stand/efiboot/efiblock.c

1.12  jmcneill /* $NetBSD: efiblock.c,v 1.12 2021/06/20 19:10:47 jmcneill Exp $ */
 1.1  jmcneill
 1.1  jmcneill /*-
 1.1  jmcneill  * Copyright (c) 2016 Kimihiro Nonaka <nonaka (at) netbsd.org>
 1.1  jmcneill  * Copyright (c) 2018 Jared McNeill <jmcneill (at) invisible.ca>
 1.1  jmcneill  * All rights reserved.
 1.1  jmcneill  *
 1.1  jmcneill  * Redistribution and use in source and binary forms, with or without
 1.1  jmcneill  * modification, are permitted provided that the following conditions
 1.1  jmcneill  * are met:
 1.1  jmcneill  * 1. Redistributions of source code must retain the above copyright
 1.1  jmcneill  *    notice, this list of conditions and the following disclaimer.
 1.1  jmcneill  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  jmcneill  *    notice, this list of conditions and the following disclaimer in the
 1.1  jmcneill  *    documentation and/or other materials provided with the distribution.
 1.1  jmcneill  *
 1.1  jmcneill  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
 1.1  jmcneill  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 1.1  jmcneill  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 1.1  jmcneill  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
 1.1  jmcneill  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 1.1  jmcneill  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 1.1  jmcneill  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1  jmcneill  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 1.1  jmcneill  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1  jmcneill  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1  jmcneill  * SUCH DAMAGE.
 1.1  jmcneill  */
 1.1  jmcneill
 1.1  jmcneill #define FSTYPENAMES
 1.1  jmcneill
 1.1  jmcneill #include <sys/param.h>
 1.2  jmcneill #include <sys/md5.h>
 1.4  jmcneill #include <sys/uuid.h>
 1.1  jmcneill
 1.8  jmcneill #include <fs/cd9660/iso.h>
 1.8  jmcneill
 1.1  jmcneill #include "efiboot.h"
 1.1  jmcneill #include "efiblock.h"
 1.1  jmcneill
1.12  jmcneill #define	EFI_BLOCK_TIMEOUT	120
1.12  jmcneill #define	EFI_BLOCK_TIMEOUT_CODE	0x810c0000
1.12  jmcneill
1.11       mrg /*
1.11       mrg  * The raidframe support is basic.  Ideally, it should be expanded to
1.11       mrg  * consider raid volumes a first-class citizen like the x86 efiboot does,
1.11       mrg  * but for now, we simply assume each RAID is potentially bootable.
1.11       mrg  */
1.11       mrg #define	RF_PROTECTED_SECTORS	64	/* XXX refer to <.../rf_optnames.h> */
1.11       mrg
 1.1  jmcneill static EFI_HANDLE *efi_block;
 1.1  jmcneill static UINTN efi_nblock;
 1.2  jmcneill static struct efi_block_part *efi_block_booted = NULL;
 1.1  jmcneill
 1.1  jmcneill static TAILQ_HEAD(, efi_block_dev) efi_block_devs = TAILQ_HEAD_INITIALIZER(efi_block_devs);
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill efi_block_parse(const char *fname, struct efi_block_part **pbpart, char **pfile)
 1.1  jmcneill {
 1.1  jmcneill 	struct efi_block_dev *bdev;
 1.1  jmcneill 	struct efi_block_part *bpart;
 1.1  jmcneill 	char pathbuf[PATH_MAX], *default_device, *ep = NULL;
 1.1  jmcneill 	const char *full_path;
 1.1  jmcneill 	intmax_t dev;
 1.1  jmcneill 	int part;
 1.1  jmcneill
