VLOG_DEFINE_THIS_MODULE(classifier);
+struct trie_node;
struct trie_ctx;
-static struct cls_subtable *find_subtable(const struct classifier *,
+
+/* Ports trie depends on both ports sharing the same ovs_be32. */
+#define TP_PORTS_OFS32 (offsetof(struct flow, tp_src) / 4)
+BUILD_ASSERT_DECL(TP_PORTS_OFS32 == offsetof(struct flow, tp_dst) / 4);
+
+/* Prefix trie for a 'field' */
+struct cls_trie {
+ const struct mf_field *field; /* Trie field, or NULL. */
+ struct trie_node *root; /* NULL if none. */
+};
+
+struct cls_subtable_entry {
+ struct cls_subtable *subtable;
+ tag_type tag;
+ unsigned int max_priority;
+};
+
+struct cls_subtable_cache {
+ struct cls_subtable_entry *subtables;
+ size_t alloc_size; /* Number of allocated elements. */
+ size_t size; /* One past last valid array element. */
+};
+
+enum {
+ CLS_MAX_INDICES = 3 /* Maximum number of lookup indices per subtable. */
+};
+
+struct cls_classifier {
+ int n_rules; /* Total number of rules. */
+ uint8_t n_flow_segments;
+ uint8_t flow_segments[CLS_MAX_INDICES]; /* Flow segment boundaries to use
+ * for staged lookup. */
+ struct hmap subtables; /* Contains "struct cls_subtable"s. */
+ struct cls_subtable_cache subtables_priority;
+ struct hmap partitions; /* Contains "struct cls_partition"s. */
+ struct cls_trie tries[CLS_MAX_TRIES]; /* Prefix tries. */
+ unsigned int n_tries;
+};
+
+/* A set of rules that all have the same fields wildcarded. */
+struct cls_subtable {
+ struct hmap_node hmap_node; /* Within struct cls_classifier 'subtables'
+ * hmap. */
+ struct hmap rules; /* Contains "struct cls_rule"s. */
+ 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. */
+ uint8_t n_indices; /* How many indices to use. */
+ uint8_t index_ofs[CLS_MAX_INDICES]; /* u32 flow segment boundaries. */
+ struct hindex indices[CLS_MAX_INDICES]; /* Staged lookup indices. */
+ unsigned int trie_plen[CLS_MAX_TRIES]; /* Trie prefix length in 'mask'. */
+ int ports_mask_len;
+ struct trie_node *ports_trie; /* NULL if none. */
+ struct minimask mask; /* Wildcards for fields. */
+ /* 'mask' must be the last field. */
+};
+
+/* Associates a metadata value (that is, a value of the OpenFlow 1.1+ metadata
+ * 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 cls_classifier's 'partitions'
+ * hmap. */
+ ovs_be64 metadata; /* metadata value for this partition. */
+ tag_type tags; /* OR of each flow's cls_subtable tag. */
+ struct tag_tracker tracker; /* Tracks the bits in 'tags'. */
+};
+
+/* Internal representation of a rule in a "struct cls_subtable". */
+struct cls_match {
+ struct cls_rule *cls_rule;
+ struct hindex_node index_nodes[CLS_MAX_INDICES]; /* Within subtable's
+ * 'indices'. */
+ struct hmap_node hmap_node; /* Within struct cls_subtable 'rules'. */
+ unsigned int priority; /* Larger numbers are higher priorities. */
+ struct cls_partition *partition;
+ struct list list; /* List of identical, lower-priority rules. */
+ struct miniflow flow; /* Matching rule. Mask is in the subtable. */
+ /* 'flow' must be the last field. */
+};
+
+static struct cls_match *
+cls_match_alloc(struct cls_rule *rule)
+{
+ int count = count_1bits(rule->match.flow.map);
+
+ struct cls_match *cls_match
+ = xmalloc(sizeof *cls_match - sizeof cls_match->flow.inline_values
+ + MINIFLOW_VALUES_SIZE(count));
+
+ cls_match->cls_rule = rule;
+ miniflow_clone_inline(&cls_match->flow, &rule->match.flow, count);
+ cls_match->priority = rule->priority;
+ rule->cls_match = cls_match;
+
+ return cls_match;
+}
+
+static struct cls_subtable *find_subtable(const struct cls_classifier *,
const struct minimask *);
-static struct cls_subtable *insert_subtable(struct classifier *,
+static struct cls_subtable *insert_subtable(struct cls_classifier *,
const struct minimask *);
-static void destroy_subtable(struct classifier *, struct cls_subtable *);
+static void destroy_subtable(struct cls_classifier *, struct cls_subtable *);
-static void update_subtables_after_insertion(struct classifier *,
+static void update_subtables_after_insertion(struct cls_classifier *,
struct cls_subtable *,
unsigned int new_priority);
-static void update_subtables_after_removal(struct classifier *,
+static void update_subtables_after_removal(struct cls_classifier *,
struct cls_subtable *,
unsigned int del_priority);
-static struct cls_rule *find_match_wc(const struct cls_subtable *,
- const struct flow *, struct trie_ctx *,
- unsigned int n_tries,
- struct flow_wildcards *);
-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_subtable *, struct cls_rule *);
+static struct cls_match *find_match_wc(const struct cls_subtable *,
+ const struct flow *, struct trie_ctx *,
+ unsigned int n_tries,
+ struct flow_wildcards *);
+static struct cls_match *find_equal(struct cls_subtable *,
+ const struct miniflow *, uint32_t hash);
+static struct cls_match *insert_rule(struct cls_classifier *,
+ 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) \
(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 *);
+static struct cls_match *next_rule_in_list__(struct cls_match *);
+static struct cls_match *next_rule_in_list(struct cls_match *);
static unsigned int minimask_get_prefix_len(const struct minimask *,
const struct mf_field *);
