usr.sbin/sysinst/gpt.c

1.6.2.3  msaitoh /*	$NetBSD: gpt.c,v 1.6.2.3 2019/08/08 05:51:43 msaitoh Exp $	*/
    1.1   martin
    1.1   martin /*
    1.1   martin  * Copyright 2018 The NetBSD Foundation, Inc.
    1.1   martin  * All rights reserved.
    1.1   martin  *
    1.1   martin  * Redistribution and use in source and binary forms, with or without
    1.1   martin  * modification, are permitted provided that the following conditions
    1.1   martin  * are met:
    1.1   martin  * 1. Redistributions of source code must retain the above copyright
    1.1   martin  *    notice, this list of conditions and the following disclaimer.
    1.1   martin  * 2. Redistributions in binary form must reproduce the above copyright
    1.1   martin  *    notice, this list of conditions and the following disclaimer in the
    1.1   martin  *    documentation and/or other materials provided with the distribution.
    1.1   martin  *
    1.1   martin  * THIS SOFTWARE IS PROVIDED BY PIERMONT INFORMATION SYSTEMS INC. ``AS IS''
    1.1   martin  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
    1.1   martin  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
    1.1   martin  * ARE DISCLAIMED. IN NO EVENT SHALL PIERMONT INFORMATION SYSTEMS INC. BE
    1.1   martin  * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
    1.1   martin  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
    1.1   martin  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
    1.1   martin  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
    1.1   martin  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
    1.1   martin  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
    1.1   martin  * THE POSSIBILITY OF SUCH DAMAGE.
    1.1   martin  *
    1.1   martin  */
    1.1   martin
    1.1   martin #include "defs.h"
    1.1   martin #include "mbr.h"
    1.1   martin #include "md.h"
    1.1   martin #include "gpt_uuid.h"
    1.1   martin #include <assert.h>
    1.1   martin #include <paths.h>
    1.1   martin #include <sys/param.h>
    1.1   martin #include <sys/ioctl.h>
    1.1   martin #include <util.h>
    1.1   martin
    1.1   martin bool	gpt_parts_check(void);	/* check for needed binaries */
    1.1   martin
    1.1   martin
    1.1   martin /*************** GPT ************************************************/
    1.1   martin /* a GPT based disk_partitions interface */
    1.1   martin
    1.1   martin #define GUID_STR_LEN	40
    1.1   martin #define	GPT_PTYPE_MAX	32	/* should be >  gpt type -l | wc -l */
    1.1   martin #define	GPT_DEV_LEN	16	/* dkNN */
    1.1   martin
    1.1   martin #define	GPT_PARTS_PER_SEC	4	/* a 512 byte sector hols 4 entries */
    1.1   martin #define	GPT_DEFAULT_MAX_PARTS	128
    1.1   martin
    1.1   martin /* a usable label will be short, so we can get away with an arbitrary limit */
    1.1   martin #define	GPT_LABEL_LEN		96
    1.1   martin
    1.1   martin #define	GPT_ATTR_BIOSBOOT	1
    1.1   martin #define	GPT_ATTR_BOOTME		2
    1.1   martin #define	GPT_ATTR_BOOTONCE	4
    1.1   martin #define	GPT_ATTR_BOOTFAILED	8
    1.1   martin #define	GPT_ATTR_NOBLOCKIO	16
    1.1   martin #define	GPT_ATTR_REQUIRED	32
    1.1   martin
    1.1   martin /* when we don't care for BIOS or UEFI boot, use the combined boot flags */
    1.1   martin #define	GPT_ATTR_BOOT	(GPT_ATTR_BIOSBOOT|GPT_ATTR_BOOTME)
    1.1   martin
    1.1   martin struct gpt_attr_desc {
    1.1   martin 	const char *name;
    1.1   martin 	uint flag;
    1.1   martin };
    1.1   martin static const struct gpt_attr_desc gpt_avail_attrs[] = {
    1.1   martin 	{ "biosboot", GPT_ATTR_BIOSBOOT },
    1.1   martin 	{ "bootme", GPT_ATTR_BOOTME },
    1.1   martin 	{ "bootonce", GPT_ATTR_BOOTONCE },
    1.1   martin 	{ "bootfailed", GPT_ATTR_BOOTFAILED },
    1.1   martin 	{ "noblockio", GPT_ATTR_NOBLOCKIO },
    1.1   martin 	{ "required", GPT_ATTR_REQUIRED },
    1.1   martin 	{ NULL, 0 }
    1.1   martin };
    1.1   martin
    1.1   martin struct gpt_ptype_desc {
    1.1   martin 	struct part_type_desc gent;
    1.1   martin 	char tid[GUID_STR_LEN];
    1.1   martin 	uint fsflags, default_fs_type;
    1.1   martin };
    1.1   martin
    1.1   martin static const
    1.1   martin struct {
    1.1   martin 	const char *name;
    1.1   martin 	uint fstype;
    1.1   martin 	enum part_type ptype;
    1.1   martin 	uint fsflags;
    1.1   martin } gpt_fs_types[] = {
    1.1   martin 	{ .name = "ffs",	.fstype = FS_BSDFFS,	.ptype = PT_root,
    1.1   martin 	  .fsflags = GLM_LIKELY_FFS },
    1.1   martin 	{ .name = "swap",	.fstype = FS_SWAP,	.ptype = PT_swap },
    1.1   martin 	{ .name = "windows",	.fstype = FS_MSDOS,	.ptype = PT_FAT,
    1.1   martin 	  .fsflags = GLM_MAYBE_FAT32|GLM_MAYBE_NTFS },
    1.1   martin 	{ .name = "windows",	.fstype = FS_NTFS,	.ptype = PT_FAT,
    1.1   martin 	  .fsflags = GLM_MAYBE_FAT32|GLM_MAYBE_NTFS },
    1.1   martin 	{ .name = "efi",	.fstype = FS_MSDOS,	.ptype = PT_EFI_SYSTEM,
    1.1   martin 	  .fsflags = GLM_MAYBE_FAT32 },
    1.1   martin 	{ .name = "bios",	.fstype = FS_MSDOS,	.ptype = PT_FAT,
    1.1   martin 	  .fsflags = GLM_MAYBE_FAT32 },
    1.1   martin 	{ .name = "lfs",	.fstype = FS_BSDLFS,	.ptype = PT_root },
    1.1   martin 	{ .name = "linux-data",	.fstype = FS_EX2FS,	.ptype = PT_root },
    1.1   martin 	{ .name = "apple",	.fstype = FS_HFS,	.ptype = PT_unknown },
    1.1   martin 	{ .name = "ccd",	.fstype = FS_CCD,	.ptype = PT_unknown },
    1.1   martin 	{ .name = "cgd",	.fstype = FS_CGD,	.ptype = PT_unknown },
    1.1   martin 	{ .name = "raid",	.fstype = FS_RAID,	.ptype = PT_root },
    1.1   martin 	{ .name = "vmcore",	.fstype = FS_VMKCORE,	.ptype = PT_unknown },
    1.1   martin 	{ .name = "vmfs",	.fstype = FS_VMFS,	.ptype = PT_unknown },
    1.1   martin 	{ .name = "vmresered",	.fstype = FS_VMWRESV,	.ptype = PT_unknown }
    1.1   martin };
    1.1   martin
    1.1   martin static size_t gpt_ptype_cnt;
    1.1   martin static struct gpt_ptype_desc gpt_ptype_descs[GPT_PTYPE_MAX];
    1.1   martin
    1.1   martin /* similar to struct gpt_ent, but matching our needs */
    1.1   martin struct gpt_part_entry {
    1.1   martin 	const struct gpt_ptype_desc *gp_type;
    1.1   martin 	char gp_id[GUID_STR_LEN];	/* partition guid as string */
    1.1   martin 	daddr_t gp_start, gp_size;
    1.1   martin 	uint gp_attr;			/* various attribute bits */
    1.1   martin 	char gp_label[GPT_LABEL_LEN];	/* user defined label */
    1.1   martin 	char gp_dev_name[GPT_DEV_LEN];	/* name of wedge */
    1.1   martin 	const char *last_mounted;	/* last mounted if known */
    1.1   martin 	uint fs_type, fs_sub_type;	/* FS_* and maybe sub type */
    1.1   martin 	uint gp_flags;
    1.1   martin #define	GPEF_ON_DISK	1		/* This entry exists on-disk */
    1.1   martin #define	GPEF_MODIFIED	2		/* this entry has been changed */
    1.1   martin #define	GPEF_WEDGE	4		/* wedge for this exists */
    1.1   martin #define	GPEF_RESIZED	8		/* size has changed */
    1.1   martin 	struct gpt_part_entry *gp_next;
    1.1   martin };
    1.1   martin
    1.1   martin static const struct gpt_ptype_desc *gpt_find_native_type(
    1.1   martin     const struct part_type_desc *gent);
    1.1   martin static const struct gpt_ptype_desc *gpt_find_guid_type(const char*);
    1.1   martin static bool
    1.1   martin gpt_info_to_part(struct gpt_part_entry *p, const struct disk_part_info *info,
    1.1   martin     const char **err_msg);
    1.1   martin
    1.1   martin const struct disk_partitioning_scheme gpt_parts;
    1.1   martin struct gpt_disk_partitions {
    1.1   martin 	struct disk_partitions dp;
    1.1   martin 	/*
    1.1   martin 	 * We keep a list of our current valid partitions, pointed
    1.1   martin 	 * to by "partitions".
    1.1   martin 	 * dp.num_part is the number of entries in "partitions".
    1.1   martin 	 * When partitions that have a representation on disk already
    1.1   martin 	 * are deleted, we move them to the "obsolete" list so we
    1.1   martin 	 * can issue the proper commands to remove it when writing back.
