/* * Filters: utility functions * * Copyright 1998 Pavel Machek * * Can be freely distributed and used under the terms of the GNU GPL. * */ /** * DOC: Filters * * You can find sources of the filter language in |filter/| * directory. File |filter/config.Y| contains filter grammar and basically translates * the source from user into a tree of &f_inst structures. These trees are * later interpreted using code in |filter/filter.c|. * * A filter is represented by a tree of &f_inst structures, one structure per * "instruction". Each &f_inst contains @code, @aux value which is * usually the data type this instruction operates on and two generic * arguments (@a1, @a2). Some instructions contain pointer(s) to other * instructions in their (@a1, @a2) fields. * * Filters use a &f_val structure for their data. Each &f_val * contains type and value (types are constants prefixed with %T_). Few * of the types are special; %T_RETURN can be or-ed with a type to indicate * that return from a function or from the whole filter should be * forced. Important thing about &f_val's is that they may be copied * with a simple |=|. That's fine for all currently defined types: strings * are read-only (and therefore okay), paths are copied for each * operation (okay too). */ #undef LOCAL_DEBUG #include "nest/bird.h" #include "lib/lists.h" #include "lib/resource.h" #include "lib/socket.h" #include "lib/string.h" #include "lib/unaligned.h" #include "lib/net.h" #include "lib/ip.h" #include "nest/route.h" #include "nest/protocol.h" #include "nest/iface.h" #include "nest/attrs.h" #include "conf/conf.h" #include "filter/filter.h" #define CMP_ERROR 999 #define FILTER_STACK_DEPTH 16384 /* Filter interpreter stack. Make this thread local after going parallel. */ struct filter_stack { struct f_val val; }; static struct filter_stack filter_stack[FILTER_STACK_DEPTH]; /* Internal filter state, to be allocated on stack when executing filters */ struct filter_state { struct rte **rte; struct rta *old_rta; struct ea_list **eattrs; struct linpool *pool; struct buffer buf; struct filter_stack *stack; int stack_ptr; int flags; }; void (*bt_assert_hook)(int result, struct f_inst *assert); static struct adata undef_adata; /* adata of length 0 used for undefined */ /* Special undef value for paths and clists */ static inline int undef_value(struct f_val v) { return ((v.type == T_PATH) || (v.type == T_CLIST) || (v.type == T_ECLIST) || (v.type == T_LCLIST)) && (v.val.ad == &undef_adata); } static struct adata * adata_empty(struct linpool *pool, int l) { struct adata *res = lp_alloc(pool, sizeof(struct adata) + l); res->length = l; return res; } static void pm_format(struct f_path_mask *p, buffer *buf) { buffer_puts(buf, "[= "); while (p) { switch(p->kind) { case PM_ASN: buffer_print(buf, "%u ", p->val); break; case PM_QUESTION: buffer_puts(buf, "? "); break; case PM_ASTERISK: buffer_puts(buf, "* "); break; case PM_ASN_RANGE: buffer_print(buf, "%u..%u ", p->val, p->val2); break; case PM_ASN_EXPR: ASSERT(0); } p = p->next; } buffer_puts(buf, "=]"); } static inline int val_is_ip4(const struct f_val v) { return (v.type == T_IP) && ipa_is_ip4(v.val.ip); } static inline int lcomm_cmp(lcomm v1, lcomm v2) { if (v1.asn != v2.asn) return (v1.asn > v2.asn) ? 1 : -1; if (v1.ldp1 != v2.ldp1) return (v1.ldp1 > v2.ldp1) ? 