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Dir : //proc/thread-self/root/proc/self/root/proc/self/root/usr/share/perl5/vendor_perl/Data/Dump.pm |
package Data::Dump; use strict; use vars qw(@EXPORT @EXPORT_OK $VERSION $DEBUG); use subs qq(dump); require Exporter; *import = \&Exporter::import; @EXPORT = qw(dd ddx); @EXPORT_OK = qw(dump pp dumpf quote); $VERSION = "1.23"; $DEBUG = 0; use overload (); use vars qw(%seen %refcnt @dump @fixup %require $TRY_BASE64 @FILTERS $INDENT); $TRY_BASE64 = 50 unless defined $TRY_BASE64; $INDENT = " " unless defined $INDENT; sub dump { local %seen; local %refcnt; local %require; local @fixup; require Data::Dump::FilterContext if @FILTERS; my $name = "a"; my @dump; for my $v (@_) { my $val = _dump($v, $name, [], tied($v)); push(@dump, [$name, $val]); } continue { $name++; } my $out = ""; if (%require) { for (sort keys %require) { $out .= "require $_;\n"; } } if (%refcnt) { # output all those with refcounts first for (@dump) { my $name = $_->[0]; if ($refcnt{$name}) { $out .= "my \$$name = $_->[1];\n"; undef $_->[1]; } } for (@fixup) { $out .= "$_;\n"; } } my $paren = (@dump != 1); $out .= "(" if $paren; $out .= format_list($paren, undef, map {defined($_->[1]) ? $_->[1] : "\$".$_->[0]} @dump ); $out .= ")" if $paren; if (%refcnt || %require) { $out .= ";\n"; $out =~ s/^/$INDENT/gm; $out = "do {\n$out}"; } print STDERR "$out\n" unless defined wantarray; $out; } *pp = \&dump; sub dd { print dump(@_), "\n"; } sub ddx { my(undef, $file, $line) = caller; $file =~ s,.*[\\/],,; my $out = "$file:$line: " . dump(@_) . "\n"; $out =~ s/^/# /gm; print $out; } sub dumpf { require Data::Dump::Filtered; goto &Data::Dump::Filtered::dump_filtered; } sub _dump { my $ref = ref $_[0]; my $rval = $ref ? $_[0] : \$_[0]; shift; my($name, $idx, $dont_remember, $pclass, $pidx) = @_; my($class, $type, $id); my $strval = overload::StrVal($rval); # Parse $strval without using regexps, in order not to clobber $1, $2,... if ((my $i = rindex($strval, "=")) >= 0) { $class = substr($strval, 0, $i); $strval = substr($strval, $i+1); } if ((my $i = index($strval, "(0x")) >= 0) { $type = substr($strval, 0, $i); $id = substr($strval, $i + 2, -1); } else { die "Can't parse " . overload::StrVal($rval); } if ($] < 5.008 && $type eq "SCALAR") { $type = "REF" if $ref eq "REF"; } warn "\$$name(@$idx) $class $type $id ($ref)" if $DEBUG; my $out; my $comment; my $hide_keys; if (@FILTERS) { my $pself = ""; $pself = fullname("self", [@$idx[$pidx..(@$idx - 1)]]) if $pclass; my $ctx = Data::Dump::FilterContext->new($rval, $class, $type, $ref, $pclass, $pidx, $idx); my @bless; for my $filter (@FILTERS) { if (my $f = $filter->($ctx, $rval)) { if (my $v = $f->{object}) { local @FILTERS; $out = _dump($v, $name, $idx, 1); $dont_remember++; } if (defined(my $c = $f->{bless})) { push(@bless, $c); } if (my $c = $f->{comment}) { $comment = $c; } if (defined(my $c = $f->{dump})) { $out = $c; $dont_remember++; } if (my $h = $f->{hide_keys}) { if (ref($h) eq "ARRAY") { $hide_keys = sub { for my $k (@$h) { return 1 if $k eq $_[0]; } return 0; }; } } } } push(@bless, "") if defined($out) && !