 1.1  jmcneill 	default_device = get_default_device();
 1.1  jmcneill 	if (strchr(fname, ':') == NULL) {
 1.1  jmcneill 		if (strlen(default_device) > 0) {
 1.1  jmcneill 			snprintf(pathbuf, sizeof(pathbuf), "%s:%s", default_device, fname);
 1.1  jmcneill 			full_path = pathbuf;
 1.1  jmcneill 			*pfile = __UNCONST(fname);
 1.1  jmcneill 		} else {
 1.1  jmcneill 			return EINVAL;
 1.1  jmcneill 		}
 1.1  jmcneill 	} else {
 1.1  jmcneill 		full_path = fname;
 1.1  jmcneill 		*pfile = strchr(fname, ':') + 1;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	if (strncasecmp(full_path, "hd", 2) != 0)
 1.1  jmcneill 		return EINVAL;
 1.1  jmcneill 	dev = strtoimax(full_path + 2, &ep, 10);
 1.1  jmcneill 	if (dev < 0 || dev >= efi_nblock)
 1.1  jmcneill 		return ENXIO;
 1.1  jmcneill 	if (ep[0] < 'a' || ep[0] >= 'a' + MAXPARTITIONS || ep[1] != ':')
 1.1  jmcneill 		return EINVAL;
 1.1  jmcneill 	part = ep[0] - 'a';
 1.1  jmcneill 	TAILQ_FOREACH(bdev, &efi_block_devs, entries) {
 1.1  jmcneill 		if (bdev->index == dev) {
 1.1  jmcneill 			TAILQ_FOREACH(bpart, &bdev->partitions, entries) {
 1.1  jmcneill 				if (bpart->index == part) {
 1.1  jmcneill 					*pbpart = bpart;
 1.1  jmcneill 					return 0;
 1.1  jmcneill 				}
 1.1  jmcneill 			}
 1.1  jmcneill 		}
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	return ENOENT;
 1.1  jmcneill }
 1.1  jmcneill
 1.2  jmcneill static void
 1.2  jmcneill efi_block_generate_hash_mbr(struct efi_block_part *bpart, struct mbr_sector *mbr)
 1.2  jmcneill {
 1.2  jmcneill 	MD5_CTX md5ctx;
 1.2  jmcneill
 1.2  jmcneill 	MD5Init(&md5ctx);
 1.2  jmcneill 	MD5Update(&md5ctx, (void *)mbr, sizeof(*mbr));
 1.2  jmcneill 	MD5Final(bpart->hash, &md5ctx);
 1.2  jmcneill }
 1.2  jmcneill
 1.6  jmcneill static void *
 1.6  jmcneill efi_block_allocate_device_buffer(struct efi_block_dev *bdev, UINTN size,
 1.6  jmcneill 	void **buf_start)
 1.6  jmcneill {
 1.6  jmcneill 	void *buf;
 1.6  jmcneill
 1.6  jmcneill 	if (bdev->bio->Media->IoAlign <= 1)
 1.6  jmcneill 		*buf_start = buf = AllocatePool(size);
 1.6  jmcneill 	else {
 1.6  jmcneill 		buf = AllocatePool(size + bdev->bio->Media->IoAlign - 1);
 1.7  jakllsch 		*buf_start = (buf == NULL) ? NULL :
 1.7  jakllsch 		    (void *)roundup2((intptr_t)buf, bdev->bio->Media->IoAlign);
 1.6  jmcneill 	}
 1.6  jmcneill
 1.6  jmcneill 	return buf;
 1.6  jmcneill }
 1.6  jmcneill
 1.1  jmcneill static int
 1.8  jmcneill efi_block_find_partitions_cd9660(struct efi_block_dev *bdev)
 1.8  jmcneill {
 1.8  jmcneill 	struct efi_block_part *bpart;
 1.8  jmcneill 	struct iso_primary_descriptor *vd;
 1.8  jmcneill 	void *buf, *buf_start;
 1.8  jmcneill 	EFI_STATUS status;
 1.8  jmcneill 	EFI_LBA lba;
 1.8  jmcneill 	UINT32 sz;
 1.8  jmcneill
1.10  jmcneill 	if (bdev->bio->Media->BlockSize != DEV_BSIZE &&
1.10  jmcneill 	    bdev->bio->Media->BlockSize != ISO_DEFAULT_BLOCK_SIZE) {
1.10  jmcneill 		return ENXIO;
1.10  jmcneill 	}
1.10  jmcneill
 1.8  jmcneill 	sz = __MAX(sizeof(*vd), bdev->bio->Media->BlockSize);
 1.8  jmcneill 	sz = roundup(sz, bdev->bio->Media->BlockSize);
1.10  jmcneill 	if ((buf = efi_block_allocate_device_buffer(bdev, sz, &buf_start)) == NULL) {
 1.8  jmcneill 		return ENOMEM;
1.10  jmcneill 	}
 1.8  jmcneill
