1 .. SPDX-License-Identifier: BSD-3-Clause
2 Copyright(c) 2016-2017 Intel Corporation.
3 Copyright (C) 2020 Marvell International Ltd.
5 IPsec Security Gateway Sample Application
6 =========================================
8 The IPsec Security Gateway application is an example of a "real world"
9 application using DPDK cryptodev framework.
14 The application demonstrates the implementation of a Security Gateway
15 (not IPsec compliant, see the Constraints section below) using DPDK based on RFC4301,
16 RFC4303, RFC3602 and RFC2404.
18 Internet Key Exchange (IKE) is not implemented, so only manual setting of
19 Security Policies and Security Associations is supported.
21 The Security Policies (SP) are implemented as ACL rules, the Security
22 Associations (SA) are stored in a table and the routing is implemented
25 The application classifies the ports as *Protected* and *Unprotected*.
26 Thus, traffic received on an Unprotected or Protected port is consider
27 Inbound or Outbound respectively.
29 The application also supports complete IPsec protocol offload to hardware
30 (Look aside crypto accelerator or using ethernet device). It also support
31 inline ipsec processing by the supported ethernet device during transmission.
32 These modes can be selected during the SA creation configuration.
34 In case of complete protocol offload, the processing of headers(ESP and outer
35 IP header) is done by the hardware and the application does not need to
36 add/remove them during outbound/inbound processing.
38 For inline offloaded outbound traffic, the application will not do the LPM
39 lookup for routing, as the port on which the packet has to be forwarded will be
40 part of the SA. Security parameters will be configured on that port only, and
41 sending the packet on other ports could result in unencrypted packets being
44 The Path for IPsec Inbound traffic is:
46 * Read packets from the port.
47 * Classify packets between IPv4 and ESP.
48 * Perform Inbound SA lookup for ESP packets based on their SPI.
49 * Perform Verification/Decryption (Not needed in case of inline ipsec).
50 * Remove ESP and outer IP header (Not needed in case of protocol offload).
51 * Inbound SP check using ACL of decrypted packets and any other IPv4 packets.
53 * Write packet to port.
55 The Path for the IPsec Outbound traffic is:
57 * Read packets from the port.
58 * Perform Outbound SP check using ACL of all IPv4 traffic.
59 * Perform Outbound SA lookup for packets that need IPsec protection.
60 * Add ESP and outer IP header (Not needed in case protocol offload).
61 * Perform Encryption/Digest (Not needed in case of inline ipsec).
63 * Write packet to port.
65 The application supports two modes of operation: poll mode and event mode.
67 * In the poll mode a core receives packets from statically configured list
68 of eth ports and eth ports' queues.
70 * In the event mode a core receives packets as events. After packet processing
71 is done core submits them back as events to an event device. This enables
72 multicore scaling and HW assisted scheduling by making use of the event device
73 capabilities. The event mode configuration is predefined. All packets reaching
74 given eth port will arrive at the same event queue. All event queues are mapped
75 to all event ports. This allows all cores to receive traffic from all ports.
76 Since the underlying event device might have varying capabilities, the worker
77 threads can be drafted differently to maximize performance. For example, if an
78 event device - eth device pair has Tx internal port, then application can call
79 rte_event_eth_tx_adapter_enqueue() instead of regular rte_event_enqueue_burst().
80 So a thread which assumes that the device pair has internal port will not be the
81 right solution for another pair. The infrastructure added for the event mode aims
82 to help application to have multiple worker threads by maximizing performance from
83 every type of event device without affecting existing paths/use cases. The worker
84 to be used will be determined by the operating conditions and the underlying device
85 capabilities. **Currently the application provides non-burst, internal port worker
86 threads and supports inline protocol only.** It also provides infrastructure for
87 non-internal port however does not define any worker threads.
89 Event mode also supports event vectorization. The event devices, ethernet device
90 pairs which support the capability ``RTE_EVENT_ETH_RX_ADAPTER_CAP_EVENT_VECTOR`` can
91 aggregate packets based on flow characteristics and generate a ``rte_event``
92 containing ``rte_event_vector``.
