#!perl package CharClass::Matcher; use strict; use 5.008; use warnings; use warnings FATAL => 'all'; use Data::Dumper; $Data::Dumper::Useqq= 1; our $hex_fmt= "0x%02X"; sub DEBUG () { 0 } $|=1 if DEBUG; require './regen/regen_lib.pl'; require './regen/charset_translations.pl'; require "./regen/regcharclass_multi_char_folds.pl"; =head1 NAME CharClass::Matcher -- Generate C macros that match character classes efficiently =head1 SYNOPSIS perl Porting/regcharclass.pl =head1 DESCRIPTION Dynamically generates macros for detecting special charclasses in latin-1, utf8, and codepoint forms. Macros can be set to return the length (in bytes) of the matched codepoint, and/or the codepoint itself. To regenerate F, run this script from perl-root. No arguments are necessary. Using WHATEVER as an example the following macros can be produced, depending on the input parameters (how to get each is described by internal comments at the C<__DATA__> line): =over 4 =item C =item C Do a lookup as appropriate based on the C flag. When possible comparisons involving octet<128 are done before checking the C flag, hopefully saving time. The version without the C<_safe> suffix should be used only when the input is known to be well-formed. =item C =item C Do a lookup assuming the string is encoded in (normalized) UTF8. The version without the C<_safe> suffix should be used only when the input is known to be well-formed. =item C =item C Do a lookup assuming the string is encoded in latin-1 (aka plan octets). The version without the C<_safe> suffix should be used only when it is known that C contains at least one character. =item C Check to see if the string matches a given codepoint (hypothetically a U32). The condition is constructed as to "break out" as early as possible if the codepoint is out of range of the condition. IOW: (cp==X || (cp>X && (cp==Y || (cp>Y && ...)))) Thus if the character is X+1 only two comparisons will be done. Making matching lookups slower, but non-matching faster. =item C A variant form of each of the macro types described above can be generated, in which the code point is returned by the macro, and an extra parameter (in the final position) is added, which is a pointer for the macro to set the byte length of the returned code point. These forms all have a C prefix instead of the C, for example C and C. These forms should not be used I on small sets of mostly widely separated code points; otherwise the code generated is inefficient. For these cases, it is best to use the C forms, and then find the code point with C(). This program can fail with a "deep recursion" message on the worst of the inappropriate sets. Examine the generated macro to see if it is acceptable. =item C A variant form of each of the C macro types described above can be generated, in which the code point and not the length is returned by the macro. These have the same caveat as L, plus they should not be used where the set contains a NULL, as 0 is returned for two different cases: a) the set doesn't include the input code point; b) the set does include it, and it is a NULL. =back The above isn't quite complete, as for specialized purposes one can get a macro like C, which assumes that it is already known that there is enough space to hold the character starting at C, but otherwise checks that it is well-formed. In other words, this is intermediary in checking between C and C. =head2 CODE FORMAT perltidy -st -bt=1 -bbt=0 -pt=0 -sbt=1 -ce -nwls== "%f" =head1 AUTHOR Author: Yves Orton (demerphq) 2007. Maintained by Perl5 Porters. =head1 BUGS No tests directly here (although the regex engine will fail tests if this code is broken). Insufficient documentation and no Getopts handler for using the module as a script. =head1 LICENSE You may distribute under the terms of either the GNU General Public License or the Artistic License, as specified in the README file. =cut # Sub naming convention: # __func : private subroutine, can not be called as a method # _func : private method, not meant for external use # func : public method. # private subs #------------------------------------------------------------------------------- # # ($cp,$n,$l,$u)=__uni_latin($str); # # Return a list of arrays, each of which when interpreted correctly # represent the string in some given encoding with specific conditions. # # $cp - list of codepoints that make up the string. # $n - list of octets that make up the string if all codepoints are invariant # regardless of if the string is in UTF-8 or not. # $l - list of octets that make up the string in latin1 encoding if all # codepoints < 256, and at least one codepoint is UTF-8 variant. # $u - list of octets that make up the string in utf8 if any codepoint is # UTF-8 variant # # High CP | Defined #-----------+---------- # 0 - 127 : $n (127/128 are the values for ASCII platforms) # 128 - 255 : $l, $u # 256 - ... : $u # sub __uni_latin1 { my $charset= shift; my $str= shift; my $max= 0; my @cp; my @cp_high; my $only_has_invariants = 1; my $a2n = get_a2n($charset); for my $ch ( split //, $str ) { my $cp= ord $ch; $max= $cp if $max < $cp; if ($cp > 255) { push @cp, $cp; push @cp_high, $cp; } else { push @cp, $a2n->[$cp]; } } my ( $n, $l, $u ); $only_has_invariants = ($charset =~ /ascii/i) ? $max < 128 : $max < 160; if ($only_has_invariants) { $n= [@cp]; } else { $l= [@cp] if $max && $max < 256; my @u; for my $ch ( split //, $str ) { push @u, map { ord } split //, cp_2_utfbytes(ord $ch, $charset); } $u = \@u; } return ( \@cp, \@cp_high, $n, $l, $u ); } # # $clean= __clean($expr); # # Cleanup a ternary expression, removing unnecessary parens and apply some # simplifications using regexes. # sub __clean { my ( $expr )= @_; #return $expr; our $parens; $parens= qr/ (?> \( (?> (?: (?> [^()]+ ) | (??