PostgreSQL provides facilities to support dynamic tracing of the database server. This allows an external utility to be called at specific points in the code and thereby trace execution.
A number of probes or trace points are already inserted into the source code. These probes are intended to be used by database developers and administrators. By default the probes are not compiled into PostgreSQL; the user needs to explicitly tell the configure script to make the probes available.
Currently, the DTrace utility is supported, which, at the time of this writing, is available on Solaris, macOS, FreeBSD, NetBSD, and Oracle Linux. The SystemTap project for Linux provides a DTrace equivalent and can also be used. Supporting other dynamic tracing utilities is theoretically possible by changing the definitions for the macros in src/include/utils/probes.h.
By default, probes are not available, so you will need to explicitly tell the configure script to make the probes available in PostgreSQL. To include DTrace support specify --enable-dtrace to configure. See Section 17.4 for further information.
A number of standard probes are provided in the source code, as shown in Table 28.47; Table 28.48 shows the types used in the probes. More probes can certainly be added to enhance PostgreSQL's observability.
| Name | Parameters | Description |
|---|---|---|
The example below shows a DTrace script for analyzing transaction counts in the system, as an alternative to snapshotting pg_stat_database before and after a performance test:
When executed, the example D script gives output such as:
SystemTap uses a different notation for trace scripts than DTrace does, even though the underlying trace points are compatible. One point worth noting is that at this writing, SystemTap scripts must reference probe names using double underscores in place of hyphens. This is expected to be fixed in future SystemTap releases.
You should remember that DTrace scripts need to be carefully written and debugged, otherwise the trace information collected might be meaningless. In most cases where problems are found it is the instrumentation that is at fault, not the underlying system. When discussing information found using dynamic tracing, be sure to enclose the script used to allow that too to be checked and discussed.
New probes can be defined within the code wherever the developer desires, though this will require a recompilation. Below are the steps for inserting new probes:
Decide on probe names and data to be made available through the probes
Add the probe definitions to src/backend/utils/probes.d
Include pg_trace.h if it is not already present in the module(s) containing the probe points, and insert TRACE_POSTGRESQL probe macros at the desired locations in the source code
Recompile and verify that the new probes are available
Example: Here is an example of how you would add a probe to trace all new transactions by transaction ID.
Decide that the probe will be named transaction-start and requires a parameter of type LocalTransactionId
Add the probe definition to src/backend/utils/probes.d:
Note the use of the double underline in the probe name. In a DTrace script using the probe, the double underline needs to be replaced with a hyphen, so transaction-start is the name to document for users.
At compile time, transaction__start is converted to a macro called TRACE_POSTGRESQL_TRANSACTION_START (notice the underscores are single here), which is available by including pg_trace.h. Add the macro call to the appropriate location in the source code. In this case, it looks like the following:
After recompiling and running the new binary, check that your newly added probe is available by executing the following DTrace command. You should see similar output:
There are a few things to be careful about when adding trace macros to the C code:
You should take care that the data types specified for a probe's parameters match the data types of the variables used in the macro. Otherwise, you will get compilation errors.
On most platforms, if PostgreSQL is built with --enable-dtrace, the arguments to a trace macro will be evaluated whenever control passes through the macro, even if no tracing is being done. This is usually not worth worrying about if you are just reporting the values of a few local variables. But beware of putting expensive function calls into the arguments. If you need to do that, consider protecting the macro with a check to see if the trace is actually enabled:
Each trace macro has a corresponding ENABLED macro.
Another useful tool for monitoring database activity is the pg_locks system table. It allows the database administrator to view information about the outstanding locks in the lock manager. For example, this capability can be used to:
View all the locks currently outstanding, all the locks on relations in a particular database, all the locks on a particular relation, or all the locks held by a particular PostgreSQL session.
Determine the relation in the current database with the most ungranted locks (which might be a source of contention among database clients).
Determine the effect of lock contention on overall database performance, as well as the extent to which contention varies with overall database traffic.
Details of the pg_locks view appear in . For more information on locking and managing concurrency with PostgreSQL, refer to .
| Type | Definition |
|---|---|
transaction-start
(LocalTransactionId)
Probe that fires at the start of a new transaction. arg0 is the transaction ID.
transaction-commit
(LocalTransactionId)
Probe that fires when a transaction completes successfully. arg0 is the transaction ID.
transaction-abort
(LocalTransactionId)
Probe that fires when a transaction completes unsuccessfully. arg0 is the transaction ID.
query-start
(const char *)
Probe that fires when the processing of a query is started. arg0 is the query string.
query-done
(const char *)
Probe that fires when the processing of a query is complete. arg0 is the query string.
query-parse-start
(const char *)
Probe that fires when the parsing of a query is started. arg0 is the query string.
query-parse-done
(const char *)
Probe that fires when the parsing of a query is complete. arg0 is the query string.
query-rewrite-start
(const char *)
Probe that fires when the rewriting of a query is started. arg0 is the query string.
query-rewrite-done
(const char *)
Probe that fires when the rewriting of a query is complete. arg0 is the query string.
query-plan-start
()
Probe that fires when the planning of a query is started.
query-plan-done
()
Probe that fires when the planning of a query is complete.
query-execute-start
()
Probe that fires when the execution of a query is started.
query-execute-done
()
Probe that fires when the execution of a query is complete.
statement-status
(const char *)
Probe that fires anytime the server process updates its pg_stat_activity.status. arg0 is the new status string.
checkpoint-start
(int)
Probe that fires when a checkpoint is started. arg0 holds the bitwise flags used to distinguish different checkpoint types, such as shutdown, immediate or force.
checkpoint-done
(int, int, int, int, int)
Probe that fires when a checkpoint is complete. (The probes listed next fire in sequence during checkpoint processing.) arg0 is the number of buffers written. arg1 is the total number of buffers. arg2, arg3 and arg4 contain the number of WAL files added, removed and recycled respectively.
clog-checkpoint-start
(bool)
Probe that fires when the CLOG portion of a checkpoint is started. arg0 is true for normal checkpoint, false for shutdown checkpoint.
clog-checkpoint-done
(bool)
Probe that fires when the CLOG portion of a checkpoint is complete. arg0 has the same meaning as for clog-checkpoint-start.
subtrans-checkpoint-start
(bool)
Probe that fires when the SUBTRANS portion of a checkpoint is started. arg0 is true for normal checkpoint, false for shutdown checkpoint.
subtrans-checkpoint-done
(bool)
Probe that fires when the SUBTRANS portion of a checkpoint is complete. arg0 has the same meaning as for subtrans-checkpoint-start.
multixact-checkpoint-start
(bool)
Probe that fires when the MultiXact portion of a checkpoint is started. arg0 is true for normal checkpoint, false for shutdown checkpoint.
multixact-checkpoint-done
(bool)
Probe that fires when the MultiXact portion of a checkpoint is complete. arg0 has the same meaning as for multixact-checkpoint-start.
buffer-checkpoint-start
(int)
Probe that fires when the buffer-writing portion of a checkpoint is started. arg0 holds the bitwise flags used to distinguish different checkpoint types, such as shutdown, immediate or force.
buffer-sync-start
(int, int)
Probe that fires when we begin to write dirty buffers during checkpoint (after identifying which buffers must be written). arg0 is the total number of buffers. arg1 is the number that are currently dirty and need to be written.
buffer-sync-written
(int)
Probe that fires after each buffer is written during checkpoint. arg0 is the ID number of the buffer.
buffer-sync-done
(int, int, int)
Probe that fires when all dirty buffers have been written. arg0 is the total number of buffers. arg1 is the number of buffers actually written by the checkpoint process. arg2 is the number that were expected to be written (arg1 of buffer-sync-start); any difference reflects other processes flushing buffers during the checkpoint.
buffer-checkpoint-sync-start
()
Probe that fires after dirty buffers have been written to the kernel, and before starting to issue fsync requests.
buffer-checkpoint-done
()
Probe that fires when syncing of buffers to disk is complete.
twophase-checkpoint-start
()
Probe that fires when the two-phase portion of a checkpoint is started.
twophase-checkpoint-done
()
Probe that fires when the two-phase portion of a checkpoint is complete.
buffer-read-start
(ForkNumber, BlockNumber, Oid, Oid, Oid, int, bool)
Probe that fires when a buffer read is started. arg0 and arg1 contain the fork and block numbers of the page (but arg1 will be -1 if this is a relation extension request). arg2, arg3, and arg4 contain the tablespace, database, and relation OIDs identifying the relation. arg5 is the ID of the backend which created the temporary relation for a local buffer, or InvalidBackendId (-1) for a shared buffer. arg6 is true for a relation extension request, false for normal read.
buffer-read-done
(ForkNumber, BlockNumber, Oid, Oid, Oid, int, bool, bool)
Probe that fires when a buffer read is complete. arg0 and arg1 contain the fork and block numbers of the page (if this is a relation extension request, arg1 now contains the block number of the newly added block). arg2, arg3, and arg4 contain the tablespace, database, and relation OIDs identifying the relation. arg5 is the ID of the backend which created the temporary relation for a local buffer, or InvalidBackendId (-1) for a shared buffer. arg6 is true for a relation extension request, false for normal read. arg7 is true if the buffer was found in the pool, false if not.
buffer-flush-start
(ForkNumber, BlockNumber, Oid, Oid, Oid)
Probe that fires before issuing any write request for a shared buffer. arg0 and arg1 contain the fork and block numbers of the page. arg2, arg3, and arg4 contain the tablespace, database, and relation OIDs identifying the relation.
