dev/pci/if_bge.c

1.16  thorpej /*	$NetBSD: if_bge.c,v 1.16 2002/07/13 22:21:20 thorpej Exp $	*/
 1.8  thorpej
 1.1     fvdl /*
 1.1     fvdl  * Copyright (c) 2001 Wind River Systems
 1.1     fvdl  * Copyright (c) 1997, 1998, 1999, 2001
 1.1     fvdl  *	Bill Paul <wpaul (at) windriver.com>.  All rights reserved.
 1.1     fvdl  *
 1.1     fvdl  * Redistribution and use in source and binary forms, with or without
 1.1     fvdl  * modification, are permitted provided that the following conditions
 1.1     fvdl  * are met:
 1.1     fvdl  * 1. Redistributions of source code must retain the above copyright
 1.1     fvdl  *    notice, this list of conditions and the following disclaimer.
 1.1     fvdl  * 2. Redistributions in binary form must reproduce the above copyright
 1.1     fvdl  *    notice, this list of conditions and the following disclaimer in the
 1.1     fvdl  *    documentation and/or other materials provided with the distribution.
 1.1     fvdl  * 3. All advertising materials mentioning features or use of this software
 1.1     fvdl  *    must display the following acknowledgement:
 1.1     fvdl  *	This product includes software developed by Bill Paul.
 1.1     fvdl  * 4. Neither the name of the author nor the names of any co-contributors
 1.1     fvdl  *    may be used to endorse or promote products derived from this software
 1.1     fvdl  *    without specific prior written permission.
 1.1     fvdl  *
 1.1     fvdl  * THIS SOFTWARE IS PROVIDED BY Bill Paul AND CONTRIBUTORS ``AS IS'' AND
 1.1     fvdl  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 1.1     fvdl  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 1.1     fvdl  * ARE DISCLAIMED.  IN NO EVENT SHALL Bill Paul OR THE VOICES IN HIS HEAD
 1.1     fvdl  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1     fvdl  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1     fvdl  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1     fvdl  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1     fvdl  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1     fvdl  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
 1.1     fvdl  * THE POSSIBILITY OF SUCH DAMAGE.
 1.1     fvdl  *
 1.1     fvdl  * $FreeBSD: if_bge.c,v 1.13 2002/04/04 06:01:31 wpaul Exp $
 1.1     fvdl  */
 1.1     fvdl
 1.1     fvdl /*
1.12  thorpej  * Broadcom BCM570x family gigabit ethernet driver for NetBSD.
 1.1     fvdl  *
1.12  thorpej  * NetBSD version by:
1.12  thorpej  *
1.12  thorpej  *	Frank van der Linden <fvdl (at) wasabisystems.com>
1.12  thorpej  *	Jason Thorpe <thorpej (at) wasabisystems.com>
1.12  thorpej  *
1.12  thorpej  * Originally written for FreeBSD by Bill Paul <wpaul (at) windriver.com>
 1.1     fvdl  * Senior Engineer, Wind River Systems
 1.1     fvdl  */
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * The Broadcom BCM5700 is based on technology originally developed by
 1.1     fvdl  * Alteon Networks as part of the Tigon I and Tigon II gigabit ethernet
 1.1     fvdl  * MAC chips. The BCM5700, sometimes refered to as the Tigon III, has
 1.1     fvdl  * two on-board MIPS R4000 CPUs and can have as much as 16MB of external
 1.1     fvdl  * SSRAM. The BCM5700 supports TCP, UDP and IP checksum offload, jumbo
 1.1     fvdl  * frames, highly configurable RX filtering, and 16 RX and TX queues
 1.1     fvdl  * (which, along with RX filter rules, can be used for QOS applications).
 1.1     fvdl  * Other features, such as TCP segmentation, may be available as part
 1.1     fvdl  * of value-added firmware updates. Unlike the Tigon I and Tigon II,
 1.1     fvdl  * firmware images can be stored in hardware and need not be compiled
 1.1     fvdl  * into the driver.
 1.1     fvdl  *
 1.1     fvdl  * The BCM5700 supports the PCI v2.2 and PCI-X v1.0 standards, and will
 1.1     fvdl  * function in a 32-bit/64-bit 33/66Mhz bus, or a 64-bit/133Mhz bus.
 1.1     fvdl  *
 1.1     fvdl  * The BCM5701 is a single-chip solution incorporating both the BCM5700
 1.1     fvdl  * MAC and a BCM5401 10/100/1000 PHY. Unlike the BCM5700, the BCM5700
 1.1     fvdl  * does not support external SSRAM.
 1.1     fvdl  *
 1.1     fvdl  * Broadcom also produces a variation of the BCM5700 under the "Altima"
 1.1     fvdl  * brand name, which is functionally similar but lacks PCI-X support.
 1.1     fvdl  *
 1.1     fvdl  * Without external SSRAM, you can only have at most 4 TX rings,
 1.1     fvdl  * and the use of the mini RX ring is disabled. This seems to imply
 1.1     fvdl  * that these features are simply not available on the BCM5701. As a
 1.1     fvdl  * result, this driver does not implement any support for the mini RX
 1.1     fvdl  * ring.
 1.1     fvdl  */
 1.1     fvdl
 1.1     fvdl #include "bpfilter.h"
 1.1     fvdl #include "vlan.h"
 1.1     fvdl
 1.1     fvdl #include <sys/param.h>
 1.1     fvdl #include <sys/systm.h>
 1.1     fvdl #include <sys/callout.h>
 1.1     fvdl #include <sys/sockio.h>
 1.1     fvdl #include <sys/mbuf.h>
 1.1     fvdl #include <sys/malloc.h>
 1.1     fvdl #include <sys/kernel.h>
 1.1     fvdl #include <sys/device.h>
 1.1     fvdl #include <sys/socket.h>
 1.1     fvdl
 1.1     fvdl #include <net/if.h>
 1.1     fvdl #include <net/if_dl.h>
 1.1     fvdl #include <net/if_media.h>
 1.1     fvdl #include <net/if_ether.h>
 1.1     fvdl
 1.1     fvdl #ifdef INET
 1.1     fvdl #include <netinet/in.h>
 1.1     fvdl #include <netinet/in_systm.h>
 1.1     fvdl #include <netinet/in_var.h>
 1.1     fvdl #include <netinet/ip.h>
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl #if NBPFILTER > 0
 1.1     fvdl #include <net/bpf.h>
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl #include <dev/pci/pcireg.h>
 1.1     fvdl #include <dev/pci/pcivar.h>
 1.1     fvdl #include <dev/pci/pcidevs.h>
 1.1     fvdl
 1.1     fvdl #include <dev/mii/mii.h>
 1.1     fvdl #include <dev/mii/miivar.h>
 1.1     fvdl #include <dev/mii/miidevs.h>
 1.1     fvdl #include <dev/mii/brgphyreg.h>
 1.1     fvdl
 1.1     fvdl #include <dev/pci/if_bgereg.h>
 1.1     fvdl
 1.1     fvdl #include <uvm/uvm_extern.h>
 1.1     fvdl
 1.1     fvdl /* #define BGE_CHECKSUM */
 1.1     fvdl
 1.1     fvdl int bge_probe(struct device *, struct cfdata *, void *);
 1.1     fvdl void bge_attach(struct device *, struct device *, void *);
 1.1     fvdl void bge_release_resources(struct bge_softc *);
 1.1     fvdl void bge_txeof(struct bge_softc *);
 1.1     fvdl void bge_rxeof(struct bge_softc *);
 1.1     fvdl
 1.1     fvdl void bge_tick(void *);
 1.1     fvdl void bge_stats_update(struct bge_softc *);
 1.1     fvdl int bge_encap(struct bge_softc *, struct mbuf *, u_int32_t *);
 1.1     fvdl
 1.1     fvdl int bge_intr(void *);
 1.1     fvdl void bge_start(struct ifnet *);
 1.1     fvdl int bge_ioctl(struct ifnet *, u_long, caddr_t);
 1.1     fvdl int bge_init(struct ifnet *);
 1.1     fvdl void bge_stop(struct bge_softc *);
 1.1     fvdl void bge_watchdog(struct ifnet *);
 1.1     fvdl void bge_shutdown(void *);
 1.1     fvdl int bge_ifmedia_upd(struct ifnet *);
 1.1     fvdl void bge_ifmedia_sts(struct ifnet *, struct ifmediareq *);
 1.1     fvdl
 1.1     fvdl u_int8_t bge_eeprom_getbyte(struct bge_softc *, int, u_int8_t *);
 1.1     fvdl int bge_read_eeprom(struct bge_softc *, caddr_t, int, int);
 1.1     fvdl
 1.1     fvdl void bge_setmulti(struct bge_softc *);
 1.1     fvdl
 1.1     fvdl void bge_handle_events(struct bge_softc *);
 1.1     fvdl int bge_alloc_jumbo_mem(struct bge_softc *);
 1.1     fvdl void bge_free_jumbo_mem(struct bge_softc *);
 1.1     fvdl void *bge_jalloc(struct bge_softc *);
 1.1     fvdl void bge_jfree(struct mbuf *, caddr_t, u_int, void *);
 1.1     fvdl int bge_newbuf_std(struct bge_softc *, int, struct mbuf *, bus_dmamap_t);
 1.1     fvdl int bge_newbuf_jumbo(struct bge_softc *, int, struct mbuf *);
 1.1     fvdl int bge_init_rx_ring_std(struct bge_softc *);
 1.1     fvdl void bge_free_rx_ring_std(struct bge_softc *);
 1.1     fvdl int bge_init_rx_ring_jumbo(struct bge_softc *);
 1.1     fvdl void bge_free_rx_ring_jumbo(struct bge_softc *);
 1.1     fvdl void bge_free_tx_ring(struct bge_softc *);
 1.1     fvdl int bge_init_tx_ring(struct bge_softc *);
 1.1     fvdl
 1.1     fvdl int bge_chipinit(struct bge_softc *);
 1.1     fvdl int bge_blockinit(struct bge_softc *);
 1.1     fvdl
 1.1     fvdl #ifdef notdef
 1.1     fvdl u_int8_t bge_vpd_readbyte(struct bge_softc *, int);
 1.1     fvdl void bge_vpd_read_res(struct bge_softc *, struct vpd_res *, int);
 1.1     fvdl void bge_vpd_read(struct bge_softc *);
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl u_int32_t bge_readmem_ind(struct bge_softc *, int);
 1.1     fvdl void bge_writemem_ind(struct bge_softc *, int, int);
 1.1     fvdl #ifdef notdef
 1.1     fvdl u_int32_t bge_readreg_ind(struct bge_softc *, int);
 1.1     fvdl #endif
 1.1     fvdl void bge_writereg_ind(struct bge_softc *, int, int);
 1.1     fvdl
 1.1     fvdl int bge_miibus_readreg(struct device *, int, int);
 1.1     fvdl void bge_miibus_writereg(struct device *, int, int, int);
 1.1     fvdl void bge_miibus_statchg(struct device *);
 1.1     fvdl
 1.1     fvdl void bge_reset(struct bge_softc *);
 1.1     fvdl
 1.1     fvdl void bge_dump_status(struct bge_softc *);
 1.1     fvdl void bge_dump_rxbd(struct bge_rx_bd *);
 1.1     fvdl
 1.1     fvdl #define BGE_DEBUG
 1.1     fvdl #ifdef BGE_DEBUG
 1.1     fvdl #define DPRINTF(x)	if (bgedebug) printf x
 1.1     fvdl #define DPRINTFN(n,x)	if (bgedebug >= (n)) printf x
 1.1     fvdl int	bgedebug = 0;
 1.1     fvdl #else
 1.1     fvdl #define DPRINTF(x)
 1.1     fvdl #define DPRINTFN(n,x)
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl struct cfattach bge_ca = {
 1.1     fvdl 	sizeof(struct bge_softc), bge_probe, bge_attach
 1.1     fvdl };
 1.1     fvdl
 1.1     fvdl u_int32_t
 1.1     fvdl bge_readmem_ind(sc, off)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	int off;
 1.1     fvdl {
 1.1     fvdl 	struct pci_attach_args	*pa = &(sc->bge_pa);
 1.1     fvdl 	pcireg_t val;
 1.1     fvdl
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_MEMWIN_BASEADDR, off);
 1.1     fvdl 	val = pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_MEMWIN_DATA);
 1.1     fvdl 	return val;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_writemem_ind(sc, off, val)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	int off, val;
 1.1     fvdl {
 1.1     fvdl 	struct pci_attach_args	*pa = &(sc->bge_pa);
 1.1     fvdl
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_MEMWIN_BASEADDR, off);
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_MEMWIN_DATA, val);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl #ifdef notdef
 1.1     fvdl u_int32_t
 1.1     fvdl bge_readreg_ind(sc, off)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	int off;
 1.1     fvdl {
 1.1     fvdl 	struct pci_attach_args	*pa = &(sc->bge_pa);
 1.1     fvdl
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_REG_BASEADDR, off);
 1.1     fvdl 	return(pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_REG_DATA));
 1.1     fvdl }
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_writereg_ind(sc, off, val)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	int off, val;
 1.1     fvdl {
 1.1     fvdl 	struct pci_attach_args	*pa = &(sc->bge_pa);
 1.1     fvdl
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_REG_BASEADDR, off);
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_REG_DATA, val);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl #ifdef notdef
 1.1     fvdl u_int8_t
 1.1     fvdl bge_vpd_readbyte(sc, addr)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	int addr;
 1.1     fvdl {
 1.1     fvdl 	int i;
 1.1     fvdl 	u_int32_t val;
 1.1     fvdl 	struct pci_attach_args	*pa = &(sc->bge_pa);
 1.1     fvdl
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_VPD_ADDR, addr);
 1.1     fvdl 	for (i = 0; i < BGE_TIMEOUT * 10; i++) {
 1.1     fvdl 		DELAY(10);
 1.1     fvdl 		if (pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_VPD_ADDR) &
 1.1     fvdl 		    BGE_VPD_FLAG)
 1.1     fvdl 			break;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (i == BGE_TIMEOUT) {
 1.1     fvdl 		printf("%s: VPD read timed out\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		return(0);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	val = pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_VPD_DATA);
 1.1     fvdl
 1.1     fvdl 	return((val >> ((addr % 4) * 8)) & 0xFF);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_vpd_read_res(sc, res, addr)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	struct vpd_res *res;
 1.1     fvdl 	int addr;
 1.1     fvdl {
 1.1     fvdl 	int i;
 1.1     fvdl 	u_int8_t *ptr;
 1.1     fvdl
 1.1     fvdl 	ptr = (u_int8_t *)res;
 1.1     fvdl 	for (i = 0; i < sizeof(struct vpd_res); i++)
 1.1     fvdl 		ptr[i] = bge_vpd_readbyte(sc, i + addr);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_vpd_read(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	int pos = 0, i;
 1.1     fvdl 	struct vpd_res res;
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_vpd_prodname != NULL)
 1.1     fvdl 		free(sc->bge_vpd_prodname, M_DEVBUF);
 1.1     fvdl 	if (sc->bge_vpd_readonly != NULL)
 1.1     fvdl 		free(sc->bge_vpd_readonly, M_DEVBUF);
 1.1     fvdl 	sc->bge_vpd_prodname = NULL;
 1.1     fvdl 	sc->bge_vpd_readonly = NULL;
 1.1     fvdl
 1.1     fvdl 	bge_vpd_read_res(sc, &res, pos);
 1.1     fvdl
 1.1     fvdl 	if (res.vr_id != VPD_RES_ID) {
 1.1     fvdl 		printf("%s: bad VPD resource id: expected %x got %x\n",
 1.1     fvdl 			sc->bge_dev.dv_xname, VPD_RES_ID, res.vr_id);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	pos += sizeof(res);
 1.1     fvdl 	sc->bge_vpd_prodname = malloc(res.vr_len + 1, M_DEVBUF, M_NOWAIT);
 1.1     fvdl 	if (sc->bge_vpd_prodname == NULL)
 1.1     fvdl 		panic("bge_vpd_read");
 1.1     fvdl 	for (i = 0; i < res.vr_len; i++)
 1.1     fvdl 		sc->bge_vpd_prodname[i] = bge_vpd_readbyte(sc, i + pos);
 1.1     fvdl 	sc->bge_vpd_prodname[i] = '\0';
 1.1     fvdl 	pos += i;
 1.1     fvdl
 1.1     fvdl 	bge_vpd_read_res(sc, &res, pos);
 1.1     fvdl
 1.1     fvdl 	if (res.vr_id != VPD_RES_READ) {
 1.1     fvdl 		printf("%s: bad VPD resource id: expected %x got %x\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname, VPD_RES_READ, res.vr_id);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	pos += sizeof(res);
 1.1     fvdl 	sc->bge_vpd_readonly = malloc(res.vr_len, M_DEVBUF, M_NOWAIT);
 1.1     fvdl 	if (sc->bge_vpd_readonly == NULL)
 1.1     fvdl 		panic("bge_vpd_read");
 1.1     fvdl 	for (i = 0; i < res.vr_len + 1; i++)
 1.1     fvdl 		sc->bge_vpd_readonly[i] = bge_vpd_readbyte(sc, i + pos);
 1.1     fvdl }
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Read a byte of data stored in the EEPROM at address 'addr.' The
 1.1     fvdl  * BCM570x supports both the traditional bitbang interface and an
 1.1     fvdl  * auto access interface for reading the EEPROM. We use the auto
 1.1     fvdl  * access method.
 1.1     fvdl  */
 1.1     fvdl u_int8_t
 1.1     fvdl bge_eeprom_getbyte(sc, addr, dest)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	int addr;
 1.1     fvdl 	u_int8_t *dest;
 1.1     fvdl {
 1.1     fvdl 	int i;
 1.1     fvdl 	u_int32_t byte = 0;
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Enable use of auto EEPROM access so we can avoid
 1.1     fvdl 	 * having to use the bitbang method.
 1.1     fvdl 	 */
 1.1     fvdl 	BGE_SETBIT(sc, BGE_MISC_LOCAL_CTL, BGE_MLC_AUTO_EEPROM);
 1.1     fvdl
 1.1     fvdl 	/* Reset the EEPROM, load the clock period. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_EE_ADDR,
 1.1     fvdl 	    BGE_EEADDR_RESET|BGE_EEHALFCLK(BGE_HALFCLK_384SCL));
 1.1     fvdl 	DELAY(20);
 1.1     fvdl
 1.1     fvdl 	/* Issue the read EEPROM command. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_EE_ADDR, BGE_EE_READCMD | addr);
 1.1     fvdl
 1.1     fvdl 	/* Wait for completion */
 1.1     fvdl 	for(i = 0; i < BGE_TIMEOUT * 10; i++) {
 1.1     fvdl 		DELAY(10);
 1.1     fvdl 		if (CSR_READ_4(sc, BGE_EE_ADDR) & BGE_EEADDR_DONE)
 1.1     fvdl 			break;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (i == BGE_TIMEOUT) {
 1.1     fvdl 		printf("%s: eeprom read timed out\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		return(0);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Get result. */
 1.1     fvdl 	byte = CSR_READ_4(sc, BGE_EE_DATA);
 1.1     fvdl
 1.1     fvdl 	*dest = (byte >> ((addr % 4) * 8)) & 0xFF;
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Read a sequence of bytes from the EEPROM.
