->sp_lout : &pp->sp_lin; break; default: return (ENODEV); } switch (cmd) { case TIOCSETA: error = suser(p); if (error != 0) return (error); *ct = *(struct termios *)data; return (0); case TIOCGETA: *(struct termios *)data = *ct; return (0); case TIOCGETD: *(int *)data = TTYDISC; return (0); case TIOCGWINSZ: bzero(data, sizeof(struct winsize)); return (0); default: return (ENOTTY); } } /* * Do the old-style ioctl compat routines... */ #if defined(COMPAT_43) term = tp->t_termios; oldcmd = cmd; error = ttsetcompat(tp, &cmd, data, &term); if (error != 0) return (error); if (cmd != oldcmd) data = (caddr_t)&term; #endif /* * Do the initial / lock state business */ if (cmd == TIOCSETA || cmd == TIOCSETAW || cmd == TIOCSETAF) { int cc; struct termios *dt = (struct termios *)data; struct termios *lt = mynor & SI_CALLOUT_MASK ? &pp->sp_lout : &pp->sp_lin; dt->c_iflag = (tp->t_iflag & lt->c_iflag) | (dt->c_iflag & ~lt->c_iflag); dt->c_oflag = (tp->t_oflag & lt->c_oflag) | (dt->c_oflag & ~lt->c_oflag); dt->c_cflag = (tp->t_cflag & lt->c_cflag) | (dt->c_cflag & ~lt->c_cflag); dt->c_lflag = (tp->t_lflag & lt->c_lflag) | (dt->c_lflag & ~lt->c_lflag); for (cc = 0; cc < NCCS; ++cc) if (lt->c_cc[cc] != 0) dt->c_cc[cc] = tp->t_cc[cc]; if (lt->c_ispeed != 0) dt->c_ispeed = tp->t_ispeed; if (lt->c_ospeed != 0) dt->c_ospeed = tp->t_ospeed; } /* * Block user-level writes to give the ttywait() * a chance to completely drain for commands * that require the port to be in a quiescent state. */ switch (cmd) { case TIOCSETAW: case TIOCSETAF: case TIOCDRAIN: #ifdef COMPAT_43 case TIOCSETP: #endif blocked++; /* block writes for ttywait() and siparam() */ si_write_enable(pp, 0); } error = (*linesw[tp->t_line].l_ioctl)(tp, cmd, data, flag, p); if (error != ENOIOCTL) goto out; oldspl = spltty(); error = ttioctl(tp, cmd, data, flag); si_disc_optim(tp, &tp->t_termios, pp); if (error != ENOIOCTL) goto outspl; switch (cmd) { case TIOCSBRK: si_command(pp, SBREAK, SI_WAIT); break; case TIOCCBRK: si_command(pp, EBREAK, SI_WAIT); break; case TIOCSDTR: (void) si_modem(pp, SET, TIOCM_DTR|TIOCM_RTS); break; case TIOCCDTR: (void) si_modem(pp, SET, 0); break; case TIOCMSET: (void) si_modem(pp, SET, *(int *)data); break; case TIOCMBIS: (void) si_modem(pp, BIS, *(int *)data); break; case TIOCMBIC: (void) si_modem(pp, BIC, *(int *)data); break; case TIOCMGET: *(int *)data = si_modem(pp, GET, 0); break; case TIOCMSDTRWAIT: /* must be root since the wait applies to following logins */ error = suser(p); if (error != 0) { goto outspl; } pp->sp_dtr_wait = *(int *)data * hz / 100; break; case TIOCMGDTRWAIT: *(int *)data = pp->sp_dtr_wait * 100 / hz; break; default: error = ENOTTY; } error = 0; outspl: splx(oldspl); out: DPRINT((pp, DBG_IOCTL|DBG_EXIT, "siioctl ret %d\n", error)); if (blocked) si_write_enable(pp, 1); return(error); } /* * Handle the Specialix ioctls. All MUST be called via the CONTROL device */ static int si_Sioctl(dev_t dev, u_long cmd, caddr_t data, int flag, struct proc *p) { struct si_softc *xsc; register struct si_port *xpp; volatile struct si_reg *regp; struct si_tcsi *dp; struct si_pstat *sps; int *ip, error = 0; int oldspl; int card, port; int mynor = minor(dev); DPRINT((0, DBG_ENTRY|DBG_IOCTL, "si_Sioctl(%x,%lx,%x,%x)\n", dev, cmd, data, flag)); #if 1 DPRINT((0, DBG_IOCTL, "TCSI_PORT=%x\n", TCSI_PORT)); DPRINT((0, DBG_IOCTL, "TCSI_CCB=%x\n", TCSI_CCB)); DPRINT((0, DBG_IOCTL, "TCSI_TTY=%x\n", TCSI_TTY)); #endif if (!IS_CONTROLDEV(mynor)) { DPRINT((0, DBG_IOCTL|DBG_FAIL, "not called from control device!