 1.8  jmcneill 	for (lba = 16;; lba++) {
1.10  jmcneill 		status = uefi_call_wrapper(bdev->bio->ReadBlocks, 5,
1.10  jmcneill 		    bdev->bio,
1.10  jmcneill 		    bdev->media_id,
1.10  jmcneill 		    lba * ISO_DEFAULT_BLOCK_SIZE / bdev->bio->Media->BlockSize,
1.10  jmcneill 		    sz,
1.10  jmcneill 		    buf_start);
1.10  jmcneill 		if (EFI_ERROR(status)) {
 1.8  jmcneill 			goto io_error;
1.10  jmcneill 		}
 1.8  jmcneill
 1.8  jmcneill 		vd = (struct iso_primary_descriptor *)buf_start;
1.10  jmcneill 		if (memcmp(vd->id, ISO_STANDARD_ID, sizeof vd->id) != 0) {
 1.8  jmcneill 			goto io_error;
1.10  jmcneill 		}
1.10  jmcneill 		if (isonum_711(vd->type) == ISO_VD_END) {
 1.8  jmcneill 			goto io_error;
1.10  jmcneill 		}
1.10  jmcneill 		if (isonum_711(vd->type) == ISO_VD_PRIMARY) {
 1.8  jmcneill 			break;
1.10  jmcneill 		}
 1.8  jmcneill 	}
 1.8  jmcneill
1.10  jmcneill 	if (isonum_723(vd->logical_block_size) != ISO_DEFAULT_BLOCK_SIZE) {
 1.8  jmcneill 		goto io_error;
1.10  jmcneill 	}
 1.8  jmcneill
 1.8  jmcneill 	bpart = alloc(sizeof(*bpart));
 1.8  jmcneill 	bpart->index = 0;
 1.8  jmcneill 	bpart->bdev = bdev;
 1.8  jmcneill 	bpart->type = EFI_BLOCK_PART_CD9660;
 1.8  jmcneill 	TAILQ_INSERT_TAIL(&bdev->partitions, bpart, entries);
 1.8  jmcneill
 1.8  jmcneill 	FreePool(buf);
 1.8  jmcneill 	return 0;
 1.8  jmcneill
 1.8  jmcneill io_error:
 1.8  jmcneill 	FreePool(buf);
 1.8  jmcneill 	return EIO;
 1.8  jmcneill }
 1.8  jmcneill
 1.8  jmcneill static int
 1.2  jmcneill efi_block_find_partitions_disklabel(struct efi_block_dev *bdev, struct mbr_sector *mbr, uint32_t start, uint32_t size)
 1.1  jmcneill {
 1.1  jmcneill 	struct efi_block_part *bpart;
 1.1  jmcneill 	struct disklabel d;
 1.1  jmcneill 	struct partition *p;
 1.1  jmcneill 	EFI_STATUS status;
 1.1  jmcneill 	EFI_LBA lba;
 1.6  jmcneill 	void *buf, *buf_start;
 1.1  jmcneill 	UINT32 sz;
 1.1  jmcneill 	int n;
 1.1  jmcneill
 1.1  jmcneill 	sz = __MAX(sizeof(d), bdev->bio->Media->BlockSize);
 1.1  jmcneill 	sz = roundup(sz, bdev->bio->Media->BlockSize);
 1.6  jmcneill 	if ((buf = efi_block_allocate_device_buffer(bdev, sz, &buf_start)) == NULL)
 1.1  jmcneill 		return ENOMEM;
 1.1  jmcneill
 1.3  jakllsch 	lba = (((EFI_LBA)start + LABELSECTOR) * DEV_BSIZE) / bdev->bio->Media->BlockSize;
 1.6  jmcneill 	status = uefi_call_wrapper(bdev->bio->ReadBlocks, 5, bdev->bio, bdev->media_id,
 1.6  jmcneill 		lba, sz, buf_start);
 1.6  jmcneill 	if (EFI_ERROR(status) || getdisklabel(buf_start, &d) != NULL) {
 1.1  jmcneill 		FreePool(buf);
 1.1  jmcneill 		return EIO;
 1.1  jmcneill 	}
 1.1  jmcneill 	FreePool(buf);
 1.1  jmcneill
 1.1  jmcneill 	if (le32toh(d.d_magic) != DISKMAGIC || le32toh(d.d_magic2) != DISKMAGIC)
 1.1  jmcneill 		return EINVAL;
 1.1  jmcneill 	if (le16toh(d.d_npartitions) > MAXPARTITIONS)
 1.1  jmcneill 		return EINVAL;
 1.1  jmcneill
 1.1  jmcneill 	for (n = 0; n < le16toh(d.d_npartitions); n++) {
 1.1  jmcneill 		p = &d.d_partitions[n];
 1.1  jmcneill 		switch (p->p_fstype) {
 1.1  jmcneill 		case FS_BSDFFS:
 1.1  jmcneill 		case FS_MSDOS:
 1.1  jmcneill 		case FS_BSDLFS:
 1.1  jmcneill 			break;
1.11       mrg 		case FS_RAID:
1.11       mrg 			p->p_size -= RF_PROTECTED_SECTORS;
1.11       mrg 			p->p_offset += RF_PROTECTED_SECTORS;
