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pmacct [IP traffic accounting : BGP : BMP : RPKI : IGP : Streaming Telemetry]
pmacct is Copyright (C) 2003-2021 by Paolo Lucente
TABLE OF CONTENTS:
I. Daemons and plugins included with pmacct distribution
II. Configuring pmacct for compilation and installing
III. Brief SQL (MySQL, PostgreSQL, SQLite 3.x) setup examples
IV. Running the libpcap-based daemon (pmacctd)
V. Running the NetFlow/IPFIX and sFlow daemons (nfacctd/sfacctd)
VI. Running the NFLOG-based daemon (uacctd)
VII. Running the pmacct IMT client (pmacct)
VIII. Running the RabbitMQ/AMQP plugin
IX. Running the Kafka plugin
X. Internal buffering and queueing
XI. Quickstart guide to packet/flow classification
XII. Quickstart guide to setup a NetFlow/IPFIX agent/probe
XIII. Quickstart guide to setup a sFlow agent/probe
XIV. Quickstart guide to setup the BGP daemon
XV. Quickstart guide to setup a NetFlow/IPFIX/sFlow replicator
XVI. Quickstart guide to setup the IS-IS daemon
XVII. Quickstart guide to setup the BMP daemon
XVIII. Quickstart guide to setup Streaming Telemetry collection
XIX. Running the print plugin to write to flat-files
XX. Quickstart guide to setup GeoIP lookups
XXI. Using pmacct as traffic/event logger
XXII. Connecting pmacct to a Redis cache
XXIII. Miscellaneous notes and troubleshooting tips
I. Daemons and plugins included with pmacct distribution
All traffic accounting daemons can print statistics to stdout, keep them in
memory tables, store persistently to open-source RDBMS (MySQL, PostgreSQL,
Sqlite 3) or to noSQL databates (ie. BerkeleyDB) and to flat-files, and
publish to AMQP and Kafka brokers (typically to insert in ElasticSearch,
InfluxDB, Druid, ClickHouse and, more in general, all backends which are not
natively supported by pmacct). BGP, BMP and Streaming Telemetry daemons can
publish control and infrastructure planes to AMQP and Kafka brokers. This is
a list of the daemons included in the pmacct distribution:
pmacctd libpcap-based accounting daemon: it captures packets from one
or multiple interfaces it is bound to. Other than acting as a
collector, this daemon can also export statistics via NetFlow,
IPFIX and sFlow protocols.
nfacctd NetFlow/IPFIX accounting daemon: it listens for NetFlow v5/v9
and IPFIX packets on one or more interfaces (IPv4 and IPv6).
Other than acting as a collector, this daemon can also
replicate to 3rd party collectors.
sfacctd sFlow accounting daemon; it listens for sFlow packets v2, v4
and v5 on one or more interfaces (both IPv4 and IPv6). Other
than acting as a collector, this daemon can also replicate to
3rd party collectors.
uacctd Linux Netlink NFLOG accounting daemon; it captures packets by
leveraging a NFLOG multicast group - and works only on Linux.
Other than acting as a collector, this daemon can also export
statistics via NetFlow, IPFIX and sFlow protocols.
pmtelemetryd Standalone Streaming Telemetry collector daemon; listens for
telemetry data binding to a TCP or UDP port and logs real-time
and/or dumps at regular time-intervals to configured backends.
pmbgpd Standalone BGP collector daemon; acts as a passive iBGP or
eBGP neighbor and maintains per-peer RIBs; can log real-time
and/or dump at regular time-intervals BGP data to configured
backends.
pmbmpd Standalone BMP collector daemon; can log real-time and/or dump
at regular time-intervals BMP/BGP data to configured backends.
pmacct commandline pmacct client; it allows to retrieve data from a
memory table plugin; it can perform queries over data or do
bulk data retrieval. Output is formatted, CSV or JSON format.
suitable for data injection in 3rd party tools like RRDtool,
Gnuplot or SNMP server among the others.
Given its open and pluggable architecture, pmacct is easily extensible with new
plugins. Here is a list of traffic accounting plugins included in the official
pmacct distribution:
memory data is stored in a memory table and can be fetched via the
pmacct command-line client tool, 'pmacct'. This plugin also
implements a push model and allows easily to inject data into
3rd party tools. The plugin is recommended for prototyping and
smaller-scale environments and is compiled in by default.
mysql a working MySQL/MariaDB installation can be used for data
storage. This plugin can be compiled using the --enable-mysql
switch.
pgsql a working PostgreSQL installation can be used for data storage.
