#include "packets.h"
#include "ovs-thread.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 struct cls_subtable *find_subtable(const struct classifier *,
+ const struct minimask *);
+static struct cls_subtable *insert_subtable(struct classifier *,
+ const struct minimask *);
-static void destroy_table(struct classifier *, struct cls_table *);
+static void destroy_subtable(struct classifier *, struct cls_subtable *);
-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 void update_subtables_after_insertion(struct classifier *,
+ struct cls_subtable *,
+ unsigned int new_priority);
+static void update_subtables_after_removal(struct classifier *,
+ struct cls_subtable *,
+ unsigned int del_priority);
-static struct cls_rule *find_match(const struct cls_table *,
+static struct cls_rule *find_match(const struct cls_subtable *,
const struct flow *);
-static struct cls_rule *find_equal(struct cls_table *,
+static struct cls_rule *find_equal(struct cls_subtable *,
const struct miniflow *, uint32_t hash);
static struct cls_rule *insert_rule(struct classifier *,
- struct cls_table *, struct cls_rule *);
+ struct cls_subtable *, struct cls_rule *);
/* Iterates RULE over HEAD and all of the cls_rules on HEAD->list. */
#define FOR_EACH_RULE_IN_LIST(RULE, HEAD) \
classifier_init(struct classifier *cls)
{
cls->n_rules = 0;
- hmap_init(&cls->tables);
- list_init(&cls->tables_priority);
+ hmap_init(&cls->subtables);
+ list_init(&cls->subtables_priority);
hmap_init(&cls->partitions);
ovs_rwlock_init(&cls->rwlock);
}
classifier_destroy(struct classifier *cls)
{
if (cls) {
- struct cls_table *partition, *next_partition;
- struct cls_table *table, *next_table;
+ struct cls_subtable *partition, *next_partition;
+ struct cls_subtable *subtable, *next_subtable;
- HMAP_FOR_EACH_SAFE (table, next_table, hmap_node, &cls->tables) {
- destroy_table(cls, table);
+ HMAP_FOR_EACH_SAFE (subtable, next_subtable, hmap_node,
+ &cls->subtables) {
+ destroy_subtable(cls, subtable);
}
- hmap_destroy(&cls->tables);
+ hmap_destroy(&cls->subtables);
HMAP_FOR_EACH_SAFE (partition, next_partition, hmap_node,
&cls->partitions) {
}
static struct cls_partition *
-create_partition(struct classifier *cls, struct cls_table *table,
+create_partition(struct classifier *cls, struct cls_subtable *subtable,
ovs_be64 metadata)
{
uint32_t hash = hash_metadata(metadata);
tag_tracker_init(&partition->tracker);
hmap_insert(&cls->partitions, &partition->hmap_node, hash);
}
- tag_tracker_add(&partition->tracker, &partition->tags, table->tag);
+ tag_tracker_add(&partition->tracker, &partition->tags, subtable->tag);
return partition;
}
classifier_replace(struct classifier *cls, struct cls_rule *rule)
{
struct cls_rule *old_rule;
- struct cls_table *table;
+ struct cls_subtable *subtable;
- table = find_table(cls, &rule->match.mask);
- if (!table) {
- table = insert_table(cls, &rule->match.mask);
+ subtable = find_subtable(cls, &rule->match.mask);
+ if (!subtable) {
+ subtable = insert_subtable(cls, &rule->match.mask);
}
- old_rule = insert_rule(cls, table, rule);
+ old_rule = insert_rule(cls, subtable, rule);
