/* * ---------------------------------------------------------------------------- * "THE BEER-WARE LICENSE" (Revision 42): * wrote this file. As long as you retain this notice you * can do whatever you want with this stuff. If we meet some day, and you think * this stuff is worth it, you can buy me a beer in return. Poul-Henning Kamp * ---------------------------------------------------------------------------- * * $Id: if_mn.c,v 1.1 1999/02/01 13:06:40 phk Exp $ * * Driver for Siemens reference design card "Easy321-R1". * * This card contains a FALC54 E1/T1 framer and a MUNICH32X 32-channel HDLC * controller. * * The driver supports E1 mode with up to 31 channels. We send CRC4 but don't * check it coming in. * * The FALC54 and MUNICH32X have far too many registers and weird modes for * comfort, so I have not bothered typing it all into a "fooreg.h" file, * you will (badly!) need the documentation anyway if you want to mess with * this gadget. * * $FreeBSD: src/sys/pci/if_mn.c,v 1.11.2.3 2001/01/23 12:47:09 phk Exp $ */ /* * Stuff to describe the MUNIC32X and FALC54 chips. */ #define M32_CHAN 32 /* We have 32 channels */ #define M32_TS 32 /* We have 32 timeslots */ #define NG_MN_NODE_TYPE "mn" #include #include #include #include #include #include #include #include #include #include #include "pci_if.h" #include #include #include #include #include static int mn_maxlatency = 1000; SYSCTL_INT(_debug, OID_AUTO, mn_maxlatency, CTLFLAG_RW, &mn_maxlatency, 0, "The number of milliseconds a packet is allowed to spend in the output queue. " "If the output queue is longer than this number of milliseconds when the packet " "arrives for output, the packet will be dropped." ); #ifndef NMN /* Most machines don't support more than 4 busmaster PCI slots, if even that many */ #define NMN 4 #endif /* From: PEB 20321 data sheet, p187, table 22 */ struct m32xreg { u_int32_t conf, cmd, stat, imask; u_int32_t fill10, piqba, piql, fill1c; u_int32_t mode1, mode2, ccba, txpoll; u_int32_t tiqba, tiql, riqba, riql; u_int32_t lconf, lccba, fill48, ltran; u_int32_t ltiqba, ltiql, lriqba, lriql; u_int32_t lreg0, lreg1, lreg2, lreg3; u_int32_t lreg4, lreg5, lre6, lstat; u_int32_t gpdir, gpdata, gpod, fill8c; u_int32_t ssccon, sscbr, ssctb, sscrb; u_int32_t ssccse, sscim, fillab, fillac; u_int32_t iomcon1, iomcon2, iomstat, fillbc; u_int32_t iomcit0, iomcit1, iomcir0, iomcir1; u_int32_t iomtmo, iomrmo, filld8, filldc; u_int32_t mbcmd, mbdata1, mbdata2, mbdata3; u_int32_t mbdata4, mbdata5, mbdata6, mbdata7; }; /* From: PEB 2254 data sheet, p80, table 10 */ struct f54wreg { u_int16_t xfifo; u_int8_t cmdr, mode, rah1, rah2, ral1, ral2; u_int8_t ipc, ccr1, ccr3, pre, rtr1, rtr2, rtr3, rtr4; u_int8_t ttr1, ttr2, ttr3, ttr4, imr0, imr1, imr2, imr3; u_int8_t imr4, fill19, fmr0, fmr1, fmr2, loop, xsw, xsp; u_int8_t xc0, xc1, rc0, rc1, xpm0, xpm1, xpm2, tswm; u_int8_t test1, idle, xsa4, xsa5, xsa6, xsa7, xsa8, fmr3; u_int8_t icb1, icb2, icb3, icb4, lim0, lim1, pcd, pcr; u_int8_t lim2, fill39[7]; u_int8_t fill40[8]; u_int8_t fill48[8]; u_int8_t fill50[8]; u_int8_t fill58[8]; u_int8_t dec, fill61, test2, fill63[5]; u_int8_t fill68[8]; u_int8_t xs[16]; }; /* From: PEB 2254 data sheet, p117, table 10 */ struct f54rreg { u_int16_t rfifo; u_int8_t fill2, mode, rah1, rah2, ral1, ral2; u_int8_t ipc, ccr1, ccr3, pre, rtr1, rtr2, rtr3, rtr4; u_int8_t ttr1, ttr2, ttr3, ttr4, imr0, imr1, imr2, imr3; u_int8_t imr4, fill19, fmr0, fmr1, fmr2, loop, xsw, xsp; u_int8_t xc0, xc1, rc0, rc1, xpm0, xpm1, xpm2, tswm; u_int8_t test, idle, xsa4, xsa5, xsa6, xsa7, xsa8, fmr13; u_int8_t icb1, icb2, icb3, icb4, lim0, lim1, pcd, pcr; u_int8_t lim2, fill39[7]; u_int8_t fill40[8]; u_int8_t