| Internet Engineering Task Force | W. Roome, Ed. |
| Internet-Draft | Bell Laboratories, Alcatel-Lucent |
| Intended status: Informational | June 4, 2015 |
| Expires: December 6, 2015 |
Interoperability testing of the ALTO Protocol
draft-roome-interop-ietf93-00
The Application-Layer Traffic Optimization (ALTO) protocol is designed to allow entities with knowledge about the network infrastructure to export such information to applications that need to choose one or more endpoints to connect to among large sets of logically equivalent ones. This document defines a data set that may be used to test the functionality and interoperability of ALTO clients and servers.
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The Application-Layer Traffic Optimization (ALTO) protocol is designed to allow entities with knowledge about the network infrastructure to export such information to applications that need to choose one or more endpoints to connect to among large sets of logically equivalent ones.
This document defines procedures to test the functionality and interoperability of ALTO clients and servers.
This document is informational and is NOT NORMATIVE on any aspects of the ALTO protocol. The normative behavior of ALTO entities is prescribed in [RFC7285].
Section 2 defines the network maps, cost maps and other data necessary to provision an ALTO server. This ensures that all tested servers will return the same results, so a client may verify that a server is operating correctly. Section 3 defines the required and optional resources for an ALTO server to provide. Section 4 describes the actions expected from a client. Section 5 describes a set of invalid client requests, to verify that a server can respond correctly to client errors.
While every effort has been made to catalogue representative test cases, this document does not attempt to codify every test case that arises in ALTO. The aim of the document is to focus on areas that highlight the key offerings of the ALTO protocol.
This section defines the data necessary to provision a tested ALTO server in a uniform manner. First it defines a default network map, and associated cost maps for the "routingcost" and "hopcount" metrics. Next it defines an optional alternate network map, along with "routingcost" and "hopcount" costs for that map. Finally it defines a set of optional endpoint properties.
Appendix A gives network and cost map data defined in this section formatted in JSON.
Every tested ALTO server MUST provide a default network map with the PIDs defined below:
PID IP Address Block
---------------------------------------
mine 100.0.0.0/8
mine1 100.0.0.0/10
mine1a 100.0.1.0/24, 100.0.64.0/24, 100.0.192.0/24
mine2 100.64.0.0/10
mine3 100.128.0.0/10
peer1 128.0.0.0/16, 130.0.0.0/16, 2001:DB8:0000::/33
peer2 129.0.0.0/16, 131.0.0.0/16, 2001:DB8:8000::/33
tran1 132.0.0.0/16
tran2 135.0.0.0/16
default 0.0.0.0/0, ::0/0
loopback 127.0.0.0/8, ::1/128
linklocal 169.254.0.0/16, ff80::/10
private 10.0.0.0/8, 172.16.0.0/12,
192.168.0.0/16, fc00::/7
Figure 1: Default Network Map
Each ALTO server MUST provide a cost map for the "routingcost" metric. The following table presents the numerical values for those costs. If a server provides a numerical-mode cost map, it MUST use these values. If a server provides an ordinal-mode cost map, the server may use whatever values it wants, provided the ordinal values preserve the order of the numerical values.
default mine mine1 mine1a mine2 mine3 peer1 peer2 tran1 tran2
default 1.0 75.0 75.0 75.0 75.0 75.0 - - - -
mine 75.0 1.0 15.0 15.0 15.0 15.0 30.0 30.0 50.0 50.0
mine1 75.0 15.0 1.0 2.5 5.0 7.0 20.0 25.0 40.0 45.0
mine1a 75.0 15.0 2.0 1.0 7.0 9.0 22.0 24.0 42.0 48.0
mine2 75.0 15.0 5.5 7.0 1.0 6.0 23.0 25.0 43.0 46.0
mine3 75.0 15.0 7.0 9.0 6.0 1.0 25.0 28.0 45.0 49.0
peer1 - 30.0 20.0 22.0 23.0 25.0 1.0 - - -
peer2 - 30.0 25.0 24.0 25.0 28.0 - 1.0 - -
tran1 - 50.0 40.0 42.0 43.0 45.0 - - 1.0 -
tran2 - 50.0 45.0 48.0 46.0 49.0 - - - 1.0
Figure 2: "routingcost" Numerical Cost Map
Note that this is a partial cost map, in that it does not define a cost for every source and destination PID.