if (!old_rule) {
if (minimask_get_metadata_mask(&rule->match.mask) == OVS_BE64_MAX) {
ovs_be64 metadata = miniflow_get_metadata(&rule->match.flow);
- rule->partition = create_partition(cls, table, metadata);
+ rule->partition = create_partition(cls, subtable, metadata);
} else {
rule->partition = NULL;
}
- table->n_table_rules++;
+ subtable->n_rules++;
cls->n_rules++;
} else {
rule->partition = old_rule->partition;
{
struct cls_partition *partition;
struct cls_rule *head;
- struct cls_table *table;
+ struct cls_subtable *subtable;
- table = find_table(cls, &rule->match.mask);
- head = find_equal(table, &rule->match.flow, rule->hmap_node.hash);
+ subtable = find_subtable(cls, &rule->match.mask);
+ head = find_equal(subtable, &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);
+ hmap_remove(&subtable->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);
+ hmap_replace(&subtable->rules, &rule->hmap_node, &next->hmap_node);
}
partition = rule->partition;
if (partition) {
tag_tracker_subtract(&partition->tracker, &partition->tags,
- table->tag);
+ subtable->tag);
if (!partition->tags) {
hmap_remove(&cls->partitions, &partition->hmap_node);
free(partition);
}
}
- if (--table->n_table_rules == 0) {
- destroy_table(cls, table);
+ if (--subtable->n_rules == 0) {
+ destroy_subtable(cls, subtable);
} else {
- update_tables_after_removal(cls, table, rule->priority);
+ update_subtables_after_removal(cls, subtable, rule->priority);
}
cls->n_rules--;
}
struct flow_wildcards *wc)
{
const struct cls_partition *partition;
- struct cls_table *table;
+ struct cls_subtable *subtable;
struct cls_rule *best;
tag_type tags;
- /* Determine 'tags' such that, if 'table->tag' doesn't intersect them, then
- * 'flow' cannot possibly match in 'table':
+ /* Determine 'tags' such that, if 'subtable->tag' doesn't intersect them,
+ * then 'flow' cannot possibly match in 'subtable':
*
* - If flow->metadata maps to a given 'partition', then we can use
* 'tags' for 'partition->tags'.
*
* - If flow->metadata has no partition, then no rule in 'cls' has an
* exact-match for flow->metadata. That means that we don't need to
- * search any table that includes flow->metadata in its mask.
+ * search any subtable that includes flow->metadata in its mask.
*
- * In either case, we always need to search any cls_tables that do not
+ * In either case, we always need to search any cls_subtables that do not
* include flow->metadata in its mask. One way to do that would be to
- * check the "cls_table"s explicitly for that, but that would require an
- * extra branch per table. Instead, we mark such a cls_table's 'tags' as
- * TAG_ALL and make sure that 'tags' is never empty. This means that
- * 'tags' always intersects such a cls_table's 'tags', so we don't need a
- * special case.
+ * check the "cls_subtable"s explicitly for that, but that would require an
+ * extra branch per subtable. Instead, we mark such a cls_subtable's
+ * 'tags' as TAG_ALL and make sure that 'tags' is never empty. This means
+ * that 'tags' always intersects such a cls_subtable's 'tags', so we don't
+ * need a special case.