-static void trie_init(struct classifier *, int trie_idx,
+static void trie_init(struct cls_classifier *, int trie_idx,
const struct mf_field *);
static unsigned int trie_lookup(const struct cls_trie *, const struct flow *,
unsigned int *checkbits);
-
+static unsigned int trie_lookup_value(const struct trie_node *,
+ const ovs_be32 value[],
+ unsigned int *checkbits);
static void trie_destroy(struct trie_node *);
static void trie_insert(struct cls_trie *, const struct cls_rule *, int mlen);
+static void trie_insert_prefix(struct trie_node **, const ovs_be32 *prefix,
+ int mlen);
static void trie_remove(struct cls_trie *, const struct cls_rule *, int mlen);
+static void trie_remove_prefix(struct trie_node **, const ovs_be32 *prefix,
+ int mlen);
static void mask_set_prefix_bits(struct flow_wildcards *, uint8_t be32ofs,
unsigned int nbits);
static bool mask_prefix_bits_set(const struct flow_wildcards *,
uint8_t be32ofs, unsigned int nbits);
+
+static void
+cls_subtable_cache_init(struct cls_subtable_cache *array)
+{
+ memset(array, 0, sizeof *array);
+}
+
+static void
+cls_subtable_cache_destroy(struct cls_subtable_cache *array)
+{
+ free(array->subtables);
+ memset(array, 0, sizeof *array);
+}
+
+/* Array insertion. */
+static void
+cls_subtable_cache_push_back(struct cls_subtable_cache *array,
+ struct cls_subtable_entry a)
+{
+ if (array->size == array->alloc_size) {
+ array->subtables = x2nrealloc(array->subtables, &array->alloc_size,
+ sizeof a);
+ }
+
+ array->subtables[array->size++] = a;
+}
+
+/* Only for rearranging entries in the same cache. */
+static inline void
+cls_subtable_cache_splice(struct cls_subtable_entry *to,
+ struct cls_subtable_entry *start,
+ struct cls_subtable_entry *end)
+{
+ if (to > end) {
+ /* Same as splicing entries to (start) from [end, to). */
+ struct cls_subtable_entry *temp = to;
+ to = start; start = end; end = temp;
+ }
+ if (to < start) {
+ while (start != end) {
+ struct cls_subtable_entry temp = *start;
+
+ memmove(to + 1, to, (start - to) * sizeof *to);
+ *to = temp;
+ start++;
+ }
+ } /* Else nothing to be done. */
+}
+
+/* Array removal. */
+static inline void
+cls_subtable_cache_remove(struct cls_subtable_cache *array,
+ struct cls_subtable_entry *elem)
+{
+ ssize_t size = (&array->subtables[array->size]
+ - (elem + 1)) * sizeof *elem;
+ if (size > 0) {
+ memmove(elem, elem + 1, size);
+ }
+ array->size--;
+}
+
+#define CLS_SUBTABLE_CACHE_FOR_EACH(SUBTABLE, ITER, ARRAY) \
+ for (ITER = (ARRAY)->subtables; \
+ ITER < &(ARRAY)->subtables[(ARRAY)->size] \
+ && OVS_LIKELY(SUBTABLE = ITER->subtable); \
+ ++ITER)
+#define CLS_SUBTABLE_CACHE_FOR_EACH_CONTINUE(SUBTABLE, ITER, ARRAY) \
+ for (++ITER; \
+ ITER < &(ARRAY)->subtables[(ARRAY)->size] \
+ && OVS_LIKELY(SUBTABLE = ITER->subtable); \
+ ++ITER)
+#define CLS_SUBTABLE_CACHE_FOR_EACH_REVERSE(SUBTABLE, ITER, ARRAY) \
+ for (ITER = &(ARRAY)->subtables[(ARRAY)->size]; \
+ ITER > (ARRAY)->subtables \
+ && OVS_LIKELY(SUBTABLE = (--ITER)->subtable);)
+
+\f
+/* flow/miniflow/minimask/minimatch utilities.
+ * These are only used by the classifier, so place them here to allow
+ * for better optimization. */
+
+static inline uint64_t
+miniflow_get_map_in_range(const struct miniflow *miniflow,
+ uint8_t start, uint8_t end, unsigned int *offset)
+{
+ uint64_t map = miniflow->map;
+ *offset = 0;
+
+ if (start > 0) {
+ uint64_t msk = (UINT64_C(1) << start) - 1; /* 'start' LSBs set */
+ *offset = count_1bits(map & msk);
+ map &= ~msk;
+ }
+ if (end < FLOW_U32S) {
+ uint64_t msk = (UINT64_C(1) << end) - 1; /* 'end' LSBs set */
+ map &= msk;
+ }
+ return map;
+}
+
+/* Returns a hash value for the bits of 'flow' where there are 1-bits in
+ * 'mask', given 'basis'.
+ *
+ * The hash values returned by this function are the same as those returned by
+ * miniflow_hash_in_minimask(), only the form of the arguments differ. */
+static inline uint32_t
+flow_hash_in_minimask(const struct flow *flow, const struct minimask *mask,
+ uint32_t basis)
+{
+ const uint32_t *mask_values = miniflow_get_u32_values(&mask->masks);
+ const uint32_t *flow_u32 = (const uint32_t *)flow;
+ const uint32_t *p = mask_values;
+ uint32_t hash;
+ uint64_t map;
+
+ hash = basis;
+ for (map = mask->masks.map; map; map = zero_rightmost_1bit(map)) {
+ hash = mhash_add(hash, flow_u32[raw_ctz(map)] & *p++);
+ }
+
+ return mhash_finish(hash, (p - mask_values) * 4);
+}
+
+/* Returns a hash value for the bits of 'flow' where there are 1-bits in
+ * 'mask', given 'basis'.
+ *
+ * The hash values returned by this function are the same as those returned by
+ * flow_hash_in_minimask(), only the form of the arguments differ. */
+static inline uint32_t
+miniflow_hash_in_minimask(const struct miniflow *flow,
+ const struct minimask *mask, uint32_t basis)
+{
+ const uint32_t *mask_values = miniflow_get_u32_values(&mask->masks);
+ const uint32_t *p = mask_values;
+ uint32_t hash = basis;
+ uint32_t flow_u32;
+
+ MINIFLOW_FOR_EACH_IN_MAP(flow_u32, flow, mask->masks.map) {
+ hash = mhash_add(hash, flow_u32 & *p++);
+ }
+
+ return mhash_finish(hash, (p - mask_values) * 4);
+}
+
+/* Returns a hash value for the bits of range [start, end) in 'flow',
+ * where there are 1-bits in 'mask', given 'hash'.
