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1 | =head1 NAME |
2 | |
3 | perlopentut - tutorial on opening things in Perl |
4 | |
5 | =head1 DESCRIPTION |
6 | |
7 | Perl has two simple, built-in ways to open files: the shell way for |
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8 | convenience, and the C way for precision. The shell way also has 2- and |
9 | 3-argument forms, which have different semantics for handling the filename. |
10 | The choice is yours. |
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11 | |
12 | =head1 Open E<agrave> la shell |
13 | |
14 | Perl's C<open> function was designed to mimic the way command-line |
15 | redirection in the shell works. Here are some basic examples |
16 | from the shell: |
17 | |
18 | $ myprogram file1 file2 file3 |
19 | $ myprogram < inputfile |
20 | $ myprogram > outputfile |
21 | $ myprogram >> outputfile |
22 | $ myprogram | otherprogram |
23 | $ otherprogram | myprogram |
24 | |
25 | And here are some more advanced examples: |
26 | |
27 | $ otherprogram | myprogram f1 - f2 |
28 | $ otherprogram 2>&1 | myprogram - |
29 | $ myprogram <&3 |
30 | $ myprogram >&4 |
31 | |
32 | Programmers accustomed to constructs like those above can take comfort |
33 | in learning that Perl directly supports these familiar constructs using |
34 | virtually the same syntax as the shell. |
35 | |
36 | =head2 Simple Opens |
37 | |
38 | The C<open> function takes two arguments: the first is a filehandle, |
39 | and the second is a single string comprising both what to open and how |
40 | to open it. C<open> returns true when it works, and when it fails, |
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41 | returns a false value and sets the special variable C<$!> to reflect |
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42 | the system error. If the filehandle was previously opened, it will |
43 | be implicitly closed first. |
44 | |
45 | For example: |
46 | |
47 | open(INFO, "datafile") || die("can't open datafile: $!"); |
48 | open(INFO, "< datafile") || die("can't open datafile: $!"); |
49 | open(RESULTS,"> runstats") || die("can't open runstats: $!"); |
50 | open(LOG, ">> logfile ") || die("can't open logfile: $!"); |
51 | |
52 | If you prefer the low-punctuation version, you could write that this way: |
53 | |
54 | open INFO, "< datafile" or die "can't open datafile: $!"; |
55 | open RESULTS,"> runstats" or die "can't open runstats: $!"; |
56 | open LOG, ">> logfile " or die "can't open logfile: $!"; |
57 | |
58 | A few things to notice. First, the leading less-than is optional. |
59 | If omitted, Perl assumes that you want to open the file for reading. |
60 | |
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61 | Note also that the first example uses the C<||> logical operator, and the |
62 | second uses C<or>, which has lower precedence. Using C<||> in the latter |
63 | examples would effectively mean |
64 | |
65 | open INFO, ( "< datafile" || die "can't open datafile: $!" ); |
66 | |
67 | which is definitely not what you want. |
68 | |
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69 | The other important thing to notice is that, just as in the shell, |
70 | any white space before or after the filename is ignored. This is good, |
71 | because you wouldn't want these to do different things: |
72 | |
73 | open INFO, "<datafile" |
74 | open INFO, "< datafile" |
75 | open INFO, "< datafile" |
76 | |
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77 | Ignoring surrounding whitespace also helps for when you read a filename |
78 | in from a different file, and forget to trim it before opening: |
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79 | |
80 | $filename = <INFO>; # oops, \n still there |
81 | open(EXTRA, "< $filename") || die "can't open $filename: $!"; |
82 | |
83 | This is not a bug, but a feature. Because C<open> mimics the shell in |
84 | its style of using redirection arrows to specify how to open the file, it |
85 | also does so with respect to extra white space around the filename itself |
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86 | as well. For accessing files with naughty names, see |
87 | L<"Dispelling the Dweomer">. |
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88 | |
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89 | There is also a 3-argument version of C<open>, which lets you put the |
90 | special redirection characters into their own argument: |
91 | |
92 | open( INFO, ">", $datafile ) || die "Can't create $datafile: $!"; |
93 | |
94 | In this case, the filename to open is the actual string in C<$datafile>, |
95 | so you don't have to worry about C<$datafile> containing characters |
96 | that might influence the open mode, or whitespace at the beginning of |
97 | the filename that would be absorbed in the 2-argument version. Also, |
98 | any reduction of unnecessary string interpolation is a good thing. |
99 | |
100 | =head2 Indirect Filehandles |
101 | |
102 | C<open>'s first argument can be a reference to a filehandle. As of |
103 | perl 5.6.0, if the argument is uninitialized, Perl will automatically |
104 | create a filehandle and put a reference to it in the first argument, |
105 | like so: |
106 | |
107 | open( my $in, $infile ) or die "Couldn't read $infile: $!"; |
108 | while ( <$in> ) { |
109 | # do something with $_ |
110 | } |
111 | close $in; |
112 | |
113 | Indirect filehandles make namespace management easier. Since filehandles |
114 | are global to the current package, two subroutines trying to open |
115 | C<INFILE> will clash. With two functions opening indirect filehandles |
116 | like C<my $infile>, there's no clash and no need to worry about future |
117 | conflicts. |
118 | |
119 | Another convenient behavior is that an indirect filehandle automatically |
