Perl 5 version 32.0 documentation

Devel::Peek

NAME

Devel::Peek - A data debugging tool for the XS programmer

SYNOPSIS

  1. use Devel::Peek;
  2. Dump( $a );
  3. Dump( $a, 5 );
  4. Dump( @a );
  5. Dump( %h );
  6. DumpArray( 5, $a, $b, ... );
  7. mstat "Point 5";
  8. use Devel::Peek ':opd=st';

DESCRIPTION

Devel::Peek contains functions which allows raw Perl datatypes to be manipulated from a Perl script. This is used by those who do XS programming to check that the data they are sending from C to Perl looks as they think it should look. The trick, then, is to know what the raw datatype is supposed to look like when it gets to Perl. This document offers some tips and hints to describe good and bad raw data.

It is very possible that this document will fall far short of being useful to the casual reader. The reader is expected to understand the material in the first few sections of perlguts.

Devel::Peek supplies a Dump() function which can dump a raw Perl datatype, and mstat("marker") function to report on memory usage (if perl is compiled with corresponding option). The function DeadCode() provides statistics on the data "frozen" into inactive CV . Devel::Peek also supplies SvREFCNT() which can query reference counts on SVs. This document will take a passive, and safe, approach to data debugging and for that it will describe only the Dump() function.

All output is to STDERR.

The Dump() function takes one or two arguments: something to dump, and an optional limit for recursion and array elements (default is 4). The first argument is evaluted in rvalue scalar context, with exceptions for @array and %hash, which dump the array or hash itself. So Dump @array works, as does Dump $foo . And Dump pos will call pos in rvalue context, whereas Dump ${\pos} will call it in lvalue context.

Function DumpArray() allows dumping of multiple values (useful when you need to analyze returns of functions).

The global variable $Devel::Peek::pv_limit can be set to limit the number of character printed in various string values. Setting it to 0 means no limit.

If use Devel::Peek directive has a :opd=FLAGS argument, this switches on debugging of opcode dispatch. FLAGS should be a combination of s, t , and P (see -D flags in perlrun).

:opd is a shortcut for :opd=st .

Runtime debugging

CvGV($cv) return one of the globs associated to a subroutine reference $cv.

debug_flags() returns a string representation of $^D (similar to what is allowed for -D flag). When called with a numeric argument, sets $^D to the corresponding value. When called with an argument of the form "flags-flags" , set on/off bits of $^D corresponding to letters before/after - . (The returned value is for $^D before the modification.)

runops_debug() returns true if the current opcode dispatcher is the debugging one. When called with an argument, switches to debugging or non-debugging dispatcher depending on the argument (active for newly-entered subs/etc only). (The returned value is for the dispatcher before the modification.)

Memory footprint debugging

When perl is compiled with support for memory footprint debugging (default with Perl's malloc()), Devel::Peek provides an access to this API.

Use mstat() function to emit a memory state statistic to the terminal. For more information on the format of output of mstat() see Using $ENV{PERL_DEBUG_MSTATS} in perldebguts.

Three additional functions allow access to this statistic from Perl. First, use mstats_fillhash(%hash) to get the information contained in the output of mstat() into %hash. The field of this hash are

  1. minbucket nbuckets sbrk_good sbrk_slack sbrked_remains sbrks
  2. start_slack topbucket topbucket_ev topbucket_odd total total_chain
  3. total_sbrk totfree

Two additional fields free , used contain array references which provide per-bucket count of free and used chunks. Two other fields mem_size , available_size contain array references which provide the information about the allocated size and usable size of chunks in each bucket. Again, see Using $ENV{PERL_DEBUG_MSTATS} in perldebguts for details.

Keep in mind that only the first several "odd-numbered" buckets are used, so the information on size of the "odd-numbered" buckets which are not used is probably meaningless.

The information in

  1. mem_size available_size minbucket nbuckets

is the property of a particular build of perl, and does not depend on the current process. If you do not provide the optional argument to the functions mstats_fillhash(), fill_mstats(), mstats2hash(), then the information in fields mem_size , available_size is not updated.

fill_mstats($buf) is a much cheaper call (both speedwise and memory-wise) which collects the statistic into $buf in machine-readable form. At a later moment you may need to call mstats2hash($buf, %hash) to use this information to fill %hash.

All three APIs fill_mstats($buf) , mstats_fillhash(%hash) , and mstats2hash($buf, %hash) are designed to allocate no memory if used the second time on the same $buf and/or %hash.

So, if you want to collect memory info in a cycle, you may call

  1. $#buf = 999;
  2. fill_mstats($_) for @buf;
  3. mstats_fillhash(%report, 1); # Static info too
  4. foreach (@buf) {
  5. # Do something...
  6. fill_mstats $_; # Collect statistic
  7. }
  8. foreach (@buf) {
  9. mstats2hash($_, %report); # Preserve static info
  10. # Do something with %report
  11. }

EXAMPLES

The following examples don't attempt to show everything as that would be a monumental task, and, frankly, we don't want this manpage to be an internals document for Perl. The examples do demonstrate some basics of the raw Perl datatypes, and should suffice to get most determined people on their way. There are no guidewires or safety nets, nor blazed trails, so be prepared to travel alone from this point and on and, if at all possible, don't fall into the quicksand (it's bad for business).

Oh, one final bit of advice: take perlguts with you. When you return we expect to see it well-thumbed.

A simple scalar string

Let's begin by looking a simple scalar which is holding a string.

  1. use Devel::Peek;
  2. $a = 42; $a = "hello";
  3. Dump $a;

The output:

  1. SV = PVIV(0xbc288) at 0xbe9a8
  2. REFCNT = 1
  3. FLAGS = (POK,pPOK)
  4. IV = 42
  5. PV = 0xb2048 "hello"\0
  6. CUR = 5
  7. LEN = 8

This says $a is an SV, a scalar. The scalar type is a PVIV, which is capable of holding an integer (IV) and/or a string (PV) value. The scalar's head is allocated at address 0xbe9a8, while the body is at 0xbc288. Its reference count is 1. It has the POK flag set, meaning its current PV field is valid. Because POK is set we look at the PV item to see what is in the scalar. The \0 at the end indicate that this PV is properly NUL-terminated. Note that the IV field still contains its old numeric value, but because FLAGS doesn't have IOK set, we must ignore the IV item. CUR indicates the number of characters in the PV. LEN indicates the number of bytes allocated for the PV (at least one more than CUR, because LEN includes an extra byte for the end-of-string marker, then usually rounded up to some efficient allocation unit).

A simple scalar number

If the scalar contains a number the raw SV will be leaner.

  1. use Devel::Peek;
  2. $a = 42;
  3. Dump $a;

The output:

  1. SV = IV(0xbc818) at 0xbe9a8
  2. REFCNT = 1
  3. FLAGS = (IOK,pIOK)
  4. IV = 42

This says $a is an SV, a scalar. The scalar is an IV, a number. Its reference count is 1. It has the IOK flag set, meaning it is currently being evaluated as a number. Because IOK is set we look at the IV item to see what is in the scalar.

A simple scalar with an extra reference

If the scalar from the previous example had an extra reference:

  1. use Devel::Peek;
  2. $a = 42;
  3. $b = \$a;
  4. Dump $a;

The output:

  1. SV = IV(0xbe860) at 0xbe9a8
  2. REFCNT = 2
  3. FLAGS = (IOK,pIOK)
  4. IV = 42

Notice that this example differs from the previous example only in its reference count. Compare this to the next example, where we dump $b instead of $a .

A reference to a simple scalar

This shows what a reference looks like when it references a simple scalar.

  1. use Devel::Peek;
  2. $a = 42;
  3. $b = \$a;
  4. Dump $b;

The output:

  1. SV = IV(0xf041c) at 0xbe9a0
  2. REFCNT = 1
  3. FLAGS = (ROK)
  4. RV = 0xbab08
  5. SV = IV(0xbe860) at 0xbe9a8
  6. REFCNT = 2
  7. FLAGS = (IOK,pIOK)
  8. IV = 42

Starting from the top, this says $b is an SV. The scalar is an IV, which is capable of holding an integer or reference value. It has the ROK flag set, meaning it is a reference (rather than an integer or string). Notice that Dump follows the reference and shows us what $b was referencing. We see the same $a that we found in the previous example.