+ *
+ * The hash values returned by this function are the same as those returned by
+ * minimatch_hash_range(), only the form of the arguments differ. */
+static inline uint32_t
+flow_hash_in_minimask_range(const struct flow *flow,
+ const struct minimask *mask,
+ uint8_t start, uint8_t end, uint32_t *basis)
+{
+ const uint32_t *mask_values = miniflow_get_u32_values(&mask->masks);
+ const uint32_t *flow_u32 = (const uint32_t *)flow;
+ unsigned int offset;
+ uint64_t map = miniflow_get_map_in_range(&mask->masks, start, end,
+ &offset);
+ const uint32_t *p = mask_values + offset;
+ uint32_t hash = *basis;
+
+ for (; map; map = zero_rightmost_1bit(map)) {
+ hash = mhash_add(hash, flow_u32[raw_ctz(map)] & *p++);
+ }
+
+ *basis = hash; /* Allow continuation from the unfinished value. */
+ return mhash_finish(hash, (p - mask_values) * 4);
+}
+
+/* Fold minimask 'mask''s wildcard mask into 'wc's wildcard mask. */
+static inline void
+flow_wildcards_fold_minimask(struct flow_wildcards *wc,
+ const struct minimask *mask)
+{
+ flow_union_with_miniflow(&wc->masks, &mask->masks);
+}
+
+/* Fold minimask 'mask''s wildcard mask into 'wc's wildcard mask
+ * in range [start, end). */
+static inline void
+flow_wildcards_fold_minimask_range(struct flow_wildcards *wc,
+ const struct minimask *mask,
+ uint8_t start, uint8_t end)
+{
+ uint32_t *dst_u32 = (uint32_t *)&wc->masks;
+ unsigned int offset;
+ uint64_t map = miniflow_get_map_in_range(&mask->masks, start, end,
+ &offset);
+ const uint32_t *p = miniflow_get_u32_values(&mask->masks) + offset;
+
+ for (; map; map = zero_rightmost_1bit(map)) {
+ dst_u32[raw_ctz(map)] |= *p++;
+ }
+}
+
+/* Returns a hash value for 'flow', given 'basis'. */
+static inline uint32_t
+miniflow_hash(const struct miniflow *flow, uint32_t basis)
+{
+ const uint32_t *values = miniflow_get_u32_values(flow);
+ const uint32_t *p = values;
+ uint32_t hash = basis;
+ uint64_t hash_map = 0;
+ uint64_t map;
+
+ for (map = flow->map; map; map = zero_rightmost_1bit(map)) {
+ if (*p) {
+ hash = mhash_add(hash, *p);
+ hash_map |= rightmost_1bit(map);
+ }
+ p++;
+ }
+ hash = mhash_add(hash, hash_map);
+ hash = mhash_add(hash, hash_map >> 32);
+
+ return mhash_finish(hash, p - values);
+}
+
+/* Returns a hash value for 'mask', given 'basis'. */
+static inline uint32_t
+minimask_hash(const struct minimask *mask, uint32_t basis)
+{
+ return miniflow_hash(&mask->masks, basis);
+}
+
+/* Returns a hash value for 'match', given 'basis'. */
+static inline uint32_t
+minimatch_hash(const struct minimatch *match, uint32_t basis)
+{
+ return miniflow_hash(&match->flow, minimask_hash(&match->mask, basis));
+}
+
+/* Returns a hash value for the bits of range [start, end) in 'minimatch',
+ * given 'basis'.
+ *
+ * The hash values returned by this function are the same as those returned by
+ * flow_hash_in_minimask_range(), only the form of the arguments differ. */
+static inline uint32_t
+minimatch_hash_range(const struct minimatch *match, uint8_t start, uint8_t end,
+ uint32_t *basis)
+{
+ unsigned int offset;
+ const uint32_t *p, *q;
+ uint32_t hash = *basis;
+ int n, i;
+
+ n = count_1bits(miniflow_get_map_in_range(&match->mask.masks, start, end,
+ &offset));
+ q = miniflow_get_u32_values(&match->mask.masks) + offset;
+ p = miniflow_get_u32_values(&match->flow) + offset;
+
+ for (i = 0; i < n; i++) {
+ hash = mhash_add(hash, p[i] & q[i]);
+ }
+ *basis = hash; /* Allow continuation from the unfinished value. */
+ return mhash_finish(hash, (offset + n) * 4);
+}
+
\f
/* cls_rule. */
{
minimatch_init(&rule->match, match);
rule->priority = priority;
+ rule->cls_match = NULL;
}
/* Same as cls_rule_init() for initialization from a "struct minimatch". */
{
minimatch_clone(&rule->match, match);
rule->priority = priority;
+ rule->cls_match = NULL;
}
/* Initializes 'dst' as a copy of 'src'.
{
minimatch_clone(&dst->match, &src->match);
dst->priority = src->priority;
+ dst->cls_match = NULL;
}
/* Initializes 'dst' with the data in 'src', destroying 'src'.
{
minimatch_move(&dst->match, &src->match);
dst->priority = src->priority;
+ dst->cls_match = NULL;
}
/* Frees memory referenced by 'rule'. Doesn't free 'rule' itself (it's
void
cls_rule_destroy(struct cls_rule *rule)
{
+ ovs_assert(!rule->cls_match);
minimatch_destroy(&rule->match);
}
/* Initializes 'cls' as a classifier that initially contains no classification
* rules. */
void
-classifier_init(struct classifier *cls, const uint8_t *flow_segments)
+classifier_init(struct classifier *cls_, const uint8_t *flow_segments)
{
+ struct cls_classifier *cls = xmalloc(sizeof *cls);
+
+ fat_rwlock_init(&cls_->rwlock);
+
+ cls_->cls = cls;
+
cls->n_rules = 0;
hmap_init(&cls->subtables);
- list_init(&cls->subtables_priority);
+ cls_subtable_cache_init(&cls->subtables_priority);
hmap_init(&cls->partitions);
- fat_rwlock_init(&cls->rwlock);
cls->n_flow_segments = 0;
if (flow_segments) {
while (cls->n_flow_segments < CLS_MAX_INDICES
/* Destroys 'cls'. Rules within 'cls', if any, are not freed; this is the
* caller's responsibility. */
void
-classifier_destroy(struct classifier *cls)
+classifier_destroy(struct classifier *cls_)
{
- if (cls) {
+ if (cls_) {
+ struct cls_classifier *cls = cls_->cls;
struct cls_subtable *partition, *next_partition;
struct cls_subtable *subtable, *next_subtable;
int i;
+ fat_rwlock_destroy(&cls_->rwlock);
+ if (!cls) {
+ return;
+ }
+
for (i = 0; i < cls->n_tries; i++) {
trie_destroy(cls->tries[i].root);
}
free(partition);
}
hmap_destroy(&cls->partitions);
- fat_rwlock_destroy(&cls->rwlock);
+
+ cls_subtable_cache_destroy(&cls->subtables_priority);
+ free(cls);
}
}
/* Set the fields for which prefix lookup should be performed. */
void
-classifier_set_prefix_fields(struct classifier *cls,
+classifier_set_prefix_fields(struct classifier *cls_,
const enum mf_field_id *trie_fields,
unsigned int n_fields)
{
+ struct cls_classifier *cls = cls_->cls;
uint64_t fields = 0;
int i, trie;
}
static void