120 | closes when it goes out of scope or when you undefine it: |
121 | |
122 | sub firstline { |
123 | open( my $in, shift ) && return scalar <$in>; |
124 | # no close() required |
125 | } |
126 | |
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127 | =head2 Pipe Opens |
128 | |
129 | In C, when you want to open a file using the standard I/O library, |
130 | you use the C<fopen> function, but when opening a pipe, you use the |
131 | C<popen> function. But in the shell, you just use a different redirection |
132 | character. That's also the case for Perl. The C<open> call |
133 | remains the same--just its argument differs. |
134 | |
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135 | If the leading character is a pipe symbol, C<open> starts up a new |
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136 | command and opens a write-only filehandle leading into that command. |
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137 | This lets you write into that handle and have what you write show up on |
138 | that command's standard input. For example: |
139 | |
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140 | open(PRINTER, "| lpr -Plp1") || die "can't run lpr: $!"; |
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141 | print PRINTER "stuff\n"; |
142 | close(PRINTER) || die "can't close lpr: $!"; |
143 | |
144 | If the trailing character is a pipe, you start up a new command and open a |
145 | read-only filehandle leading out of that command. This lets whatever that |
146 | command writes to its standard output show up on your handle for reading. |
147 | For example: |
148 | |
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149 | open(NET, "netstat -i -n |") || die "can't fork netstat: $!"; |
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150 | while (<NET>) { } # do something with input |
151 | close(NET) || die "can't close netstat: $!"; |
152 | |
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153 | What happens if you try to open a pipe to or from a non-existent |
154 | command? If possible, Perl will detect the failure and set C<$!> as |
155 | usual. But if the command contains special shell characters, such as |
156 | C<E<gt>> or C<*>, called 'metacharacters', Perl does not execute the |
157 | command directly. Instead, Perl runs the shell, which then tries to |
158 | run the command. This means that it's the shell that gets the error |
159 | indication. In such a case, the C<open> call will only indicate |
160 | failure if Perl can't even run the shell. See L<perlfaq8/"How can I |
161 | capture STDERR from an external command?"> to see how to cope with |
162 | this. There's also an explanation in L<perlipc>. |
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163 | |
164 | If you would like to open a bidirectional pipe, the IPC::Open2 |
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165 | library will handle this for you. Check out |
166 | L<perlipc/"Bidirectional Communication with Another Process"> |
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167 | |
168 | =head2 The Minus File |
169 | |
170 | Again following the lead of the standard shell utilities, Perl's |
171 | C<open> function treats a file whose name is a single minus, "-", in a |
172 | special way. If you open minus for reading, it really means to access |
173 | the standard input. If you open minus for writing, it really means to |
174 | access the standard output. |
175 | |
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176 | If minus can be used as the default input or default output, what happens |
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177 | if you open a pipe into or out of minus? What's the default command it |
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178 | would run? The same script as you're currently running! This is actually |
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179 | a stealth C<fork> hidden inside an C<open> call. See |
180 | L<perlipc/"Safe Pipe Opens"> for details. |
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181 | |
182 | =head2 Mixing Reads and Writes |
183 | |
184 | It is possible to specify both read and write access. All you do is |
185 | add a "+" symbol in front of the redirection. But as in the shell, |
186 | using a less-than on a file never creates a new file; it only opens an |
187 | existing one. On the other hand, using a greater-than always clobbers |
188 | (truncates to zero length) an existing file, or creates a brand-new one |
189 | if there isn't an old one. Adding a "+" for read-write doesn't affect |
190 | whether it only works on existing files or always clobbers existing ones. |
191 | |
192 | open(WTMP, "+< /usr/adm/wtmp") |
193 | || die "can't open /usr/adm/wtmp: $!"; |
194 | |
195 | open(SCREEN, "+> /tmp/lkscreen") |
196 | || die "can't open /tmp/lkscreen: $!"; |
197 | |
198 | open(LOGFILE, "+>> /tmp/applog" |
199 | || die "can't open /tmp/applog: $!"; |
200 | |
201 | The first one won't create a new file, and the second one will always |
202 | clobber an old one. The third one will create a new file if necessary |
203 | and not clobber an old one, and it will allow you to read at any point |
204 | in the file, but all writes will always go to the end. In short, |
205 | the first case is substantially more common than the second and third |
206 | cases, which are almost always wrong. (If you know C, the plus in |
207 | Perl's C<open> is historically derived from the one in C's fopen(3S), |
208 | which it ultimately calls.) |
209 | |
210 | In fact, when it comes to updating a file, unless you're working on |
211 | a binary file as in the WTMP case above, you probably don't want to |
