Ubuntu Manpage: SIFTR — Statistical Information For TCP Research

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NAME

       SIFTR — Statistical Information For TCP Research

SYNOPSIS

       To load the driver as a module at run-time, run the following command as root:

             kldload siftr

       Alternatively,  to  load  the  driver  as  a  module  at  boot  time,  add  the  following  line into the
       loader.conf(5) file:

             siftr_load="YES"

DESCRIPTION

The SIFTR (Statistical Information For TCP Research) kernel module logs a range of statistics on active
TCP connections to a log file. It provides the ability to make highly granular measurements of TCP
connection state, aimed at system administrators, developers and researchers.

Compile-time Configuration
The default operation of SIFTR is to capture IPv4 TCP/IP packets. SIFTR can be configured to support
IPv4 and IPv6 by uncommenting:

CFLAGS+=-DSIFTR_IPV6

in ⟨sys/modules/siftr/Makefile⟩ and recompiling.

In the IPv4-only (default) mode, standard dotted decimal notation (e.g. "136.186.229.95") is used to
format IPv4 addresses for logging. In IPv6 mode, standard dotted decimal notation is used to format IPv4
addresses, and standard colon-separated hex notation (see RFC 4291) is used to format IPv6 addresses for
logging. Note that SIFTR uses uncompressed notation to format IPv6 addresses. For example, the address
"fe80::20f:feff:fea2:531b" would be logged as "fe80:0:0:0:20f:feff:fea2:531b".

Run-time Configuration
SIFTR utilises the sysctl(8) interface to export its configuration variables to user-space. The
following variables are available:

net.inet.siftr.enabled
controls whether the module performs its measurements or not. By default, the value
is set to 0, which means the module will not be taking any measurements. Having the
module loaded with net.inet.siftr.enabled set to 0 will have no impact on the
performance of the network stack, as the packet filtering hooks are only inserted
when net.inet.siftr.enabled is set to 1.

net.inet.siftr.ppl
controls how many inbound/outbound packets for a given TCP connection will cause a
log message to be generated for the connection. By default, the value is set to 1,
which means the module will log a message for every packet of every TCP connection.
The value can be set to any integer in the range [1,2^32], and can be changed at any
time, even while the module is enabled.

net.inet.siftr.logfile
controls the path to the file that the module writes its log messages to. By
default, the file /var/log/siftr.log is used. The path can be changed at any time,
even while the module is enabled.

net.inet.siftr.genhashes
controls whether a hash is generated for each TCP packet seen by SIFTR. By default,
the value is set to 0, which means no hashes are generated. The hashes are useful to
correlate which TCP packet triggered the generation of a particular log message, but
calculating them adds additional computational overhead into the fast path.

net.inet.siftr.port_filter
controls on which source or destination port siftr should capture SIFTR. By default,
the value is set to 0, which means all ports are eligible for logging. Set to any
other value, only packets where either the source or destination port is equal to
this number are logged.

Log Format
A typical SIFTR log file will contain 3 different types of log message. All messages are written in
plain ASCII text.

Note: The "\" present in the example log messages in this section indicates a line continuation and is
not part of the actual log message.

The first type of log message is written to the file when the module is enabled and starts collecting
data from the running kernel. The text below shows an example module enable log. The fields are tab
delimited key-value pairs which describe some basic information about the system.

enable_time_secs=1238556193 enable_time_usecs=462104 \
siftrver=1.2.2 hz=1000 tcp_rtt_scale=32 \
sysname=FreeBSD sysver=604000 ipmode=4

Field descriptions are as follows:

enable_time_secs
time at which the module was enabled, in seconds since the UNIX epoch.

enable_time_usecs
time at which the module was enabled, in microseconds since enable_time_secs.

siftrver version of SIFTR.

hz tick rate of the kernel in ticks per second.

tcp_rtt_scale
smoothed RTT estimate scaling factor.

sysname operating system name.

sysver operating system version.

ipmode IP mode as defined at compile time. An ipmode of "4" means IPv6 is not supported and
IP addresses are logged in regular dotted quad format. An ipmode of "6" means IPv6
is supported, and IP addresses are logged in dotted quad or hex format, as described
in the "Compile-time Configuration" subsection.

