k3d/vendor/sigs.k8s.io/yaml/yaml.go

/*
Copyright 2021 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 yaml

import (
	"bytes"
	"encoding/json"
	"fmt"
	"io"
	"reflect"
	"strconv"

	"sigs.k8s.io/yaml/goyaml.v2"
)

// Marshal marshals obj into JSON using stdlib json.Marshal, and then converts JSON to YAML using JSONToYAML (see that method for more reference)
func Marshal(obj interface{}) ([]byte, error) {
	jsonBytes, err := json.Marshal(obj)
	if err != nil {
		return nil, fmt.Errorf("error marshaling into JSON: %w", err)
	}

	return JSONToYAML(jsonBytes)
}

// JSONOpt is a decoding option for decoding from JSON format.
type JSONOpt func(*json.Decoder) *json.Decoder

// Unmarshal first converts the given YAML to JSON, and then unmarshals the JSON into obj. Options for the
// standard library json.Decoder can be optionally specified, e.g. to decode untyped numbers into json.Number instead of float64, or to disallow unknown fields (but for that purpose, see also UnmarshalStrict). obj must be a non-nil pointer.
//
// Important notes about the Unmarshal logic:
//
//   - Decoding is case-insensitive, unlike the rest of Kubernetes API machinery, as this is using the stdlib json library. This might be confusing to users.
//   - This decodes any number (although it is an integer) into a float64 if the type of obj is unknown, e.g. *map[string]interface{}, *interface{}, or *[]interface{}. This means integers above +/- 2^53 will lose precision when round-tripping. Make a JSONOpt that calls d.UseNumber() to avoid this.
//   - Duplicate fields, including in-case-sensitive matches, are ignored in an undefined order. Note that the YAML specification forbids duplicate fields, so this logic is more permissive than it needs to. See UnmarshalStrict for an alternative.
//   - Unknown fields, i.e. serialized data that do not map to a field in obj, are ignored. Use d.DisallowUnknownFields() or UnmarshalStrict to override.
//   - As per the YAML 1.1 specification, which yaml.v2 used underneath implements, literal 'yes' and 'no' strings without quotation marks will be converted to true/false implicitly.
//   - YAML non-string keys, e.g. ints, bools and floats, are converted to strings implicitly during the YAML to JSON conversion process.
//   - There are no compatibility guarantees for returned error values.
func Unmarshal(yamlBytes []byte, obj interface{}, opts ...JSONOpt) error {
	return unmarshal(yamlBytes, obj, yaml.Unmarshal, opts...)
}

// UnmarshalStrict is similar to Unmarshal (please read its documentation for reference), with the following exceptions:
//
//   - Duplicate fields in an object yield an error. This is according to the YAML specification.
//   - If obj, or any of its recursive children, is a struct, presence of fields in the serialized data unknown to the struct will yield an error.
func UnmarshalStrict(yamlBytes []byte, obj interface{}, opts ...JSONOpt) error {
	return unmarshal(yamlBytes, obj, yaml.UnmarshalStrict, append(opts, DisallowUnknownFields)...)
}

// unmarshal unmarshals the given YAML byte stream into the given interface,
// optionally performing the unmarshalling strictly
func unmarshal(yamlBytes []byte, obj interface{}, unmarshalFn func([]byte, interface{}) error, opts ...JSONOpt) error {
	jsonTarget := reflect.ValueOf(obj)

	jsonBytes, err := yamlToJSONTarget(yamlBytes, &jsonTarget, unmarshalFn)
	if err != nil {
		return fmt.Errorf("error converting YAML to JSON: %w", err)
	}

	err = jsonUnmarshal(bytes.NewReader(jsonBytes), obj, opts...)
	if err != nil {
		return fmt.Errorf("error unmarshaling JSON: %w", err)
	}

	return nil
}

// jsonUnmarshal unmarshals the JSON byte stream from the given reader into the
// object, optionally applying decoder options prior to decoding.  We are not
// using json.Unmarshal directly as we want the chance to pass in non-default
// options.
func jsonUnmarshal(reader io.Reader, obj interface{}, opts ...JSONOpt) error {
	d := json.NewDecoder(reader)
	for _, opt := range opts {
		d = opt(d)
	}
	if err := d.Decode(&obj); err != nil {
		return fmt.Errorf("while decoding JSON: %v", err)
	}
	return nil
}