Each ALTO server MAY provide a cost map for the "hopcount" metric. The following table gives the numerical values. As with "routingcost", a numerical-mode cost map MUST use these values, and an ordinal-mode cost map may use any values consistent with this ordering.
default mine mine1 mine1a mine2 mine3 peer1 peer2 tran1 tran2
default 1.0 10.0 10.0 10.0 10.0 10.0 - - - -
mine 10.0 1.0 3.0 3.0 3.0 3.0 5.0 6.0 8.0 8.0
mine1 10.0 3.0 1.0 2.0 2.0 2.0 4.0 5.0 6.0 7.0
mine1a 10.0 3.0 2.0 1.0 2.0 3.0 5.0 6.0 7.0 8.0
mine2 10.0 3.0 2.0 2.0 1.0 2.0 4.0 5.0 6.0 7.0
mine3 10.0 3.0 2.0 3.0 2.0 1.0 4.0 5.0 6.0 7.0
peer1 - 5.0 4.0 5.0 4.0 4.0 1.0 - - -
peer2 - 6.0 5.0 6.0 5.0 5.0 - 1.0 - -
tran1 - 8.0 6.0 7.0 6.0 6.0 - - 1.0 -
tran2 - 8.0 7.0 8.0 7.0 7.0 - - - 1.0
Figure 3: "hopcount" Numerical Cost Map
Every tested ALTO server MAY provide an alternate, or secondary, network map with the PIDs defined below:
PID IP Address Block
---------------------------------------
dc1 101.0.0.0/16
dc2 102.0.0.0/16
dc3 103.0.0.0/16
dc4 104.0.0.0/16
user1 201.0.0.0/16
user2 202.0.0.0/16
user3 203.0.0.0/16
user4 204.0.0.0/16
default 0.0.0.0/0, ::0/0
loopback 127.0.0.0/8, ::1/128
linklocal 169.254.0.0/16, ff80::/10
private 10.0.0.0/8, 172.16.0.0/12,
192.168.0.0/16, fc00::/7
Figure 4: Alternate Network Map
Each ALTO server MAY provide a cost map for the "routingcost" metric for the alternate network map. The following table presents the numerical values for those costs. If a server provides a numerical-mode cost map, it MUST use these values. If a server provides an ordinal-mode cost map, the server may use whatever values it wants, provided the ordinal values preserve the order of the numerical values.
dc1 dc2 dc3 dc4 default user1 user2 user3 user4
dc1 0.0 5.0 5.0 5.0 50.0 10.0 20.0 30.0 40.0
dc2 5.0 0.0 5.0 5.0 50.0 20.0 10.0 20.0 30.0
dc3 5.0 5.0 0.0 5.0 50.0 30.0 20.0 10.0 20.0
dc4 5.0 5.0 5.0 0.0 50.0 40.0 30.0 20.0 10.0
default 50.0 50.0 50.0 50.0 0.0 - - - -
user1 10.0 20.0 30.0 40.0 - 0.0 - - -
user2 20.0 10.0 20.0 30.0 - - 0.0 - -
user3 30.0 20.0 10.0 20.0 - - - 0.0 -
user4 40.0 30.0 20.0 10.0 - - - - 0.0
Figure 5: "routingcost" Numerical Cost Map
Note that this is a partial cost map, in that it does not define a cost for every source and destination PID.
Each ALTO server MAY provide a cost map for the "hopcount" metric. The following table gives the numerical values. As with "routingcost", a numerical-mode cost map MUST use these values, and an ordinal-mode cost map may use any values consistent with this ordering.
