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|
package hcl
import (
"fmt"
"math/big"
"github.com/zclconf/go-cty/cty"
"github.com/zclconf/go-cty/cty/convert"
)
// Index is a helper function that performs the same operation as the index
// operator in the HCL expression language. That is, the result is the
// same as it would be for collection[key] in a configuration expression.
//
// This is exported so that applications can perform indexing in a manner
// consistent with how the language does it, including handling of null and
// unknown values, etc.
//
// Diagnostics are produced if the given combination of values is not valid.
// Therefore a pointer to a source range must be provided to use in diagnostics,
// though nil can be provided if the calling application is going to
// ignore the subject of the returned diagnostics anyway.
func Index(collection, key cty.Value, srcRange *Range) (cty.Value, Diagnostics) {
if collection.IsNull() {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Attempt to index null value",
Detail: "This value is null, so it does not have any indices.",
Subject: srcRange,
},
}
}
if key.IsNull() {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Invalid index",
Detail: "Can't use a null value as an indexing key.",
Subject: srcRange,
},
}
}
ty := collection.Type()
kty := key.Type()
if kty == cty.DynamicPseudoType || ty == cty.DynamicPseudoType {
return cty.DynamicVal, nil
}
switch {
case ty.IsListType() || ty.IsTupleType() || ty.IsMapType():
var wantType cty.Type
switch {
case ty.IsListType() || ty.IsTupleType():
wantType = cty.Number
case ty.IsMapType():
wantType = cty.String
default:
// should never happen
panic("don't know what key type we want")
}
key, keyErr := convert.Convert(key, wantType)
if keyErr != nil {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Invalid index",
Detail: fmt.Sprintf(
"The given key does not identify an element in this collection value: %s.",
keyErr.Error(),
),
Subject: srcRange,
},
}
}
has := collection.HasIndex(key)
if !has.IsKnown() {
if ty.IsTupleType() {
return cty.DynamicVal, nil
} else {
return cty.UnknownVal(ty.ElementType()), nil
}
}
if has.False() {
// We have a more specialized error message for the situation of
// using a fractional number to index into a sequence, because
// that will tend to happen if the user is trying to use division
// to calculate an index and not realizing that HCL does float
// division rather than integer division.
if (ty.IsListType() || ty.IsTupleType()) && key.Type().Equals(cty.Number) {
if key.IsKnown() && !key.IsNull() {
bf := key.AsBigFloat()
if _, acc := bf.Int(nil); acc != big.Exact {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Invalid index",
Detail: fmt.Sprintf("The given key does not identify an element in this collection value: indexing a sequence requires a whole number, but the given index (%g) has a fractional part.", bf),
Subject: srcRange,
},
}
}
}
}
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Invalid index",
Detail: "The given key does not identify an element in this collection value.",
Subject: srcRange,
},
}
}
return collection.Index(key), nil
case ty.IsObjectType():
key, keyErr := convert.Convert(key, cty.String)
if keyErr != nil {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Invalid index",
Detail: fmt.Sprintf(
"The given key does not identify an element in this collection value: %s.",
keyErr.Error(),
),
Subject: srcRange,
},
}
}
if !collection.IsKnown() {
return cty.DynamicVal, nil
}
if !key.IsKnown() {
return cty.DynamicVal, nil
}
attrName := key.AsString()
if !ty.HasAttribute(attrName) {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Invalid index",
Detail: "The given key does not identify an element in this collection value.",
Subject: srcRange,
},
}
}
return collection.GetAttr(attrName), nil
default:
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Invalid index",
Detail: "This value does not have any indices.",
Subject: srcRange,
},
}
}
}
// GetAttr is a helper function that performs the same operation as the
// attribute access in the HCL expression language. That is, the result is the
// same as it would be for obj.attr in a configuration expression.
//
// This is exported so that applications can access attributes in a manner
// consistent with how the language does it, including handling of null and
// unknown values, etc.
//
// Diagnostics are produced if the given combination of values is not valid.
// Therefore a pointer to a source range must be provided to use in diagnostics,
// though nil can be provided if the calling application is going to
// ignore the subject of the returned diagnostics anyway.
func GetAttr(obj cty.Value, attrName string, srcRange *Range) (cty.Value, Diagnostics) {
if obj.IsNull() {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Attempt to get attribute from null value",
Detail: "This value is null, so it does not have any attributes.",
Subject: srcRange,
},
}
}
ty := obj.Type()
switch {
case ty.IsObjectType():
if !ty.HasAttribute(attrName) {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Unsupported attribute",
Detail: fmt.Sprintf("This object does not have an attribute named %q.", attrName),
Subject: srcRange,
},
}
}
if !obj.IsKnown() {
return cty.UnknownVal(ty.AttributeType(attrName)), nil
}
return obj.GetAttr(attrName), nil
case ty.IsMapType():
if !obj.IsKnown() {
return cty.UnknownVal(ty.ElementType()), nil
}
idx := cty.StringVal(attrName)
if obj.HasIndex(idx).False() {
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Missing map element",
Detail: fmt.Sprintf("This map does not have an element with the key %q.", attrName),
Subject: srcRange,
},
}
}
return obj.Index(idx), nil
case ty == cty.DynamicPseudoType:
return cty.DynamicVal, nil
default:
return cty.DynamicVal, Diagnostics{
{
Severity: DiagError,
Summary: "Unsupported attribute",
Detail: "This value does not have any attributes.",
Subject: srcRange,
},
}
}
}
// ApplyPath is a helper function that applies a cty.Path to a value using the
// indexing and attribute access operations from HCL.
//
// This is similar to calling the path's own Apply method, but ApplyPath uses
// the more relaxed typing rules that apply to these operations in HCL, rather
// than cty's relatively-strict rules. ApplyPath is implemented in terms of
// Index and GetAttr, and so it has the same behavior for individual steps
// but will stop and return any errors returned by intermediate steps.
//
// Diagnostics are produced if the given path cannot be applied to the given
// value. Therefore a pointer to a source range must be provided to use in
// diagnostics, though nil can be provided if the calling application is going
// to ignore the subject of the returned diagnostics anyway.
func ApplyPath(val cty.Value, path cty.Path, srcRange *Range) (cty.Value, Diagnostics) {
var diags Diagnostics
for _, step := range path {
var stepDiags Diagnostics
switch ts := step.(type) {
case cty.IndexStep:
val, stepDiags = Index(val, ts.Key, srcRange)
case cty.GetAttrStep:
val, stepDiags = GetAttr(val, ts.Name, srcRange)
default:
// Should never happen because the above are all of the step types.
diags = diags.Append(&Diagnostic{
Severity: DiagError,
Summary: "Invalid path step",
Detail: fmt.Sprintf("Go type %T is not a valid path step. This is a bug in this program.", step),
Subject: srcRange,
})
return cty.DynamicVal, diags
}
diags = append(diags, stepDiags...)
if stepDiags.HasErrors() {
return cty.DynamicVal, diags
}
}
return val, diags
}
|
