/* $NetBSD: elink3.c,v 1.112 2005/05/30 04:43:46 christos Exp $ */ /*- * Copyright (c) 1998, 2001 The NetBSD Foundation, Inc. * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by Jason R. Thorpe of the Numerical Aerospace Simulation Facility, * NASA Ames Research Center. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the NetBSD * Foundation, Inc. and its contributors. * 4. Neither the name of The NetBSD Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS * ``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 FOUNDATION OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ /* * Copyright (c) 1996, 1997 Jonathan Stone * Copyright (c) 1994 Herb Peyerl * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Herb Peyerl. * 4. The name of Herb Peyerl may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include __KERNEL_RCSID(0, "$NetBSD: elink3.c,v 1.112 2005/05/30 04:43:46 christos Exp $"); #include "opt_inet.h" #include "opt_ns.h" #include "bpfilter.h" #include "rnd.h" #include #include #include #include #include #include #include #include #include #include #include #if NRND > 0 #include #endif #include #include #include #include #if NBPFILTER > 0 #include #include #endif #include #include #include #include #include #include #include #include #ifdef DEBUG int epdebug = 0; #endif /* * XXX endian workaround for big-endian CPUs with pcmcia: * if stream methods for bus_space_multi are not provided, define them * using non-stream bus_space_{read,write}_multi_. * Assumes host CPU is same endian-ness as bus. */ #ifndef __BUS_SPACE_HAS_STREAM_METHODS #define bus_space_read_multi_stream_2 bus_space_read_multi_2 #define bus_space_read_multi_stream_4 bus_space_read_multi_4 #define bus_space_write_multi_stream_2 bus_space_write_multi_2 #define bus_space_write_multi_stream_4 bus_space_write_multi_4 #endif /* __BUS_SPACE_HAS_STREAM_METHODS */ /* * Structure to map media-present bits in boards to ifmedia codes and * printable media names. Used for table-driven ifmedia initialization. */ struct ep_media { int epm_mpbit; /* media present bit */ const char *epm_name; /* name of medium */ int epm_ifmedia; /* ifmedia word for medium */ int epm_epmedia; /* ELINKMEDIA_* constant */ }; /* * Media table for the Demon/Vortex/Boomerang chipsets. * * Note that MII on the Demon and Vortex (3c59x) indicates an external * MII connector (for connecting an external PHY) ... I think. Treat * it as `manual' on these chips. * * Any Boomerang (3c90x) chips with MII really do have an internal * MII and real PHYs attached; no `native' media. */ const struct ep_media ep_vortex_media[] = { { ELINK_PCI_10BASE_T, "10baseT", IFM_ETHER|IFM_10_T, ELINKMEDIA_10BASE_T }, { ELINK_PCI_10BASE_T, "10baseT-FDX", IFM_ETHER|IFM_10_T|IFM_FDX, ELINKMEDIA_10BASE_T }, { ELINK_PCI_AUI, "10base5", IFM_ETHER|IFM_10_5, ELINKMEDIA_AUI }, { ELINK_PCI_BNC, "10base2", IFM_ETHER|IFM_10_2, ELINKMEDIA_10BASE_2 }, { ELINK_PCI_100BASE_TX, "100baseTX", IFM_ETHER|IFM_100_TX, ELINKMEDIA_100BASE_TX }, { ELINK_PCI_100BASE_TX, "100baseTX-FDX",IFM_ETHER|IFM_100_TX|IFM_FDX, ELINKMEDIA_100BASE_TX }, { ELINK_PCI_100BASE_FX, "100baseFX", IFM_ETHER|IFM_100_FX, ELINKMEDIA_100BASE_FX }, { ELINK_PCI_100BASE_MII,"manual", IFM_ETHER|IFM_MANUAL, ELINKMEDIA_MII }, { ELINK_PCI_100BASE_T4, "100baseT4", IFM_ETHER|IFM_100_T4, ELINKMEDIA_100BASE_T4 }, { 0, NULL, 0, 0 }, }; /* * Media table for the older 3Com Etherlink III chipset, used * in the 3c509, 3c579, and 3c589. */ const struct ep_media ep_509_media[] = { { ELINK_W0_CC_UTP, "10baseT", IFM_ETHER|IFM_10_T, ELINKMEDIA_10BASE_T }, { ELINK_W0_CC_AUI, "10base5", IFM_ETHER|IFM_10_5, ELINKMEDIA_AUI }, { ELINK_W0_CC_BNC, "10base2", IFM_ETHER|IFM_10_2, ELINKMEDIA_10BASE_2 }, { 0, NULL, 0, 0 }, }; void ep_internalconfig(struct ep_softc *sc); void ep_vortex_probemedia(struct ep_softc *sc); void ep_509_probemedia(struct ep_softc *sc); static void eptxstat(struct ep_softc *); static int epstatus(struct ep_softc *); int epinit(struct ifnet *); void epstop(struct ifnet *, int); int epioctl(struct ifnet *, u_long, caddr_t); void epstart(struct ifnet *); void epwatchdog(struct ifnet *); void epreset(struct ep_softc *); static void epshutdown(void *); void epread(struct ep_softc *); struct mbuf *epget(struct ep_softc *, int); void epmbuffill(void *); void epmbufempty(struct ep_softc *); void epsetfilter(struct ep_softc *); void ep_roadrunner_mii_enable(struct ep_softc *); void epsetmedia(struct ep_softc *); /* ifmedia callbacks */ int ep_media_change(struct ifnet *ifp); void ep_media_status(struct ifnet *ifp, struct ifmediareq *req); /* MII callbacks */ int ep_mii_readreg(struct device *, int, int); void ep_mii_writereg(struct device *, int, int, int); void ep_statchg(struct device *); void ep_tick(void *); static int epbusyeeprom(struct ep_softc *); u_int16_t ep_read_eeprom(struct ep_softc *, u_int16_t); static inline void ep_reset_cmd(struct ep_softc *sc, u_int cmd, u_int arg); static inline void ep_finish_reset(bus_space_tag_t, bus_space_handle_t); static inline void ep_discard_rxtop(bus_space_tag_t, bus_space_handle_t); static __inline int ep_w1_reg(struct ep_softc *, int); /* * MII bit-bang glue. */ u_int32_t ep_mii_bitbang_read(struct device *); void ep_mii_bitbang_write(struct device *, u_int32_t); const struct mii_bitbang_ops ep_mii_bitbang_ops = { ep_mii_bitbang_read, ep_mii_bitbang_write, { PHYSMGMT_DATA, /* MII_BIT_MDO */ PHYSMGMT_DATA, /* MII_BIT_MDI */ PHYSMGMT_CLK, /* MII_BIT_MDC */ PHYSMGMT_DIR, /* MII_BIT_DIR_HOST_PHY */ 0, /* MII_BIT_DIR_PHY_HOST */ } }; /* * Some chips (3c515 [Corkscrew] and 3c574 [RoadRunner]) have * Window 1 registers offset! */ static __inline int ep_w1_reg(sc, reg) struct ep_softc *sc; int reg; { switch (sc->ep_chipset) { case ELINK_CHIPSET_CORKSCREW: return (reg + 0x10); case ELINK_CHIPSET_ROADRUNNER: switch (reg) { case ELINK_W1_FREE_TX: case ELINK_W1_RUNNER_RDCTL: case ELINK_W1_RUNNER_WRCTL: return (reg); } return (reg + 0x10); } return (reg); } /* * Wait for any pending