/* ldb database library Copyright (C) Simo Sorce 2005 ** NOTE! The following LGPL license applies to the ldb ** library. This does NOT imply that all of Samba is released ** under the LGPL This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This library 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, see . */ /* * Name: ldb * * Component: ldb dn creation and manipulation utility functions * * Description: - explode a dn into it's own basic elements * and put them in a structure (only if necessary) * - manipulate ldb_dn structures * * Author: Simo Sorce */ #include "ldb_private.h" #include #define LDB_DN_NULL_FAILED(x) if (!(x)) goto failed #define LDB_FREE(x) do { talloc_free(x); x = NULL; } while(0) /** internal ldb exploded dn structures */ struct ldb_dn_component { char *name; struct ldb_val value; char *cf_name; struct ldb_val cf_value; }; struct ldb_dn_ext_component { char *name; struct ldb_val value; }; struct ldb_dn { struct ldb_context *ldb; /* Special DNs are always linearized */ bool special; bool invalid; bool valid_case; char *linearized; char *ext_linearized; char *casefold; unsigned int comp_num; struct ldb_dn_component *components; unsigned int ext_comp_num; struct ldb_dn_ext_component *ext_components; }; /* it is helpful to be able to break on this in gdb */ static void ldb_dn_mark_invalid(struct ldb_dn *dn) { dn->invalid = true; } /* strdn may be NULL */ struct ldb_dn *ldb_dn_from_ldb_val(void *mem_ctx, struct ldb_context *ldb, const struct ldb_val *strdn) { struct ldb_dn *dn; if (! ldb) return NULL; if (strdn && strdn->data && (strnlen((const char*)strdn->data, strdn->length) != strdn->length)) { /* The RDN must not contain a character with value 0x0 */ return NULL; } dn = talloc_zero(mem_ctx, struct ldb_dn); LDB_DN_NULL_FAILED(dn); dn->ldb = talloc_get_type(ldb, struct ldb_context); if (dn->ldb == NULL) { /* the caller probably got the arguments to ldb_dn_new() mixed up */ talloc_free(dn); return NULL; } if (strdn->data && strdn->length) { const char *data = (const char *)strdn->data; size_t length = strdn->length; if (data[0] == '@') { dn->special = true; } dn->ext_linearized = talloc_strndup(dn, data, length); LDB_DN_NULL_FAILED(dn->ext_linearized); if (data[0] == '<') { const char *p_save, *p = dn->ext_linearized; do { p_save = p; p = strstr(p, ">;"); if (p) { p = p + 2; } } while (p); if (p_save == dn->ext_linearized) { dn->linearized = talloc_strdup(dn, ""); } else { dn->linearized = talloc_strdup(dn, p_save); } LDB_DN_NULL_FAILED(dn->linearized); } else { dn->linearized = dn->ext_linearized; dn->ext_linearized = NULL; } } else { dn->linearized = talloc_strdup(dn, ""); LDB_DN_NULL_FAILED(dn->linearized); } return dn; failed: talloc_free(dn); return NULL; } /* strdn may be NULL */ struct ldb_dn *ldb_dn_new(void *mem_ctx, struct ldb_context *ldb, const char *strdn) { struct ldb_val blob; blob.data = discard_const_p(uint8_t, strdn); blob.length = strdn ? strlen(strdn) : 0; return ldb_dn_from_ldb_val(mem_ctx, ldb, &blob); } struct ldb_dn *ldb_dn_new_fmt(void *mem_ctx, struct ldb_context *ldb, const char *new_fmt, ...) { char *strdn; va_list ap; if ( (! mem_ctx) || (! ldb)) return NULL; va_start(ap, new_fmt); strdn = talloc_vasprintf(mem_ctx, new_fmt, ap); va_end(ap); if (strdn) { struct ldb_dn *dn = ldb_dn_new(mem_ctx, ldb, strdn); talloc_free(strdn); return dn; } return NULL; } /* see RFC2253 section 2.4 */ static int ldb_dn_escape_internal(char *dst, const char *src, int len) { const char *p, *s; char *d; size_t l; p = s = src; d = dst; while (p - src < len) { p += strcspn(p, ",=\n\r+<>#;\\\" "); if (p - src == len) /* found no escapable chars */ break; /* copy the part of the string before the stop */ memcpy(d, s, p - s); d += (p - s); /* move to current position */ switch (*p) { case ' ': if (p == src || (p-src)==(len-1)) { /* if at the beginning or end * of the string then escape */ *d++ = '\\'; *d++ = *p++; } else { /* otherwise don't escape */ *d++ = *p++; } break; case '#': /* despite the RFC, windows escapes a # anywhere in the string */ case ',': case '+': case '"': case '\\': case '<': case '>': case '?': /* these must be escaped using \c form */ *d++ = '\\'; *d++ = *p++; break; default: { /* any others get \XX form */ unsigned char v; const char *hexbytes = "0123456789ABCDEF"; v = *(const unsigned char *)p; *d++ = '\\'; *d++ = hexbytes[v>>4]; *d++ = hexbytes[v&0xF]; p++; break; } } s = p; /* move forward */ } /* copy the last part (with zero) and return */ l = len - (s - src); memcpy(d, s, l + 1); /* return the length of the resulting string */ return (l + (d - dst)); } char *ldb_dn_escape_value(void *mem_ctx, struct ldb_val value) { char *dst; if (!value.length) return NULL; /* allocate destination string, it