93 The aggregation size and timeout can be given using command line options vector-size
94 (default vector-size is 16) and vector-tmo (default vector-tmo is 102400ns).
95 By default event vectorization is disabled and it can be enabled using event-vector
98 Additionally the event mode introduces two submodes of processing packets:
100 * Driver submode: This submode has bare minimum changes in the application to support
101 IPsec. There are no lookups, no routing done in the application. And for inline
102 protocol use case, the worker thread resembles l2fwd worker thread as the IPsec
103 processing is done entirely in HW. This mode can be used to benchmark the raw
104 performance of the HW. The driver submode is selected with --single-sa option
105 (used also by poll mode). When --single-sa option is used in conjunction with event
106 mode then index passed to --single-sa is ignored.
108 * App submode: This submode has all the features currently implemented with the
109 application (non librte_ipsec path). All the lookups, routing follows existing
110 methods and report numbers that can be compared against regular poll mode
116 * No IPv6 options headers.
118 * Supported algorithms: AES-CBC, AES-CTR, AES-GCM, 3DES-CBC, HMAC-SHA1,
119 AES-GMAC, AES_CTR, AES_XCBC_MAC, AES_CCM, CHACHA20_POLY1305 and NULL.
120 * Each SA must be handle by a unique lcore (*1 RX queue per port*).
122 Compiling the Application
123 -------------------------
125 To compile the sample application see :doc:`compiling`.
127 The application is located in the ``ipsec-secgw`` sub-directory.
130 Running the Application
131 -----------------------
133 The application has a number of command line options::
136 ./<build_dir>/examples/dpdk-ipsec-secgw [EAL options] --
137 -p PORTMASK -P -u PORTMASK -j FRAMESIZE
138 -l -w REPLAY_WINDOW_SIZE -e -a
140 -t STATISTICS_INTERVAL
141 -s NUMBER_OF_MBUFS_IN_PACKET_POOL
143 --config (port,queue,lcore)[,(port,queue,lcore)]
145 --cryptodev_mask MASK
147 --event-schedule-type TYPE
152 --frag-ttl FRAG_TTL_NS
156 * ``-p PORTMASK``: Hexadecimal bitmask of ports to configure.
158 * ``-P``: *optional*. Sets all ports to promiscuous mode so that packets are
159 accepted regardless of the packet's Ethernet MAC destination address.
160 Without this option, only packets with the Ethernet MAC destination address
161 set to the Ethernet address of the port are accepted (default is enabled).
163 * ``-u PORTMASK``: hexadecimal bitmask of unprotected ports
165 * ``-j FRAMESIZE``: *optional*. data buffer size (in bytes),
166 in other words maximum data size for one segment.
167 Packets with length bigger then FRAMESIZE still can be received,
168 but will be segmented.
169 Default value: RTE_MBUF_DEFAULT_BUF_SIZE (2176)
170 Minimum value: RTE_MBUF_DEFAULT_BUF_SIZE (2176)
171 Maximum value: UINT16_MAX (65535).
173 * ``-l``: enables code-path that uses librte_ipsec.
175 * ``-w REPLAY_WINDOW_SIZE``: specifies the IPsec sequence number replay window
176 size for each Security Association (available only with librte_ipsec
179 * ``-e``: enables Security Association extended sequence number processing
180 (available only with librte_ipsec code path).
182 * ``-a``: enables Security Association sequence number atomic behavior
183 (available only with librte_ipsec code path).
185 * ``-c``: specifies the SAD cache size. Stores the most recent SA in a per
186 lcore cache. Cache represents flat array containing SA's indexed by SPI.
187 Zero value disables cache.
190 * ``-t``: specifies the statistics screen update interval in seconds. If set
191 to zero or omitted statistics screen is disabled.
194 * ``-s``: sets number of mbufs in packet pool, if not provided number of mbufs
195 will be calculated based on number of cores, eth ports and crypto queues.
197 * ``-f CONFIG_FILE_PATH``: the full path of text-based file containing all
198 configuration items for running the application (See Configuration file
199 syntax section below). ``-f CONFIG_FILE_PATH`` **must** be specified.