 1.1     fvdl  */
 1.1     fvdl int
 1.1     fvdl bge_read_eeprom(sc, dest, off, cnt)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	caddr_t dest;
 1.1     fvdl 	int off;
 1.1     fvdl 	int cnt;
 1.1     fvdl {
 1.1     fvdl 	int err = 0, i;
 1.1     fvdl 	u_int8_t byte = 0;
 1.1     fvdl
 1.1     fvdl 	for (i = 0; i < cnt; i++) {
 1.1     fvdl 		err = bge_eeprom_getbyte(sc, off + i, &byte);
 1.1     fvdl 		if (err)
 1.1     fvdl 			break;
 1.1     fvdl 		*(dest + i) = byte;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	return(err ? 1 : 0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl int
 1.1     fvdl bge_miibus_readreg(dev, phy, reg)
 1.1     fvdl 	struct device *dev;
 1.1     fvdl 	int phy, reg;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = (struct bge_softc *)dev;
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl 	u_int32_t val;
 1.1     fvdl 	int i;
 1.1     fvdl
 1.1     fvdl 	ifp = &sc->ethercom.ec_if;
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_asicrev == BGE_ASICREV_BCM5701_B5 && phy != 1)
 1.1     fvdl 		return(0);
 1.1     fvdl
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MI_COMM, BGE_MICMD_READ|BGE_MICOMM_BUSY|
 1.1     fvdl 	    BGE_MIPHY(phy)|BGE_MIREG(reg));
 1.1     fvdl
 1.1     fvdl 	for (i = 0; i < BGE_TIMEOUT; i++) {
 1.1     fvdl 		val = CSR_READ_4(sc, BGE_MI_COMM);
 1.1     fvdl 		if (!(val & BGE_MICOMM_BUSY))
 1.1     fvdl 			break;
 1.9  thorpej 		delay(10);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (i == BGE_TIMEOUT) {
 1.1     fvdl 		printf("%s: PHY read timed out\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		return(0);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	val = CSR_READ_4(sc, BGE_MI_COMM);
 1.1     fvdl
 1.1     fvdl 	if (val & BGE_MICOMM_READFAIL)
 1.1     fvdl 		return(0);
 1.1     fvdl
 1.1     fvdl 	return(val & 0xFFFF);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_miibus_writereg(dev, phy, reg, val)
 1.1     fvdl 	struct device *dev;
 1.1     fvdl 	int phy, reg, val;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = (struct bge_softc *)dev;
 1.1     fvdl 	int i;
 1.1     fvdl
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MI_COMM, BGE_MICMD_WRITE|BGE_MICOMM_BUSY|
 1.1     fvdl 	    BGE_MIPHY(phy)|BGE_MIREG(reg)|val);
 1.1     fvdl
 1.1     fvdl 	for (i = 0; i < BGE_TIMEOUT; i++) {
 1.1     fvdl 		if (!(CSR_READ_4(sc, BGE_MI_COMM) & BGE_MICOMM_BUSY))
 1.1     fvdl 			break;
 1.9  thorpej 		delay(10);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (i == BGE_TIMEOUT) {
 1.1     fvdl 		printf("%s: PHY read timed out\n", sc->bge_dev.dv_xname);
 1.1     fvdl 	}
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_miibus_statchg(dev)
 1.1     fvdl 	struct device *dev;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = (struct bge_softc *)dev;
 1.1     fvdl 	struct mii_data *mii = &sc->bge_mii;
 1.1     fvdl
 1.1     fvdl 	BGE_CLRBIT(sc, BGE_MAC_MODE, BGE_MACMODE_PORTMODE);
 1.1     fvdl 	if (IFM_SUBTYPE(mii->mii_media_active) == IFM_1000_T) {
 1.1     fvdl 		BGE_SETBIT(sc, BGE_MAC_MODE, BGE_PORTMODE_GMII);
 1.1     fvdl 	} else {
 1.1     fvdl 		BGE_SETBIT(sc, BGE_MAC_MODE, BGE_PORTMODE_MII);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if ((mii->mii_media_active & IFM_GMASK) == IFM_FDX) {
 1.1     fvdl 		BGE_CLRBIT(sc, BGE_MAC_MODE, BGE_MACMODE_HALF_DUPLEX);
 1.1     fvdl 	} else {
 1.1     fvdl 		BGE_SETBIT(sc, BGE_MAC_MODE, BGE_MACMODE_HALF_DUPLEX);
 1.1     fvdl 	}
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Handle events that have triggered interrupts.
 1.1     fvdl  */
 1.1     fvdl void
 1.1     fvdl bge_handle_events(sc)
 1.1     fvdl 	struct bge_softc		*sc;
 1.1     fvdl {
 1.1     fvdl
 1.1     fvdl 	return;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Memory management for jumbo frames.
 1.1     fvdl  */
 1.1     fvdl
 1.1     fvdl int
 1.1     fvdl bge_alloc_jumbo_mem(sc)
 1.1     fvdl 	struct bge_softc		*sc;
 1.1     fvdl {
 1.1     fvdl 	caddr_t			ptr, kva;
 1.1     fvdl 	bus_dma_segment_t	seg;
 1.1     fvdl 	int		i, rseg, state, error;
 1.1     fvdl 	struct bge_jpool_entry   *entry;
 1.1     fvdl
 1.1     fvdl 	state = error = 0;
 1.1     fvdl
 1.1     fvdl 	/* Grab a big chunk o' storage. */
 1.1     fvdl 	if (bus_dmamem_alloc(sc->bge_dmatag, BGE_JMEM, PAGE_SIZE, 0,
 1.1     fvdl 	     &seg, 1, &rseg, BUS_DMA_NOWAIT)) {
 1.1     fvdl 		printf("%s: can't alloc rx buffers\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		return ENOBUFS;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	state = 1;
 1.1     fvdl 	if (bus_dmamem_map(sc->bge_dmatag, &seg, rseg, BGE_JMEM, &kva,
 1.1     fvdl 	    BUS_DMA_NOWAIT)) {
 1.1     fvdl 		printf("%s: can't map dma buffers (%d bytes)\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname, (int)BGE_JMEM);
 1.1     fvdl 		error = ENOBUFS;
 1.1     fvdl 		goto out;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	state = 2;
 1.1     fvdl 	if (bus_dmamap_create(sc->bge_dmatag, BGE_JMEM, 1, BGE_JMEM, 0,
 1.1     fvdl 	    BUS_DMA_NOWAIT, &sc->bge_cdata.bge_rx_jumbo_map)) {
 1.1     fvdl 		printf("%s: can't create dma map\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		error = ENOBUFS;
 1.1     fvdl 		goto out;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	state = 3;
 1.1     fvdl 	if (bus_dmamap_load(sc->bge_dmatag, sc->bge_cdata.bge_rx_jumbo_map,
 1.1     fvdl 	    kva, BGE_JMEM, NULL, BUS_DMA_NOWAIT)) {
 1.1     fvdl 		printf("%s: can't load dma map\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		error = ENOBUFS;
 1.1     fvdl 		goto out;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	state = 4;
 1.1     fvdl 	sc->bge_cdata.bge_jumbo_buf = (caddr_t)kva;
 1.1     fvdl 	DPRINTFN(1,("bge_jumbo_buf = 0x%p\n", sc->bge_cdata.bge_jumbo_buf));
 1.1     fvdl
 1.1     fvdl 	SLIST_INIT(&sc->bge_jfree_listhead);
 1.1     fvdl 	SLIST_INIT(&sc->bge_jinuse_listhead);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Now divide it up into 9K pieces and save the addresses
 1.1     fvdl 	 * in an array.
 1.1     fvdl 	 */
 1.1     fvdl 	ptr = sc->bge_cdata.bge_jumbo_buf;
 1.1     fvdl 	for (i = 0; i < BGE_JSLOTS; i++) {
 1.1     fvdl 		sc->bge_cdata.bge_jslots[i] = ptr;
 1.1     fvdl 		ptr += BGE_JLEN;
 1.1     fvdl 		entry = malloc(sizeof(struct bge_jpool_entry),
 1.1     fvdl 		    M_DEVBUF, M_NOWAIT);
 1.1     fvdl 		if (entry == NULL) {
 1.1     fvdl 			printf("%s: no memory for jumbo buffer queue!\n",
 1.1     fvdl 			    sc->bge_dev.dv_xname);
 1.1     fvdl 			error = ENOBUFS;
 1.1     fvdl 			goto out;
 1.1     fvdl 		}
 1.1     fvdl 		entry->slot = i;
 1.1     fvdl 		SLIST_INSERT_HEAD(&sc->bge_jfree_listhead,
 1.1     fvdl 				 entry, jpool_entries);
 1.1     fvdl 	}
 1.1     fvdl out:
 1.1     fvdl 	if (error != 0) {
 1.1     fvdl 		switch (state) {
 1.1     fvdl 		case 4:
 1.1     fvdl 			bus_dmamap_unload(sc->bge_dmatag,
 1.1     fvdl 			    sc->bge_cdata.bge_rx_jumbo_map);
 1.1     fvdl 		case 3:
 1.1     fvdl 			bus_dmamap_destroy(sc->bge_dmatag,
 1.1     fvdl 			    sc->bge_cdata.bge_rx_jumbo_map);
 1.1     fvdl 		case 2:
 1.1     fvdl 			bus_dmamem_unmap(sc->bge_dmatag, kva, BGE_JMEM);
 1.1     fvdl 		case 1:
 1.1     fvdl 			bus_dmamem_free(sc->bge_dmatag, &seg, rseg);
 1.1     fvdl 			break;
 1.1     fvdl 		default:
 1.1     fvdl 			break;
 1.1     fvdl 		}
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	return error;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Allocate a jumbo buffer.
 1.1     fvdl  */
 1.1     fvdl void *
 1.1     fvdl bge_jalloc(sc)
 1.1     fvdl 	struct bge_softc		*sc;
 1.1     fvdl {
 1.1     fvdl 	struct bge_jpool_entry   *entry;
 1.1     fvdl
 1.1     fvdl 	entry = SLIST_FIRST(&sc->bge_jfree_listhead);
 1.1     fvdl
 1.1     fvdl 	if (entry == NULL) {
 1.1     fvdl 		printf("%s: no free jumbo buffers\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		return(NULL);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	SLIST_REMOVE_HEAD(&sc->bge_jfree_listhead, jpool_entries);
 1.1     fvdl 	SLIST_INSERT_HEAD(&sc->bge_jinuse_listhead, entry, jpool_entries);
 1.1     fvdl 	return(sc->bge_cdata.bge_jslots[entry->slot]);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Release a jumbo buffer.
 1.1     fvdl  */
 1.1     fvdl void
 1.1     fvdl bge_jfree(m, buf, size, arg)
 1.1     fvdl 	struct mbuf	*m;
 1.1     fvdl 	caddr_t		buf;
 1.1     fvdl 	u_int		size;
 1.1     fvdl 	void		*arg;
 1.1     fvdl {
 1.1     fvdl 	struct bge_jpool_entry *entry;
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	int i, s;
 1.1     fvdl
 1.1     fvdl 	/* Extract the softc struct pointer. */
 1.1     fvdl 	sc = (struct bge_softc *)arg;
 1.1     fvdl
 1.1     fvdl 	if (sc == NULL)
 1.1     fvdl 		panic("bge_jfree: can't find softc pointer!");
 1.1     fvdl
 1.1     fvdl 	/* calculate the slot this buffer belongs to */
 1.1     fvdl
 1.1     fvdl 	i = ((caddr_t)buf
 1.1     fvdl 	     - (caddr_t)sc->bge_cdata.bge_jumbo_buf) / BGE_JLEN;
 1.1     fvdl
 1.1     fvdl 	if ((i < 0) || (i >= BGE_JSLOTS))
 1.1     fvdl 		panic("bge_jfree: asked to free buffer that we don't manage!");
 1.1     fvdl
 1.1     fvdl 	s = splvm();
 1.1     fvdl 	entry = SLIST_FIRST(&sc->bge_jinuse_listhead);
 1.1     fvdl 	if (entry == NULL)
 1.1     fvdl 		panic("bge_jfree: buffer not in use!");
 1.1     fvdl 	entry->slot = i;
 1.1     fvdl 	SLIST_REMOVE_HEAD(&sc->bge_jinuse_listhead, jpool_entries);
 1.1     fvdl 	SLIST_INSERT_HEAD(&sc->bge_jfree_listhead, entry, jpool_entries);
 1.1     fvdl
 1.1     fvdl 	if (__predict_true(m != NULL))
 1.1     fvdl   		pool_cache_put(&mbpool_cache, m);
 1.1     fvdl 	splx(s);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Intialize a standard receive ring descriptor.
 1.1     fvdl  */
 1.1     fvdl int
 1.1     fvdl bge_newbuf_std(sc, i, m, dmamap)
 1.1     fvdl 	struct bge_softc	*sc;
 1.1     fvdl 	int			i;
 1.1     fvdl 	struct mbuf		*m;
 1.1     fvdl 	bus_dmamap_t dmamap;
 1.1     fvdl {
 1.1     fvdl 	struct mbuf		*m_new = NULL;
 1.1     fvdl 	struct bge_rx_bd	*r;
 1.1     fvdl 	int			error;
 1.1     fvdl
 1.1     fvdl 	if (dmamap == NULL) {
 1.1     fvdl 		error = bus_dmamap_create(sc->bge_dmatag, MCLBYTES, 1,
 1.1     fvdl 		    MCLBYTES, 0, BUS_DMA_NOWAIT, &dmamap);
 1.1     fvdl 		if (error != 0)
 1.1     fvdl 			return error;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	sc->bge_cdata.bge_rx_std_map[i] = dmamap;
 1.1     fvdl
 1.1     fvdl 	if (m == NULL) {
 1.1     fvdl 		MGETHDR(m_new, M_DONTWAIT, MT_DATA);
 1.1     fvdl 		if (m_new == NULL) {
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 		}
 1.1     fvdl
 1.1     fvdl 		MCLGET(m_new, M_DONTWAIT);
 1.1     fvdl 		if (!(m_new->m_flags & M_EXT)) {
 1.1     fvdl 			m_freem(m_new);
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 		}
 1.1     fvdl 		m_new->m_len = m_new->m_pkthdr.len = MCLBYTES;
1.10     fvdl 		m_adj(m_new, ETHER_ALIGN);
 1.1     fvdl
 1.1     fvdl 		if (bus_dmamap_load_mbuf(sc->bge_dmatag, dmamap, m_new,
 1.1     fvdl 		    BUS_DMA_READ|BUS_DMA_NOWAIT))
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 	} else {
 1.1     fvdl 		m_new = m;
 1.1     fvdl 		m_new->m_len = m_new->m_pkthdr.len = MCLBYTES;
 1.1     fvdl 		m_new->m_data = m_new->m_ext.ext_buf;
1.10     fvdl 		m_adj(m_new, ETHER_ALIGN);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	sc->bge_cdata.bge_rx_std_chain[i] = m_new;
 1.1     fvdl 	r = &sc->bge_rdata->bge_rx_std_ring[i];
 1.1     fvdl 	bge_set_hostaddr(&r->bge_addr,
1.10     fvdl 	    dmamap->dm_segs[0].ds_addr);
 1.1     fvdl 	r->bge_flags = BGE_RXBDFLAG_END;
 1.1     fvdl 	r->bge_len = m_new->m_len;
 1.1     fvdl 	r->bge_idx = i;
 1.1     fvdl
 1.1     fvdl 	bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 	    offsetof(struct bge_ring_data, bge_rx_std_ring) +
 1.1     fvdl 		i * sizeof (struct bge_rx_bd),
 1.1     fvdl 	    sizeof (struct bge_rx_bd),
 1.1     fvdl 	    BUS_DMASYNC_PREWRITE|BUS_DMASYNC_PREREAD);
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Initialize a jumbo receive ring descriptor. This allocates
 1.1     fvdl  * a jumbo buffer from the pool managed internally by the driver.
 1.1     fvdl  */
 1.1     fvdl int
 1.1     fvdl bge_newbuf_jumbo(sc, i, m)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	int i;
 1.1     fvdl 	struct mbuf *m;
 1.1     fvdl {
 1.1     fvdl 	struct mbuf *m_new = NULL;
 1.1     fvdl 	struct bge_rx_bd *r;
 1.1     fvdl
 1.1     fvdl 	if (m == NULL) {
 1.1     fvdl 		caddr_t			*buf = NULL;
 1.1     fvdl
 1.1     fvdl 		/* Allocate the mbuf. */
 1.1     fvdl 		MGETHDR(m_new, M_DONTWAIT, MT_DATA);
 1.1     fvdl 		if (m_new == NULL) {
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 		}
 1.1     fvdl
 1.1     fvdl 		/* Allocate the jumbo buffer */
 1.1     fvdl 		buf = bge_jalloc(sc);
 1.1     fvdl 		if (buf == NULL) {
 1.1     fvdl 			m_freem(m_new);
 1.1     fvdl 			printf("%s: jumbo allocation failed "
 1.1     fvdl 			    "-- packet dropped!\n", sc->bge_dev.dv_xname);
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 		}
 1.1     fvdl
 1.1     fvdl 		/* Attach the buffer to the mbuf. */
 1.1     fvdl 		m_new->m_len = m_new->m_pkthdr.len = BGE_JUMBO_FRAMELEN;
 1.1     fvdl 		MEXTADD(m_new, buf, BGE_JUMBO_FRAMELEN, M_DEVBUF,
 1.1     fvdl 		    bge_jfree, sc);
 1.1     fvdl 	} else {
 1.1     fvdl 		m_new = m;
 1.1     fvdl 		m_new->m_data = m_new->m_ext.ext_buf;
 1.1     fvdl 		m_new->m_ext.ext_size = BGE_JUMBO_FRAMELEN;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	m_adj(m_new, ETHER_ALIGN);
 1.1     fvdl 	/* Set up the descriptor. */
 1.1     fvdl 	r = &sc->bge_rdata->bge_rx_jumbo_ring[i];
 1.1     fvdl 	sc->bge_cdata.bge_rx_jumbo_chain[i] = m_new;
 1.1     fvdl 	bge_set_hostaddr(&r->bge_addr, BGE_JUMBO_DMA_ADDR(sc, m_new));
 1.1     fvdl 	r->bge_flags = BGE_RXBDFLAG_END|BGE_RXBDFLAG_JUMBO_RING;
 1.1     fvdl 	r->bge_len = m_new->m_len;
 1.1     fvdl 	r->bge_idx = i;
 1.1     fvdl
 1.1     fvdl 	bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 	    offsetof(struct bge_ring_data, bge_rx_jumbo_ring) +
 1.1     fvdl 		i * sizeof (struct bge_rx_bd),
 1.1     fvdl 	    sizeof (struct bge_rx_bd),
 1.1     fvdl 	    BUS_DMASYNC_PREWRITE|BUS_DMASYNC_PREREAD);
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * The standard receive ring has 512 entries in it. At 2K per mbuf cluster,
 1.1     fvdl  * that's 1MB or memory, which is a lot. For now, we fill only the first
 1.1     fvdl  * 256 ring entries and hope that our CPU is fast enough to keep up with
 1.1     fvdl  * the NIC.