dc1 dc2 dc3 dc4 default user1 user2 user3 user4
dc1 0.0 1.0 1.0 1.0 8.0 3.0 4.0 5.0 6.0
dc2 1.0 0.0 1.0 1.0 8.0 4.0 3.0 4.0 5.0
dc3 1.0 1.0 0.0 1.0 8.0 5.0 4.0 3.0 4.0
dc4 1.0 1.0 1.0 0.0 8.0 6.0 5.0 4.0 3.0
default 8.0 8.0 8.0 8.0 0.0 - - - -
user1 3.0 4.0 5.0 6.0 - 0.0 - - -
user2 4.0 3.0 4.0 5.0 - - 0.0 - -
user3 5.0 4.0 3.0 4.0 - - - 0.0 -
user4 6.0 5.0 4.0 3.0 - - - - 0.0
Figure 6: "hopcount" Numerical Cost Map
An ALTO server may provide the private endpoint property "priv:ietf-type" with the following values for endpoints in the indicated address blocks:
Value IP Address Block
---------------------------------------
mine 100.0.0.0/8
peer 128.0.0.0/6, 2001:DB8::/32
transit 132.0.0.0/16, 135.0.0.0/16
Figure 7: Values for "priv:ietf-type" endpoint property
An ALTO server MUST provide the following resources, as required by [RFC7285]:
A server MAY provide whatever additional resources it desires, as long as they are consistent with the network maps, cost maps and endpoint properties defined in Section 2. In particular, a server may provide:
However, a server MUST NOT provide more than the two network maps defined in this document. This restriction simplifies testing, because it allows a client to automatically identify the alternate network map (e.g., any network map which is not the default must be the alternate network). If servers could offer three or more network maps, a client would have to be provisioned with the resource id of the alternate network map.
Note that if a server provides a Network Map resource for the alternate network map, [RFC7285] requires the server to also provide a Cost Map resource for the "routingcost" metric, in either "numerical" or "ordinal" mode, and an Endpoint Property Service for that network map's "pid" property.
A server MAY structure the IRD however it wants. In particular, a server may
When given the URI for an ALTO server's IRD, an ALTO client should read the IRD, and for each resource that it recognizes, verify that the server returns the correct response. Note that most of the data the server returns is determined by the network maps, cost maps and property values specified in Section 2, and hence can be verified by a client. Some data cannot be determined a priori (e.g., resource id and tag of a network map), but a client can verify their consistency (e.g., a cost map's dependent-vtag field should match the vtag field of the associated network map).
It is expected that not every client will be able recognize and verify every possible resource. However, each client MUST be able to verify the default network map and the associated "routingcost" cost map. In particular, although clients are not required to recognize the alternate network map, if presented with an IRD with two network maps, every client MUST be able to distinguish the default network map, and its associated cost map, from the alternate network map.
Ideally clients should be scripted. That is, when given the URI for a server, an ideal client would verify the server automatically, without further operator intervention. A client should log the resources it tested, and clearly highlight any response the client considered incorrect.
The HTTP GET-mode resources (Network Map and Cost Map) do not require client input, and hence testing is straight-forward: the client sends the appropriate HTTP GET request, and verifies the response.
However, POST-mode resources, such as Filtered Cost Maps and Endpoint Property Services, require client input. The following sections present recommended input parameters for various resources, and clients SHOULD implement as many of these tests as possible. Clients MAY add additional tests, and are encouraged to do so.
All tests require an appropriate "cost-type" parameter. At a minimum, clients should run these tests for the "routingcost" metric for the default network map. If possible, clients should also run these tests for the "hopcount" metric and the alternate network map.
Clients should remember that when testing "ordinal" costs, any values are acceptable as long as they are consistent with the order of the "numerical" costs defined in Section 2. Clients are also reminded that ordinal values are only comparable to other values in the same request, and a server may recalculate ordinal values for each request. Hence the same cost point may have ordinal value "6" in a full cost map, but have value "1" in a filtered cost map.
mine mine1 mine1a mine2 mine3 peer1 peer2
mine - - - - - 30.0 30.0
mine1 - - - - - 20.0 25.0
mine1a - - - - - 22.0 24.0
mine2 - - - - - 23.0 25.0
mine3 - - - - - 25.0 28.0
peer1 30.0 20.0 22.0 23.0 25.0 - -
peer2 30.0 25.0 24.0 25.0 28.0 - -
Figure 8: Filtered Cost Map Constraint Test
Every client should verify that the server's EPS resource for the default network's "pid" property returns the correct PID name for a representative set of endpoint addresses. If possible, clients should also verify the alternate network's "pid" property and the "priv:ietf-type" property.
The table below gives the expected values for a set of addresses. Clients are encouraged to test other addresses as well.
