# NFA backtracking

The various engines seem to first construct (or "compile") an NFA from the regular expression, then execute the NFA, following transitions from state to state, and backtracking to a previous state when a route fails. *Please note:* the backtracking is done on the NFA, not on the regular expression.

An **NFA** is a kind of automata, with a graph of nodes (states) connected by directed arcs (transitions). An arc is labeled with a character; when that character is seen in the text, that arc is followed. An NFA is a *Non-deterministic Finite Automata* - the "non-deterministic" part means that two arcs leaving a node can have the same label, so that both are followed simultaneously. There can also be *epsilon* transitions (ε, representing the empty string - no character), which are always followed without needing a input character.

**Backtracking** means when we come to a choice, we checkpoint the state (where we are in the automata and in the text). Then, make a choice. If it doesn't work out, we revert or "backtrack" to that checkpoint, and tnry the next choice. Like navigating a cave, when might go deeper and deeper through a series of forks before we hit a dead-end, "nesting" the checkpoints.

# Java source code analysis

### Constructing NFA

The process for contructing an NFA from a regular expression is called "Thompson's construction". For details, please see MJD article or Regular Expression Matching Can Be Simple And Fast (about 1/5 the way through, section "Converting Regular Expressions to NFAs"). There's also a wikipedia article
Thompson's construction.

Java's implementation (`java/util/regex/Pattern.java`

)
recursively-descent parses the regular expression, with methods *expr()* (alternation `|`

), *sequence()*, *atom()*, *closure()* (optional `?`

and star `*`

), generating the NFA as *Node* objects with a *next* field for the transition to another *Node*. There are many, many different *Node* subclasses.

notes: (1) *expr()* calls *sequence()* which returns with a so-called "double return" - it returns *head* explicitly, and *tail* via a global field *root*; in effect a *(head, tail)* tuple.
(2) There is no *Sequence* object; instead, the objects in a sequence have form a linked list, with their *next* fields.

### Executing

**transitions**
The NFA is traversed with *match()* methods. The *match* method on one *Node* subclass calls *match()* method on the *next* one, so that the path through the automaton is a recursive call. The last node is a *LastNode* object, that checks that the whole of the text has been used.

**checkpointing**
The arguments of *match()* includes an index *i* into the text. It also has an implicit argument of the object it is called on. Together, this index and object represent the present state, and the *matvch()* invocation effectively checkpoints it, so we can *backtrack* to it later.

**backtracking**
The method *match* returns a *boolean*, of whether the match succeeded or not. If *true*, the returns chain all the way back to the initial call (popping off all the checkpoints, as if quickly retracing our steps back). But if *false* (due to a character not matching; or running out of text; or reaching the `LastNode`

while there's still text left), backtracking occurs.

The simplest backtracking is *alternation*. The code, in *Branch.match* (line 4599 of above source) tries the first choice; if it fails, troies the second choice; and so on. If all choices fail, return *false*.

# ELI5 pedagogical implementation

Although the java implementation is may be the simplest of the engines, because least optimized, it is still very complex! There are many *PCRE* features, it handles unicode, many explicit optimizations (e.g. *Boyer-Moore* substring matching), but also many minor optimizations in the flow of the code itself, making it hard to learn from. Therefore, following is an *ELI5* simplification, using only *sequence* and *alternation* (i.e. not even *star* or *optional*, so not actually regular expressions).

```
public class MyPattern {
public static void main(String[] args) {
// ab|ac // non-deterministic
Node eg =
new Branch(
new Sequence( new Single('a'), new Single('b') ),
new Sequence( new Single('a'), new Single('c') )
);
re = new Sequence(re, new LastNode());
System.out.println( re.match(0, "ac") );
}
abstract static class Node {
abstract void setNext(Node next);
abstract boolean match(int i, String s);
}
static class LastNode extends Node {
void setNext(Node next){ throw new RuntimeException("don't call me"); }
boolean match(int i, String s) {
return i==s.length();
}
}
static class Single extends Node {
Node next;
char ch;
Single(char ch) { this.ch = ch; }
void setNext(Node next) { this.next = next; }
boolean match(int i, String s) {
return i<s.length()&& s.charAt(i)==ch&& next.match(i+1, s);
}
}
static class Branch extends Node {
Node left, right;
Branch(Node l, Node r) { this.left=l; this.right=r; }
void setNext(Node next) {
left.setNext(next);
right.setNext(next);
}
boolean match(int i, String s) {
return left.match(i, s) || right.match(i, s);
}
}
static class Sequence extends Node {
Node left, right;
Sequence(Node l, Node r) {
this.left=l;
this.right=r;
left.setNext(right);
}
void setNext(Node next) { right.setNext(next); }
boolean match(int i, String s) {
return left.match(i, s);
}
}
}
```

# Proof

To be proven: the above code parses a subset of regular expressions (i.e. without *star* or *optional*). In the following "regular expression" has this restricted meaning.

First we'll prove the constructed NFA from a regular expression is equivalent; then, that the code constructs an equivalent NFA; and finally that backtracking parsing is equivalent to that.

### Proof: regular expression to NFA

We'll begin by proving the plain regular-expression-to-NFA conversion is correct.

**define regular expression**
The standard definition of the meaning of a regular expression is in terms of the *set of words* it generates (not what it parses). This set is called a *language*, and we say *L(R)* is the language of regular expression *R*.

It's very useful to be able to express every possible regular expression in the same way (as a language), because then we can ignore the details of the actual regular expression that generated it.

**literal **`a`

: *L(*`a`

) -> {a} - gives the set of that single-letter word

**alternation:** *L(A|B) -> L(A) U L(B)* - whenever two regular expressions *A* and *B* are or-ed together, we can easily work out the language produced. Assuming we know the language of each of the expressions, both can be generated, so the resulting language is just the union of their languages.

**sequence:** *L(AB) -> L(A) X L(B)* - the *X* means all combinations of: a word in *L(A)* followed by a word in *L(B)*.

The language of a regular expression can be built up by finding the languages of the operations forming it (following an abstract syntax tree).

**to NFA**
The NFA of regular expression *A* is notated as *N(A)*. A word generated is the sequence of characters encountered by following a path of transitions through an NFA from the start node to the exit node. Its language *L(N(A))* is the set of all such words it can generate, by following all paths.

Defining it as a language enables us to compare NFAs with regular expressions.

The possible paths through this are: from the start node (on the left), any path can be taken through *N(A)* to the middle node; then, any path can be taken through *N(B)* to the exit node on the right. This produces the same language as *L(AB) = L(A) X L(B)*

(We assume that *A* and *B* have already been done correctly i.e. *L(N(A))=L(A)* and *L(N(B))=L(A)*).

**alternation:** The NFA for *A|B* is constructed by combining the start nodes of *N(A)* and *N(B)*, and the exit nodes of *N(A)* and *N(B)*:

```
_______
/ N(A) \
O >O
\_______/
N(B)
```

This combines the possible paths, just as *L(A|B) -> L(A) U L(B)*, and so the same language is produced: *L(N(A|B)) = L(A|B)*.

(Again, we assume that *A* and *B* have already been done correctly, *L(N(A))=L(A)* and *L(N(B))=L(A)*).

The set of words produced by all possible paths through this NFA is simply *{a}* - the set of just the one, single-letter word *a*. This is the same as for the regular expression `a`

, or *L(N(a)) = {a} = L(a)*.

In summary, as we build up the NFA from the regular expression, operator by operator, the language of the NFA is the same as the regular expression at each step of the way.

### Proof: code constructs NFA

To prove that the code above constructs the NFA, we'll first prove that that the method *setNext()* sets all the last arc out of the NFA.

**lemma: setNext() sets all exit arcs**
A *Node* object represents a node in an NFA. The *exit arcs* are all transitions to the NFA's exit node. In the code, these are represented by the *next* field referencing another node. We want to show that calling method *setNext()* will set all such exit arcs.

**sequence:** The exit arcs of NFA *N(AB)* are the exit arcs of *N(B)* (as all arcs from *N(A)* go to *N(B)*, not to the exit node).

For a **Sequence** object (representing *N(AB)*), calling *right.setNext()* sets all its exit arcs, assuming the *setNext()* method of the component node *right* (representing *N(B)*) works correctly.

**alternation:** The exit arcs of NFA *N(A|B)* is the union of the exit arcs of *N(A)* and *N(B)*.

For a **Branch** object (representing *N(A|B)*), calling both *left.setNext()* and *right.setNext()* sets all its exit arcs, again assuming those methods work correctly (on the *left* and *right* nodes, representing *N(A)* and *N(B)*).

**literal **`a`

: The exit arc of NFA *N(a)* is simply the one arc labeled *a*.

For a **Single** object (representing *N(a)*), setting the field *next* sets its exit arc.

Combining the above three, calling *setNode* on a *Node* object will set all exit arcs.

**Proof: code constructs NFA**
To prove this without the complication of parsing and backtracking, we won't use *match()* yet, but add a new method *gen()* that prints out the language of the NFA.

In the code, a transition from one *Node* object to another is represented by the first calling a method on the second. The transfer of control to another *Node* object represents the transition to another node.

**sequence:** In a **Sequence** object, the entry arcs should connect to the *left* node. This is done by the method *gen()* calling *left.gen()*.

In the constructor, the exit arcs of the *left* node are connected to the *right* node by calling *left.setNext(right)*. This is where *setNode()* calls originate, because a sequence is the only place where the concept of "following" is specified.

note: *Sequence* acts as scaffolding to assemble the NFA, and after passing control to the *left* node has no further riole.

**alternation:** In a **Branch** object, the entry arcs are connected to both the *left* and *right* nodes, by *gen()* calls both *left.gen()* and *right.gen()*.

**literal:** In a **Single** node, control is transitioned to the next node with *next.gen()*.

After the expression is constructed, all exit arcs are connected to a *LastNode* object by added as a sequence: *new Sequence(re, new LastNode())*.

Here are the *gen()* methods. They record the literal character encountered in the path of transitions, and are print when control reaches the *LastNode*.

```
abstract Node:
abstract void gen(String path);
LastNode:
void gen(String path) { System.out.println(path); }
Single:
void gen(String path) { next.gen(path+ch); }
Branch:
void gen(String path) { left.gen(path); right.gen(path); }
Sequence:
void gen(String path) { left.gen(path); }
```

Thus, calling *gen("")* on a *Node* object will print out its language.

# Parsing and Backtracking

In a sense, the method *gen()* above always "backtracks" at *Branch*, because it first recurses into the *left* node, and when that returns, the state is restored: we are back to the same *Branch* object, that respresents the NFA node, and the state of the word generated is also what it was before the *left* recursion. When it recurses into the *right* node, it is as if for the first time.

The change for "backtracking" in the method *match* is simply to not continue recursing if the sought word is already generated. This does not change which words are accepted.

The change for parsing is to check the word character by character, and to abandon an avenue when a character does not match, instead of continuing all the way to the *LastNode*. One way for a character to "not match" is to not exist i.e. when the text is too short. This is the *i < s.length()* check in *Single.match()*.

Conversely, there could be too many characters in the text. This is addressed by *LastNode.match()* checking that all characters in the text have been read, with *i==s.length()*.