1.11       mrg 			break;
 1.1  jmcneill 		default:
 1.1  jmcneill 			continue;
 1.1  jmcneill 		}
 1.1  jmcneill
 1.1  jmcneill 		bpart = alloc(sizeof(*bpart));
 1.1  jmcneill 		bpart->index = n;
 1.1  jmcneill 		bpart->bdev = bdev;
 1.1  jmcneill 		bpart->type = EFI_BLOCK_PART_DISKLABEL;
1.11       mrg 		bpart->disklabel.secsize = d.d_secsize;
 1.1  jmcneill 		bpart->disklabel.part = *p;
 1.2  jmcneill 		efi_block_generate_hash_mbr(bpart, mbr);
 1.1  jmcneill 		TAILQ_INSERT_TAIL(&bdev->partitions, bpart, entries);
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill efi_block_find_partitions_mbr(struct efi_block_dev *bdev)
 1.1  jmcneill {
 1.1  jmcneill 	struct mbr_sector mbr;
 1.1  jmcneill 	struct mbr_partition *mbr_part;
 1.1  jmcneill 	EFI_STATUS status;
 1.6  jmcneill 	void *buf, *buf_start;
 1.1  jmcneill 	UINT32 sz;
 1.1  jmcneill 	int n;
 1.1  jmcneill
 1.1  jmcneill 	sz = __MAX(sizeof(mbr), bdev->bio->Media->BlockSize);
 1.1  jmcneill 	sz = roundup(sz, bdev->bio->Media->BlockSize);
 1.6  jmcneill 	if ((buf = efi_block_allocate_device_buffer(bdev, sz, &buf_start)) == NULL)
 1.1  jmcneill 		return ENOMEM;
 1.1  jmcneill
 1.6  jmcneill 	status = uefi_call_wrapper(bdev->bio->ReadBlocks, 5, bdev->bio, bdev->media_id,
 1.6  jmcneill 		0, sz, buf_start);
 1.1  jmcneill 	if (EFI_ERROR(status)) {
 1.1  jmcneill 		FreePool(buf);
 1.1  jmcneill 		return EIO;
 1.1  jmcneill 	}
 1.6  jmcneill 	memcpy(&mbr, buf_start, sizeof(mbr));
 1.1  jmcneill 	FreePool(buf);
 1.1  jmcneill
 1.1  jmcneill 	if (le32toh(mbr.mbr_magic) != MBR_MAGIC)
 1.1  jmcneill 		return ENOENT;
 1.1  jmcneill
 1.1  jmcneill 	for (n = 0; n < MBR_PART_COUNT; n++) {
 1.1  jmcneill 		mbr_part = &mbr.mbr_parts[n];
 1.1  jmcneill 		if (le32toh(mbr_part->mbrp_size) == 0)
 1.1  jmcneill 			continue;
 1.1  jmcneill 		if (mbr_part->mbrp_type == MBR_PTYPE_NETBSD) {
 1.2  jmcneill 			efi_block_find_partitions_disklabel(bdev, &mbr, le32toh(mbr_part->mbrp_start), le32toh(mbr_part->mbrp_size));
 1.1  jmcneill 			break;
 1.1  jmcneill 		}
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.4  jmcneill static const struct {
 1.4  jmcneill 	struct uuid guid;
 1.4  jmcneill 	uint8_t fstype;
 1.4  jmcneill } gpt_guid_to_str[] = {
 1.4  jmcneill 	{ GPT_ENT_TYPE_NETBSD_FFS,		FS_BSDFFS },
 1.4  jmcneill 	{ GPT_ENT_TYPE_NETBSD_LFS,		FS_BSDLFS },
 1.4  jmcneill 	{ GPT_ENT_TYPE_NETBSD_RAIDFRAME,	FS_RAID },
 1.4  jmcneill 	{ GPT_ENT_TYPE_NETBSD_CCD,		FS_CCD },
 1.4  jmcneill 	{ GPT_ENT_TYPE_NETBSD_CGD,		FS_CGD },
 1.4  jmcneill 	{ GPT_ENT_TYPE_MS_BASIC_DATA,		FS_MSDOS },	/* or NTFS? ambiguous */
 1.9       tnn 	{ GPT_ENT_TYPE_EFI,			FS_MSDOS },
 1.4  jmcneill };
 1.4  jmcneill
 1.4  jmcneill static int
 1.4  jmcneill efi_block_find_partitions_gpt_entry(struct efi_block_dev *bdev, struct gpt_hdr *hdr, struct gpt_ent *ent, UINT32 index)
 1.4  jmcneill {
 1.4  jmcneill 	struct efi_block_part *bpart;
 1.4  jmcneill 	uint8_t fstype = FS_UNUSED;
 1.4  jmcneill 	struct uuid uuid;
 1.4  jmcneill 	int n;
 1.4  jmcneill
 1.4  jmcneill 	memcpy(&uuid, ent->ent_type, sizeof(uuid));
 1.4  jmcneill 	for (n = 0; n < __arraycount(gpt_guid_to_str); n++)
 1.4  jmcneill 		if (memcmp(ent->ent_type, &gpt_guid_to_str[n].guid, sizeof(ent->ent_type)) == 0) {
 1.4  jmcneill 			fstype = gpt_guid_to_str[n].fstype;
