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#! /usr/bin/env perl
#############################################
# Help pkfix decipher fonts in a PostScript #
# file produced by an ancient dvips #
# #
# By Scott Pakin <scott+pkfh@pakin.org> #
#############################################
use File::Spec;
use File::Temp qw (tempfile);
use File::Basename;
use Getopt::Long;
use Pod::Usage;
use warnings;
use strict;
# Define some global variables.
my $progname = basename $0; # Name of this program
our $VERSION = "1.4"; # Version number of this program
my %name2chars; # Map from a font name to a character list
my $GS = $ENV{"GS"} || "gs"; # Name of the Ghostscript interpreter
my $TFTOPL = $ENV{"TFTOPL"} || "tftopl"; # Name of the TFM to PL converter
my $dpi = 300; # Number of dots per inch used to generate bitmapped characters
my @tfmlist; # List of TFM files to use
my %fontmatch; # Map from a font name to its best match
my $xinc = 36; # Width of font name in PostScript points
my $yinc = 24; # Height of font in PostScript points
my $init_yinc = 36; # Space after title
my %tfmfontwidth; # Map from font name to character number to character width
my %tfm2size; # Map from font name to design size
my %tfmmissing; # Set of TFM files we looked for but didn't find
my ($dvips_xscale, $dvips_yscale); # Scaling factors from Dvips's PostScript CTM
my $discard_output = $^O eq "MSWin32" ? "> NUL:" : "> /dev/null 2>&1"; # Command suffix to discard all output
# Define the global variables that the user can modify from the command line.
my $wanthelp = 0; # 1=user wants to see the program's documentation
my $wantversion = 0; # 1=user wants to see the program's version number
my $verbose = 1; # 0=quiet; 1=verbose output; 2=more verbose output
my @forced_fonts; # Font mappings the user asserts are correct
my @exclude_res; # Regexps for fonts to exclude
my @extra_tfms; # Extra TFM files to use
my %retained_t3s; # Type 3 fonts to retain as is
my $sample_file_ps; # Name of a PostScript file of font samples to write
my $sample_file_tex; # Name of a TeX file of font samples to write
my $single_font_use = 0; # 1=one use per font; 0=allow repetitions
my $samples_per_page = 25; # Number of font samples to print per page
my $tfm_cache_file; # Name of a file in which to cache font metrics
my $any_scale = 0; # 0=1X, 1.1X, 1.2X, ...; 1=any scale is allowed
###########################################################################
# Read %tfm2size, %tfmfontwidth, and %tfmmissing from a file named by
# $tfm_cache_file.
sub read_tfm_cache_file
{
open(CACHEFILE, "<", $tfm_cache_file) || do {
print STDERR "Ignoring TFM cache file $tfm_cache_file ($!).\n" if $verbose;
return;
};
print STDERR "Reading TFM data from $tfm_cache_file ... " if $verbose;
my $numlines = 0;
while (my $oneline = <CACHEFILE>) {
chomp $oneline;
my @fields = split " ", $oneline;
die "${progname}: Internal error" if $#fields == -1;
my $tfm = shift @fields;
if ($#fields == -1) {
# No metrics -- TFM file must not have been found.
$tfmmissing{$tfm} = 1;
}
else {
# Parse and store the TFM data.
$tfm2size{$tfm} = shift @fields;
my %widths = @fields;
$tfmfontwidth{$tfm} = \%widths;
}
$numlines++;
}
close CACHEFILE;
print STDERR "done ($numlines entries).\n" if $verbose;
}
# Write %tfm2size, %tfmfontwidth, and %tfmmissing to a file named by
# $tfm_cache_file.
sub write_tfm_cache_file
{
my $numlines = 0;
print STDERR "Writing TFM data to $tfm_cache_file ... " if $verbose;
open(CACHEFILE, ">", $tfm_cache_file) || die "${progname}: Failed to create $tfm_cache_file ($!)\n";
while (my ($tfm, $size) = each %tfm2size) {
my @widths = %{$tfmfontwidth{$tfm}};
print CACHEFILE "$tfm $size @widths\n";
$numlines++;
}
foreach my $tfm (keys %tfmmissing) {
print CACHEFILE "$tfm\n";
$numlines++;
}
close CACHEFILE;
print STDERR "done ($numlines entries).\n" if $verbose;
}
# Given the base name of a .tfm file, process the file and return the
# font's design size and a mapping from character number to character
# width.
sub tfm2widths ($)
{
my $tfmname = $_[0]; # Name of the TFM file
my $designsize; # Design size of the font
my %num2width; # Resultant mapping
my $plname; # Name of PL file; some tftopl programs can't write to stdout.
my $plfile; # Filehandle corresponding to $plname
# First see if the information is already cached.
if (defined $tfm2size{$tfmname}) {
print STDERR " Processing $tfmname ... cached.\n" if $verbose >= 2;
return [$tfm2size{$tfmname}, %{$tfmfontwidth{$tfmname}}];
}
if (defined $tfmmissing{$tfmname}) {
print STDERR " Processing $tfmname ... cached as not found.\n" if $verbose >= 2;
return [$designsize, %num2width];
}
# The information is not cached -- read it from a file.
($plfile, $plname) = tempfile (DIR => File::Spec->tmpdir(), SUFFIX => ".pl");
close $plfile;
if (!system "$TFTOPL $tfmname $plname $discard_output") {
print STDERR " Processing $tfmname ... " if $verbose >= 2;
open (PLFILE, "<$plname") || die "${progname}: Unable to open $tfmname ($!)\n";
my $charnum; # Current character number
while (my $oneline = <PLFILE>) {
# Store the current character width.
$oneline =~ /\(CHARWD R (\S+)\)/ && do {
$num2width{$charnum} = $1 * $designsize;
next;
};
# Store the current character number.
$oneline =~ /\(CHARACTER (\S) (\S+)/ && do {
if ($1 eq "O") {
# Octal character number
$charnum = oct $2;
}
elsif ($1 eq "C") {
# ASCII character number
$charnum = ord $2;
}
else {
die "${progname}: Unknown TFM character type \"$1\"\n";
}
next;
};
# Store the font design size.
$oneline =~ /\(DESIGNSIZE R (\S+)\)/ && do {
$designsize = $1 + 0.0;
next;
};
}
close PLFILE;
print STDERR "done.\n" if $verbose >= 2;
}
else {
print STDERR " Discarding $tfmname (not found).\n" if $verbose >= 3;
}
unlink $plname;
return [$designsize, %num2width];
}
# Given two character maps, one for a document font and one for a TFM
# file, return the optimal scale factor for the TFM file to best match
# the document font.
sub optimal_scale ($$)
{
my %docmap = %{$_[0]}; # Map for a document font
my %tfmmap = %{$_[1]}; # Map for a TFM font
my $doc_dot_tfm = 0.0; # Sum of $docmap{$c}*$tfmmap{$c} for all $c
my $tfm_dot_tfm = 0.0; # Sum of $tfmmap{$c}**2 for all $c
while (my ($char, $docwidth) = each %docmap) {
my $tfmwidth = $tfmmap{$char};
return undef if !defined $tfmwidth; # Match is impossible.
