freebsd-skq/contrib/lib9p/genacl.c
jceel 5ab91d3e1d Import lib9p 7ddb1164407da19b9b1afb83df83ae65a71a9a66.
Approved by:	trasz
MFC after:	1 month
Sponsored by:	Conclusive Engineering (development), vStack.com (funding)
2020-05-14 19:57:52 +00:00

721 lines
20 KiB
C

/*
* Copyright 2016 Chris Torek <torek@ixsystems.com>
* All rights reserved
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted providing that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
* IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#include <assert.h>
#include <stdlib.h>
#include <string.h>
#include <errno.h>
#include <sys/types.h>
#include <sys/acl.h>
#include <sys/stat.h>
#include "lib9p.h"
#include "lib9p_impl.h"
#include "genacl.h"
#include "fid.h"
#include "log.h"
typedef int econvertfn(acl_entry_t, struct l9p_ace *);
#ifndef __APPLE__
static struct l9p_acl *l9p_new_acl(uint32_t acetype, uint32_t aceasize);
static struct l9p_acl *l9p_growacl(struct l9p_acl *acl, uint32_t aceasize);
static int l9p_count_aces(acl_t sysacl);
static struct l9p_acl *l9p_sysacl_to_acl(int, acl_t, econvertfn *);
#endif
static bool l9p_ingroup(gid_t tid, gid_t gid, gid_t *gids, size_t ngids);
static int l9p_check_aces(int32_t mask, struct l9p_acl *acl, struct stat *st,
uid_t uid, gid_t gid, gid_t *gids, size_t ngids);
void
l9p_acl_free(struct l9p_acl *acl)
{
free(acl);
}
/*
* Is the given group ID tid (test-id) any of the gid's in agids?
*/
static bool
l9p_ingroup(gid_t tid, gid_t gid, gid_t *gids, size_t ngids)
{
size_t i;
if (tid == gid)
return (true);
for (i = 0; i < ngids; i++)
if (tid == gids[i])
return (true);
return (false);
}
/* #define ACE_DEBUG */
/*
* Note that NFSv4 tests are done on a "first match" basis.
* That is, we check each ACE sequentially until we run out
* of ACEs, or find something explicitly denied (DENIED!),
* or have cleared out all our attempt-something bits. Once
* we come across an ALLOW entry for the bits we're trying,
* we clear those from the bits we're still looking for, in
* the order they appear.
*
* The result is either "definitely allowed" (we cleared
* all the bits), "definitely denied" (we hit a deny with
* some or all of the bits), or "unspecified". We
* represent these three states as +1 (positive = yes = allow),
* -1 (negative = no = denied), or 0 (no strong answer).
*
* For our caller's convenience, if we are called with a
* mask of 0, we return 0 (no answer).
*/
static int
l9p_check_aces(int32_t mask, struct l9p_acl *acl, struct stat *st,
uid_t uid, gid_t gid, gid_t *gids, size_t ngids)
{
uint32_t i;
struct l9p_ace *ace;
#ifdef ACE_DEBUG
const char *acetype, *allowdeny;
bool show_tid;
#endif
bool match;
uid_t tid;
if (mask == 0)
return (0);
for (i = 0; mask != 0 && i < acl->acl_nace; i++) {
ace = &acl->acl_aces[i];
switch (ace->ace_type) {
case L9P_ACET_ACCESS_ALLOWED:
case L9P_ACET_ACCESS_DENIED:
break;
default:
/* audit, alarm - ignore */
continue;
}
#ifdef ACE_DEBUG
show_tid = false;
#endif
if (ace->ace_flags & L9P_ACEF_OWNER) {
#ifdef ACE_DEBUG
acetype = "OWNER@";
#endif
match = st->st_uid == uid;
} else if (ace->ace_flags & L9P_ACEF_GROUP) {
#ifdef ACE_DEBUG
acetype = "GROUP@";
#endif
match = l9p_ingroup(st->st_gid, gid, gids, ngids);
} else if (ace->ace_flags & L9P_ACEF_EVERYONE) {
#ifdef ACE_DEBUG
acetype = "EVERYONE@";
#endif
match = true;
} else {
if (ace->ace_idsize != sizeof(tid))
continue;
#ifdef ACE_DEBUG
show_tid = true;
#endif
memcpy(&tid, &ace->ace_idbytes, sizeof(tid));
if (ace->ace_flags & L9P_ACEF_IDENTIFIER_GROUP) {
#ifdef ACE_DEBUG
acetype = "group";
#endif
match = l9p_ingroup(tid, gid, gids, ngids);
} else {
#ifdef ACE_DEBUG
acetype = "user";
#endif
match = tid == uid;
}
}
/*
* If this ACE applies to us, check remaining bits.