-trie_init(struct classifier *cls, int trie_idx,
+trie_init(struct cls_classifier *cls, int trie_idx,
const struct mf_field *field)
{
struct cls_trie *trie = &cls->tries[trie_idx];
struct cls_subtable *subtable;
+ struct cls_subtable_entry *iter;
if (trie_idx < cls->n_tries) {
trie_destroy(trie->root);
trie->field = field;
/* Add existing rules to the trie. */
- LIST_FOR_EACH (subtable, list_node, &cls->subtables_priority) {
+ CLS_SUBTABLE_CACHE_FOR_EACH (subtable, iter, &cls->subtables_priority) {
unsigned int plen;
plen = field ? minimask_get_prefix_len(&subtable->mask, field) : 0;
subtable->trie_plen[trie_idx] = plen;
if (plen) {
- struct cls_rule *head;
+ struct cls_match *head;
HMAP_FOR_EACH (head, hmap_node, &subtable->rules) {
- struct cls_rule *rule;
+ struct cls_match *match;
- FOR_EACH_RULE_IN_LIST (rule, head) {
- trie_insert(trie, rule, plen);
+ FOR_EACH_RULE_IN_LIST (match, head) {
+ trie_insert(trie, match->cls_rule, plen);
}
}
}
bool
classifier_is_empty(const struct classifier *cls)
{
- return cls->n_rules == 0;
+ return cls->cls->n_rules == 0;
}
/* Returns the number of rules in 'cls'. */
int
classifier_count(const struct classifier *cls)
{
- return cls->n_rules;
+ return cls->cls->n_rules;
}
static uint32_t
}
static struct cls_partition *
-find_partition(const struct classifier *cls, ovs_be64 metadata, uint32_t hash)
+find_partition(const struct cls_classifier *cls, ovs_be64 metadata,
+ uint32_t hash)
{
struct cls_partition *partition;
}
static struct cls_partition *
-create_partition(struct classifier *cls, struct cls_subtable *subtable,
+create_partition(struct cls_classifier *cls, struct cls_subtable *subtable,
ovs_be64 metadata)
{
uint32_t hash = hash_metadata(metadata);
return partition;
}
+static inline ovs_be32 minimatch_get_ports(const struct minimatch *match)
+{
+ /* Could optimize to use the same map if needed for fast path. */
+ return MINIFLOW_GET_BE32(&match->flow, tp_src)
+ & MINIFLOW_GET_BE32(&match->mask.masks, tp_src);
+}
+
/* Inserts 'rule' into 'cls'. Until 'rule' is removed from 'cls', the caller
* must not modify or free it.
*
* 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)
+classifier_replace(struct classifier *cls_, struct cls_rule *rule)
{
- struct cls_rule *old_rule;
+ struct cls_classifier *cls = cls_->cls;
+ struct cls_match *old_rule;
struct cls_subtable *subtable;
subtable = find_subtable(cls, &rule->match.mask);
if (!old_rule) {
int i;
+ rule->cls_match->partition = NULL;
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, subtable, metadata);
- } else {
- rule->partition = NULL;
+ rule->cls_match->partition = create_partition(cls, subtable,
+ metadata);
}
subtable->n_rules++;
trie_insert(&cls->tries[i], rule, subtable->trie_plen[i]);
}
}
+
+ /* Ports trie. */
+ if (subtable->ports_mask_len) {
+ /* We mask the value to be inserted to always have the wildcarded
+ * bits in known (zero) state, so we can include them in comparison
+ * and they will always match (== their original value does not
+ * matter). */
+ ovs_be32 masked_ports = minimatch_get_ports(&rule->match);
+
+ trie_insert_prefix(&subtable->ports_trie, &masked_ports,
+ subtable->ports_mask_len);
+ }
+
+ return NULL;
} else {
- rule->partition = old_rule->partition;
+ struct cls_rule *old_cls_rule = old_rule->cls_rule;
+
+ rule->cls_match->partition = old_rule->partition;
+ old_cls_rule->cls_match = NULL;
+ free(old_rule);
+ return old_cls_rule;
}
- return old_rule;
}
/* Inserts 'rule' into 'cls'. Until 'rule' is removed from 'cls', the caller
* '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)
+classifier_remove(struct classifier *cls_, struct cls_rule *rule)
{
+ struct cls_classifier *cls = cls_->cls;
struct cls_partition *partition;
- struct cls_rule *head;
+ struct cls_match *cls_match = rule->cls_match;
+ struct cls_match *head;
struct cls_subtable *subtable;
int i;
+ ovs_assert(cls_match);
+
subtable = find_subtable(cls, &rule->match.mask);
+ ovs_assert(subtable);
+
+ if (subtable->ports_mask_len) {
+ ovs_be32 masked_ports = minimatch_get_ports(&rule->match);
+ trie_remove_prefix(&subtable->ports_trie,
+ &masked_ports, subtable->ports_mask_len);
+ }
for (i = 0; i < cls->n_tries; i++) {
if (subtable->trie_plen[i]) {
trie_remove(&cls->tries[i], rule, subtable->trie_plen[i]);
/* Remove rule node from indices. */
for (i = 0; i < subtable->n_indices; i++) {
- hindex_remove(&subtable->indices[i], &rule->index_nodes[i]);
+ hindex_remove(&subtable->indices[i], &cls_match->index_nodes[i]);
}
- 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(&subtable->rules, &rule->hmap_node);
+ head = find_equal(subtable, &rule->match.flow, cls_match->hmap_node.hash);
+ if (head != cls_match) {
+ list_remove(&cls_match->list);
+ } else if (list_is_empty(&cls_match->list)) {
+ hmap_remove(&subtable->rules, &cls_match->hmap_node);
} else {
- struct cls_rule *next = CONTAINER_OF(rule->list.next,
- struct cls_rule, list);
+ struct cls_match *next = CONTAINER_OF(cls_match->list.next,
+ struct cls_match, list);
- list_remove(&rule->list);
- hmap_replace(&subtable->rules, &rule->hmap_node, &next->hmap_node);
+ list_remove(&cls_match->list);
+ hmap_replace(&subtable->rules, &cls_match->hmap_node,
+ &next->hmap_node);
}
- partition = rule->partition;
+ partition = cls_match->partition;
if (partition) {
tag_tracker_subtract(&partition->tracker, &partition->tags,
subtable->tag);
if (--subtable->n_rules == 0) {
destroy_subtable(cls, subtable);
} else {
- update_subtables_after_removal(cls, subtable, rule->priority);
+ update_subtables_after_removal(cls, subtable, cls_match->priority);
}
cls->n_rules--;
+
+ rule->cls_match = NULL;
+ free(cls_match);
}
/* Prefix tree context. Valid when 'lookup_done' is true. Can skip all
ctx->lookup_done = false;
}
+static inline void
+lookahead_subtable(const struct cls_subtable_entry *subtables)
+{
+ ovs_prefetch_range(subtables->subtable, sizeof *subtables->subtable);
+}
+
/* 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.
