/* $OpenBSD: musycc.c,v 1.19 2008/09/18 09:06:27 chl Exp $ */ /* * Copyright (c) 2004,2005 Internet Business Solutions AG, Zurich, Switzerland * Written by: Claudio Jeker * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include "bpfilter.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if NBPFILTER > 0 #include #endif #include #include int musycc_alloc_groupdesc(struct musycc_softc *); int musycc_alloc_intqueue(struct musycc_softc *); int musycc_alloc_group(struct musycc_group *); void musycc_free_groupdesc(struct musycc_softc *); void musycc_free_intqueue(struct musycc_softc *); void musycc_free_dmadesc(struct musycc_group *); void musycc_free_group(struct musycc_group *); void musycc_set_group(struct musycc_group *, int, int, int); int musycc_set_tsmap(struct musycc_group *, struct channel_softc *, char); int musycc_set_chandesc(struct musycc_group *, int, int, int); void musycc_activate_channel(struct musycc_group *, int); void musycc_state_engine(struct musycc_group *, int, enum musycc_event); struct dma_desc *musycc_dma_get(struct musycc_group *); void musycc_dma_free(struct musycc_group *, struct dma_desc *); int musycc_list_tx_init(struct musycc_group *, int, int); int musycc_list_rx_init(struct musycc_group *, int, int); void musycc_list_tx_free(struct musycc_group *, int); void musycc_list_rx_free(struct musycc_group *, int); void musycc_reinit_dma(struct musycc_group *, int); int musycc_newbuf(struct musycc_group *, struct dma_desc *, struct mbuf *); int musycc_encap(struct musycc_group *, struct mbuf *, int); void musycc_rxeom(struct musycc_group *, int, int); void musycc_txeom(struct musycc_group *, int, int); void musycc_kick(struct musycc_group *); void musycc_sreq(struct musycc_group *, int, u_int32_t, int, enum musycc_event); #ifndef ACCOOM_DEBUG #define musycc_dump_group(n, x) #define musycc_dump_desc(n, x) #define musycc_dump_dma(n, x, y) #else int accoom_debug = 0; char *musycc_intr_print(u_int32_t); void musycc_dump_group(int, struct musycc_group *); void musycc_dump_desc(int, struct musycc_group *); void musycc_dump_dma(int, struct musycc_group *, int); #endif int musycc_attach_common(struct musycc_softc *sc, u_int32_t portmap, u_int32_t mode) { struct musycc_group *mg; int i, j; if (musycc_alloc_groupdesc(sc) == -1) { printf(": couldn't alloc group descriptors\n"); return (-1); } if (musycc_alloc_intqueue(sc) == -1) { printf(": couldn't alloc interrupt queue\n"); musycc_free_groupdesc(sc); return (-1); } /* * global configuration: set EBUS to sane defaults: * intel mode, elapse = 3, blapse = 3, alapse = 3 * XXX XXX disable INTB for now */ sc->mc_global_conf = (portmap & MUSYCC_CONF_PORTMAP) | MUSYCC_CONF_MPUSEL | MUSYCC_CONF_ECKEN | MUSYCC_CONF_ELAPSE_SET(3) | MUSYCC_CONF_ALAPSE_SET(3) | MUSYCC_CONF_BLAPSE_SET(3) | MUSYCC_CONF_INTB; /* initialize group descriptors */ sc->mc_groups = malloc(sc->mc_ngroups * sizeof(struct musycc_group), M_DEVBUF, M_NOWAIT | M_ZERO); if (sc->mc_groups == NULL) { printf(": couldn't alloc group descriptors\n"); musycc_free_groupdesc(sc); musycc_free_intqueue(sc); return (-1); } for (i = 0; i < sc->mc_ngroups; i++) { mg = &sc->mc_groups[i]; mg->mg_hdlc = sc; mg->mg_gnum = i; mg->mg_port = i >> (portmap & MUSYCC_CONF_PORTMAP); mg->mg_dmat = sc->mc_dmat; if (musycc_alloc_group(mg) == -1) { printf(": couldn't alloc group structures\n"); for (j = 0; j < i; j++) musycc_free_group(&sc->mc_groups[j]); musycc_free_groupdesc(sc); musycc_free_intqueue(sc); return (-1); } mg->mg_group = (struct musycc_grpdesc *) (sc->mc_groupkva + MUSYCC_GROUPBASE(i)); bzero(mg->mg_group, sizeof(struct musycc_grpdesc)); musycc_set_group(mg, MUSYCC_GRCFG_POLL32, MUSYCC_MAXFRM_MAX, MUSYCC_MAXFRM_MAX); musycc_set_port(mg, mode); bus_dmamap_sync(sc->mc_dmat, sc->mc_cfgmap, MUSYCC_GROUPBASE(i), sizeof(struct musycc_grpdesc), BUS_DMASYNC_PREWRITE); bus_space_write_4(sc->mc_st, sc->mc_sh, MUSYCC_GROUPBASE(i), sc->mc_cfgmap->dm_segs[0].ds_addr + MUSYCC_GROUPBASE(i)); } /* Dual Address Cycle Base Pointer */ bus_space_write_4(sc->mc_st, sc->mc_sh, MUSYCC_DACB_PTR, 0); /* Global Configuration Descriptor */ bus_space_write_4(sc->mc_st, sc->mc_sh, MUSYCC_GLOBALCONF, sc->mc_global_conf); /* Interrupt Queue Descriptor */ bus_space_write_4(sc->mc_st, sc->mc_sh, MUSYCC_INTQPTR, sc->mc_intrqptr); /* * Interrupt Queue Length. * NOTE: a value of 1 indicates a queue length of 2 descriptors! */ bus_space_write_4(sc->mc_st, sc->mc_sh, MUSYCC_INTQLEN, MUSYCC_INTLEN - 1); /* Configure groups, needs to be done only once per group */ for (i = 0; i < sc->mc_ngroups; i++) { mg = &sc->mc_groups[i]; musycc_sreq(mg, 0, MUSYCC_SREQ_SET(5), MUSYCC_SREQ_BOTH, EV_NULL); mg->mg_loaded = 1; } return (0); } int musycc_alloc_groupdesc(struct musycc_softc *sc) { /* * Allocate per group/port shared memory. * One big cunck of nports * 2048 bytes is allocated. This is * done to ensure that all group structures are 2048 bytes aligned. */ if (bus_dmamem_alloc(sc->mc_dmat, sc->mc_ngroups * 2048, 2048, 0, sc->mc_cfgseg, 1, &sc->mc_cfgnseg, BUS_DMA_NOWAIT)) { return (-1); } if (bus_dmamem_map(sc->mc_dmat, sc->mc_cfgseg, sc->mc_cfgnseg, sc->mc_ngroups * 2048, &sc->mc_groupkva, BUS_DMA_NOWAIT)) { bus_dmamem_free(sc->mc_dmat, sc->mc_cfgseg, sc->mc_cfgnseg); return (-1); } /* create and load bus dma segment, one for all ports */ if (bus_dmamap_create(sc->mc_dmat, sc->mc_ngroups * 2048, 1, sc->mc_ngroups * 2048, 0, BUS_DMA_NOWAIT, &sc->mc_cfgmap)) { bus_dmamem_unmap(sc->mc_dmat, sc->mc_groupkva, sc->mc_ngroups * 2048); bus_dmamem_free(sc->mc_dmat, sc->mc_cfgseg, sc->mc_cfgnseg); return (-1); } if (bus_dmamap_load(sc->mc_dmat, sc->mc_cfgmap, sc->mc_groupkva, sc->mc_ngroups * 2048, NULL, BUS_DMA_NOWAIT)) { musycc_free_groupdesc(sc); return (-1); } return (0); } int musycc_alloc_intqueue(struct musycc_softc *sc) { /* * allocate interrupt queue, use one page for the queue */ if (bus_dmamem_alloc(sc->mc_dmat, sizeof(struct musycc_intdesc), 4, 0, sc->mc_intrseg, 1, &sc->mc_intrnseg, BUS_DMA_NOWAIT)) { return (-1); } if (bus_dmamem_map(sc->mc_dmat, sc->mc_intrseg, sc->mc_intrnseg, sizeof(struct musycc_intdesc), (caddr_t *)&sc->mc_intrd, BUS_DMA_NOWAIT)) { bus_dmamem_free(sc->mc_dmat, sc->mc_intrseg, sc->mc_intrnseg); return (-1); } /* create and load bus dma segment */ if (bus_dmamap_create(sc->mc_dmat, sizeof(struct musycc_intdesc), 1, sizeof(struct musycc_intdesc), 0, BUS_DMA_NOWAIT, &sc->mc_intrmap)) { bus_dmamem_unmap(sc->mc_dmat, (caddr_t)sc->mc_intrd, sizeof(struct musycc_intdesc)); bus_dmamem_free(sc->mc_dmat, sc->mc_intrseg, sc->mc_intrnseg); return (-1); } if (bus_dmamap_load(sc->mc_dmat, sc->mc_intrmap, sc->mc_intrd, sizeof(struct musycc_intdesc), NULL, BUS_DMA_NOWAIT)) { musycc_free_intqueue(sc); return (-1); } /* initialize the interrupt queue pointer */ sc->mc_intrqptr = sc->mc_intrmap->dm_segs[0].ds_addr + offsetof(struct musycc_intdesc, md_intrq[0]); return (0); } int musycc_alloc_group(struct musycc_group *mg) { struct dma_desc *dd; int j; /* Allocate per group dma memory */ if (bus_dmamem_alloc(mg->mg_dmat, MUSYCC_DMA_MAPSIZE, PAGE_SIZE, 0, mg->mg_listseg, 1, &mg->mg_listnseg, BUS_DMA_NOWAIT)) return (-1); if (bus_dmamem_map(mg->mg_dmat, mg->mg_listseg, mg->mg_listnseg, MUSYCC_DMA_MAPSIZE, &mg->mg_listkva, BUS_DMA_NOWAIT)) { bus_dmamem_free(mg->mg_dmat, mg->mg_listseg, mg->mg_listnseg); return (-1); } /* create and load bus dma segment */ if (bus_dmamap_create(mg->mg_dmat, MUSYCC_DMA_MAPSIZE, 1, MUSYCC_DMA_MAPSIZE, 0, BUS_DMA_NOWAIT, &mg->mg_listmap)) { bus_dmamem_unmap(mg->mg_dmat, mg->mg_listkva, MUSYCC_DMA_MAPSIZE); bus_dmamem_free(mg->mg_dmat, mg->mg_listseg, mg->mg_listnseg); return (-1); } if (bus_dmamap_load(mg->mg_dmat, mg->mg_listmap, mg->mg_listkva, MUSYCC_DMA_MAPSIZE, NULL, BUS_DMA_NOWAIT)) { musycc_free_dmadesc(mg); return (-1); } /* * Create spare maps for musycc_start and musycc_newbuf. * Limit the dma queue to MUSYCC_DMA_SIZE entries even though there * is no actual hard limit from the chip. */ if (bus_dmamap_create(mg->mg_dmat, MCLBYTES, MUSYCC_DMA_SIZE, MCLBYTES, 0, BUS_DMA_NOWAIT, &mg->mg_tx_sparemap) != 0) { musycc_free_dmadesc(mg); return (-1); } if (bus_dmamap_create(mg->mg_dmat, MCLBYTES, MUSYCC_DMA_SIZE, MCLBYTES, 0, BUS_DMA_NOWAIT, &mg->mg_rx_sparemap) != 0) { bus_dmamap_destroy(mg->mg_dmat, mg->mg_tx_sparemap); musycc_free_dmadesc(mg); return (-1); } mg->mg_dma_pool = (struct dma_desc *)mg->mg_listkva; bzero(mg->mg_dma_pool, MUSYCC_DMA_CNT * sizeof(struct dma_desc)); /* add all descriptors to the freelist */ for (j = 0; j < MUSYCC_DMA_CNT; j++) { dd = &mg->mg_dma_pool[j]; /* initialize, same as for spare maps */ if (bus_dmamap_create(mg->mg_dmat, MCLBYTES, MUSYCC_DMA_SIZE, MCLBYTES, 0, BUS_DMA_NOWAIT, &dd->map)) { musycc_free_group(mg); return (-1); } /* link */ dd->nextdesc = mg->mg_freelist; mg->mg_freelist = dd; mg->mg_freecnt++; } return (0); } void musycc_free_groupdesc(struct musycc_softc *sc) { bus_dmamap_destroy(sc->mc_dmat, sc->mc_cfgmap); bus_dmamem_unmap(sc->mc_dmat, sc->mc_groupkva, sc->mc_ngroups * 2048); bus_dmamem_free(sc->mc_dmat, sc->mc_cfgseg, sc->mc_cfgnseg); } void musycc_free_intqueue(struct musycc_softc *sc) { bus_dmamap_destroy(sc->mc_dmat, sc->mc_intrmap); bus_dmamem_unmap(sc->mc_dmat, (caddr_t)sc->mc_intrd, sizeof(struct musycc_intdesc)); bus_dmamem_free(sc->mc_dmat, sc->mc_intrseg, sc->mc_intrnseg); } void musycc_free_dmadesc(struct musycc_group *mg) { bus_dmamap_destroy(mg->mg_dmat, mg->mg_listmap); bus_dmamem_unmap(mg->mg_dmat, mg->mg_listkva, MUSYCC_DMA_MAPSIZE); bus_dmamem_free(mg->mg_dmat, mg->mg_listseg, mg->mg_listnseg); } void musycc_free_group(struct musycc_group *mg) { bus_dmamap_destroy(mg->mg_dmat, mg->mg_tx_sparemap); bus_dmamap_destroy(mg->mg_dmat, mg->mg_tx_sparemap); /* XXX dma descriptors ? */ musycc_free_dmadesc(mg); mg->mg_dma_pool = NULL; mg->mg_freelist = NULL; mg->mg_freecnt = 0; } void musycc_set_group(struct musycc_group *mg, int poll, int maxa, int maxb) { /* set global conf and interrupt descriptor */ mg->mg_group->global_conf = htole32(mg->mg_hdlc->mc_global_conf); /* * Interrupt Queue and Length. * NOTE: a value of 1 indicates the queue length of 2 descriptors! */ mg->mg_group->int_queuep = htole32(mg->mg_hdlc->mc_intrqptr); mg->mg_group->int_queuelen = htole32(MUSYCC_INTLEN - 1); /* group config */ mg->mg_group->group_conf = htole32(MUSYCC_GRCFG_RXENBL | MUSYCC_GRCFG_TXENBL | MUSYCC_GRCFG_SUBDSBL | MUSYCC_GRCFG_MSKCOFA | MUSYCC_GRCFG_MSKOOF | MUSYCC_GRCFG_MCENBL | (poll & MUSYCC_GRCFG_POLL64)); /* memory protection, not supported by device */ /* message length config, preinit with useful data */ /* this is currently not used and the max is limited to 4094 bytes */ mg->mg_group->msglen_conf = htole32(maxa); mg->mg_group->msglen_conf |= htole32(maxb << MUSYCC_MAXFRM2_SHIFT); } void musycc_set_port(struct musycc_group *mg, int mode) { /* * All signals trigger on falling edge only exception is TSYNC * which triggers on rising edge. For the framer TSYNC is set to * falling edge too but Musycc needs rising edge or everything gets * off by one. Don't three-state TX (not needed). */ mg->mg_group->port_conf = htole32(MUSYCC_PORT_TSYNC_EDGE | MUSYCC_PORT_TRITX | (mode & MUSYCC_PORT_MODEMASK)); if (mg->mg_loaded) musycc_sreq(mg, 0, MUSYCC_SREQ_SET(21), MUSYCC_SREQ_RX, EV_NULL); } /* * Channel specifc calls */ int musycc_set_tsmap(struct musycc_group *mg, struct channel_softc *cc, char slot) { int i, nslots = 0, off, scale; u_int32_t tslots = cc->cc_tslots; ACCOOM_PRINTF(1, ("%s: musycc_set_tsmap %08x slot %c\n", cc->cc_ifp->if_xname, tslots, slot)); switch (slot) { case 'A': /* single port, non interleaved */ off = 0; scale = 1; break; case 'a': /* dual port, interleaved */ case 'b': off = slot - 'a'; scale = 2; break; case '1': /* possible quad port, interleaved */ case '2': case '3': case '4': off = slot - '1'; scale = 4; break; default: /* impossible */ log(LOG_ERR, "%s: accessing unsupported slot %c", cc->cc_ifp->if_xname, slot); return (-1); } /* * setup timeslot map but first make sure no timeslot is already used * note: 56kbps mode for T1-SF needs to be set in here * note2: if running with port mapping the other group needs to be * checked too or we may get funny results. Currenly not possible * because of the slot offsets (odd, even slots). */ for (i = 0; i < sizeof(u_int32_t) * 8; i++) if (tslots & (1 << i)) if (mg->mg_group->tx_tsmap[i * scale + off] & MUSYCC_TSLOT_ENABLED || mg->mg_group->rx_tsmap[i * scale + off] & MUSYCC_TSLOT_ENABLED) return (0); for (i = 0; i < sizeof(u_int32_t) * 8; i++) if (tslots & (1 << i)) { nslots++; mg->mg_group->tx_tsmap[i * scale + off] = MUSYCC_TSLOT_CHAN(cc->cc_channel) | MUSYCC_TSLOT_ENABLED; mg->mg_group->rx_tsmap[i * scale + off] = MUSYCC_TSLOT_CHAN(cc->cc_channel) | MUSYCC_TSLOT_ENABLED; } return (nslots); } int musycc_set_chandesc(struct musycc_group *mg, int chan, int nslots, int proto) { u_int64_t mask = ULLONG_MAX; int idx, n; ACCOOM_PRINTF(1, ("%s: musycc_set_chandesc nslots %d proto %d\n", mg->mg_channels[chan]->cc_ifp->if_xname, nslots, proto)); if (nslots == 0 || nslots > 32) return (EINVAL); n = 64 - 2 * nslots; mask >>= n; for (idx = 0; idx <= n; idx += 2) if (!