2 * Copyright (c) 2009, 2010, 2011, 2012 Nicira, Inc.
4 * Licensed under the Apache License, Version 2.0 (the "License");
5 * you may not use this file except in compliance with the License.
6 * You may obtain a copy of the License at:
8 * http://www.apache.org/licenses/LICENSE-2.0
10 * Unless required by applicable law or agreed to in writing, software
11 * distributed under the License is distributed on an "AS IS" BASIS,
12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13 * See the License for the specific language governing permissions and
14 * limitations under the License.
17 /* "White box" tests for classifier.
19 * With very few exceptions, these tests obtain complete coverage of every
20 * basic block and every branch in the classifier implementation, e.g. a clean
21 * report from "gcov -b". (Covering the exceptions would require finding
22 * collisions in the hash function used for flow data, etc.)
24 * This test should receive a clean report from "valgrind --leak-check=full":
25 * it frees every heap block that it allocates.
29 #include "classifier.h"
32 #include "byte-order.h"
33 #include "command-line.h"
37 #include "unaligned.h"
42 /* Fields in a rule. */
44 /* struct flow all-caps */ \
45 /* member name name */ \
46 /* ----------- -------- */ \
47 CLS_FIELD(tunnel.tun_id, TUN_ID) \
48 CLS_FIELD(metadata, METADATA) \
49 CLS_FIELD(nw_src, NW_SRC) \
50 CLS_FIELD(nw_dst, NW_DST) \
51 CLS_FIELD(in_port, IN_PORT) \
52 CLS_FIELD(vlan_tci, VLAN_TCI) \
53 CLS_FIELD(dl_type, DL_TYPE) \
54 CLS_FIELD(tp_src, TP_SRC) \
55 CLS_FIELD(tp_dst, TP_DST) \
56 CLS_FIELD(dl_src, DL_SRC) \
57 CLS_FIELD(dl_dst, DL_DST) \
58 CLS_FIELD(nw_proto, NW_PROTO) \
59 CLS_FIELD(nw_tos, NW_DSCP)
63 * (These are also indexed into struct classifier's 'tables' array.) */
65 #define CLS_FIELD(MEMBER, NAME) CLS_F_IDX_##NAME,
71 /* Field information. */
73 int ofs; /* Offset in struct flow. */
74 int len; /* Length in bytes. */
75 const char *name; /* Name (for debugging). */
78 static const struct cls_field cls_fields[CLS_N_FIELDS] = {
79 #define CLS_FIELD(MEMBER, NAME) \
80 { offsetof(struct flow, MEMBER), \
81 sizeof ((struct flow *)0)->MEMBER, \
88 int aux; /* Auxiliary data. */
89 struct cls_rule cls_rule; /* Classifier rule data. */
92 static struct test_rule *
93 test_rule_from_cls_rule(const struct cls_rule *rule)
95 return rule ? CONTAINER_OF(rule, struct test_rule, cls_rule) : NULL;
99 test_rule_destroy(struct test_rule *rule)
102 cls_rule_destroy(&rule->cls_rule);
107 static struct test_rule *make_rule(int wc_fields, unsigned int priority,
109 static void free_rule(struct test_rule *);
110 static struct test_rule *clone_rule(const struct test_rule *);
112 /* Trivial (linear) classifier. */
115 size_t allocated_rules;
116 struct test_rule **rules;
120 tcls_init(struct tcls *tcls)
123 tcls->allocated_rules = 0;
128 tcls_destroy(struct tcls *tcls)
133 for (i = 0; i < tcls->n_rules; i++) {
134 test_rule_destroy(tcls->rules[i]);
141 tcls_is_empty(const struct tcls *tcls)
143 return tcls->n_rules == 0;
146 static struct test_rule *
147 tcls_insert(struct tcls *tcls, const struct test_rule *rule)
151 for (i = 0; i < tcls->n_rules; i++) {
152 const struct cls_rule *pos = &tcls->rules[i]->cls_rule;
153 if (cls_rule_equal(pos, &rule->cls_rule)) {
155 free_rule(tcls->rules[i]);
156 tcls->rules[i] = clone_rule(rule);
157 return tcls->rules[i];
158 } else if (pos->priority < rule->cls_rule.priority) {
163 if (tcls->n_rules >= tcls->allocated_rules) {
164 tcls->rules = x2nrealloc(tcls->rules, &tcls->allocated_rules,
165 sizeof *tcls->rules);
167 if (i != tcls->n_rules) {
168 memmove(&tcls->rules[i + 1], &tcls->rules[i],
169 sizeof *tcls->rules * (tcls->n_rules - i));
171 tcls->rules[i] = clone_rule(rule);
