docker-rsyslog

An rsyslog container intended to transfer syslog input into kafka with a JSON format (because rsyslog is more mature, performant and production tested compared to logstash syslog inputs).

Differentiation from official rsyslog container images

Why not the official image?

This project was started in 2017. About a year later, an upstream official rsyslog impages project started which will likely be better maintained and hopefully cover similar use cases. However, at the time of the last update to this readme (June 2021):

• rsyslog/syslog_appliance_alpine states: "Note: currently this is in BETA state".
• Using Rsyslog Docker Containers still has the development warning notice.
• github: rsyslog / rsyslog-docker warns "a playground for rsyslog docker tasks - nothing production yet".
• The alpine: add kafka module issue was still open.
• rsyslog.conf.d only provided limited bundled config use-cases such as logging to file or a cloud logging provider (sematext), but not Kafka.

Besides the "beta" status, other differences compared to the official container are:

• A focus on kafka output functionality.
• An attempt to adopt and overlay some Twelve-Factor concepts, most notably, the suggestion to Store config in the environment by using confd.
  • Newly introduced (since v8.33) rsyslog container friendly features such as backticks that can echo evn var values as string constants along with the config.enabled parameter for configuration objects would also likely suffice, but confd supports more backends than just env vars.
• A larger number of pre-defined use-cases split into respective rulesets and queues.

Features

rsyslog is fast, highly adaptable, but notoriously difficult to configure via config files. This image tries to pre-package some common use-cases that can be controlled via setting env vars. The objective is to avoid needing to supply configuration in rainerscript or legacy config syntaxes.

Some basic performance testing was done to adapt and override conservative defaults so that this container can function in the role of a central syslog service. Choices made in the default config were based on rough and ready benchmark suite hacked together at benchmark-syslog.

However, for complex and flexible use-cases, it may be preferable to bind mount/supply a configuration file and directory instead of using the config templated via confd.

Inputs

Accept multiple syslog inputs:

• Handle formats (RFC3164 and RFC5424).
  • Also accept structured logs (with @cee tag to indicate JSON payload).
  • Deal with syslog output forwarded from some quirky non-standard systems like AIX.
• Accept multiple syslog transports (UDP, TCP or RELP).
• Accept multiple security options (TLS or not).
• Optionally append useful metadata with rsyslog_support_metadata_formats=on to add context about how a message was received.

The table below lists pre-configured inputs:

Outputs

Some built-in use cases, e.g.:

• Split and output files to a volume.
• Produce JSON to a Kafka topic.
• Relay syslog RFC3164 or RFC5424 formats to other syslog servers (e.g. a SIEM product).
  • If need be, spoof the original UDP source because SIEM vendor products like IBM QRadar assume the log source is sending directly (not relayed) and set log source identities using network packet headers instead of the syslog header (insert profanity of choice here...).
• Send JSON over TCP (e.g. to logstash).

Formats

Legacy formats/templates can easily be set via pre-defined rsyslog template names (i.e. rsyslog_TraditionalForwardFormat or rsyslog_TraditionalFileFormat). However several additional output templates can be set per output:

• RFC5424:
  • TmplRFC5424 (same as rsyslog_SyslogProtocol23Format).
  • TmplRFC5424Meta which appends a extra structured data element fields with more info about how the message was received in a syslog-relay structured element.
• JSON output templates:
  • TmplRSyslogJSON is the full native rsyslog message object (might duplicate fields, but also useful to debug with).
  • TmplJSON is a JSON output option for a subset of common syslog fields and the parsed msg portion (the message after the syslog header pieces)
  • TmplJSONRawMsg includes the full raw message including original syslog headers - potentially useful as provenance / evidence on exactly how the message was transferred from a source
  • Optionally convert structured data in RFC5424 into a nested JSON object (or null if not present) with rsyslog_mmpstrucdata=on.
  • Optionally parse JSON message payloads with rsyslog_mmjsonparse=on (as a default, usually preceded by @cee cookie).
    • Use rsyslog_mmjsonparse_without_cee=on to try parse messages as JSON without the cookie.
• A raw template RawMsg can be useful to bypass most rsyslog parsing and simply relay that data as is.
  • One might also then skip parsing with parser="rsyslog.pmnull" for a given ruleset.
  • Note that some network devices and Solaris don't provide syslog header names so the original log source identity can end up being lost).
• An extended raw message template RawMsgEndMeta can append metadata to the end of the message.
  • This might help in cases where you relay syslog events to a SIEM that has parsers which expect the original log source format but might tolerate adding the metadata at the end.
  • A shorter version, rawMsgEndMetaShort, includes just the fromhost and fromhost-ip properties to limit the amount of metadata tagged on the end, and is especially suited to UDP forwarding where the MTU might be limited to ~1500 bytes or less.
• Allow logging rule-set extension via volume mounts with user provided configuration files (e.g. for custom filters and outputs)

See the ENV instructions with rsyslog_ environment name prefixes in the Dockerfile to review default settings and options further.

The container also supports advanced debug scenarios.

Usage

TL;DR

YOLO

The 'yolo' way:

docker container run --rm -it --name syslog jpvriel/rsyslog:latest

NB!:

• NOT for production! (volumes left dangling between container runs, data loss likely, and client problems validating self-signed certs)
• Default self-signed cert's private key isn't private, it's PUBLIC, since it's checked into the code repo for testing purposes.
• Without SYS_NICE capability and the host usernamespace, rsyslogd will lack permission to set UDP threading schedular priority with the pthread_setschedparam() system call.

TZ should be set

NB!: when rsyslog starts, TZ should be set so it can efficiently deal with log source timestamps that lack timezone info (RFC3164).

• The timezone within docker container is UTC, even if your host has this set otherwise.
• Newer versions of rsyslog check if TZ is set within a container. See rsyslog assumes UTC if TZ env var is not set and misses using the actual system's localtime is closed as of v8.33.

SYS_NICE capability and the host usernamespace are required for rsyslogd to set UDP input scheduling priority

Note, the SYS_NICE capability is needed to set a FIFO IO priority for the UDP input threads. In addition, if docker is setup with userns-remap enabled, then it's also necessary to add --userns host, otherwise the following warning occurs:

rsyslogd: imudp: pthread_setschedparam() failed - ignoring: Operation not permitted

It's possible to ingore the above error message and run rsyslogd with docker user namespace remapping in place. The rsyslogd container's UDP input should still be functional, as well as more secure, but the performance implications and required container networking fine tuning needed has not been investigated to determine the full performance and UDP reliability impact.

