DBIx::Class::Storage::DBIHacks;
#
-# This module contains code that should never have seen the light of day,
-# does not belong in the Storage, or is otherwise unfit for public
-# display. The arrival of SQLA2 should immediately obsolete 90% of this
+# This module contains code supporting a battery of special cases and tests for
+# many corner cases pushing the envelope of what DBIC can do. When work on
+# these utilities began in mid 2009 (51a296b402c) it wasn't immediately obvious
+# that these pieces, despite their misleading on-first-sighe-flakiness, will
+# become part of the generic query rewriting machinery of DBIC, allowing it to
+# both generate and process queries representing incredibly complex sets with
+# reasonable efficiency.
+#
+# Now (end of 2015), more than 6 years later the routines in this class have
+# stabilized enough, and are meticulously covered with tests, to a point where
+# an effort to formalize them into user-facing APIs might be worthwhile.
+#
+# An implementor working on publicizing and/or replacing the routines with a
+# more modern SQL generation framework should keep in mind that pretty much all
+# existing tests are constructed on the basis of real-world code used in
+# production somewhere.
+#
+# Please hack on this responsibly ;)
#
use strict;
use List::Util 'first';
use Scalar::Util 'blessed';
-use Sub::Name 'subname';
-use DBIx::Class::_Util 'UNRESOLVABLE_CONDITION';
+use DBIx::Class::_Util qw(UNRESOLVABLE_CONDITION serialize);
use SQL::Abstract qw(is_plain_value is_literal_value);
+use DBIx::Class::Carp;
use namespace::clean;
#
$self->_use_join_optimizer
);
- my $orig_aliastypes = $self->_resolve_aliastypes_from_select_args($attrs);
+ my $orig_aliastypes =
+ $attrs->{_precalculated_aliastypes}
+ ||
+ $self->_resolve_aliastypes_from_select_args($attrs)
+ ;
my $new_aliastypes = { %$orig_aliastypes };
my $outer_attrs = { %$attrs };
delete @{$outer_attrs}{qw(from bind rows offset group_by _grouped_by_distinct having)};
- my $inner_attrs = { %$attrs };
- delete @{$inner_attrs}{qw(for collapse select as _related_results_construction)};
+ my $inner_attrs = { %$attrs, _simple_passthrough_construction => 1 };
+ delete @{$inner_attrs}{qw(for collapse select as)};
# there is no point of ordering the insides if there is no limit
delete $inner_attrs->{order_by} if (
push @{$inner_attrs->{as}}, $attrs->{as}[$i];
}
- # We will need to fetch all native columns in the inner subquery, which may
+ my $inner_aliastypes = $self->_resolve_aliastypes_from_select_args($inner_attrs);
+
+ # In the inner subq we will need to fetch *only* native columns which may
# be a part of an *outer* join condition, or an order_by (which needs to be
# preserved outside), or wheres. In other words everything but the inner
# selector
# We can not just fetch everything because a potential has_many restricting
# join collapse *will not work* on heavy data types.
- my $connecting_aliastypes = $self->_resolve_aliastypes_from_select_args({
- %$inner_attrs,
- select => [],
- });
- for (sort map { keys %{$_->{-seen_columns}||{}} } map { values %$_ } values %$connecting_aliastypes) {
+ # essentially a map of all non-selecting seen columns
+ # the sort is there for a nicer select list
+ for (
+ sort
+ map
+ { keys %{$_->{-seen_columns}||{}} }
+ map
+ { values %{$inner_aliastypes->{$_}} }
+ grep
+ { $_ ne 'selecting' }
+ keys %$inner_aliastypes
+ ) {
my $ci = $colinfo->{$_} or next;
if (
$ci->{-source_alias} eq $root_alias
local $self->{_use_join_optimizer} = 1;
# throw away multijoins since we def. do not care about those inside the subquery
- ($inner_attrs->{from}, my $inner_aliastypes) = $self->_prune_unused_joins ({
- %$inner_attrs, _force_prune_multiplying_joins => 1
+ # $inner_aliastypes *will* be redefined at this point
+ ($inner_attrs->{from}, $inner_aliastypes ) = $self->_prune_unused_joins ({
+ %$inner_attrs,
+ _force_prune_multiplying_joins => 1,
+ _precalculated_aliastypes => $inner_aliastypes,
});
# uh-oh a multiplier (which is not us) left in, this is a problem for limits
});
}
- # This is totally horrific - the {where} ends up in both the inner and outer query
- # Unfortunately not much can be done until SQLA2 introspection arrives, and even
- # then if where conditions apply to the *right* side of the prefetch, you may have
- # to both filter the inner select (e.g. to apply a limit) and then have to re-filter
- # the outer select to exclude joins you didn't want in the first place
+ # FIXME: The {where} ends up in both the inner and outer query, i.e. *twice*
+ #
+ # This is rather horrific, and while we currently *do* have enough
+ # introspection tooling available to attempt a stab at properly deciding
+ # whether or not to include the where condition on the outside, the
+ # machinery is still too slow to apply it here.