* earlier, 'wc' should have been initialized (e.g., by
* flow_wildcards_init_catchall()). */
struct cls_rule *
-classifier_lookup(const struct classifier *cls, const struct flow *flow,
+classifier_lookup(const struct classifier *cls_, const struct flow *flow,
struct flow_wildcards *wc)
{
+ struct cls_classifier *cls = cls_->cls;
const struct cls_partition *partition;
- struct cls_subtable *subtable;
- struct cls_rule *best;
tag_type tags;
+ struct cls_match *best;
struct trie_ctx trie_ctx[CLS_MAX_TRIES];
int i;
+ struct cls_subtable_entry *subtables = cls->subtables_priority.subtables;
+ int n_subtables = cls->subtables_priority.size;
+ int64_t best_priority = -1;
+
+ /* Prefetch the subtables array. */
+ ovs_prefetch_range(subtables, n_subtables * sizeof *subtables);
/* Determine 'tags' such that, if 'subtable->tag' doesn't intersect them,
* then 'flow' cannot possibly match in 'subtable':
for (i = 0; i < cls->n_tries; i++) {
trie_ctx_init(&trie_ctx[i], &cls->tries[i]);
}
+
+ /* Prefetch the first subtables. */
+ if (n_subtables > 1) {
+ lookahead_subtable(subtables);
+ lookahead_subtable(subtables + 1);
+ }
+
best = NULL;
- LIST_FOR_EACH (subtable, list_node, &cls->subtables_priority) {
- struct cls_rule *rule;
+ for (i = 0; OVS_LIKELY(i < n_subtables); i++) {
+ struct cls_match *rule;
+
+ if ((int64_t)subtables[i].max_priority <= best_priority) {
+ /* Subtables are in descending priority order,
+ * can not find anything better. */
+ break;
+ }
- if (!tag_intersects(tags, subtable->tag)) {
+ /* Prefetch a forthcoming subtable. */
+ if (i + 2 < n_subtables) {
+ lookahead_subtable(&subtables[i + 2]);
+ }
+
+ if (!tag_intersects(tags, subtables[i].tag)) {
continue;
}
- rule = find_match_wc(subtable, flow, trie_ctx, cls->n_tries, wc);
- if (rule) {
+ rule = find_match_wc(subtables[i].subtable, flow, trie_ctx,
+ cls->n_tries, wc);
+ if (rule && (int64_t)rule->priority > best_priority) {
+ best_priority = (int64_t)rule->priority;
best = rule;
- 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, subtable->tag)) {
- continue;
- }
+ }
+ }
- rule = find_match_wc(subtable, flow, trie_ctx, cls->n_tries,
- wc);
- if (rule && rule->priority > best->priority) {
- best = rule;
- }
- }
- break;
+ return best ? best->cls_rule : NULL;
+}
+
+/* Returns true if 'target' satisifies 'match', that is, if each bit for which
+ * 'match' specifies a particular value has the correct value in 'target'.
+ *
+ * 'flow' and 'mask' have the same mask! */
+static bool
+miniflow_and_mask_matches_miniflow(const struct miniflow *flow,
+ const struct minimask *mask,
+ const struct miniflow *target)
+{
+ const uint32_t *flowp = miniflow_get_u32_values(flow);
+ const uint32_t *maskp = miniflow_get_u32_values(&mask->masks);
+ uint32_t target_u32;
+
+ MINIFLOW_FOR_EACH_IN_MAP(target_u32, target, mask->masks.map) {
+ if ((*flowp++ ^ target_u32) & *maskp++) {
+ return false;
}
}
- return best;
+ return true;
+}
+
+static inline struct cls_match *
+find_match_miniflow(const struct cls_subtable *subtable,
+ const struct miniflow *flow,
+ uint32_t hash)
+{
+ struct cls_match *rule;
+
+ HMAP_FOR_EACH_WITH_HASH (rule, hmap_node, hash, &subtable->rules) {
+ if (miniflow_and_mask_matches_miniflow(&rule->flow, &subtable->mask,
+ flow)) {
+ return rule;
+ }
+ }
+
+ return NULL;
+}
+
+/* Finds and returns the highest-priority rule in 'cls' that matches
+ * 'miniflow'. Returns a null pointer if no rules in 'cls' match 'flow'.
+ * If multiple rules of equal priority match 'flow', returns one arbitrarily.
+ *
+ * This function is optimized for the userspace datapath, which only ever has
+ * one priority value for it's flows!
