/* Unix SMB/CIFS implementation. new hash based name mangling implementation Copyright (C) Andrew Tridgell 2002 Copyright (C) Simo Sorce 2002 This program 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 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; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ /* this mangling scheme uses the following format Annnn~n.AAA where nnnnn is a base 36 hash, and A represents characters from the original string The hash is taken of the leading part of the long filename, in uppercase for simplicity, we only allow ascii characters in 8.3 names */ /* hash alghorithm changed to FNV1 by idra@samba.org (Simo Sorce). * see http://www.isthe.com/chongo/tech/comp/fnv/index.html for a * discussion on Fowler / Noll / Vo (FNV) Hash by one of it's authors */ /* =============================================================================== NOTE NOTE NOTE!!! This file deliberately uses non-multibyte string functions in many places. This is *not* a mistake. This code is multi-byte safe, but it gets this property through some very subtle knowledge of the way multi-byte strings are encoded and the fact that this mangling algorithm only supports ascii characters in 8.3 names. please don't convert this file to use the *_m() functions!! =============================================================================== */ #include "includes.h" #if 0 #define M_DEBUG(level, x) DEBUG(level, x) #else #define M_DEBUG(level, x) #endif /* these flags are used to mark characters in as having particular properties */ #define FLAG_BASECHAR 1 #define FLAG_ASCII 2 #define FLAG_ILLEGAL 4 #define FLAG_WILDCARD 8 /* the "possible" flags are used as a fast way to find possible DOS reserved filenames */ #define FLAG_POSSIBLE1 16 #define FLAG_POSSIBLE2 32 #define FLAG_POSSIBLE3 64 #define FLAG_POSSIBLE4 128 /* by default have a max of 4096 entries in the cache. */ #ifndef MANGLE_CACHE_SIZE #define MANGLE_CACHE_SIZE 4096 #endif #define FNV1_PRIME 0x01000193 /*the following number is a fnv1 of the string: idra@samba.org 2002 */ #define FNV1_INIT 0xa6b93095 /* these tables are used to provide fast tests for characters */ static unsigned char char_flags[256]; #define FLAG_CHECK(c, flag) (char_flags[(unsigned char)(c)] & (flag)) /* this determines how many characters are used from the original filename in the 8.3 mangled name. A larger value leads to a weaker hash and more collisions. The largest possible value is 6. */ static unsigned mangle_prefix; /* we will use a very simple direct mapped prefix cache. The big advantage of this cache structure is speed and low memory usage The cache is indexed by the low-order bits of the hash, and confirmed by hashing the resulting cache entry to match the known hash */ static char **prefix_cache; static u32 *prefix_cache_hashes; /* these are the characters we use in the 8.3 hash. Must be 36 chars long */ static const char *basechars = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"; static unsigned char base_reverse[256]; #define base_forward(v) basechars[v] /* the list of reserved dos names - all of these are illegal */ static const char *reserved_names[] = { "AUX", "LOCK$", "CON", "COM1", "COM2", "COM3", "COM4", "LPT1", "LPT2", "LPT3", "NUL", "PRN", NULL }; /* hash a string of the specified length. The string does not need to be null terminated this hash needs to be fast with a low collision rate (what hash doesn't?) */ static u32 mangle_hash(const char *key, unsigned length) { u32 value; u32 i; fstring str; /* we have to uppercase here to ensure that the mangled name doesn't depend on the case of the long name. Note that this is the only place where we need to use a multi-byte string function */ strncpy(str, key, length); str[length] = 0; strupper_m(str); /* the length of a multi-byte string can change after a strupper_m */ length = strlen(str); /* Set the initial value from the key size. */ for (value = FNV1_INIT, i=0; i < length; i++) { value *= (u32)FNV1_PRIME; value ^= (u32)(str[i]); } /* note that we force it to a 31 bit hash, to keep within the limits of the 36^6 mangle space */ return value & ~0x80000000; } /* initialise (ie. allocate) the prefix cache */ static BOOL cache_init(void) { if (prefix_cache) return True; prefix_cache = calloc(MANGLE_CACHE_SIZE, sizeof(char *)); if (!prefix_cache) return False; prefix_cache_hashes = calloc(MANGLE_CACHE_SIZE, sizeof(u32)); if (!prefix_cache_hashes) return False; return True; } /* insert an entry into the prefix cache. The string might not be null terminated */ static void cache_insert(const char *prefix, int length, u32 hash) { int i = hash % MANGLE_CACHE_SIZE; if (prefix_cache[i]) { free(prefix_cache[i]); } prefix_cache[i] = strndup(prefix, length); prefix_cache_hashes[i] = hash; } /* lookup an entry in the prefix cache. Return NULL if not found. */ static const char *cache_lookup(u32 hash) { int i = hash % MANGLE_CACHE_SIZE; if (!prefix_cache[i] || hash != prefix_cache_hashes[i]) { return NULL; } /* yep, it matched */ return prefix_cache[i]; } /* determine if a string is possibly in a mangled format, ignoring case In this algorithm, mangled names use only pure ascii characters (no multi-byte) so we can avoid doing a UCS2 conversion */ static BOOL is_mangled_component(const char *name) { unsigned int len, i; M_DEBUG(10,("is_mangled_component %s ?\n", name)); /* check the length */ len = strlen(name); if (len > 12 || len < 8) return False; /* the best distinguishing characteristic is the ~ */ if (name[6] != '~') return False; /* check extension */ if (len > 8) { if (name[8] != '.') return False; for (i=9; name[i]; i++) { if (! FLAG_CHECK(name[i], FLAG_ASCII)) { return False; } } } /* check lead characters */ for (i=0;i<mangle_prefix;i++) { if (! FLAG_CHECK(name[i], FLAG_ASCII)) { return False; } } /* check rest of hash */ if (! FLAG_CHECK(name[7], FLAG_BASECHAR)) { return False; } for (i=mangle_prefix;i<6;i++) { if (! FLAG_CHECK(name[i], FLAG_BASECHAR)) { return False; } } M_DEBUG(10,("is_mangled %s -> yes\n", name)); return True; } /* determine if a string is possibly in a mangled format, ignoring case In this algorithm, mangled names use only pure ascii characters (no multi-byte) so we can avoid doing a UCS2 conversion NOTE! This interface must be able to handle a path with unix directory separators. It should return true if any component is mangled */ static BOOL is_mangled(const char *name) { const char *p; const char *s; M_DEBUG(10,("is_mangled %s ?\n", name)); for (s=name; (p=strchr(s, '/')); s=p+1) { char *component = strndup(s, PTR_DIFF(p, s)); if (is_mangled_component(component)) { free(component); return True; } free(component); } /* and the last part ... */ return is_mangled_component(s); } /* see if a filename is an allowable 8.3 name. we are only going to allow ascii characters in 8.3 names, as this simplifies things greatly (it means that we know the string won't get larger when converted from UNIX to DOS formats) */ static BOOL is_8_3(const char *name, BOOL check_case, BOOL allow_wildcards) { int len, i; char *dot_p; /* as a special case, the names '.' and '..' are allowable 8.3 names */ if (name[0] == '.') { if (!name[1] || (name[1] == '.' && !name[2])) { return True; } } /* the simplest test is on the overall length of the filename. Note that we deliberately use the ascii string length (not the multi-byte one) as it is faster, and gives us the result we need in this case. Using strlen_m would not only be slower, it would be incorrect */ len = strlen(name); if (len > 12) return False; /* find the '.'