Minimally sane

Create named volumes beforehand:

docker volume create syslog_log
docker volume create syslog_work
docker volume create syslog_tls

Provide 3 files for TLS setup placed in the syslog_tls and mounted as a volume at /etc/pki/rsyslog:

• a key.pem,
• a signed certificate, cert.pem, and
• your own trusted CA, e.g. ca.pem

(file names can be modified via ENV vars at runtime if need be)

Run docker mounting volumes and ensuring TZ is set/passed

docker container run --rm -it \
 --userns host \
 --cap-add sys_nice \
 -v syslog_log:/var/log/remote \
 -v syslog_work:/var/lib/rsyslog \
 -v syslog_tls:/etc/pki/rsyslog \
 -e TZ='Africa/Johannesburg' \
 --name syslog jpvriel/rsyslog:latest

Omit --userns host and --cap-add SYS_NICE if you prefer the security benifits of docker usernamespace remapping, which will imply rsyslogd runs with default UDP thread priority scheduling instead of being able to set it.

docker-compose

The usual docker-compose up.

Version dependency on compose file format v2.2 and docker engine >= 1.13.0.

Note:

• Assumes TZ is set and passes this along (see above).
• Assumes or creates named volumes (syslog_log, syslog_metrics, syslog_work, syslog_tls).
• The syslog_metrics volume will only be used if rsyslog_impstats_log_file_enabled env var is set to on.
• Again, the host usernamespace and SYS_NICE capability are set to allow control of UDP input scheduling priority, but can be commented out.

The volume name is forced (doesn't use the directory prefix). E.g. if run from a directory docker-rsyslog, then:

$ docker container inspect -f "{{range .Mounts}}{{.Destination}} = {{.Source}}{{println}}{{end}}" dockerrsyslog_syslog_1
/var/log/remote = /var/lib/docker/volumes/syslog_log/_data
/var/lib/rsyslog = /var/lib/docker/volumes/syslog_work/_data
/etc/pki/rsyslog = /var/lib/docker/volumes/syslog_tls/_data

Signal handling and clean exit

As per man rsyslogd, the daemon process responds to various signals. The entrypoint.sh entry-point script has handlers to pass these along provided the container is stopped as follows:

docker container stop -t 300 syslog

Notice the example has 300 seconds (5 minutes grace) to allow rsyslog to stop gracefully.

If you DON'T see INFO: rsyslog stopped normally, then you know the container was stopped or got killed prematurely. The docker stop command first sends a TERM signal, but the default is to only wait 10 seconds and then KILL. rsyslog may need more time to sync data to disk or forward output. Therefore, tune the --time option for the stop command.

Stopping the container should allow the entry point script to execute kill -SIGTERM $(cat /var/run/rsyslogd.pid) so that rsyslog closes files and stops cleanly.

If you see ERROR: Ungraceful exit..., then most likely, the rsyslogd process died/aborted somehow.

Environment variables

test/test_syslog_server.env as an example will provide ideas on some env vars you can set.

Reading the ENV rsyslog_* optons in the Dockerfile will provide a more exhaustive list about what rsyslog configuration options are supported via environment variables.

How env vars get applied

The variable naming convention is roughly:

rsyslog_<module>_<settingSection>_<camelCaseSetting>

Excuse the mix of snake_case and camelCase. To understand how it applies, a quick example is rsyslog_module_imtcp_streamDriver_authMode which sets the option streamDriver.authMode in the imtcp module and golang text templates via confd get applied:

module(
  load="imtcp"
  maxSessions="{{ getenv "rsyslog_module_imtcp_maxSessions" }}"
  streamDriver.name="gtls"
  streamDriver.mode="1"
    #This indicates TLS is enabled. 0 indicated disabled.
  streamDriver.authMode="{{ getenv "rsyslog_module_imtcp_streamDriver_authMode" }}"
  {{ if getenv "rsyslog_module_imtcp_streamDriver_authMode" | ne "anon" }}
  permittedPeer={{ getenv "rsyslog_tls_permittedPeer" }}
  {{ end }}
)

See Are there naming conventions for variables in shell scripts?

• snake_case works better for environment variables not set by the operating system.
• CamelCase helps understand which rsyslog settings map into config when possible.

Some options are used to add or remove entire blocks of config, e.g. rsyslog_omkafka_enabled='off' will cause the entire omkafka block of rsyslog config to not be generated.

Other options are shared, e.g.

• rsyslog_tls_permittedPeer is provided to both the TCP TLS and RELP TLS input modules
• rsyslog_om_action_queue_maxDiskSpace is shared for all output action queues.

Limited config via env vars

rsyslog is a traditional UNIX-like application not written with micro-services and container architecture in mind. It has many complex configuration options and syntax not easily managed as environment variables or command switches.

Only a few common configuration scenarios are catered for as environment variables. See 'Optional config file volumes' to handle more complex cases.

docker-compose env_file gotchas

NB!: Watch out for rsyslog configuration with arrays and docker's env_file handling.

If the array is quoted as an environment variable, e.g. a='["o1","o2"]', the docker passes along the environment variable with the literal quotes included (i.e. '["o1","o2"]' and not ["o1","o2"]). The rsyslog configuration then fails to interpret the value as an array.

• rsyslog rainerscript has array objects, e.g, ["o1", "o2"], where [ signifies the start of an array object.
• For rsyslog, '["o1", "o2"]' will be read by rainerscript as a string instead of an array.
• Using an .env file with square just brackets and unquoted seems to pass the array into rsyslog rainerscript without mangling it (via confd and golang text templates used in the background).
• For bash, [ are ] are special pattern character and export a=["o1","o2"]; echo $a results in [o1,o2] as output. Python also seems to end up interpreting the environment variables in this way.
• Docker / docker-compose has the nasty unexpected behaviour that quotes in the supplied .env file are not interpolated, but instead literally included! This breaks rsyslog config because env_var='value' in the .env file gets injected as setting="'value'" into rsyslog config instead of the expected setting="value".

See:

• Inconsistent env var parsing from docker-compose.yml
• strange interpretation/parsing of .env file

More details about some env vars to setup the container at runtime are discussed in the "Optional Output Modules" section.

Volumes and file mounts

The container will use the following for rsyslog's "working" directory and is needed to recreate a container without losing data from previous runs:

rsyslog TLS X509 certificate and private key

The container expects the following in order to use TLS/SSL:

• /etc/pki/rsyslog/cert.pem
• /etc/pki/rsyslog/key.pem

If not provided with valid files in those volumes, a default signed cert is used, but this will obviously work poorly for clients validating the server cert. It's only for testing.

• /var/lib/rsyslog

rsyslog output files

If enabling and using file output, a named volume is recommended for /var/log/remote. E.g, on my docker setup, the files get written out the hosts named docker volume storage at /var/lib/docker/volumes/syslog_log/_data/<hostname>. Instead of logging all events to a single file, this can be split further into <hostname>/<filename based on facility or message content>:

The default traditional file output template applied is, but it can be modified to something better like rsyslog_SyslogProtocol23Format (RFC5424) or any other built-in rsyslog templates via the rsyslog_omfile_template env var.

