#!perl -w use 5.012; use strict; use warnings; require 'regen/regen_lib.pl'; # This program outputs the 256 lines that form the guts of the PL_charclass # table. The output should be used to manually replace the table contents in # l1_charclass_tab.h. Each line is a bit map of properties that the Unicode # code point at the corresponding position in the table array has. The first # line corresponds to code point U+0000, NULL, the last line to U=00FF. For # an application to see if the code point "i" has a particular property, it # just does # 'PL_charclass[i] & BIT' # The bit names are of the form '_CC_property_suffix', where 'CC' stands for # character class, and 'property' is the corresponding property, and 'suffix' # is one of '_A' to mean the property is true only if the corresponding code # point is ASCII, and '_L1' means that the range includes any Latin1 # character (ISO-8859-1 including the C0 and C1 controls). A property without # these suffixes does not have different forms for both ranges. # The data in the table is pretty well set in stone, so that this program need # be run only when adding new properties to it. my @properties = qw( ALNUMC_A ALNUMC_L1 ALPHA_A ALPHA_L1 BLANK_A BLANK_L1 CHARNAME_CONT CNTRL_A CNTRL_L1 DIGIT_A GRAPH_A GRAPH_L1 IDFIRST_A IDFIRST_L1 LOWER_A LOWER_L1 OCTAL_A PRINT_A PRINT_L1 PSXSPC_A PSXSPC_L1 PUNCT_A PUNCT_L1 SPACE_A SPACE_L1 UPPER_A UPPER_L1 WORDCHAR_A WORDCHAR_L1 XDIGIT_A ); # Read in the case fold mappings. my %folded_closure; my $file="lib/unicore/CaseFolding.txt"; open my $fh, "<", $file or die "Failed to read '$file': $!"; while (<$fh>) { chomp; # Lines look like (without the initial '#' #0130; F; 0069 0307; # LATIN CAPITAL LETTER I WITH DOT ABOVE my ($line, $comment) = split / \s+ \# \s+ /x, $_; next if $line eq "" || substr($line, 0, 1) eq '#'; my ($hex_from, $fold_type, @folded) = split /[\s;]+/, $line; my $from = hex $hex_from; # Perl only deals with C and F folds next if $fold_type ne 'C' and $fold_type ne 'F'; # Get each code point in the range that participates in this line's fold. # The hash has keys of each code point in the range, and values of what it # folds to and what folds to it foreach my $hex_fold (@folded) { my $fold = hex $hex_fold; push @{$folded_closure{$fold}}, $from if $fold < 256; push @{$folded_closure{$from}}, $fold if $from < 256; } } # Now having read all the lines, combine them into the full closure of each # code point in the range by adding lists together that share a common element foreach my $folded (keys %folded_closure) { foreach my $from (grep { $_ < 256 } @{$folded_closure{$folded}}) { push @{$folded_closure{$from}}, @{$folded_closure{$folded}}; } } my @bits; # Bit map for each code point foreach my $folded (keys %folded_closure) { $bits[$folded] = "_CC_NONLATIN1_FOLD" if grep { $_ > 255 } @{$folded_closure{$folded}}; } for my $ord (0..255) { my $char = chr($ord); utf8::upgrade($char); # Important to use Unicode semantics! for my $property (@properties) { my $name = $property; # The property name that corresponds to this doesn't have a suffix. # If is a latin1 version, no further checking is needed. if (! ($name =~ s/_L1$//)) { # Here, isn't an L1. It's either a special one or the suffix ends # in _A. In the latter case, it's automatically false for # non-ascii. The one current special is valid over the whole range. next if $name =~ s/_A$// && $ord >= 128; } my $re; if ($name eq 'PUNCT') {; # Sadly, this is inconsistent: \pP and \pS for the ascii range, # just \pP outside it. $re = qr/\p{Punct}|[^\P{Symbol}\P{ASCII}]/; } elsif ($name eq 'CHARNAME_CONT') {; $re = qr/[-\w ():\xa0]/; } elsif ($name eq 'SPACE') {; $re = qr/\s/; } elsif ($name eq 'IDFIRST') { $re = qr/[_\p{Alpha}]/; } elsif ($name eq 'PSXSPC') { $re = qr/[\v\p{Space}]/; } elsif ($name eq 'WORDCHAR') { $re = qr/\w/; } elsif ($name eq 'ALNUMC') { # Like \w, but no underscore $re = qr/\p{Alnum}/; } elsif ($name eq 'OCTAL') { $re = qr/[0-7]/; } else { # The remainder have the same name and values as Unicode $re = eval "qr/\\p{$name}/"; use Carp; carp $@ if ! defined $re; } #print "$ord, $name $property, $re\n"; if ($char =~ $re) { # Add this property if matches $bits[$ord] .= '|' if $bits[$ord]; $bits[$ord] .= "_CC_$property"; } } #print __LINE__, " $ord $char $bits[$ord]\n"; } # Names of C0 controls my @C0 = qw ( NUL SOH STX ETX EOT ENQ ACK BEL BS HT LF VT FF CR SO SI DLE DC1 DC2 DC3 DC4 NAK SYN ETB CAN EOM SUB ESC FS GS RS US ); # Names of C1 controls, plus the adjacent DEL my @C1 = qw( DEL PAD HOP BPH NBH IND NEL SSA ESA HTS HTJ VTS PLD PLU RI SS2 SS3 DCS PU1 PU2 STS CCH MW SPA EPA SOS SGC SCI CSI ST OSC PM APC ); my $out_fh = open_new('l1_char_class_tab.h', '>', {style => '*', by => $0, from => $file}); # Output the table using fairly short names for each char. for my $ord (0..255) { my $name; if ($ord < 32) { # A C0 control $name = $C0[$ord]; } elsif ($ord > 32 && $ord < 127) { # Graphic $name = "'" . chr($ord) . "'"; } elsif ($ord >= 127 && $ord <= 0x9f) { $name = $C1[$ord - 127]; # A C1 control + DEL } else { # SPACE, or, if Latin1, shorten the name */ use charnames(); $name = charnames::viacode($ord); $name =~ s/LATIN CAPITAL LETTER // || $name =~ s/LATIN SMALL LETTER (.*)/\L$1/; } printf $out_fh "/* U+%02X %s */ %s,\n", $ord, $name, $bits[$ord]; } read_only_bottom_close_and_rename($out_fh)