will be at most 3 times the source */ dst = talloc_array(mem_ctx, char, value.length * 3 + 1); if ( ! dst) { talloc_free(dst); return NULL; } ldb_dn_escape_internal(dst, (const char *)value.data, value.length); dst = talloc_realloc(mem_ctx, dst, char, strlen(dst) + 1); return dst; } /* explode a DN string into a ldb_dn structure based on RFC4514 except that we don't support multiple valued RDNs TODO: according to MS-ADTS:3.1.1.5.2 Naming Constraints DN must be compliant with RFC2253 */ static bool ldb_dn_explode(struct ldb_dn *dn) { char *p, *ex_name, *ex_value, *data, *d, *dt, *t; bool trim = false; bool in_extended = false; bool in_ex_name = false; bool in_ex_value = false; bool in_attr = false; bool in_value = false; bool in_quote = false; bool is_oid = false; bool escape = false; unsigned int x; size_t l; int ret; char *parse_dn; bool is_index; if ( ! dn || dn->invalid) return false; if (dn->components) { return true; } if (dn->ext_linearized) { parse_dn = dn->ext_linearized; } else { parse_dn = dn->linearized; } if ( ! parse_dn ) { return false; } is_index = (strncmp(parse_dn, "DN=@INDEX:", 10) == 0); /* Empty DNs */ if (parse_dn[0] == '\0') { return true; } /* Special DNs case */ if (dn->special) { return true; } /* make sure we free this if alloced previously before replacing */ talloc_free(dn->components); LDB_FREE(dn->ext_components); dn->ext_comp_num = 0; /* in the common case we have 3 or more components */ /* make sure all components are zeroed, other functions depend on it */ dn->components = talloc_zero_array(dn, struct ldb_dn_component, 3); if ( ! dn->components) { return false; } dn->comp_num = 0; /* Components data space is allocated here once */ data = talloc_array(dn->components, char, strlen(parse_dn) + 1); if (!data) { return false; } p = parse_dn; in_extended = true; in_ex_name = false; in_ex_value = false; trim = true; t = NULL; d = dt = data; while (*p) { if (in_extended) { if (!in_ex_name && !in_ex_value) { if (p[0] == '<') { p++; ex_name = d; in_ex_name = true; continue; } else if (p[0] == '\0') { p++; continue; } else { in_extended = false; in_attr = true; dt = d; continue; } } if (in_ex_name && *p == '=') { *d++ = '\0'; p++; ex_value = d; in_ex_name = false; in_ex_value = true; continue; } if (in_ex_value && *p == '>') { const struct ldb_dn_extended_syntax *ext_syntax; struct ldb_val ex_val = { .data = (uint8_t *)ex_value, .length = d - ex_value }; *d++ = '\0'; p++; in_ex_value = false; /* Process name and ex_value */ dn->ext_components = talloc_realloc(dn, dn->ext_components, struct ldb_dn_ext_component, dn->ext_comp_num + 1); if ( ! dn->ext_components) { /* ouch ! */ goto failed; } ext_syntax = ldb_dn_extended_syntax_by_name(dn->ldb, ex_name); if (!ext_syntax) { /* We don't know about this type of extended DN */ goto failed; } dn->ext_components[dn->ext_comp_num].name = talloc_strdup(dn->ext_components, ex_name); if (!dn->ext_components[dn->ext_comp_num].name) { /* ouch */ goto failed; } ret = ext_syntax->read_fn(dn->ldb, dn->ext_components, &ex_val, &dn->ext_components[dn->ext_comp_num].value); if (ret != LDB_SUCCESS) { ldb_dn_mark_invalid(dn); goto failed; } dn->ext_comp_num++; if (*p == '\0') { /* We have reached the end (extended component only)! */ talloc_free(data); return true; } else if (*p == ';') { p++; continue; } else { ldb_dn_mark_invalid(dn); goto failed; } } *d++ = *p++; continue; } if (in_attr) { if (trim) { if (*p == ' ') { p++; continue; } /* first char */ trim = false; if (!isascii(*p)) { /* attr names must be ascii only */ ldb_dn_mark_invalid(dn); goto failed; } if (isdigit(*p)) { is_oid = true; } else if ( ! isalpha(*p)) { /* not a digit nor an alpha, * invalid attribute name */ ldb_dn_mark_invalid(dn); goto failed; } /* Copy this character across from parse_dn, * now we have trimmed out spaces */ *d++ = *p++; continue; } if (*p == ' ') { p++; /* valid only if we are at the end */ trim = true; continue; } if (trim && (*p != '=')) { /* spaces/tabs are not allowed */ ldb_dn_mark_invalid(dn); goto failed; } if (*p == '=') { /* attribute terminated */ in_attr = false; in_value = true; trim = true; l = 0; /* Terminate this string in d * (which is a copy of parse_dn * with spaces trimmed) */ *d++ = '\0'; dn->components[dn->comp_num].name = talloc_strdup(dn->components, dt); if ( ! dn->components[dn->comp_num].name) { /* ouch */ goto failed; } dt = d; p++; continue; } if (!isascii(*p)) { /* attr names must be ascii only */ ldb_dn_mark_invalid(dn); goto failed; } if (is_oid && ( ! (isdigit(*p) || (*p == '.')))) { /* not a digit nor a dot, * invalid attribute oid */ ldb_dn_mark_invalid(dn); goto failed; } else if ( ! (isalpha(*p) || isdigit(*p) || (*p == '-'))) { /* not ALPHA, DIGIT or HYPHEN */ ldb_dn_mark_invalid(dn); goto failed; } *d++ = *p++; continue; } if (in_value) { if (in_quote) { if (*p == '\"') { if (p[-1] != '\\') { p++; in_quote = false; continue; } } *d++ = *p++; l++; continue; } if (trim) { if (*p == ' ') { p++; continue; } /* first char */ trim = false; if (*p == '\"') { in_quote = true; p++; continue; } } switch (*p) { /* TODO: support ber encoded values case '#': */ case ',': if (escape) { *d++ = *p++; l++; escape = false; continue; } /* ok found value terminator */ if ( t ) { /* trim back */ d -= (p - t); l -= (p - t); } in_attr = true; in_value = false; trim = true; p++; *d++ = '\0'; dn->components[dn->comp_num].value.data = (uint8_t *)talloc_strdup(dn->components, dt); dn->components[dn->comp_num].value.length = l; if ( ! dn->components[dn->comp_num].value.data) { /* ouch ! */ goto failed; } dt = d; dn->comp_num++; if (dn->comp_num > 2) { dn->components = talloc_realloc(dn, dn->components, struct ldb_dn_component, dn->comp_num + 1); if ( ! dn->components) { /* ouch ! */ goto failed; } /* make sure all components are zeroed, other functions depend on this */ memset(&dn->components[dn->comp_num], '\0', sizeof(struct ldb_dn_component)); } continue; case '+': case '=': /* to main compatibility with earlier versions of ldb indexing, we have to accept the base64 encoded binary index values, which contain a '+' or '=' which should normally be escaped */ if (is_index) { if ( t ) t = NULL; *d++ = *p++; l++; break; } /* fall through */ case '\"': case '<': case '>': case ';': /* a string with not escaped specials is invalid (tested) */ if ( ! escape) { ldb_dn_mark_invalid(dn); goto failed; } escape = false; *d++ = *p++; l++; if ( t ) t = NULL; break; case '\\': if ( ! escape) { escape = true; p++; continue; } escape = false; *d++ = *p++; l++; if ( t ) t = NULL; break; default: if (escape) { if (isxdigit(p[0]) && isxdigit(p[1])) { if (sscanf(p, "%02x", &x) != 1) { /* invalid escaping sequence */ ldb_dn_mark_invalid(dn); goto failed; } p += 2; *d++ = (unsigned char)x; } else { *d++ = *p++; } escape = false; l++; if ( t ) t = NULL; break; } if (*p == ' ') { if ( ! t) t = p; } else { if ( t ) t = NULL; } *d++ = *p++; l++; break; } } } if (in_attr || in_quote) { /* invalid dn */ ldb_dn_mark_invalid(dn); goto failed; } /* save last element */ if ( t ) { /* trim back */ d -= (p - t); l -= (p - t); } *d++ = '\0'; dn->components[dn->comp_num].value.length = l; dn->components[dn->comp_num].value.data = (uint8_t *)talloc_strdup(dn->components, dt); if ( ! dn->components[dn->comp_num].value.data) { /* ouch */ goto failed; } dn->comp_num++; talloc_free(data); return true; failed: dn->comp_num = 0; talloc_free(dn->components); return false; } bool ldb_dn_validate(struct ldb_dn *dn) { return ldb_dn_explode(dn); } const char *ldb_dn_get_linearized(struct ldb_dn *dn) { unsigned int i; size_t len; char *d, *n; if ( ! dn || ( dn->invalid)) return NULL; if (dn->linearized) return dn->linearized; if ( ! dn->components) { ldb_dn_mark_invalid(dn); return NULL; } if (dn->comp_num == 0) { dn->linearized = talloc_strdup(dn, ""); if ( ! dn->linearized) return NULL; return dn->linearized; } /* calculate maximum possible length of DN */ for (len = 0, i = 0; i < dn->comp_num; i++) { /* name len */ len += strlen(dn->components[i].name); /* max escaped data len */ len += (dn->components[i].value.length * 3); len += 2; /* '=' and ',' */ } dn->linearized = talloc_array(dn, char, len); if ( ! dn->linearized) return NULL; d = dn->linearized; for (i = 0; i < dn->comp_num; i++) { /* copy the name */ n = dn->components[i].name; while (*n) *d++ = *n++; *d++ = '='; /* and the value */ d += ldb_dn_escape_internal( d, (char *)dn->components[i].value.data, dn->components[i].value.length); *d++ = ','; } *(--d) = '\0'; /* don't waste more memory than necessary */ dn->linearized = talloc_realloc(dn, dn->linearized, char, (d - dn->linearized + 1)); return dn->linearized; } static int ldb_dn_extended_component_compare(const void *p1, const void *p2) { const struct ldb_dn_ext_component *ec1 = (const struct ldb_dn_ext_component *)p1; const struct ldb_dn_ext_component *ec2 = (const struct ldb_dn_ext_component *)p2; return strcmp(ec1->name, ec2->name); } char *ldb_dn_get_extended_linearized(void *mem_ctx, struct ldb_dn *dn, int mode) { const char *linearized = ldb_dn_get_linearized(dn); char *p = NULL; unsigned int i; if (!linearized) { return NULL; } if (!ldb_dn_has_extended(dn)) { return talloc_strdup(mem_ctx, linearized); } if (!ldb_dn_validate(dn)) { return NULL; } /* sort the extended components by name. The idea is to make * the resulting DNs consistent, plus to ensure that we put * 'DELETED' first, so it can be very quickly recognised */ TYPESAFE_QSORT(dn->ext_components, dn->ext_comp_num, ldb_dn_extended_component_compare); for (i = 0; i < dn->ext_comp_num; i++) { const struct ldb_dn_extended_syntax *ext_syntax; const char *name = dn->ext_components[i].name; struct ldb_val ec_val = dn->ext_components[i].value; struct ldb_val val; int ret; ext_syntax = ldb_dn_extended_syntax_by_name(dn->ldb, name); if (!ext_syntax) { return NULL; } if (mode == 1) { ret = ext_syntax->write_clear_fn(dn->ldb, mem_ctx, &ec_val, &val); } else if (mode == 0) { ret = ext_syntax->write_hex_fn(dn->ldb, mem_ctx, &ec_val, &val); } else { ret = -1; } if (ret != LDB_SUCCESS) { return NULL; } if (i == 0) { p = talloc_asprintf(mem_ctx, "<%s=%s>", name, val.data); } else { p = talloc_asprintf_append_buffer(p, ";<%s=%s>", name, val.data); } talloc_free(val.data); if (!p) { return NULL; } } if (dn->ext_comp_num && *linearized) { p = talloc_asprintf_append_buffer(p, ";%s", linearized); } if (!p) { return NULL; } return p; } /* filter out all but an acceptable list of extended DN components */ void ldb_dn_extended_filter(struct ldb_dn *dn, const char * const *accept) { unsigned int i; for (i=0; iext_comp_num; i++) { if (!ldb_attr_in_list(accept, dn->ext_components[i].name)) { memmove(&dn->ext_components[i], &dn->ext_components[i+1], (dn->ext_comp_num-(i+1))*sizeof(dn->ext_components[0])); dn->ext_comp_num--; i--; } } LDB_FREE(dn->ext_linearized); } char *ldb_dn_alloc_linearized(void *mem_ctx, struct ldb_dn *dn) { return talloc_strdup(mem_ctx, ldb_dn_get_linearized(dn)); } /* casefold a dn. We need to casefold the attribute names, and canonicalize attribute values of case insensitive attributes. */ static bool ldb_dn_casefold_internal(struct ldb_dn *dn) { unsigned int i; int ret; if ( ! dn || dn->invalid) return false; if (dn->valid_case) return true; if (( ! dn->components) && ( ! ldb_dn_explode(dn))) { return false; } for (i = 0; i < dn->comp_num; i++) { const struct ldb_schema_attribute *a; dn->components[i].cf_name = ldb_attr_casefold(dn->components, dn->components[i].name); if (!dn->components[i].cf_name) { goto failed; } a = ldb_schema_attribute_by_name(dn->ldb, dn->components[i].cf_name); ret = a->syntax->canonicalise_fn(dn->ldb, dn->components, &(dn->components[i].value), &(dn->components[i].cf_value)); if (ret != 0) { goto failed; } } dn->valid_case = true; return true; failed: for (i = 0; i < dn->comp_num; i++) { LDB_FREE(dn->components[i].cf_name); LDB_FREE(dn->components[i].cf_value.data); } return false; } const char *ldb_dn_get_casefold(struct ldb_dn *dn) { unsigned int i; size_t len; char *d, *n; if (dn->casefold) return dn->casefold; if (dn->special) { dn->casefold = talloc_strdup(dn, dn->linearized); if (!dn->casefold) return NULL; dn->valid_case = true; return dn->casefold; } if ( ! ldb_dn_casefold_internal(dn)) { return NULL; } if (dn->comp_num == 0) { dn->casefold = talloc_strdup(dn, ""); return dn->casefold; } /* calculate maximum possible length of DN */ for (len = 0, i = 0; i < dn->comp_num; i++) { /* name len */ len += strlen(dn->components[i].cf_name); /* max escaped data len */ len += (dn->components[i].cf_value.length * 3); len += 2; /* '=' and ',' */ } dn->casefold = talloc_array(dn, char, len); if ( ! dn->casefold) return NULL; d = dn->casefold; for (i = 0; i < dn->comp_num; i++) { /* copy the name */ n = dn->components[i].cf_name; while (*n) *d++ = *n++; *d++ = '='; /* and the value */ d += ldb_dn_escape_internal( d, (char *)dn->components[i].cf_value.data, dn->components[i].cf_value.length); *d++ = ','; } *(--d) = '\0'; /* don't waste more memory than necessary */ dn->casefold = talloc_realloc(dn, dn->casefold, char, strlen(dn->casefold) + 1); return dn->casefold; } char *ldb_dn_alloc_casefold(void *mem_ctx, struct ldb_dn *dn) { return talloc_strdup(mem_ctx, ldb_dn_get_casefold(dn)); } /* Determine if dn is below base, in the ldap tree. Used for * evaluating a subtree search. * 0 if they match, otherwise non-zero */ int ldb_dn_compare_base(struct ldb_dn *base, struct ldb_dn *dn) { int ret; long long int n_base, n_dn; if ( ! base || base->invalid) return 1; if ( ! dn || dn->invalid) return -1; if (( ! base->valid_case) || ( ! dn->valid_case)) { if (base->linearized && dn->linearized) { /* try with a normal compare first, if we are lucky * we will avoid exploding and casfolding */ int dif; dif = strlen(dn->linearized) - strlen(base->linearized); if (dif < 0) { return dif; } if (strcmp(base->linearized, &dn->linearized[dif]) == 0) { return 0; } } if ( ! ldb_dn_casefold_internal(base)) { return 1; } if ( ! ldb_dn_casefold_internal(dn)) { return -1; } } /* if base has more components, * they don't have the same base */ if (base->comp_num > dn->comp_num) { return (dn->comp_num - base->comp_num); } if ((dn->comp_num == 0) || (base->comp_num == 0)) { if (dn->special && base->special) { return strcmp(base->linearized, dn->linearized); } else if (dn->special) { return -1; } else if (base->special) { return 1; } else { return 0; } } n_base = base->comp_num - 1; n_dn = dn->comp_num - 1; while (n_base >= 0) { char *b_name = base->components[n_base].cf_name; char *dn_name = dn->components[n_dn].cf_name; char *b_vdata = (char *)base->components[n_base].cf_value.data; char *dn_vdata = (char *)dn->components[n_dn].cf_value.data; size_t b_vlen = base->components[n_base].cf_value.length; size_t dn_vlen = dn->components[n_dn].cf_value.length; /* compare attr names */ ret = strcmp(b_name, dn_name); if (ret != 0) return ret; /* compare attr.cf_value. */ if (b_vlen != dn_vlen) { return b_vlen - dn_vlen; } ret = strcmp(b_vdata, dn_vdata); if (ret != 0) return ret; n_base--; n_dn--; } return 0; } /* compare DNs using casefolding compare functions. If they match, then return 0 */ int ldb_dn_compare(struct ldb_dn *dn0, struct ldb_dn *dn1) { unsigned int i; int ret; if (( ! dn0) || dn0->invalid || ! dn1 || dn1->invalid) { return -1; } if (( ! dn0->valid_case) || ( ! dn1->valid_case)) { if (dn0->linearized && dn1->linearized) { /* try with a normal compare first, if we are lucky * we will avoid exploding and casfolding */ if (strcmp(dn0->linearized, dn1->linearized) == 0) { return 0; } } if ( ! ldb_dn_casefold_internal(dn0)) { return 1; } if ( ! ldb_dn_casefold_internal(dn1)) { return -1; } } if (dn0->comp_num != dn1->comp_num) { return (dn1->comp_num - dn0->comp_num); } if (dn0->comp_num == 0) { if (dn0->special && dn1->special) { return strcmp(dn0->linearized, dn1->linearized); } else if (dn0->special) { return 1; } else if (dn1->special) { return -1; } else { return 0; } } for (i = 0; i < dn0->comp_num; i++) { char *dn0_name = dn0->components[i].cf_name; char *dn1_name = dn1->components[i].cf_name; char *dn0_vdata = (char *)dn0->components[i].cf_value.data; char *dn1_vdata = (char *)dn1->components[i].cf_value.data; size_t dn0_vlen = dn0->components[i].cf_value.length; size_t dn1_vlen = dn1->components[i].cf_value.length; /* compare attr names */ ret = strcmp(dn0_name, dn1_name); if (ret != 0) { return ret; } /* compare attr.cf_value. */ if (dn0_vlen != dn1_vlen) { return dn0_vlen - dn1_vlen; } ret = strcmp(dn0_vdata, dn1_vdata); if (ret != 0) { return ret; } } return 0; } static struct ldb_dn_component ldb_dn_copy_component( void *mem_ctx, struct ldb_dn_component *src) { struct ldb_dn_component dst; memset(&dst, 0, sizeof(dst)); if (src == NULL) { return dst; } dst.value = ldb_val_dup(mem_ctx, &(src->value)); if (dst.value.data == NULL) { return dst; } dst.name = talloc_strdup(mem_ctx, src->name); if (dst.name == NULL) { LDB_FREE(dst.value.data); return dst; } if (src->cf_value.data) { dst.cf_value = ldb_val_dup(mem_ctx, &(src->cf_value)); if (dst.cf_value.data == NULL) { LDB_FREE(dst.value.data); LDB_FREE(dst.name); return dst; } dst.cf_name = talloc_strdup(mem_ctx, src->cf_name); if (dst.cf_name == NULL) { LDB_FREE(dst.cf_name); LDB_FREE(dst.value.data); LDB_FREE(dst.name); return dst; } } else { dst.cf_value.data = NULL; dst.cf_name = NULL; } return dst; } static struct ldb_dn_ext_component ldb_dn_ext_copy_component( void *mem_ctx, struct ldb_dn_ext_component *src) { struct ldb_dn_ext_component dst; memset(&dst, 0, sizeof(dst)); if (src == NULL) { return dst; } dst.value = ldb_val_dup(mem_ctx, &(src->value)); if (dst.value.data == NULL) { return dst; } dst.name = talloc_strdup(mem_ctx, src->name); if (dst.name == NULL) { LDB_FREE(dst.value.data); return dst; } return dst; } struct ldb_dn *ldb_dn_copy(void *mem_ctx, struct ldb_dn *dn) { struct ldb_dn *new_dn; if (!dn || dn->invalid) { return NULL; } new_dn = talloc_zero(mem_ctx, struct ldb_dn); if ( !new_dn) { return NULL; } *new_dn = *dn; if (dn->components) { unsigned int i; new_dn->components = talloc_zero_array(new_dn, struct ldb_dn_component, dn->comp_num); if ( ! new_dn->components) { talloc_free(new_dn); return NULL; } for (i = 0; i < dn->comp_num; i++) { new_dn->components[i] = ldb_dn_copy_component(new_dn->components, &dn->components[i]); if ( ! new_dn->components[i].value.data) { talloc_free(new_dn); return NULL; } } } if (dn->ext_components) { unsigned int i; new_dn->ext_components = talloc_zero_array(new_dn, struct ldb_dn_ext_component, dn->ext_comp_num); if ( ! new_dn->ext_components) { talloc_free(new_dn); return NULL; } for (i = 0; i < dn->ext_comp_num; i++) { new_dn->ext_components[i] = ldb_dn_ext_copy_component( new_dn->ext_components, &dn->ext_components[i]); if ( ! new_dn->ext_components[i].value.data) { talloc_free(new_dn); return NULL; } } } if (dn->casefold) { new_dn->casefold = talloc_strdup(new_dn, dn->casefold); if ( ! new_dn->casefold) { talloc_free(new_dn); return NULL; } } if (dn->linearized) { new_dn->linearized = talloc_strdup(new_dn, dn->linearized); if ( ! new_dn->linearized) { talloc_free(new_dn); return NULL; } } if (dn->ext_linearized) { new_dn->ext_linearized = talloc_strdup(new_dn, dn->ext_linearized); if ( ! new_dn->ext_linearized) { talloc_free(new_dn); return NULL; } } return new_dn; } /* modify the given dn by adding a base. * * return true if successful and false if not * if false is returned the dn may be marked invalid */ bool ldb_dn_add_base(struct ldb_dn *dn, struct ldb_dn *base) { const char *s; char *t; if ( !base || base->invalid || !dn || dn->invalid) { return false; } if (dn->components) { unsigned int i; if ( ! ldb_dn_validate(base)) { return false; } s = NULL; if (dn->valid_case) { if ( ! (s = ldb_dn_get_casefold(base))) { return false; } } dn->components = talloc_realloc(dn, dn->components, struct ldb_dn_component, dn->comp_num + base->comp_num); if ( ! dn->components) { ldb_dn_mark_invalid(dn); return false; } for (i = 0; i < base->comp_num; dn->comp_num++, i++) { dn->components[dn->comp_num] = ldb_dn_copy_component(dn->components, &base->components[i]); if (dn->components[dn->comp_num].value.data == NULL) { ldb_dn_mark_invalid(dn); return false; } } if (dn->casefold && s) { if (*dn->casefold) { t = talloc_asprintf(dn, "%s,%s", dn->casefold, s); } else { t = talloc_strdup(dn, s); } LDB_FREE(dn->casefold); dn->casefold = t; } } if (dn->linearized) { s = ldb_dn_get_linearized(base); if ( ! s) { return false; } if (*dn->linearized) { t = talloc_asprintf(dn, "%s,%s", dn->linearized, s); } else { t = talloc_strdup(dn, s); } if ( ! t) { ldb_dn_mark_invalid(dn); return false; } LDB_FREE(dn->linearized); dn->linearized = t; } /* Wipe the ext_linearized DN, * the GUID and SID are almost certainly no longer valid */ LDB_FREE(dn->ext_linearized); LDB_FREE(dn->ext_components); dn->ext_comp_num = 0; return true; } /* modify the given dn by adding a base. * * return true if successful and false if not * if false is returned the dn may be marked invalid */ bool ldb_dn_add_base_fmt(struct ldb_dn *dn, const char *base_fmt, ...) { struct ldb_dn *base; char *base_str; va_list ap; bool ret; if ( !dn || dn->invalid) { return false; } va_start(ap, base_fmt); base_str = talloc_vasprintf(dn, base_fmt, ap); va_end(ap); if (base_str == NULL) { return false; } base = ldb_dn_new(base_str, dn->ldb, base_str); ret = ldb_dn_add_base(dn, base); talloc_free(base_str); return ret; } /* modify the given dn by adding children elements. * * return true if successful and false if not * if false is returned the dn may be marked invalid */ bool ldb_dn_add_child(struct ldb_dn *dn, struct ldb_dn *child) { const char *s; char *t; if ( !child || child->invalid || !dn || dn->invalid) { return false; } if (dn->components) { unsigned int n; long long int i, j; if ( ! ldb_dn_validate(child)) { return false; } s = NULL; if (dn->valid_case) { if ( ! (s = ldb_dn_get_casefold(child))) { return false; } } n = dn->comp_num + child->comp_num; dn->components = talloc_realloc(dn, dn->components, struct ldb_dn_component, n); if ( ! dn->components) { ldb_dn_mark_invalid(dn); return false; } for (i = dn->comp_num - 1, j = n - 1; i >= 0; i--, j--) { dn->components[j] = dn->components[i]; } for (i = 0; i < child->comp_num; i++) { dn->components[i] = ldb_dn_copy_component(dn->components, &child->components[i]); if (dn->components[i].value.data == NULL) { ldb_dn_mark_invalid(dn); return false; } } dn->comp_num = n; if (dn->casefold && s) { t = talloc_asprintf(dn, "%s,%s", s, dn->casefold); LDB_FREE(dn->casefold); dn->casefold = t; } } if (dn->linearized) { s = ldb_dn_get_linearized(child); if ( ! s) { return false; } t = talloc_asprintf(dn, "%s,%s", s, dn->linearized); if ( ! t) { ldb_dn_mark_invalid(dn); return false; } LDB_FREE(dn->linearized); dn->linearized = t; } /* Wipe the ext_linearized DN, * the GUID and SID are almost certainly no longer valid */ LDB_FREE(dn->ext_linearized); LDB_FREE(dn->ext_components); dn->ext_comp_num = 0; return true; } /* modify the given dn by adding children elements. * * return true if successful and false if not * if false is returned the dn may be marked invalid */ bool ldb_dn_add_child_fmt(struct ldb_dn *dn, const char *child_fmt, ...) { struct ldb_dn *child; char *child_str; va_list ap; bool ret; if ( !dn || dn->invalid) { return false; } va_start(ap, child_fmt); child_str = talloc_vasprintf(dn, child_fmt, ap); va_end(ap); if (child_str == NULL) { return false; } child = ldb_dn_new(child_str, dn->ldb, child_str); ret = ldb_dn_add_child(dn, child); talloc_free(child_str); return ret; } bool ldb_dn_remove_base_components(struct ldb_dn *dn, unsigned int num) { long long