/*- * Copyright (c) 2012 The NetBSD Foundation, Inc. * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by Matt Thomas of 3am Software Foundry. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE 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. */ #define _ARM32_BUS_DMA_PRIVATE #define GMAC_PRIVATE #include "locators.h" #include "opt_broadcom.h" #include __KERNEL_RCSID(1, "$NetBSD: bcm53xx_eth.c,v 1.42 2022/09/17 19:41:18 thorpej Exp $"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include //#define BCMETH_MPSAFE #ifdef BCMETH_COUNTERS #define BCMETH_EVCNT_ADD(a, b) ((void)((a).ev_count += (b))) #else #define BCMETH_EVCNT_ADD(a, b) do { } while (/*CONSTCOND*/0) #endif #define BCMETH_EVCNT_INCR(a) BCMETH_EVCNT_ADD((a), 1) #define BCMETH_MAXTXMBUFS 128 #define BCMETH_NTXSEGS 30 #define BCMETH_MAXRXMBUFS 255 #define BCMETH_MINRXMBUFS 64 #define BCMETH_NRXSEGS 1 #define BCMETH_RINGSIZE PAGE_SIZE #if 1 #define BCMETH_RCVMAGIC 0xfeedface #endif static int bcmeth_ccb_match(device_t, cfdata_t, void *); static void bcmeth_ccb_attach(device_t, device_t, void *); struct bcmeth_txqueue { bus_dmamap_t txq_descmap; struct gmac_txdb *txq_consumer; struct gmac_txdb *txq_producer; struct gmac_txdb *txq_first; struct gmac_txdb *txq_last; struct ifqueue txq_mbufs; struct mbuf *txq_next; size_t txq_free; size_t txq_threshold; size_t txq_lastintr; bus_size_t txq_reg_xmtaddrlo; bus_size_t txq_reg_xmtptr; bus_size_t txq_reg_xmtctl; bus_size_t txq_reg_xmtsts0; bus_size_t txq_reg_xmtsts1; bus_dma_segment_t txq_descmap_seg; }; struct bcmeth_rxqueue { bus_dmamap_t rxq_descmap; struct gmac_rxdb *rxq_consumer; struct gmac_rxdb *rxq_producer; struct gmac_rxdb *rxq_first; struct gmac_rxdb *rxq_last; struct mbuf *rxq_mhead; struct mbuf **rxq_mtail; struct mbuf *rxq_mconsumer; size_t rxq_inuse; size_t rxq_threshold; bus_size_t rxq_reg_rcvaddrlo; bus_size_t rxq_reg_rcvptr; bus_size_t rxq_reg_rcvctl; bus_size_t rxq_reg_rcvsts0; bus_size_t rxq_reg_rcvsts1; bus_dma_segment_t rxq_descmap_seg; }; struct bcmeth_mapcache { u_int dmc_nmaps; u_int dmc_maxseg; u_int dmc_maxmaps; u_int dmc_maxmapsize; bus_dmamap_t dmc_maps[0]; }; struct bcmeth_softc { device_t sc_dev; bus_space_tag_t sc_bst; bus_space_handle_t sc_bsh; bus_dma_tag_t sc_dmat; kmutex_t *sc_lock; kmutex_t *sc_hwlock; struct ethercom sc_ec; #define sc_if sc_ec.ec_if struct ifmedia sc_media; void *sc_soft_ih; void *sc_ih; struct bcmeth_rxqueue sc_rxq; struct bcmeth_txqueue sc_txq; size_t sc_rcvoffset; uint32_t sc_macaddr[2]; uint32_t sc_maxfrm; uint32_t sc_cmdcfg; uint32_t sc_intmask; uint32_t sc_rcvlazy; volatile uint32_t sc_soft_flags; #define SOFT_RXINTR 0x01 #define SOFT_TXINTR 0x02 #ifdef BCMETH_COUNTERS struct evcnt sc_ev_intr; struct evcnt sc_ev_soft_intr; struct evcnt sc_ev_work; struct evcnt sc_ev_tx_stall; struct evcnt sc_ev_rx_badmagic_lo; struct evcnt sc_ev_rx_badmagic_hi; #endif struct ifqueue sc_rx_bufcache; struct bcmeth_mapcache *sc_rx_mapcache; struct bcmeth_mapcache *sc_tx_mapcache; struct workqueue *sc_workq; struct work sc_work; volatile uint32_t sc_work_flags; #define WORK_RXINTR 0x01 #define WORK_RXUNDERFLOW 0x02 #define WORK_REINIT 0x04 uint8_t sc_enaddr[ETHER_ADDR_LEN]; }; static void bcmeth_ifstart(struct ifnet *); static void bcmeth_ifwatchdog(struct ifnet *); static int bcmeth_ifinit(struct ifnet *); static void bcmeth_ifstop(struct ifnet *, int); static int bcmeth_ifioctl(struct ifnet *, u_long, void *); static int bcmeth_mapcache_create(struct bcmeth_softc *, struct bcmeth_mapcache **, size_t, size_t, size_t); static void bcmeth_mapcache_destroy(struct bcmeth_softc *, struct bcmeth_mapcache *); static bus_dmamap_t bcmeth_mapcache_get(struct bcmeth_softc *, struct bcmeth_mapcache *); static void bcmeth_mapcache_put(struct bcmeth_softc *, struct bcmeth_mapcache *, bus_dmamap_t); static int bcmeth_txq_attach(struct bcmeth_softc *, struct bcmeth_txqueue *, u_int); static void bcmeth_txq_purge(struct bcmeth_softc *, struct bcmeth_txqueue *); static void bcmeth_txq_reset(struct bcmeth_softc *, struct bcmeth_txqueue *); static bool bcmeth_txq_consume(struct bcmeth_softc *, struct bcmeth_txqueue *); static bool bcmeth_txq_produce(struct bcmeth_softc *, struct bcmeth_txqueue *, struct mbuf *m); static bool bcmeth_txq_active_p(struct bcmeth_softc *, struct bcmeth_txqueue *); static int bcmeth_rxq_attach(struct bcmeth_softc *, struct bcmeth_rxqueue *, u_int); static bool bcmeth_rxq_produce(struct bcmeth_softc *, struct bcmeth_rxqueue *); static void bcmeth_rxq_purge(struct bcmeth_softc *, struct bcmeth_rxqueue *, bool); static void bcmeth_rxq_reset(struct bcmeth_softc *, struct bcmeth_rxqueue *); static int bcmeth_intr(void *); #ifdef BCMETH_MPSAFETX static void bcmeth_soft_txintr(struct bcmeth_softc *); #endif static void bcmeth_soft_intr(void *); static void bcmeth_worker(struct work *, void *); static int bcmeth_mediachange(struct ifnet *); static void bcmeth_mediastatus(struct ifnet *, struct ifmediareq *); static inline uint32_t bcmeth_read_4(struct bcmeth_softc *sc, bus_size_t o) { return bus_space_read_4(sc->sc_bst, sc->sc_bsh, o); } static inline void bcmeth_write_4(struct bcmeth_softc *sc, bus_size_t o, uint32_t v) { bus_space_write_4(sc->sc_bst, sc->sc_bsh, o, v); } CFATTACH_DECL_NEW(bcmeth_ccb, sizeof(struct bcmeth_softc), bcmeth_ccb_match, bcmeth_ccb_attach, NULL, NULL); static int bcmeth_ccb_match(device_t parent, cfdata_t cf, void *aux) { struct bcmccb_attach_args * const ccbaa = aux; const struct bcm_locators * const loc = &ccbaa->ccbaa_loc; if (strcmp(cf->cf_name, loc->loc_name)) return 0; #ifdef DIAGNOSTIC const int port = cf->cf_loc[BCMCCBCF_PORT]; #endif KASSERT(port == BCMCCBCF_PORT_DEFAULT || port == loc->loc_port); return 1; } static void bcmeth_ccb_attach(device_t parent, device_t self, void *aux) { struct bcmeth_softc * const sc = device_private(self); struct ethercom * const ec = &sc->sc_ec; struct ifnet * const ifp = &ec->ec_if; struct