main/massif/ms_print.in - platform/external/valgrind - Git at Google

 #! @PERL@

 ##--------------------------------------------------------------------##
 ##--- Massif's results printer                         ms_print.in ---##
 ##--------------------------------------------------------------------##

 #  This file is part of Massif, a Valgrind tool for profiling memory
 #  usage of programs.
 #
 #  Copyright (C) 2007-2007 Nicholas Nethercote
 #     njn@valgrind.org
 #
 #  This program is free software; you can redistribute it and/or
 #  modify it under the terms of the GNU General Public License as
 #  published by the Free Software Foundation; either version 2 of the
 #  License, or (at your option) any later version.
 #
 #  This program is distributed in the hope that it will be useful, but
 #  WITHOUT ANY WARRANTY; without even the implied warranty of
 #  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 #  General Public License for more details.
 #
 #  You should have received a copy of the GNU General Public License
 #  along with this program; if not, write to the Free Software
 #  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
 #  02111-1307, USA.
 #
 #  The GNU General Public License is contained in the file COPYING.

 use warnings;
 use strict;

 #----------------------------------------------------------------------------
 # Global variables, main data structures
 #----------------------------------------------------------------------------

 # Command line of profiled program.
 my $cmd;

 # Time unit used in profile.
 my $time_unit;

 # Threshold dictating what percentage an entry must represent for us to
 # bother showing it.
 my $threshold = 1.0;

 # Graph x and y dimensions.
 my $graph_x = 72;
 my $graph_y = 20;

 # Input file name
 my $input_file = undef;

 # Tmp file name.
 my $tmp_file = "ms_print.tmp.$$";

 # Version number.
 my $version = "@VERSION@";

 # Args passed, for printing.
 my $ms_print_args;

 # Usage message.
 my $usage = <<END
 usage: ms_print [options] massif-out-file

   options for the user, with defaults in [ ], are:
     -h --help             show this message
     --version             show version
     --threshold=<m.n>     significance threshold, in percent [$threshold]
     --x=<4..1000>         graph width, in columns [72]
     --y=<4..1000>         graph height, in rows [20]

   ms_print is Copyright (C) 2007-2007 Nicholas Nethercote.
   and licensed under the GNU General Public License, version 2.
   Bug reports, feedback, admiration, abuse, etc, to: njn\@valgrind.org.

 END
 ;

 # Used in various places of output.
 my $fancy    = '-' x 80;
 my $fancy_nl = $fancy . "\n";

 # Returns 0 if the denominator is 0.
 sub safe_div_0($$)
 {
     my ($x, $y) = @_;
     return ($y ? $x / $y : 0);
 }

 #-----------------------------------------------------------------------------
 # Argument and option handling
 #-----------------------------------------------------------------------------
 sub process_cmd_line()
 {
     my @files;

     # Grab a copy of the arguments, for printing later.
     for my $arg (@ARGV) {
         $ms_print_args .= " $arg";       # The arguments.
     }

     for my $arg (@ARGV) {

         # Option handling
         if ($arg =~ /^-/) {

             # --version
             if ($arg =~ /^--version$/) {
                 die("ms_print-$version\n");

             # --threshold=X (tolerates a trailing '%')
             } elsif ($arg =~ /^--threshold=([\d\.]+)%?$/) {
                 $threshold = $1;
                 ($1 >= 0 && $1 <= 100) or die($usage);

             } elsif ($arg =~ /^--x=(\d+)$/) {
                 $graph_x = $1;
                 (4 <= $graph_x && $graph_x <= 1000) or die($usage);

             } elsif ($arg =~ /^--y=(\d+)$/) {
                 $graph_y = $1;
                 (4 <= $graph_y && $graph_y <= 1000) or die($usage);

             } else {            # -h and --help fall under this case
                 die($usage);
             }
         } else {
             # Not an option.  Remember it as a filename.
             push(@files, $arg);
         }
     }

     # Must have chosen exactly one input file.
     if (scalar @files) {
         $input_file = $files[0];
     } else {
         die($usage);
     }
 }

 #-----------------------------------------------------------------------------
 # Reading the input file: auxiliary functions
 #-----------------------------------------------------------------------------

 # Gets the next line, stripping comments and skipping blanks.
 # Returns undef at EOF.
 sub get_line()
 {
     while (my $line = <INPUTFILE>) {
         $line =~ s/#.*$//;          # remove comments
         if ($line !~ /^\s*$/) {
             return $line;           # return $line if non-empty
         }
     }
     return undef;       # EOF: return undef
 }

 sub equals_num_line($$)
 {
     my ($line, $fieldname) = @_;
     defined($line)
         or die("Line $.: expected \"$fieldname\" line, got end of file\n");
     $line =~ s/^$fieldname=(.*)\s*$//
         or die("Line $.: expected \"$fieldname\" line, got:\n$line");
     return $1;
 }

 sub is_significant_XPt($$$)
 {
     my ($is_top_node, $xpt_szB, $total_szB) = @_;
     ($xpt_szB <= $total_szB) or die;
     # Nb: we always consider the alloc-XPt significant, even if the size is
     # zero.
     return $is_top_node || 0 == $threshold ||
         ( $total_szB != 0 && $xpt_szB * 100 / $total_szB >= $threshold );
 }

 #-----------------------------------------------------------------------------
 # Reading the input file: reading heap trees
 #-----------------------------------------------------------------------------

 # Forward declaration, because it's recursive.
 sub read_heap_tree($$$$$);

 # Return pair:  if the tree was significant, both are zero.  If it was
 # insignificant, the first element is 1 and the second is the number of
 # bytes.
 sub read_heap_tree($$$$$)
 {
     # Read the line and determine if it is significant.
     my ($is_top_node, $this_prefix, $child_midfix, $arrow, $mem_total_B) = @_;
     my $line = get_line();
     (defined $line and $line =~ /^\s*n(\d+):\s*(\d+)(.*)$/)
         or die("Line $.: expected a tree node line, got:\n$line\n");
     my $n_children = $1;
     my $bytes      = $2;
     my $details    = $3;
     my $perc       = safe_div_0(100 * $bytes, $mem_total_B);
     # Nb: we always print the alloc-XPt, even if its size is zero.
     my $is_significant = is_significant_XPt($is_top_node, $bytes, $mem_total_B);

