ceph-csi/vendor/github.com/antlr4-go/antlr/v4/atn_deserializer.go

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// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
// Use of this file is governed by the BSD 3-clause license that
// can be found in the LICENSE.txt file in the project root.
package antlr
import (
"fmt"
"strconv"
)
const serializedVersion = 4
type loopEndStateIntPair struct {
item0 *LoopEndState
item1 int
}
type blockStartStateIntPair struct {
item0 BlockStartState
item1 int
}
type ATNDeserializer struct {
options *ATNDeserializationOptions
data []int32
pos int
}
func NewATNDeserializer(options *ATNDeserializationOptions) *ATNDeserializer {
if options == nil {
options = &defaultATNDeserializationOptions
}
return &ATNDeserializer{options: options}
}
//goland:noinspection GoUnusedFunction
func stringInSlice(a string, list []string) int {
for i, b := range list {
if b == a {
return i
}
}
return -1
}
func (a *ATNDeserializer) Deserialize(data []int32) *ATN {
a.data = data
a.pos = 0
a.checkVersion()
atn := a.readATN()
a.readStates(atn)
a.readRules(atn)
a.readModes(atn)
sets := a.readSets(atn, nil)
a.readEdges(atn, sets)
a.readDecisions(atn)
a.readLexerActions(atn)
a.markPrecedenceDecisions(atn)
a.verifyATN(atn)
if a.options.GenerateRuleBypassTransitions() && atn.grammarType == ATNTypeParser {
a.generateRuleBypassTransitions(atn)
// Re-verify after modification
a.verifyATN(atn)
}
return atn
}
func (a *ATNDeserializer) checkVersion() {
version := a.readInt()
if version != serializedVersion {
panic("Could not deserialize ATN with version " + strconv.Itoa(version) + " (expected " + strconv.Itoa(serializedVersion) + ").")
}
}
func (a *ATNDeserializer) readATN() *ATN {
grammarType := a.readInt()
maxTokenType := a.readInt()
return NewATN(grammarType, maxTokenType)
}
func (a *ATNDeserializer) readStates(atn *ATN) {
nstates := a.readInt()
// Allocate worst case size.
loopBackStateNumbers := make([]loopEndStateIntPair, 0, nstates)
endStateNumbers := make([]blockStartStateIntPair, 0, nstates)
// Preallocate states slice.
atn.states = make([]ATNState, 0, nstates)
for i := 0; i < nstates; i++ {
stype := a.readInt()
// Ignore bad types of states
if stype == ATNStateInvalidType {
atn.addState(nil)
continue
}
ruleIndex := a.readInt()
s := a.stateFactory(stype, ruleIndex)
if stype == ATNStateLoopEnd {
loopBackStateNumber := a.readInt()
loopBackStateNumbers = append(loopBackStateNumbers, loopEndStateIntPair{s.(*LoopEndState), loopBackStateNumber})
} else if s2, ok := s.(BlockStartState); ok {
endStateNumber := a.readInt()
endStateNumbers = append(endStateNumbers, blockStartStateIntPair{s2, endStateNumber})
}
atn.addState(s)
}
// Delay the assignment of loop back and end states until we know all the state
// instances have been initialized
for _, pair := range loopBackStateNumbers {
pair.item0.loopBackState = atn.states[pair.item1]
}
for _, pair := range endStateNumbers {
pair.item0.setEndState(atn.states[pair.item1].(*BlockEndState))
}
numNonGreedyStates := a.readInt()
for j := 0; j < numNonGreedyStates; j++ {
stateNumber := a.readInt()
atn.states[stateNumber].(DecisionState).setNonGreedy(true)
}
numPrecedenceStates := a.readInt()
for j := 0; j < numPrecedenceStates; j++ {
stateNumber := a.readInt()
atn.states[stateNumber].(*RuleStartState).isPrecedenceRule = true
}
}
func (a *ATNDeserializer) readRules(atn *ATN) {
nrules := a.readInt()
if atn.grammarType == ATNTypeLexer {
atn.ruleToTokenType = make([]int, nrules)
}
atn.ruleToStartState = make([]*RuleStartState, nrules)
for i := range atn.ruleToStartState {
s := a.readInt()
startState := atn.states[s].(*RuleStartState)
atn.ruleToStartState[i] = startState
if atn.grammarType == ATNTypeLexer {
tokenType := a.readInt()
atn.ruleToTokenType[i] = tokenType
}
}
atn.ruleToStopState = make([]*RuleStopState, nrules)
for _, state := range atn.states {
if s2, ok := state.(*RuleStopState); ok {
atn.ruleToStopState[s2.ruleIndex] = s2
atn.ruleToStartState[s2.ruleIndex].stopState = s2
}
}
}
func (a *ATNDeserializer) readModes(atn *ATN) {
nmodes := a.readInt()
atn.modeToStartState = make([]*TokensStartState, nmodes)
for i := range atn.modeToStartState {
s := a.readInt()
atn.modeToStartState[i] = atn.states[s].(*TokensStartState)
}
}
func (a *ATNDeserializer) readSets(_ *ATN, sets []*IntervalSet) []*IntervalSet {
m := a.readInt()
// Preallocate the needed capacity.
