dev/ic/dwc_eqos.c

1.13       ryo /* $NetBSD: dwc_eqos.c,v 1.13 2022/08/24 19:22:37 ryo Exp $ */
 1.1  jmcneill
 1.1  jmcneill /*-
 1.1  jmcneill  * Copyright (c) 2022 Jared McNeill <jmcneill (at) invisible.ca>
 1.1  jmcneill  * All rights reserved.
 1.1  jmcneill  *
 1.1  jmcneill  * Redistribution and use in source and binary forms, with or without
 1.1  jmcneill  * modification, are permitted provided that the following conditions
 1.1  jmcneill  * are met:
 1.1  jmcneill  * 1. Redistributions of source code must retain the above copyright
 1.1  jmcneill  *    notice, this list of conditions and the following disclaimer.
 1.1  jmcneill  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  jmcneill  *    notice, this list of conditions and the following disclaimer in the
 1.1  jmcneill  *    documentation and/or other materials provided with the distribution.
 1.1  jmcneill  *
 1.1  jmcneill  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
 1.1  jmcneill  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
 1.1  jmcneill  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
 1.1  jmcneill  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
 1.1  jmcneill  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
 1.1  jmcneill  * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
 1.1  jmcneill  * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
 1.1  jmcneill  * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
 1.1  jmcneill  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1  jmcneill  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1  jmcneill  * SUCH DAMAGE.
 1.1  jmcneill  */
 1.1  jmcneill
 1.1  jmcneill /*
 1.1  jmcneill  * DesignWare Ethernet Quality-of-Service controller
 1.1  jmcneill  */
 1.1  jmcneill
 1.1  jmcneill #include "opt_net_mpsafe.h"
 1.1  jmcneill
 1.1  jmcneill #include <sys/cdefs.h>
1.13       ryo __KERNEL_RCSID(0, "$NetBSD: dwc_eqos.c,v 1.13 2022/08/24 19:22:37 ryo Exp $");
 1.1  jmcneill
 1.1  jmcneill #include <sys/param.h>
 1.1  jmcneill #include <sys/bus.h>
 1.1  jmcneill #include <sys/device.h>
 1.1  jmcneill #include <sys/intr.h>
 1.1  jmcneill #include <sys/systm.h>
 1.1  jmcneill #include <sys/kernel.h>
 1.1  jmcneill #include <sys/mutex.h>
 1.1  jmcneill #include <sys/callout.h>
 1.1  jmcneill #include <sys/cprng.h>
 1.2       mrg #include <sys/evcnt.h>
 1.1  jmcneill
 1.1  jmcneill #include <sys/rndsource.h>
 1.1  jmcneill
 1.1  jmcneill #include <net/if.h>
 1.1  jmcneill #include <net/if_dl.h>
 1.1  jmcneill #include <net/if_ether.h>
 1.1  jmcneill #include <net/if_media.h>
 1.1  jmcneill #include <net/bpf.h>
 1.1  jmcneill
 1.1  jmcneill #include <dev/mii/miivar.h>
 1.1  jmcneill
 1.1  jmcneill #include <dev/ic/dwc_eqos_reg.h>
 1.1  jmcneill #include <dev/ic/dwc_eqos_var.h>
 1.1  jmcneill
1.13       ryo #define	EQOS_MAX_MTU		9000	/* up to 16364? but not tested */
1.13       ryo #define	EQOS_TXDMA_SIZE		(EQOS_MAX_MTU + ETHER_HDR_LEN + ETHER_CRC_LEN)
1.13       ryo #define	EQOS_RXDMA_SIZE		2048	/* Fixed value by hardware */
1.13       ryo CTASSERT(MCLBYTES >= EQOS_RXDMA_SIZE);
 1.8    martin
 1.1  jmcneill #ifdef EQOS_DEBUG
 1.8    martin unsigned int eqos_debug;
 1.8    martin #define	DPRINTF(FLAG, FORMAT, ...)	\
 1.8    martin 	if (eqos_debug & FLAG) 		\
 1.8    martin 		device_printf(sc->sc_dev, "%s: " FORMAT, \
 1.8    martin 		    __func__, ##__VA_ARGS__)
 1.1  jmcneill #else
 1.8    martin #define	DPRINTF(FLAG, FORMAT, ...)	((void)0)
 1.1  jmcneill #endif
 1.8    martin #define	EDEB_NOTE		1U<<0
 1.8    martin #define	EDEB_INTR		1U<<1
 1.8    martin #define	EDEB_RXRING		1U<<2
 1.8    martin #define	EDEB_TXRING		1U<<3
 1.1  jmcneill
 1.1  jmcneill #ifdef NET_MPSAFE
 1.1  jmcneill #define	EQOS_MPSAFE		1
 1.1  jmcneill #define	CALLOUT_FLAGS		CALLOUT_MPSAFE
 1.1  jmcneill #else
 1.1  jmcneill #define	CALLOUT_FLAGS		0
 1.1  jmcneill #endif
 1.1  jmcneill
 1.1  jmcneill #define	DESC_BOUNDARY		(1ULL << 32)
 1.1  jmcneill #define	DESC_ALIGN		sizeof(struct eqos_dma_desc)
 1.1  jmcneill #define	TX_DESC_COUNT		EQOS_DMA_DESC_COUNT
 1.1  jmcneill #define	TX_DESC_SIZE		(TX_DESC_COUNT * DESC_ALIGN)
 1.1  jmcneill #define	RX_DESC_COUNT		EQOS_DMA_DESC_COUNT
 1.1  jmcneill #define	RX_DESC_SIZE		(RX_DESC_COUNT * DESC_ALIGN)
 1.1  jmcneill #define	MII_BUSY_RETRY		1000
 1.1  jmcneill
 1.1  jmcneill #define	DESC_OFF(n)		((n) * sizeof(struct eqos_dma_desc))
 1.1  jmcneill #define	TX_SKIP(n, o)		(((n) + (o)) % TX_DESC_COUNT)
 1.1  jmcneill #define	TX_NEXT(n)		TX_SKIP(n, 1)
 1.1  jmcneill #define	RX_NEXT(n)		(((n) + 1) % RX_DESC_COUNT)
 1.1  jmcneill
 1.1  jmcneill #define	TX_MAX_SEGS		128
 1.1  jmcneill
 1.1  jmcneill #define	EQOS_LOCK(sc)			mutex_enter(&(sc)->sc_lock)
 1.1  jmcneill #define	EQOS_UNLOCK(sc)			mutex_exit(&(sc)->sc_lock)
 1.1  jmcneill #define	EQOS_ASSERT_LOCKED(sc)		KASSERT(mutex_owned(&(sc)->sc_lock))
 1.1  jmcneill
 1.1  jmcneill #define	EQOS_TXLOCK(sc)			mutex_enter(&(sc)->sc_txlock)
 1.1  jmcneill #define	EQOS_TXUNLOCK(sc)		mutex_exit(&(sc)->sc_txlock)
 1.1  jmcneill #define	EQOS_ASSERT_TXLOCKED(sc)	KASSERT(mutex_owned(&(sc)->sc_txlock))
 1.1  jmcneill
 1.1  jmcneill #define	EQOS_HW_FEATURE_ADDR64_32BIT(sc)				\
 1.1  jmcneill 	(((sc)->sc_hw_feature[1] & GMAC_MAC_HW_FEATURE1_ADDR64_MASK) ==	\
 1.1  jmcneill 	    GMAC_MAC_HW_FEATURE1_ADDR64_32BIT)
 1.1  jmcneill
 1.1  jmcneill
 1.1  jmcneill #define	RD4(sc, reg)			\
 1.1  jmcneill 	bus_space_read_4((sc)->sc_bst, (sc)->sc_bsh, (reg))
 1.1  jmcneill #define	WR4(sc, reg, val)		\
 1.1  jmcneill 	bus_space_write_4((sc)->sc_bst, (sc)->sc_bsh, (reg), (val))
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_mii_readreg(device_t dev, int phy, int reg, uint16_t *val)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc *sc = device_private(dev);
 1.1  jmcneill 	uint32_t addr;
 1.1  jmcneill 	int retry;
 1.1  jmcneill
 1.1  jmcneill 	addr = sc->sc_clock_range |
 1.1  jmcneill 	    (phy << GMAC_MAC_MDIO_ADDRESS_PA_SHIFT) |
 1.1  jmcneill 	    (reg << GMAC_MAC_MDIO_ADDRESS_RDA_SHIFT) |
 1.1  jmcneill 	    GMAC_MAC_MDIO_ADDRESS_GOC_READ |
 1.1  jmcneill 	    GMAC_MAC_MDIO_ADDRESS_GB;
 1.1  jmcneill 	WR4(sc, GMAC_MAC_MDIO_ADDRESS, addr);
 1.1  jmcneill
 1.1  jmcneill 	delay(10000);
 1.1  jmcneill
 1.1  jmcneill 	for (retry = MII_BUSY_RETRY; retry > 0; retry--) {
 1.1  jmcneill 		addr = RD4(sc, GMAC_MAC_MDIO_ADDRESS);
 1.1  jmcneill 		if ((addr & GMAC_MAC_MDIO_ADDRESS_GB) == 0) {
 1.1  jmcneill 			*val = RD4(sc, GMAC_MAC_MDIO_DATA) & 0xFFFF;
 1.1  jmcneill 			break;
 1.1  jmcneill 		}
 1.1  jmcneill 		delay(10);
 1.1  jmcneill 	}
 1.1  jmcneill 	if (retry == 0) {
 1.1  jmcneill 		device_printf(dev, "phy read timeout, phy=%d reg=%d\n",
 1.1  jmcneill 		    phy, reg);
 1.1  jmcneill 		return ETIMEDOUT;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_mii_writereg(device_t dev, int phy, int reg, uint16_t val)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc *sc = device_private(dev);
 1.1  jmcneill 	uint32_t addr;
 1.1  jmcneill 	int retry;
 1.1  jmcneill
 1.1  jmcneill 	WR4(sc, GMAC_MAC_MDIO_DATA, val);
 1.1  jmcneill
 1.1  jmcneill 	addr = sc->sc_clock_range |
 1.1  jmcneill 	    (phy << GMAC_MAC_MDIO_ADDRESS_PA_SHIFT) |
 1.1  jmcneill 	    (reg << GMAC_MAC_MDIO_ADDRESS_RDA_SHIFT) |
 1.1  jmcneill 	    GMAC_MAC_MDIO_ADDRESS_GOC_WRITE |
 1.1  jmcneill 	    GMAC_MAC_MDIO_ADDRESS_GB;
 1.1  jmcneill 	WR4(sc, GMAC_MAC_MDIO_ADDRESS, addr);
 1.1  jmcneill
 1.1  jmcneill 	delay(10000);
 1.1  jmcneill
 1.1  jmcneill 	for (retry = MII_BUSY_RETRY; retry > 0; retry--) {
 1.1  jmcneill 		addr = RD4(sc, GMAC_MAC_MDIO_ADDRESS);
 1.1  jmcneill 		if ((addr & GMAC_MAC_MDIO_ADDRESS_GB) == 0) {
 1.1  jmcneill 			break;
 1.1  jmcneill 		}
 1.1  jmcneill 		delay(10);
 1.1  jmcneill 	}
 1.1  jmcneill 	if (retry == 0) {
 1.1  jmcneill 		device_printf(dev, "phy write timeout, phy=%d reg=%d\n",
 1.1  jmcneill 		    phy, reg);
 1.1  jmcneill 		return ETIMEDOUT;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_update_link(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	struct mii_data *mii = &sc->sc_mii;
 1.1  jmcneill 	uint64_t baudrate;
 1.1  jmcneill 	uint32_t conf;
 1.1  jmcneill
 1.1  jmcneill 	baudrate = ifmedia_baudrate(mii->mii_media_active);
 1.1  jmcneill
 1.1  jmcneill 	conf = RD4(sc, GMAC_MAC_CONFIGURATION);
 1.1  jmcneill 	switch (baudrate) {
 1.1  jmcneill 	case IF_Mbps(10):
 1.1  jmcneill 		conf |= GMAC_MAC_CONFIGURATION_PS;
 1.1  jmcneill 		conf &= ~GMAC_MAC_CONFIGURATION_FES;