This plugin can be compiled using the --enable-pgsql switch.
sqlite3 a working SQLite 3.x or BerkeleyDB 5.x (compiled in with the
SQLite API) installation can be used for data storage. This
plugin can be compiled using the --enable-sqlite3 switch.
print data is printed at regular intervals to flat-files or standard
output in tab-spaced, CSV and JSON formats. This plugin is
compiled in by default.
amqp data is sent to a RabbitMQ broker, running AMQP protocol, for
delivery to consumer applications or tools. Popular consumers
are ElasticSearch, InfluxDB, Druid and ClickHouse. This plugin
can be compiled using the --enable-rabbitmq switch.
kafka data is sent to a Kafka broker for delivery to consumer
applications or tools. Popular consumers are ElasticSearch,
InfluxDB, Druid and ClickHouse. This plugin can be compiled
using the --enable-kafka switch.
tee applies to nfacctd and sfacctd daemons only. It's a featureful
packet replicator for NetFlow/IPFIX/sFlow data. This plugin is
compiled in by default.
nfprobe applies to pmacctd and uacctd daemons only. Exports collected
data via NetFlow v5/v9 or IPFIX. This plugin is compiled in by
default.
sfprobe applies to pmacctd and uacctd daemons only. Exports collected
data via sFlow v5. This plugin is compiled in by default.
II. Configuring pmacct for compilation and installing
The simplest way to configure the package for compilation is to download the
latest stable released tarball from http://www.pmacct.net/ and let the configure
script to probe default headers and libraries for you. The only dependency that
pmacct brings is libpcap library and headers: libpcap-dev on Debian/Ubuntu,
libpcap-devel on CentOS/RHEL (note: this may need enabling extra yum repos!) or
(self-compiled) equivalent must be installed on the system. Then, a first round
of guessing is done via pkg-config then, for some libraries, "typical" default
locations are checked, ie. /usr/local/lib. Switches one likely wants enabled are
already set so, ie. 64 bits counters and multi-threading (pre- requisite for
the BGP, BMP, and IGP daemon codes); the full list of switches enabled by default
are marked as 'default: yes' in the "./configure --help" output. SQL plugins, AMQP
and Kafka support are all disabled by default instead. A few examples will follow;
to get the list of available switches, you can use the following command-line:
shell> ./configure --help
Examples on how to enable support for (1) MySQL, (2) PostgreSQL and (3) SQLite:
(1) libmysqlclient-dev package or (self-compiled) equivalent being installed:
shell> ./configure --enable-mysql
(2) libpq-dev package or (self-compiled) equivalent being installed:
shell> ./configure --enable-pgsql
(3) libsqlite3-dev package or (self-compiled) equivalent being installed:
shell> ./configure --enable-sqlite3
If cloning the GitHub repository ( https://github.com/pmacct/pmacct ) instead,
the configure script has to be generated, resulting in one extra step than the
process just described. Please refer to the Building section of the README.md
document for instruction about cloning the repo, generate the configure script
along with the required installed packages.
Then compile and install simply typing:
shell> make; make install
Should you want, for example, to compile pmacct with PostgreSQL support and
have installed PostgreSQL in /usr/local/postgresql and pkg-config is unable
to help, you can supply this non-default location as follows (assuming you
are running the bash shell):
shell> export PGSQL_LIBS="-L/usr/local/postgresql/lib -lpq"
shell> export PGSQL_CFLAGS="-I/usr/local/postgresql/include"
shell> ./configure --enable-pgsql
If the library does actually support pkg-config but the .pc pkg-config file
is in some non-standard location, this can be supplied as follows:
shell> export PKG_CONFIG_PATH=/usr/local/postgresql/pkgconfig/
shell> ./configure --enable-pgsql
Special case is to compile pmacct with MySQL support but MySQL is installed
in some non-default location. MySQL brings the mysql_config tool that works
similarly to pkg-config. Make sure the tool is on the path so that it can be
executed by the configure script, ie.:
shell> export PATH=$PATH:/usr/local/mysql/bin
shell> ./configure --enable-mysql
By default all tools - flow, BGP, BMP and Streaming Telemetry - are compiled.
Specific tool sets can be disabled. For example, to compile only flow tools
(ie. no pmbgpd, pmbmpd, pmtelemetryd) the following command-line can be used:
shell> ./configure --disable-bgp-bins --disable-bmp-bins --disable-st-bins
Once daemons are installed you can check:
* Basic instrumenting of each daemon via its help page, ie.:
shell> pmacctd -h
* Review daemon version and build details, ie.:
shell> sfacctd -V
* Check supported traffic aggregation primitives and their description, ie.:
shell> nfacctd -a
IIa. Compiling pmacct with JSON support
JSON encoding is supported via the Jansson library (http://www.digip.org/jansson/
and https://github.com/akheron/jansson); a library version >= 2.5 is required. To
compile pmacct with JSON support simply do:
shell> ./configure --enable-jansson
However should you have installed Jansson in the /usr/local/jansson directory
and pkg-config is unable to help, you can supply this non-default location as
follows (assuming you are running the bash shell):
shell> export JANSSON_LIBS="-L/usr/local/jansson/lib -ljansson"
shell> export JANSSON_CFLAGS="-I/usr/local/jansson/include"
shell> ./configure --enable-jansson
IIb. Compiling pmacct with Apache Avro support
Apache Avro encoding is supported via libavro library (http://avro.apache.org/
and https://avro.apache.org/docs/1.9.1/api/c/index.html); Avro depends on the
Jansson JSON parser version 2.3 or higher so please review the previous section
"Compiling pmacct with JSON support"; then, to compile pmacct with Apache Avro
support simply do:
shell> ./configure --enable-jansson --enable-avro
However should you have installed libavro in the /usr/local/avro directory
and pkg-config is unable to help, you can supply this non-default location as
follows (assuming you are running the bash shell):
shell> export AVRO_LIBS="-L/usr/local/avro/lib -lavro"
shell> export AVRO_CFLAGS="-I/usr/local/avro/include"
shell> ./configure --enable-kafka --enable-jansson --enable-avro
IIc. Compiling pmacct against a own libpcap library
Compiling against a downloaded libpcap library may be wanted for several
reasons including the version packaged with the Operating System is too
old, a custom libpcap library needs to be compiled (ie. with support for
PF_RING) or static linking is wanted.
