225 lines
6.2 KiB
Go
225 lines
6.2 KiB
Go
package hclwrite
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import (
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"fmt"
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"github.com/hashicorp/hcl/v2"
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"github.com/hashicorp/hcl/v2/hclsyntax"
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"github.com/zclconf/go-cty/cty"
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)
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type Expression struct {
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inTree
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absTraversals nodeSet
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}
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func newExpression() *Expression {
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return &Expression{
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inTree: newInTree(),
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absTraversals: newNodeSet(),
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}
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}
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// NewExpressionRaw constructs an expression containing the given raw tokens.
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//
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// There is no automatic validation that the given tokens produce a valid
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// expression. Callers of thus function must take care to produce invalid
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// expression tokens. Where possible, use the higher-level functions
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// NewExpressionLiteral or NewExpressionAbsTraversal instead.
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//
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// Because NewExpressionRaw does not interpret the given tokens in any way,
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// an expression created by NewExpressionRaw will produce an empty result
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// for calls to its method Variables, even if the given token sequence
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// contains a subslice that would normally be interpreted as a traversal under
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// parsing.
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func NewExpressionRaw(tokens Tokens) *Expression {
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expr := newExpression()
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// We copy the tokens here in order to make sure that later mutations
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// by the caller don't inadvertently cause our expression to become
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// invalid.
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copyTokens := make(Tokens, len(tokens))
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copy(copyTokens, tokens)
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expr.children.AppendUnstructuredTokens(copyTokens)
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return expr
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}
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// NewExpressionLiteral constructs an an expression that represents the given
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// literal value.
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//
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// Since an unknown value cannot be represented in source code, this function
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// will panic if the given value is unknown or contains a nested unknown value.
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// Use val.IsWhollyKnown before calling to be sure.
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//
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// HCL native syntax does not directly represent lists, maps, and sets, and
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// instead relies on the automatic conversions to those collection types from
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// either list or tuple constructor syntax. Therefore converting collection
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// values to source code and re-reading them will lose type information, and
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// the reader must provide a suitable type at decode time to recover the
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// original value.
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func NewExpressionLiteral(val cty.Value) *Expression {
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toks := TokensForValue(val)
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expr := newExpression()
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expr.children.AppendUnstructuredTokens(toks)
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return expr
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}
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// NewExpressionAbsTraversal constructs an expression that represents the
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// given traversal, which must be absolute or this function will panic.
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func NewExpressionAbsTraversal(traversal hcl.Traversal) *Expression {
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if traversal.IsRelative() {
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panic("can't construct expression from relative traversal")
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}
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physT := newTraversal()
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rootName := traversal.RootName()
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steps := traversal[1:]
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{
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tn := newTraverseName()
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tn.name = tn.children.Append(newIdentifier(&Token{
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Type: hclsyntax.TokenIdent,
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Bytes: []byte(rootName),
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}))
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physT.steps.Add(physT.children.Append(tn))
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}
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for _, step := range steps {
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switch ts := step.(type) {
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case hcl.TraverseAttr:
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tn := newTraverseName()
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tn.children.AppendUnstructuredTokens(Tokens{
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{
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Type: hclsyntax.TokenDot,
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Bytes: []byte{'.'},
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},
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})
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tn.name = tn.children.Append(newIdentifier(&Token{
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Type: hclsyntax.TokenIdent,
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Bytes: []byte(ts.Name),
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}))
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physT.steps.Add(physT.children.Append(tn))
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case hcl.TraverseIndex:
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ti := newTraverseIndex()
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ti.children.AppendUnstructuredTokens(Tokens{
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{
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Type: hclsyntax.TokenOBrack,
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Bytes: []byte{'['},
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},
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})
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indexExpr := NewExpressionLiteral(ts.Key)
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ti.key = ti.children.Append(indexExpr)
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ti.children.AppendUnstructuredTokens(Tokens{
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{
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Type: hclsyntax.TokenCBrack,
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Bytes: []byte{']'},
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},
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})
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physT.steps.Add(physT.children.Append(ti))
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}
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}
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expr := newExpression()
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expr.absTraversals.Add(expr.children.Append(physT))
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return expr
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}
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// Variables returns the absolute traversals that exist within the receiving
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// expression.
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func (e *Expression) Variables() []*Traversal {
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nodes := e.absTraversals.List()
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ret := make([]*Traversal, len(nodes))
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for i, node := range nodes {
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ret[i] = node.content.(*Traversal)
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}
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return ret
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}
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// RenameVariablePrefix examines each of the absolute traversals in the
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// receiving expression to see if they have the given sequence of names as
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// a prefix prefix. If so, they are updated in place to have the given
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// replacement names instead of that prefix.
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//
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// This can be used to implement symbol renaming. The calling application can
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// visit all relevant expressions in its input and apply the same renaming
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// to implement a global symbol rename.
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//
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// The search and replacement traversals must be the same length, or this
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// method will panic. Only attribute access operations can be matched and
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// replaced. Index steps never match the prefix.
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func (e *Expression) RenameVariablePrefix(search, replacement []string) {
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if len(search) != len(replacement) {
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panic(fmt.Sprintf("search and replacement length mismatch (%d and %d)", len(search), len(replacement)))
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}
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Traversals:
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for node := range e.absTraversals {
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traversal := node.content.(*Traversal)
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if len(traversal.steps) < len(search) {
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// If it's shorter then it can't have our prefix
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continue
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}
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stepNodes := traversal.steps.List()
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for i, name := range search {
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step, isName := stepNodes[i].content.(*TraverseName)
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if !isName {
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continue Traversals // only name nodes can match
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}
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foundNameBytes := step.name.content.(*identifier).token.Bytes
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if len(foundNameBytes) != len(name) {
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continue Traversals
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}
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if string(foundNameBytes) != name {
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continue Traversals
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}
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}
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// If we get here then the prefix matched, so now we'll swap in
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// the replacement strings.
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for i, name := range replacement {
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step := stepNodes[i].content.(*TraverseName)
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token := step.name.content.(*identifier).token
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token.Bytes = []byte(name)
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}
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}
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}
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// Traversal represents a sequence of variable, attribute, and/or index
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// operations.
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type Traversal struct {
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inTree
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steps nodeSet
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}
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func newTraversal() *Traversal {
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return &Traversal{
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inTree: newInTree(),
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steps: newNodeSet(),
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}
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}
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type TraverseName struct {
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inTree
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name *node
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}
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func newTraverseName() *TraverseName {
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return &TraverseName{
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inTree: newInTree(),
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}
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}
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type TraverseIndex struct {
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inTree
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key *node
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}
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func newTraverseIndex() *TraverseIndex {
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return &TraverseIndex{
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inTree: newInTree(),
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}
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}
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