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DBD::SQLite(3) User Contributed Perl Documentation DBD::SQLite(3)
NAME
DBD::SQLite - Self-contained RDBMS in a DBI Driver
SYNOPSIS
use DBI;
my $dbh = DBI->connect("dbi:SQLite:dbname=$dbfile","","");
DESCRIPTION
SQLite is a public domain file-based relational database engine that you can find at
<http://www.sqlite.org/>.
DBD::SQLite is a Perl DBI driver for SQLite, that includes the entire thing in the distribution. So
in order to get a fast transaction capable RDBMS working for your perl project you simply have to
install this module, and nothing else.
SQLite supports the following features:
Implements a large subset of SQL92
See <http://www.sqlite.org/lang.html> for details.
A complete DB in a single disk file
Everything for your database is stored in a single disk file, making it easier to move things
around than with DBD::CSV.
Atomic commit and rollback
Yes, DBD::SQLite is small and light, but it supports full transactions!
Extensible
User-defined aggregate or regular functions can be registered with the SQL parser.
There's lots more to it, so please refer to the docs on the SQLite web page, listed above, for SQL
details. Also refer to DBI for details on how to use DBI itself. The API works like every DBI module
does. However, currently many statement attributes are not implemented or are limited by the
typeless nature of the SQLite database.
NOTABLE DIFFERENCES FROM OTHER DRIVERS
Database Name Is A File Name
SQLite creates a file per a database. You should pass the "path" of the database file (with or
without a parent directory) in the DBI connection string (as a database "name"):
my $dbh = DBI->connect("dbi:SQLite:dbname=$dbfile","","");
The file is opened in read/write mode, and will be created if it does not exist yet.
Although the database is stored in a single file, the directory containing the database file must be
writable by SQLite because the library will create several temporary files there.
If the filename $dbfile is ":memory:", then a private, temporary in-memory database is created for
the connection. This in-memory database will vanish when the database connection is closed. It is
handy for your library tests.
Note that future versions of SQLite might make use of additional special filenames that begin with
the ":" character. It is recommended that when a database filename actually does begin with a ":"
character you should prefix the filename with a pathname such as "./" to avoid ambiguity.
If the filename $dbfile is an empty string, then a private, temporary on-disk database will be
created. This private database will be automatically deleted as soon as the database connection is
closed.
Accessing A Database With Other Tools
To access the database from the command line, try using "dbish" which comes with the DBI::Shell
module. Just type:
dbish dbi:SQLite:foo.db
On the command line to access the file foo.db.
Alternatively you can install SQLite from the link above without conflicting with DBD::SQLite and use
the supplied "sqlite3" command line tool.
Blobs
As of version 1.11, blobs should "just work" in SQLite as text columns. However this will cause the
data to be treated as a string, so SQL statements such as length(x) will return the length of the
column as a NUL terminated string, rather than the size of the blob in bytes. In order to store
natively as a BLOB use the following code:
use DBI qw(:sql_types);
my $dbh = DBI->connect("dbi:SQLite:dbfile","","");
my $blob = `cat foo.jpg`;
my $sth = $dbh->prepare("INSERT INTO mytable VALUES (1, ?)");
$sth->bind_param(1, $blob, SQL_BLOB);
$sth->execute();
And then retrieval just works:
$sth = $dbh->prepare("SELECT * FROM mytable WHERE id = 1");
$sth->execute();
my $row = $sth->fetch;
my $blobo = $row->[1];
# now $blobo == $blob
Functions And Bind Parameters
As of this writing, a SQL that compares a return value of a function with a numeric bind value like
this doesn't work as you might expect.
my $sth = $dbh->prepare(q{
SELECT bar FROM foo GROUP BY bar HAVING count(*) > ?;
});
$sth->execute(5);
This is because DBD::SQLite assumes that all the bind values are text (and should be quoted) by
default. Thus the above statement becomes like this while executing:
SELECT bar FROM foo GROUP BY bar HAVING count(*) > "5";
There are three workarounds for this.
Use bind_param() explicitly
As shown above in the "BLOB" section, you can always use "bind_param()" to tell the type of a
bind value.
use DBI qw(:sql_types); # Don't forget this
my $sth = $dbh->prepare(q{
SELECT bar FROM foo GROUP BY bar HAVING count(*) > ?;
});
$sth->bind_param(1, 5, SQL_INTEGER);
$sth->execute();
Add zero to make it a number
This is somewhat weird, but works anyway.
my $sth = $dbh->prepare(q{
SELECT bar FROM foo GROUP BY bar HAVING count(*) > (? + 0);
});
$sth->execute(5);
Set "sqlite_see_if_its_a_number" database handle attribute
As of version 1.32_02, you can use "sqlite_see_if_its_a_number" to let DBD::SQLite to see if the
bind values are numbers or not.
$dbh->{sqlite_see_if_its_a_number} = 1;
my $sth = $dbh->prepare(q{
SELECT bar FROM foo GROUP BY bar HAVING count(*) > ?;
});
$sth->execute(5);
You can set it to true when you connect to a database.
my $dbh = DBI->connect('dbi:SQLite:foo', undef, undef, {
AutoCommit => 1,
RaiseError => 1,
sqlite_see_if_its_a_number => 1,
});
This is the most straightforward solution, but as noted above, existing data in your databases
created by DBD::SQLite have not always been stored as numbers, so this *might* cause other
obscure problems. Use this sparingly when you handle existing databases. If you handle databases
created by other tools like native "sqlite3" command line tool, this attribute would help you.
Placeholders
SQLite supports several placeholder expressions, including "?" and ":AAAA". Consult the DBI and
sqlite documentation for details.