 1.1  jmcneill 		break;
 1.1  jmcneill 	case IF_Mbps(100):
 1.1  jmcneill 		conf |= GMAC_MAC_CONFIGURATION_PS;
 1.1  jmcneill 		conf |= GMAC_MAC_CONFIGURATION_FES;
 1.1  jmcneill 		break;
 1.1  jmcneill 	case IF_Gbps(1):
 1.1  jmcneill 		conf &= ~GMAC_MAC_CONFIGURATION_PS;
 1.1  jmcneill 		conf &= ~GMAC_MAC_CONFIGURATION_FES;
 1.1  jmcneill 		break;
 1.1  jmcneill 	case IF_Mbps(2500ULL):
 1.1  jmcneill 		conf &= ~GMAC_MAC_CONFIGURATION_PS;
 1.1  jmcneill 		conf |= GMAC_MAC_CONFIGURATION_FES;
 1.1  jmcneill 		break;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	if ((IFM_OPTIONS(mii->mii_media_active) & IFM_FDX) != 0) {
 1.1  jmcneill 		conf |= GMAC_MAC_CONFIGURATION_DM;
 1.1  jmcneill 	} else {
 1.1  jmcneill 		conf &= ~GMAC_MAC_CONFIGURATION_DM;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	WR4(sc, GMAC_MAC_CONFIGURATION, conf);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_mii_statchg(struct ifnet *ifp)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc * const sc = ifp->if_softc;
 1.1  jmcneill
 1.1  jmcneill 	eqos_update_link(sc);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_dma_sync(struct eqos_softc *sc, bus_dmamap_t map,
 1.1  jmcneill     u_int start, u_int end, u_int total, int flags)
 1.1  jmcneill {
 1.1  jmcneill 	if (end > start) {
 1.1  jmcneill 		bus_dmamap_sync(sc->sc_dmat, map, DESC_OFF(start),
 1.1  jmcneill 		    DESC_OFF(end) - DESC_OFF(start), flags);
 1.1  jmcneill 	} else {
 1.1  jmcneill 		bus_dmamap_sync(sc->sc_dmat, map, DESC_OFF(start),
 1.1  jmcneill 		    DESC_OFF(total) - DESC_OFF(start), flags);
 1.8    martin 		if (end > 0) {
 1.1  jmcneill 			bus_dmamap_sync(sc->sc_dmat, map, DESC_OFF(0),
 1.1  jmcneill 			    DESC_OFF(end) - DESC_OFF(0), flags);
 1.1  jmcneill 		}
 1.1  jmcneill 	}
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_setup_txdesc(struct eqos_softc *sc, int index, int flags,
 1.1  jmcneill     bus_addr_t paddr, u_int len, u_int total_len)
 1.1  jmcneill {
 1.1  jmcneill 	uint32_t tdes2, tdes3;
 1.1  jmcneill
 1.1  jmcneill 	if (paddr == 0 || len == 0) {
 1.8    martin 		DPRINTF(EDEB_TXRING,
 1.8    martin 		    "tx for desc %u done!\n", index);
 1.1  jmcneill 		KASSERT(flags == 0);
 1.1  jmcneill 		tdes2 = 0;
 1.1  jmcneill 		tdes3 = 0;
 1.1  jmcneill 		--sc->sc_tx.queued;
 1.1  jmcneill 	} else {
1.12       ryo 		tdes2 = (flags & EQOS_TDES3_TX_LD) ? EQOS_TDES2_TX_IOC : 0;
 1.1  jmcneill 		tdes3 = flags;
 1.1  jmcneill 		++sc->sc_tx.queued;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	KASSERT(!EQOS_HW_FEATURE_ADDR64_32BIT(sc) || (paddr >> 32) == 0);
 1.1  jmcneill
 1.1  jmcneill 	sc->sc_tx.desc_ring[index].tdes0 = htole32((uint32_t)paddr);
 1.1  jmcneill 	sc->sc_tx.desc_ring[index].tdes1 = htole32((uint32_t)(paddr >> 32));
 1.1  jmcneill 	sc->sc_tx.desc_ring[index].tdes2 = htole32(tdes2 | len);
 1.1  jmcneill 	sc->sc_tx.desc_ring[index].tdes3 = htole32(tdes3 | total_len);
 1.8    martin 	DPRINTF(EDEB_TXRING, "preparing desc %u\n", index);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_setup_txbuf(struct eqos_softc *sc, int index, struct mbuf *m)
 1.1  jmcneill {
 1.1  jmcneill 	bus_dma_segment_t *segs;
 1.1  jmcneill 	int error, nsegs, cur, i;
 1.1  jmcneill 	uint32_t flags;
 1.1  jmcneill 	bool nospace;
 1.1  jmcneill
 1.1  jmcneill 	/* at least one descriptor free ? */
 1.1  jmcneill 	if (sc->sc_tx.queued >= TX_DESC_COUNT - 1)
 1.1  jmcneill 		return -1;
 1.1  jmcneill
 1.1  jmcneill 	error = bus_dmamap_load_mbuf(sc->sc_dmat,
 1.1  jmcneill 	    sc->sc_tx.buf_map[index].map, m, BUS_DMA_WRITE | BUS_DMA_NOWAIT);
 1.1  jmcneill 	if (error == EFBIG) {
 1.1  jmcneill 		device_printf(sc->sc_dev,
 1.1  jmcneill 		    "TX packet needs too many DMA segments, dropping...\n");
 1.1  jmcneill 		return -2;
 1.1  jmcneill 	}
 1.1  jmcneill 	if (error != 0) {
 1.1  jmcneill 		device_printf(sc->sc_dev,
 1.1  jmcneill 		    "TX packet cannot be mapped, retried...\n");
 1.1  jmcneill 		return 0;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	segs = sc->sc_tx.buf_map[index].map->dm_segs;
 1.1  jmcneill 	nsegs = sc->sc_tx.buf_map[index].map->dm_nsegs;
 1.1  jmcneill
 1.1  jmcneill 	nospace = sc->sc_tx.queued >= TX_DESC_COUNT - nsegs;
 1.1  jmcneill 	if (nospace) {
 1.1  jmcneill 		bus_dmamap_unload(sc->sc_dmat,
 1.1  jmcneill 		    sc->sc_tx.buf_map[index].map);
 1.1  jmcneill 		/* XXX coalesce and retry ? */
 1.1  jmcneill 		return -1;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.2       mrg 	bus_dmamap_sync(sc->sc_dmat, sc->sc_tx.buf_map[index].map,
 1.5  riastrad 	    0, sc->sc_tx.buf_map[index].map->dm_mapsize, BUS_DMASYNC_PREWRITE);
 1.1  jmcneill
 1.1  jmcneill 	/* stored in same index as loaded map */
 1.1  jmcneill 	sc->sc_tx.buf_map[index].mbuf = m;
 1.1  jmcneill
1.12       ryo 	flags = EQOS_TDES3_TX_FD;
 1.1  jmcneill
 1.1  jmcneill 	for (cur = index, i = 0; i < nsegs; i++) {
 1.1  jmcneill 		if (i == nsegs - 1)
1.12       ryo 			flags |= EQOS_TDES3_TX_LD;
 1.1  jmcneill
 1.1  jmcneill 		eqos_setup_txdesc(sc, cur, flags, segs[i].ds_addr,
 1.1  jmcneill 		    segs[i].ds_len, m->m_pkthdr.len);
1.12       ryo 		flags &= ~EQOS_TDES3_TX_FD;
 1.1  jmcneill 		cur = TX_NEXT(cur);
 1.1  jmcneill
1.12       ryo 		flags |= EQOS_TDES3_TX_OWN;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	/*
 1.1  jmcneill 	 * Defer setting OWN bit on the first descriptor until all
 1.4  riastrad 	 * descriptors have been updated.  The hardware will not try to
 1.4  riastrad 	 * process any descriptors past the first one still owned by
 1.4  riastrad 	 * software (i.e., with the OWN bit clear).
 1.1  jmcneill 	 */
 1.4  riastrad 	bus_dmamap_sync(sc->sc_dmat, sc->sc_tx.desc_map,
 1.4  riastrad 	    DESC_OFF(index), offsetof(struct eqos_dma_desc, tdes3),
 1.4  riastrad 	    BUS_DMASYNC_PREWRITE);
 1.8    martin 	DPRINTF(EDEB_TXRING, "passing tx desc %u to hardware, cur: %u, "
 1.8    martin 	    "next: %u, queued: %u\n",
 1.8    martin 	    index, sc->sc_tx.cur, sc->sc_tx.next, sc->sc_tx.queued);
1.12       ryo 	sc->sc_tx.desc_ring[index].tdes3 |= htole32(EQOS_TDES3_TX_OWN);
 1.1  jmcneill
 1.1  jmcneill 	return nsegs;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_setup_rxdesc(struct eqos_softc *sc, int index, bus_addr_t paddr)
 1.1  jmcneill {
 1.4  riastrad
 1.1  jmcneill 	sc->sc_rx.desc_ring[index].tdes0 = htole32((uint32_t)paddr);
 1.1  jmcneill 	sc->sc_rx.desc_ring[index].tdes1 = htole32((uint32_t)(paddr >> 32));
 1.1  jmcneill 	sc->sc_rx.desc_ring[index].tdes2 = htole32(0);
 1.4  riastrad 	bus_dmamap_sync(sc->sc_dmat, sc->sc_rx.desc_map,
 1.4  riastrad 	    DESC_OFF(index), offsetof(struct eqos_dma_desc, tdes3),
 1.4  riastrad 	    BUS_DMASYNC_PREWRITE);
1.12       ryo 	sc->sc_rx.desc_ring[index].tdes3 = htole32(EQOS_TDES3_RX_OWN |
1.12       ryo 	    EQOS_TDES3_RX_IOC | EQOS_TDES3_RX_BUF1V);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_setup_rxbuf(struct eqos_softc *sc, int index, struct mbuf *m)
 1.1  jmcneill {
 1.1  jmcneill 	int error;
 1.1  jmcneill
1.13       ryo #if MCLBYTES >= (EQOS_RXDMA_SIZE + ETHER_ALIGN)
1.13       ryo 	m_adj(m, ETHER_ALIGN);
1.13       ryo #endif
1.13       ryo
 1.1  jmcneill 	error = bus_dmamap_load_mbuf(sc->sc_dmat,
 1.1  jmcneill 	    sc->sc_rx.buf_map[index].map, m, BUS_DMA_READ | BUS_DMA_NOWAIT);
 1.1  jmcneill 	if (error != 0)
 1.1  jmcneill 		return error;
 1.1  jmcneill
 1.1  jmcneill 	bus_dmamap_sync(sc->sc_dmat, sc->sc_rx.buf_map[index].map,
 1.1  jmcneill 	    0, sc->sc_rx.buf_map[index].map->dm_mapsize,
 1.1  jmcneill 	    BUS_DMASYNC_PREREAD);
 1.1  jmcneill
 1.1  jmcneill 	sc->sc_rx.buf_map[index].mbuf = m;
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static struct mbuf *
 1.1  jmcneill eqos_alloc_mbufcl(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	struct mbuf *m;
 1.1  jmcneill
 1.1  jmcneill 	m = m_getcl(M_NOWAIT, MT_DATA, M_PKTHDR);
 1.1  jmcneill 	if (m != NULL)
 1.1  jmcneill 		m->m_pkthdr.len = m->m_len = m->m_ext.ext_size;
 1.1  jmcneill
 1.1  jmcneill 	return m;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_enable_intr(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_INTR_ENABLE,
 1.1  jmcneill 	    GMAC_DMA_CHAN0_INTR_ENABLE_NIE |
 1.1  jmcneill 	    GMAC_DMA_CHAN0_INTR_ENABLE_AIE |
 1.1  jmcneill 	    GMAC_DMA_CHAN0_INTR_ENABLE_FBE |
 1.1  jmcneill 	    GMAC_DMA_CHAN0_INTR_ENABLE_RIE |