* If any of those bits also apply, check the type:
* DENY means "stop now", ALLOW means allow these bits
* and keep checking.
*/
#ifdef ACE_DEBUG
allowdeny = ace->ace_type == L9P_ACET_ACCESS_DENIED ?
"deny" : "allow";
#endif
if (match && (ace->ace_mask & (uint32_t)mask) != 0) {
#ifdef ACE_DEBUG
if (show_tid)
L9P_LOG(L9P_DEBUG,
"ACE: %s %s %d: mask 0x%x ace_mask 0x%x",
allowdeny, acetype, (int)tid,
(u_int)mask, (u_int)ace->ace_mask);
else
L9P_LOG(L9P_DEBUG,
"ACE: %s %s: mask 0x%x ace_mask 0x%x",
allowdeny, acetype,
(u_int)mask, (u_int)ace->ace_mask);
#endif
if (ace->ace_type == L9P_ACET_ACCESS_DENIED)
return (-1);
mask &= ~ace->ace_mask;
#ifdef ACE_DEBUG
L9P_LOG(L9P_DEBUG, "clear 0x%x: now mask=0x%x",
(u_int)ace->ace_mask, (u_int)mask);
#endif
} else {
#ifdef ACE_DEBUG
if (show_tid)
L9P_LOG(L9P_DEBUG,
"ACE: SKIP %s %s %d: "
"match %d mask 0x%x ace_mask 0x%x",
allowdeny, acetype, (int)tid,
(int)match, (u_int)mask,
(u_int)ace->ace_mask);
else
L9P_LOG(L9P_DEBUG,
"ACE: SKIP %s %s: "
"match %d mask 0x%x ace_mask 0x%x",
allowdeny, acetype,
(int)match, (u_int)mask,
(u_int)ace->ace_mask);
#endif
}
}
/* Return 1 if access definitely granted. */
#ifdef ACE_DEBUG
L9P_LOG(L9P_DEBUG, "ACE: end of ACEs, mask now 0x%x: %s",
mask, mask ? "no-definitive-answer" : "ALLOW");
#endif
return (mask == 0 ? 1 : 0);
}
/*
* Test against ACLs.
*
* The return value is normally 0 (access allowed) or EPERM
* (access denied), so it could just be a boolean....
*
* For "make new dir in dir" and "remove dir in dir", you must
* set the mask to test the directory permissions (not ADD_FILE but
* ADD_SUBDIRECTORY, and DELETE_CHILD). For "make new file in dir"
* you must set the opmask to test file ADD_FILE.
*
* The L9P_ACE_DELETE flag means "can delete this thing"; it's not
* clear whether it should override the parent directory's ACL if
* any. In our case it does not, but a caller may try
* L9P_ACE_DELETE_CHILD (separately, on its own) and then a
* (second, separate) L9P_ACE_DELETE, to make the permissions work
* as "or" instead of "and".
*
* Pass a NULL parent/pstat if they are not applicable, e.g.,
* for doing operations on an existing file, such as reading or
* writing data or attributes. Pass in a null child/cstat if
* that's not applicable, such as creating a new file/dir.
*
* NB: it's probably wise to allow the owner of any file to update
* the ACLs of that file, but we leave that test to the caller.
