stand/efiboot/efinet.c

1.1  nonaka /*	$NetBSD: efinet.c,v 1.1 2018/04/11 10:32:09 nonaka Exp $	*/
1.1  nonaka
1.1  nonaka /*-
1.1  nonaka  * Copyright (c) 2001 Doug Rabson
1.1  nonaka  * Copyright (c) 2002, 2006 Marcel Moolenaar
1.1  nonaka  * All rights reserved.
1.1  nonaka  *
1.1  nonaka  * Redistribution and use in source and binary forms, with or without
1.1  nonaka  * modification, are permitted provided that the following conditions
1.1  nonaka  * are met:
1.1  nonaka  * 1. Redistributions of source code must retain the above copyright
1.1  nonaka  *    notice, this list of conditions and the following disclaimer.
1.1  nonaka  * 2. Redistributions in binary form must reproduce the above copyright
1.1  nonaka  *    notice, this list of conditions and the following disclaimer in the
1.1  nonaka  *    documentation and/or other materials provided with the distribution.
1.1  nonaka  *
1.1  nonaka  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
1.1  nonaka  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1  nonaka  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1  nonaka  * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
1.1  nonaka  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1  nonaka  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1  nonaka  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1  nonaka  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1  nonaka  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1  nonaka  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1  nonaka  * SUCH DAMAGE.
1.1  nonaka  */
1.1  nonaka
1.1  nonaka #include <sys/cdefs.h>
1.1  nonaka #if 0
1.1  nonaka __FBSDID("$FreeBSD: head/stand/efi/libefi/efinet.c 321621 2017-07-27 15:06:34Z andrew $");
1.1  nonaka #endif
1.1  nonaka
1.1  nonaka #include "efiboot.h"
1.1  nonaka
1.1  nonaka #include <lib/libsa/net.h>
1.1  nonaka #include <lib/libsa/netif.h>
1.1  nonaka
1.1  nonaka #include <bootinfo.h>
1.1  nonaka #include "devopen.h"
1.1  nonaka
1.1  nonaka #ifndef ETHER_ALIGN
1.1  nonaka #define ETHER_ALIGN	2
1.1  nonaka #endif
1.1  nonaka
1.1  nonaka #define ETHER_EXT_LEN	(ETHER_HDR_LEN + ETHER_CRC_LEN + ETHER_ALIGN)
1.1  nonaka
1.1  nonaka #if defined(DEBUG) || defined(ARP_DEBUG) || defined(BOOTP_DEBUG) || \
1.1  nonaka     defined(NET_DEBUG) || defined(NETIF_DEBUG) || defined(NFS_DEBUG) || \
1.1  nonaka     defined(RARP_DEBUG) || defined(RPC_DEBUG)
1.1  nonaka int debug = 1;
1.1  nonaka #else
1.1  nonaka int debug = 0;
1.1  nonaka #endif
1.1  nonaka
1.1  nonaka extern bool kernel_loaded;
1.1  nonaka
1.1  nonaka struct efinetinfo {