 1.1     fvdl  */
 1.1     fvdl int
 1.1     fvdl bge_init_rx_ring_std(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	int i;
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_flags & BGE_RXRING_VALID)
 1.1     fvdl 		return 0;
 1.1     fvdl
 1.1     fvdl 	for (i = 0; i < BGE_SSLOTS; i++) {
 1.1     fvdl 		if (bge_newbuf_std(sc, i, NULL, 0) == ENOBUFS)
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	sc->bge_std = i - 1;
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_RX_STD_PROD_LO, sc->bge_std);
 1.1     fvdl
 1.1     fvdl 	sc->bge_flags |= BGE_RXRING_VALID;
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_free_rx_ring_std(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	int i;
 1.1     fvdl
 1.1     fvdl 	if (!(sc->bge_flags & BGE_RXRING_VALID))
 1.1     fvdl 		return;
 1.1     fvdl
 1.1     fvdl 	for (i = 0; i < BGE_STD_RX_RING_CNT; i++) {
 1.1     fvdl 		if (sc->bge_cdata.bge_rx_std_chain[i] != NULL) {
 1.1     fvdl 			m_freem(sc->bge_cdata.bge_rx_std_chain[i]);
 1.1     fvdl 			sc->bge_cdata.bge_rx_std_chain[i] = NULL;
 1.1     fvdl 			bus_dmamap_destroy(sc->bge_dmatag,
 1.1     fvdl 			    sc->bge_cdata.bge_rx_std_map[i]);
 1.1     fvdl 		}
 1.1     fvdl 		memset((char *)&sc->bge_rdata->bge_rx_std_ring[i], 0,
 1.1     fvdl 		    sizeof(struct bge_rx_bd));
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	sc->bge_flags &= ~BGE_RXRING_VALID;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl int
 1.1     fvdl bge_init_rx_ring_jumbo(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	int i;
 1.1     fvdl 	struct bge_rcb *rcb;
 1.1     fvdl 	struct bge_rcb_opaque *rcbo;
 1.1     fvdl
 1.1     fvdl 	for (i = 0; i < BGE_JUMBO_RX_RING_CNT; i++) {
 1.1     fvdl 		if (bge_newbuf_jumbo(sc, i, NULL) == ENOBUFS)
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 	};
 1.1     fvdl
 1.1     fvdl 	sc->bge_jumbo = i - 1;
 1.1     fvdl
 1.1     fvdl 	rcb = &sc->bge_rdata->bge_info.bge_jumbo_rx_rcb;
 1.1     fvdl 	rcbo = (struct bge_rcb_opaque *)rcb;
 1.1     fvdl 	rcb->bge_flags = 0;
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_JUMBO_RCB_MAXLEN_FLAGS, rcbo->bge_reg2);
 1.1     fvdl
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_RX_JUMBO_PROD_LO, sc->bge_jumbo);
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_free_rx_ring_jumbo(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	int i;
 1.1     fvdl
 1.1     fvdl 	if (!(sc->bge_flags & BGE_JUMBO_RXRING_VALID))
 1.1     fvdl 		return;
 1.1     fvdl
 1.1     fvdl 	for (i = 0; i < BGE_JUMBO_RX_RING_CNT; i++) {
 1.1     fvdl 		if (sc->bge_cdata.bge_rx_jumbo_chain[i] != NULL) {
 1.1     fvdl 			m_freem(sc->bge_cdata.bge_rx_jumbo_chain[i]);
 1.1     fvdl 			sc->bge_cdata.bge_rx_jumbo_chain[i] = NULL;
 1.1     fvdl 		}
 1.1     fvdl 		memset((char *)&sc->bge_rdata->bge_rx_jumbo_ring[i], 0,
 1.1     fvdl 		    sizeof(struct bge_rx_bd));
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	sc->bge_flags &= ~BGE_JUMBO_RXRING_VALID;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_free_tx_ring(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	int i, freed;
 1.1     fvdl 	struct txdmamap_pool_entry *dma;
 1.1     fvdl
 1.1     fvdl 	if (!(sc->bge_flags & BGE_TXRING_VALID))
 1.1     fvdl 		return;
 1.1     fvdl
 1.1     fvdl 	freed = 0;
 1.1     fvdl
 1.1     fvdl 	for (i = 0; i < BGE_TX_RING_CNT; i++) {
 1.1     fvdl 		if (sc->bge_cdata.bge_tx_chain[i] != NULL) {
 1.1     fvdl 			freed++;
 1.1     fvdl 			m_freem(sc->bge_cdata.bge_tx_chain[i]);
 1.1     fvdl 			sc->bge_cdata.bge_tx_chain[i] = NULL;
 1.1     fvdl 			SLIST_INSERT_HEAD(&sc->txdma_list, sc->txdma[i],
 1.1     fvdl 					    link);
 1.1     fvdl 			sc->txdma[i] = 0;
 1.1     fvdl 		}
 1.1     fvdl 		memset((char *)&sc->bge_rdata->bge_tx_ring[i], 0,
 1.1     fvdl 		    sizeof(struct bge_tx_bd));
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	while ((dma = SLIST_FIRST(&sc->txdma_list))) {
 1.1     fvdl 		SLIST_REMOVE_HEAD(&sc->txdma_list, link);
 1.1     fvdl 		bus_dmamap_destroy(sc->bge_dmatag, dma->dmamap);
 1.1     fvdl 		free(dma, M_DEVBUF);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	sc->bge_flags &= ~BGE_TXRING_VALID;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl int
 1.1     fvdl bge_init_tx_ring(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	int i;
 1.1     fvdl 	bus_dmamap_t dmamap;
 1.1     fvdl 	struct txdmamap_pool_entry *dma;
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_flags & BGE_TXRING_VALID)
 1.1     fvdl 		return 0;
 1.1     fvdl
 1.1     fvdl 	sc->bge_txcnt = 0;
 1.1     fvdl 	sc->bge_tx_saved_considx = 0;
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_TX_HOST_PROD0_LO, 0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_TX_NIC_PROD0_LO, 0);
 1.1     fvdl
 1.1     fvdl 	SLIST_INIT(&sc->txdma_list);
 1.1     fvdl 	for (i = 0; i < BGE_RSLOTS; i++) {
 1.1     fvdl 		if (bus_dmamap_create(sc->bge_dmatag, ETHER_MAX_LEN_JUMBO,
 1.1     fvdl 		    BGE_NTXSEG, ETHER_MAX_LEN_JUMBO, 0, BUS_DMA_NOWAIT,
 1.1     fvdl 		    &dmamap))
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 		if (dmamap == NULL)
 1.1     fvdl 			panic("dmamap NULL in bge_init_tx_ring");
 1.1     fvdl 		dma = malloc(sizeof(*dma), M_DEVBUF, M_NOWAIT);
 1.1     fvdl 		if (dma == NULL) {
 1.1     fvdl 			printf("%s: can't alloc txdmamap_pool_entry\n",
 1.1     fvdl 			    sc->bge_dev.dv_xname);
 1.1     fvdl 			bus_dmamap_destroy(sc->bge_dmatag, dmamap);
 1.1     fvdl 			return (ENOMEM);
 1.1     fvdl 		}
 1.1     fvdl 		dma->dmamap = dmamap;
 1.1     fvdl 		SLIST_INSERT_HEAD(&sc->txdma_list, dma, link);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	sc->bge_flags |= BGE_TXRING_VALID;
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_setmulti(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	struct ethercom		*ac = &sc->ethercom;
 1.1     fvdl 	struct ifnet		*ifp = &ac->ec_if;
 1.1     fvdl 	struct ether_multi	*enm;
 1.1     fvdl 	struct ether_multistep  step;
 1.1     fvdl 	u_int32_t		hashes[4] = { 0, 0, 0, 0 };
 1.1     fvdl 	u_int32_t		h;
 1.1     fvdl 	int			i;
 1.1     fvdl
1.13  thorpej 	if (ifp->if_flags & IFF_PROMISC)
1.13  thorpej 		goto allmulti;
 1.1     fvdl
 1.1     fvdl 	/* Now program new ones. */
 1.1     fvdl 	ETHER_FIRST_MULTI(step, ac, enm);
 1.1     fvdl 	while (enm != NULL) {
1.13  thorpej 		if (memcmp(enm->enm_addrlo, enm->enm_addrhi, ETHER_ADDR_LEN)) {
1.13  thorpej 			/*
1.13  thorpej 			 * We must listen to a range of multicast addresses.
1.13  thorpej 			 * For now, just accept all multicasts, rather than
1.13  thorpej 			 * trying to set only those filter bits needed to match
1.13  thorpej 			 * the range.  (At this time, the only use of address
1.13  thorpej 			 * ranges is for IP multicast routing, for which the
1.13  thorpej 			 * range is big enough to require all bits set.)
1.13  thorpej 			 */
1.13  thorpej 			goto allmulti;
1.13  thorpej 		}
1.13  thorpej
1.13  thorpej 		h = ether_crc32_le(enm->enm_addrlo, ETHER_ADDR_LEN);
1.13  thorpej
1.13  thorpej 		/* Just want the 7 least-significant bits. */
1.13  thorpej 		h &= 0x7f;
1.13  thorpej
 1.1     fvdl 		hashes[(h & 0x60) >> 5] |= 1 << (h & 0x1F);
 1.1     fvdl 		ETHER_NEXT_MULTI(step, enm);
 1.1     fvdl 	}
 1.1     fvdl
1.13  thorpej 	ifp->if_flags &= ~IFF_ALLMULTI;
1.13  thorpej 	goto setit;
1.13  thorpej
1.13  thorpej  allmulti:
1.13  thorpej 	ifp->if_flags |= IFF_ALLMULTI;
1.13  thorpej 	hashes[0] = hashes[1] = hashes[2] = hashes[3] = 0xffffffff;
1.13  thorpej
1.13  thorpej  setit:
 1.1     fvdl 	for (i = 0; i < 4; i++)
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_MAR0 + (i * 4), hashes[i]);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl int bge_swapbits[] = {
 1.1     fvdl 	0,
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_DATA,
 1.1     fvdl 	BGE_MODECTL_WORDSWAP_DATA,
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_NONFRAME,
 1.1     fvdl 	BGE_MODECTL_WORDSWAP_NONFRAME,
 1.1     fvdl
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_DATA|BGE_MODECTL_WORDSWAP_DATA,
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_DATA|BGE_MODECTL_BYTESWAP_NONFRAME,
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_DATA|BGE_MODECTL_WORDSWAP_NONFRAME,
 1.1     fvdl
 1.1     fvdl 	BGE_MODECTL_WORDSWAP_DATA|BGE_MODECTL_BYTESWAP_NONFRAME,
 1.1     fvdl 	BGE_MODECTL_WORDSWAP_DATA|BGE_MODECTL_WORDSWAP_NONFRAME,
 1.1     fvdl
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_NONFRAME|BGE_MODECTL_WORDSWAP_NONFRAME,
 1.1     fvdl
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_DATA|BGE_MODECTL_WORDSWAP_DATA|
 1.1     fvdl 	    BGE_MODECTL_BYTESWAP_NONFRAME,
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_DATA|BGE_MODECTL_WORDSWAP_DATA|
 1.1     fvdl 	    BGE_MODECTL_WORDSWAP_NONFRAME,
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_DATA|BGE_MODECTL_BYTESWAP_NONFRAME|
 1.1     fvdl 	    BGE_MODECTL_WORDSWAP_NONFRAME,
 1.1     fvdl 	BGE_MODECTL_WORDSWAP_DATA|BGE_MODECTL_BYTESWAP_NONFRAME|
 1.1     fvdl 	    BGE_MODECTL_WORDSWAP_NONFRAME,
 1.1     fvdl
 1.1     fvdl 	BGE_MODECTL_BYTESWAP_DATA|BGE_MODECTL_WORDSWAP_DATA|
 1.1     fvdl 	    BGE_MODECTL_BYTESWAP_NONFRAME|BGE_MODECTL_WORDSWAP_NONFRAME,
 1.1     fvdl };
 1.1     fvdl
 1.1     fvdl int bge_swapindex = 0;
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Do endian, PCI and DMA initialization. Also check the on-board ROM
 1.1     fvdl  * self-test results.
 1.1     fvdl  */
 1.1     fvdl int
 1.1     fvdl bge_chipinit(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	u_int32_t		cachesize;
 1.1     fvdl 	int			i;
 1.1     fvdl 	struct pci_attach_args	*pa = &(sc->bge_pa);
 1.1     fvdl
 1.1     fvdl
 1.1     fvdl 	/* Set endianness before we access any non-PCI registers. */
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_MISC_CTL,
 1.1     fvdl 	    BGE_INIT);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Check the 'ROM failed' bit on the RX CPU to see if
 1.1     fvdl 	 * self-tests passed.
 1.1     fvdl 	 */
 1.1     fvdl 	if (CSR_READ_4(sc, BGE_RXCPU_MODE) & BGE_RXCPUMODE_ROMFAIL) {
 1.1     fvdl 		printf("%s: RX CPU self-diagnostics failed!\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		return(ENODEV);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Clear the MAC control register */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MAC_MODE, 0);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Clear the MAC statistics block in the NIC's
 1.1     fvdl 	 * internal memory.
 1.1     fvdl 	 */
 1.1     fvdl 	for (i = BGE_STATS_BLOCK;
 1.1     fvdl 	    i < BGE_STATS_BLOCK_END + 1; i += sizeof(u_int32_t))
 1.1     fvdl 		BGE_MEMWIN_WRITE(pa->pa_pc, pa->pa_tag, i, 0);
 1.1     fvdl
 1.1     fvdl 	for (i = BGE_STATUS_BLOCK;
 1.1     fvdl 	    i < BGE_STATUS_BLOCK_END + 1; i += sizeof(u_int32_t))
 1.1     fvdl 		BGE_MEMWIN_WRITE(pa->pa_pc, pa->pa_tag, i, 0);
 1.1     fvdl
 1.1     fvdl 	/* Set up the PCI DMA control register. */
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_DMA_RW_CTL,
 1.1     fvdl 	    BGE_PCI_READ_CMD|BGE_PCI_WRITE_CMD|0x0F);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Set up general mode register.
 1.1     fvdl 	 */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MODE_CTL, BGE_DMA_SWAP_OPTIONS|
 1.1     fvdl 		    BGE_MODECTL_MAC_ATTN_INTR|BGE_MODECTL_HOST_SEND_BDS|
 1.1     fvdl 		    BGE_MODECTL_NO_RX_CRC|BGE_MODECTL_TX_NO_PHDR_CSUM|
 1.1     fvdl 		    BGE_MODECTL_RX_NO_PHDR_CSUM);
 1.1     fvdl
 1.1     fvdl 	/* Get cache line size. */
 1.1     fvdl 	cachesize = pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_CACHESZ);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Avoid violating PCI spec on certain chip revs.
 1.1     fvdl 	 */
 1.1     fvdl 	if (pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_CMD) &
 1.1     fvdl 	    PCIM_CMD_MWIEN) {
 1.1     fvdl 		switch(cachesize) {
 1.1     fvdl 		case 1:
 1.1     fvdl 			PCI_SETBIT(pa->pa_pc, pa->pa_tag, BGE_PCI_DMA_RW_CTL,
 1.1     fvdl 				   BGE_PCI_WRITE_BNDRY_16BYTES);
 1.1     fvdl 			break;
 1.1     fvdl 		case 2:
 1.1     fvdl 			PCI_SETBIT(pa->pa_pc, pa->pa_tag, BGE_PCI_DMA_RW_CTL,
 1.1     fvdl 				   BGE_PCI_WRITE_BNDRY_32BYTES);
 1.1     fvdl 			break;
 1.1     fvdl 		case 4:
 1.1     fvdl 			PCI_SETBIT(pa->pa_pc, pa->pa_tag, BGE_PCI_DMA_RW_CTL,
 1.1     fvdl 				   BGE_PCI_WRITE_BNDRY_64BYTES);
 1.1     fvdl 			break;
 1.1     fvdl 		case 8:
 1.1     fvdl 			PCI_SETBIT(pa->pa_pc, pa->pa_tag, BGE_PCI_DMA_RW_CTL,
 1.1     fvdl 				   BGE_PCI_WRITE_BNDRY_128BYTES);
 1.1     fvdl 			break;
 1.1     fvdl 		case 16:
 1.1     fvdl 			PCI_SETBIT(pa->pa_pc, pa->pa_tag, BGE_PCI_DMA_RW_CTL,
 1.1     fvdl 				   BGE_PCI_WRITE_BNDRY_256BYTES);
 1.1     fvdl 			break;
 1.1     fvdl 		case 32:
 1.1     fvdl 			PCI_SETBIT(pa->pa_pc, pa->pa_tag, BGE_PCI_DMA_RW_CTL,
 1.1     fvdl 				   BGE_PCI_WRITE_BNDRY_512BYTES);
 1.1     fvdl 			break;
 1.1     fvdl 		case 64:
 1.1     fvdl 			PCI_SETBIT(pa->pa_pc, pa->pa_tag, BGE_PCI_DMA_RW_CTL,
 1.1     fvdl 				   BGE_PCI_WRITE_BNDRY_1024BYTES);
 1.1     fvdl 			break;
 1.1     fvdl 		default:
 1.1     fvdl 		/* Disable PCI memory write and invalidate. */
 1.1     fvdl #if 0
 1.1     fvdl 			if (bootverbose)
 1.1     fvdl 				printf("%s: cache line size %d not "
 1.1     fvdl 				    "supported; disabling PCI MWI\n",
 1.1     fvdl 				    sc->bge_dev.dv_xname, cachesize);
 1.1     fvdl #endif
 1.1     fvdl 			PCI_CLRBIT(pa->pa_pc, pa->pa_tag, BGE_PCI_CMD,
 1.1     fvdl 			    PCIM_CMD_MWIEN);
 1.1     fvdl 			break;
 1.1     fvdl 		}
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl #ifdef __brokenalpha__
 1.1     fvdl 	/*
 1.1     fvdl 	 * Must insure that we do not cross an 8K (bytes) boundary
 1.1     fvdl 	 * for DMA reads.  Our highest limit is 1K bytes.  This is a
 1.1     fvdl 	 * restriction on some ALPHA platforms with early revision
 1.1     fvdl 	 * 21174 PCI chipsets, such as the AlphaPC 164lx
 1.1     fvdl 	 */
 1.1     fvdl 	PCI_SETBIT(sc, BGE_PCI_DMA_RW_CTL, BGE_PCI_READ_BNDRY_1024, 4);
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl 	/* Set the timer prescaler (always 66Mhz) */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MISC_CFG, 65 << 1/*BGE_32BITTIME_66MHZ*/);
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl int
 1.1     fvdl bge_blockinit(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	struct bge_rcb		*rcb;
 1.1     fvdl 	struct bge_rcb_opaque	*rcbo;
 1.1     fvdl 	bus_size_t		rcb_addr;
 1.1     fvdl 	int			i;
 1.1     fvdl 	struct ifnet		*ifp = &sc->ethercom.ec_if;
 1.1     fvdl 	bge_hostaddr		taddr;
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Initialize the memory window pointer register so that
 1.1     fvdl 	 * we can access the first 32K of internal NIC RAM. This will
 1.1     fvdl 	 * allow us to set up the TX send ring RCBs and the RX return
 1.1     fvdl 	 * ring RCBs, plus other things which live in NIC memory.