+ */
+struct cls_rule *classifier_lookup_miniflow_first(const struct classifier *cls_,
+ const struct miniflow *flow)
+{
+ struct cls_classifier *cls = cls_->cls;
+ struct cls_subtable *subtable;
+ struct cls_subtable_entry *iter;
+
+ CLS_SUBTABLE_CACHE_FOR_EACH (subtable, iter, &cls->subtables_priority) {
+ struct cls_match *rule;
+
+ rule = find_match_miniflow(subtable, flow,
+ miniflow_hash_in_minimask(flow,
+ &subtable->mask,
+ 0));
+ if (rule) {
+ return rule->cls_rule;
+ }
+ }
+
+ return NULL;
}
/* 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,
+classifier_find_rule_exactly(const struct classifier *cls_,
const struct cls_rule *target)
{
- struct cls_rule *head, *rule;
+ struct cls_classifier *cls = cls_->cls;
+ struct cls_match *head, *rule;
struct cls_subtable *subtable;
subtable = find_subtable(cls, &target->match.mask);
&target->match.mask, 0));
FOR_EACH_RULE_IN_LIST (rule, head) {
if (target->priority >= rule->priority) {
- return target->priority == rule->priority ? rule : NULL;
+ return target->priority == rule->priority ? rule->cls_rule : NULL;
}
}
return NULL;
* considered to overlap if both rules have the same priority and a packet
* could match both. */
bool
-classifier_rule_overlaps(const struct classifier *cls,
+classifier_rule_overlaps(const struct classifier *cls_,
const struct cls_rule *target)
{
+ struct cls_classifier *cls = cls_->cls;
struct cls_subtable *subtable;
+ struct cls_subtable_entry *iter;
/* Iterate subtables in the descending max priority order. */
- LIST_FOR_EACH (subtable, list_node, &cls->subtables_priority) {
+ CLS_SUBTABLE_CACHE_FOR_EACH (subtable, iter, &cls->subtables_priority) {
uint32_t storage[FLOW_U32S];
struct minimask mask;
- struct cls_rule *head;
+ struct cls_match *head;
- if (target->priority > subtable->max_priority) {
+ if (target->priority > iter->max_priority) {
break; /* Can skip this and the rest of the subtables. */
}
minimask_combine(&mask, &target->match.mask, &subtable->mask, storage);
HMAP_FOR_EACH (head, hmap_node, &subtable->rules) {
- struct cls_rule *rule;
+ struct cls_match *rule;
FOR_EACH_RULE_IN_LIST (rule, head) {
if (rule->priority < target->priority) {
}
if (rule->priority == target->priority
&& miniflow_equal_in_minimask(&target->match.flow,
- &rule->match.flow, &mask)) {
+ &rule->flow, &mask)) {
return true;
}
}
/* Iteration. */
static bool
-rule_matches(const struct cls_rule *rule, const struct cls_rule *target)
+rule_matches(const struct cls_match *rule, const struct cls_rule *target)
{
return (!target
- || miniflow_equal_in_minimask(&rule->match.flow,
+ || miniflow_equal_in_minimask(&rule->flow,
&target->match.flow,
&target->match.mask));
}
-static struct cls_rule *
+static struct cls_match *
search_subtable(const struct cls_subtable *subtable,
const struct cls_rule *target)
{
if (!target || !minimask_has_extra(&subtable->mask, &target->match.mask)) {
- struct cls_rule *rule;
+ struct cls_match *rule;
HMAP_FOR_EACH (rule, hmap_node, &subtable->rules) {
if (rule_matches(rule, target)) {
cls_cursor_init(struct cls_cursor *cursor, const struct classifier *cls,
const struct cls_rule *target)
{
- cursor->cls = cls;
+ cursor->cls = cls->cls;
cursor->target = target && !cls_rule_is_catchall(target) ? target : NULL;
}
struct cls_subtable *subtable;
HMAP_FOR_EACH (subtable, hmap_node, &cursor->cls->subtables) {
- struct cls_rule *rule = search_subtable(subtable, cursor->target);
+ struct cls_match *rule = search_subtable(subtable, cursor->target);
if (rule) {
cursor->subtable = subtable;
- return rule;
+ return rule->cls_rule;
}
}
struct cls_rule *
cls_cursor_next(struct cls_cursor *cursor, const struct cls_rule *rule_)
{
- struct cls_rule *rule = CONST_CAST(struct cls_rule *, rule_);
+ struct cls_match *rule = CONST_CAST(struct cls_match *, rule_->cls_match);
const struct cls_subtable *subtable;
- struct cls_rule *next;
+ struct cls_match *next;
next = next_rule_in_list__(rule);
if (next->priority < rule->priority) {
- return next;
+ return next->cls_rule;
}
/* 'next' is the head of the list, that is, the rule that is included in
rule = next;
HMAP_FOR_EACH_CONTINUE (rule, hmap_node, &cursor->subtable->rules) {
if (rule_matches(rule, cursor->target)) {
- return rule;
+ return rule->cls_rule;
}
}
rule = search_subtable(subtable, cursor->target);
if (rule) {
cursor->subtable = subtable;
- return rule;
+ return rule->cls_rule;
}
}
}
\f
static struct cls_subtable *
-find_subtable(const struct classifier *cls, const struct minimask *mask)
+find_subtable(const struct cls_classifier *cls, const struct minimask *mask)
{
struct cls_subtable *subtable;
}
static struct cls_subtable *
-insert_subtable(struct classifier *cls, const struct minimask *mask)
+insert_subtable(struct cls_classifier *cls, const struct minimask *mask)
{
uint32_t hash = minimask_hash(mask, 0);
struct cls_subtable *subtable;
int i, index = 0;
struct flow_wildcards old, new;
uint8_t prev;
+ struct cls_subtable_entry elem;
+ int count = count_1bits(mask->masks.map);
- subtable = xzalloc(sizeof *subtable);
+ subtable = xzalloc(sizeof *subtable - sizeof mask->masks.inline_values
+ + MINIFLOW_VALUES_SIZE(count));
hmap_init(&subtable->rules);
- minimask_clone(&subtable->mask, mask);
+ miniflow_clone_inline(&subtable->mask.masks, &mask->masks, count);
/* Init indices for segmented lookup, if any. */
flow_wildcards_init_catchall(&new);
}
subtable->n_indices = index;
- hmap_insert(&cls->subtables, &subtable->hmap_node, hash);
- 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);
cls->tries[i].field);
}
+ /* Ports trie. */
+ subtable->ports_trie = NULL;
+ subtable->ports_mask_len
+ = 32 - ctz32(ntohl(MINIFLOW_GET_BE32(&mask->masks, tp_src)));
+
+ hmap_insert(&cls->subtables, &subtable->hmap_node, hash);
+ elem.subtable = subtable;
+ elem.tag = subtable->tag;
+ elem.max_priority = subtable->max_priority;
+ cls_subtable_cache_push_back(&cls->subtables_priority, elem);
+
return subtable;
