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patch.go
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patch.go
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/*
Copyright 2014 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 strategicpatch
import (
"fmt"
"reflect"
"sort"
"k8s.io/kubernetes/pkg/util/json"
forkedjson "k8s.io/kubernetes/third_party/forked/golang/json"
"github.com/davecgh/go-spew/spew"
"github.com/ghodss/yaml"
)
// An alternate implementation of JSON Merge Patch
// (https://tools.ietf.org/html/rfc7386) which supports the ability to annotate
// certain fields with metadata that indicates whether the elements of JSON
// lists should be merged or replaced.
//
// For more information, see the PATCH section of docs/devel/api-conventions.md.
//
// Some of the content of this package was borrowed with minor adaptations from
// evanphx/json-patch and openshift/origin.
const (
directiveMarker = "$patch"
deleteDirective = "delete"
replaceDirective = "replace"
mergeDirective = "merge"
)
// IsPreconditionFailed returns true if the provided error indicates
// a precondition failed.
func IsPreconditionFailed(err error) bool {
_, ok := err.(errPreconditionFailed)
return ok
}
type errPreconditionFailed struct {
message string
}
func newErrPreconditionFailed(target map[string]interface{}) errPreconditionFailed {
s := fmt.Sprintf("precondition failed for: %v", target)
return errPreconditionFailed{s}
}
func (err errPreconditionFailed) Error() string {
return err.message
}
type errConflict struct {
message string
}
func newErrConflict(patch, current string) errConflict {
s := fmt.Sprintf("patch:\n%s\nconflicts with changes made from original to current:\n%s\n", patch, current)
return errConflict{s}
}
func (err errConflict) Error() string {
return err.message
}
// IsConflict returns true if the provided error indicates
// a conflict between the patch and the current configuration.
func IsConflict(err error) bool {
_, ok := err.(errConflict)
return ok
}
var errBadJSONDoc = fmt.Errorf("Invalid JSON document")
var errNoListOfLists = fmt.Errorf("Lists of lists are not supported")
// The following code is adapted from github.com/openshift/origin/pkg/util/jsonmerge.
// Instead of defining a Delta that holds an original, a patch and a set of preconditions,
// the reconcile method accepts a set of preconditions as an argument.
// PreconditionFunc asserts that an incompatible change is not present within a patch.
type PreconditionFunc func(interface{}) bool
// RequireKeyUnchanged returns a precondition function that fails if the provided key
// is present in the patch (indicating that its value has changed).
func RequireKeyUnchanged(key string) PreconditionFunc {
return func(patch interface{}) bool {
patchMap, ok := patch.(map[string]interface{})
if !ok {
return true
}
// The presence of key means that its value has been changed, so the test fails.
_, ok = patchMap[key]
return !ok
}
}
// Deprecated: Use the synonym CreateTwoWayMergePatch, instead.
func CreateStrategicMergePatch(original, modified []byte, dataStruct interface{}) ([]byte, error) {
return CreateTwoWayMergePatch(original, modified, dataStruct)
}
// CreateTwoWayMergePatch creates a patch that can be passed to StrategicMergePatch from an original
// document and a modified document, which are passed to the method as json encoded content. It will
// return a patch that yields the modified document when applied to the original document, or an error
// if either of the two documents is invalid.
func CreateTwoWayMergePatch(original, modified []byte, dataStruct interface{}, fns ...PreconditionFunc) ([]byte, error) {
originalMap := map[string]interface{}{}
if len(original) > 0 {
if err := json.Unmarshal(original, &originalMap); err != nil {
return nil, errBadJSONDoc
}
}
modifiedMap := map[string]interface{}{}
if len(modified) > 0 {
if err := json.Unmarshal(modified, &modifiedMap); err != nil {
return nil, errBadJSONDoc
}
}
t, err := getTagStructType(dataStruct)
if err != nil {
return nil, err
}
patchMap, err := diffMaps(originalMap, modifiedMap, t, false, false)
if err != nil {
return nil, err
}
// Apply the preconditions to the patch, and return an error if any of them fail.
