summaryrefslogtreecommitdiff
path: root/lib/dpif.h
blob: 2e739dc784be0d5cbf9830619fee01e54b69ef7d (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
742
743
744
745
746
747
748
749
750
751
752
753
754
755
756
757
758
759
760
761
762
763
764
765
766
767
768
769
770
771
772
773
774
775
776
777
778
779
780
781
782
783
784
785
786
787
788
789
790
791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
806
807
808
809
810
811
812
813
814
815
816
817
818
819
820
821
822
823
824
825
826
827
828
829
830
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
848
849
850
851
852
853
854
855
856
857
858
859
860
861
862
863
864
865
866
867
868
869
870
871
872
873
874
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
905
906
907
908
909
910
911
912
913
914
915
916
917
918
/*
 * Copyright (c) 2008, 2009, 2010, 2011, 2012, 2013, 2014 Nicira, Inc.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at:
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

/*
 * dpif, the DataPath InterFace.
 *
 * In Open vSwitch terminology, a "datapath" is a flow-based software switch.
 * A datapath has no intelligence of its own.  Rather, it relies entirely on
 * its client to set up flows.  The datapath layer is core to the Open vSwitch
 * software switch: one could say, without much exaggeration, that everything
 * in ovs-vswitchd above dpif exists only to make the correct decisions
 * interacting with dpif.
 *
 * Typically, the client of a datapath is the software switch module in
 * "ovs-vswitchd", but other clients can be written.  The "ovs-dpctl" utility
 * is also a (simple) client.
 *
 *
 * Overview
 * ========
 *
 * The terms written in quotes below are defined in later sections.
 *
 * When a datapath "port" receives a packet, it extracts the headers (the
 * "flow").  If the datapath's "flow table" contains a "flow entry" matching
 * the packet, then it executes the "actions" in the flow entry and increments
 * the flow's statistics.  If there is no matching flow entry, the datapath
 * instead appends the packet to an "upcall" queue.
 *
 *
 * Ports
 * =====
 *
 * A datapath has a set of ports that are analogous to the ports on an Ethernet
 * switch.  At the datapath level, each port has the following information
 * associated with it:
 *
 *    - A name, a short string that must be unique within the host.  This is
 *      typically a name that would be familiar to the system administrator,
 *      e.g. "eth0" or "vif1.1", but it is otherwise arbitrary.
 *
 *    - A 32-bit port number that must be unique within the datapath but is
 *      otherwise arbitrary.  The port number is the most important identifier
 *      for a port in the datapath interface.
 *
 *    - A type, a short string that identifies the kind of port.  On a Linux
 *      host, typical types are "system" (for a network device such as eth0),
 *      "internal" (for a simulated port used to connect to the TCP/IP stack),
 *      and "gre" (for a GRE tunnel).
 *
 *    - A Netlink PID for each upcall reading thread (see "Upcall Queuing and
 *      Ordering" below).
 *
 * The dpif interface has functions for adding and deleting ports.  When a
 * datapath implements these (e.g. as the Linux and netdev datapaths do), then
 * Open vSwitch's ovs-vswitchd daemon can directly control what ports are used
 * for switching.  Some datapaths might not implement them, or implement them
 * with restrictions on the types of ports that can be added or removed
 * (e.g. on ESX), on systems where port membership can only be changed by some
 * external entity.
 *
 * Each datapath must have a port, sometimes called the "local port", whose
 * name is the same as the datapath itself, with port number 0.  The local port
 * cannot be deleted.
 *
 * Ports are available as "struct netdev"s.  To obtain a "struct netdev *" for
 * a port named 'name' with type 'port_type', in a datapath of type
 * 'datapath_type', call netdev_open(name, dpif_port_open_type(datapath_type,
 * port_type).  The netdev can be used to get and set important data related to
 * the port, such as:
 *
 *    - MTU (netdev_get_mtu(), netdev_set_mtu()).
 *
 *    - Ethernet address (netdev_get_etheraddr(), netdev_set_etheraddr()).
 *
 *    - Statistics such as the number of packets and bytes transmitted and
 *      received (netdev_get_stats()).
 *
 *    - Carrier status (netdev_get_carrier()).
 *
 *    - Speed (netdev_get_features()).
 *
 *    - QoS queue configuration (netdev_get_queue(), netdev_set_queue() and
 *      related functions.)
 *
 *    - Arbitrary port-specific configuration parameters (netdev_get_config(),
 *      netdev_set_config()).  An example of such a parameter is the IP
 *      endpoint for a GRE tunnel.
 *
 *
 * Flow Table
 * ==========
 *
 * The flow table is a collection of "flow entries".  Each flow entry contains:
 *
 *    - A "flow", that is, a summary of the headers in an Ethernet packet.  The
 *      flow must be unique within the flow table.  Flows are fine-grained
 *      entities that include L2, L3, and L4 headers.  A single TCP connection
 *      consists of two flows, one in each direction.
 *
 *      In Open vSwitch userspace, "struct flow" is the typical way to describe
 *      a flow, but the datapath interface uses a different data format to
 *      allow ABI forward- and backward-compatibility.  Refer to OVS_KEY_ATTR_*
 *      and "struct ovs_key_*" in include/odp-netlink.h for details.
 *      lib/odp-util.h defines several functions for working with these flows.
 *
 *    - A "mask" that, for each bit in the flow, specifies whether the datapath
 *      should consider the corresponding flow bit when deciding whether a
 *      given packet matches the flow entry.  The original datapath design did
 *      not support matching: every flow entry was exact match.  With the
 *      addition of a mask, the interface supports datapaths with a spectrum of
 *      wildcard matching capabilities, from those that only support exact
 *      matches to those that support bitwise wildcarding on the entire flow
 *      key, as well as datapaths with capabilities somewhere in between.
 *
 *      Datapaths do not provide a way to query their wildcarding capabilities,
 *      nor is it expected that the client should attempt to probe for the
 *      details of their support.  Instead, a client installs flows with masks
