/*- * Copyright (c) 1994 Matt Thomas (thomas@lkg.dec.com) * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. The name of the author may not be used to endorse or promote products * derived from this software withough specific prior written permission * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * $Id: if_le.c,v 1.27 1995/12/15 00:54:19 bde Exp $ */ /* * DEC EtherWORKS 2 Ethernet Controllers * DEC EtherWORKS 3 Ethernet Controllers * * Written by Matt Thomas * BPF support code stolen directly from if_ec.c * * This driver supports the DEPCA, DE100, DE101, DE200, DE201, * DE2002, DE203, DE204, DE205, and DE422 cards. */ #include "le.h" #if NLE > 0 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "bpfilter.h" #ifdef INET #include #include #include #include #include #endif #ifdef IPX #include #include #endif #ifdef NS #include #include #endif #include #include #include #include #include #include #include #if NBPFILTER > 0 #include #include #endif /* Forward declarations */ typedef struct le_softc le_softc_t; typedef struct le_board le_board_t; typedef u_short le_mcbits_t; #define LE_MC_NBPW_LOG2 4 #define LE_MC_NBPW (1 << LE_MC_NBPW_LOG2) #if __FreeBSD__ > 1 #define IF_RESET_ARGS int unit #define LE_RESET(ifp) (((sc)->if_reset)((sc)->le_if.if_unit)) #else #define IF_RESET_ARGS int unit, int dummy #define LE_RESET(ifp) (((sc)->if_reset)((sc)->le_if.if_unit, 0)) #endif #if !defined(LE_NOLEMAC) /* * - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - * * Start of DEC EtherWORKS III (LEMAC) dependent structures * */ #include "i386/isa/ic/lemac.h" /* Include LEMAC definitions */ static int lemac_probe(le_softc_t *sc, const le_board_t *bd, int *msize); struct le_lemac_info { u_int lemac__lastpage; /* last 2K page */ u_int lemac__memmode; /* Are we in 2K, 32K, or 64K mode */ u_int lemac__membase; /* Physical address of start of RAM */ u_int lemac__txctl; /* Transmit Control Byte */ u_int lemac__txmax; /* Maximum # of outstanding transmits */ le_mcbits_t lemac__mctbl[LEMAC_MCTBL_SIZE/sizeof(le_mcbits_t)]; /* local copy of multicast table */ u_char lemac__eeprom[LEMAC_EEP_SIZE]; /* local copy eeprom */ char lemac__prodname[LEMAC_EEP_PRDNMSZ+1]; /* prodname name */ #define lemac_lastpage le_un.un_lemac.lemac__lastpage #define lemac_memmode le_un.un_lemac.lemac__memmode #define lemac_membase le_un.un_lemac.lemac__membase #define lemac_txctl le_un.un_lemac.lemac__txctl #define lemac_txmax le_un.un_lemac.lemac__txmax #define lemac_mctbl le_un.un_lemac.lemac__mctbl #define lemac_eeprom le_un.un_lemac.lemac__eeprom #define lemac_prodname le_un.un_lemac.lemac__prodname }; #endif /* !defined(LE_NOLEMAC) */ #if !defined(LE_NOLANCE) /* * - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - * * Start of DEC EtherWORKS II (LANCE) dependent structures * */ #include "i386/isa/ic/am7990.h" #ifndef LN_DOSTATS #define LN_DOSTATS 1 #endif static int depca_probe(le_softc_t *sc, const le_board_t *bd, int *msize); typedef struct lance_descinfo lance_descinfo_t; typedef struct lance_ring lance_ring_t; typedef unsigned lance_addr_t; struct lance_descinfo { caddr_t di_addr; /* address of descriptor */ lance_addr_t di_bufaddr; /* LANCE address of buffer owned by descriptor */ unsigned di_buflen; /* size of buffer owned by descriptor */ struct mbuf *di_mbuf; /* mbuf being transmitted/received */ }; struct lance_ring { lance_descinfo_t *ri_first; /* Pointer to first descriptor in ring */ lance_descinfo_t *ri_last; /* Pointer to last + 1 descriptor in ring */ lance_descinfo_t *ri_nextin; /* Pointer to next one to be given to HOST */ lance_descinfo_t *ri_nextout; /* Pointer to next one to be given to LANCE */ unsigned ri_max; /* Size of Ring - 1 */ unsigned ri_free; /* Number of free rings entires (owned by HOST) */ lance_addr_t ri_heap; /* Start of RAM for this ring */ lance_addr_t ri_heapend; /* End + 1 of RAM for this ring */ lance_addr_t ri_outptr; /* Pointer to first output byte */ unsigned ri_outsize; /* Space remaining for output */ }; struct le_lance_info { unsigned lance__csr1; /* LANCE Address of init block (low 16) */ unsigned lance__csr2; /* LANCE Address of init block (high 8) */ unsigned lance__csr3; /* Copy of CSR3 */ unsigned lance__rap; /* IO Port Offset of RAP */ unsigned lance__rdp; /* IO Port Offset of RDP */ unsigned lance__ramoffset; /* Offset to valid LANCE RAM */ unsigned lance__ramsize; /* Amount of RAM shared by LANCE */ unsigned lance__rxbufsize; /* Size of a receive buffer */ ln_initb_t lance__initb; /* local copy of LANCE initblock */ ln_initb_t *lance__raminitb; /* copy to board's LANCE initblock (debugging) */ ln_desc_t *lance__ramdesc; /* copy to board's LANCE descriptors (debugging) */ lance_ring_t lance__rxinfo; /* Receive ring information */ lance_ring_t lance__txinfo; /* Transmit ring information */ #define lance_csr1 le_un.un_lance.lance__csr1 #define lance_csr2 le_un.un_lance.lance__csr2 #define lance_csr3 le_un.un_lance.lance__csr3 #define lance_rap le_un.un_lance.lance__rap #define lance_rdp le_un.un_lance.lance__rdp #define lance_ramoffset le_un.un_lance.lance__ramoffset #define lance_ramsize le_un.un_lance.lance__ramsize #define lance_rxbufsize le_un.un_lance.lance__rxbufsize #define lance_initb le_un.un_lance.lance__initb #define lance_raminitb le_un.un_lance.lance__raminitb #define lance_ramdesc le_un.un_lance.lance__ramdesc #define lance_rxinfo le_un.un_lance.lance__rxinfo #define lance_txinfo le_un.un_lance.lance__txinfo }; #endif /* !defined(LE_NOLANCE) */ /* * - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - * * Start of Common Code * */ static void (*le_intrvec[NLE])(le_softc_t *sc); /* * Ethernet status, per interface. */ struct le_softc { struct arpcom le_ac; /* Common Ethernet/ARP Structure */ void (*if_init) __P((int)); /* Interface init routine */ void (*if_reset) __P((int)); /* Interface reset routine */ caddr_t le_membase; /* Starting memory address (virtual) */ unsigned le_iobase; /* Starting I/O base address */ unsigned le_irq; /* Interrupt Request Value */ unsigned le_flags; /* local copy of if_flags */ #define LE_BRDCSTONLY 0x01000000 /* If only broadcast is enabled */ u_int le_mcmask; /* bit mask for CRC-32 for multicast hash */ le_mcbits_t *le_mctbl; /* pointer to multicast table */ const char *le_prodname; /* product name DE20x-xx */ #if NBPFILTER > 0 caddr_t le_bpf; /* BPF context */ #endif u_char le_hwaddr[6]; /* local copy of hwaddr */ unsigned le_scast_drops; /* singlecast drops */ unsigned le_mcast_drops; /* multicast drops */ unsigned le_bcast_drops; /* broadcast drops */ union { #if !defined(LE_NOLEMAC) struct le_lemac_info