<http://www.sqlite.org/lang_expr.html#varparam>
Note that a question mark actually means a next unused (numbered) placeholder. You're advised not to
use it with other (numbered or named) placeholders to avoid confusion.
my $sth = $dbh->prepare(
'update TABLE set a=?1 where b=?2 and a IS NOT ?1'
);
$sth->execute(1, 2);
Foreign Keys
BE PREPARED! WOLVES APPROACH!!
SQLite has started supporting foreign key constraints since 3.6.19 (released on Oct 14, 2009; bundled
in DBD::SQLite 1.26_05). To be exact, SQLite has long been able to parse a schema with foreign keys,
but the constraints has not been enforced. Now you can issue a pragma actually to enable this feature
and enforce the constraints.
To do this, issue the following pragma (see below), preferably as soon as you connect to a database
and you're not in a transaction:
$dbh->do("PRAGMA foreign_keys = ON");
And you can explicitly disable the feature whenever you like by turning the pragma off:
$dbh->do("PRAGMA foreign_keys = OFF");
As of this writing, this feature is disabled by default by the sqlite team, and by us, to secure
backward compatibility, as this feature may break your applications, and actually broke some for us.
If you have used a schema with foreign key constraints but haven't cared them much and supposed
they're always ignored for SQLite, be prepared, and please do extensive testing to ensure that your
applications will continue to work when the foreign keys support is enabled by default. It is very
likely that the sqlite team will turn it default-on in the future, and we plan to do it NO LATER THAN
they do so.
See <http://www.sqlite.org/foreignkeys.html> for details.
Pragma
SQLite has a set of "Pragma"s to modifiy its operation or to query for its internal data. These are
specific to SQLite and are not likely to work with other DBD libraries, but you may find some of
these are quite useful. DBD::SQLite actually sets some (like "show_datatypes") for you when you
connect to a database. See <http://www.sqlite.org/pragma.html> for details.
Transactions
DBI/DBD::SQLite's transactions may be a bit confusing. They behave differently according to the
status of the "AutoCommit" flag:
When the AutoCommit flag is on
You're supposed to always use the auto-commit mode, except you explicitly begin a transaction,
and when the transaction ended, you're supposed to go back to the auto-commit mode. To begin a
transaction, call "begin_work" method, or issue a "BEGIN" statement. To end it, call
"commit/rollback" methods, or issue the corresponding statements.
$dbh->{AutoCommit} = 1;
$dbh->begin_work; # or $dbh->do('BEGIN TRANSACTION');
# $dbh->{AutoCommit} is turned off temporarily during a transaction;
$dbh->commit; # or $dbh->do('COMMIT');
# $dbh->{AutoCommit} is turned on again;
When the AutoCommit flag is off
You're supposed to always use the transactional mode, until you explicitly turn on the AutoCommit
flag. You can explicitly issue a "BEGIN" statement (only when an actual transaction has not begun
yet) but you're not allowed to call "begin_work" method (if you don't issue a "BEGIN", it will be
issued internally). You can commit or roll it back freely. Another transaction will
automatically begins if you execute another statement.
$dbh->{AutoCommit} = 0;
# $dbh->do('BEGIN TRANSACTION') is not necessary, but possible
...
$dbh->commit; # or $dbh->do('COMMIT');
# $dbh->{AutoCommit} stays intact;
$dbh->{AutoCommit} = 1; # ends the transactional mode
This "AutoCommit" mode is independent from the autocommit mode of the internal SQLite library, which
always begins by a "BEGIN" statement, and ends by a "COMMIT" or a <ROLLBACK>.
Transaction and Database Locking
Transaction by "AutoCommit" or "begin_work" is nice and handy, but sometimes you may get an annoying
"database is locked" error. This typically happens when someone begins a transaction, and tries to
write to a database while other person is reading from the database (in another transaction). You
might be surprised but SQLite doesn't lock a database when you just begin a normal (deferred)
transaction to maximize concurrency. It reserves a lock when you issue a statement to write, but
until you actually try to write with a "commit" statement, it allows other people to read from the
database. However, reading from the database also requires "shared lock", and that prevents to give
you the "exclusive lock" you reserved, thus you get the "database is locked" error, and other people
will get the same error if they try to write afterwards, as you still have a "pending" lock.
"busy_timeout" doesn't help in this case.
To avoid this, set a transaction type explicitly. You can issue a "begin immediate transaction" (or
"begin exclusive transaction") for each transaction, or set "sqlite_use_immediate_transaction"
database handle attribute to true (since 1.30_02) to always use an immediate transaction (even when
you simply use "begin_work" or turn off the "AutoCommit".).
my $dbh = DBI->connect("dbi:SQLite::memory:", "", "", {
sqlite_use_immediate_transaction => 1,
});
Note that this works only when all of the connections use the same (non-deferred) transaction. See
<http://sqlite.org/lockingv3.html> for locking details.
"$sth->finish" and Transaction Rollback
As the DBI doc says, you almost certainly do not need to call "finish" in DBI method if you fetch all
rows (probably in a loop). However, there are several exceptions to this rule, and rolling-back of
an unfinished "SELECT" statement is one of such exceptional cases.
SQLite prohibits "ROLLBACK" of unfinished "SELECT" statements in a transaction (See
<http://sqlite.org/lang_transaction.html> for details). So you need to call "finish" before you issue
a rollback.
$sth = $dbh->prepare("SELECT * FROM t");
$dbh->begin_work;
eval {
$sth->execute;
$row = $sth->fetch;
...
die "For some reason";
...