173 return tcls->rules[i];
177 tcls_remove(struct tcls *cls, const struct test_rule *rule)
181 for (i = 0; i < cls->n_rules; i++) {
182 struct test_rule *pos = cls->rules[i];
184 test_rule_destroy(pos);
186 memmove(&cls->rules[i], &cls->rules[i + 1],
187 sizeof *cls->rules * (cls->n_rules - i - 1));
197 match(const struct cls_rule *wild_, const struct flow *fixed)
202 minimatch_expand(&wild_->match, &wild);
203 for (f_idx = 0; f_idx < CLS_N_FIELDS; f_idx++) {
206 if (f_idx == CLS_F_IDX_NW_SRC) {
207 eq = !((fixed->nw_src ^ wild.flow.nw_src)
208 & wild.wc.masks.nw_src);
209 } else if (f_idx == CLS_F_IDX_NW_DST) {
210 eq = !((fixed->nw_dst ^ wild.flow.nw_dst)
211 & wild.wc.masks.nw_dst);
212 } else if (f_idx == CLS_F_IDX_TP_SRC) {
213 eq = !((fixed->tp_src ^ wild.flow.tp_src)
214 & wild.wc.masks.tp_src);
215 } else if (f_idx == CLS_F_IDX_TP_DST) {
216 eq = !((fixed->tp_dst ^ wild.flow.tp_dst)
217 & wild.wc.masks.tp_dst);
218 } else if (f_idx == CLS_F_IDX_DL_SRC) {
219 eq = eth_addr_equal_except(fixed->dl_src, wild.flow.dl_src,
220 wild.wc.masks.dl_src);
221 } else if (f_idx == CLS_F_IDX_DL_DST) {
222 eq = eth_addr_equal_except(fixed->dl_dst, wild.flow.dl_dst,
223 wild.wc.masks.dl_dst);
224 } else if (f_idx == CLS_F_IDX_VLAN_TCI) {
225 eq = !((fixed->vlan_tci ^ wild.flow.vlan_tci)
226 & wild.wc.masks.vlan_tci);
227 } else if (f_idx == CLS_F_IDX_TUN_ID) {
228 eq = !((fixed->tunnel.tun_id ^ wild.flow.tunnel.tun_id)
229 & wild.wc.masks.tunnel.tun_id);
230 } else if (f_idx == CLS_F_IDX_METADATA) {
231 eq = !((fixed->metadata ^ wild.flow.metadata)
232 & wild.wc.masks.metadata);
233 } else if (f_idx == CLS_F_IDX_NW_DSCP) {
234 eq = !((fixed->nw_tos ^ wild.flow.nw_tos) &
235 (wild.wc.masks.nw_tos & IP_DSCP_MASK));
236 } else if (f_idx == CLS_F_IDX_NW_PROTO) {
237 eq = !((fixed->nw_proto ^ wild.flow.nw_proto)
238 & wild.wc.masks.nw_proto);
239 } else if (f_idx == CLS_F_IDX_DL_TYPE) {
240 eq = !((fixed->dl_type ^ wild.flow.dl_type)
241 & wild.wc.masks.dl_type);
242 } else if (f_idx == CLS_F_IDX_IN_PORT) {
243 eq = !((fixed->in_port ^ wild.flow.in_port)
244 & wild.wc.masks.in_port);
256 static struct cls_rule *
257 tcls_lookup(const struct tcls *cls, const struct flow *flow)
261 for (i = 0; i < cls->n_rules; i++) {
262 struct test_rule *pos = cls->rules[i];
263 if (match(&pos->cls_rule, flow)) {
264 return &pos->cls_rule;
271 tcls_delete_matches(struct tcls *cls, const struct cls_rule *target)
275 for (i = 0; i < cls->n_rules; ) {
276 struct test_rule *pos = cls->rules[i];
277 if (!minimask_has_extra(&pos->cls_rule.match.mask,
278 &target->match.mask)) {
281 miniflow_expand(&pos->cls_rule.match.flow, &flow);
282 if (match(target, &flow)) {
283 tcls_remove(cls, pos);
291 static ovs_be32 nw_src_values[] = { CONSTANT_HTONL(0xc0a80001),
292 CONSTANT_HTONL(0xc0a04455) };
293 static ovs_be32 nw_dst_values[] = { CONSTANT_HTONL(0xc0a80002),
294 CONSTANT_HTONL(0xc0a04455) };
295 static ovs_be64 tun_id_values[] = {
297 CONSTANT_HTONLL(UINT64_C(0xfedcba9876543210)) };
298 static ovs_be64 metadata_values[] = {
300 CONSTANT_HTONLL(UINT64_C(0xfedcba9876543210)) };
301 static uint16_t in_port_values[] = { 1, OFPP_LOCAL };
302 static ovs_be16 vlan_tci_values[] = { CONSTANT_HTONS(101), CONSTANT_HTONS(0) };
303 static ovs_be16 dl_type_values[]
304 = { CONSTANT_HTONS(ETH_TYPE_IP), CONSTANT_HTONS(ETH_TYPE_ARP) };
305 static ovs_be16 tp_src_values[] = { CONSTANT_HTONS(49362),
306 CONSTANT_HTONS(80) };
307 static ovs_be16 tp_dst_values[] = { CONSTANT_HTONS(6667), CONSTANT_HTONS(22) };
308 static uint8_t dl_src_values[][6] = { { 0x00, 0x02, 0xe3, 0x0f, 0x80, 0xa4 },
309 { 0x5e, 0x33, 0x7f, 0x5f, 0x1e, 0x99 } };
310 static uint8_t dl_dst_values[][6] = { { 0x4a, 0x27, 0x71, 0xae, 0x64, 0xc1 },
311 { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff } };
312 static uint8_t nw_proto_values[] = { IPPROTO_TCP, IPPROTO_ICMP };
313 static uint8_t nw_dscp_values[] = { 48, 0 };
315 static void *values[CLS_N_FIELDS][2];
320 values[CLS_F_IDX_TUN_ID][0] = &tun_id_values[0];
321 values[CLS_F_IDX_TUN_ID][1] = &tun_id_values[1];
323 values[CLS_F_IDX_METADATA][0] = &metadata_values[0];
324 values[CLS_F_IDX_METADATA][1] = &metadata_values[1];
326 values[CLS_F_IDX_IN_PORT][0] = &in_port_values[0];
327 values[CLS_F_IDX_IN_PORT][1] = &in_port_values[1];
329 values[CLS_F_IDX_VLAN_TCI][0] = &vlan_tci_values[0];
330 values[CLS_F_IDX_VLAN_TCI][1] = &vlan_tci_values[1];
332 values[CLS_F_IDX_DL_SRC][0] = dl_src_values[0];
333 values[CLS_F_IDX_DL_SRC][1] = dl_src_values[1];
335 values[CLS_F_IDX_DL_DST][0] = dl_dst_values[0];
336 values[CLS_F_IDX_DL_DST][1] = dl_dst_values[1];
338 values[CLS_F_IDX_DL_TYPE][0] = &dl_type_values[0];
339 values[CLS_F_IDX_DL_TYPE][1] = &dl_type_values[1];
341 values[CLS_F_IDX_NW_SRC][0] = &nw_src_values[0];
342 values[CLS_F_IDX_NW_SRC][1] = &nw_src_values[1];
344 values[CLS_F_IDX_NW_DST][0] = &nw_dst_values[0];
345 values[CLS_F_IDX_NW_DST][1] = &nw_dst_values[1];
347 values[CLS_F_IDX_NW_PROTO][0] = &nw_proto_values[0];
348 values[CLS_F_IDX_NW_PROTO][1] = &nw_proto_values[1];
350 values[CLS_F_IDX_NW_DSCP][0] = &nw_dscp_values[0];
351 values[CLS_F_IDX_NW_DSCP][1] = &nw_dscp_values[1];
353 values[CLS_F_IDX_TP_SRC][0] = &tp_src_values[0];
354 values[CLS_F_IDX_TP_SRC][1] = &tp_src_values[1];
356 values[CLS_F_IDX_TP_DST][0] = &tp_dst_values[0];
357 values[CLS_F_IDX_TP_DST][1] = &tp_dst_values[1];
360 #define N_NW_SRC_VALUES ARRAY_SIZE(nw_src_values)
361 #define N_NW_DST_VALUES ARRAY_SIZE(nw_dst_values)
362 #define N_TUN_ID_VALUES ARRAY_SIZE(tun_id_values)
363 #define N_METADATA_VALUES ARRAY_SIZE(metadata_values)
364 #define N_IN_PORT_VALUES ARRAY_SIZE(in_port_values)
365 #define N_VLAN_TCI_VALUES ARRAY_SIZE(vlan_tci_values)
366 #define N_DL_TYPE_VALUES ARRAY_SIZE(dl_type_values)
367 #define N_TP_SRC_VALUES ARRAY_SIZE(tp_src_values)
368 #define N_TP_DST_VALUES ARRAY_SIZE(tp_dst_values)
369 #define N_DL_SRC_VALUES ARRAY_SIZE(dl_src_values)
370 #define N_DL_DST_VALUES ARRAY_SIZE(dl_dst_values)
371 #define N_NW_PROTO_VALUES ARRAY_SIZE(nw_proto_values)
372 #define N_NW_DSCP_VALUES ARRAY_SIZE(nw_dscp_values)
374 #define N_FLOW_VALUES (N_NW_SRC_VALUES * \
378 N_VLAN_TCI_VALUES * \
384 N_NW_PROTO_VALUES * \
388 get_value(unsigned int *x, unsigned n_values)
390 unsigned int rem = *x % n_values;
396 compare_classifiers(struct classifier *cls, struct tcls *tcls)
398 static const int confidence = 500;
401 assert(classifier_count(cls) == tcls->n_rules);
402 for (i = 0; i < confidence; i++) {
403 struct cls_rule *cr0, *cr1;
407 x = rand () % N_FLOW_VALUES;
408 memset(&flow, 0, sizeof flow);
409 flow.nw_src = nw_src_values[get_value(&x, N_NW_SRC_VALUES)];
410 flow.nw_dst = nw_dst_values[get_value(&x, N_NW_DST_VALUES)];
411 flow.tunnel.tun_id = tun_id_values[get_value(&x, N_TUN_ID_VALUES)];
412 flow.metadata = metadata_values[get_value(&x, N_METADATA_VALUES)];
413 flow.in_port = in_port_values[get_value(&x, N_IN_PORT_VALUES)];
414 flow.vlan_tci = vlan_tci_values[get_value(&x, N_VLAN_TCI_VALUES)];
415 flow.dl_type = dl_type_values[get_value(&x, N_DL_TYPE_VALUES)];
416 flow.tp_src = tp_src_values[get_value(&x, N_TP_SRC_VALUES)];
417 flow.tp_dst = tp_dst_values[get_value(&x, N_TP_DST_VALUES)];
418 memcpy(flow.dl_src, dl_src_values[get_value(&x, N_DL_SRC_VALUES)],
420 memcpy(flow.dl_dst, dl_dst_values[get_value(&x, N_DL_DST_VALUES)],
422 flow.nw_proto = nw_proto_values[get_value(&x, N_NW_PROTO_VALUES)];
423 flow.nw_tos = nw_dscp_values[get_value(&x, N_NW_DSCP_VALUES)];
425 cr0 = classifier_lookup(cls, &flow);
426 cr1 = tcls_lookup(tcls, &flow);