 *      that wildcard as many bits as acceptable.  The datapath then actually
 *      wildcards as many of those bits as it can and changes the wildcard bits
 *      that it does not support into exact match bits.  A datapath that can
 *      wildcard any bit, for example, would install the supplied mask, an
 *      exact-match only datapath would install an exact-match mask regardless
 *      of what mask the client supplied, and a datapath in the middle of the
 *      spectrum would selectively change some wildcard bits into exact match
 *      bits.
 *
 *      Regardless of the requested or installed mask, the datapath retains the
 *      original flow supplied by the client.  (It does not, for example, "zero
 *      out" the wildcarded bits.)  This allows the client to unambiguously
 *      identify the flow entry in later flow table operations.
 *
 *      The flow table does not have priorities; that is, all flow entries have
 *      equal priority.  Detecting overlapping flow entries is expensive in
 *      general, so the datapath is not required to do it.  It is primarily the
 *      client's responsibility not to install flow entries whose flow and mask
 *      combinations overlap.
 *
 *    - A list of "actions" that tell the datapath what to do with packets
 *      within a flow.  Some examples of actions are OVS_ACTION_ATTR_OUTPUT,
 *      which transmits the packet out a port, and OVS_ACTION_ATTR_SET, which
 *      modifies packet headers.  Refer to OVS_ACTION_ATTR_* and "struct
 *      ovs_action_*" in include/odp-netlink.h for details.  lib/odp-util.h
 *      defines several functions for working with datapath actions.
 *
 *      The actions list may be empty.  This indicates that nothing should be
 *      done to matching packets, that is, they should be dropped.
 *
 *      (In case you are familiar with OpenFlow, datapath actions are analogous
 *      to OpenFlow actions.)
 *
 *    - Statistics: the number of packets and bytes that the flow has
 *      processed, the last time that the flow processed a packet, and the
 *      union of all the TCP flags in packets processed by the flow.  (The
 *      latter is 0 if the flow is not a TCP flow.)
 *
 * The datapath's client manages the flow table, primarily in reaction to
 * "upcalls" (see below).
 *
 *
 * Upcalls
 * =======
 *
 * A datapath sometimes needs to notify its client that a packet was received.
 * The datapath mechanism to do this is called an "upcall".
 *
 * Upcalls are used in two situations:
 *
 *    - When a packet is received, but there is no matching flow entry in its
 *      flow table (a flow table "miss"), this causes an upcall of type
 *      DPIF_UC_MISS.  These are called "miss" upcalls.
 *
 *    - A datapath action of type OVS_ACTION_ATTR_USERSPACE causes an upcall of
 *      type DPIF_UC_ACTION.  These are called "action" upcalls.
 *
 * An upcall contains an entire packet.  There is no attempt to, e.g., copy
 * only as much of the packet as normally needed to make a forwarding decision.
 * Such an optimization is doable, but experimental prototypes showed it to be
 * of little benefit because an upcall typically contains the first packet of a
 * flow, which is usually short (e.g. a TCP SYN).  Also, the entire packet can
 * sometimes really be needed.
 *
 * After a client reads a given upcall, the datapath is finished with it, that
 * is, the datapath doesn't maintain any lingering state past that point.
 *
 * The latency from the time that a packet arrives at a port to the time that
 * it is received from dpif_recv() is critical in some benchmarks.  For
 * example, if this latency is 1 ms, then a netperf TCP_CRR test, which opens
 * and closes TCP connections one at a time as quickly as it can, cannot
 * possibly achieve more than 500 transactions per second, since every
 * connection consists of two flows with 1-ms latency to set up each one.
 *
 * To receive upcalls, a client has to enable them with dpif_recv_set().  A
 * datapath should generally support being opened multiple times (e.g. so that
 * one may run "ovs-dpctl show" or "ovs-dpctl dump-flows" while "ovs-vswitchd"
 * is also running) but need not support more than one of these clients
 * enabling upcalls at once.
 *
 *
 * Upcall Queuing and Ordering
 * ---------------------------
 *
 * The datapath's client reads upcalls one at a time by calling dpif_recv().
 * When more than one upcall is pending, the order in which the datapath
 * presents upcalls to its client is important.  The datapath's client does not
 * directly control this order, so the datapath implementer must take care
 * during design.
 *
 * The minimal behavior, suitable for initial testing of a datapath
 * implementation, is that all upcalls are appended to a single queue, which is
 * delivered to the client in order.
 *
 * The datapath should ensure that a high rate of upcalls from one particular
 * port cannot cause upcalls from other sources to be dropped or unreasonably
 * delayed.  Otherwise, one port conducting a port scan or otherwise initiating
 * high-rate traffic spanning many flows could suppress other traffic.
 * Ideally, the datapath should present upcalls from each port in a "round
 * robin" manner, to ensure fairness.
 *
 * The client has no control over "miss" upcalls and no insight into the
 * datapath's implementation, so the datapath is entirely responsible for
 * queuing and delivering them.  On the other hand, the datapath has
 * considerable freedom of implementation.  One good approach is to maintain a
 * separate queue for each port, to prevent any given port's upcalls from
 * interfering with other ports' upcalls.  If this is impractical, then another
 * reasonable choice is to maintain some fixed number of queues and assign each
 * port to one of them.  Ports assigned to the same queue can then interfere
 * with each other, but not with ports assigned to different queues.  Other
 * approaches are also possible.
 *
 * The client has some control over "action" upcalls: it can specify a 32-bit
 * "Netlink PID" as part of the action.  This terminology comes from the Linux
 * datapath implementation, which uses a protocol called Netlink in which a PID
 * designates a particular socket and the upcall data is delivered to the
 * socket's receive queue.  Generically, though, a Netlink PID identifies a
 * queue for upcalls.  The basic requirements on the datapath are:
