NAME
SQL::Abstract::More - extension of SQL::Abstract with more constructs and more flexible API
SYNOPSIS
use SQL::Abstract::More; # will inherit from SQL::Abstract::Classic;
#or
use SQL::Abstract::More -extends => 'SQL::Abstract'; # will inherit from SQL::Abstract;
my $sqla = SQL::Abstract::More->new();
my ($sql, @bind);
# ex1: named parameters, select DISTINCT, ORDER BY, LIMIT/OFFSET
($sql, @bind) = $sqla->select(
-columns => [-distinct => qw/col1 col2/],
-from => 'Foo',
-where => {bar => {">" => 123}},
-order_by => [qw/col1 -col2 +col3/], # BY col1, col2 DESC, col3 ASC
-limit => 100,
-offset => 300,
);
# ex2: column aliasing, join
($sql, @bind) = $sqla->select(
-columns => [ qw/Foo.col_A|a Bar.col_B|b /],
-from => [-join => qw/Foo fk=pk Bar /],
);
# ex3: INTERSECT (or similar syntax for UNION)
($sql, @bind) = $sqla->select(
-columns => [qw/col1 col2/],
-from => 'Foo',
-where => {col1 => 123},
-intersect => [ -columns => [qw/col3 col4/],
-from => 'Bar',
-where => {col3 => 456},
],
);
# ex4 : subqueries
my $subq1 = [ $sqla->select(-columns => 'f|x', -from => 'Foo',
-union => [-columns => 'b|x',
-from => 'Bar',
-where => {barbar => 123}],
-as => 'Foo_union_Bar',
) ];
my $subq2 = [ $sqla->select(-columns => 'MAX(amount)',
-from => 'Expenses',
-where => {exp_id => {-ident => 'x'}, date => {">" => '01.01.2024'}},
-as => 'max_amount',
) ];
($sql, @bind) = $sqla->select(
-columns => ['x', \$subq2],
-from => \$subq1,
-order_by => 'x',
);
# ex5: passing datatype specifications
($sql, @bind) = $sqla->select(
-from => 'Foo',
-where => {bar => [{dbd_attrs => {ora_type => ORA_XMLTYPE}}, $xml]},
);
my $sth = $dbh->prepare($sql);
$sqla->bind_params($sth, @bind);
$sth->execute;
# ex6: multicolumns-in
$sqla = SQL::Abstract::More->new(
multicols_sep => '/',
has_multicols_in_SQL => 1,
);
($sql, @bind) = $sqla->select(
-from => 'Foo',
-where => {"foo/bar/buz" => {-in => ['1/a/X', '2/b/Y', '3/c/Z']}},
);
# ex7: merging several criteria
my $merged = $sqla->merge_conditions($cond_A, $cond_B, ...);
($sql, @bind) = $sqla->select(..., -where => $merged, ..);
# ex8: insert / update / delete
($sql, @bind) = $sqla->insert(
-add_sql => 'OR IGNORE', # SQLite syntax
-into => $table,
-values => {col => $val, ...},
);
($sql, @bind) = $sqla->insert(
-into => $table,
-columns => [qw/a b/],
-select => {-from => 'Bar', -columns => [qw/x y/], -where => ...},
);
($sql, @bind) = $sqla->update(
-table => $table,
-set => {col => $val, ...},
-where => \%conditions,
);
($sql, @bind) = $sqla->delete (
-from => $table
-where => \%conditions,
);
# ex9 : initial WITH clause -- example borrowed from https://sqlite.org/lang_with.html
($sql, @bind) = $sqla->with_recursive(
[ -table => 'parent_of',
-columns => [qw/name parent/],
-as_select => {-columns => [qw/name mom/],
-from => 'family',
-union => [-columns => [qw/name dad/], -from => 'family']},
],
[ -table => 'ancestor_of_alice',
-columns => [qw/name/],
-as_select => {-columns => [qw/parent/],
-from => 'parent_of',
-where => {name => 'Alice'},
-union_all => [-columns => [qw/parent/],
-from => [qw/-join parent_of {name} ancestor_of_alice/]],
},
],
)->select(
-columns => 'family.name',
-from => [qw/-join ancestor_of_alice {name} family/],
-where => {died => undef},
-order_by => 'born',
);
DESCRIPTION
This module generates SQL from Perl data structures. It is a subclass of SQL::Abstract::Classic or SQL::Abstract, fully compatible with the parent class, but with many improvements :
methods take arguments as named parameters instead of positional parameters. This is more flexible for identifying and assembling various SQL clauses, like
-where
,-order_by
,-group_by
, etc.additional SQL constructs like
-union
,-group_by
,join
,-with_recursive
, etc. are supportedsubqueries can be used in a column list or as a datasource (i.e
SELECT ... FROM (SELECT ..)
