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1 | package SQL::Abstract; # see doc at end of file |
2 | |
3 | # LDNOTE : this code is heavy refactoring from original SQLA. |
4 | # Several design decisions will need discussion during |
5 | # the test / diffusion / acceptance phase; those are marked with flag |
6 | # 'LDNOTE' (note by laurent.dami AT free.fr) |
7 | |
8 | use Carp; |
9 | use strict; |
10 | use warnings; |
fffe6900 |
11 | use List::Util qw/first/; |
12 | use Scalar::Util qw/blessed/; |
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13 | |
14 | #====================================================================== |
15 | # GLOBALS |
16 | #====================================================================== |
17 | |
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18 | our $VERSION = '1.49_04'; |
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19 | $VERSION = eval $VERSION; # numify for warning-free dev releases |
20 | |
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21 | |
22 | our $AUTOLOAD; |
23 | |
24 | # special operators (-in, -between). May be extended/overridden by user. |
25 | # See section WHERE: BUILTIN SPECIAL OPERATORS below for implementation |
26 | my @BUILTIN_SPECIAL_OPS = ( |
27 | {regex => qr/^(not )?between$/i, handler => \&_where_field_BETWEEN}, |
28 | {regex => qr/^(not )?in$/i, handler => \&_where_field_IN}, |
29 | ); |
30 | |
31 | #====================================================================== |
32 | # DEBUGGING AND ERROR REPORTING |
33 | #====================================================================== |
34 | |
35 | sub _debug { |
36 | return unless $_[0]->{debug}; shift; # a little faster |
37 | my $func = (caller(1))[3]; |
38 | warn "[$func] ", @_, "\n"; |
39 | } |
40 | |
41 | sub belch (@) { |
42 | my($func) = (caller(1))[3]; |
43 | carp "[$func] Warning: ", @_; |
44 | } |
45 | |
46 | sub puke (@) { |
47 | my($func) = (caller(1))[3]; |
48 | croak "[$func] Fatal: ", @_; |
49 | } |
50 | |
51 | |
52 | #====================================================================== |
53 | # NEW |
54 | #====================================================================== |
55 | |
56 | sub new { |
57 | my $self = shift; |
58 | my $class = ref($self) || $self; |
59 | my %opt = (ref $_[0] eq 'HASH') ? %{$_[0]} : @_; |
60 | |
61 | # choose our case by keeping an option around |
62 | delete $opt{case} if $opt{case} && $opt{case} ne 'lower'; |
63 | |
64 | # default logic for interpreting arrayrefs |
65 | $opt{logic} = uc $opt{logic} || 'OR'; |
66 | |
67 | # how to return bind vars |
68 | # LDNOTE: changed nwiger code : why this 'delete' ?? |
69 | # $opt{bindtype} ||= delete($opt{bind_type}) || 'normal'; |
70 | $opt{bindtype} ||= 'normal'; |
71 | |
72 | # default comparison is "=", but can be overridden |
73 | $opt{cmp} ||= '='; |
74 | |
75 | # try to recognize which are the 'equality' and 'unequality' ops |
76 | # (temporary quickfix, should go through a more seasoned API) |
77 | $opt{equality_op} = qr/^(\Q$opt{cmp}\E|is|(is\s+)?like)$/i; |
78 | $opt{inequality_op} = qr/^(!=|<>|(is\s+)?not(\s+like)?)$/i; |
79 | |
80 | # SQL booleans |
81 | $opt{sqltrue} ||= '1=1'; |
82 | $opt{sqlfalse} ||= '0=1'; |
83 | |
84 | # special operators |
85 | $opt{special_ops} ||= []; |
86 | push @{$opt{special_ops}}, @BUILTIN_SPECIAL_OPS; |
87 | |
88 | return bless \%opt, $class; |
89 | } |
90 | |
91 | |
92 | |
93 | #====================================================================== |
94 | # INSERT methods |
95 | #====================================================================== |
96 | |
97 | sub insert { |
98 | my $self = shift; |
99 | my $table = $self->_table(shift); |
100 | my $data = shift || return; |
101 | |
102 | my $method = $self->_METHOD_FOR_refkind("_insert", $data); |
103 | my ($sql, @bind) = $self->$method($data); |
104 | $sql = join " ", $self->_sqlcase('insert into'), $table, $sql; |
105 | return wantarray ? ($sql, @bind) : $sql; |
106 | } |
107 | |
108 | sub _insert_HASHREF { # explicit list of fields and then values |
109 | my ($self, $data) = @_; |
110 | |
111 | my @fields = sort keys %$data; |
112 | |
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113 | my ($sql, @bind) = $self->_insert_values($data); |
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114 | |
115 | # assemble SQL |
116 | $_ = $self->_quote($_) foreach @fields; |
117 | $sql = "( ".join(", ", @fields).") ".$sql; |
118 | |
119 | return ($sql, @bind); |
120 | } |
121 | |
122 | sub _insert_ARRAYREF { # just generate values(?,?) part (no list of fields) |
123 | my ($self, $data) = @_; |
124 | |
125 | # no names (arrayref) so can't generate bindtype |
126 | $self->{bindtype} ne 'columns' |
127 | or belch "can't do 'columns' bindtype when called with arrayref"; |
128 | |
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129 | # fold the list of values into a hash of column name - value pairs |
130 | # (where the column names are artificially generated, and their |
131 | # lexicographical ordering keep the ordering of the original list) |
132 | my $i = "a"; # incremented values will be in lexicographical order |
133 | my $data_in_hash = { map { ($i++ => $_) } @$data }; |
134 | |
135 | return $self->_insert_values($data_in_hash); |
136 | } |
137 | |
138 | sub _insert_ARRAYREFREF { # literal SQL with bind |
139 | my ($self, $data) = @_; |
140 | |
141 | my ($sql, @bind) = @${$data}; |
142 | $self->_assert_bindval_matches_bindtype(@bind); |
143 | |
144 | return ($sql, @bind); |
145 | } |
146 | |
147 | |
148 | sub _insert_SCALARREF { # literal SQL without bind |
149 | my ($self, $data) = @_; |
150 | |
151 | return ($$data); |
152 | } |
153 | |
154 | sub _insert_values { |
155 | my ($self, $data) = @_; |
156 | |
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157 | my (@values, @all_bind); |
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158 | foreach my $column (sort keys %$data) { |
159 | my $v = $data->{$column}; |
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160 | |
161 | $self->_SWITCH_refkind($v, { |
162 | |
163 | ARRAYREF => sub { |
164 | if ($self->{array_datatypes}) { # if array datatype are activated |
165 | push @values, '?'; |
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166 | push @all_bind, $self->_bindtype($column, $v); |
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167 | } |
168 | else { # else literal SQL with bind |
169 | my ($sql, @bind) = @$v; |
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170 | $self->_assert_bindval_matches_bindtype(@bind); |
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171 | push @values, $sql; |
172 | push @all_bind, @bind; |
173 | } |
174 | }, |
175 | |
176 | ARRAYREFREF => sub { # literal SQL with bind |
177 | my ($sql, @bind) = @${$v}; |
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178 | $self->_assert_bindval_matches_bindtype(@bind); |
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179 | push @values, $sql; |
180 | push @all_bind, @bind; |
181 | }, |
182 | |
183 | # THINK : anything useful to do with a HASHREF ? |
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184 | HASHREF => sub { # (nothing, but old SQLA passed it through) |
185 | #TODO in SQLA >= 2.0 it will die instead |
186 | belch "HASH ref as bind value in insert is not supported"; |
187 | push @values, '?'; |
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188 | push @all_bind, $self->_bindtype($column, $v); |
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189 | }, |
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190 | |
191 | SCALARREF => sub { # literal SQL without bind |
192 | push @values, $$v; |
193 | }, |
194 | |
195 | SCALAR_or_UNDEF => sub { |
196 | push @values, '?'; |
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197 | push @all_bind, $self->_bindtype($column, $v); |
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198 | }, |
199 | |
200 | }); |
201 | |
202 | } |
203 | |
204 | my $sql = $self->_sqlcase('values')." ( ".join(", ", @values)." )"; |
205 | return ($sql, @all_bind); |
206 | } |
207 | |
208 | |
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209 | |
210 | #====================================================================== |
211 | # UPDATE methods |
212 | #====================================================================== |
213 | |
214 | |
215 | sub update { |
216 | my $self = shift; |
217 | my $table = $self->_table(shift); |
218 | my $data = shift || return; |
219 | my $where = shift; |
220 | |
221 | # first build the 'SET' part of the sql statement |
222 | my (@set, @all_bind); |
223 | puke "Unsupported data type specified to \$sql->update" |
224 | unless ref $data eq 'HASH'; |
225 | |
226 | for my $k (sort keys %$data) { |
227 | my $v = $data->{$k}; |
228 | my $r = ref $v; |
229 | my $label = $self->_quote($k); |
230 | |
231 | $self->_SWITCH_refkind($v, { |
232 | ARRAYREF => sub { |
233 | if ($self->{array_datatypes}) { # array datatype |
234 | push @set, "$label = ?"; |
235 | push @all_bind, $self->_bindtype($k, $v); |
236 | } |
237 | else { # literal SQL with bind |
238 | my ($sql, @bind) = @$v; |
fe3ae272 |
239 | $self->_assert_bindval_matches_bindtype(@bind); |
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240 | push @set, "$label = $sql"; |
fe3ae272 |
241 | push @all_bind, @bind; |
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242 | } |
243 | }, |
244 | ARRAYREFREF => sub { # literal SQL with bind |
245 | my ($sql, @bind) = @${$v}; |
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246 | $self->_assert_bindval_matches_bindtype(@bind); |
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247 | push @set, "$label = $sql"; |
fe3ae272 |
248 | push @all_bind, @bind; |
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249 | }, |
250 | SCALARREF => sub { # literal SQL without bind |
251 | push @set, "$label = $$v"; |
252 | }, |
253 | SCALAR_or_UNDEF => sub { |
254 | push @set, "$label = ?"; |
255 | push @all_bind, $self->_bindtype($k, $v); |
256 | }, |
257 | }); |
258 | } |
259 | |
260 | # generate sql |
261 | my $sql = $self->_sqlcase('update') . " $table " . $self->_sqlcase('set ') |
262 | . join ', ', @set; |
263 | |
264 | if ($where) { |
265 | my($where_sql, @where_bind) = $self->where($where); |
266 | $sql .= $where_sql; |
267 | push @all_bind, @where_bind; |
268 | } |
269 | |
270 | return wantarray ? ($sql, @all_bind) : $sql; |
271 | } |
272 | |
273 | |
274 | |
275 | |
276 | #====================================================================== |
277 | # SELECT |
