dev/pci/if_rge.c

1.31   msaitoh /*	$NetBSD: if_rge.c,v 1.31 2024/01/18 03:47:26 msaitoh Exp $	*/
1.17  jakllsch /*	$OpenBSD: if_rge.c,v 1.9 2020/12/12 11:48:53 jan Exp $	*/
 1.1     sevan
 1.1     sevan /*
1.17  jakllsch  * Copyright (c) 2019, 2020 Kevin Lo <kevlo (at) openbsd.org>
 1.1     sevan  *
 1.1     sevan  * Permission to use, copy, modify, and distribute this software for any
 1.1     sevan  * purpose with or without fee is hereby granted, provided that the above
 1.1     sevan  * copyright notice and this permission notice appear in all copies.
 1.1     sevan  *
 1.1     sevan  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
 1.1     sevan  * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
 1.1     sevan  * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
 1.1     sevan  * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
 1.1     sevan  * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
 1.1     sevan  * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
 1.1     sevan  * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
 1.1     sevan  */
 1.1     sevan
 1.2     sevan #include <sys/cdefs.h>
1.31   msaitoh __KERNEL_RCSID(0, "$NetBSD: if_rge.c,v 1.31 2024/01/18 03:47:26 msaitoh Exp $");
1.30     skrll
1.30     skrll #if defined(_KERNEL_OPT)
1.30     skrll #include "opt_net_mpsafe.h"
1.30     skrll #endif
 1.2     sevan
 1.2     sevan #include <sys/types.h>
 1.1     sevan
 1.1     sevan #include <sys/param.h>
 1.1     sevan #include <sys/systm.h>
 1.1     sevan #include <sys/sockio.h>
 1.1     sevan #include <sys/mbuf.h>
 1.1     sevan #include <sys/kernel.h>
 1.1     sevan #include <sys/socket.h>
 1.1     sevan #include <sys/device.h>
 1.1     sevan #include <sys/endian.h>
 1.3     sevan #include <sys/callout.h>
 1.3     sevan #include <sys/workqueue.h>
 1.1     sevan
 1.1     sevan #include <net/if.h>
 1.2     sevan
 1.2     sevan #include <net/if_dl.h>
 1.2     sevan #include <net/if_ether.h>
 1.2     sevan
 1.1     sevan #include <net/if_media.h>
 1.1     sevan
 1.1     sevan #include <netinet/in.h>
 1.2     sevan #include <net/if_ether.h>
 1.1     sevan
 1.1     sevan #include <net/bpf.h>
 1.1     sevan
 1.2     sevan #include <sys/bus.h>
 1.1     sevan #include <machine/intr.h>
 1.1     sevan
 1.1     sevan #include <dev/mii/mii.h>
 1.1     sevan
 1.1     sevan #include <dev/pci/pcivar.h>
 1.1     sevan #include <dev/pci/pcireg.h>
 1.1     sevan #include <dev/pci/pcidevs.h>
 1.1     sevan
 1.1     sevan #include <dev/pci/if_rgereg.h>
 1.1     sevan
 1.2     sevan #ifdef __NetBSD__
 1.2     sevan #define letoh32 	htole32
 1.2     sevan #define nitems(x) 	__arraycount(x)
 1.7     sevan
 1.7     sevan static struct mbuf *
1.17  jakllsch MCLGETL(struct rge_softc *sc __unused, int how,
1.17  jakllsch     u_int size)
 1.7     sevan {
 1.7     sevan 	struct mbuf *m;
 1.7     sevan
 1.7     sevan 	MGETHDR(m, how, MT_DATA);
 1.7     sevan 	if (m == NULL)
 1.7     sevan 		return NULL;
 1.7     sevan
 1.7     sevan 	MEXTMALLOC(m, size, how);
 1.7     sevan 	if ((m->m_flags & M_EXT) == 0) {
 1.7     sevan 		m_freem(m);
 1.7     sevan 		return NULL;
 1.7     sevan 	}
 1.7     sevan 	return m;
 1.7     sevan }
 1.7     sevan
 1.3     sevan #ifdef NET_MPSAFE
 1.3     sevan #define 	RGE_MPSAFE	1
 1.3     sevan #define 	CALLOUT_FLAGS	CALLOUT_MPSAFE
 1.3     sevan #else
 1.3     sevan #define 	CALLOUT_FLAGS	0
 1.3     sevan #endif
 1.2     sevan #endif
 1.2     sevan
1.17  jakllsch #ifdef RGE_DEBUG
1.17  jakllsch #define DPRINTF(x)	do { if (rge_debug > 0) printf x; } while (0)
1.17  jakllsch int rge_debug = 0;
1.17  jakllsch #else
1.17  jakllsch #define DPRINTF(x)
1.17  jakllsch #endif
1.17  jakllsch
 1.2     sevan static int		rge_match(device_t, cfdata_t, void *);
 1.5     skrll static void		rge_attach(device_t, device_t, void *);
 1.1     sevan int		rge_intr(void *);
 1.1     sevan int		rge_encap(struct rge_softc *, struct mbuf *, int);
 1.2     sevan int		rge_ioctl(struct ifnet *, u_long, void *);
 1.2     sevan void		rge_start(struct ifnet *);
 1.1     sevan void		rge_watchdog(struct ifnet *);
 1.1     sevan int		rge_init(struct ifnet *);
1.17  jakllsch void		rge_stop(struct ifnet *, int);
 1.1     sevan int		rge_ifmedia_upd(struct ifnet *);
 1.1     sevan void		rge_ifmedia_sts(struct ifnet *, struct ifmediareq *);
 1.1     sevan int		rge_allocmem(struct rge_softc *);
 1.1     sevan int		rge_newbuf(struct rge_softc *, int);
1.26       mrg static int	rge_rx_list_init(struct rge_softc *);
1.26       mrg static void	rge_rx_list_fini(struct rge_softc *);
1.26       mrg static void	rge_tx_list_init(struct rge_softc *);
1.26       mrg static void	rge_tx_list_fini(struct rge_softc *);
 1.1     sevan int		rge_rxeof(struct rge_softc *);
 1.1     sevan int		rge_txeof(struct rge_softc *);
 1.1     sevan void		rge_reset(struct rge_softc *);
 1.1     sevan void		rge_iff(struct rge_softc *);
 1.1     sevan void		rge_set_phy_power(struct rge_softc *, int);
 1.1     sevan void		rge_phy_config(struct rge_softc *);
1.17  jakllsch void		rge_phy_config_mac_cfg2(struct rge_softc *);
1.17  jakllsch void		rge_phy_config_mac_cfg3(struct rge_softc *);
1.17  jakllsch void		rge_phy_config_mac_cfg4(struct rge_softc *);
1.17  jakllsch void		rge_phy_config_mac_cfg5(struct rge_softc *);
1.17  jakllsch void		rge_phy_config_mcu(struct rge_softc *, uint16_t);
 1.1     sevan void		rge_set_macaddr(struct rge_softc *, const uint8_t *);
 1.1     sevan void		rge_get_macaddr(struct rge_softc *, uint8_t *);
 1.1     sevan void		rge_hw_init(struct rge_softc *);
 1.1     sevan void		rge_disable_phy_ocp_pwrsave(struct rge_softc *);
 1.1     sevan void		rge_patch_phy_mcu(struct rge_softc *, int);
 1.1     sevan void		rge_add_media_types(struct rge_softc *);
 1.1     sevan void		rge_config_imtype(struct rge_softc *, int);
1.17  jakllsch void		rge_disable_hw_im(struct rge_softc *);
 1.1     sevan void		rge_disable_sim_im(struct rge_softc *);
 1.1     sevan void		rge_setup_sim_im(struct rge_softc *);
 1.1     sevan void		rge_setup_intr(struct rge_softc *, int);
 1.1     sevan void		rge_exit_oob(struct rge_softc *);
 1.1     sevan void		rge_write_csi(struct rge_softc *, uint32_t, uint32_t);
 1.1     sevan uint32_t	rge_read_csi(struct rge_softc *, uint32_t);
 1.1     sevan void		rge_write_mac_ocp(struct rge_softc *, uint16_t, uint16_t);
 1.1     sevan uint16_t	rge_read_mac_ocp(struct rge_softc *, uint16_t);
 1.1     sevan void		rge_write_ephy(struct rge_softc *, uint16_t, uint16_t);
1.17  jakllsch uint16_t	rge_read_ephy(struct rge_softc *, uint16_t);
 1.1     sevan void		rge_write_phy(struct rge_softc *, uint16_t, uint16_t, uint16_t);
1.17  jakllsch uint16_t	rge_read_phy(struct rge_softc *, uint16_t, uint16_t);
 1.1     sevan void		rge_write_phy_ocp(struct rge_softc *, uint16_t, uint16_t);
 1.1     sevan uint16_t	rge_read_phy_ocp(struct rge_softc *, uint16_t);
 1.1     sevan int		rge_get_link_status(struct rge_softc *);
1.30     skrll void		rge_txstart(void *);
 1.1     sevan void		rge_tick(void *);
 1.1     sevan void		rge_link_state(struct rge_softc *);
 1.1     sevan
 1.1     sevan static const struct {
 1.1     sevan 	uint16_t reg;
 1.1     sevan 	uint16_t val;
1.17  jakllsch }  rtl8125_mac_cfg2_mcu[] = {
 1.1     sevan 	RTL8125_MAC_CFG2_MCU
 1.1     sevan }, rtl8125_mac_cfg3_mcu[] = {
 1.1     sevan 	RTL8125_MAC_CFG3_MCU
1.17  jakllsch }, rtl8125_mac_cfg4_mcu[] = {
1.17  jakllsch 	RTL8125_MAC_CFG4_MCU
1.17  jakllsch }, rtl8125_mac_cfg5_mcu[] = {
1.17  jakllsch 	RTL8125_MAC_CFG5_MCU
 1.1     sevan };
 1.1     sevan
 1.2     sevan CFATTACH_DECL_NEW(rge, sizeof(struct rge_softc), rge_match, rge_attach,
 1.2     sevan 		NULL, NULL); /* Sevan - detach function? */
 1.1     sevan
1.19   thorpej static const struct device_compatible_entry compat_data[] = {
1.19   thorpej 	{ .id = PCI_ID_CODE(PCI_VENDOR_REALTEK, PCI_PRODUCT_REALTEK_E3000) },
1.19   thorpej 	{ .id = PCI_ID_CODE(PCI_VENDOR_REALTEK, PCI_PRODUCT_REALTEK_RT8125) },
1.19   thorpej
1.19   thorpej 	PCI_COMPAT_EOL
 1.1     sevan };
 1.1     sevan
 1.2     sevan static int
 1.2     sevan rge_match(device_t parent, cfdata_t match, void *aux)
 1.1     sevan {
 1.2     sevan 	struct pci_attach_args *pa =aux;
 1.2     sevan
1.19   thorpej 	return pci_compatible_match(pa, compat_data);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.2     sevan rge_attach(device_t parent, device_t self, void *aux)
 1.1     sevan {
1.11     sevan 	struct rge_softc *sc = device_private(self);
 1.1     sevan 	struct pci_attach_args *pa = aux;
 1.1     sevan 	pci_chipset_tag_t pc = pa->pa_pc;
1.17  jakllsch 	pci_intr_handle_t *ihp;
 1.2     sevan 	char intrbuf[PCI_INTRSTR_LEN];
 1.1     sevan 	const char *intrstr = NULL;
 1.1     sevan 	struct ifnet *ifp;
 1.1     sevan 	pcireg_t reg;
 1.1     sevan 	uint32_t hwrev;
 1.1     sevan 	uint8_t eaddr[ETHER_ADDR_LEN];
 1.1     sevan 	int offset;
1.17  jakllsch 	pcireg_t command;
1.31   msaitoh 	const char *revstr;
 1.1     sevan
 1.1     sevan 	pci_set_powerstate(pa->pa_pc, pa->pa_tag, PCI_PMCSR_STATE_D0);
 1.1     sevan
1.12     sevan 	sc->sc_dev = self;
1.12     sevan
1.17  jakllsch 	pci_aprint_devinfo(pa, "Ethernet controller");
1.17  jakllsch
 1.5     skrll 	/*
 1.1     sevan 	 * Map control/status registers.
 1.1     sevan 	 */
 1.1     sevan 	if (pci_mapreg_map(pa, RGE_PCI_BAR2, PCI_MAPREG_TYPE_MEM |
 1.1     sevan 	    PCI_MAPREG_MEM_TYPE_64BIT, 0, &sc->rge_btag, &sc->rge_bhandle,
 1.2     sevan 	    NULL, &sc->rge_bsize)) {
 1.1     sevan 		if (pci_mapreg_map(pa, RGE_PCI_BAR1, PCI_MAPREG_TYPE_MEM |
 1.1     sevan 		    PCI_MAPREG_MEM_TYPE_32BIT, 0, &sc->rge_btag,
 1.2     sevan 		    &sc->rge_bhandle, NULL, &sc->rge_bsize)) {
 1.1     sevan 			if (pci_mapreg_map(pa, RGE_PCI_BAR0, PCI_MAPREG_TYPE_IO,
 1.1     sevan 			    0, &sc->rge_btag, &sc->rge_bhandle, NULL,
 1.2     sevan 			    &sc->rge_bsize)) {
1.13     sevan 				aprint_error(": can't map mem or i/o space\n");
 1.1     sevan 				return;
 1.1     sevan 			}
 1.1     sevan 		}
 1.1     sevan 	}
 1.1     sevan
1.17  jakllsch 	int counts[PCI_INTR_TYPE_SIZE] = {
1.17  jakllsch  		[PCI_INTR_TYPE_INTX] = 1,
1.17  jakllsch  		[PCI_INTR_TYPE_MSI] = 1,
1.17  jakllsch  		[PCI_INTR_TYPE_MSIX] = 1,
1.17  jakllsch  	};
1.17  jakllsch 	int max_type = PCI_INTR_TYPE_MSIX;
 1.5     skrll 	/*
 1.1     sevan 	 * Allocate interrupt.
 1.1     sevan 	 */
1.17  jakllsch 	if (pci_intr_alloc(pa, &ihp, counts, max_type) != 0) {
1.13     sevan 		aprint_error(": couldn't map interrupt\n");
 1.1     sevan 		return;
 1.1     sevan 	}
1.17  jakllsch 	switch (pci_intr_type(pc, ihp[0])) {
1.17  jakllsch 	case PCI_INTR_TYPE_MSIX:
1.17  jakllsch 	case PCI_INTR_TYPE_MSI:
1.17  jakllsch 		sc->rge_flags |= RGE_FLAG_MSI;
1.17  jakllsch 		break;
1.17  jakllsch 	default:
1.17  jakllsch 		break;
1.17  jakllsch 	}
1.17  jakllsch 	intrstr = pci_intr_string(pc, ihp[0], intrbuf, sizeof(intrbuf));
1.17  jakllsch 	sc->sc_ih = pci_intr_establish_xname(pc, ihp[0], IPL_NET, rge_intr,
1.14     sevan 	    sc, device_xname(sc->sc_dev));
 1.1     sevan 	if (sc->sc_ih == NULL) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, ": couldn't establish interrupt");
 1.1     sevan 		if (intrstr != NULL)
1.13     sevan 			aprint_error(" at %s\n", intrstr);
1.13     sevan 		aprint_error("\n");
 1.1     sevan 		return;
 1.1     sevan 	}
1.13     sevan 	aprint_normal_dev(sc->sc_dev, "interrupting at %s\n", intrstr);
 1.1     sevan
 1.9   thorpej 	if (pci_dma64_available(pa))
 1.9   thorpej 		sc->sc_dmat = pa->pa_dmat64;
 1.9   thorpej 	else
 1.9   thorpej 		sc->sc_dmat = pa->pa_dmat;
 1.9   thorpej
 1.1     sevan 	sc->sc_pc = pa->pa_pc;
 1.1     sevan 	sc->sc_tag = pa->pa_tag;
 1.1     sevan
 1.1     sevan 	/* Determine hardware revision */
 1.1     sevan 	hwrev = RGE_READ_4(sc, RGE_TXCFG) & RGE_TXCFG_HWREV;
 1.1     sevan 	switch (hwrev) {
 1.1     sevan 	case 0x60800000:
 1.1     sevan 		sc->rge_type = MAC_CFG2;
1.31   msaitoh 		revstr = "Z1";
 1.1     sevan 		break;
 1.1     sevan 	case 0x60900000:
 1.1     sevan 		sc->rge_type = MAC_CFG3;
1.31   msaitoh 		revstr = "Z2";
 1.1     sevan 		break;
1.17  jakllsch 	case 0x64000000:
1.17  jakllsch 		sc->rge_type = MAC_CFG4;
1.31   msaitoh 		revstr = "A";
1.17  jakllsch 		break;
1.17  jakllsch 	case 0x64100000:
1.17  jakllsch 		sc->rge_type = MAC_CFG5;
1.31   msaitoh 		revstr = "B";
1.17  jakllsch 		break;
 1.1     sevan 	default:
1.13     sevan 		aprint_error(": unknown version 0x%08x\n", hwrev);
 1.1     sevan 		return;
 1.1     sevan 	}
 1.1     sevan
1.31   msaitoh 	aprint_normal_dev(sc->sc_dev, "HW rev. %s\n", revstr);
 1.1     sevan 	rge_config_imtype(sc, RGE_IMTYPE_SIM);
 1.1     sevan
 1.5     skrll 	/*
 1.1     sevan 	 * PCI Express check.