     # We precede this node's line with "$this_prefix.$arrow".  We precede
     # any children of this node with "$this_prefix$child_midfix$arrow".
     if ($is_significant) {
         # Nb: $details might have '%' in it, so don't embed directly in the
         # format string.
         printf(TMPFILE
             "$this_prefix$arrow%05.2f%% (%sB)%s\n", $perc, commify($bytes),
             $details);
     }

     # Now read all the children.
     my $n_insig_children = 0;
     my $total_insig_children_szB = 0;
     my $this_prefix2 = $this_prefix . $child_midfix;
     for (my $i = 0; $i < $n_children; $i++) {
         # If child is the last sibling, the midfix is empty.
         my $child_midfix2 = ( $i+1 == $n_children ? "  " : "| " );
         my ($is_child_insignificant, $child_insig_bytes) =
             # '0' means it's not the top node of the tree.
             read_heap_tree(0, $this_prefix2, $child_midfix2, "->",
                 $mem_total_B);
         $n_insig_children += $is_child_insignificant;
         $total_insig_children_szB += $child_insig_bytes;
     }

     if ($is_significant) {
         # If this was significant but any children were insignificant, print
         # the "in N places" line for them.
         if ($n_insig_children > 0) {
             $perc = safe_div_0(100 * $total_insig_children_szB, $mem_total_B);
             printf(TMPFILE "%s->%05.2f%% (%sB) in %d+ places, all below "
                  . "ms_print's threshold (%05.2f%%)\n",
                 $this_prefix2, $perc, commify($total_insig_children_szB),
                 $n_insig_children, $threshold);
             print(TMPFILE "$this_prefix2\n");
         }

         # If this node has no children, print an extra (mostly) empty line.
         if (0 == $n_children) {
             print(TMPFILE "$this_prefix2\n");
         }
         return (0, 0);

     } else {
         return (1, $bytes);
     }
 }

 #-----------------------------------------------------------------------------
 # Reading the input file: main
 #-----------------------------------------------------------------------------

 sub max_label_2($$)
 {
     my ($szB, $szB_scaled) = @_;

     # For the label, if $szB is 999B or below, we print it as an integer.
     # Otherwise, we print it as a float with 5 characters (including the '.').
     # Examples (for bytes):
     #       1 -->     1  B
     #     999 -->   999  B
     #    1000 --> 0.977 KB
     #    1024 --> 1.000 KB
     #   10240 --> 10.00 KB
     #  102400 --> 100.0 KB
     # 1024000 --> 0.977 MB
     # 1048576 --> 1.000 MB
     #
     if    ($szB < 1000)        { return sprintf("%5d",   $szB);        }
     elsif ($szB_scaled < 10)   { return sprintf("%5.3f", $szB_scaled); }
     elsif ($szB_scaled < 100)  { return sprintf("%5.2f", $szB_scaled); }
     else                       { return sprintf("%5.1f", $szB_scaled); }
 }

 # Work out the units for the max value, measured in instructions.
 sub i_max_label($)
 {
     my ($nI) = @_;

     # We repeat until the number is less than 1000.
     my $nI_scaled = $nI;
     my $unit = "i";
     # Nb: 'k' is the "kilo" (1000) prefix.
     if ($nI_scaled >= 1000) { $unit = "ki"; $nI_scaled /= 1024; }
     if ($nI_scaled >= 1000) { $unit = "Mi"; $nI_scaled /= 1024; }
     if ($nI_scaled >= 1000) { $unit = "Gi"; $nI_scaled /= 1024; }
     if ($nI_scaled >= 1000) { $unit = "Ti"; $nI_scaled /= 1024; }
     if ($nI_scaled >= 1000) { $unit = "Pi"; $nI_scaled /= 1024; }
     if ($nI_scaled >= 1000) { $unit = "Ei"; $nI_scaled /= 1024; }
     if ($nI_scaled >= 1000) { $unit = "Zi"; $nI_scaled /= 1024; }
     if ($nI_scaled >= 1000) { $unit = "Yi"; $nI_scaled /= 1024; }

     return (max_label_2($nI, $nI_scaled), $unit);
 }

 # Work out the units for the max value, measured in bytes.
 sub B_max_label($)
 {
     my ($szB) = @_;

     # We repeat until the number is less than 1000, but we divide by 1024 on
     # each scaling.
     my $szB_scaled = $szB;
     my $unit = "B";
     # Nb: 'K' or 'k' are acceptable as the "binary kilo" (1024) prefix.
     # (Strictly speaking, should use "KiB" (kibibyte), "MiB" (mebibyte), etc,
     # but they're not in common use.)
     if ($szB_scaled >= 1000) { $unit = "KB"; $szB_scaled /= 1024; }
     if ($szB_scaled >= 1000) { $unit = "MB"; $szB_scaled /= 1024; }
     if ($szB_scaled >= 1000) { $unit = "GB"; $szB_scaled /= 1024; }
     if ($szB_scaled >= 1000) { $unit = "TB"; $szB_scaled /= 1024; }
     if ($szB_scaled >= 1000) { $unit = "PB"; $szB_scaled /= 1024; }
     if ($szB_scaled >= 1000) { $unit = "EB"; $szB_scaled /= 1024; }
     if ($szB_scaled >= 1000) { $unit = "ZB"; $szB_scaled /= 1024; }
     if ($szB_scaled >= 1000) { $unit = "YB"; $szB_scaled /= 1024; }

     return (max_label_2($szB, $szB_scaled), $unit);
 }

 # Work out the units for the max value, measured in ms/s/h.
 sub t_max_label($)
 {
     my ($szB) = @_;

     # We scale from millisecond to seconds to hours.
     #
     # XXX: this allows a number with 6 chars, eg. "3599.0 s"
     my $szB_scaled = $szB;
     my $unit = "ms";
     if ($szB_scaled >= 1000) { $unit = "s"; $szB_scaled /= 1000; }
     if ($szB_scaled >= 3600) { $unit = "h"; $szB_scaled /= 3600; }

     return (max_label_2($szB, $szB_scaled), $unit);
 }

 # This prints four things:
 #   - the output header
 #   - the graph
 #   - the snapshot summaries (number, list of detailed ones)
 #   - the snapshots
 #
 # The first three parts can't be printed until we've read the whole input file;
 # but the fourth part is much easier to print while we're reading the file.  So
 # we print the fourth part to a tmp file, and then dump the tmp file at the
 # end.
 #
 sub read_input_file()
 {
     my $desc = "";              # Concatenated description lines.
     my $peak_mem_total_szB = 0;