*/
int l9p_acl_check_access(int32_t opmask, struct l9p_acl_check_args *args)
{
struct l9p_acl *parent, *child;
struct stat *pstat, *cstat;
int32_t pop, cop;
size_t ngids;
uid_t uid;
gid_t gid, *gids;
int panswer, canswer;
assert(opmask != 0);
parent = args->aca_parent;
pstat = args->aca_pstat;
child = args->aca_child;
cstat = args->aca_cstat;
uid = args->aca_uid;
gid = args->aca_gid;
gids = args->aca_groups;
ngids = args->aca_ngroups;
#ifdef ACE_DEBUG
L9P_LOG(L9P_DEBUG,
"l9p_acl_check_access: opmask=0x%x uid=%ld gid=%ld ngids=%zd",
(u_int)opmask, (long)uid, (long)gid, ngids);
#endif
/*
* If caller said "superuser semantics", check that first.
* Note that we apply them regardless of ACLs.
*/
if (uid == 0 && args->aca_superuser)
return (0);
/*
* If told to ignore ACLs and use only stat-based permissions,
* discard any non-NULL ACL pointers.
*
* This will need some fancying up when we support POSIX ACLs.
*/
if ((args->aca_aclmode & L9P_ACM_NFS_ACL) == 0)
parent = child = NULL;
assert(parent == NULL || parent->acl_acetype == L9P_ACLTYPE_NFSv4);
assert(parent == NULL || pstat != NULL);
assert(child == NULL || child->acl_acetype == L9P_ACLTYPE_NFSv4);
assert(child == NULL || cstat != NULL);
assert(pstat != NULL || cstat != NULL);
/*
* If the operation is UNLINK we should have either both ACLs
* or no ACLs, but we won't require that here.
*
* If a parent ACL is supplied, it's a directory by definition.
* Make sure we're allowed to do this there, whatever this is.
* If a child ACL is supplied, check it too. Note that the
* DELETE permission only applies in the child though, not
* in the parent, and the DELETE_CHILD only applies in the
* parent.
*/
pop = cop = opmask;
if (parent != NULL || pstat != NULL) {
/*
* Remove child-only bits from parent op and
* parent-only bits from child op.
*
* L9P_ACE_DELETE is child-only.
*
* L9P_ACE_DELETE_CHILD is parent-only, and three data
* access bits overlap with three directory access bits.
* We should have child==NULL && cstat==NULL, so the
* three data bits should be redundant, but it's
* both trivial and safest to remove them anyway.
*/
pop &= ~L9P_ACE_DELETE;
cop &= ~(L9P_ACE_DELETE_CHILD | L9P_ACE_LIST_DIRECTORY |
L9P_ACE_ADD_FILE | L9P_ACE_ADD_SUBDIRECTORY);
} else {
/*
* Remove child-only bits from parent op. We need
* not bother since we just found we have no parent
* and no pstat, and hence won't actually *use* pop.
*
* pop &= ~(L9P_ACE_READ_DATA | L9P_ACE_WRITE_DATA |
* L9P_ACE_APPEND_DATA);
*/
}
panswer = 0;
canswer = 0;
if (parent != NULL)
panswer = l9p_check_aces(pop, parent, pstat,
uid, gid, gids, ngids);
if (child != NULL)
canswer = l9p_check_aces(cop, child, cstat,
uid, gid, gids, ngids);
if (panswer || canswer) {
/*
* Got a definitive answer from parent and/or
* child ACLs. We're not quite done yet though.
*/
if (opmask == L9P_ACOP_UNLINK) {
/*
* For UNLINK, we can get an allow from child
* and deny from parent, or vice versa. It's
* not 100% clear how to handle the two-answer
* case. ZFS says that if either says "allow",
* we allow, and if both definitely say "deny",
* we deny. This makes sense, so we do that
* here for all cases, even "strict".
*/
if (panswer > 0 || canswer > 0)
return (0);
if (panswer < 0 && canswer < 0)
return (EPERM);
/* non-definitive answer from one! move on */
} else {
/*
* Have at least one definitive answer, and
* should have only one; obey whichever
* one it is.
*/
if (panswer)
return (panswer < 0 ? EPERM : 0);
return (canswer < 0 ? EPERM : 0);
}
}
/*
* No definitive answer from ACLs alone. Check for ZFS style
* permissions checking and an "UNLINK" operation under ACLs.
* If so, find write-and-execute permission on parent.
