/* tree.c Routines for manipulating parse trees... */ /* * Copyright (c) 2004-2017 by Internet Systems Consortium, Inc. ("ISC") * Copyright (c) 1995-2003 by Internet Software Consortium * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL ISC BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT * OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * * Internet Systems Consortium, Inc. * 950 Charter Street * Redwood City, CA 94063 * * https://www.isc.org/ * */ #include "dhcpd.h" #include #include #include #ifdef HAVE_REGEX_H # include #endif struct binding_scope *global_scope; static int do_host_lookup (struct data_string *, struct dns_host_entry *); #define DS_SPRINTF_SIZE 128 /* * If we are using a data_string structure to hold a NUL-terminated * ASCII string, this function can be used to append a printf-formatted * string to the end of it. The data_string structure will be resized to * be big enough to hold the new string. * * If the append works, then 1 is returned. * * If it is not possible to allocate a buffer big enough to hold the * new value, then the old data_string is unchanged, and 0 is returned. */ int data_string_sprintfa(struct data_string *ds, const char *fmt, ...) { va_list args; int cur_strlen; int max; int vsnprintf_ret; int new_len; struct buffer *tmp_buffer; /* * If the data_string is empty, then initialize it. */ if (ds->data == NULL) { /* INSIST(ds.buffer == NULL); */ if (!buffer_allocate(&ds->buffer, DS_SPRINTF_SIZE, MDL)) { return 0; } ds->data = ds->buffer->data; ds->len = DS_SPRINTF_SIZE; *((char *)ds->data) = '\0'; } /* * Get the length of the string, and figure out how much space * is left. */ cur_strlen = strlen((char *)ds->data); max = ds->len - cur_strlen; /* * Use vsnprintf(), which won't write past our space, but will * tell us how much space it wants. */ va_start(args, fmt); vsnprintf_ret = vsnprintf((char *)ds->data+cur_strlen, max, fmt, args); va_end(args); /* INSIST(vsnprintf_ret >= 0); */ /* * If our buffer is not big enough, we need a new buffer. */ if (vsnprintf_ret >= max) { /* * Figure out a size big enough. */ new_len = ds->len * 2; while (new_len <= cur_strlen + vsnprintf_ret) { new_len *= 2; } /* * Create a new buffer and fill it. */ tmp_buffer = NULL; if (!buffer_allocate(&tmp_buffer, new_len, MDL)) { /* * If we can't create a big enough buffer, * we should remove any truncated output that we had. */ *((char *)ds->data+cur_strlen) = '\0'; va_end(args); return 0; } memcpy(tmp_buffer->data, ds->data, cur_strlen); /* Rerun the vsprintf. */ va_start(args, fmt); vsprintf((char *)tmp_buffer->data + cur_strlen, fmt, args); va_end(args); /* * Replace our old buffer with the new buffer. */ buffer_dereference(&ds->buffer, MDL); buffer_reference(&ds->buffer, tmp_buffer, MDL); buffer_dereference(&tmp_buffer, MDL); ds->data = ds->buffer->data; ds->len = new_len; } return 1; } pair cons (car, cdr) caddr_t car; pair cdr; { pair foo = (pair)dmalloc (sizeof *foo, MDL); if (!foo) log_fatal ("no memory for cons."); foo -> car = car; foo -> cdr = cdr; return foo; } int make_const_option_cache (oc, buffer, data, len, option, file, line) struct option_cache **oc; struct buffer **buffer; u_int8_t *data; unsigned len; struct option *option; const char *file; int line; { struct buffer *bp; if (buffer) { bp = *buffer; *buffer = 0; } else { bp = (struct buffer *)0; if (!buffer_allocate (&bp, len, file, line)) { log_error ("%s(%d): can't allocate buffer.", file, line); return 0; } } if (!option_cache_allocate (oc, file, line)) { log_error ("%s(%d): can't allocate option cache.", file, line); buffer_dereference (&bp, file, line); return 0; } (*oc) -> data.len = len; (*oc) -> data.buffer = bp; (*oc) -> data.data = &bp -> data [0]; (*oc) -> data.terminated = 0; if (data) memcpy (&bp -> data [0], data, len); option_reference(&((*oc)->option), option, MDL); return 1; } int make_host_lookup (expr, name) struct expression **expr; const char *name; { if (!expression_allocate (expr, MDL)) { log_error ("No memory for host lookup tree node."); return 0; } (*expr) -> op = expr_host_lookup; if (!enter_dns_host (&((*expr) -> data.host_lookup), name)) { expression_dereference (expr, MDL); return 0; } return 1; } int enter_dns_host (dh, name) struct dns_host_entry **dh; const char *name; { /* XXX This should really keep a hash table of hostnames XXX and just add a new reference to a hostname that XXX already exists, if possible, rather than creating XXX a new structure. */ if (!dns_host_entry_allocate (dh, name, MDL)) { log_error ("Can't allocate space for new host."); return 0; } return 1; } int make_const_data (struct expression **expr, const unsigned char *data, unsigned len, int terminated, int allocate, const char *file, int line) { struct expression *nt; if (!expression_allocate (expr, file, line)) { log_error ("No memory for make_const_data tree node."); return 0; } nt = *expr; if (len) { if (allocate) { if (!buffer_allocate (&nt -> data.const_data.buffer, len + terminated, file, line)) { log_error ("Can't allocate const_data buffer"); expression_dereference (expr, file, line); return 0; } nt -> data.const_data.data = &nt -> data.const_data.buffer -> data [0]; memcpy (nt -> data.const_data.buffer -> data, data, len + terminated); } else nt -> data.const_data.data = data; nt -> data.const_data.terminated = terminated; } else nt -> data.const_data.data = 0; nt -> op = expr_const_data; nt -> data.const_data.len = len; return 1; } int make_const_int (expr, val) struct expression **expr; unsigned long val; { if (!expression_allocate (expr, MDL)) { log_error ("No memory for make_const_int tree node."); return 0; } (*expr) -> op = expr_const_int; (*expr) -> data.const_int = val; return 1; } int make_concat (expr, left, right) struct expression **expr; struct expression *left, *right; { /* If we're concatenating a null tree to a non-null tree, just return the non-null tree; if both trees are null, return a null tree. */ if (!left) { if (!right) return 0; expression_reference (expr, right, MDL); return 1; } if (!right) { expression_reference (expr, left, MDL); return 1; } /* Otherwise, allocate a new node to concatenate the two. */ if (!expression_allocate (expr, MDL)) { log_error ("No memory for concatenation expression node."); return 0; } (*expr) -> op = expr_concat; expression_reference (&(*expr) -> data.concat [0], left, MDL); expression_reference (&(*expr) -> data.concat [1], right, MDL); return 1; } int make_encapsulation (expr, name) struct expression **expr; struct data_string *name; { /* Allocate a new node to store the encapsulation. */ if (!expression_allocate (expr, MDL)) { log_error ("No memory for encapsulation expression node."); return 0; } (*expr) -> op = expr_encapsulate; data_string_copy (&(*expr) -> data.encapsulate, name, MDL); return 1; } int make_substring (new, expr, offset, length) struct expression **new; struct expression *expr; struct expression *offset; struct expression *length; { /* Allocate an expression node to compute the substring. */ if (!expression_allocate (new, MDL)) { log_error ("no memory for substring expression."); return 0; } (*new) -> op = expr_substring; expression_reference (&(*new) -> data.substring.expr, expr, MDL); expression_reference (&(*new) -> data.substring.offset, offset, MDL); expression_reference (&(*new) -> data.substring.len, length, MDL); return 1; } int make_limit (new, expr, limit) struct expression **new; struct expression *expr; int limit; { /* Allocate a node to enforce a limit on evaluation. */ if (!expression_allocate (new, MDL)) log_error ("no memory for limit expression"); (*new) -> op = expr_substring; expression_reference (&(*new) -> data.substring.expr, expr, MDL); /* Offset is a constant 0. */ if (!expression_allocate (&(*new) -> data.substring.offset, MDL)) { log_error ("no memory for limit offset expression"); expression_dereference (new, MDL); return 0; } (*new) -> data.substring.offset -> op = expr_const_int; (*new) -> data.substring.offset -> data.const_int = 0; /* Length is a constant: the specified limit. */ if (!expression_allocate (&(*new) -> data.substring.len, MDL)) { log_error ("no memory for limit length expression"); expression_dereference (new, MDL); return 0; } (*new) -> data.substring.len -> op = expr_const_int; (*new) -> data.substring.len -> data.const_int = limit; return 1; } int option_cache (struct option_cache **oc, struct data_string *dp, struct expression *expr, struct option *option, const char *file, int line) { if (!option_cache_allocate (oc, file, line)) return 0; if (dp) data_string_copy (&(*oc) -> data, dp, file, line); if (expr) expression_reference (&(*oc) -> expression, expr, file, line); option_reference(&(*oc)->option, option, MDL); return 1; } int make_let (result, name) struct executable_statement **result; const char *name; { if (!(executable_statement_allocate (result, MDL))) return 0; (*result) -> op = let_statement; (*result) -> data.let.name = dmalloc (strlen (name) + 1, MDL); if (!(*result) -> data.let.name) { executable_statement_dereference (result, MDL); return 0; } strcpy ((*result) -> data.let.name, name); return 1; } static int do_host_lookup (result, dns) struct data_string *result; struct dns_host_entry *dns; { struct hostent *h; unsigned i, count; unsigned new_len; #ifdef DEBUG_EVAL log_debug ("time: now = %d dns = %d diff = %d", cur_time, dns -> timeout, cur_time - dns -> timeout); #endif /* If the record hasn't timed out, just copy the data and return. */ if (cur_time <= dns -> timeout) { #ifdef DEBUG_EVAL log_debug ("easy copy: %d %s", dns -> data.len, (dns -> data.len > 4 ? inet_ntoa (*(struct in_addr *)(dns -> data.data)) : 0)); #endif data_string_copy (result, &dns -> data, MDL); return 1; } #ifdef DEBUG_EVAL log_debug ("Looking up %s", dns -> hostname); #endif /* Otherwise, look it up... */ h = gethostbyname (dns -> hostname); if (!h) { #ifndef NO_H_ERRNO switch (h_errno) { case HOST_NOT_FOUND: #endif log_error ("%s: host unknown.", dns -> hostname); #ifndef NO_H_ERRNO break; case TRY_AGAIN: log_error ("%s: temporary name server failure", dns -> hostname); break; case NO_RECOVERY: log_error ("%s: name server failed", dns -> hostname); break; case NO_DATA: log_error ("%s: no A record associated with address", dns -> hostname); } #endif /* !NO_H_ERRNO */ /* Okay to try again after a minute. */ dns -> timeout = cur_time + 60; data_string_forget (&dns -> data, MDL); return 0; } #ifdef DEBUG_EVAL log_debug ("Lookup succeeded; first address is %s", inet_ntoa (h -> h_addr_list [0])); #endif /* Count the number of addresses we got... */ for (count = 0; h -> h_addr_list [count]; count++) ; /* Dereference the old data, if any. */ data_string_forget (&dns -> data, MDL); /* Do we need to allocate more memory? */ new_len = count * h -> h_length; if (!buffer_allocate (&dns -> data.buffer, new_len, MDL)) { log_error ("No memory for %s.", dns -> hostname); return 0; } dns -> data.data = &dns -> data.buffer -> data [0]; dns -> data.len = new_len; dns -> data.terminated = 0; /* Addresses are conveniently stored one to the buffer, so we have to copy them out one at a time... :'( */ for (i = 0; i < count; i++) { memcpy (&dns -> data.buffer -> data [h -> h_length * i], h -> h_addr_list [i], (unsigned)(h -> h_length)); } #ifdef DEBUG_EVAL log_debug ("dns -> data: %x h -> h_addr_list [0]: %x", *(int *)(dns -> buffer), h -> h_addr_list [0]); #endif /* XXX Set the timeout for an hour from now. XXX This should really use the time on the DNS reply. */ dns -> timeout = cur_time + 3600; #ifdef DEBUG_EVAL log_debug ("hard copy: %d %s", dns -> data.len, (dns -> data.len > 4 ? inet_ntoa (*(struct in_addr *)(dns -> data.data)) : 0)); #endif data_string_copy (result, &dns -> data, MDL); return 1; } int evaluate_expression (result, packet, lease, client_state, in_options, cfg_options, scope, expr, file, line) struct binding_value **result; struct packet *packet; struct lease *lease; struct client_state *client_state; struct option_state *in_options; struct option_state *cfg_options; struct binding_scope **scope; struct expression *expr; const char *file; int line; { struct binding_value *bv; int status; struct binding *binding; bv = (struct binding_value *)0; if (expr -> op == expr_variable_reference) { if (!scope || !