package copystructure import ( "errors" "reflect" "sync" "github.com/mitchellh/reflectwalk" ) // Copy returns a deep copy of v. func Copy(v interface{}) (interface{}, error) { return Config{}.Copy(v) } // CopierFunc is a function that knows how to deep copy a specific type. // Register these globally with the Copiers variable. type CopierFunc func(interface{}) (interface{}, error) // Copiers is a map of types that behave specially when they are copied. // If a type is found in this map while deep copying, this function // will be called to copy it instead of attempting to copy all fields. // // The key should be the type, obtained using: reflect.TypeOf(value with type). // // It is unsafe to write to this map after Copies have started. If you // are writing to this map while also copying, wrap all modifications to // this map as well as to Copy in a mutex. var Copiers map[reflect.Type]CopierFunc = make(map[reflect.Type]CopierFunc) // Must is a helper that wraps a call to a function returning // (interface{}, error) and panics if the error is non-nil. It is intended // for use in variable initializations and should only be used when a copy // error should be a crashing case. func Must(v interface{}, err error) interface{} { if err != nil { panic("copy error: " + err.Error()) } return v } var errPointerRequired = errors.New("Copy argument must be a pointer when Lock is true") type Config struct { // Lock any types that are a sync.Locker and are not a mutex while copying. // If there is an RLocker method, use that to get the sync.Locker. Lock bool // Copiers is a map of types associated with a CopierFunc. Use the global // Copiers map if this is nil. Copiers map[reflect.Type]CopierFunc } func (c Config) Copy(v interface{}) (interface{}, error) { if c.Lock && reflect.ValueOf(v).Kind() != reflect.Ptr { return nil, errPointerRequired } w := new(walker) if c.Lock { w.useLocks = true } if c.Copiers == nil { c.Copiers = Copiers } err := reflectwalk.Walk(v, w) if err != nil { return nil, err } // Get the result. If the result is nil, then we want to turn it // into a typed nil if we can. result := w.Result if result == nil { val := reflect.ValueOf(v) result = reflect.Indirect(reflect.New(val.Type())).Interface() } return result, nil } // Return the key used to index interfaces types we've seen. Store the number // of pointers in the upper 32bits, and the depth in the lower 32bits. This is // easy to calculate, easy to match a key with our current depth, and we don't // need to deal with initializing and cleaning up nested maps or slices. func ifaceKey(pointers, depth int) uint64 { return uint64(pointers)<<32 | uint64(depth) } type walker struct { Result interface{} depth int ignoreDepth int vals []reflect.Value cs []reflect.Value // This stores the number of pointers we've walked over, indexed by depth. ps []int // If an interface is indirected by a pointer, we need to know the type of // interface to create when creating the new value. Store the interface // types here, indexed by both the walk depth and the number of pointers // already seen at that depth. Use ifaceKey to calculate the proper uint64 // value. ifaceTypes map[uint64]reflect.Type // any locks we've taken, indexed by depth locks []sync.Locker // take locks while walking the structure useLocks bool } func (w *walker) Enter(l reflectwalk.Location) error { w.depth++ // ensure we have enough elements to index via w.depth for w.depth >= len(w.locks) { w.locks = append(w.locks, nil) } for len(w.ps) < w.depth+1 { w.ps = append(w.ps, 0) } return nil } func (w *walker) Exit(l reflectwalk.Location) error { locker := w.locks[w.depth] w.locks[w.depth] = nil if locker != nil { defer locker.Unlock() } // clear out pointers and interfaces as we exit the stack w.ps[w.depth] = 0 for k := range w.ifaceTypes { mask := uint64(^uint32(0)) if k&mask == uint64(w.depth) { delete(w.ifaceTypes, k) } } w.depth-- if w.ignoreDepth > w.depth { w.ignoreDepth = 0 } if w.ignoring() { return nil } switch l { case reflectwalk.Array: fallthrough case reflectwalk.Map: fallthrough case reflectwalk.Slice: w.replacePointerMaybe() // Pop map off our container w.cs = w.cs[:len(w.cs)-1] case reflectwalk.MapValue: // Pop off the key and value mv := w.valPop() mk := w.valPop() m := w.cs[len(w.cs)-1] // If mv is the zero value, SetMapIndex deletes the key form the map, // or in this case never adds it. We need to create a properly typed // zero value so that this key can be set. if !mv.IsValid() { mv = reflect.Zero(m.Elem().Type().Elem()) } m.Elem().SetMapIndex(mk, mv) case reflectwalk.ArrayElem: // Pop off the value and the index and set it on the array v := w.valPop() i := w.valPop().Interface().(int) if v.IsValid() { a := w.cs[len(w.cs)-1] ae := a.Elem().Index(i) // storing array as pointer on stack - so need Elem() call if ae.CanSet() { ae.Set(v) } } case reflectwalk.SliceElem: // Pop off the value and the index and set it on the slice v := w.valPop() i := w.valPop().Interface().(int) if v.IsValid() { s := w.cs[len(w.cs)-1] se := s.Elem().Index(i) if se.CanSet() { se.Set(v) } } case reflectwalk.Struct: w.replacePointerMaybe() // Remove the struct from the container stack w.cs = w.cs[:len(w.cs)-1] case reflectwalk.StructField: // Pop off the value and the field v := w.valPop() f := w.valPop().Interface().(reflect.StructField) if v.IsValid() { s := w.cs[len(w.cs)-1] sf := reflect.Indirect(s).FieldByName(f.Name) if sf.CanSet() { sf.Set(v) } } case reflectwalk.WalkLoc: // Clear out the slices for GC w.cs = nil w.vals = nil } return nil } func (w *walker) Map(m reflect.Value) error { if w.ignoring() { return nil } w.lock(m) // Create the map. If the map itself is nil, then just make a nil map var newMap reflect.Value if m.IsNil() { newMap = reflect.New(m.Type()) } else { newMap = wrapPtr(reflect.MakeMap(m.Type())) } w.cs = append(w.cs, newMap) w.valPush(newMap) return nil } func (w *walker) MapElem(m, k, v reflect.Value) error { return nil } func (w *walker) PointerEnter(v bool) error { if v { w.ps[w.depth]++ } return nil } func (w *walker) PointerExit(v bool) error { if v { w.ps[w.depth]-- } return nil } func (w *walker) Interface(v reflect.Value) error { if !v.IsValid() { return nil } if w.ifaceTypes == nil { w.ifaceTypes = make(map[uint64]reflect.Type) } w.ifaceTypes[ifaceKey(w.ps[w.depth], w.depth)] = v.Type() return nil } func (w *walker) Primitive(v reflect.Value) error { if w.ignoring() { return nil } w.lock(v) // IsValid verifies the v is non-zero and CanInterface verifies // that we're allowed to read this value (unexported fields). var newV reflect.Value if v.IsValid() && v.CanInterface() { newV = reflect.New(v.Type()) newV.Elem().Set(v) } w.valPush(newV) w.replacePointerMaybe() return nil } func (w *walker) Slice(s reflect.Value) error { if w.ignoring() { return nil } w.lock(s) var newS reflect.Value if s.IsNil() { newS = reflect.New(s.Type()) } else { newS = wrapPtr(reflect.MakeSlice(s.Type(), s.Len(), s.Cap())) } w.cs = append(w.cs, newS) w.valPush(newS) return nil } func (w *walker) SliceElem(i int, elem reflect.Value) error { if w.ignoring() { return nil } // We don't write the slice here because elem might still be // arbitrarily complex. Just record the index and continue on. w.valPush(reflect.ValueOf(i)) return nil } func (w *walker) Array(a reflect.Value) error { if w.ignoring() { return nil } w.lock(a) newA := reflect.New(a.Type()) w.cs = append(w.cs, newA) w.valPush(newA) return nil } func (w *walker) ArrayElem(i int, elem reflect.Value) error { if w.ignoring() { return nil } // We don't write the array here because elem might still be // arbitrarily complex. Just record the index and continue on. w.valPush(reflect.ValueOf(i)) return nil } func (w *walker) Struct(s reflect.Value) error { if w.ignoring() { return nil } w.lock(s) var v reflect.Value if c, ok := Copiers[s.Type()]; ok { // We have a Copier for this struct, so we use that copier to // get the copy, and we ignore anything deeper than this. w.ignoreDepth = w.depth dup, err := c(s.Interface()) if err != nil { return err } // We need to put a pointer to the value on the value stack, // so allocate a new pointer and set it. v = reflect.New(s.Type()) reflect.Indirect(v).Set(reflect.ValueOf(dup)) } else { // No copier, we copy ourselves and allow reflectwalk to guide // us deeper into the structure for copying. v = reflect.New(s.Type()) } // Push the value onto the value stack for setting the struct field, // and add the struct itself to the containers stack in case we walk // deeper so that its own fields can be modified. w.valPush(v) w.cs = append(w.cs, v) return nil } func (w *walker) StructField(f reflect.StructField, v reflect.Value) error { if w.ignoring() { return nil } // If PkgPath is non-empty, this is a private (unexported) field. // We do not set this unexported since the Go runtime doesn't allow us. if f.PkgPath != "" { return reflectwalk.SkipEntry } // Push the field onto the stack, we'll handle it when we exit // the struct field in Exit... w.valPush(reflect.ValueOf(f)) return nil } // ignore causes the walker to ignore any more values until we exit this on func (w *walker) ignore() { w.ignoreDepth = w.depth } func (w *walker) ignoring() bool { return w.ignoreDepth > 0 && w.depth >= w.ignoreDepth } func (w *walker) pointerPeek() bool { return w.ps[w.depth] > 0 } func (w *walker) valPop() reflect.Value { result := w.vals[len(w.vals)-1] w.vals = w.vals[:len(w.vals)-1] // If we're out of values, that means we popped everything off. In // this case, we reset the result so the next pushed value becomes // the result. if len(w.vals) == 0 { w.Result = nil } return result } func (w *walker) valPush(v reflect.Value) { w.vals = append(w.vals, v) // If we haven't set the result yet, then this is the result since // it is the first (outermost) value we're seeing. if w.Result == nil && v.IsValid() { w.Result = v.Interface() } } func (w *walker) replacePointerMaybe() { // Determine the last pointer value. If it is NOT a pointer, then // we need to push that onto the stack. if !w.pointerPeek() { w.valPush(reflect.Indirect(w.valPop())) return } v := w.valPop() // If the expected type is a pointer to an interface of any depth, // such as *interface{}, **interface{}, etc., then we need to convert // the value "v" from *CONCRETE to *interface{} so types match for // Set. // // Example if v is type *Foo where Foo is a struct, v would become // *interface{} instead. This only happens if we have an interface expectation // at this depth. // // For more info, see GH-16 if iType, ok := w.ifaceTypes[ifaceKey(w.ps[w.depth], w.depth)]; ok && iType.Kind() == reflect.Interface { y := reflect.New(iType) // Create *interface{} y.Elem().Set(reflect.Indirect(v)) // Assign "Foo" to interface{} (dereferenced) v = y // v is now typed *interface{} (where *v = Foo) } for i := 1; i < w.ps[w.depth]; i++ { if iType, ok := w.ifaceTypes[ifaceKey(w.ps[w.depth]-i, w.depth)]; ok { iface := reflect.New(iType).Elem() iface.Set(v) v = iface } p := reflect.New(v.Type()) p.Elem().Set(v) v = p } w.valPush(v) } // if this value is a Locker, lock it and add it to the locks slice func (w *walker) lock(v reflect.Value) { if !w.useLocks { return } if !v.IsValid() || !v.CanInterface() { return } type rlocker interface { RLocker() sync.Locker } var locker sync.Locker // We can't call Interface() on a value directly, since that requires // a copy. This is OK, since the pointer to a value which is a sync.Locker // is also a sync.Locker. if v.Kind() == reflect.Ptr { switch l := v.Interface().(type) { case rlocker: // don't lock a mutex directly if _, ok := l.(*sync.RWMutex); !ok { locker = l.RLocker() } case sync.Locker: locker = l } } else if v.CanAddr() { switch l := v.Addr().Interface().(type) { case rlocker: // don't lock a mutex directly if _, ok := l.(*sync.RWMutex); !ok { locker = l.RLocker() } case sync.Locker: locker = l } } // still no callable locker if locker == nil { return } // don't lock a mutex directly switch locker.(type) { case *sync.Mutex, *sync.RWMutex: return } locker.Lock() w.locks[w.depth] = locker } // wrapPtr is a helper that takes v and always make it *v. copystructure // stores things internally as pointers until the last moment before unwrapping func wrapPtr(v reflect.Value) reflect.Value { if !v.IsValid() { return v } vPtr := reflect.New(v.Type()) vPtr.Elem().Set(v) return vPtr }