// Copyright (c) 2013 Conformal Systems LLC. // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package btcjson import ( "encoding/json" "fmt" "strings" ) // Message contains a message to be sent to the bitcoin client. type Message struct { Jsonrpc string `json:"jsonrpc"` Id interface{} `json:"id,omitempty"` Method string `json:"method"` Params interface{} `json:"params"` } // Reply is the general form of the reply from the bitcoin client. // The form of the Result part varies from one command to the next so it // is currently implemented as an interface. type Reply struct { Result interface{} `json:"result"` Error *Error `json:"error"` // This has to be a pointer for go to put a null in it when empty. Id *interface{} `json:"id"` } // InfoResult contains the data returned by the getinfo command. type InfoResult struct { Version int `json:"version,omitempty"` ProtocolVersion int `json:"protocolversion,omitempty"` WalletVersion int `json:"walletversion,omitempty"` Balance float64 `json:"balance,omitempty"` Blocks int `json:"blocks,omitempty"` Connections int `json:"connections,omitempty"` Proxy string `json:"proxy,omitempty"` Difficulty float64 `json:"difficulty,omitempty"` TestNet bool `json:"testnet,omitempty"` KeypoolOldest int64 `json:"keypoololdest,omitempty"` KeypoolSize int `json:"keypoolsize,omitempty"` PaytxFee float64 `json:"paytxfee,omitempty"` Errors string `json:"errors,omitempty"` } // BlockResult models the data from the getblock command when the verbose flag // is set. When the verbose flag is not set, getblock return a hex-encoded // string. type BlockResult struct { Hash string `json:"hash"` Confirmations uint64 `json:"confirmations"` Size int `json:"size"` Height int64 `json:"height"` Version uint32 `json:"version"` MerkleRoot string `json:"merkleroot"` Tx []string `json:"tx,omitempty"` RawTx []TxRawResult `json:"rawtx,omitempty"` Time int64 `json:"time"` Nonce uint32 `json:"nonce"` Bits string `json:"bits"` Difficulty float64 `json:"difficulty"` PreviousHash string `json:"previousblockhash"` NextHash string `json:"nextblockhash"` } // DecodeScriptResult models the data returned from the decodescript command. type DecodeScriptResult struct { Asm string `json:"asm"` ReqSigs int `json:"reqSigs,omitempty"` Type string `json:"type"` Addresses []string `json:"addresses,omitempty"` P2sh string `json:"p2sh"` } // TxRawResult models the data from the getrawtransaction command. type TxRawResult struct { Hex string `json:"hex"` Txid string `json:"txid"` Version uint32 `json:"version"` LockTime uint32 `json:"locktime"` Vin []Vin `json:"vin"` Vout []Vout `json:"vout"` BlockHash string `json:"blockhash,omitempty"` Confirmations uint64 `json:"confirmations,omitempty"` Time int64 `json:"time,omitempty"` Blocktime int64 `json:"blocktime,omitempty"` } // TxRawDecodeResult models the data from the decoderawtransaction command. type TxRawDecodeResult struct { Txid string `json:"txid"` Version uint32 `json:"version"` Locktime uint32 `json:"locktime"` Vin []Vin `json:"vin"` Vout []Vout `json:"vout"` } // ScriptSig models a signature script. It is defined seperately since it only // applies to non-coinbase. Therefore the field in the Vin structure needs // to be a pointer. type ScriptSig struct { Asm string `json:"asm"` Hex string `json:"hex"` } // Vin models parts of the tx data. It is defined seperately since both // getrawtransaction and decoderawtransaction use the same structure. type Vin struct { Coinbase string `json:"coinbase"` Txid string `json:"txid"` Vout int `json:"vout"` ScriptSig *ScriptSig `json:"scriptSig"` Sequence uint32 `json:"sequence"` } func (v *Vin) IsCoinBase() bool { return len(v.Coinbase) > 0 } func (v *Vin) MarshalJSON() ([]byte, error) { if v.IsCoinBase() { coinbaseStruct := struct { Coinbase string `json:"coinbase"` Sequence uint32 `json:"sequence"` }{ Coinbase: v.Coinbase, Sequence: v.Sequence, } return json.Marshal(coinbaseStruct) } txStruct := struct { Txid string `json:"txid"` Vout int `json:"vout"` ScriptSig *ScriptSig `json:"scriptSig"` Sequence uint32 `json:"sequence"` }{ Txid: v.Txid, Vout: v.Vout, ScriptSig: v.ScriptSig, Sequence: v.Sequence, } return json.Marshal(txStruct) } // Vout models parts of the tx data. It is defined seperately since both // getrawtransaction and decoderawtransaction use the same structure. type Vout struct { Value float64 `json:"value"` N int `json:"n"` ScriptPubKey struct { Asm string `json:"asm"` Hex string `json:"hex"` ReqSigs int `json:"reqSigs,omitempty"` Type string `json:"type"` Addresses []string `json:"addresses,omitempty"` } `json:"scriptPubKey"` } // GetMiningInfoResult models the data from the