    1.1   martin 	 */
    1.1   martin 	struct gpt_part_entry *partitions,	/* current partitions */
    1.1   martin 	    *obsolete;				/* deleted partitions */
    1.1   martin 	size_t max_num_parts;			/* how many entries max? */
    1.1   martin 	size_t prologue, epilogue;		/* number of sectors res. */
    1.1   martin 	bool has_gpt;	/* disk already has a GPT */
    1.1   martin };
    1.1   martin
    1.1   martin /*
    1.1   martin  * Init global variables from MD details
    1.1   martin  */
    1.1   martin static void
    1.1   martin gpt_md_init(bool is_boot_disk, size_t *max_parts, size_t *head, size_t *tail)
    1.1   martin {
    1.1   martin 	size_t num;
    1.1   martin
    1.1   martin 	if (is_boot_disk) {
    1.1   martin #ifdef MD_GPT_INITIAL_SIZE
    1.1   martin #if MD_GPT_INITIAL_SIZE < 2*512
    1.1   martin #error	impossible small GPT prologue
    1.1   martin #endif
    1.1   martin 		num = ((MD_GPT_INITIAL_SIZE-(2*512))/512)*GPT_PARTS_PER_SEC;
    1.1   martin #else
    1.1   martin 		num = GPT_DEFAULT_MAX_PARTS;
    1.1   martin #endif
    1.1   martin 	} else {
    1.1   martin 		num = GPT_DEFAULT_MAX_PARTS;
    1.1   martin 	}
    1.1   martin 	*max_parts = num;
    1.1   martin 	*head = 2 + num/GPT_PARTS_PER_SEC;
    1.1   martin 	*tail = 1 + num/GPT_PARTS_PER_SEC;
    1.1   martin }
    1.1   martin
    1.1   martin /*
    1.1   martin  * Parse a part of "gpt show" output into a struct gpt_part_entry.
    1.1   martin  * Output is from "show -a" format if details = false, otherwise
    1.1   martin  * from details for a specific partition (show -i or show -b)
    1.1   martin  */
    1.1   martin static void
    1.1   martin gpt_add_info(struct gpt_part_entry *part, const char *tag, char *val,
    1.1   martin     bool details)
    1.1   martin {
    1.1   martin 	char *s, *e;
    1.1   martin
    1.1   martin 	if (details && strcmp(tag, "Start:") == 0) {
    1.1   martin 		part->gp_start = strtouq(val, NULL, 10);
    1.1   martin 	} else if (details && strcmp(tag, "Size:") == 0) {
    1.1   martin 		part->gp_size = strtouq(val, NULL, 10);
    1.1   martin 	} else if (details && strcmp(tag, "Type:") == 0) {
    1.1   martin 		s = strchr(val, '(');
    1.1   martin 		if (!s)
    1.1   martin 			return;
    1.1   martin 		e = strchr(s, ')');
    1.1   martin 		if (!e)
    1.1   martin 			return;
    1.1   martin 		*e = 0;
    1.1   martin 		part->gp_type = gpt_find_guid_type(s+1);
    1.1   martin 	} else if (strcmp(tag, "TypeID:") == 0) {
    1.1   martin 		part->gp_type = gpt_find_guid_type(val);
    1.1   martin 	} else if (strcmp(tag, "GUID:") == 0) {
    1.1   martin 		strlcpy(part->gp_id, val, sizeof(part->gp_id));
    1.1   martin 	} else if (strcmp(tag, "Label:") == 0) {
1.6.2.1  msaitoh 		strlcpy(part->gp_label, val, sizeof(part->gp_label));
    1.1   martin 	} else if (strcmp(tag, "Attributes:") == 0) {
    1.1   martin 		char *n;
    1.1   martin
    1.1   martin 		while ((n = strsep(&val, ", ")) != NULL) {
    1.1   martin 			if (*n == 0)
    1.1   martin 				continue;
    1.1   martin 			for (const struct gpt_attr_desc *p = gpt_avail_attrs;
    1.1   martin 			    p->name != NULL; p++) {
    1.1   martin 				if (strcmp(p->name, n) == 0)
    1.1   martin 					part->gp_attr |= p->flag;
    1.1   martin 			}
    1.1   martin 		}
    1.1   martin 	}
    1.1   martin }
    1.1   martin
1.6.2.2  msaitoh /*
1.6.2.2  msaitoh  * Find the partition matching this wedge info and record that we
1.6.2.2  msaitoh  * have a wedge already.
1.6.2.2  msaitoh  */
1.6.2.2  msaitoh static void
1.6.2.2  msaitoh update_part_from_wedge_info(struct gpt_disk_partitions *parts,
1.6.2.2  msaitoh     const struct dkwedge_info *dkw)
1.6.2.2  msaitoh {
1.6.2.2  msaitoh 	for (struct gpt_part_entry *p = parts->partitions; p != NULL;
1.6.2.2  msaitoh 	    p = p->gp_next) {
1.6.2.2  msaitoh 		if (p->gp_start != dkw->dkw_offset ||
1.6.2.2  msaitoh 		    (uint64_t)p->gp_size != dkw->dkw_size)
1.6.2.2  msaitoh 			continue;
1.6.2.2  msaitoh 		p->gp_flags |= GPEF_WEDGE;
1.6.2.2  msaitoh 		strlcpy(p->gp_dev_name, dkw->dkw_devname,
1.6.2.2  msaitoh 		    sizeof p->gp_dev_name);
1.6.2.2  msaitoh 		return;
1.6.2.2  msaitoh 	}
1.6.2.2  msaitoh }
1.6.2.2  msaitoh
    1.1   martin static struct disk_partitions *
    1.1   martin gpt_read_from_disk(const char *dev, daddr_t start, daddr_t len)
    1.1   martin {
    1.1   martin 	char diskpath[MAXPATHLEN];
    1.1   martin 	int fd;
1.6.2.2  msaitoh 	struct dkwedge_info *dkw;
1.6.2.2  msaitoh 	struct dkwedge_list dkwl;
1.6.2.2  msaitoh 	size_t bufsize, dk;
    1.1   martin
    1.1   martin 	assert(start == 0);
    1.1   martin 	assert(have_gpt);
    1.1   martin
    1.1   martin 	if (run_program(RUN_SILENT | RUN_ERROR_OK,
    1.1   martin 	    "gpt -rq header %s", dev) != 0)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	/* read the partitions */
    1.1   martin 	int i;
    1.1   martin 	unsigned int p_index;
    1.1   martin 	daddr_t p_start = 0, p_size = 0, avail_start = 0, avail_size = 0,
    1.1   martin 	    disk_size = 0;
    1.1   martin 	char *textbuf, *t, *tt, p_type[STRSIZE];
    1.1   martin 	static const char regpart_prefix[] = "GPT part - ";
    1.1   martin 	struct gpt_disk_partitions *parts;
    1.1   martin 	struct gpt_part_entry *last = NULL, *add_to = NULL;
    1.1   martin
    1.1   martin 	if (collect(T_OUTPUT, &textbuf, "gpt -r show -a %s 2>/dev/null", dev)
    1.1   martin 	    < 1)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	/* parse output and create our list */
    1.1   martin 	parts = calloc(1, sizeof(*parts));
    1.1   martin 	if (parts == NULL)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	(void)strtok(textbuf, "\n"); /* ignore first line */
    1.1   martin 	while ((t = strtok(NULL, "\n")) != NULL) {
    1.1   martin 		i = 0; p_start = 0; p_size = 0; p_index = 0;
    1.1   martin 		p_type[0] = 0;
    1.1   martin 		while ((tt = strsep(&t, " \t")) != NULL) {
    1.1   martin 			if (strlen(tt) == 0)
    1.1   martin 				continue;
    1.1   martin 			if (i == 0) {
    1.1   martin 				if (add_to != NULL)
    1.1   martin 					gpt_add_info(add_to, tt, t, false);
    1.1   martin 				p_start = strtouq(tt, NULL, 10);
    1.1   martin 				if (p_start == 0 && add_to != NULL)
    1.1   martin 					break;
    1.1   martin 				else
    1.1   martin 					add_to = NULL;
    1.1   martin 			}
    1.1   martin 			if (i == 1)
    1.1   martin 				p_size = strtouq(tt, NULL, 10);
    1.1   martin 			if (i == 2)
    1.1   martin 				p_index = strtouq(tt, NULL, 10);
    1.1   martin 			if (i > 2 || (i == 2 && p_index == 0)) {
    1.1   martin 				if (p_type[0])
    1.1   martin 					strlcat(p_type, " ", STRSIZE);
    1.1   martin 				strlcat(p_type, tt, STRSIZE);
    1.1   martin 			}
    1.1   martin 			i++;
    1.1   martin 		}
    1.1   martin
    1.1   martin 		if (p_start == 0 || p_size == 0)
    1.1   martin 			continue;
    1.1   martin 		else if (strcmp(p_type, "Pri GPT table") == 0) {
    1.1   martin 			avail_start = p_start + p_size;
    1.1   martin 			parts->prologue = avail_start;
    1.1   martin 			parts->epilogue = p_size + 1;
    1.1   martin 			parts->max_num_parts = p_size * GPT_PARTS_PER_SEC;
    1.1   martin 		} else if (strcmp(p_type, "Sec GPT table") == 0)
    1.1   martin 			avail_size = p_start - avail_start;
    1.1   martin 		else if(strcmp(p_type, "Sec GPT header") == 0)
    1.1   martin 			disk_size = p_start + p_size;
    1.1   martin 		else if (p_index == 0 && strlen(p_type) > 0)
    1.1   martin 			/* Utilitary entry (PMBR, etc) */
    1.1   martin 			continue;
