Provided by: libparanoid-perl_2.09-1_all 
NAME
Paranoid::IO - Paranoid IO support
VERSION
$Id: lib/Paranoid/IO.pm, 2.09 2021/12/28 15:46:49 acorliss Exp $
SYNOPSIS
use Fcntl qw(:DEFAULT :flock :mode :seek);
use Paranoid::IO;
# Implicit open
$chars = pread("./foo.log", $in, 2048);
# Implcit write/append
$chars = pwrite("./bar.log", $out);
$chars = pappend("./bar.log", $out);
# Adjust block read size
PIOBLKSIZE = 8192;
# Adjust max file size for file scans
PIOMAXFSIZE = 65536;
# Enable flock lock stack
PIOLOCKSTACK = 1;
# Explicit open
$fh = popen($filename, O_RDWR | O_CREAT | O_TRUNC, 0600);
$rv = pseek($filename, 0, SEEK_END);
$rv = pflock($filename, LOCK_EX);
if ($rv > 0) {
pseek($filename, 0, SEEK_SET) && ptruncate($filename);
}
$rv = pwrite($fileanme, $text) && pclose($filename);
$rv = plockstat($filename);
$rv = pclose($filename);
DESCRIPTION
Paranoid::IO is intended to make basic file I/O access easier while keeping with the tenets of paranoid
programming. Most of these calls are essentially wrappers for the basic system calls (exposed as
sysopen, syswrite, etc.) with some additional logic to reduce the need to explicitly code every step of
normal safe access rules, such as file locking. In the most basic of usage patterns, even explicitly
opening files isn't necessary.
For the most part the system calls that are wrapped here act identically as the underlying calls, both in
the arguments they take and the values they return. The one notable difference, however, is the popen
function itself. A glob variable isn't passed for assignation since this module stores those references
internally along with some meta data, so popen returns file handles directly.
That semantic, however, is what gives the rest of the functions the flexibility of accepting either a
file name or a file handle to work on. In the case of file names some of these functions can open files
automatically, and the rest of the features are granted automatically.
In the case of passing file handles the full feature set of this module is only available if the file
handle was originally opened with popen. The calls will still work even if it wasn't, but some of the
safety features, like being fork-safe, won't have the meta data to work properly.
The features provided by this module are:
• Opportunistic file access
• File handle caching
• Fork-safe file access
• Inherent file locking
• O_APPEND access patterns where needed even for files not opened with O_APPEND
• Intelligent file tracking
• Optional flock lock stack for transactional I/O patterns
The following sections will explain each feature in more depth:
Opportunistic file access
Opportunistic file access is defined here as not needing the explicit I/O handling for what can be
implied. For instance, to read content from a file one can simply use the pread function without having
to open and apply a shared file lock. In a similar manner one should be able to write or append to a
file. Files are automatically opened (with the file mode being intuited by the type of call) as needed.
Only where more complicated access patterns (such as read/write file handles) should an explicit popen
call be needed.
Opportunism is limited to where it makes sense, however. Files are not opportunistically opened if the
first I/O call is to pseek, ptell, or pflock. The intent of the file I/O (in regards to read/write file
modes) is impossible to tell within those calls.
File handle caching
This module provides a replacement for Perl's internal sysopen, which should be used even where
read/write file access is necessary. One key benefit for doing so is that it provides internal file
handle caching based on the file name. All the additional functions provided by this module use it
internally to retrieve that cached file handle to avoid the overhead of repetitive opening and closing of
files.
Fork-safe file access
A greater benefit of popen, however, is in it's fork-safe behavior. Every call checks to see if the file
handle it has was inherited from its parent, and if so, transparently closed and reopened so I/O can
continue without both processes conflicting over cursor positions and buffers. After files are reopened
read cursors are placed at the same location they were prior to the first I/O access in the child.
File modes are preserved without the obvious conflicts of intent as well. Files opened in the parent
with O_TRUNC are reopened without that flag to prevent content from being clobbered.
Inherent file locking
Except where explicitly ignored (like for pnlread) all read, write, and append operations use locking
internally, alleviating the need for the developer to do so explicitly. Locks are applied and removed as
quickly as possible to facilitate concurrent access.
If you're managing flocks directly, however, all of the read/write functions in this module not only
support an option boolean argument to disable internal flocking, but also have pnl* wrapper functions
that set that argument for you.
O_APPEND access patterns
pappend allows you to mimic O_APPEND access patterns even for files that weren't explicitly opened with
O_APPEND. If you open a file with O_RDWR you can still call pappend and the content will be appended to
the end of the file, without moving the file's cursor position for regular reads and writes.
