kilo/vendor/sigs.k8s.io/controller-tools/pkg/crd/schema.go
leonnicolas 3eaacc01ae
go.*: Update k8s packages
- update k8s client_go
 - update k8s apiextensions-apiserver
 - update k8s controller-tools

Signed-off-by: leonnicolas <leonloechner@gmx.de>
2022-04-23 11:09:50 +02:00

457 lines
16 KiB
Go

/*
Copyright 2019 The Kubernetes Authors.
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
package crd
import (
"errors"
"fmt"
"go/ast"
"go/token"
"go/types"
"strings"
apiext "k8s.io/apiextensions-apiserver/pkg/apis/apiextensions/v1"
crdmarkers "sigs.k8s.io/controller-tools/pkg/crd/markers"
"sigs.k8s.io/controller-tools/pkg/loader"
"sigs.k8s.io/controller-tools/pkg/markers"
)
// Schema flattening is done in a recursive mapping method.
// Start reading at infoToSchema.
const (
// defPrefix is the prefix used to link to definitions in the OpenAPI schema.
defPrefix = "#/definitions/"
)
// byteType is the types.Type for byte (see the types documention
// for why we need to look this up in the Universe), saved
// for quick comparison.
var byteType = types.Universe.Lookup("byte").Type()
// SchemaMarker is any marker that needs to modify the schema of the underlying type or field.
type SchemaMarker interface {
// ApplyToSchema is called after the rest of the schema for a given type
// or field is generated, to modify the schema appropriately.
ApplyToSchema(*apiext.JSONSchemaProps) error
}
// applyFirstMarker is applied before any other markers. It's a bit of a hack.
type applyFirstMarker interface {
ApplyFirst()
}
// schemaRequester knows how to marker that another schema (e.g. via an external reference) is necessary.
type schemaRequester interface {
NeedSchemaFor(typ TypeIdent)
}
// schemaContext stores and provides information across a hierarchy of schema generation.
type schemaContext struct {
pkg *loader.Package
info *markers.TypeInfo
schemaRequester schemaRequester
PackageMarkers markers.MarkerValues
allowDangerousTypes bool
}
// newSchemaContext constructs a new schemaContext for the given package and schema requester.
// It must have type info added before use via ForInfo.
func newSchemaContext(pkg *loader.Package, req schemaRequester, allowDangerousTypes bool) *schemaContext {
pkg.NeedTypesInfo()
return &schemaContext{
pkg: pkg,
schemaRequester: req,
allowDangerousTypes: allowDangerousTypes,
}
}
// ForInfo produces a new schemaContext with containing the same information
// as this one, except with the given type information.
func (c *schemaContext) ForInfo(info *markers.TypeInfo) *schemaContext {
return &schemaContext{
pkg: c.pkg,
info: info,
schemaRequester: c.schemaRequester,
allowDangerousTypes: c.allowDangerousTypes,
}
}
// requestSchema asks for the schema for a type in the package with the
// given import path.
func (c *schemaContext) requestSchema(pkgPath, typeName string) {
pkg := c.pkg
if pkgPath != "" {
pkg = c.pkg.Imports()[pkgPath]
}
c.schemaRequester.NeedSchemaFor(TypeIdent{
Package: pkg,
Name: typeName,
})
}
// infoToSchema creates a schema for the type in the given set of type information.
func infoToSchema(ctx *schemaContext) *apiext.JSONSchemaProps {
// If the obj implements a JSON marshaler and has a marker, use the markers value and do not traverse as
// the marshaler could be doing anything. If there is no marker, fall back to traversing.
if obj := ctx.pkg.Types.Scope().Lookup(ctx.info.Name); obj != nil && implementsJSONMarshaler(obj.Type()) {
schema := &apiext.JSONSchemaProps{}
applyMarkers(ctx, ctx.info.Markers, schema, ctx.info.RawSpec.Type)
if schema.Type != "" {
return schema
}
}
return typeToSchema(ctx, ctx.info.RawSpec.Type)
}
// applyMarkers applies schema markers to the given schema, respecting "apply first" markers.
func applyMarkers(ctx *schemaContext, markerSet markers.MarkerValues, props *apiext.JSONSchemaProps, node ast.Node) {
// apply "apply first" markers first...
for _, markerValues := range markerSet {
for _, markerValue := range markerValues {
if _, isApplyFirst := markerValue.(applyFirstMarker); !isApplyFirst {
continue
}
schemaMarker, isSchemaMarker := markerValue.(SchemaMarker)
if !isSchemaMarker {
continue
}
if err := schemaMarker.ApplyToSchema(props); err != nil {
ctx.pkg.AddError(loader.ErrFromNode(err /* an okay guess */, node))
}
}
}
// ...then the rest of the markers
for _, markerValues := range markerSet {
for _, markerValue := range markerValues {
if _, isApplyFirst := markerValue.(applyFirstMarker); isApplyFirst {
// skip apply-first markers, which were already applied
continue
}
schemaMarker, isSchemaMarker := markerValue.(SchemaMarker)
if !isSchemaMarker {
continue
}
if err := schemaMarker.ApplyToSchema(props); err != nil {
ctx.pkg.AddError(loader.ErrFromNode(err /* an okay guess */, node))
}
}
}
}
// typeToSchema creates a schema for the given AST type.
func typeToSchema(ctx *schemaContext, rawType ast.Expr) *apiext.JSONSchemaProps {
var props *apiext.JSONSchemaProps
switch expr := rawType.(type) {
case *ast.Ident:
props = localNamedToSchema(ctx, expr)
case *ast.SelectorExpr:
props = namedToSchema(ctx, expr)
case *ast.ArrayType:
props = arrayToSchema(ctx, expr)
case *ast.MapType:
props = mapToSchema(ctx, expr)
case *ast.StarExpr:
props = typeToSchema(ctx, expr.X)
case *ast.StructType:
props = structToSchema(ctx, expr)
default:
ctx.pkg.AddError(loader.ErrFromNode(fmt.Errorf("unsupported AST kind %T", expr), rawType))
// NB(directxman12): we explicitly don't handle interfaces
return &apiext.JSONSchemaProps{}
}
props.Description = ctx.info.Doc
applyMarkers(ctx, ctx.info.Markers, props, rawType)
return props
}
// qualifiedName constructs a JSONSchema-safe qualified name for a type
// (`<typeName>` or `<safePkgPath>~0<typeName>`, where `<safePkgPath>`
// is the package path with `/` replaced by `~1`, according to JSONPointer
// escapes).
func qualifiedName(pkgName, typeName string) string {
if pkgName != "" {
return strings.Replace(pkgName, "/", "~1", -1) + "~0" + typeName
}
return typeName
}
// TypeRefLink creates a definition link for the given type and package.
func TypeRefLink(pkgName, typeName string) string {
return defPrefix + qualifiedName(pkgName, typeName)
}
// localNamedToSchema creates a schema (ref) for a *potentially* local type reference
// (could be external from a dot-import).
func localNamedToSchema(ctx *schemaContext, ident *ast.Ident) *apiext.JSONSchemaProps {
typeInfo := ctx.pkg.TypesInfo.TypeOf(ident)
if typeInfo == types.Typ[types.Invalid] {
ctx.pkg.AddError(loader.ErrFromNode(fmt.Errorf("unknown type %s", ident.Name), ident))
return &apiext.JSONSchemaProps{}
}
if basicInfo, isBasic := typeInfo.(*types.Basic); isBasic {
typ, fmt, err := builtinToType(basicInfo, ctx.allowDangerousTypes)
if err != nil {
ctx.pkg.AddError(loader.ErrFromNode(err, ident))
}
return &apiext.JSONSchemaProps{
Type: typ,
Format: fmt,
}
}
// NB(directxman12): if there are dot imports, this might be an external reference,
// so use typechecking info to get the actual object
typeNameInfo := typeInfo.(*types.Named).Obj()
pkg := typeNameInfo.Pkg()
pkgPath := loader.NonVendorPath(pkg.Path())
if pkg == ctx.pkg.Types {
pkgPath = ""
}
ctx.requestSchema(pkgPath, typeNameInfo.Name())
link := TypeRefLink(pkgPath, typeNameInfo.Name())
return &apiext.JSONSchemaProps{
Ref: &link,
}
}
// namedSchema creates a schema (ref) for an explicitly external type reference.
func namedToSchema(ctx *schemaContext, named *ast.SelectorExpr) *apiext.JSONSchemaProps {
typeInfoRaw := ctx.pkg.TypesInfo.TypeOf(named)
if typeInfoRaw == types.Typ[types.Invalid] {
ctx.pkg.AddError(loader.ErrFromNode(fmt.Errorf("unknown type %v.%s", named.X, named.Sel.Name), named))
return &apiext.JSONSchemaProps{}
}
typeInfo := typeInfoRaw.(*types.Named)
typeNameInfo := typeInfo.Obj()
nonVendorPath := loader.NonVendorPath(typeNameInfo.Pkg().Path())
ctx.requestSchema(nonVendorPath, typeNameInfo.Name())
link := TypeRefLink(nonVendorPath, typeNameInfo.Name())
return &apiext.JSONSchemaProps{
Ref: &link,
}
// NB(directxman12): we special-case things like resource.Quantity during the "collapse" phase.
}
// arrayToSchema creates a schema for the items of the given array, dealing appropriately
// with the special `[]byte` type (according to OpenAPI standards).
func arrayToSchema(ctx *schemaContext, array *ast.ArrayType) *apiext.JSONSchemaProps {
eltType := ctx.pkg.TypesInfo.TypeOf(array.Elt)
if eltType == byteType && array.Len == nil {
// byte slices are represented as base64-encoded strings
// (the format is defined in OpenAPI v3, but not JSON Schema)
return &apiext.JSONSchemaProps{
Type: "string",
Format: "byte",
}
}
// TODO(directxman12): backwards-compat would require access to markers from base info
items := typeToSchema(ctx.ForInfo(&markers.TypeInfo{}), array.Elt)
return &apiext.JSONSchemaProps{
Type: "array",
Items: &apiext.JSONSchemaPropsOrArray{Schema: items},
}
}
// mapToSchema creates a schema for items of the given map. Key types must eventually resolve
// to string (other types aren't allowed by JSON, and thus the kubernetes API standards).
func mapToSchema(ctx *schemaContext, mapType *ast.MapType) *apiext.JSONSchemaProps {
keyInfo := ctx.pkg.TypesInfo.TypeOf(mapType.Key)
// check that we've got a type that actually corresponds to a string
for keyInfo != nil {
switch typedKey := keyInfo.(type) {
case *types.Basic:
if typedKey.Info()&types.IsString == 0 {
ctx.pkg.AddError(loader.ErrFromNode(fmt.Errorf("map keys must be strings, not %s", keyInfo.String()), mapType.Key))
return &apiext.JSONSchemaProps{}
}
keyInfo = nil // stop iterating
case *types.Named:
keyInfo = typedKey.Underlying()
default:
ctx.pkg.AddError(loader.ErrFromNode(fmt.Errorf("map keys must be strings, not %s", keyInfo.String()), mapType.Key))
return &apiext.JSONSchemaProps{}
}
}
// TODO(directxman12): backwards-compat would require access to markers from base info
var valSchema *apiext.JSONSchemaProps
switch val := mapType.Value.(type) {
case *ast.Ident:
valSchema = localNamedToSchema(ctx.ForInfo(&markers.TypeInfo{}), val)
case *ast.SelectorExpr:
valSchema = namedToSchema(ctx.ForInfo(&markers.TypeInfo{}), val)
case *ast.ArrayType:
valSchema = arrayToSchema(ctx.ForInfo(&markers.TypeInfo{}), val)
case *ast.StarExpr:
valSchema = typeToSchema(ctx.ForInfo(&markers.TypeInfo{}), val)
case *ast.MapType:
valSchema = typeToSchema(ctx.ForInfo(&markers.TypeInfo{}), val)
default:
ctx.pkg.AddError(loader.ErrFromNode(fmt.Errorf("not a supported map value type: %T", mapType.Value), mapType.Value))
return &apiext.JSONSchemaProps{}
}
return &apiext.JSONSchemaProps{
Type: "object",
AdditionalProperties: &apiext.JSONSchemaPropsOrBool{
Schema: valSchema,
Allows: true, /* set automatically by serialization, but useful for testing */
},
}
}
// structToSchema creates a schema for the given struct. Embedded fields are placed in AllOf,
// and can be flattened later with a Flattener.
func structToSchema(ctx *schemaContext, structType *ast.StructType) *apiext.JSONSchemaProps {
props := &apiext.JSONSchemaProps{
Type: "object",
Properties: make(map[string]apiext.JSONSchemaProps),
}
if ctx.info.RawSpec.Type != structType {
ctx.pkg.AddError(loader.ErrFromNode(fmt.Errorf("encountered non-top-level struct (possibly embedded), those aren't allowed"), structType))
return props
}
for _, field := range ctx.info.Fields {
jsonTag, hasTag := field.Tag.Lookup("json")
if !hasTag {
// if the field doesn't have a JSON tag, it doesn't belong in output (and shouldn't exist in a serialized type)
ctx.pkg.AddError(loader.ErrFromNode(fmt.Errorf("encountered struct field %q without JSON tag in type %q", field.Name, ctx.info.Name), field.RawField))
continue
}
jsonOpts := strings.Split(jsonTag, ",")
if len(jsonOpts) == 1 && jsonOpts[0] == "-" {
// skipped fields have the tag "-" (note that "-," means the field is named "-")
continue
}
inline := false
omitEmpty := false
for _, opt := range jsonOpts[1:] {
switch opt {
case "inline":
inline = true
case "omitempty":
omitEmpty = true
}
}
fieldName := jsonOpts[0]
inline = inline || fieldName == "" // anonymous fields are inline fields in YAML/JSON
// if no default required mode is set, default to required
defaultMode := "required"
if ctx.PackageMarkers.Get("kubebuilder:validation:Optional") != nil {
defaultMode = "optional"
}
switch defaultMode {
// if this package isn't set to optional default...
case "required":
// ...everything that's not inline, omitempty, or explicitly optional is required
if !inline && !omitEmpty && field.Markers.Get("kubebuilder:validation:Optional") == nil && field.Markers.Get("optional") == nil {
props.Required = append(props.Required, fieldName)
}
// if this package isn't set to required default...
case "optional":
// ...everything that isn't explicitly required is optional
if field.Markers.Get("kubebuilder:validation:Required") != nil {
props.Required = append(props.Required, fieldName)
}
}
var propSchema *apiext.JSONSchemaProps
if field.Markers.Get(crdmarkers.SchemalessName) != nil {
propSchema = &apiext.JSONSchemaProps{}
} else {
propSchema = typeToSchema(ctx.ForInfo(&markers.TypeInfo{}), field.RawField.Type)
}
propSchema.Description = field.Doc
applyMarkers(ctx, field.Markers, propSchema, field.RawField)
if inline {
props.AllOf = append(props.AllOf, *propSchema)
continue
}
props.Properties[fieldName] = *propSchema
}
return props
}
// builtinToType converts builtin basic types to their equivalent JSON schema form.
// It *only* handles types allowed by the kubernetes API standards. Floats are not
// allowed unless allowDangerousTypes is true
func builtinToType(basic *types.Basic, allowDangerousTypes bool) (typ string, format string, err error) {
// NB(directxman12): formats from OpenAPI v3 are slightly different than those defined
// in JSONSchema. This'll use the OpenAPI v3 ones, since they're useful for bounding our
// non-string types.
basicInfo := basic.Info()
switch {
case basicInfo&types.IsBoolean != 0:
typ = "boolean"
case basicInfo&types.IsString != 0:
typ = "string"
case basicInfo&types.IsInteger != 0:
typ = "integer"
case basicInfo&types.IsFloat != 0:
if allowDangerousTypes {
typ = "number"
} else {
return "", "", errors.New("found float, the usage of which is highly discouraged, as support for them varies across languages. Please consider serializing your float as string instead. If you are really sure you want to use them, re-run with crd:allowDangerousTypes=true")
}
default:
return "", "", fmt.Errorf("unsupported type %q", basic.String())
}
switch basic.Kind() {
case types.Int32, types.Uint32:
format = "int32"
case types.Int64, types.Uint64:
format = "int64"
}
return typ, format, nil
}
// Open coded go/types representation of encoding/json.Marshaller
var jsonMarshaler = types.NewInterfaceType([]*types.Func{
types.NewFunc(token.NoPos, nil, "MarshalJSON",
types.NewSignature(nil, nil,
types.NewTuple(
types.NewVar(token.NoPos, nil, "", types.NewSlice(types.Universe.Lookup("byte").Type())),
types.NewVar(token.NoPos, nil, "", types.Universe.Lookup("error").Type())), false)),
}, nil).Complete()
func implementsJSONMarshaler(typ types.Type) bool {
return types.Implements(typ, jsonMarshaler) || types.Implements(types.NewPointer(typ), jsonMarshaler)
}