getmininginfo command. type GetMiningInfoResult struct { CurrentBlockSize float64 `json:"currentblocksize"` Difficulty float64 `json:"difficulty"` Errors string `json:"errors"` Generate bool `json:"generate"` GenProcLimit float64 `json:"genproclimit"` PooledTx float64 `json:"pooledtx"` Testnet bool `json:"testnet"` Blocks float64 `json:"blocks"` CurrentBlockTx float64 `json:"currentblocktx"` HashesPerSec float64 `json:"hashespersec"` } // ValidateAddressResult models the data from the validateaddress command. type ValidateAddressResult struct { IsValid bool `json:"isvalid"` Address string `json:"address,omitempty"` IsMine bool `json:"ismine,omitempty"` IsScript bool `json:"isscript,omitempty"` PubKey string `json:"pubkey,omitempty"` IsCompressed bool `json:"iscompressed,omitempty"` Account string `json:"account,omitempty"` } type SignRawTransactionResult struct { Hex string `json:"hex"` Complete bool `json:"complete"` } type ListUnSpentResult struct { TxId string `json:"txid"` Vout float64 `json:"vout"` Address string `json:"address"` Account string `json:"account"` ScriptPubKey string `json:"scriptPubKey"` Amount float64 `json:"amount"` Confirmations float64 `json:"confirmations"` } // Error models the error field of the json returned by a bitcoin client. When // there is no error, this should be a nil pointer to produce the null in the // json that bitcoind produces. type Error struct { Code int `json:"code,omitempty"` Message string `json:"message,omitempty"` } // Guarantee Error satisifies the builtin error interface var _, _ error = Error{}, &Error{} // Error returns a string describing the btcjson error. This // satisifies the builtin error interface. func (e Error) Error() string { return fmt.Sprintf("%d: %s", e.Code, e.Message) } // jsonWithArgs takes a command, an id, and an interface which contains an // array of the arguments for that command. It knows NOTHING about the commands // so all error checking of the arguments must happen before it is called. func jsonWithArgs(command string, id interface{}, args interface{}) ([]byte, error) { rawMessage := Message{"1.0", id, command, args} finalMessage, err := json.Marshal(rawMessage) if err != nil { return nil, err } return finalMessage, nil } // CreateMessage takes a string and the optional arguments for it. Then, // if it is a recognized bitcoin json message, generates the json message ready // to send off to the daemon or server. // It is capable of handeling all of the commands from the standard client, // described at: // https://en.bitcoin.it/wiki/Original_Bitcoin_client/API_Calls_list func CreateMessage(message string, args ...interface{}) ([]byte, error) { finalMessage, err := CreateMessageWithId(message, "btcd", args...) return finalMessage, err } // CreateMessageWithId takes a string, an id, and the optional arguments for // it. Then, if it is a recognized bitcoin json message, generates the json // message ready to send off to the daemon or server. It is capable of handling // all of the commands from the standard client, described at: // https://en.bitcoin.it/wiki/Original_Bitcoin_client/API_Calls_list func CreateMessageWithId(message string, id interface{}, args ...interface{}) ([]byte, error) { var finalMessage []byte var err error // Different commands have different required and optional arguments. // Need to handle them based on that. switch message { // No args case "getblockcount", "getblocknumber", "getconnectioncount", "getdifficulty", "getgenerate", "gethashespersec", "getinfo", "getmininginfo", "getpeerinfo", "getrawmempool", "keypoolrefill", "listaddressgroupings", "listlockunspent", "stop", "walletlock", "getbestblockhash": if len(args) > 0 { err = fmt.Errorf("Too many arguments for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One optional int case "listaccounts": if len(args) > 1 { err = fmt.Errorf("Too many arguments for %s", message) return finalMessage, err } if len(args) == 1 { _, ok := args[0].(int) if !ok { err = fmt.Errorf("Argument must be int for %s", message) return finalMessage, err } } finalMessage, err = jsonWithArgs(message, id, args) // One required int case "getblockhash": if len(args) != 1 { err = fmt.Errorf("Missing argument for %s", message) return finalMessage, err } _, ok := args[0].(int) if !ok { err = fmt.Errorf("Argument must be int for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One required float case "settxfee": if len(args) != 1 { err = fmt.Errorf("Missing argument for %s", message) return finalMessage, err } _, ok := args[0].