fill48[4], frs0, frs1, rsw, rsp; u_int16_t fec, cvc, cec1, ebc; u_int16_t cec2, cec3; u_int8_t rsa4, rsa5, rsa6, rsa7; u_int8_t rsa8, rsa6s, tsr0, tsr1, sis, rsis; u_int16_t rbc; u_int8_t isr0, isr1, isr2, isr3, fill6c, fill6d, gis, vstr; u_int8_t rs[16]; }; /* Transmit & receive descriptors */ struct trxd { u_int32_t flags; vm_offset_t next; vm_offset_t data; u_int32_t status; /* only used for receive */ struct mbuf *m; /* software use only */ struct trxd *vnext; /* software use only */ }; /* Channel specification */ struct cspec { u_int32_t flags; vm_offset_t rdesc; vm_offset_t tdesc; u_int32_t itbs; }; struct m32_mem { vm_offset_t csa; u_int32_t ccb; u_int32_t reserve1[2]; u_int32_t ts[M32_TS]; struct cspec cs[M32_CHAN]; vm_offset_t crxd[M32_CHAN]; vm_offset_t ctxd[M32_CHAN]; }; struct softc; struct sockaddr; struct rtentry; static int mn_probe (device_t self); static int mn_attach (device_t self); static void mn_create_channel(struct softc *sc, int chan); static int mn_reset(struct softc *sc); static struct trxd * mn_alloc_desc(void); static void mn_free_desc(struct trxd *dp); static void mn_intr(void *xsc); static u_int32_t mn_parse_ts(const char *s, int *nbit); #ifdef notyet static void m32_dump(struct softc *sc); static void f54_dump(struct softc *sc); static void mn_fmt_ts(char *p, u_int32_t ts); #endif /* notyet */ static void f54_init(struct softc *sc); static ng_constructor_t ngmn_constructor; static ng_rcvmsg_t ngmn_rcvmsg; static ng_shutdown_t ngmn_shutdown; static ng_newhook_t ngmn_newhook; static ng_connect_t ngmn_connect; static ng_rcvdata_t ngmn_rcvdata; static ng_disconnect_t ngmn_disconnect; static struct ng_type mntypestruct = { NG_VERSION, NG_MN_NODE_TYPE, NULL, ngmn_constructor, ngmn_rcvmsg, ngmn_shutdown, ngmn_newhook, NULL, ngmn_connect, ngmn_rcvdata, ngmn_rcvdata, ngmn_disconnect, NULL }; static MALLOC_DEFINE(M_MN, "mn", "Mx driver related"); #define NIQB 64 struct schan { enum {DOWN, UP} state; struct softc *sc; int chan; u_int32_t ts; char name[8]; struct trxd *r1, *rl; struct trxd *x1, *xl; hook_p hook; time_t last_recv; time_t last_rxerr; time_t last_xmit; u_long rx_error; u_long short_error; u_long crc_error; u_long dribble_error; u_long long_error; u_long abort_error; u_long overflow_error; int last_error; int prev_error; u_long tx_pending; u_long tx_limit; }; enum framing {WHOKNOWS, E1, E1U, T1, T1U}; struct softc { int unit; device_t dev; struct resource *irq; void *intrhand; enum framing framing; int nhooks; void *m0v, *m1v; vm_offset_t m0p, m1p; struct m32xreg *m32x; struct f54wreg *f54w; struct f54rreg *f54r; struct m32_mem m32_mem; u_int32_t tiqb[NIQB]; u_int32_t riqb[NIQB]; u_int32_t piqb[NIQB]; u_int32_t ltiqb[NIQB]; u_int32_t lriqb[NIQB]; char name[8]; u_int32_t falc_irq, falc_state, framer_state; struct schan *ch[M32_CHAN]; char nodename[NG_NODESIZ]; node_p node; u_long cnt_fec; u_long cnt_cvc; u_long cnt_cec1; u_long cnt_ebc; u_long cnt_cec2; u_long cnt_cec3; u_long cnt_rbc; }; static int ngmn_constructor(node_p *nodep) { return (EINVAL); } static int ngmn_shutdown(node_p nodep) { return (EINVAL); } static void ngmn_config(node_p node, char *set, char *ret) { struct softc *sc; enum framing wframing; sc = node->private; if (set != NULL) { if (!strncmp(set, "line ", 5)) { wframing = sc->framing; if (!strcmp(set, "line e1")) { wframing = E1; } else if (!strcmp(set, "line e1u")) { wframing = E1U; } else { strcat(ret, "ENOGROK\n"); return; } if (wframing == sc->framing) return; if (sc->nhooks > 0) { ksprintf(ret, "Cannot change line when %d hooks open\n", sc->nhooks); return; } sc->framing = wframing; #if 1 f54_init(sc); #else mn_reset(sc); #endif } else { kprintf("%s CONFIG SET [%s]\n", sc->nodename, set); strcat(ret, "ENOGROK\n"); return; } } } static int ngmn_rcvmsg(node_p node, struct ng_mesg *msg, const char *retaddr, struct ng_mesg **resp) { struct softc *sc; struct schan *sch; char *s, *r; int pos, i; sc = node->private; if (msg->header.typecookie != NGM_GENERIC_COOKIE) { if (resp != NULL) *resp = NULL; kfree(msg, M_NETGRAPH); return (EINVAL); } if (msg->header.cmd != NGM_TEXT_CONFIG && msg->header.cmd != NGM_TEXT_STATUS) { if (resp != NULL) *resp = NULL; kfree(msg, M_NETGRAPH); return (EINVAL); } NG_MKRESPONSE(*resp, msg, sizeof(struct ng_mesg) + NG_TEXTRESPONSE, M_INTWAIT); if (*resp == NULL) { kfree(msg, M_NETGRAPH); return (ENOMEM); } if (msg->header.arglen) s = (char *)msg->data; else s = NULL; r = (char *)(*resp)->data; *r = '\0'; if (msg->header.cmd == NGM_TEXT_CONFIG) { ngmn_config(node, s, r); (*resp)->header.arglen = strlen(r) + 1; kfree(msg, M_NETGRAPH); return (0); } pos = 0; pos += ksprintf(pos + r,"Framer status %pb%i;\n", "\20" "\40LOS\37AIS\36LFA\35RRA" "\34AUXP\33NMF\32LMFA\31frs0.0" "\30frs1.7\27TS16RA\26TS16LOS\25TS16AIS" "\24TS16LFA\23frs1.2\22XLS\21XLO" "\20RS1\17rsw.6\16RRA\15RY0" "\14RY1\13RY2\12RY3\11RY4" "\10SI1\7SI2\6rsp.5\5rsp.4" "\4rsp.3\3RSIF\2RS13\1RS15", sc->framer_state); pos += ksprintf(pos + r," Framing errors: %lu", sc->cnt_fec); pos += ksprintf(pos + r," Code Violations: %lu\n", sc->cnt_cvc); pos += ksprintf(pos + r," Falc State %pb%i;\n", "\20" "\40LOS\37AIS\36LFA\35RRA" "\34AUXP\33NMF\32LMFA\31frs0.0" "\30frs1.7\27TS16RA\26TS16LOS\25TS16AIS" "\24TS16LFA\23frs1.2\22XLS\21XLO" "\20RS1\17rsw.6\16RRA\15RY0" "\14RY1\13RY2\12RY3\11RY4" "\10SI1\7SI2\6rsp.5\5rsp.4" "\4rsp.3\3RSIF\2RS13\1RS15", sc->falc_state); pos += ksprintf(pos + r, " Falc IRQ %pb%i\n", "\20" "\40RME\37RFS\36T8MS\35RMB\34CASC\33CRC4\32SA6SC\31RPF" "\30b27\27RDO\26ALLS\25XDU\24XMB\23b22\22XLSC\21XPR" "\20FAR\17LFA\16MFAR\15T400MS\14AIS\13LOS\12RAR\11RA" "\10ES\7SEC\6LMFA16\5AIS16\4RA16\3API\2SLN\1SLP", sc->falc_irq); for (i = 0; i < M32_CHAN; i++) { if (!sc->ch[i]) continue; sch = sc->ch[i]; pos += ksprintf(r + pos, " Chan %d <%s> ", i, sch->hook->name); pos += ksprintf(r + pos, " Last Rx: "); if (sch->last_recv) pos += ksprintf(r + pos, "%lu s", time_uptime - sch->last_recv); else pos += ksprintf(r + pos, "never"); pos += ksprintf(r + pos, ", last RxErr: "); if (sch->last_rxerr) pos += ksprintf(r + pos, "%lu s", time_uptime - sch->last_rxerr); else pos += ksprintf(r + pos, "never"); pos += ksprintf(r + pos, ", last Tx: "); if (sch->last_xmit) pos += ksprintf(r + pos, "%lu s\n", time_uptime - sch->last_xmit); else pos += ksprintf(r + pos, "never\n"); pos += ksprintf(r + pos, " RX error(s) %lu", sch->rx_error); pos += ksprintf(r + pos, " Short: %lu", sch->short_error); pos += ksprintf(r + pos, " CRC: %lu", sch->crc_error); pos += ksprintf(r + pos, " Mod8: %lu", sch->dribble_error); pos += ksprintf(r + pos, " Long: %lu", sch->long_error); pos += ksprintf(r + pos, " Abort: %lu", sch->abort_error); pos += ksprintf(r + pos, " Overflow: %lu\n", sch->overflow_error); pos += ksprintf(r + pos, " Last error: %pb%i Prev error: %pb%i\n", "\20\7SHORT\5CRC\4MOD8\3LONG\2ABORT\1OVERRUN", sch->last_error, "\20\7SHORT\5CRC\4MOD8\3LONG\2ABORT\1OVERRUN", sch->prev_error); pos += ksprintf(r + pos, " Xmit bytes pending %ld\n", sch->tx_pending); } (*resp)->header.arglen = pos + 1; kfree(msg, M_NETGRAPH); return (0); } static int ngmn_newhook(node_p node, hook_p hook, const char *name) { u_int32_t ts, chan; struct softc *sc; int nbit; sc = node->private; if (name[0] != 't' || name[1] != 's') return (EINVAL); ts = mn_parse_ts(name + 2, &nbit); kprintf("%d bits %x\n", nbit, ts); if (sc->framing == E1 && (ts & 1)) return (EINVAL); if (sc->framing == E1U && nbit != 