212 | use this approach for updating. Instead, Perl's B<-i> flag comes to |
213 | the rescue. The following command takes all the C, C++, or yacc source |
214 | or header files and changes all their foo's to bar's, leaving |
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215 | the old version in the original filename with a ".orig" tacked |
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216 | on the end: |
217 | |
218 | $ perl -i.orig -pe 's/\bfoo\b/bar/g' *.[Cchy] |
219 | |
220 | This is a short cut for some renaming games that are really |
221 | the best way to update textfiles. See the second question in |
222 | L<perlfaq5> for more details. |
223 | |
224 | =head2 Filters |
225 | |
226 | One of the most common uses for C<open> is one you never |
227 | even notice. When you process the ARGV filehandle using |
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228 | C<< <ARGV> >>, Perl actually does an implicit open |
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229 | on each file in @ARGV. Thus a program called like this: |
230 | |
231 | $ myprogram file1 file2 file3 |
232 | |
233 | Can have all its files opened and processed one at a time |
234 | using a construct no more complex than: |
235 | |
236 | while (<>) { |
237 | # do something with $_ |
238 | } |
239 | |
240 | If @ARGV is empty when the loop first begins, Perl pretends you've opened |
241 | up minus, that is, the standard input. In fact, $ARGV, the currently |
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242 | open file during C<< <ARGV> >> processing, is even set to "-" |
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243 | in these circumstances. |
244 | |
245 | You are welcome to pre-process your @ARGV before starting the loop to |
246 | make sure it's to your liking. One reason to do this might be to remove |
247 | command options beginning with a minus. While you can always roll the |
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248 | simple ones by hand, the Getopts modules are good for this: |
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249 | |
250 | use Getopt::Std; |
251 | |
252 | # -v, -D, -o ARG, sets $opt_v, $opt_D, $opt_o |
253 | getopts("vDo:"); |
254 | |
255 | # -v, -D, -o ARG, sets $args{v}, $args{D}, $args{o} |
256 | getopts("vDo:", \%args); |
257 | |
258 | Or the standard Getopt::Long module to permit named arguments: |
259 | |
260 | use Getopt::Long; |
261 | GetOptions( "verbose" => \$verbose, # --verbose |
262 | "Debug" => \$debug, # --Debug |
263 | "output=s" => \$output ); |
264 | # --output=somestring or --output somestring |
265 | |
266 | Another reason for preprocessing arguments is to make an empty |
267 | argument list default to all files: |
268 | |
269 | @ARGV = glob("*") unless @ARGV; |
270 | |
271 | You could even filter out all but plain, text files. This is a bit |
272 | silent, of course, and you might prefer to mention them on the way. |
273 | |
274 | @ARGV = grep { -f && -T } @ARGV; |
275 | |
276 | If you're using the B<-n> or B<-p> command-line options, you |
277 | should put changes to @ARGV in a C<BEGIN{}> block. |
278 | |
279 | Remember that a normal C<open> has special properties, in that it might |
280 | call fopen(3S) or it might called popen(3S), depending on what its |
281 | argument looks like; that's why it's sometimes called "magic open". |
282 | Here's an example: |
283 | |
284 | $pwdinfo = `domainname` =~ /^(\(none\))?$/ |
285 | ? '< /etc/passwd' |
286 | : 'ypcat passwd |'; |
287 | |
288 | open(PWD, $pwdinfo) |
289 | or die "can't open $pwdinfo: $!"; |
290 | |
291 | This sort of thing also comes into play in filter processing. Because |
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292 | C<< <ARGV> >> processing employs the normal, shell-style Perl C<open>, |
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293 | it respects all the special things we've already seen: |
294 | |
295 | $ myprogram f1 "cmd1|" - f2 "cmd2|" f3 < tmpfile |
296 | |
297 | That program will read from the file F<f1>, the process F<cmd1>, standard |
298 | input (F<tmpfile> in this case), the F<f2> file, the F<cmd2> command, |
299 | and finally the F<f3> file. |
300 | |
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301 | Yes, this also means that if you have files named "-" (and so on) in |
302 | your directory, they won't be processed as literal files by C<open>. |
303 | You'll need to pass them as "./-", much as you would for the I<rm> program, |
304 | or you could use C<sysopen> as described below. |
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305 | |
306 | One of the more interesting applications is to change files of a certain |
307 | name into pipes. For example, to autoprocess gzipped or compressed |
308 | files by decompressing them with I<gzip>: |
309 | |
310 | @ARGV = map { /^\.(gz|Z)$/ ? "gzip -dc $_ |" : $_ } @ARGV; |
311 | |
312 | Or, if you have the I<GET> program installed from LWP, |
313 | you can fetch URLs before processing them: |
314 | |
315 | @ARGV = map { m#^\w+://# ? "GET $_ |" : $_ } @ARGV; |
316 | |
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317 | It's not for nothing that this is called magic C<< <ARGV> >>. |
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318 | Pretty nifty, eh? |
319 | |
320 | =head1 Open E<agrave> la C |
321 | |
322 | If you want the convenience of the shell, then Perl's C<open> is |
323 | definitely the way to go. On the other hand, if you want finer precision |
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324 | than C's simplistic fopen(3S) provides you should look to Perl's |
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325 | C<sysopen>, which is a direct hook into the open(2) system call. |
326 | That does mean it's a bit more involved, but that's the price of |
327 | precision. |
