A couple of days ago the following commit has popped up in PostgreSQL tree for the upcoming 9.5, introducing a feature particularly interesting for developers of backend extensions and plugins:

commit: bd4e2fd97d3db84bd970d6051f775b7ff2af0e9d
author: Robert Haas <rhaas@postgresql.org>
date: Fri, 30 Jan 2015 12:56:48 -0500
Provide a way to supress the "out of memory" error when allocating.

Using the new interface MemoryContextAllocExtended, callers can
specify MCXT_ALLOC_NO_OOM if they are prepared to handle a NULL
return value.

Michael Paquier, reviewed and somewhat revised by me.

The memory allocation routines are located in the code of PostgreSQL in mcxt.c while being declared in palloc.h, the most famous routines of this set being palloc(), palloc0(), or repalloc() which work on CurrentMemoryContext. There are as well some higher-level routines called MemoryContextAlloc* able to perform allocations in a memory context specified by caller. Using those routines it is possible to allocate memory in any context other than the current one. Each existing allocation routine share a common property: when allocation request cannot be completed because of an out-of-memory error, process simply errors out, contrary to what a malloc() would do by returning a NULL pointer to the caller with ENONEM set as errno.

The commit above introduces in backend code a routine allowing to bypass this out-of-memory error and get back a NULL pointer if system runs out of memory, something particularly useful for features having a plan B if plan A that needed a certain amount of allocated buffer could not get the memory wanted. Let's imagine for example the case of a backend process performing some compression of data using a custom data type. If compression buffer cannot be allocated, process can store the data as-is instead of failing, making this case more robust.

So, the new routine is called MemoryContextAllocExtended, and comes with three control flags:

• MCXT_ALLOC_HUGE, to perform allocations higher than 1GB. This is equivale

[continue reading]

Unlogged tables

Stubborn vacuum

[continue reading]

[continue reading]

[continue reading]

[continue reading]

[continue reading]

One of the lesser known Postgres parameters is also one of the most powerful: session_replication_role. In a nutshell, it allows you to completely bypass all triggers and rules for a specified amount of time. This was invented to allow replication systems to bypass all foreign keys and user triggers, but also can be used to greatly speed up bulk loading and updating.

(Triggerfish picture by Shayne Thomas)

The problem with disabling triggers

Once upon a time, there were two replication systems, Slony and Bucardo, that both shared the same problem: triggers (and rules) on a "target" table could really mess things up. In general, when you are replicating table information, you only want to replicate the data itself, and avoid any side effects. In other words, you need to prevent any "post-processing" of the data, which is what rules and triggers may do. The disabling of those was done in a fairly standard, but very ugly method: updating the system catalogs for the tables in question to trick Postgres into thinking that there were no rules or triggers. Here's what such SQL looks like in the Bucardo source code:

$SQL = q{
    UPDATE pg_class
    SET    reltriggers = 0, relhasrules = false
    WHERE  (
};
$SQL .= join "OR\n"
    => map { "(oid = '$_->{safeschema}.$_->{safetable}'::regclass)" }
      grep { $_->{reltype} eq 'table' }
      @$goatlist;
$SQL .= ')';

This had a number of bad side effects. First and foremost, updating the system catalogs is never a recommended step. While it is *possible*, it is certainly discouraged. Because access to the system catalogs do not follow strict MVCC rules, odd things can sometimes happen. Another problem is that editing the system catalogs causes locking issues, as well as bloat on the system tables themselves. Yet another problem is that it was tricky do get this right; even the format of the system catalogs change over time, so that your code would need to have alternate paths for disabling and enabling triggers depending on the version of Postgres in use. Finally, the

[continue reading]

Andreas 'ads' Scherbaum

As Josh Berkus blogged before, Pivotal is hosting the inaugural South Bay PostgreSQL Meetup in the Palo Alto office.

We were able to secure two very good speaker:

• Mason Sharp, from TransLattice: Scale-out PostgreSQL with PostgreSQL-XL
• Peter van Hardenberg, from Heroku: Postgres 9.4, new opportunities for users, admins and hackers

Please sign up at the Meetup website, if you plan to attend.

