package SQL::Abstract; # see doc at end of file # LDNOTE : this code is heavy refactoring from original SQLA. # Several design decisions will need discussion during # the test / diffusion / acceptance phase; those are marked with flag # 'LDNOTE' (note by laurent.dami AT free.fr) use Carp; use strict; use warnings; use List::Util qw/first/; use Scalar::Util qw/blessed/; #====================================================================== # GLOBALS #====================================================================== our $VERSION = '1.60'; # This would confuse some packagers #$VERSION = eval $VERSION; # numify for warning-free dev releases our $AUTOLOAD; # special operators (-in, -between). May be extended/overridden by user. # See section WHERE: BUILTIN SPECIAL OPERATORS below for implementation my @BUILTIN_SPECIAL_OPS = ( {regex => qr/^(not )?between$/i, handler => '_where_field_BETWEEN'}, {regex => qr/^(not )?in$/i, handler => '_where_field_IN'}, ); # unaryish operators - key maps to handler my @BUILTIN_UNARY_OPS = ( # the digits are backcompat stuff { regex => qr/^and (?: \s? \d+ )? $/xi, handler => '_where_op_ANDOR' }, { regex => qr/^or (?: \s? \d+ )? $/xi, handler => '_where_op_ANDOR' }, { regex => qr/^nest (?: \s? \d+ )? $/xi, handler => '_where_op_NEST' }, { regex => qr/^ (?: not \s )? bool $/xi, handler => '_where_op_BOOL' }, ); #====================================================================== # DEBUGGING AND ERROR REPORTING #====================================================================== sub _debug { return unless $_[0]->{debug}; shift; # a little faster my $func = (caller(1))[3]; warn "[$func] ", @_, "\n"; } sub belch (@) { my($func) = (caller(1))[3]; carp "[$func] Warning: ", @_; } sub puke (@) { my($func) = (caller(1))[3]; croak "[$func] Fatal: ", @_; } #====================================================================== # NEW #====================================================================== sub new { my $self = shift; my $class = ref($self) || $self; my %opt = (ref $_[0] eq 'HASH') ? %{$_[0]} : @_; # choose our case by keeping an option around delete $opt{case} if $opt{case} && $opt{case} ne 'lower'; # default logic for interpreting arrayrefs $opt{logic} = $opt{logic} ? uc $opt{logic} : 'OR'; # how to return bind vars # LDNOTE: changed nwiger code : why this 'delete' ?? # $opt{bindtype} ||= delete($opt{bind_type}) || 'normal'; $opt{bindtype} ||= 'normal'; # default comparison is "=", but can be overridden $opt{cmp} ||= '='; # try to recognize which are the 'equality' and 'unequality' ops # (temporary quickfix, should go through a more seasoned API) $opt{equality_op} = qr/^(\Q$opt{cmp}\E|is|(is\s+)?like)$/i; $opt{inequality_op} = qr/^(!=|<>|(is\s+)?not(\s+like)?)$/i; # SQL booleans $opt{sqltrue} ||= '1=1'; $opt{sqlfalse} ||= '0=1'; # special operators $opt{special_ops} ||= []; push @{$opt{special_ops}}, @BUILTIN_SPECIAL_OPS; # unary operators $opt{unary_ops} ||= []; push @{$opt{unary_ops}}, @BUILTIN_UNARY_OPS; return bless \%opt, $class; } #====================================================================== # INSERT methods #====================================================================== sub insert { my $self = shift; my $table = $self->_table(shift); my $data = shift || return; my $method = $self->_METHOD_FOR_refkind("_insert", $data); my ($sql, @bind) = $self->$method($data); $sql = join " ", $self->_sqlcase('insert into'), $table, $sql; return wantarray ? ($sql, @bind) : $sql; } sub _insert_HASHREF { # explicit list of fields and then values my ($self, $data) = @_; my @fields = sort keys %$data; my ($sql, @bind) = $self->_insert_values($data); # assemble SQL $_ = $self->_quote($_) foreach @fields; $sql = "( ".join(", ", @fields).") ".$sql; return ($sql, @bind); } sub _insert_ARRAYREF { # just generate values(?,?) part (no list of fields) my ($self, $data) = @_; # no names (arrayref) so can't generate bindtype $self->{bindtype} ne 'columns' or belch "can't do 'columns' bindtype when called with arrayref"; # fold the list of values into a hash of column name - value pairs # (where the column names are artificially generated, and their # lexicographical ordering keep the ordering of the original list) my $i = "a"; # incremented values will be in lexicographical order my $data_in_hash = { map { ($i++ => $_) } @$data }; return $self->_insert_values($data_in_hash); } sub _insert_ARRAYREFREF { # literal SQL with bind my ($self, $data) = @_; my ($sql, @bind) = @${$data}; $self->_assert_bindval_matches_bindtype(@bind); return ($sql, @bind); } sub _insert_SCALARREF { # literal SQL without bind my ($self, $data) = @_; return ($$data); } sub _insert_values { my ($self, $data) = @_; my (@values, @all_bind); foreach my $column (sort keys %$data) { my $v = $data->{$column}; $self->_SWITCH_refkind($v, { ARRAYREF => sub { if ($self->{array_datatypes}) { # if array datatype are activated push @values, '?'; push @all_bind, $self->_bindtype($column, $v); } else { # else literal SQL with bind my ($sql, @bind) = @$v; $self->_assert_bindval_matches_bindtype(@bind); push @values, $sql; push @all_bind, @bind; } }, ARRAYREFREF => sub { # literal SQL with bind my ($sql, @bind) = @${$v}; $self->_assert_bindval_matches_bindtype(@bind); push @values, $sql; push @all_bind, @bind; }, # THINK : anything useful to do with a HASHREF ? HASHREF => sub { # (nothing, but old SQLA passed it through) #TODO in SQLA >= 2.0 it will die instead belch "HASH ref as bind value in insert is not supported"; push @values, '?'; push @all_bind, $self->_bindtype($column, $v); }, SCALARREF => sub { # literal SQL without bind push @values, $$v; }, SCALAR_or_UNDEF => sub { push @values, '?'; push @all_bind, $self->_bindtype($column, $v); }, }); } my $sql = $self->_sqlcase('values')." ( ".join(", ", @values)." )"; return ($sql, @all_bind); } #====================================================================== # UPDATE methods #====================================================================== sub update { my $self = shift; my $table = $self->_table(shift); my $data = shift || return; my $where = shift; # first build the 'SET' part of the sql statement my (@set, @all_bind); puke "Unsupported data type specified to \$sql->update" unless ref $data eq 'HASH'; for my $k (sort keys %$data) { my $v = $data->{$k}; my $r = ref $v; my $label = $self->_quote($k); $self->_SWITCH_refkind($v, { ARRAYREF => sub { if ($self->{array_datatypes}) { # array datatype push @set, "$label = ?"; push @all_bind, $self->_bindtype($k, $v); } else { # literal SQL with bind my ($sql, @bind) = @$v; $self->_assert_bindval_matches_bindtype(@bind); push @set, "$label = $sql"; push @all_bind, @bind; } }, ARRAYREFREF => sub { # literal SQL with bind my ($sql, @bind) = @${$v}; $self->_assert_bindval_matches_bindtype(@bind); push @set, "$label = $sql"; push @all_bind, @bind; }, SCALARREF => sub { # literal SQL without bind push @set, "$label = $$v"; }, SCALAR_or_UNDEF => sub { push @set, "$label = ?"; push @all_bind, $self->_bindtype($k, $v); }, }); } # generate sql my $sql = $self->_sqlcase('update') . " $table " . $self->_sqlcase('set ') . join ', ', @set; if ($where) { my($where_sql, @where_bind) = $self->where($where); $sql .= $where_sql; push @all_bind, @where_bind; } return wantarray ? ($sql, @all_bind) : $sql; } #====================================================================== # SELECT #====================================================================== sub select { my $self = shift; my $table = $self->_table(shift); my $fields = shift || '*'; my $where = shift; my $order = shift; my($where_sql, @bind) = $self->where($where, $order); my $f = (ref $fields eq 'ARRAY') ? join ', ', map { $self->_quote($_) } @$fields : $fields; my $sql = join(' ', $self->_sqlcase('select'), $f, $self->_sqlcase('from'), $table) . $where_sql; return wantarray ? ($sql, @bind) : $sql; } #====================================================================== # DELETE #====================================================================== sub delete { my $self = shift; my $table = $self->_table(shift); my $where = shift; my($where_sql, @bind) = $self->where($where); my $sql = $self->_sqlcase('delete from') . " $table" . $where_sql; return wantarray ? ($sql, @bind) : $sql; } #====================================================================== # WHERE: entry point #====================================================================== # Finally, a separate routine just to handle WHERE clauses sub where { my ($self, $where, $order) = @_; # where ? my ($sql, @bind) = $self->_recurse_where($where); $sql = $sql ? $self->_sqlcase(' where ') . "( $sql )" : ''; # order by? if ($order) { $sql .