Simple Two-way Active Measurement Protocol (STAMP) Data Model
ZTE Corp.
gregimirsky@gmail.com
ZTE Corp.
xiao.min2@zte.com.cn
Ericsson
wei.s.luo@ericsson.com
Transport
Network Working Group
Internet-Draft
IPPM
STAMP
YANG
This document specifies the data model for implementations of Sender and Reflector
for Simple Two-way Active Measurement Protocol (STAMP) mode using YANG.
The Simple Two-way Active Measurement Protocol (STAMP) can be used
to measure performance parameters of IP networks such as latency, jitter,
and packet loss by sending test packets and monitoring their
experience in the network. The STAMP protocol [Editor:ref to STAMP draft] in unauthenticated mode is on-wire compatible
with STAMP Light, mdiscussed in Appendix I . The STAMP Light is known to have many implementations
though no common management framework being defined, thus leaving some aspects of test packet
processing to interpretation. As one of goals of STAMP is to support these variations, this document presents their analysis;
describes common STAMP and STAMP model while allowing for STAMP extensions in the future. This document defines the STAMP data model
and specifies it formally using the YANG data modeling language .
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL
NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED",
"MAY", and "OPTIONAL" in this document are to be interpreted as
described in BCP 14
when, and only when, they appear in all capitals, as shown here.
The scope of this document includes model of the STAMP as defined in
[Editor:ref to STAMP draft].
| STAMP Reflector |
+-------------------+ +-------------------+
]]>
This section describes all the parameters of the the stamp data model.
The stamp-session-sender container holds items that are related
to the configuration of the stamp Session-Sender logical entity.
The stamp-session-sender-state container holds information about
the state of the particular STAMP test session.
RPCs stamp-sender-start and stamp-sender-stop respectively start and stop
the referenced by session-id STAMP test session.
The data model supports several scenarios for a STAMP Sender to execute test sessions and calculate
performance metrics:
The test mode in which the test packets are sent unbound in time at defined by
the parameter 'interval' in the stamp-session-sender container frequency is referred as continuous
mode. Performance metrics in the continuous mode are calculated at period defined by the
parameter 'measurement-interval'.
The test mode that has specific number of the test packets configured for the test session in the
'number-of-packets' parameter is referred as periodic mode. The test session may be repeated by the
STAMP-Sender with the same parameters. The 'repeat' parameter defines number of tests and the
'repeat-interval' - the interval between the consecuitive tests. The performance metrics are calculated
after each test session when the interval defined by the 'session-timeout' expires.
The stamp-session-reflector container holds
items that are related to the configuration of the STAMP
Session-Reflector logical entity.
The stamp-session-refl-state container holds Session-Reflector
state data for the particular STAMP test session.
Creating STAMP data model presents number of challenges and among them
is identification of a test-session at Session-Reflector. A Session-Reflector MAY require
only as little as its IP and UDP port number in received STAMP-Test packet to spawn new
test session. More so, to test processing of Class-of-Service along the same route in
Equal Cost Multi-Path environment Session-Sender may run STAMP test sessions
concurrently using the same source IP address, source UDP port number, destination
IP address, and destination UDP port number. Thus the only parameter that can be used to
differentiate these test sessions would be DSCP value. The DSCP field may get re-marked
along the path and without use of that will go undetected,
but by using five-tuple instead of four-tuple as a key we can ensure that STAMP test packets that
are considered as different test sessions follow the same path even in ECMP environments.