(float64) if !ok { err = fmt.Errorf("Argument must be float64 for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One optional string case "getmemorypool", "getnewaddress", "getwork", "help", "getrawchangeaddress": if len(args) > 1 { err = fmt.Errorf("Too many arguments for %s", message) return finalMessage, err } if len(args) == 1 { _, ok := args[0].(string) if !ok { err = fmt.Errorf("Optional argument must be string for %s", message) return finalMessage, err } } finalMessage, err = jsonWithArgs(message, id, args) // One required string case "backupwallet", "decoderawtransaction", "dumpprivkey", "encryptwallet", "getaccount", "getaccountaddress", "getaddressesbyaccount", "getblock", "gettransaction", "sendrawtransaction", "validateaddress": if len(args) != 1 { err = fmt.Errorf("%s requires one argument", message) return finalMessage, err } _, ok := args[0].(string) if !ok { err = fmt.Errorf("Argument must be string for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // Two required strings case "setaccount", "signmessage", "walletpassphrasechange", "addnode": if len(args) != 2 { err = fmt.Errorf("Missing arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(string) _, ok2 := args[1].(string) if !ok1 || !ok2 { err = fmt.Errorf("Arguments must be string for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One required string, one required int case "walletpassphrase": if len(args) != 2 { err = fmt.Errorf("Missing arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(string) _, ok2 := args[1].(int) if !ok1 || !ok2 { err = fmt.Errorf("Arguments must be string and int for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // Three required strings case "verifymessage": if len(args) != 3 { err = fmt.Errorf("Three arguments required for %s", message) return finalMessage, err } _, ok1 := args[0].(string) _, ok2 := args[1].(string) _, ok3 := args[2].(string) if !ok1 || !ok2 || !ok3 { err = fmt.Errorf("Arguments must be string for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One required bool, one optional string case "getaddednodeinfo": if len(args) > 2 || len(args) == 0 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(bool) ok2 := true if len(args) == 2 { _, ok2 = args[1].(string) } if !ok1 || !ok2 { err = fmt.Errorf("Arguments must be bool and optionally string for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One required bool, one optional int case "setgenerate": if len(args) > 2 || len(args) == 0 { err = fmt.Errorf("Wrong number of argument for %s", message) return finalMessage, err } _, ok1 := args[0].(bool) ok2 := true if len(args) == 2 { _, ok2 = args[1].(int) } if !ok1 || !ok2 { err = fmt.Errorf("Arguments must be bool and optionally int for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One optional string, one optional int case "getbalance", "getreceivedbyaccount": if len(args) > 2 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } ok1 := true ok2 := true if len(args) >= 1 { _, ok1 = args[0].(string) } if len(args) == 2 { _, ok2 = args[1].(int) } if !ok1 || !ok2 { err = fmt.Errorf("Optional arguments must be string and int for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One required string, one optional int case "getrawtransaction", "getreceivedbyaddress": if len(args) > 2 || len(args) == 0 { err = fmt.Errorf("Wrong number of argument for %s", message) return finalMessage, err } _, ok1 := args[0].(string) ok2 := true if len(args) == 2 { _, ok2 = args[1].(int) } if !ok1 || !ok2 { err = fmt.Errorf("Arguments must be string and optionally int for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One required string, one optional string // Strictly, the optional arg for submit block is an object, but // bitcoind ignores it for now, so best to just allow string until // support for it is complete. case "submitblock": if len(args) > 2 || len(args) == 0 { err = fmt.Errorf("Wrong number of argument for %s", message) return finalMessage, err } _, ok1 := args[0].(string) ok2 := true if len(args) == 2 { _, ok2 = args[1].(string) } if !ok1 || !ok2 { err = fmt.Errorf("Arguments must be string and optionally string for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One optional int, one optional bool case "listreceivedbyaccount", "listreceivedbyaddress": if len(args) > 2 { err = fmt.Errorf("Wrong number of argument for %s", message) return finalMessage, err } ok1 := true ok2 := true if len(args) >= 1 { _, ok1 = args[0].(int) } if len(args) == 2 { _, ok2 = args[1].(bool) } if !ok1 || !ok2 { err = fmt.Errorf("Optional arguments must be int and bool for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One optional string, two optional ints case "listtransactions": if len(args) > 3 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } ok1 := true ok2 := true ok3 := true if len(args) >= 1 { _, ok1 = args[0].