 1.4  jmcneill 			break;
 1.4  jmcneill 		}
 1.4  jmcneill 	if (fstype == FS_UNUSED)
 1.4  jmcneill 		return 0;
 1.4  jmcneill
 1.4  jmcneill 	bpart = alloc(sizeof(*bpart));
 1.4  jmcneill 	bpart->index = index;
 1.4  jmcneill 	bpart->bdev = bdev;
 1.4  jmcneill 	bpart->type = EFI_BLOCK_PART_GPT;
 1.4  jmcneill 	bpart->gpt.fstype = fstype;
 1.4  jmcneill 	bpart->gpt.ent = *ent;
1.11       mrg 	if (fstype == FS_RAID) {
1.11       mrg 		bpart->gpt.ent.ent_lba_start += RF_PROTECTED_SECTORS;
1.11       mrg 		bpart->gpt.ent.ent_lba_end -= RF_PROTECTED_SECTORS;
1.11       mrg 	}
 1.4  jmcneill 	memcpy(bpart->hash, ent->ent_guid, sizeof(bpart->hash));
 1.4  jmcneill 	TAILQ_INSERT_TAIL(&bdev->partitions, bpart, entries);
 1.4  jmcneill
 1.4  jmcneill 	return 0;
 1.4  jmcneill }
 1.4  jmcneill
 1.4  jmcneill static int
 1.4  jmcneill efi_block_find_partitions_gpt(struct efi_block_dev *bdev)
 1.4  jmcneill {
 1.4  jmcneill 	struct gpt_hdr hdr;
 1.4  jmcneill 	struct gpt_ent ent;
 1.4  jmcneill 	EFI_STATUS status;
 1.6  jmcneill 	void *buf, *buf_start;
 1.4  jmcneill 	UINT32 sz, entry;
 1.4  jmcneill
 1.4  jmcneill 	sz = __MAX(sizeof(hdr), bdev->bio->Media->BlockSize);
 1.4  jmcneill 	sz = roundup(sz, bdev->bio->Media->BlockSize);
 1.6  jmcneill 	if ((buf = efi_block_allocate_device_buffer(bdev, sz, &buf_start)) == NULL)
 1.4  jmcneill 		return ENOMEM;
 1.4  jmcneill
 1.6  jmcneill 	status = uefi_call_wrapper(bdev->bio->ReadBlocks, 5, bdev->bio, bdev->media_id,
 1.6  jmcneill 		GPT_HDR_BLKNO, sz, buf_start);
 1.4  jmcneill 	if (EFI_ERROR(status)) {
 1.4  jmcneill 		FreePool(buf);
 1.4  jmcneill 		return EIO;
 1.4  jmcneill 	}
 1.6  jmcneill 	memcpy(&hdr, buf_start, sizeof(hdr));
 1.4  jmcneill 	FreePool(buf);
 1.4  jmcneill
 1.4  jmcneill 	if (memcmp(hdr.hdr_sig, GPT_HDR_SIG, sizeof(hdr.hdr_sig)) != 0)
 1.4  jmcneill 		return ENOENT;
 1.4  jmcneill 	if (le32toh(hdr.hdr_entsz) < sizeof(ent))
 1.4  jmcneill 		return EINVAL;
 1.4  jmcneill
 1.4  jmcneill 	sz = __MAX(le32toh(hdr.hdr_entsz) * le32toh(hdr.hdr_entries), bdev->bio->Media->BlockSize);
 1.4  jmcneill 	sz = roundup(sz, bdev->bio->Media->BlockSize);
 1.6  jmcneill 	if ((buf = efi_block_allocate_device_buffer(bdev, sz, &buf_start)) == NULL)
 1.4  jmcneill 		return ENOMEM;
 1.4  jmcneill
 1.6  jmcneill 	status = uefi_call_wrapper(bdev->bio->ReadBlocks, 5, bdev->bio, bdev->media_id,
 1.6  jmcneill 		le64toh(hdr.hdr_lba_table), sz, buf_start);
 1.4  jmcneill 	if (EFI_ERROR(status)) {
 1.4  jmcneill 		FreePool(buf);
 1.4  jmcneill 		return EIO;
 1.4  jmcneill 	}
 1.4  jmcneill
 1.4  jmcneill 	for (entry = 0; entry < le32toh(hdr.hdr_entries); entry++) {
 1.6  jmcneill 		memcpy(&ent, buf_start + (entry * le32toh(hdr.hdr_entsz)),
 1.6  jmcneill 			sizeof(ent));
 1.4  jmcneill 		efi_block_find_partitions_gpt_entry(bdev, &hdr, &ent, entry);
 1.4  jmcneill 	}
 1.4  jmcneill
 1.4  jmcneill 	FreePool(buf);
 1.4  jmcneill
 1.4  jmcneill 	return 0;
 1.4  jmcneill }
 1.4  jmcneill
 1.1  jmcneill static int
 1.1  jmcneill efi_block_find_partitions(struct efi_block_dev *bdev)
 1.1  jmcneill {
 1.4  jmcneill 	int error;
 1.4  jmcneill
 1.4  jmcneill 	error = efi_block_find_partitions_gpt(bdev);
 1.4  jmcneill 	if (error)
 1.4  jmcneill 		error = efi_block_find_partitions_mbr(bdev);