Intelligent file tracking
popen caches file handles by file name. If files are opened with relative paths this has the potential
to cause some confusion if the process or children are changing their working directories. In
anticipation of this popen also tracks the real path (as resolved by the realpath system call) and file
name. This way you can still access the same file regardless of the process or its children's movements
on the file system.
This could be, however, a double-edged sword if your program intends to open identically named files in
multiple locations. If that is your intent you would be cautioned to avoid using relative paths with
popen.
Optional flock lock stack for transactional I/O patterns
Complex I/O patterns on file I/O can sometimes extensive nested function calls that each manipulate
flocks independently. Those nested calls can come into conflict when one call degrades a needed lock
applied by a previous call.
For instance, a pattern where a new block needs to be allocated to an opened file, but an index of blocks
must be maintained within the same file. One might have a function which retrieves the list of block
addresses from the index, and that function rationally applies a shared flock before reading, and removes
it afterwards. One might try to get an exclusive lock on the file, then retrieve the index using the
existing function. That function, however, would end up replacing your exclusive lock with the shared
lock, potentially making it impossible to reacquire that exclusive lock depending on other processes and
their I/O.
The lock stack attempts to solve those kinds of problems by maintaining a stack of flocks, and making
sure that no new locks degrade the previous locks. In previous example, it would notice that the stack
was opened with an exclusive lock, and when the index retrieval function attempts to apply the shared
lock, it would simply upgrade that lock to preserve the exclusive lock. Since a stack tracks each call
to pflock(), once that function attempts to release the shared lock, the lock stack would simply pop off
it's upgraded call from the stack, and make sure the preceding lock stays in place.
Another way to describe this in psuedo code:
# Enable the lock stack
PIOLOCKSTACK = 1;
sub readIdx {
pflock($file, LOCK_SH);
# ... read data
pflock($file, LOCK_UN);
# ... return data
}
sub writeIdx {
pflock($file, LOCK_EX);
# ... write data
pflock($file, LOCK_UN);
}
sub writeData {
pflock($file, LOCK_EX);
# ... write data
pflock($file, LOCK_UN);
}
sub writeTx {
pflock($file, LOCK_EX);
readIdx();
writeData();
writeIdx();
pflock($file, LOCK_UN);
}
# Execute the transaction
writeTx();
Without the lock stack, executing the transaction function would cause the following to happen:
writeTx:
# apply LOCK_EX
# readIdx:
# apply LOCK_SH
# read data
# release all locks w/LOCK_UN
# writeData:
# apply LOCK_EX
# ERROR: any write decisions at this point based on the previous
# ERROR: index read may cause file corruption because the index
# ERROR: may have changed while this process was waiting to
# ERROR: reacquire the exclusive lock!
With the lock stack in place, however, it goes like this:
writeTx:
# apply LOCK_EX
# lock stack: (LOCK_EX)
# readIdx:
# asks for LOCK_SH, but maintains LOCK_EX
# lock stack: (LOCK_EX, LOCK_EX)
# read data
# deletes its lock from the stack, but preserves the previous lock
# lock stack: (LOCK_EX)
# writeData:
# asks for LOCK_EX
# lock stack: (LOCK_EX, LOCK_EX)
# writes data
# deletes its lock from the stack, but preserves the previous lock
# lock stack: (LOCK_EX)
# writeIdx:
# asks for LOCK_EX
# lock stack: (LOCK_EX, LOCK_EX)
# writes data
# deletes its lock from the stack, but preserves the previous lock
# lock stack: (LOCK_EX)
# release lock
# lock stack: ()
At no point was the advisory lock lost, and hence, transactional integrity was preserved for all
compliant processes.
The lock stack is off by default to allow the developer complete control over locking and I/O patterns,
but it's there to make functions easier to write without having to worry about any locks applied outside
of their code scope.
One downside of the lock stack is that affects all I/O performed via the Paranoid::IO framework, it is
not locallized to specific file handles. For that reason, one must be confident that flocks are applied
as atomically as possible throughout the code space leveraging it.
IMPORT LISTS
This module exports the following symbols by default:
pclose pcloseAll popen preopen ptell pseek pflock
plockstat pread pnlread pwrite pappend ptruncate
The following specialized import lists also exist:
List Members
---------------------------------------------------------
all @defaults PIOBLKSIZE PIOMAXFSIZE PIOLOCKSTACK
SUBROUTINES/METHODS
PIOBLKSIZE
PIOBLKSIZE = 65536;
This lvalue function is not exported by default. It is used to determine the default block size to read
when a size is not explicitly passed. Depending on hardware and file system parameters there might be
performance gains to be had when doing default-sized reads.