 1.1     sevan 	 */
 1.1     sevan 	if (pci_get_capability(pa->pa_pc, pa->pa_tag, PCI_CAP_PCIEXPRESS,
 1.1     sevan 	    &offset, NULL)) {
1.17  jakllsch 		/* Disable PCIe ASPM and ECPM. */
 1.1     sevan 		reg = pci_conf_read(pa->pa_pc, pa->pa_tag,
 1.2     sevan 		    offset + PCIE_LCSR);
1.17  jakllsch 		reg &= ~(PCIE_LCSR_ASPM_L0S | PCIE_LCSR_ASPM_L1 |
1.17  jakllsch 		    PCIE_LCSR_ENCLKPM);
 1.2     sevan 		pci_conf_write(pa->pa_pc, pa->pa_tag, offset + PCIE_LCSR,
 1.1     sevan 		    reg);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	rge_exit_oob(sc);
 1.1     sevan 	rge_hw_init(sc);
 1.1     sevan
 1.1     sevan 	rge_get_macaddr(sc, eaddr);
1.13     sevan 	aprint_normal_dev(sc->sc_dev, "Ethernet address %s\n",
1.13     sevan 	    ether_sprintf(eaddr));
 1.1     sevan
 1.2     sevan 	memcpy(sc->sc_enaddr, eaddr, ETHER_ADDR_LEN);
 1.1     sevan
 1.1     sevan 	rge_set_phy_power(sc, 1);
 1.1     sevan 	rge_phy_config(sc);
 1.1     sevan
 1.1     sevan 	if (rge_allocmem(sc))
 1.1     sevan 		return;
 1.1     sevan
 1.2     sevan 	ifp = &sc->sc_ec.ec_if;
 1.1     sevan 	ifp->if_softc = sc;
1.14     sevan 	strlcpy(ifp->if_xname, device_xname(sc->sc_dev), IFNAMSIZ);
 1.1     sevan 	ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST;
 1.2     sevan #ifdef RGE_MPSAFE
1.18  knakahar 	ifp->if_extflags = IFEF_MPSAFE;
 1.2     sevan #endif
 1.1     sevan 	ifp->if_ioctl = rge_ioctl;
1.17  jakllsch 	ifp->if_stop = rge_stop;
 1.2     sevan 	ifp->if_start = rge_start;
1.17  jakllsch 	ifp->if_init = rge_init;
 1.1     sevan 	ifp->if_watchdog = rge_watchdog;
1.17  jakllsch 	IFQ_SET_MAXLEN(&ifp->if_snd, RGE_TX_LIST_CNT - 1);
 1.1     sevan
1.17  jakllsch #if notyet
1.17  jakllsch 	ifp->if_capabilities = IFCAP_CSUM_IPv4_Rx |
 1.2     sevan 	    IFCAP_CSUM_IPv4_Tx |IFCAP_CSUM_TCPv4_Rx | IFCAP_CSUM_TCPv4_Tx|
 1.2     sevan 	    IFCAP_CSUM_UDPv4_Rx | IFCAP_CSUM_UDPv4_Tx;
1.17  jakllsch #endif
 1.1     sevan
1.17  jakllsch 	sc->sc_ec.ec_capabilities |= ETHERCAP_VLAN_MTU;
1.17  jakllsch 	sc->sc_ec.ec_capabilities |= ETHERCAP_VLAN_HWTAGGING;
 1.1     sevan
 1.3     sevan 	callout_init(&sc->sc_timeout, CALLOUT_FLAGS);
 1.3     sevan 	callout_setfunc(&sc->sc_timeout, rge_tick, sc);
1.17  jakllsch
1.17  jakllsch 	command = pci_conf_read(pa->pa_pc, pa->pa_tag, PCI_COMMAND_STATUS_REG);
1.17  jakllsch 	command |= PCI_COMMAND_MASTER_ENABLE;
1.17  jakllsch 	pci_conf_write(pa->pa_pc, pa->pa_tag, PCI_COMMAND_STATUS_REG, command);
 1.1     sevan
 1.1     sevan 	/* Initialize ifmedia structures. */
1.17  jakllsch 	sc->sc_ec.ec_ifmedia = &sc->sc_media;
 1.1     sevan 	ifmedia_init(&sc->sc_media, IFM_IMASK, rge_ifmedia_upd,
 1.1     sevan 	    rge_ifmedia_sts);
 1.1     sevan 	rge_add_media_types(sc);
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_AUTO, 0, NULL);
 1.1     sevan 	ifmedia_set(&sc->sc_media, IFM_ETHER | IFM_AUTO);
 1.1     sevan 	sc->sc_media.ifm_media = sc->sc_media.ifm_cur->ifm_media;
 1.1     sevan
 1.1     sevan 	if_attach(ifp);
1.29   mlelstv 	if_deferred_start_init(ifp, NULL);
 1.2     sevan 	ether_ifattach(ifp, eaddr);
1.20   msaitoh
1.20   msaitoh 	if (pmf_device_register(self, NULL, NULL))
1.20   msaitoh 		pmf_class_network_register(self, ifp);
1.20   msaitoh 	else
1.20   msaitoh 		aprint_error_dev(self, "couldn't establish power handler\n");
 1.1     sevan }
 1.1     sevan
 1.1     sevan int
 1.1     sevan rge_intr(void *arg)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = arg;
 1.2     sevan 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1     sevan 	uint32_t status;
 1.1     sevan 	int claimed = 0, rx, tx;
 1.1     sevan
 1.1     sevan 	if (!(ifp->if_flags & IFF_RUNNING))
 1.1     sevan 		return (0);
 1.1     sevan
 1.1     sevan 	/* Disable interrupts. */
 1.1     sevan 	RGE_WRITE_4(sc, RGE_IMR, 0);
 1.1     sevan
 1.1     sevan 	if (!(sc->rge_flags & RGE_FLAG_MSI)) {
1.17  jakllsch 		if ((RGE_READ_4(sc, RGE_ISR) & sc->rge_intrs) == 0)
 1.1     sevan 			return (0);
 1.1     sevan 	}
1.17  jakllsch
1.17  jakllsch 	status = RGE_READ_4(sc, RGE_ISR);
 1.1     sevan 	if (status)
 1.1     sevan 		RGE_WRITE_4(sc, RGE_ISR, status);
 1.1     sevan
 1.1     sevan 	if (status & RGE_ISR_PCS_TIMEOUT)
 1.1     sevan 		claimed = 1;
 1.1     sevan
 1.1     sevan 	rx = tx = 0;
1.17  jakllsch 	if (status & sc->rge_intrs) {
 1.1     sevan 		if (status &
 1.1     sevan 		    (sc->rge_rx_ack | RGE_ISR_RX_ERR | RGE_ISR_RX_FIFO_OFLOW)) {
 1.1     sevan 			rx |= rge_rxeof(sc);
 1.1     sevan 			claimed = 1;
 1.1     sevan 		}
 1.1     sevan
 1.1     sevan 		if (status & (sc->rge_tx_ack | RGE_ISR_TX_ERR)) {
 1.1     sevan 			tx |= rge_txeof(sc);
 1.1     sevan 			claimed = 1;
 1.1     sevan 		}
 1.1     sevan
 1.1     sevan 		if (status & RGE_ISR_SYSTEM_ERR) {
 1.2     sevan 			KERNEL_LOCK(1, NULL);
 1.1     sevan 			rge_init(ifp);
 1.2     sevan 			KERNEL_UNLOCK_ONE(NULL);
 1.1     sevan 			claimed = 1;
 1.1     sevan 		}
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	if (sc->rge_timerintr) {
 1.1     sevan 		if ((tx | rx) == 0) {
 1.1     sevan 			/*
 1.1     sevan 			 * Nothing needs to be processed, fallback
 1.1     sevan 			 * to use TX/RX interrupts.
 1.1     sevan 			 */
 1.1     sevan 			rge_setup_intr(sc, RGE_IMTYPE_NONE);
 1.1     sevan
 1.1     sevan 			/*
 1.1     sevan 			 * Recollect, mainly to avoid the possible
 1.1     sevan 			 * race introduced by changing interrupt
 1.1     sevan 			 * masks.
 1.1     sevan 			 */
 1.1     sevan 			rge_rxeof(sc);
 1.1     sevan 			rge_txeof(sc);
 1.1     sevan 		} else
 1.1     sevan 			RGE_WRITE_4(sc, RGE_TIMERCNT, 1);
 1.1     sevan 	} else if (tx | rx) {
 1.1     sevan 		/*
 1.1     sevan 		 * Assume that using simulated interrupt moderation
 1.1     sevan 		 * (hardware timer based) could reduce the interrupt
 1.1     sevan 		 * rate.
 1.1     sevan 		 */
 1.1     sevan 		rge_setup_intr(sc, RGE_IMTYPE_SIM);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	RGE_WRITE_4(sc, RGE_IMR, sc->rge_intrs);
 1.1     sevan
 1.1     sevan 	return (claimed);
 1.1     sevan }
 1.1     sevan
 1.1     sevan int
 1.1     sevan rge_encap(struct rge_softc *sc, struct mbuf *m, int idx)
 1.1     sevan {
 1.1     sevan 	struct rge_tx_desc *d = NULL;
 1.1     sevan 	struct rge_txq *txq;
 1.1     sevan 	bus_dmamap_t txmap;
 1.1     sevan 	uint32_t cmdsts, cflags = 0;
 1.1     sevan 	int cur, error, i, last, nsegs;
 1.1     sevan
1.17  jakllsch #if notyet
 1.1     sevan 	/*
 1.1     sevan 	 * Set RGE_TDEXTSTS_IPCSUM if any checksum offloading is requested.
 1.1     sevan 	 * Otherwise, RGE_TDEXTSTS_TCPCSUM / RGE_TDEXTSTS_UDPCSUM does not
 1.1     sevan 	 * take affect.
 1.1     sevan 	 */
 1.1     sevan 	if ((m->m_pkthdr.csum_flags &
 1.2     sevan 	    (M_CSUM_IPv4 | M_CSUM_TCPv4 | M_CSUM_UDPv4)) != 0) {
 1.1     sevan 		cflags |= RGE_TDEXTSTS_IPCSUM;
 1.1     sevan 		if (m->m_pkthdr.csum_flags & M_TCP_CSUM_OUT)
 1.1     sevan 			cflags |= RGE_TDEXTSTS_TCPCSUM;
 1.1     sevan 		if (m->m_pkthdr.csum_flags & M_UDP_CSUM_OUT)
 1.1     sevan 			cflags |= RGE_TDEXTSTS_UDPCSUM;
 1.1     sevan 	}
1.17  jakllsch #endif
 1.1     sevan
 1.1     sevan 	txq = &sc->rge_ldata.rge_txq[idx];
 1.1     sevan 	txmap = txq->txq_dmamap;
 1.1     sevan
 1.1     sevan 	error = bus_dmamap_load_mbuf(sc->sc_dmat, txmap, m, BUS_DMA_NOWAIT);
 1.1     sevan 	switch (error) {
 1.1     sevan 	case 0:
 1.1     sevan 		break;
 1.1     sevan 	case EFBIG: /* mbuf chain is too fragmented */
 1.1     sevan 		if (m_defrag(m, M_DONTWAIT) == 0 &&
 1.1     sevan 		    bus_dmamap_load_mbuf(sc->sc_dmat, txmap, m,
 1.1     sevan 		    BUS_DMA_NOWAIT) == 0)
 1.1     sevan 			break;
 1.1     sevan
 1.1     sevan 		/* FALLTHROUGH */
 1.1     sevan 	default:
 1.1     sevan 		return (0);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	bus_dmamap_sync(sc->sc_dmat, txmap, 0, txmap->dm_mapsize,
 1.1     sevan 	    BUS_DMASYNC_PREWRITE);
 1.1     sevan
 1.1     sevan 	nsegs = txmap->dm_nsegs;
 1.1     sevan
 1.1     sevan 	/* Set up hardware VLAN tagging. */
1.17  jakllsch 	if (vlan_has_tag(m))
1.17  jakllsch 		cflags |= bswap16(vlan_get_tag(m)) | RGE_TDEXTSTS_VTAG;
 1.1     sevan
1.17  jakllsch 	last = cur = idx;
 1.1     sevan 	cmdsts = RGE_TDCMDSTS_SOF;
 1.1     sevan
 1.1     sevan 	for (i = 0; i < txmap->dm_nsegs; i++) {
 1.1     sevan 		d = &sc->rge_ldata.rge_tx_list[cur];
 1.1     sevan
 1.1     sevan 		d->rge_extsts = htole32(cflags);
 1.1     sevan 		d->rge_addrlo = htole32(RGE_ADDR_LO(txmap->dm_segs[i].ds_addr));
 1.1     sevan 		d->rge_addrhi = htole32(RGE_ADDR_HI(txmap->dm_segs[i].ds_addr));
 1.1     sevan
 1.1     sevan 		cmdsts |= txmap->dm_segs[i].ds_len;
 1.1     sevan
 1.1     sevan 		if (cur == RGE_TX_LIST_CNT - 1)
 1.1     sevan 			cmdsts |= RGE_TDCMDSTS_EOR;
 1.1     sevan
 1.1     sevan 		d->rge_cmdsts = htole32(cmdsts);
 1.1     sevan
 1.1     sevan 		last = cur;
 1.1     sevan 		cmdsts = RGE_TDCMDSTS_OWN;
 1.1     sevan 		cur = RGE_NEXT_TX_DESC(cur);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Set EOF on the last descriptor. */
 1.1     sevan 	d->rge_cmdsts |= htole32(RGE_TDCMDSTS_EOF);
 1.1     sevan
 1.1     sevan 	/* Transfer ownership of packet to the chip. */
 1.1     sevan 	d = &sc->rge_ldata.rge_tx_list[idx];
 1.1     sevan
 1.1     sevan 	d->rge_cmdsts |= htole32(RGE_TDCMDSTS_OWN);
 1.1     sevan
 1.1     sevan 	bus_dmamap_sync(sc->sc_dmat, sc->rge_ldata.rge_tx_list_map,
 1.1     sevan 	    cur * sizeof(struct rge_tx_desc), sizeof(struct rge_tx_desc),
 1.1     sevan 	    BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
 1.1     sevan
 1.1     sevan 	/* Update info of TX queue and descriptors. */
 1.1     sevan 	txq->txq_mbuf = m;
 1.1     sevan 	txq->txq_descidx = last;
 1.1     sevan
 1.1     sevan 	return (nsegs);
 1.1     sevan }
 1.1     sevan
 1.1     sevan int
 1.2     sevan rge_ioctl(struct ifnet *ifp, u_long cmd, void *data)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = ifp->if_softc;
1.17  jakllsch 	//struct ifreq *ifr = (struct ifreq *)data;
 1.1     sevan 	int s, error = 0;
 1.1     sevan
 1.1     sevan 	s = splnet();
 1.1     sevan
 1.1     sevan 	switch (cmd) {
 1.1     sevan 	case SIOCSIFFLAGS:
1.17  jakllsch 		if ((error = ifioctl_common(ifp, cmd, data)) != 0)
1.17  jakllsch 			break;
1.17  jakllsch 		/* XXX set an ifflags callback and let ether_ioctl
1.17  jakllsch 		 * handle all of this.