1.1  nonaka 	EFI_SIMPLE_NETWORK *net;
1.1  nonaka 	bool bootdev;
1.1  nonaka 	size_t pktbufsz;
1.1  nonaka 	UINT8 *pktbuf;
1.1  nonaka 	struct {
1.1  nonaka 		int type;
1.1  nonaka 		u_int tag;
1.1  nonaka 	} bus;
1.1  nonaka };
1.1  nonaka static struct btinfo_netif bi_netif;
1.1  nonaka
1.1  nonaka static int	efinet_match(struct netif *, void *);
1.1  nonaka static int	efinet_probe(struct netif *, void *);
1.1  nonaka static void	efinet_init(struct iodesc *, void *);
1.1  nonaka static int	efinet_get(struct iodesc *, void *, size_t, saseconds_t);
1.1  nonaka static int	efinet_put(struct iodesc *, void *, size_t);
1.1  nonaka static void	efinet_end(struct netif *);
1.1  nonaka
1.1  nonaka struct netif_driver efinetif = {
1.1  nonaka 	.netif_bname = "net",
1.1  nonaka 	.netif_match = efinet_match,
1.1  nonaka 	.netif_probe = efinet_probe,
1.1  nonaka 	.netif_init = efinet_init,
1.1  nonaka 	.netif_get = efinet_get,
1.1  nonaka 	.netif_put = efinet_put,
1.1  nonaka 	.netif_end = efinet_end,
1.1  nonaka 	.netif_ifs = NULL,
1.1  nonaka 	.netif_nifs = 0
1.1  nonaka };
1.1  nonaka
1.1  nonaka #ifdef EFINET_DEBUG
1.1  nonaka static void
1.1  nonaka dump_mode(EFI_SIMPLE_NETWORK_MODE *mode)
1.1  nonaka {
1.1  nonaka 	int i;
1.1  nonaka
1.1  nonaka 	printf("State                 = %x\n", mode->State);
1.1  nonaka 	printf("HwAddressSize         = %u\n", mode->HwAddressSize);
1.1  nonaka 	printf("MediaHeaderSize       = %u\n", mode->MediaHeaderSize);
1.1  nonaka 	printf("MaxPacketSize         = %u\n", mode->MaxPacketSize);
1.1  nonaka 	printf("NvRamSize             = %u\n", mode->NvRamSize);
1.1  nonaka 	printf("NvRamAccessSize       = %u\n", mode->NvRamAccessSize);
1.1  nonaka 	printf("ReceiveFilterMask     = %x\n", mode->ReceiveFilterMask);
1.1  nonaka 	printf("ReceiveFilterSetting  = %u\n", mode->ReceiveFilterSetting);
1.1  nonaka 	printf("MaxMCastFilterCount   = %u\n", mode->MaxMCastFilterCount);
1.1  nonaka 	printf("MCastFilterCount      = %u\n", mode->MCastFilterCount);
1.1  nonaka 	printf("MCastFilter           = {");
1.1  nonaka 	for (i = 0; i < mode->MCastFilterCount; i++)
1.1  nonaka 		printf(" %s", ether_sprintf(mode->MCastFilter[i].Addr));
1.1  nonaka 	printf(" }\n");
1.1  nonaka 	printf("CurrentAddress        = %s\n",
1.1  nonaka 	    ether_sprintf(mode->CurrentAddress.Addr));
1.1  nonaka 	printf("BroadcastAddress      = %s\n",
1.1  nonaka 	    ether_sprintf(mode->BroadcastAddress.Addr));
1.1  nonaka 	printf("PermanentAddress      = %s\n",
1.1  nonaka 	    ether_sprintf(mode->PermanentAddress.Addr));
1.1  nonaka 	printf("IfType                = %u\n", mode->IfType);