+ # Thus for the time being we do not attempt any sanitation of the where
+ # clause and just pass it through on both sides of the subquery. This *will*
+ # be addressed at a later stage, most likely after folding the SQL generator
+ # into SQLMaker proper
#
# OTOH it can be seen as a plus: <ash> (notes that this query would make a DBA cry ;)
+ #
return $outer_attrs;
}
+# This is probably the ickiest, yet most relied upon part of the codebase:
+# this is the place where we take arbitrary SQL input and break it into its
+# constituent parts, making sure we know which *sources* are used in what
+# *capacity* ( selecting / restricting / grouping / ordering / joining, etc )
+# Although the method is pretty horrific, the worst thing that can happen is
+# for a classification failure, which in turn will result in a vocal exception,
+# and will lead to a relatively prompt fix.
+# The code has been slowly improving and is covered with a formiddable battery
+# of tests, so can be considered "reliably stable" at this point (Oct 2015).
+#
+# A note to implementors attempting to "replace" this - keep in mind that while
+# there are multiple optimization avenues, the actual "scan literal elements"
+# part *MAY NEVER BE REMOVED*, even if it is limited only ot the (future) AST
+# nodes that are deemed opaque (i.e. contain literal expressions). The use of
+# blackbox literals is at this point firmly a user-facing API, and is one of
+# *the* reasons DBIC remains as flexible as it is. In other words, when working
+# on this keep in mind that the following is widespread and *encouraged* way
+# of using DBIC in the wild when push comes to shove:
#
-# I KNOW THIS SUCKS! GET SQLA2 OUT THE DOOR SO THIS CAN DIE!
+# $rs->search( {}, {
+# select => \[ $random, @stuff],
+# from => \[ $random, @stuff ],
+# where => \[ $random, @stuff ],
+# group_by => \[ $random, @stuff ],
+# order_by => \[ $random, @stuff ],
+# } )
+#
+# Various incarnations of the above are reflected in many of the tests. If one
+# gets to fail, you get to fix it. A "this is crazy, nobody does that" is not
+# acceptable going forward.
#
-# Due to a lack of SQLA2 we fall back to crude scans of all the
-# select/where/order/group attributes, in order to determine what
-# aliases are needed to fulfill the query. This information is used
-# throughout the code to prune unnecessary JOINs from the queries
-# in an attempt to reduce the execution time.
-# Although the method is pretty horrific, the worst thing that can
-# happen is for it to fail due to some scalar SQL, which in turn will
-# result in a vocal exception.
sub _resolve_aliastypes_from_select_args {
my ( $self, $attrs ) = @_;
# generate sql chunks
my $to_scan = {
restricting => [
- $sql_maker->_recurse_where ($attrs->{where}),
+ ($sql_maker->_recurse_where ($attrs->{where}))[0],
$sql_maker->_parse_rs_attrs ({ having => $attrs->{having} }),
],
grouping => [
),
],
selecting => [
- map { ($sql_maker->_recurse_fields($_))[0] } @{$attrs->{select}},
+ # kill all selectors which look like a proper subquery
+ # this is a sucky heuristic *BUT* - if we get it wrong the query will simply
+ # fail to run, so we are relatively safe
+ grep
+ { $_ !~ / \A \s* \( \s* SELECT \s+ .+? \s+ FROM \s+ .+? \) \s* \z /xsi }
+ map
+ { ($sql_maker->_recurse_fields($_))[0] }
+ @{$attrs->{select}}
],
- ordering => [
- map { $_->[0] } $self->_extract_order_criteria ($attrs->{order_by}, $sql_maker),
+ ordering => [ map
+ {
+ ( my $sql = (ref $_ ? $_->[0] : $_) ) =~ s/ \s+ (?: ASC | DESC ) \s* \z //xi;
+ $sql;
+ }
+ $sql_maker->_order_by_chunks( $attrs->{order_by} ),
],
};
- # throw away empty chunks and all 2-value arrayrefs: the thinking is that these are
- # bind value specs left in by the sloppy renderer above. It is ok to do this
- # at this point, since we are going to end up rewriting this crap anyway
- for my $v (values %$to_scan) {
- my @nv;
- for (@$v) {
- next if (
- ! defined $_
- or
- (
- ref $_ eq 'ARRAY'
- and
- ( @$_ == 0 or @$_ == 2 )
- )
- );
+ # we will be bulk-scanning anyway - pieces will not matter in that case,
+ # thus join everything up
+ # throw away empty-string chunks, and make sure no binds snuck in
+ # note that we operate over @{$to_scan->{$type}}, hence the
+ # semi-mindbending ... map ... for values ...