$doc_dot_tfm += $docwidth * $tfmwidth;
$tfm_dot_tfm += $tfmwidth**2;
}
return 1.0 if $tfm_dot_tfm == 0.0; # Handle TFM characters that all have zero width.
my $optscale = $doc_dot_tfm / $tfm_dot_tfm;
unless ($any_scale) {
# Allow only values >= 1.0 and only multiples of 0.1.
return 1.0 if $optscale < 1.0;
$optscale = int($optscale*10 + 0.5) / 10;
}
return $optscale;
}
# Compare two character maps and return their mismatch (smaller is
# better). The third, optional, argument is a scale factor for the
# TFM file.
sub compare_maps ($$;$)
{
my %docmap = %{$_[0]}; # Map for a document font
my %tfmmap = %{$_[1]}; # Map for a TFM font
my $scale = $_[2] || 1.0; # Scale for each TFM width
my $sqdiff = 0; # Sum of squares of differences
while (my ($char, $docwidth) = each %docmap) {
my $tfmwidth = $tfmmap{$char};
return 10**9 if !defined $tfmwidth; # Match is impossible.
$sqdiff += ($docwidth - $tfmwidth*$scale) ** 2;
}
return $sqdiff;
}
# Given a Type 3 font definition, surround it with DVIPSBitmapFont comments.
sub write_comments ($$)
{
my ($fontname, $fontdef) = @_;
return $fontdef if !defined $fontmatch{$fontname}; # Font should not be substituted
my $tfm = $fontmatch{$fontname}->{"tfm"};
my $scale = $fontmatch{$fontname}->{"scale"};
my $origsize = $tfm2size{$tfm};
my $begincomment = sprintf '%%DVIPSBitmapFont: %s %s %.5g %d',
$fontname, $tfm, $origsize*$scale, 1+$#{$name2chars{$fontname}};
my $endcomment = '%EndDVIPSBitmapFont';
return "\n" . $begincomment . "\n" . $fontdef . "\n" . $endcomment . "\n";
}
# Escape an array of characters for PostScript's benefit.
sub psify (@)
{
my @ps_chars;
foreach my $onechar (@_) {
my $charnum = ord $onechar;
if ($onechar =~ /[\\()]/) {
push @ps_chars, "\\" . $onechar;
}
elsif ($charnum >= 32 && $charnum <= 126) {
push @ps_chars, $onechar;
}
else {
push @ps_chars, sprintf "\\%03o", $charnum;
}
}
return @ps_chars;
}
# Escape an array of characters for TeX's benefit.
sub texify (@)
{
my @texchars;
foreach my $onechar (@_) {
if ($onechar =~ m|[\000-\037\\{}\177-\377]|) {
push @texchars, sprintf '\char"%02X{}', ord $onechar;
}
else {
push @texchars, $onechar;
}
}
return join "", @texchars;
}
# Parse a font specification into a list of hashes of information.
sub parse_font_spec ($)
{
my $spec = $_[0];
my $parse_error = "${progname}: Unable to parse font specification \"$spec\"\n";
if ($spec =~ /^\s*([-\w\*]+)(.*)$/o) {
my $tfm = $1; # Name of tfm file (e.g., "cmr10")
my $scale_info = $2; # Concatenation of scale type and scale factor
my $scale_type; # "X"=multiply, "@"=assign
my $scale_amount; # How much to scale the TFM file, "*"=automatic
# Parse the different scale types.
if ($scale_info =~ /^\s*$/o) {
# Empty
$scale_type = 'X';
$scale_amount = 1.0;
}
elsif ($scale_info =~ /^\s*\@\s*([\d.]+)\s*X\s*$/io) {
# "@ <number> X"
$scale_type = 'X';
$scale_amount = $1 + 0.0;
}
elsif ($scale_info =~ /^\s*\@\s*([\d.]+)\s*(pt|bp)\s*$/io) {
# "@ <number> pt" or "@ <number> bp"
$scale_type = '@';
$scale_amount = $1;
$scale_amount *= 72.0/72.27 if $2 eq "bp"; # Convert to TeX points
}
elsif ($scale_info =~ /^\s*\@\s*\*\s*$/o) {
# "@ *"
$scale_type = 'X';
$scale_amount = "*"
}
else {
die $parse_error;
}
# If the tfm file contains a "*", replace the "*" with a
# variety of font sizes.
my @fontlist;
if ($tfm =~ /\*/) {
foreach my $fsize (5..17) {
my $full_tfm = $tfm;
$full_tfm =~ s/\*/$fsize/g;
push @fontlist, {"tfm" => $full_tfm,
"scale_type" => $scale_type,
"scale" => $scale_amount};
}
}
else {
push @fontlist, {"tfm" => $tfm,
"scale_type" => $scale_type,
"scale" => $scale_amount};
}
return \@fontlist;
}
die $parse_error;
}
# Return all of the unique items in a given list.
sub unique_items (@)
{
my %item_hash;
foreach my $item (@_) {
$item_hash{$item} = 1;
}
return keys %item_hash;
}
###########################################################################
# Parse the command line.
Getopt::Long::Configure ("bundling");
GetOptions ("h|help" => \$wanthelp,
"v|verbose+" => \$verbose,
"V|version" => \$wantversion,
"q|quiet" => sub {$verbose = 0},
"f|force=s" => \@forced_fonts,
"i|include=s" => \@extra_tfms,
"x|exclude=s" => \@exclude_res,
"k|keep=s" => sub {$retained_t3s{$_[1]} = 1},
"t|tex=s" => \$sample_file_tex,
"p|ps=s" => \$sample_file_ps,
"s|spp=i" => \$samples_per_page,
"C|cache=s" => \$tfm_cache_file,
"a|any-scale!" => \$any_scale,
"1|no-repeats" => \$single_font_use) || pod2usage(2);
if ($wantversion) {
print "pkfix-helper $VERSION\n";
exit 0;
}
if ($wanthelp) {
pod2usage (-verbose => $verbose,
-exitval => "NOEXIT");
print "Report bugs to scott+pkfh\@pakin.org.\n" if $verbose == 1;
exit 0;
}
my $infilename = $#ARGV>=0 ? $ARGV[0] : "-";
my $outfilename = $#ARGV>=1 ? $ARGV[1] : "-";
die "${progname}: Samples per page must be at least 1 ($samples_per_page was specified)\n" if $samples_per_page < 1;
# Convert any user-specified TFMs to the appropriate internal format.
foreach my $tfm (@extra_tfms) {
my $font_spec = parse_font_spec $tfm;
push @tfmlist, @$font_spec;
}
# Parse the list of forced font mappings.
foreach my $mapstr (@forced_fonts) {
$mapstr =~ /^(\w+)\s*=\s*(.*)$/ || die "${progname}: Unable to parse font specification \"$mapstr\"\n";
my $parsed_font_spec = parse_font_spec $2;
if (defined $fontmatch{$1}) {
# Append to an existing font match.
$fontmatch{$1} = [@{$fontmatch{$1}}, @$parsed_font_spec];
}
else {
# Define a new font match,
$fontmatch{$1} = $parsed_font_spec;
}
}
# Construct a list of (possibly nonexistent) TFM files to try. These
# should be in order of decreasing likelihood. Each entry in the list
# is of the form {full name, scale factor}.
@exclude_res = ('^\s*$') if $#exclude_res == -1;
