| … | |
… | |
| 10 | # to go back to "/" no matter how myfun exits: |
10 | # to go back to "/" no matter how myfun exits: |
| 11 | sub myfun { |
11 | sub myfun { |
| 12 | scope_guard { chdir "/" }; |
12 | scope_guard { chdir "/" }; |
| 13 | chdir "/etc"; |
13 | chdir "/etc"; |
| 14 | |
14 | |
| 15 | call_function_that_might_die_or_other_fun_stuff; |
15 | code_that_might_die_or_does_other_fun_stuff; |
| 16 | } |
16 | } |
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17 | |
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18 | # create an object that, when the last reference to it is gone, |
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19 | # invokes the given codeblock: |
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20 | my $guard = guard { print "destroyed!\n" }; |
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21 | undef $guard; # probably destroyed here |
| 17 | |
22 | |
| 18 | =head1 DESCRIPTION |
23 | =head1 DESCRIPTION |
| 19 | |
24 | |
| 20 | This module implements so-called "guards". A guard is something (usually |
25 | This module implements so-called "guards". A guard is something (usually |
| 21 | an object) that "guards" a resource, ensuring that it is cleaned up when |
26 | an object) that "guards" a resource, ensuring that it is cleaned up when |
| … | |
… | |
| 34 | |
39 | |
| 35 | =cut |
40 | =cut |
| 36 | |
41 | |
| 37 | package Guard; |
42 | package Guard; |
| 38 | |
43 | |
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44 | no warnings; |
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45 | |
| 39 | BEGIN { |
46 | BEGIN { |
| 40 | $VERSION = '0.1'; |
47 | $VERSION = '1.021'; |
| 41 | @ISA = qw(Exporter); |
48 | @ISA = qw(Exporter); |
| 42 | @EXPORT = qw(guard scope_guard); |
49 | @EXPORT = qw(guard scope_guard); |
| 43 | |
50 | |
| 44 | require Exporter; |
51 | require Exporter; |
| 45 | |
52 | |
| … | |
… | |
| 107 | |
114 | |
| 108 | See the EXCEPTIONS section for an explanation of how exceptions |
115 | See the EXCEPTIONS section for an explanation of how exceptions |
| 109 | (i.e. C<die>) are handled inside guard blocks. |
116 | (i.e. C<die>) are handled inside guard blocks. |
| 110 | |
117 | |
| 111 | Example: acquire a Coro::Semaphore for a second by registering a |
118 | Example: acquire a Coro::Semaphore for a second by registering a |
| 112 | timer. The timer callback references the guard used to unlock it again. |
119 | timer. The timer callback references the guard used to unlock it |
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120 | again. (Please ignore the fact that C<Coro::Semaphore> has a C<guard> |
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121 | method that does this already): |
| 113 | |
122 | |
| 114 | use Guard; |
123 | use Guard; |
| 115 | use AnyEvent; |
124 | use AnyEvent; |
| 116 | use Coro::Semaphore; |
125 | use Coro::Semaphore; |
| 117 | |
126 | |
| … | |
… | |
| 131 | |
140 | |
| 132 | The advantage of doing this with a guard instead of simply calling C<< |
141 | The advantage of doing this with a guard instead of simply calling C<< |
| 133 | $sem->down >> in the callback is that you can opt not to create the timer, |
142 | $sem->down >> in the callback is that you can opt not to create the timer, |
| 134 | or your code can throw an exception before it can create the timer, or you |
143 | or your code can throw an exception before it can create the timer, or you |
| 135 | can create multiple timers or other event watchers and only when the last |
144 | can create multiple timers or other event watchers and only when the last |
| 136 | one gets executed will the lock be unlocked. |
145 | one gets executed will the lock be unlocked. Using the C<guard>, you do |
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146 | not have to worry about catching all the places where you have to unlock |
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147 | the semaphore. |
| 137 | |
148 | |
| 138 | =item Guard::cancel $guard |
149 | =item $guard->cancel |
| 139 | |
150 | |
| 140 | Calling this function will "disable" the guard object returned by the |
151 | Calling this function will "disable" the guard object returned by the |
| 141 | C<guard> function, i.e. it will free the BLOCK originally passed to |