+ ( $_ = join ' ', map {
+
+ ( ! defined $_ ) ? ()
+ : ( length ref $_ ) ? (require Data::Dumper::Concise && $self->throw_exception(
+ "Unexpected ref in scan-plan: " . Data::Dumper::Concise::Dumper($_)
+ ))
+ : ( $_ =~ /^\s*$/ ) ? ()
+ : $_
+
+ } @$_ ) for values %$to_scan;
+
+ # throw away empty to-scan's
+ (
+ length $to_scan->{$_}
+ or
+ delete $to_scan->{$_}
+ ) for keys %$to_scan;
- if (ref $_) {
- require Data::Dumper::Concise;
- $self->throw_exception("Unexpected ref in scan-plan: " . Data::Dumper::Concise::Dumper($v) );
- }
- push @nv, $_;
- }
- $v = \@nv;
- }
+ # these will be used for matching in the loop below
+ my $all_aliases = join ' | ', map { quotemeta $_ } keys %$alias_list;
+ my $fq_col_re = qr/
+ $lquote ( $all_aliases ) $rquote $sep (?: $lquote ([^$rquote]+) $rquote )?
+ |
+ \b ( $all_aliases ) \. ( [^\s\)\($rquote]+ )?
+ /x;
- # kill all selectors which look like a proper subquery
- # this is a sucky heuristic *BUT* - if we get it wrong the query will simply
- # fail to run, so we are relatively safe
- $to_scan->{selecting} = [ grep {
- $_ !~ / \A \s* \( \s* SELECT \s+ .+? \s+ FROM \s+ .+? \) \s* \z /xsi
- } @{ $to_scan->{selecting} || [] } ];
- # first see if we have any exact matches (qualified or unqualified)
+ my $all_unq_columns = join ' | ',
+ map
+ { quotemeta $_ }
+ grep
+ # using a regex here shows up on profiles, boggle
+ { index( $_, '.') < 0 }
+ keys %$colinfo
+ ;
+ my $unq_col_re = $all_unq_columns
+ ? qr/
+ $lquote ( $all_unq_columns ) $rquote
+ |
+ (?: \A | \s ) ( $all_unq_columns ) (?: \s | \z )
+ /x
+ : undef
+ ;
+
+
+ # the actual scan, per type
for my $type (keys %$to_scan) {
- for my $piece (@{$to_scan->{$type}}) {
- if ($colinfo->{$piece} and my $alias = $colinfo->{$piece}{-source_alias}) {
- $aliases_by_type->{$type}{$alias} ||= { -parents => $alias_list->{$alias}{-join_path}||[] };
- $aliases_by_type->{$type}{$alias}{-seen_columns}{$colinfo->{$piece}{-fq_colname}} = $piece;
- }
- }
- }
- # now loop through all fully qualified columns and get the corresponding
- # alias (should work even if they are in scalarrefs)
- for my $alias (keys %$alias_list) {
- my $al_re = qr/
- $lquote $alias $rquote $sep (?: $lquote ([^$rquote]+) $rquote )?
- |
- \b $alias \. ([^\s\)\($rquote]+)?