 *
 *    - The datapath must provide a Netlink PID associated with each port.  The
 *      client can retrieve the PID with dpif_port_get_pid().
 *
 *    - The datapath must provide a "special" Netlink PID not associated with
 *      any port.  dpif_port_get_pid() also provides this PID.  (ovs-vswitchd
 *      uses this PID to queue special packets that must not be lost even if a
 *      port is otherwise busy, such as packets used for tunnel monitoring.)
 *
 * The minimal behavior of dpif_port_get_pid() and the treatment of the Netlink
 * PID in "action" upcalls is that dpif_port_get_pid() returns a constant value
 * and all upcalls are appended to a single queue.
 *
 * The preferred behavior is:
 *
 *    - Each port has a PID that identifies the queue used for "miss" upcalls
 *      on that port.  (Thus, if each port has its own queue for "miss"
 *      upcalls, then each port has a different Netlink PID.)
 *
 *    - "miss" upcalls for a given port and "action" upcalls that specify that
 *      port's Netlink PID add their upcalls to the same queue.  The upcalls
 *      are delivered to the datapath's client in the order that the packets
 *      were received, regardless of whether the upcalls are "miss" or "action"
 *      upcalls.
 *
 *    - Upcalls that specify the "special" Netlink PID are queued separately.
 *
 * Multiple threads may want to read upcalls simultaneously from a single
 * datapath.  To support multiple threads well, one extends the above preferred
 * behavior:
 *
 *    - Each port has multiple PIDs.  The datapath distributes "miss" upcalls
 *      across the PIDs, ensuring that a given flow is mapped in a stable way
 *      to a single PID.
 *
 *    - For "action" upcalls, the thread can specify its own Netlink PID or
 *      other threads' Netlink PID of the same port for offloading purpose
 *      (e.g. in a "round robin" manner).
 *
 *
 * Packet Format
 * =============
 *
 * The datapath interface works with packets in a particular form.  This is the
 * form taken by packets received via upcalls (i.e. by dpif_recv()).  Packets
 * supplied to the datapath for processing (i.e. to dpif_execute()) also take
 * this form.
 *
 * A VLAN tag is represented by an 802.1Q header.  If the layer below the
 * datapath interface uses another representation, then the datapath interface
 * must perform conversion.
 *
 * The datapath interface requires all packets to fit within the MTU.  Some
 * operating systems internally process packets larger than MTU, with features
 * such as TSO and UFO.  When such a packet passes through the datapath
 * interface, it must be broken into multiple MTU or smaller sized packets for
 * presentation as upcalls.  (This does not happen often, because an upcall
 * typically contains the first packet of a flow, which is usually short.)
 *
 * Some operating system TCP/IP stacks maintain packets in an unchecksummed or
 * partially checksummed state until transmission.  The datapath interface
 * requires all host-generated packets to be fully checksummed (e.g. IP and TCP
 * checksums must be correct).  On such an OS, the datapath interface must fill
 * in these checksums.
 *
 * Packets passed through the datapath interface must be at least 14 bytes
 * long, that is, they must have a complete Ethernet header.  They are not
 * required to be padded to the minimum Ethernet length.
 *
 *
 * Typical Usage
 * =============
 *
 * Typically, the client of a datapath begins by configuring the datapath with
 * a set of ports.  Afterward, the client runs in a loop polling for upcalls to
 * arrive.
 *
 * For each upcall received, the client examines the enclosed packet and
 * figures out what should be done with it.  For example, if the client
 * implements a MAC-learning switch, then it searches the forwarding database
 * for the packet's destination MAC and VLAN and determines the set of ports to
 * which it should be sent.  In any case, the client composes a set of datapath
 * actions to properly dispatch the packet and then directs the datapath to
 * execute those actions on the packet (e.g. with dpif_execute()).
 *
 * Most of the time, the actions that the client executed on the packet apply
 * to every packet with the same flow.  For example, the flow includes both
 * destination MAC and VLAN ID (and much more), so this is true for the
 * MAC-learning switch example above.  In such a case, the client can also
 * direct the datapath to treat any further packets in the flow in the same
 * way, using dpif_flow_put() to add a new flow entry.
 *
 * Other tasks the client might need to perform, in addition to reacting to
 * upcalls, include:
 *
 *    - Periodically polling flow statistics, perhaps to supply to its own
 *      clients.
 *
 *    - Deleting flow entries from the datapath that haven't been used
 *      recently, to save memory.
 *
 *    - Updating flow entries whose actions should change.  For example, if a
 *      MAC learning switch learns that a MAC has moved, then it must update
 *      the actions of flow entries that sent packets to the MAC at its old
 *      location.
 *
 *    - Adding and removing ports to achieve a new configuration.
 *
 *
 * Thread-safety
 * =============
 *
 * Most of the dpif functions are fully thread-safe: they may be called from
 * any number of threads on the same or different dpif objects.  The exceptions
 * are:
 *
 *    - dpif_port_poll() and dpif_port_poll_wait() are conditionally
 *      thread-safe: they may be called from different threads only on
 *      different dpif objects.
 *
 *    - dpif_flow_dump_next() is conditionally thread-safe: It may be called
 *      from different threads with the same 'struct dpif_flow_dump', but all
 *      other parameters must be different for each thread.
 *
 *    - dpif_flow_dump_done() is conditionally thread-safe: All threads that
 *      share the same 'struct dpif_flow_dump' must have finished using it.
 *      This function must then be called exactly once for a particular
 *      dpif_flow_dump to finish the corresponding flow dump operation.
 *
 *    - Functions that operate on 'struct dpif_port_dump' are conditionally
 *      thread-safe with respect to those objects.  That is, one may dump ports
 *      from any number of threads at once, but each thread must use its own
 *      struct dpif_port_dump.
 */
#ifndef DPIF_H
#define DPIF_H 1