The second type of log message is written to the file when a data log message is generated. The text
below shows an example data log triggered by an IPv4 TCP/IP packet. The data is CSV formatted.

o,0xbec491a5,1238556193.463551,172.16.7.28,22,172.16.2.5,55931, \
1073725440,172312,6144,66560,66608,8,1,4,1448,936,1,996,255, \
33304,208,66608,0,208,0

Field descriptions are as follows:

1 Direction of packet that triggered the log message. Either "i" for in, or "o" for
out.

2 Hash of the packet that triggered the log message.

3 Time at which the packet that triggered the log message was processed by the pfil(9)
hook function, in seconds and microseconds since the UNIX epoch.

4 The IPv4 or IPv6 address of the local host, in dotted quad (IPv4 packet) or colon-
separated hex (IPv6 packet) notation.

5 The TCP port that the local host is communicating via.

6 The IPv4 or IPv6 address of the foreign host, in dotted quad (IPv4 packet) or colon-
separated hex (IPv6 packet) notation.

7 The TCP port that the foreign host is communicating via.

8 The slow start threshold for the flow, in bytes.

9 The current congestion window for the flow, in bytes.

10 The current bandwidth-controlled window for the flow, in bytes.

11 The current sending window for the flow, in bytes. The post scaled value is
reported, except during the initial handshake (first few packets), during which time
the unscaled value is reported.

12 The current receive window for the flow, in bytes. The post scaled value is always
reported.

13 The current window scaling factor for the sending window.

14 The current window scaling factor for the receiving window.

15 The current state of the TCP finite state machine, as defined in ⟨netinet/tcp_fsm.h⟩.

16 The maximum segment size for the flow, in bytes.

17 The current smoothed RTT estimate for the flow, in units of TCP_RTT_SCALE * HZ, where
TCP_RTT_SCALE is a define found in tcp_var.h, and HZ is the kernel's tick timer.
Divide by TCP_RTT_SCALE * HZ to get the RTT in secs. TCP_RTT_SCALE and HZ are
reported in the enable log message.

18 SACK enabled indicator. 1 if SACK enabled, 0 otherwise.

19 The current state of the TCP flags for the flow. See ⟨netinet/tcp_var.h⟩ for
information about the various flags.

20 The current retransmission timeout length for the flow, in units of HZ, where HZ is
the kernel's tick timer. Divide by HZ to get the timeout length in seconds. HZ is
reported in the enable log message.

21 The current size of the socket send buffer in bytes.

22 The current number of bytes in the socket send buffer.

23 The current size of the socket receive buffer in bytes.

24 The current number of bytes in the socket receive buffer.

25 The current number of unacknowledged bytes in-flight. Bytes acknowledged via SACK
are not excluded from this count.

26 The current number of segments in the reassembly queue.

27 Flowid for the connection. A caveat: Zero '0' either represents a valid flowid or a
default value when it's not being set. There is no easy way to differentiate without
looking at actual network interface card and drivers being used.

28 Flow type for the connection. Flowtype defines which protocol fields are hashed to
produce the flowid. A complete listing is available in sys/mbuf.h under
M_HASHTYPE_*.