 1.1  jmcneill 	    GMAC_DMA_CHAN0_INTR_ENABLE_TIE);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_disable_intr(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_INTR_ENABLE, 0);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_tick(void *softc)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc *sc = softc;
 1.1  jmcneill 	struct mii_data *mii = &sc->sc_mii;
 1.1  jmcneill #ifndef EQOS_MPSAFE
 1.1  jmcneill 	int s = splnet();
 1.1  jmcneill #endif
 1.1  jmcneill
 1.1  jmcneill 	EQOS_LOCK(sc);
 1.1  jmcneill 	mii_tick(mii);
 1.1  jmcneill 	callout_schedule(&sc->sc_stat_ch, hz);
 1.1  jmcneill 	EQOS_UNLOCK(sc);
 1.1  jmcneill
 1.1  jmcneill #ifndef EQOS_MPSAFE
 1.1  jmcneill 	splx(s);
 1.1  jmcneill #endif
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static uint32_t
 1.1  jmcneill eqos_bitrev32(uint32_t x)
 1.1  jmcneill {
 1.1  jmcneill 	x = (((x & 0xaaaaaaaa) >> 1) | ((x & 0x55555555) << 1));
 1.1  jmcneill 	x = (((x & 0xcccccccc) >> 2) | ((x & 0x33333333) << 2));
 1.1  jmcneill 	x = (((x & 0xf0f0f0f0) >> 4) | ((x & 0x0f0f0f0f) << 4));
 1.1  jmcneill 	x = (((x & 0xff00ff00) >> 8) | ((x & 0x00ff00ff) << 8));
 1.1  jmcneill
 1.1  jmcneill 	return (x >> 16) | (x << 16);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_setup_rxfilter(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	struct ethercom *ec = &sc->sc_ec;
 1.1  jmcneill 	struct ifnet *ifp = &ec->ec_if;
 1.1  jmcneill 	uint32_t pfil, crc, hashreg, hashbit, hash[2];
 1.1  jmcneill 	struct ether_multi *enm;
 1.1  jmcneill 	struct ether_multistep step;
 1.1  jmcneill 	const uint8_t *eaddr;
 1.1  jmcneill 	uint32_t val;
 1.1  jmcneill
 1.1  jmcneill 	EQOS_ASSERT_LOCKED(sc);
 1.1  jmcneill
 1.1  jmcneill 	pfil = RD4(sc, GMAC_MAC_PACKET_FILTER);
 1.1  jmcneill 	pfil &= ~(GMAC_MAC_PACKET_FILTER_PR |
 1.1  jmcneill 		  GMAC_MAC_PACKET_FILTER_PM |
 1.1  jmcneill 		  GMAC_MAC_PACKET_FILTER_HMC |
 1.1  jmcneill 		  GMAC_MAC_PACKET_FILTER_PCF_MASK);
 1.1  jmcneill 	hash[0] = hash[1] = ~0U;
 1.1  jmcneill
 1.1  jmcneill 	if ((ifp->if_flags & IFF_PROMISC) != 0) {
 1.1  jmcneill 		pfil |= GMAC_MAC_PACKET_FILTER_PR |
 1.1  jmcneill 			GMAC_MAC_PACKET_FILTER_PCF_ALL;
 1.1  jmcneill 	} else if ((ifp->if_flags & IFF_ALLMULTI) != 0) {
 1.1  jmcneill 		pfil |= GMAC_MAC_PACKET_FILTER_PM;
 1.1  jmcneill 	} else {
 1.1  jmcneill 		hash[0] = hash[1] = 0;
 1.1  jmcneill 		pfil |= GMAC_MAC_PACKET_FILTER_HMC;
 1.1  jmcneill 		ETHER_LOCK(ec);
 1.1  jmcneill 		ETHER_FIRST_MULTI(step, ec, enm);
 1.1  jmcneill 		while (enm != NULL) {
 1.1  jmcneill 			crc = ether_crc32_le(enm->enm_addrlo, ETHER_ADDR_LEN);
 1.1  jmcneill 			crc &= 0x7f;
 1.1  jmcneill 			crc = eqos_bitrev32(~crc) >> 26;
 1.1  jmcneill 			hashreg = (crc >> 5);
 1.1  jmcneill 			hashbit = (crc & 0x1f);
 1.1  jmcneill 			hash[hashreg] |= (1 << hashbit);
 1.1  jmcneill 			ETHER_NEXT_MULTI(step, enm);
 1.1  jmcneill 		}
 1.1  jmcneill 		ETHER_UNLOCK(ec);
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	/* Write our unicast address */
 1.1  jmcneill 	eaddr = CLLADDR(ifp->if_sadl);
 1.1  jmcneill 	val = eaddr[4] | (eaddr[5] << 8);
 1.1  jmcneill 	WR4(sc, GMAC_MAC_ADDRESS0_HIGH, val);
 1.1  jmcneill 	val = eaddr[0] | (eaddr[1] << 8) | (eaddr[2] << 16) |
 1.1  jmcneill 	    (eaddr[3] << 24);
 1.1  jmcneill 	WR4(sc, GMAC_MAC_ADDRESS0_LOW, val);
 1.1  jmcneill
 1.1  jmcneill 	/* Multicast hash filters */
 1.9    martin 	WR4(sc, GMAC_MAC_HASH_TABLE_REG0, hash[0]);
 1.9    martin 	WR4(sc, GMAC_MAC_HASH_TABLE_REG1, hash[1]);
 1.1  jmcneill
 1.8    martin 	DPRINTF(EDEB_NOTE, "writing new packet filter config "
 1.8    martin 	    "%08x, hash[1]=%08x, hash[0]=%08x\n", pfil, hash[1], hash[0]);
 1.1  jmcneill 	/* Packet filter config */
 1.1  jmcneill 	WR4(sc, GMAC_MAC_PACKET_FILTER, pfil);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_reset(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	uint32_t val;
 1.1  jmcneill 	int retry;
 1.1  jmcneill
 1.1  jmcneill 	WR4(sc, GMAC_DMA_MODE, GMAC_DMA_MODE_SWR);
 1.1  jmcneill 	for (retry = 2000; retry > 0; retry--) {
 1.1  jmcneill 		delay(1000);
 1.1  jmcneill 		val = RD4(sc, GMAC_DMA_MODE);
 1.1  jmcneill 		if ((val & GMAC_DMA_MODE_SWR) == 0) {
 1.1  jmcneill 			return 0;
 1.1  jmcneill 		}
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	device_printf(sc->sc_dev, "reset timeout!\n");
 1.1  jmcneill 	return ETIMEDOUT;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_init_rings(struct eqos_softc *sc, int qid)
 1.1  jmcneill {
 1.7    martin 	sc->sc_tx.cur = sc->sc_tx.next = sc->sc_tx.queued = 0;
 1.1  jmcneill
1.13       ryo 	sc->sc_rx_discarding = false;
1.13       ryo 	if (sc->sc_rx_receiving_m != NULL)
1.13       ryo 		m_freem(sc->sc_rx_receiving_m);
1.13       ryo 	sc->sc_rx_receiving_m = NULL;
1.13       ryo 	sc->sc_rx_receiving_m_last = NULL;
1.13       ryo
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_TX_BASE_ADDR_HI,
 1.1  jmcneill 	    (uint32_t)(sc->sc_tx.desc_ring_paddr >> 32));
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_TX_BASE_ADDR,
 1.1  jmcneill 	    (uint32_t)sc->sc_tx.desc_ring_paddr);
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_TX_RING_LEN, TX_DESC_COUNT - 1);
 1.8    martin 	DPRINTF(EDEB_TXRING, "tx ring paddr %lx with %u decriptors\n",
 1.8    martin 	    sc->sc_tx.desc_ring_paddr, TX_DESC_COUNT);
 1.1  jmcneill
 1.8    martin 	sc->sc_rx.cur = sc->sc_rx.next = sc->sc_rx.queued = 0;
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_RX_BASE_ADDR_HI,
 1.1  jmcneill 	    (uint32_t)(sc->sc_rx.desc_ring_paddr >> 32));
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_RX_BASE_ADDR,
 1.1  jmcneill 	    (uint32_t)sc->sc_rx.desc_ring_paddr);
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_RX_RING_LEN, RX_DESC_COUNT - 1);
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_RX_END_ADDR,
 1.1  jmcneill 	    (uint32_t)sc->sc_rx.desc_ring_paddr +
 1.1  jmcneill 	    DESC_OFF((sc->sc_rx.cur - 1) % RX_DESC_COUNT));
 1.8    martin 	DPRINTF(EDEB_RXRING, "rx ring paddr %lx with %u decriptors\n",
 1.8    martin 	    sc->sc_rx.desc_ring_paddr, RX_DESC_COUNT);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_init_locked(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1  jmcneill 	struct mii_data *mii = &sc->sc_mii;
1.10       ryo 	uint32_t val, tqs, rqs;
 1.1  jmcneill
 1.1  jmcneill 	EQOS_ASSERT_LOCKED(sc);
 1.1  jmcneill 	EQOS_ASSERT_TXLOCKED(sc);
 1.1  jmcneill
 1.1  jmcneill 	if ((ifp->if_flags & IFF_RUNNING) != 0)
 1.1  jmcneill 		return 0;
 1.1  jmcneill
 1.1  jmcneill 	/* Setup TX/RX rings */
 1.1  jmcneill 	eqos_init_rings(sc, 0);
 1.1  jmcneill
 1.1  jmcneill 	/* Setup RX filter */
 1.1  jmcneill 	eqos_setup_rxfilter(sc);
 1.1  jmcneill
 1.1  jmcneill 	WR4(sc, GMAC_MAC_1US_TIC_COUNTER, (sc->sc_csr_clock / 1000000) - 1);
 1.1  jmcneill
 1.1  jmcneill 	/* Enable transmit and receive DMA */
 1.1  jmcneill 	val = RD4(sc, GMAC_DMA_CHAN0_CONTROL);
 1.1  jmcneill 	val &= ~GMAC_DMA_CHAN0_CONTROL_DSL_MASK;
 1.1  jmcneill 	val |= ((DESC_ALIGN - 16) / 8) << GMAC_DMA_CHAN0_CONTROL_DSL_SHIFT;
 1.1  jmcneill 	val |= GMAC_DMA_CHAN0_CONTROL_PBLX8;
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_CONTROL, val);
 1.1  jmcneill 	val = RD4(sc, GMAC_DMA_CHAN0_TX_CONTROL);
 1.1  jmcneill 	val |= GMAC_DMA_CHAN0_TX_CONTROL_OSP;
 1.1  jmcneill 	val |= GMAC_DMA_CHAN0_TX_CONTROL_START;
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_TX_CONTROL, val);
 1.1  jmcneill 	val = RD4(sc, GMAC_DMA_CHAN0_RX_CONTROL);
 1.1  jmcneill 	val &= ~GMAC_DMA_CHAN0_RX_CONTROL_RBSZ_MASK;
 1.1  jmcneill 	val |= (MCLBYTES << GMAC_DMA_CHAN0_RX_CONTROL_RBSZ_SHIFT);
 1.1  jmcneill 	val |= GMAC_DMA_CHAN0_RX_CONTROL_START;
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_RX_CONTROL, val);
 1.1  jmcneill
 1.6  jmcneill 	/* Disable counters */
 1.6  jmcneill 	WR4(sc, GMAC_MMC_CONTROL,
 1.6  jmcneill 	    GMAC_MMC_CONTROL_CNTFREEZ |
 1.6  jmcneill 	    GMAC_MMC_CONTROL_CNTPRST |
 1.6  jmcneill 	    GMAC_MMC_CONTROL_CNTPRSTLVL);
 1.6  jmcneill
 1.1  jmcneill 	/* Configure operation modes */
 1.1  jmcneill 	WR4(sc, GMAC_MTL_TXQ0_OPERATION_MODE,
 1.1  jmcneill 	    GMAC_MTL_TXQ0_OPERATION_MODE_TSF |
 1.1  jmcneill 	    GMAC_MTL_TXQ0_OPERATION_MODE_TXQEN_EN);
 1.1  jmcneill 	WR4(sc, GMAC_MTL_RXQ0_OPERATION_MODE,
 1.1  jmcneill 	    GMAC_MTL_RXQ0_OPERATION_MODE_RSF |
 1.1  jmcneill 	    GMAC_MTL_RXQ0_OPERATION_MODE_FEP |
 1.1  jmcneill 	    GMAC_MTL_RXQ0_OPERATION_MODE_FUP);
 1.1  jmcneill
1.10       ryo 	/*
1.10       ryo 	 * TX/RX fifo size in hw_feature[1] are log2(n/128), and
1.10       ryo 	 * TQS/RQS in TXQ0/RXQ0_OPERATION_MODE are n/256-1.