. Note that once again we use the non-multibyte function */ dot_p = strchr(name, '.'); if (!dot_p) { /* if the name doesn't contain a '.' then its length must be less than 8 */ if (len > 8) { return False; } } else { int prefix_len, suffix_len; /* if it does contain a dot then the prefix must be <= 8 and the suffix <= 3 in length */ prefix_len = PTR_DIFF(dot_p, name); suffix_len = len - (prefix_len+1); if (prefix_len > 8 || suffix_len > 3) { return False; } /* a 8.3 name cannot contain more than 1 '.' */ if (strchr(dot_p+1, '.')) { return False; } } /* the length are all OK. Now check to see if the characters themselves are OK */ for (i=0; name[i]; i++) { /* note that we may allow wildcard petterns! */ if (!FLAG_CHECK(name[i], FLAG_ASCII|(allow_wildcards ? FLAG_WILDCARD : 0)) && name[i] != '.') { return False; } } /* it is a good 8.3 name */ return True; } /* reset the mangling cache on a smb.conf reload. This only really makes sense for mangling backends that have parameters in smb.conf, and as this backend doesn't this is a NULL operation */ static void mangle_reset(void) { /* noop */ } /* try to find a 8.3 name in the cache, and if found then replace the string with the original long name. The filename must be able to hold at least sizeof(fstring) */ static BOOL check_cache(char *name) { u32 hash, multiplier; unsigned int i; const char *prefix; char extension[4]; /* make sure that this is a mangled name from this cache */ if (!is_mangled(name)) { M_DEBUG(10,("check_cache: %s -> not mangled\n", name)); return False; } /* we need to extract the hash from the 8.3 name */ hash = base_reverse[(unsigned char)name[7]]; for (multiplier=36, i=5;i>=mangle_prefix;i--) { u32 v = base_reverse[(unsigned char)name[i]]; hash += multiplier * v; multiplier *= 36; } /* now look in the prefix cache for that hash */ prefix = cache_lookup(hash); if (!prefix) { M_DEBUG(10,("check_cache: %s -> %08X -> not found\n", name, hash)); return False; } /* we found it - construct the full name */ if (name[8] == '.') { strncpy(extension, name+9, 3); extension[3] = 0; } else { extension[0] = 0; } if (extension[0]) { M_DEBUG(10,("check_cache: %s -> %s.%s\n", name, prefix, extension)); slprintf(name, sizeof(fstring), "%s.%s", prefix, extension); } else { M_DEBUG(10,("check_cache: %s -> %s\n", name, prefix)); fstrcpy(name, prefix); } return True; } /* look for a DOS reserved name */ static BOOL is_reserved_name(const char *name) { if (FLAG_CHECK(name[0], FLAG_POSSIBLE1) && FLAG_CHECK(name[1], FLAG_POSSIBLE2) && FLAG_CHECK(name[2], FLAG_POSSIBLE3) && FLAG_CHECK(name[3], FLAG_POSSIBLE4)) { /* a likely match, scan the lot */ int i; for (i=0; reserved_names[i]; i++) { int len = strlen(reserved_names[i]); /* note that we match on COM1 as well as COM1.foo */ if (strncasecmp(name, reserved_names[i], len) == 0 && (name[len] == '.' || name[len] == 0)) { return True; } } } return False; } /* See if a filename is a legal long filename. A filename ending in a '.' is not legal unless it's "." or "..". JRA. */ static BOOL is_legal_name(const char *name) { const char *dot_pos = NULL; BOOL alldots = True; size_t numdots = 0; while (*name) { if (FLAG_CHECK(name[0], FLAG_ILLEGAL)) { return False; } if (name[0] == '.') { dot_pos = name; numdots++; } else { alldots = False; } name++; } if (dot_pos) { if (alldots && (numdots == 1 || numdots == 2)) return True; /* . or .. is a valid name */ /* A valid long name cannot end in '.' */ if (dot_pos[1] == '\0') return False; } return True; } /* the main forward mapping function, which converts a long filename to a 8.3 name if need83 is not set then we only do the mangling if the name is illegal as a long name if cache83 is not set then we don't cache the result the name parameter must be able to hold 13 bytes */ static void name_map(fstring name, BOOL need83, BOOL cache83) { char *dot_p; char lead_chars[7]; char extension[4]; unsigned int extension_length, i; unsigned int prefix_len; u32 hash, v; char new_name[13]; /* reserved names are handled specially */ if (!is_reserved_name(name)) { /* if the name is already a valid 8.3 name then we don't need to do anything */ if (is_8_3(name, False, False)) { return; } /* if the caller doesn't strictly need 8.3 then just check for illegal filenames */ if (!need83 && is_legal_name(name)) { return; } } /* find the '.' if any */ dot_p = strrchr(name, '.'); if (dot_p) { /* if the extension contains any illegal characters or is too long or zero length then we treat it as part of the prefix */ for (i=0; i<4 && dot_p[i+1]; i++) { if (! FLAG_CHECK(dot_p[i+1], FLAG_ASCII)) { dot_p = NULL; break; } } if (i == 0 || i == 4) dot_p = NULL; } /* the leading characters in the mangled name is taken from the first characters of the name, if they are ascii otherwise '_' is used */ for (i=0;i<mangle_prefix && name[i];i++) { lead_chars[i] = name[i]; if (! FLAG_CHECK(lead_chars[i], FLAG_ASCII)) { lead_chars[i] = '_'; } lead_chars[i] = toupper(lead_chars[i]); } for (;i<mangle_prefix;i++) { lead_chars[i] = '_'; } /* the prefix is anything up to the first dot */ if (dot_p) { prefix_len = PTR_DIFF(dot_p, name); } else { prefix_len = strlen(name); } /* the extension of the mangled name is taken from the first 3 ascii chars after the dot */ extension_length = 0; if (dot_p) { for (i=1; extension_length < 3 && dot_p[i]; i++) { char c = dot_p[i]; if (FLAG_CHECK(c, FLAG_ASCII)) { extension[extension_length++] = toupper(c); } } } /* find the hash for this prefix */ v = hash = mangle_hash(name, prefix_len); /* now form the mangled name. */ for (i=0;i<mangle_prefix;i++) { new_name[i] = lead_chars[i]; } new_name[7] = base_forward(v % 36); new_name[6] = '~'; for (i=5; i>=mangle_prefix; i--) { v = v / 36; new_name[i] = base_forward(v % 36); } /* add the extension */ if (extension_length) { new_name[8] = '.'; memcpy(&new_name[9], extension, extension_length); new_name[9+extension_length] = 0; } else { new_name[8] = 0; } if (cache83) { /* put it in the cache */ cache_insert(name, prefix_len, hash); } M_DEBUG(10,("name_map: %s -> %08X -> %s (cache=%d)\n", name, hash, new_name, cache83)); /* and overwrite the old name */ fstrcpy(name, new_name); /* all done, we've managed to mangle it */ } /* initialise the flags table we allow only a very restricted set of characters as 'ascii' in this mangling backend. This isn't a significant problem as modern clients use the 'long' filenames anyway, and those don't have these restrictions. */ static void init_tables(void) { int i; memset(char_flags, 0, sizeof(char_flags)); for (i=1;i<128;i++) { if ((i >= '0' && i <= '9') || (i >= 'a' && i <= 'z') || (i >= 'A' && i <= 'Z')) { char_flags[i] |= (FLAG_ASCII | FLAG_BASECHAR); } if (strchr("_-$~", i)) { char_flags[i] |= FLAG_ASCII; } if (strchr("*\\/?<>|\":", i)) { char_flags[i] |= FLAG_ILLEGAL; } if (strchr("*?\"<>", i)) { char_flags[i] |= FLAG_WILDCARD; } } memset(base_reverse, 0, sizeof(base_reverse)); for (i=0;i<36;i++) { base_reverse[(unsigned char)base_forward(i)] = i; } /* fill in the reserved names flags. These are used as a very fast filter for finding possible DOS reserved filenames */ for (i=0; reserved_names[i]; i++) { unsigned char c1, c2, c3, c4; c1 = (unsigned char)reserved_names[i][0]; c2 = (unsigned char)reserved_names[i][1]; c3 = (unsigned char)reserved_names[i][2]; c4 = (unsigned char)reserved_names[i][3]; char_flags[c1] |= FLAG_POSSIBLE1; char_flags[c2] |= FLAG_POSSIBLE2; char_flags[c3] |= FLAG_POSSIBLE3; char_flags[c4] |= FLAG_POSSIBLE4; char_flags[tolower(c1)] |= FLAG_POSSIBLE1; char_flags[tolower(c2)] |= FLAG_POSSIBLE2; char_flags[tolower(c3)] |= FLAG_POSSIBLE3; char_flags[tolower(c4)] |= FLAG_POSSIBLE4; char_flags[(unsigned char)'.'] |= FLAG_POSSIBLE4; } } /* the following provides the abstraction layer to make it easier to drop in an alternative mangling implementation */ static struct mangle_fns mangle_fns = { is_mangled, is_8_3, mangle_reset, check_cache, name_map }; /* return the methods for this mangling implementation */ struct mangle_fns *mangle_hash2_init(void) { /* the mangle prefix can only be in the mange 1 to 6 */ mangle_prefix = lp_mangle_prefix(); if (mangle_prefix > 6) { mangle_prefix = 6; } if (mangle_prefix < 1) { mangle_prefix = 1; } init_tables(); mangle_reset(); if (!cache_init()) { return NULL; } return &mangle_fns; }