1 : -1; if (v1.ldp2 != v2.ldp2) return (v1.ldp2 > v2.ldp2) ? 1 : -1; return 0; } /** * val_compare - compare two values * @v1: first value * @v2: second value * * Compares two values and returns -1, 0, 1 on <, =, > or CMP_ERROR on * error. Tree module relies on this giving consistent results so * that it can be used for building balanced trees. */ int val_compare(struct f_val v1, struct f_val v2) { if (v1.type != v2.type) { if (v1.type == T_VOID) /* Hack for else */ return -1; if (v2.type == T_VOID) return 1; /* IP->Quad implicit conversion */ if ((v1.type == T_QUAD) && val_is_ip4(v2)) return uint_cmp(v1.val.i, ipa_to_u32(v2.val.ip)); if (val_is_ip4(v1) && (v2.type == T_QUAD)) return uint_cmp(ipa_to_u32(v1.val.ip), v2.val.i); debug( "Types do not match in val_compare\n" ); return CMP_ERROR; } switch (v1.type) { case T_VOID: return 0; case T_ENUM: case T_INT: case T_BOOL: case T_PAIR: case T_QUAD: return uint_cmp(v1.val.i, v2.val.i); case T_EC: case T_RD: return u64_cmp(v1.val.ec, v2.val.ec); case T_LC: return lcomm_cmp(v1.val.lc, v2.val.lc); case T_IP: return ipa_compare(v1.val.ip, v2.val.ip); case T_NET: return net_compare(v1.val.net, v2.val.net); case T_STRING: return strcmp(v1.val.s, v2.val.s); default: return CMP_ERROR; } } static int pm_same(struct f_path_mask *m1, struct f_path_mask *m2) { while (m1 && m2) { if (m1->kind != m2->kind) return 0; if (m1->kind == PM_ASN_EXPR) { if (!i_same((struct f_inst *) m1->val, (struct f_inst *) m2->val)) return 0; } else { if ((m1->val != m2->val) || (m1->val2 != m2->val2)) return 0; } m1 = m1->next; m2 = m2->next; } return !m1 && !m2; } /** * val_same - compare two values * @v1: first value * @v2: second value * * Compares two values and returns 1 if they are same and 0 if not. * Comparison of values of different types is valid and returns 0. */ int val_same(struct f_val v1, struct f_val v2) { int rc; rc = val_compare(v1, v2); if (rc != CMP_ERROR) return !rc; if (v1.type != v2.type) return 0; switch (v1.type) { case T_PATH_MASK: return pm_same(v1.val.path_mask, v2.val.path_mask); case T_PATH: case T_CLIST: case T_ECLIST: case T_LCLIST: return adata_same(v1.val.ad, v2.val.ad); case T_SET: return same_tree(v1.val.t, v2.val.t); case T_PREFIX_SET: return trie_same(v1.val.ti, v2.val.ti); default: bug("Invalid type in val_same(): %x", v1.type); } } static int clist_set_type(struct f_tree *set, struct f_val *v) { switch (set->from.type) { case T_PAIR: v->type = T_PAIR; return 1; case T_QUAD: v->type = T_QUAD; return 1; case T_IP: if (val_is_ip4(set->from) && val_is_ip4(set->to)) { v->type = T_QUAD; return 1; } /* Fall through */ default: v->type = T_VOID; return 0; } } static inline int eclist_set_type(struct f_tree *set) { return set->from.type == T_EC; } static inline int lclist_set_type(struct f_tree *set) { return set->from.type == T_LC; } static int clist_match_set(struct adata *clist, struct f_tree *set) { if (!clist) return 0; struct f_val v; if (!clist_set_type(set, &v)) return CMP_ERROR; u32 *l = (u32 *) clist->data; u32 *end = l + clist->length/4; while (l < end) { v.val.i = *l++; if (find_tree(set, v)) return 1; } return 0; } static int eclist_match_set(struct adata *list, struct f_tree *set) { if (!list) return 0; if (!eclist_set_type(set)) return CMP_ERROR; struct f_val v; u32 *l = int_set_get_data(list); int