if cap(sets)-len(sets) < m {
isets := make([]*IntervalSet, len(sets), len(sets)+m)
copy(isets, sets)
sets = isets
}
for i := 0; i < m; i++ {
iset := NewIntervalSet()
sets = append(sets, iset)
n := a.readInt()
containsEOF := a.readInt()
if containsEOF != 0 {
iset.addOne(-1)
}
for j := 0; j < n; j++ {
i1 := a.readInt()
i2 := a.readInt()
iset.addRange(i1, i2)
}
}
return sets
}
func (a *ATNDeserializer) readEdges(atn *ATN, sets []*IntervalSet) {
nedges := a.readInt()
for i := 0; i < nedges; i++ {
var (
src = a.readInt()
trg = a.readInt()
ttype = a.readInt()
arg1 = a.readInt()
arg2 = a.readInt()
arg3 = a.readInt()
trans = a.edgeFactory(atn, ttype, src, trg, arg1, arg2, arg3, sets)
srcState = atn.states[src]
)
srcState.AddTransition(trans, -1)
}
// Edges for rule stop states can be derived, so they are not serialized
for _, state := range atn.states {
for _, t := range state.GetTransitions() {
var rt, ok = t.(*RuleTransition)
if !ok {
continue
}
outermostPrecedenceReturn := -1
if atn.ruleToStartState[rt.getTarget().GetRuleIndex()].isPrecedenceRule {
if rt.precedence == 0 {
outermostPrecedenceReturn = rt.getTarget().GetRuleIndex()
}
}
trans := NewEpsilonTransition(rt.followState, outermostPrecedenceReturn)
atn.ruleToStopState[rt.getTarget().GetRuleIndex()].AddTransition(trans, -1)
}
}
for _, state := range atn.states {
if s2, ok := state.(BlockStartState); ok {
// We need to know the end state to set its start state
if s2.getEndState() == nil {
panic("IllegalState")
}
// Block end states can only be associated to a single block start state
if s2.getEndState().startState != nil {
panic("IllegalState")
}
s2.getEndState().startState = state
}
if s2, ok := state.(*PlusLoopbackState); ok {
for _, t := range s2.GetTransitions() {
if t2, ok := t.getTarget().(*PlusBlockStartState); ok {
t2.loopBackState = state
}
}
} else if s2, ok := state.(*StarLoopbackState); ok {
for _, t := range s2.GetTransitions() {
if t2, ok := t.getTarget().(*StarLoopEntryState); ok {
t2.loopBackState = state
}
}
}
}
}
func (a *ATNDeserializer) readDecisions(atn *ATN) {
ndecisions := a.readInt()
for i := 0; i < ndecisions; i++ {
s := a.readInt()
decState := atn.states[s].(DecisionState)
atn.DecisionToState = append(atn.DecisionToState, decState)
decState.setDecision(i)
}
}
func (a *ATNDeserializer) readLexerActions(atn *ATN) {
if atn.grammarType == ATNTypeLexer {
count := a.readInt()
atn.lexerActions = make([]LexerAction, count)
for i := range atn.lexerActions {
actionType := a.readInt()
data1 := a.readInt()
data2 := a.readInt()
atn.lexerActions[i] = a.lexerActionFactory(actionType, data1, data2)
}
}
}
func (a *ATNDeserializer) generateRuleBypassTransitions(atn *ATN) {
count := len(atn.ruleToStartState)
for i := 0; i < count; i++ {
atn.ruleToTokenType[i] = atn.maxTokenType + i + 1
}
for i := 0; i < count; i++ {
a.generateRuleBypassTransition(atn, i)
}
}
func (a *ATNDeserializer) generateRuleBypassTransition(atn *ATN, idx int) {
bypassStart := NewBasicBlockStartState()
bypassStart.ruleIndex = idx
atn.addState(bypassStart)
bypassStop := NewBlockEndState()
bypassStop.ruleIndex = idx
atn.addState(bypassStop)
bypassStart.endState = bypassStop
atn.defineDecisionState(&bypassStart.BaseDecisionState)
bypassStop.startState = bypassStart
var excludeTransition Transition
var endState ATNState
if atn.ruleToStartState[idx].isPrecedenceRule {
// Wrap from the beginning of the rule to the StarLoopEntryState
endState = nil
for i := 0; i < len(atn.states); i++ {
state := atn.states[i]
if a.stateIsEndStateFor(state, idx) != nil {
endState = state
excludeTransition = state.(*StarLoopEntryState).loopBackState.GetTransitions()[0]
break
}
}
if excludeTransition == nil {
panic("Couldn't identify final state of the precedence rule prefix section.")
