// Copyright (c) 2020 Tailscale Inc & AUTHORS All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package deephash hashes a Go value recursively, in a predictable // order, without looping. package deephash import ( "bufio" "crypto/sha256" "fmt" "hash" "reflect" "sync" "inet.af/netaddr" "tailscale.com/tailcfg" "tailscale.com/types/wgkey" ) func Hash(v ...interface{}) string { h := sha256.New() // 64 matches the chunk size in crypto/sha256/sha256.go b := bufio.NewWriterSize(h, 64) Print(b, v) b.Flush() return fmt.Sprintf("%x", h.Sum(nil)) } // UpdateHash sets last to the hash of v and reports whether its value changed. func UpdateHash(last *string, v ...interface{}) (changed bool) { sig := Hash(v) if *last != sig { *last = sig return true } return false } func Print(w *bufio.Writer, v ...interface{}) { print(w, reflect.ValueOf(v), make(map[uintptr]bool)) } var ( netaddrIPType = reflect.TypeOf(netaddr.IP{}) netaddrIPPrefix = reflect.TypeOf(netaddr.IPPrefix{}) wgkeyKeyType = reflect.TypeOf(wgkey.Key{}) wgkeyPrivateType = reflect.TypeOf(wgkey.Private{}) tailcfgDiscoKeyType = reflect.TypeOf(tailcfg.DiscoKey{}) ) // print hashes v into w. // It reports whether it was able to do so without hitting a cycle. func print(w *bufio.Writer, v reflect.Value, visited map[uintptr]bool) (acyclic bool) { if !v.IsValid() { return true } // Special case some common types. if v.CanInterface() { switch v.Type() { case netaddrIPType: var b []byte var err error if v.CanAddr() { x := v.Addr().Interface().(*netaddr.IP) b, err = x.MarshalText() } else { x := v.Interface().(netaddr.IP) b, err = x.MarshalText() } if err == nil { w.Write(b) return true } case netaddrIPPrefix: var b []byte var err error if v.CanAddr() { x := v.Addr().Interface().(*netaddr.IPPrefix) b, err = x.MarshalText() } else { x := v.Interface().(netaddr.IPPrefix) b, err = x.MarshalText() } if err == nil { w.Write(b) return true } case wgkeyKeyType: if v.CanAddr() { x := v.Addr().Interface().(*wgkey.Key) w.Write(x[:]) } else { x := v.Interface().(wgkey.Key) w.Write(x[:]) } return true case wgkeyPrivateType: if v.CanAddr() { x := v.Addr().Interface().(*wgkey.Private) w.Write(x[:]) } else { x := v.Interface().(wgkey.Private) w.Write(x[:]) } return true case tailcfgDiscoKeyType: if v.CanAddr() { x := v.Addr().Interface().(*tailcfg.DiscoKey) w.Write(x[:]) } else { x := v.Interface().(tailcfg.DiscoKey) w.Write(x[:]) } return true } } // Generic handling. switch v.Kind() { default: panic(fmt.Sprintf("unhandled kind %v for type %v", v.Kind(), v.Type())) case reflect.Ptr: ptr := v.Pointer() if visited[ptr] { return false } visited[ptr] = true return print(w, v.Elem(), visited) case reflect.Struct: acyclic = true w.WriteString("struct{\n") for i, n := 0, v.NumField(); i < n; i++ { fmt.Fprintf(w, " [%d]: ", i) if !print(w, v.Field(i), visited) { acyclic = false } w.WriteString("\n") } w.WriteString("}\n") return acyclic case reflect.Slice, reflect.Array: if v.Type().Elem().Kind() == reflect.Uint8 && v.CanInterface() { fmt.Fprintf(w, "%q", v.Interface()) return true } fmt.Fprintf(w, "[%d]{\n", v.Len()) acyclic = true for i, ln := 0, v.Len(); i < ln; i++ { fmt.Fprintf(w, " [%d]: ", i) if !print(w, v.Index(i), visited) { acyclic = false } w.WriteString("\n") } w.WriteString("}\n") return acyclic case reflect.Interface: return print(w, v.Elem(), visited) case reflect.Map: if hashMapAcyclic(w, v, visited) { return true } return hashMapFallback(w, v, visited) case reflect.String: w.WriteString(v.String()) case reflect.Bool: fmt.Fprintf(w, "%v", v.Bool()) case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: fmt.Fprintf(w, "%v", v.Int()) case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr: fmt.Fprintf(w, "%v", v.Uint()) case reflect.Float32, reflect.Float64: fmt.Fprintf(w, "%v", v.Float()) case reflect.Complex64, reflect.Complex128: fmt.Fprintf(w, "%v", v.Complex()) } return true } type mapHasher struct { xbuf [sha256.Size]byte // XOR'ed accumulated buffer ebuf [sha256.Size]byte // scratch buffer s256 hash.Hash // sha256 hash.Hash bw *bufio.Writer // to hasher into ebuf } func (mh *mapHasher) Reset() { for i := range mh.xbuf { mh.xbuf[i] = 0 } } func (mh *mapHasher) startEntry() { for i := range mh.ebuf { mh.ebuf[i] = 0 } mh.bw.Flush() mh.s256.Reset() } func (mh *mapHasher) endEntry() { mh.bw.Flush() for i, b := range mh.s256.Sum(mh.ebuf[:0]) { mh.xbuf[i] ^= b } } var mapHasherPool = &sync.Pool{ New: func() interface{} { mh := new(mapHasher) mh.s256 = sha256.New() mh.bw = bufio.NewWriter(mh.s256) return mh }, } // hashMapAcyclic is the faster sort-free version of map hashing. If // it detects a cycle it returns false and guarantees that nothing was // written to w. func hashMapAcyclic(w *bufio.Writer, v reflect.Value, visited map[uintptr]bool) (acyclic bool) { mh := mapHasherPool.Get().(*mapHasher) defer mapHasherPool.Put(mh) mh.Reset() iter := v.MapRange() for iter.Next() { mh.startEntry() if !print(mh.bw, iter.Key(), visited) { return false } if !print(mh.bw, iter.Value(), visited) { return false } mh.endEntry() } w.Write(mh.xbuf[:]) return true } func hashMapFallback(w *bufio.Writer, v reflect.Value, visited map[uintptr]bool) (acyclic bool) { acyclic = true sm := newSortedMap(v) fmt.Fprintf(w, "map[%d]{\n", len(sm.Key)) for i, k := range sm.Key { if !print(w, k, visited) { acyclic = false } w.WriteString(": ") if !print(w, sm.Value[i], visited) { acyclic = false } w.WriteString("\n") } w.WriteString("}\n") return acyclic }