bcmccb_attach_args * const ccbaa = aux; const struct bcm_locators * const loc = &ccbaa->ccbaa_loc; const char * const xname = device_xname(self); prop_dictionary_t dict = device_properties(self); int error; sc->sc_bst = ccbaa->ccbaa_ccb_bst; sc->sc_dmat = ccbaa->ccbaa_dmat; bus_space_subregion(sc->sc_bst, ccbaa->ccbaa_ccb_bsh, loc->loc_offset, loc->loc_size, &sc->sc_bsh); /* * We need to use the coherent dma tag for the GMAC. */ sc->sc_dmat = &bcm53xx_coherent_dma_tag; #if _ARM32_NEED_BUS_DMA_BOUNCE if (device_cfdata(self)->cf_flags & 2) { sc->sc_dmat = &bcm53xx_bounce_dma_tag; } #endif prop_data_t eaprop = prop_dictionary_get(dict, "mac-address"); if (eaprop == NULL) { uint32_t mac0 = bcmeth_read_4(sc, UNIMAC_MAC_0); uint32_t mac1 = bcmeth_read_4(sc, UNIMAC_MAC_1); if ((mac0 == 0 && mac1 == 0) || (mac1 & 1)) { aprint_error(": mac-address property is missing\n"); return; } sc->sc_enaddr[0] = (mac0 >> 0) & 0xff; sc->sc_enaddr[1] = (mac0 >> 8) & 0xff; sc->sc_enaddr[2] = (mac0 >> 16) & 0xff; sc->sc_enaddr[3] = (mac0 >> 24) & 0xff; sc->sc_enaddr[4] = (mac1 >> 0) & 0xff; sc->sc_enaddr[5] = (mac1 >> 8) & 0xff; } else { KASSERT(prop_object_type(eaprop) == PROP_TYPE_DATA); KASSERT(prop_data_size(eaprop) == ETHER_ADDR_LEN); memcpy(sc->sc_enaddr, prop_data_data_nocopy(eaprop), ETHER_ADDR_LEN); } sc->sc_dev = self; sc->sc_lock = mutex_obj_alloc(MUTEX_DEFAULT, IPL_SOFTNET); sc->sc_hwlock = mutex_obj_alloc(MUTEX_DEFAULT, IPL_VM); bcmeth_write_4(sc, GMAC_INTMASK, 0); // disable interrupts aprint_naive("\n"); aprint_normal(": Gigabit Ethernet Controller\n"); error = bcmeth_rxq_attach(sc, &sc->sc_rxq, 0); if (error) { aprint_error(": failed to init rxq: %d\n", error); goto fail_1; } error = bcmeth_txq_attach(sc, &sc->sc_txq, 0); if (error) { aprint_error(": failed to init txq: %d\n", error); goto fail_1; } error = bcmeth_mapcache_create(sc, &sc->sc_rx_mapcache, BCMETH_MAXRXMBUFS, MCLBYTES, BCMETH_NRXSEGS); if (error) { aprint_error(": failed to allocate rx dmamaps: %d\n", error); goto fail_1; } error = bcmeth_mapcache_create(sc, &sc->sc_tx_mapcache, BCMETH_MAXTXMBUFS, MCLBYTES, BCMETH_NTXSEGS); if (error) { aprint_error(": failed to allocate tx dmamaps: %d\n", error); goto fail_1; } error = workqueue_create(&sc->sc_workq, xname, bcmeth_worker, sc, (PRI_USER + MAXPRI_USER) / 2, IPL_NET, WQ_MPSAFE|WQ_PERCPU); if (error) { aprint_error(": failed to create workqueue: %d\n", error); goto fail_2; } sc->sc_soft_ih = softint_establish(SOFTINT_MPSAFE | SOFTINT_NET, bcmeth_soft_intr, sc); if (sc->sc_ih == NULL) { aprint_error_dev(self, "failed to establish interrupt %d\n", loc->loc_intrs[0]); goto fail_3; } sc->sc_ih = intr_establish(loc->loc_intrs[0], IPL_VM, IST_LEVEL, bcmeth_intr, sc); if (sc->sc_ih == NULL) { aprint_error_dev(self, "failed to establish interrupt %d\n", loc->loc_intrs[0]); goto fail_4; } else { aprint_normal_dev(self, "interrupting on irq %d\n", loc->loc_intrs[0]); } aprint_normal_dev(sc->sc_dev, "Ethernet address %s\n", ether_sprintf(sc->sc_enaddr)); /* * Since each port in plugged into the switch/flow-accelerator, * we hard code at Gige Full-Duplex with Flow Control enabled. */ int ifmedia = IFM_ETHER | IFM_1000_T | IFM_FDX; //ifmedia |= IFM_FLOW | IFM_ETH_TXPAUSE | IFM_ETH_RXPAUSE; ec->ec_ifmedia = &sc->sc_media; ifmedia_init(&sc->sc_media, IFM_IMASK, bcmeth_mediachange, bcmeth_mediastatus); ifmedia_add(&sc->sc_media, ifmedia, 0, NULL); ifmedia_set(&sc->sc_media, ifmedia); ec->ec_capabilities = ETHERCAP_VLAN_MTU | ETHERCAP_JUMBO_MTU; strlcpy(ifp->if_xname, xname, IFNAMSIZ); ifp->if_softc = sc; ifp->if_baudrate = IF_Mbps(1000); ifp->if_capabilities = 0; ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST; #ifdef BCMETH_MPSAFE ifp->if_flags2 = IFF2_MPSAFE; #endif ifp->if_ioctl = bcmeth_ifioctl; ifp->if_start = bcmeth_ifstart; ifp->if_watchdog = bcmeth_ifwatchdog; ifp->if_init = bcmeth_ifinit; ifp->if_stop = bcmeth_ifstop; IFQ_SET_READY(&ifp->if_snd); bcmeth_ifstop(ifp, true); /* * Attach the interface. */ if_initialize(ifp); ether_ifattach(ifp, sc->sc_enaddr); if_register(ifp); #ifdef BCMETH_COUNTERS evcnt_attach_dynamic(&sc->sc_ev_intr, EVCNT_TYPE_INTR, NULL, xname, "intr"); evcnt_attach_dynamic(&sc->sc_ev_soft_intr, EVCNT_TYPE_INTR, NULL, xname, "soft intr"); evcnt_attach_dynamic(&sc->sc_ev_work, EVCNT_TYPE_MISC, NULL, xname, "work items"); evcnt_attach_dynamic(&sc->sc_ev_tx_stall, EVCNT_TYPE_MISC, NULL, xname, "tx stalls"); evcnt_attach_dynamic(&sc->sc_ev_rx_badmagic_lo, EVCNT_TYPE_MISC, NULL, xname, "rx badmagic lo"); evcnt_attach_dynamic(&sc->sc_ev_rx_badmagic_hi, EVCNT_TYPE_MISC, NULL, xname, "rx badmagic hi"); #endif return; fail_4: intr_disestablish(sc->sc_ih); fail_3: softint_disestablish(sc->sc_soft_ih); fail_2: workqueue_destroy(sc->sc_workq); fail_1: mutex_obj_free(sc->sc_lock); mutex_obj_free(sc->sc_hwlock); } static int bcmeth_mediachange(struct ifnet *ifp) { //struct bcmeth_softc * const sc = ifp->if_softc; return 0; } static void bcmeth_mediastatus(struct ifnet *ifp, struct ifmediareq *ifm) { //struct bcmeth_softc * const sc = ifp->if_softc; ifm->ifm_status = IFM_AVALID | IFM_ACTIVE; ifm->ifm_active = IFM_ETHER | IFM_FDX | IFM_1000_T; } static uint64_t bcmeth_macaddr_create(const uint8_t *enaddr) { return (enaddr[3] << 0) // UNIMAC_MAC_0 | (enaddr[2] << 8) // UNIMAC_MAC_0 | (enaddr[1] << 16) // UNIMAC_MAC_0 | ((uint64_t)enaddr[0] << 24) // UNIMAC_MAC_0 | ((uint64_t)enaddr[5] << 32) // UNIMAC_MAC_1 | ((uint64_t)enaddr[4] << 40); // UNIMAC_MAC_1 } static int bcmeth_ifinit(struct ifnet *ifp) { struct bcmeth_softc * const sc = ifp->if_softc; int error = 0; sc->sc_maxfrm = uimax(ifp->if_mtu + 32, MCLBYTES); if (ifp->if_mtu > ETHERMTU_JUMBO) return error; KASSERT(ifp->if_flags & IFF_UP); /* * Stop the interface */ bcmeth_ifstop(ifp, 0); /* * Reserve enough space at the front so that we can insert a maxsized * link header and a VLAN tag. Also make sure we have enough room for * the rcvsts field