278 | #====================================================================== |
279 | |
280 | |
281 | sub select { |
282 | my $self = shift; |
283 | my $table = $self->_table(shift); |
284 | my $fields = shift || '*'; |
285 | my $where = shift; |
286 | my $order = shift; |
287 | |
288 | my($where_sql, @bind) = $self->where($where, $order); |
289 | |
290 | my $f = (ref $fields eq 'ARRAY') ? join ', ', map { $self->_quote($_) } @$fields |
291 | : $fields; |
292 | my $sql = join(' ', $self->_sqlcase('select'), $f, |
293 | $self->_sqlcase('from'), $table) |
294 | . $where_sql; |
295 | |
296 | return wantarray ? ($sql, @bind) : $sql; |
297 | } |
298 | |
299 | #====================================================================== |
300 | # DELETE |
301 | #====================================================================== |
302 | |
303 | |
304 | sub delete { |
305 | my $self = shift; |
306 | my $table = $self->_table(shift); |
307 | my $where = shift; |
308 | |
309 | |
310 | my($where_sql, @bind) = $self->where($where); |
311 | my $sql = $self->_sqlcase('delete from') . " $table" . $where_sql; |
312 | |
313 | return wantarray ? ($sql, @bind) : $sql; |
314 | } |
315 | |
316 | |
317 | #====================================================================== |
318 | # WHERE: entry point |
319 | #====================================================================== |
320 | |
321 | |
322 | |
323 | # Finally, a separate routine just to handle WHERE clauses |
324 | sub where { |
325 | my ($self, $where, $order) = @_; |
326 | |
327 | # where ? |
328 | my ($sql, @bind) = $self->_recurse_where($where); |
329 | $sql = $sql ? $self->_sqlcase(' where ') . "( $sql )" : ''; |
330 | |
331 | # order by? |
332 | if ($order) { |
333 | $sql .= $self->_order_by($order); |
334 | } |
335 | |
336 | return wantarray ? ($sql, @bind) : $sql; |
337 | } |
338 | |
339 | |
340 | sub _recurse_where { |
341 | my ($self, $where, $logic) = @_; |
342 | |
343 | # dispatch on appropriate method according to refkind of $where |
344 | my $method = $self->_METHOD_FOR_refkind("_where", $where); |
311b2151 |
345 | |
346 | |
347 | my ($sql, @bind) = $self->$method($where, $logic); |
348 | |
349 | # DBIx::Class directly calls _recurse_where in scalar context, so |
350 | # we must implement it, even if not in the official API |
351 | return wantarray ? ($sql, @bind) : $sql; |
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352 | } |
353 | |
354 | |
355 | |
356 | #====================================================================== |
357 | # WHERE: top-level ARRAYREF |
358 | #====================================================================== |
359 | |
360 | |
361 | sub _where_ARRAYREF { |
362 | my ($self, $where, $logic) = @_; |
363 | |
364 | $logic = uc($logic || $self->{logic}); |
365 | $logic eq 'AND' or $logic eq 'OR' or puke "unknown logic: $logic"; |
366 | |
367 | my @clauses = @$where; |
368 | |
369 | # if the array starts with [-and|or => ...], recurse with that logic |
370 | my $first = $clauses[0] || ''; |
371 | if ($first =~ /^-(and|or)/i) { |
372 | $logic = $1; |
373 | shift @clauses; |
374 | return $self->_where_ARRAYREF(\@clauses, $logic); |
375 | } |
376 | |
377 | #otherwise.. |
378 | my (@sql_clauses, @all_bind); |
379 | |
380 | # need to use while() so can shift() for pairs |
381 | while (my $el = shift @clauses) { |
382 | |
383 | # switch according to kind of $el and get corresponding ($sql, @bind) |
384 | my ($sql, @bind) = $self->_SWITCH_refkind($el, { |
385 | |
386 | # skip empty elements, otherwise get invalid trailing AND stuff |
387 | ARRAYREF => sub {$self->_recurse_where($el) if @$el}, |
388 | |
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389 | ARRAYREFREF => sub { @{${$el}} if @{${$el}}}, |
390 | |
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391 | HASHREF => sub {$self->_recurse_where($el, 'and') if %$el}, |
392 | # LDNOTE : previous SQLA code for hashrefs was creating a dirty |
393 | # side-effect: the first hashref within an array would change |
394 | # the global logic to 'AND'. So [ {cond1, cond2}, [cond3, cond4] ] |
395 | # was interpreted as "(cond1 AND cond2) OR (cond3 AND cond4)", |
396 | # whereas it should be "(cond1 AND cond2) OR (cond3 OR cond4)". |
397 | |
398 | SCALARREF => sub { ($$el); }, |
399 | |
400 | SCALAR => sub {# top-level arrayref with scalars, recurse in pairs |
401 | $self->_recurse_where({$el => shift(@clauses)})}, |
402 | |
403 | UNDEF => sub {puke "not supported : UNDEF in arrayref" }, |
404 | }); |
405 | |
4b7b6026 |
406 | if ($sql) { |
407 | push @sql_clauses, $sql; |
408 | push @all_bind, @bind; |
409 | } |
96449e8e |
410 | } |
411 | |
412 | return $self->_join_sql_clauses($logic, \@sql_clauses, \@all_bind); |
413 | } |
414 | |
474e3335 |
415 | #====================================================================== |
416 | # WHERE: top-level ARRAYREFREF |
417 | #====================================================================== |
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418 | |
474e3335 |
419 | sub _where_ARRAYREFREF { |
420 | my ($self, $where) = @_; |
421 | my ($sql, @bind) = @{${$where}}; |
422 | |
423 | return ($sql, @bind); |
424 | } |
96449e8e |
425 | |
426 | #====================================================================== |
427 | # WHERE: top-level HASHREF |
428 | #====================================================================== |
429 | |
430 | sub _where_HASHREF { |
431 | my ($self, $where) = @_; |
432 | my (@sql_clauses, @all_bind); |
433 | |
434 | # LDNOTE : don't really know why we need to sort keys |
435 | for my $k (sort keys %$where) { |
436 | my $v = $where->{$k}; |
437 | |
438 | # ($k => $v) is either a special op or a regular hashpair |
439 | my ($sql, @bind) = ($k =~ /^-(.+)/) ? $self->_where_op_in_hash($1, $v) |
440 | : do { |
441 | my $method = $self->_METHOD_FOR_refkind("_where_hashpair", $v); |
442 | $self->$method($k, $v); |
443 | }; |
444 | |
445 | push @sql_clauses, $sql; |
446 | push @all_bind, @bind; |
447 | } |
448 | |
449 | return $self->_join_sql_clauses('and', \@sql_clauses, \@all_bind); |
450 | } |
451 | |
452 | |
453 | sub _where_op_in_hash { |
454 | my ($self, $op, $v) = @_; |
455 | |
456 | $op =~ /^(AND|OR|NEST)[_\d]*/i |
457 | or puke "unknown operator: -$op"; |
458 | $op = uc($1); # uppercase, remove trailing digits |
459 | $self->_debug("OP(-$op) within hashref, recursing..."); |
460 | |
461 | $self->_SWITCH_refkind($v, { |
462 | |
463 | ARRAYREF => sub { |
464 | # LDNOTE : should deprecate {-or => [...]} and {-and => [...]} |
465 | # because they are misleading; the only proper way would be |
466 | # -nest => [-or => ...], -nest => [-and ...] |
467 | return $self->_where_ARRAYREF($v, $op eq 'NEST' ? '' : $op); |
468 | }, |
469 | |
470 | HASHREF => sub { |
471 | if ($op eq 'OR') { |
472 | belch "-or => {...} should be -nest => [...]"; |
473 | return $self->_where_ARRAYREF([%$v], 'OR'); |
474 | } |
475 | else { # NEST | AND |
476 | return $self->_where_HASHREF($v); |
477 | } |
478 | }, |
479 | |
480 | SCALARREF => sub { # literal SQL |
481 | $op eq 'NEST' |
482 | or puke "-$op => \\\$scalar not supported, use -nest => ..."; |
483 | return ($$v); |
484 | }, |
485 | |
486 | ARRAYREFREF => sub { # literal SQL |
487 | $op eq 'NEST' |
488 | or puke "-$op => \\[..] not supported, use -nest => ..."; |
489 | return @{${$v}}; |
490 | }, |
491 | |
492 | SCALAR => sub { # permissively interpreted as SQL |
493 | $op eq 'NEST' |
494 | or puke "-$op => 'scalar' not supported, use -nest => \\'scalar'"; |
495 | belch "literal SQL should be -nest => \\'scalar' " |
496 | . "instead of -nest => 'scalar' "; |
497 | return ($v); |
498 | }, |
499 | |
500 | UNDEF => sub { |
501 | puke "-$op => undef not supported"; |
502 | }, |
503 | }); |
504 | } |
505 | |
506 | |
507 | sub _where_hashpair_ARRAYREF { |
508 | my ($self, $k, $v) = @_; |
509 | |
510 | if( @$v ) { |
511 | my @v = @$v; # need copy because of shift below |
512 | $self->_debug("ARRAY($k) means distribute over elements"); |
513 | |
514 | # put apart first element if it is an operator (-and, -or) |
515 | my $op = $v[0] =~ /^-/ ? shift @v : undef; |
516 | $self->_debug("OP($op) reinjected into the distributed array") if $op; |
517 | |
518 | my @distributed = map { {$k => $_} } @v; |
519 | unshift @distributed, $op if $op; |
520 | |
521 | return $self->_recurse_where(\@distributed); |
522 | } |
523 | else { |
524 | # LDNOTE : not sure of this one. What does "distribute over nothing" mean? |
525 | $self->_debug("empty ARRAY($k) means 0=1"); |
526 | return ($self->{sqlfalse}); |
527 | } |
528 | } |
529 | |
530 | sub _where_hashpair_HASHREF { |
531 | my ($self, $k, $v) = @_; |
532 | |
533 | my (@all_sql, @all_bind); |
534 | |
535 | for my $op (sort keys %$v) { |
536 | my $val = $v->{$op}; |
537 | |
538 | # put the operator in canonical form |
539 | $op =~ s/^-//; # remove initial dash |
540 | $op =~ tr/_/ /; # underscores become spaces |
541 | $op =~ s/^\s+//; # no initial space |
542 | $op =~ s/\s+$//; # no final space |
543 | $op =~ s/\s+/ /; # multiple spaces become one |
544 | |
545 | my ($sql, @bind); |
546 | |
547 | # CASE: special operators like -in or -between |
548 | my $special_op = first {$op =~ $_->{regex}} @{$self->{special_ops}}; |
549 | if ($special_op) { |
550 | ($sql, @bind) = $special_op->{handler}->($self, $k, $op, $val); |
551 | } |
96449e8e |
552 | else { |
cf838930 |
553 | $self->_SWITCH_refkind($val, { |
554 | |
555 | ARRAYREF => sub { # CASE: col => {op => \@vals} |
556 | ($sql, @bind) = $self->_where_field_op_ARRAYREF($k, $op, $val); |
557 | }, |
558 | |
fe3ae272 |
559 | SCALARREF => sub { # CASE: col => {op => \$scalar} (literal SQL without bind) |
cf838930 |
560 | $sql = join ' ', $self->_convert($self->_quote($k)), |
561 | $self->_sqlcase($op), |
562 | $$val; |
563 | }, |
564 | |
fe3ae272 |
565 | ARRAYREFREF => sub { # CASE: col => {op => \[$sql, @bind]} (literal SQL with bind) |
b3be7bd0 |
566 | my ($sub_sql, @sub_bind) = @$$val; |
fe3ae272 |
567 | $self->_assert_bindval_matches_bindtype(@sub_bind); |
b3be7bd0 |
568 | $sql = join ' ', $self->_convert($self->_quote($k)), |
569 | $self->_sqlcase($op), |
570 | $sub_sql; |
fe3ae272 |
571 | @bind = @sub_bind; |
b3be7bd0 |
572 | }, |
573 | |
cf838930 |
574 | UNDEF => sub { # CASE: col => {op => undef} : sql "IS (NOT)? NULL" |
575 | my $is = ($op =~ $self->{equality_op}) ? 'is' : |
576 | ($op =~ $self->{inequality_op}) ? 'is not' : |
577 | puke "unexpected operator '$op' with undef operand"; |
578 | $sql = $self->_quote($k) . $self->_sqlcase(" $is null"); |
579 | }, |
580 | |
581 | FALLBACK => sub { # CASE: col => {op => $scalar} |
582 | $sql = join ' ', $self->_convert($self->_quote($k)), |
583 | $self->_sqlcase($op), |
584 | $self->_convert('?'); |
585 | @bind = $self->_bindtype($k, $val); |
586 | }, |
587 | }); |
96449e8e |
588 | } |
589 | |
590 | push @all_sql, $sql; |
591 | push @all_bind, @bind; |
592 | } |
593 | |
594 | return $self->_join_sql_clauses('and', \@all_sql, \@all_bind); |
595 | } |
596 | |
597 | |
598 | |
599 | sub _where_field_op_ARRAYREF { |
600 | my ($self, $k, $op, $vals) = @_; |
601 | |
602 | if(@$vals) { |
603 | $self->_debug("ARRAY($vals) means multiple elements: [ @$vals ]"); |
604 | |
605 | |
606 | |
607 | # LDNOTE : change the distribution logic when |
608 | # $op =~ $self->{inequality_op}, because of Morgan laws : |
609 | # with {field => {'!=' => [22, 33]}}, it would be ridiculous to generate |
610 | # WHERE field != 22 OR field != 33 : the user probably means |
611 | # WHERE field != 22 AND field != 33. |
612 | my $logic = ($op =~ $self->{inequality_op}) ? 'AND' : 'OR'; |
613 | |
614 | # distribute $op over each member of @$vals |
615 | return $self->_recurse_where([map { {$k => {$op, $_}} } @$vals], $logic); |
616 | |
617 | } |
618 | else { |
619 | # try to DWIM on equality operators |
620 | # LDNOTE : not 100% sure this is the correct thing to do ... |
621 | return ($self->{sqlfalse}) if $op =~ $self->{equality_op}; |
622 | return ($self->{sqltrue}) if $op =~ $self->{inequality_op}; |
623 | |
624 | # otherwise |
625 | puke "operator '$op' applied on an empty array (field '$k')"; |
626 | } |
627 | } |
628 | |
629 | |
630 | sub _where_hashpair_SCALARREF { |
631 | my ($self, $k, $v) = @_; |
632 | $self->_debug("SCALAR($k) means literal SQL: $$v"); |
633 | my $sql = $self->_quote($k) . " " . $$v; |
634 | return ($sql); |
635 | } |
636 | |
fe3ae272 |
637 | # literal SQL with bind |
96449e8e |
638 | sub _where_hashpair_ARRAYREFREF { |
639 | my ($self, $k, $v) = @_; |
640 | $self->_debug("REF($k) means literal SQL: @${$v}"); |
641 | my ($sql, @bind) = @${$v}; |
fe3ae272 |
642 | $self->_assert_bindval_matches_bindtype(@bind); |
96449e8e |
643 | $sql = $self->_quote($k) . " " . $sql; |
96449e8e |
644 | return ($sql, @bind ); |
645 | } |
646 | |
fe3ae272 |
647 | # literal SQL without bind |
96449e8e |
648 | sub _where_hashpair_SCALAR { |
649 | my ($self, $k, $v) = @_; |
650 | $self->_debug("NOREF($k) means simple key=val: $k $self->{cmp} $v"); |
651 | my $sql = join ' ', $self->_convert($self->_quote($k)), |
652 | $self->_sqlcase($self->{cmp}), |
653 | $self->_convert('?'); |
654 | my @bind = $self->_bindtype($k, $v); |
655 | return ( $sql, @bind); |
656 | } |
657 | |
658 | |
659 | sub _where_hashpair_UNDEF { |
660 | my ($self, $k, $v) = @_; |
661 | $self->_debug("UNDEF($k) means IS NULL"); |
662 | my $sql = $self->_quote($k) . $self->_sqlcase(' is null'); |
663 | return ($sql); |
664 | } |
665 | |
666 | #====================================================================== |
667 | # WHERE: TOP-LEVEL OTHERS (SCALARREF, SCALAR, UNDEF) |
668 | #====================================================================== |
669 | |
670 | |
671 | sub _where_SCALARREF { |
672 | my ($self, $where) = @_; |
673 | |
674 | # literal sql |
675 | $self->_debug("SCALAR(*top) means literal SQL: $$where"); |
676 | return ($$where); |
677 | } |
678 | |
679 | |
680 | sub _where_SCALAR { |
681 | my ($self, $where) = @_; |
682 | |
683 | # literal sql |
684 | $self->_debug("NOREF(*top) means literal SQL: $where"); |
685 | return ($where); |
686 | } |
687 | |
688 | |
689 | sub _where_UNDEF { |
690 | my ($self) = @_; |
691 | return (); |
692 | } |
693 | |
694 | |
695 | #====================================================================== |
696 | # WHERE: BUILTIN SPECIAL OPERATORS (-in, -between) |
697 | #====================================================================== |
698 | |
699 | |
700 | sub _where_field_BETWEEN { |
701 | my ($self, $k, $op, $vals) = @_; |
702 | |
703 | ref $vals eq 'ARRAY' && @$vals == 2 |
704 | or puke "special op 'between' requires an arrayref of two values"; |
705 | |
706 | my ($label) = $self->_convert($self->_quote($k)); |
707 | my ($placeholder) = $self->_convert('?'); |
708 | my $and = $self->_sqlcase('and'); |
709 | $op = $self->_sqlcase($op); |
710 | |
711 | my $sql = "( $label $op $placeholder $and $placeholder )"; |
712 | my @bind = $self->_bindtype($k, @$vals); |
713 | return ($sql, @bind) |
714 | } |
715 | |
716 | |
717 | sub _where_field_IN { |
718 | my ($self, $k, $op, $vals) = @_; |
719 | |
720 | # backwards compatibility : if scalar, force into an arrayref |
721 | $vals = [$vals] if defined $vals && ! ref $vals; |
722 | |
96449e8e |
723 | my ($label) = $self->_convert($self->_quote($k)); |
724 | my ($placeholder) = $self->_convert('?'); |
96449e8e |
725 | $op = $self->_sqlcase($op); |
726 | |
8a0d798a |
727 | my ($sql, @bind) = $self->_SWITCH_refkind($vals, { |
728 | ARRAYREF => sub { # list of choices |
729 | if (@$vals) { # nonempty list |
730 | my $placeholders = join ", ", (($placeholder) x @$vals); |
731 | my $sql = "$label $op ( $placeholders )"; |
732 | my @bind = $self->_bindtype($k, @$vals); |
96449e8e |
733 | |
8a0d798a |
734 | return ($sql, @bind); |
735 | } |
736 | else { # empty list : some databases won't understand "IN ()", so DWIM |
737 | my $sql = ($op =~ /\bnot\b/i) ? $self->{sqltrue} : $self->{sqlfalse}; |
738 | return ($sql); |
739 | } |
740 | }, |
741 | |
742 | ARRAYREFREF => sub { # literal SQL with bind |
743 | my ($sql, @bind) = @$$vals; |
fe3ae272 |
744 | $self->_assert_bindval_matches_bindtype(@bind); |
8a0d798a |
745 | return ("$label $op ( $sql )", @bind); |
746 | }, |
747 | |
748 | FALLBACK => sub { |
749 | puke "special op 'in' requires an arrayref (or arrayref-ref)"; |
750 | }, |
751 | }); |
752 | |
753 | return ($sql, @bind); |
96449e8e |
754 | } |
755 | |
756 | |
757 | |
758 | |
759 | |
760 | |
761 | #====================================================================== |
762 | # ORDER BY |
763 | #====================================================================== |
764 | |
765 | sub _order_by { |
766 | my ($self, $arg) = @_; |
767 | |
768 | # construct list of ordering instructions |
769 | my @order = $self->_SWITCH_refkind($arg, { |
770 | |
771 | ARRAYREF => sub { |
772 | map {$self->_SWITCH_refkind($_, { |
773 | SCALAR => sub {$self->_quote($_)}, |
fffe6900 |
774 | UNDEF => sub {}, |
96449e8e |
775 | SCALARREF => sub {$$_}, # literal SQL, no quoting |
776 | HASHREF => sub {$self->_order_by_hash($_)} |
777 | }) } @$arg; |
778 | }, |
779 | |
780 | SCALAR => sub {$self->_quote($arg)}, |
b6475fb1 |
781 | UNDEF => sub {}, |
96449e8e |
782 | SCALARREF => sub {$$arg}, # literal SQL, no quoting |
783 | HASHREF => sub {$self->_order_by_hash($arg)}, |
784 | |
785 | }); |
786 | |
787 | # build SQL |
788 | my $order = join ', ', @order; |
789 | return $order ? $self->_sqlcase(' order by')." $order" : ''; |
790 | } |
791 | |
792 | |
793 | sub _order_by_hash { |
794 | my ($self, $hash) = @_; |
795 | |
796 | # get first pair in hash |
797 | my ($key, $val) = each %$hash; |
798 | |
799 | # check if one pair was found and no other pair in hash |
800 | $key && !(each %$hash) |
801 | or puke "hash passed to _order_by must have exactly one key (-desc or -asc)"; |
802 | |
803 | my ($order) = ($key =~ /^-(desc|asc)/i) |
804 | or puke "invalid key in _order_by hash : $key"; |
805 | |
806 | return $self->_quote($val) ." ". $self->_sqlcase($order); |
807 | } |
808 | |
809 | |
810 | |
811 | #====================================================================== |
812 | # DATASOURCE (FOR NOW, JUST PLAIN TABLE OR LIST OF TABLES) |
813 | #====================================================================== |
814 | |
815 | sub _table { |
816 | my $self = shift; |
817 | my $from = shift; |
818 | $self->_SWITCH_refkind($from, { |
819 | ARRAYREF => sub {join ', ', map { $self->_quote($_) } @$from;}, |
820 | SCALAR => sub {$self->_quote($from)}, |
821 | SCALARREF => sub {$$from}, |
822 | ARRAYREFREF => sub {join ', ', @$from;}, |
823 | }); |
824 | } |
825 | |
826 | |
827 | #====================================================================== |
828 | # UTILITY FUNCTIONS |
829 | #====================================================================== |
830 | |
831 | sub _quote { |
832 | my $self = shift; |
833 | my $label = shift; |
834 | |
835 | $label or puke "can't quote an empty label"; |
836 | |
837 | # left and right quote characters |
838 | my ($ql, $qr, @other) = $self->_SWITCH_refkind($self->{quote_char}, { |
839 | SCALAR => sub {($self->{quote_char}, $self->{quote_char})}, |
840 | ARRAYREF => sub {@{$self->{quote_char}}}, |
841 | UNDEF => sub {()}, |
842 | }); |
843 | not @other |
844 | or puke "quote_char must be an arrayref of 2 values"; |
845 | |
846 | # no quoting if no quoting chars |
847 | $ql or return $label; |
848 | |
849 | # no quoting for literal SQL |
850 | return $$label if ref($label) eq 'SCALAR'; |
851 | |
852 | # separate table / column (if applicable) |
853 | my $sep = $self->{name_sep} || ''; |
854 | my @to_quote = $sep ? split /\Q$sep\E/, $label : ($label); |
855 | |
856 | # do the quoting, except for "*" or for `table`.* |
857 | my @quoted = map { $_ eq '*' ? $_: $ql.$_.$qr} @to_quote; |
858 | |
859 | # reassemble and return. |
860 | return join $sep, @quoted; |
861 | } |
862 | |
863 | |
864 | # Conversion, if applicable |
865 | sub _convert ($) { |
866 | my ($self, $arg) = @_; |
867 | |
868 | # LDNOTE : modified the previous implementation below because |
869 | # it was not consistent : the first "return" is always an array, |
870 | # the second "return" is context-dependent. Anyway, _convert |
871 | # seems always used with just a single argument, so make it a |
872 | # scalar function. |
873 | # return @_ unless $self->{convert}; |
874 | # my $conv = $self->_sqlcase($self->{convert}); |
875 | # my @ret = map { $conv.'('.$_.')' } @_; |
876 | # return wantarray ? @ret : $ret[0]; |
877 | if ($self->{convert}) { |
878 | my $conv = $self->_sqlcase($self->{convert}); |
879 | $arg = $conv.'('.$arg.')'; |
880 | } |
881 | return $arg; |
882 | } |
883 | |
884 | # And bindtype |
885 | sub _bindtype (@) { |
886 | my $self = shift; |
887 | my($col, @vals) = @_; |
888 | |
889 | #LDNOTE : changed original implementation below because it did not make |
890 | # sense when bindtype eq 'columns' and @vals > 1. |
891 | # return $self->{bindtype} eq 'columns' ? [ $col, @vals ] : @vals; |
892 | |
893 | return $self->{bindtype} eq 'columns' ? map {[$col, $_]} @vals : @vals; |
894 | } |
895 | |
fe3ae272 |
896 | # Dies if any element of @bind is not in [colname => value] format |
897 | # if bindtype is 'columns'. |
898 | sub _assert_bindval_matches_bindtype { |
899 | my ($self, @bind) = @_; |
900 | |
901 | if ($self->{bindtype} eq 'columns') { |
902 | foreach my $val (@bind) { |
903 | if (!defined $val || ref($val) ne 'ARRAY' || @$val != 2) { |
904 | die "bindtype 'columns' selected, you need to pass: [column_name => bind_value]" |
905 | } |
906 | } |
907 | } |
908 | } |
909 | |
96449e8e |
910 | sub _join_sql_clauses { |
911 | my ($self, $logic, $clauses_aref, $bind_aref) = @_; |
912 | |
913 | if (@$clauses_aref > 1) { |
914 | my $join = " " . $self->_sqlcase($logic) . " "; |
915 | my $sql = '( ' . join($join, @$clauses_aref) . ' )'; |
916 | return ($sql, @$bind_aref); |
917 | } |
918 | elsif (@$clauses_aref) { |
919 | return ($clauses_aref->[0], @$bind_aref); # no parentheses |
920 | } |
921 | else { |
922 | return (); # if no SQL, ignore @$bind_aref |
923 | } |
924 | } |
925 | |
926 | |
927 | # Fix SQL case, if so requested |
928 | sub _sqlcase { |
929 | my $self = shift; |
930 | |
931 | # LDNOTE: if $self->{case} is true, then it contains 'lower', so we |
932 | # don't touch the argument ... crooked logic, but let's not change it! |
933 | return $self->{case} ? $_[0] : uc($_[0]); |
934 | } |
935 | |
936 | |
937 | #====================================================================== |
938 | # DISPATCHING FROM REFKIND |
939 | #====================================================================== |
940 | |
941 | sub _refkind { |
942 | my ($self, $data) = @_; |
943 | my $suffix = ''; |
944 | my $ref; |
90aab162 |
945 | my $n_steps = 0; |
96449e8e |
946 | |
96449e8e |
947 | while (1) { |
90aab162 |
948 | # blessed objects are treated like scalars |
949 | $ref = (blessed $data) ? '' : ref $data; |
950 | $n_steps += 1 if $ref; |
951 | last if $ref ne 'REF'; |
96449e8e |
952 | $data = $$data; |
953 | } |
954 | |
90aab162 |
955 | my $base = $ref || (defined $data ? 'SCALAR' : 'UNDEF'); |
956 | |
957 | return $base . ('REF' x $n_steps); |
96449e8e |
958 | } |
959 | |
90aab162 |
960 | |
961 | |
96449e8e |
962 | sub _try_refkind { |
963 | my ($self, $data) = @_; |
964 | my @try = ($self->_refkind($data)); |
965 | push @try, 'SCALAR_or_UNDEF' if $try[0] eq 'SCALAR' || $try[0] eq 'UNDEF'; |
966 | push @try, 'FALLBACK'; |
967 | return @try; |
968 | } |
969 | |
970 | sub _METHOD_FOR_refkind { |
971 | my ($self, $meth_prefix, $data) = @_; |
972 | my $method = first {$_} map {$self->can($meth_prefix."_".$_)} |
973 | $self->_try_refkind($data) |
974 | or puke "cannot dispatch on '$meth_prefix' for ".$self->_refkind($data); |
975 | return $method; |
976 | } |
977 | |
978 | |
979 | sub _SWITCH_refkind { |
980 | my ($self, $data, $dispatch_table) = @_; |
981 | |
982 | my $coderef = first {$_} map {$dispatch_table->{$_}} |
983 | $self->_try_refkind($data) |
984 | or puke "no dispatch entry for ".$self->_refkind($data); |
985 | $coderef->(); |
986 | } |
987 | |
988 | |
989 | |
990 | |
991 | #====================================================================== |
992 | # VALUES, GENERATE, AUTOLOAD |
993 | #====================================================================== |
994 | |
995 | # LDNOTE: original code from nwiger, didn't touch code in that section |
996 | # I feel the AUTOLOAD stuff should not be the default, it should |
997 | # only be activated on explicit demand by user. |
998 | |
999 | sub values { |
1000 | my $self = shift; |
1001 | my $data = shift || return; |
1002 | puke "Argument to ", __PACKAGE__, "->values must be a \\%hash" |
1003 | unless ref $data eq 'HASH'; |
bab725ce |
1004 | |
1005 | my @all_bind; |
1006 | foreach my $k ( sort keys %$data ) { |
1007 | my $v = $data->{$k}; |
1008 | $self->_SWITCH_refkind($v, { |
1009 | ARRAYREF => sub { |
1010 | if ($self->{array_datatypes}) { # array datatype |
1011 | push @all_bind, $self->_bindtype($k, $v); |
1012 | } |
1013 | else { # literal SQL with bind |
1014 | my ($sql, @bind) = @$v; |
1015 | $self->_assert_bindval_matches_bindtype(@bind); |
1016 | push @all_bind, @bind; |
1017 | } |
1018 | }, |
1019 | ARRAYREFREF => sub { # literal SQL with bind |
1020 | my ($sql, @bind) = @${$v}; |
1021 | $self->_assert_bindval_matches_bindtype(@bind); |
1022 | push @all_bind, @bind; |
1023 | }, |
1024 | SCALARREF => sub { # literal SQL without bind |
1025 | }, |
1026 | SCALAR_or_UNDEF => sub { |
1027 | push @all_bind, $self->_bindtype($k, $v); |
1028 | }, |
1029 | }); |
1030 | } |
1031 | |
1032 | return @all_bind; |
96449e8e |
1033 | } |
1034 | |
1035 | sub generate { |
1036 | my $self = shift; |
1037 | |
1038 | my(@sql, @sqlq, @sqlv); |
1039 | |
1040 | for (@_) { |
1041 | my $ref = ref $_; |
1042 | if ($ref eq 'HASH') { |
1043 | for my $k (sort keys %$_) { |
1044 | my $v = $_->{$k}; |
1045 | my $r = ref $v; |
1046 | my $label = $self->_quote($k); |
1047 | if ($r eq 'ARRAY') { |
fe3ae272 |
1048 | # literal SQL with bind |
1049 | my ($sql, @bind) = @$v; |
1050 | $self->_assert_bindval_matches_bindtype(@bind); |
96449e8e |
1051 | push @sqlq, "$label = $sql"; |
fe3ae272 |
1052 | push @sqlv, @bind; |
96449e8e |
1053 | } elsif ($r eq 'SCALAR') { |
fe3ae272 |
1054 | # literal SQL without bind |
96449e8e |
1055 | push @sqlq, "$label = $$v"; |
1056 | } else { |
1057 | push @sqlq, "$label = ?"; |
1058 | push @sqlv, $self->_bindtype($k, $v); |
1059 | } |
1060 | } |
1061 | push @sql, $self->_sqlcase('set'), join ', ', @sqlq; |
1062 | } elsif ($ref eq 'ARRAY') { |
1063 | # unlike insert(), assume these are ONLY the column names, i.e. for SQL |
1064 | for my $v (@$_) { |
1065 | my $r = ref $v; |
fe3ae272 |
1066 | if ($r eq 'ARRAY') { # literal SQL with bind |
1067 | my ($sql, @bind) = @$v; |
1068 | $self->_assert_bindval_matches_bindtype(@bind); |
1069 | push @sqlq, $sql; |
1070 | push @sqlv, @bind; |
1071 | } elsif ($r eq 'SCALAR') { # literal SQL without bind |
96449e8e |
1072 | # embedded literal SQL |
1073 | push @sqlq, $$v; |
1074 | } else { |
1075 | push @sqlq, '?'; |
1076 | push @sqlv, $v; |
1077 | } |
1078 | } |
1079 | push @sql, '(' . join(', ', @sqlq) . ')'; |
1080 | } elsif ($ref eq 'SCALAR') { |
1081 | # literal SQL |
1082 | push @sql, $$_; |
1083 | } else { |
1084 | # strings get case twiddled |
1085 | push @sql, $self->_sqlcase($_); |
1086 | } |
1087 | } |
1088 | |
1089 | my $sql = join ' ', @sql; |
1090 | |
1091 | # this is pretty tricky |
1092 | # if ask for an array, return ($stmt, @bind) |
1093 | # otherwise, s/?/shift @sqlv/ to put it inline |
1094 | if (wantarray) { |
1095 | return ($sql, @sqlv); |
1096 | } else { |
1097 | 1 while $sql =~ s/\?/my $d = shift(@sqlv); |
1098 | ref $d ? $d->[1] : $d/e; |
1099 | return $sql; |
1100 | } |
1101 | } |
1102 | |
1103 | |
1104 | sub DESTROY { 1 } |
1105 | |
1106 | sub AUTOLOAD { |
1107 | # This allows us to check for a local, then _form, attr |
1108 | my $self = shift; |
1109 | my($name) = $AUTOLOAD =~ /.*::(.+)/; |
1110 | return $self->generate($name, @_); |
1111 | } |
1112 | |
1113 | 1; |
1114 | |
1115 | |
1116 | |
1117 | __END__ |
32eab2da |
1118 | |
1119 | =head1 NAME |
1120 | |
1121 | SQL::Abstract - Generate SQL from Perl data structures |
1122 | |
1123 | =head1 SYNOPSIS |
1124 | |
1125 | use SQL::Abstract; |
1126 | |
1127 | my $sql = SQL::Abstract->new; |
1128 | |
1129 | my($stmt, @bind) = $sql->select($table, \@fields, \%where, \@order); |
1130 | |
1131 | my($stmt, @bind) = $sql->insert($table, \%fieldvals || \@values); |
1132 | |
1133 | my($stmt, @bind) = $sql->update($table, \%fieldvals, \%where); |
1134 | |
1135 | my($stmt, @bind) = $sql->delete($table, \%where); |
1136 | |
1137 | # Then, use these in your DBI statements |
1138 | my $sth = $dbh->prepare($stmt); |
1139 | $sth->execute(@bind); |
1140 | |
1141 | # Just generate the WHERE clause |
abe72f94 |
1142 | my($stmt, @bind) = $sql->where(\%where, \@order); |
32eab2da |
1143 | |
1144 | # Return values in the same order, for hashed queries |
1145 | # See PERFORMANCE section for more details |
1146 | my @bind = $sql->values(\%fieldvals); |
1147 | |
1148 | =head1 DESCRIPTION |
1149 | |
1150 | This module was inspired by the excellent L<DBIx::Abstract>. |
1151 | However, in using that module I found that what I really wanted |
1152 | to do was generate SQL, but still retain complete control over my |
1153 | statement handles and use the DBI interface. So, I set out to |
1154 | create an abstract SQL generation module. |
1155 | |
1156 | While based on the concepts used by L<DBIx::Abstract>, there are |
1157 | several important differences, especially when it comes to WHERE |
1158 | clauses. I have modified the concepts used to make the SQL easier |
1159 | to generate from Perl data structures and, IMO, more intuitive. |
1160 | The underlying idea is for this module to do what you mean, based |
1161 | on the data structures you provide it. The big advantage is that |
1162 | you don't have to modify your code every time your data changes, |
1163 | as this module figures it out. |
1164 | |
1165 | To begin with, an SQL INSERT is as easy as just specifying a hash |
1166 | of C<key=value> pairs: |
1167 | |
1168 | my %data = ( |
1169 | name => 'Jimbo Bobson', |
1170 | phone => '123-456-7890', |
1171 | address => '42 Sister Lane', |
1172 | city => 'St. Louis', |
1173 | state => 'Louisiana', |
1174 | ); |
1175 | |
1176 | The SQL can then be generated with this: |
1177 | |
1178 | my($stmt, @bind) = $sql->insert('people', \%data); |
1179 | |
1180 | Which would give you something like this: |
1181 | |
1182 | $stmt = "INSERT INTO people |
1183 | (address, city, name, phone, state) |
1184 | VALUES (?, ?, ?, ?, ?)"; |
1185 | @bind = ('42 Sister Lane', 'St. Louis', 'Jimbo Bobson', |
1186 | '123-456-7890', 'Louisiana'); |
1187 | |
1188 | These are then used directly in your DBI code: |
1189 | |
1190 | my $sth = $dbh->prepare($stmt); |
1191 | $sth->execute(@bind); |
1192 | |
96449e8e |
1193 | =head2 Inserting and Updating Arrays |
1194 | |
1195 | If your database has array types (like for example Postgres), |
1196 | activate the special option C<< array_datatypes => 1 >> |
1197 | when creating the C<SQL::Abstract> object. |
1198 | Then you may use an arrayref to insert and update database array types: |
1199 | |
1200 | my $sql = SQL::Abstract->new(array_datatypes => 1); |
1201 | my %data = ( |
1202 | planets => [qw/Mercury Venus Earth Mars/] |
1203 | ); |
1204 | |
1205 | my($stmt, @bind) = $sql->insert('solar_system', \%data); |
1206 | |
1207 | This results in: |
1208 | |
1209 | $stmt = "INSERT INTO solar_system (planets) VALUES (?)" |
1210 | |
1211 | @bind = (['Mercury', 'Venus', 'Earth', 'Mars']); |
1212 | |
1213 | |
1214 | =head2 Inserting and Updating SQL |
1215 | |
1216 | In order to apply SQL functions to elements of your C<%data> you may |
1217 | specify a reference to an arrayref for the given hash value. For example, |
1218 | if you need to execute the Oracle C<to_date> function on a value, you can |
1219 | say something like this: |
32eab2da |
1220 | |
1221 | my %data = ( |
1222 | name => 'Bill', |
96449e8e |
1223 | date_entered => \["to_date(?,'MM/DD/YYYY')", "03/02/2003"], |
32eab2da |
1224 | ); |
1225 | |
1226 | The first value in the array is the actual SQL. Any other values are |
1227 | optional and would be included in the bind values array. This gives |
1228 | you: |
1229 | |
1230 | my($stmt, @bind) = $sql->insert('people', \%data); |
1231 | |
1232 | $stmt = "INSERT INTO people (name, date_entered) |
1233 | VALUES (?, to_date(?,'MM/DD/YYYY'))"; |
1234 | @bind = ('Bill', '03/02/2003'); |
1235 | |
1236 | An UPDATE is just as easy, all you change is the name of the function: |
1237 | |
1238 | my($stmt, @bind) = $sql->update('people', \%data); |
1239 | |
1240 | Notice that your C<%data> isn't touched; the module will generate |
1241 | the appropriately quirky SQL for you automatically. Usually you'll |
1242 | want to specify a WHERE clause for your UPDATE, though, which is |
1243 | where handling C<%where> hashes comes in handy... |
1244 | |
96449e8e |
1245 | =head2 Complex where statements |
1246 | |
32eab2da |
1247 | This module can generate pretty complicated WHERE statements |
1248 | easily. For example, simple C<key=value> pairs are taken to mean |
1249 | equality, and if you want to see if a field is within a set |
1250 | of values, you can use an arrayref. Let's say we wanted to |
1251 | SELECT some data based on this criteria: |
1252 | |
1253 | my %where = ( |
1254 | requestor => 'inna', |
1255 | worker => ['nwiger', 'rcwe', 'sfz'], |
1256 | status => { '!=', 'completed' } |
1257 | ); |
1258 | |
1259 | my($stmt, @bind) = $sql->select('tickets', '*', \%where); |
1260 | |
1261 | The above would give you something like this: |
1262 | |
1263 | $stmt = "SELECT * FROM tickets WHERE |
1264 | ( requestor = ? ) AND ( status != ? ) |
1265 | AND ( worker = ? OR worker = ? OR worker = ? )"; |
1266 | @bind = ('inna', 'completed', 'nwiger', 'rcwe', 'sfz'); |
1267 | |
1268 | Which you could then use in DBI code like so: |
1269 | |
1270 | my $sth = $dbh->prepare($stmt); |
1271 | $sth->execute(@bind); |
1272 | |
1273 | Easy, eh? |
1274 | |
1275 | =head1 FUNCTIONS |
1276 | |
1277 | The functions are simple. There's one for each major SQL operation, |
1278 | and a constructor you use first. The arguments are specified in a |
1279 | similar order to each function (table, then fields, then a where |
1280 | clause) to try and simplify things. |
1281 | |
83cab70b |
1282 | |
83cab70b |
1283 | |
32eab2da |
1284 | |
1285 | =head2 new(option => 'value') |
1286 | |
1287 | The C<new()> function takes a list of options and values, and returns |
1288 | a new B<SQL::Abstract> object which can then be used to generate SQL |
1289 | through the methods below. The options accepted are: |
1290 | |
1291 | =over |
1292 | |
1293 | =item case |
1294 | |
1295 | If set to 'lower', then SQL will be generated in all lowercase. By |
1296 | default SQL is generated in "textbook" case meaning something like: |
1297 | |
1298 | SELECT a_field FROM a_table WHERE some_field LIKE '%someval%' |
1299 | |
96449e8e |
1300 | Any setting other than 'lower' is ignored. |
1301 | |
32eab2da |
1302 | =item cmp |
1303 | |
1304 | This determines what the default comparison operator is. By default |
1305 | it is C<=>, meaning that a hash like this: |
1306 | |
1307 | %where = (name => 'nwiger', email => 'nate@wiger.org'); |
1308 | |
1309 | Will generate SQL like this: |
1310 | |
1311 | WHERE name = 'nwiger' AND email = 'nate@wiger.org' |
1312 | |
1313 | However, you may want loose comparisons by default, so if you set |
1314 | C<cmp> to C<like> you would get SQL such as: |
1315 | |
1316 | WHERE name like 'nwiger' AND email like 'nate@wiger.org' |
1317 | |
1318 | You can also override the comparsion on an individual basis - see |
1319 | the huge section on L</"WHERE CLAUSES"> at the bottom. |
1320 | |
96449e8e |
1321 | =item sqltrue, sqlfalse |
1322 | |
1323 | Expressions for inserting boolean values within SQL statements. |
1324 | By default these are C<1=1> and C<1=0>. |
1325 | |
32eab2da |
1326 | =item logic |
1327 | |
1328 | This determines the default logical operator for multiple WHERE |
1329 | statements in arrays. By default it is "or", meaning that a WHERE |
1330 | array of the form: |
1331 | |
1332 | @where = ( |
1333 | event_date => {'>=', '2/13/99'}, |
1334 | event_date => {'<=', '4/24/03'}, |
1335 | ); |
1336 | |
1337 | Will generate SQL like this: |
1338 | |
1339 | WHERE event_date >= '2/13/99' OR event_date <= '4/24/03' |
1340 | |
1341 | This is probably not what you want given this query, though (look |
1342 | at the dates). To change the "OR" to an "AND", simply specify: |
1343 | |
1344 | my $sql = SQL::Abstract->new(logic => 'and'); |
1345 | |
1346 | Which will change the above C<WHERE> to: |
1347 | |
1348 | WHERE event_date >= '2/13/99' AND event_date <= '4/24/03' |
1349 | |
96449e8e |
1350 | The logic can also be changed locally by inserting |
1351 | an extra first element in the array : |
1352 | |
1353 | @where = (-and => event_date => {'>=', '2/13/99'}, |
1354 | event_date => {'<=', '4/24/03'} ); |
1355 | |
1356 | See the L</"WHERE CLAUSES"> section for explanations. |
1357 | |
32eab2da |
1358 | =item convert |
1359 | |
1360 | This will automatically convert comparisons using the specified SQL |
1361 | function for both column and value. This is mostly used with an argument |
1362 | of C<upper> or C<lower>, so that the SQL will have the effect of |
1363 | case-insensitive "searches". For example, this: |
1364 | |
1365 | $sql = SQL::Abstract->new(convert => 'upper'); |
1366 | %where = (keywords => 'MaKe iT CAse inSeNSItive'); |
1367 | |
1368 | Will turn out the following SQL: |
1369 | |
1370 | WHERE upper(keywords) like upper('MaKe iT CAse inSeNSItive') |
1371 | |
1372 | The conversion can be C<upper()>, C<lower()>, or any other SQL function |
1373 | that can be applied symmetrically to fields (actually B<SQL::Abstract> does |
1374 | not validate this option; it will just pass through what you specify verbatim). |
1375 | |
1376 | =item bindtype |
1377 | |
1378 | This is a kludge because many databases suck. For example, you can't |
1379 | just bind values using DBI's C<execute()> for Oracle C<CLOB> or C<BLOB> fields. |
1380 | Instead, you have to use C<bind_param()>: |
1381 | |
1382 | $sth->bind_param(1, 'reg data'); |
1383 | $sth->bind_param(2, $lots, {ora_type => ORA_CLOB}); |
1384 | |
1385 | The problem is, B<SQL::Abstract> will normally just return a C<@bind> array, |
1386 | which loses track of which field each slot refers to. Fear not. |
1387 | |
1388 | If you specify C<bindtype> in new, you can determine how C<@bind> is returned. |
1389 | Currently, you can specify either C<normal> (default) or C<columns>. If you |
1390 | specify C<columns>, you will get an array that looks like this: |
1391 | |
1392 | my $sql = SQL::Abstract->new(bindtype => 'columns'); |
1393 | my($stmt, @bind) = $sql->insert(...); |
1394 | |
1395 | @bind = ( |
1396 | [ 'column1', 'value1' ], |
1397 | [ 'column2', 'value2' ], |
1398 | [ 'column3', 'value3' ], |
1399 | ); |
1400 | |
1401 | You can then iterate through this manually, using DBI's C<bind_param()>. |
e3f9dff4 |
1402 | |
32eab2da |
1403 | $sth->prepare($stmt); |
1404 | my $i = 1; |
1405 | for (@bind) { |
1406 | my($col, $data) = @$_; |
1407 | if ($col eq 'details' || $col eq 'comments') { |
1408 | $sth->bind_param($i, $data, {ora_type => ORA_CLOB}); |
1409 | } elsif ($col eq 'image') { |
1410 | $sth->bind_param($i, $data, {ora_type => ORA_BLOB}); |
1411 | } else { |
1412 | $sth->bind_param($i, $data); |
1413 | } |
1414 | $i++; |
1415 | } |
1416 | $sth->execute; # execute without @bind now |
1417 | |
1418 | Now, why would you still use B<SQL::Abstract> if you have to do this crap? |
1419 | Basically, the advantage is still that you don't have to care which fields |
1420 | are or are not included. You could wrap that above C<for> loop in a simple |
1421 | sub called C<bind_fields()> or something and reuse it repeatedly. You still |
1422 | get a layer of abstraction over manual SQL specification. |
1423 | |
deb148a2 |
1424 | Note that if you set L</bindtype> to C<columns>, the C<\[$sql, @bind]> |
1425 | construct (see L</Literal SQL with placeholders and bind values (subqueries)>) |
1426 | will expect the bind values in this format. |
1427 | |
32eab2da |
1428 | =item quote_char |
1429 | |
1430 | This is the character that a table or column name will be quoted |
1431 | with. By default this is an empty string, but you could set it to |
1432 | the character C<`>, to generate SQL like this: |
1433 | |
1434 | SELECT `a_field` FROM `a_table` WHERE `some_field` LIKE '%someval%' |
1435 | |
96449e8e |
1436 | Alternatively, you can supply an array ref of two items, the first being the left |
1437 | hand quote character, and the second the right hand quote character. For |
1438 | example, you could supply C<['[',']']> for SQL Server 2000 compliant quotes |
1439 | that generates SQL like this: |
1440 | |
1441 | SELECT [a_field] FROM [a_table] WHERE [some_field] LIKE '%someval%' |
1442 | |
1443 | Quoting is useful if you have tables or columns names that are reserved |
1444 | words in your database's SQL dialect. |
32eab2da |
1445 | |
1446 | =item name_sep |
1447 | |
1448 | This is the character that separates a table and column name. It is |
1449 | necessary to specify this when the C<quote_char> option is selected, |
1450 | so that tables and column names can be individually quoted like this: |
1451 | |
1452 | SELECT `table`.`one_field` FROM `table` WHERE `table`.`other_field` = 1 |
1453 | |
96449e8e |
1454 | =item array_datatypes |
32eab2da |
1455 | |
96449e8e |
1456 | When this option is true, arrayrefs in INSERT or UPDATE are |
1457 | interpreted as array datatypes and are passed directly |
1458 | to the DBI layer. |
1459 | When this option is false, arrayrefs are interpreted |
1460 | as literal SQL, just like refs to arrayrefs |
1461 | (but this behavior is for backwards compatibility; when writing |
1462 | new queries, use the "reference to arrayref" syntax |
1463 | for literal SQL). |
32eab2da |
1464 | |
32eab2da |
1465 | |
96449e8e |
1466 | =item special_ops |
32eab2da |
1467 | |
96449e8e |
1468 | Takes a reference to a list of "special operators" |
1469 | to extend the syntax understood by L<SQL::Abstract>. |
1470 | See section L</"SPECIAL OPERATORS"> for details. |
32eab2da |
1471 | |
32eab2da |
1472 | |
32eab2da |
1473 | |
96449e8e |
1474 | =back |
32eab2da |
1475 | |
1476 | =head2 insert($table, \@values || \%fieldvals) |
1477 | |
1478 | This is the simplest function. You simply give it a table name |
1479 | and either an arrayref of values or hashref of field/value pairs. |
1480 | It returns an SQL INSERT statement and a list of bind values. |
96449e8e |
1481 | See the sections on L</"Inserting and Updating Arrays"> and |
1482 | L</"Inserting and Updating SQL"> for information on how to insert |
1483 | with those data types. |
32eab2da |
1484 | |
1485 | =head2 update($table, \%fieldvals, \%where) |
1486 | |
1487 | This takes a table, hashref of field/value pairs, and an optional |
86298391 |
1488 | hashref L<WHERE clause|/WHERE CLAUSES>. It returns an SQL UPDATE function and a list |
32eab2da |
1489 | of bind values. |
96449e8e |
1490 | See the sections on L</"Inserting and Updating Arrays"> and |
1491 | L</"Inserting and Updating SQL"> for information on how to insert |
1492 | with those data types. |
32eab2da |
1493 | |
96449e8e |
1494 | =head2 select($source, $fields, $where, $order) |
32eab2da |
1495 | |
96449e8e |
1496 | This returns a SQL SELECT statement and associated list of bind values, as |
1497 | specified by the arguments : |
32eab2da |
1498 | |
96449e8e |
1499 | =over |
32eab2da |
1500 | |
96449e8e |
1501 | =item $source |
32eab2da |
1502 | |
96449e8e |
1503 | Specification of the 'FROM' part of the statement. |
1504 | The argument can be either a plain scalar (interpreted as a table |
1505 | name, will be quoted), or an arrayref (interpreted as a list |
1506 | of table names, joined by commas, quoted), or a scalarref |
1507 | (literal table name, not quoted), or a ref to an arrayref |
1508 | (list of literal table names, joined by commas, not quoted). |
32eab2da |
1509 | |
96449e8e |
1510 | =item $fields |
32eab2da |
1511 | |
96449e8e |
1512 | Specification of the list of fields to retrieve from |
1513 | the source. |
1514 | The argument can be either an arrayref (interpreted as a list |
1515 | of field names, will be joined by commas and quoted), or a |
1516 | plain scalar (literal SQL, not quoted). |
1517 | Please observe that this API is not as flexible as for |
e3f9dff4 |
1518 | the first argument C<$table>, for backwards compatibility reasons. |
32eab2da |
1519 | |
96449e8e |
1520 | =item $where |
32eab2da |
1521 | |
96449e8e |
1522 | Optional argument to specify the WHERE part of the query. |
1523 | The argument is most often a hashref, but can also be |
1524 | an arrayref or plain scalar -- |
1525 | see section L<WHERE clause|/"WHERE CLAUSES"> for details. |
32eab2da |
1526 | |
96449e8e |
1527 | =item $order |
32eab2da |
1528 | |
96449e8e |
1529 | Optional argument to specify the ORDER BY part of the query. |
1530 | The argument can be a scalar, a hashref or an arrayref |
1531 | -- see section L<ORDER BY clause|/"ORDER BY CLAUSES"> |
1532 | for details. |
32eab2da |
1533 | |
96449e8e |
1534 | =back |
32eab2da |
1535 | |
32eab2da |
1536 | |
1537 | =head2 delete($table, \%where) |
1538 | |
86298391 |
1539 | This takes a table name and optional hashref L<WHERE clause|/WHERE CLAUSES>. |
32eab2da |
1540 | It returns an SQL DELETE statement and list of bind values. |
1541 | |
32eab2da |
1542 | =head2 where(\%where, \@order) |
1543 | |
1544 | This is used to generate just the WHERE clause. For example, |
1545 | if you have an arbitrary data structure and know what the |
1546 | rest of your SQL is going to look like, but want an easy way |
1547 | to produce a WHERE clause, use this. It returns an SQL WHERE |
1548 | clause and list of bind values. |
1549 | |
32eab2da |
1550 | |
1551 | =head2 values(\%data) |
1552 | |
1553 | This just returns the values from the hash C<%data>, in the same |
1554 | order that would be returned from any of the other above queries. |
1555 | Using this allows you to markedly speed up your queries if you |
1556 | are affecting lots of rows. See below under the L</"PERFORMANCE"> section. |
1557 | |
32eab2da |
1558 | =head2 generate($any, 'number', $of, \@data, $struct, \%types) |
1559 | |
1560 | Warning: This is an experimental method and subject to change. |
1561 | |
1562 | This returns arbitrarily generated SQL. It's a really basic shortcut. |
1563 | It will return two different things, depending on return context: |
1564 | |
1565 | my($stmt, @bind) = $sql->generate('create table', \$table, \@fields); |
1566 | my $stmt_and_val = $sql->generate('create table', \$table, \@fields); |
1567 | |
1568 | These would return the following: |
1569 | |
1570 | # First calling form |
1571 | $stmt = "CREATE TABLE test (?, ?)"; |
1572 | @bind = (field1, field2); |
1573 | |
1574 | # Second calling form |
1575 | $stmt_and_val = "CREATE TABLE test (field1, field2)"; |
1576 | |
1577 | Depending on what you're trying to do, it's up to you to choose the correct |
1578 | format. In this example, the second form is what you would want. |
1579 | |
1580 | By the same token: |
1581 | |
1582 | $sql->generate('alter session', { nls_date_format => 'MM/YY' }); |
1583 | |
1584 | Might give you: |
1585 | |
1586 | ALTER SESSION SET nls_date_format = 'MM/YY' |
1587 | |
1588 | You get the idea. Strings get their case twiddled, but everything |
1589 | else remains verbatim. |
1590 | |
32eab2da |
1591 | |
32eab2da |
1592 | |
32eab2da |
1593 | |
1594 | =head1 WHERE CLAUSES |
1595 | |
96449e8e |
1596 | =head2 Introduction |
1597 | |
32eab2da |
1598 | This module uses a variation on the idea from L<DBIx::Abstract>. It |
1599 | is B<NOT>, repeat I<not> 100% compatible. B<The main logic of this |
1600 | module is that things in arrays are OR'ed, and things in hashes |
1601 | are AND'ed.> |
1602 | |
1603 | The easiest way to explain is to show lots of examples. After |
1604 | each C<%where> hash shown, it is assumed you used: |
1605 | |
1606 | my($stmt, @bind) = $sql->where(\%where); |
1607 | |
1608 | However, note that the C<%where> hash can be used directly in any |
1609 | of the other functions as well, as described above. |
1610 | |
96449e8e |
1611 | =head2 Key-value pairs |
1612 | |
32eab2da |
1613 | So, let's get started. To begin, a simple hash: |
1614 | |
1615 | my %where = ( |
1616 | user => 'nwiger', |
1617 | status => 'completed' |
1618 | ); |
1619 | |
1620 | Is converted to SQL C<key = val> statements: |
1621 | |
1622 | $stmt = "WHERE user = ? AND status = ?"; |
1623 | @bind = ('nwiger', 'completed'); |
1624 | |
1625 | One common thing I end up doing is having a list of values that |
1626 | a field can be in. To do this, simply specify a list inside of |
1627 | an arrayref: |
1628 | |
1629 | my %where = ( |
1630 | user => 'nwiger', |
1631 | status => ['assigned', 'in-progress', 'pending']; |
1632 | ); |
1633 | |
1634 | This simple code will create the following: |
1635 | |
1636 | $stmt = "WHERE user = ? AND ( status = ? OR status = ? OR status = ? )"; |
1637 | @bind = ('nwiger', 'assigned', 'in-progress', 'pending'); |
1638 | |
96449e8e |
1639 | An empty arrayref will be considered a logical false and |
8a68b5be |
1640 | will generate 0=1. |
1641 | |
96449e8e |
1642 | =head2 Key-value pairs |
1643 | |
32eab2da |
1644 | If you want to specify a different type of operator for your comparison, |
1645 | you can use a hashref for a given column: |
1646 | |
1647 | my %where = ( |
1648 | user => 'nwiger', |
1649 | status => { '!=', 'completed' } |
1650 | ); |
1651 | |
1652 | Which would generate: |
1653 | |
1654 | $stmt = "WHERE user = ? AND status != ?"; |
1655 | @bind = ('nwiger', 'completed'); |
1656 | |
1657 | To test against multiple values, just enclose the values in an arrayref: |
1658 | |
1659 | status => { '!=', ['assigned', 'in-progress', 'pending'] }; |
1660 | |
1661 | Which would give you: |
1662 | |
96449e8e |
1663 | "WHERE status != ? AND status != ? AND status != ?" |
32eab2da |
1664 | |
96449e8e |
1665 | Notice that since the operator was recognized as being a 'negative' |
1666 | operator, the arrayref was interpreted with 'AND' logic (because |
1667 | of Morgan's laws). By contrast, the reverse |
1668 | |
1669 | status => { '=', ['assigned', 'in-progress', 'pending'] }; |
1670 | |
1671 | would generate : |
1672 | |
1673 | "WHERE status = ? OR status = ? OR status = ?" |
1674 | |
1675 | |
1676 | The hashref can also contain multiple pairs, in which case it is expanded |
32eab2da |
1677 | into an C<AND> of its elements: |
1678 | |
1679 | my %where = ( |
1680 | user => 'nwiger', |
1681 | status => { '!=', 'completed', -not_like => 'pending%' } |
1682 | ); |
1683 | |
1684 | # Or more dynamically, like from a form |
1685 | $where{user} = 'nwiger'; |
1686 | $where{status}{'!='} = 'completed'; |
1687 | $where{status}{'-not_like'} = 'pending%'; |
1688 | |
1689 | # Both generate this |
1690 | $stmt = "WHERE user = ? AND status != ? AND status NOT LIKE ?"; |
1691 | @bind = ('nwiger', 'completed', 'pending%'); |
1692 | |
96449e8e |
1693 | |
32eab2da |
1694 | To get an OR instead, you can combine it with the arrayref idea: |
1695 | |
1696 | my %where => ( |
1697 | user => 'nwiger', |
1698 | priority => [ {'=', 2}, {'!=', 1} ] |
1699 | ); |
1700 | |
1701 | Which would generate: |
1702 | |
1703 | $stmt = "WHERE user = ? AND priority = ? OR priority != ?"; |
1704 | @bind = ('nwiger', '2', '1'); |
1705 | |
44b9e502 |
1706 | If you want to include literal SQL (with or without bind values), just use a |
1707 | scalar reference or array reference as the value: |
1708 | |
1709 | my %where = ( |
1710 | date_entered => { '>' => \["to_date(?, 'MM/DD/YYYY')", "11/26/2008"] }, |
1711 | date_expires => { '<' => \"now()" } |
1712 | ); |
1713 | |
1714 | Which would generate: |
1715 | |
1716 | $stmt = "WHERE date_entered > "to_date(?, 'MM/DD/YYYY') AND date_expires < now()"; |
1717 | @bind = ('11/26/2008'); |
1718 | |
96449e8e |
1719 | |
1720 | =head2 Logic and nesting operators |
1721 | |
1722 | In the example above, |
1723 | there is a subtle trap if you want to say something like |
32eab2da |
1724 | this (notice the C<AND>): |
1725 | |
1726 | WHERE priority != ? AND priority != ? |
1727 | |
1728 | Because, in Perl you I<can't> do this: |
1729 | |
1730 | priority => { '!=', 2, '!=', 1 } |
1731 | |
1732 | As the second C<!=> key will obliterate the first. The solution |
1733 | is to use the special C<-modifier> form inside an arrayref: |
1734 | |
96449e8e |
1735 | priority => [ -and => {'!=', 2}, |
1736 | {'!=', 1} ] |
1737 | |
32eab2da |
1738 | |
1739 | Normally, these would be joined by C<OR>, but the modifier tells it |
1740 | to use C<AND> instead. (Hint: You can use this in conjunction with the |
1741 | C<logic> option to C<new()> in order to change the way your queries |
1742 | work by default.) B<Important:> Note that the C<-modifier> goes |
1743 | B<INSIDE> the arrayref, as an extra first element. This will |
1744 | B<NOT> do what you think it might: |
1745 | |
1746 | priority => -and => [{'!=', 2}, {'!=', 1}] # WRONG! |
1747 | |
1748 | Here is a quick list of equivalencies, since there is some overlap: |
1749 | |
1750 | # Same |
1751 | status => {'!=', 'completed', 'not like', 'pending%' } |
1752 | status => [ -and => {'!=', 'completed'}, {'not like', 'pending%'}] |
1753 | |
1754 | # Same |
1755 | status => {'=', ['assigned', 'in-progress']} |
1756 | status => [ -or => {'=', 'assigned'}, {'=', 'in-progress'}] |
1757 | status => [ {'=', 'assigned'}, {'=', 'in-progress'} ] |
1758 | |
1759 | In addition to C<-and> and C<-or>, there is also a special C<-nest> |
1760 | operator which adds an additional set of parens, to create a subquery. |
1761 | For example, to get something like this: |
1762 | |
86298391 |
1763 | $stmt = "WHERE user = ? AND ( workhrs > ? OR geo = ? )"; |
32eab2da |
1764 | @bind = ('nwiger', '20', 'ASIA'); |
1765 | |
1766 | You would do: |
1767 | |
1768 | my %where = ( |
1769 | user => 'nwiger', |
1770 | -nest => [ workhrs => {'>', 20}, geo => 'ASIA' ], |
1771 | ); |
1772 | |
e3f9dff4 |
1773 | If you need several nested subexpressions, you can number |
1774 | the C<-nest> branches : |
1775 | |
1776 | my %where = ( |
1777 | user => 'nwiger', |
1778 | -nest1 => ..., |
1779 | -nest2 => ..., |
1780 | ... |
1781 | ); |
1782 | |
1783 | |
96449e8e |
1784 | =head2 Special operators : IN, BETWEEN, etc. |
1785 | |
32eab2da |
1786 | You can also use the hashref format to compare a list of fields using the |
1787 | C<IN> comparison operator, by specifying the list as an arrayref: |
1788 | |
1789 | my %where = ( |
1790 | status => 'completed', |
1791 | reportid => { -in => [567, 2335, 2] } |
1792 | ); |
1793 | |
1794 | Which would generate: |
1795 | |
1796 | $stmt = "WHERE status = ? AND reportid IN (?,?,?)"; |
1797 | @bind = ('completed', '567', '2335', '2'); |
1798 | |
96449e8e |
1799 | The reverse operator C<-not_in> generates SQL C<NOT IN> and is used in |
1800 | the same way. |
1801 | |
1802 | Another pair of operators is C<-between> and C<-not_between>, |
1803 | used with an arrayref of two values: |
32eab2da |
1804 | |
1805 | my %where = ( |
1806 | user => 'nwiger', |
1807 | completion_date => { |
1808 | -not_between => ['2002-10-01', '2003-02-06'] |
1809 | } |
1810 | ); |
1811 | |
1812 | Would give you: |
1813 | |
1814 | WHERE user = ? AND completion_date NOT BETWEEN ( ? AND ? ) |
1815 | |
96449e8e |
1816 | These are the two builtin "special operators"; but the |
1817 | list can be expanded : see section L</"SPECIAL OPERATORS"> below. |
1818 | |
1819 | =head2 Nested conditions |
1820 | |
32eab2da |
1821 | So far, we've seen how multiple conditions are joined with a top-level |
1822 | C<AND>. We can change this by putting the different conditions we want in |
1823 | hashes and then putting those hashes in an array. For example: |
1824 | |
1825 | my @where = ( |
1826 | { |
1827 | user => 'nwiger', |
1828 | status => { -like => ['pending%', 'dispatched'] }, |
1829 | }, |
1830 | { |
1831 | user => 'robot', |
1832 | status => 'unassigned', |
1833 | } |
1834 | ); |
1835 | |
1836 | This data structure would create the following: |
1837 | |
1838 | $stmt = "WHERE ( user = ? AND ( status LIKE ? OR status LIKE ? ) ) |
1839 | OR ( user = ? AND status = ? ) )"; |
1840 | @bind = ('nwiger', 'pending', 'dispatched', 'robot', 'unassigned'); |
1841 | |
1842 | This can be combined with the C<-nest> operator to properly group |
1843 | SQL statements: |
1844 | |
1845 | my @where = ( |
1846 | -and => [ |
1847 | user => 'nwiger', |
1848 | -nest => [ |
d2a8fe1a |
1849 | ["-and", workhrs => {'>', 20}, geo => 'ASIA' ], |
1850 | ["-and", workhrs => {'<', 50}, geo => 'EURO' ] |
32eab2da |
1851 | ], |
1852 | ], |
1853 | ); |
1854 | |
1855 | That would yield: |
1856 | |
1857 | WHERE ( user = ? AND |
1858 | ( ( workhrs > ? AND geo = ? ) |
1859 | OR ( workhrs < ? AND geo = ? ) ) ) |
1860 | |
96449e8e |
1861 | =head2 Literal SQL |
1862 | |
32eab2da |
1863 | Finally, sometimes only literal SQL will do. If you want to include |
1864 | literal SQL verbatim, you can specify it as a scalar reference, namely: |
1865 | |
1866 | my $inn = 'is Not Null'; |
1867 | my %where = ( |
1868 | priority => { '<', 2 }, |
1869 | requestor => \$inn |
1870 | ); |
1871 | |
1872 | This would create: |
1873 | |
1874 | $stmt = "WHERE priority < ? AND requestor is Not Null"; |
1875 | @bind = ('2'); |
1876 | |
1877 | Note that in this example, you only get one bind parameter back, since |
1878 | the verbatim SQL is passed as part of the statement. |
1879 | |
1880 | Of course, just to prove a point, the above can also be accomplished |
1881 | with this: |
1882 | |
1883 | my %where = ( |
1884 | priority => { '<', 2 }, |
1885 | requestor => { '!=', undef }, |
1886 | ); |
1887 | |
96449e8e |
1888 | |
32eab2da |
1889 | TMTOWTDI. |
1890 | |
96449e8e |
1891 | Conditions on boolean columns can be expressed in the |
1892 | same way, passing a reference to an empty string : |
1893 | |
1894 | my %where = ( |
1895 | priority => { '<', 2 }, |
1896 | is_ready => \""; |
1897 | ); |
1898 | |
1899 | which yields |
1900 | |
1901 | $stmt = "WHERE priority < ? AND is_ready"; |
1902 | @bind = ('2'); |
1903 | |
1904 | |
1905 | =head2 Literal SQL with placeholders and bind values (subqueries) |
1906 | |
1907 | If the literal SQL to be inserted has placeholders and bind values, |
1908 | use a reference to an arrayref (yes this is a double reference -- |
1909 | not so common, but perfectly legal Perl). For example, to find a date |
1910 | in Postgres you can use something like this: |
1911 | |
1912 | my %where = ( |
1913 | date_column => \[q/= date '2008-09-30' - ?::integer/, 10/] |
1914 | ) |
1915 | |
1916 | This would create: |
1917 | |
d2a8fe1a |
1918 | $stmt = "WHERE ( date_column = date '2008-09-30' - ?::integer )" |
96449e8e |
1919 | @bind = ('10'); |
1920 | |
deb148a2 |
1921 | Note that you must pass the bind values in the same format as they are returned |
1922 | by C</where>. That means that if you set L</bindtype> to C<columns>, you must |
26f2dca5 |
1923 | provide the bind values in the C<< [ column_meta => value ] >> format, where |
1924 | C<column_meta> is an opaque scalar value; most commonly the column name, but |
1925 | you can use any scalar scalar value (including references and blessed |
1926 | references), L<SQL::Abstract> will simply pass it through intact. So eg. the |
1927 | above example will look like: |
deb148a2 |
1928 | |
1929 | my %where = ( |
1930 | date_column => \[q/= date '2008-09-30' - ?::integer/, [ dummy => 10 ]/] |
1931 | ) |
96449e8e |
1932 | |
1933 | Literal SQL is especially useful for nesting parenthesized clauses in the |
1934 | main SQL query. Here is a first example : |
1935 | |
1936 | my ($sub_stmt, @sub_bind) = ("SELECT c1 FROM t1 WHERE c2 < ? AND c3 LIKE ?", |
1937 | 100, "foo%"); |
1938 | my %where = ( |
1939 | foo => 1234, |
1940 | bar => \["IN ($sub_stmt)" => @sub_bind], |
1941 | ); |
1942 | |
1943 | This yields : |
1944 | |
1945 | $stmt = "WHERE (foo = ? AND bar IN (SELECT c1 FROM t1 |
1946 | WHERE c2 < ? AND c3 LIKE ?))"; |
1947 | @bind = (1234, 100, "foo%"); |
1948 | |
1949 | Other subquery operators, like for example C<"E<gt> ALL"> or C<"NOT IN">, |
1950 | are expressed in the same way. Of course the C<$sub_stmt> and |
1951 | its associated bind values can be generated through a former call |
1952 | to C<select()> : |
1953 | |
1954 | my ($sub_stmt, @sub_bind) |
1955 | = $sql->select("t1", "c1", {c2 => {"<" => 100}, |
1956 | c3 => {-like => "foo%"}}); |
1957 | my %where = ( |
1958 | foo => 1234, |
1959 | bar => \["> ALL ($sub_stmt)" => @sub_bind], |
1960 | ); |
1961 | |
1962 | In the examples above, the subquery was used as an operator on a column; |
1963 | but the same principle also applies for a clause within the main C<%where> |
1964 | hash, like an EXISTS subquery : |
1965 | |
1966 | my ($sub_stmt, @sub_bind) |
1967 | = $sql->select("t1", "*", {c1 => 1, c2 => \"> t0.c0"}); |
1968 | my %where = ( |
1969 | foo => 1234, |
1970 | -nest => \["EXISTS ($sub_stmt)" => @sub_bind], |
1971 | ); |
1972 | |
1973 | which yields |
1974 | |
1975 | $stmt = "WHERE (foo = ? AND EXISTS (SELECT * FROM t1 |
1976 | WHERE c1 = ? AND c2 > t0.c0))"; |
1977 | @bind = (1234, 1); |
1978 | |
1979 | |
1980 | Observe that the condition on C<c2> in the subquery refers to |
1981 | column C<t0.c0> of the main query : this is I<not> a bind |
1982 | value, so we have to express it through a scalar ref. |
1983 | Writing C<< c2 => {">" => "t0.c0"} >> would have generated |
1984 | C<< c2 > ? >> with bind value C<"t0.c0"> ... not exactly |
1985 | what we wanted here. |
1986 | |
1987 | Another use of the subquery technique is when some SQL clauses need |
1988 | parentheses, as it often occurs with some proprietary SQL extensions |
1989 | like for example fulltext expressions, geospatial expressions, |
1990 | NATIVE clauses, etc. Here is an example of a fulltext query in MySQL : |
1991 | |
1992 | my %where = ( |
1993 | -nest => \["MATCH (col1, col2) AGAINST (?)" => qw/apples/] |
1994 | ); |
1995 | |
1996 | Finally, here is an example where a subquery is used |
1997 | for expressing unary negation: |
1998 | |
1999 | my ($sub_stmt, @sub_bind) |
2000 | = $sql->where({age => [{"<" => 10}, {">" => 20}]}); |
2001 | $sub_stmt =~ s/^ where //i; # don't want "WHERE" in the subclause |
2002 | my %where = ( |
2003 | lname => {like => '%son%'}, |
2004 | -nest => \["NOT ($sub_stmt)" => @sub_bind], |
2005 | ); |
2006 | |
2007 | This yields |
2008 | |
2009 | $stmt = "lname LIKE ? AND NOT ( age < ? OR age > ? )" |
2010 | @bind = ('%son%', 10, 20) |
2011 | |
2012 | |
2013 | |
2014 | =head2 Conclusion |
2015 | |
32eab2da |
2016 | These pages could go on for a while, since the nesting of the data |
2017 | structures this module can handle are pretty much unlimited (the |
2018 | module implements the C<WHERE> expansion as a recursive function |
2019 | internally). Your best bet is to "play around" with the module a |
2020 | little to see how the data structures behave, and choose the best |
2021 | format for your data based on that. |
2022 | |
2023 | And of course, all the values above will probably be replaced with |
2024 | variables gotten from forms or the command line. After all, if you |
2025 | knew everything ahead of time, you wouldn't have to worry about |
2026 | dynamically-generating SQL and could just hardwire it into your |
2027 | script. |
2028 | |
96449e8e |
2029 | |
2030 | |
2031 | |
86298391 |
2032 | =head1 ORDER BY CLAUSES |
2033 | |
2034 | Some functions take an order by clause. This can either be a scalar (just a |
2035 | column name,) a hash of C<< { -desc => 'col' } >> or C<< { -asc => 'col' } >>, |
1cfa1db3 |
2036 | or an array of either of the two previous forms. Examples: |
2037 | |
2038 | Given | Will Generate |
2039 | ---------------------------------------------------------- |
2040 | \'colA DESC' | ORDER BY colA DESC |
2041 | 'colA' | ORDER BY colA |
2042 | [qw/colA colB/] | ORDER BY colA, colB |
2043 | {-asc => 'colA'} | ORDER BY colA ASC |
2044 | {-desc => 'colB'} | ORDER BY colB DESC |
2045 | [ | |
2046 | {-asc => 'colA'}, | ORDER BY colA ASC, colB DESC |
2047 | {-desc => 'colB'} | |
2048 | ] | |
2049 | [colA => {-asc => 'colB'}] | ORDER BY colA, colB ASC |
2050 | ========================================================== |
86298391 |
2051 | |
96449e8e |
2052 | |
2053 | |
2054 | =head1 SPECIAL OPERATORS |
2055 | |
e3f9dff4 |
2056 | my $sqlmaker = SQL::Abstract->new(special_ops => [ |
2057 | {regex => qr/.../, |
2058 | handler => sub { |
2059 | my ($self, $field, $op, $arg) = @_; |
2060 | ... |
2061 | }, |
2062 | }, |
2063 | ]); |
2064 | |
2065 | A "special operator" is a SQL syntactic clause that can be |
2066 | applied to a field, instead of a usual binary operator. |
2067 | For example : |
2068 | |
2069 | WHERE field IN (?, ?, ?) |
2070 | WHERE field BETWEEN ? AND ? |
2071 | WHERE MATCH(field) AGAINST (?, ?) |
96449e8e |
2072 | |
e3f9dff4 |
2073 | Special operators IN and BETWEEN are fairly standard and therefore |
2074 | are builtin within C<SQL::Abstract>. For other operators, |
2075 | like the MATCH .. AGAINST example above which is |
2076 | specific to MySQL, you can write your own operator handlers : |
2077 | supply a C<special_ops> argument to the C<new> method. |
2078 | That argument takes an arrayref of operator definitions; |
2079 | each operator definition is a hashref with two entries |
96449e8e |
2080 | |
e3f9dff4 |
2081 | =over |
2082 | |
2083 | =item regex |
2084 | |
2085 | the regular expression to match the operator |
96449e8e |
2086 | |
e3f9dff4 |
2087 | =item handler |
2088 | |
2089 | coderef that will be called when meeting that operator |
2090 | in the input tree. The coderef will be called with |
2091 | arguments C<< ($self, $field, $op, $arg) >>, and |
2092 | should return a C<< ($sql, @bind) >> structure. |
2093 | |
2094 | =back |
2095 | |
2096 | For example, here is an implementation |
2097 | of the MATCH .. AGAINST syntax for MySQL |
2098 | |
2099 | my $sqlmaker = SQL::Abstract->new(special_ops => [ |
2100 | |
2101 | # special op for MySql MATCH (field) AGAINST(word1, word2, ...) |
2102 | {regex => qr/^match$/i, |
2103 | handler => sub { |
2104 | my ($self, $field, $op, $arg) = @_; |
2105 | $arg = [$arg] if not ref $arg; |
2106 | my $label = $self->_quote($field); |
2107 | my ($placeholder) = $self->_convert('?'); |
2108 | my $placeholders = join ", ", (($placeholder) x @$arg); |
2109 | my $sql = $self->_sqlcase('match') . " ($label) " |
2110 | . $self->_sqlcase('against') . " ($placeholders) "; |
2111 | my @bind = $self->_bindtype($field, @$arg); |
2112 | return ($sql, @bind); |
2113 | } |
2114 | }, |
2115 | |
2116 | ]); |
96449e8e |
2117 | |
2118 | |
32eab2da |
2119 | =head1 PERFORMANCE |
2120 | |
2121 | Thanks to some benchmarking by Mark Stosberg, it turns out that |
2122 | this module is many orders of magnitude faster than using C<DBIx::Abstract>. |
2123 | I must admit this wasn't an intentional design issue, but it's a |
2124 | byproduct of the fact that you get to control your C<DBI> handles |
2125 | yourself. |
2126 | |
2127 | To maximize performance, use a code snippet like the following: |
2128 | |
2129 | # prepare a statement handle using the first row |
2130 | # and then reuse it for the rest of the rows |
2131 | my($sth, $stmt); |
2132 | for my $href (@array_of_hashrefs) { |
2133 | $stmt ||= $sql->insert('table', $href); |
2134 | $sth ||= $dbh->prepare($stmt); |
2135 | $sth->execute($sql->values($href)); |
2136 | } |
2137 | |
2138 | The reason this works is because the keys in your C<$href> are sorted |
2139 | internally by B<SQL::Abstract>. Thus, as long as your data retains |
2140 | the same structure, you only have to generate the SQL the first time |
2141 | around. On subsequent queries, simply use the C<values> function provided |
2142 | by this module to return your values in the correct order. |
2143 | |
96449e8e |
2144 | |
32eab2da |
2145 | =head1 FORMBUILDER |
2146 | |
2147 | If you use my C<CGI::FormBuilder> module at all, you'll hopefully |
2148 | really like this part (I do, at least). Building up a complex query |
2149 | can be as simple as the following: |
2150 | |
2151 | #!/usr/bin/perl |
2152 | |
2153 | use CGI::FormBuilder; |
2154 | use SQL::Abstract; |
2155 | |
2156 | my $form = CGI::FormBuilder->new(...); |
2157 | my $sql = SQL::Abstract->new; |
2158 | |
2159 | if ($form->submitted) { |
2160 | my $field = $form->field; |
2161 | my $id = delete $field->{id}; |
2162 | my($stmt, @bind) = $sql->update('table', $field, {id => $id}); |
2163 | } |
2164 | |
2165 | Of course, you would still have to connect using C<DBI> to run the |
2166 | query, but the point is that if you make your form look like your |
2167 | table, the actual query script can be extremely simplistic. |
2168 | |
2169 | If you're B<REALLY> lazy (I am), check out C<HTML::QuickTable> for |
2170 | a fast interface to returning and formatting data. I frequently |
2171 | use these three modules together to write complex database query |
2172 | apps in under 50 lines. |
2173 | |
32eab2da |
2174 | |
96449e8e |
2175 | =head1 CHANGES |
2176 | |
2177 | Version 1.50 was a major internal refactoring of C<SQL::Abstract>. |
2178 | Great care has been taken to preserve the I<published> behavior |
2179 | documented in previous versions in the 1.* family; however, |
2180 | some features that were previously undocumented, or behaved |
2181 | differently from the documentation, had to be changed in order |
2182 | to clarify the semantics. Hence, client code that was relying |
2183 | on some dark areas of C<SQL::Abstract> v1.* |
2184 | B<might behave differently> in v1.50. |
32eab2da |
2185 | |
d2a8fe1a |
2186 | The main changes are : |
2187 | |
96449e8e |
2188 | =over |
32eab2da |
2189 | |
96449e8e |
2190 | =item * |
32eab2da |
2191 | |
96449e8e |
2192 | support for literal SQL through the C<< \ [$sql, bind] >> syntax. |
2193 | |
2194 | =item * |
2195 | |
145fbfc8 |
2196 | support for the { operator => \"..." } construct (to embed literal SQL) |
2197 | |
2198 | =item * |
2199 | |
9c37b9c0 |
2200 | support for the { operator => \["...", @bind] } construct (to embed literal SQL with bind values) |
2201 | |
2202 | =item * |
2203 | |
96449e8e |
2204 | added -nest1, -nest2 or -nest_1, -nest_2, ... |
2205 | |
2206 | =item * |
2207 | |
2208 | optional support for L<array datatypes|/"Inserting and Updating Arrays"> |
2209 | |
2210 | =item * |
2211 | |
2212 | defensive programming : check arguments |
2213 | |
2214 | =item * |
2215 | |
2216 | fixed bug with global logic, which was previously implemented |
2217 | through global variables yielding side-effects. Prior versons would |
2218 | interpret C<< [ {cond1, cond2}, [cond3, cond4] ] >> |
2219 | as C<< "(cond1 AND cond2) OR (cond3 AND cond4)" >>. |
2220 | Now this is interpreted |
2221 | as C<< "(cond1 AND cond2) OR (cond3 OR cond4)" >>. |
2222 | |
2223 | =item * |
2224 | |
2225 | C<-and> / C<-or> operators are no longer accepted |
2226 | in the middle of an arrayref : they are |
2227 | only admitted if in first position. |
2228 | |
2229 | =item * |
2230 | |
2231 | changed logic for distributing an op over arrayrefs |
2232 | |
2233 | =item * |
2234 | |
2235 | fixed semantics of _bindtype on array args |
2236 | |
2237 | =item * |
2238 | |
2239 | dropped the C<_anoncopy> of the %where tree. No longer necessary, |
2240 | we just avoid shifting arrays within that tree. |
2241 | |
2242 | =item * |
2243 | |
2244 | dropped the C<_modlogic> function |
2245 | |
2246 | =back |
32eab2da |
2247 | |
32eab2da |
2248 | |
32eab2da |
2249 | |
2250 | =head1 ACKNOWLEDGEMENTS |
2251 | |
2252 | There are a number of individuals that have really helped out with |
2253 | this module. Unfortunately, most of them submitted bugs via CPAN |
2254 | so I have no idea who they are! But the people I do know are: |
2255 | |
86298391 |
2256 | Ash Berlin (order_by hash term support) |
b643abe1 |
2257 | Matt Trout (DBIx::Class support) |
32eab2da |
2258 | Mark Stosberg (benchmarking) |
2259 | Chas Owens (initial "IN" operator support) |
2260 | Philip Collins (per-field SQL functions) |
2261 | Eric Kolve (hashref "AND" support) |
2262 | Mike Fragassi (enhancements to "BETWEEN" and "LIKE") |
2263 | Dan Kubb (support for "quote_char" and "name_sep") |
f5aab26e |
2264 | Guillermo Roditi (patch to cleanup "IN" and "BETWEEN", fix and tests for _order_by) |
96449e8e |
2265 | Laurent Dami (internal refactoring, multiple -nest, extensible list of special operators, literal SQL) |
dbdf7648 |
2266 | Norbert Buchmuller (support for literal SQL in hashpair, misc. fixes & tests) |
32eab2da |
2267 | |
2268 | Thanks! |
2269 | |
32eab2da |
2270 | =head1 SEE ALSO |
2271 | |
86298391 |
2272 | L<DBIx::Class>, L<DBIx::Abstract>, L<CGI::FormBuilder>, L<HTML::QuickTable>. |
32eab2da |
2273 | |
32eab2da |
2274 | =head1 AUTHOR |
2275 | |
b643abe1 |
2276 | Copyright (c) 2001-2007 Nathan Wiger <nwiger@cpan.org>. All Rights Reserved. |
2277 | |
2278 | This module is actively maintained by Matt Trout <mst@shadowcatsystems.co.uk> |
32eab2da |
2279 | |
abe72f94 |
2280 | For support, your best bet is to try the C<DBIx::Class> users mailing list. |
2281 | While not an official support venue, C<DBIx::Class> makes heavy use of |
2282 | C<SQL::Abstract>, and as such list members there are very familiar with |
2283 | how to create queries. |
2284 | |
32eab2da |
2285 | This module is free software; you may copy this under the terms of |
2286 | the GNU General Public License, or the Artistic License, copies of |
2287 | which should have accompanied your Perl kit. |
2288 | |
2289 | =cut |
2290 | |