427 assert((cr0 == NULL) == (cr1 == NULL));
429 const struct test_rule *tr0 = test_rule_from_cls_rule(cr0);
430 const struct test_rule *tr1 = test_rule_from_cls_rule(cr1);
432 assert(cls_rule_equal(cr0, cr1));
433 assert(tr0->aux == tr1->aux);
439 destroy_classifier(struct classifier *cls)
441 struct test_rule *rule, *next_rule;
442 struct cls_cursor cursor;
444 cls_cursor_init(&cursor, cls, NULL);
445 CLS_CURSOR_FOR_EACH_SAFE (rule, next_rule, cls_rule, &cursor) {
446 classifier_remove(cls, &rule->cls_rule);
449 classifier_destroy(cls);
453 check_tables(const struct classifier *cls,
454 int n_tables, int n_rules, int n_dups)
456 const struct cls_table *table;
457 struct test_rule *test_rule;
458 struct cls_cursor cursor;
459 int found_tables = 0;
462 int found_rules2 = 0;
464 HMAP_FOR_EACH (table, hmap_node, &cls->tables) {
465 const struct cls_rule *head;
467 assert(!hmap_is_empty(&table->rules));
470 HMAP_FOR_EACH (head, hmap_node, &table->rules) {
471 unsigned int prev_priority = UINT_MAX;
472 const struct cls_rule *rule;
475 LIST_FOR_EACH (rule, list, &head->list) {
476 assert(rule->priority < prev_priority);
477 prev_priority = rule->priority;
480 assert(classifier_find_rule_exactly(cls, rule) == rule);
485 assert(found_tables == hmap_count(&cls->tables));
486 assert(n_tables == -1 || n_tables == hmap_count(&cls->tables));
487 assert(n_rules == -1 || found_rules == n_rules);
488 assert(n_dups == -1 || found_dups == n_dups);
490 cls_cursor_init(&cursor, cls, NULL);
491 CLS_CURSOR_FOR_EACH (test_rule, cls_rule, &cursor) {
494 assert(found_rules == found_rules2);
497 static struct test_rule *
498 make_rule(int wc_fields, unsigned int priority, int value_pat)
500 const struct cls_field *f;
501 struct test_rule *rule;
504 match_init_catchall(&match);
505 for (f = &cls_fields[0]; f < &cls_fields[CLS_N_FIELDS]; f++) {
506 int f_idx = f - cls_fields;
507 int value_idx = (value_pat & (1u << f_idx)) != 0;
508 memcpy((char *) &match.flow + f->ofs,
509 values[f_idx][value_idx], f->len);
511 if (f_idx == CLS_F_IDX_NW_SRC) {
512 match.wc.masks.nw_src = htonl(UINT32_MAX);
513 } else if (f_idx == CLS_F_IDX_NW_DST) {
514 match.wc.masks.nw_dst = htonl(UINT32_MAX);
515 } else if (f_idx == CLS_F_IDX_TP_SRC) {
516 match.wc.masks.tp_src = htons(UINT16_MAX);
517 } else if (f_idx == CLS_F_IDX_TP_DST) {
518 match.wc.masks.tp_dst = htons(UINT16_MAX);
519 } else if (f_idx == CLS_F_IDX_DL_SRC) {
520 memset(match.wc.masks.dl_src, 0xff, ETH_ADDR_LEN);
521 } else if (f_idx == CLS_F_IDX_DL_DST) {
522 memset(match.wc.masks.dl_dst, 0xff, ETH_ADDR_LEN);
523 } else if (f_idx == CLS_F_IDX_VLAN_TCI) {
524 match.wc.masks.vlan_tci = htons(UINT16_MAX);
525 } else if (f_idx == CLS_F_IDX_TUN_ID) {
526 match.wc.masks.tunnel.tun_id = htonll(UINT64_MAX);
527 } else if (f_idx == CLS_F_IDX_METADATA) {
528 match.wc.masks.metadata = htonll(UINT64_MAX);
529 } else if (f_idx == CLS_F_IDX_NW_DSCP) {
530 match.wc.masks.nw_tos |= IP_DSCP_MASK;
531 } else if (f_idx == CLS_F_IDX_NW_PROTO) {
532 match.wc.masks.nw_proto = UINT8_MAX;
533 } else if (f_idx == CLS_F_IDX_DL_TYPE) {
534 match.wc.masks.dl_type = htons(UINT16_MAX);
535 } else if (f_idx == CLS_F_IDX_IN_PORT) {
536 match.wc.masks.in_port = UINT16_MAX;
542 rule = xzalloc(sizeof *rule);
543 cls_rule_init(&rule->cls_rule, &match, wc_fields ? priority : UINT_MAX);
547 static struct test_rule *
548 clone_rule(const struct test_rule *src)
550 struct test_rule *dst;
552 dst = xmalloc(sizeof *dst);
554 cls_rule_clone(&dst->cls_rule, &src->cls_rule);
559 free_rule(struct test_rule *rule)
561 cls_rule_destroy(&rule->cls_rule);
566 shuffle(unsigned int *p, size_t n)
568 for (; n > 1; n--, p++) {
569 unsigned int *q = &p[rand() % n];
570 unsigned int tmp = *p;
577 shuffle_u32s(uint32_t *p, size_t n)
