Name
Data::NFA - Non deterministic finite state machine from regular expression.
Synopsis
Create a non deterministic finite state machine from a regular expression which can then be converted into a deterministic finite state machine by Data::DFA and used to parse sequences of symbols.
For example, the regular expression:
((a|b)*)**4produces the following machine:
use Data::NFA qw(:all);
use Data::Table::Text qw(:all);
use Test::More qw(no_plan);
my $N = 4;
my $s = q(zeroOrMore(choice(element("a"), element("b"))));
my $nfa = eval qq(fromExpr(($s)x$N));
ok $nfa->printNws("((a|b)*)**$N: ") eq nws <<END;
((a|b)*)**4:
Location F Transitions Jumps
0 1 { a => 1 } [2, 4, 6, 8, 10, 12, 14, 16]
1 1 undef [0, 2, 3, 4, 6, 8, 10, 12, 14, 16]
2 0 { b => 3 } undef
3 1 undef [0, 2, 4, 6, 8, 10, 12, 14, 16]
4 1 { a => 5 } [6, 8, 10, 12, 14, 16]
5 1 undef [4, 6, 7, 8, 10, 12, 14, 16]
6 0 { b => 7 } undef
7 1 undef [4, 6, 8, 10, 12, 14, 16]
8 1 { a => 9 } [10, 12, 14, 16]
9 1 undef [8, 10, 11, 12, 14, 16]
10 0 { b => 11 } undef
11 1 undef [8, 10, 12, 14, 16]
12 1 { a => 13 } [14, 16]
13 1 undef [12, 14, 15, 16]
14 0 { b => 15 } undef
15 1 undef [12, 14, 16]
16 1 undef undef
ENDDescription
Non deterministic finite state machine from regular expression.
Version 20200621.
The following sections describe the methods in each functional area of this module. For an alphabetic listing of all methods by name see Index.
Construct regular expression
Construct a regular expression that defines the language to be parsed using the following combining operations which can all be imported:
element($label)
One element. An element can also be represented by a string or number
Parameter Description
1 $label Transition symbolExample:
my $nfa = fromExpr(𝗲𝗹𝗲𝗺𝗲𝗻𝘁("a"));
ok $nfa->print("Element: a") eq <<END;
Element: a
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 1 undef undef\
END
ok $nfa->isFinal(2);
ok !$nfa->isFinal(0);
ok $nfa->parse(qw(a));
ok !$nfa->parse(qw(a b));
ok !$nfa->parse(qw(b));
ok !$nfa->parse(qw(b a));This is a static method and so should either be imported or invoked as:
Data::NFA::elementsequence(@elements)
Sequence of elements and/or symbols.
Parameter Description
1 @elements ElementsExample:
my $nfa = fromExpr(qw(a b));
is_deeply $nfa->print("ab"), <<END;
ab
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3]
3 { b => 4 } undef
4 1 undef undef
END
ok !$nfa->parse(qw());
ok $nfa->parse(qw(a b));
ok !$nfa->parse(qw(b a));
ok !$nfa->parse(qw(a));
ok !$nfa->parse(qw(b));This is a static method and so should either be imported or invoked as:
Data::NFA::sequenceoptional(@element)
An optional sequence of elements and/or symbols.
Parameter Description
1 @element ElementsExample:
my $nfa = fromExpr("a", 𝗼𝗽𝘁𝗶𝗼𝗻𝗮𝗹("b"), "c");
is_deeply $nfa->print("ab?c"), <<END;
ab?c
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3 .. 6]
3 undef [4, 5, 6]
4 { b => 5 } undef
5 undef [6]
6 { c => 7 } undef
7 1 undef undef
END
ok !$nfa->parse(qw(a));
ok $nfa->parse(qw(a b c));
ok $nfa->parse(qw(a c));
ok !$nfa->parse(qw(a c b));This is a static method and so should either be imported or invoked as:
Data::NFA::optionalzeroOrMore(@element)
Zero or more repetitions of a sequence of elements and/or symbols.
Parameter Description
1 @element ElementsExample:
my $nfa = fromExpr("a", 𝘇𝗲𝗿𝗼𝗢𝗿𝗠𝗼𝗿𝗲("b"), "c");
is_deeply $nfa->print("ab*c"), <<END;
ab*c
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3, 4, 6, 7]
3 undef [4, 6, 7]
4 { b => 5 } undef
5 undef [3, 4, 6, 7]
6 undef [7]
7 { c => 8 } undef
8 1 undef undef
END
ok $nfa->parse(qw(a c));
ok $nfa->parse(qw(a b c));
ok $nfa->parse(qw(a b b c));
ok !$nfa->parse(qw(a b b d));
my $nfa = fromExpr("a",
𝘇𝗲𝗿𝗼𝗢𝗿𝗠𝗼𝗿𝗲(choice("a",
"a")),
"a");
is_deeply $nfa->print("(a(a|a)*a"), <<END;
(a(a|a)*a
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3, 4, 5, 7, 8, 10, 11]
3 undef [4, 5, 7, 8, 10, 11]
4 undef [5, 7, 8]
5 { a => 6 } undef
6 undef [3, 4, 5, 7 .. 11]
7 undef [8]
8 { a => 9 } undef
9 undef [3, 4, 5, 7, 8, 10, 11]
10 undef [11]
11 { a => 12 } undef
12 1 undef undef
END
ok !$nfa->parse(qw(a));
ok $nfa->parse(qw(a a));
ok $nfa->parse(qw(a a a));
ok !$nfa->parse(qw(a b a));This is a static method and so should either be imported or invoked as:
Data::NFA::zeroOrMoreoneOrMore(@element)
One or more repetitions of a sequence of elements and/or symbols.
Parameter Description
1 @element ElementsExample:
my $nfa = fromExpr("a", 𝗼𝗻𝗲𝗢𝗿𝗠𝗼𝗿𝗲("b"), "c");
is_deeply $nfa->print("One or More: ab+c"), <<END;
One or More: ab+c
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3, 4]
3 undef [4]
4 { b => 5 } undef
5 undef [3, 4, 6, 7]
6 undef [7]
7 { c => 8 } undef
8 1 undef undef
END
ok !$nfa->parse(qw(a c));
ok $nfa->parse(qw(a b c));
ok $nfa->parse(qw(a b b c));
ok !$nfa->parse(qw(a b b d));This is a static method and so should either be imported or invoked as:
Data::NFA::oneOrMorechoice(@elements)
Choice from amongst one or more elements and/or symbols.
Parameter Description
1 @elements Elements to be chosen fromExample:
my $nfa = fromExpr("a",
𝗰𝗵𝗼𝗶𝗰𝗲(qw(b c)),
"d");
is_deeply $nfa->print("(a(b|c)d"), <<END;
(a(b|c)d
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3, 4, 6, 7]
3 undef [4, 6, 7]
4 { b => 5 } undef
5 undef [8, 9]
6 undef [7]
7 { c => 8 } undef
8 undef [9]
9 { d => 10 } undef
10 1 undef undef
END
ok $nfa->parse(qw(a b d));
ok $nfa->parse(qw(a c d));
ok !$nfa->parse(qw(a b c d));This is a static method and so should either be imported or invoked as:
Data::NFA::choiceexcept(@elements)
Choice from amongst all symbols except the ones mentioned
Parameter Description
1 @elements Elements not to be chosen fromExample:
my $nfa = fromExpr(choice(qw(a b c)), 𝗲𝘅𝗰𝗲𝗽𝘁(qw(c x)), choice(qw(a b c)));
is_deeply $nfa->print("(a|b|c)(c!x)(a|b|c)"), <<END;
(a|b|c)(c!x)(a|b|c)
Location F Transitions Jumps
0 undef [1, 2, 4, 5, 7, 8]
1 undef [2, 4, 5, 7, 8]
2 { a => 3 } undef
3 undef [9, 10, 11, 13, 14]
4 undef [5]
5 { b => 6 } undef
6 undef [9, 10, 11, 13, 14]
7 undef [8]
8 { c => 9 } undef
9 undef [10, 11, 13, 14]
10 undef [11, 13, 14]
11 { a => 12 } undef
12 undef [15, 16, 17, 19, 20, 22, 23]
13 undef [14]
14 { b => 15 } undef
15 undef [16, 17, 19, 20, 22, 23]
16 undef [17, 19, 20, 22, 23]
17 { a => 18 } undef
18 1 undef [24]
19 undef [20]
20 { b => 21 } undef
21 1 undef [24]
22 undef [23]
23 { c => 24 } undef
24 1 undef undef
END
ok !$nfa->parse(qw(a a));
ok $nfa->parse(qw(a a a));
ok !$nfa->parse(qw(a c a));This is a static method and so should either be imported or invoked as:
Data::NFA::exceptNon deterministic finite state machine
Create a non deterministic finite state machine to represent a regular expression.
fromExpr(@expression)
Create an NFA from a regular @expression.
Parameter Description
1 @expression Regular expressionsExample:
my $nfa = 𝗳𝗿𝗼𝗺𝗘𝘅𝗽𝗿
("a",
oneOrMore(choice(qw(b c))),
optional("d"),
element("e")
);
is_deeply $nfa->print("a(b|c)+d?e"), <<END;
a(b|c)+d?e
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3, 4, 5, 7, 8]
3 undef [4, 5, 7, 8]
4 undef [5, 7, 8]
5 { b => 6 } undef
6 undef [3, 4, 5, 7 .. 14]
7 undef [8]
8 { c => 9 } undef
9 undef [3, 4, 5, 7, 8, 10 .. 14]
10 undef [11 .. 14]
11 undef [12, 13, 14]
12 { d => 13 } undef
13 undef [14]
14 { e => 15 } undef
15 1 undef undef
END
is_deeply ['a'..'e'], [$nfa->symbols];
ok !$nfa->parse(qw(a e));
ok !$nfa->parse(qw(a d e));
ok $nfa->parse(qw(a b c e));
ok $nfa->parse(qw(a b c d e));This is a static method and so should either be imported or invoked as:
Data::NFA::fromExprprint($states, $title)
Print the current $states of the non deterministic finite state automaton using the specified $title. If it is non deterministic, the non deterministic jumps will be shown as well as the transitions table. If deterministic, only the transitions table will be shown.
Parameter Description
1 $states States
2 $title TitleExample:
my $nfa = fromExpr
("a",
oneOrMore(choice(qw(b c))),
optional("d"),
element("e")
);
is_deeply $nfa->𝗽𝗿𝗶𝗻𝘁("a(b|c)+d?e"), <<END;
a(b|c)+d?e
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3, 4, 5, 7, 8]
3 undef [4, 5, 7, 8]
4 undef [5, 7, 8]
5 { b => 6 } undef
6 undef [3, 4, 5, 7 .. 14]
7 undef [8]
8 { c => 9 } undef
9 undef [3, 4, 5, 7, 8, 10 .. 14]
10 undef [11 .. 14]
11 undef [12, 13, 14]
12 { d => 13 } undef
13 undef [14]
14 { e => 15 } undef
15 1 undef undef
END
is_deeply ['a'..'e'], [$nfa->symbols];
ok !$nfa->parse(qw(a e));
ok !$nfa->parse(qw(a d e));
ok $nfa->parse(qw(a b c e));
ok $nfa->parse(qw(a b c d e));symbols($states)
Return an array of all the transition symbols.
Parameter Description
1 $states StatesExample:
my $nfa = fromExpr
("a",
oneOrMore(choice(qw(b c))),
optional("d"),
element("e")
);
is_deeply $nfa->print("a(b|c)+d?e"), <<END;
a(b|c)+d?e
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 undef [3, 4, 5, 7, 8]
3 undef [4, 5, 7, 8]
4 undef [5, 7, 8]
5 { b => 6 } undef
6 undef [3, 4, 5, 7 .. 14]
7 undef [8]
8 { c => 9 } undef
9 undef [3, 4, 5, 7, 8, 10 .. 14]
10 undef [11 .. 14]
11 undef [12, 13, 14]
12 { d => 13 } undef
13 undef [14]
14 { e => 15 } undef
15 1 undef undef
END
is_deeply ['a'..'e'], [$nfa->𝘀𝘆𝗺𝗯𝗼𝗹𝘀];
ok !$nfa->parse(qw(a e));
ok !$nfa->parse(qw(a d e));
ok $nfa->parse(qw(a b c e));
ok $nfa->parse(qw(a b c d e));isFinal($states, $state)
Whether, in the $states specifying an NFA the named state $state is a final state.
Parameter Description
1 $states States
2 $state Name of state to testExample:
my $nfa = fromExpr(element("a"));
ok $nfa->print("Element: a") eq <<END;
Element: a
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 1 undef undef\
END
ok $nfa->𝗶𝘀𝗙𝗶𝗻𝗮𝗹(2);
ok !$nfa->𝗶𝘀𝗙𝗶𝗻𝗮𝗹(0);
ok $nfa->parse(qw(a));
ok !$nfa->parse(qw(a b));
ok !$nfa->parse(qw(b));
ok !$nfa->parse(qw(b a));allTransitions($states)
Return all transitions in the NFA specified by $states as {stateName}{symbol} = [reachable states].
Parameter Description
1 $states StatesExample:
my $s = q(zeroOrMore(choice("a")));
my $nfa = eval qq(fromExpr(sequence($s,$s)));
is_deeply $nfa->print("a*"), <<END;
a*
Location F Transitions Jumps
0 1 undef [1 .. 4, 6 .. 9, 11]
1 1 undef [2, 3, 4, 6 .. 9, 11]
2 1 undef [3, 4, 6 .. 9, 11]
3 undef [4]
4 { a => 5 } undef
5 1 undef [2, 3, 4, 6 .. 9, 11]
6 1 undef [7, 8, 9, 11]
7 1 undef [8, 9, 11]
8 undef [9]
9 { a => 10 } undef
10 1 undef [7, 8, 9, 11]
11 1 undef undef
END
ok $nfa->parse(qw());
ok $nfa->parse(qw(a));
ok !$nfa->parse(qw(b));
ok $nfa->parse(qw(a a));
ok !$nfa->parse(qw(b b));
ok !$nfa->parse(qw(a b));
ok !$nfa->parse(qw(b a));
ok !$nfa->parse(qw(c));
is_deeply $nfa->𝗮𝗹𝗹𝗧𝗿𝗮𝗻𝘀𝗶𝘁𝗶𝗼𝗻𝘀, {
"0" => { a => [10, 11, 2 .. 9] },
"1" => { a => [10, 11, 2 .. 9] },
"2" => { a => [10, 11, 2 .. 9] },
"3" => { a => [11, 2 .. 9] },
"4" => { a => [11, 2 .. 9] },
"5" => { a => [10, 11, 2 .. 9] },
"6" => { a => [10, 11, 7, 8, 9] },
"7" => { a => [10, 11, 7, 8, 9] },
"8" => { a => [10, 11, 7, 8, 9] },
"9" => { a => [10, 11, 7, 8, 9] },
"10" => { a => [10, 11, 7, 8, 9] },
"11" => { a => [] },
};
is_deeply $nfa->print("a*a* 2"), <<END;
a*a* 2
Location F Transitions Jumps
0 1 undef [1 .. 4, 6 .. 9, 11]
1 1 undef [2, 3, 4, 6 .. 9, 11]
2 1 undef [3, 4, 6 .. 9, 11]
3 undef [4]
4 { a => 5 } undef
5 1 undef [2, 3, 4, 6 .. 9, 11]
6 1 undef [7, 8, 9, 11]
7 1 undef [8, 9, 11]
8 undef [9]
9 { a => 10 } undef
10 1 undef [7, 8, 9, 11]
11 1 undef undef
ENDparse($states, @symbols)
Parse, using the NFA specified by $states, the list of symbols in @symbols.
Parameter Description
1 $states States
2 @symbols Array of symbolsExample:
my $nfa = fromExpr(element("a"));
ok $nfa->print("Element: a") eq <<END;
Element: a
Location F Transitions Jumps
0 undef [1]
1 { a => 2 } undef
2 1 undef undef\
END
ok $nfa->isFinal(2);
ok !$nfa->isFinal(0);
ok $nfa->𝗽𝗮𝗿𝘀𝗲(qw(a));
ok !$nfa->𝗽𝗮𝗿𝘀𝗲(qw(a b));
ok !$nfa->𝗽𝗮𝗿𝘀𝗲(qw(b));
ok !$nfa->𝗽𝗮𝗿𝘀𝗲(qw(b a));Data::NFA::State Definition
NFA State
Output fields
final - Whether this state is final
jumps - {to => 1} : jumps from this state not consuming any input symbols
transitions - {symbol => state} : transitions from this state consuming one input symbol
Private Methods
newNfa(%options)
Create a new NFA
Parameter Description
1 %options OptionsnewNfaState(%options)
Create a new NFA state.
Parameter Description
1 %options OptionsaddNewState($nfa)
Create a new NFA state and add it to an NFA created with newNfa.
Parameter Description
1 $nfa NfafromExpr2($states, $expr, $symbols)
Create an NFA from a regular expression.
Parameter Description
1 $states States
2 $expr Regular expression constructed from L<element|/element> L<sequence|/sequence> L<optional|/optional> L<zeroOrMore|/zeroOrMore> L<oneOrMore|/oneOrMore> L<choice|/choice>
3 $symbols Set of symbols used by the NFA.propagateFinalState($states)
Mark the $states that can reach the final state with a jump as final.
Parameter Description
1 $states StatesstatesReachableViaJumps($states, $StateName)
Find the names of all the $states that can be reached from a specified $stateName via jumps alone.
Parameter Description
1 $states States
2 $StateName Name of start stateremoveEmptyFields($states)
Remove empty fields from the states representing an NFA.
Parameter Description
1 $states StatesprintFinalState($state)
Print the final field of the specified $state.
Parameter Description
1 $state StateprintWithJumps($states, $title)
Print the current $states of an NFA with jumps using the specvified $title.
Parameter Description
1 $states States
2 $title Optional titleprintWithOutJumps($states, $title)
Print the current $states of an NFA without jumps using the specified $title.
Parameter Description
1 $states States
2 $title Title.statesReachableViaSymbol($states, $StateName, $symbol, $cache)
Find the names of all the states that can be reached from a specified state via a specified symbol and all the jumps available.
Parameter Description
1 $states States
2 $StateName Name of start state
3 $symbol Symbol to reach on
4 $cache A hash to be used as a cacheparse2($states, $stateName, @symbols)
Parse an array of symbols
Parameter Description
1 $states States
2 $stateName Current state
3 @symbols Remaining symbolsIndex
1 addNewState - Create a new NFA state and add it to an NFA created with newNfa.
2 allTransitions - Return all transitions in the NFA specified by $states as {stateName}{symbol} = [reachable states].
3 choice - Choice from amongst one or more elements and/or symbols.
4 element - One element.
5 except - Choice from amongst all symbols except the ones mentioned
6 fromExpr - Create an NFA from a regular @expression.
7 fromExpr2 - Create an NFA from a regular expression.
8 isFinal - Whether, in the $states specifying an NFA the named state $state is a final state.
9 newNfa - Create a new NFA
10 newNfaState - Create a new NFA state.
11 oneOrMore - One or more repetitions of a sequence of elements and/or symbols.
12 optional - An optional sequence of elements and/or symbols.
13 parse - Parse, using the NFA specified by $states, the list of symbols in @symbols.
14 parse2 - Parse an array of symbols
15 print - Print the current $states of the non deterministic finite state automaton using the specified $title.
16 printFinalState - Print the final field of the specified $state.
17 printWithJumps - Print the current $states of an NFA with jumps using the specvified $title.
18 printWithOutJumps - Print the current $states of an NFA without jumps using the specified $title.
19 propagateFinalState - Mark the $states that can reach the final state with a jump as final.
20 removeEmptyFields - Remove empty fields from the states representing an NFA.
21 sequence - Sequence of elements and/or symbols.
22 statesReachableViaJumps - Find the names of all the $states that can be reached from a specified $stateName via jumps alone.
23 statesReachableViaSymbol - Find the names of all the states that can be reached from a specified state via a specified symbol and all the jumps available.
24 symbols - Return an array of all the transition symbols.
25 zeroOrMore - Zero or more repetitions of a sequence of elements and/or symbols.
Installation
This module is written in 100% Pure Perl and, thus, it is easy to read, comprehend, use, modify and install via cpan:
sudo cpan install Data::NFAAuthor
Copyright
Copyright (c) 2016-2019 Philip R Brenan.
This module is free software. It may be used, redistributed and/or modified under the same terms as Perl itself.