@bless; if (@bless) { $class = shift(@bless); warn "More than one filter callback tried to bless object" if @bless; } } unless ($dont_remember) { if (my $s = $seen{$id}) { my($sname, $sidx) = @$s; $refcnt{$sname}++; my $sref = fullname($sname, $sidx, ($ref && $type eq "SCALAR")); warn "SEEN: [\$$name(@$idx)] => [\$$sname(@$sidx)] ($ref,$sref)" if $DEBUG; return $sref unless $sname eq $name; $refcnt{$name}++; push(@fixup, fullname($name,$idx)." = $sref"); return "do{my \$fix}" if @$idx && $idx->[-1] eq '$'; return "'fix'"; } $seen{$id} = [$name, $idx]; } if ($class) { $pclass = $class; $pidx = @$idx; } if (defined $out) { # keep it } elsif ($type eq "SCALAR" || $type eq "REF" || $type eq "REGEXP") { if ($ref) { if ($class && $class eq "Regexp") { my $v = "$rval"; my $mod = ""; if ($v =~ /^\(\?\^?([msix-]*):([\x00-\xFF]*)\)\z/) { $mod = $1; $v = $2; $mod =~ s/-.*//; } my $sep = '/'; my $sep_count = ($v =~ tr/\///); if ($sep_count) { # see if we can find a better one for ('|', ',', ':', '#') { my $c = eval "\$v =~ tr/\Q$_\E//"; #print "SEP $_ $c $sep_count\n"; if ($c < $sep_count) { $sep = $_; $sep_count = $c; last if $sep_count == 0; } } } $v =~ s/\Q$sep\E/\\$sep/g; $out = "qr$sep$v$sep$mod"; undef($class); } else { delete $seen{$id} if $type eq "SCALAR"; # will be seen again shortly my $val = _dump($$rval, $name, [@$idx, "\$"], 0, $pclass, $pidx); $out = $class ? "do{\\(my \$o = $val)}" : "\\$val"; } } else { if (!defined $$rval) { $out = "undef"; } elsif (do {no warnings 'numeric'; $$rval + 0 eq $$rval}) { $out = $$rval; } else { $out = str($$rval); } if ($class && !@$idx) { # Top is an object, not a reference to one as perl needs $refcnt{$name}++; my $obj = fullname($name, $idx); my $cl = quote($class); push(@fixup, "bless \\$obj, $cl"); } } } elsif ($type eq "GLOB") { if ($ref) { delete $seen{$id}; my $val = _dump($$rval, $name, [@$idx, "*"], 0, $pclass, $pidx); $out = "\\$val"; if ($out =~ /^\\\*Symbol::/) { $require{Symbol}++; $out = "Symbol::gensym()"; } } else { my $val = "$$rval"; $out = "$$rval"; for my $k (qw(SCALAR ARRAY HASH)) { my $gval = *$$rval{$k}; next unless defined $gval; next if $k eq "SCALAR" && ! defined $$gval; # always there my $f = scalar @fixup; push(@fixup, "RESERVED"); # overwritten after _dump() below $gval = _dump($gval, $name, [@$idx, "*{$k}"], 0, $pclass, $pidx); $refcnt{$name}++; my $gname = fullname($name, $idx); $fixup[$f] = "$gname = $gval"; #XXX indent $gval } } } elsif ($type eq "ARRAY") { my @vals; my $tied = tied_str(tied(@$rval)); my $i = 0; for my $v (@$rval) { push(@vals, _dump($v, $name, [@$idx, "[$i]"], $tied, $pclass, $pidx)); $i++; } $out = "[" . format_list(1, $tied, @vals) . "]"; } elsif ($type eq "HASH") { my(@keys, @vals); my $tied = tied_str(tied(%$rval)); # statistics to determine variation in key lengths my $kstat_max = 0; my $kstat_sum = 0; my $kstat_sum2 = 0; my @orig_keys = keys %$rval; if ($hide_keys) { @orig_keys = grep !$hide_keys->($_), @orig_keys; } my $text_keys = 0; for (@orig_keys) { $text_keys++, last unless /^[-+]?(?:0|[1-9]\d*)(?:\.\d+)?\z/; } if ($text_keys) { @orig_keys = sort { lc($a) cmp lc($b) } @orig_keys; } else { @orig_keys = sort { $a <=> $b } @orig_keys; } my $quote; for my $key (@orig_keys) { next if $key =~ /^-?[a-zA-Z_]\w*\z/; next if $key =~ /^-?