counter"); printf("INCR counter: %lld\n", reply->integer); freeReplyObject(reply); /* again ... */ reply = redisCommand(c,"INCR counter"); printf("INCR counter: %lld\n", reply->integer); 云数据库 Redis 版

tree-like data type ...................................................... 2945 F.23. pageinspect — low-level inspection of database pages .................................. 2953 F.24. passwordcheck — verify statistics ................................................... 2997 F.32. pg_surgery — perform low-level surgery on relation data .............................. 3002 F.33. pg_trgm — support for similarity visibility map information and utilities ................................. 3010 F.35. pg_walinspect — low-level WAL inspection ............................................... 3012 F.36. postgres_fdw — access

tree-like data type ................................................. 2787 F.23. pageinspect — low-level inspection of database pages ............................. 2795 F.24. passwordcheck — verify password tuple-level statistics ............................................. 2836 F.32. pg_surgery — perform low-level surgery on relation data ........................ 2841 F.33. pg_trgm — support for similarity of visibility map information and utilities ............................ 2849 F.35. pg_walinspect — low-level WAL inspection ......................................... 2851 F.36. postgres_fdw — access data stored

old_snapshot — inspect old_snapshot_threshold state ....................... 2898 F.25. pageinspect — low-level inspection of database pages .................................. 2899 F.26. passwordcheck — verify statistics ................................................... 2943 F.34. pg_surgery — perform low-level surgery on relation data .............................. 2948 F.35. pg_trgm — support for similarity .............................. 2956 xxi PostgreSQL 16.1 Documentation F.37. pg_walinspect — low-level WAL inspection ............................................... 2958 F.38. postgres_fdw — access

old_snapshot — inspect old_snapshot_threshold state ................. 2753 F.25. pageinspect — low-level inspection of database pages ............................. 2754 F.26. passwordcheck — verify password tuple-level statistics ............................................. 2795 F.34. pg_surgery — perform low-level surgery on relation data ........................ 2800 F.35. pg_trgm — support for similarity of visibility map information and utilities ............................ 2808 F.37. pg_walinspect — low-level WAL inspection ......................................... 2810 F.38. postgres_fdw — access data stored

normalize the tokens pro- duced by the parser. Text search parsers and templates are built from low-level C functions; therefore it requires C program- ming ability to develop new ones, and superuser privileges rname)(mail=$username))" Here is an example for a search+bind configuration that uses DNS SRV discovery to find the host name(s) and port(s) for the LDAP service for the domain name example.net: 685 the exclusive one is deprecated and will eventually be removed. 25.3.3.1. Making a Non-Exclusive Low-Level Backup A non-exclusive low level backup is one that allows other concurrent backups to be running

normalize the tokens produced by the parser. Text search parsers and templates are built from low-level C functions; therefore it requires C pro- gramming ability to develop new ones, and superuser privileges rname)(mail=$username))" Here is an example for a search+bind configuration that uses DNS SRV discovery to find the host name(s) and port(s) for the LDAP service for the domain name example.net: host the exclusive one is deprecated and will eventually be removed. 25.3.3.1. Making a Non-Exclusive Low-Level Backup A non-exclusive low level backup is one that allows other concurrent backups to be running

normalize the tokens pro- duced by the parser. Text search parsers and templates are built from low-level C functions; therefore it requires C program- ming ability to develop new ones, and superuser privileges installed to use this option. --with-bonjour Build with support for Bonjour automatic service discovery. This requires Bonjour support in your operating system. Recommended on macOS. 560 Installation rname)(mail=$username))" Here is an example for a search+bind configuration that uses DNS SRV discovery to find the host name(s) and port(s) for the LDAP service for the domain name example.net: host

normalize the tokens pro- duced by the parser. Text search parsers and templates are built from low-level C functions; therefore it requires C program- ming ability to develop new ones, and superuser privileges installed to use this option. --with-bonjour Build with support for Bonjour automatic service discovery. This requires Bonjour support in your operating system. Recommended on macOS. --with-uuid=LIBRARY rname)(mail=$username))" Here is an example for a search+bind configuration that uses DNS SRV discovery to find the host name(s) and port(s) for the LDAP service for the domain name example.net: 689

normalize the tokens produced by the parser. Text search parsers and templates are built from low-level C functions; therefore it requires C pro- gramming ability to develop new ones, and superuser privileges installed to use this option. --with-bonjour Build with support for Bonjour automatic service discovery. This requires Bonjour support in your operating system. Recommended on macOS. --with-uuid=LIBRARY rname)(mail=$username))" Here is an example for a search+bind configuration that uses DNS SRV discovery to find the host name(s) and port(s) for the LDAP service for the domain name example.net: host