#!perl -w use 5.015; use strict; use warnings; use Unicode::UCD qw(prop_invlist prop_invmap); require 'regen/regen_lib.pl'; require 'regen/charset_translations.pl'; # This program outputs charclass_invlists.h, which contains various inversion # lists in the form of C arrays that are to be used as-is for inversion lists. # Thus, the lists it contains are essentially pre-compiled, and need only a # light-weight fast wrapper to make them usable at run-time. # As such, this code knows about the internal structure of these lists, and # any change made to that has to be done here as well. A random number stored # in the headers is used to minimize the possibility of things getting # out-of-sync, or the wrong data structure being passed. Currently that # random number is: my $VERSION_DATA_STRUCTURE_TYPE = 148565664; my $out_fh = open_new('charclass_invlists.h', '>', {style => '*', by => $0, from => "Unicode::UCD"}); my $is_in_ifndef_ext_re = 0; print $out_fh "/* See the generating file for comments */\n\n"; my %include_in_ext_re = ( NonL1_Perl_Non_Final_Folds => 1 ); sub end_ifndef_ext_re { if ($is_in_ifndef_ext_re) { print $out_fh "\n#endif\t/* #ifndef PERL_IN_XSUB_RE */\n"; $is_in_ifndef_ext_re = 0; } } sub output_invlist ($$;$) { my $name = shift; my $invlist = shift; # Reference to inversion list array my $charset = shift // ""; # name of character set for comment die "No inversion list for $name" unless defined $invlist && ref $invlist eq 'ARRAY' && @$invlist; # Output the inversion list $invlist using the name $name for it. # It is output in the exact internal form for inversion lists. # Is the last element of the header 0, or 1 ? my $zero_or_one = 0; if ($invlist->[0] != 0) { unshift @$invlist, 0; $zero_or_one = 1; } my $count = @$invlist; if ($is_in_ifndef_ext_re) { if (exists $include_in_ext_re{$name}) { end_ifndef_ext_re; } } elsif (! exists $include_in_ext_re{$name}) { print $out_fh "\n#ifndef PERL_IN_XSUB_RE\n" unless exists $include_in_ext_re{$name}; $is_in_ifndef_ext_re = 1; } print $out_fh "\nstatic const UV ${name}_invlist[] = {"; print $out_fh " /* for $charset */" if $charset; print $out_fh "\n"; print $out_fh "\t$count,\t/* Number of elements */\n"; print $out_fh "\t$VERSION_DATA_STRUCTURE_TYPE, /* Version and data structure type */\n"; print $out_fh "\t", $zero_or_one, ",\t/* 0 if the list starts at 0;", "\n\t\t 1 if it starts at the element beyond 0 */\n"; # The main body are the UVs passed in to this routine. Do the final # element separately for my $i (0 .. @$invlist - 1 - 1) { print $out_fh "\t$invlist->[$i],\n"; } # The final element does not have a trailing comma, as C can't handle it. print $out_fh "\t$invlist->[-1]\n"; print $out_fh "};\n"; } sub mk_invlist_from_cp_list { # Returns an inversion list constructed from the sorted input array of # code points my $list_ref = shift; # Initialize to just the first element my @invlist = ( $list_ref->[0], $list_ref->[0] + 1); # For each succeeding element, if it extends the previous range, adjust # up, otherwise add it. for my $i (1 .. @$list_ref - 1) { if ($invlist[-1] == $list_ref->[$i]) { $invlist[-1]++; } else { push @invlist, $list_ref->[$i], $list_ref->[$i] + 1; } } return @invlist; } # Read in the Case Folding rules, and construct arrays of code points for the # properties we need. my ($cp_ref, $folds_ref, $format) = prop_invmap("Case_Folding"); die "Could not find inversion map for Case_Folding" unless defined $format; die "Incorrect format '$format' for Case_Folding inversion map" unless $format eq 'al'; my @has_multi_char_fold; my @is_non_final_fold; for my $i (0 .. @$folds_ref - 1) { next unless ref $folds_ref->[$i]; # Skip single-char folds push @has_multi_char_fold, $cp_ref->[$i]; # Add to the non-finals list each code point that is in a non-final # position for my $j (0 .. @{$folds_ref->[$i]} - 2) { push @is_non_final_fold, $folds_ref->[$i][$j] unless grep { $folds_ref->[$i][$j] == $_ } @is_non_final_fold; } } sub _Perl_Non_Final_Folds { @is_non_final_fold = sort { $a <=> $b } @is_non_final_fold; return mk_invlist_from_cp_list(\@is_non_final_fold); } sub UpperLatin1 { return mk_invlist_from_cp_list([ 128 .. 