foreach my $size_scale ([10, 1.0],
[12, 1.0],
[10, 1.1],
[17, 1.0],
[ 9, 1.0],
[ 8, 1.0],
[ 7, 1.0],
[ 6, 1.0],
[ 5, 1.0],
[10, 1.2],
# The following are common cmbx12 section headings.
[12, 14.40/12],
[12, 17.28/12],
[12, 20.74/12],
[12, 24.88/12]) {
my ($pointsize, $scale) = @$size_scale;
FONTLOOP:
foreach my $basefont (qw (cmr cmb cmtt cmbsy cmbx cmbxsl cmbxti
cmcsc cmex cmitt cmmi cmmib cmsl cmsltt
cmss cmssbx cmssi cmsy cmti lasy lasyb
msam msbm cmssdc cmtcsc)) {
my $friendly_name = sprintf "%s%d \@ %.5gX", $basefont, $pointsize, $scale;
foreach my $regexp (@exclude_res) {
next FONTLOOP if $friendly_name =~ $regexp;
}
push @tfmlist, {"tfm" => $basefont . $pointsize,
"scale_type" => "X",
"scale" => $scale};
}
}
# Read the entire input file.
$| = 1;
if ($verbose) {
printf STDERR "Reading %s ... ", $infilename eq "-" ? "standard input" : $infilename;
}
my $entirefile;
{
local $/ = undef;
open (INFILE, "<$infilename") || die "open(\"$infilename\"): $!\n";
binmode INFILE;
$entirefile = <INFILE>;
close INFILE;
}
print STDERR "done.\n" if $verbose;
# Rename the fonts in each subdocument (figure).
my @fontrenames;
my $fignum = 1;
my $numrenamed = 0;
while ($entirefile =~ /(\%\%BeginDocument: (.*?)\n.*?\%\%EndDocument)/gs) {
my $figure = $1;
my $newfigure = $1;
my $figname = $2;
if ($verbose >= 2) {
if ($fignum == 1) {
print STDERR "Renaming all fonts encountered in included documents:\n";
}
print STDERR " $figname\n";
}
while ($figure =~ m|/(\S+)\s+\d+\s+\d+\s+df(.*?>[^<>]*?[DI])\s+E|gs) {
my $fontname = $1; # Name of current font (e.g., "Fa")
$newfigure =~ s,(?<=/)$fontname\b,${fontname}_$fignum,gs;
$newfigure =~ s,\b$fontname(?=\(),${fontname}_$fignum,gs;
$numrenamed++;
if ($verbose >= 2) {
printf STDERR " %s --> %s_%d\n", $fontname, $fontname, $fignum;
}
}
if ($figure ne $newfigure) {
# Remove the font-defining dictionary from the the subdocument
# as it may confuse pkfix. Store it so we can later reinsert
# it into the main document's font-defining dictionary.
my $texdict = "";
if ($newfigure =~ s/TeXDict begin \d+ \d+ \d+ \d+ \d+ \(.*?\)\s+\@start(.*?)end//gs) {
$texdict = $1;
}
else {
warn "${progname}: Failed to extract a font-defining TeXDict from $figname\n";
}
push @fontrenames, [$figure, $newfigure, $texdict];
}
$fignum++;
}
if ($verbose && $entirefile =~ /\%\%BeginDocument:/s) {
print STDERR "Number of Type 3 fonts encountered in included documents: $numrenamed\n";
}
foreach my $ren (@fontrenames) {
my ($before, $after, $notused) = @$ren;
$entirefile =~ s/\Q$before\E/$after/gs;
}
# If the document contains a subdocument with (now renamed) font
# definitions, hoist those definitions adjacent to the main document's
# font definitions so pkfix can find them.
if (@fontrenames) {
if ($entirefile =~ /(TeXDict begin (\d+) (\d+) (\d+) (\d+) (\d+) \(.*?\)\s+\@start.*?)(?=end)/s) {
my $fontdict = $1;
my $morefonts = "";
foreach my $ren (@fontrenames) {
$morefonts .= $ren->[2];
}
$entirefile =~ s/(\Q$fontdict\E)/$1$morefonts/s;
}
else {
warn "${progname}: Failed to find a font-defining TeXDict\n";
}
}
# Construct a mapping from each document font name to a list of valid
# characters in that font.
while ($entirefile =~ m|/(\S+)\s+\d+\s+\d+\s+df(.*?>[^<>]*?[DI])\s+E|gs) {
my $fontname = $1; # Name of current font (e.g., "Fa")
my $fontbody = $2; # List of character definitions as hexadecimal strings
my $charnum = 0; # Current character number
my @charlist = (); # List of valid characters in PostScript-friendly format
while ($fontbody =~ /<[0-9A-F\s]+>(.*?[DI])/gs) {
# Put the current character number in $charnum then append the
# corresponding character to @charlist.
my @chardef = split " ", $1;
if ($chardef[$#chardef] eq "I") {
$charnum++;
}
else {
$charnum = $chardef[$#chardef-1];
}
push @charlist, chr $charnum;
}
$name2chars{$fontname} = \@charlist;
}
my @sortedfontnames = sort {$#{$name2chars{$b}} <=> $#{$name2chars{$a}}
|| $a cmp $b} keys %name2chars;
if ($verbose) {
printf STDERR "Total number of Type 3 fonts encountered: %d\n", 1+$#sortedfontnames;
if ($verbose >= 2) {
foreach my $fontname (@sortedfontnames) {
printf STDERR " %-5.5s -- %3d character(s)\n", $fontname, 1+$#{$name2chars{$fontname}};
}
}
}
die "${progname}: No Type 3 fonts were encountered in the input file\n" if $#sortedfontnames==-1;
# Determine the number of dots per inch used to generate the bitmaps.
if ($entirefile =~ /dpi=(\d+)/i
|| $entirefile =~ /Resolution (\d+)dpi/i) {
$dpi = $1 + 0;
printf STDERR "Bitmapped fonts are typeset at $dpi DPI.\n" if $verbose;
}
else {
warn "${progname}: Could not determine the target printer resolution; assuming $dpi DPI\n";
}
# Insert some helper code after the tex.pro ProcSet.
my $output_width_ps = $entirefile; # PostScript code to output character widths
my $showfontnamecode = <<"SHOWFONTNAME";
\%\%BeginProcSet: $progname.pro
TeXDict begin
% char0 char1 PRINT-WIDTH -
%
% Output the name of the current font (font-name-string), its character
% number (char0), and the character's width in PostScript points.
/print-width {
pop
(FONT: ) print font-name-string print
( CHAR: ) print 8 string cvs print
( XPOS: ) print currentpoint pop 80 string cvs print
(\\n) print
} bind def
% font-name sample-string PRINT-CHAR-WIDTHS -
%
% Store the name of font-name in the string font-name-string. Then, select
% font-name and, for each character of test-string, call print-width
% to output its width.