len = int_set_get_size(list); int i; v.type = T_EC; for (i = 0; i < len; i += 2) { v.val.ec = ec_get(l, i); if (find_tree(set, v)) return 1; } return 0; } static int lclist_match_set(struct adata *list, struct f_tree *set) { if (!list) return 0; if (!lclist_set_type(set)) return CMP_ERROR; struct f_val v; u32 *l = int_set_get_data(list); int len = int_set_get_size(list); int i; v.type = T_LC; for (i = 0; i < len; i += 3) { v.val.lc = lc_get(l, i); if (find_tree(set, v)) return 1; } return 0; } static struct adata * clist_filter(struct linpool *pool, struct adata *list, struct f_val set, int pos) { if (!list) return NULL; int tree = (set.type == T_SET); /* 1 -> set is T_SET, 0 -> set is T_CLIST */ struct f_val v; if (tree) clist_set_type(set.val.t, &v); else v.type = T_PAIR; int len = int_set_get_size(list); u32 *l = int_set_get_data(list); u32 tmp[len]; u32 *k = tmp; u32 *end = l + len; while (l < end) { v.val.i = *l++; /* pos && member(val, set) || !pos && !member(val, set), member() depends on tree */ if ((tree ? !!find_tree(set.val.t, v) : int_set_contains(set.val.ad, v.val.i)) == pos) *k++ = v.val.i; } uint nl = (k - tmp) * sizeof(u32); if (nl == list->length) return list; struct adata *res = adata_empty(pool, nl); memcpy(res->data, tmp, nl); return res; } static struct adata * eclist_filter(struct linpool *pool, struct adata *list, struct f_val set, int pos) { if (!list) return NULL; int tree = (set.type == T_SET); /* 1 -> set is T_SET, 0 -> set is T_CLIST */ struct f_val v; int len = int_set_get_size(list); u32 *l = int_set_get_data(list); u32 tmp[len]; u32 *k = tmp; int i; v.type = T_EC; for (i = 0; i < len; i += 2) { v.val.ec = ec_get(l, i); /* pos && member(val, set) || !pos && !member(val, set), member() depends on tree */ if ((tree ? !!find_tree(set.val.t, v) : ec_set_contains(set.val.ad, v.val.ec)) == pos) { *k++ = l[i]; *k++ = l[i+1]; } } uint nl = (k - tmp) * sizeof(u32); if (nl == list->length) return list; struct adata *res = adata_empty(pool, nl); memcpy(res->data, tmp, nl); return res; } static struct adata * lclist_filter(struct linpool *pool, struct adata *list, struct f_val set, int pos) { if (!list) return NULL; int tree = (set.type == T_SET); /* 1 -> set is T_SET, 0 -> set is T_CLIST */ struct f_val v; int len = int_set_get_size(list); u32 *l = int_set_get_data(list); u32 tmp[len]; u32 *k = tmp; int i; v.type = T_LC; for (i = 0; i < len; i += 3) { v.val.lc = lc_get(l, i); /* pos && member(val, set) || !pos && !member(val, set), member() depends on tree */ if ((tree ? !!find_tree(set.val.t, v) : lc_set_contains(set.val.ad, v.val.lc)) == pos) k = lc_copy(k, l+i); } uint nl = (k - tmp) * sizeof(u32); if (nl == list->length) return list; struct adata *res = adata_empty(pool, nl); memcpy(res->data, tmp, nl); return res; } /** * val_in_range - implement |~| operator * @v1: element * @v2: set * * Checks if @v1 is element (|~| operator) of @v2. */ static int val_in_range(struct f_val v1, struct f_val v2) { if ((v1.type == T_PATH) && (v2.type == T_PATH_MASK)) return as_path_match(v1.val.ad, v2.val.path_mask); if ((v1.type == T_INT) && (v2.type == T_PATH)) return as_path_contains(v2.val.ad, v1.val.i, 1); if (((v1.type == T_PAIR) || (v1.type == T_QUAD)) && (v2.type == T_CLIST)) return int_set_contains(v2.val.ad, v1.val.i); /* IP->Quad implicit