{ $parens }) )* ) \) ) /x; ## remove redundant parens 1 while $expr =~ s/ \( \s* ( $parens ) \s* \) /$1/gx; # repeatedly simplify conditions like # ( (cond1) ? ( (cond2) ? X : Y ) : Y ) # into # ( ( (cond1) && (cond2) ) ? X : Y ) # Also similarly handles expressions like: # : (cond1) ? ( (cond2) ? X : Y ) : Y ) # Note the inclusion of the close paren in ([:()]) and the open paren in ([()]) is # purely to ensure we have a balanced set of parens in the expression which makes # it easier to understand the pattern in an editor that understands paren's, we do # not expect either of these cases to actually fire. - Yves 1 while $expr =~ s/ ([:()]) \s* ($parens) \s* \? \s* \( \s* ($parens) \s* \? \s* ($parens|[^()?:\s]+?) \s* : \s* ($parens|[^()?:\s]+?) \s* \) \s* : \s* \5 \s* ([()]) /$1 ( $2 && $3 ) ? $4 : $5 $6/gx; #$expr=~s/\(\(U8\*\)s\)\[(\d+)\]/S$1/g if length $expr > 8000; #$expr=~s/\s+//g if length $expr > 8000; die "Expression too long" if length $expr > 8000; return $expr; } # # $text= __macro(@args); # Join args together by newlines, and then neatly add backslashes to the end # of every line as expected by the C pre-processor for #define's. # sub __macro { my $str= join "\n", @_; $str =~ s/\s*$//; my @lines= map { s/\s+$//; s/\t/ /g; $_ } split /\n/, $str; my $last= pop @lines; $str= join "\n", ( map { sprintf "%-76s\\", $_ } @lines ), $last; 1 while $str =~ s/^(\t*) {8}/$1\t/gm; return $str . "\n"; } # # my $op=__incrdepth($op); # # take an 'op' hashref and add one to it and all its childrens depths. # sub __incrdepth { my $op= shift; return unless ref $op; $op->{depth} += 1; __incrdepth( $op->{yes} ); __incrdepth( $op->{no} ); return $op; } # join two branches of an opcode together with a condition, incrementing # the depth on the yes branch when we do so. # returns the new root opcode of the tree. sub __cond_join { my ( $cond, $yes, $no )= @_; if (ref $yes) { return { test => $cond, yes => __incrdepth( $yes ), no => $no, depth => 0, }; } else { return { test => $cond, yes => $yes, no => __incrdepth($no), depth => 0, }; } } # Methods # constructor # # my $obj=CLASS->new(op=>'SOMENAME',title=>'blah',txt=>[..]); # # Create a new CharClass::Matcher object by parsing the text in # the txt array. Currently applies the following rules: # # Element starts with C<0x>, line is evaled the result treated as # a number which is passed to chr(). # # Element starts with C<">, line is evaled and the result treated # as a string. # # Each string is then stored in the 'strs' subhash as a hash record # made up of the results of __uni_latin1, using the keynames # 'low','latin1','utf8', as well as the synthesized 'LATIN1', 'high', and # 'UTF8' which hold a merge of 'low' and their lowercase equivalents. # # Size data is tracked per type in the 'size' subhash. # # Return an object # sub new { my $class= shift; my %opt= @_; for ( qw(op txt) ) { die "in " . __PACKAGE__ . " constructor '$_;' is a mandatory field" if !exists $opt{$_}; } my $self= bless { op => $opt{op}, title => $opt{title} || '', }, $class; foreach my $txt ( @{ $opt{txt} } ) { my $str= $txt; if ( $str =~ /^[""]/ ) { $str= eval $str; } elsif ($str =~ / - /x ) { # A range: Replace this element on the # list with its expansion my ($lower, $upper) = $str =~ / 0x (.+?) \s* - \s* 0x (.+) /x; die "Format must be like '0xDEAD - 0xBEAF'; instead was '$str'" if ! defined $lower || ! defined $upper; foreach my $cp (hex $lower .. hex $upper) { push @{$opt{txt}}, sprintf "0x%X", $cp; } next; } elsif ($str =~ s/ ^ N (?= 0x ) //x ) { # Otherwise undocumented, a leading N means is already in the # native character set; don't convert. $str= chr eval $str; } elsif ( $str =~ /^0x/ ) { $str= eval $str; $str = chr $str; } elsif ( $str =~ / \s* \\p \{ ( .*? ) \} /x) { my $property = $1; use Unicode::UCD qw(prop_invlist); my @invlist = prop_invlist($property, '_perl_core_internal_ok'); if (! @invlist) { # An empty return could mean an unknown property, or merely # that it is empty. Call in scalar context to differentiate my $count = prop_invlist($property, '_perl_core_internal_ok'); die "$property not found" unless defined $count; } # Replace this element on the list with the property's expansion for (my $i = 0; $i < @invlist; $i += 2) { foreach my $cp ($invlist[$i] .. $invlist[$i+1] - 1) { # prop_invlist() returns native values; add leading 'N' # to indicate that. push @{$opt{txt}}, sprintf "N0x%X", $cp; } } next; } elsif ($str =~ / ^ do \s+ ( .* ) /x) { die "do '$1' failed: $!$@" if ! do $1 or $@; next; } elsif ($str =~ / ^ & \s* ( .* ) /x) { # user-furnished sub() call my @results = eval "$1"; die "eval '$1' failed: $@" if $@; push @{$opt{txt}}, @results; next; } else { die "Unparsable line: $txt\n"; } my ( $cp, $cp_high, $low, $latin1, $utf8 )= __uni_latin1( $opt{charset}, $str ); my $UTF8= $low || $utf8; my $LATIN1= $low || $latin1; my $high = (scalar grep { $_ < 256 } @$cp) ? 0 : $utf8; #die Dumper($txt,$cp,$low,$latin1,$utf8) # if $txt=~/NEL/ or $utf8 and @$utf8>3; @{ $self->{strs}{$str} }{qw( str txt low utf8 latin1 high cp cp_high UTF8 LATIN1 )}= ( $str, $txt, $low, $utf8, $latin1, $high, $cp, $cp_high, $UTF8, $LATIN1 ); my $rec= $self->{strs}{$str}; foreach my $key ( qw(low utf8 latin1 high cp cp_high UTF8 LATIN1) ) { $self->{size}{$key}{ 0 + @{ $self->{strs}{$str}{$key} } }++ if $self->{strs}{$str}{$key}; } $self->{has_multi} ||= @$cp > 1; $self->{has_ascii} ||= $latin1 && @$latin1; $self->{has_low} ||= $low && @$low; $self->{has_high} ||= !$low && !$latin1; } $self->{val_fmt}= $hex_fmt; $self->{count}= 0 + keys %{ $self->{strs} }; return $self; } # my $trie = make_trie($type,$maxlen); # # using the data stored in the object build a trie of a specific type, # and with specific maximum depth. The trie is made up the elements of # the given types array for each string in the object (assuming it is # not too long.) # # returns the trie, or undef if there was no relevant data in the object. # sub make_trie { my ( $self, $type, $maxlen )= @_; my $strs= $self->{strs}; my %trie; foreach my $rec ( values %$strs ) { die "panic: unknown type '$type'" if !exists $rec->{$type}; my $dat= $rec->{$type}; next unless $dat; next if $maxlen && @$dat > $maxlen; my $node= \%trie; foreach my $elem ( @$dat ) { $node->{$elem} ||= {}; $node= $node->{$elem}; } $node->{''}= $rec->{str}; } return 0 + keys( %trie ) ? \%trie : undef; } sub pop_count ($) { my $word = shift; # This returns a list of the positions of the bits in the input word that # are 1. my @positions; my $position = 0; while ($word) { push @positions, $position if $word & 1; $position++; $word >>= 1; } return @positions; } # my $optree= _optree() # # recursively convert a trie to an optree where every node represents # an if else branch. # # sub _optree { my ( $self, $trie, $test_type, $ret_type, $else, $depth )= @_; return unless defined $trie; if ( $self->{has_multi} and $ret_type =~ /cp|both/ ) { die "Can't do 'cp' optree from multi-codepoint strings"; } $ret_type ||= 'len'; $else= 0 unless defined $else; $depth= 0 unless defined $depth; # if we have an empty string as a key it means we are in an # accepting state and unless we can match further on should # return the value of the '' key. if (exists $trie->{''} ) { # we can now update the "else" value, anything failing to match # after this point should return the value from this. if ( $ret_type eq 'cp' ) { $else= $self->{strs}{ $trie->{''} }{cp}[0]; $else= sprintf "$self->{val_fmt}", $else if $else > 9; } elsif ( $ret_type eq 'len' ) { $else= $depth; } elsif ( $ret_type eq 'both') { $else= $self->{strs}{ $trie->{''} }{cp}[0]; $else= sprintf "$self->{val_fmt}", $else if $else > 9; $else= "len=$depth, $else"; } } # extract the meaningful keys from the trie, filter out '' as # it means we are an accepting state (end of sequence). my @conds= sort { $a <=> $b } grep { length $_ } keys %$trie; # if we haven't any keys there is no further we can match and we # can return the "else" value. return $else if !