= $self->_order_by($order); } return wantarray ? ($sql, @bind) : $sql; } sub _recurse_where { my ($self, $where, $logic) = @_; # dispatch on appropriate method according to refkind of $where my $method = $self->_METHOD_FOR_refkind("_where", $where); my ($sql, @bind) = $self->$method($where, $logic); # DBIx::Class directly calls _recurse_where in scalar context, so # we must implement it, even if not in the official API return wantarray ? ($sql, @bind) : $sql; } #====================================================================== # WHERE: top-level ARRAYREF #====================================================================== sub _where_ARRAYREF { my ($self, $where, $logic) = @_; $logic = uc($logic || $self->{logic}); $logic eq 'AND' or $logic eq 'OR' or puke "unknown logic: $logic"; my @clauses = @$where; my (@sql_clauses, @all_bind); # need to use while() so can shift() for pairs while (my $el = shift @clauses) { # switch according to kind of $el and get corresponding ($sql, @bind) my ($sql, @bind) = $self->_SWITCH_refkind($el, { # skip empty elements, otherwise get invalid trailing AND stuff ARRAYREF => sub {$self->_recurse_where($el) if @$el}, ARRAYREFREF => sub { @{${$el}} if @{${$el}}}, HASHREF => sub {$self->_recurse_where($el, 'and') if %$el}, # LDNOTE : previous SQLA code for hashrefs was creating a dirty # side-effect: the first hashref within an array would change # the global logic to 'AND'. So [ {cond1, cond2}, [cond3, cond4] ] # was interpreted as "(cond1 AND cond2) OR (cond3 AND cond4)", # whereas it should be "(cond1 AND cond2) OR (cond3 OR cond4)". SCALARREF => sub { ($$el); }, SCALAR => sub {# top-level arrayref with scalars, recurse in pairs $self->_recurse_where({$el => shift(@clauses)})}, UNDEF => sub {puke "not supported : UNDEF in arrayref" }, }); if ($sql) { push @sql_clauses, $sql; push @all_bind, @bind; } } return $self->_join_sql_clauses($logic, \@sql_clauses, \@all_bind); } #====================================================================== # WHERE: top-level ARRAYREFREF #====================================================================== sub _where_ARRAYREFREF { my ($self, $where) = @_; my ($sql, @bind) = @{${$where}}; return ($sql, @bind); } #====================================================================== # WHERE: top-level HASHREF #====================================================================== sub _where_HASHREF { my ($self, $where) = @_; my (@sql_clauses, @all_bind); for my $k (sort keys %$where) { my $v = $where->{$k}; # ($k => $v) is either a special op or a regular hashpair my ($sql, @bind) = ($k =~ /^(-.+)/) ? $self->_where_op_in_hash($1, $v) : do { my $method = $self->_METHOD_FOR_refkind("_where_hashpair", $v); $self->$method($k, $v); }; push @sql_clauses, $sql; push @all_bind, @bind; } return $self->_join_sql_clauses('and', \@sql_clauses, \@all_bind); } sub _where_op_in_hash { my ($self, $orig_op, $v) = @_; # put the operator in canonical form my $op = $orig_op; $op =~ s/^-//; # remove initial dash $op =~ s/[_\t ]+/ /g; # underscores and whitespace become single spaces $op =~ s/^\s+|\s+$//g;# remove leading/trailing space $self->_debug("OP(-$op) within hashref, recursing..."); my $op_entry = first {$op =~ $_->{regex}} @{$self->{unary_ops}}; my $handler = $op_entry->{handler}; if (! $handler) { puke "unknown operator: $orig_op"; } elsif (not ref $handler) { if ($op =~ s/\s?\d+$//) { belch 'Use of [and|or|nest]_N modifiers is deprecated and will be removed in SQLA v2.0. ' . "You probably wanted ...-and => [ -$op => COND1, -$op => COND2 ... ]"; } return $self->$handler ($op, $v); } elsif (ref $handler eq 'CODE') { return $handler->($self, $op, $v); } else { puke "Illegal handler for operator $orig_op - expecting a method name or a coderef"; } } sub _where_op_ANDOR { my ($self, $op, $v) = @_; $self->_SWITCH_refkind($v, { ARRAYREF => sub { return $self->_where_ARRAYREF($v, $op); }, HASHREF => sub { return ( $op =~ /^or/i ) ? $self->_where_ARRAYREF( [ map { $_ => $v->{$_} } ( sort keys %$v ) ], $op ) : $self->_where_HASHREF($v); }, SCALARREF => sub { puke "-$op => \\\$scalar not supported, use -nest => ..."; }, ARRAYREFREF => sub { puke "-$op => \\[..] not supported, use -nest => ..."; }, SCALAR => sub { # permissively interpreted as SQL puke "-$op => 'scalar' not supported, use -nest => \\'scalar'"; }, UNDEF => sub { puke "-$op => undef not supported"; }, }); } sub _where_op_NEST { my ($self, $op, $v) = @_; $self->_SWITCH_refkind($v, { ARRAYREF => sub { return $self->_where_ARRAYREF($v, ''); }, HASHREF => sub { return $self->_where_HASHREF($v); }, SCALARREF => sub { # literal SQL return ($$v); }, ARRAYREFREF => sub { # literal SQL return @{${$v}}; }, SCALAR => sub { # permissively interpreted as SQL belch "literal SQL should be -nest => \\'scalar' " . "instead of -nest => 'scalar' "; return ($v); }, UNDEF => sub { puke "-$op => undef not supported"; }, }); } sub _where_op_BOOL { my ($self, $op, $v) = @_; my ( $prefix, $suffix ) = ( $op =~ /\bnot\b/i ) ? ( '(NOT ', ')' ) : ( '', '' ); $self->_SWITCH_refkind($v, { ARRAYREF => sub { my ( $sql, @bind ) = $self->_where_ARRAYREF($v, ''); return ( ($prefix . $sql . $suffix), @bind ); }, ARRAYREFREF => sub { my ( $sql, @bind ) = @{ ${$v} }; return ( ($prefix . $sql . $suffix), @bind ); }, HASHREF => sub { my ( $sql, @bind ) = $self->_where_HASHREF($v); return ( ($prefix . $sql . $suffix), @bind ); }, SCALARREF => sub { # literal SQL return ($prefix . $$v . $suffix); }, SCALAR => sub { # interpreted as SQL column return ($prefix . $self->_convert($self->_quote($v)) . $suffix); }, UNDEF => sub { puke "-$op => undef not supported"; }, }); } sub _where_hashpair_ARRAYREF { my ($self, $k, $v) = @_; if( @$v ) { my @v = @$v; # need copy because of shift below $self->_debug("ARRAY($k) means distribute over elements"); # put apart first element if it is an operator (-and, -or) my $op = ( (defined $v[0] && $v[0] =~ /^ - (?: AND|OR ) $/ix) ? shift @v : '' ); my @distributed = map { {$k => $_} } @v; if ($op) { $self->_debug("OP($op) reinjected into the distributed array"); unshift @distributed, $op; } my $logic = $op ? substr($op, 1) : ''; return $self->_recurse_where(\@distributed, $logic); } else { # LDNOTE : not sure of this one. What does "distribute over nothing" mean? $self->_debug("empty ARRAY($k) means 0=1"); return ($self->{sqlfalse}); } } sub _where_hashpair_HASHREF { my ($self, $k, $v, $logic) = @_; $logic ||= 'and'; my ($all_sql, @all_bind); for my $orig_op (sort keys %$v) { my $val = $v->{$orig_op}; # put the operator in canonical form my $op = $orig_op; $op =~ s/^-//; # remove initial dash $op =~ s/[_\t ]+/ /g; # underscores and whitespace become single spaces $op =~ s/^\s+|\s+$//g;# remove leading/trailing space my ($sql, @bind); # CASE: special operators like -in or -between my $special_op = first {$op =~ $_->{regex}} @{$self->{special_ops}}; if ($special_op) { my $handler = $special_op->{handler}; if (! $handler) { puke "No handler supplied for special operator $orig_op"; } elsif (not ref $handler) { ($sql, @bind) = $self->$handler ($k, $op, $val); } elsif (ref $handler eq 'CODE') { ($sql, @bind) = $handler->($self, $k, $op, $val); } else { puke "Illegal handler for special operator $orig_op - expecting a method name or a coderef"; } } else { $self->_SWITCH_refkind($val, { ARRAYREF => sub { # CASE: col => {op => \@vals} ($sql, @bind) = $self->_where_field_op_ARRAYREF($k, $op, $val); }, SCALARREF => sub { # CASE: col => {op => \$scalar} (literal SQL without bind) $sql = join ' ', $self->_convert($self->_quote($k)), $self->_sqlcase($op), $$val; }, ARRAYREFREF => sub { # CASE: col => {op => \[$sql, @bind]} (literal SQL with bind) my ($sub_sql, @sub_bind) = @$$val; $self->_assert_bindval_matches_bindtype(@sub_bind); $sql = join ' ', $self->_convert($self->_quote($k)), $self->_sqlcase($op), $sub_sql; @bind = @sub_bind; }, HASHREF => sub { ($sql, @bind) = $self->_where_hashpair_HASHREF($k, $val, $op); }, UNDEF => sub { # CASE: col => {op => undef} : sql "IS (NOT)? NULL" my $is = ($op =~ $self->{equality_op}) ? 'is' : ($op =~ $self->{inequality_op}) ? 