*/
partition = (hmap_is_empty(&cls->partitions)
? NULL
tags = partition ? partition->tags : TAG_ARBITRARY;
best = NULL;
- LIST_FOR_EACH (table, list_node, &cls->tables_priority) {
+ LIST_FOR_EACH (subtable, list_node, &cls->subtables_priority) {
struct cls_rule *rule;
- if (!tag_intersects(tags, table->tag)) {
+ if (!tag_intersects(tags, subtable->tag)) {
continue;
}
- rule = find_match(table, flow);
+ rule = find_match(subtable, flow);
if (wc) {
- flow_wildcards_fold_minimask(wc, &table->mask);
+ flow_wildcards_fold_minimask(wc, &subtable->mask);
}
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,
+ LIST_FOR_EACH_CONTINUE (subtable, list_node,
+ &cls->subtables_priority) {
+ if (subtable->max_priority <= best->priority) {
+ /* Subtables are in descending priority order,
* can not find anything better. */
return best;
}
- if (!tag_intersects(tags, table->tag)) {
+ if (!tag_intersects(tags, subtable->tag)) {
continue;
}
- rule = find_match(table, flow);
+ rule = find_match(subtable, flow);
if (wc) {
- flow_wildcards_fold_minimask(wc, &table->mask);
+ flow_wildcards_fold_minimask(wc, &subtable->mask);
}
if (rule && rule->priority > best->priority) {
best = rule;
const struct cls_rule *target)
{
struct cls_rule *head, *rule;
- struct cls_table *table;
+ struct cls_subtable *subtable;
- table = find_table(cls, &target->match.mask);
- if (!table) {
+ subtable = find_subtable(cls, &target->match.mask);
+ if (!subtable) {
return NULL;
}
/* Skip if there is no hope. */
- if (target->priority > table->max_priority) {
+ if (target->priority > subtable->max_priority) {
return NULL;
}
- head = find_equal(table, &target->match.flow,
+ head = find_equal(subtable, &target->match.flow,
miniflow_hash_in_minimask(&target->match.flow,
&target->match.mask, 0));
FOR_EACH_RULE_IN_LIST (rule, head) {
classifier_rule_overlaps(const struct classifier *cls,
const struct cls_rule *target)
{
- struct cls_table *table;
+ struct cls_subtable *subtable;
- /* Iterate tables in the descending max priority order. */
- LIST_FOR_EACH (table, list_node, &cls->tables_priority) {
+ /* Iterate subtables in the descending max priority order. */
+ LIST_FOR_EACH (subtable, list_node, &cls->subtables_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. */
+ if (target->priority > subtable->max_priority) {
+ break; /* Can skip this and the rest of the subtables. */
}
- minimask_combine(&mask, &target->match.mask, &table->mask, storage);
- HMAP_FOR_EACH (head, hmap_node, &table->rules) {
+ minimask_combine(&mask, &target->match.mask, &subtable->mask, storage);
+ HMAP_FOR_EACH (head, hmap_node, &subtable->rules) {
struct cls_rule *rule;
FOR_EACH_RULE_IN_LIST (rule, head) {
}
static struct cls_rule *
-search_table(const struct cls_table *table, const struct cls_rule *target)
+search_subtable(const struct cls_subtable *subtable,
+ const struct cls_rule *target)
{
- if (!target || !minimask_has_extra(&table->mask, &target->match.mask)) {
+ if (!target || !minimask_has_extra(&subtable->mask, &target->match.mask)) {
struct cls_rule *rule;
- HMAP_FOR_EACH (rule, hmap_node, &table->rules) {
+ HMAP_FOR_EACH (rule, hmap_node, &subtable->rules) {
if (rule_matches(rule, target)) {
return rule;
}
struct cls_rule *
cls_cursor_first(struct cls_cursor *cursor)
{
- struct cls_table *table;
+ struct cls_subtable *subtable;
- HMAP_FOR_EACH (table, hmap_node, &cursor->cls->tables) {
- struct cls_rule *rule = search_table(table, cursor->target);