*scope) return 0; binding = find_binding (*scope, expr -> data.variable); if (binding && binding -> value) { if (result) binding_value_reference (result, binding -> value, file, line); return 1; } else return 0; } else if (expr -> op == expr_funcall) { struct string_list *s; struct expression *arg; struct binding_scope *ns; struct binding *nb; if (!scope || !*scope) { log_error ("%s: no such function.", expr -> data.funcall.name); return 0; } binding = find_binding (*scope, expr -> data.funcall.name); if (!binding || !binding -> value) { log_error ("%s: no such function.", expr -> data.funcall.name); return 0; } if (binding -> value -> type != binding_function) { log_error ("%s: not a function.", expr -> data.funcall.name); return 0; } /* Create a new binding scope in which to define the arguments to the function. */ ns = (struct binding_scope *)0; if (!binding_scope_allocate (&ns, MDL)) { log_error ("%s: can't allocate argument scope.", expr -> data.funcall.name); return 0; } arg = expr -> data.funcall.arglist; s = binding -> value -> value.fundef -> args; while (arg && s) { nb = dmalloc (sizeof *nb, MDL); if (!nb) { blb: binding_scope_dereference (&ns, MDL); return 0; } else { memset (nb, 0, sizeof *nb); nb -> name = dmalloc (strlen (s -> string) + 1, MDL); if (nb -> name) strcpy (nb -> name, s -> string); else { dfree (nb, MDL); goto blb; } } evaluate_expression (&nb -> value, packet, lease, client_state, in_options, cfg_options, scope, arg -> data.arg.val, file, line); nb -> next = ns -> bindings; ns -> bindings = nb; arg = arg -> data.arg.next; s = s -> next; } if (arg) { log_error ("%s: too many arguments.", expr -> data.funcall.name); binding_scope_dereference (&ns, MDL); return 0; } if (s) { log_error ("%s: too few arguments.", expr -> data.funcall.name); binding_scope_dereference (&ns, MDL); return 0; } if (scope && *scope) binding_scope_reference (&ns -> outer, *scope, MDL); status = (execute_statements (&bv, packet, lease, client_state, in_options, cfg_options, &ns, binding->value->value.fundef->statements, NULL)); binding_scope_dereference (&ns, MDL); if (!bv) return 1; } else if (is_boolean_expression (expr)) { if (!binding_value_allocate (&bv, MDL)) return 0; bv -> type = binding_boolean; status = (evaluate_boolean_expression (&bv -> value.boolean, packet, lease, client_state, in_options, cfg_options, scope, expr)); } else if (is_numeric_expression (expr)) { if (!binding_value_allocate (&bv, MDL)) return 0; bv -> type = binding_numeric; status = (evaluate_numeric_expression (&bv -> value.intval, packet, lease, client_state, in_options, cfg_options, scope, expr)); } else if (is_data_expression (expr)) { if (!binding_value_allocate (&bv, MDL)) return 0; bv -> type = binding_data; status = (evaluate_data_expression (&bv -> value.data, packet, lease, client_state, in_options, cfg_options, scope, expr, MDL)); } else { log_error ("%s: invalid expression type: %d", "evaluate_expression", expr -> op); return 0; } if (result && status) binding_value_reference (result, bv, file, line); binding_value_dereference (&bv, MDL); return status; } int binding_value_dereference (struct binding_value **v, const char *file, int line) { struct binding_value *bv = *v; *v = (struct binding_value *)0; /* Decrement the reference count. If it's nonzero, we're done. */ --(bv -> refcnt); rc_register (file, line, v, bv, bv -> refcnt, 1, RC_MISC); if (bv -> refcnt > 0) return 1; if (bv -> refcnt < 0) { log_error ("%s(%d): negative refcnt!", file, line); #if defined (DEBUG_RC_HISTORY) dump_rc_history (bv); #endif #if defined (POINTER_DEBUG) abort (); #else return 0; #endif } switch (bv -> type) { case binding_boolean: case binding_numeric: break; case binding_data: if (bv -> value.data.buffer) data_string_forget (&bv -> value.data, file, line); break; default: log_error ("%s(%d): invalid binding type: %d", file, line, bv -> type); return 0; } free_binding_value(bv, file, line); return 1; } int evaluate_boolean_expression (result, packet, lease, client_state, in_options, cfg_options, scope, expr) int *result; struct packet *packet; struct lease *lease; struct client_state *client_state; struct option_state *in_options; struct option_state *cfg_options; struct binding_scope **scope; struct expression *expr; { struct data_string left, right; int bleft, bright; int sleft, sright; struct binding *binding; struct binding_value *bv, *obv; #ifdef HAVE_REGEX_H int regflags = REG_EXTENDED | REG_NOSUB; regex_t re; #endif switch (expr -> op) { case expr_check: *result = check_collection (packet, lease, expr -> data.check); #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: check (%s) returns %s", expr -> data.check -> name, *result ? "true" : "false"); #endif return 1; case expr_equal: case expr_not_equal: bv = obv = (struct binding_value *)0; sleft = evaluate_expression (&bv, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.equal [0], MDL); sright = evaluate_expression (&obv, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.equal [1], MDL); if (sleft && sright) { if (bv -> type != obv -> type) *result = expr -> op == expr_not_equal; else { switch (obv -> type) { case binding_boolean: if (bv -> value.boolean == obv -> value.boolean) *result = expr -> op == expr_equal; else *result = expr -> op == expr_not_equal; break; case binding_data: if ((bv -> value.data.len == obv -> value.data.len) && !memcmp (bv -> value.data.data, obv -> value.data.data, obv -> value.data.len)) *result = expr -> op == expr_equal; else *result = expr -> op == expr_not_equal; break; case binding_numeric: if (bv -> value.intval == obv -> value.intval) *result = expr -> op == expr_equal; else *result = expr -> op == expr_not_equal; break; case binding_function: if (bv -> value.fundef == obv -> value.fundef) *result = expr -> op == expr_equal; else *result = expr -> op == expr_not_equal; break; default: *result = expr -> op == expr_not_equal; break; } } } else if (!sleft && !sright) *result = expr -> op == expr_equal; else *result = expr -> op == expr_not_equal; #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: %sequal = %s", expr -> op == expr_not_equal ? "not" : "", (*result ? "true" : "false")); #endif if (sleft) binding_value_dereference (&bv, MDL); if (sright) binding_value_dereference (&obv, MDL); return 1; case expr_iregex_match: #ifdef HAVE_REGEX_H regflags |= REG_ICASE; #endif /* FALL THROUGH */ case expr_regex_match: #ifdef HAVE_REGEX_H memset(&left, 0, sizeof left); bleft = evaluate_data_expression(&left, packet, lease, client_state, in_options, cfg_options, scope, expr->data.equal[0], MDL); /* This is annoying, regexec requires the string being processed * to be NULL terminated, but left may not be, so pass it into * the termination function to ensure it's null terminated. */ if (bleft && (data_string_terminate(&left, MDL) == 0)) { /* failed to make a null terminated version, couldn't * create a copy, probably a memory issue, an error * message has already been logged */ bleft = 0; } memset(&right, 0, sizeof right); bright = evaluate_data_expression(&right, packet, lease, client_state, in_options, cfg_options, scope, expr->data.equal[1], MDL); *result = 0; memset(&re, 0, sizeof(re)); if (bleft && bright && (left.data != NULL) && (right.data != NULL) && (regcomp(&re, (char *)right.data, regflags) == 0) && (regexec(&re, (char *)left.data, (size_t)0, NULL, 0) == 0)) *result = 1; #if defined (DEBUG_EXPRESSIONS) log_debug("bool: %s ~= %s yields %s", bleft ? print_hex_1(left.len, left.data, 20) : "NULL", bright ? print_hex_2 (right.len, right.data, 20) : "NULL", *result ? "true" : "false"); #endif if (bleft) data_string_forget(&left, MDL); if (bright) data_string_forget(&right, MDL); regfree(&re); /* * If we have bleft and bright then we have a good * syntax, otherwise not. * * XXX: we don't warn on invalid regular expression * syntax, should we? */ return bleft && bright; #else /* It shouldn't be possible to configure a regex operator * when there's no support. */ log_fatal("Impossible condition at %s:%d.", MDL); break; #endif case expr_and: sleft = evaluate_boolean_expression (&bleft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); if (sleft && bleft) sright = evaluate_boolean_expression (&bright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); else sright = bright = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: and (%s, %s) = %s", sleft ? (bleft ? "true" : "false") : "NULL", sright ? (bright ? "true" : "false") : "NULL", ((sleft && sright) ? (bleft && bright ? "true" : "false") : "NULL")); #endif if (sleft && sright) { *result = bleft && bright; return 1; } return 0; case expr_or: bleft = bright = 0; sleft = evaluate_boolean_expression (&bleft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.or [0]); if (!sleft || !bleft) sright = evaluate_boolean_expression (&bright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.or [1]); else sright = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: or (%s, %s) = %s", sleft ? (bleft ? "true" : "false") : "NULL", sright ? (bright ? "true" : "false") : "NULL", ((sleft || sright) ? (bleft || bright ? "true" : "false") : "NULL")); #endif if (sleft || sright) { *result = bleft || bright; return 1; } return 0; case expr_not: sleft = evaluate_boolean_expression(&bleft, packet, lease, client_state, in_options, cfg_options, scope, expr->data.not); #if defined (DEBUG_EXPRESSIONS) log_debug("bool: not (%s) = %s", sleft ? (bleft ? "true" : "false") : "NULL", sleft ? (!bleft ? "true" : "false") : "NULL"); #endif if (sleft) { *result = !bleft; return 1; } return 0; case expr_exists: memset (&left, 0, sizeof left); if (!in_options || !get_option (&left, expr -> data.exists -> universe, packet, lease, client_state, in_options, cfg_options, in_options, scope, expr -> data.exists -> code, MDL)) *result = 0; else { *result = 1; data_string_forget (&left, MDL); } #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: exists %s.%s = %s", expr -> data.option -> universe -> name, expr -> data.option -> name, *result ? "true" : "false"); #endif return 1; case expr_known: if (!packet) { #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: known = NULL"); #endif return 0; } #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: known = %s", packet -> known ? "true" : "false"); #endif *result = packet -> known; return 1; case expr_static: if (!lease || !(lease -> flags & STATIC_LEASE)) { #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: static = false (%s %s %s %d)", lease ? "y" : "n", (lease && (lease -> flags & STATIC_LEASE) ? "y" : "n"), piaddr (lease -> ip_addr), lease ? lease -> flags : 0); #endif *result = 0; return 1; } #if defined (DEBUG_EXPRESSIONS) log_debug ("bool: static = true"); #endif *result = 1; return 1; case expr_variable_exists: if (scope && *scope) { binding = find_binding (*scope, expr -> data.variable); if (binding) { if (binding -> value) *result = 1; else *result = 0; } else *result = 0; } else *result = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("boolean: %s? = %s", expr -> data.variable, *result ? "true" : "false"); #endif return 1; case expr_variable_reference: if (scope && *scope) { binding = find_binding (*scope, expr -> data.variable); if (binding && binding -> value) { if (binding -> value -> type == binding_boolean) { *result = binding -> value -> value.boolean; sleft = 1; } else { log_error ("binding type %d in %s.", binding -> value -> type, "evaluate_boolean_expression"); sleft = 0; } } else sleft = 0; } else sleft = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("boolean: %s = %s", expr -> data.variable, sleft ? (*result ? "true" : "false") : "NULL"); #endif return sleft; case expr_funcall: bv = (struct binding_value *)0; sleft = evaluate_expression (&bv, packet, lease, client_state, in_options, cfg_options, scope, expr, MDL); if (sleft) { if (bv -> type != binding_boolean) log_error ("%s() returned type %d in %s.", expr -> data.funcall.name, bv -> type, "evaluate_boolean_expression"); else *result = bv -> value.boolean; binding_value_dereference (&bv, MDL); } #if defined (DEBUG_EXPRESSIONS) log_debug ("boolean: %s() = %s", expr -> data.funcall.name, sleft ? (*result ? "true" : "false") : "NULL"); #endif break; case