#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>

#include "dpdk.h"
#include "dp-packet.h"
#include "netdev.h"
#include "openflow/openflow.h"
#include "openvswitch/ofp-util.h"
#include "ovs-numa.h"
#include "packets.h"
#include "util.h"

#ifdef  __cplusplus
extern "C" {
#endif

struct dpif;
struct dpif_class;
struct dpif_flow;
struct ds;
struct flow;
struct flow_wildcards;
struct nlattr;
struct sset;

int dp_register_provider(const struct dpif_class *);
int dp_unregister_provider(const char *type);
void dp_blacklist_provider(const char *type);
void dp_enumerate_types(struct sset *types);
const char *dpif_normalize_type(const char *);

int dp_enumerate_names(const char *type, struct sset *names);
void dp_parse_name(const char *datapath_name, char **name, char **type);

int dpif_open(const char *name, const char *type, struct dpif **);
int dpif_create(const char *name, const char *type, struct dpif **);
int dpif_create_and_open(const char *name, const char *type, struct dpif **);
void dpif_close(struct dpif *);

bool dpif_run(struct dpif *);
void dpif_wait(struct dpif *);

const char *dpif_name(const struct dpif *);
const char *dpif_base_name(const struct dpif *);
const char *dpif_type(const struct dpif *);

int dpif_delete(struct dpif *);

/* Statistics for a dpif as a whole. */
struct dpif_dp_stats {
    uint64_t n_hit;             /* Number of flow table matches. */
    uint64_t n_missed;          /* Number of flow table misses. */
    uint64_t n_lost;            /* Number of misses not sent to userspace. */
    uint64_t n_flows;           /* Number of flows present. */
    uint64_t n_mask_hit;        /* Number of mega flow masks visited for
                                   flow table matches. */
    uint32_t n_masks;           /* Number of mega flow masks. */
};
int dpif_get_dp_stats(const struct dpif *, struct dpif_dp_stats *);


/* Port operations. */

const char *dpif_port_open_type(const char *datapath_type,
                                const char *port_type);
int dpif_port_add(struct dpif *, struct netdev *, odp_port_t *port_nop);
int dpif_port_del(struct dpif *, odp_port_t port_no, bool local_delete);

