Renamed 'State' to 'state' to avoid exposing the insides of the engine

regex/nfa.go

@@ -22,18 +22,18 @@ const (
 	alwaysTrueAssert // An assertion that is always true
 )
 
-type State struct {
+type state struct {
 	content                    stateContents    // Contents of current state
 	isEmpty                    bool             // If it is empty - Union operator and Kleene star states will be empty
 	isLast                     bool             // If it is the last state (acept state)
-	output                     []*State         // The outputs of the current state ie. the 'outward arrows'. A union operator state will have more than one of these.
-	transitions                map[int][]*State // Transitions to different states (maps a character (int representation) to a _list of states. This is useful if one character can lead multiple states eg. ab|aa)
+	output                     []*state         // The outputs of the current state ie. the 'outward arrows'. A union operator state will have more than one of these.
+	transitions                map[int][]*state // Transitions to different states (maps a character (int representation) to a _list of states. This is useful if one character can lead multiple states eg. ab|aa)
 	isKleene                   bool             // Identifies whether current node is a 0-state representing Kleene star
 	assert                     assertType       // Type of assertion of current node - NONE means that the node doesn't assert anything
 	allChars                   bool             // Whether or not the state represents all characters (eg. a 'dot' metacharacter). A 'dot' node doesn't store any contents directly, as it would take up too much space
 	except                     []rune           // Only valid if allChars is true - match all characters _except_ the ones in this block. Useful for inverting character classes.
 	lookaroundRegex            string           // Only for lookaround states - Contents of the regex that the lookaround state holds
-	lookaroundNFA              *State           // Holds the NFA of the lookaroundRegex - if it exists
+	lookaroundNFA              *state           // Holds the NFA of the lookaroundRegex - if it exists
 	lookaroundNumCaptureGroups int              // Number of capturing groups in lookaround regex if current node is a lookaround
 	groupBegin                 bool             // Whether or not the node starts a capturing group
 	groupEnd                   bool             // Whether or not the node ends a capturing group
@@ -44,14 +44,14 @@ type State struct {
 }
 
 // Clones the NFA starting from the given state.
-func cloneState(start *State) *State {
-	return cloneStateHelper(start, make(map[*State]*State))
+func cloneState(start *state) *state {
+	return cloneStateHelper(start, make(map[*state]*state))
 }
 
 // Helper function for clone. The map is used to keep track of which states have
 // already been copied, and which ones haven't.
 // This function was created using output from Llama3.1:405B.
-func cloneStateHelper(stateToClone *State, cloneMap map[*State]*State) *State {
+func cloneStateHelper(stateToClone *state, cloneMap map[*state]*state) *state {
 	// Base case - if the clone exists in our map, return it.
 	if clone, exists := cloneMap[stateToClone]; exists {
 		return clone
@@ -61,12 +61,12 @@ func cloneStateHelper(stateToClone *State, cloneMap map[*State]*State) *State {
 	}
 	// Recursive case - if the clone doesn't exist, create it, add it to the map,
 	// and recursively call for each of the transition states.
-	clone := &State{
+	clone := &state{
 		content:         append([]int{}, stateToClone.content...),
 		isEmpty:         stateToClone.isEmpty,
 		isLast:          stateToClone.isLast,
-		output:          make([]*State, len(stateToClone.output)),
-		transitions:     make(map[int][]*State),
+		output:          make([]*state, len(stateToClone.output)),
+		transitions:     make(map[int][]*state),
 		isKleene:        stateToClone.isKleene,
 		assert:          stateToClone.assert,
 		zeroMatchFound:  stateToClone.zeroMatchFound,
@@ -86,7 +86,7 @@ func cloneStateHelper(stateToClone *State, cloneMap map[*State]*State) *State {
 		}
 	}
 	for k, v := range stateToClone.transitions {
-		clone.transitions[k] = make([]*State, len(v))
+		clone.transitions[k] = make([]*state, len(v))
 		for i, s := range v {
 			if s == stateToClone {
 				clone.transitions[k][i] = clone
@@ -104,7 +104,7 @@ func cloneStateHelper(stateToClone *State, cloneMap map[*State]*State) *State {
 
 // Checks if the given state's assertion is true. Returns true if the given
 // state doesn't have an assertion.
-func (s State) checkAssertion(str []rune, idx int) bool {
+func (s state) checkAssertion(str []rune, idx int) bool {
 	if s.assert == alwaysTrueAssert {
 		return true
 	}
@@ -171,7 +171,7 @@ func (s State) checkAssertion(str []rune, idx int) bool {
 }
 
 // Returns true if the contents of 's' contain the value at the given index of the given string
-func (s State) contentContains(str []rune, idx int) bool {
+func (s state) contentContains(str []rune, idx int) bool {
 	if s.assert != noneAssert {
 		return s.checkAssertion(str, idx)
 	}
@@ -182,19 +182,19 @@ func (s State) contentContains(str []rune, idx int) bool {
 	return slices.Contains(s.content, int(str[idx]))
 }
 
-func (s State) isLookaround() bool {
+func (s state) isLookaround() bool {
 	return s.assert == plaAssert || s.assert == plbAssert || s.assert == nlaAssert || s.assert == nlbAssert
 }
 
 // Returns the matches for the character at the given index of the given string.
 // Also returns the number of matches. Returns -1 if an assertion failed.
-func (s State) matchesFor(str []rune, idx int) ([]*State, int) {
+func (s state) matchesFor(str []rune, idx int) ([]*state, int) {
 	// Assertions can be viewed as 'checks'. If the check fails, we return
 	// an empty array and 0.
 	// If it passes, we treat it like any other state, and return all the transitions.
 	if s.assert != noneAssert {
 		if s.checkAssertion(str, idx) == false {
-			return make([]*State, 0), -1
+			return make([]*state, 0), -1
 		}
 	}
 	listTransitions := s.transitions[int(str[idx])]
@@ -211,39 +211,39 @@ func (s State) matchesFor(str []rune, idx int) ([]*State, int) {
 }
 
 // verifyLastStatesHelper performs the depth-first recursion needed for verifyLastStates
-func verifyLastStatesHelper(state *State, visited map[*State]bool) {
-	if len(state.transitions) == 0 {
-		state.isLast = true
+func verifyLastStatesHelper(st *state, visited map[*state]bool) {
+	if len(st.transitions) == 0 {
+		st.isLast = true
 		return
 	}
 	//	if len(state.transitions) == 1 && len(state.transitions[state.content]) == 1 && state.transitions[state.content][0] == state { // Eg. a*
-	if len(state.transitions) == 1 { // Eg. a*
+	if len(st.transitions) == 1 { // Eg. a*
 		var moreThanOneTrans bool // Dummy variable, check if all the transitions for the current's state's contents have a length of one
-		for _, c := range state.content {
-			if len(state.transitions[c]) != 1 || state.transitions[c][0] != state {
+		for _, c := range st.content {
+			if len(st.transitions[c]) != 1 || st.transitions[c][0] != st {
 				moreThanOneTrans = true
 			}
 		}
-		state.isLast = !moreThanOneTrans
+		st.isLast = !moreThanOneTrans
 	}
 
-	if state.isKleene { // A State representing a Kleene Star has transitions going out, which loop back to it. If all those transitions point to the same (single) state, then it must be a last state
-		transitionDests := make([]*State, 0)
-		for _, v := range state.transitions {
+	if st.isKleene { // A State representing a Kleene Star has transitions going out, which loop back to it. If all those transitions point to the same (single) state, then it must be a last state
+		transitionDests := make([]*state, 0)
+		for _, v := range st.transitions {
 			transitionDests = append(transitionDests, v...)
 		}
 		if allEqual(transitionDests...) {
-			state.isLast = true
+			st.isLast = true
 			return
 		}
 	}
-	if visited[state] == true {
+	if visited[st] == true {
 		return
 	}
-	visited[state] = true
-	for _, states := range state.transitions {
+	visited[st] = true
+	for _, states := range st.transitions {
 		for i := range states {
-			if states[i] != state {
+			if states[i] != st {
 				verifyLastStatesHelper(states[i], visited)
 			}
 		}
@@ -251,12 +251,12 @@ func verifyLastStatesHelper(state *State, visited map[*State]bool) {
 }
 
 // verifyLastStates enables the 'isLast' flag for the leaf nodes (last states)
-func verifyLastStates(start []*State) {
-	verifyLastStatesHelper(start[0], make(map[*State]bool))
+func verifyLastStates(start []*state) {
+	verifyLastStatesHelper(start[0], make(map[*state]bool))
 }
 
 // Concatenates s1 and s2, returns the start of the concatenation.
-func concatenate(s1 *State, s2 *State) *State {
+func concatenate(s1 *state, s2 *state) *state {
 	if s1 == nil {
 		return s2
 	}
@@ -269,13 +269,13 @@ func concatenate(s1 *State, s2 *State) *State {
 	return s1
 }
 
-func kleene(s1 State) (*State, error) {
+func kleene(s1 state) (*state, error) {
 	if s1.isEmpty && s1.assert != noneAssert {
 		return nil, fmt.Errorf("previous token is not quantifiable")
 	}
 
-	toReturn := &State{}
-	toReturn.transitions = make(map[int][]*State)
+	toReturn := &state{}
+	toReturn.transitions = make(map[int][]*state)
 	toReturn.content = newContents(EPSILON)
 	toReturn.isEmpty = true
 	toReturn.isKleene = true
@@ -291,9 +291,9 @@ func kleene(s1 State) (*State, error) {
 	return toReturn, nil
 }
 
-func alternate(s1 *State, s2 *State) *State {
-	toReturn := &State{}
-	toReturn.transitions = make(map[int][]*State)
+func alternate(s1 *state, s2 *state) *state {
+	toReturn := &state{}
+	toReturn.transitions = make(map[int][]*state)
 	toReturn.output = append(toReturn.output, s1.output...)
 	toReturn.output = append(toReturn.output, s2.output...)
 	// Unique append is used here (and elsewhere) to ensure that,
@@ -313,9 +313,9 @@ func alternate(s1 *State, s2 *State) *State {
 	return toReturn
 }
 
-func question(s1 *State) *State { // Use the fact that ab? == a(b|)
-	s2 := &State{}
-	s2.transitions = make(map[int][]*State)
+func question(s1 *state) *state { // Use the fact that ab? == a(b|)
+	s2 := &state{}
+	s2.transitions = make(map[int][]*state)
 	s2.content = newContents(EPSILON)
 	s2.output = append(s2.output, s2)
 	s2.isEmpty = true
@@ -324,10 +324,10 @@ func question(s1 *State) *State { // Use the fact that ab? == a(b|)
 }
 
 // Creates and returns a new state with the 'default' values.
-func newState() State {
-	ret := State{
-		output:          make([]*State, 0),
-		transitions:     make(map[int][]*State),
+func newState() state {
+	ret := state{
+		output:          make([]*state, 0),
+		transitions:     make(map[int][]*state),
 		assert:          noneAssert,
 		except:          append([]rune{}, 0),
 		lookaroundRegex: "",
@@ -339,7 +339,7 @@ func newState() State {
 }
 
 // Creates and returns a state that _always_ has a zero-length match.
-func zeroLengthMatchState() State {
+func zeroLengthMatchState() state {
 	start := newState()
 	start.content = newContents(EPSILON)
 	start.isEmpty = true