expr_none: case expr_match: case expr_substring: case expr_suffix: case expr_lcase: case expr_ucase: case expr_option: case expr_hardware: case expr_const_data: case expr_packet: case expr_concat: case expr_encapsulate: case expr_host_lookup: case expr_encode_int8: case expr_encode_int16: case expr_encode_int32: case expr_binary_to_ascii: case expr_reverse: case expr_pick_first_value: case expr_host_decl_name: case expr_config_option: case expr_leased_address: case expr_null: case expr_filename: case expr_sname: case expr_gethostname: case expr_v6relay: case expr_concat_dclist: log_error ("Data opcode in evaluate_boolean_expression: %d", expr -> op); return 0; case expr_extract_int8: case expr_extract_int16: case expr_extract_int32: case expr_const_int: case expr_lease_time: case expr_dns_transaction: case expr_add: case expr_subtract: case expr_multiply: case expr_divide: case expr_remainder: case expr_binary_and: case expr_binary_or: case expr_binary_xor: case expr_client_state: log_error ("Numeric opcode in evaluate_boolean_expression: %d", expr -> op); return 0; case expr_ns_add: case expr_ns_delete: case expr_ns_exists: case expr_ns_not_exists: log_error ("dns opcode in evaluate_boolean_expression: %d", expr -> op); return 0; case expr_function: log_error ("function definition in evaluate_boolean_expr"); return 0; case expr_arg: break; } log_error ("Bogus opcode in evaluate_boolean_expression: %d", expr -> op); return 0; } int evaluate_data_expression (result, packet, lease, client_state, in_options, cfg_options, scope, expr, file, line) struct data_string *result; struct packet *packet; struct lease *lease; struct client_state *client_state; struct option_state *in_options; struct option_state *cfg_options; struct binding_scope **scope; struct expression *expr; const char *file; int line; { struct data_string data, other; unsigned long offset, len, i; int s0, s1, s2, s3; int status; struct binding *binding; unsigned char *s; struct binding_value *bv; struct packet *relay_packet; struct option_state *relay_options; switch (expr -> op) { /* Extract N bytes starting at byte M of a data string. */ case expr_substring: memset (&data, 0, sizeof data); s0 = evaluate_data_expression (&data, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.substring.expr, MDL); /* Evaluate the offset and length. */ s1 = evaluate_numeric_expression (&offset, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.substring.offset); s2 = evaluate_numeric_expression (&len, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.substring.len); if (s0 && s1 && s2) { /* If the offset is after end of the string, return an empty string. Otherwise, do the adjustments and return what's left. */ if (data.len > offset) { data_string_copy (result, &data, file, line); result -> len -= offset; if (result -> len > len) { result -> len = len; result -> terminated = 0; } result -> data += offset; } s3 = 1; } else s3 = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("data: substring (%s, %s, %s) = %s", s0 ? print_hex_1 (data.len, data.data, 30) : "NULL", s1 ? print_dec_1 (offset) : "NULL", s2 ? print_dec_2 (len) : "NULL", (s3 ? print_hex_2 (result -> len, result -> data, 30) : "NULL")); #endif if (s0) data_string_forget (&data, MDL); if (s3) return 1; return 0; /* Extract the last N bytes of a data string. */ case expr_suffix: memset (&data, 0, sizeof data); s0 = evaluate_data_expression (&data, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.suffix.expr, MDL); /* Evaluate the length. */ s1 = evaluate_numeric_expression (&len, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.suffix.len); if (s0 && s1) { data_string_copy (result, &data, file, line); /* If we are returning the last N bytes of a string whose length is <= N, just return the string - otherwise, compute a new starting address and decrease the length. */ if (data.len > len) { result -> data += data.len - len; result -> len = len; } data_string_forget (&data, MDL); } #if defined (DEBUG_EXPRESSIONS) log_debug ("data: suffix (%s, %s) = %s", s0 ? print_hex_1 (data.len, data.data, 30) : "NULL", s1 ? print_dec_1 (len) : "NULL", ((s0 && s1) ? print_hex_2 (result -> len, result -> data, 30) : "NULL")); #endif return s0 && s1; /* Convert string to lowercase. */ case expr_lcase: memset(&data, 0, sizeof data); s0 = evaluate_data_expression(&data, packet, lease, client_state, in_options, cfg_options, scope, expr->data.lcase, MDL); s1 = 0; if (s0) { result->len = data.len; if (buffer_allocate(&result->buffer, result->len + data.terminated, MDL)) { result->data = &result->buffer->data[0]; memcpy(result->buffer->data, data.data, data.len + data.terminated); result->terminated = data.terminated; s = (unsigned char *)result->data; for (i = 0; i < result->len; i++, s++) *s = tolower(*s); s1 = 1; } else { log_error("data: lcase: no buffer memory."); } } #if defined (DEBUG_EXPRESSIONS) log_debug("data: lcase (%s) = %s", s0 ? print_hex_1(data.len, data.data, 30) : "NULL", s1 ? print_hex_2(result->len, result->data, 30) : "NULL"); #endif if (s0) data_string_forget(&data, MDL); return s1; /* Convert string to uppercase. */ case expr_ucase: memset(&data, 0, sizeof data); s0 = evaluate_data_expression(&data, packet, lease, client_state, in_options, cfg_options, scope, expr->data.lcase, MDL); s1 = 0; if (s0) { result->len = data.len; if (buffer_allocate(&result->buffer, result->len + data.terminated, file, line)) { result->data = &result->buffer->data[0]; memcpy(result->buffer->data, data.data, data.len + data.terminated); result->terminated = data.terminated; s = (unsigned char *)result->data; for (i = 0; i < result->len; i++, s++) *s = toupper(*s); s1 = 1; } else { log_error("data: lcase: no buffer memory."); } } #if defined (DEBUG_EXPRESSIONS) log_debug("data: ucase (%s) = %s", s0 ? print_hex_1(data.len, data.data, 30) : "NULL", s1 ? print_hex_2(result->len, result->data, 30) : "NULL"); #endif if (s0) data_string_forget(&data, MDL); return s1; /* Extract an option. */ case expr_option: if (in_options) s0 = get_option (result, expr -> data.option -> universe, packet, lease, client_state, in_options, cfg_options, in_options, scope, expr -> data.option -> code, file, line); else s0 = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("data: option %s.%s = %s", expr -> data.option -> universe -> name, expr -> data.option -> name, s0 ? print_hex_1 (result -> len, result -> data, 60) : "NULL"); #endif return s0; case expr_config_option: if (cfg_options) s0 = get_option (result, expr -> data.option -> universe, packet, lease, client_state, in_options, cfg_options, cfg_options, scope, expr -> data.option -> code, file, line); else s0 = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("data: config-option %s.%s = %s", expr -> data.option -> universe -> name, expr -> data.option -> name, s0 ? print_hex_1 (result -> len, result -> data, 60) : "NULL"); #endif return s0; /* Combine the hardware type and address. */ case expr_hardware: /* On the client, hardware is our hardware. */ if (client_state) { memset(result, 0, sizeof(*result)); result->data = client_state->interface->hw_address.hbuf; result->len = client_state->interface->hw_address.hlen; #if defined (DEBUG_EXPRESSIONS) log_debug("data: hardware = %s", print_hex_1(result->len, result->data, 60)); #endif return (1); } /* The server cares about the client's hardware address, so only in the case where we are examining a packet or have a lease with a hardware address can we return anything. */ if (packet != NULL && packet->raw != NULL) { if (packet->raw->hlen > sizeof(packet->raw->chaddr)) { log_error("data: hardware: invalid hlen (%d)\n", packet->raw->hlen); return (0); } result->len = packet->raw->hlen + 1; if (buffer_allocate(&result->buffer, result->len, MDL)){ result->data = &result->buffer->data[0]; result->buffer->data[0] = packet->raw->htype; memcpy(&result->buffer->data[1], packet->raw->chaddr, packet->raw->hlen); result->terminated = 0; } else { log_error("data: hardware: " "no memory for buffer."); return (0); } } else if (lease != NULL) { result->len = lease->hardware_addr.hlen; if (buffer_allocate(&result->buffer, result->len, MDL)){ result->data = &result->buffer->data[0]; memcpy(result->buffer->data, lease->hardware_addr.hbuf, result->len); result->terminated = 0; } else { log_error("data: hardware: " "no memory for buffer."); return (0); } } else { log_error("data: hardware: no raw packet or lease " "is available"); return (0); } #if defined (DEBUG_EXPRESSIONS) log_debug("data: hardware = %s", print_hex_1(result->len, result->data, 60)); #endif return (1); /* Extract part of the raw packet. */ case expr_packet: if (!packet || !packet -> raw) { log_error ("data: packet: raw packet not available"); return 0; } s0 = evaluate_numeric_expression (&offset, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.packet.offset); s1 = evaluate_numeric_expression (&len, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.packet.len); if (s0 && s1 && offset < packet -> packet_length) { if (offset + len > packet -> packet_length) result -> len = packet -> packet_length - offset; else result -> len = len; if (buffer_allocate (&result -> buffer, result -> len, file, line)) { result -> data = &result -> buffer -> data [0]; memcpy (result -> buffer -> data, (((unsigned char *)(packet -> raw)) + offset), result -> len); result -> terminated = 0; } else { log_error ("data: packet: no buffer memory."); return 0; } s2 = 1; } else s2 = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("data: packet (%ld, %ld) = %s", offset, len, s2 ? print_hex_1 (result -> len, result -> data, 60) : NULL); #endif return s2; /* The encapsulation of all defined options in an option space... */ case expr_encapsulate: if (cfg_options) s0 = option_space_encapsulate (result, packet, lease, client_state, in_options, cfg_options, scope, &expr -> data.encapsulate); else s0 = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("data: encapsulate (%s) = %s", expr -> data.encapsulate.data, s0 ? print_hex_1 (result -> len, result -> data, 60) : "NULL"); #endif return s0; /* Some constant data... */ case expr_const_data: #if defined (DEBUG_EXPRESSIONS) log_debug ("data: const = %s", print_hex_1 (expr -> data.const_data.len, expr -> data.const_data.data, 60)); #endif data_string_copy (result, &expr -> data.const_data, file, line); return 1; /* Hostname lookup... */ case expr_host_lookup: s0 = do_host_lookup (result, expr -> data.host_lookup); #if defined (DEBUG_EXPRESSIONS) log_debug ("data: DNS lookup (%s) = %s", expr -> data.host_lookup -> hostname, (s0 ? print_dotted_quads (result -> len, result -> data) : "NULL")); #endif return s0; /* Concatenation... */ case expr_concat: memset (&data, 0, sizeof data); s0 = evaluate_data_expression (&data, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.concat [0], MDL); memset (&other, 0, sizeof other); s1 = evaluate_data_expression (&other, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.concat [1], MDL); if (s0 && s1) { result -> len = data.len + other.len; if (!buffer_allocate (&result -> buffer, (result -> len + other.terminated), file, line)) { log_error ("data: concat: no memory"); result -> len = 0; data_string_forget (&data, MDL); data_string_forget (&other, MDL); return 0; } result -> data = &result -> buffer -> data [0]; memcpy (result -> buffer -> data, data.data, data.len); memcpy (&result -> buffer -> data [data.len], other.data, other.len + other.terminated); } if (s0) data_string_forget (&data, MDL); if (s1) data_string_forget (&other, MDL); #if defined (DEBUG_EXPRESSIONS) log_debug ("data: concat (%s, %s) = %s", s0 ? print_hex_1 (data.len, data.data, 20) : "NULL", s1 ? print_hex_2 (other.len, other.data, 20) : "NULL", ((s0 && s1) ? print_hex_3 (result -> len, result -> data, 30) : "NULL")); #endif return s0 && s1; case expr_encode_int8: s0 = evaluate_numeric_expression (&len, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.encode_int); if (s0) { result -> len = 1; if (!buffer_allocate (&result -> buffer, 1, file, line)) { log_error ("data: encode_int8: no memory"); result -> len = 0; s0 = 0; } else { result -> data = &result -> buffer -> data [0]; result -> buffer -> data [0] = len; } } else result -> len = 0; #if