/* * Copyright (c) 2009, 2010, 2011, 2012, 2013 Nicira, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include "classifier.h" #include #include #include "byte-order.h" #include "dynamic-string.h" #include "flow.h" #include "hash.h" #include "odp-util.h" #include "ofp-util.h" #include "packets.h" static struct cls_table *find_table(const struct classifier *, const struct minimask *); static struct cls_table *insert_table(struct classifier *, const struct minimask *); static void destroy_table(struct classifier *, struct cls_table *); static void update_tables_after_insertion(struct classifier *, struct cls_table *, unsigned int new_priority); static void update_tables_after_removal(struct classifier *, struct cls_table *, unsigned int del_priority); static struct cls_rule *find_match(const struct cls_table *, const struct flow *); static struct cls_rule *find_equal(struct cls_table *, const struct miniflow *, uint32_t hash); static struct cls_rule *insert_rule(struct classifier *, struct cls_table *, struct cls_rule *); /* Iterates RULE over HEAD and all of the cls_rules on HEAD->list. */ #define FOR_EACH_RULE_IN_LIST(RULE, HEAD) \ for ((RULE) = (HEAD); (RULE) != NULL; (RULE) = next_rule_in_list(RULE)) #define FOR_EACH_RULE_IN_LIST_SAFE(RULE, NEXT, HEAD) \ for ((RULE) = (HEAD); \ (RULE) != NULL && ((NEXT) = next_rule_in_list(RULE), true); \ (RULE) = (NEXT)) static struct cls_rule *next_rule_in_list__(struct cls_rule *); static struct cls_rule *next_rule_in_list(struct cls_rule *); /* cls_rule. */ /* Initializes 'rule' to match packets specified by 'match' at the given * 'priority'. 'match' must satisfy the invariant described in the comment at * the definition of struct match. * * The caller must eventually destroy 'rule' with cls_rule_destroy(). * * (OpenFlow uses priorities between 0 and UINT16_MAX, inclusive, but * internally Open vSwitch supports a wider range.) */ void cls_rule_init(struct cls_rule *rule, const struct match *match, unsigned int priority) { minimatch_init(&rule->match, match); rule->priority = priority; } /* Same as cls_rule_init() for initialization from a "struct minimatch". */ void cls_rule_init_from_minimatch(struct cls_rule *rule, const struct minimatch *match, unsigned int priority) { minimatch_clone(&rule->match, match); rule->priority = priority; } /* Initializes 'dst' as a copy of 'src'. * * The caller must eventually destroy 'rule' with cls_rule_destroy(). */ void cls_rule_clone(struct cls_rule *dst, const struct cls_rule *src) { minimatch_clone(&dst->match, &src->match); dst->priority = src->priority; } /* Frees memory referenced by 'rule'. Doesn't free 'rule' itself (it's * normally embedded into a larger structure). * * ('rule' must not currently be in a classifier.) */ void cls_rule_destroy(struct cls_rule *rule) { minimatch_destroy(&rule->match); } /* Returns true if 'a' and 'b' match the same packets at the same priority, * false if they differ in some way. */ bool cls_rule_equal(const struct cls_rule *a, const struct cls_rule *b) { return a->priority == b->priority && minimatch_equal(&a->match, &b->match); } /* Returns a hash value for 'rule', folding in 'basis'. */ uint32_t cls_rule_hash(const struct cls_rule *rule, uint32_t basis) { return minimatch_hash(&rule->match, hash_int(rule->priority, basis)); } /* Appends a string describing 'rule' to 's'. */ void cls_rule_format(const struct cls_rule *rule, struct ds *s) { minimatch_format(&rule->match, s, rule->priority); } /* Returns true if 'rule' matches every packet, false otherwise. */ bool cls_rule_is_catchall(const struct cls_rule *rule) { return minimask_is_catchall(&rule->match.mask); } /* Initializes 'cls' as a classifier that initially contains no classification * rules. */ void classifier_init(struct classifier *cls) { cls->n_rules = 0; hmap_init(&cls->tables); list_init(&cls->tables_priority); } /* Destroys 'cls'. Rules