1.1  nonaka 	printf("MacAddressChangeable  = %d\n", mode->MacAddressChangeable);
1.1  nonaka 	printf("MultipleTxSupported   = %d\n", mode->MultipleTxSupported);
1.1  nonaka 	printf("MediaPresentSupported = %d\n", mode->MediaPresentSupported);
1.1  nonaka 	printf("MediaPresent          = %d\n", mode->MediaPresent);
1.1  nonaka }
1.1  nonaka #endif
1.1  nonaka
1.1  nonaka static int
1.1  nonaka efinet_match(struct netif *nif, void *machdep_hint)
1.1  nonaka {
1.1  nonaka 	struct devdesc *dev = machdep_hint;
1.1  nonaka
1.1  nonaka 	if (dev->d_unit != nif->nif_unit)
1.1  nonaka 		return 0;
1.1  nonaka
1.1  nonaka 	return 1;
1.1  nonaka }
1.1  nonaka
1.1  nonaka static int
1.1  nonaka efinet_probe(struct netif *nif, void *machdep_hint)
1.1  nonaka {
1.1  nonaka
1.1  nonaka 	return 0;
1.1  nonaka }
1.1  nonaka
1.1  nonaka static int
1.1  nonaka efinet_put(struct iodesc *desc, void *pkt, size_t len)
1.1  nonaka {
1.1  nonaka 	struct netif *nif = desc->io_netif;
1.1  nonaka 	struct efinetinfo *eni = nif->nif_devdata;
1.1  nonaka 	EFI_SIMPLE_NETWORK *net;
1.1  nonaka 	EFI_STATUS status;
1.1  nonaka 	void *buf;
1.1  nonaka
1.1  nonaka 	if (eni == NULL)
1.1  nonaka 		return -1;
1.1  nonaka 	net = eni->net;
1.1  nonaka
1.1  nonaka 	status = uefi_call_wrapper(net->Transmit, 7, net, 0, (UINTN)len, pkt, NULL,
1.1  nonaka 	    NULL, NULL);
1.1  nonaka 	if (EFI_ERROR(status))
1.1  nonaka 		return -1;
1.1  nonaka
1.1  nonaka 	/* Wait for the buffer to be transmitted */
1.1  nonaka 	do {
1.1  nonaka 		buf = NULL;	/* XXX Is this needed? */
1.1  nonaka 		status = uefi_call_wrapper(net->GetStatus, 3, net, NULL, &buf);
1.1  nonaka 		/*
1.1  nonaka 		 * XXX EFI1.1 and the E1000 card returns a different
1.1  nonaka 		 * address than we gave.  Sigh.
1.1  nonaka 		 */
1.1  nonaka 	} while (!EFI_ERROR(status) && buf == NULL);
1.1  nonaka
1.1  nonaka 	/* XXX How do we deal with status != EFI_SUCCESS now? */
1.1  nonaka 	return EFI_ERROR(status) ? -1 : len;
1.1  nonaka }
1.1  nonaka
1.1  nonaka static int
1.1  nonaka efinet_get(struct iodesc *desc, void *pkt, size_t len, saseconds_t timeout)
1.1  nonaka {
1.1  nonaka 	struct netif *nif = desc->io_netif;
1.1  nonaka 	struct efinetinfo *eni = nif->nif_devdata;
1.1  nonaka 	EFI_SIMPLE_NETWORK *net;
1.1  nonaka 	EFI_STATUS status;
1.1  nonaka 	UINTN bufsz, rsz;
1.1  nonaka 	time_t t;
1.1  nonaka 	char *buf, *ptr;
1.1  nonaka 	int ret = -1;
1.1  nonaka
1.1  nonaka 	if (eni == NULL)
1.1  nonaka 		return -1;
1.1  nonaka 	net = eni->net;
1.1  nonaka
1.1  nonaka 	if (eni->pktbufsz < net->Mode->MaxPacketSize + ETHER_EXT_LEN) {