defined (DEBUG_EXPRESSIONS) if (!s0) log_debug ("data: encode_int8 (NULL) = NULL"); else log_debug ("data: encode_int8 (%ld) = %s", len, print_hex_2 (result -> len, result -> data, 20)); #endif return s0; case expr_encode_int16: s0 = evaluate_numeric_expression (&len, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.encode_int); if (s0) { result -> len = 2; if (!buffer_allocate (&result -> buffer, 2, file, line)) { log_error ("data: encode_int16: no memory"); result -> len = 0; s0 = 0; } else { result -> data = &result -> buffer -> data [0]; putUShort (result -> buffer -> data, len); } } else result -> len = 0; #if defined (DEBUG_EXPRESSIONS) if (!s0) log_debug ("data: encode_int16 (NULL) = NULL"); else log_debug ("data: encode_int16 (%ld) = %s", len, print_hex_2 (result -> len, result -> data, 20)); #endif return s0; case expr_encode_int32: s0 = evaluate_numeric_expression (&len, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.encode_int); if (s0) { result -> len = 4; if (!buffer_allocate (&result -> buffer, 4, file, line)) { log_error ("data: encode_int32: no memory"); result -> len = 0; s0 = 0; } else { result -> data = &result -> buffer -> data [0]; putULong (result -> buffer -> data, len); } } else result -> len = 0; #if defined (DEBUG_EXPRESSIONS) if (!s0) log_debug ("data: encode_int32 (NULL) = NULL"); else log_debug ("data: encode_int32 (%ld) = %s", len, print_hex_2 (result -> len, result -> data, 20)); #endif return s0; case expr_binary_to_ascii: /* Evaluate the base (offset) and width (len): */ s0 = evaluate_numeric_expression (&offset, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.b2a.base); s1 = evaluate_numeric_expression (&len, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.b2a.width); /* Evaluate the separator string. */ memset (&data, 0, sizeof data); s2 = evaluate_data_expression (&data, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.b2a.separator, MDL); /* Evaluate the data to be converted. */ memset (&other, 0, sizeof other); s3 = evaluate_data_expression (&other, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.b2a.buffer, MDL); if (s0 && s1 && s2 && s3) { unsigned buflen, i; if (len != 8 && len != 16 && len != 32) { log_info ("binary_to_ascii: %s %ld!", "invalid width", len); status = 0; goto b2a_out; } len /= 8; /* The buffer must be a multiple of the number's width. */ if (other.len % len) { log_info ("binary-to-ascii: %s %d %s %ld!", "length of buffer", other.len, "not a multiple of width", len); status = 0; goto b2a_out; } /* Count the width of the output. */ buflen = 0; for (i = 0; i < other.len; i += len) { if (len == 1) { if (offset == 8) { if (other.data [i] < 8) buflen++; else if (other.data [i] < 64) buflen += 2; else buflen += 3; } else if (offset == 10) { if (other.data [i] < 10) buflen++; else if (other.data [i] < 100) buflen += 2; else buflen += 3; } else if (offset == 16) { if (other.data [i] < 16) buflen++; else buflen += 2; } else buflen += (converted_length (&other.data [i], offset, 1)); } else buflen += (converted_length (&other.data [i], offset, len)); if (i + len != other.len) buflen += data.len; } if (!buffer_allocate (&result -> buffer, buflen + 1, file, line)) { log_error ("data: binary-to-ascii: no memory"); status = 0; goto b2a_out; } result -> data = &result -> buffer -> data [0]; result -> len = buflen; result -> terminated = 1; buflen = 0; for (i = 0; i < other.len; i += len) { buflen += (binary_to_ascii (&result -> buffer -> data [buflen], &other.data [i], offset, len)); if (i + len != other.len) { memcpy (&result -> buffer -> data [buflen], data.data, data.len); buflen += data.len; } } /* NUL terminate. */ result -> buffer -> data [buflen] = 0; status = 1; } else status = 0; b2a_out: #if defined (DEBUG_EXPRESSIONS) log_debug ("data: binary-to-ascii (%s, %s, %s, %s) = %s", s0 ? print_dec_1 (offset) : "NULL", s1 ? print_dec_2 (len) : "NULL", s2 ? print_hex_1 (data.len, data.data, 30) : "NULL", s3 ? print_hex_2 (other.len, other.data, 30) : "NULL", (status ? print_hex_3 (result -> len, result -> data, 30) : "NULL")); #endif if (s2) data_string_forget (&data, MDL); if (s3) data_string_forget (&other, MDL); if (status) return 1; return 0; case expr_reverse: /* Evaluate the width (len): */ s0 = evaluate_numeric_expression (&len, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.reverse.width); /* Evaluate the data. */ memset (&data, 0, sizeof data); s1 = evaluate_data_expression (&data, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.reverse.buffer, MDL); if (s0 && s1) { int i; /* The buffer must be a multiple of the number's width. */ if (data.len % len) { log_info ("reverse: %s %d %s %ld!", "length of buffer", data.len, "not a multiple of width", len); status = 0; goto reverse_out; } /* XXX reverse in place? I don't think we can. */ if (!buffer_allocate (&result -> buffer, data.len, file, line)) { log_error ("data: reverse: no memory"); status = 0; goto reverse_out; } result -> data = &result -> buffer -> data [0]; result -> len = data.len; result -> terminated = 0; for (i = 0; i < data.len; i += len) { memcpy (&result -> buffer -> data [i], &data.data [data.len - i - len], len); } status = 1; } else status = 0; reverse_out: #if defined (DEBUG_EXPRESSIONS) log_debug ("data: reverse (%s, %s) = %s", s0 ? print_dec_1 (len) : "NULL", s1 ? print_hex_1 (data.len, data.data, 30) : "NULL", (status ? print_hex_3 (result -> len, result -> data, 30) : "NULL")); #endif if (s0) data_string_forget (&data, MDL); if (status) return 1; return 0; case expr_leased_address: if (!lease) { log_debug("data: \"leased-address\" configuration " "directive: there is no lease associated " "with this client."); return 0; } result -> len = lease -> ip_addr.len; if (buffer_allocate (&result -> buffer, result -> len, file, line)) { result -> data = &result -> buffer -> data [0]; memcpy (&result -> buffer -> data [0], lease -> ip_addr.iabuf, lease -> ip_addr.len); result -> terminated = 0; } else { log_error ("data: leased-address: no memory."); return 0; } #if defined (DEBUG_EXPRESSIONS) log_debug ("data: leased-address = %s", print_hex_1 (result -> len, result -> data, 60)); #endif return 1; case expr_pick_first_value: memset (&data, 0, sizeof data); if ((evaluate_data_expression (result, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.pick_first_value.car, MDL))) { #if defined (DEBUG_EXPRESSIONS) log_debug ("data: pick_first_value (%s, xxx)", print_hex_1 (result -> len, result -> data, 40)); #endif return 1; } if (expr -> data.pick_first_value.cdr && (evaluate_data_expression (result, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.pick_first_value.cdr, MDL))) { #if defined (DEBUG_EXPRESSIONS) log_debug ("data: pick_first_value (NULL, %s)", print_hex_1 (result -> len, result -> data, 40)); #endif return 1; } #if defined (DEBUG_EXPRESSIONS) log_debug ("data: pick_first_value (NULL, NULL) = NULL"); #endif return 0; case expr_host_decl_name: if (!lease || !lease -> host) { log_error ("data: host_decl_name: not available"); return 0; } result -> len = strlen (lease -> host -> name); if (buffer_allocate (&result -> buffer, result -> len + 1, file, line)) { result -> data = &result -> buffer -> data [0]; strcpy ((char *)&result -> buffer -> data [0], lease -> host -> name); result -> terminated = 1; } else { log_error ("data: host-decl-name: no memory."); return 0; } #if defined (DEBUG_EXPRESSIONS) log_debug ("data: host-decl-name = %s", lease -> host -> name); #endif return 1; case expr_null: #if defined (DEBUG_EXPRESSIONS) log_debug ("data: null = NULL"); #endif return 0; case expr_variable_reference: if (scope && *scope) { binding = find_binding (*scope, expr -> data.variable); if (binding && binding -> value) { if (binding -> value -> type == binding_data) { data_string_copy (result, &binding -> value -> value.data, file, line); s0 = 1; } else if (binding -> value -> type != binding_data) { log_error ("binding type %d in %s.", binding -> value -> type, "evaluate_data_expression"); s0 = 0; } else s0 = 0; } else s0 = 0; } else s0 = 0; #if defined (DEBUG_EXPRESSIONS) log_debug ("data: %s = %s", expr -> data.variable, s0 ? print_hex_1 (result -> len, result -> data, 50) : "NULL"); #endif return s0; case expr_funcall: bv = (struct binding_value *)0; s0 = evaluate_expression (&bv, packet, lease, client_state, in_options, cfg_options, scope, expr, MDL); if (s0) { if (bv -> type != binding_data) log_error ("%s() returned type %d in %s.", expr -> data.funcall.name, bv -> type, "evaluate_data_expression"); else data_string_copy (result, &bv -> value.data, file, line); binding_value_dereference (&bv, MDL); } #if defined (DEBUG_EXPRESSIONS) log_debug ("data: %s = %s", expr -> data.funcall.name, s0 ? print_hex_1 (result -> len, result -> data, 50) : "NULL"); #endif break; /* Extract the filename. */ case expr_filename: if (packet && packet -> raw -> file [0]) { char *fn = memchr (packet -> raw -> file, 0, sizeof packet -> raw -> file); if (!fn) fn = ((char *)packet -> raw -> file + sizeof packet -> raw -> file); result -> len = fn - &(packet -> raw -> file [0]); if (buffer_allocate (&result -> buffer, result -> len + 1, file, line)) { result -> data = &result -> buffer -> data [0]; memcpy (&result -> buffer -> data [0], packet -> raw -> file, result -> len); result -> buffer -> data [result -> len] = 0; result -> terminated = 1; s0 = 1; } else { log_error ("data: filename: no memory."); s0 = 0; } } else s0 = 0; #if defined (DEBUG_EXPRESSIONS) log_info ("data: filename = \"%s\"", s0 ? (const char *)(result -> data) : "NULL"); #endif return s0; /* Extract the server name. */ case expr_sname: if (packet && packet -> raw -> sname [0]) { char *fn = memchr (packet -> raw -> sname, 0, sizeof packet -> raw -> sname); if (!fn) fn = ((char *)packet -> raw -> sname + sizeof packet -> raw -> sname); result -> len = fn - &packet -> raw -> sname [0]; if (buffer_allocate (&result -> buffer, result -> len + 1, file, line)) { result -> data = &result -> buffer -> data [0]; memcpy (&result -> buffer -> data [0], packet -> raw -> sname, result -> len); result -> buffer -> data [result -> len] = 0; result -> terminated = 1; s0 = 1; } else { log_error ("data: sname: no memory."); s0 = 0; } } else s0 = 0; #if defined (DEBUG_EXPRESSIONS) log_info ("data: sname = \"%s\"", s0 ? (const char *)(result -> data) : "NULL"); #endif return s0; /* Provide the system's local hostname as a return value. */ case expr_gethostname: /* * Allocate a buffer to return. * * The largest valid hostname is maybe 64 octets at a single * label, or 255 octets if you think a hostname is allowed * to contain labels (plus termination). */ memset(result, 0, sizeof(*result)); if (!buffer_allocate(&result->buffer, 255, file, line)) { log_error("data: gethostname(): no memory for buffer"); return 0; } result->data = result->buffer->data; /* * On successful completion, gethostname() resturns 0. It may * not null-terminate the string if there was insufficient * space. */ if (!gethostname((char *)result->buffer->data, 255)) { if (result->buffer->data[255] == '\0') result->len = strlen((char *)result->buffer->data); else result->len = 255; return 1; } data_string_forget(result, MDL); return 0; /* Find an option within a v6relay context * * The numeric expression in relay indicates which relay * to try and use as the context. The relays are numbered * 1 to 32 with 1 being the one closest to the client and * 32 closest to the server. A value of greater than 33 * indicates using the one closest to the server whatever * the count. A value of 0 indicates not using the relay * options, this is included for completeness and consistency * with the host-identier code. * * The data expression in roption is evaluated in that * context and the result returned. */ case expr_v6relay: len = 0; s1 = 0; memset (&data, 0, sizeof data); /* Evaluate the relay count */ s0 = evaluate_numeric_expression(&len, packet, lease, client_state, in_options, cfg_options, scope, expr->data.v6relay.relay); /* no number or an obviously invalid number */ if ((s0 == 0) || ((len > 0) && ((packet == NULL) || (packet->dhcpv6_container_packet == NULL)))) { #if defined (DEBUG_EXPRESSIONS) log_debug("data: v6relay(%lu) = NULL", len); #endif return (0); } /* Find