sun3/dev/if_le.c

1.1  glass /*
1.1  glass  * Copyright (c) 1982, 1990 The Regents of the University of California.
1.1  glass  * All rights reserved.
1.1  glass  *
1.1  glass  * Redistribution and use in source and binary forms, with or without
1.1  glass  * modification, are permitted provided that the following conditions
1.1  glass  * are met:
1.1  glass  * 1. Redistributions of source code must retain the above copyright
1.1  glass  *    notice, this list of conditions and the following disclaimer.
1.1  glass  * 2. Redistributions in binary form must reproduce the above copyright
1.1  glass  *    notice, this list of conditions and the following disclaimer in the
1.1  glass  *    documentation and/or other materials provided with the distribution.
1.1  glass  * 3. All advertising materials mentioning features or use of this software
1.1  glass  *    must display the following acknowledgement:
1.1  glass  *	This product includes software developed by the University of
1.1  glass  *	California, Berkeley and its contributors.
1.1  glass  * 4. Neither the name of the University nor the names of its contributors
1.1  glass  *    may be used to endorse or promote products derived from this software
1.1  glass  *    without specific prior written permission.
1.1  glass  *
1.1  glass  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.1  glass  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1  glass  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1  glass  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.1  glass  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1  glass  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1  glass  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1  glass  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1  glass  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1  glass  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1  glass  * SUCH DAMAGE.
1.1  glass  *
1.1  glass  *	from: @(#)if_le.c	7.6 (Berkeley) 5/8/91
1.1  glass  *	if_le.c,v 1.2 1993/05/22 07:56:23 cgd Exp
1.1  glass  */
1.1  glass
1.1  glass #include "bpfilter.h"
1.1  glass
1.1  glass /*
1.1  glass  * AMD 7990 LANCE
1.1  glass  *
1.1  glass  * This driver will generate and accept tailer encapsulated packets even
1.1  glass  * though it buys us nothing.  The motivation was to avoid incompatibilities
1.1  glass  * with VAXen, SUNs, and others that handle and benefit from them.
1.1  glass  * This reasoning is dubious.
1.1  glass  */
1.8  glass #include <sys/param.h>
1.8  glass #include <sys/systm.h>
1.8  glass #include <sys/mbuf.h>
1.8  glass #include <sys/buf.h>
1.8  glass #include <sys/protosw.h>
1.8  glass #include <sys/socket.h>
1.8  glass #include <sys/syslog.h>
1.8  glass #include <sys/ioctl.h>
1.8  glass #include <sys/errno.h>
1.8  glass #include <sys/device.h>
1.8  glass
1.8  glass #include <net/if.h>
1.8  glass #include <net/netisr.h>
1.8  glass #include <net/route.h>
1.1  glass
1.1  glass #ifdef INET
1.8  glass #include <netinet/in.h>
1.8  glass #include <netinet/in_systm.h>
1.8  glass #include <netinet/in_var.h>
1.8  glass #include <netinet/ip.h>
1.8  glass #include <netinet/if_ether.h>
1.1  glass #endif
1.1  glass
1.1  glass #ifdef NS
1.8  glass #include <netns/ns.h>
1.8  glass #include <netns/ns_if.h>
1.1  glass #endif
1.1  glass
1.1  glass #ifdef RMP
1.8  glass #include <netrmp/rmp.h>
1.8  glass #include <netrmp/rmp_var.h>
1.1  glass #endif
1.1  glass
1.8  glass #include <machine/autoconf.h>
1.1  glass
1.1  glass #include "if_lereg.h"
1.1  glass
1.1  glass #if NBPFILTER > 0
1.8  glass #include <net/bpf.h>
1.8  glass #include <net/bpfdesc.h>
1.1  glass #endif
1.1  glass
1.1  glass #include "if_le.h"
1.1  glass #include "if_le_subr.h"
1.1  glass
1.7  glass int	ledebug = 0;		/* console error messages */
1.1  glass
1.8  glass int	leintr(), leioctl(), ether_output(), lestart();
1.8  glass void    leinit();
1.1  glass struct	mbuf *leget();
1.1  glass extern	struct ifnet loif;
1.1  glass
1.1  glass /* access LANCE registers */
1.1  glass
1.1  glass void leattach __P((struct device *, struct device *, void *));
1.1  glass int lematch __P((struct device *, struct cfdata *, void *args));
1.1  glass
1.1  glass struct cfdriver lecd =
1.1  glass { NULL, "le", lematch, leattach, DV_DULL, sizeof(struct le_softc), 0};
1.1  glass
1.3  glass #define ISQUADALIGN(a) ((a & 0x3) == 0)
1.3  glass
1.1  glass int lematch(parent, cf, args)
1.1  glass      struct device *parent;
1.1  glass      struct cfdata *cf;
1.1  glass      void *args;
1.1  glass {
1.1  glass     return le_machdep_match(parent, cf, args);
1.1  glass }
1.1  glass /*
1.1  glass  * Interface exists: make available by filling in network interface
1.1  glass  * record.  System will initialize the interface when it is ready
1.1  glass  * to accept packets.