/print-char-widths {
/sample-string exch def
/font-name exch def
font-name 8 string cvs /font-name-string exch def
font-name cvx exec {print-width} sample-string kshow
} bind def
end
\%\%EndProcSet
SHOWFONTNAME
;#'
if ($output_width_ps !~ s/\%\%BeginProcSet: tex\w*\.pro.*?\%\%EndProcSet/$&\n$showfontnamecode/s) {
print STDERR "No tex.pro ProcSet was found. We have to guess where to inject PostScript code.\n" if $verbose >= 3;
die "${progname}: Unable to inject prologue code\n" if $output_width_ps !~ s/TeXDict begin\s+\d+\s+\d+\s+bop/\n$showfontnamecode\n$&/s;
}
# Define some code to display the width of every valid character in
# every bitmapped font. Fonts are displayed in decreasing order of
# the number of characters used.
my $displaycode = "\%\%Page: 1 1\nTeXDict begin\n1 0 bop\n";
foreach my $fontnum (0 .. $#sortedfontnames) {
# Duplicate the last character of the sample string so kshow can
# process the final character delta.
my $fontname = $sortedfontnames[$fontnum];
my @charlist = psify @{$name2chars{$fontname}};
my $samplestring = join("", @charlist) . $charlist[$#charlist];
# Typeset the string starting at horizontal offset 0.
$displaycode .= sprintf "0 0 moveto\n";
$displaycode .= "/$fontname ($samplestring) print-char-widths\n";
}
# Dvips scales the page. Determine the scaling it uses.
$displaycode .= <<'ENDDISPLAYCODE';
(CURRENTMATRIX: ) print
matrix currentmatrix ==
(\n) print
eop
end
ENDDISPLAYCODE
;
# Replace the bulk of the PostScript file with the display code.
if ($output_width_ps !~ s/\%\%Page:.*(\%\%Trailer)/$displaycode$1/s) {
print STDERR 'No %%Page and/or %%Trailer comments were found. We have to guess where to inject PostScript code.', "\n" if $verbose >= 3;
die "${progname}: Unable to inject display code\n" if $output_width_ps !~ s/TeXDict begin\s+\d+\s+\d+\s+bop.*eop\s+end/\n$displaycode\n/s;
}
# Output the modified PostScript code to a temporary file, run
# Ghostscript on the temporary file, and process Ghostscript's output.
my ($psfile, $psfilename) = tempfile ("pkfix-helper-XXXXXX",
DIR => File::Spec->tmpdir(),
SUFFIX => ".ps");
binmode $psfile;
print $psfile $output_width_ps;
close $psfile;
undef $output_width_ps;
my %fontwidth; # Map from font name to character number to character width
my @previnfo = ("", 0.0); # Previous font name and final character position
my $gscmd = "$GS -q -dNOPAUSE -dBATCH -dNODISPLAY $psfilename";
print STDERR "Finding character widths ... " if $verbose >= 1;
print STDERR "\n Invoking: $gscmd\n" if $verbose >= 2;
print STDERR "done.\n" if $verbose >= 1;
open (GSCMD, "$gscmd|") || die "${progname}: failed to fork ($!)\n";
while (my $oneline = <GSCMD>) {
if ($oneline =~ /FONT: (\S+)\s*CHAR: (\d+)\s*XPOS: (\S+)/o) {
my ($fontname, $charnum, $xpos) = ($1, $2, $3);
my $width = $xpos + 0.0;
$width -= $previnfo[1] if $fontname eq $previnfo[0];
$fontwidth{$fontname}->{$charnum} = $width * 72.27 / $dpi;
@previnfo = ($fontname, $xpos);
}
elsif ($oneline =~ /CURRENTMATRIX: \[\s*([-\d.]+)\s+[-\d.]+\s+[-\d.]+\s+([-\d.]+)\s+[-\d.]+\s+[-\d.]+\s*\]/o) {
$dvips_xscale = $1 * 1.0;
$dvips_yscale = $2 * -1.0;
}
}
close GSCMD || die "${progname}: failed to run $GS ($!)\n";
unlink $psfilename;
die "${progname}: No character-width information was found\n" if !%fontwidth;
# Read TFM font metrics from a cache file if specified.
read_tfm_cache_file() if defined $tfm_cache_file;
# Read each TFM file and store its design size and character widths.
print STDERR "Reading TFM files ... " if $verbose;
print STDERR "\n" if $verbose >= 2;
foreach my $tfm (sort {$a cmp $b}
unique_items map {$_->{"tfm"}} (@tfmlist, map {@$_} values %fontmatch)) {
my ($designsize, %num2widths) = @{tfm2widths $tfm};
if (%num2widths) {
$tfmfontwidth{$tfm} = \%num2widths;
$tfm2size{$tfm} = $designsize * 1.0;
}
else {
$tfmmissing{$tfm} = 1;
}
}
# Remove nonexistent fonts from @tfmlist and replace all absolute
# ("@") scaling with relative ("X") scaling.
my @goodtfmlist;
foreach my $tfminfo (@tfmlist) {
my $tfm = $tfminfo->{"tfm"};
next if !defined ($tfmfontwidth{$tfm});
$tfminfo->{"designsize"} = $tfm2size{$tfm};
if ($tfminfo->{"scale_type"} eq "@") {
# Convert absolute to relative sizes.
$tfminfo->{"scale_type"} = "X";
$tfminfo->{"scale"} /= $tfminfo->{"designsize"};
}
push @goodtfmlist, $tfminfo;
}
@tfmlist = @goodtfmlist;
undef @goodtfmlist;
# Do the same for all user-specified font mappings but abort if none
# of the specified possibilities represent a valid TFM file.
while (my ($fontname, $tfmlist) = each %fontmatch) {
my $anyvalid = 0;
foreach my $tfminfo (@$tfmlist) {
my $tfm = $tfminfo->{"tfm"};
next if !defined ($tfmfontwidth{$tfm});
$tfminfo->{"designsize"} = $tfm2size{$tfm};
if ($tfminfo->{"scale_type"} eq "@") {
# Convert absolute to relative sizes.
$tfminfo->{"scale_type"} = "X";
$tfminfo->{"scale"} /= $tfminfo->{"designsize"};
}
$anyvalid = 1;
}
if (!$anyvalid) {
print STDERR "failed.\n" if $verbose;
die "${progname}: Unable to utilize any of the TFM files specified for font $fontname\n";
}
}
# Report the number of fonts in our repertoire.
my $numtfms = keys %tfm2size;
my $numfonts = 1 + $#tfmlist;
print STDERR "done ($numtfms TFMs in $numfonts scaling variations).\n" if $verbose;
die "${progname}: No TFM files were processed successfully\n" if !$numtfms;
# Write the TFM font metrics to a a cache file if specified.
write_tfm_cache_file() if defined $tfm_cache_file;
# Compare every document font (ordered by decreasing number of
# characters utilized) to every TFM file (in increasing order of
# obscurity).
print STDERR "Matching fonts:\n" if $verbose;
foreach my $fontname (@sortedfontnames) {
my @besttfms; # Best matching TFM file(s), sizes, and scales
my $bestmatch = 10**9; # Best matching value
# Don't substitute the font if we were told not to.
if (defined $retained_t3s{$fontname}) {
print STDERR " Retaining $fontname as a bitmapped font.\n" if $verbose == 1;
next;
}
# Determine the list of eligible fonts to compare against.
my @eligible_tfms;
foreach my $tfminfo ($fontmatch{$fontname} ? @{$fontmatch{$fontname}} : @tfmlist) {
if ($tfminfo->{"scale"} eq "*") {
# Replace "*" with the best scaling factor we can find.
next if !defined $tfmfontwidth{$tfminfo->{"tfm"}};
my $newscale = optimal_scale $fontwidth{$fontname}, $tfmfontwidth{$tfminfo->{"tfm"}};
if (defined $newscale) {
# Replace the "*" with the optimal multiplier.
my %newtfminfo = %$tfminfo;
$newtfminfo{"scale"} = $newscale;
push @eligible_tfms, \%newtfminfo;
}
else {
# Fonts are incomparable.
my $tfm = $tfminfo->{"tfm"};
print STDERR " Not scaling $tfm; ${fontname}'s character set is not a subset of ${tfm}'s.\n" if $verbose >= 2;
}
}
else {
# The desired scaling factor is specified explicitly.
push @eligible_tfms, $tfminfo;
}
}
die "${progname}: No fonts are eligible to match $fontname\n" if !@eligible_tfms;
# Try each TFM file in increasing order of obscurity.
print STDERR " Processing $fontname ... " if $verbose == 1;
foreach my $tfminfo (@eligible_tfms) {
my $tfm = $tfminfo->{"tfm"};
next if !defined $tfmfontwidth{$tfm};
my $scale = $tfminfo->{"scale"};
printf STDERR " Comparing %s and %s \@ %.5gX ... ", $fontname, $tfm, $scale if $verbose >= 2;
my $match = compare_maps $fontwidth{$fontname}, $tfmfontwidth{$tfm}, $scale;