// JSONToYAML converts JSON to YAML. Notable implementation details:
//
//   - Duplicate fields, are case-sensitively ignored in an undefined order.
//   - The sequence indentation style is compact, which means that the "- " marker for a YAML sequence will be on the same indentation level as the sequence field name.
//   - Unlike Unmarshal, all integers, up to 64 bits, are preserved during this round-trip.
func JSONToYAML(j []byte) ([]byte, error) {
	// Convert the JSON to an object.
	var jsonObj interface{}

	// We are using yaml.Unmarshal here (instead of json.Unmarshal) because the
	// Go JSON library doesn't try to pick the right number type (int, float,
	// etc.) when unmarshalling to interface{}, it just picks float64
	// universally. go-yaml does go through the effort of picking the right
	// number type, so we can preserve number type throughout this process.
	err := yaml.Unmarshal(j, &jsonObj)
	if err != nil {
		return nil, err
	}

	// Marshal this object into YAML.
	yamlBytes, err := yaml.Marshal(jsonObj)
	if err != nil {
		return nil, err
	}

	return yamlBytes, nil
}

// YAMLToJSON converts YAML to JSON. Since JSON is a subset of YAML,
// passing JSON through this method should be a no-op.
//
// Some things YAML can do that are not supported by JSON:
//   - In YAML you can have binary and null keys in your maps. These are invalid
//     in JSON, and therefore int, bool and float keys are converted to strings implicitly.
//   - Binary data in YAML with the !!binary tag is not supported. If you want to
//     use binary data with this library, encode the data as base64 as usual but do
//     not use the !!binary tag in your YAML. This will ensure the original base64
//     encoded data makes it all the way through to the JSON.
//   - And more... read the YAML specification for more details.
//
// Notable about the implementation:
//
// - Duplicate fields are case-sensitively ignored in an undefined order. Note that the YAML specification forbids duplicate fields, so this logic is more permissive than it needs to. See YAMLToJSONStrict for an alternative.
// - As per the YAML 1.1 specification, which yaml.v2 used underneath implements, literal 'yes' and 'no' strings without quotation marks will be converted to true/false implicitly.
// - Unlike Unmarshal, all integers, up to 64 bits, are preserved during this round-trip.
// - There are no compatibility guarantees for returned error values.
func YAMLToJSON(y []byte) ([]byte, error) {
	return yamlToJSONTarget(y, nil, yaml.Unmarshal)
}

// YAMLToJSONStrict is like YAMLToJSON but enables strict YAML decoding,
// returning an error on any duplicate field names.
func YAMLToJSONStrict(y []byte) ([]byte, error) {
	return yamlToJSONTarget(y, nil, yaml.UnmarshalStrict)
}

func yamlToJSONTarget(yamlBytes []byte, jsonTarget *reflect.Value, unmarshalFn func([]byte, interface{}) error) ([]byte, error) {
	// Convert the YAML to an object.
	var yamlObj interface{}
	err := unmarshalFn(yamlBytes, &yamlObj)
	if err != nil {
		return nil, err
	}

	// YAML objects are not completely compatible with JSON objects (e.g. you
	// can have non-string keys in YAML). So, convert the YAML-compatible object
	// to a JSON-compatible object, failing with an error if irrecoverable
	// incompatibilties happen along the way.
	jsonObj, err := convertToJSONableObject(yamlObj, jsonTarget)
	if err != nil {
		return nil, err
	}

	// Convert this object to JSON and return the data.
	jsonBytes, err := json.Marshal(jsonObj)
	if err != nil {
		return nil, err
	}
	return jsonBytes, nil
}

func convertToJSONableObject(yamlObj interface{}, jsonTarget *reflect.Value) (interface{}, error) {
	var err error

