Monitoring
Important
Installing Prometheus and Grafana is beyond the scope of this project. We assume they are correctly installed in your system. However, for experimentation we provide instructions in Part 4 of the Quickstart.
Monitoring Instances
For each PostgreSQL instance, the operator provides an exporter of metrics for
Prometheus via HTTP or HTTPS, on port 9187, named metrics
.
The operator comes with a predefined set of metrics, as well as a highly
configurable and customizable system to define additional queries via one or
more ConfigMap
or Secret
resources (see the
"User defined metrics" section below for details).
Important
Starting from version 1.11, CloudNativePG already installs
by default a set of predefined metrics in
a ConfigMap
called default-monitoring
.
Info
You can inspect the exported metrics by following the instructions in the "How to inspect the exported metrics" section below.
All monitoring queries that are performed on PostgreSQL are:
- atomic (one transaction per query)
- executed with the
pg_monitor
role - executed with
application_name
set tocnpg_metrics_exporter
- executed as user
postgres
Please refer to the "Predefined Roles" section in PostgreSQL
documentation
for details on the pg_monitor
role.
Queries, by default, are run against the main database, as defined by
the specified bootstrap
method of the Cluster
resource, according
to the following logic:
- using
initdb
: queries will be run by default against the specified database ininitdb.database
, orapp
if not specified - using
recovery
: queries will be run by default against the specified database inrecovery.database
, orpostgres
if not specified - using
pg_basebackup
: queries will be run by default against the specified database inpg_basebackup.database
, orpostgres
if not specified
The default database can always be overridden for a given user-defined metric,
by specifying a list of one or more databases in the target_databases
option.
Prometheus/Grafana
If you are interested in evaluating the integration of CloudNativePG with Prometheus and Grafana, you can find a quick setup guide in Part 4 of the quickstart
Prometheus Operator example
A specific PostgreSQL cluster can be monitored using the Prometheus Operator's resource PodMonitor.
A PodMonitor
that correctly points to the Cluster can be automatically created by the operator by setting
.spec.monitoring.enablePodMonitor
to true
in the Cluster resource itself (default: false
).
Important
Any change to the PodMonitor
created automatically will be overridden by the Operator at the next reconciliation
cycle, in case you need to customize it, you can do so as described below.
To deploy a PodMonitor
for a specific Cluster manually, define it as follows and adjust as needed:
apiVersion: monitoring.coreos.com/v1
kind: PodMonitor
metadata:
name: cluster-example
spec:
selector:
matchLabels:
"cnpg.io/cluster": cluster-example
podMetricsEndpoints:
- port: metrics
Important
Ensure you modify the example above with a unique name, as well as the
correct cluster's namespace and labels (e.g., cluster-example
).
Important
The postgresql
label, used in previous versions of this document, is deprecated
and will be removed in the future. Please use the cnpg.io/cluster
label
instead to select the instances.
Enabling TLS on the Metrics Port
To enable TLS communication on the metrics port, configure the .spec.monitoring.tls.enabled
setting to true
. This setup ensures that the metrics exporter uses the same
server certificate used by PostgreSQL to secure communication on port 5432.
Important
Changing the .spec.monitoring.tls.enabled
setting will trigger a rolling restart of the Cluster.
If the PodMonitor
is managed by the operator (.spec.monitoring.enablePodMonitor
set to true
),
it will automatically contain the necessary configurations to access the metrics via TLS.
To manually deploy a PodMonitor
suitable for reading metrics via TLS, define it as follows and
adjust as needed:
apiVersion: monitoring.coreos.com/v1
kind: PodMonitor
metadata:
name: cluster-example
spec:
selector:
matchLabels:
"cnpg.io/cluster": cluster-example
podMetricsEndpoints:
- port: metrics
scheme: https
tlsConfig:
ca:
secret:
name: cluster-example-ca
key: ca.crt
serverName: cluster-example-rw
Important
Ensure you modify the example above with a unique name, as well as the
correct Cluster's namespace and labels (e.g., cluster-example
).