file "ietf-stamp@2018-01-05.yang"
module ietf-stamp {
namespace "urn:ietf:params:xml:ns:yang:ietf-stamp";
//namespace need to be assigned by IANA
prefix "ietf-stamp";
import ietf-inet-types {
prefix inet;
}
import ietf-yang-types {
prefix yang;
}
import ietf-key-chain {
prefix kc;
}
organization
"IETF IPPM (IP Performance Metrics) Working Group";
contact
"draft-ietf-ippm-stamp-yang@tools.ietf.org";
description "STAMP Data Model";
revision "2018-01-05" {
description
"00 version. Base STAMP specification is covered";
reference "";
}
feature session-sender {
description
"This feature relates to the device functions as the
STAMP Session-Sender";
}
feature session-reflector {
description
"This feature relates to the device functions as the
STAMP Session-Reflector";
}
feature stamp-authentication {
description
"STAMP authentication supported";
}
typedef enable {
type boolean;
description "enable";
}
typedef session-reflector-mode {
type enumeration {
enum stateful {
description
"When the Session-Reflector is stateful,
i.e. is aware of STAMP-Test session state.";
}
enum stateless {
description
"When the Session-Reflector is stateless,
i.e. is not aware of the state of
STAMP-Test session.";
}
}
description "State of the Session-Reflector";
}
typedef session-dscp-mode {
type enumeration {
enum copy-received-value {
description
"Use DSCP value copied from received
STAMP test packet of the test session.";
}
enum use-configured-value {
description
"Use DSCP value configured for this
test session on the Session-Reflector.";
}
}
description
"DSCP handling mode by Session-Reflector.";
}
typedef percentage {
type decimal64 {
fraction-digits 5;
}
description "Percentage";
}
typedef percentile {
type decimal64 {
fraction-digits 2;
}
description
"Percentile is a measure used in statistics
indicating the value below which a given
percentage of observations in a group of
observations fall.";
}
grouping maintenance-statistics {
description "Maintenance statistics grouping";
leaf sent-packets {
type uint32;
description "Packets sent";
}
leaf rcv-packets {
type uint32;
description "Packets received";
}
leaf sent-packets-error {
type uint32;
description "Packets sent error";
}
leaf rcv-packets-error {
type uint32;
description "Packets received error";
}
leaf last-sent-seq {
type uint32;
description "Last sent sequence number";
}
leaf last-rcv-seq {
type uint32;
description "Last received sequence number";
}
}
grouping stamp-session-percentile {
description "Percentile grouping";
leaf first-percentile {
type percentile;
default 95.00;
description
"First percentile to report";
}
leaf second-percentile {
type percentile;
default 99.00;
description
"Second percentile to report";
}
leaf third-percentile {
type percentile;
default 99.90;
description
"Third percentile to report";
}
}
grouping delay-statistics {
description "Delay statistics grouping";
container delay {
description "Packets transmitted delay";
leaf min {
type yang:gauge32;
units microseconds;
description
"Min of Packets transmitted delay";
}
leaf max {
type yang:gauge32;
units microseconds;
description
"Max of Packets transmitted delay";
}
leaf avg {
type yang:gauge32;
units microseconds;
description
"Avg of Packets transmitted delay";
}
}
container delay-variation {
description
"Packets transmitted delay variation";
leaf min {
type uint32;
units microseconds;
description
"Min of Packets transmitted
delay variation";
}
leaf max {
type uint32;
units microseconds;
description
"Max of Packets transmitted
delay variation";
}
leaf avg {
type uint32;
units microseconds;
description
"Avg of Packets transmitted
delay variation";
}
}
}
grouping time-percentile-report {
description "Delay percentile report grouping";
container delay-percentile {
description
"Report round-trip, near- and far-end delay";
leaf rtt-delay {
type percentile;
description
"Percentile of round-trip delay";
}
leaf near-end-delay {
type percentile;
description
"Percentile of near-end delay";
}
leaf far-end-delay {
type percentile;
description
"Percentile of far-end delay";
}
}
container delay-variation-percentile {
description
"Report round-trip, near- and far-end delay variation";
leaf rtt-delay-variation {
type percentile;
description
"Percentile of round-trip delay-variation";
}
leaf near-end-delay-variation {
type percentile;
description
"Percentile of near-end delay variation";