for _, fn := range fns {
if !fn(patchMap) {
return nil, newErrPreconditionFailed(patchMap)
}
}
return json.Marshal(patchMap)
}
// Returns a (recursive) strategic merge patch that yields modified when applied to original.
func diffMaps(original, modified map[string]interface{}, t reflect.Type, ignoreChangesAndAdditions, ignoreDeletions bool) (map[string]interface{}, error) {
patch := map[string]interface{}{}
if t.Kind() == reflect.Ptr {
t = t.Elem()
}
for key, modifiedValue := range modified {
originalValue, ok := original[key]
if !ok {
// Key was added, so add to patch
if !ignoreChangesAndAdditions {
patch[key] = modifiedValue
}
continue
}
if key == directiveMarker {
originalString, ok := originalValue.(string)
if !ok {
return nil, fmt.Errorf("invalid value for special key: %s", directiveMarker)
}
modifiedString, ok := modifiedValue.(string)
if !ok {
return nil, fmt.Errorf("invalid value for special key: %s", directiveMarker)
}
if modifiedString != originalString {
patch[directiveMarker] = modifiedValue
}
continue
}
if reflect.TypeOf(originalValue) != reflect.TypeOf(modifiedValue) {
// Types have changed, so add to patch
if !ignoreChangesAndAdditions {
patch[key] = modifiedValue
}
continue
}
// Types are the same, so compare values
switch originalValueTyped := originalValue.(type) {
case map[string]interface{}:
modifiedValueTyped := modifiedValue.(map[string]interface{})
fieldType, _, _, err := forkedjson.LookupPatchMetadata(t, key)
if err != nil {
return nil, err
}
patchValue, err := diffMaps(originalValueTyped, modifiedValueTyped, fieldType, ignoreChangesAndAdditions, ignoreDeletions)
if err != nil {
return nil, err
}
if len(patchValue) > 0 {
patch[key] = patchValue
}
continue
case []interface{}:
modifiedValueTyped := modifiedValue.([]interface{})
fieldType, fieldPatchStrategy, fieldPatchMergeKey, err := forkedjson.LookupPatchMetadata(t, key)
if err != nil {
return nil, err
}
if fieldPatchStrategy == mergeDirective {
patchValue, err := diffLists(originalValueTyped, modifiedValueTyped, fieldType.Elem(), fieldPatchMergeKey, ignoreChangesAndAdditions, ignoreDeletions)
if err != nil {
return nil, err
}
if len(patchValue) > 0 {
patch[key] = patchValue
}
continue
}
}
if !ignoreChangesAndAdditions {
if !reflect.DeepEqual(originalValue, modifiedValue) {
// Values are different, so add to patch
patch[key] = modifiedValue
}
}
}
if !ignoreDeletions {
// Add nils for deleted values
for key := range original {
_, found := modified[key]
if !found {
patch[key] = nil
}
}
}
return patch, nil
}
// Returns a (recursive) strategic merge patch that yields modified when applied to original,
// for a pair of lists with merge semantics.
func diffLists(original, modified []interface{}, t reflect.Type, mergeKey string, ignoreChangesAndAdditions, ignoreDeletions bool) ([]interface{}, error) {
if len(original) == 0 {
if len(modified) == 0 || ignoreChangesAndAdditions {
return nil, nil
}
return modified, nil
}
elementType, err := sliceElementType(original, modified)
if err != nil {
return nil, err
}
var patch []interface{}
if elementType.Kind() == reflect.Map {
patch, err = diffListsOfMaps(original, modified, t, mergeKey, ignoreChangesAndAdditions, ignoreDeletions)
} else if !ignoreChangesAndAdditions {
patch, err = diffListsOfScalars(original, modified)
}
if err != nil {
return nil, err
}
return patch, nil
}
// Returns a (recursive) strategic merge patch that yields modified when applied to original,
// for a pair of lists of scalars with merge semantics.
func diffListsOfScalars(original, modified []interface{}) ([]interface{}, error) {
if len(modified) == 0 {
// There is no need to check the length of original because there is no way to create
// a patch that deletes a scalar from a list of scalars with merge semantics.
