This document provides methodologies for the performance benchmarking
of firewalls. It covers four areas: forwarding, connection, latency
and filtering. In addition to defining tests, this document also
describes specific formats for reporting test results.
A previous document, "Benchmarking Terminology for Firewall
Performance" [1], defines many of the terms that are used in this
document. The terminology document SHOULD be consulted before
attempting to make use of this document.
In this document, the words that are used to define the significance
of each particular requirement are capitalized. These words are:
* "MUST" This word, or the words "REQUIRED" and "SHALL" mean that
the item is an absolute requirement of the specification.
* "SHOULD" This word or the adjective "RECOMMENDED" means that there
may exist valid reasons in particular circumstances to ignore this
item, but the full implications should be understood and the case
carefully weighed before choosing a different course.
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* "MAY" This word or the adjective "OPTIONAL" means that this item
is truly optional. One vendor may choose to include the item
because a particular marketplace requires it or because it
enhances the product, for example; another vendor may omit the
same item.
An implementation is not compliant if it fails to satisfy one or more
of the MUST requirements. An implementation that satisfies all the
MUST and all the SHOULD requirements is said to be "unconditionally
compliant"; one that satisfies all the MUST requirements but not all
the SHOULD requirements is said to be "conditionally compliant".
Firewalls can control access between networks. Usually, a firewall
protects a private network from public or shared network(s) to which
it is connected. A firewall can be as simple as a single device that
filters packets or as complex as a group of devices that combine
packet filtering and application-level proxy and network translation
services. This document focuses on benchmarking firewall
performance, wherever possible, independent of implementation.
Test configurations defined in this document will be confined to
dual-homed and tri-homed as shown in figure 1 and figure 2
respectively.
Firewalls employing dual-homed configurations connect two networks.
One interface of the firewall is attached to the unprotected network
[1], typically the public network (Internet). The other interface is
connected to the protected network [1], typically the internal LAN.
In the case of dual-homed configurations, servers which are made
accessible to the public (Unprotected) network are attached to the
private (Protected) network.
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+----------+ +----------+
| | | +----------+ | | |
| Servers/ |----| | | |------| Servers/ |
| Clients | | | | | | Clients |
| | |-------| DUT/SUT |--------| | |
+----------+ | | | | +----------+
Protected | +----------+ | Unprotected
Network | | Network
Figure 1 (Dual-Homed)
Tri-homed [1] configurations employ a third segment called a
Demilitarized Zone (DMZ). With tri-homed configurations, servers
accessible to the public network are attached to the DMZ. Tri-Homed
configurations offer additional security by separating server(s)
accessible to the public network from internal hosts.
+----------+ +----------+
| | | +----------+ | | |
| Clients |----| | | |------| Servers/ |
| | | | | | | Clients |
+----------+ |-------| DUT/SUT |--------| | |
| | | | +----------+
| +----------+ |
Protected | | | Unprotected
Network | Network
|
-----------------
| DMZ
|
|
+-----------+
| |
| Servers |
| |
+-----------+
Figure 2 (Tri-Homed)
Since firewall testing may involve data sources which emulate
multiple users or hosts, the methodology uses the terms virtual
clients/servers. For these firewall tests, virtual clients/servers
specify application layer entities which may not be associated with a
unique physical interface. For example, four virtual clients may
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originate from the same data source [1]. The test report MUST
indicate the number of virtual clients and virtual servers
participating in the test.
While the function of a firewall is to enforce access control
policies, the criteria by which those policies are defined vary
depending on the implementation. Firewalls may use network layer,
transport layer or, in many cases, application-layer criteria to make
access-control decisions.
For the purposes of benchmarking firewall performance, this document
references HTTP 1.1 or higher as the application layer entity. The
methodologies MAY be used as a template for benchmarking with other
applications. Since testing may involve proxy based DUT/SUTs, HTTP
version considerations are discussed in appendix A.
Since the number of interfaces are not fixed, the traffic flows will
be dependent upon the configuration used in benchmarking the DUT/SUT.
Note that the term "traffic flows" is associated with client-to-
server requests.
For Dual-Homed configurations, there are two unique traffic flows:
Client Server
------ ------
Protected -> Unprotected
Unprotected -> Protected
For Tri-Homed configurations, there are three unique traffic flows:
Client Server
------ ------
Protected -> Unprotected
Protected -> DMZ
Unprotected -> DMZ
One or more clients may target multiple servers for a given
application. Each virtual client MUST initiate connections in a
round-robin fashion. For example, if the test consisted of six
virtual clients targeting three servers, the pattern would be as
follows:
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Client Target Server (In order of request)
#1 1 2 3 1...
#2 2 3 1 2...
#3 3 1 2 3...
#4 1 2 3 1...
#5 2 3 1 2...
#6 3 1 2 3...
Many firewalls implement network address translation (NAT) [1], a
function which translates private internet addresses to public
internet addresses. This involves additional processing on the part
of the DUT/SUT and may impact performance. Therefore, tests SHOULD
be ran with NAT disabled and NAT enabled to determine the performance
differential, if any. The test report MUST indicate whether NAT was
enabled or disabled.