     # Info about each snapshot.
     my @snapshot_nums = ();
     my @times         = ();
     my @mem_total_Bs  = ();
     my @is_detaileds  = ();
     my $peak_num = -1;      # An initial value that will be ok if no peak
                             # entry is in the file.

     #-------------------------------------------------------------------------
     # Read start of input file.
     #-------------------------------------------------------------------------
     open(INPUTFILE, "< $input_file")
          || die "Cannot open $input_file for reading\n";

     # Read "desc:" lines.
     my $line;
     while ($line = get_line()) {
         if ($line =~ s/^desc://) {
             $desc .= $line;
         } else {
             last;
         }
     }

     # Read "cmd:" line (Nb: will already be in $line from "desc:" loop above).
     ($line =~ /^cmd:\s*(.*)$/) or die("Line $.: missing 'cmd' line\n");
     $cmd = $1;

     # Read "time_unit:" line.
     $line = get_line();
     ($line =~ /^time_unit:\s*(.*)$/) or
         die("Line $.: missing 'time_unit' line\n");
     $time_unit = $1;

     #-------------------------------------------------------------------------
     # Print snapshot list header to $tmp_file.
     #-------------------------------------------------------------------------
     open(TMPFILE, "> $tmp_file")
          || die "Cannot open $tmp_file for reading\n";

     my $time_column = sprintf("%14s", "time($time_unit)");
     my $column_format = "%3s %14s %16s %16s %13s %12s\n";
     my $header =
         $fancy_nl .
         sprintf($column_format
         ,   "n"
         ,   $time_column
         ,   "total(B)"
         ,   "useful-heap(B)"
         ,   "extra-heap(B)"
         ,   "stacks(B)"
         ) .
         $fancy_nl;
     print(TMPFILE $header);

     #-------------------------------------------------------------------------
     # Read body of input file.
     #-------------------------------------------------------------------------
     $line = get_line();
     while (defined $line) {
         my $snapshot_num     = equals_num_line($line,      "snapshot");
         my $time             = equals_num_line(get_line(), "time");
         my $mem_heap_B       = equals_num_line(get_line(), "mem_heap_B");
         my $mem_heap_extra_B = equals_num_line(get_line(), "mem_heap_extra_B");
         my $mem_stacks_B     = equals_num_line(get_line(), "mem_stacks_B");
         my $mem_total_B      = $mem_heap_B + $mem_heap_extra_B + $mem_stacks_B;
         my $heap_tree        = equals_num_line(get_line(), "heap_tree");

         # Print the snapshot data to $tmp_file.
         printf(TMPFILE $column_format,
         ,   $snapshot_num
         ,   commify($time)
         ,   commify($mem_total_B)
         ,   commify($mem_heap_B)
         ,   commify($mem_heap_extra_B)
         ,   commify($mem_stacks_B)
         );

         # Remember the snapshot data.
         push(@snapshot_nums, $snapshot_num);
         push(@times,         $time);
         push(@mem_total_Bs,  $mem_total_B);
         push(@is_detaileds,  ( $heap_tree eq "empty" ? 0 : 1 ));
         $peak_mem_total_szB = $mem_total_B
             if $mem_total_B > $peak_mem_total_szB;

         # Read the heap tree, and if it's detailed, print it and a subsequent
         # snapshot list header to $tmp_file.
         if      ($heap_tree eq "empty") {
             $line = get_line();
         } elsif ($heap_tree =~ "(detailed|peak)") {
             # If "peak", remember the number.
             if ($heap_tree eq "peak") {
                 $peak_num = $snapshot_num;
             }
             # '1' means it's the top node of the tree.
             read_heap_tree(1, "", "", "", $mem_total_B);

             # Print the header, unless there are no more snapshots.
             $line = get_line();
             if (defined $line) {
                 print(TMPFILE $header);
             }
         } else {
             die("Line $.: expected 'empty' or '...' after 'heap_tree='\n");
         }
     }

     close(INPUTFILE);
     close(TMPFILE);

     #-------------------------------------------------------------------------
     # Print header.
     #-------------------------------------------------------------------------
     print($fancy_nl);
     print("Command:            $cmd\n");
     print("Massif arguments:  $desc");
     print("ms_print arguments:$ms_print_args\n");
     print($fancy_nl);
     print("\n\n");

     #-------------------------------------------------------------------------
     # Setup for graph.
     #-------------------------------------------------------------------------
     # The ASCII graph.
     # Row    0 ([0..graph_x][0]) is the X-axis.
     # Column 0 ([0][0..graph_y]) is the Y-axis.
     # The rest ([1][1]..[graph_x][graph_y]) is the usable graph area.
     my @graph;
     my $x;
     my $y;

     my $n_snapshots = scalar(@snapshot_nums);
     ($n_snapshots > 0) or die;
     my $end_time = $times[$n_snapshots-1];
     ($end_time >= 0) or die;

     # Setup graph[][].
     $graph[0][0] = '+';                                     # axes join point
     for ($x = 1; $x <= $graph_x; $x++) { $graph[$x][0] = '-'; } # X-axis
     for ($y = 1; $y <= $graph_y; $y++) { $graph[0][$y] = '|'; } # Y-axis
     $graph[$graph_x][0] = '>';                                  # X-axis arrow
     $graph[0][$graph_y] = '^';                                  # Y-axis arrow
     for ($x = 1; $x <= $graph_x; $x++) {                        # usable area
        for ($y = 1; $y <= $graph_y; $y++) {
           $graph[$x][$y] = ' ';
        }
     }