The default is 4096, which is generally a safe size for most applications.
PIOMAXFSIZE
PIOMAXFSIZE = 131072;
This lvalue function is not exported by default. It is used to determine the maximum file size that will
be read. This is not used in this module, but provided for use in dependent modules that may want to
impose file size limits, such as Paranoid::IO::Line and others.
The default is 65536.
PIOLOCKSTACK
PIOLOCKSTACK = 1
This lvalue function is not exported by default. It is used to enable the flock lock stack functionality
in order to support transactional I/O patterns. It is disabled by default.
popen
$fh = popen($filename);
$fh = popen($filename, $mode);
$fh = popen($filename, $mode, $perms);
$fh = popen($fh);
Returns a file handle if the file could be opened. If the mode is omitted the default is O_CREAT |
O_RDWR. File permissions (for newly created files) default to 0666 ^ UMASK.
Failures to open a file will result in an undef return value, with a text description of the fault stored
in Paranoid::ERROR.
If a file handle is passed to popen it will attempt to match it to a tracked file handle and, if
identified, take the appropriate action. If it doesn't match any tracked file handles it will just
return that file handle back to the caller.
pclose
$rv = pclose($filename);
$rv = pclose($fh);
Returns the value from close. Attempts to close a file that's already closed is considered a success,
and true value is returned. Handing it a stale file handle, however, will be handed to the internal
close, with all the expected results.
preopen
$rv = preopen();
$rv = preopen(@filenames);
$rv = preopen(@filehandles);
This checks each tracked file handle (i.e., file handles that were opened by popen) and reopens them if
necessary. This is typically only useful after a fork. It is also not striclty necessary since every
call to a function in this module does that with every invocation, but if you have several file handles
that you may not access immediately you run the risk of the parent moving the current file position
before the child gets back to those files. You may or may not care. If you do, use this function
immediately after a fork.
Called with a list of file names means that only those files are examined and reopened. Any failure to
reopen any single file handle will result in a false return value. That said, any failures will not
interrupt the function from trying every file in the list.
pcloseAll
$rv = pcloseAll();
$rv = pcloseAll(@filenames);
$rv = pcloseAll(@filehandles);
This function returns a boolean value denoting any errors while trying to close every tracked file
handle. This function is also not strictly necessary for all the normal Perl I/O reasons, but it's here
for those that want to be explicit.
ptell
$pos = ptell($filename);
$pos = ptell($fh);
Returns the current position of the file cursor. Returns the results of sysseek, which means that any
successful seek is true, even if the cursor is at the beginning of the file. In that instance it returns
"0 but true" which is boolean true while converting to an integer appropriately.
Any failures are returned as false or undef.
pseek
$rv = pseek($filename, $pos, $whence);
$rv = pseek($fh, $pos, $whence);
This returns the return value from sysseek. The appropriate whence values sould be one of the SEEK_*
constants as exported by Fcntl.
pflock
$rv = pflock($filename, $locktype);
$rv = pflock($fh, $locktype);
This returns the return value from flock. The appropriate lock type values should be one of the LOCK_*
constants as exported by Fcntl.
NOTE: This function essentially acts like a pass-through to the native flock function for any file handle
not opened via this module's functions.
plockstat
$lock = plockstat($filename);
This returns the last flock applied via pflock.
pread
$bytes = pread($filename, $text, $length);
$bytes = pread($filename, $text, $length, $offset);
$bytes = pread($fh, $text, $length);
$bytes = pread($fh, $text, $length, $offset);
This returns the number of bytes read, or undef on errors. If this is called prior to an explicit popen
it will default to a mode of O_RDONLY. Length defaults to PIOBLKSIZE.
pnlread
$bytes = pnlread($filename, $text, $length);
$bytes = pnlread($filename, $text, $length, $offset);
$bytes = pnlread($fh, $text, $length);
$bytes = pnlread($fh, $text, $length, $offset);
This is a wrapper function for pread that calls it with inherent file locking disabled. It is assumed
that the dev is either managing flocks directly, or they're not needed for this application.
pwrite
$bytes = pwrite($filename, $text);
$bytes = pwrite($filename, $text, $length);
$bytes = pwrite($filename, $text, $length, $offset);
$bytes = pwrite($filename, $text, $length, $nolock);
$bytes = pwrite($fh, $text);
$bytes = pwrite($fj, $text, $length);
$bytes = pwrite($fh, $text, $length, $offset);
$bytes = pwrite($fh, $text, $length, $offset, $nolock);
This returns the number of bytes written, or undef for any critical failures. If this is called prior to
an explicit popen it uses a default mode of O_WRONLY | O_CREAT | O_TRUNC.