328 | |
329 | C<sysopen> takes 3 (or 4) arguments. |
330 | |
331 | sysopen HANDLE, PATH, FLAGS, [MASK] |
332 | |
333 | The HANDLE argument is a filehandle just as with C<open>. The PATH is |
334 | a literal path, one that doesn't pay attention to any greater-thans or |
335 | less-thans or pipes or minuses, nor ignore white space. If it's there, |
336 | it's part of the path. The FLAGS argument contains one or more values |
337 | derived from the Fcntl module that have been or'd together using the |
338 | bitwise "|" operator. The final argument, the MASK, is optional; if |
339 | present, it is combined with the user's current umask for the creation |
340 | mode of the file. You should usually omit this. |
341 | |
342 | Although the traditional values of read-only, write-only, and read-write |
343 | are 0, 1, and 2 respectively, this is known not to hold true on some |
344 | systems. Instead, it's best to load in the appropriate constants first |
345 | from the Fcntl module, which supplies the following standard flags: |
346 | |
347 | O_RDONLY Read only |
348 | O_WRONLY Write only |
349 | O_RDWR Read and write |
350 | O_CREAT Create the file if it doesn't exist |
351 | O_EXCL Fail if the file already exists |
352 | O_APPEND Append to the file |
353 | O_TRUNC Truncate the file |
354 | O_NONBLOCK Non-blocking access |
355 | |
ca6e1c26 |
356 | Less common flags that are sometimes available on some operating |
357 | systems include C<O_BINARY>, C<O_TEXT>, C<O_SHLOCK>, C<O_EXLOCK>, |
358 | C<O_DEFER>, C<O_SYNC>, C<O_ASYNC>, C<O_DSYNC>, C<O_RSYNC>, |
359 | C<O_NOCTTY>, C<O_NDELAY> and C<O_LARGEFILE>. Consult your open(2) |
360 | manpage or its local equivalent for details. (Note: starting from |
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361 | Perl release 5.6 the C<O_LARGEFILE> flag, if available, is automatically |
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362 | added to the sysopen() flags because large files are the default.) |
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363 | |
364 | Here's how to use C<sysopen> to emulate the simple C<open> calls we had |
365 | before. We'll omit the C<|| die $!> checks for clarity, but make sure |
366 | you always check the return values in real code. These aren't quite |
367 | the same, since C<open> will trim leading and trailing white space, |
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368 | but you'll get the idea. |
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369 | |
370 | To open a file for reading: |
371 | |
372 | open(FH, "< $path"); |
373 | sysopen(FH, $path, O_RDONLY); |
374 | |
375 | To open a file for writing, creating a new file if needed or else truncating |
376 | an old file: |
377 | |
378 | open(FH, "> $path"); |
379 | sysopen(FH, $path, O_WRONLY | O_TRUNC | O_CREAT); |
380 | |
381 | To open a file for appending, creating one if necessary: |
382 | |
383 | open(FH, ">> $path"); |
384 | sysopen(FH, $path, O_WRONLY | O_APPEND | O_CREAT); |
385 | |
386 | To open a file for update, where the file must already exist: |
387 | |
388 | open(FH, "+< $path"); |
389 | sysopen(FH, $path, O_RDWR); |
390 | |
391 | And here are things you can do with C<sysopen> that you cannot do with |
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392 | a regular C<open>. As you'll see, it's just a matter of controlling the |
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393 | flags in the third argument. |
394 | |
395 | To open a file for writing, creating a new file which must not previously |
396 | exist: |
397 | |
398 | sysopen(FH, $path, O_WRONLY | O_EXCL | O_CREAT); |
399 | |
400 | To open a file for appending, where that file must already exist: |
401 | |
402 | sysopen(FH, $path, O_WRONLY | O_APPEND); |
403 | |
404 | To open a file for update, creating a new file if necessary: |
405 | |
406 | sysopen(FH, $path, O_RDWR | O_CREAT); |
407 | |
408 | To open a file for update, where that file must not already exist: |
409 | |
410 | sysopen(FH, $path, O_RDWR | O_EXCL | O_CREAT); |
411 | |
412 | To open a file without blocking, creating one if necessary: |
413 | |
414 | sysopen(FH, $path, O_WRONLY | O_NONBLOCK | O_CREAT); |
415 | |
416 | =head2 Permissions E<agrave> la mode |
417 | |
418 | If you omit the MASK argument to C<sysopen>, Perl uses the octal value |
419 | 0666. The normal MASK to use for executables and directories should |
420 | be 0777, and for anything else, 0666. |
421 | |
422 | Why so permissive? Well, it isn't really. The MASK will be modified |
423 | by your process's current C<umask>. A umask is a number representing |
424 | I<disabled> permissions bits; that is, bits that will not be turned on |
425 | in the created files' permissions field. |
426 | |
427 | For example, if your C<umask> were 027, then the 020 part would |
428 | disable the group from writing, and the 007 part would disable others |
429 | from reading, writing, or executing. Under these conditions, passing |
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430 | C<sysopen> 0666 would create a file with mode 0640, since C<0666 & ~027> |
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431 | is 0640. |
432 | |
433 | You should seldom use the MASK argument to C<sysopen()>. That takes |
434 | away the user's freedom to choose what permission new files will have. |
435 | Denying choice is almost always a bad thing. One exception would be for |
436 | cases where sensitive or private data is being stored, such as with mail |
437 | folders, cookie files, and internal temporary files. |
438 | |
439 | =head1 Obscure Open Tricks |
440 | |
441 | =head2 Re-Opening Files (dups) |
442 | |
443 | Sometimes you already have a filehandle open, and want to make another |
444 | handle that's a duplicate of the first one. In the shell, we place an |