+ HMAP_FOR_EACH (subtable, hmap_node, &cursor->cls->subtables) {
+ struct cls_rule *rule = search_subtable(subtable, cursor->target);
if (rule) {
- cursor->table = table;
+ cursor->subtable = subtable;
return rule;
}
}
cls_cursor_next(struct cls_cursor *cursor, const struct cls_rule *rule_)
{
struct cls_rule *rule = CONST_CAST(struct cls_rule *, rule_);
- const struct cls_table *table;
+ const struct cls_subtable *subtable;
struct cls_rule *next;
next = next_rule_in_list__(rule);
}
/* '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.) */
+ * the subtable'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) {
+ HMAP_FOR_EACH_CONTINUE (rule, hmap_node, &cursor->subtable->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);
+ subtable = cursor->subtable;
+ HMAP_FOR_EACH_CONTINUE (subtable, hmap_node, &cursor->cls->subtables) {
+ rule = search_subtable(subtable, cursor->target);
if (rule) {
- cursor->table = table;
+ cursor->subtable = subtable;
return rule;
}
}
return NULL;
}
\f
-static struct cls_table *
-find_table(const struct classifier *cls, const struct minimask *mask)
+static struct cls_subtable *
+find_subtable(const struct classifier *cls, const struct minimask *mask)
{
- struct cls_table *table;
+ struct cls_subtable *subtable;
- HMAP_FOR_EACH_IN_BUCKET (table, hmap_node, minimask_hash(mask, 0),
- &cls->tables) {
- if (minimask_equal(mask, &table->mask)) {
- return table;
+ HMAP_FOR_EACH_IN_BUCKET (subtable, hmap_node, minimask_hash(mask, 0),
+ &cls->subtables) {
+ if (minimask_equal(mask, &subtable->mask)) {
+ return subtable;
}
}
return NULL;
}
-static struct cls_table *
-insert_table(struct classifier *cls, const struct minimask *mask)
+static struct cls_subtable *
+insert_subtable(struct classifier *cls, const struct minimask *mask)
{
uint32_t hash = minimask_hash(mask, 0);
- struct cls_table *table;
+ struct cls_subtable *subtable;
- 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);
- table->tag = (minimask_get_metadata_mask(mask) == OVS_BE64_MAX
- ? tag_create_deterministic(hash)
- : TAG_ALL);
+ subtable = xzalloc(sizeof *subtable);
+ hmap_init(&subtable->rules);
+ minimask_clone(&subtable->mask, mask);
+ hmap_insert(&cls->subtables, &subtable->hmap_node, minimask_hash(mask, 0));
+ list_push_back(&cls->subtables_priority, &subtable->list_node);
+ subtable->tag = (minimask_get_metadata_mask(mask) == OVS_BE64_MAX
+ ? tag_create_deterministic(hash)
+ : TAG_ALL);
- return table;
+ return subtable;
}
static void
-destroy_table(struct classifier *cls, struct cls_table *table)
+destroy_subtable(struct classifier *cls, struct cls_subtable *subtable)
{
- minimask_destroy(&table->mask);
- hmap_remove(&cls->tables, &table->hmap_node);
- hmap_destroy(&table->rules);
- list_remove(&table->list_node);
- free(table);
+ minimask_destroy(&subtable->mask);
+ hmap_remove(&cls->subtables, &subtable->hmap_node);
+ hmap_destroy(&subtable->rules);
+ list_remove(&subtable->list_node);
+ free(subtable);
}
-/* This function performs the following updates for 'table' in 'cls' following
- * the addition of a new rule with priority 'new_priority' to 'table':
+/* This function performs the following updates for 'subtable' in 'cls'
+ * following the addition of a new rule with priority 'new_priority' to
+ * 'subtable':
*
- * - Update 'table->max_priority' and 'table->max_count' if necessary.
+ * - Update 'subtable->max_priority' and 'subtable->max_count' if necessary.
*
- * - Update 'table''s position in 'cls->tables_priority' if necessary.