un_lemac; /* LEMAC specific information */ #endif #if !defined(LE_NOLANCE) struct le_lance_info un_lance; /* Am7990 specific information */ #endif } le_un; }; #define le_if le_ac.ac_if static int le_probe(struct isa_device *dvp); static int le_attach(struct isa_device *dvp); static int le_ioctl(struct ifnet *ifp, int command, caddr_t data); static void le_input(le_softc_t *sc, caddr_t seg1, size_t total_len, size_t len2, caddr_t seg2); static void le_multi_filter(le_softc_t *sc); static void le_multi_op(le_softc_t *sc, const u_char *mca, int oper_flg); static int le_read_macaddr(le_softc_t *sc, int ioreg, int skippat); #define LE_CRC32_POLY 0xEDB88320UL /* CRC-32 Poly -- Little Endian */ struct le_board { int (*bd_probe)(le_softc_t *sc, const le_board_t *bd, int *msize); }; static le_softc_t le_softc[NLE]; static const le_board_t le_boards[] = { #if !defined(LE_NOLEMAC) { lemac_probe }, /* DE20[345] */ #endif #if !defined(LE_NOLANCE) { depca_probe }, /* DE{20[012],422} */ #endif { NULL } /* Must Be Last! */ }; /* * This tells the autoconf code how to set us up. */ struct isa_driver ledriver = { le_probe, le_attach, "le", }; static unsigned le_intrs[NLE]; #define LE_ADDREQUAL(a1, a2) \ (((u_short *)a1)[0] == ((u_short *)a2)[0] \ || ((u_short *)a1)[1] == ((u_short *)a2)[1] \ || ((u_short *)a1)[2] == ((u_short *)a2)[2]) #define LE_ADDRBRDCST(a1) \ (((u_short *)a1)[0] == 0xFFFFU \ || ((u_short *)a1)[1] == 0xFFFFU \ || ((u_short *)a1)[2] == 0xFFFFU) #define LE_INL(sc, reg) \ ({ u_long data; \ __asm __volatile("inl %1, %0": "=a" (data): "d" ((u_short)((sc)->le_iobase + (reg)))); \ data; }) #define LE_OUTL(sc, reg, data) \ ({__asm __volatile("outl %0, %1"::"a" ((u_long)(data)), "d" ((u_short)((sc)->le_iobase + (reg))));}) #define LE_INW(sc, reg) \ ({ u_short data; \ __asm __volatile("inw %1, %0": "=a" (data): "d" ((u_short)((sc)->le_iobase + (reg)))); \ data; }) #define LE_OUTW(sc, reg, data) \ ({__asm __volatile("outw %0, %1"::"a" ((u_short)(data)), "d" ((u_short)((sc)->le_iobase + (reg))));}) #define LE_INB(sc, reg) \ ({ u_char data; \ __asm __volatile("inb %1, %0": "=a" (data): "d" ((u_short)((sc)->le_iobase + (reg)))); \ data; }) #define LE_OUTB(sc, reg, data) \ ({__asm __volatile("outb %0, %1"::"a" ((u_char)(data)), "d" ((u_short)((sc)->le_iobase + (reg))));}) #define MEMCPY(to, from, len) bcopy(from, to, len) #define MEMSET(where, what, howmuch) bzero(where, howmuch) #define MEMCMP(l, r, len) bcmp(l, r, len) static struct kern_devconf kdc_le[NLE] = { { 0, 0, 0, /* filled in by dev_attach */ "le", 0, { MDDT_ISA, 0, "net" }, isa_generic_externalize, 0, 0, ISA_EXTERNALLEN, &kdc_isa0, /* parent */ 0, /* parentdata */ DC_UNCONFIGURED, /* state */ "Ethernet adapter: DEC EtherWorks II or EtherWorks III", DC_CLS_NETIF /* class */ } }; static inline void le_registerdev(struct isa_device *id) { if(id->id_unit) kdc_le[id->id_unit] = kdc_le[0]; kdc_le[id->id_unit].kdc_unit = id->id_unit; kdc_le[id->id_unit].kdc_isa = id; dev_attach(&kdc_le[id->id_unit]); } static int le_probe( struct isa_device *dvp) { le_softc_t *sc = &le_softc[dvp->id_unit]; const le_board_t *bd; int iospace; if (dvp->id_unit >= NLE) { printf("%s%d not configured -- too many devices\n", ledriver.name, dvp->id_unit); return 0; } le_registerdev(dvp); sc->le_iobase = dvp->id_iobase; sc->le_membase = (u_char *) dvp->id_maddr; sc->le_irq = dvp->id_irq; sc->le_if.if_name = ledriver.name; sc->le_if.if_unit = dvp->id_unit; /* * Find and Initialize board.. */ sc->le_flags &= ~(IFF_UP|IFF_ALLMULTI); for (bd = le_boards; bd->bd_probe != NULL; bd++) { if ((iospace = (*bd->bd_probe)(sc, bd, &dvp->id_msize)) != 0) { return iospace; } } return 0; } static int le_attach( struct isa_device *dvp) { le_softc_t *sc = &le_softc[dvp->id_unit]; struct ifnet *ifp = &sc->le_if; struct ifaddr *ifa = ifp->if_addrlist; ifp->if_mtu = ETHERMTU; printf("%s%d: %s ethernet address %s\n", ifp->if_name, ifp->if_unit, sc->le_prodname, ether_sprintf(sc->le_ac.ac_enaddr)); ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST; ifp->if_output = ether_output; ifp->if_ioctl = le_ioctl; ifp->if_type = IFT_ETHER; ifp->if_addrlen = 6; ifp->if_hdrlen = 14; #if NBPFILTER > 0 bpfattach(&sc->le_bpf, ifp, DLT_EN10MB, sizeof(struct ether_header)); #endif if_attach(ifp); kdc_le[dvp->id_unit].kdc_state = DC_IDLE; while (ifa && ifa->ifa_addr && ifa->ifa_addr->sa_family != AF_LINK) ifa = ifa->ifa_next; if (ifa != NULL && ifa->ifa_addr != NULL) { struct sockaddr_dl *sdl; /* * Provide our ether address to the higher layers */ sdl = (struct sockaddr_dl *) ifa->ifa_addr; sdl->sdl_type = IFT_ETHER; sdl->sdl_alen = 6; sdl->sdl_slen = 0; MEMCPY(LLADDR(sdl), sc->le_ac.ac_enaddr, 6); } return 1; } void le_intr( int unit) { int s = splimp(); le_intrs[unit]++; (*le_intrvec[unit])(&le_softc[unit]); splx(s); } #define LE_XTRA 0 static void le_input( le_softc_t *sc, caddr_t seg1, size_t total_len, size_t len1, caddr_t seg2) { struct ether_header eh; struct mbuf *m; if (total_len - sizeof(eh) > ETHERMTU || total_len - sizeof(eh) < ETHERMIN) { sc->le_if.if_ierrors++; return; } MEMCPY(&eh, seg1, sizeof(eh)); #if NBPFILTER > 0 if (sc->le_bpf != NULL && seg2 == NULL) { bpf_tap(sc->le_bpf, seg1, total_len); /* * If this is single cast but not to us * drop it! */ if ((eh.ether_dhost[0] & 1) == 0) { if (!LE_ADDREQUAL(eh.ether_dhost, sc->le_ac.ac_enaddr)) { sc->le_scast_drops++; return; } } else if ((sc->le_flags & IFF_MULTICAST) == 0) { sc->le_mcast_drops++; return; } else if (sc->le_flags & LE_BRDCSTONLY) { if (!LE_ADDRBRDCST(eh.ether_dhost)) { sc->le_bcast_drops++; return; } } } #endif seg1 += sizeof(eh); total_len -= sizeof(eh); len1 -= sizeof(eh); MGETHDR(m, M_DONTWAIT, MT_DATA); if (m == NULL) { sc->le_if.if_ierrors++; return; } m->m_pkthdr.len = total_len; m->m_pkthdr.rcvif = &sc->le_if; if (total_len + LE_XTRA > MHLEN /* >= MINCLSIZE */) { MCLGET(m, M_DONTWAIT); if ((m->m_flags & M_EXT) == 0) { m_free(m); sc->le_if.if_ierrors++; return; } } else if (total_len + LE_XTRA > MHLEN && MINCLSIZE == (MHLEN+MLEN)) { MGET(m->m_next, M_DONTWAIT, MT_DATA); if (m->m_next == NULL) { m_free(m); sc->le_if.if_ierrors++; return; } m->m_next->m_len = total_len - MHLEN - LE_XTRA; len1 = total_len = MHLEN - LE_XTRA; MEMCPY(mtod(m->m_next, caddr_t), &seg1[MHLEN-LE_XTRA], m->m_next->m_len); } else if (total_len + LE_XTRA > MHLEN) { panic("le_input: pkt of unknown length"); } m->m_data += LE_XTRA; m->m_len = total_len; MEMCPY(mtod(m, caddr_t), seg1, len1); if (seg2 != NULL) MEMCPY(mtod(m, caddr_t) + len1, seg2, total_len - len1); #if NBPFILTER > 0 if (sc->le_bpf != NULL && seg2 != NULL) { bpf_mtap(sc->le_bpf, m); /* * If