Date: Monday, February 16th, 2015

Time: 6:30pm

Location: 3495 Deer Creek Road Palo Alto, CA 94304 United States

PostgreSQL 9.4 and below doesn't support importing whole set of tables from a FOREIGN server, but PostgreSQL 9.5 does with the upcoming Import Foreign Schema. To use will require FDW wrapper designers to be aware of this feature and use the plumbing in their wrappers. IMPORT FOREIGN SCHEMA for ogr_fdw come PostgreSQL 9.5 release is on the features ticket list. The ogr_fdw comes with this to die for commandline utility called ogr_fdw_info that does generate the table structures for you and will also list all the tables in the Foreign data source if you don't give it a specific table name. So with this utility I wrote a little hack involving using PostgreSQL COPY PROGRAM feature to call out to the ogr_fdw_info commandline tool to figure out the table names and some DO magic to create the tables.

Though ogr_fdw is designed to be a spatial foreign data wrapper, it's turning out to be a pretty nice non-spatial FDW as well especially for reading spreadsheets which we seem to get a lot of. This hack I am about to demonstrate I am demonstrating with LibreOffice/OpenOffice workbook, but works equally well with Excel workbooks and most any data source that OGR supports.

A couple of days back a new mode has been added in vacuumdb for the support of parallel jobs:

commit: a17923204736d8842eade3517d6a8ee81290fca4
author: Alvaro Herrera <alvherre@alvh.no-ip.org>
date: Fri, 23 Jan 2015 15:02:45 -0300
vacuumdb: enable parallel mode

This mode allows vacuumdb to open several server connections to vacuum
or analyze several tables simultaneously.

Author: Dilip Kumar.  Some reworking by Álvaro Herrera
Reviewed by: Jeff Janes, Amit Kapila, Magnus Hagander, Andres Freund

When specifying a number of jobs with -j, the number of maximum connections defined by max_connections should be higher than the number of jobs specified as process creates a number of connections to the remote database equal to the number of jobs, and then reuses those connections to process the tables specified.

This of course supports all the modes already present in vacuumdb, like --analyze, --analyze-in-stages, etc. The list of tables processed in parallel can as well be customized when passing several values via --tables.

An important thing to note is that when using this feature with -f (VACUUM FULL), there are risks of deadlocks when processing catalog tables. For example in this case what happens was a conflict between pg_index and pg_depend:

$ vacuumdb -j 32 -f -d postgres
vacuumdb: vacuuming database "postgres"
vacuumdb: vacuuming of database "postgres" failed: ERROR:  deadlock detected
DETAIL:  Process 2656 waits for RowExclusiveLock on relation 2608 of database 12974; blocked by process 2642.
Process 2642 waits for AccessShareLock on relation 2610 of database 12974; blocked by process 2656.
HINT:  See server log for query details.
$ psql -At -c "SELECT relname FROM pg_class WHERE oid IN (2608,2610);"
pg_index
pg_depend

Note that this has higher chances to happen if:

• the number of relations defined on the database processed is low.
• the quantity of data to be processed is low
• the number of jobs is high

So be careful when using parallel jobs with FULL on a complete database.

Today version 1.4.0 of Barman has been officially released. The most important feature is incremental backup support, which relies on rsync and hard links and helps you reduce both backup time and disk space by 50-70%.

Barman adds one configuration option, called reuse_backup. By setting this option to link, Barman will transparently reuse the latest available backup in the catalogue of a given server when issuing a barman backup command.

“Mhh … hang on … Did you just say ‘Reuse’? In what terms?”

Essentially, Barman will reuse the previous backup in two phases:

• when reading the backup files;
• when permanently saving the backup files.

Barman simply exploits rsync’s robust and proven technology in order:

• to skip transferring those database files that have not changed from the latest base backup;
• use hard links on the backup side in order to save disk space (data deduplication).

If you happen to follow me on Twitter, you might have already seen this message about data deduplication on one of our customer’s database:

This particular case involves a very large database of 13.2 Terabyte. Consider doing a weekly backup of a 13.2 TB database. You face two major problems:

• backup time
• backup size (with a large impact on retention policies)

As you can see, over 8.2 TB of data had not changed between the two backups, with a subsequent reduction of both backup time (17 hours instead of more than 50!) and disk space (5TB instead of 13TB!), as well as network bandwidth (by the way, Barman allows you to enable network compression too).

I must confess that a 13TB database is quite an exceptional case. However, what we have witnessed so far, even on smaller (and much smaller) databases, is an almost constant deduplication ratio in all the backups that we are managing with 2ndQuadrant. On average, deduplication ratio is between 50% and 70%.

The experience gained on this topic by Barman’s development team won’t stop here. A similar approach is being followed by Marco Nenciarini in its attempt to introduce file level incrementa

[continue reading]

The simplest tools are usually the best.

One of the tools I usually need when I go see customers is vmstat. Nothing beats vmstat to give me a real overview of what the server is really doing. This overview gives system metrics, such as CPU usage, and disk usage. That's quite useful to check where the bottleneck comes from.

I wish I had a PostgreSQL tool like that. I wished enough to eventually build it. I call it pgstat because I couldn't find a better name for it.

It's an online command tool that connects to a database and grabs its activity statistics. As PostgreSQL has many statistics, you have a command switch to choose the one you want (-s):

• archiver for pg_stat_archiver
• bgwriter for pg_stat_bgwriter
• connection for connections by type
• database for pg_stat_database
• table for pg_stat_all_tables
• tableio for pg_statio_all_tables
• index for pg_stat_all_indexes
• function for pg_stat_user_function
• statement for pg_stat_statements
• pbpools for pgBouncer pools statistics
• pbstats for pgBouncer general statistics

It looks a lot like vmstat. You ask it the statistics you want, and the frequency to gather these statistics. Just like this:

$ pgstat -s connection
 - total - active - lockwaiting - idle in transaction - idle -
    1546       15             0                     0   1531  
    1544       17             0                     0   1527  
    1544       14             0                     0   1530  
    1546       26             0                     0   1520  
    1543       21             0                     0   1522 

Yeah, way too many idle connections. Actually, way too many connections. Definitely needs a pooler there.

This is what happens on a 10-secondes 10-clients pgbench test:

$ pgstat -s database 1
- backends - ------ xacts ------ -------------- blocks -------------- -------------- tuples -------------- ------ temp ------ ------- misc --------
                commit rollback     read    hit read_time write_time      ret    fet    ins    upd    del    files     bytes   conflicts deadlocks
         1

[continue reading]

$ sudo apt-get install python-yaml python-icalendar python-flask python-pygithub

api_token: 6b36b3d7579d06c9f8e88bc6fb33864e4765e5fac4a3c2fd1bc33aad
bind_address: ::0
bind_port: 5000
repositories:
- repository: your-user-name/your-project
- repository: your-user-name/another-project

$ ./github_icalendar/main.py github-ics.cfg

[continue reading]

One of the foreign data wrappers I included in the PostgreSQL 9.3 Windows FDW bag and PostgreSQL 9.4 Windows FDW bag is the www_fdw extension used for querying web services. Someone asked that since I didn't build curl with SSL support, they are unable to use it with https connections. The main reason I didn't is that the EDB installs come with ssleay32.dll and libeay32.dll (even the 64-bit) which are dependencies of curl when built with SSL support. I wanted to minimize the issue of distributing dlls that are packaged with Windows PostgreSQL installers already.

Though this article is specific to using www_fdw on Windows systems, many of the issues are equally applicable to other platforms, so may be worth a read if you are running into similar issues with using specialty SSL certificates on Linux/Unix/Mac.

In PostgreSQL 9.5, we will see a boost in scalability for read workload
when the data can fit in RAM.  I have ran a pgbench read-only load to
compare the performance difference between 9.4 and HEAD (62f5e447)
on IBM POWER-8 having 24 cores, 192 hardware threads, 492GB RAM
and here is the performance data

The data is mainly taken for 2 kind of workloads, when all the data fits

in shared buffers (scale_factor = 300) and when all the data can't fit in

shared buffers, but can fit in RAM (scale_factor = 1000).

First lets talk about 300 scale factor case, in 9.4 it peaks at 32 clients,

now it peaks at 64 clients and we can see the performance improvement

upto (~98%) and it is better in all cases at higher client count starting from

32 clients.  Now the main work which lead to this improvement is
commit - ab5194e6 (Improve LWLock scalability).  The previous implementation
has a bottleneck around spin locks that were acquired for  LWLock
Acquisition and Release and the implantation for 9.5 has changed the
LWLock implementation to use atomic operations to manipulate the state.
Thanks to Andres Freund (and according to me the credit goes to reviewers
(Robert Haas and myself) as well who have reviewed multiple versions
of this patch) author of this patch due to whom many PostgreSQL users will
be happy.

Now lets discuss about 1000 scale factor case,  in this case, we could

see the good performance improvement (~25%) even at 32 clients and it

went upto (~96%) at higher client count, in this case also where in 9.4

it was peaking at 32 client count, now it peaks at 64 client count and

the performance is better at all higher client counts.  The main work

which lead to this improvement is commit id 5d7962c6 (Change locking

regimen around buffer replacement) and  commit id  3acc10c9 (Increase

the number of buffer mapping partitions to 128).  In this case there were

mainly 2 bottlenecks (a) a BufFreeList LWLock was getting acquired to

find a free buffer for a page (to find free buffer, it needs to ex

[continue reading]

[continue reading]

Regular Expression Stop Words for Postgresql

Jan 24, 2015 – Portland

While working on a NLP project with OCR-derived text, I discovered a need that wasn’t immediately met by the built in parsers and dictionaries which ship with Postgresql. Fortunately text search in Postgresql is fairly extensible.

This post looks at the process of implementing a custom dictionary which can be used to create stop words which are really stop regular expressions.

Background on Parsing, Dictionaries, and Stop Words

The first step in using most text search features is converting unstructured text into text search vectors. A text search vector is a set of (lexeme, position) pairs.

=# select to_tsvector('Time is an illusion.  Lunchtime doubly so.');
                to_tsvector
--------------------------------------------
 'doubli':6 'illus':4 'lunchtim':5 'time':1
(1 row)

As you might expect, the internal representation of a ts_vector is simply information about where words are located inside a big string.

typedef struct
{
  int32   vl_len_;    /* varlena header (do not touch directly!) */
  int32   size; 
  WordEntry entries[1];   /* variable length */
  /* lexemes follow the entries[] array */
} TSVectorData;

The transformation from text to ts_vector involves parsing text into tokens, then filtering the tokens through a dictionary which may change or eliminate words.

A text search configuration can be used to map token categories to dictionaries. The official documentation contains additional details.

The Problem Statement

The text corpus is derived from an OCR process which results in some unhelpful tokens.

a-433
-43 44 40
Lunchtime is 46 #@$dfsdf an illusion.Q!~ Lunchtime ksdfkjsadjfksdjf so.
431,-

So how to get pleasant ts_vectors?

One solution would be adding a token type ocr gibberish to the parser and removing mappings from ocr_gibberish to any dictionary. While you can write your own parser, the default is pretty good, and it does not appear to be easily extended.

Another approach would be to use a dictionary as a white

[continue reading]

MixERP PgDoc is a console-based application that creates beautiful PostgreSQL database documentation. The first release supported Windows and with the second release today, we now support OSX and Linux (tested on OSX Yosemite and Ubuntu 14.4). Please make sure you have Mono installed first before you download PgDoc here:

http://mixerp.org/erp/mixerp-pgdoc-mono.zip

Running on OSX and Linux

Extract the downloaded archive mixerp-pgdoc-mono.zip. Open terminal and type

mono /path/to/mixerp-pgdoc.exe <arguments>

Or simply

mono /users/nirvan/desktop/pg-doc/mixerp-pgdoc.exe -s=localhost -d=mixerp -u=postgres -p=secret -o=/users/nirvan/desktop/db-doc

I have created a category in MixERP Forums for further discussion.

PostgreSQL 9.4 introduces a new statistic in the catalogue, called pg_stat_archiver.
Thanks to the SQL language it is now possible, in an instant, to check the state of the archiving process of transactional logs (WALs), crucial component of a PostgreSQL disaster recovery system.

Introduction and reasons

The need for the pg_stat_archiver view comes from the last few years of experience with Barman as a solution for disaster recovery of PostgreSQL databases in business continuity environments.

In particular, some of the needs and recurring questions that DBAs, system administrators, CTOs and CIOs repeatedly – and legimitately – share with us, are:

• how much disk space will I need?
• how can I keep the whole backup process, including continuous archiving, under control?

The starting point can only be a business requirement and it is defined through the concept of retention policy.
Usually, a company defines a disaster recovery plan within a business continuity plan, where it is clearly defined the period of retention of backup data. In the same documents we find both the recovery point objective (RPO) and the recovery time objective (RTO) definitions, the two key metrics that respectively measure the amount of data that a business can afford to lose and the maximum allowed time to recover from a disaster.
Monitoring and studying the past behaviour of a database are important elements for correctly sizing the storage requirements of a PostgreSQL backup solution.

For example, a company may decide to retain data of a PostgreSQL database for a month, in order to reconstruct the state of the database in a consistent manner at any point in time from the first available backup to the last available WAL file (through the rock solid Point-in-Time-Recovery technology of PostgreSQL, introduced 10 years ago).

The required size is given not only by the number of periodic full backups (for example, one a week), but also the number of WAL files stored in the Barman archive, each containing all the transactions that have been pro

[continue reading]

In the spirit of open-source, we would like to share how we handled the talk selection process for PGConf US 2015. This post will discuss the entire process of how a talk ends up in one of our United States PostgreSQL Association conferences; our goal is to help you understand what our conference is looking for in talk proposals and help you decide what you submit for PGConf US 2016!

read more

One of the changes coming to you in PostGIS 2.2 are additional extensions. Two ones close to my heart are the address_standardizer (which was a separate project before, but folded into PostGIS in upcoming 2.2) and the SFCGAL extension for doing very advanced 3D stuff. We had a need to have address standardizer running on our Ubuntu box, but since PostGIS 2.2 isn't released yet, you can't get it without some compiling. Luckily the steps are fairly trivial if you are already running PostGIS 2.1. In this article, I'll walk thru just building an installing the address_standardizer extension from the PostGIS 2.2 code base. Though I'm doing this on Ubuntu, the instructions are pretty much the same on any Linux, just replacing with your Linux package manager.

When: Thu Jan 29, 6pm-8pm
Where: Renewable Funding, 400 SW 6th Ave

We’ll go over Foreign Data Wrappers, focusing on the Postgres FDW.

Our labs are casual, attendee-led affairs with no agenda set in advance. The goal is to share what we know & learn together.

Show up with a couple of Pg databases – they can be on the same cluster or different ones, doesn’t really matter. One of them should have at least one table with data in it.

We do need to know who’s coming so we can notify building security, so please sign up in advance here.

Grab dinner at the carts & come on over!

We’ve just released a new version of PoWA, the PostgreSQL Workload Analyzer. Check out complete release note here.

This new version adds an highly requested feature : you can now collect stats from multiple PostgreSQL servers using a single PoWA instance. This should be usefull if you have many servers to monitor. We’ve also improved the UI in many ways : the graph should be easier to read on full screen and the install process is more convienient

This version is probably the major release of the 1.x branch. We’re currently working on the branch that will change almost everything : PoWA 2.x will be only compatible with PostgreSQL 9.4 because we want to use the new stats and features of latest version. This should allow PoWA 2.x to some nice things like finding missing indexes or displaying advanced filesysteme stats. The 2.x version will also have a brand new user interface and we hope this will be similar to what we did when we rewrote completely the pgBadger interface 2 years ago…

Here’s a some preview:

Of course we will continue to maintain PoWA 1.x for the users who installed it on PostgreSQL 9.3 servers

If you go to FOSDEM 2015 next week, come see us ! We will be presenting these new features and more !

If you can’t go to FOSDEM 2015, subscribe to the powa-users mailing list to receive news and updates.

Postgres provides much clear ERROR reporting messages compare to other databases/data-stores I have worked or been working at my $DAYJOB. However, someone reported following error on their Secondary Postgres replicated database server.

2015-01-22 15:20:49.247 GMT 56914 LOG: unexpected pageaddr 142D/73000000 in log file 5166, segment 75, offset 0
2015-01-22 15:20:49.413 GMT 42933 FATAL: could not connect to the primary server: ERROR: Unsupported startup parameter: replication


On the first site, it looks scary but it’s actually not !

I googled a bit but I couldn’t able to find quick answer. So, I investigated further to understand what does reported error mean?  Fortunately, the replication was up-to-date because most of our clients have been recommended or setup to use hybrid replication (WAL shipping using OmniPITR + Streaming Replication).

While discussing further with the team, it turned out they introduced pgbouncer, a connection pooling solution, in to their architecture to better manage connections on the db server. The pgbouncer is set up to run on port 5432 (default Postgres port) on the master database server and make Postgres to listen on 5433. This change wasn’t reflected on secondary replicated database server recovery.conf file and it was still pointing to port 5432. So, we found the cause of the error & the mystery is solved !!

recovery.conf file has been modified to use port 5433 and restarted secondary database to load the config changes. Yay !! Secondary database is connected to primary db server using streaming replication.

2015-01-22 15:41:09.357 GMT 49294 LOG: database system is ready to accept read only connections
2015-01-22 15:41:09.512 GMT 49296 LOG: restored log file "000000030000142E0000006A" from archive
2015-01-22 15:41:10.016 GMT 49296 LOG: unexpected pageaddr 142D/8E000000 in log file 5166, segment 107, offset 0
2015-01-22 15:41:10.182 GMT 49408 LOG: streaming replication successfully connected to primary

I wanted to share my experience that can be useful if you see this ERROR  in you

[continue reading]