445 | ampersand in front of a file descriptor number when doing redirections. |
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446 | For example, C<< 2>&1 >> makes descriptor 2 (that's STDERR in Perl) |
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447 | be redirected into descriptor 1 (which is usually Perl's STDOUT). |
448 | The same is essentially true in Perl: a filename that begins with an |
449 | ampersand is treated instead as a file descriptor if a number, or as a |
450 | filehandle if a string. |
451 | |
452 | open(SAVEOUT, ">&SAVEERR") || die "couldn't dup SAVEERR: $!"; |
453 | open(MHCONTEXT, "<&4") || die "couldn't dup fd4: $!"; |
454 | |
455 | That means that if a function is expecting a filename, but you don't |
456 | want to give it a filename because you already have the file open, you |
457 | can just pass the filehandle with a leading ampersand. It's best to |
458 | use a fully qualified handle though, just in case the function happens |
459 | to be in a different package: |
460 | |
461 | somefunction("&main::LOGFILE"); |
462 | |
463 | This way if somefunction() is planning on opening its argument, it can |
464 | just use the already opened handle. This differs from passing a handle, |
465 | because with a handle, you don't open the file. Here you have something |
466 | you can pass to open. |
467 | |
468 | If you have one of those tricky, newfangled I/O objects that the C++ |
469 | folks are raving about, then this doesn't work because those aren't a |
470 | proper filehandle in the native Perl sense. You'll have to use fileno() |
471 | to pull out the proper descriptor number, assuming you can: |
472 | |
473 | use IO::Socket; |
474 | $handle = IO::Socket::INET->new("www.perl.com:80"); |
475 | $fd = $handle->fileno; |
476 | somefunction("&$fd"); # not an indirect function call |
477 | |
478 | It can be easier (and certainly will be faster) just to use real |
479 | filehandles though: |
480 | |
481 | use IO::Socket; |
482 | local *REMOTE = IO::Socket::INET->new("www.perl.com:80"); |
483 | die "can't connect" unless defined(fileno(REMOTE)); |
484 | somefunction("&main::REMOTE"); |
485 | |
486 | If the filehandle or descriptor number is preceded not just with a simple |
487 | "&" but rather with a "&=" combination, then Perl will not create a |
488 | completely new descriptor opened to the same place using the dup(2) |
489 | system call. Instead, it will just make something of an alias to the |
490 | existing one using the fdopen(3S) library call This is slightly more |
491 | parsimonious of systems resources, although this is less a concern |
492 | these days. Here's an example of that: |
493 | |
494 | $fd = $ENV{"MHCONTEXTFD"}; |
495 | open(MHCONTEXT, "<&=$fd") or die "couldn't fdopen $fd: $!"; |
496 | |
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497 | If you're using magic C<< <ARGV> >>, you could even pass in as a |
498 | command line argument in @ARGV something like C<"<&=$MHCONTEXTFD">, |
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499 | but we've never seen anyone actually do this. |
500 | |
501 | =head2 Dispelling the Dweomer |
502 | |
503 | Perl is more of a DWIMmer language than something like Java--where DWIM |
504 | is an acronym for "do what I mean". But this principle sometimes leads |
505 | to more hidden magic than one knows what to do with. In this way, Perl |
506 | is also filled with I<dweomer>, an obscure word meaning an enchantment. |
507 | Sometimes, Perl's DWIMmer is just too much like dweomer for comfort. |
508 | |
509 | If magic C<open> is a bit too magical for you, you don't have to turn |
510 | to C<sysopen>. To open a file with arbitrary weird characters in |
511 | it, it's necessary to protect any leading and trailing whitespace. |
512 | Leading whitespace is protected by inserting a C<"./"> in front of a |
513 | filename that starts with whitespace. Trailing whitespace is protected |
1a193132 |
514 | by appending an ASCII NUL byte (C<"\0">) at the end of the string. |
f8284313 |
515 | |
516 | $file =~ s#^(\s)#./$1#; |
517 | open(FH, "< $file\0") || die "can't open $file: $!"; |
518 | |
519 | This assumes, of course, that your system considers dot the current |
520 | working directory, slash the directory separator, and disallows ASCII |
521 | NULs within a valid filename. Most systems follow these conventions, |
522 | including all POSIX systems as well as proprietary Microsoft systems. |
523 | The only vaguely popular system that doesn't work this way is the |
524 | proprietary Macintosh system, which uses a colon where the rest of us |
525 | use a slash. Maybe C<sysopen> isn't such a bad idea after all. |
526 | |
c47ff5f1 |
527 | If you want to use C<< <ARGV> >> processing in a totally boring |
f8284313 |
528 | and non-magical way, you could do this first: |
529 | |
530 | # "Sam sat on the ground and put his head in his hands. |
531 | # 'I wish I had never come here, and I don't want to see |
532 | # no more magic,' he said, and fell silent." |
533 | for (@ARGV) { |
534 | s#^([^./])#./$1#; |
535 | $_ .= "\0"; |
536 | } |
537 | while (<>) { |
538 | # now process $_ |
539 | } |
540 | |
541 | But be warned that users will not appreciate being unable to use "-" |
542 | to mean standard input, per the standard convention. |
543 | |
544 | =head2 Paths as Opens |
545 | |
546 | You've probably noticed how Perl's C<warn> and C<die> functions can |
547 | produce messages like: |
548 | |
1761cee5 |
549 | Some warning at scriptname line 29, <FH> line 7. |
f8284313 |
550 | |
551 | That's because you opened a filehandle FH, and had read in seven records |
1a193132 |
552 | from it. But what was the name of the file, rather than the handle? |
f8284313 |
553 | |
1a193132 |