Once libpcap is downloaded, if static linking is wanted (ideal for example
for distributing pmacct without external dependencies), the library can be
configured for comipiling:
shell> ./configure --disable-so
Which passes the compiler the '-static' knob. pmacct should be pointed to
the own libpcap library when configuring for compiling:
shell> ./configure --with-pcap-libs=/path/to/libpcap-x.y.z --with-pcap-includes=/path/to/libpcap-x.y.z
Once pmacct is compiled, it can be confirmed that the right library was
picked by doing, for example, a 'pmacctd -V' and seeing the version of
libpcap matches with the supplied version. It has to be noted however
that static compiling on GNU systems can yeld variable success; the
recommendation is to consider containers first (look into the 'docker/'
directory).
A use-case for a PF_RING-enabled libpcap is that by hashing and balancing
collected traffic over multiple NIC queues (ie. if using Intel X520) it
is possible to scale pmacctd horizontally, with one pmacctd instance
reading from one or multiple queues. The queues can be managed via the
'ethtool' tool (ie. 'ethtool -l enp1s0f0' to list, 'ethtool -L enp1s0f0
combined 16' to access 16 queues, etc.) and pmacctd can be bound to a
single queue, ie. 'pmacctd -i enp1s0f0@0', or multiple ones via a
pcap_interfaces_map, ie.
ifname=enp1s0f0@0 ifindex=100
ifname=enp1s0f0@1 ifindex=101
ifname=enp1s0f0@2 ifindex=102
ifname=enp1s0f0@3 ifindex=103
III. Brief SQL and noSQL setup examples
RDBMS require a table schema to store data. pmacct offers two options: use one
of the few pre-determined table schemas available (sections IIIa, b and c) or
compose a custom schema to fit your needs (section IIId). If you are blind to
SQL the former approach is recommended, although it can pose scalability issues
in larger deployments; if you know some SQL the latter is definitely the way to
go. Scripts for setting up RDBMS are located in the 'sql/' tree of the pmacct
distribution tarball. For further guidance read the relevant README files in
such directory. One of the crucial concepts to deal with, when using default
table schemas, is table versioning: please read more about this topic in the
FAQS document (Q17).
IIIa. MySQL examples
shell> cd sql/
- To create v1 tables:
shell> mysql -u root -p < pmacct-create-db_v1.mysql
shell> mysql -u root -p < pmacct-grant-db.mysql
Data will be available in 'acct' table of 'pmacct' DB.
- To create v2 tables:
shell> mysql -u root -p < pmacct-create-db_v2.mysql
shell> mysql -u root -p < pmacct-grant-db.mysql
Data will be available in 'acct_v2' table of 'pmacct' DB.
... And so on for the newer versions.
IIIb. PostgreSQL examples
Which user has to execute the following two scripts and how to autenticate with the
PostgreSQL server depends upon your current configuration. Keep in mind that both
scripts need postgres superuser permissions to execute some commands successfully:
shell> cp -p *.pgsql /tmp
shell> su - postgres
To create v1 tables:
shell> psql -d template1 -f /tmp/pmacct-create-db.pgsql
shell> psql -d pmacct -f /tmp/pmacct-create-table_v1.pgsql
To create v2 tables:
shell> psql -d template1 -f /tmp/pmacct-create-db.pgsql
shell> psql -d pmacct -f /tmp/pmacct-create-table_v2.pgsql
... And so on for the newer versions.
A few tables will be created into 'pmacct' DB. 'acct' ('acct_v2' or 'acct_v3') table is
the default table where data will be written when in 'typed' mode (see 'sql_data' option
in CONFIG-KEYS document; default value is 'typed'); 'acct_uni' ('acct_uni_v2' or
'acct_uni_v3') is the default table where data will be written when in 'unified' mode.
Since v6, PostgreSQL tables are greatly simplified: unified mode is no longer supported
and an unique table ('acct_v6', for example) is created instead.
IIIc. SQLite examples
shell> cd sql/
- To create v1 tables:
shell> sqlite3 /tmp/pmacct.db < pmacct-create-table.sqlite3
Data will be available in 'acct' table of '/tmp/pmacct.db' DB. Of course, you can change
the database filename basing on your preferences.
