#!perl -w use v5.15.8; use strict; use warnings; require './regen/regen_lib.pl'; require './regen/charset_translations.pl'; use Unicode::UCD 'prop_invlist'; # This program outputs l1_charclass_tab.h, which defines the guts of the # PL_charclass table. 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 0x0, NULL, the last line to 0xFF. 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. # This program need be run only when adding new properties to it, or upon a # new Unicode release, to make sure things haven't been changed by it. # keys are the names of the bits; values are what generates the code points # that have the bit set, or 0 if \p{key} is the generator my %bit_names = ( NONLATIN1_SIMPLE_FOLD => \&Non_Latin1_Simple_Folds, NONLATIN1_FOLD => \&Non_Latin1_Folds, ALPHANUMERIC => 'Alnum', # Like \w, but no underscore ALPHA => 'XPosixAlpha', ASCII => 0, BLANK => 0, CASED => 0, CHARNAME_CONT => '_Perl_Charname_Continue', CNTRL => 0, DIGIT => 0, GRAPH => 0, IDFIRST => \&Id_First, LOWER => 'XPosixLower', NON_FINAL_FOLD => \&Non_Final_Folds, PRINT => 0, PUNCT => \&Punct_and_Symbols, QUOTEMETA => '_Perl_Quotemeta', SPACE => 'XPerlSpace', UPPER => 'XPosixUpper', WORDCHAR => 'XPosixWord', XDIGIT => 0, VERTSPACE => 0, IS_IN_SOME_FOLD => '_Perl_Any_Folds', BINDIGIT => [ ord '0', ord '1' ], OCTDIGIT => [ ord '0', ord '1', ord '2', ord '3', ord '4', ord '5', ord '6', ord '7' ], # These are the control characters that there are mnemonics for MNEMONIC_CNTRL => [ ord "\a", ord "\b", ord "\e", ord "\f", ord "\n", ord "\r", ord "\t" ], ); sub uniques { # Returns non-duplicated input values. From "Perl Best Practices: # Encapsulated Cleverness". p. 455 in first edition. my %seen; return grep { ! $seen{$_}++ } @_; } sub expand_invlist { # Return the code points that are in the inversion list given by the # argument my $invlist_ref = shift; my $i; my @full_list; for (my $i = 0; $i < @$invlist_ref; $i += 2) { my $upper = ($i + 1) < @$invlist_ref ? $invlist_ref->[$i+1] - 1 # In range : $Unicode::UCD::MAX_CP; # To infinity. for my $j ($invlist_ref->[$i] .. $upper) { push @full_list, $j; } } return @full_list; } # Read in the case fold mappings. my %folded_closure; my %simple_folded_closure; my @non_final_folds; my @non_latin1_simple_folds; my @folds; use Unicode::UCD; # Use the Unicode data file if we are on an ASCII platform (which its data # is for), and it is in the modern format (starting in Unicode 3.1.0) and # it is available. This avoids being affected by potential bugs # introduced by other layers of Perl my $file="lib/unicore/CaseFolding.txt"; if (ord('A') == 65 && pack("C*", split /\./, Unicode::UCD::UnicodeVersion()) ge v3.1.0 && open my $fh, "<", $file) { @folds = <$fh>; } else { my ($invlist_ref, $invmap_ref, undef, $default) = Unicode::UCD::prop_invmap('Case_Folding'); for my $i (0 .. @$invlist_ref - 1 - 1) { next if $invmap_ref->[$i] == $default; my $adjust = -1; for my $j ($invlist_ref->[$i] .. $invlist_ref->[$i+1] -1) { $adjust++; # Single-code point maps go to a 'C' type if (! ref $invmap_ref->[$i]) { push @folds, sprintf("%04X; C; %04X\n", $j, $invmap_ref->[$i] + $adjust); } else { # Multi-code point maps go to 'F'. prop_invmap() # guarantees that no adjustment is needed for these, # as the range will contain just one element push @folds, sprintf("%04X; F; %s\n", $j, join " ", map { sprintf "%04X", $_ } @{$invmap_ref->[$i]}); } } } } for (@folds) { chomp; # Lines look like (without the initial '#' #0130; F; 0069 0307; # LATIN CAPITAL LETTER I WITH DOT ABOVE # Get rid of comments, ignore blank or comment-only lines my $line = $_ =~ s/ (?: \s* \# .* )? $ //rx; next unless length $line; my ($hex_from, $fold_type, @folded) = split /[\s;]+/, $line; my $from = hex $hex_from; # Perl only deals with S, C, and F folds next if $fold_type ne 'C' and $fold_type ne 'F' and $fold_type ne 'S'; # 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 for my $i (0 .. @folded - 1) { my $fold = hex $folded[$i]; if ($fold < 256) { push @{$folded_closure{$fold}}, $from; push @{$simple_folded_closure{$fold}}, $from if $fold_type ne 'F'; } if ($from < 256) { push @{$folded_closure{$from}}, $fold; push @{$simple_folded_closure{$from}}, $fold if $fold_type ne 'F'; } if (($fold_type eq 'C' || $fold_type eq 'S') && ($fold < 256 != $from < 256)) { # Fold is simple (hence can't be a non-final fold, so the 'if' # above is mutualy exclusive from the 'if below) and crosses # 255/256 boundary. We keep track of the Latin1 code points # in such folds. push @non_latin1_simple_folds, ($fold < 256) ? $fold : $from; } elsif ($i < @folded-1 && $fold < 256 && ! grep { $_ == $fold } @non_final_folds) { push @non_final_folds, $fold; # Also add the upper case, which in the latin1 range folds to # $fold push @non_final_folds, ord uc chr $fold; } } } # 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}}; } } foreach my $folded (keys %simple_folded_closure) { foreach my $from (grep { $_ < 256 } @{$simple_folded_closure{$folded}}) { push @{$simple_folded_closure{$from}}, @{$simple_folded_closure{$folded}}; } } # We have the single-character folds that cross the 255/256, like KELVIN # SIGN => 'k', but we need the closure, so add like 'K' to it foreach my $folded (@non_latin1_simple_folds) { foreach my $fold (@{$simple_folded_closure{$folded}}) { if ($fold < 256 && ! grep { $fold == $_ } @non_latin1_simple_folds) { push @non_latin1_simple_folds, $fold; } } } sub Id_First { my @alpha_invlist = prop_invlist("XPosixAlpha"); my @ids = expand_invlist(\@alpha_invlist); push @ids, ord "_"; return sort { $a <=> $b } uniques @ids; } sub Non_Latin1_Folds { my @return; foreach my $folded (keys %folded_closure) { push @return, $folded if grep { $_ > 255 } @{$folded_closure{$folded}}; } return @return; } sub Non_Latin1_Simple_Folds { # Latin1 code points that are folded to by # non-Latin1 code points as single character # folds return @non_latin1_simple_folds; } sub Non_Final_Folds { return @non_final_folds; } sub Punct_and_Symbols { # Sadly, this is inconsistent: \pP and \pS for the ascii range; # just \pP outside it. my @punct_invlist = prop_invlist("Punct"); my @return = expand_invlist(\@punct_invlist); my @symbols_invlist = prop_invlist("Symbol"); my @symbols = expand_invlist(\@symbols_invlist); foreach my $cp (@symbols) { last if $cp > 0x7f; push @return, $cp; } return sort { $a <=> $b } uniques @return; } my @bits; # Each element is a bit map for a single code point # For each bit type, calculate which code points should have it set foreach my $bit_name (sort keys %bit_names) { my @code_points; my $property = $bit_name; # The bit name is the same as its property, # unless overridden $property = $bit_names{$bit_name} if $bit_names{$bit_name}; if (! ref $property) { my @invlist = prop_invlist($property, '_perl_core_internal_ok'); @code_points = expand_invlist(\@invlist); } elsif (ref $property eq 'CODE') { @code_points = &$property; } elsif (ref $property eq 'ARRAY') { @code_points = @{$property}; } foreach my $cp (@code_points) { last if $cp > 0xFF; $bits[$cp] .= '|' if $bits[$cp]; $bits[$cp] .= "(1U<', {style => '*', by => $0, from => "Unicode::UCD"}); print $out_fh <[$i]] = $i; } } print $out_fh "\n" . get_conditional_compile_line_start($charset); for my $ord (0..255) { my $name; my $char = chr $ord; if ($char =~ /\p{PosixGraph}/) { my $quote = $char eq "'" ? '"' : "'"; $name = $quote . chr($ord) . $quote; } elsif ($char =~ /\p{XPosixGraph}/) { use charnames(); $name = charnames::viacode($ord); $name =~ s/LATIN CAPITAL LETTER // or $name =~ s/LATIN SMALL LETTER (.*)/\L$1/ or $name =~ s/ SIGN\b// or $name =~ s/EXCLAMATION MARK/'!'/ or $name =~ s/QUESTION MARK/'?'/ or $name =~ s/QUOTATION MARK/QUOTE/ or $name =~ s/ INDICATOR//; $name =~ s/\bWITH\b/\L$&/; $name =~ s/\bONE\b/1/; $name =~ s/\b(TWO|HALF)\b/2/; $name =~ s/\bTHREE\b/3/; $name =~ s/\b QUARTER S? \b/4/x; $name =~ s/VULGAR FRACTION (.) (.)/$1\/$2/; $name =~ s/\bTILDE\b/'~'/i or $name =~ s/\bCIRCUMFLEX\b/'^'/i or $name =~ s/\bSTROKE\b/'\/'/i or $name =~ s/ ABOVE\b//i; } else { use Unicode::UCD qw(prop_invmap); my ($list_ref, $map_ref, $format) = prop_invmap("_Perl_Name_Alias", '_perl_core_internal_ok'); if ($format !~ /^s/) { use Carp; carp "Unexpected format '$format' for '_Perl_Name_Alias"; last; } my $which = Unicode::UCD::search_invlist($list_ref, $ord); if (! defined $which) { use Carp; carp "No name found for code pont $ord"; } else { my $map = $map_ref->[$which]; if (! ref $map) { $name = $map; } else { # Just pick the first abbreviation if more than one my @names = grep { $_ =~ /abbreviation/ } @$map; $name = $names[0]; } $name =~ s/:.*//; } } my $index = $a2n[$ord]; my $i8; $i8 = $utf_to_i8[$index] if @utf_to_i8; $out[$index] = "/* "; $out[$index] .= sprintf "0x%02X ", $index if $ord != $index; $out[$index] .= sprintf "U+%02X ", $ord; $out[$index] .= sprintf "I8=%02X ", $i8 if defined $i8 && $i8 != $ord; $out[$index] .= "$name */ "; $out[$index] .= $bits[$ord]; $out[$index] .= ",\n"; } $out[-1] =~ s/,$//; # No trailing comma in the final entry print $out_fh join "", @out; print $out_fh "\n" . get_conditional_compile_line_end(); } read_only_bottom_close_and_rename($out_fh)