The third type of log message is written to the file when the module is disabled and ceases collecting
data from the running kernel. The text below shows an example module disable log. The fields are tab
delimited key-value pairs which provide statistics about operations since the module was most recently
enabled.

disable_time_secs=1238556197 disable_time_usecs=933607 \
num_inbound_tcp_pkts=356 num_outbound_tcp_pkts=627 \
total_tcp_pkts=983 num_inbound_skipped_pkts_malloc=0 \
num_outbound_skipped_pkts_malloc=0 num_inbound_skipped_pkts_mtx=0 \
num_outbound_skipped_pkts_mtx=0 num_inbound_skipped_pkts_tcb=0 \
num_outbound_skipped_pkts_tcb=0 num_inbound_skipped_pkts_icb=0 \
num_outbound_skipped_pkts_icb=0 total_skipped_tcp_pkts=0 \
flow_list=172.16.7.28;22-172.16.2.5;55931,

Field descriptions are as follows:

disable_time_secs
Time at which the module was disabled, in seconds since the UNIX epoch.

disable_time_usecs
Time at which the module was disabled, in microseconds since disable_time_secs.

num_inbound_tcp_pkts
Number of TCP packets that traversed up the network stack. This only includes
inbound TCP packets during the periods when SIFTR was enabled.

num_outbound_tcp_pkts
Number of TCP packets that traversed down the network stack. This only includes
outbound TCP packets during the periods when SIFTR was enabled.

total_tcp_pkts
The summation of num_inbound_tcp_pkts and num_outbound_tcp_pkts.

num_inbound_skipped_pkts_malloc
Number of inbound packets that were not processed because of failed malloc() calls.

num_outbound_skipped_pkts_malloc
Number of outbound packets that were not processed because of failed malloc() calls.

num_inbound_skipped_pkts_mtx
Number of inbound packets that were not processed because of failure to add the
packet to the packet processing queue.

num_outbound_skipped_pkts_mtx
Number of outbound packets that were not processed because of failure to add the
packet to the packet processing queue.

num_inbound_skipped_pkts_tcb
Number of inbound packets that were not processed because of failure to find the TCP
control block associated with the packet.

num_outbound_skipped_pkts_tcb
Number of outbound packets that were not processed because of failure to find the TCP
control block associated with the packet.

num_inbound_skipped_pkts_icb
Number of inbound packets that were not processed because of failure to find the IP
control block associated with the packet.

num_outbound_skipped_pkts_icb
Number of outbound packets that were not processed because of failure to find the IP
control block associated with the packet.

total_skipped_tcp_pkts
The summation of all skipped packet counters.

flow_list A CSV list of TCP flows that triggered data log messages to be generated since the
module was loaded. Each flow entry in the CSV list is formatted as
"local_ip;local_port-foreign_ip;foreign_port". If there are no entries in the list
(i.e., no data log messages were generated), the value will be blank. If there is at
least one entry in the list, a trailing comma will always be present.

The total number of data log messages found in the log file for a module enable/disable cycle should
equate to total_tcp_pkts - total_skipped_tcp_pkts.

IMPLEMENTATION NOTES

SIFTR hooks into the network stack using the pfil(9) interface. In its current incarnation, it hooks
into the AF_INET/AF_INET6 (IPv4/IPv6) pfil(9) filtering points, which means it sees packets at the IP
layer of the network stack. This means that TCP packets inbound to the stack are intercepted before they
have been processed by the TCP layer. Packets outbound from the stack are intercepted after they have
been processed by the TCP layer.

The diagram below illustrates how SIFTR inserts itself into the stack.

----------------------------------
Upper Layers
----------------------------------
^ |
| |
| |
| v
TCP in TCP out
----------------------------------
^ |
|________ _________|
| |
| v
---------
| SIFTR |
---------
^ |
________| |__________
| |
| v
IPv{4/6} in IPv{4/6} out
----------------------------------
^ |
| |
| v
Layer 2 in Layer 2 out
----------------------------------
Physical Layer
----------------------------------

SIFTR uses the alq(9) interface to manage writing data to disk.

At first glance, you might mistakenly think that SIFTR extracts information from individual TCP packets.
This is not the case. SIFTR uses TCP packet events (inbound and outbound) for each TCP flow originating
from the system to trigger a dump of the state of the TCP control block for that flow. With the PPL set
to 1, we are in effect sampling each TCP flow's control block state as frequently as flow packets
enter/leave the system. For example, setting PPL to 2 halves the sampling rate i.e., every second flow
packet (inbound OR outbound) causes a dump of the control block state.