	// Resolve jsonTarget to a concrete value (i.e. not a pointer or an
	// interface). We pass decodingNull as false because we're not actually
	// decoding into the value, we're just checking if the ultimate target is a
	// string.
	if jsonTarget != nil {
		jsonUnmarshaler, textUnmarshaler, pointerValue := indirect(*jsonTarget, false)
		// We have a JSON or Text Umarshaler at this level, so we can't be trying
		// to decode into a string.
		if jsonUnmarshaler != nil || textUnmarshaler != nil {
			jsonTarget = nil
		} else {
			jsonTarget = &pointerValue
		}
	}

	// If yamlObj is a number or a boolean, check if jsonTarget is a string -
	// if so, coerce.  Else return normal.
	// If yamlObj is a map or array, find the field that each key is
	// unmarshaling to, and when you recurse pass the reflect.Value for that
	// field back into this function.
	switch typedYAMLObj := yamlObj.(type) {
	case map[interface{}]interface{}:
		// JSON does not support arbitrary keys in a map, so we must convert
		// these keys to strings.
		//
		// From my reading of go-yaml v2 (specifically the resolve function),
		// keys can only have the types string, int, int64, float64, binary
		// (unsupported), or null (unsupported).
		strMap := make(map[string]interface{})
		for k, v := range typedYAMLObj {
			// Resolve the key to a string first.
			var keyString string
			switch typedKey := k.(type) {
			case string:
				keyString = typedKey
			case int:
				keyString = strconv.Itoa(typedKey)
			case int64:
				// go-yaml will only return an int64 as a key if the system
				// architecture is 32-bit and the key's value is between 32-bit
				// and 64-bit. Otherwise the key type will simply be int.
				keyString = strconv.FormatInt(typedKey, 10)
			case float64:
				// Stolen from go-yaml to use the same conversion to string as
				// the go-yaml library uses to convert float to string when
				// Marshaling.
				s := strconv.FormatFloat(typedKey, 'g', -1, 32)
				switch s {
				case "+Inf":
					s = ".inf"
				case "-Inf":
					s = "-.inf"
				case "NaN":
					s = ".nan"
				}
				keyString = s
			case bool:
				if typedKey {
					keyString = "true"
				} else {
					keyString = "false"
				}
			default:
				return nil, fmt.Errorf("unsupported map key of type: %s, key: %+#v, value: %+#v",
					reflect.TypeOf(k), k, v)
			}

			// jsonTarget should be a struct or a map. If it's a struct, find
			// the field it's going to map to and pass its reflect.Value. If
			// it's a map, find the element type of the map and pass the
			// reflect.Value created from that type. If it's neither, just pass
			// nil - JSON conversion will error for us if it's a real issue.
			if jsonTarget != nil {
				t := *jsonTarget
				if t.Kind() == reflect.Struct {
					keyBytes := []byte(keyString)
					// Find the field that the JSON library would use.
					var f *field
					fields := cachedTypeFields(t.Type())
					for i := range fields {
						ff := &fields[i]
						if bytes.Equal(ff.nameBytes, keyBytes) {
							f = ff
							break
						}
						// Do case-insensitive comparison.
						if f == nil && ff.equalFold(ff.nameBytes, keyBytes) {
							f = ff
						}
					}
					if f != nil {
						// Find the reflect.Value of the most preferential
						// struct field.
						jtf := t.Field(f.index[0])
						strMap[keyString], err = convertToJSONableObject(v, &jtf)
						if err != nil {
							return nil, err
						}
						continue
					}
				} else if t.Kind() == reflect.Map {
					// Create a zero value of the map's element type to use as
					// the JSON target.
					jtv := reflect.Zero(t.Type().Elem())
					strMap[keyString], err = convertToJSONableObject(v, &jtv)
					if err != nil {
						return nil, err
					}
					continue
				}
			}
			strMap[keyString], err = convertToJSONableObject(v, nil)
			if err != nil {
				return nil, err
			}
		}
		return strMap, nil
	case []interface{}:
		// We need to recurse into arrays in case there are any
		// map[interface{}]interface{}'s inside and to convert any
		// numbers to strings.