- /x;
-
- for my $type (keys %$to_scan) {
- for my $piece (@{$to_scan->{$type}}) {
- if (my @matches = $piece =~ /$al_re/g) {
- $aliases_by_type->{$type}{$alias} ||= { -parents => $alias_list->{$alias}{-join_path}||[] };
- $aliases_by_type->{$type}{$alias}{-seen_columns}{"$alias.$_"} = "$alias.$_"
- for grep { defined $_ } @matches;
- }
+
+ # now loop through all fully qualified columns and get the corresponding
+ # alias (should work even if they are in scalarrefs)
+ #
+ # The regex captures in multiples of 4, with one of the two pairs being
+ # undef. There may be a *lot* of matches, hence the convoluted loop
+ my @matches = $to_scan->{$type} =~ /$fq_col_re/g;
+ my $i = 0;
+ while( $i < $#matches ) {
+
+ if (
+ defined $matches[$i]
+ ) {
+ $aliases_by_type->{$type}{$matches[$i]} ||= { -parents => $alias_list->{$matches[$i]}{-join_path}||[] };
+
+ $aliases_by_type->{$type}{$matches[$i]}{-seen_columns}{"$matches[$i].$matches[$i+1]"} = "$matches[$i].$matches[$i+1]"
+ if defined $matches[$i+1];
+
+ $i += 2;
}
+
+ $i += 2;
}
- }
- # now loop through unqualified column names, and try to locate them within
- # the chunks
- for my $col (keys %$colinfo) {
- next if $col =~ / \. /x; # if column is qualified it was caught by the above
- my $col_re = qr/ $lquote ($col) $rquote /x;
+ # now loop through unqualified column names, and try to locate them within
+ # the chunks, if there are any unqualified columns in the 1st place
+ next unless $unq_col_re;
- for my $type (keys %$to_scan) {
- for my $piece (@{$to_scan->{$type}}) {
- if ( my @matches = $piece =~ /$col_re/g) {
- my $alias = $colinfo->{$col}{-source_alias};
- $aliases_by_type->{$type}{$alias} ||= { -parents => $alias_list->{$alias}{-join_path}||[] };
- $aliases_by_type->{$type}{$alias}{-seen_columns}{"$alias.$_"} = $_
- for grep { defined $_ } @matches;
- }
- }
+ # The regex captures in multiples of 2, one of the two being undef
+ for ( $to_scan->{$type} =~ /$unq_col_re/g ) {
+ defined $_ or next;
+ my $alias = $colinfo->{$_}{-source_alias} or next;
+ $aliases_by_type->{$type}{$alias} ||= { -parents => $alias_list->{$alias}{-join_path}||[] };
+ $aliases_by_type->{$type}{$alias}{-seen_columns}{"$alias.$_"} = $_
}
}
+
# Add any non-left joins to the restriction list (such joins are indeed restrictions)
- for my $j (values %$alias_list) {
- my $alias = $j->{-alias} or next;
- $aliases_by_type->{restricting}{$alias} ||= { -parents => $j->{-join_path}||[] } if (
- (not $j->{-join_type})
+ (
+ $_->{-alias}
+ and
+ ! $aliases_by_type->{restricting}{ $_->{-alias} }
+ and
+ (
+ not $_->{-join_type}
or
- ($j->{-join_type} !~ /^left (?: \s+ outer)? $/xi)
- );
- }
+ $_->{-join_type} !~ /^left (?: \s+ outer)? $/xi
+ )
+ and
+ $aliases_by_type->{restricting}{ $_->{-alias} } = { -parents => $_->{-join_path}||[] }
+ ) for values %$alias_list;
- for (keys %$aliases_by_type) {
- delete $aliases_by_type->{$_} unless keys %{$aliases_by_type->{$_}};
- }
- return $aliases_by_type;
+ # final cleanup
+ (
+ keys %{$aliases_by_type->{$_}}
+ or
+ delete $aliases_by_type->{$_}
+ ) for keys %$aliases_by_type;
+
+
+ $aliases_by_type;
}
# This is the engine behind { distinct => 1 } and the general
# of the external order and convert them to MIN(X) for ASC or MAX(X)
# for DESC, and group_by the root columns. The end result should be
# exactly what we expect
-
- # FIXME - this code is a joke, will need to be completely rewritten in
- # the DQ branch. But I need to push a POC here, otherwise the
- # pesky tests won't pass
- # wrap any part of the order_by that "responds" to an ordering alias
- # into a MIN/MAX
+ #
$sql_maker ||= $self->sql_maker;
$order_chunks ||= [
map { ref $_ eq 'ARRAY' ? $_ : [ $_ ] } $sql_maker->_order_by_chunks($attrs->{order_by})
my ($chunk, $is_desc) = $sql_maker->_split_order_chunk($order_chunks->[$o_idx][0]);
+ # we reached that far - wrap any part of the order_by that "responded"
+ # to an ordering alias into a MIN/MAX
$new_order_by[$o_idx] = \[
sprintf( '%s( %s )%s',
($is_desc ? 'MAX' : 'MIN'),
return {} if $colnames and ! @$colnames;
- my $alias2src = $self->_resolve_ident_sources($ident);
+ my $sources = $self->_resolve_ident_sources($ident);
+
+ $_ = { rsrc => $_, colinfos => $_->columns_info }
+ for values %$sources;
my (%seen_cols, @auto_colnames);
# compile a global list of column names, to be able to properly
# disambiguate unqualified column names (if at all possible)
- for my $alias (keys %$alias2src) {
- my $rsrc = $alias2src->{$alias};
- for my $colname ($rsrc->columns) {
- push @{$seen_cols{$colname}}, $alias;
- push @auto_colnames, "$alias.$colname" unless $colnames;
- }
+ for my $alias (keys %$sources) {
+ (
+ ++$seen_cols{$_}{$alias}
+ and
+ ! $colnames
+ and
+ push @auto_colnames, "$alias.$_"
+ ) for keys %{ $sources->{$alias}{colinfos} };
}
$colnames ||= [
@auto_colnames,
- grep { @{$seen_cols{$_}} == 1 } (keys %seen_cols),
+ ( grep { keys %{$seen_cols{$_}} == 1 } keys %seen_cols ),
];
- my (%return, $colinfos);
- foreach my $col (@$colnames) {
- my ($source_alias, $colname) = $col =~ m/^ (?: ([^\.]+) \. )? (.+) $/x;
+ my %return;
+ for (@$colnames) {
+ my ($colname, $source_alias) = reverse split /\./, $_;
- # if the column was seen exactly once - we know which rsrc it came from
- $source_alias ||= $seen_cols{$colname}[0]
- if ($seen_cols{$colname} and @{$seen_cols{$colname}} == 1);
+ my $assumed_alias =
+ $source_alias
+ ||
+ # if the column was seen exactly once - we know which rsrc it came from
+ (
+ $seen_cols{$colname}
+ and
+ keys %{$seen_cols{$colname}} == 1
+ and
+ ( %{$seen_cols{$colname}} )[0]
+ )
+ ||
+ next
+ ;
- next unless $source_alias;
+ $self->throw_exception(
+ "No such column '$colname' on source " . $sources->{$assumed_alias}{rsrc}->source_name
+ ) unless $seen_cols{$colname}{$assumed_alias};
- my $rsrc = $alias2src->{$source_alias}
- or next;
-
- $return{$col} = {
- %{
- ( $colinfos->{$source_alias} ||= $rsrc->columns_info )->{$colname}
- ||
- $self->throw_exception(
- "No such column '$colname' on source " . $rsrc->source_name
- );
- },
- -result_source => $rsrc,
- -source_alias => $source_alias,
- -fq_colname => $col eq $colname ? "$source_alias.$col" : $col,
+ $return{$_} = {
+ %{ $sources->{$assumed_alias}{colinfos}{$colname} },
+ -result_source => $sources->{$assumed_alias}{rsrc},
+ -source_alias => $assumed_alias,
+ -fq_colname => "$assumed_alias.$colname",
-colname => $colname,
};
- $return{"$source_alias.$colname"} = $return{$col} if $col eq $colname;
+ $return{"$assumed_alias.$colname"} = $return{$_}
+ unless $source_alias;
}
return \%return;
# resultset {where} stacks
#
# FIXME - while relatively robust, this is still imperfect, one of the first
-# things to tackle with DQ
+# things to tackle when we get access to a formalized AST. Note that this code
+# is covered by a *ridiculous* amount of tests, so starting with porting this
+# code would be a rather good exercise
sub _collapse_cond {
my ($self, $where, $where_is_anded_array) = @_;
+ my $fin;
+
if (! $where) {
return;
}
my $chunk = shift @pieces;
if (ref $chunk eq 'HASH') {
- push @pairs, map { [ $_ => $chunk->{$_} ] } sort keys %$chunk;
+ for (sort keys %$chunk) {
+
+ # Match SQLA 1.79 behavior
+ unless( length $_ ) {
+ is_literal_value($chunk->{$_})
+ ? carp 'Hash-pairs consisting of an empty string with a literal are deprecated, use -and => [ $literal ] instead'
+ : $self->throw_exception("Supplying an empty left hand side argument is not supported in hash-pairs")
+ ;
+ }
+
+ push @pairs, $_ => $chunk->{$_};
+ }
}
elsif (ref $chunk eq 'ARRAY') {
- push @pairs, [ -or => $chunk ]
+ push @pairs, -or => $chunk
if @$chunk;
}
- elsif ( ! ref $chunk) {
- push @pairs, [ $chunk, shift @pieces ];
+ elsif ( ! length ref $chunk) {
+
+ # Match SQLA 1.79 behavior
+ $self->throw_exception("Supplying an empty left hand side argument is not supported in array-pairs")
+ if $where_is_anded_array and (! defined $chunk or ! length $chunk);
+
+ push @pairs, $chunk, shift @pieces;
}
else {
- push @pairs, [ '', $chunk ];
+ push @pairs, '', $chunk;
}
}
or return;
# Consolidate various @conds back into something more compact
- my $fin;
-
for my $c (@conds) {
if (ref $c ne 'HASH') {
push @{$fin->{-and}}, $c;
}
else {
for my $col (sort keys %$c) {
- if (exists $fin->{$col}) {
- my ($l, $r) = ($fin->{$col}, $c->{$col});
- (ref $_ ne 'ARRAY' or !@$_) and $_ = [ -and => $_ ] for ($l, $r);
-
- if (@$l and @$r and $l->[0] eq $r->[0] and $l->[0] eq '-and') {
- $fin->{$col} = [ -and => map { @$_[1..$#$_] } ($l, $r) ];
- }
- else {
- $fin->{$col} = [ -and => $fin->{$col}, $c->{$col} ];
- }
+ # consolidate all -and nodes
+ if ($col =~ /^\-and$/i) {
+ push @{$fin->{-and}},
+ ref $c->{$col} eq 'ARRAY' ? @{$c->{$col}}
+ : ref $c->{$col} eq 'HASH' ? %{$c->{$col}}
+ : { $col => $c->{$col} }
+ ;
+ }
+ elsif ($col =~ /^\-/) {
+ push @{$fin->{-and}}, { $col => $c->{$col} };
+ }
+ elsif (exists $fin->{$col}) {
+ $fin->{$col} = [ -and => map {
+ (ref $_ eq 'ARRAY' and ($_->[0]||'') =~ /^\-and$/i )
+ ? @{$_}[1..$#$_]
+ : $_
+ ;
+ } ($fin->{$col}, $c->{$col}) ];
}
else {
$fin->{$col} = $c->{$col};
}
}
}
-
- if ( ref $fin->{-and} eq 'ARRAY' and @{$fin->{-and}} == 1 ) {
- my $piece = (delete $fin->{-and})->[0];
- if (ref $piece eq 'ARRAY') {
- $fin->{-or} = $fin->{-or} ? [ $piece, $fin->{-or} ] : $piece;
- }
- elsif (! exists $fin->{''}) {
- $fin->{''} = $piece;
- }
- }
-
- return $fin;
}
elsif (ref $where eq 'ARRAY') {
- my @w = @$where;
+ # we are always at top-level here, it is safe to dump empty *standalone* pieces
+ my $fin_idx;
- while ( @w and (
- (ref $w[0] eq 'ARRAY' and ! @{$w[0]} )
- or
- (ref $w[0] eq 'HASH' and ! keys %{$w[0]})
- )) { shift @w };
+ for (my $i = 0; $i <= $#$where; $i++ ) {
- return unless @w;
+ # Match SQLA 1.79 behavior
+ $self->throw_exception(
+ "Supplying an empty left hand side argument is not supported in array-pairs"
+ ) if (! defined $where->[$i] or ! length $where->[$i]);
- if ( @w == 1 ) {
- return ( ref $w[0] )
- ? $self->_collapse_cond($w[0])
- : { $w[0] => undef }
- ;
- }
- elsif ( @w == 2 and ! ref $w[0]) {
- if ( ( $w[0]||'' ) =~ /^\-and$/i ) {
- return (ref $w[1] eq 'HASH' or ref $w[1] eq 'ARRAY')
- ? $self->_collapse_cond($w[1], (ref $w[1] eq 'ARRAY') )
- : $self->throw_exception("Unsupported top-level op/arg pair: [ $w[0] => $w[1] ]")
- ;
+ my $logic_mod = lc ( ($where->[$i] =~ /^(\-(?:and|or))$/i)[0] || '' );
+
+ if ($logic_mod) {
+ $i++;
+ $self->throw_exception("Unsupported top-level op/arg pair: [ $logic_mod => $where->[$i] ]")
+ unless ref $where->[$i] eq 'HASH' or ref $where->[$i] eq 'ARRAY';
+
+ my $sub_elt = $self->_collapse_cond({ $logic_mod => $where->[$i] })
+ or next;
+
+ my @keys = keys %$sub_elt;
+ if ( @keys == 1 and $keys[0] !~ /^\-/ ) {
+ $fin_idx->{ "COL_$keys[0]_" . serialize $sub_elt } = $sub_elt;
+ }
+ else {
+ $fin_idx->{ "SER_" . serialize $sub_elt } = $sub_elt;
+ }
+ }
+ elsif (! length ref $where->[$i] ) {
+ my $sub_elt = $self->_collapse_cond({ @{$where}[$i, $i+1] })
+ or next;
+
+ $fin_idx->{ "COL_$where->[$i]_" . serialize $sub_elt } = $sub_elt;
+ $i++;
}
else {
- return $self->_collapse_cond({ @w });
+ $fin_idx->{ "SER_" . serialize $where->[$i] } = $self->_collapse_cond( $where->[$i] ) || next;
}
}
+
+ if (! $fin_idx) {
+ return;
+ }
+ elsif ( keys %$fin_idx == 1 ) {
+ $fin = (values %$fin_idx)[0];
+ }
else {
- return { -or => \@w };
+ my @or;
+
+ # at this point everything is at most one level deep - unroll if needed
+ for (sort keys %$fin_idx) {
+ if ( ref $fin_idx->{$_} eq 'HASH' and keys %{$fin_idx->{$_}} == 1 ) {
+ my ($l, $r) = %{$fin_idx->{$_}};
+
+ if (
+ ref $r eq 'ARRAY'
+ and
+ (
+ ( @$r == 1 and $l =~ /^\-and$/i )
+ or
+ $l =~ /^\-or$/i
+ )
+ ) {
+ push @or, @$r
+ }
+
+ elsif (
+ ref $r eq 'HASH'
+ and
+ keys %$r == 1
+ and
+ $l =~ /^\-(?:and|or)$/i
+ ) {
+ push @or, %$r;
+ }
+
+ else {
+ push @or, $l, $r;
+ }
+ }
+ else {
+ push @or, $fin_idx->{$_};
+ }
+ }
+
+ $fin->{-or} = \@or;
}
}
else {
# not a hash not an array
- return { '' => $where };
+ $fin = { -and => [ $where ] };
}
- die 'should not get here';
+ # unroll single-element -and's
+ while (
+ $fin->{-and}
+ and
+ @{$fin->{-and}} < 2
+ ) {
+ my $and = delete $fin->{-and};
+ last if @$and == 0;
+
+ # at this point we have @$and == 1
+ if (
+ ref $and->[0] eq 'HASH'
+ and
+ ! grep { exists $fin->{$_} } keys %{$and->[0]}
+ ) {
+ $fin = {
+ %$fin, %{$and->[0]}
+ };
+ }
+ else {
+ $fin->{-and} = $and;
+ last;
+ }
+ }
+
+ # compress same-column conds found in $fin
+ for my $col ( grep { $_ !~ /^\-/ } keys %$fin ) {
+ next unless ref $fin->{$col} eq 'ARRAY' and ($fin->{$col}[0]||'') =~ /^\-and$/i;
+ my $val_bag = { map {
+ (! defined $_ ) ? ( UNDEF => undef )
+ : ( ! length ref $_ or is_plain_value $_ ) ? ( "VAL_$_" => $_ )
+ : ( ( 'SER_' . serialize $_ ) => $_ )
+ } @{$fin->{$col}}[1 .. $#{$fin->{$col}}] };
+
+ if (keys %$val_bag == 1 ) {
+ ($fin->{$col}) = values %$val_bag;
+ }
+ else {
+ $fin->{$col} = [ -and => map { $val_bag->{$_} } sort keys %$val_bag ];
+ }
+ }
+
+ return keys %$fin ? $fin : ();
}
sub _collapse_cond_unroll_pairs {
my @conds;
while (@$pairs) {
- my ($lhs, $rhs) = @{ shift @$pairs };
+ my ($lhs, $rhs) = splice @$pairs, 0, 2;
- if ($lhs eq '') {
+ if (! length $lhs) {
push @conds, $self->_collapse_cond($rhs);
}
elsif ( $lhs =~ /^\-and$/i ) {
if (ref $rhs eq 'HASH' and ! keys %$rhs) {
# FIXME - SQLA seems to be doing... nothing...?
}
+ # normalize top level -ident, for saner extract_fixed_condition_columns code
elsif (ref $rhs eq 'HASH' and keys %$rhs == 1 and exists $rhs->{-ident}) {
push @conds, { $lhs => { '=', $rhs } };
}
push @conds, { $lhs => $rhs->{-value} };
}
elsif (ref $rhs eq 'HASH' and keys %$rhs == 1 and exists $rhs->{'='}) {
- if( is_literal_value $rhs->{'='}) {
+ if ( length ref $rhs->{'='} and is_literal_value $rhs->{'='} ) {
push @conds, { $lhs => $rhs };
}
else {
- for my $p ($self->_collapse_cond_unroll_pairs([ [ $lhs => $rhs->{'='} ] ])) {
+ for my $p ($self->_collapse_cond_unroll_pairs([ $lhs => $rhs->{'='} ])) {
# extra sanity check
if (keys %$p > 1) {
my ($l, $r) = %$p;
- push @conds, ( ! length ref $r or is_plain_value($r) )
+ push @conds, (
+ ! length ref $r
+ or
+ # the unroller recursion may return a '=' prepended value already
+ ref $r eq 'HASH' and keys %$rhs == 1 and exists $rhs->{'='}
+ or
+ is_plain_value($r)
+ )
? { $l => $r }
: { $l => { '=' => $r } }
;
if @$rhs == 1;
if( $rhs->[0] =~ /^\-and$/i ) {
- unshift @$pairs, map { [ $lhs => $_ ] } @{$rhs}[1..$#$rhs];
+ unshift @$pairs, map { $lhs => $_ } @{$rhs}[1..$#$rhs];
}
# if not an AND then it's an OR
elsif(@$rhs == 2) {
- unshift @$pairs, [ $lhs => $rhs->[1] ];
+ unshift @$pairs, $lhs => $rhs->[1];
}
else {
- push @conds, { $lhs => $rhs };
+ push @conds, { $lhs => [ @{$rhs}[1..$#$rhs] ] };
}
}
elsif (@$rhs == 1) {
- unshift @$pairs, [ $lhs => $rhs->[0] ];
+ unshift @$pairs, $lhs => $rhs->[0];
}
else {
push @conds, { $lhs => $rhs };
}
}
+ # unroll func + { -value => ... }
+ elsif (
+ ref $rhs eq 'HASH'
+ and
+ ( my ($subop) = keys %$rhs ) == 1
+ and
+ length ref ((values %$rhs)[0])
+ and
+ my $vref = is_plain_value( (values %$rhs)[0] )
+ ) {
+ push @conds, { $lhs => { $subop => $$vref } }
+ }
else {
push @conds, { $lhs => $rhs };
}
# is instead used to infer inambiguous values from conditions
# (e.g. the inheritance of resultset conditions on new_result)
#
-my $undef_marker = \ do{ my $x = 'undef' };
sub _extract_fixed_condition_columns {
my ($self, $where, $consider_nulls) = @_;
my $where_hash = $self->_collapse_cond($_[1]);
my $vals;
if (!defined ($v = $where_hash->{$c}) ) {
- $vals->{$undef_marker} = $v if $consider_nulls
+ $vals->{UNDEF} = $v if $consider_nulls
}
elsif (
ref $v eq 'HASH'
) {
if (exists $v->{-value}) {
if (defined $v->{-value}) {
- $vals->{$v->{-value}} = $v->{-value}
+ $vals->{"VAL_$v->{-value}"} = $v->{-value}
}
elsif( $consider_nulls ) {
- $vals->{$undef_marker} = $v->{-value};
+ $vals->{UNDEF} = $v->{-value};
}
}
# do not need to check for plain values - _collapse_cond did it for us
- elsif(ref $v->{'='} and is_literal_value($v->{'='}) ) {
- $vals->{$v->{'='}} = $v->{'='};
+ elsif(
+ length ref $v->{'='}
+ and
+ (
+ ( ref $v->{'='} eq 'HASH' and keys %{$v->{'='}} == 1 and exists $v->{'='}{-ident} )
+ or
+ is_literal_value($v->{'='})
+ )
+ ) {
+ $vals->{ 'SER_' . serialize $v->{'='} } = $v->{'='};
}
}
elsif (
or
is_plain_value ($v)
) {
- $vals->{$v} = $v;
+ $vals->{"VAL_$v"} = $v;
}
elsif (ref $v eq 'ARRAY' and ($v->[0]||'') eq '-and') {
for ( @{$v}[1..$#$v] ) {
my $subval = $self->_extract_fixed_condition_columns({ $c => $_ }, 'consider nulls'); # always fish nulls out on recursion
next unless exists $subval->{$c}; # didn't find anything
- $vals->{defined $subval->{$c} ? $subval->{$c} : $undef_marker} = $subval->{$c};
+ $vals->{
+ ! defined $subval->{$c} ? 'UNDEF'
+ : ( ! length ref $subval->{$c} or is_plain_value $subval->{$c} ) ? "VAL_$subval->{$c}"
+ : ( 'SER_' . serialize $subval->{$c} )
+ } = $subval->{$c};
}
}
if (keys %$vals == 1) {
($res->{$c}) = (values %$vals)
- unless !$consider_nulls and exists $vals->{$undef_marker};
+ unless !$consider_nulls and exists $vals->{UNDEF};
}
elsif (keys %$vals > 1) {
$res->{$c} = UNRESOLVABLE_CONDITION;
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