 1.1     fvdl 	 */
 1.1     fvdl
 1.1     fvdl 	pci_conf_write(sc->bge_pa.pa_pc, sc->bge_pa.pa_tag,
 1.1     fvdl 	    BGE_PCI_MEMWIN_BASEADDR, 0);
 1.1     fvdl
 1.1     fvdl 	/* Configure mbuf memory pool */
 1.1     fvdl 	if (sc->bge_extram) {
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_BMAN_MBUFPOOL_BASEADDR, BGE_EXT_SSRAM);
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_BMAN_MBUFPOOL_LEN, 0x18000);
 1.1     fvdl 	} else {
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_BMAN_MBUFPOOL_BASEADDR, BGE_BUFFPOOL_1);
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_BMAN_MBUFPOOL_LEN, 0x18000);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Configure DMA resource pool */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_BMAN_DMA_DESCPOOL_BASEADDR, BGE_DMA_DESCRIPTORS);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_BMAN_DMA_DESCPOOL_LEN, 0x2000);
 1.1     fvdl
 1.1     fvdl 	/* Configure mbuf pool watermarks */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_BMAN_MBUFPOOL_READDMA_LOWAT, 24);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_BMAN_MBUFPOOL_MACRX_LOWAT, 24);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_BMAN_MBUFPOOL_HIWAT, 48);
 1.1     fvdl
 1.1     fvdl 	/* Configure DMA resource watermarks */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_BMAN_DMA_DESCPOOL_LOWAT, 5);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_BMAN_DMA_DESCPOOL_HIWAT, 10);
 1.1     fvdl
 1.1     fvdl 	/* Enable buffer manager */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_BMAN_MODE,
 1.1     fvdl 	    BGE_BMANMODE_ENABLE|BGE_BMANMODE_LOMBUF_ATTN);
 1.1     fvdl
 1.1     fvdl 	/* Poll for buffer manager start indication */
 1.1     fvdl 	for (i = 0; i < BGE_TIMEOUT; i++) {
 1.1     fvdl 		if (CSR_READ_4(sc, BGE_BMAN_MODE) & BGE_BMANMODE_ENABLE)
 1.1     fvdl 			break;
 1.1     fvdl 		DELAY(10);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (i == BGE_TIMEOUT) {
 1.1     fvdl 		printf("%s: buffer manager failed to start\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		return(ENXIO);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Enable flow-through queues */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_FTQ_RESET, 0xFFFFFFFF);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_FTQ_RESET, 0);
 1.1     fvdl
 1.1     fvdl 	/* Wait until queue initialization is complete */
 1.1     fvdl 	for (i = 0; i < BGE_TIMEOUT; i++) {
 1.1     fvdl 		if (CSR_READ_4(sc, BGE_FTQ_RESET) == 0)
 1.1     fvdl 			break;
 1.1     fvdl 		DELAY(10);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (i == BGE_TIMEOUT) {
 1.1     fvdl 		printf("%s: flow-through queue init failed\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		return(ENXIO);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Initialize the standard RX ring control block */
 1.1     fvdl 	rcb = &sc->bge_rdata->bge_info.bge_std_rx_rcb;
 1.1     fvdl 	bge_set_hostaddr(&rcb->bge_hostaddr,
 1.1     fvdl 	    BGE_RING_DMA_ADDR(sc, bge_rx_std_ring));
 1.1     fvdl 	rcb->bge_max_len = BGE_MAX_FRAMELEN;
 1.1     fvdl 	if (sc->bge_extram)
 1.1     fvdl 		rcb->bge_nicaddr = BGE_EXT_STD_RX_RINGS;
 1.1     fvdl 	else
 1.1     fvdl 		rcb->bge_nicaddr = BGE_STD_RX_RINGS;
 1.1     fvdl 	rcb->bge_flags = 0;
 1.1     fvdl 	rcbo = (struct bge_rcb_opaque *)rcb;
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_STD_RCB_HADDR_HI, rcbo->bge_reg0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_STD_RCB_HADDR_LO, rcbo->bge_reg1);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_STD_RCB_MAXLEN_FLAGS, rcbo->bge_reg2);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_STD_RCB_NICADDR, rcbo->bge_reg3);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Initialize the jumbo RX ring control block
 1.1     fvdl 	 * We set the 'ring disabled' bit in the flags
 1.1     fvdl 	 * field until we're actually ready to start
 1.1     fvdl 	 * using this ring (i.e. once we set the MTU
 1.1     fvdl 	 * high enough to require it).
 1.1     fvdl 	 */
 1.1     fvdl 	rcb = &sc->bge_rdata->bge_info.bge_jumbo_rx_rcb;
 1.1     fvdl 	bge_set_hostaddr(&rcb->bge_hostaddr,
 1.1     fvdl 	    BGE_RING_DMA_ADDR(sc, bge_rx_jumbo_ring));
 1.1     fvdl 	rcb->bge_max_len = BGE_MAX_FRAMELEN;
 1.1     fvdl 	if (sc->bge_extram)
 1.1     fvdl 		rcb->bge_nicaddr = BGE_EXT_JUMBO_RX_RINGS;
 1.1     fvdl 	else
 1.1     fvdl 		rcb->bge_nicaddr = BGE_JUMBO_RX_RINGS;
 1.1     fvdl 	rcb->bge_flags = BGE_RCB_FLAG_RING_DISABLED;
 1.1     fvdl
 1.1     fvdl 	rcbo = (struct bge_rcb_opaque *)rcb;
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_JUMBO_RCB_HADDR_HI, rcbo->bge_reg0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_JUMBO_RCB_HADDR_LO, rcbo->bge_reg1);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_JUMBO_RCB_MAXLEN_FLAGS, rcbo->bge_reg2);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_JUMBO_RCB_NICADDR, rcbo->bge_reg3);
 1.1     fvdl
 1.1     fvdl 	/* Set up dummy disabled mini ring RCB */
 1.1     fvdl 	rcb = &sc->bge_rdata->bge_info.bge_mini_rx_rcb;
 1.1     fvdl 	rcb->bge_flags = BGE_RCB_FLAG_RING_DISABLED;
 1.1     fvdl 	rcbo = (struct bge_rcb_opaque *)rcb;
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_MINI_RCB_MAXLEN_FLAGS, rcbo->bge_reg2);
 1.1     fvdl
 1.1     fvdl 	bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 	    offsetof(struct bge_ring_data, bge_info), sizeof (struct bge_gib),
 1.1     fvdl 	    BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Set the BD ring replentish thresholds. The recommended
 1.1     fvdl 	 * values are 1/8th the number of descriptors allocated to
 1.1     fvdl 	 * each ring.
 1.1     fvdl 	 */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RBDI_STD_REPL_THRESH, BGE_STD_RX_RING_CNT/8);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RBDI_JUMBO_REPL_THRESH, BGE_JUMBO_RX_RING_CNT/8);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Disable all unused send rings by setting the 'ring disabled'
 1.1     fvdl 	 * bit in the flags field of all the TX send ring control blocks.
 1.1     fvdl 	 * These are located in NIC memory.
 1.1     fvdl 	 */
 1.1     fvdl 	rcb_addr = BGE_MEMWIN_START + BGE_SEND_RING_RCB;
 1.1     fvdl 	for (i = 0; i < BGE_TX_RINGS_EXTSSRAM_MAX; i++) {
 1.1     fvdl 		RCB_WRITE_2(sc, rcb_addr, bge_flags,
 1.1     fvdl 			    BGE_RCB_FLAG_RING_DISABLED);
 1.1     fvdl 		RCB_WRITE_2(sc, rcb_addr, bge_max_len, 0);
 1.1     fvdl 		RCB_WRITE_4(sc, rcb_addr, bge_nicaddr, 0);
 1.1     fvdl 		rcb_addr += sizeof(struct bge_rcb);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Configure TX RCB 0 (we use only the first ring) */
 1.1     fvdl 	rcb_addr = BGE_MEMWIN_START + BGE_SEND_RING_RCB;
 1.1     fvdl 	bge_set_hostaddr(&taddr, BGE_RING_DMA_ADDR(sc, bge_tx_ring));
 1.1     fvdl 	RCB_WRITE_4(sc, rcb_addr, bge_hostaddr.bge_addr_hi, taddr.bge_addr_hi);
 1.1     fvdl 	RCB_WRITE_4(sc, rcb_addr, bge_hostaddr.bge_addr_lo, taddr.bge_addr_lo);
 1.1     fvdl 	RCB_WRITE_4(sc, rcb_addr, bge_nicaddr,
 1.1     fvdl 		    BGE_NIC_TXRING_ADDR(0, BGE_TX_RING_CNT));
 1.1     fvdl 	RCB_WRITE_2(sc, rcb_addr, bge_max_len, BGE_TX_RING_CNT);
 1.1     fvdl 	RCB_WRITE_2(sc, rcb_addr, bge_flags, 0);
 1.1     fvdl
 1.1     fvdl 	/* Disable all unused RX return rings */
 1.1     fvdl 	rcb_addr = BGE_MEMWIN_START + BGE_RX_RETURN_RING_RCB;
 1.1     fvdl 	for (i = 0; i < BGE_RX_RINGS_MAX; i++) {
 1.1     fvdl 		RCB_WRITE_4(sc, rcb_addr, bge_hostaddr.bge_addr_hi, 0);
 1.1     fvdl 		RCB_WRITE_4(sc, rcb_addr, bge_hostaddr.bge_addr_lo, 0);
 1.1     fvdl 		RCB_WRITE_2(sc, rcb_addr, bge_flags,
 1.1     fvdl 			    BGE_RCB_FLAG_RING_DISABLED);
 1.1     fvdl 		RCB_WRITE_2(sc, rcb_addr, bge_max_len, BGE_RETURN_RING_CNT);
 1.1     fvdl 		RCB_WRITE_4(sc, rcb_addr, bge_nicaddr, 0);
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_MBX_RX_CONS0_LO +
 1.1     fvdl 		    (i * (sizeof(u_int64_t))), 0);
 1.1     fvdl 		rcb_addr += sizeof(struct bge_rcb);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Initialize RX ring indexes */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_RX_STD_PROD_LO, 0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_RX_JUMBO_PROD_LO, 0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_RX_MINI_PROD_LO, 0);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Set up RX return ring 0
 1.1     fvdl 	 * Note that the NIC address for RX return rings is 0x00000000.
 1.1     fvdl 	 * The return rings live entirely within the host, so the
 1.1     fvdl 	 * nicaddr field in the RCB isn't used.
 1.1     fvdl 	 */
 1.1     fvdl 	rcb_addr = BGE_MEMWIN_START + BGE_RX_RETURN_RING_RCB;
 1.1     fvdl 	bge_set_hostaddr(&taddr, BGE_RING_DMA_ADDR(sc, bge_rx_return_ring));
 1.1     fvdl 	RCB_WRITE_4(sc, rcb_addr, bge_hostaddr.bge_addr_hi, taddr.bge_addr_hi);
 1.1     fvdl 	RCB_WRITE_4(sc, rcb_addr, bge_hostaddr.bge_addr_lo, taddr.bge_addr_lo);
 1.1     fvdl 	RCB_WRITE_4(sc, rcb_addr, bge_nicaddr, 0x00000000);
 1.1     fvdl 	RCB_WRITE_2(sc, rcb_addr, bge_max_len, BGE_RETURN_RING_CNT);
 1.1     fvdl 	RCB_WRITE_2(sc, rcb_addr, bge_flags, 0);
 1.1     fvdl
 1.1     fvdl 	/* Set random backoff seed for TX */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_TX_RANDOM_BACKOFF,
 1.1     fvdl 	    LLADDR(ifp->if_sadl)[0] + LLADDR(ifp->if_sadl)[1] +
 1.1     fvdl 	    LLADDR(ifp->if_sadl)[2] + LLADDR(ifp->if_sadl)[3] +
 1.1     fvdl 	    LLADDR(ifp->if_sadl)[4] + LLADDR(ifp->if_sadl)[5] +
 1.1     fvdl 	    BGE_TX_BACKOFF_SEED_MASK);
 1.1     fvdl
 1.1     fvdl 	/* Set inter-packet gap */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_TX_LENGTHS, 0x2620);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Specify which ring to use for packets that don't match
 1.1     fvdl 	 * any RX rules.
 1.1     fvdl 	 */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_RULES_CFG, 0x08);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Configure number of RX lists. One interrupt distribution
 1.1     fvdl 	 * list, sixteen active lists, one bad frames class.
 1.1     fvdl 	 */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RXLP_CFG, 0x181);
 1.1     fvdl
 1.1     fvdl 	/* Inialize RX list placement stats mask. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RXLP_STATS_ENABLE_MASK, 0x007FFFFF);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RXLP_STATS_CTL, 0x1);
 1.1     fvdl
 1.1     fvdl 	/* Disable host coalescing until we get it set up */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_MODE, 0x00000000);
 1.1     fvdl
 1.1     fvdl 	/* Poll to make sure it's shut down. */
 1.1     fvdl 	for (i = 0; i < BGE_TIMEOUT; i++) {
 1.1     fvdl 		if (!(CSR_READ_4(sc, BGE_HCC_MODE) & BGE_HCCMODE_ENABLE))
 1.1     fvdl 			break;
 1.1     fvdl 		DELAY(10);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (i == BGE_TIMEOUT) {
 1.1     fvdl 		printf("%s: host coalescing engine failed to idle\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		return(ENXIO);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Set up host coalescing defaults */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_RX_COAL_TICKS, sc->bge_rx_coal_ticks);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_TX_COAL_TICKS, sc->bge_tx_coal_ticks);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_RX_MAX_COAL_BDS, sc->bge_rx_max_coal_bds);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_TX_MAX_COAL_BDS, sc->bge_tx_max_coal_bds);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_RX_COAL_TICKS_INT, 0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_TX_COAL_TICKS_INT, 0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_RX_MAX_COAL_BDS_INT, 0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_TX_MAX_COAL_BDS_INT, 0);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_STATS_TICKS, sc->bge_stat_ticks);
 1.1     fvdl
 1.1     fvdl 	/* Set up address of statistics block */
 1.1     fvdl 	bge_set_hostaddr(&taddr, BGE_RING_DMA_ADDR(sc, bge_info.bge_stats));
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_STATS_BASEADDR, BGE_STATS_BLOCK);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_STATS_ADDR_HI, taddr.bge_addr_hi);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_STATS_ADDR_LO, taddr.bge_addr_lo);
 1.1     fvdl
 1.1     fvdl 	/* Set up address of status block */
 1.1     fvdl 	bge_set_hostaddr(&taddr, BGE_RING_DMA_ADDR(sc, bge_status_block));
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_STATUSBLK_BASEADDR, BGE_STATUS_BLOCK);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_STATUSBLK_ADDR_HI, taddr.bge_addr_hi);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_STATUSBLK_ADDR_LO, taddr.bge_addr_lo);
 1.1     fvdl 	sc->bge_rdata->bge_status_block.bge_idx[0].bge_rx_prod_idx = 0;
 1.1     fvdl 	sc->bge_rdata->bge_status_block.bge_idx[0].bge_tx_cons_idx = 0;
 1.1     fvdl
 1.1     fvdl 	/* Turn on host coalescing state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_HCC_MODE, BGE_HCCMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on RX BD completion state machine and enable attentions */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RBDC_MODE,
 1.1     fvdl 	    BGE_RBDCMODE_ENABLE|BGE_RBDCMODE_ATTN);
 1.1     fvdl
 1.1     fvdl 	/* Turn on RX list placement state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RXLP_MODE, BGE_RXLPMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on RX list selector state machine. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RXLS_MODE, BGE_RXLSMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on DMA, clear stats */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MAC_MODE, BGE_MACMODE_TXDMA_ENB|
 1.1     fvdl 	    BGE_MACMODE_RXDMA_ENB|BGE_MACMODE_RX_STATS_CLEAR|
 1.1     fvdl 	    BGE_MACMODE_TX_STATS_CLEAR|BGE_MACMODE_RX_STATS_ENB|
 1.1     fvdl 	    BGE_MACMODE_TX_STATS_ENB|BGE_MACMODE_FRMHDR_DMA_ENB|
 1.1     fvdl 	    (sc->bge_tbi ? BGE_PORTMODE_TBI : BGE_PORTMODE_MII));
 1.1     fvdl
 1.1     fvdl 	/* Set misc. local control, enable interrupts on attentions */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MISC_LOCAL_CTL, BGE_MLC_INTR_ONATTN);
 1.1     fvdl
 1.1     fvdl #ifdef notdef
 1.1     fvdl 	/* Assert GPIO pins for PHY reset */
 1.1     fvdl 	BGE_SETBIT(sc, BGE_MISC_LOCAL_CTL, BGE_MLC_MISCIO_OUT0|
 1.1     fvdl 	    BGE_MLC_MISCIO_OUT1|BGE_MLC_MISCIO_OUT2);
 1.1     fvdl 	BGE_SETBIT(sc, BGE_MISC_LOCAL_CTL, BGE_MLC_MISCIO_OUTEN0|
 1.1     fvdl 	    BGE_MLC_MISCIO_OUTEN1|BGE_MLC_MISCIO_OUTEN2);
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl 	/* Turn on DMA completion state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_DMAC_MODE, BGE_DMACMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on write DMA state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_WDMA_MODE,
 1.1     fvdl 	    BGE_WDMAMODE_ENABLE|BGE_WDMAMODE_ALL_ATTNS);
 1.1     fvdl
 1.1     fvdl 	/* Turn on read DMA state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RDMA_MODE,
 1.1     fvdl 	    BGE_RDMAMODE_ENABLE|BGE_RDMAMODE_ALL_ATTNS);
 1.1     fvdl
 1.1     fvdl 	/* Turn on RX data completion state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RDC_MODE, BGE_RDCMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on RX BD initiator state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RBDI_MODE, BGE_RBDIMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on RX data and RX BD initiator state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RDBDI_MODE, BGE_RDBDIMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on Mbuf cluster free state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBCF_MODE, BGE_MBCFMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on send BD completion state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_SBDC_MODE, BGE_SBDCMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on send data completion state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_SDC_MODE, BGE_SDCMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on send data initiator state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_SDI_MODE, BGE_SDIMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on send BD initiator state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_SBDI_MODE, BGE_SBDIMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on send BD selector state machine */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_SRS_MODE, BGE_SRSMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_SDI_STATS_ENABLE_MASK, 0x007FFFFF);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_SDI_STATS_CTL,
 1.1     fvdl 	    BGE_SDISTATSCTL_ENABLE|BGE_SDISTATSCTL_FASTER);
 1.1     fvdl
 1.1     fvdl 	/* init LED register */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MAC_LED_CTL, 0x00000000);
 1.1     fvdl
 1.1     fvdl 	/* ack/clear link change events */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MAC_STS, BGE_MACSTAT_SYNC_CHANGED|
 1.1     fvdl 	    BGE_MACSTAT_CFG_CHANGED);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MI_STS, 0);
 1.1     fvdl
 1.1     fvdl 	/* Enable PHY auto polling (for MII/GMII only) */
 1.1     fvdl 	if (sc->bge_tbi) {
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_MI_STS, BGE_MISTS_LINK);
 1.1     fvdl  	} else {
 1.1     fvdl 		BGE_SETBIT(sc, BGE_MI_MODE, BGE_MIMODE_AUTOPOLL|10<<16);
 1.2     fvdl 		if (BGE_IS_5700_Ax_Bx(sc->bge_asicrev))
 1.1     fvdl 			CSR_WRITE_4(sc, BGE_MAC_EVT_ENB,
 1.1     fvdl 			    BGE_EVTENB_MI_INTERRUPT);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Enable link state change attentions. */
 1.1     fvdl 	BGE_SETBIT(sc, BGE_MAC_EVT_ENB, BGE_EVTENB_LINK_CHANGED);
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
1.16  thorpej static const struct bge_revision {
1.16  thorpej 	uint32_t		br_asicrev;
1.16  thorpej 	uint32_t		br_quirks;
1.16  thorpej 	const char		*br_name;
1.16  thorpej } bge_revisions[] = {
1.16  thorpej 	{ BGE_ASICREV_BCM5700_A0,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5700 A0" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5700_A1,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5700 A1" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5700_B0,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5700 B0" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5700_B1,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5700 B1" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5700_B2,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5700 B2" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5700_ALTIMA,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5700 Altima" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5700_C0,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5700 C0" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5701_A0,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5701 A0" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5701_B0,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5701 B0" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5701_B2,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5701 B2" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5701_B5,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5701 B5" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5703_A0,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5703 A0" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5703_A1,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5703 A1" },
1.16  thorpej
1.16  thorpej 	{ BGE_ASICREV_BCM5703_A2,
1.16  thorpej 	  0,
1.16  thorpej 	  "BCM5703 A2" },
1.16  thorpej
1.16  thorpej 	{ 0, 0, NULL }
1.16  thorpej };
1.16  thorpej
1.16  thorpej static const struct bge_revision *
1.16  thorpej bge_lookup_rev(uint32_t asicrev)
1.16  thorpej {
1.16  thorpej 	const struct bge_revision *br;
1.16  thorpej
1.16  thorpej 	for (br = bge_revisions; br->br_name != NULL; br++) {
1.16  thorpej 		if (br->br_asicrev == asicrev)
1.16  thorpej 			return (br);
1.16  thorpej 	}
1.16  thorpej
1.16  thorpej 	return (NULL);
1.16  thorpej }
1.16  thorpej
 1.7  thorpej static const struct bge_product {
 1.7  thorpej 	pci_vendor_id_t		bp_vendor;
 1.7  thorpej 	pci_product_id_t	bp_product;
 1.7  thorpej 	const char		*bp_name;
 1.7  thorpej } bge_products[] = {
 1.7  thorpej 	/*
 1.7  thorpej 	 * The BCM5700 documentation seems to indicate that the hardware
 1.7  thorpej 	 * still has the Alteon vendor ID burned into it, though it
 1.7  thorpej 	 * should always be overridden by the value in the EEPROM.  We'll
 1.7  thorpej 	 * check for it anyway.