\n")); return(ENODEV); } oldspl = spltty(); /* better safe than sorry */ ip = (int *)data; #define SUCHECK if ((error = suser(p))) goto out switch (cmd) { case TCSIPORTS: *ip = si_Nports; goto out; case TCSIMODULES: *ip = si_Nmodules; goto out; case TCSISDBG_ALL: SUCHECK; si_debug = *ip; goto out; case TCSIGDBG_ALL: *ip = si_debug; goto out; default: /* * Check that a controller for this port exists */ /* may also be a struct si_pstat, a superset of si_tcsi */ dp = (struct si_tcsi *)data; sps = (struct si_pstat *)data; card = dp->tc_card; xsc = &si_softc[card]; /* check.. */ if (card < 0 || card >= NSI || xsc->sc_type == SIEMPTY) { error = ENOENT; goto out; } /* * And check that a port exists */ port = dp->tc_port; if (port < 0 || port >= xsc->sc_nport) { error = ENOENT; goto out; } xpp = xsc->sc_ports + port; regp = (struct si_reg *)xsc->sc_maddr; } switch (cmd) { case TCSIDEBUG: #ifdef SI_DEBUG SUCHECK; if (xpp->sp_debug) xpp->sp_debug = 0; else { xpp->sp_debug = DBG_ALL; DPRINT((xpp, DBG_IOCTL, "debug toggled %s\n", (xpp->sp_debug&DBG_ALL)?"ON":"OFF")); } break; #else error = ENODEV; goto out; #endif case TCSISDBG_LEVEL: case TCSIGDBG_LEVEL: #ifdef SI_DEBUG if (cmd == TCSIGDBG_LEVEL) { dp->tc_dbglvl = xpp->sp_debug; } else { SUCHECK; xpp->sp_debug = dp->tc_dbglvl; } break; #else error = ENODEV; goto out; #endif case TCSIGRXIT: dp->tc_int = regp->rx_int_count; break; case TCSIRXIT: SUCHECK; regp->rx_int_count = dp->tc_int; break; case TCSIGIT: dp->tc_int = regp->int_count; break; case TCSIIT: SUCHECK; regp->int_count = dp->tc_int; break; case TCSISTATE: dp->tc_int = xpp->sp_ccb->hi_ip; break; /* these next three use a different structure */ case TCSI_PORT: SUCHECK; si_bcopy(xpp, &sps->tc_siport, sizeof(sps->tc_siport)); break; case TCSI_CCB: SUCHECK; si_bcopy((char *)xpp->sp_ccb, &sps->tc_ccb, sizeof(sps->tc_ccb)); break; case TCSI_TTY: SUCHECK; si_bcopy(xpp->sp_tty, &sps->tc_tty, sizeof(sps->tc_tty)); break; default: error = EINVAL; goto out; } out: splx(oldspl); return(error); /* success */ } /* * siparam() : Configure line params * called at spltty(); * this may sleep, does not flush, nor wait for drain, nor block writes * caller must arrange this if it's important.. */ static int siparam(tp, t) register struct tty *tp; register struct termios *t; { register struct si_port *pp = TP2PP(tp); volatile struct si_channel *ccbp; int oldspl, cflag, iflag, oflag, lflag; int error = 0; /* shutup gcc */ int ispeed = 0; /* shutup gcc */ int ospeed = 0; /* shutup gcc */ BYTE val; DPRINT((pp, DBG_ENTRY|DBG_PARAM, "siparam(%x,%x)\n", tp, t)); cflag = t->c_cflag; iflag = t->c_iflag; oflag = t->c_oflag; lflag = t->c_lflag; DPRINT((pp, DBG_PARAM, "OFLAG 0x%x CFLAG 0x%x IFLAG 0x%x LFLAG 0x%x\n", oflag, cflag, iflag, lflag)); /* XXX - if Jet host and SXDC module, use extended baud rates */ /* if not hung up.. */ if (t->c_ospeed != 0) { /* translate baud rate to firmware values */ ospeed = ttspeedtab(t->c_ospeed, bdrates); ispeed = t->c_ispeed ? ttspeedtab(t->c_ispeed, bdrates) : ospeed; /* enforce legit baud rate */ if (ospeed < 0 || ispeed < 0) return (EINVAL); } oldspl = spltty(); ccbp = pp->sp_ccb; /* ========== set hi_break ========== */ val = 0; if (iflag & IGNBRK) /* Breaks */ val |= BR_IGN; if (iflag & BRKINT) /* Interrupt on break? */ val |= BR_INT; if (iflag & PARMRK) /* Parity mark? */ val |= BR_PARMRK; if (iflag & IGNPAR) /* Ignore chars with parity errors? */ val |= BR_PARIGN; ccbp->hi_break = val; /* ========== set hi_csr ========== */ /* if not hung up.. */ if (t->c_ospeed != 0) { /* Set I/O speeds */ val = (ispeed << 4) | ospeed; } ccbp->hi_csr = val; /* ========== set hi_mr2 ========== */ val = 0; if (cflag & CSTOPB) /* Stop bits */ val |= MR2_2_STOP; else val |= MR2_1_STOP; /* * Enable H/W RTS/CTS handshaking. The default TA/MTA is * a DCE, hence the reverse sense of RTS and CTS */ /* Output Flow - RTS must be raised before data can be sent */ if (cflag & CCTS_OFLOW) val |= MR2_RTSCONT; ccbp->hi_mr2 = val; /* ========== set hi_mr1 ========== */ val = 0; if (!(cflag & PARENB)) /* Parity */ val |= MR1_NONE; else val |= MR1_WITH; if (cflag & PARODD) val |= MR1_ODD; if ((cflag & CS8) == CS8) { /* 8 data bits? */ val |= MR1_8_BITS; } else if ((cflag & CS7) == CS7) { /* 7 data bits? */ val |= MR1_7_BITS; } else if ((cflag & CS6) == CS6) { /* 6 data bits? */ val |= MR1_6_BITS; } else { /* Must be 5 */ val |= MR1_5_BITS; } /* * Enable H/W RTS/CTS handshaking. The default TA/MTA is * a DCE, hence the reverse sense of RTS and CTS */ /* Input Flow - CTS is raised when port is ready to receive data */ if (cflag & CRTS_IFLOW) val |= MR1_CTSCONT; ccbp->hi_mr1 = val; /* ========== set hi_mask ========== */ val = 0xff; if ((cflag & CS8) == CS8) { /* 8 data bits? */ val &= 0xFF; } else if ((cflag & CS7) == CS7) { /* 7 data bits? */ val &= 0x7F; } else if ((cflag & CS6) == CS6) { /* 6 data bits? */ val &= 0x3F; } else { /* Must be 5 */ val &= 0x1F; } if (iflag & ISTRIP) val &= 0x7F; ccbp->hi_mask = val; /* ========== set hi_prtcl ========== */ val = 0; /* Monitor DCD etc. if a modem */ if (!(cflag & CLOCAL)) val |= SP_DCEN; if (iflag & IXANY) val |= SP_TANY; if (iflag & IXON) val |= SP_TXEN; if (iflag & IXOFF) val |= SP_RXEN; if (iflag & INPCK) val |= SP_PAEN; ccbp->hi_prtcl = val; /* ========== set hi_{rx|tx}{on|off} ========== */ /* XXX: the card TOTALLY shields us from the flow control... */ ccbp->hi_txon = t->c_cc[VSTART]; ccbp->hi_txoff = t->c_cc[VSTOP]; ccbp->hi_rxon = t->c_cc[VSTART]; ccbp->hi_rxoff = t->c_cc[VSTOP]; /* ========== send settings to the card ========== */ /* potential sleep here */ if (ccbp->hi_stat == IDLE_CLOSE) /* Not yet open */ si_command(pp, LOPEN, SI_WAIT); /* open it */ else si_command(pp, CONFIG, SI_WAIT); /* change params */ /* ========== set DTR etc ========== */ /* Hangup if ospeed == 0 */ if (t->c_ospeed == 0) { (void) si_modem(pp, BIC, TIOCM_DTR|TIOCM_RTS); } else { /* * If the previous speed was 0, may need to re-enable * the modem signals */ (void) si_modem(pp, SET, TIOCM_DTR|TIOCM_RTS); } DPRINT((pp, DBG_PARAM, "siparam, complete: MR1 %x MR2 %x HI_MASK %x PRTCL %x HI_BREAK %x\n", ccbp->hi_mr1, ccbp->hi_mr2, ccbp->hi_mask, ccbp->hi_prtcl, ccbp->hi_break)); splx(oldspl); return(error); } /* * Enable or Disable the writes to this channel... * "state" -> enabled = 1; disabled = 0; */ static void si_write_enable(pp, state) register struct si_port *pp; int state; { int oldspl; oldspl = spltty(); if (state) { pp->sp_state &= ~SS_BLOCKWRITE; if (pp->sp_state & SS_WAITWRITE) { pp->sp_state &= ~SS_WAITWRITE; /* thunder away! */ wakeup((caddr_t)pp); } } else { pp->sp_state |= SS_BLOCKWRITE; } splx(oldspl); } /* * Set/Get state of modem control lines. * Due to