Important
The serverName
field in the metrics endpoint must match one of the names
defined in the server certificate. If the default certificate is in use,
the serverName
value should be in the format <cluster-name>-rw
.
Predefined set of metrics
Every PostgreSQL instance exporter automatically exposes a set of predefined metrics, which can be classified in two major categories:
-
PostgreSQL related metrics, starting with
cnpg_collector_*
, including:- number of WAL files and total size on disk
- number of
.ready
and.done
files in the archive status folder - requested minimum and maximum number of synchronous replicas, as well as the expected and actually observed values
- number of distinct nodes accommodating the instances
- timestamps indicating last failed and last available backup, as well as the first point of recoverability for the cluster
- flag indicating if replica cluster mode is enabled or disabled
- flag indicating if a manual switchover is required
- flag indicating if fencing is enabled or disabled
-
Go runtime related metrics, starting with
go_*
Below is a sample of the metrics returned by the localhost:9187/metrics
endpoint of an instance. As you can see, the Prometheus format is
self-documenting:
# HELP cnpg_collector_collection_duration_seconds Collection time duration in seconds
# TYPE cnpg_collector_collection_duration_seconds gauge
cnpg_collector_collection_duration_seconds{collector="Collect.up"} 0.0031393
# HELP cnpg_collector_collections_total Total number of times PostgreSQL was accessed for metrics.
# TYPE cnpg_collector_collections_total counter
cnpg_collector_collections_total 2
# HELP cnpg_collector_fencing_on 1 if the instance is fenced, 0 otherwise
# TYPE cnpg_collector_fencing_on gauge
cnpg_collector_fencing_on 0
# HELP cnpg_collector_nodes_used NodesUsed represents the count of distinct nodes accommodating the instances. A value of '-1' suggests that the metric is not available. A value of '1' suggests that all instances are hosted on a single node, implying the absence of High Availability (HA). Ideally this value should match the number of instances in the cluster.
# TYPE cnpg_collector_nodes_used gauge
cnpg_collector_nodes_used 3
# HELP cnpg_collector_last_collection_error 1 if the last collection ended with error, 0 otherwise.
# TYPE cnpg_collector_last_collection_error gauge
cnpg_collector_last_collection_error 0
# HELP cnpg_collector_manual_switchover_required 1 if a manual switchover is required, 0 otherwise
# TYPE cnpg_collector_manual_switchover_required gauge
cnpg_collector_manual_switchover_required 0
# HELP cnpg_collector_pg_wal Total size in bytes of WAL segments in the '/var/lib/postgresql/data/pgdata/pg_wal' directory computed as (wal_segment_size * count)
# TYPE cnpg_collector_pg_wal gauge
cnpg_collector_pg_wal{value="count"} 9
cnpg_collector_pg_wal{value="slots_max"} NaN
cnpg_collector_pg_wal{value="keep"} 32
cnpg_collector_pg_wal{value="max"} 64
cnpg_collector_pg_wal{value="min"} 5
cnpg_collector_pg_wal{value="size"} 1.50994944e+08
cnpg_collector_pg_wal{value="volume_max"} 128
cnpg_collector_pg_wal{value="volume_size"} 2.147483648e+09
# HELP cnpg_collector_pg_wal_archive_status Number of WAL segments in the '/var/lib/postgresql/data/pgdata/pg_wal/archive_status' directory (ready, done)
# TYPE cnpg_collector_pg_wal_archive_status gauge
cnpg_collector_pg_wal_archive_status{value="done"} 6
cnpg_collector_pg_wal_archive_status{value="ready"} 0
# HELP cnpg_collector_replica_mode 1 if the cluster is in replica mode, 0 otherwise
# TYPE cnpg_collector_replica_mode gauge
cnpg_collector_replica_mode 0
# HELP cnpg_collector_sync_replicas Number of requested synchronous replicas (synchronous_standby_names)
# TYPE cnpg_collector_sync_replicas gauge
cnpg_collector_sync_replicas{value="expected"} 0
cnpg_collector_sync_replicas{value="max"} 0
cnpg_collector_sync_replicas{value="min"} 0
cnpg_collector_sync_replicas{value="observed"} 0
# HELP cnpg_collector_up 1 if PostgreSQL is up, 0 otherwise.
# TYPE cnpg_collector_up gauge
cnpg_collector_up{cluster="cluster-example"} 1
# HELP cnpg_collector_postgres_version Postgres version
# TYPE cnpg_collector_postgres_version gauge
cnpg_collector_postgres_version{cluster="cluster-example",full="16.3"} 16.3
# HELP cnpg_collector_last_failed_backup_timestamp The last failed backup as a unix timestamp
# TYPE cnpg_collector_last_failed_backup_timestamp gauge
cnpg_collector_last_failed_backup_timestamp 0
# HELP cnpg_collector_last_available_backup_timestamp The last available backup as a unix timestamp
# TYPE cnpg_collector_last_available_backup_timestamp gauge
cnpg_collector_last_available_backup_timestamp 1.63238406e+09
# HELP cnpg_collector_first_recoverability_point The first point of recoverability for the cluster as a unix timestamp
# TYPE cnpg_collector_first_recoverability_point gauge
cnpg_collector_first_recoverability_point 1.63238406e+09
# HELP cnpg_collector_lo_pages Estimated number of pages in the pg_largeobject table
# TYPE cnpg_collector_lo_pages gauge
cnpg_collector_lo_pages{datname="app"} 0
cnpg_collector_lo_pages{datname="postgres"} 78
# HELP cnpg_collector_wal_buffers_full Number of times WAL data was written to disk because WAL buffers became full. Only available on PG 14+
# TYPE cnpg_collector_wal_buffers_full gauge
cnpg_collector_wal_buffers_full{stats_reset="2023-06-19T10:51:27.473259Z"} 6472
# HELP cnpg_collector_wal_bytes Total amount of WAL generated in bytes. Only available on PG 14+
# TYPE cnpg_collector_wal_bytes gauge
cnpg_collector_wal_bytes{stats_reset="2023-06-19T10:51:27.473259Z"} 1.0035147e+07
# HELP cnpg_collector_wal_fpi Total number of WAL full page images generated. Only available on PG 14+
# TYPE cnpg_collector_wal_fpi gauge
cnpg_collector_wal_fpi{stats_reset="2023-06-19T10:51:27.473259Z"} 1474
# HELP cnpg_collector_wal_records Total number of WAL records generated. Only available on PG 14+
# TYPE cnpg_collector_wal_records gauge
cnpg_collector_wal_records{stats_reset="2023-06-19T10:51:27.473259Z"} 26178
# HELP cnpg_collector_wal_sync Number of times WAL files were synced to disk via issue_xlog_fsync request (if fsync is on and wal_sync_method is either fdatasync, fsync or fsync_writethrough, otherwise zero). Only available on PG 14+
# TYPE cnpg_collector_wal_sync gauge
cnpg_collector_wal_sync{stats_reset="2023-06-19T10:51:27.473259Z"} 37
# HELP cnpg_collector_wal_sync_time Total amount of time spent syncing WAL files to disk via issue_xlog_fsync request, in milliseconds (if track_wal_io_timing is enabled, fsync is on, and wal_sync_method is either fdatasync, fsync or fsync_writethrough, otherwise zero). Only available on PG 14+
# TYPE cnpg_collector_wal_sync_time gauge
cnpg_collector_wal_sync_time{stats_reset="2023-06-19T10:51:27.473259Z"} 0
# HELP cnpg_collector_wal_write Number of times WAL buffers were written out to disk via XLogWrite request. Only available on PG 14+
# TYPE cnpg_collector_wal_write gauge
cnpg_collector_wal_write{stats_reset="2023-06-19T10:51:27.473259Z"} 7243
# HELP cnpg_collector_wal_write_time Total amount of time spent writing WAL buffers to disk via XLogWrite request, in milliseconds (if track_wal_io_timing is enabled, otherwise zero). This includes the sync time when wal_sync_method is either open_datasync or open_sync. Only available on PG 14+
