Difference between revisions of "VPP/SecurityGroups"

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(Add note about some vppctl support for ACLs)
(CLI)
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  Please see the following vppctl commands:
 
  Please see the following vppctl commands:
 
+
 
  clear acl-plugin sessions
 
  clear acl-plugin sessions
 
  delete acl-plugin acl
 
  delete acl-plugin acl

Revision as of 13:24, 20 March 2024

VPP Security Groups

Introduction

Features are tracked as they are developed in the following VPP-427.

The 1.2 version of the plugin is committed via change 5805

The 1.1 version of the plugin is committed via change 3423

ACL Node architecture in 17.01

Changes/News in the version 1.2

Unified L2 / L3 processing path

This version adds the processing for the packets in the routed data path in addition to the switching data path by the same code with the same API.

It also collapses the entire processing into the single node - per-AF, per-L2/L3, per-direction. (So in total there are 8 nodes using the same core code).

The node architecture on the diagram here is thus now simplified, with an ACL node combining the session lookup and ACL lookup.

(1704: The old processing path is still there, but is not used and is left for the time being for potential backwards compatibility/ fallback purposes. The goal is to have it removed by 17.07 version.)

IPv6 extension header skipping

This version adds the skipping of most of the known extension headers during the ACL processing, so one can for example skip the Segment Routing header when matching.

In this version, the extension headers to be skipped are treated with the semantics of https://tools.ietf.org/html/rfc6564 semantics.

For a given extension header value, one can choose - either to skip it, or to treat it as a L4 protocol number - so as to be able to match on that within the ACL.


Performance

The initial performance tests of 1.2 version show the comparable performance to 1.1, which is expected since the main focus for this version was getting to feature completeness. The performance (along side with multithread-safety) will be the target of the 1.3 version for the release 17.07.

Example packet traces

The below packet trace shows the inbound security ACL in the L3 packet path and an outbound security ACL in L2 packet path, this can be reproduced as part of the unit tests, by doing "TEST=acl_plugin_l2l3 make test-debug":


00:00:01:433983: pg-input
  stream pcap3, 73 bytes, 3 sw_if_index
  current data 0, length 73, free-list 6, clone-count 0, trace 0x1
  IP6: 02:03:00:00:ff:02 -> 02:fe:30:f6:b7:4e
  UDP: fd01:3::2 -> fd01:4::3
    tos 0x00, flow label 0x0, hop limit 64, payload length 19
  UDP: 1235 -> 4322
    length 19, checksum 0xda44
00:00:01:434603: ethernet-input
  IP6: 02:03:00:00:ff:02 -> 02:fe:30:f6:b7:4e
00:00:01:434625: ip6-input
  UDP: fd01:3::2 -> fd01:4::3
    tos 0x00, flow label 0x0, hop limit 64, payload length 19
  UDP: 1235 -> 4322
    length 19, checksum 0xda44
00:00:01:434636: acl-plugin-in-ip6-fa
  acl-plugin: sw_if_index 3, next index 1, action: 1, match: acl 1 rule 1 trace_bits 00000000
  pkt info 00000000030001fd 0200000000000000 00000000040001fd 0300000000000000 0000001110e204d3 0000000000000420
00:00:01:434683: ip6-lookup
  fib 0 dpo-idx 257 flow hash: 0x00000000
  UDP: fd01:3::2 -> fd01:4::3
    tos 0x00, flow label 0x0, hop limit 64, payload length 19
  UDP: 1235 -> 4322
    length 19, checksum 0xda44
00:00:01:434699: ip6-rewrite
  tx_sw_if_index 4 adj-idx 257 : ipv6 via fd01:4::3 loop0: 02040000ff03dead0000000086dd flow hash: 0x00000000
  00000000: 02040000ff03dead0000000086dd600000000013113ffd010003000000000000
  00000020: 000000000002fd01000400000000000000000000000304d310e20013da443020
  00000040: 332034202d31202d310000000000000000000000000000000000000000000000
  00000060: 00000000000000000000000000000000000000000000000000000000
00:00:01:434728: loop0-output
  loop0
  IP6: de:ad:00:00:00:00 -> 02:04:00:00:ff:03
  UDP: fd01:3::2 -> fd01:4::3
    tos 0x00, flow label 0x0, hop limit 63, payload length 19
  UDP: 1235 -> 4322
    length 19, checksum 0xda44
00:00:01:434739: l2-input
  l2-input: sw_if_index 4 dst 02:04:00:00:ff:03 src de:ad:00:00:00:00
00:00:01:434749: l2-fwd
  l2-fwd:   sw_if_index 4 dst 02:04:00:00:ff:03 src de:ad:00:00:00:00 bd_index 1
00:00:01:434759: l2-flood
  l2-flood: sw_if_index 4 dst 02:04:00:00:ff:03 src de:ad:00:00:00:00 bd_index 1
00:00:01:434775: l2-output
  l2-output: sw_if_index 2 dst 02:04:00:00:ff:03 src de:ad:00:00:00:00 data 86 dd 60 00 00 00 00 13 11 3f fd 01
00:00:01:434800: l2-output-classify
  l2-classify: sw_if_index 2, table 5, offset 0, next 2
00:00:01:434816: acl-plugin-out-ip6-l2
  acl-plugin: sw_if_index 2, next index 1, action: 1, match: acl 0 rule 1 trace_bits 00000000
  pkt info 00000000030001fd 0200000000000000 00000000040001fd 0300000000000000 0000001110e204d3 0000000000000420
00:00:01:434848: pg1-output
  pg1
  IP6: de:ad:00:00:00:00 -> 02:04:00:00:ff:03
  UDP: fd01:3::2 -> fd01:4::3
    tos 0x00, flow label 0x0, hop limit 63, payload length 19
  UDP: 1235 -> 4322
    length 19, checksum 0xda44
00:00:01:434858: pg1-tx
    buffer 0xb4b4: current data 0, length 73, free-list 5, clone-count 0, trace 0x1
  IP6: de:ad:00:00:00:00 -> 02:04:00:00:ff:03
  UDP: fd01:3::2 -> fd01:4::3
    tos 0x00, flow label 0x0, hop limit 63, payload length 19
  UDP: 1235 -> 4322
    length 19, checksum 0xda44
00:00:01:434941: l2-flood
  l2-flood: sw_if_index 4 dst 02:04:00:00:ff:03 src de:ad:00:00:00:00 bd_index 1
00:00:01:434957: l2-output
  l2-output: sw_if_index 1 dst 02:04:00:00:ff:03 src de:ad:00:00:00:00 data 86 dd 60 00 00 00 00 13 11 3f fd 01
00:00:01:434966: l2-output-classify
  l2-classify: sw_if_index 1, table 3, offset 0, next 2
00:00:01:434969: acl-plugin-out-ip6-l2
  acl-plugin: sw_if_index 1, next index 1, action: 1, match: acl 0 rule 1 trace_bits 00000000
  pkt info 00000000030001fd 0200000000000000 00000000040001fd 0300000000000000 0000001110e204d3 0000000000000420
00:00:01:434975: pg0-output
  pg0
  IP6: de:ad:00:00:00:00 -> 02:04:00:00:ff:03
  UDP: fd01:3::2 -> fd01:4::3
    tos 0x00, flow label 0x0, hop limit 63, payload length 19
  UDP: 1235 -> 4322
    length 19, checksum 0xda44
00:00:01:434978: pg0-tx
    buffer 0xb4b4: current data 0, length 73, free-list 6, clone-count 0, trace 0x1
  IP6: de:ad:00:00:00:00 -> 02:04:00:00:ff:03
  UDP: fd01:3::2 -> fd01:4::3
    tos 0x00, flow label 0x0, hop limit 63, payload length 19
  UDP: 1235 -> 4322
    length 19, checksum 0xda44

A trace in the other direction:

00:00:02:616543: pg-input
  stream pcap1, 73 bytes, 1 sw_if_index
  current data 0, length 73, free-list 7, clone-count 0, trace 0x1
  IP6: 02:04:00:00:ff:03 -> de:ad:00:00:00:00
  UDP: fd01:4::3 -> fd01:3::2
    tos 0x00, flow label 0x0, hop limit 64, payload length 19
  UDP: 4322 -> 1235
    length 19, checksum 0xda44
00:00:02:617044: ethernet-input
  IP6: 02:04:00:00:ff:03 -> de:ad:00:00:00:00
00:00:02:617074: l2-input
  l2-input: sw_if_index 1 dst de:ad:00:00:00:00 src 02:04:00:00:ff:03
00:00:02:617086: l2-input-classify
  l2-classify: sw_if_index 1, table 3, offset 0, next 17
00:00:02:617101: acl-plugin-in-ip6-l2
  acl-plugin: sw_if_index 1, next index 7, action: 1, match: acl 8 rule 1 trace_bits 00000000
  pkt info 00000000040001fd 0300000000000000 00000000030001fd 0200000000000000 0000001104d310e2 0000000000000420
00:00:02:617155: l2-learn
  l2-learn: sw_if_index 1 dst de:ad:00:00:00:00 src 02:04:00:00:ff:03 bd_index 1
00:00:02:617173: l2-fwd
  l2-fwd:   sw_if_index 1 dst de:ad:00:00:00:00 src 02:04:00:00:ff:03 bd_index 1
00:00:02:617182: ip6-input
  UDP: fd01:4::3 -> fd01:3::2
    tos 0x00, flow label 0x0, hop limit 64, payload length 19
  UDP: 4322 -> 1235
    length 19, checksum 0xda44
00:00:02:617191: ip6-lookup
  fib 0 dpo-idx 507 flow hash: 0x00000000
  UDP: fd01:4::3 -> fd01:3::2
    tos 0x00, flow label 0x0, hop limit 64, payload length 19
  UDP: 4322 -> 1235
    length 19, checksum 0xda44
00:00:02:617215: ip6-rewrite
  tx_sw_if_index 3 adj-idx 507 : ipv6 via fd01:3::2 pg2: 02030000ff0202fe30f6b74e86dd flow hash: 0x00000000
  00000000: 02030000ff0202fe30f6b74e86dd600000000013113ffd010004000000000000
  00000020: 000000000003fd01000300000000000000000000000210e204d30013da443020
  00000040: 332034202d31202d310000000000000000000000000000000000000000000000
  00000060: 00000000000000000000000000000000000000000000000000000000
00:00:02:617227: acl-plugin-out-ip6-fa
  acl-plugin: sw_if_index 3, next index 1, action: 1, match: acl 9 rule 1 trace_bits 00000000
  pkt info 00000000040001fd 0300000000000000 00000000030001fd 0200000000000000 0000001104d310e2 0000000000000420
00:00:02:617238: pg2-output
  pg2
  IP6: 02:fe:30:f6:b7:4e -> 02:03:00:00:ff:02
  UDP: fd01:4::3 -> fd01:3::2
    tos 0x00, flow label 0x0, hop limit 63, payload length 19
  UDP: 4322 -> 1235
    length 19, checksum 0xda44
00:00:02:617253: pg2-tx
    buffer 0xb4b4: current data 0, length 73, free-list 7, clone-count 0, trace 0x1
  IP6: 02:fe:30:f6:b7:4e -> 02:03:00:00:ff:02
  UDP: fd01:4::3 -> fd01:3::2
    tos 0x00, flow label 0x0, hop limit 63, payload length 19
  UDP: 4322 -> 1235
    length 19, checksum 0xda44

The below is a sample trace from an L2-only path with just an ingress ACL on IPv4, from a "test_acl_plugin.py" run:

00:00:01:189275: pg-input
  stream pcap1, 9014 bytes, 1 sw_if_index
  current data 0, length 9014, free-list 6, clone-count 0, trace 0x1
  IP4: 00:00:00:ff:01:01 -> 00:00:00:ff:02:08
  UDP: 172.17.101.1 -> 172.17.102.8
    tos 0x00, ttl 64, length 9000, checksum 0x3498
    fragment id 0x0001
  UDP: 11 -> 21541
    length 8980, checksum 0xfa5e
00:00:01:189796: ethernet-input
  IP4: 00:00:00:ff:01:01 -> 00:00:00:ff:02:08
00:00:01:189879: l2-input
  l2-input: sw_if_index 1 dst 00:00:00:ff:02:08 src 00:00:00:ff:01:01
00:00:01:189901: l2-input-classify
  l2-classify: sw_if_index 1, table 0, offset 0, next 16
00:00:01:189932: acl-plugin-in-ip4-l2
  acl-plugin: sw_if_index 1, next index 7, action: 1, match: acl 2 rule 0 trace_bits 00000000
  pkt info 0000000000000000 016511ac00000000 0000000000000000 086611ac00000000 000000115425000b 0000000000000420
00:00:01:190038: l2-learn
  l2-learn: sw_if_index 1 dst 00:00:00:ff:02:08 src 00:00:00:ff:01:01 bd_index 1
00:00:01:190059: l2-fwd
  l2-fwd:   sw_if_index 1 dst 00:00:00:ff:02:08 src 00:00:00:ff:01:01 bd_index 1
00:00:01:190076: l2-flood
  l2-flood: sw_if_index 1 dst 00:00:00:ff:02:08 src 00:00:00:ff:01:01 bd_index 1
00:00:01:190091: l2-output
  l2-output: sw_if_index 2 dst 00:00:00:ff:02:08 src 00:00:00:ff:01:01 data 08 00 45 00 23 28 00 01 00 00 40 11
00:00:01:190108: pg1-output
  pg1
  IP4: 00:00:00:ff:01:01 -> 00:00:00:ff:02:08
  UDP: 172.17.101.1 -> 172.17.102.8
    tos 0x00, ttl 64, length 9000, checksum 0x3498
    fragment id 0x0001
  UDP: 11 -> 21541
    length 8980, checksum 0xfa5e
00:00:01:190202: pg1-tx
    buffer 0x7008: current data 0, length 9014, free-list 6, clone-count 0, trace 0x1
  IP4: 00:00:00:ff:01:01 -> 00:00:00:ff:02:08
  UDP: 172.17.101.1 -> 172.17.102.8
    tos 0x00, ttl 64, length 9000, checksum 0x3498
    fragment id 0x0001
  UDP: 11 -> 21541
    length 8980, checksum 0xfa5e

CLI

The ACL plugin does not supply the "supported" debug CLI for configuration, but has the full support for talking to it via VAT CLI, which are documented below.

Note from 2024: In contrast with the above statement
there seems to be some debug CLI support introduced in
https://gerrit.fd.io/r/c/vpp/+/5805 and
https://gerrit.fd.io/r/c/vpp/+/8805 .

Please see the following vppctl commands:

clear acl-plugin sessions
delete acl-plugin acl
set acl-plugin
set acl-plugin acl
set acl-plugin interface
set flow classify
set interface input acl
set interface output acl
show acl-plugin acl
show acl-plugin decode 5tuple
show acl-plugin interface
show acl-plugin lookup context
show acl-plugin lookup user
show acl-plugin macip acl
show acl-plugin macip interface
show acl-plugin memory
show acl-plugin sessions
show acl-plugin tables
show inacl
show outacl              

acl_plugin_get_version : get plugin version

Show the version of the ACL plugin

vat# acl_plugin_get_version
vl_api_acl_plugin_get_version_reply_t_handler:133: ACL plugin version: 1.1
vat#

acl_add_replace : add or replace an ACL

Add a new ACL or replace the existing one. To replace an existing ACL, pass the ID of this ACL. If you prefer a new ACL to be created, pass the 0xffffffff (-1)

Since the single API call defines the entire ACL, all of the entries of this ACL are specified on the same line, separated by commas.

A quasi-BNF syntax of the VAT command line is below:

acl_add_replace <acl-idx> [<ipv4|ipv6> <permit|permit+reflect|deny|action N> [src IP/plen] [dst IP/plen] [sport X-Y] [dport X-Y] [proto P] [tcpflags FL MASK], ... , ...


An example of adding a single ACL permitting IPv4 and IPv6 is below:

vat# acl_add_replace permit, ipv6 permit
vl_api_acl_add_replace_reply_t_handler:107: ACL index: 0
vat#

Replacing this ACL#0 by one with two host entries:

vat# acl_add_replace 0 ipv6 permit dst 2001:db8::1/128, ipv4 permit src 192.0.2.1/32
vl_api_acl_add_replace_reply_t_handler:107: ACL index: 0
vat#

acl_del : delete an ACL

Simply pass the ID of the ACL to delete it:

vat# acl_del 0
vat#

acl_dump : dump ACL(s)

Use the command without any arguments to dump all configured ACLs, or supply the optional ACL ID to dump only that ACL:

vat# acl_dump
vl_api_acl_details_t_handler:193: acl_index: 0, count: 2
   tag {}
   ipv6 action 1 src ::/0 dst 2001:db8::1/128 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 1.1.1.1/32 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0
vl_api_acl_details_t_handler:193: acl_index: 1, count: 2
   tag {}
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv6 action 1 src ::/0 dst ::/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0
vl_api_acl_details_t_handler:193: acl_index: 2, count: 5
   tag {}
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0
vat# acl_dump 2
vl_api_acl_details_t_handler:193: acl_index: 2, count: 5
   tag {}
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0,
   ipv4 action 1 src 0.0.0.0/0 dst 0.0.0.0/0 proto 0 sport 0-65535 dport 0-65535 tcpflags 0 0
vat#


Notice that the output format of each ACL is (minus the newlines) suitable for feeding it as input to VAT to recreate that ACL.

acl_interface_add_del (not recommended) : add/delete ACL to/from list of applied ACLs on an interface

This command allows to append/delete one input or output ACL to the list of the ACLs applied to an interface.

Because one would mostly want to predictably set the ACLs, the usage of this API is not recommended.

The pseudo-BNF format is below:

acl_interface_add_del <intfc> | sw_if_index <if-idx> [add|del] [input|output] acl <acl-idx>

acl_interface_set_acl_list : set the list of inbound+outbound ACLs for a given interface

This command sets in one shot the list of input and output ACLs applied to the interface. It unapplies any previously applied ACLs, which makes this command idempotent.

 acl_interface_set_acl_list <intfc> | sw_if_index <if-idx> input [acl-idx list] output [acl-idx list]


An example:

vat# acl_interface_set_acl_list sw_if_index 0 input 0 output 0 1 2
vat#

acl_interface_list_dump : show which interfaces have which lists of which ACLs applied

acl_interface_list_dump [<intfc> | sw_if_index <if-idx>]

This command lists which ACLs are applied on which interface and in which direction.

The below example is a result from setting the ACL on the interface using the previous command:


vat# acl_interface_list_dump
vl_api_acl_interface_list_details_t_handler:152: sw_if_index: 0, count: 4, n_input: 1
   input 0
  output 0 1 2
vat#

macip_acl_add : add a MACIP ACL

macip_acl_add [ipv4|ipv6] [permit|deny|action N] [ip <ADDR>/<PREFIX-LEN> mac <MAC> mask <MAC-MASK>, ...


vat# macip_acl_add ipv4 permit ip 1.1.1.1/32 mac 00:01:02:03:04:05 mask ff:ff:ff:ff:ff:ff, ipv6 permit ip 2001:db8::1/128  mac 00:01:02:03:04:05 mask 00:00:00:00:00:00
vl_api_macip_acl_add_reply_t_handler:107: ACL index: 7
vat#

macip_acl_del : delete a MACIP ACL

Delete the MACIP ACL by its index

vat# macip_acl_del 6
vat#

macip_acl_dump

Dump the MACIP ACLs (or just one if you supply its index)

vat# macip_acl_dump
vl_api_macip_acl_details_t_handler:226: MACIP acl_index: 0, count: 0
   tag {}
vl_api_macip_acl_details_t_handler:226: MACIP acl_index: 1, count: 1
   tag {}
   ipv6 action 1 ip ::/0 mac 00:00:00:00:00:00 mask 00:00:00:00:00:00
vl_api_macip_acl_details_t_handler:226: MACIP acl_index: 2, count: 1
   tag {}
   ipv6 action 1 ip ::/0 mac 00:00:00:00:00:00 mask 00:00:00:00:00:00
vl_api_macip_acl_details_t_handler:226: MACIP acl_index: 3, count: 1
   tag {}
   ipv6 action 1 ip ::/0 mac 00:00:00:00:00:00 mask 00:00:00:00:00:00
vl_api_macip_acl_details_t_handler:226: MACIP acl_index: 4, count: 1
   tag {}
   ipv4 action 1 ip 1.1.1.1/32 mac 00:01:02:03:04:05 mask ff:ff:ff:ff:ff:ff
vl_api_macip_acl_details_t_handler:226: MACIP acl_index: 5, count: 1
   tag {}
   ipv4 action 1 ip 1.1.1.1/32 mac 00:01:02:03:04:05 mask 00:00:00:00:00:00
vl_api_macip_acl_details_t_handler:226: MACIP acl_index: 7, count: 2
   tag {}
   ipv4 action 1 ip 1.1.1.1/32 mac 00:01:02:03:04:05 mask ff:ff:ff:ff:ff:ff,
   ipv6 action 1 ip 2001:db8::1/128 mac 00:01:02:03:04:05 mask 00:00:00:00:00:00
vat#

macip_acl_interface_add_del: apply/unapply the MACIP ACL to/from a given interface

macip_acl_interface_add_del <intfc> | sw_if_index <if-idx> [add|del] acl <acl-idx>
vat# macip_acl_interface_add_del local0 add acl 7
vat#

macip_acl_interface_get: get the list of interfaces and associated MACIP ACLs

vat# macip_acl_interface_add_del local0 add acl 7
vat# macip_acl_interface_get
vl_api_macip_acl_interface_get_reply_t_handler:241: sw_if_index with MACIP ACL count: 1
  macip_acl_interface_add_del sw_if_index 0 add acl 7
  
vat# macip_acl_interface_add_del local0 del acl 7
vat# macip_acl_interface_get
vl_api_macip_acl_interface_get_reply_t_handler:241: sw_if_index with MACIP ACL count: 1
  macip_acl_interface_add_del sw_if_index 0 add acl -1
  
vat#

Initial performance tests

The first version of the ACL plugin was explicitly focused on getting things "correct" as the first priority, even if at some expense of getting them "fast". But understanding the performance is very important, so we did limited performance testing. The performance testing was done using MoonGen, running on the same host as VPP. The VPP was run by doing "make release-build; make release-plugins; make release-run" process. The VPP is configured via VAT.

The performance was done by testing with 200000 unidirectional UDP streams, by submitting the line-rate 10Gbps of traffic by MoonGen (14.88Mpps of 64-byte packets) and observing the amount of traffic received on the other side.

First, we test the baseline configuration which just doing briding between the two interfaces.

 sw_interface_set_flags TenGigabitEthernet81/0/0 admin-up link-up
 sw_interface_set_flags TenGigabitEthernet81/0/1 admin-up link-up
 bridge_domain_add_del bd_id 42 flood 1 uu-flood 1 forward 1 learn 1 arp-term 0
 sw_interface_set_l2_bridge TenGigabitEthernet81/0/0 bd_id 42
 sw_interface_set_l2_bridge TenGigabitEthernet81/0/1 bd_id 42


This configuration exhibited 9.52 Mpps performance.

Then we added a trivial case of a one-line "permit" ACL which is checked on input and output of the packet path, using the following VAT commands:

 acl_add_replace permit
 acl_interface_add_del sw_if_index 1 add input acl 0
 acl_interface_add_del sw_if_index 1 add output acl 0
 acl_interface_add_del sw_if_index 2 add input acl 0
 acl_interface_add_del sw_if_index 2 add output acl 0

This configuration causes two very simple ACL checks - on input of the packet path and on the output, see the below trace(NB: this is a trace from 1701, the trace from 1704 looks different, though the logic is very similar. See the sample traces above):

 00:02:12:167665: dpdk-input
   TenGigabitEthernet81/0/0 rx queue 0
   buffer 0x5358: current data 0, length 60, free-list 0, totlen-nifb 0, trace 0x0
   PKT MBUF: port 0, nb_segs 1, pkt_len 60
     buf_len 2176, data_len 60, ol_flags 0x180, data_off 128, phys_addr 0x6ee4d640
     packet_type 0x0
     Packet Offload Flags
   IP4: 01:02:03:04:05:06 -> 07:08:09:0a:0b:0c
   UDP: 10.0.80.47 -> 10.1.0.10
     tos 0x00, ttl 64, length 46, checksum 0x1686
     fragment id 0x0000
   UDP: 1234 -> 319
     length 26, checksum 0x956f
 00:02:12:167682: ethernet-input
   IP4: 01:02:03:04:05:06 -> 07:08:09:0a:0b:0c
 00:02:12:167691: l2-input
   l2-input: sw_if_index 1 dst 07:08:09:0a:0b:0c src 01:02:03:04:05:06
 00:02:12:167693: l2-input-classify
   l2-classify: sw_if_index 1, table 0, offset 0, next 9
 00:02:12:167700: acl-plugin-in
   ACL_IN: sw_if_index 1, next index 10, match: inacl 0 rule 0 trace_bits 00000000
 00:02:12:167709: l2-learn
   l2-learn: sw_if_index 1 dst 07:08:09:0a:0b:0c src 01:02:03:04:05:06 bd_index 1
 00:02:12:167712: l2-flood
   l2-flood: sw_if_index 1 dst 07:08:09:0a:0b:0c src 01:02:03:04:05:06 bd_index 1
 00:02:12:167714: l2-output
   l2-output: sw_if_index 2 dst 07:08:09:0a:0b:0c src 01:02:03:04:05:06
 00:02:12:167716: l2-output-classify
   l2-classify: sw_if_index 2, table 6, offset 0, next 5
 00:02:12:167723: acl-plugin-out
   ACL_OUT: sw_if_index 2, next index 4, match: outacl 0 rule 0 trace_bits 00000000
 00:02:12:167734: TenGigabitEthernet81/0/1-output
   TenGigabitEthernet81/0/1
   IP4: 01:02:03:04:05:06 -> 07:08:09:0a:0b:0c
   UDP: 10.0.80.47 -> 10.1.0.10
     tos 0x00, ttl 64, length 46, checksum 0x1686
     fragment id 0x0000
   UDP: 1234 -> 319
     length 26, checksum 0x956f
 00:02:12:167736: TenGigabitEthernet81/0/1-tx
   TenGigabitEthernet81/0/1 tx queue 0
   buffer 0x5358: current data 0, length 60, free-list 0, totlen-nifb 0, trace 0x0
   IP4: 01:02:03:04:05:06 -> 07:08:09:0a:0b:0c
   UDP: 10.0.80.47 -> 10.1.0.10
     tos 0x00, ttl 64, length 46, checksum 0x1686
     fragment id 0x0000
   UDP: 1234 -> 319
     length 26, checksum 0x956f

This configuration exhibited the performance of 4.62 Mpps.

To test the impact of the linear match, we add lines to ACL one by one:

 acl_add_replace 0 permit src 1.1.1.1/32,permit

performance: 4.50Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32,permit

performance: 4.34 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32,permit

performance: 4.19 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, permit

performance: 4.04 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, permit

performance: 3.90 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, permit

performance: 3.77 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32,  permit

performance: 3.64 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32, src 1.1.1.8/32, permit

performance: 3.55 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32, src 1.1.1.8/32, src 1.1.1.9/32, permit

performance: 3.23 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32, src 1.1.1.8/32, src 1.1.1.9/32, src 1.1.1.10/32, permit

performance: 3.33 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32, src 1.1.1.8/32, src 1.1.1.9/32, src 1.1.1.10/32, src 1.1.1.11/32, permit

performance: 3.24 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32, src 1.1.1.8/32, src 1.1.1.9/32, src 1.1.1.10/32, src 1.1.1.11/32, src 1.1.1.12/32, permit

performance: 3.14 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32, src 1.1.1.8/32, src 1.1.1.9/32, src 1.1.1.10/32, src 1.1.1.11/32, src 1.1.1.12/32, src 1.1.1.13/32, permit

performance: 3.06 Mpps

 acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32, src 1.1.1.8/32, src 1.1.1.9/32, src 1.1.1.10/32, src 1.1.1.11/32, src 1.1.1.12/32, src 1.1.1.13/32, src

1.1.1.14/32, permit

performance: 2.85 Mpps


We can see that the performance impact is not strictly linear, but it gives the impression.

Changing the last match to "permit and reflect" in order to cause the stateful processing path:

acl_add_replace 0 permit src 1.1.1.1/32,src 1.1.1.2/32, src 1.1.1.3/32, src 1.1.1.4/32, src 1.1.1.5/32, src 1.1.1.6/32, src 1.1.1.7/32, src 1.1.1.8/32, src 1.1.1.9/32, src 1.1.1.10/32, src 1.1.1.11/32, src 1.1.1.12/32, src 1.1.1.13/32, src 1.1.1.14/32, permit+reflect

performance: 3.68 Mpps

We can see that the performance of the stateful path is less than the performance of the stateless path with small ACLs - this is most probably due to the current code organization of session tracker nodes, which use some code sharing between the nodes to ease the maintenance of it.


Removing all ACLs:

 acl_interface_add_del sw_if_index 1 del input acl 0
 acl_interface_add_del sw_if_index 1 del output acl 0
 acl_interface_add_del sw_if_index 2 del input acl 0
 acl_interface_add_del sw_if_index 2 del output acl 0

We get to 9.47 Mpps.

Let's test multiple ACL matching:

 acl_add_replace src 1.1.1.1/32
 acl_add_replace src 1.1.1.1/32
 acl_add_replace src 1.1.1.1/32
 acl_add_replace src 1.1.1.1/32
 acl_add_replace src 1.1.1.1/32

First same condition as before, with just one ACL check:

 acl_interface_set_acl_list sw_if_index 1 input 0 output 0
 acl_interface_set_acl_list sw_if_index 2 input 0 output 0


performance: 4.67 Mpps

Two ACLs:

 acl_interface_set_acl_list sw_if_index 1 input 1 0 output 1 0
 acl_interface_set_acl_list sw_if_index 2 input 1 0 output 1 0

performance: 4.16 Mpps

Three ACLs:

 acl_interface_set_acl_list sw_if_index 1 input 2 1 0 output 2 1 0
 acl_interface_set_acl_list sw_if_index 2 input 2 1 0 output 2 1 0

performance: 3.73 Mpps

Four ACLs:

 acl_interface_set_acl_list sw_if_index 1 input 3 2 1 0 output 3 2 1 0
 acl_interface_set_acl_list sw_if_index 2 input 3 2 1 0 output 3 2 1 0

performance: 3.38 Mpps

Five ACLs:

 acl_interface_set_acl_list sw_if_index 1 input 4 3 2 1 0 output 4 3 2 1 0
 acl_interface_set_acl_list sw_if_index 2 input 4 3 2 1 0 output 4 3 2 1 0

Performance: 3.10 Mpps

Six ACLs:

 acl_interface_set_acl_list sw_if_index 1 input 5 4 3 2 1 0 output 5 4 3 2 1 0
 acl_interface_set_acl_list sw_if_index 2 input 5 4 3 2 1 0 output 5 4 3 2 1 0

Performance: 2.85 Mpps

Convert to last "permit" to stateful:

 acl_add_replace 0 permit+reflect

Performance: 3.67 Mpps

These two performance axis might combine 0 i.e. if the ACL 5 in the above test were to be long and not match, the performance will be worse than just with that ACL and worse than with 6 trivial ACLs.

Removing all ACLs:

 acl_interface_set_acl_list sw_if_index 1 
 acl_interface_set_acl_list sw_if_index 2 

The performance is 9.45 Mpps.


MACIP ACLs


 macip_acl_add permit
 macip_acl_interface_add_del sw_if_index 1 add acl 0

Performance: 7.30 Mpps

 macip_acl_add permit ip 128.1.0.0/7, permit ip 10.0.0.0/8
 macip_acl_interface_add_del sw_if_index 1 add acl 1

Performance: 7.31 Mpps (the hit on the first classify table)

 macip_acl_add permit ip 128.1.0.0/9, permit ip 10.0.0.0/8
 macip_acl_interface_add_del sw_if_index 1 add acl 1

Performance: 7.31 Mpps (the hit on the first classify table)

(more testing with MACIP ACLs should be done)

Requirements

  • Support classifiers/filters on any interface type (bridged / routed)
  • Filter on IP-addresses with address mask or prefix length (IPv4 and IPv6)
  • Filter on source and destination TCP/UDP port ranges
  • Filter on source and destination L2 MAC addresses
  • Support IPv6 with extension headers present
  • Support fragmented packets and unknown transport layer headers
  • Combinations of the above filters (e.g. MAC + IP)
  • Filters on ingress and egress interfaces
  • Stateful firewall. No application layer filtering.

Work list

Task Owner Priority Status Description
API definition Ole 0 Done VPP-513
Connection tracker Andrew 0 Done VPP-514
Stateful ACLs 0 VPP-515
ACL policy matching node (MVP) Andrew 0 Done input output
Direct classifier policy matching -
Control Plane test code (new framework) Pavel 0 WIP
Data Plane tests (performance + scale) 0


 1. Python tests/examples -> Ole + Pavel
 2a. IPv4 matching in all plugin -> Andrew - done.
 2b. make it “deny by default” -> Andrew - done.
 2c. port range support -> Andrew - done.
 2d. ICMP type/code matching -> Andrew - done.
 3. Performance testing -> Andrew - done.
 --- MVP ---
 4a. Plumbing for stateful sessions from ACL plugin (to be able to specify “match and track” (“permit and create the forward/return session”) -> Andrew - done.
 4b. Stateful session tracking - timeouts -> Andrew - Done.
 4c. Stateful session tracking - lightweight TCP state -> Andrew - Done
 5. MACIP(L2) rules -> Andrew - done.
 6. Code cleanups -> Andrew

 
 PHASE2:
 A. ACL/Sessions support for L3 (routed) mode - (big) !
 B. Can we implement the ACL match purely in terms of classifier tables ? How expensive/(in)efficient that would be ?
 C. Extension header handling during the slow path lookup - easy in ACL plugin
 D. classifier match for the sessions with extension headers - currently no extension headers supported

API

API file as implemented in 17.01

MACIP (formerly "L2") API

MACIP (renamed to avoid confusion) is an ingress-only ACL which permits the traffic based on a mix of MAC and IP address matches.

The use of this mechanism is to prevent spoofing.

API file as implemented

API as implemented supports MAC address masks and prefixes, however, be aware: the current implementation is done using chained classifier tables, so each variation of the masks/prefix lengths means an extra table and hence the performance impact.

These filters are per-packet so you will want to care for performance.

For best performance, use the exact match MAC mask (ff:ff:ff:ff:ff:ff) and the maximum prefix length (/32 for IPv4 and /128 for IPv6).

Design and prototyping

The ACL matching is implemented in this phase as a simple array search, under the assumption that given the rules are per-port, the rule list will be small.