as well. */ KASSERT(ALIGN(max_linkhdr) == max_linkhdr); KASSERTMSG(max_linkhdr > sizeof(struct ether_header), "%u > %zu", max_linkhdr, sizeof(struct ether_header)); sc->sc_rcvoffset = max_linkhdr + 4 - sizeof(struct ether_header); if (sc->sc_rcvoffset <= 4) sc->sc_rcvoffset += 4; KASSERT((sc->sc_rcvoffset & 3) == 2); KASSERT(sc->sc_rcvoffset <= __SHIFTOUT(RCVCTL_RCVOFFSET, RCVCTL_RCVOFFSET)); KASSERT(sc->sc_rcvoffset >= 6); /* * If our frame size has changed (or it's our first time through) * destroy the existing transmit mapcache. */ if (sc->sc_tx_mapcache != NULL && sc->sc_maxfrm != sc->sc_tx_mapcache->dmc_maxmapsize) { bcmeth_mapcache_destroy(sc, sc->sc_tx_mapcache); sc->sc_tx_mapcache = NULL; } if (sc->sc_tx_mapcache == NULL) { error = bcmeth_mapcache_create(sc, &sc->sc_tx_mapcache, BCMETH_MAXTXMBUFS, sc->sc_maxfrm, BCMETH_NTXSEGS); if (error) return error; } sc->sc_cmdcfg = NO_LENGTH_CHECK | PAUSE_IGNORE | __SHIFTIN(ETH_SPEED_1000, ETH_SPEED) | RX_ENA | TX_ENA; if (ifp->if_flags & IFF_PROMISC) { sc->sc_cmdcfg |= PROMISC_EN; } else { sc->sc_cmdcfg &= ~PROMISC_EN; } const uint8_t * const lladdr = CLLADDR(ifp->if_sadl); const uint64_t macstnaddr = bcmeth_macaddr_create(lladdr); /* * We make sure that a received Ethernet packet start on a non-word * boundary so that the packet payload will be on a word boundary. * So to check the destination address we keep around two words to * quickly compare with. */ #if __ARMEL__ sc->sc_macaddr[0] = lladdr[0] | (lladdr[1] << 8); sc->sc_macaddr[1] = lladdr[2] | (lladdr[3] << 8) | (lladdr[4] << 16) | (lladdr[5] << 24); #else sc->sc_macaddr[0] = lladdr[1] | (lladdr[0] << 8); sc->sc_macaddr[1] = lladdr[5] | (lladdr[4] << 8) | (lladdr[1] << 16) | (lladdr[2] << 24); #endif sc->sc_intmask = DESCPROTOERR | DATAERR | DESCERR; /* 5. Load RCVADDR_LO with new pointer */ bcmeth_rxq_reset(sc, &sc->sc_rxq); bcmeth_write_4(sc, sc->sc_rxq.rxq_reg_rcvctl, __SHIFTIN(sc->sc_rcvoffset, RCVCTL_RCVOFFSET) | RCVCTL_PARITY_DIS | RCVCTL_OFLOW_CONTINUE | __SHIFTIN(3, RCVCTL_BURSTLEN)); /* 6. Load XMTADDR_LO with new pointer */ bcmeth_txq_reset(sc, &sc->sc_txq); bcmeth_write_4(sc, sc->sc_txq.txq_reg_xmtctl, XMTCTL_DMA_ACT_INDEX | XMTCTL_PARITY_DIS | __SHIFTIN(3, XMTCTL_BURSTLEN)); /* 7. Setup other UNIMAC registers */ bcmeth_write_4(sc, UNIMAC_FRAME_LEN, sc->sc_maxfrm); bcmeth_write_4(sc, UNIMAC_MAC_0, (uint32_t)(macstnaddr >> 0)); bcmeth_write_4(sc, UNIMAC_MAC_1, (uint32_t)(macstnaddr >> 32)); bcmeth_write_4(sc, UNIMAC_COMMAND_CONFIG, sc->sc_cmdcfg); uint32_t devctl = bcmeth_read_4(sc, GMAC_DEVCONTROL); devctl |= RGMII_LINK_STATUS_SEL | NWAY_AUTO_POLL_EN | TXARB_STRICT_MODE; devctl &= ~FLOW_CTRL_MODE; devctl &= ~MIB_RD_RESET_EN; devctl &= ~RXQ_OVERFLOW_CTRL_SEL; devctl &= ~CPU_FLOW_CTRL_ON; bcmeth_write_4(sc, GMAC_DEVCONTROL, devctl); /* Setup lazy receive (at most 1ms). */ const struct cpu_softc * const cpu = curcpu()->ci_softc; sc->sc_rcvlazy = __SHIFTIN(4, INTRCVLAZY_FRAMECOUNT) | __SHIFTIN(cpu->cpu_clk.clk_apb / 1000, INTRCVLAZY_TIMEOUT); bcmeth_write_4(sc, GMAC_INTRCVLAZY, sc->sc_rcvlazy); /* 11. Enable transmit queues in TQUEUE, and ensure that the transmit scheduling mode is correctly set in TCTRL. */ sc->sc_intmask |= XMTINT_0 | XMTUF; bcmeth_write_4(sc, sc->sc_txq.txq_reg_xmtctl, bcmeth_read_4(sc, sc->sc_txq.txq_reg_xmtctl) | XMTCTL_ENABLE); /* 12. Enable receive queues in RQUEUE, */ sc->sc_intmask |= RCVINT | RCVDESCUF | RCVFIFOOF; bcmeth_write_4(sc, sc->sc_rxq.rxq_reg_rcvctl, bcmeth_read_4(sc, sc->sc_rxq.rxq_reg_rcvctl) | RCVCTL_ENABLE); bcmeth_rxq_produce(sc, &sc->sc_rxq); /* fill with rx buffers */ #if 0 aprint_normal_dev(sc->sc_dev, "devctl=%#x ucmdcfg=%#x xmtctl=%#x rcvctl=%#x\n", devctl, sc->sc_cmdcfg, bcmeth_read_4(sc, sc->sc_txq.txq_reg_xmtctl), bcmeth_read_4(sc, sc->sc_rxq.rxq_reg_rcvctl)); #endif sc->sc_soft_flags = 0; bcmeth_write_4(sc, GMAC_INTMASK, sc->sc_intmask); ifp->if_flags |= IFF_RUNNING; return error; } static void bcmeth_ifstop(struct ifnet *ifp, int disable) { struct bcmeth_softc * const sc = ifp->if_softc; struct bcmeth_txqueue * const txq = &sc->sc_txq; struct bcmeth_rxqueue * const rxq = &sc->sc_rxq; KASSERT(!cpu_intr_p()); sc->sc_soft_flags = 0; sc->sc_work_flags = 0; /* Disable Rx processing */ bcmeth_write_4(sc, rxq->rxq_reg_rcvctl, bcmeth_read_4(sc, rxq->rxq_reg_rcvctl) & ~RCVCTL_ENABLE); /* Disable Tx processing */ bcmeth_write_4(sc, txq->txq_reg_xmtctl, bcmeth_read_4(sc, txq->txq_reg_xmtctl) & ~XMTCTL_ENABLE); /* Disable all interrupts */ bcmeth_write_4(sc, GMAC_INTMASK, 0); for (;;) { uint32_t tx0 = bcmeth_read_4(sc, txq->txq_reg_xmtsts0); uint32_t rx0 = bcmeth_read_4(sc, rxq->rxq_reg_rcvsts0); if (__SHIFTOUT(tx0, XMTSTATE) == XMTSTATE_DIS && __SHIFTOUT(rx0, RCVSTATE) == RCVSTATE_DIS) break; delay(50); } /* * Now reset the controller. * * 3. Set SW_RESET bit in UNIMAC_COMMAND_CONFIG register * 4. Clear SW_RESET bit in UNIMAC_COMMAND_CONFIG register */ bcmeth_write_4(sc, UNIMAC_COMMAND_CONFIG, SW_RESET); bcmeth_write_4(sc, GMAC_INTSTATUS, ~0); sc->sc_intmask = 0; ifp->if_flags &= ~IFF_RUNNING; /* * Let's consume any remaining transmitted packets. And if we are * disabling the interface, purge ourselves of any untransmitted * packets. But don't consume any received packets, just drop them. * If we aren't disabling the interface, save the mbufs in the * receive queue for reuse. */ bcmeth_rxq_purge(sc, &sc->sc_rxq, disable); bcmeth_txq_consume(sc, &sc->sc_txq); if (disable) { bcmeth_txq_purge(sc, &sc->sc_txq); IF_PURGE(&ifp->if_snd); } bcmeth_write_4(sc, UNIMAC_COMMAND_CONFIG, 0); } static void bcmeth_ifwatchdog(struct ifnet *ifp) { } static int bcmeth_ifioctl(struct ifnet *ifp, u_long cmd, void *data) { const int s = splnet(); int error; switch (cmd) { default: error = ether_ioctl(ifp, cmd, data); if (error != ENETRESET) break; if (cmd == SIOCADDMULTI || cmd == SIOCDELMULTI) { error = 0; break; } error = bcmeth_ifinit(ifp); break; } splx(s); return error; } static void bcmeth_rxq_desc_presync( struct bcmeth_softc *sc, struct bcmeth_rxqueue *rxq, struct gmac_rxdb *rxdb, size_t count) { bus_dmamap_sync(sc->sc_dmat, rxq->rxq_descmap, (rxdb - rxq->rxq_first) * sizeof(*rxdb), count * sizeof(*rxdb), BUS_DMASYNC_PREWRITE); } static void bcmeth_rxq_desc_postsync( struct bcmeth_softc *sc, struct bcmeth_rxqueue *rxq, struct gmac_rxdb *rxdb, size_t count) { bus_dmamap_sync(sc->sc_dmat, rxq->rxq_descmap, (rxdb - rxq->rxq_first) * sizeof(*rxdb), count * sizeof(*rxdb), BUS_DMASYNC_POSTWRITE); } static void bcmeth_txq_desc_presync( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq, struct gmac_txdb *txdb, size_t count) { bus_dmamap_sync(sc->sc_dmat, txq->txq_descmap, (txdb - txq->txq_first) * sizeof(*txdb), count * sizeof(*txdb), BUS_DMASYNC_PREWRITE); } static void bcmeth_txq_desc_postsync( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq, struct gmac_txdb *txdb, size_t count) { bus_dmamap_sync(sc->sc_dmat, txq->txq_descmap, (txdb - txq->txq_first) * sizeof(*txdb), count * sizeof(*txdb), BUS_DMASYNC_POSTWRITE); } static bus_dmamap_t bcmeth_mapcache_get( struct bcmeth_softc *sc, struct bcmeth_mapcache *dmc) { KASSERT(dmc->dmc_nmaps > 0); KASSERT(dmc->dmc_maps[dmc->dmc_nmaps-1] != NULL); return dmc->dmc_maps[--dmc->dmc_nmaps]; } static void bcmeth_mapcache_put( struct bcmeth_softc *sc, struct bcmeth_mapcache *dmc, bus_dmamap_t map) { KASSERT(map != NULL); KASSERT(dmc->dmc_nmaps < dmc->dmc_maxmaps); dmc->dmc_maps[dmc->dmc_nmaps++] = map; } static void bcmeth_mapcache_destroy( struct bcmeth_softc *sc, struct bcmeth_mapcache *dmc) { const size_t dmc_size = offsetof(struct bcmeth_mapcache, dmc_maps[dmc->dmc_maxmaps]); for (u_int i = 0; i < dmc->dmc_maxmaps; i++) { bus_dmamap_destroy(sc->sc_dmat, dmc->dmc_maps[i]); } kmem_intr_free(dmc, dmc_size); } static int bcmeth_mapcache_create( struct bcmeth_softc *sc, struct bcmeth_mapcache **dmc_p, size_t maxmaps, size_t maxmapsize, size_t maxseg) { const size_t dmc_size = offsetof(struct bcmeth_mapcache, dmc_maps[maxmaps]); struct bcmeth_mapcache * const dmc = kmem_intr_zalloc(dmc_size, KM_NOSLEEP); dmc->dmc_maxmaps = maxmaps; dmc->dmc_nmaps = maxmaps; dmc->dmc_maxmapsize = maxmapsize; dmc->dmc_maxseg = maxseg; for (u_int i = 0; i < maxmaps; i++) { int error = bus_dmamap_create(sc->sc_dmat, dmc->dmc_maxmapsize, dmc->dmc_maxseg, dmc->dmc_maxmapsize, 0, BUS_DMA_WAITOK | BUS_DMA_ALLOCNOW, &dmc->dmc_maps[i]); if (error) { aprint_error_dev(sc->sc_dev, "failed to creat dma map cache " "entry %u of %zu: %d\n", i, maxmaps, error); while (i-- > 0) { bus_dmamap_destroy(sc->sc_dmat, dmc->dmc_maps[i]); } kmem_intr_free(dmc, dmc_size); return error; } KASSERT(dmc->dmc_maps[i] != NULL); } *dmc_p = dmc; return 0; } #if 0 static void bcmeth_dmamem_free( bus_dma_tag_t dmat, size_t map_size, bus_dma_segment_t *seg, bus_dmamap_t map, void *kvap) { bus_dmamap_destroy(dmat, map); bus_dmamem_unmap(dmat, kvap, map_size); bus_dmamem_free(dmat, seg, 1); } #endif static int bcmeth_dmamem_alloc( bus_dma_tag_t dmat, size_t map_size, bus_dma_segment_t *seg, bus_dmamap_t *map, void **kvap) { int error; int nseg; *kvap = NULL; *map = NULL; error = bus_dmamem_alloc(dmat, map_size, 2*PAGE_SIZE, 0, seg, 1, &nseg, 0); if (error) return error; KASSERT(nseg == 1); error = bus_dmamem_map(dmat, seg, nseg, map_size, (void **)kvap, 0); if (error == 0) { error = bus_dmamap_create(dmat, map_size, 1, map_size, 0, 0, map); if (error == 0) { error = bus_dmamap_load(dmat, *map, *kvap, map_size, NULL, 0); if (error == 0) return 0; bus_dmamap_destroy(dmat, *map); *map = NULL; } bus_dmamem_unmap(dmat, *kvap, map_size); *kvap = NULL; } bus_dmamem_free(dmat, seg, nseg); return 0; } static struct mbuf * bcmeth_rx_buf_alloc( struct bcmeth_softc *sc) { struct mbuf *m = m_gethdr(M_DONTWAIT, MT_DATA); if (m == NULL) { printf("%s:%d: %s\n", __func__, __LINE__, "m_gethdr"); return NULL; } MCLGET(m, M_DONTWAIT); if ((m->m_flags & M_EXT) == 0) { printf("%s:%d: %s\n", __func__, __LINE__, "MCLGET"); m_freem(m); return NULL; } m->m_len = m->m_pkthdr.len = m->m_ext.ext_size; bus_dmamap_t map = bcmeth_mapcache_get(sc, sc->sc_rx_mapcache); if (map == NULL) { printf("%s:%d: %s\n", __func__, __LINE__, "map get"); m_freem(m); return NULL; } M_SETCTX(m, map); m->m_len = m->m_pkthdr.len = MCLBYTES; int error = bus_dmamap_load_mbuf(sc->sc_dmat, map, m, BUS_DMA_READ | BUS_DMA_NOWAIT); if (error) { aprint_error_dev(sc->sc_dev, "fail to load rx dmamap: %d\n", error); M_SETCTX(m, NULL); m_freem(m); bcmeth_mapcache_put(sc, sc->sc_rx_mapcache, map); return NULL; } KASSERT(map->dm_mapsize == MCLBYTES); #ifdef BCMETH_RCVMAGIC *mtod(m, uint32_t *) = htole32(BCMETH_RCVMAGIC); bus_dmamap_sync(sc->sc_dmat, map, 0, sizeof(uint32_t), BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE); bus_dmamap_sync(sc->sc_dmat, map, sizeof(uint32_t), map->dm_mapsize - sizeof(uint32_t), BUS_DMASYNC_PREREAD); #else bus_dmamap_sync(sc->sc_dmat, map, 0, map->dm_mapsize, BUS_DMASYNC_PREREAD); #endif return m; } static void bcmeth_rx_map_unload( struct bcmeth_softc *sc, struct mbuf *m) { KASSERT(m); for (; m != NULL; m = m->m_next) { bus_dmamap_t map = M_GETCTX(m, bus_dmamap_t); KASSERT(map); KASSERT(map->dm_mapsize == MCLBYTES); bus_dmamap_sync(sc->sc_dmat, map, 0, m->m_len, BUS_DMASYNC_POSTREAD); bus_dmamap_unload(sc->sc_dmat, map); bcmeth_mapcache_put(sc, sc->sc_rx_mapcache, map); M_SETCTX(m, NULL); } } static bool bcmeth_rxq_produce( struct bcmeth_softc *sc, struct bcmeth_rxqueue *rxq) { struct gmac_rxdb *producer = rxq->rxq_producer; bool produced = false; while (rxq->rxq_inuse < rxq->rxq_threshold) { struct mbuf *m; IF_DEQUEUE(&sc->sc_rx_bufcache, m); if (m == NULL) { m = bcmeth_rx_buf_alloc(sc); if (m == NULL) { printf("%s: bcmeth_rx_buf_alloc failed\n", __func__); break; } } bus_dmamap_t map = M_GETCTX(m, bus_dmamap_t); KASSERT(map); producer->rxdb_buflen = htole32(MCLBYTES); producer->rxdb_addrlo = htole32(map->dm_segs[0].ds_addr); producer->rxdb_flags &= htole32(RXDB_FLAG_ET); *rxq->rxq_mtail = m; rxq->rxq_mtail = &m->m_next; m->m_len = MCLBYTES; m->m_next = NULL; rxq->rxq_inuse++; if (++producer == rxq->rxq_last) { membar_producer(); bcmeth_rxq_desc_presync(sc, rxq, rxq->rxq_producer, rxq->rxq_last - rxq->rxq_producer); producer = rxq->rxq_producer = rxq->rxq_first; } produced = true; } if (produced) { membar_producer(); if (producer != rxq->rxq_producer) { bcmeth_rxq_desc_presync(sc, rxq, rxq->rxq_producer, producer - rxq->rxq_producer); rxq->rxq_producer = producer; } bcmeth_write_4(sc, rxq->rxq_reg_rcvptr, rxq->rxq_descmap->dm_segs[0].ds_addr + ((uintptr_t)producer & RCVPTR)); } return true; } static void bcmeth_rx_input( struct bcmeth_softc *sc, struct mbuf *m, uint32_t rxdb_flags) { struct ifnet * const ifp = &sc->sc_if; bcmeth_rx_map_unload(sc, m); m_adj(m, sc->sc_rcvoffset); /* * If we are in promiscuous mode and this isn't a multicast, check the * destination address to make sure it matches our own. If it doesn't, * mark the packet as being received promiscuously. */ if ((sc->sc_cmdcfg & PROMISC_EN) && (m->m_data[0] & 1) == 0 && (*(uint16_t *)&m->m_data[0] != sc->sc_macaddr[0] || *(uint32_t *)&m->m_data[2] != sc->sc_macaddr[1])) { m->m_flags |= M_PROMISC; } m_set_rcvif(m, ifp); /* * Let's give it to the network subsystm to deal with. */ #ifdef BCMETH_MPSAFE mutex_exit(sc->sc_lock); if_input(ifp, m); mutex_enter(sc->sc_lock); #else int s = splnet(); if_input(ifp, m); splx(s); #endif } static bool bcmeth_rxq_consume( struct bcmeth_softc *sc, struct bcmeth_rxqueue *rxq, size_t atmost) { struct ifnet * const ifp = &sc->sc_if; struct gmac_rxdb *consumer = rxq->rxq_consumer; size_t rxconsumed = 0; bool didconsume = false; while (atmost-- > 0) { if (consumer == rxq->rxq_producer) { KASSERT(rxq->rxq_inuse == 0); break; } uint32_t rcvsts0 = bcmeth_read_4(sc, rxq->rxq_reg_rcvsts0); uint32_t currdscr = __SHIFTOUT(rcvsts0, RCV_CURRDSCR); if (consumer == rxq->rxq_first + currdscr) { break; } bcmeth_rxq_desc_postsync(sc, rxq, consumer, 1); /* * We own this packet again. Copy the rxsts word from it. */ rxconsumed++; didconsume = true; uint32_t rxsts; KASSERT(rxq->rxq_mhead != NULL); bus_dmamap_t map = M_GETCTX(rxq->rxq_mhead, bus_dmamap_t); bus_dmamap_sync(sc->sc_dmat, map, 0, arm_dcache_align, BUS_DMASYNC_POSTREAD); memcpy(&rxsts, rxq->rxq_mhead->m_data, 4); rxsts = le32toh(rxsts); #if 0 KASSERTMSG(rxsts != BCMETH_RCVMAGIC, "currdscr=%u consumer=%zd", currdscr, consumer - rxq->rxq_first); #endif /* * Get the count of descriptors. Fetch the correct number * of mbufs. */ #ifdef BCMETH_RCVMAGIC size_t desc_count = rxsts != BCMETH_RCVMAGIC ? __SHIFTOUT(rxsts, RXSTS_DESC_COUNT) + 1 : 1; #else size_t desc_count = __SHIFTOUT(rxsts, RXSTS_DESC_COUNT) + 1; #endif struct mbuf *m = rxq->rxq_mhead; struct mbuf *m_last = m; for (size_t i = 1; i < desc_count; i++) { if (++consumer == rxq->rxq_last) { consumer = rxq->rxq_first; } KASSERTMSG(consumer != rxq->rxq_first + currdscr, "i=%zu rxsts=%#x desc_count=%zu currdscr=%u " "consumer=%zd", i, rxsts, desc_count, currdscr, consumer - rxq->rxq_first); m_last = m_last->m_next; } /* * Now remove it/them from the list of enqueued mbufs. */ if ((rxq->rxq_mhead = m_last->m_next) == NULL) rxq->rxq_mtail = &rxq->rxq_mhead; m_last->m_next = NULL; #ifdef BCMETH_RCVMAGIC if (rxsts == BCMETH_RCVMAGIC) { if_statinc(ifp, if_ierrors); if ((m->m_ext.ext_paddr >> 28) == 8) { BCMETH_EVCNT_INCR(sc->sc_ev_rx_badmagic_lo); } else { BCMETH_EVCNT_INCR( sc->sc_ev_rx_badmagic_hi); } IF_ENQUEUE(&sc->sc_rx_bufcache, m); } else #endif /* BCMETH_RCVMAGIC */ if (rxsts & (RXSTS_CRC_ERROR |RXSTS_OVERSIZED |RXSTS_PKT_OVERFLOW)) { aprint_error_dev(sc->sc_dev, "[%zu]: count=%zu rxsts=%#x\n", consumer - rxq->rxq_first, desc_count, rxsts); /* * We encountered an error, take the mbufs and add them * to the rx bufcache so we can quickly reuse them. */ if_statinc(ifp, if_ierrors); do { struct mbuf *m0 = m->m_next; m->m_next = NULL; IF_ENQUEUE(&sc->sc_rx_bufcache, m); m = m0; } while (m); } else { uint32_t framelen = __SHIFTOUT(rxsts, RXSTS_FRAMELEN); framelen += sc->sc_rcvoffset; m->m_pkthdr.len = framelen; if (desc_count == 1) { KASSERT(framelen <= MCLBYTES); m->m_len = framelen; } else { m_last->m_len = framelen & (MCLBYTES - 1); } #ifdef BCMETH_MPSAFE /* * Wrap at the last entry! */ if (++consumer == rxq->rxq_last) { KASSERT(consumer[-1].rxdb_flags & htole32(RXDB_FLAG_ET)); rxq->rxq_consumer = rxq->rxq_first; } else { rxq->rxq_consumer = consumer; } rxq->rxq_inuse -= rxconsumed; #endif /* BCMETH_MPSAFE */ /* * Receive the packet (which releases our lock) */ bcmeth_rx_input(sc, m, rxsts); #ifdef BCMETH_MPSAFE /* * Since we had to give up our lock, we need to * refresh these. */ consumer = rxq->rxq_consumer; rxconsumed = 0; continue; #endif /* BCMETH_MPSAFE */ } /* * Wrap at the last entry! */ if (++consumer == rxq->rxq_last) { KASSERT(consumer[-1].rxdb_flags & htole32(RXDB_FLAG_ET)); consumer = rxq->rxq_first; } } /* * Update queue info. */ rxq->rxq_consumer = consumer; rxq->rxq_inuse -= rxconsumed; /* * Did we consume anything? */ return didconsume; } static void bcmeth_rxq_purge( struct bcmeth_softc *sc, struct bcmeth_rxqueue *rxq, bool discard) { struct mbuf *m; if ((m = rxq->rxq_mhead) != NULL) { if (discard) { bcmeth_rx_map_unload(sc, m); m_freem(m); } else { while (m != NULL) { struct mbuf *m0 = m->m_next; m->m_next = NULL; IF_ENQUEUE(&sc->sc_rx_bufcache, m); m = m0; } } } rxq->rxq_mhead = NULL; rxq->rxq_mtail = &rxq->rxq_mhead; rxq->rxq_inuse = 0; } static void bcmeth_rxq_reset( struct bcmeth_softc *sc, struct bcmeth_rxqueue *rxq) { /* * sync all the descriptors */ bcmeth_rxq_desc_postsync(sc, rxq, rxq->rxq_first, rxq->rxq_last - rxq->rxq_first); /* * Make sure we own all descriptors in the ring. */ struct gmac_rxdb *rxdb; for (rxdb = rxq->rxq_first; rxdb < rxq->rxq_last - 1; rxdb++) { rxdb->rxdb_flags = htole32(RXDB_FLAG_IC); } /* * Last descriptor has the wrap flag. */ rxdb->rxdb_flags = htole32(RXDB_FLAG_ET | RXDB_FLAG_IC); /* * Reset the producer consumer indexes. */ rxq->rxq_consumer = rxq->rxq_first; rxq->rxq_producer = rxq->rxq_first; rxq->rxq_inuse = 0; if (rxq->rxq_threshold < BCMETH_MINRXMBUFS) rxq->rxq_threshold = BCMETH_MINRXMBUFS; sc->sc_intmask |= RCVINT | RCVFIFOOF | RCVDESCUF; /* * Restart the receiver at the first descriptor */ bcmeth_write_4(sc, rxq->rxq_reg_rcvaddrlo, rxq->rxq_descmap->dm_segs[0].ds_addr); } static int bcmeth_rxq_attach( struct bcmeth_softc *sc, struct bcmeth_rxqueue *rxq, u_int qno) { size_t desc_count = BCMETH_RINGSIZE / sizeof(rxq->rxq_first[0]); int error; void *descs; KASSERT(desc_count == 256 || desc_count == 512); error = bcmeth_dmamem_alloc(sc->sc_dmat, BCMETH_RINGSIZE, &rxq->rxq_descmap_seg, &rxq->rxq_descmap, &descs); if (error) return error; memset(descs, 0, BCMETH_RINGSIZE); rxq->rxq_first = descs; rxq->rxq_last = rxq->rxq_first + desc_count; rxq->rxq_consumer = descs; rxq->rxq_producer = descs; bcmeth_rxq_purge(sc, rxq, true); bcmeth_rxq_reset(sc, rxq); rxq->rxq_reg_rcvaddrlo = GMAC_RCVADDR_LOW; rxq->rxq_reg_rcvctl = GMAC_RCVCONTROL; rxq->rxq_reg_rcvptr = GMAC_RCVPTR; rxq->rxq_reg_rcvsts0 = GMAC_RCVSTATUS0; rxq->rxq_reg_rcvsts1 = GMAC_RCVSTATUS1; return 0; } static bool bcmeth_txq_active_p( struct bcmeth_softc * const sc, struct bcmeth_txqueue *txq) { return !IF_IS_EMPTY(&txq->txq_mbufs); } static bool bcmeth_txq_fillable_p( struct bcmeth_softc * const sc, struct bcmeth_txqueue *txq) { return txq->txq_free >= txq->txq_threshold; } static int bcmeth_txq_attach( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq, u_int qno) { size_t desc_count = BCMETH_RINGSIZE / sizeof(txq->txq_first[0]); int error; void *descs; KASSERT(desc_count == 256 || desc_count == 512); error = bcmeth_dmamem_alloc(sc->sc_dmat, BCMETH_RINGSIZE, &txq->txq_descmap_seg, &txq->txq_descmap, &descs); if (error) return error; memset(descs, 0, BCMETH_RINGSIZE); txq->txq_first = descs; txq->txq_last = txq->txq_first + desc_count; txq->txq_consumer = descs; txq->txq_producer = descs; IFQ_SET_MAXLEN(&txq->txq_mbufs, BCMETH_MAXTXMBUFS); txq->txq_reg_xmtaddrlo = GMAC_XMTADDR_LOW; txq->txq_reg_xmtctl = GMAC_XMTCONTROL; txq->txq_reg_xmtptr = GMAC_XMTPTR; txq->txq_reg_xmtsts0 = GMAC_XMTSTATUS0; txq->txq_reg_xmtsts1 = GMAC_XMTSTATUS1; bcmeth_txq_reset(sc, txq); return 0; } static int bcmeth_txq_map_load( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq, struct mbuf *m) { bus_dmamap_t map; int error; map = M_GETCTX(m, bus_dmamap_t); if (map != NULL) return 0; map = bcmeth_mapcache_get(sc, sc->sc_tx_mapcache); if (map == NULL) return ENOMEM; error = bus_dmamap_load_mbuf(sc->sc_dmat, map, m, BUS_DMA_WRITE | BUS_DMA_NOWAIT); if (error) return error; bus_dmamap_sync(sc->sc_dmat, map, 0, m->m_pkthdr.len, BUS_DMASYNC_PREWRITE); M_SETCTX(m, map); return 0; } static void bcmeth_txq_map_unload( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq, struct mbuf *m) { KASSERT(m); bus_dmamap_t map = M_GETCTX(m, bus_dmamap_t); bus_dmamap_sync(sc->sc_dmat, map, 0, map->dm_mapsize, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, map); bcmeth_mapcache_put(sc, sc->sc_tx_mapcache, map); } static bool bcmeth_txq_produce( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq, struct mbuf *m) { bus_dmamap_t map = M_GETCTX(m, bus_dmamap_t); if (map->dm_nsegs > txq->txq_free) return false; /* * TCP Offload flag must be set in the first descriptor. */ struct gmac_txdb *producer = txq->txq_producer; uint32_t first_flags = TXDB_FLAG_SF; uint32_t last_flags = TXDB_FLAG_EF; /* * If we've produced enough descriptors without consuming any * we need to ask for an interrupt to reclaim some. */ txq->txq_lastintr += map->dm_nsegs; if (txq->txq_lastintr >= txq->txq_threshold || txq->txq_mbufs.ifq_len + 1 == txq->txq_mbufs.ifq_maxlen) { txq->txq_lastintr = 0; last_flags |= TXDB_FLAG_IC; } KASSERT(producer != txq->txq_last); struct gmac_txdb *start = producer; size_t count = map->dm_nsegs; producer->txdb_flags |= htole32(first_flags); producer->txdb_addrlo = htole32(map->dm_segs[0].ds_addr); producer->txdb_buflen = htole32(map->dm_segs[0].ds_len); for (u_int i = 1; i < map->dm_nsegs; i++) { #if 0 printf("[%zu]: %#x/%#x/%#x/%#x\n", producer - txq->txq_first, le32toh(producer->txdb_flags), le32toh(producer->txdb_buflen), le32toh(producer->txdb_addrlo), le32toh(producer->txdb_addrhi)); #endif if (__predict_false(++producer == txq->txq_last)) { bcmeth_txq_desc_presync(sc, txq, start, txq->txq_last - start); count -= txq->txq_last - start; producer = txq->txq_first; start = txq->txq_first; } producer->txdb_addrlo = htole32(map->dm_segs[i].ds_addr); producer->txdb_buflen = htole32(map->dm_segs[i].ds_len); } producer->txdb_flags |= htole32(last_flags); #if 0 printf("[%zu]: %#x/%#x/%#x/%#x\n", producer - txq->txq_first, le32toh(producer->txdb_flags), le32toh(producer->txdb_buflen), le32toh(producer->txdb_addrlo), le32toh(producer->txdb_addrhi)); #endif if (count) bcmeth_txq_desc_presync(sc, txq, start, count); /* * Reduce free count by the number of segments we consumed. */ txq->txq_free -= map->dm_nsegs; KASSERT(map->dm_nsegs == 1 || txq->txq_producer != producer); KASSERT(map->dm_nsegs == 1 || (txq->txq_producer->txdb_flags & htole32(TXDB_FLAG_EF)) == 0); KASSERT(producer->txdb_flags & htole32(TXDB_FLAG_EF)); #if 0 printf("%s: mbuf %p: produced a %u byte packet in %u segments " "(%zd..%zd)\n", __func__, m, m->m_pkthdr.len, map->dm_nsegs, txq->txq_producer - txq->txq_first, producer - txq->txq_first); #endif if (producer + 1 == txq->txq_last) txq->txq_producer = txq->txq_first; else txq->txq_producer = producer + 1; IF_ENQUEUE(&txq->txq_mbufs, m); /* * Let the transmitter know there's more to do */ bcmeth_write_4(sc, txq->txq_reg_xmtptr, txq->txq_descmap->dm_segs[0].ds_addr + ((uintptr_t)txq->txq_producer & XMT_LASTDSCR)); return true; } static struct mbuf * bcmeth_copy_packet(struct mbuf *m) { struct mbuf *mext = NULL; size_t misalignment = 0; size_t hlen = 0; for (mext = m; mext != NULL; mext = mext->m_next) { if (mext->m_flags & M_EXT) { misalignment = mtod(mext, vaddr_t) & arm_dcache_align; break; } hlen += m->m_len; } struct mbuf *n = m->m_next; if (m != mext && hlen + misalignment <= MHLEN && false) { KASSERT(m->m_pktdat <= m->m_data && m->m_data <= &m->m_pktdat[MHLEN - m->m_len]); size_t oldoff = m->m_data - m->m_pktdat; size_t off; if (mext == NULL) { off = (oldoff + hlen > MHLEN) ? 0 : oldoff; } else { off = MHLEN - (hlen + misalignment); } KASSERT(off + hlen + misalignment <= MHLEN); if (((oldoff ^ off) & arm_dcache_align) != 0 || off < oldoff) { memmove(&m->m_pktdat[off], m->m_data, m->m_len); m->m_data = &m->m_pktdat[off]; } m_copydata(n, 0, hlen - m->m_len, &m->m_data[m->m_len]); m->m_len = hlen; m->m_next = mext; while (n != mext) { n = m_free(n); } return m; } struct mbuf *m0 = m_gethdr(M_DONTWAIT, m->m_type); if (m0 == NULL) { return NULL; } m_copy_pkthdr(m0, m); MCLAIM(m0, m->m_owner); if (m0->m_pkthdr.len > MHLEN) { MCLGET(m0, M_DONTWAIT); if ((m0->m_flags & M_EXT) == 0) { m_freem(m0); return NULL; } } m0->m_len = m->m_pkthdr.len; m_copydata(m, 0, m0->m_len, mtod(m0, void *)); m_freem(m); return m0; } static bool bcmeth_txq_enqueue( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq) { for (;;) { if (IF_QFULL(&txq->txq_mbufs)) return false; struct mbuf *m = txq->txq_next; if (m == NULL) { int s = splnet(); IF_DEQUEUE(&sc->sc_if.if_snd, m); splx(s); if (m == NULL) return true; M_SETCTX(m, NULL); } else { txq->txq_next = NULL; } /* * If LINK2 is set and this packet uses multiple mbufs, * consolidate it into a single mbuf. */ if (m->m_next != NULL && (sc->sc_if.if_flags & IFF_LINK2)) { struct mbuf *m0 = bcmeth_copy_packet(m); if (m0 == NULL) { txq->txq_next = m; return true; } m = m0; } int error = bcmeth_txq_map_load(sc, txq, m); if (error) { aprint_error_dev(sc->sc_dev, "discarded packet due to " "dmamap load failure: %d\n", error); m_freem(m); continue; } KASSERT(txq->txq_next == NULL); if (!bcmeth_txq_produce(sc, txq, m)) { txq->txq_next = m; return false; } KASSERT(txq->txq_next == NULL); } } static bool bcmeth_txq_consume( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq) { struct ifnet * const ifp = &sc->sc_if; struct gmac_txdb *consumer = txq->txq_consumer; size_t txfree = 0; #if 0 printf("%s: entry: free=%zu\n", __func__, txq->txq_free); #endif for (;;) { if (consumer == txq->txq_producer) { txq->txq_consumer = consumer; txq->txq_free += txfree; txq->txq_lastintr -= uimin(txq->txq_lastintr, txfree); #if 0 printf("%s: empty: freed %zu descriptors going from " "%zu to %zu\n", __func__, txfree, txq->txq_free - txfree, txq->txq_free); #endif KASSERT(txq->txq_lastintr == 0); KASSERT(txq->txq_free == txq->txq_last - txq->txq_first - 1); return true; } bcmeth_txq_desc_postsync(sc, txq, consumer, 1); uint32_t s0 = bcmeth_read_4(sc, txq->txq_reg_xmtsts0); if (consumer == txq->txq_first + __SHIFTOUT(s0, XMT_CURRDSCR)) { txq->txq_consumer = consumer; txq->txq_free += txfree; txq->txq_lastintr -= uimin(txq->txq_lastintr, txfree); #if 0 printf("%s: freed %zu descriptors\n", __func__, txfree); #endif return bcmeth_txq_fillable_p(sc, txq); } /* * If this is the last descriptor in the chain, get the * mbuf, free its dmamap, and free the mbuf chain itself. */ const uint32_t txdb_flags = le32toh(consumer->txdb_flags); if (txdb_flags & TXDB_FLAG_EF) { struct mbuf *m; IF_DEQUEUE(&txq->txq_mbufs, m); KASSERT(m); bcmeth_txq_map_unload(sc, txq, m); #if 0 printf("%s: mbuf %p: consumed a %u byte packet\n", __func__, m, m->m_pkthdr.len); #endif bpf_mtap(ifp, m, BPF_D_OUT); if_statinc(ifp, if_opackets); if_statadd(ifp, if_obytes, m->m_pkthdr.len); if (m->m_flags & M_MCAST) if_statinc(ifp, if_omcasts); m_freem(m); } /* * We own this packet again. Clear all flags except wrap. */ txfree++; /* * Wrap at the last entry! */ if (txdb_flags & TXDB_FLAG_ET) { consumer->txdb_flags = htole32(TXDB_FLAG_ET); KASSERT(consumer + 1 == txq->txq_last); consumer = txq->txq_first; } else { consumer->txdb_flags = 0; consumer++; KASSERT(consumer < txq->txq_last); } } } static void bcmeth_txq_purge( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq) { struct mbuf *m; KASSERT((bcmeth_read_4(sc, UNIMAC_COMMAND_CONFIG) & TX_ENA) == 0); for (;;) { IF_DEQUEUE(&txq->txq_mbufs, m); if (m == NULL) break; bcmeth_txq_map_unload(sc, txq, m); m_freem(m); } if ((m = txq->txq_next) != NULL) { txq->txq_next = NULL; bcmeth_txq_map_unload(sc, txq, m); m_freem(m); } } static void bcmeth_txq_reset( struct bcmeth_softc *sc, struct bcmeth_txqueue *txq) { /* * sync all the descriptors */ bcmeth_txq_desc_postsync(sc, txq, txq->txq_first, txq->txq_last - txq->txq_first); /* * Make sure we own all descriptors in the ring. */ struct gmac_txdb *txdb; for (txdb = txq->txq_first; txdb < txq->txq_last - 1; txdb++) { txdb->txdb_flags = 0; } /* * Last descriptor has the wrap flag. */ txdb->txdb_flags = htole32(TXDB_FLAG_ET); /* * Reset the producer consumer indexes. */ txq->txq_consumer = txq->txq_first; txq->txq_producer = txq->txq_first; txq->txq_free = txq->txq_last - txq->txq_first - 1; txq->txq_threshold = txq->txq_free / 2; txq->txq_lastintr = 0; /* * What do we want to get interrupted on? */ sc->sc_intmask |= XMTINT_0 | XMTUF; /* * Restart the transmiter at the first descriptor */ bcmeth_write_4(sc, txq->txq_reg_xmtaddrlo, txq->txq_descmap->dm_segs->ds_addr); } static void bcmeth_ifstart(struct ifnet *ifp) { struct bcmeth_softc * const sc = ifp->if_softc; if (__predict_false((ifp->if_flags & IFF_RUNNING) == 0)) { return; } #ifdef BCMETH_MPSAFETX if (cpu_intr_p()) { #endif atomic_or_uint(&sc->sc_soft_flags, SOFT_TXINTR); softint_schedule(sc->sc_soft_ih); #ifdef BCMETH_MPSAFETX } else { /* * Either we are in a softintr thread already or some other * thread so just borrow it to do the send and save ourselves * the overhead of a fast soft int. */ bcmeth_soft_txintr(sc); } #endif } int bcmeth_intr(void *arg) { struct bcmeth_softc * const sc = arg; uint32_t soft_flags = 0; uint32_t work_flags = 0; int rv = 0; mutex_enter(sc->sc_hwlock); uint32_t intmask = sc->sc_intmask; BCMETH_EVCNT_INCR(sc->sc_ev_intr); for (;;) { uint32_t intstatus = bcmeth_read_4(sc, GMAC_INTSTATUS); intstatus &= intmask; bcmeth_write_4(sc, GMAC_INTSTATUS, intstatus); /* write 1 to clear */ if (intstatus == 0) { break; } #if 0 aprint_normal_dev(sc->sc_dev, "%s: intstatus=%#x intmask=%#x\n", __func__, intstatus, bcmeth_read_4(sc, GMAC_INTMASK)); #endif if (intstatus & RCVINT) { struct bcmeth_rxqueue * const rxq = &sc->sc_rxq; intmask &= ~RCVINT; uint32_t rcvsts0 = bcmeth_read_4(sc, rxq->rxq_reg_rcvsts0); uint32_t descs = __SHIFTOUT(rcvsts0, RCV_CURRDSCR); if (descs < rxq->rxq_consumer - rxq->rxq_first) { /* * We wrapped at the end so count how far * we are from the end. */ descs += rxq->rxq_last - rxq->rxq_consumer; } else { descs -= rxq->rxq_consumer - rxq->rxq_first; } /* * If we "timedout" we can't be hogging so use * softints. If we exceeded then we might hogging * so let the workqueue deal with them. */ const uint32_t framecount = __SHIFTOUT(sc->sc_rcvlazy, INTRCVLAZY_FRAMECOUNT); if (descs < framecount || (curcpu()->ci_curlwp->l_flag & LW_IDLE)) { soft_flags |= SOFT_RXINTR; } else { work_flags |= WORK_RXINTR; } } if (intstatus & XMTINT_0) { intmask &= ~XMTINT_0; soft_flags |= SOFT_TXINTR; } if (intstatus & RCVDESCUF) { intmask &= ~RCVDESCUF; work_flags |= WORK_RXUNDERFLOW; } intstatus &= intmask; if (intstatus) { aprint_error_dev(sc->sc_dev, "intr: intstatus=%#x\n", intstatus); aprint_error_dev(sc->sc_dev, "rcvbase=%p/%#lx rcvptr=%#x rcvsts=%#x/%#x\n", sc->sc_rxq.rxq_first, sc->sc_rxq.rxq_descmap->dm_segs[0].ds_addr, bcmeth_read_4(sc, sc->sc_rxq.rxq_reg_rcvptr), bcmeth_read_4(sc, sc->sc_rxq.rxq_reg_rcvsts0), bcmeth_read_4(sc, sc->sc_rxq.rxq_reg_rcvsts1)); aprint_error_dev(sc->sc_dev, "xmtbase=%p/%#lx xmtptr=%#x xmtsts=%#x/%#x\n", sc->sc_txq.txq_first, sc->sc_txq.txq_descmap->dm_segs[0].ds_addr, bcmeth_read_4(sc, sc->sc_txq.txq_reg_xmtptr), bcmeth_read_4(sc, sc->sc_txq.txq_reg_xmtsts0), bcmeth_read_4(sc, sc->sc_txq.txq_reg_xmtsts1)); intmask &= ~intstatus; work_flags |= WORK_REINIT; break; } } if (intmask != sc->sc_intmask) { bcmeth_write_4(sc, GMAC_INTMASK, sc->sc_intmask); } if (work_flags) { if (sc->sc_work_flags == 0) { workqueue_enqueue(sc->sc_workq, &sc->sc_work, NULL); } atomic_or_32(&sc->sc_work_flags, work_flags); rv = 1; } if (soft_flags) { if (sc->sc_soft_flags == 0) { softint_schedule(sc->sc_soft_ih); } atomic_or_32(&sc->sc_soft_flags, soft_flags); rv = 1; } mutex_exit(sc->sc_hwlock); return rv; } #ifdef BCMETH_MPSAFETX void bcmeth_soft_txintr(struct bcmeth_softc *sc) { mutex_enter(sc->sc_lock); /* * Let's do what we came here for. Consume transmitted * packets off the transmit ring. */ if (!bcmeth_txq_consume(sc, &sc->sc_txq) || !bcmeth_txq_enqueue(sc, &sc->sc_txq)) { BCMETH_EVCNT_INCR(sc->sc_ev_tx_stall); } if (sc->sc_if.if_flags & IFF_RUNNING) { mutex_spin_enter(sc->sc_hwlock); sc->sc_intmask |= XMTINT_0; bcmeth_write_4(sc, GMAC_INTMASK, sc->sc_intmask); mutex_spin_exit(sc->sc_hwlock); } mutex_exit(sc->sc_lock); } #endif /* BCMETH_MPSAFETX */ void bcmeth_soft_intr(void *arg) { struct bcmeth_softc * const sc = arg; struct ifnet * const ifp = &sc->sc_if; uint32_t intmask = 0; mutex_enter(sc->sc_lock); u_int soft_flags = atomic_swap_uint(&sc->sc_soft_flags, 0); BCMETH_EVCNT_INCR(sc->sc_ev_soft_intr); if ((soft_flags & SOFT_TXINTR) || bcmeth_txq_active_p(sc, &sc->sc_txq)) { /* * Let's do what we came here for. Consume transmitted * packets off the transmit ring. */ if (!bcmeth_txq_consume(sc, &sc->sc_txq) || !bcmeth_txq_enqueue(sc, &sc->sc_txq)) { BCMETH_EVCNT_INCR(sc->sc_ev_tx_stall); } intmask |= XMTINT_0; } if (soft_flags & SOFT_RXINTR) { /* * Let's consume */ while (bcmeth_rxq_consume(sc, &sc->sc_rxq, sc->sc_rxq.rxq_threshold / 4)) { /* * We've consumed a quarter of the ring and still have * more to do. Refill the ring. */ bcmeth_rxq_produce(sc, &sc->sc_rxq); } intmask |= RCVINT; } if (ifp->if_flags & IFF_RUNNING) { bcmeth_rxq_produce(sc, &sc->sc_rxq); mutex_spin_enter(sc->sc_hwlock); sc->sc_intmask |= intmask; bcmeth_write_4(sc, GMAC_INTMASK, sc->sc_intmask); mutex_spin_exit(sc->sc_hwlock); } mutex_exit(sc->sc_lock); } void bcmeth_worker(struct work *wk, void *arg) { struct bcmeth_softc * const sc = arg; struct ifnet * const ifp = &sc->sc_if; uint32_t intmask = 0; mutex_enter(sc->sc_lock); BCMETH_EVCNT_INCR(sc->sc_ev_work); uint32_t work_flags = atomic_swap_32(&sc->sc_work_flags, 0); if (work_flags & WORK_REINIT) { int s = splnet(); sc->sc_soft_flags = 0; bcmeth_ifinit(ifp); splx(s); work_flags &= ~WORK_RXUNDERFLOW; } if (work_flags & WORK_RXUNDERFLOW) { struct bcmeth_rxqueue * const rxq = &sc->sc_rxq; size_t threshold = 5 * rxq->rxq_threshold / 4; if (threshold >= rxq->rxq_last - rxq->rxq_first) { threshold = rxq->rxq_last - rxq->rxq_first - 1; } else { intmask |= RCVDESCUF; } aprint_normal_dev(sc->sc_dev, "increasing receive buffers from %zu to %zu\n", rxq->rxq_threshold, threshold); rxq->rxq_threshold = threshold; } if (work_flags & WORK_RXINTR) { /* * Let's consume */ while (bcmeth_rxq_consume(sc, &sc->sc_rxq, sc->sc_rxq.rxq_threshold / 4)) { /* * We've consumed a quarter of the ring and still have * more to do. Refill the ring. */ bcmeth_rxq_produce(sc, &sc->sc_rxq); } intmask |= RCVINT; } if (ifp->if_flags & IFF_RUNNING) { bcmeth_rxq_produce(sc, &sc->sc_rxq); #if 0 uint32_t intstatus = bcmeth_read_4(sc, GMAC_INTSTATUS); if (intstatus & RCVINT) { bcmeth_write_4(sc, GMAC_INTSTATUS, RCVINT); work_flags |= WORK_RXINTR; continue; } #endif mutex_spin_enter(sc->sc_hwlock); sc->sc_intmask |= intmask; bcmeth_write_4(sc, GMAC_INTMASK, sc->sc_intmask); mutex_spin_exit(sc->sc_hwlock); } mutex_exit(sc->sc_lock); }