Rule sets [1] are a collection of access control policies that
determine which packets the DUT/SUT will forward and which it will
reject [1]. Since criteria by which these access control policies
may be defined will vary depending on the capabilities of the
DUT/SUT, the following is limited to providing guidelines for
configuring rule sets when benchmarking the performance of the
DUT/SUT.
It is RECOMMENDED that a rule be entered for each host (Virtual
client). In addition, testing SHOULD be performed using different
size rule sets to determine its impact on the performance of the
DUT/SUT. Rule sets MUST be configured in a manner, such that, rules
associated with actual test traffic are configured at the end of the
rule set and not at the beginning.
The DUT/SUT SHOULD be configured to deny access to all traffic which
was not previously defined in the rule set. The test report SHOULD
include the DUT/SUT configured rule set(s).
Some firewalls include caching agents to reduce network load. When
making a request through a caching agent, the caching agent attempts
to service the response from its internal memory. The cache itself
saves responses it receives, such as responses for HTTP GET requests.
Testing SHOULD be performed with any caching agents on the DUT/SUT
disabled.
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Access control may involve authentication processes such as user,
client or session authentication. Authentication is usually
performed by devices external to the firewall itself, such as an
authentication server(s) and may add to the latency of the system.
Any authentication processes MUST be included as part of connection
setup process.
Some test instruments allow configuration of one or more TCP stack
parameters, thereby influencing the traffic flows which will be
offered and impacting performance measurements. While this document
does not attempt to specify which TCP parameters should be
configurable, any such TCP parameter(s) MUST be noted in the test
report. In addition, when comparing multiple DUT/SUTs, the same TCP
parameters MUST be used.
To determine the throughput of network-layer data traversing the
DUT/SUT, as defined in RFC 1242 [3]. Note that while RFC 1242 uses
the term frames, which is associated with the link layer, the
procedure uses the term packets, since it is referencing the network
layer.
The following parameters MUST be defined:
Packet size - Number of bytes in the IP packet, exclusive of any
link layer header or checksums.
Test Duration - Duration of the test, expressed in seconds.
The test instrument MUST offer unicast IP packets to the DUT/SUT at a
constant rate. The test MAY consist of either bi-directional or
unidirectional traffic; for example, an emulated client may offer a
unicast stream of packets to an emulated server, or the test
instrument may simulate a client/server exchange by offering
bidirectional traffic.
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This test will employ an iterative search algorithm. Each iteration
will involve the test instrument varying the intended load until the
maximum rate, at which no packet loss occurs, is found. Since
backpressure mechanisms may be employed, resulting in the intended
load and offered load being different, the test SHOULD be performed
in either a packet based or time based manner as described in RFC
2889 [5]. As with RFC 1242, the term packet is used in place of
frame. The duration of the test portion of each trial MUST be at
least 30 seconds.
It is RECOMMENDED to perform the throughput measurements with
different packet sizes. When testing with different packet sizes the
DUT/SUT configuration MUST remain the same.
Throughput:
Maximum offered load, expressed in either bits per second or
packets per second, at which no packet loss is detected. The bits
to be counted are in the IP packet (header plus payload); other
fields, such as link-layer headers and trailers, MUST NOT be
included in the measurement.
Forwarding Rate:
Forwarding rate, expressed in either bits per second or packets
per second, the device is observed to successfully forward to the
correct destination interface in response to a specified offered
load. The bits to be counted are in the IP packet (header plus
payload); other fields, such as link-layer headers and trailers,
MUST NOT be included in the measurement.
The test report MUST note the packet size(s), test duration,
throughput and forwarding rate. In addition, the test report MUST
conform to the reporting requirements set in section 4, Test Setup.
If the test involved offering packets which target more than one
segment (Protected, Unprotected or DMZ), the report MUST identify the
results as an aggregate throughput measurement.
The throughput results SHOULD be reported in the format of a table
with a row for each of the tested packet sizes. There SHOULD be
columns for the packet size, the intended load, the offered load,
resultant throughput and forwarding rate for each test.
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The intermediate results of the search algorithm MAY be saved in log
file which includes the packet size, test duration and for each
iteration:
- Step Iteration
- Pass/Fail Status
- Total packets offered
- Total packets forwarded
- Intended load
- Offered load (If applicable)
- Forwarding rate
To determine the maximum number of concurrent TCP connections
supported through or with the DUT/SUT, as defined in RFC 2647 [1].
This test is intended to find the maximum number of entries the
DUT/SUT can store in its connection table.
Connection Attempt Rate:
The aggregate rate, expressed in connections per second, at which
TCP connection requests are attempted. The rate SHOULD be set at
or lower than the maximum rate at which the DUT/SUT can accept
connection requests.
Aging Time:
The time, expressed in seconds, the DUT/SUT will keep a connection
in its connection table after receiving a TCP FIN or RST packet.
Validation Method:
HTTP 1.1 or higher MUST be used for this test for both clients and
servers. The client and server MUST use the same HTTP version.
Object Size:
Defines the number of bytes, excluding any bytes associated with
the HTTP header, to be transferred in response to an HTTP 1.1 or
higher GET request.