@conds; my $test = $test_type =~ /^cp/ ? "cp" : "((const U8*)s)[$depth]"; # First we loop over the possible keys/conditions and find out what they # look like; we group conditions with the same optree together. my %dmp_res; my @res_order; local $Data::Dumper::Sortkeys=1; foreach my $cond ( @conds ) { # get the optree for this child/condition my $res= $self->_optree( $trie->{$cond}, $test_type, $ret_type, $else, $depth + 1 ); # convert it to a string with Dumper my $res_code= Dumper( $res ); push @{$dmp_res{$res_code}{vals}}, $cond; if (!$dmp_res{$res_code}{optree}) { $dmp_res{$res_code}{optree}= $res; push @res_order, $res_code; } } # now that we have deduped the optrees we construct a new optree containing the merged # results. my %root; my $node= \%root; foreach my $res_code_idx (0 .. $#res_order) { my $res_code= $res_order[$res_code_idx]; $node->{vals}= $dmp_res{$res_code}{vals}; $node->{test}= $test; $node->{yes}= $dmp_res{$res_code}{optree}; $node->{depth}= $depth; if ($res_code_idx < $#res_order) { $node= $node->{no}= {}; } else { $node->{no}= $else; } } # return the optree. return \%root; } # my $optree= optree(%opts); # # Convert a trie to an optree, wrapper for _optree sub optree { my $self= shift; my %opt= @_; my $trie= $self->make_trie( $opt{type}, $opt{max_depth} ); $opt{ret_type} ||= 'len'; my $test_type= $opt{type} =~ /^cp/ ? 'cp' : 'depth'; return $self->_optree( $trie, $test_type, $opt{ret_type}, $opt{else}, 0 ); } # my $optree= generic_optree(%opts); # # build a "generic" optree out of the three 'low', 'latin1', 'utf8' # sets of strings, including a branch for handling the string type check. # sub generic_optree { my $self= shift; my %opt= @_; $opt{ret_type} ||= 'len'; my $test_type= 'depth'; my $else= $opt{else} || 0; my $latin1= $self->make_trie( 'latin1', $opt{max_depth} ); my $utf8= $self->make_trie( 'utf8', $opt{max_depth} ); $_= $self->_optree( $_, $test_type, $opt{ret_type}, $else, 0 ) for $latin1, $utf8; if ( $utf8 ) { $else= __cond_join( "( is_utf8 )", $utf8, $latin1 || $else ); } elsif ( $latin1 ) { $else= __cond_join( "!( is_utf8 )", $latin1, $else ); } if ($opt{type} eq 'generic') { my $low= $self->make_trie( 'low', $opt{max_depth} ); if ( $low ) { $else= $self->_optree( $low, $test_type, $opt{ret_type}, $else, 0 ); } } return $else; } # length_optree() # # create a string length guarded optree. # sub length_optree { my $self= shift; my %opt= @_; my $type= $opt{type}; die "Can't do a length_optree on type 'cp', makes no sense." if $type =~ /^cp/; my $else= ( $opt{else} ||= 0 ); return $else if $self->{count} == 0; my $method = $type =~ /generic/ ? 'generic_optree' : 'optree'; if ($method eq 'optree' && scalar keys %{$self->{size}{$type}} == 1) { # Here is non-generic output (meaning that we are only generating one # type), and all things that match have the same number ('size') of # bytes. The length guard is simply that we have that number of # bytes. my @size = keys %{$self->{size}{$type}}; my $cond= "((e) - (s)) >= $size[0]"; my $optree = $self->$method(%opt); $else= __cond_join( $cond, $optree, $else ); } elsif ($self->{has_multi}) { my @size; # Here, there can be a match of a multiple character string. We use # the traditional method which is to have a branch for each possible # size (longest first) and test for the legal values for that size. my %sizes= ( %{ $self->{size}{low} || {} }, %{ $self->{size}{latin1} || {} }, %{ $self->{size}{utf8} || {} } ); if ($method eq 'generic_optree') { @size= sort { $a <=> $b } keys %sizes; } else { @size= sort { $a <=> $b } keys %{ $self->{size}{$type} }; } for my $size ( @size ) { my $optree= $self->$method( %opt, type => $type, max_depth => $size ); my $cond= "((e)-(s) > " . ( $size - 1 ).")"; $else= __cond_join( $cond, $optree, $else ); } } else { my $utf8; # Here, has more than one possible size, and only matches a single # character. For non-utf8, the needed length is 1; for utf8, it is # found by array lookup 'UTF8SKIP'. # If want just the code points above 255, set up to look for those; # otherwise assume will be looking for all non-UTF-8-invariant code # poiints. my $trie_type = ($type eq 'high') ? 'high' : 'utf8'; # If we do want more than the 0-255 range, find those, and if they # exist... if ($opt{type} !~ /latin1/i && ($utf8 = $self->make_trie($trie_type, 0))) { # ... get them into an optree, and set them up as the 'else' clause $utf8 = $self->_optree( $utf8, 'depth', $opt{ret_type}, 0, 0 ); # We could make this # UTF8_IS_START(*s) && ((e) - (s)) >= UTF8SKIP(s))"; # to avoid doing the UTF8SKIP and subsequent branches for invariants # that don't match. But the current macros that get generated # have only a few things that can match past this, so I (khw) # don't think it is worth it. (Even better would be to use # calculate_mask(keys %$utf8) instead of UTF8_IS_START, and use it # if it saves a bunch. We assume that input text likely to be # well-formed . my $cond = "LIKELY(((e) - (s)) >= UTF8SKIP(s))"; $else = __cond_join($cond, $utf8, $else); # For 'generic', we also will want the latin1 UTF-8 variants for # the case where the input isn't UTF-8. my $latin1; if ($method eq 'generic_optree') { $latin1 = $self->make_trie( 'latin1', 1); $latin1= $self->_optree( $latin1, 'depth', $opt{ret_type}, 0, 0 ); } # If we want the UTF-8 invariants, get those. my $low; if ($opt{type} !