)WHERE .. IN
clauses can range over multiple columns (tuples)values passed to
select
,insert
orupdate
can directly incorporate information about datatypes, in the form of arrayrefs of shape[{dbd_attrs => \%type}, $value]
several SQL dialects can adapt the generated SQL to various DBMS vendors
This module was designed for the specific needs of DBIx::DataModel, but is published as a standalone distribution, because it may possibly be useful for other needs.
Unfortunately, this module cannot be used with DBIx::Class, because DBIx::Class
creates its own instance of SQL::Abstract
and has no API to let the client instantiate from any other class.
CLASS METHODS
import
The import()
method is called automatically when a client writes use SQL::Abstract::More
.
At this point there is a choice to make about the class to inherit from. Originally this module was designed as an extension of SQL::Abstract in its versions prior to 1.81. Then SQL::Abstract was rewritten with a largely different architecture, published under v2.000001. A fork of the previous version is now published under SQL::Abstract::Classic. SQL::Abstract::More
can inherit from either version; initially it used SQL::Abstract as the default parent, but now the default is back to SQL::Abstract::Classic for better compatibility with previous behaviours (see for example https://rt.cpan.org/Ticket/Display.html?id=143837).
The choice of the parent class is made according to the following rules :
SQL::Abstract::Classic is the default parent.
another parent can be specified through the
-extends
keyword:use SQL::Abstract::More -extends => 'SQL::Abstract';
Classic
is a shorthand toSQL::Abstract::Classic
use SQL::Abstract::More -extends => 'Classic';
If the environment variable
SQL_ABSTRACT_MORE_EXTENDS
is defined, its value is used as an implicit-extends
BEGIN {$ENV{SQL_ABSTRACT_MORE_EXTENDS} = 'Classic'; use SQL::Abstract::More; # will inherit from SQL::Abstract::Classic; }
Multiple calls to
import()
must all resolve to the same parent; otherwise an exception is raised.
new
my $sqla = SQL::Abstract::More->new(%options);
where %options
may contain any of the options for the parent class (see "new" in SQL::Abstract), plus the following :
- table_alias
-
A
sprintf
format description for generating table aliasing clauses. The default is%s AS %s
.The argument can also be a method coderef :
SQL::Abstract::More->new(table_alias => sub { my ($self, $table, $alias) = @_; my $syntax_for_aliased_table = ...; return $syntax_for_aliased_table; })
- column_alias
-
A
sprintf
format description for generating column aliasing clauses. The default is%s AS %s
.Like for
table_alias
, the argument can also be a method coderef. - limit_offset
-
Name of a "limit-offset dialect", which can be one of
LimitOffset
,LimitXY
,LimitYX
,OffsetFetchRows
orRowNum
. Most of thoses are copied from SQL::Abstract::Limit -- see that module for explanations. TheOffsetFetchRows
dialect has been added here and corresponds to Oracle syntax starting from version 12c (OFFSET ? ROWS FETCH ? ROWS ONLY
). Unlike the SQL::Abstract::Limit implementation, limit and offset values are treated here as regular values, with placeholders '?' in the SQL; values are postponed to the@bind
list.The argument can also be a coderef. That coderef takes
$self, $limit, $offset
as arguments, and should return($sql, @bind)
. If$sql
contains%s
, it is treated as asprintf
format string, where the original SQL is injected into%s
. - join_syntax
-
A hashref where keys are abbreviations for join operators to be used in the "join" method, and values are associated SQL clauses with placeholders in
sprintf
format. The default is described below under the "join" method. - join_assoc_right
-
A boolean telling if multiple joins should be associative on the right or on the left. Default is false (i.e. left-associative).
- max_members_IN
-
An integer specifying the maximum number of members in a "IN" clause. If the number of given members is greater than this maximum,
SQL::Abstract::More
will automatically split it into separate clauses connected by 'OR' (or connected by 'AND' if used with the-not_in
operator).my $sqla = SQL::Abstract::More->new(max_members_IN => 3); ($sql, @bind) = $sqla->select( -from => 'Foo', -where => {foo => {-in => [1 .. 5]}}, bar => {-not_in => [6 .. 10]}}, ); # .. WHERE ( (foo IN (?,?,?) OR foo IN (?, ?)) # AND (bar NOT IN (?,?,?) AND bar NOT IN (?, ?)) )
- multicols_sep
-
A string or compiled regular expression used as a separator for "multicolumns". This separator can then be used on the left-hand side and right-hand side of an
IN
operator, like this :my $sqla = SQL::Abstract::More->new(multicols_sep => '/'); ($sql, @bind) = $sqla->select( -from => 'Foo', -where => {"x/y/z" => {-in => ['1/A/foo', '2/B/bar']}}, );
Alternatively, tuple values on the right-hand side can also be given as arrayrefs instead of plain scalars with separators :
-where => {"x/y/z" => {-in => [[1, 'A', 'foo'], [2, 'B', 'bar']]}},
but the left-hand side must stay a plain scalar because an array reference wouldn't be a proper key for a Perl hash; in addition, the presence of the separator in the string is necessary to trigger the special algorithm for multicolumns.