DCE-like behaviour of the adapter, some signals need translation: * TIOCM_DTR DSR * TIOCM_RTS CTS */ static int si_modem(pp, cmd, bits) struct si_port *pp; enum si_mctl cmd; int bits; { volatile struct si_channel *ccbp; int x; DPRINT((pp, DBG_ENTRY|DBG_MODEM, "si_modem(%x,%s,%x)\n", pp, si_mctl2str(cmd), bits)); ccbp = pp->sp_ccb; /* Find channel address */ switch (cmd) { case GET: x = ccbp->hi_ip; bits = TIOCM_LE; if (x & IP_DCD) bits |= TIOCM_CAR; if (x & IP_DTR) bits |= TIOCM_DTR; if (x & IP_RTS) bits |= TIOCM_RTS; if (x & IP_RI) bits |= TIOCM_RI; return(bits); case SET: ccbp->hi_op &= ~(OP_DSR|OP_CTS); /* fall through */ case BIS: x = 0; if (bits & TIOCM_DTR) x |= OP_DSR; if (bits & TIOCM_RTS) x |= OP_CTS; ccbp->hi_op |= x; break; case BIC: if (bits & TIOCM_DTR) ccbp->hi_op &= ~OP_DSR; if (bits & TIOCM_RTS) ccbp->hi_op &= ~OP_CTS; } return 0; } /* * Handle change of modem state */ static void si_modem_state(pp, tp, hi_ip) register struct si_port *pp; register struct tty *tp; register int hi_ip; { /* if a modem dev */ if (hi_ip & IP_DCD) { if ( !(pp->sp_last_hi_ip & IP_DCD)) { DPRINT((pp, DBG_INTR, "modem carr on t_line %d\n", tp->t_line)); (void)(*linesw[tp->t_line].l_modem)(tp, 1); } } else { if (pp->sp_last_hi_ip & IP_DCD) { DPRINT((pp, DBG_INTR, "modem carr off\n")); if ((*linesw[tp->t_line].l_modem)(tp, 0)) (void) si_modem(pp, SET, 0); } } pp->sp_last_hi_ip = hi_ip; } /* * Poller to catch missed interrupts. * * Note that the SYSV Specialix drivers poll at 100 times per second to get * better response. We could really use a "periodic" version timeout(). :-) */ #ifdef POLL static void si_poll(void *nothing) { register struct si_softc *sc; register int i; volatile struct si_reg *regp; register struct si_port *pp; int lost, oldspl, port; DPRINT((0, DBG_POLL, "si_poll()\n")); oldspl = spltty(); if (in_intr) goto out; lost = 0; for (i=0; isc_type == SIEMPTY) continue; regp = (struct si_reg *)sc->sc_maddr; /* * See if there has been a pending interrupt for 2 seconds * or so. The test (int_scounter >= 200) won't correspond * to 2 seconds if int_count gets changed. */ if (regp->int_pending != 0) { if (regp->int_scounter >= 200 && regp->initstat == 1) { printf("si%d: lost intr\n", i); lost++; } } else { regp->int_scounter = 0; } /* * gripe about no input flow control.. */ pp = sc->sc_ports; for (port = 0; port < sc->sc_nport; pp++, port++) { if (pp->sp_delta_overflows > 0) { printf("si%d: %d tty level buffer overflows\n", i, pp->sp_delta_overflows); pp->sp_delta_overflows = 0; } } } if (lost || si_realpoll) si_intr(-1); /* call intr with fake vector */ out: splx(oldspl); timeout(si_poll, (caddr_t)0L, si_pollrate); } #endif /* ifdef POLL */ /* * The interrupt handler polls ALL ports on ALL adapters each time * it is called. */ static BYTE si_rxbuf[SI_BUFFERSIZE]; /* input staging area */ static BYTE si_txbuf[SI_BUFFERSIZE]; /* output staging area */ static void si_intr(int unit) { register struct si_softc *sc; register struct si_port *pp; volatile struct si_channel *ccbp; register struct tty *tp; volatile caddr_t maddr; BYTE op, ip; int x, card, port, n, i, isopen; volatile BYTE *z; BYTE c; DPRINT((0, (unit < 0) ? DBG_POLL:DBG_INTR, "si_intr(%d)\n", unit)); if (in_intr) { if (unit < 0) /* should never happen */ printf("si%d: Warning poll entered during interrupt\n", unit); else printf("si%d: Warning interrupt handler re-entered\n", unit); return; } in_intr = 1; /* * When we get an int we poll all the channels and do ALL pending * work, not just the first one we find. This allows all cards to * share the same vector. * * XXX - But if we're sharing the vector with something that's NOT * a SI/XIO/SX card, we may be making more work for ourselves. */ for (card = 0; card < NSI; card++) { sc = &si_softc[card]; if (sc->sc_type == SIEMPTY) continue; /* * First, clear the interrupt */ switch(sc->sc_type) { case SIHOST: maddr = sc->sc_maddr; ((volatile struct si_reg *)maddr)->int_pending = 0; /* flag nothing pending */ *(maddr+SIINTCL) = 0x00; /* Set IRQ clear */ *(maddr+SIINTCL_CL) = 0x00; /* Clear IRQ clear */ break; case SIHOST2: maddr = sc->sc_maddr; ((volatile struct si_reg *)maddr)->int_pending = 0; *(maddr+SIPLIRQCLR) = 0x00; *(maddr+SIPLIRQCLR) = 0x10; break; #if NPCI > 0 case SIPCI: maddr = sc->sc_maddr; ((volatile struct si_reg *)maddr)->int_pending = 0; *(maddr+SIPCIINTCL) = 0x0; break; case SIJETPCI: /* fall through to JETISA case */ #endif case SIJETISA: maddr = sc->sc_maddr; ((volatile struct si_reg *)maddr)->int_pending = 0; *(maddr+SIJETINTCL) = 0x0; break; #if NEISA > 0 case SIEISA: maddr = sc->sc_maddr; ((volatile struct si_reg *)maddr)->int_pending = 0; (void)inb(sc->sc_eisa_iobase + 3); break; #endif case SIEMPTY: default: continue; } ((volatile struct si_reg *)maddr)->int_scounter = 0; /* * check each port */ for (pp = sc->sc_ports, port=0; port < sc->sc_nport; pp++, port++) { ccbp = pp->sp_ccb; tp = pp->sp_tty; /* * See if a command has completed ? */ if (ccbp->hi_stat != pp->sp_pend) { DPRINT((pp, DBG_INTR, "si_intr hi_stat = 0x%x, pend = %d\n", ccbp->hi_stat, pp->sp_pend)); switch(pp->sp_pend) { case LOPEN: case MPEND: case MOPEN: case CONFIG: case SBREAK: case EBREAK: pp->sp_pend = ccbp->hi_stat; /* sleeping in si_command */ wakeup(&pp->sp_state); break; default: pp->sp_pend = ccbp->hi_stat; } } /* * Continue on if it's closed */ if (ccbp->hi_stat == IDLE_CLOSE) { continue; } /* * Do modem state change if not a local device */ si_modem_state(pp, tp, ccbp->hi_ip); /* * Check to see if we should 'receive' characters. */ if (tp->t_state & TS_CONNECTED && tp->t_state & TS_ISOPEN) isopen = 1; else isopen = 0; /* * Do input break processing */ if (ccbp->hi_state & ST_BREAK) { if (isopen) { (*linesw[tp->t_line].l_rint)(TTY_BI, tp); } ccbp->hi_state &= ~ST_BREAK; /* A Bit iffy this */ DPRINT((pp, DBG_INTR, "si_intr break\n")); } /* * Do RX stuff - if not open then dump any characters. * XXX: This is VERY messy and needs to be cleaned up. * * XXX: can we leave data in the host adapter buffer * when the clists are full? That may be dangerous * if the user cannot get an interrupt signal through. */ more_rx: /* XXX Sorry. the nesting was driving me bats! :-( */ if (!isopen) { ccbp->hi_rxopos = ccbp->hi_rxipos; goto end_rx; } /* * If the tty input buffers are blocked, stop emptying * the incoming buffers and let the auto flow control * assert.. */ if (tp->t_state & TS_TBLOCK) { goto end_rx; } /* * Process read characters if not skipped above */ op = ccbp->hi_rxopos; ip = ccbp->hi_rxipos; c = ip - op; if (c == 0) { goto end_rx; } n = c & 0xff; if (n > 250) n = 250; DPRINT((pp, DBG_INTR, "n = %d, op = %d, ip = %d\n", n, op, ip)); /* * Suck characters out of host card buffer into the * "input staging buffer" - so that we dont leave the * host card in limbo while we're possibly echoing * characters and