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This test will employ an iterative search algorithm to determine the
maximum number of concurrent TCP connections supported through or
with the DUT/SUT.
For each iteration, the aggregate number of concurrent TCP
connections attempted by the virtual client(s) will be varied. The
destination address will be that of the server or that of the NAT
proxy. The aggregate rate will be defined by connection attempt
rate, and will be attempted in a round-robin fashion (See 4.5).
To validate all connections, the virtual client(s) MUST request an
object using an HTTP 1.1 or higher GET request. The requests MUST be
initiated on each connection after all of the TCP connections have
been established.
When testing proxy-based DUT/SUTs, the virtual client(s) MUST request
two objects using HTTP 1.1 or higher GET requests. The first GET
request is required for connection time establishment [1]
measurements as specified in appendix B. The second request is used
for validation as previously mentioned. When comparing proxy and
non-proxy based DUT/SUTs, the test MUST be performed in the same
manner.
Between each iteration, it is RECOMMENDED that the test instrument
issue a TCP RST referencing each connection attempted for the
previous iteration, regardless of whether or not the connection
attempt was successful. The test instrument will wait for aging time
before continuing to the next iteration.
Maximum concurrent connections:
Total number of TCP connections open for the last successful
iteration performed in the search algorithm.
Minimum connection establishment time:
Lowest TCP connection establishment time measured, as defined in
appendix B.
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Maximum connection establishment time:
Highest TCP connection establishment time measured, as defined in
appendix B.
Average connection establishment time:
The mean of all measurements of connection establishment times.
Aggregate connection establishment time:
The total of all measurements of connection establishment times.
The test report MUST note the object size, number of completed
requests and number of completed responses.
The intermediate results of the search algorithm MAY be reported in a
tabular format with a column for each iteration. There SHOULD be
rows for the number of requests attempted, number and percentage
requests completed, number of responses attempted, number and
percentage of responses completed. The table MAY be combined with
the transport-layer reporting, provided that the table identify this
as an application layer measurement.
Version information:
The test report MUST note the version of HTTP client(s) and
server(s).
The test report MUST note the connection attempt rate, aging time,
minimum TCP connection establishment time, maximum TCP connection
establishment time, average connection establishment time, aggregate
connection establishment time and maximum concurrent connections
measured.
The intermediate results of the search algorithm MAY be reported in
the format of a table with a column for each iteration. There SHOULD
be rows for the total number of TCP connections attempted, number and
percentage of TCP connections completed, minimum TCP connection
establishment time, maximum TCP connection establishment time,
average connection establishment time and the aggregate connection
establishment time.
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To determine the maximum TCP connection establishment rate through or
with the DUT/SUT, as defined by RFC 2647 [1]. This test is intended
to find the maximum rate the DUT/SUT can update its connection table.
Number of Connections:
Defines the aggregate number of TCP connections that must be
established.
Aging Time:
The time, expressed in seconds, the DUT/SUT will keep a connection
in it's state table after receiving a TCP FIN or RST packet.
Validation Method:
HTTP 1.1 or higher MUST be used for this test for both clients and
servers. The client and server MUST use the same HTTP version.
Object Size:
Defines the number of bytes, excluding any bytes associated with
the HTTP header, to be transferred in response to an HTTP 1.1 or
higher GET request.
This test will employ an iterative search algorithm to determine the
maximum rate at which the DUT/SUT can accept TCP connection requests.
For each iteration, the aggregate rate at which TCP connection
requests are attempted by the virtual client(s) will be varied. The
destination address will be that of the server or that of the NAT
proxy. The aggregate number of connections, defined by number of
connections, will be attempted in a round-robin fashion (See 4.5).
The same application-layer object transfers required for validation
and establishment time measurements as described in the concurrent
TCP connection capacity test MUST be performed.
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Between each iteration, it is RECOMMENDED that the test instrument
issue a TCP RST referencing each connection attempted for the
previous iteration, regardless of whether or not the connection
attempt was successful. The test instrument will wait for aging time
before continuing to the next iteration.
Highest connection rate:
Highest rate, in connections per second, for which all connections
successfully opened in the search algorithm.
Minimum connection establishment time:
Lowest TCP connection establishment time measured, as defined in
appendix B.
Maximum connection establishment time:
Highest TCP connection establishment time measured, as defined in
appendix B.
Average connection establishment time:
The mean of all measurements of connection establishment times.
Aggregate connection establishment time:
The total of all measurements of connection establishment times.
The test report MUST note object size(s), number of completed
requests and number of completed responses.
The intermediate results of the search algorithm MAY be reported in a
tabular format with a column for each iteration. There SHOULD be
rows for the number of requests attempted, number and percentage
requests completed, number of responses attempted, number and
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percentage of responses completed. The table MAY be combined with
the transport-layer reporting, provided that the table identify this
as an application layer measurement.
Version information:
The test report MUST note the version of HTTP client(s) and
server(s).
The test report MUST note the number of connections, aging time,
minimum TCP connection establishment time, maximum TCP connection
establishment time, average connection establishment time, aggregate
connection establishment time and highest connection rate measured.