[1-9]\d{0,8}\z/; $quote++; last; } for my $key (@orig_keys) { my $val = \$rval->{$key}; # capture value before we modify $key $key = quote($key) if $quote; $kstat_max = length($key) if length($key) > $kstat_max; $kstat_sum += length($key); $kstat_sum2 += length($key)*length($key); push(@keys, $key); push(@vals, _dump($$val, $name, [@$idx, "{$key}"], $tied, $pclass, $pidx)); } my $nl = ""; my $klen_pad = 0; my $tmp = "@keys @vals"; if (length($tmp) > 60 || $tmp =~ /\n/ || $tied) { $nl = "\n"; # Determine what padding to add if ($kstat_max < 4) { $klen_pad = $kstat_max; } elsif (@keys >= 2) { my $n = @keys; my $avg = $kstat_sum/$n; my $stddev = sqrt(($kstat_sum2 - $n * $avg * $avg) / ($n - 1)); # I am not actually very happy with this heuristics if ($stddev / $kstat_max < 0.25) { $klen_pad = $kstat_max; } if ($DEBUG) { push(@keys, "__S"); push(@vals, sprintf("%.2f (%d/%.1f/%.1f)", $stddev / $kstat_max, $kstat_max, $avg, $stddev)); } } } $out = "{$nl"; $out .= "$INDENT# $tied$nl" if $tied; while (@keys) { my $key = shift @keys; my $val = shift @vals; my $vpad = $INDENT . (" " x ($klen_pad ? $klen_pad + 4 : 0)); $val =~ s/\n/\n$vpad/gm; my $kpad = $nl ? $INDENT : " "; $key .= " " x ($klen_pad - length($key)) if $nl && $klen_pad > length($key); $out .= "$kpad$key => $val,$nl"; } $out =~ s/,$/ / unless $nl; $out .= "}"; } elsif ($type eq "CODE") { $out = 'sub { ... }'; } elsif ($type eq "VSTRING") { $out = sprintf +($ref ? '\v%vd' : 'v%vd'), $$rval; } else { warn "Can't handle $type data"; $out = "'#$type#'"; } if ($class && $ref) { $out = "bless($out, " . quote($class) . ")"; } if ($comment) { $comment =~ s/^/# /gm; $comment .= "\n" unless $comment =~ /\n\z/; $comment =~ s/^#[ \t]+\n/\n/; $out = "$comment$out"; } return $out; } sub tied_str { my $tied = shift; if ($tied) { if (my $tied_ref = ref($tied)) { $tied = "tied $tied_ref"; } else { $tied = "tied"; } } return $tied; } sub fullname { my($name, $idx, $ref) = @_; substr($name, 0, 0) = "\$"; my @i = @$idx; # need copy in order to not modify @$idx if ($ref && @i && $i[0] eq "\$") { shift(@i); # remove one deref $ref = 0; } while (@i && $i[0] eq "\$") { shift @i; $name = "\$$name"; } my $last_was_index; for my $i (@i) { if ($i eq "*" || $i eq "\$") { $last_was_index = 0; $name = "$i\{$name}"; } elsif ($i =~ s/^\*//) { $name .= $i; $last_was_index++; } else { $name .= "->" unless $last_was_index++; $name .= $i; } } $name = "\\$name" if $ref; $name; } sub format_list { my $paren = shift; my $comment = shift; my $indent_lim = $paren ? 0 : 1; if (@_ > 3) { # can we use range operator to shorten the list? my $i = 0; while ($i < @_) { my $j = $i + 1; my $v = $_[$i]; while ($j < @_) { # XXX allow string increment too? if ($v eq "0" || $v =~ /^-?[1-9]\d{0,9}\z/) { $v++; } elsif ($v =~ /^"([A-Za-z]{1,3}\d*)"\z/) { $v = $1; $v++; $v = qq("$v"); } else { last; } last if $_[$j] ne $v; $j++; } if ($j - $i > 3) { splice(@_, $i, $j - $i, "$_[$i] .. $_[$j-1]"); } $i++; } } my $tmp = "@_"; if ($comment || (@_ > $indent_lim && (length($tmp) > 60 || $tmp =~ /\n/))) { my @elem = @_; for (@elem) { s/^/$INDENT/gm; } return "\n" . ($comment ? "$INDENT# $comment\n" : "") . join(",\n", @elem, ""); } else { return join(", ", @_); } } sub str { if (length($_[0]) > 20) { for ($_[0]) { # Check for repeated string if (/^(.)\1\1\1/s) { # seems to be a repeating sequence, let's check if it really is # without backtracking unless (/[^\Q$1\E]/) { my $base = quote($1); my $repeat = length; return "($base x $repeat)" } } # Length protection because the RE engine will blow the stack [RT#33520] if (length($_) < 16 * 1024 && /^(.{2,5}?)