 1.7  thorpej 	 */
 1.7  thorpej 	{ PCI_VENDOR_ALTEON,
 1.7  thorpej 	  PCI_PRODUCT_ALTEON_BCM5700,
 1.7  thorpej 	  "Broadcom BCM5700 Gigabit Ethernet" },
 1.7  thorpej 	{ PCI_VENDOR_ALTEON,
 1.7  thorpej 	  PCI_PRODUCT_ALTEON_BCM5701,
 1.7  thorpej 	  "Broadcom BCM5701 Gigabit Ethernet" },
 1.7  thorpej
 1.7  thorpej 	{ PCI_VENDOR_ALTIMA,
 1.7  thorpej 	  PCI_PRODUCT_ALTIMA_AC1000,
 1.7  thorpej 	  "Altima AC1000 Gigabit Ethernet" },
1.14    enami 	{ PCI_VENDOR_ALTIMA,
1.14    enami 	  PCI_PRODUCT_ALTIMA_AC1001,
1.14    enami 	  "Altima AC1001 Gigabit Ethernet" },
 1.7  thorpej 	{ PCI_VENDOR_ALTIMA,
 1.7  thorpej 	  PCI_PRODUCT_ALTIMA_AC9100,
 1.7  thorpej 	  "Altima AC9100 Gigabit Ethernet" },
 1.7  thorpej
 1.7  thorpej 	{ PCI_VENDOR_BROADCOM,
 1.7  thorpej 	  PCI_PRODUCT_BROADCOM_BCM5700,
 1.7  thorpej 	  "Broadcom BCM5700 Gigabit Ethernet" },
 1.7  thorpej 	{ PCI_VENDOR_BROADCOM,
 1.7  thorpej 	  PCI_PRODUCT_BROADCOM_BCM5701,
 1.7  thorpej 	  "Broadcom BCM5700 Gigabit Ethernet" },
 1.7  thorpej
 1.7  thorpej 	{ PCI_VENDOR_SCHNEIDERKOCH,
 1.7  thorpej 	  PCI_PRODUCT_SCHNEIDERKOCH_SK_9DX1,
 1.8  thorpej 	  "SysKonnect SK-9Dx1 Gigabit Ethernet" },
 1.7  thorpej
 1.7  thorpej 	{ PCI_VENDOR_3COM,
 1.7  thorpej 	  PCI_PRODUCT_3COM_3C996,
 1.7  thorpej 	  "3Com 3c996 Gigabit Ethernet" },
 1.7  thorpej
 1.7  thorpej 	{ 0,
 1.7  thorpej 	  0,
 1.7  thorpej 	  NULL },
 1.7  thorpej };
 1.7  thorpej
 1.7  thorpej static const struct bge_product *
 1.7  thorpej bge_lookup(const struct pci_attach_args *pa)
 1.7  thorpej {
 1.7  thorpej 	const struct bge_product *bp;
 1.7  thorpej
 1.7  thorpej 	for (bp = bge_products; bp->bp_name != NULL; bp++) {
 1.7  thorpej 		if (PCI_VENDOR(pa->pa_id) == bp->bp_vendor &&
 1.7  thorpej 		    PCI_PRODUCT(pa->pa_id) == bp->bp_product)
 1.7  thorpej 			return (bp);
 1.7  thorpej 	}
 1.7  thorpej
 1.7  thorpej 	return (NULL);
 1.7  thorpej }
 1.7  thorpej
 1.1     fvdl /*
 1.1     fvdl  * Probe for a Broadcom chip. Check the PCI vendor and device IDs
 1.1     fvdl  * against our list and return its name if we find a match. Note
 1.1     fvdl  * that since the Broadcom controller contains VPD support, we
 1.1     fvdl  * can get the device name string from the controller itself instead
 1.1     fvdl  * of the compiled-in string. This is a little slow, but it guarantees
 1.1     fvdl  * we'll always announce the right product name.
 1.1     fvdl  */
 1.1     fvdl int
 1.1     fvdl bge_probe(parent, match, aux)
 1.1     fvdl 	struct device *parent;
 1.1     fvdl 	struct cfdata *match;
 1.1     fvdl 	void *aux;
 1.1     fvdl {
 1.1     fvdl 	struct pci_attach_args *pa = (struct pci_attach_args *)aux;
 1.1     fvdl
 1.7  thorpej 	if (bge_lookup(pa) != NULL)
 1.1     fvdl 		return (1);
 1.1     fvdl
 1.1     fvdl 	return (0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_attach(parent, self, aux)
 1.1     fvdl 	struct device *parent, *self;
 1.1     fvdl 	void *aux;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc	*sc = (struct bge_softc *)self;
 1.1     fvdl 	struct pci_attach_args	*pa = aux;
 1.7  thorpej 	const struct bge_product *bp;
1.16  thorpej 	const struct bge_revision *br;
 1.1     fvdl 	pci_chipset_tag_t	pc = pa->pa_pc;
 1.1     fvdl 	pci_intr_handle_t	ih;
 1.1     fvdl 	const char		*intrstr = NULL;
 1.1     fvdl 	bus_dma_segment_t	seg;
 1.1     fvdl 	int			rseg;
 1.1     fvdl 	u_int32_t		hwcfg = 0;
 1.1     fvdl 	u_int32_t		command;
 1.1     fvdl 	struct ifnet		*ifp;
 1.1     fvdl 	int			unit;
 1.1     fvdl 	caddr_t			kva;
 1.1     fvdl 	u_char			eaddr[ETHER_ADDR_LEN];
 1.1     fvdl 	pcireg_t		memtype;
 1.1     fvdl 	bus_addr_t		memaddr;
 1.1     fvdl 	bus_size_t		memsize;
 1.1     fvdl
 1.7  thorpej 	bp = bge_lookup(pa);
 1.7  thorpej 	KASSERT(bp != NULL);
 1.7  thorpej
 1.1     fvdl 	sc->bge_pa = *pa;
 1.1     fvdl
1.16  thorpej 	printf(": %s\n", bp->bp_name);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Map control/status registers.
 1.1     fvdl 	 */
 1.1     fvdl 	DPRINTFN(5, ("Map control/status regs\n"));
 1.1     fvdl 	command = pci_conf_read(pc, pa->pa_tag, PCI_COMMAND_STATUS_REG);
 1.1     fvdl 	command |= PCI_COMMAND_MEM_ENABLE | PCI_COMMAND_MASTER_ENABLE;
 1.1     fvdl 	pci_conf_write(pc, pa->pa_tag, PCI_COMMAND_STATUS_REG, command);
 1.1     fvdl 	command = pci_conf_read(pc, pa->pa_tag, PCI_COMMAND_STATUS_REG);
 1.1     fvdl
 1.1     fvdl 	if (!(command & PCI_COMMAND_MEM_ENABLE)) {
 1.1     fvdl 		printf("%s: failed to enable memory mapping!\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	DPRINTFN(5, ("pci_mem_find\n"));
 1.1     fvdl 	memtype = pci_mapreg_type(pa->pa_pc, pa->pa_tag, BGE_PCI_BAR0);
 1.1     fvdl  	switch (memtype) {
 1.1     fvdl         case PCI_MAPREG_TYPE_MEM | PCI_MAPREG_MEM_TYPE_32BIT:
 1.1     fvdl         case PCI_MAPREG_TYPE_MEM | PCI_MAPREG_MEM_TYPE_64BIT:
 1.1     fvdl 		if (pci_mapreg_map(pa, BGE_PCI_BAR0,
 1.1     fvdl                     memtype, 0, &sc->bge_btag, &sc->bge_bhandle,
 1.1     fvdl 		    &memaddr, &memsize) == 0)
 1.1     fvdl 			break;
 1.1     fvdl 	default:
 1.1     fvdl 		printf("%s: can't find mem space\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	DPRINTFN(5, ("pci_intr_map\n"));
 1.1     fvdl 	if (pci_intr_map(pa, &ih)) {
 1.1     fvdl 		printf("%s: couldn't map interrupt\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	DPRINTFN(5, ("pci_intr_string\n"));
 1.1     fvdl 	intrstr = pci_intr_string(pc, ih);
 1.1     fvdl
 1.1     fvdl 	DPRINTFN(5, ("pci_intr_establish\n"));
 1.1     fvdl 	sc->bge_intrhand = pci_intr_establish(pc, ih, IPL_NET, bge_intr, sc);
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_intrhand == NULL) {
 1.1     fvdl 		printf("%s: couldn't establish interrupt",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		if (intrstr != NULL)
 1.1     fvdl 			printf(" at %s", intrstr);
 1.1     fvdl 		printf("\n");
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl 	printf("%s: interrupting at %s\n", sc->bge_dev.dv_xname, intrstr);
 1.1     fvdl
 1.1     fvdl 	/* Try to reset the chip. */
 1.1     fvdl 	DPRINTFN(5, ("bge_reset\n"));
 1.1     fvdl 	bge_reset(sc);
 1.1     fvdl
 1.1     fvdl 	if (bge_chipinit(sc)) {
 1.1     fvdl 		printf("%s: chip initializatino failed\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.1     fvdl 		bge_release_resources(sc);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Get station address from the EEPROM.
 1.1     fvdl 	 */
 1.1     fvdl 	if (bge_read_eeprom(sc, (caddr_t)eaddr,
 1.1     fvdl 	    BGE_EE_MAC_OFFSET + 2, ETHER_ADDR_LEN)) {
 1.1     fvdl 		printf("bge%d: failed to read station address\n", unit);
 1.1     fvdl 		bge_release_resources(sc);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/*
1.16  thorpej 	 * Save ASIC rev.  Look up any quirks associated with this
1.16  thorpej 	 * ASIC.
 1.1     fvdl 	 */
1.16  thorpej 	sc->bge_asicrev =
1.16  thorpej 	    pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_MISC_CTL) &
1.16  thorpej 	    BGE_PCIMISCCTL_ASICREV;
1.16  thorpej 	br = bge_lookup_rev(sc->bge_asicrev);
1.16  thorpej
1.16  thorpej 	printf("%s: ", sc->bge_dev.dv_xname);
1.16  thorpej 	if (br == NULL) {
1.16  thorpej 		printf("unknown ASIC 0x%08x", sc->bge_asicrev);
1.16  thorpej 		sc->bge_quirks = 0;
1.16  thorpej 	} else {
1.16  thorpej 		printf("ASIC %s", br->br_name);
1.16  thorpej 		sc->bge_quirks = br->br_quirks;
1.16  thorpej 	}
1.16  thorpej 	printf(", Ethernet address %s\n", ether_sprintf(eaddr));
 1.1     fvdl
 1.1     fvdl 	/* Allocate the general information block and ring buffers. */
 1.1     fvdl 	sc->bge_dmatag = pa->pa_dmat;
 1.1     fvdl 	DPRINTFN(5, ("bus_dmamem_alloc\n"));
 1.1     fvdl 	if (bus_dmamem_alloc(sc->bge_dmatag, sizeof(struct bge_ring_data),
 1.1     fvdl 			     PAGE_SIZE, 0, &seg, 1, &rseg, BUS_DMA_NOWAIT)) {
 1.1     fvdl 		printf("%s: can't alloc rx buffers\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl 	DPRINTFN(5, ("bus_dmamem_map\n"));
 1.1     fvdl 	if (bus_dmamem_map(sc->bge_dmatag, &seg, rseg,
 1.1     fvdl 			   sizeof(struct bge_ring_data), &kva,
 1.1     fvdl 			   BUS_DMA_NOWAIT)) {
 1.1     fvdl 		printf("%s: can't map dma buffers (%d bytes)\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname, (int)sizeof(struct bge_ring_data));
 1.1     fvdl 		bus_dmamem_free(sc->bge_dmatag, &seg, rseg);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl 	DPRINTFN(5, ("bus_dmamem_create\n"));
 1.1     fvdl 	if (bus_dmamap_create(sc->bge_dmatag, sizeof(struct bge_ring_data), 1,
 1.1     fvdl 	    sizeof(struct bge_ring_data), 0,
 1.1     fvdl 	    BUS_DMA_NOWAIT, &sc->bge_ring_map)) {
 1.1     fvdl 		printf("%s: can't create dma map\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		bus_dmamem_unmap(sc->bge_dmatag, kva,
 1.1     fvdl 				 sizeof(struct bge_ring_data));
 1.1     fvdl 		bus_dmamem_free(sc->bge_dmatag, &seg, rseg);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl 	DPRINTFN(5, ("bus_dmamem_load\n"));
 1.1     fvdl 	if (bus_dmamap_load(sc->bge_dmatag, sc->bge_ring_map, kva,
 1.1     fvdl 			    sizeof(struct bge_ring_data), NULL,
 1.1     fvdl 			    BUS_DMA_NOWAIT)) {
 1.1     fvdl 		bus_dmamap_destroy(sc->bge_dmatag, sc->bge_ring_map);
 1.1     fvdl 		bus_dmamem_unmap(sc->bge_dmatag, kva,
 1.1     fvdl 				 sizeof(struct bge_ring_data));
 1.1     fvdl 		bus_dmamem_free(sc->bge_dmatag, &seg, rseg);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	DPRINTFN(5, ("bzero\n"));
 1.1     fvdl 	sc->bge_rdata = (struct bge_ring_data *)kva;
 1.1     fvdl
 1.1     fvdl 	memset(sc->bge_rdata, sizeof(struct bge_ring_data), 0);
 1.1     fvdl
 1.1     fvdl 	/* Try to allocate memory for jumbo buffers. */
 1.1     fvdl 	if (bge_alloc_jumbo_mem(sc)) {
 1.1     fvdl 		printf("%s: jumbo buffer allocation failed\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname);
 1.8  thorpej 	} else
 1.8  thorpej 		sc->ethercom.ec_capabilities |= ETHERCAP_JUMBO_MTU;
 1.1     fvdl
 1.1     fvdl 	/* Set default tuneable values. */
 1.1     fvdl 	sc->bge_stat_ticks = BGE_TICKS_PER_SEC;
 1.1     fvdl 	sc->bge_rx_coal_ticks = 150;
 1.1     fvdl 	sc->bge_tx_coal_ticks = 150;
 1.1     fvdl 	sc->bge_rx_max_coal_bds = 64;
 1.1     fvdl 	sc->bge_tx_max_coal_bds = 128;
 1.1     fvdl
 1.1     fvdl 	/* Set up ifnet structure */
 1.1     fvdl 	ifp = &sc->ethercom.ec_if;
 1.1     fvdl 	ifp->if_softc = sc;
 1.1     fvdl 	ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST;
 1.1     fvdl 	ifp->if_ioctl = bge_ioctl;
 1.1     fvdl 	ifp->if_start = bge_start;
 1.1     fvdl 	ifp->if_init = bge_init;
 1.1     fvdl 	ifp->if_watchdog = bge_watchdog;
 1.1     fvdl 	IFQ_SET_MAXLEN(&ifp->if_snd, BGE_TX_RING_CNT - 1);
 1.1     fvdl 	IFQ_SET_READY(&ifp->if_snd);
 1.1     fvdl 	DPRINTFN(5, ("bcopy\n"));
 1.1     fvdl 	strcpy(ifp->if_xname, sc->bge_dev.dv_xname);
 1.1     fvdl
 1.1     fvdl 	sc->ethercom.ec_if.if_capabilities |=
 1.1     fvdl 	  IFCAP_CSUM_IPv4 | IFCAP_CSUM_TCPv4 | IFCAP_CSUM_UDPv4;
 1.1     fvdl 	sc->ethercom.ec_capabilities |=
 1.1     fvdl 	    ETHERCAP_VLAN_HWTAGGING | ETHERCAP_VLAN_MTU;
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Do MII setup.