152 | C<guard> function, i.e. it will free the BLOCK originally passed to |
| 142 | C<guard >and will arrange for the BLOCK not to be executed. |
153 | C<guard >and will arrange for the BLOCK not to be executed. |
| 143 | |
154 | |
| … | |
… | |
| 156 | all, they are usually used to clean up after such exceptions. However, if |
167 | all, they are usually used to clean up after such exceptions. However, if |
| 157 | something truly exceptional is happening, a guard block should be allowed |
168 | something truly exceptional is happening, a guard block should be allowed |
| 158 | to die. Also, programming errors are a large source of exceptions, and the |
169 | to die. Also, programming errors are a large source of exceptions, and the |
| 159 | programmer certainly wants to know about those. |
170 | programmer certainly wants to know about those. |
| 160 | |
171 | |
| 161 | Since in most cases, the block executing when the guard gets executes does |
172 | Since in most cases, the block executing when the guard gets executed does |
| 162 | not know or does not care about the guard blocks, it makes little sense to |
173 | not know or does not care about the guard blocks, it makes little sense to |
| 163 | let containing code handle the exception. |
174 | let containing code handle the exception. |
| 164 | |
175 | |
| 165 | Therefore, whenever a guard block throws an exception, it will be caught, |
176 | Therefore, whenever a guard block throws an exception, it will be caught, |
| 166 | and this module will call the code reference stored in C<$Guard::DIED> |
177 | followed by calling the code reference stored in C<$Guard::DIED> (with |
| 167 | (with C<$@> set to the actual exception), which is similar to how most |
178 | C<$@> set to the actual exception), which is similar to how most event |
| 168 | event loops handle this case. |
179 | loops handle this case. |
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180 | |
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181 | The default for C<$Guard::DIED> is to call C<warn "$@">. |
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182 | |
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183 | The C<$@> variable will be restored to its value before the guard call in |
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184 | all cases, so guards will not disturb C<$@> in any way. |
| 169 | |
185 | |
| 170 | The code reference stored in C<$Guard::DIED> should not die (behaviour is |
186 | The code reference stored in C<$Guard::DIED> should not die (behaviour is |
| 171 | not guaranteed, but right now, the exception will simply be ignored). |
187 | not guaranteed, but right now, the exception will simply be ignored). |
| 172 | |
188 | |
| 173 | The default for C<$Guard::DIED> is to call C<warn "$@">. |
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| 174 | |
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| 175 | =head1 AUTHOR |
189 | =head1 AUTHOR |
| 176 | |
190 | |
| 177 | Marc Lehmann <schmorp@schmorp.de> |
191 | Marc Lehmann <schmorp@schmorp.de> |
| 178 | http://home.schmorp.de/ |
192 | http://home.schmorp.de/ |
| 179 | |
193 | |
| 180 | =head1 THANKS |
194 | =head1 THANKS |
| 181 | |
195 | |
| 182 | Thanks to Marco Maisenhelder, who reminded me of the C<$Guard::DIED> |
196 | Thanks to Marco Maisenhelder, who reminded me of the C<$Guard::DIED> |
| 183 | solution to the problem of exceptions. |
197 | solution to the problem of exceptions. |
| 184 | |
198 | |
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199 | =head1 SEE ALSO |
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200 | |
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201 | L<Scope::Guard> and L<Sub::ScopeFinalizer>, which actually implement |
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202 | dynamic, not scoped guards, and have a lot higher CPU, memory and typing |
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203 | overhead. |
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204 | |
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205 | L<Hook::Scope>, which has apparently never been finished and corrupts |
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206 | memory when used. |
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207 | |
| 185 | =cut |
208 | =cut |
| 186 | |
209 | |