the correct packet for the requested relay */ i = len; relay_packet = packet; relay_options = in_options; while ((i != 0) && (relay_packet->dhcpv6_container_packet != NULL)) { relay_packet = relay_packet->dhcpv6_container_packet; relay_options = relay_packet->options; i--; } /* We wanted a specific relay but were unable to find it */ if ((len <= MAX_V6RELAY_HOPS) && (i != 0)) { #if defined (DEBUG_EXPRESSIONS) log_debug("data: v6relay(%lu) = NULL", len); #endif return (0); } s1 = evaluate_data_expression(&data, relay_packet, lease, client_state, relay_options, cfg_options, scope, expr->data.v6relay.roption, MDL); if (s1) { data_string_copy(result, &data, file, line); data_string_forget(&data, MDL); } #if defined (DEBUG_EXPRESSIONS) log_debug("data: v6relay(%lu) = %s", len, s1 ? print_hex_3(result->len, result->data, 30) : "NULL"); #endif return (s1); case expr_concat_dclist: { /* Operands are compressed domain-name lists ("Dc" format) * Fetch both compressed lists then call concat_dclists which * combines them into a single compressed list. */ memset(&data, 0, sizeof data); int outcome = 0; s0 = evaluate_data_expression(&data, packet, lease, client_state, in_options, cfg_options, scope, expr->data.concat[0], MDL); memset (&other, 0, sizeof other); s1 = evaluate_data_expression (&other, packet, lease, client_state, in_options, cfg_options, scope, expr->data.concat[1], MDL); if (s0 && s1) { outcome = concat_dclists(result, &data, &other); if (outcome == 0) { log_error ("data: concat_dclist failed"); } } #if defined (DEBUG_EXPRESSIONS) log_debug ("data: concat_dclists (%s, %s) = %s", (s0 ? print_hex_1(data.len, data.data, data.len) : "NULL"), (s1 ? print_hex_2(other.len, other.data, other.len) : "NULL"), (((s0 && s1) && result->len > 0) ? print_hex_3 (result->len, result->data, result->len) : "NULL")); #endif if (s0) data_string_forget (&data, MDL); if (s1) data_string_forget (&other, MDL); return (outcome); } /* expr_concat_dclist */ case expr_check: case expr_equal: case expr_not_equal: case expr_regex_match: case expr_iregex_match: case expr_and: case expr_or: case expr_not: case expr_match: case expr_static: case expr_known: case expr_none: case expr_exists: case expr_variable_exists: log_error ("Boolean opcode in evaluate_data_expression: %d", expr -> op); return 0; case expr_extract_int8: case expr_extract_int16: case expr_extract_int32: case expr_const_int: case expr_lease_time: case expr_dns_transaction: case expr_add: case expr_subtract: case expr_multiply: case expr_divide: case expr_remainder: case expr_binary_and: case expr_binary_or: case expr_binary_xor: case expr_client_state: log_error ("Numeric opcode in evaluate_data_expression: %d", expr -> op); return 0; case expr_ns_add: case expr_ns_delete: case expr_ns_exists: case expr_ns_not_exists: log_error ("dns opcode in evaluate_boolean_expression: %d", expr -> op); return 0; case expr_function: log_error ("function definition in evaluate_data_expression"); return 0; case expr_arg: break; } log_error ("Bogus opcode in evaluate_data_expression: %d", expr -> op); return 0; } int evaluate_numeric_expression (result, packet, lease, client_state, in_options, cfg_options, scope, expr) unsigned long *result; struct packet *packet; struct lease *lease; struct client_state *client_state; struct option_state *in_options; struct option_state *cfg_options; struct binding_scope **scope; struct expression *expr; { struct data_string data; int status, sleft, sright; struct binding *binding; struct binding_value *bv; unsigned long ileft, iright; int rc = 0; switch (expr -> op) { case expr_check: case expr_equal: case expr_not_equal: case expr_regex_match: case expr_iregex_match: case expr_and: case expr_or: case expr_not: case expr_match: case expr_static: case expr_known: case expr_none: case expr_exists: case expr_variable_exists: log_error ("Boolean opcode in evaluate_numeric_expression: %d", expr -> op); return 0; case expr_substring: case expr_suffix: case expr_lcase: case expr_ucase: case expr_option: case expr_hardware: case expr_const_data: case expr_packet: case expr_concat: case expr_encapsulate: case expr_host_lookup: case expr_encode_int8: case expr_encode_int16: case expr_encode_int32: case expr_binary_to_ascii: case expr_reverse: case expr_filename: case expr_sname: case expr_pick_first_value: case expr_host_decl_name: case expr_config_option: case expr_leased_address: case expr_null: case expr_gethostname: case expr_v6relay: log_error ("Data opcode in evaluate_numeric_expression: %d", expr -> op); return 0; case expr_extract_int8: memset (&data, 0, sizeof data); status = evaluate_data_expression (&data, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.extract_int, MDL); if (status) *result = data.data [0]; #if defined (DEBUG_EXPRESSIONS) log_debug ("num: extract_int8 (%s) = %s", status ? print_hex_1 (data.len, data.data, 60) : "NULL", status ? print_dec_1 (*result) : "NULL" ); #endif if (status) data_string_forget (&data, MDL); return status; case expr_extract_int16: memset(&data, 0, sizeof(data)); status = (evaluate_data_expression (&data, packet, lease, client_state, in_options, cfg_options, scope, expr->data.extract_int, MDL)); if (status && data.len >= 2) { *result = getUShort(data.data); rc = 1; } #if defined (DEBUG_EXPRESSIONS) if (rc == 1) { log_debug("num: extract_int16 (%s) = %ld", print_hex_1(data.len, data.data, 60), *result); } else { log_debug("num: extract_int16 (NULL) = NULL"); } #endif if (status) data_string_forget(&data, MDL); return (rc); case expr_extract_int32: memset (&data, 0, sizeof data); status = (evaluate_data_expression (&data, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.extract_int, MDL)); if (status && data.len >= 4) { *result = getULong (data.data); rc = 1; } #if defined (DEBUG_EXPRESSIONS) if (rc == 1) { log_debug ("num: extract_int32 (%s) = %ld", print_hex_1 (data.len, data.data, 60), *result); } else { log_debug ("num: extract_int32 (NULL) = NULL"); } #endif if (status) data_string_forget (&data, MDL); return (rc); case expr_const_int: *result = expr -> data.const_int; #if defined (DEBUG_EXPRESSIONS) log_debug ("number: CONSTANT = %ld", *result); #endif return 1; case expr_lease_time: if (!lease) { log_error("data: leased_lease: not available"); return (0); } if (lease->ends < cur_time) { log_error("%s %lu when it is now %lu", "data: lease_time: lease ends at", (long)(lease->ends), (long)cur_time); return (0); } *result = lease->ends - cur_time; #if defined (DEBUG_EXPRESSIONS) log_debug("number: lease-time = (%lu - %lu) = %ld", (long unsigned)lease->ends, (long unsigned)cur_time, *result); #endif return (1); case expr_variable_reference: if (scope && *scope) { binding = find_binding (*scope, expr -> data.variable); if (binding && binding -> value) { if (binding -> value -> type == binding_numeric) { *result = binding -> value -> value.intval; status = 1; } else { log_error ("binding type %d in %s.", binding -> value -> type, "evaluate_numeric_expression"); status = 0; } } else status = 0; } else status = 0; #if defined (DEBUG_EXPRESSIONS) if (status) log_debug ("numeric: %s = %ld", expr -> data.variable, *result); else log_debug ("numeric: %s = NULL", expr -> data.variable); #endif return status; case expr_funcall: bv = (struct binding_value *)0; status = evaluate_expression (&bv, packet, lease, client_state, in_options, cfg_options, scope, expr, MDL); if (status) { if (bv -> type != binding_numeric) log_error ("%s() returned type %d in %s.", expr -> data.funcall.name, bv -> type, "evaluate_numeric_expression"); else *result = bv -> value.intval; binding_value_dereference (&bv, MDL); } #if defined (DEBUG_EXPRESSIONS) log_debug ("data: %s = %ld", expr -> data.funcall.name, status ? *result : 0); #endif break; case expr_add: sleft = evaluate_numeric_expression (&ileft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); sright = evaluate_numeric_expression (&iright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); #if defined (DEBUG_EXPRESSIONS) if (sleft && sright) log_debug ("num: %ld + %ld = %ld", ileft, iright, ileft + iright); else if (sleft) log_debug ("num: %ld + NULL = NULL", ileft); else log_debug ("num: NULL + %ld = NULL", iright); #endif if (sleft && sright) { *result = ileft + iright; return 1; } return 0; case expr_subtract: sleft = evaluate_numeric_expression (&ileft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); sright = evaluate_numeric_expression (&iright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); #if defined (DEBUG_EXPRESSIONS) if (sleft && sright) log_debug ("num: %ld - %ld = %ld", ileft, iright, ileft - iright); else if (sleft) log_debug ("num: %ld - NULL = NULL", ileft); else log_debug ("num: NULL - %ld = NULL", iright); #endif if (sleft && sright) { *result = ileft - iright; return 1; } return 0; case expr_multiply: sleft = evaluate_numeric_expression (&ileft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); sright = evaluate_numeric_expression (&iright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); #if defined (DEBUG_EXPRESSIONS) if (sleft && sright) log_debug ("num: %ld * %ld = %ld", ileft, iright, ileft * iright); else if (sleft) log_debug ("num: %ld * NULL = NULL", ileft); else log_debug ("num: NULL * %ld = NULL", iright); #endif if (sleft && sright) { *result = ileft * iright; return 1; } return 0; case expr_divide: sleft = evaluate_numeric_expression (&ileft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); sright = evaluate_numeric_expression (&iright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); #if defined (DEBUG_EXPRESSIONS) if (sleft && sright) { if (iright != 0) log_debug ("num: %ld / %ld = %ld", ileft, iright, ileft / iright); else log_debug ("num: %ld / %ld = NULL", ileft, iright); } else if (sleft) log_debug ("num: %ld / NULL = NULL", ileft); else log_debug ("num: NULL / %ld = NULL", iright); #endif if (sleft && sright && iright) { *result = ileft / iright; return 1; } return 0; case expr_remainder: sleft = evaluate_numeric_expression (&ileft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); sright = evaluate_numeric_expression (&iright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); #if defined (DEBUG_EXPRESSIONS) if (sleft && sright) { if (iright != 0) log_debug ("num: %ld %% %ld = %ld", ileft, iright, ileft % iright); else log_debug ("num: %ld %% %ld = NULL", ileft, iright); } else if (sleft) log_debug ("num: %ld %% NULL = NULL", ileft); else log_debug ("num: NULL %% %ld = NULL", iright); #endif if (sleft && sright && iright) { *result = ileft % iright; return 1; } return 0; case expr_binary_and: sleft = evaluate_numeric_expression (&ileft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); sright = evaluate_numeric_expression (&iright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); #if defined (DEBUG_EXPRESSIONS) if (sleft && sright) log_debug ("num: %ld | %ld = %ld", ileft, iright, ileft & iright); else if (sleft) log_debug ("num: %ld & NULL = NULL", ileft); else log_debug ("num: NULL & %ld = NULL", iright); #endif if (sleft && sright) { *result = ileft & iright; return 1; } return 0; case expr_binary_or: sleft = evaluate_numeric_expression (&ileft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); sright = evaluate_numeric_expression (&iright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); #if defined (DEBUG_EXPRESSIONS) if (sleft && sright) log_debug ("num: %ld | %ld = %ld", ileft, iright, ileft | iright); else if (sleft) log_debug ("num: %ld | NULL = NULL", ileft); else log_debug ("num: NULL | %ld = NULL", iright); #endif if (sleft && sright) { *result = ileft | iright; return 1; } return 0; case expr_binary_xor: sleft = evaluate_numeric_expression (&ileft, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [0]); sright = evaluate_numeric_expression (&iright, packet, lease, client_state, in_options, cfg_options, scope, expr -> data.and [1]); #if defined (DEBUG_EXPRESSIONS) if (sleft && sright) log_debug ("num: %ld ^ %ld = %ld", ileft, iright, ileft ^ iright); else if (sleft) log_debug ("num: %ld ^ NULL = NULL", ileft); else log_debug ("num: NULL ^ %ld = NULL", iright); #endif if (sleft && sright) { *result = ileft ^ iright; return 1; } return 0; case expr_client_state: if (client_state) { #if defined (DEBUG_EXPRESSIONS) log_debug ("num: client-state = %d", client_state -> state); #endif *result = client_state -> state; return 1; } else { #if defined (DEBUG_EXPRESSIONS) log_debug ("num: client-state = NULL"); #endif return 0; } case expr_function: log_error ("function definition in evaluate_numeric_expr"); return 0; case expr_arg: break; default: log_fatal("Impossible case at %s:%d. Undefined operator " "%d.", MDL, expr->op); break; } log_error ("evaluate_numeric_expression: bogus opcode %d", expr -> op); return 0; } /* * Return data hanging off of an option cache structure, or if there * isn't any, evaluate the expression hanging off of it and return the * result of that evaluation. There should never be both an expression * and a valid data_string. * * returns 0 if there wasn't an expression or it couldn't be evaluated * returns non-zero if there was an expression or string that was evaluated * When it returns zero the arguements, in particualr resutl, should not * be modified */ int evaluate_option_cache (result, packet, lease, client_state, in_options, cfg_options, scope, oc, file, line) struct data_string *result; struct packet *packet; struct lease *lease; struct client_state *client_state; struct option_state *in_options; struct option_state *cfg_options; struct binding_scope **scope; struct option_cache *oc; const char *file; int line; { if (oc->data.data != NULL) { data_string_copy (result, &oc -> data, file, line); return 1; } if (!oc -> expression) return 0; return evaluate_data_expression (result, packet, lease, client_state, in_options, cfg_options, scope, oc -> expression, file, line); } /* Evaluate an option cache and extract a boolean from the result. * The boolean option cache is actually a trinary value where: * * 0 = return 0, ignore parameter 0 (also the case for no data) * 1 = return 1, ignore parameter 0 * 2 = return 0, ignore parameter 1 * * This supports both classic boolean flags on/off as well as the * allow/deny/ignore keywords */ int evaluate_boolean_option_cache (ignorep, packet, lease, client_state, in_options, cfg_options, scope, oc, file, line) int *ignorep; struct packet *packet; struct lease *lease; struct client_state *client_state; struct option_state *in_options; struct option_state *cfg_options; struct binding_scope **scope; struct option_cache *oc; const char *file; int line; { int result = 0; if (ignorep) *ignorep = 0; /* Only attempt to evaluate if option_cache is not null. This permits * us to be called with option_lookup() as an argument. */ if (oc && in_options) { struct data_string ds; memset(&ds, 0, sizeof ds); if (evaluate_option_cache(&ds, packet, lease, client_state, in_options, cfg_options, scope, oc, file, line)) { /* We have a value for the option set result and * ignore parameter accordingly. */ if (ds.len) { if (ds.data[0] == 1) result = 1; else if ((ds.data[0] == 2) && (ignorep != NULL)) *ignorep = 1; } data_string_forget(&ds, MDL); } } return (result); } /* Evaluate a boolean expression and return the result of the evaluation, or FALSE if it failed. */ int evaluate_boolean_expression_result (ignorep, packet, lease, client_state, in_options, cfg_options, scope, expr) int *ignorep; struct packet *packet; struct lease *lease; struct client_state *client_state; struct option_state *in_options; struct option_state *cfg_options; struct binding_scope **scope; struct expression *expr; { int result; /* So that we can be called with option_lookup as an argument. */ if (!expr) return 0; if (!evaluate_boolean_expression (&result, packet, lease, client_state, in_options, cfg_options, scope, expr)) return 0; if (result == 2) { *ignorep = 1; result = 0; } else *ignorep = 0; return result; } /* Dereference an expression node, and if the reference count goes to zero, dereference any data it refers to, and then free it. */ void expression_dereference (eptr, file, line) struct expression **eptr; const char *file; int line; { struct expression *expr = *eptr; /* Zero the pointer. */ *eptr = (struct expression *)0; /* Decrement the reference count. If it's nonzero, we're done. */ --(expr -> refcnt); rc_register (file, line, eptr, expr, expr -> refcnt, 1, RC_MISC); if (expr -> refcnt > 0) return; if (expr -> refcnt < 0) { log_error ("%s(%d): negative refcnt!", file, line); #if defined (DEBUG_RC_HISTORY) dump_rc_history (expr); #endif #if defined (POINTER_DEBUG) abort (); #else return; #endif } /* Dereference subexpressions. */ switch (expr -> op) { /* All the binary operators can be handled the same way. */ case expr_equal: case expr_not_equal: case expr_regex_match: case expr_iregex_match: case expr_concat: case expr_and: case expr_or: case expr_add: case expr_subtract: case expr_multiply: case expr_divide: case expr_remainder: case expr_binary_and: case expr_binary_or: case expr_binary_xor: case expr_client_state: if (expr -> data.equal [0]) expression_dereference (&expr -> data.equal [0], file, line); if (expr -> data.equal [1]) expression_dereference (&expr -> data.equal [1], file, line); break; case expr_substring: if (expr -> data.substring.expr) expression_dereference (&expr -> data.substring.expr, file, line); if (expr -> data.substring.offset) expression_dereference (&expr -> data.substring.offset, file, line); if (expr -> data.substring.len) expression_dereference (&expr -> data.substring.len, file, line); break; case expr_suffix: if (expr -> data.suffix.expr) expression_dereference (&expr -> data.suffix.expr, file, line); if (expr -> data.suffix.len) expression_dereference (&expr -> data.suffix.len, file, line); break; case expr_lcase: if (expr->data.lcase) expression_dereference(&expr->data.lcase, MDL); break; case expr_ucase: if (expr->data.ucase) expression_dereference(&expr->data.ucase, MDL); break; case expr_not: if (expr -> data.not) expression_dereference (&expr -> data.not, file, line); break; case expr_packet: if (expr -> data.packet.offset) expression_dereference (&expr -> data.packet.offset, file, line); if (expr -> data.packet.len) expression_dereference (&expr -> data.packet.len, file, line); break; case expr_extract_int8: case expr_extract_int16: case expr_extract_int32: if (expr -> data.extract_int) expression_dereference (&expr -> data.extract_int, file, line); break; case expr_encode_int8: case expr_encode_int16: case expr_encode_int32: if (expr -> data.encode_int) expression_dereference (&expr -> data.encode_int, file, line); break; case expr_encapsulate: case expr_const_data: data_string_forget (&expr -> data.const_data, file, line); break; case expr_host_lookup: if (expr -> data.host_lookup) dns_host_entry_dereference (&expr -> data.host_lookup, file, line); break; case expr_binary_to_ascii: if (expr -> data.b2a.base) expression_dereference (&expr -> data.b2a.base, file, line); if (expr -> data.b2a.width) expression_dereference (&expr -> data.b2a.width, file, line); if (expr -> data.b2a.separator) expression_dereference (&expr -> data.b2a.separator, file, line); if (expr -> data.b2a.buffer) expression_dereference (&expr -> data.b2a.buffer, file, line); break; case expr_pick_first_value: if (expr -> data.pick_first_value.car) expression_dereference (&expr -> data.pick_first_value.car, file, line); if (expr -> data.pick_first_value.cdr) expression_dereference (&expr -> data.pick_first_value.cdr, file, line); break; case expr_reverse: if (expr -> data.reverse.width) expression_dereference (&expr -> data.reverse.width, file, line); if (expr -> data.reverse.buffer) expression_dereference (&expr -> data.reverse.buffer, file, line); break; case expr_variable_reference: case expr_variable_exists: if (expr -> data.variable) dfree (expr -> data.variable, file, line); break; case expr_funcall: if (expr -> data.funcall.name) dfree (expr -> data.funcall.name, file, line); if (expr -> data.funcall.arglist) expression_dereference (&expr -> data.funcall.arglist, file, line); break; case expr_arg: if (expr -> data.arg.val) expression_dereference (&expr -> data.arg.val, file, line); if (expr -> data.arg.next) expression_dereference (&expr -> data.arg.next, file, line); break; case expr_function: fundef_dereference (&expr -> data.func, file, line); break; case expr_v6relay: if (expr->data.v6relay.relay) expression_dereference(&expr->data.v6relay.relay, file, line); if (expr->data.v6relay.roption) expression_dereference(&expr->data.v6relay.roption, file, line); break; /* No subexpressions. */ case expr_leased_address: case expr_lease_time: case expr_filename: case expr_sname: case expr_const_int: case expr_check: case expr_option: case expr_hardware: case expr_exists: case expr_known: case expr_null: case expr_gethostname: break; default: break; } free_expression (expr, MDL); } int is_boolean_expression (expr) struct expression *expr; { return (expr -> op == expr_check || expr -> op == expr_exists || expr -> op == expr_variable_exists || expr -> op == expr_equal || expr -> op == expr_not_equal || expr->op == expr_regex_match || expr->op == expr_iregex_match || expr -> op == expr_and || expr -> op == expr_or || expr -> op == expr_not || expr -> op == expr_known || expr -> op == expr_static); } int is_data_expression (expr) struct expression *expr; { return (expr->op == expr_substring || expr->op == expr_suffix || expr->op == expr_lcase || expr->op == expr_ucase || expr->op == expr_option || expr->op == expr_hardware || expr->op == expr_const_data || expr->op == expr_packet || expr->op == expr_concat || expr->op == expr_encapsulate || expr->op == expr_encode_int8 || expr->op == expr_encode_int16 || expr->op == expr_encode_int32 || expr->op == expr_host_lookup || expr->op == expr_binary_to_ascii || expr->op == expr_filename || expr->op == expr_sname || expr->op == expr_reverse || expr->op == expr_pick_first_value || expr->op == expr_host_decl_name || expr->op == expr_leased_address || expr->op == expr_config_option || expr->op == expr_null || expr->op == expr_gethostname || expr->op == expr_v6relay); } int is_numeric_expression (expr) struct expression *expr; { return (expr -> op == expr_extract_int8 || expr -> op == expr_extract_int16 || expr -> op == expr_extract_int32 || expr -> op == expr_const_int || expr -> op == expr_lease_time || expr -> op == expr_add || expr -> op == expr_subtract || expr -> op == expr_multiply || expr -> op == expr_divide || expr -> op == expr_remainder || expr -> op == expr_binary_and || expr -> op == expr_binary_or || expr -> op == expr_binary_xor || expr -> op == expr_client_state); } int is_compound_expression (expr) struct expression *expr; { return (expr -> op == expr_substring || expr -> op == expr_suffix || expr -> op == expr_option || expr -> op == expr_concat || expr -> op == expr_encode_int8 || expr -> op == expr_encode_int16 || expr -> op == expr_encode_int32 || expr -> op == expr_binary_to_ascii || expr -> op == expr_reverse || expr -> op == expr_pick_first_value || expr -> op == expr_config_option || expr -> op == expr_extract_int8 || expr -> op == expr_extract_int16 || expr -> op == expr_extract_int32 || expr -> op == expr_v6relay); } static int op_val (enum expr_op); static int op_val (op) enum expr_op op; { switch (op) { case expr_none: case expr_match: case expr_static: case expr_check: case expr_substring: case expr_suffix: case expr_lcase: case expr_ucase: case expr_concat: case expr_encapsulate: case expr_host_lookup: case expr_not: case expr_option: case expr_hardware: case expr_packet: case expr_const_data: case expr_extract_int8: case expr_extract_int16: case expr_extract_int32: case expr_encode_int8: case expr_encode_int16: case expr_encode_int32: case expr_const_int: case expr_exists: case expr_variable_exists: case expr_known: case expr_binary_to_ascii: case expr_reverse: case expr_filename: case expr_sname: case expr_pick_first_value: case expr_host_decl_name: case expr_config_option: case expr_leased_address: case expr_lease_time: case expr_dns_transaction: case expr_null: case expr_variable_reference: case expr_ns_add: case expr_ns_delete: case expr_ns_exists: case expr_ns_not_exists: case expr_arg: case expr_funcall: case expr_function: /* XXXDPN: Need to assign sane precedences to these. */ case expr_binary_and: case expr_binary_or: case expr_binary_xor: case expr_client_state: case expr_gethostname: case expr_v6relay: case expr_concat_dclist: return 100; case expr_equal: case expr_not_equal: case expr_regex_match: case expr_iregex_match: return 4; case expr_or: case expr_and: return 3; case expr_add: case expr_subtract: return 2; case expr_multiply: case expr_divide: case expr_remainder: return 1; } return 100; } int op_precedence (op1, op2) enum expr_op op1, op2; { return op_val (op1) - op_val (op2); } enum expression_context expression_context (struct expression *expr) { if (is_data_expression (expr)) return context_data; if (is_numeric_expression (expr)) return context_numeric; if (is_boolean_expression (expr)) return context_boolean; return context_any; } enum expression_context op_context (op) enum expr_op op; { switch (op) { /* XXX Why aren't these specific? */ case expr_none: case expr_match: case expr_static: case expr_check: case expr_substring: case expr_suffix: case expr_lcase: case expr_ucase: case expr_concat: case expr_encapsulate: case expr_host_lookup: case expr_not: case expr_option: case expr_hardware: case expr_packet: case expr_const_data: case expr_extract_int8: case expr_extract_int16: case expr_extract_int32: case expr_encode_int8: case expr_encode_int16: case expr_encode_int32: case expr_const_int: case expr_exists: case expr_variable_exists: case expr_known: case expr_binary_to_ascii: case expr_reverse: case expr_filename: case expr_sname: case expr_pick_first_value: case expr_host_decl_name: case expr_config_option: case expr_leased_address: case expr_lease_time: case expr_null: case expr_variable_reference: case expr_ns_add: case expr_ns_delete: case expr_ns_exists: case expr_ns_not_exists: case expr_dns_transaction: case expr_arg: case expr_funcall: case expr_function: case expr_gethostname: case expr_v6relay: case expr_concat_dclist: return context_any; case expr_equal: case expr_not_equal: case expr_regex_match: case expr_iregex_match: return context_data; case expr_and: return context_boolean; case expr_or: return context_boolean; case expr_add: case expr_subtract: case expr_multiply: case expr_divide: case expr_remainder: case expr_binary_and: case expr_binary_or: case expr_binary_xor: case expr_client_state: return context_numeric; } return context_any; } int write_expression (file, expr, col, indent, firstp) FILE *file; struct expression *expr; int col; int indent; int firstp; { struct expression *e; const char *s; char obuf [65]; int scol; int width; /* If this promises to be a fat expression, start a new line. */ if (!firstp && is_compound_expression (expr)) { indent_spaces (file, indent); col = indent; } switch (expr -> op) { case expr_none: col = token_print_indent (file, col, indent, "", "", "null"); break; case expr_check: col = token_print_indent (file, col, indent, "", "", "check"); col = token_print_indent_concat (file, col, indent, " ", "", "\"", expr -> data.check -> name, "\"", (char *)0); break; case expr_regex_match: s = "~="; goto binary; case expr_iregex_match: s = "~~"; goto binary; case expr_not_equal: s = "!="; goto binary; case expr_equal: s = "="; binary: col = write_expression (file, expr -> data.equal [0], col, indent, 1); col = token_print_indent (file, col, indent, " ", " ", s); col = write_expression (file, expr -> data.equal [1], col, indent + 2, 0); break; case expr_substring: col = token_print_indent (file, col, indent, "", "", "substring"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; col = write_expression (file, expr -> data.substring.expr, col, scol, 1); col = token_print_indent (file, col, indent, "", " ", ","); col = write_expression (file, expr -> data.substring.offset, col, indent, 0); col = token_print_indent (file, col, scol, "", " ", ","); col = write_expression (file, expr -> data.substring.len, col, scol, 0); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_suffix: col = token_print_indent (file, col, indent, "", "", "suffix"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; col = write_expression (file, expr -> data.suffix.expr, col, scol, 1); col = token_print_indent (file, col, scol, "", " ", ","); col = write_expression (file, expr -> data.suffix.len, col, scol, 0); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_lcase: col = token_print_indent(file, col, indent, "", "", "lcase"); col = token_print_indent(file, col, indent, " ", "", "("); scol = col; col = write_expression(file, expr->data.lcase, col, scol, 1); col = token_print_indent(file, col, indent, "", "", ")"); break; case expr_ucase: col = token_print_indent(file, col, indent, "", "", "ucase"); col = token_print_indent(file, col, indent, " ", "", "("); scol = col; col = write_expression(file, expr->data.ucase, col, scol, 1); col = token_print_indent(file, col, indent, "", "", ")"); break; case expr_concat: e = expr; col = token_print_indent (file, col, indent, "", "", "concat"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; firstp = 1; concat_again: col = write_expression (file, e -> data.concat [0], col, scol, firstp); firstp = 0; if (!e -> data.concat [1]) goto no_concat_cdr; col = token_print_indent (file, col, scol, "", " ", ","); if (e -> data.concat [1] -> op == expr_concat) { e = e -> data.concat [1]; goto concat_again; } col = write_expression (file, e -> data.concat [1], col, scol, 0); no_concat_cdr: col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_host_lookup: col = token_print_indent (file, col, indent, "", "", "gethostbyname"); col = token_print_indent (file, col, indent, " ", "", "("); col = token_print_indent_concat (file, col, indent, "", "", "\"", expr -> data.host_lookup -> hostname, "\"", (char *)0); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_add: s = "+"; goto binary; case expr_subtract: s = "-"; goto binary; case expr_multiply: s = "*"; goto binary; case expr_divide: s = "/"; goto binary; case expr_remainder: s = "%"; goto binary; case expr_binary_and: s = "&"; goto binary; case expr_binary_or: s = "|"; goto binary; case expr_binary_xor: s = "^"; goto binary; case expr_and: s = "and"; goto binary; case expr_or: s = "or"; goto binary; case expr_not: col = token_print_indent (file, col, indent, "", " ", "not"); col = write_expression (file, expr -> data.not, col, indent + 2, 1); break; case expr_option: s = "option"; print_option_name: col = token_print_indent (file, col, indent, "", "", s); if (expr -> data.option -> universe != &dhcp_universe) { col = token_print_indent (file, col, indent, " ", "", (expr -> data.option -> universe -> name)); col = token_print_indent (file, col, indent, "", "", "."); col = token_print_indent (file, col, indent, "", "", expr -> data.option -> name); } else { col = token_print_indent (file, col, indent, " ", "", expr -> data.option -> name); } break; case expr_hardware: col = token_print_indent (file, col, indent, "", "", "hardware"); break; case expr_packet: col = token_print_indent (file, col, indent, "", "", "packet"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; col = write_expression (file, expr -> data.packet.offset, col, indent, 1); col = token_print_indent (file, col, scol, "", " ", ","); col = write_expression (file, expr -> data.packet.len, col, scol, 0); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_const_data: col = token_indent_data_string (file, col, indent, "", "", &expr -> data.const_data); break; case expr_extract_int8: width = 8; extract_int: col = token_print_indent (file, col, indent, "", "", "extract-int"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; col = write_expression (file, expr -> data.extract_int, col, indent, 1); col = token_print_indent (file, col, scol, "", " ", ","); sprintf (obuf, "%d", width); col = token_print_indent (file, col, scol, " ", "", obuf); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_extract_int16: width = 16; goto extract_int; case expr_extract_int32: width = 32; goto extract_int; case expr_encode_int8: width = 8; encode_int: col = token_print_indent (file, col, indent, "", "", "encode-int"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; col = write_expression (file, expr -> data.extract_int, col, indent, 1); col = token_print_indent (file, col, scol, "", " ", ","); sprintf (obuf, "%d", width); col = token_print_indent (file, col, scol, " ", "", obuf); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_encode_int16: width = 16; goto encode_int; case expr_encode_int32: width = 32; goto encode_int; case expr_const_int: sprintf (obuf, "%lu", expr -> data.const_int); col = token_print_indent (file, col, indent, "", "", obuf); break; case expr_exists: s = "exists"; goto print_option_name; case expr_encapsulate: col = token_print_indent (file, col, indent, "", "", "encapsulate"); col = token_indent_data_string (file, col, indent, " ", "", &expr -> data.encapsulate); break; case expr_known: col = token_print_indent (file, col, indent, "", "", "known"); break; case expr_reverse: col = token_print_indent (file, col, indent, "", "", "reverse"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; col = write_expression (file, expr -> data.reverse.width, col, scol, 1); col = token_print_indent (file, col, scol, "", " ", ","); col = write_expression (file, expr -> data.reverse.buffer, col, scol, 0); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_leased_address: col = token_print_indent (file, col, indent, "", "", "leased-address"); break; case expr_client_state: col = token_print_indent (file, col, indent, "", "", "client-state"); break; case expr_binary_to_ascii: col = token_print_indent (file, col, indent, "", "", "binary-to-ascii"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; col = write_expression (file, expr -> data.b2a.base, col, scol, 1); col = token_print_indent (file, col, scol, "", " ", ","); col = write_expression (file, expr -> data.b2a.width, col, scol, 0); col = token_print_indent (file, col, scol, "", " ", ","); col = write_expression (file, expr -> data.b2a.separator, col, scol, 0); col = token_print_indent (file, col, scol, "", " ", ","); col = write_expression (file, expr -> data.b2a.buffer, col, scol, 0); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_config_option: s = "config-option"; goto print_option_name; case expr_host_decl_name: col = token_print_indent (file, col, indent, "", "", "host-decl-name"); break; case expr_pick_first_value: e = expr; col = token_print_indent (file, col, indent, "", "", "pick-first-value"); col = token_print_indent (file, col, indent, " ", "", "("); scol = col; firstp = 1; pick_again: col = write_expression (file, e -> data.pick_first_value.car, col, scol, firstp); firstp = 0; /* We're being very lisp-like right now - instead of representing this expression as (first middle . last) we're representing it as (first middle last), which means that the tail cdr is always nil. Apologies to non-wisp-lizards - may this obscure way of describing the problem motivate you to learn more about the one true computing language. */ if (!e -> data.pick_first_value.cdr) goto no_pick_cdr; col = token_print_indent (file, col, scol, "", " ", ","); if (e -> data.pick_first_value.cdr -> op == expr_pick_first_value) { e = e -> data.pick_first_value.cdr; goto pick_again; } col = write_expression (file, e -> data.pick_first_value.cdr, col, scol, 0); no_pick_cdr: col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_lease_time: col = token_print_indent (file, col, indent, "", "", "lease-time"); break; case expr_static: col = token_print_indent (file, col, indent, "", "", "static"); break; case expr_null: col = token_print_indent (file, col, indent, "", "", "null"); break; case expr_variable_reference: col = token_print_indent (file, indent, indent, "", "", expr -> data.variable); break; case expr_variable_exists: col = token_print_indent (file, indent, indent, "", "", "defined"); col = token_print_indent (file, col, indent, " ", "", "("); col = token_print_indent (file, col, indent, "", "", expr -> data.variable); col = token_print_indent (file, col, indent, "", "", ")"); break; case expr_gethostname: col = token_print_indent(file, col, indent, "", "", "gethostname()"); break; case expr_funcall: col = token_print_indent(file, indent, indent, "", "", expr->data.funcall.name); col = token_print_indent(file, col, indent, " ", "", "("); firstp = 1; e = expr->data.funcall.arglist; while (e != NULL) { if (!firstp) col = token_print_indent(file, col, indent, "", " ", ","); col = write_expression(file, e->data.arg.val, col, indent, firstp); firstp = 0; e = e->data.arg.next; } col = token_print_indent(file, col, indent, "", "", ")"); break; case expr_v6relay: col = token_print_indent(file, col, indent, "", "", "v6relay"); col = token_print_indent(file, col, indent, " ", "", "("); scol = col; col = write_expression(file, expr->data.v6relay.relay, col, scol, 1); col = token_print_indent (file, col, scol, "", " ", ","); col = write_expression(file, expr->data.v6relay.roption, col, scol, 0); col = token_print_indent(file, col, indent, "", "", ")"); break; default: log_fatal ("invalid expression type in print_expression: %d", expr -> op); } return col; } struct binding *find_binding (struct binding_scope *scope, const char *name) { struct binding *bp; struct binding_scope *s; for (s = scope; s; s = s -> outer) { for (bp = s -> bindings; bp; bp = bp -> next) { if (!strcasecmp (name, bp -> name)) { return bp; } } } return (struct binding *)0; } int free_bindings (struct binding_scope *scope, const char *file, int line) { struct binding *bp, *next; for (bp = scope -> bindings; bp; bp = next) { next = bp -> next; if (bp -> name) dfree (bp -> name, file, line); if (bp -> value) binding_value_dereference (&bp -> value, file, line); dfree (bp, file, line); } scope -> bindings = (struct binding *)0; return 1; } int binding_scope_dereference (ptr, file, line) struct binding_scope **ptr; const char *file; int line; { struct binding_scope *binding_scope; if (!ptr || !