Address def.pid alt.pid priv:ietf-type
---------------- ------- ------- --------------
ipv4:0.0.0.1 default default -
ipv4:10.1.2.3 private private -
ipv4:100.0.0.1 mine1 default mine
ipv4:100.0.1.1 mine1a default mine
ipv4:100.0.192.1 mine1a default mine
ipv4:100.0.64.1 mine1a default mine
ipv4:100.130.0.1 mine3 default mine
ipv4:100.200.0.1 mine default mine
ipv4:100.75.0.1 mine2 default mine
ipv4:101.0.0.1 default dc1 -
ipv4:101.1.0.1 default default -
ipv4:102.0.0.1 default dc2 -
ipv4:103.0.0.1 default dc3 -
ipv4:104.0.0.1 default dc4 -
ipv4:127.0.0.1 loopback loopback -
ipv4:127.255.255.255 loopback loopback -
ipv4:128.0.0.1 peer1 default peer
ipv4:129.0.0.1 peer2 default peer
ipv4:130.0.0.1 peer1 default peer
ipv4:131.0.0.1 peer2 default peer
ipv4:132.0.0.1 tran1 default transit
ipv4:135.0.0.1 tran2 default transit
ipv4:169.254.1.2 linklocal linklocal -
ipv4:201.0.0.1 default user1 -
ipv4:201.1.2.3 default default -
ipv4:202.0.0.1 default user2 -
ipv4:203.0.0.1 default user3 -
ipv4:204.0.0.1 default user4 -
ipv4:99.0.0.1 default default -
ipv6:::1 loopback loopback -
ipv6:::2 default default -
ipv6:2001:db8:: peer1 default peer
ipv6:2001:db8:8000::1 peer2 default peer
ipv6:fc00:1:: private private -
ipv6:ff80:1:2:: linklocal linklocal -
Figure 9: EPS Test Addresses And Property Values
TBD!!!
TBD!!!
This document does not present any new security considerations above and beyond what is documented in the ALTO protocol [RFC7285].
This document does not require any action from IANA.
| [RFC7159] | Bray, T., "The JavaScript Object Notation (JSON) Data Interchange Format", RFC 7159, March 2014. |
| [RFC7285] | Almi, R., Penno, R., Yang, Y., Kiesel, S., Previdi, S., Roome, W., Shalunov, S. and R. Woundy, "Application-Layer Traffic Optimization (ALTO) Protocol", RFC 7285, September 2014. |
This section presents the network and cost maps defined in Section 2 formatted as JSON ([RFC7159]) objects.
"network-map": {
"default": {
"ipv4": ["0.0.0.0/0"],
"ipv6": ["::/0"] },
"linklocal": {
"ipv4": ["169.254.0.0/16"],
"ipv6": ["FF80::/10"] },
"loopback": {
"ipv4": ["127.0.0.0/8"],
"ipv6": ["::1/128"] },
"mine": {
"ipv4": ["100.0.0.0/8"] },
"mine1": {
"ipv4": ["100.0.0.0/10"] },
"mine1a": {
"ipv4": ["100.0.64.0/24", "100.0.192.0/24", "100.0.1.0/24"] },
"mine2": {
"ipv4": ["100.64.0.0/10"] },
"mine3": {
"ipv4": ["100.128.0.0/10"] },
"peer1": {
"ipv4": ["130.0.0.0/16", "128.0.0.0/16"],
"ipv6": ["2001:DB8::/33"] },
"peer2": {
"ipv4": ["131.0.0.0/16", "129.0.0.0/16"],
"ipv6": ["2001:DB8:8000::/33"] },
"private": {
"ipv4": ["10.0.0.0/8", "172.16.0.0/12", "192.168.0.0/16"],
"ipv6": ["FC00::/7"] },
"tran1": {
"ipv4": ["132.0.0.0/16"] },
"tran2": {
"ipv4": ["135.0.0.0/16"] }
}
Figure 10: Default Network Map, in JSON
"cost-map": {