~ /non_low|high/ && ($low= $self->make_trie( 'low', 1))) { $low= $self->_optree( $low, 'depth', $opt{ret_type}, 0, 0 ); # Expand out the UTF-8 invariants as a string so that we # can use them as the conditional $low = $self->_cond_as_str( $low, 0, \%opt); # If there are Latin1 variants, add a test for them. if ($latin1) { $else = __cond_join("(! is_utf8 )", $latin1, $else); } elsif ($method eq 'generic_optree') { # Otherwise for 'generic' only we know that what # follows must be valid for just UTF-8 strings, $else->{test} = "( is_utf8 && $else->{test} )"; } # If the invariants match, we are done; otherwise we have # to go to the 'else' clause. $else = __cond_join($low, 1, $else); } elsif ($latin1) { # Here, didn't want or didn't have invariants, # but we do have latin variants $else = __cond_join("(! is_utf8)", $latin1, $else); } # We need at least one byte available to start off the tests $else = __cond_join("LIKELY((e) > (s))", $else, 0); } else { # Here, we don't want or there aren't any variants. A single # byte available is enough. my $cond= "((e) > (s))"; my $optree = $self->$method(%opt); $else= __cond_join( $cond, $optree, $else ); } } return $else; } sub calculate_mask(@) { # Look at the input list of byte values. This routine returns an array of # mask/base pairs to generate that list. my @list = @_; my $list_count = @list; # Consider a set of byte values, A, B, C .... If we want to determine if # is one of them, we can write c==A || c==B || c==C .... If the # values are consecutive, we can shorten that to A<=c && c<=Z, which uses # far fewer branches. If only some of them are consecutive we can still # save some branches by creating range tests for just those that are # consecutive. _cond_as_str() does this work for looking for ranges. # # Another approach is to look at the bit patterns for A, B, C .... and see # if they have some commonalities. That's what this function does. For # example, consider a set consisting of the bytes # 0xF0, 0xF1, 0xF2, and 0xF3. We could write: # 0xF0 <= c && c <= 0xF4 # But the following mask/compare also works, and has just one test: # (c & 0xFC) == 0xF0 # The reason it works is that the set consists of exactly those bytes # whose first 4 bits are 1, and the next two are 0. (The value of the # other 2 bits is immaterial in determining if a byte is in the set or # not.) The mask masks out those 2 irrelevant bits, and the comparison # makes sure that the result matches all bytes which match those 6 # material bits exactly. In other words, the set of bytes contains # exactly those whose bottom two bit positions are either 0 or 1. The # same principle applies to bit positions that are not necessarily # adjacent. And it can be applied to bytes that differ in 1 through all 8 # bit positions. In order to be a candidate for this optimization, the # number of bytes in the set must be a power of 2. # # Consider a different example, the set 0x53, 0x54, 0x73, and 0x74. That # requires 4 tests using either ranges or individual values, and even # though the number in the set is a power of 2, it doesn't qualify for the # mask optimization described above because the number of bits that are # different is too large for that. However, the set can be expressed as # two branches with masks thusly: # (c & 0xDF) == 0x53 || (c & 0xDF) == 0x54 # a branch savings of 50%. This is done by splitting the set into two # subsets each of which has 2 elements, and within each set the values # differ by 1 byte. # # This function attempts to find some way to save some branches using the # mask technique. If not, it returns an empty list; if so, it # returns a list consisting of # [ [compare1, mask1], [compare2, mask2], ... # [compare_n, undef], [compare_m, undef], ... # ] # The is undef in the above for those bytes that must be tested # for individually. # # This function does not attempt to find the optimal set. To do so would # probably require testing all possible combinations, and keeping track of # the current best one. # # There are probably much better algorithms, but this is the one I (khw) # came up with. We start with doing a bit-wise compare of every byte in # the set with every other byte. The results are sorted into arrays of # all those that differ by the same bit positions. These are stored in a # hash with the each key being the bits they differ in. Here is the hash # for the 0x53, 0x54, 0x73, 0x74 set: # { # 4 => { # "0,1,2,5" => [ # 83, # 116, # 84, # 115 # ] # }, # 3 => { # "0,1,2" => [ # 83, # 84, # 115, # 116 # ] # } # 1 => { # 5 => [ # 83, # 115, # 84, # 116 # ] # }, # } # # The set consisting of values which differ in the 4 bit positions 0, 1, # 2, and 5 from some other value in the set consists of all 4 values. # Likewise all 4 values differ from some other value in the 3 bit # positions 0, 1, and 2; and all 4 values differ from some other value in # the single bit position 5. The keys at the uppermost level in the above # hash, 1, 3, and 4, give the number of bit positions that each sub-key # below it has. For example, the 4 key could have as its value an array # consisting of "0,1,2,5", "0,1,2,6", and "3,4,6,7", if the inputs were # such. The best optimization will group the most values into a single # mask. The most values will be the ones that differ in the most # positions, the ones with the largest value for the topmost key. These # keys, are thus just for convenience of sorting by that number, and do # not have any bearing on the core of the algorithm. # # We start with an element from largest number of differing bits. The # largest in this case is 4 bits, and there is only one situation in this # set which has 4 differing bits, "0,1,2,5". We look for any subset of # this set which has 16 values that differ in these 4 bits. There aren't # any, because there are only 4 values in the entire set. We then look at # the next possible thing, which is 3 bits differing in positions "0,1,2". # We look for a subset that has 8 values that differ in these 3 bits. # Again there are none. So we go to look for the next possible thing, # which is a subset of 2**1 values that differ only in bit position 5. 83 # and 115 do, so we calculate a mask and base for those and remove them # from every set. Since there is only the one set remaining, we remove # them from just this one. We then look to see if there is another set of # 2 values that differ in bit position 5. 