* Note that WRITE overlaps with ADD_FILE -- that's ZFS's
* way of saying "allow write to dir" -- but EXECUTE is
* separate from LIST_DIRECTORY, so that's at least a little
* bit cleaner.
*
* Note also that only a definitive yes (both bits are
* explicitly allowed) results in granting unlink, and
* a definitive no (at least one bit explicitly denied)
* results in EPERM. Only "no answer" moves on.
*/
if ((args->aca_aclmode & L9P_ACM_ZFS_ACL) &&
opmask == L9P_ACOP_UNLINK && parent != NULL) {
panswer = l9p_check_aces(L9P_ACE_ADD_FILE | L9P_ACE_EXECUTE,
parent, pstat, uid, gid, gids, ngids);
if (panswer)
return (panswer < 0 ? EPERM : 0);
}
/*
* No definitive answer from ACLs.
*
* Try POSIX style rwx permissions if allowed. This should
* be rare, occurring mainly when caller supplied no ACLs
* or set the mode to suppress them.
*
* The stat to check is the parent's if we don't have a child
* (i.e., this is a dir op), or if the DELETE_CHILD bit is set
* (i.e., this is an unlink or similar). Otherwise it's the
* child's.
*/
if (args->aca_aclmode & L9P_ACM_STAT_MODE) {
struct stat *st;
int rwx, bits;
rwx = l9p_ace_mask_to_rwx(opmask);
if ((st = cstat) == NULL || (opmask & L9P_ACE_DELETE_CHILD))
st = pstat;
if (uid == st->st_uid)
bits = (st->st_mode >> 6) & 7;
else if (l9p_ingroup(st->st_gid, gid, gids, ngids))
bits = (st->st_mode >> 3) & 7;
else
bits = st->st_mode & 7;
/*
* If all the desired bits are set, we're OK.
*/
if ((rwx & bits) == rwx)
return (0);
}
/* all methods have failed, return EPERM */
return (EPERM);
}
/*
* Collapse fancy ACL operation mask down to simple Unix bits.
*
* Directory operations don't map that well. However, listing
* a directory really does require read permission, and adding
* or deleting files really does require write permission, so
* this is probably sufficient.
*/
int
l9p_ace_mask_to_rwx(int32_t opmask)
{
int rwx = 0;
if (opmask &
(L9P_ACE_READ_DATA | L9P_ACE_READ_NAMED_ATTRS |
L9P_ACE_READ_ATTRIBUTES | L9P_ACE_READ_ACL))
rwx |= 4;
if (opmask &
(L9P_ACE_WRITE_DATA | L9P_ACE_APPEND_DATA |
L9P_ACE_ADD_FILE | L9P_ACE_ADD_SUBDIRECTORY |
L9P_ACE_DELETE | L9P_ACE_DELETE_CHILD |
L9P_ACE_WRITE_NAMED_ATTRS | L9P_ACE_WRITE_ATTRIBUTES |
L9P_ACE_WRITE_ACL))
rwx |= 2;
if (opmask & L9P_ACE_EXECUTE)
rwx |= 1;
return (rwx);
}
#ifndef __APPLE__
/*
* Allocate new ACL holder and ACEs.
*/
static struct l9p_acl *
l9p_new_acl(uint32_t acetype, uint32_t aceasize)
{
struct l9p_acl *ret;
size_t asize, size;
asize = aceasize * sizeof(struct l9p_ace);
size = sizeof(struct l9p_acl) + asize;
ret = malloc(size);
if (ret != NULL) {
ret->acl_acetype = acetype;
ret->acl_nace = 0;
ret->acl_aceasize = aceasize;
}
return (ret);
}
/*
* Expand ACL to accomodate more entries.
*
* Currently won't shrink, only grow, so it's a fast no-op until
* we hit the allocated size. After that, it's best to grow in
* big chunks, or this will be O(n**2).