- To create v2 tables:
shell> sqlite3 /tmp/pmacct.db < pmacct-create-table_v2.sqlite3
Data will be available in 'acct_v2' table of '/tmp/pmacct.db' DB.
... And so on for the newer versions.
IIId. Custom SQL tables
Custom tables can be built by creating your own SQL schema and indexes. This
allows to mix-and-match the primitives relevant to your accounting scenario.
To flag intention to build a custom table the sql_optimize_clauses directive
must be set to true, ie.:
sql_optimize_clauses: true
sql_table: <table name>
aggregate: <aggregation primitives list>
How to build the custom schema? Let's say the aggregation method of choice
(aggregate directive) is "vlan, in_iface, out_iface, etype" the table name is
"acct" and the database of choice is MySQL. The SQL schema is composed of four
main parts, explained below:
1) A fixed skeleton needed by pmacct logics:
CREATE TABLE <table_name> (
packets INT UNSIGNED NOT NULL,
bytes BIGINT UNSIGNED NOT NULL,
stamp_inserted DATETIME NOT NULL,
stamp_updated DATETIME
);
2) Indexing: primary key (of your choice, this is only an example) plus
any additional index you may find relevant.
3) Primitives enabled in pmacct, in this specific example the ones below; should
one need more/others, these can be looked up in the sql/README.mysql file in
the section named "Aggregation primitives to SQL schema mapping:" :
vlan INT(2) UNSIGNED NOT NULL,
iface_in INT(4) UNSIGNED NOT NULL,
iface_out INT(4) UNSIGNED NOT NULL,
etype INT(2) UNSIGNED NOT NULL,
4) Any additional fields, ignored by pmacct, that can be of use, these can be
for lookup purposes, auto-increment, etc. and can be of course also part of
the indexing you might choose.
Putting the pieces together, the resulting SQL schema is below along with the
required statements to create the database:
DROP DATABASE IF EXISTS pmacct;
CREATE DATABASE pmacct;
USE pmacct;
DROP TABLE IF EXISTS acct;
CREATE TABLE acct (
vlan INT(2) UNSIGNED NOT NULL,
iface_in INT(4) UNSIGNED NOT NULL,
iface_out INT(4) UNSIGNED NOT NULL,
etype INT(2) UNSIGNED NOT NULL,
packets INT UNSIGNED NOT NULL,
bytes BIGINT UNSIGNED NOT NULL,
stamp_inserted DATETIME NOT NULL,
stamp_updated DATETIME,
PRIMARY KEY (vlan, iface_in, iface_out, etype, stamp_inserted)
);
To grant default pmacct user permission to write into the database look at the
file sql/pmacct-grant-db.mysql
IIIe. Historical accounting
Enabling historical accounting allows to aggregate data in time-bins (ie. 5 mins, hour,
day, etc.) in a flexible and fully configurable way. Two timestamps are available: the
'stamp_inserted' field, representing the basetime of the time-bin, and 'stamp_updated',
the last time the time-bin was updated. Following a pretty standard config fragment to
slice data into nicely aligned (or rounded-off) 5 minutes time-bins:
sql_history: 5m
sql_history_roundoff: m
IIIf. INSERTs-only
UPDATE queries are expensive; this is why, even if they are supported by pmacct, a
savy approach would be to cache data for longer times in memory and write them off
once per time-bin (sql_history): this results into a much lighter INSERTs-only setup.
This is an example based on 5 minutes time-bins:
sql_refresh_time: 300
sql_history: 5m
sql_history_roundoff: m
sql_dont_try_update: true
Note that sql_refresh_time is always expressed in seconds. An alternative approach
for cases where sql_refresh_time must be kept shorter than sql_history (for example
because a) of long sql_history periods, ie. hours or days, and/or because b) near
real-time data feed is a requirement) is to set up a synthetic auto-increment 'id'
field: it successfully prevents duplicates but comes at the expenses of GROUP BYs
when querying data.
IV. Running the libpcap-based daemon (pmacctd)
All deamons including pmacctd can be run with commandline options, using a
config file or a mix of the two. Sample configuration files are in examples/
tree. Note also that most of the new features are available only as config
directives. To be aware of the existing configuration directives, please
read the CONFIG-KEYS document.
Show all available pmacctd commandline switches:
shell> pmacctd -h
Run pmacctd reading configuration from a specified file (see examples/ tree
for a brief list of some commonly useed keys; divert your eyes to CONFIG-KEYS
for the full list). This example applies to all daemons:
shell> pmacctd -f pmacctd.conf
Daemonize the process; listen on eth0; aggregate data by src_host/dst_host;
write to a MySQL server; filter in only traffic with source prefix 10.0.0.0/16;
note that filters work the same as tcpdump so you can refer to libpcap/tcpdump
man pages for examples and further reading about the supported filtering syntax.
shell> pmacctd -D -c src_host,dst_host -i eth0 -P mysql src net 10.0.0.0/16
Or written the configuration way:
!
daemonize: true
plugins: mysql
aggregate: src_host, dst_host
pcap_interface: eth0
pcap_filter: src net 10.0.0.0/16
! ...