200 **ONLY** the UNIX format configuration file is accepted.
202 * ``--config (port,queue,lcore)[,(port,queue,lcore)]``: in poll mode determines
203 which queues from which ports are mapped to which cores. In event mode this
204 option is not used as packets are dynamically scheduled to cores by HW.
206 * ``--single-sa SAIDX``: in poll mode use a single SA for outbound traffic,
207 bypassing the SP on both Inbound and Outbound. This option is meant for
208 debugging/performance purposes. In event mode selects driver submode, SA index
211 * ``--cryptodev_mask MASK``: hexadecimal bitmask of the crypto devices
214 * ``--transfer-mode MODE``: sets operating mode of the application
215 "poll" : packet transfer via polling (default)
216 "event" : Packet transfer via event device
218 * ``--event-schedule-type TYPE``: queue schedule type, applies only when
219 --transfer-mode is set to event.
220 "ordered" : Ordered (default)
222 "parallel" : Parallel
223 When --event-schedule-type is set as RTE_SCHED_TYPE_ORDERED/ATOMIC, event
224 device will ensure the ordering. Ordering will be lost when tried in PARALLEL.
226 * ``--rxoffload MASK``: RX HW offload capabilities to enable/use on this port
227 (bitmask of RTE_ETH_RX_OFFLOAD_* values). It is an optional parameter and
228 allows user to disable some of the RX HW offload capabilities.
229 By default all HW RX offloads are enabled.
231 * ``--txoffload MASK``: TX HW offload capabilities to enable/use on this port
232 (bitmask of RTE_ETH_TX_OFFLOAD_* values). It is an optional parameter and
233 allows user to disable some of the TX HW offload capabilities.
234 By default all HW TX offloads are enabled.
236 * ``--reassemble NUM``: max number of entries in reassemble fragment table.
237 Zero value disables reassembly functionality.
240 * ``--mtu MTU``: MTU value (in bytes) on all attached ethernet ports.
241 Outgoing packets with length bigger then MTU will be fragmented.
242 Incoming packets with length bigger then MTU will be discarded.
245 * ``--frag-ttl FRAG_TTL_NS``: fragment lifetime (in nanoseconds).
246 If packet is not reassembled within this time, received fragments
247 will be discarded. Fragment lifetime should be decreased when
248 there is a high fragmented traffic loss in high bandwidth networks.
249 Should be lower for low number of reassembly buckets.
250 Valid values: from 1 ns to 10 s. Default value: 10000000 (10 s).
252 * ``--per-port-pool``: Enable per ethdev port pktmbuf pool.
253 By default one packet mbuf pool per socket is created and configured
256 * ``--vector-pool-sz``: Number of buffers in vector pool.
257 By default, vector pool size depeneds on packet pool size
258 and size of each vector.
260 The mapping of lcores to port/queues is similar to other l3fwd applications.
262 For example, given the following command line to run application in poll mode::
264 ./<build_dir>/examples/dpdk-ipsec-secgw -l 20,21 -n 4 --socket-mem 0,2048 \
265 --vdev "crypto_null" -- -p 0xf -P -u 0x3 \
266 --config="(0,0,20),(1,0,20),(2,0,21),(3,0,21)" \
267 -f /path/to/config_file --transfer-mode poll \
269 where each option means:
271 * The ``-l`` option enables cores 20 and 21.
273 * The ``-n`` option sets memory 4 channels.
275 * The ``--socket-mem`` to use 2GB on socket 1.
277 * The ``--vdev "crypto_null"`` option creates virtual NULL cryptodev PMD.
279 * The ``-p`` option enables ports (detected) 0, 1, 2 and 3.
281 * The ``-P`` option enables promiscuous mode.
283 * The ``-u`` option sets ports 0 and 1 as unprotected, leaving 2 and 3 as protected.