return nil, nil
}
patch := []interface{}{}
originalScalars := uniqifyAndSortScalars(original)
modifiedScalars := uniqifyAndSortScalars(modified)
originalIndex, modifiedIndex := 0, 0
loopB:
for ; modifiedIndex < len(modifiedScalars); modifiedIndex++ {
for ; originalIndex < len(originalScalars); originalIndex++ {
originalString := fmt.Sprintf("%v", original[originalIndex])
modifiedString := fmt.Sprintf("%v", modified[modifiedIndex])
if originalString >= modifiedString {
if originalString != modifiedString {
patch = append(patch, modified[modifiedIndex])
}
continue loopB
}
// There is no else clause because there is no way to create a patch that deletes
// a scalar from a list of scalars with merge semantics.
}
break
}
// Add any remaining items found only in modified
for ; modifiedIndex < len(modifiedScalars); modifiedIndex++ {
patch = append(patch, modified[modifiedIndex])
}
return patch, nil
}
var errNoMergeKeyFmt = "map: %v does not contain declared merge key: %s"
var errBadArgTypeFmt = "expected a %s, but received a %s"
// Returns a (recursive) strategic merge patch that yields modified when applied to original,
// for a pair of lists of maps with merge semantics.
func diffListsOfMaps(original, modified []interface{}, t reflect.Type, mergeKey string, ignoreChangesAndAdditions, ignoreDeletions bool) ([]interface{}, error) {
patch := make([]interface{}, 0)
originalSorted, err := sortMergeListsByNameArray(original, t, mergeKey, false)
if err != nil {
return nil, err
}
modifiedSorted, err := sortMergeListsByNameArray(modified, t, mergeKey, false)
if err != nil {
return nil, err
}
originalIndex, modifiedIndex := 0, 0
loopB:
for ; modifiedIndex < len(modifiedSorted); modifiedIndex++ {
modifiedMap, ok := modifiedSorted[modifiedIndex].(map[string]interface{})
if !ok {
t := reflect.TypeOf(modifiedSorted[modifiedIndex])
return nil, fmt.Errorf(errBadArgTypeFmt, "map[string]interface{}", t.Kind().String())
}
modifiedValue, ok := modifiedMap[mergeKey]
if !ok {
return nil, fmt.Errorf(errNoMergeKeyFmt, modifiedMap, mergeKey)
}
for ; originalIndex < len(originalSorted); originalIndex++ {
originalMap, ok := originalSorted[originalIndex].(map[string]interface{})
if !ok {
t := reflect.TypeOf(originalSorted[originalIndex])
return nil, fmt.Errorf(errBadArgTypeFmt, "map[string]interface{}", t.Kind().String())
}
originalValue, ok := originalMap[mergeKey]
if !ok {
return nil, fmt.Errorf(errNoMergeKeyFmt, originalMap, mergeKey)
}
// Assume that the merge key values are comparable strings
originalString := fmt.Sprintf("%v", originalValue)
modifiedString := fmt.Sprintf("%v", modifiedValue)
if originalString >= modifiedString {
if originalString == modifiedString {
// Merge key values are equal, so recurse
patchValue, err := diffMaps(originalMap, modifiedMap, t, ignoreChangesAndAdditions, ignoreDeletions)
if err != nil {
return nil, err
}
originalIndex++
if len(patchValue) > 0 {
patchValue[mergeKey] = modifiedValue
patch = append(patch, patchValue)
}
} else if !ignoreChangesAndAdditions {
// Item was added, so add to patch
patch = append(patch, modifiedMap)
}
continue loopB
}
if !ignoreDeletions {
// Item was deleted, so add delete directive
patch = append(patch, map[string]interface{}{mergeKey: originalValue, directiveMarker: deleteDirective})
}
}
break
}
if !ignoreDeletions {
// Delete any remaining items found only in original
for ; originalIndex < len(originalSorted); originalIndex++ {
originalMap, ok := originalSorted[originalIndex].(map[string]interface{})
if !ok {
t := reflect.TypeOf(originalSorted[originalIndex])
return nil, fmt.Errorf(errBadArgTypeFmt, "map[string]interface{}", t.Kind().String())
}
originalValue, ok := originalMap[mergeKey]
if !ok {
return nil, fmt.Errorf(errNoMergeKeyFmt, originalMap, mergeKey)
}
patch = append(patch, map[string]interface{}{mergeKey: originalValue, directiveMarker: deleteDirective})
}
}
if !ignoreChangesAndAdditions {
// Add any remaining items found only in modified
for ; modifiedIndex < len(modifiedSorted); modifiedIndex++ {
patch = append(patch, modifiedSorted[modifiedIndex])
}
}
return patch, nil
}
// Deprecated: StrategicMergePatchData is deprecated. Use the synonym StrategicMergePatch,
// instead, which follows the naming convention of evanphx/json-patch.