1.17  jakllsch 		 */
 1.1     sevan 		if (ifp->if_flags & IFF_UP) {
 1.1     sevan 			if (ifp->if_flags & IFF_RUNNING)
 1.1     sevan 				error = ENETRESET;
 1.1     sevan 			else
 1.1     sevan 				rge_init(ifp);
 1.1     sevan 		} else {
 1.1     sevan 			if (ifp->if_flags & IFF_RUNNING)
1.17  jakllsch 				rge_stop(ifp, 1);
 1.1     sevan 		}
 1.1     sevan 		break;
 1.1     sevan 	default:
 1.2     sevan 		error = ether_ioctl(ifp, cmd, data);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	if (error == ENETRESET) {
 1.1     sevan 		if (ifp->if_flags & IFF_RUNNING)
 1.1     sevan 			rge_iff(sc);
 1.1     sevan 		error = 0;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	splx(s);
 1.1     sevan 	return (error);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.3     sevan rge_start(struct ifnet *ifp)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = ifp->if_softc;
 1.1     sevan 	struct mbuf *m;
 1.1     sevan 	int free, idx, used;
 1.1     sevan 	int queued = 0;
 1.1     sevan
 1.2     sevan #define LINK_STATE_IS_UP(_s)    \
 1.2     sevan 	((_s) >= LINK_STATE_UP || (_s) == LINK_STATE_UNKNOWN)
 1.2     sevan
 1.1     sevan 	if (!LINK_STATE_IS_UP(ifp->if_link_state)) {
1.17  jakllsch 		IFQ_PURGE(&ifp->if_snd);
 1.1     sevan 		return;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Calculate free space. */
 1.1     sevan 	idx = sc->rge_ldata.rge_txq_prodidx;
 1.1     sevan 	free = sc->rge_ldata.rge_txq_considx;
 1.1     sevan 	if (free <= idx)
 1.1     sevan 		free += RGE_TX_LIST_CNT;
 1.1     sevan 	free -= idx;
 1.1     sevan
 1.1     sevan 	for (;;) {
 1.1     sevan 		if (RGE_TX_NSEGS >= free + 2) {
 1.3     sevan 			SET(ifp->if_flags, IFF_OACTIVE);
 1.1     sevan 			break;
 1.1     sevan 		}
 1.1     sevan
 1.3     sevan 		IFQ_DEQUEUE(&ifp->if_snd, m);
 1.1     sevan 		if (m == NULL)
 1.1     sevan 			break;
 1.1     sevan
 1.1     sevan 		used = rge_encap(sc, m, idx);
 1.1     sevan 		if (used == 0) {
 1.1     sevan 			m_freem(m);
 1.1     sevan 			continue;
 1.1     sevan 		}
 1.1     sevan
 1.1     sevan 		KASSERT(used <= free);
 1.1     sevan 		free -= used;
 1.1     sevan
1.17  jakllsch 		bpf_mtap(ifp, m, BPF_D_OUT);
 1.1     sevan
 1.1     sevan 		idx += used;
 1.1     sevan 		if (idx >= RGE_TX_LIST_CNT)
 1.1     sevan 			idx -= RGE_TX_LIST_CNT;
 1.1     sevan
 1.1     sevan 		queued++;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	if (queued == 0)
 1.1     sevan 		return;
 1.1     sevan
 1.1     sevan 	/* Set a timeout in case the chip goes out to lunch. */
 1.1     sevan 	ifp->if_timer = 5;
 1.1     sevan
 1.1     sevan 	sc->rge_ldata.rge_txq_prodidx = idx;
1.30     skrll 	rge_txstart(sc);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_watchdog(struct ifnet *ifp)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = ifp->if_softc;
 1.1     sevan
1.16  jakllsch 	device_printf(sc->sc_dev, "watchdog timeout\n");
 1.4     skrll 	if_statinc(ifp, if_oerrors);
 1.1     sevan
 1.1     sevan 	rge_init(ifp);
 1.1     sevan }
 1.1     sevan
 1.1     sevan int
 1.1     sevan rge_init(struct ifnet *ifp)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = ifp->if_softc;
 1.1     sevan 	uint32_t val;
1.26       mrg 	unsigned i;
 1.1     sevan
1.17  jakllsch 	rge_stop(ifp, 0);
 1.1     sevan
 1.1     sevan 	/* Set MAC address. */
1.17  jakllsch 	rge_set_macaddr(sc, CLLADDR(ifp->if_sadl));
 1.1     sevan
1.17  jakllsch 	/* Set Maximum frame size. */
1.17  jakllsch 	RGE_WRITE_2(sc, RGE_RXMAXSIZE, RGE_JUMBO_FRAMELEN);
 1.1     sevan
 1.1     sevan 	/* Initialize RX descriptors list. */
1.26       mrg 	int error = rge_rx_list_init(sc);
1.26       mrg 	if (error != 0) {
1.16  jakllsch 		device_printf(sc->sc_dev,
1.13     sevan 		    "init failed: no memory for RX buffers\n");
1.17  jakllsch 		rge_stop(ifp, 1);
1.26       mrg 		return error;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Initialize TX descriptors. */
 1.1     sevan 	rge_tx_list_init(sc);
 1.1     sevan
 1.1     sevan 	/* Load the addresses of the RX and TX lists into the chip. */
 1.1     sevan 	RGE_WRITE_4(sc, RGE_RXDESC_ADDR_LO,
 1.1     sevan 	    RGE_ADDR_LO(sc->rge_ldata.rge_rx_list_map->dm_segs[0].ds_addr));
 1.1     sevan 	RGE_WRITE_4(sc, RGE_RXDESC_ADDR_HI,
 1.1     sevan 	    RGE_ADDR_HI(sc->rge_ldata.rge_rx_list_map->dm_segs[0].ds_addr));
 1.1     sevan 	RGE_WRITE_4(sc, RGE_TXDESC_ADDR_LO,
 1.1     sevan 	    RGE_ADDR_LO(sc->rge_ldata.rge_tx_list_map->dm_segs[0].ds_addr));
 1.1     sevan 	RGE_WRITE_4(sc, RGE_TXDESC_ADDR_HI,
 1.1     sevan 	    RGE_ADDR_HI(sc->rge_ldata.rge_tx_list_map->dm_segs[0].ds_addr));
 1.1     sevan
 1.1     sevan 	RGE_SETBIT_1(sc, RGE_EECMD, RGE_EECMD_WRITECFG);
 1.1     sevan
 1.1     sevan 	RGE_CLRBIT_1(sc, 0xf1, 0x80);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_CFG2, RGE_CFG2_CLKREQ_EN);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_CFG5, RGE_CFG5_PME_STS);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_CFG3, RGE_CFG3_RDY_TO_L23);
 1.1     sevan
 1.1     sevan 	/* Clear interrupt moderation timer. */
 1.1     sevan 	for (i = 0; i < 64; i++)
1.17  jakllsch 		RGE_WRITE_4(sc, RGE_INTMITI(i), 0);
 1.1     sevan
 1.1     sevan 	/* Set the initial RX and TX configurations. */
 1.1     sevan 	RGE_WRITE_4(sc, RGE_RXCFG, RGE_RXCFG_CONFIG);
 1.1     sevan 	RGE_WRITE_4(sc, RGE_TXCFG, RGE_TXCFG_CONFIG);
 1.1     sevan
 1.1     sevan 	val = rge_read_csi(sc, 0x70c) & ~0xff000000;
 1.1     sevan 	rge_write_csi(sc, 0x70c, val | 0x27000000);
 1.1     sevan
 1.1     sevan 	/* Enable hardware optimization function. */
 1.1     sevan 	val = pci_conf_read(sc->sc_pc, sc->sc_tag, 0x78) & ~0x00007000;
 1.1     sevan 	pci_conf_write(sc->sc_pc, sc->sc_tag, 0x78, val | 0x00005000);
 1.1     sevan
 1.1     sevan 	RGE_WRITE_2(sc, 0x0382, 0x221b);
 1.1     sevan 	RGE_WRITE_1(sc, 0x4500, 0);
 1.1     sevan 	RGE_WRITE_2(sc, 0x4800, 0);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_CFG1, RGE_CFG1_SPEED_DOWN);
 1.1     sevan
 1.1     sevan 	rge_write_mac_ocp(sc, 0xc140, 0xffff);
 1.1     sevan 	rge_write_mac_ocp(sc, 0xc142, 0xffff);
 1.1     sevan
 1.1     sevan 	val = rge_read_mac_ocp(sc, 0xd3e2) & ~0x0fff;
 1.1     sevan 	rge_write_mac_ocp(sc, 0xd3e2, val | 0x03a9);
 1.1     sevan
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xd3e4, 0x00ff);
 1.1     sevan 	RGE_MAC_SETBIT(sc, 0xe860, 0x0080);
 1.1     sevan 	RGE_MAC_SETBIT(sc, 0xeb58, 0x0001);
 1.1     sevan
 1.1     sevan 	val = rge_read_mac_ocp(sc, 0xe614) & ~0x0700;
1.17  jakllsch 	if (sc->rge_type == MAC_CFG2 || sc->rge_type == MAC_CFG3)
1.17  jakllsch 		rge_write_mac_ocp(sc, 0xe614, val | 0x0400);
1.17  jakllsch 	else
1.17  jakllsch 		rge_write_mac_ocp(sc, 0xe614, val | 0x0200);
 1.1     sevan
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xe63e, 0x0c00);
 1.1     sevan
1.17  jakllsch 	if (sc->rge_type == MAC_CFG2 || sc->rge_type == MAC_CFG3) {
1.17  jakllsch 		val = rge_read_mac_ocp(sc, 0xe63e) & ~0x0030;
1.17  jakllsch 		rge_write_mac_ocp(sc, 0xe63e, val | 0x0020);
1.17  jakllsch 	} else
1.17  jakllsch 		RGE_MAC_CLRBIT(sc, 0xe63e, 0x0030);
 1.1     sevan
 1.1     sevan 	RGE_MAC_SETBIT(sc, 0xc0b4, 0x000c);
 1.1     sevan
1.17  jakllsch 	val = rge_read_mac_ocp(sc, 0xeb6a) & ~0x00ff;
 1.1     sevan 	rge_write_mac_ocp(sc, 0xeb6a, val | 0x0033);
 1.1     sevan
 1.1     sevan 	val = rge_read_mac_ocp(sc, 0xeb50) & ~0x03e0;
 1.1     sevan 	rge_write_mac_ocp(sc, 0xeb50, val | 0x0040);
 1.1     sevan
 1.1     sevan 	val = rge_read_mac_ocp(sc, 0xe056) & ~0x00f0;
 1.1     sevan 	rge_write_mac_ocp(sc, 0xe056, val | 0x0030);
 1.1     sevan
 1.1     sevan 	RGE_WRITE_1(sc, RGE_TDFNR, 0x10);
 1.1     sevan
1.17  jakllsch 	RGE_SETBIT_1(sc, RGE_DLLPR, RGE_DLLPR_TX_10M_PS_EN);
1.17  jakllsch
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xe040, 0x1000);
 1.1     sevan
1.17  jakllsch 	val = rge_read_mac_ocp(sc, 0xea1c) & ~0x0003;
1.17  jakllsch 	rge_write_mac_ocp(sc, 0xea1c, val | 0x0001);
1.17  jakllsch
 1.1     sevan 	val = rge_read_mac_ocp(sc, 0xe0c0) & ~0x4f0f;
 1.1     sevan 	rge_write_mac_ocp(sc, 0xe0c0, val | 0x4403);
 1.1     sevan
 1.1     sevan 	RGE_MAC_SETBIT(sc, 0xe052, 0x0068);
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xe052, 0x0080);
 1.1     sevan
 1.1     sevan 	val = rge_read_mac_ocp(sc, 0xc0ac) & ~0x0080;
 1.1     sevan 	rge_write_mac_ocp(sc, 0xc0ac, val | 0x1f00);
 1.1     sevan
 1.1     sevan 	val = rge_read_mac_ocp(sc, 0xd430) & ~0x0fff;
 1.1     sevan 	rge_write_mac_ocp(sc, 0xd430, val | 0x047f);
 1.1     sevan
1.17  jakllsch 	val = rge_read_mac_ocp(sc, 0xe84c) & ~0x0040;
1.17  jakllsch 	if (sc->rge_type == MAC_CFG2 || sc->rge_type == MAC_CFG3)
1.17  jakllsch 		rge_write_mac_ocp(sc, 0xe84c, 0x00c0);
1.17  jakllsch 	else
1.17  jakllsch 		rge_write_mac_ocp(sc, 0xe84c, 0x0080);
1.17  jakllsch
1.17  jakllsch 	RGE_SETBIT_1(sc, RGE_DLLPR, RGE_DLLPR_PFM_EN);
1.17  jakllsch
1.17  jakllsch 	if (sc->rge_type == MAC_CFG2 || sc->rge_type == MAC_CFG3)
1.17  jakllsch 		RGE_SETBIT_1(sc, RGE_MCUCMD, 0x01);
 1.1     sevan
 1.1     sevan 	/* Disable EEE plus. */
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xe080, 0x0002);
 1.1     sevan
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xea1c, 0x0004);
 1.1     sevan
 1.1     sevan 	RGE_MAC_SETBIT(sc, 0xeb54, 0x0001);
 1.1     sevan 	DELAY(1);
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xeb54, 0x0001);
 1.1     sevan
 1.1     sevan 	RGE_CLRBIT_4(sc, 0x1880, 0x0030);
 1.1     sevan
 1.1     sevan 	rge_write_mac_ocp(sc, 0xe098, 0xc302);
 1.1     sevan
1.17  jakllsch 	if ((sc->sc_ec.ec_capenable & ETHERCAP_VLAN_HWTAGGING) != 0)
 1.1     sevan 		RGE_SETBIT_4(sc, RGE_RXCFG, RGE_RXCFG_VLANSTRIP);
1.17  jakllsch 	else
1.17  jakllsch 		RGE_CLRBIT_4(sc, RGE_RXCFG, RGE_RXCFG_VLANSTRIP);
 1.1     sevan
 1.1     sevan 	RGE_SETBIT_2(sc, RGE_CPLUSCMD, RGE_CPLUSCMD_RXCSUM);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < 10; i++) {
 1.1     sevan 		if (!(rge_read_mac_ocp(sc, 0xe00e) & 0x2000))
 1.1     sevan 			break;
 1.1     sevan 		DELAY(1000);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Disable RXDV gate. */
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_PPSW, 0x08);
 1.1     sevan 	DELAY(2000);
 1.1     sevan
 1.1     sevan 	rge_ifmedia_upd(ifp);
 1.1     sevan
 1.1     sevan 	/* Enable transmit and receive. */
 1.1     sevan 	RGE_WRITE_1(sc, RGE_CMD, RGE_CMD_TXENB | RGE_CMD_RXENB);
 1.1     sevan
 1.1     sevan 	/* Program promiscuous mode and multicast filters. */
 1.1     sevan 	rge_iff(sc);
 1.1     sevan
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_CFG2, RGE_CFG2_CLKREQ_EN);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_CFG5, RGE_CFG5_PME_STS);
 1.1     sevan
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_EECMD, RGE_EECMD_WRITECFG);
 1.1     sevan
 1.1     sevan 	/* Enable interrupts. */
 1.1     sevan 	rge_setup_intr(sc, RGE_IMTYPE_SIM);
 1.1     sevan
 1.1     sevan 	ifp->if_flags |= IFF_RUNNING;
 1.3     sevan 	CLR(ifp->if_flags, IFF_OACTIVE);
 1.1     sevan
 1.3     sevan 	callout_schedule(&sc->sc_timeout, 1);
 1.1     sevan
 1.1     sevan 	return (0);
 1.1     sevan }
 1.1     sevan
 1.1     sevan /*
 1.1     sevan  * Stop the adapter and free any mbufs allocated to the RX and TX lists.
 1.1     sevan  */
 1.1     sevan void
1.17  jakllsch rge_stop(struct ifnet *ifp, int disable)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = ifp->if_softc;
 1.1     sevan
1.27  riastrad 	callout_halt(&sc->sc_timeout, NULL);
 1.1     sevan
 1.1     sevan 	ifp->if_timer = 0;
 1.1     sevan 	ifp->if_flags &= ~IFF_RUNNING;
 1.1     sevan 	sc->rge_timerintr = 0;
 1.1     sevan
 1.1     sevan 	RGE_CLRBIT_4(sc, RGE_RXCFG, RGE_RXCFG_ALLPHYS | RGE_RXCFG_INDIV |
 1.1     sevan 	    RGE_RXCFG_MULTI | RGE_RXCFG_BROAD | RGE_RXCFG_RUNT |
 1.1     sevan 	    RGE_RXCFG_ERRPKT);
 1.1     sevan
 1.1     sevan 	RGE_WRITE_4(sc, RGE_IMR, 0);
1.17  jakllsch
1.17  jakllsch 	/* Clear timer interrupts. */
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_TIMERINT0, 0);
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_TIMERINT1, 0);
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_TIMERINT2, 0);
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_TIMERINT3, 0);
 1.1     sevan
 1.1     sevan 	rge_reset(sc);
 1.1     sevan
1.17  jakllsch //	intr_barrier(sc->sc_ih);
1.17  jakllsch //	ifq_barrier(&ifp->if_snd);
 1.2     sevan /*	ifq_clr_oactive(&ifp->if_snd); Sevan - OpenBSD queue API */
 1.1     sevan
 1.1     sevan 	if (sc->rge_head != NULL) {
 1.1     sevan 		m_freem(sc->rge_head);
 1.1     sevan 		sc->rge_head = sc->rge_tail = NULL;
 1.1     sevan 	}
 1.1     sevan
1.26       mrg 	rge_tx_list_fini(sc);
1.26       mrg 	rge_rx_list_fini(sc);
 1.1     sevan }
 1.1     sevan
 1.1     sevan /*
 1.1     sevan  * Set media options.