\1*\z/s) { my $base = quote($1); my $repeat = length($_)/length($1); return "($base x $repeat)"; } } } local $_ = "e; if (length($_) > 40 && !/\\x\{/ && length($_) > (length($_[0]) * 2)) { # too much binary data, better to represent as a hex/base64 string # Base64 is more compact than hex when string is longer than # 17 bytes (not counting any require statement needed). # But on the other hand, hex is much more readable. if ($TRY_BASE64 && length($_[0]) > $TRY_BASE64 && (defined &utf8::is_utf8 && !utf8::is_utf8($_[0])) && eval { require MIME::Base64 }) { $require{"MIME::Base64"}++; return "MIME::Base64::decode(\"" . MIME::Base64::encode($_[0],"") . "\")"; } return "pack(\"H*\",\"" . unpack("H*", $_[0]) . "\")"; } return $_; } my %esc = ( "\a" => "\\a", "\b" => "\\b", "\t" => "\\t", "\n" => "\\n", "\f" => "\\f", "\r" => "\\r", "\e" => "\\e", ); # put a string value in double quotes sub quote { local($_) = $_[0]; # If there are many '"' we might want to use qq() instead s/([\\\"\@\$])/\\$1/g; return qq("$_") unless /[^\040-\176]/; # fast exit s/([\a\b\t\n\f\r\e])/$esc{$1}/g; # no need for 3 digits in escape for these s/([\0-\037])(?!\d)/sprintf('\\%o',ord($1))/eg; s/([\0-\037\177-\377])/sprintf('\\x%02X',ord($1))/eg; s/([^\040-\176])/sprintf('\\x{%X}',ord($1))/eg; return qq("$_"); } 1; __END__ =head1 NAME Data::Dump - Pretty printing of data structures =head1 SYNOPSIS use Data::Dump qw(dump); $str = dump(@list); @copy_of_list = eval $str; # or use it for easy debug printout use Data::Dump; dd localtime; =head1 DESCRIPTION This module provide a few functions that traverse their argument and produces a string as its result. The string contains Perl code that, when C<eval>ed, produces a deep copy of the original arguments. The main feature of the module is that it strives to produce output that is easy to read. Example: @a = (1, [2, 3], {4 => 5}); dump(@a); Produces: "(1, [2, 3], { 4 => 5 })" If you dump just a little data, it is output on a single line. If you dump data that is more complex or there is a lot of it, line breaks are automatically added to keep it easy to read. The following functions are provided (only the dd* functions are exported by default): =over =item dump( ... ) =item pp( ... ) Returns a string containing a Perl expression. If you pass this string to Perl's built-in eval() function it should return a copy of the arguments you passed to dump(). If you call the function with multiple arguments then the output will be wrapped in parenthesis "( ..., ... )". If you call the function with a single argument the output will not have the wrapping. If you call the function with a single scalar (non-reference) argument it will just return the scalar quoted if needed, but never break it into multiple lines. If you pass multiple arguments or references to arrays of hashes then the return value might contain line breaks to format it for easier reading. The returned string will never be "\n" terminated, even if contains multiple lines. This allows code like this to place the semicolon in the expected place: print '$obj = ', dump($obj), ";\n"; If dump() is called in void context, then the dump is printed on STDERR and then "\n" terminated. You might find this useful for quick debug printouts, but the dd*() functions might be better alternatives for this. There is no difference between dump() and pp(), except that dump() shares its name with a not-so-useful perl builtin. Because of this some might want to avoid using that name. =item quote( $string ) Returns a quoted version of the provided string. It differs from C<dump($string)> in that it will quote even numbers and not try to come up with clever expressions that might shorten the output. If a non-scalar argument is provided then it's just stringified instead of traversed. =item dd( ... ) =item ddx( ... ) These functions will call dump() on their argument and print the result to STDOUT (actually, it's the currently selected output handle, but STDOUT is the default for that). The difference between them is only that ddx() will prefix the lines it prints with "# " and mark the first line with the file and line number where it was called. This is meant to be useful for debug printouts of state within programs. =item dumpf( ..., \&filter ) Short hand for calling the dump_filtered() function of L<Data::Dump::Filtered>. This works like dump(), but the last argument should be a filter callback function. As objects are visited the filter callback is invoked and it can modify how the objects are dumped. =back =head1 CONFIGURATION There are a few global variables that can be set to modify the output generated by the dump functions. It's wise to localize the setting of these. =over =item $Data::Dump::INDENT This holds the string that's used for indenting multiline data structures. It's default value is " " (two spaces). Set it to "" to suppress indentation. Setting it to "| " makes for nice visuals even if the dump output then fails to be valid Perl. =item $Data::Dump::TRY_BASE64 How long must a binary string be before we try to use the base64 encoding for the dump output. The default is 50. Set it to 0 to disable base64 dumps. =back =head1 LIMITATIONS Code references will be dumped as C<< sub { ... } >>. Thus, C<eval>ing them will not reproduce the original routine. The C<...>-operator used will also require perl-5.12 or better to be evaled. If you forget to explicitly import the C<dump> function, your code will core dump. That's because you just called the builtin C<dump> function by accident, which intentionally dumps core. Because of this you can also import the same function as C<pp>, mnemonic for "pretty-print". =head1 HISTORY The C<Data::Dump> module grew out of frustration with Sarathy's in-most-cases-excellent C<Data::Dumper>. Basic ideas and some code are shared with Sarathy's module. The C<Data::Dump> module provides a much simpler interface than C<Data::Dumper>. No OO interface is available and there are fewer configuration options to worry about. The other benefit is that the dump produced does not try to set any variables. It only returns what is needed to produce a copy of the arguments. This means that C<dump("foo")> simply returns C<'"foo"'>, and C<dump(1..3)> simply returns C<'(1, 2, 3)'>. =head1 SEE ALSO L<Data::Dump::Filtered>, L<Data::Dump::Trace>, L<Data::Dumper>, L<JSON>, L<Storable> =head1 AUTHORS The C<Data::Dump> module is written by Gisle Aas <gisle@aas.no>, based on C<Data::Dumper> by Gurusamy Sarathy <gsar@umich.edu>. Copyright 1998-2010 Gisle Aas. Copyright 1996-1998 Gurusamy Sarathy. This library is free software; you can redistribute it and/or modify it under the same terms as Perl itself. =cut