/* * All Rights Reserved, Copyright (C) Fujitsu Limited 1995 * * This software may be used, modified, copied, distributed, and sold, in * both source and binary form provided that the above copyright, these * terms and the following disclaimer are retained. The name of the author * and/or the contributor may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND THE CONTRIBUTOR ``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 OR THE CONTRIBUTOR 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. */ /* * $FreeBSD$ * * Device driver for Fujitsu MB86960A/MB86965A based Ethernet cards. * To be used with FreeBSD 2.x * Contributed by M. Sekiguchi. * * This version is intended to be a generic template for various * MB86960A/MB86965A based Ethernet cards. It currently supports * Fujitsu FMV-180 series for ISA and Allied-Telesis AT1700/RE2000 * series for ISA, as well as Fujitsu MBH10302 PC card. * There are some currently- * unused hooks embedded, which are primarily intended to support * other types of Ethernet cards, but the author is not sure whether * they are useful. * * This version also includes some alignments for * RE1000/RE1000+/ME1500 support. It is incomplete, however, since the * cards are not for AT-compatibles. (They are for PC98 bus -- a * proprietary bus architecture available only in Japan.) Further * work for PC98 version will be available as a part of FreeBSD(98) * project. * * This software is a derivative work of if_ed.c version 1.56 by David * Greenman available as a part of FreeBSD 2.0 RELEASE source distribution. * * The following lines are retained from the original if_ed.c: * * Copyright (C) 1993, David Greenman. This software may be used, modified, * copied, distributed, and sold, in both source and binary form provided * that the above copyright and these terms are retained. Under no * circumstances is the author responsible for the proper functioning * of this software, nor does the author assume any responsibility * for damages incurred with its use. */ /* * Modified for Allied-Telesis RE1000 series. */ /* * TODO: * o To support MBH10304 PC card. It is another MB8696x based * PCMCIA Ethernet card by Fujitsu, which is not compatible with * MBH10302. * o To merge FreeBSD(98) efforts into a single source file. * o To support ISA PnP auto configuration for FMV-183/184. * o To reconsider mbuf usage. * o To reconsider transmission buffer usage, including * transmission buffer size (currently 4KB x 2) and pros-and- * cons of multiple frame transmission. * o To test IPX codes. */ #include "isa.h" #include "fe.h" #include "crd.h" #include "bpfilter.h" #include #include #include #include #include #include #include #include #include #include #include #ifdef INET #include #include #include #include #include #endif /* IPX code is not tested. FIXME. */ #ifdef IPX #include #include #endif /* To be used with IPv6 package of INRIA. */ #ifdef INET6 /* IPv6 added by shin 96.2.6 */ #include #endif /* XNS code is not tested. FIXME. */ #ifdef NS #include #include #endif #if NBPFILTER > 0 #include #include #endif #include #ifdef PC98 #include #else #include #endif #include #include /* PCCARD suport */ #if NCRD > 0 #include #include #include #include #endif #include #include /* * This version of fe is an ISA device driver. * Override the following macro to adapt it to another bus. * (E.g., PC98.) */ #define DEVICE struct isa_device /* * Default settings for fe driver specific options. * They can be set in config file by "options" statements. */ /* * Debug control. * 0: No debug at all. All debug specific codes are stripped off. * 1: Silent. No debug messages are logged except emergent ones. * 2: Brief. Lair events and/or important information are logged. * 3: Detailed. Logs all information which *may* be useful for debugging. * 4: Trace. All actions in the driver is logged. Super verbose. */ #ifndef FE_DEBUG #define FE_DEBUG 1 #endif /* * Transmit just one packet per a "send" command to 86960. * This option is intended for performance test. An EXPERIMENTAL option. */ #ifndef FE_SINGLE_TRANSMISSION #define FE_SINGLE_TRANSMISSION 0 #endif /* * Device configuration flags. */ /* DLCR6 settings. */ #define FE_FLAGS_DLCR6_VALUE 0x007F /* Force DLCR6 override. */ #define FE_FLAGS_OVERRIDE_DLCR6 0x0080 /* Shouldn't these be defined somewhere else such as isa_device.h? */ #define NO_IOADDR (-1) #define NO_IRQ 0 /* * Data type for a multicast address filter on 8696x. */ struct fe_filter { u_char data [ FE_FILTER_LEN ]; }; /* * Special filter values. */ static struct fe_filter const fe_filter_nothing = { FE_FILTER_NOTHING }; static struct fe_filter const fe_filter_all = { FE_FILTER_ALL }; /* How many registers does an fe-supported adapter have at maximum? */ #define MAXREGISTERS 32 /* * fe_softc: per line info and status */ static struct fe_softc { /* Used by "common" codes. */ struct arpcom arpcom; /* Ethernet common */ /* Used by config codes. */ /* Set by probe() and not modified in later phases. */ char * typestr; /* printable name of the interface. */ u_short iobase; /* base I/O address of the adapter. */ u_short ioaddr [ MAXREGISTERS ]; /* I/O addresses of register. */ u_short txb_size; /* size of TX buffer, in bytes */ u_char proto_dlcr4; /* DLCR4 prototype. */ u_char proto_dlcr5; /* DLCR5 prototype. */ u_char proto_dlcr6; /* DLCR6 prototype. */ u_char proto_dlcr7; /* DLCR7 prototype. */ u_char proto_bmpr13; /* BMPR13 prototype. */ /* Vendor specific hooks. */ void ( * init )( struct fe_softc * ); /* Just before fe_init(). */ void ( * stop )( struct fe_softc * ); /* Just after fe_stop(). */ /* Transmission buffer management. */ u_short txb_free; /* free bytes in TX buffer */ u_char txb_count; /* number of packets in TX buffer */ u_char txb_sched; /* number of scheduled packets */ /* Excessive collision counter (see fe_tint() for details. */ u_char tx_excolls; /* # of excessive collisions. */ /* Multicast address filter management. */ u_char filter_change; /* MARs must be changed ASAP. */ struct fe_filter filter;/* new filter value. */ } fe_softc[NFE]; #define sc_if arpcom.ac_if #define sc_unit arpcom.ac_if.if_unit #define sc_enaddr arpcom.ac_enaddr /* Standard driver entry points. These can be static. */ static int fe_probe ( struct isa_device * ); static int fe_attach ( struct isa_device * ); static void fe_init ( int ); static int fe_ioctl ( struct ifnet *, int, caddr_t ); static void fe_start ( struct ifnet * ); static void fe_reset ( int ); static void fe_watchdog ( struct ifnet * ); /* Local functions. Order of declaration is confused. FIXME. */ #ifdef PC98 static int fe_probe_re1000 ( DEVICE *, struct fe_softc * ); static int fe_probe_re1000p( DEVICE *, struct fe_softc * ); #else static int fe_probe_fmv ( DEVICE *, struct fe_softc * ); static int fe_probe_ati ( DEVICE *, struct fe_softc * ); static void fe_init_ati ( struct fe_softc * ); static int fe_probe_gwy ( DEVICE *, struct fe_softc * ); #if NCRD > 0 static int fe_probe_mbh ( DEVICE *, struct fe_softc * ); static void fe_init_mbh ( struct fe_softc * ); static int fe_probe_tdk ( DEVICE *, struct fe_softc * ); #endif #endif static int fe_get_packet ( struct fe_softc *, u_short ); static void fe_stop ( int ); static void fe_tint ( struct fe_softc *, u_char ); static void fe_rint ( struct fe_softc *, u_char ); static void fe_xmit ( struct fe_softc * ); static void fe_emptybuffer ( struct fe_softc * ); static void fe_write_mbufs ( struct fe_softc *, struct mbuf * ); static struct fe_filter fe_mcaf ( struct fe_softc * ); static int fe_hash ( u_char * ); static void fe_setmode ( struct fe_softc * ); static void fe_loadmar ( struct fe_softc * ); #if FE_DEBUG >= 1 static void fe_dump ( int, struct fe_softc *, char * ); #endif /* Driver struct used in the config code. This must be public (external.) */ struct isa_driver fedriver = { fe_probe, fe_attach, "fe", 1 /* It's safe to mark as "sensitive" */ }; /* * Fe driver specific constants which relate to 86960/86965. */ /* Interrupt masks */ #define FE_TMASK ( FE_D2_COLL16 | FE_D2_TXDONE ) #define FE_RMASK ( FE_D3_OVRFLO | FE_D3_CRCERR \ | FE_D3_ALGERR | FE_D3_SRTPKT | FE_D3_PKTRDY ) /* Maximum number of iterations for a receive interrupt. */ #define FE_MAX_RECV_COUNT ( ( 65536 - 2048 * 2 ) / 64 ) /* * Maximum size of SRAM is 65536, * minimum size of transmission buffer in fe is 2x2KB, * and minimum amount of received packet including headers * added by the chip is 64 bytes. * Hence FE_MAX_RECV_COUNT is the upper limit for number * of packets in the receive buffer. */ /* * Routines to access contiguous I/O ports. */ static void inblk ( struct fe_softc * sc, int offs, u_char * mem, int len ) { while ( --len >= 0 ) { *mem++ = inb( sc->ioaddr[ offs++ ] ); } } static void outblk ( struct fe_softc * sc, int offs, u_char const * mem, int len ) { while ( --len >= 0 ) { outb( sc->ioaddr[ offs++ ], *mem++ ); } } /* PCCARD Support */ #if NCRD > 0 /* * PC-Card (PCMCIA) specific code. */ static int fe_card_intr(struct pccard_dev *); /* Interrupt handler */ static void feunload(struct pccard_dev *); /* Disable driver */ static void fesuspend(struct pccard_dev *); /* Suspend driver */ static int feinit(struct pccard_dev *, int); /* init device */ static struct pccard_drv fe_info = { "fe", fe_card_intr, feunload, fesuspend, feinit, 0, /* Attributes - presently unused */ &net_imask /* Interrupt mask for device */ /* XXX - Should this also include net_imask? */ }; /* * Called when a power down is requested. Shuts down the * device and configures the device as unavailable (but * still loaded...). A resume is done by calling * feinit with first=0. This is called when the user suspends * the system, or the APM code suspends the system. */ static void fesuspend(struct pccard_dev *dp) { printf("fe%d: suspending\n", dp->isahd.id_unit); } /* * Initialize the device - called from Slot manager. * if first is set, then initially check for * the device's existence before initializing it. * Once initialized, the device table may be set up. */ static int feinit(struct pccard_dev *dp, int first) { /* validate unit number. */ struct fe_softc *sc; if (first) { if (dp->isahd.id_unit >= NFE) return (ENODEV); /* * Probe the device. If a value is returned, * the device was found at the location. */ #if FE_DEBUG >= 2 printf("Start Probe\n"); #endif sc = &fe_softc[dp->isahd.id_unit]; memcpy( sc->sc_enaddr, dp->misc, ETHER_ADDR_LEN ); if (fe_probe(&dp->isahd) == 0) return (ENXIO); #if FE_DEBUG >= 2 printf("Start attach\n"); #endif if (fe_attach(&dp->isahd) == 0) return (ENXIO); } /* * XXX TODO: * If it was initialized before, the device structure * should also be initialized. We should * reset (and possibly restart) the hardware, but * I am not sure of the best way to do this... */ return (0); } /* * feunload - unload the driver and clear the table. * XXX TODO: * This is usually called when the card is ejected, but * can be caused by a modunload of a controller driver. * The idea is to reset the driver's view of the device * and ensure that any driver entry points such as * read and write do not hang. */ static void feunload(struct pccard_dev *dp) { struct fe_softc *sc = &fe_softc[dp->isahd.id_unit]; printf("fe%d: unload\n", dp->isahd.id_unit); fe_stop(dp->isahd.id_unit); } /* * fe_card_intr - Shared interrupt called from * front end of PC-Card handler. */ static int fe_card_intr(struct pccard_dev *dp) { feintr(dp->isahd.id_unit); return (1); } #endif /* NCRD > 0 */ /* * Hardware probe routines. */ /* How and where to probe; to support automatic I/O address detection. */ struct fe_probe_list { int ( * probe ) ( DEVICE *, struct fe_softc * ); u_short const * addresses; }; /* Lists of possible addresses. */ #ifdef PC98 static u_short const fe_re1000_addr [] = { 0x0D0, 0x0D2, 0x0D4, 0x0D6, 0x0D8, 0x0DA, 0x0DC, 0x0DE, 0x1D0, 0x1D2, 0x1D4, 0x1D6, 0x1D8, 0x1DA, 0x1DC, 0x1DE, 0 }; static u_short const fe_re1000p_addr [] = { 0x0D0, 0x0D2, 0x0D4, 0x0D8, 0x1D4, 0x1D6, 0x1D8, 0x1DA, 0 }; #else static u_short const fe_fmv_addr [] = { 0x220, 0x240, 0x260, 0x280, 0x2A0, 0x2C0, 0x300, 0x340, 0 }; static u_short const fe_ati_addr [] = { 0x240, 0x260, 0x280, 0x2A0, 0x300, 0x320, 0x340, 0x380, 0 }; #endif static struct fe_probe_list const fe_probe_list [] = { #ifdef PC98 { fe_probe_re1000, fe_re1000_addr }, { fe_probe_re1000p, fe_re1000p_addr }, #else { fe_probe_fmv, fe_fmv_addr }, { fe_probe_ati, fe_ati_addr }, #if NCRD > 0 { fe_probe_mbh, NULL }, /* PCMCIAs cannot be auto-detected. */ { fe_probe_tdk, NULL }, #endif #endif { NULL, NULL } }; /* * Determine if the device is present * * on entry: * a pointer to an isa_device struct * on exit: * zero if device not found * or number of i/o addresses used (if found) */ static int fe_probe ( DEVICE * dev ) { #if NCRD > 0 static int fe_already_init; #endif struct fe_softc * sc; int u; int nports; struct fe_probe_list const * list; u_short const * addr; u_short single [ 2 ]; /* Initialize "minimum" parts of our softc. */ sc = &fe_softc[ dev->id_unit ]; sc->sc_unit = dev->id_unit; #if NCRD > 0 /* * If PC-Card probe required, then register driver with * slot manager. */ if (fe_already_init != 1) { pccard_add_driver(&fe_info); fe_already_init = 1; } #endif /* NCRD > 0 */ /* Probe each possibility, one at a time. */ for ( list = fe_probe_list; list->probe != NULL; list++ ) { if ( dev->id_iobase != NO_IOADDR ) { /* Probe one specific address. */ single[ 0 ] = dev->id_iobase; single[ 1 ] = 0; addr = single; } else if ( list->addresses != NULL ) { /* Auto detect. */ addr = list->addresses; } else { /* We need a list of addresses to do auto detect. */ continue; } /* Probe all possible addresses for the board. */ while ( *addr != 0 ) { /* See if the address is already in use. */ for ( u = 0; u < NFE; u++ ) { if ( fe_softc[u].iobase == *addr ) break; } #if FE_DEBUG >= 3 if ( u == NFE ) { log( LOG_INFO, "fe%d: probing %d at 0x%x\n", sc->sc_unit, list - fe_probe_list, *addr ); } else if ( u == sc->sc_unit ) { log( LOG_INFO, "fe%d: re-probing %d at 0x%x?\n", sc->sc_unit, list - fe_probe_list, *addr ); } else { log( LOG_INFO, "fe%d: skipping %d at 0x%x\n", sc->sc_unit, list - fe_probe_list, *addr ); } #endif /* Probe the address if it is free. */ if ( u == NFE || u == sc->sc_unit ) { /* Probe an address. */ sc->iobase = *addr; nports = list->probe( dev, sc ); if ( nports > 0 ) { /* Found. */ dev->id_iobase = *addr; return ( nports ); } sc->iobase = 0; } /* Try next. */ addr++; } } /* Probe failed. */ return ( 0 ); } /* * Check for specific bits in specific registers have specific values. */ struct fe_simple_probe_struct { u_char port; /* Offset from the base I/O address. */ u_char mask; /* Bits to be checked. */ u_char bits; /* Values to be compared against. */ }; static int fe_simple_probe ( struct fe_softc const * sc, struct fe_simple_probe_struct const * sp ) { struct fe_simple_probe_struct const * p; for ( p = sp; p->mask != 0; p++ ) { #if FE_DEBUG >=2 printf("Probe Port:%x,Value:%x,Mask:%x.Bits:%x\n", p->port,inb(sc->ioaddr[ p->port]),p->mask,p->bits); #endif if ( ( inb( sc->ioaddr[ p->port ] ) & p->mask ) != p->bits ) { return ( 0 ); } } return ( 1 ); } /* * Routines to read all bytes from the config EEPROM through MB86965A. * I'm not sure what exactly I'm doing here... I was told just to follow * the steps, and it worked. Could someone tell me why the following * code works? (Or, why all similar codes I tried previously doesn't * work.) FIXME. */ static void fe_strobe_eeprom ( u_short bmpr16 ) { /* * We must guarantee 800ns (or more) interval to access slow * EEPROMs. The following redundant code provides enough * delay with ISA timing. (Even if the bus clock is "tuned.") * Some modification will be needed on faster busses. */ outb( bmpr16, FE_B16_SELECT ); outb( bmpr16, FE_B16_SELECT ); outb( bmpr16, FE_B16_SELECT | FE_B16_CLOCK ); outb( bmpr16, FE_B16_SELECT | FE_B16_CLOCK ); outb( bmpr16, FE_B16_SELECT ); outb( bmpr16, FE_B16_SELECT ); } static void fe_read_eeprom ( struct fe_softc * sc, u_char * data ) { u_short bmpr16 = sc->ioaddr[ FE_BMPR16 ]; u_short bmpr17 = sc->ioaddr[ FE_BMPR17 ]; u_char n, val, bit; /* Read bytes from EEPROM; two bytes per an iteration. */ for ( n = 0; n < FE_EEPROM_SIZE / 2; n++ ) { /* Reset the EEPROM interface. */ outb( bmpr16, 0x00 ); outb( bmpr17, 0x00 ); /* Start EEPROM access. */ outb( bmpr16, FE_B16_SELECT ); outb( bmpr17, FE_B17_DATA ); fe_strobe_eeprom( bmpr16 ); /* Pass the iteration count to the chip. */ val = 0x80 | n; for ( bit = 0x80; bit != 0x00; bit >>= 1 ) { outb( bmpr17, ( val & bit ) ? FE_B17_DATA : 0 ); fe_strobe_eeprom( bmpr16 ); } outb( bmpr17, 0x00 ); /* Read a byte. */ val = 0; for ( bit = 0x80; bit != 0x00; bit >>= 1 ) { fe_strobe_eeprom( bmpr16 ); if ( inb( bmpr17 ) & FE_B17_DATA ) { val |= bit; } } *data++ = val; /* Read one more byte. */ val = 0; for ( bit = 0x80; bit != 0x00; bit >>= 1 ) { fe_strobe_eeprom( bmpr16 ); if ( inb( bmpr17 ) & FE_B17_DATA ) { val |= bit; } } *data++ = val; } /* Reset the EEPROM interface, again. */ outb( bmpr16, 0x00 ); outb( bmpr17, 0x00 ); #if FE_DEBUG >= 3 /* Report what we got. */ data -= FE_EEPROM_SIZE; log( LOG_INFO, "fe%d: EEPROM:" " %02x%02x%02x%02x %02x%02x%02x%02x -" " %02x%02x%02x%02x %02x%02x%02x%02x -" " %02x%02x%02x%02x %02x%02x%02x%02x -" " %02x%02x%02x%02x %02x%02x%02x%02x\n", sc->sc_unit, data[ 0], data[ 1], data[ 2], data[ 3], data[ 4], data[ 5], data[ 6], data[ 7], data[ 8], data[ 9], data[10], data[11], data[12], data[13], data[14], data[15], data[16], data[17], data[18], data[19], data[20], data[21], data[22], data[23], data[24], data[25], data[26], data[27], data[28], data[29], data[30], data[31] ); #endif } /* * Hardware (vendor) specific probe routines. */ #ifdef PC98 /* * Probe and initialization for Allied-Telesis RE1000 series. */ static int fe_probe_re1000 ( DEVICE * isa_dev, struct fe_softc * sc ) { int i, n; int dlcr6, dlcr7; u_char c = 0; static u_short const irqmap [ 4 ] = { IRQ3, IRQ5, IRQ6, IRQ12 }; #if FE_DEBUG >= 3 log( LOG_INFO, "fe%d: probe (0x%x) for RE1000\n", sc->sc_unit, sc->iobase ); fe_dump( LOG_INFO, sc, NULL ); #endif /* Setup an I/O address mapping table. */ for ( i = 0; i < MAXREGISTERS; i++ ) { sc->ioaddr[ i ] = sc->iobase + (i/2)*0x200 + (i%2); } /* * RE1000 does not use 86965 EEPROM interface. */ c ^= sc->sc_enaddr[0] = inb(sc->ioaddr[FE_RE1000_MAC0]); c ^= sc->sc_enaddr[1] = inb(sc->ioaddr[FE_RE1000_MAC1]); c ^= sc->sc_enaddr[2] = inb(sc->ioaddr[FE_RE1000_MAC2]); c ^= sc->sc_enaddr[3] = inb(sc->ioaddr[FE_RE1000_MAC3]); c ^= sc->sc_enaddr[4] = inb(sc->ioaddr[FE_RE1000_MAC4]); c ^= sc->sc_enaddr[5] = inb(sc->ioaddr[FE_RE1000_MAC5]); c ^= inb(sc->ioaddr[FE_RE1000_MACCHK]); if (c != 0) return 0; if ( sc->sc_enaddr[ 0 ] != 0x00 || sc->sc_enaddr[ 1 ] != 0x00 || sc->sc_enaddr[ 2 ] != 0xF4 ) return 0; /* * check interrupt configure */ for (n=0; n<4; n++) { if (isa_dev->id_irq == irqmap[n]) break; } if (n == 4) return 0; /* * set irq */ c = inb(sc->ioaddr[FE_RE1000_IRQCONF]); c &= (~ FE_RE1000_IRQCONF_IRQ); c |= (1 << (n + FE_RE1000_IRQCONF_IRQSHIFT)); outb(sc->ioaddr[FE_RE1000_IRQCONF], c); sc->typestr = "RE1000"; /* * Program the 86965 as follows: * SRAM: 32KB, 100ns, byte-wide access. * Transmission buffer: 4KB x 2. * System bus interface: 16 bits. */ sc->proto_dlcr4 = FE_D4_LBC_DISABLE | FE_D4_CNTRL; /* FIXME */ sc->proto_dlcr5 = 0; sc->proto_dlcr6 = FE_D6_BUFSIZ_32KB | FE_D6_TXBSIZ_2x4KB | FE_D6_BBW_BYTE | FE_D6_SBW_WORD | FE_D6_SRAM_100ns; sc->proto_dlcr7 = FE_D7_BYTSWP_LH | FE_D7_IDENT_EC; sc->proto_bmpr13 = FE_B13_TPTYPE_UTP | FE_B13_PORT_AUTO; #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "RE1000 found" ); #endif /* Initialize 86965. */ outb( sc->ioaddr[FE_DLCR6], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY(200); /* Disable all interrupts. */ outb( sc->ioaddr[FE_DLCR2], 0 ); outb( sc->ioaddr[FE_DLCR3], 0 ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "end of fe_probe_re1000()" ); #endif /* * That's all. RE1000 occupies 2*16 I/O addresses, by the way. */ return 2; /* ??? */ } /* * Probe and initialization for Allied-Telesis RE1000Plus/ME1500 series. */ static int fe_probe_re1000p ( DEVICE * isa_dev, struct fe_softc * sc ) { int i, n, signature; int dlcr6, dlcr7; u_char eeprom [ FE_EEPROM_SIZE ]; static u_short const irqmap [ 4 ] = { IRQ3, IRQ5, IRQ6, IRQ12 }; static struct fe_simple_probe_struct const probe_signature1 [] = { { FE_DLCR0, 0xBF, 0x00 }, { FE_DLCR2, 0xFF, 0x00 }, { FE_DLCR4, 0x0F, 0x06 }, { FE_DLCR6, 0x0F, 0x06 }, { 0 } }; static struct fe_simple_probe_struct const probe_signature2 [] = { { FE_DLCR1, 0xFF, 0x00 }, { FE_DLCR3, 0xFF, 0x00 }, { FE_DLCR5, 0xFF, 0x41 }, { 0 } }; static struct fe_simple_probe_struct const probe_table [] = { { FE_DLCR2, 0x71, 0x00 }, { FE_DLCR4, 0x08, 0x00 }, { FE_DLCR5, 0x80, 0x00 }, { 0 } }; static struct fe_simple_probe_struct const vendor_code [] = { { FE_DLCR8, 0xFF, 0x00 }, { FE_DLCR9, 0xFF, 0x00 }, { FE_DLCR10, 0xFF, 0xF4 }, { 0 } }; #if FE_DEBUG >= 3 log( LOG_INFO, "fe%d: probe (0x%x) for RE1000Plus/ME1500\n", sc->sc_unit, sc->iobase ); fe_dump( LOG_INFO, sc, NULL ); #endif /* Setup an I/O address mapping table. */ for ( i = 0; i < 16; i++ ) { sc->ioaddr[ i ] = sc->iobase + (i/2)*0x200 + (i%2); } for ( i = 16; i < MAXREGISTERS; i++ ) { sc->ioaddr[ i ] = sc->iobase + i*0x200 - 0x1000; } /* First, check the "signature" */ signature = 0; if (fe_simple_probe(sc, probe_signature1)) { outb(sc->ioaddr[FE_DLCR6], (inb(sc->ioaddr[FE_DLCR6]) & 0xCF) | 0x16); if (fe_simple_probe(sc, probe_signature2)) signature = 1; } /* * If the "signature" not detected, 86965 *might* be previously * initialized. So, check the Ethernet address here. * * Allied-Telesis uses 00 00 F4 ?? ?? ??. */ if (signature == 0) { /* Simple check */ if (!fe_simple_probe(sc, probe_table)) return 0; /* Disable DLC */ dlcr6 = inb(sc->ioaddr[FE_DLCR6]); outb(sc->ioaddr[FE_DLCR6], dlcr6 | FE_D6_DLC_DISABLE); /* Select register bank for DLCR */ dlcr7 = inb(sc->ioaddr[FE_DLCR7]); outb(sc->ioaddr[FE_DLCR7], dlcr7 & 0xF3 | FE_D7_RBS_DLCR); /* Check the Ethernet address */ if (!fe_simple_probe(sc, vendor_code)) return 0; /* Restore configuration registers */ DELAY(200); outb(sc->ioaddr[FE_DLCR6], dlcr6); outb(sc->ioaddr[FE_DLCR7], dlcr7); } /* * We are now almost sure we have an 86965 at the given * address. So, read EEPROM through 86965. We have to write * into LSI registers to read from EEPROM. I want to avoid it * at this stage, but I cannot test the presense of the chip * any further without reading EEPROM. FIXME. */ fe_read_eeprom( sc, eeprom ); /* Make sure that config info in EEPROM and 86965 agree. */ if ( eeprom[ FE_EEPROM_CONF ] != inb( sc->ioaddr[FE_BMPR19] ) ) { return 0; } /* * Initialize constants in the per-line structure. */ /* Get our station address from EEPROM. */ bcopy( eeprom + FE_ATI_EEP_ADDR, sc->sc_enaddr, ETHER_ADDR_LEN ); sc->typestr = "RE1000Plus/ME1500"; /* * Read IRQ configuration. */ n = (inb(sc->ioaddr[FE_BMPR19]) & FE_B19_IRQ ) >> FE_B19_IRQ_SHIFT; isa_dev->id_irq = irqmap[n]; /* * Program the 86965 as follows: * SRAM: 32KB, 100ns, byte-wide access. * Transmission buffer: 4KB x 2. * System bus interface: 16 bits. */ sc->proto_dlcr4 = FE_D4_LBC_DISABLE | FE_D4_CNTRL; /* FIXME */ sc->proto_dlcr5 = 0; sc->proto_dlcr6 = FE_D6_BUFSIZ_32KB | FE_D6_TXBSIZ_2x4KB | FE_D6_BBW_BYTE | FE_D6_SBW_WORD | FE_D6_SRAM_100ns; sc->proto_dlcr7 = FE_D7_BYTSWP_LH | FE_D7_IDENT_EC; sc->proto_bmpr13 = FE_B13_TPTYPE_UTP | FE_B13_PORT_AUTO; #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "RE1000Plus/ME1500 found" ); #endif /* Initialize 86965. */ outb( sc->ioaddr[FE_DLCR6], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY(200); /* Disable all interrupts. */ outb( sc->ioaddr[FE_DLCR2], 0 ); outb( sc->ioaddr[FE_DLCR3], 0 ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "end of fe_probe_re1000p()" ); #endif /* * That's all. RE1000Plus/ME1500 occupies 2*16 I/O addresses, by the way. */ return 2; /* ??? */ } #else /* * Probe and initialization for Fujitsu FMV-180 series boards */ static int fe_probe_fmv ( DEVICE * dev, struct fe_softc * sc ) { int i, n; static u_short const baseaddr [ 8 ] = { 0x220, 0x240, 0x260, 0x280, 0x2A0, 0x2C0, 0x300, 0x340 }; static u_short const irqmap [ 4 ] = { IRQ3, IRQ7, IRQ10, IRQ15 }; static struct fe_simple_probe_struct const probe_table [] = { { FE_DLCR2, 0x70, 0x00 }, { FE_DLCR4, 0x08, 0x00 }, /* { FE_DLCR5, 0x80, 0x00 }, Doesn't work. */ { FE_FMV0, 0x78, 0x50 }, /* ERRDY+PRRDY */ { FE_FMV1, 0xB0, 0x00 }, /* FMV-183/184 has 0x48 bits. */ { FE_FMV3, 0x7F, 0x00 }, #if 1 /* * Test *vendor* part of the station address for Fujitsu. * The test will gain reliability of probe process, but * it rejects FMV-180 clone boards manufactured by other vendors. * We have to turn the test off when such cards are made available. */ { FE_FMV4, 0xFF, 0x00 }, { FE_FMV5, 0xFF, 0x00 }, { FE_FMV6, 0xFF, 0x0E }, #else /* * We can always verify the *first* 2 bits (in Ethernet * bit order) are "no multicast" and "no local" even for * unknown vendors. */ { FE_FMV4, 0x03, 0x00 }, #endif { 0 } }; /* "Hardware revision ID" */ int revision; /* * See if the specified address is possible for FMV-180 series. */ for ( i = 0; i < 8; i++ ) { if ( baseaddr[ i ] == sc->iobase ) break; } if ( i == 8 ) return 0; /* Setup an I/O address mapping table. */ for ( i = 0; i < MAXREGISTERS; i++ ) { sc->ioaddr[ i ] = sc->iobase + i; } /* Simple probe. */ if ( !fe_simple_probe( sc, probe_table ) ) return 0; /* Check if our I/O address matches config info. on EEPROM. */ n = ( inb( sc->ioaddr[ FE_FMV2 ] ) & FE_FMV2_IOS ) >> FE_FMV2_IOS_SHIFT; if ( baseaddr[ n ] != sc->iobase ) { #if 0 /* May not work on some revisions of the cards... FIXME. */ return 0; #else /* Just log the fact and see what happens... FIXME. */ log( LOG_WARNING, "fe%d: strange I/O config?n", sc->sc_unit ); #endif } /* Find the "hardware revision." */ revision = inb( sc->ioaddr[ FE_FMV1 ] ) & FE_FMV1_REV; /* Determine the card type. */ sc->typestr = NULL; switch ( inb( sc->ioaddr[ FE_FMV0 ] ) & FE_FMV0_MEDIA ) { case 0: /* No interface? This doesn't seem to be an FMV-180... */ return 0; case FE_FMV0_MEDIUM_T: switch ( revision ) { case 8: sc->typestr = "FMV-183"; break; case 12: sc->typestr = "FMV-183 (on-board)"; break; } break; case FE_FMV0_MEDIUM_T | FE_FMV0_MEDIUM_5: switch ( revision ) { case 0: sc->typestr = "FMV-181"; break; case 1: sc->typestr = "FMV-181A"; break; } break; case FE_FMV0_MEDIUM_2: switch ( revision ) { case 8: sc->typestr = "FMV-184 (CSR = 2)"; break; } break; case FE_FMV0_MEDIUM_5: switch ( revision ) { case 8: sc->typestr = "FMV-184 (CSR = 1)"; break; } break; case FE_FMV0_MEDIUM_2 | FE_FMV0_MEDIUM_5: switch ( revision ) { case 0: sc->typestr = "FMV-182"; break; case 1: sc->typestr = "FMV-182A"; break; case 8: sc->typestr = "FMV-184 (CSR = 3)"; break; } break; } if ( sc->typestr == NULL ) { /* Unknown card type... Hope the driver works. */ sc->typestr = "unknown FMV-180 version"; log( LOG_WARNING, "fe%d: %s: %x-%x-%x-%x\n", sc->sc_unit, sc->typestr, inb( sc->ioaddr[ FE_FMV0 ] ), inb( sc->ioaddr[ FE_FMV1 ] ), inb( sc->ioaddr[ FE_FMV2 ] ), inb( sc->ioaddr[ FE_FMV3 ] ) ); } /* * An FMV-180 has been proved. * Determine which IRQ to be used. * * In this version, we give a priority to the kernel config file. * If the EEPROM and config don't match, say it to the user for * an attention. */ n = ( inb( sc->ioaddr[ FE_FMV2 ] ) & FE_FMV2_IRS ) >> FE_FMV2_IRS_SHIFT; if ( dev->id_irq == NO_IRQ ) { /* Just use the probed value. */ dev->id_irq = irqmap[ n ]; } else if ( dev->id_irq != irqmap[ n ] ) { /* Don't match. */ log( LOG_WARNING, "fe%d: check IRQ in config; it may be incorrect", sc->sc_unit ); } /* * Initialize constants in the per-line structure. */ /* Get our station address from EEPROM. */ inblk( sc, FE_FMV4, sc->sc_enaddr, ETHER_ADDR_LEN ); /* Make sure we got a valid station address. */ if ( ( sc->sc_enaddr[ 0 ] & 0x03 ) != 0x00 || ( sc->sc_enaddr[ 0 ] == 0x00 && sc->sc_enaddr[ 1 ] == 0x00 && sc->sc_enaddr[ 2 ] == 0x00 ) ) return 0; /* * Register values which (may) depend on board design. * * Program the 86960 as follows: * SRAM: 32KB, 100ns, byte-wide access. * Transmission buffer: 4KB x 2. * System bus interface: 16 bits. */ sc->proto_dlcr4 = FE_D4_LBC_DISABLE | FE_D4_CNTRL; sc->proto_dlcr5 = 0; sc->proto_dlcr6 = FE_D6_BUFSIZ_32KB | FE_D6_TXBSIZ_2x4KB | FE_D6_BBW_BYTE | FE_D6_SBW_WORD | FE_D6_SRAM_100ns; sc->proto_dlcr7 = FE_D7_BYTSWP_LH | FE_D7_IDENT_EC; sc->proto_bmpr13 = FE_B13_TPTYPE_UTP | FE_B13_PORT_AUTO; /* * Minimum initialization of the hardware. * We write into registers; hope I/O ports have no * overlap with other boards. */ /* Initialize ASIC. */ outb( sc->ioaddr[ FE_FMV3 ], 0 ); outb( sc->ioaddr[ FE_FMV10 ], 0 ); /* Initialize 86960. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Disable all interrupts. */ outb( sc->ioaddr[ FE_DLCR2 ], 0 ); outb( sc->ioaddr[ FE_DLCR3 ], 0 ); /* "Refresh" hardware configuration. FIXME. */ outb( sc->ioaddr[ FE_FMV2 ], inb( sc->ioaddr[ FE_FMV2 ] ) ); /* Turn the "master interrupt control" flag of ASIC on. */ outb( sc->ioaddr[ FE_FMV3 ], FE_FMV3_IRQENB ); /* * That's all. FMV-180 occupies 32 I/O addresses, by the way. */ return 32; } /* * Probe and initialization for Allied-Telesis AT1700/RE2000 series. */ static int fe_probe_ati ( DEVICE * dev, struct fe_softc * sc ) { int i, n; u_char eeprom [ FE_EEPROM_SIZE ]; u_char save16, save17; static u_short const baseaddr [ 8 ] = { 0x260, 0x280, 0x2A0, 0x240, 0x340, 0x320, 0x380, 0x300 }; static u_short const irqmaps [ 4 ][ 4 ] = { { IRQ3, IRQ4, IRQ5, IRQ9 }, { IRQ10, IRQ11, IRQ12, IRQ15 }, { IRQ3, IRQ11, IRQ5, IRQ15 }, { IRQ10, IRQ11, IRQ14, IRQ15 }, }; static struct fe_simple_probe_struct const probe_table [] = { { FE_DLCR2, 0x70, 0x00 }, { FE_DLCR4, 0x08, 0x00 }, { FE_DLCR5, 0x80, 0x00 }, #if 0 { FE_BMPR16, 0x1B, 0x00 }, { FE_BMPR17, 0x7F, 0x00 }, #endif { 0 } }; /* Assume we have 86965 and no need to restore these. */ save16 = 0; save17 = 0; #if FE_DEBUG >= 3 log( LOG_INFO, "fe%d: probe (0x%x) for ATI\n", sc->sc_unit, sc->iobase ); fe_dump( LOG_INFO, sc, NULL ); #endif /* * See if the specified address is possible for MB86965A JLI mode. */ for ( i = 0; i < 8; i++ ) { if ( baseaddr[ i ] == sc->iobase ) break; } if ( i == 8 ) goto NOTFOUND; /* Setup an I/O address mapping table. */ for ( i = 0; i < MAXREGISTERS; i++ ) { sc->ioaddr[ i ] = sc->iobase + i; } /* * We should test if MB86965A is on the base address now. * Unfortunately, it is very hard to probe it reliably, since * we have no way to reset the chip under software control. * On cold boot, we could check the "signature" bit patterns * described in the Fujitsu document. On warm boot, however, * we can predict almost nothing about register values. */ if ( !fe_simple_probe( sc, probe_table ) ) goto NOTFOUND; /* Check if our I/O address matches config info on 86965. */ n = ( inb( sc->ioaddr[ FE_BMPR19 ] ) & FE_B19_ADDR ) >> FE_B19_ADDR_SHIFT; if ( baseaddr[ n ] != sc->iobase ) goto NOTFOUND; /* * We are now almost sure we have an AT1700 at the given * address. So, read EEPROM through 86965. We have to write * into LSI registers to read from EEPROM. I want to avoid it * at this stage, but I cannot test the presence of the chip * any further without reading EEPROM. FIXME. */ save16 = inb( sc->ioaddr[ FE_BMPR16 ] ); save17 = inb( sc->ioaddr[ FE_BMPR17 ] ); fe_read_eeprom( sc, eeprom ); /* Make sure the EEPROM is turned off. */ outb( sc->ioaddr[ FE_BMPR16 ], 0 ); outb( sc->ioaddr[ FE_BMPR17 ], 0 ); /* Make sure that config info in EEPROM and 86965 agree. */ if ( eeprom[ FE_EEPROM_CONF ] != inb( sc->ioaddr[ FE_BMPR19 ] ) ) { goto NOTFOUND; } /* * The following model identification codes are stolen from * from the NetBSD port of the fe driver. My reviewers * suggested minor revision. */ /* Determine the card type. */ switch (eeprom[FE_ATI_EEP_MODEL]) { case FE_ATI_MODEL_AT1700T: sc->typestr = "AT-1700T/RE2001"; break; case FE_ATI_MODEL_AT1700BT: sc->typestr = "AT-1700BT/RE2003"; break; case FE_ATI_MODEL_AT1700FT: sc->typestr = "AT-1700FT/RE2009"; break; case FE_ATI_MODEL_AT1700AT: sc->typestr = "AT-1700AT/RE2005"; break; default: sc->typestr = "unknown AT-1700/RE2000 ?"; break; } /* * Try to determine IRQ settings. * Different models use different ranges of IRQs. */ if ( dev->id_irq == NO_IRQ ) { n = ( inb( sc->ioaddr[ FE_BMPR19 ] ) & FE_B19_IRQ ) >> FE_B19_IRQ_SHIFT; switch ( eeprom[ FE_ATI_EEP_REVISION ] & 0xf0 ) { case 0x30: dev->id_irq = irqmaps[ 3 ][ n ]; break; case 0x10: case 0x50: dev->id_irq = irqmaps[ 2 ][ n ]; break; case 0x40: case 0x60: if ( eeprom[ FE_ATI_EEP_MAGIC ] & 0x04 ) { dev->id_irq = irqmaps[ 1 ][ n ]; } else { dev->id_irq = irqmaps[ 0 ][ n ]; } break; default: dev->id_irq = irqmaps[ 0 ][ n ]; break; } } /* * Initialize constants in the per-line structure. */ /* Get our station address from EEPROM. */ bcopy( eeprom + FE_ATI_EEP_ADDR, sc->sc_enaddr, ETHER_ADDR_LEN ); #if 1 /* * This test doesn't work well for AT1700 look-alike by * other vendors. */ /* Make sure the vendor part is for Allied-Telesis. */ if ( sc->sc_enaddr[ 0 ] != 0x00 || sc->sc_enaddr[ 1 ] != 0x00 || sc->sc_enaddr[ 2 ] != 0xF4 ) return 0; #else /* Make sure we got a valid station address. */ if ( ( sc->sc_enaddr[ 0 ] & 0x03 ) != 0x00 || ( sc->sc_enaddr[ 0 ] == 0x00 && sc->sc_enaddr[ 1 ] == 0x00 && sc->sc_enaddr[ 2 ] == 0x00 ) ) return 0; #endif /* * Program the 86960 as follows: * SRAM: 32KB, 100ns, byte-wide access. * Transmission buffer: 4KB x 2. * System bus interface: 16 bits. */ sc->proto_dlcr4 = FE_D4_LBC_DISABLE | FE_D4_CNTRL; /* FIXME */ sc->proto_dlcr5 = 0; sc->proto_dlcr6 = FE_D6_BUFSIZ_32KB | FE_D6_TXBSIZ_2x4KB | FE_D6_BBW_BYTE | FE_D6_SBW_WORD | FE_D6_SRAM_100ns; sc->proto_dlcr7 = FE_D7_BYTSWP_LH | FE_D7_IDENT_EC; #if 0 /* XXXX Should we use this? FIXME. */ sc->proto_bmpr13 = eeprom[ FE_ATI_EEP_MEDIA ]; #else sc->proto_bmpr13 = FE_B13_TPTYPE_UTP | FE_B13_PORT_AUTO; #endif #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "ATI found" ); #endif /* Setup hooks. This may solves a nasty bug. FIXME. */ sc->init = fe_init_ati; /* Initialize 86965. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Disable all interrupts. */ outb( sc->ioaddr[ FE_DLCR2 ], 0 ); outb( sc->ioaddr[ FE_DLCR3 ], 0 ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "end of fe_probe_ati()" ); #endif /* * That's all. AT1700 occupies 32 I/O addresses, by the way. */ return 32; NOTFOUND: /* * We have no AT1700 at a given address. * Restore BMPR16 and BMPR17 if we have destroyed them, * hoping that the hardware on the address didn't get * bad side effect. */ if ( save16 != 0 | save17 != 0 ) { outb( sc->ioaddr[ FE_BMPR16 ], save16 ); outb( sc->ioaddr[ FE_BMPR17 ], save17 ); } return ( 0 ); } /* ATI specific initialization routine. */ static void fe_init_ati ( struct fe_softc * sc ) { /* * I've told that the following operation "Resets" the chip. * Hope this solve a bug which hangs up the driver under * heavy load... FIXME. */ /* Minimal initialization of 86965. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* "Reset" by wrting into an undocument register location. */ outb( sc->ioaddr[ 0x1F ], 0 ); /* How long do we have to wait after the reset? FIXME. */ DELAY( 300 ); } /* * Probe and initialization for Gateway Communications' old cards. */ static int fe_probe_gwy ( DEVICE * dev, struct fe_softc * sc ) { int i,type; static struct fe_simple_probe_struct probe_table [] = { { FE_DLCR2, 0x70, 0x00 }, { FE_DLCR4, 0x08, 0x00 }, { FE_DLCR7, 0xC0, 0x00 }, /* * Test *vendor* part of the address for Gateway. * This test is essential to identify Gateway's cards. * We shuld define some symbolic names for the * following offsets. FIXME. */ { 0x18, 0xFF, 0x00 }, { 0x19, 0xFF, 0x00 }, { 0x1A, 0xFF, 0x61 }, { 0 } }; /* * We need explicit IRQ and supported address. * I'm not sure which address and IRQ is possible for Gateway * Ethernet family. The following accepts everything. FIXME. */ if ( dev->id_irq == NO_IRQ || ( sc->iobase & ~0x3E0 ) != 0 ) { return ( 0 ); } #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "top of probe" ); #endif /* Setup an I/O address mapping table. */ for ( i = 0; i < MAXREGISTERS; i++ ) { sc->ioaddr[ i ] = sc->iobase + i; } /* See if the card is on its address. */ if ( !fe_simple_probe( sc, probe_table ) ) { return 0; } /* Determine the card type. */ sc->typestr = "Gateway Ethernet w/ Fujitsu chipset"; /* Get our station address from EEPROM. */ inblk( sc, 0x18, sc->sc_enaddr, ETHER_ADDR_LEN ); /* * Program the 86960 as follows: * SRAM: 16KB, 100ns, byte-wide access. * Transmission buffer: 2KB x 2. * System bus interface: 16 bits. * Make sure to clear out ID bits in DLCR7 * (They actually are Encoder/Decoder control in NICE.) */ sc->proto_dlcr4 = FE_D4_LBC_DISABLE | FE_D4_CNTRL; sc->proto_dlcr5 = 0; sc->proto_dlcr6 = FE_D6_BUFSIZ_16KB | FE_D6_TXBSIZ_2x2KB | FE_D6_BBW_BYTE | FE_D6_SBW_WORD | FE_D6_SRAM_100ns; sc->proto_dlcr7 = FE_D7_BYTSWP_LH; sc->proto_bmpr13 = 0; /* Minimal initialization of 86960. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Disable all interrupts. */ outb( sc->ioaddr[ FE_DLCR2 ], 0 ); outb( sc->ioaddr[ FE_DLCR3 ], 0 ); /* That's all. The card occupies 32 I/O addresses, as always. */ return 32; } #if NCRD > 0 /* * Probe and initialization for Fujitsu MBH10302 PCMCIA Ethernet interface. * Note that this is for 10302 only; MBH10304 is handled by fe_probe_tdk(). */ static int fe_probe_mbh ( DEVICE * dev, struct fe_softc * sc ) { int i,type; static struct fe_simple_probe_struct probe_table [] = { { FE_DLCR0, 0x09, 0x00 }, { FE_DLCR2, 0x79, 0x00 }, { FE_DLCR4, 0x08, 0x00 }, { FE_DLCR6, 0xFF, 0xB6 }, /* * The following location has the first byte of the card's * Ethernet (MAC) address. * We can always verify the *first* 2 bits (in Ethernet * bit order) are "global" and "unicast" for any vendors'. */ { FE_MBH10, 0x03, 0x00 }, /* Just a gap? Seems reliable, anyway. */ { 0x12, 0xFF, 0x00 }, { 0x13, 0xFF, 0x00 }, { 0x14, 0xFF, 0x00 }, { 0x15, 0xFF, 0x00 }, { 0x16, 0xFF, 0x00 }, { 0x17, 0xFF, 0x00 }, #if 0 { 0x18, 0xFF, 0xFF }, { 0x19, 0xFF, 0xFF }, #endif { 0 } }; /* * We need explicit IRQ and supported address. */ if ( dev->id_irq == NO_IRQ || ( sc->iobase & ~0x3E0 ) != 0 ) { return ( 0 ); } #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "top of probe" ); #endif /* Setup an I/O address mapping table. */ for ( i = 0; i < MAXREGISTERS; i++ ) { sc->ioaddr[ i ] = sc->iobase + i; } /* * See if MBH10302 is on its address. * I'm not sure the following probe code works. FIXME. */ if ( !fe_simple_probe( sc, probe_table ) ) return 0; /* Determine the card type. */ sc->typestr = "MBH10302 (PCMCIA)"; /* * Initialize constants in the per-line structure. */ /* Get our station address from EEPROM. */ inblk( sc, FE_MBH10, sc->sc_enaddr, ETHER_ADDR_LEN ); /* Make sure we got a valid station address. */ if ( sc->sc_enaddr[ 0 ] == 0x00 && sc->sc_enaddr[ 1 ] == 0x00 && sc->sc_enaddr[ 2 ] == 0x00 ) return 0; /* * Program the 86960 as follows: * SRAM: 32KB, 100ns, byte-wide access. * Transmission buffer: 4KB x 2. * System bus interface: 16 bits. */ sc->proto_dlcr4 = FE_D4_LBC_DISABLE | FE_D4_CNTRL; sc->proto_dlcr5 = 0; sc->proto_dlcr6 = FE_D6_BUFSIZ_32KB | FE_D6_TXBSIZ_2x4KB | FE_D6_BBW_BYTE | FE_D6_SBW_WORD | FE_D6_SRAM_100ns; sc->proto_dlcr7 = FE_D7_BYTSWP_LH | FE_D7_IDENT_NICE; sc->proto_bmpr13 = FE_B13_TPTYPE_UTP | FE_B13_PORT_AUTO; /* Setup hooks. We need a special initialization procedure. */ sc->init = fe_init_mbh; /* * Minimum initialization. */ /* Minimal initialization of 86960. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Disable all interrupts. */ outb( sc->ioaddr[ FE_DLCR2 ], 0 ); outb( sc->ioaddr[ FE_DLCR3 ], 0 ); #if 1 /* FIXME. */ /* Initialize system bus interface and encoder/decoder operation. */ outb( sc->ioaddr[ FE_MBH0 ], FE_MBH0_MAGIC | FE_MBH0_INTR_DISABLE ); #endif /* * That's all. MBH10302 occupies 32 I/O addresses, by the way. */ return 32; } /* MBH specific initialization routine. */ static void fe_init_mbh ( struct fe_softc * sc ) { /* Minimal initialization of 86960. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Disable all interrupts. */ outb( sc->ioaddr[ FE_DLCR2 ], 0 ); outb( sc->ioaddr[ FE_DLCR3 ], 0 ); /* Enable master interrupt flag. */ outb( sc->ioaddr[ FE_MBH0 ], FE_MBH0_MAGIC | FE_MBH0_INTR_ENABLE ); } #endif /* PC98 */ #endif /* NCRD > 0 */ #if NCRD > 0 /* * Probe and initialization for TDK/CONTEC PCMCIA Ethernet interface. * by MASUI Kenji * * (Contec uses TDK Ethenet chip -- hosokawa) * * This version of fe_probe_tdk has been rewrote to handle * *generic* PC card implementation of Fujitsu MB8696x family. The * name _tdk is just for a historical reason. :-) */ static int fe_probe_tdk ( DEVICE * dev, struct fe_softc * sc ) { int i; static struct fe_simple_probe_struct probe_table [] = { { FE_DLCR2, 0x70, 0x00 }, { FE_DLCR4, 0x08, 0x00 }, /* { FE_DLCR5, 0x80, 0x00 }, Does not work well. */ { 0 } }; if ( dev->id_irq == NO_IRQ ) { return ( 0 ); } /* Setup an I/O address mapping table. */ for ( i = 0; i < MAXREGISTERS; i++ ) { sc->ioaddr[ i ] = sc->iobase + i; } /* * See if C-NET(PC)C is on its address. */ if ( !fe_simple_probe( sc, probe_table ) ) return 0; /* Determine the card type. */ sc->typestr = "Generic MB8696x Ethernet (PCMCIA)"; /* * Initialize constants in the per-line structure. */ /* The station address *must*be* already in sc_enaddr; Make sure we got a valid station address. */ if ( ( sc->sc_enaddr[ 0 ] & 0x03 ) != 0x00 || ( sc->sc_enaddr[ 0 ] == 0x00 && sc->sc_enaddr[ 1 ] == 0x00 && sc->sc_enaddr[ 2 ] == 0x00 ) ) return 0; /* * Program the 86965 as follows: * SRAM: 32KB, 100ns, byte-wide access. * Transmission buffer: 4KB x 2. * System bus interface: 16 bits. * XXX: Should we remove IDENT_NICE from DLCR7? Or, * even add IDENT_EC instead? FIXME. */ sc->proto_dlcr4 = FE_D4_LBC_DISABLE | FE_D4_CNTRL; sc->proto_dlcr5 = 0; sc->proto_dlcr6 = FE_D6_BUFSIZ_32KB | FE_D6_TXBSIZ_2x4KB | FE_D6_BBW_BYTE | FE_D6_SBW_WORD | FE_D6_SRAM_100ns; sc->proto_dlcr7 = FE_D7_BYTSWP_LH | FE_D7_IDENT_NICE; sc->proto_bmpr13 = FE_B13_TPTYPE_UTP | FE_B13_PORT_AUTO; /* Minimul initialization of 86960. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Disable all interrupts. */ outb( sc->ioaddr[ FE_DLCR2 ], 0 ); outb( sc->ioaddr[ FE_DLCR3 ], 0 ); /* * That's all. C-NET(PC)C occupies 16 I/O addresses. * XXX: Are there any card with 32 I/O addresses? FIXME. */ return 16; } #endif /* * Install interface into kernel networking data structures */ static int fe_attach ( DEVICE * dev ) { #if NCRD > 0 static int already_ifattach[NFE]; #endif struct fe_softc *sc = &fe_softc[dev->id_unit]; /* * Initialize ifnet structure */ sc->sc_if.if_softc = sc; sc->sc_if.if_unit = sc->sc_unit; sc->sc_if.if_name = "fe"; sc->sc_if.if_output = ether_output; sc->sc_if.if_start = fe_start; sc->sc_if.if_ioctl = fe_ioctl; sc->sc_if.if_watchdog = fe_watchdog; /* * Set default interface flags. */ sc->sc_if.if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST; /* * Set maximum size of output queue, if it has not been set. * It is done here as this driver may be started after the * system initialization (i.e., the interface is PCMCIA.) * * I'm not sure this is really necessary, but, even if it is, * it should be done somewhere else, e.g., in if_attach(), * since it must be a common workaround for all network drivers. * FIXME. */ if ( sc->sc_if.if_snd.ifq_maxlen == 0 ) { sc->sc_if.if_snd.ifq_maxlen = ifqmaxlen; } #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "attach()" ); #endif #if FE_SINGLE_TRANSMISSION /* Override txb config to allocate minimum. */ sc->proto_dlcr6 &= ~FE_D6_TXBSIZ sc->proto_dlcr6 |= FE_D6_TXBSIZ_2x2KB; #endif /* Modify hardware config if it is requested. */ if ( dev->id_flags & FE_FLAGS_OVERRIDE_DLCR6 ) { sc->proto_dlcr6 = dev->id_flags & FE_FLAGS_DLCR6_VALUE; } /* Find TX buffer size, based on the hardware dependent proto. */ switch ( sc->proto_dlcr6 & FE_D6_TXBSIZ ) { case FE_D6_TXBSIZ_2x2KB: sc->txb_size = 2048; break; case FE_D6_TXBSIZ_2x4KB: sc->txb_size = 4096; break; case FE_D6_TXBSIZ_2x8KB: sc->txb_size = 8192; break; default: /* Oops, we can't work with single buffer configuration. */ #if FE_DEBUG >= 2 log( LOG_WARNING, "fe%d: strange TXBSIZ config; fixing\n", sc->sc_unit ); #endif sc->proto_dlcr6 &= ~FE_D6_TXBSIZ; sc->proto_dlcr6 |= FE_D6_TXBSIZ_2x2KB; sc->txb_size = 2048; break; } /* Attach and stop the interface. */ #if NCRD > 0 if (already_ifattach[dev->id_unit] != 1) { if_attach(&sc->sc_if); already_ifattach[dev->id_unit] = 1; } #else if_attach(&sc->sc_if); #endif /* NCRD > 0 */ fe_stop(sc->sc_unit); /* This changes the state to IDLE. */ ether_ifattach(&sc->sc_if); /* Print additional info when attached. */ printf( "fe%d: address %6D, type %s\n", sc->sc_unit, sc->sc_enaddr, ":" , sc->typestr ); #if FE_DEBUG >= 3 { int buf, txb, bbw, sbw, ram; buf = txb = bbw = sbw = ram = -1; switch ( sc->proto_dlcr6 & FE_D6_BUFSIZ ) { case FE_D6_BUFSIZ_8KB: buf = 8; break; case FE_D6_BUFSIZ_16KB: buf = 16; break; case FE_D6_BUFSIZ_32KB: buf = 32; break; case FE_D6_BUFSIZ_64KB: buf = 64; break; } switch ( sc->proto_dlcr6 & FE_D6_TXBSIZ ) { case FE_D6_TXBSIZ_2x2KB: txb = 2; break; case FE_D6_TXBSIZ_2x4KB: txb = 4; break; case FE_D6_TXBSIZ_2x8KB: txb = 8; break; } switch ( sc->proto_dlcr6 & FE_D6_BBW ) { case FE_D6_BBW_BYTE: bbw = 8; break; case FE_D6_BBW_WORD: bbw = 16; break; } switch ( sc->proto_dlcr6 & FE_D6_SBW ) { case FE_D6_SBW_BYTE: sbw = 8; break; case FE_D6_SBW_WORD: sbw = 16; break; } switch ( sc->proto_dlcr6 & FE_D6_SRAM ) { case FE_D6_SRAM_100ns: ram = 100; break; case FE_D6_SRAM_150ns: ram = 150; break; } printf( "fe%d: SRAM %dKB %dbit %dns, TXB %dKBx2, %dbit I/O\n", sc->sc_unit, buf, bbw, ram, txb, sbw ); } #endif #if NBPFILTER > 0 /* If BPF is in the kernel, call the attach for it. */ bpfattach( &sc->sc_if, DLT_EN10MB, sizeof(struct ether_header)); #endif return 1; } /* * Reset interface. */ static void fe_reset ( int unit ) { /* * Stop interface and re-initialize. */ fe_stop(unit); fe_init(unit); } /* * Stop everything on the interface. * * All buffered packets, both transmitting and receiving, * if any, will be lost by stopping the interface. */ static void fe_stop ( int unit ) { struct fe_softc *sc = &fe_softc[unit]; int s; s = splimp(); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "stop()" ); #endif /* Disable interrupts. */ outb( sc->ioaddr[ FE_DLCR2 ], 0x00 ); outb( sc->ioaddr[ FE_DLCR3 ], 0x00 ); /* Stop interface hardware. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Clear all interrupt status. */ outb( sc->ioaddr[ FE_DLCR0 ], 0xFF ); outb( sc->ioaddr[ FE_DLCR1 ], 0xFF ); /* Put the chip in stand-by mode. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR7 ], sc->proto_dlcr7 | FE_D7_POWER_DOWN ); DELAY( 200 ); /* Reset transmitter variables and interface flags. */ sc->sc_if.if_flags &= ~( IFF_OACTIVE | IFF_RUNNING ); sc->sc_if.if_timer = 0; sc->txb_free = sc->txb_size; sc->txb_count = 0; sc->txb_sched = 0; /* MAR loading can be delayed. */ sc->filter_change = 0; /* Update config status also. */ /* Call a hook. */ if ( sc->stop ) sc->stop( sc ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "end of stop()" ); #endif (void) splx(s); } /* * Device timeout/watchdog routine. Entered if the device neglects to * generate an interrupt after a transmit has been started on it. */ static void fe_watchdog ( struct ifnet *ifp ) { struct fe_softc *sc = (struct fe_softc *)ifp; #if FE_DEBUG >= 1 /* A "debug" message. */ log( LOG_ERR, "fe%d: transmission timeout (%d+%d)%s\n", ifp->if_unit, sc->txb_sched, sc->txb_count, ( ifp->if_flags & IFF_UP ) ? "" : " when down" ); if ( sc->sc_if.if_opackets == 0 && sc->sc_if.if_ipackets == 0 ) { log( LOG_WARNING, "fe%d: wrong IRQ setting in config?\n", ifp->if_unit ); } #endif #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, NULL ); #endif /* Record how many packets are lost by this accident. */ ifp->if_oerrors += sc->txb_sched + sc->txb_count; /* Put the interface into known initial state. */ if ( ifp->if_flags & IFF_UP ) { fe_reset( ifp->if_unit ); } else { fe_stop( ifp->if_unit ); } } /* * Initialize device. */ static void fe_init ( int unit ) { struct fe_softc *sc = &fe_softc[unit]; int i, s; #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "init()" ); #endif /* We need an address. */ if (TAILQ_EMPTY(&sc->sc_if.if_addrhead)) { /* XXX unlikely */ #if FE_DEBUG >= 1 log( LOG_ERR, "fe%d: init() without any address\n", sc->sc_unit ); #endif return; } #if FE_DEBUG >= 1 /* * Make sure we have a valid station address. * The following test is applicable for any Ethernet interfaces. * It can be done in somewhere common to all of them. FIXME. */ if ( ( sc->sc_enaddr[ 0 ] & 0x01 ) != 0 || ( sc->sc_enaddr[ 0 ] == 0x00 && sc->sc_enaddr[ 1 ] == 0x00 && sc->sc_enaddr[ 2 ] == 0x00 ) ) { log( LOG_ERR, "fe%d: invalid station address (%6D)\n", sc->sc_unit, sc->sc_enaddr, ":" ); return; } #endif /* Start initializing 86960. */ s = splimp(); /* Call a hook. */ if ( sc->init ) sc->init( sc ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "after init hook" ); #endif /* * Make sure to disable the chip, also. * This may also help re-programming the chip after * hot insertion of PCMCIAs. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Power up the chip and select register bank for DLCRs. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR7 ], sc->proto_dlcr7 | FE_D7_RBS_DLCR | FE_D7_POWER_UP ); DELAY( 200 ); /* Feed the station address. */ outblk( sc, FE_DLCR8, sc->sc_enaddr, ETHER_ADDR_LEN ); /* Clear multicast address filter to receive nothing. */ outb( sc->ioaddr[ FE_DLCR7 ], sc->proto_dlcr7 | FE_D7_RBS_MAR | FE_D7_POWER_UP ); outblk( sc, FE_MAR8, fe_filter_nothing.data, FE_FILTER_LEN ); /* Select the BMPR bank for runtime register access. */ outb( sc->ioaddr[ FE_DLCR7 ], sc->proto_dlcr7 | FE_D7_RBS_BMPR | FE_D7_POWER_UP ); /* Initialize registers. */ outb( sc->ioaddr[ FE_DLCR0 ], 0xFF ); /* Clear all bits. */ outb( sc->ioaddr[ FE_DLCR1 ], 0xFF ); /* ditto. */ outb( sc->ioaddr[ FE_DLCR2 ], 0x00 ); outb( sc->ioaddr[ FE_DLCR3 ], 0x00 ); outb( sc->ioaddr[ FE_DLCR4 ], sc->proto_dlcr4 ); outb( sc->ioaddr[ FE_DLCR5 ], sc->proto_dlcr5 ); outb( sc->ioaddr[ FE_BMPR10 ], 0x00 ); outb( sc->ioaddr[ FE_BMPR11 ], FE_B11_CTRL_SKIP | FE_B11_MODE1 ); outb( sc->ioaddr[ FE_BMPR12 ], 0x00 ); outb( sc->ioaddr[ FE_BMPR13 ], sc->proto_bmpr13 ); outb( sc->ioaddr[ FE_BMPR14 ], 0x00 ); outb( sc->ioaddr[ FE_BMPR15 ], 0x00 ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "just before enabling DLC" ); #endif /* Enable interrupts. */ outb( sc->ioaddr[ FE_DLCR2 ], FE_TMASK ); outb( sc->ioaddr[ FE_DLCR3 ], FE_RMASK ); /* Enable transmitter and receiver. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_ENABLE ); DELAY( 200 ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "just after enabling DLC" ); #endif /* * Make sure to empty the receive buffer. * * This may be redundant, but *if* the receive buffer were full * at this point, then the driver would hang. I have experienced * some strange hang-up just after UP. I hope the following * code solve the problem. * * I have changed the order of hardware initialization. * I think the receive buffer cannot have any packets at this * point in this version. The following code *must* be * redundant now. FIXME. * * I've heard a rumore that on some PC card implementation of * 8696x, the receive buffer can have some data at this point. * The following message helps discovering the fact. FIXME. */ if ( !