579 for (; n > 1; n--, p++) {
580 uint32_t *q = &p[rand() % n];
587 /* Classifier tests. */
589 /* Tests an empty classifier. */
591 test_empty(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
593 struct classifier cls;
596 classifier_init(&cls);
598 assert(classifier_is_empty(&cls));
599 assert(tcls_is_empty(&tcls));
600 compare_classifiers(&cls, &tcls);
601 classifier_destroy(&cls);
605 /* Destroys a null classifier. */
607 test_destroy_null(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
609 classifier_destroy(NULL);
612 /* Tests classification with one rule at a time. */
614 test_single_rule(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
616 unsigned int wc_fields; /* Hilarious. */
618 for (wc_fields = 0; wc_fields < (1u << CLS_N_FIELDS); wc_fields++) {
619 struct classifier cls;
620 struct test_rule *rule, *tcls_rule;
623 rule = make_rule(wc_fields,
624 hash_bytes(&wc_fields, sizeof wc_fields, 0), 0);
626 classifier_init(&cls);
629 tcls_rule = tcls_insert(&tcls, rule);
630 classifier_insert(&cls, &rule->cls_rule);
631 check_tables(&cls, 1, 1, 0);
632 compare_classifiers(&cls, &tcls);
634 classifier_remove(&cls, &rule->cls_rule);
635 tcls_remove(&tcls, tcls_rule);
636 assert(classifier_is_empty(&cls));
637 assert(tcls_is_empty(&tcls));
638 compare_classifiers(&cls, &tcls);
641 classifier_destroy(&cls);
646 /* Tests replacing one rule by another. */
648 test_rule_replacement(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
650 unsigned int wc_fields;
652 for (wc_fields = 0; wc_fields < (1u << CLS_N_FIELDS); wc_fields++) {
653 struct classifier cls;
654 struct test_rule *rule1;
655 struct test_rule *rule2;
658 rule1 = make_rule(wc_fields, OFP_DEFAULT_PRIORITY, UINT_MAX);
659 rule2 = make_rule(wc_fields, OFP_DEFAULT_PRIORITY, UINT_MAX);
663 classifier_init(&cls);
665 tcls_insert(&tcls, rule1);
666 classifier_insert(&cls, &rule1->cls_rule);
667 check_tables(&cls, 1, 1, 0);
668 compare_classifiers(&cls, &tcls);
672 tcls_insert(&tcls, rule2);
673 assert(test_rule_from_cls_rule(
674 classifier_replace(&cls, &rule2->cls_rule)) == rule1);
676 check_tables(&cls, 1, 1, 0);
677 compare_classifiers(&cls, &tcls);
679 destroy_classifier(&cls);
684 factorial(int n_items)
689 for (i = 2; i <= n_items; i++) {
704 reverse(int *a, int n)
708 for (i = 0; i < n / 2; i++) {
715 next_permutation(int *a, int n)
719 for (k = n - 2; k >= 0; k--) {
720 if (a[k] < a[k + 1]) {
723 for (l = n - 1; ; l--) {
726 reverse(a + (k + 1), n - (k + 1));
735 /* Tests classification with rules that have the same matching criteria. */
737 test_many_rules_in_one_list (int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
739 enum { N_RULES = 3 };
742 for (n_pris = N_RULES; n_pris >= 1; n_pris--) {
743 int ops[N_RULES * 2];
749 for (i = 1; i < N_RULES; i++) {
750 pris[i] = pris[i - 1] + (n_pris > i);
753 for (i = 0; i < N_RULES * 2; i++) {
759 struct test_rule *rules[N_RULES];
760 struct test_rule *tcls_rules[N_RULES];
761 int pri_rules[N_RULES];
762 struct classifier cls;
767 for (i = 0; i < N_RULES; i++) {
768 rules[i] = make_rule(456, pris[i], 0);
769 tcls_rules[i] = NULL;
773 classifier_init(&cls);
776 for (i = 0; i < ARRAY_SIZE(ops); i++) {
780 if (!tcls_rules[j]) {
781 struct test_rule *displaced_rule;
783 tcls_rules[j] = tcls_insert(&tcls, rules[j]);
784 displaced_rule = test_rule_from_cls_rule(
785 classifier_replace(&cls, &rules[j]->cls_rule));
786 if (pri_rules[pris[j]] >= 0) {
787 int k = pri_rules[pris[j]];
788 assert(displaced_rule != NULL);
789 assert(displaced_rule != rules[j]);
790 assert(pris[j] == displaced_rule->cls_rule.priority);
791 tcls_rules[k] = NULL;
793 assert(displaced_rule == NULL);
795 pri_rules[pris[j]] = j;
797 classifier_remove(&cls, &rules[j]->cls_rule);
