NAME

SYNOPSIS

DESCRIPTION

In the data collection mode, sc_bdrmap uses Paris traceroute with ICMP-echo probes to trace the paths towards every distinct address block, using a stop-set to avoid re-probing portions of paths that do not provide useful constraints for the first hop border routers, as well as alias resolution techniques (Mercator, Ally, Prefixscan, and the Too-Big-Trick) to collapse the interface graph into a router-level topology. sc_bdrmap will also use probes with the record-route and pre-specified timestamp IP-level options to collect additional information on the return path from a router, where the probes are usable.

In the data analysis mode, sc_bdrmap uses the collected data to infer a router-level topology of the hosting network and the interconnecting routers belonging to the hosting network's neighbors.

The supported options to sc_bdrmap are as follows:

-6

specifies that sc_bdrmap should infer IPv6 border routers, and that the input files are for the IPv6 topology. This feature is currently work in progress.

-a ip2as-file

specifies the IP prefix to Autonomous System (AS) mapping file that sc_bdrmap should use when collecting and analysing topology data. See the examples section for a description of how this file must be formatted.

-A

specifies the AS numbers (ASNs) that sc_bdrmap should collect data towards. This option is useful for testing and debugging.

-c allyconf

specifies the number of times that sc_bdrmap should repeat pair-wise alias inferences that were made implying a central shared IP-ID counter. By default, each pair of aliases is tested five additional times at 5 minute intervals because two IP addresses belonging to two different routers could happen to return IP-ID values that imply a central shared IP-ID counter.

-C flowid

specifies the checksum that scamper should use in ICMP probes, or the source port that scamper should use in UDP probes, so that traceroutes to the same destination will also use the same flowid. By default, the flowid is 0x420.

-d dump

specifies the dump ID to use to analyze the collected data. Currently, ID values 1 (routers) and 2 (traces) are valid, which dumps inferred routers and annotated traceroute paths, respectively.

-D

causes sc_bdrmap to detach and become a daemon.

-f firsthop

specifies the first hop in a traceroute path that sc_bdrmap should begin at when collecting traceroute paths. If sc_bdrmap is being run behind a NAT router, the private IP address of that router is uninteresting, and this option allows that hop to be skipped.

-g delegated-file

specifies an IP address delegations file that can be provided to sc_bdrmap to allow inferences in the analysis phase of who operates unrouted IP address space.

-i

specifies the IP addresses that sc_bdrmap should collect data towards. This option is useful for testing and debugging.

-l log-file

specifies the name of a file to log progress output from sc_bdrmap generated at run time.

-M ipmap-file

specifies the name of a file containing individual IP address to ASN mappings, which override heuristics inferring if the IP address is from a reserved address, or an IXP address.

-n names-file

specifies the name of a file containing IP address to domain name system names.

-o output-file

specifies the name of the output file to be written during the data collection phase. The output file will use the warts(5) format.

-O option

allows the behavior of sc_bdrmap to be further tailored. The current choices for this option are:

• dumpborders: only dump inferred border routers, not all VP routers.
• dumponedsts: further annotate routers that were only observed towards one AS.
• dumptracesets: dump the traceroutes observed towards networks where no topology was observed to be routed by a neighbor network.
• impatient: probe the destination ASes in order of number of address blocks, so that the probing will complete fastest.
• noalias: do not do alias resolution probes when collecting topology data.
• nogss: do not use a global stop set when collecting topology data.
• noipopts: do not probe with IP record route and IP prespecified timestamp options.
• nomerge: do not analytically merge IP interfaces to routers based on common adjacent neighbor routers.
• noself: do not report links to other routers operated by the network hosting the vantage point.
• randomdst: probe a random address in each address block, rather than the first.
• udp: probe using UDP traceroute probes.

-p port

specifies the port on the local host where scamper(1) is accepting control socket connections.

-r relationships-file

specifies the AS relationships file which is used in the analysis phase to reason about who owns each router in the observed topology.

-R unix

specifies the name of a unix domain socket where a remote scamper(1) instance is accepting remote control socket connections.

-S srcaddr

specifies the source address that scamper(1) should use in probes.

-U unix

specifies the name of a unix domain socket where a local scamper(1) instance is accepting control socket connections.

-v vpases

specifies the name of a file, or a list of ASes, that represent the network hosting the vantage point.

-x ixp-file

specifies the name of a file that contains a list of prefixes used by an IXP to enable interconnection at their facilities.

EXAMPLES

the following command will collect raw topology data to support inference of border routers for the network hosting the vantage point, storing raw data into bdrmap.warts, and logging run-time information into logfile1.txt:

To infer border routers from the collected data, using the same input files as above, with a set of AS relationships contained in asrel.txt, and a set of prefix delegations assembled from the Regional Internet Registry (RIR) Statistics files in delegated.txt:

To view annotated traceroutes stored in bdrmap.warts with IP to DNS names information stored in names.txt:

SEE ALSO

M. Luckie, A. Dhamdhere, B. Huffaker, D. Clark, and k. claffy, bdrmap: Inference of Borders Between IP Networks, Proc. ACM/SIGCOMM Internet Measurement Conference 2016.

R. Govindan and H. Tangmunarunkit, Heuristics for Internet Map Discovery, Proc. IEEE INFOCOM 2000.

N. Spring, R. Mahajan, and D. Wetherall, Measuring ISP topologies with Rocketfuel, Proc. ACM SIGCOMM 2002.

B. Donnet, P. Raoult, T. Friedman, and M. Crovella, Efficient algorithms for large-scale topology discovery, Proc. ACM SIGMETRICS 2005.

B. Augustin, X. Cuvellier, B. Orgogozo, F. Viger, T. Friedman, M. Latapy, C. Magnien, and R. Teixeira, Avoiding traceroute anomalies with Paris traceroute, Proc. ACM/SIGCOMM Internet Measurement Conference 2006.

A. Bender, R. Sherwood, and N. Spring, Fixing Ally's growing pains with velocity modeling, Proc. ACM/SIGCOMM Internet Measurement Conference 2008.

M. Luckie, Scamper: a Scalable and Extensible Packet Prober for Active Measurement of the Internet, Proc. ACM/SIGCOMM Internet Measurement Conference 2010.

R. Beverly, W. Brinkmeyer, M. Luckie, and J.P. Rohrer, IPv6 Alias Resolution via Induced Fragmentation, Proc. Passive and Active Measurement Conference 2013.

M. Luckie, R. Beverly, W. Brinkmeyer, and k claffy, Speedtrap: Internet-scale IPv6 Alias Resolution, Proc. ACM/SIGCOMM Internet Measurement Conference 2013.

M. Luckie, B. Huffaker, A. Dhamdhere, V. Giotsas, and k claffy, AS Relationships, Customer Cones, and Validation, Proc. ACM/SIGCOMM Internet Measurement Conference 2013.

AUTHOR