+ * - Update 'subtable''s position in 'cls->subtables_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;
+update_subtables_after_insertion(struct classifier *cls,
+ struct cls_subtable *subtable,
+ unsigned int new_priority)
+{
+ if (new_priority == subtable->max_priority) {
+ ++subtable->max_count;
+ } else if (new_priority > subtable->max_priority) {
+ struct cls_subtable *iter;
+
+ subtable->max_priority = new_priority;
+ subtable->max_count = 1;
+
+ /* Possibly move 'subtable' earlier in the priority list. If we break
+ * out of the loop, then 'subtable' should be moved just after that
+ * 'iter'. If the loop terminates normally, then 'iter' will be the
+ * list head and we'll move subtable just after that (e.g. to the front
+ * of the list). */
+ iter = subtable;
LIST_FOR_EACH_REVERSE_CONTINUE (iter, list_node,
- &cls->tables_priority) {
- if (iter->max_priority >= table->max_priority) {
+ &cls->subtables_priority) {
+ if (iter->max_priority >= subtable->max_priority) {
break;
}
}
- /* Move 'table' just after 'iter' (unless it's already there). */
- if (iter->list_node.next != &table->list_node) {
+ /* Move 'subtable' just after 'iter' (unless it's already there). */
+ if (iter->list_node.next != &subtable->list_node) {
list_splice(iter->list_node.next,
- &table->list_node, table->list_node.next);
+ &subtable->list_node, subtable->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':
+/* This function performs the following updates for 'subtable' in 'cls'
+ * following the deletion of a rule with priority 'del_priority' from
+ * 'subtable':
*
- * - Update 'table->max_priority' and 'table->max_count' if necessary.
+ * - Update 'subtable->max_priority' and 'subtable->max_count' if necessary.
*
- * - Update 'table''s position in 'cls->tables_priority' if necessary.
+ * - Update 'subtable''s position in 'cls->subtables_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)
+update_subtables_after_removal(struct classifier *cls,
+ struct cls_subtable *subtable,
+ unsigned int del_priority)
{
- struct cls_table *iter;
+ struct cls_subtable *iter;
- if (del_priority == table->max_priority && --table->max_count == 0) {
+ if (del_priority == subtable->max_priority && --subtable->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;
+ subtable->max_priority = 0;
+ HMAP_FOR_EACH (head, hmap_node, &subtable->rules) {
+ if (head->priority > subtable->max_priority) {
+ subtable->max_priority = head->priority;
+ subtable->max_count = 1;
+ } else if (head->priority == subtable->max_priority) {
+ ++subtable->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) {
+ /* Possibly move 'subtable' later in the priority list. If we break
+ * out of the loop, then 'subtable' should be moved just before that
+ * 'iter'. If the loop terminates normally, then 'iter' will be the
+ * list head and we'll move subtable just before that (e.g. to the back
+ * of the list). */
+ iter = subtable;
+ LIST_FOR_EACH_CONTINUE (iter, list_node, &cls->subtables_priority) {
+ if (iter->max_priority <= subtable->max_priority) {
break;
}
}
- /* Move 'table' just before 'iter' (unless it's already there). */
- if (iter->list_node.prev != &table->list_node) {
+ /* Move 'subtable' just before 'iter' (unless it's already there). */
+ if (iter->list_node.prev != &subtable->list_node) {
list_splice(&iter->list_node,
- &table->list_node, table->list_node.next);
+ &subtable->list_node, subtable->list_node.next);
}
}
}
static struct cls_rule *
-find_match(const struct cls_table *table, const struct flow *flow)
+find_match(const struct cls_subtable *subtable, const struct flow *flow)
{
- uint32_t hash = flow_hash_in_minimask(flow, &table->mask, 0);
+ uint32_t hash = flow_hash_in_minimask(flow, &subtable->mask, 0);
struct cls_rule *rule;
- HMAP_FOR_EACH_WITH_HASH (rule, hmap_node, hash, &table->rules) {
+ HMAP_FOR_EACH_WITH_HASH (rule, hmap_node, hash, &subtable->rules) {
if (minimatch_matches_flow(&rule->match, flow)) {
return rule;
}
}
static struct cls_rule *
-find_equal(struct cls_table *table, const struct miniflow *flow, uint32_t hash)
+find_equal(struct cls_subtable *subtable, const struct miniflow *flow,
+ uint32_t hash)
{
struct cls_rule *head;
- HMAP_FOR_EACH_WITH_HASH (head, hmap_node, hash, &table->rules) {
+ HMAP_FOR_EACH_WITH_HASH (head, hmap_node, hash, &subtable->rules) {