     #-------------------------------------------------------------------------
     # Write snapshot bars into graph[][].
     #-------------------------------------------------------------------------
     # Each row represents K bytes, which is 1/graph_y of the peak size
     # (and K can be non-integral).  When drawing the column for a snapshot,
     # in order to fill the slot in row y (where the first row drawn on is
     # row 1) with a full-char (eg. ':'), it must be >= y*K.  For example, if
     # K = 10 bytes, then the values 0, 4, 5, 9, 10, 14, 15, 19, 20, 24, 25,
     # 29, 30 would be drawn like this (showing one per column):
     #
     #                       y    y * K
     #                       -    -----------
     # 30 |            :     3    3 * 10 = 30
     # 20 |        :::::     2    2 * 10 = 20
     # 10 |    :::::::::     1    1 * 10 = 10
     # 0  +-------------

     my $peak_char     = '#';
     my $detailed_char = '@';
     my $normal_char   = ':';

     # Work out how many bytes each row represents.  If the peak size was 0,
     # make it 1 so that the Y-axis covers a non-zero range of values.
     # Likewise for end_time.
     if (0 == $peak_mem_total_szB) { $peak_mem_total_szB = 1; }
     if (0 == $end_time          ) { $end_time           = 1; }
     my $K = $peak_mem_total_szB / $graph_y;

        $x          = 0;
     my $prev_x     = 0;
     my $prev_y_max = 0;
     my $prev_char  = ':';

     for (my $i = 0; $i < $n_snapshots; $i++) {

         # Work out which column this snapshot belongs to.
         $prev_x = $x;
         my $x_pos_frac = ($times[$i] / ($end_time)) * $graph_x;
         $x = int($x_pos_frac) + 1;    # +1 due to Y-axis
         # The final snapshot will spill over into the n+1th column, which
         # doesn't get shown.  So we fudge that one and pull it back a
         # column, as if the end_time was actually end_time+epsilon.
         if ($times[$i] == $end_time) {
             ($x == $graph_x+1) or die;
             $x = $graph_x;
         }

         # If there was a gap between the previous snapshot's column and this
         # one, we draw a horizontal line in the gap (so long as it doesn't
         # trash the x-axis).  Without this, graphs with a few sparse
         # snapshots look funny -- as if the memory usage is in temporary
         # spikes.
         if ($prev_y_max > 0) {
             for (my $x2 = $prev_x + 1; $x2 < $x; $x2++) {
                 $graph[$x2][$prev_y_max] = $prev_char;
             }
         }

         # Choose the column char.
         my $char;
         if    ($i == $peak_num)   { $char = $peak_char;     }
         elsif ($is_detaileds[$i]) { $char = $detailed_char; }
         else                      { $char = $normal_char;   }

         # Grow this snapshot bar from bottom to top.
         my $y_max = 0;
         for ($y = 1; $y <= $graph_y; $y++) {
             if ($mem_total_Bs[$i] >= $y * $K) {
                 # Priority order for chars: peak > detailed > normal
                 my $should_draw_char =
                     (($char eq $peak_char)
                      or
                      ($char eq $detailed_char and
                       $graph[$x][$y] ne $peak_char
                      )
                      or
                      ($char eq $normal_char and
                       $graph[$x][$y] ne $peak_char and
                       $graph[$x][$y] ne $detailed_char
                      )
                     );

                 if ($should_draw_char) {
                     $graph[$x][$y] = $char;
                 }
                 $y_max = $y;
             }
         }
         $prev_y_max = $y_max;
         $prev_char = $char;
     }

     #-------------------------------------------------------------------------
     # Print graph[][].
     #-------------------------------------------------------------------------
     my ($y_label, $y_unit) = B_max_label($peak_mem_total_szB);
     my ($x_label, $x_unit);
     if    ($time_unit eq "i")  { ($x_label, $x_unit) = i_max_label($end_time) }
     elsif ($time_unit eq "ms") { ($x_label, $x_unit) = t_max_label($end_time) }
     elsif ($time_unit eq "B")  { ($x_label, $x_unit) = B_max_label($end_time) }
     else                       { die "bad time_unit: $time_unit\n"; }

     printf("    %2s\n", $y_unit);
     for ($y = $graph_y; $y >= 0; $y--) {
         if ($graph_y == $y) {            # top row
             print($y_label);
         } elsif (0 == $y) {              # bottom row
             print("   0 ");
         } else {                         # anywhere else
             print("     ");
         }

         # Axis and data for the row.
         for ($x = 0; $x <= $graph_x; $x++) {
             printf("%s", $graph[$x][$y]);
         }
         if (0 == $y) {
             print("$x_unit\n");
         } else {
             print("\n");
         }
     }
     printf("     0%s%5s\n", ' ' x ($graph_x-5), $x_label);

     #-------------------------------------------------------------------------
     # Print snapshot numbers.
     #-------------------------------------------------------------------------
     print("\n");
     print("Number of snapshots: $n_snapshots\n");
     print(" Detailed snapshots: [");
     my $first_detailed = 1;
     for (my $i = 0; $i < $n_snapshots; $i++) {
         if ($is_detaileds[$i]) {
             if ($first_detailed) {
                 printf("$i");
                 $first_detailed = 0;
             } else {
                 printf(", $i");
             }
             if ($i == $peak_num) {
                 print(" (peak)");
             }
         }
     }
     print("]\n\n");

     #-------------------------------------------------------------------------
     # Print snapshots, from $tmp_file.
     #-------------------------------------------------------------------------
     open(TMPFILE, "< $tmp_file")
          || die "Cannot open $tmp_file for reading\n";

     while (my $line = <TMPFILE>) {
         print($line);
     }
     unlink($tmp_file);
 }

 #-----------------------------------------------------------------------------
 # Misc functions
 #-----------------------------------------------------------------------------
 sub commify ($) {
     my ($val) = @_;
     1 while ($val =~ s/^(\d+)(\d{3})/$1,$2/);
     return $val;
 }


