%YAML 1.1 --- # Suricata configuration file. In addition to the comments describing all # options in this file, full documentation can be found at: # https://suricata.readthedocs.io/en/latest/configuration/suricata-yaml.html # # This configuration file generated by: # Suricata 6.0.10 ## ## Step 1: Inform Suricata about your network ## vars: # more specific is better for alert accuracy and performance address-groups: {% for (name, value) in suricata['address_group'] %} {{ name }}: "[{{ value | join(',') }}]" {% endfor %} port-groups: {% for (name, value) in suricata['port_group'] %} {{ name }}: "[{{ value | join(',') }}]" {% endfor %} ## ## Step 2: Select outputs to enable ## # The default logging directory. Any log or output file will be # placed here if it's not specified with a full path name. This can be # overridden with the -l command line parameter. default-log-dir: /var/log/suricata/ # Configure the type of alert (and other) logging you would like. {% if suricata.log is vyos_defined %} outputs: {% if suricata.log.eve is vyos_defined %} # Extensible Event Format (nicknamed EVE) event log in JSON format - eve-log: enabled: yes filetype: {{ suricata.log.eve.filetype }} #regular|syslog|unix_dgram|unix_stream|redis filename: {{ suricata.log.eve.filename }} types: {% if suricata.log.eve.type is not vyos_defined or "alert" in suricata.log.eve.type %} - alert: tagged-packets: yes {% endif %} {% if "http" in suricata.log.eve.type %} - http: enabled: yes extended: yes {% endif %} {% if "tls" in suricata.log.eve.type %} - tls: enabled: yes extended: yes # enable this for extended logging information {% endif %} {% for protocol in suricata.log.eve.type %} {% if protocol not in ["alert","http","tls"] %} - {{ protocol }}: enabled: yes {% endif %} {% endfor %} {% endif %} {% endif %} ## ## Step 3: Configure common capture settings ## ## See "Advanced Capture Options" below for more options, including Netmap ## and PF_RING. ## # Linux high speed capture support af-packet: {% for interface in suricata.interface %} - interface: {{ interface }} # Default clusterid. AF_PACKET will load balance packets based on flow. cluster-id: {{ 100 - loop.index }} # Default AF_PACKET cluster type. AF_PACKET can load balance per flow or per hash. # This is only supported for Linux kernel > 3.1 # possible value are: # * cluster_flow: all packets of a given flow are sent to the same socket # * cluster_cpu: all packets treated in kernel by a CPU are sent to the same socket # * cluster_qm: all packets linked by network card to a RSS queue are sent to the same # socket. Requires at least Linux 3.14. # * cluster_ebpf: eBPF file load balancing. See doc/userguide/capture-hardware/ebpf-xdp.rst for # more info. # Recommended modes are cluster_flow on most boxes and cluster_cpu or cluster_qm on system # with capture card using RSS (requires cpu affinity tuning and system IRQ tuning) cluster-type: cluster_flow # In some fragmentation cases, the hash can not be computed. If "defrag" is set # to yes, the kernel will do the needed defragmentation before sending the packets. defrag: yes {% endfor %} # Cross platform libpcap capture support pcap: {% for interface in suricata.interface %} - interface: {{ interface }} {% endfor %} # Settings for reading pcap files pcap-file: # Possible values are: # - yes: checksum validation is forced # - no: checksum validation is disabled # - auto: Suricata uses a statistical approach to detect when # checksum off-loading is used. (default) # Warning: 'checksum-validation' must be set to yes to have checksum tested checksum-checks: auto # See "Advanced Capture Options" below for more options, including Netmap # and PF_RING. ## ## Step 4: App Layer Protocol configuration ## # Configure the app-layer parsers. # # The error-policy setting applies to all app-layer parsers. Values can be # "drop-flow", "pass-flow", "bypass", "drop-packet", "pass-packet", "reject" or # "ignore" (the default). # # The protocol's section details each protocol. # # The option "enabled" takes 3 values - "yes", "no", "detection-only". # "yes" enables both detection and the parser, "no" disables both, and # "detection-only" enables protocol detection only (parser disabled). app-layer: # error-policy: ignore protocols: rfb: enabled: yes detection-ports: dp: 5900, 5901, 5902, 5903, 5904, 5905, 5906, 5907, 5908, 5909 # MQTT, disabled by default. mqtt: enabled: yes # max-msg-length: 1mb # subscribe-topic-match-limit: 100 # unsubscribe-topic-match-limit: 100 # Maximum number of live MQTT transactions per flow # max-tx: 4096 krb5: enabled: yes snmp: enabled: yes ikev2: enabled: yes tls: enabled: yes detection-ports: dp: 443 # Generate JA3 fingerprint from client hello. If not specified it # will be disabled by default, but enabled if rules require it. #ja3-fingerprints: auto # What to do when the encrypted communications start: # - default: keep tracking TLS session, check for protocol anomalies, # inspect tls_* keywords. Disables inspection of unmodified # 'content' signatures. # - bypass: stop processing this flow as much as