( inb( sc->ioaddr[ FE_DLCR5 ] ) & FE_D5_BUFEMP ) ) { log( LOG_WARNING, "fe%d: receive buffer has some data after reset\n", sc->sc_unit ); fe_emptybuffer( sc ); } #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "after ERB loop" ); #endif /* Do we need this here? Actually, no. I must be paranoia. */ outb( sc->ioaddr[ FE_DLCR0 ], 0xFF ); /* Clear all bits. */ outb( sc->ioaddr[ FE_DLCR1 ], 0xFF ); /* ditto. */ #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "after FIXME" ); #endif /* Set 'running' flag, because we are now running. */ sc->sc_if.if_flags |= IFF_RUNNING; /* * At this point, the interface is running properly, * except that it receives *no* packets. we then call * fe_setmode() to tell the chip what packets to be * received, based on the if_flags and multicast group * list. It completes the initialization process. */ fe_setmode( sc ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "after setmode" ); #endif /* ...and attempt to start output queued packets. */ fe_start( &sc->sc_if ); #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, "init() done" ); #endif (void) splx(s); } /* * This routine actually starts the transmission on the interface */ static void fe_xmit ( struct fe_softc * sc ) { /* * Set a timer just in case we never hear from the board again. * We use longer timeout for multiple packet transmission. * I'm not sure this timer value is appropriate. FIXME. */ sc->sc_if.if_timer = 1 + sc->txb_count; /* Update txb variables. */ sc->txb_sched = sc->txb_count; sc->txb_count = 0; sc->txb_free = sc->txb_size; sc->tx_excolls = 0; /* Start transmitter, passing packets in TX buffer. */ outb( sc->ioaddr[ FE_BMPR10 ], sc->txb_sched | FE_B10_START ); } /* * Start output on interface. * We make two assumptions here: * 1) that the current priority is set to splimp _before_ this code * is called *and* is returned to the appropriate priority after * return * 2) that the IFF_OACTIVE flag is checked before this code is called * (i.e. that the output part of the interface is idle) */ void fe_start ( struct ifnet *ifp ) { struct fe_softc *sc = ifp->if_softc; struct mbuf *m; #if FE_DEBUG >= 1 /* Just a sanity check. */ if ( ( sc->txb_count == 0 ) != ( sc->txb_free == sc->txb_size ) ) { /* * Txb_count and txb_free co-works to manage the * transmission buffer. Txb_count keeps track of the * used potion of the buffer, while txb_free does unused * potion. So, as long as the driver runs properly, * txb_count is zero if and only if txb_free is same * as txb_size (which represents whole buffer.) */ log( LOG_ERR, "fe%d: inconsistent txb variables (%d, %d)\n", sc->sc_unit, sc->txb_count, sc->txb_free ); /* * So, what should I do, then? * * We now know txb_count and txb_free contradicts. We * cannot, however, tell which is wrong. More * over, we cannot peek 86960 transmission buffer or * reset the transmission buffer. (In fact, we can * reset the entire interface. I don't want to do it.) * * If txb_count is incorrect, leaving it as-is will cause * sending of garbage after next interrupt. We have to * avoid it. Hence, we reset the txb_count here. If * txb_free was incorrect, resetting txb_count just loose * some packets. We can live with it. */ sc->txb_count = 0; } #endif #if FE_DEBUG >= 1 /* * First, see if there are buffered packets and an idle * transmitter - should never happen at this point. */ if ( ( sc->txb_count > 0 ) && ( sc->txb_sched == 0 ) ) { log( LOG_ERR, "fe%d: transmitter idle with %d buffered packets\n", sc->sc_unit, sc->txb_count ); fe_xmit( sc ); } #endif /* * Stop accepting more transmission packets temporarily, when * a filter change request is delayed. Updating the MARs on * 86960 flushes the transmission buffer, so it is delayed * until all buffered transmission packets have been sent * out. */ if ( sc->filter_change ) { /* * Filter change request is delayed only when the DLC is * working. DLC soon raise an interrupt after finishing * the work. */ goto indicate_active; } for (;;) { /* * See if there is room to put another packet in the buffer. * We *could* do better job by peeking the send queue to * know the length of the next packet. Current version just * tests against the worst case (i.e., longest packet). FIXME. * * When adding the packet-peek feature, don't forget adding a * test on txb_count against QUEUEING_MAX. * There is a little chance the packet count exceeds * the limit. Assume transmission buffer is 8KB (2x8KB * configuration) and an application sends a bunch of small * (i.e., minimum packet sized) packets rapidly. An 8KB * buffer can hold 130 blocks of 62 bytes long... */ if ( sc->txb_free < ETHER_MAX_LEN - ETHER_CRC_LEN + FE_DATA_LEN_LEN ) { /* No room. */ goto indicate_active; } #if FE_SINGLE_TRANSMISSION if ( sc->txb_count > 0 ) { /* Just one packet per a transmission buffer. */ goto indicate_active; } #endif /* * Get the next mbuf chain for a packet to send. */ IF_DEQUEUE( &sc->sc_if.if_snd, m ); if ( m == NULL ) { /* No more packets to send. */ goto indicate_inactive; } /* * Copy the mbuf chain into the transmission buffer. * txb_* variables are updated as necessary. */ fe_write_mbufs( sc, m ); /* Start transmitter if it's idle. */ if ( ( sc->txb_count > 0 ) && ( sc->txb_sched == 0 ) ) { fe_xmit( sc ); } /* * Tap off here if there is a bpf listener, * and the device is *not* in promiscuous mode. * (86960 receives self-generated packets if * and only if it is in "receive everything" * mode.) */ #if NBPFILTER > 0 if ( sc->sc_if.if_bpf && !( sc->sc_if.if_flags & IFF_PROMISC ) ) { bpf_mtap( &sc->sc_if, m ); } #endif m_freem( m ); } indicate_inactive: /* * We are using the !OACTIVE flag to indicate to * the outside world that we can accept an * additional packet rather than that the * transmitter is _actually_ active. Indeed, the * transmitter may be active, but if we haven't * filled all the buffers with data then we still * want to accept more. */ sc->sc_if.if_flags &= ~IFF_OACTIVE; return; indicate_active: /* * The transmitter is active, and there are no room for * more outgoing packets in the transmission buffer. */ sc->sc_if.if_flags |= IFF_OACTIVE; return; } /* * Drop (skip) a packet from receive buffer in 86960 memory. */ static void fe_droppacket ( struct fe_softc * sc, int len ) { int i; /* * 86960 manual says that we have to read 8 bytes from the buffer * before skip the packets and that there must be more than 8 bytes * remaining in the buffer when issue a skip command. * Remember, we have already read 4 bytes before come here. */ if ( len > 12 ) { /* Read 4 more bytes, and skip the rest of the packet. */ ( void )inw( sc->ioaddr[ FE_BMPR8 ] ); ( void )inw( sc->ioaddr[ FE_BMPR8 ] ); outb( sc->ioaddr[ FE_BMPR14 ], FE_B14_SKIP ); } else { /* We should not come here unless receiving RUNTs. */ for ( i = 0; i < len; i += 2 ) { ( void )inw( sc->ioaddr[ FE_BMPR8 ] ); } } } /* * Empty receiving buffer. */ static void fe_emptybuffer ( struct fe_softc * sc ) { int i; u_char saved_dlcr5; #if FE_DEBUG >= 1 log( LOG_WARNING, "fe%d: emptying receive buffer", sc->sc_unit ); #endif /* * Stop receiving packets, temporarily. */ saved_dlcr5 = inb( sc->ioaddr[ FE_DLCR5 ] ); outb( sc->ioaddr[ FE_DLCR5 ], sc->proto_dlcr5 ); /* * When we come here, the receive buffer management should * have been broken. So, we cannot use skip operation. */ for ( i = 0; i < sc->txb_size; i += 2 ) { if ( inb( sc->ioaddr[ FE_DLCR5 ] ) & FE_D5_BUFEMP ) break; ( void )inw( sc->ioaddr[ FE_BMPR8 ] ); } /* * Double check. */ if ( inb( sc->ioaddr[ FE_DLCR5 ] ) & FE_D5_BUFEMP ) { log( LOG_ERR, "fe%d: could not empty receive buffer\n", sc->sc_unit ); /* Hmm. What should I do if this happens? FIXME. */ } /* * Restart receiving packets. */ outb( sc->ioaddr[ FE_DLCR5 ], saved_dlcr5 ); } /* * Transmission interrupt handler * The control flow of this function looks silly. FIXME. */ static void fe_tint ( struct fe_softc * sc, u_char tstat ) { int left; int col; /* * Handle "excessive collision" interrupt. */ if ( tstat & FE_D0_COLL16 ) { /* * Find how many packets (including this collided one) * are left unsent in transmission buffer. */ left = inb( sc->ioaddr[ FE_BMPR10 ] ); #if FE_DEBUG >= 2 log( LOG_WARNING, "fe%d: excessive collision (%d/%d)\n", sc->sc_unit, left, sc->txb_sched ); #endif #if FE_DEBUG >= 3 fe_dump( LOG_INFO, sc, NULL ); #endif /* * Clear the collision flag (in 86960) here * to avoid confusing statistics. */ outb( sc->ioaddr[ FE_DLCR0 ], FE_D0_COLLID ); /* * Restart transmitter, skipping the * collided packet. * * We *must* skip the packet to keep network running * properly. Excessive collision error is an * indication of the network overload. If we * tried sending the same packet after excessive * collision, the network would be filled with * out-of-time packets. Packets belonging * to reliable transport (such as TCP) are resent * by some upper layer. */ outb( sc->ioaddr[ FE_BMPR11 ], FE_B11_CTRL_SKIP | FE_B11_MODE1 ); /* Update statistics. */ sc->tx_excolls++; } /* * Handle "transmission complete" interrupt. */ if ( tstat & FE_D0_TXDONE ) { /* * Add in total number of collisions on last * transmission. We also clear "collision occurred" flag * here. * * 86960 has a design flaw on collision count on multiple * packet transmission. When we send two or more packets * with one start command (that's what we do when the * transmission queue is crowded), 86960 informs us number * of collisions occurred on the last packet on the * transmission only. Number of collisions on previous * packets are lost. I have told that the fact is clearly * stated in the Fujitsu document. * * I considered not to mind it seriously. Collision * count is not so important, anyway. Any comments? FIXME. */ if ( inb( sc->ioaddr[ FE_DLCR0 ] ) & FE_D0_COLLID ) { /* Clear collision flag. */ outb( sc->ioaddr[ FE_DLCR0 ], FE_D0_COLLID ); /* Extract collision count from 86960. */ col = inb( sc->ioaddr[ FE_DLCR4 ] ); col = ( col & FE_D4_COL ) >> FE_D4_COL_SHIFT; if ( col == 0 ) { /* * Status register indicates collisions, * while the collision count is zero. * This can happen after multiple packet * transmission, indicating that one or more * previous packet(s) had been collided. * * Since the accurate number of collisions * has been lost, we just guess it as 1; * Am I too optimistic? FIXME. */ col = 1; } sc->sc_if.if_collisions += col; #if FE_DEBUG >= 3 log( LOG_WARNING, "fe%d: %d collision(s) (%d)\n", sc->sc_unit, col, sc->txb_sched ); #endif } /* * Update transmission statistics. * Be sure to reflect number of excessive collisions. */ sc->sc_if.if_opackets += sc->txb_sched - sc->tx_excolls; sc->sc_if.if_oerrors += sc->tx_excolls; sc->sc_if.if_collisions += sc->tx_excolls * 16; sc->txb_sched = 0; /* * The transmitter is no more active. * Reset output active flag and watchdog timer. */ sc->sc_if.if_flags &= ~IFF_OACTIVE; sc->sc_if.if_timer = 0; /* * If more data is ready to transmit in the buffer, start * transmitting them. Otherwise keep transmitter idle, * even if more data is queued. This gives receive * process a slight priority. */ if ( sc->txb_count > 0 ) fe_xmit( sc ); } } /* * Ethernet interface receiver interrupt. */ static void fe_rint ( struct fe_softc * sc, u_char rstat ) { u_short len; u_char status; int i; /* * Update statistics if this interrupt is caused by an error. */ if ( rstat & ( FE_D1_OVRFLO | FE_D1_CRCERR | FE_D1_ALGERR | FE_D1_SRTPKT ) ) { #if FE_DEBUG >= 3 log( LOG_WARNING, "fe%d: receive error: %s%s%s%s(%02x)\n", sc->sc_unit, rstat & FE_D1_OVRFLO ? "OVR " : "", rstat & FE_D1_CRCERR ? "CRC " : "", rstat & FE_D1_ALGERR ? "ALG " : "", rstat & FE_D1_SRTPKT ? "LEN " : "", rstat ); #endif sc->sc_if.if_ierrors++; } /* * MB86960 has a flag indicating "receive queue empty." * We just loop, checking the flag, to pull out all received * packets. * * We limit the number of iterations to avoid infinite-loop. * It can be caused by a very slow CPU (some broken * peripheral may insert incredible number of wait cycles) * or, worse, by a broken MB86960 chip. */ for ( i = 0; i < FE_MAX_RECV_COUNT; i++ ) { /* Stop the iteration if 86960 indicates no packets. */ if ( inb( sc->ioaddr[ FE_DLCR5 ] ) & FE_D5_BUFEMP ) break; /* * Extract A receive status byte. * As our 86960 is in 16 bit bus access mode, we have to * use inw() to get the status byte. The significant * value is returned in lower 8 bits. */ status = ( u_char )inw( sc->ioaddr[ FE_BMPR8 ] ); #if FE_DEBUG >= 4 log( LOG_INFO, "fe%d: receive status = %04x\n", sc->sc_unit, status ); #endif /* * Extract the packet length. * It is a sum of a header (14 bytes) and a payload. * CRC has been stripped off by the 86960. */ len = inw( sc->ioaddr[ FE_BMPR8 ] ); /* * If there was an error, update statistics and drop * the packet, unless the interface is in promiscuous * mode. */ if ( ( status & 0xF0 ) != 0x20 ) { if ( !