"default": {
"default": 1.0, "mine": 75.0, "mine1": 75.0, "mine1a": 75.0,
"mine2": 75.0, "mine3": 75.0 },
"mine": {
"default": 75.0, "mine": 1.0, "mine1": 15.0, "mine1a": 15.0,
"mine2": 15.0, "mine3": 15.0, "peer1": 30.0, "peer2": 30.0,
"tran1": 50.0, "tran2": 50.0 },
"mine1": {
"default": 75.0, "mine": 15.0, "mine1": 1.0, "mine1a": 2.5,
"mine2": 5.0, "mine3": 7.0, "peer1": 20.0, "peer2": 25.0,
"tran1": 40.0, "tran2": 45.0 },
"mine1a": {
"default": 75.0, "mine": 15.0, "mine1": 2.0, "mine1a": 1.0,
"mine2": 7.0, "mine3": 9.0, "peer1": 22.0, "peer2": 24.0,
"tran1": 42.0, "tran2": 48.0 },
"mine2": {
"default": 75.0, "mine": 15.0, "mine1": 5.5, "mine1a": 7.0,
"mine2": 1.0, "mine3": 6.0, "peer1": 23.0, "peer2": 25.0,
"tran1": 43.0, "tran2": 46.0 },
"mine3": {
"default": 75.0, "mine": 15.0, "mine1": 7.0, "mine1a": 9.0,
"mine2": 6.0, "mine3": 1.0, "peer1": 25.0, "peer2": 28.0,
"tran1": 45.0, "tran2": 49.0 },
"peer1": {
"mine": 30.0, "mine1": 20.0, "mine1a": 22.0, "mine2": 23.0,
"mine3": 25.0, "peer1": 1.0 },
"peer2": {
"mine": 30.0, "mine1": 25.0, "mine1a": 24.0, "mine2": 25.0,
"mine3": 28.0, "peer2": 1.0 },
"tran1": {
"mine": 50.0, "mine1": 40.0, "mine1a": 42.0, "mine2": 43.0,
"mine3": 45.0, "tran1": 1.0 },
"tran2": {
"mine": 50.0, "mine1": 45.0, "mine1a": 48.0, "mine2": 46.0,
"mine3": 49.0, "tran2": 1.0 }
}
Figure 11: Default "routingcost" Cost Map, in JSON
"cost-map": {
"default": {
"default": 1.0, "mine": 10.0, "mine1": 10.0, "mine1a": 10.0,
"mine2": 10.0, "mine3": 10.0 },
"mine": {
"default": 10.0, "mine": 1.0, "mine1": 3.0, "mine1a": 3.0,
"mine2": 3.0, "mine3": 3.0, "peer1": 5.0, "peer2": 6.0,
"tran1": 8.0, "tran2": 8.0 },
"mine1": {
"default": 10.0, "mine": 3.0, "mine1": 1.0, "mine1a": 2.0,
"mine2": 2.0, "mine3": 2.0, "peer1": 4.0, "peer2": 5.0,
"tran1": 6.0, "tran2": 7.0 },
"mine1a": {
"default": 10.0, "mine": 3.0, "mine1": 2.0, "mine1a": 1.0,
"mine2": 2.0, "mine3": 3.0, "peer1": 5.0, "peer2": 6.0,
"tran1": 7.0, "tran2": 8.0 },
"mine2": {
"default": 10.0, "mine": 3.0, "mine1": 2.0, "mine1a": 2.0,
"mine2": 1.0, "mine3": 2.0, "peer1": 4.0, "peer2": 5.0,
"tran1": 6.0, "tran2": 7.0 },
"mine3": {
"default": 10.0, "mine": 3.0, "mine1": 2.0, "mine1a": 3.0,
"mine2": 2.0, "mine3": 1.0, "peer1": 4.0, "peer2": 5.0,
"tran1": 6.0, "tran2": 7.0 },
"peer1": {
"mine": 5.0, "mine1": 4.0, "mine1a": 5.0, "mine2": 4.0,
"mine3": 4.0, "peer1": 1.0 },
"peer2": {
"mine": 6.0, "mine1": 5.0, "mine1a": 6.0, "mine2": 5.0,
"mine3": 5.0, "peer2": 1.0 },
"tran1": {
"mine": 8.0, "mine1": 6.0, "mine1a": 7.0, "mine2": 6.0,
"mine3": 6.0, "tran1": 1.0 },
"tran2": {
"mine": 8.0, "mine1": 7.0, "mine1a": 8.0, "mine2": 7.0,
"mine3": 7.0, "tran2": 1.0 }
}
Figure 12: Default "hopcount" Cost Map, in JSON
"network-map": {
"dc1": {
"ipv4": ["101.0.0.0/16"] },