Print collected traffic data aggregated by src_host/dst_host over the screen;
refresh data every 30 seconds and listen on eth0.
shell> pmacctd -P print -r 30 -i eth0 -c src_host,dst_host
Or written the configuration way:
!
plugins: print
print_refresh_time: 30
aggregate: src_host, dst_host
pcap_interface: eth0
! ...
Print collected traffic data aggregated by src_host/dst_host over the screen;
refresh data every 30 seconds and listen on eth0 and eth1, listed in the file
pointed by pcap_interfaces_map (see 'examples/pcap_interfaces.map.example' for
more advanced uses of the map):
!
plugins: print
print_refresh_time: 30
aggregate: src_host, dst_host
pcap_interfaces_map: /path/to/pcap_interfaces.map
! ...
Then in /path/to/pcap_interfaces.map:
!
ifindex=100 ifname=eth0
ifindex=200 ifname=eth1
! ...
Daemonize the process; let pmacct aggregate traffic in order to show in vs out
traffic for network 192.168.0.0/16; send data to a PostgreSQL server. This
configuration is not possible via commandline switches; the corresponding
configuration follows:
!
daemonize: true
plugins: pgsql[in], pgsql[out]
aggregate[in]: dst_host
aggregate[out]: src_host
aggregate_filter[in]: dst net 192.168.0.0/16
aggregate_filter[out]: src net 192.168.0.0/16
sql_table[in]: acct_in
sql_table[out]: acct_out
! ...
And now enabling historical accounting. Split traffic by hour and write
to the database every 60 seconds:
!
daemonize: true
plugins: pgsql[in], pgsql[out]
aggregate[in]: dst_host
aggregate[out]: src_host
aggregate_filter[in]: dst net 192.168.0.0/16
aggregate_filter[out]: src net 192.168.0.0/16
sql_table[in]: acct_in
sql_table[out]: acct_out
sql_refresh_time: 60
sql_history: 1h
sql_history_roundoff: h
! ...
Let's now translate the same example in the memory plugin world. One of
the use-cases for this plugin is when feeding 3rd party tools with bytes/
packets/flows counters. Examples how to query the memory table with the
'pmacct' client tool will follow later in this document. Now, note that
each memory table need its own pipe file in order to get queried by the
client:
!
daemonize: true
plugins: memory[in], memory[out]
aggregate[in]: dst_host
aggregate[out]: src_host
aggregate_filter[in]: dst net 192.168.0.0/16
aggregate_filter[out]: src net 192.168.0.0/16
imt_path[in]: /tmp/pmacct_in.pipe
imt_path[out]: /tmp/pmacct_out.pipe
! ...
As a further note, check CONFIG-KEYS document about more imt_* directives
as they will support in the task of fine tuning the size and boundaries
of memory tables, if default values are not ok for your setup.
Now, fire multiple instances of pmacctd, each on a different interface;
again, because each instance will have its own memory table, it will
require its own pipe file for client queries aswell (as explained in the
previous examples):
shell> pmacctd -D -i eth0 -m 8 -s 65535 -p /tmp/pipe.eth0
shell> pmacctd -D -i ppp0 -m 0 -s 32768 -p /tmp/pipe.ppp0
Run pmacctd logging what happens to syslog and using "local2" facility:
shell> pmacctd -c src_host,dst_host -S local2
NOTE: superuser privileges are needed to execute pmacctd correctly.
V. Running the NetFlow/IPFIX and sFlow daemons (nfacctd/sfacctd)
All examples about pmacctd are also valid for nfacctd and sfacctd with the exception
of directives that apply exclusively to libpcap. If you have skipped examples in the
previous section, please read them before continuing. All config keys available are
in the CONFIG-KEYS document. Some examples:
Run nfacctd reading configuration from a specified file:
shell> nfacctd -f nfacctd.conf
Daemonize the process; aggregate data by sum_host (by host, summing inbound + outbound
traffic); write to a local MySQL server. Listen on port 5678 for incoming Netflow
datagrams (from one or multiple NetFlow agents):
shell> nfacctd -D -c sum_host -P mysql -l 5678
Let's now configure pmacct to insert data in MySQL every two minutes, enable historical
accounting with 10 minutes time-bins and make use of a SQL table version 4:
!
daemonize: true
plugins: mysql
aggregate: sum_host
nfacctd_port: 5678
sql_refresh_time: 120
sql_history: 10m
sql_history_roundoff: mh
sql_table_version: 4
! ...