conversion */ if (val_is_ip4(v1) && (v2.type == T_CLIST)) return int_set_contains(v2.val.ad, ipa_to_u32(v1.val.ip)); if ((v1.type == T_EC) && (v2.type == T_ECLIST)) return ec_set_contains(v2.val.ad, v1.val.ec); if ((v1.type == T_LC) && (v2.type == T_LCLIST)) return lc_set_contains(v2.val.ad, v1.val.lc); if ((v1.type == T_STRING) && (v2.type == T_STRING)) return patmatch(v2.val.s, v1.val.s); if ((v1.type == T_IP) && (v2.type == T_NET)) return ipa_in_netX(v1.val.ip, v2.val.net); if ((v1.type == T_NET) && (v2.type == T_NET)) return net_in_netX(v1.val.net, v2.val.net); if ((v1.type == T_NET) && (v2.type == T_PREFIX_SET)) return trie_match_net(v2.val.ti, v1.val.net); if (v2.type != T_SET) return CMP_ERROR; /* With integrated Quad<->IP implicit conversion */ if ((v1.type == v2.val.t->from.type) || ((v1.type == T_QUAD) && val_is_ip4(v2.val.t->from) && val_is_ip4(v2.val.t->to))) return !!find_tree(v2.val.t, v1); if (v1.type == T_CLIST) return clist_match_set(v1.val.ad, v2.val.t); if (v1.type == T_ECLIST) return eclist_match_set(v1.val.ad, v2.val.t); if (v1.type == T_LCLIST) return lclist_match_set(v1.val.ad, v2.val.t); if (v1.type == T_PATH) return as_path_match_set(v1.val.ad, v2.val.t); return CMP_ERROR; } /* * val_format - format filter value */ void val_format(struct f_val v, buffer *buf) { char buf2[1024]; switch (v.type) { case T_VOID: buffer_puts(buf, "(void)"); return; case T_BOOL: buffer_puts(buf, v.val.i ? "TRUE" : "FALSE"); return; case T_INT: buffer_print(buf, "%u", v.val.i); return; case T_STRING: buffer_print(buf, "%s", v.val.s); return; case T_IP: buffer_print(buf, "%I", v.val.ip); return; case T_NET: buffer_print(buf, "%N", v.val.net); return; case T_PAIR: buffer_print(buf, "(%u,%u)", v.val.i >> 16, v.val.i & 0xffff); return; case T_QUAD: buffer_print(buf, "%R", v.val.i); return; case T_EC: ec_format(buf2, v.val.ec); buffer_print(buf, "%s", buf2); return; case T_LC: lc_format(buf2, v.val.lc); buffer_print(buf, "%s", buf2); return; case T_RD: rd_format(v.val.ec, buf2, 1024); buffer_print(buf, "%s", buf2); return; case T_PREFIX_SET: trie_format(v.val.ti, buf); return; case T_SET: tree_format(v.val.t, buf); return; case T_ENUM: buffer_print(buf, "(enum %x)%u", v.type, v.val.i); return; case T_PATH: as_path_format(v.val.ad, buf2, 1000); buffer_print(buf, "(path %s)", buf2); return; case T_CLIST: int_set_format(v.val.ad, 1, -1, buf2, 1000); buffer_print(buf, "(clist %s)", buf2); return; case T_ECLIST: ec_set_format(v.val.ad, -1, buf2, 1000); buffer_print(buf, "(eclist %s)", buf2); return; case T_LCLIST: lc_set_format(v.val.ad, -1, buf2, 1000); buffer_print(buf, "(lclist %s)", buf2); return; case T_PATH_MASK: pm_format(v.val.path_mask, buf); return; default: buffer_print(buf, "[unknown type %x]", v.type); return; } } static inline void f_cache_eattrs(struct filter_state *fs) { fs->eattrs = &((*fs->rte)->attrs->eattrs); } static inline void f_rte_cow(struct filter_state *fs) { if (!