1.10       ryo 	 */
1.10       ryo 	tqs = (128 << __SHIFTOUT(sc->sc_hw_feature[1],
1.10       ryo 	    GMAC_MAC_HW_FEATURE1_TXFIFOSIZE) / 256) - 1;
1.10       ryo 	val = RD4(sc, GMAC_MTL_TXQ0_OPERATION_MODE);
1.10       ryo 	val &= ~GMAC_MTL_TXQ0_OPERATION_MODE_TQS;
1.10       ryo 	val |= __SHIFTIN(tqs, GMAC_MTL_TXQ0_OPERATION_MODE_TQS);
1.10       ryo 	WR4(sc, GMAC_MTL_TXQ0_OPERATION_MODE, val);
1.10       ryo
1.10       ryo 	rqs = (128 << __SHIFTOUT(sc->sc_hw_feature[1],
1.10       ryo 	    GMAC_MAC_HW_FEATURE1_RXFIFOSIZE) / 256) - 1;
1.10       ryo 	val = RD4(sc, GMAC_MTL_RXQ0_OPERATION_MODE);
1.10       ryo 	val &= ~GMAC_MTL_RXQ0_OPERATION_MODE_RQS;
1.10       ryo 	val |= __SHIFTIN(rqs, GMAC_MTL_RXQ0_OPERATION_MODE_RQS);
1.10       ryo 	WR4(sc, GMAC_MTL_RXQ0_OPERATION_MODE, val);
1.10       ryo
 1.1  jmcneill 	/* Enable flow control */
 1.1  jmcneill 	val = RD4(sc, GMAC_MAC_Q0_TX_FLOW_CTRL);
 1.1  jmcneill 	val |= 0xFFFFU << GMAC_MAC_Q0_TX_FLOW_CTRL_PT_SHIFT;
 1.1  jmcneill 	val |= GMAC_MAC_Q0_TX_FLOW_CTRL_TFE;
 1.1  jmcneill 	WR4(sc, GMAC_MAC_Q0_TX_FLOW_CTRL, val);
 1.1  jmcneill 	val = RD4(sc, GMAC_MAC_RX_FLOW_CTRL);
 1.1  jmcneill 	val |= GMAC_MAC_RX_FLOW_CTRL_RFE;
 1.1  jmcneill 	WR4(sc, GMAC_MAC_RX_FLOW_CTRL, val);
 1.1  jmcneill
1.10       ryo 	/* set RX queue mode. must be in DCB mode. */
1.10       ryo 	val = __SHIFTIN(GMAC_RXQ_CTRL0_EN_DCB, GMAC_RXQ_CTRL0_EN_MASK);
1.10       ryo 	WR4(sc, GMAC_RXQ_CTRL0, val);
1.10       ryo
 1.1  jmcneill 	/* Enable transmitter and receiver */
 1.1  jmcneill 	val = RD4(sc, GMAC_MAC_CONFIGURATION);
 1.1  jmcneill 	val |= GMAC_MAC_CONFIGURATION_BE;
 1.1  jmcneill 	val |= GMAC_MAC_CONFIGURATION_JD;
 1.1  jmcneill 	val |= GMAC_MAC_CONFIGURATION_JE;
 1.1  jmcneill 	val |= GMAC_MAC_CONFIGURATION_DCRS;
 1.1  jmcneill 	val |= GMAC_MAC_CONFIGURATION_TE;
 1.1  jmcneill 	val |= GMAC_MAC_CONFIGURATION_RE;
 1.1  jmcneill 	WR4(sc, GMAC_MAC_CONFIGURATION, val);
 1.1  jmcneill
 1.1  jmcneill 	/* Enable interrupts */
 1.1  jmcneill 	eqos_enable_intr(sc);
 1.1  jmcneill
 1.1  jmcneill 	ifp->if_flags |= IFF_RUNNING;
 1.1  jmcneill 	ifp->if_flags &= ~IFF_OACTIVE;
 1.1  jmcneill
 1.1  jmcneill 	mii_mediachg(mii);
 1.1  jmcneill 	callout_schedule(&sc->sc_stat_ch, hz);
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_init(struct ifnet *ifp)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc *sc = ifp->if_softc;
 1.1  jmcneill 	int error;
 1.1  jmcneill
 1.1  jmcneill 	EQOS_LOCK(sc);
 1.1  jmcneill 	EQOS_TXLOCK(sc);
 1.1  jmcneill 	error = eqos_init_locked(sc);
 1.1  jmcneill 	EQOS_TXUNLOCK(sc);
 1.1  jmcneill 	EQOS_UNLOCK(sc);
 1.1  jmcneill
 1.1  jmcneill 	return error;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_stop_locked(struct eqos_softc *sc, int disable)
 1.1  jmcneill {
 1.1  jmcneill 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1  jmcneill 	uint32_t val;
 1.1  jmcneill 	int retry;
 1.1  jmcneill
 1.1  jmcneill 	EQOS_ASSERT_LOCKED(sc);
 1.1  jmcneill
 1.1  jmcneill 	callout_stop(&sc->sc_stat_ch);
 1.1  jmcneill
 1.1  jmcneill 	mii_down(&sc->sc_mii);
 1.1  jmcneill
 1.1  jmcneill 	/* Disable receiver */
 1.1  jmcneill 	val = RD4(sc, GMAC_MAC_CONFIGURATION);
 1.1  jmcneill 	val &= ~GMAC_MAC_CONFIGURATION_RE;
 1.1  jmcneill 	WR4(sc, GMAC_MAC_CONFIGURATION, val);
 1.1  jmcneill
 1.1  jmcneill 	/* Stop receive DMA */
 1.1  jmcneill 	val = RD4(sc, GMAC_DMA_CHAN0_RX_CONTROL);
 1.1  jmcneill 	val &= ~GMAC_DMA_CHAN0_RX_CONTROL_START;
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_RX_CONTROL, val);
 1.1  jmcneill
 1.1  jmcneill 	/* Stop transmit DMA */
 1.1  jmcneill 	val = RD4(sc, GMAC_DMA_CHAN0_TX_CONTROL);
 1.1  jmcneill 	val &= ~GMAC_DMA_CHAN0_TX_CONTROL_START;
 1.1  jmcneill 	WR4(sc, GMAC_DMA_CHAN0_TX_CONTROL, val);
 1.1  jmcneill
 1.1  jmcneill 	if (disable) {
 1.1  jmcneill 		/* Flush data in the TX FIFO */
 1.1  jmcneill 		val = RD4(sc, GMAC_MTL_TXQ0_OPERATION_MODE);
 1.1  jmcneill 		val |= GMAC_MTL_TXQ0_OPERATION_MODE_FTQ;
 1.1  jmcneill 		WR4(sc, GMAC_MTL_TXQ0_OPERATION_MODE, val);
 1.1  jmcneill 		/* Wait for flush to complete */
 1.1  jmcneill 		for (retry = 10000; retry > 0; retry--) {
 1.1  jmcneill 			val = RD4(sc, GMAC_MTL_TXQ0_OPERATION_MODE);
 1.1  jmcneill 			if ((val & GMAC_MTL_TXQ0_OPERATION_MODE_FTQ) == 0) {
 1.1  jmcneill 				break;
 1.1  jmcneill 			}
 1.1  jmcneill 			delay(1);
 1.1  jmcneill 		}
 1.1  jmcneill 		if (retry == 0) {
 1.1  jmcneill 			device_printf(sc->sc_dev,
 1.1  jmcneill 			    "timeout flushing TX queue\n");
 1.1  jmcneill 		}
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	/* Disable transmitter */
 1.1  jmcneill 	val = RD4(sc, GMAC_MAC_CONFIGURATION);
 1.1  jmcneill 	val &= ~GMAC_MAC_CONFIGURATION_TE;
 1.1  jmcneill 	WR4(sc, GMAC_MAC_CONFIGURATION, val);
 1.1  jmcneill
 1.1  jmcneill 	/* Disable interrupts */
 1.1  jmcneill 	eqos_disable_intr(sc);
 1.1  jmcneill
 1.1  jmcneill 	ifp->if_flags &= ~(IFF_RUNNING | IFF_OACTIVE);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_stop(struct ifnet *ifp, int disable)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc * const sc = ifp->if_softc;
 1.1  jmcneill
 1.1  jmcneill 	EQOS_LOCK(sc);
 1.1  jmcneill 	eqos_stop_locked(sc, disable);
 1.1  jmcneill 	EQOS_UNLOCK(sc);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_rxintr(struct eqos_softc *sc, int qid)
 1.1  jmcneill {
 1.1  jmcneill 	struct ifnet *ifp = &sc->sc_ec.ec_if;
1.13       ryo 	int error, index, pkts = 0;
1.13       ryo 	struct mbuf *m, *m0, *new_m, *mprev;
 1.1  jmcneill 	uint32_t tdes3;
1.13       ryo 	bool discarding;
1.13       ryo
1.13       ryo 	/* restore jumboframe context */
1.13       ryo 	discarding = sc->sc_rx_discarding;
1.13       ryo 	m0 = sc->sc_rx_receiving_m;
1.13       ryo 	mprev = sc->sc_rx_receiving_m_last;
 1.1  jmcneill
 1.1  jmcneill 	for (index = sc->sc_rx.cur; ; index = RX_NEXT(index)) {
 1.1  jmcneill 		eqos_dma_sync(sc, sc->sc_rx.desc_map,
 1.1  jmcneill 		    index, index + 1, RX_DESC_COUNT,
 1.1  jmcneill 		    BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
 1.1  jmcneill
 1.1  jmcneill 		tdes3 = le32toh(sc->sc_rx.desc_ring[index].tdes3);
1.12       ryo 		if ((tdes3 & EQOS_TDES3_RX_OWN) != 0) {
 1.1  jmcneill 			break;
 1.1  jmcneill 		}
 1.1  jmcneill
1.13       ryo 		/* now discarding untill the last packet */
1.13       ryo 		if (discarding)
1.13       ryo 			goto rx_next;
1.13       ryo
1.13       ryo 		if ((tdes3 & EQOS_TDES3_RX_CTXT) != 0)
1.13       ryo 			goto rx_next;	/* ignore receive context descriptor */
1.13       ryo
1.13       ryo 		/* error packet? */
1.13       ryo 		if ((tdes3 & (EQOS_TDES3_RX_CE | EQOS_TDES3_RX_RWT |
1.13       ryo 		    EQOS_TDES3_RX_OE | EQOS_TDES3_RX_RE |
1.13       ryo 		    EQOS_TDES3_RX_DE)) != 0) {
1.13       ryo #ifdef EQOS_DEBUG
1.13       ryo 			char buf[128];
1.13       ryo 			snprintb(buf, sizeof(buf),
1.13       ryo 			    "\177\020"
1.13       ryo 			    "b\x1e" "CTXT\0"	/* 30 */
1.13       ryo 			    "b\x18" "CE\0"	/* 24 */
1.13       ryo 			    "b\x17" "GP\0"	/* 23 */
1.13       ryo 			    "b\x16" "WDT\0"	/* 22 */
1.13       ryo 			    "b\x15" "OE\0"	/* 21 */
1.13       ryo 			    "b\x14" "RE\0"	/* 20 */
1.13       ryo 			    "b\x13" "DE\0"	/* 19 */
1.13       ryo 			    "b\x0f" "ES\0"	/* 15 */
1.13       ryo 			    "\0", tdes3);
1.13       ryo 			DPRINTF(EDEB_NOTE, "rxdesc[%d].tdes3=%s\n", index, buf);
1.13       ryo #endif
1.13       ryo 			if_statinc(ifp, if_ierrors);
1.13       ryo 			if (m0 != NULL) {
1.13       ryo 				m_freem(m0);
1.13       ryo 				m0 = mprev = NULL;
1.13       ryo 			}
1.13       ryo 			discarding = true;
1.13       ryo 			goto rx_next;
1.13       ryo 		}
1.13       ryo
 1.1  jmcneill 		bus_dmamap_sync(sc->sc_dmat, sc->sc_rx.buf_map[index].map,
 1.1  jmcneill 		    0, sc->sc_rx.buf_map[index].map->dm_mapsize,
 1.1  jmcneill 		    BUS_DMASYNC_POSTREAD);
1.13       ryo 		m = sc->sc_rx.buf_map[index].mbuf;
1.13       ryo 		new_m = eqos_alloc_mbufcl(sc);
1.13       ryo 		if (new_m == NULL) {
1.13       ryo 			/*
1.13       ryo 			 * cannot allocate new mbuf. discard this received
1.13       ryo 			 * packet, and reuse the mbuf for next.
