FD.io VPP  v18.07.1-19-g511ce25
Vector Packet Processing
VPP Inband OAM (iOAM)

In-band OAM (iOAM) is an implementation study to record operational information in the packet while the packet traverses a path between two points in the network.

Overview of iOAM can be found in iOAM-Devnet page. The following IETF drafts detail the motivation and mechanism for recording operational information:

Terminology

In-band OAM is expected to be deployed in a specific domain rather than on the overall Internet. The part of the network which employs in-band OAM is referred to as **"in-band OAM-domain"**.

In-band OAM data is added to a packet on entering the in-band OAM-domain and is removed from the packet when exiting the domain. Within the in-band OAM-domain, network nodes that the packet traverses may update the in-band OAM data records.

  • The node which adds in-band OAM data to the packet is called the **"in-band OAM encapsulating node"**.
  • The node which removes the in-band OAM data is referred to as the **"in-band OAM decapsulating node"**.
  • Nodes within the domain which are aware of in-band OAM data and read and/or write or process the in-band OAM data are called **"in-band OAM transit nodes"**.

Features supported in the current release

VPP can function as in-band OAM encapsulating, transit and decapsulating node. In this version of VPP in-band OAM data is transported as options in an IPv6 hop-by-hop extension header. Hence in-band OAM can be enabled for IPv6 traffic.

The following iOAM features are supported:

  • In-band OAM Tracing : In-band OAM supports multiple data records to be recorded in the packet as the packet traverses the network. These data records offer insights into the operational behavior of the network. The following information can be collected in the tracing data from the nodes a packet traverses:
    • Node ID
    • Ingress interface ID
    • Egress interface ID
    • Timestamp
    • Pre-configured application data
  • In-band OAM Proof of Transit (POT): Proof of transit iOAM data is added to every packet for verifying that a packet traverses a specific set of nodes. In-band OAM data is updated at every node that is enabled with iOAM proof of transit and is used to verify whether a packet traversed all the specified nodes. When the verifier receives each packet, it can validate whether the packet traversed the specified nodes.

Configuration

Configuring iOAM involves:

  • Selecting the packets for which iOAM data must be inserted, updated or removed
    • Selection of packets for iOAM data insertion on iOAM encapsulating node. Selection of packets is done by 5-tuple based classification
    • Selection of packets for updating iOAM data is implicitly done on the presence of iOAM options in the packet
    • Selection of packets for removing the iOAM data is done on 5-tuple based classification
  • The kind of data to be collected
    • Tracing data
    • Proof of transit
  • Additional details for processing iOAM data to be collected
    • For trace data - trace type, number of nodes to be recorded in the trace, time stamp precision, etc.
    • For POT data - configuration of POT profile required to process the POT data

The CLI for configuring iOAM is explained here followed by detailed steps and examples to deploy iOAM on VPP as an encapsulating, transit or decapsulating iOAM node in the subsequent sub-sections.

VPP iOAM configuration for enabling trace and POT is as follows:

set ioam rewrite trace-type <0x1f|0x7|0x9|0x11|0x19>
trace-elts <number of trace elements> trace-tsp <0|1|2|3>
node-id <node ID in hex> app-data <application data in hex> [pot]

A description of each of the options of the CLI follows:

  • trace-type : An entry in the "Node data List" array of the trace option can have different formats, following the needs of the a deployment. For example: Some deployments might only be interested in recording the node identifiers, whereas others might be interested in recording node identifier and timestamp. The following types are currently supported:
    • 0x1f : Node data to include hop limit (8 bits), node ID (24 bits), ingress and egress interface IDs (16 bits each), timestamp (32 bits), application data (32 bits)
    • 0x7 : Node data to include hop limit (8 bits), node ID (24 bits), ingress and egress interface IDs (16 bits each)
    • 0x9 : Node data to include hop limit (8 bits), node ID (24 bits), timestamp (32 bits)
    • 0x11: Node data to include hop limit (8 bits), node ID (24 bits), application data (32 bits)
    • 0x19: Node data to include hop limit (8 bits), node ID (24 bits), timestamp (32 bits), application data (32 bits)
  • trace-elts : Defines the length of the node data array in the trace option.
  • trace-tsp : Defines the timestamp precision to use with the enumerated value for precision as follows:
    • 0 : 32bits timestamp in seconds
    • 1 : 32bits timestamp in milliseconds
    • 2 : 32bits timestamp in microseconds
    • 3 : 32bits timestamp in nanoseconds
  • node-id : Unique identifier for the node, included in the node ID field of the node data in trace option.
  • app-data : The value configured here is included as is in application data field of node data in trace option.
  • pot : Enables POT option to be included in the iOAM options.

