// Copyright 2016 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . // Package bind generates Ethereum contract Go bindings. // // Detailed usage document and tutorial available on the go-ethereum Wiki page: // https://github.com/ethereum/go-ethereum/wiki/Native-DApps:-Go-bindings-to-Ethereum-contracts package bind import ( "bytes" "errors" "fmt" "go/format" "regexp" "strings" "text/template" "unicode" "github.com/ethereum/go-ethereum/accounts/abi" "github.com/ethereum/go-ethereum/log" ) // Lang is a target programming language selector to generate bindings for. type Lang int const ( LangGo Lang = iota LangJava LangObjC ) // Bind generates a Go wrapper around a contract ABI. This wrapper isn't meant // to be used as is in client code, but rather as an intermediate struct which // enforces compile time type safety and naming convention opposed to having to // manually maintain hard coded strings that break on runtime. func Bind(types []string, abis []string, bytecodes []string, fsigs []map[string]string, pkg string, lang Lang, libs map[string]string, aliases map[string]string) (string, error) { // Process each individual contract requested binding contracts := make(map[string]*tmplContract) // Map used to flag each encountered library as such isLib := make(map[string]struct{}) for i := 0; i < len(types); i++ { // Parse the actual ABI to generate the binding for evmABI, err := abi.JSON(strings.NewReader(abis[i])) if err != nil { return "", err } // Strip any whitespace from the JSON ABI strippedABI := strings.Map(func(r rune) rune { if unicode.IsSpace(r) { return -1 } return r }, abis[i]) // Extract the call and transact methods; events, struct definitions; and sort them alphabetically var ( calls = make(map[string]*tmplMethod) transacts = make(map[string]*tmplMethod) events = make(map[string]*tmplEvent) structs = make(map[string]*tmplStruct) // identifiers are used to detect duplicated identifier of function // and event. For all calls, transacts and events, abigen will generate // corresponding bindings. However we have to ensure there is no // identifier coliision in the bindings of these categories. callIdentifiers = make(map[string]bool) transactIdentifiers = make(map[string]bool) eventIdentifiers = make(map[string]bool) ) for _, original := range evmABI.Methods { // Normalize the method for capital cases and non-anonymous inputs/outputs normalized := original normalizedName := methodNormalizer[lang](alias(aliases, original.Name)) // Ensure there is no duplicated identifier var identifiers = callIdentifiers if !original.Const { identifiers = transactIdentifiers } if identifiers[normalizedName] { return "", fmt.Errorf("duplicated identifier \"%s\"(normalized \"%s\"), use --alias for renaming", original.Name, normalizedName) } identifiers[normalizedName] = true normalized.Name = normalizedName normalized.Inputs = make([]abi.Argument, len(original.Inputs)) copy(normalized.Inputs, original.Inputs) for j, input := range normalized.Inputs { if input.Name == "" { normalized.Inputs[j].Name = fmt.Sprintf("arg%d", j) } if hasStruct(input.Type) { bindStructType[lang](input.Type, structs) } } normalized.Outputs = make([]abi.Argument, len(original.Outputs)) copy(normalized.Outputs, original.Outputs) for j, output := range normalized.Outputs { if output.Name != "" { normalized.Outputs[j].Name = capitalise(output.Name) } if hasStruct(output.Type) { bindStructType[lang](output.Type, structs) } } // Append the methods to the call or transact lists if original.Const { calls[original.Name] = &tmplMethod{Original: original, Normalized: normalized, Structured: structured(original.Outputs)} } else { transacts[original.Name] = &tmplMethod{Original: original, Normalized: normalized, Structured: structured(original.Outputs)} } } for _, original := range evmABI.Events { // Skip anonymous events as they don't support explicit filtering if original.Anonymous { continue } // Normalize the event for capital cases and non-anonymous outputs normalized := original // Ensure there is no duplicated identifier normalizedName := methodNormalizer[lang](alias(aliases, original.Name)) if eventIdentifiers[normalizedName] { return "", fmt.Errorf("duplicated identifier \"%s\"(normalized \"%s\"), use --alias for renaming", original.Name, normalizedName) } eventIdentifiers[normalizedName] = true normalized.Name = normalizedName normalized.Inputs = make([]abi.Argument, len(original.Inputs)) copy(normalized.Inputs, original.Inputs) for j, input := range normalized.Inputs { if input.Name == "" { normalized.Inputs[j].Name = fmt.Sprintf("arg%d", j) } if hasStruct(input.Type) { bindStructType[lang](input.Type, structs) } } // Append the event to the accumulator list events[original.Name] = &tmplEvent{Original: original, Normalized: normalized} } // There is no easy way