285 * The ``--config`` option enables one queue per port with the following mapping:
287 +----------+-----------+-----------+---------------------------------------+
288 | **Port** | **Queue** | **lcore** | **Description** |
290 +----------+-----------+-----------+---------------------------------------+
291 | 0 | 0 | 20 | Map queue 0 from port 0 to lcore 20. |
293 +----------+-----------+-----------+---------------------------------------+
294 | 1 | 0 | 20 | Map queue 0 from port 1 to lcore 20. |
296 +----------+-----------+-----------+---------------------------------------+
297 | 2 | 0 | 21 | Map queue 0 from port 2 to lcore 21. |
299 +----------+-----------+-----------+---------------------------------------+
300 | 3 | 0 | 21 | Map queue 0 from port 3 to lcore 21. |
302 +----------+-----------+-----------+---------------------------------------+
304 * The ``-f /path/to/config_file`` option enables the application read and
305 parse the configuration file specified, and configures the application
306 with a given set of SP, SA and Routing entries accordingly. The syntax of
307 the configuration file will be explained below in more detail. Please
308 **note** the parser only accepts UNIX format text file. Other formats
309 such as DOS/MAC format will cause a parse error.
311 * The ``--transfer-mode`` option selects poll mode for processing packets.
313 Similarly for example, given the following command line to run application in
316 ./<build_dir>/examples/dpdk-ipsec-secgw -c 0x3 -- -P -p 0x3 -u 0x1 \
317 -f /path/to/config_file --transfer-mode event \
318 --event-schedule-type parallel --event-vector --vector-size 32 \
319 --vector-tmo 102400 \
321 where each option means:
323 * The ``-c`` option selects cores 0 and 1 to run on.
325 * The ``-P`` option enables promiscuous mode.
327 * The ``-p`` option enables ports (detected) 0 and 1.
329 * The ``-u`` option sets ports 0 as unprotected, leaving 1 as protected.
331 * The ``-f /path/to/config_file`` option has the same behavior as in poll
334 * The ``--transfer-mode`` option selects event mode for processing packets.
336 * The ``--event-schedule-type`` option selects parallel ordering of event queues.
338 * The ``--event-vector`` option enables event vectorization.
340 * The ``--vector-size`` option specifies max vector size.
342 * The ``--vector-tmo`` option specifies max timeout in nanoseconds for vectorization.
345 Refer to the *DPDK Getting Started Guide* for general information on running
346 applications and the Environment Abstraction Layer (EAL) options.
348 The application would do a best effort to "map" crypto devices to cores, with
349 hardware devices having priority. Basically, hardware devices if present would
350 be assigned to a core before software ones.
351 This means that if the application is using a single core and both hardware
352 and software crypto devices are detected, hardware devices will be used.
354 A way to achieve the case where you want to force the use of virtual crypto
355 devices is to only use the Ethernet devices needed (via the allow flag)
356 and therefore implicitly blocking all hardware crypto devices.
358 For example, something like the following command line:
360 .. code-block:: console
362 ./<build_dir>/examples/dpdk-ipsec-secgw -l 20,21 -n 4 --socket-mem 0,2048 \
363 -a 81:00.0 -a 81:00.1 -a 81:00.2 -a 81:00.3 \
364 --vdev "crypto_aesni_mb" --vdev "crypto_null" \
366 -p 0xf -P -u 0x3 --config="(0,0,20),(1,0,20),(2,0,21),(3,0,21)" \
373 The following sections provide the syntax of configurations to initialize
374 your SP, SA, Routing, Flow and Neighbour tables.
375 Configurations shall be specified in the configuration file to be passed to
376 the application. The file is then parsed by the application. The successful
377 parsing will result in the appropriate rules being applied to the tables
381 Configuration File Syntax
382 ~~~~~~~~~~~~~~~~~~~~~~~~~
384 As mention in the overview, the Security Policies are ACL rules.
385 The application parsers the rules specified in the configuration file and
386 passes them to the ACL table, and replicates them per socket in use.
388 Following are the configuration file syntax.
393 The parse treats one line in the configuration file as one configuration
394 item (unless the line concatenation symbol exists). Every configuration
395 item shall follow the syntax of either SP, SA, Routing, Flow or Neighbour
396 rules specified below.
398 The configuration parser supports the following special symbols:
400 * Comment symbol **#**. Any character from this symbol to the end of
401 line is treated as comment and will not be parsed.