reset to complete. * On newer hardware we could poll SC_COMMAND_IN_PROGRESS, * but older hardware doesn't implement it and we must delay. */ static inline void ep_finish_reset(iot, ioh) bus_space_tag_t iot; bus_space_handle_t ioh; { int i; for (i = 0; i < 10000; i++) { if ((bus_space_read_2(iot, ioh, ELINK_STATUS) & COMMAND_IN_PROGRESS) == 0) break; DELAY(10); } } /* * Issue a (reset) command, and be sure it has completed. * Used for global reset, TX_RESET, RX_RESET. */ static inline void ep_reset_cmd(sc, cmd, arg) struct ep_softc *sc; u_int cmd, arg; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; bus_space_write_2(iot, ioh, cmd, arg); ep_finish_reset(iot, ioh); } static inline void ep_discard_rxtop(iot, ioh) bus_space_tag_t iot; bus_space_handle_t ioh; { int i; bus_space_write_2(iot, ioh, ELINK_COMMAND, RX_DISCARD_TOP_PACK); /* * Spin for about 1 msec, to avoid forcing a DELAY() between * every received packet (adding latency and limiting pkt-recv rate). * On PCI, at 4 30-nsec PCI bus cycles for a read, 8000 iterations * is about right. */ for (i = 0; i < 8000; i++) { if ((bus_space_read_2(iot, ioh, ELINK_STATUS) & COMMAND_IN_PROGRESS) == 0) return; } /* Didn't complete in a hurry. Do DELAY()s. */ ep_finish_reset(iot, ioh); } /* * Back-end attach and configure. */ int epconfig(sc, chipset, enaddr) struct ep_softc *sc; u_short chipset; u_int8_t *enaddr; { struct ifnet *ifp = &sc->sc_ethercom.ec_if; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; u_int16_t i; u_int8_t myla[ETHER_ADDR_LEN]; callout_init(&sc->sc_mii_callout); callout_init(&sc->sc_mbuf_callout); sc->ep_chipset = chipset; /* * We could have been groveling around in other register * windows in the front-end; make sure we're in window 0 * to read the EEPROM. */ GO_WINDOW(0); if (enaddr == NULL) { /* * Read the station address from the eeprom. */ for (i = 0; i < ETHER_ADDR_LEN / 2; i++) { u_int16_t x = ep_read_eeprom(sc, i); myla[(i << 1)] = x >> 8; myla[(i << 1) + 1] = x; } enaddr = myla; } /* * Vortex-based (3c59x pci,eisa) and Boomerang (3c900) cards * allow FDDI-sized (4500) byte packets. Commands only take an * 11-bit parameter, and 11 bits isn't enough to hold a full-size * packet length. * Commands to these cards implicitly upshift a packet size * or threshold by 2 bits. * To detect cards with large-packet support, we probe by setting * the transmit threshold register, then change windows and * read back the threshold register directly, and see if the * threshold value was shifted or not. */ bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_TX_AVAIL_THRESH | ELINK_LARGEWIN_PROBE); GO_WINDOW(5); i = bus_space_read_2(iot, ioh, ELINK_W5_TX_AVAIL_THRESH); GO_WINDOW(1); switch (i) { case ELINK_LARGEWIN_PROBE: case (ELINK_LARGEWIN_PROBE & ELINK_LARGEWIN_MASK): sc->ep_pktlenshift = 0; break; case (ELINK_LARGEWIN_PROBE << 2): sc->ep_pktlenshift = 2; break; default: aprint_error( "%s: wrote 0x%x to TX_AVAIL_THRESH, read back 0x%x. " "Interface disabled\n", sc->sc_dev.dv_xname, ELINK_LARGEWIN_PROBE, (int) i); return (1); } /* * Ensure Tx-available interrupts are enabled for * start the interface. * XXX should be in epinit()? */ bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_TX_AVAIL_THRESH | (1600 >> sc->ep_pktlenshift)); strcpy(ifp->if_xname, sc->sc_dev.dv_xname); ifp->if_softc = sc; ifp->if_start = epstart; ifp->if_ioctl = epioctl; ifp->if_watchdog = epwatchdog; ifp->if_init = epinit; ifp->if_stop = epstop; ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_NOTRAILERS | IFF_MULTICAST; IFQ_SET_READY(&ifp->if_snd); if_attach(ifp); ether_ifattach(ifp, enaddr); /* * Finish configuration: * determine chipset if the front-end couldn't do so, * show board details, set media. */ /* * Print RAM size. We also print the Ethernet address in here. * It's extracted from the ifp, so we have to make sure it's * been attached first. */ ep_internalconfig(sc); GO_WINDOW(0); /* * Display some additional information, if pertinent. */ if (sc->ep_flags & ELINK_FLAGS_USEFIFOBUFFER) aprint_normal("%s: RoadRunner FIFO buffer enabled\n", sc->sc_dev.dv_xname); /* * Initialize our media structures and MII info. We'll * probe the MII if we discover that we have one. */ sc->sc_mii.mii_ifp = ifp; sc->sc_mii.mii_readreg = ep_mii_readreg; sc->sc_mii.mii_writereg = ep_mii_writereg; sc->sc_mii.mii_statchg = ep_statchg; ifmedia_init(&sc->sc_mii.mii_media, IFM_IMASK, ep_media_change, ep_media_status); /* * All CORKSCREW chips have MII. */ if (sc->ep_chipset == ELINK_CHIPSET_CORKSCREW) sc->ep_flags |= ELINK_FLAGS_MII; /* * Now, determine which media we have. */ switch (sc->ep_chipset) { case ELINK_CHIPSET_ROADRUNNER: if (sc->ep_flags & ELINK_FLAGS_MII) { ep_roadrunner_mii_enable(sc); GO_WINDOW(0); } /* FALLTHROUGH */ case ELINK_CHIPSET_CORKSCREW: case ELINK_CHIPSET_BOOMERANG: /* * If the device has MII, probe it. We won't be using * any `native' media in this case, only PHYs. If * we don't, just treat the Boomerang like the Vortex. */ if (sc->ep_flags & ELINK_FLAGS_MII) { mii_attach(&sc->sc_dev, &sc->sc_mii, 0xffffffff, MII_PHY_ANY, MII_OFFSET_ANY, 0); if (LIST_FIRST(&sc->sc_mii.mii_phys) == NULL) { ifmedia_add(&sc->sc_mii.mii_media, IFM_ETHER|IFM_NONE, 0, NULL); ifmedia_set(&sc->sc_mii.mii_media, IFM_ETHER|IFM_NONE); } else { ifmedia_set(&sc->sc_mii.mii_media, IFM_ETHER|IFM_AUTO); } break; } /* FALLTHROUGH */ case ELINK_CHIPSET_VORTEX: ep_vortex_probemedia(sc); break; default: ep_509_probemedia(sc); break; } GO_WINDOW(1); /* Window 1 is operating window */ #if NRND > 0 rnd_attach_source(&sc->rnd_source, sc->sc_dev.dv_xname, RND_TYPE_NET, 0); #endif sc->tx_start_thresh = 20; /* probably a good starting point. */ /* Establish callback to reset card when we reboot. */ sc->sd_hook = shutdownhook_establish(epshutdown, sc); ep_reset_cmd(sc, ELINK_COMMAND, RX_RESET); ep_reset_cmd(sc, ELINK_COMMAND, TX_RESET); /* The attach is successful. */ sc->sc_flags |= ELINK_FLAGS_ATTACHED; return (0); } /* * Show interface-model-independent info from window 3 * internal-configuration register. */ void ep_internalconfig(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; u_int config0; u_int config1; int ram_size, ram_width, ram_split; /* * NVRAM buffer Rx:Tx config names for busmastering cards * (Demon, Vortex, and later). */ const char *const onboard_ram_config[] = { "5:3", "3:1", "1:1", "3:5" }; GO_WINDOW(3); config0 = (u_int)bus_space_read_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG); config1 = (u_int)bus_space_read_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG + 2); GO_WINDOW(0); ram_size = (config0 & CONFIG_RAMSIZE) >> CONFIG_RAMSIZE_SHIFT; ram_width = (config0 & CONFIG_RAMWIDTH) >> CONFIG_RAMWIDTH_SHIFT; ram_split = (config1 & CONFIG_RAMSPLIT) >> CONFIG_RAMSPLIT_SHIFT; aprint_normal("%s: address %s, %dKB %s-wide FIFO, %s Rx:Tx split\n", sc->sc_dev.dv_xname, ether_sprintf(LLADDR(sc->sc_ethercom.ec_if.if_sadl)), 8 << ram_size, (ram_width) ? "word" : "byte", onboard_ram_config[ram_split]); } /* * Find supported media on 3c509-generation hardware that doesn't have * a "reset_options" register in window 3. * Use the config_cntrl register in window 0 instead. * Used on original, 10Mbit ISA (3c509), 3c509B, and pre-Demon EISA cards * that implement CONFIG_CTRL. We don't have a good way to set the * default active medium; punt to ifconfig instead. */ void ep_509_probemedia(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; struct ifmedia *ifm = &sc->sc_mii.mii_media; u_int16_t ep_w0_config, port; const struct ep_media *epm; const char *sep = "", *defmedianame = NULL; int defmedia = 0; GO_WINDOW(0); ep_w0_config = bus_space_read_2(iot, ioh, ELINK_W0_CONFIG_CTRL); aprint_normal("%s: ", sc->sc_dev.dv_xname); /* Sanity check that there are any media! */ if ((ep_w0_config & ELINK_W0_CC_MEDIAMASK) == 0) { aprint_error("no media present!\n"); ifmedia_add(ifm, IFM_ETHER|IFM_NONE, 0, NULL); ifmedia_set(ifm, IFM_ETHER|IFM_NONE); return; } /* * Get the default media from the EEPROM. */ port = ep_read_eeprom(sc, EEPROM_ADDR_CFG) >> 14; #define PRINT(str) aprint_normal("%s%s", sep, str); sep = ", " for (epm = ep_509_media; epm->epm_name != NULL; epm++) { if (ep_w0_config & epm->epm_mpbit) { /* * This simple test works because 509 chipsets * don't do full-duplex. */ if (epm->epm_epmedia == port || defmedia == 0) { defmedia = epm->epm_ifmedia; defmedianame = epm->epm_name; } ifmedia_add(ifm, epm->epm_ifmedia, epm->epm_epmedia, NULL); PRINT(epm->epm_name); } } #undef PRINT #ifdef DIAGNOSTIC if (defmedia == 0) panic("ep_509_probemedia: impossible"); #endif aprint_normal(" (default %s)\n", defmedianame); ifmedia_set(ifm, defmedia); } /* * Find media present on large-packet-capable elink3 devices. * Show onboard configuration of large-packet-capable elink3 devices * (Demon, Vortex, Boomerang), which do not implement CONFIG_CTRL in window 0. * Use media and card-version info in window 3 instead. */ void ep_vortex_probemedia(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; struct ifmedia *ifm = &sc->sc_mii.mii_media; const struct ep_media *epm; u_int config1; int reset_options; int default_media; /* 3-bit encoding of default (EEPROM) media */ int defmedia = 0; const char *sep = "", *defmedianame = NULL; GO_WINDOW(3); config1 = (u_int)bus_space_read_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG + 2); reset_options = (int)bus_space_read_2(iot, ioh, ELINK_W3_RESET_OPTIONS); GO_WINDOW(0); default_media = (config1 & CONFIG_MEDIAMASK) >> CONFIG_MEDIAMASK_SHIFT; aprint_normal("%s: ", sc->sc_dev.dv_xname); /* Sanity check that there are any media! */ if ((reset_options & ELINK_PCI_MEDIAMASK) == 0) { aprint_error("no media present!\n"); ifmedia_add(ifm, IFM_ETHER|IFM_NONE, 0, NULL); ifmedia_set(ifm, IFM_ETHER|IFM_NONE); return; } #define PRINT(str) aprint_normal("%s%s", sep, str); sep = ", " for (epm = ep_vortex_media; epm->epm_name != NULL; epm++) { if (reset_options & epm->epm_mpbit) { /* * Default media is a little more complicated * on the Vortex. We support full-duplex which * uses the same reset options bit. * * XXX Check EEPROM for default to FDX? */ if (epm->epm_epmedia == default_media) { if ((epm->epm_ifmedia & IFM_FDX) == 0) { defmedia = epm->epm_ifmedia; defmedianame = epm->epm_name; } } else if (defmedia == 0) { defmedia = epm->epm_ifmedia; defmedianame = epm->epm_name; } ifmedia_add(ifm, epm->epm_ifmedia, epm->epm_epmedia, NULL); PRINT(epm->epm_name); } } #undef PRINT #ifdef DIAGNOSTIC if (defmedia == 0) panic("ep_vortex_probemedia: impossible"); #endif aprint_normal(" (default %s)\n", defmedianame); ifmedia_set(ifm, defmedia); } /* * One second timer, used to tick the MII. */ void ep_tick(arg) void *arg; { struct ep_softc *sc = arg; int s; #ifdef DIAGNOSTIC if ((sc->ep_flags & ELINK_FLAGS_MII) == 0) panic("ep_tick"); #endif if ((sc->sc_dev.dv_flags & DVF_ACTIVE) == 0) return; s = splnet(); mii_tick(&sc->sc_mii); splx(s); callout_reset(&sc->sc_mii_callout, hz, ep_tick, sc); } /* * Bring device up. * * The order in here seems important. Otherwise we may not receive * interrupts. ?! */ int epinit(ifp) struct ifnet *ifp; { struct ep_softc *sc = ifp->if_softc; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; int i, error; u_int8_t *addr; if (!sc->enabled && (error = epenable(sc)) != 0) return (error); /* Make sure any pending reset has completed before touching board */ ep_finish_reset(iot, ioh); /* * Cancel any pending I/O. */ epstop(ifp, 0); if (sc->bustype != ELINK_BUS_PCI && sc->bustype != ELINK_BUS_EISA && sc->bustype != ELINK_BUS_MCA) { GO_WINDOW(0); bus_space_write_2(iot, ioh, ELINK_W0_CONFIG_CTRL, 0); bus_space_write_2(iot, ioh, ELINK_W0_CONFIG_CTRL, ENABLE_DRQ_IRQ); } if (sc->bustype == ELINK_BUS_PCMCIA) { bus_space_write_2(iot, ioh, ELINK_W0_RESOURCE_CFG, 0x3f00); } GO_WINDOW(2); /* Reload the ether_addr. */ addr = LLADDR(ifp->if_sadl); for (i = 0; i < 6; i += 2) bus_space_write_2(iot, ioh, ELINK_W2_ADDR_0 + i, (addr[i] << 0) | (addr[i + 1] << 8)); /* * Reset the