Support #3466
Updated by Victor Julien about 5 years ago
i am executing this command <pre> suricata -T /etc/suricata/suricata.yaml </pre> and this error is showing <pre> [ERRCODE: SC_ERR_UNKNOWN_VALUE(129)] - signature at /etc/suricata/rules/emerging-dns.rules:113 uses unknown classtype: "command-and-control", using default priority 3. This message won't be shown again for this classtype </pre> I already added the emerging-dns.rules rule in the rules directory my yaml configuration file is this <pre> %YAML 1.1 --- Suricata configuration file. In addition to the comments describing all options in this file, full documentation can be found at: https://redmine.openinfosecfoundation.org/projects/suricata/wiki/Suricatayaml ## Step 1: inform Suricata about your network ## vars: # more specifc is better for alert accuracy and performance address-groups: #HOME_NET: "[10.242.4.3,10.242.4.4]" HOME_NET: "[192.168.1.0/24]" #HOME_NET: "[10.0.0.0/8]" #HOME_NET: "[172.16.0.0/12]" #HOME_NET: "any" EXTERNAL_NET: "!$HOME_NET" #EXTERNAL_NET: "any" HTTP_SERVERS: "$HOME_NET" SMTP_SERVERS: "$HOME_NET" SQL_SERVERS: "$HOME_NET" DNS_SERVERS: "$HOME_NET" TELNET_SERVERS: "$HOME_NET" AIM_SERVERS: "$EXTERNAL_NET" DNP3_SERVER: "$HOME_NET" DNP3_CLIENT: "$HOME_NET" MODBUS_CLIENT: "$HOME_NET" MODBUS_SERVER: "$HOME_NET" ENIP_CLIENT: "$HOME_NET" ENIP_SERVER: "$HOME_NET" port-groups: HTTP_PORTS: "80" SHELLCODE_PORTS: "!80" ORACLE_PORTS: 1521 SSH_PORTS: 22 DNP3_PORTS: 20000 MODBUS_PORTS: 502 FILE_DATA_PORTS: "[$HTTP_PORTS,110,143]" FTP_PORTS: 21 ## Step 2: select the rules to enable or disable ## default-rule-path: /etc/suricata/rules rule-files: - botcc.rules # - botcc.portgrouped.rules #- ciarmy.rules #- compromised.rules #- drop.rules #- dshield.rules #- emerging-activex.rules #- emerging-attack_response.rules #- emerging-chat.rules #- emerging-current_events.rules - emerging-dns.rules #- emerging-dos.rules #- emerging-exploit.rules #- emerging-ftp.rules #- emerging-games.rules #- emerging-icmp_info.rules #- emerging-icmp.rules #- emerging-imap.rules #- emerging-inappropriate.rules #- emerging-info.rules #- emerging-malware.rules #- emerging-misc.rules #- emerging-mobile_malware.rules #- emerging-netbios.rules #- emerging-p2p.rules #- emerging-policy.rules #- emerging-pop3.rules #- emerging-rpc.rules #- emerging-scada.rules ##- emerging-scada_special.rules #- emerging-scan.rules #- emerging-shellcode.rules #- emerging-smtp.rules #- emerging-snmp.rules #- emerging-sql.rules #- emerging-telnet.rules #- emerging-tftp.rules #- emerging-trojan.rules #- emerging-user_agents.rules #- emerging-voip.rules #- emerging-web_client.rules #- emerging-web_server.rules #- emerging-web_specific_apps.rules #- emerging-worm.rules #- tor.rules - decoder-events.rules # available in suricata sources under rules dir - stream-events.rules # available in suricata sources under rules dir #- http-events.rules # available in suricata sources under rules dir #- smtp-events.rules # available in suricata sources under rules dir - dns-events.rules # available in suricata sources under rules dir - tls-events.rules # available in suricata sources under rules dir - modbus-events.rules # available in suricata sources under rules dir - app-layer-events.rules # available in suricata sources under rules dir - dnp3-events.rules # available in suricata sources under rules dir - ntp-events.rules # available in suricata sources under rules dir - snwaf.rules classification-file: /etc/suricata/classification.config reference-config-file: /etc/suricata/reference.config threshold-file: /etc/suricata/threshold.config ## Step 3: select outputs to enable ## The default logging directory. Any log or output file will be placed here if its not specified with a full path name. This can be overridden with the -l command line parameter. default-log-dir: /var/log/suricata/ global stats configuration stats: enabled: yes # The interval field (in seconds) controls at what interval # the loggers are invoked. interval: 8 Configure the type of alert (and other) logging you would like. outputs: # a line based alerts log similar to Snort's fast.log - fast: enabled: yes filename: fast.log append: yes #filetype: regular # 'regular', 'unix_stream' or 'unix_dgram' Extensible Event Format (nicknamed EVE) event log in JSON format - eve-log: enabled: yes filetype: regular #regular|syslog|unix_dgram|unix_stream|redis filename: eve.json #prefix: "@cee: " # prefix to prepend to each log entry # the following are valid when type: syslog above #identity: "suricata" #facility: local5 #level: Info ## possible levels: Emergency, Alert, Critical, ## Error, Warning, Notice, Info, Debug #redis: # server: 127.0.0.1 # port: 6379 # async: true ## if redis replies are read asynchronously # mode: list ## possible values: list|lpush (default), rpush, channel|publish # ## lpush and rpush are using a Redis list. "list" is an alias for lpush # ## publish is using a Redis channel. "channel" is