1.1  nonaka 		bufsz = net->Mode->MaxPacketSize + ETHER_EXT_LEN;
1.1  nonaka 		buf = alloc(bufsz);
1.1  nonaka 		if (buf == NULL)
1.1  nonaka 			return -1;
1.1  nonaka 		dealloc(eni->pktbuf, eni->pktbufsz);
1.1  nonaka 		eni->pktbufsz = bufsz;
1.1  nonaka 		eni->pktbuf = buf;
1.1  nonaka 	}
1.1  nonaka 	ptr = eni->pktbuf + ETHER_ALIGN;
1.1  nonaka
1.1  nonaka 	t = getsecs();
1.1  nonaka 	while ((getsecs() - t) < timeout) {
1.1  nonaka 		rsz = eni->pktbufsz;
1.1  nonaka 		status = uefi_call_wrapper(net->Receive, 7, net, NULL, &rsz, ptr,
1.1  nonaka 		    NULL, NULL, NULL);
1.1  nonaka 		if (!EFI_ERROR(status)) {
1.1  nonaka 			rsz = min(rsz, len);
1.1  nonaka 			memcpy(pkt, ptr, rsz);
1.1  nonaka 			ret = (int)rsz;
1.1  nonaka 			break;
1.1  nonaka 		}
1.1  nonaka 		if (status != EFI_NOT_READY)
1.1  nonaka 			break;
1.1  nonaka 	}
1.1  nonaka
1.1  nonaka 	return ret;
1.1  nonaka }
1.1  nonaka
1.1  nonaka static void
1.1  nonaka efinet_init(struct iodesc *desc, void *machdep_hint)
1.1  nonaka {
1.1  nonaka 	struct netif *nif = desc->io_netif;
1.1  nonaka 	struct efinetinfo *eni;
1.1  nonaka 	EFI_SIMPLE_NETWORK *net;
1.1  nonaka 	EFI_STATUS status;
1.1  nonaka 	UINT32 mask;
1.1  nonaka
1.1  nonaka 	if (nif->nif_driver->netif_ifs[nif->nif_unit].dif_unit < 0) {
1.1  nonaka 		printf("Invalid network interface %d\n", nif->nif_unit);
1.1  nonaka 		return;
1.1  nonaka 	}
1.1  nonaka
1.1  nonaka 	eni = nif->nif_driver->netif_ifs[nif->nif_unit].dif_private;
1.1  nonaka 	nif->nif_devdata = eni;
1.1  nonaka 	net = eni->net;
1.1  nonaka 	if (net->Mode->State == EfiSimpleNetworkStopped) {
1.1  nonaka 		status = uefi_call_wrapper(net->Start, 1, net);
1.1  nonaka 		if (EFI_ERROR(status)) {
1.1  nonaka 			printf("net%d: cannot start interface (status=%"
1.1  nonaka 			    PRIxMAX ")\n", nif->nif_unit, (uintmax_t)status);
1.1  nonaka 			return;
1.1  nonaka 		}
1.1  nonaka 	}
1.1  nonaka
1.1  nonaka 	if (net->Mode->State != EfiSimpleNetworkInitialized) {
1.1  nonaka 		status = uefi_call_wrapper(net->Initialize, 3, net, 0, 0);
1.1  nonaka 		if (EFI_ERROR(status)) {
1.1  nonaka 			printf("net%d: cannot init. interface (status=%"
1.1  nonaka 			    PRIxMAX ")\n", nif->nif_unit, (uintmax_t)status);
1.1  nonaka 			return;
1.1  nonaka 		}
1.1  nonaka 	}
1.1  nonaka
1.1  nonaka 	mask = EFI_SIMPLE_NETWORK_RECEIVE_UNICAST |
1.1  nonaka 	    EFI_SIMPLE_NETWORK_RECEIVE_BROADCAST;
1.1  nonaka
1.1  nonaka 	status = uefi_call_wrapper(net->ReceiveFilters, 6, net, mask, 0, FALSE,
1.1  nonaka 	    0, NULL);
1.1  nonaka 	if (EFI_ERROR(status)) {
1.1  nonaka 		printf("net%d: cannot set rx. filters (status=%" PRIxMAX ")\n",