((*fs->rte)->flags & REF_COW)) return; *fs->rte = rte_cow(*fs->rte); } /* * rta_cow - prepare rta for modification by filter */ static void f_rta_cow(struct filter_state *fs) { if (!rta_is_cached((*fs->rte)->attrs)) return; /* Prepare to modify rte */ f_rte_cow(fs); /* Store old rta to free it later, it stores reference from rte_cow() */ fs->old_rta = (*fs->rte)->attrs; /* * Get shallow copy of rta. Fields eattrs and nexthops of rta are shared * with fs->old_rta (they will be copied when the cached rta will be obtained * at the end of f_run()), also the lock of hostentry is inherited (we * suppose hostentry is not changed by filters). */ (*fs->rte)->attrs = rta_do_cow((*fs->rte)->attrs, fs->pool); /* Re-cache the ea_list */ f_cache_eattrs(fs); } static char * val_format_str(struct filter_state *fs, struct f_val v) { buffer b; LOG_BUFFER_INIT(b); val_format(v, &b); return lp_strdup(fs->pool, b.start); } static struct tbf rl_runtime_err = TBF_DEFAULT_LOG_LIMITS; /** * interpret * @fs: filter state * @what: filter to interpret * * Interpret given tree of filter instructions. This is core function * of filter system and does all the hard work. * * Each instruction has 4 fields: code (which is instruction code), * aux (which is extension to instruction code, typically type), * arg1 and arg2 - arguments. Depending on instruction, arguments * are either integers, or pointers to instruction trees. Common * instructions like +, that have two expressions as arguments use * TWOARGS macro to get both of them evaluated. */ static enum filter_return interpret(struct filter_state *fs, struct f_inst *what) { struct symbol *sym; struct f_val *vp; unsigned u1, u2; enum filter_return fret; int i; u32 as; #define res fs->stack[fs->stack_ptr].val #define v0 res #define v1 fs->stack[fs->stack_ptr + 1].val #define v2 fs->stack[fs->stack_ptr + 2].val #define v3 fs->stack[fs->stack_ptr + 3].val res = (struct f_val) { .type = T_VOID }; for ( ; what; what = what->next) { res = (struct f_val) { .type = T_VOID }; switch (what->fi_code) { #define runtime(fmt, ...) do { \ if (!(fs->flags & FF_SILENT)) \ log_rl(&rl_runtime_err, L_ERR "filters, line %d: " fmt, what->lineno, ##__VA_ARGS__); \ return F_ERROR; \ } while(0) #define ARG_ANY_T(n, tt) INTERPRET(what->a##n.p, tt) #define ARG_ANY(n) ARG_ANY_T(n, n) #define ARG_T(n,tt,t) do { \ ARG_ANY_T(n,tt); \ if (v##tt.type != t) \ runtime("Argument %d of instruction %s must be of type %02x, got %02x", \ n, f_instruction_name(what->fi_code), t, v##tt.type); \ } while (0) #define ARG(n,t) ARG_T(n,n,t) #define INTERPRET(what_, n) do { \ fs->stack_ptr += n; \ fret = interpret(fs, what_); \ fs->stack_ptr -= n; \ if (fret == F_RETURN) \ bug("This shall not happen"); \ if (fret > F_RETURN) \ return fret; \ } while (0) #define ACCESS_RTE do { if (!fs->rte) runtime("No route to access"); } while (0) #define ACCESS_EATTRS do { if (!fs->eattrs) f_cache_eattrs(fs); } while (0) #define BITFIELD_MASK(what_) (1u << EA_BIT_GET(what_->a2.i)) #include "filter/f-inst.c" #undef res #undef runtime #undef ARG_ANY #undef ARG #undef INTERPRET #undef ACCESS_RTE #undef ACCESS_EATTRS } } return F_NOP; } #define ARG(n) \ if (!i_same(f1->a##n.p, f2->a##n.p)) \ return 0; #define ONEARG ARG(1); #define TWOARGS ONEARG; ARG(2); #define THREEARGS TWOARGS; ARG(3); #define A2_SAME if (f1->a2.i != f2->a2.i) return 0; /* * i_same - function that does real comparing of instruction trees, you should call filter_same from outside */ int i_same(struct f_inst *f1, struct f_inst *f2) { if ((!!f1) != (!!f2)) return 0; if (!f1) return 1; if (f1->aux != f2->aux) return 0; if (f1->fi_code != f2->fi_code) return 0; if (f1 == f2) /* It looks strange, but it is possible