if ($bestmatch > $match) {
# We found a closer match than what we had before.
$bestmatch = $match;
@besttfms = ($tfminfo);
}
elsif ($bestmatch == $match) {
# We found an equal match to what we had before.
push @besttfms, $tfminfo;
}
printf STDERR "done (mismatch=%.5f).\n", $match if $verbose >= 2;
}
# Select the first of the best matches.
$fontmatch{$fontname} = $besttfms[0];
my $besttfminfo = $fontmatch{$fontname};
my $besttfm = $besttfminfo->{"tfm"};
my $bestscale = $besttfminfo->{"scale"};
if ($verbose >= 2) {
if ($#besttfms == 0) {
# Single winner
printf STDERR " Best match for %s is %s \@ %.5gX with mismatch=%.5f.\n\n",
$fontname, $besttfm, $bestscale, $bestmatch;
}
else {
# Tie for first place
printf STDERR " Best match for %s is %s \@ %.5gX (tied among %s) with mismatch=%.5f.\n\n",
$fontname, $besttfm, $bestscale,
join("/", map {sprintf "%s\@%.5gX", $_->{"tfm"}, $_->{"scale"}} @besttfms),
$bestmatch;
}
}
elsif ($verbose == 1) {
printf STDERR "done (%s \@ %.5gX, mismatch=%.5f).\n", $besttfm, $bestscale, $bestmatch;
}
warn "${progname}: Best match for $fontname is rather poor\n" if $bestmatch>=1.0;
# Optionally remove the font from @goodtfmlist.
if ($single_font_use) {
@tfmlist = grep {$_->{"tfm"} ne $besttfm
|| $_->{"scale"} != $bestscale} @tfmlist;
}
}
# Insert %DVIPSBitmapFont comments around every Type 3 font definition.
my $commented_ps = $entirefile;
my $infilename_ps = $infilename; # PostScript version of $infilename
$infilename_ps =~ s/([\(\)\\])/\\$1/g;
$commented_ps =~ s|^\%(End)?DVIPSBitmapFont.*$||gm; # Remove existing comments (if any)
$commented_ps =~ s|/(\S+)\s+\d+\s+\d+\s+df.*?>[^<]*?[DI]\s+E|write_comments($1, $&)|gse;
if ($commented_ps !~ /\%\%EndProlog/) {
# pkfix fails silently if it doesn't see an %%EndProlog.
print STDERR "No %%EndProlog comment was found. Adding one.\n" if $verbose >= 3;
$commented_ps =~ s|TeXDict begin\s+\d+\s+\d+\s+bop|\%\%EndProlog\n$&|s;
}
# Help pkfix handle ancient versions of dvips by artificially making
# dvips look newer.
$commented_ps =~ s|(\%\%Creator: dvips\S*) \S+|$1 5.62|; # pkfix rejects dvips <= 5.58
if ($commented_ps =~ s|(\d+)\s+(\d+)\s+(\d+)\s+(\d+)\s+(\d+)\s+\@start|$1 $2 $3 $4 $5 ($infilename_ps) \@start|gx) {
# pkfix expects *six* arguments to @start, not five as in old
# versions of dvips.
$commented_ps =~ s|/\@start\s*\{|$& pop |;
}
if ($commented_ps !~ /^%DVIPSParameters:.*dpi=([\dx]+)/) {
# Tell pkfix what resolution to use.
my $dvips_params = "\%DVIPSParameters: dpi=$dpi";
if ($commented_ps !~ s|^\%\%EndComments.*$|$&\n$dvips_params|m) {
# Comments must have been stripped.
$commented_ps =~ s|\n|\n$dvips_params\n|;
}
}
# Write the modified PostScript code to the specified file.
open (OUTFILE, ">$outfilename") || die "${progname}: Unable to open $outfilename ($!)\n";
print OUTFILE $commented_ps;
close OUTFILE;
undef $commented_ps;
# If the user requested a PostScript font sample, produce that.
if (defined $sample_file_ps) {
# Insert some helper code at an appropriate place in the file.
my $sample_ps = $entirefile;
my $showfontnamecode = <<"SHOWFONTNAME";
\%\%BeginProcSet: $progname.pro
TeXDict begin
% font-name sample-string PRINT-FONT-SAMPLE -
%
% Store the name of font-name in the string font-name-string. Then,
% output font-name-string in Times Bold in case the user wants to view
% the font samples. Next, select font-name and output the sample
% string. Finally, move the cursor to the next line in preparation for
% the next invocation of print-font-sample.
/print-font-sample {
/sample-string exch def
/font-name exch def
font-name 8 string cvs /font-name-string exch def
gsave
/Times-Bold 12 selectfont
font-name-string show (:) show
grestore
gsave
42 0 rmoveto
font-name cvx exec
currentfont bitmap-font-transform makefont setfont
sample-string show
grestore
0 -24 rmoveto
} def
\% Define a transformation matrix for dvips bitmapped fonts. We _could_
\% do this dynamically but there seems to be a bug in GhostView (v3.6.1)
\% or GhostScript (ESP v7.07.1) that causes the page layout to change
\% with rescaling. To avoid problems we simply hardwire the scaling
\% factor.
/bitmap-font-transform [$dvips_xscale 0.0 0.0 $dvips_yscale 0 0] def
end
\%\%EndProcSet
SHOWFONTNAME
;
if ($sample_ps !~ s/\%\%BeginProcSet: tex\w*\.pro.*\%\%EndProcSet/$&\n$showfontnamecode/s) {
print STDERR "No tex.pro ProcSet was found. We have to guess where to inject PostScript code.\n" if $verbose >= 3;
die "${progname}: Unable to inject prologue code\n" if $sample_ps !~ s/TeXDict begin\s+\d+\s+\d+\s+bop/\n$showfontnamecode\n$&/s;
}
# Generate code to output a sample of each font in turn.
my $displaycode = <<"PAGEHEADER";
\%\%Page: 1 1
TeXDict begin
1 0 bop
\% Display a page title.
0 0 moveto
initmatrix
gsave
/Helvetica 18 selectfont
(Fonts used by $infilename_ps) show
grestore
0 -$init_yinc rmoveto
\% Display samples of each document font in decreasing order of the number
\% of characters utilized from the font.