The intermediate results of the search algorithm MAY be reported in
the format of a table with a column for each iteration. There SHOULD
be rows for the connection attempt rate, total number of TCP
connections attempted, total number of TCP connections completed,
minimum TCP connection establishment time, maximum TCP connection
establishment time, average connection establishment time and the
aggregate connection establishment time.
Number of Connections:
Defines the number of TCP connections that will be attempted to be
torn down.
Aging Time:
The time, expressed in seconds, the DUT/SUT will keep a connection
in it's state table after receiving a TCP FIN or RST packet.
Close Method:
Defines method for closing TCP connections. The test MUST be
performed with either a three-way or four-way handshake. In a
four-way handshake, each side sends separate FIN and ACK messages.
In a three-way handshake, one side sends a combined FIN/ACK
message upon receipt of a FIN.
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Close Direction:
Defines whether closing of connections are to be initiated from
the client or from the server.
This test will employ an iterative search algorithm to determine the
maximum TCP connection tear down rate supported by the DUT/SUT. The
test iterates through different TCP connection tear down rates with a
fixed number of TCP connections.
In the case of proxy based DUT/SUTs, the DUT/SUT will itself receive
the ACK in response to issuing a FIN packet to close its side of the
TCP connection. For validation purposes, the virtual client or
server, whichever is applicable, MAY verify that the DUT/SUT received
the final ACK by re-transmitting the final ACK. A TCP RST should be
received in response to the retransmitted ACK.
Between each iteration, it is RECOMMENDED that the virtual client(s)
or server(s), whichever is applicable, issue a TCP RST referencing
each connection which was attempted to be torn down, regardless of
whether or not the connection tear down attempt was successful. The
test will wait for aging time before continuing to the next
iteration.
Highest connection tear down rate:
Highest rate, in connections per second, for which all TCP
connections were successfully torn down in the search algorithm.
The following tear down time [1] measurements MUST only include
connections for which both sides of the connection were successfully
torn down. For example, tear down times for connections which are
left in a FINWAIT-2 [8] state should not be included:
Minimum connection tear down time:
Lowest TCP connection tear down time measured as defined in
appendix C.
Maximum connection tear down time:
Highest TCP connection tear down time measured as defined in
appendix C.
Average connection tear down time:
The mean of all measurements of connection tear down times.
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Aggregate connection tear down time:
The total of all measurements of connection tear down times.
The test report MUST note the number of connections, aging time,
close method, close direction, minimum TCP connection tear down time,
maximum TCP connection tear down time, average TCP connection tear
down time and the aggregate TCP connection tear down time and highest
connection tear down rate measured. In addition, the test report MUST
conform to the reporting requirements set in section 4, Test Setup.
The intermediate results of the search algorithm MAY be reported in
the format of a table with a column for each iteration. There SHOULD
be rows for the number of TCP tear downs attempted, number and
percentage of TCP connection tear downs completed, minimum TCP
connection tear down time, maximum TCP connection tear down time,
average TCP connection tear down time, aggregate TCP connection tear
down time and validation failures, if required.
To determine the effect of a denial of service attack on a DUT/SUT
TCP connection establishment and/or HTTP transfer rates. The denial
of service handling test MUST be run after obtaining baseline
measurements from sections 5.3 and/or 5.6.
The TCP SYN flood attack exploits TCP's three-way handshake mechanism
by having an attacking source host generate TCP SYN packets with
random source addresses towards a victim host, thereby consuming that
host's resources.
Use the same setup parameters as defined in section 5.3.2 or 5.6.2,
depending on whether testing against the baseline TCP connection
establishment rate test or HTTP transfer rate test, respectfully.
In addition, the following setup parameters MUST be defined:
SYN attack rate:
Rate, expressed in packets per second, at which the server(s) or
NAT proxy address is targeted with TCP SYN packets.
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Use the same procedure as defined in section 5.3.3 or 5.6.3,
depending on whether testing against the baseline TCP connection
establishment rate or HTTP transfer rate test, respectfully. In
addition, the test instrument will generate TCP SYN packets targeting
the server(s) IP address or NAT proxy address at a rate defined by
SYN attack rate.
The test instrument originating the TCP SYN attack MUST be attached
to the unprotected network. In addition, the test instrument MUST
not respond to the SYN/ACK packets sent by target server or NAT proxy
in response to the SYN packet.
Some firewalls employ mechanisms to guard against SYN attacks. If
such mechanisms exist on the DUT/SUT, tests SHOULD be run with these
mechanisms enabled and disabled to determine how well the DUT/SUT can
maintain, under such attacks, the baseline connection establishment
rates and HTTP transfer rates determined in section 5.3 and section
5.6, respectively.
Perform the same measurements as defined in section 5.3.4 or 5.6.4,
depending on whether testing against the baseline TCP connection
establishment rate test or HTTP transfer rate, respectfully.
In addition, the test instrument SHOULD track TCP SYN packets
associated with the SYN attack which the DUT/SUT forwards on the
protected or DMZ interface(s).
The test SHOULD use the same reporting format as described in section
5.3.5 or 5.6.5, depending on whether testing against the baseline TCP
connection establishment rate test or HTTP transfer rate,
respectfully.