554 | If you aren't running with C<strict refs>, or if you've turned them off |
f8284313 |
555 | temporarily, then all you have to do is this: |
556 | |
557 | open($path, "< $path") || die "can't open $path: $!"; |
558 | while (<$path>) { |
559 | # whatever |
560 | } |
561 | |
562 | Since you're using the pathname of the file as its handle, |
563 | you'll get warnings more like |
564 | |
1761cee5 |
565 | Some warning at scriptname line 29, </etc/motd> line 7. |
f8284313 |
566 | |
567 | =head2 Single Argument Open |
568 | |
569 | Remember how we said that Perl's open took two arguments? That was a |
570 | passive prevarication. You see, it can also take just one argument. |
571 | If and only if the variable is a global variable, not a lexical, you |
572 | can pass C<open> just one argument, the filehandle, and it will |
573 | get the path from the global scalar variable of the same name. |
574 | |
575 | $FILE = "/etc/motd"; |
576 | open FILE or die "can't open $FILE: $!"; |
577 | while (<FILE>) { |
578 | # whatever |
579 | } |
580 | |
581 | Why is this here? Someone has to cater to the hysterical porpoises. |
582 | It's something that's been in Perl since the very beginning, if not |
583 | before. |
584 | |
585 | =head2 Playing with STDIN and STDOUT |
586 | |
587 | One clever move with STDOUT is to explicitly close it when you're done |
588 | with the program. |
589 | |
590 | END { close(STDOUT) || die "can't close stdout: $!" } |
591 | |
592 | If you don't do this, and your program fills up the disk partition due |
593 | to a command line redirection, it won't report the error exit with a |
594 | failure status. |
595 | |
596 | You don't have to accept the STDIN and STDOUT you were given. You are |
597 | welcome to reopen them if you'd like. |
598 | |
599 | open(STDIN, "< datafile") |
600 | || die "can't open datafile: $!"; |
601 | |
602 | open(STDOUT, "> output") |
603 | || die "can't open output: $!"; |
604 | |
00dcde61 |
605 | And then these can be accessed directly or passed on to subprocesses. |
f8284313 |
606 | This makes it look as though the program were initially invoked |
607 | with those redirections from the command line. |
608 | |
609 | It's probably more interesting to connect these to pipes. For example: |
610 | |
611 | $pager = $ENV{PAGER} || "(less || more)"; |
612 | open(STDOUT, "| $pager") |
613 | || die "can't fork a pager: $!"; |
614 | |
615 | This makes it appear as though your program were called with its stdout |
616 | already piped into your pager. You can also use this kind of thing |
617 | in conjunction with an implicit fork to yourself. You might do this |
618 | if you would rather handle the post processing in your own program, |
619 | just in a different process: |
620 | |
621 | head(100); |
622 | while (<>) { |
623 | print; |
624 | } |
625 | |
626 | sub head { |
627 | my $lines = shift || 20; |
628 | return unless $pid = open(STDOUT, "|-"); |
629 | die "cannot fork: $!" unless defined $pid; |
630 | while (<STDIN>) { |
631 | print; |
632 | last if --$lines < 0; |
633 | } |
634 | exit; |
635 | } |
636 | |
637 | This technique can be applied to repeatedly push as many filters on your |
638 | output stream as you wish. |
639 | |
640 | =head1 Other I/O Issues |
641 | |
642 | These topics aren't really arguments related to C<open> or C<sysopen>, |
643 | but they do affect what you do with your open files. |
644 | |
645 | =head2 Opening Non-File Files |
646 | |
647 | When is a file not a file? Well, you could say when it exists but |
648 | isn't a plain file. We'll check whether it's a symbolic link first, |
649 | just in case. |
650 | |
651 | if (-l $file || ! -f _) { |
652 | print "$file is not a plain file\n"; |
653 | } |
654 | |
655 | What other kinds of files are there than, well, files? Directories, |
656 | symbolic links, named pipes, Unix-domain sockets, and block and character |
657 | devices. Those are all files, too--just not I<plain> files. This isn't |
658 | the same issue as being a text file. Not all text files are plain files. |
1a193132 |
659 | Not all plain files are text files. That's why there are separate C<-f> |
f8284313 |
660 | and C<-T> file tests. |
661 | |
662 | To open a directory, you should use the C<opendir> function, then |
663 | process it with C<readdir>, carefully restoring the directory |
664 | name if necessary: |
665 | |
666 | opendir(DIR, $dirname) or die "can't opendir $dirname: $!"; |
667 | while (defined($file = readdir(DIR))) { |
668 | # do something with "$dirname/$file" |
669 | } |
670 | closedir(DIR); |
671 | |
672 | If you want to process directories recursively, it's better to use the |
1a193132 |
673 | File::Find module. For example, this prints out all files recursively |
674 | and adds a slash to their names if the file is a directory. |
f8284313 |
675 | |
676 | @ARGV = qw(.) unless @ARGV; |
677 | use File::Find; |
678 | find sub { print $File::Find::name, -d && '/', "\n" }, @ARGV; |
679 | |
680 | This finds all bogus symbolic links beneath a particular directory: |
681 | |
682 | find sub { print "$File::Find::name\n" if -l && !-e }, $dir; |
683 | |
684 | As you see, with symbolic links, you can just pretend that it is |
685 | what it points to. Or, if you want to know I<what> it points to, then |
686 | C<readlink> is called for: |
687 | |
688 | if (-l $file) { |
689 | if (defined($whither = readlink($file))) { |
690 | print "$file points to $whither\n"; |
691 | } else { |
692 | print "$file points nowhere: $!\n"; |
693 | } |
694 | } |
695 | |
1a193132 |
696 | =head2 Opening Named Pipes |
697 | |
f8284313 |
698 | Named pipes are a different matter. You pretend they're regular files, |
699 | but their opens will normally block until there is both a reader and |
700 | a writer. You can read more about them in L<perlipc/"Named Pipes">. |
701 | Unix-domain sockets are rather different beasts as well; they're |
702 | described in L<perlipc/"Unix-Domain TCP Clients and Servers">. |
703 | |
1a193132 |
704 | When it comes to opening devices, it can be easy and it can be tricky. |
f8284313 |
705 | We'll assume that if you're opening up a block device, you know what |
706 | you're doing. The character devices are more interesting. These are |
707 | typically used for modems, mice, and some kinds of printers. This is |
708 | described in L<perlfaq8/"How do I read and write the serial port?"> |
709 | It's often enough to open them carefully: |
710 | |
711 | sysopen(TTYIN, "/dev/ttyS1", O_RDWR | O_NDELAY | O_NOCTTY) |
712 | # (O_NOCTTY no longer needed on POSIX systems) |
713 | or die "can't open /dev/ttyS1: $!"; |
714 | open(TTYOUT, "+>&TTYIN") |
715 | or die "can't dup TTYIN: $!"; |
716 | |
717 | $ofh = select(TTYOUT); $| = 1; select($ofh); |
718 | |
719 | print TTYOUT "+++at\015"; |
720 | $answer = <TTYIN>; |
721 | |
1a193132 |
722 | With descriptors that you haven't opened using C<sysopen>, such as |
723 | sockets, you can set them to be non-blocking using C<fcntl>: |
f8284313 |
724 | |
725 | use Fcntl; |
726 | fcntl(Connection, F_SETFL, O_NONBLOCK) |
727 | or die "can't set non blocking: $!"; |
728 | |
729 | Rather than losing yourself in a morass of twisting, turning C<ioctl>s, |
730 | all dissimilar, if you're going to manipulate ttys, it's best to |
731 | make calls out to the stty(1) program if you have it, or else use the |
732 | portable POSIX interface. To figure this all out, you'll need to read the |
733 | termios(3) manpage, which describes the POSIX interface to tty devices, |
734 | and then L<POSIX>, which describes Perl's interface to POSIX. There are |
735 | also some high-level modules on CPAN that can help you with these games. |
736 | Check out Term::ReadKey and Term::ReadLine. |
737 | |
1a193132 |
738 | =head2 Opening Sockets |
739 | |
f8284313 |
740 | What else can you open? To open a connection using sockets, you won't use |
13a2d996 |
741 | one of Perl's two open functions. See |
742 | L<perlipc/"Sockets: Client/Server Communication"> for that. Here's an |
743 | example. Once you have it, you can use FH as a bidirectional filehandle. |
f8284313 |
744 | |
745 | use IO::Socket; |
746 | local *FH = IO::Socket::INET->new("www.perl.com:80"); |
747 | |
748 | For opening up a URL, the LWP modules from CPAN are just what |
749 | the doctor ordered. There's no filehandle interface, but |
750 | it's still easy to get the contents of a document: |
751 | |
752 | use LWP::Simple; |
6cecdcac |
753 | $doc = get('http://www.linpro.no/lwp/'); |
f8284313 |
754 | |
755 | =head2 Binary Files |
756 | |
757 | On certain legacy systems with what could charitably be called terminally |
758 | convoluted (some would say broken) I/O models, a file isn't a file--at |
759 | least, not with respect to the C standard I/O library. On these old |
760 | systems whose libraries (but not kernels) distinguish between text and |
761 | binary streams, to get files to behave properly you'll have to bend over |
762 | backwards to avoid nasty problems. On such infelicitous systems, sockets |
763 | and pipes are already opened in binary mode, and there is currently no |
764 | way to turn that off. With files, you have more options. |
765 | |
766 | Another option is to use the C<binmode> function on the appropriate |
767 | handles before doing regular I/O on them: |
768 | |
769 | binmode(STDIN); |
770 | binmode(STDOUT); |
771 | while (<STDIN>) { print } |
772 | |
773 | Passing C<sysopen> a non-standard flag option will also open the file in |
774 | binary mode on those systems that support it. This is the equivalent of |
1a193132 |
775 | opening the file normally, then calling C<binmode> on the handle. |
f8284313 |
776 | |
777 | sysopen(BINDAT, "records.data", O_RDWR | O_BINARY) |
778 | || die "can't open records.data: $!"; |
779 | |
780 | Now you can use C<read> and C<print> on that handle without worrying |
1a193132 |
781 | about the non-standard system I/O library breaking your data. It's not |
f8284313 |
782 | a pretty picture, but then, legacy systems seldom are. CP/M will be |
783 | with us until the end of days, and after. |
784 | |
785 | On systems with exotic I/O systems, it turns out that, astonishingly |
786 | enough, even unbuffered I/O using C<sysread> and C<syswrite> might do |
787 | sneaky data mutilation behind your back. |
788 | |
789 | while (sysread(WHENCE, $buf, 1024)) { |
790 | syswrite(WHITHER, $buf, length($buf)); |
791 | } |
792 | |
793 | Depending on the vicissitudes of your runtime system, even these calls |
794 | may need C<binmode> or C<O_BINARY> first. Systems known to be free of |
e6f03d26 |
795 | such difficulties include Unix, the Mac OS, Plan 9, and Inferno. |
f8284313 |
796 | |
797 | =head2 File Locking |
798 | |
799 | In a multitasking environment, you may need to be careful not to collide |
1a193132 |
800 | with other processes who want to do I/O on the same files as you |
f8284313 |
801 | are working on. You'll often need shared or exclusive locks |
802 | on files for reading and writing respectively. You might just |
803 | pretend that only exclusive locks exist. |
804 | |
805 | Never use the existence of a file C<-e $file> as a locking indication, |
806 | because there is a race condition between the test for the existence of |
1a193132 |
807 | the file and its creation. It's possible for another process to create |
808 | a file in the slice of time between your existence check and your attempt |
809 | to create the file. Atomicity is critical. |
f8284313 |
810 | |
811 | Perl's most portable locking interface is via the C<flock> function, |
1a193132 |
812 | whose simplicity is emulated on systems that don't directly support it |