1.1  glass  */
1.1  glass void leattach(parent, self, args)
1.1  glass      struct device *parent;
1.1  glass      struct device *self;
1.1  glass      void *args;
1.1  glass {
1.1  glass 	register struct lereg2 *ler2;
1.3  glass 	unsigned int a;
1.1  glass 	struct le_softc *le = (struct le_softc *) self;
1.1  glass 	struct ifnet *ifp = &le->sc_if;
1.1  glass 	char *cp;
1.1  glass 	int i, unit;
1.1  glass
1.1  glass 	unit = le->sc_dev.dv_unit;
1.1  glass 	if (le_machdep_attach(parent, self, args)) {
1.1  glass 	    printf(": bad attach??\n");
1.1  glass 	    return;
1.1  glass 	}
1.1  glass 	ler2 = le->sc_r2;
1.2  glass 	printf(": ether address %s\n", ether_sprintf(le->sc_addr));
1.1  glass
1.1  glass 	/*
1.1  glass 	 * Setup for transmit/receive
1.1  glass 	 */
1.1  glass 	ler2->ler2_mode = LE_MODE;
1.1  glass 	ler2->ler2_padr[0] = le->sc_addr[1];
1.1  glass 	ler2->ler2_padr[1] = le->sc_addr[0];
1.1  glass 	ler2->ler2_padr[2] = le->sc_addr[3];
1.1  glass 	ler2->ler2_padr[3] = le->sc_addr[2];
1.1  glass 	ler2->ler2_padr[4] = le->sc_addr[5];
1.1  glass 	ler2->ler2_padr[5] = le->sc_addr[4];
1.1  glass #ifdef RMP
1.1  glass 	/*
1.1  glass 	 * Set up logical addr filter to accept multicast 9:0:9:0:0:4
1.1  glass 	 * This should be an ioctl() to the driver.  (XXX)
1.1  glass 	 */
1.1  glass 	ler2->ler2_ladrf0 = 0x00100000;
1.1  glass 	ler2->ler2_ladrf1 = 0x0;
1.1  glass #else
1.1  glass 	ler2->ler2_ladrf0 = 0;
1.1  glass 	ler2->ler2_ladrf1 = 0;
1.1  glass #endif
1.3  glass 	a = LANCE_ADDR(ler2->ler2_rmd);
1.3  glass 	if (!ISQUADALIGN(a))
1.3  glass 	    panic("rdra not quad aligned");
1.3  glass 	ler2->ler2_rlen = LE_RLEN | (a >> 16);
1.3  glass 	ler2->ler2_rdra = a & LE_ADDR_LOW_MASK;
1.3  glass 	a = LANCE_ADDR(ler2->ler2_tmd);
1.3  glass 	if (!ISQUADALIGN(a))
1.3  glass 	    panic("tdra not quad aligned");
1.3  glass 	ler2->ler2_tlen = LE_TLEN | (a >> 16);
1.3  glass 	ler2->ler2_tdra = a & LE_ADDR_LOW_MASK;
1.1  glass
1.1  glass 	ifp->if_unit = unit;
1.1  glass 	ifp->if_name = "le";
1.1  glass 	ifp->if_ioctl = leioctl;
1.1  glass 	ifp->if_output = ether_output;
1.1  glass 	ifp->if_start = lestart;
1.1  glass 	ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX;
1.1  glass #if NBPFILTER > 0
1.1  glass 	bpfattach(&le->sc_bpf, ifp, DLT_EN10MB, sizeof(struct ether_header));
1.1  glass #endif
1.1  glass 	if_attach(ifp);
1.9    gwr 	ether_ifattach(ifp);
1.1  glass }
1.1  glass
1.1  glass ledrinit(ler2)
1.1  glass 	register struct lereg2 *ler2;
1.1  glass {
1.3  glass         unsigned int a;
1.1  glass 	register int i;
1.1  glass
1.1  glass 	for (i = 0; i < LERBUF; i++) {
1.3  glass 	        a = LANCE_ADDR(&ler2->ler2_rbuf[i][0]);
1.3  glass #if 0
1.3  glass 		if (!ISQUADALIGN(a))
1.3  glass 		    panic("rbuf not quad aligned");
1.3  glass #endif
1.3  glass 		ler2->ler2_rmd[i].rmd0 = a & LE_ADDR_LOW_MASK;
1.3  glass 		ler2->ler2_rmd[i].rmd1_bits = LE_OWN;
1.3  glass 		ler2->ler2_rmd[i].rmd1_hadr = a >> 16;
1.1  glass 		ler2->ler2_rmd[i].rmd2 = -LEMTU;
1.1  glass 		ler2->ler2_rmd[i].rmd3 = 0;
1.1  glass 	}
1.1  glass 	for (i = 0; i < LETBUF; i++) {
1.5  glass 	        a = LANCE_ADDR(&ler2->ler2_tbuf[i][0]);
1.3  glass #if 0
1.3  glass 		if (!ISQUADALIGN(a))
1.3  glass 		    panic("rbuf not quad aligned");
1.3  glass #endif
1.3  glass 		ler2->ler2_tmd[i].tmd0 = a & LE_ADDR_LOW_MASK;
1.3  glass 		ler2->ler2_tmd[i].tmd1_bits = 0;
1.3  glass 		ler2->ler2_tmd[i].tmd1_hadr = a >> 16;
1.1  glass 		ler2->ler2_tmd[i].tmd2 = 0;
1.1  glass 		ler2->ler2_tmd[i].tmd3 = 0;
1.1  glass 	}
1.1  glass }
1.1  glass
1.1  glass lereset(unit)