The generated SQL depends on the boolean flag
has_multicols_in_SQL
, as explained in the next paragraph. - has_multicols_in_SQL
-
A boolean flag that controls which kind of SQL will be generated for multicolumns. If the flag is true, this means that the underlying DBMS supports multicolumns in SQL, so we just generate tuple expressions. In the example from the previous paragraph, the SQL and bind values would be :
# $sql : "WHERE (x, y, z) IN ((?, ?, ?), (?, ?, ?))" # @bind : [ qw/1 A foo 2 B bar/ ]
It is also possible to use a subquery, like this :
($sql, @bind) = $sqla->select( -from => 'Foo', -where => {"x/y/z" => {-in => \[ 'SELECT (a, b, c) FROM Bar ' . 'WHERE a > ?', 99]}}, ); # $sql : "WHERE (x, y, z) IN (SELECT (a, b, c) FROM Bar WHERE a > ?)" # @bind : [ 99 ]
If the flag is false, the condition on tuples will be automatically converted using boolean logic :
# $sql : "WHERE ( (x = ? AND y = ? AND z = ?) OR (x = ? AND y = ? AND z = ?))" # @bind : [ qw/1 A foo 2 B bar/ ]
If the flag is false, subqueries are not allowed.
- select_implicitly_for
-
A value that will be automatically added as a
-for
clause in calls to "select". This default clause can always be overridden by an explicit-for
in a given select :my $sqla = SQL::Abstract->new(-select_implicitly_for => 'READ ONLY'); ($sql, @bind) = $sqla->select(-from => 'Foo'); # SELECT * FROM FOO FOR READ ONLY ($sql, @bind) = $sqla->select(-from => 'Foo', -for => 'UPDATE'); # SELECT * FROM FOO FOR UPDATE ($sql, @bind) = $sqla->select(-from => 'Foo', -for => undef); # SELECT * FROM FOO
- sql_dialect
-
This is actually a "meta-argument" : it injects a collection of regular arguments, tuned for a specific SQL dialect. Dialects implemented so far are :
- MsAccess
-
For Microsoft Access. Overrides the
join
syntax to be right-associative. - BasisJDBC
-
For Livelink Collection Server (formerly "Basis"), accessed through a JDBC driver. Overrides the
column_alias
syntax. Setsmax_members_IN
to 255. - MySQL_old
-
For old versions of MySQL. Overrides the
limit_offset
syntax. Recent versions of MySQL do not need that because they now implement the regular "LIMIT ? OFFSET ?" ANSI syntax. - Oracle
-
For old versions of Oracle. Overrides the
limit_offset
to use the "RowNum" dialect (beware, this injects an additional columnrownum__index
into your resultset). Also setsmax_members_IN
to 999 andhas_multicols_in_SQL
to true. - Oracle12c
-
For Oracle starting from version 12c. Like the "Oracle" dialect, except for
limit_offset
which usesOffsetFetchRows
.
INSTANCE METHODS
select
# positional parameters, directly passed to the parent class
($sql, @bind) = $sqla->select($table, $columns, $where, $order);
# named parameters, handled in this class
($sql, @bind) = $sqla->select(
-columns => \@columns,
# OR: -columns => [-distinct => @columns],
-from => $table || \@joined_tables,
-where => \%where,
-union => [ %select_subargs ], # OR -intersect, -minus, etc
-order_by => \@order,
-group_by => \@group_by,
-having => \%having_criteria,
-limit => $limit, -offset => $offset,
# OR: -page_size => $size, -page_index => $index,
-for => $purpose,
);
my $details = $sqla->select(..., want_details => 1);
# keys in %$details: sql, bind, aliased_tables, aliased_columns
If called with positional parameters, as in SQL::Abstract, select()
just forwards the call to the parent class. Otherwise, if called with named parameters, as in the example above, some additional SQL processing is performed.