Va. NetFlow daemon & accounting NetFlow v9/IPFIX options
NetFlow v9/IPFIX can send option records other than flow ones, typically used to send
to a collector mappings among interface SNMP ifIndexes to interface names or VRF ID's
to VRF names or extra sampling information. nfacctd_account_options enables accounting
of option records then these should be split from regular flow records. Below is a
sample config:
nfacctd_time_new: true
nfacctd_account_options: true
!
plugins: print[data], print[option_vrf], print[option_if], print[option_sampling]
!
pre_tag_filter[data]: 100
aggregate[data]: peer_src_ip, in_iface, out_iface, tos, vrf_id_ingress, vrf_id_egress
print_refresh_time[data]: 300
print_history[data]: 300
print_history_roundoff[data]: m
print_output_file_append[data]: true
print_output_file[data]: /path/to/flow_%s
print_output[data]: csv
!
pre_tag_filter[option_vrf]: 200
aggregate[option_vrf]: peer_src_ip, vrf_id_ingress, vrf_name
print_refresh_time[option_vrf]: 300
print_history[option_vrf]: 300
print_history_roundoff[option_vrf]: m
print_output_file_append[option_vrf]: true
print_output_file[option_vrf]: /path/to/option_vrf_%s
print_output[option_vrf]: event_csv
!
pre_tag_filter[option_if]: 200
aggregate[option_if]: peer_src_ip, in_iface, int_descr
print_refresh_time[option_if]: 300
print_history[option_if]: 300
print_history_roundoff[option_if]: m
print_output_file_append[option_if]: true
print_output_file[option_if]: /path/to/option_if_%s
print_output[option_if]: event_csv
!
pre_tag_filter[option_sampling]: 200
aggregate[option_sampling]: peer_src_ip, sampler_id, sampler_interval
print_refresh_time[option_sampling]: 300
print_history[option_sampling]: 300
print_history_roundoff[option_sampling]: m
print_output_file_append[option_sampling]: true
print_output_file[option_sampling]: /path/to/option_sampling_%s
print_output[option_sampling]: event_csv
!
aggregate_primitives: /path/to/primitives.lst
pre_tag_map: /path/to/pretag.map
maps_refresh: true
Below is the referenced pretag.map:
set_tag=100 ip=0.0.0.0/0 sample_type=flow
set_tag=200 ip=0.0.0.0/0 sample_type=option
Below is the referenced primitives.lst:
name=vrf_id_ingress field_type=234 len=4 semantics=u_int
name=vrf_id_egress field_type=235 len=4 semantics=u_int
name=vrf_name field_type=236 len=32 semantics=str
!
name=int_descr field_type=83 len=64 semantics=str
!
name=sampler_interval field_type=50 len=4 semantics=u_int
name=sampler_id field_type=48 len=2 semantics=u_int
Vb. Distributing NetFlow v9/IPFIX templates when clustering
One of the possible ways to cluster multiple nfacctd daemons running on the same
system (ie. to harness all [configured] CPU threads) is to rely on the Linux/BSD
SO_REUSEPORT feature (read more in the "Miscellaneous notes and troubleshooting
tips" section of this document).
NetFlow v9/IPFIX protocols are template-based and templates are emitted in
specific Options packets and are indeed needed in order to properly decode
actual Data packets. Hence a load-balancing cluster (when not hashing but
performing some sort of round-robin) does pose the problem of disseminating the
templates across the clustered daemons. For this very purpose there are two
config knobs: nfacctd_templates_receiver (to export received templates) and
nfacctd_templates_port (to define a port to receive templates from the rest
of the cluster). When multiple daemons are clustered a replicator (nfacctd with
'tee' plugin configured is required). Here is an example of the configs needed:
nfacctd clustered daemon config (other daemons in the same cluster would be
listening on different nfacctd_templates_port ports, ie. 20002, 20003, etc.):
!
! [ .. existing config .. ]
!
nfacctd_templates_receiver: 127.0.0.1:10000
nfacctd_templates_port: 20001
The replicator piece needs two bits, a config and a tee_receivers file (in the
example receivers.lst). Here is the config:
nfacctd_port: 10000
!
plugins: tee[a]
!
tee_receivers[a]: /path/to/receivers.lst
tee_transparent[a]: true
And here is the receivers.lst file:
id=1 ip=127.0.0.1:20001,127.0.0.1:20002,127.0.0.1:20003,[..]
Vc. Examples configuring NetFlow v9/IPFIX export
Example to configure NetFlow v9 export on a Cisco running IOS/IOS-XE:
ip flow-cache timeout active 1
ip flow-cache mpls label-positions 1
!
ip flow-export source Loopback0
ip flow-export version 9 bgp-nexthop
ip flow-export template timeout-rate 1
ip flow-export template refresh-rate 4
ip flow-export destination X.X.X.X 2100
!
interface GigabitEthernet0/0
ip address Y.Y.Y.Y Z.Z.Z.Z
ip flow ingress
Example to configure NetFlow v9 export on a Cisco running IOS-XR:
sampler-map NFACCTD-SMP
random 1 out-of 10
!
flow monitor-map NFACCTD-MON
record ipv4
exporter NFACCTD-EXP
!
flow exporter-map NFACCTD-EXP
version v9
transport udp 2100
destination X.X.X.X
!