PAGEHEADER
;
my $pageno = 1;
foreach my $fontnum (0 .. $#sortedfontnames) {
my $fontname = $sortedfontnames[$fontnum];
my $samplestring = join("", psify @{$name2chars{$fontname}});
$displaycode .= "/$fontname ($samplestring) print-font-sample\n";
if ($fontnum % $samples_per_page == $samples_per_page-1
&& $fontnum != $#sortedfontnames) {
# Insert a page break after every $samples_per_page font samples.
$pageno++;
$displaycode .= <<"PAGETRANSITION";
eop
end
\%\%Page: $pageno $pageno
TeXDict begin
$pageno @{[$pageno-1]} bop
0 0 moveto
initmatrix
PAGETRANSITION
;
}
}
$displaycode .= "eop\nend\n";
if ($sample_ps !~ s/\%\%Page:.*(\%\%Trailer)/$displaycode$1/s) {
print STDERR 'No %%Page and/or %%Trailer comments were found. We have to guess where to inject PostScript code.', "\n" if $verbose >= 3;
die "${progname}: Unable to inject display code\n" if $sample_ps !~ s/TeXDict begin\s+\d+\s+\d+\s+bop.*eop\s+end/\n$displaycode\n/s;
}
# Write the PostScript file.
open (SAMPLE_PS, ">$sample_file_ps") || die "${progname}: Unable to open $sample_file_ps ($!)\n";
binmode SAMPLE_PS;
print SAMPLE_PS $sample_ps;
close SAMPLE_PS;
undef $sample_ps;
}
# If the user requested a TeX font sample, produce that.
if (defined $sample_file_tex) {
my $oneline; # One line to write to the TeX file.
open (SAMPLE_TEX, ">$sample_file_tex") || die "${progname}: Unable to open $sample_file_tex ($!)\n";
select (SAMPLE_TEX);
$| = 1;
select (STDOUT);
format SAMPLE_TEX =
% ^<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< ~~
$oneline
.
$oneline = <<"TEX_HEADER";
This file was generated by $0. DO NOT EDIT. Edit $progname instead.
Note that this is a Plain TeX document. Compile it with tex, *not*
latex.
TEX_HEADER
;
write SAMPLE_TEX;
print SAMPLE_TEX <<'TEX_BOILERPLATE';
% Make printable all special characters between
% \makeprintable...\endmakeprintable except for "\", "{", and "}".
\def\makeprintable{%
\begingroup
\def\do##1{\catcode`##1=12}%
\dospecials
\catcode`\\=0\relax
\catcode`\{=1\relax
\catcode`\}=2\relax
}
\let\endmakeprintable=\endgroup
% Put a piece of text at specific PostScript coordinates.
\newdimen\xofs
\newdimen\yofs
\def\put(#1,#2)#{%
\leavevmode
\begingroup
\makeprintable
\xofs=#1bp
\yofs=#2bp
\afterassignment\puthelper
\toks0=%
}
\def\puthelper{%
\lower\yofs
\rlap{\hskip\xofs\the\toks0}%
\endmakeprintable
\endgroup
}
% We use Times Bold at 12 point for font names.
\font\timesbXII=ptmb at 12bp
% Don't add extra space to paragraphs.
\parindent=0pt
\parskip=0pt
% Output the document's title.
\font\somefont=phvr at 18bp
TEX_BOILERPLATE
;
# Output the document's title.
my $infilename_tex = texify split "", $infilename;
print SAMPLE_TEX '\put(0, 0){\somefont New fonts to use for ', "$infilename_tex}\n";
# Output samples of each font in turn.
print SAMPLE_TEX "\n\% Output font samples.\n";
my $firstfontnum = 0;
foreach my $fontnum (0 .. $#sortedfontnames) {
# Output a single font sample.
my $fontname = $sortedfontnames[$fontnum];
my $samplestring = texify @{$name2chars{$fontname}};
my $yoffset = ($fontnum-$firstfontnum)*$yinc + $init_yinc;
printf SAMPLE_TEX "\\put(0, %d){\\timesbXII %s:}%%\n", $yoffset, $fontname;
my $tfm = $fontmatch{$fontname}->{"tfm"};
my $scale = $fontmatch{$fontname}->{"scale"};
my $size = $tfm2size{$tfm};
printf SAMPLE_TEX "\\font\\somefont=%s%s\\somefont\n",
$tfm, $scale==1.0 ? "" : sprintf(" at %.5gbp", $scale*$size);
printf SAMPLE_TEX "\\put(%d, %d){%s}%%\n", $xinc, $yoffset, $samplestring;
if ($fontnum % $samples_per_page == $samples_per_page-1) {
# Insert a page break after every $samples_per_page font samples.
print SAMPLE_TEX "\\vskip 0pt plus 1fill\\eject\n";
$firstfontnum = $fontnum;
}
}
# Complete the TeX file.
print SAMPLE_TEX "\n\\bye\n";
close SAMPLE_TEX;
}
###########################################################################
__END__
=head1 NAME
pkfix-helper - preprocess dvips-produced PostScript documents before passing them to pkfix
=head1 SYNOPSIS
pkfix-helper
[B<--help>]
[B<--verbose>]
[B<--force>=I<name>=I<fontspec>]
[B<--ps>=I<filename.ps>]
[B<--tex>=I<filename.tex>]
[B<--cache>=I<filename>]
[B<--include>=I<fontspec>]
[B<--exclude>=I<regexp>]
[B<--keep>=I<fontspec>]
[B<--quiet>]
[B<--no-repeats>]
[B<--spp>=I<number>]
[I<input.ps> [I<output.ps>]]
=head1 DESCRIPTION
=head2 Motivation
PostScript documents created with old versions of B<dvips> almost
invariably utilize bitmapped (PostScript S<Type 3>) fonts. The
problem with bitmapped fonts is that they target a specific device
resolution; a PostScript file produced using S<300 DPI> fonts will
look grainy on a S<600 DPI> printer. Even worse, I<all> bitmapped
fonts look grainy when zoomed in on screen. The solution is to use
vector (PostScript S<Type 1>) fonts, which are resolution-independent
and appear crisp at any size or scale.
While it is no longer difficult to configure B<dvips> to use vector
fonts, it is not always possible to rerun B<dvips> on an old F<.dvi>
file. The F<.dvi> file and document source may have been lost; or,
the source may no longer compile because packages it depends upon may
no longer be available.
Heiko Oberdiek's B<pkfix> script replaces bitmapped fonts in
B<dvips>-produced PostScript files with the corresponding vector
fonts. It works by parsing the PostScript comments with which
B<dvips> surrounds bitmapped-font definitions. For example, a font
definition beginning with the comment C<%DVIPSBitmapFont: Fi cmss10 11
28> and ending with a matching C<%EndDVIPSBitmapFont> is known to
define font C<Fi> as C<cmss10> (Computer Modern Sans Serif at a design
size of S<10 points>) scaled to S<C<11> points>. Only the C<28>
characters actually used by the document are defined. B<pkfix> then
replaces the font definition with one that defines C<Fi> using the
same set of characters but taken from the F<cmss10.pfb> vector font
file.
Unfortunately, B<pkfix> works only with versions of B<dvips> newer
than v5.58 S<(ca. 1996)>. Naturally, the older a PostScript document,
the less likely its sources still exist and can still be recompiled.
Older versions of B<dvips> lack C<%DVIPSBitmapFont> comments and
various other PostScript comments on which B<pkfix> relies. Without
PostScript comments to guide it, B<pkfix> is unable to determine which
vector fonts correspond with which bitmapped fonts.
=head2 Overview
The B<pkfix-helper> script is a preprocessor for B<pkfix> that
attempts to determine the association between each document-font name
S<(e.g., C<Fi>)> in a PostScript file and the original font S<(e.g.,
C<cmss10>)> and fonts size (e.g., S<C<11> points>). It then
fabricates the PostScript comments that B<pkfix> expects to see so
that B<pkfix> can do its job.