}
leaf far-end-delay-variation {
type percentile;
description
"Percentile of far-end delay-variation";
}
}
}
grouping packet-loss-statistics {
description
"Grouping for Packet Loss statistics";
leaf loss-count {
type int32;
description
"Number of lost packets
during the test interval.";
}
leaf loss-ratio {
type percentage;
description
"Ratio of packets lost to packets
sent during the test interval.";
}
leaf loss-burst-max {
type int32;
description
"Maximum number of consequtively
lost packets during the test interval.";
}
leaf loss-burst-min {
type int32;
description
"Minimum number of consequtively
lost packets during the test interval.";
}
leaf loss-burst-count {
type int32;
description
"Number of occasions with packet
loss during the test interval.";
}
}
grouping session-parameters {
description
"Parameters common among
Session-Sender and Session-Reflector";
leaf sender-ip {
type inet:ip-address;
mandatory true;
description "Sender IP address";
}
leaf sender-udp-port {
type inet:port-number {
range "49152..65535";
}
mandatory true;
description "Sender UDP port number";
}
leaf reflector-ip {
type inet:ip-address;
mandatory true;
description "Reflector IP address";
}
leaf reflector-udp-port {
type inet:port-number{
range "862 | 49152..65535";
}
default 862;
description "Reflector UDP port number";
}
}
grouping session-auth-params {
description
"Grouping for STAMP authentication parameters";
container authentication-params {
if-feature stamp-authentication;
presence "Enables STAMP authentication";
description
"Parameters for STAMP Light authentication";
leaf key-chain {
type kc:key-chain-ref;
description "Name of key-chain";
}
}
}
/* Configuration Data */
container stamp {
description
"Top level container for stamp configuration";
container stamp-session-sender {
if-feature session-sender;
description "stamp Session-Sender container";
leaf sender-enable {
type enable;
default "true";
description
"Whether this network element is enabled to
act as STAMP Sender";
}
list test-session {
key "session-id";
unique "sender-ip sender-udp-port reflector-ip"
+" reflector-udp-port dscp-value";
description
"This structure is a container of test session
managed objects";
leaf session-id {
type uint32;
description "Session ID";
}
leaf test-session-enable {
type enable;
default "true";
description
"Whether this STAMP Test session is enabled";
}
leaf number-of-packets {
type union {
type uint32 {
range 1..4294967294 {
description
"The overall number of UDP test packet
to be transmitted by the sender for this
test session";
}
}
type enumeration {
enum forever {
description
"Indicates that the test session SHALL
be run *forever*.";
}
}
}
default 10;
description
"This value determines if the STAMP-Test session is
bound by number of test packets or not.";
}
leaf packet-padding-size {
type uint32;
default 27;
description
"Size of the Packet Padding. Suggested to run
Path MTU Discovery to avoid packet fragmentation in
IPv4 and packet blackholing in IPv6";
}
leaf interval {
type uint32;
units microseconds;
description
"Time interval between transmission of two
consecutive packets in the test session in
microseconds";
}
leaf session-timeout {
when "../number-of-packets != 'forever'" {
description
"Test session timeout only valid if the
test mode is periodic.";
}
type uint32;
units "seconds";
default 900;
description
"The timeout value for the Session-Sender to
collect outstanding reflected packets.";
}
leaf measurement-interval {
when "../number-of-packets = 'forever'" {
description
"Valid only when the test to run forever,
i.e. continuously.";
}
type uint32;
units "seconds";
default 60;
description
"Interval to calculate performance metric when
the test mode is 'continuous'.";
}
leaf repeat {
type union {
type uint32 {
range 0..4294967294;
}
type enumeration {
enum forever {
description
"Indicates that the test session SHALL
be repeated *forever* using the
information in repeat-interval
parameter, and SHALL NOT decrement
the value.";
}
}
}
default 0;
description
"This value determines if the STAMP-Test session must
be repeated. When a test session has completed, the
repeat parameter is checked. The default value
of 0 indicates that the session MUST NOT be repeated.
If the repeat value is 1 through 4,294,967,294
then the test session SHALL be repeated using the
information in repeat-interval parameter.