The distinction between interrogating individual packets versus interrogating the control block is
important, because SIFTR does not remove the need for packet capturing tools like tcpdump(1). SIFTR
allows you to correlate and observe the cause-and-affect relationship between what you see on the wire
(captured using a tool like tcpdump(1)) and changes in the TCP control block corresponding to the flow of
interest. It is therefore useful to use SIFTR and a tool like tcpdump(1) to gather the necessary data to
piece together the complete picture. Use of either tool on its own will not be able to provide all of
the necessary data.

As a result of needing to interrogate the TCP control block, certain packets during the lifecycle of a
connection are unable to trigger a SIFTR log message. The initial handshake takes place without the
existence of a control block and the final ACK is exchanged when the connection is in the TIMEWAIT state.

SIFTR was designed to minimise the delay introduced to packets traversing the network stack. This design
called for a highly optimised and minimal hook function that extracted the minimal details necessary
whilst holding the packet up, and passing these details to another thread for actual processing and
logging.

This multithreaded design does introduce some contention issues when accessing the data structure shared
between the threads of operation. When the hook function tries to place details in the structure, it
must first acquire an exclusive lock. Likewise, when the processing thread tries to read details from
the structure, it must also acquire an exclusive lock to do so. If one thread holds the lock, the other
must wait before it can obtain it. This does introduce some additional bounded delay into the kernel's
packet processing code path.

In some cases (e.g., low memory, connection termination), TCP packets that enter the SIFTR pfil(9) hook
function will not trigger a log message to be generated. SIFTR refers to this outcome as a "skipped
packet". Note that SIFTR always ensures that packets are allowed to continue through the stack, even if
they could not successfully trigger a data log message. SIFTR will therefore not introduce any packet
loss for TCP/IP packets traversing the network stack.

Important Behaviours
The behaviour of a log file path change whilst the module is enabled is as follows:

1. Attempt to open the new file path for writing. If this fails, the path change will fail and the
existing path will continue to be used.

2. Assuming the new path is valid and opened successfully:

- Flush all pending log messages to the old file path.

- Close the old file path.

- Switch the active log file pointer to point at the new file path.

- Commence logging to the new file.

During the time between the flush of pending log messages to the old file and commencing logging to the
new file, new log messages will still be generated and buffered. As soon as the new file path is ready
for writing, the accumulated log messages will be written out to the file.

EXAMPLES

       To enable the module's operations, run the following command as root: sysctl net.inet.siftr.enabled=1

       To change the granularity of log messages such that 1 log message is generated for every 10  TCP  packets
       per connection, run the following command as root: sysctl net.inet.siftr.ppl=10

       To  change  the  log  file  location  to  /tmp/siftr.log,  run  the  following  command  as  root: sysctl
       net.inet.siftr.logfile=/tmp/siftr.log

ACKNOWLEDGEMENTS

       Development of this software was made possible in part by  grants  from  the  Cisco  University  Research
       Program Fund at Community Foundation Silicon Valley, and the FreeBSD Foundation.

HISTORY

       SIFTR first appeared in FreeBSD 7.4 and FreeBSD 8.2.

       SIFTR  was  first  released  in  2007  by  Lawrence  Stewart and James Healy whilst working on the NewTCP
       research project at Swinburne University of Technology's  Centre  for  Advanced  Internet  Architectures,
       Melbourne,  Australia,  which  was  made  possible  in part by a grant from the Cisco University Research
       Program Fund at Community Foundation Silicon Valley.  More details are available at:

       http://caia.swin.edu.au/urp/newtcp/

       Work on SIFTR v1.2.x was sponsored by the FreeBSD Foundation as part of the "Enhancing  the  FreeBSD  TCP
       Implementation" project 2008-2009.  More details are available at:

       http://www.freebsdfoundation.org/

       http://caia.swin.edu.au/freebsd/etcp09/

AUTHORS

       SIFTR was written by Lawrence Stewart <lstewart@FreeBSD.org> and James Healy <jimmy@deefa.com>.