};
if($@) {
$sth->finish; # You need this for SQLite
$dbh->rollback;
} else {
$dbh->commit;
}
Processing Multiple Statements At A Time
DBI's statement handle is not supposed to process multiple statements at a time. So if you pass a
string that contains multiple statements (a "dump") to a statement handle (via "prepare" or "do"),
DBD::SQLite only processes the first statement, and discards the rest.
Since 1.30_01, you can retrieve those ignored (unprepared) statements via
"$sth->{sqlite_unprepared_statements}". It usually contains nothing but white spaces, but if you
really care, you can check this attribute to see if there's anything left undone. Also, if you set a
"sqlite_allow_multiple_statements" attribute of a database handle to true when you connect to a
database, "do" method automatically checks the "sqlite_unprepared_statements" attribute, and if it
finds anything undone (even if what's left is just a single white space), it repeats the process
again, to the end.
Performance
SQLite is fast, very fast. Matt processed his 72MB log file with it, inserting the data (400,000+
rows) by using transactions and only committing every 1000 rows (otherwise the insertion is quite
slow), and then performing queries on the data.
Queries like count(*) and avg(bytes) took fractions of a second to return, but what surprised him
most of all was:
SELECT url, count(*) as count
FROM access_log
GROUP BY url
ORDER BY count desc
LIMIT 20
To discover the top 20 hit URLs on the site (<http://axkit.org>), and it returned within 2 seconds.
He was seriously considering switching his log analysis code to use this little speed demon!
Oh yeah, and that was with no indexes on the table, on a 400MHz PIII.
For best performance be sure to tune your hdparm settings if you are using linux. Also you might want
to set:
PRAGMA synchronous = OFF
Which will prevent sqlite from doing fsync's when writing (which slows down non-transactional writes
significantly) at the expense of some peace of mind. Also try playing with the cache_size pragma.
The memory usage of SQLite can also be tuned using the cache_size pragma.
$dbh->do("PRAGMA cache_size = 800000");
The above will allocate 800M for DB cache; the default is 2M. Your sweet spot probably lies
somewhere in between.
DRIVER PRIVATE ATTRIBUTES
Database Handle Attributes
sqlite_version
Returns the version of the SQLite library which DBD::SQLite is using, e.g., "2.8.0". Can only be
read.
sqlite_unicode
If set to a true value, DBD::SQLite will turn the UTF-8 flag on for all text strings coming out
of the database (this feature is currently disabled for perl < 5.8.5). For more details on the
UTF-8 flag see perlunicode. The default is for the UTF-8 flag to be turned off.
Also note that due to some bizarreness in SQLite's type system (see
<http://www.sqlite.org/datatype3.html>), if you want to retain blob-style behavior for some
columns under "$dbh->{sqlite_unicode} = 1" (say, to store images in the database), you have to
state so explicitly using the 3-argument form of "bind_param" in DBI when doing updates:
use DBI qw(:sql_types);
$dbh->{sqlite_unicode} = 1;
my $sth = $dbh->prepare("INSERT INTO mytable (blobcolumn) VALUES (?)");
# Binary_data will be stored as is.
$sth->bind_param(1, $binary_data, SQL_BLOB);
Defining the column type as "BLOB" in the DDL is not sufficient.
This attribute was originally named as "unicode", and renamed to "sqlite_unicode" for integrity
since version 1.26_06. Old "unicode" attribute is still accessible but will be deprecated in the
near future.
sqlite_allow_multiple_statements
If you set this to true, "do" method will process multiple statements at one go. This may be
handy, but with performance penalty. See above for details.
sqlite_use_immediate_transaction
If you set this to true, DBD::SQLite tries to issue a "begin immediate transaction" (instead of
"begin transaction") when necessary. See above for details.
sqlite_see_if_its_a_number
If you set this to true, DBD::SQLite tries to see if the bind values are number or not, and does
not quote if they are numbers. See above for details.
Statement Handle Attributes
sqlite_unprepared_statements
Returns an unprepared part of the statement you pass to "prepare". Typically this contains
nothing but white spaces after a semicolon. See above for details.
METHODS
See also to the DBI documentation for the details of other common methods.
table_info
$sth = $dbh->table_info(undef, $schema, $table, $type, \%attr);
Returns all tables and schemas (databases) as specified in "table_info" in DBI. The schema and table
arguments will do a "LIKE" search. You can specify an ESCAPE character by including an 'Escape'
attribute in \%attr. The $type argument accepts a comma separated list of the following types
'TABLE', 'VIEW', 'LOCAL TEMPORARY' and 'SYSTEM TABLE' (by default all are returned). Note that a
statement handle is returned, and not a direct list of tables.
The following fields are returned:
TABLE_CAT: Always NULL, as SQLite does not have the concept of catalogs.
TABLE_SCHEM: The name of the schema (database) that the table or view is in. The default schema is
'main', temporary tables are in 'temp' and other databases will be in the name given when the
database was attached.
TABLE_NAME: The name of the table or view.
TABLE_TYPE: The type of object returned. Will be one of 'TABLE', 'VIEW', 'LOCAL TEMPORARY' or 'SYSTEM
TABLE'.
primary_key, primary_key_info
@names = $dbh->primary_key(undef, $schema, $table);
$sth = $dbh->primary_key_info(undef, $schema, $table, \%attr);
You can retrieve primary key names or more detailed information. As noted above, SQLite does not
have the concept of catalogs, so the first argument of the mothods is usually "undef", and you'll
usually set "undef" for the second one (unless you want to know the primary keys of temporary
tables).