    1.1   martin 		else if (p_index == 0) {
    1.1   martin 			/* Free space */
    1.1   martin 			continue;
    1.1   martin 		} else {
    1.1   martin 			/* Usual partition */
    1.1   martin 			tt = p_type;
    1.1   martin 			if (strncmp(tt, regpart_prefix,
    1.1   martin 			    strlen(regpart_prefix)) == 0)
    1.1   martin 				tt += strlen(regpart_prefix);
    1.1   martin
    1.1   martin 			/* Add to our linked list */
    1.1   martin 			struct gpt_part_entry *np = calloc(1, sizeof(*np));
    1.1   martin 			if (np == NULL)
    1.1   martin 				break;
    1.1   martin
    1.1   martin 			strlcpy(np->gp_label, tt, sizeof(np->gp_label));
    1.1   martin 			np->gp_start = p_start;
    1.1   martin 			np->gp_size = p_size;
    1.1   martin 			np->gp_flags |= GPEF_ON_DISK;
    1.1   martin
    1.1   martin 			if (last == NULL)
    1.1   martin 				parts->partitions = np;
    1.1   martin 			else
    1.1   martin 				last->gp_next = np;
    1.1   martin 			last = np;
    1.1   martin 			add_to = np;
    1.1   martin 			parts->dp.num_part++;
    1.1   martin 		}
    1.1   martin 	}
    1.1   martin 	free(textbuf);
    1.1   martin
    1.2   martin 	/* If the GPT was not complete (e.g. truncated image), barf */
    1.2   martin 	if (disk_size <= 0) {
    1.2   martin 		free(parts);
    1.2   martin 		return NULL;
    1.2   martin 	}
    1.2   martin
    1.1   martin 	parts->dp.pscheme = &gpt_parts;
    1.1   martin 	parts->dp.disk = dev;
    1.1   martin 	parts->dp.disk_start = start;
    1.1   martin 	parts->dp.disk_size = disk_size;
    1.1   martin 	parts->dp.free_space = avail_size;
    1.1   martin 	parts->has_gpt = true;
    1.1   martin
    1.1   martin 	fd = opendisk(parts->dp.disk, O_RDONLY, diskpath, sizeof(diskpath), 0);
    1.1   martin 	for (struct gpt_part_entry *p = parts->partitions; p != NULL;
    1.1   martin 	    p = p->gp_next) {
    1.1   martin #ifdef DEFAULT_UFS2
    1.1   martin 		bool fs_is_default = false;
    1.1   martin #endif
    1.1   martin
    1.5   martin 		if (p->gp_type != NULL) {
    1.5   martin
    1.5   martin 			if (p->gp_type->fsflags != 0) {
    1.5   martin 				const char *lm = get_last_mounted(fd,
    1.5   martin 				    p->gp_start, &p->fs_type,
    1.5   martin 				    &p->fs_sub_type, p->gp_type->fsflags);
    1.5   martin 				if (lm != NULL && *lm != 0) {
    1.5   martin 					char *path = strdup(lm);
    1.5   martin 					canonicalize_last_mounted(path);
    1.5   martin 					p->last_mounted = path;
    1.5   martin 				} else {
    1.5   martin 					p->fs_type = p->gp_type->
    1.5   martin 					    default_fs_type;
    1.5   martin #ifdef DEFAULT_UFS2
    1.5   martin 					fs_is_default = true;
    1.5   martin #endif
    1.5   martin 				}
    1.1   martin 			} else {
    1.1   martin 				p->fs_type = p->gp_type->default_fs_type;
    1.1   martin #ifdef DEFAULT_UFS2
    1.1   martin 				fs_is_default = true;
    1.1   martin #endif
    1.1   martin 			}
    1.1   martin #ifdef DEFAULT_UFS2
    1.5   martin 			if (fs_is_default && p->fs_type == FS_BSDFFS)
    1.5   martin 				p->fs_sub_type = 2;
    1.1   martin #endif
    1.1   martin 		}
    1.1   martin
    1.1   martin 		parts->dp.free_space -= p->gp_size;
    1.1   martin 	}
1.6.2.2  msaitoh
1.6.2.2  msaitoh 	/*
1.6.2.2  msaitoh 	 * Check if we have any (matching/auto-configured) wedges already
1.6.2.2  msaitoh 	 */
1.6.2.2  msaitoh 	dkw = NULL;
1.6.2.2  msaitoh 	dkwl.dkwl_buf = dkw;
1.6.2.2  msaitoh 	dkwl.dkwl_bufsize = 0;
1.6.2.2  msaitoh 	if (ioctl(fd, DIOCLWEDGES, &dkwl) == 0) {
1.6.2.2  msaitoh 		/* do not even try to deal with any races at this point */
1.6.2.2  msaitoh 		bufsize = dkwl.dkwl_nwedges * sizeof(*dkw);
1.6.2.2  msaitoh 		dkw = malloc(bufsize);
1.6.2.2  msaitoh 		dkwl.dkwl_buf = dkw;
1.6.2.2  msaitoh 		dkwl.dkwl_bufsize = bufsize;
1.6.2.2  msaitoh 		if (dkw != NULL && ioctl(fd, DIOCLWEDGES, &dkwl) == 0) {
1.6.2.2  msaitoh 			for (dk = 0; dk < dkwl.dkwl_ncopied; dk++)
1.6.2.2  msaitoh 				update_part_from_wedge_info(parts, &dkw[dk]);
1.6.2.2  msaitoh 		}
1.6.2.2  msaitoh 		free(dkw);
1.6.2.2  msaitoh 	}
1.6.2.2  msaitoh
    1.1   martin 	close(fd);
    1.1   martin
    1.1   martin 	return &parts->dp;
    1.1   martin }
    1.1   martin
    1.1   martin static struct disk_partitions *
    1.1   martin gpt_create_new(const char *disk, daddr_t start, daddr_t len, daddr_t total,
    1.1   martin     bool is_boot_drive)
    1.1   martin {
    1.1   martin 	struct gpt_disk_partitions *parts;
    1.1   martin
    1.1   martin 	if (start != 0) {
    1.1   martin 		assert(0);
    1.1   martin 		return NULL;
    1.1   martin 	}
    1.1   martin
    1.3   martin 	parts = calloc(1, sizeof(*parts));
    1.1   martin 	if (!parts)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	parts->dp.pscheme = &gpt_parts;
    1.1   martin 	parts->dp.disk = disk;
    1.1   martin
    1.1   martin 	gpt_md_init(is_boot_drive, &parts->max_num_parts, &parts->prologue,
    1.1   martin 	    &parts->epilogue);
    1.1   martin
    1.1   martin 	parts->dp.disk_start = start;
    1.1   martin 	parts->dp.disk_size = len;
    1.1   martin 	parts->dp.free_space = len - start - parts->prologue - parts->epilogue;
    1.1   martin 	parts->has_gpt = false;
    1.1   martin
    1.1   martin 	return &parts->dp;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_get_part_info(const struct disk_partitions *arg, part_id id,
    1.1   martin     struct disk_part_info *info)
    1.1   martin {
    1.5   martin 	static const struct part_type_desc gpt_unknown_type =
    1.5   martin 		{ .generic_ptype = PT_undef,
    1.5   martin 		  .short_desc = "<unknown>" };
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	const struct gpt_part_entry *p = parts->partitions;
    1.1   martin 	part_id no;
    1.1   martin
    1.1   martin 	for (no = 0; p != NULL && no < id; no++)
    1.1   martin 		p = p->gp_next;
    1.1   martin
    1.1   martin 	if (no != id || p == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	memset(info, 0, sizeof(*info));
    1.1   martin 	info->start = p->gp_start;
    1.1   martin 	info->size = p->gp_size;
    1.1   martin 	if (p->gp_type)
    1.1   martin 		info->nat_type = &p->gp_type->gent;
    1.5   martin 	else
    1.5   martin 		info->nat_type = &gpt_unknown_type;
    1.1   martin 	info->last_mounted = p->last_mounted;
    1.1   martin 	info->fs_type = p->fs_type;
    1.1   martin 	info->fs_sub_type = p->fs_sub_type;
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_get_part_attr_str(const struct disk_partitions *arg, part_id id,
    1.1   martin     char *str, size_t avail_space)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	const struct gpt_part_entry *p = parts->partitions;
    1.1   martin 	part_id no;
    1.1   martin 	static const char *flags = NULL;
    1.1   martin
    1.1   martin 	for (no = 0; p != NULL && no < id; no++)
    1.1   martin 		p = p->gp_next;
    1.1   martin
    1.1   martin 	if (no != id || p == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if (flags == NULL)
    1.1   martin 		flags = msg_string(MSG_gpt_flags);
    1.1   martin
    1.1   martin 	if (avail_space < 2)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if (p->gp_attr & GPT_ATTR_BOOT)
    1.1   martin 		*str++ = flags[0];
    1.1   martin 	*str = 0;
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin /*
    1.1   martin  * Find insert position and check for duplicates.
    1.1   martin  * If all goes well, insert the new "entry" in the "list".
    1.1   martin  * If there are collisions, report "no free space".
    1.1   martin  * We keep all lists sorted by start sector number,
    1.1   martin  */
    1.1   martin static bool
    1.1   martin gpt_insert_part_into_list(struct gpt_disk_partitions *parts,
    1.1   martin     struct gpt_part_entry **list,
    1.1   martin     struct gpt_part_entry *entry, const char **err_msg)
    1.1   martin {
    1.1   martin 	struct gpt_part_entry *p, *last;
    1.1   martin
    1.1   martin 	/* find the first entry past the new one (if any) */
    1.1   martin 	for (last = NULL, p = *list; p != NULL; last = p, p = p->gp_next) {
    1.1   martin 		if (p->gp_start > entry->gp_start)
    1.1   martin 			break;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	/* check if last partition overlaps with new one */
    1.1   martin 	if (last) {
    1.1   martin 		if (last->gp_start + last->gp_size > entry->gp_start) {
    1.1   martin 			if (err_msg)
    1.1   martin 				*err_msg = msg_string(MSG_No_free_space);
    1.1   martin 			return false;
    1.1   martin 		}
    1.1   martin 	}
    1.1   martin
    1.1   martin 	if (p == NULL) {
    1.1   martin 		entry->gp_next = NULL;
    1.1   martin 		if (last != NULL) {
    1.1   martin 			last->gp_next = entry;
    1.1   martin 		}
    1.1   martin 	} else {
    1.1   martin 		/* check if new entry overlaps with next */
    1.1   martin 		if (entry->gp_start + entry->gp_size > p->gp_start) {
    1.1   martin 			if (err_msg)
    1.1   martin 				*err_msg = msg_string(MSG_No_free_space);
    1.1   martin 			return false;
    1.1   martin 		}
    1.1   martin
    1.1   martin 		entry->gp_next = p;
    1.1   martin 		if (last != NULL)
    1.1   martin 			last->gp_next = entry;
    1.1   martin 		else
    1.1   martin 			*list = entry;
    1.1   martin 	}
    1.1   martin 	if (*list == NULL)
    1.1   martin 		*list = entry;
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_set_part_info(struct disk_partitions *arg, part_id id,
    1.1   martin     const struct disk_part_info *info, const char **err_msg)
    1.1   martin {
    1.1   martin 	struct gpt_disk_partitions *parts =
    1.1   martin 	    (struct gpt_disk_partitions*)arg;
    1.1   martin 	struct gpt_part_entry *p = parts->partitions, *n;
    1.1   martin 	part_id no;
    1.1   martin 	daddr_t lendiff;
    1.1   martin
    1.1   martin 	for (no = 0; p != NULL && no < id; no++)
    1.1   martin 		p = p->gp_next;
    1.1   martin
    1.1   martin 	if (no != id || p == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if ((p->gp_flags & GPEF_ON_DISK)) {
    1.1   martin 		if (info->start != p->gp_start) {
    1.1   martin 			/* partition moved, we need to delete and re-add */
    1.1   martin 			n = calloc(1, sizeof(*n));
    1.1   martin 			if (n == NULL) {
    1.1   martin 				if (err_msg)
    1.1   martin 					*err_msg = err_outofmem;
    1.1   martin 				return false;
    1.1   martin 			}
    1.1   martin 			*n = *p;
    1.1   martin 			p->gp_flags &= ~GPEF_ON_DISK;
    1.1   martin 			if (!gpt_insert_part_into_list(parts, &parts->obsolete,
    1.1   martin 			    n, err_msg))
    1.1   martin 				return false;
    1.1   martin 		} else if (info->size != p->gp_size) {
    1.1   martin 			p->gp_flags |= GPEF_RESIZED;
    1.1   martin 		}
    1.1   martin 	}
    1.1   martin
    1.1   martin 	p->gp_flags |= GPEF_MODIFIED;
    1.1   martin
    1.1   martin 	lendiff = info->size - p->gp_size;
    1.1   martin 	parts->dp.free_space -= lendiff;
    1.1   martin 	return gpt_info_to_part(p, info, err_msg);
    1.1   martin }
    1.1   martin
    1.1   martin static size_t
    1.1   martin gpt_get_free_spaces_internal(const struct gpt_disk_partitions *parts,
    1.1   martin     struct disk_part_free_space *result, size_t max_num_result,
    1.1   martin     daddr_t min_space_size, daddr_t align, daddr_t start, daddr_t ignore)
    1.1   martin {
    1.1   martin 	size_t cnt = 0;
    1.1   martin 	daddr_t s, e, from, size, end_of_disk;
    1.1   martin 	struct gpt_part_entry *p;
    1.1   martin
    1.1   martin 	if (align > 1)
    1.1   martin 		start = max(roundup(start, align), align);
    1.1   martin 	if (start < 0 || start < (daddr_t)parts->prologue)
    1.1   martin 		start = parts->prologue;
    1.1   martin 	if (parts->dp.disk_start != 0 && parts->dp.disk_start > start)
    1.1   martin 		start = parts->dp.disk_start;
    1.1   martin 	if (min_space_size < 1)
    1.1   martin 		min_space_size = 1;
    1.1   martin 	end_of_disk = parts->dp.disk_start + parts->dp.disk_size
    1.1   martin 	    - parts->epilogue;
    1.1   martin 	from = start;
    1.1   martin 	while (from < end_of_disk && cnt < max_num_result) {
    1.1   martin again:
    1.1   martin 		size = parts->dp.disk_start + parts->dp.disk_size - from;
    1.1   martin 		start = from;
    1.1   martin 		if (start + size > end_of_disk)
    1.1   martin 			size = end_of_disk - start;
    1.1   martin 		for (p = parts->partitions; p != NULL; p = p->gp_next) {
    1.1   martin 			s = p->gp_start;
    1.1   martin 			e = p->gp_size + s;
    1.1   martin 			if (s == ignore)
    1.1   martin 				continue;
    1.1   martin 			if (e < from)
    1.1   martin 				continue;
    1.1   martin 			if (s <= from && e > from) {
    1.1   martin 				if (e - 1 >= end_of_disk)
    1.1   martin 					return cnt;
    1.1   martin 				from = e + 1;
    1.1   martin 				if (align > 1) {
    1.1   martin 					from = max(roundup(from, align), align);
    1.1   martin 					if (from >= end_of_disk) {
    1.1   martin 						size = 0;
    1.1   martin 						break;
    1.1   martin 					}
    1.1   martin 				}
    1.1   martin 				goto again;
    1.1   martin 			}
    1.1   martin 			if (s > from && s - from < size) {
    1.1   martin 				size = s - from;
    1.1   martin 			}
    1.1   martin 		}
    1.1   martin 		if (size >= min_space_size) {
    1.1   martin 			result->start = start;
    1.1   martin 			result->size = size;
    1.1   martin 			result++;
    1.1   martin 			cnt++;
    1.1   martin 		}
    1.1   martin 		from += size + 1;
    1.1   martin 		if (align > 1)
    1.1   martin 			from = max(roundup(from, align), align);
    1.1   martin 	}
    1.1   martin
    1.1   martin 	return cnt;
    1.1   martin }
    1.1   martin
    1.1   martin static daddr_t
    1.1   martin gpt_max_free_space_at(const struct disk_partitions *arg, daddr_t start)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	struct disk_part_free_space space;
    1.1   martin
    1.1   martin 	if (gpt_get_free_spaces_internal(parts, &space, 1, 1, 0,
    1.1   martin 	    start, start) == 1)
    1.1   martin 		return space.size;
    1.1   martin
    1.1   martin 	return 0;
    1.1   martin }
    1.1   martin
    1.1   martin static size_t
    1.1   martin gpt_get_free_spaces(const struct disk_partitions *arg,
    1.1   martin     struct disk_part_free_space *result, size_t max_num_result,
    1.1   martin     daddr_t min_space_size, daddr_t align, daddr_t start,
    1.1   martin     daddr_t ignore)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin
    1.1   martin 	return gpt_get_free_spaces_internal(parts, result,
    1.1   martin 	    max_num_result, min_space_size, align, start, ignore);
    1.1   martin }
    1.1   martin
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_adapt(const struct disk_partitions *arg,
    1.1   martin     const struct disk_part_info *src, struct disk_part_info *dest)
    1.1   martin {
    1.1   martin 	/* slightly simplistic, enhance when needed */
    1.1   martin 	memcpy(dest, src, sizeof(*dest));
    1.1   martin
    1.1   martin 	if (src->nat_type == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	dest->nat_type = arg->pscheme->get_generic_part_type(
    1.1   martin 	    src->nat_type->generic_ptype);
    1.1   martin 	if (dest->nat_type == NULL)
    1.1   martin 		dest->nat_type = arg->pscheme->get_generic_part_type(
    1.1   martin 		    PT_unknown);
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static void
    1.1   martin gpt_match_ptype(const char *name, struct gpt_ptype_desc *t)
    1.1   martin {
    1.1   martin 	size_t i;
    1.1   martin
    1.1   martin 	for (i = 0; i < __arraycount(gpt_fs_types); i++) {
    1.1   martin 		if (strcmp(name, gpt_fs_types[i].name) == 0) {
    1.1   martin 			t->gent.generic_ptype = gpt_fs_types[i].ptype;
    1.1   martin 			t->fsflags = gpt_fs_types[i].fsflags;
    1.1   martin 			t->default_fs_type = gpt_fs_types[i].fstype;
    1.1   martin 			return;
    1.1   martin 		}
    1.1   martin 	}
    1.1   martin
    1.1   martin 	t->gent.generic_ptype = PT_unknown;
    1.1   martin 	t->fsflags = 0;
    1.1   martin 	t->default_fs_type = FS_BSDFFS;
    1.1   martin }
    1.1   martin
    1.1   martin static void
    1.1   martin gpt_internal_add_ptype(const char *uid, const char *name, const char *desc)
    1.1   martin {
    1.1   martin 	strlcpy(gpt_ptype_descs[gpt_ptype_cnt].tid, uid,
    1.1   martin 	    sizeof(gpt_ptype_descs[gpt_ptype_cnt].tid));
    1.1   martin 	gpt_ptype_descs[gpt_ptype_cnt].gent.short_desc = name;
    1.1   martin 	gpt_ptype_descs[gpt_ptype_cnt].gent.description = desc;
    1.1   martin 	gpt_match_ptype(name, &gpt_ptype_descs[gpt_ptype_cnt]);
    1.1   martin 	gpt_ptype_cnt++;
    1.1   martin }
    1.1   martin
    1.1   martin static void
    1.1   martin gpt_init_ptypes(void)
    1.1   martin {
    1.1   martin 	if (gpt_ptype_cnt == 0)
    1.1   martin 		gpt_uuid_query(gpt_internal_add_ptype);
    1.1   martin }
    1.1   martin
    1.1   martin static size_t
    1.1   martin gpt_type_count(void)
    1.1   martin {
    1.1   martin 	if (gpt_ptype_cnt == 0)
    1.1   martin 		gpt_init_ptypes();
    1.1   martin
    1.1   martin 	return gpt_ptype_cnt;
    1.1   martin }
    1.1   martin
    1.1   martin static const struct part_type_desc *
    1.1   martin gpt_get_ptype(size_t ndx)
    1.1   martin {
    1.1   martin 	if (gpt_ptype_cnt == 0)
    1.1   martin 		gpt_init_ptypes();
    1.1   martin
    1.1   martin 	if (ndx >= gpt_ptype_cnt)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	return &gpt_ptype_descs[ndx].gent;
    1.1   martin }
    1.1   martin
    1.1   martin static const struct part_type_desc *
    1.1   martin gpt_get_generic_type(enum part_type gent)
    1.1   martin {
    1.1   martin 	if (gpt_ptype_cnt == 0)
    1.1   martin 		gpt_init_ptypes();
    1.1   martin
    1.1   martin 	for (size_t i = 0; i < gpt_ptype_cnt; i++)
    1.1   martin 		if (gpt_ptype_descs[i].gent.generic_ptype == gent)
    1.1   martin 			return &gpt_ptype_descs[i].gent;
    1.1   martin
    1.1   martin 	return NULL;
    1.1   martin }
    1.1   martin
    1.1   martin static const struct gpt_ptype_desc *
    1.1   martin gpt_find_native_type(const struct part_type_desc *gent)
    1.1   martin {
    1.1   martin 	if (gpt_ptype_cnt == 0)
    1.1   martin 		gpt_init_ptypes();
    1.1   martin
    1.1   martin 	if (gent == NULL)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	for (size_t i = 0; i < gpt_ptype_cnt; i++)
    1.1   martin 		if (gent == &gpt_ptype_descs[i].gent)
    1.1   martin 			return &gpt_ptype_descs[i];
    1.1   martin
    1.1   martin 	gent = gpt_get_generic_type(gent->generic_ptype);
    1.1   martin 	if (gent == NULL)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	/* this can not recurse deeper than once, we would not have found a
    1.1   martin 	 * generic type a few lines above if it would. */
    1.1   martin 	return gpt_find_native_type(gent);
    1.1   martin }
    1.1   martin
    1.1   martin static const struct gpt_ptype_desc *
    1.1   martin gpt_find_guid_type(const char *uid)
    1.1   martin {
    1.1   martin 	if (gpt_ptype_cnt == 0)
    1.1   martin 		gpt_init_ptypes();
    1.1   martin
    1.1   martin 	if (uid == NULL || uid[0] == 0)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	for (size_t i = 0; i < gpt_ptype_cnt; i++)
    1.1   martin 		if (strcmp(gpt_ptype_descs[i].tid, uid) == 0)
    1.1   martin 			return &gpt_ptype_descs[i];
    1.1   martin
    1.1   martin 	return NULL;
    1.1   martin }
    1.1   martin
    1.1   martin static const struct part_type_desc *
    1.1   martin gpt_find_type(const char *desc)
    1.1   martin {
    1.1   martin 	if (gpt_ptype_cnt == 0)
    1.1   martin 		gpt_init_ptypes();
    1.1   martin
    1.1   martin 	if (desc == NULL || desc[0] == 0)
    1.1   martin 		return NULL;
    1.1   martin
    1.1   martin 	for (size_t i = 0; i < gpt_ptype_cnt; i++)
    1.1   martin 		if (strcmp(gpt_ptype_descs[i].gent.short_desc, desc) == 0)
    1.1   martin 			return &gpt_ptype_descs[i].gent;
    1.1   martin
    1.1   martin 	return NULL;
    1.1   martin }
    1.1   martin
    1.1   martin static const struct part_type_desc *
    1.1   martin gpt_get_fs_part_type(unsigned fstype, unsigned fs_sub_type)
    1.1   martin {
    1.1   martin 	size_t i;
    1.1   martin
    1.1   martin 	for (i = 0; i < __arraycount(gpt_fs_types); i++)
    1.1   martin 		if (fstype == gpt_fs_types[i].fstype)
    1.1   martin 			return gpt_find_type(gpt_fs_types[i].name);
    1.1   martin
    1.1   martin 	return gpt_get_generic_type(PT_root);
    1.1   martin }
    1.1   martin
    1.1   martin static daddr_t
    1.1   martin gpt_get_part_alignment(const struct disk_partitions *parts)
    1.1   martin {
    1.1   martin
    1.1   martin 	assert(parts->disk_size > 0);
    1.1   martin 	if (parts->disk_size < 0)
    1.1   martin 		return 1;
    1.1   martin
    1.1   martin 	/* Use 1MB offset/alignemnt for large (>128GB) disks */
    1.1   martin 	if (parts->disk_size > HUGE_DISK_SIZE)
    1.1   martin 		return 2048;
    1.1   martin 	else if (parts->disk_size > TINY_DISK_SIZE)
    1.1   martin 		return 64;
    1.1   martin 	else
    1.1   martin 		return 4;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_can_add_partition(const struct disk_partitions *arg)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	struct disk_part_free_space space;
    1.1   martin 	daddr_t align;
    1.1   martin
    1.1   martin 	if (parts->dp.num_part >= parts->max_num_parts)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	align = gpt_get_part_alignment(arg);
    1.1   martin 	if (parts->dp.free_space <= align)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if (gpt_get_free_spaces_internal(parts, &space, 1, align, align,
    1.1   martin 	    0, -1) < 1)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_info_to_part(struct gpt_part_entry *p, const struct disk_part_info *info,
    1.1   martin     const char **err_msg)
    1.1   martin {
    1.1   martin 	p->gp_type = gpt_find_native_type(info->nat_type);
    1.1   martin 	p->gp_start = info->start;
    1.1   martin 	p->gp_size = info->size;
    1.1   martin 	if (info->last_mounted != NULL && info->last_mounted !=
    1.1   martin 	    p->last_mounted) {
    1.1   martin 		free(__UNCONST(p->last_mounted));
    1.1   martin 		p->last_mounted = strdup(info->last_mounted);
    1.1   martin 	}
    1.1   martin 	p->fs_type = info->fs_type;
    1.1   martin 	p->fs_sub_type = info->fs_sub_type;
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static part_id
    1.1   martin gpt_add_part(struct disk_partitions *arg,
    1.1   martin     const struct disk_part_info *info, const char **err_msg)
    1.1   martin {
    1.1   martin 	struct gpt_disk_partitions *parts =
    1.1   martin 	    (struct gpt_disk_partitions*)arg;
    1.1   martin 	struct disk_part_free_space space;
    1.1   martin 	struct disk_part_info data = *info;
    1.1   martin 	struct gpt_part_entry *p;
    1.1   martin 	bool ok;
    1.1   martin
    1.1   martin 	if (err_msg != NULL)
    1.1   martin 		*err_msg = NULL;
    1.1   martin
    1.1   martin 	if (gpt_get_free_spaces_internal(parts, &space, 1, 1, 1,
    1.1   martin 	    info->start, -1) < 1) {
    1.1   martin 		if (err_msg)
    1.1   martin 			*err_msg = msg_string(MSG_No_free_space);
    1.1   martin 		return NO_PART;
    1.1   martin 	}
    1.1   martin 	if (parts->dp.num_part >= parts->max_num_parts) {
    1.1   martin 		if (err_msg)
    1.1   martin 			*err_msg = msg_string(MSG_err_too_many_partitions);
    1.1   martin 		return NO_PART;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	if (data.size > space.size)
    1.1   martin 		data.size = space.size;
    1.1   martin
    1.1   martin 	p = calloc(1, sizeof(*p));
    1.1   martin 	if (p == NULL) {
    1.1   martin 		if (err_msg != NULL)
    1.1   martin 			*err_msg = INTERNAL_ERROR;
    1.1   martin 		return NO_PART;
    1.1   martin 	}
    1.1   martin 	if (!gpt_info_to_part(p, &data, err_msg)) {
    1.1   martin 		free(p);
    1.1   martin 		return NO_PART;
    1.1   martin 	}
    1.1   martin 	p->gp_flags |= GPEF_MODIFIED;
    1.1   martin 	ok = gpt_insert_part_into_list(parts, &parts->partitions, p, err_msg);
    1.1   martin 	if (ok) {
    1.1   martin 		parts->dp.num_part++;
    1.1   martin 		parts->dp.free_space -= p->gp_size;
    1.1   martin 		return parts->dp.num_part-1;
    1.1   martin 	} else {
    1.1   martin 		free(p);
    1.1   martin 		return NO_PART;
    1.1   martin 	}
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_delete_partition(struct disk_partitions *arg, part_id id,
    1.1   martin     const char **err_msg)
    1.1   martin {
    1.1   martin 	struct gpt_disk_partitions *parts = (struct gpt_disk_partitions*)arg;
    1.1   martin 	struct gpt_part_entry *p, *last = NULL;
    1.1   martin 	part_id i;
    1.1   martin 	bool res;
    1.1   martin
    1.1   martin 	if (parts->dp.num_part == 0)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	for (i = 0, p = parts->partitions;
    1.1   martin 	    i != id && i < parts->dp.num_part && p != NULL;
    1.1   martin 	    i++, p = p->gp_next)
    1.1   martin 		last = p;
    1.1   martin
    1.1   martin 	if (p == NULL) {
    1.1   martin 		if (err_msg)
    1.1   martin 			*err_msg = INTERNAL_ERROR;
    1.1   martin 		return false;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	if (last == NULL)
    1.1   martin 		parts->partitions = p->gp_next;
    1.1   martin 	else
    1.1   martin 		last->gp_next = p->gp_next;
    1.1   martin
    1.1   martin 	res = true;
    1.1   martin 	if (p->gp_flags & GPEF_ON_DISK) {
    1.1   martin 		if (!gpt_insert_part_into_list(parts, &parts->obsolete,
    1.1   martin 		    p, err_msg))
    1.1   martin 			res = false;
    1.1   martin 	} else {
    1.1   martin 		free(p);
    1.1   martin 	}
    1.1   martin
    1.1   martin 	if (res) {
    1.1   martin 		parts->dp.num_part--;
    1.1   martin 		parts->dp.free_space += p->gp_size;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	return res;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_delete_all_partitions(struct disk_partitions *arg)
    1.1   martin {
    1.1   martin 	struct gpt_disk_partitions *parts = (struct gpt_disk_partitions*)arg;
    1.1   martin
    1.1   martin 	while (parts->dp.num_part > 0) {
    1.1   martin 		if (!gpt_delete_partition(&parts->dp, 0, NULL))
    1.1   martin 			return false;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_read_part(const char *disk, daddr_t start, struct gpt_part_entry *p)
    1.1   martin {
    1.1   martin 	char *textbuf, *t, *tt;
    1.1   martin 	static const char expected_hdr[] = "Details for index ";
    1.1   martin
    1.1   martin 	/* run gpt show for this partition */
    1.1   martin 	if (collect(T_OUTPUT, &textbuf,
    1.1   martin 	    "gpt -r show -b %" PRIu64 " %s 2>/dev/null", start, disk) < 1)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * gpt show should respond with single partition details, but will
    1.1   martin 	 * fall back to "show -a" output if something is wrong
    1.1   martin 	 */
    1.1   martin 	t = strtok(textbuf, "\n"); /* first line is special */
    1.1   martin 	if (strncmp(t, expected_hdr, sizeof(expected_hdr)-1) != 0) {
    1.1   martin 		free(textbuf);
    1.1   martin 		return false;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	/* parse output into "old" */
    1.1   martin 	while ((t = strtok(NULL, "\n")) != NULL) {
    1.1   martin 		tt = strsep(&t, " \t");
    1.1   martin 		if (strlen(tt) == 0)
    1.1   martin 			continue;
    1.1   martin 		gpt_add_info(p, tt, t, true);
    1.1   martin 	}
    1.1   martin 	free(textbuf);
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_apply_attr(const char *disk, const char *cmd, off_t start, uint todo)
    1.1   martin {
    1.1   martin 	size_t i;
    1.1   martin 	char attr_str[STRSIZE];
    1.1   martin
    1.1   martin 	if (todo == 0)
    1.1   martin 		return true;
    1.1   martin
    1.1   martin 	strcpy(attr_str, "-a ");
    1.1   martin 	for (i = 0; todo != 0; i++) {
    1.1   martin 		if (!(gpt_avail_attrs[i].flag & todo))
    1.1   martin 			continue;
    1.1   martin 		todo &= ~gpt_avail_attrs[i].flag;
    1.1   martin 		if (attr_str[0])
    1.1   martin 			strlcat(attr_str, ",",
    1.1   martin 			    sizeof(attr_str));
    1.1   martin 		strlcat(attr_str,
    1.1   martin 		    gpt_avail_attrs[i].name,
    1.1   martin 		    sizeof(attr_str));
    1.1   martin 	}
    1.1   martin 	if (run_program(RUN_SILENT,
    1.1   martin 	    "gpt %s %s -b %" PRIu64 " %s", cmd, attr_str, start, disk) != 0)
    1.1   martin 		return false;
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin /*
    1.1   martin  * Modify an existing on-disk partition.
    1.1   martin  * Start and size can not be changed here, caller needs to deal
    1.1   martin  * with that kind of changes upfront.
    1.1   martin  */
    1.1   martin static bool
    1.1   martin gpt_modify_part(const char *disk, struct gpt_part_entry *p)
    1.1   martin {
    1.1   martin 	struct gpt_part_entry old;
    1.1   martin 	uint todo_set, todo_unset;
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * Query current on-disk state
    1.1   martin 	 */
    1.1   martin 	memset(&old, 0, sizeof old);
    1.1   martin 	if (!gpt_read_part(disk, p->gp_start, &old))
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	/* Reject unsupported changes */
    1.1   martin 	if (old.gp_start != p->gp_start || old.gp_size != p->gp_size)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * GUID should never change, but the internal copy
    1.1   martin 	 * may not yet know it.
    1.1   martin 	 */
    1.1   martin 	strcpy(p->gp_id, old.gp_id);
    1.1   martin
    1.1   martin 	/* Check type */
    1.1   martin 	if (p->gp_type != old.gp_type) {
    1.1   martin 		if (run_program(RUN_SILENT,
    1.1   martin 		    "gpt label -b %" PRIu64 " -T %s %s",
    1.1   martin 		    p->gp_start, p->gp_type->tid, disk) != 0)
    1.1   martin 			return false;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	/* Check label */
    1.1   martin 	if (strcmp(p->gp_label, old.gp_label) != 0) {
    1.1   martin 		if (run_program(RUN_SILENT,
    1.1   martin 		    "gpt label -b %" PRIu64 " -l %s %s",
    1.1   martin 		    p->gp_start, p->gp_label, disk) != 0)
    1.1   martin 			return false;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	/* Check attributes */
    1.1   martin 	if (p->gp_attr != old.gp_attr) {
    1.1   martin 		if (p->gp_attr == 0) {
    1.1   martin 			if (run_program(RUN_SILENT,
    1.1   martin 			    "gpt set -N -b %" PRIu64 " %s",
    1.1   martin 			    p->gp_start, disk) != 0)
    1.1   martin 				return false;
    1.1   martin 		} else {
    1.1   martin 			todo_set = (p->gp_attr ^ old.gp_attr) & p->gp_attr;
    1.1   martin 			todo_unset = (p->gp_attr ^ old.gp_attr) & old.gp_attr;
    1.1   martin 			if (!gpt_apply_attr(disk, "unset", p->gp_start,
    1.1   martin 			    todo_unset))
    1.1   martin 				return false;
    1.1   martin 			if (!gpt_apply_attr(disk, "set", p->gp_start,
    1.1   martin 			    todo_set))
    1.1   martin 				return false;
    1.1   martin 		}
    1.1   martin 	}
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin /*
    1.1   martin  * verbatim copy from sys/dev/dkwedge/dkwedge_bsdlabel.c:
    1.1   martin  *  map FS_* to wedge strings
    1.1   martin  */
    1.1   martin static const char *
    1.1   martin bsdlabel_fstype_to_str(uint8_t fstype)
    1.1   martin {
    1.1   martin 	const char *str;
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * For each type known to FSTYPE_DEFN (from <sys/disklabel.h>),
    1.1   martin 	 * a suitable case branch will convert the type number to a string.
    1.1   martin 	 */
    1.1   martin 	switch (fstype) {
    1.1   martin #define FSTYPE_TO_STR_CASE(tag, number, name, fsck, mount) \
    1.1   martin 	case __CONCAT(FS_,tag):	str = __CONCAT(DKW_PTYPE_,tag);			break;
    1.1   martin 	FSTYPE_DEFN(FSTYPE_TO_STR_CASE)
    1.1   martin #undef FSTYPE_TO_STR_CASE
    1.1   martin 	default:		str = NULL;			break;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	return (str);
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_add_wedge(const char *disk, struct gpt_part_entry *p)
    1.1   martin {
    1.1   martin 	struct dkwedge_info dkw;
    1.1   martin 	const char *tname;
    1.1   martin 	char diskpath[MAXPATHLEN];
    1.1   martin 	int fd;
    1.1   martin
    1.1   martin 	memset(&dkw, 0, sizeof(dkw));
    1.1   martin 	tname = bsdlabel_fstype_to_str(p->fs_type);
    1.1   martin 	if (tname)
    1.1   martin 		strlcpy(dkw.dkw_ptype, tname, sizeof(dkw.dkw_ptype));
    1.1   martin
    1.1   martin 	strlcpy((char*)&dkw.dkw_wname, p->gp_id, sizeof(dkw.dkw_wname));
    1.1   martin 	dkw.dkw_offset = p->gp_start;
    1.1   martin 	dkw.dkw_size = p->gp_size;
    1.1   martin
    1.1   martin 	fd = opendisk(disk, O_RDWR, diskpath, sizeof(diskpath), 0);
    1.1   martin 	if (fd < 0)
    1.1   martin 		return false;
    1.1   martin 	if (ioctl(fd, DIOCAWEDGE, &dkw) == -1) {
    1.1   martin 		close(fd);
    1.1   martin 		return false;
    1.1   martin 	}
    1.1   martin 	close(fd);
    1.1   martin
    1.1   martin 	strlcpy(p->gp_dev_name, dkw.dkw_devname, sizeof(p->gp_dev_name));
    1.1   martin 	p->gp_flags |= GPEF_WEDGE;
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_get_part_device(const struct disk_partitions *arg,
    1.1   martin     part_id id, char *devname, size_t max_devname_len, int *part,
    1.1   martin     enum dev_name_usage usage, bool with_path)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	struct  gpt_part_entry *p = parts->partitions;
    1.1   martin 	part_id no;
    1.1   martin
    1.1   martin
    1.1   martin 	for (no = 0; p != NULL && no < id; no++)
    1.1   martin 		p = p->gp_next;
    1.1   martin
    1.1   martin 	if (no != id || p == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if (part)
    1.1   martin 		*part = -1;
    1.1   martin
    1.1   martin 	if (!(p->gp_flags & GPEF_WEDGE) &&
    1.1   martin 	    (usage == plain_name || usage == raw_dev_name))
    1.1   martin 		gpt_add_wedge(arg->disk, p);
    1.1   martin
    1.1   martin 	switch (usage) {
    1.1   martin 	case logical_name:
    1.1   martin 		if (p->gp_label[0] != 0)
    1.1   martin 			snprintf(devname, max_devname_len,
    1.1   martin 			    "NAME=%s", p->gp_label);
    1.1   martin 		else
    1.1   martin 			snprintf(devname, max_devname_len,
    1.1   martin 			    "NAME=%s", p->gp_id);
    1.1   martin 		break;
    1.1   martin 	case plain_name:
    1.1   martin 		assert(p->gp_flags & GPEF_WEDGE);
    1.1   martin 		if (with_path)
    1.1   martin 			snprintf(devname, max_devname_len, _PATH_DEV "%s",
    1.1   martin 			    p->gp_dev_name);
    1.1   martin 		else
    1.1   martin 			strlcpy(devname, p->gp_dev_name, max_devname_len);
    1.1   martin 		break;
    1.1   martin 	case raw_dev_name:
    1.1   martin 		assert(p->gp_flags & GPEF_WEDGE);
    1.1   martin 		if (with_path)
    1.1   martin 			snprintf(devname, max_devname_len, _PATH_DEV "r%s",
    1.1   martin 			    p->gp_dev_name);
    1.1   martin 		else
    1.1   martin 			snprintf(devname, max_devname_len, "r%s",
    1.1   martin 			    p->gp_dev_name);
    1.1   martin 		break;
    1.1   martin 	default:
    1.1   martin 		return false;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_write_to_disk(struct disk_partitions *arg)
    1.1   martin {
    1.1   martin 	struct gpt_disk_partitions *parts = (struct gpt_disk_partitions*)arg;
    1.1   martin 	struct gpt_part_entry *p, *n;
    1.1   martin 	char label_arg[sizeof(p->gp_label) + 4];
    1.1   martin 	char diskpath[MAXPATHLEN];
    1.1   martin 	int fd, bits = 0;
    1.1   martin 	bool root_is_new = false, efi_is_new = false;
    1.1   martin 	part_id root_id = NO_PART, efi_id = NO_PART, pno;
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * Remove all wedges on this disk - they may become invalid and we
    1.1   martin 	 * have no easy way to associate them with the partitioning data.
    1.1   martin 	 * Instead we will explicitly request creation of wedges on demand
    1.1   martin 	 * later.
    1.1   martin 	 */
    1.1   martin 	fd = opendisk(arg->disk, O_RDWR, diskpath, sizeof(diskpath), 0);
    1.1   martin 	if (fd < 0)
    1.1   martin 		return false;
    1.1   martin 	if (ioctl(fd, DIOCRMWEDGES, &bits) == -1)
    1.1   martin 		return false;
    1.1   martin 	close(fd);
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * Mark all partitions as "have no wedge yet". While there,
    1.1   martin 	 * collect first root and efi partition (if available)
    1.1   martin 	 */
    1.1   martin 	for (pno = 0, p = parts->partitions; p != NULL; p = p->gp_next, pno++) {
    1.1   martin 		p->gp_flags &= ~GPEF_WEDGE;
    1.5   martin 		if (root_id == NO_PART && p->gp_type != NULL) {
    1.1   martin 			if (p->gp_type->gent.generic_ptype == PT_root &&
    1.1   martin 			    p->gp_start == pm->ptstart) {
    1.1   martin 				root_id = pno;
    1.1   martin 				root_is_new = !(p->gp_flags & GPEF_ON_DISK);
    1.1   martin 			} else if (efi_id == NO_PART &&
    1.1   martin 			    p->gp_type->gent.generic_ptype == PT_EFI_SYSTEM) {
    1.1   martin 				efi_id = pno;
    1.1   martin 				efi_is_new = !(p->gp_flags & GPEF_ON_DISK);
    1.1   martin 			}
    1.1   martin 		}
    1.1   martin 	}
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * If no GPT on disk yet, create it.
    1.1   martin 	 */
    1.1   martin 	if (!parts->has_gpt) {
    1.1   martin 		char limit[30];
    1.1   martin
    1.1   martin 		if (parts->max_num_parts > 0)
    1.1   martin 			sprintf(limit, "-p %zu", parts->max_num_parts);
    1.1   martin 		else
    1.1   martin 			limit[0] = 0;
    1.1   martin 		if (run_program(RUN_SILENT, "gpt create %s %s",
    1.1   martin 		    limit, parts->dp.disk))
    1.1   martin 			return false;
    1.1   martin 		parts->has_gpt = true;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * Delete all old partitions
    1.1   martin 	 */
    1.1   martin 	for (p = parts->obsolete; p != NULL; p = n) {
    1.1   martin 		run_program(RUN_SILENT, "gpt -n remove -b %" PRIu64 " %s",
    1.1   martin 		    p->gp_start, arg->disk);
    1.1   martin 		n = p->gp_next;
    1.1   martin 		free(p);
    1.1   martin 	}
    1.1   martin 	parts->obsolete = NULL;
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * Modify existing but changed partitions
    1.1   martin 	 */
    1.1   martin 	for (p = parts->partitions; p != NULL; p = p->gp_next) {
    1.1   martin 		if (!(p->gp_flags & GPEF_ON_DISK))
    1.1   martin 			continue;
    1.1   martin
    1.1   martin 		if (p->gp_flags & GPEF_RESIZED) {
    1.1   martin 			run_program(RUN_SILENT,
    1.1   martin 			    "gpt -n resize -b %" PRIu64 " -s %" PRIu64 "s %s",
    1.1   martin 			    p->gp_start, p->gp_size, arg->disk);
    1.1   martin 			p->gp_flags &= ~GPEF_RESIZED;
    1.1   martin 		}
    1.1   martin
    1.1   martin 		if (!(p->gp_flags & GPEF_MODIFIED))
    1.1   martin 			continue;
    1.1   martin
    1.1   martin 		if (!gpt_modify_part(parts->dp.disk, p))
    1.1   martin 			return false;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * Add new partitions
    1.1   martin 	 */
    1.1   martin 	for (p = parts->partitions; p != NULL; p = p->gp_next) {
    1.1   martin 		if (p->gp_flags & GPEF_ON_DISK)
    1.1   martin 			continue;
    1.1   martin 		if (!(p->gp_flags & GPEF_MODIFIED))
    1.1   martin 			continue;
    1.1   martin
    1.1   martin 		if (p->gp_label[0] == 0)
    1.1   martin 			label_arg[0] = 0;
    1.1   martin 		else
    1.1   martin 			sprintf(label_arg, "-l %s", p->gp_label);
    1.1   martin
    1.5   martin 		if (p->gp_type != NULL)
    1.5   martin 			run_program(RUN_SILENT,
    1.5   martin 			    "gpt -n add -b %" PRIu64 " -s %" PRIu64
    1.5   martin 			    "s -t %s %s %s",
    1.5   martin 			    p->gp_start, p->gp_size, p->gp_type->tid,
    1.5   martin 			    label_arg, arg->disk);
    1.5   martin 		else
    1.5   martin 			run_program(RUN_SILENT,
    1.5   martin 			    "gpt -n add -b %" PRIu64 " -s %" PRIu64
    1.5   martin 			    "s %s %s",
    1.5   martin 			    p->gp_start, p->gp_size, label_arg, arg->disk);
    1.1   martin 		gpt_apply_attr(arg->disk, "set", p->gp_start, p->gp_attr);
    1.1   martin 		gpt_read_part(arg->disk, p->gp_start, p);
    1.1   martin 		p->gp_flags |= GPEF_ON_DISK;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	/*
    1.1   martin 	 * Additional MD bootloader magic...
    1.1   martin 	 */
    1.1   martin 	if (!md_gpt_post_write(&parts->dp, root_id, root_is_new, efi_id,
    1.1   martin 	    efi_is_new))
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
1.6.2.3  msaitoh static part_id
1.6.2.3  msaitoh gpt_find_by_name(struct disk_partitions *arg, const char *name)
1.6.2.3  msaitoh {
1.6.2.3  msaitoh 	struct gpt_disk_partitions *parts = (struct gpt_disk_partitions*)arg;
1.6.2.3  msaitoh 	struct gpt_part_entry *p;
1.6.2.3  msaitoh 	part_id pno;
1.6.2.3  msaitoh
1.6.2.3  msaitoh 	for (pno = 0, p = parts->partitions; p != NULL;
1.6.2.3  msaitoh 	    p = p->gp_next, pno++) {
1.6.2.3  msaitoh 		if (strcmp(p->gp_label, name) == 0)
1.6.2.3  msaitoh 			return pno;
1.6.2.3  msaitoh 		if (strcmp(p->gp_id, name) == 0)
1.6.2.3  msaitoh 			return pno;
1.6.2.3  msaitoh 	}
1.6.2.3  msaitoh
1.6.2.3  msaitoh 	return NO_PART;
1.6.2.3  msaitoh }
1.6.2.3  msaitoh
    1.1   martin bool
    1.1   martin gpt_parts_check(void)
    1.1   martin {
    1.1   martin
    1.1   martin 	check_available_binaries();
    1.1   martin
    1.1   martin 	return have_gpt && have_dk;
    1.1   martin }
    1.1   martin
    1.1   martin static void
    1.1   martin gpt_free(struct disk_partitions *arg)
    1.1   martin {
    1.1   martin 	struct gpt_disk_partitions *parts = (struct gpt_disk_partitions*)arg;
    1.1   martin 	struct gpt_part_entry *p, *n;
    1.1   martin
    1.1   martin 	assert(parts != NULL);
    1.1   martin 	for (p = parts->partitions; p != NULL; p = n) {
    1.1   martin 		free(__UNCONST(p->last_mounted));
    1.1   martin 		n = p->gp_next;
    1.1   martin 		free(p);
    1.1   martin 	}
    1.1   martin 	free(parts);
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_custom_attribute_writable(const struct disk_partitions *arg,
    1.1   martin     part_id ptn, size_t attr_no)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	size_t i;
    1.1   martin 	struct gpt_part_entry *p;
    1.1   martin
    1.1   martin 	if (attr_no >= arg->pscheme->custom_attribute_count)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	const msg label = arg->pscheme->custom_attributes[attr_no].label;
    1.1   martin
    1.1   martin 	/* we can not edit the uuid attribute */
    1.1   martin 	if (label == MSG_ptn_uuid)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	/* the label is always editable */
    1.1   martin 	if (label == MSG_ptn_label)
    1.1   martin 		return true;
    1.1   martin
    1.1   martin 	/* the GPT type is read only */
    1.1   martin 	if (label == MSG_ptn_gpt_type)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	/* BOOTME makes no sense on swap partitions */
    1.1   martin 	for (i = 0, p = parts->partitions; p != NULL; i++, p = p->gp_next)
    1.1   martin 		if (i == ptn)
    1.1   martin 			break;
    1.1   martin
    1.1   martin 	if (p == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.5   martin 	if (p->fs_type == FS_SWAP ||
    1.5   martin 	    (p->gp_type != NULL && p->gp_type->gent.generic_ptype == PT_swap))
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.6   martin static const char *
    1.6   martin gpt_get_label_str(const struct disk_partitions *arg, part_id ptn)
    1.6   martin {
    1.6   martin 	const struct gpt_disk_partitions *parts =
    1.6   martin 	    (const struct gpt_disk_partitions*)arg;
    1.6   martin 	size_t i;
    1.6   martin 	struct gpt_part_entry *p;
    1.6   martin
    1.6   martin 	for (i = 0, p = parts->partitions; p != NULL; i++, p = p->gp_next)
    1.6   martin 		if (i == ptn)
    1.6   martin 			break;
    1.6   martin
    1.6   martin 	if (p == NULL)
    1.6   martin 		return NULL;
    1.6   martin
    1.6   martin 	if (p->gp_label[0] != 0)
    1.6   martin 		return p->gp_label;
    1.6   martin 	return p->gp_id;
    1.6   martin }
    1.6   martin
    1.1   martin static bool
    1.1   martin gpt_format_custom_attribute(const struct disk_partitions *arg,
    1.1   martin     part_id ptn, size_t attr_no, const struct disk_part_info *info,
    1.1   martin     char *out, size_t out_space)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	size_t i;
    1.1   martin 	struct gpt_part_entry *p, data;
    1.1   martin
    1.1   martin 	for (i = 0, p = parts->partitions; p != NULL; i++, p = p->gp_next)
    1.1   martin 		if (i == ptn)
    1.1   martin 			break;
    1.1   martin
    1.1   martin 	if (p == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if (attr_no >= parts->dp.pscheme->custom_attribute_count)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	const msg label = parts->dp.pscheme->custom_attributes[attr_no].label;
    1.1   martin
    1.1   martin 	if (info != NULL) {
    1.1   martin 		data = *p;
    1.1   martin 		gpt_info_to_part(&data, info, NULL);
    1.1   martin 		p = &data;
    1.1   martin 	}
    1.1   martin
    1.1   martin 	if (label == MSG_ptn_label)
    1.1   martin 		strlcpy(out, p->gp_label, out_space);
    1.1   martin 	else if (label == MSG_ptn_uuid)
    1.1   martin 		strlcpy(out, p->gp_id, out_space);
    1.5   martin 	else if (label == MSG_ptn_gpt_type) {
    1.5   martin 		if (p->gp_type != NULL)
    1.5   martin 			strlcpy(out, p->gp_type->gent.description, out_space);
    1.5   martin 		else if (out_space > 1)
    1.5   martin 			out[0] = 0;
    1.5   martin 	} else if (label == MSG_ptn_boot)
    1.1   martin 		strlcpy(out, msg_string(p->gp_attr & GPT_ATTR_BOOT ?
    1.1   martin 		    MSG_Yes : MSG_No), out_space);
    1.1   martin 	else
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_custom_attribute_toggle(struct disk_partitions *arg,
    1.1   martin     part_id ptn, size_t attr_no)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	size_t i;
    1.1   martin 	struct gpt_part_entry *p;
    1.1   martin
    1.1   martin 	for (i = 0, p = parts->partitions; p != NULL; i++, p = p->gp_next)
    1.1   martin 		if (i == ptn)
    1.1   martin 			break;
    1.1   martin
    1.1   martin 	if (p == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if (attr_no >= parts->dp.pscheme->custom_attribute_count)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	const msg label = parts->dp.pscheme->custom_attributes[attr_no].label;
    1.1   martin 	if (label != MSG_ptn_boot)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if (p->gp_attr & GPT_ATTR_BOOT) {
    1.1   martin 		p->gp_attr &= ~GPT_ATTR_BOOT;
    1.1   martin 	} else {
    1.1   martin 		for (i = 0, p = parts->partitions; p != NULL;
    1.1   martin 		    i++, p = p->gp_next)
    1.1   martin 			if (i == ptn)
    1.1   martin 				p->gp_attr |= GPT_ATTR_BOOT;
    1.1   martin 			else
    1.1   martin 				p->gp_attr &= ~GPT_ATTR_BOOT;
    1.1   martin 	}
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_custom_attribute_set_str(struct disk_partitions *arg,
    1.1   martin     part_id ptn, size_t attr_no, const char *new_val)
    1.1   martin {
    1.1   martin 	const struct gpt_disk_partitions *parts =
    1.1   martin 	    (const struct gpt_disk_partitions*)arg;
    1.1   martin 	size_t i;
    1.1   martin 	struct gpt_part_entry *p;
    1.1   martin
    1.1   martin 	for (i = 0, p = parts->partitions; p != NULL; i++, p = p->gp_next)
    1.1   martin 		if (i == ptn)
    1.1   martin 			break;
    1.1   martin
    1.1   martin 	if (p == NULL)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	if (attr_no >= parts->dp.pscheme->custom_attribute_count)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	const msg label = parts->dp.pscheme->custom_attributes[attr_no].label;
    1.1   martin
    1.1   martin 	if (label != MSG_ptn_label)
    1.1   martin 		return false;
    1.1   martin
    1.1   martin 	strlcpy(p->gp_label, new_val, sizeof(p->gp_label));
    1.1   martin 	return true;
    1.1   martin }
    1.1   martin
    1.1   martin static bool
    1.1   martin gpt_have_boot_support(const char *disk)
    1.1   martin {
    1.1   martin #ifdef	HAVE_GPT_BOOT
    1.1   martin 	return true;
    1.1   martin #else
    1.1   martin 	return false;
    1.1   martin #endif
    1.1   martin }
    1.1   martin
    1.1   martin const struct disk_part_custom_attribute gpt_custom_attrs[] = {
    1.1   martin 	{ .label = MSG_ptn_label,	.type = pet_str },
    1.1   martin 	{ .label = MSG_ptn_uuid,	.type = pet_str },
    1.1   martin 	{ .label = MSG_ptn_gpt_type,	.type = pet_str },
    1.1   martin 	{ .label = MSG_ptn_boot,	.type = pet_bool },
    1.1   martin };
    1.1   martin
    1.1   martin const struct disk_partitioning_scheme
    1.1   martin gpt_parts = {
    1.1   martin 	.name = MSG_parttype_gpt,
    1.1   martin 	.short_name = MSG_parttype_gpt_short,
    1.1   martin 	.part_flag_desc = MSG_gpt_flag_desc,
    1.1   martin 	.custom_attribute_count = __arraycount(gpt_custom_attrs),
    1.1   martin 	.custom_attributes = gpt_custom_attrs,
    1.1   martin 	.get_part_types_count = gpt_type_count,
    1.1   martin 	.get_part_type = gpt_get_ptype,
    1.1   martin 	.get_generic_part_type = gpt_get_generic_type,
    1.1   martin 	.get_fs_part_type = gpt_get_fs_part_type,
    1.1   martin 	.get_part_alignment = gpt_get_part_alignment,
    1.1   martin 	.read_from_disk = gpt_read_from_disk,
    1.1   martin 	.create_new_for_disk = gpt_create_new,
    1.1   martin 	.have_boot_support = gpt_have_boot_support,
1.6.2.3  msaitoh 	.find_by_name = gpt_find_by_name,
    1.1   martin 	.can_add_partition = gpt_can_add_partition,
    1.1   martin 	.custom_attribute_writable = gpt_custom_attribute_writable,
    1.1   martin 	.format_custom_attribute = gpt_format_custom_attribute,
    1.1   martin 	.custom_attribute_toggle = gpt_custom_attribute_toggle,
    1.1   martin 	.custom_attribute_set_str = gpt_custom_attribute_set_str,
    1.6   martin 	.other_partition_identifier = gpt_get_label_str,
    1.1   martin 	.get_part_device = gpt_get_part_device,
    1.1   martin 	.max_free_space_at = gpt_max_free_space_at,
    1.1   martin 	.get_free_spaces = gpt_get_free_spaces,
    1.1   martin 	.adapt_foreign_part_info = gpt_adapt,
    1.1   martin 	.get_part_info = gpt_get_part_info,
    1.1   martin 	.get_part_attr_str = gpt_get_part_attr_str,
    1.1   martin 	.set_part_info = gpt_set_part_info,
    1.1   martin 	.add_partition = gpt_add_part,
    1.1   martin 	.delete_all_partitions = gpt_delete_all_partitions,
    1.1   martin 	.delete_partition = gpt_delete_partition,
    1.1   martin 	.write_to_disk = gpt_write_to_disk,
    1.1   martin 	.free = gpt_free,
    1.1   martin };