if (miniflow_equal(&head->match.flow, flow)) {
return head;
}
}
static struct cls_rule *
-insert_rule(struct classifier *cls,
- struct cls_table *table, struct cls_rule *new)
+insert_rule(struct classifier *cls, struct cls_subtable *subtable,
+ 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);
+ head = find_equal(subtable, &new->match.flow, new->hmap_node.hash);
if (!head) {
- hmap_insert(&table->rules, &new->hmap_node, new->hmap_node.hash);
+ hmap_insert(&subtable->rules, &new->hmap_node, new->hmap_node.hash);
list_init(&new->list);
goto out;
} else {
if (new->priority >= rule->priority) {
if (rule == head) {
/* 'new' is the new highest-priority flow in the list. */
- hmap_replace(&table->rules,
+ hmap_replace(&subtable->rules,
&rule->hmap_node, &new->hmap_node);
}
out:
if (!old) {
- update_tables_after_insertion(cls, table, new->priority);
+ update_subtables_after_insertion(cls, subtable, new->priority);
}
return old;
}
*
* This is how the classifier works. In a "struct classifier", each form of
* "struct cls_rule" present (based on its ->match.mask) goes into a separate
- * "struct cls_table". A lookup does a hash lookup in every "struct cls_table"
- * in the classifier and tracks the highest-priority match that it finds. The
- * tables are kept in a descending priority order according to the highest
- * priority rule in each table, which allows lookup to skip over tables that
- * can't possibly have a higher-priority match than already found.
+ * "struct cls_subtable". A lookup does a hash lookup in every "struct
+ * cls_subtable" in the classifier and tracks the highest-priority match that
+ * it finds. The subtables are kept in a descending priority order according
+ * to the highest priority rule in each subtable, which allows lookup to skip
+ * over subtables that can't possibly have a higher-priority match than
+ * already found.
*
* One detail: a classifier can contain multiple rules that are identical other
* than their priority. When this happens, only the highest priority rule out
* of a group of otherwise identical rules is stored directly in the "struct
- * cls_table", with the other almost-identical rules chained off a linked list
- * inside that highest-priority rule.
+ * cls_subtable", with the other almost-identical rules chained off a linked
+ * list inside that highest-priority rule.
*
*
* Partitioning
* The classifier has a special optimization to speed up matching in this
* scenario:
*
- * - Each cls_table that matches on metadata gets a tag derived from the
- * table's mask, so that it is likely that each table has a unique tag.
- * (Duplicate tags have a performance cost but do not affect
+ * - Each cls_subtable that matches on metadata gets a tag derived from the
+ * subtable's mask, so that it is likely that each subtable has a unique
+ * tag. (Duplicate tags have a performance cost but do not affect
* correctness.)
*
* - For each metadata value matched by any cls_rule, the classifier
* constructs a "struct cls_partition" indexed by the metadata value.
* The cls_partition has a 'tags' member whose value is the bitwise-OR of
- * the tags of each cls_table that contains any rule that matches on the
- * cls_partition's metadata value. In other words, struct cls_partition
- * associates metadata values with tables that need to be checked with
- * flows with that specific metadata value.
+ * the tags of each cls_subtable that contains any rule that matches on
+ * the cls_partition's metadata value. In other words, struct
+ * cls_partition associates metadata values with subtables that need to
+ * be checked with flows with that specific metadata value.
*
* Thus, a flow lookup can start by looking up the partition associated with
- * the flow's metadata, and then skip over any cls_table whose 'tag' does not
- * intersect the partition's 'tags'. (The flow must also be looked up in any
- * cls_table that doesn't match on metadata. We handle that by giving any such
- * cls_table TAG_ALL as its 'tags' so that it matches any tag.)
+ * the flow's metadata, and then skip over any cls_subtable whose 'tag' does
+ * not intersect the partition's 'tags'. (The flow must also be looked up in
+ * any cls_subtable that doesn't match on metadata. We handle that by giving
+ * any such cls_subtable TAG_ALL as its 'tags' so that it matches any tag.)