In addition, the report MUST indicate a denial of service handling
test, SYN attack rate, number of TCP SYN attack packets transmitted
and the number of TCP SYN attack packets forwarded by the DUT/SUT.
The report MUST indicate whether or not the DUT has any SYN attack
mechanisms enabled.
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Number of connections:
Defines the aggregate number of connections attempted. The number
SHOULD be a multiple of the number of virtual clients
participating in the test.
Close Method:
Defines the method for closing TCP connections. The test MUST be
performed with either a three-way or four-way handshake. In a
four-way handshake, each side sends separate FIN and ACK messages.
In a three-way handshake, one side sends a combined FIN/ACK
message upon receipt of a FIN.
Close Direction:
Defines whether closing of connections are to be initiated from
the client or from the server.
Session Type:
The virtual clients/servers MUST use HTTP 1.1 or higher. The
client and server MUST use the same HTTP version.
GET requests per connection:
Defines the number of HTTP 1.1 or higher GET requests attempted
per connection.
Object Size:
Defines the number of bytes, excluding any bytes associated with
the HTTP header, to be transferred in response to an HTTP 1.1 or
higher GET request.
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Each HTTP 1.1 or higher virtual client will request one or more
objects from an HTTP 1.1 or higher server using one or more HTTP GET
requests over each connection. The aggregate number of connections
attempted, defined by number of connections, MUST be evenly divided
among all of the participating virtual clients.
If the virtual client(s) make multiple HTTP GET requests per
connection, it MUST request the same object size for each GET
request. Multiple iterations of this test may be run with objects of
different sizes.
Average Transfer Rate :
The average transfer rate of the DUT/SUT MUST be measured and
shall be referenced to the requested object(s). The measurement
will start on transmission of the first bit of the first requested
object and end on transmission of the last bit of the last
requested object. The average transfer rate, in bits per second,
will be calculated using the following formula:
OBJECTS * OBJECTSIZE * 8
TRANSFER RATE (bit/s) = --------------------------
DURATION
OBJECTS - Total number of objects successfully transferred across
all connections.
OBJECTSIZE - Object size in bytes
DURATION - Aggregate transfer time based on aforementioned time
references.
The following measurements SHOULD be performed for each connection-
oriented protocol:
Goodput [1]:
Goodput as defined in section 3.17 of RFC 2647. Measurements MUST
only reference the protocol payload, excluding any of the protocol
header. In addition, the test instrument MUST exclude any bits
associated with the connection establishment, connection tear
down, security associations [1] or connection maintenance [1].
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Since connection-oriented protocols require that data be
acknowledged, the offered load [4] will be varying. Therefore,
the test instrument should measure the average forwarding rate
over the duration of the test. Measurement should start on
transmission of the first bit of the payload of the first datagram
and end on transmission of the last bit of the payload of the last
datagram.
Number of bytes transferred - Total payload bytes transferred.
Number of Timeouts - Total number of timeout events.
Retransmitted bytes - Total number of retransmitted bytes.
The test report MUST note number of GET requests per connection and
object size(s).
The transfer rate results SHOULD be reported in tabular form with a
column for each of the object sizes tested. There SHOULD be a row
for the number and percentage of completed requests, number and
percentage of completed responses, and the resultant transfer rate
for each iteration of the test.
Failure analysis:
The test report SHOULD indicate the number and percentage of HTTP
GET request and responses that failed to complete.
Version information:
The test report MUST note the version of HTTP client(s) and
server(s).
The test report MUST note the number of connections, close method,
close direction and the protocol for which the measurement was made.
The results SHOULD be reported in tabular form for each of the HTTP
object sizes tested. There SHOULD be a row for the total bytes
transferred, total timeouts, total retransmitted bytes and and
resultant goodput. Note that total bytes refers to total datagram
payload bytes transferred. The table MAY be combined with the
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application layer reporting, provided the table clearly identifies
the protocol for which the measurement was made.
Failure analysis:
The test report SHOULD indicate the number and percentage of
connection establishment failures as well as number and percentage
of TCP tear down failures.
It is RECOMMENDED that the report include a graph to plot the
distribution of both connection establishment failures and connection
tear down failures. The x coordinate SHOULD be the elapsed test
time, the y coordinate SHOULD be the number of failures for a given
sampling period. There SHOULD be two lines on the graph, one for
connection failures and one for tear down failures. The graph MUST
note the sampling period.
Close Method:
Defines method for closing TCP connections. The test MUST be
performed with either a three-way or four-way handshake. In a
four-way handshake, each side sends separate FIN and ACK messages.
In a three-way handshake, one side sends a combined FIN/ACK
message upon receipt of a FIN.
Close Direction:
Defines whether closing of connections are to be initiated from
the client or from the server.
Session Type:
HTTP 1.1 or higher MUST be used for this test. The client and
server MUST use the same HTTP version.
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Test Duration:
Time, expressed in seconds, for which the virtual client(s) will
sustain the attempted GET request rate. It is RECOMMENDED that
the duration be at least 30 seconds.
Requests per connection:
Number of object requests per connection.