( sc->sc_if.if_flags & IFF_PROMISC ) ) { sc->sc_if.if_ierrors++; fe_droppacket( sc, len ); continue; } } /* * MB86960 checks the packet length and drop big packet * before passing it to us. There are no chance we can * get big packets through it, even if they are actually * sent over a line. Hence, if the length exceeds * the specified limit, it means some serious failure, * such as out-of-sync on receive buffer management. * * Same for short packets, since we have programmed * 86960 to drop short packets. */ if ( len > ETHER_MAX_LEN - ETHER_CRC_LEN || len < ETHER_MIN_LEN - ETHER_CRC_LEN ) { #if FE_DEBUG >= 1 log( LOG_WARNING, "fe%d: received a %s packet? (%u bytes)\n", sc->sc_unit, len < ETHER_MIN_LEN - ETHER_CRC_LEN ? "partial" : "big", len ); #endif sc->sc_if.if_ierrors++; fe_emptybuffer( sc ); continue; } /* * Go get a packet. */ if ( fe_get_packet( sc, len ) < 0 ) { /* Skip a packet, updating statistics. */ #if FE_DEBUG >= 2 log( LOG_WARNING, "%s%d: out of mbuf;" " dropping a packet (%u bytes)\n", sc->sc_unit, len ); #endif sc->sc_if.if_ierrors++; fe_droppacket( sc, len ); /* * We stop receiving packets, even if there are * more in the buffer. We hope we can get more * mbuf next time. */ return; } /* Successfully received a packet. Update stat. */ sc->sc_if.if_ipackets++; } } /* * Ethernet interface interrupt processor */ void feintr ( int unit ) { struct fe_softc *sc = &fe_softc[unit]; u_char tstat, rstat; /* * Loop until there are no more new interrupt conditions. */ for (;;) { #if FE_DEBUG >= 4 fe_dump( LOG_INFO, sc, "intr()" ); #endif /* * Get interrupt conditions, masking unneeded flags. */ tstat = inb( sc->ioaddr[ FE_DLCR0 ] ) & FE_TMASK; rstat = inb( sc->ioaddr[ FE_DLCR1 ] ) & FE_RMASK; if ( tstat == 0 && rstat == 0 ) break; /* * Reset the conditions we are acknowledging. */ outb( sc->ioaddr[ FE_DLCR0 ], tstat ); outb( sc->ioaddr[ FE_DLCR1 ], rstat ); /* * Handle transmitter interrupts. Handle these first because * the receiver will reset the board under some conditions. */ if ( tstat ) { fe_tint( sc, tstat ); } /* * Handle receiver interrupts */ if ( rstat ) { fe_rint( sc, rstat ); } /* * Update the multicast address filter if it is * needed and possible. We do it now, because * we can make sure the transmission buffer is empty, * and there is a good chance that the receive queue * is empty. It will minimize the possibility of * packet loss. */ if ( sc->filter_change && sc->txb_count == 0 && sc->txb_sched == 0 ) { fe_loadmar(sc); sc->sc_if.if_flags &= ~IFF_OACTIVE; } /* * If it looks like the transmitter can take more data, * attempt to start output on the interface. This is done * after handling the receiver interrupt to give the * receive operation priority. * * BTW, I'm not sure in what case the OACTIVE is on at * this point. Is the following test redundant? * * No. This routine polls for both transmitter and * receiver interrupts. 86960 can raise a receiver * interrupt when the transmission buffer is full. */ if ( ( sc->sc_if.if_flags & IFF_OACTIVE ) == 0 ) { fe_start( &sc->sc_if ); } } } /* * Process an ioctl request. This code needs some work - it looks * pretty ugly. */ static int fe_ioctl ( struct ifnet * ifp, int command, caddr_t data ) { struct fe_softc *sc = ifp->if_softc; int s, error = 0; #if FE_DEBUG >= 3 log( LOG_INFO, "fe%d: ioctl(%x)\n", sc->sc_unit, command ); #endif s = splimp(); switch (command) { case SIOCSIFADDR: { struct ifaddr * ifa = ( struct ifaddr * )data; sc->sc_if.if_flags |= IFF_UP; switch (ifa->ifa_addr->sa_family) { #ifdef INET case AF_INET: fe_init( sc->sc_unit ); /* before arp_ifinit */ arp_ifinit( &sc->arpcom, ifa ); break; #endif #ifdef IPX /* * XXX - This code is probably wrong */ case AF_IPX: { register struct ipx_addr *ina = &(IA_SIPX(ifa)->sipx_addr); if (ipx_nullhost(*ina)) ina->x_host = *(union ipx_host *) (sc->sc_enaddr); else { bcopy((caddr_t) ina->x_host.c_host, (caddr_t) sc->sc_enaddr, sizeof(sc->sc_enaddr)); } /* * Set new address */ fe_init(sc->sc_unit); break; } #endif #ifdef INET6 case AF_INET6: /* IPV6 added by shin 96.2.6 */ fe_init(sc->sc_unit); ndp6_ifinit(&sc->arpcom, ifa); break; #endif #ifdef NS /* * XXX - This code is probably wrong */ case AF_NS: { register struct ns_addr *ina = &(IA_SNS(ifa)->sns_addr); if (ns_nullhost(*ina)) ina->x_host = *(union ns_host *) (sc->sc_enaddr); else { bcopy((caddr_t) ina->x_host.c_host, (caddr_t) sc->sc_enaddr, sizeof(sc->sc_enaddr)); } /* * Set new address */ fe_init(sc->sc_unit); break; } #endif default: fe_init( sc->sc_unit ); break; } break; } #ifdef SIOCGIFADDR case SIOCGIFADDR: { struct ifreq * ifr = ( struct ifreq * )data; struct sockaddr * sa = ( struct sockaddr * )&ifr->ifr_data; bcopy((caddr_t)sc->sc_enaddr, (caddr_t)sa->sa_data, ETHER_ADDR_LEN); break; } #endif #ifdef SIOCGIFPHYSADDR case SIOCGIFPHYSADDR: { struct ifreq * ifr = ( struct ifreq * )data; bcopy((caddr_t)sc->sc_enaddr, (caddr_t)&ifr->ifr_data, ETHER_ADDR_LEN); break; } #endif #ifdef notdef #ifdef SIOCSIFPHYSADDR case SIOCSIFPHYSADDR: { /* * Set the physical (Ethernet) address of the interface. * When and by whom is this command used? FIXME. */ struct ifreq * ifr = ( struct ifreq * )data; bcopy((caddr_t)&ifr->ifr_data, (caddr_t)sc->sc_enaddr, ETHER_ADDR_LEN); fe_setlinkaddr( sc ); break; } #endif #endif /* notdef */ #ifdef SIOCSIFFLAGS case SIOCSIFFLAGS: { /* * Switch interface state between "running" and * "stopped", reflecting the UP flag. */ if ( sc->sc_if.if_flags & IFF_UP ) { if ( ( sc->sc_if.if_flags & IFF_RUNNING ) == 0 ) { fe_init( sc->sc_unit ); } } else { if ( ( sc->sc_if.if_flags & IFF_RUNNING ) != 0 ) { fe_stop( sc->sc_unit ); } } /* * Promiscuous and/or multicast flags may have changed, * so reprogram the multicast filter and/or receive mode. */ fe_setmode( sc ); #if FE_DEBUG >= 1 /* "ifconfig fe0 debug" to print register dump. */ if ( sc->sc_if.if_flags & IFF_DEBUG ) { fe_dump( LOG_DEBUG, sc, "SIOCSIFFLAGS(DEBUG)" ); } #endif break; } #endif #ifdef SIOCADDMULTI case SIOCADDMULTI: case SIOCDELMULTI: { /* * Update out multicast list. */ struct ifreq * ifr = ( struct ifreq * )data; error = ( command == SIOCADDMULTI ) ? ether_addmulti( ifr, &sc->arpcom ) : ether_delmulti( ifr, &sc->arpcom ); if ( error == ENETRESET ) { /* * Multicast list has changed; set the hardware filter * accordingly. */ fe_setmode( sc ); error = 0; } break; } #endif #ifdef SIOCSIFMTU case SIOCSIFMTU: { /* * Set the interface MTU. */ struct ifreq * ifr = ( struct ifreq * )data; if ( ifr->ifr_mtu > ETHERMTU ) { error = EINVAL; } else { sc->sc_if.if_mtu = ifr->ifr_mtu; } break; } #endif default: error = EINVAL; } (void) splx(s); return (error); } /* * Retrieve packet from receive buffer and send to the next level up via * ether_input(). If there is a BPF listener, give a copy to BPF, too. * Returns 0 if success, -1 if error (i.e., mbuf allocation failure). */ static int fe_get_packet ( struct fe_softc * sc, u_short len ) { struct ether_header *eh; struct mbuf *m; /* * NFS wants the data be aligned to the word (4 byte) * boundary. Ethernet header has 14 bytes. There is a * 2-byte gap. */ #define NFS_MAGIC_OFFSET 2 /* * This function assumes that an Ethernet packet fits in an * mbuf (with a cluster attached when necessary.) On FreeBSD * 2.0 for x86, which is the primary target of this driver, an * mbuf cluster has 4096 bytes, and we are happy. On ancient * BSDs, such as vanilla 4.3 for 386, a cluster size was 1024, * however. If the following #error message were printed upon * compile, you need to rewrite this function. */ #if ( MCLBYTES < ETHER_MAX_LEN - ETHER_CRC_LEN + NFS_MAGIC_OFFSET ) #error "Too small MCLBYTES to use fe driver." #endif /* * Our strategy has one more problem. There is a policy on * mbuf cluster allocation. It says that we must have at * least MINCLSIZE (208 bytes on FreeBSD 2.0 for x86) to * allocate a cluster. For a packet of a size between * (MHLEN - 2) to (MINCLSIZE - 2), our code violates the rule... * On the other hand, the current code is short, simple, * and fast, however. It does no harmful thing, just waists * some memory. Any comments? FIXME. */ /* Allocate an mbuf with packet header info. */ MGETHDR(m, M_DONTWAIT, MT_DATA); if ( m == NULL ) return -1; /* Attach a cluster if this packet doesn't fit in a normal mbuf. */ if ( len > MHLEN - NFS_MAGIC_OFFSET ) { MCLGET( m, M_DONTWAIT ); if ( !( m->m_flags & M_EXT ) ) { m_freem( m ); return -1; } } /* Initialize packet header info. */ m->m_pkthdr.rcvif = &sc->sc_if; m->m_pkthdr.len = len; /* Set the length of this packet. */ m->m_len = len; /* The following silliness is to make NFS happy */ m->m_data += NFS_MAGIC_OFFSET; /* Get a packet. */ insw( sc->ioaddr[ FE_BMPR8 ], m->m_data, ( len + 1 ) >> 1 ); /* Get (actually just point to) the header part. */ eh = mtod( m, struct ether_header *); #define ETHER_ADDR_IS_MULTICAST(A) (*(char *)(A) & 1) #if NBPFILTER > 0 /* * Check if there's a BPF listener on this interface. * If it is, hand off the raw packet to bpf. */ if ( sc->sc_if.if_bpf ) { bpf_mtap( &sc->sc_if, m ); } #endif /* * Make sure this packet is (or may be) directed to us. * That is, the packet is either unicasted to our address, * or broad/multi-casted. If any other packets are * received, it is an indication of an error -- probably * 86960 is in a wrong operation mode. * Promiscuous mode is an exception. Under the mode, all * packets on the media must be received. (We must have * programmed the 86960 so.) */ if ( ( sc->sc_if.if_flags & IFF_PROMISC ) && !ETHER_ADDR_IS_MULTICAST( eh->ether_dhost ) && bcmp( eh->ether_dhost, sc->sc_enaddr, ETHER_ADDR_LEN ) != 0 ) { /* * The packet was not for us. This is normal since * we are now in promiscuous mode. Just drop the packet. */ m_freem( m ); return 0; } #if FE_DEBUG >= 3 if ( !ETHER_ADDR_IS_MULTICAST( eh->ether_dhost ) && bcmp( eh->ether_dhost, sc->sc_enaddr, ETHER_ADDR_LEN ) != 0 ) { /* * This packet was not for us. We can't be in promiscuous * mode since the case was handled by above test. * We found an error (of this driver.) */ log( LOG_WARNING, "fe%d: got an unwanted packet, dst = %6D\n", sc->sc_unit, eh->ether_dhost , ":" ); m_freem( m ); return 0; } #endif /* Strip off the Ethernet header. */ m->m_pkthdr.len -= sizeof ( struct ether_header ); m->m_len -= sizeof ( struct ether_header ); m->m_data += sizeof ( struct ether_header ); /* Feed the packet to upper layer. */ ether_input( &sc->sc_if, eh, m ); return 0; } /* * Write an mbuf chain to the transmission buffer memory using 16 bit PIO. * Returns number of bytes actually written, including length word. * * If an mbuf chain is too long for an Ethernet frame, it is not sent. * Packets shorter than Ethernet minimum are legal, and we pad them * before sending out. An exception is "partial" packets which are * shorter than mandatory Ethernet header. */ static void fe_write_mbufs ( struct fe_softc *sc, struct mbuf *m ) { u_short addr_bmpr8 = sc->ioaddr[ FE_BMPR8 ]; u_short length, len; struct mbuf *mp; u_char *data; u_short savebyte; /* WARNING: Architecture dependent! */ #define NO_PENDING_BYTE 0xFFFF static u_char padding [ ETHER_MIN_LEN - ETHER_CRC_LEN - ETHER_HDR_LEN ]; #if FE_DEBUG >= 2 /* First, count up the total number of bytes to copy */ length = 0; for ( mp = m; mp != NULL; mp = mp->m_next ) { length += mp->m_len; } /* Check if this matches the one in the packet header. */ if ( length != m->m_pkthdr.len ) { log( LOG_WARNING, "fe%d: packet length mismatch? (%d/%d)\n", sc->sc_unit, length, m->m_pkthdr.len ); } #else /* Just use the length value in the packet header. */ length = m->m_pkthdr.len; #endif #if FE_DEBUG >= 1 /* * Should never send big packets. If such a packet is passed, * it should be a bug of upper layer. We just ignore it. * ... Partial (too short) packets, neither. */ if ( length < ETHER_HDR_LEN || length > ETHER_MAX_LEN - ETHER_CRC_LEN ) { log( LOG_ERR, "fe%d: got an out-of-spec packet (%u bytes) to send\n", sc->sc_unit, length ); sc->sc_if.if_oerrors++; return; } #endif /* * Put the length word for this frame. * Does 86960 accept odd length? -- Yes. * Do we need to pad the length to minimum size by ourselves? * -- Generally yes. But for (or will be) the last * packet in the transmission buffer, we can skip the * padding process. It may gain performance slightly. FIXME. */ outw( addr_bmpr8, max( length, ETHER_MIN_LEN - ETHER_CRC_LEN ) ); /* * Update buffer status now. * Truncate the length up to an even number, since we use outw(). */ length = ( length + 1 ) & ~1; sc->txb_free -= FE_DATA_LEN_LEN + max( length, ETHER_MIN_LEN - ETHER_CRC_LEN); sc->txb_count++; /* * Transfer the data from mbuf chain to the transmission buffer. * MB86960 seems to require that data be transferred as words, and * only words. So that we require some extra code to patch * over odd-length mbufs. */ savebyte = NO_PENDING_BYTE; for ( mp = m; mp != 0; mp = mp->m_next ) { /* Ignore empty mbuf. */ len = mp->m_len; if ( len == 0 ) continue; /* Find the actual data to send. */ data = mtod(mp, caddr_t); /* Finish the last byte. */ if ( savebyte != NO_PENDING_BYTE ) { outw( addr_bmpr8, savebyte | ( *data << 8 ) ); data++; len--; savebyte = NO_PENDING_BYTE; } /* output contiguous words */ if (len > 1) { outsw( addr_bmpr8, data, len >> 1); data += len & ~1; len &= 1; } /* Save a remaining byte, if there is one. */ if ( len > 0 ) { savebyte = *data; } } /* Spit the last byte, if the length is odd. */ if ( savebyte != NO_PENDING_BYTE ) { outw( addr_bmpr8, savebyte ); } /* Pad to the Ethernet minimum length, if the packet is too short. */ if ( length < ETHER_MIN_LEN - ETHER_CRC_LEN ) { outsw( addr_bmpr8, padding, ( ETHER_MIN_LEN - ETHER_CRC_LEN - length ) >> 1); } } /* * Compute hash value for an Ethernet address */ static int fe_hash ( u_char * ep ) { #define FE_HASH_MAGIC_NUMBER 0xEDB88320L u_long hash = 0xFFFFFFFFL; int i, j; u_char b; u_long m; for ( i = ETHER_ADDR_LEN; --i >= 0; ) { b = *ep++; for ( j = 8; --j >= 0; ) { m = hash; hash >>= 1; if ( ( m ^ b ) & 1 ) hash ^= FE_HASH_MAGIC_NUMBER; b >>= 1; } } return ( ( int )( hash >> 26 ) ); } /* * Compute the multicast address filter from the * list of multicast addresses we need to listen to. */ static struct fe_filter fe_mcaf ( struct fe_softc *sc ) { int index; struct fe_filter filter; struct ether_multi *enm; struct ether_multistep step; filter = fe_filter_nothing; ETHER_FIRST_MULTI(step, &sc->arpcom, enm); while ( enm != NULL) { if ( bcmp(enm->enm_addrlo, enm->enm_addrhi, ETHER_ADDR_LEN) ) { return ( fe_filter_all ); } index = fe_hash( enm->enm_addrlo ); #if FE_DEBUG >= 4 log( LOG_INFO, "fe%d: hash(%6D) == %d\n", sc->sc_unit, enm->enm_addrlo , ":", index ); #endif filter.data[index >> 3] |= 1 << (index & 7); ETHER_NEXT_MULTI(step, enm); } return ( filter ); } /* * Calculate a new "multicast packet filter" and put the 86960 * receiver in appropriate mode. */ static void fe_setmode ( struct fe_softc *sc ) { int flags = sc->sc_if.if_flags; /* * If the interface is not running, we postpone the update * process for receive modes and multicast address filter * until the interface is restarted. It reduces some * complicated job on maintaining chip states. (Earlier versions * of this driver had a bug on that point...) * * To complete the trick, fe_init() calls fe_setmode() after * restarting the interface. */ if ( !( flags & IFF_RUNNING ) ) return; /* * Promiscuous mode is handled separately. */ if ( flags & IFF_PROMISC ) { /* * Program 86960 to receive all packets on the segment * including those directed to other stations. * Multicast filter stored in MARs are ignored * under this setting, so we don't need to update it. * * Promiscuous mode in FreeBSD 2 is used solely by * BPF, and BPF only listens to valid (no error) packets. * So, we ignore erroneous ones even in this mode. * (Older versions of fe driver mistook the point.) */ outb( sc->ioaddr[ FE_DLCR5 ], sc->proto_dlcr5 | FE_D5_AFM0 | FE_D5_AFM1 ); sc->filter_change = 0; #if FE_DEBUG >= 3 log( LOG_INFO, "fe%d: promiscuous mode\n", sc->sc_unit ); #endif return; } /* * Turn the chip to the normal (non-promiscuous) mode. */ outb( sc->ioaddr[ FE_DLCR5 ], sc->proto_dlcr5 | FE_D5_AFM1 ); /* * Find the new multicast filter value. * I'm not sure we have to handle modes other than MULTICAST. * Who sets ALLMULTI? Who turns MULTICAST off? FIXME. */ if ( flags & IFF_ALLMULTI ) { sc->filter = fe_filter_all; } else if ( flags & IFF_MULTICAST ) { sc->filter = fe_mcaf( sc ); } else { sc->filter = fe_filter_nothing; } sc->filter_change = 1; #if FE_DEBUG >= 3 log( LOG_INFO, "fe%d: address filter: [%8D]\n", sc->sc_unit, sc->filter.data, " " ); #endif /* * We have to update the multicast filter in the 86960, A.S.A.P. * * Note that the DLC (Data Link Control unit, i.e. transmitter * and receiver) must be stopped when feeding the filter, and * DLC trashes all packets in both transmission and receive * buffers when stopped. * * ... Are the above sentences correct? I have to check the * manual of the MB86960A. FIXME. * * To reduce the packet loss, we delay the filter update * process until buffers are empty. */ if ( sc->txb_sched == 0 && sc->txb_count == 0 && !( inb( sc->ioaddr[ FE_DLCR1 ] ) & FE_D1_PKTRDY ) ) { /* * Buffers are (apparently) empty. Load * the new filter value into MARs now. */ fe_loadmar(sc); } else { /* * Buffers are not empty. Mark that we have to update * the MARs. The new filter will be loaded by feintr() * later. */ #if FE_DEBUG >= 4 log( LOG_INFO, "fe%d: filter change delayed\n", sc->sc_unit ); #endif } } /* * Load a new multicast address filter into MARs. * * The caller must have splimp'ed before fe_loadmar. * This function starts the DLC upon return. So it can be called only * when the chip is working, i.e., from the driver's point of view, when * a device is RUNNING. (I mistook the point in previous versions.) */ static void fe_loadmar ( struct fe_softc * sc ) { /* Stop the DLC (transmitter and receiver). */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_DISABLE ); DELAY( 200 ); /* Select register bank 1 for MARs. */ outb( sc->ioaddr[ FE_DLCR7 ], sc->proto_dlcr7 | FE_D7_RBS_MAR | FE_D7_POWER_UP ); /* Copy filter value into the registers. */ outblk( sc, FE_MAR8, sc->filter.data, FE_FILTER_LEN ); /* Restore the bank selection for BMPRs (i.e., runtime registers). */ outb( sc->ioaddr[ FE_DLCR7 ], sc->proto_dlcr7 | FE_D7_RBS_BMPR | FE_D7_POWER_UP ); /* Restart the DLC. */ DELAY( 200 ); outb( sc->ioaddr[ FE_DLCR6 ], sc->proto_dlcr6 | FE_D6_DLC_ENABLE ); DELAY( 200 ); /* We have just updated the filter. */ sc->filter_change = 0; #if FE_DEBUG >= 3 log( LOG_INFO, "fe%d: address filter changed\n", sc->sc_unit ); #endif } #if FE_DEBUG >= 1 static void fe_dump ( int level, struct fe_softc * sc, char * message ) { log( level, "fe%d: %s," " DLCR = %02x %02x %02x %02x %02x %02x %02x %02x," " BMPR = xx xx %02x %02x %02x %02x %02x %02x," " asic = %02x %02x %02x %02x %02x %02x %02x %02x" " + %02x %02x %02x %02x %02x %02x %02x %02x\n", sc->sc_unit, message ? message : "registers", inb( sc->ioaddr[ FE_DLCR0 ] ), inb( sc->ioaddr[ FE_DLCR1 ] ), inb( sc->ioaddr[ FE_DLCR2 ] ), inb( sc->ioaddr[ FE_DLCR3 ] ), inb( sc->ioaddr[ FE_DLCR4 ] ), inb( sc->ioaddr[ FE_DLCR5 ] ), inb( sc->ioaddr[ FE_DLCR6 ] ), inb( sc->ioaddr[ FE_DLCR7 ] ), inb( sc->ioaddr[ FE_BMPR10 ] ), inb( sc->ioaddr[ FE_BMPR11 ] ), inb( sc->ioaddr[ FE_BMPR12 ] ), inb( sc->ioaddr[ FE_BMPR13 ] ), inb( sc->ioaddr[ FE_BMPR14 ] ), inb( sc->ioaddr[ FE_BMPR15 ] ), inb( sc->ioaddr[ 0x10 ] ), inb( sc->ioaddr[ 0x11 ] ), inb( sc->ioaddr[ 0x12 ] ), inb( sc->ioaddr[ 0x13 ] ), inb( sc->ioaddr[ 0x14 ] ), inb( sc->ioaddr[ 0x15 ] ), inb( sc->ioaddr[ 0x16 ] ), inb( sc->ioaddr[ 0x17 ] ), inb( sc->ioaddr[ 0x18 ] ), inb( sc->ioaddr[ 0x19 ] ), inb( sc->ioaddr[ 0x1A ] ), inb( sc->ioaddr[ 0x1B ] ), inb( sc->ioaddr[ 0x1C ] ), inb( sc->ioaddr[ 0x1D ] ), inb( sc->ioaddr[ 0x1E ] ), inb( sc->ioaddr[ 0x1F ] ) ); } #endif