The implementation MUST decrement the value of repeat
after determining a repeated session is expected.";
}
leaf repeat-interval {
when "../repeat != '0'";
type uint32;
units seconds;
default 0;
description
"This parameter determines the timing of repeated
STAMP-Test sessions when repeat is more than 0.";
}
leaf dscp-value {
type inet:dscp;
default 0;
description
"DSCP value to be set in the test packet.";
}
leaf test-session-reflector-mode {
type session-reflector-mode;
default "stateless";
description
"The mode of STAMP-Reflector for the test session.";
}
uses session-parameters;
uses session-auth-params;
uses stamp-session-percentile;
}
}
container stamp-session-reflector {
if-feature session-reflector;
description
"stamp Session-Reflector container";
leaf reflector-enable {
type enable;
default "true";
description
"Whether this network element is enabled to
act as stamp Reflector";
}
leaf ref-wait {
type uint32 {
range 1..604800;
}
units seconds;
default 900;
description
"REFWAIT(STAMP test session timeout in seconds),
the default value is 900";
}
leaf reflector-mode-state {
type session-reflector-mode;
default stateless;
description
"The state of the mode of the stamp
Session-Reflector";
}
list test-session {
key "session-id";
unique "sender-ip sender-udp-port reflector-ip"
+" reflector-udp-port";
description
"This structure is a container of test session
managed objects";
leaf session-id {
type uint32;
description "Session ID";
}
leaf dscp-handling-mode {
type session-dscp-mode;
default copy-received-value;
description
"Session-Reflector handling of DSCP:
- use value copied from received STAMP-Test packet;
- use value explicitly configured";
}
leaf dscp-value {
when "../dscp-handling-mode = 'use-configured-value'";
type inet:dscp;
default 0;
description
"DSCP value to be set in the reflected packet
if dscp-handling-mode is set to use-configured-value.";
}
uses session-parameters;
uses session-auth-params;
}
}
}
/* Operational state data nodes */
container stamp-state{
config "false";
description
"Top level container for stamp state data";
container stamp-session-sender-state {
if-feature session-sender;
description
"Session-Sender container for state data";
list test-session-state{
key "session-id";
description
"This structure is a container of test session
managed objects";
leaf session-id {
type uint32;
description "Session ID";
}
leaf sender-session-state {
type enumeration {
enum active {
description "Test session is active";
}
enum ready {
description "Test session is idle";
}
}
description
"State of the particular stamp test
session at the sender";
}
container current-stats {
description
"This container contains the results for the current
Measurement Interval in a Measurement session ";
leaf start-time {
type yang:date-and-time;
mandatory true;
description
"The time that the current Measurement Interval started";
}
leaf packet-padding-size {
type uint32;
default 27;
description
"Size of the Packet Padding. Suggested to run
Path MTU Discovery to avoid packet fragmentation
in IPv4 and packet backholing in IPv6";
}
leaf interval {
type uint32;
units microseconds;
description
"Time interval between transmission of two
consecutive packets in the test session";
}
leaf duplicate-packets {
type uint32;
description "Duplicate packets";
}
leaf reordered-packets {
type uint32;
description "Reordered packets";
}
uses session-parameters;
leaf dscp {
type inet:dscp;
description
"The DSCP value that was placed in the header of
STAMP UDP test packets by the Session-Sender.";
}
uses maintenance-statistics;
container two-way-delay {
description
"two way delay result of the test session";
uses delay-statistics;
}
container one-way-delay-far-end {
description
"one way delay far-end of the test session";
uses delay-statistics;
}
container one-way-delay-near-end {
description
"one way delay near-end of the test session";
uses delay-statistics;
}
container low-percentile {
when "/stamp/stamp-session-sender/"
+"test-session[session-id]/"
+"first-percentile != '0.00'" {
description
"Only valid if the
the first-percentile is not NULL";
}
description
"Low percentile report";
uses time-percentile-report;
}
container mid-percentile {
when "/stamp/stamp-session-sender/"
+"test-session[session-id]/"
+"second-percentile != '0.00'" {
description
"Only valid if the
the first-percentile is not NULL";
}
description
"Mid percentile report";
uses time-percentile-report;
}