func StrategicMergePatchData(original, patch []byte, dataStruct interface{}) ([]byte, error) {
return StrategicMergePatch(original, patch, dataStruct)
}
// StrategicMergePatch applies a strategic merge patch. The patch and the original document
// must be json encoded content. A patch can be created from an original and a modified document
// by calling CreateStrategicMergePatch.
func StrategicMergePatch(original, patch []byte, dataStruct interface{}) ([]byte, error) {
if original == nil {
original = []byte("{}")
}
if patch == nil {
patch = []byte("{}")
}
originalMap := map[string]interface{}{}
err := json.Unmarshal(original, &originalMap)
if err != nil {
return nil, errBadJSONDoc
}
patchMap := map[string]interface{}{}
err = json.Unmarshal(patch, &patchMap)
if err != nil {
return nil, errBadJSONDoc
}
t, err := getTagStructType(dataStruct)
if err != nil {
return nil, err
}
result, err := mergeMap(originalMap, patchMap, t)
if err != nil {
return nil, err
}
return json.Marshal(result)
}
func getTagStructType(dataStruct interface{}) (reflect.Type, error) {
if dataStruct == nil {
return nil, fmt.Errorf(errBadArgTypeFmt, "struct", "nil")
}
t := reflect.TypeOf(dataStruct)
if t.Kind() == reflect.Ptr {
t = t.Elem()
}
if t.Kind() != reflect.Struct {
return nil, fmt.Errorf(errBadArgTypeFmt, "struct", t.Kind().String())
}
return t, nil
}
var errBadPatchTypeFmt = "unknown patch type: %s in map: %v"
// Merge fields from a patch map into the original map. Note: This may modify
// both the original map and the patch because getting a deep copy of a map in
// golang is highly non-trivial.
func mergeMap(original, patch map[string]interface{}, t reflect.Type) (map[string]interface{}, error) {
if v, ok := patch[directiveMarker]; ok {
if v == replaceDirective {
// If the patch contains "$patch: replace", don't merge it, just use the
// patch directly. Later on, we can add a single level replace that only
// affects the map that the $patch is in.
delete(patch, directiveMarker)
return patch, nil
}
if v == deleteDirective {
// If the patch contains "$patch: delete", don't merge it, just return
// an empty map.
return map[string]interface{}{}, nil
}
return nil, fmt.Errorf(errBadPatchTypeFmt, v, patch)
}
// nil is an accepted value for original to simplify logic in other places.
// If original is nil, replace it with an empty map and then apply the patch.
if original == nil {
original = map[string]interface{}{}
}
// Start merging the patch into the original.
for k, patchV := range patch {
// If the value of this key is null, delete the key if it exists in the
// original. Otherwise, skip it.
if patchV == nil {
if _, ok := original[k]; ok {
delete(original, k)
}
continue
}
_, ok := original[k]
if !ok {
// If it's not in the original document, just take the patch value.
original[k] = patchV
continue
}
// If the data type is a pointer, resolve the element.
if t.Kind() == reflect.Ptr {
t = t.Elem()
}
// If they're both maps or lists, recurse into the value.
originalType := reflect.TypeOf(original[k])
patchType := reflect.TypeOf(patchV)
if originalType == patchType {
// First find the fieldPatchStrategy and fieldPatchMergeKey.