(mg->mg_fifomask & mask << idx)) break; if (idx > n) return (EBUSY); mg->mg_fifomask |= mask << idx; /* setup channel descriptor */ mg->mg_group->tx_cconf[chan] = htole32(MUSYCC_CHAN_BUFIDX_SET(idx) | MUSYCC_CHAN_BUFLEN_SET(nslots * 2 - 1) | MUSYCC_CHAN_PROTO_SET(proto)); mg->mg_group->rx_cconf[chan] = htole32(MUSYCC_CHAN_BUFIDX_SET(idx) | MUSYCC_CHAN_BUFLEN_SET(nslots * 2 - 1) | MUSYCC_CHAN_MSKIDLE | MUSYCC_CHAN_MSKSUERR | MUSYCC_CHAN_MSKSINC | MUSYCC_CHAN_MSKSDEC | MUSYCC_CHAN_MSKSFILT | MUSYCC_CHAN_PROTO_SET(proto)); return (0); } int musycc_init_channel(struct channel_softc *cc, char slot) { struct musycc_group *mg; struct ifnet *ifp = cc->cc_ifp; int nslots, rv, s; if (cc->cc_state == CHAN_FLOAT) return (ENOTTY); mg = cc->cc_group; ACCOOM_PRINTF(2, ("%s: musycc_init_channel [state %d] slot %c\n", cc->cc_ifp->if_xname, cc->cc_state, slot)); if (cc->cc_state != CHAN_IDLE) { musycc_sreq(mg, cc->cc_channel, MUSYCC_SREQ_SET(9), MUSYCC_SREQ_BOTH, EV_STOP); tsleep(cc, PZERO | PCATCH, "musycc", hz); if (cc->cc_state != CHAN_IDLE) { ACCOOM_PRINTF(0, ("%s: failed to reset channel\n", cc->cc_ifp->if_xname)); return (EIO); } } s = splnet(); /* setup timeslot map */ nslots = musycc_set_tsmap(mg, cc, slot); if (nslots == -1) { rv = EINVAL; goto fail; } else if (nslots == 0) { rv = EBUSY; goto fail; } if ((rv = musycc_set_chandesc(mg, cc->cc_channel, nslots, MUSYCC_PROTO_HDLC16))) goto fail; /* setup tx DMA chain */ musycc_list_tx_init(mg, cc->cc_channel, MUSYCC_DMA_SIZE); /* setup rx DMA chain */ if ((rv = musycc_list_rx_init(mg, cc->cc_channel, MUSYCC_DMA_SIZE))) { ACCOOM_PRINTF(0, ("%s: initialization failed: " "no memory for rx buffers\n", cc->cc_ifp->if_xname)); goto fail; } /* IFF_RUNNING set by sppp_ioctl() */ ifp->if_flags &= ~IFF_OACTIVE; cc->cc_state = CHAN_TRANSIENT; splx(s); musycc_dump_group(3, mg); musycc_activate_channel(mg, cc->cc_channel); tsleep(cc, PZERO | PCATCH, "musycc", hz); /* * XXX we could actually check if the activation of the channels was * successful but what type of error should we return? */ return (0); fail: splx(s); cc->cc_state = CHAN_IDLE; /* force idle state */ musycc_free_channel(mg, cc->cc_channel); return (rv); } void musycc_activate_channel(struct musycc_group *mg, int chan) { ACCOOM_PRINTF(2, ("%s: musycc_activate_channel\n", mg->mg_channels[chan]->cc_ifp->if_xname)); musycc_sreq(mg, chan, MUSYCC_SREQ_SET(26), MUSYCC_SREQ_BOTH, EV_NULL); musycc_sreq(mg, chan, MUSYCC_SREQ_SET(24), MUSYCC_SREQ_BOTH, EV_NULL); musycc_sreq(mg, chan, MUSYCC_SREQ_SET(8), MUSYCC_SREQ_BOTH, EV_ACTIVATE); } void musycc_stop_channel(struct channel_softc *cc) { struct musycc_group *mg = cc->cc_group; if (cc->cc_state == CHAN_FLOAT) { /* impossible */ log(LOG_ERR, "%s: unexpected state in musycc_stop_channel", cc->cc_ifp->if_xname); cc->cc_state = CHAN_IDLE; /* reset */ musycc_free_channel(mg, cc->cc_channel); return; } ACCOOM_PRINTF(2, ("%s: musycc_stop_channel\n", cc->cc_ifp->if_xname)); musycc_sreq(mg, cc->cc_channel, MUSYCC_SREQ_SET(9), MUSYCC_SREQ_BOTH, EV_STOP); tsleep(cc, PZERO | PCATCH, "musycc", hz); } void musycc_free_channel(struct musycc_group *mg, int chan) { u_int64_t mask = ULLONG_MAX; int i, idx, s, slots; ACCOOM_PRINTF(2, ("%s: musycc_free_channel\n", mg->mg_channels[chan]->cc_ifp->if_xname)); s = splnet(); /* Clear the timeout timer. */ mg->mg_channels[chan]->cc_ifp->if_timer = 0; /* clear timeslot map */ for (i = 0; i < 128; i++) { if (mg->mg_group->tx_tsmap[i] & MUSYCC_TSLOT_ENABLED) if ((mg->mg_group->tx_tsmap[i] & MUSYCC_TSLOT_MASK) == chan) mg->mg_group->tx_tsmap[i] = 0; if (mg->mg_group->rx_tsmap[i] & MUSYCC_TSLOT_ENABLED) if ((mg->mg_group->rx_tsmap[i] & MUSYCC_TSLOT_MASK) == chan) mg->mg_group->rx_tsmap[i] = 0; } /* clear channel descriptor, especially free FIFO space */ idx = MUSYCC_CHAN_BUFIDX_GET(letoh32(mg->mg_group->tx_cconf[chan])); slots = MUSYCC_CHAN_BUFLEN_GET(letoh32(mg->mg_group->tx_cconf[chan])); slots = (slots + 1) / 2; mask >>= 64 - 2 * slots; mask <<= idx; mg->mg_fifomask &= ~mask; mg->mg_group->tx_cconf[chan] = 0; mg->mg_group->rx_cconf[chan] = 0; /* free dma rings */ musycc_list_rx_free(mg, chan); musycc_list_tx_free(mg, chan); splx(s); /* update chip info with sreq */ musycc_sreq(mg, chan, MUSYCC_SREQ_SET(24), MUSYCC_SREQ_BOTH, EV_NULL); musycc_sreq(mg, chan, MUSYCC_SREQ_SET(26), MUSYCC_SREQ_BOTH, EV_IDLE); } void musycc_state_engine(struct musycc_group *mg, int chan, enum musycc_event ev) { enum musycc_state state; if (mg->mg_channels[chan] == NULL) return; state = mg->mg_channels[chan]->cc_state; ACCOOM_PRINTF(2, ("%s: musycc_state_engine state %d event %d\n", mg->mg_channels[chan]->cc_ifp->if_xname, state, ev)); switch (ev) { case EV_NULL: /* no state change */ return; case EV_ACTIVATE: state = CHAN_RUNNING; break; case EV_STOP: /* channel disabled now free dma rings et al. */ mg->mg_channels[chan]->cc_state = CHAN_TRANSIENT; musycc_free_channel(mg, chan); return; case EV_IDLE: state = CHAN_IDLE; break; case EV_WATCHDOG: musycc_reinit_dma(mg, chan); return; } mg->mg_channels[chan]->cc_state = state; wakeup(mg->mg_channels[chan]); } /* * DMA handling functions */ struct dma_desc * musycc_dma_get(struct musycc_group *mg) { struct dma_desc *dd; splassert(IPL_NET); if (mg->mg_freecnt == 0) return (NULL); mg->mg_freecnt--; dd = mg->mg_freelist; mg->mg_freelist = dd->nextdesc; /* clear some important data */ dd->nextdesc = NULL; dd->mbuf = NULL; return (dd); } void musycc_dma_free(struct musycc_group *mg, struct dma_desc *dd) { splassert(IPL_NET); dd->nextdesc = mg->mg_freelist; mg->mg_freelist = dd; mg->mg_freecnt++; } /* * Initialize the transmit descriptors. Acctually they are left empty until * a packet comes in. */ int musycc_list_tx_init(struct musycc_group *mg, int c, int size) { struct musycc_dma_data *md; struct dma_desc *dd; bus_addr_t base; int i; splassert(IPL_NET); ACCOOM_PRINTF(2, ("musycc_list_tx_init\n")); md = &mg->mg_dma_d[c]; md->tx_pend = NULL; md->tx_cur = NULL; md->tx_cnt = size; md->tx_pkts = 0; base = mg->mg_listmap->dm_segs[0].ds_addr; for (i = 0; i < md->tx_cnt; i++) { dd = musycc_dma_get(mg); if (dd == NULL) { ACCOOM_PRINTF(0, ("musycc_list_tx_init: " "out of dma_desc\n")); musycc_list_tx_free(mg, c); return (ENOBUFS); } dd->status = 0 /* MUSYCC_STATUS_NOPOLL */; dd->data = 0; if (md->tx_cur) { md->tx_cur->nextdesc = dd; md->tx_cur->next = htole32(base + (caddr_t)dd - mg->mg_listkva); md->tx_cur = dd; } else md->tx_pend = md->tx_cur = dd; } dd->nextdesc = md->tx_pend; dd->next = htole32(base + (caddr_t)md->tx_pend - mg->mg_listkva); md->tx_pend = dd; mg->mg_group->tx_headp[c] = htole32(base + (caddr_t)dd - mg->mg_listkva); bus_dmamap_sync(mg->mg_dmat, mg->mg_listmap, 0, MUSYCC_DMA_MAPSIZE, BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE); return (0); } /* * Initialize the RX descriptors and allocate mbufs for them. Note that * we arrange the descriptors in a closed ring, so that the last descriptor * points back to the first. */ int musycc_list_rx_init(struct musycc_group *mg, int c, int size) { struct musycc_dma_data *md; struct dma_desc *dd = NULL, *last; bus_addr_t base; int i; splassert(IPL_NET); ACCOOM_PRINTF(2, ("musycc_list_rx_init\n")); md = &mg->mg_dma_d[c]; md->rx_cnt = size; base = mg->mg_listmap->dm_segs[0].ds_addr; for (i = 0; i < size; i++) { dd = musycc_dma_get(mg); if (dd == NULL) { ACCOOM_PRINTF(0, ("musycc_list_rx_init: " "out of dma_desc\n")); musycc_list_rx_free(mg, c); return (ENOBUFS); } if (musycc_newbuf(mg, dd, NULL) == ENOBUFS) { ACCOOM_PRINTF(0, ("musycc_list_rx_init: " "out of mbufs\n")); musycc_list_rx_free(mg, c); return (ENOBUFS); } if (md->rx_prod) { md->rx_prod->nextdesc = dd; md->rx_prod->next = htole32(base + (caddr_t)dd - mg->mg_listkva); md->rx_prod = dd; } else last = md->rx_prod = dd; } dd->nextdesc = last; dd->next = htole32(base + (caddr_t)last - mg->mg_listkva); mg->mg_group->rx_headp[c] = htole32(base + (caddr_t)dd - mg->mg_listkva); bus_dmamap_sync(mg->mg_dmat, mg->mg_listmap, 0, MUSYCC_DMA_MAPSIZE, BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE); return (0); } void musycc_list_tx_free(struct musycc_group *mg, int c) { struct musycc_dma_data *md; struct dma_desc *dd, *tmp; md = &mg->mg_dma_d[c]; splassert(IPL_NET); ACCOOM_PRINTF(2, ("musycc_list_tx_free\n")); dd = md->tx_pend; do { if (dd == NULL) break; if (dd->map->dm_nsegs != 0) { bus_dmamap_t map = dd->map; bus_dmamap_unload(mg->mg_dmat, map); } if (dd->mbuf != NULL) { m_freem(dd->mbuf); dd->mbuf = NULL; } tmp = dd; dd = dd->nextdesc; musycc_dma_free(mg, tmp); } while (dd != md->tx_pend); md->tx_pend = md->tx_cur = NULL; md->tx_cnt = md->tx_use = md->tx_pkts = 0; } void musycc_list_rx_free(struct musycc_group *mg, int c) { struct musycc_dma_data *md; struct dma_desc *dd, *tmp; md = &mg->mg_dma_d[c]; splassert(IPL_NET); ACCOOM_PRINTF(2, ("musycc_list_rx_free\n")); dd = md->rx_prod; do { if (dd == NULL) break; if (dd->map->dm_nsegs != 0) { bus_dmamap_t map = dd->map; bus_dmamap_unload(mg->mg_dmat, map); } if (dd->mbuf != NULL) { m_freem(dd->mbuf); dd->mbuf = NULL; } tmp = dd; dd = dd->nextdesc; musycc_dma_free(mg, tmp); } while (dd != md->rx_prod); md->rx_prod = NULL; md->rx_cnt = 0; } /* only used by the watchdog timeout */ void musycc_reinit_dma(struct musycc_group *mg, int c) { int s; s = splnet(); musycc_list_tx_free(mg, c); musycc_list_rx_free(mg, c); /* setup tx & rx DMA chain */ if (musycc_list_tx_init(mg, c, MUSYCC_DMA_SIZE) || musycc_list_rx_init(mg, c, MUSYCC_DMA_SIZE)) { log(LOG_ERR, "%s: Failed to malloc memory\n", mg->mg_channels[c]->cc_ifp->if_xname); musycc_free_channel(mg, c); } splx(s); musycc_activate_channel(mg, c); } /* * Initialize an RX descriptor and attach an mbuf cluster. */ int musycc_newbuf(struct musycc_group *mg, struct dma_desc *c, struct mbuf *m) { struct mbuf *m_new = NULL; bus_dmamap_t map; if (m == NULL) { MGETHDR(m_new, M_DONTWAIT, MT_DATA); if (m_new == NULL) return (ENOBUFS); MCLGET(m_new, M_DONTWAIT); if (!(m_new->m_flags & M_EXT)) { m_freem(m_new); return (ENOBUFS); } m_new->m_len = m_new->m_pkthdr.len = MCLBYTES; } else { m_new = m; m_new->m_len = m_new->m_pkthdr.len = MCLBYTES; m_new->m_data = m_new->m_ext.ext_buf; } if (bus_dmamap_load(mg->mg_dmat, mg->mg_rx_sparemap, mtod(m_new, caddr_t), m_new->m_pkthdr.len, NULL, BUS_DMA_NOWAIT) != 0) { ACCOOM_PRINTF(0, ("%s: rx load failed\n", mg->mg_hdlc->mc_dev.dv_xname)); m_freem(m_new); return (ENOBUFS); } map = c->map; c->map = mg->mg_rx_sparemap; mg->mg_rx_sparemap = map; bus_dmamap_sync(mg->mg_dmat, c->map, 0, c->map->dm_mapsize, BUS_DMASYNC_PREREAD); c->mbuf = m_new; c->data = htole32(c->map->dm_segs[0].ds_addr); c->status = htole32(MUSYCC_STATUS_NOPOLL | MUSYCC_STATUS_LEN(m_new->m_pkthdr.len)); bus_dmamap_sync(mg->mg_dmat, mg->mg_listmap, ((caddr_t)c - mg->mg_listkva), sizeof(struct dma_desc), BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE); return (0); } /* * Encapsulate an mbuf chain in a descriptor by coupling the mbuf data * pointers to the fragment pointers. */ int musycc_encap(struct musycc_group *mg, struct mbuf *m_head, int c) { struct dma_desc *cur, *tmp; bus_dmamap_t map; bus_addr_t base; u_int32_t status; int i; splassert(IPL_NET); map = mg->mg_tx_sparemap; if (bus_dmamap_load_mbuf(mg->mg_dmat, map, m_head, BUS_DMA_NOWAIT) != 0) { ACCOOM_PRINTF(0, ("%s: musycc_encap: dmamap_load failed\n", mg->mg_channels[c]->cc_ifp->if_xname)); return (ENOBUFS); } cur = mg->mg_dma_d[c].tx_cur; base = mg->mg_listmap->dm_segs[0].ds_addr; if (map->dm_nsegs + mg->mg_dma_d[c].tx_use >= mg->mg_dma_d[c].tx_cnt) { ACCOOM_PRINTF(1, ("%s: tx out of dma bufs\n", mg->mg_channels[c]->cc_ifp->if_xname)); return (ENOBUFS); } i = 0; while (i < map->dm_nsegs) { status = /* MUSYCC_STATUS_NOPOLL | */ MUSYCC_STATUS_LEN(map->dm_segs[i].ds_len); if (cur != mg->mg_dma_d[c].tx_cur) status |= MUSYCC_STATUS_OWNER; cur->status = htole32(status); cur->data = htole32(map->dm_segs[i].ds_addr); bus_dmamap_sync(mg->mg_dmat, mg->mg_listmap, ((caddr_t)cur - mg->mg_listkva), sizeof(struct