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271 lines
7.3 KiB
Go
271 lines
7.3 KiB
Go
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package cty
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import (
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"errors"
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"fmt"
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)
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// A Path is a sequence of operations to locate a nested value within a
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// data structure.
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//
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// The empty Path represents the given item. Any PathSteps within represent
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// taking a single step down into a data structure.
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//
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// Path has some convenience methods for gradually constructing a path,
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// but callers can also feel free to just produce a slice of PathStep manually
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// and convert to this type, which may be more appropriate in environments
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// where memory pressure is a concern.
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//
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// Although a Path is technically mutable, by convention callers should not
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// mutate a path once it has been built and passed to some other subsystem.
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// Instead, use Copy and then mutate the copy before using it.
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type Path []PathStep
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// PathStep represents a single step down into a data structure, as part
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// of a Path. PathStep is a closed interface, meaning that the only
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// permitted implementations are those within this package.
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type PathStep interface {
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pathStepSigil() pathStepImpl
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Apply(Value) (Value, error)
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}
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// embed pathImpl into a struct to declare it a PathStep implementation
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type pathStepImpl struct{}
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func (p pathStepImpl) pathStepSigil() pathStepImpl {
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return p
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}
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// Index returns a new Path that is the reciever with an IndexStep appended
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// to the end.
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//
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// This is provided as a convenient way to construct paths, but each call
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// will create garbage so it should not be used where memory pressure is a
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// concern.
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func (p Path) Index(v Value) Path {
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ret := make(Path, len(p)+1)
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copy(ret, p)
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ret[len(p)] = IndexStep{
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Key: v,
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}
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return ret
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}
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// IndexInt is a typed convenience method for Index.
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func (p Path) IndexInt(v int) Path {
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return p.Index(NumberIntVal(int64(v)))
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}
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// IndexString is a typed convenience method for Index.
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func (p Path) IndexString(v string) Path {
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return p.Index(StringVal(v))
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}
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// IndexPath is a convenience method to start a new Path with an IndexStep.
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func IndexPath(v Value) Path {
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return Path{}.Index(v)
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}
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// IndexIntPath is a typed convenience method for IndexPath.
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func IndexIntPath(v int) Path {
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return IndexPath(NumberIntVal(int64(v)))
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}
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// IndexStringPath is a typed convenience method for IndexPath.
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func IndexStringPath(v string) Path {
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return IndexPath(StringVal(v))
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}
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// GetAttr returns a new Path that is the reciever with a GetAttrStep appended
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// to the end.
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//
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// This is provided as a convenient way to construct paths, but each call
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// will create garbage so it should not be used where memory pressure is a
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// concern.
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func (p Path) GetAttr(name string) Path {
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ret := make(Path, len(p)+1)
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copy(ret, p)
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ret[len(p)] = GetAttrStep{
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Name: name,
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}
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return ret
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}
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// Equals compares 2 Paths for exact equality.
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func (p Path) Equals(other Path) bool {
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if len(p) != len(other) {
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return false
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}
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for i := range p {
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pv := p[i]
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switch pv := pv.(type) {
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case GetAttrStep:
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ov, ok := other[i].(GetAttrStep)
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if !ok || pv != ov {
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return false
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}
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case IndexStep:
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ov, ok := other[i].(IndexStep)
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if !ok {
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return false
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}
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if !pv.Key.RawEquals(ov.Key) {
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return false
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}
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default:
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// Any invalid steps default to evaluating false.
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return false
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}
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}
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return true
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}
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// HasPrefix determines if the path p contains the provided prefix.
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func (p Path) HasPrefix(prefix Path) bool {
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if len(prefix) > len(p) {
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return false
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}
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return p[:len(prefix)].Equals(prefix)
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}
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// GetAttrPath is a convenience method to start a new Path with a GetAttrStep.
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func GetAttrPath(name string) Path {
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return Path{}.GetAttr(name)
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}
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// Apply applies each of the steps in turn to successive values starting with
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// the given value, and returns the result. If any step returns an error,
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// the whole operation returns an error.
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func (p Path) Apply(val Value) (Value, error) {
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var err error
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for i, step := range p {
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val, err = step.Apply(val)
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if err != nil {
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return NilVal, fmt.Errorf("at step %d: %s", i, err)
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}
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}
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return val, nil
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}
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// LastStep applies the given path up to the last step and then returns
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// the resulting value and the final step.
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//
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// This is useful when dealing with assignment operations, since in that
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// case the *value* of the last step is not important (and may not, in fact,
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// present at all) and we care only about its location.
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//
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// Since LastStep applies all steps except the last, it will return errors
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// for those steps in the same way as Apply does.
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//
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// If the path has *no* steps then the returned PathStep will be nil,
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// representing that any operation should be applied directly to the
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// given value.
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func (p Path) LastStep(val Value) (Value, PathStep, error) {
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var err error
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if len(p) == 0 {
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return val, nil, nil
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}
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journey := p[:len(p)-1]
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val, err = journey.Apply(val)
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if err != nil {
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return NilVal, nil, err
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}
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return val, p[len(p)-1], nil
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}
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// Copy makes a shallow copy of the receiver. Often when paths are passed to
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// caller code they come with the constraint that they are valid only until
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// the caller returns, due to how they are constructed internally. Callers
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// can use Copy to conveniently produce a copy of the value that _they_ control
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// the validity of.
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func (p Path) Copy() Path {
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ret := make(Path, len(p))
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copy(ret, p)
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return ret
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}
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// IndexStep is a Step implementation representing applying the index operation
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// to a value, which must be of either a list, map, or set type.
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//
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// When describing a path through a *type* rather than a concrete value,
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// the Key may be an unknown value, indicating that the step applies to
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// *any* key of the given type.
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//
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// When indexing into a set, the Key is actually the element being accessed
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// itself, since in sets elements are their own identity.
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type IndexStep struct {
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pathStepImpl
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Key Value
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}
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// Apply returns the value resulting from indexing the given value with
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// our key value.
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func (s IndexStep) Apply(val Value) (Value, error) {
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if val == NilVal || val.IsNull() {
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return NilVal, errors.New("cannot index a null value")
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}
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switch s.Key.Type() {
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case Number:
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if !(val.Type().IsListType() || val.Type().IsTupleType()) {
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return NilVal, errors.New("not a list type")
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}
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case String:
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if !val.Type().IsMapType() {
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return NilVal, errors.New("not a map type")
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}
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default:
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return NilVal, errors.New("key value not number or string")
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}
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has := val.HasIndex(s.Key)
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if !has.IsKnown() {
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return UnknownVal(val.Type().ElementType()), nil
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}
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if !has.True() {
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return NilVal, errors.New("value does not have given index key")
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}
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return val.Index(s.Key), nil
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}
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func (s IndexStep) GoString() string {
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return fmt.Sprintf("cty.IndexStep{Key:%#v}", s.Key)
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}
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// GetAttrStep is a Step implementation representing retrieving an attribute
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// from a value, which must be of an object type.
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type GetAttrStep struct {
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pathStepImpl
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Name string
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}
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// Apply returns the value of our named attribute from the given value, which
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// must be of an object type that has a value of that name.
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func (s GetAttrStep) Apply(val Value) (Value, error) {
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if val == NilVal || val.IsNull() {
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return NilVal, errors.New("cannot access attributes on a null value")
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}
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if !val.Type().IsObjectType() {
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return NilVal, errors.New("not an object type")
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}
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if !val.Type().HasAttribute(s.Name) {
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return NilVal, fmt.Errorf("object has no attribute %q", s.Name)
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}
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return val.GetAttr(s.Name), nil
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}
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func (s GetAttrStep) GoString() string {
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return fmt.Sprintf("cty.GetAttrStep{Name:%q}", s.Name)
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}
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