buffer-flush-done
(ForkNumber, BlockNumber, Oid, Oid, Oid)
Probe that fires when a write request is complete. (Note that this just reflects the time to pass the data to the kernel; it's typically not actually been written to disk yet.) The arguments are the same as for buffer-flush-start.
buffer-write-dirty-start
(ForkNumber, BlockNumber, Oid, Oid, Oid)
Probe that fires when a server process begins to write a dirty buffer. (If this happens often, it implies that shared_buffers is too small or the background writer control parameters need adjustment.) arg0 and arg1 contain the fork and block numbers of the page. arg2, arg3, and arg4 contain the tablespace, database, and relation OIDs identifying the relation.
buffer-write-dirty-done
(ForkNumber, BlockNumber, Oid, Oid, Oid)
Probe that fires when a dirty-buffer write is complete. The arguments are the same as for buffer-write-dirty-start.
wal-buffer-write-dirty-start
()
Probe that fires when a server process begins to write a dirty WAL buffer because no more WAL buffer space is available. (If this happens often, it implies that wal_buffers is too small.)
wal-buffer-write-dirty-done
()
Probe that fires when a dirty WAL buffer write is complete.
wal-insert
(unsigned char, unsigned char)
Probe that fires when a WAL record is inserted. arg0 is the resource manager (rmid) for the record. arg1 contains the info flags.
wal-switch
()
Probe that fires when a WAL segment switch is requested.
smgr-md-read-start
(ForkNumber, BlockNumber, Oid, Oid, Oid, int)
Probe that fires when beginning to read a block from a relation. arg0 and arg1 contain the fork and block numbers of the page. arg2, arg3, and arg4 contain the tablespace, database, and relation OIDs identifying the relation. arg5 is the ID of the backend which created the temporary relation for a local buffer, or InvalidBackendId (-1) for a shared buffer.
smgr-md-read-done
(ForkNumber, BlockNumber, Oid, Oid, Oid, int, int, int)
Probe that fires when a block read is complete. arg0 and arg1 contain the fork and block numbers of the page. arg2, arg3, and arg4 contain the tablespace, database, and relation OIDs identifying the relation. arg5 is the ID of the backend which created the temporary relation for a local buffer, or InvalidBackendId (-1) for a shared buffer. arg6 is the number of bytes actually read, while arg7 is the number requested (if these are different it indicates trouble).
smgr-md-write-start
(ForkNumber, BlockNumber, Oid, Oid, Oid, int)
Probe that fires when beginning to write a block to a relation. arg0 and arg1 contain the fork and block numbers of the page. arg2, arg3, and arg4 contain the tablespace, database, and relation OIDs identifying the relation. arg5 is the ID of the backend which created the temporary relation for a local buffer, or InvalidBackendId (-1) for a shared buffer.
smgr-md-write-done
(ForkNumber, BlockNumber, Oid, Oid, Oid, int, int, int)
Probe that fires when a block write is complete. arg0 and arg1 contain the fork and block numbers of the page. arg2, arg3, and arg4 contain the tablespace, database, and relation OIDs identifying the relation. arg5 is the ID of the backend which created the temporary relation for a local buffer, or InvalidBackendId (-1) for a shared buffer. arg6 is the number of bytes actually written, while arg7 is the number requested (if these are different it indicates trouble).
sort-start
(int, bool, int, int, bool, int)
Probe that fires when a sort operation is started. arg0 indicates heap, index or datum sort. arg1 is true for unique-value enforcement. arg2 is the number of key columns. arg3 is the number of kilobytes of work memory allowed. arg4 is true if random access to the sort result is required. arg5 indicates serial when 0, parallel worker when 1, or parallel leader when 2.
sort-done
(bool, long)
Probe that fires when a sort is complete. arg0 is true for external sort, false for internal sort. arg1 is the number of disk blocks used for an external sort, or kilobytes of memory used for an internal sort.
lwlock-acquire
(char *, LWLockMode)
Probe that fires when an LWLock has been acquired. arg0 is the LWLock's tranche. arg1 is the requested lock mode, either exclusive or shared.
lwlock-release
(char *)
Probe that fires when an LWLock has been released (but note that any released waiters have not yet been awakened). arg0 is the LWLock's tranche.
lwlock-wait-start
(char *, LWLockMode)
Probe that fires when an LWLock was not immediately available and a server process has begun to wait for the lock to become available. arg0 is the LWLock's tranche. arg1 is the requested lock mode, either exclusive or shared.
lwlock-wait-done
(char *, LWLockMode)
Probe that fires when a server process has been released from its wait for an LWLock (it does not actually have the lock yet). arg0 is the LWLock's tranche. arg1 is the requested lock mode, either exclusive or shared.
lwlock-condacquire
(char *, LWLockMode)
Probe that fires when an LWLock was successfully acquired when the caller specified no waiting. arg0 is the LWLock's tranche. arg1 is the requested lock mode, either exclusive or shared.
lwlock-condacquire-fail
(char *, LWLockMode)
Probe that fires when an LWLock was not successfully acquired when the caller specified no waiting. arg0 is the LWLock's tranche. arg1 is the requested lock mode, either exclusive or shared.
lock-wait-start
(unsigned int, unsigned int, unsigned int, unsigned int, unsigned int, LOCKMODE)
Probe that fires when a request for a heavyweight lock (lmgr lock) has begun to wait because the lock is not available. arg0 through arg3 are the tag fields identifying the object being locked. arg4 indicates the type of object being locked. arg5 indicates the lock type being requested.
lock-wait-done
(unsigned int, unsigned int, unsigned int, unsigned int, unsigned int, LOCKMODE)
Probe that fires when a request for a heavyweight lock (lmgr lock) has finished waiting (i.e., has acquired the lock). The arguments are the same as for lock-wait-start.
deadlock-found
()
Probe that fires when a deadlock is found by the deadlock detector.
LocalTransactionId
unsigned int
LWLockMode
int
LOCKMODE
int
BlockNumber
unsigned int
Oid
unsigned int
ForkNumber
int
bool
unsigned char
On most Unix platforms, PostgreSQL modifies its command title as reported by ps, so that individual server processes can readily be identified. A sample display is
(The appropriate invocation of ps varies across different platforms, as do the details of what is shown. This example is from a recent Linux system.) The first process listed here is the primary server process. The command arguments shown for it are the same ones used when it was launched. The next four processes are background worker processes automatically launched by the primary process. (The “autovacuum launcher” process will not be present if you have set the system not to run autovacuum.) Each of the remaining processes is a server process handling one client connection. Each such process sets its command line display in the form
The user, database, and (client) host items remain the same for the life of the client connection, but the activity indicator changes. The activity can be idle (i.e., waiting for a client command), idle in transaction (waiting for client inside a BEGIN block), or a command type name such as SELECT. Also, waiting is appended if the server process is presently waiting on a lock held by another session. In the above example we can infer that process 15606 is waiting for process 15610 to complete its transaction and thereby release some lock. (Process 15610 must be the blocker, because there is no other active session. In more complicated cases it would be necessary to look into the pg_locks system view to determine who is blocking whom.)
If cluster_name has been configured the cluster name will also be shown in ps output:
If you have turned off update_process_title then the activity indicator is not updated; the process title is set only once when a new process is launched. On some platforms this saves a measurable amount of per-command overhead; on others it's insignificant.
Solaris requires special handling. You must use /usr/ucb/ps, rather than /bin/ps. You also must use two w flags, not just one. In addition, your original invocation of the postgres command must have a shorter ps status display than that provided by each server process. If you fail to do all three things, the ps output for each server process will be the original postgres command line.
PostgreSQL's cumulative statistics system supports collection and reporting of information about server activity. Presently, accesses to tables and indexes in both disk-block and individual-row terms are counted. The total number of rows in each table, and information about vacuum and analyze actions for each table are also counted. If enabled, calls to user-defined functions and the total time spent in each one are counted as well.
PostgreSQL also supports reporting dynamic information about exactly what is going on in the system right now, such as the exact command currently being executed by other server processes, and which other connections exist in the system. This facility is independent of the cumulative statistics system.
Since collection of statistics adds some overhead to query execution, the system can be configured to collect or not collect information. This is controlled by configuration parameters that are normally set in postgresql.conf. (See for details about setting configuration parameters.)
The parameter enables monitoring of the current command being executed by any server process.
The parameter controls whether cumulative statistics are collected about table and index accesses.
The parameter enables tracking of usage of user-defined functions.
The parameter enables monitoring of block read and write times.
The parameter enables monitoring of WAL write times.
Normally these parameters are set in postgresql.conf so that they apply to all server processes, but it is possible to turn them on or off in individual sessions using the command. (To prevent ordinary users from hiding their activity from the administrator, only superusers are allowed to change these parameters with SET.)
Cumulative statistics are collected in shared memory. Every PostgreSQL process collects statistics locally, then updates the shared data at appropriate intervals. When a server, including a physical replica, shuts down cleanly, a permanent copy of the statistics data is stored in the pg_stat subdirectory, so that statistics can be retained across server restarts. In contrast, when starting from an unclean shutdown (e.g., after an immediate shutdown, a server crash, starting from a base backup, and point-in-time recovery), all statistics counters are reset.
Several predefined views, listed in , are available to show the current state of the system. There are also several other views, listed in , available to show the accumulated statistics. Alternatively, one can build custom views using the underlying cumulative statistics functions, as discussed in .
When using the cumulative statistics views and functions to monitor collected data, it is important to realize that the information does not update instantaneously. Each individual server process flushes out accumulated statistics to shared memory just before going idle, but not more frequently than once per PGSTAT_MIN_INTERVAL milliseconds (1 second unless altered while building the server); so a query or transaction still in progress does not affect the displayed totals and the displayed information lags behind actual activity. However, current-query information collected by track_activities is always up-to-date.
Another important point is that when a server process is asked to display any of the accumulated statistics, accessed values are cached until the end of its current transaction in the default configuration. So the statistics will show static information as long as you continue the current transaction. Similarly, information about the current queries of all sessions is collected when any such information is first requested within a transaction, and the same information will be displayed throughout the transaction. This is a feature, not a bug, because it allows you to perform several queries on the statistics and correlate the results without worrying that the numbers are changing underneath you. When analyzing statistics interactively, or with expensive queries, the time delta between accesses to individual statistics can lead to significant skew in the cached statistics. To minimize skew, stats_fetch_consistency can be set to snapshot, at the price of increased memory usage for caching not-needed statistics data. Conversely, if it's known that statistics are only accessed once, caching accessed statistics is unnecessary and can be avoided by setting stats_fetch_consistency to none. You can invoke pg_stat_clear_snapshot() to discard the current transaction's statistics snapshot or cached values (if any). The next use of statistical information will (when in snapshot mode) cause a new snapshot to be built or (when in cache mode) accessed statistics to be cached.
A transaction can also see its own statistics (not yet flushed out to the shared memory statistics) in the views pg_stat_xact_all_tables, pg_stat_xact_sys_tables, pg_stat_xact_user_tables, and pg_stat_xact_user_functions. These numbers do not act as stated above; instead they update continuously throughout the transaction.
The per-index statistics are particularly useful to determine which indexes are being used and how effective they are.
The pg_statio_ views are primarily useful to determine the effectiveness of the buffer cache. When the number of actual disk reads is much smaller than the number of buffer hits, then the cache is satisfying most read requests without invoking a kernel call. However, these statistics do not give the entire story: due to the way in which PostgreSQL handles disk I/O, data that is not in the PostgreSQL buffer cache might still reside in the kernel's I/O cache, and might therefore still be fetched without requiring a physical read. Users interested in obtaining more detailed information on PostgreSQL I/O behavior are advised to use the PostgreSQL statistics views in combination with operating system utilities that allow insight into the kernel's handling of I/O.
pg_stat_activityThe pg_stat_activity view will have one row per server process, showing information related to the current activity of that process.
pg_stat_activity ViewThe wait_event and state columns are independent. If a backend is in the active state, it may or may not be waiting on some event. If the state is active and wait_event is non-null, it means that a query is being executed, but is being blocked somewhere in the system.
ActivityBufferPinClientExtensionIOIPCLockLWLockTimeoutHere is an example of how wait events can be viewed:
pg_stat_replicationThe pg_stat_replication view will contain one row per WAL sender process, showing statistics about replication to that sender's connected standby server. Only directly connected standbys are listed; no information is available about downstream standby servers.
pg_stat_replication ViewThe lag times reported in the pg_stat_replication view are measurements of the time taken for recent WAL to be written, flushed and replayed and for the sender to know about it. These times represent the commit delay that was (or would have been) introduced by each synchronous commit level, if the remote server was configured as a synchronous standby. For an asynchronous standby, the replay_lag column approximates the delay before recent transactions became visible to queries. If the standby server has entirely caught up with the sending server and there is no more WAL activity, the most recently measured lag times will continue to be displayed for a short time and then show NULL.
Lag times work automatically for physical replication. Logical decoding plugins may optionally emit tracking messages; if they do not, the tracking mechanism will simply display NULL lag.
The reported lag times are not predictions of how long it will take for the standby to catch up with the sending server assuming the current rate of replay. Such a system would show similar times while new WAL is being generated, but would differ when the sender becomes idle. In particular, when the standby has caught up completely, pg_stat_replication shows the time taken to write, flush and replay the most recent reported WAL location rather than zero as some users might expect. This is consistent with the goal of measuring synchronous commit and transaction visibility delays for recent write transactions. To reduce confusion for users expecting a different model of lag, the lag columns revert to NULL after a short time on a fully replayed idle system. Monitoring systems should choose whether to represent this as missing data, zero or continue to display the last known value.
pg_stat_replication_slotsThe pg_stat_replication_slots view will contain one row per logical replication slot, showing statistics about its usage.
pg_stat_replication_slots Viewpg_stat_wal_receiverThe pg_stat_wal_receiver view will contain only one row, showing statistics about the WAL receiver from that receiver's connected server.
pg_stat_wal_receiver Viewpg_stat_recovery_prefetchThe pg_stat_recovery_prefetch view will contain only one row. The columns wal_distance, block_distance and io_depth show current values, and the other columns show cumulative counters that can be reset with the pg_stat_reset_shared function.
pg_stat_recovery_prefetch Viewpg_stat_subscriptionpg_stat_subscription Viewpg_stat_subscription_statsThe pg_stat_subscription_stats view will contain one row per subscription.
pg_stat_subscription_stats Viewpg_stat_sslThe pg_stat_ssl view will contain one row per backend or WAL sender process, showing statistics about SSL usage on this connection. It can be joined to pg_stat_activity or pg_stat_replication on the pid column to get more details about the connection.
pg_stat_ssl Viewpg_stat_gssapiThe pg_stat_gssapi view will contain one row per backend, showing information about GSSAPI usage on this connection. It can be joined to pg_stat_activity or pg_stat_replication on the pid column to get more details about the connection.
pg_stat_gssapi Viewpg_stat_archiverThe pg_stat_archiver view will always have a single row, containing data about the archiver process of the cluster.
pg_stat_archiver ViewNormally, WAL files are archived in order, oldest to newest, but that is not guaranteed, and does not hold under special circumstances like when promoting a standby or after crash recovery. Therefore it is not safe to assume that all files older than last_archived_wal have also been successfully archived.
pg_stat_bgwriterThe pg_stat_bgwriter view will always have a single row, containing global data for the cluster.
pg_stat_bgwriter Viewpg_stat_walThe pg_stat_wal view will always have a single row, containing data about WAL activity of the cluster.
pg_stat_wal Viewpg_stat_databaseThe pg_stat_database view will contain one row for each database in the cluster, plus one for shared objects, showing database-wide statistics.
pg_stat_database Viewpg_stat_database_conflictsThe pg_stat_database_conflicts view will contain one row per database, showing database-wide statistics about query cancels occurring due to conflicts with recovery on standby servers. This view will only contain information on standby servers, since conflicts do not occur on primary servers.
pg_stat_database_conflicts Viewpg_stat_all_tablesThe pg_stat_all_tables view will contain one row for each table in the current database (including TOAST tables), showing statistics about accesses to that specific table. The pg_stat_user_tables and pg_stat_sys_tables views contain the same information, but filtered to only show user and system tables respectively.
pg_stat_all_tables Viewpg_stat_all_indexesThe pg_stat_all_indexes view will contain one row for each index in the current database, showing statistics about accesses to that specific index. The pg_stat_user_indexes and pg_stat_sys_indexes views contain the same information, but filtered to only show user and system indexes respectively.
pg_stat_all_indexes ViewIndexes can be used by simple index scans, “bitmap” index scans, and the optimizer. In a bitmap scan the output of several indexes can be combined via AND or OR rules, so it is difficult to associate individual heap row fetches with specific indexes when a bitmap scan is used. Therefore, a bitmap scan increments the pg_stat_all_indexes.idx_tup_read count(s) for the index(es) it uses, and it increments the pg_stat_all_tables.idx_tup_fetch count for the table, but it does not affect pg_stat_all_indexes.idx_tup_fetch. The optimizer also accesses indexes to check for supplied constants whose values are outside the recorded range of the optimizer statistics because the optimizer statistics might be stale.
The idx_tup_read and idx_tup_fetch counts can be different even without any use of bitmap scans, because idx_tup_read counts index entries retrieved from the index while idx_tup_fetch counts live rows fetched from the table. The latter will be less if any dead or not-yet-committed rows are fetched using the index, or if any heap fetches are avoided by means of an index-only scan.
pg_statio_all_tablesThe pg_statio_all_tables view will contain one row for each table in the current database (including TOAST tables), showing statistics about I/O on that specific table. The pg_statio_user_tables and pg_statio_sys_tables views contain the same information, but filtered to only show user and system tables respectively.
pg_statio_all_tables Viewpg_statio_all_indexesThe pg_statio_all_indexes view will contain one row for each index in the current database, showing statistics about I/O on that specific index. The pg_statio_user_indexes and pg_statio_sys_indexes views contain the same information, but filtered to only show user and system indexes respectively.
pg_statio_all_indexes Viewpg_statio_all_sequencesThe pg_statio_all_sequences view will contain one row for each sequence in the current database, showing statistics about I/O on that specific sequence.
pg_statio_all_sequences Viewpg_stat_user_functionspg_stat_user_functions Viewpg_stat_slruPostgreSQL accesses certain on-disk information via SLRU (simple least-recently-used) caches. The pg_stat_slru view will contain one row for each tracked SLRU cache, showing statistics about access to cached pages.
pg_stat_slru ViewOther ways of looking at the statistics can be set up by writing queries that use the same underlying statistics access functions used by the standard views shown above. For details such as the functions' names, consult the definitions of the standard views. (For example, in psql you could issue \d+ pg_stat_activity.) The access functions for per-database statistics take a database OID as an argument to identify which database to report on. The per-table and per-index functions take a table or index OID. The functions for per-function statistics take a function OID. Note that only tables, indexes, and functions in the current database can be seen with these functions.
Using pg_stat_reset() also resets counters that autovacuum uses to determine when to trigger a vacuum or an analyze. Resetting these counters can cause autovacuum to not perform necessary work, which can cause problems such as table bloat or out-dated table statistics. A database-wide ANALYZE is recommended after the statistics have been reset.
Some of the information in the dynamic statistics views shown in is security restricted. Ordinary users can only see all the information about their own sessions (sessions belonging to a role that they are a member of). In rows about other sessions, many columns will be null. Note, however, that the existence of a session and its general properties such as its sessions user and database are visible to all users. Superusers and roles with privileges of built-in role pg_read_all_stats (see also ) can see all the information about all sessions.
| View Name | Description |
|---|
| View Name | Description |
|---|
| Wait Event Type | Description |
|---|
Extensions can add LWLock types to the list shown in . In some cases, the name assigned by an extension will not be available in all server processes; so an LWLock wait event might be reported as just “extension” rather than the extension-assigned name.
The pg_stat_user_functions view will contain one row for each tracked function, showing statistics about executions of that function. The parameter controls exactly which functions are tracked.
Additional functions related to the cumulative statistics system are listed in .
pg_stat_get_activity, the underlying function of the pg_stat_activity view, returns a set of records containing all the available information about each backend process. Sometimes it may be more convenient to obtain just a subset of this information. In such cases, an older set of per-backend statistics access functions can be used; these are shown in . These access functions use a backend ID number, which ranges from one to the number of currently active backends. The function pg_stat_get_backend_idset provides a convenient way to generate one row for each active backend for invoking these functions. For example, to show the PIDs and current queries of all backends:
| Description |
| Waiting in main loop of archiver process. |
| Waiting in main loop of autovacuum launcher process. |
| Waiting in background writer process, hibernating. |
| Waiting in main loop of background writer process. |
| Waiting in main loop of checkpointer process. |
| Waiting in main loop of logical replication apply process. |
| Waiting in main loop of logical replication launcher process. |
| Waiting in main loop of startup process for WAL to arrive, during streaming recovery. |
| Waiting in main loop of syslogger process. |
| Waiting in main loop of WAL receiver process. |
| Waiting in main loop of WAL sender process. |
| Waiting in main loop of WAL writer process. |
| Description |
| Waiting to acquire an exclusive pin on a buffer. |
| Description |
| Waiting to read data from the client. |
| Waiting to write data to the client. |
| Waiting to read data from the client while establishing a GSSAPI session. |
| Waiting in WAL receiver to establish connection to remote server. |
| Waiting in WAL receiver to receive data from remote server. |
| Waiting for SSL while attempting connection. |
| Waiting for WAL to be flushed in WAL sender process. |
| Waiting for any activity when processing replies from WAL receiver in WAL sender process. |
| Description |
| Waiting in an extension. |
| Description |
| Waiting for base backup to read from a file. |
| Waiting for a read from a buffered file. |
| Waiting for a write to a buffered file. |
| Waiting for a buffered file to be truncated. |
| Waiting for a read from the |
| Waiting for the |
| Waiting for an update to the |
| Waiting for a write to the |
| Waiting for a write to update the |
| Waiting for a read during a file copy operation. |
| Waiting for a write during a file copy operation. |
| Waiting to fill a dynamic shared memory backing file with zeroes. |
| Waiting for a relation data file to be extended. |
| Waiting for a relation data file to reach durable storage. |
| Waiting for an immediate synchronization of a relation data file to durable storage. |
| Waiting for an asynchronous prefetch from a relation data file. |
| Waiting for a read from a relation data file. |
| Waiting for changes to a relation data file to reach durable storage. |
| Waiting for a relation data file to be truncated. |
| Waiting for a write to a relation data file. |
| Waiting for a read while adding a line to the data directory lock file. |
| Waiting for data to reach durable storage while adding a line to the data directory lock file. |
| Waiting for a write while adding a line to the data directory lock file. |
| Waiting to read while creating the data directory lock file. |
| Waiting for data to reach durable storage while creating the data directory lock file. |
| Waiting for a write while creating the data directory lock file. |
| Waiting for a read during recheck of the data directory lock file. |
| Waiting for logical rewrite mappings to reach durable storage during a checkpoint. |
| Waiting for mapping data to reach durable storage during a logical rewrite. |
| Waiting for a write of mapping data during a logical rewrite. |
| Waiting for logical rewrite mappings to reach durable storage. |
| Waiting for truncate of mapping data during a logical rewrite. |
| Waiting for a write of logical rewrite mappings. |
| Waiting for a read of the relation map file. |
| Waiting for the relation map file to reach durable storage. |
| Waiting for a write to the relation map file. |
| Waiting for a read during reorder buffer management. |
| Waiting for a write during reorder buffer management. |
| Waiting for a read of a logical mapping during reorder buffer management. |
| Waiting for a read from a replication slot control file. |
| Waiting for a replication slot control file to reach durable storage while restoring it to memory. |
| Waiting for a replication slot control file to reach durable storage. |
| Waiting for a write to a replication slot control file. |
| Waiting for SLRU data to reach durable storage during a checkpoint or database shutdown. |
| Waiting for a read of an SLRU page. |
| Waiting for SLRU data to reach durable storage following a page write. |
| Waiting for a write of an SLRU page. |
| Waiting for a read of a serialized historical catalog snapshot. |
| Waiting for a serialized historical catalog snapshot to reach durable storage. |
| Waiting for a write of a serialized historical catalog snapshot. |
| Waiting for a timeline history file received via streaming replication to reach durable storage. |
| Waiting for a write of a timeline history file received via streaming replication. |
| Waiting for a read of a timeline history file. |
| Waiting for a newly created timeline history file to reach durable storage. |
| Waiting for a write of a newly created timeline history file. |
| Waiting for a read of a two phase state file. |
| Waiting for a two phase state file to reach durable storage. |
| Waiting for a write of a two phase state file. |
| Waiting for the version file to be written while creating a database. |
| Waiting for WAL to reach durable storage during bootstrapping. |
| Waiting for a write of a WAL page during bootstrapping. |
| Waiting for a read when creating a new WAL segment by copying an existing one. |
| Waiting for a new WAL segment created by copying an existing one to reach durable storage. |
| Waiting for a write when creating a new WAL segment by copying an existing one. |
| Waiting for a newly initialized WAL file to reach durable storage. |
| Waiting for a write while initializing a new WAL file. |
| Waiting for a read from a WAL file. |
| Waiting for a read from a timeline history file during a walsender timeline command. |
| Waiting for a WAL file to reach durable storage. |
| Waiting for data to reach durable storage while assigning a new WAL sync method. |
| Waiting for a write to a WAL file. |
| Description |
| Waiting to acquire an advisory user lock. |
| Waiting to extend a relation. |
| Waiting to update |
| Waiting to acquire a lock on a non-relation database object. |
| Waiting to acquire a lock on a page of a relation. |
| Waiting to acquire a lock on a relation. |
| Waiting to acquire a speculative insertion lock. |
| Waiting for a transaction to finish. |
| Waiting to acquire a lock on a tuple. |
| Waiting to acquire a user lock. |
| Waiting to acquire a virtual transaction ID lock. |
| Description |
| Waiting to manage an extension's space allocation in shared memory. |
| Waiting to update the |
| Waiting to read or update the current state of autovacuum workers. |
| Waiting to ensure that a table selected for autovacuum still needs vacuuming. |
| Waiting to read or update background worker state. |
| Waiting to read or update vacuum-related information for a B-tree index. |
| Waiting to access a data page in memory. |
| Waiting to associate a data block with a buffer in the buffer pool. |
| Waiting to manage fsync requests. |
| Waiting to read or update the last value set for a transaction commit timestamp. |
| Waiting for I/O on a commit timestamp SLRU buffer. |
| Waiting to access the commit timestamp SLRU cache. |
| Waiting to read or update the |
| Waiting to read or update dynamic shared memory allocation information. |
| Waiting to read or update a process' fast-path lock information. |
| Waiting to read or update information about “heavyweight” locks. |
| Waiting to read or update the state of logical replication workers. |
| Waiting to read or update shared multixact state. |
| Waiting for I/O on a multixact member SLRU buffer. |
| Waiting to access the multixact member SLRU cache. |
| Waiting for I/O on a multixact offset SLRU buffer. |
| Waiting to access the multixact offset SLRU cache. |
| Waiting to read or truncate multixact information. |
| Waiting for I/O on a |
| Waiting to read or update |
| Waiting to update limit on |
| Waiting to access the |
| Waiting to allocate a new OID. |
| Waiting to read or update old snapshot control information. |
| Waiting to choose the next subplan during Parallel Append plan execution. |
| Waiting to synchronize workers during Parallel Hash Join plan execution. |
| Waiting for parallel query dynamic shared memory allocation. |
| Waiting for parallel query dynamic shared memory allocation. |
| Waiting to access a parallel query's information about composite types. |
| Waiting to access a parallel query's information about type modifiers that identify anonymous record types. |
| Waiting to access the list of predicate locks held by the current serializable transaction during a parallel query. |
| Waiting to access predicate lock information used by serializable transactions. |
| Waiting to access the shared per-process data structures (typically, to get a snapshot or report a session's transaction ID). |
| Waiting to read or update a |
| Waiting to read or update a |
| Waiting to create, drop or use a replication origin. |
| Waiting to read or update the progress of one replication origin. |
| Waiting to allocate or free a replication slot. |
| Waiting to read or update replication slot state. |
| Waiting for I/O on a replication slot. |
| Waiting for I/O on a serializable transaction conflict SLRU buffer. |
| Waiting to access the list of finished serializable transactions. |
| Waiting to access the list of predicate locks held by serializable transactions. |
| Waiting for stats dynamic shared memory allocator access |
| Waiting for stats shared memory hash table access |
| Waiting for shared memory stats data access |
| Waiting to read or update information about serializable transactions. |
| Waiting to access the serializable transaction conflict SLRU cache. |
| Waiting to access a shared TID bitmap during a parallel bitmap index scan. |
| Waiting to access a shared tuple store during parallel query. |
| Waiting to find or allocate space in shared memory. |
| Waiting to retrieve messages from the shared catalog invalidation queue. |
| Waiting to add a message to the shared catalog invalidation queue. |
| Waiting for I/O on a sub-transaction SLRU buffer. |
| Waiting to access the sub-transaction SLRU cache. |
| Waiting to read or update information about the state of synchronous replication. |
| Waiting to select the starting location of a synchronized table scan. |
| Waiting to create or drop a tablespace. |
| Waiting to read or update the state of prepared transactions. |
| Waiting to replace a page in WAL buffers. |
| Waiting to insert WAL data into a memory buffer. |
| Waiting for WAL buffers to be written to disk. |
| Waiting to update limits on transaction id and multixact consumption. |
| Waiting for I/O on a transaction status SLRU buffer. |
| Waiting to access the transaction status SLRU cache. |
| Waiting to execute |
| Waiting to allocate a new transaction ID. |
| Description |
| Waiting during base backup when throttling activity. |
| Waiting between writes while performing a checkpoint. |
| Waiting due to a call to |
| Waiting to apply WAL during recovery because of a delay setting. |
| Waiting during recovery when WAL data is not available from any source ( |
| Waiting while sending synchronization requests to the checkpointer, because the request queue is full. |
| Waiting in a cost-based vacuum delay point. |
| Waiting to acquire an exclusive lock to truncate off any empty pages at the end of a table vacuumed. |
Column Type Description |
A unique, cluster-wide identifier for the replication slot |
Number of transactions spilled to disk once the memory used by logical decoding to decode changes from WAL has exceeded |
Number of times transactions were spilled to disk while decoding changes from WAL for this slot. This counter is incremented each time a transaction is spilled, and the same transaction may be spilled multiple times. |
Amount of decoded transaction data spilled to disk while performing decoding of changes from WAL for this slot. This and other spill counters can be used to gauge the I/O which occurred during logical decoding and allow tuning |
Number of in-progress transactions streamed to the decoding output plugin after the memory used by logical decoding to decode changes from WAL for this slot has exceeded |
Number of times in-progress transactions were streamed to the decoding output plugin while decoding changes from WAL for this slot. This counter is incremented each time a transaction is streamed, and the same transaction may be streamed multiple times. |
Amount of transaction data decoded for streaming in-progress transactions to the decoding output plugin while decoding changes from WAL for this slot. This and other streaming counters for this slot can be used to tune |
Number of decoded transactions sent to the decoding output plugin for this slot. This counts top-level transactions only, and is not incremented for subtransactions. Note that this includes the transactions that are streamed and/or spilled. |
Amount of transaction data decoded for sending transactions to the decoding output plugin while decoding changes from WAL for this slot. Note that this includes data that is streamed and/or spilled. |
Time at which these statistics were last reset |
Column Type Description |
Process ID of the WAL receiver process |
Activity status of the WAL receiver process |
First write-ahead log location used when WAL receiver is started |
First timeline number used when WAL receiver is started |
Last write-ahead log location already received and written to disk, but not flushed. This should not be used for data integrity checks. |
Last write-ahead log location already received and flushed to disk, the initial value of this field being the first log location used when WAL receiver is started |
Timeline number of last write-ahead log location received and flushed to disk, the initial value of this field being the timeline number of the first log location used when WAL receiver is started |
Send time of last message received from origin WAL sender |
Receipt time of last message received from origin WAL sender |
Last write-ahead log location reported to origin WAL sender |
Time of last write-ahead log location reported to origin WAL sender |
Replication slot name used by this WAL receiver |
Host of the PostgreSQL instance this WAL receiver is connected to. This can be a host name, an IP address, or a directory path if the connection is via Unix socket. (The path case can be distinguished because it will always be an absolute path, beginning with |
Port number of the PostgreSQL instance this WAL receiver is connected to. |
Connection string used by this WAL receiver, with security-sensitive fields obfuscated. |
Column Type Description |
Time at which these statistics were last reset |
Number of blocks prefetched because they were not in the buffer pool |
Number of blocks not prefetched because they were already in the buffer pool |
Number of blocks not prefetched because they would be zero-initialized |
Number of blocks not prefetched because they didn't exist yet |
Number of blocks not prefetched because a full page image was included in the WAL |
Number of blocks not prefetched because they were already recently prefetched |
How many bytes ahead the prefetcher is looking |
How many blocks ahead the prefetcher is looking |
How many prefetches have been initiated but are not yet known to have completed |
Column Type Description |
OID of the subscription |
Name of the subscription |
Process ID of the subscription worker process |
OID of the relation that the worker is synchronizing; null for the main apply worker |
Last write-ahead log location received, the initial value of this field being 0 |
Send time of last message received from origin WAL sender |
Receipt time of last message received from origin WAL sender |
Last write-ahead log location reported to origin WAL sender |
Time of last write-ahead log location reported to origin WAL sender |
Column Type Description |
OID of the subscription |
Name of the subscription |
Number of times an error occurred while applying changes |
Number of times an error occurred during the initial table synchronization |
Time at which these statistics were last reset |
Column Type Description |
Process ID of a backend or WAL sender process |
True if SSL is used on this connection |
Version of SSL in use, or NULL if SSL is not in use on this connection |
Name of SSL cipher in use, or NULL if SSL is not in use on this connection |
Number of bits in the encryption algorithm used, or NULL if SSL is not used on this connection |
Distinguished Name (DN) field from the client certificate used, or NULL if no client certificate was supplied or if SSL is not in use on this connection. This field is truncated if the DN field is longer than |
Serial number of the client certificate, or NULL if no client certificate was supplied or if SSL is not in use on this connection. The combination of certificate serial number and certificate issuer uniquely identifies a certificate (unless the issuer erroneously reuses serial numbers). |
DN of the issuer of the client certificate, or NULL if no client certificate was supplied or if SSL is not in use on this connection. This field is truncated like |
Column Type Description |
Process ID of a backend |
True if GSSAPI authentication was used for this connection |
Principal used to authenticate this connection, or NULL if GSSAPI was not used to authenticate this connection. This field is truncated if the principal is longer than |
True if GSSAPI encryption is in use on this connection |
Column Type Description |
Number of WAL files that have been successfully archived |
Name of the WAL file most recently successfully archived |
Time of the most recent successful archive operation |
Number of failed attempts for archiving WAL files |
Name of the WAL file of the most recent failed archival operation |
Time of the most recent failed archival operation |
Time at which these statistics were last reset |
Column Type Description |
Number of scheduled checkpoints that have been performed |
Number of requested checkpoints that have been performed |
Total amount of time that has been spent in the portion of checkpoint processing where files are written to disk, in milliseconds |
Total amount of time that has been spent in the portion of checkpoint processing where files are synchronized to disk, in milliseconds |
Number of buffers written during checkpoints |
Number of buffers written by the background writer |
Number of times the background writer stopped a cleaning scan because it had written too many buffers |
Number of buffers written directly by a backend |
Number of times a backend had to execute its own |
Number of buffers allocated |
Time at which these statistics were last reset |
Column Type Description |
OID of a database |
Name of this database |
Number of queries in this database that have been canceled due to dropped tablespaces |
Number of queries in this database that have been canceled due to lock timeouts |
Number of queries in this database that have been canceled due to old snapshots |
Number of queries in this database that have been canceled due to pinned buffers |
Number of queries in this database that have been canceled due to deadlocks |
Column Type Description |
OID of the table for this index |
OID of this index |
Name of the schema this index is in |
Name of the table for this index |
Name of this index |
Number of index scans initiated on this index |
Number of index entries returned by scans on this index |
Number of live table rows fetched by simple index scans using this index |
Column Type Description |
OID of a table |
Name of the schema that this table is in |
Name of this table |
Number of disk blocks read from this table |
Number of buffer hits in this table |
Number of disk blocks read from all indexes on this table |
Number of buffer hits in all indexes on this table |
Number of disk blocks read from this table's TOAST table (if any) |
Number of buffer hits in this table's TOAST table (if any) |
Number of disk blocks read from this table's TOAST table indexes (if any) |
Number of buffer hits in this table's TOAST table indexes (if any) |
Column Type Description |
OID of the table for this index |
OID of this index |
Name of the schema this index is in |
Name of the table for this index |
Name of this index |
Number of disk blocks read from this index |
Number of buffer hits in this index |
Column Type Description |
OID of a sequence |
Name of the schema this sequence is in |
Name of this sequence |
Number of disk blocks read from this sequence |
Number of buffer hits in this sequence |
Column Type Description |
OID of a function |
Name of the schema this function is in |
Name of this function |
Number of times this function has been called |
Total time spent in this function and all other functions called by it, in milliseconds |
Total time spent in this function itself, not including other functions called by it, in milliseconds |
Column Type Description |
Name of the SLRU |
Number of blocks zeroed during initializations |
Number of times disk blocks were found already in the SLRU, so that a read was not necessary (this only includes hits in the SLRU, not the operating system's file system cache) |
Number of disk blocks read for this SLRU |
Number of disk blocks written for this SLRU |
Number of blocks checked for existence for this SLRU |
Number of flushes of dirty data for this SLRU |
Number of truncates for this SLRU |
Time at which these statistics were last reset |
Function Description |
Returns the process ID of the server process attached to the current session. |
Returns a record of information about the backend with the specified process ID, or one record for each active backend in the system if |
Returns the timestamp of the current statistics snapshot, or NULL if no statistics snapshot has been taken. A snapshot is taken the first time cumulative statistics are accessed in a transaction if |
Discards the current statistics snapshot or cached information. |
Resets all statistics counters for the current database to zero. This function is restricted to superusers by default, but other users can be granted EXECUTE to run the function. |
Resets some cluster-wide statistics counters to zero, depending on the argument. The argument can be This function is restricted to superusers by default, but other users can be granted EXECUTE to run the function. |
Resets statistics for a single table or index in the current database or shared across all databases in the cluster to zero. This function is restricted to superusers by default, but other users can be granted EXECUTE to run the function. |
Resets statistics for a single function in the current database to zero. This function is restricted to superusers by default, but other users can be granted EXECUTE to run the function. |
Resets statistics to zero for a single SLRU cache, or for all SLRUs in the cluster. If the argument is NULL, all counters shown in the This function is restricted to superusers by default, but other users can be granted EXECUTE to run the function. |
Resets statistics of the replication slot defined by the argument. If the argument is This function is restricted to superusers by default, but other users can be granted EXECUTE to run the function. |
Resets statistics for a single subscription shown in the This function is restricted to superusers by default, but other users can be granted EXECUTE to run the function. |
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Column Type Description |
OID of the database this backend is connected to |
Name of the database this backend is connected to |
Process ID of this backend |
Process ID of the parallel group leader, if this process is a parallel query worker. |
OID of the user logged into this backend |
Name of the user logged into this backend |
Name of the application that is connected to this backend |
IP address of the client connected to this backend. If this field is null, it indicates either that the client is connected via a Unix socket on the server machine or that this is an internal process such as autovacuum. |
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TCP port number that the client is using for communication with this backend, or |
Time when this process was started. For client backends, this is the time the client connected to the server. |
Time when this process' current transaction was started, or null if no transaction is active. If the current query is the first of its transaction, this column is equal to the |
Time when the currently active query was started, or if |
Time when the |
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Current overall state of this backend. Possible values are:
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Top-level transaction identifier of this backend, if any. |
The current backend's |
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Type of current backend. Possible types are |
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| Description |
| Waiting for subplan nodes of an |
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| Waiting for the termination of another backend. |
| Waiting for WAL files required for a backup to be successfully archived. |
| Waiting for background worker to shut down. |
| Waiting for background worker to start up. |
| Waiting for the page number needed to continue a parallel B-tree scan to become available. |
| Waiting for buffer I/O to complete. |
| Waiting for a checkpoint to complete. |
| Waiting for a checkpoint to start. |
| Waiting for activity from a child process while executing a |
| Waiting for an elected Parallel Hash participant to allocate a hash table. |
| Waiting to elect a Parallel Hash participant to allocate a hash table. |
| Waiting for other Parallel Hash participants to finish loading a hash table. |
| Waiting for an elected Parallel Hash participant to allocate the initial hash table. |
| Waiting to elect a Parallel Hash participant to allocate the initial hash table. |
| Waiting for other Parallel Hash participants to finish hashing the inner relation. |
| Waiting for other Parallel Hash participants to finish partitioning the outer relation. |
| Waiting for an elected Parallel Hash participant to allocate more batches. |
| Waiting to elect a Parallel Hash participant to decide on future batch growth. |
| Waiting to elect a Parallel Hash participant to allocate more batches. |
| Waiting for an elected Parallel Hash participant to decide on future batch growth. |
| Waiting for other Parallel Hash participants to finish repartitioning. |
| Waiting for an elected Parallel Hash participant to finish allocating more buckets. |
| Waiting to elect a Parallel Hash participant to allocate more buckets. |
| Waiting for other Parallel Hash participants to finish inserting tuples into new buckets. |
| Waiting for a logical replication remote server to send data for initial table synchronization. |
| Waiting for a logical replication remote server to change state. |
| Waiting for another process to be attached to a shared message queue. |
| Waiting to write a protocol message to a shared message queue. |
| Waiting to receive bytes from a shared message queue. |
| Waiting to send bytes to a shared message queue. |
| Waiting for parallel bitmap scan to become initialized. |
| Waiting for parallel |
| Waiting for parallel workers to finish computing. |
| Waiting for the group leader to clear the transaction ID at end of a parallel operation. |
| Waiting for a barrier event to be processed by all backends. |
| Waiting for standby promotion. |
| Waiting for recovery conflict resolution for a vacuum cleanup. |
| Waiting for recovery conflict resolution for dropping a tablespace. |
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| Waiting for recovery to be resumed. |
| Waiting for a replication origin to become inactive so it can be dropped. |
| Waiting for a replication slot to become inactive so it can be dropped. |
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| Waiting to obtain a valid snapshot for a |
| Waiting for confirmation from a remote server during synchronous replication. |
| Waiting for the WAL receiver to exit. |
| Waiting for startup process to send initial data for streaming replication. |
| Waiting for the group leader to update transaction status at end of a parallel operation. |
Column Type Description |
Process ID of a WAL sender process |
OID of the user logged into this WAL sender process |
Name of the user logged into this WAL sender process |
Name of the application that is connected to this WAL sender |
IP address of the client connected to this WAL sender. If this field is null, it indicates that the client is connected via a Unix socket on the server machine. |
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TCP port number that the client is using for communication with this WAL sender, or |
Time when this process was started, i.e., when the client connected to this WAL sender |
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Current WAL sender state. Possible values are:
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Last write-ahead log location sent on this connection |
Last write-ahead log location written to disk by this standby server |
Last write-ahead log location flushed to disk by this standby server |
Last write-ahead log location replayed into the database on this standby server |
Time elapsed between flushing recent WAL locally and receiving notification that this standby server has written it (but not yet flushed it or applied it). This can be used to gauge the delay that |
Time elapsed between flushing recent WAL locally and receiving notification that this standby server has written and flushed it (but not yet applied it). This can be used to gauge the delay that |
Time elapsed between flushing recent WAL locally and receiving notification that this standby server has written, flushed and applied it. This can be used to gauge the delay that |
Priority of this standby server for being chosen as the synchronous standby in a priority-based synchronous replication. This has no effect in a quorum-based synchronous replication. |
Synchronous state of this standby server. Possible values are:
|
Send time of last reply message received from standby server |
Column Type Description |
Total number of WAL records generated |
Total number of WAL full page images generated |
Total amount of WAL generated in bytes |
Number of times WAL data was written to disk because WAL buffers became full |
|
|
|
Total amount of time spent syncing WAL files to disk via |
Time at which these statistics were last reset |
Column Type Description |
OID of this database, or 0 for objects belonging to a shared relation |
Name of this database, or |
Number of backends currently connected to this database, or |
Number of transactions in this database that have been committed |
Number of transactions in this database that have been rolled back |
Number of disk blocks read in this database |
Number of times disk blocks were found already in the buffer cache, so that a read was not necessary (this only includes hits in the PostgreSQL buffer cache, not the operating system's file system cache) |
Number of live rows fetched by sequential scans and index entries returned by index scans in this database |
Number of live rows fetched by index scans in this database |
Number of rows inserted by queries in this database |
Number of rows updated by queries in this database |
Number of rows deleted by queries in this database |
|
|
|
Number of deadlocks detected in this database |
Number of data page checksum failures detected in this database (or on a shared object), or NULL if data checksums are not enabled. |
Time at which the last data page checksum failure was detected in this database (or on a shared object), or NULL if data checksums are not enabled. |
|
|
Time spent by database sessions in this database, in milliseconds (note that statistics are only updated when the state of a session changes, so if sessions have been idle for a long time, this idle time won't be included) |
|
|
Total number of sessions established to this database |
Number of database sessions to this database that were terminated because connection to the client was lost |
Number of database sessions to this database that were terminated by fatal errors |
Number of database sessions to this database that were terminated by operator intervention |
Time at which these statistics were last reset |
Column Type Description |
OID of a table |
Name of the schema that this table is in |
Name of this table |
Number of sequential scans initiated on this table |
Number of live rows fetched by sequential scans |
Number of index scans initiated on this table |
Number of live rows fetched by index scans |
Number of rows inserted |
|
Number of rows deleted |
Number of rows HOT updated (i.e., with no separate index update required) |
Estimated number of live rows |
Estimated number of dead rows |
Estimated number of rows modified since this table was last analyzed |
Estimated number of rows inserted since this table was last vacuumed |
Last time at which this table was manually vacuumed (not counting |
Last time at which this table was vacuumed by the autovacuum daemon |
Last time at which this table was manually analyzed |
Last time at which this table was analyzed by the autovacuum daemon |
Number of times this table has been manually vacuumed (not counting |
Number of times this table has been vacuumed by the autovacuum daemon |
Number of times this table has been manually analyzed |
Number of times this table has been analyzed by the autovacuum daemon |
Function Description |
Returns the set of currently active backend ID numbers (from 1 to the number of active backends). |
Returns the text of this backend's most recent query. |
Returns the time when the backend's most recent query was started. |
Returns the IP address of the client connected to this backend. |
Returns the TCP port number that the client is using for communication. |
Returns the OID of the database this backend is connected to. |
Returns the process ID of this backend. |
Returns the time when this process was started. |
Returns the OID of the user logged into this backend. |
|
|
Returns the time when the backend's current transaction was started. |
PostgreSQL has the ability to report the progress of certain commands during command execution. Currently, the only commands which support progress reporting are ANALYZE, CLUSTER, CREATE INDEX, VACUUM, COPY, and BASE_BACKUP (i.e., replication command that pg_basebackup issues to take a base backup). This may be expanded in the future.
Whenever ANALYZE is running, the pg_stat_progress_analyze view will contain a row for each backend that is currently running that command. The tables below describe the information that will be reported and provide information about how to interpret it.
pg_stat_progress_analyze ViewNote that when ANALYZE is run on a partitioned table, all of its partitions are also recursively analyzed. In that case, ANALYZE progress is reported first for the parent table, whereby its inheritance statistics are collected, followed by that for each partition.
Whenever CREATE INDEX or REINDEX is running, the pg_stat_progress_create_index view will contain one row for each backend that is currently creating indexes. The tables below describe the information that will be reported and provide information about how to interpret it.
pg_stat_progress_create_index ViewWhenever VACUUM is running, the pg_stat_progress_vacuum view will contain one row for each backend (including autovacuum worker processes) that is currently vacuuming. The tables below describe the information that will be reported and provide information about how to interpret it. Progress for VACUUM FULL commands is reported via pg_stat_progress_cluster because both VACUUM FULL and CLUSTER rewrite the table, while regular VACUUM only modifies it in place. See Section 28.4.4.
pg_stat_progress_vacuum ViewWhenever CLUSTER or VACUUM FULL is running, the pg_stat_progress_cluster view will contain a row for each backend that is currently running either command. The tables below describe the information that will be reported and provide information about how to interpret it.
pg_stat_progress_cluster ViewWhenever an application like pg_basebackup is taking a base backup, the pg_stat_progress_basebackup view will contain a row for each WAL sender process that is currently running the BASE_BACKUP replication command and streaming the backup. The tables below describe the information that will be reported and provide information about how to interpret it.
pg_stat_progress_basebackup ViewWhenever COPY is running, the pg_stat_progress_copy view will contain one row for each backend that is currently running a COPY command. The table below describes the information that will be reported and provides information about how to interpret it.
pg_stat_progress_copy ViewOne row per server process, showing information related to the current activity of that process, such as state and current query. See for details.
One row per WAL sender process, showing statistics about replication to that sender's connected standby server. See for details.
Only one row, showing statistics about the WAL receiver from that receiver's connected server. See for details.
Only one row, showing statistics about blocks prefetched during recovery. See for details.
At least one row per subscription, showing information about the subscription workers. See for details.
One row per connection (regular and replication), showing information about SSL used on this connection. See for details.
One row per connection (regular and replication), showing information about GSSAPI authentication and encryption used on this connection. See for details.
One row for each backend (including autovacuum worker processes) running ANALYZE, showing current progress. See .
One row for each backend running CREATE INDEX or REINDEX, showing current progress. See .
One row for each backend (including autovacuum worker processes) running VACUUM, showing current progress. See .
One row for each backend running CLUSTER or VACUUM FULL, showing current progress. See .
One row for each WAL sender process streaming a base backup, showing current progress. See .
One row for each backend running COPY, showing current progress. See .
One row only, showing statistics about the WAL archiver process's activity. See for details.
One row only, showing statistics about the background writer process's activity. See for details.
One row only, showing statistics about WAL activity. See for details.
One row per database, showing database-wide statistics. See for details.
One row per database, showing database-wide statistics about query cancels due to conflict with recovery on standby servers. See for details.
One row for each table in the current database, showing statistics about accesses to that specific table. See for details.
One row for each index in the current database, showing statistics about accesses to that specific index. See for details.
One row for each table in the current database, showing statistics about I/O on that specific table. See for details.
One row for each index in the current database, showing statistics about I/O on that specific index. See for details.
One row for each sequence in the current database, showing statistics about I/O on that specific sequence. See for details.
One row for each tracked function, showing statistics about executions of that function. See for details.
One row per SLRU, showing statistics of operations. See for details.
One row per replication slot, showing statistics about the replication slot's usage. See for details.
One row per subscription, showing statistics about errors. See for details.
Host name of the connected client, as reported by a reverse DNS lookup of client_addr. This field will only be non-null for IP connections, and only when is enabled.
The type of event for which the backend is waiting, if any; otherwise NULL. See .
Wait event name if backend is currently waiting, otherwise NULL. See through .
disabled: This state is reported if is disabled in this backend.
Identifier of this backend's most recent query. If state is active this field shows the identifier of the currently executing query. In all other states, it shows the identifier of last query that was executed. Query identifiers are not computed by default so this field will be null unless parameter is enabled or a third-party module that computes query identifiers is configured.
Text of this backend's most recent query. If state is active this field shows the currently executing query. In all other states, it shows the last query that was executed. By default the query text is truncated at 1024 bytes; this value can be changed via the parameter .
The server process is idle. This event type indicates a process waiting for activity in its main processing loop. wait_event will identify the specific wait point; see .
The server process is waiting for exclusive access to a data buffer. Buffer pin waits can be protracted if another process holds an open cursor that last read data from the buffer in question. See .
The server process is waiting for activity on a socket connected to a user application. Thus, the server expects something to happen that is independent of its internal processes. wait_event will identify the specific wait point; see .
The server process is waiting for some condition defined by an extension module. See .
The server process is waiting for an I/O operation to complete. wait_event will identify the specific wait point; see .
The server process is waiting for some interaction with another server process. wait_event will identify the specific wait point; see .
The server process is waiting for a heavyweight lock. Heavyweight locks, also known as lock manager locks or simply locks, primarily protect SQL-visible objects such as tables. However, they are also used to ensure mutual exclusion for certain internal operations such as relation extension. wait_event will identify the type of lock awaited; see .
The server process is waiting for a lightweight lock. Most such locks protect a particular data structure in shared memory. wait_event will contain a name identifying the purpose of the lightweight lock. (Some locks have specific names; others are part of a group of locks each with a similar purpose.) See .
The server process is waiting for a timeout to expire. wait_event will identify the specific wait point; see .
Waiting for to complete.
Waiting for to complete.
Waiting for to complete.
Waiting for to complete.
Host name of the connected client, as reported by a reverse DNS lookup of client_addr. This field will only be non-null for IP connections, and only when is enabled.
This standby's xmin horizon reported by .
Number of times WAL buffers were written out to disk via XLogWrite request. See for more information about the internal WAL function XLogWrite.
Number of times WAL files were synced to disk via issue_xlog_fsync request (if is on and is either fdatasync, fsync or fsync_writethrough, otherwise zero). See for more information about the internal WAL function issue_xlog_fsync.
Total amount of time spent writing WAL buffers to disk via XLogWrite request, in milliseconds (if is enabled, otherwise zero). This includes the sync time when wal_sync_method is either open_datasync or open_sync.
Number of queries canceled due to conflicts with recovery in this database. (Conflicts occur only on standby servers; see for details.)
Number of temporary files created by queries in this database. All temporary files are counted, regardless of why the temporary file was created (e.g., sorting or hashing), and regardless of the setting.
Total amount of data written to temporary files by queries in this database. All temporary files are counted, regardless of why the temporary file was created, and regardless of the setting.
Time spent reading data file blocks by backends in this database, in milliseconds (if is enabled, otherwise zero)
Time spent writing data file blocks by backends in this database, in milliseconds (if is enabled, otherwise zero)
Time spent executing SQL statements in this database, in milliseconds (this corresponds to the states active and fastpath function call in )
Time spent idling while in a transaction in this database, in milliseconds (this corresponds to the states idle in transaction and idle in transaction (aborted) in )
Number of rows updated (includes )
Returns the wait event type name if this backend is currently waiting, otherwise NULL. See for details.
Returns the wait event name if this backend is currently waiting, otherwise NULL. See through .
| Phase | Description |
|---|---|
| Phase | Description |
|---|---|
| Phase | Description |
|---|---|
| Phase | Description |
|---|---|
| Phase | Description |
|---|---|
Column Type
Description
pid integer
Process ID of backend.
datid oid
OID of the database to which this backend is connected.
datname name
Name of the database to which this backend is connected.
relid oid
OID of the table being analyzed.
phase text
Current processing phase. See Table 28.37.
sample_blks_total bigint
Total number of heap blocks that will be sampled.
sample_blks_scanned bigint
Number of heap blocks scanned.
ext_stats_total bigint
Number of extended statistics.
ext_stats_computed bigint
Number of extended statistics computed. This counter only advances when the phase is computing extended statistics.
child_tables_total bigint
Number of child tables.
child_tables_done bigint
Number of child tables scanned. This counter only advances when the phase is acquiring inherited sample rows.
current_child_table_relid oid
OID of the child table currently being scanned. This field is only valid when the phase is acquiring inherited sample rows.
initializing
The command is preparing to begin scanning the heap. This phase is expected to be very brief.
acquiring sample rows
The command is currently scanning the table given by relid to obtain sample rows.
acquiring inherited sample rows
The command is currently scanning child tables to obtain sample rows. Columns child_tables_total, child_tables_done, and current_child_table_relid contain the progress information for this phase.
computing statistics
The command is computing statistics from the sample rows obtained during the table scan.
computing extended statistics
The command is computing extended statistics from the sample rows obtained during the table scan.
finalizing analyze
The command is updating pg_class. When this phase is completed, ANALYZE will end.
Column Type
Description
pid integer
Process ID of backend.
datid oid
OID of the database to which this backend is connected.
datname name
Name of the database to which this backend is connected.
relid oid
OID of the table on which the index is being created.
index_relid oid
OID of the index being created or reindexed. During a non-concurrent CREATE INDEX, this is 0.
command text
The command that is running: CREATE INDEX, CREATE INDEX CONCURRENTLY, REINDEX, or REINDEX CONCURRENTLY.
phase text
Current processing phase of index creation. See Table 28.39.
lockers_total bigint
Total number of lockers to wait for, when applicable.
lockers_done bigint
Number of lockers already waited for.
current_locker_pid bigint
Process ID of the locker currently being waited for.
blocks_total bigint
Total number of blocks to be processed in the current phase.
blocks_done bigint
Number of blocks already processed in the current phase.
tuples_total bigint
Total number of tuples to be processed in the current phase.
tuples_done bigint
Number of tuples already processed in the current phase.
partitions_total bigint
When creating an index on a partitioned table, this column is set to the total number of partitions on which the index is to be created. This field is 0 during a REINDEX.
partitions_done bigint
When creating an index on a partitioned table, this column is set to the number of partitions on which the index has been created. This field is 0 during a REINDEX.
initializing
CREATE INDEX or REINDEX is preparing to create the index. This phase is expected to be very brief.
waiting for writers before build
CREATE INDEX CONCURRENTLY or REINDEX CONCURRENTLY is waiting for transactions with write locks that can potentially see the table to finish. This phase is skipped when not in concurrent mode. Columns lockers_total, lockers_done and current_locker_pid contain the progress information for this phase.
building index
The index is being built by the access method-specific code. In this phase, access methods that support progress reporting fill in their own progress data, and the subphase is indicated in this column. Typically, blocks_total and blocks_done will contain progress data, as well as potentially tuples_total and tuples_done.
waiting for writers before validation
CREATE INDEX CONCURRENTLY or REINDEX CONCURRENTLY is waiting for transactions with write locks that can potentially write into the table to finish. This phase is skipped when not in concurrent mode. Columns lockers_total, lockers_done and current_locker_pid contain the progress information for this phase.
index validation: scanning index
CREATE INDEX CONCURRENTLY is scanning the index searching for tuples that need to be validated. This phase is skipped when not in concurrent mode. Columns blocks_total (set to the total size of the index) and blocks_done contain the progress information for this phase.
index validation: sorting tuples
CREATE INDEX CONCURRENTLY is sorting the output of the index scanning phase.
index validation: scanning table
CREATE INDEX CONCURRENTLY is scanning the table to validate the index tuples collected in the previous two phases. This phase is skipped when not in concurrent mode. Columns blocks_total (set to the total size of the table) and blocks_done contain the progress information for this phase.
waiting for old snapshots
CREATE INDEX CONCURRENTLY or REINDEX CONCURRENTLY is waiting for transactions that can potentially see the table to release their snapshots. This phase is skipped when not in concurrent mode. Columns lockers_total, lockers_done and current_locker_pid contain the progress information for this phase.
waiting for readers before marking dead
REINDEX CONCURRENTLY is waiting for transactions with read locks on the table to finish, before marking the old index dead. This phase is skipped when not in concurrent mode. Columns lockers_total, lockers_done and current_locker_pid contain the progress information for this phase.
waiting for readers before dropping
REINDEX CONCURRENTLY is waiting for transactions with read locks on the table to finish, before dropping the old index. This phase is skipped when not in concurrent mode. Columns lockers_total, lockers_done and current_locker_pid contain the progress information for this phase.
Column Type
Description
pid integer
Process ID of backend.
datid oid
OID of the database to which this backend is connected.
datname name
Name of the database to which this backend is connected.
relid oid
OID of the table being vacuumed.
phase text
Current processing phase of vacuum. See Table 28.41.
heap_blks_total bigint
Total number of heap blocks in the table. This number is reported as of the beginning of the scan; blocks added later will not be (and need not be) visited by this VACUUM.
heap_blks_scanned bigint
Number of heap blocks scanned. Because the visibility map is used to optimize scans, some blocks will be skipped without inspection; skipped blocks are included in this total, so that this number will eventually become equal to heap_blks_total when the vacuum is complete. This counter only advances when the phase is scanning heap.
heap_blks_vacuumed bigint
Number of heap blocks vacuumed. Unless the table has no indexes, this counter only advances when the phase is vacuuming heap. Blocks that contain no dead tuples are skipped, so the counter may sometimes skip forward in large increments.
index_vacuum_count bigint
Number of completed index vacuum cycles.
max_dead_tuples bigint
Number of dead tuples that we can store before needing to perform an index vacuum cycle, based on maintenance_work_mem.
num_dead_tuples bigint
Number of dead tuples collected since the last index vacuum cycle.
initializing
VACUUM is preparing to begin scanning the heap. This phase is expected to be very brief.
scanning heap
VACUUM is currently scanning the heap. It will prune and defragment each page if required, and possibly perform freezing activity. The heap_blks_scanned column can be used to monitor the progress of the scan.
vacuuming indexes
VACUUM is currently vacuuming the indexes. If a table has any indexes, this will happen at least once per vacuum, after the heap has been completely scanned. It may happen multiple times per vacuum if maintenance_work_mem (or, in the case of autovacuum, autovacuum_work_mem if set) is insufficient to store the number of dead tuples found.
vacuuming heap
VACUUM is currently vacuuming the heap. Vacuuming the heap is distinct from scanning the heap, and occurs after each instance of vacuuming indexes. If heap_blks_scanned is less than heap_blks_total, the system will return to scanning the heap after this phase is completed; otherwise, it will begin cleaning up indexes after this phase is completed.
cleaning up indexes
VACUUM is currently cleaning up indexes. This occurs after the heap has been completely scanned and all vacuuming of the indexes and the heap has been completed.
truncating heap
VACUUM is currently truncating the heap so as to return empty pages at the end of the relation to the operating system. This occurs after cleaning up indexes.
performing final cleanup
VACUUM is performing final cleanup. During this phase, VACUUM will vacuum the free space map, update statistics in pg_class, and report statistics to the cumulative statistics system. When this phase is completed, VACUUM will end.
Column Type
Description
pid integer
Process ID of backend.
datid oid
OID of the database to which this backend is connected.
datname name
Name of the database to which this backend is connected.
relid oid
OID of the table being clustered.
command text
The command that is running. Either CLUSTER or VACUUM FULL.
phase text
Current processing phase. See Table 28.43.
cluster_index_relid oid
If the table is being scanned using an index, this is the OID of the index being used; otherwise, it is zero.
heap_tuples_scanned bigint
Number of heap tuples scanned. This counter only advances when the phase is seq scanning heap, index scanning heap or writing new heap.
heap_tuples_written bigint
Number of heap tuples written. This counter only advances when the phase is seq scanning heap, index scanning heap or writing new heap.
heap_blks_total bigint
Total number of heap blocks in the table. This number is reported as of the beginning of seq scanning heap.
heap_blks_scanned bigint
Number of heap blocks scanned. This counter only advances when the phase is seq scanning heap.
index_rebuild_count bigint
Number of indexes rebuilt. This counter only advances when the phase is rebuilding index.
initializing
The command is preparing to begin scanning the heap. This phase is expected to be very brief.
seq scanning heap
The command is currently scanning the table using a sequential scan.
index scanning heap
CLUSTER is currently scanning the table using an index scan.
sorting tuples
CLUSTER is currently sorting tuples.
writing new heap
CLUSTER is currently writing the new heap.
swapping relation files
The command is currently swapping newly-built files into place.
rebuilding index
The command is currently rebuilding an index.
performing final cleanup
The command is performing final cleanup. When this phase is completed, CLUSTER or VACUUM FULL will end.
Column Type
Description
pid integer
Process ID of a WAL sender process.
phase text
Current processing phase. See Table 28.45.
backup_total bigint
Total amount of data that will be streamed. This is estimated and reported as of the beginning of streaming database files phase. Note that this is only an approximation since the database may change during streaming database files phase and WAL log may be included in the backup later. This is always the same value as backup_streamed once the amount of data streamed exceeds the estimated total size. If the estimation is disabled in pg_basebackup (i.e., --no-estimate-size option is specified), this is NULL.
backup_streamed bigint
Amount of data streamed. This counter only advances when the phase is streaming database files or transferring wal files.
tablespaces_total bigint
Total number of tablespaces that will be streamed.
tablespaces_streamed bigint
Number of tablespaces streamed. This counter only advances when the phase is streaming database files.
initializing
The WAL sender process is preparing to begin the backup. This phase is expected to be very brief.
waiting for checkpoint to finish
The WAL sender process is currently performing pg_backup_start to prepare to take a base backup, and waiting for the start-of-backup checkpoint to finish.
estimating backup size
The WAL sender process is currently estimating the total amount of database files that will be streamed as a base backup.
streaming database files
The WAL sender process is currently streaming database files as a base backup.
waiting for wal archiving to finish
The WAL sender process is currently performing pg_backup_stop to finish the backup, and waiting for all the WAL files required for the base backup to be successfully archived. If either --wal-method=none or --wal-method=stream is specified in pg_basebackup, the backup will end when this phase is completed.
transferring wal files
The WAL sender process is currently transferring all WAL logs generated during the backup. This phase occurs after waiting for wal archiving to finish phase if --wal-method=fetch is specified in pg_basebackup. The backup will end when this phase is completed.
Column Type
Description
pid integer
Process ID of backend.
datid oid
OID of the database to which this backend is connected.
datname name
Name of the database to which this backend is connected.
relid oid
OID of the table on which the COPY command is executed. It is set to 0 if copying from a SELECT query.
command text
The command that is running: COPY FROM, or COPY TO.
type text
The io type that the data is read from or written to: FILE, PROGRAM, PIPE (for COPY FROM STDIN and COPY TO STDOUT), or CALLBACK (used for example during the initial table synchronization in logical replication).
bytes_processed bigint
Number of bytes already processed by COPY command.
bytes_total bigint
Size of source file for COPY FROM command in bytes. It is set to 0 if not available.
tuples_processed bigint
Number of tuples already processed by COPY command.
tuples_excluded bigint
Number of tuples not processed because they were excluded by the WHERE clause of the COPY command.