 #----------------------------------------------------------------------------
 # "main()"
 #----------------------------------------------------------------------------
 process_cmd_line();
 read_input_file();

 ##--------------------------------------------------------------------##
 ##--- end                                              ms_print.in ---##
 ##--------------------------------------------------------------------##
	#! @PERL@

	##--------------------------------------------------------------------##
	##--- Massif's results printer ms_print.in ---##
	##--------------------------------------------------------------------##

	# This file is part of Massif, a Valgrind tool for profiling memory
	# usage of programs.
	#
	# Copyright (C) 2007-2007 Nicholas Nethercote
	# njn@valgrind.org
	#
	# This program is free software; you can redistribute it and/or
	# modify it under the terms of the GNU General Public License as
	# published by the Free Software Foundation; either version 2 of the
	# License, or (at your option) any later version.
	#
	# This program is distributed in the hope that it will be useful, but
	# WITHOUT ANY WARRANTY; without even the implied warranty of
	# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	# General Public License for more details.
	#
	# You should have received a copy of the GNU General Public License
	# along with this program; if not, write to the Free Software
	# Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
	# 02111-1307, USA.
	#
	# The GNU General Public License is contained in the file COPYING.

	use warnings;
	use strict;

	#----------------------------------------------------------------------------
	# Global variables, main data structures
	#----------------------------------------------------------------------------

	# Command line of profiled program.
	my $cmd;

	# Time unit used in profile.
	my $time_unit;

	# Threshold dictating what percentage an entry must represent for us to
	# bother showing it.
	my $threshold = 1.0;

	# Graph x and y dimensions.
	my $graph_x = 72;
	my $graph_y = 20;

	# Input file name
	my $input_file = undef;

	# Tmp file name.
	my $tmp_file = "ms_print.tmp.$$";

	# Version number.
	my $version = "@VERSION@";

	# Args passed, for printing.
	my $ms_print_args;

	# Usage message.
	my $usage = <<END
	usage: ms_print [options] massif-out-file

	options for the user, with defaults in [ ], are:
	-h --help show this message
	--version show version
	--threshold=<m.n> significance threshold, in percent [$threshold]
	--x=<4..1000> graph width, in columns [72]
	--y=<4..1000> graph height, in rows [20]

	ms_print is Copyright (C) 2007-2007 Nicholas Nethercote.
	and licensed under the GNU General Public License, version 2.
	Bug reports, feedback, admiration, abuse, etc, to: njn\@valgrind.org.

	END
	;

	# Used in various places of output.
	my $fancy = '-' x 80;
	my $fancy_nl = $fancy . "\n";

	# Returns 0 if the denominator is 0.
	sub safe_div_0($$)
	{
	my ($x, $y) = @_;
	return ($y ? $x / $y : 0);
	}

	#-----------------------------------------------------------------------------
	# Argument and option handling
	#-----------------------------------------------------------------------------
	sub process_cmd_line()
	{
	my @files;

	# Grab a copy of the arguments, for printing later.
	for my $arg (@ARGV) {
	$ms_print_args .= " $arg"; # The arguments.
	}

	for my $arg (@ARGV) {

	# Option handling
	if ($arg =~ /^-/) {

	# --version
	if ($arg =~ /^--version$/) {
	die("ms_print-$version\n");

	# --threshold=X (tolerates a trailing '%')
	} elsif ($arg =~ /^--threshold=([\d\.]+)%?$/) {
	$threshold = $1;
	($1 >= 0 && $1 <= 100) or die($usage);

	} elsif ($arg =~ /^--x=(\d+)$/) {
	$graph_x = $1;
	(4 <= $graph_x && $graph_x <= 1000) or die($usage);

	} elsif ($arg =~ /^--y=(\d+)$/) {
	$graph_y = $1;
	(4 <= $graph_y && $graph_y <= 1000) or die($usage);

	} else { # -h and --help fall under this case
	die($usage);
	}
	} else {
	# Not an option. Remember it as a filename.
	push(@files, $arg);
	}
	}

	# Must have chosen exactly one input file.
	if (scalar @files) {
	$input_file = $files[0];
	} else {
	die($usage);
	}
	}

	#-----------------------------------------------------------------------------
	# Reading the input file: auxiliary functions
	#-----------------------------------------------------------------------------

	# Gets the next line, stripping comments and skipping blanks.
	# Returns undef at EOF.
	sub get_line()
	{
	while (my $line = <INPUTFILE>) {
	$line =~ s/#.*$//; # remove comments
	if ($line !~ /^\s*$/) {
	return $line; # return $line if non-empty
	}
	}
	return undef; # EOF: return undef
	}

	sub equals_num_line($$)
	{
	my ($line, $fieldname) = @_;
	defined($line)
	or die("Line $.: expected \"$fieldname\" line, got end of file\n");
	$line =~ s/^$fieldname=(.)\s$//
	or die("Line $.: expected \"$fieldname\" line, got:\n$line");
	return $1;
	}

	sub is_significant_XPt($$$)
	{
	my ($is_top_node, $xpt_szB, $total_szB) = @_;
	($xpt_szB <= $total_szB) or die;
	# Nb: we always consider the alloc-XPt significant, even if the size is
	# zero.
	return $is_top_node \|\| 0 == $threshold \|\|
	( $total_szB != 0 && $xpt_szB * 100 / $total_szB >= $threshold );
	}

	#-----------------------------------------------------------------------------
	# Reading the input file: reading heap trees
	#-----------------------------------------------------------------------------

	# Forward declaration, because it's recursive.
	sub read_heap_tree($$$$$);

	# Return pair: if the tree was significant, both are zero. If it was
	# insignificant, the first element is 1 and the second is the number of
	# bytes.
	sub read_heap_tree($$$$$)
	{
	# Read the line and determine if it is significant.
	my ($is_top_node, $this_prefix, $child_midfix, $arrow, $mem_total_B) = @_;
	my $line = get_line();
	(defined $line and $line =~ /^\sn(\d+):\s(\d+)(.*)$/)
	or die("Line $.: expected a tree node line, got:\n$line\n");
	my $n_children = $1;
	my $bytes = $2;
	my $details = $3;
	my $perc = safe_div_0(100 * $bytes, $mem_total_B);
	# Nb: we always print the alloc-XPt, even if its size is zero.
	my $is_significant = is_significant_XPt($is_top_node, $bytes, $mem_total_B);