(string) } if len(args) > 1 { _, ok2 = args[1].(int) } if len(args) == 3 { _, ok3 = args[2].(int) } if !ok1 || !ok2 || !ok3 { err = fmt.Errorf("Optional arguments must be string and up to two ints for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One required string, one optional string, one optional bool case "importprivkey": if len(args) > 3 || len(args) == 0 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(string) ok2 := true ok3 := true if len(args) > 1 { _, ok2 = args[1].(string) } if len(args) == 3 { _, ok3 = args[2].(bool) } if !ok1 || !ok2 || !ok3 { err = fmt.Errorf("Arguments must be string and optionally string and bool for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // Two optional ints case "listunspent": if len(args) > 2 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } ok1 := true ok2 := true if len(args) >= 1 { _, ok1 = args[0].(int) } if len(args) == 2 { _, ok2 = args[1].(int) } if !ok1 || !ok2 { err = fmt.Errorf("Optional arguments must be ints for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // Two optional strings case "listsinceblock": if len(args) > 2 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } ok1 := true ok2 := true if len(args) >= 1 { _, ok1 = args[0].(string) } if len(args) == 2 { _, ok2 = args[1].(string) } if !ok1 || !ok2 { err = fmt.Errorf("Optional arguments must be strings for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // Two required strings, one required float, one optional int, // two optional strings. case "sendfrom": if len(args) > 6 || len(args) < 3 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(string) _, ok2 := args[1].(string) _, ok3 := args[2].(float64) ok4 := true ok5 := true ok6 := true if len(args) >= 4 { _, ok4 = args[3].(int) } if len(args) >= 5 { _, ok5 = args[4].(string) } if len(args) == 6 { _, ok6 = args[5].(string) } if !ok1 || !ok2 || !ok3 || !ok4 || !ok5 || !ok6 { err = fmt.Errorf("Arguments must be string, string, float64 and optionally int and two strings for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // Two required strings, one required float, one optional int, // one optional string. case "move": if len(args) > 5 || len(args) < 3 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(string) _, ok2 := args[1].(string) _, ok3 := args[2].(float64) ok4 := true ok5 := true if len(args) >= 4 { _, ok4 = args[3].(int) } if len(args) == 5 { _, ok5 = args[4].(string) } if !ok1 || !ok2 || !ok3 || !ok4 || !ok5 { err = fmt.Errorf("Arguments must be string, string, float64 and optionally int and string for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // One required strings, one required float, two optional strings case "sendtoaddress": if len(args) > 4 || len(args) < 2 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(string) _, ok2 := args[1].(float64) ok3 := true ok4 := true if len(args) >= 3 { _, ok3 = args[2].(string) } if len(args) == 4 { _, ok4 = args[3].(string) } if !ok1 || !ok2 || !ok3 || !ok4 { err = fmt.Errorf("Arguments must be string, float64 and optionally two strings for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // required int, required pair of keys (string), optional string case "addmultisignaddress": if len(args) > 4 || len(args) < 3 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(int) _, ok2 := args[1].(string) _, ok3 := args[2].(string) ok4 := true if len(args) == 4 { _, ok4 = args[2].(string) } if !ok1 || !ok2 || !ok3 || !ok4 { err = fmt.Errorf("Arguments must be int, two string and optionally one for %s", message) return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // Must be a set of string, int, string, float (any number of those). case "createrawtransaction": if len(args)%4 != 0 || len(args) == 0 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } type vlist struct { Txid string `json:"txid"` Vout int `json:"vout"` } vList := make([]vlist, len(args)/4) addresses := make(map[string]float64) for i := 0; i < len(args)/4; i += 1 { txid, ok1 := args[(i*4)+0].(string) vout, ok2 := args[(i*4)+1].(int) add, ok3 := args[(i*4)+2].(string) amt, ok4 := args[(i*4)+3].(float64) if !ok1 || !ok2 || !ok3 || !ok4 { err = fmt.Errorf("Incorrect arguement types.") return finalMessage, err } vList[i].Txid = txid vList[i].Vout = vout addresses[add] = amt } finalMessage, err = jsonWithArgs(message, id, []interface{}{vList, addresses}) // string, string/float pairs, optional int, and string case "sendmany": if len(args) < 3 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } var minconf int var comment string _, ok1 := args[0].