 1.1     sevan  */
 1.1     sevan int
 1.1     sevan rge_ifmedia_upd(struct ifnet *ifp)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = ifp->if_softc;
 1.1     sevan 	struct ifmedia *ifm = &sc->sc_media;
 1.1     sevan 	int anar, gig, val;
 1.1     sevan
 1.1     sevan 	if (IFM_TYPE(ifm->ifm_media) != IFM_ETHER)
 1.1     sevan 		return (EINVAL);
 1.1     sevan
 1.1     sevan 	/* Disable Gigabit Lite. */
 1.1     sevan 	RGE_PHY_CLRBIT(sc, 0xa428, 0x0200);
 1.1     sevan 	RGE_PHY_CLRBIT(sc, 0xa5ea, 0x0001);
 1.1     sevan
 1.1     sevan 	val = rge_read_phy_ocp(sc, 0xa5d4);
 1.1     sevan 	val &= ~RGE_ADV_2500TFDX;
 1.1     sevan
 1.1     sevan 	anar = gig = 0;
 1.1     sevan 	switch (IFM_SUBTYPE(ifm->ifm_media)) {
 1.1     sevan 	case IFM_AUTO:
1.17  jakllsch 		anar = ANAR_TX_FD | ANAR_TX | ANAR_10_FD | ANAR_10;
1.17  jakllsch 		gig = GTCR_ADV_1000TFDX | GTCR_ADV_1000THDX;
 1.1     sevan 		val |= RGE_ADV_2500TFDX;
 1.1     sevan 		break;
 1.1     sevan 	case IFM_2500_T:
1.17  jakllsch 		anar = ANAR_TX_FD | ANAR_TX | ANAR_10_FD | ANAR_10;
1.17  jakllsch 		gig = GTCR_ADV_1000TFDX | GTCR_ADV_1000THDX;
 1.1     sevan 		val |= RGE_ADV_2500TFDX;
 1.1     sevan 		ifp->if_baudrate = IF_Mbps(2500);
 1.1     sevan 		break;
 1.1     sevan 	case IFM_1000_T:
1.17  jakllsch 		anar = ANAR_TX_FD | ANAR_TX | ANAR_10_FD | ANAR_10;
1.17  jakllsch 		gig = GTCR_ADV_1000TFDX | GTCR_ADV_1000THDX;
 1.1     sevan 		ifp->if_baudrate = IF_Gbps(1);
 1.1     sevan 		break;
 1.1     sevan 	case IFM_100_TX:
1.17  jakllsch 		gig = rge_read_phy(sc, 0, MII_100T2CR) &
1.17  jakllsch 		    ~(GTCR_ADV_1000TFDX | GTCR_ADV_1000THDX);
1.17  jakllsch 		anar = ((ifm->ifm_media & IFM_GMASK) == IFM_FDX) ?
1.17  jakllsch 		    ANAR_TX | ANAR_TX_FD | ANAR_10_FD | ANAR_10 :
1.17  jakllsch 		    ANAR_TX | ANAR_10_FD | ANAR_10;
 1.1     sevan 		ifp->if_baudrate = IF_Mbps(100);
 1.1     sevan 		break;
 1.1     sevan 	case IFM_10_T:
1.17  jakllsch 		gig = rge_read_phy(sc, 0, MII_100T2CR) &
1.17  jakllsch 		    ~(GTCR_ADV_1000TFDX | GTCR_ADV_1000THDX);
1.17  jakllsch 		anar = ((ifm->ifm_media & IFM_GMASK) == IFM_FDX) ?
1.17  jakllsch 		    ANAR_10_FD | ANAR_10 : ANAR_10;
 1.1     sevan 		ifp->if_baudrate = IF_Mbps(10);
 1.1     sevan 		break;
 1.1     sevan 	default:
1.16  jakllsch 		device_printf(sc->sc_dev,
1.13     sevan 		    "unsupported media type\n");
 1.1     sevan 		return (EINVAL);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	rge_write_phy(sc, 0, MII_ANAR, anar | ANAR_PAUSE_ASYM | ANAR_FC);
 1.1     sevan 	rge_write_phy(sc, 0, MII_100T2CR, gig);
 1.1     sevan 	rge_write_phy_ocp(sc, 0xa5d4, val);
1.17  jakllsch 	rge_write_phy(sc, 0, MII_BMCR, BMCR_RESET | BMCR_AUTOEN |
1.17  jakllsch 	    BMCR_STARTNEG);
 1.1     sevan
 1.1     sevan 	return (0);
 1.1     sevan }
 1.1     sevan
 1.1     sevan /*
 1.1     sevan  * Report current media status.
 1.1     sevan  */
 1.1     sevan void
 1.1     sevan rge_ifmedia_sts(struct ifnet *ifp, struct ifmediareq *ifmr)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = ifp->if_softc;
 1.1     sevan 	uint16_t status = 0;
 1.1     sevan
 1.1     sevan 	ifmr->ifm_status = IFM_AVALID;
 1.1     sevan 	ifmr->ifm_active = IFM_ETHER;
 1.1     sevan
 1.1     sevan 	if (rge_get_link_status(sc)) {
 1.1     sevan 		ifmr->ifm_status |= IFM_ACTIVE;
 1.1     sevan
 1.1     sevan 		status = RGE_READ_2(sc, RGE_PHYSTAT);
 1.1     sevan 		if ((status & RGE_PHYSTAT_FDX) ||
 1.1     sevan 		    (status & RGE_PHYSTAT_2500MBPS))
 1.1     sevan 			ifmr->ifm_active |= IFM_FDX;
 1.1     sevan 		else
 1.1     sevan 			ifmr->ifm_active |= IFM_HDX;
 1.1     sevan
 1.1     sevan 		if (status & RGE_PHYSTAT_10MBPS)
 1.1     sevan 			ifmr->ifm_active |= IFM_10_T;
 1.1     sevan 		else if (status & RGE_PHYSTAT_100MBPS)
 1.1     sevan 			ifmr->ifm_active |= IFM_100_TX;
 1.1     sevan 		else if (status & RGE_PHYSTAT_1000MBPS)
 1.1     sevan 			ifmr->ifm_active |= IFM_1000_T;
 1.1     sevan 		else if (status & RGE_PHYSTAT_2500MBPS)
 1.1     sevan 			ifmr->ifm_active |= IFM_2500_T;
 1.1     sevan 	}
 1.1     sevan }
 1.1     sevan
 1.5     skrll /*
 1.1     sevan  * Allocate memory for RX/TX rings.
1.28       mrg  *
1.28       mrg  * XXX There is no tear-down for this if it any part fails, so everything
1.28       mrg  * remains allocated.
 1.1     sevan  */
 1.1     sevan int
 1.1     sevan rge_allocmem(struct rge_softc *sc)
 1.1     sevan {
 1.1     sevan 	int error, i;
 1.1     sevan
 1.1     sevan 	/* Allocate DMA'able memory for the TX ring. */
 1.1     sevan 	error = bus_dmamap_create(sc->sc_dmat, RGE_TX_LIST_SZ, 1,
 1.1     sevan 	    RGE_TX_LIST_SZ, 0, BUS_DMA_NOWAIT, &sc->rge_ldata.rge_tx_list_map);
 1.1     sevan 	if (error) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, "can't create TX list map\n");
 1.1     sevan 		return (error);
 1.1     sevan 	}
 1.1     sevan 	error = bus_dmamem_alloc(sc->sc_dmat, RGE_TX_LIST_SZ, RGE_ALIGN, 0,
 1.1     sevan 	    &sc->rge_ldata.rge_tx_listseg, 1, &sc->rge_ldata.rge_tx_listnseg,
1.17  jakllsch 	    BUS_DMA_NOWAIT);
 1.1     sevan 	if (error) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, "can't alloc TX list\n");
 1.1     sevan 		return (error);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Load the map for the TX ring. */
 1.1     sevan 	error = bus_dmamem_map(sc->sc_dmat, &sc->rge_ldata.rge_tx_listseg,
 1.1     sevan 	    sc->rge_ldata.rge_tx_listnseg, RGE_TX_LIST_SZ,
 1.8     sevan 	    (void **) &sc->rge_ldata.rge_tx_list,
1.17  jakllsch 	    BUS_DMA_NOWAIT | BUS_DMA_COHERENT);
 1.1     sevan 	if (error) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, "can't map TX dma buffers\n");
 1.1     sevan 		bus_dmamem_free(sc->sc_dmat, &sc->rge_ldata.rge_tx_listseg,
 1.1     sevan 		    sc->rge_ldata.rge_tx_listnseg);
 1.1     sevan 		return (error);
 1.1     sevan 	}
1.17  jakllsch 	memset(sc->rge_ldata.rge_tx_list, 0, RGE_TX_LIST_SZ);
 1.1     sevan 	error = bus_dmamap_load(sc->sc_dmat, sc->rge_ldata.rge_tx_list_map,
 1.1     sevan 	    sc->rge_ldata.rge_tx_list, RGE_TX_LIST_SZ, NULL, BUS_DMA_NOWAIT);
 1.1     sevan 	if (error) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, "can't load TX dma map\n");
 1.1     sevan 		bus_dmamap_destroy(sc->sc_dmat, sc->rge_ldata.rge_tx_list_map);
 1.1     sevan 		bus_dmamem_unmap(sc->sc_dmat,
 1.2     sevan 		    sc->rge_ldata.rge_tx_list, RGE_TX_LIST_SZ);
 1.1     sevan 		bus_dmamem_free(sc->sc_dmat, &sc->rge_ldata.rge_tx_listseg,
 1.1     sevan 		    sc->rge_ldata.rge_tx_listnseg);
 1.1     sevan 		return (error);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Create DMA maps for TX buffers. */
 1.1     sevan 	for (i = 0; i < RGE_TX_LIST_CNT; i++) {
 1.1     sevan 		error = bus_dmamap_create(sc->sc_dmat, RGE_JUMBO_FRAMELEN,
 1.1     sevan 		    RGE_TX_NSEGS, RGE_JUMBO_FRAMELEN, 0, 0,
 1.1     sevan 		    &sc->rge_ldata.rge_txq[i].txq_dmamap);
 1.1     sevan 		if (error) {
1.13     sevan 			aprint_error_dev(sc->sc_dev, "can't create DMA map for TX\n");
 1.1     sevan 			return (error);
 1.1     sevan 		}
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Allocate DMA'able memory for the RX ring. */
 1.1     sevan 	error = bus_dmamap_create(sc->sc_dmat, RGE_RX_LIST_SZ, 1,
 1.1     sevan 	    RGE_RX_LIST_SZ, 0, 0, &sc->rge_ldata.rge_rx_list_map);
 1.1     sevan 	if (error) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, "can't create RX list map\n");
 1.1     sevan 		return (error);
 1.1     sevan 	}
 1.1     sevan 	error = bus_dmamem_alloc(sc->sc_dmat, RGE_RX_LIST_SZ, RGE_ALIGN, 0,
 1.1     sevan 	    &sc->rge_ldata.rge_rx_listseg, 1, &sc->rge_ldata.rge_rx_listnseg,
1.17  jakllsch 	    BUS_DMA_NOWAIT);
 1.1     sevan 	if (error) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, "can't alloc RX list\n");
 1.1     sevan 		return (error);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Load the map for the RX ring. */
 1.1     sevan 	error = bus_dmamem_map(sc->sc_dmat, &sc->rge_ldata.rge_rx_listseg,
 1.1     sevan 	    sc->rge_ldata.rge_rx_listnseg, RGE_RX_LIST_SZ,
 1.8     sevan 	    (void **) &sc->rge_ldata.rge_rx_list,
1.17  jakllsch 	    BUS_DMA_NOWAIT | BUS_DMA_COHERENT);
 1.1     sevan 	if (error) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, "can't map RX dma buffers\n");
 1.1     sevan 		bus_dmamem_free(sc->sc_dmat, &sc->rge_ldata.rge_rx_listseg,
 1.1     sevan 		    sc->rge_ldata.rge_rx_listnseg);
 1.1     sevan 		return (error);
 1.1     sevan 	}
1.17  jakllsch 	memset(sc->rge_ldata.rge_rx_list, 0, RGE_RX_LIST_SZ);
 1.1     sevan 	error = bus_dmamap_load(sc->sc_dmat, sc->rge_ldata.rge_rx_list_map,
 1.1     sevan 	    sc->rge_ldata.rge_rx_list, RGE_RX_LIST_SZ, NULL, BUS_DMA_NOWAIT);
 1.1     sevan 	if (error) {
1.13     sevan 		aprint_error_dev(sc->sc_dev, "can't load RX dma map\n");
 1.1     sevan 		bus_dmamap_destroy(sc->sc_dmat, sc->rge_ldata.rge_rx_list_map);
 1.1     sevan 		bus_dmamem_unmap(sc->sc_dmat,
 1.2     sevan 		    sc->rge_ldata.rge_rx_list, RGE_RX_LIST_SZ);
 1.1     sevan 		bus_dmamem_free(sc->sc_dmat, &sc->rge_ldata.rge_rx_listseg,
 1.1     sevan 		    sc->rge_ldata.rge_rx_listnseg);
 1.1     sevan 		return (error);
 1.1     sevan 	}
 1.1     sevan
1.28       mrg 	/*
1.28       mrg 	 * Create DMA maps for RX buffers.  Use BUS_DMA_ALLOCNOW to avoid any
1.28       mrg 	 * potential failure in bus_dmamap_load_mbuf() in the RX path.
1.28       mrg 	 */
 1.1     sevan 	for (i = 0; i < RGE_RX_LIST_CNT; i++) {
 1.1     sevan 		error = bus_dmamap_create(sc->sc_dmat, RGE_JUMBO_FRAMELEN, 1,
1.28       mrg 		    RGE_JUMBO_FRAMELEN, 0, BUS_DMA_ALLOCNOW,
 1.1     sevan 		    &sc->rge_ldata.rge_rxq[i].rxq_dmamap);
 1.1     sevan 		if (error) {
1.13     sevan 			aprint_error_dev(sc->sc_dev, "can't create DMA map for RX\n");
 1.1     sevan 			return (error);
 1.1     sevan 		}
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	return (error);
 1.1     sevan }
 1.1     sevan
 1.1     sevan /*
1.28       mrg  * Set an RX descriptor and sync it.
1.28       mrg  */
1.28       mrg static void
1.28       mrg rge_load_rxbuf(struct rge_softc *sc, int idx)
1.28       mrg {
1.28       mrg 	struct rge_rx_desc *r = &sc->rge_ldata.rge_rx_list[idx];
1.28       mrg 	struct rge_rxq *rxq = &sc->rge_ldata.rge_rxq[idx];
1.28       mrg 	bus_dmamap_t rxmap = rxq->rxq_dmamap;
1.28       mrg 	uint32_t cmdsts;
1.28       mrg
1.28       mrg 	cmdsts = rxmap->dm_segs[0].ds_len | RGE_RDCMDSTS_OWN;
1.28       mrg 	if (idx == RGE_RX_LIST_CNT - 1)
1.28       mrg 		cmdsts |= RGE_RDCMDSTS_EOR;
1.28       mrg
1.28       mrg 	r->hi_qword0.rge_addr = htole64(rxmap->dm_segs[0].ds_addr);
1.28       mrg 	r->hi_qword1.rx_qword4.rge_extsts = 0;
1.28       mrg 	r->hi_qword1.rx_qword4.rge_cmdsts = htole32(cmdsts);
1.28       mrg
1.28       mrg 	bus_dmamap_sync(sc->sc_dmat, sc->rge_ldata.rge_rx_list_map,
1.28       mrg 	    idx * sizeof(struct rge_rx_desc), sizeof(struct rge_rx_desc),
1.28       mrg 	    BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
1.28       mrg }
1.28       mrg
1.28       mrg /*
 1.1     sevan  * Initialize the RX descriptor and attach an mbuf cluster.