Trace configuration

On in-band OAM encapsulating node

  • Configure classifier and apply ACL to select packets for iOAM data insertion

    • Example to enable iOAM data insertion for all the packets towards IPv6 address db06::06:

    vpp# classify table miss-next node ip6-lookup mask l3 ip6 dst

    vpp# classify session acl-hit-next node ip6-add-hop-by-hop table-index 0 match l3 ip6 dst db06::06

    vpp# set int input acl intfc GigabitEthernet0/0/0 ip6-table 0

  • Enable tracing : Specify node ID, maximum number of nodes for which trace data should be recorded, type of data to be included for recording, optionally application data to be included
    • Example to enable tracing with a maximum of 4 nodes recorded and the data to be recorded to include - hop limit, node id, ingress and egress interface IDs, timestamp (millisecond precision), application data (0x1234):
vpp# set ioam rewrite trace-type 0x1f trace-elts 4 trace-tsp 1
node-id 0x1 app-data 0x1234

On in-band OAM transit node

  • The transit node requires trace type, timestamp precision, node ID and optionally application data to be configured, to update its node data in the trace option.

Example:

vpp# set ioam rewrite trace-type 0x1f trace-elts 4 trace-tsp 1  
node-id 0x2 app-data 0x1234  

On the In-band OAM decapsulating node

  • The decapsulating node similar to encapsulating node requires classification of the packets to remove iOAM data from.
    • Example to decapsulate iOAM data for packets towards db06::06, configure classifier and enable it as an ACL as follows:
vpp# classify table miss-next node ip6-lookup mask l3 ip6 dst

vpp# classify session acl-hit-next node ip6-lookup table-index 0
match l3 ip6 dst db06::06 opaque-index 100

vpp# set int input acl intfc GigabitEthernet0/0/0 ip6-table 0
  • Decapsulating node requires trace type, timestamp precision, node ID and optionally application data to be configured, to update its node data in the trace option before it is decapsulated.

Example:

vpp# set ioam rewrite trace-type 0x1f trace-elts 4  
trace-tsp 1 node-id 0x3 app-data 0x1234  

Proof of Transit configuration

For details on proof-of-transit, see the IETF draft iOAM-ietf-proof-of-transit. To enable Proof of Transit all the nodes that participate and hence are verified for transit need a proof of transit profile. A script to generate a proof of transit profile as per the mechanism described in iOAM-ietf-proof-of-transit will be available at iOAM-Devnet.

The Proof of transit mechanism implemented here is based on Shamir's Secret Sharing algorithm. The overall algorithm uses two polynomials POLY-1 and POLY-2. The degree of polynomials depends on number of nodes to be verified for transit. POLY-1 is secret and constant. Each node gets a point on POLY-1 at setup-time and keeps it secret. POLY-2 is public, random and per packet. Each node is assigned a point on POLY-1 and POLY-2 with the same x index. Each node derives its point on POLY-2 each time a packet arrives at it. A node then contributes its points on POLY-1 and POLY-2 to construct POLY-3 (POLY-3 = POLY-1 + POLY-2) using lagrange extrapolation and forwards it towards the verifier by updating POT data in the packet. The verifier constructs POLY-3 from the accumulated value from all the nodes and its own points on POLY-1 and POLY-2 and verifies whether POLY-3 = POLY-1 + POLY-2. Only the verifier knows POLY-1. The solution leverages finite field arithmetic in a field of size "prime number" for reasons explained in description of Shamir's secret sharing algorithm.

Here is an explanation of POT profile list and profile configuration CLI to realize the above mechanism. It is best to use the script provided at iOAM-Devnet to generate this configuration.

  • Create POT profile : set pot profile name <string> id [0-1] [validator-key 0xu64] prime-number 0xu64 secret_share 0xu64 lpc 0xu64 polynomial2 0xu64 bits-in-random [0-64]
    • name : Profile list name.
    • id : Profile id, it can be 0 or 1. A maximum of two profiles can be configured per profile list.
    • validator-key : Secret key configured only on the verifier/decapsulating node used to compare and verify proof of transit.
    • prime-number : Prime number for finite field arithmetic as required by the proof of transit mechanism.
    • secret_share : Unique point for each node on the secret polynomial POLY-1.
    • lpc : Lagrange Polynomial Constant(LPC) calculated per node based on its point (x value used for evaluating the points on the polynomial) on the polynomial used in lagrange extrapolation for reconstructing polynomial (POLY-3).
    • polynomial2 : Is the pre-evaluated value of the point on 2nd polynomial(POLY-2). This is unique for each node. It is pre-evaluated for all the coefficients of POLY-2 except for the constant part of the polynomial that changes per packet and is received as part of the POT data in the packet.
    • bits-in-random : To control the size of the random number to be generated. This number has to match the other numbers generated and used in the profile as per the algorithm.
  • Set a configured profile as active/in-use : set pot profile-active name <string> ID [0-1]
    • name : Name of the profile list to be used for computing POT data per packet.
    • ID : Identifier of the profile within the list to be used.