'is not' : puke "unexpected operator '$orig_op' with undef operand"; $sql = $self->_quote($k) . $self->_sqlcase(" $is null"); }, FALLBACK => sub { # CASE: col => {op => $scalar} $sql = join ' ', $self->_convert($self->_quote($k)), $self->_sqlcase($op), $self->_convert('?'); @bind = $self->_bindtype($k, $val); }, }); } ($all_sql) = (defined $all_sql and $all_sql) ? $self->_join_sql_clauses($logic, [$all_sql, $sql], []) : $sql; push @all_bind, @bind; } return ($all_sql, @all_bind); } sub _where_field_op_ARRAYREF { my ($self, $k, $op, $vals) = @_; my @vals = @$vals; #always work on a copy if(@vals) { $self->_debug(sprintf '%s means multiple elements: [ %s ]', $vals, join (', ', map { defined $_ ? "'$_'" : 'NULL' } @vals ), ); # see if the first element is an -and/-or op my $logic; if (defined $vals[0] && $vals[0] =~ /^ - ( AND|OR ) $/ix) { $logic = uc $1; shift @vals; } # distribute $op over each remaining member of @vals, append logic if exists return $self->_recurse_where([map { {$k => {$op, $_}} } @vals], $logic); # LDNOTE : had planned to change the distribution logic when # $op =~ $self->{inequality_op}, because of Morgan laws : # with {field => {'!=' => [22, 33]}}, it would be ridiculous to generate # WHERE field != 22 OR field != 33 : the user probably means # WHERE field != 22 AND field != 33. # To do this, replace the above to roughly : # my $logic = ($op =~ $self->{inequality_op}) ? 'AND' : 'OR'; # return $self->_recurse_where([map { {$k => {$op, $_}} } @vals], $logic); } else { # try to DWIM on equality operators # LDNOTE : not 100% sure this is the correct thing to do ... return ($self->{sqlfalse}) if $op =~ $self->{equality_op}; return ($self->{sqltrue}) if $op =~ $self->{inequality_op}; # otherwise puke "operator '$op' applied on an empty array (field '$k')"; } } sub _where_hashpair_SCALARREF { my ($self, $k, $v) = @_; $self->_debug("SCALAR($k) means literal SQL: $$v"); my $sql = $self->_quote($k) . " " . $$v; return ($sql); } # literal SQL with bind sub _where_hashpair_ARRAYREFREF { my ($self, $k, $v) = @_; $self->_debug("REF($k) means literal SQL: @${$v}"); my ($sql, @bind) = @${$v}; $self->_assert_bindval_matches_bindtype(@bind); $sql = $self->_quote($k) . " " . $sql; return ($sql, @bind ); } # literal SQL without bind sub _where_hashpair_SCALAR { my ($self, $k, $v) = @_; $self->_debug("NOREF($k) means simple key=val: $k $self->{cmp} $v"); my $sql = join ' ', $self->_convert($self->_quote($k)), $self->_sqlcase($self->{cmp}), $self->_convert('?'); my @bind = $self->_bindtype($k, $v); return ( $sql, @bind); } sub _where_hashpair_UNDEF { my ($self, $k, $v) = @_; $self->_debug("UNDEF($k) means IS NULL"); my $sql = $self->_quote($k) . $self->_sqlcase(' is null'); return ($sql); } #====================================================================== # WHERE: TOP-LEVEL OTHERS (SCALARREF, SCALAR, UNDEF) #====================================================================== sub _where_SCALARREF { my ($self, $where) = @_; # literal sql $self->_debug("SCALAR(*top) means literal SQL: $$where"); return ($$where); } sub _where_SCALAR { my ($self, $where) = @_; # literal sql $self->_debug("NOREF(*top) means literal SQL: $where"); return ($where); } sub _where_UNDEF { my ($self) = @_; return (); } #====================================================================== # WHERE: BUILTIN SPECIAL OPERATORS (-in, -between) #====================================================================== sub _where_field_BETWEEN { my ($self, $k, $op, $vals) = @_; my ($label, $and, $placeholder); $label = $self->_convert($self->_quote($k)); $and = ' ' . $self->_sqlcase('and') . ' '; $placeholder = $self->_convert('?'); $op = $self->_sqlcase($op); my ($clause, @bind) = $self->_SWITCH_refkind($vals, { ARRAYREFREF => sub { return @$$vals; }, SCALARREF => sub { return $$vals; }, ARRAYREF => sub { puke "special op 'between' accepts an arrayref with exactly two values" if @$vals != 2; my (@all_sql, @all_bind); foreach my $val (@$vals) { my ($sql, @bind) = $self->_SWITCH_refkind($val, { SCALAR => sub { return ($placeholder, ($val)); }, SCALARREF => sub { return ($self->_convert($$val), ()); }, ARRAYREFREF => sub { my ($sql, @bind) = @$$val; return ($self->_convert($sql), @bind); }, }); push @all_sql, $sql; push @all_bind, @bind; } return ( (join $and, @all_sql), $self->_bindtype($k, @all_bind), ); }, FALLBACK => sub { puke "special op 'between' accepts an arrayref with two values, or a single literal scalarref/arrayref-ref"; }, }); my $sql = "( $label $op $clause )"; return ($sql, @bind) } sub _where_field_IN { my ($self, $k, $op, $vals) = @_; # backwards compatibility : if scalar, force into an arrayref $vals = [$vals] if defined $vals && ! ref $vals; my ($label) = $self->_convert($self->_quote($k)); my ($placeholder) = $self->_convert('?'); $op = $self->_sqlcase($op); my ($sql, @bind) = $self->_SWITCH_refkind($vals, { ARRAYREF => sub { # list of choices if (@$vals) { # nonempty list my $placeholders = join ", ", (($placeholder) x @$vals); my $sql = "$label $op ( $placeholders )"; my @bind = $self->_bindtype($k, @$vals); return ($sql, @bind); } else { # empty list : some databases won't understand "IN ()", so DWIM my $sql = ($op =~ /\bnot\b/i) ? $self->{sqltrue} : $self->{sqlfalse}; return ($sql); } }, SCALARREF => sub { # literal SQL my $sql = $self->_open_outer_paren ($$vals); return ("$label $op ( $sql )"); }, ARRAYREFREF => sub { # literal SQL with bind my ($sql, @bind) = @$$vals; $self->_assert_bindval_matches_bindtype(@bind); $sql = $self->_open_outer_paren ($sql); return ("$label $op ( $sql )", @bind); }, FALLBACK => sub { puke "special op 'in' requires an arrayref (or scalarref/arrayref-ref)"; }, }); return ($sql, @bind); } # Some databases (SQLite) treat col IN (1, 2) different from # col IN ( (1, 2) ). Use this to strip all outer parens while # adding them back in the corresponding method sub _open_outer_paren { my ($self, $sql) = @_; $sql = $1 while $sql =~ /^ \s* \( (.*) \) \s* $/x; return $sql; } #====================================================================== # ORDER BY #====================================================================== sub _order_by { my ($self, $arg) = @_; my (@sql, @bind); for my $c ($self->_order_by_chunks ($arg) ) { $self->_SWITCH_refkind ($c, { SCALAR => sub { push @sql, $c }, ARRAYREF => sub { push @sql, shift @$c; push @bind, @$c }, }); } my $sql = @sql ? sprintf ('%s %s', $self->_sqlcase(' order by'), join (', ', @sql) ) : '' ; return wantarray ? ($sql, @bind) : $sql; } sub _order_by_chunks { my ($self, $arg) = @_; return $self->_SWITCH_refkind($arg, { ARRAYREF => sub { map { $self->_order_by_chunks ($_ ) } @$arg; }, ARRAYREFREF => sub { [ @$$arg ] }, SCALAR => sub {$self->_quote($arg)}, UNDEF => sub {return () }, SCALARREF => sub {$$arg}, # literal SQL, no quoting HASHREF => sub { # get first pair in hash my ($key, $val) = each %$arg; return () unless $key; if ( (keys %$arg) > 1 or not $key =~ /^-(desc|asc)/i ) { puke "hash passed to _order_by must have exactly one key (-desc or -asc)"; } my $direction = $1; my @ret; for my $c ($self->_order_by_chunks ($val)) { my ($sql, @bind); $self->_SWITCH_refkind ($c, { SCALAR => sub { $sql = $c; }, ARRAYREF => sub { ($sql, @bind) = @$c; }, }); $sql = $sql . ' ' . $self->_sqlcase($direction); push @ret, [ $sql, @bind]; } return @ret; }, }); } #====================================================================== # DATASOURCE (FOR NOW, JUST PLAIN TABLE OR LIST OF TABLES) #====================================================================== sub _table { my $self = shift; my $from = shift; $self->_SWITCH_refkind($from, { ARRAYREF => sub {join ', ', map { $self->_quote($_) } @$from;}, SCALAR => sub {$self->_quote($from)}, SCALARREF => sub {$$from}, ARRAYREFREF => sub {join ', ', @$from;}, }); } #====================================================================== # UTILITY FUNCTIONS #====================================================================== sub _quote { my $self = shift; my $label = shift; $label or puke "can't quote an empty label"; # left and right quote characters my ($ql, $qr, @other) = $self->_SWITCH_refkind($self->{quote_char}, { SCALAR => sub {($self->{quote_char}, $self->{quote_char})}, ARRAYREF => sub {@{$self->{quote_char}}}, UNDEF => sub {()}, }); not @other or puke "quote_char must be an arrayref of 2 values"; # no quoting if no quoting chars $ql or return $label; # no quoting for literal SQL return $$label if ref($label) eq 'SCALAR'; # separate table / column (if applicable) my $sep = $self->{name_sep} || ''; my @to_quote = $sep ? split /\Q$sep\E/, $label : ($label); # do the quoting, except for "*" or for `table`.