 1.1     sevan  */
 1.1     sevan int
 1.1     sevan rge_newbuf(struct rge_softc *sc, int idx)
 1.1     sevan {
 1.1     sevan 	struct mbuf *m;
 1.1     sevan 	struct rge_rxq *rxq;
 1.1     sevan 	bus_dmamap_t rxmap;
1.28       mrg 	int error __diagused;
 1.1     sevan
1.17  jakllsch 	m = MCLGETL(NULL, M_DONTWAIT, RGE_JUMBO_FRAMELEN);
 1.1     sevan 	if (m == NULL)
 1.1     sevan 		return (ENOBUFS);
 1.1     sevan
 1.1     sevan 	m->m_len = m->m_pkthdr.len = RGE_JUMBO_FRAMELEN;
 1.1     sevan
 1.1     sevan 	rxq = &sc->rge_ldata.rge_rxq[idx];
 1.1     sevan 	rxmap = rxq->rxq_dmamap;
 1.1     sevan
1.28       mrg 	if (rxq->rxq_mbuf != NULL)
1.28       mrg 		bus_dmamap_unload(sc->sc_dmat, rxq->rxq_dmamap);
1.28       mrg
1.28       mrg 	/* This map was created with BUS_DMA_ALLOCNOW so should never fail. */
1.28       mrg 	error = bus_dmamap_load_mbuf(sc->sc_dmat, rxmap, m, BUS_DMA_NOWAIT);
1.28       mrg 	KASSERTMSG(error == 0, "error=%d", error);
 1.1     sevan
 1.1     sevan 	bus_dmamap_sync(sc->sc_dmat, rxmap, 0, rxmap->dm_mapsize,
 1.1     sevan 	    BUS_DMASYNC_PREREAD);
 1.1     sevan
 1.1     sevan 	/* Map the segments into RX descriptors. */
 1.1     sevan
 1.1     sevan 	rxq->rxq_mbuf = m;
1.28       mrg 	rge_load_rxbuf(sc, idx);
 1.1     sevan
1.28       mrg 	return 0;
 1.1     sevan }
 1.1     sevan
1.26       mrg static int
 1.1     sevan rge_rx_list_init(struct rge_softc *sc)
 1.1     sevan {
1.26       mrg 	unsigned i;
 1.1     sevan
 1.1     sevan 	memset(sc->rge_ldata.rge_rx_list, 0, RGE_RX_LIST_SZ);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < RGE_RX_LIST_CNT; i++) {
 1.1     sevan 		sc->rge_ldata.rge_rxq[i].rxq_mbuf = NULL;
1.26       mrg 		if (rge_newbuf(sc, i) != 0) {
1.26       mrg 			rge_rx_list_fini(sc);
 1.1     sevan 			return (ENOBUFS);
1.26       mrg 		}
 1.1     sevan 	}
 1.1     sevan
1.17  jakllsch 	sc->rge_ldata.rge_rxq_prodidx = sc->rge_ldata.rge_rxq_considx = 0;
 1.1     sevan 	sc->rge_head = sc->rge_tail = NULL;
 1.1     sevan
 1.1     sevan 	return (0);
 1.1     sevan }
 1.1     sevan
1.26       mrg static void
1.26       mrg rge_rx_list_fini(struct rge_softc *sc)
1.26       mrg {
1.26       mrg 	unsigned i;
1.26       mrg
1.26       mrg 	/* Free the RX list buffers. */
1.26       mrg 	for (i = 0; i < RGE_RX_LIST_CNT; i++) {
1.26       mrg 		if (sc->rge_ldata.rge_rxq[i].rxq_mbuf != NULL) {
1.26       mrg 			bus_dmamap_unload(sc->sc_dmat,
1.26       mrg 			    sc->rge_ldata.rge_rxq[i].rxq_dmamap);
1.26       mrg 			m_freem(sc->rge_ldata.rge_rxq[i].rxq_mbuf);
1.26       mrg 			sc->rge_ldata.rge_rxq[i].rxq_mbuf = NULL;
1.26       mrg 		}
1.26       mrg 	}
1.26       mrg }
1.26       mrg
1.26       mrg static void
 1.1     sevan rge_tx_list_init(struct rge_softc *sc)
 1.1     sevan {
1.26       mrg 	unsigned i;
 1.1     sevan
 1.1     sevan 	memset(sc->rge_ldata.rge_tx_list, 0, RGE_TX_LIST_SZ);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < RGE_TX_LIST_CNT; i++)
 1.1     sevan 		sc->rge_ldata.rge_txq[i].txq_mbuf = NULL;
 1.1     sevan
 1.1     sevan 	bus_dmamap_sync(sc->sc_dmat, sc->rge_ldata.rge_tx_list_map, 0,
 1.1     sevan 	    sc->rge_ldata.rge_tx_list_map->dm_mapsize,
 1.1     sevan 	    BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
 1.1     sevan
 1.1     sevan 	sc->rge_ldata.rge_txq_prodidx = sc->rge_ldata.rge_txq_considx = 0;
 1.1     sevan }
 1.1     sevan
1.26       mrg static void
1.26       mrg rge_tx_list_fini(struct rge_softc *sc)
1.26       mrg {
1.26       mrg 	unsigned i;
1.26       mrg
1.26       mrg 	/* Free the TX list buffers. */
1.26       mrg 	for (i = 0; i < RGE_TX_LIST_CNT; i++) {
1.26       mrg 		if (sc->rge_ldata.rge_txq[i].txq_mbuf != NULL) {
1.26       mrg 			bus_dmamap_unload(sc->sc_dmat,
1.26       mrg 			    sc->rge_ldata.rge_txq[i].txq_dmamap);
1.26       mrg 			m_freem(sc->rge_ldata.rge_txq[i].txq_mbuf);
1.26       mrg 			sc->rge_ldata.rge_txq[i].txq_mbuf = NULL;
1.26       mrg 		}
1.26       mrg 	}
1.26       mrg }
1.26       mrg
 1.1     sevan int
 1.1     sevan rge_rxeof(struct rge_softc *sc)
 1.1     sevan {
 1.1     sevan 	struct mbuf *m;
 1.2     sevan 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1     sevan 	struct rge_rx_desc *cur_rx;
 1.1     sevan 	struct rge_rxq *rxq;
 1.1     sevan 	uint32_t rxstat, extsts;
 1.1     sevan 	int i, total_len, rx = 0;
 1.1     sevan
1.17  jakllsch 	for (i = sc->rge_ldata.rge_rxq_considx; ; i = RGE_NEXT_RX_DESC(i)) {
 1.1     sevan 		/* Invalidate the descriptor memory. */
 1.1     sevan 		bus_dmamap_sync(sc->sc_dmat, sc->rge_ldata.rge_rx_list_map,
 1.1     sevan 		    i * sizeof(struct rge_rx_desc), sizeof(struct rge_rx_desc),
 1.1     sevan 		    BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
 1.1     sevan
 1.1     sevan 		cur_rx = &sc->rge_ldata.rge_rx_list[i];
 1.1     sevan
 1.1     sevan 		if (RGE_OWN(cur_rx))
 1.1     sevan 			break;
 1.1     sevan
1.25    nonaka 		rxstat = letoh32(cur_rx->hi_qword1.rx_qword4.rge_cmdsts);
1.25    nonaka 		extsts = letoh32(cur_rx->hi_qword1.rx_qword4.rge_extsts);
 1.5     skrll
 1.1     sevan 		total_len = RGE_RXBYTES(cur_rx);
 1.1     sevan 		rxq = &sc->rge_ldata.rge_rxq[i];
 1.1     sevan 		m = rxq->rxq_mbuf;
 1.1     sevan 		rx = 1;
 1.1     sevan
1.28       mrg 		/* Invalidate the RX mbuf. */
 1.1     sevan 		bus_dmamap_sync(sc->sc_dmat, rxq->rxq_dmamap, 0,
 1.1     sevan 		    rxq->rxq_dmamap->dm_mapsize, BUS_DMASYNC_POSTREAD);
 1.1     sevan
 1.1     sevan 		if ((rxstat & (RGE_RDCMDSTS_SOF | RGE_RDCMDSTS_EOF)) !=
 1.1     sevan 		    (RGE_RDCMDSTS_SOF | RGE_RDCMDSTS_EOF)) {
1.28       mrg 			if_statinc(ifp, if_ierrors);
1.28       mrg 			rge_load_rxbuf(sc, i);
 1.1     sevan 			continue;
 1.1     sevan 		}
 1.1     sevan
 1.1     sevan 		if (rxstat & RGE_RDCMDSTS_RXERRSUM) {
 1.4     skrll 			if_statinc(ifp, if_ierrors);
 1.1     sevan 			/*
 1.1     sevan 			 * If this is part of a multi-fragment packet,
 1.1     sevan 			 * discard all the pieces.
 1.1     sevan 			 */
1.28       mrg 			if (sc->rge_head != NULL) {
 1.1     sevan 				m_freem(sc->rge_head);
 1.1     sevan 				sc->rge_head = sc->rge_tail = NULL;
 1.1     sevan 			}
1.28       mrg 			rge_load_rxbuf(sc, i);
 1.1     sevan 			continue;
 1.1     sevan 		}
 1.1     sevan
 1.1     sevan 		/*
 1.1     sevan 		 * If allocating a replacement mbuf fails,
 1.1     sevan 		 * reload the current one.
 1.1     sevan 		 */
1.26       mrg 		if (rge_newbuf(sc, i) != 0) {
1.28       mrg 			if_statinc(ifp, if_iqdrops);
 1.1     sevan 			if (sc->rge_head != NULL) {
 1.1     sevan 				m_freem(sc->rge_head);
 1.1     sevan 				sc->rge_head = sc->rge_tail = NULL;
 1.1     sevan 			}
1.28       mrg 			rge_load_rxbuf(sc, i);
 1.1     sevan 			continue;
 1.1     sevan 		}
 1.1     sevan
1.17  jakllsch 		m_set_rcvif(m, ifp);
 1.1     sevan 		if (sc->rge_head != NULL) {
 1.1     sevan 			m->m_len = total_len;
 1.1     sevan 			/*
 1.1     sevan 			 * Special case: if there's 4 bytes or less
 1.1     sevan 			 * in this buffer, the mbuf can be discarded:
 1.1     sevan 			 * the last 4 bytes is the CRC, which we don't
 1.1     sevan 			 * care about anyway.
 1.1     sevan 			 */
 1.1     sevan 			if (m->m_len <= ETHER_CRC_LEN) {
 1.1     sevan 				sc->rge_tail->m_len -=
 1.1     sevan 				    (ETHER_CRC_LEN - m->m_len);
 1.1     sevan 				m_freem(m);
 1.1     sevan 			} else {
 1.1     sevan 				m->m_len -= ETHER_CRC_LEN;
 1.1     sevan 				m->m_flags &= ~M_PKTHDR;
 1.1     sevan 				sc->rge_tail->m_next = m;
 1.1     sevan 			}
 1.1     sevan 			m = sc->rge_head;
 1.1     sevan 			sc->rge_head = sc->rge_tail = NULL;
 1.1     sevan 			m->m_pkthdr.len = total_len - ETHER_CRC_LEN;
 1.1     sevan 		} else
1.17  jakllsch 	#if 0
 1.1     sevan 			m->m_pkthdr.len = m->m_len =
 1.1     sevan 			    (total_len - ETHER_CRC_LEN);
1.17  jakllsch 	#else
1.17  jakllsch 		{
1.17  jakllsch 			m->m_pkthdr.len = m->m_len = total_len;
1.17  jakllsch 			m->m_flags |= M_HASFCS;
1.17  jakllsch 		}
1.17  jakllsch 	#endif
 1.1     sevan
1.17  jakllsch #if notyet
 1.1     sevan 		/* Check IP header checksum. */
1.25    nonaka 		if (!(extsts & RGE_RDEXTSTS_IPCSUMERR) &&
 1.1     sevan 		    (extsts & RGE_RDEXTSTS_IPV4))
 1.1     sevan 			m->m_pkthdr.csum_flags |= M_IPV4_CSUM_IN_OK;
 1.1     sevan
 1.1     sevan 		/* Check TCP/UDP checksum. */
 1.1     sevan 		if ((extsts & (RGE_RDEXTSTS_IPV4 | RGE_RDEXTSTS_IPV6)) &&
1.25    nonaka 		    (((extsts & RGE_RDEXTSTS_TCPPKT) &&
1.25    nonaka 		    !(extsts & RGE_RDEXTSTS_TCPCSUMERR)) ||
1.25    nonaka 		    ((extsts & RGE_RDEXTSTS_UDPPKT) &&
1.25    nonaka 		    !(extsts & RGE_RDEXTSTS_UDPCSUMERR))))
 1.1     sevan 			m->m_pkthdr.csum_flags |= M_TCP_CSUM_IN_OK |
 1.1     sevan 			    M_UDP_CSUM_IN_OK;
1.17  jakllsch #endif
 1.1     sevan
 1.1     sevan 		if (extsts & RGE_RDEXTSTS_VTAG) {
1.17  jakllsch 			vlan_set_tag(m,
1.17  jakllsch 			    bswap16(extsts & RGE_RDEXTSTS_VLAN_MASK));
 1.1     sevan 		}
 1.1     sevan
1.17  jakllsch 		if_percpuq_enqueue(ifp->if_percpuq, m);
 1.1     sevan 	}
 1.1     sevan
1.17  jakllsch 	sc->rge_ldata.rge_rxq_considx = i;
 1.1     sevan
 1.1     sevan 	return (rx);
 1.1     sevan }
 1.1     sevan
 1.1     sevan int
 1.1     sevan rge_txeof(struct rge_softc *sc)
 1.1     sevan {
 1.2     sevan 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1     sevan 	struct rge_txq *txq;
 1.1     sevan 	uint32_t txstat;
 1.1     sevan 	int cons, idx, prod;
 1.1     sevan 	int free = 0;
 1.1     sevan
 1.1     sevan 	prod = sc->rge_ldata.rge_txq_prodidx;
 1.1     sevan 	cons = sc->rge_ldata.rge_txq_considx;
 1.1     sevan
 1.1     sevan 	while (prod != cons) {
 1.1     sevan 		txq = &sc->rge_ldata.rge_txq[cons];
 1.1     sevan 		idx = txq->txq_descidx;
 1.1     sevan
 1.1     sevan 		bus_dmamap_sync(sc->sc_dmat, sc->rge_ldata.rge_tx_list_map,
 1.1     sevan 		    idx * sizeof(struct rge_tx_desc),
 1.1     sevan 		    sizeof(struct rge_tx_desc),
 1.1     sevan 		    BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE);
 1.1     sevan
 1.1     sevan 		txstat = letoh32(sc->rge_ldata.rge_tx_list[idx].rge_cmdsts);
 1.1     sevan
 1.1     sevan 		if (txstat & RGE_TDCMDSTS_OWN) {
 1.1     sevan 			free = 2;
 1.1     sevan 			break;
 1.1     sevan 		}
 1.1     sevan
 1.5     skrll 		bus_dmamap_sync(sc->sc_dmat, txq->txq_dmamap, 0,
 1.1     sevan 		    txq->txq_dmamap->dm_mapsize, BUS_DMASYNC_POSTWRITE);
 1.1     sevan 		bus_dmamap_unload(sc->sc_dmat, txq->txq_dmamap);
 1.1     sevan 		m_freem(txq->txq_mbuf);
 1.1     sevan 		txq->txq_mbuf = NULL;
 1.1     sevan
1.29   mlelstv 		net_stat_ref_t nsr = IF_STAT_GETREF(ifp);
 1.1     sevan 		if (txstat & (RGE_TDCMDSTS_EXCESSCOLL | RGE_TDCMDSTS_COLL))
1.29   mlelstv 			if_statinc_ref(nsr, if_collisions);
 1.1     sevan 		if (txstat & RGE_TDCMDSTS_TXERR)
1.29   mlelstv 			if_statinc_ref(nsr, if_oerrors);
1.29   mlelstv 		else
1.29   mlelstv 			if_statinc_ref(nsr, if_opackets);
1.29   mlelstv 		IF_STAT_PUTREF(ifp);
 1.1     sevan
 1.1     sevan 		bus_dmamap_sync(sc->sc_dmat, sc->rge_ldata.rge_tx_list_map,
 1.1     sevan 		    idx * sizeof(struct rge_tx_desc),
 1.1     sevan 		    sizeof(struct rge_tx_desc),
 1.1     sevan 		    BUS_DMASYNC_PREREAD | BUS_DMASYNC_PREWRITE);
 1.1     sevan
 1.1     sevan 		cons = RGE_NEXT_TX_DESC(idx);
 1.1     sevan 		free = 1;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	if (free == 0)
 1.1     sevan 		return (0);
 1.1     sevan
 1.1     sevan 	sc->rge_ldata.rge_txq_considx = cons;
 1.1     sevan
1.17  jakllsch 	if (free == 2)
1.30     skrll 		rge_txstart(sc);
1.29   mlelstv
1.29   mlelstv 	CLR(ifp->if_flags, IFF_OACTIVE);
1.29   mlelstv 	ifp->if_timer = 0;
1.29   mlelstv 	if_schedule_deferred_start(ifp);
 1.1     sevan
 1.1     sevan 	return (1);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_reset(struct rge_softc *sc)
 1.1     sevan {
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	/* Enable RXDV gate. */
 1.1     sevan 	RGE_SETBIT_1(sc, RGE_PPSW, 0x08);
 1.1     sevan 	DELAY(2000);
 1.1     sevan
1.17  jakllsch 	for (i = 0; i < 3000; i++) {
1.17  jakllsch 		DELAY(50);
 1.1     sevan 		if ((RGE_READ_1(sc, RGE_MCUCMD) & (RGE_MCUCMD_RXFIFO_EMPTY |
 1.1     sevan 		    RGE_MCUCMD_TXFIFO_EMPTY)) == (RGE_MCUCMD_RXFIFO_EMPTY |
 1.1     sevan 		    RGE_MCUCMD_TXFIFO_EMPTY))
 1.1     sevan 			break;
 1.1     sevan 	}
1.17  jakllsch 	if (sc->rge_type == MAC_CFG4 || sc->rge_type == MAC_CFG5) {
1.17  jakllsch 		for (i = 0; i < 3000; i++) {
1.17  jakllsch 			DELAY(50);
1.17  jakllsch 			if ((RGE_READ_2(sc, RGE_IM) & 0x0103) == 0x0103)
1.17  jakllsch 				break;
1.17  jakllsch 		}
1.17  jakllsch 	}
1.17  jakllsch
1.17  jakllsch 	DELAY(2000);
 1.1     sevan
 1.1     sevan 	/* Soft reset. */
 1.1     sevan 	RGE_WRITE_1(sc, RGE_CMD, RGE_CMD_RESET);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < RGE_TIMEOUT; i++) {
 1.1     sevan 		DELAY(100);
 1.1     sevan 		if (!(RGE_READ_1(sc, RGE_CMD) & RGE_CMD_RESET))
 1.1     sevan 			break;
 1.1     sevan 	}
 1.1     sevan 	if (i == RGE_TIMEOUT)
1.16  jakllsch 		device_printf(sc->sc_dev, "reset never completed!\n");
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_iff(struct rge_softc *sc)
 1.1     sevan {
 1.2     sevan 	struct ifnet *ifp = &sc->sc_ec.ec_if;
1.17  jakllsch 	struct ethercom *ec = &sc->sc_ec;
 1.1     sevan 	struct ether_multi *enm;
 1.1     sevan 	struct ether_multistep step;
 1.1     sevan 	uint32_t hashes[2];
 1.1     sevan 	uint32_t rxfilt;
 1.1     sevan 	int h = 0;
 1.1     sevan
 1.1     sevan 	rxfilt = RGE_READ_4(sc, RGE_RXCFG);
 1.1     sevan 	rxfilt &= ~(RGE_RXCFG_ALLPHYS | RGE_RXCFG_MULTI);
 1.1     sevan 	ifp->if_flags &= ~IFF_ALLMULTI;
 1.1     sevan
 1.1     sevan 	/*
 1.1     sevan 	 * Always accept frames destined to our station address.