32) return (EINVAL); if (ts == 0) return (EINVAL); if (sc->framing == E1) chan = ffs(ts) - 1; else chan = 1; if (!sc->ch[chan]) mn_create_channel(sc, chan); else if (sc->ch[chan]->state == UP) return (EBUSY); sc->ch[chan]->ts = ts; sc->ch[chan]->hook = hook; sc->ch[chan]->tx_limit = nbit * 8; hook->private = sc->ch[chan]; sc->nhooks++; return(0); } static struct trxd *mn_desc_free; static struct trxd * mn_alloc_desc(void) { struct trxd *dp; dp = mn_desc_free; if (dp) mn_desc_free = dp->vnext; else dp = (struct trxd *)kmalloc(sizeof *dp, M_MN, M_INTWAIT); return (dp); } static void mn_free_desc(struct trxd *dp) { dp->vnext = mn_desc_free; mn_desc_free = dp; } static u_int32_t mn_parse_ts(const char *s, int *nbit) { unsigned r; int i, j; char *p; r = 0; j = -1; *nbit = 0; while(*s) { i = strtol(s, &p, 0); if (i < 0 || i > 31) return (0); while (j != -1 && j < i) { r |= 1 << j++; (*nbit)++; } j = -1; r |= 1 << i; (*nbit)++; if (*p == ',') { s = p + 1; continue; } else if (*p == '-') { j = i + 1; s = p + 1; continue; } else if (!*p) { break; } else { return (0); } } return (r); } #ifdef notyet static void mn_fmt_ts(char *p, u_int32_t ts) { char *s; int j; s = ""; ts &= 0xffffffff; for (j = 0; j < 32; j++) { if (!(ts & (1 << j))) continue; ksprintf(p, "%s%d", s, j); p += strlen(p); s = ","; if (!(ts & (1 << (j+1)))) continue; for (; j < 32; j++) if (!(ts & (1 << (j+1)))) break; ksprintf(p, "-%d", j); p += strlen(p); s = ","; } } #endif /* notyet */ /* * OUTPUT */ static int ngmn_rcvdata(hook_p hook, struct mbuf *m, meta_p meta) { struct mbuf *m2; struct trxd *dp, *dp2; struct schan *sch; struct softc *sc; int chan, pitch, len; sch = hook->private; sc = sch->sc; chan = sch->chan; if (sch->state != UP) { NG_FREE_DATA(m, meta); return (0); } if (sch->tx_pending + m->m_pkthdr.len > sch->tx_limit * mn_maxlatency) { NG_FREE_DATA(m, meta); return (0); } NG_FREE_META(meta); pitch = 0; m2 = m; dp2 = sc->ch[chan]->xl; len = m->m_pkthdr.len; while (len) { dp = mn_alloc_desc(); if (!dp) { pitch++; m_freem(m); sc->ch[chan]->xl = dp2; dp = dp2->vnext; while (dp) { dp2 = dp->vnext; mn_free_desc(dp); dp = dp2; } sc->ch[chan]->xl->vnext = NULL; break; } dp->data = vtophys(m2->m_data); dp->flags = m2->m_len << 16; dp->flags += 1; len -= m2->m_len; dp->next = vtophys(dp); dp->vnext = NULL; sc->ch[chan]->xl->next = vtophys(dp); sc->ch[chan]->xl->vnext = dp; sc->ch[chan]->xl = dp; if (!len) { dp->m = m; dp->flags |= 0xc0000000; dp2->flags &= ~0x40000000; } else { dp->m = NULL; m2 = m2->m_next; } } if (pitch) kprintf("%s%d: Short on mem, pitched %d packets\n", sc->name, chan, pitch); else { #if 0 kprintf("%d = %d + %d (%p)\n", sch->tx_pending + m->m_pkthdr.len, sch->tx_pending , m->m_pkthdr.len, m); #endif sch->tx_pending += m->m_pkthdr.len; sc->m32x->txpoll &= ~(1 << chan); } return (0); } /* * OPEN */ static int ngmn_connect(hook_p hook) { int i, nts, chan; struct trxd *dp, *dp2; struct mbuf *m; struct softc *sc; struct schan *sch; u_int32_t u; sch = hook->private; chan = sch->chan; sc = sch->sc; if (sch->state == UP) return (0); sch->state = UP; /* Count and configure the timeslots for this channel */ for (nts = i = 0; i < 32; i++) if (sch->ts & (1 << i)) { sc->m32_mem.ts[i] = 0x00ff00ff | (chan << 24) | (chan << 8); nts++; } /* Init the receiver & xmitter to HDLC */ sc->m32_mem.cs[chan].flags = 0x80e90006; /* Allocate two buffers per timeslot */ if (nts == 32) sc->m32_mem.cs[chan].itbs = 63; else sc->m32_mem.cs[chan].itbs = nts * 2; /* Setup a transmit chain with one descriptor */ /* XXX: we actually send a 1 byte packet */ dp = mn_alloc_desc(); MGETHDR(m, M_WAITOK, MT_DATA); m->m_pkthdr.len = 0; dp->m = m; dp->flags = 0xc0000000 + (1 << 16); dp->next = vtophys(dp); dp->vnext = NULL; dp->data = vtophys(sc->name); sc->m32_mem.cs[chan].tdesc = vtophys(dp); sc->ch[chan]->x1 = dp; sc->ch[chan]->xl = dp; /* Setup a receive chain with 5 + NTS descriptors */ dp = mn_alloc_desc(); m = NULL; MGETHDR(m, M_WAITOK, MT_DATA); MCLGET(m, M_WAITOK); dp->m = m; dp->data = vtophys(m->m_data); dp->flags = 0x40000000; dp->flags += 1600 << 16; dp->next = vtophys(dp); dp->vnext = NULL; sc->ch[chan]->rl = dp; for (i = 0; i < (nts + 10); i++) { dp2 = dp; dp = mn_alloc_desc(); m = NULL; MGETHDR(m, M_WAITOK, MT_DATA); MCLGET(m, M_WAITOK); dp->m = m; dp->data = vtophys(m->m_data); dp->flags = 0x00000000; dp->flags += 1600 << 16; dp->next = vtophys(dp2); dp->vnext = dp2; } sc->m32_mem.cs[chan].rdesc = vtophys(dp); sc->ch[chan]->r1 = dp; /* Initialize this channel */ sc->m32_mem.ccb = 0x00008000 + (chan << 8); sc->m32x->cmd = 0x1; DELAY(1000); u = sc->m32x->stat; if (!(u & 1)) kprintf("%s: init chan %d stat %08x\n", sc->name, chan, u); sc->m32x->stat = 1; return (0); } /* * CLOSE */ static int ngmn_disconnect(hook_p hook) { int chan, i; struct softc *sc; struct schan *sch; struct trxd *dp, *dp2; u_int32_t u; sch = hook->private; chan = sch->chan; sc = sch->sc; if (sch->state == DOWN) return (0); sch->state = DOWN; /* Set receiver & transmitter off */ sc->m32_mem.cs[chan].flags = 0x80920006; sc->m32_mem.cs[chan].itbs = 0; /* free the timeslots */ for (i = 0; i < 32; i++) if (sc->ch[chan]->ts & (1 << i)) sc->m32_mem.ts[i] = 0x20002000; /* Initialize this channel */ sc->m32_mem.ccb = 0x00008000 + (chan << 8); sc->m32x->cmd = 0x1; DELAY(30); u = sc->m32x->stat; if (!(u & 1)) kprintf("%s: zap chan %d stat %08x\n", sc->name, chan, u); sc->m32x->stat = 1; /* Free all receive descriptors and mbufs */ for (dp = sc->ch[chan]->r1; dp ; dp = dp2) { if (dp->m) m_freem(dp->m); sc->ch[chan]->r1 = dp2 = dp->vnext; mn_free_desc(dp); } /* Free all transmit descriptors and mbufs */ for (dp = sc->ch[chan]->x1; dp ; dp = dp2) { if (dp->m) { sc->ch[chan]->tx_pending -= dp->m->m_pkthdr.len; m_freem(dp->m); } sc->ch[chan]->x1 = dp2 = dp->vnext; mn_free_desc(dp); } sc->nhooks--; return(0); } /* * Create a new channel. */ static void mn_create_channel(struct softc *sc, int chan) { struct schan *sch; sch = sc->ch[chan] = (struct schan *)kmalloc(sizeof *sc->ch[chan], M_MN, M_WAITOK | M_ZERO); sch->sc = sc; sch->state = DOWN; sch->chan = chan; ksprintf(sch->name, "%s%d", sc->name, chan); return; } #ifdef notyet /* * Dump Munich32x state */ static void m32_dump(struct softc *sc) { u_int32_t *tp4; int i, j; kprintf("mn%d: MUNICH32X dump\n", sc->unit); tp4 = (u_int32_t *)sc->m0v; for(j = 0; j < 64; j += 8) { kprintf("%02x", j * sizeof *tp4); for(i = 0; i < 8; i++) kprintf(" %08x", tp4[i+j]); kprintf("\n"); } for(j = 0; j < M32_CHAN; j++) { if (!sc->ch[j]) continue; kprintf("CH%d: state %d ts %08x", j, sc->ch[j]->state, sc->ch[j]->ts); kprintf(" %08x %08x %08x %08x %08x %08x\n", sc->m32_mem.cs[j].flags, sc->m32_mem.cs[j].rdesc, sc->m32_mem.cs[j].tdesc, sc->m32_mem.cs[j].itbs, sc->m32_mem.crxd[j], sc->m32_mem.ctxd[j] ); } } /* * Dump Falch54 state */ static void f54_dump(struct softc *sc) { u_int8_t *tp1; int i, j; kprintf("%s: FALC54 dump\n", sc->name); tp1 = (u_int8_t *)sc->m1v; for(j = 0; j < 128; j += 16) { kprintf("%s: %02x |", sc->name, j * sizeof *tp1); for(i = 0; i < 16; i++) kprintf(" %02x", tp1[i+j]); kprintf("\n"); } } #endif /* notyet */ /* * Init Munich32x */ static void m32_init(struct softc *sc) { sc->m32x->conf = 0x00000000; sc->m32x->mode1 = 0x81048000 + 1600; /* XXX: temp */ #if 1 sc->m32x->mode2 = 0x00000081; sc->m32x->txpoll = 0xffffffff; #elif 1 sc->m32x->mode2 = 0x00000081; sc->m32x->txpoll = 0xffffffff; #else sc->m32x->mode2 = 0x00000101; #endif sc->m32x->lconf = 0x6060009B; sc->m32x->imask = 0x00000000; } /* * Init the Falc54 */ static void f54_init(struct softc *sc) { sc->f54w->ipc = 0x07; sc->f54w->xpm0 = 0xbd; sc->f54w->xpm1 = 0x03; sc->f54w->xpm2 = 0x00; sc->f54w->imr0 = 0x18; /* RMB, CASC */ sc->f54w->imr1 = 0x08; /* XMB */ sc->f54w->imr2 = 0x00; sc->f54w->imr3 = 0x38; /* LMFA16, AIS16, RA16 */ sc->f54w->imr4 = 0x00; sc->f54w->fmr0 = 0xf0; /* X: HDB3, R: HDB3 */ sc->f54w->fmr1 = 0x0e; /* Send CRC4, 2Mbit, ECM */ if (sc->framing == E1) sc->f54w->fmr2 = 0x03; /* Auto Rem-Alarm, Auto resync */ else if (sc->framing == E1U) sc->f54w->fmr2 = 0x33; /* dais, rtm, Auto Rem-Alarm, Auto resync */ sc->f54w->lim1 = 0xb0; /* XCLK=8kHz, .62V threshold */ sc->f54w->pcd = 0x0a; sc->f54w->pcr = 0x15; sc->f54w->xsw = 0x9f; /* fmr4 */ if (sc->framing == E1) sc->f54w->xsp = 0x1c; /* fmr5 */ else if (sc->framing == E1U) sc->f54w->xsp = 0x3c; /* tt0, fmr5 */ sc->f54w->xc0 = 0x07; sc->f54w->xc1 = 0x3d; sc->f54w->rc0 = 0x05; sc->f54w->rc1 = 0x00; sc->f54w->cmdr = 0x51; } static int mn_reset(struct softc *sc) { u_int32_t u; int i; sc->m32x->ccba = vtophys(&sc->m32_mem.csa); sc->m32_mem.csa = vtophys(&sc->m32_mem.ccb); bzero(sc->tiqb, sizeof sc->tiqb); sc->m32x->tiqba = vtophys(&sc->tiqb); sc->m32x->tiql = NIQB / 16 - 1; bzero(sc->riqb, sizeof sc->riqb); sc->m32x->riqba = vtophys(&sc->riqb); sc->m32x->riql = NIQB / 16 - 1; bzero(sc->ltiqb, sizeof sc->ltiqb); sc->m32x->ltiqba = vtophys(&sc->ltiqb); sc->m32x->ltiql = NIQB / 16 - 1; bzero(sc->lriqb, sizeof sc->lriqb); sc->m32x->lriqba = vtophys(&sc->lriqb); sc->m32x->lriql = NIQB / 16 - 1; bzero(sc->piqb, sizeof sc->piqb); sc->m32x->piqba = vtophys(&sc->piqb); sc->m32x->piql = NIQB / 16 - 1; m32_init(sc); f54_init(sc); u = sc->m32x->stat; sc->m32x->stat = u; sc->m32_mem.ccb = 0x4; sc->m32x->cmd = 0x1; DELAY(1000); u = sc->m32x->stat; sc->m32x->stat = u; /* set all timeslots to known state */ for (i = 0; i < 32; i++) sc->m32_mem.ts[i] = 0x20002000; if (!(u & 1)) { kprintf( "mn%d: WARNING: Controller failed the PCI bus-master test.\n" "mn%d: WARNING: Use a PCI slot which can support bus-master cards.\n", sc->unit, sc->unit); return (0); } return (1); } /* * FALC54 interrupt handling */ static void f54_intr(struct softc *sc) { unsigned u, s; #if 0 unsigned g; g = sc->f54r->gis; #endif u = sc->f54r->isr0 << 24; u |= sc->f54r->isr1 << 16; u |= sc->f54r->isr2 << 8; u |= sc->f54r->isr3; sc->falc_irq = u; /* don't chat about the 1 sec heart beat */ if (u & ~0x40) { #if 0 kprintf("%s*: FALC54 IRQ GIS:%02x %pb%i\n", sc->name, g, "\20" "\40RME\37RFS\36T8MS\35RMB\34CASC\33CRC4\32SA6SC\31RPF" "\30b27\27RDO\26ALLS\25XDU\24XMB\23b22\22XLSC\21XPR" "\20FAR\17LFA\16MFAR\15T400MS\14AIS\13LOS\12RAR\11RA" "\10ES\7SEC\6LMFA16\5AIS16\4RA16\3API\2SLN\1SLP", u); #endif s = sc->f54r->frs0 << 24; s |= sc->f54r->frs1 << 16; s |= sc->f54r->rsw << 8; s |= sc->f54r->rsp; sc->falc_state = s; s &= ~0x01844038; /* undefined or static bits */ s &= ~0x00009fc7; /* bits we don't care about */ s &= ~0x00780000; /* XXX: TS16 related */ s &= ~0x06000000; /* XXX: Multiframe related */ #if 0 kprintf("%s*: FALC54 Status %pb%i\n", sc->name, "\20" "\40LOS\37AIS\36LFA\35RRA\34AUXP\33NMF\32LMFA\31frs0.0" "\30frs1.7\27TS16RA\26TS16LOS\25TS16AIS\24TS16LFA\23frs1.2\22XLS\21XLO" "\20RS1\17rsw.6\16RRA\15RY0\14RY1\13RY2\12RY3\11RY4" "\10SI1\7SI2\6rsp.5\5rsp.4\4rsp.3\3RSIF\2RS13\1RS15", s); #endif if (s != sc->framer_state) { #if 0 for (i = 0; i < M32_CHAN; i++) { if (!sc->ch[i]) continue; sp = &sc->ch[i]->ifsppp; if (!(sp->pp_if.if_flags & IFF_UP)) continue; if (s) timeout((timeout_t *)sp->pp_down, sp, 1 * hz); else timeout((timeout_t *)sp->pp_up, sp, 1 * hz); } #endif sc->framer_state = s; } } /* Once per second check error counters */ /* XXX: not clear if this is actually ok */ if (!