container high-percentile {
when "/stamp/stamp-session-sender/"
+"test-session[session-id]/"
+"third-percentile != '0.00'" {
description
"Only valid if the
the first-percentile is not NULL";
}
description
"High percentile report";
uses time-percentile-report;
}
container two-way-loss {
description
"two way loss count and ratio result of
the test session";
uses packet-loss-statistics;
}
container one-way-loss-far-end {
when "/stamp/stamp-session-sender/"
+"test-session[session-id]/"
+"test-session-reflector-mode = 'stateful'" {
description
"One-way statistic is only valid if the
session-reflector is in stateful mode.";
}
description
"one way loss count and ratio far-end of
the test session";
uses packet-loss-statistics;
}
container one-way-loss-near-end {
when "/stamp/stamp-session-sender/"
+"test-session[session-id]/"
+"test-session-reflector-mode = 'stateful'" {
description
"One-way statistic is only valid if the
session-reflector is in stateful mode.";
}
description
"one way loss count and ratio near-end of
the test session";
uses packet-loss-statistics;
}
}
list history-stats {
key id;
description
"This container contains the results for the history
Measurement Interval in a Measurement session ";
leaf id {
type uint32;
description
"The identifier for the Measurement Interval
within this session";
}
leaf end-time {
type yang:date-and-time;
mandatory true;
description
"The time that the Measurement Interval ended";
}
leaf number-of-packets {
type uint32;
description
"The overall number of UDP test packets to be
transmitted by the sender for this test session";
}
leaf packet-padding-size {
type uint32;
default 27;
description
"Size of the Packet Padding. Suggested to run
Path MTU Discovery to avoid packet fragmentation
in IPv4 and packet blackholing in IPv6";
}
leaf interval {
type uint32;
units microseconds;
description
"Time interval between transmission of two
consecutive packets in the test session";
}
leaf duplicate-packets {
type uint32;
description "Duplicate packets";
}
leaf reordered-packets {
type uint32;
description "Reordered packets";
}
leaf loss-packets {
type uint32;
description "Loss packets";
}
uses session-parameters;
leaf dscp {
type inet:dscp;
description
"The DSCP value that was placed in the header of
STAMP UDP test packets by the Session-Sender.";
}
uses maintenance-statistics;
container two-way-delay{
description
"two way delay result of the test session";
uses delay-statistics;
}
container one-way-delay-far-end{
description
"one way delay far end of the test session";
uses delay-statistics;
}
container one-way-delay-near-end{
description
"one way delay near end of the test session";
uses delay-statistics;
}
}
}
}
container stamp-session-refl-state {
if-feature session-reflector;
description
"stamp Session-Reflector container for
state data";
leaf reflector-light-admin-status {
type boolean;
mandatory "true";
description
"Whether this network element is enabled to
act as stamp Reflector";
}
list test-session-state {
key "session-id";
description
"This structure is a container of test session
managed objects";
leaf session-id {
type uint32;
description "Session ID";
}
uses maintenance-statistics;
uses session-parameters;
}
}
}
rpc stamp-sender-start {
description
"start the configured sender session";
input {
leaf session-id {
type uint32;
mandatory true;
description
"The session to be started";
}
}
}
rpc stamp-sender-stop {
description
"stop the configured sender session";
input {
leaf session-id {
type uint32;
mandatory true;
description
"The session to be stopped";
}
}
}
}
]]>
This document registers a URI in the IETF XML registry .
Following the format in , the following registration is
requested to be made.
URI: urn:ietf:params:xml:ns:yang:ietf-stamp
Registrant Contact: The IPPM WG of the IETF.
XML: N/A, the requested URI is an XML namespace.
This document registers a YANG module in the YANG Module Names
registry .
name: ietf-stamp
namespace: urn:ietf:params:xml:ns:yang:ietf-stamp
prefix: stamp
reference: RFC XXXX
The configuration, state, action data defined in
this document may be accessed via the NETCONF protocol
. SSH is mandatory secure transport
that is the lowest NETCONF layer.
The NETCONF access control model provides means to restrict
access for particular NETCONF users to a pre-configured subset of all
available NETCONF protocol operations and content.
Authors recognize and appreciate valuable comments providen by Adrian Pan.