interface GigabitEthernet0/0/0/1
ipv4 address Y.Y.Y.Y Z.Z.Z.Z
flow ipv4 monitor NFACCTD-MON sampler NFACCTD-SMP ingress
Example to configure IPFIX export on a Juniper:
services {
flow-monitoring {
version-ipfix {
template ipv4 {
flow-active-timeout 60;
flow-inactive-timeout 70;
template-refresh-rate seconds 30;
option-refresh-rate seconds 30;
ipv4-template;
}
}
}
}
chassis {
fpc 0 {
sampling-instance s1;
}
}
forwarding-options {
sampling {
instance {
s1 {
input {
rate 10;
}
family inet {
output {
flow-server X.X.X.X {
port 2100;
version-ipfix {
template {
ipv4;
}
}
}
inline-jflow {
source-address Y.Y.Y.Y;
}
}
}
}
}
}
}
Example to configure NetFlow v9 export on a Huawei:
ip netstream timeout active 1
ip netstream timeout inactive 5
ip netstream mpls-aware label-and-ip
ip netstream export version 9 origin-as bgp-nexthop
ip netstream export index-switch 32
ip netstream export template timeout-rate 1
ip netstream sampler fix-packets 1000 inbound
ip netstream export source Y.Y.Y.Y
ip netstream export host X.X.X.X 2100
ipv6 netstream timeout active 1
ipv6 netstream timeout inactive 5
ipv6 netstream mpls-aware label-and-ip
ipv6 netstream export version 9 origin-as bgp-nexthop
ipv6 netstream export index-switch 32
ipv6 netstream export template timeout-rate 1
ipv6 netstream sampler fix-packets 1000 inbound
interface Eth-Trunk1.100
ip netstream inbound
ipv6 netstream inbound
Contribution of further configuration examples for Cisco and Juniper devices
and/or other relevant vendors is more than welcome.
VI. Running the NFLOG-based daemon (uacctd)
All examples about pmacctd are also valid for uacctd with the exception of directives
that apply exclusively to libpcap. If you've skipped examples in the "Running the
libpcap-based daemon (pmacctd)" section, please read them before continuing. All
configuration keys available are in the CONFIG-KEYS document.
The daemon depends on the package libnetfilter-log-dev in Debian/Ubuntu,
libnetfilter_log in CentOS/RHEL (or equivalent package in the preferred Linux
distribution). The support for NFLOG is disabled by default and should be enabled
as follows:
shell> ./configure --enable-nflog
NFLOG_CFLAGS and NFLOG_LIBS can be used if includes and library are not in default
locations. The Linux NFLOG infrastructure requires a couple parameters in order to
work properly: the NFLOG multicast group (uacctd_group) to which captured packets
have to be sent to and the Netlink buffer size (uacctd_nl_size). The default buffer
settings (128KB) typically works OK for small environments. The traffic is captured
with an iptables rule. For example in one of the following ways:
* iptables -t mangle -I POSTROUTING -j NFLOG --nflog-group 5
* iptables -t raw -I PREROUTING -j NFLOG --nflog-group 5
Apart from determining how and what traffic to capture with iptables, which is topic
outside the scope of this document, the most relevant point is the "--nflog-nlgroup"
iptables setting has to match with the "uacctd_group" uacctd one. To review the packet
flow in iptables: https://commons.wikimedia.org/wiki/File:Netfilter-packet-flow.svg
A couple examples follow:
Run uacctd reading configuration from a specified file.
shell> uacctd -f uacctd.conf
Daemonize the process; aggregate data by sum_host (by host, summing inbound + outbound
traffic); write to a local MySQL server. Listen on NFLOG multicast group #5. Let's make
pmacct divide data into historical time-bins of 5 minutes. Let's disable UPDATE queries
and hence align refresh time with the timeslot length. Finally, let's make use of a SQL
table, version 4:
!
uacctd_group: 5
daemonize: true
plugins: mysql
aggregate: sum_host
sql_refresh_time: 300
sql_history: 5m
sql_history_roundoff: mh
sql_table_version: 4
sql_dont_try_update: true
! ...
VII. Running the pmacct IMT client (pmacct)
The 'pmacct' client tool allows to query memory tables. Messaging happens over a UNIX
pipe file: authorization is strictly connected to permissions of the pipe file. Note:
while writing queries commandline, it may happen to write chars with a special meaning
for the shell itself (ie. ; or *). Mind to either escape ( \; or \* ) them or put in
quotes ( " ).
Show all available pmacct client commandline switches:
shell> pmacct -h
Fetch data stored in the memory table:
shell> pmacct -s
Fetch data stored in the memory table using JSON output (and nicely format it with
the 'jq' tool):
shell> pmacct -s -O json | jq
Match data between source IP 192.168.0.10 and destination IP 192.168.0.3 and return
a formatted output; display all fields (-a), this way the output is easy to be parsed
by tools like awk/sed; each unused field will be zero-filled:
shell> pmacct -c src_host,dst_host -M 192.168.0.10,192.168.0.3 -a
Similar to the previous example; it is requested to reset data for matched entries;
the server will return the actual counters to the client, then will reset them:
shell> pmacct -c src_host,dst_host -M 192.168.0.10,192.168.0.3 -r
Fetch data for IP address dst_host 10.0.1.200; we also ask for a 'counter only' output
('-N') suitable, this time, for injecting data in tools like MRTG or RRDtool (sample
scripts are in the examples/ tree). Bytes counter will be returned (but the '-n' switch
allows also select which counter to display). If multiple entries match the request (ie
because the query is based on dst_host but the daemon is actually aggregating traffic
as "src_host, dst_host") their counters will be summed:
shell> pmacct -c dst_host -N 10.0.1.200
Query the memory table available via pipe file /tmp/pipe.eth0:
shell> pmacct -c sum_port -N 80 -p /tmp/pipe.eth0
Find all data matching host 192.168.84.133 as either their source or destination address.