(string) if !ok1 { err = fmt.Errorf("Incorrect arguement types.") return finalMessage, err } addresses := make(map[string]float64) for i := 1; i < len(args); i += 2 { add, ok1 := args[i].(string) if ok1 { if len(args) > i+1 { amt, ok2 := args[i+1].(float64) if !ok2 { err = fmt.Errorf("Incorrect arguement types.") return finalMessage, err } // Put a single pair into addresses addresses[add] = amt } else { comment = add } } else { if _, ok := args[i].(int); ok { minconf = args[i].(int) } if len(args)-1 > i { if _, ok := args[i+1].(string); ok { comment = args[i+1].(string) } } } } finalMessage, err = jsonWithArgs(message, id, []interface{}{args[0].(string), addresses, minconf, comment}) // bool and an array of stuff case "lockunspent": if len(args) < 2 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(bool) if !ok1 { err = fmt.Errorf("Incorrect arguement types.") return finalMessage, err } finalMessage, err = jsonWithArgs(message, id, args) // one required string (hex) and optional sets of one string, one int, // and one string along with another optional string. case "signrawtransaction": if len(args) < 1 { err = fmt.Errorf("Wrong number of arguments for %s", message) return finalMessage, err } _, ok1 := args[0].(string) if !ok1 { err = fmt.Errorf("Incorrect arguement types.") return finalMessage, err } type txlist struct { Txid string `json:"txid"` Vout int `json:"vout"` ScriptPubKey string `json:"scriptPubKey"` } txList := make([]txlist, 1) if len(args) > 1 { txid, ok2 := args[1].(string) vout, ok3 := args[2].(int) spkey, ok4 := args[3].(string) if !ok1 || !ok2 || !ok3 || !ok4 { err = fmt.Errorf("Incorrect arguement types.") return finalMessage, err } txList[0].Txid = txid txList[0].Vout = vout txList[0].ScriptPubKey = spkey } /* pkeyList := make([]string, (len(args)-1)/4) for i := 0; i < len(args)/4; i += 1 { fmt.Println(args[(i*4)+4]) txid, ok1 := args[(i*4)+1].(string) vout, ok2 := args[(i*4)+2].(int) spkey, ok3 := args[(i*4)+3].(string) pkey, ok4 := args[(i*4)+4].(string) if !ok1 || !ok2 || !ok3 || !ok4 { err = fmt.Errorf("Incorrect arguement types.") return finalMessage, err } txList[i].Txid = txid txList[i].Vout = vout txList[i].ScriptPubKey = spkey pkeyList[i] = pkey } */ finalMessage, err = jsonWithArgs(message, id, []interface{}{args[0].(string), txList}) // Any other message default: err = fmt.Errorf("Not a valid command: %s", message) } return finalMessage, err } // ReadResultCmd unmarshalls the json reply with data struct for specific // commands or an interface if it is not a command where we already have a // struct ready. func ReadResultCmd(cmd string, message []byte) (Reply, error) { var result Reply var err error var objmap map[string]json.RawMessage err = json.Unmarshal(message, &objmap) if err != nil { if strings.Contains(string(message), "401 Unauthorized.") { err = fmt.Errorf("Authentication error.") } else { err = fmt.Errorf("Error unmarshalling json reply: %v", err) } return result, err } // Take care of the parts that are the same for all replies. var jsonErr Error var id interface{} err = json.Unmarshal(objmap["error"], &jsonErr) if err != nil { err = fmt.Errorf("Error unmarshalling json reply: %v", err) return result, err } err = json.Unmarshal(objmap["id"], &id) if err != nil { err = fmt.Errorf("Error unmarshalling json reply: %v", err) return result, err } // If it is a command where we have already worked out the reply, // generate put the results in the proper structure. // We handle the error condition after the switch statement. switch cmd { case "getinfo": var res InfoResult err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } case "getblock": // getblock can either return a JSON object or a hex-encoded // string depending on the verbose flag. Choose the right form // accordingly. if strings.Contains(string(objmap["result"]), "{") { var res BlockResult err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } } else { var res string err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } } case "getrawtransaction": // getrawtransaction can either return a JSON object or a // hex-encoded string depending on the verbose flag. Choose the // right form accordingly. if strings.Contains(string(objmap["result"]), "{") { var res TxRawResult err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } } else { var res string err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } } case "decoderawtransaction": var res TxRawDecodeResult err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } case "getaddressesbyaccount": var res []string err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } case "getmininginfo": var res GetMiningInfoResult