84 and 116 do, so we calculate # a mask and base for those and remove them from every set (again only # this set remains in this example). The set is now empty, and there are # no more sets to look at, so we are done. if ($list_count == 256) { # All 256 is trivially masked return (0, 0); } my %hash; # Generate bits-differing lists for each element compared against each # other element for my $i (0 .. $list_count - 2) { for my $j ($i + 1 .. $list_count - 1) { my @bits_that_differ = pop_count($list[$i] ^ $list[$j]); my $differ_count = @bits_that_differ; my $key = join ",", @bits_that_differ; push @{$hash{$differ_count}{$key}}, $list[$i] unless grep { $_ == $list[$i] } @{$hash{$differ_count}{$key}}; push @{$hash{$differ_count}{$key}}, $list[$j]; } } print STDERR __LINE__, ": calculate_mask() called: List of values grouped by differing bits: ", Dumper \%hash if DEBUG; my @final_results; foreach my $count (reverse sort { $a <=> $b } keys %hash) { my $need = 2 ** $count; # Need 8 values for 3 differing bits, etc foreach my $bits (sort keys $hash{$count}->%*) { print STDERR __LINE__, ": For $count bit(s) difference ($bits), need $need; have ", scalar @{$hash{$count}{$bits}}, "\n" if DEBUG; # Look only as long as there are at least as many elements in the # subset as are needed while ((my $cur_count = @{$hash{$count}{$bits}}) >= $need) { print STDERR __LINE__, ": Looking at bit positions ($bits): ", Dumper $hash{$count}{$bits} if DEBUG; # Start with the first element in it my $try_base = $hash{$count}{$bits}[0]; my @subset = $try_base; # If it succeeds, we return a mask and a base to compare # against the masked value. That base will be the AND of # every element in the subset. Initialize to the one element # we have so far. my $compare = $try_base; # We are trying to find a subset of this that has # elements that differ in the bit positions given by the # string $bits, which is comma separated. my @bits = split ",", $bits; TRY: # Look through the remainder of the list for other # elements that differ only by these bit positions. for (my $i = 1; $i < $cur_count; $i++) { my $try_this = $hash{$count}{$bits}[$i]; my @positions = pop_count($try_base ^ $try_this); print STDERR __LINE__, ": $try_base vs $try_this: is (", join(',', @positions), ") a subset of ($bits)?" if DEBUG;; foreach my $pos (@positions) { unless (grep { $pos == $_ } @bits) { print STDERR " No\n" if DEBUG; my $remaining = $cur_count - $i - 1; if ($remaining && @subset + $remaining < $need) { print STDERR __LINE__, ": Can stop trying $try_base, because even if all the remaining $remaining values work, they wouldn't add up to the needed $need when combined with the existing ", scalar @subset, " ones\n" if DEBUG; last TRY; } next TRY; } } print STDERR " Yes\n" if DEBUG; push @subset, $try_this; # Add this to the mask base, in case it ultimately # succeeds, $compare &= $try_this; } print STDERR __LINE__, ": subset (", join(", ", @subset), ") has ", scalar @subset, " elements; needs $need\n" if DEBUG; if (@subset < $need) { shift @{$hash{$count}{$bits}}; next; # Try with next value } # Create the mask my $mask = 0; foreach my $position (@bits) { $mask |= 1 << $position; } $mask = ~$mask & 0xFF; push @final_results, [$compare, $mask]; printf STDERR "%d: Got it: compare=%d=0x%X; mask=%X\n", __LINE__, $compare, $compare, $mask if DEBUG; # These values are now spoken for. Remove them from future # consideration foreach my $remove_count (sort keys %hash) { foreach my $bits (sort keys %{$hash{$remove_count}}) { foreach my $to_remove (@subset) { @{$hash{$remove_count}{$bits}} = grep { $_ != $to_remove } @{$hash{$remove_count}{$bits}}; } } } } } } # Any values that remain in the list are ones that have to be tested for # individually. my @individuals; foreach my $count (reverse sort { $a <=> $b } keys %hash) { foreach my $bits (sort keys $hash{$count}->%*) { foreach my $remaining (@{$hash{$count}{$bits}}) { # If we already know about this value, just ignore it. next if grep { $remaining == $_ } @individuals; # Otherwise it needs to be returned as something to match # individually push @final_results, [$remaining, undef]; push @individuals, $remaining; } } } # Sort by increasing numeric value @final_results = sort { $a->[0] <=> $b->[0] } @final_results; print STDERR __LINE__, ": Final return: ", Dumper \@final_results if DEBUG; return @final_results; } # _cond_as_str # turn a list of conditions into a text expression # - merges ranges of conditions, and joins the result with || sub _cond_as_str { my ( $self, $op, $combine, $opts_ref )= @_; my $cond= $op->{vals}; my $test= $op->{test}; my $is_cp_ret = $opts_ref->{ret_type} eq "cp"; return "( $test )" if !defined $cond; # rangify the list. my @ranges; my $Update= sub { # We skip this if there are optimizations that # we can apply (below) to the individual ranges if ( ($is_cp_ret || $combine) && @ranges && ref $ranges[-1]) { if ( $ranges[-1][0] == $ranges[-1][1] ) { $ranges[-1]= $ranges[-1][0]; } elsif ( $ranges[-1][0] + 1 == $ranges[-1][1] ) { $ranges[-1]= $ranges[-1][0]; push @ranges, $ranges[-1] + 1; } } }; for my $condition ( @$cond ) { if ( !@ranges || $condition != $ranges[-1][1] + 1 ) { $Update->(); push @ranges, [ $condition, $condition ]; } else { $ranges[-1][1]++; } } $Update->(); return $self->_combine( $test, @ranges ) if $combine; if ($is_cp_ret) { @ranges= map { ref $_ ? sprintf( "( $self->{val_fmt} <= $test && $test <= $self->{val_fmt} )", @$_ ) : sprintf( "$self->{val_fmt} == $test", $_ ); } @ranges; return "( " . join( " || ", @ranges ) . " )"; } # If the input set has certain characteristics, we can optimize tests # for it. This doesn't apply if returning the code point, as we want # each element of the set individually. The code above is for this # simpler case. return 1 if @$cond == 256; # If all bytes match, is trivially true my @masks; if (@ranges > 1) { # See if the entire set shares optimizable characteristics, and if so, # return the optimization. We delay checking for this on sets with # just a single range, as there may be better optimizations available # in that case. @masks = calculate_mask(@$cond); # Stringify the output of calculate_mask() if (@masks) { my @return; foreach my $mask_ref (@masks) { if (defined $mask_ref->[1]) { push @return, sprintf "( ( $test & $self->{val_fmt} ) == $self->{val_fmt} )", $mask_ref->[1], $mask_ref->[0]; } else { # An undefined mask means to use the value as-is push @return, sprintf "$test == $self->{val_fmt}", $mask_ref->[0]; } } # The best possible case below for specifying this set of values via # ranges is 1 branch per range. If our mask method yielded better # results, there is no sense trying something that is bound to be # worse. if (@return < @ranges) { return "( " . join( " || ", @return ) . " )"; } @masks = @return; } } # Here, there was no entire-class optimization that was clearly better # than doing things by ranges. Look at each range. my $range_count_extra = 0; for (my $i = 0; $i < @ranges; $i++) { if (! ref $ranges[$i]) { # Trivial case: no range $ranges[$i] = sprintf "$self->{val_fmt} == $test", $ranges[$i]; } elsif ($ranges[$i]->[0] == $ranges[$i]->[1]) { $ranges[$i] = # Trivial case: single element range sprintf "$self->{val_fmt} == $test", $ranges[$i]->[0]; } elsif ($ranges[$i]->[0] == 0) { # If the range matches all 256 possible bytes, it is trivially # true. return 1 if $ranges[0]->[1] == 0xFF; # @ranges must be 1 in # this case $ranges[$i] = sprintf "( $test <= $self->{val_fmt} )", $ranges[$i]->[1]; } elsif ($ranges[$i]->[1] == 255) { # Similarly the max possible is 255, so can omit an upper bound # test if the calculated max is the max possible one. $ranges[$i] = sprintf "( $test >= $self->{val_fmt} )", $ranges[0]->[0]; } else { my $output = ""; # Well-formed UTF-8 continuation bytes on ascii platforms must be # in the range 0x80 .. 0xBF. If we know that the input is # well-formed (indicated by not trying to be 'safe'), we can omit # tests that verify that the input is within either of these # bounds. (No legal UTF-8 character can begin with anything in # this range, so we don't have to worry about this being a # continuation byte or not.) if ($opts_ref->{charset} =~ /ascii/i && (! $opts_ref->{safe} && ! $opts_ref->{no_length_checks}) && $opts_ref->{type} =~ / ^ (?: utf8 | high ) $ /xi) { my $lower_limit_is_80 = ($ranges[$i]->[0] == 0x80); my $upper_limit_is_BF = ($ranges[$i]->[1] == 0xBF); # If the range is the entire legal range, it matches any legal # byte, so we can omit both tests. (This should happen only # if the number of ranges is 1.) if ($lower_limit_is_80 && $upper_limit_is_BF) { return 1; } elsif ($lower_limit_is_80) { # Just use the upper limit test $output = sprintf("( $test <= $self->{val_fmt} )", $ranges[$i]->[1]); } elsif ($upper_limit_is_BF) { # Just use the lower limit test $output = sprintf("( $test >= $self->{val_fmt} )", $ranges[$i]->[0]); } } # If we didn't change to omit a test above, see if the number of # elements is a power of 2 (only a single bit in the # representation of its count will be set) and if so, it may be # that a mask/compare optimization is possible. if ($output eq "" && pop_count($ranges[$i]->[1] - $ranges[$i]->[0] + 1) == 1) { my @list; push @list, $_ for ($ranges[$i]->[0] .. $ranges[$i]->[1]); my @this_masks = calculate_mask(@list); # Use the mask if there is just one for the whole range. # Otherwise there is no savings over the two branches that can # define the range. if (@this_masks == 1 && defined $this_masks[0][1]) { $output = sprintf "( $test & $self->{val_fmt} ) == $self->{val_fmt}", $this_masks[0][1], $this_masks[0][0]; } } if ($output ne "") { # Prefer any optimization $ranges[$i] = $output; } else { # No optimization happened. We need a test that the code # point is within both bounds. But, if the bounds are # adjacent code points, it is cleaner to say # 'first == test || second == test' # than it is to say # 'first <= test && test <= second' $range_count_extra++; # This range requires 2 branches to # represent if ($ranges[$i]->[0] + 1 == $ranges[$i]->[1]) { $ranges[$i] = "( " . join( " || ", ( map { sprintf "$self->{val_fmt} == $test", $_ } @{$ranges[$i]} ) ) . " )"; } else { # Full bounds checking $ranges[$i] = sprintf("( $self->{val_fmt} <= $test && $test <= $self->{val_fmt} )", $ranges[$i]->[0], $ranges[$i]->[1]); } } } } # We have generated the list of bytes in two ways; one trying to use masks # to cut the number of branches down, and the other to look at individual # ranges (some of which could be cut down by using a mask for just it). # We return whichever method uses the fewest branches. return "( " . join( " || ", (@masks && @masks < @ranges + $range_count_extra) ? @masks : @ranges) . " )"; } # _combine # recursively turn a list of conditions into a fast break-out condition # used by _cond_as_str() for 'cp' type macros. sub _combine { my ( $self, $test, @cond )= @_; return if !@cond; my $item= shift @cond; my ( $cstr, $gtv ); if ( ref $item ) { # @item should be a 2-element array giving range start # and end if ($item->[0] == 0) { # UV's are never negative, so skip "0 <= " # test which could generate a compiler warning # that test is always true $cstr= sprintf( "$test <= $self->{val_fmt}", $item->[1] ); } else { $cstr= sprintf( "( $self->{val_fmt} <= $test && $test <= $self->{val_fmt} )", @$item ); } $gtv= sprintf "$self->{val_fmt}", $item->[1]; } else { $cstr= sprintf( "$self->{val_fmt} == $test", $item ); $gtv= sprintf "$self->{val_fmt}", $item; } if ( @cond ) { my $combine= $self->_combine( $test, @cond ); if (@cond >1) { return "( $cstr || ( $gtv < $test &&\n" . $combine . " ) )"; } else { return "( $cstr || $combine )"; } } else { return $cstr; } } # _render() # recursively convert an optree to text with reasonably neat formatting sub _render { my ( $self, $op, $combine, $brace, $opts_ref, $def, $submacros )= @_; return 0 if ! defined $op; # The set is empty if ( !ref $op ) { return $op; } my $cond= $self->_cond_as_str( $op, $combine, $opts_ref ); #no warnings 'recursion'; # This would allow really really inefficient # code to be generated. See pod my $yes= $self->_render( $op->{yes}, $combine, 1, $opts_ref, $def, $submacros ); return $yes if $cond eq '1'; my $no= $self->_render( $op->{no}, $combine, 0, $opts_ref, $def, $submacros ); return "( $cond )" if $yes eq '1' and $no eq '0'; my ( $lb, $rb )= $brace ? ( "( ", " )" ) : ( "", "" ); return "$lb$cond ? $yes : $no$rb" if !ref( $op->{yes} ) && !ref( $op->{no} ); my $ind1= " " x 4; my $ind= "\n" . ( $ind1 x $op->{depth} ); if ( ref $op->{yes} ) { $yes= $ind . $ind1 . $yes; } else { $yes= " " . $yes; } my $str= "$lb$cond ?$yes$ind: $no$rb"; if (length $str > 6000) { push @$submacros, sprintf "#define $def\n( %s )", "_part" . (my $yes_idx= 0+@$submacros), $yes; push @$submacros, sprintf "#define $def\n( %s )", "_part" . (my $no_idx= 0+@$submacros), $no; return sprintf "%s%s ? $def : $def%s", $lb, $cond, "_part$yes_idx", "_part$no_idx", $rb; } return $str; } # $expr=render($op,$combine) # # convert an optree to text with reasonably neat formatting. If $combine # is true then the condition is created using "fast breakouts" which # produce uglier expressions that are more efficient for common case, # longer lists such as that resulting from type 'cp' output. # Currently only used for type 'cp' macros. sub render { my ( $self, $op, $combine, $opts_ref, $def_fmt )= @_; my @submacros; my $macro= sprintf "#define $def_fmt\n( %s )", "", $self->_render( $op, $combine, 0, $opts_ref, $def_fmt, \@submacros ); return join "\n\n", map { "/*** GENERATED CODE ***/\n" . __macro( __clean( $_ ) ) } @submacros, $macro; } # make_macro # make a macro of a given type. # calls into make_trie and (generic_|length_)optree as needed # Opts are: # type : 'cp','cp_high', 'generic','high','low','latin1','utf8','LATIN1','UTF8' # ret_type : 'cp' or 'len' # safe : don't assume is well-formed UTF-8, so