In particular, this example shows how to use wildcards and how to spawn multiple queries
(each separated by the ';' symbol). Take care to follow the same order when specifying
the primitive name (-c) and its actual value ('-M' or '-N'):
shell> pmacct -c src_host,dst_host -N "192.168.84.133,*;*,192.168.84.133"
Find all web and smtp traffic; we are interested in have just the total of such traffic
(for example, to split legal network usage from the total); the output will be a unique
counter, sum of the partial (coming from each query) values.
shell> pmacct -c src_port,dst_port -N "25,*;*,25;80,*;*,80" -S
Show traffic between the specified hosts; this aims to be a simple example of a batch
query; note that as value of both '-N' and '-M' switches it can be supplied a value like:
'file:/home/paolo/queries.list': actual values will be read from the specified file (and
they need to be written into it, one per line) instead of commandline:
shell> pmacct -c src_host,dst_host -N "10.0.0.10,10.0.0.1;10.0.0.9,10.0.0.1;10.0.0.8,10.0.0.1"
shell> pmacct -c src_host,dst_host -N "file:/home/paolo/queries.list"
VIII. Running the RabbitMQ/AMQP plugin
The Advanced Message Queuing Protocol (AMQP) is an open standard for passing business
messages between applications. RabbitMQ is a messaging broker, an intermediary for
messaging, which implementes AMQP. pmacct RabbitMQ/AMQP plugin is designed to send
aggregated network traffic data, in JSON or Avro format, through a RabbitMQ server
to 3rd party applications (typically, but not limited to, noSQL databases like
ElasticSearch, InfluxDB, etc.). Requirements to use the plugin are:
* A working RabbitMQ server: http://www.rabbitmq.com/
* RabbitMQ C API, rabbitmq-c: https://github.com/alanxz/rabbitmq-c/
* Libjansson to cook JSON objects: http://www.digip.org/jansson/
Additionally, the Apache Avro C library (http://avro.apache.org/) needs to be
installed to be able to send messages packed using Avro (you will also need to
pass --enable-avro to the configuration script).
Once these elements are installed, pmacct can be configured for compiling. pmacct
makes use of pkg-config for finding libraries and headers location and checks some
"typical" default locations, ie. /usr/local/lib and /usr/local/include. So all
you should do is just:
shell> ./configure --enable-rabbitmq --enable-jansson
But, for example, should you have installed RabbitMQ in /usr/local/rabbitmq and
pkg-config is unable to help, you can supply this non-default location as follows
(assuming you are running the bash shell):
shell> export RABBITMQ_LIBS="-L/usr/local/rabbitmq/lib -lrabbitmq"
shell> export RABBITMQ_CFLAGS="-I/usr/local/rabbitmq/include"
shell> ./configure --enable-rabbitmq --enable-jansson
You can check further information on how to compile pmacct with JSON/libjansson
support in the section "Compiling pmacct with JSON support" of this document.
You can check further information on how to compile pmacct with Avro support in
the section "Compiling pmacct with Apache Avro support" of this document.
Then "make; make install" as usual. Following a configuration snippet showing a
basic RabbitMQ/AMQP plugin configuration (assumes: RabbitMQ server is available
at localhost; look all configurable directives up in the CONFIG-KEYS document):
! ..
plugins: amqp
!
aggregate: src_host, dst_host, src_port, dst_port, proto, tos
amqp_output: json
amqp_exchange: pmacct
amqp_routing_key: acct
amqp_refresh_time: 300
amqp_history: 5m
amqp_history_roundoff: m
! ..
pmacct will only declare a message exchange and provide a routing key, ie. it
will not get involved with queues at all. A basic consumer script, in Python,
is provided as sample to: declare a queue, bind the queue to the exchange and
show consumed data on the screen or post to a REST API. The script is located
in the pmacct default distribution tarball in 'examples/amqp/amqp_receiver.py'
and requires the 'pika' Python module installed. Should this not be available,
installation instructions are available at the following page:
http://www.rabbitmq.com/tutorials/tutorial-one-python.html
IX. Running the Kafka plugin
Apache Kafka is a distributed streaming platform. Its qualities being: fast,
scalable, durable and distributed by design. pmacct Kafka plugin is designed
to send aggregated network traffic data, in JSON or Avro format, through a
Kafka broker to 3rd party applications (typically, but not limited to, noSQL
databases like ElasticSearch, InfluxDB, etc.). Requirements to use the plugin
are: