Find and fix inconsistent B-tree indexes

Inconsistencies in database indexes can occur for a variety of reasons including software defects, hardware issues, or underlying changes in behavior such as sort order changes.

The PostgreSQL community has built tools to identify and remediate such issues. This includes tools like amcheck, which is recommended by the PostgreSQL community to identify consistency issues, including issues that earlier versions of PostgreSQL 14 exhibited.

We have written this playbook as a reference for Cloud SQL for PostgreSQL users who experience such issues. We hope this page provides information that may also aid other PostgreSQL users in identifying and remediating inconsistent b-tree indexes. Our goal is to continually improve this document as a resource for the broader open source community. If you have any feedback, please use the Send Feedback button at the top and bottom of this page.

Resolving an index's inconsistencies involves the following steps:

  1. Before you begin.

    Before you begin reindexing, you should back up your database, set the correct permissions, verify your psql client version, and download the amcheck extension.

  2. Check for inconsistent B-tree indexes.

    To identify the indexes you need to fix inconsistencies for, you need to identify all B-tree indexes with inconsistencies and identify all unique and primary key violations.

  3. Fix the index's inconsistencies.

    Reindexing an index fixes all its inconsistencies. You may need to adjust your instance's memory settings to improve performance.

  4. Monitor reindexing operations.

    We recommend that you monitor the progress of the reindexing operation to ensure that the operation is progressing and is not blocked.

  5. Verify that the indexes are consistent.

    After you have successfully reindexed your index, we recommend that you verify that your index does not contain any inconsistencies.

Before you begin

Backup your database

To ensure that no data is lost during reindexing, we recommend that you back up your database. For more information, see Create an on-demand backup.

Set the cloudsqlsuperuser permission

To complete the steps on this page, you must have cloudsqlsuperuser permissions. For more information, see session_replication_role.

Ensure that the psql client version is 9.6 or higher

To complete the steps on this page, you must ensure that your psql client version is 9.6 or higher. Run the command psql --version to verify your current psql client version.

Install the amcheck extension

To check for index inconsistencies, you must enable the amcheck extension.

PostgreSQL 9.6

To install amcheck for PostgreSQL 9.6, run the following statement:

  CREATE EXTENSION amcheck_next;
  

If you get an error saying `Could not open extension control file...`, verify that you're running the correct target maintenance version (POSTGRES_9_6_24.R20220710.01_12).

PostgreSQL 10 and later

To install amcheck for PostgreSQL 10 and later, run the following statement:

  CREATE EXTENSION amcheck;
  

Check for inconsistent B-tree indexes

The following sections describe how to check for inconsistent B-tree indexes by checking for an index's inconsistencies as well as unique and primary key violations.

Check for inconsistencies

Run the following statement to check for inconsistencies in all B-tree indexes in each of your databases:

Code Sample

  DO $$
  DECLARE
    r RECORD;
    version varchar(100);
  BEGIN
    RAISE NOTICE 'Started amcheck on database: %', current_database();
    SHOW server_version into version;
    SELECT split_part(version, '.', 1) into version;
    FOR r IN
      SELECT c.oid, c.oid::regclass relname, i.indisunique
        FROM pg_index i
        JOIN pg_opclass op ON i.indclass[0] = op.oid
        JOIN pg_am am ON op.opcmethod = am.oid
        JOIN pg_class c ON i.indexrelid = c.oid
        JOIN pg_namespace n ON c.relnamespace = n.oid
      WHERE am.amname = 'btree'
        AND c.relpersistence != 't'
        AND c.relkind = 'i'
        AND i.indisready AND i.indisvalid LOOP
      BEGIN
        RAISE NOTICE 'Checking index %:', r.relname;
        IF version = '10' THEN
          PERFORM bt_index_check(index => r.oid);
        ELSE
          PERFORM bt_index_check(index => r.oid, heapallindexed => r.indisunique);
        END IF;
      EXCEPTION
        WHEN undefined_function THEN
          RAISE EXCEPTION 'Failed to find the amcheck extension';
        WHEN OTHERS THEN
          RAISE LOG 'Failed to check index %: %', r.relname, sqlerrm;
          RAISE WARNING 'Failed to check index %: %', r.relname, sqlerrm;
      END;
    END LOOP;
    RAISE NOTICE 'Finished amcheck on database: %', current_database();
  END $$;
  

You should receive output similar to the following:

Output

  NOTICE:  Checking index t_pkey:
  NOTICE:  Checking index t_i_key:
  WARNING:  Failed to check index t_i_key: item order invariant violated for index "t_i_key"
  NOTICE:  Checking index t_j_key:
  WARNING:  Failed to check index t_j_key: item order invariant violated for index "t_j_key"
  NOTICE:  Checking index ij:
  WARNING:  Failed to check index ij: item order invariant violated for index "ij"
  

For more information about viewing PostgreSQL logs, see View instance logs.

Identify and fix unique and primary key violations

This section describes how to check your index for unique and primary key violations, and if some exist, how you fix them.

Identify unique key violations

Unique key violations must be fixed before you reindex an index. To check for all unique key violations, run the following command in each database:

Code Sample

  WITH q AS (
      /* this gets info for all UNIQUE indexes */
      SELECT indexrelid::regclass as idxname,
            indrelid::regclass as tblname,
            indcollation,
            pg_get_indexdef(indexrelid),
            format('(%s)',(select string_agg(quote_ident(attname), ', ')
                from pg_attribute a
                join unnest(indkey) ia(nr) on ia.nr = a.attnum
              where attrelid = indrelid)) as idxfields,
            COALESCE(substring(pg_get_indexdef(indexrelid) FROM '[)] (WHERE .*)$'), '') as whereclause
        FROM pg_index
      WHERE indisunique
      /* next line excludes indexes not affected by collation changes */
        AND trim(replace(indcollation::text, '0', '')) != ''
  )
  SELECT
  /* the format constructs the query to execute for each index */
  format(
  $sql$
  DO $$ BEGIN RAISE NOTICE 'checking index=%3$I    on   table=%1$I      key_columns=%2$I '; END;$$;
  SELECT this,
        prev,
        /* we detect both reversed ordering or just not unique */
        (CASE WHEN this = prev THEN 'DUPLICATE' ELSE 'BACKWARDS' END) as violation_type
    FROM (SELECT %2$s AS this,
                lag(%2$s) OVER (ORDER BY %2$s) AS prev
            FROM %1$s %4$s
          ) s
  WHERE this <= prev and this IS NOT NULL and prev IS NOT NULL; /* change to just '<' if looking for reverse order in index */
  $sql$, tblname, idxfields, idxname, whereclause
  )
    FROM q
  -- LIMIT 20 /* may use limit for testing */
  -- the next line tells psql to executes this query and then execute each returned line separately
  \gexec
  

The output of the script is similar to the following:

Output

  NOTICE:  checking index=users_email_key on table=users key_columns="(email)"
  NOTICE:  checking index=games_title_key on table=games  key_columns="(title)"
          this        |        prev        | violation_type
  --------------------+--------------------+----------------
  Game #16 $soccer 2  | Game #16 $soccer 2 | DUPLICATE
  Game #18 $soccer 2  | Game #18 $soccer 2 | DUPLICATE
  Game #2 $soccer 2   | Game #2 $soccer 2  | DUPLICATE
  Game #5 $soccer 2   | Game #5 $soccer 2  | DUPLICATE
  

In this output, the table header NOTICE shows the index, column, and table for the values displayed below it. If your output contains rows displaying DUPLICATE or BACKWARDS, then this shows corruption in the index and may need to be fixed. Rows with BACKWARDS indicate possible duplicate values that might be hidden. If you see either of these entries in the table, see Fix duplicate key violations.

Fix duplicate key violations

If you have identified a duplicate unique index or if a reindex operation fails due to a duplicate key violation error, complete the following steps to find and remove the duplicate key(s).

  1. Extract the key_columns from the NOTICE table header, as shown in the preceding sample output. In the following example, the key column is email.

    Code Sample

      NOTICE:  checking index=users_email_key on table=users key_columns="(email)"
    

    Use these values in KEY_COLUMNS in the query in step 3.

  2. Find the schema for your table. Use psql to connect to your database and run the following command:

    Code Sample

    \dt TABLE_NAME
    
    The value in the schema column is the value you use for SCHEMA_NAME in the query in step 3.

    For example, for the following query:

     \dt games
     

    The output is similar to the following:

     List of relations
     Schema  | Name  | Type  | Owner
     --------+-------+-------+----------
     public  | games | table | postgres
     (1 row)
     

  3. Run the following statements to force a full table scan and get duplicate keys.

    Code Sample

    SET enable_indexscan = off;
    SET enable_bitmapscan = off;
    SET enable_indexonlyscan = off;
    
    SELECT KEY_COLUMNS, count(*)
      FROM SCHEMA_NAME.TABLE_NAME
    GROUP BY KEY_COLUMNS
    HAVING count(*) > 1;
    

    In the above statement, KEY_COLUMNS are one or more columns covered by the unique index or primary key in the table you are checking. These were identified when you checked for unique key violations. The statement returns the duplicate keys and a count of the duplicates for each.