within 'cls', if any, are not freed; this is the * caller's responsibility. */ void classifier_destroy(struct classifier *cls) { if (cls) { struct cls_table *table, *next_table; HMAP_FOR_EACH_SAFE (table, next_table, hmap_node, &cls->tables) { destroy_table(cls, table); } hmap_destroy(&cls->tables); } } /* Returns true if 'cls' contains no classification rules, false otherwise. */ bool classifier_is_empty(const struct classifier *cls) { return cls->n_rules == 0; } /* Returns the number of rules in 'cls'. */ int classifier_count(const struct classifier *cls) { return cls->n_rules; } /* Inserts 'rule' into 'cls'. Until 'rule' is removed from 'cls', the caller * must not modify or free it. * * If 'cls' already contains an identical rule (including wildcards, values of * fixed fields, and priority), replaces the old rule by 'rule' and returns the * rule that was replaced. The caller takes ownership of the returned rule and * is thus responsible for destroying it with cls_rule_destroy(), freeing the * memory block in which it resides, etc., as necessary. * * Returns NULL if 'cls' does not contain a rule with an identical key, after * inserting the new rule. In this case, no rules are displaced by the new * rule, even rules that cannot have any effect because the new rule matches a * superset of their flows and has higher priority. */ struct cls_rule * classifier_replace(struct classifier *cls, struct cls_rule *rule) { struct cls_rule *old_rule; struct cls_table *table; table = find_table(cls, &rule->match.mask); if (!table) { table = insert_table(cls, &rule->match.mask); } old_rule = insert_rule(cls, table, rule); if (!old_rule) { table->n_table_rules++; cls->n_rules++; } return old_rule; } /* Inserts 'rule' into 'cls'. Until 'rule' is removed from 'cls', the caller * must not modify or free it. * * 'cls' must not contain an identical rule (including wildcards, values of * fixed fields, and priority). Use classifier_find_rule_exactly() to find * such a rule. */ void classifier_insert(struct classifier *cls, struct cls_rule *rule) { struct cls_rule *displaced_rule = classifier_replace(cls, rule); ovs_assert(!displaced_rule); } /* Removes 'rule' from 'cls'. It is the caller's responsibility to destroy * 'rule' with cls_rule_destroy(), freeing the memory block in which 'rule' * resides, etc., as necessary. */ void classifier_remove(struct classifier *cls, struct cls_rule *rule) { struct cls_rule *head; struct cls_table *table; table = find_table(cls, &rule->match.mask); head = find_equal(table, &rule->match.flow, rule->hmap_node.hash); if (head != rule) { list_remove(&rule->list); } else if (list_is_empty(&rule->list)) { hmap_remove(&table->rules, &rule->hmap_node); } else { struct cls_rule *next = CONTAINER_OF(rule->list.next, struct cls_rule, list); list_remove(&rule->list); hmap_replace(&table->rules, &rule->hmap_node, &next->hmap_node); } if (--table->n_table_rules == 0) { destroy_table(cls, table); } else { update_tables_after_removal(cls, table, rule->priority); } cls->n_rules--; } /* Finds and returns the highest-priority rule in 'cls' that matches 'flow'. * Returns a null pointer if no rules in 'cls' match 'flow'. If multiple rules * of equal priority match 'flow', returns one arbitrarily. */ struct cls_rule * classifier_lookup(const struct classifier *cls, const struct flow *flow) { struct cls_table *table; struct cls_rule *best; best = NULL; LIST_FOR_EACH (table, list_node, &cls->tables_priority) { struct cls_rule *rule = find_match(table, flow); if (rule) { best = rule; LIST_FOR_EACH_CONTINUE (table, list_node, &cls->tables_priority) { if (table->max_priority <= best->priority) { /* Tables in descending priority order, * can not find anything better. */ return best; } rule = find_match(table, flow); if (rule && rule->priority > best->priority) { best = rule; } } break; } } return best; } /* Finds and returns