int i; if ( ! ldb_dn_validate(dn)) { return false; } if (dn->comp_num < num) { return false; } /* free components */ for (i = num; i > 0; i--) { LDB_FREE(dn->components[dn->comp_num - i].name); LDB_FREE(dn->components[dn->comp_num - i].value.data); LDB_FREE(dn->components[dn->comp_num - i].cf_name); LDB_FREE(dn->components[dn->comp_num - i].cf_value.data); } dn->comp_num -= num; if (dn->valid_case) { for (i = 0; i < dn->comp_num; i++) { LDB_FREE(dn->components[i].cf_name); LDB_FREE(dn->components[i].cf_value.data); } dn->valid_case = false; } LDB_FREE(dn->casefold); LDB_FREE(dn->linearized); /* Wipe the ext_linearized DN, * the GUID and SID are almost certainly no longer valid */ LDB_FREE(dn->ext_linearized); LDB_FREE(dn->ext_components); dn->ext_comp_num = 0; return true; } bool ldb_dn_remove_child_components(struct ldb_dn *dn, unsigned int num) { unsigned int i, j; if ( ! ldb_dn_validate(dn)) { return false; } if (dn->comp_num < num) { return false; } for (i = 0, j = num; j < dn->comp_num; i++, j++) { if (i < num) { LDB_FREE(dn->components[i].name); LDB_FREE(dn->components[i].value.data); LDB_FREE(dn->components[i].cf_name); LDB_FREE(dn->components[i].cf_value.data); } dn->components[i] = dn->components[j]; } dn->comp_num -= num; if (dn->valid_case) { for (i = 0; i < dn->comp_num; i++) { LDB_FREE(dn->components[i].cf_name); LDB_FREE(dn->components[i].cf_value.data); } dn->valid_case = false; } LDB_FREE(dn->casefold); LDB_FREE(dn->linearized); /* Wipe the ext_linearized DN, * the GUID and SID are almost certainly no longer valid */ LDB_FREE(dn->ext_linearized); LDB_FREE(dn->ext_components); dn->ext_comp_num = 0; return true; } struct ldb_dn *ldb_dn_get_parent(void *mem_ctx, struct ldb_dn *dn) { struct ldb_dn *new_dn; new_dn = ldb_dn_copy(mem_ctx, dn); if ( !new_dn ) { return NULL; } if ( ! ldb_dn_remove_child_components(new_dn, 1)) { talloc_free(new_dn); return NULL; } /* Wipe the ext_linearized DN, * the GUID and SID are almost certainly no longer valid */ LDB_FREE(dn->ext_linearized); LDB_FREE(dn->ext_components); dn->ext_comp_num = 0; return new_dn; } /* Create a 'canonical name' string from a DN: ie dc=samba,dc=org -> samba.org/ uid=administrator,ou=users,dc=samba,dc=org = samba.org/users/administrator There are two formats, the EX format has the last '/' replaced with a newline (\n). */ static char *ldb_dn_canonical(void *mem_ctx, struct ldb_dn *dn, int ex_format) { long long int i; TALLOC_CTX *tmpctx; char *cracked = NULL; const char *format = (ex_format ? "\n" : "/" ); if ( ! ldb_dn_validate(dn)) { return NULL; } tmpctx = talloc_new(mem_ctx); /* Walk backwards down the DN, grabbing 'dc' components at first */ for (i = dn->comp_num - 1; i >= 0; i--) { if (ldb_attr_cmp(dn->components[i].name, "dc") != 0) { break; } if (cracked) { cracked = talloc_asprintf(tmpctx, "%s.%s", ldb_dn_escape_value(tmpctx, dn->components[i].value), cracked); } else { cracked = ldb_dn_escape_value(tmpctx, dn->components[i].value); } if (!cracked) { goto done; } } /* Only domain components? Finish here */ if (i < 0) { cracked = talloc_strdup_append_buffer(cracked, format); talloc_steal(mem_ctx, cracked); goto done; } /* Now walk backwards appending remaining components */ for (; i > 0; i--) { cracked = talloc_asprintf_append_buffer(cracked, "/%s", ldb_dn_escape_value(tmpctx, dn->components[i].value)); if (!cracked) { goto done; } } /* Last one, possibly a newline for the 'ex' format */ cracked = talloc_asprintf_append_buffer(cracked, "%s%s", format, ldb_dn_escape_value(tmpctx, dn->components[i].value)); talloc_steal(mem_ctx, cracked); done: talloc_free(tmpctx); return cracked; } /* Wrapper functions for the above, for the two different string formats */ char *ldb_dn_canonical_string(void *mem_ctx, struct ldb_dn *dn) { return ldb_dn_canonical(mem_ctx, dn, 0); } char *ldb_dn_canonical_ex_string(void *mem_ctx, struct ldb_dn *dn) { return ldb_dn_canonical(mem_ctx, dn, 1); } int ldb_dn_get_comp_num(struct ldb_dn *dn) { if ( ! ldb_dn_validate(dn)) { return -1; } return dn->comp_num; } const char *ldb_dn_get_component_name(struct ldb_dn *dn, unsigned int num) { if ( ! ldb_dn_validate(dn)) { return NULL; } if (num >= dn->comp_num) return NULL; return dn->components[num].name; } const struct ldb_val *ldb_dn_get_component_val(struct ldb_dn *dn, unsigned int num) { if ( ! ldb_dn_validate(dn)) { return NULL; } if (num >= dn->comp_num) return NULL; return &dn->components[num].value; } const char *ldb_dn_get_rdn_name(struct ldb_dn *dn) { if ( ! ldb_dn_validate(dn)) { return NULL; } if (dn->comp_num == 0) return NULL; return dn->components[0].name; } const struct ldb_val *ldb_dn_get_rdn_val(struct ldb_dn *dn) { if ( ! ldb_dn_validate(dn)) { return NULL; } if (dn->comp_num == 0) return