*/
static struct l9p_acl *
l9p_growacl(struct l9p_acl *acl, uint32_t aceasize)
{
struct l9p_acl *tmp;
size_t asize, size;
if (acl->acl_aceasize < aceasize) {
asize = aceasize * sizeof(struct l9p_ace);
size = sizeof(struct l9p_acl) + asize;
tmp = realloc(acl, size);
if (tmp == NULL)
free(acl);
acl = tmp;
}
return (acl);
}
/*
* Annoyingly, there's no POSIX-standard way to count the number
* of ACEs in a system ACL other than to walk through them all.
* This is silly, but at least 2n is still O(n), and the walk is
* short. (If the system ACL mysteriously grows, we'll handle
* that OK via growacl(), too.)
*/
static int
l9p_count_aces(acl_t sysacl)
{
acl_entry_t entry;
uint32_t n;
int id;
id = ACL_FIRST_ENTRY;
for (n = 0; acl_get_entry(sysacl, id, &entry) == 1; n++)
id = ACL_NEXT_ENTRY;
return ((int)n);
}
/*
* Create ACL with ACEs from the given acl_t. We use the given
* convert function on each ACE.
*/
static struct l9p_acl *
l9p_sysacl_to_acl(int acetype, acl_t sysacl, econvertfn *convert)
{
struct l9p_acl *acl;
acl_entry_t entry;
uint32_t n;
int error, id;
acl = l9p_new_acl((uint32_t)acetype, (uint32_t)l9p_count_aces(sysacl));
if (acl == NULL)
return (NULL);
id = ACL_FIRST_ENTRY;
for (n = 0;;) {
if (acl_get_entry(sysacl, id, &entry) != 1)
break;
acl = l9p_growacl(acl, n + 1);
if (acl == NULL)
return (NULL);
error = (*convert)(entry, &acl->acl_aces[n]);
id = ACL_NEXT_ENTRY;
if (error == 0)
n++;
}
acl->acl_nace = n;
return (acl);
}
#endif
#if defined(HAVE_POSIX_ACLS) && 0 /* not yet */
struct l9p_acl *
l9p_posix_acl_to_acl(acl_t sysacl)
{
}
#endif
#if defined(HAVE_FREEBSD_ACLS)
static int
l9p_frombsdnfs4(acl_entry_t sysace, struct l9p_ace *ace)
{
acl_tag_t tag; /* e.g., USER_OBJ, GROUP, etc */
acl_entry_type_t entry_type; /* e.g., allow/deny */
acl_permset_t absdperm;
acl_flagset_t absdflag;
acl_perm_t bsdperm; /* e.g., READ_DATA */
acl_flag_t bsdflag; /* e.g., FILE_INHERIT_ACE */
uint32_t flags, mask;
int error;
uid_t uid, *aid;
error = acl_get_tag_type(sysace, &tag);
if (error == 0)
error = acl_get_entry_type_np(sysace, &entry_type);
if (error == 0)
error = acl_get_flagset_np(sysace, &absdflag);
if (error == 0)
error = acl_get_permset(sysace, &absdperm);
if (error)
return (error);
flags = 0;
uid = 0;
aid = NULL;
/* move user/group/everyone + id-is-group-id into flags */
switch (tag) {
case ACL_USER_OBJ:
flags |= L9P_ACEF_OWNER;
break;
case ACL_GROUP_OBJ:
flags |= L9P_ACEF_GROUP;
break;
case ACL_EVERYONE:
flags |= L9P_ACEF_EVERYONE;
break;
case ACL_GROUP:
flags |= L9P_ACEF_IDENTIFIER_GROUP;
/* FALLTHROUGH */
case ACL_USER:
aid = acl_get_qualifier(sysace); /* ugh, this malloc()s */
if (aid == NULL)
return (ENOMEM);
uid = *(uid_t *)aid;
free(aid);
aid = &uid;
break;
default:
return (EINVAL); /* can't happen */
}
switch (entry_type) {
case ACL_ENTRY_TYPE_ALLOW:
ace->ace_type = L9P_ACET_ACCESS_ALLOWED;
break;
case ACL_ENTRY_TYPE_DENY:
ace->ace_type = L9P_ACET_ACCESS_DENIED;
break;
case ACL_ENTRY_TYPE_AUDIT:
ace->ace_type = L9P_ACET_SYSTEM_AUDIT;
break;
case ACL_ENTRY_TYPE_ALARM:
ace->ace_type = L9P_ACET_SYSTEM_ALARM;
break;
default:
return (EINVAL); /* can't happen */
}
/* transform remaining BSD flags to internal NFS-y form */
bsdflag = *absdflag;
if (bsdflag & ACL_ENTRY_FILE_INHERIT)
flags |= L9P_ACEF_FILE_INHERIT_ACE;
if (bsdflag & ACL_ENTRY_DIRECTORY_INHERIT)
flags |= L9P_ACEF_DIRECTORY_INHERIT_ACE;
if (bsdflag & ACL_ENTRY_NO_PROPAGATE_INHERIT)
flags |= L9P_ACEF_NO_PROPAGATE_INHERIT_ACE;
if (bsdflag & ACL_ENTRY_INHERIT_ONLY)
flags |= L9P_ACEF_INHERIT_ONLY_ACE;
if (bsdflag & ACL_ENTRY_SUCCESSFUL_ACCESS)
flags |= L9P_ACEF_SUCCESSFUL_ACCESS_ACE_FLAG;
if (bsdflag & ACL_ENTRY_FAILED_ACCESS)
flags |= L9P_ACEF_FAILED_ACCESS_ACE_FLAG;
ace->ace_flags = flags;
/*
* Transform BSD permissions to ace_mask. Note that directory
* vs file bits are the same in both sets, so we don't need
* to worry about that, at least.
*
* There seem to be no BSD equivalents for WRITE_RETENTION
* and WRITE_RETENTION_HOLD.
*/
mask = 0;
bsdperm = *absdperm;
if (bsdperm & ACL_READ_DATA)
mask |= L9P_ACE_READ_DATA;
if (bsdperm & ACL_WRITE_DATA)
mask |= L9P_ACE_WRITE_DATA;
if (bsdperm & ACL_APPEND_DATA)
mask |= L9P_ACE_APPEND_DATA;
if (bsdperm & ACL_READ_NAMED_ATTRS)
mask |= L9P_ACE_READ_NAMED_ATTRS;
if (bsdperm & ACL_WRITE_NAMED_ATTRS)
mask |= L9P_ACE_WRITE_NAMED_ATTRS;
if (bsdperm & ACL_EXECUTE)
mask |= L9P_ACE_EXECUTE;
if (bsdperm & ACL_DELETE_CHILD)
mask |= L9P_ACE_DELETE_CHILD;
if (bsdperm & ACL_READ_ATTRIBUTES)
mask |= L9P_ACE_READ_ATTRIBUTES;
if (bsdperm & ACL_WRITE_ATTRIBUTES)
mask |= L9P_ACE_WRITE_ATTRIBUTES;
/* L9P_ACE_WRITE_RETENTION */
/* L9P_ACE_WRITE_RETENTION_HOLD */
/* 0x00800 */
if (bsdperm & ACL_DELETE)
mask |= L9P_ACE_DELETE;
if (bsdperm & ACL_READ_ACL)
mask |= L9P_ACE_READ_ACL;
if (bsdperm & ACL_WRITE_ACL)
mask |= L9P_ACE_WRITE_ACL;
if (bsdperm & ACL_WRITE_OWNER)
mask |= L9P_ACE_WRITE_OWNER;
if (bsdperm & ACL_SYNCHRONIZE)
mask |= L9P_ACE_SYNCHRONIZE;
ace->ace_mask = mask;
/* fill in variable-size user or group ID bytes */
if (aid == NULL)
ace->ace_idsize = 0;
else {
ace->ace_idsize = sizeof(uid);
memcpy(&ace->ace_idbytes[0], aid, sizeof(uid));
}
return (0);
}
struct l9p_acl *
l9p_freebsd_nfsv4acl_to_acl(acl_t sysacl)
{
return (l9p_sysacl_to_acl(L9P_ACLTYPE_NFSv4, sysacl, l9p_frombsdnfs4));
}
#endif
#if defined(HAVE_DARWIN_ACLS) && 0 /* not yet */
struct l9p_acl *
l9p_darwin_nfsv4acl_to_acl(acl_t sysacl)
{
}
#endif