station-address receive filter. * A bug workaround for busmastering (Vortex, Demon) cards. */ for (i = 0; i < 6; i += 2) bus_space_write_2(iot, ioh, ELINK_W2_RECVMASK_0 + i, 0); ep_reset_cmd(sc, ELINK_COMMAND, RX_RESET); ep_reset_cmd(sc, ELINK_COMMAND, TX_RESET); GO_WINDOW(1); /* Window 1 is operating window */ for (i = 0; i < 31; i++) bus_space_read_2(iot, ioh, ep_w1_reg(sc, ELINK_W1_TX_STATUS)); /* Set threshold for Tx-space available interrupt. */ bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_TX_AVAIL_THRESH | (1600 >> sc->ep_pktlenshift)); if (sc->ep_chipset == ELINK_CHIPSET_ROADRUNNER) { /* * Enable options in the PCMCIA LAN COR register, via * RoadRunner Window 1. * * XXX MAGIC CONSTANTS! */ u_int16_t cor; bus_space_write_2(iot, ioh, ELINK_W1_RUNNER_RDCTL, (1 << 11)); cor = bus_space_read_2(iot, ioh, 0) & ~0x30; if (sc->ep_flags & ELINK_FLAGS_USESHAREDMEM) cor |= 0x10; if (sc->ep_flags & ELINK_FLAGS_FORCENOWAIT) cor |= 0x20; bus_space_write_2(iot, ioh, 0, cor); bus_space_write_2(iot, ioh, ELINK_W1_RUNNER_WRCTL, 0); bus_space_write_2(iot, ioh, ELINK_W1_RUNNER_RDCTL, 0); if (sc->ep_flags & ELINK_FLAGS_MII) { ep_roadrunner_mii_enable(sc); GO_WINDOW(1); } } /* Enable interrupts. */ bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_RD_0_MASK | WATCHED_INTERRUPTS); bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_INTR_MASK | WATCHED_INTERRUPTS); /* * Attempt to get rid of any stray interrupts that occurred during * configuration. On the i386 this isn't possible because one may * already be queued. However, a single stray interrupt is * unimportant. */ bus_space_write_2(iot, ioh, ELINK_COMMAND, ACK_INTR | 0xff); epsetfilter(sc); epsetmedia(sc); bus_space_write_2(iot, ioh, ELINK_COMMAND, RX_ENABLE); bus_space_write_2(iot, ioh, ELINK_COMMAND, TX_ENABLE); epmbuffill(sc); /* Interface is now `running', with no output active. */ ifp->if_flags |= IFF_RUNNING; ifp->if_flags &= ~IFF_OACTIVE; if (sc->ep_flags & ELINK_FLAGS_MII) { /* Start the one second clock. */ callout_reset(&sc->sc_mii_callout, hz, ep_tick, sc); } /* Attempt to start output, if any. */ epstart(ifp); return (0); } /* * Set multicast receive filter. * elink3 hardware has no selective multicast filter in hardware. * Enable reception of all multicasts and filter in software. */ void epsetfilter(sc) struct ep_softc *sc; { struct ifnet *ifp = &sc->sc_ethercom.ec_if; GO_WINDOW(1); /* Window 1 is operating window */ bus_space_write_2(sc->sc_iot, sc->sc_ioh, ELINK_COMMAND, SET_RX_FILTER | FIL_INDIVIDUAL | FIL_BRDCST | ((ifp->if_flags & IFF_MULTICAST) ? FIL_MULTICAST : 0) | ((ifp->if_flags & IFF_PROMISC) ? FIL_PROMISC : 0)); } int ep_media_change(ifp) struct ifnet *ifp; { struct ep_softc *sc = ifp->if_softc; if (sc->enabled && (ifp->if_flags & IFF_UP) != 0) epreset(sc); return (0); } /* * Reset and enable the MII on the RoadRunner. */ void ep_roadrunner_mii_enable(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; GO_WINDOW(3); bus_space_write_2(iot, ioh, ELINK_W3_RESET_OPTIONS, ELINK_PCI_100BASE_MII|ELINK_RUNNER_ENABLE_MII); delay(1000); bus_space_write_2(iot, ioh, ELINK_W3_RESET_OPTIONS, ELINK_PCI_100BASE_MII|ELINK_RUNNER_MII_RESET| ELINK_RUNNER_ENABLE_MII); ep_reset_cmd(sc, ELINK_COMMAND, TX_RESET); ep_reset_cmd(sc, ELINK_COMMAND, RX_RESET); delay(1000); bus_space_write_2(iot, ioh, ELINK_W3_RESET_OPTIONS, ELINK_PCI_100BASE_MII|ELINK_RUNNER_ENABLE_MII); } /* * Set the card to use the specified media. */ void epsetmedia(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; /* Turn everything off. First turn off linkbeat and UTP. */ GO_WINDOW(4); bus_space_write_2(iot, ioh, ELINK_W4_MEDIA_TYPE, 0x0); /* Turn off coax */ bus_space_write_2(iot, ioh, ELINK_COMMAND, STOP_TRANSCEIVER); delay(1000); /* * If the device has MII, select it, and then tell the * PHY which media to use. */ if (sc->ep_flags & ELINK_FLAGS_MII) { int config0, config1; GO_WINDOW(3); if (sc->ep_chipset == ELINK_CHIPSET_ROADRUNNER) { int resopt; resopt = bus_space_read_2(iot, ioh, ELINK_W3_RESET_OPTIONS); bus_space_write_2(iot, ioh, ELINK_W3_RESET_OPTIONS, resopt | ELINK_RUNNER_ENABLE_MII); } config0 = (u_int)bus_space_read_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG); config1 = (u_int)bus_space_read_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG + 2); config1 = config1 & ~CONFIG_MEDIAMASK; config1 |= (ELINKMEDIA_MII << CONFIG_MEDIAMASK_SHIFT); bus_space_write_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG, config0); bus_space_write_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG + 2, config1); GO_WINDOW(1); /* back to operating window */ mii_mediachg(&sc->sc_mii); return; } /* * Now turn on the selected media/transceiver. */ GO_WINDOW(4); switch (IFM_SUBTYPE(sc->sc_mii.mii_media.ifm_cur->ifm_media)) { case IFM_10_T: bus_space_write_2(iot, ioh, ELINK_W4_MEDIA_TYPE, JABBER_GUARD_ENABLE|LINKBEAT_ENABLE); break; case IFM_10_2: bus_space_write_2(iot, ioh, ELINK_COMMAND, START_TRANSCEIVER); DELAY(1000); /* 50ms not enmough? */ break; case IFM_100_TX: case IFM_100_FX: case IFM_100_T4: /* XXX check documentation */ bus_space_write_2(iot, ioh, ELINK_W4_MEDIA_TYPE, LINKBEAT_ENABLE); DELAY(1000); /* not strictly necessary? */ break; case IFM_10_5: bus_space_write_2(iot, ioh, ELINK_W4_MEDIA_TYPE, SQE_ENABLE); DELAY(1000); /* not strictly necessary? */ break; case IFM_MANUAL: /* * Nothing to do here; we are actually enabling the * external PHY on the MII port. */ break; case IFM_NONE: printf("%s: interface disabled\n", sc->sc_dev.dv_xname); return; default: panic("epsetmedia: impossible"); } /* * Tell the chip which port to use. */ switch (sc->ep_chipset) { case ELINK_CHIPSET_VORTEX: case ELINK_CHIPSET_BOOMERANG: { int mctl, config0, config1; GO_WINDOW(3); config0 = (u_int)bus_space_read_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG); config1 = (u_int)bus_space_read_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG + 2); config1 = config1 & ~CONFIG_MEDIAMASK; config1 |= (sc->sc_mii.mii_media.ifm_cur->ifm_data << CONFIG_MEDIAMASK_SHIFT); bus_space_write_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG, config0); bus_space_write_2(iot, ioh, ELINK_W3_INTERNAL_CONFIG + 2, config1); mctl = bus_space_read_2(iot, ioh, ELINK_W3_MAC_CONTROL); if (sc->sc_mii.mii_media.ifm_cur->ifm_media & IFM_FDX) mctl |= MAC_CONTROL_FDX; else mctl &= ~MAC_CONTROL_FDX; bus_space_write_2(iot, ioh, ELINK_W3_MAC_CONTROL, mctl); break; } default: { int w0_addr_cfg; GO_WINDOW(0); w0_addr_cfg = bus_space_read_2(iot, ioh, ELINK_W0_ADDRESS_CFG); w0_addr_cfg &= 0x3fff; bus_space_write_2(iot, ioh, ELINK_W0_ADDRESS_CFG, w0_addr_cfg | (sc->sc_mii.mii_media.ifm_cur->ifm_data << 14)); DELAY(1000); break; } } GO_WINDOW(1); /* Window 1 is operating window */ } /* * Get currently-selected media from card. * (if_media callback, may be called before interface is brought up). */ void ep_media_status(ifp, req) struct ifnet *ifp; struct ifmediareq *req; { struct ep_softc *sc = ifp->if_softc; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; if (sc->enabled == 0) { req->ifm_active = IFM_ETHER|IFM_NONE; req->ifm_status = 0; return; } /* * If we have MII, go ask the PHY what's going on. */ if (sc->ep_flags & ELINK_FLAGS_MII) { mii_pollstat(&sc->sc_mii); req->ifm_active = sc->sc_mii.mii_media_active; req->ifm_status = sc->sc_mii.mii_media_status; return; } /* * Ok, at this point we claim that our active media is * the currently selected media. We'll update our status * if our chipset allows us to detect link. */ req->ifm_active = sc->sc_mii.mii_media.ifm_cur->ifm_media; req->ifm_status = 0; switch (sc->ep_chipset) { case ELINK_CHIPSET_VORTEX: case ELINK_CHIPSET_BOOMERANG: GO_WINDOW(4); req->ifm_status = IFM_AVALID; if (bus_space_read_2(iot, ioh, ELINK_W4_MEDIA_TYPE) & LINKBEAT_DETECT) req->ifm_status |= IFM_ACTIVE; GO_WINDOW(1); /* back to operating window */ break; } } /* * Start outputting on the interface. * Always called as splnet(). */ void epstart(ifp) struct ifnet *ifp; { struct ep_softc *sc = ifp->if_softc; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; struct mbuf *m, *m0; int sh, len, pad; bus_size_t txreg; /* Don't transmit if interface is busy or not running */ if ((ifp->if_flags & (IFF_RUNNING | IFF_OACTIVE)) != IFF_RUNNING) return; startagain: /* Sneak a peek at the next packet */ IFQ_POLL(&ifp->if_snd, m0); if (m0 == 0) return; /* We need to use m->m_pkthdr.len, so require the header */ if ((m0->m_flags & M_PKTHDR) == 0) panic("epstart: no header mbuf"); len = m0->m_pkthdr.len; pad = (4 - len) & 3; /* * The 3c509 automatically pads short packets to minimum ethernet * length, but we drop packets that are too large. Perhaps we should * truncate them instead? */ if (len + pad > ETHER_MAX_LEN) { /* packet is obviously too large: toss it */ ++ifp->if_oerrors; IFQ_DEQUEUE(&ifp->if_snd, m0); m_freem(m0); goto readcheck; } if (bus_space_read_2(iot, ioh, ep_w1_reg(sc, ELINK_W1_FREE_TX)) < len + pad + 4) { bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_TX_AVAIL_THRESH | ((len + pad + 4) >> sc->ep_pktlenshift)); /* not enough room in FIFO */ ifp->if_flags |= IFF_OACTIVE; return; } else { bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_TX_AVAIL_THRESH | ELINK_THRESH_DISABLE); } IFQ_DEQUEUE(&ifp->if_snd, m0); if (m0 == 0) /* not really needed */ return; bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_TX_START_THRESH | ((len / 4 + sc->tx_start_thresh) /* >> sc->ep_pktlenshift*/)); #if NBPFILTER > 0 if (ifp->if_bpf) bpf_mtap(ifp->if_bpf, m0); #endif /* * Do the output at a high interrupt priority level so that an * interrupt from another device won't cause a FIFO underrun. * We choose splsched() since that blocks essentially everything * except for interrupts from serial devices (which typically * lose data if their interrupt isn't serviced fast enough). * * XXX THIS CAN CAUSE CLOCK DRIFT! */ sh = splsched(); txreg = ep_w1_reg(sc, ELINK_W1_TX_PIO_WR_1); if (sc->ep_flags & ELINK_FLAGS_USEFIFOBUFFER) { /* * Prime the FIFO buffer counter (number of 16-bit * words about to be written to the FIFO). * * NOTE: NO OTHER ACCESS CAN BE PERFORMED WHILE THIS * COUNTER IS NON-ZERO! */ bus_space_write_2(iot, ioh, ELINK_W1_RUNNER_WRCTL, (len + pad) >> 1); } bus_space_write_2(iot, ioh, txreg, len); bus_space_write_2(iot, ioh, txreg, 0xffff); /* Second is meaningless */ if (ELINK_IS_BUS_32(sc->bustype)) { for (m = m0; m;) { if (m->m_len > 3) { /* align our reads from core */ if (mtod(m, u_long) & 3) { u_long count = 4 - (mtod(m, u_long) & 3); bus_space_write_multi_1(iot, ioh, txreg, mtod(m, u_int8_t *), count); m->m_data = (void *)(mtod(m, u_long) + count); m->m_len -= count; } bus_space_write_multi_stream_4(iot, ioh, txreg, mtod(m, u_int32_t *), m->m_len >> 2); m->m_data = (void *)(mtod(m, u_long) + (u_long)(m->m_len & ~3)); m->m_len -= m->m_len & ~3; } if (m->m_len) { bus_space_write_multi_1(iot, ioh, txreg, mtod(m, u_int8_t *), m->m_len); } MFREE(m, m0); m = m0; } } else { for (m = m0; m;) { if (m->m_len > 1) { if (mtod(m, u_long) & 1) { bus_space_write_1(iot, ioh, txreg, *(mtod(m, u_int8_t *))); m->m_data = (void *)(mtod(m, u_long) + 1); m->m_len -= 1; } bus_space_write_multi_stream_2(iot, ioh, txreg, mtod(m, u_int16_t *), m->m_len >> 1); } if (m->m_len & 1) { bus_space_write_1(iot, ioh, txreg, *(mtod(m, u_int8_t *) + m->m_len - 1)); } MFREE(m, m0); m = m0; } } while (pad--) bus_space_write_1(iot, ioh, txreg, 0); splx(sh); ++ifp->if_opackets; readcheck: if ((bus_space_read_2(iot, ioh, ep_w1_reg(sc, ELINK_W1_RX_STATUS)) & ERR_INCOMPLETE) == 0) { /* We received a complete packet. */ u_int16_t status = bus_space_read_2(iot, ioh, ELINK_STATUS); if ((status & INTR_LATCH) == 0) { /* * No interrupt, read the packet and continue * Is this supposed to happen? Is my motherboard * completely busted? */ epread(sc); } else { /* Got an interrupt, return so that it gets serviced. */ return; } } else { /* Check if we are stuck and reset [see XXX comment] */ if (epstatus(sc)) { if (ifp->if_flags & IFF_DEBUG) printf("%s: adapter reset\n", sc->sc_dev.dv_xname); epreset(sc); } } goto startagain; } /* * XXX: The 3c509 card can get in a mode where both the fifo status bit * FIFOS_RX_OVERRUN and the status bit ERR_INCOMPLETE are set * We detect this situation and we reset the adapter. * It happens at times when there is a lot of broadcast traffic * on the cable (once in a blue moon). */ static int epstatus(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; u_int16_t fifost; /* * Check the FIFO status and act accordingly */ GO_WINDOW(4); fifost = bus_space_read_2(iot, ioh, ELINK_W4_FIFO_DIAG); GO_WINDOW(1); if (fifost & FIFOS_RX_UNDERRUN) { if (sc->sc_ethercom.ec_if.if_flags & IFF_DEBUG) printf("%s: RX underrun\n", sc->sc_dev.dv_xname); epreset(sc); return 0; } if (fifost & FIFOS_RX_STATUS_OVERRUN) { if (sc->sc_ethercom.ec_if.if_flags & IFF_DEBUG) printf("%s: RX Status overrun\n", sc->sc_dev.dv_xname); return 1; } if (fifost & FIFOS_RX_OVERRUN) { if (sc->sc_ethercom.ec_if.if_flags & IFF_DEBUG) printf("%s: RX overrun\n", sc->sc_dev.dv_xname); return 1; } if (fifost & FIFOS_TX_OVERRUN) { if (sc->sc_ethercom.ec_if.if_flags & IFF_DEBUG) printf("%s: TX overrun\n", sc->sc_dev.dv_xname); epreset(sc); return 0; } return 0; } static void eptxstat(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; int i; /* * We need to read+write TX_STATUS until we get a 0 status * in order to turn off the interrupt flag. */ while ((i = bus_space_read_2(iot, ioh, ep_w1_reg(sc, ELINK_W1_TX_STATUS))) & TXS_COMPLETE) { bus_space_write_2(iot, ioh, ep_w1_reg(sc, ELINK_W1_TX_STATUS), 0x0); if (i & TXS_JABBER) { ++sc->sc_ethercom.ec_if.if_oerrors; if (sc->sc_ethercom.ec_if.if_flags & IFF_DEBUG) printf("%s: jabber (%x)\n", sc->sc_dev.dv_xname, i); epreset(sc); } else if (i & TXS_UNDERRUN) { ++sc->sc_ethercom.ec_if.if_oerrors; if (sc->sc_ethercom.ec_if.if_flags & IFF_DEBUG) printf("%s: fifo underrun (%x) @%d\n", sc->sc_dev.dv_xname, i, sc->tx_start_thresh); if (sc->tx_succ_ok < 100) sc->tx_start_thresh = min(ETHER_MAX_LEN, sc->tx_start_thresh + 20); sc->tx_succ_ok = 0; epreset(sc); } else if (i & TXS_MAX_COLLISION) { ++sc->sc_ethercom.ec_if.if_collisions; bus_space_write_2(iot, ioh, ELINK_COMMAND, TX_ENABLE); sc->sc_ethercom.ec_if.if_flags &= ~IFF_OACTIVE; } else sc->tx_succ_ok = (sc->tx_succ_ok+1) & 127; } } int epintr(arg) void *arg; { struct ep_softc *sc = arg; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; struct ifnet *ifp = &sc->sc_ethercom.ec_if; u_int16_t status; int ret = 0; if (sc->enabled == 0 || (sc->sc_dev.dv_flags & DVF_ACTIVE) == 0) return (0); for (;;) { status = bus_space_read_2(iot, ioh, ELINK_STATUS); if ((status & WATCHED_INTERRUPTS) == 0) { if ((status & INTR_LATCH) == 0) { #if 0 printf("%s: intr latch cleared\n", sc->sc_dev.dv_xname); #endif break; } } ret = 1; /* * Acknowledge any interrupts. It's important that we do this * first, since there would otherwise be a race condition. * Due to the i386 interrupt queueing, we may get spurious * interrupts occasionally. */ bus_space_write_2(iot, ioh, ELINK_COMMAND, ACK_INTR | (status & (INTR_LATCH | ALL_INTERRUPTS))); #if 0 status = bus_space_read_2(iot, ioh, ELINK_STATUS); printf("%s: intr%s%s%s%s\n", sc->sc_dev.dv_xname, (status & RX_COMPLETE)?" RX_COMPLETE":"", (status & TX_COMPLETE)?" TX_COMPLETE":"", (status & TX_AVAIL)?" TX_AVAIL":"", (status & CARD_FAILURE)?" CARD_FAILURE":""); #endif if (status & RX_COMPLETE) { epread(sc); } if (status & TX_AVAIL) { sc->sc_ethercom.ec_if.if_flags &= ~IFF_OACTIVE; epstart(&sc->sc_ethercom.ec_if); } if (status & CARD_FAILURE) { printf("%s: adapter failure (%x)\n", sc->sc_dev.dv_xname, status); #if 1 epinit(ifp); #else epreset(sc); #endif return (1); } if (status & TX_COMPLETE) { eptxstat(sc); epstart(ifp); } #if NRND > 0 if (status) rnd_add_uint32(&sc->rnd_source, status); #endif } /* no more interrupts */ return (ret); } void epread(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; struct ifnet *ifp = &sc->sc_ethercom.ec_if; struct mbuf *m; int len; len = bus_space_read_2(iot, ioh, ep_w1_reg(sc, ELINK_W1_RX_STATUS)); again: if (ifp->if_flags & IFF_DEBUG) { int err = len & ERR_MASK; const char *s = NULL; if (len & ERR_INCOMPLETE) s = "incomplete packet"; else if (err == ERR_OVERRUN) s = "packet overrun"; else if (err == ERR_RUNT) s = "runt packet"; else if (err == ERR_ALIGNMENT) s = "bad alignment"; else if (err == ERR_CRC) s = "bad crc"; else if (err == ERR_OVERSIZE) s = "oversized packet"; else if (err == ERR_DRIBBLE) s = "dribble bits"; if (s) printf("%s: %s\n", sc->sc_dev.dv_xname, s); } if (len & ERR_INCOMPLETE) return; if (len & ERR_RX) { ++ifp->if_ierrors; goto abort; } len &= RX_BYTES_MASK; /* Lower 11 bits = RX bytes. */ /* Pull packet off interface. */ m = epget(sc, len); if (m == 0) { ifp->if_ierrors++; goto abort; } ++ifp->if_ipackets; #if NBPFILTER > 0 /* * Check if there's a BPF listener on this interface. * If so, hand off the raw packet to BPF. */ if (ifp->if_bpf) bpf_mtap(ifp->if_bpf, m); #endif (*ifp->if_input)(ifp, m); /* * In periods of high traffic we can actually receive enough * packets so that the fifo overrun bit will be set at this point, * even though we just read a packet. In this case we * are not going to receive any more interrupts. We check for * this condition and read again until the fifo is not full. * We could simplify this test by not using epstatus(), but * rechecking the RX_STATUS register directly. This test could * result in unnecessary looping in cases where there is a new * packet but the fifo is not full, but it will not fix the * stuck behavior. * * Even with this improvement, we still get packet overrun errors * which are hurting performance. Maybe when I get some more time * I'll modify epread() so that it can handle RX_EARLY interrupts. */ if (epstatus(sc)) { len = bus_space_read_2(iot, ioh, ep_w1_reg(sc, ELINK_W1_RX_STATUS)); /* Check if we are stuck and reset [see XXX comment] */ if (len & ERR_INCOMPLETE) { if (ifp->if_flags & IFF_DEBUG) printf("%s: adapter reset\n", sc->sc_dev.dv_xname); epreset(sc); return; } goto again; } return; abort: ep_discard_rxtop(iot, ioh); } struct mbuf * epget(sc, totlen) struct ep_softc *sc; int totlen; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; struct ifnet *ifp = &sc->sc_ethercom.ec_if; struct mbuf *m; bus_size_t rxreg; int len, remaining; int s; caddr_t newdata; u_long offset; m = sc->mb[sc->next_mb]; sc->mb[sc->next_mb] = 0; if (m == 0) { MGETHDR(m, M_DONTWAIT, MT_DATA); if (m == 0) return 0; } else { /* If the queue is no longer full, refill. */ if (sc->last_mb == sc->next_mb) callout_reset(&sc->sc_mbuf_callout, 1, epmbuffill, sc); /* Convert one of our saved mbuf's. */ sc->next_mb = (sc->next_mb + 1) % MAX_MBS; m->m_data = m->m_pktdat; m->m_flags = M_PKTHDR; memset(&m->m_pkthdr, 0, sizeof(m->m_pkthdr)); } m->m_pkthdr.rcvif = ifp; m->m_pkthdr.len = totlen; len = MHLEN; /* * Allocate big enough space to hold whole packet, to avoid * allocating new mbufs on splsched(). */ if (totlen + ALIGNBYTES > len) { if (totlen + ALIGNBYTES > MCLBYTES) { len = ALIGN(totlen + ALIGNBYTES); MEXTMALLOC(m, len, M_DONTWAIT); } else { len = MCLBYTES; MCLGET(m, M_DONTWAIT); } if ((m->m_flags & M_EXT) == 0) { m_free(m); return 0; } } /* align the struct ip header */ newdata = (caddr_t) ALIGN(m->m_data + sizeof(struct ether_header)) - sizeof(struct ether_header); m->m_data = newdata; m->m_len = totlen; rxreg = ep_w1_reg(sc, ELINK_W1_RX_PIO_RD_1); remaining = totlen; offset = mtod(m, u_long); /* * We read the packet at a high interrupt priority level so that * an interrupt from another device won't cause the card's packet * buffer to overflow. We choose splsched() since that blocks * essentially everything except for interrupts from serial * devices (which typically lose data if their interrupt isn't * serviced fast enough). * * XXX THIS CAN CAUSE CLOCK DRIFT! */ s = splsched(); if (sc->ep_flags & ELINK_FLAGS_USEFIFOBUFFER) { /* * Prime the FIFO buffer counter (number of 16-bit * words about to be read from the FIFO). * * NOTE: NO OTHER ACCESS CAN BE PERFORMED WHILE THIS * COUNTER IS NON-ZERO! */ bus_space_write_2(iot, ioh, ELINK_W1_RUNNER_RDCTL, totlen >> 1); } if (ELINK_IS_BUS_32(sc->bustype)) { /* * Read bytes up to the point where we are aligned. * (We can align to 4 bytes, rather than ALIGNBYTES, * here because we're later reading 4-byte chunks.) */ if ((remaining > 3) && (offset & 3)) { int count = (4 - (offset & 3)); bus_space_read_multi_1(iot, ioh, rxreg, (u_int8_t *) offset, count); offset += count; remaining -= count; } if (remaining > 3) { bus_space_read_multi_stream_4(iot, ioh, rxreg, (u_int32_t *) offset, remaining >> 2); offset += remaining & ~3; remaining &= 3; } if (remaining) { bus_space_read_multi_1(iot, ioh, rxreg, (u_int8_t *) offset, remaining); } } else { if ((remaining > 1) && (offset & 1)) { bus_space_read_multi_1(iot, ioh, rxreg, (u_int8_t *) offset, 1); remaining -= 1; offset += 1; } if (remaining > 1) { bus_space_read_multi_stream_2(iot, ioh, rxreg, (u_int16_t *) offset, remaining >> 1); offset += remaining & ~1; } if (remaining & 1) { bus_space_read_multi_1(iot, ioh, rxreg, (u_int8_t *) offset, remaining & 1); } } ep_discard_rxtop(iot, ioh); if (sc->ep_flags & ELINK_FLAGS_USEFIFOBUFFER) bus_space_write_2(iot, ioh, ELINK_W1_RUNNER_RDCTL, 0); splx(s); return (m); } int epioctl(ifp, cmd, data) struct ifnet *ifp; u_long cmd; caddr_t data; { struct ep_softc *sc = ifp->if_softc; struct ifreq *ifr = (struct ifreq *)data; int s, error = 0; s = splnet(); switch (cmd) { case SIOCSIFMEDIA: case SIOCGIFMEDIA: error = ifmedia_ioctl(ifp, ifr, &sc->sc_mii.mii_media, cmd); break; case SIOCADDMULTI: case SIOCDELMULTI: if (sc->enabled == 0) { error = EIO; break; } default: error = ether_ioctl(ifp, cmd, data); if (error == ENETRESET) { /* * Multicast list has changed; set the hardware filter * accordingly. */ if (ifp->if_flags & IFF_RUNNING) epreset(sc); error = 0; } break; } splx(s); return (error); } void epreset(sc) struct ep_softc *sc; { int s; s = splnet(); epinit(&sc->sc_ethercom.ec_if); splx(s); } void epwatchdog(ifp) struct ifnet *ifp; { struct ep_softc *sc = ifp->if_softc; log(LOG_ERR, "%s: device timeout\n", sc->sc_dev.dv_xname); ++sc->sc_ethercom.ec_if.if_oerrors; epreset(sc); } void epstop(ifp, disable) struct ifnet *ifp; int disable; { struct ep_softc *sc = ifp->if_softc; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; if (sc->ep_flags & ELINK_FLAGS_MII) { /* Stop the one second clock. */ callout_stop(&sc->sc_mbuf_callout); /* Down the MII. */ mii_down(&sc->sc_mii); } if (sc->ep_chipset == ELINK_CHIPSET_ROADRUNNER) { /* * Clear the FIFO buffer count, thus halting * any currently-running transactions. */ GO_WINDOW(1); /* sanity */ bus_space_write_2(iot, ioh, ELINK_W1_RUNNER_WRCTL, 0); bus_space_write_2(iot, ioh, ELINK_W1_RUNNER_RDCTL, 0); } bus_space_write_2(iot, ioh, ELINK_COMMAND, RX_DISABLE); ep_discard_rxtop(iot, ioh); bus_space_write_2(iot, ioh, ELINK_COMMAND, TX_DISABLE); bus_space_write_2(iot, ioh, ELINK_COMMAND, STOP_TRANSCEIVER); ep_reset_cmd(sc, ELINK_COMMAND, RX_RESET); ep_reset_cmd(sc, ELINK_COMMAND, TX_RESET); bus_space_write_2(iot, ioh, ELINK_COMMAND, ACK_INTR | INTR_LATCH); bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_RD_0_MASK); bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_INTR_MASK); bus_space_write_2(iot, ioh, ELINK_COMMAND, SET_RX_FILTER); epmbufempty(sc); if (disable) epdisable(sc); ifp->if_flags &= ~IFF_RUNNING; } /* * Before reboots, reset card completely. */ static void epshutdown(arg) void *arg; { struct ep_softc *sc = arg; int s = splnet(); if (sc->enabled) { epstop(&sc->sc_ethercom.ec_if, 0); ep_reset_cmd(sc, ELINK_COMMAND, GLOBAL_RESET); epdisable(sc); sc->enabled = 0; } splx(s); } /* * We get eeprom data from the id_port given an offset into the * eeprom. Basically; after the ID_sequence is sent to all of * the cards; they enter the ID_CMD state where they will accept * command requests. 0x80-0xbf loads the eeprom data. We then * read the port 16 times and with every read; the cards check * for contention (ie: if one card writes a 0 bit and another * writes a 1 bit then the host sees a 0. At the end of the cycle; * each card compares the data on the bus; if there is a difference * then that card goes into ID_WAIT state again). In the meantime; * one bit of data is returned in the AX register which is conveniently * returned to us by bus_space_read_2(). Hence; we read 16 times getting one * bit of data with each read. * * NOTE: the caller must provide an i/o handle for ELINK_ID_PORT! */ u_int16_t epreadeeprom(iot, ioh, offset) bus_space_tag_t iot; bus_space_handle_t ioh; int offset; { u_int16_t data = 0; int i; bus_space_write_2(iot, ioh, 0, 0x80 + offset); delay(1000); for (i = 0; i < 16; i++) data = (data << 1) | (bus_space_read_2(iot, ioh, 0) & 1); return (data); } static int epbusyeeprom(sc) struct ep_softc *sc; { bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; bus_size_t eecmd; int i = 100, j; uint16_t busybit; if (sc->bustype == ELINK_BUS_PCMCIA) { delay(1000); return 0; } if (sc->ep_chipset == ELINK_CHIPSET_CORKSCREW) { eecmd = CORK_ASIC_EEPROM_COMMAND; busybit = CORK_EEPROM_BUSY; } else { eecmd = ELINK_W0_EEPROM_COMMAND; busybit = EEPROM_BUSY; } j = 0; /* bad GCC flow analysis */ while (i--) { j = bus_space_read_2(iot, ioh, eecmd); if (j & busybit) delay(100); else break; } if (i == 0) { printf("\n%s: eeprom failed to come ready\n", sc->sc_dev.dv_xname); return (1); } if (sc->ep_chipset != ELINK_CHIPSET_CORKSCREW && (j & EEPROM_TST_MODE) != 0) { /* XXX PnP mode? */ printf("\n%s: erase pencil mark!\n", sc->sc_dev.dv_xname); return (1); } return (0); } u_int16_t ep_read_eeprom(sc, offset) struct ep_softc *sc; u_int16_t offset; { bus_size_t eecmd, eedata; u_int16_t readcmd; if (sc->ep_chipset == ELINK_CHIPSET_CORKSCREW) { eecmd = CORK_ASIC_EEPROM_COMMAND; eedata = CORK_ASIC_EEPROM_DATA; } else { eecmd = ELINK_W0_EEPROM_COMMAND; eedata = ELINK_W0_EEPROM_DATA; } /* * RoadRunner has a larger EEPROM, so a different read command * is required. */ if (sc->ep_chipset == ELINK_CHIPSET_ROADRUNNER) readcmd = READ_EEPROM_RR; else readcmd = READ_EEPROM; if (epbusyeeprom(sc)) return (0); /* XXX why is eeprom busy? */ bus_space_write_2(sc->sc_iot, sc->sc_ioh, eecmd, readcmd | offset); if (epbusyeeprom(sc)) return (0); /* XXX why is eeprom busy? */ return (bus_space_read_2(sc->sc_iot, sc->sc_ioh, eedata)); } void epmbuffill(v) void *v; { struct ep_softc *sc = v; struct mbuf *m; int s, i; s = splnet(); i = sc->last_mb; do { if (sc->mb[i] == 0) { MGET(m, M_DONTWAIT, MT_DATA); if (m == 0) break; sc->mb[i] = m; } i = (i + 1) % MAX_MBS; } while (i != sc->next_mb); sc->last_mb = i; /* If the queue was not filled, try again. */ if (sc->last_mb != sc->next_mb) callout_reset(&sc->sc_mbuf_callout, 1, epmbuffill, sc); splx(s); } void epmbufempty(sc) struct ep_softc *sc; { int s, i; s = splnet(); for (i = 0; imb[i]) { m_freem(sc->mb[i]); sc->mb[i] = NULL; } } sc->last_mb = sc->next_mb = 0; callout_stop(&sc->sc_mbuf_callout); splx(s); } int epenable(sc) struct ep_softc *sc; { if (sc->enabled == 0 && sc->enable != NULL) { if ((*sc->enable)(sc) != 0) { printf("%s: device enable failed\n", sc->sc_dev.dv_xname); return (EIO); } } sc->enabled = 1; return (0); } void epdisable(sc) struct ep_softc *sc; { if (sc->enabled != 0 && sc->disable != NULL) { (*sc->disable)(sc); sc->enabled = 0; } } /* * ep_activate: * * Handle device activation/deactivation requests. */ int ep_activate(self, act) struct device *self; enum devact act; { struct ep_softc *sc = (struct ep_softc *)self; struct ifnet *ifp = &sc->sc_ethercom.ec_if; int error = 0, s; s = splnet(); switch (act) { case DVACT_ACTIVATE: error = EOPNOTSUPP; break; case DVACT_DEACTIVATE: if (sc->ep_flags & ELINK_FLAGS_MII) mii_activate(&sc->sc_mii, act, MII_PHY_ANY, MII_OFFSET_ANY); if_deactivate(ifp); break; } splx(s); return (error); } /* * ep_detach: * * Detach a elink3 interface. */ int ep_detach(self, flags) struct device *self; int flags; { struct ep_softc *sc = (struct ep_softc *)self; struct ifnet *ifp = &sc->sc_ethercom.ec_if; /* Succeed now if there's no work to do. */ if ((sc->sc_flags & ELINK_FLAGS_ATTACHED) == 0) return (0); epdisable(sc); callout_stop(&sc->sc_mii_callout); callout_stop(&sc->sc_mbuf_callout); if (sc->ep_flags & ELINK_FLAGS_MII) { /* Detach all PHYs */ mii_detach(&sc->sc_mii, MII_PHY_ANY, MII_OFFSET_ANY); } /* Delete all remaining media. */ ifmedia_delete_instance(&sc->sc_mii.mii_media, IFM_INST_ANY); #if NRND > 0 rnd_detach_source(&sc->rnd_source); #endif ether_ifdetach(ifp); if_detach(ifp); shutdownhook_disestablish(sc->sd_hook); return (0); } u_int32_t ep_mii_bitbang_read(self) struct device *self; { struct ep_softc *sc = (void *) self; /* We're already in Window 4. */ return (bus_space_read_2(sc->sc_iot, sc->sc_ioh, ELINK_W4_BOOM_PHYSMGMT)); } void ep_mii_bitbang_write(self, val) struct device *self; u_int32_t val; { struct ep_softc *sc = (void *) self; /* We're already in Window 4. */ bus_space_write_2(sc->sc_iot, sc->sc_ioh, ELINK_W4_BOOM_PHYSMGMT, val); } int ep_mii_readreg(self, phy, reg) struct device *self; int phy, reg; { struct ep_softc *sc = (void *) self; int val; GO_WINDOW(4); val = mii_bitbang_readreg(self, &ep_mii_bitbang_ops, phy, reg); GO_WINDOW(1); return (val); } void ep_mii_writereg(self, phy, reg, val) struct device *self; int phy, reg, val; { struct ep_softc *sc = (void *) self; GO_WINDOW(4); mii_bitbang_writereg(self, &ep_mii_bitbang_ops, phy, reg, val); GO_WINDOW(1); } void ep_statchg(self) struct device *self; { struct ep_softc *sc = (struct ep_softc *)self; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; int mctl; GO_WINDOW(3); mctl = bus_space_read_2(iot, ioh, ELINK_W3_MAC_CONTROL); if (sc->sc_mii.mii_media_active & IFM_FDX) mctl |= MAC_CONTROL_FDX; else mctl &= ~MAC_CONTROL_FDX; bus_space_write_2(iot, ioh, ELINK_W3_MAC_CONTROL, mctl); GO_WINDOW(1); /* back to operating window */ }