 1.1     sevan 	 * Always accept broadcast frames.
 1.1     sevan 	 */
 1.1     sevan 	rxfilt |= RGE_RXCFG_INDIV | RGE_RXCFG_BROAD;
 1.1     sevan
1.17  jakllsch 	if (ifp->if_flags & IFF_PROMISC) {
1.17  jakllsch  allmulti:
 1.1     sevan 		ifp->if_flags |= IFF_ALLMULTI;
 1.1     sevan 		rxfilt |= RGE_RXCFG_MULTI;
 1.1     sevan 		if (ifp->if_flags & IFF_PROMISC)
 1.1     sevan 			rxfilt |= RGE_RXCFG_ALLPHYS;
 1.1     sevan 		hashes[0] = hashes[1] = 0xffffffff;
 1.1     sevan 	} else {
 1.1     sevan 		rxfilt |= RGE_RXCFG_MULTI;
 1.1     sevan 		/* Program new filter. */
 1.1     sevan 		memset(hashes, 0, sizeof(hashes));
 1.1     sevan
1.17  jakllsch 		ETHER_LOCK(ec);
1.17  jakllsch 		ETHER_FIRST_MULTI(step, ec, enm);
 1.1     sevan 		while (enm != NULL) {
1.17  jakllsch 			if (memcmp(enm->enm_addrlo, enm->enm_addrhi,
1.17  jakllsch 			    ETHER_ADDR_LEN) != 0) {
1.17  jakllsch 			    	ETHER_UNLOCK(ec);
1.17  jakllsch 				goto allmulti;
1.17  jakllsch 			}
 1.1     sevan 			h = ether_crc32_be(enm->enm_addrlo,
 1.1     sevan 			    ETHER_ADDR_LEN) >> 26;
 1.1     sevan
 1.1     sevan 			if (h < 32)
1.21   msaitoh 				hashes[0] |= (1U << h);
 1.1     sevan 			else
1.21   msaitoh 				hashes[1] |= (1U << (h - 32));
 1.1     sevan
 1.1     sevan 			ETHER_NEXT_MULTI(step, enm);
 1.1     sevan 		}
1.17  jakllsch 		ETHER_UNLOCK(ec);
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	RGE_WRITE_4(sc, RGE_RXCFG, rxfilt);
 1.2     sevan 	RGE_WRITE_4(sc, RGE_MAR0, bswap32(hashes[1]));
 1.2     sevan 	RGE_WRITE_4(sc, RGE_MAR4, bswap32(hashes[0]));
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_set_phy_power(struct rge_softc *sc, int on)
 1.1     sevan {
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	if (on) {
 1.1     sevan 		RGE_SETBIT_1(sc, RGE_PMCH, 0xc0);
 1.1     sevan
 1.1     sevan 		rge_write_phy(sc, 0, MII_BMCR, BMCR_AUTOEN);
 1.1     sevan
 1.1     sevan 		for (i = 0; i < RGE_TIMEOUT; i++) {
1.10     sevan 			if ((rge_read_phy_ocp(sc, 0xa420) & 0x0007) == 3)
 1.1     sevan 				break;
 1.1     sevan 			DELAY(1000);
 1.1     sevan 		}
1.17  jakllsch 	} else {
 1.1     sevan 		rge_write_phy(sc, 0, MII_BMCR, BMCR_AUTOEN | BMCR_PDOWN);
1.17  jakllsch 		RGE_CLRBIT_1(sc, RGE_PMCH, 0x80);
1.17  jakllsch 		RGE_CLRBIT_1(sc, RGE_PPSW, 0x40);
1.17  jakllsch 	}
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_phy_config(struct rge_softc *sc)
 1.1     sevan {
1.17  jakllsch 	/* Read microcode version. */
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x801e);
1.17  jakllsch 	sc->rge_mcodever = rge_read_phy_ocp(sc, 0xa438);
1.17  jakllsch
1.17  jakllsch 	switch (sc->rge_type) {
1.17  jakllsch 	case MAC_CFG2:
1.17  jakllsch 		rge_phy_config_mac_cfg2(sc);
1.17  jakllsch 		break;
1.17  jakllsch 	case MAC_CFG3:
1.17  jakllsch 		rge_phy_config_mac_cfg3(sc);
1.17  jakllsch 		break;
1.17  jakllsch 	case MAC_CFG4:
1.17  jakllsch 		rge_phy_config_mac_cfg4(sc);
1.17  jakllsch 		break;
1.17  jakllsch 	case MAC_CFG5:
1.17  jakllsch 		rge_phy_config_mac_cfg5(sc);
1.17  jakllsch 		break;
1.17  jakllsch 	default:
1.17  jakllsch 		break;	/* Can't happen. */
1.17  jakllsch 	}
1.17  jakllsch
1.17  jakllsch 	rge_write_phy(sc, 0x0a5b, 0x12,
1.17  jakllsch 	    rge_read_phy(sc, 0x0a5b, 0x12) & ~0x8000);
1.17  jakllsch
1.17  jakllsch 	/* Disable EEE. */
1.17  jakllsch 	RGE_MAC_CLRBIT(sc, 0xe040, 0x0003);
1.17  jakllsch 	if (sc->rge_type == MAC_CFG2 || sc->rge_type == MAC_CFG3) {
1.17  jakllsch 		RGE_MAC_CLRBIT(sc, 0xeb62, 0x0006);
1.17  jakllsch 		RGE_PHY_CLRBIT(sc, 0xa432, 0x0010);
1.17  jakllsch 	}
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa5d0, 0x0006);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa6d4, 0x0001);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa6d8, 0x0010);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa428, 0x0080);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa4a2, 0x0200);
1.17  jakllsch
1.17  jakllsch 	rge_patch_phy_mcu(sc, 1);
1.17  jakllsch 	RGE_MAC_CLRBIT(sc, 0xe052, 0x0001);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa442, 0x3000);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa430, 0x8000);
1.17  jakllsch 	rge_patch_phy_mcu(sc, 0);
1.17  jakllsch }
1.17  jakllsch
1.17  jakllsch void
1.17  jakllsch rge_phy_config_mac_cfg2(struct rge_softc *sc)
1.17  jakllsch {
1.17  jakllsch 	uint16_t val;
1.17  jakllsch 	int i;
1.17  jakllsch
1.17  jakllsch 	for (i = 0; i < nitems(rtl8125_mac_cfg2_ephy); i++)
1.17  jakllsch 		rge_write_ephy(sc, rtl8125_mac_cfg2_ephy[i].reg,
1.17  jakllsch 		    rtl8125_mac_cfg2_ephy[i].val);
1.17  jakllsch
1.17  jakllsch 	rge_phy_config_mcu(sc, RGE_MAC_CFG2_MCODE_VER);
1.17  jakllsch
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xad40) & ~0x03ff;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad40, val | 0x0084);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xad4e, 0x0010);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xad16) & ~0x03ff;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad16, val | 0x0006);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xad32) & ~0x03ff;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad32, val | 0x0006);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xac08, 0x1100);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xac8a) & ~0xf000;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac8a, val | 0x7000);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xad18, 0x0400);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xad1a, 0x03ff);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xad1c, 0x03ff);
1.17  jakllsch
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80ea);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0xc400);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80eb);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0x0700;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x0300);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80f8);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x1c00);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80f1);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x3000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80fe);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0xa500);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8102);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x5000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8105);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x3300);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8100);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x7000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8104);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0xf000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8106);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x6500);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80dc);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0xed00);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80df);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xa438, 0x0100);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80e1);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa438, 0x0100);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xbf06) & ~0x003f;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbf06, val | 0x0038);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x819f);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0xd0b6);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbc34, 0x5555);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xbf0a) & ~0x0e00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbf0a, val | 0x0a00);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa5c0, 0x0400);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xa442, 0x0800);
1.17  jakllsch }
1.17  jakllsch
1.17  jakllsch void
1.17  jakllsch rge_phy_config_mac_cfg3(struct rge_softc *sc)
1.17  jakllsch {
1.17  jakllsch 	struct ifnet *ifp = &sc->sc_ec.ec_if;
1.17  jakllsch 	uint16_t val;
 1.1     sevan 	int i;
 1.1     sevan 	static const uint16_t mac_cfg3_a438_value[] =
 1.1     sevan 	    { 0x0043, 0x00a7, 0x00d6, 0x00ec, 0x00f6, 0x00fb, 0x00fd, 0x00ff,
 1.1     sevan 	      0x00bb, 0x0058, 0x0029, 0x0013, 0x0009, 0x0004, 0x0002 };
 1.1     sevan
 1.1     sevan 	static const uint16_t mac_cfg3_b88e_value[] =
 1.5     skrll 	    { 0xc091, 0x6e12, 0xc092, 0x1214, 0xc094, 0x1516, 0xc096, 0x171b,
 1.1     sevan 	      0xc098, 0x1b1c, 0xc09a, 0x1f1f, 0xc09c, 0x2021, 0xc09e, 0x2224,
 1.1     sevan 	      0xc0a0, 0x2424, 0xc0a2, 0x2424, 0xc0a4, 0x2424, 0xc018, 0x0af2,
 1.1     sevan 	      0xc01a, 0x0d4a, 0xc01c, 0x0f26, 0xc01e, 0x118d, 0xc020, 0x14f3,
 1.1     sevan 	      0xc022, 0x175a, 0xc024, 0x19c0, 0xc026, 0x1c26, 0xc089, 0x6050,
 1.1     sevan 	      0xc08a, 0x5f6e, 0xc08c, 0x6e6e, 0xc08e, 0x6e6e, 0xc090, 0x6e12 };
 1.1     sevan
1.17  jakllsch 	for (i = 0; i < nitems(rtl8125_mac_cfg3_ephy); i++)
1.17  jakllsch 		rge_write_ephy(sc, rtl8125_mac_cfg3_ephy[i].reg,
1.17  jakllsch 		    rtl8125_mac_cfg3_ephy[i].val);
1.17  jakllsch
1.17  jakllsch 	val = rge_read_ephy(sc, 0x002a) & ~0x7000;
1.17  jakllsch 	rge_write_ephy(sc, 0x002a, val | 0x3000);
1.17  jakllsch 	RGE_EPHY_CLRBIT(sc, 0x0019, 0x0040);
1.17  jakllsch 	RGE_EPHY_SETBIT(sc, 0x001b, 0x0e00);
1.17  jakllsch 	RGE_EPHY_CLRBIT(sc, 0x001b, 0x7000);
1.17  jakllsch 	rge_write_ephy(sc, 0x0002, 0x6042);
1.17  jakllsch 	rge_write_ephy(sc, 0x0006, 0x0014);
1.17  jakllsch 	val = rge_read_ephy(sc, 0x006a) & ~0x7000;
1.17  jakllsch 	rge_write_ephy(sc, 0x006a, val | 0x3000);
1.17  jakllsch 	RGE_EPHY_CLRBIT(sc, 0x0059, 0x0040);
1.17  jakllsch 	RGE_EPHY_SETBIT(sc, 0x005b, 0x0e00);
1.17  jakllsch 	RGE_EPHY_CLRBIT(sc, 0x005b, 0x7000);
1.17  jakllsch 	rge_write_ephy(sc, 0x0042, 0x6042);
1.17  jakllsch 	rge_write_ephy(sc, 0x0046, 0x0014);
1.17  jakllsch
1.17  jakllsch 	rge_phy_config_mcu(sc, RGE_MAC_CFG3_MCODE_VER);
1.17  jakllsch
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xad4e, 0x0010);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xad16) & ~0x03ff;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad16, val | 0x03ff);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xad32) & ~0x003f;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad32, val | 0x0006);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xac08, 0x1000);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xac08, 0x0100);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xacc0) & ~0x0003;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xacc0, val | 0x0002);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xad40) & ~0x00e0;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad40, val | 0x0040);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xad40) & ~0x0007;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad40, val | 0x0004);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xac14, 0x0080);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xac80, 0x0300);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xac5e) & ~0x0007;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac5e, val | 0x0002);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad4c, 0x00a8);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac5c, 0x01ff);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xac8a) & ~0x00f0;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac8a, val | 0x0030);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8157);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xb87e) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, val | 0x0500);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8159);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xb87e) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, val | 0x0700);
1.17  jakllsch 	RGE_WRITE_2(sc, RGE_EEE_TXIDLE_TIMER, ifp->if_mtu + ETHER_HDR_LEN +
1.17  jakllsch 	    32);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x80a2);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x0153);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x809c);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x0153);
1.17  jakllsch
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x81b3);
1.17  jakllsch 	for (i = 0; i < nitems(mac_cfg3_a438_value); i++)
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xa438, mac_cfg3_a438_value[i]);
1.17  jakllsch 	for (i = 0; i < 26; i++)
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xa438, 0);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8257);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x020f);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80ea);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x7843);
1.17  jakllsch
1.17  jakllsch 	rge_patch_phy_mcu(sc, 1);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xb896, 0x0001);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xb892, 0xff00);
1.17  jakllsch 	for (i = 0; i < nitems(mac_cfg3_b88e_value); i += 2) {
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xb88e, mac_cfg3_b88e_value[i]);
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xb890, mac_cfg3_b88e_value[i + 1]);
1.17  jakllsch 	}
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xb896, 0x0001);
1.17  jakllsch 	rge_patch_phy_mcu(sc, 0);
1.17  jakllsch
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xd068, 0x2000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x81a2);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xa438, 0x0100);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xb54c) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb54c, val | 0xdb00);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa454, 0x0001);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xa5d4, 0x0020);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xad4e, 0x0010);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa86a, 0x0001);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xa442, 0x0800);
1.17  jakllsch }
1.17  jakllsch
1.17  jakllsch void
1.17  jakllsch rge_phy_config_mac_cfg4(struct rge_softc *sc)
1.17  jakllsch {
1.17  jakllsch 	struct ifnet *ifp = &sc->sc_ec.ec_if;
1.17  jakllsch 	uint16_t val;
1.17  jakllsch 	int i;
1.17  jakllsch 	static const uint16_t mac_cfg4_b87c_value[] =
1.23     skrll 	    { 0x8013, 0x0700, 0x8fb9, 0x2801, 0x8fba, 0x0100, 0x8fbc, 0x1900,
1.23     skrll 	      0x8fbe, 0xe100, 0x8fc0, 0x0800, 0x8fc2, 0xe500, 0x8fc4, 0x0f00,
1.23     skrll 	      0x8fc6, 0xf100, 0x8fc8, 0x0400, 0x8fca, 0xf300, 0x8fcc, 0xfd00,
1.23     skrll 	      0x8fce, 0xff00, 0x8fd0, 0xfb00, 0x8fd2, 0x0100, 0x8fd4, 0xf400,
1.23     skrll 	      0x8fd6, 0xff00, 0x8fd8, 0xf600, 0x813d, 0x390e, 0x814f, 0x790e,
1.17  jakllsch 	      0x80b0, 0x0f31 };
1.17  jakllsch
1.17  jakllsch 	for (i = 0; i < nitems(rtl8125_mac_cfg4_ephy); i++)
1.17  jakllsch 		rge_write_ephy(sc, rtl8125_mac_cfg4_ephy[i].reg,
1.17  jakllsch 		    rtl8125_mac_cfg4_ephy[i].val);
1.17  jakllsch