		// If jsonTarget is a slice (which it really should be), find the
		// thing it's going to map to. If it's not a slice, just pass nil
		// - JSON conversion will error for us if it's a real issue.
		var jsonSliceElemValue *reflect.Value
		if jsonTarget != nil {
			t := *jsonTarget
			if t.Kind() == reflect.Slice {
				// By default slices point to nil, but we need a reflect.Value
				// pointing to a value of the slice type, so we create one here.
				ev := reflect.Indirect(reflect.New(t.Type().Elem()))
				jsonSliceElemValue = &ev
			}
		}

		// Make and use a new array.
		arr := make([]interface{}, len(typedYAMLObj))
		for i, v := range typedYAMLObj {
			arr[i], err = convertToJSONableObject(v, jsonSliceElemValue)
			if err != nil {
				return nil, err
			}
		}
		return arr, nil
	default:
		// If the target type is a string and the YAML type is a number,
		// convert the YAML type to a string.
		if jsonTarget != nil && (*jsonTarget).Kind() == reflect.String {
			// Based on my reading of go-yaml, it may return int, int64,
			// float64, or uint64.
			var s string
			switch typedVal := typedYAMLObj.(type) {
			case int:
				s = strconv.FormatInt(int64(typedVal), 10)
			case int64:
				s = strconv.FormatInt(typedVal, 10)
			case float64:
				s = strconv.FormatFloat(typedVal, 'g', -1, 32)
			case uint64:
				s = strconv.FormatUint(typedVal, 10)
			case bool:
				if typedVal {
					s = "true"
				} else {
					s = "false"
				}
			}
			if len(s) > 0 {
				yamlObj = interface{}(s)
			}
		}
		return yamlObj, nil
	}
}

// JSONObjectToYAMLObject converts an in-memory JSON object into a YAML in-memory MapSlice,
// without going through a byte representation. A nil or empty map[string]interface{} input is
// converted to an empty map, i.e. yaml.MapSlice(nil).
//
// interface{} slices stay interface{} slices. map[string]interface{} becomes yaml.MapSlice.
//
// int64 and float64 are down casted following the logic of github.com/go-yaml/yaml:
// - float64s are down-casted as far as possible without data-loss to int, int64, uint64.
// - int64s are down-casted to int if possible without data-loss.
//
// Big int/int64/uint64 do not lose precision as in the json-yaml roundtripping case.
//
// string, bool and any other types are unchanged.
func JSONObjectToYAMLObject(j map[string]interface{}) yaml.MapSlice {
	if len(j) == 0 {
		return nil
	}
	ret := make(yaml.MapSlice, 0, len(j))
	for k, v := range j {
		ret = append(ret, yaml.MapItem{Key: k, Value: jsonToYAMLValue(v)})
	}
	return ret
}

func jsonToYAMLValue(j interface{}) interface{} {
	switch j := j.(type) {
	case map[string]interface{}:
		if j == nil {
			return interface{}(nil)
		}
		return JSONObjectToYAMLObject(j)
	case []interface{}:
		if j == nil {
			return interface{}(nil)
		}
		ret := make([]interface{}, len(j))
		for i := range j {
			ret[i] = jsonToYAMLValue(j[i])
		}
		return ret
	case float64:
		// replicate the logic in https://github.com/go-yaml/yaml/blob/51d6538a90f86fe93ac480b35f37b2be17fef232/resolve.go#L151
		if i64 := int64(j); j == float64(i64) {
			if i := int(i64); i64 == int64(i) {
				return i
			}
			return i64
		}
		if ui64 := uint64(j); j == float64(ui64) {
			return ui64
		}
		return j
	case int64:
		if i := int(j); j == int64(i) {
			return i
		}
		return j
	}
	return j
}