1.1  nonaka 		    nif->nif_unit, (uintmax_t)status);
1.1  nonaka 		return;
1.1  nonaka 	}
1.1  nonaka
1.1  nonaka 	if (!kernel_loaded) {
1.1  nonaka 		bi_netif.bus = eni->bus.type;
1.1  nonaka 		bi_netif.addr.tag = eni->bus.tag;
1.1  nonaka 		snprintf(bi_netif.ifname, sizeof(bi_netif.ifname), "net%d",
1.1  nonaka 		    nif->nif_unit);
1.1  nonaka 		BI_ADD(&bi_netif, BTINFO_NETIF, sizeof(bi_netif));
1.1  nonaka 	}
1.1  nonaka
1.1  nonaka #ifdef EFINET_DEBUG
1.1  nonaka 	dump_mode(net->Mode);
1.1  nonaka #endif
1.1  nonaka
1.1  nonaka 	memcpy(desc->myea, net->Mode->CurrentAddress.Addr, 6);
1.1  nonaka 	desc->xid = 1;
1.1  nonaka }
1.1  nonaka
1.1  nonaka static void
1.1  nonaka efinet_end(struct netif *nif)
1.1  nonaka {
1.1  nonaka 	struct efinetinfo *eni = nif->nif_devdata;
1.1  nonaka 	EFI_SIMPLE_NETWORK *net;
1.1  nonaka
1.1  nonaka 	if (eni == NULL)
1.1  nonaka 		return;
1.1  nonaka 	net = eni->net;
1.1  nonaka
1.1  nonaka 	uefi_call_wrapper(net->Shutdown, 1, net);
1.1  nonaka }
1.1  nonaka
1.1  nonaka static bool
1.1  nonaka efi_net_pci_probe(struct efinetinfo *eni, EFI_DEVICE_PATH *dp, EFI_DEVICE_PATH *pdp)
1.1  nonaka {
1.1  nonaka 	PCI_DEVICE_PATH *pci = (PCI_DEVICE_PATH *)dp;
1.1  nonaka 	int bus = -1;
1.1  nonaka
1.1  nonaka 	if (pdp != NULL &&
1.1  nonaka 	    DevicePathType(pdp) == ACPI_DEVICE_PATH &&
1.1  nonaka 	    (DevicePathSubType(pdp) == ACPI_DP ||
1.1  nonaka 	     DevicePathSubType(pdp) == EXPANDED_ACPI_DP)) {
1.1  nonaka 		ACPI_HID_DEVICE_PATH *acpi = (ACPI_HID_DEVICE_PATH *)pdp;
1.1  nonaka 		/* PCI root bus */
1.1  nonaka 		if (acpi->HID == EISA_PNP_ID(0x0A08) ||
1.1  nonaka 		    acpi->HID == EISA_PNP_ID(0x0A03)) {
1.1  nonaka 			bus = acpi->UID;
1.1  nonaka 		}
1.1  nonaka 	}
1.1  nonaka 	if (bus < 0)
1.1  nonaka 		return false;
1.1  nonaka
1.1  nonaka 	eni->bus.type = BI_BUS_PCI;
1.1  nonaka 	eni->bus.tag = (bus & 0xff) << 8;
1.1  nonaka 	eni->bus.tag |= (pci->Device & 0x1f) << 3;
1.1  nonaka 	eni->bus.tag |= pci->Function & 0x7;
1.1  nonaka 	return true;
1.1  nonaka }
1.1  nonaka
1.1  nonaka void
1.1  nonaka efi_net_probe(void)
1.1  nonaka {
1.1  nonaka 	struct efinetinfo *enis;
1.1  nonaka 	struct netif_dif *dif;
1.1  nonaka 	struct netif_stats *stats;
1.1  nonaka 	EFI_DEVICE_PATH *dp0, *dp, *pdp;
1.1  nonaka 	EFI_SIMPLE_NETWORK *net;
1.1  nonaka 	EFI_HANDLE *handles;
1.1  nonaka 	EFI_STATUS status;
1.1  nonaka 	UINTN i, nhandles;
1.1  nonaka 	int nifs;
1.1  nonaka 	bool found;
1.1  nonaka
1.1  nonaka 	status = LibLocateHandle(ByProtocol, &SimpleNetworkProtocol, NULL,
1.1  nonaka 	    &nhandles, &handles);
1.1  nonaka 	if (EFI_ERROR(status) || nhandles == 0)