fieldType, fieldPatchStrategy, fieldPatchMergeKey, err := forkedjson.LookupPatchMetadata(t, k)
if err != nil {
return nil, err
}
if originalType.Kind() == reflect.Map && fieldPatchStrategy != replaceDirective {
typedOriginal := original[k].(map[string]interface{})
typedPatch := patchV.(map[string]interface{})
var err error
original[k], err = mergeMap(typedOriginal, typedPatch, fieldType)
if err != nil {
return nil, err
}
continue
}
if originalType.Kind() == reflect.Slice && fieldPatchStrategy == mergeDirective {
elemType := fieldType.Elem()
typedOriginal := original[k].([]interface{})
typedPatch := patchV.([]interface{})
var err error
original[k], err = mergeSlice(typedOriginal, typedPatch, elemType, fieldPatchMergeKey)
if err != nil {
return nil, err
}
continue
}
}
// If originalType and patchType are different OR the types are both
// maps or slices but we're just supposed to replace them, just take
// the value from patch.
original[k] = patchV
}
return original, nil
}
// Merge two slices together. Note: This may modify both the original slice and
// the patch because getting a deep copy of a slice in golang is highly
// non-trivial.
func mergeSlice(original, patch []interface{}, elemType reflect.Type, mergeKey string) ([]interface{}, error) {
if len(original) == 0 && len(patch) == 0 {
return original, nil
}
// All the values must be of the same type, but not a list.
t, err := sliceElementType(original, patch)
if err != nil {
return nil, err
}
// If the elements are not maps, merge the slices of scalars.
if t.Kind() != reflect.Map {
// Maybe in the future add a "concat" mode that doesn't
// uniqify.
both := append(original, patch...)
return uniqifyScalars(both), nil
}
if mergeKey == "" {
return nil, fmt.Errorf("cannot merge lists without merge key for type %s", elemType.Kind().String())
}
// First look for any special $patch elements.
patchWithoutSpecialElements := []interface{}{}
replace := false
for _, v := range patch {
typedV := v.(map[string]interface{})
patchType, ok := typedV[directiveMarker]
if ok {
if patchType == deleteDirective {
mergeValue, ok := typedV[mergeKey]
if ok {
_, originalKey, found, err := findMapInSliceBasedOnKeyValue(original, mergeKey, mergeValue)
if err != nil {
return nil, err
}
if found {
// Delete the element at originalKey.
original = append(original[:originalKey], original[originalKey+1:]...)
}
} else {
return nil, fmt.Errorf("delete patch type with no merge key defined")
}
} else if patchType == replaceDirective {
replace = true
// Continue iterating through the array to prune any other $patch elements.
} else if patchType == mergeDirective {
return nil, fmt.Errorf("merging lists cannot yet be specified in the patch")
} else {
return nil, fmt.Errorf(errBadPatchTypeFmt, patchType, typedV)
}
} else {
patchWithoutSpecialElements = append(patchWithoutSpecialElements, v)
}
}
if replace {
return patchWithoutSpecialElements, nil
}
patch = patchWithoutSpecialElements
// Merge patch into original.
for _, v := range patch {
// Because earlier we confirmed that all the elements are maps.
typedV := v.(map[string]interface{})
mergeValue, ok := typedV[mergeKey]
if !ok {
return nil, fmt.Errorf(errNoMergeKeyFmt, typedV, mergeKey)
}
// If we find a value with this merge key value in original, merge the
// maps. Otherwise append onto original.
originalMap, originalKey, found, err := findMapInSliceBasedOnKeyValue(original, mergeKey, mergeValue)
if err != nil {
return nil, err
}
if found {
var mergedMaps interface{}
var err error
// Merge into original.
mergedMaps, err = mergeMap(originalMap, typedV, elemType)
if err != nil {
return nil, err
}
original[originalKey] = mergedMaps
} else {
original = append(original, v)
}
}
return original, nil
}
// This method no longer panics if any element of the slice is not a map.
func findMapInSliceBasedOnKeyValue(m []interface{}, key string, value interface{}) (map[string]interface{}, int, bool, error) {
for k, v := range m {
typedV, ok := v.(map[string]interface{})
if !ok {
return nil, 0, false, fmt.Errorf("value for key %v is not a map.", k)
}
valueToMatch, ok := typedV[key]
if ok && valueToMatch == value {
return typedV, k, true, nil
}
}
return nil, 0, false, nil
}
// This function takes a JSON map and sorts all the lists that should be merged
// by key. This is needed by tests because in JSON, list order is significant,
// but in Strategic Merge Patch, merge lists do not have significant order.
// Sorting the lists allows for order-insensitive comparison of patched maps.
func sortMergeListsByName(mapJSON []byte, dataStruct interface{}) ([]byte, error) {
var m map[string]interface{}
err := json.Unmarshal(mapJSON, &m)
if err != nil {
return nil, err
}
newM, err := sortMergeListsByNameMap(m, reflect.TypeOf(dataStruct))
if err != nil {
return nil, err
}
return json.Marshal(newM)
}
func sortMergeListsByNameMap(s map[string]interface{}, t reflect.Type) (map[string]interface{}, error) {
newS := map[string]interface{}{}
for k, v := range s {
if k != directiveMarker {
fieldType, fieldPatchStrategy, fieldPatchMergeKey, err := forkedjson.LookupPatchMetadata(t, k)
if err != nil {
return nil, err
}
// If v is a map or a merge slice, recurse.
if typedV, ok := v.(map[string]interface{}); ok {
var err error
v, err = sortMergeListsByNameMap(typedV, fieldType)
if err != nil {
return nil, err
}
} else if typedV, ok := v.([]interface{}); ok {
if fieldPatchStrategy == mergeDirective {
var err error
v, err = sortMergeListsByNameArray(typedV, fieldType.Elem(), fieldPatchMergeKey, true)
if err != nil {
return nil, err
}
}
}
}
newS[k] = v
}
return newS, nil
}
func sortMergeListsByNameArray(s []interface{}, elemType reflect.Type, mergeKey string, recurse bool) ([]interface{}, error) {
if len(s) == 0 {
return s, nil
}
// We don't support lists of lists yet.
t, err := sliceElementType(s)
if err != nil {
return nil, err
}
// If the elements are not maps...
if t.Kind() != reflect.Map {
// Sort the elements, because they may have been merged out of order.
return uniqifyAndSortScalars(s), nil
}
// Elements are maps - if one of the keys of the map is a map or a
// list, we may need to recurse into it.
newS := []interface{}{}
for _, elem := range s {
if recurse {
typedElem := elem.(map[string]interface{})
newElem, err := sortMergeListsByNameMap(typedElem, elemType)
if err != nil {
return nil, err
}
newS = append(newS, newElem)
} else {
newS = append(newS, elem)
}
}
// Sort the maps.
newS = sortMapsBasedOnField(newS, mergeKey)
return newS, nil
}
func sortMapsBasedOnField(m []interface{}, fieldName string) []interface{} {
mapM := mapSliceFromSlice(m)
ss := SortableSliceOfMaps{mapM, fieldName}
sort.Sort(ss)
newS := sliceFromMapSlice(ss.s)
return newS
}
func mapSliceFromSlice(m []interface{}) []map[string]interface{} {
newM := []map[string]interface{}{}
for _, v := range m {
vt := v.(map[string]interface{})
newM = append(newM, vt)
}
return newM
}
func sliceFromMapSlice(s []map[string]interface{}) []interface{} {
newS := []interface{}{}
for _, v := range s {
newS = append(newS, v)
}
return newS
}
type SortableSliceOfMaps struct {
s []map[string]interface{}
k string // key to sort on
}
func (ss SortableSliceOfMaps) Len() int {
return len(ss.s)
}
func (ss SortableSliceOfMaps) Less(i, j int) bool {
iStr := fmt.Sprintf("%v", ss.s[i][ss.k])
jStr := fmt.Sprintf("%v", ss.s[j][ss.k])
return sort.StringsAreSorted([]string{iStr, jStr})
}
func (ss SortableSliceOfMaps) Swap(i, j int) {
tmp := ss.s[i]
ss.s[i] = ss.s[j]
ss.s[j] = tmp
}
func uniqifyAndSortScalars(s []interface{}) []interface{} {
s = uniqifyScalars(s)
ss := SortableSliceOfScalars{s}
sort.Sort(ss)
return ss.s
}
func uniqifyScalars(s []interface{}) []interface{} {
// Clever algorithm to uniqify.