 1.8  jmcneill 	if (error)
 1.8  jmcneill 		error = efi_block_find_partitions_cd9660(bdev);
 1.4  jmcneill
 1.4  jmcneill 	return error;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill void
 1.1  jmcneill efi_block_probe(void)
 1.1  jmcneill {
 1.1  jmcneill 	struct efi_block_dev *bdev;
 1.4  jmcneill 	struct efi_block_part *bpart;
 1.1  jmcneill 	EFI_BLOCK_IO *bio;
 1.1  jmcneill 	EFI_STATUS status;
 1.1  jmcneill 	uint16_t devindex = 0;
 1.1  jmcneill 	int depth = -1;
 1.1  jmcneill 	int n;
 1.1  jmcneill
 1.1  jmcneill 	status = LibLocateHandle(ByProtocol, &BlockIoProtocol, NULL, &efi_nblock, &efi_block);
 1.1  jmcneill 	if (EFI_ERROR(status))
 1.1  jmcneill 		return;
 1.1  jmcneill
 1.1  jmcneill 	if (efi_bootdp) {
 1.1  jmcneill 		depth = efi_device_path_depth(efi_bootdp, MEDIA_DEVICE_PATH);
 1.1  jmcneill 		if (depth == 0)
 1.1  jmcneill 			depth = 1;
 1.5  jmcneill 		else if (depth == -1)
 1.5  jmcneill 			depth = 2;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	for (n = 0; n < efi_nblock; n++) {
 1.1  jmcneill 		status = uefi_call_wrapper(BS->HandleProtocol, 3, efi_block[n], &BlockIoProtocol, (void **)&bio);
 1.1  jmcneill 		if (EFI_ERROR(status) || !bio->Media->MediaPresent)
 1.1  jmcneill 			continue;
 1.1  jmcneill
 1.1  jmcneill 		if (bio->Media->LogicalPartition)
 1.1  jmcneill 			continue;
 1.1  jmcneill
 1.1  jmcneill 		bdev = alloc(sizeof(*bdev));
 1.1  jmcneill 		bdev->index = devindex++;
 1.1  jmcneill 		bdev->bio = bio;
 1.1  jmcneill 		bdev->media_id = bio->Media->MediaId;
 1.1  jmcneill 		bdev->path = DevicePathFromHandle(efi_block[n]);
 1.1  jmcneill 		TAILQ_INIT(&bdev->partitions);
 1.1  jmcneill 		TAILQ_INSERT_TAIL(&efi_block_devs, bdev, entries);
 1.1  jmcneill
 1.4  jmcneill 		efi_block_find_partitions(bdev);
 1.4  jmcneill
 1.1  jmcneill 		if (depth > 0 && efi_device_path_ncmp(efi_bootdp, DevicePathFromHandle(efi_block[n]), depth) == 0) {
 1.4  jmcneill 			TAILQ_FOREACH(bpart, &bdev->partitions, entries) {
 1.4  jmcneill 				uint8_t fstype = FS_UNUSED;
 1.4  jmcneill 				switch (bpart->type) {
 1.4  jmcneill 				case EFI_BLOCK_PART_DISKLABEL:
 1.4  jmcneill 					fstype = bpart->disklabel.part.p_fstype;
 1.4  jmcneill 					break;
 1.4  jmcneill 				case EFI_BLOCK_PART_GPT:
 1.4  jmcneill 					fstype = bpart->gpt.fstype;
 1.4  jmcneill 					break;
 1.8  jmcneill 				case EFI_BLOCK_PART_CD9660:
 1.8  jmcneill 					fstype = FS_ISO9660;
 1.8  jmcneill 					break;
 1.4  jmcneill 				}
1.11       mrg 				if (fstype == FS_BSDFFS || fstype == FS_ISO9660 || fstype == FS_RAID) {
 1.4  jmcneill 					char devname[9];
 1.4  jmcneill 					snprintf(devname, sizeof(devname), "hd%u%c", bdev->index, bpart->index + 'a');
 1.4  jmcneill 					set_default_device(devname);
 1.8  jmcneill 					set_default_fstype(fstype);
 1.4  jmcneill 					break;
 1.4  jmcneill 				}
 1.4  jmcneill 			}
 1.1  jmcneill 		}
 1.4  jmcneill 	}
 1.4  jmcneill }
 1.1  jmcneill
 1.4  jmcneill static void
 1.4  jmcneill print_guid(const uint8_t *guid)
 1.4  jmcneill {
 1.4  jmcneill 	const int index[] = { 3, 2, 1, 0, 5, 4, 7, 6, 8, 9, 10, 11, 12, 13, 14, 15 };
 1.4  jmcneill 	int i;
 1.4  jmcneill
 1.4  jmcneill 	for (i = 0; i < 16; i++) {
 1.4  jmcneill 		printf("%02x", guid[index[i]]);