# TYPE cnpg_collector_wal_write_time gauge
cnpg_collector_wal_write_time{stats_reset="2023-06-19T10:51:27.473259Z"} 0
# HELP cnpg_last_error 1 if the last collection ended with error, 0 otherwise.
# TYPE cnpg_last_error gauge
cnpg_last_error 0
# HELP go_gc_duration_seconds A summary of the pause duration of garbage collection cycles.
# TYPE go_gc_duration_seconds summary
go_gc_duration_seconds{quantile="0"} 5.01e-05
go_gc_duration_seconds{quantile="0.25"} 7.27e-05
go_gc_duration_seconds{quantile="0.5"} 0.0001748
go_gc_duration_seconds{quantile="0.75"} 0.0002959
go_gc_duration_seconds{quantile="1"} 0.0012776
go_gc_duration_seconds_sum 0.0035741
go_gc_duration_seconds_count 13
# HELP go_goroutines Number of goroutines that currently exist.
# TYPE go_goroutines gauge
go_goroutines 25
# HELP go_info Information about the Go environment.
# TYPE go_info gauge
go_info{version="go1.20.5"} 1
# HELP go_memstats_alloc_bytes Number of bytes allocated and still in use.
# TYPE go_memstats_alloc_bytes gauge
go_memstats_alloc_bytes 4.493744e+06
# HELP go_memstats_alloc_bytes_total Total number of bytes allocated, even if freed.
# TYPE go_memstats_alloc_bytes_total counter
go_memstats_alloc_bytes_total 2.1698216e+07
# HELP go_memstats_buck_hash_sys_bytes Number of bytes used by the profiling bucket hash table.
# TYPE go_memstats_buck_hash_sys_bytes gauge
go_memstats_buck_hash_sys_bytes 1.456234e+06
# HELP go_memstats_frees_total Total number of frees.
# TYPE go_memstats_frees_total counter
go_memstats_frees_total 172118
# HELP go_memstats_gc_cpu_fraction The fraction of this program's available CPU time used by the GC since the program started.
# TYPE go_memstats_gc_cpu_fraction gauge
go_memstats_gc_cpu_fraction 1.0749468700447189e-05
# HELP go_memstats_gc_sys_bytes Number of bytes used for garbage collection system metadata.
# TYPE go_memstats_gc_sys_bytes gauge
go_memstats_gc_sys_bytes 5.530048e+06
# HELP go_memstats_heap_alloc_bytes Number of heap bytes allocated and still in use.
# TYPE go_memstats_heap_alloc_bytes gauge
go_memstats_heap_alloc_bytes 4.493744e+06
# HELP go_memstats_heap_idle_bytes Number of heap bytes waiting to be used.
# TYPE go_memstats_heap_idle_bytes gauge
go_memstats_heap_idle_bytes 5.8236928e+07
# HELP go_memstats_heap_inuse_bytes Number of heap bytes that are in use.
# TYPE go_memstats_heap_inuse_bytes gauge
go_memstats_heap_inuse_bytes 7.528448e+06
# HELP go_memstats_heap_objects Number of allocated objects.
# TYPE go_memstats_heap_objects gauge
go_memstats_heap_objects 26306
# HELP go_memstats_heap_released_bytes Number of heap bytes released to OS.
# TYPE go_memstats_heap_released_bytes gauge
go_memstats_heap_released_bytes 5.7401344e+07
# HELP go_memstats_heap_sys_bytes Number of heap bytes obtained from system.
# TYPE go_memstats_heap_sys_bytes gauge
go_memstats_heap_sys_bytes 6.5765376e+07
# HELP go_memstats_last_gc_time_seconds Number of seconds since 1970 of last garbage collection.
# TYPE go_memstats_last_gc_time_seconds gauge
go_memstats_last_gc_time_seconds 1.6311727586032727e+09
# HELP go_memstats_lookups_total Total number of pointer lookups.
# TYPE go_memstats_lookups_total counter
go_memstats_lookups_total 0
# HELP go_memstats_mallocs_total Total number of mallocs.
# TYPE go_memstats_mallocs_total counter
go_memstats_mallocs_total 198424
# HELP go_memstats_mcache_inuse_bytes Number of bytes in use by mcache structures.
# TYPE go_memstats_mcache_inuse_bytes gauge
go_memstats_mcache_inuse_bytes 14400
# HELP go_memstats_mcache_sys_bytes Number of bytes used for mcache structures obtained from system.
# TYPE go_memstats_mcache_sys_bytes gauge
go_memstats_mcache_sys_bytes 16384
# HELP go_memstats_mspan_inuse_bytes Number of bytes in use by mspan structures.
# TYPE go_memstats_mspan_inuse_bytes gauge
go_memstats_mspan_inuse_bytes 191896
# HELP go_memstats_mspan_sys_bytes Number of bytes used for mspan structures obtained from system.
# TYPE go_memstats_mspan_sys_bytes gauge
go_memstats_mspan_sys_bytes 212992
# HELP go_memstats_next_gc_bytes Number of heap bytes when next garbage collection will take place.
# TYPE go_memstats_next_gc_bytes gauge
go_memstats_next_gc_bytes 8.689632e+06
# HELP go_memstats_other_sys_bytes Number of bytes used for other system allocations.
# TYPE go_memstats_other_sys_bytes gauge
go_memstats_other_sys_bytes 2.566622e+06
# HELP go_memstats_stack_inuse_bytes Number of bytes in use by the stack allocator.
# TYPE go_memstats_stack_inuse_bytes gauge
go_memstats_stack_inuse_bytes 1.343488e+06
# HELP go_memstats_stack_sys_bytes Number of bytes obtained from system for stack allocator.
# TYPE go_memstats_stack_sys_bytes gauge
go_memstats_stack_sys_bytes 1.343488e+06
# HELP go_memstats_sys_bytes Number of bytes obtained from system.
# TYPE go_memstats_sys_bytes gauge
go_memstats_sys_bytes 7.6891144e+07
# HELP go_threads Number of OS threads created.
# TYPE go_threads gauge
go_threads 18
Note
cnpg_collector_postgres_version
is a GaugeVec metric containing
the Major.Minor
version of PostgreSQL. The full semantic version
Major.Minor.Patch
can be found inside one of its label field
named full
.
Note
cnpg_collector_first_recoverability_point
and cnpg_collector_last_available_backup_timestamp
will be zero until your first backup to the object store. This is separate from the WAL archival.
User defined metrics
This feature is currently in beta state and the format is inspired by the queries.yaml file (release 0.12) of the PostgreSQL Prometheus Exporter.
Custom metrics can be defined by users by referring to the created Configmap
/Secret
in a Cluster
definition
under the .spec.monitoring.customQueriesConfigMap
or customQueriesSecret
section as in the following example:
apiVersion: postgresql.cnpg.io/v1
kind: Cluster
metadata:
name: cluster-example
namespace: test
spec:
instances: 3
storage:
size: 1Gi
monitoring:
customQueriesConfigMap:
- name: example-monitoring
key: custom-queries
The customQueriesConfigMap
/customQueriesSecret
sections contain a list of
ConfigMap
/Secret
references specifying the key in which the custom queries are defined.
Take care that the referred resources have to be created in the same namespace as the Cluster resource.
Note
If you want ConfigMaps and Secrets to be automatically reloaded by instances, you can
add a label with key cnpg.io/reload
to it, otherwise you will have to reload
the instances using the kubectl cnpg reload
subcommand.
Important
When a user defined metric overwrites an already existing metric the instance manager prints a json warning log,
containing the message:Query with the same name already found. Overwriting the existing one.
and a key queryName
containing the overwritten query name.
Example of a user defined metric
Here you can see an example of a ConfigMap
containing a single custom query,
referenced by the Cluster
example above:
apiVersion: v1
kind: ConfigMap
metadata:
name: example-monitoring
namespace: test
labels:
cnpg.io/reload: ""
data:
custom-queries: |
pg_replication:
query: "SELECT CASE WHEN NOT pg_is_in_recovery()
THEN 0
ELSE GREATEST (0,
EXTRACT(EPOCH FROM (now() - pg_last_xact_replay_timestamp())))
END AS lag,
pg_is_in_recovery() AS in_recovery,
EXISTS (TABLE pg_stat_wal_receiver) AS is_wal_receiver_up,
(SELECT count(*) FROM pg_stat_replication) AS streaming_replicas"
metrics:
- lag:
usage: "GAUGE"
description: "Replication lag behind primary in seconds"
- in_recovery:
usage: "GAUGE"
description: "Whether the instance is in recovery"
- is_wal_receiver_up:
usage: "GAUGE"
description: "Whether the instance wal_receiver is up"
- streaming_replicas:
usage: "GAUGE"
description: "Number of streaming replicas connected to the instance"
A list of basic monitoring queries can be found in the
default-monitoring.yaml
file
that is already installed in your CloudNativePG deployment (see "Default set of metrics").
Example of a user defined metric with predicate query
The predicate_query
option allows the user to execute the query
to collect the metrics only under the specified conditions.
To do so the user needs to provide a predicate query that returns at most one row with a single boolean
column.
The predicate query is executed in the same transaction as the main query and against the same databases.
some_query: |
predicate_query: |
SELECT
some_bool as predicate
FROM some_table
query: |
SELECT
count(*) as rows
FROM some_table
metrics:
- rows:
usage: "GAUGE"
description: "number of rows"
Example of a user defined metric running on multiple databases
If the target_databases
option lists more than one database
the metric is collected from each of them.
Database auto-discovery can be enabled for a specific query by specifying a
shell-like pattern (i.e., containing *
, ?
or []
) in the list of
target_databases
. If provided, the operator will expand the list of target
databases by adding all the databases returned by the execution of SELECT
datname FROM pg_database WHERE datallowconn AND NOT datistemplate
and matching
the pattern according to path.Match() rules.
Note
The *
character has a special meaning in yaml,
so you need to quote ("*"
) the target_databases
value when it includes such a pattern.
It is recommended that you always include the name of the database
in the returned labels, for example using the current_database()
function
as in the following example:
some_query: |
query: |
SELECT
current_database() as datname,
count(*) as rows
FROM some_table
metrics:
- datname:
usage: "LABEL"
description: "Name of current database"
- rows:
usage: "GAUGE"
description: "number of rows"
target_databases:
- albert
- bb
- freddie
This will produce in the following metric being exposed:
cnpg_some_query_rows{datname="albert"} 2
cnpg_some_query_rows{datname="bb"} 5
cnpg_some_query_rows{datname="freddie"} 10
Here is an example of a query with auto-discovery enabled which also
runs on the template1
database (otherwise not returned by the
aforementioned query):
some_query: |
query: |
SELECT
current_database() as datname,
count(*) as rows
FROM some_table
metrics:
- datname:
usage: "LABEL"
description: "Name of current database"
- rows:
usage: "GAUGE"
description: "number of rows"
target_databases:
- "*"
- "template1"
The above example will produce the following metrics (provided the databases exist):
cnpg_some_query_rows{datname="albert"} 2
cnpg_some_query_rows{datname="bb"} 5
cnpg_some_query_rows{datname="freddie"} 10
cnpg_some_query_rows{datname="template1"} 7
cnpg_some_query_rows{datname="postgres"} 42
Structure of a user defined metric
Every custom query has the following basic structure:
<MetricName>:
query: "<SQLQuery>"
metrics:
- <ColumnName>:
usage: "<MetricType>"
description: "<MetricDescription>"
Here is a short description of all the available fields:
<MetricName>
: the name of the Prometheus metricname
: override<MetricName>
, if definedquery
: the SQL query to run on the target database to generate the metricsprimary
: whether to run the query only on the primary instancemaster
: same asprimary
(for compatibility with the Prometheus PostgreSQL exporter's syntax - deprecated)runonserver
: a semantic version range to limit the versions of PostgreSQL the query should run on (e.g.">=11.0.0"
or">=12.0.0 <=15.0.0"
)target_databases
: a list of databases to run thequery
against, or a shell-like pattern to enable auto discovery. Overwrites the default database if provided.predicate_query
: a SQL query that returns at most one row and oneboolean
column to run on the target database. The system evaluates the predicate and iftrue
executes thequery
.metrics
: section containing a list of all exported columns, defined as follows:<ColumnName>
: the name of the column returned by the queryname
: override theColumnName
of the column in the metric, if definedusage
: one of the values described belowdescription
: the metric's descriptionmetrics_mapping
: the optional column mapping whenusage
is set toMAPPEDMETRIC
The possible values for usage
are:
Column Usage Label | Description |
---|---|
DISCARD |
this column should be ignored |
LABEL |
use this column as a label |
COUNTER |
use this column as a counter |
GAUGE |
use this column as a gauge |
MAPPEDMETRIC |
use this column with the supplied mapping of text values |
DURATION |
use this column as a text duration (in milliseconds) |
HISTOGRAM |
use this column as a histogram |
Please visit the "Metric Types" page from the Prometheus documentation for more information.
Output of a user defined metric
Custom defined metrics are returned by the Prometheus exporter endpoint (:9187/metrics
)
with the following format:
cnpg_<MetricName>_<ColumnName>{<LabelColumnName>=<LabelColumnValue> ... } <ColumnValue>
Note
LabelColumnName
are metrics with usage
set to LABEL
and their Value
Considering the pg_replication
example above, the exporter's endpoint would
return the following output when invoked:
# HELP cnpg_pg_replication_in_recovery Whether the instance is in recovery
# TYPE cnpg_pg_replication_in_recovery gauge
cnpg_pg_replication_in_recovery 0
# HELP cnpg_pg_replication_lag Replication lag behind primary in seconds
# TYPE cnpg_pg_replication_lag gauge
cnpg_pg_replication_lag 0
# HELP cnpg_pg_replication_streaming_replicas Number of streaming replicas connected to the instance
# TYPE cnpg_pg_replication_streaming_replicas gauge
cnpg_pg_replication_streaming_replicas 2
# HELP cnpg_pg_replication_is_wal_receiver_up Whether the instance wal_receiver is up
# TYPE cnpg_pg_replication_is_wal_receiver_up gauge
cnpg_pg_replication_is_wal_receiver_up 0
Default set of metrics
The operator can be configured to automatically inject in a Cluster a set of
monitoring queries defined in a ConfigMap or a Secret, inside the operator's namespace.
You have to set the MONITORING_QUERIES_CONFIGMAP
or
MONITORING_QUERIES_SECRET
key in the "operator configuration",
respectively to the name of the ConfigMap or the Secret;
the operator will then use the content of the queries
key.
Any change to the queries
content will be immediately reflected on all the
deployed Clusters using it.
The operator installation manifests come with a predefined ConfigMap,
called cnpg-default-monitoring
, to be used by all Clusters.
MONITORING_QUERIES_CONFIGMAP
is by default set to cnpg-default-monitoring
in the operator configuration.
If you want to disable the default set of metrics, you can:
- disable it at operator level: set the MONITORING_QUERIES_CONFIGMAP
/MONITORING_QUERIES_SECRET
key to ""
(empty string), in the operator ConfigMap. Changes to operator ConfigMap require an operator restart.
- disable it for a specific Cluster: set .spec.monitoring.disableDefaultQueries
to true
in the Cluster.
Important
The ConfigMap or Secret specified via MONITORING_QUERIES_CONFIGMAP
/MONITORING_QUERIES_SECRET
will always be copied to the Cluster's namespace with a fixed name: cnpg-default-monitoring
.
So that, if you intend to have default metrics, you should not create a ConfigMap with this name in the cluster's namespace.
Differences with the Prometheus Postgres exporter
CloudNativePG is inspired by the PostgreSQL Prometheus Exporter, but
presents some differences. In particular, the cache_seconds
field is not implemented
in CloudNativePG's exporter.
Monitoring the operator
The operator internally exposes Prometheus metrics
via HTTP on port 8080, named metrics
.
Info
You can inspect the exported metrics by following the instructions in the "How to inspect the exported metrics" section below.
Currently, the operator exposes default kubebuilder
metrics, see
kubebuilder documentation for more details.
Prometheus Operator example
The operator deployment can be monitored using the Prometheus Operator by defining the following PodMonitor resource:
apiVersion: monitoring.coreos.com/v1
kind: PodMonitor
metadata:
name: cnpg-controller-manager
spec:
selector:
matchLabels:
app.kubernetes.io/name: cloudnative-pg
podMetricsEndpoints:
- port: metrics
How to inspect the exported metrics
In this section we provide some basic instructions on how to inspect
the metrics exported by a specific PostgreSQL instance manager (primary
or replica) or the operator, using a temporary pod running curl
in
the same namespace.
Note
In the example below we assume we are working in the default namespace, alongside with the PostgreSQL cluster. Please feel free to adapt this example to your use case, by applying basic Kubernetes knowledge.
Create the curl.yaml
file with this content:
apiVersion: v1
kind: Pod
metadata:
name: curl
spec:
containers:
- name: curl
image: curlimages/curl:8.2.1
command: ['sleep', '3600']
Then create the pod:
kubectl apply -f curl.yaml
In case you want to inspect the metrics exported by an instance, you need to connect to port 9187 of the target pod. This is the generic command to be run (make sure you use the correct IP for the pod):
kubectl exec -ti curl -- curl -s <pod_ip>:9187/metrics
For example, if your PostgreSQL cluster is called cluster-example
and
you want to retrieve the exported metrics of the first pod in the cluster,
you can run the following command to programmatically get the IP of
that pod:
POD_IP=$(kubectl get pod cluster-example-1 --template '{{.status.podIP}}')
And then run:
kubectl exec -ti curl -- curl -s ${POD_IP}:9187/metrics
If you enabled TLS metrics, run instead:
kubectl exec -ti curl -- curl -sk https://${POD_IP}:9187/metrics
In case you want to access the metrics of the operator, you need to point to the pod where the operator is running, and use TCP port 8080 as target.
At the end of the inspection, please make sure you delete the curl
pod:
kubectl delete -f curl.yaml
Auxiliary resources
Important
These resources are provided for illustration and experimentation, and do not represent any kind of recommendation for your production system
In the doc/src/samples/monitoring/
directory you will find a series of sample files for observability.
Please refer to Part 4 of the quickstart
section for context:
kube-stack-config.yaml
: a configuration file for the kube-stack helm chart installation. It ensures that Prometheus listens for all PodMonitor resources.prometheusrule.yaml
: aPrometheusRule
with alerts for CloudNativePG. NOTE: this does not include inter-operation with notification services. Please refer to the Prometheus documentation.podmonitor.yaml
: aPodMonitor
for the CloudNativePG Operator deployment.
In addition, we provide the "raw" sources for the Prometheus alert rules in the
alerts.yaml
file.
The Grafana dashboard has a dedicated repository now.
Note that, for the configuration of kube-prometheus-stack
, other fields and
settings are available over what we provide in kube-stack-config.yaml
.
You can execute helm show values prometheus-community/kube-prometheus-stack
to view them. For further information, please refer to the
kube-prometheus-stack
page.