an alias for publish # key: suricata ## key or channel to use (default to suricata) # Redis pipelining set up. This will enable to only do a query every # 'batch-size' events. This should lower the latency induced by network # connection at the cost of some memory. There is no flushing implemented # so this setting as to be reserved to high traffic suricata. # pipelining: # enabled: yes ## set enable to yes to enable query pipelining # batch-size: 10 ## number of entry to keep in buffer types: - alert: # payload: yes # enable dumping payload in Base64 # payload-buffer-size: 4kb # max size of payload buffer to output in eve-log # payload-printable: yes # enable dumping payload in printable (lossy) format # packet: yes # enable dumping of packet (without stream segments) # http-body: yes # enable dumping of http body in Base64 # http-body-printable: yes # enable dumping of http body in printable format metadata: yes # add L7/applayer fields, flowbit and other vars to the alert # Enable the logging of tagged packets for rules using the # "tag" keyword. tagged-packets: yes # HTTP X-Forwarded-For support by adding an extra field or overwriting # the source or destination IP address (depending on flow direction) # with the one reported in the X-Forwarded-For HTTP header. This is # helpful when reviewing alerts for traffic that is being reverse # or forward proxied. xff: enabled: no # Two operation modes are available, "extra-data" and "overwrite". mode: extra-data # Two proxy deployments are supported, "reverse" and "forward". In # a "reverse" deployment the IP address used is the last one, in a # "forward" deployment the first IP address is used. deployment: reverse # Header name where the actual IP address will be reported, if more # than one IP address is present, the last IP address will be the # one taken into consideration. header: X-Forwarded-For - http: extended: yes # enable this for extended logging information # custom allows additional http fields to be included in eve-log # the example below adds three additional fields when uncommented #custom: [Accept-Encoding, Accept-Language, Authorization] - dns: # control logging of queries and answers # default yes, no to disable query: yes # enable logging of DNS queries answer: yes # enable logging of DNS answers # control which RR types are logged # all enabled if custom not specified #custom: [a, aaaa, cname, mx, ns, ptr, txt] - tls: extended: yes # enable this for extended logging information # output TLS transaction where the session is resumed using a # session id #session-resumption: no # custom allows to control which tls fields that are included # in eve-log #custom: [subject, issuer, session_resumed, serial, fingerprint, sni, version, not_before, not_after, certificate, chain] - files: force-magic: no # force logging magic on all logged files # force logging of checksums, available hash functions are md5, # sha1 and sha256 #force-hash: [md5] #- drop: # alerts: yes # log alerts that caused drops # flows: all # start or all: 'start' logs only a single drop # # per flow direction. All logs each dropped pkt. - smtp: #extended: yes # enable this for extended logging information # this includes: bcc, message-id, subject, x_mailer, user-agent # custom fields logging from the list: # reply-to, bcc, message-id, subject, x-mailer, user-agent, received, # x-originating-ip, in-reply-to, references, importance, priority, # sensitivity, organization, content-md5, date #custom: [received, x-mailer, x-originating-ip, relays, reply-to, bcc] # output md5 of fields: body, subject # for the body you need to set app-layer.protocols.smtp.mime.body-md5 # to yes #md5: [body, subject] #- dnp3 #- nfs - ssh #- stats: #totals: yes # stats for all threads merged together #threads: no # per thread stats #deltas: no # include delta values # bi-directional flows #- flow # uni-directional flows #- netflow # Vars log flowbits and other packet and flow vars #- vars # alert output for use with Barnyard2 - unified2-alert: enabled: no filename: unified2.alert # File size limit. Can be specified in kb, mb, gb. Just a number # is parsed as bytes. #limit: 32mb # By default unified2 log files have the file creation time (in # unix epoch format) appended to the filename. Set this to yes to # disable this behaviour. #nostamp: no # Sensor ID field of unified2 alerts. #sensor-id: 0 # Include payload of packets related to alerts. Defaults to true, set to # false if payload is not required. #payload: yes # HTTP X-Forwarded-For support by adding the unified2 extra header or # overwriting the source or destination IP address (depending on flow # direction) with the one reported in the X-Forwarded-For HTTP header. # This is helpful when reviewing alerts for traffic that is being reverse # or forward proxied. xff: enabled: no # Two operation modes are available, "extra-data" and "overwrite". Note # that in the "overwrite" mode, if the reported IP address in the HTTP # X-Forwarded-For header is of a different version of the packet # received, it will fall-back to "extra-data" mode. mode: extra-data # Two proxy deployments are supported, "reverse" and "forward". In # a "reverse" deployment the IP address used is the last one, in a # "forward" deployment the first IP address is used. deployment: reverse # Header name where the actual IP address will be reported, if more # than one IP address is present, the last IP address will be the # one taken into consideration. header: X-Forwarded-For # a line based log of HTTP requests (no alerts) - http-log: enabled: yes filename: http.log append: yes #extended: yes # enable this for extended logging information #custom: yes # enabled the custom logging format (defined by customformat) #customformat: "%{%D-%H:%M:%S}t.%z %{X-Forwarded-For}i %H %m %h %u %s %B %a:%p -> %A:%P" #filetype: regular # 'regular', 'unix_stream' or 'unix_dgram' # a line based log of TLS handshake parameters (no alerts) - tls-log: enabled: yes # Log TLS connections. filename: tls.log # File to store TLS logs. append: yes #extended: yes # Log extended information like fingerprint #custom: yes # enabled the custom logging format (defined by customformat) #customformat: "%{%D-%H:%M:%S}t.%z %a:%p -> %A:%P %v %n %d %D" #filetype: regular # 'regular', 'unix_stream' or 'unix_dgram' # output TLS transaction where the session is resumed using a # session id #session-resumption: no # output module to store certificates chain to disk - tls-store: enabled: no #certs-log-dir: certs # directory to store the certificates files # a line based log of DNS requests and/or replies (no alerts) - dns-log: enabled: yes filename: dns.log append: yes #filetype: regular # 'regular', 'unix_stream' or 'unix_dgram' # Packet log... log packets in pcap format. 3 modes of operation: "normal" # "multi" and "sguil". # # In normal mode a pcap file "filename" is created in the default-log-dir, # or are as specified by "dir". # In multi mode, a file is created per thread. This will perform much # better, but will create multiple files where 'normal' would create one. # In multi mode the filename takes a few special variables: # - %n -- thread number # - %i -- thread id # - %t -- timestamp (secs or secs.usecs based on 'ts-format' # E.g. filename: pcap.%n.%t # # Note that it's possible to use directories, but the directories are not # created by Suricata. E.g. filename: pcaps/%n/log.%s will log into the # per thread directory. # # Also note that the limit and max-files settings are enforced per thread. # So the size limit when using 8 threads with 1000mb files and 2000 files # is: 8*1000*2000 ~ 16TiB. # # In Sguil mode "dir" indicates the base directory. In this base dir the # pcaps are created in th directory structure Sguil expects: # # $sguil-base-dir/YYYY-MM-DD/$filename.<timestamp> # # By default all packets are logged except: # - TCP streams beyond stream.reassembly.depth # - encrypted streams after the key exchange # - pcap-log: enabled: no filename: log.pcap # File size limit. Can be specified in kb, mb, gb. Just a number # is parsed as bytes. limit: 1000mb # If set to a value will enable ring buffer mode. Will keep Maximum of "max-files" of size "limit" max-files: 2000 mode: normal # normal, multi or sguil. # Directory to place pcap files. If not provided the default log # directory will be used. Required for "sguil" mode. #dir: /nsm_data/ #ts-format: usec # sec or usec second format (default) is filename.sec usec is filename.sec.usec use-stream-depth: no #If set to "yes" packets seen after reaching stream inspection depth are ignored. "no" logs all packets honor-pass-rules: no # If set to "yes", flows in which a pass rule matched will stopped being logged. # a full alerts log containing much information for signature writers # or for investigating suspected false positives. - alert-debug: enabled: no filename: alert-debug.log append: yes #filetype: regular # 'regular', 'unix_stream' or 'unix_dgram' # alert output to prelude (http://www.prelude-technologies.com/) only # available if Suricata has been compiled with --enable-prelude - alert-prelude: enabled: no profile: suricata log-packet-content: no log-packet-header: yes # Stats.log contains data from various counters of the suricata engine. - stats: enabled: yes filename: stats.log append: yes # append to file (yes) or overwrite it (no) totals: yes # stats for all threads merged together threads: no # per thread stats #null-values: yes # print counters that have value 0 # a line based alerts log similar to fast.log into syslog - syslog: enabled: no # reported identity to syslog. If ommited the program name (usually # suricata) will be used. #identity: "suricata" facility: local5 #level: Info ## possible levels: Emergency, Alert, Critical, ## Error, Warning, Notice, Info, Debug # a line based information for dropped packets in IPS mode - drop: enabled: yes filename: drop.log append: yes #filetype: regular # 'regular', 'unix_stream' or 'unix_dgram' # output module to store extracted files to disk # # The files are stored to the log-dir in a format "file.<id>" where <id> is # an incrementing number starting at 1. For each file "file.<id>" a meta # file "file.<id>.meta" is created. # # File extraction depends on a lot of things to be fully done: # - file-store stream-depth. For optimal results, set this to 0 (unlimited) # - http request / response body sizes. Again set to 0 for optimal results. # - rules that contain the "filestore" keyword. - file-store: enabled: no # set to yes to enable log-dir: files # directory to store the files force-magic: no # force logging magic on all stored files # force logging of checksums, available hash functions are md5, # sha1 and sha256 #force-hash: [md5] force-filestore: no # force storing of all files # override global stream-depth for sessions in which we want to # perform file extraction. Set to 0 for unlimited. #stream-depth: 0 #waldo: file.waldo # waldo file to store the file_id across runs # uncomment to disable meta file writing #write-meta: no # uncomment the following variable to define how many files can # remain open for filestore by Suricata. Default value is 0 which # means files get closed after each write #max-open-files: 1000 # output module to log files tracked in a easily parsable json format - file-log: enabled: no filename: files-json.log append: yes #filetype: regular # 'regular', 'unix_stream' or 'unix_dgram' force-magic: no # force logging magic on all logged files # force logging of checksums, available hash functions are md5, # sha1 and sha256 #force-hash: [md5] # Log TCP data after stream normalization # 2 types: file or dir. File logs into a single logfile. Dir creates # 2 files per TCP session and stores the raw TCP data into them. # Using 'both' will enable both file and dir modes. # # Note: limited by stream.depth - tcp-data: enabled: no type: file filename: tcp-data.log # Log HTTP body data after normalization, dechunking and unzipping. # 2 types: file or dir. File logs into a single logfile. Dir creates # 2 files per HTTP session and stores the normalized data into them. # Using 'both' will enable both file and dir modes. # # Note: limited by the body limit settings - http-body-data: enabled: yes type: file filename: http-data.log # Lua Output Support - execute lua script to generate alert and event # output. # Documented at: # https://redmine.openinfosecfoundation.org/projects/suricata/wiki/Lua_Output - lua: enabled: no #scripts-dir: /etc/suricata/lua-output/ scripts: # - script1.lua Logging configuration. This is not about logging IDS alerts/events, but output about what Suricata is doing, like startup messages, errors, etc. logging: # The default log level, can be overridden in an output section. # Note that debug level logging will only be emitted if Suricata was # compiled with the --enable-debug configure option. # # This value is overriden by the SC_LOG_LEVEL env var. default-log-level: notice # The default output format. Optional parameter, should default to # something reasonable if not provided. Can be overriden in an # output section. You can leave this out to get the default. # # This value is overriden by the SC_LOG_FORMAT env var. #default-log-format: "[%i] %t - (%f:%l) <%d> (%n) -- " # A regex to filter output. Can be overridden in an output section. # Defaults to empty (no filter). # # This value is overriden by the SC_LOG_OP_FILTER env var. default-output-filter: # Define your logging outputs. If none are defined, or they are all # disabled you will get the default - console output. outputs: - console: enabled: yes # type: json - file: enabled: yes level: info filename: /var/log/suricata/suricata.log # type: json - syslog: enabled: no facility: local5 format: "[%i] <%d> -- " # type: json ## Step 4: configure common capture settings ## See "Advanced Capture Options" below for more options, including NETMAP and PF_RING. ## Linux high speed capture support af-packet: - interface: enp0s3 # Number of receive threads. "auto" uses the number of cores #threads: auto # Default clusterid. AF_PACKET will load balance packets based on flow. cluster-id: 99 # 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_round_robin: round robin load balancing # * cluster_flow: all packets of a given flow are send to the same socket # * cluster_cpu: all packets treated in kernel by a CPU are send 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_random: packets are sent randomly to sockets but with an equipartition. # Requires at least Linux 3.14. # * cluster_rollover: kernel rotates between sockets filling each socket before moving # to the next. Requires at least Linux 3.10. # Recommended modes are cluster_flow on most boxes and cluster_cpu or cluster_qm on system # with capture card using RSS (require cpu affinity tuning and system irq tuning) cluster-type: cluster_flow # In some fragmentation case, 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 # After Linux kernel 3.10 it is possible to activate the rollover option: if a socket is # full then kernel will send the packet on the next socket with room available. This option # can minimize packet drop and increase the treated bandwidth on single intensive flow. #rollover: yes # To use the ring feature of AF_PACKET, set 'use-mmap' to yes #use-mmap: yes # Lock memory map to avoid it goes to swap. Be careful that over suscribing could lock # your system #mmap-locked: yes # Use tpacket_v3 capture mode, only active if use-mmap is true # Don't use it in IPS or TAP mode as it causes severe latency #tpacket-v3: yes # Ring size will be computed with respect to max_pending_packets and number # of threads. You can set manually the ring size in number of packets by setting # the following value. If you are using flow cluster-type and have really network # intensive single-flow you could want to set the ring-size independently of the number # of threads: #ring-size: 2048 # Block size is used by tpacket_v3 only. It should set to a value high enough to contain # a decent number of packets. Size is in bytes so please consider your MTU. It should be # a power of 2 and it must be multiple of page size (usually 4096). #block-size: 32768 # tpacket_v3 block timeout: an open block is passed to userspace if it is not # filled after block-timeout milliseconds. #block-timeout: 10 # On busy system, this could help to set it to yes to recover from a packet drop # phase. This will result in some packets (at max a ring flush) being non treated. #use-emergency-flush: yes # recv buffer size, increase value could improve performance # buffer-size: 32768 # Set to yes to disable promiscuous mode # disable-promisc: no # Choose checksum verification mode for the interface. At the moment # of the capture, some packets may be with an invalid checksum due to # offloading to the network card of the checksum computation. # Possible values are: # - kernel: use indication sent by kernel for each packet (default) # - yes: checksum validation is forced # - no: checksum validation is disabled # - auto: suricata uses a statistical approach to detect when # checksum off-loading is used. # Warning: 'checksum-validation' must be set to yes to have any validation #checksum-checks: kernel # BPF filter to apply to this interface. The pcap filter syntax apply here. #bpf-filter: port 80 or udp # You can use the following variables to activate AF_PACKET tap or IPS mode. # If copy-mode is set to ips or tap, the traffic coming to the current # interface will be copied to the copy-iface interface. If 'tap' is set, the # copy is complete. If 'ips' is set, the packet matching a 'drop' action # will not be copied. #copy-mode: ips #copy-iface: eth1 # Put default values here. These will be used for an interface that is not # in the list above. - interface: default #threads: auto #use-mmap: no #rollover: yes #tpacket-v3: yes Cross platform libpcap capture support pcap: - interface: enp0s3 # On Linux, pcap will try to use mmaped capture and will use buffer-size # as total of memory used by the ring. So set this to something bigger # than 1% of your bandwidth. #buffer-size: 16777216 #bpf-filter: "tcp and port 25" # Choose checksum verification mode for the interface. At the moment # of the capture, some packets may be with an invalid checksum due to # offloading to the network card of the checksum computation. # 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 any validation #checksum-checks: auto # With some accelerator cards using a modified libpcap (like myricom), you # may want to have the same number of capture threads as the number of capture # rings. In this case, set up the threads variable to N to start N threads # listening on the same interface. #threads: 16 # set to no to disable promiscuous mode: #promisc: no # set snaplen, if not set it defaults to MTU if MTU can be known # via ioctl call and to full capture if not. #snaplen: 1518 # Put default values here - interface: default #checksum-checks: auto 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 5: App Layer Protocol Configuration ## Configure the app-layer parsers. The protocols 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: protocols: tls: enabled: yes detection-ports: dp: 443 # Completely stop processing TLS/SSL session after the handshake # completed. If bypass is enabled this will also trigger flow # bypass. If disabled (the default), TLS/SSL session is still # tracked for Heartbleed and other anomalies. #no-reassemble: yes dcerpc: enabled: yes ftp: enabled: yes ssh: enabled: yes smtp: enabled: yes # Configure SMTP-MIME Decoder mime: # Decode MIME messages from SMTP transactions # (may be resource intensive) # This field supercedes 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 msn: enabled: detection-only smb: enabled: yes detection-ports: dp: 139, 445 # smb2 detection is disabled internally inside the engine. #smb2: # enabled: yes # Note: NFS parser depends on Rust support: pass --enable-rust # to configure. nfs: enabled: no dns: # memcaps. Globally and per flow/state. #global-memcap: 16mb #state-memcap: 512kb # How many unreplied DNS requests are considered a flood. # If the limit is reached, app-layer-event:dns.flooded; will match. #request-flood: 500 tcp: enabled: yes detection-ports: dp: 53 udp: enabled: yes detection-ports: dp: 53 http: enabled: yes # memcap: 64mb # 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. # double-decode-path: Double decode path section of the URI # double-decode-query: Double decode query section of the URI # response-body-decompress-layer-limit: # Limit to how many layers of compression will be # decompressed. Defaults to 2. # # server-config: List of server configurations to use if address matches # address: List of ip addresses or networks for this block # personalitiy: List of personalities used by this block # 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. # double-decode-path: Double decode path section of the URI # double-decode-query: Double decode query section of the URI # # uri-include-all: Include all parts of the URI. By default the # 'scheme', username/password, hostname and port # are excluded. Setting this option to true adds # all of them to the normalized uri as inspected # by http_uri, urilen, pcre with /U and the other # keywords that inspect the normalized uri. # Note that this does not affect http_raw_uri. # Also, note that including all was the default in # 1.4 and 2.0beta1. # # meta-field-limit: Hard size limit for request and response size # limits. Applies to request line and headers, # response line and headers. Does not apply to # request or response bodies. Default is 18k. # If this limit is reached an event is raised. # # 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 # Take a random value for inspection sizes around the specified value. # This lower the risk of some evasion technics but could lead # 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 choosen in 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 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 poor significant 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 positive modbus: # How many unreplied Modbus requests are considered a flood. # If the limit is reached, 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 # Note: parser depends on experimental Rust support # with --enable-rust-experimental passed to configure ntp: enabled: no Limit for the maximum number of asn1 frames to decode (default 256) asn1-max-frames: 256 ############################################################################## ## Advanced settings below ## ############################################################################## ## Run Options ## Run suricata as user and group. #run-as: user: suri group: suri Some logging module 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: /usr/local/var/run/suricata.pid Daemon working directory Suricata will change directory to this one if provided Default: "/" #daemon-directory: "/" 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 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 switch 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. # If you are using the CUDA pattern matcher (mpm-algo: ac-cuda), different rules apply. In that case try something like 60000 or more. This is because the CUDA pattern matcher buffers and scans as many packets as possible in parallel. #max-pending-packets: 1024 Runmode the engine should use. Please check --list-runmodes to get the available runmodes for each packet acquisition method. Defaults to "autofp" (auto flow pinned load balancing). #runmode: autofp Specifies the kind of flow load balancer used by the flow pinned autofp mode. # Supported schedulers are: # round-robin - Flows assigned to threads in a round robin fashion. active-packets - Flows assigned to threads that have the lowest number of unprocessed packets (default). hash - Flow alloted usihng the address hash. More of a random technique. Was the default in Suricata 1.2.1 and older. # #autofp-scheduler: active-packets Preallocated size for 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 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: auto #filename: custom.socket Magic file. The extension .mgc is added to the value here. #magic-file: /usr/share/file/magic #magic-file: legacy: uricontent: enabled ## Detection settings ## Set the order of alerts bassed on actions The default order is pass, drop, reject, alert action-order: - pass - drop - reject - alert IP Reputation #reputation-categories-file: /usr/local/etc/suricata/iprep/categories.txt #default-reputation-path: /usr/local/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: [192.168.1.0/24, 192.168.1.25] old-solaris: [] solaris: [] hpux10: [] hpux11: [] irix: [] macos: [] vista: [] windows2k3: [] Defrag settings: defrag: memcap: 32mb 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 determine the size of the hash used to identify flows inside the engine, and by default the value is 65536. At the startup, the engine can preallocate a number of flows, to get a better performance. The number of flows preallocated is 10000 by default. emergency-recovery is the percentage of flows that the engine need to prune before unsetting the emergency state. The emergency state is activated when the memcap limit is reached, allowing to create new flows, but prunning 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 doens't find a flow to prune, it will set the emergency bit and it will try again with more agressive timeouts. If that doesn't work, then it will try to kill the last time seen flows not in use. The memcap can be specified in kb, mb, gb. Just a number indicates it's in bytes. flow: memcap: 128mb 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" determine the seconds to wait after a hanshake or stream startup before the engine free 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 it spend that amount 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: 32mb # Can be specified in kb, mb, gb. Just a # number indicates it's in bytes. checksum-validation: yes # To validate the checksum of received # packet. If csum validation is specified as # "yes", then packet with invalid csum will not # be processed by the engine stream/app layer. # Warning: locally generated trafic 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 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.depth is reached # reassembly: memcap: 64mb # Can be specified in kb, mb, gb. Just a number # indicates it's in bytes. 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 lower the risk of some evasion technics but could lead # 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 checksum-validation: yes # reject wrong csums inline: auto # auto will use inline mode in IPS mode, yes or no set it statically reassembly: memcap: 256mb 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 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 # it will sometimes detect non-teredo as teredo. teredo: enabled: true ## Performance tuning and profiling ## The detection engine builds internal groups of signatures. The engine allow us to specify the profile to use for them, to manage memory on an efficient way keeping a 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 at "- custom-values" as your convenience. 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. On not specifying a value, we use 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 it's 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-cuda" - Aho-Corasick, CUDA 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 one's memory, in which case one can use "full" with "ac". Rest of the mpms can be run in "full" mode. # There is also a CUDA pattern matcher (only available if Suricata was compiled with --enable-cuda: b2g_cuda. Make sure to update your max-pending-packets setting above as well if you use b2g_cuda. 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 # on 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 explicitely 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 Luajit has a strange memory requirement, it's '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 the --enable-profiling configure flag. # profiling: # Run profiling for every xth 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 # 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 permit to do send all needed packet to suricata via this a 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 packet to be sent to another queue after an ACCEPT decision set 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 packet to queue inside kernel qthreshold: 1 # set the delay before flushing packet in the queue inside kernel 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 exists. # 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 wich have built-in netmap support or compile and install netmap module and appropriate NIC driver on your Linux system. To reach maximum throughput disable all receive-, segmentation-, checksum- offloadings on NIC. 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: # To specify OS endpoint add plus sign at the end (e.g. "eth0+") - interface: eth2 # Number of receive threads. "auto" uses number of RSS queues on interface. #threads: auto # You can use the following variables to activate netmap tap or IPS mode. # If copy-mode is set to ips or tap, the traffic coming to the current # interface will be copied to the copy-iface interface. If 'tap' is set, the # copy is complete. If 'ips' is set, the packet matching a 'drop' action # will not be copied. # To specify the OS as the copy-iface (so the OS can route packets, or forward # to a service running on the same machine) add a plus sign at the end # (e.g. "copy-iface: eth0+"). Don't forget to set up a symmetrical eth0+ -> eth0 # for return packets. Hardware checksumming must be off on the interface if # using an OS endpoint (e.g. 'ifconfig eth0 -rxcsum -txcsum -rxcsum6 -txcsum6' for FreeBSD # or 'ethtool -K eth0 tx off rx off' for Linux). #copy-mode: tap #copy-iface: eth3 # Set to yes to disable promiscuous mode # disable-promisc: no # Choose checksum verification mode for the interface. At the moment # of the capture, some packets may be with an invalid checksum due to # offloading to the network card of the checksum computation. # 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. # Warning: 'checksum-validation' must be set to yes to have any validation #checksum-checks: auto # BPF filter to apply to this interface. The pcap filter syntax apply here. #bpf-filter: port 80 or udp #- interface: eth3 #threads: auto #copy-mode: tap #copy-iface: eth2 # Put default values here - 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: eth0 # Number of receive threads (>1 will enable experimental flow pinned # runmode) threads: 1 # Default clusterid. PF_RING will load balance packets based on flow. # All threads/processes that will participate need to have the same # clusterid. cluster-id: 99 # Default PF_RING cluster type. PF_RING can load balance per flow. # Possible values are cluster_flow or cluster_round_robin. cluster-type: cluster_flow # bpf filter for this interface #bpf-filter: tcp # Choose checksum verification mode for the interface. At the moment # of the capture, some packets may be with an invalid checksum due to # offloading to the network card of the checksum computation. # Possible values are: # - rxonly: only compute checksum for packets received by network card. # - 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 any validation #checksum-checks: auto # Second interface #- interface: eth1 # threads: 3 # cluster-id: 93 # cluster-type: cluster_flow # Put default values here - 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 # The 8000 above should be the same number 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: # The Host Buffer Allowance for all streams # (-1 = OFF, 1 - 100 = percentage of the host buffer that can be held back) # This may be enabled when sharing streams with another application. # Otherwise, it should be turned off. hba: -1 # use_all_streams set to "yes" 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. use-all-streams: yes # The streams to listen on. This can be either: # a list of individual streams (e.g. streams: [0,1,2,3]) # or # a range of streams (e.g. streams: ["0-3"]) streams: ["0-3"] Tilera mpipe configuration. for use on Tilera TILE-Gx. mpipe: # Load balancing modes: "static", "dynamic", "sticky", or "round-robin". load-balance: dynamic # Number of Packets in each ingress packet queue. Must be 128, 512, 2028 or 65536 iqueue-packets: 2048 # List of interfaces we will listen on. inputs: - interface: xgbe2 - interface: xgbe3 - interface: xgbe4 # Relative weight of memory for packets of each mPipe buffer size. stack: size128: 0 size256: 9 size512: 0 size1024: 0 size1664: 7 size4096: 0 size10386: 0 size16384: 0 ## Hardware accelaration ## Cuda configuration. cuda: # The "mpm" profile. On not specifying any of these parameters, the engine's # internal default values are used, which are same as the ones specified in # in the default conf file. mpm: # The minimum length required to buffer data to the gpu. # Anything below this is MPM'ed on the CPU. # Can be specified in kb, mb, gb. Just a number indicates it's in bytes. # A value of 0 indicates there's no limit. data-buffer-size-min-limit: 0 # The maximum length for data that we would buffer to the gpu. # Anything over this is MPM'ed on the CPU. # Can be specified in kb, mb, gb. Just a number indicates it's in bytes. data-buffer-size-max-limit: 1500 # The ring buffer size used by the CudaBuffer API to buffer data. cudabuffer-buffer-size: 500mb # The max chunk size that can be sent to the gpu in a single go. gpu-transfer-size: 50mb # The timeout limit for batching of packets in microseconds. batching-timeout: 2000 # The device to use for the mpm. Currently we don't support load balancing # on multiple gpus. In case you have multiple devices on your system, you # can specify the device to use, using this conf. By default we hold 0, to # specify the first device cuda sees. To find out device-id associated with # the card(s) on the system run "suricata --list-cuda-cards". device-id: 0 # No of Cuda streams used for asynchronous processing. All values > 0 are valid. # For this option you need a device with Compute Capability > 1.0. cuda-streams: 2 ## Include other configs ## Includes. Files included here will be handled as if they were inlined in this configuration file. #include: include1.yaml #include: include2.yaml </pre> what can i do to resolve this error.