DRIVER PRIVATE METHODS
The following methods can be called via the func() method with a little tweak, but the use of func()
method is now discouraged by the DBI author for various reasons (see DBI's document
http://search.cpan.org/dist/DBI/lib/DBI/DBD.pm#Using_install_method()_to_expose_driver-private_methods
<http://search .cpan.org/dist/DBI/lib/DBI/DBD.pm#Using_install_method () _to_expose_driver-
private_methods> for details). So, if you're using DBI >= 1.608, use these "sqlite_" methods. If you
need to use an older DBI, you can call these like this:
$dbh->func( ..., "(method name without sqlite_ prefix)" );
Exception: "sqlite_trace" should always be called as is, even with "func()" method (to avoid conflict
with DBI's trace() method).
$dbh->func( ..., "sqlite_trace");
$dbh->sqlite_last_insert_rowid()
This method returns the last inserted rowid. If you specify an INTEGER PRIMARY KEY as the first
column in your table, that is the column that is returned. Otherwise, it is the hidden ROWID column.
See the sqlite docs for details.
Generally you should not be using this method. Use the DBI last_insert_id method instead. The usage
of this is:
$h->last_insert_id($catalog, $schema, $table_name, $field_name [, \%attr ])
Running "$h->last_insert_id("","","","")" is the equivalent of running
"$dbh->sqlite_last_insert_rowid()" directly.
$dbh->sqlite_busy_timeout()
Retrieve the current busy timeout.
$dbh->sqlite_busy_timeout( $ms )
Set the current busy timeout. The timeout is in milliseconds.
$dbh->sqlite_create_function( $name, $argc, $code_ref )
This method will register a new function which will be usable in an SQL query. The method's
parameters are:
$name
The name of the function. This is the name of the function as it will be used from SQL.
$argc
The number of arguments taken by the function. If this number is -1, the function can take any
number of arguments.
$code_ref
This should be a reference to the function's implementation.
For example, here is how to define a now() function which returns the current number of seconds since
the epoch:
$dbh->sqlite_create_function( 'now', 0, sub { return time } );
After this, it could be use from SQL as:
INSERT INTO mytable ( now() );
REGEXP function
SQLite includes syntactic support for an infix operator 'REGEXP', but without any implementation. The
"DBD::SQLite" driver automatically registers an implementation that performs standard perl regular
expression matching, using current locale. So for example you can search for words starting with an
'A' with a query like
SELECT * from table WHERE column REGEXP '\bA\w+'
If you want case-insensitive searching, use perl regex flags, like this :
SELECT * from table WHERE column REGEXP '(?i:\bA\w+)'
The default REGEXP implementation can be overridden through the "create_function" API described
above.
Note that regexp matching will not use SQLite indices, but will iterate over all rows, so it could be
quite costly in terms of performance.
$dbh->sqlite_create_collation( $name, $code_ref )
This method manually registers a new function which will be usable in an SQL query as a COLLATE
option for sorting. Such functions can also be registered automatically on demand: see section
"COLLATION FUNCTIONS" below.
The method's parameters are:
$name
The name of the function exposed to SQL.
$code_ref
Reference to the function's implementation. The driver will check that this is a proper sorting
function.
$dbh->sqlite_collation_needed( $code_ref )
This method manually registers a callback function that will be invoked whenever an undefined
collation sequence is required from an SQL statement. The callback is invoked as
$code_ref->($dbh, $collation_name)
and should register the desired collation using "sqlite_create_collation".
An initial callback is already registered by "DBD::SQLite", so for most common cases it will be
simpler to just add your collation sequences in the %DBD::SQLite::COLLATION hash (see section
"COLLATION FUNCTIONS" below).
$dbh->sqlite_create_aggregate( $name, $argc, $pkg )
This method will register a new aggregate function which can then be used from SQL. The method's
parameters are:
$name
The name of the aggregate function, this is the name under which the function will be available
from SQL.
$argc
This is an integer which tells the SQL parser how many arguments the function takes. If that
number is -1, the function can take any number of arguments.
$pkg
This is the package which implements the aggregator interface.
The aggregator interface consists of defining three methods:
new()
This method will be called once to create an object which should be used to aggregate the rows in
a particular group. The step() and finalize() methods will be called upon the reference return by
the method.
step(@_)
This method will be called once for each row in the aggregate.
finalize()
This method will be called once all rows in the aggregate were processed and it should return the
aggregate function's result. When there is no rows in the aggregate, finalize() will be called
right after new().
Here is a simple aggregate function which returns the variance (example adapted from pysqlite):
package variance;
sub new { bless [], shift; }
sub step {
my ( $self, $value ) = @_;
push @$self, $value;
}
sub finalize {
my $self = $_[0];
my $n = @$self;
# Variance is NULL unless there is more than one row
return undef unless $n || $n == 1;
my $mu = 0;
foreach my $v ( @$self ) {
$mu += $v;
}
$mu /= $n;
my $sigma = 0;
foreach my $v ( @$self ) {
$sigma += ($x - $mu)**2;
}
$sigma = $sigma / ($n - 1);
return $sigma;
}
$dbh->sqlite_create_aggregate( "variance", 1, 'variance' );
The aggregate function can then be used as:
SELECT group_name, variance(score)
FROM results
GROUP BY group_name;
For more examples, see the DBD::SQLite::Cookbook.
$dbh->sqlite_progress_handler( $n_opcodes, $code_ref )
This method registers a handler to be invoked periodically during long running calls to SQLite.
An example use for this interface is to keep a GUI updated during a large query. The parameters are:
$n_opcodes
The progress handler is invoked once for every $n_opcodes virtual machine opcodes in SQLite.
$code_ref
Reference to the handler subroutine. If the progress handler returns non-zero, the SQLite
operation is interrupted. This feature can be used to implement a "Cancel" button on a GUI dialog
box.