this is single cast but not to us * drop it! */ if ((eh.ether_dhost[0] & 1) == 0) { if (!LE_ADDREQUAL(eh.ether_dhost, sc->le_ac.ac_enaddr)) { sc->le_scast_drops++; m_freem(m); return; } } else if ((sc->le_flags & IFF_MULTICAST) == 0) { sc->le_mcast_drops++; m_freem(m); return; } else if (sc->le_flags & LE_BRDCSTONLY) { if (!LE_ADDRBRDCST(eh.ether_dhost)) { sc->le_bcast_drops++; m_freem(m); return; } } } #endif ether_input(&sc->le_if, &eh, m); } static int le_ioctl( struct ifnet *ifp, int cmd, caddr_t data) { le_softc_t *sc = &le_softc[ifp->if_unit]; int s, error = 0; if ((sc->le_flags & IFF_UP) == 0) return EIO; s = splimp(); switch (cmd) { case SIOCSIFADDR: { struct ifaddr *ifa = (struct ifaddr *)data; ifp->if_flags |= IFF_UP; switch(ifa->ifa_addr->sa_family) { #ifdef INET case AF_INET: { (*sc->if_init)(ifp->if_unit); arp_ifinit((struct arpcom *)ifp, ifa); break; } #endif /* INET */ #ifdef IPX /* This magic copied from if_is.c; I don't use XNS, * so I have no way of telling if this actually * works or not. */ case AF_IPX: { struct ipx_addr *ina = &(IA_SIPX(ifa)->sipx_addr); if (ipx_nullhost(*ina)) { ina->x_host = *(union ipx_host *)(sc->le_ac.ac_enaddr); } else { ifp->if_flags &= ~IFF_RUNNING; bcopy((caddr_t)ina->x_host.c_host, (caddr_t)sc->le_ac.ac_enaddr, sizeof sc->le_ac.ac_enaddr); } (*sc->if_init)(ifp->if_unit); break; } #endif /* IPX */ #ifdef NS /* This magic copied from if_is.c; I don't use XNS, * so I have no way of telling if this actually * works or not. */ case AF_NS: { struct ns_addr *ina = &(IA_SNS(ifa)->sns_addr); if (ns_nullhost(*ina)) { ina->x_host = *(union ns_host *)(sc->le_ac.ac_enaddr); } else { ifp->if_flags &= ~IFF_RUNNING; bcopy((caddr_t)ina->x_host.c_host, (caddr_t)sc->le_ac.ac_enaddr, sizeof sc->le_ac.ac_enaddr); } (*sc->if_init)(ifp->if_unit); break; } #endif /* NS */ default: { (*sc->if_init)(ifp->if_unit); break; } } break; } case SIOCSIFFLAGS: { (*sc->if_init)(ifp->if_unit); break; } case SIOCADDMULTI: case SIOCDELMULTI: { /* * Update multicast listeners */ if (cmd == SIOCADDMULTI) error = ether_addmulti((struct ifreq *)data, &sc->le_ac); else error = ether_delmulti((struct ifreq *)data, &sc->le_ac); if (error == ENETRESET) { /* reset multicast filtering */ (*sc->if_init)(ifp->if_unit); error = 0; } break; } default: { error = EINVAL; } } splx(s); kdc_le[ifp->if_unit].kdc_state = (ifp->if_flags & IFF_UP) ? DC_BUSY : DC_IDLE; return error; } /* * This is the standard method of reading the DEC Address ROMS. * I don't understand it but it does work. */ static int le_read_macaddr( le_softc_t *sc, int ioreg, int skippat) { int cksum, rom_cksum; if (!skippat) { int idx, idx2, found, octet; static u_char testpat[] = { 0xFF, 0, 0x55, 0xAA, 0xFF, 0, 0x55, 0xAA }; idx2 = found = 0; for (idx = 0; idx < 32; idx++) { octet = LE_INB(sc, ioreg); if (octet == testpat[idx2]) { if (++idx2 == sizeof testpat) { ++found; break; } } else { idx2 = 0; } } if (!found) return -1; } cksum = 0; sc->le_hwaddr[0] = LE_INB(sc, ioreg); sc->le_hwaddr[1] = LE_INB(sc, ioreg); cksum = *(u_short *) &sc->le_hwaddr[0]; sc->le_hwaddr[2] = LE_INB(sc, ioreg); sc->le_hwaddr[3] = LE_INB(sc, ioreg); cksum *= 2; if (cksum > 65535) cksum -= 65535; cksum += *(u_short *) &sc->le_hwaddr[2]; if (cksum > 65535) cksum -= 65535; sc->le_hwaddr[4] = LE_INB(sc, ioreg); sc->le_hwaddr[5] = LE_INB(sc, ioreg); cksum *= 2; if (cksum > 65535) cksum -= 65535; cksum += *(u_short *) &sc->le_hwaddr[4]; if (cksum >= 65535) cksum -= 65535; rom_cksum = LE_INB(sc, ioreg); rom_cksum |= LE_INB(sc, ioreg) << 8; if (cksum != rom_cksum) return -1; return 0; } static void le_multi_filter( le_softc_t *sc) { struct ether_multistep step; struct ether_multi *enm; #ifdef ISO extern char all_es_snpa[]; #endif MEMSET(sc->le_mctbl, 0, (sc->le_mcmask + 1) / 8); if (sc->le_if.if_flags & IFF_ALLMULTI) { sc->le_flags |= IFF_MULTICAST|IFF_ALLMULTI; return; } sc->le_flags &= ~IFF_MULTICAST; if (sc->le_ac.ac_ipaddr.s_addr != 0) { le_multi_op(sc, etherbroadcastaddr, TRUE); sc->le_flags |= LE_BRDCSTONLY|IFF_MULTICAST; } #ifdef ISO le_multi_op(sc, all_es_snpa, TRUE); #endif ETHER_FIRST_MULTI(step, &sc->le_ac, enm); if (enm != NULL) sc->le_flags |= IFF_MULTICAST; while (enm != NULL) { if (MEMCMP(enm->enm_addrlo, enm->enm_addrhi, 6) != 0) { sc->le_flags |= IFF_ALLMULTI; return; } le_multi_op(sc, enm->enm_addrlo, TRUE); ETHER_NEXT_MULTI(step, enm); sc->le_flags &= ~LE_BRDCSTONLY; } sc->le_flags &= ~IFF_ALLMULTI; } static void le_multi_op( le_softc_t *sc, const u_char *mca, int enable) { u_int idx, bit, data, crc = 0xFFFFFFFFUL; #ifdef __alpha for (data = *(__unaligned u_long *) mca, bit = 0; bit < 48; bit++, data >>= 1) crc = (crc >> 1) ^ (((crc ^ data) & 1) ? LE_CRC32_POLY : 0); #else for (idx = 0; idx < 6; idx++) for (data = *mca++, bit = 0; bit < 8; bit++, data >>= 1) crc = (crc >> 1) ^ (((crc ^ data) & 1) ? LE_CRC32_POLY : 0); #endif /* * The following two line convert the N bit index into a longword index * and a longword mask. */ crc &= sc->le_mcmask; bit = 1 << (crc & (LE_MC_NBPW -1)); idx = crc >> (LE_MC_NBPW_LOG2); /* * Set or clear hash filter bit in our table. */ if (enable) { sc->le_mctbl[idx] |= bit; /* Set Bit */ } else { sc->le_mctbl[idx] &= ~bit; /* Clear Bit */ } } #if !defined(LE_NOLEMAC) /* * - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - * * Start of DEC EtherWORKS III (LEMAC) dependent code * */ #define LEMAC_INTR_ENABLE(sc) \ LE_OUTB(sc, LEMAC_REG_IC, LE_INB(sc, LEMAC_REG_IC) | LEMAC_IC_ALL) #define LEMAC_INTR_DISABLE(sc) \ LE_OUTB(sc, LEMAC_REG_IC, LE_INB(sc, LEMAC_REG_IC) & ~LEMAC_IC_ALL) #define LEMAC_64K_MODE(mbase) (((mbase) >= 0x0A) && ((mbase) <= 0x0F)) #define LEMAC_32K_MODE(mbase) (((mbase) >= 0x14) && ((mbase) <= 0x1F)) #define LEMAC_2K_MODE(mbase) ( (mbase) >= 0x40) static void lemac_init(int unit); static void lemac_start(struct ifnet *ifp); static void lemac_reset(IF_RESET_ARGS); static void lemac_intr(le_softc_t *sc); static void lemac_rne_intr(le_softc_t *sc); static void lemac_tne_intr(le_softc_t *sc); static void lemac_txd_intr(le_softc_t *sc, unsigned cs_value); static void lemac_rxd_intr(le_softc_t *sc, unsigned cs_value); static int lemac_read_eeprom(le_softc_t *sc); static void lemac_init_adapmem(le_softc_t *sc); #define LE_MCBITS_ALL_1S ((le_mcbits_t)~(le_mcbits_t)0) static const le_mcbits_t lemac_allmulti_mctbl[16] = { LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, LE_MCBITS_ALL_1S, }; /* * An IRQ mapping table. Less space than switch statement. */ static const int lemac_irqs[] = { IRQ5, IRQ10, IRQ11, IRQ15 }; /* * Some tuning/monitoring variables. */ static unsigned lemac_deftxmax = 16; /* see lemac_max above */ static unsigned lemac_txnospc = 0; /* total # of tranmit starvations */ static unsigned lemac_tne_intrs = 0; /* total # of tranmit done intrs */ static unsigned lemac_rne_intrs = 0; /* total # of receive done intrs */ static unsigned lemac_txd_intrs = 0; /* total # of tranmit error intrs */ static unsigned lemac_rxd_intrs = 0; /* total # of receive error intrs */ static int lemac_probe( le_softc_t *sc, const le_board_t *bd, int *msize) { int irq, portval; LE_OUTB(sc, LEMAC_REG_IOP, LEMAC_IOP_EEINIT); DELAY(LEMAC_EEP_DELAY); /* * Read Ethernet address if card is present. */ if (le_read_macaddr(sc, LEMAC_REG_APD, 0) < 0) return 0; MEMCPY(sc->le_ac.ac_enaddr, sc->le_hwaddr, 6); /* * Clear interrupts and set IRQ. */ portval = LE_INB(sc, LEMAC_REG_IC) & LEMAC_IC_IRQMSK; irq = lemac_irqs[portval >> 5]; LE_OUTB(sc, LEMAC_REG_IC, portval); /* * Make sure settings match. */ if (irq != sc->le_irq) { printf("%s%d: lemac configuration error: expected IRQ 0x%x actual 0x%x\n", sc->le_if.if_name, sc->le_if.if_unit, sc->le_irq, irq); return 0; } /* * Try to reset the unit */ sc->if_init = lemac_init; sc->le_if.if_start = lemac_start; sc->if_reset = lemac_reset; sc->lemac_memmode = 2; LE_RESET(sc); if ((sc->le_flags & IFF_UP) == 0) return 0; /* * Check for correct memory base configuration. */ if (vtophys(sc->le_membase) != sc->lemac_membase) { printf("%s%d: lemac configuration error: expected iomem 0x%x actual 0x%x\n", sc->le_if.if_name, sc->le_if.if_unit, vtophys(sc->le_membase), sc->lemac_membase); return 0; } sc->le_prodname = sc->lemac_prodname; sc->le_mctbl = sc->lemac_mctbl; sc->le_mcmask = (1 << LEMAC_MCTBL_BITS) - 1; sc->lemac_txmax = lemac_deftxmax; *msize = 2048; le_intrvec[sc->le_if.if_unit] = lemac_intr; return LEMAC_IOSPACE; } /* * Do a hard reset of the board; */ static void lemac_reset( IF_RESET_ARGS) { le_softc_t *sc = &le_softc[unit]; int portval, cksum; /* * Initialize board.. */ sc->le_flags &= IFF_UP; sc->le_if.if_flags &= ~IFF_OACTIVE; LEMAC_INTR_DISABLE(sc); LE_OUTB(sc, LEMAC_REG_IOP, LEMAC_IOP_EEINIT); DELAY(LEMAC_EEP_DELAY); /* Disable Interrupts */ /* LE_OUTB(sc, LEMAC_REG_IC, LE_INB(sc, LEMAC_REG_IC) & ICR_IRQ_SEL); */ /* * Read EEPROM information. NOTE - the placement of this function * is important because functions hereafter may rely on information * read from the EEPROM. */ if ((cksum = lemac_read_eeprom(sc)) != LEMAC_EEP_CKSUM) { printf("%s%d: reset: EEPROM checksum failed (0x%x)\n", sc->le_if.if_name, sc->le_if.if_unit, cksum); return; } /* * Force to 2K mode if not already configured. */ portval = LE_INB(sc, LEMAC_REG_MBR); if (!LEMAC_2K_MODE(portval)) { if (LEMAC_64K_MODE(portval)) { portval = (((portval * 2) & 0xF) << 4); sc->lemac_memmode = 64; } else if (LEMAC_32K_MODE(portval)) { portval = ((portval & 0xF) << 4); sc->lemac_memmode = 32; } LE_OUTB(sc, LEMAC_REG_MBR, portval); } sc->lemac_membase = portval * (2 * 1024) + (512 * 1024); /* * Initialize Free Memory Queue, Init mcast table with broadcast. */ lemac_init_adapmem(sc); sc->le_flags |= IFF_UP; return; } static void lemac_init( int unit) { le_softc_t *sc = &le_softc[unit]; int s; if ((sc->le_flags & IFF_UP) == 0) return; s = splimp(); /* * If the interface has the up flag */ if (sc->le_if.if_flags & IFF_UP) { int saved_cs = LE_INB(sc, LEMAC_REG_CS); LE_OUTB(sc, LEMAC_REG_CS, saved_cs | (LEMAC_CS_TXD | LEMAC_CS_RXD)); LE_OUTB(sc, LEMAC_REG_PA0, sc->le_ac.ac_enaddr[0]); LE_OUTB(sc, LEMAC_REG_PA1, sc->le_ac.ac_enaddr[1]); LE_OUTB(sc, LEMAC_REG_PA2, sc->le_ac.ac_enaddr[2]); LE_OUTB(sc, LEMAC_REG_PA3, sc->le_ac.ac_enaddr[3]); LE_OUTB(sc, LEMAC_REG_PA4, sc->le_ac.ac_enaddr[4]); LE_OUTB(sc, LEMAC_REG_PA5, sc->le_ac.ac_enaddr[5]); LE_OUTB(sc, LEMAC_REG_IC, LE_INB(sc, LEMAC_REG_IC) | LEMAC_IC_IE); if (sc->le_if.if_flags & IFF_PROMISC) { LE_OUTB(sc, LEMAC_REG_CS, LEMAC_CS_MCE | LEMAC_CS_PME); } else { LEMAC_INTR_DISABLE(sc); le_multi_filter(sc); LE_OUTB(sc, LEMAC_REG_MPN, 0); if ((sc->le_flags | sc->le_if.if_flags) & IFF_ALLMULTI) { MEMCPY(&sc->le_membase[LEMAC_MCTBL_OFF], lemac_allmulti_mctbl, sizeof(lemac_allmulti_mctbl)); } else { MEMCPY(&sc->le_membase[LEMAC_MCTBL_OFF], sc->lemac_mctbl, sizeof(sc->lemac_mctbl)); } LE_OUTB(sc, LEMAC_REG_CS, LEMAC_CS_MCE); } LE_OUTB(sc, LEMAC_REG_CTL, LE_INB(sc, LEMAC_REG_CTL) ^ LEMAC_CTL_LED); LEMAC_INTR_ENABLE(sc); sc->le_if.if_flags |= IFF_RUNNING; } else { LE_OUTB(sc, LEMAC_REG_CS, LEMAC_CS_RXD|LEMAC_CS_TXD); LEMAC_INTR_DISABLE(sc); sc->le_if.if_flags &= ~IFF_RUNNING; } splx(s); } /* * What to do upon receipt of an interrupt. */ static void lemac_intr( le_softc_t *sc) { int cs_value; LEMAC_INTR_DISABLE(sc); /* Mask interrupts */ /* * Determine cause of interrupt. Receive events take * priority over Transmit. */ cs_value = LE_INB(sc, LEMAC_REG_CS); /* * Check for Receive Queue not being empty. * Check for Transmit Done Queue not being empty. */ if (cs_value & LEMAC_CS_RNE) lemac_rne_intr(sc); if (cs_value & LEMAC_CS_TNE) lemac_tne_intr(sc); /* * Check for Transmitter Disabled. * Check for Receiver Disabled. */ if (cs_value & LEMAC_CS_TXD) lemac_txd_intr(sc, cs_value); if (cs_value & LEMAC_CS_RXD) lemac_rxd_intr(sc, cs_value); /* * Toggle LED and unmask interrupts. */ LE_OUTB(sc, LEMAC_REG_CTL, LE_INB(sc, LEMAC_REG_CTL) ^ LEMAC_CTL_LED); LEMAC_INTR_ENABLE(sc); /* Unmask interrupts */ } static void lemac_rne_intr( le_softc_t *sc) { int rxcount, rxlen, rxpg; u_char *rxptr; lemac_rne_intrs++; rxcount = LE_INB(sc, LEMAC_REG_RQC); while (rxcount--) { rxpg = LE_INB(sc, LEMAC_REG_RQ); LE_OUTB(sc, LEMAC_REG_MPN, rxpg); rxptr = sc->le_membase; sc->le_if.if_ipackets++; if (*rxptr & LEMAC_RX_OK) { /* * Get receive length - subtract out checksum. */ rxlen = ((*(u_int *)rxptr >> 8) & 0x7FF) - 4; le_input(sc, rxptr + sizeof(u_int), rxlen, rxlen, NULL); } else { /* end if (*rxptr & LEMAC_RX_OK) */ sc->le_if.if_ierrors++; } LE_OUTB(sc, LEMAC_REG_FMQ, rxpg); /* Return this page to Free Memory Queue */ } /* end while (recv_count--) */ return; } static void lemac_rxd_intr( le_softc_t *sc, unsigned cs_value) { /* * Handle CS_RXD (Receiver disabled) here. * * Check Free Memory Queue Count. If not equal to zero * then just turn Receiver back on. If it is equal to * zero then check to see if transmitter is disabled. * Process transmit TXD loop once more. If all else * fails then do software init (0xC0 to EEPROM Init) * and rebuild Free Memory Queue. */ lemac_rxd_intrs++; /* * Re-enable Receiver. */ cs_value &= ~LEMAC_CS_RXD; LE_OUTB(sc, LEMAC_REG_CS, cs_value); if (LE_INB(sc, LEMAC_REG_FMC) > 0) return; if (cs_value & LEMAC_CS_TXD) lemac_txd_intr(sc, cs_value); if ((LE_INB(sc, LEMAC_REG_CS) & LEMAC_CS_RXD) == 0) return; printf("%s%d: fatal RXD error, attempting recovery\n", sc->le_if.if_name, sc->le_if.if_unit); LE_RESET(sc); if (sc->le_flags & IFF_UP) { lemac_init(sc->le_if.if_unit); return; } /* * Error during initializion. Mark card as disabled. */ printf("%s%d: recovery failed -- board disabled\n", sc->le_if.if_name, sc->le_if.if_unit); return; } static void lemac_start( struct ifnet *ifp) { le_softc_t *sc = (le_softc_t *) ifp; struct ifqueue *ifq = &ifp->if_snd; if ((ifp->if_flags & IFF_RUNNING) == 0) return; LEMAC_INTR_DISABLE(sc); while (ifq->ifq_head != NULL) { struct mbuf *m; int tx_pg; u_int txhdr, txoff; if (LE_INB(sc, LEMAC_REG_TQC) >= sc->lemac_txmax) { ifp->if_flags |= IFF_OACTIVE; break; } tx_pg = LE_INB(sc, LEMAC_REG_FMQ); /* get free memory page */ /* * Check for good transmit page. */ if (tx_pg == 0 || tx_pg > sc->lemac_lastpage) { lemac_txnospc++; ifp->if_flags |= IFF_OACTIVE; break; } IF_DEQUEUE(ifq, m); LE_OUTB(sc, LEMAC_REG_MPN, tx_pg); /* Shift 2K window. */ /* * The first four bytes of each transmit buffer are for * control information. The first byte is the control * byte, then the length (why not word aligned??), then * the off to the buffer. */ txoff = (mtod(m, u_int) & (sizeof(u_long) - 1)) + LEMAC_TX_HDRSZ; txhdr = sc->lemac_txctl | (m->m_pkthdr.len << 8) | (txoff << 24); *(u_int *) sc->le_membase = txhdr; /* * Copy the packet to the board */ m_copydata(m, 0, m->m_pkthdr.len, sc->le_membase + txoff); LE_OUTB(sc, LEMAC_REG_TQ, tx_pg); /* tell chip to transmit this packet */ #if NBPFILTER > 0 if (sc->le_bpf) bpf_mtap(sc->le_bpf, m); #endif m_freem(m); /* free the mbuf */ } LEMAC_INTR_ENABLE(sc); } static void lemac_tne_intr( le_softc_t *sc) { int txsts, txcount = LE_INB(sc, LEMAC_REG_TDC); lemac_tne_intrs++; while (txcount--) { txsts = LE_INB(sc, LEMAC_REG_TDQ); sc->le_if.if_opackets++; /* another one done */ if ((txsts & LEMAC_TDQ_COL) != LEMAC_TDQ_NOCOL) sc->le_if.if_collisions++; } sc->le_if.if_flags &= ~IFF_OACTIVE; lemac_start(&sc->le_if); } static void lemac_txd_intr( le_softc_t *sc, unsigned cs_value) { /* * Read transmit status, remove transmit buffer from * transmit queue and place on free memory queue, * then reset transmitter. * Increment appropriate counters. */ lemac_txd_intrs++; sc->le_if.if_oerrors++; if (LE_INB(sc, LEMAC_REG_TS) & LEMAC_TS_ECL) sc->le_if.if_collisions++; sc->le_if.if_flags &= ~IFF_OACTIVE; LE_OUTB(sc, LEMAC_REG_FMQ, LE_INB(sc, LEMAC_REG_TQ)); /* Get Page number and write it back out */ LE_OUTB(sc, LEMAC_REG_CS, cs_value & ~LEMAC_CS_TXD); /* Turn back on transmitter */ return; } static int lemac_read_eeprom( le_softc_t *sc) { int word_off, cksum; u_char *ep; cksum = 0; ep = sc->lemac_eeprom; for (word_off = 0; word_off < LEMAC_EEP_SIZE / 2; word_off++) { LE_OUTB(sc, LEMAC_REG_PI1, word_off); LE_OUTB(sc, LEMAC_REG_IOP, LEMAC_IOP_EEREAD); DELAY(LEMAC_EEP_DELAY); *ep = LE_INB(sc, LEMAC_REG_EE1); cksum += *ep++; *ep = LE_INB(sc, LEMAC_REG_EE2); cksum += *ep++; } /* * Set up Transmit Control Byte for use later during transmit. */ sc->lemac_txctl |= LEMAC_TX_FLAGS; if ((sc->lemac_eeprom[LEMAC_EEP_SWFLAGS] & LEMAC_EEP_SW_SQE) == 0) sc->lemac_txctl &= ~LEMAC_TX_SQE; if (sc->lemac_eeprom[LEMAC_EEP_SWFLAGS] & LEMAC_EEP_SW_LAB) sc->lemac_txctl |= LEMAC_TX_LAB; MEMCPY(sc->lemac_prodname, &sc->lemac_eeprom[LEMAC_EEP_PRDNM], LEMAC_EEP_PRDNMSZ); sc->lemac_prodname[LEMAC_EEP_PRDNMSZ] = '\0'; return cksum % 256; } static void lemac_init_adapmem( le_softc_t *sc) { int pg, conf; conf = LE_INB(sc, LEMAC_REG_CNF); if ((sc->lemac_eeprom[LEMAC_EEP_SETUP] & LEMAC_EEP_ST_DRAM) == 0) { sc->lemac_lastpage = 63; conf &= ~LEMAC_CNF_DRAM; } else { sc->lemac_lastpage = 127; conf |= LEMAC_CNF_DRAM; } LE_OUTB(sc, LEMAC_REG_CNF, conf); for (pg = 1; pg <= sc->lemac_lastpage; pg++) LE_OUTB(sc, LEMAC_REG_FMQ, pg); return; } #endif /* !defined(LE_NOLEMAC) */ #if !defined(LE_NOLANCE) /* * - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - * * Start of DEPCA (DE200/DE201/DE202/DE422 etal) support. * */ static void depca_intr(le_softc_t *sc); static int lance_init_adapmem(le_softc_t *sc); static int lance_init_ring(le_softc_t *sc, ln_ring_t *rp, lance_ring_t *ri, unsigned ndescs, unsigned bufoffset, unsigned descoffset); static void lance_init(int unit); static void lance_reset(IF_RESET_ARGS); static void lance_intr(le_softc_t *sc); static int lance_rx_intr(le_softc_t *sc); static void lance_start(struct ifnet *ifp); static int lance_tx_intr(le_softc_t *sc); #define LN_BUFSIZE /* 380 */ 304 /* 1520 / 4 */ #define LN_TXDESC_RATIO 2048 #define LN_DESC_MAX 128 #if LN_DOSTATS static struct { unsigned lance_rx_misses; unsigned lance_rx_badcrc; unsigned lance_rx_badalign; unsigned lance_rx_badframe; unsigned lance_rx_buferror; unsigned lance_tx_deferred; unsigned lance_tx_single_collisions; unsigned lance_tx_multiple_collisions; unsigned lance_tx_excessive_collisions; unsigned lance_tx_late_collisions; unsigned lance_memory_errors; unsigned lance_inits; unsigned lance_tx_intrs; unsigned lance_tx_nospc[2]; unsigned lance_tx_drains[2]; unsigned lance_tx_orphaned; unsigned lance_tx_adoptions; unsigned lance_tx_emptied; unsigned lance_tx_deftxint; unsigned lance_tx_buferror; unsigned lance_high_txoutptr; unsigned lance_low_txheapsize; unsigned lance_low_txfree; unsigned lance_tx_intr_hidescs; /* unsigned lance_tx_intr_descs[LN_DESC_MAX]; */ unsigned lance_rx_intrs; unsigned lance_rx_badsop; unsigned lance_rx_contig; unsigned lance_rx_noncontig; unsigned lance_rx_intr_hidescs; unsigned lance_rx_ndescs[4096 / LN_BUFSIZE]; /* unsigned lance_rx_intr_descs[LN_DESC_MAX]; */ } lance_stats; #define LN_STAT(stat) (lance_stats.lance_ ## stat) #define LN_MINSTAT(stat, val) (LN_STAT(stat > (val)) ? LN_STAT(stat = (val)) : 0) #define LN_MAXSTAT(stat, val) (LN_STAT(stat < (val)) ? LN_STAT(stat = (val)) : 0) #else #define LN_STAT(stat) 0 #define LN_MINSTAT(stat, val) 0 #define LN_MAXSTAT(stat, val) 0 #endif #define LN_SELCSR(sc, csrno) (LE_OUTW(sc, sc->lance_rap, csrno)) #define LN_INQCSR(sc) (LE_INW(sc, sc->lance_rap)) #define LN_WRCSR(sc, val) (LE_OUTW(sc, sc->lance_rdp, val)) #define LN_RDCSR(sc) (LE_INW(sc, sc->lance_rdp)) #define LN_ZERO(sc, vaddr, len) bzero(vaddr, len) #define LN_COPYTO(sc, from, to, len) bcopy(from, to, len) #define LN_SETFLAG(sc, vaddr, val) \ (((volatile u_char *) vaddr)[3] = (val)) #define LN_PUTDESC(sc, desc, vaddr) \ (((volatile u_short *) vaddr)[0] = ((u_short *) desc)[0], \ ((volatile u_short *) vaddr)[2] = ((u_short *) desc)[2], \ ((volatile u_short *) vaddr)[1] = ((u_short *) desc)[1]) /* * Only get the descriptor