/** * security.c - Handling security/ACLs in NTFS. Originated from the Linux-NTFS project. * * Copyright (c) 2004 Anton Altaparmakov * Copyright (c) 2005-2006 Szabolcs Szakacsits * Copyright (c) 2006 Yura Pakhuchiy * Copyright (c) 2007-2015 Jean-Pierre Andre * * This program/include file is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as published * by the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program/include file is distributed in the hope that it will be * useful, but WITHOUT ANY WARRANTY; without even the implied warranty * of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program (in the main directory of the NTFS-3G * distribution in the file COPYING); if not, write to the Free Software * Foundation,Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #ifdef HAVE_STDIO_H #include #endif #ifdef HAVE_STDLIB_H #include #endif #ifdef HAVE_STRING_H #include #endif #ifdef HAVE_ERRNO_H #include #endif #ifdef HAVE_FCNTL_H #include #endif #ifdef HAVE_SYS_STAT_H #include #endif #include #include #include #include "compat.h" #include "param.h" #include "types.h" #include "layout.h" #include "attrib.h" #include "index.h" #include "dir.h" #include "bitmap.h" #include "security.h" #include "acls.h" #include "cache.h" #include "misc.h" #include "xattrs.h" /* * JPA NTFS constants or structs * should be moved to layout.h */ #define ALIGN_SDS_BLOCK 0x40000 /* Alignment for a $SDS block */ #define ALIGN_SDS_ENTRY 16 /* Alignment for a $SDS entry */ #define STUFFSZ 0x4000 /* unitary stuffing size for $SDS */ #define FIRST_SECURITY_ID 0x100 /* Lowest security id */ /* Mask for attributes which can be forced */ #define FILE_ATTR_SETTABLE ( FILE_ATTR_READONLY \ | FILE_ATTR_HIDDEN \ | FILE_ATTR_SYSTEM \ | FILE_ATTR_ARCHIVE \ | FILE_ATTR_TEMPORARY \ | FILE_ATTR_OFFLINE \ | FILE_ATTR_NOT_CONTENT_INDEXED ) struct SII { /* this is an image of an $SII index entry */ le16 offs; le16 size; le32 fill1; le16 indexsz; le16 indexksz; le16 flags; le16 fill2; le32 keysecurid; /* did not find official description for the following */ le32 hash; le32 securid; le32 dataoffsl; /* documented as badly aligned */ le32 dataoffsh; le32 datasize; } ; struct SDH { /* this is an image of an $SDH index entry */ le16 offs; le16 size; le32 fill1; le16 indexsz; le16 indexksz; le16 flags; le16 fill2; le32 keyhash; le32 keysecurid; /* did not find official description for the following */ le32 hash; le32 securid; le32 dataoffsl; le32 dataoffsh; le32 datasize; le32 fill3; } ; /* * A few useful constants */ static ntfschar sii_stream[] = { const_cpu_to_le16('$'), const_cpu_to_le16('S'), const_cpu_to_le16('I'), const_cpu_to_le16('I'), const_cpu_to_le16(0) }; static ntfschar sdh_stream[] = { const_cpu_to_le16('$'), const_cpu_to_le16('S'), const_cpu_to_le16('D'), const_cpu_to_le16('H'), const_cpu_to_le16(0) }; /* * null SID (S-1-0-0) */ extern const SID *nullsid; /* * The zero GUID. */ static const GUID __zero_guid = { const_cpu_to_le32(0), const_cpu_to_le16(0), const_cpu_to_le16(0), { 0, 0, 0, 0, 0, 0, 0, 0 } }; static const GUID *const zero_guid = &__zero_guid; /** * ntfs_guid_is_zero - check if a GUID is zero * @guid: [IN] guid to check * * Return TRUE if @guid is a valid pointer to a GUID and it is the zero GUID * and FALSE otherwise. */ BOOL ntfs_guid_is_zero(const GUID *guid) { return (memcmp(guid, zero_guid, sizeof(*zero_guid))); } /** * ntfs_guid_to_mbs - convert a GUID to a multi byte string * @guid: [IN] guid to convert * @guid_str: [OUT] string in which to return the GUID (optional) * * Convert the GUID pointed to by @guid to a multi byte string of the form * "XXXXXXXX-XXXX-XXXX-XXXX-XXXXXXXXXXXX". Therefore, @guid_str (if not NULL) * needs to be able to store at least 37 bytes. * * If @guid_str is not NULL it will contain the converted GUID on return. If * it is NULL a string will be allocated and this will be returned. The caller * is responsible for free()ing the string in that case. * * On success return the converted string and on failure return NULL with errno * set to the error code. */ char *ntfs_guid_to_mbs(const GUID *guid, char *guid_str) { char *_guid_str; int res; if (!guid) { errno = EINVAL; return NULL; } _guid_str = guid_str; if (!_guid_str) { _guid_str = (char*)ntfs_malloc(37); if (!_guid_str) return _guid_str; } res = snprintf(_guid_str, 37, "%08x-%04x-%04x-%02x%02x-%02x%02x%02x%02x%02x%02x", (unsigned int)le32_to_cpu(guid->data1), le16_to_cpu(guid->data2), le16_to_cpu(guid->data3), guid->data4[0], guid->data4[1], guid->data4[2], guid->data4[3], guid->data4[4], guid->data4[5], guid->data4[6], guid->data4[7]); if (res == 36) return _guid_str; if (!guid_str) free(_guid_str); errno = EINVAL; return NULL; } /** * ntfs_sid_to_mbs_size - determine maximum size for the string of a SID * @sid: [IN] SID for which to determine the maximum string size * * Determine the maximum multi byte string size in bytes which is needed to * store the standard textual representation of the SID pointed to by @sid. * See ntfs_sid_to_mbs(), below. * * On success return the maximum number of bytes needed to store the multi byte * string and on failure return -1 with errno set to the error code. */ int ntfs_sid_to_mbs_size(const SID *sid) { int size, i; if (!ntfs_valid_sid(sid)) { errno = EINVAL; return -1; } /* Start with "S-". */ size = 2; /* * Add the SID_REVISION. Hopefully the compiler will optimize this * away as SID_REVISION is a constant. */ for (i = SID_REVISION; i > 0; i /= 10) size++; /* Add the "-". */ size++; /* * Add the identifier authority. If it needs to be in decimal, the * maximum is 2^32-1 = 4294967295 = 10 characters. If it needs to be * in hexadecimal, then maximum is 0x665544332211 = 14 characters. */ if (!sid->identifier_authority.high_part) size += 10; else size += 14; /* * Finally, add the sub authorities. For each we have a "-" followed * by a decimal which can be up to 2^32-1 = 4294967295 = 10 characters. */ size += (1 + 10) * sid->sub_authority_count; /* We need the zero byte at the end, too. */ size++; return size * sizeof(char); } /** * ntfs_sid_to_mbs - convert a SID to a multi byte string * @sid: [IN] SID to convert * @sid_str: [OUT] string in which to return the SID (optional) * @sid_str_size: [IN] size in bytes of @sid_str * * Convert the SID pointed to by @sid to its standard textual representation. * @sid_str (if not NULL) needs to be able to store at least * ntfs_sid_to_mbs_size() bytes. @sid_str_size is the size in bytes of * @sid_str if @sid_str is not NULL. * * The standard textual representation of the SID is of the form: * S-R-I-S-S... * Where: * - The first "S" is the literal character 'S' identifying the following * digits as a SID. * - R is the revision level of the SID expressed as a sequence of digits * in decimal. * - I is the 48-bit identifier_authority, expressed as digits in decimal, * if I < 2^32, or hexadecimal prefixed by "0x", if I >= 2^32. * - S... is one or more sub_authority values, expressed as digits in * decimal. * * If @sid_str is not NULL it will contain the converted SUID on return. If it * is NULL a string will be allocated and this will be returned. The caller is * responsible for free()ing the string in that case. * * On success return the converted string and on failure return NULL with errno * set to the error code. */ char *ntfs_sid_to_mbs(const SID *sid, char *sid_str, size_t sid_str_size) { u64 u; le32 leauth; char *s; int i, j, cnt; /* * No need to check @sid if !@sid_str since ntfs_sid_to_mbs_size() will * check @sid, too. 8 is the minimum SID string size. */ if (sid_str && (sid_str_size < 8 || !ntfs_valid_sid(sid))) { errno = EINVAL; return NULL; } /* Allocate string if not provided. */ if (!sid_str) { cnt = ntfs_sid_to_mbs_size(sid); if (cnt < 0) return NULL; s = (char*)ntfs_malloc(cnt); if (!s) return s; sid_str = s; /* So we know we allocated it. */ sid_str_size = 0; } else { s = sid_str; cnt = sid_str_size; } /* Start with "S-R-". */ i = snprintf(s, cnt, "S-%hhu-", (unsigned char)sid->revision); if (i < 0 || i >= cnt) goto err_out; s += i; cnt -= i; /* Add the identifier authority. */ for (u = i = 0, j = 40; i < 6; i++, j -= 8) u += (u64)sid->identifier_authority.value[i] << j; if (!sid->identifier_authority.high_part) i = snprintf(s, cnt, "%lu", (unsigned long)u); else i = snprintf(s, cnt, "0x%llx", (unsigned long long)u); if (i < 0 || i >= cnt) goto err_out; s += i; cnt -= i; /* Finally, add the sub authorities. */ for (j = 0; j < sid->sub_authority_count; j++) { leauth = sid->sub_authority[j]; i = snprintf(s, cnt, "-%u", (unsigned int) le32_to_cpu(leauth)); if (i < 0 || i >= cnt) goto err_out; s += i; cnt -= i; } return sid_str; err_out: if (i >= cnt) i = EMSGSIZE; else i = errno; if (!sid_str_size) free(sid_str); errno = i; return NULL; } /** * ntfs_generate_guid - generatates a random current guid. * @guid: [OUT] pointer to a GUID struct to hold the generated guid. * * perhaps not a very good random number generator though... */ void ntfs_generate_guid(GUID *guid) { unsigned int i; u8 *p = (u8 *)guid; /* this is called at most once from mkntfs */ srandom(time((time_t*)NULL) ^ (getpid() << 16)); for (i = 0; i < sizeof(GUID); i++) { p[i] = (u8)(random() & 0xFF); if (i == 7) p[7] = (p[7] & 0x0F) | 0x40; if (i == 8) p[8] = (p[8] & 0x3F) | 0x80; } } /** * ntfs_security_hash - calculate the hash of a security descriptor * @sd: self-relative security descriptor whose hash to calculate * @length: size in bytes of the security descritor @sd * * Calculate the hash of the self-relative security descriptor @sd of length * @length bytes. * * This hash is used in the $Secure system file as the primary key for the $SDH * index and is also stored in the header of each security descriptor in the * $SDS data stream as well as in the index data of both the $SII and $SDH * indexes. In all three cases it forms part of the SDS_ENTRY_HEADER * structure. * * Return the calculated security hash in little endian. */ le32 ntfs_security_hash(const SECURITY_DESCRIPTOR_RELATIVE *sd, const u32 len) { const le32 *pos = (const le32*)sd; const le32 *end = pos + (len >> 2); u32 hash = 0; while (pos < end) { hash = le32_to_cpup(pos) + ntfs_rol32(hash, 3); pos++; } return cpu_to_le32(hash); } /* * Get the first entry of current index block * cut and pasted form ntfs_ie_get_first() in index.c */ static INDEX_ENTRY *ntfs_ie_get_first(INDEX_HEADER *ih) { return (INDEX_ENTRY*)((u8*)ih + le32_to_cpu(ih->entries_offset)); } /* * Stuff a 256KB block into $SDS before writing descriptors * into the block. * * This prevents $SDS from being automatically declared as sparse * when the second copy of the first security descriptor is written * 256KB further ahead. * * Having $SDS declared as a sparse file is not wrong by itself * and chkdsk leaves it as a sparse file. It does however complain * and add a sparse flag (0x0200) into field file_attributes of * STANDARD_INFORMATION of $Secure. This probably means that a * sparse attribute (ATTR_IS_SPARSE) is only allowed in sparse * files (FILE_ATTR_SPARSE_FILE). * * Windows normally does not convert to sparse attribute or sparse * file. Stuffing is just a way to get to the same result. */ static int entersecurity_stuff(ntfs_volume *vol, off_t offs) { int res; int written; unsigned long total; char *stuff; res = 0; total = 0; stuff = (char*)ntfs_malloc(STUFFSZ); if (stuff) { memset(stuff, 0, STUFFSZ); do { written = ntfs_attr_data_write(vol->secure_ni, STREAM_SDS, 4, stuff, STUFFSZ, offs); if (written == STUFFSZ) { total += STUFFSZ; offs += STUFFSZ; } else { errno = ENOSPC; res = -1; } } while (!res && (total < ALIGN_SDS_BLOCK)); free(stuff); } else { errno = ENOMEM; res = -1; } return (res); } /* * Enter a new security descriptor into $Secure (data only) * it has to be written twice with an offset of 256KB * * Should only be called by entersecurityattr() to ensure consistency * * Returns zero if sucessful */ static int entersecurity_data(ntfs_volume *vol, const SECURITY_DESCRIPTOR_RELATIVE *attr, s64 attrsz, le32 hash, le32 keyid, off_t offs, int gap) { int res; int written1; int written2; char *fullattr; int fullsz; SECURITY_DESCRIPTOR_HEADER *phsds; res = -1; fullsz = attrsz + gap + sizeof(SECURITY_DESCRIPTOR_HEADER); fullattr = (char*)ntfs_malloc(fullsz); if (fullattr) { /* * Clear the gap from previous descriptor * this could be useful for appending the second * copy to the end of file. When creating a new * 256K block, the gap is cleared while writing * the first copy */ if (gap) memset(fullattr,0,gap); memcpy(&fullattr[gap + sizeof(SECURITY_DESCRIPTOR_HEADER)], attr,attrsz); phsds = (SECURITY_DESCRIPTOR_HEADER*)&fullattr[gap]; phsds->hash = hash; phsds->security_id = keyid; phsds->offset = cpu_to_le64(offs); phsds->length = cpu_to_le32(fullsz - gap); written1 = ntfs_attr_data_write(vol->secure_ni, STREAM_SDS, 4, fullattr, fullsz, offs - gap); written2 = ntfs_attr_data_write(vol->secure_ni, STREAM_SDS, 4, fullattr, fullsz, offs - gap + ALIGN_SDS_BLOCK); if ((written1 == fullsz) && (written2 == written1)) { /* * Make sure the data size for $SDS marks the end * of the last security attribute. Windows uses * this to determine where the next attribute will * be written, which causes issues if chkdsk had * previously deleted the last entries without * adjusting the size. */ res = ntfs_attr_shrink_size(vol->secure_ni,STREAM_SDS, 4, offs - gap + ALIGN_SDS_BLOCK + fullsz); } else errno = ENOSPC; free(fullattr); } else errno = ENOMEM; return (res); } /* * Enter a new security descriptor in $Secure (indexes only) * * Should only be called by entersecurityattr() to ensure consistency * * Returns zero if sucessful */ static int entersecurity_indexes(ntfs_volume *vol, s64 attrsz, le32 hash, le32 keyid, off_t offs) { union { struct { le32 dataoffsl; le32 dataoffsh; } parts; le64 all; } realign; int res; ntfs_index_context *xsii; ntfs_index_context *xsdh; struct SII newsii; struct SDH newsdh; res = -1; /* enter a new $SII record */ xsii = vol->secure_xsii; ntfs_index_ctx_reinit(xsii); newsii.offs = const_cpu_to_le16(20); newsii.size = const_cpu_to_le16(sizeof(struct SII) - 20); newsii.fill1 = const_cpu_to_le32(0); newsii.indexsz = const_cpu_to_le16(sizeof(struct SII)); newsii.indexksz = const_cpu_to_le16(sizeof(SII_INDEX_KEY)); newsii.flags = const_cpu_to_le16(0); newsii.fill2 = const_cpu_to_le16(0); newsii.keysecurid = keyid; newsii.hash = hash; newsii.securid = keyid; realign.all = cpu_to_le64(offs); newsii.dataoffsh = realign.parts.dataoffsh; newsii.dataoffsl = realign.parts.dataoffsl; newsii.datasize = cpu_to_le32(attrsz + sizeof(SECURITY_DESCRIPTOR_HEADER)); if (!ntfs_ie_add(xsii,(INDEX_ENTRY*)&newsii)) { /* enter a new $SDH record */ xsdh = vol->secure_xsdh; ntfs_index_ctx_reinit(xsdh); newsdh.offs = const_cpu_to_le16(24); newsdh.size = const_cpu_to_le16( sizeof(SECURITY_DESCRIPTOR_HEADER)); newsdh.fill1 = const_cpu_to_le32(0); newsdh.indexsz = const_cpu_to_le16( sizeof(struct SDH)); newsdh.indexksz = const_cpu_to_le16( sizeof(SDH_INDEX_KEY)); newsdh.flags = const_cpu_to_le16(0); newsdh.fill2 = const_cpu_to_le16(0); newsdh.keyhash = hash; newsdh.keysecurid = keyid; newsdh.hash = hash; newsdh.securid = keyid; newsdh.dataoffsh = realign.parts.dataoffsh; newsdh.dataoffsl = realign.parts.dataoffsl; newsdh.datasize = cpu_to_le32(attrsz + sizeof(SECURITY_DESCRIPTOR_HEADER)); /* special filler value, Windows generally */ /* fills with 0x00490049, sometimes with zero */ newsdh.fill3 = const_cpu_to_le32(0x00490049); if (!ntfs_ie_add(xsdh,(INDEX_ENTRY*)&newsdh)) res = 0; } return (res); } /* * Enter a new security descriptor in $Secure (data and indexes) * Returns id of entry, or zero if there is a problem. * (should not be called for NTFS version < 3.0) * * important : calls have to be serialized, however no locking is * needed while fuse is not multithreaded */ static le32 entersecurityattr(ntfs_volume *vol, const SECURITY_DESCRIPTOR_RELATIVE *attr, s64 attrsz, le32 hash) { union { struct { le32 dataoffsl; le32 dataoffsh; } parts; le64 all; } realign; le32 securid; le32 keyid; u32 newkey; off_t offs; int gap; int