1.1  nonaka 		return;
1.1  nonaka
1.1  nonaka 	enis = alloc(nhandles * sizeof(*enis));
1.1  nonaka 	if (enis == NULL)
1.1  nonaka 		return;
1.1  nonaka 	memset(enis, 0, nhandles * sizeof(*enis));
1.1  nonaka
1.1  nonaka 	nifs = 0;
1.1  nonaka 	for (i = 0; i < nhandles; i++) {
1.1  nonaka 		status = uefi_call_wrapper(BS->HandleProtocol, 3, handles[i],
1.1  nonaka 		    &DevicePathProtocol, (void **)&dp0);
1.1  nonaka 		if (EFI_ERROR(status))
1.1  nonaka 			continue;
1.1  nonaka
1.1  nonaka 		found = false;
1.1  nonaka 		for (dp = dp0; !IsDevicePathEnd(dp); dp = NextDevicePathNode(dp)) {
1.1  nonaka 			if (DevicePathType(dp) == MESSAGING_DEVICE_PATH &&
1.1  nonaka 			    DevicePathSubType(dp) == MSG_MAC_ADDR_DP) {
1.1  nonaka 				found = true;
1.1  nonaka 				break;
1.1  nonaka 			}
1.1  nonaka 		}
1.1  nonaka 		if (!found)
1.1  nonaka 			continue;
1.1  nonaka
1.1  nonaka 		status = uefi_call_wrapper(BS->OpenProtocol, 6, handles[i],
1.1  nonaka 		    &SimpleNetworkProtocol, (void **)&net, IH, NULL,
1.1  nonaka 		    EFI_OPEN_PROTOCOL_EXCLUSIVE);
1.1  nonaka 		if (EFI_ERROR(status)) {
1.1  nonaka 			printf("Unable to open network interface %" PRIuMAX
1.1  nonaka 			    " for exclusive access: %" PRIxMAX "\n",
1.1  nonaka 			    (uintmax_t)i, (uintmax_t)status);
1.1  nonaka 		}
1.1  nonaka
1.1  nonaka 		found = false;
1.1  nonaka 		for (pdp = NULL, dp = dp0;
1.1  nonaka 		    !IsDevicePathEnd(dp);
1.1  nonaka 		    pdp = dp, dp = NextDevicePathNode(dp)) {
1.1  nonaka 			if (DevicePathType(dp) == HARDWARE_DEVICE_PATH) {
1.1  nonaka 				if (DevicePathSubType(dp) == HW_PCI_DP)
1.1  nonaka 					found = efi_net_pci_probe(&enis[nifs],
1.1  nonaka 					    dp, pdp);
1.1  nonaka 				break;
1.1  nonaka 			}
1.1  nonaka 		}
1.1  nonaka 		if (found) {
1.1  nonaka 			enis[nifs].net = net;
1.1  nonaka 			enis[nifs].bootdev = efi_pxe_match_booted_interface(
1.1  nonaka 			    &net->Mode->CurrentAddress, net->Mode->HwAddressSize);
1.1  nonaka 			enis[nifs].pktbufsz = net->Mode->MaxPacketSize +
1.1  nonaka 			    ETHER_EXT_LEN;
1.1  nonaka 			enis[nifs].pktbuf = alloc(enis[nifs].pktbufsz);
1.1  nonaka 			if (enis[nifs].pktbuf == NULL) {
1.1  nonaka 				while (i-- > 0) {
1.1  nonaka 					dealloc(enis[i].pktbuf, enis[i].pktbufsz);
1.1  nonaka 					if (i == 0)
1.1  nonaka 						break;
1.1  nonaka 				}
1.1  nonaka 				dealloc(enis, nhandles * sizeof(*enis));
1.1  nonaka 				FreePool(handles);
1.1  nonaka 				return;
1.1  nonaka 			}
1.1  nonaka 			nifs++;
1.1  nonaka 		}
1.1  nonaka 	}
1.1  nonaka
1.1  nonaka 	FreePool(handles);
1.1  nonaka
1.1  nonaka 	if (nifs == 0)