813 | such as SysV or Windows. The underlying semantics may affect how |
f8284313 |
814 | it all works, so you should learn how C<flock> is implemented on your |
815 | system's port of Perl. |
816 | |
817 | File locking I<does not> lock out another process that would like to |
818 | do I/O. A file lock only locks out others trying to get a lock, not |
819 | processes trying to do I/O. Because locks are advisory, if one process |
820 | uses locking and another doesn't, all bets are off. |
821 | |
822 | By default, the C<flock> call will block until a lock is granted. |
823 | A request for a shared lock will be granted as soon as there is no |
d1be9408 |
824 | exclusive locker. A request for an exclusive lock will be granted as |
f8284313 |
825 | soon as there is no locker of any kind. Locks are on file descriptors, |
826 | not file names. You can't lock a file until you open it, and you can't |
827 | hold on to a lock once the file has been closed. |
828 | |
829 | Here's how to get a blocking shared lock on a file, typically used |
830 | for reading: |
831 | |
832 | use 5.004; |
833 | use Fcntl qw(:DEFAULT :flock); |
834 | open(FH, "< filename") or die "can't open filename: $!"; |
835 | flock(FH, LOCK_SH) or die "can't lock filename: $!"; |
836 | # now read from FH |
837 | |
838 | You can get a non-blocking lock by using C<LOCK_NB>. |
839 | |
840 | flock(FH, LOCK_SH | LOCK_NB) |
841 | or die "can't lock filename: $!"; |
842 | |
843 | This can be useful for producing more user-friendly behaviour by warning |
844 | if you're going to be blocking: |
845 | |
846 | use 5.004; |
847 | use Fcntl qw(:DEFAULT :flock); |
848 | open(FH, "< filename") or die "can't open filename: $!"; |
849 | unless (flock(FH, LOCK_SH | LOCK_NB)) { |
850 | $| = 1; |
851 | print "Waiting for lock..."; |
852 | flock(FH, LOCK_SH) or die "can't lock filename: $!"; |
853 | print "got it.\n" |
854 | } |
855 | # now read from FH |
856 | |
857 | To get an exclusive lock, typically used for writing, you have to be |
858 | careful. We C<sysopen> the file so it can be locked before it gets |
859 | emptied. You can get a nonblocking version using C<LOCK_EX | LOCK_NB>. |
860 | |
861 | use 5.004; |
862 | use Fcntl qw(:DEFAULT :flock); |
863 | sysopen(FH, "filename", O_WRONLY | O_CREAT) |
864 | or die "can't open filename: $!"; |
865 | flock(FH, LOCK_EX) |
866 | or die "can't lock filename: $!"; |
867 | truncate(FH, 0) |
868 | or die "can't truncate filename: $!"; |
869 | # now write to FH |
870 | |
871 | Finally, due to the uncounted millions who cannot be dissuaded from |
872 | wasting cycles on useless vanity devices called hit counters, here's |
873 | how to increment a number in a file safely: |
874 | |
875 | use Fcntl qw(:DEFAULT :flock); |
876 | |
877 | sysopen(FH, "numfile", O_RDWR | O_CREAT) |
878 | or die "can't open numfile: $!"; |
879 | # autoflush FH |
880 | $ofh = select(FH); $| = 1; select ($ofh); |
881 | flock(FH, LOCK_EX) |
882 | or die "can't write-lock numfile: $!"; |
883 | |
884 | $num = <FH> || 0; |
885 | seek(FH, 0, 0) |
886 | or die "can't rewind numfile : $!"; |
887 | print FH $num+1, "\n" |
888 | or die "can't write numfile: $!"; |
889 | |
890 | truncate(FH, tell(FH)) |
891 | or die "can't truncate numfile: $!"; |
892 | close(FH) |
893 | or die "can't close numfile: $!"; |
894 | |
ae258fbb |
895 | =head2 IO Layers |
896 | |
897 | In Perl 5.8.0 a new I/O framework called "PerlIO" was introduced. |
898 | This is a new "plumbing" for all the I/O happening in Perl; for the |
1a193132 |
899 | most part everything will work just as it did, but PerlIO also brought |
900 | in some new features such as the ability to think of I/O as "layers". |
ae258fbb |
901 | One I/O layer may in addition to just moving the data also do |
902 | transformations on the data. Such transformations may include |
903 | compression and decompression, encryption and decryption, and transforming |
904 | between various character encodings. |
905 | |
906 | Full discussion about the features of PerlIO is out of scope for this |
907 | tutorial, but here is how to recognize the layers being used: |
908 | |
909 | =over 4 |
910 | |
911 | =item * |
912 | |
1a193132 |
913 | The three-(or more)-argument form of C<open> is being used and the |
ae258fbb |
914 | second argument contains something else in addition to the usual |
915 | C<< '<' >>, C<< '>' >>, C<< '>>' >>, C<< '|' >> and their variants, |
916 | for example: |
917 | |
918 | open(my $fh, "<:utf8", $fn); |
919 | |
920 | =item * |
921 | |
1a193132 |
922 | The two-argument form of C<binmode> is being used, for example |
ae258fbb |
923 | |
924 | binmode($fh, ":encoding(utf16)"); |
925 | |
926 | =back |
927 | |
80fea0d2 |
928 | For more detailed discussion about PerlIO see L<PerlIO>; |
ae258fbb |
929 | for more detailed discussion about Unicode and I/O see L<perluniintro>. |
930 | |
f8284313 |
931 | =head1 SEE ALSO |
932 | |
1a193132 |
933 | The C<open> and C<sysopen> functions in perlfunc(1); |
934 | the system open(2), dup(2), fopen(3), and fdopen(3) manpages; |
f8284313 |
935 | the POSIX documentation. |
936 | |
937 | =head1 AUTHOR and COPYRIGHT |
938 | |
939 | Copyright 1998 Tom Christiansen. |
940 | |
5a7beb56 |
941 | This documentation is free; you can redistribute it and/or modify it |
942 | under the same terms as Perl itself. |
f8284313 |
943 | |
944 | Irrespective of its distribution, all code examples in these files are |
945 | hereby placed into the public domain. You are permitted and |
946 | encouraged to use this code in your own programs for fun or for profit |
947 | as you see fit. A simple comment in the code giving credit would be |
948 | courteous but is not required. |
949 | |
950 | =head1 HISTORY |
951 | |
952 | First release: Sat Jan 9 08:09:11 MST 1999 |