 1.4  jmcneill 		if (i == 3 || i == 5 || i == 7 || i == 9)
 1.4  jmcneill 			printf("-");
 1.1  jmcneill 	}
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill void
 1.1  jmcneill efi_block_show(void)
 1.1  jmcneill {
 1.1  jmcneill 	struct efi_block_dev *bdev;
 1.1  jmcneill 	struct efi_block_part *bpart;
 1.1  jmcneill 	uint64_t size;
 1.1  jmcneill 	CHAR16 *path;
 1.1  jmcneill
 1.1  jmcneill 	TAILQ_FOREACH(bdev, &efi_block_devs, entries) {
 1.1  jmcneill 		printf("hd%u (", bdev->index);
 1.1  jmcneill
 1.1  jmcneill 		/* Size in MB */
 1.1  jmcneill 		size = ((bdev->bio->Media->LastBlock + 1) * bdev->bio->Media->BlockSize) / (1024 * 1024);
 1.1  jmcneill 		if (size >= 10000)
 1.1  jmcneill 			printf("%"PRIu64" GB", size / 1024);
 1.1  jmcneill 		else
 1.1  jmcneill 			printf("%"PRIu64" MB", size);
 1.1  jmcneill 		printf("): ");
 1.1  jmcneill
 1.1  jmcneill 		path = DevicePathToStr(bdev->path);
 1.1  jmcneill 		Print(L"%s", path);
 1.1  jmcneill 		FreePool(path);
 1.1  jmcneill
 1.1  jmcneill 		printf("\n");
 1.1  jmcneill
 1.1  jmcneill 		TAILQ_FOREACH(bpart, &bdev->partitions, entries) {
 1.1  jmcneill 			switch (bpart->type) {
 1.1  jmcneill 			case EFI_BLOCK_PART_DISKLABEL:
 1.1  jmcneill 				printf("  hd%u%c (", bdev->index, bpart->index + 'a');
 1.1  jmcneill
 1.1  jmcneill 				/* Size in MB */
 1.1  jmcneill 				size = ((uint64_t)bpart->disklabel.secsize * bpart->disklabel.part.p_size) / (1024 * 1024);
 1.1  jmcneill 				if (size >= 10000)
 1.1  jmcneill 					printf("%"PRIu64" GB", size / 1024);
 1.1  jmcneill 				else
 1.1  jmcneill 					printf("%"PRIu64" MB", size);
 1.1  jmcneill 				printf("): ");
 1.1  jmcneill
 1.1  jmcneill 				printf("%s\n", fstypenames[bpart->disklabel.part.p_fstype]);
 1.1  jmcneill 				break;
 1.4  jmcneill 			case EFI_BLOCK_PART_GPT:
 1.4  jmcneill 				printf("  hd%u%c ", bdev->index, bpart->index + 'a');
 1.4  jmcneill
 1.4  jmcneill 				if (bpart->gpt.ent.ent_name[0] == 0x0000) {
 1.4  jmcneill 					printf("\"");
 1.4  jmcneill 					print_guid(bpart->gpt.ent.ent_guid);
 1.4  jmcneill 					printf("\"");
 1.4  jmcneill 				} else {
 1.4  jmcneill 					Print(L"\"%s\"", bpart->gpt.ent.ent_name);
 1.4  jmcneill 				}
 1.4  jmcneill
 1.4  jmcneill 				/* Size in MB */
 1.4  jmcneill 				size = (le64toh(bpart->gpt.ent.ent_lba_end) - le64toh(bpart->gpt.ent.ent_lba_start)) * bdev->bio->Media->BlockSize;
 1.4  jmcneill 				size /= (1024 * 1024);
 1.4  jmcneill 				if (size >= 10000)
 1.4  jmcneill 					printf(" (%"PRIu64" GB): ", size / 1024);
 1.4  jmcneill 				else
 1.4  jmcneill 					printf(" (%"PRIu64" MB): ", size);
 1.4  jmcneill
 1.4  jmcneill 				printf("%s\n", fstypenames[bpart->gpt.fstype]);
 1.4  jmcneill 				break;
 1.8  jmcneill 			case EFI_BLOCK_PART_CD9660:
 1.8  jmcneill 				printf("  hd%u%c %s\n", bdev->index, bpart->index + 'a', fstypenames[FS_ISO9660]);
 1.8  jmcneill 				break;
 1.1  jmcneill 			default:
 1.1  jmcneill 				break;
 1.1  jmcneill 			}
 1.1  jmcneill 		}
 1.1  jmcneill 	}
 1.1  jmcneill }
 1.1  jmcneill
 1.2  jmcneill struct efi_block_part *
 1.2  jmcneill efi_block_boot_part(void)
 1.2  jmcneill {
 1.2  jmcneill 	return efi_block_booted;
 1.2  jmcneill }
 1.2  jmcneill
 1.1  jmcneill int
 1.1  jmcneill efi_block_open(struct open_file *f, ...)