flags and length/status. All else * read-only. */ #define LN_GETDESC(sc, desc, vaddr) \ (((u_short *) desc)[1] = ((volatile u_short *) vaddr)[1], \ ((u_short *) desc)[3] = ((volatile u_short *) vaddr)[3]) /* * These definitions are specific to the DEC "DEPCA-style" NICs. * (DEPCA, DE10x, DE20[012], DE422) * */ #define DEPCA_REG_NICSR 0 /* (RW;16) NI Control / Status */ #define DEPCA_REG_RDP 4 /* (RW:16) LANCE RDP (data) register */ #define DEPCA_REG_RAP 6 /* (RW:16) LANCE RAP (address) register */ #define DEPCA_REG_ADDRROM 12 /* (R : 8) DEPCA Ethernet Address ROM */ #define DEPCA_IOSPACE 16 /* DEPCAs use 16 bytes of IO space */ #define DEPCA_NICSR_LED 0x0001 /* Light the LED on the back of the DEPCA */ #define DEPCA_NICSR_ENABINTR 0x0002 /* Enable Interrupts */ #define DEPCA_NICSR_MASKINTR 0x0004 /* Mask Interrupts */ #define DEPCA_NICSR_AAC 0x0008 /* Address Counter Clear */ #define DEPCA_NICSR_REMOTEBOOT 0x0010 /* Remote Boot Enabled (ignored) */ #define DEPCA_NICSR_32KRAM 0x0020 /* DEPCA LANCE RAM size 64K (C) / 32K (S) */ #define DEPCA_NICSR_LOW32K 0x0040 /* Bank Select (A15 = !This Bit) */ #define DEPCA_NICSR_SHE 0x0080 /* Shared RAM Enabled (ie hide ROM) */ #define DEPCA_NICSR_BOOTTMO 0x0100 /* Remote Boot Timeout (ignored) */ #define DEPCA_RDNICSR(sc) (LE_INW(sc, DEPCA_REG_NICSR)) #define DEPCA_WRNICSR(sc, val) (LE_OUTW(sc, DEPCA_REG_NICSR, val)) #define DEPCA_IDSTR_OFFSET 0xC006 /* ID String Offset */ #define DEPCA_REG_EISAID 0x80 #define DEPCA_EISAID_MASK 0xf0ffffff #define DEPCA_EISAID_DE422 0x2042A310 typedef enum { DEPCA_CLASSIC, DEPCA_DE100, DEPCA_DE101, DEPCA_EE100, DEPCA_DE200, DEPCA_DE201, DEPCA_DE202, DEPCA_DE422, DEPCA_UNKNOWN } depca_t; static const char *depca_signatures[] = { "DEPCA", "DE100", "DE101", "EE100", "DE200", "DE201", "DE202", "DE422", NULL }; static int depca_probe( le_softc_t *sc, const le_board_t *bd, int *msize) { unsigned nicsr, idx, idstr_offset = DEPCA_IDSTR_OFFSET; /* * Find out how memory we are dealing with. Adjust * the ID string offset approriately if we are at * 32K. Make sure the ROM is enabled. */ nicsr = DEPCA_RDNICSR(sc); nicsr &= ~(DEPCA_NICSR_SHE|DEPCA_NICSR_LED|DEPCA_NICSR_ENABINTR); if (nicsr & DEPCA_NICSR_32KRAM) { /* * Make we are going to read the upper * 32K so we do read the ROM. */ sc->lance_ramsize = 32 * 1024; nicsr &= ~DEPCA_NICSR_LOW32K; sc->lance_ramoffset = 32 * 1024; idstr_offset -= sc->lance_ramsize; } else { sc->lance_ramsize = 64 * 1024; sc->lance_ramoffset = 0; } DEPCA_WRNICSR(sc, nicsr); sc->le_prodname = NULL; for (idx = 0; depca_signatures[idx] != NULL; idx++) { if (bcmp(depca_signatures[idx], sc->le_membase + idstr_offset, 5) == 0) { sc->le_prodname = depca_signatures[idx]; break; } } if (sc->le_prodname == NULL) { /* * Try to get the EISA device if it's a DE422. */ if (sc->le_iobase > 0x1000 && (sc->le_iobase & 0x0F00) == 0x0C00 && (LE_INL(sc, DEPCA_REG_EISAID) & DEPCA_EISAID_MASK) == DEPCA_EISAID_DE422) { sc->le_prodname = "DE422"; } else { return 0; } } if (idx == DEPCA_CLASSIC) sc->lance_ramsize -= 16384; /* Can't use the ROM area on a DEPCA */ /* * Try to read the address ROM. * Stop the LANCE, reset the Address ROM Counter (AAC), * read the NICSR to "clock" in the reset, and then * re-enable the Address ROM Counter. Now read the * address ROM. */ sc->lance_rdp = DEPCA_REG_RDP; sc->lance_rap = DEPCA_REG_RAP; sc->lance_csr3 = LN_CSR3_ALE; sc->le_mctbl = sc->lance_initb.ln_multi_mask; sc->le_mcmask = LN_MC_MASK; LN_SELCSR(sc, LN_CSR0); LN_WRCSR(sc, LN_CSR0_STOP); if (idx < DEPCA_DE200) { DEPCA_WRNICSR(sc, DEPCA_RDNICSR(sc) & ~DEPCA_NICSR_AAC); DEPCA_WRNICSR(sc, DEPCA_RDNICSR(sc) | DEPCA_NICSR_AAC); } if (le_read_macaddr(sc, DEPCA_REG_ADDRROM, idx == DEPCA_CLASSIC) < 0) return 0; MEMCPY(sc->le_ac.ac_enaddr, sc->le_hwaddr, 6); /* * Renable shared RAM. */ DEPCA_WRNICSR(sc, DEPCA_RDNICSR(sc) | DEPCA_NICSR_SHE); le_intrvec[sc->le_if.if_unit] = depca_intr; if (!lance_init_adapmem(sc)) return 0; sc->if_reset = lance_reset; sc->if_init = lance_init; sc->le_if.if_start = lance_start; DEPCA_WRNICSR(sc, DEPCA_NICSR_SHE | DEPCA_NICSR_ENABINTR); LE_RESET(sc); LN_STAT(low_txfree = sc->lance_txinfo.ri_max); LN_STAT(low_txheapsize = 0xFFFFFFFF); *msize = sc->lance_ramsize; return DEPCA_IOSPACE; } static void depca_intr( le_softc_t *sc) { DEPCA_WRNICSR(sc, DEPCA_RDNICSR(sc) ^ DEPCA_NICSR_LED); lance_intr(sc); } /* * Here's as good a place to describe our paritioning of the * LANCE shared RAM space. (NOTE: this driver does not yet support * the concept of a LANCE being able to DMA). * * First is the 24 (00:23) bytes for LANCE Initialization Block * Next are the recieve descriptors. The number is calculated from * how many LN_BUFSIZE buffers we can allocate (this number must * be a power of 2). Next are the transmit descriptors. The amount * of transmit descriptors is derived from the size of the RAM * divided by 1K. Now come the receive buffers (one for each receive * descriptor). Finally is the transmit heap. (no fixed buffers are * allocated so as to make the most use of the limited space). */ static int lance_init_adapmem( le_softc_t *sc) { lance_addr_t rxbufoffset; lance_addr_t rxdescoffset, txdescoffset; unsigned rxdescs, txdescs; /* * First calculate how many descriptors we heap. * Note this assumes the ramsize is a power of two. */ sc->lance_rxbufsize = LN_BUFSIZE; rxdescs = 1; while (rxdescs * sc->lance_rxbufsize < sc->lance_ramsize) rxdescs *= 2; rxdescs /= 2; if (rxdescs > LN_DESC_MAX) { sc->lance_rxbufsize *= rxdescs / LN_DESC_MAX; rxdescs = LN_DESC_MAX; } txdescs = sc->lance_ramsize / LN_TXDESC_RATIO; if (txdescs > LN_DESC_MAX) txdescs = LN_DESC_MAX; /* * Now calculate where everything goes in memory */ rxdescoffset = sizeof(ln_initb_t); txdescoffset = rxdescoffset + sizeof(ln_desc_t) * rxdescs; rxbufoffset = txdescoffset + sizeof(ln_desc_t) * txdescs; sc->le_mctbl = (le_mcbits_t *) sc->lance_initb.ln_multi_mask; /* * Remember these for debugging. */ sc->lance_raminitb = (ln_initb_t *) sc->le_membase; sc->lance_ramdesc = (ln_desc_t *) (sc->le_membase + rxdescoffset); /* * Initialize the rings. */ if (!lance_init_ring(sc, &sc->lance_initb.ln_rxring, &sc->lance_rxinfo, rxdescs, rxbufoffset, rxdescoffset)) return 0; sc->lance_rxinfo.ri_heap = rxbufoffset; sc->lance_rxinfo.ri_heapend = rxbufoffset + sc->lance_rxbufsize * rxdescs; if (!lance_init_ring(sc, &sc->lance_initb.ln_txring, &sc->lance_txinfo, txdescs, 0, txdescoffset)) return 0; sc->lance_txinfo.ri_heap = sc->lance_rxinfo.ri_heapend; sc->lance_txinfo.ri_heapend = sc->lance_ramsize; /* * Set CSR1 and CSR2 to the address of the init block (which * for us