a rule in 'cls' with exactly the same priority and * matching criteria as 'target'. Returns a null pointer if 'cls' doesn't * contain an exact match. */ struct cls_rule * classifier_find_rule_exactly(const struct classifier *cls, const struct cls_rule *target) { struct cls_rule *head, *rule; struct cls_table *table; table = find_table(cls, &target->match.mask); if (!table) { return NULL; } /* Skip if there is no hope. */ if (target->priority > table->max_priority) { return NULL; } head = find_equal(table, &target->match.flow, miniflow_hash_in_minimask(&target->match.flow, &target->match.mask, 0)); FOR_EACH_RULE_IN_LIST (rule, head) { if (target->priority >= rule->priority) { return target->priority == rule->priority ? rule : NULL; } } return NULL; } /* Finds and returns a rule in 'cls' with priority 'priority' and exactly the * same matching criteria as 'target'. Returns a null pointer if 'cls' doesn't * contain an exact match. */ struct cls_rule * classifier_find_match_exactly(const struct classifier *cls, const struct match *target, unsigned int priority) { struct cls_rule *retval; struct cls_rule cr; cls_rule_init(&cr, target, priority); retval = classifier_find_rule_exactly(cls, &cr); cls_rule_destroy(&cr); return retval; } /* Checks if 'target' would overlap any other rule in 'cls'. Two rules are * considered to overlap if both rules have the same priority and a packet * could match both. */ bool classifier_rule_overlaps(const struct classifier *cls, const struct cls_rule *target) { struct cls_table *table; /* Iterate tables in the descending max priority order. */ LIST_FOR_EACH (table, list_node, &cls->tables_priority) { uint32_t storage[FLOW_U32S]; struct minimask mask; struct cls_rule *head; if (target->priority > table->max_priority) { break; /* Can skip this and the rest of the tables. */ } minimask_combine(&mask, &target->match.mask, &table->mask, storage); HMAP_FOR_EACH (head, hmap_node, &table->rules) { struct cls_rule *rule; FOR_EACH_RULE_IN_LIST (rule, head) { if (rule->priority < target->priority) { break; /* Rules in descending priority order. */ } if (rule->priority == target->priority && miniflow_equal_in_minimask(&target->match.flow, &rule->match.flow, &mask)) { return true; } } } } return false; } /* Returns true if 'rule' exactly matches 'criteria' or if 'rule' is more * specific than 'criteria'. That is, 'rule' matches 'criteria' and this * function returns true if, for every field: * * - 'criteria' and 'rule' specify the same (non-wildcarded) value for the * field, or * * - 'criteria' wildcards the field, * * Conversely, 'rule' does not match 'criteria' and this function returns false * if, for at least one field: * * - 'criteria' and 'rule' specify different values for the field, or * * - 'criteria' specifies a value for the field but 'rule' wildcards it. * * Equivalently, the truth table for whether a field matches is: * * rule * * c wildcard exact * r +---------+---------+ * i wild | yes | yes | * t card | | | * e +---------+---------+ * r exact | no |if values| * i | |are equal| * a +---------+---------+ * * This is the matching rule used by OpenFlow 1.0 non-strict OFPT_FLOW_MOD * commands and by OpenFlow 1.0 aggregate and flow stats. * * Ignores rule->priority. */ bool cls_rule_is_loose_match(const struct cls_rule *rule, const struct minimatch *criteria) { return (!minimask_has_extra(&rule->match.mask, &criteria->mask) && miniflow_equal_in_minimask(&rule->match.flow, &criteria->flow, &criteria->mask)); } /* Iteration. */ static bool rule_matches(const struct cls_rule *rule, const struct cls_rule *target) { return (!target || miniflow_equal_in_minimask(&rule->match.flow, &target->match.flow, &target->match.mask)); } static struct cls_rule * search_table(const struct cls_table *table, const struct cls_rule *target) { if (!target || !minimask_has_extra(&table->mask, &target->match.mask)) { struct