Object Size:
Defines the number of bytes, excluding any bytes associated with
the HTTP header, to be transferred in response to an HTTP 1.1 or
higher GET request.
This test will employ an iterative search algorithm to determine the
maximum transaction rate that the DUT/SUT can sustain.
For each iteration, HTTP 1.1 or higher virtual client(s) will vary
the aggregate GET request rate offered to HTTP 1.1 or higher
server(s). The virtual client(s) will maintain the offered request
rate for the defined test duration.
If the virtual client(s) make multiple HTTP GET requests per
connection, it MUST request the same object size for each GET
request. Multiple tests MAY be performed with different object
sizes.
Maximum Transaction Rate:
The maximum rate at which all transactions, that is all
requests/responses cycles, are completed.
Transaction Time:
The test instrument SHOULD measure minimum, maximum and average
transaction times. The transaction time will start when the
virtual client issues the GET request and end when the requesting
virtual client receives the last bit of the requested object.
The test report MUST conform to the reporting requirements set in
section 4, Test Setup.
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The test report MUST note the test duration, object size, requests
per connection, minimum transaction time, maximum transaction time,
average transaction time and maximum transaction rate measured
The intermediate results of the search algorithm MAY be reported in a
table format with a column for each iteration. There SHOULD be rows
for the GET request attempt rate, number of requests attempted,
number and percentage of requests completed, number of responses
attempted, number and percentage of responses completed, minimum
transaction time, average transaction time and maximum transaction
time.
Version information:
The test report MUST note the version of HTTP client(s) and
server(s).
The test report MUST note the close method, close direction, number
of connections established and number of connections torn down.
The intermediate results of the search algorithm MAY be reported in a
table format with a column for each iteration. There SHOULD be rows
for the number of connections attempted, number and percentage of
connections completed, number and percentage of connection tear downs
completed. The table MAY be combined with the application layer
reporting, provided the table identify this as transport layer
measurement.
To characterize the behavior of the DUT/SUT when presented with a
combination of both legal and Illegal [1] traffic. Note that Illegal
traffic does not refer to an attack, but traffic which has been
explicitly defined by a rule(s) to drop.
Setup parameters will use the same parameters as specified in the
HTTP transfer rate test (Section 5.6.2). In addition, the following
setup parameters MUST be defined:
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Illegal traffic percentage:
Percentage of HTTP 1.1 or higher connections which have been
explicitly defined in a rule(s) to drop.
Each HTTP 1.1 or higher client will request one or more objects from
an HTTP 1.1 or higher server using one or more HTTP GET requests over
each connection. The aggregate number of connections attempted,
defined by number of connections, MUST be evenly divided among all of
the participating virtual clients.
The virtual client(s) MUST offer the connection requests, both legal
and illegal, in an evenly distributed manner. Many firewalls have
the capability to filter on different traffic criteria (IP addresses,
Port numbers, etc.). Multiple iterations of this test MAY be run
with the DUT/SUT configured to filter on different traffic criteria.
The same measurements as defined in HTTP transfer rate test (Section
5.6.4) SHOULD be performed. Any forwarding rate measurements MUST
only include bits which are associated with legal traffic.
Test reporting format SHOULD be the same as specified in the HTTP
transfer rate test (Section 5.6.5).
In addition, the report MUST note the percentage of illegal HTTP
connections.
Failure analysis:
Test report MUST note the number and percentage of illegal
connections that were allowed by the DUT/SUT.
To determine the performance impact when the DUT/SUT is presented
with IP fragmented traffic. IP packets which have been fragmented,
due to crossing a network that supports a smaller MTU (Maximum
Transmission Unit) than the actual IP packet, may require the
firewall to perform re-assembly prior to the rule set being applied.
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While IP fragmentation is a common form of attack, either on the
firewall itself or on internal hosts, this test will focus on
determining how the additional processing associated with the re-
assembly of the packets have on the forwarding rate of the DUT/SUT.
RFC 1858 addresses some fragmentation attacks that get around IP
filtering processes used in routers and hosts.
Packet size:
Number of bytes in the IP/UDP packet, exclusive of link-layer
headers and checksums, prior to fragmentation.
MTU:
Maximum transmission unit, expressed in bytes. For testing
purposes, this MAY be configured to values smaller than the MTU
supported by the link layer.
Intended Load:
Intended load, expressed as percentage of media utilization.
Each HTTP 1.1 or higher client will request one or more objects from
an HTTP 1.1 or higher server using one or more HTTP GET requests over
each connection. The aggregate number of connections attempted,
defined by number of connections, MUST be evenly divided among all of
the participating virtual clients. If the virtual client(s) make
multiple HTTP GET requests per connection, it MUST request the same
object size for each GET request.
A test instrument attached to the unprotected side of the network,
will offer a unidirectional stream of unicast fragmented IP/UDP
traffic, targeting a server attached to either the protected or DMZ
segment. The test instrument MUST offer the unidirectional stream
over the duration of the test, that is, duration over which the HTTP
traffic is being offered.
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Baseline measurements SHOULD be performed with IP filtering deny
rule(s) to filter fragmented traffic. If the DUT/SUT has logging
capability, the log SHOULD be checked to determine if it contains the
correct information regarding the fragmented traffic.