*
*
* Thread-safety
/* A flow classifier. */
struct classifier {
int n_rules; /* Total number of rules. */
- struct hmap tables; /* Contains "struct cls_table"s. */
- struct list tables_priority; /* Tables in descending priority order */
+ struct hmap subtables; /* Contains "struct cls_subtable"s. */
+ struct list subtables_priority; /* Subtables in descending priority order.
+ */
struct hmap partitions; /* Contains "struct cls_partition"s. */
struct ovs_rwlock rwlock OVS_ACQ_AFTER(ofproto_mutex);
};
/* A set of rules that all have the same fields wildcarded. */
-struct cls_table {
- struct hmap_node hmap_node; /* Within struct classifier 'tables' hmap. */
- struct list list_node; /* Within classifier 'tables_priority_list' */
+struct cls_subtable {
+ struct hmap_node hmap_node; /* Within struct classifier 'subtables' hmap.
+ */
+ struct list list_node; /* Within classifier 'subtables_priority' list.
+ */
struct hmap rules; /* Contains "struct cls_rule"s. */
struct minimask mask; /* Wildcards for fields. */
- int n_table_rules; /* Number of rules, including duplicates. */
- unsigned int max_priority; /* Max priority of any rule in the table. */
+ int n_rules; /* Number of rules, including duplicates. */
+ unsigned int max_priority; /* Max priority of any rule in the subtable. */
unsigned int max_count; /* Count of max_priority rules. */
tag_type tag; /* Tag generated from mask for partitioning. */
};
-/* Returns true if 'table' is a "catch-all" table that will match every
+/* Returns true if 'table' is a "catch-all" subtable that will match every
* packet (if there is no higher-priority match). */
static inline bool
-cls_table_is_catchall(const struct cls_table *table)
+cls_subtable_is_catchall(const struct cls_subtable *subtable)
{
- return minimask_is_catchall(&table->mask);
+ return minimask_is_catchall(&subtable->mask);
}
-/* A rule in a "struct cls_table". */
+/* A rule in a "struct cls_subtable". */
struct cls_rule {
- struct hmap_node hmap_node; /* Within struct cls_table 'rules'. */
+ struct hmap_node hmap_node; /* Within struct cls_subtable 'rules'. */
struct list list; /* List of identical, lower-priority rules. */
struct minimatch match; /* Matching rule. */
unsigned int priority; /* Larger numbers are higher priorities. */
};
/* Associates a metadata value (that is, a value of the OpenFlow 1.1+ metadata
- * field) with tags for the "cls_table"s that contain rules that match that
+ * field) with tags for the "cls_subtable"s that contain rules that match that
* metadata value. */
struct cls_partition {
struct hmap_node hmap_node; /* In struct classifier's 'partitions' hmap. */
ovs_be64 metadata; /* metadata value for this partition. */
- tag_type tags; /* OR of each included flow's cls_table tag. */
+ tag_type tags; /* OR of each flow's cls_subtable tag. */
struct tag_tracker tracker; /* Tracks the bits in 'tags'. */
};
struct cls_cursor {
const struct classifier *cls;
- const struct cls_table *table;
+ const struct cls_subtable *subtable;
const struct cls_rule *target;
};
void cls_cursor_init(struct cls_cursor *cursor, const struct classifier *cls,
const struct cls_rule *match) OVS_REQ_RDLOCK(cls->rwlock);
struct cls_rule *cls_cursor_first(struct cls_cursor *cursor);
-struct cls_rule *cls_cursor_next(struct cls_cursor *cursor, const struct cls_rule *);
+struct cls_rule *cls_cursor_next(struct cls_cursor *, const struct cls_rule *);
#define CLS_CURSOR_FOR_EACH(RULE, MEMBER, CURSOR) \
for (ASSIGN_CONTAINER(RULE, cls_cursor_first(CURSOR), MEMBER); \