ECS fields

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This section defines Elastic Common Schema (ECS) fields—a common set of fields to be used when storing event data in Elasticsearch.

This is an exhaustive list, and fields listed here are not necessarily used by Journalbeat. The goal of ECS is to enable and encourage users of Elasticsearch to normalize their event data, so that they can better analyze, visualize, and correlate the data represented in their events.

See the ECS reference for more information.

@timestamp

Date/time when the event originated. This is the date/time extracted from the event, typically representing when the event was generated by the source. If the event source has no original timestamp, this value is typically populated by the first time the event was received by the pipeline. Required field for all events.

type: date

example: 2016-05-23T08:05:34.853Z

required: True

labels

Custom key/value pairs. Can be used to add meta information to events. Should not contain nested objects. All values are stored as keyword. Example: docker and k8s labels.

type: object

example: {"application": "foo-bar", "env": "production"}

message

For log events the message field contains the log message, optimized for viewing in a log viewer. For structured logs without an original message field, other fields can be concatenated to form a human-readable summary of the event. If multiple messages exist, they can be combined into one message.

type: text

example: Hello World

tags

List of keywords used to tag each event.

type: keyword

example: ["production", "env2"]

agent

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The agent fields contain the data about the software entity, if any, that collects, detects, or observes events on a host, or takes measurements on a host. Examples include Beats. Agents may also run on observers. ECS agent.* fields shall be populated with details of the agent running on the host or observer where the event happened or the measurement was taken.

agent.build.original

Extended build information for the agent. This field is intended to contain any build information that a data source may provide, no specific formatting is required.

type: keyword

example: metricbeat version 7.6.0 (amd64), libbeat 7.6.0 [6a23e8f8f30f5001ba344e4e54d8d9cb82cb107c built 2020-02-05 23:10:10 +0000 UTC]

agent.ephemeral_id

Ephemeral identifier of this agent (if one exists). This id normally changes across restarts, but agent.id does not.

type: keyword

example: 8a4f500f

agent.id

Unique identifier of this agent (if one exists). Example: For Beats this would be beat.id.

type: keyword

example: 8a4f500d

agent.name

Custom name of the agent. This is a name that can be given to an agent. This can be helpful if for example two Filebeat instances are running on the same host but a human readable separation is needed on which Filebeat instance data is coming from. If no name is given, the name is often left empty.

type: keyword

example: foo

agent.type

Type of the agent. The agent type always stays the same and should be given by the agent used. In case of Filebeat the agent would always be Filebeat also if two Filebeat instances are run on the same machine.

type: keyword

example: filebeat

agent.version

Version of the agent.

type: keyword

example: 6.0.0-rc2

An autonomous system (AS) is a collection of connected Internet Protocol (IP) routing prefixes under the control of one or more network operators on behalf of a single administrative entity or domain that presents a common, clearly defined routing policy to the internet.

as.number

Unique number allocated to the autonomous system. The autonomous system number (ASN) uniquely identifies each network on the Internet.

type: long

example: 15169

as.organization.name

Organization name.

type: keyword

example: Google LLC

as.organization.name.text

type: text

client

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A client is defined as the initiator of a network connection for events regarding sessions, connections, or bidirectional flow records. For TCP events, the client is the initiator of the TCP connection that sends the SYN packet(s). For other protocols, the client is generally the initiator or requestor in the network transaction. Some systems use the term "originator" to refer the client in TCP connections. The client fields describe details about the system acting as the client in the network event. Client fields are usually populated in conjunction with server fields. Client fields are generally not populated for packet-level events. Client / server representations can add semantic context to an exchange, which is helpful to visualize the data in certain situations. If your context falls in that category, you should still ensure that source and destination are filled appropriately.

client.address

Some event client addresses are defined ambiguously. The event will sometimes list an IP, a domain or a unix socket. You should always store the raw address in the .address field. Then it should be duplicated to .ip or .domain, depending on which one it is.

type: keyword

client.as.number

Unique number allocated to the autonomous system. The autonomous system number (ASN) uniquely identifies each network on the Internet.

type: long

example: 15169

client.as.organization.name

Organization name.

type: keyword

example: Google LLC

client.as.organization.name.text

type: text

client.bytes

Bytes sent from the client to the server.

type: long

example: 184

format: bytes

client.domain

Client domain.

type: keyword

client.geo.city_name

City name.

type: keyword

example: Montreal

client.geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

client.geo.continent_name

Name of the continent.

type: keyword

example: North America

client.geo.country_iso_code

Country ISO code.

type: keyword

example: CA

client.geo.country_name

Country name.

type: keyword

example: Canada

client.geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

client.geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

client.geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

client.geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

client.geo.region_name

Region name.

type: keyword

example: Quebec

client.geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

client.ip

IP address of the client (IPv4 or IPv6).

type: ip

client.mac

MAC address of the client. The notation format from RFC 7042 is suggested: Each octet (that is, 8-bit byte) is represented by two [uppercase] hexadecimal digits giving the value of the octet as an unsigned integer. Successive octets are separated by a hyphen.

type: keyword

example: 00-00-5E-00-53-23

client.nat.ip

Translated IP of source based NAT sessions (e.g. internal client to internet). Typically connections traversing load balancers, firewalls, or routers.

type: ip

client.nat.port

Translated port of source based NAT sessions (e.g. internal client to internet). Typically connections traversing load balancers, firewalls, or routers.

type: long

format: string

client.packets

Packets sent from the client to the server.

type: long

example: 12

client.port

Port of the client.

type: long

format: string

client.registered_domain

The highest registered client domain, stripped of the subdomain. For example, the registered domain for "foo.example.com" is "example.com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last two labels will not work well for TLDs such as "co.uk".

type: keyword

example: example.com

client.subdomain

The subdomain portion of a fully qualified domain name includes all of the names except the host name under the registered_domain. In a partially qualified domain, or if the the qualification level of the full name cannot be determined, subdomain contains all of the names below the registered domain. For example the subdomain portion of "www.east.mydomain.co.uk" is "east". If the domain has multiple levels of subdomain, such as "sub2.sub1.example.com", the subdomain field should contain "sub2.sub1", with no trailing period.

type: keyword

example: east

client.top_level_domain

The effective top level domain (eTLD), also known as the domain suffix, is the last part of the domain name. For example, the top level domain for example.com is "com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last label will not work well for effective TLDs such as "co.uk".

type: keyword

example: co.uk

client.user.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

client.user.email

User email address.

type: keyword

client.user.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

client.user.full_name.text

type: text

client.user.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

client.user.group.id

Unique identifier for the group on the system/platform.

type: keyword

client.user.group.name

Name of the group.

type: keyword

client.user.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

client.user.id

Unique identifier of the user.

type: keyword

client.user.name

Short name or login of the user.

type: keyword

example: albert

client.user.name.text

type: text

client.user.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

cloud

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Fields related to the cloud or infrastructure the events are coming from.

cloud.account.id

The cloud account or organization id used to identify different entities in a multi-tenant environment. Examples: AWS account id, Google Cloud ORG Id, or other unique identifier.

type: keyword

example: 666777888999

cloud.account.name

The cloud account name or alias used to identify different entities in a multi-tenant environment. Examples: AWS account name, Google Cloud ORG display name.

type: keyword

example: elastic-dev

cloud.availability_zone

Availability zone in which this host, resource, or service is located.

type: keyword

example: us-east-1c

cloud.instance.id

Instance ID of the host machine.

type: keyword

example: i-1234567890abcdef0

cloud.instance.name

Instance name of the host machine.

type: keyword

cloud.machine.type

Machine type of the host machine.

type: keyword

example: t2.medium

cloud.project.id

The cloud project identifier. Examples: Google Cloud Project id, Azure Project id.

type: keyword

example: my-project

cloud.project.name

The cloud project name. Examples: Google Cloud Project name, Azure Project name.

type: keyword

example: my project

cloud.provider

Name of the cloud provider. Example values are aws, azure, gcp, or digitalocean.

type: keyword

example: aws

cloud.region

Region in which this host, resource, or service is located.

type: keyword

example: us-east-1

cloud.service.name

The cloud service name is intended to distinguish services running on different platforms within a provider, eg AWS EC2 vs Lambda, GCP GCE vs App Engine, Azure VM vs App Server. Examples: app engine, app service, cloud run, fargate, lambda.

type: keyword

example: lambda

code_signature

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These fields contain information about binary code signatures.

code_signature.exists

Boolean to capture if a signature is present.

type: boolean

example: true

code_signature.signing_id

The identifier used to sign the process. This is used to identify the application manufactured by a software vendor. The field is relevant to Apple *OS only.

type: keyword

example: com.apple.xpc.proxy

code_signature.status

Additional information about the certificate status. This is useful for logging cryptographic errors with the certificate validity or trust status. Leave unpopulated if the validity or trust of the certificate was unchecked.

type: keyword

example: ERROR_UNTRUSTED_ROOT

code_signature.subject_name

Subject name of the code signer

type: keyword

example: Microsoft Corporation

code_signature.team_id

The team identifier used to sign the process. This is used to identify the team or vendor of a software product. The field is relevant to Apple *OS only.

type: keyword

example: EQHXZ8M8AV

code_signature.trusted

Stores the trust status of the certificate chain. Validating the trust of the certificate chain may be complicated, and this field should only be populated by tools that actively check the status.

type: boolean

example: true

code_signature.valid

Boolean to capture if the digital signature is verified against the binary content. Leave unpopulated if a certificate was unchecked.

type: boolean

example: true

container

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Container fields are used for meta information about the specific container that is the source of information. These fields help correlate data based containers from any runtime.

container.id

Unique container id.

type: keyword

container.image.name

Name of the image the container was built on.

type: keyword

container.image.tag

Container image tags.

type: keyword

container.labels

Image labels.

type: object

container.name

Container name.

type: keyword

container.runtime

Runtime managing this container.

type: keyword

example: docker

data_stream

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The data_stream fields take part in defining the new data stream naming scheme. In the new data stream naming scheme the value of the data stream fields combine to the name of the actual data stream in the following manner: {data_stream.type}-{data_stream.dataset}-{data_stream.namespace}. This means the fields can only contain characters that are valid as part of names of data streams. More details about this can be found in this blog post. An Elasticsearch data stream consists of one or more backing indices, and a data stream name forms part of the backing indices names. Due to this convention, data streams must also follow index naming restrictions. For example, data stream names cannot include \, /, *, ?, ", <, >, |, ` ` (space character), ,, or #. Please see the Elasticsearch reference for additional restrictions.

data_stream.dataset

The field can contain anything that makes sense to signify the source of the data. Examples include nginx.access, prometheus, endpoint etc. For data streams that otherwise fit, but that do not have dataset set we use the value "generic" for the dataset value. event.dataset should have the same value as data_stream.dataset. Beyond the Elasticsearch data stream naming criteria noted above, the dataset value has additional restrictions: * Must not contain - * No longer than 100 characters

type: constant_keyword

example: nginx.access

data_stream.namespace

A user defined namespace. Namespaces are useful to allow grouping of data. Many users already organize their indices this way, and the data stream naming scheme now provides this best practice as a default. Many users will populate this field with default. If no value is used, it falls back to default. Beyond the Elasticsearch index naming criteria noted above, namespace value has the additional restrictions: * Must not contain - * No longer than 100 characters

type: constant_keyword

example: production

data_stream.type

An overarching type for the data stream. Currently allowed values are "logs" and "metrics". We expect to also add "traces" and "synthetics" in the near future.

type: constant_keyword

example: logs

destination

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Destination fields capture details about the receiver of a network exchange/packet. These fields are populated from a network event, packet, or other event containing details of a network transaction. Destination fields are usually populated in conjunction with source fields. The source and destination fields are considered the baseline and should always be filled if an event contains source and destination details from a network transaction. If the event also contains identification of the client and server roles, then the client and server fields should also be populated.

destination.address

Some event destination addresses are defined ambiguously. The event will sometimes list an IP, a domain or a unix socket. You should always store the raw address in the .address field. Then it should be duplicated to .ip or .domain, depending on which one it is.

type: keyword

destination.as.number

Unique number allocated to the autonomous system. The autonomous system number (ASN) uniquely identifies each network on the Internet.

type: long

example: 15169

destination.as.organization.name

Organization name.

type: keyword

example: Google LLC

destination.as.organization.name.text

type: text

destination.bytes

Bytes sent from the destination to the source.

type: long

example: 184

format: bytes

destination.domain

Destination domain.

type: keyword

destination.geo.city_name

City name.

type: keyword

example: Montreal

destination.geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

destination.geo.continent_name

Name of the continent.

type: keyword

example: North America

destination.geo.country_iso_code

Country ISO code.

type: keyword

example: CA

destination.geo.country_name

Country name.

type: keyword

example: Canada

destination.geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

destination.geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

destination.geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

destination.geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

destination.geo.region_name

Region name.

type: keyword

example: Quebec

destination.geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

destination.ip

IP address of the destination (IPv4 or IPv6).

type: ip

destination.mac

MAC address of the destination. The notation format from RFC 7042 is suggested: Each octet (that is, 8-bit byte) is represented by two [uppercase] hexadecimal digits giving the value of the octet as an unsigned integer. Successive octets are separated by a hyphen.

type: keyword

example: 00-00-5E-00-53-23

destination.nat.ip

Translated ip of destination based NAT sessions (e.g. internet to private DMZ) Typically used with load balancers, firewalls, or routers.

type: ip

destination.nat.port

Port the source session is translated to by NAT Device. Typically used with load balancers, firewalls, or routers.

type: long

format: string

destination.packets

Packets sent from the destination to the source.

type: long

example: 12

destination.port

Port of the destination.

type: long

format: string

destination.registered_domain

The highest registered destination domain, stripped of the subdomain. For example, the registered domain for "foo.example.com" is "example.com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last two labels will not work well for TLDs such as "co.uk".

type: keyword

example: example.com

destination.subdomain

The subdomain portion of a fully qualified domain name includes all of the names except the host name under the registered_domain. In a partially qualified domain, or if the the qualification level of the full name cannot be determined, subdomain contains all of the names below the registered domain. For example the subdomain portion of "www.east.mydomain.co.uk" is "east". If the domain has multiple levels of subdomain, such as "sub2.sub1.example.com", the subdomain field should contain "sub2.sub1", with no trailing period.

type: keyword

example: east

destination.top_level_domain

The effective top level domain (eTLD), also known as the domain suffix, is the last part of the domain name. For example, the top level domain for example.com is "com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last label will not work well for effective TLDs such as "co.uk".

type: keyword

example: co.uk

destination.user.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

destination.user.email

User email address.

type: keyword

destination.user.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

destination.user.full_name.text

type: text

destination.user.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

destination.user.group.id

Unique identifier for the group on the system/platform.

type: keyword

destination.user.group.name

Name of the group.

type: keyword

destination.user.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

destination.user.id

Unique identifier of the user.

type: keyword

destination.user.name

Short name or login of the user.

type: keyword

example: albert

destination.user.name.text

type: text

destination.user.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

dll

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These fields contain information about code libraries dynamically loaded into processes.

Many operating systems refer to "shared code libraries" with different names, but this field set refers to all of the following: * Dynamic-link library (.dll) commonly used on Windows * Shared Object (.so) commonly used on Unix-like operating systems * Dynamic library (.dylib) commonly used on macOS

dll.code_signature.exists

Boolean to capture if a signature is present.

type: boolean

example: true

dll.code_signature.signing_id

The identifier used to sign the process. This is used to identify the application manufactured by a software vendor. The field is relevant to Apple *OS only.

type: keyword

example: com.apple.xpc.proxy

dll.code_signature.status

Additional information about the certificate status. This is useful for logging cryptographic errors with the certificate validity or trust status. Leave unpopulated if the validity or trust of the certificate was unchecked.

type: keyword

example: ERROR_UNTRUSTED_ROOT

dll.code_signature.subject_name

Subject name of the code signer

type: keyword

example: Microsoft Corporation

dll.code_signature.team_id

The team identifier used to sign the process. This is used to identify the team or vendor of a software product. The field is relevant to Apple *OS only.

type: keyword

example: EQHXZ8M8AV

dll.code_signature.trusted

Stores the trust status of the certificate chain. Validating the trust of the certificate chain may be complicated, and this field should only be populated by tools that actively check the status.

type: boolean

example: true

dll.code_signature.valid

Boolean to capture if the digital signature is verified against the binary content. Leave unpopulated if a certificate was unchecked.

type: boolean

example: true

dll.hash.md5

MD5 hash.

type: keyword

dll.hash.sha1

SHA1 hash.

type: keyword

dll.hash.sha256

SHA256 hash.

type: keyword

dll.hash.sha512

SHA512 hash.

type: keyword

dll.hash.ssdeep

SSDEEP hash.

type: keyword

dll.name

Name of the library. This generally maps to the name of the file on disk.

type: keyword

example: kernel32.dll

dll.path

Full file path of the library.

type: keyword

example: C:\Windows\System32\kernel32.dll

dll.pe.architecture

CPU architecture target for the file.

type: keyword

example: x64

dll.pe.company

Internal company name of the file, provided at compile-time.

type: keyword

example: Microsoft Corporation

dll.pe.description

Internal description of the file, provided at compile-time.

type: keyword

example: Paint

dll.pe.file_version

Internal version of the file, provided at compile-time.

type: keyword

example: 6.3.9600.17415

dll.pe.imphash

A hash of the imports in a PE file. An imphash — or import hash — can be used to fingerprint binaries even after recompilation or other code-level transformations have occurred, which would change more traditional hash values. Learn more at https://www.fireeye.com/blog/threat-research/2014/01/tracking-malware-import-hashing.html.

type: keyword

example: 0c6803c4e922103c4dca5963aad36ddf

dll.pe.original_file_name

Internal name of the file, provided at compile-time.

type: keyword

example: MSPAINT.EXE

dll.pe.product

Internal product name of the file, provided at compile-time.

type: keyword

example: Microsoft® Windows® Operating System

dns

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Fields describing DNS queries and answers. DNS events should either represent a single DNS query prior to getting answers (dns.type:query) or they should represent a full exchange and contain the query details as well as all of the answers that were provided for this query (dns.type:answer).

dns.answers

An array containing an object for each answer section returned by the server. The main keys that should be present in these objects are defined by ECS. Records that have more information may contain more keys than what ECS defines. Not all DNS data sources give all details about DNS answers. At minimum, answer objects must contain the data key. If more information is available, map as much of it to ECS as possible, and add any additional fields to the answer objects as custom fields.

type: object

dns.answers.class

The class of DNS data contained in this resource record.

type: keyword

example: IN

dns.answers.data

The data describing the resource. The meaning of this data depends on the type and class of the resource record.

type: keyword

example: 10.10.10.10

dns.answers.name

The domain name to which this resource record pertains. If a chain of CNAME is being resolved, each answer’s name should be the one that corresponds with the answer’s data. It should not simply be the original question.name repeated.

type: keyword

example: www.example.com

dns.answers.ttl

The time interval in seconds that this resource record may be cached before it should be discarded. Zero values mean that the data should not be cached.

type: long

example: 180

dns.answers.type

The type of data contained in this resource record.

type: keyword

example: CNAME

dns.header_flags

Array of 2 letter DNS header flags. Expected values are: AA, TC, RD, RA, AD, CD, DO.

type: keyword

example: ["RD", "RA"]

dns.id

The DNS packet identifier assigned by the program that generated the query. The identifier is copied to the response.

type: keyword

example: 62111

dns.op_code

The DNS operation code that specifies the kind of query in the message. This value is set by the originator of a query and copied into the response.

type: keyword

example: QUERY

dns.question.class

The class of records being queried.

type: keyword

example: IN

dns.question.name

The name being queried. If the name field contains non-printable characters (below 32 or above 126), those characters should be represented as escaped base 10 integers (\DDD). Back slashes and quotes should be escaped. Tabs, carriage returns, and line feeds should be converted to \t, \r, and \n respectively.

type: keyword

example: www.example.com

dns.question.registered_domain

The highest registered domain, stripped of the subdomain. For example, the registered domain for "foo.example.com" is "example.com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last two labels will not work well for TLDs such as "co.uk".

type: keyword

example: example.com

dns.question.subdomain

The subdomain is all of the labels under the registered_domain. If the domain has multiple levels of subdomain, such as "sub2.sub1.example.com", the subdomain field should contain "sub2.sub1", with no trailing period.

type: keyword

example: www

dns.question.top_level_domain

The effective top level domain (eTLD), also known as the domain suffix, is the last part of the domain name. For example, the top level domain for example.com is "com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last label will not work well for effective TLDs such as "co.uk".