length := len(s) - 1
for i := 0; i < length; i++ {
for j := i + 1; j <= length; j++ {
if s[i] == s[j] {
s[j] = s[length]
s = s[0:length]
length--
j--
}
}
}
return s
}
type SortableSliceOfScalars struct {
s []interface{}
}
func (ss SortableSliceOfScalars) Len() int {
return len(ss.s)
}
func (ss SortableSliceOfScalars) Less(i, j int) bool {
iStr := fmt.Sprintf("%v", ss.s[i])
jStr := fmt.Sprintf("%v", ss.s[j])
return sort.StringsAreSorted([]string{iStr, jStr})
}
func (ss SortableSliceOfScalars) Swap(i, j int) {
tmp := ss.s[i]
ss.s[i] = ss.s[j]
ss.s[j] = tmp
}
// Returns the type of the elements of N slice(s). If the type is different,
// another slice or undefined, returns an error.
func sliceElementType(slices ...[]interface{}) (reflect.Type, error) {
var prevType reflect.Type
for _, s := range slices {
// Go through elements of all given slices and make sure they are all the same type.
for _, v := range s {
currentType := reflect.TypeOf(v)
if prevType == nil {
prevType = currentType
// We don't support lists of lists yet.
if prevType.Kind() == reflect.Slice {
return nil, errNoListOfLists
}
} else {
if prevType != currentType {
return nil, fmt.Errorf("list element types are not identical: %v", fmt.Sprint(slices))
}
prevType = currentType
}
}
}
if prevType == nil {
return nil, fmt.Errorf("no elements in any of the given slices")
}
return prevType, nil
}
// HasConflicts returns true if the left and right JSON interface objects overlap with
// different values in any key. All keys are required to be strings. Since patches of the
// same Type have congruent keys, this is valid for multiple patch types. This method
// supports JSON merge patch semantics.
func HasConflicts(left, right interface{}) (bool, error) {
switch typedLeft := left.(type) {
case map[string]interface{}:
switch typedRight := right.(type) {
case map[string]interface{}:
for key, leftValue := range typedLeft {
rightValue, ok := typedRight[key]
if !ok {
return false, nil
}
return HasConflicts(leftValue, rightValue)
}
return false, nil
default:
return true, nil
}
case []interface{}:
switch typedRight := right.(type) {
case []interface{}:
if len(typedLeft) != len(typedRight) {
return true, nil
}
for i := range typedLeft {
return HasConflicts(typedLeft[i], typedRight[i])
}
return false, nil
default:
return true, nil
}
case string, float64, bool, int, int64, nil:
return !reflect.DeepEqual(left, right), nil
default:
return true, fmt.Errorf("unknown type: %v", reflect.TypeOf(left))
}
}
// MergingMapsHaveConflicts returns true if the left and right JSON interface
// objects overlap with different values in any key. All keys are required to be
// strings. Since patches of the same Type have congruent keys, this is valid
// for multiple patch types. This method supports strategic merge patch semantics.
func MergingMapsHaveConflicts(left, right map[string]interface{}, dataStruct interface{}) (bool, error) {
t, err := getTagStructType(dataStruct)
if err != nil {
return true, err
}
return mergingMapFieldsHaveConflicts(left, right, t, "", "")
}
func mergingMapFieldsHaveConflicts(
left, right interface{},
fieldType reflect.Type,
fieldPatchStrategy, fieldPatchMergeKey string,
) (bool, error) {
switch leftType := left.(type) {
case map[string]interface{}:
switch rightType := right.(type) {
case map[string]interface{}:
leftMarker, okLeft := leftType[directiveMarker]
rightMarker, okRight := rightType[directiveMarker]
// if one or the other has a directive marker,