}
} else {
endState = atn.ruleToStopState[idx]
}
// All non-excluded transitions that currently target end state need to target
// blockEnd instead
for i := 0; i < len(atn.states); i++ {
state := atn.states[i]
for j := 0; j < len(state.GetTransitions()); j++ {
transition := state.GetTransitions()[j]
if transition == excludeTransition {
continue
}
if transition.getTarget() == endState {
transition.setTarget(bypassStop)
}
}
}
// All transitions leaving the rule start state need to leave blockStart instead
ruleToStartState := atn.ruleToStartState[idx]
count := len(ruleToStartState.GetTransitions())
for count > 0 {
bypassStart.AddTransition(ruleToStartState.GetTransitions()[count-1], -1)
ruleToStartState.SetTransitions([]Transition{ruleToStartState.GetTransitions()[len(ruleToStartState.GetTransitions())-1]})
}
// Link the new states
atn.ruleToStartState[idx].AddTransition(NewEpsilonTransition(bypassStart, -1), -1)
bypassStop.AddTransition(NewEpsilonTransition(endState, -1), -1)
MatchState := NewBasicState()
atn.addState(MatchState)
MatchState.AddTransition(NewAtomTransition(bypassStop, atn.ruleToTokenType[idx]), -1)
bypassStart.AddTransition(NewEpsilonTransition(MatchState, -1), -1)
}
func (a *ATNDeserializer) stateIsEndStateFor(state ATNState, idx int) ATNState {
if state.GetRuleIndex() != idx {
return nil
}
if _, ok := state.(*StarLoopEntryState); !ok {
return nil
}
maybeLoopEndState := state.GetTransitions()[len(state.GetTransitions())-1].getTarget()
if _, ok := maybeLoopEndState.(*LoopEndState); !ok {
return nil
}
var _, ok = maybeLoopEndState.GetTransitions()[0].getTarget().(*RuleStopState)
if maybeLoopEndState.(*LoopEndState).epsilonOnlyTransitions && ok {
return state
}
return nil
}
// markPrecedenceDecisions analyzes the StarLoopEntryState states in the
// specified ATN to set the StarLoopEntryState.precedenceRuleDecision field to
// the correct value.
func (a *ATNDeserializer) markPrecedenceDecisions(atn *ATN) {
for _, state := range atn.states {
if _, ok := state.(*StarLoopEntryState); !ok {
continue
}
// We analyze the [ATN] to determine if an ATN decision state is the
// decision for the closure block that determines whether a
// precedence rule should continue or complete.
if atn.ruleToStartState[state.GetRuleIndex()].isPrecedenceRule {
maybeLoopEndState := state.GetTransitions()[len(state.GetTransitions())-1].getTarget()
if s3, ok := maybeLoopEndState.(*LoopEndState); ok {
var _, ok2 = maybeLoopEndState.GetTransitions()[0].getTarget().(*RuleStopState)
if s3.epsilonOnlyTransitions && ok2 {
state.(*StarLoopEntryState).precedenceRuleDecision = true
}
}
}
}
}
func (a *ATNDeserializer) verifyATN(atn *ATN) {
if !a.options.VerifyATN() {
return
}
// Verify assumptions
for _, state := range atn.states {
if state == nil {
continue
}
a.checkCondition(state.GetEpsilonOnlyTransitions() || len(state.GetTransitions()) <= 1, "")
switch s2 := state.(type) {
case *PlusBlockStartState:
a.checkCondition(s2.loopBackState != nil, "")
case *StarLoopEntryState:
a.checkCondition(s2.loopBackState != nil, "")
a.checkCondition(len(s2.GetTransitions()) == 2, "")
switch s2.transitions[0].getTarget().(type) {
case *StarBlockStartState:
_, ok := s2.transitions[1].getTarget().(*LoopEndState)
a.checkCondition(ok, "")
a.checkCondition(!s2.nonGreedy, "")
case *LoopEndState:
var _, ok = s2.transitions[1].getTarget().(*StarBlockStartState)
a.checkCondition(ok, "")
a.checkCondition(s2.nonGreedy, "")
default:
panic("IllegalState")
}
case *StarLoopbackState:
a.checkCondition(len(state.GetTransitions()) == 1, "")
var _, ok = state.GetTransitions()[0].getTarget().(*StarLoopEntryState)
a.checkCondition(ok, "")
case *LoopEndState:
a.checkCondition(s2.loopBackState != nil, "")
case *RuleStartState:
a.checkCondition(s2.stopState != nil, "")
case BlockStartState:
a.checkCondition(s2.getEndState() != nil, "")
case *BlockEndState:
a.checkCondition(s2.startState != nil, "")
case DecisionState:
a.checkCondition(len(s2.GetTransitions()) <= 1 || s2.getDecision() >= 0, "")
default:
var _, ok = s2.(*RuleStopState)
a.checkCondition(len(s2.GetTransitions()) <= 1 || ok, "")
}
}
}
func (a *ATNDeserializer) checkCondition(condition bool, message string) {
if !condition {
if message == "" {
message = "IllegalState"
}
panic(message)
}
}
func (a *ATNDeserializer) readInt() int {
v := a.data[a.pos]
a.pos++
return int(v) // data is 32 bits but int is at least that big
}
func (a *ATNDeserializer) edgeFactory(atn *ATN, typeIndex, _, trg, arg1, arg2, arg3 int, sets []*IntervalSet) Transition {
target := atn.states[trg]
switch typeIndex {
case TransitionEPSILON:
return NewEpsilonTransition(target, -1)
case TransitionRANGE:
if arg3 != 0 {
return NewRangeTransition(target, TokenEOF, arg2)
}
return NewRangeTransition(target, arg1, arg2)
case TransitionRULE:
return NewRuleTransition(atn.states[arg1], arg2, arg3, target)
case TransitionPREDICATE:
return NewPredicateTransition(target, arg1, arg2, arg3 != 0)
case TransitionPRECEDENCE:
return NewPrecedencePredicateTransition(target, arg1)
case TransitionATOM:
if arg3 != 0 {
return NewAtomTransition(target, TokenEOF)
}
return NewAtomTransition(target, arg1)
case TransitionACTION:
return NewActionTransition(target, arg1, arg2, arg3 != 0)
case TransitionSET:
return NewSetTransition(target, sets[arg1])
case TransitionNOTSET:
return NewNotSetTransition(target, sets[arg1])
case TransitionWILDCARD:
return NewWildcardTransition(target)
}
panic("The specified transition type is not valid.")
}
func (a *ATNDeserializer) stateFactory(typeIndex, ruleIndex int) ATNState {
var s ATNState
switch typeIndex {
case ATNStateInvalidType:
return nil
case ATNStateBasic:
s = NewBasicState()
case ATNStateRuleStart:
s = NewRuleStartState()
case ATNStateBlockStart:
s = NewBasicBlockStartState()
case ATNStatePlusBlockStart:
s = NewPlusBlockStartState()
case ATNStateStarBlockStart:
s = NewStarBlockStartState()
case ATNStateTokenStart:
s = NewTokensStartState()
case ATNStateRuleStop:
s = NewRuleStopState()
case ATNStateBlockEnd:
s = NewBlockEndState()
case ATNStateStarLoopBack:
s = NewStarLoopbackState()
case ATNStateStarLoopEntry:
s = NewStarLoopEntryState()
case ATNStatePlusLoopBack:
s = NewPlusLoopbackState()
case ATNStateLoopEnd:
s = NewLoopEndState()
default:
panic(fmt.Sprintf("state type %d is invalid", typeIndex))
}
s.SetRuleIndex(ruleIndex)
return s
}
func (a *ATNDeserializer) lexerActionFactory(typeIndex, data1, data2 int) LexerAction {
switch typeIndex {
case LexerActionTypeChannel:
return NewLexerChannelAction(data1)
case LexerActionTypeCustom:
return NewLexerCustomAction(data1, data2)
case LexerActionTypeMode:
return NewLexerModeAction(data1)
case LexerActionTypeMore:
return LexerMoreActionINSTANCE
case LexerActionTypePopMode:
return LexerPopModeActionINSTANCE
case LexerActionTypePushMode:
return NewLexerPushModeAction(data1)
case LexerActionTypeSkip:
return LexerSkipActionINSTANCE
case LexerActionTypeType:
return NewLexerTypeAction(data1)
default:
panic(fmt.Sprintf("lexer action %d is invalid", typeIndex))
}
}