1.1  glass 	register int unit;
1.1  glass {
1.3  glass         register struct le_softc *le = (struct le_softc *) lecd.cd_devs[unit];
1.1  glass 	register struct lereg1 *ler1 = le->sc_r1;
1.3  glass 	register struct lereg2 *ler2 = le->sc_r2;
1.3  glass 	unsigned int a;
1.1  glass 	register int timo = 100000;
1.1  glass 	register int stat;
1.1  glass
1.1  glass #ifdef lint
1.1  glass 	stat = unit;
1.1  glass #endif
1.1  glass #if NBPFILTER > 0
1.1  glass 	if (le->sc_if.if_flags & IFF_PROMISC)
1.1  glass 		/* set the promiscuous bit */
1.1  glass 		le->sc_r2->ler2_mode = LE_MODE|0x8000;
1.1  glass 	else
1.1  glass 		le->sc_r2->ler2_mode = LE_MODE;
1.1  glass #endif
1.3  glass 	if (ledebug)
1.3  glass 	    printf("le: resetting unit %d, reg %x, ram %x\n",
1.3  glass 		   unit, le->sc_r1, le->sc_r2);
1.1  glass 	LERDWR(le, LE_CSR0, ler1->ler1_rap);
1.1  glass 	LERDWR(le, LE_STOP, ler1->ler1_rdp);
1.1  glass 	ledrinit(le->sc_r2);
1.1  glass 	le->sc_rmd = 0;
1.1  glass 	LERDWR(le, LE_CSR1, ler1->ler1_rap);
1.3  glass 	a = LANCE_ADDR(ler2);
1.3  glass 	LERDWR(le, a & LE_ADDR_LOW_MASK, ler1->ler1_rdp);
1.1  glass 	LERDWR(le, LE_CSR2, ler1->ler1_rap);
1.3  glass 	LERDWR(le, a >> 16, ler1->ler1_rdp);
1.1  glass 	LERDWR(le, LE_CSR0, ler1->ler1_rap);
1.1  glass 	LERDWR(le, LE_INIT, ler1->ler1_rdp);
1.1  glass 	do {
1.1  glass 		if (--timo == 0) {
1.1  glass 			printf("le%d: init timeout, stat = 0x%x\n",
1.1  glass 			       unit, stat);
1.1  glass 			break;
1.1  glass 		}
1.1  glass 		LERDWR(le, ler1->ler1_rdp, stat);
1.1  glass 	} while ((stat & LE_IDON) == 0);
1.1  glass 	LERDWR(le, LE_STOP, ler1->ler1_rdp);
1.1  glass 	LERDWR(le, LE_CSR3, ler1->ler1_rap);
1.1  glass 	LERDWR(le, LE_BSWP, ler1->ler1_rdp);
1.1  glass 	LERDWR(le, LE_CSR0, ler1->ler1_rap);
1.1  glass 	LERDWR(le, LE_STRT | LE_INEA, ler1->ler1_rdp);
1.1  glass 	le->sc_if.if_flags &= ~IFF_OACTIVE;
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Initialization of interface
1.1  glass  */
1.6  glass void leinit(unit)
1.1  glass 	int unit;
1.1  glass {
1.1  glass 	struct le_softc *le = lecd.cd_devs[unit];
1.1  glass 	register struct ifnet *ifp = &le->sc_if;
1.1  glass 	int s;
1.1  glass
1.1  glass 	/* not yet, if address still unknown */
1.1  glass 	if (ifp->if_addrlist == (struct ifaddr *)0)
1.1  glass 		return;
1.1  glass 	if ((ifp->if_flags & IFF_RUNNING) == 0) {
1.1  glass 		s = splimp();
1.3  glass 		if (ledebug)
1.3  glass 		    printf("le: initializing unit %d, reg %x, ram %x\n",
1.3  glass 			   unit, le->sc_r1, le->sc_r2);
1.1  glass 		ifp->if_flags |= IFF_RUNNING;
1.1  glass 		lereset(unit);
1.1  glass 	        (void) lestart(ifp);
1.1  glass 		splx(s);
1.1  glass 	}
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Start output on interface.  Get another datagram to send
1.1  glass  * off of the interface queue, and copy it to the interface
1.1  glass  * before starting the output.
1.1  glass  */
1.8  glass int lestart(ifp)
1.1  glass 	struct ifnet *ifp;
1.1  glass {
1.1  glass 	register struct le_softc *le = lecd.cd_devs[ifp->if_unit];
1.1  glass 	register struct letmd *tmd;
1.1  glass 	register struct mbuf *m;
1.1  glass 	int len;
1.1  glass
1.1  glass 	if ((le->sc_if.if_flags & IFF_RUNNING) == 0)
1.8  glass 		return 0;
1.1  glass 	IF_DEQUEUE(&le->sc_if.if_snd, m);
1.1  glass 	if (m == 0)
1.8  glass 		return 0;
1.1  glass 	len = leput(le->sc_r2->ler2_tbuf[0], m);
1.1  glass #if NBPFILTER > 0
1.1  glass 	/*
1.1  glass 	 * If bpf is listening on this interface, let it
1.1  glass 	 * see the packet before we commit it to the wire.
1.1  glass 	 */
1.1  glass 	if (le->sc_bpf)
1.1  glass                 bpf_tap(le->sc_bpf, le->sc_r2->ler2_tbuf[0], len);
1.1  glass #endif
1.1  glass 	tmd = le->sc_r2->ler2_tmd;
1.1  glass 	tmd->tmd3 = 0;
1.1  glass 	tmd->tmd2 = -len;
1.3  glass 	tmd->tmd1_bits = LE_OWN | LE_STP | LE_ENP;
1.1  glass 	le->sc_if.if_flags |= IFF_OACTIVE;
1.8  glass 	return 0;
1.1  glass }
1.1  glass
1.1  glass leintr(unit)
1.1  glass 	register int unit;
1.1  glass {
1.1  glass 	register struct le_softc *le = lecd.cd_devs[unit];
1.1  glass 	register struct lereg1 *ler1;
1.1  glass 	register int stat;
1.1  glass
1.1  glass 	le_machdep_intrcheck(le, unit);
1.1  glass 	ler1 = le->sc_r1;
1.1  glass 	LERDWR(le, ler1->ler1_rdp, stat);
1.4  glass 	if (ledebug)
1.7  glass 	    printf("[le%d: stat %b]\n", unit, stat, LE_STATUS_BITS);
1.1  glass 	if (stat & LE_SERR) {
1.1  glass 		leerror(unit, stat);
1.1  glass 		if (stat & LE_MERR) {
1.1  glass 			le->sc_merr++;
1.1  glass 			lereset(unit);
1.1  glass 			return(1);
1.1  glass 		}
1.1  glass 		if (stat & LE_BABL)
1.1  glass 			le->sc_babl++;
1.1  glass 		if (stat & LE_CERR)
1.1  glass 			le->sc_cerr++;
1.1  glass 		if (stat & LE_MISS)
1.1  glass 			le->sc_miss++;
1.1  glass 		LERDWR(le, LE_BABL|LE_CERR|LE_MISS|LE_INEA, ler1->ler1_rdp);
1.1  glass 	}
1.1  glass 	if ((stat & LE_RXON) == 0) {
1.1  glass 		le->sc_rxoff++;
1.1  glass 		lereset(unit);
1.1  glass 		return(1);
1.1  glass 	}
1.1  glass 	if ((stat & LE_TXON) == 0) {
1.1  glass 		le->sc_txoff++;
1.1  glass 		lereset(unit);
1.1  glass 		return(1);
1.1  glass 	}
1.1  glass 	if (stat & LE_RINT) {
1.1  glass 		/* interrupt is cleared in lerint */
1.1  glass 		lerint(unit);
1.1  glass 	}
1.1  glass 	if (stat & LE_TINT) {
1.1  glass 		LERDWR(le, LE_TINT|LE_INEA, ler1->ler1_rdp);
1.1  glass 		lexint(unit);
1.1  glass 	}
1.1  glass 	return(1);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Ethernet interface transmitter interrupt.
1.1  glass  * Start another output if more data to send.
1.1  glass  */
1.1  glass lexint(unit)
1.1  glass 	register int unit;
1.1  glass {
1.1  glass 	register struct le_softc *le = lecd.cd_devs[unit];
1.1  glass 	register struct letmd *tmd = le->sc_r2->ler2_tmd;
1.1  glass
1.1  glass 	if ((le->sc_if.if_flags & IFF_OACTIVE) == 0) {
1.1  glass 		le->sc_xint++;
1.1  glass 		return;
1.1  glass 	}
1.3  glass 	if (tmd->tmd1_bits & LE_OWN) {
1.1  glass 		le->sc_xown++;
1.1  glass 		return;
1.1  glass 	}
1.3  glass 	if (tmd->tmd1_bits & LE_ERR) {
1.1  glass err:
1.1  glass 		lexerror(unit);
1.1  glass 		le->sc_if.if_oerrors++;
1.1  glass 		if (tmd->tmd3 & (LE_TBUFF|LE_UFLO)) {
1.1  glass 			le->sc_uflo++;
1.1  glass 			lereset(unit);
1.1  glass 		}
1.1  glass 		else if (tmd->tmd3 & LE_LCOL)
1.1  glass 			le->sc_if.if_collisions++;
1.1  glass 		else if (tmd->tmd3 & LE_RTRY)
1.1  glass 			le->sc_if.if_collisions += 16;
1.1  glass 	}
1.1  glass 	else if (tmd->tmd3 & LE_TBUFF)
1.1  glass 		/* XXX documentation says BUFF not included in ERR */
1.1  glass 		goto err;
1.3  glass 	else if (tmd->tmd1_bits & LE_ONE)
1.1  glass 		le->sc_if.if_collisions++;
1.3  glass 	else if (tmd->tmd1_bits & LE_MORE)
1.1  glass 		/* what is the real number? */
1.1  glass 		le->sc_if.if_collisions += 2;
1.1  glass 	else
1.1  glass 		le->sc_if.if_opackets++;
1.1  glass 	le->sc_if.if_flags &= ~IFF_OACTIVE;
1.1  glass 	(void) lestart(&le->sc_if);
1.1  glass }
1.1  glass
1.1  glass #define	LENEXTRMP \
1.1  glass 	if (++bix == LERBUF) bix = 0, rmd = le->sc_r2->ler2_rmd; else ++rmd
1.1  glass
1.1  glass /*
1.1  glass  * Ethernet interface receiver interrupt.
1.1  glass  * If input error just drop packet.
1.1  glass  * Decapsulate packet based on type and pass to type specific
1.1  glass  * higher-level input routine.
1.1  glass  */
1.1  glass lerint(unit)
1.1  glass 	int unit;
1.1  glass {
1.1  glass 	register struct le_softc *le = lecd.cd_devs[unit];
1.1  glass 	register int bix = le->sc_rmd;
1.1  glass 	register struct lermd *rmd = &le->sc_r2->ler2_rmd[bix];
1.1  glass
1.1  glass 	/*
1.1  glass 	 * Out of sync with hardware, should never happen?
1.1  glass 	 */
1.3  glass 	if (rmd->rmd1_bits & LE_OWN) {
1.1  glass 		LERDWR(le->sc_r0, LE_RINT|LE_INEA, le->sc_r1->ler1_rdp);
1.1  glass 		return;
1.1  glass 	}
1.1  glass
1.1  glass 	/*
1.1  glass 	 * Process all buffers with valid data
1.1  glass 	 */
1.3  glass 	while ((rmd->rmd1_bits & LE_OWN) == 0) {
1.1  glass 		int len = rmd->rmd3;
1.1  glass
1.1  glass 		/* Clear interrupt to avoid race condition */
1.1  glass 		LERDWR(le->sc_r0, LE_RINT|LE_INEA, le->sc_r1->ler1_rdp);
1.1  glass
1.3  glass 		if (rmd->rmd1_bits & LE_ERR) {
1.1  glass 			le->sc_rmd = bix;
1.1  glass 			lererror(unit, "bad packet");
1.1  glass 			le->sc_if.if_ierrors++;
1.3  glass 		} else if ((rmd->rmd1_bits & (LE_STP|LE_ENP)) != (LE_STP|LE_ENP)) {
1.1  glass 			/*
1.1  glass 			 * Find the end of the packet so we can see how long
1.1  glass 			 * it was.  We still throw it away.
1.1  glass 			 */
1.1  glass 			do {
1.1  glass 				LERDWR(le->sc_r0, LE_RINT|LE_INEA,
1.1  glass 				       le->sc_r1->ler1_rdp);
1.1  glass 				rmd->rmd3 = 0;
1.3  glass 				rmd->rmd1_bits = LE_OWN;
1.1  glass 				LENEXTRMP;
1.3  glass 			} while (!(rmd->rmd1_bits & (LE_OWN|LE_ERR|LE_STP|LE_ENP)));
1.1  glass 			le->sc_rmd = bix;
1.1  glass 			lererror(unit, "chained buffer");
1.1  glass 			le->sc_rxlen++;
1.1  glass 			/*
1.1  glass 			 * If search terminated without successful completion
1.1  glass 			 * we reset the hardware (conservative).
1.1  glass 			 */
1.3  glass 			if ((rmd->rmd1_bits & (LE_OWN|LE_ERR|LE_STP|LE_ENP)) !=
1.1  glass 			    LE_ENP) {
1.1  glass 				lereset(unit);
1.1  glass 				return;
1.1  glass 			}
1.1  glass 		} else
1.1  glass 			leread(unit, le->sc_r2->ler2_rbuf[bix], len);
1.1  glass 		rmd->rmd3 = 0;
1.3  glass 		rmd->rmd1_bits = LE_OWN;
1.1  glass 		LENEXTRMP;
1.1  glass 	}
1.1  glass 	le->sc_rmd = bix;
1.1  glass }
1.1  glass
1.1  glass leread(unit, buf, len)
1.1  glass 	int unit;
1.1  glass 	char *buf;
1.1  glass 	int len;
1.1  glass {
1.1  glass 	register struct le_softc *le = lecd.cd_devs[unit];
1.1  glass 	register struct ether_header *et;
1.1  glass     	struct mbuf *m;
1.1  glass 	int off, resid;
1.1  glass
1.1  glass 	le->sc_if.if_ipackets++;
1.1  glass 	et = (struct ether_header *)buf;
1.1  glass 	et->ether_type = ntohs((u_short)et->ether_type);
1.1  glass 	/* adjust input length to account for header and CRC */
1.1  glass 	len = len - sizeof(struct ether_header) - 4;
1.1  glass
1.1  glass #ifdef RMP
1.1  glass 	/*  (XXX)
1.1  glass 	 *
1.1  glass 	 *  If Ethernet Type field is < MaxPacketSize, we probably have
1.1  glass 	 *  a IEEE802 packet here.  Make sure that the size is at least
1.1  glass 	 *  that of the HP LLC.  Also do sanity checks on length of LLC
1.1  glass 	 *  (old Ethernet Type field) and packet length.
1.1  glass 	 *
1.1  glass 	 *  Provided the above checks succeed, change `len' to reflect
1.1  glass 	 *  the length of the LLC (i.e. et->ether_type) and change the
1.1  glass 	 *  type field to ETHERTYPE_IEEE so we can switch() on it later.
1.1  glass 	 *  Yes, this is a hack and will eventually be done "right".
1.1  glass 	 */
1.1  glass 	if (et->ether_type <= IEEE802LEN_MAX && len >= sizeof(struct hp_llc) &&
1.1  glass 	    len >= et->ether_type && len >= IEEE802LEN_MIN) {
1.1  glass 		len = et->ether_type;
1.1  glass 		et->ether_type = ETHERTYPE_IEEE;	/* hack! */
1.1  glass 	}
1.1  glass #endif
1.1  glass
1.1  glass #define	ledataaddr(et, off, type)	((type)(((caddr_t)((et)+1)+(off))))
1.1  glass 	if (et->ether_type >= ETHERTYPE_TRAIL &&
1.1  glass 	    et->ether_type < ETHERTYPE_TRAIL+ETHERTYPE_NTRAILER) {
1.1  glass 		off = (et->ether_type - ETHERTYPE_TRAIL) * 512;
1.1  glass 		if (off >= ETHERMTU)
1.1  glass 			return;		/* sanity */
1.1  glass 		et->ether_type = ntohs(*ledataaddr(et, off, u_short *));
1.1  glass 		resid = ntohs(*(ledataaddr(et, off+2, u_short *)));
1.1  glass 		if (off + resid > len)
1.1  glass 			return;		/* sanity */
1.1  glass 		len = off + resid;
1.1  glass 	} else
1.1  glass 		off = 0;
1.1  glass
1.1  glass 	if (len <= 0) {
1.1  glass 		if (ledebug)
1.1  glass 			log(LOG_WARNING,
1.1  glass 			    "le%d: ierror(runt packet): from %s: len=%d\n",
1.1  glass 			    unit, ether_sprintf(et->ether_shost), len);
1.1  glass 		le->sc_runt++;
1.1  glass 		le->sc_if.if_ierrors++;
1.1  glass 		return;
1.1  glass 	}
1.1  glass #if NBPFILTER > 0
1.1  glass 	/*
1.1  glass 	 * Check if there's a bpf filter listening on this interface.
1.1  glass 	 * If so, hand off the raw packet to bpf, which must deal with
1.1  glass 	 * trailers in its own way.
1.1  glass 	 */
1.1  glass 	if (le->sc_bpf) {
1.1  glass 		bpf_tap(le->sc_bpf, buf, len + sizeof(struct ether_header));
1.1  glass
1.1  glass 		/*
1.1  glass 		 * Note that the interface cannot be in promiscuous mode if
1.1  glass 		 * there are no bpf listeners.  And if we are in promiscuous
1.1  glass 		 * mode, we have to check if this packet is really ours.
1.1  glass 		 *
1.1  glass 		 * XXX This test does not support multicasts.
1.1  glass 		 */
1.1  glass 		if ((le->sc_if.if_flags & IFF_PROMISC)
1.1  glass 		    && bcmp(et->ether_dhost, le->sc_addr,
1.1  glass 			    sizeof(et->ether_dhost)) != 0
1.1  glass 		    && bcmp(et->ether_dhost, etherbroadcastaddr,
1.1  glass 			    sizeof(et->ether_dhost)) != 0)
1.1  glass 			return;
1.1  glass 	}
1.1  glass #endif
1.1  glass 	/*
1.1  glass 	 * Pull packet off interface.  Off is nonzero if packet
1.1  glass 	 * has trailing header; leget will then force this header
1.1  glass 	 * information to be at the front, but we still have to drop
1.1  glass 	 * the type and length which are at the front of any trailer data.
1.1  glass 	 */
1.1  glass 	m = leget(buf, len, off, &le->sc_if);
1.1  glass 	if (m == 0)
1.1  glass 		return;
1.1  glass #ifdef RMP
1.1  glass 	/*
1.1  glass 	 * (XXX)
1.1  glass 	 * This needs to be integrated with the ISO stuff in ether_input()
1.1  glass 	 */
1.1  glass 	if (et->ether_type == ETHERTYPE_IEEE) {
1.1  glass 		/*
1.1  glass 		 *  Snag the Logical Link Control header (IEEE 802.2).
1.1  glass 		 */
1.1  glass 		struct hp_llc *llc = &(mtod(m, struct rmp_packet *)->hp_llc);
1.1  glass
1.1  glass 		/*
1.1  glass 		 *  If the DSAP (and HP's extended DXSAP) indicate this
1.1  glass 		 *  is an RMP packet, hand it to the raw input routine.
1.1  glass 		 */
1.1  glass 		if (llc->dsap == IEEE_DSAP_HP && llc->dxsap == HPEXT_DXSAP) {
1.1  glass 			static struct sockproto rmp_sp = {AF_RMP,RMPPROTO_BOOT};
1.1  glass 			static struct sockaddr rmp_src = {AF_RMP};
1.1  glass 			static struct sockaddr rmp_dst = {AF_RMP};
1.1  glass
1.1  glass 			bcopy(et->ether_shost, rmp_src.sa_data,
1.1  glass 			      sizeof(et->ether_shost));
1.1  glass 			bcopy(et->ether_dhost, rmp_dst.sa_data,
1.1  glass 			      sizeof(et->ether_dhost));
1.1  glass
1.1  glass 			raw_input(m, &rmp_sp, &rmp_src, &rmp_dst);
1.1  glass 			return;
1.1  glass 		}
1.1  glass 	}
1.1  glass #endif
1.1  glass 	ether_input(&le->sc_if, et, m);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Routine to copy from mbuf chain to transmit
1.1  glass  * buffer in board local memory.
1.1  glass  */
1.1  glass leput(lebuf, m)
1.1  glass 	register char *lebuf;
1.1  glass 	register struct mbuf *m;
1.1  glass {
1.1  glass 	register struct mbuf *mp;
1.1  glass 	register int len, tlen = 0;
1.1  glass
1.1  glass 	for (mp = m; mp; mp = mp->m_next) {
1.1  glass 		len = mp->m_len;
1.1  glass 		if (len == 0)
1.1  glass 			continue;
1.1  glass 		tlen += len;
1.1  glass 		bcopy(mtod(mp, char *), lebuf, len);
1.1  glass 		lebuf += len;
1.1  glass 	}
1.1  glass 	m_freem(m);
1.1  glass 	if (tlen < LEMINSIZE) {
1.1  glass 		bzero(lebuf, LEMINSIZE - tlen);
1.1  glass 		tlen = LEMINSIZE;
1.1  glass 	}
1.1  glass 	return(tlen);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Routine to copy from board local memory into mbufs.
1.1  glass  */
1.1  glass struct mbuf *
1.1  glass leget(lebuf, totlen, off0, ifp)
1.1  glass 	char *lebuf;
1.1  glass 	int totlen, off0;
1.1  glass 	struct ifnet *ifp;
1.1  glass {
1.1  glass 	register struct mbuf *m;
1.1  glass 	struct mbuf *top = 0, **mp = &top;
1.1  glass 	register int off = off0, len;
1.1  glass 	register char *cp;
1.1  glass 	char *epkt;
1.1  glass
1.1  glass 	lebuf += sizeof (struct ether_header);
1.1  glass 	cp = lebuf;
1.1  glass 	epkt = cp + totlen;
1.1  glass 	if (off) {
1.1  glass 		cp += off + 2 * sizeof(u_short);
1.1  glass 		totlen -= 2 * sizeof(u_short);
1.1  glass 	}
1.1  glass
1.1  glass 	MGETHDR(m, M_DONTWAIT, MT_DATA);
1.1  glass 	if (m == 0)
1.1  glass 		return (0);
1.1  glass 	m->m_pkthdr.rcvif = ifp;
1.1  glass 	m->m_pkthdr.len = totlen;
1.1  glass 	m->m_len = MHLEN;
1.1  glass
1.1  glass 	while (totlen > 0) {
1.1  glass 		if (top) {
1.1  glass 			MGET(m, M_DONTWAIT, MT_DATA);
1.1  glass 			if (m == 0) {
1.1  glass 				m_freem(top);
1.1  glass 				return (0);
1.1  glass 			}
1.1  glass 			m->m_len = MLEN;
1.1  glass 		}
1.1  glass 		len = min(totlen, epkt - cp);
1.1  glass 		if (len >= MINCLSIZE) {
1.1  glass 			MCLGET(m, M_DONTWAIT);
1.1  glass 			if (m->m_flags & M_EXT)
1.1  glass 				m->m_len = len = min(len, MCLBYTES);
1.1  glass 			else
1.1  glass 				len = m->m_len;
1.1  glass 		} else {
1.1  glass 			/*
1.1  glass 			 * Place initial small packet/header at end of mbuf.
1.1  glass 			 */
1.1  glass 			if (len < m->m_len) {
1.1  glass 				if (top == 0 && len + max_linkhdr <= m->m_len)
1.1  glass 					m->m_data += max_linkhdr;
1.1  glass 				m->m_len = len;
1.1  glass 			} else
1.1  glass 				len = m->m_len;
1.1  glass 		}
1.1  glass 		bcopy(cp, mtod(m, caddr_t), (unsigned)len);
1.1  glass 		cp += len;
1.1  glass 		*mp = m;
1.1  glass 		mp = &m->m_next;
1.1  glass 		totlen -= len;
1.1  glass 		if (cp == epkt)
1.1  glass 			cp = lebuf;
1.1  glass 	}
1.1  glass 	return (top);
1.1  glass }
1.1  glass
1.1  glass /*
1.1  glass  * Process an ioctl request.
1.1  glass  */
1.1  glass leioctl(ifp, cmd, data)
1.1  glass 	register struct ifnet *ifp;
1.1  glass 	int cmd;
1.1  glass 	caddr_t data;
1.1  glass {
1.1  glass 	register struct ifaddr *ifa = (struct ifaddr *)data;
1.1  glass 	struct le_softc *le = (struct le_softc *) lecd.cd_devs[ifp->if_unit];
1.1  glass 	struct lereg1 *ler1 = le->sc_r1;
1.1  glass 	int s = splimp(), error = 0;
1.1  glass
1.1  glass 	switch (cmd) {
1.1  glass
1.1  glass 	case SIOCSIFADDR:
1.1  glass 		ifp->if_flags |= IFF_UP;
1.1  glass 		switch (ifa->ifa_addr->sa_family) {
1.1  glass #ifdef INET
1.1  glass 		case AF_INET:
1.1  glass 			leinit(ifp->if_unit);	/* before arpwhohas */
1.1  glass 			((struct arpcom *)ifp)->ac_ipaddr =
1.1  glass 				IA_SIN(ifa)->sin_addr;
1.1  glass 			arpwhohas((struct arpcom *)ifp, &IA_SIN(ifa)->sin_addr);
1.1  glass 			break;
1.1  glass #endif
1.1  glass #ifdef NS
1.1  glass 		case AF_NS:
1.1  glass 		    {
1.1  glass 			register struct ns_addr *ina = &(IA_SNS(ifa)->sns_addr);
1.1  glass
1.1  glass 			if (ns_nullhost(*ina))
1.1  glass 				ina->x_host = *(union ns_host *)(le->sc_addr);
1.1  glass 			else {
1.1  glass 				/*
1.1  glass 				 * The manual says we can't change the address
1.1  glass 				 * while the receiver is armed,
1.1  glass 				 * so reset everything
1.1  glass 				 */
1.1  glass 				ifp->if_flags &= ~IFF_RUNNING;
1.1  glass 				bcopy((caddr_t)ina->x_host.c_host,
1.1  glass 				    (caddr_t)le->sc_addr, sizeof(le->sc_addr));
1.1  glass 			}
1.1  glass 			leinit(ifp->if_unit); /* does le_setaddr() */
1.1  glass 			break;
1.1  glass 		    }
1.1  glass #endif
1.1  glass 		default:
1.1  glass 			leinit(ifp->if_unit);
1.1  glass 			break;
1.1  glass 		}
1.1  glass 		break;
1.1  glass
1.1  glass 	case SIOCSIFFLAGS:
1.1  glass 		if ((ifp->if_flags & IFF_UP) == 0 &&
1.1  glass 		    ifp->if_flags & IFF_RUNNING) {
1.1  glass 			LERDWR(le->sc_r0, LE_STOP, ler1->ler1_rdp);
1.1  glass 			ifp->if_flags &= ~IFF_RUNNING;
1.1  glass 		} else if (ifp->if_flags & IFF_UP &&
1.1  glass 		    (ifp->if_flags & IFF_RUNNING) == 0)
1.1  glass 			leinit(ifp->if_unit);
1.1  glass 		/*
1.1  glass 		 * If the state of the promiscuous bit changes, the interface
1.1  glass 		 * must be reset to effect the change.
1.1  glass 		 */
1.1  glass 		if (((ifp->if_flags ^ le->sc_iflags) & IFF_PROMISC) &&
1.1  glass 		    (ifp->if_flags & IFF_RUNNING)) {
1.1  glass 			le->sc_iflags = ifp->if_flags;
1.1  glass 			lereset(ifp->if_unit);
1.8  glass 			(void) lestart(ifp);
1.1  glass 		}
1.1  glass 		break;
1.1  glass
1.1  glass 	default:
1.1  glass 		error = EINVAL;
1.1  glass 	}
1.1  glass 	splx(s);
1.1  glass 	return (error);
1.1  glass }
1.1  glass
1.1  glass leerror(unit, stat)
1.1  glass 	int unit;
1.1  glass 	int stat;
1.1  glass {
1.1  glass 	struct le_softc *le = NULL;
1.1  glass
1.1  glass
1.1  glass 	if (!ledebug)
1.1  glass 		return;
1.1  glass
1.1  glass 	le = (struct le_softc *) lecd.cd_devs[unit];
1.1  glass 	/*
1.1  glass 	 * Not all transceivers implement heartbeat
1.1  glass 	 * so we only log CERR once.
1.1  glass 	 */
1.1  glass 	if ((stat & LE_CERR) && le->sc_cerr)
1.1  glass 		return;
1.1  glass 	log(LOG_WARNING,
1.1  glass 	    "le%d: error: stat=%b\n", unit,
1.1  glass 	    stat,
1.4  glass 	    LE_STATUS_BITS);
1.1  glass }
1.1  glass
1.1  glass lererror(unit, msg)
1.1  glass 	int unit;
1.1  glass 	char *msg;
1.1  glass {
1.1  glass 	register struct le_softc *le = lecd.cd_devs[unit];
1.1  glass 	register struct lermd *rmd;
1.1  glass 	int len;
1.1  glass
1.1  glass 	if (!ledebug)
1.1  glass 		return;
1.1  glass
1.1  glass 	rmd = &le->sc_r2->ler2_rmd[le->sc_rmd];
1.1  glass 	len = rmd->rmd3;
1.1  glass 	log(LOG_WARNING,
1.3  glass 	    "le%d: ierror(%s): from %s: buf=%d, len=%d, rmd1_bits=%b\n",
1.1  glass 	    unit, msg,
1.1  glass 	    len > 11 ? ether_sprintf(&le->sc_r2->ler2_rbuf[le->sc_rmd][6]) : "unknown",
1.1  glass 	    le->sc_rmd, len,
1.3  glass 	    rmd->rmd1_bits,
1.4  glass 	    "\20\10OWN\7ERR\6FRAM\5OFLO\4CRC\3RBUF\2STP\1ENP");
1.1  glass }
1.1  glass
1.1  glass lexerror(unit)
1.1  glass 	int unit;
1.1  glass {
1.1  glass 	register struct le_softc *le = lecd.cd_devs[unit];
1.1  glass 	register struct letmd *tmd;
1.1  glass 	int len;
1.1  glass
1.1  glass 	if (!ledebug)
1.1  glass 		return;
1.1  glass
1.1  glass 	tmd = le->sc_r2->ler2_tmd;
1.1  glass 	len = -tmd->tmd2;
1.1  glass 	log(LOG_WARNING,
1.3  glass 	    "le%d: oerror: to %s: buf=%d, len=%d, tmd1_bits=%b, tmd3=%b\n",
1.1  glass 	    unit,
1.1  glass 	    len > 5 ? ether_sprintf(&le->sc_r2->ler2_tbuf[0][0]) : "unknown",
1.1  glass 	    0, len,
1.3  glass 	    tmd->tmd1_bits,
1.4  glass 	    "\20\10OWN\7ERR\6RES\5MORE\4ONE\3DEF\2STP\1ENP",
1.1  glass 	    tmd->tmd3,
1.1  glass 	    "\20\20BUFF\17UFLO\16RES\15LCOL\14LCAR\13RTRY");
1.1  glass }