type: keyword

example: co.uk

dns.question.type

The type of record being queried.

type: keyword

example: AAAA

dns.resolved_ip

Array containing all IPs seen in answers.data. The answers array can be difficult to use, because of the variety of data formats it can contain. Extracting all IP addresses seen in there to dns.resolved_ip makes it possible to index them as IP addresses, and makes them easier to visualize and query for.

type: ip

example: ["10.10.10.10", "10.10.10.11"]

dns.response_code

The DNS response code.

type: keyword

example: NOERROR

dns.type

The type of DNS event captured, query or answer. If your source of DNS events only gives you DNS queries, you should only create dns events of type dns.type:query. If your source of DNS events gives you answers as well, you should create one event per query (optionally as soon as the query is seen). And a second event containing all query details as well as an array of answers.

type: keyword

example: answer

ecs

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Meta-information specific to ECS.

ecs.version

ECS version this event conforms to. ecs.version is a required field and must exist in all events. When querying across multiple indices — which may conform to slightly different ECS versions — this field lets integrations adjust to the schema version of the events.

type: keyword

example: 1.0.0

required: True

elf

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These fields contain Linux Executable Linkable Format (ELF) metadata.

elf.architecture

Machine architecture of the ELF file.

type: keyword

example: x86-64

elf.byte_order

Byte sequence of ELF file.

type: keyword

example: Little Endian

elf.cpu_type

CPU type of the ELF file.

type: keyword

example: Intel

elf.creation_date

Extracted when possible from the file’s metadata. Indicates when it was built or compiled. It can also be faked by malware creators.

type: date

elf.exports

List of exported element names and types.

type: flattened

elf.header.abi_version

Version of the ELF Application Binary Interface (ABI).

type: keyword

elf.header.class

Header class of the ELF file.

type: keyword

elf.header.data

Data table of the ELF header.

type: keyword

elf.header.entrypoint

Header entrypoint of the ELF file.

type: long

format: string

elf.header.object_version

"0x1" for original ELF files.

type: keyword

elf.header.os_abi

Application Binary Interface (ABI) of the Linux OS.

type: keyword

elf.header.type

Header type of the ELF file.

type: keyword

elf.header.version

Version of the ELF header.

type: keyword

elf.imports

List of imported element names and types.

type: flattened

elf.sections

An array containing an object for each section of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.sections.*.

type: nested

elf.sections.chi2

Chi-square probability distribution of the section.

type: long

format: number

elf.sections.entropy

Shannon entropy calculation from the section.

type: long

format: number

elf.sections.flags

ELF Section List flags.

type: keyword

elf.sections.name

ELF Section List name.

type: keyword

elf.sections.physical_offset

ELF Section List offset.

type: keyword

elf.sections.physical_size

ELF Section List physical size.

type: long

format: bytes

elf.sections.type

ELF Section List type.

type: keyword

elf.sections.virtual_address

ELF Section List virtual address.

type: long

format: string

elf.sections.virtual_size

ELF Section List virtual size.

type: long

format: string

elf.segments

An array containing an object for each segment of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.segments.*.

type: nested

elf.segments.sections

ELF object segment sections.

type: keyword

elf.segments.type

ELF object segment type.

type: keyword

elf.shared_libraries

List of shared libraries used by this ELF object.

type: keyword

elf.telfhash

telfhash symbol hash for ELF file.

type: keyword

error

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These fields can represent errors of any kind. Use them for errors that happen while fetching events or in cases where the event itself contains an error.

error.code

Error code describing the error.

type: keyword

error.id

Unique identifier for the error.

type: keyword

error.message

Error message.

type: text

error.stack_trace

The stack trace of this error in plain text.

type: keyword

Field is not indexed.

error.stack_trace.text

type: text

error.type

The type of the error, for example the class name of the exception.

type: keyword

example: java.lang.NullPointerException

event

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The event fields are used for context information about the log or metric event itself. A log is defined as an event containing details of something that happened. Log events must include the time at which the thing happened. Examples of log events include a process starting on a host, a network packet being sent from a source to a destination, or a network connection between a client and a server being initiated or closed. A metric is defined as an event containing one or more numerical measurements and the time at which the measurement was taken. Examples of metric events include memory pressure measured on a host and device temperature. See the event.kind definition in this section for additional details about metric and state events.

event.action

The action captured by the event. This describes the information in the event. It is more specific than event.category. Examples are group-add, process-started, file-created. The value is normally defined by the implementer.

type: keyword

example: user-password-change

event.agent_id_status

Agents are normally responsible for populating the agent.id field value. If the system receiving events is capable of validating the value based on authentication information for the client then this field can be used to reflect the outcome of that validation. For example if the agent’s connection is authenticated with mTLS and the client cert contains the ID of the agent to which the cert was issued then the agent.id value in events can be checked against the certificate. If the values match then event.agent_id_status: verified is added to the event, otherwise one of the other allowed values should be used. If no validation is performed then the field should be omitted. The allowed values are: verified - The agent.id field value matches expected value obtained from auth metadata. mismatch - The agent.id field value does not match the expected value obtained from auth metadata. missing - There was no agent.id field in the event to validate. auth_metadata_missing - There was no auth metadata or it was missing information about the agent ID.

type: keyword

example: verified

event.category

This is one of four ECS Categorization Fields, and indicates the second level in the ECS category hierarchy. event.category represents the "big buckets" of ECS categories. For example, filtering on event.category:process yields all events relating to process activity. This field is closely related to event.type, which is used as a subcategory. This field is an array. This will allow proper categorization of some events that fall in multiple categories.

type: keyword

example: authentication

event.code

Identification code for this event, if one exists. Some event sources use event codes to identify messages unambiguously, regardless of message language or wording adjustments over time. An example of this is the Windows Event ID.

type: keyword

example: 4648

event.created

event.created contains the date/time when the event was first read by an agent, or by your pipeline. This field is distinct from @timestamp in that @timestamp typically contain the time extracted from the original event. In most situations, these two timestamps will be slightly different. The difference can be used to calculate the delay between your source generating an event, and the time when your agent first processed it. This can be used to monitor your agent’s or pipeline’s ability to keep up with your event source. In case the two timestamps are identical, @timestamp should be used.

type: date

example: 2016-05-23T08:05:34.857Z

event.dataset

Name of the dataset. If an event source publishes more than one type of log or events (e.g. access log, error log), the dataset is used to specify which one the event comes from. It’s recommended but not required to start the dataset name with the module name, followed by a dot, then the dataset name.

type: keyword

example: apache.access

event.duration

Duration of the event in nanoseconds. If event.start and event.end are known this value should be the difference between the end and start time.

type: long

format: duration

event.end

event.end contains the date when the event ended or when the activity was last observed.

type: date

event.hash

Hash (perhaps logstash fingerprint) of raw field to be able to demonstrate log integrity.

type: keyword

example: 123456789012345678901234567890ABCD

event.id

Unique ID to describe the event.

type: keyword

example: 8a4f500d

event.ingested

Timestamp when an event arrived in the central data store. This is different from @timestamp, which is when the event originally occurred. It’s also different from event.created, which is meant to capture the first time an agent saw the event. In normal conditions, assuming no tampering, the timestamps should chronologically look like this: @timestamp < event.created < event.ingested.

type: date

example: 2016-05-23T08:05:35.101Z

event.kind

This is one of four ECS Categorization Fields, and indicates the highest level in the ECS category hierarchy. event.kind gives high-level information about what type of information the event contains, without being specific to the contents of the event. For example, values of this field distinguish alert events from metric events. The value of this field can be used to inform how these kinds of events should be handled. They may warrant different retention, different access control, it may also help understand whether the data coming in at a regular interval or not.

type: keyword

example: alert

event.module

Name of the module this data is coming from. If your monitoring agent supports the concept of modules or plugins to process events of a given source (e.g. Apache logs), event.module should contain the name of this module.

type: keyword

example: apache

event.original

Raw text message of entire event. Used to demonstrate log integrity or where the full log message (before splitting it up in multiple parts) may be required, e.g. for reindex. This field is not indexed and doc_values are disabled. It cannot be searched, but it can be retrieved from _source. If users wish to override this and index this field, please see Field data types in the Elasticsearch Reference.

type: keyword

example: Sep 19 08:26:10 host CEF:0|Security| threatmanager|1.0|100| worm successfully stopped|10|src=10.0.0.1 dst=2.1.2.2spt=1232

Field is not indexed.

event.outcome

This is one of four ECS Categorization Fields, and indicates the lowest level in the ECS category hierarchy. event.outcome simply denotes whether the event represents a success or a failure from the perspective of the entity that produced the event. Note that when a single transaction is described in multiple events, each event may populate different values of event.outcome, according to their perspective. Also note that in the case of a compound event (a single event that contains multiple logical events), this field should be populated with the value that best captures the overall success or failure from the perspective of the event producer. Further note that not all events will have an associated outcome. For example, this field is generally not populated for metric events, events with event.type:info, or any events for which an outcome does not make logical sense.

type: keyword

example: success

event.provider

Source of the event. Event transports such as Syslog or the Windows Event Log typically mention the source of an event. It can be the name of the software that generated the event (e.g. Sysmon, httpd), or of a subsystem of the operating system (kernel, Microsoft-Windows-Security-Auditing).

type: keyword

example: kernel

event.reason

Reason why this event happened, according to the source. This describes the why of a particular action or outcome captured in the event. Where event.action captures the action from the event, event.reason describes why that action was taken. For example, a web proxy with an event.action which denied the request may also populate event.reason with the reason why (e.g. blocked site).

type: keyword

example: Terminated an unexpected process

event.reference

Reference URL linking to additional information about this event. This URL links to a static definition of this event. Alert events, indicated by event.kind:alert, are a common use case for this field.

type: keyword

example: https://system.example.com/event/#0001234

event.risk_score

Risk score or priority of the event (e.g. security solutions). Use your system’s original value here.

type: float

event.risk_score_norm

Normalized risk score or priority of the event, on a scale of 0 to 100. This is mainly useful if you use more than one system that assigns risk scores, and you want to see a normalized value across all systems.

type: float

event.sequence

Sequence number of the event. The sequence number is a value published by some event sources, to make the exact ordering of events unambiguous, regardless of the timestamp precision.

type: long

format: string

event.severity

The numeric severity of the event according to your event source. What the different severity values mean can be different between sources and use cases. It’s up to the implementer to make sure severities are consistent across events from the same source. The Syslog severity belongs in log.syslog.severity.code. event.severity is meant to represent the severity according to the event source (e.g. firewall, IDS). If the event source does not publish its own severity, you may optionally copy the log.syslog.severity.code to event.severity.

type: long

example: 7

format: string

event.start

event.start contains the date when the event started or when the activity was first observed.

type: date

event.timezone

This field should be populated when the event’s timestamp does not include timezone information already (e.g. default Syslog timestamps). It’s optional otherwise. Acceptable timezone formats are: a canonical ID (e.g. "Europe/Amsterdam"), abbreviated (e.g. "EST") or an HH:mm differential (e.g. "-05:00").

type: keyword

event.type

This is one of four ECS Categorization Fields, and indicates the third level in the ECS category hierarchy. event.type represents a categorization "sub-bucket" that, when used along with the event.category field values, enables filtering events down to a level appropriate for single visualization. This field is an array. This will allow proper categorization of some events that fall in multiple event types.

type: keyword

event.url

URL linking to an external system to continue investigation of this event. This URL links to another system where in-depth investigation of the specific occurrence of this event can take place. Alert events, indicated by event.kind:alert, are a common use case for this field.

type: keyword

example: https://mysystem.example.com/alert/5271dedb-f5b0-4218-87f0-4ac4870a38fe

file

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A file is defined as a set of information that has been created on, or has existed on a filesystem. File objects can be associated with host events, network events, and/or file events (e.g., those produced by File Integrity Monitoring [FIM] products or services). File fields provide details about the affected file associated with the event or metric.

file.accessed

Last time the file was accessed. Note that not all filesystems keep track of access time.

type: date

file.attributes

Array of file attributes. Attributes names will vary by platform. Here’s a non-exhaustive list of values that are expected in this field: archive, compressed, directory, encrypted, execute, hidden, read, readonly, system, write.

type: keyword

example: ["readonly", "system"]

file.code_signature.exists

Boolean to capture if a signature is present.

type: boolean

example: true

file.code_signature.signing_id

The identifier used to sign the process. This is used to identify the application manufactured by a software vendor. The field is relevant to Apple *OS only.

type: keyword

example: com.apple.xpc.proxy

file.code_signature.status

Additional information about the certificate status. This is useful for logging cryptographic errors with the certificate validity or trust status. Leave unpopulated if the validity or trust of the certificate was unchecked.

type: keyword

example: ERROR_UNTRUSTED_ROOT

file.code_signature.subject_name

Subject name of the code signer

type: keyword

example: Microsoft Corporation

file.code_signature.team_id

The team identifier used to sign the process. This is used to identify the team or vendor of a software product. The field is relevant to Apple *OS only.

type: keyword

example: EQHXZ8M8AV

file.code_signature.trusted

Stores the trust status of the certificate chain. Validating the trust of the certificate chain may be complicated, and this field should only be populated by tools that actively check the status.

type: boolean

example: true

file.code_signature.valid

Boolean to capture if the digital signature is verified against the binary content. Leave unpopulated if a certificate was unchecked.

type: boolean

example: true

file.created

File creation time. Note that not all filesystems store the creation time.

type: date

file.ctime

Last time the file attributes or metadata changed. Note that changes to the file content will update mtime. This implies ctime will be adjusted at the same time, since mtime is an attribute of the file.

type: date

file.device

Device that is the source of the file.

type: keyword

example: sda

file.directory

Directory where the file is located. It should include the drive letter, when appropriate.

type: keyword

example: /home/alice

file.drive_letter

Drive letter where the file is located. This field is only relevant on Windows. The value should be uppercase, and not include the colon.

type: keyword

example: C

file.elf.architecture

Machine architecture of the ELF file.

type: keyword

example: x86-64

file.elf.byte_order

Byte sequence of ELF file.

type: keyword

example: Little Endian

file.elf.cpu_type

CPU type of the ELF file.

type: keyword

example: Intel

file.elf.creation_date

Extracted when possible from the file’s metadata. Indicates when it was built or compiled. It can also be faked by malware creators.

type: date

file.elf.exports

List of exported element names and types.

type: flattened

file.elf.header.abi_version

Version of the ELF Application Binary Interface (ABI).

type: keyword

file.elf.header.class

Header class of the ELF file.

type: keyword

file.elf.header.data

Data table of the ELF header.

type: keyword

file.elf.header.entrypoint

Header entrypoint of the ELF file.

type: long

format: string

file.elf.header.object_version

"0x1" for original ELF files.

type: keyword

file.elf.header.os_abi

Application Binary Interface (ABI) of the Linux OS.

type: keyword

file.elf.header.type

Header type of the ELF file.

type: keyword

file.elf.header.version

Version of the ELF header.

type: keyword

file.elf.imports

List of imported element names and types.

type: flattened

file.elf.sections

An array containing an object for each section of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.sections.*.

type: nested

file.elf.sections.chi2

Chi-square probability distribution of the section.

type: long

format: number

file.elf.sections.entropy

Shannon entropy calculation from the section.

type: long

format: number

file.elf.sections.flags

ELF Section List flags.

type: keyword

file.elf.sections.name

ELF Section List name.

type: keyword

file.elf.sections.physical_offset

ELF Section List offset.

type: keyword

file.elf.sections.physical_size

ELF Section List physical size.

type: long

format: bytes

file.elf.sections.type

ELF Section List type.

type: keyword

file.elf.sections.virtual_address

ELF Section List virtual address.

type: long

format: string

file.elf.sections.virtual_size

ELF Section List virtual size.

type: long

format: string

file.elf.segments

An array containing an object for each segment of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.segments.*.

type: nested

file.elf.segments.sections

ELF object segment sections.

type: keyword

file.elf.segments.type

ELF object segment type.

type: keyword

file.elf.shared_libraries

List of shared libraries used by this ELF object.

type: keyword

file.elf.telfhash

telfhash symbol hash for ELF file.

type: keyword

file.extension

File extension, excluding the leading dot. Note that when the file name has multiple extensions (example.tar.gz), only the last one should be captured ("gz", not "tar.gz").

type: keyword

example: png

file.gid

Primary group ID (GID) of the file.

type: keyword

example: 1001

file.group

Primary group name of the file.

type: keyword

example: alice

file.hash.md5

MD5 hash.

type: keyword

file.hash.sha1

SHA1 hash.

type: keyword

file.hash.sha256

SHA256 hash.

type: keyword

file.hash.sha512

SHA512 hash.

type: keyword

file.hash.ssdeep

SSDEEP hash.

type: keyword

file.inode

Inode representing the file in the filesystem.

type: keyword

example: 256383

file.mime_type

MIME type should identify the format of the file or stream of bytes using IANA official types, where possible. When more than one type is applicable, the most specific type should be used.

type: keyword

file.mode

Mode of the file in octal representation.

type: keyword

example: 0640

file.mtime

Last time the file content was modified.

type: date

file.name

Name of the file including the extension, without the directory.

type: keyword

example: example.png

file.owner

File owner’s username.

type: keyword

example: alice

file.path

Full path to the file, including the file name. It should include the drive letter, when appropriate.

type: keyword

example: /home/alice/example.png

file.path.text

type: text

file.pe.architecture

CPU architecture target for the file.

type: keyword

example: x64

file.pe.company

Internal company name of the file, provided at compile-time.

type: keyword

example: Microsoft Corporation

file.pe.description

Internal description of the file, provided at compile-time.

type: keyword

example: Paint

file.pe.file_version

Internal version of the file, provided at compile-time.

type: keyword

example: 6.3.9600.17415

file.pe.imphash

A hash of the imports in a PE file. An imphash — or import hash — can be used to fingerprint binaries even after recompilation or other code-level transformations have occurred, which would change more traditional hash values. Learn more at https://www.fireeye.com/blog/threat-research/2014/01/tracking-malware-import-hashing.html.

type: keyword

example: 0c6803c4e922103c4dca5963aad36ddf

file.pe.original_file_name

Internal name of the file, provided at compile-time.

type: keyword

example: MSPAINT.EXE

file.pe.product

Internal product name of the file, provided at compile-time.

type: keyword

example: Microsoft® Windows® Operating System

file.size

File size in bytes. Only relevant when file.type is "file".

type: long

example: 16384

file.target_path

Target path for symlinks.

type: keyword

file.target_path.text

type: text

file.type

File type (file, dir, or symlink).

type: keyword

example: file

file.uid

The user ID (UID) or security identifier (SID) of the file owner.

type: keyword

example: 1001

file.x509.alternative_names

List of subject alternative names (SAN). Name types vary by certificate authority and certificate type but commonly contain IP addresses, DNS names (and wildcards), and email addresses.

type: keyword

example: *.elastic.co

file.x509.issuer.common_name

List of common name (CN) of issuing certificate authority.

type: keyword

example: Example SHA2 High Assurance Server CA

file.x509.issuer.country

List of country © codes

type: keyword

example: US

file.x509.issuer.distinguished_name

Distinguished name (DN) of issuing certificate authority.

type: keyword

example: C=US, O=Example Inc, OU=www.example.com, CN=Example SHA2 High Assurance Server CA

file.x509.issuer.locality

List of locality names (L)

type: keyword

example: Mountain View

file.x509.issuer.organization

List of organizations (O) of issuing certificate authority.

type: keyword

example: Example Inc

file.x509.issuer.organizational_unit

List of organizational units (OU) of issuing certificate authority.

type: keyword

example: www.example.com

file.x509.issuer.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

file.x509.not_after

Time at which the certificate is no longer considered valid.

type: date

example: 2020-07-16 03:15:39+00:00

file.x509.not_before

Time at which the certificate is first considered valid.

type: date

example: 2019-08-16 01:40:25+00:00

file.x509.public_key_algorithm

Algorithm used to generate the public key.

type: keyword

example: RSA

file.x509.public_key_curve

The curve used by the elliptic curve public key algorithm. This is algorithm specific.

type: keyword

example: nistp521

file.x509.public_key_exponent

Exponent used to derive the public key. This is algorithm specific.

type: long

example: 65537

Field is not indexed.

file.x509.public_key_size

The size of the public key space in bits.

type: long

example: 2048

file.x509.serial_number

Unique serial number issued by the certificate authority. For consistency, if this value is alphanumeric, it should be formatted without colons and uppercase characters.

