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Transcript
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in
PostgreSQL
HSR Hochschule für Technik Rapperswil
Institut für Software
Oberseestrasse 10
Postfach 1475
CH-8640 Rapperswil
http://www.hsr.ch
Advisor:
Prof. Stefan Keller
Author:
Michel Ott
Rapperswil
May 26th, 2011
Table of Figures
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Table of Contents
Table of Figures
IV
Tables
IV
Figures
IV
Listings
V
List Of Abbreviations
1
Introduction
VI
1
1.1
Project description
1
1.2
Restrictions on the scope of the project
1
2
Overview
2
2.1
PostgreSQL
2
2.2
Key Value Pair
2
2.3
Hstore
3
2.3.1 Functions
2.3.2 Working principle
4
5
2.4
6
Benchmark Tools
2.4.1 Pgbench
2.4.2 HSR Texas Geo Database Benchmark
6
6
3
8
Benchmark proposal
3.1
Terms
8
3.2
Generate / Preprocessing phase
8
3.3
Execution phase
9
3.4
Benchmark / Analysis phase
9
3.5
Performance Benchmark Design
10
3.5.1 Table Schema
3.5.2 Statements
10
11
3.5.3 Datasets
11
3.6
13
4
Test Application
Benchmark Mai 2011
16
4.1
Technical specification
16
4.2
Execution
16
4.2.1 Preparing Database
4.2.2 Generating Test Data
4.2.3 Executing Benchmark
17
17
18
4.3
Results
19
4.4
Findings
25
4.5
Conclusion
31
Bibliography
University of Applied Science Rapperswil
32
II
Table of Figures
Appendix
University of Applied Science Rapperswil
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
33
III
Table of Figures
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Table of Figures
Tables
Table 1: KVP additional information table ................................................................................................................. 3
Table 2: KVP table ................................................................................................................................................................. 3
Table 3: Columns of a test dataset record ............................................................................................................... 12
Table 4: Number of dataset length ............................................................................................................................. 13
Table 5: Input parameters for test data generator .............................................................................................. 14
Table 6: Input parameters for benchmark application ..................................................................................... 15
Table 7: Hardware specification of system under test ...................................................................................... 16
Table 8: Software specification of system under test ......................................................................................... 16
Table 9: Hstore table abstract ....................................................................................................................................... 26
Table 10: KVP table abstract ......................................................................................................................................... 28
Table 11: Hstore tuple examples ................................................................................................................................. 30
Figures
Figure 1: KVP example SQL statement ......................................................................................................................... 3
Figure 2: hstore create table SQL example ................................................................................................................ 3
Figure 3: hstore insert SQL example ............................................................................................................................. 4
Figure 5: Example of a test data file ........................................................................................................................... 12
Figure 6: Number of test cicle ....................................................................................................................................... 13
Figure 7: Test / benchmark application incl. test data generator ................................................................ 14
Figure 8: Database setup script .................................................................................................................................... 17
Figure 9: Test data generation script ........................................................................................................................ 18
Figure 10: Benchmark script example ...................................................................................................................... 19
Figure 11: Overview KVP vs. hstore benchmark .................................................................................................. 20
Figure 12: Benchmark KVP vs. hstore from 10 to 2.5K ..................................................................................... 20
Figure 13: Overview KVP hstore with combined index .................................................................................... 21
Figure 14: Benchmark KVP hstore from 10 to 2.5K with combined index ............................................... 22
Figure 15: Overview of difference between KVP single and combined index ......................................... 22
Figure 16: 10 to 2.5K: Difference between KVP single and combined index ........................................... 23
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Table of Figures
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Figure 17: Overview of KVP with index on ‘key’ and combined index against hstore ........................ 23
Figure 18: 10 to 2.5K: KVP with index on ‘key’ and combined index against hstore ........................... 24
Figure 19: Index size overview .................................................................................................................................... 24
Figure 20: Index size for 10 to 5’000 records ........................................................................................................ 25
Listings
Listing 1: Hstore data type definition ........................................................................................................................... 5
Listing 2: Registering a PostgreSQL operator ........................................................................................................... 5
Listing 3: Defining a PostgreSQL function .................................................................................................................. 5
Listing 4: KVP Benchmark Table ................................................................................................................................. 10
Listing 5: Hstore Benchmark Table ............................................................................................................................ 10
Listing 6: KVP index .......................................................................................................................................................... 11
Listing 7: Hstore index ..................................................................................................................................................... 11
Listing 8: KVP select example ....................................................................................................................................... 11
Listing 9: KVP select example ....................................................................................................................................... 11
Listing 10: Transformed test data to KVP SQL statement ................................................................................ 12
Listing 11: Transformed test data to hstore SQL statement ........................................................................... 12
Listing 12: Explain Analyze statement for hstore without index .................................................................. 26
Listing 13: Output of Explain Analyze statement for hstore without index ............................................. 26
Listing 14: Explain Analyze statement for hstore with index ......................................................................... 26
Listing 15: Output of Explain Analyze statement for hstore with index .................................................... 27
Listing 16: Explain Analyze statement for KVP..................................................................................................... 28
Listing 17: Output of Explain Analyze statement for KVP ................................................................................ 28
Listing 18: Programming example of explain sequences ................................................................................. 28
Listing 19: Output of Explain Analyze statement for KVP with index on attribute ‘key’ .................... 29
Listing 20: Explain Analyze statement for KVP ..................................................................................................... 29
Listing 21: Output of Explain Analyze statement for KVP with combined index ................................... 30
Listing 22: Querying all person how lives in region with zip code ‘8000’ ................................................ 30
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List Of Abbreviations
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
List Of Abbreviations
Abbreviation
Description
bash
Bourne-again shell
CPU
Central Processing Unit
DB2
Commercial relational database management system developed by IBM
GiST
Generalized Search Tree
KVP
Key Value Pair
ms
milliseconds
MSSQL
Commercial relational database management system produced by Microsoft
OpenFTS
Open Source Full Text Search engine
Oracle
Commercial object-relational database management system produced by
Oracle Corporation
PgSQL
PostgreSQL – Open source object relational database
PostGIS
Adds support for geographic objects to the PostgreSQL object-relational database
SQL
Structured Query Language
URL
Uniform Resource Locator
University of Applied Science Rapperswil
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Chapter 1: Introduction
1
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Introduction
The following chapter describes the scope of the project and its boundaries and restrictions. In
general the goal is to benchmark the performance of PostgreSQL key-value-pairs against PostgreSQL hstore data type.
1.1
Project description
As part of this term paper a project evolved to benchmark PostgreSQL key-value-pairs, further
referred to as KVP, versus PostgreSQL in combination with hstore, further referred to as hstore
data type (probably an abbreviation for hash storage structure à la Perl hash). Hstore is part of
PostgreSQL distribution since version 8.2 as an additional module and storage for semi structural
data with GiST index access. The PostgreSQL core distribution does not know of key value pair
(KVP) information in a single attribute. That means it is not possible to store an associative array
e.g. {surname : ‘John’, name : ‘Smith’} in a attribute and query John’s name. This additional functionality was introduced by Oleg Bartunov and Teodor Sigaev and enhanced by Andrew Gierth
under the synonym ‘hstore’. Hstore is an enhancement for PostgreSQL, which provides a new
data type and a bunch of functions to store and query for KVP information. Dictionaries or associative arrays are the parent synonym for key value pairs (KVP) or abstract data structures
(ADT). They handle pairs, also known as items, as keys and their corresponding values. Most
modern script languages support dictionaries/associative arrays as a primary container type.
KVP is also called entity attribute value model (EAV) or object attribute value mode.
Both techniques, KVP and hstore, store arbitrary data as objects in the database, however, the
design of the database tables and therefore its schema is quite different in a way how the data is
stored, referenced and queried. The goal of this document is to find an answer which technique
performs faster.
1.2
Restrictions on the scope of the project
The purpose of this benchmark is not to test the stability or scalability of PostgresSQL. This is
rather a test of KVP and hstore on a given PostgreSQL environment. This implies that the performance tuning of PostgreSQL is not in scope of this document. Nevertheless this document and
all the applications can be the basis for such a test. In addition, benchmarking the insertion of the
test data is also out-of-scope.
Secondly, the semantics of the data, which is used for the test, is not relevant for any outcome of
the benchmark. For this reason the ‘lorem ipsum dolor’ 1 dummy text is used in the test data generation application and a name generator, which is based on combining syllables.
‘lorem ipsum dolor’ is a nonsense paragraph which aims at demonstrating a font to a reader without distracting him by the ‘gibberish’ of the text (Walsh, 1996).
1
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Chapter 2: Overview
2
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Overview
Today PostgreSQL has a huge community, not only because it is for free, but also due to the fact
that it has a lot of extensions like the geospatial extension PostGIS or the hstore mentioned before. The following chapter first describes what PostgreSQL is, then It explains the difference between key-value-pairs (KVP) as a table structure versus KVP using the hstore data type.
By studying subchapter 2.2 Key Value Pair and 2.3 Hstore you will recognize that KVP stores the
key and one or more related values in different table columns whereas hstore introduces a new
abstract data type allowing storing an associated array in the form of unique keys and related
values within a single table column. Suitable is KVP for easy data storage and data capture, rows
with many attributes that are rarely examined, and semi structured data.
2.1
PostgreSQL
PostgreSQL is an open source relational database, even an object-relational database according
(PostgreSQL Global Development Group). Since its life of over 15 years, PostgreSQL has a proven
standing in different applications fields. This, because it implements a set of capabilities that are
well known from proprietary software vendors like Oracle, IBM DB2 or Microsoft and of course it
provides all the other features such as scalability, maintainability, asynchronous replication, etc.
This and many more brings PostgreSQL in a position of a real competitor for proprietary software vendors in companies of different size and as of actual state, PostgreSQL is an enterprise
class database (PostgreSQL Global Development Group).
Additionally, PostgreSQL’s SQL implementation conforms the ANSI-SQL:2008 standard and implements beside the standard SQL statements select, insert, etc. also primary and foreign keys
with restrictions, check constraints, unique constraints, cascading and many more.
Its highly customizable environment let users and developers easily extend PostgreSQL. Examples are Generalized Search Tree (GiST), Open Source Full Text Search engine (OpenFTS) and
PostGIS. This is done by using one of dozen different programming languages, including Java,
Perl, Python, Ruby, Tcl, C/C++, and its own PL/pgSQL. Developers and users can draw upon hundreds of built-in functions of the standard library from basic math and string operations to cryptography and Oracle compatibility (PostgreSQL Global Development Group).
2.2
Key Value Pair
Not to be mistaken, key value pair (KVP) in the context of this paper is not the same as known in
database context. The normal interpretation is an associated array in an abstract data type, the
value, along a unique identifier, the key. This purpose belongs in this paper to the term ‘hstore’
described in the chapter below.
Thus, KVP means the standard way of creating, maintaining, and using tables in PostgreSQL with
exactly two attributes key and value. That means that the KVP table can store different unique
key value pairs for specific information. That implies that for a given key value pair a unique
identifier is needed that reverses to this information. Consequently that KVP table needed to be
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Chapter 2: Overview
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
enhanced with an identifier and an additional table is needed to store additional information.
From this it follows that the base schema of the KVP structure look likes the following.
Table: bench_kvp_info
id : Integer
attribute_1 : Text
attribute_n : Text
Table 1: KVP additional information table
Table: bench_kvp
id_fk : Integer
key : Text
value : Text
Table 2: KVP table
The bench_kvp_info table holds a unique identifier for specific information and the additional
data to it. For example it could hold the information of a restaurant such as street, postal code,
phone number and so on. The bench_kvp table stores in addition information that is not foreseeable. Such as those, that could describe or give more specific information to the restaurant like
the type of cuisine, a URL to its homepage, and so on.
Key value pairs are information that specify and information more exactly but not necessary
mandatory for all data in the information table. This structure allows adding easily new nonmandatory information without touching the table schema.
In Postgresql it can be setup as follow:
1
2
CREATE TABLE bench_kvp_info (
id integer PRIMARY KEY,
attribute_1 text,
attribute_n text
);
CREATE TABLE bench_kvp (
id integer REFERENCE bench_kvp_info(id),
key text NOT NULL,
value text
);
Figure 1: KVP example SQL statement
2.3
Hstore
Hstore means in this paper an associated array stored in an abstract data type composed of a
unique identifier based on the ‘hstore’ PostgreSQL enhancement developed by Oleg Bartunov and
Teodor Sigaev as an additional module. The hstore enhancement introduces an abstract data
type called ‘hstore’ which can store an associated array. In addition it provides a bunch of different functions and operators as well as indexing possibilities on the abstract data type. An index
can be created on the GiST, GIN, BTree, or Hash engine (Bartunov, Sigaev, & Gierth).
A pure hstore table can be created in the following way:
1
2
CREATE TABLE bench_hstore (
kvp_hstore hstore
);
CREATE INDEX hidx ON bench_hstore USING GIST(kvp_hstore);
Figure 2: hstore create table SQL example
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Chapter 2: Overview
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Inserting a tuple is as easy as creating an attribute of type hstore:
1
INSERT INTO bench_hstore(kvp_hstore) VALUES(
hstore(‘
’’id’’=>1,
‘‘surname’’=>’’McNeal’’,
‘‘forename’’=>’’Bob’’
’)
);
INSERT INTO bench_hstore(kvp_hstore) VALUES(
hstore(‘
’’id’’=>2,
‘‘surname’’=>’’Gates’’
’)
);
2
Figure 3: hstore insert SQL example
2.3.1
Functions
As you can see in the above example, the length of the array may vary from tuple to tuple. Important to see is that each line the associated array has a key and a value separated by comma e.g.
hstore(‘’’id’’=>2, ‘‘surname’’=>’’Gates’’’)
hstore(‘‘‘<key 1>’’ => ‘‘<value 1>’’, …, ‘‘<key n>’’ => ‘‘<value n>’’’)
means that we have two different unique keys, ‘id’ and ‘surname’, and each unique key has a value, for ‘id’ it is ‘2’ and for ‘surname’ it is ‘Gates’. Unique means that in a tuple a key can only be
defined once. For example the id ‘surname’ can only appear once in the same tuple; the following
hstore is not allowed:
hstore(‘’’id’’=>1, ‘‘surname’’=>’’Gates’’’, ‘‘surname’’=>’’McNeal’’)
As mentioned above in the introduction of this chapter hstore provide in addition to the ‘hstore’
data type a lot of PostgreSQL functions and operators, which can be used for querying, manipulating, and comparing values. At this point only some of them are explained.
The most important one is to query a specific value in a key. In the KVP methodology you do it
like this:
SELECT surname, forname FROM bench_kvp WHERE id = 2;
On a hstore data type it works like as follow:
SELECT kvp_hstore->’surname’ AS surname, kvp_hstore->’forname’ AS forename
FROM bench_hstore WHERE kvp_hstore->’id’ = ‘2’;
Although the id is in this example an integer, you need query it as if it is a string (see the WHERE
clause).
Because tuples can have hstores of different length and therefore various keys, it is sometimes
important to find out if a key exists in the hstore attribute:
SELECT kvp_hstore ? ‘forename’ AS available FROM bench_hstore;
This statement gives you for each tuple a ‘t’ for true or ‘f’ for false if key ‘forename’ is whether
available or not.
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Chapter 2: Overview
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Or maybe you want to know all possible keys in a hstore:
SELECT skeys(kvp_hstore) AS keys FROM bench_hstore GROUP BY keys;
To become the key only once in the result list, a ‘GROUP BY’ clause by keys need to be added to
the statement.
2.3.2
Working principle
Hstore is implemented in C as a PostgreSQL add-on and provides a SQL script to install the data
type and all the PostgreSQL functions. Hstore tries to build a buffer over all the keys, which are in
the hstore data type, if they are in alphabetical order. If not in some special functions the array
will be sorted to have it alphabetical order. Hstore as data type is defined as follow:
1
CREATE TYPE hstore (
INTERNALLENGTH = -1,
INPUT = hstore_in,
OUTPUT = hstore_out,
RECEIVE = hstore_recv,
SEND = hstore_send,
STORAGE = extended
);
Listing 1: Hstore data type definition
The important parameter is the ‘INPUT’ one, which is linked to a C method. The ‘hstore_in’ method parses the hstore string to a C structure that holds the key, value, and length of the key and
value as well as the position in the array. The position is needed because the array is not really
stored as an array in the database but rather as string (see Table 10: KVP table abstract). Querying now for a specific key value pair combination, hstore needs only to loop over this buffer and
find the key right key value combination to get the position of the key and value in the array.
Exemplary we take the comparison operator ‘->’. Each operator, such as the hstore operators,
needs to be registered in PostgreSQL. Executing the following statement can do this:
1
CREATE OPERATOR -> (
LEFTARG = hstore,
RIGHTARG = text,
PROCEDURE = fetchval
);
Listing 2: Registering a PostgreSQL operator
The important part is the ‘PROCEDURE’ parameter. This parameter links the operator to a PostgreSQL function. So that means the ‘fetchval’ function need to be defined as follow:
1
2
3
4
CREATE OR REPLACE FUNCTION fetchval(hstore,text)
RETURNS text
AS 'MODULE_PATHNAME','hstore_fetchval'
LANGUAGE C STRICT IMMUTABLE;
Listing 3: Defining a PostgreSQL function
As we see, the function returns a text. The PostgreSQL function ‘fetchval’ is now linked to a Cimplementation called ‘hstore_fetchval’ defined on line 3 in Listing 3.
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Chapter 2: Overview
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
For more information please visit the official PostgreSQL hstore documentation 2.
2.4
Benchmark Tools
Currently two programs should be mentioned for benchmarking PostgreSQL. Both, pgbench and
HSR Texas Geo Database Benchmark, are running in sequential mode SQL statements to test the
database under test. For the test proposed in this paper an own benchmark tools has been written to fulfill the desired hypotheses.
2.4.1
Pgbench
Pgbench is shipped in the PostgreSQL distribution package and runs test on a PostgreSQL instance in a sequential mode. Sequential mode means that the same SQL statement is run over and
over in possible multiple concurrent database sessions, which fulfill the multi-processing architecture. At the end of the benchmark it calculates the average transaction time per seconds.
Pgbench provides an own scripting language to customize the test scripts for using own data sets
and test SQL statements. In addition it includes some industry-standard test cases, which let you
compare PostgreSQL with other database products (Smith, 2010, S. 189).
Custom scripts in pgbench allow you to create your own test scripts. It can handle statements
with variable, which are known in Java as prepared statements. It is possible to define a SELECT
statement like this:
1
SELECT value FROM bench_kvp WHERE forname = :sforname;
As you can see ‘:sforename’ is a variable that will be replaced on runtime with the variable value.
All your statements need to be wrapped around the statements ‘BEGIN;’ and ‘END;’, which defines the beginning and the end of the benchmark.
Variables like ‘:sforename’ can be filled before the test begins that means before the ‘BEGIN;’statement. Each variable assigned need to be set by the function ‘\set’:
1
\set sforname ‘Greg’
Pgbench provides additional functions like ‘\setrandom’ for a random integer number, ‘\setshell’
to read the result of a shell command into a variable or ‘\shell’ to run a shell command but ignoring the result, and ‘\sleep’ causes the script execution to sleep for a specific duration.
2.4.2
HSR Texas Geo Database Benchmark
HSR Texas Geo Database Benchmark is another benchmark program written in Python to test
spatial database systems regarding its performance. The benchmark is based predefined set of
queries consisting simple spatial statements. The queries are run on different data sizes to moni-
PostgreSQL hstore documentation can be found here:
http://www.postgresql.org/docs/current/static/hstore.html
2
The explenation in this paper are based on the PostgreSQL hstore documentation 9.0:
http://www.postgresql.org/docs/9.0/static/hstore.html
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Chapter 2: Overview
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
tor the behavior. For all this queries this program provides the test data that comes from Texas
USA. A test script looks like this:
1
SELECT count(*)
FROM {dataset polygons} pg
WHERE ST_Intersects(@bbox, pg.geo);
This SELECT statement counts all polygons that intersect with a given bounding box ‘@bbox’.
In general, the benchmark program is based on a cube.
Different queries can be run on different systems by using different dataset. Each dataset will be installed on
each system and all queries are run on all systems times
the number of datasets. This guarantees that the different systems can be compared, because all are using the
same data and statements.
Figure 4: HSR Texas Geo Database
Benchmark Cube
Source: (Krummenacher, 2009)
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Chapter 3: Benchmark proposal
3
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Benchmark proposal
Before we can have a look at the benchmarking utility and the result, we need first to consider
what the ingredients of a benchmark are. The term benchmark can be substitute into three different processes described in the following chapter.
3.1
Terms
The term benchmark has a high cohesion to the term test. Looking into the Cambridge dictionary
benchmark is defined as follows:
“a level of quality which can be used as a standard when comparing other things”
(Cambridge University Press).
“That by which the existence, quality, or genuineness of anything is or may be determined; […]” (Oxford University Press).
The definition suggests that two different things of approximately the same topic need to be put
in contrast to each other. That means that the ‘things’ need to be converted in a form that makes
them comparable. At this point the term test come in place, which does exactly this transformation:
“an act of using something to find out whether it is working correctly or how effective it is” (Cambridge University Press)
“To evaluate or check (something) by comparison with an established standard; to
measure against a comparable or equivalent point of reference, esp. in order to assess performance or set performance standards.” (Oxford University Press)
(Cambridge University Press).
A test tries to find a form, which makes the ‘things’ comparable. The result of the test act is a
standardized input form for the benchmark. To bring the ‘things’ into this comparable form, an
upstream process needs to provide meaningful data that can be transformed by the test process
and analyzed with accurate techniques by the benchmarking process to find at the end conclusions and define further activities.
3.2
Generate / Preprocessing phase
The generate / preprocessing phase is the first step in a benchmark. This process tries to find
accurate data and need to be prepared for the testing. The steps in this phase must not be underestimated, because the impact of a statistical irrelevant result is very high. The better the data
and therefore the ground for the test itself is the higher is the probability that the analysis of the
test result gives a significant outcome.
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Chapter 3: Benchmark proposal
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
So some questions need here to be considered:
What exactly I want to test?
What should be the data and can they be transformed in the test process?
Does the data fit into the given environment?
Etc.
All these questions are very fundamental and often at the first moment very easy to answer.
However, finding the right data that fit into the environment and test process is not that easy e.g.
3.3
test data has a wrong encoding and cannot be loaded,
data does not cover the whole test design, and no significant result can be achieved,
etc..
Execution phase
The test execution phase defines the design of the chosen test technique. In general it can be divided into the following fields:
Load Testing: measures and establishes benchmarks for the system under test by pushing
transactions to the system. It can be incremental, or can be set amount that is proportional to the
values of the system.
Performance Testing: that is run repeatedly until acceptable performance levels are achieved
through database tuning activities.
Stress Testing: is the goal to break the system under test to gauge the system limits.
Volume Testing: is similar to load testing, but involves placing a large amount of requesting objects on the system.
The data for the system under test comes from the preprocessing phase and need to be transformed into a form that can be loaded into the data source (e.g. inserting data in a database). In
the test design need to be defined if the insertion of the data need also to be tested or only the
queries.
3.4
Benchmark / Analysis phase
After all data has been loaded and run on the system under test, the given data from the test execution phase need to be analyzed from different aspects. Here it is important to know in advance, how the results could look like to choose the right algorithm and mathematical formulas
for the analysis. Tools can heavily support this process, by automatically trying different mathematical functions like correlations, regressions, O-notation, and probabilities to calculate the
course of a graph.
At the end the user need to interpret the result of the benchmark phase and draw the right conclusions.
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Chapter 3: Benchmark proposal
3.5
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Performance Benchmark Design
To benchmark the KVP and hstore in PostgreSQL the decision has been taken in favor of a perfromance test. In this benchmark it is not important how stable and scalable PostgreSQL is, it is
more interesting how does KVP and hstore perform on given preconfigured PostgreSQL environment.
3.5.1
Table Schema
As described in chapter 2.2 Key Value Pair and 2.3 Hstore, the table schemas need to be defined
in such a way that the comparison between KVP and hstore is “fair”. The goal of the schema definitions is to have for both an associative array in matters of the data, which need to be stored. It
is not important to have an equal representation of the key value pairs in the database, however
the philosophy of what information type at its granularity need to be stored and queried is important. It means that the data are note foreseeable in sense of additional information that could
be provided to a specific data record.
In this benchmark we use the following table schemas to represent the associative array in a database table.
For KVP
1
2
CREATE TABLE bench_kvp_id (bench_id BIGINT PRIMARY KEY);
CREATE TABLE bench_kvp (
bench_id BIGINT REFERENCES bench_kvp_id(bench_id),
key TEXT NOT NULL,
value TEXT
);
Listing 4: KVP Benchmark Table
and for hstore:
1
CREATE TABLE bench_hstore (
bench_id BIGINT PRIMARY KEY,
bench_hstore HSTORE NOT NULL
);
Listing 5: Hstore Benchmark Table
You can imagine that the KVP and hstore table schema provides the same strategy of storing an
associative array. In spite of the strategy, the way how they store the data are quite different. The
KVP table creates for each key value pair a new tuple and reference it to a unique identifier,
which holds the additional information to the key value pairs.
In contrast to KVP, hstore needs only one tuple for the key value pairs. Hstore saves the key value
pairs in an associative string array, which looks like an array that developers used to use in their
programming language.
For both a test run will be executed once with an index and once without. For the KVP table the
standard PostgreSQL index take place, which is a bitmap index. In addition to the table creation
statement in Listing 4 we need to create an index for the KVP table:
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CREATE INDEX kvpidx1 ON bench_kvp (key);
CREATE INDEX kvpidx2 ON bench_kvp (key, value);
Listing 6: KVP index
Index for KVP shall be tested in two different ways. Firstly with a single index on the key
attribute and secondly a combined index on the attributes key and value.
For hstore an index can be created as follow:
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CREATE INDEX hidx ON bench_hstore USING GIST (bench_hstore);
Listing 7: Hstore index
3.5.2
Statements
To query a tuple based on a key value pair we have for each, KVP and hstore, an own SELECT
statement. Because KVP needs for each key value pair a new tuple we have first to find the
unique identifier to the key value pair and then we can select the information we need. This example selects all the information of a person with surname McNeal:
1
SELECT * FROM bench_kvp WHERE bench_id = (
SELECT bench_id FROM bench_kvp
WHERE key = 'surname' AND value = 'McNeal'
);
Listing 8: KVP select example
By using hstore we need first to convert the attribute which stores the hstore string into a hstore
object and then we could query the for a specific key value pair. The following statement does
this:
1
SELECT * FROM bench_hstore
WHERE hstore(bench_hstore)->'surname'='McNeal';
Listing 9: KVP select example
3.5.3
Datasets
For the load process an own test data generator (see also the next chapter 3.6 Test Application)
has been written in Python that generates based on the ‘lorem ipsum dolor’ dummy text and random numbers different sets of data. ‘lorem ipsum dolor’ is a nonsense paragraph which aims at
demonstrating a font to a reader without distracting him by the ‘gibberish’ of the text (Walsh,
1996). Each dataset includes at maximum 5 attributes and the amount of attributes varies from
dataset to dataset whereas the first two columns, id and forename, are mandatory in each record
to guarantee a valid key value pair. This variation guarantees that the hstore does not have the
same length and a more significant test can be achieved.
A sample record has the following attributes:
Column
Description
id : integer, sequence
Mandatory. A unique sequence identifier.
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surname : Text
Mandatory. A fancy name.
forename : Text
Optional: A fancy name. Can be empty to have a variable KVP length.
zip : Integer
Optional: A number between 1000 and 9000. Can be empty to have a variable KVP length.
comment : Text
Optional: A ‘dummy’ text. Can be empty to have a variable KVP length.
Table 3: Columns of a test dataset record
and an abstract of a test file looks as follow:
1
2
3
4
id,forename,surname,zip,comment
1,cucyp,,6593,lorem ipsum dolor sit amet consetetur sadipscing
elitr sed diam nonumy eirmod tempor invidunt ut labore et dolore magna aliquyam erat sed diam voluptua at vero eos et accusam et justo duo dolores et ea rebum stet clita kasd gubergren
no sea takimata sanctus est lorem ipsum dolor sit amet
2,kasarzyc,ecnalehad,8463,
3,inwa,,,
Figure 5: Example of a test data file
The test data records needs to be transformed into a valid KVP SQL statement like this:
1
2
3
4
5
6
7
8
INSERT INTO bench_kvp_info(id) VALUES(1)
INSERT INTO bench_kvp(id, key, value) VALUES(1, ‘id’, ‘1’);
INSERT INTO bench_kvp(id, key, value) VALUES(1, ‘forname’,
‘cucyp’);
INSERT INTO bench_kvp(id, key, value) VALUES(1, ‘zip’, ‘6593’);
INSERT INTO bench_kvp(id, key, value) VALUES(1, ‘comment’, ‘lorem ipsum dolor sit amet consetetur sadipscing elitr …’);
INSERT INTO
INSERT INTO
INSERT INTO
sarzyc’);
9 INSERT INTO
nalehad);
10 INSERT INTO
bench_kvp_info(id) VALUES(2)
bench_kvp(id, key, value) VALUES(2, ‘id’, ‘2’);
bench_kvp(id, key, value) VALUES(2, ‘forname’, ‘kabench_kvp(id, key, value) VALUES(2, ‘surname, ‘ecbench_kvp(id, key, value) VALUES(2, ‘zip, ‘8463’);
11 INSERT INTO bench_kvp_info(id) VALUES(3)
12 INSERT INTO bench_kvp(id, key, value) VALUES(3, ‘id’, ‘3’);
13 INSERT INTO bench_kvp(id, key, value) VALUES(3, ‘forname’, ‘inwa’);
Listing 10: Transformed test data to KVP SQL statement
and hstore SQL statement like this:
1
2
3
INSERT INTO bench_hstore(bench_hstore) VALUES(hstore(‘’’id’’=>1,’’forename’’=>’’cucyp’’,’’zip’’=>6593,’’com
ment’’=>’’lorem ipsum dolor …’’’))
INSERT INTO bench_hstore(bench_hstore) VALUES(hstore(‘’’id’’=>2,’’forename’’=>’’kasarzyc’’,’’surname’’=>’’e
cnalehad’’,’’zip’’=>8463’))
INSERT INTO bench_hstore(bench_hstore) VALUES(hstore(‘’’id’’=>3,’’forename’’=>’’inwa’’’))
Listing 11: Transformed test data to hstore SQL statement
The test tool automatically adds an additional unique id of type ‘String’ respectively of type ‘Text’.
The following dataset length are used to test KVP and hstore:
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Datasets
10 records
100 records
500 records
1’000 records
2’500 records
5’000 records
10’000 records
20’000 records
35’000 records
50’000 records
100’000 records
250’000 records
Table 4: Number of dataset length
Additionally, for KVP and hstore one test circle, means test phase and benchmark phase, take
place once with database index and once without for each dataset length. In total 24 different test
cycle were executed:
12 [# of length]× 2 [# of types]× 2 [# of indices]×3 [warm start] =144 [cicles]
Figure 6: Number of test cicle
‘# of length’ defines the number of different datasets that need to be run, ‘# of types’ means the
amount of different data sources that need to be testes. In our case it is KVP and hstore. ‘#of indices’ means that the test will be run once with indexed data and once without. This results in 20
different test cycles.
3.6
Test Application
For benchmarking KVP and hstore an own application has been written in Python. It supports all
three phases: Generate / Preprocessing, Execution, and Bechmark / Analysis. It has been written
in a way that it can be enhanced for other data sources like MySQL, MSSQL, Oracle, etc. by inheriting the general adapter object, which ensures the database connection and runs all the benchmark task (compare with Figure 7).
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Data generator
Log and Graphs
<
write
Data
write
>
n standalone processes
hstore
{name: ‘Joe’, …}
.csv
< load
{name: ‘Anne’, …}
Benchmark
Adapter
insert >
set >
{name:’Smith’, …}
{name:’Bob’, …}
{name:’Marco’,
...}
insert >
< add
< get
KVP
inherit >
Task queue
< get
Response queue
Processes excute task >
< write response
excute task >
(Adapters)
Figure 7: Test / benchmark application incl. test data generator
As you can see in the Figure 7 the test applications consists of a bundle of two modules. The first
module is accountable for the preprocessing phase, or to be more precise, for test data generation. Based on input parameters it creates a dataset in a format that is readable for the execution
phase. The following input parameters are mandatory:
Parameter
Description
-a or –amount
Integer: Amount of records to be created.
-t or --desc-type
String: Description type can be ‘words’, ‘lines’, or ‘chars’.
-l or --desc-length
Integer: defines how many words, lines, or characters need to be added
to the attribute comment in a test data record.
Table 5: Input parameters for test data generator
As described in chapter Error! Reference source not found. the test data generator creates a
sequence of unique identifiers (ID), a forname and surname based on the name generator by
Chris Gonnerman, a random zip code between 1000 and 9000, and a comment based on the lorem ipsum generator of Per Erik Strandberg.
The name generator creates names by randomly assembling random syllables. No name lists or
other fancy features are included (Gonnerman, 2003). Lorem ipsum generator creates different
length of dummy texts including non-ascii characters if needed (Strandberg, 2007).
The second module contains the two other phases, execution and benchmark / analysis, and need
to be run separately. The input parameters for this module are the following:
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Parameter
Description
-t or --type
String: Type of database test. Currently ‘pgsql’ and ‘pgsqlhstore’ supported.
-x or --processes
Integer: The amount of parallel processes that should be allocated. If this
parameter is not set, then the software tries to find out the maximum
parallel processes of the CPU architecture.
-s or --server
String: Server or hostname where the database runs e.g. localhost
-p or --port
Integer: Port of the database server.
-d or --database
String: Database name.
-u or --user
String: A user how has the rights to create tables, do insertions and run
queries.
-p or --password
String: User’s password.
-a or --data
String: File that includes all test records.
-i or --index
Boolean: Defines whether an index on the tables should be allocated or
not.
-n or --no-hot-start
Boolean: The flag defines if a hot start is required. If it is not set, it runs
the test 2 times before it measures on the 3 round the transaction time.
-l or --log
Boolean: Whether a log file should be created or not.
-g or --graph
Boolean: Should a Graph be created or not. If it is set, than the --log parameter need also to be set.
Table 6: Input parameters for benchmark application
At the beginning, this module try to find out how many processes the hardware can run in parallel if the parameter ‘-x’ or ‘--processes’ is not set. Each process is a separate adapter object, which
is waiting on tasks from the task queue.
In the next steps it takes the input data, generates a unique identifier and calls the appropriate
database adapter for insertion. Then it loops over all unique identifier and creates tasks, which it
puts into the task queue. Each adapter takes autonomous a task from the queue and executes it.
The time the adapter needs to execute the task flow back over the response queue to the benchmark object in the module. The benchmark object reads all response, generates the average and
tries to find a suitable regression curve. Additionally all this information will be written in a file
and a suitable graphical representation will be created for manual analysis.
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Benchmark Mai 2011
The following chapter specifies the hardware and software used for the system under test and
describes the results as well as the findings.
4.1
Technical specification
The server on which KVP and hstore need to be tested has the following hardware specification:
Type
Comment
Processor
CPU
Intel(R) Xeon(R) CPU E5520 @ 2.27GHz
Instructions set
64-bit
# of cores
4
# of threads
8
# of CPUs
2
Memory
Total
24’732’476 kB about 24 GB
Speed
1066 MHz
Idle modus
Only Ubuntu and PostgreSQL are running on the same hard disk whereas
23’677’164 kB about 23 GB RAM is free
Table 7: Hardware specification of system under test
The software specification is as follow:
Software
Coment
OS
Ubuntu 10.04.2 LTS
Kernel
2.6.32-28-server
GCC
4.4.2
Database
PostgreSQL 9.0.4 and PostGIS 1.5.2
Python
Version 2.6.5 and the following add-ons:
Numpy
Scipy
Matplotlib
Table 8: Software specification of system under test
4.2
Execution
Before the test can be started a database and the test data need to be created. The following subchapters describe which steps are needed to be ready for executing a benchmark. For all steps,
preparing database, generating test data, and executing benchmark, an example bash script is
provided.
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Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Preparing Database
To prepare the database you need first to login as a user that has the privilege to create a database such as user ‘postgres’:
1
sudo su postgres
As ‘postgres’ user you can run the first script called ‘step_1.sh’ which creates a new database user
‘benchmark’, a database called ‘benchmark’ and runs the hstore script that install the ‘hsotre’
data type and a bunch of PostgreSQL functions.
1
./step_1.sh
The content of the ‘step_1.sh’ script is as follow:
1
2
#!/bin/bash
# first login as user with privilege to create a database e.g.
sudo su postgres
3
4
5
6
7
8
# create new user benchmark
createuser -l -D -R -S benchmark
# alter user's password
psql -U postgres -c "ALTER USER benchmark WITH PASSWORD
'benchmark'"
9
10
11
12
13
14
15
16
17
# create new database benchmark
createdb -U postgres benchmark
# create language plpgsql on benchmark database
createlang -U postgres -d benchmark plpgsql
# load hstore data type and functions
psql -U postgres -d benchmark -f
/usr/share/postgresql/9.0/contrib/hstore.sql
18
19 # grant access to user benchmark
20 psql -U postgres -d benchmark -c "GRANT ALL PRIVILEGES ON DATABASE benchmark TO benchmark"
Figure 8: Database setup script
4.2.2
Generating Test Data
As described in chapter 3.6 Test Application the data generator need to be run separately. The
data can be created by executing the ‘step_2.sh’ bash script which creates the defined data sets
from chapter Error! Reference source not found. Error! Reference source not found..
1
./step_2.sh
The bash script ‘step_2.sh’ has the following content:
1
2
3
4
5
6
7
8
9
#!/bin/bash
# - for 10
python generator.py -a 10 -t words -l 50
mv data/testdata.csv data/testdata_10.csv
# create test data sets
# - for 100
python generator.py -a 100 -t words -l 50
mv data/testdata.csv data/testdata_100.csv
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# create test data sets
# - for 500
python generator.py -a 500 -t words -l 50
mv data/testdata.csv data/testdata_500.csv
# etc.
Figure 9: Test data generation script
4.2.3
Executing Benchmark
Now all prerequisites are fulfilled and the benchmark can be started. Also for this step an example script is available. Run the following command to benchmark KVP and hstore once with index
and once without based on the generated datasets in the previous script.
1
./step_3.sh
The ‘step_3.sh’ script includes the following statements.
1
2
3
4
5
6
7
8
9
10
11
12
#!/bin/bash
############
#for hstore
############
# - for 10
# - without index
python benchmark.py -t pgsqlhstore -s localhost -p 5432 -d
benchmark -u benchmark -w benchmark -a data/testdata_10.csv -l
-g -n
mv output/1.png output/hstore_10_1.png
mv output/2.png output/hstore_10_2.png
mv output/log.csv output/hstore_10_log.csv
mv output/log_summary.csv output/hstore_10_log_summary.csv
psql -d benchmark -c "EXPLAIN ANALYZE SELECT * FROM
bench_hstore WHERE hstore(bench_hstore)->'id'='7';" > output/analyze.log
mv output/analyze.log output/hstore_10_analyze.log
13
14
15 # - with index
16 python benchmark.py -t pgsqlhstore -s localhost -p 5432 -d
benchmark -u benchmark -w benchmark -a data/testdata_10.csv -i
-l -g -n
17 mv output/1.png output/hstore_10_index_1.png
18 mv output/2.png output/hstore_10_index_2.png
19 mv output/log.csv output/hstore_10_index_log.csv
20 mv output/log_summary.csv output/hstore_10_index_log_summary.csv
21 psql -d benchmark -c "EXPLAIN ANALYZE SELECT * FROM
bench_hstore WHERE hstore(bench_hstore)->'id'='7';" > output/analyze.log
22 mv output/analyze.log output/hstore_10_index_analyze.log
23
24 ############
25 #for KVP
26 ############
27 # - for 10
28 # - without index
29 python benchmark.py -t pgsql -s localhost -p 5432 -d benchmark
-u benchmark -w benchmark -a data/testdata_10.csv -l -g -n
30 mv output/1.png output/kvp_10_1.png
31 mv output/2.png output/kvp_10_2.png
32 mv output/log.csv output/kvp_10_log.csv
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33 mv output/log_summary.csv output/kvp_10_log_summary.csv
34 psql -d benchmark -c "EXPLAIN ANALYZE SELECT * FROM bench_kvp
WHERE bench_id = (SELECT bench_id FROM bench_kvp WHERE key =
'id' AND value = '7');" > output/analyze.log
35 mv output/analyze.log output/kvp_10_analyze.log
36
37 # - with index
38 python benchmark.py -t pgsql -s localhost -p 5432 -d benchmark
-u benchmark -w benchmark -a data/testdata_10.csv -i -l -g -n
39 mv output/1.png output/kvp_10_index_1.png
40 mv output/2.png output/kvp_10_index_2.png
41 mv output/log.csv output/kvp_10_index_log.csv
42 mv output/log_summary.csv output/kvp_10_index_log_summary.csv
43 psql -d benchmark -c "EXPLAIN ANALYZE SELECT * FROM bench_kvp
WHERE bench_id = (SELECT bench_id FROM bench_kvp WHERE key =
'id' AND value = '7');" > output/analyze.log
44 mv output/analyze.log output/kvp_10_index_analyze.log
# etc.
Figure 10: Benchmark script example
4.3
Results
The test has been executed in May 2011 based on the test design described in chapter Error!
Reference source not found. and the hardware specification in chapter 4.1. All the test logs
were aggregated into a single file showing the start and end time as well as the duration and the
average time in seconds per SELECT statement. The detail aggregation and the full extent diagrams can be reviewed in the appendix on page 32.
In general it can be said that the hstore performs much better than a KVP table schema. Nevertheless this general conclusion needs to be differentiated and a closer look on the different data
sets gives us a detailed understanding why the first assumption is not accurate enough.
On the first test run each data set has been tested twice, once without an index and once with an
index. For the KVP schema an index on the attribute ‘key’ has been used. This benchmark gave
the result as in Figure 11. In general, hstore does a really good job when querying a tuple by a
given key value pair. Specifically when using big data sets, which results in a lot of tuples in the
database table. One reason could be that hstore needs for storing arbitrary information only one
attribute on the same tuple as all the other information are stored. But more on that later in
chapter 4.4 Findings.
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Figure 11: Overview KVP vs. hstore benchmark
From 10 to approximately 500 records the KVP is much faster by querying a key value pair. Afterwards hstore demonstrates its strength especially when having more than 2’500 tuples in the
hstore table, whereas by using an index on the KVP table, hstore is faster by a factor of 4.04 and
without an index by a factor of 7.9. This sounds like KVP is a performance killer, which is not the
truth, because if we look at the absolute querying time per SELECT statement, than KVP needs in
average for 2’500 records heavy data set 0.01954 seconds (19.54 ms) without and 0.01512
seconds (15.12 ms) with an index compared to hstore 0.00484 seconds (4.84 ms) without and
0.00191 (1.91 ms) with index. The difference is only around 13 milliseconds per SELECT statement, which is not that much.
Figure 12: Benchmark KVP vs. hstore from 10 to 2.5K
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The circumstance changes, if we use a combined index for the KVP table on the attributes ‘key’
and ‘value’. Hstore is still a tick faster than the KVP schema, but the difference between the average SELECT transaction time for KVP indexed table shrunk extremely fast. Overall we can say
that the combined index comes very near to the hstore schema. Despite the fact that the combined index gives some performance boost, we can still see the problem, that the more tuples we
store in the KVP table the higher will be the difference between the hstore and the KVP. This concludes that the more arbitrary data results need to be store, the faster grows the combined index
and the longer needs PostgreSQL to find the right key value pair combination. But more on that
later in chapter 4.4 Findings.
Figure 13: Overview KVP hstore with combined index
For small data stets the KVP schema is still a little bit faster however this changes quickly by an
amount of circa 500 and more records / tuples per associative array.
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Figure 14: Benchmark KVP hstore from 10 to 2.5K with combined index
Having a nearer look to the data sets between 10 and 2’500 tuples we see that the average transaction time on a 2’500 big data set shrunk to 0.00948 (9.48 ms) from 0.01512 seconds (15.12
ms) that leads to the fact that a combined index is faster by a factor of 1.6.
15.12ms
» 1.6
9.48ms
Applying this calculation to the 35’000 big data set we become a factor of 1.72 because it shrunk
from 194.98 milliseconds to 113.2 milliseconds, which is not that much.
Figure 15: Overview of difference between KVP single and combined index
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Small data sets show a contrary perspective. From 10 to 500 records the difference between the
hstore and a KVP with a combined index is negative. This means that the KVP is faster then the
hstore. From more or less 500 records upwards hstore will be faster even only a little bit.
Figure 16: 10 to 2.5K: Difference between KVP single and combined index
The subsequent two diagrams show the KVP without and with and index on attribute ‘key’ as
well as with combined index against hstore with and without index. It depict that KVP with a
combined index comes very near to the hstore data type.
Figure 17: Overview of KVP with index on ‘key’ and combined index against hstore
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Figure 18: 10 to 2.5K: KVP with index on ‘key’ and combined index against hstore
Analyzing the indices of hstore and KVP shows, that KVP needs a lot more size on the disk to
build the index. Both an index on the attribute ‘key’ and a combined index on the attributes ‘key’
and ‘value’ whereat the combined index need more disk size then the index on the attribute ‘key’.
Surprisingly a GiST index on the hstore nees much less disk size even though GiST creates for
each unique key in the hstore an own index.
Figure 19: Index size overview
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Especially in the area of 1’000 tuples and more is the different significant. KVP with an index on
the attribute ‘key’ needs by 1’000 tuples 3.73 times more disk space than the GiST index on a
hstore and 3.55 times for the combined index.
Figure 20: Index size for 10 to 5’000 records
4.4
Findings
As described in the chapter 0
Results, hstore is by a factor of 7.9 faster than KVP with an index on the key attribute and 4.95
with a combined index by 2’500 records in an array. This can be traced back to the fact that KVP
needs much more units (cost)3 of work to get the right tuple, whereupon the size in bytes for a
single tuple is a lot lower. Lets say we want to save 2’500 array entries in a KVP and hstore
schema. For the hstore we have exactly 2’500 tuples in the database table
åarray entries = åtuples
as follow:
Database table:
bench_hstore
bench_id : BIGINT
bench_hstore : HSTORE
1
"id"=>"1", "comment"=>"lorem ipsum dolor sit amet consetetur sadipscing elitr sed diam nonumy eirmod tempor invidunt ut labore et dolore
magna aliquyam erat sed diam voluptua at vero eos et accusam et justo
The cost factor in the EXPLAIN result defines the cost to read a single database page from disk. It does not
relate to anything and therefore it can only be compared to other ‘cost’ units (Nasby, 2010).
3
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
duo dolores et ea rebum stet clita kasd gubergren no sea takimata sanctus est lorem ipsum dolor sit amet ", "surname"=>"ebsaveq", "forename"=>"maeznidus"
2
"id"=>"2", "zip"=>"6489", "comment"=>"lorem ipsum dolor sit amet consetetur sadipscing elitr sed diam nonumy eirmod tempor invidunt ut labore et dolore magna aliquyam erat sed diam voluptua at vero eos et accusam et justo duo dolores et ea rebum stet clita kasd gubergren no sea
takimata sanctus est lorem ipsum dolor sit amet ", "surname"=>"epofod",
"forename"=>"teer"
…
2500
"id"=>"2500", "comment"=>"lorem ipsum dolor sit amet consetetur sadipscing elitr sed diam nonumy eirmod tempor invidunt ut labore et dolore magna aliquyam erat sed diam voluptua at vero eos et accusam et
justo duo dolores et ea rebum stet clita kasd gubergren no sea takimata
sanctus est lorem ipsum dolor sit amet ", "forename"=>"sorietet"
Table 9: Hstore table abstract
What we need to do is to analyze an example query. As an example we take this one:
1
EXPLAIN ANALYZE SELECT * FROM bench_hstore
WHERE hstore(bench_hstore)->'id'='1735';
Listing 12: Explain Analyze statement for hstore without index
The analysis says that the cost for getting the first tuple is 0 and all tuples needs 213.72 cost
units. PostgreSQL thinks that he will return 45 rows each of a size of 40 bytes.
1
2
3
4
Seq Scan on bench_hstore (cost=0.00..213.72 rows=45 width=40)
(actual time=1.318..1.778 rows=1 loops=1)
Filter: ((bench_hstore -> 'id'::text) = '1735'::text)
Total runtime: 1.822 ms
(3 rows)
Listing 13: Output of Explain Analyze statement for hstore without index
The actual time shows the effectively milliseconds needed to execute the example statement.
PostgreSQL needed 1 loop, returned 1 row and required 1.822 milliseconds.
Hstore with an index needs to have another SELECT statement in the analyze query because the
hstore operator to query an indexed attribute is a little bit different. In hstore it can be done by
using the ‘@>’ operator.
1
EXPLAIN ANALYZE SELECT * FROM bench_hstore
WHERE bench_hstore @>'id=>1735';
Listing 14: Explain Analyze statement for hstore with index
The difference between a hstore without and with an index is, the hstore without an index is
doing a sequential scan for each SELECT statement. That means that it begins at tuple one and
continuous until the query is satisfied. When using an index at bitmap heap scan takes place.
PostgreSQL has found a small subset of tuples that can fulfill the query. The smaller set of tuples
to loop over enhances the performance to find the right tuple.
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Chapter 4: Benchmark Mai 2011
1
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Bitmap Heap Scan on bench_hstore
(cost=4.27..11.33 rows=2 width=218)
(actual time=0.481..0.534 rows=1 loops=1)
Recheck Cond: (bench_hstore @> '"id"=>"1735"'::hstore)
-> Bitmap Index Scan on hidx_2_5k
(cost=0.00..4.27 rows=2 width=0)
(actual time=0.308..0.308 rows=70 loops=1)
Index Cond: (bench_hstore @> '"id"=>"1735"'::hstore)
Total runtime: 0.721 ms
(5 rows)
2
3
4
5
6
Listing 15: Output of Explain Analyze statement for hstore with index
Now lets have a look at the KVP tables. Remember that we have in the schema two different
tables but we only need the table with the attributes ‘key’ and ‘value’. For the same amount of
array entries in the KVP table a multiple of tuples will be stored. Each key value pair entry in the
array needs to be a separate tuple in the table. If we have the following keys ‘id’, ‘surname’, ‘forname’, ‘zip’, and ‘comment’ for a 2’500 big array and each key in this array has an assigned value,
then it will results to 12’500 tuples in the database table. Compared to hstore it has 5 times more
tuples or to be more precise the sum of all filled keys.
åtuples = åvalue in the array , whereas value ¹ null
The database table includes then for each key value pair an own tuple:
Database table:
bench_kvp
bench_id : BIGINT
key : TEXT NOT NULL
value : TEXT
1
id
1
1
comment
lorem ipsum dolor sit amet consetetur sadipscing elitr sed diam nonumy eirmod tempor invidunt ut labore et dolore magna aliquyam erat
sed diam voluptua at vero eos et accusam et justo duo dolores et ea rebum stet clita kasd gubergren no sea takimata sanctus est lorem ipsum dolor sit amet
1
surname
Ebsaveq
1
forename
Maeznidus
2
id
2
2
zip
6489
2
comment
lorem ipsum dolor sit amet consetetur sadipscing elitr sed diam nonumy eirmod tempor invidunt ut labore et dolore magna aliquyam erat
sed diam voluptua at vero eos et accusam et justo duo dolores et ea rebum stet clita kasd gubergren no sea takimata sanctus est lorem ipsum dolor sit amet
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Chapter 4: Benchmark Mai 2011
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
2
surname
epofod
2
forename
Teer
…
…
…
2500
id
2500
2500
Comment
lorem ipsum dolor sit amet consetetur sadipscing elitr sed diam nonumy eirmod tempor invidunt ut labore et dolore magna aliquyam erat
sed diam voluptua at vero eos et accusam et justo duo dolores et ea rebum stet clita kasd gubergren no sea takimata sanctus est lorem ipsum dolor sit amet
2500
forename
sorietet
Table 10: KVP table abstract
Taking the same key value pair we used for hstore gives the following KVP SQL statement:
1
EXPLAIN ANALYZE SELECT * FROM bench_kvp
WHERE bench_id = (
SELECT bench_id FROM bench_kvp
WHERE key = 'id' AND value = '1735'
);
Listing 16: Explain Analyze statement for KVP
which results in the following EXPLAIN output:
1
2
3
4
5
6
Seq Scan on bench_kvp (cost=229.38..437.03 rows=3 width=60)
(actual time=3.125..3.579 rows=2 loops=1)
Filter: (bench_id = $0)
InitPlan 1 (returns $0)
-> Seq Scan on bench_kvp
(cost=0.00..229.38 rows=1 width=8)
(actual time=1.406..2.162 rows=1 loops=1)
Filter: ((key = 'id'::text) AND
(value = '1735'::text))
Total runtime: 3.607 ms
Listing 17: Output of Explain Analyze statement for KVP
To get the same result as for hstore two different sequences are needed. The inner sequence
looks for the key value pair and gives the unique identifier back. The sequence cost to get all
tuples back is 229.38 whereas each tuple is 8 bytes big. Then with the given identifier a second
sequence collects all tuples that relates to the given identifier. The cost for the first sequence begins where the inner sequence stops and ends at 437.03.
In a procedural language it works like this:
1
2
3
4
5
For each row in input_1
For each row in input_2
// Do_something
Next
Next
Listing 18: Programming example of explain sequences
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Chapter 4: Benchmark Mai 2011
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
The difficulty of creating an own hstore like database schema is, that more sequences and therefore more reads of pages on the disk are needed which results in higher cost units. The lower size
of the tuples in bytes does compensate the amount of pages to be read on the disk. Because in the
short run it looks like that at the best-case only 60 bytes for the first sequence and 8 bytes for
second sequence are needed. That is not the truth because if the first read in the second sequence
finds the key value pair, than 8 bytes are consumed. With the found identifier the first sequence
read all the tuples that match the identifier. In our case we have 5 key value pair combinations
that means 5 tuples in the KVP table. Each tuple consumes 60 bytes, which is for all 5 tuples 300
bytes, plus the 8 bytes for the second sequence results in a total size of 308 bytes. Compared to
the hstore in uses in the best-case only 213 bytes.
Using an index on the key attribute can enforce finding the unique identifier for a given key value
pair. Analyzing the technique shows that we have an additional sequence.
1
2
3
4
5
6
7
8
9
Seq Scan on bench_kvp (cost=199.48..406.88 rows=3 width=60)
(actual time=2.268..2.730 rows=2 loops=1)
Filter: (bench_id = $0)
InitPlan 1 (returns $0)
-> Bitmap Heap Scan on bench_kvp
(cost=62.99..199.48 rows=1 width=8)
(actual time=0.925..1.227 rows=1 loops=1)
Recheck Cond: (key = 'id'::text)
Filter: (value = '1735'::text)
-> Bitmap Index Scan on kvpidx
(cost=0.00..62.99 rows=2499 width=0)
(actual time=0.373..0.373 rows=2500 loops=1)
Index Cond: (key = 'id'::text)
Total runtime: 2.770 ms
Listing 19: Output of Explain Analyze statement for KVP with index on attribute ‘key’
It reads the index to find all the tuples, which have the given key and afterwards in the second
sequence PostgreSQL needs to find the value in a shorter list of key value pairs. This enables to
have an enhancement of factor 1.29, which is calculated by the average SELECT time without an
index divided by the average SELECT time with an index on the ‘key’ attribute.
19.54ms
» 1.29
15.12ms
Interesting is what happens if we take a combined index on the attributes ‘key’ and ‘value’. Again
we take the same statement as before
1
EXPLAIN ANALYZE SELECT * FROM bench_kvp
WHERE bench_id = (
SELECT bench_id FROM bench_kvp
WHERE key = 'id' AND value = '1735'
);
Listing 20: Explain Analyze statement for KVP
Using a combined index reduces the cost consumption by a factor of 2.06, calculated in the same
way as before: Average SELECT time without an index divided by the average SELECT time with a
combined index.
19.54ms
» 2.06
9.48ms
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Chapter 4: Benchmark Mai 2011
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
This factor results, because no additional sequence is needed, like we had it when using only an
index on the attribute ‘key’. The first index scan can directly find the unique identifier for a given
key value pair and reading afterward all tuples for that identifier. The bytes, which are needed to
gather the data, are exactly the same, as we needed for the first index alternative. In contrast to
the first alternative the combined index on the attributes ‘key’ and ‘value’ will grow very fast,
because for each key value pair combination a new entry in the index is needed. It is in the nature
of the key value pair philosophy, that only arbitrary unforeseen information is stored as key value pair and therefore the probability that an equal key value pair appears in the table is very unlikely.
1
2
3
4
5
6
7
Seq Scan on bench_kvp (cost=8.27..215.91 rows=3 width=60)
(actual time=1.376..1.954 rows=5 loops=1)
Filter: (bench_id = $0)
InitPlan 1 (returns $0)
-> Index Scan using kvpidx2 on bench_kvp
(cost=0.00..8.27 rows=1 width=8)
(actual time=0.048..0.049 rows=1 loops=1)
Index Cond: ((key = 'id'::text) AND
(value = '1735'::text))
Total runtime: 2.028 ms
(6 rows)
Listing 21: Output of Explain Analyze statement for KVP with combined index
Lastly we need to have a short look on the hstore implementation. Please consider for that chapter 2.3.2 Working principle.
Lets take the following hstore example:
bench_id : BIGINT
bench_hstore : HSTORE
1
"zip"=>"8000 ", "surname"=>"ebsaveq", "forename"=>"maeznidus"
2
"zip"=>"6489", "surname"=>"epofod", "forename"=>"teer"
3
"zip"=>"8000 ", "surname"=>"kjuefs", "forename"=>"beer"
Table 11: Hstore tuple examples
Now we want to find all names how lives in the region with zip code 8000. For that, we need the
following SQL statement:
1
SELECT hstore(bench_hstore)->’surname’ FROM bench_hstore
WHERE hstore(bench_hstore)->'zip’=’8000';
Listing 22: Querying all person how lives in region with zip code ‘8000’
In this example PostgreSQL calls six times the ‘fetchval’ function, because it loops over each tuple
and calls the function twice. Once to get the value of the attribute ‘surname’ and once the get the
‘zip’ so that PostgreSQL can compare the returned value with the value ‘8000’. When PostgreSQL
is calling the ‘fetchval’ function he hands the array over to the C function ‘hstore_fetchval’, which
finds the key in the buffer. Based on the buffer entry it knows on which position begins the value
and how long it is. For the key ‘zip’ and the first tuple it would be something like start position 8
and length 4. So know hstore can substring the array and return the value ‘8000’ back to PostgreSQL, which will then compare it with the given value after the equals sign.
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Chapter 4: Benchmark Mai 2011
4.5
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Conclusion
As described in the previous chapters hstore perform much faster then a KVP schema described
in chapter 2.2. The stored data of type hstore are not lost in the database and can be migrated
with a minimum of effort to another schema, because it is stored as string in the form of an associative array in the database. In addition, hstore provides PostgreSQL functions to transform the
associative array into a column row like table, as it is know in every database management system. The keys in the associative array are transposed to columns and each row in the array is a
tuple in the column row like table. The values are transformed to the values in a tuple. Therefore
the fear for a later migration should not be the criteria of not using hstore.
Also the way how it is implemented nees much less size on the disk for the indices and costs less
performance. This shows the explain analysis in chapter 4.4 and the graphs on page 24 and 25.
The cost of reading data is much lower then the one of a KVP schema. To remember, the cost defines a factor of reading a page from the disk. The higher it is the more it needs to read on the
disk and the slower it will be. In addition hstore buffers all the keys and values to provide a faster
read and along a single buffer entry it stores the position of the key and value in the string, which
is of type hstore in the database table that represents the associative array. That means when
hstore found the key it does not need to substring the string because it already knows the position in the string.
Thus, it is to consider that for small datasets hstore is not the preferable method to store key value pairs. Especially when having an array size of 1 to more or less 500 records. At this size a KVP
schema is preferable. The problem we face here is at the beginning we do not have a lot of
records in the table. But when the time goes over the 500 records limit can be easily exceeded
and then switching from the KVP schema to the hstore is not that easy, because not only the data
need to be transformed to the hstore array but also the database tables and all the SQL statements for querying, inserting, modifying and deleting records need to be changed to the new
schema. The conclusion is to first think about how many data will be expected during the database table lifetime and then choosing the right schema. If you are unsure which one you should
take, my succession is to use hstore as default, because the difference of the average querying
time between the KVP and the hstore schema is at 500 records only -0.45 milliseconds, which
means that KVP is 0.45 ms faster.
To summarize, hstore provides in general a faster mechanism to store key value pairs. It is easy
to use and offers a lot of operations to compare, transform, and search for data. Not only the performance but also the pagings and bytes which are needed to get the data for a given key value
pair is better than setting up an own key value pair schema. All in all hstore is the preferable way
of storing arbitrary unforeseen information in a database table.
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Bibliography
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
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Appendix
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Appendix
Benchmark with KVP index on attribute ‘key’
Benchmark of hstore and KVP once with index (w) and once without index (o). For KVP an index
on the attribute ‘key’ has been choosen.
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Appendix
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
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Appendix
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
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Appendix
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Benchmark with combined KVP index
Benchmark of hstore and KVP once with index (w) and once without index (o). For KVP a combined index on the attribute ‘key’ and ‘value’ has been choosen.
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Appendix
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
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Appendix
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Differences between KVP and hstore
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Appendix
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
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Appendix
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
Average SELECT time for KVP and hstore
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
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Appendix
Key/Value Pair versus hstore
Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
KVP and hstore index sizes
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Benchmarking Entity-Attribute-Value Structures in PostgreSQL.
44