}
static void
-destroy_subtable(struct classifier *cls, struct cls_subtable *subtable)
+destroy_subtable(struct cls_classifier *cls, struct cls_subtable *subtable)
{
int i;
+ struct cls_subtable *table = NULL;
+ struct cls_subtable_entry *iter;
+
+ CLS_SUBTABLE_CACHE_FOR_EACH (table, iter, &cls->subtables_priority) {
+ if (table == subtable) {
+ cls_subtable_cache_remove(&cls->subtables_priority, iter);
+ break;
+ }
+ }
+
+ trie_destroy(subtable->ports_trie);
for (i = 0; i < subtable->n_indices; i++) {
hindex_destroy(&subtable->indices[i]);
minimask_destroy(&subtable->mask);
hmap_remove(&cls->subtables, &subtable->hmap_node);
hmap_destroy(&subtable->rules);
- list_remove(&subtable->list_node);
free(subtable);
}
* 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_subtables_after_insertion(struct classifier *cls,
+update_subtables_after_insertion(struct cls_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;
+ struct cls_subtable *table;
+ struct cls_subtable_entry *iter, *subtable_iter = NULL;
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
+ * out of the loop, then 'subtable_iter' should be moved just before
* '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->subtables_priority) {
- if (iter->max_priority >= subtable->max_priority) {
+ * first list element and we'll move subtable just before that
+ * (e.g. to the front of the list). */
+ CLS_SUBTABLE_CACHE_FOR_EACH_REVERSE (table, iter, &cls->subtables_priority) {
+ if (table == subtable) {
+ subtable_iter = iter; /* Locate the subtable as we go. */
+ iter->max_priority = new_priority;
+ } else if (table->max_priority >= new_priority) {
+ ovs_assert(subtable_iter != NULL);
+ iter++;
break;
}
}
- /* Move 'subtable' just after 'iter' (unless it's already there). */
- if (iter->list_node.next != &subtable->list_node) {
- list_splice(iter->list_node.next,
- &subtable->list_node, subtable->list_node.next);
+ /* Move 'subtable' just before 'iter' (unless it's already there). */
+ if (iter != subtable_iter) {
+ cls_subtable_cache_splice(iter, subtable_iter, subtable_iter + 1);
}
}
}
* 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_subtables_after_removal(struct classifier *cls,
+update_subtables_after_removal(struct cls_classifier *cls,
struct cls_subtable *subtable,
unsigned int del_priority)
{
- struct cls_subtable *iter;
-
if (del_priority == subtable->max_priority && --subtable->max_count == 0) {
- struct cls_rule *head;
+ struct cls_match *head;
+ struct cls_subtable *table;
+ struct cls_subtable_entry *iter, *subtable_iter = NULL;
subtable->max_priority = 0;
HMAP_FOR_EACH (head, hmap_node, &subtable->rules) {
* '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) {
+ CLS_SUBTABLE_CACHE_FOR_EACH (table, iter, &cls->subtables_priority) {
+ if (table == subtable) {
+ subtable_iter = iter; /* Locate the subtable as we go. */
+ iter->max_priority = subtable->max_priority;
+ } else if (table->max_priority <= subtable->max_priority) {
+ ovs_assert(subtable_iter != NULL);
break;
}
}
/* Move 'subtable' just before 'iter' (unless it's already there). */
- if (iter->list_node.prev != &subtable->list_node) {
- list_splice(&iter->list_node,
- &subtable->list_node, subtable->list_node.next);
+ if (iter != subtable_iter) {
+ cls_subtable_cache_splice(iter, subtable_iter, subtable_iter + 1);
}
}
}
return false;
}
-static inline struct cls_rule *
+/* Returns true if 'target' satisifies 'flow'/'mask', that is, if each bit
+ * for which 'flow', for which 'mask' has a bit set, specifies a particular
+ * value has the correct value in 'target'.
+ *
+ * This function is equivalent to miniflow_equal_flow_in_minimask(flow,
+ * target, mask) but it is faster because of the invariant that
+ * flow->map and mask->masks.map are the same. */
+static inline bool
+miniflow_and_mask_matches_flow(const struct miniflow *flow,
+ const struct minimask *mask,
+ const struct flow *target)
+{
+ const uint32_t *flowp = miniflow_get_u32_values(flow);
+ const uint32_t *maskp = miniflow_get_u32_values(&mask->masks);
+ uint32_t target_u32;
+
+ FLOW_FOR_EACH_IN_MAP(target_u32, target, mask->masks.map) {
+ if ((*flowp++ ^ target_u32) & *maskp++) {
+ return false;
+ }
+ }
+
+ return true;
+}
+
+static inline struct cls_match *
find_match(const struct cls_subtable *subtable, const struct flow *flow,
uint32_t hash)
{
- struct cls_rule *rule;
+ struct cls_match *rule;
HMAP_FOR_EACH_WITH_HASH (rule, hmap_node, hash, &subtable->rules) {
- if (minimatch_matches_flow(&rule->match, flow)) {
+ if (miniflow_and_mask_matches_flow(&rule->flow, &subtable->mask,
+ flow)) {
return rule;
}
}
return NULL;
}
-static struct cls_rule *
+static struct cls_match *
find_match_wc(const struct cls_subtable *subtable, const struct flow *flow,
struct trie_ctx trie_ctx[CLS_MAX_TRIES], unsigned int n_tries,
struct flow_wildcards *wc)
{
uint32_t basis = 0, hash;
- struct cls_rule *rule = NULL;
+ struct cls_match *rule = NULL;
int i;
struct range ofs;
- if (!wc) {
+ if (OVS_UNLIKELY(!wc)) {
return find_match(subtable, flow,
flow_hash_in_minimask(flow, &subtable->mask, 0));
}
* not match, then we know that we will never get a match, but we do
* not yet know how many wildcards we need to fold into 'wc' so we
* continue iterating through indices to find that out. (We won't
- * waste time calling minimatch_matches_flow() again because we've set
- * 'rule' nonnull.)
+ * waste time calling miniflow_and_mask_matches_flow() again because
+ * we've set 'rule' nonnull.)
*
* This check shows a measurable benefit with non-trivial flow tables.
*
* optimization. */
if (!inode->s && !rule) {
ASSIGN_CONTAINER(rule, inode - i, index_nodes);
- if (minimatch_matches_flow(&rule->match, flow)) {
+ if (miniflow_and_mask_matches_flow(&rule->flow, &subtable->mask,
+ flow)) {
goto out;
}
}
* but it didn't match. */
rule = NULL;
}
+ if (!rule && subtable->ports_mask_len) {
+ /* Ports are always part of the final range, if any.