The test SHOULD be repeated with the DUT/SUT rule set changed to
allow the fragmented traffic through. When running multiple
iterations of the test, it is RECOMMENDED to vary the MTU while
keeping all other parameters constant.
Then setup the DUT/SUT to the policy or rule set the manufacturer
required to be defined to protect against fragmentation attacks and
repeat the measurements outlined in the baseline procedures.
Test instrument SHOULD perform the same measurements as defined in
HTTP test (Section 5.6.4).
Transmitted UDP/IP Packets:
Number of UDP packets transmitted by client.
Received UDP/IP Packets:
Number of UDP/IP Packets received by server.
The test report SHOULD be the same as described in section 5.6.5.
Note that any forwarding rate measurements for the HTTP traffic
excludes any bits associated with the fragmented traffic which may be
forward by the DUT/SUT.
The test report MUST note the packet size, MTU size, intended load,
number of UDP/IP packets transmitted and number of UDP/IP packets
forwarded. The test report SHOULD also note whether or not the
DUT/SUT forwarded the offered UDP/IP traffic fragmented.
To determine the latency of network-layer or application-layer data
traversing the DUT/SUT. RFC 1242 [3] defines latency.
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Packet size, expressed as the number of bytes in the IP packet,
exclusive of link-layer headers and checksums.
Intended load, expressed as percentage of media utilization.
Test duration, expressed in seconds.
The test instruments MUST generate packets with unique timestamp
signatures.
Object Size:
Defines the number of bytes, excluding any bytes associated with
the HTTP header, to be transferred in response to an HTTP 1.1 or
higher GET request. The minimum object size supported by the
media SHOULD be used, but other object sizes MAY be used as well.
Connection type:
The test instrument MUST use one HTTP 1.1 or higher connection for
latency measurements.
Number of objects requested.
Number of objects transferred.
Test duration, expressed in seconds.
Test instruments MUST generate packets with unique timestamp
signatures.
A client will offer a unidirectional stream of unicast packets to a
server. The packets MUST use a connectionless protocol like IP or
UDP/IP.
The test instrument MUST offer packets in a steady state. As noted
in the latency discussion in RFC 2544 [2], latency measurements MUST
be taken at the throughput level, that is, at the highest offered
load with zero packet loss. Measurements taken at the throughput
level are the only ones that can legitimately be termed latency.
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It is RECOMMENDED that implementers use offered loads not only at the
throughput level, but also at load levels that are less than or
greater than the throughput level. To avoid confusion with existing
terminology, measurements from such tests MUST be labeled as delay
rather than latency.
It is RECOMMENDED to perform the latency measurements with different
packet sizes. When testing with different packet sizes the DUT/SUT
configuration MUST remain the same.
If desired, a step test MAY be used in which offered loads increment
or decrement through a range of load levels.
The duration of the test portion of each trial MUST be at least 30
seconds.
An HTTP 1.1 or higher client will request one or more objects from an
HTTP 1.1 or higher server using one or more HTTP GET requests. If
the test instrument makes multiple HTTP GET requests, it MUST request
the same-sized object each time. Multiple iterations of this test
may be performed with objects of different sizes.
Implementers MAY configure the test instrument to run for a fixed
duration. In this case, the test instrument MUST report the number
of objects requested and returned for the duration of the test. For
fixed-duration tests it is RECOMMENDED that the duration be at least
30 seconds.
Minimum delay:
The smallest delay incurred by data traversing the DUT/SUT at the
network layer or application layer, as appropriate.
Maximum delay:
The largest delay incurred by data traversing the DUT/SUT at the
network layer or application layer, as appropriate.
Average delay:
The mean of all measurements of delay incurred by data traversing
the DUT/SUT at the network layer or application layer, as
appropriate.
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Delay distribution:
A set of histograms of all delay measurements observed for data
traversing the DUT/SUT at the network layer or application layer,
as appropriate.
The test report MUST note the packet size(s), offered load(s) and
test duration used. In addition, the test report MUST conform to the
reporting requirements set in section 4, Test Setup.
The latency results SHOULD be reported in the format of a table with
a row for each of the tested packet sizes. There SHOULD be columns
for the packet size, the intended rate, the offered rate, and the
resultant latency or delay values for each test.
The test report MUST note the object size(s) and number of requests
and responses completed. If applicable, the report MUST note the
test duration if a fixed duration was used. In addition, the test
report MUST conform to the reporting requirements set in section 4,
Test Setup.
The latency results SHOULD be reported in the format of a table with
a row for each of the object sizes. There SHOULD be columns for the
object size, the number of completed requests, the number of
completed responses, and the resultant latency or delay values for
each test.
Failure analysis:
The test report SHOULD indicate the number and percentage of HTTP
GET request or responses that failed to complete within the test
duration.
Version information:
The test report MUST note the version of HTTP client and server.
[1] Newman, D., "Benchmarking Terminology for Firewall Devices", RFC
2647, August 1999.
[2] Bradner, S. and J. McQuaid, "Benchmarking Methodology for
Network Interconnect Devices", RFC 2544, March 1999.