size; BOOL found; struct SII *psii; INDEX_ENTRY *entry; INDEX_ENTRY *next; ntfs_index_context *xsii; int retries; ntfs_attr *na; int olderrno; /* find the first available securid beyond the last key */ /* in $Secure:$SII. This also determines the first */ /* available location in $Secure:$SDS, as this stream */ /* is always appended to and the id's are allocated */ /* in sequence */ securid = const_cpu_to_le32(0); xsii = vol->secure_xsii; ntfs_index_ctx_reinit(xsii); offs = size = 0; keyid = const_cpu_to_le32(-1); olderrno = errno; found = !ntfs_index_lookup((char*)&keyid, sizeof(SII_INDEX_KEY), xsii); if (!found && (errno != ENOENT)) { ntfs_log_perror("Inconsistency in index $SII"); psii = (struct SII*)NULL; } else { /* restore errno to avoid misinterpretation */ errno = olderrno; entry = xsii->entry; psii = (struct SII*)xsii->entry; } if (psii) { /* * Get last entry in block, but must get first one * one first, as we should already be beyond the * last one. For some reason the search for the last * entry sometimes does not return the last block... * we assume this can only happen in root block */ if (xsii->is_in_root) entry = ntfs_ie_get_first ((INDEX_HEADER*)&xsii->ir->index); else entry = ntfs_ie_get_first ((INDEX_HEADER*)&xsii->ib->index); /* * All index blocks should be at least half full * so there always is a last entry but one, * except when creating the first entry in index root. * This was however found not to be true : chkdsk * sometimes deletes all the (unused) keys in the last * index block without rebalancing the tree. * When this happens, a new search is restarted from * the smallest key. */ keyid = const_cpu_to_le32(0); retries = 0; while (entry) { next = ntfs_index_next(entry,xsii); if (next) { psii = (struct SII*)next; /* save last key and */ /* available position */ keyid = psii->keysecurid; realign.parts.dataoffsh = psii->dataoffsh; realign.parts.dataoffsl = psii->dataoffsl; offs = le64_to_cpu(realign.all); size = le32_to_cpu(psii->datasize); } entry = next; if (!entry && !keyid && !retries) { /* search failed, retry from smallest key */ ntfs_index_ctx_reinit(xsii); found = !ntfs_index_lookup((char*)&keyid, sizeof(SII_INDEX_KEY), xsii); if (!found && (errno != ENOENT)) { ntfs_log_perror("Index $SII is broken"); psii = (struct SII*)NULL; } else { /* restore errno */ errno = olderrno; entry = xsii->entry; psii = (struct SII*)entry; } if (psii && !(psii->flags & INDEX_ENTRY_END)) { /* save first key and */ /* available position */ keyid = psii->keysecurid; realign.parts.dataoffsh = psii->dataoffsh; realign.parts.dataoffsl = psii->dataoffsl; offs = le64_to_cpu(realign.all); size = le32_to_cpu(psii->datasize); } retries++; } } } if (!keyid) { /* * could not find any entry, before creating the first * entry, make a double check by making sure size of $SII * is less than needed for one entry */ securid = const_cpu_to_le32(0); na = ntfs_attr_open(vol->secure_ni,AT_INDEX_ROOT,sii_stream,4); if (na) { if ((size_t)na->data_size < (sizeof(struct SII) + sizeof(INDEX_ENTRY_HEADER))) { ntfs_log_error("Creating the first security_id\n"); securid = const_cpu_to_le32(FIRST_SECURITY_ID); } ntfs_attr_close(na); } if (!securid) { ntfs_log_error("Error creating a security_id\n"); errno = EIO; } } else { newkey = le32_to_cpu(keyid) + 1; securid = cpu_to_le32(newkey); } /* * The security attr has to be written twice 256KB * apart. This implies that offsets like * 0x40000*odd_integer must be left available for * the second copy. So align to next block when * the last byte overflows on a wrong block. */ if (securid) { gap = (-size) & (ALIGN_SDS_ENTRY - 1); offs += gap + size; if ((offs + attrsz + sizeof(SECURITY_DESCRIPTOR_HEADER) - 1) & ALIGN_SDS_BLOCK) { offs = ((offs + attrsz + sizeof(SECURITY_DESCRIPTOR_HEADER) - 1) | (ALIGN_SDS_BLOCK - 1)) + 1; } if (!(offs & (ALIGN_SDS_BLOCK - 1))) entersecurity_stuff(vol, offs); /* * now write the security attr to storage : * first data, then SII, then SDH * If failure occurs while writing SDS, data will never * be accessed through indexes, and will be overwritten * by the next allocated descriptor * If failure occurs while writing SII, the id has not * recorded and will be reallocated later * If failure occurs while writing SDH, the space allocated * in SDS or SII will not be reused, an inconsistency * will persist with no significant consequence */ if (entersecurity_data(vol, attr, attrsz, hash, securid, offs, gap) || entersecurity_indexes(vol, attrsz, hash, securid, offs)) securid = const_cpu_to_le32(0); } /* inode now is dirty, synchronize it all */ ntfs_index_entry_mark_dirty(vol->secure_xsii); ntfs_index_ctx_reinit(vol->secure_xsii); ntfs_index_entry_mark_dirty(vol->secure_xsdh); ntfs_index_ctx_reinit(vol->secure_xsdh); NInoSetDirty(vol->secure_ni); if (ntfs_inode_sync(vol->secure_ni)) ntfs_log_perror("Could not sync $Secure\n"); return (securid); } /* * Find a matching security descriptor in $Secure, * if none, allocate a new id and write the descriptor to storage * Returns id of entry, or zero if there is a problem. * * important : calls have to be serialized, however no locking is * needed while fuse is not multithreaded */ static le32 setsecurityattr(ntfs_volume *vol, const SECURITY_DESCRIPTOR_RELATIVE *attr, s64 attrsz) { struct SDH *psdh; /* this is an image of index (le) */ union { struct { le32 dataoffsl; le32 dataoffsh; } parts; le64 all; } realign; BOOL found; BOOL collision; size_t size; size_t rdsize; s64 offs; int res; ntfs_index_context *xsdh; char *oldattr; SDH_INDEX_KEY key; INDEX_ENTRY *entry; le32 securid; le32 hash; int olderrno; hash = ntfs_security_hash(attr,attrsz); oldattr = (char*)NULL; securid = const_cpu_to_le32(0); res = 0; xsdh = vol->secure_xsdh; if (vol->secure_ni && xsdh && !vol->secure_reentry++) { ntfs_index_ctx_reinit(xsdh); /* * find the nearest key as (hash,0) * (do not search for partial key : in case of collision, * it could return a key which is not the first one which * collides) */ key.hash = hash; key.security_id = const_cpu_to_le32(0); olderrno = errno; found = !ntfs_index_lookup((char*)&key, sizeof(SDH_INDEX_KEY), xsdh); if (!found && (errno != ENOENT)) ntfs_log_perror("Inconsistency in index $SDH"); else { /* restore errno to avoid misinterpretation */ errno = olderrno; entry = xsdh->entry; found = FALSE; /* * lookup() may return a node with no data, * if so get next */ if (entry->ie_flags & INDEX_ENTRY_END) entry = ntfs_index_next(entry,xsdh); do { collision = FALSE; psdh = (struct SDH*)entry; if (psdh) size = (size_t) le32_to_cpu(psdh->datasize) - sizeof(SECURITY_DESCRIPTOR_HEADER); else size = 0; /* if hash is not the same, the key is not present */ if (psdh && (size > 0) && (psdh->keyhash == hash)) { /* if hash is the same */ /* check the whole record */ realign.parts.dataoffsh = psdh->dataoffsh; realign.parts.dataoffsl = psdh->dataoffsl; offs = le64_to_cpu(realign.all) + sizeof(SECURITY_DESCRIPTOR_HEADER); oldattr = (char*)ntfs_malloc(size); if (oldattr) { rdsize = ntfs_attr_data_read( vol->secure_ni, STREAM_SDS, 4, oldattr, size, offs); found = (rdsize == size) && !memcmp(oldattr,attr,size); free(oldattr); /* if the records do not compare */ /* (hash collision), try next one */ if (!found) { entry = ntfs_index_next( entry,xsdh); collision = TRUE; } } else res = ENOMEM; } } while (collision && entry); if (found) securid = psdh->keysecurid; else { if (res) { errno = res; securid = const_cpu_to_le32(0); } else { /* * no matching key : * have to build a new one */ securid = entersecurityattr(vol, attr, attrsz, hash); } } } } if (--vol->secure_reentry) ntfs_log_perror("Reentry error, check no multithreading\n"); return (securid); } /* * Update the security descriptor of a file * Either as an attribute (complying with pre v3.x NTFS version) * or, when possible, as an entry in $Secure (for NTFS v3.x) * * returns 0 if success */ static int update_secur_descr(ntfs_volume *vol, char *newattr, ntfs_inode *ni) { int newattrsz; int written; int res; ntfs_attr *na; newattrsz = ntfs_attr_size(newattr); #if !FORCE_FORMAT_v1x if ((vol->major_ver < 3) || !vol->secure_ni) { #endif /* update for NTFS format v1.x */ /* update the old security attribute */ na = ntfs_attr_open(ni, AT_SECURITY_DESCRIPTOR, AT_UNNAMED, 0); if (na) { /* resize attribute */ res = ntfs_attr_truncate(na, (s64) newattrsz); /* overwrite value */ if (!res) { written = (int)ntfs_attr_pwrite(na, (s64) 0, (s64) newattrsz, newattr); if (written != newattrsz) { ntfs_log_error("Failed to update " "a v1.x security descriptor\n"); errno = EIO; res = -1; } } ntfs_attr_close(na); /* if old security attribute was found, also */ /* truncate standard information attribute to v1.x */ /* this is needed when security data is wanted */ /* as v1.x though volume is formatted for v3.x */ na = ntfs_attr_open(ni, AT_STANDARD_INFORMATION, AT_UNNAMED, 0); if (na) { clear_nino_flag(ni, v3_Extensions); /* * Truncating the record does not sweep extensions * from copy in memory. Clear security_id to be safe */ ni->security_id = const_cpu_to_le32(0); res = ntfs_attr_truncate(na, (s64)48); ntfs_attr_close(na); clear_nino_flag(ni, v3_Extensions); } } else { /* * insert the new security attribute if there * were none */ res = ntfs_attr_add(ni, AT_SECURITY_DESCRIPTOR, AT_UNNAMED, 0, (u8*)newattr, (s64) newattrsz); } #if !FORCE_FORMAT_v1x } else { /* update for NTFS format v3.x */ le32 securid; securid = setsecurityattr(vol, (const SECURITY_DESCRIPTOR_RELATIVE*)newattr, (s64)newattrsz); if (securid) { na = ntfs_attr_open(ni, AT_STANDARD_INFORMATION, AT_UNNAMED, 0); if (na) { res = 0; if (!test_nino_flag(ni, v3_Extensions)) { /* expand standard information attribute to v3.x */ res = ntfs_attr_truncate(na, (s64)sizeof(STANDARD_INFORMATION)); ni->owner_id = const_cpu_to_le32(0); ni->quota_charged = const_cpu_to_le64(0); ni->usn = const_cpu_to_le64(0); ntfs_attr_remove(ni, AT_SECURITY_DESCRIPTOR, AT_UNNAMED, 0); } set_nino_flag(ni, v3_Extensions); ni->security_id = securid; ntfs_attr_close(na); } else { ntfs_log_error("Failed to update " "standard informations\n"); errno = EIO; res = -1; } } else res = -1; } #endif /* mark node as dirty */ NInoSetDirty(ni); return (res); } /* * Upgrade the security descriptor of a file * This is intended to allow graceful upgrades for files which * were created in previous versions, with a security attributes * and no security id. * * It will allocate a security id and replace the individual * security attribute by a reference to the global one * * Special files are not upgraded (currently / and files in * directories /$*) * * Though most code is similar to update_secur_desc() it has * been kept apart to facilitate the further processing of * special cases or even to remove it if found dangerous. * * returns 0 if success, * 1 if not upgradable. This is not an error. * -1 if there is a problem */ static int upgrade_secur_desc(ntfs_volume *vol, const char *attr, ntfs_inode *ni) { int attrsz; int res; le32 securid; ntfs_attr *na; /* * upgrade requires NTFS format v3.x * also refuse upgrading for special files * whose number is less than FILE_first_user */ if ((vol->major_ver >= 3) && (ni->mft_no >= FILE_first_user)) { attrsz = ntfs_attr_size(attr); securid = setsecurityattr(vol, (const SECURITY_DESCRIPTOR_RELATIVE*)attr, (s64)attrsz); if (securid) { na = ntfs_attr_open(ni, AT_STANDARD_INFORMATION, AT_UNNAMED, 0); if (na) { /* expand standard information attribute to v3.x */ res = ntfs_attr_truncate(na, (s64)sizeof(STANDARD_INFORMATION)); ni->owner_id = const_cpu_to_le32(0); ni->quota_charged = const_cpu_to_le64(0); ni->usn = const_cpu_to_le64(0); ntfs_attr_remove(ni, AT_SECURITY_DESCRIPTOR, AT_UNNAMED, 0); set_nino_flag(ni, v3_Extensions); ni->security_id = securid; ntfs_attr_close(na); } else { ntfs_log_error("Failed to upgrade " "standard informations\n"); errno = EIO; res = -1; } } else res = -1; /* mark node as dirty */ NInoSetDirty(ni); } else res = 1; return (res); } /* * Optional simplified checking of group membership * * This only takes into account the groups defined in * /etc/group at initialization time. * It does not take into account the groups dynamically set by * setgroups() nor the changes in /etc/group since initialization * * This optional method could be useful if standard checking * leads to a performance concern. * * Should not be called for user root, however the group may be root * */ static BOOL staticgroupmember(struct SECURITY_CONTEXT *scx, uid_t uid, gid_t gid) { BOOL ingroup; int grcnt; gid_t *groups; struct MAPPING *user; ingroup = FALSE; if (uid) { user = scx->mapping[MAPUSERS]; while (user && ((uid_t)user->xid != uid)) user = user->next; if (user) { groups = user->groups; grcnt = user->grcnt; while ((--grcnt >= 0) && (groups[grcnt] != gid)) { } ingroup = (grcnt >= 0); } } return (ingroup); } #if defined(__sun) && defined (__SVR4) /* * Check whether current thread owner is member of file group * Solaris/OpenIndiana version * Should not be called for user root, however the group may be root * * The group list is available in "/proc/$PID/cred" * */ static BOOL groupmember(struct SECURITY_CONTEXT *scx, uid_t uid, gid_t gid) { typedef struct prcred { uid_t pr_euid; /* effective user id */ uid_t pr_ruid; /* real user id */ uid_t pr_suid; /* saved user id (from exec) */ gid_t pr_egid; /* effective group id */ gid_t pr_rgid; /* real group id */ gid_t pr_sgid; /* saved group id (from exec) */ int pr_ngroups; /* number of supplementary groups */ gid_t pr_groups[1]; /* array of supplementary groups */ } prcred_t; enum { readset = 16 }; prcred_t basecreds; gid_t groups[readset]; char filename[64]; int fd; int k; int cnt; gid_t *p; BOOL ismember; int got; pid_t tid; if (scx->vol->secure_flags & (1 << SECURITY_STATICGRPS)) ismember = staticgroupmember(scx, uid, gid); else { ismember = FALSE; /* default return */ tid = scx->tid; sprintf(filename,"/proc/%u/cred",tid); fd = open(filename,O_RDONLY); if (fd >= 0) { got = read(fd, &basecreds, sizeof(prcred_t)); if (got == sizeof(prcred_t)) { if (basecreds.pr_egid == gid) ismember = TRUE; p = basecreds.pr_groups; cnt = 1; k = 0; while (!ismember && (k < basecreds.pr_ngroups) && (cnt > 0) && (*p != gid)) { k++; cnt--; p++; if (cnt <= 0) { got = read(fd, groups, readset*sizeof(gid_t)); cnt = got/sizeof(gid_t); p = groups; } } if ((cnt > 0) && (k < basecreds.pr_ngroups)) ismember = TRUE; } close(fd); } } return (ismember); } #else /* defined(__sun) && defined (__SVR4) */ /* * Check whether current thread owner is member of file group * Linux version * Should not be called for user root, however the group may be root * * As indicated by Miklos Szeredi : * * The group list is available in * * /proc/$PID/task/$TID/status * * and fuse supplies TID in get_fuse_context()->pid. The only problem is * finding out PID, for which I have no good solution, except to iterate * through all processes. This is rather slow, but may be speeded up * with caching and heuristics (for single threaded programs PID = TID). * * The following implementation gets the group list from * /proc/$TID/task/$TID/status which apparently exists and * contains the same data. */ static BOOL groupmember(struct SECURITY_CONTEXT *scx, uid_t uid, gid_t gid) { static char key[] = "\nGroups:"; char buf[BUFSZ+1]; char filename[64]; enum { INKEY, INSEP, INNUM, INEND } state; int fd; char c; int matched; BOOL ismember; int got; char *p; gid_t grp; pid_t tid; if (scx->vol->secure_flags & (1 << SECURITY_STATICGRPS)) ismember = staticgroupmember(scx, uid, gid); else { ismember = FALSE; /* default return */ tid = scx->tid; sprintf(filename,"/proc/%u/task/%u/status",tid,tid); fd = open(filename,O_RDONLY); if (fd >= 0) { got = read(fd, buf, BUFSZ); buf[got] = 0; state = INKEY; matched = 0; p = buf; grp = 0; /* * A simple automaton to process lines like * Groups: 14 500 513 */ do { c = *p++; if (!c) { /* refill buffer */ got = read(fd, buf, BUFSZ); buf[got] = 0; p = buf; c = *p++; /* 0 at end of file */ } switch (state) { case INKEY : if (key[matched] == c) { if (!key[++matched]) state = INSEP; } else if (key[0] == c) matched = 1; else matched = 0; break; case INSEP : if ((c >= '0') && (c <= '9')) { grp = c - '0'; state = INNUM; } else if ((c != ' ') && (c != '\t')) state = INEND; break; case INNUM : if ((c >= '0') && (c <= '9')) grp = grp*10 + c - '0'; else { ismember = (grp == gid); if ((c != ' ') && (c != '\t')) state = INEND; else state = INSEP; } default : break; } } while (!ismember && c && (state != INEND)); close(fd); if (!c) ntfs_log_error("No group record found in %s\n",filename); } else ntfs_log_error("Could not open %s\n",filename); } return (ismember); } #endif /* defined(__sun) && defined (__SVR4) */ #if POSIXACLS /* * Extract the basic permissions from a Posix ACL * * This is only to be used when Posix ACLs are compiled in, * but not enabled in the mount options. * * it replaces the permission mask by the group permissions. * If special groups are mapped, they are also considered as world. */ static int ntfs_basic_perms(const struct SECURITY_CONTEXT *scx, const struct POSIX_SECURITY *pxdesc) { int k; int perms; const struct POSIX_ACE *pace; const struct MAPPING* group; k = 0; perms = pxdesc->mode; for (k=0; k < pxdesc->acccnt; k++) { pace = &pxdesc->acl.ace[k]; if (pace->tag == POSIX_ACL_GROUP_OBJ) perms = (perms & 07707) | ((pace->perms & 7) << 3); else if (pace->tag == POSIX_ACL_GROUP) { group = scx->mapping[MAPGROUPS]; while (group && (group->xid != pace->id)) group = group->next; if (group && group->grcnt && (*(group->groups) == (gid_t)pace->id)) perms |= pace->perms & 7; } } return (perms); } #endif /* POSIXACLS */ /* * Cacheing is done two-way : * - from uid, gid and perm to securid (CACHED_SECURID) * - from a securid to uid, gid and perm (CACHED_PERMISSIONS) * * CACHED_SECURID data is kept in a most-recent-first list * which should not be too long to be efficient. Its optimal * size is depends on usage and is hard to determine. * * CACHED_PERMISSIONS data is kept in a two-level indexed array. It * is optimal at the expense of storage. Use of a most-recent-first * list would save memory and provide similar performances for * standard usage, but not for file servers with too many file * owners * * CACHED_PERMISSIONS_LEGACY is a special case for CACHED_PERMISSIONS * for legacy directories which were not allocated a security_id * it is organized in a most-recent-first list. * * In main caches, data is never invalidated, as the meaning of * a security_id only changes when user mapping is changed, which * current implies remounting. However returned entries may be * overwritten at next update, so data has to be copied elsewhere * before another cache update is made. * In legacy cache, data has to be invalidated when protection is * changed. * * Though the same data may be found in both list, they * must be kept separately : the interpretation of ACL * in both direction are approximations which could be non * reciprocal for some configuration of the user mapping data * * During the process of recompiling ntfs-3g from a tgz archive, * security processing added 7.6% to the cpu time used by ntfs-3g * and 30% if the cache is disabled. */ static struct PERMISSIONS_CACHE *create_caches(struct SECURITY_CONTEXT *scx, u32 securindex) { struct PERMISSIONS_CACHE *cache; unsigned int index1; unsigned int i; cache = (struct PERMISSIONS_CACHE*)NULL; /* create the first permissions blocks */ index1 = securindex >> CACHE_PERMISSIONS_BITS; cache = (struct PERMISSIONS_CACHE*) ntfs_malloc(sizeof(struct PERMISSIONS_CACHE) + index1*sizeof(struct CACHED_PERMISSIONS*)); if (cache) { cache->head.last = index1; cache->head.p_reads = 0; cache->head.p_hits = 0; cache->head.p_writes = 0; *scx->pseccache = cache; for (i=0; i<=index1; i++) cache->cachetable[i] = (struct CACHED_PERMISSIONS*)NULL; } return (cache); } /* * Free memory used by caches * The only purpose is to facilitate the detection of memory leaks */ static void free_caches(struct SECURITY_CONTEXT *scx) { unsigned int index1; struct PERMISSIONS_CACHE *pseccache; pseccache = *scx->pseccache; if (pseccache) { for (index1=0; index1<=pseccache->head.last; index1++) if (pseccache->cachetable[index1]) { #if POSIXACLS struct CACHED_PERMISSIONS *cacheentry; unsigned int index2; for (index2=0; index2<(1<< CACHE_PERMISSIONS_BITS); index2++) { cacheentry = &pseccache->cachetable[index1][index2]; if (cacheentry->valid && cacheentry->pxdesc) free(cacheentry->pxdesc); } #endif free(pseccache->cachetable[index1]); } free(pseccache); } } static int compare(const struct CACHED_SECURID *cached, const struct CACHED_SECURID *item) { #if POSIXACLS size_t csize; size_t isize; /* only compare data and sizes */ csize = (cached->variable ? sizeof(struct POSIX_ACL) + (((struct POSIX_SECURITY*)cached->variable)->acccnt + ((struct POSIX_SECURITY*)cached->variable)->defcnt) *sizeof(struct POSIX_ACE) : 0); isize = (item->variable ? sizeof(struct POSIX_ACL) + (((struct POSIX_SECURITY*)item->variable)->acccnt + ((struct POSIX_SECURITY*)item->variable)->defcnt) *sizeof(struct POSIX_ACE) : 0); return ((cached->uid != item->uid) || (cached->gid != item->gid) || (cached->dmode != item->dmode) || (csize != isize) || (csize && isize && memcmp(&((struct POSIX_SECURITY*)cached->variable)->acl, &((struct POSIX_SECURITY*)item->variable)->acl, csize))); #else return ((cached->uid != item->uid) || (cached->gid != item->gid) || (cached->dmode != item->dmode)); #endif } static int leg_compare(const struct CACHED_PERMISSIONS_LEGACY *cached, const struct CACHED_PERMISSIONS_LEGACY *item) { return (cached->mft_no != item->mft_no); } /* * Resize permission cache table * do not call unless resizing is needed * * If allocation fails, the cache size is not updated * Lack of memory is not considered as an error, the cache is left * consistent and errno is not set. */ static void resize_cache(struct SECURITY_CONTEXT *scx, u32 securindex) { struct PERMISSIONS_CACHE *oldcache; struct PERMISSIONS_CACHE *newcache; int newcnt; int oldcnt; unsigned int index1; unsigned int i; oldcache = *scx->pseccache; index1 = securindex >> CACHE_PERMISSIONS_BITS; newcnt = index1 + 1; if (newcnt <= ((CACHE_PERMISSIONS_SIZE + (1 << CACHE_PERMISSIONS_BITS) - 1) >> CACHE_PERMISSIONS_BITS)) { /* expand cache beyond current end, do not use realloc() */ /* to avoid losing data when there is no more memory */ oldcnt = oldcache->head.last + 1; newcache = (struct PERMISSIONS_CACHE*) ntfs_malloc( sizeof(struct PERMISSIONS_CACHE) + (newcnt - 1)*sizeof(struct CACHED_PERMISSIONS*)); if (newcache) { memcpy(newcache,oldcache, sizeof(struct PERMISSIONS_CACHE) + (oldcnt - 1)*sizeof(struct CACHED_PERMISSIONS*)); free(oldcache); /* mark new entries as not valid */ for (i=newcache->head.last+1; i<=index1; i++) newcache->cachetable[i] = (struct CACHED_PERMISSIONS*)NULL; newcache->head.last = index1; *scx->pseccache = newcache; } } } /* * Enter uid, gid and mode into cache, if possible * * returns the updated or created cache entry, * or NULL if not possible (typically if there is no * security id associated) */ #if POSIXACLS static struct CACHED_PERMISSIONS *enter_cache(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, uid_t uid, gid_t gid, struct POSIX_SECURITY *pxdesc) #else static struct CACHED_PERMISSIONS *enter_cache(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, uid_t uid, gid_t gid, mode_t mode) #endif { struct CACHED_PERMISSIONS *cacheentry; struct CACHED_PERMISSIONS *cacheblock; struct PERMISSIONS_CACHE *pcache; u32 securindex; #if POSIXACLS int pxsize; struct POSIX_SECURITY *pxcached; #endif unsigned int index1; unsigned int index2; int i; /* cacheing is only possible if a security_id has been defined */ if (test_nino_flag(ni, v3_Extensions) && ni->security_id) { /* * Immediately test the most frequent situation * where the entry exists */ securindex = le32_to_cpu(ni->security_id); index1 = securindex >> CACHE_PERMISSIONS_BITS; index2 = securindex & ((1 << CACHE_PERMISSIONS_BITS) - 1); pcache = *scx->pseccache; if (pcache && (pcache->head.last >= index1) && pcache->cachetable[index1]) { cacheentry = &pcache->cachetable[index1][index2]; cacheentry->uid = uid; cacheentry->gid = gid; #if POSIXACLS if (cacheentry->valid && cacheentry->pxdesc) free(cacheentry->pxdesc); if (pxdesc) { pxsize = sizeof(struct POSIX_SECURITY) + (pxdesc->acccnt + pxdesc->defcnt)*sizeof(struct POSIX_ACE); pxcached = (struct POSIX_SECURITY*)malloc(pxsize); if (pxcached) { memcpy(pxcached, pxdesc, pxsize); cacheentry->pxdesc = pxcached; } else { cacheentry->valid = 0; cacheentry = (struct CACHED_PERMISSIONS*)NULL; } cacheentry->mode = pxdesc->mode & 07777; } else cacheentry->pxdesc = (struct POSIX_SECURITY*)NULL; #else cacheentry->mode = mode & 07777; #endif cacheentry->inh_fileid = const_cpu_to_le32(0); cacheentry->inh_dirid = const_cpu_to_le32(0); cacheentry->valid = 1; pcache->head.p_writes++; } else { if (!pcache) { /* create the first cache block */ pcache = create_caches(scx, securindex); } else { if (index1 > pcache->head.last) { resize_cache(scx, securindex); pcache = *scx->pseccache; } } /* allocate block, if cache table was allocated */ if (pcache && (index1 <= pcache->head.last)) { cacheblock = (struct CACHED_PERMISSIONS*) malloc(sizeof(struct CACHED_PERMISSIONS) << CACHE_PERMISSIONS_BITS); pcache->cachetable[index1] = cacheblock; for (i=0; i<(1 << CACHE_PERMISSIONS_BITS); i++) cacheblock[i].valid = 0; cacheentry = &cacheblock[index2]; if (cacheentry) { cacheentry->uid = uid; cacheentry->gid = gid; #if POSIXACLS if (pxdesc) { pxsize = sizeof(struct POSIX_SECURITY) + (pxdesc->acccnt + pxdesc->defcnt)*sizeof(struct POSIX_ACE); pxcached = (struct POSIX_SECURITY*)malloc(pxsize); if (pxcached) { memcpy(pxcached, pxdesc, pxsize); cacheentry->pxdesc = pxcached; } else { cacheentry->valid = 0; cacheentry = (struct CACHED_PERMISSIONS*)NULL; } cacheentry->mode = pxdesc->mode & 07777; } else cacheentry->pxdesc = (struct POSIX_SECURITY*)NULL; #else cacheentry->mode = mode & 07777; #endif cacheentry->inh_fileid = const_cpu_to_le32(0); cacheentry->inh_dirid = const_cpu_to_le32(0); cacheentry->valid = 1; pcache->head.p_writes++; } } else cacheentry = (struct CACHED_PERMISSIONS*)NULL; } } else { cacheentry = (struct CACHED_PERMISSIONS*)NULL; #if CACHE_LEGACY_SIZE if (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) { struct CACHED_PERMISSIONS_LEGACY wanted; struct CACHED_PERMISSIONS_LEGACY *legacy; wanted.perm.uid = uid; wanted.perm.gid = gid; #if POSIXACLS wanted.perm.mode = pxdesc->mode & 07777; wanted.perm.inh_fileid = const_cpu_to_le32(0); wanted.perm.inh_dirid = const_cpu_to_le32(0); wanted.mft_no = ni->mft_no; wanted.variable = (void*)pxdesc; wanted.varsize = sizeof(struct POSIX_SECURITY) + (pxdesc->acccnt + pxdesc->defcnt)*sizeof(struct POSIX_ACE); #else wanted.perm.mode = mode & 07777; wanted.perm.inh_fileid = const_cpu_to_le32(0); wanted.perm.inh_dirid = const_cpu_to_le32(0); wanted.mft_no = ni->mft_no; wanted.variable = (void*)NULL; wanted.varsize = 0; #endif legacy = (struct CACHED_PERMISSIONS_LEGACY*)ntfs_enter_cache( scx->vol->legacy_cache, GENERIC(&wanted), (cache_compare)leg_compare); if (legacy) { cacheentry = &legacy->perm; #if POSIXACLS /* * give direct access to the cached pxdesc * in the permissions structure */ cacheentry->pxdesc = legacy->variable; #endif } } #endif } return (cacheentry); } /* * Fetch owner, group and permission of a file, if cached * * Beware : do not use the returned entry after a cache update : * the cache may be relocated making the returned entry meaningless * * returns the cache entry, or NULL if not available */ static struct CACHED_PERMISSIONS *fetch_cache(struct SECURITY_CONTEXT *scx, ntfs_inode *ni) { struct CACHED_PERMISSIONS *cacheentry; struct PERMISSIONS_CACHE *pcache; u32 securindex; unsigned int index1; unsigned int index2; /* cacheing is only possible if a security_id has been defined */ cacheentry = (struct CACHED_PERMISSIONS*)NULL; if (test_nino_flag(ni, v3_Extensions) && (ni->security_id)) { securindex = le32_to_cpu(ni->security_id); index1 = securindex >> CACHE_PERMISSIONS_BITS; index2 = securindex & ((1 << CACHE_PERMISSIONS_BITS) - 1); pcache = *scx->pseccache; if (pcache && (pcache->head.last >= index1) && pcache->cachetable[index1]) { cacheentry = &pcache->cachetable[index1][index2]; /* reject if entry is not valid */ if (!cacheentry->valid) cacheentry = (struct CACHED_PERMISSIONS*)NULL; else pcache->head.p_hits++; if (pcache) pcache->head.p_reads++; } } #if CACHE_LEGACY_SIZE else { cacheentry = (struct CACHED_PERMISSIONS*)NULL; if (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) { struct CACHED_PERMISSIONS_LEGACY wanted; struct CACHED_PERMISSIONS_LEGACY *legacy; wanted.mft_no = ni->mft_no; wanted.variable = (void*)NULL; wanted.varsize = 0; legacy = (struct CACHED_PERMISSIONS_LEGACY*)ntfs_fetch_cache( scx->vol->legacy_cache, GENERIC(&wanted), (cache_compare)leg_compare); if (legacy) cacheentry = &legacy->perm; } } #endif #if POSIXACLS if (cacheentry && !cacheentry->pxdesc) { ntfs_log_error("No Posix descriptor in cache\n"); cacheentry = (struct CACHED_PERMISSIONS*)NULL; } #endif return (cacheentry); } /* * Retrieve a security attribute from $Secure */ static char *retrievesecurityattr(ntfs_volume *vol, SII_INDEX_KEY id) { struct SII *psii; union { struct { le32 dataoffsl; le32 dataoffsh; } parts; le64 all; } realign; int found; size_t size; size_t rdsize; s64 offs; ntfs_inode *ni; ntfs_index_context *xsii; char *securattr; securattr = (char*)NULL; ni = vol->secure_ni; xsii = vol->secure_xsii; if (ni && xsii) { ntfs_index_ctx_reinit(xsii); found = !ntfs_index_lookup((char*)&id, sizeof(SII_INDEX_KEY), xsii); if (found) { psii = (struct SII*)xsii->entry; size = (size_t) le32_to_cpu(psii->datasize) - sizeof(SECURITY_DESCRIPTOR_HEADER); /* work around bad alignment problem */ realign.parts.dataoffsh = psii->dataoffsh; realign.parts.dataoffsl = psii->dataoffsl; offs = le64_to_cpu(realign.all) + sizeof(SECURITY_DESCRIPTOR_HEADER); securattr = (char*)ntfs_malloc(size); if (securattr) { rdsize = ntfs_attr_data_read( ni, STREAM_SDS, 4, securattr, size, offs); if ((rdsize != size) || !ntfs_valid_descr(securattr, rdsize)) { /* error to be logged by caller */ free(securattr); securattr = (char*)NULL; } } } else if (errno != ENOENT) ntfs_log_perror("Inconsistency in index $SII"); } if (!securattr) { ntfs_log_error("Failed to retrieve a security descriptor\n"); errno = EIO; } return (securattr); } /* * Get the security descriptor associated to a file * * Either : * - read the security descriptor attribute (v1.x format) * - or find the descriptor in $Secure:$SDS (v3.x format) * * in both case, sanity checks are done on the attribute and * the descriptor can be assumed safe * * The returned descriptor is dynamically allocated and has to be freed */ static char *getsecurityattr(ntfs_volume *vol, ntfs_inode *ni) { SII_INDEX_KEY securid; char *securattr; s64 readallsz; /* * Warning : in some situations, after fixing by chkdsk, * v3_Extensions are marked present (long standard informations) * with a default security descriptor inserted in an * attribute */ if (test_nino_flag(ni, v3_Extensions) && vol->secure_ni && ni->security_id) { /* get v3.x descriptor in $Secure */ securid.security_id = ni->security_id; securattr = retrievesecurityattr(vol,securid); if (!securattr) ntfs_log_error("Bad security descriptor for 0x%lx\n", (long)le32_to_cpu(ni->security_id)); } else { /* get v1.x security attribute */ readallsz = 0; securattr = ntfs_attr_readall(ni, AT_SECURITY_DESCRIPTOR, AT_UNNAMED, 0, &readallsz); if (securattr && !ntfs_valid_descr(securattr, readallsz)) { ntfs_log_error("Bad security descriptor for inode %lld\n", (long long)ni->mft_no); free(securattr); securattr = (char*)NULL; } } if (!securattr) { /* * in some situations, there is no security * descriptor, and chkdsk does not detect or fix * anything. This could be a normal situation. * When this happens, simulate a descriptor with * minimum rights, so that a real descriptor can * be created by chown or chmod */ ntfs_log_error("No security descriptor found for inode %lld\n", (long long)ni->mft_no); securattr = ntfs_build_descr(0, 0, adminsid, adminsid); } return (securattr); } #if POSIXACLS /* * Determine which access types to a file are allowed * according to the relation of current process to the file * * When Posix ACLs are compiled in but not enabled in the mount * options POSIX_ACL_USER, POSIX_ACL_GROUP and POSIX_ACL_MASK * are ignored. */ static int access_check_posix(struct SECURITY_CONTEXT *scx, struct POSIX_SECURITY *pxdesc, mode_t request, uid_t uid, gid_t gid) { struct POSIX_ACE *pxace; int userperms; int groupperms; int mask; BOOL somegroup; BOOL needgroups; BOOL noacl; mode_t perms; int i; noacl = !