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbf86, 0x9000);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xc402, 0x0400);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xc402, 0x0400);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbd86, 0x1010);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbd88, 0x1010);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xbd4e) & ~0x0c00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbd4e, val | 0x0800);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xbf46) & ~0x0f00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbf46, val | 0x0700);
1.17  jakllsch
1.17  jakllsch 	rge_phy_config_mcu(sc, RGE_MAC_CFG4_MCODE_VER);
1.17  jakllsch
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xa442, 0x0800);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xbc08, 0x000c);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8fff);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x0400);
1.17  jakllsch 	for (i = 0; i < 6; i++) {
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xb87c, 0x8560 + i * 2);
1.17  jakllsch 		if (i < 3)
1.17  jakllsch 			rge_write_phy_ocp(sc, 0xb87e, 0x19cc);
1.17  jakllsch 		else
1.17  jakllsch 			rge_write_phy_ocp(sc, 0xb87e, 0x147d);
1.17  jakllsch 	}
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8ffe);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x0907);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xacda) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xacda, val | 0xff00);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xacde) & ~0xf000;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xacde, val | 0xf000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x80d6);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x2801);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x80F2);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x2801);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x80f4);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x6077);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb506, 0x01e7);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac8c, 0x0ffc);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac46, 0xb7b4);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac50, 0x0fbc);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac3c, 0x9240);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac4E, 0x0db4);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xacc6, 0x0707);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xacc8, 0xa0d3);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad08, 0x0007);
1.17  jakllsch 	for (i = 0; i < nitems(mac_cfg4_b87c_value); i += 2) {
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xb87c, mac_cfg4_b87c_value[i]);
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xb87e, mac_cfg4_b87c_value[i + 1]);
1.17  jakllsch 	}
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xbf4c, 0x0002);
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xbcca, 0x0300);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8141);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x320e);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8153);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x720e);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xa432, 0x0040);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8529);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x050e);
1.17  jakllsch 	RGE_WRITE_2(sc, RGE_EEE_TXIDLE_TIMER, ifp->if_mtu + ETHER_HDR_LEN +
1.17  jakllsch 	    32);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x816c);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0xc4a0);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8170);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0xc4a0);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8174);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x04a0);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8178);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x04a0);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x817c);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x0719);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8ff4);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x0400);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8ff1);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x0404);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbf4a, 0x001b);
1.17  jakllsch 	for (i = 0; i < 6; i++) {
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xb87c, 0x8033 + i * 4);
1.17  jakllsch 		if (i == 2)
1.17  jakllsch 			rge_write_phy_ocp(sc, 0xb87e, 0xfc32);
1.17  jakllsch 		else
1.17  jakllsch 			rge_write_phy_ocp(sc, 0xb87e, 0x7c13);
1.17  jakllsch 	}
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8145);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x370e);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8157);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x770e);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8169);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x0d0a);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x817b);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x1d0a);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x8217);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x5000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x821a);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x5000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80da);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x0403);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80dc);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x1000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80b3);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x0384);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80b7);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x2007);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80ba);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x6c00);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80b5);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0xf009);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80bd);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x9f00);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80c7);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0xf083);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80dd);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x03f0);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80df);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x1000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80cb);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x2007);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80ce);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x6c00);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80c9);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x8009);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80d1);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0x8000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80a3);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x200a);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80a5);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0xf0ad);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x809f);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x6073);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80a1);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, 0x000b);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x80a9);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xa438) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa438, val | 0xc000);
1.17  jakllsch 	rge_patch_phy_mcu(sc, 1);
1.23     skrll 	RGE_PHY_CLRBIT(sc, 0xb896, 0x0001);
1.23     skrll 	RGE_PHY_CLRBIT(sc, 0xb892, 0xff00);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb88e, 0xc23e);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb890, 0x0000);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb88e, 0xc240);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb890, 0x0103);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb88e, 0xc242);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb890, 0x0507);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb88e, 0xc244);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb890, 0x090b);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb88e, 0xc246);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb890, 0x0c0e);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb88e, 0xc248);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb890, 0x1012);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb88e, 0xc24a);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb890, 0x1416);
1.23     skrll 	RGE_PHY_SETBIT(sc, 0xb896, 0x0001);
1.17  jakllsch 	rge_patch_phy_mcu(sc, 0);
1.23     skrll 	RGE_PHY_SETBIT(sc, 0xa86a, 0x0001);
1.23     skrll 	RGE_PHY_SETBIT(sc, 0xa6f0, 0x0001);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbfa0, 0xd70d);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbfa2, 0x4100);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbfa4, 0xe868);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbfa6, 0xdc59);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb54c, 0x3c18);
1.17  jakllsch 	RGE_PHY_CLRBIT(sc, 0xbfa4, 0x0020);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xa436, 0x817d);
1.23     skrll 	RGE_PHY_SETBIT(sc, 0xa438, 0x1000);
1.17  jakllsch }
1.17  jakllsch
1.17  jakllsch void
1.17  jakllsch rge_phy_config_mac_cfg5(struct rge_softc *sc)
1.17  jakllsch {
1.17  jakllsch 	struct ifnet *ifp = &sc->sc_ec.ec_if;
1.17  jakllsch 	uint16_t val;
1.17  jakllsch 	int i;
 1.1     sevan
1.17  jakllsch 	for (i = 0; i < nitems(rtl8125_mac_cfg5_ephy); i++)
1.17  jakllsch 		rge_write_ephy(sc, rtl8125_mac_cfg5_ephy[i].reg,
1.17  jakllsch 		    rtl8125_mac_cfg5_ephy[i].val);
1.17  jakllsch
1.17  jakllsch 	val = rge_read_ephy(sc, 0x0022) & ~0x0030;
1.17  jakllsch 	rge_write_ephy(sc, 0x0022, val | 0x0020);
1.17  jakllsch 	val = rge_read_ephy(sc, 0x0062) & ~0x0030;
1.17  jakllsch 	rge_write_ephy(sc, 0x0062, val | 0x0020);
1.17  jakllsch
1.17  jakllsch 	rge_phy_config_mcu(sc, RGE_MAC_CFG5_MCODE_VER);
1.17  jakllsch
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xa442, 0x0800);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xac46) & ~0x00f0;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xac46, val | 0x0090);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xad30) & ~0x0003;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xad30, val | 0x0001);
1.17  jakllsch 	RGE_WRITE_2(sc, RGE_EEE_TXIDLE_TIMER, ifp->if_mtu + ETHER_HDR_LEN +
1.17  jakllsch 	    32);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x80f5);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x760e);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8107);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, 0x360e);
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87c, 0x8551);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xb87e) & ~0xff00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xb87e, val | 0x0800);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xbf00) & ~0xe000;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbf00, val | 0xa000);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xbf46) & ~0x0f00;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbf46, val | 0x0300);
1.17  jakllsch 	for (i = 0; i < 10; i++) {
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xa436, 0x8044 + i * 6);
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xa438, 0x2417);
1.17  jakllsch 	}
1.17  jakllsch 	RGE_PHY_SETBIT(sc, 0xa4ca, 0x0040);
1.17  jakllsch 	val = rge_read_phy_ocp(sc, 0xbf84) & ~0xe000;
1.17  jakllsch 	rge_write_phy_ocp(sc, 0xbf84, val | 0xa000);
1.17  jakllsch }
 1.1     sevan
1.17  jakllsch void
1.17  jakllsch rge_phy_config_mcu(struct rge_softc *sc, uint16_t mcode_version)
1.17  jakllsch {
1.17  jakllsch 	if (sc->rge_mcodever != mcode_version) {
1.17  jakllsch 		int i;
 1.1     sevan
1.17  jakllsch 		rge_patch_phy_mcu(sc, 1);
 1.1     sevan
1.17  jakllsch 		if (sc->rge_type == MAC_CFG2 || sc->rge_type == MAC_CFG3) {
 1.1     sevan 			rge_write_phy_ocp(sc, 0xa436, 0x8024);
1.17  jakllsch 			if (sc->rge_type == MAC_CFG2)
1.17  jakllsch 				rge_write_phy_ocp(sc, 0xa438, 0x8600);
1.17  jakllsch 			else
1.17  jakllsch 				rge_write_phy_ocp(sc, 0xa438, 0x8601);
 1.1     sevan 			rge_write_phy_ocp(sc, 0xa436, 0xb82e);
 1.1     sevan 			rge_write_phy_ocp(sc, 0xa438, 0x0001);
 1.1     sevan
 1.1     sevan 			RGE_PHY_SETBIT(sc, 0xb820, 0x0080);
1.17  jakllsch 		}
1.17  jakllsch
1.17  jakllsch 		if (sc->rge_type == MAC_CFG2) {
 1.1     sevan 			for (i = 0; i < nitems(rtl8125_mac_cfg2_mcu); i++) {
 1.1     sevan 				rge_write_phy_ocp(sc,
 1.1     sevan 				    rtl8125_mac_cfg2_mcu[i].reg,
 1.1     sevan 				    rtl8125_mac_cfg2_mcu[i].val);
 1.1     sevan 			}
1.17  jakllsch 		} else if (sc->rge_type == MAC_CFG3) {
 1.1     sevan 			for (i = 0; i < nitems(rtl8125_mac_cfg3_mcu); i++) {
 1.1     sevan 				rge_write_phy_ocp(sc,
 1.1     sevan 				    rtl8125_mac_cfg3_mcu[i].reg,
 1.1     sevan 				    rtl8125_mac_cfg3_mcu[i].val);
 1.1     sevan 			}
1.17  jakllsch 		} else if (sc->rge_type == MAC_CFG4) {
1.17  jakllsch 			for (i = 0; i < nitems(rtl8125_mac_cfg4_mcu); i++) {
1.17  jakllsch 				rge_write_phy_ocp(sc,
1.17  jakllsch 				    rtl8125_mac_cfg4_mcu[i].reg,
1.17  jakllsch 				    rtl8125_mac_cfg4_mcu[i].val);
1.17  jakllsch 			}
1.17  jakllsch 		} else if (sc->rge_type == MAC_CFG5) {
1.17  jakllsch 			for (i = 0; i < nitems(rtl8125_mac_cfg5_mcu); i++) {
1.17  jakllsch 				rge_write_phy_ocp(sc,
1.17  jakllsch 				    rtl8125_mac_cfg5_mcu[i].reg,
1.17  jakllsch 				    rtl8125_mac_cfg5_mcu[i].val);
1.17  jakllsch 			}
1.17  jakllsch 		}
1.17  jakllsch
1.17  jakllsch 		if (sc->rge_type == MAC_CFG2 || sc->rge_type == MAC_CFG3) {
 1.1     sevan 			RGE_PHY_CLRBIT(sc, 0xb820, 0x0080);
 1.1     sevan
 1.1     sevan 			rge_write_phy_ocp(sc, 0xa436, 0);
 1.1     sevan 			rge_write_phy_ocp(sc, 0xa438, 0);
 1.1     sevan 			RGE_PHY_CLRBIT(sc, 0xb82e, 0x0001);
 1.1     sevan 			rge_write_phy_ocp(sc, 0xa436, 0x8024);
 1.1     sevan 			rge_write_phy_ocp(sc, 0xa438, 0);
1.17  jakllsch 		}
 1.1     sevan
 1.1     sevan 		rge_patch_phy_mcu(sc, 0);
 1.1     sevan
1.17  jakllsch 		/* Write microcode version. */
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xa436, 0x801e);
1.17  jakllsch 		rge_write_phy_ocp(sc, 0xa438, mcode_version);
 1.1     sevan 	}
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_set_macaddr(struct rge_softc *sc, const uint8_t *addr)
 1.1     sevan {
 1.1     sevan 	RGE_SETBIT_1(sc, RGE_EECMD, RGE_EECMD_WRITECFG);
 1.1     sevan 	RGE_WRITE_4(sc, RGE_MAC0,