Set this argument to "undef" if you want to unregister a previous progress handler.
$dbh->sqlite_commit_hook( $code_ref )
This method registers a callback function to be invoked whenever a transaction is committed. Any
callback set by a previous call to "sqlite_commit_hook" is overridden. A reference to the previous
callback (if any) is returned. Registering an "undef" disables the callback.
When the commit hook callback returns zero, the commit operation is allowed to continue normally. If
the callback returns non-zero, then the commit is converted into a rollback (in that case, any
attempt to explicitly call "$dbh->rollback()" afterwards would yield an error).
$dbh->sqlite_rollback_hook( $code_ref )
This method registers a callback function to be invoked whenever a transaction is rolled back. Any
callback set by a previous call to "sqlite_rollback_hook" is overridden. A reference to the previous
callback (if any) is returned. Registering an "undef" disables the callback.
$dbh->sqlite_update_hook( $code_ref )
This method registers a callback function to be invoked whenever a row is updated, inserted or
deleted. Any callback set by a previous call to "sqlite_update_hook" is overridden. A reference to
the previous callback (if any) is returned. Registering an "undef" disables the callback.
The callback will be called as
$code_ref->($action_code, $database, $table, $rowid)
where
$action_code
is an integer equal to either "DBD::SQLite::INSERT", "DBD::SQLite::DELETE" or
"DBD::SQLite::UPDATE" (see "Action Codes");
$database
is the name of the database containing the affected row;
$table
is the name of the table containing the affected row;
$rowid
is the unique 64-bit signed integer key of the affected row within that table.
$dbh->sqlite_set_authorizer( $code_ref )
This method registers an authorizer callback to be invoked whenever SQL statements are being compiled
by the "prepare" in DBI method. The authorizer callback should return "DBD::SQLite::OK" to allow the
action, "DBD::SQLite::IGNORE" to disallow the specific action but allow the SQL statement to continue
to be compiled, or "DBD::SQLite::DENY" to cause the entire SQL statement to be rejected with an
error. If the authorizer callback returns any other value, then then "prepare" call that triggered
the authorizer will fail with an error message.
An authorizer is used when preparing SQL statements from an untrusted source, to ensure that the SQL
statements do not try to access data they are not allowed to see, or that they do not try to execute
malicious statements that damage the database. For example, an application may allow a user to enter
arbitrary SQL queries for evaluation by a database. But the application does not want the user to be
able to make arbitrary changes to the database. An authorizer could then be put in place while the
user-entered SQL is being prepared that disallows everything except SELECT statements.
The callback will be called as
$code_ref->($action_code, $string1, $string2, $database, $trigger_or_view)
where
$action_code
is an integer that specifies what action is being authorized (see "Action Codes").
$string1, $string2
are strings that depend on the action code (see "Action Codes").
$database
is the name of the database ("main", "temp", etc.) if applicable.
$trigger_or_view
is the name of the inner-most trigger or view that is responsible for the access attempt, or
"undef" if this access attempt is directly from top-level SQL code.
$dbh->sqlite_backup_from_file( $filename )
This method accesses the SQLite Online Backup API, and will take a backup of the named database file,
copying it to, and overwriting, your current database connection. This can be particularly handy if
your current connection is to the special :memory: database, and you wish to populate it from an
existing DB.
$dbh->sqlite_backup_to_file( $filename )
This method accesses the SQLite Online Backup API, and will take a backup of the currently connected
database, and write it out to the named file.
$dbh->sqlite_enable_load_extension( $bool )
Calling this method with a true value enables loading (external) sqlite3 extensions. After the call,
you can load extensions like this:
$dbh->sqlite_enable_load_extension(1);
$sth = $dbh->prepare("select load_extension('libsqlitefunctions.so')")
or die "Cannot prepare: " . $dbh->errstr();
$dbh->sqlite_trace( $code_ref )
This method registers a trace callback to be invoked whenever SQL statements are being run.
The callback will be called as
$code_ref->($statement)
where
$statement
is a UTF-8 rendering of the SQL statement text as the statement first begins executing.
Additional callbacks might occur as each triggered subprogram is entered. The callbacks for triggers
contain a UTF-8 SQL comment that identifies the trigger.
See also "TRACING" in DBI for better tracing options.
$dbh->sqlite_profile( $code_ref )
This method registers a profile callback to be invoked whenever a SQL statement finishes.
The callback will be called as
$code_ref->($statement, $elapsed_time)
where
$statement
is the original statement text (without bind parameters).
$elapsed_time
is an estimate of wall-clock time of how long that statement took to run (in milliseconds).
This method is considered experimental and is subject to change in future versions of SQLite.
See also DBI::Profile for better profiling options.
DBD::SQLite::compile_options()
Returns an array of compile options (available since sqlite 3.6.23, bundled in DBD::SQLite 1.30_01),
or an empty array if the bundled library is old or compiled with SQLITE_OMIT_COMPILEOPTION_DIAGS.
DRIVER CONSTANTS
A subset of SQLite C constants are made available to Perl, because they may be needed when writing
hooks or authorizer callbacks. For accessing such constants, the "DBD::SQLite" module must be
explicitly "use"d at compile time. For example, an authorizer that forbids any DELETE operation would
be written as follows :
use DBD::SQLite;
$dbh->sqlite_set_authorizer(sub {
my $action_code = shift;
return $action_code == DBD::SQLite::DELETE ? DBD::SQLite::DENY
: DBD::SQLite::OK;
});
The list of constants implemented in "DBD::SQLite" is given below; more information can be found ad
at <http://www.sqlite.org/c3ref/constlist.html>.