don't skip any range # checks, and add length guards to macro # no_length_checks : like safe, but don't add length guards. # # type defaults to 'generic', and ret_type to 'len' unless type is 'cp' # in which case it defaults to 'cp' as well. # # It is illegal to do a type 'cp' macro on a pattern with multi-codepoint # sequences in it, as the generated macro will accept only a single codepoint # as an argument. # # It is also illegal to do a non-safe macro on a pattern with multi-codepoint # sequences in it, as even if it is known to be well-formed, we need to not # run off the end of the buffer when, say, the buffer ends with the first two # characters, but three are looked at by the macro. # # returns the macro. sub make_macro { my $self= shift; my %opts= @_; my $type= $opts{type} || 'generic'; if ($self->{has_multi}) { if ($type =~ /^cp/) { die "Can't do a 'cp' on multi-codepoint character class '$self->{op}'" } elsif (! $opts{safe}) { die "'safe' is required on multi-codepoint character class '$self->{op}'" } } my $ret_type= $opts{ret_type} || ( $opts{type} =~ /^cp/ ? 'cp' : 'len' ); my $method; if ( $opts{safe} ) { $method= 'length_optree'; } elsif ( $type =~ /generic/ ) { $method= 'generic_optree'; } else { $method= 'optree'; } my @args= $type =~ /^cp/ ? 'cp' : 's'; push @args, "e" if $opts{safe}; push @args, "is_utf8" if $type =~ /generic/; push @args, "len" if $ret_type eq 'both'; my $pfx= $ret_type eq 'both' ? 'what_len_' : $ret_type eq 'cp' ? 'what_' : 'is_'; my $ext= $type =~ /generic/ ? '' : '_' . lc( $type ); $ext .= '_non_low' if $type eq 'generic_non_low'; $ext .= "_safe" if $opts{safe}; $ext .= "_no_length_checks" if $opts{no_length_checks}; my $argstr= join ",", @args; my $def_fmt="$pfx$self->{op}$ext%s($argstr)"; my $optree= $self->$method( %opts, type => $type, ret_type => $ret_type ); return $self->render( $optree, ($type =~ /^cp/) ? 1 : 0, \%opts, $def_fmt ); } # if we aren't being used as a module (highly likely) then process # the __DATA__ below and produce macros in regcharclass.h # if an argument is provided to the script then it is assumed to # be the path of the file to output to, if the arg is '-' outputs # to STDOUT. if ( !caller ) { $|++; my $path= shift @ARGV || "regcharclass.h"; my $out_fh; if ( $path eq '-' ) { $out_fh= \*STDOUT; } else { $out_fh = open_new( $path ); } print $out_fh read_only_top( lang => 'C', by => $0, file => 'regcharclass.h', style => '*', copyright => [2007, 2011], final => <new( op => $op, title => $title, txt => \@txt, charset => $charset); #die Dumper(\@types,\%mods); my @mods; push @mods, 'safe' if delete $mods{safe}; push @mods, 'no_length_checks' if delete $mods{no_length_checks}; unshift @mods, 'fast' if delete $mods{fast} || ! @mods; # Default to 'fast' # do this one # first, as # traditional if (%mods) { die "Unknown modifiers: ", join ", ", map { "'$_'" } sort keys %mods; } foreach my $type_spec ( @types ) { my ( $type, $ret )= split /-/, $type_spec; $ret ||= 'len'; foreach my $mod ( @mods ) { # 'safe' is irrelevant with code point macros, so skip if # there is also a 'fast', but don't skip if this is the only # way a cp macro will get generated. Below we convert 'safe' # to 'fast' in this instance next if $type =~ /^cp/ && ($mod eq 'safe' || $mod eq 'no_length_checks') && grep { 'fast' =~ $_ } @mods; delete $mods{$mod}; my $macro= $obj->make_macro( type => $type, ret_type => $ret, safe => $mod eq 'safe' && $type !~ /^cp/, charset => $charset, no_length_checks => $mod eq 'no_length_checks' && $type !~ /^cp/, ); print $out_fh $macro, "\n"; } } }; my @data = ; foreach my $charset (get_supported_code_pages()) { my $first_time = 1; undef $op; undef $title; undef @txt; undef @types; undef %mods; print $out_fh "\n", get_conditional_compile_line_start($charset); my @data_copy = @data; for (@data_copy) { s/^ \s* (?: \# .* ) ? $ //x; # squeeze out comment and blanks next unless /\S/; chomp; if ( /^[A-Z]/ ) { $doit->($charset) unless $first_time; # This starts a new # definition; do the # previous one $first_time = 0; ( $op, $title )= split /\s*:\s*/, $_, 2; @txt= (); } elsif ( s/^=>// ) { my ( $type, $modifier )= split /:/, $_; @types= split ' ', $type; undef %mods; map { $mods{$_} = 1 } split ' ', $modifier; } else { push @txt, "$_"; } } $doit->($charset); print $out_fh get_conditional_compile_line_end(); } print $out_fh "\n#endif /* PERL_REGCHARCLASS_H_ */\n"; if($path eq '-') { print $out_fh "/* ex: set ro: */\n"; } else { # Some of the sources for these macros come from Unicode tables my $sources_list = "lib/unicore/mktables.lst"; my @sources = ($0, qw(lib/unicore/mktables lib/Unicode/UCD.pm regen/regcharclass_multi_char_folds.pl regen/charset_translations.pl )); { # Depend on mktables’ own sources. It’s a shorter list of files than # those that Unicode::UCD uses. if (! open my $mktables_list, '<', $sources_list) { # This should force a rebuild once $sources_list exists push @sources, $sources_list; } else { while(<$mktables_list>) { last if /===/; chomp; push @sources, "lib/unicore/$_" if /^[^#]/; } } } read_only_bottom_close_and_rename($out_fh, \@sources) } } # The form of the input is a series of definitions to make macros for. # The first line gives the base name of the macro, followed by a colon, and # then text to be used in comments associated with the macro that are its # title or description. In all cases the first (perhaps only) parameter to # the macro is a pointer to the first byte of the code point it is to test to # see if it is in the class determined by the macro. In the case of non-UTF8, # the code point consists only of a single byte. # # The second line must begin with a '=>' and be followed by the types of # macro(s) to be generated; these are specified below. A colon follows the # types, followed by the modifiers, also specified below. At least one # modifier is required. # # The subsequent lines give what code points go into the class defined by the # macro. Multiple characters may be specified via a string like "\x0D\x0A", # enclosed in quotes. Otherwise the lines consist of one of: # 1) a single Unicode code point, prefaced by 0x # 2) a single range of Unicode code points separated by a minus (and # optional space) # 3) a single Unicode property specified in the standard Perl form # "\p{...