1.21   msaitoh 	    (uint32_t)addr[3] << 24 | addr[2] << 16 | addr[1] << 8 | addr[0]);
 1.1     sevan 	RGE_WRITE_4(sc, RGE_MAC4,
 1.1     sevan 	    addr[5] <<  8 | addr[4]);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_EECMD, RGE_EECMD_WRITECFG);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_get_macaddr(struct rge_softc *sc, uint8_t *addr)
 1.1     sevan {
1.22   msaitoh 	int i;
1.22   msaitoh
1.22   msaitoh 	for (i = 0; i < ETHER_ADDR_LEN; i++)
1.22   msaitoh 		addr[i] = RGE_READ_1(sc, RGE_ADDR0 + i);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_hw_init(struct rge_softc *sc)
 1.1     sevan {
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	RGE_SETBIT_1(sc, RGE_EECMD, RGE_EECMD_WRITECFG);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_CFG5, RGE_CFG5_PME_STS);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_CFG2, RGE_CFG2_CLKREQ_EN);
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_EECMD, RGE_EECMD_WRITECFG);
 1.1     sevan 	RGE_CLRBIT_1(sc, 0xf1, 0x80);
 1.1     sevan
 1.1     sevan 	/* Disable UPS. */
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xd40a, 0x0010);
 1.1     sevan
 1.1     sevan 	/* Configure MAC MCU. */
 1.1     sevan 	rge_write_mac_ocp(sc, 0xfc38, 0);
 1.1     sevan
 1.1     sevan 	for (i = 0xfc28; i < 0xfc38; i += 2)
 1.1     sevan 		rge_write_mac_ocp(sc, i, 0);
 1.1     sevan
 1.1     sevan 	DELAY(3000);
 1.1     sevan 	rge_write_mac_ocp(sc, 0xfc26, 0);
 1.1     sevan
 1.1     sevan 	if (sc->rge_type == MAC_CFG3) {
1.17  jakllsch 		for (i = 0; i < nitems(rtl8125_mac_bps); i++) {
1.17  jakllsch 			rge_write_mac_ocp(sc, rtl8125_mac_bps[i].reg,
1.17  jakllsch 			    rtl8125_mac_bps[i].val);
1.17  jakllsch 		}
1.17  jakllsch 	} else if (sc->rge_type == MAC_CFG5) {
1.17  jakllsch 		for (i = 0; i < nitems(rtl8125b_mac_bps); i++) {
1.17  jakllsch 			rge_write_mac_ocp(sc, rtl8125b_mac_bps[i].reg,
1.17  jakllsch 			    rtl8125b_mac_bps[i].val);
1.17  jakllsch 		}
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	/* Disable PHY power saving. */
 1.1     sevan 	rge_disable_phy_ocp_pwrsave(sc);
 1.1     sevan
 1.1     sevan 	/* Set PCIe uncorrectable error status. */
 1.1     sevan 	rge_write_csi(sc, 0x108,
 1.1     sevan 	    rge_read_csi(sc, 0x108) | 0x00100000);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_disable_phy_ocp_pwrsave(struct rge_softc *sc)
 1.1     sevan {
 1.1     sevan 	if (rge_read_phy_ocp(sc, 0xc416) != 0x0500) {
 1.1     sevan 		rge_patch_phy_mcu(sc, 1);
 1.1     sevan 		rge_write_phy_ocp(sc, 0xc416, 0);
 1.1     sevan 		rge_write_phy_ocp(sc, 0xc416, 0x0500);
 1.1     sevan 		rge_patch_phy_mcu(sc, 0);
 1.1     sevan 	}
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_patch_phy_mcu(struct rge_softc *sc, int set)
 1.1     sevan {
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	if (set)
 1.1     sevan 		RGE_PHY_SETBIT(sc, 0xb820, 0x0010);
 1.1     sevan 	else
 1.1     sevan 		RGE_PHY_CLRBIT(sc, 0xb820, 0x0010);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < 1000; i++) {
1.17  jakllsch 		if ((rge_read_phy_ocp(sc, 0xb800) & 0x0040) == 0x0040)
1.17  jakllsch 			break;
 1.1     sevan 		DELAY(100);
 1.1     sevan 	}
1.17  jakllsch 	if (i == 1000) {
1.17  jakllsch 		DPRINTF(("timeout waiting to patch phy mcu\n"));
1.17  jakllsch 		return;
1.17  jakllsch 	}
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_add_media_types(struct rge_softc *sc)
 1.1     sevan {
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_10_T, 0, NULL);
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_10_T | IFM_FDX, 0, NULL);
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_100_TX, 0, NULL);
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_100_TX | IFM_FDX, 0, NULL);
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_1000_T, 0, NULL);
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_1000_T | IFM_FDX, 0, NULL);
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_2500_T, 0, NULL);
 1.1     sevan 	ifmedia_add(&sc->sc_media, IFM_ETHER | IFM_2500_T | IFM_FDX, 0, NULL);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_config_imtype(struct rge_softc *sc, int imtype)
 1.1     sevan {
 1.1     sevan 	switch (imtype) {
 1.1     sevan 	case RGE_IMTYPE_NONE:
 1.1     sevan 		sc->rge_intrs = RGE_INTRS;
 1.1     sevan 		sc->rge_rx_ack = RGE_ISR_RX_OK | RGE_ISR_RX_DESC_UNAVAIL |
 1.1     sevan 		    RGE_ISR_RX_FIFO_OFLOW;
 1.1     sevan 		sc->rge_tx_ack = RGE_ISR_TX_OK;
 1.1     sevan 		break;
 1.1     sevan 	case RGE_IMTYPE_SIM:
 1.1     sevan 		sc->rge_intrs = RGE_INTRS_TIMER;
 1.1     sevan 		sc->rge_rx_ack = RGE_ISR_PCS_TIMEOUT;
 1.1     sevan 		sc->rge_tx_ack = RGE_ISR_PCS_TIMEOUT;
 1.1     sevan 		break;
 1.1     sevan 	default:
1.14     sevan 		panic("%s: unknown imtype %d", device_xname(sc->sc_dev), imtype);
 1.1     sevan 	}
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
1.17  jakllsch rge_disable_hw_im(struct rge_softc *sc)
1.17  jakllsch {
1.17  jakllsch 	RGE_WRITE_2(sc, RGE_IM, 0);
1.17  jakllsch }
1.17  jakllsch
1.17  jakllsch void
 1.1     sevan rge_disable_sim_im(struct rge_softc *sc)
 1.1     sevan {
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_TIMERINT0, 0);
 1.1     sevan 	sc->rge_timerintr = 0;
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_setup_sim_im(struct rge_softc *sc)
 1.1     sevan {
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_TIMERINT0, 0x2600);
 1.1     sevan 	RGE_WRITE_4(sc, RGE_TIMERCNT, 1);
 1.1     sevan 	sc->rge_timerintr = 1;
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_setup_intr(struct rge_softc *sc, int imtype)
 1.1     sevan {
 1.1     sevan 	rge_config_imtype(sc, imtype);
 1.1     sevan
 1.1     sevan 	/* Enable interrupts. */
 1.1     sevan 	RGE_WRITE_4(sc, RGE_IMR, sc->rge_intrs);
 1.1     sevan
 1.1     sevan 	switch (imtype) {
 1.1     sevan 	case RGE_IMTYPE_NONE:
 1.1     sevan 		rge_disable_sim_im(sc);
1.17  jakllsch 		rge_disable_hw_im(sc);
 1.1     sevan 		break;
 1.1     sevan 	case RGE_IMTYPE_SIM:
1.17  jakllsch 		rge_disable_hw_im(sc);
 1.1     sevan 		rge_setup_sim_im(sc);
 1.1     sevan 		break;
 1.1     sevan 	default:
1.14     sevan 		panic("%s: unknown imtype %d", device_xname(sc->sc_dev), imtype);
 1.1     sevan 	}
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_exit_oob(struct rge_softc *sc)
 1.1     sevan {
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	RGE_CLRBIT_4(sc, RGE_RXCFG, RGE_RXCFG_ALLPHYS | RGE_RXCFG_INDIV |
 1.1     sevan 	    RGE_RXCFG_MULTI | RGE_RXCFG_BROAD | RGE_RXCFG_RUNT |
 1.1     sevan 	    RGE_RXCFG_ERRPKT);
 1.1     sevan
 1.1     sevan 	/* Disable RealWoW. */
 1.1     sevan 	rge_write_mac_ocp(sc, 0xc0bc, 0x00ff);
 1.1     sevan
 1.1     sevan 	rge_reset(sc);
 1.1     sevan
 1.1     sevan 	/* Disable OOB. */
 1.1     sevan 	RGE_CLRBIT_1(sc, RGE_MCUCMD, RGE_MCUCMD_IS_OOB);
 1.1     sevan
 1.1     sevan 	RGE_MAC_CLRBIT(sc, 0xe8de, 0x4000);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < 10; i++) {
 1.1     sevan 		DELAY(100);
 1.1     sevan 		if (RGE_READ_2(sc, RGE_TWICMD) & 0x0200)
 1.1     sevan 			break;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	rge_write_mac_ocp(sc, 0xc0aa, 0x07d0);
1.17  jakllsch 	rge_write_mac_ocp(sc, 0xc0a6, 0x01b5);
 1.1     sevan 	rge_write_mac_ocp(sc, 0xc01e, 0x5555);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < 10; i++) {
 1.1     sevan 		DELAY(100);
 1.1     sevan 		if (RGE_READ_2(sc, RGE_TWICMD) & 0x0200)
 1.1     sevan 			break;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	if (rge_read_mac_ocp(sc, 0xd42c) & 0x0100) {
1.17  jakllsch 		printf("%s: rge_exit_oob(): rtl8125_is_ups_resume!!\n",
1.17  jakllsch 		    device_xname(sc->sc_dev));
 1.1     sevan 		for (i = 0; i < RGE_TIMEOUT; i++) {
1.10     sevan 			if ((rge_read_phy_ocp(sc, 0xa420) & 0x0007) == 2)
 1.1     sevan 				break;
 1.1     sevan 			DELAY(1000);
 1.1     sevan 		}
 1.1     sevan 		RGE_MAC_CLRBIT(sc, 0xd408, 0x0100);
1.17  jakllsch 		if (sc->rge_type == MAC_CFG4 || sc->rge_type == MAC_CFG5)
1.17  jakllsch 			RGE_PHY_CLRBIT(sc, 0xa466, 0x0001);
 1.1     sevan 		RGE_PHY_CLRBIT(sc, 0xa468, 0x000a);
 1.1     sevan 	}
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_write_csi(struct rge_softc *sc, uint32_t reg, uint32_t val)
 1.1     sevan {
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	RGE_WRITE_4(sc, RGE_CSIDR, val);
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_CSIAR, (reg & RGE_CSIAR_ADDR_MASK) |
 1.1     sevan 	    (RGE_CSIAR_BYTE_EN << RGE_CSIAR_BYTE_EN_SHIFT) | RGE_CSIAR_BUSY);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < 10; i++) {
 1.1     sevan 		 DELAY(100);
 1.1     sevan 		 if (!(RGE_READ_4(sc, RGE_CSIAR) & RGE_CSIAR_BUSY))
 1.1     sevan 			break;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	DELAY(20);
 1.1     sevan }
 1.1     sevan
 1.1     sevan uint32_t
 1.1     sevan rge_read_csi(struct rge_softc *sc, uint32_t reg)
 1.1     sevan {
 1.1     sevan 	int i;
 1.1     sevan
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_CSIAR, (reg & RGE_CSIAR_ADDR_MASK) |
 1.1     sevan 	    (RGE_CSIAR_BYTE_EN << RGE_CSIAR_BYTE_EN_SHIFT));
 1.1     sevan
 1.1     sevan 	for (i = 0; i < 10; i++) {
 1.1     sevan 		 DELAY(100);
 1.1     sevan 		 if (RGE_READ_4(sc, RGE_CSIAR) & RGE_CSIAR_BUSY)
 1.1     sevan 			break;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	DELAY(20);
 1.1     sevan
 1.1     sevan 	return (RGE_READ_4(sc, RGE_CSIDR));
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_write_mac_ocp(struct rge_softc *sc, uint16_t reg, uint16_t val)
 1.1     sevan {
 1.1     sevan 	uint32_t tmp;
 1.1     sevan
 1.1     sevan 	tmp = (reg >> 1) << RGE_MACOCP_ADDR_SHIFT;
 1.1     sevan 	tmp += val;
 1.1     sevan 	tmp |= RGE_MACOCP_BUSY;
 1.1     sevan 	RGE_WRITE_4(sc, RGE_MACOCP, tmp);
 1.1     sevan }
 1.1     sevan
 1.1     sevan uint16_t
 1.1     sevan rge_read_mac_ocp(struct rge_softc *sc, uint16_t reg)
 1.1     sevan {
 1.1     sevan 	uint32_t val;
 1.1     sevan
 1.1     sevan 	val = (reg >> 1) << RGE_MACOCP_ADDR_SHIFT;
 1.1     sevan 	RGE_WRITE_4(sc, RGE_MACOCP, val);
 1.1     sevan
 1.1     sevan 	return (RGE_READ_4(sc, RGE_MACOCP) & RGE_MACOCP_DATA_MASK);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_write_ephy(struct rge_softc *sc, uint16_t reg, uint16_t val)
 1.1     sevan {
 1.1     sevan 	uint32_t tmp;
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	tmp = (reg & RGE_EPHYAR_ADDR_MASK) << RGE_EPHYAR_ADDR_SHIFT;
 1.1     sevan 	tmp |= RGE_EPHYAR_BUSY | (val & RGE_EPHYAR_DATA_MASK);
 1.1     sevan 	RGE_WRITE_4(sc, RGE_EPHYAR, tmp);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < 10; i++) {
 1.1     sevan 		DELAY(100);
 1.1     sevan 		if (!(RGE_READ_4(sc, RGE_EPHYAR) & RGE_EPHYAR_BUSY))
 1.1     sevan 			break;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	DELAY(20);
 1.1     sevan }
 1.1     sevan
1.17  jakllsch uint16_t
1.17  jakllsch rge_read_ephy(struct rge_softc *sc, uint16_t reg)
1.17  jakllsch {
1.17  jakllsch 	uint32_t val;
1.17  jakllsch 	int i;
1.17  jakllsch
1.17  jakllsch 	val = (reg & RGE_EPHYAR_ADDR_MASK) << RGE_EPHYAR_ADDR_SHIFT;
1.17  jakllsch 	RGE_WRITE_4(sc, RGE_EPHYAR, val);
1.17  jakllsch
1.17  jakllsch 	for (i = 0; i < 10; i++) {
1.17  jakllsch 		DELAY(100);
1.17  jakllsch 		val = RGE_READ_4(sc, RGE_EPHYAR);
1.17  jakllsch 		if (val & RGE_EPHYAR_BUSY)
1.17  jakllsch 			break;
1.17  jakllsch 	}
1.17  jakllsch
1.17  jakllsch 	DELAY(20);
1.17  jakllsch
1.17  jakllsch 	return (val & RGE_EPHYAR_DATA_MASK);
1.17  jakllsch }
1.17  jakllsch
 1.1     sevan void
 1.1     sevan rge_write_phy(struct rge_softc *sc, uint16_t addr, uint16_t reg, uint16_t val)
 1.1     sevan {
 1.1     sevan 	uint16_t off, phyaddr;
 1.1     sevan
 1.1     sevan 	phyaddr = addr ? addr : RGE_PHYBASE + (reg / 8);
 1.1     sevan 	phyaddr <<= 4;
 1.1     sevan
 1.1     sevan 	off = addr ? reg : 0x10 + (reg % 8);
 1.1     sevan
 1.1     sevan 	phyaddr += (off - 16) << 1;
 1.1     sevan
 1.1     sevan 	rge_write_phy_ocp(sc, phyaddr, val);
 1.1     sevan }
 1.1     sevan
1.17  jakllsch uint16_t
1.17  jakllsch rge_read_phy(struct rge_softc *sc, uint16_t addr, uint16_t reg)
1.17  jakllsch {
1.17  jakllsch 	uint16_t off, phyaddr;
1.17  jakllsch
1.17  jakllsch 	phyaddr = addr ? addr : RGE_PHYBASE + (reg / 8);
1.17  jakllsch 	phyaddr <<= 4;
1.17  jakllsch
1.17  jakllsch 	off = addr ? reg : 0x10 + (reg % 8);
1.17  jakllsch
1.17  jakllsch 	phyaddr += (off - 16) << 1;
1.17  jakllsch
1.17  jakllsch 	return (rge_read_phy_ocp(sc, phyaddr));
1.17  jakllsch }
1.17  jakllsch
 1.1     sevan void
 1.1     sevan rge_write_phy_ocp(struct rge_softc *sc, uint16_t reg, uint16_t val)
 1.1     sevan {
 1.1     sevan 	uint32_t tmp;
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	tmp = (reg >> 1) << RGE_PHYOCP_ADDR_SHIFT;
 1.1     sevan 	tmp |= RGE_PHYOCP_BUSY | val;
 1.1     sevan 	RGE_WRITE_4(sc, RGE_PHYOCP, tmp);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < RGE_TIMEOUT; i++) {
 1.1     sevan 		DELAY(1);
 1.1     sevan 		if (!(RGE_READ_4(sc, RGE_PHYOCP) & RGE_PHYOCP_BUSY))
 1.1     sevan 			break;
 1.1     sevan 	}
 1.1     sevan }
 1.1     sevan
 1.1     sevan uint16_t
 1.1     sevan rge_read_phy_ocp(struct rge_softc *sc, uint16_t reg)
 1.1     sevan {
 1.1     sevan 	uint32_t val;
 1.1     sevan 	int i;
 1.1     sevan
 1.1     sevan 	val = (reg >> 1) << RGE_PHYOCP_ADDR_SHIFT;
 1.1     sevan 	RGE_WRITE_4(sc, RGE_PHYOCP, val);
 1.1     sevan
 1.1     sevan 	for (i = 0; i < RGE_TIMEOUT; i++) {
 1.1     sevan 		DELAY(1);
 1.1     sevan 		val = RGE_READ_4(sc, RGE_PHYOCP);
 1.1     sevan 		if (val & RGE_PHYOCP_BUSY)
 1.1     sevan 			break;
 1.1     sevan 	}
 1.1     sevan
 1.1     sevan 	return (val & RGE_PHYOCP_DATA_MASK);
 1.1     sevan }
 1.1     sevan
 1.1     sevan int
 1.1     sevan rge_get_link_status(struct rge_softc *sc)
 1.1     sevan {
 1.1     sevan 	return ((RGE_READ_2(sc, RGE_PHYSTAT) & RGE_PHYSTAT_LINK) ? 1 : 0);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
1.30     skrll rge_txstart(void *arg)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = arg;
 1.1     sevan
 1.1     sevan 	RGE_WRITE_2(sc, RGE_TXSTART, RGE_TXSTART_START);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_tick(void *arg)
 1.1     sevan {
 1.1     sevan 	struct rge_softc *sc = arg;
 1.1     sevan 	int s;
 1.1     sevan
 1.1     sevan 	s = splnet();
 1.1     sevan 	rge_link_state(sc);
 1.1     sevan 	splx(s);
 1.1     sevan
1.17  jakllsch 	callout_schedule(&sc->sc_timeout, hz);
 1.1     sevan }
 1.1     sevan
 1.1     sevan void
 1.1     sevan rge_link_state(struct rge_softc *sc)
 1.1     sevan {
 1.2     sevan 	struct ifnet *ifp = &sc->sc_ec.ec_if;
 1.1     sevan 	int link = LINK_STATE_DOWN;
 1.1     sevan
 1.1     sevan 	if (rge_get_link_status(sc))
 1.1     sevan 		link = LINK_STATE_UP;
 1.1     sevan
1.17  jakllsch 	if (ifp->if_link_state != link) { /* XXX not safe to access */
1.17  jakllsch 		if_link_state_change(ifp, link);
 1.1     sevan 	}
 1.1     sevan }