is always 0. */ sc->lance_csr1 = LN_ADDR_LO(0 + sc->lance_ramoffset); sc->lance_csr2 = LN_ADDR_HI(0 + sc->lance_ramoffset); return 1; } static int lance_init_ring( le_softc_t *sc, ln_ring_t *rp, lance_ring_t *ri, unsigned ndescs, lance_addr_t bufoffset, lance_addr_t descoffset) { lance_descinfo_t *di; /* * Initialize the ring pointer in the LANCE InitBlock */ rp->r_addr_lo = LN_ADDR_LO(descoffset + sc->lance_ramoffset); rp->r_addr_hi = LN_ADDR_HI(descoffset + sc->lance_ramoffset); rp->r_log2_size = ffs(ndescs) - 1; /* * Allocate the ring entry descriptors and initialize * our ring information data structure. All these are * our copies and do not live in the LANCE RAM. */ ri->ri_first = (lance_descinfo_t *) malloc(ndescs * sizeof(*di), M_DEVBUF, M_NOWAIT); if (ri->ri_first == NULL) { printf("lance_init_ring: malloc(%d) failed\n", ndescs * sizeof(*di)); return 0; } ri->ri_free = ri->ri_max = ndescs; ri->ri_last = ri->ri_first + ri->ri_max; for (di = ri->ri_first; di < ri->ri_last; di++) { di->di_addr = sc->le_membase + descoffset; di->di_mbuf = NULL; if (bufoffset) { di->di_bufaddr = bufoffset; di->di_buflen = sc->lance_rxbufsize; bufoffset += sc->lance_rxbufsize; } descoffset += sizeof(ln_desc_t); } return 1; } static void lance_dumpcsrs( le_softc_t *sc, const char *id) { printf("%s%d: %s: nicsr=%04x", sc->le_if.if_name, sc->le_if.if_unit, id, DEPCA_RDNICSR(sc)); LN_SELCSR(sc, LN_CSR0); printf(" csr0=%04x", LN_RDCSR(sc)); LN_SELCSR(sc, LN_CSR1); printf(" csr1=%04x", LN_RDCSR(sc)); LN_SELCSR(sc, LN_CSR2); printf(" csr2=%04x", LN_RDCSR(sc)); LN_SELCSR(sc, LN_CSR3); printf(" csr3=%04x\n", LN_RDCSR(sc)); LN_SELCSR(sc, LN_CSR0); } static void lance_reset( IF_RESET_ARGS) { le_softc_t *sc = &le_softc[unit]; register int cnt, csr; /* lance_dumpcsrs(sc, "lance_reset: start"); */ LN_WRCSR(sc, LN_RDCSR(sc) & ~LN_CSR0_ENABINTR); LN_WRCSR(sc, LN_CSR0_STOP); DELAY(100); sc->le_flags &= ~IFF_UP; sc->le_if.if_flags &= ~(IFF_UP|IFF_RUNNING); le_multi_filter(sc); /* initialize the multicast table */ if ((sc->le_flags | sc->le_if.if_flags) & IFF_ALLMULTI) { sc->lance_initb.ln_multi_mask[0] = 0xFFFFU; sc->lance_initb.ln_multi_mask[1] = 0xFFFFU; sc->lance_initb.ln_multi_mask[2] = 0xFFFFU; sc->lance_initb.ln_multi_mask[3] = 0xFFFFU; } sc->lance_initb.ln_physaddr[0] = ((u_short *) sc->le_ac.ac_enaddr)[0]; sc->lance_initb.ln_physaddr[1] = ((u_short *) sc->le_ac.ac_enaddr)[1]; sc->lance_initb.ln_physaddr[2] = ((u_short *) sc->le_ac.ac_enaddr)[2]; if (sc->le_if.if_flags & IFF_PROMISC) { sc->lance_initb.ln_mode |= LN_MODE_PROMISC; } else { sc->lance_initb.ln_mode &= ~LN_MODE_PROMISC; } /* * We force the init block to be at the start * of the LANCE's RAM buffer. */ LN_COPYTO(sc, &sc->lance_initb, sc->le_membase, sizeof(sc->lance_initb)); LN_SELCSR(sc, LN_CSR1); LN_WRCSR(sc, sc->lance_csr1); LN_SELCSR(sc, LN_CSR2); LN_WRCSR(sc, sc->lance_csr2); LN_SELCSR(sc, LN_CSR3); LN_WRCSR(sc, sc->lance_csr3); /* lance_dumpcsrs(sc, "lance_reset: preinit"); */ /* * clear INITDONE and INIT the chip */ LN_SELCSR(sc, LN_CSR0); LN_WRCSR(sc, LN_CSR0_INIT|LN_CSR0_INITDONE); csr = 0; cnt = 100; while (cnt-- > 0) { if (((csr = LN_RDCSR(sc)) & LN_CSR0_INITDONE) != 0) break; DELAY(10000); } if ((csr & LN_CSR0_INITDONE) == 0) { /* make sure we got out okay */ lance_dumpcsrs(sc, "lance_reset: reset failure"); } else { /* lance_dumpcsrs(sc, "lance_reset: end"); */ sc->le_if.if_flags |= IFF_UP; sc->le_flags |= IFF_UP; } } static void lance_init( int unit) { le_softc_t *sc = &le_softc[unit]; lance_ring_t *ri; lance_descinfo_t *di; ln_desc_t desc; LN_STAT(inits++); if (sc->le_if.if_flags & IFF_RUNNING) { LE_RESET(sc); lance_tx_intr(sc); /* * If we were running, requeue any pending transmits. */ ri = &sc->lance_txinfo; di = ri->ri_nextout; while (ri->ri_free < ri->ri_max) { if (--di == ri->ri_first) di = ri->ri_nextout - 1; if (di->di_mbuf == NULL) break; IF_PREPEND(&sc->le_if.if_snd, di->di_mbuf); di->di_mbuf = NULL; ri->ri_free++; } } else { LE_RESET(sc); } /* * Reset the transmit ring. Make sure we own all the buffers. * Also reset the transmit heap. */ sc->le_if.if_flags &= ~IFF_OACTIVE; ri = &sc->lance_txinfo; for (di = ri->ri_first; di < ri->ri_last; di++) { if (di->di_mbuf != NULL) { m_freem(di->di_mbuf); di->di_mbuf = NULL; } desc.d_flag = 0; desc.d_addr_lo = LN_ADDR_LO(ri->ri_heap + sc->lance_ramoffset); desc.d_addr_hi = LN_ADDR_HI(ri->ri_heap + sc->lance_ramoffset); desc.d_buflen = 0; LN_PUTDESC(sc, &desc, di->di_addr); } ri->ri_nextin = ri->ri_nextout = ri->ri_first; ri->ri_free = ri->ri_max; ri->ri_outptr = ri->ri_heap; ri->ri_outsize = ri->ri_heapend - ri->ri_heap; ri = &sc->lance_rxinfo; desc.d_flag = LN_DFLAG_OWNER; desc.d_buflen = 0 - sc->lance_rxbufsize; for (di = ri->ri_first; di < ri->ri_last; di++) { desc.d_addr_lo = LN_ADDR_LO(di->di_bufaddr + sc->lance_ramoffset); desc.d_addr_hi = LN_ADDR_HI(di->di_bufaddr + sc->lance_ramoffset); LN_PUTDESC(sc, &desc, di->di_addr); } ri->ri_nextin = ri->ri_nextout = ri->ri_first; ri->ri_outptr = ri->ri_heap; ri->ri_outsize = ri->ri_heapend - ri->ri_heap; ri->ri_free = 0; if (sc->le_if.if_flags & IFF_UP) { sc->le_if.if_flags |= IFF_RUNNING; LN_WRCSR(sc, LN_CSR0_START|LN_CSR0_INITDONE|LN_CSR0_ENABINTR); /* lance_dumpcsrs(sc, "lance_init: up"); */ lance_start(&sc->le_if); } else { /* lance_dumpcsrs(sc, "lance_init: down"); */ sc->le_if.if_flags &= ~IFF_RUNNING; } } static void lance_intr( le_softc_t *sc) { unsigned oldcsr; oldcsr = LN_RDCSR(sc); oldcsr &= ~LN_CSR0_ENABINTR; LN_WRCSR(sc, oldcsr); LN_WRCSR(sc, LN_CSR0_ENABINTR); if (oldcsr & LN_CSR0_ERRSUM) { if (oldcsr & LN_CSR0_MISS) { /* * LN_CSR0_MISS is signaled when the LANCE receiver * loses a packet because it doesn't own a receive * descriptor. Rev. D LANCE chips, which are no * longer used, require a chip reset as described * below. */ LN_STAT(rx_misses++); } if (oldcsr & LN_CSR0_MEMERROR) { LN_STAT(memory_errors++); if (oldcsr & (LN_CSR0_RXON|LN_CSR0_TXON)) { lance_init(sc->le_if.if_unit); return; } } } if ((oldcsr & LN_CSR0_RXINT) && lance_rx_intr(sc)) { lance_init(sc->le_if.if_unit); return; } if (oldcsr & LN_CSR0_TXINT) { if (lance_tx_intr(sc)) lance_start(&sc->le_if); } if (oldcsr == (LN_CSR0_PENDINTR|LN_CSR0_RXON|LN_CSR0_TXON)) printf("%s%d: lance_intr: stray interrupt\n", sc->le_if.if_name, sc->le_if.if_unit); } static int lance_rx_intr( le_softc_t *sc) { lance_ring_t *ri = &sc->lance_rxinfo; lance_descinfo_t *eop; ln_desc_t desc; int ndescs, total_len, rxdescs; LN_STAT(rx_intrs++); for (rxdescs = 0;;) { /* * Now to try to find the end of this packet chain. */ for (ndescs = 1, eop = ri->ri_nextin;; ndescs++) { /* * If we don't