798 tcls_remove(&tcls, tcls_rules[j]);
799 tcls_rules[j] = NULL;
800 pri_rules[pris[j]] = -1;
804 for (m = 0; m < N_RULES; m++) {
805 n += tcls_rules[m] != NULL;
807 check_tables(&cls, n > 0, n, n - 1);
809 compare_classifiers(&cls, &tcls);
812 classifier_destroy(&cls);
815 for (i = 0; i < N_RULES; i++) {
818 } while (next_permutation(ops, ARRAY_SIZE(ops)));
819 assert(n_permutations == (factorial(N_RULES * 2) >> N_RULES));
824 count_ones(unsigned long int x)
829 x = zero_rightmost_1bit(x);
837 array_contains(int *array, int n, int value)
841 for (i = 0; i < n; i++) {
842 if (array[i] == value) {
850 /* Tests classification with two rules at a time that fall into the same
851 * table but different lists. */
853 test_many_rules_in_one_table(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
857 for (iteration = 0; iteration < 50; iteration++) {
858 enum { N_RULES = 20 };
859 struct test_rule *rules[N_RULES];
860 struct test_rule *tcls_rules[N_RULES];
861 struct classifier cls;
863 int value_pats[N_RULES];
869 wcf = rand() & ((1u << CLS_N_FIELDS) - 1);
870 value_mask = ~wcf & ((1u << CLS_N_FIELDS) - 1);
871 } while ((1 << count_ones(value_mask)) < N_RULES);
873 classifier_init(&cls);
876 for (i = 0; i < N_RULES; i++) {
877 unsigned int priority = rand();
880 value_pats[i] = rand() & value_mask;
881 } while (array_contains(value_pats, i, value_pats[i]));
883 rules[i] = make_rule(wcf, priority, value_pats[i]);
884 tcls_rules[i] = tcls_insert(&tcls, rules[i]);
885 classifier_insert(&cls, &rules[i]->cls_rule);
887 check_tables(&cls, 1, i + 1, 0);
888 compare_classifiers(&cls, &tcls);
891 for (i = 0; i < N_RULES; i++) {
892 tcls_remove(&tcls, tcls_rules[i]);
893 classifier_remove(&cls, &rules[i]->cls_rule);
896 check_tables(&cls, i < N_RULES - 1, N_RULES - (i + 1), 0);
897 compare_classifiers(&cls, &tcls);
900 classifier_destroy(&cls);
905 /* Tests classification with many rules at a time that fall into random lists
908 test_many_rules_in_n_tables(int n_tables)
910 enum { MAX_RULES = 50 };
915 assert(n_tables < 10);
916 for (i = 0; i < n_tables; i++) {
918 wcfs[i] = rand() & ((1u << CLS_N_FIELDS) - 1);
919 } while (array_contains(wcfs, i, wcfs[i]));
922 for (iteration = 0; iteration < 30; iteration++) {
923 unsigned int priorities[MAX_RULES];
924 struct classifier cls;
928 for (i = 0; i < MAX_RULES; i++) {
929 priorities[i] = i * 129;
931 shuffle(priorities, ARRAY_SIZE(priorities));
933 classifier_init(&cls);
936 for (i = 0; i < MAX_RULES; i++) {
937 struct test_rule *rule;
938 unsigned int priority = priorities[i];
939 int wcf = wcfs[rand() % n_tables];
940 int value_pat = rand() & ((1u << CLS_N_FIELDS) - 1);
941 rule = make_rule(wcf, priority, value_pat);
942 tcls_insert(&tcls, rule);
943 classifier_insert(&cls, &rule->cls_rule);
944 check_tables(&cls, -1, i + 1, -1);
945 compare_classifiers(&cls, &tcls);
948 while (!classifier_is_empty(&cls)) {
949 struct test_rule *rule, *next_rule;
950 struct test_rule *target;
951 struct cls_cursor cursor;
953 target = clone_rule(tcls.rules[rand() % tcls.n_rules]);
955 cls_cursor_init(&cursor, &cls, &target->cls_rule);
956 CLS_CURSOR_FOR_EACH_SAFE (rule, next_rule, cls_rule, &cursor) {
957 classifier_remove(&cls, &rule->cls_rule);
960 tcls_delete_matches(&tcls, &target->cls_rule);
961 compare_classifiers(&cls, &tcls);
962 check_tables(&cls, -1, -1, -1);
966 destroy_classifier(&cls);
972 test_many_rules_in_two_tables(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
974 test_many_rules_in_n_tables(2);
978 test_many_rules_in_five_tables(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
980 test_many_rules_in_n_tables(5);
983 /* Miniflow tests. */
988 static const uint32_t values[] =
989 { 0xffffffff, 0xaaaaaaaa, 0x55555555, 0x80000000,