(u & 0x40)) return; sc->cnt_fec += sc->f54r->fec; sc->cnt_cvc += sc->f54r->cvc; sc->cnt_cec1 += sc->f54r->cec1; sc->cnt_ebc += sc->f54r->ebc; sc->cnt_cec2 += sc->f54r->cec2; sc->cnt_cec3 += sc->f54r->cec3; sc->cnt_rbc += sc->f54r->rbc; } /* * Transmit interrupt for one channel */ static void mn_tx_intr(struct softc *sc, u_int32_t vector) { u_int32_t chan; struct trxd *dp; struct mbuf *m; chan = vector & 0x1f; if (!sc->ch[chan]) return; if (sc->ch[chan]->state != UP) { kprintf("%s: tx_intr when not UP\n", sc->name); return; } for (;;) { dp = sc->ch[chan]->x1; if (vtophys(dp) == sc->m32_mem.ctxd[chan]) return; m = dp->m; if (m) { #if 0 kprintf("%d = %d - %d (%p)\n", sc->ch[chan]->tx_pending - m->m_pkthdr.len, sc->ch[chan]->tx_pending , m->m_pkthdr.len, m); #endif sc->ch[chan]->tx_pending -= m->m_pkthdr.len; m_freem(m); } sc->ch[chan]->last_xmit = time_uptime; sc->ch[chan]->x1 = dp->vnext; mn_free_desc(dp); } } /* * Receive interrupt for one channel */ static void mn_rx_intr(struct softc *sc, u_int32_t vector) { u_int32_t chan, err; struct trxd *dp; struct mbuf *m; struct schan *sch; chan = vector & 0x1f; if (!sc->ch[chan]) return; sch = sc->ch[chan]; if (sch->state != UP) { kprintf("%s: rx_intr when not UP\n", sc->name); return; } vector &= ~0x1f; if (vector == 0x30000b00) sch->rx_error++; for (;;) { dp = sch->r1; if (vtophys(dp) == sc->m32_mem.crxd[chan]) return; m = dp->m; dp->m = NULL; m->m_pkthdr.len = m->m_len = (dp->status >> 16) & 0x1fff; err = (dp->status >> 8) & 0xff; if (!err) { ng_queue_data(sch->hook, m, NULL); sch->last_recv = time_uptime; m = NULL; /* we could be down by now... */ if (sch->state != UP) return; } else if (err & 0x40) { sch->short_error++; } else if (err & 0x10) { sch->crc_error++; } else if (err & 0x08) { sch->dribble_error++; } else if (err & 0x04) { sch->long_error++; } else if (err & 0x02) { sch->abort_error++; } else if (err & 0x01) { sch->overflow_error++; } if (err) { sch->last_rxerr = time_uptime; sch->prev_error = sch->last_error; sch->last_error = err; } sc->ch[chan]->r1 = dp->vnext; /* Replenish desc + mbuf supplies */ if (!m) { MGETHDR(m, M_NOWAIT, MT_DATA); if (m == NULL) { mn_free_desc(dp); return; /* ENOBUFS */ } MCLGET(m, M_NOWAIT); if((m->m_flags & M_EXT) == 0) { mn_free_desc(dp); m_freem(m); return; /* ENOBUFS */ } } dp->m = m; dp->data = vtophys(m->m_data); dp->flags = 0x40000000; dp->flags += 1600 << 16; dp->next = vtophys(dp); dp->vnext = NULL; sc->ch[chan]->rl->next = vtophys(dp); sc->ch[chan]->rl->vnext = dp; sc->ch[chan]->rl->flags &= ~0x40000000; sc->ch[chan]->rl = dp; } } /* * Interupt handler */ static void mn_intr(void *xsc) { struct softc *sc; u_int32_t stat, lstat, u; int i, j; sc = xsc; stat = sc->m32x->stat; lstat = sc->m32x->lstat; #if 0 if (!stat && !(lstat & 2)) return; #endif if (stat & ~0xc200) { kprintf("%s: I stat=%08x lstat=%08x\n", sc->name, stat, lstat); } if ((stat & 0x200) || (lstat & 2)) f54_intr(sc); for (j = i = 0; i < 64; i ++) { u = sc->riqb[i]; if (u) { sc->riqb[i] = 0; mn_rx_intr(sc, u); if ((u & ~0x1f) == 0x30000800 || (u & ~0x1f) == 0x30000b00) continue; u &= ~0x30000400; /* bits we don't care about */ if ((u & ~0x1f) == 0x00000900) continue; if (!(u & ~0x1f)) continue; if (!j) kprintf("%s*: RIQB:", sc->name); kprintf(" [%d]=%08x", i, u); j++; } } if (j) kprintf("\n"); for (j = i = 0; i < 64; i ++) { u = sc->tiqb[i]; if (u) { sc->tiqb[i] = 0; mn_tx_intr(sc, u); if ((u & ~0x1f) == 0x20000800) continue; u &= ~0x20000000; /* bits we don't care about */ if (!u) continue; if (!j) kprintf("%s*: TIQB:", sc->name); kprintf(" [%d]=%08x", i, u); j++; } } if (j) kprintf("\n"); sc->m32x->stat = stat; } /* * PCI initialization stuff */ static int mn_probe (device_t self) { u_int id = pci_get_devid(self); if (sizeof (struct m32xreg) != 256) { kprintf("MN: sizeof(struct m32xreg) = %zd, should have been 256\n", sizeof (struct m32xreg)); return (ENXIO); } if (sizeof (struct f54rreg) != 128) { kprintf("MN: sizeof(struct f54rreg) = %zd, should have been 128\n", sizeof (struct f54rreg)); return (ENXIO); } if (sizeof (struct f54wreg) != 128) { kprintf("MN: sizeof(struct f54wreg) = %zd, should have been 128\n", sizeof (struct f54wreg)); return (ENXIO); } if (id != 0x2101110a) return (ENXIO); device_set_desc_copy(self, "Munich32X E1/T1 HDLC Controller"); return (0); } static int mn_attach (device_t self) { struct softc *sc; u_int32_t u; u_int32_t ver; static int once; int rid, error; struct resource *res; if (!once) { if (ng_newtype(&mntypestruct)) kprintf("ng_newtype failed\n"); once++; } sc = (struct softc *)kmalloc(sizeof *sc, M_MN, M_WAITOK | M_ZERO); device_set_softc(self, sc); sc->dev = self; sc->unit = device_get_unit(self); sc->framing = E1; ksprintf(sc->name, "mn%d", sc->unit); rid = PCIR_MAPS; res = bus_alloc_resource_any(self, SYS_RES_MEMORY, &rid, RF_ACTIVE); if (res == NULL) { device_printf(self, "Could not map memory\n"); return ENXIO; } sc->m0v = rman_get_virtual(res); sc->m0p = rman_get_start(res); rid = PCIR_MAPS + 4; res = bus_alloc_resource_any(self, SYS_RES_MEMORY, &rid, RF_ACTIVE); if (res == NULL) { device_printf(self, "Could not map memory\n"); return ENXIO; } sc->m1v = rman_get_virtual(res); sc->m1p = rman_get_start(res); /* Allocate interrupt */ rid = 0; sc->irq = bus_alloc_resource_any(self, SYS_RES_IRQ, &rid, RF_SHAREABLE | RF_ACTIVE); if (sc->irq == NULL) { kprintf("couldn't map interrupt\n"); return(ENXIO); } error = bus_setup_intr(self, sc->irq, INTR_MPSAFE, mn_intr, sc, &sc->intrhand, NULL); if (error) { kprintf("couldn't set up irq\n"); return(ENXIO); } u = pci_read_config(self, PCIR_COMMAND, 1); kprintf("%x\n", u); pci_write_config(self, PCIR_COMMAND, u | PCIM_CMD_PERRESPEN | PCIM_CMD_BUSMASTEREN | PCIM_CMD_MEMEN, 1); #if 0 pci_write_config(self, PCIR_COMMAND, 0x02800046, 4); #endif u = pci_read_config(self, PCIR_COMMAND, 1); kprintf("%x\n", u); ver = pci_get_revid(self); sc->m32x = (struct m32xreg *) sc->m0v; sc->f54w = (struct f54wreg *) sc->m1v; sc->f54r = (struct f54rreg *) sc->m1v; /* We must reset before poking at FALC54 registers */ u = mn_reset(sc); if (!u) return (0); kprintf("mn%d: Munich32X", sc->unit); switch (ver) { case 0x13: kprintf(" Rev 2.2"); break; default: kprintf(" Rev 0x%x\n", ver); } kprintf(", Falc54"); switch (sc->f54r->vstr) { case 0: kprintf(" Rev < 1.3\n"); break; case 1: kprintf(" Rev 1.3\n"); break; case 2: kprintf(" Rev 1.4\n"); break; case 0x10: kprintf("-LH Rev 1.1\n"); break; case 0x13: kprintf("-LH Rev 1.3\n"); break; default: kprintf(" Rev 0x%x\n", sc->f54r->vstr); } if (ng_make_node_common(&mntypestruct, &sc->node) != 0) { kprintf("ng_make_node_common failed\n"); return (0); } sc->node->private = sc; ksprintf(sc->nodename, "%s%d", NG_MN_NODE_TYPE, sc->unit); if (ng_name_node(sc->node, sc->nodename)) { ng_rmnode(sc->node); ng_unref(sc->node); return (0); } return (0); } static device_method_t mn_methods[] = { /* Device interface */ DEVMETHOD(device_probe, mn_probe), DEVMETHOD(device_attach, mn_attach), DEVMETHOD(device_suspend, bus_generic_suspend), DEVMETHOD(device_resume, bus_generic_resume), DEVMETHOD(device_shutdown, bus_generic_shutdown), DEVMETHOD_END }; static driver_t mn_driver = { "mn", mn_methods, 0 }; static devclass_t mn_devclass; DECLARE_DUMMY_MODULE(if_mn); DRIVER_MODULE(if_mn, pci, mn_driver, mn_devclass, NULL, NULL);