The redirection of the traffic to the node performing the ACL match is done by installing an empty L2 classifier table whose "miss-next" index diverts the traffic to the node.

The ACL match node can also redirect the traffic to the stateful-session setup node (by having a "permit" = 2 in the ACE), which will create the session on that interface.

...TBD: more details...

Examples

YANG model

Open Issues

Closed Issues

  • Security Group use case specific API. Done in a plugin.

Existing functionality

The existing functionality has a classifier (https://wiki.fd.io/view/VPP/Introduction_To_N-tuple_Classifiers) matching.

As the above document explains, the classifier is a series of chained tables, with each table having a specific mask, but this mask is the same for all entries.

This has been tested to happen in the L2 bridged case (test case: http://stdio.be/vpp/t/aytest-bridge-tap-py.txt).

Therefore, if we have an example policy:

 nova secgroup-create test-secgroup test
 nova secgroup-add-rule test-secgroup icmp -1 -1 0.0.0.0/0
 nova secgroup-add-rule test-secgroup tcp 22 22 0.0.0.0/0

So, assuming we match with offset 0 (from the beginning of the packet) the mask will look like this for the first line:

 000000000000 000000000000 0000 00 00 0000 0000 0000 00 FF 0000 00000000 00000000  00 00 0000 0000 
   eth dst      eth src    et   ihl t  len id    fo ttl pr  cs   ip4src   ip4dst    t  c  cs   id
   +-------- L2 ---------------+----------- L3 IPv4 ------------------------------+--------L4 ICMP -----+

For the TCP matching on port 22 it will look as follows:

 000000000000 000000000000 0000 00 00 0000 0000 0000 00 FF 0000 00000000 00000000  0000 FFFF 00000000 00000000 0000 0000 0000 0000
   eth dst      eth src    et   ihl t  len id    fo ttl pr  cs   ip4src   ip4dst    sp  dp    seq      ack      fl  win   cs   urg
   +-------- L2 ---------------+----------- L3 IPv4 ------------------------------+--------L4 TCP ---------------------------------+


(One would need to round up the number of bytes to the nearest 16-byte boundary that makes sense)

For IPv6 assuming no extension headers, it will look similar, with the L3 header being the IPv6 one:


 000000000000 000000000000 0000 0 00 00000 0000 FF 00 00000000000000000000000000000000 00000000000000000000000000000000 00 00 0000 0000 
   eth dst      eth src    et   v TC  fll  len  nh hl             ipv6 src                   ipv dst                    t  c  cs   id
   +-------- L2 ---------------+----------- L3 IPv6 --------------------------------------------------------------------+--------L4 ICMP -----+

For the TCP matching on port 22 it will look as follows:

 000000000000 000000000000 0000 0 00 00000 0000 FF 00 00000000000000000000000000000000 00000000000000000000000000000000 0000 FFFF 00000000 00000000 0000 0000 0000 0000
   eth dst      eth src    et   v TC  fll  len  nh hl             ipv6 src                   ipv dst                      sp  dp    seq      ack      fl  win   cs   urg
   +-------- L2 ---------------+----------- L3 IPv6 --------------------------------------------------------------------+--------L4 TCP ---------------------------------


Then using these masks one would create 4 tables, by using the API call:

 classify_add_del_table(is_add=1, skip_n_vectors=0, mask=<MMMM>, match_n_vectors=<NNNN>,nbuckets=32,memory_size=20000, next_table_index=-1, miss_next_index=-1)

Let's call these tables "IPv4PROTO", "IPv4PROTO_TCPDPORT", "IPv6PROTO", "IPv6PROTO_TCPDPORT".

One would mention "IPv4PROTO" table as "next_table_index" table for "IPv4PROTO_TCPDPORT", and "IPv6PROTO" as "next_table_index" table for IPv6PROTO_TCPDPORT table.

Then one needs to populate the tables with the correct matches for "ICMP" and "tcp dst port 22". That can be done using API call:

 classify_add_del_session(is_add=1, table_index=<XXXX>, match=<bytes-to-match>, hit-next-index -1)

The bytes "XXXX" above would be the match of one or several vectors, corresponding to the packet contents with the desired value.

WARNING: if the "skip" is nonzero in the table configuration, the match is still the entire bitstring, without skipping any leading bytes !!!

Then one would apply the IPv4PROTO_TCPDPORT and IPv6PROTO_TCPDPORT as l2 input classify tables.

The CLI for that is set interface l2 output classify intfc <name> ip[46]-table <tableid>.

The API for this is

  classify_set_interface_l2_tables(sw_if_index=<INTFC>, ip4_table_index=<IPv4PROTO_TCPDPORT>, ip6_table_index=<IPv6PROTO_TCPDPORT>, other_table_index=-1, is_input=0)


This would allow to create a unidirectional policy, assuming the other policy is "permit all" it would be fine. If not - then a mirror table entries will need to be created using the same logic.

The full script showing this process in detail using the python API is at http://stdio.be/vpp/t/classifier_script_simple_policy.txt

The Java API is located in $ROOT/vpp-api/java..

References