* my @quoted = map { $_ eq '*' ? $_: $ql.$_.$qr} @to_quote; # reassemble and return. return join $sep, @quoted; } # Conversion, if applicable sub _convert ($) { my ($self, $arg) = @_; # LDNOTE : modified the previous implementation below because # it was not consistent : the first "return" is always an array, # the second "return" is context-dependent. Anyway, _convert # seems always used with just a single argument, so make it a # scalar function. # return @_ unless $self->{convert}; # my $conv = $self->_sqlcase($self->{convert}); # my @ret = map { $conv.'('.$_.')' } @_; # return wantarray ? @ret : $ret[0]; if ($self->{convert}) { my $conv = $self->_sqlcase($self->{convert}); $arg = $conv.'('.$arg.')'; } return $arg; } # And bindtype sub _bindtype (@) { my $self = shift; my($col, @vals) = @_; #LDNOTE : changed original implementation below because it did not make # sense when bindtype eq 'columns' and @vals > 1. # return $self->{bindtype} eq 'columns' ? [ $col, @vals ] : @vals; return $self->{bindtype} eq 'columns' ? map {[$col, $_]} @vals : @vals; } # Dies if any element of @bind is not in [colname => value] format # if bindtype is 'columns'. sub _assert_bindval_matches_bindtype { my ($self, @bind) = @_; if ($self->{bindtype} eq 'columns') { foreach my $val (@bind) { if (!defined $val || ref($val) ne 'ARRAY' || @$val != 2) { die "bindtype 'columns' selected, you need to pass: [column_name => bind_value]" } } } } sub _join_sql_clauses { my ($self, $logic, $clauses_aref, $bind_aref) = @_; if (@$clauses_aref > 1) { my $join = " " . $self->_sqlcase($logic) . " "; my $sql = '( ' . join($join, @$clauses_aref) . ' )'; return ($sql, @$bind_aref); } elsif (@$clauses_aref) { return ($clauses_aref->[0], @$bind_aref); # no parentheses } else { return (); # if no SQL, ignore @$bind_aref } } # Fix SQL case, if so requested sub _sqlcase { my $self = shift; # LDNOTE: if $self->{case} is true, then it contains 'lower', so we # don't touch the argument ... crooked logic, but let's not change it! return $self->{case} ? $_[0] : uc($_[0]); } #====================================================================== # DISPATCHING FROM REFKIND #====================================================================== sub _refkind { my ($self, $data) = @_; my $suffix = ''; my $ref; my $n_steps = 0; while (1) { # blessed objects are treated like scalars $ref = (blessed $data) ? '' : ref $data; $n_steps += 1 if $ref; last if $ref ne 'REF'; $data = $$data; } my $base = $ref || (defined $data ? 'SCALAR' : 'UNDEF'); return $base . ('REF' x $n_steps); } sub _try_refkind { my ($self, $data) = @_; my @try = ($self->_refkind($data)); push @try, 'SCALAR_or_UNDEF' if $try[0] eq 'SCALAR' || $try[0] eq 'UNDEF'; push @try, 'FALLBACK'; return @try; } sub _METHOD_FOR_refkind { my ($self, $meth_prefix, $data) = @_; my $method = first {$_} map {$self->can($meth_prefix."_".$_)} $self->_try_refkind($data) or puke "cannot dispatch on '$meth_prefix' for ".$self->_refkind($data); return $method; } sub _SWITCH_refkind { my ($self, $data, $dispatch_table) = @_; my $coderef = first {$_} map {$dispatch_table->{$_}} $self->_try_refkind($data) or puke "no dispatch entry for ".$self->_refkind($data); $coderef->(); } #====================================================================== # VALUES, GENERATE, AUTOLOAD #====================================================================== # LDNOTE: original code from nwiger, didn't touch code in that section # I feel the AUTOLOAD stuff should not be the default, it should # only be activated on explicit demand by user. sub values { my $self = shift; my $data = shift || return; puke "Argument to ", __PACKAGE__, "->values must be a \\%hash" unless ref $data eq 'HASH'; my @all_bind; foreach my $k ( sort keys %$data ) { my $v = $data->{$k}; $self->_SWITCH_refkind($v, { ARRAYREF => sub { if ($self->{array_datatypes}) { # array datatype push @all_bind, $self->_bindtype($k, $v); } else { # literal SQL with bind my ($sql, @bind) = @$v; $self->_assert_bindval_matches_bindtype(@bind); push @all_bind, @bind; } }, ARRAYREFREF => sub { # literal SQL with bind my ($sql, @bind) = @${$v}; $self->_assert_bindval_matches_bindtype(@bind); push @all_bind, @bind; }, SCALARREF => sub { # literal SQL without bind }, SCALAR_or_UNDEF => sub { push @all_bind, $self->_bindtype($k, $v); }, }); } return @all_bind; } sub generate { my $self = shift; my(@sql, @sqlq, @sqlv); for (@_) { my $ref = ref $_; if ($ref eq 'HASH') { for my $k (sort keys %$_) { my $v = $_->{$k}; my $r = ref $v; my $label = $self->_quote($k); if ($r eq 'ARRAY') { # literal SQL with bind my ($sql, @bind) = @$v; $self->_assert_bindval_matches_bindtype(@bind); push @sqlq, "$label = $sql"; push @sqlv, @bind; } elsif ($r eq 'SCALAR') { # literal SQL without bind push @sqlq, "$label = $$v"; } else { push @sqlq, "$label = ?"; push @sqlv, $self->_bindtype($k, $v); } } push @sql, $self->_sqlcase('set'), join ', ', @sqlq; } elsif ($ref eq 'ARRAY') { # unlike insert(), assume these are ONLY the column names, i.e. for SQL for my $v (@$_) { my $r = ref $v; if ($r eq 'ARRAY') { # literal SQL with bind my ($sql, @bind) = @$v; $self->_assert_bindval_matches_bindtype(@bind); push @sqlq, $sql; push @sqlv, @bind; } elsif ($r eq 'SCALAR') { # literal SQL without bind # embedded literal SQL push @sqlq, $$v; } else { push @sqlq, '?'; push @sqlv, $v; } } push @sql, '(' . join(', ', @sqlq) . ')'; } elsif ($ref eq 'SCALAR') { # literal SQL push @sql, $$_; } else { # strings get case twiddled push @sql, $self->_sqlcase($_); } } my $sql = join ' ', @sql; # this is pretty tricky # if ask for an array, return ($stmt, @bind) # otherwise, s/?/shift @sqlv/ to put it inline if (wantarray) { return ($sql, @sqlv); } else { 1 while $sql =~ s/\?/my $d = shift(@sqlv); ref $d ? $d->[1] : $d/e; return $sql; } } sub DESTROY { 1 } sub AUTOLOAD { # This allows us to check for a local, then _form, attr my $self = shift; my($name) = $AUTOLOAD =~ /.*::(.+)/; return $self->generate($name, @_); } 1; __END__ =head1 NAME SQL::Abstract - Generate SQL from Perl data structures =head1 SYNOPSIS use SQL::Abstract; my $sql = SQL::Abstract->new; my($stmt, @bind) = $sql->select($table, \@fields, \%where, \@order); my($stmt, @bind) = $sql->insert($table, \%fieldvals || \@values); my($stmt, @bind) = $sql->update($table, \%fieldvals, \%where); my($stmt, @bind) = $sql->delete($table, \%where); # Then, use these in your DBI statements my $sth = $dbh->prepare($stmt); $sth->execute(@bind); # Just generate the WHERE clause my($stmt, @bind) = $sql->where(\%where, \@order); # Return values in the same order, for hashed queries # See PERFORMANCE section for more details my @bind = $sql->values(\%fieldvals); =head1 DESCRIPTION This module was inspired by the excellent L. However, in using that module I found that what I really wanted to do was generate SQL, but still retain complete control over my statement handles and use the DBI interface. So, I set out to create an abstract SQL generation module. While based on the concepts used by L, there are several important differences, especially when it comes to WHERE clauses. I have modified the concepts used to make the SQL easier to generate from Perl data structures and, IMO, more intuitive. The underlying idea is for this module to do what you mean, based on the data structures you provide it. The big advantage is that you don't have to modify your code every time your data changes, as this module figures it out. To begin with, an SQL INSERT is as easy as just specifying a hash of C pairs: my %data = ( name => 'Jimbo Bobson', phone => '123-456-7890', address => '42 Sister Lane', city => 'St. Louis', state => 'Louisiana', ); The SQL can then be generated with this: my($stmt, @bind) = $sql->insert('people', \%data); Which would give you something like this: $stmt = "INSERT INTO people (address, city, name, phone, state) VALUES (?, ?, ?, ?, ?)"; @bind = ('42 Sister Lane', 'St. Louis', 'Jimbo Bobson', '123-456-7890', 'Louisiana'); These are then used directly in your DBI code: my $sth = $dbh->prepare($stmt); $sth->execute(@bind); =head2 Inserting and Updating Arrays If your database has array types (like for example Postgres), activate the special option C<< array_datatypes => 1 >> when creating the C object. Then