possibly flushing input inside the * ldisc l_rint() routine. */ if (n <= SI_BUFFERSIZE - op) { DPRINT((pp, DBG_INTR, "\tsingle copy\n")); z = ccbp->hi_rxbuf + op; si_bcopy((caddr_t)z, si_rxbuf, n); op += n; } else { x = SI_BUFFERSIZE - op; DPRINT((pp, DBG_INTR, "\tdouble part 1 %d\n", x)); z = ccbp->hi_rxbuf + op; si_bcopy((caddr_t)z, si_rxbuf, x); DPRINT((pp, DBG_INTR, "\tdouble part 2 %d\n", n - x)); z = ccbp->hi_rxbuf; si_bcopy((caddr_t)z, si_rxbuf + x, n - x); op += n; } /* clear collected characters from buffer */ ccbp->hi_rxopos = op; DPRINT((pp, DBG_INTR, "n = %d, op = %d, ip = %d\n", n, op, ip)); /* * at this point... * n = number of chars placed in si_rxbuf */ /* * Avoid the grotesquely inefficient lineswitch * routine (ttyinput) in "raw" mode. It usually * takes about 450 instructions (that's without * canonical processing or echo!). slinput is * reasonably fast (usually 40 instructions * plus call overhead). */ if (tp->t_state & TS_CAN_BYPASS_L_RINT) { /* block if the driver supports it */ if (tp->t_rawq.c_cc + n >= SI_I_HIGH_WATER && (tp->t_cflag & CRTS_IFLOW || tp->t_iflag & IXOFF) && !(tp->t_state & TS_TBLOCK)) ttyblock(tp); tk_nin += n; tk_rawcc += n; tp->t_rawcc += n; pp->sp_delta_overflows += b_to_q((char *)si_rxbuf, n, &tp->t_rawq); ttwakeup(tp); if (tp->t_state & TS_TTSTOP && (tp->t_iflag & IXANY || tp->t_cc[VSTART] == tp->t_cc[VSTOP])) { tp->t_state &= ~TS_TTSTOP; tp->t_lflag &= ~FLUSHO; si_start(tp); } } else { /* * It'd be nice to not have to go through the * function call overhead for each char here. * It'd be nice to block input it, saving a * loop here and the call/return overhead. */ for(x = 0; x < n; x++) { i = si_rxbuf[x]; if ((*linesw[tp->t_line].l_rint)(i, tp) == -1) { pp->sp_delta_overflows++; } /* * doesn't seem to be much point doing * this here.. this driver has no * softtty processing! ?? */ if (pp->sp_hotchar && i == pp->sp_hotchar) { setsofttty(); } } } goto more_rx; /* try for more until RXbuf is empty */ end_rx: /* XXX: Again, sorry about the gotos.. :-) */ /* * Do TX stuff */ (*linesw[tp->t_line].l_start)(tp); } /* end of for (all ports on this controller) */ } /* end of for (all controllers) */ in_intr = 0; DPRINT((0, (unit < 0) ? DBG_POLL:DBG_INTR, "end si_intr(%d)\n", unit)); } /* * Nudge the transmitter... * * XXX: I inherited some funny code here. It implies the host card only * interrupts when the transmit buffer reaches the low-water-mark, and does * not interrupt when it's actually hits empty. In some cases, we have * processes waiting for complete drain, and we need to simulate an interrupt * about when we think the buffer is going to be empty (and retry if not). * I really am not certain about this... I *need* the hardware manuals. */ static void si_start(tp) register struct tty *tp; { struct si_port *pp; volatile struct si_channel *ccbp; register struct clist *qp; BYTE ipos; int nchar; int oldspl, count, n, amount, buffer_full; oldspl = spltty(); qp = &tp->t_outq; pp = TP2PP(tp); DPRINT((pp, DBG_ENTRY|DBG_START, "si_start(%x) t_state %x sp_state %x t_outq.c_cc %d\n", tp, tp->t_state, pp->sp_state, qp->c_cc)); if (tp->t_state & (TS_TIMEOUT|TS_TTSTOP)) goto out; buffer_full = 0; ccbp = pp->sp_ccb; count = (int)ccbp->hi_txipos - (int)ccbp->hi_txopos; DPRINT((pp, DBG_START, "count %d\n", (BYTE)count)); while ((nchar = qp->c_cc) > 0) { if ((BYTE)count >= 255) { buffer_full++; break; } amount = min(nchar, (255 - (BYTE)count)); ipos = (unsigned int)ccbp->hi_txipos; n = q_to_b(&tp->t_outq, si_txbuf, amount); /* will it fit in one lump? */ if ((SI_BUFFERSIZE - ipos) >= n) { si_bcopy(si_txbuf, (char *)&ccbp->hi_txbuf[ipos], n); } else { si_bcopy(si_txbuf, (char *)&ccbp->hi_txbuf[ipos], SI_BUFFERSIZE - ipos); si_bcopy(si_txbuf + (SI_BUFFERSIZE - ipos), (char *)&ccbp->hi_txbuf[0], n - (SI_BUFFERSIZE - ipos)); } ccbp->hi_txipos += n; count = (int)ccbp->hi_txipos - (int)ccbp->hi_txopos; } if (count != 0 && nchar == 0) { tp->t_state |= TS_BUSY; } else { tp->t_state &= ~TS_BUSY; } /* wakeup time? */ ttwwakeup(tp); DPRINT((pp, DBG_START, "count %d, nchar %d, tp->t_state 0x%x\n", (BYTE)count, nchar, tp->t_state)); if (tp->t_state & TS_BUSY) { int time; time = ttspeedtab(tp->t_ospeed, chartimes); if (time > 0) { if (time < nchar) time = nchar / time; else time = 2; } else { DPRINT((pp, DBG_START, "bad char time value! %d\n", time)); time = hz/10; } if ((pp->sp_state & (SS_LSTART|SS_INLSTART)) == SS_LSTART) { untimeout(si_lstart, (caddr_t)pp, pp->lstart_ch); } else { pp->sp_state |= SS_LSTART; } DPRINT((pp, DBG_START, "arming lstart, time=%d\n", time)); pp->lstart_ch = timeout(si_lstart, (caddr_t)pp, time); } out: splx(oldspl); DPRINT((pp, DBG_EXIT|DBG_START, "leave si_start()\n")); } /* * Note: called at splsoftclock from the timeout code * This has to deal with two things... cause wakeups while waiting for * tty drains on last process exit, and call l_start at about the right * time for protocols like ppp. */ static void si_lstart(void *arg) { register struct si_port *pp = arg; register struct tty *tp; int oldspl; DPRINT((pp, DBG_ENTRY|DBG_LSTART, "si_lstart(%x) sp_state %x\n", pp, pp->sp_state)); oldspl = spltty(); if ((pp->sp_state & SS_OPEN) == 0 || (pp->sp_state & SS_LSTART) == 0) { splx(oldspl); return; } pp->sp_state &= ~SS_LSTART; pp->sp_state |= SS_INLSTART; tp = pp->sp_tty; /* deal with the process exit case */ ttwwakeup(tp); /* nudge protocols - eg: ppp */ (*linesw[tp->t_line].l_start)(tp); pp->sp_state &= ~SS_INLSTART; splx(oldspl); } /* * Stop output on a line. called at spltty(); */ void sistop(tp, rw) register struct tty *tp; int rw; { volatile struct si_channel *ccbp; struct si_port *pp; pp = TP2PP(tp); ccbp = pp->sp_ccb; DPRINT((TP2PP(tp), DBG_ENTRY|DBG_STOP, "sistop(%x,%x)\n", tp, rw)); /* XXX: must check (rw & FWRITE | FREAD) etc flushing... */ if (rw & FWRITE) { /* what level are we meant to be flushing anyway? */ if (tp->t_state & TS_BUSY) { si_command(TP2PP(tp), WFLUSH, SI_NOWAIT); tp->t_state &= ~TS_BUSY; ttwwakeup(tp); /* Bruce???? */ } } #if 1 /* XXX: this doesn't work right yet.. */ /* XXX: this may have been failing because we used to call l_rint() * while we were looping based on these two counters. Now, we collect * the data and then loop stuffing it into l_rint(), making this * useless. Should we cause this to blow away the staging buffer? */ if (rw & FREAD) { ccbp->hi_rxopos = ccbp->hi_rxipos; } #endif } /* * Issue a command to the host card CPU. */ static void si_command(pp, cmd, waitflag) struct si_port *pp; /* port control block (local) */ int cmd; int waitflag; { int oldspl; volatile struct si_channel *ccbp = pp->sp_ccb; int x; DPRINT((pp, DBG_ENTRY|DBG_PARAM, "si_command(%x,%x,%d): hi_stat 0x%x\n", pp, cmd, waitflag, ccbp->hi_stat)); oldspl = spltty(); /* Keep others out */ /* wait until it's finished what it was doing.. */ /* XXX: sits in IDLE_BREAK until something disturbs it or break * is turned off. */ while((x = ccbp->hi_stat) != IDLE_OPEN && x != IDLE_CLOSE && x != IDLE_BREAK && x != cmd) { if (in_intr) { /* Prevent sleep in intr */ DPRINT((pp, DBG_PARAM, "cmd intr collision - completing %d\trequested %d\n", x, cmd)); splx(oldspl); return; } else if (ttysleep(pp->sp_tty, (caddr_t)&pp->sp_state, TTIPRI|PCATCH, "sicmd1", 1)) { splx(oldspl); return; } } /* it should now be in IDLE_{OPEN|CLOSE|BREAK}, or "cmd" */ /* if there was a pending command, cause a state-change wakeup */ switch(pp->sp_pend) { case LOPEN: case MPEND: case MOPEN: case CONFIG: case SBREAK: case EBREAK: wakeup(&pp->sp_state); break; default: break; } pp->sp_pend = cmd; /* New command pending */ ccbp->hi_stat = cmd; /* Post it */ if (waitflag) { if (in_intr) { /* If in interrupt handler */ DPRINT((pp, DBG_PARAM, "attempt to sleep in si_intr - cmd req %d\n", cmd)); splx(oldspl); return; } else while(ccbp->hi_stat != IDLE_OPEN && ccbp->hi_stat != IDLE_BREAK) { if (ttysleep(pp->sp_tty, (caddr_t)&pp->sp_state, TTIPRI|PCATCH, "sicmd2", 0)) break; } } splx(oldspl); } static void si_disc_optim(tp, t, pp) struct tty *tp; struct termios *t; struct si_port *pp; { /* * XXX can skip a lot more cases if Smarts. Maybe * (IGNCR | ISTRIP | IXON) in c_iflag. But perhaps we * shouldn't skip if (TS_CNTTB | TS_LNCH) is set in t_state. */ if (!(t->c_iflag & (ICRNL | IGNCR | IMAXBEL | INLCR | ISTRIP | IXON)) && (!(t->c_iflag & BRKINT) || (t->c_iflag & IGNBRK)) && (!(t->c_iflag & PARMRK) || (t->c_iflag & (IGNPAR | IGNBRK)) == (IGNPAR | IGNBRK)) && !(t->c_lflag & (ECHO | ICANON | IEXTEN | ISIG | PENDIN)) && linesw[tp->t_line].l_rint == ttyinput) tp->t_state |= TS_CAN_BYPASS_L_RINT; else tp->t_state &= ~TS_CAN_BYPASS_L_RINT; pp->sp_hotchar = linesw[tp->t_line].l_hotchar; DPRINT((pp, DBG_OPTIM, "bypass: %s, hotchar: %x\n", (tp->t_state & TS_CAN_BYPASS_L_RINT) ? "on" : "off", pp->sp_hotchar)); } #ifdef SI_DEBUG static void #ifdef __STDC__ si_dprintf(struct si_port *pp, int flags, const char *fmt, ...) #else si_dprintf(pp, flags, fmt, va_alist) struct si_port *pp; int flags; char *fmt; #endif { va_list ap; if ((pp == NULL && (si_debug&flags)) || (pp != NULL && ((pp->sp_debug&flags) || (si_debug&flags)))) { if (pp != NULL) printf("%ci%d(%d): ", 's', (int)SI_CARD(minor(pp->sp_tty->t_dev)), (int)SI_PORT(minor(pp->sp_tty->t_dev))); va_start(ap, fmt); vprintf(fmt, ap); va_end(ap); } } static char * si_mctl2str(cmd) enum si_mctl cmd; { switch (cmd) { case GET: return("GET"); case SET: return("SET"); case BIS: return("BIS"); case BIC: return("BIC"); } return("BAD"); } #endif /* DEBUG */ static char * si_modulename(host_type, uart_type) int host_type, uart_type; { switch (host_type) { /* Z280 based cards */ #if NEISA > 0 case SIEISA: #endif case SIHOST2: case SIHOST: #if NPCI > 0 case SIPCI: #endif switch (uart_type) { case 0: return(" (XIO)"); case 1: return(" (SI)"); } break; /* T225 based hosts */ #if NPCI > 0 case SIJETPCI: #endif case SIJETISA: switch (uart_type) { case 0: return(" (SI)"); case 40: return(" (XIO)"); case 72: return(" (SXDC)"); } break; } return(""); } static int si_devsw_installed; static void si_drvinit(void *unused) { dev_t dev; if (!si_devsw_installed) { dev = makedev(CDEV_MAJOR, 0); cdevsw_add(&dev,&si_cdevsw, NULL); si_devsw_installed = 1; } } SYSINIT(sidev,SI_SUB_DRIVERS,SI_ORDER_MIDDLE+CDEV_MAJOR,si_drvinit,NULL)