Note that the value of RV coincides with the numbers we see when we stringify $b. The addresses inside IV() are addresses of X*** structures which hold the current state of an SV . This address may change during lifetime of an SV.

A reference to an array

This shows what a reference to an array looks like.

  1. use Devel::Peek;
  2. $a = [42];
  3. Dump $a;

The output:

  1. SV = IV(0xc85998) at 0xc859a8
  2. REFCNT = 1
  3. FLAGS = (ROK)
  4. RV = 0xc70de8
  5. SV = PVAV(0xc71e10) at 0xc70de8
  6. REFCNT = 1
  7. FLAGS = ()
  8. ARRAY = 0xc7e820
  9. FILL = 0
  10. MAX = 0
  11. FLAGS = (REAL)
  12. Elt No. 0
  13. SV = IV(0xc70f88) at 0xc70f98
  14. REFCNT = 1
  15. FLAGS = (IOK,pIOK)
  16. IV = 42

This says $a is a reference (ROK), which points to another SV which is a PVAV, an array. The array has one element, element zero, which is another SV. The field FILL above indicates the last element in the array, similar to $#$a .

If $a pointed to an array of two elements then we would see the following.

  1. use Devel::Peek 'Dump';
  2. $a = [42,24];
  3. Dump $a;

The output:

  1. SV = IV(0x158c998) at 0x158c9a8
  2. REFCNT = 1
  3. FLAGS = (ROK)
  4. RV = 0x1577de8
  5. SV = PVAV(0x1578e10) at 0x1577de8
  6. REFCNT = 1
  7. FLAGS = ()
  8. ARRAY = 0x1585820
  9. FILL = 1
  10. MAX = 1
  11. FLAGS = (REAL)
  12. Elt No. 0
  13. SV = IV(0x1577f88) at 0x1577f98
  14. REFCNT = 1
  15. FLAGS = (IOK,pIOK)
  16. IV = 42
  17. Elt No. 1
  18. SV = IV(0x158be88) at 0x158be98
  19. REFCNT = 1
  20. FLAGS = (IOK,pIOK)
  21. IV = 24

Note that Dump will not report all the elements in the array, only several first (depending on how deep it already went into the report tree).

A reference to a hash

The following shows the raw form of a reference to a hash.

  1. use Devel::Peek;
  2. $a = {hello=>42};
  3. Dump $a;

The output:

  1. SV = IV(0x55cb50b50fb0) at 0x55cb50b50fc0
  2. REFCNT = 1
  3. FLAGS = (ROK)
  4. RV = 0x55cb50b2b758
  5. SV = PVHV(0x55cb50b319c0) at 0x55cb50b2b758
  6. REFCNT = 1
  7. FLAGS = (SHAREKEYS)
  8. ARRAY = 0x55cb50b941a0 (0:7, 1:1)
  9. hash quality = 100.0%
  10. KEYS = 1
  11. FILL = 1
  12. MAX = 7
  13. Elt "hello" HASH = 0x3128ece4
  14. SV = IV(0x55cb50b464f8) at 0x55cb50b46508
  15. REFCNT = 1
  16. FLAGS = (IOK,pIOK)
  17. IV = 42

This shows $a is a reference pointing to an SV. That SV is a PVHV, a hash.

The "quality" of a hash is defined as the total number of comparisons needed to access every element once, relative to the expected number needed for a random hash. The value can go over 100%.

The total number of comparisons is equal to the sum of the squares of the number of entries in each bucket. For a random hash of <n> keys into <k> buckets, the expected value is:

  1. n + n(n-1)/2k

Dumping a large array or hash

The Dump() function, by default, dumps up to 4 elements from a toplevel array or hash. This number can be increased by supplying a second argument to the function.