/* A port within a datapath.
 *
 * 'name' and 'type' are suitable for passing to netdev_open(). */
struct dpif_port {
    char *name;                 /* Network device name, e.g. "eth0". */
    char *type;                 /* Network device type, e.g. "system". */
    odp_port_t port_no;         /* Port number within datapath. */
};
void dpif_port_clone(struct dpif_port *, const struct dpif_port *);
void dpif_port_destroy(struct dpif_port *);
bool dpif_port_exists(const struct dpif *dpif, const char *devname);
int dpif_port_query_by_number(const struct dpif *, odp_port_t port_no,
                              struct dpif_port *);
int dpif_port_query_by_name(const struct dpif *, const char *devname,
                            struct dpif_port *);
int dpif_port_get_name(struct dpif *, odp_port_t port_no,
                       char *name, size_t name_size);
uint32_t dpif_port_get_pid(const struct dpif *, odp_port_t port_no,
                           uint32_t hash);

struct dpif_port_dump {
    const struct dpif *dpif;
    int error;
    void *state;
};
void dpif_port_dump_start(struct dpif_port_dump *, const struct dpif *);
bool dpif_port_dump_next(struct dpif_port_dump *, struct dpif_port *);
int dpif_port_dump_done(struct dpif_port_dump *);

/* Iterates through each DPIF_PORT in DPIF, using DUMP as state.
 *
 * Arguments all have pointer type.
 *
 * If you break out of the loop, then you need to free the dump structure by
 * hand using dpif_port_dump_done(). */
#define DPIF_PORT_FOR_EACH(DPIF_PORT, DUMP, DPIF)   \
    for (dpif_port_dump_start(DUMP, DPIF);          \
         (dpif_port_dump_next(DUMP, DPIF_PORT)      \
          ? true                                    \
          : (dpif_port_dump_done(DUMP), false));    \
        )

int dpif_port_poll(const struct dpif *, char **devnamep);
void dpif_port_poll_wait(const struct dpif *);

/* Flow table operations. */

struct dpif_flow_stats {
    uint64_t n_packets;
    uint64_t n_bytes;
    long long int used;
    uint16_t tcp_flags;
};

void dpif_flow_stats_extract(const struct flow *, const struct dp_packet *packet,
                             long long int used, struct dpif_flow_stats *);
void dpif_flow_stats_format(const struct dpif_flow_stats *, struct ds *);

enum dpif_flow_put_flags {
    DPIF_FP_CREATE = 1 << 0,    /* Allow creating a new flow. */
    DPIF_FP_MODIFY = 1 << 1,    /* Allow modifying an existing flow. */
    DPIF_FP_ZERO_STATS = 1 << 2, /* Zero the stats of an existing flow. */
    DPIF_FP_PROBE = 1 << 3      /* Suppress error messages, if any. */
};

bool dpif_probe_feature(struct dpif *, const char *name,
                        const struct ofpbuf *key, const struct ofpbuf *actions,
                        const ovs_u128 *ufid);
void dpif_flow_hash(const struct dpif *, const void *key, size_t key_len,
                    ovs_u128 *hash);
int dpif_flow_flush(struct dpif *);
int dpif_flow_put(struct dpif *, enum dpif_flow_put_flags,
                  const struct nlattr *key, size_t key_len,
                  const struct nlattr *mask, size_t mask_len,
                  const struct nlattr *actions, size_t actions_len,
                  const ovs_u128 *ufid, const unsigned pmd_id,
                  struct dpif_flow_stats *);
int dpif_flow_del(struct dpif *,
                  const struct nlattr *key, size_t key_len,
                  const ovs_u128 *ufid, const unsigned pmd_id,
                  struct dpif_flow_stats *);
int dpif_flow_get(struct dpif *,
                  const struct nlattr *key, size_t key_len,
                  const ovs_u128 *ufid, const unsigned pmd_id,
                  struct ofpbuf *, struct dpif_flow *);

/* Flow dumping interface
 * ======================
 *
 * This interface allows iteration through all of the flows currently installed
 * in a datapath.  It is somewhat complicated by two requirements:
 *
 *    - Efficient support for dumping flows in parallel from multiple threads.
 *
 *    - Allow callers to avoid making unnecessary copies of data returned by
 *      the interface across several flows in cases where the dpif
 *      implementation has to maintain a copy of that information anyhow.
 *      (That is, allow the client visibility into any underlying batching as
 *      part of its own batching.)
 *
 *
 * Usage
 * -----
 *
 * 1. Call dpif_flow_dump_create().
 * 2. In each thread that participates in the dump (which may be just a single
 *    thread if parallelism isn't important):
 *        (a) Call dpif_flow_dump_thread_create().
 *        (b) Call dpif_flow_dump_next() repeatedly until it returns 0.
 *        (c) Call dpif_flow_dump_thread_destroy().
 * 3. Call dpif_flow_dump_destroy().
 *
 * All error reporting is deferred to the call to dpif_flow_dump_destroy().
 */
struct dpif_flow_dump *dpif_flow_dump_create(const struct dpif *, bool terse,
                                             char *type);
int dpif_flow_dump_destroy(struct dpif_flow_dump *);

struct dpif_flow_dump_thread *dpif_flow_dump_thread_create(
    struct dpif_flow_dump *);
void dpif_flow_dump_thread_destroy(struct dpif_flow_dump_thread *);