Optional config files

For more advanced custom configuration, template config via env vars would be too tedious (given RainerScript and rsyslog options are so vast), so dedicated configuration file volumes can be used instead for custom filering or output in the folling sub-directories:

• /etc/rsyslog.d/input/filters
• /etc/rsyslog.d/output/filters
• /etc/rsyslog.d/output/extra

Placing a *.conf in the input/filters or output/filters sub-directory is included and applied globally to either (to all of) the inputs or outputs. Per-input, or per-output filters can also be included in additional sub-directories named the same as the respective ruleset. E.g.:

• /etc/rsyslog.d/input/filters/remote_in_udp/*.conf will only apply to the remote_in_udp ruleset.
• /etc/rsyslog.d/output/filters/fwd_syslog/*.conf will only apply to the fwd_syslog ruleset.

When including filters, the filters need to make use of conditional expressions to match and then discard the unwanted message with the stop keyword.

Example of a simple black-list (exclude) approach:

if $fromhost-ip == '192.168.0.1' then { stop }

Example of a white-list approach:

if (
  $syslogfacility == '4' or
  $syslogfacility == '10' or
  $syslogfacility == '13' or
  $syslogfacility == '14'
) then { continue } else { stop }

Including extra outputs is Experimental (not tested)

Additional outputs

Pre-defined support for some common forwarding use cases:

• Kafka: rsyslog_omkafka_enabled=on and other options to be set.
  • JSON output, but template can be changed
• syslog forwarding / relay: rsyslog_omfwd_syslog_enabled=on and other options to be set.
  • RFC5424 output, but template can be changed
• JSON forwarding / relay over TCP: rsyslog_omfwd_json_enabled=on and other options to be set.
  • Useful for sending directly to logstash (no need for kafka)

And obviously, file output can be disabled with rsyslog_omfile_enabled=off.

Actual potential storage use for output action queues is affected by the shared setting rsyslog_om_action_queue_maxDiskSpace(in bytes):

$$ < maxDiskSpace > * < outputs > $$

Kafka output

The Kafka output wraps the key config items for omkafka so refer to rsyslog's documentation and look out for rsyslog_omkafka related ENV instructions in the Dockerfile to get a sense of options that can be set.

In terms of kafka security, only the SASL/PLAIN with the SASL_SSL security protocol has been tested. In theory, SASL with Kerberos might be possible, but requires the rsyslog container to have keytab files mounted, etc.

Extra input and/or output

Beta: partially tested

If an input or forwarding use case isn't covered as above, then:

1. Use /etc/rsyslog.d/extra/ with your own config files
2. Add your own inputs and, if desired, intergrate them with pre-existing filters and output rulesets.
   1. Incorporate $IncludeConfig /etc/rsyslog.d/input/filters/*.conf into your own input processing ruleset to apply "global" input filters.
   2. Set your input module to use ruleset="central", or if you first need to do your own custom adaptation (e.g. filters and enrichment) the use call central in your own own input processing ruleset. This approach will retain the pre-bundled outputs and output filters.
3. Add your own outputs if desired. You can intergrate them with pre-existing inputs, input filters and global output filters, via the rsyslog_call_fwd_extra_rule option:
   1. Set evn var rsyslog_call_fwd_extra_rule=true which enables call fwd_extra at the end of the master output ruleset grouping.
   2. If you enable the env var, but fail to define a ruleset called fwd_extra in your extra config, the rsyslog config will become invalid.

More detail?

• See test/etc/rsyslog.d/extra/91_extra_test.conf for examples of adding custom extra config.
• See 50-ruleset.conf template to understand more details about the pre-bundled rulesets that handle inputs and outpus.

E.g. to have a standalone setup that goes from some kafka input to a mongodb output without touching or being touched by the other "pre-canned" rulesets:

/etc/rsyslog.d/extra/99_extra.conf

module(load="imkafka")
module(load="ommongodb")

input(
  type="imkafka"
  topic="mytopic"
  broker=["host1:9092","host2:9092","host3:9092"]
  consumergroup="default"
  ruleset="extra"
)

ruleset(name="extra" parser="rsyslog.rfc3164") {
  action(
    server="mymonddb"
    serverport=27017
    ...
  )
}

E.g. to create an extra input and plug it into the pre-canned output, use call central within your own input ruleset to call the standard output (implies global output filters apply):

/etc/rsyslog.d/extra/49_input_extra.conf

module(load="imkafka")
input(
  type="imkafka"
  topic="mytopic"
  broker=["host1:9092","host2:9092","host3:9092"]
  consumergroup="default"
  ruleset="kafka_in_extra_topic"
)

# apply global input filters
ruleset(name="kafka_in_extra_topic" parser="rsyslog.rfc3164") {
  $IncludeConfig /etc/rsyslog.d/input/filters/*.conf
  call central
}

E.g. to create an extra output which intergates with the "pre-canned" pipeline that will already call fwd_extra at the end of the normal output ruleset (implies global output filters apply):

/etc/rsyslog.d/extra/89_fwd_extra.conf

module(load="ommongodb")
ruleset(name="fwd_extra")
{
  action(
    server="mymonddb"
    serverport=27017
    ...
  )
}

Template examples

For each pre-canned output, a template can be set. Some advanced templates have flags to enable/include them (i.e. grep -E 'rsyslog_.*__template' Dockerfile to get an idea of the options).

By default rsyslog_support_metadata_formats and rsyslog_mmpstrucdata options are off. They can help add meta-data and make structured data elements parsable as JSON. For JSON output, recommended combinations are:

• TmplJSON and rsyslog_support_metadata_formats=off, or
• TmplJSONRawMsg or TmplRFC5424Meta require rsyslog_support_metadata_formats=on, otherwise these templates won't work.

The table shows compatible template and options.

rsyslog_support_metadata_formats is also needed add logic that builds in some extra validation steps in order to output the meta-data with more accurate information about the origin of the message. rsyslog readily parses almost any valid text as a hostname with RFC3164, even when the message looks like it's ignoring the conventions and it's unlikely a valid hostname - as per this issue: pmrfc3164 blindly swallows the first word of an invalid syslog header as the hostname.

Refer to etc/confd/templates/60-output_format.conf.tmpl and https://github.com/JPvRiel/docker-rsyslog/blob/master/README_related.md#rsyslog-meta-data for more details and motivation behind this feature.

The following template output examples are based on enabling these extra features:

rsyslog_support_metadata_formats=on
rsyslog_mmpstrucdata=on

TmplRFC5424Meta

Meta-data about message origin pre-pended to the structured data element list:

<14>1 2017-09-19T23:43:29+00:00 behave test - - [syslog-relay@16543 timegenerated="2017-10-24T00:43:55.323108+00:00" fromhost="dockerrsyslog_sut_run_1.dockerrsyslog_default" fromhost-ip="172.18.0.9" myhostname="test_syslog_server" inputname="imptcp" format="RFC5424" pri-valid="true" header-valid="true" tls="false" authenticated-client="false"][test@16543 key1="value1" key2="value2"] Well formed RFC5424 with structured data

TmplJSON

Message missing structured data (e.g. null - or RFC3164 message) with more minimal output. Takes hostname from rsyslog parser without any sanity checks.