  1. use Devel::Peek;
  2. $a = [10,11,12,13,14];
  3. Dump $a;

Notice that Dump() prints only elements 10 through 13 in the above code. The following code will print all of the elements.

  1. use Devel::Peek 'Dump';
  2. $a = [10,11,12,13,14];
  3. Dump $a, 5;

A reference to an SV which holds a C pointer

This is what you really need to know as an XS programmer, of course. When an XSUB returns a pointer to a C structure that pointer is stored in an SV and a reference to that SV is placed on the XSUB stack. So the output from an XSUB which uses something like the T_PTROBJ map might look something like this:

  1. SV = IV(0xf381c) at 0xc859a8
  2. REFCNT = 1
  3. FLAGS = (ROK)
  4. RV = 0xb8ad8
  5. SV = PVMG(0xbb3c8) at 0xc859a0
  6. REFCNT = 1
  7. FLAGS = (OBJECT,IOK,pIOK)
  8. IV = 729160
  9. NV = 0
  10. PV = 0
  11. STASH = 0xc1d10 "CookBookB::Opaque"

This shows that we have an SV which is a reference, which points at another SV. In this case that second SV is a PVMG, a blessed scalar. Because it is blessed it has the OBJECT flag set. Note that an SV which holds a C pointer also has the IOK flag set. The STASH is set to the package name which this SV was blessed into.

The output from an XSUB which uses something like the T_PTRREF map, which doesn't bless the object, might look something like this:

  1. SV = IV(0xf381c) at 0xc859a8
  2. REFCNT = 1
  3. FLAGS = (ROK)
  4. RV = 0xb8ad8
  5. SV = PVMG(0xbb3c8) at 0xc859a0
  6. REFCNT = 1
  7. FLAGS = (IOK,pIOK)
  8. IV = 729160
  9. NV = 0
  10. PV = 0

A reference to a subroutine

Looks like this:

  1. SV = IV(0x24d2dd8) at 0x24d2de8
  2. REFCNT = 1
  3. FLAGS = (TEMP,ROK)
  4. RV = 0x24e79d8
  5. SV = PVCV(0x24e5798) at 0x24e79d8
  6. REFCNT = 2
  7. FLAGS = ()
  8. COMP_STASH = 0x22c9c50 "main"
  9. START = 0x22eed60 ===> 0
  10. ROOT = 0x22ee490
  11. GVGV::GV = 0x22de9d8 "MY" :: "top_targets"
  12. FILE = "(eval 5)"
  13. DEPTH = 0
  14. FLAGS = 0x0
  15. OUTSIDE_SEQ = 93
  16. PADLIST = 0x22e9ed8
  17. PADNAME = 0x22e9ec0(0x22eed00) PAD = 0x22e9ea8(0x22eecd0)
  18. OUTSIDE = 0x22c9fb0 (MAIN)

This shows that

  • the subroutine is not an XSUB (since START and ROOT are non-zero, and XSUB is not listed, and is thus null);

  • that it was compiled in the package main ;

  • under the name MY::top_targets ;

  • inside a 5th eval in the program;

  • it is not currently executed (because DEPTH is 0);

  • it has no prototype (PROTOTYPE field is missing).

EXPORTS

Dump , mstat , DeadCode , DumpArray , DumpWithOP and DumpProg , fill_mstats , mstats_fillhash , mstats2hash by default. Additionally available SvREFCNT , SvREFCNT_inc and SvREFCNT_dec .

BUGS

Readers have been known to skip important parts of perlguts, causing much frustration for all.

AUTHOR

Ilya Zakharevich ilya@math.ohio-state.edu

Copyright (c) 1995-98 Ilya Zakharevich. All rights reserved. This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself.

Author of this software makes no claim whatsoever about suitability, reliability, edability, editability or usability of this product, and should not be kept liable for any damage resulting from the use of it. If you can use it, you are in luck, if not, I should not be kept responsible. Keep a handy copy of your backup tape at hand.

SEE ALSO

perlguts, and perlguts, again.