+ * No match was found for the ports. Use the ports trie to figure out
+ * which ports bits to unwildcard. */
+ unsigned int mbits;
+ ovs_be32 value, mask;
+
+ mask = MINIFLOW_GET_BE32(&subtable->mask.masks, tp_src);
+ value = ((OVS_FORCE ovs_be32 *)flow)[TP_PORTS_OFS32] & mask;
+ trie_lookup_value(subtable->ports_trie, &value, &mbits);
+
+ ((OVS_FORCE ovs_be32 *)&wc->masks)[TP_PORTS_OFS32] |=
+ mask & htonl(~0 << (32 - mbits));
+
+ ofs.start = TP_PORTS_OFS32;
+ goto range_out;
+ }
out:
/* Must unwildcard all the fields, as they were looked at. */
flow_wildcards_fold_minimask(wc, &subtable->mask);
return NULL;
}
-static struct cls_rule *
+static struct cls_match *
find_equal(struct cls_subtable *subtable, const struct miniflow *flow,
uint32_t hash)
{
- struct cls_rule *head;
+ struct cls_match *head;
HMAP_FOR_EACH_WITH_HASH (head, hmap_node, hash, &subtable->rules) {
- if (miniflow_equal(&head->match.flow, flow)) {
+ if (miniflow_equal(&head->flow, flow)) {
return head;
}
}
return NULL;
}
-static struct cls_rule *
-insert_rule(struct classifier *cls, struct cls_subtable *subtable,
+static struct cls_match *
+insert_rule(struct cls_classifier *cls, struct cls_subtable *subtable,
struct cls_rule *new)
{
- struct cls_rule *head;
- struct cls_rule *old = NULL;
+ struct cls_match *cls_match = cls_match_alloc(new);
+ struct cls_match *head;
+ struct cls_match *old = NULL;
int i;
uint32_t basis = 0, hash;
uint8_t prev_be32ofs = 0;
for (i = 0; i < subtable->n_indices; i++) {
hash = minimatch_hash_range(&new->match, prev_be32ofs,
subtable->index_ofs[i], &basis);
- hindex_insert(&subtable->indices[i], &new->index_nodes[i], hash);
+ hindex_insert(&subtable->indices[i], &cls_match->index_nodes[i], hash);
prev_be32ofs = subtable->index_ofs[i];
}
hash = minimatch_hash_range(&new->match, prev_be32ofs, FLOW_U32S, &basis);
head = find_equal(subtable, &new->match.flow, hash);
if (!head) {
- hmap_insert(&subtable->rules, &new->hmap_node, hash);
- list_init(&new->list);
+ hmap_insert(&subtable->rules, &cls_match->hmap_node, hash);
+ list_init(&cls_match->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;
+ struct cls_match *rule;
- new->hmap_node.hash = hash; /* Otherwise done by hmap_insert. */
+ cls_match->hmap_node.hash = hash; /* Otherwise done by hmap_insert. */
FOR_EACH_RULE_IN_LIST (rule, head) {
- if (new->priority >= rule->priority) {
+ if (cls_match->priority >= rule->priority) {
if (rule == head) {
/* 'new' is the new highest-priority flow in the list. */
hmap_replace(&subtable->rules,
- &rule->hmap_node, &new->hmap_node);
+ &rule->hmap_node, &cls_match->hmap_node);
}
- if (new->priority == rule->priority) {
- list_replace(&new->list, &rule->list);
+ if (cls_match->priority == rule->priority) {
+ list_replace(&cls_match->list, &rule->list);
old = rule;
goto out;
} else {
- list_insert(&rule->list, &new->list);
+ list_insert(&rule->list, &cls_match->list);
goto out;
}
}
}
/* Insert 'new' at the end of the list. */
- list_push_back(&head->list, &new->list);
+ list_push_back(&head->list, &cls_match->list);
}
out:
if (!old) {
- update_subtables_after_insertion(cls, subtable, new->priority);
+ update_subtables_after_insertion(cls, subtable, cls_match->priority);
} else {
/* Remove old node from indices. */
for (i = 0; i < subtable->n_indices; i++) {
return old;
}
-static struct cls_rule *
-next_rule_in_list__(struct cls_rule *rule)
+static struct cls_match *
+next_rule_in_list__(struct cls_match *rule)
{
- struct cls_rule *next = OBJECT_CONTAINING(rule->list.next, next, list);
+ struct cls_match *next = OBJECT_CONTAINING(rule->list.next, next, list);
return next;
}
-static struct cls_rule *
-next_rule_in_list(struct cls_rule *rule)
+static struct cls_match *
+next_rule_in_list(struct cls_match *rule)
{
- struct cls_rule *next = next_rule_in_list__(rule);
+ struct cls_match *next = next_rule_in_list__(rule);
return next->priority < rule->priority ? next : NULL;
}
\f
static const ovs_be32 *
minimatch_get_prefix(const struct minimatch *match, const struct mf_field *mf)
{
- return (OVS_FORCE const ovs_be32 *)match->flow.values +
+ return miniflow_get_be32_values(&match->flow) +
count_1bits(match->flow.map & ((UINT64_C(1) << mf->flow_be32ofs) - 1));
}
static void
trie_insert(struct cls_trie *trie, const struct cls_rule *rule, int mlen)
{
- const ovs_be32 *prefix = minimatch_get_prefix(&rule->match, trie->field);
+ trie_insert_prefix(&trie->root,
+ minimatch_get_prefix(&rule->match, trie->field), mlen);
+}
+
+static void
+trie_insert_prefix(struct trie_node **edge, const ovs_be32 *prefix, int mlen)
+{
struct trie_node *node;
- struct trie_node **edge;
int ofs = 0;
/* Walk the tree. */
- for (edge = &trie->root;
- (node = *edge) != NULL;
+ for (; (node = *edge) != NULL;
edge = trie_next_edge(node, prefix, ofs)) {
unsigned int eqbits = trie_prefix_equal_bits(node, prefix, ofs, mlen);
ofs += eqbits;
static void
trie_remove(struct cls_trie *trie, const struct cls_rule *rule, int mlen)
{
- const ovs_be32 *prefix = minimatch_get_prefix(&rule->match, trie->field);
+ trie_remove_prefix(&trie->root,
+ minimatch_get_prefix(&rule->match, trie->field), mlen);
+}
+
+/* 'mlen' must be the (non-zero) CIDR prefix length of the 'trie->field' mask
+ * in 'rule'. */
+static void
+trie_remove_prefix(struct trie_node **root, const ovs_be32 *prefix, int mlen)
+{
struct trie_node *node;
struct trie_node **edges[sizeof(union mf_value) * 8];
int depth = 0, ofs = 0;
/* Walk the tree. */
- for (edges[depth] = &trie->root;
+ for (edges[0] = root;
(node = *edges[depth]) != NULL;
edges[++depth] = trie_next_edge(node, prefix, ofs)) {
unsigned int eqbits = trie_prefix_equal_bits(node, prefix, ofs, mlen);
+
if (eqbits < node->nbits) {
/* Mismatch, nothing to be removed. This should never happen, as
* only rules in the classifier are ever removed. */
git://git.onelab.eu / sliver-openvswitch.git / blobdiff