}" # 4) a line like 'do path'. This will do a 'do' on the file given by # 'path'. It is assumed that this does nothing but load subroutines # (See item 5 below). The reason 'require path' is not used instead is # because 'do' doesn't assume that path is in @INC. # 5) a subroutine call # &pkg::foo(arg1, ...) # where pkg::foo was loaded by a 'do' line (item 4). The subroutine # returns an array of entries of forms like items 1-3 above. This # allows more complex inputs than achievable from the other input types. # # A blank line or one whose first non-blank character is '#' is a comment. # The definition of the macro is terminated by a line unlike those described. # # Valid types: # low generate a macro whose name is 'is_BASE_low' and defines a # class that includes only ASCII-range chars. (BASE is the # input macro base name.) # latin1 generate a macro whose name is 'is_BASE_latin1' and defines a # class that includes only upper-Latin1-range chars. It is not # designed to take a UTF-8 input parameter. # high generate a macro whose name is 'is_BASE_high' and defines a # class that includes all relevant code points that are above # the Latin1 range. This is for very specialized uses only. # It is designed to take only an input UTF-8 parameter. # utf8 generate a macro whose name is 'is_BASE_utf8' and defines a # class that includes all relevant characters that aren't ASCII. # It is designed to take only an input UTF-8 parameter. # LATIN1 generate a macro whose name is 'is_BASE_latin1' and defines a # class that includes both ASCII and upper-Latin1-range chars. # It is not designed to take a UTF-8 input parameter. # UTF8 generate a macro whose name is 'is_BASE_utf8' and defines a # class that can include any code point, adding the 'low' ones # to what 'utf8' works on. It is designed to take only an input # UTF-8 parameter. # generic generate a macro whose name is 'is_BASE". It has a 2nd, # boolean, parameter which indicates if the first one points to # a UTF-8 string or not. Thus it works in all circumstances. # generic_non_low generate a macro whose name is 'is_BASE_non_low". It has # a 2nd, boolean, parameter which indicates if the first one # points to a UTF-8 string or not. It excludes any ASCII-range # matches, but otherwise it works in all circumstances. # cp generate a macro whose name is 'is_BASE_cp' and defines a # class that returns true if the UV parameter is a member of the # class; false if not. # cp_high like cp, but it is assumed that it is known that the UV # parameter is above Latin1. The name of the generated macro is # 'is_BASE_cp_high'. This is different from high-cp, derived # below. # A macro of the given type is generated for each type listed in the input. # The default return value is the number of octets read to generate the match. # Append "-cp" to the type to have it instead return the matched codepoint. # The macro name is changed to 'what_BASE...'. See pod for # caveats # Appending '-both" instead adds an extra parameter to the end of the argument # list, which is a pointer as to where to store the number of # bytes matched, while also returning the code point. The macro # name is changed to 'what_len_BASE...'. See pod for caveats # # Valid modifiers: # safe The input string is not necessarily valid UTF-8. In # particular an extra parameter (always the 2nd) to the macro is # required, which points to one beyond the end of the string. # The macro will make sure not to read off the end of the # string. In the case of non-UTF8, it makes sure that the # string has at least one byte in it. The macro name has # '_safe' appended to it. # no_length_checks The input string is not necessarily valid UTF-8, but it # is to be assumed that the length has already been checked and # found to be valid # fast The input string is valid UTF-8. No bounds checking is done, # and the macro can make assumptions that lead to faster # execution. # only_ascii_platform Skip this definition if the character set is for # a non-ASCII platform. # only_ebcdic_platform Skip this definition if the character set is for # a non-EBCDIC platform. # No modifier need be specified; fast is assumed for this case. If both # 'fast', and 'safe' are specified, two macros will be created for each # 'type'. # # If run on a non-ASCII platform will automatically convert the Unicode input # to native. The documentation above is slightly wrong in this case. 'low' # actually refers to code points whose UTF-8 representation is the same as the # non-UTF-8 version (invariants); and 'latin1' refers to all the rest of the # code points less than 256. 1; # in the unlikely case we are being used as a module __DATA__ # This is no longer used, but retained in case it is needed some day. # TRICKYFOLD: Problematic fold case letters. When adding to this list, also should add them to regcomp.c and fold_grind.t # => generic cp generic-cp generic-both :fast safe # 0x00DF # LATIN SMALL LETTER SHARP S # 0x0390 # GREEK SMALL LETTER IOTA WITH DIALYTIKA AND TONOS # 0x03B0 # GREEK SMALL LETTER UPSILON WITH DIALYTIKA AND TONOS # 0x1E9E # LATIN CAPITAL LETTER SHARP S, because maps to same as 00DF # 0x1FD3 # GREEK SMALL LETTER IOTA WITH DIALYTIKA AND OXIA; maps same as 0390 # 0x1FE3 # GREEK SMALL LETTER UPSILON WITH DIALYTIKA AND OXIA; maps same as 03B0 LNBREAK: Line Break: \R => generic UTF8 LATIN1 : safe "\x0D\x0A" # CRLF - Network (Windows) line ending \p{VertSpace} HORIZWS: Horizontal Whitespace: \h \H => high cp_high : fast \p{HorizSpace} VERTWS: Vertical Whitespace: \v \V => high cp_high : fast \p{VertSpace} XDIGIT: Hexadecimal digits => high cp_high : fast \p{XDigit} XPERLSPACE: \p{XPerlSpace} => high cp_high : fast \p{XPerlSpace} REPLACEMENT: Unicode REPLACEMENT CHARACTER => UTF8 :safe 0xFFFD NONCHAR: Non character code points => UTF8 :safe \p{_Perl_Nchar} SURROGATE: Surrogate code points => UTF8 :safe \p{_Perl_Surrogate} QUOTEMETA: Meta-characters that \Q should quote => high :fast \p{_Perl_Quotemeta} MULTI_CHAR_FOLD: multi-char strings that are folded to by a single character => UTF8 :safe # 1 => All folds ®charclass_multi_char_folds::multi_char_folds(1) MULTI_CHAR_FOLD: multi-char strings that are folded to by a single character => LATIN1 : safe ®charclass_multi_char_folds::multi_char_folds(0) # 0 => Latin1-only FOLDS_TO_MULTI: characters that fold to multi-char strings => UTF8 :fast \p{_Perl_Folds_To_Multi_Char} PROBLEMATIC_LOCALE_FOLD : characters whose fold is problematic under locale => UTF8 cp :fast \p{_Perl_Problematic_Locale_Folds} PROBLEMATIC_LOCALE_FOLDEDS_START : The first folded character of folds which are problematic under locale => UTF8 cp :fast \p{_Perl_Problematic_Locale_Foldeds_Start} PATWS: pattern white space => generic cp : safe \p{_Perl_PatWS} HANGUL_ED: Hangul syllables whose first character is \xED => UTF8 :only_ascii_platform safe 0xD000 - 0xD7FF