403 * Line concatenation symbol **\\**. This symbol shall be placed in the end
404 of the line to be concatenated to the line below. Multiple lines'
405 concatenation is supported.
411 The SP rule syntax is shown as follows:
413 .. code-block:: console
415 sp <ip_ver> <dir> esp <action> <priority> <src_ip> <dst_ip>
416 <proto> <sport> <dport>
419 where each options means:
423 * IP protocol version
429 * *ipv4*: IP protocol version 4
430 * *ipv6*: IP protocol version 6
434 * The traffic direction
440 * *in*: inbound traffic
441 * *out*: outbound traffic
451 * *protect <SA_idx>*: the specified traffic is protected by SA rule
453 * *bypass*: the specified traffic is bypassed
454 * *discard*: the specified traffic is discarded
460 * Optional: Yes, default priority 0 will be used
466 * The source IP address and mask
468 * Optional: Yes, default address 0.0.0.0 and mask of 0 will be used
472 * *src X.X.X.X/Y* for IPv4
473 * *src XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX/Y* for IPv6
477 * The destination IP address and mask
479 * Optional: Yes, default address 0.0.0.0 and mask of 0 will be used
483 * *dst X.X.X.X/Y* for IPv4
484 * *dst XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX/Y* for IPv6
488 * The protocol start and end range
490 * Optional: yes, default range of 0 to 0 will be used
492 * Syntax: *proto X:Y*
496 * The source port start and end range
498 * Optional: yes, default range of 0 to 0 will be used
500 * Syntax: *sport X:Y*
504 * The destination port start and end range
506 * Optional: yes, default range of 0 to 0 will be used
508 * Syntax: *dport X:Y*
512 .. code-block:: console
514 sp ipv4 out esp protect 105 pri 1 dst 192.168.115.0/24 sport 0:65535 \
517 sp ipv6 in esp bypass pri 1 dst 0000:0000:0000:0000:5555:5555:\
518 0000:0000/96 sport 0:65535 dport 0:65535
524 The successfully parsed SA rules will be stored in an array table.
526 The SA rule syntax is shown as follows:
528 .. code-block:: console
530 sa <dir> <spi> <cipher_algo> <cipher_key> <auth_algo> <auth_key>
531 <mode> <src_ip> <dst_ip> <action_type> <port_id> <fallback>
532 <flow-direction> <port_id> <queue_id> <udp-encap>
534 where each options means:
538 * The traffic direction
544 * *in*: inbound traffic
545 * *out*: outbound traffic
553 * Syntax: unsigned integer number
559 * Optional: Yes, unless <aead_algo> is not used
563 * *null*: NULL algorithm
564 * *aes-128-cbc*: AES-CBC 128-bit algorithm
565 * *aes-192-cbc*: AES-CBC 192-bit algorithm
566 * *aes-256-cbc*: AES-CBC 256-bit algorithm
567 * *aes-128-ctr*: AES-CTR 128-bit algorithm
568 * *3des-cbc*: 3DES-CBC 192-bit algorithm
570 * Syntax: *cipher_algo <your algorithm>*
574 * Cipher key, NOT available when 'null' algorithm is used
576 * Optional: Yes, unless <aead_algo> is not used.
577 Must be followed by <cipher_algo> option
579 * Syntax: Hexadecimal bytes (0x0-0xFF) concatenate by colon symbol ':'.
580 The number of bytes should be as same as the specified cipher algorithm
583 For example: *cipher_key A1:B2:C3:D4:A1:B2:C3:D4:A1:B2:C3:D4:
588 * Authentication algorithm
590 * Optional: Yes, unless <aead_algo> is not used
594 * *null*: NULL algorithm
595 * *sha1-hmac*: HMAC SHA1 algorithm
599 * Authentication key, NOT available when 'null' or 'aes-128-gcm' algorithm
602 * Optional: Yes, unless <aead_algo> is not used.
603 Must be followed by <auth_algo> option
605 * Syntax: Hexadecimal bytes (0x0-0xFF) concatenate by colon symbol ':'.