#define PMD_ID_NULL OVS_CORE_UNSPEC

/* A datapath flow as dumped by dpif_flow_dump_next(). */
struct dpif_flow {
    const struct nlattr *key;     /* Flow key, as OVS_KEY_ATTR_* attrs. */
    size_t key_len;               /* 'key' length in bytes. */
    const struct nlattr *mask;    /* Flow mask, as OVS_KEY_ATTR_* attrs. */
    size_t mask_len;              /* 'mask' length in bytes. */
    const struct nlattr *actions; /* Actions, as OVS_ACTION_ATTR_ */
    size_t actions_len;           /* 'actions' length in bytes. */
    ovs_u128 ufid;                /* Unique flow identifier. */
    bool ufid_present;            /* True if 'ufid' was provided by datapath.*/
    unsigned pmd_id;              /* Datapath poll mode driver id. */
    struct dpif_flow_stats stats; /* Flow statistics. */
    bool offloaded;               /* True if flow is offloaded */
};
int dpif_flow_dump_next(struct dpif_flow_dump_thread *,
                        struct dpif_flow *flows, int max_flows);

#define DPIF_FLOW_BUFSIZE 2048

/* Operation batching interface.
 *
 * Some datapaths are faster at performing N operations together than the same
 * N operations individually, hence an interface for batching.
 */

enum dpif_op_type {
    DPIF_OP_FLOW_PUT = 1,
    DPIF_OP_FLOW_DEL,
    DPIF_OP_EXECUTE,
    DPIF_OP_FLOW_GET,
};

/* Add or modify a flow.
 *
 * The flow is specified by the Netlink attributes with types OVS_KEY_ATTR_* in
 * the 'key_len' bytes starting at 'key'.  The associated actions are specified
 * by the Netlink attributes with types OVS_ACTION_ATTR_* in the 'actions_len'
 * bytes starting at 'actions'.
 *
 *   - If the flow's key does not exist in the dpif, then the flow will be
 *     added if 'flags' includes DPIF_FP_CREATE.  Otherwise the operation will
 *     fail with ENOENT.
 *
 *     If the operation succeeds, then 'stats', if nonnull, will be zeroed.
 *
 *   - If the flow's key does exist in the dpif, then the flow's actions will
 *     be updated if 'flags' includes DPIF_FP_MODIFY.  Otherwise the operation
 *     will fail with EEXIST.  If the flow's actions are updated, then its
 *     statistics will be zeroed if 'flags' includes DPIF_FP_ZERO_STATS, and
 *     left as-is otherwise.
 *
 *     If the operation succeeds, then 'stats', if nonnull, will be set to the
 *     flow's statistics before the update.
 *
 *   - If the datapath implements multiple pmd thread with its own flow
 *     table, 'pmd_id' should be used to specify the particular polling
 *     thread for the operation. PMD_ID_NULL means that the flow should
 *     be put on all the polling threads.
 */
struct dpif_flow_put {
    /* Input. */
    enum dpif_flow_put_flags flags; /* DPIF_FP_*. */
    const struct nlattr *key;       /* Flow to put. */
    size_t key_len;                 /* Length of 'key' in bytes. */
    const struct nlattr *mask;      /* Mask to put. */
    size_t mask_len;                /* Length of 'mask' in bytes. */
    const struct nlattr *actions;   /* Actions to perform on flow. */
    size_t actions_len;             /* Length of 'actions' in bytes. */
    const ovs_u128 *ufid;           /* Optional unique flow identifier. */
    unsigned pmd_id;                /* Datapath poll mode driver id. */

    /* Output. */
    struct dpif_flow_stats *stats;  /* Optional flow statistics. */
};

/* Delete a flow.
 *
 * The flow is specified by the Netlink attributes with types OVS_KEY_ATTR_* in
 * the 'key_len' bytes starting at 'key', or the unique identifier 'ufid'. If
 * the flow was created using 'ufid', then 'ufid' must be specified to delete
 * the flow. If both are specified, 'key' will be ignored for flow deletion.
 * Succeeds with status 0 if the flow is deleted, or fails with ENOENT if the
 * dpif does not contain such a flow.
 *
 * Callers should always provide the 'key' to improve dpif logging in the event
 * of errors or unexpected behaviour.
 *
 * If the datapath implements multiple polling thread with its own flow table,
 * 'pmd_id' should be used to specify the particular polling thread for the
 * operation. PMD_ID_NULL means that the flow should be deleted from all the
 * polling threads.
 *
 * If the operation succeeds, then 'stats', if nonnull, will be set to the
 * flow's statistics before its deletion. */
struct dpif_flow_del {
    /* Input. */
    const struct nlattr *key;       /* Flow to delete. */
    size_t key_len;                 /* Length of 'key' in bytes. */
    const ovs_u128 *ufid;           /* Unique identifier of flow to delete. */
    bool terse;                     /* OK to skip sending/receiving full flow
                                     * info? */
    unsigned pmd_id;                /* Datapath poll mode driver id. */