possible. No further # TLS parsing and inspection. Offload flow bypass to kernel # or hardware if possible. # - full: keep tracking and inspection as normal. Unmodified content # keyword signatures are inspected as well. # # For best performance, select 'bypass'. # #encryption-handling: default dcerpc: enabled: yes ftp: enabled: yes # memcap: 64mb rdp: enabled: yes ssh: enabled: yes #hassh: yes # HTTP2: Experimental HTTP 2 support. Disabled by default. http2: enabled: no # use http keywords on HTTP2 traffic http1-rules: no smtp: enabled: yes raw-extraction: no # Configure SMTP-MIME Decoder mime: # Decode MIME messages from SMTP transactions # (may be resource intensive) # This field supersedes all others because it turns the entire # process on or off decode-mime: yes # Decode MIME entity bodies (ie. Base64, quoted-printable, etc.) decode-base64: yes decode-quoted-printable: yes # Maximum bytes per header data value stored in the data structure # (default is 2000) header-value-depth: 2000 # Extract URLs and save in state data structure extract-urls: yes # Set to yes to compute the md5 of the mail body. You will then # be able to journalize it. body-md5: no # Configure inspected-tracker for file_data keyword inspected-tracker: content-limit: 100000 content-inspect-min-size: 32768 content-inspect-window: 4096 imap: enabled: detection-only smb: enabled: yes detection-ports: dp: 139, 445 # Stream reassembly size for SMB streams. By default track it completely. #stream-depth: 0 nfs: enabled: yes tftp: enabled: yes dns: tcp: enabled: yes detection-ports: dp: 53 udp: enabled: yes detection-ports: dp: 53 http: enabled: yes # memcap: Maximum memory capacity for HTTP # Default is unlimited, values can be 64mb, e.g. # default-config: Used when no server-config matches # personality: List of personalities used by default # request-body-limit: Limit reassembly of request body for inspection # by http_client_body & pcre /P option. # response-body-limit: Limit reassembly of response body for inspection # by file_data, http_server_body & pcre /Q option. # # For advanced options, see the user guide # server-config: List of server configurations to use if address matches # address: List of IP addresses or networks for this block # personality: List of personalities used by this block # # Then, all the fields from default-config can be overloaded # # Currently Available Personalities: # Minimal, Generic, IDS (default), IIS_4_0, IIS_5_0, IIS_5_1, IIS_6_0, # IIS_7_0, IIS_7_5, Apache_2 libhtp: default-config: personality: IDS # Can be specified in kb, mb, gb. Just a number indicates # it's in bytes. request-body-limit: 100kb response-body-limit: 100kb # inspection limits request-body-minimal-inspect-size: 32kb request-body-inspect-window: 4kb response-body-minimal-inspect-size: 40kb response-body-inspect-window: 16kb # response body decompression (0 disables) response-body-decompress-layer-limit: 2 # auto will use http-body-inline mode in IPS mode, yes or no set it statically http-body-inline: auto # Decompress SWF files. # Two types: 'deflate', 'lzma', 'both' will decompress deflate and lzma # compress-depth: # Specifies the maximum amount of data to decompress, # set 0 for unlimited. # decompress-depth: # Specifies the maximum amount of decompressed data to obtain, # set 0 for unlimited. swf-decompression: enabled: yes type: both compress-depth: 100kb decompress-depth: 100kb # Use a random value for inspection sizes around the specified value. # This lowers the risk of some evasion techniques but could lead # to detection change between runs. It is set to 'yes' by default. #randomize-inspection-sizes: yes # If "randomize-inspection-sizes" is active, the value of various # inspection size will be chosen from the [1 - range%, 1 + range%] # range # Default value of "randomize-inspection-range" is 10. #randomize-inspection-range: 10 # decoding double-decode-path: no double-decode-query: no # Can enable LZMA decompression #lzma-enabled: false # Memory limit usage for LZMA decompression dictionary # Data is decompressed until dictionary reaches this size #lzma-memlimit: 1mb # Maximum decompressed size with a compression ratio # above 2048 (only LZMA can reach this ratio, deflate cannot) #compression-bomb-limit: 1mb # Maximum time spent decompressing a single transaction in usec #decompression-time-limit: 100000 server-config: #- apache: # address: [192.168.1.0/24, 127.0.0.0/8, "::1"] # personality: Apache_2 # # Can be specified in kb, mb, gb. Just a number indicates # # it's in bytes. # request-body-limit: 4096 # response-body-limit: 4096 # double-decode-path: no # double-decode-query: no #- iis7: # address: # - 192.168.0.0/24 # - 192.168.10.0/24 # personality: IIS_7_0 # # Can be specified in kb, mb, gb. Just a number indicates # # it's in bytes. # request-body-limit: 4096 # response-body-limit: 4096 # double-decode-path: no # double-decode-query: no # Note: Modbus probe parser is minimalist due to the limited usage in the field. # Only Modbus message length (greater than Modbus header length) # and protocol ID (equal to 0) are checked in probing parser # It is important to enable detection port and define Modbus port # to avoid false positives modbus: # How many unanswered Modbus requests are considered a flood. # If the limit is reached, the app-layer-event:modbus.flooded; will match. #request-flood: 500 enabled: no detection-ports: dp: 502 # According to MODBUS Messaging on TCP/IP Implementation Guide V1.0b, it # is recommended to keep the TCP connection opened with a remote device # and not to open and close it for each MODBUS/TCP transaction. In that # case, it is important to set the depth of the stream reassembling as # unlimited (stream.reassembly.depth: 0) # Stream reassembly size for modbus. By default track it completely. stream-depth: 0 # DNP3 dnp3: enabled: no detection-ports: dp: 20000 # SCADA EtherNet/IP and CIP protocol support enip: enabled: no detection-ports: dp: 44818 sp: 44818 ntp: enabled: yes dhcp: enabled: yes sip: enabled: yes # Limit for the maximum number of asn1 frames to decode (default 256) asn1-max-frames: 256 # Datasets default settings # datasets: # # Default fallback memcap and hashsize values for datasets in case these # # were not explicitly defined. # defaults: # memcap: 100mb # hashsize: 2048 ############################################################################## ## ## Advanced settings below ## ############################################################################## ## ## Run Options ## # Run Suricata with a specific user-id and group-id: #run-as: # user: suri # group: suri # Some logging modules will use that name in event as identifier. The default # value is the hostname #sensor-name: suricata # Default location of the pid file. The pid file is only used in # daemon mode (start Suricata with -D). If not running in daemon mode # the --pidfile command line option must be used to create a pid file. #pid-file: /var/run/suricata.pid # Daemon working directory # Suricata will change directory to this one if provided # Default: "/" #daemon-directory: "/" # Umask. # Suricata will use this umask if it is provided. By default it will use the # umask passed on by the shell. #umask: 022 # Suricata core dump configuration. Limits the size of the core dump file to # approximately max-dump. The actual core dump size will be a multiple of the # page size. Core dumps that would be larger than max-dump are truncated. On # Linux, the actual core dump size may be a few pages larger than max-dump. # Setting max-dump to 0 disables core dumping. # Setting max-dump to 'unlimited' will give the full core dump file. # On 32-bit Linux, a max-dump value >= ULONG_MAX may cause the core dump size # to be 'unlimited'. coredump: max-dump: unlimited # If the Suricata box is a router for the sniffed networks, set it to 'router'. If # it is a pure sniffing setup, set it to 'sniffer-only'. # If set to auto, the variable is internally switched to 'router' in IPS mode # and 'sniffer-only' in IDS mode. # This feature is currently only used by the reject* keywords. host-mode: auto # Number of packets preallocated per thread. The default is 1024. A higher number # will make sure each CPU will be more easily kept busy, but may negatively # impact caching. #max-pending-packets: 1024 # Runmode the engine should use. Please check --list-runmodes to get the available # runmodes for each packet acquisition method. Default depends on selected capture # method. 'workers' generally gives best performance. #runmode: autofp # Specifies the kind of flow load balancer used by the flow pinned autofp mode. # # Supported schedulers are: # # hash - Flow assigned to threads using the 5-7 tuple hash. # ippair - Flow assigned to threads using addresses only. # #autofp-scheduler: hash # Preallocated size for each packet. Default is 1514 which is the classical # size for pcap on Ethernet. You should adjust this value to the highest # packet size (MTU + hardware header) on your system. #default-packet-size: 1514 # Unix command socket that can be used to pass commands to Suricata. # An external tool can then connect to get information from Suricata # or trigger some modifications of the engine. Set enabled to yes # to activate the feature. In auto mode, the feature will only be # activated in live capture mode. You can use the filename variable to set # the file name of the socket. unix-command: enabled: yes filename: /run/suricata/suricata.socket # Magic file. The extension .mgc is added to the value here. #magic-file: /usr/share/file/magic #magic-file: # GeoIP2 database file. Specify path and filename of GeoIP2 database # if using rules with "geoip" rule option. #geoip-database: /usr/local/share/GeoLite2/GeoLite2-Country.mmdb legacy: uricontent: enabled ## ## Detection settings ## # Set the order of alerts based on actions # The default order is pass, drop, reject, alert # action-order: # - pass # - drop # - reject # - alert # Define maximum number of possible alerts that can be triggered for the same # packet. Default is 15 #packet-alert-max: 15 # IP Reputation #reputation-categories-file: /etc/suricata/iprep/categories.txt #default-reputation-path: /etc/suricata/iprep #reputation-files: # - reputation.list # When run with the option --engine-analysis, the engine will read each of # the parameters below, and print reports for each of the enabled sections # and exit. The reports are printed to a file in the default log dir # given by the parameter "default-log-dir", with engine reporting # subsection below printing reports in its own report file. engine-analysis: # enables printing reports for fast-pattern for every rule. rules-fast-pattern: yes # enables printing reports for each rule rules: yes #recursion and match limits for PCRE where supported pcre: match-limit: 3500 match-limit-recursion: 1500 ## ## Advanced Traffic Tracking and Reconstruction Settings ## # Host specific policies for defragmentation and TCP stream # reassembly. The host OS lookup is done using a radix tree, just # like a routing table so the most specific entry matches. host-os-policy: # Make the default policy windows. windows: [0.0.0.0/0] bsd: [] bsd-right: [] old-linux: [] linux: [] old-solaris: [] solaris: [] hpux10: [] hpux11: [] irix: [] macos: [] vista: [] windows2k3: [] # Defrag settings: # The memcap-policy value can be "drop-flow", "pass-flow", "bypass", # "drop-packet", "pass-packet", "reject" or "ignore" (which is the default). defrag: memcap: 32mb # memcap-policy: ignore hash-size: 65536 trackers: 65535 # number of defragmented flows to follow max-frags: 65535 # number of fragments to keep (higher than trackers) prealloc: yes timeout: 60 # Enable defrag per host settings # host-config: # # - dmz: # timeout: 30 # address: [192.168.1.0/24, 127.0.0.0/8, 1.1.1.0/24, 2.2.2.0/24, "1.1.1.1", "2.2.2.2", "::1"] # # - lan: # timeout: 45 # address: # - 192.168.0.0/24 # - 192.168.10.0/24 # - 172.16.14.0/24 # Flow settings: # By default, the reserved memory (memcap) for flows is 32MB. This is the limit # for flow allocation inside the engine. You can change this value to allow # more memory usage for flows. # The hash-size determines the size of the hash used to identify flows inside # the engine, and by default the value is 65536. # At startup, the engine can preallocate a number of flows, to get better # performance. The number of flows preallocated is 10000 by default. # emergency-recovery is the percentage of flows that the engine needs to # prune before clearing the emergency state. The emergency state is activated # when the memcap limit is reached, allowing new flows to be created, but # pruning them with the emergency timeouts (they are defined below). # If the memcap is reached, the engine will try to prune flows # with the default timeouts. If it doesn't find a flow to prune, it will set # the emergency bit and it will try again with more aggressive timeouts. # If that doesn't work, then it will try to kill the oldest flows using # last time seen flows. # The memcap can be specified in kb, mb, gb. Just a number indicates it's # in bytes. # The memcap-policy can be "drop-flow", "pass-flow", "bypass", "drop-packet", # "pass-packet", "reject" or "ignore" (which is the default). flow: memcap: 128mb #memcap-policy: ignore hash-size: 65536 prealloc: 10000 emergency-recovery: 30 #managers: 1 # default to one flow manager #recyclers: 1 # default to one flow recycler thread # This option controls the use of VLAN ids in the flow (and defrag) # hashing. Normally this should be enabled, but in some (broken) # setups where both sides of a flow are not tagged with the same VLAN # tag, we can ignore the VLAN id's in the flow hashing. vlan: use-for-tracking: true # Specific timeouts for flows. Here you can specify the timeouts that the # active flows will wait to transit from the current state to another, on each # protocol. The value of "new" determines the seconds to wait after a handshake or # stream startup before the engine frees the data of that flow it doesn't # change the state to established (usually if we don't receive more packets # of that flow). The value of "established" is the amount of # seconds that the engine will wait to free the flow if that time elapses # without receiving new packets or closing the connection. "closed" is the # amount of time to wait after a flow is closed (usually zero). "bypassed" # timeout controls locally bypassed flows. For these flows we don't do any other # tracking. If no packets have been seen after this timeout, the flow is discarded. # # There's an emergency mode that will become active under attack circumstances, # making the engine to check flow status faster. This configuration variables # use the prefix "emergency-" and work similar as the normal ones. # Some timeouts doesn't apply to all the protocols, like "closed", for udp and # icmp. flow-timeouts: default: new: 30 established: 300 closed: 0 bypassed: 100 emergency-new: 10 emergency-established: 100 emergency-closed: 0 emergency-bypassed: 50 tcp: new: 60 established: 600 closed: 60 bypassed: 100 emergency-new: 5 emergency-established: 100 emergency-closed: 10 emergency-bypassed: 50 udp: new: 30 established: 300 