you may use an arrayref to insert and update database array types: my $sql = SQL::Abstract->new(array_datatypes => 1); my %data = ( planets => [qw/Mercury Venus Earth Mars/] ); my($stmt, @bind) = $sql->insert('solar_system', \%data); This results in: $stmt = "INSERT INTO solar_system (planets) VALUES (?)" @bind = (['Mercury', 'Venus', 'Earth', 'Mars']); =head2 Inserting and Updating SQL In order to apply SQL functions to elements of your C<%data> you may specify a reference to an arrayref for the given hash value. For example, if you need to execute the Oracle C function on a value, you can say something like this: my %data = ( name => 'Bill', date_entered => \["to_date(?,'MM/DD/YYYY')", "03/02/2003"], ); The first value in the array is the actual SQL. Any other values are optional and would be included in the bind values array. This gives you: my($stmt, @bind) = $sql->insert('people', \%data); $stmt = "INSERT INTO people (name, date_entered) VALUES (?, to_date(?,'MM/DD/YYYY'))"; @bind = ('Bill', '03/02/2003'); An UPDATE is just as easy, all you change is the name of the function: my($stmt, @bind) = $sql->update('people', \%data); Notice that your C<%data> isn't touched; the module will generate the appropriately quirky SQL for you automatically. Usually you'll want to specify a WHERE clause for your UPDATE, though, which is where handling C<%where> hashes comes in handy... =head2 Complex where statements This module can generate pretty complicated WHERE statements easily. For example, simple C pairs are taken to mean equality, and if you want to see if a field is within a set of values, you can use an arrayref. Let's say we wanted to SELECT some data based on this criteria: my %where = ( requestor => 'inna', worker => ['nwiger', 'rcwe', 'sfz'], status => { '!=', 'completed' } ); my($stmt, @bind) = $sql->select('tickets', '*', \%where); The above would give you something like this: $stmt = "SELECT * FROM tickets WHERE ( requestor = ? ) AND ( status != ? ) AND ( worker = ? OR worker = ? OR worker = ? )"; @bind = ('inna', 'completed', 'nwiger', 'rcwe', 'sfz'); Which you could then use in DBI code like so: my $sth = $dbh->prepare($stmt); $sth->execute(@bind); Easy, eh? =head1 FUNCTIONS The functions are simple. There's one for each major SQL operation, and a constructor you use first. The arguments are specified in a similar order to each function (table, then fields, then a where clause) to try and simplify things. =head2 new(option => 'value') The C function takes a list of options and values, and returns a new B object which can then be used to generate SQL through the methods below. The options accepted are: =over =item case If set to 'lower', then SQL will be generated in all lowercase. By default SQL is generated in "textbook" case meaning something like: SELECT a_field FROM a_table WHERE some_field LIKE '%someval%' Any setting other than 'lower' is ignored. =item cmp This determines what the default comparison operator is. By default it is C<=>, meaning that a hash like this: %where = (name => 'nwiger', email => 'nate@wiger.org'); Will generate SQL like this: WHERE name = 'nwiger' AND email = 'nate@wiger.org' However, you may want loose comparisons by default, so if you set C to C you would get SQL such as: WHERE name like 'nwiger' AND email like 'nate@wiger.org' You can also override the comparsion on an individual basis - see the huge section on L at the bottom. =item sqltrue, sqlfalse Expressions for inserting boolean values within SQL statements. By default these are C<1=1> and C<1=0>. They are used by the special operators C<-in> and C<-not_in> for generating correct SQL even when the argument is an empty array (see below). =item logic This determines the default logical operator for multiple WHERE statements in arrays or hashes. If absent, the default logic is "or" for arrays, and "and" for hashes. This means that a WHERE array of the form: @where = ( event_date => {'>=', '2/13/99'}, event_date => {'<=', '4/24/03'}, ); will generate SQL like this: WHERE event_date >= '2/13/99' OR event_date <= '4/24/03' This is probably not what you want given this query, though (look at the dates). To change the "OR" to an "AND", simply specify: my $sql = SQL::Abstract->new(logic => 'and'); Which will change the above C to: WHERE event_date >= '2/13/99' AND event_date <= '4/24/03' The logic can also be changed locally by inserting a modifier in front of an arrayref : @where = (-and => [event_date => {'>=', '2/13/99'}, event_date => {'<=', '4/24/03'} ]); See the L section for explanations. =item convert This will automatically convert comparisons using the specified SQL function for both column and value. This is mostly used with an argument of C or C, so that the SQL will have the effect of case-insensitive "searches". For example, this: $sql = SQL::Abstract->new(convert => 'upper'); %where = (keywords => 'MaKe iT CAse inSeNSItive'); Will turn out the following SQL: WHERE upper(keywords) like upper('MaKe iT CAse inSeNSItive') The conversion can be C, C, or any other SQL function that can be applied symmetrically to fields (actually B does not validate this option; it will just pass through what you specify verbatim). =item bindtype This is a kludge because many databases suck. For example, you can't just bind values using DBI's C for Oracle C or C fields. Instead, you have to use C: $sth->bind_param(1, 'reg data'); $sth->bind_param(2, $lots, {ora_type => ORA_CLOB}); The problem is, B will normally just return a C<@bind> array, which loses track of which field each slot refers to. Fear not. If you specify C in new, you can determine how C<@bind> is returned. Currently, you can specify either C (default) or C. If you specify C, you will get an array that looks like this: my $sql = SQL::Abstract->new(bindtype => 'columns'); my($stmt, @bind) = $sql->insert(...); @bind = ( [ 'column1', 'value1' ], [ 'column2', 'value2' ], [ 'column3', 'value3' ], ); You can then iterate through this manually, using DBI's C. $sth->prepare($stmt); my $i = 1; for (@bind) { my($col, $data) = @$_; if ($col eq 'details' || $col eq 'comments') { $sth->bind_param($i, $data, {ora_type => ORA_CLOB}); } elsif ($col eq 'image') { $sth->bind_param($i, $data, {ora_type => ORA_BLOB}); } else { $sth->bind_param($i, $data); } $i++; } $sth->execute; # execute without @bind now Now, why would you still use B if you have to do this crap? Basically, the advantage is still that you don't have to care which fields are or are not included. You could wrap that above C loop in a simple sub called C or something and reuse it repeatedly. You still get a layer of abstraction over manual SQL specification. Note that if you set L to C, the C<\[$sql, @bind]> construct (see L) will expect the bind values in this format. =item quote_char This is the character that a table or column name will be quoted with. By default this is an empty string, but you could set it to the character C<`>, to generate SQL like this: SELECT `a_field` FROM `a_table` WHERE `some_field` LIKE '%someval%' Alternatively, you can supply an array ref of two items, the first being the left hand quote character, and the second the right hand quote character. For example, you could supply C<['[',']']> for SQL Server 2000 compliant quotes that generates SQL like this: SELECT [a_field] FROM [a_table] WHERE [some_field] LIKE '%someval%' Quoting is useful if you have tables or columns names that are reserved words in your database's SQL dialect. =item name_sep This is the character that separates a table and column name. It is necessary to specify this when the C option is selected, so that tables and column names can be individually quoted like this: SELECT `table`.`one_field` FROM `table` WHERE `table`.