 1.1     fvdl 	 */
 1.1     fvdl 	DPRINTFN(5, ("mii setup\n"));
 1.1     fvdl 	sc->bge_mii.mii_ifp = ifp;
 1.1     fvdl 	sc->bge_mii.mii_readreg = bge_miibus_readreg;
 1.1     fvdl 	sc->bge_mii.mii_writereg = bge_miibus_writereg;
 1.1     fvdl 	sc->bge_mii.mii_statchg = bge_miibus_statchg;
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Figure out what sort of media we have by checking the
 1.1     fvdl 	 * hardware config word in the EEPROM. Note: on some BCM5700
 1.1     fvdl 	 * cards, this value appears to be unset. If that's the
 1.1     fvdl 	 * case, we have to rely on identifying the NIC by its PCI
 1.1     fvdl 	 * subsystem ID, as we do below for the SysKonnect SK-9D41.
 1.1     fvdl 	 */
 1.1     fvdl 	bge_read_eeprom(sc, (caddr_t)&hwcfg,
 1.1     fvdl 		    BGE_EE_HWCFG_OFFSET, sizeof(hwcfg));
 1.1     fvdl 	if ((be32toh(hwcfg) & BGE_HWCFG_MEDIA) == BGE_MEDIA_FIBER)
 1.1     fvdl 		sc->bge_tbi = 1;
 1.1     fvdl
 1.1     fvdl 	/* The SysKonnect SK-9D41 is a 1000baseSX card. */
 1.1     fvdl 	if ((pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_SUBSYS) >> 16) ==
 1.1     fvdl 	    SK_SUBSYSID_9D41)
 1.1     fvdl 		sc->bge_tbi = 1;
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_tbi) {
 1.1     fvdl 		ifmedia_init(&sc->bge_ifmedia, IFM_IMASK, bge_ifmedia_upd,
 1.1     fvdl 		    bge_ifmedia_sts);
 1.1     fvdl 		ifmedia_add(&sc->bge_ifmedia, IFM_ETHER|IFM_1000_SX, 0, NULL);
 1.1     fvdl 		ifmedia_add(&sc->bge_ifmedia, IFM_ETHER|IFM_1000_SX|IFM_FDX,
 1.1     fvdl 			    0, NULL);
 1.1     fvdl 		ifmedia_add(&sc->bge_ifmedia, IFM_ETHER|IFM_AUTO, 0, NULL);
 1.1     fvdl 		ifmedia_set(&sc->bge_ifmedia, IFM_ETHER|IFM_AUTO);
 1.1     fvdl 	} else {
 1.1     fvdl 		/*
 1.1     fvdl 		 * Do transceiver setup.
 1.1     fvdl 		 */
 1.1     fvdl 		ifmedia_init(&sc->bge_mii.mii_media, 0, bge_ifmedia_upd,
 1.1     fvdl 			     bge_ifmedia_sts);
 1.1     fvdl 		mii_attach(&sc->bge_dev, &sc->bge_mii, 0xffffffff,
 1.1     fvdl 			   MII_PHY_ANY, MII_OFFSET_ANY, 0);
 1.1     fvdl
 1.1     fvdl 		if (LIST_FIRST(&sc->bge_mii.mii_phys) == NULL) {
 1.1     fvdl 			printf("%s: no PHY found!\n", sc->bge_dev.dv_xname);
 1.1     fvdl 			ifmedia_add(&sc->bge_mii.mii_media,
 1.1     fvdl 				    IFM_ETHER|IFM_MANUAL, 0, NULL);
 1.1     fvdl 			ifmedia_set(&sc->bge_mii.mii_media,
 1.1     fvdl 				    IFM_ETHER|IFM_MANUAL);
 1.1     fvdl 		} else
 1.1     fvdl 			ifmedia_set(&sc->bge_mii.mii_media,
 1.1     fvdl 				    IFM_ETHER|IFM_AUTO);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Call MI attach routine.
 1.1     fvdl 	 */
 1.1     fvdl 	DPRINTFN(5, ("if_attach\n"));
 1.1     fvdl 	if_attach(ifp);
 1.1     fvdl 	DPRINTFN(5, ("ether_ifattach\n"));
 1.1     fvdl 	ether_ifattach(ifp, eaddr);
 1.1     fvdl 	DPRINTFN(5, ("callout_init\n"));
 1.1     fvdl 	callout_init(&sc->bge_timeout);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_release_resources(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	if (sc->bge_vpd_prodname != NULL)
 1.1     fvdl 		free(sc->bge_vpd_prodname, M_DEVBUF);
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_vpd_readonly != NULL)
 1.1     fvdl 		free(sc->bge_vpd_readonly, M_DEVBUF);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_reset(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	struct pci_attach_args *pa = &sc->bge_pa;
 1.1     fvdl 	u_int32_t cachesize, command, pcistate;
 1.1     fvdl 	int i, val = 0;
 1.1     fvdl
 1.1     fvdl 	/* Save some important PCI state. */
 1.1     fvdl 	cachesize = pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_CACHESZ);
 1.1     fvdl 	command = pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_CMD);
 1.1     fvdl 	pcistate = pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_PCISTATE);
 1.1     fvdl
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_MISC_CTL,
 1.1     fvdl 	    BGE_PCIMISCCTL_INDIRECT_ACCESS|BGE_PCIMISCCTL_MASK_PCI_INTR|
 1.1     fvdl 	    BGE_HIF_SWAP_OPTIONS|BGE_PCIMISCCTL_PCISTATE_RW);
 1.1     fvdl
 1.1     fvdl 	/* Issue global reset */
 1.1     fvdl 	bge_writereg_ind(sc, BGE_MISC_CFG,
 1.1     fvdl 	    BGE_MISCCFG_RESET_CORE_CLOCKS|(65<<1));
 1.1     fvdl
 1.1     fvdl 	DELAY(1000);
 1.1     fvdl
 1.1     fvdl 	/* Reset some of the PCI state that got zapped by reset */
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_MISC_CTL,
 1.1     fvdl 	    BGE_PCIMISCCTL_INDIRECT_ACCESS|BGE_PCIMISCCTL_MASK_PCI_INTR|
 1.1     fvdl 	    BGE_HIF_SWAP_OPTIONS|BGE_PCIMISCCTL_PCISTATE_RW);
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_CMD, command);
 1.1     fvdl 	pci_conf_write(pa->pa_pc, pa->pa_tag, BGE_PCI_CACHESZ, cachesize);
 1.1     fvdl 	bge_writereg_ind(sc, BGE_MISC_CFG, (65 << 1));
 1.1     fvdl
 1.1     fvdl 	/* Enable memory arbiter. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MARB_MODE, BGE_MARBMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Prevent PXE restart: write a magic number to the
 1.1     fvdl 	 * general communications memory at 0xB50.
 1.1     fvdl 	 */
 1.1     fvdl 	bge_writemem_ind(sc, BGE_SOFTWARE_GENCOMM, BGE_MAGIC_NUMBER);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Poll the value location we just wrote until
 1.1     fvdl 	 * we see the 1's complement of the magic number.
 1.1     fvdl 	 * This indicates that the firmware initialization
 1.1     fvdl 	 * is complete.
 1.1     fvdl 	 */
 1.1     fvdl 	for (i = 0; i < 750; i++) {
 1.1     fvdl 		val = bge_readmem_ind(sc, BGE_SOFTWARE_GENCOMM);
 1.1     fvdl 		if (val == ~BGE_MAGIC_NUMBER)
 1.1     fvdl 			break;
 1.1     fvdl 		DELAY(1000);
 1.1     fvdl 	}
 1.1     fvdl
 1.8  thorpej 	if (i == 750) {
 1.1     fvdl 		printf("%s: firmware handshake timed out, val = %x\n",
 1.1     fvdl 		    sc->bge_dev.dv_xname, val);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * XXX Wait for the value of the PCISTATE register to
 1.1     fvdl 	 * return to its original pre-reset state. This is a
 1.1     fvdl 	 * fairly good indicator of reset completion. If we don't
 1.1     fvdl 	 * wait for the reset to fully complete, trying to read
 1.1     fvdl 	 * from the device's non-PCI registers may yield garbage
 1.1     fvdl 	 * results.
 1.1     fvdl 	 */
 1.1     fvdl 	for (i = 0; i < BGE_TIMEOUT; i++) {
 1.1     fvdl 		if (pci_conf_read(pa->pa_pc, pa->pa_tag, BGE_PCI_PCISTATE) ==
 1.1     fvdl 		    pcistate)
 1.1     fvdl 			break;
 1.1     fvdl 		DELAY(10);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Enable memory arbiter. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MARB_MODE, BGE_MARBMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Fix up byte swapping */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MODE_CTL, BGE_DMA_SWAP_OPTIONS);
 1.1     fvdl
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MAC_MODE, 0);
 1.1     fvdl
 1.1     fvdl 	DELAY(10000);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Frame reception handling. This is called if there's a frame
 1.1     fvdl  * on the receive return list.
 1.1     fvdl  *
 1.1     fvdl  * Note: we have to be able to handle two possibilities here:
 1.1     fvdl  * 1) the frame is from the jumbo recieve ring
 1.1     fvdl  * 2) the frame is from the standard receive ring
 1.1     fvdl  */
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_rxeof(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl 	int stdcnt = 0, jumbocnt = 0;
 1.1     fvdl 	int have_tag = 0;
 1.1     fvdl 	u_int16_t vlan_tag = 0;
 1.1     fvdl 	bus_dmamap_t dmamap;
 1.1     fvdl 	bus_addr_t offset, toff;
 1.1     fvdl 	bus_size_t tlen;
 1.1     fvdl 	int tosync;
 1.1     fvdl
 1.1     fvdl 	ifp = &sc->ethercom.ec_if;
 1.1     fvdl
 1.1     fvdl 	bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 	    offsetof(struct bge_ring_data, bge_status_block),
 1.1     fvdl 	    sizeof (struct bge_status_block),
 1.1     fvdl 	    BUS_DMASYNC_POSTREAD);
 1.1     fvdl
 1.1     fvdl 	offset = offsetof(struct bge_ring_data, bge_rx_return_ring);
 1.1     fvdl 	tosync = sc->bge_rdata->bge_status_block.bge_idx[0].bge_rx_prod_idx -
 1.1     fvdl 	    sc->bge_rx_saved_considx;
 1.1     fvdl
 1.1     fvdl 	toff = offset + (sc->bge_rx_saved_considx * sizeof (struct bge_rx_bd));
 1.1     fvdl
 1.1     fvdl 	if (tosync < 0) {
 1.1     fvdl 		tlen = (BGE_RETURN_RING_CNT - sc->bge_rx_saved_considx) *
 1.1     fvdl 		    sizeof (struct bge_rx_bd);
 1.1     fvdl 		bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 		    toff, tlen, BUS_DMASYNC_POSTREAD);
 1.1     fvdl 		tosync = -tosync;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 	    offset, tosync * sizeof (struct bge_rx_bd),
 1.1     fvdl 	    BUS_DMASYNC_POSTREAD);
 1.1     fvdl
 1.1     fvdl 	while(sc->bge_rx_saved_considx !=
 1.1     fvdl 	    sc->bge_rdata->bge_status_block.bge_idx[0].bge_rx_prod_idx) {
 1.1     fvdl 		struct bge_rx_bd	*cur_rx;
 1.1     fvdl 		u_int32_t		rxidx;
 1.1     fvdl 		struct mbuf		*m = NULL;
 1.1     fvdl
 1.1     fvdl 		cur_rx = &sc->bge_rdata->
 1.1     fvdl 			bge_rx_return_ring[sc->bge_rx_saved_considx];
 1.1     fvdl
 1.1     fvdl 		rxidx = cur_rx->bge_idx;
 1.1     fvdl 		BGE_INC(sc->bge_rx_saved_considx, BGE_RETURN_RING_CNT);
 1.1     fvdl
 1.1     fvdl 		if (cur_rx->bge_flags & BGE_RXBDFLAG_VLAN_TAG) {
 1.1     fvdl 			have_tag = 1;
 1.1     fvdl 			vlan_tag = cur_rx->bge_vlan_tag;
 1.1     fvdl 		}
 1.1     fvdl
 1.1     fvdl 		if (cur_rx->bge_flags & BGE_RXBDFLAG_JUMBO_RING) {
 1.1     fvdl 			BGE_INC(sc->bge_jumbo, BGE_JUMBO_RX_RING_CNT);
 1.1     fvdl 			m = sc->bge_cdata.bge_rx_jumbo_chain[rxidx];
 1.1     fvdl 			sc->bge_cdata.bge_rx_jumbo_chain[rxidx] = NULL;
 1.1     fvdl 			jumbocnt++;
 1.1     fvdl 			if (cur_rx->bge_flags & BGE_RXBDFLAG_ERROR) {
 1.1     fvdl 				ifp->if_ierrors++;
 1.1     fvdl 				bge_newbuf_jumbo(sc, sc->bge_jumbo, m);
 1.1     fvdl 				continue;
 1.1     fvdl 			}
 1.1     fvdl 			if (bge_newbuf_jumbo(sc, sc->bge_jumbo,
 1.1     fvdl 					     NULL)== ENOBUFS) {
 1.1     fvdl 				ifp->if_ierrors++;
 1.1     fvdl 				bge_newbuf_jumbo(sc, sc->bge_jumbo, m);
 1.1     fvdl 				continue;
 1.1     fvdl 			}
 1.1     fvdl 		} else {
 1.1     fvdl 			BGE_INC(sc->bge_std, BGE_STD_RX_RING_CNT);
 1.1     fvdl 			m = sc->bge_cdata.bge_rx_std_chain[rxidx];
 1.1     fvdl 			sc->bge_cdata.bge_rx_std_chain[rxidx] = NULL;
 1.1     fvdl 			stdcnt++;
 1.1     fvdl 			dmamap = sc->bge_cdata.bge_rx_std_map[rxidx];
 1.1     fvdl 			sc->bge_cdata.bge_rx_std_map[rxidx] = 0;
 1.1     fvdl 			if (cur_rx->bge_flags & BGE_RXBDFLAG_ERROR) {
 1.1     fvdl 				ifp->if_ierrors++;
 1.1     fvdl 				bge_newbuf_std(sc, sc->bge_std, m, dmamap);
 1.1     fvdl 				continue;
 1.1     fvdl 			}
 1.1     fvdl 			if (bge_newbuf_std(sc, sc->bge_std,
 1.1     fvdl 			    NULL, dmamap) == ENOBUFS) {
 1.1     fvdl 				ifp->if_ierrors++;
 1.1     fvdl 				bge_newbuf_std(sc, sc->bge_std, m, dmamap);
 1.1     fvdl 				continue;
 1.1     fvdl 			}
 1.1     fvdl 		}
 1.1     fvdl
 1.1     fvdl 		ifp->if_ipackets++;
 1.1     fvdl 		m->m_pkthdr.len = m->m_len = cur_rx->bge_len;
 1.1     fvdl 		m->m_pkthdr.rcvif = ifp;
 1.1     fvdl
 1.1     fvdl #if NBPFILTER > 0
 1.1     fvdl 		/*
 1.1     fvdl 		 * Handle BPF listeners. Let the BPF user see the packet.
 1.1     fvdl 		 */
 1.1     fvdl 		if (ifp->if_bpf)
 1.1     fvdl 			bpf_mtap(ifp->if_bpf, m);
 1.1     fvdl #endif
 1.1     fvdl
 1.2     fvdl 		if (sc->bge_asicrev != BGE_ASICREV_BCM5700_B0) {
 1.2     fvdl 			m->m_pkthdr.csum_flags |= M_CSUM_IPv4;
 1.2     fvdl 			if ((cur_rx->bge_ip_csum ^ 0xffff) != 0)
 1.2     fvdl 				m->m_pkthdr.csum_flags |= M_CSUM_IPv4_BAD;
 1.4     fvdl #if 0	/* XXX appears to be broken */
 1.2     fvdl 			if (cur_rx->bge_flags & BGE_RXBDFLAG_TCP_UDP_CSUM) {
 1.2     fvdl 				m->m_pkthdr.csum_data =
 1.2     fvdl 				    cur_rx->bge_tcp_udp_csum;
 1.2     fvdl 				m->m_pkthdr.csum_flags |=
 1.2     fvdl 				    (M_CSUM_TCPv4|M_CSUM_UDPv4|M_CSUM_DATA);
 1.2     fvdl 			}
 1.4     fvdl #endif
 1.1     fvdl 		}
 1.1     fvdl
 1.1     fvdl 		/*
 1.1     fvdl 		 * If we received a packet with a vlan tag, pass it
 1.1     fvdl 		 * to vlan_input() instead of ether_input().
 1.1     fvdl 		 */
 1.1     fvdl 		if (have_tag) {
 1.1     fvdl 			struct mbuf *n;
 1.1     fvdl
 1.1     fvdl 			n = m_aux_add(m, AF_LINK, ETHERTYPE_VLAN);
 1.1     fvdl 			if (n != NULL) {
 1.1     fvdl 				*mtod(n, int *) = vlan_tag;
 1.1     fvdl 				n->m_len = sizeof(int);
 1.1     fvdl 				have_tag = vlan_tag = 0;
 1.1     fvdl 			} else {
 1.1     fvdl 				printf("%s: no mbuf for tag\n", ifp->if_xname);
 1.1     fvdl 				m_freem(m);
 1.1     fvdl 				have_tag = vlan_tag = 0;
 1.1     fvdl 				continue;
 1.1     fvdl 			}
 1.1     fvdl 		}
 1.1     fvdl 		(*ifp->if_input)(ifp, m);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_RX_CONS0_LO, sc->bge_rx_saved_considx);
 1.1     fvdl 	if (stdcnt)
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_MBX_RX_STD_PROD_LO, sc->bge_std);
 1.1     fvdl 	if (jumbocnt)
 1.1     fvdl 		CSR_WRITE_4(sc, BGE_MBX_RX_JUMBO_PROD_LO, sc->bge_jumbo);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_txeof(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	struct bge_tx_bd *cur_tx = NULL;
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl 	struct txdmamap_pool_entry *dma;
 1.1     fvdl 	bus_addr_t offset, toff;
 1.1     fvdl 	bus_size_t tlen;
 1.1     fvdl 	int tosync;
 1.1     fvdl 	struct mbuf *m;
 1.1     fvdl
 1.1     fvdl 	ifp = &sc->ethercom.ec_if;
 1.1     fvdl
 1.1     fvdl 	bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 	    offsetof(struct bge_ring_data, bge_status_block),
 1.1     fvdl 	    sizeof (struct bge_status_block),
 1.1     fvdl 	    BUS_DMASYNC_POSTREAD);
 1.1     fvdl
 1.1     fvdl 	offset = offsetof(struct bge_ring_data, bge_tx_ring);
 1.1     fvdl 	tosync = sc->bge_rdata->bge_status_block.bge_idx[0].bge_tx_cons_idx -
 1.1     fvdl 	    sc->bge_tx_saved_considx;
 1.1     fvdl
 1.1     fvdl 	toff = offset + (sc->bge_tx_saved_considx * sizeof (struct bge_tx_bd));
 1.1     fvdl
 1.1     fvdl 	if (tosync < 0) {
 1.1     fvdl 		tlen = (BGE_TX_RING_CNT - sc->bge_tx_saved_considx) *
 1.1     fvdl 		    sizeof (struct bge_tx_bd);
 1.1     fvdl 		bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 		    toff, tlen, BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE);
 1.1     fvdl 		tosync = -tosync;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	bus_dmamap_sync(sc->bge_dmatag, sc->bge_ring_map,
 1.1     fvdl 	    offset, tosync * sizeof (struct bge_tx_bd),
 1.1     fvdl 	    BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Go through our tx ring and free mbufs for those
 1.1     fvdl 	 * frames that have been sent.
 1.1     fvdl 	 */
 1.1     fvdl 	while (sc->bge_tx_saved_considx !=
 1.1     fvdl 	    sc->bge_rdata->bge_status_block.bge_idx[0].bge_tx_cons_idx) {
 1.1     fvdl 		u_int32_t		idx = 0;
 1.1     fvdl
 1.1     fvdl 		idx = sc->bge_tx_saved_considx;
 1.1     fvdl 		cur_tx = &sc->bge_rdata->bge_tx_ring[idx];
 1.1     fvdl 		if (cur_tx->bge_flags & BGE_TXBDFLAG_END)
 1.1     fvdl 			ifp->if_opackets++;
 1.1     fvdl 		m = sc->bge_cdata.bge_tx_chain[idx];
 1.1     fvdl 		if (m != NULL) {
 1.1     fvdl 			sc->bge_cdata.bge_tx_chain[idx] = NULL;
 1.1     fvdl 			dma = sc->txdma[idx];
 1.1     fvdl 			bus_dmamap_sync(sc->bge_dmatag, dma->dmamap, 0,
 1.1     fvdl 			    dma->dmamap->dm_mapsize, BUS_DMASYNC_POSTWRITE);
 1.1     fvdl 			bus_dmamap_unload(sc->bge_dmatag, dma->dmamap);
 1.1     fvdl 			SLIST_INSERT_HEAD(&sc->txdma_list, dma, link);
 1.1     fvdl 			sc->txdma[idx] = NULL;
 1.1     fvdl
 1.1     fvdl 			m_freem(m);
 1.1     fvdl 		}
 1.1     fvdl 		sc->bge_txcnt--;
 1.1     fvdl 		BGE_INC(sc->bge_tx_saved_considx, BGE_TX_RING_CNT);
 1.1     fvdl 		ifp->if_timer = 0;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (cur_tx != NULL)
 1.1     fvdl 		ifp->if_flags &= ~IFF_OACTIVE;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl int
 1.1     fvdl bge_intr(xsc)
 1.1     fvdl 	void *xsc;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl
 1.1     fvdl 	sc = xsc;
 1.1     fvdl 	ifp = &sc->ethercom.ec_if;
 1.1     fvdl
 1.1     fvdl #ifdef notdef
 1.1     fvdl 	/* Avoid this for now -- checking this register is expensive. */
 1.1     fvdl 	/* Make sure this is really our interrupt. */
 1.1     fvdl 	if (!(CSR_READ_4(sc, BGE_MISC_LOCAL_CTL) & BGE_MLC_INTR_STATE))
 1.1     fvdl 		return (0);
 1.1     fvdl #endif
 1.1     fvdl 	/* Ack interrupt and stop others from occuring. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_IRQ0_LO, 1);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Process link state changes.
 1.1     fvdl 	 * Grrr. The link status word in the status block does
 1.1     fvdl 	 * not work correctly on the BCM5700 rev AX and BX chips,
 1.1     fvdl 	 * according to all avaibable information. Hence, we have
 1.1     fvdl 	 * to enable MII interrupts in order to properly obtain
 1.1     fvdl 	 * async link changes. Unfortunately, this also means that
 1.1     fvdl 	 * we have to read the MAC status register to detect link
 1.1     fvdl 	 * changes, thereby adding an additional register access to
 1.1     fvdl 	 * the interrupt handler.
 1.1     fvdl 	 */
 1.1     fvdl
 1.2     fvdl 	if (BGE_IS_5700_Ax_Bx(sc->bge_asicrev)) {
 1.1     fvdl 		u_int32_t		status;
 1.1     fvdl
 1.1     fvdl 		status = CSR_READ_4(sc, BGE_MAC_STS);
 1.1     fvdl 		if (status & BGE_MACSTAT_MI_INTERRUPT) {
 1.1     fvdl 			sc->bge_link = 0;
 1.1     fvdl 			callout_stop(&sc->bge_timeout);
 1.1     fvdl 			bge_tick(sc);
 1.1     fvdl 			/* Clear the interrupt */
 1.1     fvdl 			CSR_WRITE_4(sc, BGE_MAC_EVT_ENB,
 1.1     fvdl 			    BGE_EVTENB_MI_INTERRUPT);
 1.1     fvdl 			bge_miibus_readreg(&sc->bge_dev, 1, BRGPHY_MII_ISR);
 1.1     fvdl 			bge_miibus_writereg(&sc->bge_dev, 1, BRGPHY_MII_IMR,
 1.1     fvdl 			    BRGPHY_INTRS);
 1.1     fvdl 		}
 1.1     fvdl 	} else {
 1.1     fvdl 		if (sc->bge_rdata->bge_status_block.bge_status &
 1.1     fvdl 		    BGE_STATFLAG_LINKSTATE_CHANGED) {
 1.1     fvdl 			sc->bge_link = 0;
 1.1     fvdl 			callout_stop(&sc->bge_timeout);
 1.1     fvdl 			bge_tick(sc);
 1.1     fvdl 			/* Clear the interrupt */
 1.1     fvdl 			CSR_WRITE_4(sc, BGE_MAC_STS, BGE_MACSTAT_SYNC_CHANGED|
 1.1     fvdl 			    BGE_MACSTAT_CFG_CHANGED);
 1.1     fvdl 		}
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (ifp->if_flags & IFF_RUNNING) {
 1.1     fvdl 		/* Check RX return ring producer/consumer */
 1.1     fvdl 		bge_rxeof(sc);
 1.1     fvdl
 1.1     fvdl 		/* Check TX ring producer/consumer */
 1.1     fvdl 		bge_txeof(sc);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	bge_handle_events(sc);
 1.1     fvdl
 1.1     fvdl 	/* Re-enable interrupts. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_IRQ0_LO, 0);
 1.1     fvdl
 1.1     fvdl 	if (ifp->if_flags & IFF_RUNNING && !IFQ_IS_EMPTY(&ifp->if_snd))
 1.1     fvdl 		bge_start(ifp);
 1.1     fvdl
 1.1     fvdl 	return (1);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_tick(xsc)
 1.1     fvdl 	void *xsc;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = xsc;
 1.1     fvdl 	struct mii_data *mii = &sc->bge_mii;
 1.1     fvdl 	struct ifmedia *ifm = NULL;
 1.1     fvdl 	struct ifnet *ifp = &sc->ethercom.ec_if;
 1.1     fvdl 	int s;
 1.1     fvdl
 1.1     fvdl 	s = splnet();
 1.1     fvdl
 1.1     fvdl 	bge_stats_update(sc);
 1.1     fvdl 	callout_reset(&sc->bge_timeout, hz, bge_tick, sc);
 1.1     fvdl 	if (sc->bge_link) {
 1.1     fvdl 		splx(s);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_tbi) {
 1.1     fvdl 		ifm = &sc->bge_ifmedia;
 1.1     fvdl 		if (CSR_READ_4(sc, BGE_MAC_STS) &
 1.1     fvdl 		    BGE_MACSTAT_TBI_PCS_SYNCHED) {
 1.1     fvdl 			sc->bge_link++;
 1.1     fvdl 			CSR_WRITE_4(sc, BGE_MAC_STS, 0xFFFFFFFF);
 1.1     fvdl 			printf("%s: gigabit link up\n", sc->bge_dev.dv_xname);
 1.1     fvdl 			if (!IFQ_IS_EMPTY(&ifp->if_snd))
 1.1     fvdl 				bge_start(ifp);
 1.1     fvdl 		}
 1.1     fvdl 		splx(s);
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	mii_tick(mii);
 1.1     fvdl
 1.1     fvdl 	if (!sc->bge_link && mii->mii_media_status & IFM_ACTIVE &&
 1.1     fvdl 	    IFM_SUBTYPE(mii->mii_media_active) != IFM_NONE) {
 1.1     fvdl 		sc->bge_link++;
 1.1     fvdl 		if (IFM_SUBTYPE(mii->mii_media_active) == IFM_1000_T ||
 1.1     fvdl 		    IFM_SUBTYPE(mii->mii_media_active) == IFM_1000_SX)
 1.1     fvdl 			printf("%s: gigabit link up\n", sc->bge_dev.dv_xname);
 1.1     fvdl 		if (!IFQ_IS_EMPTY(&ifp->if_snd))
 1.1     fvdl 			bge_start(ifp);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	splx(s);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_stats_update(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	struct ifnet *ifp = &sc->ethercom.ec_if;
 1.1     fvdl 	bus_size_t stats = BGE_MEMWIN_START + BGE_STATS_BLOCK;
 1.1     fvdl
 1.1     fvdl #define READ_STAT(sc, stats, stat) \
 1.1     fvdl 	  CSR_READ_4(sc, stats + offsetof(struct bge_stats, stat))
 1.1     fvdl
 1.1     fvdl 	ifp->if_collisions +=
 1.1     fvdl 	  (READ_STAT(sc, stats, dot3StatsSingleCollisionFrames.bge_addr_lo) +
 1.1     fvdl 	   READ_STAT(sc, stats, dot3StatsMultipleCollisionFrames.bge_addr_lo) +
 1.1     fvdl 	   READ_STAT(sc, stats, dot3StatsExcessiveCollisions.bge_addr_lo) +
 1.1     fvdl 	   READ_STAT(sc, stats, dot3StatsLateCollisions.bge_addr_lo)) -
 1.1     fvdl 	  ifp->if_collisions;
 1.1     fvdl
 1.1     fvdl #undef READ_STAT
 1.1     fvdl
 1.1     fvdl #ifdef notdef
 1.1     fvdl 	ifp->if_collisions +=
 1.1     fvdl 	   (sc->bge_rdata->bge_info.bge_stats.dot3StatsSingleCollisionFrames +
 1.1     fvdl 	   sc->bge_rdata->bge_info.bge_stats.dot3StatsMultipleCollisionFrames +
 1.1     fvdl 	   sc->bge_rdata->bge_info.bge_stats.dot3StatsExcessiveCollisions +
 1.1     fvdl 	   sc->bge_rdata->bge_info.bge_stats.dot3StatsLateCollisions) -
 1.1     fvdl 	   ifp->if_collisions;
 1.1     fvdl #endif
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Encapsulate an mbuf chain in the tx ring  by coupling the mbuf data
 1.1     fvdl  * pointers to descriptors.
 1.1     fvdl  */
 1.1     fvdl int
 1.1     fvdl bge_encap(sc, m_head, txidx)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	struct mbuf *m_head;
 1.1     fvdl 	u_int32_t *txidx;
 1.1     fvdl {
 1.1     fvdl 	struct bge_tx_bd	*f = NULL;
 1.1     fvdl 	u_int32_t		frag, cur, cnt = 0;
 1.1     fvdl 	u_int16_t		csum_flags = 0;
 1.1     fvdl 	struct txdmamap_pool_entry *dma;
 1.1     fvdl 	bus_dmamap_t dmamap;
 1.1     fvdl 	int			i = 0;
 1.1     fvdl 	struct mbuf		*n;
 1.1     fvdl
 1.1     fvdl 	cur = frag = *txidx;
 1.1     fvdl
 1.1     fvdl 	if (m_head->m_pkthdr.csum_flags) {
 1.1     fvdl 		if (m_head->m_pkthdr.csum_flags & M_CSUM_IPv4)
 1.1     fvdl 			csum_flags |= BGE_TXBDFLAG_IP_CSUM;
 1.8  thorpej 		if (m_head->m_pkthdr.csum_flags & (M_CSUM_TCPv4|M_CSUM_UDPv4))
 1.1     fvdl 			csum_flags |= BGE_TXBDFLAG_TCP_UDP_CSUM;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	dma = SLIST_FIRST(&sc->txdma_list);
 1.1     fvdl 	if (dma == NULL)
 1.1     fvdl 		return ENOBUFS;
 1.1     fvdl 	dmamap = dma->dmamap;
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Start packing the mbufs in this chain into
 1.1     fvdl 	 * the fragment pointers. Stop when we run out
 1.1     fvdl 	 * of fragments or hit the end of the mbuf chain.
 1.1     fvdl 	 */
 1.1     fvdl 	if (bus_dmamap_load_mbuf(sc->bge_dmatag, dmamap, m_head,
 1.1     fvdl 	    BUS_DMA_NOWAIT))
 1.1     fvdl 		return(ENOBUFS);
 1.1     fvdl
 1.6  thorpej 	n = sc->ethercom.ec_nvlans ?
 1.6  thorpej 	    m_aux_find(m_head, AF_LINK, ETHERTYPE_VLAN) : NULL;
 1.6  thorpej
 1.1     fvdl 	for (i = 0; i < dmamap->dm_nsegs; i++) {
 1.1     fvdl 		f = &sc->bge_rdata->bge_tx_ring[frag];
 1.1     fvdl 		if (sc->bge_cdata.bge_tx_chain[frag] != NULL)
 1.1     fvdl 			break;
 1.1     fvdl 		bge_set_hostaddr(&f->bge_addr, dmamap->dm_segs[i].ds_addr);
 1.1     fvdl 		f->bge_len = dmamap->dm_segs[i].ds_len;
 1.1     fvdl 		f->bge_flags = csum_flags;
 1.1     fvdl
 1.1     fvdl 		if (n != NULL) {
 1.1     fvdl 			f->bge_flags |= BGE_TXBDFLAG_VLAN_TAG;
 1.1     fvdl 			f->bge_vlan_tag = *mtod(n, int *);
 1.1     fvdl 		} else {
 1.1     fvdl 			f->bge_vlan_tag = 0;
 1.1     fvdl 		}
 1.1     fvdl 		/*
 1.1     fvdl 		 * Sanity check: avoid coming within 16 descriptors
 1.1     fvdl 		 * of the end of the ring.
 1.1     fvdl 		 */
 1.1     fvdl 		if ((BGE_TX_RING_CNT - (sc->bge_txcnt + cnt)) < 16)
 1.1     fvdl 			return(ENOBUFS);
 1.1     fvdl 		cur = frag;
 1.1     fvdl 		BGE_INC(frag, BGE_TX_RING_CNT);
 1.1     fvdl 		cnt++;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	if (i < dmamap->dm_nsegs)
 1.1     fvdl 		return ENOBUFS;
 1.1     fvdl
 1.1     fvdl 	bus_dmamap_sync(sc->bge_dmatag, dmamap, 0, dmamap->dm_mapsize,
 1.1     fvdl 	    BUS_DMASYNC_PREWRITE);
 1.1     fvdl
 1.1     fvdl 	if (frag == sc->bge_tx_saved_considx)
 1.1     fvdl 		return(ENOBUFS);
 1.1     fvdl
 1.1     fvdl 	sc->bge_rdata->bge_tx_ring[cur].bge_flags |= BGE_TXBDFLAG_END;
 1.1     fvdl 	sc->bge_cdata.bge_tx_chain[cur] = m_head;
 1.1     fvdl 	SLIST_REMOVE_HEAD(&sc->txdma_list, link);
 1.1     fvdl 	sc->txdma[cur] = dma;
 1.1     fvdl 	sc->bge_txcnt += cnt;
 1.1     fvdl
 1.1     fvdl 	*txidx = frag;
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Main transmit routine. To avoid having to do mbuf copies, we put pointers
 1.1     fvdl  * to the mbuf data regions directly in the transmit descriptors.
 1.1     fvdl  */
 1.1     fvdl void
 1.1     fvdl bge_start(ifp)
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl 	struct mbuf *m_head = NULL;
 1.1     fvdl 	u_int32_t prodidx = 0;
 1.1     fvdl 	int pkts = 0;
 1.1     fvdl
 1.1     fvdl 	sc = ifp->if_softc;
 1.1     fvdl
 1.1     fvdl 	if (!sc->bge_link && ifp->if_snd.ifq_len < 10)
 1.1     fvdl 		return;
 1.1     fvdl
 1.1     fvdl 	prodidx = CSR_READ_4(sc, BGE_MBX_TX_HOST_PROD0_LO);
 1.1     fvdl
 1.1     fvdl 	while(sc->bge_cdata.bge_tx_chain[prodidx] == NULL) {
 1.1     fvdl 		IFQ_POLL(&ifp->if_snd, m_head);
 1.1     fvdl 		if (m_head == NULL)
 1.1     fvdl 			break;
 1.1     fvdl
 1.1     fvdl #if 0
 1.1     fvdl 		/*
 1.1     fvdl 		 * XXX
 1.1     fvdl 		 * safety overkill.  If this is a fragmented packet chain
 1.1     fvdl 		 * with delayed TCP/UDP checksums, then only encapsulate
 1.1     fvdl 		 * it if we have enough descriptors to handle the entire
 1.1     fvdl 		 * chain at once.
 1.1     fvdl 		 * (paranoia -- may not actually be needed)
 1.1     fvdl 		 */
 1.1     fvdl 		if (m_head->m_flags & M_FIRSTFRAG &&
 1.1     fvdl 		    m_head->m_pkthdr.csum_flags & (CSUM_DELAY_DATA)) {
 1.1     fvdl 			if ((BGE_TX_RING_CNT - sc->bge_txcnt) <
 1.1     fvdl 			    m_head->m_pkthdr.csum_data + 16) {
 1.1     fvdl 				ifp->if_flags |= IFF_OACTIVE;
 1.1     fvdl 				break;
 1.1     fvdl 			}
 1.1     fvdl 		}
 1.1     fvdl #endif
 1.1     fvdl
 1.1     fvdl 		/*
 1.1     fvdl 		 * Pack the data into the transmit ring. If we
 1.1     fvdl 		 * don't have room, set the OACTIVE flag and wait
 1.1     fvdl 		 * for the NIC to drain the ring.