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[3] Bradner, S., "Benchmarking Terminology for Network
Interconnection Devices", RFC 1242, July 1991.
[4] Mandeville, R., "Benchmarking Terminology for LAN Switching
Devices", RFC 2285, February 1998.
[5] Mandeville, R. and J. Perser, "Benchmarking Methodology for LAN
Switching Devices", RFC 2889, August 2000.
[6] Fielding, R., Gettys, J., Mogul, J., Frystyk, H., Masinter, L.,
Leach, P. and T. Berners-Lee, "Hypertext Transfer Protocol -
HTTP/1.1", RFC 2616, June 1999.
[7] Clark, D., "IP Datagram Reassembly Algorithm", RFC 815, July
1982.
[8] Postel, J., "Transmission Control Protocol", STD 7, RFC 793,
September 1981.
The primary goal of this document is to provide methodologies in
benchmarking firewall performance. While there is some overlap
between performance and security issues, assessment of firewall
security is outside the scope of this document.
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APPENDIX A: HTTP (HyperText Transfer Protocol)
The most common versions of HTTP in use today are HTTP/1.0 and
HTTP/1.1 with the main difference being in regard to persistent
connections. HTTP 1.0, by default, does not support persistent
connections. A separate TCP connection is opened up for each GET
request the client wants to initiate and closed after the requested
object transfer is completed. While some implementations HTTP/1.0
supports persistence through the use of a keep-alive, there is no
official specification for how the keep-alive operates. In addition,
HTTP 1.0 proxies do support persistent connection as they do not
recognize the connection header.
HTTP/1.1, by default, does support persistent connection and is
therefore the version that is referenced in this methodology. Proxy
based DUT/SUTs may monitor the TCP connection and after a timeout,
close the connection if no activity is detected. The duration of
this timeout is not defined in the HTTP/1.1 specification and will
vary between DUT/SUTs. If the DUT/SUT closes inactive connections,
the aging timer on the DUT SHOULD be configured for a duration that
exceeds the test time.
While this document cannot foresee future changes to HTTP and it
impact on the methodologies defined herein, such changes should be
accommodated for so that newer versions of HTTP may be used in
benchmarking firewall performance.
APPENDIX B: Connection Establishment Time Measurements
Some connection oriented protocols, such as TCP, involve an odd
number of messages when establishing a connection. In the case of
proxy based DUT/SUTs, the DUT/SUT will terminate the connection,
setting up a separate connection to the server. Since, in such
cases, the test instrument does not own both sides of the connection,
measurements will be made two different ways. While the following
describes the measurements with reference to TCP, the methodology may
be used with other connection oriented protocols which involve an odd
number of messages.
When testing non-proxy based DUT/SUTs , the establishment time shall
be directly measured and is considered to be from the time the first
bit of the first SYN packet is transmitted by the client to the time
the last bit of the final ACK in the three-way handshake is received
by the target server.
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If the DUT/SUT is proxy based, the connection establishment time is
considered to be from the time the first bit of the first SYN packet
is transmitted by the client to the time the client transmits the
first bit of the first acknowledged TCP datagram (t4-t0 in the
following timeline).
t0: Client sends a SYN.
t1: Proxy sends a SYN/ACK.
t2: Client sends the final ACK.
t3: Proxy establishes separate connection with server.
t4: Client sends TCP datagram to server.
*t5: Proxy sends ACK of the datagram to client.
* While t5 is not considered part of the TCP connection
establishment, acknowledgement of t4 must be received for the
connection to be considered successful.
APPENDIX C: Connection Tear Down Time Measurements
While TCP connections are full duplex, tearing down of such
connections are performed in a simplex fashion, that is, FIN segments
are sent by each host/device terminating each side of the TCP
connection.
When making connection tear down times measurements, such
measurements will be made from the perspective of the entity, that
is, virtual client/server initiating the connection tear down
request. In addition, the measurement will be performed in the same
manner, independent of whether or not the DUT/SUT is proxy-based. The
connection tear down will be considered the interval between the
transmission of the first bit of the first TCP FIN packet transmitted
by the virtual client or server, whichever is applicable, requesting
a connection tear down to receipt of the last bit of the
corresponding ACK packet on the same virtual client/server interface.
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Authors' Addresses
Brooks Hickman
Spirent Communications
26750 Agoura Road
Calabasas, CA 91302
USA
Phone: + 1 818 676 2412
EMail: brooks.hickman@spirentcom.com
David Newman
Network Test Inc.
31324 Via Colinas, Suite 113
Westlake Village, CA 91362-6761
USA
Phone: + 1 818 889-0011
EMail: dnewman@networktest.com
Saldju Tadjudin
Spirent Communications
26750 Agoura Road
Calabasas, CA 91302
USA
Phone: + 1 818 676 2468
EMail: Saldju.Tadjudin@spirentcom.com
Terry Martin
GVNW Consulting Inc.
8050 SW Warm Springs Road
Tualatin Or. 97062
USA
Phone: + 1 503 612 4422
EMail: tmartin@gvnw.com
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Full Copyright Statement
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Acknowledgement
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