*ptr) { log_error ("%s(%d): null pointer", file, line); #if defined (POINTER_DEBUG) abort (); #else return 0; #endif } binding_scope = *ptr; *ptr = (struct binding_scope *)0; --binding_scope -> refcnt; rc_register (file, line, ptr, binding_scope, binding_scope -> refcnt, 1, RC_MISC); if (binding_scope -> refcnt > 0) return 1; if (binding_scope -> refcnt < 0) { log_error ("%s(%d): negative refcnt!", file, line); #if defined (DEBUG_RC_HISTORY) dump_rc_history (binding_scope); #endif #if defined (POINTER_DEBUG) abort (); #else return 0; #endif } free_bindings (binding_scope, file, line); if (binding_scope -> outer) binding_scope_dereference (&binding_scope -> outer, MDL); dfree (binding_scope, file, line); return 1; } int fundef_dereference (ptr, file, line) struct fundef **ptr; const char *file; int line; { struct fundef *bp; struct string_list *sp, *next; if ((ptr == NULL) || (*ptr == NULL)) { log_error ("%s(%d): null pointer", file, line); #if defined (POINTER_DEBUG) abort (); #else return 0; #endif } bp = *ptr; bp -> refcnt--; rc_register (file, line, ptr, bp, bp -> refcnt, 1, RC_MISC); if (bp -> refcnt < 0) { log_error ("%s(%d): negative refcnt!", file, line); #if defined (DEBUG_RC_HISTORY) dump_rc_history (bp); #endif #if defined (POINTER_DEBUG) abort (); #else return 0; #endif } if (!bp -> refcnt) { for (sp = bp -> args; sp; sp = next) { next = sp -> next; dfree (sp, file, line); } if (bp -> statements) executable_statement_dereference (&bp -> statements, file, line); dfree (bp, file, line); } *ptr = (struct fundef *)0; return 1; } #if defined (NOTYET) /* Post 3.0 final. */ int data_subexpression_length (int *rv, struct expression *expr) { int crhs, clhs, llhs, lrhs; switch (expr -> op) { case expr_substring: if (expr -> data.substring.len && expr -> data.substring.len -> op == expr_const_int) { (*rv = (int)expr -> data.substring.len -> data.const_int); return 1; } return 0; case expr_packet: case expr_suffix: if (expr -> data.suffix.len && expr -> data.suffix.len -> op == expr_const_int) { (*rv = (int)expr -> data.suffix.len -> data.const_int); return 1; } return 0; case expr_lcase: return data_subexpression_length(rv, expr->data.lcase); case expr_ucase: return data_subexpression_length(rv, expr->data.ucase); case expr_concat: clhs = data_subexpression_length (&llhs, expr -> data.concat [0]); crhs = data_subexpression_length (&lrhs, expr -> data.concat [1]); if (crhs == 0 || clhs == 0) return 0; *rv = llhs + lrhs; return 1; break; case expr_hardware: return 0; case expr_const_data: *rv = expr -> data.const_data.len; return 2; case expr_reverse: return data_subexpression_length (rv, expr -> data.reverse.buffer); case expr_leased_address: case expr_lease_time: *rv = 4; return 2; case expr_pick_first_value: clhs = data_subexpression_length (&llhs, expr -> data.concat [0]); crhs = data_subexpression_length (&lrhs, expr -> data.concat [1]); if (crhs == 0 || clhs == 0) return 0; if (llhs > lrhs) *rv = llhs; else *rv = lrhs; return 1; case expr_v6relay: clhs = data_subexpression_length (&llhs, expr -> data.v6relay.relay); crhs = data_subexpression_length (&lrhs, expr -> data.v6relay.roption); if (crhs == 0 || clhs == 0) return 0; *rv = llhs + lrhs; return 1; break; case expr_binary_to_ascii: case expr_config_option: case expr_host_decl_name: case expr_encapsulate: case expr_filename: case expr_sname: case expr_host_lookup: case expr_option: case expr_none: case expr_match: case expr_check: case expr_equal: case expr_regex_match: case expr_iregex_match: case expr_and: case expr_or: case expr_not: case expr_extract_int8: case expr_extract_int16: case expr_extract_int32: case expr_encode_int8: case expr_encode_int16: case expr_encode_int32: case expr_const_int: case expr_exists: case expr_known: case expr_static: case expr_not_equal: case expr_null: case expr_variable_exists: case expr_variable_reference: case expr_arg: case expr_funcall: case expr_function: case expr_add: case expr_subtract: case expr_multiply: case expr_divide: case expr_remainder: case expr_binary_and: case expr_binary_or: case expr_binary_xor: case expr_client_state: case expr_gethostname: return 0; } return 0; } int expr_valid_for_context (struct expression *expr, enum expression_context context) { /* We don't know at parse time what type of value a function may return, so we can't flag an error on it. */ if (expr -> op == expr_funcall || expr -> op == expr_variable_reference) return 1; switch (context) { case context_any: return 1; case context_boolean: if (is_boolean_expression (expr)) return 1; return 0; case context_data: if (is_data_expression (expr)) return 1; return 0; case context_numeric: if (is_numeric_expression (expr)) return 1; return 0; case context_data_or_numeric: if (is_numeric_expression (expr) || is_data_expression (expr)) { return 1; } return 0; case context_function: if (expr -> op == expr_function) return 1; return 0; } return 0; } #endif /* NOTYET */ struct binding *create_binding (struct binding_scope **scope, const char *name) { struct binding *binding; if (!*scope) { if (!binding_scope_allocate (scope, MDL)) return (struct binding *)0; } binding = find_binding (*scope, name); if (!binding) { binding = dmalloc (sizeof *binding, MDL); if (!binding) return (struct binding *)0; memset (binding, 0, sizeof *binding); binding -> name = dmalloc (strlen (name) + 1, MDL); if (!binding -> name) { dfree (binding, MDL); return (struct binding *)0; } strcpy (binding -> name, name); binding -> next = (*scope) -> bindings; (*scope) -> bindings = binding; } return binding; } int bind_ds_value (struct binding_scope **scope, const char *name, struct data_string *value) { struct binding *binding; binding = create_binding (scope, name); if (!binding) return 0; if (binding -> value) binding_value_dereference (&binding -> value, MDL); if (!binding_value_allocate (&binding -> value, MDL)) return 0; data_string_copy (&binding -> value -> value.data, value, MDL); binding -> value -> type = binding_data; return 1; } int find_bound_string (struct data_string *value, struct binding_scope *scope, const char *name) { struct binding *binding; binding = find_binding (scope, name); if (!binding || !binding -> value || binding -> value -> type != binding_data) return 0; if (binding -> value -> value.data.terminated) { data_string_copy (value, &binding -> value -> value.data, MDL); } else { if (buffer_allocate (&value->buffer, binding->value->value.data.len, MDL) == 0) { return 0; } memcpy (value -> buffer -> data, binding -> value -> value.data.data, binding -> value -> value.data.len); value -> data = value -> buffer -> data; value -> len = binding -> value -> value.data.len; } return 1; } int unset (struct binding_scope *scope, const char *name) { struct binding *binding; binding = find_binding (scope, name); if (binding) { if (binding -> value) binding_value_dereference (&binding -> value, MDL); return 1; } return 0; } /*! * \brief Adds two Dc-formatted lists into a single Dc-formatted list * * Given two data_strings containing compressed lists, it constructs a * third data_string containing a single compressed list: * * 1. Decompressing the first list into a buffer * 2. Decompressing the second list onto the end of the buffer * 3. Compressing the buffer into the result * * If either list is empty, the result will be the equal to the compressed * content of the non-empty list. If both lists are empty, the result will * be an "empty" list: a 1 byte buffer containing 0x00. * * It relies on two functions to decompress and compress: * * - MRns_name_uncompress_list() - produces a null-terminated string of * comma-separated domain-names from a buffer containing "Dc" formatted * data * * - MRns_name_compress_list() - produces a buffer containing "Dc" formatted * data from a null-terminated string containing comma-separated domain-names * * \param result data_string which will contain the combined list * in Dc format * \param list1 data_string containing first Dc formatted list * \param list2 data_string containing second Dc formatted list * \return 0 if there is an error, the length of the new list when successful */ int concat_dclists (struct data_string* result, struct data_string* list1, struct data_string* list2) { char uncompbuf[32*NS_MAXCDNAME]; char *uncomp = uncompbuf; int uncomp_len = 0; int compbuf_max = 0; int list_len = 0; int i; /* If not empty, uncompress first list into the uncompressed buffer */ if (list1 && (list1->data) && (list1->len)) { list_len = MRns_name_uncompress_list(list1->data, list1->len, uncomp, sizeof(uncompbuf)); if (list_len < 0) { log_error ("concat_dclists:" " error decompressing domain list 1"); return (0); } uncomp_len = list_len; uncomp += list_len; } /* If not empty, uncompress second list into the uncompressed buffer */ if (list2 && (list2->data) && (list2->len)) { /* If first list wasn't empty, add a comma */ if (uncomp_len > 0) { *uncomp++ = ','; uncomp_len++; } list_len = MRns_name_uncompress_list(list2->data, list2->len, uncomp, (sizeof(uncompbuf) - uncomp_len)); if (list_len < 0) { log_error ("concat_dclists:" " error decompressing domain list 2"); return (0); } uncomp_len += list_len; uncomp += list_len; } /* If both lists were empty, return an "empty" result */ if (uncomp_len == 0) { if (!buffer_allocate (&result->buffer, 1, MDL)) { log_error ("concat_dclists: empty list allocate fail"); result->len = 0; return (0); } result->len = 1; result->data = result->buffer->data; return (1); } /* Estimate the buffer size needed for decompression. The largest * decompression would if one where there are no repeated portions, * (i.e. no compressions). Therefore that size should be the * decompressed string length + 2 for each comma + a final null. Each * dot gets replaced with a length byte and is accounted for in string * length. Mininum length is * uncomp_len + 3. */ compbuf_max = uncomp_len + 3; uncomp = uncompbuf; for (i = 0; i < uncomp_len; i++) if (*uncomp++ == ',') compbuf_max += 2; /* Allocate compression buffer based on estimated max */ if (!buffer_allocate (&result->buffer, compbuf_max, MDL)) { log_error ("concat_dclists: No memory for result"); result->len = 0; return (0); } /* Compress the combined list into result */ list_len = MRns_name_compress_list(uncompbuf, uncomp_len, result->buffer->data, compbuf_max); if (list_len <= 0) { log_error ("concat_dlists: error compressing result"); data_string_forget(result, MDL); result->len = 0; return (0); } /* Update result length to actual size */ result->len = list_len; result->data = result->buffer->data; return (list_len); } /* vim: set tabstop=8: */