	# We precede this node's line with "$this_prefix.$arrow". We precede
	# any children of this node with "$this_prefix$child_midfix$arrow".
	if ($is_significant) {
	# Nb: $details might have '%' in it, so don't embed directly in the
	# format string.
	printf(TMPFILE
	"$this_prefix$arrow%05.2f%% (%sB)%s\n", $perc, commify($bytes),
	$details);
	}

	# Now read all the children.
	my $n_insig_children = 0;
	my $total_insig_children_szB = 0;
	my $this_prefix2 = $this_prefix . $child_midfix;
	for (my $i = 0; $i < $n_children; $i++) {
	# If child is the last sibling, the midfix is empty.
	my $child_midfix2 = ( $i+1 == $n_children ? " " : "\| " );
	my ($is_child_insignificant, $child_insig_bytes) =
	# '0' means it's not the top node of the tree.
	read_heap_tree(0, $this_prefix2, $child_midfix2, "->",
	$mem_total_B);
	$n_insig_children += $is_child_insignificant;
	$total_insig_children_szB += $child_insig_bytes;
	}

	if ($is_significant) {
	# If this was significant but any children were insignificant, print
	# the "in N places" line for them.
	if ($n_insig_children > 0) {
	$perc = safe_div_0(100 * $total_insig_children_szB, $mem_total_B);
	printf(TMPFILE "%s->%05.2f%% (%sB) in %d+ places, all below "
	. "ms_print's threshold (%05.2f%%)\n",
	$this_prefix2, $perc, commify($total_insig_children_szB),
	$n_insig_children, $threshold);
	print(TMPFILE "$this_prefix2\n");
	}

	# If this node has no children, print an extra (mostly) empty line.
	if (0 == $n_children) {
	print(TMPFILE "$this_prefix2\n");
	}
	return (0, 0);

	} else {
	return (1, $bytes);
	}
	}

	#-----------------------------------------------------------------------------
	# Reading the input file: main
	#-----------------------------------------------------------------------------

	sub max_label_2($$)
	{
	my ($szB, $szB_scaled) = @_;

	# For the label, if $szB is 999B or below, we print it as an integer.
	# Otherwise, we print it as a float with 5 characters (including the '.').
	# Examples (for bytes):
	# 1 --> 1 B
	# 999 --> 999 B
	# 1000 --> 0.977 KB
	# 1024 --> 1.000 KB
	# 10240 --> 10.00 KB
	# 102400 --> 100.0 KB
	# 1024000 --> 0.977 MB
	# 1048576 --> 1.000 MB
	#
	if ($szB < 1000) { return sprintf("%5d", $szB); }
	elsif ($szB_scaled < 10) { return sprintf("%5.3f", $szB_scaled); }
	elsif ($szB_scaled < 100) { return sprintf("%5.2f", $szB_scaled); }
	else { return sprintf("%5.1f", $szB_scaled); }
	}

	# Work out the units for the max value, measured in instructions.
	sub i_max_label($)
	{
	my ($nI) = @_;

	# We repeat until the number is less than 1000.
	my $nI_scaled = $nI;
	my $unit = "i";
	# Nb: 'k' is the "kilo" (1000) prefix.
	if ($nI_scaled >= 1000) { $unit = "ki"; $nI_scaled /= 1024; }
	if ($nI_scaled >= 1000) { $unit = "Mi"; $nI_scaled /= 1024; }
	if ($nI_scaled >= 1000) { $unit = "Gi"; $nI_scaled /= 1024; }
	if ($nI_scaled >= 1000) { $unit = "Ti"; $nI_scaled /= 1024; }
	if ($nI_scaled >= 1000) { $unit = "Pi"; $nI_scaled /= 1024; }
	if ($nI_scaled >= 1000) { $unit = "Ei"; $nI_scaled /= 1024; }
	if ($nI_scaled >= 1000) { $unit = "Zi"; $nI_scaled /= 1024; }
	if ($nI_scaled >= 1000) { $unit = "Yi"; $nI_scaled /= 1024; }

	return (max_label_2($nI, $nI_scaled), $unit);
	}

	# Work out the units for the max value, measured in bytes.
	sub B_max_label($)
	{
	my ($szB) = @_;

	# We repeat until the number is less than 1000, but we divide by 1024 on
	# each scaling.
	my $szB_scaled = $szB;
	my $unit = "B";
	# Nb: 'K' or 'k' are acceptable as the "binary kilo" (1024) prefix.
	# (Strictly speaking, should use "KiB" (kibibyte), "MiB" (mebibyte), etc,
	# but they're not in common use.)
	if ($szB_scaled >= 1000) { $unit = "KB"; $szB_scaled /= 1024; }
	if ($szB_scaled >= 1000) { $unit = "MB"; $szB_scaled /= 1024; }
	if ($szB_scaled >= 1000) { $unit = "GB"; $szB_scaled /= 1024; }
	if ($szB_scaled >= 1000) { $unit = "TB"; $szB_scaled /= 1024; }
	if ($szB_scaled >= 1000) { $unit = "PB"; $szB_scaled /= 1024; }
	if ($szB_scaled >= 1000) { $unit = "EB"; $szB_scaled /= 1024; }
	if ($szB_scaled >= 1000) { $unit = "ZB"; $szB_scaled /= 1024; }
	if ($szB_scaled >= 1000) { $unit = "YB"; $szB_scaled /= 1024; }

	return (max_label_2($szB, $szB_scaled), $unit);
	}

	# Work out the units for the max value, measured in ms/s/h.
	sub t_max_label($)
	{
	my ($szB) = @_;

	# We scale from millisecond to seconds to hours.
	#
	# XXX: this allows a number with 6 chars, eg. "3599.0 s"
	my $szB_scaled = $szB;
	my $unit = "ms";
	if ($szB_scaled >= 1000) { $unit = "s"; $szB_scaled /= 1000; }
	if ($szB_scaled >= 3600) { $unit = "h"; $szB_scaled /= 3600; }

	return (max_label_2($szB, $szB_scaled), $unit);
	}

	# This prints four things:
	# - the output header
	# - the graph
	# - the snapshot summaries (number, list of detailed ones)
	# - the snapshots
	#
	# The first three parts can't be printed until we've read the whole input file;
	# but the fourth part is much easier to print while we're reading the file. So
	# we print the fourth part to a tmp file, and then dump the tmp file at the
	# end.
	#
	sub read_input_file()
	{
	my $desc = ""; # Concatenated description lines.
	my $peak_mem_total_szB = 0;

	# Info about each snapshot.
	my @snapshot_nums = ();
	my @times = ();
	my @mem_total_Bs = ();
	my @is_detaileds = ();
	my $peak_num = -1; # An initial value that will be ok if no peak
	# entry is in the file.

	#-------------------------------------------------------------------------
	# Read start of input file.
	#-------------------------------------------------------------------------
	open(INPUTFILE, "< $input_file")
	\|\| die "Cannot open $input_file for reading\n";

	# Read "desc:" lines.
	my $line;
	while ($line = get_line()) {
	if ($line =~ s/^desc://) {
	$desc .= $line;
	} else {
	last;
	}
	}

	# Read "cmd:" line (Nb: will already be in $line from "desc:" loop above).
	($line =~ /^cmd:\s(.)$/) or die("Line $.: missing 'cmd' line\n");
	$cmd = $1;

	# Read "time_unit:" line.
	$line = get_line();
	($line =~ /^time_unit:\s(.)$/) or
	die("Line $.: missing 'time_unit' line\n");
	$time_unit = $1;

	#-------------------------------------------------------------------------
	# Print snapshot list header to $tmp_file.
	#-------------------------------------------------------------------------
	open(TMPFILE, "> $tmp_file")
	\|\| die "Cannot open $tmp_file for reading\n";

	my $time_column = sprintf("%14s", "time($time_unit)");
	my $column_format = "%3s %14s %16s %16s %13s %12s\n";
	my $header =
	$fancy_nl .
	sprintf($column_format
	, "n"
	, $time_column
	, "total(B)"
	, "useful-heap(B)"
	, "extra-heap(B)"
	, "stacks(B)"
	) .
	$fancy_nl;
	print(TMPFILE $header);

	#-------------------------------------------------------------------------
	# Read body of input file.
	#-------------------------------------------------------------------------
	$line = get_line();
	while (defined $line) {
	my $snapshot_num = equals_num_line($line, "snapshot");
	my $time = equals_num_line(get_line(), "time");
	my $mem_heap_B = equals_num_line(get_line(), "mem_heap_B");
	my $mem_heap_extra_B = equals_num_line(get_line(), "mem_heap_extra_B");
	my $mem_stacks_B = equals_num_line(get_line(), "mem_stacks_B");
	my $mem_total_B = $mem_heap_B + $mem_heap_extra_B + $mem_stacks_B;
	my $heap_tree = equals_num_line(get_line(), "heap_tree");

	# Print the snapshot data to $tmp_file.
	printf(TMPFILE $column_format,
	, $snapshot_num
	, commify($time)
	, commify($mem_total_B)
	, commify($mem_heap_B)
	, commify($mem_heap_extra_B)
	, commify($mem_stacks_B)
	);

	# Remember the snapshot data.
	push(@snapshot_nums, $snapshot_num);
	push(@times, $time);
	push(@mem_total_Bs, $mem_total_B);
	push(@is_detaileds, ( $heap_tree eq "empty" ? 0 : 1 ));
	$peak_mem_total_szB = $mem_total_B
	if $mem_total_B > $peak_mem_total_szB;

	# Read the heap tree, and if it's detailed, print it and a subsequent
	# snapshot list header to $tmp_file.
	if ($heap_tree eq "empty") {
	$line = get_line();
	} elsif ($heap_tree =~ "(detailed\|peak)") {
	# If "peak", remember the number.
	if ($heap_tree eq "peak") {
	$peak_num = $snapshot_num;
	}
	# '1' means it's the top node of the tree.
	read_heap_tree(1, "", "", "", $mem_total_B);

	# Print the header, unless there are no more snapshots.
	$line = get_line();
	if (defined $line) {
	print(TMPFILE $header);
	}
	} else {
	die("Line $.: expected 'empty' or '...' after 'heap_tree='\n");
	}
	}

	close(INPUTFILE);
	close(TMPFILE);

	#-------------------------------------------------------------------------
	# Print header.
	#-------------------------------------------------------------------------
	print($fancy_nl);
	print("Command: $cmd\n");
	print("Massif arguments: $desc");
	print("ms_print arguments:$ms_print_args\n");
	print($fancy_nl);
	print("\n\n");

	#-------------------------------------------------------------------------
	# Setup for graph.
	#-------------------------------------------------------------------------
	# The ASCII graph.
	# Row 0 ([0..graph_x][0]) is the X-axis.
	# Column 0 ([0][0..graph_y]) is the Y-axis.
	# The rest ([1][1]..[graph_x][graph_y]) is the usable graph area.
	my @graph;
	my $x;
	my $y;

	my $n_snapshots = scalar(@snapshot_nums);
	($n_snapshots > 0) or die;
	my $end_time = $times[$n_snapshots-1];
	($end_time >= 0) or die;

	# Setup graph[][].
	$graph[0][0] = '+'; # axes join point
	for ($x = 1; $x <= $graph_x; $x++) { $graph[$x][0] = '-'; } # X-axis
	for ($y = 1; $y <= $graph_y; $y++) { $graph[0][$y] = '\|'; } # Y-axis
	$graph[$graph_x][0] = '>'; # X-axis arrow
	$graph[0][$graph_y] = '^'; # Y-axis arrow
	for ($x = 1; $x <= $graph_x; $x++) { # usable area
	for ($y = 1; $y <= $graph_y; $y++) {
	$graph[$x][$y] = ' ';
	}
	}