255 ]); } output_invlist("Latin1", [ 0, 256 ]); output_invlist("AboveLatin1", [ 256 ]); end_ifndef_ext_re; # We construct lists for all the POSIX and backslash sequence character # classes in two forms: # 1) ones which match only in the ASCII range # 2) ones which match either in the Latin1 range, or the entire Unicode range # # These get compiled in, and hence affect the memory footprint of every Perl # program, even those not using Unicode. To minimize the size, currently # the Latin1 version is generated for the beyond ASCII range except for those # lists that are quite small for the entire range, such as for \s, which is 22 # UVs long plus 4 UVs (currently) for the header. # # To save even more memory, the ASCII versions could be derived from the # larger ones at runtime, saving some memory (minus the expense of the machine # instructions to do so), but these are all small anyway, so their total is # about 100 UVs. # # In the list of properties below that get generated, the L1 prefix is a fake # property that means just the Latin1 range of the full property (whose name # has an X prefix instead of L1). # # An initial & means to use the subroutine from this file instead of an # official inversion list. for my $charset (get_supported_code_pages()) { print $out_fh "\n" . get_conditional_compile_line_start($charset); my @a2n = @{get_a2n($charset)}; for my $prop (qw( ASCII Cased VertSpace XPerlSpace XPosixAlnum XPosixAlpha XPosixBlank XPosixCntrl XPosixDigit XPosixGraph XPosixLower XPosixPrint XPosixPunct XPosixSpace XPosixUpper XPosixWord XPosixXDigit _Perl_Any_Folds &NonL1_Perl_Non_Final_Folds _Perl_Folds_To_Multi_Char &UpperLatin1 _Perl_IDStart _Perl_IDCont ) ) { # For the Latin1 properties, we change to use the eXtended version of the # base property, then go through the result and get rid of everything not # in Latin1 (above 255). Actually, we retain the element for the range # that crosses the 255/256 boundary if it is one that matches the # property. For example, in the Word property, there is a range of code # points that start at U+00F8 and goes through U+02C1. Instead of # artificially cutting that off at 256 because 256 is the first code point # above Latin1, we let the range go to its natural ending. That gives us # extra information with no added space taken. But if the range that # crosses the boundary is one that doesn't match the property, we don't # start a new range above 255, as that could be construed as going to # infinity. For example, the Upper property doesn't include the character # at 255, but does include the one at 256. We don't include the 256 one. my $prop_name = $prop; my $is_local_sub = $prop_name =~ s/^&//; my $lookup_prop = $prop_name; my $l1_only = ($lookup_prop =~ s/^L1Posix/XPosix/ or $lookup_prop =~ s/^L1//); my $nonl1_only = 0; $nonl1_only = $lookup_prop =~ s/^NonL1// unless $l1_only; my @invlist; if ($is_local_sub) { @invlist = eval $lookup_prop; } else { @invlist = prop_invlist($lookup_prop, '_perl_core_internal_ok'); } die "Could not find inversion list for '$lookup_prop'" unless @invlist; my @full_list; for (my $i = 0; $i < @invlist; $i += 2) { my $upper = ($i + 1) < @invlist ? $invlist[$i+1] - 1 # In range : $Unicode::UCD::MAX_CP; # To infinity. You may want # to stop much much earlier; # going this high may expose # perl deficiencies with very # large numbers. for my $j ($invlist[$i] .. $upper) { if ($j < 256) { push @full_list, $a2n[$j]; } else { push @full_list, $j; } } } @full_list = sort { $a <=> $b } @full_list; @invlist = mk_invlist_from_cp_list(\@full_list); if ($l1_only) { for my $i (0 .. @invlist - 1 - 1) { if ($invlist[$i] > 255) { # In an inversion list, even-numbered elements give the code # points that begin ranges that match the property; # odd-numbered give ones that begin ranges that don't match. # If $i is odd, we are at the first code point above 255 that # doesn't match, which means the range it is ending does # match, and crosses the 255/256 boundary. We want to include # this ending point, so increment $i, so the splice below # includes it. Conversely, if $i is even, it is the first # code point above 255 that matches, which means there was no # matching range that crossed the boundary, and we don't want # to include this code point, so splice before it. $i++ if $i % 2 != 0; # Remove everything past this. splice @invlist, $i; last; } } } elsif ($nonl1_only) { my $found_nonl1 = 0; for my $i (0 .. @invlist - 1 - 1) { next if $invlist[$i] < 256; # Here, we have the first element in the array that indicates an # element above Latin1. Get rid of all previous ones. splice @invlist, 0, $i; # If this one's index is not divisible by 2, it means that this # element is inverting away from being in the list, which means # all code points from 256 to this one are in this list. unshift @invlist, 256 if $i % 2 != 0; $found_nonl1 = 1; last; } die "No non-Latin1 code points in $lookup_prop" unless $found_nonl1; } output_invlist($prop_name, \@invlist, $charset); } end_ifndef_ext_re; print $out_fh "\n" . get_conditional_compile_line_end(); } read_only_bottom_close_and_rename($out_fh)