dma_desc), BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE); if (++i >= map->dm_nsegs) break; cur = cur->nextdesc; } bus_dmamap_sync(mg->mg_dmat, map, 0, map->dm_mapsize, BUS_DMASYNC_PREWRITE); cur->mbuf = m_head; mg->mg_tx_sparemap = cur->map; cur->map = map; cur->status |= htole32(MUSYCC_STATUS_EOM); tmp = mg->mg_dma_d[c].tx_cur; mg->mg_dma_d[c].tx_cur = cur->nextdesc; mg->mg_dma_d[c].tx_use += i; mg->mg_dma_d[c].tx_pkts++; /* * Last but not least, flag the buffer if the buffer is flagged to * early, it may happen, that the buffer is already transmitted * before we changed all relevant variables. */ tmp->status |= htole32(MUSYCC_STATUS_OWNER); #if 0 /* check for transmited packets NO POLLING mode only */ /* * Note: a bug in the HDLC chip seems to make it impossible to use * no polling mode. */ musycc_txeom(mg, c); if (mg->mg_dma_d[c].tx_pend == tmp) { /* and restart as needed */ printf("%s: tx needs kick\n", mg->mg_channels[c]->cc_ifp->if_xname); mg->mg_group->tx_headp[c] = htole32(base + (caddr_t)mg->mg_dma_d[c].tx_pend - mg->mg_listkva); musycc_sreq(mg, c, MUSYCC_SREQ_SET(8), MUSYCC_SREQ_TX); } #endif return (0); } /* * API towards the kernel */ /* start transmit of new network buffer */ void musycc_start(struct ifnet *ifp) { struct musycc_group *mg; struct channel_softc *cc; struct mbuf *m = NULL; int s; cc = ifp->if_softc; mg = cc->cc_group; ACCOOM_PRINTF(3, ("musycc_start\n")); if (cc->cc_state != CHAN_RUNNING) return; if (ifp->if_flags & IFF_OACTIVE) return; if (sppp_isempty(ifp)) return; s = splnet(); while ((m = sppp_pick(ifp)) != NULL) { if (musycc_encap(mg, m, cc->cc_channel)) { ifp->if_flags |= IFF_OACTIVE; break; } #if NBPFILTER > 0 if (ifp->if_bpf) bpf_mtap(ifp->if_bpf, m, BPF_DIRECTION_OUT); #endif /* now we are committed to transmit the packet */ sppp_dequeue(ifp); } splx(s); /* * Set a timeout in case the chip goes out to lunch. */ ifp->if_timer = 5; return; } /* * Watchdog/transmission transmit timeout handler. Called when a * transmission is started on the interface, but no interrupt is * received before the timeout. This usually indicates that the * card has wedged for some reason. */ void musycc_watchdog(struct ifnet *ifp) { struct channel_softc *cc = ifp->if_softc; log(LOG_ERR, "%s: device timeout\n", cc->cc_ifp->if_xname); ifp->if_oerrors++; musycc_sreq(cc->cc_group, cc->cc_channel, MUSYCC_SREQ_SET(9), MUSYCC_SREQ_BOTH, EV_WATCHDOG); } /* * Interrupt specific functions */ /* * A frame has been uploaded: pass the resulting mbuf chain up to * the higher level protocols. */ void musycc_rxeom(struct musycc_group *mg, int channel, int forcekick) { struct mbuf *m; struct ifnet *ifp; struct dma_desc *cur_rx, *start_rx; int total_len = 0, consumed = 0; u_int32_t rxstat; ACCOOM_PRINTF(3, ("musycc_rxeom\n")); ifp = mg->mg_channels[channel]->cc_ifp; start_rx = cur_rx = mg->mg_dma_d[channel].rx_prod; if (cur_rx == NULL) return; /* dma ring got cleared */ do { bus_dmamap_sync(mg->mg_dmat, mg->mg_listmap, ((caddr_t)cur_rx - mg->mg_listkva), sizeof(struct dma_desc), BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE); rxstat = letoh32(cur_rx->status); if (!(rxstat & MUSYCC_STATUS_OWNER)) break; m = cur_rx->mbuf; cur_rx->mbuf = NULL; total_len = MUSYCC_STATUS_LEN(rxstat); /* * If an error occurs, update stats, clear the * status word and leave the mbuf cluster in place: * it should simply get re-used next time this descriptor * comes up in the ring. */ if (rxstat & MUSYCC_STATUS_ERROR) { ifp->if_ierrors++; ACCOOM_PRINTF(1, ("%s: rx error %08x\n", ifp->if_xname, rxstat)); musycc_newbuf(mg, cur_rx, m); cur_rx = cur_rx->nextdesc; consumed++; continue; } /* No errors; receive the packet. */ bus_dmamap_sync(mg->mg_dmat, cur_rx->map, 0, cur_rx->map->dm_mapsize, BUS_DMASYNC_POSTREAD); if (musycc_newbuf(mg, cur_rx, NULL) != 0) { cur_rx = cur_rx->nextdesc; consumed++; continue; } cur_rx = cur_rx->nextdesc; consumed++; /* TODO support mbuf chains */ m->m_pkthdr.rcvif = ifp; m->m_pkthdr.len = m->m_len = total_len; ifp->if_ipackets++; #if NBPFILTER > 0 if (ifp->if_bpf) bpf_mtap(ifp->if_bpf, m, BPF_DIRECTION_IN); #endif /* pass it on. */ sppp_input(ifp, m); } while (cur_rx != start_rx); mg->mg_dma_d[channel].rx_prod = cur_rx; if ((cur_rx == start_rx && consumed) || forcekick) { /* send SREQ to signal the new buffers */ ACCOOM_PRINTF(1, ("%s: rx kick, consumed %d pkts\n", mg->mg_channels[channel]->cc_ifp->if_xname, consumed)); mg->mg_group->rx_headp[channel] = htole32( mg->mg_listmap->dm_segs[0].ds_addr + (caddr_t)cur_rx - mg->mg_listkva); musycc_sreq(mg, channel, MUSYCC_SREQ_SET(8), MUSYCC_SREQ_RX, EV_NULL); } } /* * A frame was downloaded to the chip. It's safe for us to clean up * the list buffers. */ void musycc_txeom(struct musycc_group *mg, int channel, int forcekick) { struct dma_desc *dd, *dd_pend; struct ifnet *ifp; ACCOOM_PRINTF(3, ("musycc_txeom\n")); ifp = mg->mg_channels[channel]->cc_ifp; /* Clear the watchdog timer. */ ifp->if_timer = 0; /* * Go through our tx list and free mbufs for those * frames that have been transmitted. */ for (dd = mg->mg_dma_d[channel].tx_pend; dd != mg->mg_dma_d[channel].tx_cur; dd = dd->nextdesc) { bus_dmamap_sync(mg->mg_dmat, mg->mg_listmap, ((caddr_t)dd - mg->mg_listkva), sizeof(struct dma_desc), BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE); if (letoh32(dd->status) & MUSYCC_STATUS_OWNER) /* musycc still owns this descriptor */ break; mg->mg_dma_d[channel].tx_use--; dd->status = 0; /* reinit dma status flags */ /* dd->status |= MUSYCC_STATUS_NOPOLL; *//* disable polling */ if (dd->map->dm_nsegs != 0) { bus_dmamap_sync(mg->mg_dmat, dd->map, 0, dd->map->dm_mapsize, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(mg->mg_dmat, dd->map); } if (dd->mbuf != NULL) { m_freem(dd->mbuf); dd->mbuf = NULL; mg->mg_dma_d[channel].tx_pkts--; ifp->if_opackets++; } } dd_pend = mg->mg_dma_d[channel].tx_pend; mg->mg_dma_d[channel].tx_pend = dd; if (ifp->if_flags & IFF_OACTIVE && dd_pend != dd) { ifp->if_flags &= ~IFF_OACTIVE; musycc_start(ifp); } if (forcekick) { /* restart */ ACCOOM_PRINTF(1, ("%s: tx kick forced\n", mg->mg_channels[channel]->cc_ifp->if_xname)); mg->mg_group->tx_headp[channel] = htole32(mg->mg_listmap->dm_segs[0].ds_addr + (caddr_t)mg->mg_dma_d[channel].tx_pend - mg->mg_listkva); musycc_sreq(mg, channel, MUSYCC_SREQ_SET(8), MUSYCC_SREQ_TX, EV_NULL); } } int musycc_intr(void *arg) { struct musycc_softc *mc = arg; struct musycc_group *mg; struct ifnet *ifp; u_int32_t intstatus, id; int i, n, chan; intstatus = bus_space_read_4(mc->mc_st, mc->mc_sh, MUSYCC_INTRSTATUS); if (intstatus & MUSYCC_INTCNT_MASK) { bus_dmamap_sync(mc->mc_dmat, mc->mc_intrmap, offsetof(struct musycc_intdesc, md_intrq[0]), MUSYCC_INTLEN * sizeof(u_int32_t), BUS_DMASYNC_POSTREAD); ACCOOM_PRINTF(4, ("%s: interrupt status %08x\n", mc->mc_dev.dv_xname, intstatus)); n = MUSYCC_NEXTINT_GET(intstatus); for (i = 0; i < (intstatus & MUSYCC_INTCNT_MASK); i++) { id = letoh32(mc->mc_intrd->md_intrq[(n + i) % MUSYCC_INTLEN]); chan = MUSYCC_INTD_CHAN(id); mg = &mc->mc_groups[MUSYCC_INTD_GRP(id)]; ACCOOM_PRINTF(4, ("%s: interrupt %s\n", mc->mc_dev.dv_xname, musycc_intr_print(id))); if (id & MUSYCC_INTD_ILOST) ACCOOM_PRINTF(0, ("%s: interrupt lost\n", mc->mc_dev.dv_xname)); switch (MUSYCC_INTD_EVENT(id)) { case MUSYCC_INTEV_NONE: break; case MUSYCC_INTEV_SACK: musycc_state_engine(mg, chan, mg->mg_sreq[mg->mg_sreqpend].event); mg->mg_sreqpend = (mg->mg_sreqpend + 1) & MUSYCC_SREQMASK; if (mg->mg_sreqpend != mg->mg_sreqprod) musycc_kick(mg); break; case MUSYCC_INTEV_EOM: case MUSYCC_INTEV_EOB: if (id & MUSYCC_INTD_DIR) musycc_txeom(mg, chan, 0); else musycc_rxeom(mg, chan, 0); break; default: ACCOOM_PRINTF(0, ("%s: unhandled event: %s\n", mc->mc_dev.dv_xname, musycc_intr_print(id))); break; } switch (MUSYCC_INTD_ERROR(id)) { case MUSYCC_INTERR_NONE: break; case MUSYCC_INTERR_COFA: if ((id & MUSYCC_INTD_DIR) == 0) /* ignore COFA for RX side */ break; if (mg->mg_channels[chan]->cc_state != CHAN_RUNNING) { /* * ignore COFA for TX side if card is * not running */ break; } ACCOOM_PRINTF(0, ("%s: error: %s\n", mc->mc_dev.dv_xname, musycc_intr_print(id))); #if 0 /* digest already transmitted packets */ musycc_txeom(mg, chan); /* adjust head pointer */ musycc_dump_dma(mg); mg->mg_group->tx_headp[chan] = htole32(mg->mg_listmap->dm_segs[0].ds_addr + (caddr_t)mg->mg_dma_d[chan].tx_pend - mg->mg_listkva); musycc_dump_dma(mg); musycc_sreq(mg, chan, MUSYCC_SREQ_SET(8), MUSYCC_SREQ_TX, CHAN_RUNNING); #endif break; case MUSYCC_INTERR_BUFF: /* * log event as this should not happen, * indicates PCI bus congestion */ log(LOG_ERR, "%s: internal FIFO %s\n", mg->mg_channels[chan]->cc_ifp->if_xname, id & MUSYCC_INTD_DIR ? "underflow" : "overflow"); /* digest queue and restarting dma engine */ ifp = mg->mg_channels[chan]->cc_ifp; if (id & MUSYCC_INTD_DIR) { ifp->if_oerrors++; musycc_txeom(mg, chan, 1); } else { ifp->if_ierrors++; musycc_rxeom(mg, chan, 1); } break; case MUSYCC_INTERR_ONR: ACCOOM_PRINTF(0, ("%s: error: %s\n", mc->mc_dev.dv_xname, musycc_intr_print(id))); /* digest queue and restarting dma engine */ ifp = mg->mg_channels[chan]->cc_ifp; if (id & MUSYCC_INTD_DIR) { ifp->if_oerrors++; musycc_txeom(mg, chan, 1); } else { ifp->if_ierrors++; musycc_rxeom(mg, chan, 1); } break; case MUSYCC_INTERR_OOF: /* ignore */ break; default: ACCOOM_PRINTF(0, ("%s: unhandled error: %s\n", mc->mc_dev.dv_xname, musycc_intr_print(id))); break; } } bus_space_write_4(mc->mc_st, mc->mc_sh, MUSYCC_INTRSTATUS, MUSYCC_NEXTINT_SET((n + i) % MUSYCC_INTLEN)); bus_space_barrier(mc->mc_st, mc->mc_sh, MUSYCC_INTRSTATUS, sizeof(u_int32_t), BUS_SPACE_BARRIER_WRITE); return (1); } else return (0); } void musycc_kick(struct musycc_group *mg) { bus_dmamap_sync(mg->mg_dmat, mg->mg_hdlc->mc_cfgmap, MUSYCC_GROUPBASE(mg->mg_gnum), sizeof(struct musycc_grpdesc), BUS_DMASYNC_PREWRITE|BUS_DMASYNC_PREREAD); ACCOOM_PRINTF(4, ("musycc_kick: group %d sreq[%d] req %08x\n", mg->mg_gnum, mg->mg_sreqpend, mg->mg_sreq[mg->mg_sreqpend].sreq)); bus_space_write_4(mg->mg_hdlc->mc_st, mg->mg_hdlc->mc_sh, MUSYCC_SERREQ(mg->mg_gnum), mg->mg_sreq[mg->mg_sreqpend].sreq); bus_space_barrier(mg->mg_hdlc->mc_st, mg->mg_hdlc->mc_sh, MUSYCC_SERREQ(mg->mg_gnum), sizeof(u_int32_t), BUS_SPACE_BARRIER_WRITE); } void musycc_sreq(struct musycc_group *mg, int channel, u_int32_t req, int dir, enum musycc_event event) { #define MUSYCC_SREQINC(x, y) \ do { \ (x) = ((x) + 1) & MUSYCC_SREQMASK; \ if (x == y) \ panic("%s: sreq queue overflow", \ mg->mg_hdlc->mc_dev.dv_xname); \ } while (0) struct timeval tv; int needskick; needskick = (mg->mg_sreqpend == mg->mg_sreqprod); getmicrouptime(&tv); ACCOOM_PRINTF(4, ("musycc_sreq: g# %d c# %d req %x dir %x\n", mg->mg_gnum, channel, req, dir)); if (dir & MUSYCC_SREQ_RX) { req &= ~MUSYCC_SREQ_TXDIR & ~MUSYCC_SREQ_MASK; req |= MUSYCC_SREQ_CHSET(channel); mg->mg_sreq[mg->mg_sreqprod].sreq = req; mg->mg_sreq[mg->mg_sreqprod].timeout = tv.tv_sec + MUSYCC_SREQTIMEOUT; if (dir == MUSYCC_SREQ_RX) mg->mg_sreq[mg->mg_sreqprod].event = event; else mg->mg_sreq[mg->mg_sreqprod].event = EV_NULL; MUSYCC_SREQINC(mg->mg_sreqprod, mg->mg_sreqpend); } if (dir & MUSYCC_SREQ_TX) { req &= ~MUSYCC_SREQ_MASK; req |= MUSYCC_SREQ_TXDIR; req |= MUSYCC_SREQ_CHSET(channel); mg->mg_sreq[mg->mg_sreqprod].timeout = tv.tv_sec + MUSYCC_SREQTIMEOUT; mg->mg_sreq[mg->mg_sreqprod].sreq = req; mg->mg_sreq[mg->mg_sreqprod].event = event; MUSYCC_SREQINC(mg->mg_sreqprod, mg->mg_sreqpend); } if (needskick) musycc_kick(mg); #undef MUSYCC_SREQINC } void musycc_tick(struct channel_softc *cc) { struct musycc_group *mg = cc->cc_group; struct timeval tv; if (mg->mg_sreqpend == mg->mg_sreqprod) return; getmicrouptime(&tv); if (mg->mg_sreq[mg->mg_sreqpend].timeout < tv.tv_sec) { log(LOG_ERR, "%s: service request timeout\n", cc->cc_ifp->if_xname); mg->mg_sreqpend++; /* digest all timed out SREQ */ while (mg->mg_sreq[mg->mg_sreqpend].timeout < tv.tv_sec && mg->mg_sreqpend != mg->mg_sreqprod) mg->mg_sreqpend++; if (mg->mg_sreqpend != mg->mg_sreqprod) musycc_kick(mg); } } /* * Extension Bus API */ int ebus_intr(void *arg) { struct musycc_softc *sc = arg; printf("%s: interrupt\n", sc->mc_dev.dv_xname); return (1); } int ebus_attach_device(struct ebus_dev *e, struct musycc_softc *mc, bus_size_t offset, bus_size_t size) { struct musycc_softc *ec = mc->mc_other; e->base = offset << 2; e->size = size; e->st = ec->mc_st; return (bus_space_subregion(ec->mc_st, ec->mc_sh, offset << 2, size, &e->sh)); } u_int8_t ebus_read(struct ebus_dev *e, bus_size_t offset) { u_int8_t value; value = bus_space_read_1(e->st, e->sh, offset << 2); bus_space_barrier(e->st, e->sh, 0, e->size, BUS_SPACE_BARRIER_READ|BUS_SPACE_BARRIER_WRITE); return (value); } void ebus_write(struct ebus_dev *e, bus_size_t offset, u_int8_t value) { bus_space_write_1(e->st, e->sh, offset << 2, value); bus_space_barrier(e->st, e->sh, 0, e->size, BUS_SPACE_BARRIER_READ|BUS_SPACE_BARRIER_WRITE); } void ebus_read_buf(struct ebus_dev *rom, bus_size_t offset, void *buf, size_t size) { u_int8_t *b = buf; size_t i; for (i = 0; i < size; i++) b[i] = ebus_read(rom, offset + i); } void ebus_set_led(struct channel_softc *cc, int on, u_int8_t value) { struct musycc_softc *sc = cc->cc_group->mg_hdlc->mc_other; value &= MUSYCC_LED_MASK; /* don't write to other ports led */ value <<= cc->cc_group->mg_gnum * 2; if (on) sc->mc_ledstate |= value; else sc->mc_ledstate &= ~value; bus_space_write_1(sc->mc_st, sc->mc_sh, sc->mc_ledbase, sc->mc_ledstate); bus_space_barrier(sc->mc_st, sc->mc_sh, sc->mc_ledbase, 1, BUS_SPACE_BARRIER_READ|BUS_SPACE_BARRIER_WRITE); } /* * Channel API */ void musycc_attach_sppp(struct channel_softc *cc, int (*if_ioctl)(struct ifnet *, u_long, caddr_t)) { struct ifnet *ifp; ifp = &cc->cc_ppp.pp_if; cc->cc_ifp = ifp; IFQ_SET_MAXLEN(&ifp->if_snd, IFQ_MAXLEN); IFQ_SET_READY(&ifp->if_snd); ifp->if_mtu = PP_MTU; ifp->if_flags = IFF_POINTOPOINT | IFF_MULTICAST /* | IFF_SIMPLEX */; cc->cc_ppp.pp_flags |= PP_CISCO; cc->cc_ppp.pp_flags |= PP_KEEPALIVE; cc->cc_ppp.pp_framebytes = 3; ifp->if_ioctl = if_ioctl; ifp->if_start = musycc_start; ifp->if_watchdog = musycc_watchdog; if_attach(ifp); if_alloc_sadl(ifp); sppp_attach(ifp); #if NBPFILTER > 0 bpfattach(&ifp->if_bpf, ifp, DLT_PPP, PPP_HEADER_LEN); #endif /* NBPFILTER > 0 */ } struct channel_softc * musycc_channel_create(const char *name, u_int8_t locked) { struct channel_softc *cc; cc = malloc(sizeof(*cc), M_DEVBUF, M_NOWAIT | M_ZERO); if (!cc) return (NULL); cc->cc_state = CHAN_FLOAT; cc->cc_locked = locked; /* set default timeslot map for E1 */ cc->cc_tslots = 0xfffffffe; /* all but timeslot 0 */ strlcpy(cc->cc_ppp.pp_if.if_xname, name, sizeof(cc->cc_ppp.pp_if.if_xname)); cc->cc_ppp.pp_if.if_softc = cc; return (cc); } int musycc_channel_attach(struct musycc_softc *mc, struct channel_softc *cc, struct device *dev, u_int8_t gnum) { struct musycc_group *mg; int i; if (cc->cc_state != CHAN_FLOAT) return (-1); /* already attached */ if (gnum >= mc->mc_ngroups) { ACCOOM_PRINTF(0, ("%s: %s tries to attach to nonexistent group", mc->mc_dev.dv_xname, cc->cc_ifp->if_xname)); return (-1); } mg = &mc->mc_groups[gnum]; for (i = 0; i < MUSYCC_NUMCHAN; i++) if (mg->mg_channels[i] == NULL) { mg->mg_channels[i] = cc; cc->cc_state = CHAN_IDLE; cc->cc_group = mg; cc->cc_channel = i; cc->cc_parent = dev; return (i); } return (-1); } void musycc_channel_detach(struct ifnet *ifp) { struct channel_softc *cc = ifp->if_softc; if (cc->cc_state != CHAN_FLOAT) { musycc_free_channel(cc->cc_group, cc->cc_channel); cc->cc_group->mg_channels[cc->cc_channel] = NULL; } if_detach(ifp); } #ifdef ACCOOM_DEBUG const char *musycc_events[] = { "NONE", "SACK", "EOB", "EOM", "EOP", "CHABT", "CHIC", "FREC", "SINC", "SDEC", "SFILT", "RFU", "RFU", "RFU", "RFU", "RFU" }; const char *musycc_errors[] = { "NONE", "BUFF", "COFA", "ONR", "PROT", "RFU", "RFU", "RFU", "OOF", "FCS", "ALIGN", "ABT", "LNG", "SHT", "SUERR", "PERR" }; const char *mu_proto[] = { "trans", "ss7", "hdlc16", "hdlc32", "rsvd4", "rsvd5", "rsvd6", "rsvd7" }; const char *mu_mode[] = { "t1", "e1", "2*e1", "4*e1", "n64", "rsvd5", "rsvd6", "rsvd7" }; char musycc_intrbuf[48]; char * musycc_intr_print(u_int32_t id) { snprintf(musycc_intrbuf, sizeof(musycc_intrbuf), "ev %s er %s grp %d chan %d dir %s", musycc_events[MUSYCC_INTD_EVENT(id)], musycc_errors[MUSYCC_INTD_ERROR(id)], MUSYCC_INTD_GRP(id), MUSYCC_INTD_CHAN(id), id & MUSYCC_INTD_DIR ? "T" : "R"); return (musycc_intrbuf); } void musycc_dump_group(int level, struct musycc_group *mg) { struct musycc_grpdesc *md = mg->mg_group; u_int32_t d; int i; if (level > accoom_debug) return; printf("%s: dumping group %d\n", mg->mg_hdlc->mc_dev.dv_xname, mg->mg_gnum); printf("===========================================================\n"); printf("global conf: %08x\n", letoh32(md->global_conf)); d = letoh32(md->group_conf); printf("group conf: [%08x] %s %s %s int %s%s inhib BSD %s%s poll %d\n", d, d & MUSYCC_GRCFG_TXENBL ? "TX" : "", d & MUSYCC_GRCFG_RXENBL ? "RX" : "", d & MUSYCC_GRCFG_SUBDSBL ? "" : "SUB", d & MUSYCC_GRCFG_MSKOOF ? "" : "O", d & MUSYCC_GRCFG_MSKCOFA ? "" : "C", d & MUSYCC_GRCFG_INHTBSD ? "TX" : "", d & MUSYCC_GRCFG_INHRBSD ? "RX" : "", (d & MUSYCC_GRCFG_POLL64) == MUSYCC_GRCFG_POLL64 ? 64 : d & MUSYCC_GRCFG_POLL32 ? 32 : d & MUSYCC_GRCFG_POLL16 ? 16 : 1); d = letoh32(md->port_conf); printf("port conf: [%08x] %s %s %s %s %s %s %s\n", d, mu_mode[d & MUSYCC_PORT_MODEMASK], d & MUSYCC_PORT_TDAT_EDGE ? "TXE" : "!TXE", d & MUSYCC_PORT_TSYNC_EDGE ? "TXS" : "!TXS", d & MUSYCC_PORT_RDAT_EDGE ? "RXE" : "!RXE", d & MUSYCC_PORT_RSYNC_EDGE ? "RXS" : "!RXS", d & MUSYCC_PORT_ROOF_EDGE ? "ROOF" : "!ROOF", d & MUSYCC_PORT_TRITX ? "!tri-state" : "tri-state"); printf("message len 1: %d 2: %d\n", letoh32(md->msglen_conf) & MUSYCC_MAXFRM_MASK, (letoh32(md->msglen_conf) >> MUSYCC_MAXFRM2_SHIFT) & MUSYCC_MAXFRM_MASK); printf("interrupt queue %x len %d\n", letoh32(md->int_queuep), letoh32(md->int_queuelen)); printf("memory protection %x\n", letoh32(md->memprot)); printf("===========================================================\n"); printf("Timeslot Map:TX\t\tRX\n"); for (i = 0; i < 128; i++) { if (md->tx_tsmap[i] & MUSYCC_TSLOT_ENABLED) printf("%d: %s%s%s[%02d]\t\t", i, md->tx_tsmap[i] & MUSYCC_TSLOT_ENABLED ? "C" : " ", md->tx_tsmap[i] & MUSYCC_TSLOT_SUB ? "S" : " ", md->tx_tsmap[i] & MUSYCC_TSLOT_56K ? "*" : " ", MUSYCC_TSLOT_CHAN(md->tx_tsmap[i])); else if (md->rx_tsmap[i] & MUSYCC_TSLOT_ENABLED) printf("%d: \t\t", i); if (md->rx_tsmap[i] & MUSYCC_TSLOT_ENABLED) printf("%s%s%s[%02d]\n", md->rx_tsmap[i] & MUSYCC_TSLOT_ENABLED ? "C" : " ", md->rx_tsmap[i] & MUSYCC_TSLOT_SUB ? "S" : " ", md->rx_tsmap[i] & MUSYCC_TSLOT_56K ? "*" : " ", MUSYCC_TSLOT_CHAN(md->rx_tsmap[i])); else printf("\n"); } printf("===========================================================\n"); printf("Channel config:\nTX\t\t\tRX\n"); for (i = 0; i < 32; i++) if (md->tx_cconf[i] != 0) { d = letoh32(md->tx_cconf[i]); printf("%s%s%s%s%s%s%s %s [%x]\t", d & MUSYCC_CHAN_MSKBUFF ? "B" : " ", d & MUSYCC_CHAN_MSKEOM ? "E" : " ", d & MUSYCC_CHAN_MSKMSG ? "M" : " ", d & MUSYCC_CHAN_MSKIDLE ? "I" : " ", d & MUSYCC_CHAN_FCS ? "F" : "", d & MUSYCC_CHAN_MAXLEN1 ? "1" : "", d & MUSYCC_CHAN_MAXLEN2 ? "2" : "", mu_proto[MUSYCC_CHAN_PROTO_GET(d)], d); d = letoh32(md->rx_cconf[i]); printf("%s%s%s%s%s%s%s %s [%x]\n", d & MUSYCC_CHAN_MSKBUFF ? "B" : " ", d & MUSYCC_CHAN_MSKEOM ? "E" : " ", d & MUSYCC_CHAN_MSKMSG ? "M" : " ", d & MUSYCC_CHAN_MSKIDLE ? "I" : " ", d & MUSYCC_CHAN_FCS ? "F" : "", d & MUSYCC_CHAN_MAXLEN1 ? "1" : "", d & MUSYCC_CHAN_MAXLEN2 ? "2" : "", mu_proto[MUSYCC_CHAN_PROTO_GET(d)], d); } printf("===========================================================\n"); musycc_dump_dma(level, mg, 0); } void musycc_dump_desc(int level, struct musycc_group *mg) { #define READ4(x) \ bus_space_read_4(mg->mg_hdlc->mc_st, mg->mg_hdlc->mc_sh, \ MUSYCC_GROUPBASE(mg->mg_gnum) + (x)) u_int32_t w; u_int8_t c1, c2; int i; if (level > accoom_debug) return; printf("%s: dumping descriptor %d at %p kva %08x + %x dma %08x\n", mg->mg_hdlc->mc_dev.dv_xname, mg->mg_gnum, mg->mg_group, mg->mg_hdlc->mc_cfgmap->dm_segs[0].ds_addr, MUSYCC_GROUPBASE(mg->mg_gnum), READ4(0)); printf("===========================================================\n"); printf("global conf: %08x\n", READ4(MUSYCC_GLOBALCONF)); w = READ4(0x060c); printf("group conf: [%08x] %s %s %s int %s%s inhib BSD %s%s poll %d\n", w, w & MUSYCC_GRCFG_TXENBL ? "TX" : "", w & MUSYCC_GRCFG_RXENBL ? "RX" : "", w & MUSYCC_GRCFG_SUBDSBL ? "" : "SUB", w & MUSYCC_GRCFG_MSKOOF ? "" : "O", w & MUSYCC_GRCFG_MSKCOFA ? "" : "C", w & MUSYCC_GRCFG_INHTBSD ? "TX" : "", w & MUSYCC_GRCFG_INHRBSD ? "RX" : "", (w & MUSYCC_GRCFG_POLL64) == MUSYCC_GRCFG_POLL64 ? 64 : w & MUSYCC_GRCFG_POLL32 ? 32 : w & MUSYCC_GRCFG_POLL16 ? 16 : 1); w = READ4(0x0618); printf("port conf: [%08x] %s %s %s %s %s %s %s\n", w, mu_mode[w & MUSYCC_PORT_MODEMASK], w & MUSYCC_PORT_TDAT_EDGE ? "TXE" : "!TXE", w & MUSYCC_PORT_TSYNC_EDGE ? "TXS" : "!TXS", w & MUSYCC_PORT_RDAT_EDGE ? "RXE" : "!RXE", w & MUSYCC_PORT_RSYNC_EDGE ? "RXS" : "!RXS", w & MUSYCC_PORT_ROOF_EDGE ? "ROOF" : "!ROOF", w & MUSYCC_PORT_TRITX ? "!tri-state" : "tri-state"); w = READ4(0x0614); printf("message len 1: %d 2: %d\n", w & MUSYCC_MAXFRM_MASK, (w >> MUSYCC_MAXFRM2_SHIFT) & MUSYCC_MAXFRM_MASK); printf("interrupt queue %x len %d\n", READ4(0x0604), READ4(0x0608)); printf("memory protection %x\n", READ4(0x0610)); printf("===========================================================\n"); printf("Timeslot Map:TX\t\tRX\n"); for (i = 0; i < 128; i++) { c1 = bus_space_read_1(mg->mg_hdlc->mc_st, mg->mg_hdlc->mc_sh, MUSYCC_GROUPBASE(mg->mg_gnum) + 0x0200 + i); c2 = bus_space_read_1(mg->mg_hdlc->mc_st, mg->mg_hdlc->mc_sh, MUSYCC_GROUPBASE(mg->mg_gnum) + 0x0400 + i); if (c1 & MUSYCC_TSLOT_ENABLED) printf("%d: %s%s%s[%02d]\t\t", i, c1 & MUSYCC_TSLOT_ENABLED ? "C" : " ", c1 & MUSYCC_TSLOT_SUB ? "S" : " ", c1 & MUSYCC_TSLOT_56K ? "*" : " ", MUSYCC_TSLOT_CHAN(c1)); else if (c2 & MUSYCC_TSLOT_ENABLED) printf("%d: \t\t", i); if (c2 & MUSYCC_TSLOT_ENABLED) printf("%s%s%s[%02d]\n", c2 & MUSYCC_TSLOT_ENABLED ? "C" : " ", c2 & MUSYCC_TSLOT_SUB ? "S" : " ", c2 & MUSYCC_TSLOT_56K ? "*" : " ", MUSYCC_TSLOT_CHAN(c2)); else printf("\n"); } printf("===========================================================\n"); printf("Channel config:\nTX\t\t\t\tRX\n"); for (i = 0; i < 32; i++) { w = READ4(0x0380 + i * 4); if (w != 0) { printf("%s%s%s%s%s%s%s %s [%08x]\t", w & MUSYCC_CHAN_MSKBUFF ? "B" : " ", w & MUSYCC_CHAN_MSKEOM ? "E" : " ", w & MUSYCC_CHAN_MSKMSG ? "M" : " ", w & MUSYCC_CHAN_MSKIDLE ? "I" : " ", w & MUSYCC_CHAN_FCS ? "F" : "", w & MUSYCC_CHAN_MAXLEN1 ? "1" : "", w & MUSYCC_CHAN_MAXLEN2 ? "2" : "", mu_proto[MUSYCC_CHAN_PROTO_GET(w)], w); w = READ4(0x0580 + i * 4); printf("%s%s%s%s%s%s%s %s [%08x]\n", w & MUSYCC_CHAN_MSKBUFF ? "B" : " ", w & MUSYCC_CHAN_MSKEOM ? "E" : " ", w & MUSYCC_CHAN_MSKMSG ? "M" : " ", w & MUSYCC_CHAN_MSKIDLE ? "I" : " ", w & MUSYCC_CHAN_FCS ? "F" : "", w & MUSYCC_CHAN_MAXLEN1 ? "1" : "", w & MUSYCC_CHAN_MAXLEN2 ? "2" : "", mu_proto[MUSYCC_CHAN_PROTO_GET(w)], w); } } printf("===========================================================\n"); musycc_dump_dma(level, mg, 0); } void musycc_dump_dma(int level, struct musycc_group *mg, int dir) { struct musycc_grpdesc *md = mg->mg_group; struct dma_desc *dd; bus_addr_t base, addr; int i; if (level > accoom_debug) return; printf("DMA Pointers:\n%8s %8s %8s %8s\n", "tx head", "tx msg", "rx head", "rx msg"); for (i = 0; i < 32; i++) { if (md->tx_headp[i] == 0 && md->rx_headp[i] == 0) continue; printf("%08x %08x %08x %08x\n", md->tx_headp[i], md->tx_msgp[i], md->rx_headp[i], md->rx_msgp[i]); } base = mg->mg_listmap->dm_segs[0].ds_addr; for (i = 0; dir & MUSYCC_SREQ_TX && i < 32; i++) { if (md->tx_headp[i] == 0) continue; printf("==================================================\n"); printf("TX DMA Ring for channel %d\n", i); printf("pend: %p cur: %p cnt: %d use: %d pkgs: %d\n", mg->mg_dma_d[i].tx_pend, mg->mg_dma_d[i].tx_cur, mg->mg_dma_d[i].tx_cnt, mg->mg_dma_d[i].tx_use, mg->mg_dma_d[i].tx_pkts); printf(" %10s %8s %8s %8s %8s %10s\n", "addr", "paddr", "next", "status", "data", "mbuf"); dd = mg->mg_dma_d[i].tx_pend; do { addr = htole32(base + ((caddr_t)dd - mg->mg_listkva)); printf("%s %p %08x %08x %08x %08x %p\n", dd == mg->mg_dma_d[i].tx_pend ? ">" : dd == mg->mg_dma_d[i].tx_cur ? "*" : " ", dd, addr, dd->next, dd->status, dd->data, dd->mbuf); dd = dd->nextdesc; } while (dd != mg->mg_dma_d[i].tx_pend); } for (i = 0; dir & MUSYCC_SREQ_RX && i < 32; i++) { if (md->rx_headp[i] == 0) continue; printf("==================================================\n"); printf("RX DMA Ring for channel %d\n", i); printf("prod: %p cnt: %d\n", mg->mg_dma_d[i].rx_prod, mg->mg_dma_d[i].rx_cnt); printf(" %8s %8s %8s %8s %10s\n", "addr", "paddr", "next", "status", "data", "mbuf"); dd = mg->mg_dma_d[i].rx_prod; do { addr = htole32(base + ((caddr_t)dd - mg->mg_listkva)); printf("%p %08x %08x %08x %08x %p\n", dd, addr, dd->next, dd->status, dd->data, dd->mbuf); dd = dd->nextdesc; } while (dd != mg->mg_dma_d[i].rx_prod); } } #endif