with call rewriting trickery */ return 1; switch(f1->fi_code) { case FI_ADD: /* fall through */ case FI_SUBTRACT: case FI_MULTIPLY: case FI_DIVIDE: case FI_OR: case FI_AND: case FI_PAIR_CONSTRUCT: case FI_EC_CONSTRUCT: case FI_NEQ: case FI_EQ: case FI_LT: case FI_LTE: TWOARGS; break; case FI_PATHMASK_CONSTRUCT: if (!pm_same(f1->a1.p, f2->a1.p)) return 0; break; case FI_NOT: ONEARG; break; case FI_NOT_MATCH: case FI_MATCH: TWOARGS; break; case FI_DEFINED: ONEARG; break; case FI_TYPE: ONEARG; break; case FI_LC_CONSTRUCT: THREEARGS; break; case FI_SET: ARG(2); { struct symbol *s1, *s2; s1 = f1->a1.p; s2 = f2->a1.p; if (strcmp(s1->name, s2->name)) return 0; if (s1->class != s2->class) return 0; } break; case FI_CONSTANT: switch (f1->aux) { case T_PREFIX_SET: if (!trie_same(f1->a2.p, f2->a2.p)) return 0; break; case T_SET: if (!same_tree(f1->a2.p, f2->a2.p)) return 0; break; case T_STRING: if (strcmp(f1->a2.p, f2->a2.p)) return 0; break; default: A2_SAME; } break; case FI_CONSTANT_INDIRECT: if (!val_same(* (struct f_val *) f1->a1.p, * (struct f_val *) f2->a1.p)) return 0; break; case FI_VARIABLE: if (strcmp((char *) f1->a2.p, (char *) f2->a2.p)) return 0; break; case FI_PRINT: case FI_LENGTH: ONEARG; break; case FI_CONDITION: THREEARGS; break; case FI_NOP: case FI_EMPTY: break; case FI_PRINT_AND_DIE: ONEARG; A2_SAME; break; case FI_PREF_GET: case FI_RTA_GET: A2_SAME; break; case FI_EA_GET: A2_SAME; break; case FI_PREF_SET: case FI_RTA_SET: case FI_EA_SET: ONEARG; A2_SAME; break; case FI_RETURN: ONEARG; break; case FI_ROA_MAXLEN: ONEARG; break; case FI_ROA_ASN: ONEARG; break; case FI_SADR_SRC: ONEARG; break; case FI_IP: ONEARG; break; case FI_IS_V4: ONEARG; break; case FI_ROUTE_DISTINGUISHER: ONEARG; break; case FI_CALL: /* Call rewriting trickery to avoid exponential behaviour */ ONEARG; if (!i_same(f1->a2.p, f2->a2.p)) return 0; f2->a2.p = f1->a2.p; break; case FI_CLEAR_LOCAL_VARS: break; /* internal instruction */ case FI_SWITCH: ONEARG; if (!same_tree(f1->a2.p, f2->a2.p)) return 0; break; case FI_IP_MASK: TWOARGS; break; case FI_PATH_PREPEND: TWOARGS; break; case FI_CLIST_ADD_DEL: TWOARGS; break; case FI_AS_PATH_FIRST: case FI_AS_PATH_LAST: case FI_AS_PATH_LAST_NAG: ONEARG; break; case FI_ROA_CHECK: TWOARGS; /* Does not really make sense - ROA check results may change anyway */ if (strcmp(((struct f_inst_roa_check *) f1)->rtc->name, ((struct f_inst_roa_check *) f2)->rtc->name)) return 0; break; case FI_FORMAT: ONEARG; break; case FI_ASSERT: ONEARG; break; default: bug( "Unknown instruction %d in same (%c)", f1->fi_code, f1->fi_code & 0xff); } return i_same(f1->next, f2->next); } /** * f_run - run a filter for a route * @filter: filter to run * @rte: route being filtered, may be modified * @tmp_pool: all filter allocations go from this pool * @flags: flags * * If filter needs to modify the route, there are several * posibilities. @rte might be read-only (with REF_COW flag), in that * case rw copy is obtained by rte_cow() and @rte is replaced. If * @rte is originally rw, it may be directly modified (and it is never * copied). * * The returned rte may reuse the (possibly cached, cloned) rta, or * (if rta was modificied) contains a modified uncached rta, which * uses parts allocated from @tmp_pool and parts shared from original * rta. There is one exception - if @rte is rw but contains a cached * rta and that is modified, rta in returned rte is also cached. * * Ownership of cached rtas is consistent with rte, i.e. * if a new rte is returned, it has its own clone of cached rta * (and cached rta of read-only source rte is intact), if rte is * modified in place, old cached rta is possibly freed. */ enum filter_return f_run(struct filter *filter, struct rte **rte, struct linpool *tmp_pool, int flags) { if (filter == FILTER_ACCEPT) return F_ACCEPT; if (filter == FILTER_REJECT) return F_REJECT; int rte_cow = ((*rte)->flags & REF_COW); DBG( "Running filter `%s'...", filter->name ); struct filter_state fs = { .rte = rte, .pool = tmp_pool, .flags = flags, .stack = filter_stack, }; LOG_BUFFER_INIT(fs.buf); enum filter_return fret = interpret(&fs, filter->root); if (fs.old_rta) { /* * Cached rta was modified and fs->rte contains now an uncached one, * sharing some part with the cached one. The cached rta should * be freed (if rte was originally COW, fs->old_rta is a clone * obtained during rte_cow()). * * This also implements the exception mentioned in f_run() * description. The reason for this is that rta reuses parts of * fs->old_rta, and these may be freed during rta_free(fs->old_rta). * This is not the problem if rte was COW, because original rte * also holds the same rta. */ if (!rte_cow) (*fs.rte)->attrs = rta_lookup((*fs.rte)->attrs); rta_free(fs.old_rta); } if (fret < F_ACCEPT) { if (!(fs.flags & FF_SILENT)) log_rl(&rl_runtime_err, L_ERR "Filter %s did not return accept nor reject. Make up your mind", filter->name); return F_ERROR; } DBG( "done (%u)\n", res.val.i ); return fret; } /* TODO: perhaps we could integrate f_eval(), f_eval_rte() and f_run() */ enum filter_return f_eval_rte(struct f_inst *expr, struct rte **rte, struct linpool *tmp_pool) { struct filter_state fs = { .rte = rte, .pool = tmp_pool, .stack = filter_stack, }; LOG_BUFFER_INIT(fs.buf); /* Note that in this function we assume that rte->attrs is private / uncached */ return interpret(&fs, expr); } enum filter_return f_eval(struct f_inst *expr, struct linpool *tmp_pool, struct f_val *pres) { struct filter_state fs = { .pool = tmp_pool, .stack = filter_stack, }; LOG_BUFFER_INIT(fs.buf); enum filter_return fret = interpret(&fs, expr); *pres = filter_stack[0].val; return fret; } uint f_eval_int(struct f_inst *expr) { /* Called independently in parse-time to eval expressions */ struct filter_state fs = { .pool = cfg_mem, .stack = filter_stack, }; LOG_BUFFER_INIT(fs.buf); if (interpret(&fs, expr) > F_RETURN) cf_error("Runtime error while evaluating expression"); if (filter_stack[0].val.type != T_INT) cf_error("Integer expression expected"); return filter_stack[0].val.val.i; } /** * filter_same - compare two filters * @new: first filter to be compared * @old: second filter to be compared, notice that this filter is * damaged while comparing. * * Returns 1 in case filters are same, otherwise 0. If there are * underlying bugs, it will rather say 0 on same filters than say * 1 on different. */ int filter_same(struct filter *new, struct filter *old) { if (old == new) /* Handle FILTER_ACCEPT and FILTER_REJECT */ return 1; if (old == FILTER_ACCEPT || old == FILTER_REJECT || new == FILTER_ACCEPT || new == FILTER_REJECT) return 0; return i_same(new->root, old->root); }