type: keyword

example: 55FBB9C7DEBF09809D12CCAA

file.x509.signature_algorithm

Identifier for certificate signature algorithm. We recommend using names found in Go Lang Crypto library. See https://github.com/golang/go/blob/go1.14/src/crypto/x509/x509.go#L337-L353.

type: keyword

example: SHA256-RSA

file.x509.subject.common_name

List of common names (CN) of subject.

type: keyword

example: shared.global.example.net

file.x509.subject.country

List of country © code

type: keyword

example: US

file.x509.subject.distinguished_name

Distinguished name (DN) of the certificate subject entity.

type: keyword

example: C=US, ST=California, L=San Francisco, O=Example, Inc., CN=shared.global.example.net

file.x509.subject.locality

List of locality names (L)

type: keyword

example: San Francisco

file.x509.subject.organization

List of organizations (O) of subject.

type: keyword

example: Example, Inc.

file.x509.subject.organizational_unit

List of organizational units (OU) of subject.

type: keyword

file.x509.subject.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

file.x509.version_number

Version of x509 format.

type: keyword

example: 3

geo

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Geo fields can carry data about a specific location related to an event. This geolocation information can be derived from techniques such as Geo IP, or be user-supplied.

geo.city_name

City name.

type: keyword

example: Montreal

geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

geo.continent_name

Name of the continent.

type: keyword

example: North America

geo.country_iso_code

Country ISO code.

type: keyword

example: CA

geo.country_name

Country name.

type: keyword

example: Canada

geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

geo.region_name

Region name.

type: keyword

example: Quebec

geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

group

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The group fields are meant to represent groups that are relevant to the event.

group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

group.id

Unique identifier for the group on the system/platform.

type: keyword

group.name

Name of the group.

type: keyword

hash

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The hash fields represent different bitwise hash algorithms and their values. Field names for common hashes (e.g. MD5, SHA1) are predefined. Add fields for other hashes by lowercasing the hash algorithm name and using underscore separators as appropriate (snake case, e.g. sha3_512). Note that this fieldset is used for common hashes that may be computed over a range of generic bytes. Entity-specific hashes such as ja3 or imphash are placed in the fieldsets to which they relate (tls and pe, respectively).

hash.md5

MD5 hash.

type: keyword

hash.sha1

SHA1 hash.

type: keyword

hash.sha256

SHA256 hash.

type: keyword

hash.sha512

SHA512 hash.

type: keyword

hash.ssdeep

SSDEEP hash.

type: keyword

host

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A host is defined as a general computing instance. ECS host.* fields should be populated with details about the host on which the event happened, or from which the measurement was taken. Host types include hardware, virtual machines, Docker containers, and Kubernetes nodes.

host.architecture

Operating system architecture.

type: keyword

example: x86_64

host.cpu.usage

Percent CPU used which is normalized by the number of CPU cores and it ranges from 0 to 1. Scaling factor: 1000. For example: For a two core host, this value should be the average of the two cores, between 0 and 1.

type: scaled_float

host.disk.read.bytes

The total number of bytes (gauge) read successfully (aggregated from all disks) since the last metric collection.

type: long

host.disk.write.bytes

The total number of bytes (gauge) written successfully (aggregated from all disks) since the last metric collection.

type: long

host.domain

Name of the domain of which the host is a member. For example, on Windows this could be the host’s Active Directory domain or NetBIOS domain name. For Linux this could be the domain of the host’s LDAP provider.

type: keyword

example: CONTOSO

host.geo.city_name

City name.

type: keyword

example: Montreal

host.geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

host.geo.continent_name

Name of the continent.

type: keyword

example: North America

host.geo.country_iso_code

Country ISO code.

type: keyword

example: CA

host.geo.country_name

Country name.

type: keyword

example: Canada

host.geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

host.geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

host.geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

host.geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

host.geo.region_name

Region name.

type: keyword

example: Quebec

host.geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

host.hostname

Hostname of the host. It normally contains what the hostname command returns on the host machine.

type: keyword

host.id

Unique host id. As hostname is not always unique, use values that are meaningful in your environment. Example: The current usage of beat.name.

type: keyword

host.ip

Host ip addresses.

type: ip

host.mac

Host MAC addresses. The notation format from RFC 7042 is suggested: Each octet (that is, 8-bit byte) is represented by two [uppercase] hexadecimal digits giving the value of the octet as an unsigned integer. Successive octets are separated by a hyphen.

type: keyword

example: ["00-00-5E-00-53-23", "00-00-5E-00-53-24"]

host.name

Name of the host. It can contain what hostname returns on Unix systems, the fully qualified domain name, or a name specified by the user. The sender decides which value to use.

type: keyword

host.network.egress.bytes

The number of bytes (gauge) sent out on all network interfaces by the host since the last metric collection.

type: long

host.network.egress.packets

The number of packets (gauge) sent out on all network interfaces by the host since the last metric collection.

type: long

host.network.ingress.bytes

The number of bytes received (gauge) on all network interfaces by the host since the last metric collection.

type: long

host.network.ingress.packets

The number of packets (gauge) received on all network interfaces by the host since the last metric collection.

type: long

host.os.family

OS family (such as redhat, debian, freebsd, windows).

type: keyword

example: debian

host.os.full

Operating system name, including the version or code name.

type: keyword

example: Mac OS Mojave

host.os.full.text

type: text

host.os.kernel

Operating system kernel version as a raw string.

type: keyword

example: 4.4.0-112-generic

host.os.name

Operating system name, without the version.

type: keyword

example: Mac OS X

host.os.name.text

type: text

host.os.platform

Operating system platform (such centos, ubuntu, windows).

type: keyword

example: darwin

host.os.type

Use the os.type field to categorize the operating system into one of the broad commercial families. One of these following values should be used (lowercase): linux, macos, unix, windows. If the OS you’re dealing with is not in the list, the field should not be populated. Please let us know by opening an issue with ECS, to propose its addition.

type: keyword

example: macos

host.os.version

Operating system version as a raw string.

type: keyword

example: 10.14.1

host.type

Type of host. For Cloud providers this can be the machine type like t2.medium. If vm, this could be the container, for example, or other information meaningful in your environment.

type: keyword

host.uptime

Seconds the host has been up.

type: long

example: 1325

host.user.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

host.user.email

User email address.

type: keyword

host.user.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

host.user.full_name.text

type: text

host.user.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

host.user.group.id

Unique identifier for the group on the system/platform.

type: keyword

host.user.group.name

Name of the group.

type: keyword

host.user.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

host.user.id

Unique identifier of the user.

type: keyword

host.user.name

Short name or login of the user.

type: keyword

example: albert

host.user.name.text

type: text

host.user.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

http

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Fields related to HTTP activity. Use the url field set to store the url of the request.

http.request.body.bytes

Size in bytes of the request body.

type: long

example: 887

format: bytes

http.request.body.content

The full HTTP request body.

type: keyword

example: Hello world

http.request.body.content.text

type: text

http.request.bytes

Total size in bytes of the request (body and headers).

type: long

example: 1437

format: bytes

http.request.id

A unique identifier for each HTTP request to correlate logs between clients and servers in transactions. The id may be contained in a non-standard HTTP header, such as X-Request-ID or X-Correlation-ID.

type: keyword

example: 123e4567-e89b-12d3-a456-426614174000

http.request.method

HTTP request method. Prior to ECS 1.6.0 the following guidance was provided: "The field value must be normalized to lowercase for querying." As of ECS 1.6.0, the guidance is deprecated because the original case of the method may be useful in anomaly detection. Original case will be mandated in ECS 2.0.0

type: keyword

example: GET, POST, PUT, PoST

http.request.mime_type

Mime type of the body of the request. This value must only be populated based on the content of the request body, not on the Content-Type header. Comparing the mime type of a request with the request’s Content-Type header can be helpful in detecting threats or misconfigured clients.

type: keyword

example: image/gif

http.request.referrer

Referrer for this HTTP request.

type: keyword

example: https://blog.example.com/

http.response.body.bytes

Size in bytes of the response body.

type: long

example: 887

format: bytes

http.response.body.content

The full HTTP response body.

type: keyword

example: Hello world

http.response.body.content.text

type: text

http.response.bytes

Total size in bytes of the response (body and headers).

type: long

example: 1437

format: bytes

http.response.mime_type

Mime type of the body of the response. This value must only be populated based on the content of the response body, not on the Content-Type header. Comparing the mime type of a response with the response’s Content-Type header can be helpful in detecting misconfigured servers.

type: keyword

example: image/gif

http.response.status_code

HTTP response status code.

type: long

example: 404

format: string

http.version

HTTP version.

type: keyword

example: 1.1

interface

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The interface fields are used to record ingress and egress interface information when reported by an observer (e.g. firewall, router, load balancer) in the context of the observer handling a network connection. In the case of a single observer interface (e.g. network sensor on a span port) only the observer.ingress information should be populated.

interface.alias

Interface alias as reported by the system, typically used in firewall implementations for e.g. inside, outside, or dmz logical interface naming.

type: keyword

example: outside

interface.id

Interface ID as reported by an observer (typically SNMP interface ID).

type: keyword

example: 10

interface.name

Interface name as reported by the system.

type: keyword

example: eth0

log

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Details about the event’s logging mechanism or logging transport. The log.* fields are typically populated with details about the logging mechanism used to create and/or transport the event. For example, syslog details belong under log.syslog.*. The details specific to your event source are typically not logged under log.*, but rather in event.* or in other ECS fields.

log.file.path

Full path to the log file this event came from, including the file name. It should include the drive letter, when appropriate. If the event wasn’t read from a log file, do not populate this field.

type: keyword

example: /var/log/fun-times.log

log.level

Original log level of the log event. If the source of the event provides a log level or textual severity, this is the one that goes in log.level. If your source doesn’t specify one, you may put your event transport’s severity here (e.g. Syslog severity). Some examples are warn, err, i, informational.

type: keyword

example: error

log.logger

The name of the logger inside an application. This is usually the name of the class which initialized the logger, or can be a custom name.

type: keyword

example: org.elasticsearch.bootstrap.Bootstrap

log.origin.file.line

The line number of the file containing the source code which originated the log event.

type: integer

example: 42

log.origin.file.name

The name of the file containing the source code which originated the log event. Note that this field is not meant to capture the log file. The correct field to capture the log file is log.file.path.

type: keyword

example: Bootstrap.java

log.origin.function

The name of the function or method which originated the log event.

type: keyword

example: init

log.original

Deprecated for removal in next major version release. This field is superseded by event.original. This is the original log message and contains the full log message before splitting it up in multiple parts. In contrast to the message field which can contain an extracted part of the log message, this field contains the original, full log message. It can have already some modifications applied like encoding or new lines removed to clean up the log message. This field is not indexed and doc_values are disabled so it can’t be queried but the value can be retrieved from _source.

type: keyword

example: Sep 19 08:26:10 localhost My log

Field is not indexed.

log.syslog

The Syslog metadata of the event, if the event was transmitted via Syslog. Please see RFCs 5424 or 3164.

type: object

log.syslog.facility.code

The Syslog numeric facility of the log event, if available. According to RFCs 5424 and 3164, this value should be an integer between 0 and 23.

type: long

example: 23

format: string

log.syslog.facility.name

The Syslog text-based facility of the log event, if available.

type: keyword

example: local7

log.syslog.priority

Syslog numeric priority of the event, if available. According to RFCs 5424 and 3164, the priority is 8 * facility + severity. This number is therefore expected to contain a value between 0 and 191.

type: long

example: 135

format: string

log.syslog.severity.code

The Syslog numeric severity of the log event, if available. If the event source publishing via Syslog provides a different numeric severity value (e.g. firewall, IDS), your source’s numeric severity should go to event.severity. If the event source does not specify a distinct severity, you can optionally copy the Syslog severity to event.severity.

type: long

example: 3

log.syslog.severity.name

The Syslog numeric severity of the log event, if available. If the event source publishing via Syslog provides a different severity value (e.g. firewall, IDS), your source’s text severity should go to log.level. If the event source does not specify a distinct severity, you can optionally copy the Syslog severity to log.level.

type: keyword

example: Error

network

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The network is defined as the communication path over which a host or network event happens. The network.* fields should be populated with details about the network activity associated with an event.

network.application

A name given to an application level protocol. This can be arbitrarily assigned for things like microservices, but also apply to things like skype, icq, facebook, twitter. This would be used in situations where the vendor or service can be decoded such as from the source/dest IP owners, ports, or wire format. The field value must be normalized to lowercase for querying. See the documentation section "Implementing ECS".

type: keyword

example: aim

network.bytes

Total bytes transferred in both directions. If source.bytes and destination.bytes are known, network.bytes is their sum.

type: long

example: 368

format: bytes

network.community_id

A hash of source and destination IPs and ports, as well as the protocol used in a communication. This is a tool-agnostic standard to identify flows. Learn more at https://github.com/corelight/community-id-spec.

type: keyword

example: 1:hO+sN4H+MG5MY/8hIrXPqc4ZQz0=

network.direction

Direction of the network traffic. Recommended values are: * ingress * egress * inbound * outbound * internal * external * unknown

When mapping events from a host-based monitoring context, populate this field from the host’s point of view, using the values "ingress" or "egress". When mapping events from a network or perimeter-based monitoring context, populate this field from the point of view of the network perimeter, using the values "inbound", "outbound", "internal" or "external". Note that "internal" is not crossing perimeter boundaries, and is meant to describe communication between two hosts within the perimeter. Note also that "external" is meant to describe traffic between two hosts that are external to the perimeter. This could for example be useful for ISPs or VPN service providers.

type: keyword

example: inbound

network.forwarded_ip

Host IP address when the source IP address is the proxy.

type: ip

example: 192.1.1.2

network.iana_number

IANA Protocol Number (https://www.iana.org/assignments/protocol-numbers/protocol-numbers.xhtml). Standardized list of protocols. This aligns well with NetFlow and sFlow related logs which use the IANA Protocol Number.

type: keyword

example: 6

network.inner

Network.inner fields are added in addition to network.vlan fields to describe the innermost VLAN when q-in-q VLAN tagging is present. Allowed fields include vlan.id and vlan.name. Inner vlan fields are typically used when sending traffic with multiple 802.1q encapsulations to a network sensor (e.g. Zeek, Wireshark.)

type: object

network.inner.vlan.id

VLAN ID as reported by the observer.

type: keyword

example: 10

network.inner.vlan.name

Optional VLAN name as reported by the observer.

type: keyword

example: outside

network.name

Name given by operators to sections of their network.

type: keyword

example: Guest Wifi

network.packets

Total packets transferred in both directions. If source.packets and destination.packets are known, network.packets is their sum.

type: long

example: 24

network.protocol

L7 Network protocol name. ex. http, lumberjack, transport protocol. The field value must be normalized to lowercase for querying. See the documentation section "Implementing ECS".

type: keyword

example: http

network.transport

Same as network.iana_number, but instead using the Keyword name of the transport layer (udp, tcp, ipv6-icmp, etc.) The field value must be normalized to lowercase for querying. See the documentation section "Implementing ECS".

type: keyword

example: tcp

network.type

In the OSI Model this would be the Network Layer. ipv4, ipv6, ipsec, pim, etc The field value must be normalized to lowercase for querying. See the documentation section "Implementing ECS".

type: keyword

example: ipv4

network.vlan.id

VLAN ID as reported by the observer.

type: keyword

example: 10

network.vlan.name

Optional VLAN name as reported by the observer.

type: keyword

example: outside

observer

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An observer is defined as a special network, security, or application device used to detect, observe, or create network, security, or application-related events and metrics. This could be a custom hardware appliance or a server that has been configured to run special network, security, or application software. Examples include firewalls, web proxies, intrusion detection/prevention systems, network monitoring sensors, web application firewalls, data loss prevention systems, and APM servers. The observer.* fields shall be populated with details of the system, if any, that detects, observes and/or creates a network, security, or application event or metric. Message queues and ETL components used in processing events or metrics are not considered observers in ECS.

observer.egress

Observer.egress holds information like interface number and name, vlan, and zone information to classify egress traffic. Single armed monitoring such as a network sensor on a span port should only use observer.ingress to categorize traffic.

type: object

observer.egress.interface.alias

Interface alias as reported by the system, typically used in firewall implementations for e.g. inside, outside, or dmz logical interface naming.

type: keyword

example: outside

observer.egress.interface.id

Interface ID as reported by an observer (typically SNMP interface ID).

type: keyword

example: 10

observer.egress.interface.name

Interface name as reported by the system.

type: keyword

example: eth0

observer.egress.vlan.id

VLAN ID as reported by the observer.

type: keyword

example: 10

observer.egress.vlan.name

Optional VLAN name as reported by the observer.

type: keyword

example: outside

observer.egress.zone

Network zone of outbound traffic as reported by the observer to categorize the destination area of egress traffic, e.g. Internal, External, DMZ, HR, Legal, etc.

type: keyword

example: Public_Internet

observer.geo.city_name

City name.

type: keyword

example: Montreal

observer.geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

observer.geo.continent_name

Name of the continent.

type: keyword

example: North America

observer.geo.country_iso_code

Country ISO code.

type: keyword

example: CA

observer.geo.country_name

Country name.

type: keyword

example: Canada

observer.geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

observer.geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

observer.geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

observer.geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

observer.geo.region_name

Region name.

type: keyword

example: Quebec

observer.geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

observer.hostname

Hostname of the observer.

type: keyword

observer.ingress

Observer.ingress holds information like interface number and name, vlan, and zone information to classify ingress traffic. Single armed monitoring such as a network sensor on a span port should only use observer.ingress to categorize traffic.

type: object

observer.ingress.interface.alias

Interface alias as reported by the system, typically used in firewall implementations for e.g. inside, outside, or dmz logical interface naming.

type: keyword

example: outside

observer.ingress.interface.id

Interface ID as reported by an observer (typically SNMP interface ID).

type: keyword

example: 10

observer.ingress.interface.name

Interface name as reported by the system.

type: keyword

example: eth0

observer.ingress.vlan.id

VLAN ID as reported by the observer.

type: keyword

example: 10

observer.ingress.vlan.name

Optional VLAN name as reported by the observer.

type: keyword

example: outside

observer.ingress.zone

Network zone of incoming traffic as reported by the observer to categorize the source area of ingress traffic. e.g. internal, External, DMZ, HR, Legal, etc.

type: keyword

example: DMZ

observer.ip

IP addresses of the observer.

type: ip

observer.mac

MAC addresses of the observer. The notation format from RFC 7042 is suggested: Each octet (that is, 8-bit byte) is represented by two [uppercase] hexadecimal digits giving the value of the octet as an unsigned integer. Successive octets are separated by a hyphen.

type: keyword

example: ["00-00-5E-00-53-23", "00-00-5E-00-53-24"]

observer.name

Custom name of the observer. This is a name that can be given to an observer. This can be helpful for example if multiple firewalls of the same model are used in an organization. If no custom name is needed, the field can be left empty.

type: keyword

example: 1_proxySG

observer.os.family

OS family (such as redhat, debian, freebsd, windows).

type: keyword

example: debian

observer.os.full

Operating system name, including the version or code name.

type: keyword

example: Mac OS Mojave

observer.os.full.text

type: text

observer.os.kernel

Operating system kernel version as a raw string.

type: keyword

example: 4.4.0-112-generic

observer.os.name

Operating system name, without the version.

type: keyword

example: Mac OS X

observer.os.name.text

type: text

observer.os.platform

Operating system platform (such centos, ubuntu, windows).

type: keyword

example: darwin

observer.os.type

Use the os.type field to categorize the operating system into one of the broad commercial families. One of these following values should be used (lowercase): linux, macos, unix, windows. If the OS you’re dealing with is not in the list, the field should not be populated. Please let us know by opening an issue with ECS, to propose its addition.

type: keyword

example: macos

observer.os.version

Operating system version as a raw string.

type: keyword

example: 10.14.1

observer.product

The product name of the observer.

type: keyword

example: s200

observer.serial_number

Observer serial number.

type: keyword

observer.type

The type of the observer the data is coming from. There is no predefined list of observer types. Some examples are forwarder, firewall, ids, ips, proxy, poller, sensor, APM server.

type: keyword

example: firewall

observer.vendor

Vendor name of the observer.

type: keyword

example: Symantec

observer.version

Observer version.

type: keyword

orchestrator

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Fields that describe the resources which container orchestrators manage or act upon.

orchestrator.api_version

API version being used to carry out the action

type: keyword

example: v1beta1

orchestrator.cluster.name

Name of the cluster.

type: keyword

orchestrator.cluster.url

URL of the API used to manage the cluster.

type: keyword

orchestrator.cluster.version

The version of the cluster.