cls_rule *rule; HMAP_FOR_EACH (rule, hmap_node, &table->rules) { if (rule_matches(rule, target)) { return rule; } } } return NULL; } /* Initializes 'cursor' for iterating through rules in 'cls': * * - If 'target' is null, the cursor will visit every rule in 'cls'. * * - If 'target' is nonnull, the cursor will visit each 'rule' in 'cls' * such that cls_rule_is_loose_match(rule, target) returns true. * * Ignores target->priority. */ void cls_cursor_init(struct cls_cursor *cursor, const struct classifier *cls, const struct cls_rule *target) { cursor->cls = cls; cursor->target = target && !cls_rule_is_catchall(target) ? target : NULL; } /* Returns the first matching cls_rule in 'cursor''s iteration, or a null * pointer if there are no matches. */ struct cls_rule * cls_cursor_first(struct cls_cursor *cursor) { struct cls_table *table; HMAP_FOR_EACH (table, hmap_node, &cursor->cls->tables) { struct cls_rule *rule = search_table(table, cursor->target); if (rule) { cursor->table = table; return rule; } } return NULL; } /* Returns the next matching cls_rule in 'cursor''s iteration, or a null * pointer if there are no more matches. */ struct cls_rule * cls_cursor_next(struct cls_cursor *cursor, struct cls_rule *rule) { const struct cls_table *table; struct cls_rule *next; next = next_rule_in_list__(rule); if (next->priority < rule->priority) { return next; } /* 'next' is the head of the list, that is, the rule that is included in * the table's hmap. (This is important when the classifier contains rules * that differ only in priority.) */ rule = next; HMAP_FOR_EACH_CONTINUE (rule, hmap_node, &cursor->table->rules) { if (rule_matches(rule, cursor->target)) { return rule; } } table = cursor->table; HMAP_FOR_EACH_CONTINUE (table, hmap_node, &cursor->cls->tables) { rule = search_table(table, cursor->target); if (rule) { cursor->table = table; return rule; } } return NULL; } static struct cls_table * find_table(const struct classifier *cls, const struct minimask *mask) { struct cls_table *table; HMAP_FOR_EACH_IN_BUCKET (table, hmap_node, minimask_hash(mask, 0), &cls->tables) { if (minimask_equal(mask, &table->mask)) { return table; } } return NULL; } static struct cls_table * insert_table(struct classifier *cls, const struct minimask *mask) { struct cls_table *table; table = xzalloc(sizeof *table); hmap_init(&table->rules); minimask_clone(&table->mask, mask); hmap_insert(&cls->tables, &table->hmap_node, minimask_hash(mask, 0)); list_push_back(&cls->tables_priority, &table->list_node); return table; } static void destroy_table(struct classifier *cls, struct cls_table *table) { minimask_destroy(&table->mask); hmap_remove(&cls->tables, &table->hmap_node); hmap_destroy(&table->rules); list_remove(&table->list_node); free(table); } /* This function performs the following updates for 'table' in 'cls' following * the addition of a new rule with priority 'new_priority' to 'table': * * - Update 'table->max_priority' and 'table->max_count' if necessary. * * - Update 'table''s position in 'cls->tables_priority' if necessary. * * This function should only be called after adding a new rule, not after * replacing a rule by an identical one or modifying a rule in-place. */ static void update_tables_after_insertion(struct classifier *cls, struct cls_table *table, unsigned int new_priority) { if (new_priority == table->max_priority) { ++table->max_count; } else if (new_priority > table->max_priority) { struct cls_table *iter; table->max_priority = new_priority; table->max_count = 1; /* Possibly move 'table' earlier in the priority list. If we break out * of the loop, then 'table' should be moved just after that 'iter'. * If the loop terminates normally, then 'iter' will be the list head * and we'll move table just after that (e.g. to the front of the * list). */ iter = table; LIST_FOR_EACH_REVERSE_CONTINUE (iter, list_node, &cls->tables_priority) { if (iter->max_priority >= table->max_priority) { break; } } /* Move 'table' just after 'iter' (unless it's already there). */ if (iter->list_node.next != &table->list_node) { list_splice(iter->list_node.next, &table->list_node, table->list_node.next); } } } /* This function performs the following updates for 'table' in 'cls' following * the deletion of a rule with priority 'del_priority' from 'table': * * - Update 'table->max_priority' and 'table->max_count' if necessary. * * - Update 'table''s position in 'cls->tables_priority' if necessary. * * This function should only be called after removing a rule, not after * replacing a rule by an identical one or modifying a rule in-place. */ static void update_tables_after_removal(struct classifier *cls, struct cls_table *table, unsigned int del_priority) { struct cls_table *iter; if (del_priority == table->max_priority && --table->max_count == 0) { struct cls_rule *head; table->max_priority = 0; HMAP_FOR_EACH (head, hmap_node, &table->rules) { if (head->priority > table->max_priority) { table->max_priority = head->priority; table->max_count = 1; } else if (head->priority == table->max_priority) { ++table->max_count; } } /* Possibly move 'table' later in the priority list. If we break out * of the loop, then 'table' should be moved just before that 'iter'. * If the loop terminates normally, then 'iter' will be the list head * and we'll move table just before that (e.g. to the back of the * list). */ iter = table; LIST_FOR_EACH_CONTINUE (iter, list_node, &cls->tables_priority) { if (iter->max_priority <= table->max_priority) { break; } } /* Move 'table' just before 'iter' (unless it's already there). */ if (iter->list_node.prev != &table->list_node) { list_splice(&iter->list_node, &table->list_node, table->list_node.next); } } } static struct cls_rule * find_match(const struct cls_table *table, const struct flow *flow) { uint32_t hash = flow_hash_in_minimask(flow, &table->mask, 0); struct cls_rule *rule; HMAP_FOR_EACH_WITH_HASH (rule, hmap_node, hash, &table->rules) { if (miniflow_equal_flow_in_minimask(&rule->match.flow, flow, &table->mask)) { return rule; } } return NULL; } static struct cls_rule * find_equal(struct cls_table *table, const struct miniflow *flow, uint32_t hash) { struct cls_rule *head; HMAP_FOR_EACH_WITH_HASH (head, hmap_node, hash, &table->rules) { if (miniflow_equal(&head->match.flow, flow)) { return head; } } return NULL; } static struct cls_rule * insert_rule(struct classifier *cls, struct cls_table *table, struct cls_rule *new) { struct cls_rule *head; struct cls_rule *old = NULL; new->hmap_node.hash = miniflow_hash_in_minimask(&new->match.flow, &new->match.mask, 0); head = find_equal(table, &new->match.flow, new->hmap_node.hash); if (!head) { hmap_insert(&table->rules, &new->hmap_node, new->hmap_node.hash); list_init(&new->list); goto out; } else { /* Scan the list for the insertion point that will keep the list in * order of decreasing priority. */ struct cls_rule *rule; FOR_EACH_RULE_IN_LIST (rule, head) { if (new->priority >= rule->priority) { if (rule == head) { /* 'new' is the new highest-priority flow in the list. */ hmap_replace(&table->rules, &rule->hmap_node, &new->hmap_node); } if (new->priority == rule->priority) { list_replace(&new->list, &rule->list); old = rule; goto out; } else { list_insert(&rule->list, &new->list); goto out; } } } /* Insert 'new' at the end of the list. */ list_push_back(&head->list, &new->list); } out: if (!old) { update_tables_after_insertion(cls, table, new->priority); } return old; } static struct cls_rule * next_rule_in_list__(struct cls_rule *rule) { struct cls_rule *next = OBJECT_CONTAINING(rule->list.next, next, list); return next; } static struct cls_rule * next_rule_in_list(struct cls_rule *rule) { struct cls_rule *next = next_rule_in_list__(rule); return next->priority < rule->priority ? next : NULL; }