       This manual page was written by Lawrence Stewart <lstewart@FreeBSD.org>.

BUGS

Current known limitations and any relevant workarounds are outlined below:

- The internal queue used to pass information between the threads of operation is currently unbounded.
This allows SIFTR to cope with bursty network traffic, but sustained high packet-per-second traffic
can cause exhaustion of kernel memory if the processing thread cannot keep up with the packet rate.

- If using SIFTR on a machine that is also running other modules utilising the pfil(9) framework e.g.
dummynet(4), ipfw(8), pf(4), the order in which you load the modules is important. You should
kldload the other modules first, as this will ensure TCP packets undergo any necessary manipulations
before SIFTR "sees" and processes them.

- There is a known, harmless lock order reversal warning between the pfil(9) mutex and tcbinfo TCP lock
reported by witness(4) when SIFTR is enabled in a kernel compiled with witness(4) support.

- There is no way to filter which TCP flows you wish to capture data for. Post processing is required
to separate out data belonging to particular flows of interest.

- The module does not detect deletion of the log file path. New log messages will simply be lost if
the log file being used by SIFTR is deleted whilst the module is set to use the file. Switching to a
new log file using the net.inet.siftr.logfile variable will create the new file and allow log
messages to begin being written to disk again. The new log file path must differ from the path to
the deleted file.

- The hash table used within the code is sized to hold 65536 flows. This is not a hard limit, because
chaining is used to handle collisions within the hash table structure. However, we suspect (based on
analogies with other hash table performance data) that the hash table look up performance (and
therefore the module's packet processing performance) will degrade in an exponential manner as the
number of unique flows handled in a module enable/disable cycle approaches and surpasses 65536.

- There is no garbage collection performed on the flow hash table. The only way currently to flush it
is to disable SIFTR.

- The PPL variable applies to packets that make it into the processing thread, not total packets
received in the hook function. Packets are skipped before the PPL variable is applied, which means
there may be a slight discrepancy in the triggering of log messages. For example, if PPL was set to
10, and the 8th packet since the last log message is skipped, the 11th packet will actually trigger
the log message to be generated. This is discussed in greater depth in CAIA technical report
070824A.

- At the time of writing, there was no simple way to hook into the TCP layer to intercept packets.
SIFTR's use of IP layer hook points means all IP traffic will be processed by the SIFTR pfil(9) hook
function, which introduces minor, but nonetheless unnecessary packet delay and processing overhead on
the system for non-TCP packets as well. Hooking in at the IP layer is also not ideal from the data
gathering point of view. Packets traversing up the stack will be intercepted and cause a log message
generation BEFORE they have been processed by the TCP layer, which means we cannot observe the cause-
and-affect relationship between inbound events and the corresponding TCP control block as precisely
as could be. Ideally, SIFTR should intercept packets after they have been processed by the TCP layer
i.e. intercept packets coming up the stack after they have been processed by tcp_input(), and
intercept packets coming down the stack after they have been processed by tcp_output(). The current
code still gives satisfactory granularity though, as inbound events tend to trigger outbound events,
allowing the cause-and-effect to be observed indirectly by capturing the state on outbound events as
well.

- The "inflight bytes" value logged by SIFTR does not take into account bytes that have been SACK'ed by
the receiving host.

- Packet hash generation does not currently work for IPv6 based TCP packets.

- Compressed notation is not used for IPv6 address representation. This consumes more bytes than is
necessary in log output.

Debian October 7, 2019 SIFTR(4)

NAME

SYNOPSIS

DESCRIPTION

IMPLEMENTATION NOTES

EXAMPLES

SEE ALSO

ACKNOWLEDGEMENTS

HISTORY

AUTHORS

BUGS