1.13       ryo 			 */
1.13       ryo 			if_statinc(ifp, if_ierrors);
1.13       ryo 			if (m0 != NULL) {
1.13       ryo 				/* also discard the halfway jumbo packet */
1.13       ryo 				m_freem(m0);
1.13       ryo 				m0 = mprev = NULL;
1.13       ryo 			}
1.13       ryo 			discarding = true;
1.13       ryo 			goto rx_next;
1.13       ryo 		}
1.13       ryo 		error = eqos_setup_rxbuf(sc, index, new_m);
1.13       ryo 		if (error)
1.13       ryo 			panic("%s: %s: unable to load RX mbuf. error=%d",
1.13       ryo 			    device_xname(sc->sc_dev), __func__, error);
 1.1  jmcneill
1.13       ryo 		if (m0 == NULL) {
1.13       ryo 			m0 = m;
1.13       ryo 		} else {
1.13       ryo 			if (m->m_flags & M_PKTHDR)
1.13       ryo 				m_remove_pkthdr(m);
1.13       ryo 			mprev->m_next = m;
1.13       ryo 		}
1.13       ryo 		mprev = m;
1.13       ryo
1.13       ryo 		if ((tdes3 & EQOS_TDES3_RX_LD) == 0) {
1.13       ryo 			/* to be continued in the next segment */
1.13       ryo 			m->m_len = EQOS_RXDMA_SIZE;
1.13       ryo 		} else {
1.13       ryo 			/* last segment */
1.13       ryo 			uint32_t totallen = tdes3 & EQOS_TDES3_RX_LENGTH_MASK;
1.13       ryo 			uint32_t mlen = totallen % EQOS_RXDMA_SIZE;
1.13       ryo 			if (mlen == 0)
1.13       ryo 				mlen = EQOS_RXDMA_SIZE;
1.13       ryo 			m->m_len = mlen;
1.13       ryo 			m0->m_pkthdr.len = totallen;
1.13       ryo 			m_set_rcvif(m0, ifp);
1.13       ryo 			m0->m_flags |= M_HASFCS;
1.13       ryo 			m0->m_nextpkt = NULL;
1.13       ryo 			if_percpuq_enqueue(ifp->if_percpuq, m0);
1.13       ryo 			m0 = mprev = NULL;
 1.1  jmcneill
 1.1  jmcneill 			++pkts;
 1.1  jmcneill 		}
 1.1  jmcneill
1.13       ryo  rx_next:
1.13       ryo 		if (discarding && (tdes3 & EQOS_TDES3_RX_LD) != 0)
1.13       ryo 			discarding = false;
1.13       ryo
1.13       ryo 		eqos_setup_rxdesc(sc, index,
1.13       ryo 		    sc->sc_rx.buf_map[index].map->dm_segs[0].ds_addr);
 1.1  jmcneill 		eqos_dma_sync(sc, sc->sc_rx.desc_map,
 1.1  jmcneill 		    index, index + 1, RX_DESC_COUNT,
 1.1  jmcneill 		    BUS_DMASYNC_PREWRITE | BUS_DMASYNC_PREREAD);
 1.1  jmcneill
 1.1  jmcneill 		WR4(sc, GMAC_DMA_CHAN0_RX_END_ADDR,
 1.1  jmcneill 		    (uint32_t)sc->sc_rx.desc_ring_paddr +
 1.1  jmcneill 		    DESC_OFF(sc->sc_rx.cur));
 1.1  jmcneill 	}
1.13       ryo 	/* save jumboframe context */
1.13       ryo 	sc->sc_rx_discarding = discarding;
1.13       ryo 	sc->sc_rx_receiving_m = m0;
1.13       ryo 	sc->sc_rx_receiving_m_last = mprev;
 1.1  jmcneill
 1.1  jmcneill 	sc->sc_rx.cur = index;
 1.1  jmcneill
 1.1  jmcneill 	if (pkts != 0) {
 1.1  jmcneill 		rnd_add_uint32(&sc->sc_rndsource, pkts);
 1.1  jmcneill 	}
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_txintr(struct eqos_softc *sc, int qid)
 1.1  jmcneill {
 1.1  jmcneill 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1  jmcneill 	struct eqos_bufmap *bmap;
 1.1  jmcneill 	struct eqos_dma_desc *desc;
 1.1  jmcneill 	uint32_t tdes3;
 1.1  jmcneill 	int i, pkts = 0;
 1.1  jmcneill
 1.8    martin 	DPRINTF(EDEB_INTR, "qid: %u\n", qid);
 1.8    martin
 1.1  jmcneill 	EQOS_ASSERT_LOCKED(sc);
 1.1  jmcneill
 1.1  jmcneill 	for (i = sc->sc_tx.next; sc->sc_tx.queued > 0; i = TX_NEXT(i)) {
 1.1  jmcneill 		KASSERT(sc->sc_tx.queued > 0);
 1.1  jmcneill 		KASSERT(sc->sc_tx.queued <= TX_DESC_COUNT);
 1.1  jmcneill 		eqos_dma_sync(sc, sc->sc_tx.desc_map,
 1.1  jmcneill 		    i, i + 1, TX_DESC_COUNT,
 1.1  jmcneill 		    BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
 1.1  jmcneill 		desc = &sc->sc_tx.desc_ring[i];
 1.1  jmcneill 		tdes3 = le32toh(desc->tdes3);
1.12       ryo 		if ((tdes3 & EQOS_TDES3_TX_OWN) != 0) {
 1.1  jmcneill 			break;
 1.1  jmcneill 		}
 1.1  jmcneill 		bmap = &sc->sc_tx.buf_map[i];
 1.1  jmcneill 		if (bmap->mbuf != NULL) {
 1.1  jmcneill 			bus_dmamap_sync(sc->sc_dmat, bmap->map,
 1.1  jmcneill 			    0, bmap->map->dm_mapsize,
 1.1  jmcneill 			    BUS_DMASYNC_POSTWRITE);
 1.1  jmcneill 			bus_dmamap_unload(sc->sc_dmat, bmap->map);
 1.1  jmcneill 			m_freem(bmap->mbuf);
 1.1  jmcneill 			bmap->mbuf = NULL;
 1.1  jmcneill 			++pkts;
 1.1  jmcneill 		}
 1.1  jmcneill
 1.1  jmcneill 		eqos_setup_txdesc(sc, i, 0, 0, 0, 0);
 1.1  jmcneill 		eqos_dma_sync(sc, sc->sc_tx.desc_map,
 1.1  jmcneill 		    i, i + 1, TX_DESC_COUNT,
 1.1  jmcneill 		    BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
 1.1  jmcneill
 1.1  jmcneill 		ifp->if_flags &= ~IFF_OACTIVE;
 1.1  jmcneill
 1.1  jmcneill 		/* Last descriptor in a packet contains DMA status */
1.12       ryo 		if ((tdes3 & EQOS_TDES3_TX_LD) != 0) {
1.12       ryo 			if ((tdes3 & EQOS_TDES3_TX_DE) != 0) {
 1.1  jmcneill 				device_printf(sc->sc_dev,
 1.1  jmcneill 				    "TX [%u] desc error: 0x%08x\n",
 1.1  jmcneill 				    i, tdes3);
 1.1  jmcneill 				if_statinc(ifp, if_oerrors);
1.12       ryo 			} else if ((tdes3 & EQOS_TDES3_TX_ES) != 0) {
 1.1  jmcneill 				device_printf(sc->sc_dev,
 1.1  jmcneill 				    "TX [%u] tx error: 0x%08x\n",
 1.1  jmcneill 				    i, tdes3);
 1.1  jmcneill 				if_statinc(ifp, if_oerrors);
 1.1  jmcneill 			} else {
 1.1  jmcneill 				if_statinc(ifp, if_opackets);
 1.1  jmcneill 			}
 1.1  jmcneill 		}
 1.1  jmcneill
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	sc->sc_tx.next = i;
 1.1  jmcneill
 1.1  jmcneill 	if (pkts != 0) {
 1.1  jmcneill 		rnd_add_uint32(&sc->sc_rndsource, pkts);
 1.1  jmcneill 	}
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_start_locked(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1  jmcneill 	struct mbuf *m;
 1.1  jmcneill 	int cnt, nsegs, start;
 1.1  jmcneill
 1.1  jmcneill 	EQOS_ASSERT_TXLOCKED(sc);
 1.1  jmcneill
 1.1  jmcneill 	if ((ifp->if_flags & (IFF_RUNNING | IFF_OACTIVE)) != IFF_RUNNING)
 1.1  jmcneill 		return;
 1.1  jmcneill
 1.1  jmcneill 	for (cnt = 0, start = sc->sc_tx.cur; ; cnt++) {
 1.1  jmcneill 		if (sc->sc_tx.queued >= TX_DESC_COUNT - TX_MAX_SEGS) {
 1.1  jmcneill 			ifp->if_flags |= IFF_OACTIVE;
 1.8    martin 			DPRINTF(EDEB_TXRING, "%u sc_tx.queued, ring full\n",
 1.8    martin 			    sc->sc_tx.queued);
 1.1  jmcneill 			break;
 1.1  jmcneill 		}
 1.1  jmcneill
 1.1  jmcneill 		IFQ_POLL(&ifp->if_snd, m);
 1.8    martin 		if (m == NULL)
 1.1  jmcneill 			break;
 1.1  jmcneill
 1.1  jmcneill 		nsegs = eqos_setup_txbuf(sc, sc->sc_tx.cur, m);
 1.1  jmcneill 		if (nsegs <= 0) {
 1.8    martin 			DPRINTF(EDEB_TXRING, "eqos_setup_txbuf failed "
 1.8    martin 			    "with %d\n", nsegs);
 1.1  jmcneill 			if (nsegs == -1) {
 1.1  jmcneill 				ifp->if_flags |= IFF_OACTIVE;
 1.1  jmcneill 			} else if (nsegs == -2) {
 1.1  jmcneill 				IFQ_DEQUEUE(&ifp->if_snd, m);
 1.1  jmcneill 				m_freem(m);
 1.1  jmcneill 			}
 1.1  jmcneill 			break;
 1.1  jmcneill 		}
 1.1  jmcneill
 1.1  jmcneill 		IFQ_DEQUEUE(&ifp->if_snd, m);
 1.1  jmcneill 		bpf_mtap(ifp, m, BPF_D_OUT);
 1.1  jmcneill
 1.1  jmcneill 		sc->sc_tx.cur = TX_SKIP(sc->sc_tx.cur, nsegs);
 1.1  jmcneill 	}
 1.1  jmcneill
 1.8    martin 	DPRINTF(EDEB_TXRING, "tx loop -> cnt = %u, cur: %u, next: %u, "
 1.8    martin 	    "queued: %u\n", cnt, sc->sc_tx.cur, sc->sc_tx.next,
 1.8    martin 	    sc->sc_tx.queued);
 1.8    martin
 1.1  jmcneill 	if (cnt != 0) {
 1.1  jmcneill 		eqos_dma_sync(sc, sc->sc_tx.desc_map,
 1.1  jmcneill 		    start, sc->sc_tx.cur, TX_DESC_COUNT,
 1.1  jmcneill 		    BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
 1.1  jmcneill
 1.1  jmcneill 		/* Start and run TX DMA */
 1.8    martin 		DPRINTF(EDEB_TXRING, "sending desc %u at %lx upto "
 1.8    martin 		    "%u-1 at %lx cur tx desc: %x cur tx buf: %x\n", start,
 1.8    martin 		    (uint32_t)sc->sc_tx.desc_ring_paddr + DESC_OFF(start),
 1.8    martin 		    sc->sc_tx.cur,
 1.8    martin 		    (uint32_t)sc->sc_tx.desc_ring_paddr +
 1.8    martin 		    DESC_OFF(sc->sc_tx.cur),
 1.8    martin 		    RD4(sc, GMAC_DMA_CHAN0_CUR_TX_DESC),
 1.8    martin 		    RD4(sc, GMAC_DMA_CHAN0_CUR_TX_BUF_ADDR));
 1.1  jmcneill 		WR4(sc, GMAC_DMA_CHAN0_TX_END_ADDR,
 1.1  jmcneill 		    (uint32_t)sc->sc_tx.desc_ring_paddr +
 1.1  jmcneill 		    DESC_OFF(sc->sc_tx.cur));
 1.1  jmcneill 	}
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_start(struct ifnet *ifp)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc *sc = ifp->if_softc;
 1.1  jmcneill
 1.1  jmcneill 	EQOS_TXLOCK(sc);
 1.1  jmcneill 	eqos_start_locked(sc);
 1.1  jmcneill 	EQOS_TXUNLOCK(sc);
 1.1  jmcneill }
 1.1  jmcneill
 1.3       mrg static void
 1.3       mrg eqos_intr_mtl(struct eqos_softc *sc, uint32_t mtl_status)
 1.3       mrg {
 1.3       mrg 	uint32_t debug_data __unused = 0, ictrl = 0;
 1.3       mrg
 1.3       mrg 	if (mtl_status == 0)
 1.3       mrg 		return;
 1.3       mrg
 1.3       mrg 	/* Drain the errors reported by MTL_INTERRUPT_STATUS */
 1.3       mrg 	sc->sc_ev_mtl.ev_count++;
 1.3       mrg
 1.3       mrg 	if ((mtl_status & GMAC_MTL_INTERRUPT_STATUS_DBGIS) != 0) {
 1.3       mrg 		debug_data = RD4(sc, GMAC_MTL_FIFO_DEBUG_DATA);
 1.3       mrg 		sc->sc_ev_mtl_debugdata.ev_count++;
 1.3       mrg 	}
 1.3       mrg 	if ((mtl_status & GMAC_MTL_INTERRUPT_STATUS_Q0IS) != 0) {
 1.3       mrg 		uint32_t new_status = 0;
 1.3       mrg
 1.3       mrg 		ictrl = RD4(sc, GMAC_MTL_Q0_INTERRUPT_CTRL_STATUS);
 1.3       mrg 		if ((ictrl & GMAC_MTL_Q0_INTERRUPT_CTRL_STATUS_RXOVFIS) != 0) {
 1.3       mrg 			new_status |= GMAC_MTL_Q0_INTERRUPT_CTRL_STATUS_RXOVFIS;
 1.3       mrg 			sc->sc_ev_mtl_rxovfis.ev_count++;
 1.3       mrg 		}
 1.3       mrg 		if ((ictrl & GMAC_MTL_Q0_INTERRUPT_CTRL_STATUS_TXUNFIS) != 0) {
 1.3       mrg 			new_status |= GMAC_MTL_Q0_INTERRUPT_CTRL_STATUS_TXUNFIS;
 1.3       mrg 			sc->sc_ev_mtl_txovfis.ev_count++;
 1.3       mrg 		}
 1.3       mrg 		if (new_status) {
 1.3       mrg 			new_status |= (ictrl &
 1.3       mrg 			    (GMAC_MTL_Q0_INTERRUPT_CTRL_STATUS_RXOIE|
 1.3       mrg 			     GMAC_MTL_Q0_INTERRUPT_CTRL_STATUS_TXUIE));
 1.3       mrg 			WR4(sc, GMAC_MTL_Q0_INTERRUPT_CTRL_STATUS, new_status);
 1.3       mrg 		}
 1.3       mrg 	}
 1.8    martin 	DPRINTF(EDEB_INTR,
 1.3       mrg 	    "GMAC_MTL_INTERRUPT_STATUS = 0x%08X, "
 1.3       mrg 	    "GMAC_MTL_FIFO_DEBUG_DATA = 0x%08X, "
 1.3       mrg 	    "GMAC_MTL_INTERRUPT_STATUS_Q0IS = 0x%08X\n",
 1.3       mrg 	    mtl_status, debug_data, ictrl);
 1.3       mrg }
 1.3       mrg
 1.1  jmcneill int
 1.1  jmcneill eqos_intr(void *arg)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc *sc = arg;
 1.1  jmcneill 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1  jmcneill 	uint32_t mac_status, mtl_status, dma_status, rx_tx_status;
 1.1  jmcneill
 1.2       mrg 	sc->sc_ev_intr.ev_count++;
 1.2       mrg
 1.1  jmcneill 	mac_status = RD4(sc, GMAC_MAC_INTERRUPT_STATUS);
 1.1  jmcneill 	mac_status &= RD4(sc, GMAC_MAC_INTERRUPT_ENABLE);
 1.1  jmcneill
 1.1  jmcneill 	if (mac_status) {
 1.2       mrg 		sc->sc_ev_mac.ev_count++;
 1.8    martin 		DPRINTF(EDEB_INTR,
 1.1  jmcneill 		    "GMAC_MAC_INTERRUPT_STATUS = 0x%08X\n", mac_status);
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	mtl_status = RD4(sc, GMAC_MTL_INTERRUPT_STATUS);
 1.3       mrg 	eqos_intr_mtl(sc, mtl_status);
 1.1  jmcneill
 1.1  jmcneill 	dma_status = RD4(sc, GMAC_DMA_CHAN0_STATUS);
 1.1  jmcneill 	dma_status &= RD4(sc, GMAC_DMA_CHAN0_INTR_ENABLE);
 1.1  jmcneill 	if (dma_status) {
 1.1  jmcneill 		WR4(sc, GMAC_DMA_CHAN0_STATUS, dma_status);
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	EQOS_LOCK(sc);
 1.1  jmcneill 	if ((dma_status & GMAC_DMA_CHAN0_STATUS_RI) != 0) {
 1.1  jmcneill 		eqos_rxintr(sc, 0);
 1.2       mrg 		sc->sc_ev_rxintr.ev_count++;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	if ((dma_status & GMAC_DMA_CHAN0_STATUS_TI) != 0) {
 1.1  jmcneill 		eqos_txintr(sc, 0);
 1.1  jmcneill 		if_schedule_deferred_start(ifp);
 1.2       mrg 		sc->sc_ev_txintr.ev_count++;
 1.1  jmcneill 	}
 1.1  jmcneill 	EQOS_UNLOCK(sc);
 1.1  jmcneill
 1.1  jmcneill 	if ((mac_status | mtl_status | dma_status) == 0) {
 1.8    martin 		DPRINTF(EDEB_NOTE, "spurious interrupt?!\n");
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	rx_tx_status = RD4(sc, GMAC_MAC_RX_TX_STATUS);
 1.1  jmcneill 	if (rx_tx_status) {
 1.2       mrg 		sc->sc_ev_status.ev_count++;
 1.2       mrg 		if ((rx_tx_status & GMAC_MAC_RX_TX_STATUS_RWT) != 0)
 1.2       mrg 			sc->sc_ev_rwt.ev_count++;
 1.2       mrg 		if ((rx_tx_status & GMAC_MAC_RX_TX_STATUS_EXCOL) != 0)
 1.2       mrg 			sc->sc_ev_excol.ev_count++;
 1.2       mrg 		if ((rx_tx_status & GMAC_MAC_RX_TX_STATUS_LCOL) != 0)
 1.2       mrg 			sc->sc_ev_lcol.ev_count++;
 1.2       mrg 		if ((rx_tx_status & GMAC_MAC_RX_TX_STATUS_EXDEF) != 0)
 1.2       mrg 			sc->sc_ev_exdef.ev_count++;
 1.2       mrg 		if ((rx_tx_status & GMAC_MAC_RX_TX_STATUS_LCARR) != 0)
 1.2       mrg 			sc->sc_ev_lcarr.ev_count++;
 1.2       mrg 		if ((rx_tx_status & GMAC_MAC_RX_TX_STATUS_NCARR) != 0)
 1.2       mrg 			sc->sc_ev_ncarr.ev_count++;
 1.2       mrg 		if ((rx_tx_status & GMAC_MAC_RX_TX_STATUS_TJT) != 0)
 1.2       mrg 			sc->sc_ev_tjt.ev_count++;
 1.8    martin
 1.8    martin 		DPRINTF(EDEB_INTR, "GMAC_MAC_RX_TX_STATUS = 0x%08x\n",
 1.1  jmcneill 		    rx_tx_status);
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	return 1;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_ioctl(struct ifnet *ifp, u_long cmd, void *data)
 1.1  jmcneill {
 1.1  jmcneill 	struct eqos_softc *sc = ifp->if_softc;
1.13       ryo 	struct ifreq *ifr = (struct ifreq *)data;
 1.1  jmcneill 	int error, s;
 1.1  jmcneill
 1.1  jmcneill #ifndef EQOS_MPSAFE
 1.1  jmcneill 	s = splnet();
 1.1  jmcneill #endif
 1.1  jmcneill
 1.1  jmcneill 	switch (cmd) {
1.13       ryo 	case SIOCSIFMTU:
1.13       ryo 		if (ifr->ifr_mtu < ETHERMIN || ifr->ifr_mtu > EQOS_MAX_MTU) {
1.13       ryo 			error = EINVAL;
1.13       ryo 		} else {
1.13       ryo 			ifp->if_mtu = ifr->ifr_mtu;
1.13       ryo 			error = 0;	/* no need ENETRESET */
1.13       ryo 		}
1.13       ryo 		break;
 1.1  jmcneill 	default:
 1.1  jmcneill #ifdef EQOS_MPSAFE
 1.1  jmcneill 		s = splnet();
 1.1  jmcneill #endif
 1.1  jmcneill 		error = ether_ioctl(ifp, cmd, data);
 1.1  jmcneill #ifdef EQOS_MPSAFE
 1.1  jmcneill 		splx(s);
 1.1  jmcneill #endif
 1.1  jmcneill 		if (error != ENETRESET)
 1.1  jmcneill 			break;
 1.1  jmcneill
 1.1  jmcneill 		error = 0;
 1.1  jmcneill
 1.1  jmcneill 		if (cmd == SIOCSIFCAP)
 1.1  jmcneill 			error = (*ifp->if_init)(ifp);
 1.1  jmcneill 		else if (cmd != SIOCADDMULTI && cmd != SIOCDELMULTI)
 1.1  jmcneill 			;
 1.1  jmcneill 		else if ((ifp->if_flags & IFF_RUNNING) != 0) {
 1.1  jmcneill 			EQOS_LOCK(sc);
 1.1  jmcneill 			eqos_setup_rxfilter(sc);
 1.1  jmcneill 			EQOS_UNLOCK(sc);
 1.1  jmcneill 		}
 1.1  jmcneill 		break;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill #ifndef EQOS_MPSAFE
 1.1  jmcneill 	splx(s);
 1.1  jmcneill #endif
 1.1  jmcneill
 1.1  jmcneill 	return error;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_get_eaddr(struct eqos_softc *sc, uint8_t *eaddr)
 1.1  jmcneill {
 1.1  jmcneill 	prop_dictionary_t prop = device_properties(sc->sc_dev);
 1.1  jmcneill 	uint32_t maclo, machi;
 1.1  jmcneill 	prop_data_t eaprop;
 1.1  jmcneill
 1.1  jmcneill 	eaprop = prop_dictionary_get(prop, "mac-address");
 1.1  jmcneill 	if (eaprop != NULL) {
 1.1  jmcneill 		KASSERT(prop_object_type(eaprop) == PROP_TYPE_DATA);
 1.1  jmcneill 		KASSERT(prop_data_size(eaprop) == ETHER_ADDR_LEN);
 1.1  jmcneill 		memcpy(eaddr, prop_data_value(eaprop),
 1.1  jmcneill 		    ETHER_ADDR_LEN);
 1.1  jmcneill 		return;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	maclo = htobe32(RD4(sc, GMAC_MAC_ADDRESS0_LOW));
 1.1  jmcneill 	machi = htobe16(RD4(sc, GMAC_MAC_ADDRESS0_HIGH) & 0xFFFF);
 1.1  jmcneill
 1.1  jmcneill 	if (maclo == 0xFFFFFFFF && machi == 0xFFFF) {
 1.1  jmcneill 		/* Create one */
 1.1  jmcneill 		maclo = 0x00f2 | (cprng_strong32() & 0xffff0000);
 1.1  jmcneill 		machi = cprng_strong32() & 0xffff;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	eaddr[0] = maclo & 0xff;
 1.1  jmcneill 	eaddr[1] = (maclo >> 8) & 0xff;
 1.1  jmcneill 	eaddr[2] = (maclo >> 16) & 0xff;
 1.1  jmcneill 	eaddr[3] = (maclo >> 24) & 0xff;
 1.1  jmcneill 	eaddr[4] = machi & 0xff;
 1.1  jmcneill 	eaddr[5] = (machi >> 8) & 0xff;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static void
 1.1  jmcneill eqos_axi_configure(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	prop_dictionary_t prop = device_properties(sc->sc_dev);
 1.1  jmcneill 	uint32_t val;
 1.1  jmcneill 	u_int uival;
 1.1  jmcneill 	bool bval;
 1.1  jmcneill
 1.1  jmcneill 	val = RD4(sc, GMAC_DMA_SYSBUS_MODE);
 1.1  jmcneill 	if (prop_dictionary_get_bool(prop, "snps,mixed-burst", &bval) && bval) {
 1.1  jmcneill 		val |= GMAC_DMA_SYSBUS_MODE_MB;
 1.1  jmcneill 	}
 1.1  jmcneill 	if (prop_dictionary_get_bool(prop, "snps,fixed-burst", &bval) && bval) {
 1.1  jmcneill 		val |= GMAC_DMA_SYSBUS_MODE_FB;
 1.1  jmcneill 	}
 1.1  jmcneill 	if (prop_dictionary_get_uint(prop, "snps,wr_osr_lmt", &uival)) {
 1.1  jmcneill 		val &= ~GMAC_DMA_SYSBUS_MODE_WR_OSR_LMT_MASK;
 1.1  jmcneill 		val |= uival << GMAC_DMA_SYSBUS_MODE_WR_OSR_LMT_SHIFT;
 1.1  jmcneill 	}
 1.1  jmcneill 	if (prop_dictionary_get_uint(prop, "snps,rd_osr_lmt", &uival)) {
 1.1  jmcneill 		val &= ~GMAC_DMA_SYSBUS_MODE_RD_OSR_LMT_MASK;
 1.1  jmcneill 		val |= uival << GMAC_DMA_SYSBUS_MODE_RD_OSR_LMT_SHIFT;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	if (!EQOS_HW_FEATURE_ADDR64_32BIT(sc)) {
 1.1  jmcneill 		val |= GMAC_DMA_SYSBUS_MODE_EAME;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	/* XXX */
 1.1  jmcneill 	val |= GMAC_DMA_SYSBUS_MODE_BLEN16;
 1.1  jmcneill 	val |= GMAC_DMA_SYSBUS_MODE_BLEN8;
 1.1  jmcneill 	val |= GMAC_DMA_SYSBUS_MODE_BLEN4;
 1.1  jmcneill
 1.1  jmcneill 	WR4(sc, GMAC_DMA_SYSBUS_MODE, val);
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill eqos_setup_dma(struct eqos_softc *sc, int qid)
 1.1  jmcneill {
 1.1  jmcneill 	struct mbuf *m;
 1.1  jmcneill 	int error, nsegs, i;
 1.1  jmcneill
 1.1  jmcneill 	/* Setup TX ring */
 1.1  jmcneill 	error = bus_dmamap_create(sc->sc_dmat, TX_DESC_SIZE, 1, TX_DESC_SIZE,
 1.1  jmcneill 	    DESC_BOUNDARY, BUS_DMA_WAITOK, &sc->sc_tx.desc_map);
 1.1  jmcneill 	if (error) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill 	error = bus_dmamem_alloc(sc->sc_dmat, TX_DESC_SIZE, DESC_ALIGN,
 1.1  jmcneill 	    DESC_BOUNDARY, &sc->sc_tx.desc_dmaseg, 1, &nsegs, BUS_DMA_WAITOK);
 1.1  jmcneill 	if (error) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill 	error = bus_dmamem_map(sc->sc_dmat, &sc->sc_tx.desc_dmaseg, nsegs,
 1.1  jmcneill 	    TX_DESC_SIZE, (void *)&sc->sc_tx.desc_ring, BUS_DMA_WAITOK);
 1.1  jmcneill 	if (error) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill 	error = bus_dmamap_load(sc->sc_dmat, sc->sc_tx.desc_map,
 1.1  jmcneill 	    sc->sc_tx.desc_ring, TX_DESC_SIZE, NULL, BUS_DMA_WAITOK);
 1.1  jmcneill 	if (error) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill 	sc->sc_tx.desc_ring_paddr = sc->sc_tx.desc_map->dm_segs[0].ds_addr;
 1.1  jmcneill
 1.1  jmcneill 	memset(sc->sc_tx.desc_ring, 0, TX_DESC_SIZE);
 1.1  jmcneill 	bus_dmamap_sync(sc->sc_dmat, sc->sc_tx.desc_map, 0, TX_DESC_SIZE,
 1.1  jmcneill 	    BUS_DMASYNC_PREWRITE);
 1.1  jmcneill
 1.1  jmcneill 	sc->sc_tx.queued = TX_DESC_COUNT;
 1.1  jmcneill 	for (i = 0; i < TX_DESC_COUNT; i++) {
1.13       ryo 		error = bus_dmamap_create(sc->sc_dmat, EQOS_TXDMA_SIZE,
 1.1  jmcneill 		    TX_MAX_SEGS, MCLBYTES, 0, BUS_DMA_WAITOK,
 1.1  jmcneill 		    &sc->sc_tx.buf_map[i].map);
 1.1  jmcneill 		if (error != 0) {
 1.1  jmcneill 			device_printf(sc->sc_dev,
 1.1  jmcneill 			    "cannot create TX buffer map\n");
 1.1  jmcneill 			return error;
 1.1  jmcneill 		}
 1.1  jmcneill 		eqos_setup_txdesc(sc, i, 0, 0, 0, 0);
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	/* Setup RX ring */
 1.1  jmcneill 	error = bus_dmamap_create(sc->sc_dmat, RX_DESC_SIZE, 1, RX_DESC_SIZE,
 1.1  jmcneill 	    DESC_BOUNDARY, BUS_DMA_WAITOK, &sc->sc_rx.desc_map);
 1.1  jmcneill 	if (error) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill 	error = bus_dmamem_alloc(sc->sc_dmat, RX_DESC_SIZE, DESC_ALIGN,
 1.1  jmcneill 	    DESC_BOUNDARY, &sc->sc_rx.desc_dmaseg, 1, &nsegs, BUS_DMA_WAITOK);
 1.1  jmcneill 	if (error) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill 	error = bus_dmamem_map(sc->sc_dmat, &sc->sc_rx.desc_dmaseg, nsegs,
 1.1  jmcneill 	    RX_DESC_SIZE, (void *)&sc->sc_rx.desc_ring, BUS_DMA_WAITOK);
 1.1  jmcneill 	if (error) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill 	error = bus_dmamap_load(sc->sc_dmat, sc->sc_rx.desc_map,
 1.1  jmcneill 	    sc->sc_rx.desc_ring, RX_DESC_SIZE, NULL, BUS_DMA_WAITOK);
 1.1  jmcneill 	if (error) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill 	sc->sc_rx.desc_ring_paddr = sc->sc_rx.desc_map->dm_segs[0].ds_addr;
 1.1  jmcneill
 1.1  jmcneill 	memset(sc->sc_rx.desc_ring, 0, RX_DESC_SIZE);
 1.1  jmcneill
 1.1  jmcneill 	for (i = 0; i < RX_DESC_COUNT; i++) {
 1.1  jmcneill 		error = bus_dmamap_create(sc->sc_dmat, MCLBYTES,
 1.1  jmcneill 		    RX_DESC_COUNT, MCLBYTES, 0, BUS_DMA_WAITOK,
 1.1  jmcneill 		    &sc->sc_rx.buf_map[i].map);
 1.1  jmcneill 		if (error != 0) {
 1.1  jmcneill 			device_printf(sc->sc_dev,
 1.1  jmcneill 			    "cannot create RX buffer map\n");
 1.1  jmcneill 			return error;
 1.1  jmcneill 		}
 1.1  jmcneill 		if ((m = eqos_alloc_mbufcl(sc)) == NULL) {
 1.1  jmcneill 			device_printf(sc->sc_dev, "cannot allocate RX mbuf\n");
 1.1  jmcneill 			return ENOMEM;
 1.1  jmcneill 		}
 1.1  jmcneill 		error = eqos_setup_rxbuf(sc, i, m);
 1.1  jmcneill 		if (error != 0) {
 1.1  jmcneill 			device_printf(sc->sc_dev, "cannot create RX buffer\n");
 1.1  jmcneill 			return error;
 1.1  jmcneill 		}
1.13       ryo 		eqos_setup_rxdesc(sc, i,
1.13       ryo 		    sc->sc_rx.buf_map[i].map->dm_segs[0].ds_addr);
 1.1  jmcneill 	}
 1.1  jmcneill 	bus_dmamap_sync(sc->sc_dmat, sc->sc_rx.desc_map,
 1.1  jmcneill 	    0, sc->sc_rx.desc_map->dm_mapsize,
 1.1  jmcneill 	    BUS_DMASYNC_PREWRITE);
 1.1  jmcneill
 1.1  jmcneill 	aprint_debug_dev(sc->sc_dev, "TX ring @ 0x%lX, RX ring @ 0x%lX\n",
 1.1  jmcneill 	    sc->sc_tx.desc_ring_paddr, sc->sc_rx.desc_ring_paddr);
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill int
 1.1  jmcneill eqos_attach(struct eqos_softc *sc)
 1.1  jmcneill {
 1.1  jmcneill 	struct mii_data *mii = &sc->sc_mii;
 1.1  jmcneill 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1  jmcneill 	uint8_t eaddr[ETHER_ADDR_LEN];
 1.1  jmcneill 	u_int userver, snpsver;
 1.1  jmcneill 	int mii_flags = 0;
 1.1  jmcneill 	int error;
 1.1  jmcneill 	int n;
 1.1  jmcneill
 1.1  jmcneill 	const uint32_t ver = RD4(sc, GMAC_MAC_VERSION);
 1.1  jmcneill 	userver = (ver & GMAC_MAC_VERSION_USERVER_MASK) >>
 1.1  jmcneill 	    GMAC_MAC_VERSION_USERVER_SHIFT;
 1.1  jmcneill 	snpsver = ver & GMAC_MAC_VERSION_SNPSVER_MASK;
 1.1  jmcneill
 1.1  jmcneill 	if (snpsver != 0x51) {
 1.1  jmcneill 		aprint_error(": EQOS version 0x%02xx not supported\n",
 1.1  jmcneill 		    snpsver);
 1.1  jmcneill 		return ENXIO;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	if (sc->sc_csr_clock < 20000000) {
 1.1  jmcneill 		aprint_error(": CSR clock too low\n");
 1.1  jmcneill 		return EINVAL;
 1.1  jmcneill 	} else if (sc->sc_csr_clock < 35000000) {
 1.1  jmcneill 		sc->sc_clock_range = GMAC_MAC_MDIO_ADDRESS_CR_20_35;
 1.1  jmcneill 	} else if (sc->sc_csr_clock < 60000000) {
 1.1  jmcneill 		sc->sc_clock_range = GMAC_MAC_MDIO_ADDRESS_CR_35_60;
 1.1  jmcneill 	} else if (sc->sc_csr_clock < 100000000) {
 1.1  jmcneill 		sc->sc_clock_range = GMAC_MAC_MDIO_ADDRESS_CR_60_100;
 1.1  jmcneill 	} else if (sc->sc_csr_clock < 150000000) {
 1.1  jmcneill 		sc->sc_clock_range = GMAC_MAC_MDIO_ADDRESS_CR_100_150;
 1.1  jmcneill 	} else if (sc->sc_csr_clock < 250000000) {
 1.1  jmcneill 		sc->sc_clock_range = GMAC_MAC_MDIO_ADDRESS_CR_150_250;
 1.1  jmcneill 	} else if (sc->sc_csr_clock < 300000000) {
 1.1  jmcneill 		sc->sc_clock_range = GMAC_MAC_MDIO_ADDRESS_CR_300_500;
 1.1  jmcneill 	} else if (sc->sc_csr_clock < 800000000) {
 1.1  jmcneill 		sc->sc_clock_range = GMAC_MAC_MDIO_ADDRESS_CR_500_800;
 1.1  jmcneill 	} else {
 1.1  jmcneill 		aprint_error(": CSR clock too high\n");
 1.1  jmcneill 		return EINVAL;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	for (n = 0; n < 4; n++) {
 1.1  jmcneill 		sc->sc_hw_feature[n] = RD4(sc, GMAC_MAC_HW_FEATURE(n));
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	aprint_naive("\n");
 1.1  jmcneill 	aprint_normal(": DesignWare EQOS ver 0x%02x (0x%02x)\n",
 1.1  jmcneill 	    snpsver, userver);
 1.1  jmcneill 	aprint_verbose_dev(sc->sc_dev, "hw features %08x %08x %08x %08x\n",
 1.1  jmcneill 	    sc->sc_hw_feature[0], sc->sc_hw_feature[1],
 1.1  jmcneill 	    sc->sc_hw_feature[2], sc->sc_hw_feature[3]);
 1.1  jmcneill
 1.1  jmcneill 	if (EQOS_HW_FEATURE_ADDR64_32BIT(sc)) {
 1.1  jmcneill 		bus_dma_tag_t ntag;
 1.1  jmcneill
 1.1  jmcneill 		error = bus_dmatag_subregion(sc->sc_dmat, 0, UINT32_MAX,
 1.1  jmcneill 		    &ntag, 0);
 1.1  jmcneill 		if (error) {
 1.1  jmcneill 			aprint_error_dev(sc->sc_dev,
 1.1  jmcneill 			    "failed to restrict DMA: %d\n", error);
 1.1  jmcneill 			return error;
 1.1  jmcneill 		}
 1.1  jmcneill 		aprint_verbose_dev(sc->sc_dev, "using 32-bit DMA\n");
 1.1  jmcneill 		sc->sc_dmat = ntag;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	mutex_init(&sc->sc_lock, MUTEX_DEFAULT, IPL_NET);
 1.1  jmcneill 	mutex_init(&sc->sc_txlock, MUTEX_DEFAULT, IPL_NET);
 1.1  jmcneill 	callout_init(&sc->sc_stat_ch, CALLOUT_FLAGS);
 1.1  jmcneill 	callout_setfunc(&sc->sc_stat_ch, eqos_tick, sc);
 1.1  jmcneill
 1.1  jmcneill 	eqos_get_eaddr(sc, eaddr);
 1.1  jmcneill 	aprint_normal_dev(sc->sc_dev, "Ethernet address %s\n", ether_sprintf(eaddr));
 1.1  jmcneill
 1.1  jmcneill 	/* Soft reset EMAC core */
 1.1  jmcneill 	error = eqos_reset(sc);
 1.1  jmcneill 	if (error != 0) {
 1.1  jmcneill 		return error;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	/* Configure AXI Bus mode parameters */
 1.1  jmcneill 	eqos_axi_configure(sc);
 1.1  jmcneill
 1.1  jmcneill 	/* Setup DMA descriptors */
 1.1  jmcneill 	if (eqos_setup_dma(sc, 0) != 0) {
 1.1  jmcneill 		aprint_error_dev(sc->sc_dev, "failed to setup DMA descriptors\n");
 1.1  jmcneill 		return EINVAL;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	/* Setup ethernet interface */
 1.1  jmcneill 	ifp->if_softc = sc;
 1.1  jmcneill 	snprintf(ifp->if_xname, IFNAMSIZ, "%s", device_xname(sc->sc_dev));
 1.1  jmcneill 	ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST;
 1.1  jmcneill #ifdef EQOS_MPSAFE
 1.1  jmcneill 	ifp->if_extflags = IFEF_MPSAFE;
 1.1  jmcneill #endif
 1.1  jmcneill 	ifp->if_start = eqos_start;
 1.1  jmcneill 	ifp->if_ioctl = eqos_ioctl;
 1.1  jmcneill 	ifp->if_init = eqos_init;
 1.1  jmcneill 	ifp->if_stop = eqos_stop;
 1.1  jmcneill 	ifp->if_capabilities = 0;
 1.1  jmcneill 	ifp->if_capenable = ifp->if_capabilities;
 1.1  jmcneill 	IFQ_SET_MAXLEN(&ifp->if_snd, IFQ_MAXLEN);
 1.1  jmcneill 	IFQ_SET_READY(&ifp->if_snd);
 1.1  jmcneill
1.13       ryo 	/* 802.1Q VLAN-sized frames, and jumbo frame are supported */
 1.1  jmcneill 	sc->sc_ec.ec_capabilities |= ETHERCAP_VLAN_MTU;
1.13       ryo 	sc->sc_ec.ec_capabilities |= ETHERCAP_JUMBO_MTU;
 1.1  jmcneill
 1.1  jmcneill 	/* Attach MII driver */
 1.1  jmcneill 	sc->sc_ec.ec_mii = mii;
 1.1  jmcneill 	ifmedia_init(&mii->mii_media, 0, ether_mediachange, ether_mediastatus);
 1.1  jmcneill 	mii->mii_ifp = ifp;
 1.1  jmcneill 	mii->mii_readreg = eqos_mii_readreg;
 1.1  jmcneill 	mii->mii_writereg = eqos_mii_writereg;
 1.1  jmcneill 	mii->mii_statchg = eqos_mii_statchg;
 1.1  jmcneill 	mii_attach(sc->sc_dev, mii, 0xffffffff, sc->sc_phy_id, MII_OFFSET_ANY,
 1.1  jmcneill 	    mii_flags);
 1.1  jmcneill
 1.1  jmcneill 	if (LIST_EMPTY(&mii->mii_phys)) {
 1.1  jmcneill 		aprint_error_dev(sc->sc_dev, "no PHY found!\n");
 1.1  jmcneill 		return ENOENT;
 1.1  jmcneill 	}
 1.1  jmcneill 	ifmedia_set(&mii->mii_media, IFM_ETHER | IFM_AUTO);
 1.1  jmcneill
 1.2       mrg 	/* Master interrupt evcnt */
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_intr, EVCNT_TYPE_INTR,
 1.2       mrg 	    NULL, device_xname(sc->sc_dev), "interrupts");
 1.2       mrg
 1.2       mrg 	/* Per-interrupt type, using main interrupt */
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_rxintr, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_intr, device_xname(sc->sc_dev), "rxintr");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_txintr, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_intr, device_xname(sc->sc_dev), "txintr");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_mac, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_intr, device_xname(sc->sc_dev), "macstatus");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_mtl, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_intr, device_xname(sc->sc_dev), "intrstatus");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_status, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_intr, device_xname(sc->sc_dev), "rxtxstatus");
 1.2       mrg
 1.3       mrg 	/* MAC Status specific type, using macstatus interrupt */
 1.3       mrg 	evcnt_attach_dynamic(&sc->sc_ev_mtl_debugdata, EVCNT_TYPE_INTR,
 1.3       mrg 	    &sc->sc_ev_mtl, device_xname(sc->sc_dev), "debugdata");
 1.3       mrg 	evcnt_attach_dynamic(&sc->sc_ev_mtl_rxovfis, EVCNT_TYPE_INTR,
 1.3       mrg 	    &sc->sc_ev_mtl, device_xname(sc->sc_dev), "rxovfis");
 1.3       mrg 	evcnt_attach_dynamic(&sc->sc_ev_mtl_txovfis, EVCNT_TYPE_INTR,
 1.3       mrg 	    &sc->sc_ev_mtl, device_xname(sc->sc_dev), "txovfis");
 1.3       mrg
 1.2       mrg 	/* RX/TX Status specific type, using rxtxstatus interrupt */
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_rwt, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_status, device_xname(sc->sc_dev), "rwt");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_excol, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_status, device_xname(sc->sc_dev), "excol");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_lcol, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_status, device_xname(sc->sc_dev), "lcol");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_exdef, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_status, device_xname(sc->sc_dev), "exdef");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_lcarr, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_status, device_xname(sc->sc_dev), "lcarr");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_ncarr, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_status, device_xname(sc->sc_dev), "ncarr");
 1.2       mrg 	evcnt_attach_dynamic(&sc->sc_ev_tjt, EVCNT_TYPE_INTR,
 1.2       mrg 	    &sc->sc_ev_status, device_xname(sc->sc_dev), "tjt");
 1.2       mrg
 1.1  jmcneill 	/* Attach interface */
 1.1  jmcneill 	if_attach(ifp);
 1.1  jmcneill 	if_deferred_start_init(ifp, NULL);
 1.1  jmcneill
 1.1  jmcneill 	/* Attach ethernet interface */
 1.1  jmcneill 	ether_ifattach(ifp, eaddr);
 1.1  jmcneill
 1.1  jmcneill 	rnd_attach_source(&sc->sc_rndsource, ifp->if_xname, RND_TYPE_NET,
 1.1  jmcneill 	    RND_FLAG_DEFAULT);
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }