hcl/json/structure.go
Martin Atkins 6c4344623b Unfold the "hcl" directory up into the root
The main HCL package is more visible this way, and so it's easier than
having to pick it out from dozens of other package directories.
2019-09-09 16:08:19 -07:00

638 lines
18 KiB
Go

package json
import (
"fmt"
"github.com/hashicorp/hcl/v2"
"github.com/hashicorp/hcl/v2/hclsyntax"
"github.com/zclconf/go-cty/cty"
"github.com/zclconf/go-cty/cty/convert"
)
// body is the implementation of "Body" used for files processed with the JSON
// parser.
type body struct {
val node
// If non-nil, the keys of this map cause the corresponding attributes to
// be treated as non-existing. This is used when Body.PartialContent is
// called, to produce the "remaining content" Body.
hiddenAttrs map[string]struct{}
}
// expression is the implementation of "Expression" used for files processed
// with the JSON parser.
type expression struct {
src node
}
func (b *body) Content(schema *hcl.BodySchema) (*hcl.BodyContent, hcl.Diagnostics) {
content, newBody, diags := b.PartialContent(schema)
hiddenAttrs := newBody.(*body).hiddenAttrs
var nameSuggestions []string
for _, attrS := range schema.Attributes {
if _, ok := hiddenAttrs[attrS.Name]; !ok {
// Only suggest an attribute name if we didn't use it already.
nameSuggestions = append(nameSuggestions, attrS.Name)
}
}
for _, blockS := range schema.Blocks {
// Blocks can appear multiple times, so we'll suggest their type
// names regardless of whether they've already been used.
nameSuggestions = append(nameSuggestions, blockS.Type)
}
jsonAttrs, attrDiags := b.collectDeepAttrs(b.val, nil)
diags = append(diags, attrDiags...)
for _, attr := range jsonAttrs {
k := attr.Name
if k == "//" {
// Ignore "//" keys in objects representing bodies, to allow
// their use as comments.
continue
}
if _, ok := hiddenAttrs[k]; !ok {
suggestion := nameSuggestion(k, nameSuggestions)
if suggestion != "" {
suggestion = fmt.Sprintf(" Did you mean %q?", suggestion)
}
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Extraneous JSON object property",
Detail: fmt.Sprintf("No argument or block type is named %q.%s", k, suggestion),
Subject: &attr.NameRange,
Context: attr.Range().Ptr(),
})
}
}
return content, diags
}
func (b *body) PartialContent(schema *hcl.BodySchema) (*hcl.BodyContent, hcl.Body, hcl.Diagnostics) {
var diags hcl.Diagnostics
jsonAttrs, attrDiags := b.collectDeepAttrs(b.val, nil)
diags = append(diags, attrDiags...)
usedNames := map[string]struct{}{}
if b.hiddenAttrs != nil {
for k := range b.hiddenAttrs {
usedNames[k] = struct{}{}
}
}
content := &hcl.BodyContent{
Attributes: map[string]*hcl.Attribute{},
Blocks: nil,
MissingItemRange: b.MissingItemRange(),
}
// Create some more convenient data structures for our work below.
attrSchemas := map[string]hcl.AttributeSchema{}
blockSchemas := map[string]hcl.BlockHeaderSchema{}
for _, attrS := range schema.Attributes {
attrSchemas[attrS.Name] = attrS
}
for _, blockS := range schema.Blocks {
blockSchemas[blockS.Type] = blockS
}
for _, jsonAttr := range jsonAttrs {
attrName := jsonAttr.Name
if _, used := b.hiddenAttrs[attrName]; used {
continue
}
if attrS, defined := attrSchemas[attrName]; defined {
if existing, exists := content.Attributes[attrName]; exists {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Duplicate argument",
Detail: fmt.Sprintf("The argument %q was already set at %s.", attrName, existing.Range),
Subject: &jsonAttr.NameRange,
Context: jsonAttr.Range().Ptr(),
})
continue
}
content.Attributes[attrS.Name] = &hcl.Attribute{
Name: attrS.Name,
Expr: &expression{src: jsonAttr.Value},
Range: hcl.RangeBetween(jsonAttr.NameRange, jsonAttr.Value.Range()),
NameRange: jsonAttr.NameRange,
}
usedNames[attrName] = struct{}{}
} else if blockS, defined := blockSchemas[attrName]; defined {
bv := jsonAttr.Value
blockDiags := b.unpackBlock(bv, blockS.Type, &jsonAttr.NameRange, blockS.LabelNames, nil, nil, &content.Blocks)
diags = append(diags, blockDiags...)
usedNames[attrName] = struct{}{}
}
// We ignore anything that isn't defined because that's the
// PartialContent contract. The Content method will catch leftovers.
}
// Make sure we got all the required attributes.
for _, attrS := range schema.Attributes {
if !attrS.Required {
continue
}
if _, defined := content.Attributes[attrS.Name]; !defined {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Missing required argument",
Detail: fmt.Sprintf("The argument %q is required, but no definition was found.", attrS.Name),
Subject: b.MissingItemRange().Ptr(),
})
}
}
unusedBody := &body{
val: b.val,
hiddenAttrs: usedNames,
}
return content, unusedBody, diags
}
// JustAttributes for JSON bodies interprets all properties of the wrapped
// JSON object as attributes and returns them.
func (b *body) JustAttributes() (hcl.Attributes, hcl.Diagnostics) {
var diags hcl.Diagnostics
attrs := make(map[string]*hcl.Attribute)
obj, ok := b.val.(*objectVal)
if !ok {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Incorrect JSON value type",
Detail: "A JSON object is required here, setting the arguments for this block.",
Subject: b.val.StartRange().Ptr(),
})
return attrs, diags
}
for _, jsonAttr := range obj.Attrs {
name := jsonAttr.Name
if name == "//" {
// Ignore "//" keys in objects representing bodies, to allow
// their use as comments.
continue
}
if _, hidden := b.hiddenAttrs[name]; hidden {
continue
}
if existing, exists := attrs[name]; exists {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Duplicate attribute definition",
Detail: fmt.Sprintf("The argument %q was already set at %s.", name, existing.Range),
Subject: &jsonAttr.NameRange,
})
continue
}
attrs[name] = &hcl.Attribute{
Name: name,
Expr: &expression{src: jsonAttr.Value},
Range: hcl.RangeBetween(jsonAttr.NameRange, jsonAttr.Value.Range()),
NameRange: jsonAttr.NameRange,
}
}
// No diagnostics possible here, since the parser already took care of
// finding duplicates and every JSON value can be a valid attribute value.
return attrs, diags
}
func (b *body) MissingItemRange() hcl.Range {
switch tv := b.val.(type) {
case *objectVal:
return tv.CloseRange
case *arrayVal:
return tv.OpenRange
default:
// Should not happen in correct operation, but might show up if the
// input is invalid and we are producing partial results.
return tv.StartRange()
}
}
func (b *body) unpackBlock(v node, typeName string, typeRange *hcl.Range, labelsLeft []string, labelsUsed []string, labelRanges []hcl.Range, blocks *hcl.Blocks) (diags hcl.Diagnostics) {
if len(labelsLeft) > 0 {
labelName := labelsLeft[0]
jsonAttrs, attrDiags := b.collectDeepAttrs(v, &labelName)
diags = append(diags, attrDiags...)
if len(jsonAttrs) == 0 {
diags = diags.Append(&hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Missing block label",
Detail: fmt.Sprintf("At least one object property is required, whose name represents the %s block's %s.", typeName, labelName),
Subject: v.StartRange().Ptr(),
})
return
}
labelsUsed := append(labelsUsed, "")
labelRanges := append(labelRanges, hcl.Range{})
for _, p := range jsonAttrs {
pk := p.Name
labelsUsed[len(labelsUsed)-1] = pk
labelRanges[len(labelRanges)-1] = p.NameRange
diags = append(diags, b.unpackBlock(p.Value, typeName, typeRange, labelsLeft[1:], labelsUsed, labelRanges, blocks)...)
}
return
}
// By the time we get here, we've peeled off all the labels and we're ready
// to deal with the block's actual content.
// need to copy the label slices because their underlying arrays will
// continue to be mutated after we return.
labels := make([]string, len(labelsUsed))
copy(labels, labelsUsed)
labelR := make([]hcl.Range, len(labelRanges))
copy(labelR, labelRanges)
switch tv := v.(type) {
case *nullVal:
// There is no block content, e.g the value is null.
return
case *objectVal:
// Single instance of the block
*blocks = append(*blocks, &hcl.Block{
Type: typeName,
Labels: labels,
Body: &body{
val: tv,
},
DefRange: tv.OpenRange,
TypeRange: *typeRange,
LabelRanges: labelR,
})
case *arrayVal:
// Multiple instances of the block
for _, av := range tv.Values {
*blocks = append(*blocks, &hcl.Block{
Type: typeName,
Labels: labels,
Body: &body{
val: av, // might be mistyped; we'll find out when content is requested for this body
},
DefRange: tv.OpenRange,
TypeRange: *typeRange,
LabelRanges: labelR,
})
}
default:
diags = diags.Append(&hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Incorrect JSON value type",
Detail: fmt.Sprintf("Either a JSON object or a JSON array is required, representing the contents of one or more %q blocks.", typeName),
Subject: v.StartRange().Ptr(),
})
}
return
}
// collectDeepAttrs takes either a single object or an array of objects and
// flattens it into a list of object attributes, collecting attributes from
// all of the objects in a given array.
//
// Ordering is preserved, so a list of objects that each have one property
// will result in those properties being returned in the same order as the
// objects appeared in the array.
//
// This is appropriate for use only for objects representing bodies or labels
// within a block.
//
// The labelName argument, if non-null, is used to tailor returned error
// messages to refer to block labels rather than attributes and child blocks.
// It has no other effect.
func (b *body) collectDeepAttrs(v node, labelName *string) ([]*objectAttr, hcl.Diagnostics) {
var diags hcl.Diagnostics
var attrs []*objectAttr
switch tv := v.(type) {
case *nullVal:
// If a value is null, then we don't return any attributes or return an error.
case *objectVal:
attrs = append(attrs, tv.Attrs...)
case *arrayVal:
for _, ev := range tv.Values {
switch tev := ev.(type) {
case *objectVal:
attrs = append(attrs, tev.Attrs...)
default:
if labelName != nil {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Incorrect JSON value type",
Detail: fmt.Sprintf("A JSON object is required here, to specify %s labels for this block.", *labelName),
Subject: ev.StartRange().Ptr(),
})
} else {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Incorrect JSON value type",
Detail: "A JSON object is required here, to define arguments and child blocks.",
Subject: ev.StartRange().Ptr(),
})
}
}
}
default:
if labelName != nil {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Incorrect JSON value type",
Detail: fmt.Sprintf("Either a JSON object or JSON array of objects is required here, to specify %s labels for this block.", *labelName),
Subject: v.StartRange().Ptr(),
})
} else {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Incorrect JSON value type",
Detail: "Either a JSON object or JSON array of objects is required here, to define arguments and child blocks.",
Subject: v.StartRange().Ptr(),
})
}
}
return attrs, diags
}
func (e *expression) Value(ctx *hcl.EvalContext) (cty.Value, hcl.Diagnostics) {
switch v := e.src.(type) {
case *stringVal:
if ctx != nil {
// Parse string contents as a HCL native language expression.
// We only do this if we have a context, so passing a nil context
// is how the caller specifies that interpolations are not allowed
// and that the string should just be returned verbatim.
templateSrc := v.Value
expr, diags := hclsyntax.ParseTemplate(
[]byte(templateSrc),
v.SrcRange.Filename,
// This won't produce _exactly_ the right result, since
// the hclsyntax parser can't "see" any escapes we removed
// while parsing JSON, but it's better than nothing.
hcl.Pos{
Line: v.SrcRange.Start.Line,
// skip over the opening quote mark
Byte: v.SrcRange.Start.Byte + 1,
Column: v.SrcRange.Start.Column + 1,
},
)
if diags.HasErrors() {
return cty.DynamicVal, diags
}
val, evalDiags := expr.Value(ctx)
diags = append(diags, evalDiags...)
return val, diags
}
return cty.StringVal(v.Value), nil
case *numberVal:
return cty.NumberVal(v.Value), nil
case *booleanVal:
return cty.BoolVal(v.Value), nil
case *arrayVal:
var diags hcl.Diagnostics
vals := []cty.Value{}
for _, jsonVal := range v.Values {
val, valDiags := (&expression{src: jsonVal}).Value(ctx)
vals = append(vals, val)
diags = append(diags, valDiags...)
}
return cty.TupleVal(vals), diags
case *objectVal:
var diags hcl.Diagnostics
attrs := map[string]cty.Value{}
attrRanges := map[string]hcl.Range{}
known := true
for _, jsonAttr := range v.Attrs {
// In this one context we allow keys to contain interpolation
// expressions too, assuming we're evaluating in interpolation
// mode. This achieves parity with the native syntax where
// object expressions can have dynamic keys, while block contents
// may not.
name, nameDiags := (&expression{src: &stringVal{
Value: jsonAttr.Name,
SrcRange: jsonAttr.NameRange,
}}).Value(ctx)
valExpr := &expression{src: jsonAttr.Value}
val, valDiags := valExpr.Value(ctx)
diags = append(diags, nameDiags...)
diags = append(diags, valDiags...)
var err error
name, err = convert.Convert(name, cty.String)
if err != nil {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Invalid object key expression",
Detail: fmt.Sprintf("Cannot use this expression as an object key: %s.", err),
Subject: &jsonAttr.NameRange,
Expression: valExpr,
EvalContext: ctx,
})
continue
}
if name.IsNull() {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Invalid object key expression",
Detail: "Cannot use null value as an object key.",
Subject: &jsonAttr.NameRange,
Expression: valExpr,
EvalContext: ctx,
})
continue
}
if !name.IsKnown() {
// This is a bit of a weird case, since our usual rules require
// us to tolerate unknowns and just represent the result as
// best we can but if we don't know the key then we can't
// know the type of our object at all, and thus we must turn
// the whole thing into cty.DynamicVal. This is consistent with
// how this situation is handled in the native syntax.
// We'll keep iterating so we can collect other errors in
// subsequent attributes.
known = false
continue
}
nameStr := name.AsString()
if _, defined := attrs[nameStr]; defined {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Duplicate object attribute",
Detail: fmt.Sprintf("An attribute named %q was already defined at %s.", nameStr, attrRanges[nameStr]),
Subject: &jsonAttr.NameRange,
Expression: e,
EvalContext: ctx,
})
continue
}
attrs[nameStr] = val
attrRanges[nameStr] = jsonAttr.NameRange
}
if !known {
// We encountered an unknown key somewhere along the way, so
// we can't know what our type will eventually be.
return cty.DynamicVal, diags
}
return cty.ObjectVal(attrs), diags
case *nullVal:
return cty.NullVal(cty.DynamicPseudoType), nil
default:
// Default to DynamicVal so that ASTs containing invalid nodes can
// still be partially-evaluated.
return cty.DynamicVal, nil
}
}
func (e *expression) Variables() []hcl.Traversal {
var vars []hcl.Traversal
switch v := e.src.(type) {
case *stringVal:
templateSrc := v.Value
expr, diags := hclsyntax.ParseTemplate(
[]byte(templateSrc),
v.SrcRange.Filename,
// This won't produce _exactly_ the right result, since
// the hclsyntax parser can't "see" any escapes we removed
// while parsing JSON, but it's better than nothing.
hcl.Pos{
Line: v.SrcRange.Start.Line,
// skip over the opening quote mark
Byte: v.SrcRange.Start.Byte + 1,
Column: v.SrcRange.Start.Column + 1,
},
)
if diags.HasErrors() {
return vars
}
return expr.Variables()
case *arrayVal:
for _, jsonVal := range v.Values {
vars = append(vars, (&expression{src: jsonVal}).Variables()...)
}
case *objectVal:
for _, jsonAttr := range v.Attrs {
keyExpr := &stringVal{ // we're going to treat key as an expression in this context
Value: jsonAttr.Name,
SrcRange: jsonAttr.NameRange,
}
vars = append(vars, (&expression{src: keyExpr}).Variables()...)
vars = append(vars, (&expression{src: jsonAttr.Value}).Variables()...)
}
}
return vars
}
func (e *expression) Range() hcl.Range {
return e.src.Range()
}
func (e *expression) StartRange() hcl.Range {
return e.src.StartRange()
}
// Implementation for hcl.AbsTraversalForExpr.
func (e *expression) AsTraversal() hcl.Traversal {
// In JSON-based syntax a traversal is given as a string containing
// traversal syntax as defined by hclsyntax.ParseTraversalAbs.
switch v := e.src.(type) {
case *stringVal:
traversal, diags := hclsyntax.ParseTraversalAbs([]byte(v.Value), v.SrcRange.Filename, v.SrcRange.Start)
if diags.HasErrors() {
return nil
}
return traversal
default:
return nil
}
}
// Implementation for hcl.ExprCall.
func (e *expression) ExprCall() *hcl.StaticCall {
// In JSON-based syntax a static call is given as a string containing
// an expression in the native syntax that also supports ExprCall.
switch v := e.src.(type) {
case *stringVal:
expr, diags := hclsyntax.ParseExpression([]byte(v.Value), v.SrcRange.Filename, v.SrcRange.Start)
if diags.HasErrors() {
return nil
}
call, diags := hcl.ExprCall(expr)
if diags.HasErrors() {
return nil
}
return call
default:
return nil
}
}
// Implementation for hcl.ExprList.
func (e *expression) ExprList() []hcl.Expression {
switch v := e.src.(type) {
case *arrayVal:
ret := make([]hcl.Expression, len(v.Values))
for i, node := range v.Values {
ret[i] = &expression{src: node}
}
return ret
default:
return nil
}
}
// Implementation for hcl.ExprMap.
func (e *expression) ExprMap() []hcl.KeyValuePair {
switch v := e.src.(type) {
case *objectVal:
ret := make([]hcl.KeyValuePair, len(v.Attrs))
for i, jsonAttr := range v.Attrs {
ret[i] = hcl.KeyValuePair{
Key: &expression{src: &stringVal{
Value: jsonAttr.Name,
SrcRange: jsonAttr.NameRange,
}},
Value: &expression{src: jsonAttr.Value},
}
}
return ret
default:
return nil
}
}