990 0x00000001, 0xface0000, 0x00d00d1e, 0xdeadbeef };
992 return values[random_uint32() % ARRAY_SIZE(values)];
996 choose(unsigned int n, unsigned int *idxp)
1007 init_consecutive_values(int n_consecutive, struct flow *flow,
1010 uint32_t *flow_u32 = (uint32_t *) flow;
1012 if (choose(FLOW_U32S - n_consecutive + 1, idxp)) {
1015 for (i = 0; i < n_consecutive; i++) {
1016 flow_u32[*idxp + i] = random_value();
1025 next_random_flow(struct flow *flow, unsigned int idx)
1027 uint32_t *flow_u32 = (uint32_t *) flow;
1030 memset(flow, 0, sizeof *flow);
1033 if (choose(1, &idx)) {
1037 /* All flows with a small number of consecutive nonzero values. */
1038 for (i = 1; i <= 4; i++) {
1039 if (init_consecutive_values(i, flow, &idx)) {
1044 /* All flows with a large number of consecutive nonzero values. */
1045 for (i = FLOW_U32S - 4; i <= FLOW_U32S; i++) {
1046 if (init_consecutive_values(i, flow, &idx)) {
1051 /* All flows with exactly two nonconsecutive nonzero values. */
1052 if (choose((FLOW_U32S - 1) * (FLOW_U32S - 2) / 2, &idx)) {
1055 for (ofs1 = 0; ofs1 < FLOW_U32S - 2; ofs1++) {
1058 for (ofs2 = ofs1 + 2; ofs2 < FLOW_U32S; ofs2++) {
1059 if (choose(1, &idx)) {
1060 flow_u32[ofs1] = random_value();
1061 flow_u32[ofs2] = random_value();
1069 /* 16 randomly chosen flows with N >= 3 nonzero values. */
1070 if (choose(16 * (FLOW_U32S - 4), &idx)) {
1071 int n = idx / 16 + 3;
1074 for (i = 0; i < n; i++) {
1075 flow_u32[i] = random_value();
1077 shuffle_u32s(flow_u32, FLOW_U32S);
1086 any_random_flow(struct flow *flow)
1088 static unsigned int max;
1090 while (next_random_flow(flow, max)) {
1095 next_random_flow(flow, random_range(max));
1099 toggle_masked_flow_bits(struct flow *flow, const struct flow_wildcards *mask)
1101 const uint32_t *mask_u32 = (const uint32_t *) &mask->masks;
1102 uint32_t *flow_u32 = (uint32_t *) flow;
1105 for (i = 0; i < FLOW_U32S; i++) {
1106 if (mask_u32[i] != 0) {
1110 bit = 1u << random_range(32);
1111 } while (!(bit & mask_u32[i]));
1118 wildcard_extra_bits(struct flow_wildcards *mask)
1120 uint32_t *mask_u32 = (uint32_t *) &mask->masks;
1123 for (i = 0; i < FLOW_U32S; i++) {
1124 if (mask_u32[i] != 0) {
1128 bit = 1u << random_range(32);
1129 } while (!(bit & mask_u32[i]));
1130 mask_u32[i] &= ~bit;
1136 test_miniflow(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
1141 random_set_seed(0xb3faca38);
1142 for (idx = 0; next_random_flow(&flow, idx); idx++) {
1143 const uint32_t *flow_u32 = (const uint32_t *) &flow;
1144 struct miniflow miniflow, miniflow2, miniflow3;
1145 struct flow flow2, flow3;
1146 struct flow_wildcards mask;
1147 struct minimask minimask;
1150 /* Convert flow to miniflow. */
1151 miniflow_init(&miniflow, &flow);
1153 /* Check that the flow equals its miniflow. */
1154 assert(miniflow_get_vid(&miniflow) == vlan_tci_to_vid(flow.vlan_tci));
1155 for (i = 0; i < FLOW_U32S; i++) {
1156 assert(miniflow_get(&miniflow, i) == flow_u32[i]);
1159 /* Check that the miniflow equals itself. */
1160 assert(miniflow_equal(&miniflow, &miniflow));
1162 /* Convert miniflow back to flow and verify that it's the same. */
1163 miniflow_expand(&miniflow, &flow2);
1164 assert(flow_equal(&flow, &flow2));
1166 /* Check that copying a miniflow works properly. */
1167 miniflow_clone(&miniflow2, &miniflow);
1168 assert(miniflow_equal(&miniflow, &miniflow2));
1169 assert(miniflow_hash(&miniflow, 0) == miniflow_hash(&miniflow2, 0));
1170 miniflow_expand(&miniflow2, &flow3);
1171 assert(flow_equal(&flow, &flow3));
1173 /* Check that masked matches work as expected for identical flows and
1176 next_random_flow(&mask.masks, 1);
1177 } while (flow_wildcards_is_catchall(&mask));
1178 minimask_init(&minimask, &mask);
1179 assert(minimask_is_catchall(&minimask)
1180 == flow_wildcards_is_catchall(&mask));
1181 assert(miniflow_equal_in_minimask(&miniflow, &miniflow2, &minimask));
1182 assert(miniflow_equal_flow_in_minimask(&miniflow, &flow2, &minimask));
1183 assert(miniflow_hash_in_minimask(&miniflow, &minimask, 0x12345678) ==
1184 flow_hash_in_minimask(&flow, &minimask, 0x12345678));
1186 /* Check that masked matches work as expected for differing flows and
1188 toggle_masked_flow_bits(&flow2, &mask);
1189 assert(!miniflow_equal_flow_in_minimask(&miniflow, &flow2, &minimask));
1190 miniflow_init(&miniflow3, &flow2);
1191 assert(!miniflow_equal_in_minimask(&miniflow, &miniflow3, &minimask));
1194 miniflow_destroy(&miniflow);
1195 miniflow_destroy(&miniflow2);
1196 miniflow_destroy(&miniflow3);
1197 minimask_destroy(&minimask);
1202 test_minimask_has_extra(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
1204 struct flow_wildcards catchall;
1205 struct minimask minicatchall;
1209 flow_wildcards_init_catchall(&catchall);
1210 minimask_init(&minicatchall, &catchall);
1211 assert(minimask_is_catchall(&minicatchall));
1213 random_set_seed(0x2ec7905b);
1214 for (idx = 0; next_random_flow(&flow, idx); idx++) {
1215 struct flow_wildcards mask;
1216 struct minimask minimask;
1219 minimask_init(&minimask, &mask);
1220 assert(!minimask_has_extra(&minimask, &minimask));
1221 assert(minimask_has_extra(&minicatchall, &minimask)
1222 == !minimask_is_catchall(&minimask));
1223 if (!minimask_is_catchall(&minimask)) {
1224 struct minimask minimask2;
1226 wildcard_extra_bits(&mask);
1227 minimask_init(&minimask2, &mask);
1228 assert(minimask_has_extra(&minimask2, &minimask));
1229 assert(!minimask_has_extra(&minimask, &minimask2));
1230 minimask_destroy(&minimask2);
1233 minimask_destroy(&minimask);
1236 minimask_destroy(&minicatchall);
1240 test_minimask_combine(int argc OVS_UNUSED, char *argv[] OVS_UNUSED)
1242 struct flow_wildcards catchall;
1243 struct minimask minicatchall;
1247 flow_wildcards_init_catchall(&catchall);
1248 minimask_init(&minicatchall, &catchall);
1249 assert(minimask_is_catchall(&minicatchall));
1251 random_set_seed(0x181bf0cd);
1252 for (idx = 0; next_random_flow(&flow, idx); idx++) {
1253 struct minimask minimask, minimask2, minicombined;
1254 struct flow_wildcards mask, mask2, combined, combined2;
1255 uint32_t storage[FLOW_U32S];
1259 minimask_init(&minimask, &mask);
1261 minimask_combine(&minicombined, &minimask, &minicatchall, storage);
1262 assert(minimask_is_catchall(&minicombined));
1264 any_random_flow(&flow2);
1265 mask2.masks = flow2;
1266 minimask_init(&minimask2, &mask2);
1268 minimask_combine(&minicombined, &minimask, &minimask2, storage);
1269 flow_wildcards_combine(&combined, &mask, &mask2);
1270 minimask_expand(&minicombined, &combined2);
1271 assert(flow_wildcards_equal(&combined, &combined2));
1273 minimask_destroy(&minimask);
1274 minimask_destroy(&minimask2);
1277 minimask_destroy(&minicatchall);
1280 static const struct command commands[] = {
1281 /* Classifier tests. */
1282 {"empty", 0, 0, test_empty},
1283 {"destroy-null", 0, 0, test_destroy_null},
1284 {"single-rule", 0, 0, test_single_rule},
1285 {"rule-replacement", 0, 0, test_rule_replacement},
1286 {"many-rules-in-one-list", 0, 0, test_many_rules_in_one_list},
1287 {"many-rules-in-one-table", 0, 0, test_many_rules_in_one_table},
1288 {"many-rules-in-two-tables", 0, 0, test_many_rules_in_two_tables},
1289 {"many-rules-in-five-tables", 0, 0, test_many_rules_in_five_tables},
1291 /* Miniflow and minimask tests. */
1292 {"miniflow", 0, 0, test_miniflow},
1293 {"minimask_has_extra", 0, 0, test_minimask_has_extra},
1294 {"minimask_combine", 0, 0, test_minimask_combine},
1300 main(int argc, char *argv[])
1302 set_program_name(argv[0]);
1304 run_command(argc - 1, argv + 1, commands);