to pass arbitrary java objects to the Go side. if len(structs) > 0 && lang == LangJava { return "", errors.New("java binding for tuple arguments is not supported yet") } contracts[types[i]] = &tmplContract{ Type: capitalise(types[i]), InputABI: strings.Replace(strippedABI, "\"", "\\\"", -1), InputBin: strings.TrimPrefix(strings.TrimSpace(bytecodes[i]), "0x"), Constructor: evmABI.Constructor, Calls: calls, Transacts: transacts, Events: events, Libraries: make(map[string]string), Structs: structs, } // Function 4-byte signatures are stored in the same sequence // as types, if available. if len(fsigs) > i { contracts[types[i]].FuncSigs = fsigs[i] } // Parse library references. for pattern, name := range libs { matched, err := regexp.Match("__\\$"+pattern+"\\$__", []byte(contracts[types[i]].InputBin)) if err != nil { log.Error("Could not search for pattern", "pattern", pattern, "contract", contracts[types[i]], "err", err) } if matched { contracts[types[i]].Libraries[pattern] = name // keep track that this type is a library if _, ok := isLib[name]; !ok { isLib[name] = struct{}{} } } } } // Check if that type has already been identified as a library for i := 0; i < len(types); i++ { _, ok := isLib[types[i]] contracts[types[i]].Library = ok } // Generate the contract template data content and render it data := &tmplData{ Package: pkg, Contracts: contracts, Libraries: libs, } buffer := new(bytes.Buffer) funcs := map[string]interface{}{ "bindtype": bindType[lang], "bindtopictype": bindTopicType[lang], "namedtype": namedType[lang], "formatmethod": formatMethod, "formatevent": formatEvent, "capitalise": capitalise, "decapitalise": decapitalise, } tmpl := template.Must(template.New("").Funcs(funcs).Parse(tmplSource[lang])) if err := tmpl.Execute(buffer, data); err != nil { return "", err } // For Go bindings pass the code through gofmt to clean it up if lang == LangGo { code, err := format.Source(buffer.Bytes()) if err != nil { return "", fmt.Errorf("%v\n%s", err, buffer) } return string(code), nil } // For all others just return as is for now return buffer.String(), nil } // bindType is a set of type binders that convert Solidity types to some supported // programming language types. var bindType = map[Lang]func(kind abi.Type, structs map[string]*tmplStruct) string{ LangGo: bindTypeGo, LangJava: bindTypeJava, } // bindBasicTypeGo converts basic solidity types(except array, slice and tuple) to Go one. func bindBasicTypeGo(kind abi.Type) string { switch kind.T { case abi.AddressTy: return "common.Address" case abi.IntTy, abi.UintTy: parts := regexp.MustCompile(`(u)?int([0-9]*)`).FindStringSubmatch(kind.String()) switch parts[2] { case "8", "16", "32", "64": return fmt.Sprintf("%sint%s", parts[1], parts[2]) } return "*big.Int" case abi.FixedBytesTy: return fmt.Sprintf("[%d]byte", kind.Size) case abi.BytesTy: return "[]byte" case abi.FunctionTy: return "[24]byte" default: // string, bool types return kind.String() } } // bindTypeGo converts solidity types to Go ones. Since there is no clear mapping // from all Solidity types to Go ones (e.g. uint17), those that cannot be exactly // mapped will use an upscaled type (e.g. BigDecimal). func bindTypeGo(kind abi.Type, structs map[string]*tmplStruct) string { switch kind.T { case abi.TupleTy: return structs[kind.TupleRawName+kind.String()].Name case abi.ArrayTy: return fmt.Sprintf("[%d]", kind.Size) + bindTypeGo(*kind.Elem, structs) case abi.SliceTy: return "[]" + bindTypeGo(*kind.Elem, structs) default: return bindBasicTypeGo(kind) } } // bindBasicTypeJava converts basic solidity types(except array, slice and tuple) to Java one. func bindBasicTypeJava(kind abi.Type) string { switch kind.T { case abi.AddressTy: return "Address" case abi.IntTy, abi.UintTy: // Note that uint and int (without digits) are also matched, // these are size 256, and will translate to BigInt (the default). parts := regexp.MustCompile(`(u)?int([0-9]*)`).FindStringSubmatch(kind.String()) if len(parts) != 3 { return kind.String() } // All unsigned integers should be translated to BigInt since gomobile doesn't // support them. if parts[1] == "u" { return "BigInt" } namedSize := map[string]string{ "8": "byte", "16": "short", "32": "int", "64": "long", }[parts[2]] // default to BigInt if namedSize == "" { namedSize = "BigInt" } return namedSize case abi.FixedBytesTy, abi.BytesTy: return "byte[]" case abi.BoolTy: return "boolean" case abi.StringTy: return "String" case abi.FunctionTy: return "byte[24]" default: return kind.String() } } // pluralizeJavaType explicitly converts multidimensional types to predefined // type in go side. func pluralizeJavaType(typ string) string { switch typ { case "boolean": return "Bools" case "String": return "Strings" case "Address": return "Addresses" case "byte[]": return "Binaries" case "BigInt": return "BigInts" } return typ + "[]" } // bindTypeJava converts a Solidity type to a Java one. Since there is no clear mapping // from all Solidity types to Java ones (e.g. uint17), those that cannot be exactly // mapped will use an upscaled type (e.g. BigDecimal). func bindTypeJava(kind abi.Type, structs map[string]*tmplStruct) string { switch kind.T { case abi.TupleTy: return structs[kind.TupleRawName+kind.String()].Name case abi.ArrayTy, abi.SliceTy: return pluralizeJavaType(bindTypeJava(*kind.Elem, structs)) default: return bindBasicTypeJava(kind) } } // bindTopicType is a set of type binders that convert Solidity types to some // supported programming language topic types. var bindTopicType = map[Lang]func(kind abi.Type, structs map[string]*tmplStruct) string{ LangGo: bindTopicTypeGo, LangJava: bindTopicTypeJava, } // bindTopicTypeGo converts a Solidity topic type to a Go one. It is almost the same // funcionality as for simple types, but dynamic types get converted to hashes. func bindTopicTypeGo(kind abi.Type, structs map[string]*tmplStruct) string { bound := bindTypeGo(kind, structs) // todo(rjl493456442) according solidity documentation, indexed event // parameters that are not value types i.e. arrays and structs are not // stored directly but instead a keccak256-hash of an encoding is stored. // // We only convert stringS and bytes to hash, still need to deal with // array(both fixed-size and dynamic-size) and struct. if bound == "string" || bound == "[]byte" { bound = "common.Hash" } return bound } // bindTopicTypeJava converts a Solidity topic type to a Java one. It is almost the same // funcionality as for simple types, but dynamic types get converted to hashes. func bindTopicTypeJava(kind abi.Type, structs map[string]*tmplStruct) string { bound := bindTypeJava(kind, structs) // todo(rjl493456442) according solidity documentation, indexed event // parameters that are not value types i.e. arrays and structs are not // stored directly but instead a keccak256-hash of an encoding is stored. // // We only convert stringS and bytes to hash, still need to deal with // array(both fixed-size and dynamic-size) and struct. if bound == "String" || bound == "byte[]" { bound = "Hash" } return bound } // bindStructType is a set of type binders that convert Solidity tuple types to some supported // programming language struct definition. var bindStructType = map[Lang]func(kind abi.Type, structs map[string]*tmplStruct) string{ LangGo: bindStructTypeGo, LangJava: bindStructTypeJava, } // bindStructTypeGo converts a Solidity tuple type to a Go one and records the mapping // in the given map. // Notably, this function will resolve and record nested struct recursively. func bindStructTypeGo(kind abi.Type, structs map[string]*tmplStruct) string { switch kind.T { case abi.TupleTy: // We compose raw struct name and canonical parameter expression // together here. The reason is before solidity v0.5.11, kind.TupleRawName // is empty, so we use canonical parameter expression to distinguish // different struct definition. From the consideration of backward // compatibility, we concat these two together so that if kind.TupleRawName // is not empty, it can have unique id. id := kind.TupleRawName + kind.String() if s, exist := structs[id]; exist { return s.Name } var fields []*tmplField for i, elem := range kind.TupleElems { field := bindStructTypeGo(*elem, structs) fields = append(fields, &tmplField{Type: field, Name: capitalise(kind.TupleRawNames[i]), SolKind: *elem}) } name := kind.TupleRawName if name == "" { name = fmt.Sprintf("Struct%d", len(structs)) } structs[id] = &tmplStruct{ Name: name, Fields: fields, } return name case abi.ArrayTy: return fmt.Sprintf("[%d]", kind.Size) + bindStructTypeGo(*kind.Elem, structs) case abi.SliceTy: return "[]" + bindStructTypeGo(*kind.Elem, structs) default: return bindBasicTypeGo(kind) } } // bindStructTypeJava converts a Solidity tuple type to a Java one and records the mapping // in the given map. // Notably, this function will resolve and record nested struct recursively. func bindStructTypeJava(kind abi.Type, structs map[string]*tmplStruct) string { switch kind.T { case abi.TupleTy: // We compose raw struct name and canonical parameter expression // together here. The reason is before solidity v0.5.11, kind.TupleRawName // is empty, so we use canonical parameter expression to distinguish // different struct definition. From the consideration of backward // compatibility, we concat these two together so that if kind.TupleRawName // is not empty, it can have unique id. id := kind.TupleRawName + kind.String() if s, exist := structs[id]; exist { return s.Name } var fields []*tmplField for i, elem := range kind.TupleElems { field := bindStructTypeJava(*elem, structs) fields = append(fields, &tmplField{Type: field, Name: decapitalise(kind.TupleRawNames[i]), SolKind: *elem}) } name := kind.TupleRawName if name == "" { name = fmt.Sprintf("Class%d", len(structs)) } structs[id] = &tmplStruct{ Name: name, Fields: fields, } return name case abi.ArrayTy, abi.SliceTy: return pluralizeJavaType(bindStructTypeJava(*kind.Elem, structs)) default: return bindBasicTypeJava(kind) } } // namedType is a set of functions that transform language specific types to // named versions that my be used inside method names. var namedType = map[Lang]func(string, abi.Type) string{ LangGo: func(string, abi.Type) string { panic("this shouldn't be needed") }, LangJava: namedTypeJava, } // namedTypeJava converts some primitive data types to named variants that can // be used as parts of method names. func namedTypeJava(javaKind string, solKind abi.Type) string { switch javaKind { case "byte[]": return "Binary" case "boolean": return "Bool" default: parts := regexp.MustCompile(`(u)?int([0-9]*)(\[[0-9]*\])?`).FindStringSubmatch(solKind.String()) if len(parts) != 4 { return javaKind } switch parts[2] { case "8", "16", "32", "64": if parts[3] == "" { return capitalise(fmt.Sprintf("%sint%s", parts[1], parts[2])) } return capitalise(fmt.Sprintf("%sint%ss", parts[1], parts[2])) default: return javaKind } } } // alias returns an alias of the given string based on the aliasing rules // or returns itself if no rule is matched. func alias(aliases map[string]string, n string) string { if alias, exist := aliases[n]; exist { return alias } return n } // methodNormalizer is a name transformer that modifies Solidity method names to // conform to target language naming concentions. var methodNormalizer = map[Lang]func(string) string{ LangGo: abi.ToCamelCase, LangJava: decapitalise, } // capitalise makes a camel-case string which starts with an upper case character. func capitalise(input string) string { return abi.ToCamelCase(input) } // decapitalise makes a camel-case string which starts with a lower case character. func decapitalise(input string) string { if len(input) == 0 { return input } goForm := abi.ToCamelCase(input) return strings.ToLower(goForm[:1]) + goForm[1:] } // structured checks whether a list of ABI data types has enough information to // operate through a proper Go struct or if flat returns are needed. func structured(args abi.Arguments) bool { if len(args) < 2 { return false } exists := make(map[string]bool) for _, out := range args { // If the name is anonymous, we can't organize into a struct if out.Name == "" { return false } // If the field name is empty when normalized or collides (var, Var, _var, _Var), // we can't organize into a struct field := capitalise(out.Name) if field == "" || exists[field] { return false } exists[field] = true } return true } // hasStruct returns an indicator whether the given type is struct, struct slice // or struct array. func hasStruct(t abi.Type) bool { switch t.T { case abi.SliceTy: return hasStruct(*t.Elem) case abi.ArrayTy: return hasStruct(*t.Elem) case abi.TupleTy: return true default: return false } } // resolveArgName converts a raw argument representation into a user friendly format. func resolveArgName(arg abi.Argument, structs map[string]*tmplStruct) string { var ( prefix string embedded string typ = &arg.Type ) loop: for { switch typ.T { case abi.SliceTy: prefix += "[]" case abi.ArrayTy: prefix += fmt.Sprintf("[%d]", typ.Size) default: embedded = typ.TupleRawName + typ.String() break loop } typ = typ.Elem } if s, exist := structs[embedded]; exist { return prefix + s.Name } else { return arg.Type.String() } } // formatMethod transforms raw method representation into a user friendly one. func formatMethod(method abi.Method, structs map[string]*tmplStruct) string { inputs := make([]string, len(method.Inputs)) for i, input := range method.Inputs { inputs[i] = fmt.Sprintf("%v %v", resolveArgName(input, structs), input.Name) } outputs := make([]string, len(method.Outputs)) for i, output := range method.Outputs { outputs[i] = resolveArgName(output, structs) if len(output.Name) > 0 { outputs[i] += fmt.Sprintf(" %v", output.Name) } } constant := "" if method.Const { constant = "constant " } return fmt.Sprintf("function %v(%v) %sreturns(%v)", method.RawName, strings.Join(inputs, ", "), constant, strings.Join(outputs, ", ")) } // formatEvent transforms raw event representation into a user friendly one. func formatEvent(event abi.Event, structs map[string]*tmplStruct) string { inputs := make([]string, len(event.Inputs)) for i, input := range event.Inputs { if input.Indexed { inputs[i] = fmt.Sprintf("%v indexed %v", resolveArgName(input, structs), input.Name) } else { inputs[i] = fmt.Sprintf("%v %v", resolveArgName(input, structs), input.Name) } } return fmt.Sprintf("event %v(%v)", event.RawName, strings.Join(inputs, ", ")) }