    For example, for the following query:

      SELECT name,count(*)
        FROM public.TEST_NAMES
      GROUP BY name
      HAVING count(*) > 1;
      

    The output is similar to the following:

      name                | count
      --------------------+-------
      Johnny              |     2
      Peter               |     2
      (2 rows)
      

    In this case, continue to the next step to remove the duplicate keys.

    If any of the columns in KEY_COLUMNS are null, you can ignore them because unique constraints do not apply for NULL columns.

    If no duplicate keys are found, you can move to Fix inconsistent indexes.

  4. Optional but recommended: Create a backup for the records containing duplicate keys. Run the following statement to create backup records:

    Code Sample

      CREATE TABLE SCHEMA_NAME.TABLE_NAME_bak
      AS SELECT * FROM SCHEMA_NAME.TABLE_NAME
      WHERE (KEY_COLUMNS)
      IN ((KEY_VALUES));
      

    In this statement, KEY_VALUES is a list of values copied from the result of the previous step. For example:

    Code Sample

      CREATE TABLE public.TEST_NAMES_bak
      AS SELECT * FROM public.TEST_NAMES
      WHERE (name) IN (('Johnny'),('Peter'))
      

    For a large number of rows, it is easier to replace the ((KEY_VALUES)) parameter in the IN statement with the SELECT statement from step 2 without the count parameter. For example:

    Code Sample

      CREATE TABLE SCHEMA_NAME.TABLE_NAME_bak
      AS SELECT * FROM SCHEMA_NAME.TABLE_NAME
      WHERE (KEY_COLUMNS)
      IN ( SELECT (KEY_COLUMNS)
      FROM SCHEMA_NAME.TABLE_NAME
      GROUP BY (KEY_COLUMNS)
      HAVING count(*) > 1);
      
  5. Add a replication role to the user to disable triggers:

    Code Sample

      ALTER USER CURRENT_USER with REPLICATION;
      SET session_replication_role = replica;
      
  6. Run the following statement to delete the duplicate keys:

    Code Sample

      BEGIN;
    
      DELETE FROM  SCHEMA_NAME.TABLE_NAME a
          USING  (
                  SELECT   min(ctid) AS ctid,
                          KEY_COLUMNS
                  FROM     SCHEMA_NAME.TABLE_NAME
                  GROUP BY KEY_COLUMNS
                          HAVING count(*) > 1 ) b
          WHERE a.KEY_COLUMNS = b.KEY_COLUMNS
          AND   a.ctid <> b.ctid;
      

    For example, for multi-column KEY_COLUMNS:

    Code Sample

      DELETE FROM public.test_random a
          USING (
                 SELECT min(ctid) AS ctid,
                 day, rnum
          FROM public.test_random
          GROUP BY day, rnum
                 HAVING count(*) > 1 ) b
          WHERE a.day=b.day and a.rnum = b.rnum
          AND a.ctid <> b.ctid;
      
    Where day and rnum are KEY_COLUMNS.

    Running this statement keeps one row and deletes others for each set of duplicate rows. If you want to control which version of the row gets deleted, run the following filter in the delete statement:

    Code Sample

      DELETE FROM  SCHEMA_NAME.TABLE_NAME
      WHERE ( KEY_COLUMNS, ctid) = (KEY_VALUES, CTID_VALUE);
      
  7. Complete the following steps to check that the DELETE command returned the expected number of rows without any errors:

    1. Run the following statement to identify the rows in which tables were changed:

      Code Sample

        SELECT schemaname, relname, n_tup_del, n_tup_upd
          FROM pg_stat_xact_all_tables
        WHERE n_tup_del+n_tup_upd > 0;
        
    2. If all the rows are correct, commit the DELETE transaction:

      Code Sample

        END;
        
    3. If there are errors, roll back the changes to fix the errors:

      Code Sample

        ROLLBACK;
        
  8. After the duplicate keys are deleted, you can reindex your index.

Fix inconsistent indexes

The following sections describe how you can fix the index inconsistencies found in your instance.

Depending on how your database is configured, you may need to do the following for each index identified in the previous steps:

  1. Prepare to reindex your index.

  2. Reindex your index.

  3. If the reindex operation fails due to foreign key violations, you must find and fix these violations.

  4. Run the reindex operation again.

Prepare to reindex your index

Find the index size

Indexing larger databases requires more time than smaller databases. To improve the speed of index and reindex operations of larger databases, you can allocate more memory and CPU power to these operations. This is an important step in planning your reindex operation. After you know the index size, you can set the memory size used by the reindex operation and set the number of parallel workers.

Run the following statement to find the index size, in kilobytes, of the index that you want to fix:

Code Sample

  SELECT i.relname                                      AS index_name,
        pg_size_pretty(pg_relation_size(x.indexrelid)) AS index_size
  FROM   pg_index x
        JOIN pg_class i
          ON i.oid = x.indexrelid
  WHERE  i.relname = 'INDEX_NAME';
  

The output of this statement is similar to the following:

Output

  index_name  | index_size
  ------------+------------
  my_index    | 16 kB
  (1 row)
  

Set memory size to use for reindexing

Based on the size of your index as determined in the previous section, it is important to set the appropriate value for maintenance_work_mem. This parameter specifies the amount of memory to use for the reindexing operation. For example, if your index size is greater than 15 GB, we recommend that you adjust your maintenance memory. For more information, see Set a database flag.

Indexing larger databases requires more time than smaller databases. To improve the speed of index and reindex operations, we recommend setting maintenance_work_mem to at least 2% of the instance memory for instances with 4GB or more memory during this reindexing operation.

Set the number of parallel workers

You can increase the number of parallel workers for reindexing by setting the max_parallel_maintenance_workers parameter in databases using PostgreSQL 11 or higher. The default value of this parameter is 2 but can be set to a higher value to increase the number of workers for reindexing. For instances with 8 or more vCPU cores, we recommend setting the max_parallel_maintenance_workers flag value to 4.

For more information, see Set a database flag.

Reindex your index

You can reindex an index without blocking your production workload using the pg_repack utility. This utility automates and simplifies the concurrent reindex process, enabling you to reindex without downtime, especially for PostgreSQL versions 11 and earlier, which do not have the REINDEX CONCURRENTLY operation. For this procedure, use pg_repack version 1.4.7.

Complete the following steps to reindex your index using pg_repack:

  1. Download, compile, and install the pg_repack utility from the pg_repack page.

    Debian GNU/Linux 11

    For convenience, we recommend that Debian Linux users download and install this pre-built executable binary for the Linux x86_64 platform.

    The sha256 checksum hash of the binary is the following:

    ecfee54364a625d9365d86cb27940b458bfdb0d6ff63bb88063039256fbde96f

    To verify that your Linux version is Debian GNU/Linux 11, run the command hostnamectl.

    Self compile

    Download, compile, and install the pg_repack utility from the pg_repack page.

  2. Create the pg_repack extension:

    Code Sample

      CREATE EXTENSION pg_repack;
      
  3. Run the following command to reindex your index concurrently:

    Code Sample

      pg_repack -h HOSTIP -p 5432 -U USERNAME -d "DATABASE_NAME" -i "INDEX_NAME" --no-superuser-check --no-kill-backend --wait-timeout=3600
      

    This command has output similar to the following:

    Output

      INFO: repacking index "public.t_i_key"
      

    If any errors occurred when running pg_repack, you can correct the error and try again. After you have fixed all of your unique key indexes and primary key indexes, you should check for foreign key violations and fix any that are found.

Find and fix foreign key violations

For information about how to find and fix foreign key violations, see Find and fix foreign key violations.

Monitor reindexing operations

Occasionally, the reindex operation may be blocked by other sessions. We recommended that you check this every 4 hours. If the reindex operation is blocked, you can cancel the blocking session so the reindex operation can complete.

Complete the following steps to identify blocking and waiting sessions and then cancel them in the INDEX operation:

  1. To identify blocking sessions, run the following query:

    Code Sample

      SELECT pid,
            usename,
            pg_blocking_pids(pid) AS blocked_by,
            query                 AS blocked_query
      FROM   pg_stat_activity
      WHERE  cardinality(pg_blocking_pids(pid)) > 0;
      
  2. To cancel a session, run the following query using the PID of the blocking session from the previous query:

    Code Sample

      SELECT pg_cancel_backend(PID);
      

Verify that your indexes are consistent

You must continue to check for index inconsistencies for each inconsistent index. After you have fixed all your instance's inconsistent indexes and key violations, you can check that no issues exist by following the steps in the previous sections: