]> git.saurik.com Git - apple/security.git/blob - SecurityTests/regressions/inc/Test/More.pm
Security-57031.1.35.tar.gz
[apple/security.git] / SecurityTests / regressions / inc / Test / More.pm
1 package Test::More;
2
3 use 5.006;
4 use strict;
5
6
7 # Can't use Carp because it might cause use_ok() to accidentally succeed
8 # even though the module being used forgot to use Carp. Yes, this
9 # actually happened.
10 sub _carp {
11 my($file, $line) = (caller(1))[1,2];
12 warn @_, " at $file line $line\n";
13 }
14
15
16
17 use vars qw($VERSION @ISA @EXPORT %EXPORT_TAGS $TODO);
18 $VERSION = '0.80';
19 $VERSION = eval $VERSION; # make the alpha version come out as a number
20
21 use Test::Builder::Module;
22 @ISA = qw(Test::Builder::Module);
23 @EXPORT = qw(ok use_ok require_ok
24 is isnt like unlike is_deeply
25 cmp_ok
26 skip todo todo_skip
27 pass fail
28 eq_array eq_hash eq_set
29 $TODO
30 plan
31 can_ok isa_ok
32 diag
33 BAIL_OUT
34 );
35
36
37 =head1 NAME
38
39 Test::More - yet another framework for writing test scripts
40
41 =head1 SYNOPSIS
42
43 use Test::More tests => 23;
44 # or
45 use Test::More qw(no_plan);
46 # or
47 use Test::More skip_all => $reason;
48
49 BEGIN { use_ok( 'Some::Module' ); }
50 require_ok( 'Some::Module' );
51
52 # Various ways to say "ok"
53 ok($got eq $expected, $test_name);
54
55 is ($got, $expected, $test_name);
56 isnt($got, $expected, $test_name);
57
58 # Rather than print STDERR "# here's what went wrong\n"
59 diag("here's what went wrong");
60
61 like ($got, qr/expected/, $test_name);
62 unlike($got, qr/expected/, $test_name);
63
64 cmp_ok($got, '==', $expected, $test_name);
65
66 is_deeply($got_complex_structure, $expected_complex_structure, $test_name);
67
68 SKIP: {
69 skip $why, $how_many unless $have_some_feature;
70
71 ok( foo(), $test_name );
72 is( foo(42), 23, $test_name );
73 };
74
75 TODO: {
76 local $TODO = $why;
77
78 ok( foo(), $test_name );
79 is( foo(42), 23, $test_name );
80 };
81
82 can_ok($module, @methods);
83 isa_ok($object, $class);
84
85 pass($test_name);
86 fail($test_name);
87
88 BAIL_OUT($why);
89
90 # UNIMPLEMENTED!!!
91 my @status = Test::More::status;
92
93
94 =head1 DESCRIPTION
95
96 B<STOP!> If you're just getting started writing tests, have a look at
97 Test::Simple first. This is a drop in replacement for Test::Simple
98 which you can switch to once you get the hang of basic testing.
99
100 The purpose of this module is to provide a wide range of testing
101 utilities. Various ways to say "ok" with better diagnostics,
102 facilities to skip tests, test future features and compare complicated
103 data structures. While you can do almost anything with a simple
104 C<ok()> function, it doesn't provide good diagnostic output.
105
106
107 =head2 I love it when a plan comes together
108
109 Before anything else, you need a testing plan. This basically declares
110 how many tests your script is going to run to protect against premature
111 failure.
112
113 The preferred way to do this is to declare a plan when you C<use Test::More>.
114
115 use Test::More tests => 23;
116
117 There are rare cases when you will not know beforehand how many tests
118 your script is going to run. In this case, you can declare that you
119 have no plan. (Try to avoid using this as it weakens your test.)
120
121 use Test::More qw(no_plan);
122
123 B<NOTE>: using no_plan requires a Test::Harness upgrade else it will
124 think everything has failed. See L<CAVEATS and NOTES>).
125
126 In some cases, you'll want to completely skip an entire testing script.
127
128 use Test::More skip_all => $skip_reason;
129
130 Your script will declare a skip with the reason why you skipped and
131 exit immediately with a zero (success). See L<Test::Harness> for
132 details.
133
134 If you want to control what functions Test::More will export, you
135 have to use the 'import' option. For example, to import everything
136 but 'fail', you'd do:
137
138 use Test::More tests => 23, import => ['!fail'];
139
140 Alternatively, you can use the plan() function. Useful for when you
141 have to calculate the number of tests.
142
143 use Test::More;
144 plan tests => keys %Stuff * 3;
145
146 or for deciding between running the tests at all:
147
148 use Test::More;
149 if( $^O eq 'MacOS' ) {
150 plan skip_all => 'Test irrelevant on MacOS';
151 }
152 else {
153 plan tests => 42;
154 }
155
156 =cut
157
158 sub plan {
159 my $tb = Test::More->builder;
160
161 $tb->plan(@_);
162 }
163
164
165 # This implements "use Test::More 'no_diag'" but the behavior is
166 # deprecated.
167 sub import_extra {
168 my $class = shift;
169 my $list = shift;
170
171 my @other = ();
172 my $idx = 0;
173 while( $idx <= $#{$list} ) {
174 my $item = $list->[$idx];
175
176 if( defined $item and $item eq 'no_diag' ) {
177 $class->builder->no_diag(1);
178 }
179 else {
180 push @other, $item;
181 }
182
183 $idx++;
184 }
185
186 @$list = @other;
187 }
188
189
190 =head2 Test names
191
192 By convention, each test is assigned a number in order. This is
193 largely done automatically for you. However, it's often very useful to
194 assign a name to each test. Which would you rather see:
195
196 ok 4
197 not ok 5
198 ok 6
199
200 or
201
202 ok 4 - basic multi-variable
203 not ok 5 - simple exponential
204 ok 6 - force == mass * acceleration
205
206 The later gives you some idea of what failed. It also makes it easier
207 to find the test in your script, simply search for "simple
208 exponential".
209
210 All test functions take a name argument. It's optional, but highly
211 suggested that you use it.
212
213
214 =head2 I'm ok, you're not ok.
215
216 The basic purpose of this module is to print out either "ok #" or "not
217 ok #" depending on if a given test succeeded or failed. Everything
218 else is just gravy.
219
220 All of the following print "ok" or "not ok" depending on if the test
221 succeeded or failed. They all also return true or false,
222 respectively.
223
224 =over 4
225
226 =item B<ok>
227
228 ok($got eq $expected, $test_name);
229
230 This simply evaluates any expression (C<$got eq $expected> is just a
231 simple example) and uses that to determine if the test succeeded or
232 failed. A true expression passes, a false one fails. Very simple.
233
234 For example:
235
236 ok( $exp{9} == 81, 'simple exponential' );
237 ok( Film->can('db_Main'), 'set_db()' );
238 ok( $p->tests == 4, 'saw tests' );
239 ok( !grep !defined $_, @items, 'items populated' );
240
241 (Mnemonic: "This is ok.")
242
243 $test_name is a very short description of the test that will be printed
244 out. It makes it very easy to find a test in your script when it fails
245 and gives others an idea of your intentions. $test_name is optional,
246 but we B<very> strongly encourage its use.
247
248 Should an ok() fail, it will produce some diagnostics:
249
250 not ok 18 - sufficient mucus
251 # Failed test 'sufficient mucus'
252 # in foo.t at line 42.
253
254 This is the same as Test::Simple's ok() routine.
255
256 =cut
257
258 sub ok ($;$) {
259 my($test, $name) = @_;
260 my $tb = Test::More->builder;
261
262 $tb->ok($test, $name);
263 }
264
265 =item B<is>
266
267 =item B<isnt>
268
269 is ( $got, $expected, $test_name );
270 isnt( $got, $expected, $test_name );
271
272 Similar to ok(), is() and isnt() compare their two arguments
273 with C<eq> and C<ne> respectively and use the result of that to
274 determine if the test succeeded or failed. So these:
275
276 # Is the ultimate answer 42?
277 is( ultimate_answer(), 42, "Meaning of Life" );
278
279 # $foo isn't empty
280 isnt( $foo, '', "Got some foo" );
281
282 are similar to these:
283
284 ok( ultimate_answer() eq 42, "Meaning of Life" );
285 ok( $foo ne '', "Got some foo" );
286
287 (Mnemonic: "This is that." "This isn't that.")
288
289 So why use these? They produce better diagnostics on failure. ok()
290 cannot know what you are testing for (beyond the name), but is() and
291 isnt() know what the test was and why it failed. For example this
292 test:
293
294 my $foo = 'waffle'; my $bar = 'yarblokos';
295 is( $foo, $bar, 'Is foo the same as bar?' );
296
297 Will produce something like this:
298
299 not ok 17 - Is foo the same as bar?
300 # Failed test 'Is foo the same as bar?'
301 # in foo.t at line 139.
302 # got: 'waffle'
303 # expected: 'yarblokos'
304
305 So you can figure out what went wrong without rerunning the test.
306
307 You are encouraged to use is() and isnt() over ok() where possible,
308 however do not be tempted to use them to find out if something is
309 true or false!
310
311 # XXX BAD!
312 is( exists $brooklyn{tree}, 1, 'A tree grows in Brooklyn' );
313
314 This does not check if C<exists $brooklyn{tree}> is true, it checks if
315 it returns 1. Very different. Similar caveats exist for false and 0.
316 In these cases, use ok().
317
318 ok( exists $brooklyn{tree}, 'A tree grows in Brooklyn' );
319
320 For those grammatical pedants out there, there's an C<isn't()>
321 function which is an alias of isnt().
322
323 =cut
324
325 sub is ($$;$) {
326 my $tb = Test::More->builder;
327
328 $tb->is_eq(@_);
329 }
330
331 sub isnt ($$;$) {
332 my $tb = Test::More->builder;
333
334 $tb->isnt_eq(@_);
335 }
336
337 *isn't = \&isnt;
338
339
340 =item B<like>
341
342 like( $got, qr/expected/, $test_name );
343
344 Similar to ok(), like() matches $got against the regex C<qr/expected/>.
345
346 So this:
347
348 like($got, qr/expected/, 'this is like that');
349
350 is similar to:
351
352 ok( $got =~ /expected/, 'this is like that');
353
354 (Mnemonic "This is like that".)
355
356 The second argument is a regular expression. It may be given as a
357 regex reference (i.e. C<qr//>) or (for better compatibility with older
358 perls) as a string that looks like a regex (alternative delimiters are
359 currently not supported):
360
361 like( $got, '/expected/', 'this is like that' );
362
363 Regex options may be placed on the end (C<'/expected/i'>).
364
365 Its advantages over ok() are similar to that of is() and isnt(). Better
366 diagnostics on failure.
367
368 =cut
369
370 sub like ($$;$) {
371 my $tb = Test::More->builder;
372
373 $tb->like(@_);
374 }
375
376
377 =item B<unlike>
378
379 unlike( $got, qr/expected/, $test_name );
380
381 Works exactly as like(), only it checks if $got B<does not> match the
382 given pattern.
383
384 =cut
385
386 sub unlike ($$;$) {
387 my $tb = Test::More->builder;
388
389 $tb->unlike(@_);
390 }
391
392
393 =item B<cmp_ok>
394
395 cmp_ok( $got, $op, $expected, $test_name );
396
397 Halfway between ok() and is() lies cmp_ok(). This allows you to
398 compare two arguments using any binary perl operator.
399
400 # ok( $got eq $expected );
401 cmp_ok( $got, 'eq', $expected, 'this eq that' );
402
403 # ok( $got == $expected );
404 cmp_ok( $got, '==', $expected, 'this == that' );
405
406 # ok( $got && $expected );
407 cmp_ok( $got, '&&', $expected, 'this && that' );
408 ...etc...
409
410 Its advantage over ok() is when the test fails you'll know what $got
411 and $expected were:
412
413 not ok 1
414 # Failed test in foo.t at line 12.
415 # '23'
416 # &&
417 # undef
418
419 It's also useful in those cases where you are comparing numbers and
420 is()'s use of C<eq> will interfere:
421
422 cmp_ok( $big_hairy_number, '==', $another_big_hairy_number );
423
424 =cut
425
426 sub cmp_ok($$$;$) {
427 my $tb = Test::More->builder;
428
429 $tb->cmp_ok(@_);
430 }
431
432
433 =item B<can_ok>
434
435 can_ok($module, @methods);
436 can_ok($object, @methods);
437
438 Checks to make sure the $module or $object can do these @methods
439 (works with functions, too).
440
441 can_ok('Foo', qw(this that whatever));
442
443 is almost exactly like saying:
444
445 ok( Foo->can('this') &&
446 Foo->can('that') &&
447 Foo->can('whatever')
448 );
449
450 only without all the typing and with a better interface. Handy for
451 quickly testing an interface.
452
453 No matter how many @methods you check, a single can_ok() call counts
454 as one test. If you desire otherwise, use:
455
456 foreach my $meth (@methods) {
457 can_ok('Foo', $meth);
458 }
459
460 =cut
461
462 sub can_ok ($@) {
463 my($proto, @methods) = @_;
464 my $class = ref $proto || $proto;
465 my $tb = Test::More->builder;
466
467 unless( $class ) {
468 my $ok = $tb->ok( 0, "->can(...)" );
469 $tb->diag(' can_ok() called with empty class or reference');
470 return $ok;
471 }
472
473 unless( @methods ) {
474 my $ok = $tb->ok( 0, "$class->can(...)" );
475 $tb->diag(' can_ok() called with no methods');
476 return $ok;
477 }
478
479 my @nok = ();
480 foreach my $method (@methods) {
481 $tb->_try(sub { $proto->can($method) }) or push @nok, $method;
482 }
483
484 my $name;
485 $name = @methods == 1 ? "$class->can('$methods[0]')"
486 : "$class->can(...)";
487
488 my $ok = $tb->ok( !@nok, $name );
489
490 $tb->diag(map " $class->can('$_') failed\n", @nok);
491
492 return $ok;
493 }
494
495 =item B<isa_ok>
496
497 isa_ok($object, $class, $object_name);
498 isa_ok($ref, $type, $ref_name);
499
500 Checks to see if the given C<< $object->isa($class) >>. Also checks to make
501 sure the object was defined in the first place. Handy for this sort
502 of thing:
503
504 my $obj = Some::Module->new;
505 isa_ok( $obj, 'Some::Module' );
506
507 where you'd otherwise have to write
508
509 my $obj = Some::Module->new;
510 ok( defined $obj && $obj->isa('Some::Module') );
511
512 to safeguard against your test script blowing up.
513
514 It works on references, too:
515
516 isa_ok( $array_ref, 'ARRAY' );
517
518 The diagnostics of this test normally just refer to 'the object'. If
519 you'd like them to be more specific, you can supply an $object_name
520 (for example 'Test customer').
521
522 =cut
523
524 sub isa_ok ($$;$) {
525 my($object, $class, $obj_name) = @_;
526 my $tb = Test::More->builder;
527
528 my $diag;
529 $obj_name = 'The object' unless defined $obj_name;
530 my $name = "$obj_name isa $class";
531 if( !defined $object ) {
532 $diag = "$obj_name isn't defined";
533 }
534 elsif( !ref $object ) {
535 $diag = "$obj_name isn't a reference";
536 }
537 else {
538 # We can't use UNIVERSAL::isa because we want to honor isa() overrides
539 my($rslt, $error) = $tb->_try(sub { $object->isa($class) });
540 if( $error ) {
541 if( $error =~ /^Can't call method "isa" on unblessed reference/ ) {
542 # Its an unblessed reference
543 if( !UNIVERSAL::isa($object, $class) ) {
544 my $ref = ref $object;
545 $diag = "$obj_name isn't a '$class' it's a '$ref'";
546 }
547 } else {
548 die <<WHOA;
549 WHOA! I tried to call ->isa on your object and got some weird error.
550 Here's the error.
551 $error
552 WHOA
553 }
554 }
555 elsif( !$rslt ) {
556 my $ref = ref $object;
557 $diag = "$obj_name isn't a '$class' it's a '$ref'";
558 }
559 }
560
561
562
563 my $ok;
564 if( $diag ) {
565 $ok = $tb->ok( 0, $name );
566 $tb->diag(" $diag\n");
567 }
568 else {
569 $ok = $tb->ok( 1, $name );
570 }
571
572 return $ok;
573 }
574
575
576 =item B<pass>
577
578 =item B<fail>
579
580 pass($test_name);
581 fail($test_name);
582
583 Sometimes you just want to say that the tests have passed. Usually
584 the case is you've got some complicated condition that is difficult to
585 wedge into an ok(). In this case, you can simply use pass() (to
586 declare the test ok) or fail (for not ok). They are synonyms for
587 ok(1) and ok(0).
588
589 Use these very, very, very sparingly.
590
591 =cut
592
593 sub pass (;$) {
594 my $tb = Test::More->builder;
595 $tb->ok(1, @_);
596 }
597
598 sub fail (;$) {
599 my $tb = Test::More->builder;
600 $tb->ok(0, @_);
601 }
602
603 =back
604
605
606 =head2 Module tests
607
608 You usually want to test if the module you're testing loads ok, rather
609 than just vomiting if its load fails. For such purposes we have
610 C<use_ok> and C<require_ok>.
611
612 =over 4
613
614 =item B<use_ok>
615
616 BEGIN { use_ok($module); }
617 BEGIN { use_ok($module, @imports); }
618
619 These simply use the given $module and test to make sure the load
620 happened ok. It's recommended that you run use_ok() inside a BEGIN
621 block so its functions are exported at compile-time and prototypes are
622 properly honored.
623
624 If @imports are given, they are passed through to the use. So this:
625
626 BEGIN { use_ok('Some::Module', qw(foo bar)) }
627
628 is like doing this:
629
630 use Some::Module qw(foo bar);
631
632 Version numbers can be checked like so:
633
634 # Just like "use Some::Module 1.02"
635 BEGIN { use_ok('Some::Module', 1.02) }
636
637 Don't try to do this:
638
639 BEGIN {
640 use_ok('Some::Module');
641
642 ...some code that depends on the use...
643 ...happening at compile time...
644 }
645
646 because the notion of "compile-time" is relative. Instead, you want:
647
648 BEGIN { use_ok('Some::Module') }
649 BEGIN { ...some code that depends on the use... }
650
651
652 =cut
653
654 sub use_ok ($;@) {
655 my($module, @imports) = @_;
656 @imports = () unless @imports;
657 my $tb = Test::More->builder;
658
659 my($pack,$filename,$line) = caller;
660
661 my $code;
662 if( @imports == 1 and $imports[0] =~ /^\d+(?:\.\d+)?$/ ) {
663 # probably a version check. Perl needs to see the bare number
664 # for it to work with non-Exporter based modules.
665 $code = <<USE;
666 package $pack;
667 use $module $imports[0];
668 1;
669 USE
670 }
671 else {
672 $code = <<USE;
673 package $pack;
674 use $module \@{\$args[0]};
675 1;
676 USE
677 }
678
679
680 my($eval_result, $eval_error) = _eval($code, \@imports);
681 my $ok = $tb->ok( $eval_result, "use $module;" );
682
683 unless( $ok ) {
684 chomp $eval_error;
685 $@ =~ s{^BEGIN failed--compilation aborted at .*$}
686 {BEGIN failed--compilation aborted at $filename line $line.}m;
687 $tb->diag(<<DIAGNOSTIC);
688 Tried to use '$module'.
689 Error: $eval_error
690 DIAGNOSTIC
691
692 }
693
694 return $ok;
695 }
696
697
698 sub _eval {
699 my($code) = shift;
700 my @args = @_;
701
702 # Work around oddities surrounding resetting of $@ by immediately
703 # storing it.
704 local($@,$!,$SIG{__DIE__}); # isolate eval
705 my $eval_result = eval $code;
706 my $eval_error = $@;
707
708 return($eval_result, $eval_error);
709 }
710
711 =item B<require_ok>
712
713 require_ok($module);
714 require_ok($file);
715
716 Like use_ok(), except it requires the $module or $file.
717
718 =cut
719
720 sub require_ok ($) {
721 my($module) = shift;
722 my $tb = Test::More->builder;
723
724 my $pack = caller;
725
726 # Try to deterine if we've been given a module name or file.
727 # Module names must be barewords, files not.
728 $module = qq['$module'] unless _is_module_name($module);
729
730 my $code = <<REQUIRE;
731 package $pack;
732 require $module;
733 1;
734 REQUIRE
735
736 my($eval_result, $eval_error) = _eval($code);
737 my $ok = $tb->ok( $eval_result, "require $module;" );
738
739 unless( $ok ) {
740 chomp $eval_error;
741 $tb->diag(<<DIAGNOSTIC);
742 Tried to require '$module'.
743 Error: $eval_error
744 DIAGNOSTIC
745
746 }
747
748 return $ok;
749 }
750
751
752 sub _is_module_name {
753 my $module = shift;
754
755 # Module names start with a letter.
756 # End with an alphanumeric.
757 # The rest is an alphanumeric or ::
758 $module =~ s/\b::\b//g;
759 $module =~ /^[a-zA-Z]\w*$/;
760 }
761
762 =back
763
764
765 =head2 Complex data structures
766
767 Not everything is a simple eq check or regex. There are times you
768 need to see if two data structures are equivalent. For these
769 instances Test::More provides a handful of useful functions.
770
771 B<NOTE> I'm not quite sure what will happen with filehandles.
772
773 =over 4
774
775 =item B<is_deeply>
776
777 is_deeply( $got, $expected, $test_name );
778
779 Similar to is(), except that if $got and $expected are references, it
780 does a deep comparison walking each data structure to see if they are
781 equivalent. If the two structures are different, it will display the
782 place where they start differing.
783
784 is_deeply() compares the dereferenced values of references, the
785 references themselves (except for their type) are ignored. This means
786 aspects such as blessing and ties are not considered "different".
787
788 is_deeply() current has very limited handling of function reference
789 and globs. It merely checks if they have the same referent. This may
790 improve in the future.
791
792 Test::Differences and Test::Deep provide more in-depth functionality
793 along these lines.
794
795 =cut
796
797 use vars qw(@Data_Stack %Refs_Seen);
798 my $DNE = bless [], 'Does::Not::Exist';
799
800 sub _dne {
801 ref $_[0] eq ref $DNE;
802 }
803
804
805 sub is_deeply {
806 my $tb = Test::More->builder;
807
808 unless( @_ == 2 or @_ == 3 ) {
809 my $msg = <<WARNING;
810 is_deeply() takes two or three args, you gave %d.
811 This usually means you passed an array or hash instead
812 of a reference to it
813 WARNING
814 chop $msg; # clip off newline so carp() will put in line/file
815
816 _carp sprintf $msg, scalar @_;
817
818 return $tb->ok(0);
819 }
820
821 my($got, $expected, $name) = @_;
822
823 $tb->_unoverload_str(\$expected, \$got);
824
825 my $ok;
826 if( !ref $got and !ref $expected ) { # neither is a reference
827 $ok = $tb->is_eq($got, $expected, $name);
828 }
829 elsif( !ref $got xor !ref $expected ) { # one's a reference, one isn't
830 $ok = $tb->ok(0, $name);
831 $tb->diag( _format_stack({ vals => [ $got, $expected ] }) );
832 }
833 else { # both references
834 local @Data_Stack = ();
835 if( _deep_check($got, $expected) ) {
836 $ok = $tb->ok(1, $name);
837 }
838 else {
839 $ok = $tb->ok(0, $name);
840 $tb->diag(_format_stack(@Data_Stack));
841 }
842 }
843
844 return $ok;
845 }
846
847 sub _format_stack {
848 my(@Stack) = @_;
849
850 my $var = '$FOO';
851 my $did_arrow = 0;
852 foreach my $entry (@Stack) {
853 my $type = $entry->{type} || '';
854 my $idx = $entry->{'idx'};
855 if( $type eq 'HASH' ) {
856 $var .= "->" unless $did_arrow++;
857 $var .= "{$idx}";
858 }
859 elsif( $type eq 'ARRAY' ) {
860 $var .= "->" unless $did_arrow++;
861 $var .= "[$idx]";
862 }
863 elsif( $type eq 'REF' ) {
864 $var = "\${$var}";
865 }
866 }
867
868 my @vals = @{$Stack[-1]{vals}}[0,1];
869 my @vars = ();
870 ($vars[0] = $var) =~ s/\$FOO/ \$got/;
871 ($vars[1] = $var) =~ s/\$FOO/\$expected/;
872
873 my $out = "Structures begin differing at:\n";
874 foreach my $idx (0..$#vals) {
875 my $val = $vals[$idx];
876 $vals[$idx] = !defined $val ? 'undef' :
877 _dne($val) ? "Does not exist" :
878 ref $val ? "$val" :
879 "'$val'";
880 }
881
882 $out .= "$vars[0] = $vals[0]\n";
883 $out .= "$vars[1] = $vals[1]\n";
884
885 $out =~ s/^/ /msg;
886 return $out;
887 }
888
889
890 sub _type {
891 my $thing = shift;
892
893 return '' if !ref $thing;
894
895 for my $type (qw(ARRAY HASH REF SCALAR GLOB CODE Regexp)) {
896 return $type if UNIVERSAL::isa($thing, $type);
897 }
898
899 return '';
900 }
901
902 =back
903
904
905 =head2 Diagnostics
906
907 If you pick the right test function, you'll usually get a good idea of
908 what went wrong when it failed. But sometimes it doesn't work out
909 that way. So here we have ways for you to write your own diagnostic
910 messages which are safer than just C<print STDERR>.
911
912 =over 4
913
914 =item B<diag>
915
916 diag(@diagnostic_message);
917
918 Prints a diagnostic message which is guaranteed not to interfere with
919 test output. Like C<print> @diagnostic_message is simply concatenated
920 together.
921
922 Handy for this sort of thing:
923
924 ok( grep(/foo/, @users), "There's a foo user" ) or
925 diag("Since there's no foo, check that /etc/bar is set up right");
926
927 which would produce:
928
929 not ok 42 - There's a foo user
930 # Failed test 'There's a foo user'
931 # in foo.t at line 52.
932 # Since there's no foo, check that /etc/bar is set up right.
933
934 You might remember C<ok() or diag()> with the mnemonic C<open() or
935 die()>.
936
937 B<NOTE> The exact formatting of the diagnostic output is still
938 changing, but it is guaranteed that whatever you throw at it it won't
939 interfere with the test.
940
941 =cut
942
943 sub diag {
944 my $tb = Test::More->builder;
945
946 $tb->diag(@_);
947 }
948
949
950 =back
951
952
953 =head2 Conditional tests
954
955 Sometimes running a test under certain conditions will cause the
956 test script to die. A certain function or method isn't implemented
957 (such as fork() on MacOS), some resource isn't available (like a
958 net connection) or a module isn't available. In these cases it's
959 necessary to skip tests, or declare that they are supposed to fail
960 but will work in the future (a todo test).
961
962 For more details on the mechanics of skip and todo tests see
963 L<Test::Harness>.
964
965 The way Test::More handles this is with a named block. Basically, a
966 block of tests which can be skipped over or made todo. It's best if I
967 just show you...
968
969 =over 4
970
971 =item B<SKIP: BLOCK>
972
973 SKIP: {
974 skip $why, $how_many if $condition;
975
976 ...normal testing code goes here...
977 }
978
979 This declares a block of tests that might be skipped, $how_many tests
980 there are, $why and under what $condition to skip them. An example is
981 the easiest way to illustrate:
982
983 SKIP: {
984 eval { require HTML::Lint };
985
986 skip "HTML::Lint not installed", 2 if $@;
987
988 my $lint = new HTML::Lint;
989 isa_ok( $lint, "HTML::Lint" );
990
991 $lint->parse( $html );
992 is( $lint->errors, 0, "No errors found in HTML" );
993 }
994
995 If the user does not have HTML::Lint installed, the whole block of
996 code I<won't be run at all>. Test::More will output special ok's
997 which Test::Harness interprets as skipped, but passing, tests.
998
999 It's important that $how_many accurately reflects the number of tests
1000 in the SKIP block so the # of tests run will match up with your plan.
1001 If your plan is C<no_plan> $how_many is optional and will default to 1.
1002
1003 It's perfectly safe to nest SKIP blocks. Each SKIP block must have
1004 the label C<SKIP>, or Test::More can't work its magic.
1005
1006 You don't skip tests which are failing because there's a bug in your
1007 program, or for which you don't yet have code written. For that you
1008 use TODO. Read on.
1009
1010 =cut
1011
1012 #'#
1013 sub skip {
1014 my($why, $how_many) = @_;
1015 my $tb = Test::More->builder;
1016
1017 unless( defined $how_many ) {
1018 # $how_many can only be avoided when no_plan is in use.
1019 _carp "skip() needs to know \$how_many tests are in the block"
1020 unless $tb->has_plan eq 'no_plan';
1021 $how_many = 1;
1022 }
1023
1024 if( defined $how_many and $how_many =~ /\D/ ) {
1025 _carp "skip() was passed a non-numeric number of tests. Did you get the arguments backwards?";
1026 $how_many = 1;
1027 }
1028
1029 for( 1..$how_many ) {
1030 $tb->skip($why);
1031 }
1032
1033 local $^W = 0;
1034 last SKIP;
1035 }
1036
1037
1038 =item B<TODO: BLOCK>
1039
1040 TODO: {
1041 local $TODO = $why if $condition;
1042
1043 ...normal testing code goes here...
1044 }
1045
1046 Declares a block of tests you expect to fail and $why. Perhaps it's
1047 because you haven't fixed a bug or haven't finished a new feature:
1048
1049 TODO: {
1050 local $TODO = "URI::Geller not finished";
1051
1052 my $card = "Eight of clubs";
1053 is( URI::Geller->your_card, $card, 'Is THIS your card?' );
1054
1055 my $spoon;
1056 URI::Geller->bend_spoon;
1057 is( $spoon, 'bent', "Spoon bending, that's original" );
1058 }
1059
1060 With a todo block, the tests inside are expected to fail. Test::More
1061 will run the tests normally, but print out special flags indicating
1062 they are "todo". Test::Harness will interpret failures as being ok.
1063 Should anything succeed, it will report it as an unexpected success.
1064 You then know the thing you had todo is done and can remove the
1065 TODO flag.
1066
1067 The nice part about todo tests, as opposed to simply commenting out a
1068 block of tests, is it's like having a programmatic todo list. You know
1069 how much work is left to be done, you're aware of what bugs there are,
1070 and you'll know immediately when they're fixed.
1071
1072 Once a todo test starts succeeding, simply move it outside the block.
1073 When the block is empty, delete it.
1074
1075 B<NOTE>: TODO tests require a Test::Harness upgrade else it will
1076 treat it as a normal failure. See L<CAVEATS and NOTES>).
1077
1078
1079 =item B<todo_skip>
1080
1081 TODO: {
1082 todo_skip $why, $how_many if $condition;
1083
1084 ...normal testing code...
1085 }
1086
1087 With todo tests, it's best to have the tests actually run. That way
1088 you'll know when they start passing. Sometimes this isn't possible.
1089 Often a failing test will cause the whole program to die or hang, even
1090 inside an C<eval BLOCK> with and using C<alarm>. In these extreme
1091 cases you have no choice but to skip over the broken tests entirely.
1092
1093 The syntax and behavior is similar to a C<SKIP: BLOCK> except the
1094 tests will be marked as failing but todo. Test::Harness will
1095 interpret them as passing.
1096
1097 =cut
1098
1099 sub todo_skip {
1100 my($why, $how_many) = @_;
1101 my $tb = Test::More->builder;
1102
1103 unless( defined $how_many ) {
1104 # $how_many can only be avoided when no_plan is in use.
1105 _carp "todo_skip() needs to know \$how_many tests are in the block"
1106 unless $tb->has_plan eq 'no_plan';
1107 $how_many = 1;
1108 }
1109
1110 for( 1..$how_many ) {
1111 $tb->todo_skip($why);
1112 }
1113
1114 local $^W = 0;
1115 last TODO;
1116 }
1117
1118 =item When do I use SKIP vs. TODO?
1119
1120 B<If it's something the user might not be able to do>, use SKIP.
1121 This includes optional modules that aren't installed, running under
1122 an OS that doesn't have some feature (like fork() or symlinks), or maybe
1123 you need an Internet connection and one isn't available.
1124
1125 B<If it's something the programmer hasn't done yet>, use TODO. This
1126 is for any code you haven't written yet, or bugs you have yet to fix,
1127 but want to put tests in your testing script (always a good idea).
1128
1129
1130 =back
1131
1132
1133 =head2 Test control
1134
1135 =over 4
1136
1137 =item B<BAIL_OUT>
1138
1139 BAIL_OUT($reason);
1140
1141 Indicates to the harness that things are going so badly all testing
1142 should terminate. This includes the running any additional test scripts.
1143
1144 This is typically used when testing cannot continue such as a critical
1145 module failing to compile or a necessary external utility not being
1146 available such as a database connection failing.
1147
1148 The test will exit with 255.
1149
1150 =cut
1151
1152 sub BAIL_OUT {
1153 my $reason = shift;
1154 my $tb = Test::More->builder;
1155
1156 $tb->BAIL_OUT($reason);
1157 }
1158
1159 =back
1160
1161
1162 =head2 Discouraged comparison functions
1163
1164 The use of the following functions is discouraged as they are not
1165 actually testing functions and produce no diagnostics to help figure
1166 out what went wrong. They were written before is_deeply() existed
1167 because I couldn't figure out how to display a useful diff of two
1168 arbitrary data structures.
1169
1170 These functions are usually used inside an ok().
1171
1172 ok( eq_array(\@got, \@expected) );
1173
1174 C<is_deeply()> can do that better and with diagnostics.
1175
1176 is_deeply( \@got, \@expected );
1177
1178 They may be deprecated in future versions.
1179
1180 =over 4
1181
1182 =item B<eq_array>
1183
1184 my $is_eq = eq_array(\@got, \@expected);
1185
1186 Checks if two arrays are equivalent. This is a deep check, so
1187 multi-level structures are handled correctly.
1188
1189 =cut
1190
1191 #'#
1192 sub eq_array {
1193 local @Data_Stack;
1194 _deep_check(@_);
1195 }
1196
1197 sub _eq_array {
1198 my($a1, $a2) = @_;
1199
1200 if( grep !_type($_) eq 'ARRAY', $a1, $a2 ) {
1201 warn "eq_array passed a non-array ref";
1202 return 0;
1203 }
1204
1205 return 1 if $a1 eq $a2;
1206
1207 my $ok = 1;
1208 my $max = $#$a1 > $#$a2 ? $#$a1 : $#$a2;
1209 for (0..$max) {
1210 my $e1 = $_ > $#$a1 ? $DNE : $a1->[$_];
1211 my $e2 = $_ > $#$a2 ? $DNE : $a2->[$_];
1212
1213 push @Data_Stack, { type => 'ARRAY', idx => $_, vals => [$e1, $e2] };
1214 $ok = _deep_check($e1,$e2);
1215 pop @Data_Stack if $ok;
1216
1217 last unless $ok;
1218 }
1219
1220 return $ok;
1221 }
1222
1223 sub _deep_check {
1224 my($e1, $e2) = @_;
1225 my $tb = Test::More->builder;
1226
1227 my $ok = 0;
1228
1229 # Effectively turn %Refs_Seen into a stack. This avoids picking up
1230 # the same referenced used twice (such as [\$a, \$a]) to be considered
1231 # circular.
1232 local %Refs_Seen = %Refs_Seen;
1233
1234 {
1235 # Quiet uninitialized value warnings when comparing undefs.
1236 local $^W = 0;
1237
1238 $tb->_unoverload_str(\$e1, \$e2);
1239
1240 # Either they're both references or both not.
1241 my $same_ref = !(!ref $e1 xor !ref $e2);
1242 my $not_ref = (!ref $e1 and !ref $e2);
1243
1244 if( defined $e1 xor defined $e2 ) {
1245 $ok = 0;
1246 }
1247 elsif ( _dne($e1) xor _dne($e2) ) {
1248 $ok = 0;
1249 }
1250 elsif ( $same_ref and ($e1 eq $e2) ) {
1251 $ok = 1;
1252 }
1253 elsif ( $not_ref ) {
1254 push @Data_Stack, { type => '', vals => [$e1, $e2] };
1255 $ok = 0;
1256 }
1257 else {
1258 if( $Refs_Seen{$e1} ) {
1259 return $Refs_Seen{$e1} eq $e2;
1260 }
1261 else {
1262 $Refs_Seen{$e1} = "$e2";
1263 }
1264
1265 my $type = _type($e1);
1266 $type = 'DIFFERENT' unless _type($e2) eq $type;
1267
1268 if( $type eq 'DIFFERENT' ) {
1269 push @Data_Stack, { type => $type, vals => [$e1, $e2] };
1270 $ok = 0;
1271 }
1272 elsif( $type eq 'ARRAY' ) {
1273 $ok = _eq_array($e1, $e2);
1274 }
1275 elsif( $type eq 'HASH' ) {
1276 $ok = _eq_hash($e1, $e2);
1277 }
1278 elsif( $type eq 'REF' ) {
1279 push @Data_Stack, { type => $type, vals => [$e1, $e2] };
1280 $ok = _deep_check($$e1, $$e2);
1281 pop @Data_Stack if $ok;
1282 }
1283 elsif( $type eq 'SCALAR' ) {
1284 push @Data_Stack, { type => 'REF', vals => [$e1, $e2] };
1285 $ok = _deep_check($$e1, $$e2);
1286 pop @Data_Stack if $ok;
1287 }
1288 elsif( $type ) {
1289 push @Data_Stack, { type => $type, vals => [$e1, $e2] };
1290 $ok = 0;
1291 }
1292 else {
1293 _whoa(1, "No type in _deep_check");
1294 }
1295 }
1296 }
1297
1298 return $ok;
1299 }
1300
1301
1302 sub _whoa {
1303 my($check, $desc) = @_;
1304 if( $check ) {
1305 die <<WHOA;
1306 WHOA! $desc
1307 This should never happen! Please contact the author immediately!
1308 WHOA
1309 }
1310 }
1311
1312
1313 =item B<eq_hash>
1314
1315 my $is_eq = eq_hash(\%got, \%expected);
1316
1317 Determines if the two hashes contain the same keys and values. This
1318 is a deep check.
1319
1320 =cut
1321
1322 sub eq_hash {
1323 local @Data_Stack;
1324 return _deep_check(@_);
1325 }
1326
1327 sub _eq_hash {
1328 my($a1, $a2) = @_;
1329
1330 if( grep !_type($_) eq 'HASH', $a1, $a2 ) {
1331 warn "eq_hash passed a non-hash ref";
1332 return 0;
1333 }
1334
1335 return 1 if $a1 eq $a2;
1336
1337 my $ok = 1;
1338 my $bigger = keys %$a1 > keys %$a2 ? $a1 : $a2;
1339 foreach my $k (keys %$bigger) {
1340 my $e1 = exists $a1->{$k} ? $a1->{$k} : $DNE;
1341 my $e2 = exists $a2->{$k} ? $a2->{$k} : $DNE;
1342
1343 push @Data_Stack, { type => 'HASH', idx => $k, vals => [$e1, $e2] };
1344 $ok = _deep_check($e1, $e2);
1345 pop @Data_Stack if $ok;
1346
1347 last unless $ok;
1348 }
1349
1350 return $ok;
1351 }
1352
1353 =item B<eq_set>
1354
1355 my $is_eq = eq_set(\@got, \@expected);
1356
1357 Similar to eq_array(), except the order of the elements is B<not>
1358 important. This is a deep check, but the irrelevancy of order only
1359 applies to the top level.
1360
1361 ok( eq_set(\@got, \@expected) );
1362
1363 Is better written:
1364
1365 is_deeply( [sort @got], [sort @expected] );
1366
1367 B<NOTE> By historical accident, this is not a true set comparison.
1368 While the order of elements does not matter, duplicate elements do.
1369
1370 B<NOTE> eq_set() does not know how to deal with references at the top
1371 level. The following is an example of a comparison which might not work:
1372
1373 eq_set([\1, \2], [\2, \1]);
1374
1375 Test::Deep contains much better set comparison functions.
1376
1377 =cut
1378
1379 sub eq_set {
1380 my($a1, $a2) = @_;
1381 return 0 unless @$a1 == @$a2;
1382
1383 # There's faster ways to do this, but this is easiest.
1384 local $^W = 0;
1385
1386 # It really doesn't matter how we sort them, as long as both arrays are
1387 # sorted with the same algorithm.
1388 #
1389 # Ensure that references are not accidentally treated the same as a
1390 # string containing the reference.
1391 #
1392 # Have to inline the sort routine due to a threading/sort bug.
1393 # See [rt.cpan.org 6782]
1394 #
1395 # I don't know how references would be sorted so we just don't sort
1396 # them. This means eq_set doesn't really work with refs.
1397 return eq_array(
1398 [grep(ref, @$a1), sort( grep(!ref, @$a1) )],
1399 [grep(ref, @$a2), sort( grep(!ref, @$a2) )],
1400 );
1401 }
1402
1403 =back
1404
1405
1406 =head2 Extending and Embedding Test::More
1407
1408 Sometimes the Test::More interface isn't quite enough. Fortunately,
1409 Test::More is built on top of Test::Builder which provides a single,
1410 unified backend for any test library to use. This means two test
1411 libraries which both use Test::Builder B<can be used together in the
1412 same program>.
1413
1414 If you simply want to do a little tweaking of how the tests behave,
1415 you can access the underlying Test::Builder object like so:
1416
1417 =over 4
1418
1419 =item B<builder>
1420
1421 my $test_builder = Test::More->builder;
1422
1423 Returns the Test::Builder object underlying Test::More for you to play
1424 with.
1425
1426
1427 =back
1428
1429
1430 =head1 EXIT CODES
1431
1432 If all your tests passed, Test::Builder will exit with zero (which is
1433 normal). If anything failed it will exit with how many failed. If
1434 you run less (or more) tests than you planned, the missing (or extras)
1435 will be considered failures. If no tests were ever run Test::Builder
1436 will throw a warning and exit with 255. If the test died, even after
1437 having successfully completed all its tests, it will still be
1438 considered a failure and will exit with 255.
1439
1440 So the exit codes are...
1441
1442 0 all tests successful
1443 255 test died or all passed but wrong # of tests run
1444 any other number how many failed (including missing or extras)
1445
1446 If you fail more than 254 tests, it will be reported as 254.
1447
1448 B<NOTE> This behavior may go away in future versions.
1449
1450
1451 =head1 CAVEATS and NOTES
1452
1453 =over 4
1454
1455 =item Backwards compatibility
1456
1457 Test::More works with Perls as old as 5.6.0.
1458
1459
1460 =item Overloaded objects
1461
1462 String overloaded objects are compared B<as strings> (or in cmp_ok()'s
1463 case, strings or numbers as appropriate to the comparison op). This
1464 prevents Test::More from piercing an object's interface allowing
1465 better blackbox testing. So if a function starts returning overloaded
1466 objects instead of bare strings your tests won't notice the
1467 difference. This is good.
1468
1469 However, it does mean that functions like is_deeply() cannot be used to
1470 test the internals of string overloaded objects. In this case I would
1471 suggest Test::Deep which contains more flexible testing functions for
1472 complex data structures.
1473
1474
1475 =item Threads
1476
1477 Test::More will only be aware of threads if "use threads" has been done
1478 I<before> Test::More is loaded. This is ok:
1479
1480 use threads;
1481 use Test::More;
1482
1483 This may cause problems:
1484
1485 use Test::More
1486 use threads;
1487
1488 5.8.1 and above are supported. Anything below that has too many bugs.
1489
1490
1491 =item Test::Harness upgrade
1492
1493 no_plan and todo depend on new Test::Harness features and fixes. If
1494 you're going to distribute tests that use no_plan or todo your
1495 end-users will have to upgrade Test::Harness to the latest one on
1496 CPAN. If you avoid no_plan and TODO tests, the stock Test::Harness
1497 will work fine.
1498
1499 Installing Test::More should also upgrade Test::Harness.
1500
1501 =back
1502
1503
1504 =head1 HISTORY
1505
1506 This is a case of convergent evolution with Joshua Pritikin's Test
1507 module. I was largely unaware of its existence when I'd first
1508 written my own ok() routines. This module exists because I can't
1509 figure out how to easily wedge test names into Test's interface (along
1510 with a few other problems).
1511
1512 The goal here is to have a testing utility that's simple to learn,
1513 quick to use and difficult to trip yourself up with while still
1514 providing more flexibility than the existing Test.pm. As such, the
1515 names of the most common routines are kept tiny, special cases and
1516 magic side-effects are kept to a minimum. WYSIWYG.
1517
1518
1519 =head1 SEE ALSO
1520
1521 L<Test::Simple> if all this confuses you and you just want to write
1522 some tests. You can upgrade to Test::More later (it's forward
1523 compatible).
1524
1525 L<Test> is the old testing module. Its main benefit is that it has
1526 been distributed with Perl since 5.004_05.
1527
1528 L<Test::Harness> for details on how your test results are interpreted
1529 by Perl.
1530
1531 L<Test::Differences> for more ways to test complex data structures.
1532 And it plays well with Test::More.
1533
1534 L<Test::Class> is like XUnit but more perlish.
1535
1536 L<Test::Deep> gives you more powerful complex data structure testing.
1537
1538 L<Test::Unit> is XUnit style testing.
1539
1540 L<Test::Inline> shows the idea of embedded testing.
1541
1542 L<Bundle::Test> installs a whole bunch of useful test modules.
1543
1544
1545 =head1 AUTHORS
1546
1547 Michael G Schwern E<lt>schwern@pobox.comE<gt> with much inspiration
1548 from Joshua Pritikin's Test module and lots of help from Barrie
1549 Slaymaker, Tony Bowden, blackstar.co.uk, chromatic, Fergal Daly and
1550 the perl-qa gang.
1551
1552
1553 =head1 BUGS
1554
1555 See F<http://rt.cpan.org> to report and view bugs.
1556
1557
1558 =head1 COPYRIGHT
1559
1560 Copyright 2001-2002, 2004-2006 by Michael G Schwern E<lt>schwern@pobox.comE<gt>.
1561
1562 This program is free software; you can redistribute it and/or
1563 modify it under the same terms as Perl itself.
1564
1565 See F<http://www.perl.com/perl/misc/Artistic.html>
1566
1567 =cut
1568
1569 1;