	#-------------------------------------------------------------------------
	# Write snapshot bars into graph[][].
	#-------------------------------------------------------------------------
	# Each row represents K bytes, which is 1/graph_y of the peak size
	# (and K can be non-integral). When drawing the column for a snapshot,
	# in order to fill the slot in row y (where the first row drawn on is
	# row 1) with a full-char (eg. ':'), it must be >= y*K. For example, if
	# K = 10 bytes, then the values 0, 4, 5, 9, 10, 14, 15, 19, 20, 24, 25,
	# 29, 30 would be drawn like this (showing one per column):
	#
	# y y * K
	# - -----------
	# 30 \| : 3 3 * 10 = 30
	# 20 \| ::::: 2 2 * 10 = 20
	# 10 \| ::::::::: 1 1 * 10 = 10
	# 0 +-------------

	my $peak_char = '#';
	my $detailed_char = '@';
	my $normal_char = ':';

	# Work out how many bytes each row represents. If the peak size was 0,
	# make it 1 so that the Y-axis covers a non-zero range of values.
	# Likewise for end_time.
	if (0 == $peak_mem_total_szB) { $peak_mem_total_szB = 1; }
	if (0 == $end_time ) { $end_time = 1; }
	my $K = $peak_mem_total_szB / $graph_y;

	$x = 0;
	my $prev_x = 0;
	my $prev_y_max = 0;
	my $prev_char = ':';

	for (my $i = 0; $i < $n_snapshots; $i++) {

	# Work out which column this snapshot belongs to.
	$prev_x = $x;
	my $x_pos_frac = ($times[$i] / ($end_time)) * $graph_x;
	$x = int($x_pos_frac) + 1; # +1 due to Y-axis
	# The final snapshot will spill over into the n+1th column, which
	# doesn't get shown. So we fudge that one and pull it back a
	# column, as if the end_time was actually end_time+epsilon.
	if ($times[$i] == $end_time) {
	($x == $graph_x+1) or die;
	$x = $graph_x;
	}

	# If there was a gap between the previous snapshot's column and this
	# one, we draw a horizontal line in the gap (so long as it doesn't
	# trash the x-axis). Without this, graphs with a few sparse
	# snapshots look funny -- as if the memory usage is in temporary
	# spikes.
	if ($prev_y_max > 0) {
	for (my $x2 = $prev_x + 1; $x2 < $x; $x2++) {
	$graph[$x2][$prev_y_max] = $prev_char;
	}
	}

	# Choose the column char.
	my $char;
	if ($i == $peak_num) { $char = $peak_char; }
	elsif ($is_detaileds[$i]) { $char = $detailed_char; }
	else { $char = $normal_char; }

	# Grow this snapshot bar from bottom to top.
	my $y_max = 0;
	for ($y = 1; $y <= $graph_y; $y++) {
	if ($mem_total_Bs[$i] >= $y * $K) {
	# Priority order for chars: peak > detailed > normal
	my $should_draw_char =
	(($char eq $peak_char)
	or
	($char eq $detailed_char and
	$graph[$x][$y] ne $peak_char
	)
	or
	($char eq $normal_char and
	$graph[$x][$y] ne $peak_char and
	$graph[$x][$y] ne $detailed_char
	)
	);

	if ($should_draw_char) {
	$graph[$x][$y] = $char;
	}
	$y_max = $y;
	}
	}
	$prev_y_max = $y_max;
	$prev_char = $char;
	}

	#-------------------------------------------------------------------------
	# Print graph[][].
	#-------------------------------------------------------------------------
	my ($y_label, $y_unit) = B_max_label($peak_mem_total_szB);
	my ($x_label, $x_unit);
	if ($time_unit eq "i") { ($x_label, $x_unit) = i_max_label($end_time) }
	elsif ($time_unit eq "ms") { ($x_label, $x_unit) = t_max_label($end_time) }
	elsif ($time_unit eq "B") { ($x_label, $x_unit) = B_max_label($end_time) }
	else { die "bad time_unit: $time_unit\n"; }

	printf(" %2s\n", $y_unit);
	for ($y = $graph_y; $y >= 0; $y--) {
	if ($graph_y == $y) { # top row
	print($y_label);
	} elsif (0 == $y) { # bottom row
	print(" 0 ");
	} else { # anywhere else
	print(" ");
	}

	# Axis and data for the row.
	for ($x = 0; $x <= $graph_x; $x++) {
	printf("%s", $graph[$x][$y]);
	}
	if (0 == $y) {
	print("$x_unit\n");
	} else {
	print("\n");
	}
	}
	printf(" 0%s%5s\n", ' ' x ($graph_x-5), $x_label);

	#-------------------------------------------------------------------------
	# Print snapshot numbers.
	#-------------------------------------------------------------------------
	print("\n");
	print("Number of snapshots: $n_snapshots\n");
	print(" Detailed snapshots: [");
	my $first_detailed = 1;
	for (my $i = 0; $i < $n_snapshots; $i++) {
	if ($is_detaileds[$i]) {
	if ($first_detailed) {
	printf("$i");
	$first_detailed = 0;
	} else {
	printf(", $i");
	}
	if ($i == $peak_num) {
	print(" (peak)");
	}
	}
	}
	print("]\n\n");

	#-------------------------------------------------------------------------
	# Print snapshots, from $tmp_file.
	#-------------------------------------------------------------------------
	open(TMPFILE, "< $tmp_file")
	\|\| die "Cannot open $tmp_file for reading\n";

	while (my $line = <TMPFILE>) {
	print($line);
	}
	unlink($tmp_file);
	}

	#-----------------------------------------------------------------------------
	# Misc functions
	#-----------------------------------------------------------------------------
	sub commify ($) {
	my ($val) = @_;
	1 while ($val =~ s/^(\d+)(\d{3})/$1,$2/);
	return $val;
	}


	#----------------------------------------------------------------------------
	# "main()"
	#----------------------------------------------------------------------------
	process_cmd_line();
	read_input_file();

	##--------------------------------------------------------------------##
	##--- end ms_print.in ---##
	##--------------------------------------------------------------------##