On In-band OAM encapsulating node

  • Configure the classifier and apply ACL to select packets for iOAM data insertion.
    • Example to enable iOAM data insertion for all the packet towards IPv6 address db06::06 -
vpp# classify table miss-next node ip6-lookup mask l3 ip6 dst

vpp# classify session acl-hit-next node
ip6-add-hop-by-hop table-index 0 match l3 ip6 dst db06::06

vpp# set int input acl intfc GigabitEthernet0/0/0 ip6-table 0
  • Configure the proof of transit profile list with profiles. Each profile list referred to by a name can contain 2 profiles, only one is in use for updating proof of transit data at any time.
    • Example profile list example with a profile generated from the script to verify transit through 3 nodes is:
vpp# set pot profile name example id 0 prime-number 0x7fff0000fa884685
secret_share 0x6c22eff0f45ec56d lpc 0x7fff0000fa884682
polynomial2 0xffb543d4a9c bits-in-random 63
  • Enable one of the profiles from the configured profile list as active so that is will be used for calculating proof of transit

Example enable profile ID 0 from profile list example configured above:

vpp# set pot profile-active name example ID 0
  • Enable POT option to be inserted
vpp# set ioam rewrite pot

On in-band OAM transit node

  • Configure the proof of transit profile list with profiles for transit node. Example:
vpp# set pot profile name example id 0 prime-number 0x7fff0000fa884685
secret_share 0x564cdbdec4eb625d lpc 0x1
polynomial2 0x23f3a227186a bits-in-random 63

On in-band OAM decapsulating node / verifier

  • The decapsulating node, similar to the encapsulating node requires classification of the packets to remove iOAM data from.
    • Example to decapsulate iOAM data for packets towards db06::06 configure classifier and enable it as an ACL as follows:
vpp# classify table miss-next node ip6-lookup mask l3 ip6 dst

vpp# classify session acl-hit-next node ip6-lookup table-index 0
match l3 ip6 dst db06::06 opaque-index 100

vpp# set int input acl intfc GigabitEthernet0/0/0 ip6-table 0
  • To update and verify the proof of transit, POT profile list should be configured.

    • Example POT profile list configured as follows:

    vpp# set pot profile name example id 0 validate-key 0x7fff0000fa88465d prime-number 0x7fff0000fa884685 secret_share 0x7a08fbfc5b93116d lpc 0x3 polynomial2 0x3ff738597ce bits-in-random 63

Operational data

Following CLIs are available to check iOAM operation:

  • To check iOAM configuration that are effective use "show ioam summary"

Example:

vpp# show ioam summary  
              REWRITE FLOW CONFIGS - Not configured  
 HOP BY HOP OPTIONS - TRACE CONFIG -  
                        Trace Type : 0x1f (31)  
         Trace timestamp precision : 1 (Milliseconds)  
                Num of trace nodes : 4  
                           Node-id : 0x2 (2)  
                          App Data : 0x1234 (4660)  
                        POT OPTION - 1 (Enabled)  
Try 'show ioam pot and show pot profile' for more information  
  • To find statistics about packets for which iOAM options were added (encapsulating node) and removed (decapsulating node) execute show errors

Example on encapsulating node:

vpp# show error
   Count                    Node                  Reason
1208804706                ip6-inacl               input ACL hits
1208804706           ip6-add-hop-by-hop           Pkts w/ added ip6 hop-by-hop options

Example on decapsulating node:

vpp# show error
   Count                    Node                  Reason
  69508569                ip6-inacl               input ACL hits
  69508569           ip6-pop-hop-by-hop           Pkts w/ removed ip6 hop-by-hop options
  • To check the POT profiles use "show pot profile"

Example:

vpp# show pot profile
Profile list in use  : example
POT Profile at index: 0
                 ID : 0
          Validator : False (0)
       Secret share : 0x564cdbdec4eb625d (6218586935324795485)
       Prime number : 0x7fff0000fa884685 (9223090566081300101)
2nd polynomial(eval) : 0x23f3a227186a (39529304496234)
                 LPC : 0x1 (1)
           Bit mask : 0x7fffffffffffffff (9223372036854775807)
Profile index in use: 0
Pkts passed : 0x36 (54)
  • To get statistics of POT for packets use "show ioam pot"