"dc2": {
"ipv4": ["102.0.0.0/16"] },
"dc3": {
"ipv4": ["103.0.0.0/16"] },
"dc4": {
"ipv4": ["104.0.0.0/16"] },
"default": {
"ipv4": ["0.0.0.0/0"],
"ipv6": ["::/0"] },
"linklocal": {
"ipv4": ["169.254.0.0/16"],
"ipv6": ["FF80::/10"] },
"loopback": {
"ipv4": ["127.0.0.0/8"],
"ipv6": ["::1/128"] },
"private": {
"ipv4": ["10.0.0.0/8", "172.16.0.0/12", "192.168.0.0/16"],
"ipv6": ["FC00::/7"] },
"user1": {
"ipv4": ["201.0.0.0/16"] },
"user2": {
"ipv4": ["202.0.0.0/16"] },
"user3": {
"ipv4": ["203.0.0.0/16"] },
"user4": {
"ipv4": ["204.0.0.0/16"] }
}
Figure 13: Alternate Network Map, in JSON
"cost-map": {
"dc1": {
"dc1": 0.0, "dc2": 5.0, "dc3": 5.0, "dc4": 5.0,
"default": 50.0, "user1": 10.0, "user2": 20.0, "user3": 30.0,
"user4": 40.0 },
"dc2": {
"dc1": 5.0, "dc2": 0.0, "dc3": 5.0, "dc4": 5.0,
"default": 50.0, "user1": 20.0, "user2": 10.0, "user3": 20.0,
"user4": 30.0 },
"dc3": {
"dc1": 5.0, "dc2": 5.0, "dc3": 0.0, "dc4": 5.0,
"default": 50.0, "user1": 30.0, "user2": 20.0, "user3": 10.0,
"user4": 20.0 },
"dc4": {
"dc1": 5.0, "dc2": 5.0, "dc3": 5.0, "dc4": 0.0,
"default": 50.0, "user1": 40.0, "user2": 30.0, "user3": 20.0,
"user4": 10.0 },
"default": {
"dc1": 50.0, "dc2": 50.0, "dc3": 50.0, "dc4": 50.0,
"default": 0.0 },
"user1": {
"dc1": 10.0, "dc2": 20.0, "dc3": 30.0, "dc4": 40.0,
"user1": 0.0 },
"user2": {
"dc1": 20.0, "dc2": 10.0, "dc3": 20.0, "dc4": 30.0,
"user2": 0.0 },
"user3": {
"dc1": 30.0, "dc2": 20.0, "dc3": 10.0, "dc4": 20.0,
"user3": 0.0 },
"user4": {
"dc1": 40.0, "dc2": 30.0, "dc3": 20.0, "dc4": 10.0,
"user4": 0.0 }
}
Figure 14: Alternate "routingcost" Cost Map, in JSON
"cost-map": {
"dc1": {
"dc1": 0.0, "dc2": 1.0, "dc3": 1.0, "dc4": 1.0,
"default": 8.0, "user1": 3.0, "user2": 4.0, "user3": 5.0,
"user4": 6.0 },
"dc2": {
"dc1": 1.0, "dc2": 0.0, "dc3": 1.0, "dc4": 1.0,
"default": 8.0, "user1": 4.0, "user2": 3.0, "user3": 4.0,
"user4": 5.0 },
"dc3": {
"dc1": 1.0, "dc2": 1.0, "dc3": 0.0, "dc4": 1.0,
"default": 8.0, "user1": 5.0, "user2": 4.0, "user3": 3.0,
"user4": 4.0 },
"dc4": {
"dc1": 1.0, "dc2": 1.0, "dc3": 1.0, "dc4": 0.0,
"default": 8.0, "user1": 6.0, "user2": 5.0, "user3": 4.0,
"user4": 3.0 },
"default": {
"dc1": 8.0, "dc2": 8.0, "dc3": 8.0, "dc4": 8.0,
"default": 0.0 },
"user1": {
"dc1": 3.0, "dc2": 4.0, "dc3": 5.0, "dc4": 6.0,
"user1": 0.0 },
"user2": {
"dc1": 4.0, "dc2": 3.0, "dc3": 4.0, "dc4": 5.0,
"user2": 0.0 },
"user3": {
"dc1": 5.0, "dc2": 4.0, "dc3": 3.0, "dc4": 4.0,
"user3": 0.0 },
"user4": {
"dc1": 6.0, "dc2": 5.0, "dc3": 4.0, "dc4": 3.0,
"user4": 0.0 }
},
Figure 15: Alternate "hopcount" Cost Map, in JSON
The editors will like to thank the ALTO working group participants for reviewing test cases. Richard Alimi and Mikio Hara contributed review cycles to the contents of this document.