bypassed: 100 emergency-new: 10 emergency-established: 100 emergency-bypassed: 50 icmp: new: 30 established: 300 bypassed: 100 emergency-new: 10 emergency-established: 100 emergency-bypassed: 50 # Stream engine settings. Here the TCP stream tracking and reassembly # engine is configured. # # stream: # memcap: 64mb # Can be specified in kb, mb, gb. Just a # # number indicates it's in bytes. # memcap-policy: ignore # Can be "drop-flow", "pass-flow", "bypass", # # "drop-packet", "pass-packet", "reject" or # # "ignore" default is "ignore" # checksum-validation: yes # To validate the checksum of received # # packet. If csum validation is specified as # # "yes", then packets with invalid csum values will not # # be processed by the engine stream/app layer. # # Warning: locally generated traffic can be # # generated without checksum due to hardware offload # # of checksum. You can control the handling of checksum # # on a per-interface basis via the 'checksum-checks' # # option # prealloc-sessions: 2k # 2k sessions prealloc'd per stream thread # midstream: false # don't allow midstream session pickups # midstream-policy: ignore # Can be "drop-flow", "pass-flow", "bypass", # # "drop-packet", "pass-packet", "reject" or # # "ignore" default is "ignore" # async-oneside: false # don't enable async stream handling # inline: no # stream inline mode # drop-invalid: yes # in inline mode, drop packets that are invalid with regards to streaming engine # max-synack-queued: 5 # Max different SYN/ACKs to queue # bypass: no # Bypass packets when stream.reassembly.depth is reached. # # Warning: first side to reach this triggers # # the bypass. # # reassembly: # memcap: 256mb # Can be specified in kb, mb, gb. Just a number # # indicates it's in bytes. # memcap-policy: ignore # Can be "drop-flow", "pass-flow", "bypass", # # "drop-packet", "pass-packet", "reject" or # # "ignore" default is "ignore" # depth: 1mb # Can be specified in kb, mb, gb. Just a number # # indicates it's in bytes. # toserver-chunk-size: 2560 # inspect raw stream in chunks of at least # # this size. Can be specified in kb, mb, # # gb. Just a number indicates it's in bytes. # toclient-chunk-size: 2560 # inspect raw stream in chunks of at least # # this size. Can be specified in kb, mb, # # gb. Just a number indicates it's in bytes. # randomize-chunk-size: yes # Take a random value for chunk size around the specified value. # # This lowers the risk of some evasion techniques but could lead # # to detection change between runs. It is set to 'yes' by default. # randomize-chunk-range: 10 # If randomize-chunk-size is active, the value of chunk-size is # # a random value between (1 - randomize-chunk-range/100)*toserver-chunk-size # # and (1 + randomize-chunk-range/100)*toserver-chunk-size and the same # # calculation for toclient-chunk-size. # # Default value of randomize-chunk-range is 10. # # raw: yes # 'Raw' reassembly enabled or disabled. # # raw is for content inspection by detection # # engine. # # segment-prealloc: 2048 # number of segments preallocated per thread # # check-overlap-different-data: true|false # # check if a segment contains different data # # than what we've already seen for that # # position in the stream. # # This is enabled automatically if inline mode # # is used or when stream-event:reassembly_overlap_different_data; # # is used in a rule. # stream: memcap: 64mb #memcap-policy: ignore checksum-validation: yes # reject incorrect csums #midstream: false #midstream-policy: ignore inline: auto # auto will use inline mode in IPS mode, yes or no set it statically reassembly: memcap: 256mb #memcap-policy: ignore depth: 1mb # reassemble 1mb into a stream toserver-chunk-size: 2560 toclient-chunk-size: 2560 randomize-chunk-size: yes #randomize-chunk-range: 10 #raw: yes #segment-prealloc: 2048 #check-overlap-different-data: true # Host table: # # Host table is used by the tagging and per host thresholding subsystems. # host: hash-size: 4096 prealloc: 1000 memcap: 32mb # IP Pair table: # # Used by xbits 'ippair' tracking. # #ippair: # hash-size: 4096 # prealloc: 1000 # memcap: 32mb # Decoder settings decoder: # Teredo decoder is known to not be completely accurate # as it will sometimes detect non-teredo as teredo. teredo: enabled: true # ports to look for Teredo. Max 4 ports. If no ports are given, or # the value is set to 'any', Teredo detection runs on _all_ UDP packets. ports: $TEREDO_PORTS # syntax: '[3544, 1234]' or '3533' or 'any'. # VXLAN decoder is assigned to up to 4 UDP ports. By default only the # IANA assigned port 4789 is enabled. vxlan: enabled: true ports: $VXLAN_PORTS # syntax: '[8472, 4789]' or '4789'. # VNTag decode support vntag: enabled: false # Geneve decoder is assigned to up to 4 UDP ports. By default only the # IANA assigned port 6081 is enabled. geneve: enabled: true ports: $GENEVE_PORTS # syntax: '[6081, 1234]' or '6081'. # maximum number of decoder layers for a packet # max-layers: 16 ## ## Performance tuning and profiling ## # The detection engine builds internal groups of signatures. The engine # allows us to specify the profile to use for them, to manage memory in an # efficient way keeping good performance. For the profile keyword you # can use the words "low", "medium", "high" or "custom". If you use custom, # make sure to define the values in the "custom-values" section. # Usually you would prefer medium/high/low. # # "sgh mpm-context", indicates how the staging should allot mpm contexts for # the signature groups. "single" indicates the use of a single context for # all the signature group heads. "full" indicates a mpm-context for each # group head. "auto" lets the engine decide the distribution of contexts # based on the information the engine gathers on the patterns from each # group head. # # The option inspection-recursion-limit is used to limit the recursive calls # in the content inspection code. For certain payload-sig combinations, we # might end up taking too much time in the content inspection code. # If the argument specified is 0, the engine uses an internally defined # default limit. When a value is not specified, there are no limits on the recursion. detect: profile: medium custom-values: toclient-groups: 3 toserver-groups: 25 sgh-mpm-context: auto inspection-recursion-limit: 3000 # If set to yes, the loading of signatures will be made after the capture # is started. This will limit the downtime in IPS mode. #delayed-detect: yes prefilter: # default prefiltering setting. "mpm" only creates MPM/fast_pattern # engines. "auto" also sets up prefilter engines for other keywords. # Use --list-keywords=all to see which keywords support prefiltering. default: mpm # the grouping values above control how many groups are created per # direction. Port whitelisting forces that port to get its own group. # Very common ports will benefit, as well as ports with many expensive # rules. grouping: #tcp-whitelist: 53, 80, 139, 443, 445, 1433, 3306, 3389, 6666, 6667, 8080 #udp-whitelist: 53, 135, 5060 profiling: # Log the rules that made it past the prefilter stage, per packet # default is off. The threshold setting determines how many rules # must have made it past pre-filter for that rule to trigger the # logging. #inspect-logging-threshold: 200 grouping: dump-to-disk: false include-rules: false # very verbose include-mpm-stats: false # Select the multi pattern algorithm you want to run for scan/search the # in the engine. # # The supported algorithms are: # "ac" - Aho-Corasick, default implementation # "ac-bs" - Aho-Corasick, reduced memory implementation # "ac-ks" - Aho-Corasick, "Ken Steele" variant # "hs" - Hyperscan, available when built with Hyperscan support # # The default mpm-algo value of "auto" will use "hs" if Hyperscan is # available, "ac" otherwise. # # The mpm you choose also decides the distribution of mpm contexts for # signature groups, specified by the conf - "detect.sgh-mpm-context". # Selecting "ac" as the mpm would require "detect.sgh-mpm-context" # to be set to "single", because of ac's memory requirements, unless the # ruleset is small enough to fit in memory, in which case one can # use "full" with "ac". The rest of the mpms can be run in "full" mode. mpm-algo: auto # Select the matching algorithm you want to use for single-pattern searches. # # Supported algorithms are "bm" (Boyer-Moore) and "hs" (Hyperscan, only # available if Suricata has been built with Hyperscan support). # # The default of "auto" will use "hs" if available, otherwise "bm". spm-algo: auto # Suricata is multi-threaded. Here the threading can be influenced. threading: set-cpu-affinity: no # Tune cpu affinity of threads. Each family of threads can be bound # to specific CPUs. # # These 2 apply to the all runmodes: # management-cpu-set is used for flow timeout handling, counters # worker-cpu-set is used for 'worker' threads # # Additionally, for autofp these apply: # receive-cpu-set is used for capture threads # verdict-cpu-set is used for IPS verdict threads # cpu-affinity: - management-cpu-set: cpu: [ 0 ] # include only these CPUs in affinity settings - receive-cpu-set: cpu: [ 0 ] # include only these CPUs in affinity settings - worker-cpu-set: cpu: [ "all" ] mode: "exclusive" # Use explicitly 3 threads and don't compute number by using # detect-thread-ratio variable: # threads: 3 prio: low: [ 0 ] medium: [ "1-2" ] high: [ 3 ] default: "medium" #- verdict-cpu-set: # cpu: [ 0 ] # prio: # default: "high" # # By default Suricata creates one "detect" thread per available CPU/CPU core. # This setting allows controlling this behaviour. A ratio setting of 2 will # create 2 detect threads for each CPU/CPU core. So for a dual core CPU this # will result in 4 detect threads. If values below 1 are used, less threads # are created. So on a dual core CPU a setting of 0.5 results in 1 detect # thread being created. Regardless of the setting at a minimum 1 detect # thread will always be created. # detect-thread-ratio: 1.0 # # By default, the per-thread stack size is left to its default setting. If # the default thread stack size is too small, use the following configuration # setting to change the size. Note that if any thread's stack size cannot be # set to this value, a fatal error occurs. # # Generally, the per-thread stack-size should not exceed 8MB. #stack-size: 8mb # Luajit has a strange memory requirement, its 'states' need to be in the # first 2G of the process' memory. # # 'luajit.states' is used to control how many states are preallocated. # State use: per detect script: 1 per detect thread. Per output script: 1 per # script. luajit: states: 128 # Profiling settings. Only effective if Suricata has been built with # the --enable-profiling configure flag. # profiling: # Run profiling for every X-th packet. The default is 1, which means we # profile every packet. If set to 1000, one packet is profiled for every # 1000 received. #sample-rate: 1000 # rule profiling rules: # Profiling can be disabled here, but it will still have a # performance impact if compiled in. enabled: yes filename: rule_perf.log append: yes # Sort options: ticks, avgticks, checks, matches, maxticks # If commented out all the sort options will be used. #sort: avgticks # Limit the number of sids for which stats are shown at exit (per sort). limit: 10 # output to json json: yes # per keyword profiling keywords: enabled: yes filename: keyword_perf.log append: yes prefilter: enabled: yes filename: prefilter_perf.log append: yes # per rulegroup profiling rulegroups: enabled: yes filename: rule_group_perf.log append: yes # packet profiling packets: # Profiling can be disabled here, but it will still have a # performance impact if compiled in. enabled: yes filename: packet_stats.log append: yes # per packet csv output csv: # Output can be disabled here, but it will still have a # performance impact if compiled in. enabled: no filename: packet_stats.csv # profiling of locking. Only available when Suricata was built with # --enable-profiling-locks. locks: enabled: no filename: lock_stats.log append: yes pcap-log: enabled: no filename: pcaplog_stats.log append: yes ## ## Netfilter integration ## # When running in NFQ inline mode, it is possible to use a simulated # non-terminal NFQUEUE verdict. # This permits sending all needed packet to Suricata via this rule: # iptables -I FORWARD -m mark ! --mark $MARK/$MASK -j NFQUEUE # And below, you can have your standard filtering ruleset. To activate # this mode, you need to set mode to 'repeat' # If you want a packet to be sent to another queue after an ACCEPT decision # set the mode to 'route' and set next-queue value. # On Linux >= 3.1, you can set batchcount to a value > 1 to improve performance # by processing several packets before sending a verdict (worker runmode only). # On Linux >= 3.6, you can set the fail-open option to yes to have the kernel # accept the packet if Suricata is not able to keep pace. # bypass mark and mask can be used to implement NFQ bypass. If bypass mark is # set then the NFQ bypass is activated. Suricata will set the bypass mark/mask # on packet of a flow that need to be bypassed. The Nefilter ruleset has to # directly accept all packets of a flow once a packet has been marked. nfq: # mode: accept # repeat-mark: 1 # repeat-mask: 1 # bypass-mark: 1 # bypass-mask: 1 # route-queue: 2 # batchcount: 20 # fail-open: yes #nflog support nflog: # netlink multicast group # (the same as the iptables --nflog-group param) # Group 0 is used by the kernel, so you can't use it - group: 2 # netlink buffer size buffer-size: 18432 # put default value here - group: default # set number of packets to queue inside kernel qthreshold: 1 # set the delay before flushing packet in the kernel's queue qtimeout: 100 # netlink max buffer size max-size: 20000 ## ## Advanced Capture Options ## # General settings affecting packet capture capture: # disable NIC offloading. It's restored when Suricata exits. # Enabled by default. #disable-offloading: false # # disable checksum validation. Same as setting '-k none' on the # commandline. #checksum-validation: none # Netmap support # # Netmap operates with NIC directly in driver, so you need FreeBSD 11+ which has # built-in Netmap support or compile and install the Netmap module and appropriate # NIC driver for your Linux system. # To reach maximum throughput disable all receive-, segmentation-, # checksum- offloading on your NIC (using ethtool or similar). # Disabling TX checksum offloading is *required* for connecting OS endpoint # with NIC endpoint. # You can find more information at https://github.com/luigirizzo/netmap # netmap: - interface: default # PF_RING configuration: for use with native PF_RING support # for more info see http://www.ntop.org/products/pf_ring/ pfring: - interface: default #threads: 2 # For FreeBSD ipfw(8) divert(4) support. # Please make sure you have ipfw_load="YES" and ipdivert_load="YES" # in /etc/loader.conf or kldload'ing the appropriate kernel modules. # Additionally, you need to have an ipfw rule for the engine to see # the packets from ipfw. For Example: # # ipfw add 100 divert 8000 ip from any to any # # N.B. This example uses "8000" -- this number must mach the values # you passed on the command line, i.e., -d 8000 # ipfw: # Reinject packets at the specified ipfw rule number. This config # option is the ipfw rule number AT WHICH rule processing continues # in the ipfw processing system after the engine has finished # inspecting the packet for acceptance. If no rule number is specified, # accepted packets are reinjected at the divert rule which they entered # and IPFW rule processing continues. No check is done to verify # this will rule makes sense so care must be taken to avoid loops in ipfw. # ## The following example tells the engine to reinject packets # back into the ipfw firewall AT rule number 5500: # # ipfw-reinjection-rule-number: 5500 napatech: # When use_all_streams is set to "yes" the initialization code will query # the Napatech service for all configured streams and listen on all of them. # When set to "no" the streams config array will be used. # # This option necessitates running the appropriate NTPL commands to create # the desired streams prior to running Suricata. #use-all-streams: no # The streams to listen on when auto-config is disabled or when and threading # cpu-affinity is disabled. This can be either: # an individual stream (e.g. streams: [0]) # or # a range of streams (e.g. streams: ["0-3"]) # streams: ["0-3"] # Stream stats can be enabled to provide fine grain packet and byte counters # for each thread/stream that is configured. # enable-stream-stats: no # When auto-config is enabled the streams will be created and assigned # automatically to the NUMA node where the thread resides. If cpu-affinity # is enabled in the threading section. Then the streams will be created # according to the number of worker threads specified in the worker-cpu-set. # Otherwise, the streams array is used to define the streams. # # This option is intended primarily to support legacy configurations. # # This option cannot be used simultaneously with either "use-all-streams" # or "hardware-bypass". # auto-config: yes # Enable hardware level flow bypass. # hardware-bypass: yes # Enable inline operation. When enabled traffic arriving on a given port is # automatically forwarded out its peer port after analysis by Suricata. # inline: no # Ports indicates which Napatech ports are to be used in auto-config mode. # these are the port IDs of the ports that will be merged prior to the # traffic being distributed to the streams. # # When hardware-bypass is enabled the ports must be configured as a segment. # specify the port(s) on which upstream and downstream traffic will arrive. # This information is necessary for the hardware to properly process flows. # # When using a tap configuration one of the ports will receive inbound traffic # for the network and the other will receive outbound traffic. The two ports on a # given segment must reside on the same network adapter. # # When using a SPAN-port configuration the upstream and downstream traffic # arrives on a single port. This is configured by setting the two sides of the # segment to reference the same port. (e.g. 0-0 to configure a SPAN port on # port 0). # # port segments are specified in the form: # ports: [0-1,2-3,4-5,6-6,7-7] # # For legacy systems when hardware-bypass is disabled this can be specified in any # of the following ways: # # a list of individual ports (e.g. ports: [0,1,2,3]) # # a range of ports (e.g. ports: [0-3]) # # "all" to indicate that all ports are to be merged together # (e.g. ports: [all]) # # This parameter has no effect if auto-config is disabled. # ports: [0-1,2-3] # When auto-config is enabled the hashmode specifies the algorithm for # determining to which stream a given packet is to be delivered. # This can be any valid Napatech NTPL hashmode command. # # The most common hashmode commands are: hash2tuple, hash2tuplesorted, # hash5tuple, hash5tuplesorted and roundrobin. # # See Napatech NTPL documentation other hashmodes and details on their use. # # This parameter has no effect if auto-config is disabled. # hashmode: hash5tuplesorted ## ## Configure Suricata to load Suricata-Update managed rules. ## # As VyOS leverages suricata-update, the default rule path points to the # generated rules instead of the built-in rules. # # default-rule-path: /etc/suricata/rules default-rule-path: /var/lib/suricata/rules rule-files: - suricata.rules ## ## Auxiliary configuration files. ## # As VyOS leverages suricata-update, the classification file points to the # generated classification instead of the built-in one. # # classification-file: /etc/suricata/classification.config classification-file: /var/lib/suricata/rules/classification.config reference-config-file: /etc/suricata/reference.config # threshold-file: /etc/suricata/threshold.config ## ## Include other configs ## # Includes: Files included here will be handled as if they were in-lined # in this configuration file. Files with relative pathnames will be # searched for in the same directory as this configuration file. You may # use absolute pathnames too. # You can specify more than 2 configuration files, if needed. #include: include1.yaml #include: include2.yaml