own this descriptor, the packet ain't * all here so return because we are done. */ LN_GETDESC(sc, &desc, eop->di_addr); if (desc.d_flag & LN_DFLAG_OWNER) return 0; /* * In case we have missed a packet and gotten the * LANCE confused, make sure we are pointing at the * start of a packet. If we aren't, something is really * strange so reinit the LANCE. */ if (desc.d_flag & LN_DFLAG_RxBUFERROR) { LN_STAT(rx_buferror++); return 1; } if ((desc.d_flag & LN_DFLAG_SOP) && eop != ri->ri_nextin) { LN_STAT(rx_badsop++); return 1; } if (desc.d_flag & LN_DFLAG_EOP) break; if (++eop == ri->ri_last) eop = ri->ri_first; } total_len = (desc.d_status & LN_DSTS_RxLENMASK) - 4; if ((desc.d_flag & LN_DFLAG_RxERRSUM) == 0) { /* * Valid Packet -- If the SOP is less than or equal to the EOP * or the length is less than the receive buffer size, then the * packet is contiguous in memory and can be copied in one shot. * Otherwise we need to copy two segments to get the entire * packet. */ if (ri->ri_nextin <= eop || total_len <= ri->ri_heapend - ri->ri_nextin->di_bufaddr) { le_input(sc, sc->le_membase + ri->ri_nextin->di_bufaddr, total_len, total_len, NULL); LN_STAT(rx_contig++); } else { le_input(sc, sc->le_membase + ri->ri_nextin->di_bufaddr, total_len, ri->ri_heapend - ri->ri_nextin->di_bufaddr, sc->le_membase + ri->ri_first->di_bufaddr); LN_STAT(rx_noncontig++); } } else { /* * If the packet is bad, increment the * counters. */ sc->le_if.if_ierrors++; if (desc.d_flag & LN_DFLAG_RxBADCRC) LN_STAT(rx_badcrc++); if (desc.d_flag & LN_DFLAG_RxOVERFLOW) LN_STAT(rx_badalign++); if (desc.d_flag & LN_DFLAG_RxFRAMING) LN_STAT(rx_badframe++); } sc->le_if.if_ipackets++; LN_STAT(rx_ndescs[ndescs-1]++); rxdescs += ndescs; while (ndescs-- > 0) { LN_SETFLAG(sc, ri->ri_nextin->di_addr, LN_DFLAG_OWNER); if (++ri->ri_nextin == ri->ri_last) ri->ri_nextin = ri->ri_first; } } /* LN_STAT(rx_intr_descs[rxdescs]++); */ LN_MAXSTAT(rx_intr_hidescs, rxdescs); return 0; } static void lance_start( struct ifnet *ifp) { le_softc_t *sc = (le_softc_t *) ifp; struct ifqueue *ifq = &ifp->if_snd; lance_ring_t *ri = &sc->lance_txinfo; lance_descinfo_t *di; ln_desc_t desc; unsigned len, slop; struct mbuf *m, *m0; caddr_t bp; if ((ifp->if_flags & IFF_RUNNING) == 0) return; for (;;) { IF_DEQUEUE(ifq, m); if (m == NULL) break; /* * Make the packet meets the minimum size for Ethernet. * The slop is so that we also use an even number of longwards. */ len = ETHERMIN + sizeof(struct ether_header); if (m->m_pkthdr.len > len) len = m->m_pkthdr.len; slop = (8 - len) & 3; /* * If there are no free ring entries (there must be always * one owned by the host), or there's not enough space for * this packet, or this packet would wrap around the end * of LANCE RAM then wait for the transmits to empty for * space and ring entries to become available. */ if (ri->ri_free == 1 || len + slop > ri->ri_outsize) { /* * Try to see if we can free up anything off the transit ring. */ if (lance_tx_intr(sc) > 0) { LN_STAT(tx_drains[0]++); IF_PREPEND(ifq, m); continue; } LN_STAT(tx_nospc[0]++); break; } if (len + slop > ri->ri_heapend - ri->ri_outptr) { /* * Since the packet won't fit in the end of the transmit * heap, see if there is space at the beginning of the transmit * heap. If not, try again when there is space. */ LN_STAT(tx_orphaned++); slop += ri->ri_heapend - ri->ri_outptr; if (len + slop > ri->ri_outsize) { LN_STAT(tx_nospc[1]++); break; } /* * Point to the beginning of the heap */ ri->ri_outptr = ri->ri_heap; LN_STAT(tx_adoptions++); } /* * Initialize the descriptor (saving the buffer address, * buffer length, and mbuf) and write the packet out * to the board. */ di = ri->ri_nextout; di->di_bufaddr = ri->ri_outptr; di->di_buflen = len + slop; di->di_mbuf = m; bp = sc->le_membase + di->di_bufaddr; for (m0 = m; m0 != NULL; m0 = m0->m_next) { LN_COPYTO(sc, mtod(m0, caddr_t), bp, m0->m_len); bp += m0->m_len; } /* * Zero out the remainder if needed (< ETHERMIN). */ if (m->m_pkthdr.len < len) LN_ZERO(sc, bp, len - m->m_pkthdr.len); /* * Finally, copy out the descriptor and tell the * LANCE to transmit!. */ desc.d_buflen = 0 - len; desc.d_addr_lo = LN_ADDR_LO(di->di_bufaddr + sc->lance_ramoffset); desc.d_addr_hi = LN_ADDR_HI(di->di_bufaddr + sc->lance_ramoffset); desc.d_flag = LN_DFLAG_SOP|LN_DFLAG_EOP|LN_DFLAG_OWNER; LN_PUTDESC(sc, &desc, di->di_addr); LN_WRCSR(sc, LN_CSR0_TXDEMAND|LN_CSR0_ENABINTR); /* * Do our bookkeeping with our transmit heap. * (if we wrap, point back to the beginning). */ ri->ri_outptr += di->di_buflen; ri->ri_outsize -= di->di_buflen; LN_MAXSTAT(high_txoutptr, ri->ri_outptr); LN_MINSTAT(low_txheapsize, ri->ri_outsize); if (ri->ri_outptr == ri->ri_heapend) ri->ri_outptr = ri->ri_heap; ri->ri_free--; if (++ri->ri_nextout == ri->ri_last) ri->ri_nextout = ri->ri_first; LN_MINSTAT(low_txfree, ri->ri_free); } if (m != NULL) { ifp->if_flags |= IFF_OACTIVE; IF_PREPEND(ifq, m); } } static int lance_tx_intr( le_softc_t *sc) { lance_ring_t *ri = &sc->lance_txinfo; unsigned xmits; LN_STAT(tx_intrs++); for (xmits = 0; ri->ri_free < ri->ri_max; ) { ln_desc_t desc; LN_GETDESC(sc, &desc, ri->ri_nextin->di_addr); if (desc.d_flag & LN_DFLAG_OWNER) break; if (desc.d_flag & (LN_DFLAG_TxONECOLL|LN_DFLAG_TxMULTCOLL)) sc->le_if.if_collisions++; if (desc.d_flag & LN_DFLAG_TxDEFERRED) LN_STAT(tx_deferred++); if (desc.d_flag & LN_DFLAG_TxONECOLL) LN_STAT(tx_single_collisions++); if (desc.d_flag & LN_DFLAG_TxMULTCOLL) LN_STAT(tx_multiple_collisions++); if (desc.d_flag & LN_DFLAG_TxERRSUM) { if (desc.d_status & (LN_DSTS_TxUNDERFLOW|LN_DSTS_TxBUFERROR| LN_DSTS_TxEXCCOLL|LN_DSTS_TxLATECOLL)) { if (desc.d_status & LN_DSTS_TxEXCCOLL) { unsigned tdr; LN_STAT(tx_excessive_collisions++); if ((tdr = (desc.d_status & LN_DSTS_TxTDRMASK)) > 0) { tdr *= 100; printf("%s%d: lance: warning: excessive collisions: TDR %dns (%d-%dm)\n", sc->le_if.if_name, sc->le_if.if_unit, tdr, (tdr*99)/1000, (tdr*117)/1000); } } if (desc.d_status & LN_DSTS_TxBUFERROR) LN_STAT(tx_buferror++); sc->le_if.if_oerrors++; if ((desc.d_status & LN_DSTS_TxLATECOLL) == 0) { lance_init(sc->le_if.if_unit); return 0; } else { LN_STAT(tx_late_collisions++); } } } m_freem(ri->ri_nextin->di_mbuf); ri->ri_nextin->di_mbuf = NULL; sc->le_if.if_opackets++; ri->ri_free++; ri->ri_outsize += ri->ri_nextin->di_buflen; if (++ri->ri_nextin == ri->ri_last) ri->ri_nextin = ri->ri_first; sc->le_if.if_flags &= ~IFF_OACTIVE; xmits++; } if (ri->ri_free == ri->ri_max) LN_STAT(tx_emptied++); /* LN_STAT(tx_intr_descs[xmits]++); */ LN_MAXSTAT(tx_intr_hidescs, xmits); return xmits; } #endif /* !defined(LE_NOLANCE) */ #endif /* NLE > 0 */