The optional boolean fifth argument (nolock) will bypass automatic flocks since it assumes you're
managing the lock directly.
pnlwrite
$bytes = pnlwrite($filename, $text);
$bytes = pnlwrite($filename, $text, $length);
$bytes = pnlwrite($filename, $text, $length, $offset);
$bytes = pnlwrite($fh, $text);
$bytes = pnlwrite($fj, $text, $length);
$bytes = pnlwrite($fh, $text, $length, $offset);
This is a wrapper function for pwrite that calls it with inherent file locking disabled. It is assumed
that the dev is either managing flocks directly, or they're not needed for this application.
pappend
$bytes = pappend($filename, $text);
$bytes = pappend($filename, $text, $length);
$bytes = pappend($filename, $text, $length, $offset);
$bytes = pappend($filename, $text, $length, $offset, $nolock);
$bytes = pappend($fh, $text);
$bytes = pappend($fh, $text, $length);
$bytes = pappend($fh, $text, $length, $offset, $nolock);
This behaves identically to pwrite with the sole exception that this preserves the file position after
explicitly seeking and writing to the end of the file. The default mode here, however, would be O_WRONLY
| O_CREAT | O_APPEND for those files not explicitly opened.
The optional boolean fifth argument (nolock) will bypass automatic flocks since it assumes you're
managing the lock directly.
pnlappend
$bytes = pnlappend($filename, $text);
$bytes = pnlappend($filename, $text, $length);
$bytes = pnlappend($filename, $text, $length, $offset);
$bytes = pnlappend($fh, $text);
$bytes = pnlappend($fj, $text, $length);
$bytes = pnlappend($fh, $text, $length, $offset);
This is a wrapper function for pappend that calls it with inherent file locking disabled. It is assumed
that the dev is either managing flocks directly, or they're not needed for this application.
ptruncate
$rv = ptruncate($filename);
$rv = ptruncate($filename, $pos, $nolock);
$rv = ptruncate($fh);
$rv = ptruncate($fh, $pos, $nolock);
This returns the result of the internal truncate call. If called without an explicit popen it will open
the named file with the default mode of O_RDWR | O_CREAT. Omitting the position to truncate from will
result in the file being truncated at the beginning of the file.
The optional boolean third argument (nolock) will bypass automatic flocks since it assumes you're
managing the lock directly.
pnltruncate
$rv = pnltruncate($filename);
$rv = pnltruncate($fh);
This is a wrapper function for pnltruncate that calls it with inherent file locking disabled. It is
assumed that the dev is either managing flocks directly, or they're not needed for this application.
DEPENDENCIES
o Cwd
o Fcntl
o IO::Handle
o Paranoid
o Paranoid::Debug
o Paranoid::Input
BUGS AND LIMITATIONS
It may not always be benficial to cache file handles. You must explicitly pclose file handles to avoid
that. That said, with straight Perl you'd have to either explicitly close the file handles or use
lexical scoping, anyway. From that perspective I don't find it onerous to do so, especially with all of
the other code-saving features this module provides.
AUTHOR
Arthur Corliss (corliss@digitalmages.com)
LICENSE AND COPYRIGHT
This software is free software. Similar to Perl, you can redistribute it and/or modify it under the
terms of either:
a) the GNU General Public License
<https://www.gnu.org/licenses/gpl-1.0.html> as published by the
Free Software Foundation <http://www.fsf.org/>; either version 1
<https://www.gnu.org/licenses/gpl-1.0.html>, or any later version
<https://www.gnu.org/licenses/license-list.html#GNUGPL>, or
b) the Artistic License 2.0
<https://opensource.org/licenses/Artistic-2.0>,
subject to the following additional term: No trademark rights to "Paranoid" have been or are conveyed
under any of the above licenses. However, "Paranoid" may be used fairly to describe this unmodified
software, in good faith, but not as a trademark.
(c) 2005 - 2021, Arthur Corliss (corliss@digitalmages.com) (tm) 2008 - 2021, Paranoid Inc.
(www.paranoid.com)
perl v5.32.1 2021-12-30 Paranoid::IO(3pm)