The following named arguments can be specified :
-columns => \@columns
-
\@columns
is a reference to an array of SQL column specifications (i.e. column names,*
ortable.*
, functions, etc.).A '|' in a column is translated into a column aliasing clause: this is convenient when using perl
qw/.../
operator for columns, as in-columns => [ qw/table1.longColumn|t1lc table2.longColumn|t2lc/ ]
SQL column aliasing is then generated through the "column_alias" method. If "quote_char" in SQL::Abstract is defined, aliased columns will be quoted, unless they contain parentheses, in which case they are considered as SQL expressions for which the user should handle the quoting himself. For example if
quote_char
is "`",-columns => [ qw/foo.bar|fb length(buz)|lbuz/ ]
will produce
SELECT `foo`.`bar` AS fb, length(buz) AS lbuz
and not
SELECT `foo`.`bar` AS fb, length(`buz`) AS lbuz
Initial items in
@columns
that start with a minus sign are shifted from the array, i.e. they are not considered as column names, but are re-injected later into the SQL (without the minus sign), just after theSELECT
keyword. This is especially useful for$sqla->select(..., -columns => [-DISTINCT => @columns], ...);
However, it may also be useful for other purposes, like vendor-specific SQL variants :
# MySQL features ->select(..., -columns => [-STRAIGHT_JOIN => @columns], ...); ->select(..., -columns => [-SQL_SMALL_RESULT => @columns], ...); # Oracle hint ->select(..., -columns => ["-/*+ FIRST_ROWS (100) */" => @columns], ...);
Within the columns array, it is also possible to insert a subquery expressed as a reference to an arrayref, as explained in "Literal SQL with placeholders and bind values (subqueries)" in SQL::Abstract. The caller is responsible for putting the SQL of the subquery within parenthesis and possibly adding a column alias; fortunately this can be done automatically when generating the subquery through a call to
select()
with an "-as" parameter :# build the subquery -- stored in an arrayref my $subquery = [ $sqla->select( -columns => 'COUNT(*)', -from => 'Foo', -where => {bar_id => {-ident => 'Bar.bar_id'}, height => {-between => [100, 200]}}, -as => 'count_foos', ) ]; # main query my ($sql, @bind) = $sqla->select( -from => 'Bar', -columns => ['col1', 'col2', \$subquery, , 'col4'], # reference to an arrayref ! -where => {color => 'green'}, );
This will produce SQL :
SELECT col1, col2, (SELECT COUNT(*) FROM Foo WHERE bar_id=Bar.bar_id and height BETWEEN ? AND ?) AS count_foos, col4 FROM Bar WHERE color = ?
The resulting
@bind
array combines bind values coming from both the subquery and from the main query, i.e.(100, 200, 'green')
.Instead of an arrayref, the argument to
-columns
can also be just a string, like for example"c1 AS foobar, MAX(c2) AS m_c2, COUNT(c3) AS n_c3"
; however this is mainly for backwards compatibility. The recommended way is to use the arrayref notation as explained above :-columns => [ qw/ c1|foobar MAX(c2)|m_c2 COUNT(c3)|n_c3 / ]
If omitted,
-columns
takes '*' as default argument. -from => $table || \@joined_tables || \$subquery
-
The argument to
-from
can be :a plain string, interpreted as a table name. Like for column aliases, a table alias can be given, using a vertical bar as separator :
-from => 'Foobar|fb', # SELECT .. FROM Foobar AS fb
a join specification, given as an arrayref starting with the keyword
-join
, followed by a list of table and join conditions according to the "join" method :-from => [-join => qw/Foo fk=pk Bar/],
a reference to a subquery arrayref, in the form
[$sql, @bind]
. The caller is responsible for putting the SQL of the subquery within parenthesis and possibly adding a table alias; fortunately this can be done automatically when generating the subquery through a call toselect()
with an "-as" parameter :my $subq = [ $sqla->select(-columns => 'f|x', -from => 'Foo', -union => [-columns => 'b|x', -from => 'Bar', -where => {barbar => 123}], -as => 'Foo_union_Bar', ) ]; my ($sql, @bind) = $sqla->select(-from => \$subq, -order_by => 'x');
a simple arrayref that does not start with
-join
. This is for compatibility with the old SQL::Abstract API. Members of the array are interpreted as a list of table names, that will be joined by", "
. Join conditions should then be expressed separately in the-where
part. This syntax is deprecated : use the-join
feature instead.$sqla->select(-from => [qw/Foo Bar Buz/], ...) # SELECT FROM Foo, Bar, Buz ..
a simple scalarref. This is for compatibility with the old SQL::Abstract API. The result is strictly equivalent to passing the scalar directly. This syntax is deprecated.
$sqla->select(-from => \ "Foo", ...) # SELECT FROM Foo ..
-where => $criteria
-
Like in SQL::Abstract,
$criteria
can be a plain SQL string like"col1 IN (3, 5, 7, 11) OR col2 IS NOT NULL"
; but in most cases, it will rather be a reference to a hash or array of conditions that will be translated into SQL clauses, like for example{col1 => 'val1', col2 => {'<>' => 'val2'}}
. The structure of that hash or array can be nested to express complex boolean combinations of criteria, including parenthesized subqueries; see "WHERE CLAUSES" in SQL::Abstract for a detailed description.When using hashrefs or arrayrefs, leaf values can be "bind values with types"; see the "BIND VALUES WITH TYPES" section below.
-union => [ %select_subargs ]
-union_all => [ %select_subargs ]
-intersect => [ %select_subargs ]
-except => [ %select_subargs ]
-minus => [ %select_subargs ]
-
generates a compound query using set operators such as
UNION
,INTERSECT
, etc. The argument%select_subargs
contains a nested set of parameters like for the main select (i.e.-columns
,-from
,-where
, etc.); however, arguments-columns
and-from
can be omitted, in which case they will be copied from the main select(). Several levels of set operators can be nested. -group_by => "string"
or-group_by => \@array
-
adds a
GROUP BY
clause in the SQL statement. Grouping columns are specified either by a plain string or by an array of strings. -having => "string"
or-having => \%criteria
-
adds a
HAVING
clause in the SQL statement. In most cases this is used together with aGROUP BY
clause. This is like a-where
clause, except that the criteria are applied after grouping has occurred. -order_by => \@order
-
\@order
is a reference to a list of columns for sorting. Columns can be prefixed by '+' or '-' for indicating sorting directions, so for example-orderBy => [qw/-col1 +col2 -col3/]
will generate the SQL clauseORDER BY col1 DESC, col2 ASC, col3 DESC
.Column names
asc
anddesc
are treated as exceptions to this rule, in order to preserve compatibility with SQL::Abstract. So-orderBy => [-desc => 'colA']
yieldsORDER BY colA DESC
and notORDER BY desc DEC, colA
. Any other syntax supported by SQL::Abstract is also supported here; see "ORDER BY CLAUSES" in SQL::Abstract for examples.The whole
-order_by
parameter can also be a plain SQL string like"col1 DESC, col3, col2 DESC"
. -page_size => $page_size
-
specifies how many rows will be retrieved per "page" of data. Default is unlimited (or more precisely the maximum value of a short integer on your system). When specified, this parameter automatically implies
-limit
. -page_index => $page_index
-
specifies the page number (starting at 1). Default is 1. When specified, this parameter automatically implies
-offset
. -limit => $limit
-
limit to the number of rows that will be retrieved. Automatically implied by
-page_size
. -offset => $offset
-
Automatically implied by
-page_index
. Defaults to 0. -for => $clause
-
specifies an additional clause to be added at the end of the SQL statement, like
-for => 'READ ONLY'
or-for => 'UPDATE'
. -want_details => 1
-
If true, the return value will be a hashref instead of the usual
($sql, @bind)
. The hashref contains the following keys : -as => $alias
-
The
$sql
part is rewritten as($sql)|$alias
. This is convenient when the result is to be used as a subquery within anotherselect()
call.- sql
-
generated SQL
- bind
-
bind values
- aliased_tables
-
a hashref of
{table_alias => table_name}
encountered while parsing the-from
parameter. - aliased_columns
-
a hashref of
{column_alias => column_name}
encountered while parsing the-columns
parameter.
insert
# positional parameters, directly passed to the parent class
($sql, @bind) = $sqla->insert($table, \@values || \%fieldvals, \%options);
# named parameters, handled in this class
($sql, @bind) = $sqla->insert(
-into => $table,
-values => {col => $val, ...},
-returning => $return_structure,
-add_sql => $keyword,
);
# insert from a subquery
($sql, @bind) = $sqla->insert(
-into => $destination_table,
-columns => \@columns_into
-select => {-from => $source_table, -columns => \@columns_from, -where => ...},
);
Like for "select", values assigned to columns can have associated SQL types; see "BIND VALUES WITH TYPES".
Parameters -into
and -values
are passed verbatim to the parent method.
Parameters -select
and -columns
are used for selecting from subqueries -- this is incompatible with the -values
parameter.
Parameter -returning
is optional and only supported by some database vendors (see "insert" in SQL::Abstract); if the $return_structure
is
a scalar or an arrayref, it is passed directly to the parent method
a hashref, it is interpreted as a SQL clause "RETURNING .. INTO ..", as required in particular by Oracle. Hash keys are field names, and hash values are references to variables that will receive the results. Then it is the client code's responsibility to use "bind_param_inout" in DBD::Oracle for binding the variables and retrieving the results, but the "bind_params" method in the present module is there for help. Example:
($sql, @bind) = $sqla->insert( -into => $table, -values => {col => $val, ...}, -returning => {key_col => \my $generated_key}, ); my $sth = $dbh->prepare($sql); $sqla->bind_params($sth, @bind); $sth->execute; print "The new key is $generated_key";
Optional parameter -add_sql
is used with some specific SQL dialects, for injecting additional SQL keywords after the INSERT
keyword. Examples :
$sqla->insert(..., -add_sql => 'IGNORE') # produces "INSERT IGNORE ..." -- MySQL
$sqla->insert(..., -add_sql => 'OR IGNORE') # produces "INSERT OR IGNORE ..." -- SQLite
update
# positional parameters, directly passed to the parent class
($sql, @bind) = $sqla->update($table, \%fieldvals, \%where);
# named parameters, handled in this class
($sql, @bind) = $sqla->update(
-table => $table,
-set => {col => $val, ...},
-where => \%conditions,
-order_by => \@order,
-limit => $limit,
-returning => $return_structure,
-add_sql => $keyword,
);
This works in the same spirit as the "insert" method above. Positional parameters are supported for backwards compatibility with the old API; but named parameters should be preferred because they improve the readability of the client's code.
Few DBMS would support parameters -order_by
and -limit
, but MySQL does -- see http://dev.mysql.com/doc/refman/5.6/en/update.html.
Optional parameter -returning
works like for the "insert" method.
Optional parameter -add_sql
is used with some specific SQL dialects, for injecting additional SQL keywords after the UPDATE
keyword. Examples :
$sqla->update(..., -add_sql => 'IGNORE') # produces "UPDATE IGNORE ..." -- MySQL
$sqla->update(..., -add_sql => 'OR IGNORE') # produces "UPDATE OR IGNORE ..." -- SQLite
delete
# positional parameters, directly passed to the parent class
($sql, @bind) = $sqla->delete($table, \%where);
# named parameters, handled in this class
($sql, @bind) = $sqla->delete (
-from => $table
-where => \%conditions,
-order_by => \@order,
-limit => $limit,
-add_sql => $keyword,
);
Positional parameters are supported for backwards compatibility with the old API; but named parameters should be preferred because they improve the readability of the client's code.
Few DBMS would support parameters -order_by
and -limit
, but MySQL does -- see http://dev.mysql.com/doc/refman/5.6/en/update.html.
Optional parameter -add_sql
is used with some specific SQL dialects, for injecting additional SQL keywords after the DELETE
keyword. Examples :
$sqla->delete(..., -add_sql => 'IGNORE') # produces "DELETE IGNORE ..." -- MySQL
$sqla->delete(..., -add_sql => 'OR IGNORE') # produces "DELETE OR IGNORE ..." -- SQLite
with_recursive, with
my $new_sqla = $sqla->with_recursive( # or: $sqla->with(
[ -table => $CTE_table_name,
-columns => \@CTE_columns,
-as_select => \%select_args ],
[ -table => $CTE_table_name2,
-columns => \@CTE_columns2,
-as_select => \%select_args2 ],
...
);
($sql, @bind) = $new_sqla->insert(...);
# or, if there is only one table expression
my $new_sqla = $sqla->with_recursive(
-table => $CTE_table_name,
-columns => \@CTE_columns,
-as_select => \%select_args,
);
Returns a new instance with an encapsulated common table expression (CTE), i.e. a kind of local view that can be used as a table name for the rest of the SQL statement -- see https://en.wikipedia.org/wiki/Hierarchical_and_recursive_queries_in_SQL for an explanation of such expressions, or, if you are using Oracle, see the documentation for so-called subquery factoring clauses in SELECT statements.
Further calls to select
, insert
, update
and delete
on that new instance will automatically prepend a WITH
or WITH RECURSIVE
clause before the usual SQL statement.
Arguments to with_recursive()
are expressed as a list of arrayrefs; each arrayref corresponds to one table expression, with the following named parameters :
-table
-
The name to be assigned to the table expression
-columns
-
An optional list of column aliases to be assigned to the columns resulting from the internal select
-as_select
-
The implementation of the table expression, given as a hashref of arguments following the same syntax as the "select" method.
-final_clause
-
An optional SQL clause that will be added after the table expression. This may be needed for example for an Oracle cycle clause, like
($sql, @bind) = $sqla->with_recursive( -table => ..., -as_select => ..., -final_clause => "CYCLE x SET is_cycle TO '1' DEFAULT '0'", )->select(...);
If there is only one table expression, its arguments can be passed directly as an array instead of a single arrayref.
table_alias
my $sql = $sqla->table_alias($table_name, $alias);
Returns the SQL fragment for aliasing a table. If $alias
is empty, just returns $table_name
.
column_alias
Like table_alias
, but for column aliasing.
limit_offset
($sql, @bind) = $sqla->limit_offset($limit, $offset);
Generates ($sql, @bind)
for a LIMIT-OFFSET clause.
join
my $join_info = $sqla->join(
<table0> <join_1> <table_1> ... <join_n> <table_n>
);
my $sth = $dbh->prepare($join_info->{sql});
$sth->execute(@{$join_info->{bind}})
while (my ($alias, $aliased) = each %{$join_info->{aliased_tables}}) {
say "$alias is an alias for table $aliased";
}
Generates join information for a JOIN clause, taking as input a collection of joined tables with their join conditions. The following example gives an idea of the available syntax :
($sql, @bind) = $sqla->join(qw[
Table1|t1 ab=cd Table2|t2
<=>{ef>gh,ij<kl,mn='foobar'} Table3
=>{t1.op=qr} Table4
]);
This will generate
Table1 AS t1 INNER JOIN Table2 AS t2 ON t1.ab=t2.cd
INNER JOIN Table3 ON t2.ef>Table3.gh
AND t2.ij<Table3.kl
AND t2.mn=?
LEFT JOIN Table4 ON t1.op=Table4.qr
with one bind value foobar
.
More precisely, the arguments to join()
should be a list containing an odd number of elements, where the odd positions are table specifications and the even positions are join specifications.
Table specifications
A table specification for join is a string containing the table name, possibly followed by a vertical bar and an alias name. For example Table1
or Table1|t1
are valid table specifications.
These are converted into internal hashrefs with keys sql
, bind
, name
, aliased_tables
, like this :
{
sql => "Table1 AS t1"
bind => [],
name => "t1"
aliased_tables => {"t1" => "Table1"}
}
Such hashrefs can be passed directly as arguments, instead of the simple string representation.
Join specifications
A join specification is a string containing an optional join operator, possibly followed by a pair of curly braces or square brackets containing the join conditions.
Default builtin join operators are <=>
, =>
, <=
, ==
, corresponding to the following SQL JOIN clauses :
'<=>' => '%s INNER JOIN %s ON %s',
'=>' => '%s LEFT OUTER JOIN %s ON %s',
'<=' => '%s RIGHT JOIN %s ON %s',
'==' => '%s NATURAL JOIN %s',
'>=<' => '%s FULL OUTER JOIN %s ON %s',
This operator table can be overridden through the join_syntax
parameter of the "new" method.
The join conditions are a comma-separated list of binary column comparisons, like for example
{ab=cd,Table1.ef<Table2.gh}
Table names may be explicitly given using dot notation, or may be implicit, in which case they will be filled automatically from the names of operands on the left-hand side and right-hand side of the join.
Strings within quotes will be treated as bind values instead of column names; pairs of quotes within such values become single quotes. Ex.
{ab=cd,ef='foo''bar',gh<ij}
becomes
ON Table1.ab=Table2.cd AND Table1.ef=? AND Table1.gh<Table2.ij
# bind value: "foo'bar"
In accordance with SQL::Abstract common conventions, if the list of comparisons is within curly braces, it will become an AND
; if it is within square brackets, it will become an OR
.
Join specifications expressed as strings are converted into internal hashrefs with keys operator
and condition
, like this :
{
operator => '<=>',
condition => { '%1$s.ab' => {'=' => {-ident => '%2$s.cd'}},
'%1$s.ef' => {'=' => {-ident => 'Table2.gh'}}},
}
The operator
is a key into the join_syntax
table; the associated value is a sprintf
format string, with placeholders for the left and right operands, and the join condition. The condition
is a structure suitable for being passed as argument to "where" in SQL::Abstract. Places where the names of left/right tables (or their aliases) are expected should be expressed as sprintf
placeholders, i.e. respectively %1$s
and %2$s
. Usually the right-hand side of the condition refers to a column of the right table; in such case it should not belong to the @bind
list, so this is why we need to use the -ident
operator from SQL::Abstract. Only when the right-hand side is a string constant (string within quotes) does it become a bind value : for example
->join(qw/Table1 {ab=cd,ef='foobar'}) Table2/)
is parsed into
[ 'Table1',
{ operator => '<=>',
condition => { '%1$s.ab' => {'=' => {-ident => '%2$s.cd'}},
'%1$s.ef' => {'=' => 'foobar'} },
},
'Table2',
]
Hashrefs for join specifications as shown above can be passed directly as arguments, instead of the simple string representation. For example the DBIx::DataModel ORM uses hashrefs for communicating with SQL::Abstract::More
.
joins with USING clause instead of ON
In most DBMS, when column names on both sides of a join are identical, the join can be expressed as
SELECT * FROM T1 INNER JOIN T2 USING (A, B)
instead of
SELECT * FROM T1 INNER JOIN T2 ON T1.A=T2.A AND T1.B=T2.B
The advantage of this syntax with a USING clause is that the joined columns will appear only once in the results, and they do not need to be prefixed by a table name if they are needed in the select list or in the WHERE part of the SQL.
To express joins with the USING syntax in SQL::Abstract::More
, just mention the column names within curly braces, without any equality operator. For example
->join(qw/Table1 {a,b} Table2 {c} Table3/)
will generate
SELECT * FROM Table1 INNER JOIN Table2 USING (a,b)
INNER JOIN Table3 USING (c)
In this case the internal hashref representation has the following shape :
{
operator => '<=>',
using => [ 'a', 'b'],
}
When they are generated directy by the client code, internal hashrefs must have either a condition
field or a using
field; it is an error to have both.
Return value
The structure returned by join()
is a hashref with the following keys :
- sql
-
a string containing the generated SQL
- bind
-
an arrayref of bind values
- aliased_tables
-
a hashref where keys are alias names and values are names of aliased tables.
merge_conditions
my $conditions = $sqla->merge_conditions($cond_A, $cond_B, ...);
This utility method takes a list of "where
" conditions and merges all of them in a single hashref. For example merging
( {a => 12, b => {">" => 34}},
{b => {"<" => 56}, c => 78} )
produces
{a => 12, b => [-and => {">" => 34}, {"<" => 56}], c => 78});
bind_params
$sqla->bind_params($sth, @bind);
For each $value
in @bind
:
if the value is a scalarref, call
$sth->bind_param_inout($index, $value, $INOUT_MAX_LEN)
(see "bind_param_inout" in DBI).
$INOUT_MAX_LEN
defaults to 99, which should be good enough for most uses; should you need another value, you can change it by settinglocal $SQL::Abstract::More::INOUT_MAX_LEN = $other_value;
if the value is an arrayref that matches "is_bind_value_with_type", then call the method and arguments returned by "is_bind_value_with_type".
for all other cases, call
$sth->bind_param($index, $value);
This method is useful either as a convenience for Oracle statements of shape "INSERT ... RETURNING ... INTO ..."
(see "insert" method above), or as a way to indicate specific datatypes to the database driver.
is_bind_value_with_type
my ($method, @args) = $sqla->is_bind_value_with_type($value);
If $value
is a ref to a pair [\%args, $orig_value]
:
if
%args
is of shape{dbd_attrs => \%sql_type}
, then return('bind_param', $orig_value, \%sql_type)
.if
%args
is of shape{sqlt_size => $num}
, then return('bind_param_inout', $orig_value, $num)
.
Otherwise, return ()
.
BIND VALUES WITH TYPES
At places where SQL::Abstract would expect a plain value, SQL::Abstract::More
also accepts a pair, i.e. an arrayref of 2 elements, where the first element is a type specification, and the second element is the value. This is convenient when the DBD driver needs additional information about the values used in the statement.
The usual type specification is a hashref {dbd_attrs => \%type}
, where \%type
is passed directly as third argument to "bind_param" in DBI, and therefore is specific to the DBD driver.
Another form of type specification is {sqlt_size => $num}
, where $num
will be passed as buffer size to "bind_param_inout" in DBI.
Here are some examples
($sql, @bind) = $sqla->insert(
-into => 'Foo',
-values => {bar => [{dbd_attrs => {ora_type => ORA_XMLTYPE}}]},
);
($sql, @bind) = $sqla->select(
-from => 'Foo',
-where => {d_begin => {">" => [{dbd_attrs => {ora_type => ORA_DATE}},
$some_date]}},
);
When using this feature, the @bind
array will contain references that cannot be passed directly to DBI methods; so you should use "bind_params" from the present module to perform the appropriate bindings before executing the statement.
UTILITY FUNCTIONS
shallow_clone
my $clone = SQL::Abstract::More::shallow_clone($some_object, %override);
Returns a shallow copy of the object passed as argument. A new hash is created with copies of the top-level keys and values, and it is blessed into the same class as the original object. Not to be confused with the full recursive copy performed by "clone" in Clone.
The optional %override
hash is also copied into $clone
; it can be used to add other attributes or to override existing attributes in $some_object
.
does()
if (SQL::Abstract::More::does $ref, 'ARRAY') {...}
Very cheap version of a does()
method, that checks whether a given reference can act as an ARRAY, HASH, SCALAR or CODE. This was designed for the limited internal needs of this module and of DBIx::DataModel; for more complete implementations of a does()
method, see Scalar::Does, UNIVERSAL::DOES or Class::DOES.
AUTHOR
Laurent Dami, <laurent dot dami at cpan dot org>
ACKNOWLEDGEMENTS
https://github.com/rouzier : support for
-having
without-order_by
https://github.com/ktat : pull request for fixing
-from => ['table']
https://metacpan.org/author/DAKKAR : signaling a regression for
-from => \ 'table'
SUPPORT
You can find documentation for this module with the perldoc command.
perldoc SQL::Abstract::More
The same documentation is also available at https://metacpan.org/module/SQL::Abstract::More
LICENSE AND COPYRIGHT
Copyright 2011-2024 Laurent Dami.
This program is free software; you can redistribute it and/or modify it under the terms of either: the GNU General Public License as published by the Free Software Foundation; or the Artistic License.
See https://dev.perl.org/licenses/ for more information.