`other_field` = 1 =item array_datatypes When this option is true, arrayrefs in INSERT or UPDATE are interpreted as array datatypes and are passed directly to the DBI layer. When this option is false, arrayrefs are interpreted as literal SQL, just like refs to arrayrefs (but this behavior is for backwards compatibility; when writing new queries, use the "reference to arrayref" syntax for literal SQL). =item special_ops Takes a reference to a list of "special operators" to extend the syntax understood by L. See section L for details. =item unary_ops Takes a reference to a list of "unary operators" to extend the syntax understood by L. See section L for details. =back =head2 insert($table, \@values || \%fieldvals) This is the simplest function. You simply give it a table name and either an arrayref of values or hashref of field/value pairs. It returns an SQL INSERT statement and a list of bind values. See the sections on L and L for information on how to insert with those data types. =head2 update($table, \%fieldvals, \%where) This takes a table, hashref of field/value pairs, and an optional hashref L. It returns an SQL UPDATE function and a list of bind values. See the sections on L and L for information on how to insert with those data types. =head2 select($source, $fields, $where, $order) This returns a SQL SELECT statement and associated list of bind values, as specified by the arguments : =over =item $source Specification of the 'FROM' part of the statement. The argument can be either a plain scalar (interpreted as a table name, will be quoted), or an arrayref (interpreted as a list of table names, joined by commas, quoted), or a scalarref (literal table name, not quoted), or a ref to an arrayref (list of literal table names, joined by commas, not quoted). =item $fields Specification of the list of fields to retrieve from the source. The argument can be either an arrayref (interpreted as a list of field names, will be joined by commas and quoted), or a plain scalar (literal SQL, not quoted). Please observe that this API is not as flexible as for the first argument C<$table>, for backwards compatibility reasons. =item $where Optional argument to specify the WHERE part of the query. The argument is most often a hashref, but can also be an arrayref or plain scalar -- see section L for details. =item $order Optional argument to specify the ORDER BY part of the query. The argument can be a scalar, a hashref or an arrayref -- see section L for details. =back =head2 delete($table, \%where) This takes a table name and optional hashref L. It returns an SQL DELETE statement and list of bind values. =head2 where(\%where, \@order) This is used to generate just the WHERE clause. For example, if you have an arbitrary data structure and know what the rest of your SQL is going to look like, but want an easy way to produce a WHERE clause, use this. It returns an SQL WHERE clause and list of bind values. =head2 values(\%data) This just returns the values from the hash C<%data>, in the same order that would be returned from any of the other above queries. Using this allows you to markedly speed up your queries if you are affecting lots of rows. See below under the L section. =head2 generate($any, 'number', $of, \@data, $struct, \%types) Warning: This is an experimental method and subject to change. This returns arbitrarily generated SQL. It's a really basic shortcut. It will return two different things, depending on return context: my($stmt, @bind) = $sql->generate('create table', \$table, \@fields); my $stmt_and_val = $sql->generate('create table', \$table, \@fields); These would return the following: # First calling form $stmt = "CREATE TABLE test (?, ?)"; @bind = (field1, field2); # Second calling form $stmt_and_val = "CREATE TABLE test (field1, field2)"; Depending on what you're trying to do, it's up to you to choose the correct format. In this example, the second form is what you would want. By the same token: $sql->generate('alter session', { nls_date_format => 'MM/YY' }); Might give you: ALTER SESSION SET nls_date_format = 'MM/YY' You get the idea. Strings get their case twiddled, but everything else remains verbatim. =head1 WHERE CLAUSES =head2 Introduction This module uses a variation on the idea from L. It is B, repeat I 100% compatible. B The easiest way to explain is to show lots of examples. After each C<%where> hash shown, it is assumed you used: my($stmt, @bind) = $sql->where(\%where); However, note that the C<%where> hash can be used directly in any of the other functions as well, as described above. =head2 Key-value pairs So, let's get started. To begin, a simple hash: my %where = ( user => 'nwiger', status => 'completed' ); Is converted to SQL C statements: $stmt = "WHERE user = ? AND status = ?"; @bind = ('nwiger', 'completed'); One common thing I end up doing is having a list of values that a field can be in. To do this, simply specify a list inside of an arrayref: my %where = ( user => 'nwiger', status => ['assigned', 'in-progress', 'pending']; ); This simple code will create the following: $stmt = "WHERE user = ? AND ( status = ? OR status = ? OR status = ? )"; @bind = ('nwiger', 'assigned', 'in-progress', 'pending'); A field associated to an empty arrayref will be considered a logical false and will generate 0=1. =head2 Specific comparison operators If you want to specify a different type of operator for your comparison, you can use a hashref for a given column: my %where = ( user => 'nwiger', status => { '!=', 'completed' } ); Which would generate: $stmt = "WHERE user = ? AND status != ?"; @bind = ('nwiger', 'completed'); To test against multiple values, just enclose the values in an arrayref: status => { '=', ['assigned', 'in-progress', 'pending'] }; Which would give you: "WHERE status = ? OR status = ? OR status = ?" The hashref can also contain multiple pairs, in which case it is expanded into an C of its elements: my %where = ( user => 'nwiger', status => { '!=', 'completed', -not_like => 'pending%' } ); # Or more dynamically, like from a form $where{user} = 'nwiger'; $where{status}{'!='} = 'completed'; $where{status}{'-not_like'} = 'pending%'; # Both generate this $stmt = "WHERE user = ? AND status != ? AND status NOT LIKE ?"; @bind = ('nwiger', 'completed', 'pending%'); To get an OR instead, you can combine it with the arrayref idea: my %where => ( user => 'nwiger', priority => [ {'=', 2}, {'!=', 1} ] ); Which would generate: $stmt = "WHERE user = ? AND priority = ? OR priority != ?"; @bind = ('nwiger', '2', '1'); If you want to include literal SQL (with or without bind values), just use a scalar reference or array reference as the value: my %where = ( date_entered => { '>' => \["to_date(?, 'MM/DD/YYYY')", "11/26/2008"] }, date_expires => { '<' => \"now()" } ); Which would generate: $stmt = "WHERE date_entered > "to_date(?, 'MM/DD/YYYY') AND date_expires < now()"; @bind = ('11/26/2008'); =head2 Logic and nesting operators In the example above, there is a subtle trap if you want to say something like this (notice the C): WHERE priority != ? AND priority != ? Because, in Perl you I do this: priority => { '!=', 2, '!=', 1 } As the second C key will obliterate the first. The solution is to use the special C<-modifier> form inside an arrayref: priority => [ -and => {'!=', 2}, {'!=', 1} ] Normally, these would be joined by C, but the modifier tells it to use C instead. (Hint: You can use this in conjunction with the C option to C in order to change the way your queries work by default.) B Note that the C<-modifier> goes B the arrayref, as an extra first element. This will B do what you think it might: priority => -and => [{'!=', 2}, {'!=', 1}] # WRONG! Here is a quick list of equivalencies, since there is some overlap: # Same status => {'!=', 'completed', 'not like', 'pending%' } status => [ -and => {'!=', 'completed'}, {'not like', 'pending%'}] # Same status => {'=', ['assigned', 'in-progress']} status => [ -or => {'=', 'assigned'}, {'=', 'in-progress'}] status => [ {'=', 'assigned'}, {'=', 'in-progress'} ] =head2 Special operators : IN, BETWEEN, etc. You can also use the hashref format to compare a list of fields using the C comparison operator, by specifying the list as an arrayref: my %where = ( status => 'completed', reportid => { -in => [567, 2335, 2] } ); Which would generate: $stmt = "WHERE status = ? AND reportid IN (?,?,?)"; @bind = ('completed', '567', '2335', '2'); The reverse operator C<-not_in> generates SQL C and is used in the same way. If the argument to C<-in> is an empty array, 'sqlfalse' is generated (by default : C<1=0>). Similarly, C<< -not_in => [] >> generates 'sqltrue' (by default : C<1=1>). In addition to the array you can supply a chunk of literal sql or literal sql with bind: my %where = { customer => { -in => \[ 'SELECT cust_id FROM cust WHERE balance > ?', 2000, ], status => { -in => \'SELECT status_codes FROM states' }, }; would generate: $stmt = "WHERE ( customer IN ( SELECT cust_id FROM cust WHERE balance > ? ) AND status IN ( SELECT status_codes FROM states ) )"; @bind = ('2000'); Another pair of operators is C<-between> and C<-not_between>, used with an arrayref of two values: my %where = ( user => 'nwiger', completion_date => { -not_between => ['2002-10-01', '2003-02-06'] } ); Would give you: WHERE user = ? AND completion_date NOT BETWEEN ( ? AND ? ) Just like with C<-in> all plausible combinations of literal SQL are possible: my %where = { start0 => { -between => [ 1, 2 ] }, start1 => { -between => \["? AND ?", 1, 2] }, start2 => { -between => \"lower(x) AND upper(y)" }, start3 => { -between => [ \"lower(x)", \["upper(?)", 'stuff' ], ] }, }; Would give you: $stmt = "WHERE ( ( start0 BETWEEN ? AND ? ) AND ( start1 BETWEEN ? AND ? ) AND ( start2 BETWEEN lower(x) AND upper(y) ) AND ( start3 BETWEEN lower(x) AND upper(?) ) )"; @bind = (1, 2, 1, 2, 'stuff'); These are the two builtin "special operators"; but the list can be expanded : see section L below. =head2 Unary operators: bool If you wish to test against boolean columns or functions within your database you can use the C<-bool> and C<-not_bool> operators. For example to test the column C being true and the column being false you would use:- my %where = ( -bool => 'is_user', -not_bool => 'is_enabled', ); Would give you: WHERE is_user AND NOT is_enabled If a more complex combination is required, testing more conditions, then you should use the and/or operators:- my %where = ( -and => [ -bool => 'one', -bool => 'two', -bool => 'three', -not_bool => 'four', ], ); Would give you: WHERE one AND two AND three AND NOT four =head2 Nested conditions, -and/-or prefixes So far, we've seen how multiple conditions are joined with a top-level C. We can change this by putting the different conditions we want in hashes and then putting those hashes in an array. For example: my @where = ( { user => 'nwiger', status => { -like => ['pending%', 'dispatched'] }, }, { user => 'robot', status => 'unassigned', } ); This data structure would create the following: $stmt = "WHERE ( user = ? AND ( status LIKE ? OR status LIKE ? ) ) OR ( user = ? AND status = ? ) )"; @bind = ('nwiger', 'pending', 'dispatched', 'robot', 'unassigned'); There is also a special C<-nest> operator which adds an additional set of parens, to create a subquery. For example, to get something like this: $stmt = "WHERE user = ? AND ( workhrs > ? OR geo = ? )"; @bind = ('nwiger', '20', 'ASIA'); You would do: my %where = ( user => 'nwiger', -nest => [ workhrs => {'>', 20}, geo => 'ASIA' ], ); Finally, clauses in hashrefs or arrayrefs can be prefixed with an C<-and> or C<-or> to change the logic inside : my @where = ( -and => [ user => 'nwiger', -nest => [ -and => [workhrs => {'>', 20}, geo => 'ASIA' ], -and => [workhrs => {'<', 50}, geo => 'EURO' ] ], ], ); That would yield: WHERE ( user = ? AND ( ( workhrs > ? AND geo = ? ) OR ( workhrs < ? AND geo = ? ) ) ) =head2 Algebraic inconsistency, for historical reasons C: when connecting several conditions, the C<-and->|C<-or> operator goes C of the nested structure; whereas when connecting several constraints on one column, the C<-and> operator goes C the arrayref. Here is an example combining both features : my @where = ( -and => [a => 1, b => 2], -or => [c => 3, d => 4], e => [-and => {-like => 'foo%'}, {-like => '%bar'} ] ) yielding WHERE ( ( ( a = ? AND b = ? ) OR ( c = ? OR d = ? ) OR ( e LIKE ? AND e LIKE ? ) ) ) This difference in syntax is unfortunate but must be preserved for historical reasons. So be careful : the two examples below would seem algebraically equivalent, but they are not {col => [-and => {-like => 'foo%'}, {-like => '%bar'}]} # yields : WHERE ( ( col LIKE ? AND col LIKE ? ) ) [-and => {col => {-like => 'foo%'}, {col => {-like => '%bar'}}]] # yields : WHERE ( ( col LIKE ? OR col LIKE ? ) ) =head2 Literal SQL Finally, sometimes only literal SQL will do. If you want to include literal SQL verbatim, you can specify it as a scalar reference, namely: my $inn = 'is Not Null'; my %where = ( priority => { '<', 2 }, requestor => \$inn ); This would create: $stmt = "WHERE priority < ? AND requestor is Not Null"; @bind = ('2'); Note that in this example, you only get one bind parameter back, since the verbatim SQL is passed as part of the statement. Of course, just to prove a point, the above can also be accomplished with this: my %where = ( priority => { '<', 2 }, requestor => { '!=', undef }, ); TMTOWTDI Conditions on boolean columns can be expressed in the same way, passing a reference to an empty string, however using liternal SQL in this way is deprecated - the preferred method is to use the boolean operators - see L : my %where = ( priority => { '<', 2 }, is_ready => \""; ); which yields $stmt = "WHERE priority < ? AND is_ready"; @bind = ('2'); =head2 Literal SQL with placeholders and bind values (subqueries) If the literal SQL to be inserted has placeholders and bind values, use a reference to an arrayref (yes this is a double reference -- not so common, but perfectly legal Perl). For example, to find a date in Postgres you can use something like this: my %where = ( date_column => \[q/= date '2008-09-30' - ?::integer/, 10/] ) This would create: $stmt = "WHERE ( date_column = date '2008-09-30' - ?::integer )" @bind = ('10'); Note that you must pass the bind values in the same format as they are returned by L. That means that if you set L to C, you must provide the bind values in the C<< [ column_meta => value ] >> format, where C is an opaque scalar value; most commonly the column name, but you can use any scalar value (including references and blessed references), L will simply pass it through intact. So if C is set to C the above example will look like: my %where = ( date_column => \[q/= date '2008-09-30' - ?::integer/, [ dummy => 10 ]/] ) Literal SQL is especially useful for nesting parenthesized clauses in the main SQL query. Here is a first example : my ($sub_stmt, @sub_bind) = ("SELECT c1 FROM t1 WHERE c2 < ? AND c3 LIKE ?", 100, "foo%"); my %where = ( foo => 1234, bar => \["IN ($sub_stmt)" => @sub_bind], ); This yields : $stmt = "WHERE (foo = ? AND bar IN (SELECT c1 FROM t1 WHERE c2 < ? AND c3 LIKE ?))"; @bind = (1234, 100, "foo%"); Other subquery operators, like for example C<"E ALL"> or C<"NOT IN">, are expressed in the same way. Of course the C<$sub_stmt> and its associated bind values can be generated through a former call to C : my ($sub_stmt, @sub_bind) = $sql->select("t1", "c1", {c2 => {"<" => 100}, c3 => {-like => "foo%"}}); my %where = ( foo => 1234, bar => \["> ALL ($sub_stmt)" => @sub_bind], ); In the examples above, the subquery was used as an operator on a column; but the same principle also applies for a clause within the main C<%where> hash, like an EXISTS subquery : my ($sub_stmt, @sub_bind) = $sql->select("t1", "*", {c1 => 1, c2 => \"> t0.c0"}); my %where = ( foo => 1234, -nest => \["EXISTS ($sub_stmt)" => @sub_bind], ); which yields $stmt = "WHERE (foo = ? AND EXISTS (SELECT * FROM t1 WHERE c1 = ? AND c2 > t0.c0))"; @bind = (1234, 1); Observe that the condition on C in the subquery refers to column C of the main query : this is I a bind value, so we have to express it through a scalar ref. Writing C<< c2 => {">" => "t0.c0"} >> would have generated C<< c2 > ? >> with bind value C<"t0.c0"> ... not exactly what we wanted here. Another use of the subquery technique is when some SQL clauses need parentheses, as it often occurs with some proprietary SQL extensions like for example fulltext expressions, geospatial expressions, NATIVE clauses, etc. Here is an example of a fulltext query in MySQL : my %where = ( -nest => \["MATCH (col1, col2) AGAINST (?)" => qw/apples/] ); Finally, here is an example where a subquery is used for expressing unary negation: my ($sub_stmt, @sub_bind) = $sql->where({age => [{"<" => 10}, {">" => 20}]}); $sub_stmt =~ s/^ where //i; # don't want "WHERE" in the subclause my %where = ( lname => {like => '%son%'}, -nest => \["NOT ($sub_stmt)" => @sub_bind], ); This yields $stmt = "lname LIKE ? AND NOT ( age < ? OR age > ? )" @bind = ('%son%', 10, 20) =head2 Conclusion These pages could go on for a while, since the nesting of the data structures this module can handle are pretty much unlimited (the module implements the C expansion as a recursive function internally). Your best bet is to "play around" with the module a little to see how the data structures behave, and choose the best format for your data based on that. And of course, all the values above will probably be replaced