Example at encapsulating or transit node:

vpp# show ioam pot
 Pkts with ip6 hop-by-hop POT options - 54
 Pkts with ip6 hop-by-hop POT options but no profile set - 0
 Pkts with POT in Policy - 0
 Pkts with POT out of Policy - 0

Example at decapsulating/verification node:

vpp# show ioam pot
 Pkts with ip6 hop-by-hop POT options - 54
 Pkts with ip6 hop-by-hop POT options but no profile set - 0
 Pkts with POT in Policy - 54
 Pkts with POT out of Policy - 0
  • Tracing - enable trace of IPv6 packets to view the data inserted and collected.

Example when the nodes are receiving data over a DPDK interface: Enable tracing using "trace add dpdk-input 20" and execute "show trace" to view the iOAM data collected:

vpp# trace add dpdk-input 20  

vpp# show trace

------------------- Start of thread 0 vpp_main -------------------  

Packet 1  

00:00:19:294697: dpdk-input  
  GigabitEthernetb/0/0 rx queue 0  
  buffer 0x10e6b: current data 0, length 214, free-list 0, totlen-nifb 0, trace 0x0  
  PKT MBUF: port 0, nb_segs 1, pkt_len 214  
    buf_len 2176, data_len 214, ol_flags 0x0, data_off 128, phys_addr 0xe9a35a00  
    packet_type 0x0  
  IP6: 00:50:56:9c:df:72 -> 00:50:56:9c:be:55  
  IP6_HOP_BY_HOP_OPTIONS: db05::2 -> db06::6  
    tos 0x00, flow label 0x0, hop limit 63, payload length 160  
00:00:19:294737: ethernet-input  
  IP6: 00:50:56:9c:df:72 -> 00:50:56:9c:be:55  
00:00:19:294753: ip6-input  
  IP6_HOP_BY_HOP_OPTIONS: db05::2 -> db06::6  
    tos 0x00, flow label 0x0, hop limit 63, payload length 160  
00:00:19:294757: ip6-lookup  
  fib 0 adj-idx 15 : indirect via db05::2 flow hash: 0x00000000  
  IP6_HOP_BY_HOP_OPTIONS: db05::2 -> db06::6  
    tos 0x00, flow label 0x0, hop limit 63, payload length 160  
00:00:19:294802: ip6-hop-by-hop  
  IP6_HOP_BY_HOP: next index 5 len 96 traced 96  Trace Type 0x1f , 1 elts left  
    [0] ttl 0x0 node ID 0x0 ingress 0x0 egress 0x0 ts 0x0  
app 0x0  
    [1] ttl 0x3e node ID 0x3 ingress 0x1 egress 0x2 ts 0xb68c2213  
app 0x1234  
    [2] ttl 0x3f node ID 0x2 ingress 0x1 egress 0x2 ts 0xb68c2204  
app 0x1234  
    [3] ttl 0x40 node ID 0x1 ingress 0x5 egress 0x6 ts 0xb68c2200  
app 0x1234  
    POT opt present  
         random = 0x577a916946071950, Cumulative = 0x10b46e78a35a392d, Index = 0x0  
00:00:19:294810: ip6-rewrite  
  tx_sw_if_index 1 adj-idx 14 : GigabitEthernetb/0/0  
                                IP6: 00:50:56:9c:be:55 -> 00:50:56:9c:df:72 flow hash: 0x00000000  
  IP6: 00:50:56:9c:be:55 -> 00:50:56:9c:df:72  
  IP6_HOP_BY_HOP_OPTIONS: db05::2 -> db06::6  
    tos 0x00, flow label 0x0, hop limit 62, payload length 160  
00:00:19:294814: GigabitEthernetb/0/0-output  
  GigabitEthernetb/0/0  
  IP6: 00:50:56:9c:be:55 -> 00:50:56:9c:df:72  
  IP6_HOP_BY_HOP_OPTIONS: db05::2 -> db06::6  
    tos 0x00, flow label 0x0, hop limit 62, payload length 160  
00:00:19:294820: GigabitEthernetb/0/0-tx    
  GigabitEthernetb/0/0 tx queue 0    
  buffer 0x10e6b: current data 0, length 214, free-list 0, totlen-nifb 0, trace 0x0    
  IP6: 00:50:56:9c:be:55 -> 00:50:56:9c:df:72

  IP6_HOP_BY_HOP_OPTIONS: db05::2 -> db06::6

    tos 0x00, flow label 0x0, hop limit 62, payload length 160