{
  "syslogfacility": 1,
  "syslogfacility-text": "user",
  "syslogseverity": 6,
  "syslogseverity-text": "info",
  "timestamp": "2017-09-19T23:43:29+00:00",
  "hostname": "behave",
  "app-name": "test",
  "procid": "99999",
  "msgid": "-",
  "structured-data": null,
  "msg": "Well formed RFC5424 with PID and no structured data"
}

TmplJSONRawMsg

Message with RFC5424 structured data and custom meta-data about message origin. Some basic sanity checks performed to avoid outputting bogus hostnames from malformed RFC3164 messages. structured-data is converted to a JSON object.

{
  "syslogfacility": 1,
  "syslogfacility-text": "user",
  "syslogseverity": 6,
  "syslogseverity-text": "info",
  "timestamp": "2017-09-19T23:43:29+00:00",
  "hostname": "behave",
  "app-name": "test",
  "procid": "-",
  "msgid": "-",
  "structured-data": {
    "test@16543": {
      "key1": "value1",
      "key2": "value2"
    }
  },
  "rawmsg": "<14>1 2017-09-19T23:43:29+00:00 behave test - - [test@16543 key1=\"value1\" key2=\"value2\"] Well formed RFC5424 with structured data",
  "syslog-relay": {
    "timegenerated": "2017-10-24T00:00:10.561635+00:00",
    "fromhost": "dockerrsyslog_sut_run_1.dockerrsyslog_default",
    "fromhost-ip": "172.18.0.9",
    "myhostname": "test_syslog_server",
    "inputname": "imptcp",
    "format": "RFC5424",
    "pri-valid": true,
    "header-valid": true,
    "tls": false,
    "authenticated-client": false
  }
}

TmplRSyslogJSON

Message with RFC5424 structured data and using the native rsyslog %jsonmesg% output

{
  "msg": "Well formed RFC5424 with structured data",
  "rawmsg": "<14>1 2017-09-19T23:43:29+00:00 behave test - - [test@16543 key1=\"value1\" key2=\"value2\"] Well formed RFC5424 with structured data",
  "timereported": "2017-09-19T23:43:29+00:00",
  "hostname": "behave",
  "syslogtag": "test",
  "inputname": "imptcp",
  "fromhost": "gateway",
  "fromhost-ip": "172.17.0.1",
  "pri": "14",
  "syslogfacility": "1",
  "syslogseverity": "6",
  "timegenerated": "2017-10-23T22:50:12.997829+00:00",
  "programname": "test",
  "protocol-version": "1",
  "structured-data": "[test@16543 key1=\"value1\" key2=\"value2\"]",
  "app-name": "test",
  "procid": "-",
  "msgid": "-",
  "uuid": null,
  "$!": {
    "rfc5424-sd": {
      "test@16543": {
        "key1": "value1",
        "key2": "value2"
      }
    }
  }
}

rsyslog processing stats (impstats)

Output stats are enabled by default, but can be disabled via rsyslog_impstats and rsyslog_dyn_stats:

• rsyslog_impstats enables the module for general input, ruleset and output action stats
• rsyslog_dyn_stats depends on impstats and adds extra stat aggregates per host with the follwing stat names:
  • msg_per_fromhost_<input ruleset_name>_pre_filter: messages per source per input ruleset - what was received. Use this to compare what a source sent vs what was received.
  • msg_per_fromhost: messages per source processed in the main output ruleset - what was handled between input after input filters, but before output actions and output filters.
  • msg_per_fromhost_<output_ruleset_name>_post_filter: messages per source per output ruleset - what was eventually sent. Use this to compare what rsyslog relayed/forwarded vs what the external system received.

This is what the dynamic stat looks like when output as JSON:

{
  "name": "msg_per_fromhost",
  "origin": "dynstats.bucket",
  "values": {
    "docker-rsyslog_test_syslog_client_centos7_1.docker-rsyslog_default": 3,
    "docker-rsyslog_test_syslog_client_ubuntu1804_1.docker-rsyslog_default": 3,
    "docker-rsyslog_sut_run_1.docker-rsyslog_default": 39
  }
}

$fromhost vs $hostname:

• $fromhost syslog property can be more reliable than $hostname property when dealing with syslog clients that don't follow RFC syslog formats which can cause the client provided hostname to be missing or not correctly interpreted.
• $fromhost can evaluate to either the FQDN of the source host or an IP if no DNS reverse lookup is available.

Due to syslog impstats being sent via the syslog engine itself, the $rawmsg property lacks the standard syslogheaders, if rsyslog_support_metadata_formats=on, then "format": "NA_internal_rsyslogd-pstats" is and "pri-valid": false and header-valid": false are set because there is no RFC spec header to inspect ude to it being internal to the syslog engine.

As per Tutorial: Sending impstats Metrics to Elasticsearch Using Rulesets and Queues, it can be useful to track how many messages rsyslog processes. Also:

• details of impstats module fields made in elasticsearch helps ask for clarification about various stats produced.
• rsyslog statistic counter details some meaning for stats and which modules support stats.
• omkafka supports impstats since version 8.35.

By default, in Dockerfile, various stats env vars set the following:

• rsyslog_module_impstats_interval='60' causes stats to be produced ever minute
• rsyslog_module_impstats_resetCounters='on' resets many counters, but at the cost of some accuracy (see doc for impstats)
• rsyslog_module_impstats_format='cee' is the format set (instead of the legacy key value pair format used)
• rsyslog_impstats_ruleset='syslog_stats' sets the ruleset to send the stats output to, whereby stats are sent via normal syslog and the call to output will cause stats to be output/forwarded to all configured output modules. This can be changed to a single select 'pre-bundled' output ruleset if it was already enabled (e.g. out_file, fwd_kafka, fwd_syslog or fwd_json), or otherwise, a custom independent output can be defined via the extra config mechanism.

More reliable stats processing

Even with the attempt to split and run impstats in it's own queue, it might be more reliable to configure impstats to log to a file in a volume:

• By setting rsyslog_impstats_log_file_enabled=on, stats events will be logged at /var/log/impstats/metrics.log.
  • See the Dockerfile if you prefer modifying the destination and volume for this.
• In theory, it should be more reliable to avoid the syslog engine and simply log to file.
• There are more sophisticated options such as Monitoring rsyslog’s Performance with impstats and Elasticsearch, which can directly indexes events from it's own ruleset.
  • But this also relies on the internal syslog engine and omelasticsearch output for delivery, so it may be less failsafe compared to a local file.
• Arguably, a more failsafe, but convoluted process would be to log rsyslog stats into the file, then use filebeat with a bit of parsing from logstash to index the data into elastic, which decouples the dependany on the syslog engine and can better tolerate downtime or network issues communicating with elasticsearch.

Log file rotation

By default, to provide simpler abstaction, and avoid needing to run multiple container services in unision, this container breaks "best-practice" an will run a log rotation process if any of the file-based logging or metric output is enabled.

When log files are produced into volumes with the destination /var/log/remote or /var/log/impstat, either an external log rotate process is needed or logrotate_enabled should be set to 'on'. To rather manage this externally, explicitly set logrotate_enabled=off and externally rotate and signal the container to let it know rotation occurred, e.g. from within a bind mount on the host:

mv metrics.log metrics.log.1 && docker container kill --signal HUP rsyslog-stat-test

Logrotate in a container limitations

An internal failure for cron and logrotate will be mostly silent and provide no error feedback, save for a limited healthcheck script hack to at least check that the crond process is running and that there are no logrotate errors seen within /var/log/logrotate.err.log.

Indeed, secondary processes inside a container adds brittle complexity:

• While there is integrated log rotation within the container, running multiple processes within a container is arguably poor microservices practise.
• The entrypoint script prioritised looking after rsyslogd and waiting on rsyslogd to exit, and so it starts crond as a secondary process for lograte, but does not wait for nor provide error feedback if crond or logrotate has an issue.
• It's common practise to use stdout and stderr for container logs, and this container follows that, but redirecting remote syslog events or impstats metrics may flood the container logging mechanisms, and are different use-cases. Hence the need to rotate something even if /var/log/remote file output is disabled.
• It's unfortunate that older implimentations of cronie's crond only support reporting to either email or syslog, but not stdout, even when in forground mode.
  • So there is no neat way to know what is happending in a container where /dev/log usually doesn't exist.
  • A hack is to install and run a netcat unix syslog listener with the container at /dev/log, e.g. netcat -lkU /dev/log to test and see why crond may be having issues.

Version

The convention is <rsyslogd version>-<docker image release build number>.

E.g. 8.29.0-3 means the output of rsyslogd -v shows rsyslogd 8.29.0, and it's the 3rd image released for that upstream version.

Development complexity and technical debt (Here be Dragons)

This project suffers from a lot complexity due to trying to "containerise" applications with a design heritage from the classic unix area where none of the authors would have read Twelve-Factor:

• rsyslogd was forked from ksyslogd in 2003.
• logrotate requires cron, and cron was intially created in ~1975.

To quote a meme:

I don't always shave yaks, but whn I do, they trample all over me...

Besides building, running and paying attention to env var options in the Docker files, or suppling extra conf files, users of the container hopefully won't need to extend much outside of that and the complexity is abstracted away well enough...

Build

Makefile build

The Makefile depends on docker-compose being installed.

If your user has docker socket permissions, e.g.:

make build

Else if you don't live dangerously ;-), and need to elevate privilege, e.g.:

sudo -E make build

Where -E helps pass on http_proxy env vars, etc.

The build argument DISABLE_YUM_MIRROR=true can help if you have a caching proxy (e.g. squid) and don't want the mirror selection process in yum to break proxy caching. However, if default mirrors are down, then build fails.

Changes to build.env should invalidate the build cache. Docker build caching for a given version and release number.

Note however, that make build focuses on the Dockerfile for the rsyslog server and doesn't trigger rebuilds of other test container dependencies (such as python behave, kafka, etc)

To force a full rebuild using pull and no cache

sudo -E make rebuild

Manual build examples

The tagging convention followed is to match the rsyslog_VERSION to the version of rsyslogd the container is based on and add a release number thereafter. This is manually set to reflect the upstream stable RPM release. E.g. export rsyslog_VERSION=8.33.1

Build command example:

docker build -t jpvriel/rsyslog:${rsyslog_VERSION}-1 -t jpvriel/rsyslog:latest .

Building from behind a caching proxy (assuming proxy env vars are appropriately set) when you don't want yum mirror plug-ins to invalidate your proxy cache:

sudo -E docker build --build-arg DISABLE_YUM_MIRROR=true --build-arg http_proxy=$http_proxy --build-arg https_proxy=$https_proxy --build-arg no_proxy=$no_proxy -t jpvriel/rsyslog:${rsyslog_VERSION}-1 -t jpvriel/rsyslog:latest .

Pre-bundled X509 test certificate and private key

Note, a pre-bundled self-signed cert and ca is used for test purposes. It is expected in the following places:

• key: /usr/local/etc/pki/test/test_syslog_server.key.pem
• cert: /usr/local/etc/pki/test/test_syslog_server.cert.pem

The default certs are generated via ./util/certs.sh to work for the sut test suite.

To embed an internal/extra org CA, add more files to etc/pki/ca-trust/source/anchors and rebuild.

Embed own CA certs for TLS

Note, there is a runtime rsyslog_global_ca_file env var to set the CA for rsyslog.

However, should you need to embed a CA for other reasons (e.g. building via a corporate TLS intercepting proxy), you embed your own CA at build time by placing your own CA certificates in etc/pki/ca-trust/source/anchors.

Testing

Security considerations

Why root is required for the container when UDP spoof is enabled

While newer versions of docker allow building and running containers without root privileges, use of the omudpspoof output module requires root access on the host.

TODO: Clarify container security requirements for using omudpspoof which likely needs host user namespace, host network and root plus some capabilities like net admin? TODO: Validate if and how UDP spoof testing can work without host root (unlikely?) and/or create a build and test option that skips this feature to have an option to build without root.

Docker user namespace remapping

If user namespace re-mapping is done, as per Isolate containers with a user namespace, then some of the bind mounts run by the test suite may have access errors. To fix this, inspect grep dockremap /etc/sub{u,g}id to understand the id range mappings.

In a default dockremap scenario, the namespace is mapped to a subuid and subgid for the dockremap account. Using setfacl, assigne access to your own current user, and the chown the bind mount source dir with re-mapped docker root uid. E.g. for the test suit the test dir has to be owned by the remapped uid.

This is a fairly complex process, so see the docker-userns-remap-acls script as an example to help with this.

System under test (SUT)

Follows docker convention to use an sut service to test. Depends on several other containers like zookeeper and kafka images in order to test component intergeneration (e.g. omkafka).

Makefile test target

Similar to build, some prepared test invocations are defined in the make file.

As rsyslog rainerscript config mistakes are likely, a shorthand to simply first test config would be:

sudo -E make test_config

The standard full test suite includes checking config and doing more advanced system intergration testing (SIT) with kafka and other mock syslog relays:

sudo -E make test

If the test fails, make aborts and the test containers are not cleaned up which allows investigating the failure. If successful, the test environment is torn down. Also, make test_clean is run before testing to ensure a previous failed test run doesn't interfere.

To find a quick recap of which tests failed after lengthy and verbose python behave output, xmlint and highlight can process the JUnit test file output:

xmllint --xpath '//failure' test/behave/reports/TESTS-*.xml  | highlight --out-format=ansi --syntax xml

The default make test attempts to runs all tests continuing past failures to get full test results:

• stdout, stderr and logging output are captured by behave (not displayed on the console).
• Test results are output to ./test/behave/reports in JUnit format.
• The sut container exits once done.
• If there were no failures, all other containers (test dependencies) will also exit.
• With one or more errors the, the sut container will exit with a non-zero return code, but other test containers (syslog server, kafka, relays and clients) will be left in the running state.

To avoid removing / clearing the container and volumes after the sut container exists, use this alternative.

sudo -E make test_no_teardown

Then, even with no failures, the other containers and volumes should still exist for futher inspection.

Makefile targets for work-in-progress (WIP) testing and debugging

To have testing stop on the first failure and start the python debugger (Pdb) within the behave (sut) container:

sudo -E make test_debug_fail

When adding new features, only testing the feature tagged with @wip can be tested with:

sudo -E make test_wip

The test_wip also triggers the debugger upon a failed step.

Note:

• The above debug and WIP tests were set to use the plain behave output formatter due to Adding the --format plain flag in addition to --no-capture fixed the issue.
• No JUnit reporting is performed with the above tests and output / logging is not captured by behave.
• Simply use continue to step through debugging or use the exit() function to stop and the container will also exit.

Manual test invocation

The "system under test" suite was written with python behave.

To build just the sut service:

docker-compose -f docker-compose.test.yml build sut

Reminder, use --build-arg http_proxy etc if you have to do this via a proxy.

Run the full test suite to regression test:

docker-compose -f docker-compose.test.yml run sut

If you're extending, run just @wip pieces to focus on new features:

docker-compose -f docker-compose.test.yml run sut behave -w behave/features

To see interplay between other test container dependencies and the syslog server container:

docker-compose -f docker-compose.test.yml up

The above will have a lot of output... An alternative is to look at docker logs <service name>

Cleanup:

docker-compose -f docker-compose.test.yml down -v

NB!: failing to cleanup causes stale volumes and test components which search those volumes could operate off stale test values! Always clean between tests.

Building test dependencies

sudo -E make test should automatically pull and build everything needed via docker-compose.test.yml.

Test services can be built directly with sudo -E make build_test, or or force a full rebuild with sudo -E make rebuild_test.

As an example, the CentOS test client can be built in isolation:

docker-compose -f docker-compose.test.yml build --build-arg DISABLE_YUM_MIRROR=true --build-arg http_proxy --build-arg https_proxy --build-arg no_proxy test_syslog_client_centos7

There's also an ubuntu syslog test client, zookeeper, kafka and other images used to provide system testing.

Debug and additional validation steps

Configuration testing and validation

Configuration passing mistakes and issues are all too common with rsyslog.

An explicit check can be done by using -N1. And a special python script assembles and outputs the full rsyslog configuration if you use -E. For example:

docker container run --rm -it \
 -v syslog_log:/var/log/remote \
 -v syslog_work:/var/lib/rsyslog \
 -v syslog_tls:/etc/pki/rsyslog \
 -e rsyslog_omfile_enabled=true \
 --name syslog jpvriel/rsyslog:latest -E

-E is interpreted by entrypoint shell script.

To run python script within a running container, use:

docker container exec <name of running container> rsyslog_config_expand.py

Output will have ## comment tags to help highlight and show when $IncludeConfig directives are expanded to produce a flattened config output with line number prefixes:

12: $IncludeConfig /etc/rsyslog.d/*.conf
##< start of include directive: $IncludeConfig /etc/rsyslog.d/*.conf
##^ expanding file: /etc/rsyslog.d/30-globals.conf
 1: # Collect stats
 2: module(load="impstats" interval="60")
...
##> end of expand directive: $IncludeConfig /etc/rsyslog.d/*.conf

This helps track back to the exact line number of config that rsyslogd had a problem with, which is otherwise non-trivial due to the use of the confd and golang text template pre-processing needed to map environment variables into the config files.

Inspect configuration while testing

The sut (system under test) service will warn about invalid config, but hides the detailed error output. The full test suite should place files in test/config_check the will help with looking for config issues.

• rsyslog -N1 stdout/stderr output.
• Copy the config files after condf templating.
• Output of rsyslog_config_expand.py to show how config riles expanded.

Live manual checks can also be done.

To see rsyslogd config syntax check output, try:

docker-compose -f docker-compose.test.yml run test_syslog_server -N1

Similarly, to expand the config used for testing:

docker-compose -f docker-compose.test.yml run test_syslog_server rsyslog_config_expand.py

As noted before, to run a minimal test container that simply generates the output for test/config_check and doesn't run the full sut:

make test_config

Checking for file output

One basic ways to see if the rsyslog container works is to run it with file output enabled and written out to a named volume.

Assuming a suitable volume is created, e.g. docker volume create syslog_log, run the container with the volume and -e rsyslog_omfile_enabled=true.

docker container run --rm -it \
 -v syslog_log:/var/log/remote \
 -v syslog_work:/var/lib/rsyslog \
 -v syslog_tls:/etc/pki/rsyslog \
 -e rsyslog_omfile_enabled=true \
 --name syslog jpvriel/rsyslog:latest

Get the container IP, e.g:

docker inspect -f '{{range .NetworkSettings.Networks}}{{.IPAddress}}{{end}}' syslog
172.17.0.3

Use logger or an alternate program to send a test message, e.g. via UDP:

logger -d -n 172.17.0.3 'Test UDP message'

Check the output file:

sudo tail /var/lib/docker/volumes/syslog_log/_data/udp/5424/$(hostname)/messages | grep --color -E 'Test UDP message|$'

Advanced debugging

One may want to debug the entry point script entrypoint.sh, rsyslogd, or both.

rsyslog depends on a command line flag -d or the rsyslog_DEBUG environment variables being set in order to debug. See rsyslog Debug Support.

Enabling debug has performance implications and is probably NOT appropriate for production. Debug flags for rsyslogd does not affect entrypoint script debugging. To make the entrypoint script be verbose about shell commands run, use ENTRYPOINT_DEBUG=true.

docker container run --rm -it \
 -v syslog_log:/var/log/remote \
 -v syslog_work:/var/lib/rsyslog \
 -v syslog_tls:/etc/pki/rsyslog \
 --name syslog jpvriel/rsyslog:latest rsyslogd -d

Alternatively, to run with rsyslogd debug enabled but silent until signaled (via SIGUSR1), add -e rsyslog_DEBUG=DebugOnDemand.

To trigger debug output, send the container a signal (which entrypoint.sh entrypoint passes on to rsyslogd)

docker container kill --signal=SIGUSR1 syslog

Sometimes you may need to debug within the container, e.g. when it doesn't even make it past configuration.

Override the entrypoint or use exec on a running container.

E.g. override entrypoint:

docker container run --rm -it \
 -v syslog_log:/var/log/remote \
 -v syslog_work:/var/lib/rsyslog \
 -v syslog_tls:/etc/pki/rsyslog \
 --name syslog --entrypoint /bin/bash jpvriel/rsyslog:latest

Then run the init script manually to see if there are problems:

ENTRYPOINT_DEBUG=true /usr/local/bin/entrypoint.sh

E.g. or exec on an already running container:

docker container exec -it syslog /bin/bash

Via the test suite and make test, the rsyslog server container can fail to start properly and exits before much opportunity to debug issues. A way to try debug after the fact is to create an image from it, run the image and override the entrypoint.

docker commit dockerrsyslog_test_syslog_server_config_1 dockerrsyslog_test_syslog_server_config_1_debug
docker container run --rm -it \
 --env-file test/test_syslog_server.env \
 -v "$(pwd)/test/etc/rsyslog.d/output/filters/:/etc/rsyslog.d/output/filters/" \
 -v dockerrsyslog_syslog_log:/var/log/remote \
 --name debug_test_syslog \
 --entrypoint /bin/bash \
 dockerrsyslog_test_syslog_server_config_1_debug

Once in the container, do debugging, e.g.:

• Inspect all rsyslog env vars with env | grep rsyslog_ (note use of --env-file when running).
• Filter env vars to a list of what's enabled or disabled: env | grep -E "=(on)|(off)"
• Check config rsyslogd -N1
• See how the env vars and config templates expanded out into config: /usr/local/bin/rsyslog_config_expand.py
• Run the entrypoint /usr/local/bin/entrypoint.sh
• Iteratively disable or change options that may be causing the issue, e.g. export rsyslog_input_filtering_enabled=off and rerun the entrypoint script.

For example, the error rsyslogd: optimizer error: we see a NOP, how come? [v8.33.1 try http://www.rsyslog.com/e/2175 ] was hard to debug (due to no config line referenced by the error message). By following the above debug approach and toggling rsyslog_output_filtering_enabled between on and off, as well as enabling and disabling included filter config files, I was able to discover that the continue keyword conflicted with the rainerscript optimiser checking code.

Then cleanup the debug image:

docker image rm dockerrsyslog_test_syslog_server_config_1_debug

Debugging test scenarios

When you just run sut via compose, the output from other containers is hard to see.

Some advice here is:

• Set rsyslog_DEBUG: 'Debug' for the test_syslog_server in docker-compose.test.yml.
• Execute docker-compose -f docker-compose.test.yml run sut behave -w behave/features.
• Run docker logs dockerrsyslog_test_syslog_server_ to see the debug output.
• Use docker-compose -f docker-compose.test.yml down and docker system prune --filter 'dangling=true' between test runs to ensure you don't end up searching on log files within volume data for previous test runs...

You may need to adapt according to how dockerd logging is configured.

For behave failures, the following can help:

• set a behave userdata defined option BEHAVE_DEBUG_ON_ERROR (defined in environment.py) which triggers the python debugger if a test step fails.
• To avoid a work in progress scenario tagged with the @wip fixture, use --tags=-wip, e.g. docker-compose -f docker-compose.test.yml run sut behave behave/features --tags=-wip.
• Use --exclude PATTERN with the behave command to skip problematic feature files.

Sanity check kafka

Kafka configuration via docker with TLS and SASL security options is fairly complex. Docker compose will create a user defined docker network, and zookeeper/kafka can be accessed within that network via their docker hostname (docker network alias). It can help to use the kafka console producer and consumers within containers and the same docker network to sanity check the kafka test dependencies. The SASL_SSL protocol is run on port 9092, but a PLAINTEXT protocol run on port 9091 can help sanity check basic function without being encumbered by security config parameters.

Run kafka test broker

docker-compose -f docker-compose.test.yml up -d test_kafka

Tail the output for the broker

docker logs -f docker-rsyslog_test_kafka_1

Checking with PLAINTEXT protocol

Assuming a topic has already been setup, run console producer on the insecure port

docker run -it --rm --net=docker-rsyslog_default wurstmeister/kafka /opt/kafka/bin/kafka-console-producer.sh --broker-list test_kafka:9091 --batch-size 1 --topic test_syslog

Run console consumer on the insecure port

docker run -it --rm --net=docker-rsyslog_default wurstmeister/kafka /opt/kafka/bin/kafka-console-consumer.sh --bootstrap-server test_kafka:9091 --topic test_syslog --from-beginning

And then type messages in the producer checking if they are echoed in the consumer.

Checking with SASL_SSL protocol

TLS and SASL config needs to be provided to the container. This can be done by bind mounting files with the correct properties/config, e.g.in the properties file:

ssl.truststore.location=/tmp/test_ca.jks
ssl.truststore.password=changeit
security.protocol=SASL_SSL
sasl.mechanism=PLAIN
sasl.jaas.config=org.apache.kafka.common.security.plain.PlainLoginModule required username="test" password="test-secret"

Alternatively, specify the settings via --consumer-property, e.g.:

docker run -it --rm --net=docker-rsyslog_default -v "$PWD/test/tls_x509/certs/test_ca.jks":/tmp/test_ca.jks:ro wurstmeister/kafka /opt/kafka/bin/kafka-console-consumer.sh --bootstrap-server test_kafka:9091 --consumer-property ssl.truststore.location=/tmp/test_ca.jks ssl.truststore.password=changeit security.protocol=SASL_SSL sasl.mechanism=PLAIN sasl.jaas.config=org.apache.kafka.common.security.plain.PlainLoginModule required username="test" password="test-secret"';' --topic test --from-beginning

And as before, checking if messages are echoed in the consumer.

Checking kafka from the host (not stuck in another container)

Instead of running with the kafka container, you can try your own kafka install or lib on your docker host, but it's complicated by two things:

• kafka is picky and requires you to use an advertised hostname when connecting? I.e. can't just connect using an IP?
• Docker networking has it's own isolated and embedded DNS resolver not exposed to your host, so your host can't (by default) use container dns aliases

While you can find the kafka IP as follows, connections to kafka by IP don't work well:

docker container inspect --format '{{ range .NetworkSettings.Networks }}{{ .IPAddress }}{{ end }}' docker-rsyslog_test_kafka_1

Useful docker inspect format tricks

If you want to double check a proper env var was set for the rsyslog or kafka container:

docker container inspect --format '{{ range .Config.Env }}{{ println . }}{{ end }}' docker-rsyslog_test_kafka_1

If you want to poke at ports and servies for each container, it would help to know the network range and IPs:

docker network inspect --format '{{ range .Containers }}{{ .Name }} = {{.IPv4Address}}{{ println }}{{ end }}' docker-rsyslog_default

Known limitations

TLS/SSL config

rsyslog appears to use GNU TLS and TLS libraries in ways which don't readily allow TLS client authentication to be optionally set. Recent versions of rsyslog are beginning to add openssl support, but it was still "beta" at the time of testing.

For imtcp, TLS settings apply globally to all inputs via a stream driver config.

For imrelp:

• TLS settings can apply per input.
• While there's no documented setting for optional TLS client authentication, it is possible to have two listeners on two different ports, one not requesting client certs, and a 2nd requiring client certificates.

#1738 provides an overview of TLS issues.

Finding TLS errors

For example, you'd likely encounter the following error because RELP GNU TLS / gtls forces asking for a client certificate.

Check docker log output for imrelp module messages:

docker container logs docker-rsyslog_test_syslog_server_1 2>&1 | grep imrelp

TLS errors might be found:

rsyslogd: imrelp[7514]: authentication error 'peer did not provide a certificate', peer is '' [v8.38.0 try http://www.rsyslog.com/e/2353 ]
rsyslogd: imrelp[7514]: error 'TLS handshake failed [gnutls error -43: Error in the certificate.]', object  'lstn 7514: conn to clt 172.23.0.9/docker-rsyslog_sut_run_1.docker-rsyslog_default' - input may not work as intended [v8.38.0 try http://www.rsyslog.com/e/2353 ]

JSON formats

As per the official CEE site, CEE sponsorship was halted and not that many systems adopted CEE. rsyslog accepts JSON formatted messages is they are preceded with an @cee cookie, but in testing, this doesn't appear to work well if the message also has RFC5424 structured data preceding the cookie.

TODO: issue now closed? Templates can be simplified and JSON int type used?

As per issue #2827, rsyslog didn't have a simple way to set or manage non-string based JSON types such as booleans, numbers or null, which adds to the complexity of 'hand-crafted' output templates.

Legacy formats

RFC3164 and the legacy file output format of many Linux distro's and *nixes does not include the year, sub-second accuracy, timezone, etc. Since it's still somewhat common to expect files in this format, the file output rsyslog_omfile_template defaults to rsyslog_TraditionalFileFormat. This can help with other logging agents that anticipate these old formats and cannot handle the newer formats.

The other forwarding/relay outputs default to using more modern RFC5424 or JSON formats.

rsyslog can accept and convert RFC3164 legacy input, but with some conversion caveats, such as guessing the timezone of the client matches that of the server, and lazy messages without conventional syslog headers are poorly assumed to map into host and process name fields.

Non-printable characters

rsyslog has a safe default of escaping non-printable characters, which, unfortunately includes tab characters. Some products expect and use tab characters to delimit fields, so while rsyslog escapes tabs as #11 by default, I decided to change this behaviour and allow tabs. Set the env var rsyslog_global_parser_escapeControlCharacterTab="on" to revert to default behaviour of espacing tabs.

Complexity with golang confd templates, rainerscript, and syslog templates

While the approach taken attempted to expose/simply running an rsyslog container by just setting a couple of environment variables, a lot of underlying complexity (and maintainer burden) occurs because:

• Confd and golang text templates dynamically change the rsyslog configuration files, so configuration errors reported by rsyslogd are hard to track back (hence the -E option for the container to see the expanded rsyslog configuration result with line numbers)
• rsyslog rainerscript syntax for assinging values to variables does not appear to support boolean true or false types, nor does it support a null type.
  • As a result, trying to populate JSON template output with such types requires literal strings be manually crafted and explicitly output as such without using native built-in json output templating, otherwise, rsyslogd will quote the JSON values as "true", "false" or "null" (which is not intended).
  • This makes creating the desired JSON templates a verbose exercise of hand picking various elements with such types. Instead, coercing types downstream (e.g. via logstash or elasticsearch index templates) might be a simpler solution that allows for simpler rsyslog templates.

Newer versions of rsyslog does support some env var handling. Note:

• The getenv() function.
  • E.g. if $msg contains getenv('TRIGGERVAR') then /path/to/errfile
  • However it doesn't seem to apply/work in all config contexts, such as configuring a module.
  • Not able to read the environmental variable in rsyslog config was still open at the time of writing this.
  • A work-around an custom variable, and then setting a value from that variable, but that'd be overly cumbersome.
• Backticks string constants to use shell commands (as of v8.33 with an enhanced echo in v8.37).
  • E.g. `echo $VARNAME`
  • See: String Constants

Status

Note, recently (~Jan 2018) the rsyslog project has started to work on an official container and added better environment viable support that could make the confd templating unnecessary, so some refactoring and merging efforts into upstream should be looked into.

Done:

• Multiple inputs
• File output
• Using confd to template config via env vars
• Add metadata to a message about peer connection (helps with provenance) - avoid spoofed syslog messages, or bad info from poorly configured clients.
• Structured data as JSON fields (mmstructdata, with null case)
• Gracefull entrypoint script exit and debugging by passing signals to rsyslogd.
• Kafka and syslog forwarding (with SASL_SSL protocol)
• JSON input (with limitations)
• JSON output
• Filtering

Not yet done:

• Refactor configuration templating:
  • Leverage new config.enabled config object feature instead of complicated script block inclusion or exclusion with confd?
  • Leverage new include()? Note, PR 2426 provides more detail as the current documentation for it is very thin?
  • Leverage new backtick string format to evaluate variable names directly. This could be a partial replacement for confd templating?
• Use mmfields module to handle LEEF and CEF extraction to JSON?
• Re-factor test suite
  • Simplify and depend on less containers one async support in behave allows better network test cases (using tmpfs shared volumes is the current work-around)
  • Watch out for pre-existing files in volumes from prior runs (testing via Makefile avoids this pitfall)
• More rsyslog -> kafka optimisation, which would first require a benchmark test suite
• expose enhancements in env config like
  • imptcp socket backlog setting! Default of 5 does not cope well with high load systems!
  • Confirm impstats counters for omkafka
• Performance tuning as per https://rsyslog.readthedocs.io/en/stable/examples/high_performance.html started with input thread settings. However, ruleset and action output queues settings haven't been optimised or exposed with settings:
  • dequeueBatchSize
  • workerThreads
  • multiple input rulesets all call a single ruleset that then calls multiple output rulesets
    • the central output ruleset might need more worker threads
  • Other docs

    • https://rsyslog.readthedocs.io/en/stable/concepts/queues.html

      By default, rulesets do not have their own queue.

      And

      Please note that when a ruleset uses its own queue, processing of the ruleset happens asynchronously to the rest of processing. As such, any modifications made to the message object (e.g. message or local variables that are set) or discarding of the message object have no effect outside that ruleset. So if you want to modify the message object inside the ruleset, you cannot define a queue for it.

    • https://rsyslog.readthedocs.io/en/stable/concepts/multi_ruleset.html

• Performance tunning hooks for the main queue and the other output action queues as per https://www.rsyslog.com/performance-tuning-elasticsearch/ example.
• Move off CentOS 7 base image and consider lighter alternatives from debian or alpine provided Kafka rsyslog modules are well supported.
• Refactor TLS/SSL given rsyslog has improved TLS support and added openssl.

Maybe someday:

• Re-factor docker entrypoint based on https://github.com/camptocamp/docker-rsyslog-bin example and https://www.camptocamp.com/en/actualite/flexible-docker-entrypoints-scripts/
• support and process events via snmptrapd?
• hasing template for checks on integrity, e.g. fmhash?
• Filter/send rsyslog performance metrics to stdout (omstdout) - is this needed?
• All syslog output to omstdout (would we even need this?)
• More test cases
  • Unit test for stopping and starting the server container to check that state files and persistent queues in /var/lib/rsyslog function as intended
  • Older and other syslog demons as clients, e.g. from centos6, syslog-ng, etc