with variables gotten from forms or the command line. After all, if you knew everything ahead of time, you wouldn't have to worry about dynamically-generating SQL and could just hardwire it into your script. =head1 ORDER BY CLAUSES Some functions take an order by clause. This can either be a scalar (just a column name,) a hash of C<< { -desc => 'col' } >> or C<< { -asc => 'col' } >>, or an array of either of the two previous forms. Examples: Given | Will Generate ---------------------------------------------------------- | \'colA DESC' | ORDER BY colA DESC | 'colA' | ORDER BY colA | [qw/colA colB/] | ORDER BY colA, colB | {-asc => 'colA'} | ORDER BY colA ASC | {-desc => 'colB'} | ORDER BY colB DESC | ['colA', {-asc => 'colB'}] | ORDER BY colA, colB ASC | { -asc => [qw/colA colB] } | ORDER BY colA ASC, colB ASC | [ | { -asc => 'colA' }, | ORDER BY colA ASC, colB DESC, { -desc => [qw/colB/], | colC ASC, colD ASC { -asc => [qw/colC colD/],| ] | =========================================================== =head1 SPECIAL OPERATORS my $sqlmaker = SQL::Abstract->new(special_ops => [ { regex => qr/.../, handler => sub { my ($self, $field, $op, $arg) = @_; ... }, }, { regex => qr/.../, handler => 'method_name', }, ]); A "special operator" is a SQL syntactic clause that can be applied to a field, instead of a usual binary operator. For example : WHERE field IN (?, ?, ?) WHERE field BETWEEN ? AND ? WHERE MATCH(field) AGAINST (?, ?) Special operators IN and BETWEEN are fairly standard and therefore are builtin within C (as the overridable methods C<_where_field_IN> and C<_where_field_BETWEEN>). For other operators, like the MATCH .. AGAINST example above which is specific to MySQL, you can write your own operator handlers - supply a C argument to the C method. That argument takes an arrayref of operator definitions; each operator definition is a hashref with two entries: =over =item regex the regular expression to match the operator =item handler Either a coderef or a plain scalar method name. In both cases the expected return is C<< ($sql, @bind) >>. When supplied with a method name, it is simply called on the L object as: $self->$method_name ($field, $op, $arg) Where: $op is the part that matched the handler regex $field is the LHS of the operator $arg is the RHS When supplied with a coderef, it is called as: $coderef->($self, $field, $op, $arg) =back For example, here is an implementation of the MATCH .. AGAINST syntax for MySQL my $sqlmaker = SQL::Abstract->new(special_ops => [ # special op for MySql MATCH (field) AGAINST(word1, word2, ...) {regex => qr/^match$/i, handler => sub { my ($self, $field, $op, $arg) = @_; $arg = [$arg] if not ref $arg; my $label = $self->_quote($field); my ($placeholder) = $self->_convert('?'); my $placeholders = join ", ", (($placeholder) x @$arg); my $sql = $self->_sqlcase('match') . " ($label) " . $self->_sqlcase('against') . " ($placeholders) "; my @bind = $self->_bindtype($field, @$arg); return ($sql, @bind); } }, ]); =head1 UNARY OPERATORS my $sqlmaker = SQL::Abstract->new(unary_ops => [ { regex => qr/.../, handler => sub { my ($self, $op, $arg) = @_; ... }, }, { regex => qr/.../, handler => 'method_name', }, ]); A "unary operator" is a SQL syntactic clause that can be applied to a field - the operator goes before the field You can write your own operator handlers - supply a C argument to the C method. That argument takes an arrayref of operator definitions; each operator definition is a hashref with two entries: =over =item regex the regular expression to match the operator =item handler Either a coderef or a plain scalar method name. In both cases the expected return is C<< $sql >>. When supplied with a method name, it is simply called on the L object as: $self->$method_name ($op, $arg) Where: $op is the part that matched the handler regex $arg is the RHS or argument of the operator When supplied with a coderef, it is called as: $coderef->($self, $op, $arg) =back =head1 PERFORMANCE Thanks to some benchmarking by Mark Stosberg, it turns out that this module is many orders of magnitude faster than using C. I must admit this wasn't an intentional design issue, but it's a byproduct of the fact that you get to control your C handles yourself. To maximize performance, use a code snippet like the following: # prepare a statement handle using the first row # and then reuse it for the rest of the rows my($sth, $stmt); for my $href (@array_of_hashrefs) { $stmt ||= $sql->insert('table', $href); $sth ||= $dbh->prepare($stmt); $sth->execute($sql->values($href)); } The reason this works is because the keys in your C<$href> are sorted internally by B. Thus, as long as your data retains the same structure, you only have to generate the SQL the first time around. On subsequent queries, simply use the C function provided by this module to return your values in the correct order. =head1 FORMBUILDER If you use my C module at all, you'll hopefully really like this part (I do, at least). Building up a complex query can be as simple as the following: #!/usr/bin/perl use CGI::FormBuilder; use SQL::Abstract; my $form = CGI::FormBuilder->new(...); my $sql = SQL::Abstract->new; if ($form->submitted) { my $field = $form->field; my $id = delete $field->{id}; my($stmt, @bind) = $sql->update('table', $field, {id => $id}); } Of course, you would still have to connect using C to run the query, but the point is that if you make your form look like your table, the actual query script can be extremely simplistic. If you're B lazy (I am), check out C for a fast interface to returning and formatting data. I frequently use these three modules together to write complex database query apps in under 50 lines. =head1 CHANGES Version 1.50 was a major internal refactoring of C. Great care has been taken to preserve the I behavior documented in previous versions in the 1.* family; however, some features that were previously undocumented, or behaved differently from the documentation, had to be changed in order to clarify the semantics. Hence, client code that was relying on some dark areas of C v1.* B in v1.50. The main changes are : =over =item * support for literal SQL through the C<< \ [$sql, bind] >> syntax. =item * support for the { operator => \"..." } construct (to embed literal SQL) =item * support for the { operator => \["...", @bind] } construct (to embed literal SQL with bind values) =item * optional support for L =item * defensive programming : check arguments =item * fixed bug with global logic, which was previously implemented through global variables yielding side-effects. Prior versions would interpret C<< [ {cond1, cond2}, [cond3, cond4] ] >> as C<< "(cond1 AND cond2) OR (cond3 AND cond4)" >>. Now this is interpreted as C<< "(cond1 AND cond2) OR (cond3 OR cond4)" >>. =item * fixed semantics of _bindtype on array args =item * dropped the C<_anoncopy> of the %where tree. No longer necessary, we just avoid shifting arrays within that tree. =item * dropped the C<_modlogic> function =back =head1 ACKNOWLEDGEMENTS There are a number of individuals that have really helped out with this module. Unfortunately, most of them submitted bugs via CPAN so I have no idea who they are! But the people I do know are: Ash Berlin (order_by hash term support) Matt Trout (DBIx::Class support) Mark Stosberg (benchmarking) Chas Owens (initial "IN" operator support) Philip Collins (per-field SQL functions) Eric Kolve (hashref "AND" support) Mike Fragassi (enhancements to "BETWEEN" and "LIKE") Dan Kubb (support for "quote_char" and "name_sep") Guillermo Roditi (patch to cleanup "IN" and "BETWEEN", fix and tests for _order_by) Laurent Dami (internal refactoring, multiple -nest, extensible list of special operators, literal SQL) Norbert Buchmuller (support for literal SQL in hashpair, misc. fixes & tests) Peter Rabbitson (rewrite of SQLA::Test, misc. fixes & tests) Thanks! =head1 SEE ALSO L, L, L, L. =head1 AUTHOR Copyright (c) 2001-2007 Nathan Wiger . All Rights Reserved. This module is actively maintained by Matt Trout For support, your best bet is to try the C users mailing list. While not an official support venue, C makes heavy use of C, and as such list members there are very familiar with how to create queries. =head1 LICENSE This module is free software; you may copy this under the terms of the GNU General Public License, or the Artistic License, copies of which should have accompanied your Perl kit. =cut