package msgpack import ( "bytes" "math/big" "sort" "github.com/vmihailenco/msgpack" "github.com/zclconf/go-cty/cty" "github.com/zclconf/go-cty/cty/convert" ) // Marshal produces a msgpack serialization of the given value that // can be decoded into the given type later using Unmarshal. // // The given value must conform to the given type, or an error will // be returned. func Marshal(val cty.Value, ty cty.Type) ([]byte, error) { errs := val.Type().TestConformance(ty) if errs != nil { // Attempt a conversion var err error val, err = convert.Convert(val, ty) if err != nil { return nil, err } } // From this point onward, val can be assumed to be conforming to t. var path cty.Path var buf bytes.Buffer enc := msgpack.NewEncoder(&buf) err := marshal(val, ty, path, enc) if err != nil { return nil, err } return buf.Bytes(), nil } func marshal(val cty.Value, ty cty.Type, path cty.Path, enc *msgpack.Encoder) error { if val.IsMarked() { return path.NewErrorf("value has marks, so it cannot be seralized") } // If we're going to decode as DynamicPseudoType then we need to save // dynamic type information to recover the real type. if ty == cty.DynamicPseudoType && val.Type() != cty.DynamicPseudoType { return marshalDynamic(val, path, enc) } if !val.IsKnown() { err := enc.Encode(unknownVal) if err != nil { return path.NewError(err) } return nil } if val.IsNull() { err := enc.EncodeNil() if err != nil { return path.NewError(err) } return nil } // The caller should've guaranteed that the given val is conformant with // the given type ty, so we'll proceed under that assumption here. switch { case ty.IsPrimitiveType(): switch ty { case cty.String: err := enc.EncodeString(val.AsString()) if err != nil { return path.NewError(err) } return nil case cty.Number: var err error switch { case val.RawEquals(cty.PositiveInfinity): err = enc.EncodeFloat64(positiveInfinity) case val.RawEquals(cty.NegativeInfinity): err = enc.EncodeFloat64(negativeInfinity) default: bf := val.AsBigFloat() if iv, acc := bf.Int64(); acc == big.Exact { err = enc.EncodeInt(iv) } else if fv, acc := bf.Float64(); acc == big.Exact { err = enc.EncodeFloat64(fv) } else { err = enc.EncodeString(bf.Text('f', -1)) } } if err != nil { return path.NewError(err) } return nil case cty.Bool: err := enc.EncodeBool(val.True()) if err != nil { return path.NewError(err) } return nil default: panic("unsupported primitive type") } case ty.IsListType(), ty.IsSetType(): enc.EncodeArrayLen(val.LengthInt()) ety := ty.ElementType() it := val.ElementIterator() path := append(path, nil) // local override of 'path' with extra element for it.Next() { ek, ev := it.Element() path[len(path)-1] = cty.IndexStep{ Key: ek, } err := marshal(ev, ety, path, enc) if err != nil { return err } } return nil case ty.IsMapType(): enc.EncodeMapLen(val.LengthInt()) ety := ty.ElementType() it := val.ElementIterator() path := append(path, nil) // local override of 'path' with extra element for it.Next() { ek, ev := it.Element() path[len(path)-1] = cty.IndexStep{ Key: ek, } var err error err = marshal(ek, ek.Type(), path, enc) if err != nil { return err } err = marshal(ev, ety, path, enc) if err != nil { return err } } return nil case ty.IsTupleType(): etys := ty.TupleElementTypes() it := val.ElementIterator() path := append(path, nil) // local override of 'path' with extra element i := 0 enc.EncodeArrayLen(len(etys)) for it.Next() { ety := etys[i] ek, ev := it.Element() path[len(path)-1] = cty.IndexStep{ Key: ek, } err := marshal(ev, ety, path, enc) if err != nil { return err } i++ } return nil case ty.IsObjectType(): atys := ty.AttributeTypes() path := append(path, nil) // local override of 'path' with extra element names := make([]string, 0, len(atys)) for k := range atys { names = append(names, k) } sort.Strings(names) enc.EncodeMapLen(len(names)) for _, k := range names { aty := atys[k] av := val.GetAttr(k) path[len(path)-1] = cty.GetAttrStep{ Name: k, } var err error err = marshal(cty.StringVal(k), cty.String, path, enc) if err != nil { return err } err = marshal(av, aty, path, enc) if err != nil { return err } } return nil case ty.IsCapsuleType(): return path.NewErrorf("capsule types not supported for msgpack encoding") default: // should never happen return path.NewErrorf("cannot msgpack-serialize %s", ty.FriendlyName()) } } // marshalDynamic adds an extra wrapping object containing dynamic type // information for the given value. func marshalDynamic(val cty.Value, path cty.Path, enc *msgpack.Encoder) error { dv := dynamicVal{ Value: val, Path: path, } return enc.Encode(&dv) }