B<pkfix-helper> works by comparing every document font against every
F<.tfm> font file it knows about (assuming that each such font has a
corresponding F<.pfb> vector version) and selecting the best matching
F<.tfm> file for every document font. B<pkfix-helper> has access only
to the widths of characters and only to those characters actually used
in the document. Also, the program recognizes only a limited set of
the most popular F<.tfm> files and scaling factors. Consequently, the
comparison is imperfect and B<pkfix-helper> may attribute an incorrect
font to a given name. Fonts comprising only one or two characters
actually used in a document are particularly problematic for
B<pkfix-helper> because many fonts may be near-enough matches to fool
the problem.
B<pkfix-helper> is designed so that a user can guide the
font-selection process by manually designating matching fonts. With a
modicum of diligence and patience a user can correct any mismatched
fonts and help the program provide proper input to B<pkfix>.
=head1 OPTIONS
B<pkfix-helper> accepts on the command line the filename of a
PostScript document to process (with the default being the standard
input device) and the filename of a modified PostScript document to
create (with the default being the standard output device). The
program also accepts the following command-line options:
=head2 Frequently Used Options
=over 4
=item B<-h>, B<--help>
Display usage information and exit. The B<--verbose> and B<--quiet>
options can be used to increase and decrease the amount of information
presented.
=item B<-v>, B<--verbose>
Increase the amount of status information that B<pkfix-helper>
displays as it runs. Additional instances of B<--verbose> on the
command line further increase the program's verbosity. By default,
only major operations are displayed. A single B<--verbose>
additionally displays information about individual font comparisons.
A second B<--verbose> additionally displays details about some of the
program's internal operations.
=item B<-f> I<name>=I<fontspec>, B<--force>=I<name>=I<fontspec>
Force B<pkfix-helper> to associate a specific font with a given font
name appearing the document. I<name> is a two-character B<dvips> font
name such as C<Fa>. I<fontspec> is a font specification such as
C<cmmi8> or S<C<cmsy10 @ 1.1X>>. An asterisk used in the name of the
base font S<(e.g., C<cmti*>)> will automatically try all integral test
font sizes from 5 to 17 points (C<cmti5>, S<C<cmti6>, ...,>
C<cmti17>). An asterisk used as a scale value S<(e.g., C<cmsy10 @
*>)> will be replaced by the scale value that gives the best match to
the original font's metrics. The B<--force> option can be specified
repeatedly on the command line.
=item B<-p> I<filename.ps>, B<--ps>=I<filename.ps>
Create a PostScript file called I<filename.ps> that shows the B<dvips>
name and a font sample of every font used by the input document.
=item B<-t> I<filename.tex>, B<--tex>=I<filename.tex>
Create a Plain TeX file called I<filename.tex> that shows the B<dvips>
name and a font sample of every font that B<pkfix-helper> used in the
output document.
=back
=head2 Infrequently Used Options
=over 4
=item B<-C> I<filename>, B<--cache>=I<filename>
Speed up TFM file processing by caching character metrics into file
I<filename>. On some systems it takes a long time to read a TFM file,
spawn F<tftopl> to convert it to PL format, and extract from the PL
data the metrics for each character. The first time B<--cache> is
specified, B<pkfix-helper> proceeds as normal then writes all of the
extracted character metrics to I<filename>. On subsequent runs in
which B<--cache>=I<filename> is specified, B<pkfix-helper> reads the
previously extracted metrics from I<filename>, going through the
F<tftopl>-based process only for TFM files that were not previously
encountered.
=item B<-q>, B<--quiet>
Instruct B<pkfix-helper> to produce no output during its run except
for fatal error messages.
=item B<-1>, B<--no-repeats>
Prevent B<pkfix-helper> from associating the same I<fontspec> with
more than one B<dvips> font name.
=item B<-i> I<fontspec>, B<--include>=I<fontspec>
Add I<fontspec> to the list of font specifications against which
B<pkfix-helper> compares I<every> document font. (In contrast,
B<--force> designates a font specification to use only for a
I<specific> document font.) The B<--include> option can be specified
repeatedly on the command line.
=item B<-x> I<regexp>, B<--exclude>=I<regexp>
Remove all font specifications matching regular expression I<regexp>
from B<pkfix-helper>'s list of known fonts. The B<--exclude> option
can be specified repeatedly on the command line.
=item B<-k> I<fontspec>, B<--keep>=I<fontspec>
Do not substitute a vector font for bitmapped font I<fontspec> (C<Fa>,
C<Fb>, etc.). This is useful when converting documents that use
obscure bitmapped fonts for which there is no vector equivalent. For
example, it was somewhat common in the past to include graphics such
as university or corporate logos into a document by converting the
bitmapped image into a single-character font and using that font in
LaTeX. B<--keep> prevents such fonts from being replaced. The
B<--keep> option can be specified repeatedly on the command line.
=item B<-a>, B<--any-scale>
Allow any value to be used to scale a font when "C<*>" is specified as
the scale factor. Normally, B<pkfix-helper> considers only integer
multiples of 0.1 that are greater than or equal to 1.0 (i.e.,
I<fontname>C<@1X>, C<@1.1X>, C<@1.2X>, C<@1.3X>, etc.).
=item B<-s>, B<--spp>
Specify the number of font samples per page to print to the files
indicated using the B<--ps> and B<--tex> options. The default
S<value, 25,> should work well in most circumstances.
=back
=head1 DIAGNOSTICS
=over 4
=item C<Best match for I<name> is rather poor>
The best font B<pkfix-helper> found for B<dvips> font name I<name> has
a mismatch value greater than or equal S<to 1.0>. (The mismatch value
is the sum of the squares of the difference between the character
widths of a document font and a potential replacement font.) Use the
B<--force> option to designate an alternative replacement font or
scaling amount.
=back
=head1 EXAMPLES
For the purpose of the following examples, assume that F<oldfile.ps>
is the name of a PostScript file produced by an old version of
B<dvips> and utilizing at least one bitmapped font. It's always worth
verifying that B<pkfix> can't convert the file on its own:
$ pkfix oldfile.ps newfile.ps
PKFIX 1.3, 2005/02/25 - Copyright (c) 2001, 2005 by Heiko Oberdiek.
==> no fonts converted
(Alternatively B<pkfix> may issue an error message such as C<!!!
Error: Parse error (@start parameters)!>.) Only when B<pkfix> can't
replace bitmapped fonts with vector fonts is B<pkfix-helper> needed.
In its simplest form, B<pkfix-helper> takes the name of an input file
(F<oldfile.ps> in this example) and the name of an output file
(F<pkfix-oldfile.ps>), which will have the same contents as the input
file but serve as suitable input for B<pkfix>:
$ pkfix-helper oldfile.ps pkfix-oldfile.ps
Reading oldfile.ps ... done.
Number of Type 3 fonts encountered: 10
Bitmapped fonts are typeset at 600 DPI.
Finding character widths ... done.
Reading TFM files ... done (103 TFMs in 193 scaling variations).
Matching fonts:
Processing Fi ... done (cmr10 @ 1X, mismatch=0.11683).
Processing Fa ... done (cmti10 @ 1X, mismatch=0.08892).
Processing Fb ... done (cmr8 @ 1X, mismatch=0.07133).
Processing Ff ... done (cmbx12 @ 1.2X, mismatch=0.02948).
Processing Fh ... done (cmtt10 @ 1X, mismatch=0.06895).
Processing Fd ... done (cmmi10 @ 1X, mismatch=0.03966).
Processing Fj ... done (cmbx12 @ 1X, mismatch=0.03972).
Processing Fe ... done (cmbx10 @ 1X, mismatch=0.00762).
Processing Fg ... done (cmsy10 @ 1X, mismatch=0.00875).