606 The number of bytes should be as same as the specified authentication
609 For example: *auth_key A1:B2:C3:D4:A1:B2:C3:D4:A1:B2:C3:D4:A1:B2:C3:D4:
616 * Optional: Yes, unless <cipher_algo> and <auth_algo> are not used
620 * *aes-128-gcm*: AES-GCM 128-bit algorithm
621 * *aes-192-gcm*: AES-GCM 192-bit algorithm
622 * *aes-256-gcm*: AES-GCM 256-bit algorithm
624 * Syntax: *cipher_algo <your algorithm>*
628 * Cipher key, NOT available when 'null' algorithm is used
630 * Optional: Yes, unless <cipher_algo> and <auth_algo> are not used.
631 Must be followed by <aead_algo> option
633 * Syntax: Hexadecimal bytes (0x0-0xFF) concatenate by colon symbol ':'.
634 Last 4 bytes of the provided key will be used as 'salt' and so, the
635 number of bytes should be same as the sum of specified AEAD algorithm
636 key size and salt size (4 bytes).
638 For example: *aead_key A1:B2:C3:D4:A1:B2:C3:D4:A1:B2:C3:D4:
639 A1:B2:C3:D4:A1:B2:C3:D4*
649 * *ipv4-tunnel*: Tunnel mode for IPv4 packets
650 * *ipv6-tunnel*: Tunnel mode for IPv6 packets
651 * *transport*: transport mode
657 * The source IP address. This option is not available when
658 transport mode is used
660 * Optional: Yes, default address 0.0.0.0 will be used
664 * *src X.X.X.X* for IPv4
665 * *src XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX* for IPv6
669 * The destination IP address. This option is not available when
670 transport mode is used
672 * Optional: Yes, default address 0.0.0.0 will be used
676 * *dst X.X.X.X* for IPv4
677 * *dst XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX* for IPv6
681 * Action type to specify the security action. This option specify
682 the SA to be performed with look aside protocol offload to HW
683 accelerator or protocol offload on ethernet device or inline
684 crypto processing on the ethernet device during transmission.
686 * Optional: Yes, default type *no-offload*
690 * *lookaside-protocol-offload*: look aside protocol offload to HW accelerator
691 * *inline-protocol-offload*: inline protocol offload on ethernet device
692 * *inline-crypto-offload*: inline crypto processing on ethernet device
693 * *no-offload*: no offloading to hardware
697 * Port/device ID of the ethernet/crypto accelerator for which the SA is
698 configured. For *inline-crypto-offload* and *inline-protocol-offload*, this
699 port will be used for routing. The routing table will not be referred in
702 * Optional: No, if *type* is not *no-offload*
706 * *port_id X* X is a valid device number in decimal
710 * Action type for ingress IPsec packets that inline processor failed to
711 process. Only a combination of *inline-crypto-offload* as a primary
712 session and *lookaside-none* as a fall-back session is supported at the
715 If used in conjunction with IPsec window, its width needs be increased
716 due to different processing times of inline and lookaside modes which
717 results in packet reordering.
723 * *lookaside-none*: use automatically chosen cryptodev to process packets
727 * *fallback lookaside-none*
731 * Option for redirecting a specific inbound ipsec flow of a port to a specific
738 * *port_id*: Port ID of the NIC for which the SA is configured.
739 * *queue_id*: Queue ID to which traffic should be redirected.
743 * Option to enable IPsec UDP encapsulation for NAT Traversal.
744 Only *lookaside-protocol-offload* and *inline-crypto-offload* modes are
745 supported at the moment.
747 * Optional: Yes, it is disabled by default
755 * Maximum segment size for TSO offload, available for egress SAs only.
757 * Optional: Yes, TSO offload not set by default
761 * *mss N* N is the segment size in bytes
766 * Option to enable per SA telemetry.
767 Currently only supported with IPsec library path.
769 * Optional: Yes, it is disabled by default
777 * Enable ESN and set the initial ESN value.
779 * Optional: Yes, ESN not enabled by default
783 * *esn N* N is the initial ESN value
787 .. code-block:: console
789 sa out 5 cipher_algo null auth_algo null mode ipv4-tunnel \
790 src 172.16.1.5 dst 172.16.2.5
792 sa out 25 cipher_algo aes-128-cbc \
793 cipher_key c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3 \
794 auth_algo sha1-hmac \
795 auth_key c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3:c3 \
797 src 1111:1111:1111:1111:1111:1111:1111:5555 \
798 dst 2222:2222:2222:2222:2222:2222:2222:5555
800 sa in 105 aead_algo aes-128-gcm \
801 aead_key de:ad:be:ef:de:ad:be:ef:de:ad:be:ef:de:ad:be:ef:de:ad:be:ef \
802 mode ipv4-tunnel src 172.16.2.5 dst 172.16.1.5
804 sa out 5 cipher_algo aes-128-cbc cipher_key 0:0:0:0:0:0:0:0:0:0:0:0:0:0:0:0 \
805 auth_algo sha1-hmac auth_key 0:0:0:0:0:0:0:0:0:0:0:0:0:0:0:0:0:0:0:0 \
806 mode ipv4-tunnel src 172.16.1.5 dst 172.16.2.5 \
807 type lookaside-protocol-offload port_id 4
809 sa in 35 aead_algo aes-128-gcm \
810 aead_key de:ad:be:ef:de:ad:be:ef:de:ad:be:ef:de:ad:be:ef:de:ad:be:ef \
811 mode ipv4-tunnel src 172.16.2.5 dst 172.16.1.5 \
812 type inline-crypto-offload port_id 0
814 sa in 117 cipher_algo null auth_algo null mode ipv4-tunnel src 172.16.2.7 \
815 dst 172.16.1.7 flow-direction 0 2
820 The Routing rule syntax is shown as follows:
822 .. code-block:: console
824 rt <ip_ver> <src_ip> <dst_ip> <port>
827 where each options means:
831 * IP protocol version
837 * *ipv4*: IP protocol version 4
838 * *ipv6*: IP protocol version 6
842 * The source IP address and mask
844 * Optional: Yes, default address 0.0.0.0 and mask of 0 will be used
848 * *src X.X.X.X/Y* for IPv4
849 * *src XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX/Y* for IPv6
853 * The destination IP address and mask
855 * Optional: Yes, default address 0.0.0.0 and mask of 0 will be used
859 * *dst X.X.X.X/Y* for IPv4
860 * *dst XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX/Y* for IPv6
864 * The traffic output port id
866 * Optional: yes, default output port 0 will be used
872 .. code-block:: console
874 rt ipv4 dst 172.16.1.5/32 port 0
876 rt ipv6 dst 1111:1111:1111:1111:1111:1111:1111:5555/116 port 0
881 Flow rule enables the usage of hardware classification capabilities to match specific
882 ingress traffic and redirect the packets to the specified queue. This feature is
883 optional and relies on hardware ``rte_flow`` support.
885 The flow rule syntax is shown as follows:
887 .. code-block:: console
889 flow <ip_ver> <src_ip> <dst_ip> <port> <queue>
892 where each options means:
896 * IP protocol version
902 * *ipv4*: IP protocol version 4
903 * *ipv6*: IP protocol version 6
907 * The source IP address and mask
909 * Optional: Yes, default address 0.0.0.0 and mask of 0 will be used
913 * *src X.X.X.X/Y* for IPv4
914 * *src XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX/Y* for IPv6
918 * The destination IP address and mask
920 * Optional: Yes, default address 0.0.0.0 and mask of 0 will be used
924 * *dst X.X.X.X/Y* for IPv4
925 * *dst XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX:XXXX/Y* for IPv6
929 * The traffic input port id
931 * Optional: yes, default input port 0 will be used
937 * The traffic input queue id
939 * Optional: yes, default input queue 0 will be used
945 .. code-block:: console
947 flow ipv4 dst 172.16.1.5/32 port 0 queue 0
949 flow ipv6 dst 1111:1111:1111:1111:1111:1111:1111:5555/116 port 1 queue 0
952 Neighbour rule syntax
953 ^^^^^^^^^^^^^^^^^^^^^
955 The Neighbour rule syntax is shown as follows:
957 .. code-block:: console
959 neigh <port> <dst_mac>
962 where each options means:
974 * The destination ethernet address to use for that port
982 Example Neighbour rules:
984 .. code-block:: console
986 neigh port 0 DE:AD:BE:EF:01:02
991 The test directory contains scripts for testing the various encryption
994 The purpose of the scripts is to automate ipsec-secgw testing
995 using another system running linux as a DUT.
997 The user must setup the following environment variables:
999 * ``SGW_PATH``: path to the ipsec-secgw binary to test.
1001 * ``REMOTE_HOST``: IP address/hostname of the DUT.
1003 * ``REMOTE_IFACE``: interface name for the test-port on the DUT.
1005 * ``ETH_DEV``: ethernet device to be used on the SUT by DPDK ('-a <pci-id>')
1007 Also the user can optionally setup:
1009 * ``SGW_LCORE``: lcore to run ipsec-secgw on (default value is 0)
1011 * ``CRYPTO_DEV``: crypto device to be used ('-a <pci-id>'). If none specified
1012 appropriate vdevs will be created by the script
1014 Scripts can be used for multiple test scenarios. To check all available
1017 .. code-block:: console
1019 /bin/bash run_test.sh -h
1021 Note that most of the tests require the appropriate crypto PMD/device to be
1024 Server configuration
1025 ~~~~~~~~~~~~~~~~~~~~
1027 Two servers are required for the tests, SUT and DUT.
1029 Make sure the user from the SUT can ssh to the DUT without entering the password.
1030 To enable this feature keys must be setup on the DUT.
1032 ``ssh-keygen`` will make a private & public key pair on the SUT.
1034 ``ssh-copy-id`` <user name>@<target host name> on the SUT will copy the public
1035 key to the DUT. It will ask for credentials so that it can upload the public key.
1037 The SUT and DUT are connected through at least 2 NIC ports.
1039 One NIC port is expected to be managed by linux on both machines and will be
1040 used as a control path.
1042 The second NIC port (test-port) should be bound to DPDK on the SUT, and should
1043 be managed by linux on the DUT.
1045 The script starts ``ipsec-secgw`` with 2 NIC devices: ``test-port`` and
1048 It then configures the local tap interface and the remote interface and IPsec
1049 policies in the following way:
1051 Traffic going over the test-port in both directions has to be protected by IPsec.
1053 Traffic going over the TAP port in both directions does not have to be protected.
1057 DUT OS(NIC1)--(IPsec)-->(NIC1)ipsec-secgw(TAP)--(plain)-->(TAP)SUT OS
1059 SUT OS(TAP)--(plain)-->(TAP)psec-secgw(NIC1)--(IPsec)-->(NIC1)DUT OS
1061 It then tries to perform some data transfer using the scheme described above.
1066 In the ipsec-secgw/test directory run
1068 /bin/bash run_test.sh <options> <ipsec_mode>
1072 * ``-4`` Perform tests with use of IPv4. One or both [-46] options needs to be
1075 * ``-6`` Perform tests with use of IPv6. One or both [-46] options needs to be
1078 * ``-m`` Add IPSec tunnel mixed IP version tests - outer IP version different
1079 than inner. Inner IP version will match selected option [-46].
1081 * ``-i`` Run tests in inline mode. Regular tests will not be invoked.
1083 * ``-f`` Run tests for fallback mechanism. Regular tests will not be invoked.
1085 * ``-l`` Run tests in legacy mode only. It cannot be used with options [-fsc].
1086 On default library mode is used.
1088 * ``-s`` Run all tests with reassembly support. On default only tests for
1089 fallback mechanism use reassembly support.
1091 * ``-c`` Run tests with use of cpu-crypto. For inline tests it will not be
1092 applied. On default lookaside-none is used.
1094 * ``-p`` Perform packet validation tests. Option [-46] is not required.
1096 * ``-h`` Show usage.
1098 If <ipsec_mode> is specified, only tests for that mode will be invoked. For the
1099 list of available modes please refer to run_test.sh.