Authorizer Return Codes
OK
DENY
IGNORE
Action Codes
The "set_authorizer" method registers a callback function that is invoked to authorize certain SQL
statement actions. The first parameter to the callback is an integer code that specifies what action
is being authorized. The second and third parameters to the callback are strings, the meaning of
which varies according to the action code. Below is the list of action codes, together with their
associated strings.
# constant string1 string2
# ======== ======= =======
CREATE_INDEX Index Name Table Name
CREATE_TABLE Table Name undef
CREATE_TEMP_INDEX Index Name Table Name
CREATE_TEMP_TABLE Table Name undef
CREATE_TEMP_TRIGGER Trigger Name Table Name
CREATE_TEMP_VIEW View Name undef
CREATE_TRIGGER Trigger Name Table Name
CREATE_VIEW View Name undef
DELETE Table Name undef
DROP_INDEX Index Name Table Name
DROP_TABLE Table Name undef
DROP_TEMP_INDEX Index Name Table Name
DROP_TEMP_TABLE Table Name undef
DROP_TEMP_TRIGGER Trigger Name Table Name
DROP_TEMP_VIEW View Name undef
DROP_TRIGGER Trigger Name Table Name
DROP_VIEW View Name undef
INSERT Table Name undef
PRAGMA Pragma Name 1st arg or undef
READ Table Name Column Name
SELECT undef undef
TRANSACTION Operation undef
UPDATE Table Name Column Name
ATTACH Filename undef
DETACH Database Name undef
ALTER_TABLE Database Name Table Name
REINDEX Index Name undef
ANALYZE Table Name undef
CREATE_VTABLE Table Name Module Name
DROP_VTABLE Table Name Module Name
FUNCTION undef Function Name
SAVEPOINT Operation Savepoint Name
COLLATION FUNCTIONS
Definition
SQLite v3 provides the ability for users to supply arbitrary comparison functions, known as user-defined userdefined
defined "collation sequences" or "collating functions", to be used for comparing two text values.
<http://www.sqlite.org/datatype3.html#collation> explains how collations are used in various SQL
expressions.
Builtin collation sequences
The following collation sequences are builtin within SQLite :
BINARY
Compares string data using memcmp(), regardless of text encoding.
NOCASE
The same as binary, except the 26 upper case characters of ASCII are folded to their lower case
equivalents before the comparison is performed. Note that only ASCII characters are case folded.
SQLite does not attempt to do full UTF case folding due to the size of the tables required.
RTRIM
The same as binary, except that trailing space characters are ignored.
In addition, "DBD::SQLite" automatically installs the following collation sequences :
perl
corresponds to the Perl "cmp" operator
perllocale
Perl "cmp" operator, in a context where "use locale" is activated.
Usage
You can write for example
CREATE TABLE foo(
txt1 COLLATE perl,
txt2 COLLATE perllocale,
txt3 COLLATE nocase
)
or
SELECT * FROM foo ORDER BY name COLLATE perllocale
Unicode handling
If the attribute "$dbh->{sqlite_unicode}" is set, strings coming from the database and passed to the
collation function will be properly tagged with the utf8 flag; but this only works if the
"sqlite_unicode" attribute is set before the first call to a perl collation sequence . The
recommended way to activate unicode is to set the parameter at connection time :
my $dbh = DBI->connect(
"dbi:SQLite:dbname=foo", "", "",
{
RaiseError => 1,
sqlite_unicode => 1,
}
);
Adding user-defined collations
The native SQLite API for adding user-defined collations is exposed through methods
"sqlite_create_collation" and "sqlite_collation_needed".
To avoid calling these functions every time a $dbh handle is created, "DBD::SQLite" offers a simpler
interface through the %DBD::SQLite::COLLATION hash : just insert your own collation functions in that
hash, and whenever an unknown collation name is encountered in SQL, the appropriate collation
function will be loaded on demand from the hash. For example, here is a way to sort text values
regardless of their accented characters :
use DBD::SQLite;
$DBD::SQLite::COLLATION{no_accents} = sub {
my ( $a, $b ) = map lc, @_;
tr[XXXXXXXXXXXXXXXXXXXXXXXXXXXX]
[aaaaaacdeeeeiiiinoooooouuuuy] for $a, $b;
$a cmp $b;
};
my $dbh = DBI->connect("dbi:SQLite:dbname=dbfile");
my $sql = "SELECT ... FROM ... ORDER BY ... COLLATE no_accents");
my $rows = $dbh->selectall_arrayref($sql);
The builtin "perl" or "perllocale" collations are predefined in that same hash.
The COLLATION hash is a global registry within the current process; hence there is a risk of
undesired side-effects. Therefore, to prevent action at distance, the hash is implemented as a
"write-only" hash, that will happily accept new entries, but will raise an exception if any attempt
is made to override or delete a existing entry (including the builtin "perl" and "perllocale").
If you really, really need to change or delete an entry, you can always grab the tied object
underneath %DBD::SQLite::COLLATION --- but don't do that unless you really know what you are doing.
Also observe that changes in the global hash will not modify existing collations in existing database
handles: it will only affect new requests for collations. In other words, if you want to change the
behaviour of a collation within an existing $dbh, you need to call the "create_collation" method
directly.
FULLTEXT SEARCH
The FTS3 extension module within SQLite allows users to create special tables with a built-in full-text fulltext
text index (hereafter "FTS3 tables"). The full-text index allows the user to efficiently query the
database for all rows that contain one or more instances of a specified word (hereafter a "token"),
even if the table contains many large documents.
Short introduction to FTS3
The detailed documentation for FTS3 can be found at <http://www.sqlite.org/fts3.html>. Here is a very
short example :
$dbh->do(<<"") or die DBI::errstr;
CREATE VIRTUAL TABLE fts_example USING fts3(content)
my $sth = $dbh->prepare("INSERT INTO fts_example(content) VALUES (?))");
$sth->execute($_) foreach @docs_to_insert;
my $results = $dbh->selectall_arrayref(<<"");
SELECT docid, snippet(content) FROM fts_example WHERE content MATCH 'foo'
The key points in this example are :
• The syntax for creating FTS3 tables is
CREATE VIRTUAL TABLE <table_name> USING fts3(<columns>)
where "<columns>" is a list of column names. Columns may be typed, but the type information is
ignored. If no columns are specified, the default is a single column named "content". In
addition, FTS3 tables have an implicit column called "docid" (or also "rowid") for numbering the
stored documents.
• Statements for inserting, updating or deleting records use the same syntax as for regular SQLite
tables.
• Full-text searches are specified with the "MATCH" operator, and an operand which may be a single
word, a word prefix ending with '*', a list of words, a "phrase query" in double quotes, or a
boolean combination of the above.
• The builtin function "snippet(...)" builds a formatted excerpt of the document text, where the
words pertaining to the query are highlighted.
There are many more details to building and searching FTS3 tables, so we strongly invite you to read
the full documentation at at <http://www.sqlite.org/fts3.html>.
Incompatible change : starting from version 1.31, "DBD::SQLite" uses the new, recommended "Enhanced
Query Syntax" for binary set operators (AND, OR, NOT, possibly nested with parenthesis). Previous
versions of "DBD::SQLite" used the "Standard Query Syntax" (see
<http://www.sqlite.org/fts3.html#section_3_2>). Unfortunately this is a compilation switch, so it
cannot be tuned at runtime; however, since FTS3 was never advertised in versions prior to 1.31, the
change should be invisible to the vast majority of "DBD::SQLite" users. If, however, there are any
applications that nevertheless were built using the "Standard Query" syntax, they have to be
migrated, because the precedence of the "OR" operator has changed. Conversion from old to new syntax
can be automated through DBD::SQLite::FTS3Transitional, published in a separate distribution.
Tokenizers
The behaviour of full-text indexes strongly depends on how documents are split into tokens; therefore
FTS3 table declarations can explicitly specify how to perform tokenization:
CREATE ... USING fts3(<columns>, tokenize=<tokenizer>)
where "<tokenizer>" is a sequence of space-separated words that triggers a specific tokenizer, as
explained below.
SQLite builtin tokenizers
SQLite comes with three builtin tokenizers :
simple
Under the simple tokenizer, a term is a contiguous sequence of eligible characters, where
eligible characters are all alphanumeric characters, the "_" character, and all characters with
UTF codepoints greater than or equal to 128. All other characters are discarded when splitting a
document into terms. They serve only to separate adjacent terms.
All uppercase characters within the ASCII range (UTF codepoints less than 128), are transformed
to their lowercase equivalents as part of the tokenization process. Thus, full-text queries are
case-insensitive when using the simple tokenizer.
porter
The porter tokenizer uses the same rules to separate the input document into terms, but as well
as folding all terms to lower case it uses the Porter Stemming algorithm to reduce related
English language words to a common root.
icu If SQLite is compiled with the SQLITE_ENABLE_ICU pre-processor symbol defined, then there exists
a built-in tokenizer named "icu" implemented using the ICU library, and taking an ICU locale
identifier as argument (such as "tr_TR" for Turkish as used in Turkey, or "en_AU" for English as
used in Australia). For example:
CREATE VIRTUAL TABLE thai_text USING fts3(text, tokenize=icu th_TH)
The ICU tokenizer implementation is very simple. It splits the input text according to the ICU
rules for finding word boundaries and discards any tokens that consist entirely of white-space.
This may be suitable for some applications in some locales, but not all. If more complex
processing is required, for example to implement stemming or discard punctuation, use the perl
tokenizer as explained below.
Perl tokenizers
In addition to the builtin SQLite tokenizers, "DBD::SQLite" implements a perl tokenizer, that can
hook to any tokenizing algorithm written in Perl. This is specified as follows :
CREATE ... USING fts3(<columns>, tokenize=perl '<perl_function>')
where "<perl_function>" is a fully qualified Perl function name (i.e. prefixed by the name of the
package in which that function is declared). So for example if the function is "my_func" in the main
program, write
CREATE ... USING fts3(<columns>, tokenize=perl 'main::my_func')
That function should return a code reference that takes a string as single argument, and returns an
iterator (another function), which returns a tuple "($term, $len, $start, $end, $index)" for each
term. Here is a simple example that tokenizes on words according to the current perl locale
sub locale_tokenizer {
return sub {
my $string = shift;
use locale;
my $regex = qr/\w+/;
my $term_index = 0;
return sub { # closure
$string =~ /$regex/g or return; # either match, or no more token
my ($start, $end) = ($-[0], $+[0]);
my $len = $end-$start;
my $term = substr($string, $start, $len);
return ($term, $len, $start, $end, $term_index++);
}
};
}
There must be three levels of subs, in a kind of "Russian dolls" structure, because :
• the external, named sub is called whenever accessing a FTS3 table with that tokenizer
• the inner, anonymous sub is called whenever a new string needs to be tokenized (either for
inserting new text into the table, or for analyzing a query).
• the innermost, anonymous sub is called repeatedly for retrieving all terms within that string.
Instead of writing tokenizers by hand, you can grab one of those already implemented in the
Search::Tokenizer module :
use Search::Tokenizer;
$dbh->do(<<"") or die DBI::errstr;
CREATE ... USING fts3(<columns>,
tokenize=perl 'Search::Tokenizer::unaccent')
or you can use "new" in Search::Tokenizer to build your own tokenizer.
Incomplete handling of utf8 characters
The current FTS3 implementation in SQLite is far from complete with respect to utf8 handling : in
particular, variable-length characters are not treated correctly by the builtin functions "offsets()"
and "snippet()".
Database space for FTS3
FTS3 stores a complete copy of the indexed documents, together with the fulltext index. On a large
collection of documents, this can consume quite a lot of disk space. If copies of documents are also
available as external resources (for example files on the filesystem), that space can sometimes be
spared --- see the tip in the Cookbook.
R* TREE SUPPORT
The RTREE extension module within SQLite adds support for creating a R-Tree, a special index for
range and multidimensional queries. This allows users to create tables that can be loaded with (as
an example) geospatial data such as latitude/longitude coordinates for buildings within a city :
CREATE VIRTUAL TABLE city_buildings USING rtree(
id, -- Integer primary key
minLong, maxLong, -- Minimum and maximum longitude
minLat, maxLat -- Minimum and maximum latitude
);
then query which buildings overlap or are contained within a specified region:
# IDs that are contained within query coordinates
my $contained_sql = <<"";
SELECT id FROM try_rtree
WHERE minLong >= ? AND maxLong <= ?
AND minLat >= ? AND maxLat <= ?
# ... and those that overlap query coordinates
my $overlap_sql = <<"";
SELECT id FROM try_rtree
WHERE maxLong >= ? AND minLong <= ?
AND maxLat >= ? AND minLat <= ?
my $contained = $dbh->selectcol_arrayref($contained_sql,undef,
$minLong, $maxLong, $minLat, $maxLat);
my $overlapping = $dbh->selectcol_arrayref($overlap_sql,undef,
$minLong, $maxLong, $minLat, $maxLat);
For more detail, please see the SQLite R-Tree page (<http://www.sqlite.org/rtree.html>). Note that
custom R-Tree queries using callbacks, as mentioned in the prior link, have not been implemented yet.
FOR DBD::SQLITE EXTENSION AUTHORS
Since 1.30_01, you can retrieve the bundled sqlite C source and/or header like this:
use File::ShareDir 'dist_dir';
use File::Spec::Functions 'catfile';
# the whole sqlite3.h header
my $sqlite3_h = catfile(dist_dir('DBD-SQLite'), 'sqlite3.h');
# or only a particular header, amalgamated in sqlite3.c
my $what_i_want = 'parse.h';
my $sqlite3_c = catfile(dist_dir('DBD-SQLite'), 'sqlite3.c');
open my $fh, '<', $sqlite3_c or die $!;
my $code = do { local $/; <$fh> };
my ($parse_h) = $code =~ m{(
/\*+[ ]Begin[ ]file[ ]$what_i_want[ ]\*+
.+?
/\*+[ ]End[ ]of[ ]$what_i_want[ ]\*+/
)}sx;
open my $out, '>', $what_i_want or die $!;
print $out $parse_h;
close $out;
You usually want to use this in your extension's "Makefile.PL", and you may want to add DBD::SQLite
to your extension's "CONFIGURE_REQUIRES" to ensure your extension users use the same C source/header
they use to build DBD::SQLite itself (instead of the ones installed in their system).
TO DO
The following items remain to be done.
Leak Detection
Implement one or more leak detection tests that only run during AUTOMATED_TESTING and RELEASE_TESTING
and validate that none of the C code we work with leaks.
Stream API for Blobs
Reading/writing into blobs using "sqlite2_blob_open" / "sqlite2_blob_close".
Flags for sqlite3_open_v2
Support the full API of sqlite3_open_v2 (flags for opening the file).
Support for custom callbacks for R-Tree queries
Custom queries of a R-Tree index using a callback are possible with the SQLite C API
(<http://www.sqlite.org/rtree.html>), so one could potentially use a callback that narrowed the
result set down based on a specific need, such as querying for overlapping circles.
SUPPORT
Bugs should be reported via the CPAN bug tracker at
http://rt.cpan.org/NoAuth/ReportBug.html?Queue=DBD-SQLite
<http://rt.cpan.org/NoAuth/ReportBug.html?Queue=DBD-SQLite>
Note that bugs of bundled sqlite library (i.e. bugs in "sqlite3.[ch]") should be reported to the
sqlite developers at sqlite.org via their bug tracker or via their mailing list.
AUTHORS
Matt Sergeant <matt@sergeant.org>
Francis J. Lacoste <flacoste@logreport.org>
Wolfgang Sourdeau <wolfgang@logreport.org>
Adam Kennedy <adamk@cpan.org>
Max Maischein <corion@cpan.org>
Laurent Dami <dami@cpan.org>
Kenichi Ishigaki <ishigaki@cpan.org>
COPYRIGHT
The bundled SQLite code in this distribution is Public Domain.
DBD::SQLite is copyright 2002 - 2007 Matt Sergeant.
Some parts copyright 2008 Francis J. Lacoste.
Some parts copyright 2008 Wolfgang Sourdeau.
Some parts copyright 2008 - 2012 Adam Kennedy.
Some parts copyright 2009 - 2012 Kenichi Ishigaki.
Some parts derived from DBD::SQLite::Amalgamation copyright 2008 Audrey Tang.
This program is free software; you can redistribute it and/or modify it under the same terms as Perl
itself.
The full text of the license can be found in the LICENSE file included with this module.
perl v5.16.2 2012-06-09 DBD::SQLite(3)
|
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