Processing Fc ... done (cmr6 @ 1X, mismatch=0.00284).
$ pkfix pkfix-oldfile.ps newfile.ps
PKFIX 1.3, 2005/02/25 - Copyright (c) 2001, 2005 by Heiko Oberdiek.
*** Font conversion: `cmti10' -> `CMTI10'.
*** Font conversion: `cmr8' -> `CMR8'.
*** Font conversion: `cmr6' -> `CMR6'.
*** Font conversion: `cmmi10' -> `CMMI10'.
*** Font conversion: `cmbx10' -> `CMBX10'.
*** Font conversion: `cmbx12' -> `CMBX12'.
*** Font conversion: `cmsy10' -> `CMSY10'.
*** Font conversion: `cmtt10' -> `CMTT10'.
*** Font conversion: `cmr10' -> `CMR10'.
*** Font conversion: `cmbx12' -> `CMBX12'.
*** Merging font `CMBX12' (2).
==> 10 converted fonts.
==> 1 merged font.
Although B<pkfix-helper> tries to automate as much as possible the
font-detection process, some fonts will invariably be incorrectly
identified. The program outputs a warning message if it I<knows> a
match is bad but the lack of a warning message does not necessarily
indicate that B<pkfix-helper> did a good job. It is therefore
strongly recommended that the user produce "before" and "after" font
sheets:
$ pkfix-helper -q oldfile.ps pkfix-oldfile.ps \
--ps=oldfonts.ps --tex=newfonts.tex
$ tex newfonts.tex
This is TeX, Version 3.14159 (Web2C 7.4.5)
(./newfonts.tex [1] )
Output written on newfonts.dvi (1 page, 1292 bytes).
Transcript written on newfonts.log.
$ dvips newfonts.dvi -o newfonts.ps
This is dvips(k) 5.92b Copyright 2002 Radical Eye Software (www.radicaleye.com)
' TeX output 2006.06.11:1636' -> newfonts.ps
<texc.pro><8r.enc><texps.pro>. <cmr6.pfb><cmsy10.pfb><cmbx10.pfb><cmbx12.pfb>
<cmmi10.pfb><cmtt10.pfb><cmr8.pfb><cmti10.pfb><cmr10.pfb>[1]
After running the preceding commands, F<oldfonts.ps> shows samples of
the fonts in F<oldfile.ps> and F<newfonts.ps> shows samples of the
replacement fonts that B<pkfix-helper> used to produce
F<pkfix-oldfile.ps>. Print F<oldfonts.ps> and F<newfonts.ps> and
compare them carefully for incorrect fonts and sizes.
Suppose that the choice of C<cmbx12 @ 1.2X> for font C<Ff> looks
wrong; say the characters look taller in F<oldfonts.ps> than in
F<newfonts.ps>. This is where the trial-and-error stage begins.
Let's hypothesize that C<cmb12> is a better match than C<cmbx12> but
we don't know how much to scale the font. Fortunately,
B<pkfix-helper> allows C<*> to be used as a scaling factor to tell the
program to automatically detect an optimal scaling factor, even if
doing so means choosing a nonstandard font size:
$ pkfix-helper oldfile.ps pkfix-oldfile.ps --force="Ff=cmb12 @ *"
Reading oldfile.ps ... done.
Number of Type 3 fonts encountered: 10
Bitmapped fonts are typeset at 600 DPI.
Finding character widths ... done.
Reading TFM files ... failed.
pkfix-helper: Unable to process user-specified TFM file "cmb12"
Oops, it looks like we don't have a F<cmb12.tfm> file on our system.
Let's try scaling up F<cmb10.tfm> instead:
$ pkfix-helper oldfile.ps pkfix-oldfile.ps --force="Ff=cmb10 @ *"
Reading oldfile.ps ... done.
Number of Type 3 fonts encountered: 10
Bitmapped fonts are typeset at 600 DPI.
Finding character widths ... done.
Reading TFM files ... done (103 TFMs in 193 scaling variations).
Matching fonts:
Processing Fi ... done (cmr10 @ 1X, mismatch=0.11683).
Processing Fa ... done (cmti10 @ 1X, mismatch=0.08892).
Processing Fb ... done (cmr8 @ 1X, mismatch=0.07133).
Processing Ff ... done (cmb10 @ 1.5X, mismatch=0.00035).
Processing Fh ... done (cmtt10 @ 1X, mismatch=0.06895).
Processing Fd ... done (cmmi10 @ 1X, mismatch=0.03966).
Processing Fj ... done (cmbx12 @ 1X, mismatch=0.03972).
Processing Fe ... done (cmbx10 @ 1X, mismatch=0.00762).
Processing Fg ... done (cmsy10 @ 1X, mismatch=0.00875).
Processing Fc ... done (cmr6 @ 1X, mismatch=0.00284).
The match has definitely improved, although S<15 pt.> is certainly an
odd size for a font. Then again, many documents I<do> use nonstandard
sizes so this may in fact be correct. The best way to verify is once
again to produce, print, and compare a pair of font samples and
iterate until all of the fonts look correct. Use one instance of
B<--force> for each font you want to alter.
=head1 ENVIRONMENT
B<pkfix-helper> honors the following environment variables:
=over 8
=item GS
The name of the Ghostscript interpreter (default: F<gs>)
=item TFTOPL
The name of a utility for converting F<.tfm> files to F<.pl> files
(default: F<tftopl>)
=back
=head1 BUGS
Even when B<pkfix-helper> finds a perfect match S<(i.e., the> correct
font in the correct size) the mismatch value is still typically
nonzero. The same error is probably what causes B<pkfix-helper>
sometimes to consider the wrong font as being a better match than the
correct font. Suggestions for fixing these bugs are welcome.
=head1 RESTRICTIONS
B<pkfix-helper> works only with PostScript files produced by B<dvips>,
not with arbitrary PostScript files. The program has not been tested
with output from versions of B<dvips> older than v5.490 S<(ca. 1992)>;
output from older versions may or may not work. Only bitmapped fonts
loaded by B<dvips> can be analyzed, not bitmapped fonts loaded by
embedded graphics.
B<pkfix-helper> works by comparing character widths, not the actual
glyphs. Consequently, it is misled by sets of fonts with similar
character widths (at least for those characters used by a given
document). As an extreme example, all Computer Modern Teletype fonts
of a given design size (e.g., C<cmtt10>, C<cmsltt10>, and C<cmitt10>)
use exactly the same widths for all characters. Human assistance is
generally needed to guide B<pkfix-helper>'s font-matching procedures.
=head1 NOTES
Files produced using the B<--tex> option are Plain TeX files and
therefore must be compiled with F<tex> (or a variation such as
F<pdftex>, F<luatex>, etc.), I<not> with F<latex>.
=head1 SEE ALSO
pkfix(1), dvips(1), tex(1), gs(1)
PostScript Language Reference, Third Edition.
Published by Addison-Wesley, ISBN 0-201-37922-8,
L<http://www.adobe.com/products/postscript/pdfs/PLRM.pdf>.
=head1 AUTHOR
Scott Pakin, I<scott+pkfh@pakin.org>
=head1 COPYRIGHT AND LICENSE
Copyright (C) 2011, Scott Pakin
This file may be distributed and/or modified under the conditions of
the LaTeX Project Public License, either version 1.3c of this license
or (at your option) any later version. The latest version of this
license is in L<http://www.latex-project.org/lppl.txt> and version
1.3c or later is part of all distributions of LaTeX version 2006/05/20
or later.
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