    /* Output. */
    struct dpif_flow_stats *stats;  /* Optional flow statistics. */
};

/* Executes actions on a specified packet.
 *
 * Performs the 'actions_len' bytes of actions in 'actions' on the Ethernet
 * frame in 'packet' and on the packet metadata in 'md'.  May modify both
 * 'packet' and 'md'.
 *
 * Some dpif providers do not implement every action.  The Linux kernel
 * datapath, in particular, does not implement ARP field modification.  If
 * 'needs_help' is true, the dpif layer executes in userspace all of the
 * actions that it can, and for OVS_ACTION_ATTR_OUTPUT and
 * OVS_ACTION_ATTR_USERSPACE actions it passes the packet through to the dpif
 * implementation.
 *
 * This works even if 'actions_len' is too long for a Netlink attribute. */
struct dpif_execute {
    /* Input. */
    const struct nlattr *actions;   /* Actions to execute on packet. */
    size_t actions_len;             /* Length of 'actions' in bytes. */
    bool needs_help;
    bool probe;                     /* Suppress error messages. */
    unsigned int mtu;               /* Maximum transmission unit to fragment.
                                       0 if not a fragmented packet */
    const struct flow *flow;         /* Flow extracted from 'packet'. */

    /* Input, but possibly modified as a side effect of execution. */
    struct dp_packet *packet;          /* Packet to execute. */
};

/* Queries the dpif for a flow entry.
 *
 * The flow is specified by the Netlink attributes with types OVS_KEY_ATTR_* in
 * the 'key_len' bytes starting at 'key', or the unique identifier 'ufid'. If
 * the flow was created using 'ufid', then 'ufid' must be specified to fetch
 * the flow. If both are specified, 'key' will be ignored for the flow query.
 * 'buffer' must point to an initialized buffer, with a recommended size of
 * DPIF_FLOW_BUFSIZE bytes.
 *
 * On success, 'flow' will be populated with the mask, actions and stats for
 * the datapath flow corresponding to 'key'. The mask and actions may point
 * within '*buffer', or may point at RCU-protected data. Therefore, callers
 * that wish to hold these over quiescent periods must make a copy of these
 * fields before quiescing.
 *
 * Callers should always provide 'key' to improve dpif logging in the event of
 * errors or unexpected behaviour.
 *
 * If the datapath implements multiple polling thread with its own flow table,
 * 'pmd_id' should be used to specify the particular polling thread for the
 * operation. PMD_ID_NULL means that the datapath will return the first
 * matching flow from any poll thread.
 *
 * Succeeds with status 0 if the flow is fetched, or fails with ENOENT if no
 * such flow exists. Other failures are indicated with a positive errno value.
 */
struct dpif_flow_get {
    /* Input. */
    const struct nlattr *key;       /* Flow to get. */
    size_t key_len;                 /* Length of 'key' in bytes. */
    const ovs_u128 *ufid;           /* Unique identifier of flow to get. */
    unsigned pmd_id;                /* Datapath poll mode driver id. */
    struct ofpbuf *buffer;          /* Storage for output parameters. */

    /* Output. */
    struct dpif_flow *flow;         /* Resulting flow from datapath. */
};

int dpif_execute(struct dpif *, struct dpif_execute *);

struct dpif_op {
    enum dpif_op_type type;
    int error;
    union {
        struct dpif_flow_put flow_put;
        struct dpif_flow_del flow_del;
        struct dpif_execute execute;
        struct dpif_flow_get flow_get;
    } u;
};

void dpif_operate(struct dpif *, struct dpif_op **ops, size_t n_ops);

/* Upcalls. */

enum dpif_upcall_type {
    DPIF_UC_MISS,               /* Miss in flow table. */
    DPIF_UC_ACTION,             /* OVS_ACTION_ATTR_USERSPACE action. */
    DPIF_N_UC_TYPES
};

const char *dpif_upcall_type_to_string(enum dpif_upcall_type);

/* A packet passed up from the datapath to userspace.
 *
 * The 'packet', 'key' and 'userdata' may point into data in a buffer
 * provided by the caller, so the buffer should be released only after the
 * upcall processing has been finished.
 *
 * While being processed, the 'packet' may be reallocated, so the packet must
 * be separately released with ofpbuf_uninit().
 */
struct dpif_upcall {
    /* All types. */
    struct dp_packet packet;    /* Packet data,'dp_packet' should be the first
                                   member to avoid a hole. This is because
                                   'rte_mbuf' in dp_packet is aligned atleast
                                   on a 64-byte boundary */
    enum dpif_upcall_type type;
    struct nlattr *key;         /* Flow key. */
    size_t key_len;             /* Length of 'key' in bytes. */
    ovs_u128 ufid;              /* Unique flow identifier for 'key'. */
    struct nlattr *mru;         /* Maximum receive unit. */
    struct nlattr *cutlen;      /* Number of bytes shrink from the end. */

    /* DPIF_UC_ACTION only. */
    struct nlattr *userdata;    /* Argument to OVS_ACTION_ATTR_USERSPACE. */
    struct nlattr *out_tun_key;    /* Output tunnel key. */
    struct nlattr *actions;    /* Argument to OVS_ACTION_ATTR_USERSPACE. */
};

/* A callback to notify higher layer of dpif about to be purged, so that
 * higher layer could try reacting to this (e.g. grabbing all flow stats
 * before they are gone).  This function is currently implemented only by
 * dpif-netdev.
 *
 * The caller needs to provide the 'aux' pointer passed down by higher
 * layer from the dpif_register_notify_cb() function and the 'pmd_id' of
 * the polling thread.
 */
    typedef void dp_purge_callback(void *aux, unsigned pmd_id);

void dpif_register_dp_purge_cb(struct dpif *, dp_purge_callback *, void *aux);

/* A callback to process an upcall, currently implemented only by dpif-netdev.
 *
 * The caller provides the 'packet' and 'flow' to process, the corresponding
 * 'ufid' as generated by dpif_flow_hash(), the polling thread id 'pmd_id',
 * the 'type' of the upcall, and if 'type' is DPIF_UC_ACTION then the
 * 'userdata' attached to the action.
 *
 * The callback must fill in 'actions' with the datapath actions to apply to
 * 'packet'.  'wc' and 'put_actions' will either be both null or both nonnull.
 * If they are nonnull, then the caller will install a flow entry to process
 * all future packets that match 'flow' and 'wc'; the callback must store a
 * wildcard mask suitable for that purpose into 'wc'.  If the actions to store
 * into the flow entry are the same as 'actions', then the callback may leave
 * 'put_actions' empty; otherwise it must store the desired actions into
 * 'put_actions'.
 *
 * Returns 0 if successful, ENOSPC if the flow limit has been reached and no
 * flow should be installed, or some otherwise a positive errno value. */
typedef int upcall_callback(const struct dp_packet *packet,
                            const struct flow *flow,
                            ovs_u128 *ufid,
                            unsigned pmd_id,
                            enum dpif_upcall_type type,
                            const struct nlattr *userdata,
                            struct ofpbuf *actions,
                            struct flow_wildcards *wc,
                            struct ofpbuf *put_actions,
                            void *aux);

void dpif_register_upcall_cb(struct dpif *, upcall_callback *, void *aux);

int dpif_recv_set(struct dpif *, bool enable);
int dpif_handlers_set(struct dpif *, uint32_t n_handlers);
int dpif_set_config(struct dpif *, const struct smap *cfg);
int dpif_port_set_config(struct dpif *, odp_port_t, const struct smap *cfg);
int dpif_recv(struct dpif *, uint32_t handler_id, struct dpif_upcall *,
              struct ofpbuf *);
void dpif_recv_purge(struct dpif *);
void dpif_recv_wait(struct dpif *, uint32_t handler_id);
void dpif_enable_upcall(struct dpif *);
void dpif_disable_upcall(struct dpif *);

void dpif_print_packet(struct dpif *, struct dpif_upcall *);

/* Meters. */
void dpif_meter_get_features(const struct dpif *,
                             struct ofputil_meter_features *);
int dpif_meter_set(struct dpif *, ofproto_meter_id *meter_id,
                   struct ofputil_meter_config *);
int dpif_meter_get(const struct dpif *, ofproto_meter_id meter_id,
                   struct ofputil_meter_stats *, uint16_t n_bands);
int dpif_meter_del(struct dpif *, ofproto_meter_id meter_id,
                   struct ofputil_meter_stats *, uint16_t n_bands);

/* Miscellaneous. */

void dpif_get_netflow_ids(const struct dpif *,
                          uint8_t *engine_type, uint8_t *engine_id);

int dpif_queue_to_priority(const struct dpif *, uint32_t queue_id,
                           uint32_t *priority);

int dpif_get_pmds_for_port(const struct dpif * dpif, odp_port_t port_no,
                           unsigned int **pmds, size_t *n);

char *dpif_get_dp_version(const struct dpif *);
bool dpif_supports_tnl_push_pop(const struct dpif *);

/* Log functions. */
struct vlog_module;

void log_flow_message(const struct dpif *dpif, int error,
                      const struct vlog_module *module,
                      const char *operation,
                      const struct nlattr *key, size_t key_len,
                      const struct nlattr *mask, size_t mask_len,
                      const ovs_u128 *ufid,
                      const struct dpif_flow_stats *stats,
                      const struct nlattr *actions, size_t actions_len);
void log_flow_put_message(const struct dpif *,
                          const struct vlog_module *,
                          const struct dpif_flow_put *,
                          int error);
void log_flow_del_message(const struct dpif *,
                          const struct vlog_module *,
                          const struct dpif_flow_del *,
                          int error);
void log_execute_message(const struct dpif *,
                         const struct vlog_module *,
                         const struct dpif_execute *,
                         bool subexecute, int error);
void log_flow_get_message(const struct dpif *,
                          const struct vlog_module *,
                          const struct dpif_flow_get *,
                          int error);
#ifdef  __cplusplus
}
#endif

#endif /* dpif.h */