 1.1     fvdl 		 */
 1.1     fvdl 		if (bge_encap(sc, m_head, &prodidx)) {
 1.1     fvdl 			ifp->if_flags |= IFF_OACTIVE;
 1.1     fvdl 			break;
 1.1     fvdl 		}
 1.1     fvdl
 1.1     fvdl 		/* now we are committed to transmit the packet */
 1.1     fvdl 		IFQ_DEQUEUE(&ifp->if_snd, m_head);
 1.1     fvdl 		pkts++;
 1.1     fvdl
 1.1     fvdl #if NBPFILTER > 0
 1.1     fvdl 		/*
 1.1     fvdl 		 * If there's a BPF listener, bounce a copy of this frame
 1.1     fvdl 		 * to him.
 1.1     fvdl 		 */
 1.1     fvdl 		if (ifp->if_bpf)
 1.1     fvdl 			bpf_mtap(ifp->if_bpf, m_head);
 1.1     fvdl #endif
 1.1     fvdl 	}
 1.1     fvdl 	if (pkts == 0)
 1.1     fvdl 		return;
 1.1     fvdl
 1.1     fvdl 	/* Transmit */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_TX_HOST_PROD0_LO, prodidx);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Set a timeout in case the chip goes out to lunch.
 1.1     fvdl 	 */
 1.1     fvdl 	ifp->if_timer = 5;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl int
 1.1     fvdl bge_init(ifp)
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = ifp->if_softc;
 1.1     fvdl 	u_int16_t *m;
 1.1     fvdl 	int s, error;
 1.1     fvdl
 1.1     fvdl 	s = splnet();
 1.1     fvdl
 1.1     fvdl 	ifp = &sc->ethercom.ec_if;
 1.1     fvdl
 1.1     fvdl 	/* Cancel pending I/O and flush buffers. */
 1.1     fvdl 	bge_stop(sc);
 1.1     fvdl 	bge_reset(sc);
 1.1     fvdl 	bge_chipinit(sc);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Init the various state machines, ring
 1.1     fvdl 	 * control blocks and firmware.
 1.1     fvdl 	 */
 1.1     fvdl 	error = bge_blockinit(sc);
 1.1     fvdl 	if (error != 0) {
 1.1     fvdl 		printf("%s: initialization error %d\n", sc->bge_dev.dv_xname,
 1.1     fvdl 		    error);
 1.1     fvdl 		splx(s);
 1.1     fvdl 		return error;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	ifp = &sc->ethercom.ec_if;
 1.1     fvdl
 1.1     fvdl 	/* Specify MTU. */
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_RX_MTU, ifp->if_mtu +
 1.1     fvdl 	    ETHER_HDR_LEN + ETHER_CRC_LEN);
 1.1     fvdl
 1.1     fvdl 	/* Load our MAC address. */
 1.1     fvdl 	m = (u_int16_t *)&(LLADDR(ifp->if_sadl)[0]);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MAC_ADDR1_LO, htons(m[0]));
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MAC_ADDR1_HI, (htons(m[1]) << 16) | htons(m[2]));
 1.1     fvdl
 1.1     fvdl 	/* Enable or disable promiscuous mode as needed. */
 1.1     fvdl 	if (ifp->if_flags & IFF_PROMISC) {
 1.1     fvdl 		BGE_SETBIT(sc, BGE_RX_MODE, BGE_RXMODE_RX_PROMISC);
 1.1     fvdl 	} else {
 1.1     fvdl 		BGE_CLRBIT(sc, BGE_RX_MODE, BGE_RXMODE_RX_PROMISC);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	/* Program multicast filter. */
 1.1     fvdl 	bge_setmulti(sc);
 1.1     fvdl
 1.1     fvdl 	/* Init RX ring. */
 1.1     fvdl 	bge_init_rx_ring_std(sc);
 1.1     fvdl
 1.1     fvdl 	/* Init jumbo RX ring. */
 1.1     fvdl 	if (ifp->if_mtu > (ETHERMTU + ETHER_HDR_LEN + ETHER_CRC_LEN))
 1.1     fvdl 		bge_init_rx_ring_jumbo(sc);
 1.1     fvdl
 1.1     fvdl 	/* Init our RX return ring index */
 1.1     fvdl 	sc->bge_rx_saved_considx = 0;
 1.1     fvdl
 1.1     fvdl 	/* Init TX ring. */
 1.1     fvdl 	bge_init_tx_ring(sc);
 1.1     fvdl
 1.1     fvdl 	/* Turn on transmitter */
 1.1     fvdl 	BGE_SETBIT(sc, BGE_TX_MODE, BGE_TXMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Turn on receiver */
 1.1     fvdl 	BGE_SETBIT(sc, BGE_RX_MODE, BGE_RXMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Tell firmware we're alive. */
 1.1     fvdl 	BGE_SETBIT(sc, BGE_MODE_CTL, BGE_MODECTL_STACKUP);
 1.1     fvdl
 1.1     fvdl 	/* Enable host interrupts. */
 1.1     fvdl 	BGE_SETBIT(sc, BGE_PCI_MISC_CTL, BGE_PCIMISCCTL_CLEAR_INTA);
 1.1     fvdl 	BGE_CLRBIT(sc, BGE_PCI_MISC_CTL, BGE_PCIMISCCTL_MASK_PCI_INTR);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_IRQ0_LO, 0);
 1.1     fvdl
 1.1     fvdl 	bge_ifmedia_upd(ifp);
 1.1     fvdl
 1.1     fvdl 	ifp->if_flags |= IFF_RUNNING;
 1.1     fvdl 	ifp->if_flags &= ~IFF_OACTIVE;
 1.1     fvdl
 1.1     fvdl 	splx(s);
 1.1     fvdl
 1.1     fvdl 	callout_reset(&sc->bge_timeout, hz, bge_tick, sc);
 1.1     fvdl
 1.1     fvdl 	return 0;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Set media options.
 1.1     fvdl  */
 1.1     fvdl int
 1.1     fvdl bge_ifmedia_upd(ifp)
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = ifp->if_softc;
 1.1     fvdl 	struct mii_data *mii = &sc->bge_mii;
 1.1     fvdl 	struct ifmedia *ifm = &sc->bge_ifmedia;
 1.1     fvdl
 1.1     fvdl 	/* If this is a 1000baseX NIC, enable the TBI port. */
 1.1     fvdl 	if (sc->bge_tbi) {
 1.1     fvdl 		if (IFM_TYPE(ifm->ifm_media) != IFM_ETHER)
 1.1     fvdl 			return(EINVAL);
 1.1     fvdl 		switch(IFM_SUBTYPE(ifm->ifm_media)) {
 1.1     fvdl 		case IFM_AUTO:
 1.1     fvdl 			break;
 1.1     fvdl 		case IFM_1000_SX:
 1.1     fvdl 			if ((ifm->ifm_media & IFM_GMASK) == IFM_FDX) {
 1.1     fvdl 				BGE_CLRBIT(sc, BGE_MAC_MODE,
 1.1     fvdl 				    BGE_MACMODE_HALF_DUPLEX);
 1.1     fvdl 			} else {
 1.1     fvdl 				BGE_SETBIT(sc, BGE_MAC_MODE,
 1.1     fvdl 				    BGE_MACMODE_HALF_DUPLEX);
 1.1     fvdl 			}
 1.1     fvdl 			break;
 1.1     fvdl 		default:
 1.1     fvdl 			return(EINVAL);
 1.1     fvdl 		}
 1.1     fvdl 		return(0);
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	sc->bge_link = 0;
 1.1     fvdl 	mii_mediachg(mii);
 1.1     fvdl
 1.1     fvdl 	return(0);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Report current media status.
 1.1     fvdl  */
 1.1     fvdl void
 1.1     fvdl bge_ifmedia_sts(ifp, ifmr)
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl 	struct ifmediareq *ifmr;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = ifp->if_softc;
 1.1     fvdl 	struct mii_data *mii = &sc->bge_mii;
 1.1     fvdl
 1.1     fvdl 	if (sc->bge_tbi) {
 1.1     fvdl 		ifmr->ifm_status = IFM_AVALID;
 1.1     fvdl 		ifmr->ifm_active = IFM_ETHER;
 1.1     fvdl 		if (CSR_READ_4(sc, BGE_MAC_STS) &
 1.1     fvdl 		    BGE_MACSTAT_TBI_PCS_SYNCHED)
 1.1     fvdl 			ifmr->ifm_status |= IFM_ACTIVE;
 1.1     fvdl 		ifmr->ifm_active |= IFM_1000_SX;
 1.1     fvdl 		if (CSR_READ_4(sc, BGE_MAC_MODE) & BGE_MACMODE_HALF_DUPLEX)
 1.1     fvdl 			ifmr->ifm_active |= IFM_HDX;
 1.1     fvdl 		else
 1.1     fvdl 			ifmr->ifm_active |= IFM_FDX;
 1.1     fvdl 		return;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	mii_pollstat(mii);
 1.1     fvdl 	ifmr->ifm_active = mii->mii_media_active;
 1.1     fvdl 	ifmr->ifm_status = mii->mii_media_status;
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl int
 1.1     fvdl bge_ioctl(ifp, command, data)
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl 	u_long command;
 1.1     fvdl 	caddr_t data;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = ifp->if_softc;
 1.1     fvdl 	struct ifreq *ifr = (struct ifreq *) data;
 1.1     fvdl 	int s, error = 0;
 1.1     fvdl 	struct mii_data *mii;
 1.1     fvdl
 1.1     fvdl 	s = splnet();
 1.1     fvdl
 1.1     fvdl 	switch(command) {
 1.1     fvdl 	case SIOCSIFFLAGS:
 1.1     fvdl 		if (ifp->if_flags & IFF_UP) {
 1.1     fvdl 			/*
 1.1     fvdl 			 * If only the state of the PROMISC flag changed,
 1.1     fvdl 			 * then just use the 'set promisc mode' command
 1.1     fvdl 			 * instead of reinitializing the entire NIC. Doing
 1.1     fvdl 			 * a full re-init means reloading the firmware and
 1.1     fvdl 			 * waiting for it to start up, which may take a
 1.1     fvdl 			 * second or two.
 1.1     fvdl 			 */
 1.1     fvdl 			if (ifp->if_flags & IFF_RUNNING &&
 1.1     fvdl 			    ifp->if_flags & IFF_PROMISC &&
 1.1     fvdl 			    !(sc->bge_if_flags & IFF_PROMISC)) {
 1.1     fvdl 				BGE_SETBIT(sc, BGE_RX_MODE,
 1.1     fvdl 				    BGE_RXMODE_RX_PROMISC);
 1.1     fvdl 			} else if (ifp->if_flags & IFF_RUNNING &&
 1.1     fvdl 			    !(ifp->if_flags & IFF_PROMISC) &&
 1.1     fvdl 			    sc->bge_if_flags & IFF_PROMISC) {
 1.1     fvdl 				BGE_CLRBIT(sc, BGE_RX_MODE,
 1.1     fvdl 				    BGE_RXMODE_RX_PROMISC);
 1.1     fvdl 			} else
 1.1     fvdl 				bge_init(ifp);
 1.1     fvdl 		} else {
 1.1     fvdl 			if (ifp->if_flags & IFF_RUNNING) {
 1.1     fvdl 				bge_stop(sc);
 1.1     fvdl 			}
 1.1     fvdl 		}
 1.1     fvdl 		sc->bge_if_flags = ifp->if_flags;
 1.1     fvdl 		error = 0;
 1.1     fvdl 		break;
 1.1     fvdl 	case SIOCSIFMEDIA:
 1.1     fvdl 	case SIOCGIFMEDIA:
 1.1     fvdl 		if (sc->bge_tbi) {
 1.1     fvdl 			error = ifmedia_ioctl(ifp, ifr, &sc->bge_ifmedia,
 1.1     fvdl 			    command);
 1.1     fvdl 		} else {
 1.1     fvdl 			mii = &sc->bge_mii;
 1.1     fvdl 			error = ifmedia_ioctl(ifp, ifr, &mii->mii_media,
 1.1     fvdl 			    command);
 1.1     fvdl 		}
 1.1     fvdl 		error = 0;
 1.1     fvdl 		break;
 1.1     fvdl 	default:
 1.1     fvdl 		error = ether_ioctl(ifp, command, data);
 1.1     fvdl 		if (error == ENETRESET) {
 1.1     fvdl 			bge_setmulti(sc);
 1.1     fvdl 			error = 0;
 1.1     fvdl 		}
 1.1     fvdl 		break;
 1.1     fvdl 	}
 1.1     fvdl
 1.1     fvdl 	splx(s);
 1.1     fvdl
 1.1     fvdl 	return(error);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl void
 1.1     fvdl bge_watchdog(ifp)
 1.1     fvdl 	struct ifnet *ifp;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl
 1.1     fvdl 	sc = ifp->if_softc;
 1.1     fvdl
 1.1     fvdl 	printf("%s: watchdog timeout -- resetting\n", sc->bge_dev.dv_xname);
 1.1     fvdl
 1.1     fvdl 	ifp->if_flags &= ~IFF_RUNNING;
 1.1     fvdl 	bge_init(ifp);
 1.1     fvdl
 1.1     fvdl 	ifp->if_oerrors++;
 1.1     fvdl }
 1.1     fvdl
1.11  thorpej static void
1.11  thorpej bge_stop_block(struct bge_softc *sc, bus_addr_t reg, uint32_t bit)
1.11  thorpej {
1.11  thorpej 	int i;
1.11  thorpej
1.11  thorpej 	BGE_CLRBIT(sc, reg, bit);
1.11  thorpej
1.11  thorpej 	for (i = 0; i < BGE_TIMEOUT; i++) {
1.11  thorpej 		if ((CSR_READ_4(sc, reg) & bit) == 0)
1.11  thorpej 			return;
1.11  thorpej 		delay(100);
1.11  thorpej 	}
1.11  thorpej
1.11  thorpej 	printf("%s: block failed to stop: reg 0x%lx, bit 0x%08x\n",
1.11  thorpej 	    sc->bge_dev.dv_xname, (u_long) reg, bit);
1.11  thorpej }
1.11  thorpej
 1.1     fvdl /*
 1.1     fvdl  * Stop the adapter and free any mbufs allocated to the
 1.1     fvdl  * RX and TX lists.
 1.1     fvdl  */
 1.1     fvdl void
 1.1     fvdl bge_stop(sc)
 1.1     fvdl 	struct bge_softc *sc;
 1.1     fvdl {
 1.1     fvdl 	struct ifnet *ifp = &sc->ethercom.ec_if;
 1.1     fvdl
 1.1     fvdl 	callout_stop(&sc->bge_timeout);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Disable all of the receiver blocks
 1.1     fvdl 	 */
1.11  thorpej 	bge_stop_block(sc, BGE_RX_MODE, BGE_RXMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_RBDI_MODE, BGE_RBDIMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_RXLP_MODE, BGE_RXLPMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_RXLS_MODE, BGE_RXLSMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_RDBDI_MODE, BGE_RBDIMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_RDC_MODE, BGE_RDCMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_RBDC_MODE, BGE_RBDCMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Disable all of the transmit blocks
 1.1     fvdl 	 */
1.11  thorpej 	bge_stop_block(sc, BGE_SRS_MODE, BGE_SRSMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_SBDI_MODE, BGE_SBDIMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_SDI_MODE, BGE_SDIMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_RDMA_MODE, BGE_RDMAMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_SDC_MODE, BGE_SDCMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_DMAC_MODE, BGE_DMACMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_SBDC_MODE, BGE_SBDCMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Shut down all of the memory managers and related
 1.1     fvdl 	 * state machines.
 1.1     fvdl 	 */
1.11  thorpej 	bge_stop_block(sc, BGE_HCC_MODE, BGE_HCCMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_WDMA_MODE, BGE_WDMAMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_MBCF_MODE, BGE_MBCFMODE_ENABLE);
1.11  thorpej
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_FTQ_RESET, 0xFFFFFFFF);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_FTQ_RESET, 0);
1.11  thorpej
1.11  thorpej 	bge_stop_block(sc, BGE_BMAN_MODE, BGE_BMANMODE_ENABLE);
1.11  thorpej 	bge_stop_block(sc, BGE_MARB_MODE, BGE_MARBMODE_ENABLE);
 1.1     fvdl
 1.1     fvdl 	/* Disable host interrupts. */
 1.1     fvdl 	BGE_SETBIT(sc, BGE_PCI_MISC_CTL, BGE_PCIMISCCTL_MASK_PCI_INTR);
 1.1     fvdl 	CSR_WRITE_4(sc, BGE_MBX_IRQ0_LO, 1);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Tell firmware we're shutting down.
 1.1     fvdl 	 */
 1.1     fvdl 	BGE_CLRBIT(sc, BGE_MODE_CTL, BGE_MODECTL_STACKUP);
 1.1     fvdl
 1.1     fvdl 	/* Free the RX lists. */
 1.1     fvdl 	bge_free_rx_ring_std(sc);
 1.1     fvdl
 1.1     fvdl 	/* Free jumbo RX list. */
 1.1     fvdl 	bge_free_rx_ring_jumbo(sc);
 1.1     fvdl
 1.1     fvdl 	/* Free TX buffers. */
 1.1     fvdl 	bge_free_tx_ring(sc);
 1.1     fvdl
 1.1     fvdl 	/*
 1.1     fvdl 	 * Isolate/power down the PHY.
 1.1     fvdl 	 */
 1.1     fvdl 	if (!sc->bge_tbi)
 1.1     fvdl 		mii_down(&sc->bge_mii);
 1.1     fvdl
 1.1     fvdl 	sc->bge_link = 0;
 1.1     fvdl
 1.1     fvdl 	sc->bge_tx_saved_considx = BGE_TXCONS_UNSET;
 1.1     fvdl
 1.1     fvdl 	ifp->if_flags &= ~(IFF_RUNNING | IFF_OACTIVE);
 1.1     fvdl }
 1.1     fvdl
 1.1     fvdl /*
 1.1     fvdl  * Stop all chip I/O so that the kernel's probe routines don't
 1.1     fvdl  * get confused by errant DMAs when rebooting.
 1.1     fvdl  */
 1.1     fvdl void
 1.1     fvdl bge_shutdown(xsc)
 1.1     fvdl 	void *xsc;
 1.1     fvdl {
 1.1     fvdl 	struct bge_softc *sc = (struct bge_softc *)xsc;
 1.1     fvdl
 1.1     fvdl 	bge_stop(sc);
 1.1     fvdl 	bge_reset(sc);
 1.1     fvdl }