 1.1  jmcneill {
 1.1  jmcneill 	struct efi_block_part *bpart;
 1.1  jmcneill 	const char *fname;
 1.1  jmcneill 	char **file;
 1.1  jmcneill 	char *path;
 1.1  jmcneill 	va_list ap;
 1.1  jmcneill 	int rv, n;
 1.1  jmcneill
 1.1  jmcneill 	va_start(ap, f);
 1.1  jmcneill 	fname = va_arg(ap, const char *);
 1.1  jmcneill 	file = va_arg(ap, char **);
 1.1  jmcneill 	va_end(ap);
 1.1  jmcneill
 1.1  jmcneill 	rv = efi_block_parse(fname, &bpart, &path);
 1.1  jmcneill 	if (rv != 0)
 1.1  jmcneill 		return rv;
 1.1  jmcneill
 1.1  jmcneill 	for (n = 0; n < ndevs; n++)
 1.1  jmcneill 		if (strcmp(DEV_NAME(&devsw[n]), "efiblock") == 0) {
 1.1  jmcneill 			f->f_dev = &devsw[n];
 1.1  jmcneill 			break;
 1.1  jmcneill 		}
 1.1  jmcneill 	if (n == ndevs)
 1.1  jmcneill 		return ENXIO;
 1.1  jmcneill
 1.1  jmcneill 	f->f_devdata = bpart;
 1.1  jmcneill
 1.1  jmcneill 	*file = path;
 1.1  jmcneill
 1.2  jmcneill 	efi_block_booted = bpart;
 1.2  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill int
 1.1  jmcneill efi_block_close(struct open_file *f)
 1.1  jmcneill {
 1.1  jmcneill 	return 0;
 1.1  jmcneill }
 1.1  jmcneill
 1.1  jmcneill int
 1.1  jmcneill efi_block_strategy(void *devdata, int rw, daddr_t dblk, size_t size, void *buf, size_t *rsize)
 1.1  jmcneill {
 1.1  jmcneill 	struct efi_block_part *bpart = devdata;
 1.1  jmcneill 	EFI_STATUS status;
 1.6  jmcneill 	void *allocated_buf, *aligned_buf;
 1.1  jmcneill
 1.1  jmcneill 	if (rw != F_READ)
 1.1  jmcneill 		return EROFS;
 1.1  jmcneill
1.12  jmcneill 	efi_set_watchdog(EFI_BLOCK_TIMEOUT, EFI_BLOCK_TIMEOUT_CODE);
1.12  jmcneill
 1.1  jmcneill 	switch (bpart->type) {
 1.1  jmcneill 	case EFI_BLOCK_PART_DISKLABEL:
 1.1  jmcneill 		if (bpart->bdev->bio->Media->BlockSize != bpart->disklabel.secsize) {
 1.1  jmcneill 			printf("%s: unsupported block size %d (expected %d)\n", __func__,
 1.1  jmcneill 			    bpart->bdev->bio->Media->BlockSize, bpart->disklabel.secsize);
 1.1  jmcneill 			return EIO;
 1.1  jmcneill 		}
 1.1  jmcneill 		dblk += bpart->disklabel.part.p_offset;
 1.1  jmcneill 		break;
 1.4  jmcneill 	case EFI_BLOCK_PART_GPT:
 1.4  jmcneill 		if (bpart->bdev->bio->Media->BlockSize != DEV_BSIZE) {
 1.4  jmcneill 			printf("%s: unsupported block size %d (expected %d)\n", __func__,
 1.4  jmcneill 			    bpart->bdev->bio->Media->BlockSize, DEV_BSIZE);
 1.4  jmcneill 			return EIO;
 1.4  jmcneill 		}
 1.4  jmcneill 		dblk += le64toh(bpart->gpt.ent.ent_lba_start);
 1.4  jmcneill 		break;
 1.8  jmcneill 	case EFI_BLOCK_PART_CD9660:
1.10  jmcneill 		dblk *= ISO_DEFAULT_BLOCK_SIZE / bpart->bdev->bio->Media->BlockSize;
 1.8  jmcneill 		break;
 1.1  jmcneill 	default:
 1.1  jmcneill 		return EINVAL;
 1.1  jmcneill 	}
 1.1  jmcneill
 1.6  jmcneill 	if ((bpart->bdev->bio->Media->IoAlign <= 1) ||
 1.6  jmcneill 		((intptr_t)buf & (bpart->bdev->bio->Media->IoAlign - 1)) == 0) {
 1.6  jmcneill 		allocated_buf = NULL;
 1.6  jmcneill 		aligned_buf = buf;
 1.6  jmcneill 	} else if ((allocated_buf = efi_block_allocate_device_buffer(bpart->bdev,
1.10  jmcneill 		size, &aligned_buf)) == NULL) {
 1.6  jmcneill 		return ENOMEM;
1.10  jmcneill 	}
 1.6  jmcneill
 1.6  jmcneill 	status = uefi_call_wrapper(bpart->bdev->bio->ReadBlocks, 5,
 1.6  jmcneill 		bpart->bdev->bio, bpart->bdev->media_id, dblk, size, aligned_buf);
 1.6  jmcneill 	if (EFI_ERROR(status)) {
 1.6  jmcneill 		if (allocated_buf != NULL)
 1.6  jmcneill 			FreePool(allocated_buf);
 1.1  jmcneill 		return EIO;
 1.6  jmcneill 	}
 1.6  jmcneill 	if (allocated_buf != NULL) {
 1.6  jmcneill 		memcpy(buf, aligned_buf, size);
 1.6  jmcneill 		FreePool(allocated_buf);
 1.6  jmcneill 	}
 1.1  jmcneill
 1.1  jmcneill 	*rsize = size;
 1.1  jmcneill
 1.1  jmcneill 	return 0;
 1.1  jmcneill }