(scx->vol->secure_flags & (1 << SECURITY_ACL)); if (noacl) perms = ntfs_basic_perms(scx, pxdesc); else perms = pxdesc->mode; /* owner and root access */ if (!scx->uid || (uid == scx->uid)) { if (!scx->uid) { /* root access if owner or other execution */ if (perms & 0101) perms |= 01777; else { /* root access if some group execution */ groupperms = 0; mask = 7; for (i=pxdesc->acccnt-1; i>=0 ; i--) { pxace = &pxdesc->acl.ace[i]; switch (pxace->tag) { case POSIX_ACL_USER_OBJ : case POSIX_ACL_GROUP_OBJ : groupperms |= pxace->perms; break; case POSIX_ACL_GROUP : if (!noacl) groupperms |= pxace->perms; break; case POSIX_ACL_MASK : if (!noacl) mask = pxace->perms & 7; break; default : break; } } perms = (groupperms & mask & 1) | 6; } } else perms &= 07700; } else { /* * analyze designated users, get mask * and identify whether we need to check * the group memberships. The groups are * not needed when all groups have the * same permissions as other for the * requested modes. */ userperms = -1; groupperms = -1; needgroups = FALSE; mask = 7; for (i=pxdesc->acccnt-1; i>=0 ; i--) { pxace = &pxdesc->acl.ace[i]; switch (pxace->tag) { case POSIX_ACL_USER : if (!noacl && ((uid_t)pxace->id == scx->uid)) userperms = pxace->perms; break; case POSIX_ACL_MASK : if (!noacl) mask = pxace->perms & 7; break; case POSIX_ACL_GROUP_OBJ : if (((pxace->perms & mask) ^ perms) & (request >> 6) & 7) needgroups = TRUE; break; case POSIX_ACL_GROUP : if (!noacl && (((pxace->perms & mask) ^ perms) & (request >> 6) & 7)) needgroups = TRUE; break; default : break; } } /* designated users */ if (userperms >= 0) perms = (perms & 07000) + (userperms & mask); else if (!needgroups) perms &= 07007; else { /* owning group */ if (!(~(perms >> 3) & request & mask) && ((gid == scx->gid) || groupmember(scx, scx->uid, gid))) perms &= 07070; else if (!noacl) { /* other groups */ groupperms = -1; somegroup = FALSE; for (i=pxdesc->acccnt-1; i>=0 ; i--) { pxace = &pxdesc->acl.ace[i]; if ((pxace->tag == POSIX_ACL_GROUP) && groupmember(scx, scx->uid, pxace->id)) { if (!(~pxace->perms & request & mask)) groupperms = pxace->perms; somegroup = TRUE; } } if (groupperms >= 0) perms = (perms & 07000) + (groupperms & mask); else if (somegroup) perms = 0; else perms &= 07007; } else perms &= 07007; } } return (perms); } /* * Get permissions to access a file * Takes into account the relation of user to file (owner, group, ...) * Do no use as mode of the file * Do no call if default_permissions is set * * returns -1 if there is a problem */ static int ntfs_get_perm(struct SECURITY_CONTEXT *scx, ntfs_inode * ni, mode_t request) { const SECURITY_DESCRIPTOR_RELATIVE *phead; const struct CACHED_PERMISSIONS *cached; char *securattr; const SID *usid; /* owner of file/directory */ const SID *gsid; /* group of file/directory */ uid_t uid; gid_t gid; int perm; BOOL isdir; struct POSIX_SECURITY *pxdesc; if (!scx->mapping[MAPUSERS]) perm = 07777; else { /* check whether available in cache */ cached = fetch_cache(scx,ni); if (cached) { uid = cached->uid; gid = cached->gid; perm = access_check_posix(scx,cached->pxdesc,request,uid,gid); } else { perm = 0; /* default to no permission */ isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); securattr = getsecurityattr(scx->vol, ni); if (securattr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*) securattr; gsid = (const SID*)& securattr[le32_to_cpu(phead->group)]; gid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); #if OWNERFROMACL usid = ntfs_acl_owner(securattr); pxdesc = ntfs_build_permissions_posix(scx->mapping,securattr, usid, gsid, isdir); if (pxdesc) perm = pxdesc->mode & 07777; else perm = -1; uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #else usid = (const SID*)& securattr[le32_to_cpu(phead->owner)]; pxdesc = ntfs_build_permissions_posix(scx,securattr, usid, gsid, isdir); if (pxdesc) perm = pxdesc->mode & 07777; else perm = -1; if (!perm && ntfs_same_sid(usid, adminsid)) { uid = find_tenant(scx, securattr); if (uid) perm = 0700; } else uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #endif /* * Create a security id if there were none * and upgrade option is selected */ if (!test_nino_flag(ni, v3_Extensions) && (perm >= 0) && (scx->vol->secure_flags & (1 << SECURITY_ADDSECURIDS))) { upgrade_secur_desc(scx->vol, securattr, ni); /* * fetch owner and group for cacheing * if there is a securid */ } if (test_nino_flag(ni, v3_Extensions) && (perm >= 0)) { enter_cache(scx, ni, uid, gid, pxdesc); } if (pxdesc) { perm = access_check_posix(scx,pxdesc,request,uid,gid); free(pxdesc); } free(securattr); } else { perm = -1; uid = gid = 0; } } } return (perm); } /* * Get a Posix ACL * * returns size or -errno if there is a problem * if size was too small, no copy is done and errno is not set, * the caller is expected to issue a new call */ int ntfs_get_posix_acl(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, const char *name, char *value, size_t size) { const SECURITY_DESCRIPTOR_RELATIVE *phead; struct POSIX_SECURITY *pxdesc; const struct CACHED_PERMISSIONS *cached; char *securattr; const SID *usid; /* owner of file/directory */ const SID *gsid; /* group of file/directory */ uid_t uid; gid_t gid; BOOL isdir; size_t outsize; outsize = 0; /* default to error */ if (!scx->mapping[MAPUSERS]) errno = ENOTSUP; else { /* check whether available in cache */ cached = fetch_cache(scx,ni); if (cached) pxdesc = cached->pxdesc; else { securattr = getsecurityattr(scx->vol, ni); isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); if (securattr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*) securattr; gsid = (const SID*)& securattr[le32_to_cpu(phead->group)]; #if OWNERFROMACL usid = ntfs_acl_owner(securattr); #else usid = (const SID*)& securattr[le32_to_cpu(phead->owner)]; #endif pxdesc = ntfs_build_permissions_posix(scx->mapping,securattr, usid, gsid, isdir); /* * fetch owner and group for cacheing */ if (pxdesc) { /* * Create a security id if there were none * and upgrade option is selected */ if (!test_nino_flag(ni, v3_Extensions) && (scx->vol->secure_flags & (1 << SECURITY_ADDSECURIDS))) { upgrade_secur_desc(scx->vol, securattr, ni); } #if OWNERFROMACL uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #else if (!(pxdesc->mode & 07777) && ntfs_same_sid(usid, adminsid)) { uid = find_tenant(scx, securattr); } else uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #endif gid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); if (pxdesc->tagsset & POSIX_ACL_EXTENSIONS) enter_cache(scx, ni, uid, gid, pxdesc); } free(securattr); } else pxdesc = (struct POSIX_SECURITY*)NULL; } if (pxdesc) { if (ntfs_valid_posix(pxdesc)) { if (!strcmp(name,"system.posix_acl_default")) { if (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) outsize = sizeof(struct POSIX_ACL) + pxdesc->defcnt*sizeof(struct POSIX_ACE); else { /* * getting default ACL from plain file : * return EACCES if size > 0 as * indicated in the man, but return ok * if size == 0, so that ls does not * display an error */ if (size > 0) { outsize = 0; errno = EACCES; } else outsize = sizeof(struct POSIX_ACL); } if (outsize && (outsize <= size)) { memcpy(value,&pxdesc->acl,sizeof(struct POSIX_ACL)); memcpy(&value[sizeof(struct POSIX_ACL)], &pxdesc->acl.ace[pxdesc->firstdef], outsize-sizeof(struct POSIX_ACL)); } } else { outsize = sizeof(struct POSIX_ACL) + pxdesc->acccnt*sizeof(struct POSIX_ACE); if (outsize <= size) memcpy(value,&pxdesc->acl,outsize); } } else { outsize = 0; errno = EIO; ntfs_log_error("Invalid Posix ACL built\n"); } if (!cached) free(pxdesc); } else outsize = 0; } return (outsize ? (int)outsize : -errno); } #else /* POSIXACLS */ /* * Get permissions to access a file * Takes into account the relation of user to file (owner, group, ...) * Do no use as mode of the file * * returns -1 if there is a problem */ static int ntfs_get_perm(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, mode_t request) { const SECURITY_DESCRIPTOR_RELATIVE *phead; const struct CACHED_PERMISSIONS *cached; char *securattr; const SID *usid; /* owner of file/directory */ const SID *gsid; /* group of file/directory */ BOOL isdir; uid_t uid; gid_t gid; int perm; if (!scx->mapping[MAPUSERS] || (!scx->uid && !(request & S_IEXEC))) perm = 07777; else { /* check whether available in cache */ cached = fetch_cache(scx,ni); if (cached) { perm = cached->mode; uid = cached->uid; gid = cached->gid; } else { perm = 0; /* default to no permission */ isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); securattr = getsecurityattr(scx->vol, ni); if (securattr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*) securattr; gsid = (const SID*)& securattr[le32_to_cpu(phead->group)]; gid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); #if OWNERFROMACL usid = ntfs_acl_owner(securattr); perm = ntfs_build_permissions(securattr, usid, gsid, isdir); uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #else usid = (const SID*)& securattr[le32_to_cpu(phead->owner)]; perm = ntfs_build_permissions(securattr, usid, gsid, isdir); if (!perm && ntfs_same_sid(usid, adminsid)) { uid = find_tenant(scx, securattr); if (uid) perm = 0700; } else uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #endif /* * Create a security id if there were none * and upgrade option is selected */ if (!test_nino_flag(ni, v3_Extensions) && (perm >= 0) && (scx->vol->secure_flags & (1 << SECURITY_ADDSECURIDS))) { upgrade_secur_desc(scx->vol, securattr, ni); /* * fetch owner and group for cacheing * if there is a securid */ } if (test_nino_flag(ni, v3_Extensions) && (perm >= 0)) { enter_cache(scx, ni, uid, gid, perm); } free(securattr); } else { perm = -1; uid = gid = 0; } } if (perm >= 0) { if (!scx->uid) { /* root access and execution */ if (perm & 0111) perm |= 01777; else perm = 0; } else if (uid == scx->uid) perm &= 07700; else /* * avoid checking group membership * when the requested perms for group * are the same as perms for other */ if ((gid == scx->gid) || ((((perm >> 3) ^ perm) & (request >> 6) & 7) && groupmember(scx, scx->uid, gid))) perm &= 07070; else perm &= 07007; } } return (perm); } #endif /* POSIXACLS */ /* * Get an NTFS ACL * * Returns size or -errno if there is a problem * if size was too small, no copy is done and errno is not set, * the caller is expected to issue a new call */ int ntfs_get_ntfs_acl(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, char *value, size_t size) { char *securattr; size_t outsize; outsize = 0; /* default to no data and no error */ securattr = getsecurityattr(scx->vol, ni); if (securattr) { outsize = ntfs_attr_size(securattr); if (outsize <= size) { memcpy(value,securattr,outsize); } free(securattr); } return (outsize ? (int)outsize : -errno); } /* * Get owner, group and permissions in an stat structure * returns permissions, or -1 if there is a problem */ int ntfs_get_owner_mode(struct SECURITY_CONTEXT *scx, ntfs_inode * ni, struct stat *stbuf) { const SECURITY_DESCRIPTOR_RELATIVE *phead; char *securattr; const SID *usid; /* owner of file/directory */ const SID *gsid; /* group of file/directory */ const struct CACHED_PERMISSIONS *cached; int perm; BOOL isdir; #if POSIXACLS struct POSIX_SECURITY *pxdesc; #endif if (!scx->mapping[MAPUSERS]) perm = 07777; else { /* check whether available in cache */ cached = fetch_cache(scx,ni); if (cached) { #if POSIXACLS if (!(scx->vol->secure_flags & (1 << SECURITY_ACL)) && cached->pxdesc) perm = ntfs_basic_perms(scx,cached->pxdesc); else #endif perm = cached->mode; stbuf->st_uid = cached->uid; stbuf->st_gid = cached->gid; stbuf->st_mode = (stbuf->st_mode & ~07777) + perm; } else { perm = -1; /* default to error */ isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); securattr = getsecurityattr(scx->vol, ni); if (securattr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*) securattr; gsid = (const SID*)& securattr[le32_to_cpu(phead->group)]; #if OWNERFROMACL usid = ntfs_acl_owner(securattr); #else usid = (const SID*)& securattr[le32_to_cpu(phead->owner)]; #endif #if POSIXACLS pxdesc = ntfs_build_permissions_posix( scx->mapping, securattr, usid, gsid, isdir); if (pxdesc) { if (!(scx->vol->secure_flags & (1 << SECURITY_ACL))) perm = ntfs_basic_perms(scx, pxdesc); else perm = pxdesc->mode & 07777; } else perm = -1; #else perm = ntfs_build_permissions(securattr, usid, gsid, isdir); #endif /* * fetch owner and group for cacheing */ if (perm >= 0) { /* * Create a security id if there were none * and upgrade option is selected */ if (!test_nino_flag(ni, v3_Extensions) && (scx->vol->secure_flags & (1 << SECURITY_ADDSECURIDS))) { upgrade_secur_desc(scx->vol, securattr, ni); } #if OWNERFROMACL stbuf->st_uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #else if (!perm && ntfs_same_sid(usid, adminsid)) { stbuf->st_uid = find_tenant(scx, securattr); if (stbuf->st_uid) perm = 0700; } else stbuf->st_uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #endif stbuf->st_gid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); stbuf->st_mode = (stbuf->st_mode & ~07777) + perm; #if POSIXACLS enter_cache(scx, ni, stbuf->st_uid, stbuf->st_gid, pxdesc); free(pxdesc); #else enter_cache(scx, ni, stbuf->st_uid, stbuf->st_gid, perm); #endif } free(securattr); } } } return (perm); } #if POSIXACLS /* * Get the base for a Posix inheritance and * build an inherited Posix descriptor */ static struct POSIX_SECURITY *inherit_posix(struct SECURITY_CONTEXT *scx, ntfs_inode *dir_ni, mode_t mode, BOOL isdir) { const struct CACHED_PERMISSIONS *cached; const SECURITY_DESCRIPTOR_RELATIVE *phead; struct POSIX_SECURITY *pxdesc; struct POSIX_SECURITY *pydesc; char *securattr; const SID *usid; const SID *gsid; uid_t uid; gid_t gid; pydesc = (struct POSIX_SECURITY*)NULL; /* check whether parent directory is available in cache */ cached = fetch_cache(scx,dir_ni); if (cached) { uid = cached->uid; gid = cached->gid; pxdesc = cached->pxdesc; if (pxdesc) { if (scx->vol->secure_flags & (1 << SECURITY_ACL)) pydesc = ntfs_build_inherited_posix(pxdesc, mode, scx->umask, isdir); else pydesc = ntfs_build_basic_posix(pxdesc, mode, scx->umask, isdir); } } else { securattr = getsecurityattr(scx->vol, dir_ni); if (securattr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*) securattr; gsid = (const SID*)& securattr[le32_to_cpu(phead->group)]; gid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); #if OWNERFROMACL usid = ntfs_acl_owner(securattr); pxdesc = ntfs_build_permissions_posix(scx->mapping,securattr, usid, gsid, TRUE); uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #else usid = (const SID*)& securattr[le32_to_cpu(phead->owner)]; pxdesc = ntfs_build_permissions_posix(scx->mapping,securattr, usid, gsid, TRUE); if (pxdesc && ntfs_same_sid(usid, adminsid)) { uid = find_tenant(scx, securattr); } else uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); #endif if (pxdesc) { /* * Create a security id if there were none * and upgrade option is selected */ if (!test_nino_flag(dir_ni, v3_Extensions) && (scx->vol->secure_flags & (1 << SECURITY_ADDSECURIDS))) { upgrade_secur_desc(scx->vol, securattr, dir_ni); /* * fetch owner and group for cacheing * if there is a securid */ } if (test_nino_flag(dir_ni, v3_Extensions)) { enter_cache(scx, dir_ni, uid, gid, pxdesc); } if (scx->vol->secure_flags & (1 << SECURITY_ACL)) pydesc = ntfs_build_inherited_posix( pxdesc, mode, scx->umask, isdir); else pydesc = ntfs_build_basic_posix( pxdesc, mode, scx->umask, isdir); free(pxdesc); } free(securattr); } } return (pydesc); } /* * Allocate a security_id for a file being created * * Returns zero if not possible (NTFS v3.x required) */ le32 ntfs_alloc_securid(struct SECURITY_CONTEXT *scx, uid_t uid, gid_t gid, ntfs_inode *dir_ni, mode_t mode, BOOL isdir) { #if !FORCE_FORMAT_v1x const struct CACHED_SECURID *cached; struct CACHED_SECURID wanted; struct POSIX_SECURITY *pxdesc; char *newattr; int newattrsz; const SID *usid; const SID *gsid; BIGSID defusid; BIGSID defgsid; le32 securid; #endif securid = const_cpu_to_le32(0); #if !FORCE_FORMAT_v1x pxdesc = inherit_posix(scx, dir_ni, mode, isdir); if (pxdesc) { /* check whether target securid is known in cache */ wanted.uid = uid; wanted.gid = gid; wanted.dmode = pxdesc->mode & mode & 07777; if (isdir) wanted.dmode |= 0x10000; wanted.variable = (void*)pxdesc; wanted.varsize = sizeof(struct POSIX_SECURITY) + (pxdesc->acccnt + pxdesc->defcnt)*sizeof(struct POSIX_ACE); cached = (const struct CACHED_SECURID*)ntfs_fetch_cache( scx->vol->securid_cache, GENERIC(&wanted), (cache_compare)compare); /* quite simple, if we are lucky */ if (cached) securid = cached->securid; /* not in cache : make sure we can create ids */ if (!cached && (scx->vol->major_ver >= 3)) { usid = ntfs_find_usid(scx->mapping[MAPUSERS],uid,(SID*)&defusid); gsid = ntfs_find_gsid(scx->mapping[MAPGROUPS],gid,(SID*)&defgsid); if (!usid || !gsid) { ntfs_log_error("File created by an unmapped user/group %d/%d\n", (int)uid, (int)gid); usid = gsid = adminsid; } newattr = ntfs_build_descr_posix(scx->mapping, pxdesc, isdir, usid, gsid); if (newattr) { newattrsz = ntfs_attr_size(newattr); securid = setsecurityattr(scx->vol, (const SECURITY_DESCRIPTOR_RELATIVE*)newattr, newattrsz); if (securid) { /* update cache, for subsequent use */ wanted.securid = securid; ntfs_enter_cache(scx->vol->securid_cache, GENERIC(&wanted), (cache_compare)compare); } free(newattr); } else { /* * could not build new security attribute * errno set by ntfs_build_descr() */ } } free(pxdesc); } #endif return (securid); } /* * Apply Posix inheritance to a newly created file * (for NTFS 1.x only : no securid) */ int ntfs_set_inherited_posix(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, uid_t uid, gid_t gid, ntfs_inode *dir_ni, mode_t mode) { struct POSIX_SECURITY *pxdesc; char *newattr; const SID *usid; const SID *gsid; BIGSID defusid; BIGSID defgsid; BOOL isdir; int res; res = -1; isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); pxdesc = inherit_posix(scx, dir_ni, mode, isdir); if (pxdesc) { usid = ntfs_find_usid(scx->mapping[MAPUSERS],uid,(SID*)&defusid); gsid = ntfs_find_gsid(scx->mapping[MAPGROUPS],gid,(SID*)&defgsid); if (!usid || !gsid) { ntfs_log_error("File created by an unmapped user/group %d/%d\n", (int)uid, (int)gid); usid = gsid = adminsid; } newattr = ntfs_build_descr_posix(scx->mapping, pxdesc, isdir, usid, gsid); if (newattr) { /* Adjust Windows read-only flag */ res = update_secur_descr(scx->vol, newattr, ni); if (!res && !isdir) { if (mode & S_IWUSR) ni->flags &= ~FILE_ATTR_READONLY; else ni->flags |= FILE_ATTR_READONLY; } #if CACHE_LEGACY_SIZE /* also invalidate legacy cache */ if (isdir && !ni->security_id) { struct CACHED_PERMISSIONS_LEGACY legacy; legacy.mft_no = ni->mft_no; legacy.variable = pxdesc; legacy.varsize = sizeof(struct POSIX_SECURITY) + (pxdesc->acccnt + pxdesc->defcnt)*sizeof(struct POSIX_ACE); ntfs_invalidate_cache(scx->vol->legacy_cache, GENERIC(&legacy), (cache_compare)leg_compare,0); } #endif free(newattr); } else { /* * could not build new security attribute * errno set by ntfs_build_descr() */ } } return (res); } #else le32 ntfs_alloc_securid(struct SECURITY_CONTEXT *scx, uid_t uid, gid_t gid, mode_t mode, BOOL isdir) { #if !FORCE_FORMAT_v1x const struct CACHED_SECURID *cached; struct CACHED_SECURID wanted; char *newattr; int newattrsz; const SID *usid; const SID *gsid; BIGSID defusid; BIGSID defgsid; le32 securid; #endif securid = const_cpu_to_le32(0); #if !FORCE_FORMAT_v1x /* check whether target securid is known in cache */ wanted.uid = uid; wanted.gid = gid; wanted.dmode = mode & 07777; if (isdir) wanted.dmode |= 0x10000; wanted.variable = (void*)NULL; wanted.varsize = 0; cached = (const struct CACHED_SECURID*)ntfs_fetch_cache( scx->vol->securid_cache, GENERIC(&wanted), (cache_compare)compare); /* quite simple, if we are lucky */ if (cached) securid = cached->securid; /* not in cache : make sure we can create ids */ if (!cached && (scx->vol->major_ver >= 3)) { usid = ntfs_find_usid(scx->mapping[MAPUSERS],uid,(SID*)&defusid); gsid = ntfs_find_gsid(scx->mapping[MAPGROUPS],gid,(SID*)&defgsid); if (!usid || !gsid) { ntfs_log_error("File created by an unmapped user/group %d/%d\n", (int)uid, (int)gid); usid = gsid = adminsid; } newattr = ntfs_build_descr(mode, isdir, usid, gsid); if (newattr) { newattrsz = ntfs_attr_size(newattr); securid = setsecurityattr(scx->vol, (const SECURITY_DESCRIPTOR_RELATIVE*)newattr, newattrsz); if (securid) { /* update cache, for subsequent use */ wanted.securid = securid; ntfs_enter_cache(scx->vol->securid_cache, GENERIC(&wanted), (cache_compare)compare); } free(newattr); } else { /* * could not build new security attribute * errno set by ntfs_build_descr() */ } } #endif return (securid); } #endif /* * Update ownership and mode of a file, reusing an existing * security descriptor when possible * * Returns zero if successful */ #if POSIXACLS int ntfs_set_owner_mode(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, uid_t uid, gid_t gid, mode_t mode, struct POSIX_SECURITY *pxdesc) #else int ntfs_set_owner_mode(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, uid_t uid, gid_t gid, mode_t mode) #endif { int res; const struct CACHED_SECURID *cached; struct CACHED_SECURID wanted; char *newattr; const SID *usid; const SID *gsid; BIGSID defusid; BIGSID defgsid; BOOL isdir; res = 0; /* check whether target securid is known in cache */ isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); wanted.uid = uid; wanted.gid = gid; wanted.dmode = mode & 07777; if (isdir) wanted.dmode |= 0x10000; #if POSIXACLS wanted.variable = (void*)pxdesc; if (pxdesc) wanted.varsize = sizeof(struct POSIX_SECURITY) + (pxdesc->acccnt + pxdesc->defcnt)*sizeof(struct POSIX_ACE); else wanted.varsize = 0; #else wanted.variable = (void*)NULL; wanted.varsize = 0; #endif if (test_nino_flag(ni, v3_Extensions)) { cached = (const struct CACHED_SECURID*)ntfs_fetch_cache( scx->vol->securid_cache, GENERIC(&wanted), (cache_compare)compare); /* quite simple, if we are lucky */ if (cached) { ni->security_id = cached->securid; NInoSetDirty(ni); /* adjust Windows read-only flag */ if (!isdir) { if (mode & S_IWUSR) ni->flags &= ~FILE_ATTR_READONLY; else ni->flags |= FILE_ATTR_READONLY; NInoFileNameSetDirty(ni); } } } else cached = (struct CACHED_SECURID*)NULL; if (!cached) { /* * Do not use usid and gsid from former attributes, * but recompute them to get repeatable results * which can be kept in cache. */ usid = ntfs_find_usid(scx->mapping[MAPUSERS],uid,(SID*)&defusid); gsid = ntfs_find_gsid(scx->mapping[MAPGROUPS],gid,(SID*)&defgsid); if (!usid || !gsid) { ntfs_log_error("File made owned by an unmapped user/group %d/%d\n", uid, gid); usid = gsid = adminsid; } #if POSIXACLS if (pxdesc) newattr = ntfs_build_descr_posix(scx->mapping, pxdesc, isdir, usid, gsid); else newattr = ntfs_build_descr(mode, isdir, usid, gsid); #else newattr = ntfs_build_descr(mode, isdir, usid, gsid); #endif if (newattr) { res = update_secur_descr(scx->vol, newattr, ni); if (!res) { /* adjust Windows read-only flag */ if (!isdir) { if (mode & S_IWUSR) ni->flags &= ~FILE_ATTR_READONLY; else ni->flags |= FILE_ATTR_READONLY; NInoFileNameSetDirty(ni); } /* update cache, for subsequent use */ if (test_nino_flag(ni, v3_Extensions)) { wanted.securid = ni->security_id; ntfs_enter_cache(scx->vol->securid_cache, GENERIC(&wanted), (cache_compare)compare); } #if CACHE_LEGACY_SIZE /* also invalidate legacy cache */ if (isdir && !ni->security_id) { struct CACHED_PERMISSIONS_LEGACY legacy; legacy.mft_no = ni->mft_no; #if POSIXACLS legacy.variable = wanted.variable; legacy.varsize = wanted.varsize; #else legacy.variable = (void*)NULL; legacy.varsize = 0; #endif ntfs_invalidate_cache(scx->vol->legacy_cache, GENERIC(&legacy), (cache_compare)leg_compare,0); } #endif } free(newattr); } else { /* * could not build new security attribute * errno set by ntfs_build_descr() */ res = -1; } } return (res); } /* * Check whether user has ownership rights on a file * * Returns TRUE if allowed * if not, errno tells why */ BOOL ntfs_allowed_as_owner(struct SECURITY_CONTEXT *scx, ntfs_inode *ni) { const struct CACHED_PERMISSIONS *cached; char *oldattr; const SID *usid; uid_t processuid; uid_t uid; BOOL gotowner; int allowed; processuid = scx->uid; /* TODO : use CAP_FOWNER process capability */ /* * Always allow for root * Also always allow if no mapping has been defined */ if (!scx->mapping[MAPUSERS] || !processuid) allowed = TRUE; else { gotowner = FALSE; /* default */ /* get the owner, either from cache or from old attribute */ cached = fetch_cache(scx, ni); if (cached) { uid = cached->uid; gotowner = TRUE; } else { oldattr = getsecurityattr(scx->vol, ni); if (oldattr) { #if OWNERFROMACL usid = ntfs_acl_owner(oldattr); #else const SECURITY_DESCRIPTOR_RELATIVE *phead; phead = (const SECURITY_DESCRIPTOR_RELATIVE*) oldattr; usid = (const SID*)&oldattr [le32_to_cpu(phead->owner)]; #endif uid = ntfs_find_user(scx->mapping[MAPUSERS], usid); gotowner = TRUE; free(oldattr); } } allowed = FALSE; if (gotowner) { /* TODO : use CAP_FOWNER process capability */ if (!processuid || (processuid == uid)) allowed = TRUE; else errno = EPERM; } } return (allowed); } #if POSIXACLS /* * Set a new access or default Posix ACL to a file * (or remove ACL if no input data) * Validity of input data is checked after merging * * Returns 0, or -1 if there is a problem which errno describes */ int ntfs_set_posix_acl(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, const char *name, const char *value, size_t size, int flags) { const SECURITY_DESCRIPTOR_RELATIVE *phead; const struct CACHED_PERMISSIONS *cached; char *oldattr; uid_t processuid; const SID *usid; const SID *gsid; uid_t uid; uid_t gid; int res; BOOL isdir; BOOL deflt; BOOL exist; int count; struct POSIX_SECURITY *oldpxdesc; struct POSIX_SECURITY *newpxdesc; /* get the current pxsec, either from cache or from old attribute */ res = -1; deflt = !strcmp(name,"system.posix_acl_default"); if (size) count = (size - sizeof(struct POSIX_ACL)) / sizeof(struct POSIX_ACE); else count = 0; isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); newpxdesc = (struct POSIX_SECURITY*)NULL; if ((!value || (((const struct POSIX_ACL*)value)->version == POSIX_VERSION)) && (!deflt || isdir || (!size && !value))) { cached = fetch_cache(scx, ni); if (cached) { uid = cached->uid; gid = cached->gid; oldpxdesc = cached->pxdesc; if (oldpxdesc) { newpxdesc = ntfs_replace_acl(oldpxdesc, (const struct POSIX_ACL*)value,count,deflt); } } else { oldattr = getsecurityattr(scx->vol, ni); if (oldattr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*)oldattr; #if OWNERFROMACL usid = ntfs_acl_owner(oldattr); #else usid = (const SID*)&oldattr[le32_to_cpu(phead->owner)]; #endif gsid = (const SID*)&oldattr[le32_to_cpu(phead->group)]; uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); gid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); oldpxdesc = ntfs_build_permissions_posix(scx->mapping, oldattr, usid, gsid, isdir); if (oldpxdesc) { if (deflt) exist = oldpxdesc->defcnt > 0; else exist = oldpxdesc->acccnt > 3; if ((exist && (flags & XATTR_CREATE)) || (!exist && (flags & XATTR_REPLACE))) { errno = (exist ? EEXIST : ENODATA); } else { newpxdesc = ntfs_replace_acl(oldpxdesc, (const struct POSIX_ACL*)value,count,deflt); } free(oldpxdesc); } free(oldattr); } } } else errno = EINVAL; if (newpxdesc) { processuid = scx->uid; /* TODO : use CAP_FOWNER process capability */ if (!processuid || (uid == processuid)) { /* * clear setgid if file group does * not match process group */ if (processuid && (gid != scx->gid) && !groupmember(scx, scx->uid, gid)) { newpxdesc->mode &= ~S_ISGID; } res = ntfs_set_owner_mode(scx, ni, uid, gid, newpxdesc->mode, newpxdesc); } else errno = EPERM; free(newpxdesc); } return (res ? -1 : 0); } /* * Remove a default Posix ACL from a file * * Returns 0, or -1 if there is a problem which errno describes */ int ntfs_remove_posix_acl(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, const char *name) { return (ntfs_set_posix_acl(scx, ni, name, (const char*)NULL, 0, 0)); } #endif /* * Set a new NTFS ACL to a file * * Returns 0, or -1 if there is a problem */ int ntfs_set_ntfs_acl(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, const char *value, size_t size, int flags) { char *attr; int res; res = -1; if ((size > 0) && !(flags & XATTR_CREATE) && ntfs_valid_descr(value,size) && (ntfs_attr_size(value) == size)) { /* need copying in order to write */ attr = (char*)ntfs_malloc(size); if (attr) { memcpy(attr,value,size); res = update_secur_descr(scx->vol, attr, ni); /* * No need to invalidate standard caches : * the relation between a securid and * the associated protection is unchanged, * only the relation between a file and * its securid and protection is changed. */ #if CACHE_LEGACY_SIZE /* * we must however invalidate the legacy * cache, which is based on inode numbers. * For safety, invalidate even if updating * failed. */ if ((ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) && !ni->security_id) { struct CACHED_PERMISSIONS_LEGACY legacy; legacy.mft_no = ni->mft_no; legacy.variable = (char*)NULL; legacy.varsize = 0; ntfs_invalidate_cache(scx->vol->legacy_cache, GENERIC(&legacy), (cache_compare)leg_compare,0); } #endif free(attr); } else errno = ENOMEM; } else errno = EINVAL; return (res ? -1 : 0); } /* * Set new permissions to a file * Checks user mapping has been defined before request for setting * * rejected if request is not originated by owner or root * * returns 0 on success * -1 on failure, with errno = EIO */ int ntfs_set_mode(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, mode_t mode) { const SECURITY_DESCRIPTOR_RELATIVE *phead; const struct CACHED_PERMISSIONS *cached; char *oldattr; const SID *usid; const SID *gsid; uid_t processuid; uid_t uid; uid_t gid; int res; #if POSIXACLS BOOL isdir; int pxsize; const struct POSIX_SECURITY *oldpxdesc; struct POSIX_SECURITY *newpxdesc = (struct POSIX_SECURITY*)NULL; #endif /* get the current owner, either from cache or from old attribute */ res = 0; cached = fetch_cache(scx, ni); if (cached) { uid = cached->uid; gid = cached->gid; #if POSIXACLS oldpxdesc = cached->pxdesc; if (oldpxdesc) { /* must copy before merging */ pxsize = sizeof(struct POSIX_SECURITY) + (oldpxdesc->acccnt + oldpxdesc->defcnt)*sizeof(struct POSIX_ACE); newpxdesc = (struct POSIX_SECURITY*)malloc(pxsize); if (newpxdesc) { memcpy(newpxdesc, oldpxdesc, pxsize); if (ntfs_merge_mode_posix(newpxdesc, mode)) res = -1; } else res = -1; } else newpxdesc = (struct POSIX_SECURITY*)NULL; #endif } else { oldattr = getsecurityattr(scx->vol, ni); if (oldattr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*)oldattr; #if OWNERFROMACL usid = ntfs_acl_owner(oldattr); #else usid = (const SID*)&oldattr[le32_to_cpu(phead->owner)]; #endif gsid = (const SID*)&oldattr[le32_to_cpu(phead->group)]; uid = ntfs_find_user(scx->mapping[MAPUSERS],usid); gid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); #if POSIXACLS isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); newpxdesc = ntfs_build_permissions_posix(scx->mapping, oldattr, usid, gsid, isdir); if (!newpxdesc || ntfs_merge_mode_posix(newpxdesc, mode)) res = -1; #endif free(oldattr); } else res = -1; } if (!res) { processuid = scx->uid; /* TODO : use CAP_FOWNER process capability */ if (!processuid || (uid == processuid)) { /* * clear setgid if file group does * not match process group */ if (processuid && (gid != scx->gid) && !groupmember(scx, scx->uid, gid)) mode &= ~S_ISGID; #if POSIXACLS if (newpxdesc) { newpxdesc->mode = mode; res = ntfs_set_owner_mode(scx, ni, uid, gid, mode, newpxdesc); } else res = ntfs_set_owner_mode(scx, ni, uid, gid, mode, newpxdesc); #else res = ntfs_set_owner_mode(scx, ni, uid, gid, mode); #endif } else { errno = EPERM; res = -1; /* neither owner nor root */ } } else { /* * Should not happen : a default descriptor is generated * by getsecurityattr() when there are none */ ntfs_log_error("File has no security descriptor\n"); res = -1; errno = EIO; } #if POSIXACLS if (newpxdesc) free(newpxdesc); #endif return (res ? -1 : 0); } /* * Create a default security descriptor for files whose descriptor * cannot be inherited */ int ntfs_sd_add_everyone(ntfs_inode *ni) { /* JPA SECURITY_DESCRIPTOR_ATTR *sd; */ SECURITY_DESCRIPTOR_RELATIVE *sd; ACL *acl; ACCESS_ALLOWED_ACE *ace; SID *sid; int ret, sd_len; /* Create SECURITY_DESCRIPTOR attribute (everyone has full access). */ /* * Calculate security descriptor length. We have 2 sub-authorities in * owner and group SIDs, but structure SID contain only one, so add * 4 bytes to every SID. */ sd_len = sizeof(SECURITY_DESCRIPTOR_ATTR) + 2 * (sizeof(SID) + 4) + sizeof(ACL) + sizeof(ACCESS_ALLOWED_ACE); sd = (SECURITY_DESCRIPTOR_RELATIVE*)ntfs_calloc(sd_len); if (!sd) return -1; sd->revision = SECURITY_DESCRIPTOR_REVISION; sd->control = SE_DACL_PRESENT | SE_SELF_RELATIVE; sid = (SID*)((u8*)sd + sizeof(SECURITY_DESCRIPTOR_ATTR)); sid->revision = SID_REVISION; sid->sub_authority_count = 2; sid->sub_authority[0] = const_cpu_to_le32(SECURITY_BUILTIN_DOMAIN_RID); sid->sub_authority[1] = const_cpu_to_le32(DOMAIN_ALIAS_RID_ADMINS); sid->identifier_authority.value[5] = 5; sd->owner = cpu_to_le32((u8*)sid - (u8*)sd); sid = (SID*)((u8*)sid + sizeof(SID) + 4); sid->revision = SID_REVISION; sid->sub_authority_count = 2; sid->sub_authority[0] = const_cpu_to_le32(SECURITY_BUILTIN_DOMAIN_RID); sid->sub_authority[1] = const_cpu_to_le32(DOMAIN_ALIAS_RID_ADMINS); sid->identifier_authority.value[5] = 5; sd->group = cpu_to_le32((u8*)sid - (u8*)sd); acl = (ACL*)((u8*)sid + sizeof(SID) + 4); acl->revision = ACL_REVISION; acl->size = const_cpu_to_le16(sizeof(ACL) + sizeof(ACCESS_ALLOWED_ACE)); acl->ace_count = const_cpu_to_le16(1); sd->dacl = cpu_to_le32((u8*)acl - (u8*)sd); ace = (ACCESS_ALLOWED_ACE*)((u8*)acl + sizeof(ACL)); ace->type = ACCESS_ALLOWED_ACE_TYPE; ace->flags = OBJECT_INHERIT_ACE | CONTAINER_INHERIT_ACE; ace->size = const_cpu_to_le16(sizeof(ACCESS_ALLOWED_ACE)); ace->mask = const_cpu_to_le32(0x1f01ff); /* FIXME */ ace->sid.revision = SID_REVISION; ace->sid.sub_authority_count = 1; ace->sid.sub_authority[0] = const_cpu_to_le32(0); ace->sid.identifier_authority.value[5] = 1; ret = ntfs_attr_add(ni, AT_SECURITY_DESCRIPTOR, AT_UNNAMED, 0, (u8*)sd, sd_len); if (ret) ntfs_log_perror("Failed to add initial SECURITY_DESCRIPTOR"); free(sd); return ret; } /* * Check whether user can access a file in a specific way * * Returns 1 if access is allowed, including user is root or no * user mapping defined * 2 if sticky and accesstype is S_IWRITE + S_IEXEC + S_ISVTX * 0 and sets errno if there is a problem or if access * is not allowed * * This is used for Posix ACL and checking creation of DOS file names */ int ntfs_allowed_access(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, int accesstype) /* access type required (S_Ixxx values) */ { int perm; int res; int allow; struct stat stbuf; /* * Always allow for root unless execution is requested. * (was checked by fuse until kernel 2.6.29) * Also always allow if no mapping has been defined */ if (!scx->mapping[MAPUSERS] || (!scx->uid && (!(accesstype & S_IEXEC) || (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY)))) allow = 1; else { perm = ntfs_get_perm(scx, ni, accesstype); if (perm >= 0) { res = EACCES; switch (accesstype) { case S_IEXEC: allow = (perm & (S_IXUSR | S_IXGRP | S_IXOTH)) != 0; break; case S_IWRITE: allow = (perm & (S_IWUSR | S_IWGRP | S_IWOTH)) != 0; break; case S_IWRITE + S_IEXEC: allow = ((perm & (S_IWUSR | S_IWGRP | S_IWOTH)) != 0) && ((perm & (S_IXUSR | S_IXGRP | S_IXOTH)) != 0); break; case S_IREAD: allow = (perm & (S_IRUSR | S_IRGRP | S_IROTH)) != 0; break; case S_IREAD + S_IEXEC: allow = ((perm & (S_IRUSR | S_IRGRP | S_IROTH)) != 0) && ((perm & (S_IXUSR | S_IXGRP | S_IXOTH)) != 0); break; case S_IREAD + S_IWRITE: allow = ((perm & (S_IRUSR | S_IRGRP | S_IROTH)) != 0) && ((perm & (S_IWUSR | S_IWGRP | S_IWOTH)) != 0); break; case S_IWRITE + S_IEXEC + S_ISVTX: if (perm & S_ISVTX) { if ((ntfs_get_owner_mode(scx,ni,&stbuf) >= 0) && (stbuf.st_uid == scx->uid)) allow = 1; else allow = 2; } else allow = ((perm & (S_IWUSR | S_IWGRP | S_IWOTH)) != 0) && ((perm & (S_IXUSR | S_IXGRP | S_IXOTH)) != 0); break; case S_IREAD + S_IWRITE + S_IEXEC: allow = ((perm & (S_IRUSR | S_IRGRP | S_IROTH)) != 0) && ((perm & (S_IWUSR | S_IWGRP | S_IWOTH)) != 0) && ((perm & (S_IXUSR | S_IXGRP | S_IXOTH)) != 0); break; default : res = EINVAL; allow = 0; break; } if (!allow) errno = res; } else allow = 0; } return (allow); } /* * Check whether user can create a file (or directory) * * Returns TRUE if access is allowed, * Also returns the gid and dsetgid applicable to the created file */ int ntfs_allowed_create(struct SECURITY_CONTEXT *scx, ntfs_inode *dir_ni, gid_t *pgid, mode_t *pdsetgid) { int perm; int res; int allow; struct stat stbuf; /* * Always allow for root. * Also always allow if no mapping has been defined */ if (!scx->mapping[MAPUSERS]) perm = 0777; else perm = ntfs_get_perm(scx, dir_ni, S_IWRITE + S_IEXEC); if (!scx->mapping[MAPUSERS] || !scx->uid) { allow = 1; } else { perm = ntfs_get_perm(scx, dir_ni, S_IWRITE + S_IEXEC); if (perm >= 0) { res = EACCES; allow = ((perm & (S_IWUSR | S_IWGRP | S_IWOTH)) != 0) && ((perm & (S_IXUSR | S_IXGRP | S_IXOTH)) != 0); if (!allow) errno = res; } else allow = 0; } *pgid = scx->gid; *pdsetgid = 0; /* return directory group if S_ISGID is set */ if (allow && (perm & S_ISGID)) { if (ntfs_get_owner_mode(scx, dir_ni, &stbuf) >= 0) { *pdsetgid = stbuf.st_mode & S_ISGID; if (perm & S_ISGID) *pgid = stbuf.st_gid; } } return (allow); } #if 0 /* not needed any more */ /* * Check whether user can access the parent directory * of a file in a specific way * * Returns true if access is allowed, including user is root and * no user mapping defined * * Sets errno if there is a problem or if not allowed * * This is used for Posix ACL and checking creation of DOS file names */ BOOL old_ntfs_allowed_dir_access(struct SECURITY_CONTEXT *scx, const char *path, int accesstype) { int allow; char *dirpath; char *name; ntfs_inode *ni; ntfs_inode *dir_ni; struct stat stbuf; allow = 0; dirpath = strdup(path); if (dirpath) { /* the root of file system is seen as a parent of itself */ /* is that correct ? */ name = strrchr(dirpath, '/'); *name = 0; dir_ni = ntfs_pathname_to_inode(scx->vol, NULL, dirpath); if (dir_ni) { allow = ntfs_allowed_access(scx, dir_ni, accesstype); ntfs_inode_close(dir_ni); /* * for an not-owned sticky directory, have to * check whether file itself is owned */ if ((accesstype == (S_IWRITE + S_IEXEC + S_ISVTX)) && (allow == 2)) { ni = ntfs_pathname_to_inode(scx->vol, NULL, path); allow = FALSE; if (ni) { allow = (ntfs_get_owner_mode(scx,ni,&stbuf) >= 0) && (stbuf.st_uid == scx->uid); ntfs_inode_close(ni); } } } free(dirpath); } return (allow); /* errno is set if not allowed */ } #endif /* * Define a new owner/group to a file * * returns zero if successful */ int ntfs_set_owner(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, uid_t uid, gid_t gid) { const SECURITY_DESCRIPTOR_RELATIVE *phead; const struct CACHED_PERMISSIONS *cached; char *oldattr; const SID *usid; const SID *gsid; uid_t fileuid; uid_t filegid; mode_t mode; int perm; BOOL isdir; int res; #if POSIXACLS struct POSIX_SECURITY *pxdesc; BOOL pxdescbuilt = FALSE; #endif res = 0; /* get the current owner and mode from cache or security attributes */ oldattr = (char*)NULL; cached = fetch_cache(scx,ni); if (cached) { fileuid = cached->uid; filegid = cached->gid; mode = cached->mode; #if POSIXACLS pxdesc = cached->pxdesc; if (!pxdesc) res = -1; #endif } else { fileuid = 0; filegid = 0; mode = 0; oldattr = getsecurityattr(scx->vol, ni); if (oldattr) { isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); phead = (const SECURITY_DESCRIPTOR_RELATIVE*) oldattr; gsid = (const SID*) &oldattr[le32_to_cpu(phead->group)]; #if OWNERFROMACL usid = ntfs_acl_owner(oldattr); #else usid = (const SID*) &oldattr[le32_to_cpu(phead->owner)]; #endif #if POSIXACLS pxdesc = ntfs_build_permissions_posix(scx->mapping, oldattr, usid, gsid, isdir); if (pxdesc) { pxdescbuilt = TRUE; fileuid = ntfs_find_user(scx->mapping[MAPUSERS],usid); filegid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); mode = perm = pxdesc->mode; } else res = -1; #else mode = perm = ntfs_build_permissions(oldattr, usid, gsid, isdir); if (perm >= 0) { fileuid = ntfs_find_user(scx->mapping[MAPUSERS],usid); filegid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); } else res = -1; #endif free(oldattr); } else res = -1; } if (!res) { /* check requested by root */ /* or chgrp requested by owner to an owned group */ if (!scx->uid || ((((int)uid < 0) || (uid == fileuid)) && ((gid == scx->gid) || groupmember(scx, scx->uid, gid)) && (fileuid == scx->uid))) { /* replace by the new usid and gsid */ /* or reuse old gid and sid for cacheing */ if ((int)uid < 0) uid = fileuid; if ((int)gid < 0) gid = filegid; #if !defined(__sun) || !defined (__SVR4) /* clear setuid and setgid if owner has changed */ /* unless request originated by root */ if (uid && (fileuid != uid)) mode &= 01777; #endif #if POSIXACLS res = ntfs_set_owner_mode(scx, ni, uid, gid, mode, pxdesc); #else res = ntfs_set_owner_mode(scx, ni, uid, gid, mode); #endif } else { res = -1; /* neither owner nor root */ errno = EPERM; } #if POSIXACLS if (pxdescbuilt) free(pxdesc); #endif } else { /* * Should not happen : a default descriptor is generated * by getsecurityattr() when there are none */ ntfs_log_error("File has no security descriptor\n"); res = -1; errno = EIO; } return (res ? -1 : 0); } /* * Define new owner/group and mode to a file * * returns zero if successful */ int ntfs_set_ownmod(struct SECURITY_CONTEXT *scx, ntfs_inode *ni, uid_t uid, gid_t gid, const mode_t mode) { const struct CACHED_PERMISSIONS *cached; char *oldattr; uid_t fileuid; uid_t filegid; int res; #if POSIXACLS const SECURITY_DESCRIPTOR_RELATIVE *phead; const SID *usid; const SID *gsid; BOOL isdir; const struct POSIX_SECURITY *oldpxdesc; struct POSIX_SECURITY *newpxdesc = (struct POSIX_SECURITY*)NULL; int pxsize; #endif res = 0; /* get the current owner and mode from cache or security attributes */ oldattr = (char*)NULL; cached = fetch_cache(scx,ni); if (cached) { fileuid = cached->uid; filegid = cached->gid; #if POSIXACLS oldpxdesc = cached->pxdesc; if (oldpxdesc) { /* must copy before merging */ pxsize = sizeof(struct POSIX_SECURITY) + (oldpxdesc->acccnt + oldpxdesc->defcnt)*sizeof(struct POSIX_ACE); newpxdesc = (struct POSIX_SECURITY*)malloc(pxsize); if (newpxdesc) { memcpy(newpxdesc, oldpxdesc, pxsize); if (ntfs_merge_mode_posix(newpxdesc, mode)) res = -1; } else res = -1; } #endif } else { fileuid = 0; filegid = 0; oldattr = getsecurityattr(scx->vol, ni); if (oldattr) { #if POSIXACLS isdir = (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) != const_cpu_to_le16(0); phead = (const SECURITY_DESCRIPTOR_RELATIVE*) oldattr; gsid = (const SID*) &oldattr[le32_to_cpu(phead->group)]; #if OWNERFROMACL usid = ntfs_acl_owner(oldattr); #else usid = (const SID*) &oldattr[le32_to_cpu(phead->owner)]; #endif newpxdesc = ntfs_build_permissions_posix(scx->mapping, oldattr, usid, gsid, isdir); if (!newpxdesc || ntfs_merge_mode_posix(newpxdesc, mode)) res = -1; else { fileuid = ntfs_find_user(scx->mapping[MAPUSERS],usid); filegid = ntfs_find_group(scx->mapping[MAPGROUPS],gsid); } #endif free(oldattr); } else res = -1; } if (!res) { /* check requested by root */ /* or chgrp requested by owner to an owned group */ if (!scx->uid || ((((int)uid < 0) || (uid == fileuid)) && ((gid == scx->gid) || groupmember(scx, scx->uid, gid)) && (fileuid == scx->uid))) { /* replace by the new usid and gsid */ /* or reuse old gid and sid for cacheing */ if ((int)uid < 0) uid = fileuid; if ((int)gid < 0) gid = filegid; #if POSIXACLS res = ntfs_set_owner_mode(scx, ni, uid, gid, mode, newpxdesc); #else res = ntfs_set_owner_mode(scx, ni, uid, gid, mode); #endif } else { res = -1; /* neither owner nor root */ errno = EPERM; } } else { /* * Should not happen : a default descriptor is generated * by getsecurityattr() when there are none */ ntfs_log_error("File has no security descriptor\n"); res = -1; errno = EIO; } #if POSIXACLS free(newpxdesc); #endif return (res ? -1 : 0); } /* * Build a security id for a descriptor inherited from * parent directory the Windows way */ static le32 build_inherited_id(struct SECURITY_CONTEXT *scx, const char *parentattr, BOOL fordir) { const SECURITY_DESCRIPTOR_RELATIVE *pphead; const ACL *ppacl; const SID *usid; const SID *gsid; BIGSID defusid; BIGSID defgsid; int offpacl; int offgroup; SECURITY_DESCRIPTOR_RELATIVE *pnhead; ACL *pnacl; int parentattrsz; char *newattr; int newattrsz; int aclsz; int usidsz; int gsidsz; int pos; le32 securid; parentattrsz = ntfs_attr_size(parentattr); pphead = (const SECURITY_DESCRIPTOR_RELATIVE*)parentattr; if (scx->mapping[MAPUSERS]) { usid = ntfs_find_usid(scx->mapping[MAPUSERS], scx->uid, (SID*)&defusid); gsid = ntfs_find_gsid(scx->mapping[MAPGROUPS], scx->gid, (SID*)&defgsid); #if OWNERFROMACL /* Get approximation of parent owner when cannot map */ if (!gsid) gsid = adminsid; if (!usid) { usid = ntfs_acl_owner(parentattr); if (!ntfs_is_user_sid(gsid)) gsid = usid; } #else /* Define owner as root when cannot map */ if (!usid) usid = adminsid; if (!gsid) gsid = adminsid; #endif } else { /* * If there is no user mapping and this is not a root * user, we have to get owner and group from somewhere, * and the parent directory has to contribute. * Windows never has to do that, because it can always * rely on a user mapping */ if (!scx->uid) usid = adminsid; else { #if OWNERFROMACL usid = ntfs_acl_owner(parentattr); #else int offowner; offowner = le32_to_cpu(pphead->owner); usid = (const SID*)&parentattr[offowner]; #endif } if (!scx->gid) gsid = adminsid; else { offgroup = le32_to_cpu(pphead->group); gsid = (const SID*)&parentattr[offgroup]; } } /* * new attribute is smaller than parent's * except for differences in SIDs which appear in * owner, group and possible grants and denials in * generic creator-owner and creator-group ACEs. * For directories, an ACE may be duplicated for * access and inheritance, so we double the count. */ usidsz = ntfs_sid_size(usid); gsidsz = ntfs_sid_size(gsid); newattrsz = parentattrsz + 3*usidsz + 3*gsidsz; if (fordir) newattrsz *= 2; newattr = (char*)ntfs_malloc(newattrsz); if (newattr) { pnhead = (SECURITY_DESCRIPTOR_RELATIVE*)newattr; pnhead->revision = SECURITY_DESCRIPTOR_REVISION; pnhead->alignment = 0; pnhead->control = (pphead->control & (SE_DACL_AUTO_INHERITED | SE_SACL_AUTO_INHERITED)) | SE_SELF_RELATIVE; pos = sizeof(SECURITY_DESCRIPTOR_RELATIVE); /* * locate and inherit DACL * do not test SE_DACL_PRESENT (wrong for "DR Watson") */ pnhead->dacl = const_cpu_to_le32(0); if (pphead->dacl) { offpacl = le32_to_cpu(pphead->dacl); ppacl = (const ACL*)&parentattr[offpacl]; pnacl = (ACL*)&newattr[pos]; aclsz = ntfs_inherit_acl(ppacl, pnacl, usid, gsid, fordir, pphead->control & SE_DACL_AUTO_INHERITED); if (aclsz) { pnhead->dacl = cpu_to_le32(pos); pos += aclsz; pnhead->control |= SE_DACL_PRESENT; } } /* * locate and inherit SACL */ pnhead->sacl = const_cpu_to_le32(0); if (pphead->sacl) { offpacl = le32_to_cpu(pphead->sacl); ppacl = (const ACL*)&parentattr[offpacl]; pnacl = (ACL*)&newattr[pos]; aclsz = ntfs_inherit_acl(ppacl, pnacl, usid, gsid, fordir, pphead->control & SE_SACL_AUTO_INHERITED); if (aclsz) { pnhead->sacl = cpu_to_le32(pos); pos += aclsz; pnhead->control |= SE_SACL_PRESENT; } } /* * inherit or redefine owner */ memcpy(&newattr[pos],usid,usidsz); pnhead->owner = cpu_to_le32(pos); pos += usidsz; /* * inherit or redefine group */ memcpy(&newattr[pos],gsid,gsidsz); pnhead->group = cpu_to_le32(pos); pos += gsidsz; securid = setsecurityattr(scx->vol, (SECURITY_DESCRIPTOR_RELATIVE*)newattr, pos); free(newattr); } else securid = const_cpu_to_le32(0); return (securid); } /* * Get an inherited security id * * For Windows compatibility, the normal initial permission setting * may be inherited from the parent directory instead of being * defined by the creation arguments. * * The following creates an inherited id for that purpose. * * Note : the owner and group of parent directory are also * inherited (which is not the case on Windows) if no user mapping * is defined. * * Returns the inherited id, or zero if not possible (eg on NTFS 1.x) */ le32 ntfs_inherited_id(struct SECURITY_CONTEXT *scx, ntfs_inode *dir_ni, BOOL fordir) { struct CACHED_PERMISSIONS *cached; char *parentattr; le32 securid; securid = const_cpu_to_le32(0); cached = (struct CACHED_PERMISSIONS*)NULL; /* * Try to get inherited id from cache, possible when * the current process owns the parent directory */ if (test_nino_flag(dir_ni, v3_Extensions) && dir_ni->security_id) { cached = fetch_cache(scx, dir_ni); if (cached && (cached->uid == scx->uid) && (cached->gid == scx->gid)) securid = (fordir ? cached->inh_dirid : cached->inh_fileid); } /* * Not cached or not available in cache, compute it all * Note : if parent directory has no id, it is not cacheable */ if (!securid) { parentattr = getsecurityattr(scx->vol, dir_ni); if (parentattr) { securid = build_inherited_id(scx, parentattr, fordir); free(parentattr); /* * Store the result into cache for further use * if the current process owns the parent directory */ if (securid) { cached = fetch_cache(scx, dir_ni); if (cached && (cached->uid == scx->uid) && (cached->gid == scx->gid)) { if (fordir) cached->inh_dirid = securid; else cached->inh_fileid = securid; } } } } return (securid); } /* * Link a group to a member of group * * Returns 0 if OK, -1 (and errno set) if error */ static int link_single_group(struct MAPPING *usermapping, struct passwd *user, gid_t gid) { struct group *group; char **grmem; int grcnt; gid_t *groups; int res; res = 0; group = getgrgid(gid); if (group && group->gr_mem) { grcnt = usermapping->grcnt; groups = usermapping->groups; grmem = group->gr_mem; while (*grmem && strcmp(user->pw_name, *grmem)) grmem++; if (*grmem) { if (!grcnt) groups = (gid_t*)malloc(sizeof(gid_t)); else groups = (gid_t*)realloc(groups, (grcnt+1)*sizeof(gid_t)); if (groups) groups[grcnt++] = gid; else { res = -1; errno = ENOMEM; } } usermapping->grcnt = grcnt; usermapping->groups = groups; } return (res); } /* * Statically link group to users * This is based on groups defined in /etc/group and does not take * the groups dynamically set by setgroups() nor any changes in * /etc/group into account * * Only mapped groups and root group are linked to mapped users * * Returns 0 if OK, -1 (and errno set) if error * */ static int link_group_members(struct SECURITY_CONTEXT *scx) { struct MAPPING *usermapping; struct MAPPING *groupmapping; struct passwd *user; int res; res = 0; for (usermapping=scx->mapping[MAPUSERS]; usermapping && !res; usermapping=usermapping->next) { usermapping->grcnt = 0; usermapping->groups = (gid_t*)NULL; user = getpwuid(usermapping->xid); if (user && user->pw_name) { for (groupmapping=scx->mapping[MAPGROUPS]; groupmapping && !res; groupmapping=groupmapping->next) { if (link_single_group(usermapping, user, groupmapping->xid)) res = -1; } if (!res && link_single_group(usermapping, user, (gid_t)0)) res = -1; } } return (res); } /* * Apply default single user mapping * returns zero if successful */ static int ntfs_do_default_mapping(struct SECURITY_CONTEXT *scx, uid_t uid, gid_t gid, const SID *usid) { struct MAPPING *usermapping; struct MAPPING *groupmapping; SID *sid; int sidsz; int res; res = -1; sidsz = ntfs_sid_size(usid); sid = (SID*)ntfs_malloc(sidsz); if (sid) { memcpy(sid,usid,sidsz); usermapping = (struct MAPPING*)ntfs_malloc(sizeof(struct MAPPING)); if (usermapping) { groupmapping = (struct MAPPING*)ntfs_malloc(sizeof(struct MAPPING)); if (groupmapping) { usermapping->sid = sid; usermapping->xid = uid; usermapping->next = (struct MAPPING*)NULL; groupmapping->sid = sid; groupmapping->xid = gid; groupmapping->next = (struct MAPPING*)NULL; scx->mapping[MAPUSERS] = usermapping; scx->mapping[MAPGROUPS] = groupmapping; res = 0; } } } return (res); } /* * Make sure there are no ambiguous mapping * Ambiguous mapping may lead to undesired configurations and * we had rather be safe until the consequences are understood */ #if 0 /* not activated for now */ static BOOL check_mapping(const struct MAPPING *usermapping, const struct MAPPING *groupmapping) { const struct MAPPING *mapping1; const struct MAPPING *mapping2; BOOL ambiguous; ambiguous = FALSE; for (mapping1=usermapping; mapping1; mapping1=mapping1->next) for (mapping2=mapping1->next; mapping2; mapping1=mapping2->next) if (ntfs_same_sid(mapping1->sid,mapping2->sid)) { if (mapping1->xid != mapping2->xid) ambiguous = TRUE; } else { if (mapping1->xid == mapping2->xid) ambiguous = TRUE; } for (mapping1=groupmapping; mapping1; mapping1=mapping1->next) for (mapping2=mapping1->next; mapping2; mapping1=mapping2->next) if (ntfs_same_sid(mapping1->sid,mapping2->sid)) { if (mapping1->xid != mapping2->xid) ambiguous = TRUE; } else { if (mapping1->xid == mapping2->xid) ambiguous = TRUE; } return (ambiguous); } #endif #if 0 /* not used any more */ /* * Try and apply default single user mapping * returns zero if successful */ static int ntfs_default_mapping(struct SECURITY_CONTEXT *scx) { const SECURITY_DESCRIPTOR_RELATIVE *phead; ntfs_inode *ni; char *securattr; const SID *usid; int res; res = -1; ni = ntfs_pathname_to_inode(scx->vol, NULL, "/."); if (ni) { securattr = getsecurityattr(scx->vol, ni); if (securattr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*)securattr; usid = (SID*)&securattr[le32_to_cpu(phead->owner)]; if (ntfs_is_user_sid(usid)) res = ntfs_do_default_mapping(scx, scx->uid, scx->gid, usid); free(securattr); } ntfs_inode_close(ni); } return (res); } #endif /* * Basic read from a user mapping file on another volume */ static int basicread(void *fileid, char *buf, size_t size, off_t offs __attribute__((unused))) { return (read(*(int*)fileid, buf, size)); } /* * Read from a user mapping file on current NTFS partition */ static int localread(void *fileid, char *buf, size_t size, off_t offs) { return (ntfs_attr_data_read((ntfs_inode*)fileid, AT_UNNAMED, 0, buf, size, offs)); } /* * Build the user mapping * - according to a mapping file if defined (or default present), * - or try default single user mapping if possible * * The mapping is specific to a mounted device * No locking done, mounting assumed non multithreaded * * returns zero if mapping is successful * (failure should not be interpreted as an error) */ int ntfs_build_mapping(struct SECURITY_CONTEXT *scx, const char *usermap_path, BOOL allowdef) { struct MAPLIST *item; struct MAPLIST *firstitem; struct MAPPING *usermapping; struct MAPPING *groupmapping; ntfs_inode *ni; int fd; static struct { u8 revision; u8 levels; be16 highbase; be32 lowbase; le32 level1; le32 level2; le32 level3; le32 level4; le32 level5; } defmap = { 1, 5, const_cpu_to_be16(0), const_cpu_to_be32(5), const_cpu_to_le32(21), const_cpu_to_le32(DEFSECAUTH1), const_cpu_to_le32(DEFSECAUTH2), const_cpu_to_le32(DEFSECAUTH3), const_cpu_to_le32(DEFSECBASE) } ; /* be sure not to map anything until done */ scx->mapping[MAPUSERS] = (struct MAPPING*)NULL; scx->mapping[MAPGROUPS] = (struct MAPPING*)NULL; if (!usermap_path) usermap_path = MAPPINGFILE; if (usermap_path[0] == '/') { fd = open(usermap_path,O_RDONLY); if (fd > 0) { firstitem = ntfs_read_mapping(basicread, (void*)&fd); close(fd); } else firstitem = (struct MAPLIST*)NULL; } else { ni = ntfs_pathname_to_inode(scx->vol, NULL, usermap_path); if (ni) { firstitem = ntfs_read_mapping(localread, ni); ntfs_inode_close(ni); } else firstitem = (struct MAPLIST*)NULL; } if (firstitem) { usermapping = ntfs_do_user_mapping(firstitem); groupmapping = ntfs_do_group_mapping(firstitem); if (usermapping && groupmapping) { scx->mapping[MAPUSERS] = usermapping; scx->mapping[MAPGROUPS] = groupmapping; } else ntfs_log_error("There were no valid user or no valid group\n"); /* now we can free the memory copy of input text */ /* and rely on internal representation */ while (firstitem) { item = firstitem->next; free(firstitem); firstitem = item; } } else { /* no mapping file, try a default mapping */ if (allowdef) { if (!ntfs_do_default_mapping(scx, 0, 0, (const SID*)&defmap)) ntfs_log_info("Using default user mapping\n"); } } return (!scx->mapping[MAPUSERS] || link_group_members(scx)); } /* * Get the ntfs attribute into an extended attribute * The attribute is returned according to cpu endianness */ int ntfs_get_ntfs_attrib(ntfs_inode *ni, char *value, size_t size) { u32 attrib; size_t outsize; outsize = 0; /* default to no data and no error */ if (ni) { attrib = le32_to_cpu(ni->flags); if (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) attrib |= const_le32_to_cpu(FILE_ATTR_DIRECTORY); else attrib &= ~const_le32_to_cpu(FILE_ATTR_DIRECTORY); if (!attrib) attrib |= const_le32_to_cpu(FILE_ATTR_NORMAL); outsize = sizeof(FILE_ATTR_FLAGS); if (size >= outsize) { if (value) memcpy(value,&attrib,outsize); else errno = EINVAL; } } return (outsize ? (int)outsize : -errno); } /* * Return the ntfs attribute into an extended attribute * The attribute is expected according to cpu endianness * * Returns 0, or -1 if there is a problem */ int ntfs_set_ntfs_attrib(ntfs_inode *ni, const char *value, size_t size, int flags) { u32 attrib; le32 settable; ATTR_FLAGS dirflags; int res; res = -1; if (ni && value && (size >= sizeof(FILE_ATTR_FLAGS))) { if (!(flags & XATTR_CREATE)) { /* copy to avoid alignment problems */ memcpy(&attrib,value,sizeof(FILE_ATTR_FLAGS)); settable = FILE_ATTR_SETTABLE; res = 0; if (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) { /* * Accept changing compression for a directory * and set index root accordingly */ settable |= FILE_ATTR_COMPRESSED; if ((ni->flags ^ cpu_to_le32(attrib)) & FILE_ATTR_COMPRESSED) { if (ni->flags & FILE_ATTR_COMPRESSED) dirflags = const_cpu_to_le16(0); else dirflags = ATTR_IS_COMPRESSED; res = ntfs_attr_set_flags(ni, AT_INDEX_ROOT, NTFS_INDEX_I30, 4, dirflags, ATTR_COMPRESSION_MASK); } } if (!res) { ni->flags = (ni->flags & ~settable) | (cpu_to_le32(attrib) & settable); NInoFileNameSetDirty(ni); NInoSetDirty(ni); } } else errno = EEXIST; } else errno = EINVAL; return (res ? -1 : 0); } /* * Open the volume's security descriptor index ($Secure) * * returns 0 if it succeeds * -1 with errno set if it fails and the volume is NTFS v3.0+ */ int ntfs_open_secure(ntfs_volume *vol) { ntfs_inode *ni; ntfs_index_context *sii; ntfs_index_context *sdh; if (vol->secure_ni) /* Already open? */ return 0; ni = ntfs_pathname_to_inode(vol, NULL, "$Secure"); if (!ni) goto err; if (ni->mft_no != FILE_Secure) { ntfs_log_error("$Secure does not have expected inode number!"); errno = EINVAL; goto err_close_ni; } /* Allocate the needed index contexts. */ sii = ntfs_index_ctx_get(ni, sii_stream, 4); if (!sii) goto err_close_ni; sdh = ntfs_index_ctx_get(ni, sdh_stream, 4); if (!sdh) goto err_close_sii; vol->secure_xsdh = sdh; vol->secure_xsii = sii; vol->secure_ni = ni; return 0; err_close_sii: ntfs_index_ctx_put(sii); err_close_ni: ntfs_inode_close(ni); err: /* Failing on NTFS pre-v3.0 is expected. */ if (vol->major_ver < 3) return 0; ntfs_log_perror("Failed to open $Secure"); return -1; } /* * Close the volume's security descriptor index ($Secure) * * returns 0 if it succeeds * -1 with errno set if it fails */ int ntfs_close_secure(ntfs_volume *vol) { int res = 0; if (vol->secure_ni) { ntfs_index_ctx_put(vol->secure_xsdh); ntfs_index_ctx_put(vol->secure_xsii); res = ntfs_inode_close(vol->secure_ni); vol->secure_ni = NULL; } return res; } /* * Destroy a security context * Allocated memory is freed to facilitate the detection of memory leaks */ void ntfs_destroy_security_context(struct SECURITY_CONTEXT *scx) { ntfs_free_mapping(scx->mapping); free_caches(scx); } /* * API for direct access to security descriptors * based on Win32 API */ /* * Selective feeding of a security descriptor into user buffer * * Returns TRUE if successful */ static BOOL feedsecurityattr(const char *attr, u32 selection, char *buf, u32 buflen, u32 *psize) { const SECURITY_DESCRIPTOR_RELATIVE *phead; SECURITY_DESCRIPTOR_RELATIVE *pnhead; const ACL *pdacl; const ACL *psacl; const SID *pusid; const SID *pgsid; unsigned int offdacl; unsigned int offsacl; unsigned int offowner; unsigned int offgroup; unsigned int daclsz; unsigned int saclsz; unsigned int usidsz; unsigned int gsidsz; unsigned int size; /* size of requested attributes */ BOOL ok; unsigned int pos; unsigned int avail; le16 control; avail = 0; control = SE_SELF_RELATIVE; phead = (const SECURITY_DESCRIPTOR_RELATIVE*)attr; size = sizeof(SECURITY_DESCRIPTOR_RELATIVE); /* locate DACL if requested and available */ if (phead->dacl && (selection & DACL_SECURITY_INFORMATION)) { offdacl = le32_to_cpu(phead->dacl); pdacl = (const ACL*)&attr[offdacl]; daclsz = le16_to_cpu(pdacl->size); size += daclsz; avail |= DACL_SECURITY_INFORMATION; } else offdacl = daclsz = 0; /* locate owner if requested and available */ offowner = le32_to_cpu(phead->owner); if (offowner && (selection & OWNER_SECURITY_INFORMATION)) { /* find end of USID */ pusid = (const SID*)&attr[offowner]; usidsz = ntfs_sid_size(pusid); size += usidsz; avail |= OWNER_SECURITY_INFORMATION; } else offowner = usidsz = 0; /* locate group if requested and available */ offgroup = le32_to_cpu(phead->group); if (offgroup && (selection & GROUP_SECURITY_INFORMATION)) { /* find end of GSID */ pgsid = (const SID*)&attr[offgroup]; gsidsz = ntfs_sid_size(pgsid); size += gsidsz; avail |= GROUP_SECURITY_INFORMATION; } else offgroup = gsidsz = 0; /* locate SACL if requested and available */ if (phead->sacl && (selection & SACL_SECURITY_INFORMATION)) { /* find end of SACL */ offsacl = le32_to_cpu(phead->sacl); psacl = (const ACL*)&attr[offsacl]; saclsz = le16_to_cpu(psacl->size); size += saclsz; avail |= SACL_SECURITY_INFORMATION; } else offsacl = saclsz = 0; /* * Check having enough size in destination buffer * (required size is returned nevertheless so that * the request can be reissued with adequate size) */ if (size > buflen) { *psize = size; errno = EINVAL; ok = FALSE; } else { if (selection & OWNER_SECURITY_INFORMATION) control |= phead->control & SE_OWNER_DEFAULTED; if (selection & GROUP_SECURITY_INFORMATION) control |= phead->control & SE_GROUP_DEFAULTED; if (selection & DACL_SECURITY_INFORMATION) control |= phead->control & (SE_DACL_PRESENT | SE_DACL_DEFAULTED | SE_DACL_AUTO_INHERITED | SE_DACL_PROTECTED); if (selection & SACL_SECURITY_INFORMATION) control |= phead->control & (SE_SACL_PRESENT | SE_SACL_DEFAULTED | SE_SACL_AUTO_INHERITED | SE_SACL_PROTECTED); /* * copy header and feed new flags, even if no detailed data */ memcpy(buf,attr,sizeof(SECURITY_DESCRIPTOR_RELATIVE)); pnhead = (SECURITY_DESCRIPTOR_RELATIVE*)buf; pnhead->control = control; pos = sizeof(SECURITY_DESCRIPTOR_RELATIVE); /* copy DACL if requested and available */ if (selection & avail & DACL_SECURITY_INFORMATION) { pnhead->dacl = cpu_to_le32(pos); memcpy(&buf[pos],&attr[offdacl],daclsz); pos += daclsz; } else pnhead->dacl = const_cpu_to_le32(0); /* copy SACL if requested and available */ if (selection & avail & SACL_SECURITY_INFORMATION) { pnhead->sacl = cpu_to_le32(pos); memcpy(&buf[pos],&attr[offsacl],saclsz); pos += saclsz; } else pnhead->sacl = const_cpu_to_le32(0); /* copy owner if requested and available */ if (selection & avail & OWNER_SECURITY_INFORMATION) { pnhead->owner = cpu_to_le32(pos); memcpy(&buf[pos],&attr[offowner],usidsz); pos += usidsz; } else pnhead->owner = const_cpu_to_le32(0); /* copy group if requested and available */ if (selection & avail & GROUP_SECURITY_INFORMATION) { pnhead->group = cpu_to_le32(pos); memcpy(&buf[pos],&attr[offgroup],gsidsz); pos += gsidsz; } else pnhead->group = const_cpu_to_le32(0); if (pos != size) ntfs_log_error("Error in security descriptor size\n"); *psize = size; ok = TRUE; } return (ok); } /* * Merge a new security descriptor into the old one * and assign to designated file * * Returns TRUE if successful */ static BOOL mergesecurityattr(ntfs_volume *vol, const char *oldattr, const char *newattr, u32 selection, ntfs_inode *ni) { const SECURITY_DESCRIPTOR_RELATIVE *oldhead; const SECURITY_DESCRIPTOR_RELATIVE *newhead; SECURITY_DESCRIPTOR_RELATIVE *targhead; const ACL *pdacl; const ACL *psacl; const SID *powner; const SID *pgroup; int offdacl; int offsacl; int offowner; int offgroup; unsigned int size; le16 control; char *target; int pos; int oldattrsz; int newattrsz; BOOL ok; ok = FALSE; /* default return */ oldhead = (const SECURITY_DESCRIPTOR_RELATIVE*)oldattr; newhead = (const SECURITY_DESCRIPTOR_RELATIVE*)newattr; oldattrsz = ntfs_attr_size(oldattr); newattrsz = ntfs_attr_size(newattr); target = (char*)ntfs_malloc(oldattrsz + newattrsz); if (target) { targhead = (SECURITY_DESCRIPTOR_RELATIVE*)target; pos = sizeof(SECURITY_DESCRIPTOR_RELATIVE); control = SE_SELF_RELATIVE; /* * copy new DACL if selected * or keep old DACL if any */ if ((selection & DACL_SECURITY_INFORMATION) ? newhead->dacl : oldhead->dacl) { if (selection & DACL_SECURITY_INFORMATION) { offdacl = le32_to_cpu(newhead->dacl); pdacl = (const ACL*)&newattr[offdacl]; } else { offdacl = le32_to_cpu(oldhead->dacl); pdacl = (const ACL*)&oldattr[offdacl]; } size = le16_to_cpu(pdacl->size); memcpy(&target[pos], pdacl, size); targhead->dacl = cpu_to_le32(pos); pos += size; } else targhead->dacl = const_cpu_to_le32(0); if (selection & DACL_SECURITY_INFORMATION) { control |= newhead->control & (SE_DACL_PRESENT | SE_DACL_DEFAULTED | SE_DACL_PROTECTED); if (newhead->control & SE_DACL_AUTO_INHERIT_REQ) control |= SE_DACL_AUTO_INHERITED; } else control |= oldhead->control & (SE_DACL_PRESENT | SE_DACL_DEFAULTED | SE_DACL_AUTO_INHERITED | SE_DACL_PROTECTED); /* * copy new SACL if selected * or keep old SACL if any */ if ((selection & SACL_SECURITY_INFORMATION) ? newhead->sacl : oldhead->sacl) { if (selection & SACL_SECURITY_INFORMATION) { offsacl = le32_to_cpu(newhead->sacl); psacl = (const ACL*)&newattr[offsacl]; } else { offsacl = le32_to_cpu(oldhead->sacl); psacl = (const ACL*)&oldattr[offsacl]; } size = le16_to_cpu(psacl->size); memcpy(&target[pos], psacl, size); targhead->sacl = cpu_to_le32(pos); pos += size; } else targhead->sacl = const_cpu_to_le32(0); if (selection & SACL_SECURITY_INFORMATION) { control |= newhead->control & (SE_SACL_PRESENT | SE_SACL_DEFAULTED | SE_SACL_PROTECTED); if (newhead->control & SE_SACL_AUTO_INHERIT_REQ) control |= SE_SACL_AUTO_INHERITED; } else control |= oldhead->control & (SE_SACL_PRESENT | SE_SACL_DEFAULTED | SE_SACL_AUTO_INHERITED | SE_SACL_PROTECTED); /* * copy new OWNER if selected * or keep old OWNER if any */ if ((selection & OWNER_SECURITY_INFORMATION) ? newhead->owner : oldhead->owner) { if (selection & OWNER_SECURITY_INFORMATION) { offowner = le32_to_cpu(newhead->owner); powner = (const SID*)&newattr[offowner]; } else { offowner = le32_to_cpu(oldhead->owner); powner = (const SID*)&oldattr[offowner]; } size = ntfs_sid_size(powner); memcpy(&target[pos], powner, size); targhead->owner = cpu_to_le32(pos); pos += size; } else targhead->owner = const_cpu_to_le32(0); if (selection & OWNER_SECURITY_INFORMATION) control |= newhead->control & SE_OWNER_DEFAULTED; else control |= oldhead->control & SE_OWNER_DEFAULTED; /* * copy new GROUP if selected * or keep old GROUP if any */ if ((selection & GROUP_SECURITY_INFORMATION) ? newhead->group : oldhead->group) { if (selection & GROUP_SECURITY_INFORMATION) { offgroup = le32_to_cpu(newhead->group); pgroup = (const SID*)&newattr[offgroup]; control |= newhead->control & SE_GROUP_DEFAULTED; } else { offgroup = le32_to_cpu(oldhead->group); pgroup = (const SID*)&oldattr[offgroup]; control |= oldhead->control & SE_GROUP_DEFAULTED; } size = ntfs_sid_size(pgroup); memcpy(&target[pos], pgroup, size); targhead->group = cpu_to_le32(pos); pos += size; } else targhead->group = const_cpu_to_le32(0); if (selection & GROUP_SECURITY_INFORMATION) control |= newhead->control & SE_GROUP_DEFAULTED; else control |= oldhead->control & SE_GROUP_DEFAULTED; targhead->revision = SECURITY_DESCRIPTOR_REVISION; targhead->alignment = 0; targhead->control = control; ok = !update_secur_descr(vol, target, ni); free(target); } return (ok); } /* * Return the security descriptor of a file * This is intended to be similar to GetFileSecurity() from Win32 * in order to facilitate the development of portable tools * * returns zero if unsuccessful (following Win32 conventions) * -1 if no securid * the securid if any * * The Win32 API is : * * BOOL WINAPI GetFileSecurity( * __in LPCTSTR lpFileName, * __in SECURITY_INFORMATION RequestedInformation, * __out_opt PSECURITY_DESCRIPTOR pSecurityDescriptor, * __in DWORD nLength, * __out LPDWORD lpnLengthNeeded * ); * */ int ntfs_get_file_security(struct SECURITY_API *scapi, const char *path, u32 selection, char *buf, u32 buflen, u32 *psize) { ntfs_inode *ni; char *attr; int res; res = 0; /* default return */ if (scapi && (scapi->magic == MAGIC_API)) { ni = ntfs_pathname_to_inode(scapi->security.vol, NULL, path); if (ni) { attr = getsecurityattr(scapi->security.vol, ni); if (attr) { if (feedsecurityattr(attr,selection, buf,buflen,psize)) { if (test_nino_flag(ni, v3_Extensions) && ni->security_id) res = le32_to_cpu( ni->security_id); else res = -1; } free(attr); } ntfs_inode_close(ni); } else errno = ENOENT; if (!res) *psize = 0; } else errno = EINVAL; /* do not clear *psize */ return (res); } /* * Set the security descriptor of a file or directory * This is intended to be similar to SetFileSecurity() from Win32 * in order to facilitate the development of portable tools * * returns zero if unsuccessful (following Win32 conventions) * -1 if no securid * the securid if any * * The Win32 API is : * * BOOL WINAPI SetFileSecurity( * __in LPCTSTR lpFileName, * __in SECURITY_INFORMATION SecurityInformation, * __in PSECURITY_DESCRIPTOR pSecurityDescriptor * ); */ int ntfs_set_file_security(struct SECURITY_API *scapi, const char *path, u32 selection, const char *attr) { const SECURITY_DESCRIPTOR_RELATIVE *phead; ntfs_inode *ni; int attrsz; BOOL missing; char *oldattr; int res; res = 0; /* default return */ if (scapi && (scapi->magic == MAGIC_API) && attr) { phead = (const SECURITY_DESCRIPTOR_RELATIVE*)attr; attrsz = ntfs_attr_size(attr); /* if selected, owner and group must be present or defaulted */ missing = ((selection & OWNER_SECURITY_INFORMATION) && !phead->owner && !(phead->control & SE_OWNER_DEFAULTED)) || ((selection & GROUP_SECURITY_INFORMATION) && !phead->group && !(phead->control & SE_GROUP_DEFAULTED)); if (!missing && (phead->control & SE_SELF_RELATIVE) && ntfs_valid_descr(attr, attrsz)) { ni = ntfs_pathname_to_inode(scapi->security.vol, NULL, path); if (ni) { oldattr = getsecurityattr(scapi->security.vol, ni); if (oldattr) { if (mergesecurityattr( scapi->security.vol, oldattr, attr, selection, ni)) { if (test_nino_flag(ni, v3_Extensions)) res = le32_to_cpu( ni->security_id); else res = -1; } free(oldattr); } ntfs_inode_close(ni); } } else errno = EINVAL; } else errno = EINVAL; return (res); } /* * Return the attributes of a file * This is intended to be similar to GetFileAttributes() from Win32 * in order to facilitate the development of portable tools * * returns -1 if unsuccessful (Win32 : INVALID_FILE_ATTRIBUTES) * * The Win32 API is : * * DWORD WINAPI GetFileAttributes( * __in LPCTSTR lpFileName * ); */ int ntfs_get_file_attributes(struct SECURITY_API *scapi, const char *path) { ntfs_inode *ni; s32 attrib; attrib = -1; /* default return */ if (scapi && (scapi->magic == MAGIC_API) && path) { ni = ntfs_pathname_to_inode(scapi->security.vol, NULL, path); if (ni) { attrib = le32_to_cpu(ni->flags); if (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) attrib |= const_le32_to_cpu(FILE_ATTR_DIRECTORY); else attrib &= ~const_le32_to_cpu(FILE_ATTR_DIRECTORY); if (!attrib) attrib |= const_le32_to_cpu(FILE_ATTR_NORMAL); ntfs_inode_close(ni); } else errno = ENOENT; } else errno = EINVAL; /* do not clear *psize */ return (attrib); } /* * Set attributes to a file or directory * This is intended to be similar to SetFileAttributes() from Win32 * in order to facilitate the development of portable tools * * Only a few flags can be set (same list as Win32) * * returns zero if unsuccessful (following Win32 conventions) * nonzero if successful * * The Win32 API is : * * BOOL WINAPI SetFileAttributes( * __in LPCTSTR lpFileName, * __in DWORD dwFileAttributes * ); */ BOOL ntfs_set_file_attributes(struct SECURITY_API *scapi, const char *path, s32 attrib) { ntfs_inode *ni; le32 settable; ATTR_FLAGS dirflags; int res; res = 0; /* default return */ if (scapi && (scapi->magic == MAGIC_API) && path) { ni = ntfs_pathname_to_inode(scapi->security.vol, NULL, path); if (ni) { settable = FILE_ATTR_SETTABLE; if (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) { /* * Accept changing compression for a directory * and set index root accordingly */ settable |= FILE_ATTR_COMPRESSED; if ((ni->flags ^ cpu_to_le32(attrib)) & FILE_ATTR_COMPRESSED) { if (ni->flags & FILE_ATTR_COMPRESSED) dirflags = const_cpu_to_le16(0); else dirflags = ATTR_IS_COMPRESSED; res = ntfs_attr_set_flags(ni, AT_INDEX_ROOT, NTFS_INDEX_I30, 4, dirflags, ATTR_COMPRESSION_MASK); } } if (!res) { ni->flags = (ni->flags & ~settable) | (cpu_to_le32(attrib) & settable); NInoSetDirty(ni); NInoFileNameSetDirty(ni); } if (!ntfs_inode_close(ni)) res = -1; } else errno = ENOENT; } return (res); } BOOL ntfs_read_directory(struct SECURITY_API *scapi, const char *path, ntfs_filldir_t callback, void *context) { ntfs_inode *ni; BOOL ok; s64 pos; ok = FALSE; /* default return */ if (scapi && (scapi->magic == MAGIC_API) && callback) { ni = ntfs_pathname_to_inode(scapi->security.vol, NULL, path); if (ni) { if (ni->mrec->flags & MFT_RECORD_IS_DIRECTORY) { pos = 0; ntfs_readdir(ni,&pos,context,callback); ok = !ntfs_inode_close(ni); } else { ntfs_inode_close(ni); errno = ENOTDIR; } } else errno = ENOENT; } else errno = EINVAL; /* do not clear *psize */ return (ok); } /* * read $SDS (for auditing security data) * * Returns the number or read bytes, or -1 if there is an error */ int ntfs_read_sds(struct SECURITY_API *scapi, char *buf, u32 size, u32 offset) { int got; got = -1; /* default return */ if (scapi && (scapi->magic == MAGIC_API)) { if (scapi->security.vol->secure_ni) got = ntfs_attr_data_read(scapi->security.vol->secure_ni, STREAM_SDS, 4, buf, size, offset); else errno = EOPNOTSUPP; } else errno = EINVAL; return (got); } /* * read $SII (for auditing security data) * * Returns next entry, or NULL if there is an error */ INDEX_ENTRY *ntfs_read_sii(struct SECURITY_API *scapi, INDEX_ENTRY *entry) { SII_INDEX_KEY key; INDEX_ENTRY *ret; BOOL found; ntfs_index_context *xsii; ret = (INDEX_ENTRY*)NULL; /* default return */ if (scapi && (scapi->magic == MAGIC_API)) { xsii = scapi->security.vol->secure_xsii; if (xsii) { if (!entry) { key.security_id = const_cpu_to_le32(0); found = !ntfs_index_lookup((char*)&key, sizeof(SII_INDEX_KEY), xsii); /* not supposed to find */ if (!found && (errno == ENOENT)) ret = xsii->entry; } else ret = ntfs_index_next(entry,xsii); if (!ret) errno = ENODATA; } else errno = EOPNOTSUPP; } else errno = EINVAL; return (ret); } /* * read $SDH (for auditing security data) * * Returns next entry, or NULL if there is an error */ INDEX_ENTRY *ntfs_read_sdh(struct SECURITY_API *scapi, INDEX_ENTRY *entry) { SDH_INDEX_KEY key; INDEX_ENTRY *ret; BOOL found; ntfs_index_context *xsdh; ret = (INDEX_ENTRY*)NULL; /* default return */ if (scapi && (scapi->magic == MAGIC_API)) { xsdh = scapi->security.vol->secure_xsdh; if (xsdh) { if (!entry) { key.hash = const_cpu_to_le32(0); key.security_id = const_cpu_to_le32(0); found = !ntfs_index_lookup((char*)&key, sizeof(SDH_INDEX_KEY), xsdh); /* not supposed to find */ if (!found && (errno == ENOENT)) ret = xsdh->entry; } else ret = ntfs_index_next(entry,xsdh); if (!ret) errno = ENODATA; } else errno = ENOTSUP; } else errno = EINVAL; return (ret); } /* * Get the mapped user SID * A buffer of 40 bytes has to be supplied * * returns the size of the SID, or zero and errno set if not found */ int ntfs_get_usid(struct SECURITY_API *scapi, uid_t uid, char *buf) { const SID *usid; BIGSID defusid; int size; size = 0; if (scapi && (scapi->magic == MAGIC_API)) { usid = ntfs_find_usid(scapi->security.mapping[MAPUSERS], uid, (SID*)&defusid); if (usid) { size = ntfs_sid_size(usid); memcpy(buf,usid,size); } else errno = ENODATA; } else errno = EINVAL; return (size); } /* * Get the mapped group SID * A buffer of 40 bytes has to be supplied * * returns the size of the SID, or zero and errno set if not found */ int ntfs_get_gsid(struct SECURITY_API *scapi, gid_t gid, char *buf) { const SID *gsid; BIGSID defgsid; int size; size = 0; if (scapi && (scapi->magic == MAGIC_API)) { gsid = ntfs_find_gsid(scapi->security.mapping[MAPGROUPS], gid, (SID*)&defgsid); if (gsid) { size = ntfs_sid_size(gsid); memcpy(buf,gsid,size); } else errno = ENODATA; } else errno = EINVAL; return (size); } /* * Get the user mapped to a SID * * returns the uid, or -1 if not found */ int ntfs_get_user(struct SECURITY_API *scapi, const SID *usid) { int uid; uid = -1; if (scapi && (scapi->magic == MAGIC_API) && ntfs_valid_sid(usid)) { if (ntfs_same_sid(usid,adminsid)) uid = 0; else { uid = ntfs_find_user(scapi->security.mapping[MAPUSERS], usid); if (!uid) { uid = -1; errno = ENODATA; } } } else errno = EINVAL; return (uid); } /* * Get the group mapped to a SID * * returns the uid, or -1 if not found */ int ntfs_get_group(struct SECURITY_API *scapi, const SID *gsid) { int gid; gid = -1; if (scapi && (scapi->magic == MAGIC_API) && ntfs_valid_sid(gsid)) { if (ntfs_same_sid(gsid,adminsid)) gid = 0; else { gid = ntfs_find_group(scapi->security.mapping[MAPGROUPS], gsid); if (!gid) { gid = -1; errno = ENODATA; } } } else errno = EINVAL; return (gid); } /* * Initializations before calling ntfs_get_file_security() * ntfs_set_file_security() and ntfs_read_directory() * * Only allowed for root * * Returns an (obscured) struct SECURITY_API* needed for further calls * NULL if not root (EPERM) or device is mounted (EBUSY) */ struct SECURITY_API *ntfs_initialize_file_security(const char *device, unsigned long flags) { ntfs_volume *vol; unsigned long mntflag; int mnt; struct SECURITY_API *scapi; struct SECURITY_CONTEXT *scx; scapi = (struct SECURITY_API*)NULL; mnt = ntfs_check_if_mounted(device, &mntflag); if (!mnt && !(mntflag & NTFS_MF_MOUNTED) && !getuid()) { vol = ntfs_mount(device, flags); if (vol) { scapi = (struct SECURITY_API*) ntfs_malloc(sizeof(struct SECURITY_API)); if (!ntfs_volume_get_free_space(vol) && scapi) { scapi->magic = MAGIC_API; scapi->seccache = (struct PERMISSIONS_CACHE*)NULL; scx = &scapi->security; scx->vol = vol; scx->uid = getuid(); scx->gid = getgid(); scx->pseccache = &scapi->seccache; scx->vol->secure_flags = 0; /* accept no mapping and no $Secure */ ntfs_build_mapping(scx,(const char*)NULL,TRUE); } else { if (scapi) free(scapi); else errno = ENOMEM; mnt = ntfs_umount(vol,FALSE); scapi = (struct SECURITY_API*)NULL; } } } else if (getuid()) errno = EPERM; else errno = EBUSY; return (scapi); } /* * Leaving after ntfs_initialize_file_security() * * Returns FALSE if FAILED */ BOOL ntfs_leave_file_security(struct SECURITY_API *scapi) { int ok; ntfs_volume *vol; ok = FALSE; if (scapi && (scapi->magic == MAGIC_API) && scapi->security.vol) { vol = scapi->security.vol; ntfs_destroy_security_context(&scapi->security); free(scapi); if (!ntfs_umount(vol, 0)) ok = TRUE; } return (ok); }