type: keyword

orchestrator.namespace

Namespace in which the action is taking place.

type: keyword

example: kube-system

orchestrator.organization

Organization affected by the event (for multi-tenant orchestrator setups).

type: keyword

example: elastic

orchestrator.resource.name

Name of the resource being acted upon.

type: keyword

example: test-pod-cdcws

orchestrator.resource.type

Type of resource being acted upon.

type: keyword

example: service

orchestrator.type

Orchestrator cluster type (e.g. kubernetes, nomad or cloudfoundry).

type: keyword

example: kubernetes

organization

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The organization fields enrich data with information about the company or entity the data is associated with. These fields help you arrange or filter data stored in an index by one or multiple organizations.

organization.id

Unique identifier for the organization.

type: keyword

organization.name

Organization name.

type: keyword

organization.name.text

type: text

The OS fields contain information about the operating system.

os.family

OS family (such as redhat, debian, freebsd, windows).

type: keyword

example: debian

os.full

Operating system name, including the version or code name.

type: keyword

example: Mac OS Mojave

os.full.text

type: text

os.kernel

Operating system kernel version as a raw string.

type: keyword

example: 4.4.0-112-generic

os.name

Operating system name, without the version.

type: keyword

example: Mac OS X

os.name.text

type: text

os.platform

Operating system platform (such centos, ubuntu, windows).

type: keyword

example: darwin

os.type

Use the os.type field to categorize the operating system into one of the broad commercial families. One of these following values should be used (lowercase): linux, macos, unix, windows. If the OS you’re dealing with is not in the list, the field should not be populated. Please let us know by opening an issue with ECS, to propose its addition.

type: keyword

example: macos

os.version

Operating system version as a raw string.

type: keyword

example: 10.14.1

package

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These fields contain information about an installed software package. It contains general information about a package, such as name, version or size. It also contains installation details, such as time or location.

package.architecture

Package architecture.

type: keyword

example: x86_64

package.build_version

Additional information about the build version of the installed package. For example use the commit SHA of a non-released package.

type: keyword

example: 36f4f7e89dd61b0988b12ee000b98966867710cd

package.checksum

Checksum of the installed package for verification.

type: keyword

example: 68b329da9893e34099c7d8ad5cb9c940

package.description

Description of the package.

type: keyword

example: Open source programming language to build simple/reliable/efficient software.

package.install_scope

Indicating how the package was installed, e.g. user-local, global.

type: keyword

example: global

package.installed

Time when package was installed.

type: date

package.license

License under which the package was released. Use a short name, e.g. the license identifier from SPDX License List where possible (https://spdx.org/licenses/).

type: keyword

example: Apache License 2.0

package.name

Package name

type: keyword

example: go

package.path

Path where the package is installed.

type: keyword

example: /usr/local/Cellar/go/1.12.9/

package.reference

Home page or reference URL of the software in this package, if available.

type: keyword

example: https://golang.org

package.size

Package size in bytes.

type: long

example: 62231

format: string

package.type

Type of package. This should contain the package file type, rather than the package manager name. Examples: rpm, dpkg, brew, npm, gem, nupkg, jar.

type: keyword

example: rpm

package.version

Package version

type: keyword

example: 1.12.9

These fields contain Windows Portable Executable (PE) metadata.

pe.architecture

CPU architecture target for the file.

type: keyword

example: x64

pe.company

Internal company name of the file, provided at compile-time.

type: keyword

example: Microsoft Corporation

pe.description

Internal description of the file, provided at compile-time.

type: keyword

example: Paint

pe.file_version

Internal version of the file, provided at compile-time.

type: keyword

example: 6.3.9600.17415

pe.imphash

A hash of the imports in a PE file. An imphash — or import hash — can be used to fingerprint binaries even after recompilation or other code-level transformations have occurred, which would change more traditional hash values. Learn more at https://www.fireeye.com/blog/threat-research/2014/01/tracking-malware-import-hashing.html.

type: keyword

example: 0c6803c4e922103c4dca5963aad36ddf

pe.original_file_name

Internal name of the file, provided at compile-time.

type: keyword

example: MSPAINT.EXE

pe.product

Internal product name of the file, provided at compile-time.

type: keyword

example: Microsoft® Windows® Operating System

process

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These fields contain information about a process. These fields can help you correlate metrics information with a process id/name from a log message. The process.pid often stays in the metric itself and is copied to the global field for correlation.

process.args

Array of process arguments, starting with the absolute path to the executable. May be filtered to protect sensitive information.

type: keyword

example: ["/usr/bin/ssh", "-l", "user", "10.0.0.16"]

process.args_count

Length of the process.args array. This field can be useful for querying or performing bucket analysis on how many arguments were provided to start a process. More arguments may be an indication of suspicious activity.

type: long

example: 4

process.code_signature.exists

Boolean to capture if a signature is present.

type: boolean

example: true

process.code_signature.signing_id

The identifier used to sign the process. This is used to identify the application manufactured by a software vendor. The field is relevant to Apple *OS only.

type: keyword

example: com.apple.xpc.proxy

process.code_signature.status

Additional information about the certificate status. This is useful for logging cryptographic errors with the certificate validity or trust status. Leave unpopulated if the validity or trust of the certificate was unchecked.

type: keyword

example: ERROR_UNTRUSTED_ROOT

process.code_signature.subject_name

Subject name of the code signer

type: keyword

example: Microsoft Corporation

process.code_signature.team_id

The team identifier used to sign the process. This is used to identify the team or vendor of a software product. The field is relevant to Apple *OS only.

type: keyword

example: EQHXZ8M8AV

process.code_signature.trusted

Stores the trust status of the certificate chain. Validating the trust of the certificate chain may be complicated, and this field should only be populated by tools that actively check the status.

type: boolean

example: true

process.code_signature.valid

Boolean to capture if the digital signature is verified against the binary content. Leave unpopulated if a certificate was unchecked.

type: boolean

example: true

process.command_line

Full command line that started the process, including the absolute path to the executable, and all arguments. Some arguments may be filtered to protect sensitive information.

type: keyword

example: /usr/bin/ssh -l user 10.0.0.16

process.command_line.text

type: text

process.elf.architecture

Machine architecture of the ELF file.

type: keyword

example: x86-64

process.elf.byte_order

Byte sequence of ELF file.

type: keyword

example: Little Endian

process.elf.cpu_type

CPU type of the ELF file.

type: keyword

example: Intel

process.elf.creation_date

Extracted when possible from the file’s metadata. Indicates when it was built or compiled. It can also be faked by malware creators.

type: date

process.elf.exports

List of exported element names and types.

type: flattened

process.elf.header.abi_version

Version of the ELF Application Binary Interface (ABI).

type: keyword

process.elf.header.class

Header class of the ELF file.

type: keyword

process.elf.header.data

Data table of the ELF header.

type: keyword

process.elf.header.entrypoint

Header entrypoint of the ELF file.

type: long

format: string

process.elf.header.object_version

"0x1" for original ELF files.

type: keyword

process.elf.header.os_abi

Application Binary Interface (ABI) of the Linux OS.

type: keyword

process.elf.header.type

Header type of the ELF file.

type: keyword

process.elf.header.version

Version of the ELF header.

type: keyword

process.elf.imports

List of imported element names and types.

type: flattened

process.elf.sections

An array containing an object for each section of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.sections.*.

type: nested

process.elf.sections.chi2

Chi-square probability distribution of the section.

type: long

format: number

process.elf.sections.entropy

Shannon entropy calculation from the section.

type: long

format: number

process.elf.sections.flags

ELF Section List flags.

type: keyword

process.elf.sections.name

ELF Section List name.

type: keyword

process.elf.sections.physical_offset

ELF Section List offset.

type: keyword

process.elf.sections.physical_size

ELF Section List physical size.

type: long

format: bytes

process.elf.sections.type

ELF Section List type.

type: keyword

process.elf.sections.virtual_address

ELF Section List virtual address.

type: long

format: string

process.elf.sections.virtual_size

ELF Section List virtual size.

type: long

format: string

process.elf.segments

An array containing an object for each segment of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.segments.*.

type: nested

process.elf.segments.sections

ELF object segment sections.

type: keyword

process.elf.segments.type

ELF object segment type.

type: keyword

process.elf.shared_libraries

List of shared libraries used by this ELF object.

type: keyword

process.elf.telfhash

telfhash symbol hash for ELF file.

type: keyword

process.entity_id

Unique identifier for the process. The implementation of this is specified by the data source, but some examples of what could be used here are a process-generated UUID, Sysmon Process GUIDs, or a hash of some uniquely identifying components of a process. Constructing a globally unique identifier is a common practice to mitigate PID reuse as well as to identify a specific process over time, across multiple monitored hosts.

type: keyword

example: c2c455d9f99375d

process.executable

Absolute path to the process executable.

type: keyword

example: /usr/bin/ssh

process.executable.text

type: text

process.exit_code

The exit code of the process, if this is a termination event. The field should be absent if there is no exit code for the event (e.g. process start).

type: long

example: 137

process.hash.md5

MD5 hash.

type: keyword

process.hash.sha1

SHA1 hash.

type: keyword

process.hash.sha256

SHA256 hash.

type: keyword

process.hash.sha512

SHA512 hash.

type: keyword

process.hash.ssdeep

SSDEEP hash.

type: keyword

process.name

Process name. Sometimes called program name or similar.

type: keyword

example: ssh

process.name.text

type: text

process.parent.args

Array of process arguments, starting with the absolute path to the executable. May be filtered to protect sensitive information.

type: keyword

example: ["/usr/bin/ssh", "-l", "user", "10.0.0.16"]

process.parent.args_count

Length of the process.args array. This field can be useful for querying or performing bucket analysis on how many arguments were provided to start a process. More arguments may be an indication of suspicious activity.

type: long

example: 4

process.parent.code_signature.exists

Boolean to capture if a signature is present.

type: boolean

example: true

process.parent.code_signature.signing_id

The identifier used to sign the process. This is used to identify the application manufactured by a software vendor. The field is relevant to Apple *OS only.

type: keyword

example: com.apple.xpc.proxy

process.parent.code_signature.status

Additional information about the certificate status. This is useful for logging cryptographic errors with the certificate validity or trust status. Leave unpopulated if the validity or trust of the certificate was unchecked.

type: keyword

example: ERROR_UNTRUSTED_ROOT

process.parent.code_signature.subject_name

Subject name of the code signer

type: keyword

example: Microsoft Corporation

process.parent.code_signature.team_id

The team identifier used to sign the process. This is used to identify the team or vendor of a software product. The field is relevant to Apple *OS only.

type: keyword

example: EQHXZ8M8AV

process.parent.code_signature.trusted

Stores the trust status of the certificate chain. Validating the trust of the certificate chain may be complicated, and this field should only be populated by tools that actively check the status.

type: boolean

example: true

process.parent.code_signature.valid

Boolean to capture if the digital signature is verified against the binary content. Leave unpopulated if a certificate was unchecked.

type: boolean

example: true

process.parent.command_line

Full command line that started the process, including the absolute path to the executable, and all arguments. Some arguments may be filtered to protect sensitive information.

type: keyword

example: /usr/bin/ssh -l user 10.0.0.16

process.parent.command_line.text

type: text

process.parent.elf.architecture

Machine architecture of the ELF file.

type: keyword

example: x86-64

process.parent.elf.byte_order

Byte sequence of ELF file.

type: keyword

example: Little Endian

process.parent.elf.cpu_type

CPU type of the ELF file.

type: keyword

example: Intel

process.parent.elf.creation_date

Extracted when possible from the file’s metadata. Indicates when it was built or compiled. It can also be faked by malware creators.

type: date

process.parent.elf.exports

List of exported element names and types.

type: flattened

process.parent.elf.header.abi_version

Version of the ELF Application Binary Interface (ABI).

type: keyword

process.parent.elf.header.class

Header class of the ELF file.

type: keyword

process.parent.elf.header.data

Data table of the ELF header.

type: keyword

process.parent.elf.header.entrypoint

Header entrypoint of the ELF file.

type: long

format: string

process.parent.elf.header.object_version

"0x1" for original ELF files.

type: keyword

process.parent.elf.header.os_abi

Application Binary Interface (ABI) of the Linux OS.

type: keyword

process.parent.elf.header.type

Header type of the ELF file.

type: keyword

process.parent.elf.header.version

Version of the ELF header.

type: keyword

process.parent.elf.imports

List of imported element names and types.

type: flattened

process.parent.elf.sections

An array containing an object for each section of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.sections.*.

type: nested

process.parent.elf.sections.chi2

Chi-square probability distribution of the section.

type: long

format: number

process.parent.elf.sections.entropy

Shannon entropy calculation from the section.

type: long

format: number

process.parent.elf.sections.flags

ELF Section List flags.

type: keyword

process.parent.elf.sections.name

ELF Section List name.

type: keyword

process.parent.elf.sections.physical_offset

ELF Section List offset.

type: keyword

process.parent.elf.sections.physical_size

ELF Section List physical size.

type: long

format: bytes

process.parent.elf.sections.type

ELF Section List type.

type: keyword

process.parent.elf.sections.virtual_address

ELF Section List virtual address.

type: long

format: string

process.parent.elf.sections.virtual_size

ELF Section List virtual size.

type: long

format: string

process.parent.elf.segments

An array containing an object for each segment of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.segments.*.

type: nested

process.parent.elf.segments.sections

ELF object segment sections.

type: keyword

process.parent.elf.segments.type

ELF object segment type.

type: keyword

process.parent.elf.shared_libraries

List of shared libraries used by this ELF object.

type: keyword

process.parent.elf.telfhash

telfhash symbol hash for ELF file.

type: keyword

process.parent.entity_id

Unique identifier for the process. The implementation of this is specified by the data source, but some examples of what could be used here are a process-generated UUID, Sysmon Process GUIDs, or a hash of some uniquely identifying components of a process. Constructing a globally unique identifier is a common practice to mitigate PID reuse as well as to identify a specific process over time, across multiple monitored hosts.

type: keyword

example: c2c455d9f99375d

process.parent.executable

Absolute path to the process executable.

type: keyword

example: /usr/bin/ssh

process.parent.executable.text

type: text

process.parent.exit_code

The exit code of the process, if this is a termination event. The field should be absent if there is no exit code for the event (e.g. process start).

type: long

example: 137

process.parent.hash.md5

MD5 hash.

type: keyword

process.parent.hash.sha1

SHA1 hash.

type: keyword

process.parent.hash.sha256

SHA256 hash.

type: keyword

process.parent.hash.sha512

SHA512 hash.

type: keyword

process.parent.hash.ssdeep

SSDEEP hash.

type: keyword

process.parent.name

Process name. Sometimes called program name or similar.

type: keyword

example: ssh

process.parent.name.text

type: text

process.parent.pe.architecture

CPU architecture target for the file.

type: keyword

example: x64

process.parent.pe.company

Internal company name of the file, provided at compile-time.

type: keyword

example: Microsoft Corporation

process.parent.pe.description

Internal description of the file, provided at compile-time.

type: keyword

example: Paint

process.parent.pe.file_version

Internal version of the file, provided at compile-time.

type: keyword

example: 6.3.9600.17415

process.parent.pe.imphash

A hash of the imports in a PE file. An imphash — or import hash — can be used to fingerprint binaries even after recompilation or other code-level transformations have occurred, which would change more traditional hash values. Learn more at https://www.fireeye.com/blog/threat-research/2014/01/tracking-malware-import-hashing.html.

type: keyword

example: 0c6803c4e922103c4dca5963aad36ddf

process.parent.pe.original_file_name

Internal name of the file, provided at compile-time.

type: keyword

example: MSPAINT.EXE

process.parent.pe.product

Internal product name of the file, provided at compile-time.

type: keyword

example: Microsoft® Windows® Operating System

process.parent.pgid

Identifier of the group of processes the process belongs to.

type: long

format: string

process.parent.pid

Process id.

type: long

example: 4242

format: string

process.parent.ppid

Parent process' pid.

type: long

example: 4241

format: string

process.parent.start

The time the process started.

type: date

example: 2016-05-23T08:05:34.853Z

process.parent.thread.id

Thread ID.

type: long

example: 4242

format: string

process.parent.thread.name

Thread name.

type: keyword

example: thread-0

process.parent.title

Process title. The proctitle, some times the same as process name. Can also be different: for example a browser setting its title to the web page currently opened.

type: keyword

process.parent.title.text

type: text

process.parent.uptime

Seconds the process has been up.

type: long

example: 1325

process.parent.working_directory

The working directory of the process.

type: keyword

example: /home/alice

process.parent.working_directory.text

type: text

process.pe.architecture

CPU architecture target for the file.

type: keyword

example: x64

process.pe.company

Internal company name of the file, provided at compile-time.

type: keyword

example: Microsoft Corporation

process.pe.description

Internal description of the file, provided at compile-time.

type: keyword

example: Paint

process.pe.file_version

Internal version of the file, provided at compile-time.

type: keyword

example: 6.3.9600.17415

process.pe.imphash

A hash of the imports in a PE file. An imphash — or import hash — can be used to fingerprint binaries even after recompilation or other code-level transformations have occurred, which would change more traditional hash values. Learn more at https://www.fireeye.com/blog/threat-research/2014/01/tracking-malware-import-hashing.html.

type: keyword

example: 0c6803c4e922103c4dca5963aad36ddf

process.pe.original_file_name

Internal name of the file, provided at compile-time.

type: keyword

example: MSPAINT.EXE

process.pe.product

Internal product name of the file, provided at compile-time.

type: keyword

example: Microsoft® Windows® Operating System

process.pgid

Identifier of the group of processes the process belongs to.

type: long

format: string

process.pid

Process id.

type: long

example: 4242

format: string

process.ppid

Parent process' pid.

type: long

example: 4241

format: string

process.start

The time the process started.

type: date

example: 2016-05-23T08:05:34.853Z

process.thread.id

Thread ID.

type: long

example: 4242

format: string

process.thread.name

Thread name.

type: keyword

example: thread-0

process.title

Process title. The proctitle, some times the same as process name. Can also be different: for example a browser setting its title to the web page currently opened.

type: keyword

process.title.text

type: text

process.uptime

Seconds the process has been up.

type: long

example: 1325

process.working_directory

The working directory of the process.

type: keyword

example: /home/alice

process.working_directory.text

type: text

registry

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Fields related to Windows Registry operations.

registry.data.bytes

Original bytes written with base64 encoding. For Windows registry operations, such as SetValueEx and RegQueryValueEx, this corresponds to the data pointed by lp_data. This is optional but provides better recoverability and should be populated for REG_BINARY encoded values.

type: keyword

example: ZQBuAC0AVQBTAAAAZQBuAAAAAAA=

registry.data.strings

Content when writing string types. Populated as an array when writing string data to the registry. For single string registry types (REG_SZ, REG_EXPAND_SZ), this should be an array with one string. For sequences of string with REG_MULTI_SZ, this array will be variable length. For numeric data, such as REG_DWORD and REG_QWORD, this should be populated with the decimal representation (e.g "1").

type: keyword

example: ["C:\rta\red_ttp\bin\myapp.exe"]

registry.data.type

Standard registry type for encoding contents

type: keyword

example: REG_SZ

registry.hive

Abbreviated name for the hive.

type: keyword

example: HKLM

registry.key

Hive-relative path of keys.

type: keyword

example: SOFTWARE\Microsoft\Windows NT\CurrentVersion\Image File Execution Options\winword.exe

registry.path

Full path, including hive, key and value

type: keyword

example: HKLM\SOFTWARE\Microsoft\Windows NT\CurrentVersion\Image File Execution Options\winword.exe\Debugger

registry.value

Name of the value written.

type: keyword

example: Debugger

related

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This field set is meant to facilitate pivoting around a piece of data. Some pieces of information can be seen in many places in an ECS event. To facilitate searching for them, store an array of all seen values to their corresponding field in related.. A concrete example is IP addresses, which can be under host, observer, source, destination, client, server, and network.forwarded_ip. If you append all IPs to related.ip, you can then search for a given IP trivially, no matter where it appeared, by querying related.ip:192.0.2.15.

related.hash

All the hashes seen on your event. Populating this field, then using it to search for hashes can help in situations where you’re unsure what the hash algorithm is (and therefore which key name to search).

type: keyword

related.hosts

All hostnames or other host identifiers seen on your event. Example identifiers include FQDNs, domain names, workstation names, or aliases.

type: keyword

related.ip

All of the IPs seen on your event.

type: ip

related.user

All the user names or other user identifiers seen on the event.

type: keyword

rule

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Rule fields are used to capture the specifics of any observer or agent rules that generate alerts or other notable events. Examples of data sources that would populate the rule fields include: network admission control platforms, network or host IDS/IPS, network firewalls, web application firewalls, url filters, endpoint detection and response (EDR) systems, etc.

rule.author

Name, organization, or pseudonym of the author or authors who created the rule used to generate this event.

type: keyword

example: ["Star-Lord"]

rule.category

A categorization value keyword used by the entity using the rule for detection of this event.

type: keyword

example: Attempted Information Leak

rule.description

The description of the rule generating the event.

type: keyword

example: Block requests to public DNS over HTTPS / TLS protocols

rule.id

A rule ID that is unique within the scope of an agent, observer, or other entity using the rule for detection of this event.

type: keyword

example: 101

rule.license

Name of the license under which the rule used to generate this event is made available.

type: keyword

example: Apache 2.0

rule.name

The name of the rule or signature generating the event.

type: keyword

example: BLOCK_DNS_over_TLS

rule.reference

Reference URL to additional information about the rule used to generate this event. The URL can point to the vendor’s documentation about the rule. If that’s not available, it can also be a link to a more general page describing this type of alert.

type: keyword

example: https://en.wikipedia.org/wiki/DNS_over_TLS

rule.ruleset

Name of the ruleset, policy, group, or parent category in which the rule used to generate this event is a member.

type: keyword

example: Standard_Protocol_Filters

rule.uuid

A rule ID that is unique within the scope of a set or group of agents, observers, or other entities using the rule for detection of this event.

type: keyword

example: 1100110011

rule.version

The version / revision of the rule being used for analysis.

type: keyword

example: 1.1

server

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A Server is defined as the responder in a network connection for events regarding sessions, connections, or bidirectional flow records. For TCP events, the server is the receiver of the initial SYN packet(s) of the TCP connection. For other protocols, the server is generally the responder in the network transaction. Some systems actually use the term "responder" to refer the server in TCP connections. The server fields describe details about the system acting as the server in the network event. Server fields are usually populated in conjunction with client fields. Server fields are generally not populated for packet-level events. Client / server representations can add semantic context to an exchange, which is helpful to visualize the data in certain situations. If your context falls in that category, you should still ensure that source and destination are filled appropriately.

server.address

Some event server addresses are defined ambiguously. The event will sometimes list an IP, a domain or a unix socket. You should always store the raw address in the .address field. Then it should be duplicated to .ip or .domain, depending on which one it is.

type: keyword

server.as.number

Unique number allocated to the autonomous system. The autonomous system number (ASN) uniquely identifies each network on the Internet.

type: long

example: 15169

server.as.organization.name

Organization name.

type: keyword

example: Google LLC

server.as.organization.name.text

type: text

server.bytes

Bytes sent from the server to the client.

type: long

example: 184

format: bytes

server.domain

Server domain.

type: keyword

server.geo.city_name

City name.

type: keyword

example: Montreal

server.geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

server.geo.continent_name

Name of the continent.

type: keyword

example: North America

server.geo.country_iso_code

Country ISO code.

type: keyword

example: CA

server.geo.country_name

Country name.

type: keyword

example: Canada

server.geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

server.geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

server.geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

server.geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

server.geo.region_name

Region name.

type: keyword

example: Quebec

server.geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

server.ip

IP address of the server (IPv4 or IPv6).

type: ip

server.mac

MAC address of the server. The notation format from RFC 7042 is suggested: Each octet (that is, 8-bit byte) is represented by two [uppercase] hexadecimal digits giving the value of the octet as an unsigned integer. Successive octets are separated by a hyphen.

type: keyword

example: 00-00-5E-00-53-23

server.nat.ip

Translated ip of destination based NAT sessions (e.g. internet to private DMZ) Typically used with load balancers, firewalls, or routers.

type: ip

server.nat.port

Translated port of destination based NAT sessions (e.g. internet to private DMZ) Typically used with load balancers, firewalls, or routers.

type: long

format: string

server.packets

Packets sent from the server to the client.

type: long

example: 12

server.port

Port of the server.

type: long

format: string

server.registered_domain

The highest registered server domain, stripped of the subdomain. For example, the registered domain for "foo.example.com" is "example.com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last two labels will not work well for TLDs such as "co.uk".

type: keyword

example: example.com

server.subdomain

The subdomain portion of a fully qualified domain name includes all of the names except the host name under the registered_domain. In a partially qualified domain, or if the the qualification level of the full name cannot be determined, subdomain contains all of the names below the registered domain. For example the subdomain portion of "www.east.mydomain.co.uk" is "east". If the domain has multiple levels of subdomain, such as "sub2.sub1.example.com", the subdomain field should contain "sub2.sub1", with no trailing period.

type: keyword

example: east

server.top_level_domain

The effective top level domain (eTLD), also known as the domain suffix, is the last part of the domain name. For example, the top level domain for example.com is "com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last label will not work well for effective TLDs such as "co.uk".

type: keyword

example: co.uk

server.user.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

server.user.email

User email address.

type: keyword

server.user.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

server.user.full_name.text

type: text

server.user.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

server.user.group.id

Unique identifier for the group on the system/platform.

type: keyword

server.user.group.name

Name of the group.

type: keyword

server.user.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

server.user.id

Unique identifier of the user.

type: keyword

server.user.name

Short name or login of the user.

type: keyword

example: albert

server.user.name.text

type: text

server.user.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

service

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The service fields describe the service for or from which the data was collected. These fields help you find and correlate logs for a specific service and version.

service.ephemeral_id

Ephemeral identifier of this service (if one exists). This id normally changes across restarts, but service.id does not.

type: keyword

example: 8a4f500f

service.id

Unique identifier of the running service. If the service is comprised of many nodes, the service.id should be the same for all nodes. This id should uniquely identify the service. This makes it possible to correlate logs and metrics for one specific service, no matter which particular node emitted the event. Note that if you need to see the events from one specific host of the service, you should filter on that host.name or host.id instead.

type: keyword

example: d37e5ebfe0ae6c4972dbe9f0174a1637bb8247f6

service.name

Name of the service data is collected from. The name of the service is normally user given. This allows for distributed services that run on multiple hosts to correlate the related instances based on the name. In the case of Elasticsearch the service.name could contain the cluster name. For Beats the service.name is by default a copy of the service.type field if no name is specified.

type: keyword

example: elasticsearch-metrics

service.node.name

Name of a service node. This allows for two nodes of the same service running on the same host to be differentiated. Therefore, service.node.name should typically be unique across nodes of a given service. In the case of Elasticsearch, the service.node.name could contain the unique node name within the Elasticsearch cluster. In cases where the service doesn’t have the concept of a node name, the host name or container name can be used to distinguish running instances that make up this service. If those do not provide uniqueness (e.g. multiple instances of the service running on the same host) - the node name can be manually set.

type: keyword

example: instance-0000000016

service.state

Current state of the service.

type: keyword

service.type

The type of the service data is collected from. The type can be used to group and correlate logs and metrics from one service type. Example: If logs or metrics are collected from Elasticsearch, service.type would be elasticsearch.

type: keyword

example: elasticsearch

service.version

Version of the service the data was collected from. This allows to look at a data set only for a specific version of a service.

type: keyword

example: 3.2.4

source

edit

Source fields capture details about the sender of a network exchange/packet. These fields are populated from a network event, packet, or other event containing details of a network transaction. Source fields are usually populated in conjunction with destination fields. The source and destination fields are considered the baseline and should always be filled if an event contains source and destination details from a network transaction. If the event also contains identification of the client and server roles, then the client and server fields should also be populated.

source.address

Some event source addresses are defined ambiguously. The event will sometimes list an IP, a domain or a unix socket. You should always store the raw address in the .address field. Then it should be duplicated to .ip or .domain, depending on which one it is.

type: keyword

source.as.number

Unique number allocated to the autonomous system. The autonomous system number (ASN) uniquely identifies each network on the Internet.

type: long

example: 15169

source.as.organization.name

Organization name.

type: keyword

example: Google LLC

source.as.organization.name.text

type: text

source.bytes

Bytes sent from the source to the destination.

type: long

example: 184

format: bytes

source.domain

Source domain.

type: keyword

source.geo.city_name

City name.

type: keyword

example: Montreal

source.geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

source.geo.continent_name

Name of the continent.

type: keyword

example: North America

source.geo.country_iso_code

Country ISO code.

type: keyword

example: CA

source.geo.country_name

Country name.

type: keyword

example: Canada

source.geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

source.geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

source.geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

source.geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

source.geo.region_name

Region name.

type: keyword

example: Quebec

source.geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

source.ip

IP address of the source (IPv4 or IPv6).

type: ip

source.mac

MAC address of the source. The notation format from RFC 7042 is suggested: Each octet (that is, 8-bit byte) is represented by two [uppercase] hexadecimal digits giving the value of the octet as an unsigned integer. Successive octets are separated by a hyphen.

type: keyword

example: 00-00-5E-00-53-23

source.nat.ip

Translated ip of source based NAT sessions (e.g. internal client to internet) Typically connections traversing load balancers, firewalls, or routers.

type: ip

source.nat.port

Translated port of source based NAT sessions. (e.g. internal client to internet) Typically used with load balancers, firewalls, or routers.

type: long

format: string

source.packets

Packets sent from the source to the destination.

type: long

example: 12

source.port

Port of the source.

type: long

format: string

source.registered_domain

The highest registered source domain, stripped of the subdomain. For example, the registered domain for "foo.example.com" is "example.com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last two labels will not work well for TLDs such as "co.uk".

type: keyword

example: example.com

source.subdomain

The subdomain portion of a fully qualified domain name includes all of the names except the host name under the registered_domain. In a partially qualified domain, or if the the qualification level of the full name cannot be determined, subdomain contains all of the names below the registered domain. For example the subdomain portion of "www.east.mydomain.co.uk" is "east". If the domain has multiple levels of subdomain, such as "sub2.sub1.example.com", the subdomain field should contain "sub2.sub1", with no trailing period.

type: keyword

example: east

source.top_level_domain

The effective top level domain (eTLD), also known as the domain suffix, is the last part of the domain name. For example, the top level domain for example.com is "com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last label will not work well for effective TLDs such as "co.uk".

type: keyword

example: co.uk

source.user.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

source.user.email

User email address.

type: keyword

source.user.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

source.user.full_name.text

type: text

source.user.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

source.user.group.id

Unique identifier for the group on the system/platform.

type: keyword

source.user.group.name

Name of the group.

type: keyword

source.user.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

source.user.id

Unique identifier of the user.

type: keyword

source.user.name

Short name or login of the user.

type: keyword

example: albert

source.user.name.text

type: text

source.user.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

threat

edit

Fields to classify events and alerts according to a threat taxonomy such as the MITRE ATT&CK® framework. These fields are for users to classify alerts from all of their sources (e.g. IDS, NGFW, etc.) within a common taxonomy. The threat.tactic.* are meant to capture the high level category of the threat (e.g. "impact"). The threat.technique.* fields are meant to capture which kind of approach is used by this detected threat, to accomplish the goal (e.g. "endpoint denial of service").

threat.enrichments

A list of associated indicators objects enriching the event, and the context of that association/enrichment.

type: nested

threat.enrichments.indicator

Object containing associated indicators enriching the event.

type: object

threat.enrichments.indicator.as.number

Unique number allocated to the autonomous system. The autonomous system number (ASN) uniquely identifies each network on the Internet.

type: long

example: 15169

threat.enrichments.indicator.as.organization.name

Organization name.

type: keyword

example: Google LLC

threat.enrichments.indicator.as.organization.name.text

type: text

threat.enrichments.indicator.confidence

Identifies the confidence rating assigned by the provider using STIX confidence scales. Expected values: * Not Specified, None, Low, Medium, High * 0-10 * Admirality Scale (1-6) * DNI Scale (5-95) * WEP Scale (Impossible - Certain)

type: keyword

example: High

threat.enrichments.indicator.description

Describes the type of action conducted by the threat.

type: keyword

example: IP x.x.x.x was observed delivering the Angler EK.

threat.enrichments.indicator.email.address

Identifies a threat indicator as an email address (irrespective of direction).

type: keyword

example: phish@example.com

threat.enrichments.indicator.file.accessed

Last time the file was accessed. Note that not all filesystems keep track of access time.

type: date

threat.enrichments.indicator.file.attributes

Array of file attributes. Attributes names will vary by platform. Here’s a non-exhaustive list of values that are expected in this field: archive, compressed, directory, encrypted, execute, hidden, read, readonly, system, write.

type: keyword

example: ["readonly", "system"]

threat.enrichments.indicator.file.code_signature.exists

Boolean to capture if a signature is present.

type: boolean

example: true

threat.enrichments.indicator.file.code_signature.signing_id

The identifier used to sign the process. This is used to identify the application manufactured by a software vendor. The field is relevant to Apple *OS only.

type: keyword

example: com.apple.xpc.proxy

threat.enrichments.indicator.file.code_signature.status

Additional information about the certificate status. This is useful for logging cryptographic errors with the certificate validity or trust status. Leave unpopulated if the validity or trust of the certificate was unchecked.

type: keyword

example: ERROR_UNTRUSTED_ROOT

threat.enrichments.indicator.file.code_signature.subject_name

Subject name of the code signer

type: keyword

example: Microsoft Corporation

threat.enrichments.indicator.file.code_signature.team_id

The team identifier used to sign the process. This is used to identify the team or vendor of a software product. The field is relevant to Apple *OS only.

type: keyword

example: EQHXZ8M8AV

threat.enrichments.indicator.file.code_signature.trusted

Stores the trust status of the certificate chain. Validating the trust of the certificate chain may be complicated, and this field should only be populated by tools that actively check the status.

type: boolean

example: true

threat.enrichments.indicator.file.code_signature.valid

Boolean to capture if the digital signature is verified against the binary content. Leave unpopulated if a certificate was unchecked.

type: boolean

example: true

threat.enrichments.indicator.file.created

File creation time. Note that not all filesystems store the creation time.

type: date

threat.enrichments.indicator.file.ctime

Last time the file attributes or metadata changed. Note that changes to the file content will update mtime. This implies ctime will be adjusted at the same time, since mtime is an attribute of the file.

type: date

threat.enrichments.indicator.file.device

Device that is the source of the file.

type: keyword

example: sda

threat.enrichments.indicator.file.directory

Directory where the file is located. It should include the drive letter, when appropriate.

type: keyword

example: /home/alice

threat.enrichments.indicator.file.drive_letter

Drive letter where the file is located. This field is only relevant on Windows. The value should be uppercase, and not include the colon.

type: keyword

example: C

threat.enrichments.indicator.file.elf.architecture

Machine architecture of the ELF file.

type: keyword

example: x86-64

threat.enrichments.indicator.file.elf.byte_order

Byte sequence of ELF file.

type: keyword

example: Little Endian

threat.enrichments.indicator.file.elf.cpu_type

CPU type of the ELF file.

type: keyword

example: Intel

threat.enrichments.indicator.file.elf.creation_date

Extracted when possible from the file’s metadata. Indicates when it was built or compiled. It can also be faked by malware creators.

type: date

threat.enrichments.indicator.file.elf.exports

List of exported element names and types.

type: flattened

threat.enrichments.indicator.file.elf.header.abi_version

Version of the ELF Application Binary Interface (ABI).

type: keyword

threat.enrichments.indicator.file.elf.header.class

Header class of the ELF file.

type: keyword

threat.enrichments.indicator.file.elf.header.data

Data table of the ELF header.

type: keyword

threat.enrichments.indicator.file.elf.header.entrypoint

Header entrypoint of the ELF file.

type: long

format: string

threat.enrichments.indicator.file.elf.header.object_version

"0x1" for original ELF files.

type: keyword

threat.enrichments.indicator.file.elf.header.os_abi

Application Binary Interface (ABI) of the Linux OS.

type: keyword

threat.enrichments.indicator.file.elf.header.type

Header type of the ELF file.

type: keyword

threat.enrichments.indicator.file.elf.header.version

Version of the ELF header.

type: keyword

threat.enrichments.indicator.file.elf.imports

List of imported element names and types.

type: flattened

threat.enrichments.indicator.file.elf.sections

An array containing an object for each section of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.sections.*.

type: nested

threat.enrichments.indicator.file.elf.sections.chi2

Chi-square probability distribution of the section.

type: long

format: number

threat.enrichments.indicator.file.elf.sections.entropy

Shannon entropy calculation from the section.

type: long

format: number

threat.enrichments.indicator.file.elf.sections.flags

ELF Section List flags.

type: keyword

threat.enrichments.indicator.file.elf.sections.name

ELF Section List name.

type: keyword

threat.enrichments.indicator.file.elf.sections.physical_offset

ELF Section List offset.

type: keyword

threat.enrichments.indicator.file.elf.sections.physical_size

ELF Section List physical size.

type: long

format: bytes

threat.enrichments.indicator.file.elf.sections.type

ELF Section List type.

type: keyword

threat.enrichments.indicator.file.elf.sections.virtual_address

ELF Section List virtual address.

type: long

format: string

threat.enrichments.indicator.file.elf.sections.virtual_size

ELF Section List virtual size.

type: long

format: string

threat.enrichments.indicator.file.elf.segments

An array containing an object for each segment of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.segments.*.

type: nested

threat.enrichments.indicator.file.elf.segments.sections

ELF object segment sections.

type: keyword

threat.enrichments.indicator.file.elf.segments.type

ELF object segment type.

type: keyword

threat.enrichments.indicator.file.elf.shared_libraries

List of shared libraries used by this ELF object.

type: keyword

threat.enrichments.indicator.file.elf.telfhash

telfhash symbol hash for ELF file.

type: keyword

threat.enrichments.indicator.file.extension

File extension, excluding the leading dot. Note that when the file name has multiple extensions (example.tar.gz), only the last one should be captured ("gz", not "tar.gz").

type: keyword

example: png

threat.enrichments.indicator.file.gid

Primary group ID (GID) of the file.

type: keyword

example: 1001

threat.enrichments.indicator.file.group

Primary group name of the file.

type: keyword

example: alice

threat.enrichments.indicator.file.inode

Inode representing the file in the filesystem.

type: keyword

example: 256383

threat.enrichments.indicator.file.mime_type

MIME type should identify the format of the file or stream of bytes using IANA official types, where possible. When more than one type is applicable, the most specific type should be used.

type: keyword

threat.enrichments.indicator.file.mode

Mode of the file in octal representation.

type: keyword

example: 0640

threat.enrichments.indicator.file.mtime

Last time the file content was modified.

type: date

threat.enrichments.indicator.file.name

Name of the file including the extension, without the directory.

type: keyword

example: example.png

threat.enrichments.indicator.file.owner

File owner’s username.

type: keyword

example: alice

threat.enrichments.indicator.file.path

Full path to the file, including the file name. It should include the drive letter, when appropriate.

type: keyword

example: /home/alice/example.png

threat.enrichments.indicator.file.path.text

type: text

threat.enrichments.indicator.file.size

File size in bytes. Only relevant when file.type is "file".

type: long

example: 16384

threat.enrichments.indicator.file.target_path

Target path for symlinks.

type: keyword

threat.enrichments.indicator.file.target_path.text

type: text

threat.enrichments.indicator.file.type

File type (file, dir, or symlink).

type: keyword

example: file

threat.enrichments.indicator.file.uid

The user ID (UID) or security identifier (SID) of the file owner.

type: keyword

example: 1001

threat.enrichments.indicator.first_seen

The date and time when intelligence source first reported sighting this indicator.

type: date

example: 2020-11-05T17:25:47.000Z

threat.enrichments.indicator.geo.city_name

City name.

type: keyword

example: Montreal

threat.enrichments.indicator.geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

threat.enrichments.indicator.geo.continent_name

Name of the continent.

type: keyword

example: North America

threat.enrichments.indicator.geo.country_iso_code

Country ISO code.

type: keyword

example: CA

threat.enrichments.indicator.geo.country_name

Country name.

type: keyword

example: Canada

threat.enrichments.indicator.geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

threat.enrichments.indicator.geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

threat.enrichments.indicator.geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

threat.enrichments.indicator.geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

threat.enrichments.indicator.geo.region_name

Region name.

type: keyword

example: Quebec

threat.enrichments.indicator.geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

threat.enrichments.indicator.hash.md5

MD5 hash.

type: keyword

threat.enrichments.indicator.hash.sha1

SHA1 hash.

type: keyword

threat.enrichments.indicator.hash.sha256

SHA256 hash.

type: keyword

threat.enrichments.indicator.hash.sha512

SHA512 hash.

type: keyword

threat.enrichments.indicator.hash.ssdeep

SSDEEP hash.

type: keyword

threat.enrichments.indicator.ip

Identifies a threat indicator as an IP address (irrespective of direction).

type: ip

example: 1.2.3.4

threat.enrichments.indicator.last_seen

The date and time when intelligence source last reported sighting this indicator.

type: date

example: 2020-11-05T17:25:47.000Z

threat.enrichments.indicator.marking.tlp

Traffic Light Protocol sharing markings. Recommended values are: * WHITE * GREEN * AMBER * RED

type: keyword

example: White

threat.enrichments.indicator.modified_at

The date and time when intelligence source last modified information for this indicator.

type: date

example: 2020-11-05T17:25:47.000Z

threat.enrichments.indicator.pe.architecture

CPU architecture target for the file.

type: keyword

example: x64

threat.enrichments.indicator.pe.company

Internal company name of the file, provided at compile-time.

type: keyword

example: Microsoft Corporation

threat.enrichments.indicator.pe.description

Internal description of the file, provided at compile-time.

type: keyword

example: Paint

threat.enrichments.indicator.pe.file_version

Internal version of the file, provided at compile-time.

type: keyword

example: 6.3.9600.17415

threat.enrichments.indicator.pe.imphash

A hash of the imports in a PE file. An imphash — or import hash — can be used to fingerprint binaries even after recompilation or other code-level transformations have occurred, which would change more traditional hash values. Learn more at https://www.fireeye.com/blog/threat-research/2014/01/tracking-malware-import-hashing.html.

type: keyword

example: 0c6803c4e922103c4dca5963aad36ddf

threat.enrichments.indicator.pe.original_file_name

Internal name of the file, provided at compile-time.

type: keyword

example: MSPAINT.EXE

threat.enrichments.indicator.pe.product

Internal product name of the file, provided at compile-time.

type: keyword

example: Microsoft® Windows® Operating System

threat.enrichments.indicator.port

Identifies a threat indicator as a port number (irrespective of direction).

type: long

example: 443

threat.enrichments.indicator.provider

The name of the indicator’s provider.

type: keyword

example: lrz_urlhaus

threat.enrichments.indicator.reference

Reference URL linking to additional information about this indicator.

type: keyword

example: https://system.example.com/indicator/0001234

threat.enrichments.indicator.registry.data.bytes

Original bytes written with base64 encoding. For Windows registry operations, such as SetValueEx and RegQueryValueEx, this corresponds to the data pointed by lp_data. This is optional but provides better recoverability and should be populated for REG_BINARY encoded values.

type: keyword

example: ZQBuAC0AVQBTAAAAZQBuAAAAAAA=

threat.enrichments.indicator.registry.data.strings

Content when writing string types. Populated as an array when writing string data to the registry. For single string registry types (REG_SZ, REG_EXPAND_SZ), this should be an array with one string. For sequences of string with REG_MULTI_SZ, this array will be variable length. For numeric data, such as REG_DWORD and REG_QWORD, this should be populated with the decimal representation (e.g "1").

type: keyword

example: ["C:\rta\red_ttp\bin\myapp.exe"]

threat.enrichments.indicator.registry.data.type

Standard registry type for encoding contents

type: keyword

example: REG_SZ

threat.enrichments.indicator.registry.hive

Abbreviated name for the hive.

type: keyword

example: HKLM

threat.enrichments.indicator.registry.key

Hive-relative path of keys.

type: keyword

example: SOFTWARE\Microsoft\Windows NT\CurrentVersion\Image File Execution Options\winword.exe

threat.enrichments.indicator.registry.path

Full path, including hive, key and value

type: keyword

example: HKLM\SOFTWARE\Microsoft\Windows NT\CurrentVersion\Image File Execution Options\winword.exe\Debugger

threat.enrichments.indicator.registry.value

Name of the value written.

type: keyword

example: Debugger

threat.enrichments.indicator.scanner_stats

Count of AV/EDR vendors that successfully detected malicious file or URL.

type: long

example: 4

threat.enrichments.indicator.sightings

Number of times this indicator was observed conducting threat activity.

type: long

example: 20

threat.enrichments.indicator.type

Type of indicator as represented by Cyber Observable in STIX 2.0. Recommended values: * autonomous-system * artifact * directory * domain-name * email-addr * file * ipv4-addr * ipv6-addr * mac-addr * mutex * port * process * software * url * user-account * windows-registry-key * x509-certificate

type: keyword

example: ipv4-addr

threat.enrichments.indicator.url.domain

Domain of the url, such as "www.elastic.co". In some cases a URL may refer to an IP and/or port directly, without a domain name. In this case, the IP address would go to the domain field. If the URL contains a literal IPv6 address enclosed by [ and ] (IETF RFC 2732), the [ and ] characters should also be captured in the domain field.

type: keyword

example: www.elastic.co

threat.enrichments.indicator.url.extension

The field contains the file extension from the original request url, excluding the leading dot. The file extension is only set if it exists, as not every url has a file extension. The leading period must not be included. For example, the value must be "png", not ".png". Note that when the file name has multiple extensions (example.tar.gz), only the last one should be captured ("gz", not "tar.gz").

type: keyword

example: png

threat.enrichments.indicator.url.fragment

Portion of the url after the #, such as "top". The # is not part of the fragment.

type: keyword

threat.enrichments.indicator.url.full

If full URLs are important to your use case, they should be stored in url.full, whether this field is reconstructed or present in the event source.

type: keyword

example: https://www.elastic.co:443/search?q=elasticsearch#top

threat.enrichments.indicator.url.full.text

type: text

threat.enrichments.indicator.url.original

Unmodified original url as seen in the event source. Note that in network monitoring, the observed URL may be a full URL, whereas in access logs, the URL is often just represented as a path. This field is meant to represent the URL as it was observed, complete or not.

type: keyword

example: https://www.elastic.co:443/search?q=elasticsearch#top or /search?q=elasticsearch

threat.enrichments.indicator.url.original.text

type: text

threat.enrichments.indicator.url.password

Password of the request.

type: keyword

threat.enrichments.indicator.url.path

Path of the request, such as "/search".

type: keyword

threat.enrichments.indicator.url.port

Port of the request, such as 443.

type: long

example: 443

format: string

threat.enrichments.indicator.url.query

The query field describes the query string of the request, such as "q=elasticsearch". The ? is excluded from the query string. If a URL contains no ?, there is no query field. If there is a ? but no query, the query field exists with an empty string. The exists query can be used to differentiate between the two cases.

type: keyword

threat.enrichments.indicator.url.registered_domain

The highest registered url domain, stripped of the subdomain. For example, the registered domain for "foo.example.com" is "example.com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last two labels will not work well for TLDs such as "co.uk".

type: keyword

example: example.com

threat.enrichments.indicator.url.scheme

Scheme of the request, such as "https". Note: The : is not part of the scheme.

type: keyword

example: https

threat.enrichments.indicator.url.subdomain

The subdomain portion of a fully qualified domain name includes all of the names except the host name under the registered_domain. In a partially qualified domain, or if the the qualification level of the full name cannot be determined, subdomain contains all of the names below the registered domain. For example the subdomain portion of "www.east.mydomain.co.uk" is "east". If the domain has multiple levels of subdomain, such as "sub2.sub1.example.com", the subdomain field should contain "sub2.sub1", with no trailing period.

type: keyword

example: east

threat.enrichments.indicator.url.top_level_domain

The effective top level domain (eTLD), also known as the domain suffix, is the last part of the domain name. For example, the top level domain for example.com is "com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last label will not work well for effective TLDs such as "co.uk".

type: keyword

example: co.uk

threat.enrichments.indicator.url.username

Username of the request.

type: keyword

threat.enrichments.indicator.x509.alternative_names

List of subject alternative names (SAN). Name types vary by certificate authority and certificate type but commonly contain IP addresses, DNS names (and wildcards), and email addresses.

type: keyword

example: *.elastic.co

threat.enrichments.indicator.x509.issuer.common_name

List of common name (CN) of issuing certificate authority.

type: keyword

example: Example SHA2 High Assurance Server CA

threat.enrichments.indicator.x509.issuer.country

List of country © codes

type: keyword

example: US

threat.enrichments.indicator.x509.issuer.distinguished_name

Distinguished name (DN) of issuing certificate authority.

type: keyword

example: C=US, O=Example Inc, OU=www.example.com, CN=Example SHA2 High Assurance Server CA

threat.enrichments.indicator.x509.issuer.locality

List of locality names (L)

type: keyword

example: Mountain View

threat.enrichments.indicator.x509.issuer.organization

List of organizations (O) of issuing certificate authority.

type: keyword

example: Example Inc

threat.enrichments.indicator.x509.issuer.organizational_unit

List of organizational units (OU) of issuing certificate authority.

type: keyword

example: www.example.com

threat.enrichments.indicator.x509.issuer.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

threat.enrichments.indicator.x509.not_after

Time at which the certificate is no longer considered valid.

type: date

example: 2020-07-16 03:15:39+00:00

threat.enrichments.indicator.x509.not_before

Time at which the certificate is first considered valid.

type: date

example: 2019-08-16 01:40:25+00:00

threat.enrichments.indicator.x509.public_key_algorithm

Algorithm used to generate the public key.

type: keyword

example: RSA

threat.enrichments.indicator.x509.public_key_curve

The curve used by the elliptic curve public key algorithm. This is algorithm specific.

type: keyword

example: nistp521

threat.enrichments.indicator.x509.public_key_exponent

Exponent used to derive the public key. This is algorithm specific.

type: long

example: 65537

Field is not indexed.

threat.enrichments.indicator.x509.public_key_size

The size of the public key space in bits.

type: long

example: 2048

threat.enrichments.indicator.x509.serial_number

Unique serial number issued by the certificate authority. For consistency, if this value is alphanumeric, it should be formatted without colons and uppercase characters.

type: keyword

example: 55FBB9C7DEBF09809D12CCAA

threat.enrichments.indicator.x509.signature_algorithm

Identifier for certificate signature algorithm. We recommend using names found in Go Lang Crypto library. See https://github.com/golang/go/blob/go1.14/src/crypto/x509/x509.go#L337-L353.

type: keyword

example: SHA256-RSA

threat.enrichments.indicator.x509.subject.common_name

List of common names (CN) of subject.

type: keyword

example: shared.global.example.net

threat.enrichments.indicator.x509.subject.country

List of country © code

type: keyword

example: US

threat.enrichments.indicator.x509.subject.distinguished_name

Distinguished name (DN) of the certificate subject entity.

type: keyword

example: C=US, ST=California, L=San Francisco, O=Example, Inc., CN=shared.global.example.net

threat.enrichments.indicator.x509.subject.locality

List of locality names (L)

type: keyword

example: San Francisco

threat.enrichments.indicator.x509.subject.organization

List of organizations (O) of subject.

type: keyword

example: Example, Inc.

threat.enrichments.indicator.x509.subject.organizational_unit

List of organizational units (OU) of subject.

type: keyword

threat.enrichments.indicator.x509.subject.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

threat.enrichments.indicator.x509.version_number

Version of x509 format.

type: keyword

example: 3

threat.enrichments.matched.atomic

Identifies the atomic indicator value that matched a local environment endpoint or network event.

type: keyword

example: bad-domain.com

threat.enrichments.matched.field

Identifies the field of the atomic indicator that matched a local environment endpoint or network event.

type: keyword

example: file.hash.sha256

threat.enrichments.matched.id

Identifies the _id of the indicator document enriching the event.

type: keyword

example: ff93aee5-86a1-4a61-b0e6-0cdc313d01b5

threat.enrichments.matched.index

Identifies the _index of the indicator document enriching the event.

type: keyword

example: filebeat-8.0.0-2021.05.23-000011

threat.enrichments.matched.type

Identifies the type of match that caused the event to be enriched with the given indicator

type: keyword

example: indicator_match_rule

threat.framework

Name of the threat framework used to further categorize and classify the tactic and technique of the reported threat. Framework classification can be provided by detecting systems, evaluated at ingest time, or retrospectively tagged to events.

type: keyword

example: MITRE ATT&CK

threat.group.alias

The alias(es) of the group for a set of related intrusion activity that are tracked by a common name in the security community. While not required, you can use a MITRE ATT&CK® group alias(es).

type: keyword

example: [ "Magecart Group 6" ]

threat.group.id

The id of the group for a set of related intrusion activity that are tracked by a common name in the security community. While not required, you can use a MITRE ATT&CK® group id.

type: keyword

example: G0037

threat.group.name

The name of the group for a set of related intrusion activity that are tracked by a common name in the security community. While not required, you can use a MITRE ATT&CK® group name.

type: keyword

example: FIN6

threat.group.reference

The reference URL of the group for a set of related intrusion activity that are tracked by a common name in the security community. While not required, you can use a MITRE ATT&CK® group reference URL.

type: keyword

example: https://attack.mitre.org/groups/G0037/

threat.indicator.as.number

Unique number allocated to the autonomous system. The autonomous system number (ASN) uniquely identifies each network on the Internet.

type: long

example: 15169

threat.indicator.as.organization.name

Organization name.

type: keyword

example: Google LLC

threat.indicator.as.organization.name.text

type: text

threat.indicator.confidence

Identifies the confidence rating assigned by the provider using STIX confidence scales. Recommended values: * Not Specified, None, Low, Medium, High * 0-10 * Admirality Scale (1-6) * DNI Scale (5-95) * WEP Scale (Impossible - Certain)

type: keyword

example: High

threat.indicator.description

Describes the type of action conducted by the threat.

type: keyword

example: IP x.x.x.x was observed delivering the Angler EK.

threat.indicator.email.address

Identifies a threat indicator as an email address (irrespective of direction).

type: keyword

example: phish@example.com

threat.indicator.file.accessed

Last time the file was accessed. Note that not all filesystems keep track of access time.

type: date

threat.indicator.file.attributes

Array of file attributes. Attributes names will vary by platform. Here’s a non-exhaustive list of values that are expected in this field: archive, compressed, directory, encrypted, execute, hidden, read, readonly, system, write.

type: keyword

example: ["readonly", "system"]

threat.indicator.file.code_signature.exists

Boolean to capture if a signature is present.

type: boolean

example: true

threat.indicator.file.code_signature.signing_id

The identifier used to sign the process. This is used to identify the application manufactured by a software vendor. The field is relevant to Apple *OS only.

type: keyword

example: com.apple.xpc.proxy

threat.indicator.file.code_signature.status

Additional information about the certificate status. This is useful for logging cryptographic errors with the certificate validity or trust status. Leave unpopulated if the validity or trust of the certificate was unchecked.

type: keyword

example: ERROR_UNTRUSTED_ROOT

threat.indicator.file.code_signature.subject_name

Subject name of the code signer

type: keyword

example: Microsoft Corporation

threat.indicator.file.code_signature.team_id

The team identifier used to sign the process. This is used to identify the team or vendor of a software product. The field is relevant to Apple *OS only.

type: keyword

example: EQHXZ8M8AV

threat.indicator.file.code_signature.trusted

Stores the trust status of the certificate chain. Validating the trust of the certificate chain may be complicated, and this field should only be populated by tools that actively check the status.

type: boolean

example: true

threat.indicator.file.code_signature.valid

Boolean to capture if the digital signature is verified against the binary content. Leave unpopulated if a certificate was unchecked.

type: boolean

example: true

threat.indicator.file.created

File creation time. Note that not all filesystems store the creation time.

type: date

threat.indicator.file.ctime

Last time the file attributes or metadata changed. Note that changes to the file content will update mtime. This implies ctime will be adjusted at the same time, since mtime is an attribute of the file.

type: date

threat.indicator.file.device

Device that is the source of the file.

type: keyword

example: sda

threat.indicator.file.directory

Directory where the file is located. It should include the drive letter, when appropriate.

type: keyword

example: /home/alice

threat.indicator.file.drive_letter

Drive letter where the file is located. This field is only relevant on Windows. The value should be uppercase, and not include the colon.

type: keyword

example: C

threat.indicator.file.elf.architecture

Machine architecture of the ELF file.

type: keyword

example: x86-64

threat.indicator.file.elf.byte_order

Byte sequence of ELF file.

type: keyword

example: Little Endian

threat.indicator.file.elf.cpu_type

CPU type of the ELF file.

type: keyword

example: Intel

threat.indicator.file.elf.creation_date

Extracted when possible from the file’s metadata. Indicates when it was built or compiled. It can also be faked by malware creators.

type: date

threat.indicator.file.elf.exports

List of exported element names and types.

type: flattened

threat.indicator.file.elf.header.abi_version

Version of the ELF Application Binary Interface (ABI).

type: keyword

threat.indicator.file.elf.header.class

Header class of the ELF file.

type: keyword

threat.indicator.file.elf.header.data

Data table of the ELF header.

type: keyword

threat.indicator.file.elf.header.entrypoint

Header entrypoint of the ELF file.

type: long

format: string

threat.indicator.file.elf.header.object_version

"0x1" for original ELF files.

type: keyword

threat.indicator.file.elf.header.os_abi

Application Binary Interface (ABI) of the Linux OS.

type: keyword

threat.indicator.file.elf.header.type

Header type of the ELF file.

type: keyword

threat.indicator.file.elf.header.version

Version of the ELF header.

type: keyword

threat.indicator.file.elf.imports

List of imported element names and types.

type: flattened

threat.indicator.file.elf.sections

An array containing an object for each section of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.sections.*.

type: nested

threat.indicator.file.elf.sections.chi2

Chi-square probability distribution of the section.

type: long

format: number

threat.indicator.file.elf.sections.entropy

Shannon entropy calculation from the section.

type: long

format: number

threat.indicator.file.elf.sections.flags

ELF Section List flags.

type: keyword

threat.indicator.file.elf.sections.name

ELF Section List name.

type: keyword

threat.indicator.file.elf.sections.physical_offset

ELF Section List offset.

type: keyword

threat.indicator.file.elf.sections.physical_size

ELF Section List physical size.

type: long

format: bytes

threat.indicator.file.elf.sections.type

ELF Section List type.

type: keyword

threat.indicator.file.elf.sections.virtual_address

ELF Section List virtual address.

type: long

format: string

threat.indicator.file.elf.sections.virtual_size

ELF Section List virtual size.

type: long

format: string

threat.indicator.file.elf.segments

An array containing an object for each segment of the ELF file. The keys that should be present in these objects are defined by sub-fields underneath elf.segments.*.

type: nested

threat.indicator.file.elf.segments.sections

ELF object segment sections.

type: keyword

threat.indicator.file.elf.segments.type

ELF object segment type.

type: keyword

threat.indicator.file.elf.shared_libraries

List of shared libraries used by this ELF object.

type: keyword

threat.indicator.file.elf.telfhash

telfhash symbol hash for ELF file.

type: keyword

threat.indicator.file.extension

File extension, excluding the leading dot. Note that when the file name has multiple extensions (example.tar.gz), only the last one should be captured ("gz", not "tar.gz").

type: keyword

example: png

threat.indicator.file.gid

Primary group ID (GID) of the file.

type: keyword

example: 1001

threat.indicator.file.group

Primary group name of the file.

type: keyword

example: alice

threat.indicator.file.inode

Inode representing the file in the filesystem.

type: keyword

example: 256383

threat.indicator.file.mime_type

MIME type should identify the format of the file or stream of bytes using IANA official types, where possible. When more than one type is applicable, the most specific type should be used.

type: keyword

threat.indicator.file.mode

Mode of the file in octal representation.

type: keyword

example: 0640

threat.indicator.file.mtime

Last time the file content was modified.

type: date

threat.indicator.file.name

Name of the file including the extension, without the directory.

type: keyword

example: example.png

threat.indicator.file.owner

File owner’s username.

type: keyword

example: alice

threat.indicator.file.path

Full path to the file, including the file name. It should include the drive letter, when appropriate.

type: keyword

example: /home/alice/example.png

threat.indicator.file.path.text

type: text

threat.indicator.file.size

File size in bytes. Only relevant when file.type is "file".

type: long

example: 16384

threat.indicator.file.target_path

Target path for symlinks.

type: keyword

threat.indicator.file.target_path.text

type: text

threat.indicator.file.type

File type (file, dir, or symlink).

type: keyword

example: file

threat.indicator.file.uid

The user ID (UID) or security identifier (SID) of the file owner.

type: keyword

example: 1001

threat.indicator.first_seen

The date and time when intelligence source first reported sighting this indicator.

type: date

example: 2020-11-05T17:25:47.000Z

threat.indicator.geo.city_name

City name.

type: keyword

example: Montreal

threat.indicator.geo.continent_code

Two-letter code representing continent’s name.

type: keyword

example: NA

threat.indicator.geo.continent_name

Name of the continent.

type: keyword

example: North America

threat.indicator.geo.country_iso_code

Country ISO code.

type: keyword

example: CA

threat.indicator.geo.country_name

Country name.

type: keyword

example: Canada

threat.indicator.geo.location

Longitude and latitude.

type: geo_point

example: { "lon": -73.614830, "lat": 45.505918 }

threat.indicator.geo.name

User-defined description of a location, at the level of granularity they care about. Could be the name of their data centers, the floor number, if this describes a local physical entity, city names. Not typically used in automated geolocation.

type: keyword

example: boston-dc

threat.indicator.geo.postal_code

Postal code associated with the location. Values appropriate for this field may also be known as a postcode or ZIP code and will vary widely from country to country.

type: keyword

example: 94040

threat.indicator.geo.region_iso_code

Region ISO code.

type: keyword

example: CA-QC

threat.indicator.geo.region_name

Region name.

type: keyword

example: Quebec

threat.indicator.geo.timezone

The time zone of the location, such as IANA time zone name.

type: keyword

example: America/Argentina/Buenos_Aires

threat.indicator.hash.md5

MD5 hash.

type: keyword

threat.indicator.hash.sha1

SHA1 hash.

type: keyword

threat.indicator.hash.sha256

SHA256 hash.

type: keyword

threat.indicator.hash.sha512

SHA512 hash.

type: keyword

threat.indicator.hash.ssdeep

SSDEEP hash.

type: keyword

threat.indicator.ip

Identifies a threat indicator as an IP address (irrespective of direction).

type: ip

example: 1.2.3.4

threat.indicator.last_seen

The date and time when intelligence source last reported sighting this indicator.

type: date

example: 2020-11-05T17:25:47.000Z

threat.indicator.marking.tlp

Traffic Light Protocol sharing markings. Recommended values are: * WHITE * GREEN * AMBER * RED

type: keyword

example: WHITE

threat.indicator.modified_at

The date and time when intelligence source last modified information for this indicator.

type: date

example: 2020-11-05T17:25:47.000Z

threat.indicator.pe.architecture

CPU architecture target for the file.

type: keyword

example: x64

threat.indicator.pe.company

Internal company name of the file, provided at compile-time.

type: keyword

example: Microsoft Corporation

threat.indicator.pe.description

Internal description of the file, provided at compile-time.

type: keyword

example: Paint

threat.indicator.pe.file_version

Internal version of the file, provided at compile-time.

type: keyword

example: 6.3.9600.17415

threat.indicator.pe.imphash

A hash of the imports in a PE file. An imphash — or import hash — can be used to fingerprint binaries even after recompilation or other code-level transformations have occurred, which would change more traditional hash values. Learn more at https://www.fireeye.com/blog/threat-research/2014/01/tracking-malware-import-hashing.html.

type: keyword

example: 0c6803c4e922103c4dca5963aad36ddf

threat.indicator.pe.original_file_name

Internal name of the file, provided at compile-time.

type: keyword

example: MSPAINT.EXE

threat.indicator.pe.product

Internal product name of the file, provided at compile-time.

type: keyword

example: Microsoft® Windows® Operating System

threat.indicator.port

Identifies a threat indicator as a port number (irrespective of direction).

type: long

example: 443

threat.indicator.provider

The name of the indicator’s provider.

type: keyword

example: lrz_urlhaus

threat.indicator.reference

Reference URL linking to additional information about this indicator.

type: keyword

example: https://system.example.com/indicator/0001234

threat.indicator.registry.data.bytes

Original bytes written with base64 encoding. For Windows registry operations, such as SetValueEx and RegQueryValueEx, this corresponds to the data pointed by lp_data. This is optional but provides better recoverability and should be populated for REG_BINARY encoded values.

type: keyword

example: ZQBuAC0AVQBTAAAAZQBuAAAAAAA=

threat.indicator.registry.data.strings

Content when writing string types. Populated as an array when writing string data to the registry. For single string registry types (REG_SZ, REG_EXPAND_SZ), this should be an array with one string. For sequences of string with REG_MULTI_SZ, this array will be variable length. For numeric data, such as REG_DWORD and REG_QWORD, this should be populated with the decimal representation (e.g "1").

type: keyword

example: ["C:\rta\red_ttp\bin\myapp.exe"]

threat.indicator.registry.data.type

Standard registry type for encoding contents

type: keyword

example: REG_SZ

threat.indicator.registry.hive

Abbreviated name for the hive.

type: keyword

example: HKLM

threat.indicator.registry.key

Hive-relative path of keys.

type: keyword

example: SOFTWARE\Microsoft\Windows NT\CurrentVersion\Image File Execution Options\winword.exe

threat.indicator.registry.path

Full path, including hive, key and value

type: keyword

example: HKLM\SOFTWARE\Microsoft\Windows NT\CurrentVersion\Image File Execution Options\winword.exe\Debugger

threat.indicator.registry.value

Name of the value written.

type: keyword

example: Debugger

threat.indicator.scanner_stats

Count of AV/EDR vendors that successfully detected malicious file or URL.

type: long

example: 4

threat.indicator.sightings

Number of times this indicator was observed conducting threat activity.

type: long

example: 20

threat.indicator.type

Type of indicator as represented by Cyber Observable in STIX 2.0. Recommended values: * autonomous-system * artifact * directory * domain-name * email-addr * file * ipv4-addr * ipv6-addr * mac-addr * mutex * port * process * software * url * user-account * windows-registry-key * x509-certificate

type: keyword

example: ipv4-addr

threat.indicator.url.domain

Domain of the url, such as "www.elastic.co". In some cases a URL may refer to an IP and/or port directly, without a domain name. In this case, the IP address would go to the domain field. If the URL contains a literal IPv6 address enclosed by [ and ] (IETF RFC 2732), the [ and ] characters should also be captured in the domain field.

type: keyword

example: www.elastic.co

threat.indicator.url.extension

The field contains the file extension from the original request url, excluding the leading dot. The file extension is only set if it exists, as not every url has a file extension. The leading period must not be included. For example, the value must be "png", not ".png". Note that when the file name has multiple extensions (example.tar.gz), only the last one should be captured ("gz", not "tar.gz").

type: keyword

example: png

threat.indicator.url.fragment

Portion of the url after the #, such as "top". The # is not part of the fragment.

type: keyword

threat.indicator.url.full

If full URLs are important to your use case, they should be stored in url.full, whether this field is reconstructed or present in the event source.

type: keyword

example: https://www.elastic.co:443/search?q=elasticsearch#top

threat.indicator.url.full.text

type: text

threat.indicator.url.original

Unmodified original url as seen in the event source. Note that in network monitoring, the observed URL may be a full URL, whereas in access logs, the URL is often just represented as a path. This field is meant to represent the URL as it was observed, complete or not.

type: keyword

example: https://www.elastic.co:443/search?q=elasticsearch#top or /search?q=elasticsearch

threat.indicator.url.original.text

type: text

threat.indicator.url.password

Password of the request.

type: keyword

threat.indicator.url.path

Path of the request, such as "/search".

type: keyword

threat.indicator.url.port

Port of the request, such as 443.

type: long

example: 443

format: string

threat.indicator.url.query

The query field describes the query string of the request, such as "q=elasticsearch". The ? is excluded from the query string. If a URL contains no ?, there is no query field. If there is a ? but no query, the query field exists with an empty string. The exists query can be used to differentiate between the two cases.

type: keyword

threat.indicator.url.registered_domain

The highest registered url domain, stripped of the subdomain. For example, the registered domain for "foo.example.com" is "example.com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last two labels will not work well for TLDs such as "co.uk".

type: keyword

example: example.com

threat.indicator.url.scheme

Scheme of the request, such as "https". Note: The : is not part of the scheme.

type: keyword

example: https

threat.indicator.url.subdomain

The subdomain portion of a fully qualified domain name includes all of the names except the host name under the registered_domain. In a partially qualified domain, or if the the qualification level of the full name cannot be determined, subdomain contains all of the names below the registered domain. For example the subdomain portion of "www.east.mydomain.co.uk" is "east". If the domain has multiple levels of subdomain, such as "sub2.sub1.example.com", the subdomain field should contain "sub2.sub1", with no trailing period.

type: keyword

example: east

threat.indicator.url.top_level_domain

The effective top level domain (eTLD), also known as the domain suffix, is the last part of the domain name. For example, the top level domain for example.com is "com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last label will not work well for effective TLDs such as "co.uk".

type: keyword

example: co.uk

threat.indicator.url.username

Username of the request.

type: keyword

threat.indicator.x509.alternative_names

List of subject alternative names (SAN). Name types vary by certificate authority and certificate type but commonly contain IP addresses, DNS names (and wildcards), and email addresses.

type: keyword

example: *.elastic.co

threat.indicator.x509.issuer.common_name

List of common name (CN) of issuing certificate authority.

type: keyword

example: Example SHA2 High Assurance Server CA

threat.indicator.x509.issuer.country

List of country © codes

type: keyword

example: US

threat.indicator.x509.issuer.distinguished_name

Distinguished name (DN) of issuing certificate authority.

type: keyword

example: C=US, O=Example Inc, OU=www.example.com, CN=Example SHA2 High Assurance Server CA

threat.indicator.x509.issuer.locality

List of locality names (L)

type: keyword

example: Mountain View

threat.indicator.x509.issuer.organization

List of organizations (O) of issuing certificate authority.

type: keyword

example: Example Inc

threat.indicator.x509.issuer.organizational_unit

List of organizational units (OU) of issuing certificate authority.

type: keyword

example: www.example.com

threat.indicator.x509.issuer.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

threat.indicator.x509.not_after

Time at which the certificate is no longer considered valid.

type: date

example: 2020-07-16 03:15:39+00:00

threat.indicator.x509.not_before

Time at which the certificate is first considered valid.

type: date

example: 2019-08-16 01:40:25+00:00

threat.indicator.x509.public_key_algorithm

Algorithm used to generate the public key.

type: keyword

example: RSA

threat.indicator.x509.public_key_curve

The curve used by the elliptic curve public key algorithm. This is algorithm specific.

type: keyword

example: nistp521

threat.indicator.x509.public_key_exponent

Exponent used to derive the public key. This is algorithm specific.

type: long

example: 65537

Field is not indexed.

threat.indicator.x509.public_key_size

The size of the public key space in bits.

type: long

example: 2048

threat.indicator.x509.serial_number

Unique serial number issued by the certificate authority. For consistency, if this value is alphanumeric, it should be formatted without colons and uppercase characters.

type: keyword

example: 55FBB9C7DEBF09809D12CCAA

threat.indicator.x509.signature_algorithm

Identifier for certificate signature algorithm. We recommend using names found in Go Lang Crypto library. See https://github.com/golang/go/blob/go1.14/src/crypto/x509/x509.go#L337-L353.

type: keyword

example: SHA256-RSA

threat.indicator.x509.subject.common_name

List of common names (CN) of subject.

type: keyword

example: shared.global.example.net

threat.indicator.x509.subject.country

List of country © code

type: keyword

example: US

threat.indicator.x509.subject.distinguished_name

Distinguished name (DN) of the certificate subject entity.

type: keyword

example: C=US, ST=California, L=San Francisco, O=Example, Inc., CN=shared.global.example.net

threat.indicator.x509.subject.locality

List of locality names (L)

type: keyword

example: San Francisco

threat.indicator.x509.subject.organization

List of organizations (O) of subject.

type: keyword

example: Example, Inc.

threat.indicator.x509.subject.organizational_unit

List of organizational units (OU) of subject.

type: keyword

threat.indicator.x509.subject.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

threat.indicator.x509.version_number

Version of x509 format.

type: keyword

example: 3

threat.software.id

The id of the software used by this threat to conduct behavior commonly modeled using MITRE ATT&CK®. While not required, you can use a MITRE ATT&CK® software id.

type: keyword

example: S0552

threat.software.name

The name of the software used by this threat to conduct behavior commonly modeled using MITRE ATT&CK®. While not required, you can use a MITRE ATT&CK® software name.

type: keyword

example: AdFind

threat.software.platforms

The platforms of the software used by this threat to conduct behavior commonly modeled using MITRE ATT&CK®. While not required, you can use a MITRE ATT&CK® software platforms. Recommended Values: * AWS * Azure * Azure AD * GCP * Linux * macOS * Network * Office 365 * SaaS * Windows

type: keyword

example: [ "Windows" ]

threat.software.reference

The reference URL of the software used by this threat to conduct behavior commonly modeled using MITRE ATT&CK®. While not required, you can use a MITRE ATT&CK® software reference URL.

type: keyword

example: https://attack.mitre.org/software/S0552/

threat.software.type

The type of software used by this threat to conduct behavior commonly modeled using MITRE ATT&CK®. While not required, you can use a MITRE ATT&CK® software type. Recommended values * Malware * Tool

type: keyword

example: Tool

threat.tactic.id

The id of tactic used by this threat. You can use a MITRE ATT&CK® tactic, for example. (ex. https://attack.mitre.org/tactics/TA0002/ )

type: keyword

example: TA0002

threat.tactic.name

Name of the type of tactic used by this threat. You can use a MITRE ATT&CK® tactic, for example. (ex. https://attack.mitre.org/tactics/TA0002/)

type: keyword

example: Execution

threat.tactic.reference

The reference url of tactic used by this threat. You can use a MITRE ATT&CK® tactic, for example. (ex. https://attack.mitre.org/tactics/TA0002/ )

type: keyword

example: https://attack.mitre.org/tactics/TA0002/

threat.technique.id

The id of technique used by this threat. You can use a MITRE ATT&CK® technique, for example. (ex. https://attack.mitre.org/techniques/T1059/)

type: keyword

example: T1059

threat.technique.name

The name of technique used by this threat. You can use a MITRE ATT&CK® technique, for example. (ex. https://attack.mitre.org/techniques/T1059/)

type: keyword

example: Command and Scripting Interpreter

threat.technique.name.text

type: text

threat.technique.reference

The reference url of technique used by this threat. You can use a MITRE ATT&CK® technique, for example. (ex. https://attack.mitre.org/techniques/T1059/)

type: keyword

example: https://attack.mitre.org/techniques/T1059/

threat.technique.subtechnique.id

The full id of subtechnique used by this threat. You can use a MITRE ATT&CK® subtechnique, for example. (ex. https://attack.mitre.org/techniques/T1059/001/)

type: keyword

example: T1059.001

threat.technique.subtechnique.name

The name of subtechnique used by this threat. You can use a MITRE ATT&CK® subtechnique, for example. (ex. https://attack.mitre.org/techniques/T1059/001/)

type: keyword

example: PowerShell

threat.technique.subtechnique.name.text

type: text

threat.technique.subtechnique.reference

The reference url of subtechnique used by this threat. You can use a MITRE ATT&CK® subtechnique, for example. (ex. https://attack.mitre.org/techniques/T1059/001/)

type: keyword

example: https://attack.mitre.org/techniques/T1059/001/

tls

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Fields related to a TLS connection. These fields focus on the TLS protocol itself and intentionally avoids in-depth analysis of the related x.509 certificate files.

tls.cipher

String indicating the cipher used during the current connection.

type: keyword

example: TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256

tls.client.certificate

PEM-encoded stand-alone certificate offered by the client. This is usually mutually-exclusive of client.certificate_chain since this value also exists in that list.

type: keyword

example: MII…​

tls.client.certificate_chain

Array of PEM-encoded certificates that make up the certificate chain offered by the client. This is usually mutually-exclusive of client.certificate since that value should be the first certificate in the chain.

type: keyword

example: ["MII…​", "MII…​"]

tls.client.hash.md5

Certificate fingerprint using the MD5 digest of DER-encoded version of certificate offered by the client. For consistency with other hash values, this value should be formatted as an uppercase hash.

type: keyword

example: 0F76C7F2C55BFD7D8E8B8F4BFBF0C9EC

tls.client.hash.sha1

Certificate fingerprint using the SHA1 digest of DER-encoded version of certificate offered by the client. For consistency with other hash values, this value should be formatted as an uppercase hash.

type: keyword

example: 9E393D93138888D288266C2D915214D1D1CCEB2A

tls.client.hash.sha256

Certificate fingerprint using the SHA256 digest of DER-encoded version of certificate offered by the client. For consistency with other hash values, this value should be formatted as an uppercase hash.

type: keyword

example: 0687F666A054EF17A08E2F2162EAB4CBC0D265E1D7875BE74BF3C712CA92DAF0

tls.client.issuer

Distinguished name of subject of the issuer of the x.509 certificate presented by the client.

type: keyword

example: CN=Example Root CA, OU=Infrastructure Team, DC=example, DC=com

tls.client.ja3

A hash that identifies clients based on how they perform an SSL/TLS handshake.

type: keyword

example: d4e5b18d6b55c71272893221c96ba240

tls.client.not_after

Date/Time indicating when client certificate is no longer considered valid.

type: date

example: 2021-01-01T00:00:00.000Z

tls.client.not_before

Date/Time indicating when client certificate is first considered valid.

type: date

example: 1970-01-01T00:00:00.000Z

tls.client.server_name

Also called an SNI, this tells the server which hostname to which the client is attempting to connect to. When this value is available, it should get copied to destination.domain.

type: keyword

example: www.elastic.co

tls.client.subject

Distinguished name of subject of the x.509 certificate presented by the client.

type: keyword

example: CN=myclient, OU=Documentation Team, DC=example, DC=com

tls.client.supported_ciphers

Array of ciphers offered by the client during the client hello.

type: keyword

example: ["TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384", "TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384", "…​"]

tls.client.x509.alternative_names

List of subject alternative names (SAN). Name types vary by certificate authority and certificate type but commonly contain IP addresses, DNS names (and wildcards), and email addresses.

type: keyword

example: *.elastic.co

tls.client.x509.issuer.common_name

List of common name (CN) of issuing certificate authority.

type: keyword

example: Example SHA2 High Assurance Server CA

tls.client.x509.issuer.country

List of country © codes

type: keyword

example: US

tls.client.x509.issuer.distinguished_name

Distinguished name (DN) of issuing certificate authority.

type: keyword

example: C=US, O=Example Inc, OU=www.example.com, CN=Example SHA2 High Assurance Server CA

tls.client.x509.issuer.locality

List of locality names (L)

type: keyword

example: Mountain View

tls.client.x509.issuer.organization

List of organizations (O) of issuing certificate authority.

type: keyword

example: Example Inc

tls.client.x509.issuer.organizational_unit

List of organizational units (OU) of issuing certificate authority.

type: keyword

example: www.example.com

tls.client.x509.issuer.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

tls.client.x509.not_after

Time at which the certificate is no longer considered valid.

type: date

example: 2020-07-16 03:15:39+00:00

tls.client.x509.not_before

Time at which the certificate is first considered valid.

type: date

example: 2019-08-16 01:40:25+00:00

tls.client.x509.public_key_algorithm

Algorithm used to generate the public key.

type: keyword

example: RSA

tls.client.x509.public_key_curve

The curve used by the elliptic curve public key algorithm. This is algorithm specific.

type: keyword

example: nistp521

tls.client.x509.public_key_exponent

Exponent used to derive the public key. This is algorithm specific.

type: long

example: 65537

Field is not indexed.

tls.client.x509.public_key_size

The size of the public key space in bits.

type: long

example: 2048

tls.client.x509.serial_number

Unique serial number issued by the certificate authority. For consistency, if this value is alphanumeric, it should be formatted without colons and uppercase characters.

type: keyword

example: 55FBB9C7DEBF09809D12CCAA

tls.client.x509.signature_algorithm

Identifier for certificate signature algorithm. We recommend using names found in Go Lang Crypto library. See https://github.com/golang/go/blob/go1.14/src/crypto/x509/x509.go#L337-L353.

type: keyword

example: SHA256-RSA

tls.client.x509.subject.common_name

List of common names (CN) of subject.

type: keyword

example: shared.global.example.net

tls.client.x509.subject.country

List of country © code

type: keyword

example: US

tls.client.x509.subject.distinguished_name

Distinguished name (DN) of the certificate subject entity.

type: keyword

example: C=US, ST=California, L=San Francisco, O=Example, Inc., CN=shared.global.example.net

tls.client.x509.subject.locality

List of locality names (L)

type: keyword

example: San Francisco

tls.client.x509.subject.organization

List of organizations (O) of subject.

type: keyword

example: Example, Inc.

tls.client.x509.subject.organizational_unit

List of organizational units (OU) of subject.

type: keyword

tls.client.x509.subject.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

tls.client.x509.version_number

Version of x509 format.

type: keyword

example: 3

tls.curve

String indicating the curve used for the given cipher, when applicable.

type: keyword

example: secp256r1

tls.established

Boolean flag indicating if the TLS negotiation was successful and transitioned to an encrypted tunnel.

type: boolean

tls.next_protocol

String indicating the protocol being tunneled. Per the values in the IANA registry (https://www.iana.org/assignments/tls-extensiontype-values/tls-extensiontype-values.xhtml#alpn-protocol-ids), this string should be lower case.

type: keyword

example: http/1.1

tls.resumed

Boolean flag indicating if this TLS connection was resumed from an existing TLS negotiation.

type: boolean

tls.server.certificate

PEM-encoded stand-alone certificate offered by the server. This is usually mutually-exclusive of server.certificate_chain since this value also exists in that list.

type: keyword

example: MII…​

tls.server.certificate_chain

Array of PEM-encoded certificates that make up the certificate chain offered by the server. This is usually mutually-exclusive of server.certificate since that value should be the first certificate in the chain.

type: keyword

example: ["MII…​", "MII…​"]

tls.server.hash.md5

Certificate fingerprint using the MD5 digest of DER-encoded version of certificate offered by the server. For consistency with other hash values, this value should be formatted as an uppercase hash.

type: keyword

example: 0F76C7F2C55BFD7D8E8B8F4BFBF0C9EC

tls.server.hash.sha1

Certificate fingerprint using the SHA1 digest of DER-encoded version of certificate offered by the server. For consistency with other hash values, this value should be formatted as an uppercase hash.

type: keyword

example: 9E393D93138888D288266C2D915214D1D1CCEB2A

tls.server.hash.sha256

Certificate fingerprint using the SHA256 digest of DER-encoded version of certificate offered by the server. For consistency with other hash values, this value should be formatted as an uppercase hash.

type: keyword

example: 0687F666A054EF17A08E2F2162EAB4CBC0D265E1D7875BE74BF3C712CA92DAF0

tls.server.issuer

Subject of the issuer of the x.509 certificate presented by the server.

type: keyword

example: CN=Example Root CA, OU=Infrastructure Team, DC=example, DC=com

tls.server.ja3s

A hash that identifies servers based on how they perform an SSL/TLS handshake.

type: keyword

example: 394441ab65754e2207b1e1b457b3641d

tls.server.not_after

Timestamp indicating when server certificate is no longer considered valid.

type: date

example: 2021-01-01T00:00:00.000Z

tls.server.not_before

Timestamp indicating when server certificate is first considered valid.

type: date

example: 1970-01-01T00:00:00.000Z

tls.server.subject

Subject of the x.509 certificate presented by the server.

type: keyword

example: CN=www.example.com, OU=Infrastructure Team, DC=example, DC=com

tls.server.x509.alternative_names

List of subject alternative names (SAN). Name types vary by certificate authority and certificate type but commonly contain IP addresses, DNS names (and wildcards), and email addresses.

type: keyword

example: *.elastic.co

tls.server.x509.issuer.common_name

List of common name (CN) of issuing certificate authority.

type: keyword

example: Example SHA2 High Assurance Server CA

tls.server.x509.issuer.country

List of country © codes

type: keyword

example: US

tls.server.x509.issuer.distinguished_name

Distinguished name (DN) of issuing certificate authority.

type: keyword

example: C=US, O=Example Inc, OU=www.example.com, CN=Example SHA2 High Assurance Server CA

tls.server.x509.issuer.locality

List of locality names (L)

type: keyword

example: Mountain View

tls.server.x509.issuer.organization

List of organizations (O) of issuing certificate authority.

type: keyword

example: Example Inc

tls.server.x509.issuer.organizational_unit

List of organizational units (OU) of issuing certificate authority.

type: keyword

example: www.example.com

tls.server.x509.issuer.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

tls.server.x509.not_after

Time at which the certificate is no longer considered valid.

type: date

example: 2020-07-16 03:15:39+00:00

tls.server.x509.not_before

Time at which the certificate is first considered valid.

type: date

example: 2019-08-16 01:40:25+00:00

tls.server.x509.public_key_algorithm

Algorithm used to generate the public key.

type: keyword

example: RSA

tls.server.x509.public_key_curve

The curve used by the elliptic curve public key algorithm. This is algorithm specific.

type: keyword

example: nistp521

tls.server.x509.public_key_exponent

Exponent used to derive the public key. This is algorithm specific.

type: long

example: 65537

Field is not indexed.

tls.server.x509.public_key_size

The size of the public key space in bits.

type: long

example: 2048

tls.server.x509.serial_number

Unique serial number issued by the certificate authority. For consistency, if this value is alphanumeric, it should be formatted without colons and uppercase characters.

type: keyword

example: 55FBB9C7DEBF09809D12CCAA

tls.server.x509.signature_algorithm

Identifier for certificate signature algorithm. We recommend using names found in Go Lang Crypto library. See https://github.com/golang/go/blob/go1.14/src/crypto/x509/x509.go#L337-L353.

type: keyword

example: SHA256-RSA

tls.server.x509.subject.common_name

List of common names (CN) of subject.

type: keyword

example: shared.global.example.net

tls.server.x509.subject.country

List of country © code

type: keyword

example: US

tls.server.x509.subject.distinguished_name

Distinguished name (DN) of the certificate subject entity.

type: keyword

example: C=US, ST=California, L=San Francisco, O=Example, Inc., CN=shared.global.example.net

tls.server.x509.subject.locality

List of locality names (L)

type: keyword

example: San Francisco

tls.server.x509.subject.organization

List of organizations (O) of subject.

type: keyword

example: Example, Inc.

tls.server.x509.subject.organizational_unit

List of organizational units (OU) of subject.

type: keyword

tls.server.x509.subject.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

tls.server.x509.version_number

Version of x509 format.

type: keyword

example: 3

tls.version

Numeric part of the version parsed from the original string.

type: keyword

example: 1.2

tls.version_protocol

Normalized lowercase protocol name parsed from original string.

type: keyword

example: tls

span.id

Unique identifier of the span within the scope of its trace. A span represents an operation within a transaction, such as a request to another service, or a database query.

type: keyword

example: 3ff9a8981b7ccd5a

trace.id

Unique identifier of the trace. A trace groups multiple events like transactions that belong together. For example, a user request handled by multiple inter-connected services.

type: keyword

example: 4bf92f3577b34da6a3ce929d0e0e4736

transaction.id

Unique identifier of the transaction within the scope of its trace. A transaction is the highest level of work measured within a service, such as a request to a server.

type: keyword

example: 00f067aa0ba902b7

url

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URL fields provide support for complete or partial URLs, and supports the breaking down into scheme, domain, path, and so on.

url.domain

Domain of the url, such as "www.elastic.co". In some cases a URL may refer to an IP and/or port directly, without a domain name. In this case, the IP address would go to the domain field. If the URL contains a literal IPv6 address enclosed by [ and ] (IETF RFC 2732), the [ and ] characters should also be captured in the domain field.

type: keyword

example: www.elastic.co

url.extension

The field contains the file extension from the original request url, excluding the leading dot. The file extension is only set if it exists, as not every url has a file extension. The leading period must not be included. For example, the value must be "png", not ".png". Note that when the file name has multiple extensions (example.tar.gz), only the last one should be captured ("gz", not "tar.gz").

type: keyword

example: png

url.fragment

Portion of the url after the #, such as "top". The # is not part of the fragment.

type: keyword

url.full

If full URLs are important to your use case, they should be stored in url.full, whether this field is reconstructed or present in the event source.

type: keyword

example: https://www.elastic.co:443/search?q=elasticsearch#top

url.full.text

type: text

url.original

Unmodified original url as seen in the event source. Note that in network monitoring, the observed URL may be a full URL, whereas in access logs, the URL is often just represented as a path. This field is meant to represent the URL as it was observed, complete or not.

type: keyword

example: https://www.elastic.co:443/search?q=elasticsearch#top or /search?q=elasticsearch

url.original.text

type: text

url.password

Password of the request.

type: keyword

url.path

Path of the request, such as "/search".

type: keyword

url.port

Port of the request, such as 443.

type: long

example: 443

format: string

url.query

The query field describes the query string of the request, such as "q=elasticsearch". The ? is excluded from the query string. If a URL contains no ?, there is no query field. If there is a ? but no query, the query field exists with an empty string. The exists query can be used to differentiate between the two cases.

type: keyword

url.registered_domain

The highest registered url domain, stripped of the subdomain. For example, the registered domain for "foo.example.com" is "example.com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last two labels will not work well for TLDs such as "co.uk".

type: keyword

example: example.com

url.scheme

Scheme of the request, such as "https". Note: The : is not part of the scheme.

type: keyword

example: https

url.subdomain

The subdomain portion of a fully qualified domain name includes all of the names except the host name under the registered_domain. In a partially qualified domain, or if the the qualification level of the full name cannot be determined, subdomain contains all of the names below the registered domain. For example the subdomain portion of "www.east.mydomain.co.uk" is "east". If the domain has multiple levels of subdomain, such as "sub2.sub1.example.com", the subdomain field should contain "sub2.sub1", with no trailing period.

type: keyword

example: east

url.top_level_domain

The effective top level domain (eTLD), also known as the domain suffix, is the last part of the domain name. For example, the top level domain for example.com is "com". This value can be determined precisely with a list like the public suffix list (http://publicsuffix.org). Trying to approximate this by simply taking the last label will not work well for effective TLDs such as "co.uk".

type: keyword

example: co.uk

url.username

Username of the request.

type: keyword

user

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The user fields describe information about the user that is relevant to the event. Fields can have one entry or multiple entries. If a user has more than one id, provide an array that includes all of them.

user.changes.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

user.changes.email

User email address.

type: keyword

user.changes.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

user.changes.full_name.text

type: text

user.changes.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

user.changes.group.id

Unique identifier for the group on the system/platform.

type: keyword

user.changes.group.name

Name of the group.

type: keyword

user.changes.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

user.changes.id

Unique identifier of the user.

type: keyword

user.changes.name

Short name or login of the user.

type: keyword

example: albert

user.changes.name.text

type: text

user.changes.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

user.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

user.effective.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

user.effective.email

User email address.

type: keyword

user.effective.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

user.effective.full_name.text

type: text

user.effective.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

user.effective.group.id

Unique identifier for the group on the system/platform.

type: keyword

user.effective.group.name

Name of the group.

type: keyword

user.effective.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

user.effective.id

Unique identifier of the user.

type: keyword

user.effective.name

Short name or login of the user.

type: keyword

example: albert

user.effective.name.text

type: text

user.effective.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

user.email

User email address.

type: keyword

user.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

user.full_name.text

type: text

user.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

user.group.id

Unique identifier for the group on the system/platform.

type: keyword

user.group.name

Name of the group.

type: keyword

user.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

user.id

Unique identifier of the user.

type: keyword

user.name

Short name or login of the user.

type: keyword

example: albert

user.name.text

type: text

user.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

user.target.domain

Name of the directory the user is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

user.target.email

User email address.

type: keyword

user.target.full_name

User’s full name, if available.

type: keyword

example: Albert Einstein

user.target.full_name.text

type: text

user.target.group.domain

Name of the directory the group is a member of. For example, an LDAP or Active Directory domain name.

type: keyword

user.target.group.id

Unique identifier for the group on the system/platform.

type: keyword

user.target.group.name

Name of the group.

type: keyword

user.target.hash

Unique user hash to correlate information for a user in anonymized form. Useful if user.id or user.name contain confidential information and cannot be used.

type: keyword

user.target.id

Unique identifier of the user.

type: keyword

user.target.name

Short name or login of the user.

type: keyword

example: albert

user.target.name.text

type: text

user.target.roles

Array of user roles at the time of the event.

type: keyword

example: ["kibana_admin", "reporting_user"]

user_agent

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The user_agent fields normally come from a browser request. They often show up in web service logs coming from the parsed user agent string.

user_agent.device.name

Name of the device.

type: keyword

example: iPhone

user_agent.name

Name of the user agent.

type: keyword

example: Safari

user_agent.original

Unparsed user_agent string.

type: keyword

example: Mozilla/5.0 (iPhone; CPU iPhone OS 12_1 like Mac OS X) AppleWebKit/605.1.15 (KHTML, like Gecko) Version/12.0 Mobile/15E148 Safari/604.1

user_agent.original.text

type: text

user_agent.os.family

OS family (such as redhat, debian, freebsd, windows).

type: keyword

example: debian

user_agent.os.full

Operating system name, including the version or code name.

type: keyword

example: Mac OS Mojave

user_agent.os.full.text

type: text

user_agent.os.kernel

Operating system kernel version as a raw string.

type: keyword

example: 4.4.0-112-generic

user_agent.os.name

Operating system name, without the version.

type: keyword

example: Mac OS X

user_agent.os.name.text

type: text

user_agent.os.platform

Operating system platform (such centos, ubuntu, windows).

type: keyword

example: darwin

user_agent.os.type

Use the os.type field to categorize the operating system into one of the broad commercial families. One of these following values should be used (lowercase): linux, macos, unix, windows. If the OS you’re dealing with is not in the list, the field should not be populated. Please let us know by opening an issue with ECS, to propose its addition.

type: keyword

example: macos

user_agent.os.version

Operating system version as a raw string.

type: keyword

example: 10.14.1

user_agent.version

Version of the user agent.

type: keyword

example: 12.0

vlan

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The VLAN fields are used to identify 802.1q tag(s) of a packet, as well as ingress and egress VLAN associations of an observer in relation to a specific packet or connection. Network.vlan fields are used to record a single VLAN tag, or the outer tag in the case of q-in-q encapsulations, for a packet or connection as observed, typically provided by a network sensor (e.g. Zeek, Wireshark) passively reporting on traffic. Network.inner VLAN fields are used to report inner q-in-q 802.1q tags (multiple 802.1q encapsulations) as observed, typically provided by a network sensor (e.g. Zeek, Wireshark) passively reporting on traffic. Network.inner VLAN fields should only be used in addition to network.vlan fields to indicate q-in-q tagging. Observer.ingress and observer.egress VLAN values are used to record observer specific information when observer events contain discrete ingress and egress VLAN information, typically provided by firewalls, routers, or load balancers.

vlan.id

VLAN ID as reported by the observer.

type: keyword

example: 10

vlan.name

Optional VLAN name as reported by the observer.

type: keyword

example: outside

vulnerability

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The vulnerability fields describe information about a vulnerability that is relevant to an event.

vulnerability.category

The type of system or architecture that the vulnerability affects. These may be platform-specific (for example, Debian or SUSE) or general (for example, Database or Firewall). For example (Qualys vulnerability categories) This field must be an array.

type: keyword

example: ["Firewall"]

vulnerability.classification

The classification of the vulnerability scoring system. For example (https://www.first.org/cvss/)

type: keyword

example: CVSS

vulnerability.description

The description of the vulnerability that provides additional context of the vulnerability. For example (Common Vulnerabilities and Exposure CVE description)

type: keyword

example: In macOS before 2.12.6, there is a vulnerability in the RPC…​

vulnerability.description.text

type: text

vulnerability.enumeration

The type of identifier used for this vulnerability. For example (https://cve.mitre.org/about/)

type: keyword

example: CVE

vulnerability.id

The identification (ID) is the number portion of a vulnerability entry. It includes a unique identification number for the vulnerability. For example (Common Vulnerabilities and Exposure CVE ID

type: keyword

example: CVE-2019-00001

vulnerability.reference

A resource that provides additional information, context, and mitigations for the identified vulnerability.

type: keyword

example: https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2019-6111

vulnerability.report_id

The report or scan identification number.

type: keyword

example: 20191018.0001

vulnerability.scanner.vendor

The name of the vulnerability scanner vendor.

type: keyword

example: Tenable

vulnerability.score.base

Scores can range from 0.0 to 10.0, with 10.0 being the most severe. Base scores cover an assessment for exploitability metrics (attack vector, complexity, privileges, and user interaction), impact metrics (confidentiality, integrity, and availability), and scope. For example (https://www.first.org/cvss/specification-document)

type: float

example: 5.5

vulnerability.score.environmental

Scores can range from 0.0 to 10.0, with 10.0 being the most severe. Environmental scores cover an assessment for any modified Base metrics, confidentiality, integrity, and availability requirements. For example (https://www.first.org/cvss/specification-document)

type: float

example: 5.5

vulnerability.score.temporal

Scores can range from 0.0 to 10.0, with 10.0 being the most severe. Temporal scores cover an assessment for code maturity, remediation level, and confidence. For example (https://www.first.org/cvss/specification-document)

type: float

vulnerability.score.version

The National Vulnerability Database (NVD) provides qualitative severity rankings of "Low", "Medium", and "High" for CVSS v2.0 base score ranges in addition to the severity ratings for CVSS v3.0 as they are defined in the CVSS v3.0 specification. CVSS is owned and managed by FIRST.Org, Inc. (FIRST), a US-based non-profit organization, whose mission is to help computer security incident response teams across the world. For example (https://nvd.nist.gov/vuln-metrics/cvss)

type: keyword

example: 2.0

vulnerability.severity

The severity of the vulnerability can help with metrics and internal prioritization regarding remediation. For example (https://nvd.nist.gov/vuln-metrics/cvss)

type: keyword

example: Critical

x509

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This implements the common core fields for x509 certificates. This information is likely logged with TLS sessions, digital signatures found in executable binaries, S/MIME information in email bodies, or analysis of files on disk. When the certificate relates to a file, use the fields at file.x509. When hashes of the DER-encoded certificate are available, the hash data set should be populated as well (e.g. file.hash.sha256). Events that contain certificate information about network connections, should use the x509 fields under the relevant TLS fields: tls.server.x509 and/or tls.client.x509.

x509.alternative_names

List of subject alternative names (SAN). Name types vary by certificate authority and certificate type but commonly contain IP addresses, DNS names (and wildcards), and email addresses.

type: keyword

example: *.elastic.co

x509.issuer.common_name

List of common name (CN) of issuing certificate authority.

type: keyword

example: Example SHA2 High Assurance Server CA

x509.issuer.country

List of country © codes

type: keyword

example: US

x509.issuer.distinguished_name

Distinguished name (DN) of issuing certificate authority.

type: keyword

example: C=US, O=Example Inc, OU=www.example.com, CN=Example SHA2 High Assurance Server CA

x509.issuer.locality

List of locality names (L)

type: keyword

example: Mountain View

x509.issuer.organization

List of organizations (O) of issuing certificate authority.

type: keyword

example: Example Inc

x509.issuer.organizational_unit

List of organizational units (OU) of issuing certificate authority.

type: keyword

example: www.example.com

x509.issuer.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

x509.not_after

Time at which the certificate is no longer considered valid.

type: date

example: 2020-07-16 03:15:39+00:00

x509.not_before

Time at which the certificate is first considered valid.

type: date

example: 2019-08-16 01:40:25+00:00

x509.public_key_algorithm

Algorithm used to generate the public key.

type: keyword

example: RSA

x509.public_key_curve

The curve used by the elliptic curve public key algorithm. This is algorithm specific.

type: keyword

example: nistp521

x509.public_key_exponent

Exponent used to derive the public key. This is algorithm specific.

type: long

example: 65537

Field is not indexed.

x509.public_key_size

The size of the public key space in bits.

type: long

example: 2048

x509.serial_number

Unique serial number issued by the certificate authority. For consistency, if this value is alphanumeric, it should be formatted without colons and uppercase characters.

type: keyword

example: 55FBB9C7DEBF09809D12CCAA

x509.signature_algorithm

Identifier for certificate signature algorithm. We recommend using names found in Go Lang Crypto library. See https://github.com/golang/go/blob/go1.14/src/crypto/x509/x509.go#L337-L353.

type: keyword

example: SHA256-RSA

x509.subject.common_name

List of common names (CN) of subject.

type: keyword

example: shared.global.example.net

x509.subject.country

List of country © code

type: keyword

example: US

x509.subject.distinguished_name

Distinguished name (DN) of the certificate subject entity.

type: keyword

example: C=US, ST=California, L=San Francisco, O=Example, Inc., CN=shared.global.example.net

x509.subject.locality

List of locality names (L)

type: keyword

example: San Francisco

x509.subject.organization

List of organizations (O) of subject.

type: keyword

example: Example, Inc.

x509.subject.organizational_unit

List of organizational units (OU) of subject.

type: keyword

x509.subject.state_or_province

List of state or province names (ST, S, or P)

type: keyword

example: California

x509.version_number

Version of x509 format.

type: keyword

example: 3