NULL; return &dn->components[0].value; } int ldb_dn_set_component(struct ldb_dn *dn, int num, const char *name, const struct ldb_val val) { char *n; struct ldb_val v; if ( ! ldb_dn_validate(dn)) { return LDB_ERR_OTHER; } if (num >= dn->comp_num) { return LDB_ERR_OTHER; } n = talloc_strdup(dn, name); if ( ! n) { return LDB_ERR_OTHER; } v.length = val.length; v.data = (uint8_t *)talloc_memdup(dn, val.data, v.length+1); if ( ! v.data) { talloc_free(n); return LDB_ERR_OTHER; } talloc_free(dn->components[num].name); talloc_free(dn->components[num].value.data); dn->components[num].name = n; dn->components[num].value = v; if (dn->valid_case) { unsigned int i; for (i = 0; i < dn->comp_num; i++) { LDB_FREE(dn->components[i].cf_name); LDB_FREE(dn->components[i].cf_value.data); } dn->valid_case = false; } LDB_FREE(dn->casefold); LDB_FREE(dn->linearized); /* Wipe the ext_linearized DN, * the GUID and SID are almost certainly no longer valid */ LDB_FREE(dn->ext_linearized); dn->ext_comp_num = 0; LDB_FREE(dn->ext_components); return LDB_SUCCESS; } const struct ldb_val *ldb_dn_get_extended_component(struct ldb_dn *dn, const char *name) { unsigned int i; if ( ! ldb_dn_validate(dn)) { return NULL; } for (i=0; i < dn->ext_comp_num; i++) { if (ldb_attr_cmp(dn->ext_components[i].name, name) == 0) { return &dn->ext_components[i].value; } } return NULL; } int ldb_dn_set_extended_component(struct ldb_dn *dn, const char *name, const struct ldb_val *val) { struct ldb_dn_ext_component *p; unsigned int i; struct ldb_val v2; if ( ! ldb_dn_validate(dn)) { return LDB_ERR_OTHER; } if (!ldb_dn_extended_syntax_by_name(dn->ldb, name)) { /* We don't know how to handle this type of thing */ return LDB_ERR_INVALID_DN_SYNTAX; } for (i=0; i < dn->ext_comp_num; i++) { if (ldb_attr_cmp(dn->ext_components[i].name, name) == 0) { if (val) { dn->ext_components[i].value = ldb_val_dup(dn->ext_components, val); dn->ext_components[i].name = talloc_strdup(dn->ext_components, name); if (!dn->ext_components[i].name || !dn->ext_components[i].value.data) { ldb_dn_mark_invalid(dn); return LDB_ERR_OPERATIONS_ERROR; } return LDB_SUCCESS; } else { if (i != (dn->ext_comp_num - 1)) { memmove(&dn->ext_components[i], &dn->ext_components[i+1], ((dn->ext_comp_num-1) - i) * sizeof(*dn->ext_components)); } dn->ext_comp_num--; dn->ext_components = talloc_realloc(dn, dn->ext_components, struct ldb_dn_ext_component, dn->ext_comp_num); if (!dn->ext_components) { ldb_dn_mark_invalid(dn); return LDB_ERR_OPERATIONS_ERROR; } return LDB_SUCCESS; } LDB_FREE(dn->ext_linearized); } } if (val == NULL) { /* removing a value that doesn't exist is not an error */ return LDB_SUCCESS; } v2 = *val; p = dn->ext_components = talloc_realloc(dn, dn->ext_components, struct ldb_dn_ext_component, dn->ext_comp_num + 1); if (!dn->ext_components) { ldb_dn_mark_invalid(dn); return LDB_ERR_OPERATIONS_ERROR; } p[dn->ext_comp_num].value = ldb_val_dup(dn->ext_components, &v2); p[dn->ext_comp_num].name = talloc_strdup(p, name); if (!dn->ext_components[i].name || !dn->ext_components[i].value.data) { ldb_dn_mark_invalid(dn); return LDB_ERR_OPERATIONS_ERROR; } dn->ext_components = p; dn->ext_comp_num++; return LDB_SUCCESS; } void ldb_dn_remove_extended_components(struct ldb_dn *dn) { dn->ext_comp_num = 0; LDB_FREE(dn->ext_components); LDB_FREE(dn->ext_linearized); } bool ldb_dn_is_valid(struct ldb_dn *dn) { if ( ! dn) return false; return ! dn->invalid; } bool ldb_dn_is_special(struct ldb_dn *dn) { if ( ! dn || dn->invalid) return false; return dn->special; } bool ldb_dn_has_extended(struct ldb_dn *dn) { if ( ! dn || dn->invalid) return false; if (dn->ext_linearized && (dn->ext_linearized[0] == '<')) return true; return dn->ext_comp_num != 0; } bool ldb_dn_check_special(struct ldb_dn *dn, const char *check) { if ( ! dn || dn->invalid) return false; return ! strcmp(dn->linearized, check); } bool ldb_dn_is_null(struct ldb_dn *dn) { if ( ! dn || dn->invalid) return false; if (ldb_dn_has_extended(dn)) return false; if (dn->linearized && (dn->linearized[0] == '\0')) return true; return false; } /* this updates dn->components, taking the components from ref_dn. This is used by code that wants to update the DN path of a DN while not impacting on the extended DN components */ int ldb_dn_update_components(struct ldb_dn *dn, const struct ldb_dn *ref_dn) { dn->components = talloc_realloc(dn, dn->components, struct ldb_dn_component, ref_dn->comp_num); if (!dn->components) { return LDB_ERR_OPERATIONS_ERROR; } memcpy(dn->components, ref_dn->components, sizeof(struct ldb_dn_component)*ref_dn->comp_num); dn->comp_num = ref_dn->comp_num; talloc_free(dn->linearized); talloc_free(dn->ext_linearized); dn->ext_linearized = NULL; dn->linearized = NULL; return LDB_SUCCESS; }