1.1  nonaka 		return;
1.1  nonaka
1.1  nonaka 	efinetif.netif_ifs = alloc(nifs * sizeof(*dif));
1.1  nonaka 	stats = alloc(nifs * sizeof(*stats));
1.1  nonaka 	if (efinetif.netif_ifs == NULL || stats == NULL) {
1.1  nonaka 		if (efinetif.netif_ifs != NULL) {
1.1  nonaka 			dealloc(efinetif.netif_ifs, nifs * sizeof(*dif));
1.1  nonaka 			efinetif.netif_ifs = NULL;
1.1  nonaka 		}
1.1  nonaka 		if (stats != NULL)
1.1  nonaka 			dealloc(stats, nifs * sizeof(*stats));
1.1  nonaka 		for (i = 0; i < nifs; i++)
1.1  nonaka 			dealloc(enis[i].pktbuf, enis[i].pktbufsz);
1.1  nonaka 		dealloc(enis, nhandles * sizeof(*enis));
1.1  nonaka 		return;
1.1  nonaka 	}
1.1  nonaka 	memset(efinetif.netif_ifs, 0, nifs * sizeof(*dif));
1.1  nonaka 	memset(stats, 0, nifs * sizeof(*stats));
1.1  nonaka 	efinetif.netif_nifs = nifs;
1.1  nonaka
1.1  nonaka 	for (i = 0; i < nifs; i++) {
1.1  nonaka 		dif = &efinetif.netif_ifs[i];
1.1  nonaka 		dif->dif_unit = i;
1.1  nonaka 		dif->dif_nsel = 1;
1.1  nonaka 		dif->dif_stats = &stats[i];
1.1  nonaka 		dif->dif_private = &enis[i];
1.1  nonaka 	}
1.1  nonaka }
1.1  nonaka
1.1  nonaka void
1.1  nonaka efi_net_show(void)
1.1  nonaka {
1.1  nonaka 	const struct netif_dif *dif;
1.1  nonaka 	const struct efinetinfo *eni;
1.1  nonaka 	EFI_SIMPLE_NETWORK *net;
1.1  nonaka 	int i;
1.1  nonaka
1.1  nonaka 	for (i = 0; i < efinetif.netif_nifs; i++) {
1.1  nonaka 		dif = &efinetif.netif_ifs[i];
1.1  nonaka 		eni = dif->dif_private;
1.1  nonaka 		net = eni->net;
1.1  nonaka
1.1  nonaka 		printf("net net%d", dif->dif_unit);
1.1  nonaka 		if (net->Mode != NULL) {
1.1  nonaka 			for (UINT32 x = 0; x < net->Mode->HwAddressSize; x++) {
1.1  nonaka 				printf("%c%02x", x == 0 ? ' ' : ':',
1.1  nonaka 				    net->Mode->CurrentAddress.Addr[x]);
1.1  nonaka 			}
1.1  nonaka 		}
1.1  nonaka 		if (eni->bus.type == BI_BUS_PCI) {
1.1  nonaka 			printf(" pci%d,%d,%d", (eni->bus.tag >> 8) & 0xff,
1.1  nonaka 			    (eni->bus.tag >> 3) & 0x1f, eni->bus.tag & 0x7);
1.1  nonaka 		}
1.1  nonaka 		if (eni->bootdev)
1.1  nonaka 			printf(" pxeboot");
1.1  nonaka 		printf("\n");
1.1  nonaka 	}
1.1  nonaka }
1.1  nonaka
1.1  nonaka int
1.1  nonaka efi_net_get_booted_interface_unit(void)
1.1  nonaka {
1.1  nonaka 	const struct netif_dif *dif;
1.1  nonaka 	const struct efinetinfo *eni;
1.1  nonaka 	int i;
1.1  nonaka
1.1  nonaka 	for (i = 0; i < efinetif.netif_nifs; i++) {
1.1  nonaka 		dif = &efinetif.netif_ifs[i];
1.1  nonaka 		eni = dif->dif_private;
1.1  nonaka 		if (eni->bootdev)
1.1  nonaka 			return dif->dif_unit;
1.1  nonaka 	}
1.1  nonaka 	return -1;
1.1  nonaka }