err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } case "validateaddress": var res ValidateAddressResult err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } case "signrawtransaction": var res SignRawTransactionResult err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } case "listunspent": var res []ListUnSpentResult err = json.Unmarshal(objmap["result"], &res) if err == nil { result.Result = res } // For commands that return a single item (or no items), we get it with // the correct concrete type for free (but treat them separately // for clarity). case "getblockcount", "getbalance", "getblocknumber", "getgenerate", "getconnetioncount", "getdifficulty", "gethashespersec", "setgenerate", "stop", "settxfee", "getaccount", "getnewaddress", "sendtoaddress", "createrawtransaction", "sendrawtransaction", "getbestblockhash", "getrawchangeaddress": err = json.Unmarshal(message, &result) // For anything else put it in an interface. All the data is still // there, just a little less convenient to deal with. default: err = json.Unmarshal(message, &result) } if err != nil { err = fmt.Errorf("Error unmarshalling json reply: %v", err) return result, err } // Only want the error field when there is an actual error to report. if jsonErr.Code != 0 { result.Error = &jsonErr } result.Id = &id return result, err } // JSONGetMethod takes a message and tries to find the bitcoin command that it // is in reply to so it can be processed further. func JSONGetMethod(message []byte) (string, error) { // Need this so we can tell what kind of message we are sending // so we can unmarshal it properly. var method string var msg interface{} err := json.Unmarshal(message, &msg) if err != nil { err := fmt.Errorf("Error, message does not appear to be valid json: %v", err) return method, err } m := msg.(map[string]interface{}) for k, v := range m { if k == "method" { method = v.(string) } } if method == "" { err := fmt.Errorf("Error, no method specified.") return method, err } return method, err } // TlsRpcCommand takes a message generated from one of the routines above // along with the login/server information and any relavent PEM encoded // certificates chains. It sends the command via https and returns a go struct // with the result. func TlsRpcCommand(user string, password string, server string, message []byte, certificates []byte, skipverify bool) (Reply, error) { return rpcCommand(user, password, server, message, true, certificates, skipverify) } // RpcCommand takes a message generated from one of the routines above // along with the login/server info, sends it, and gets a reply, returning // a go struct with the result. func RpcCommand(user string, password string, server string, message []byte) (Reply, error) { return rpcCommand(user, password, server, message, false, nil, false) } func rpcCommand(user string, password string, server string, message []byte, https bool, certificates []byte, skipverify bool) (Reply, error) { var result Reply method, err := JSONGetMethod(message) if err != nil { return result, err } body, err := rpcRawCommand(user, password, server, message, https, certificates, skipverify) if err != nil { err := fmt.Errorf("Error getting json reply: %v", err) return result, err } result, err = ReadResultCmd(method, body) if err != nil { err := fmt.Errorf("Error reading json message: %v", err) return result, err } return result, err } // TlsRpcRawCommand takes a message generated from one of the routines above // along with the login,server info and PEM encoded certificate chains for the // server sends it, and gets a reply, returning // the raw []byte response for use with ReadResultCmd. func TlsRpcRawCommand(user string, password string, server string, message []byte, certificates []byte, skipverify bool) ([]byte, error) { return rpcRawCommand(user, password, server, message, true, certificates, skipverify) } // RpcRawCommand takes a message generated from one of the routines above // along with the login/server info, sends it, and gets a reply, returning // the raw []byte response for use with ReadResultCmd. func RpcRawCommand(user string, password string, server string, message []byte) ([]byte, error) { return rpcRawCommand(user, password, server, message, false, nil, false) } // rpcRawCommand is a helper function for the above two functions. func rpcRawCommand(user string, password string, server string, message []byte, https bool, certificates []byte, skipverify bool) ([]byte, error) { var result []byte var msg interface{} err := json.Unmarshal(message, &msg) if err != nil { err := fmt.Errorf("Error, message does not appear to be valid json: %v", err) return result, err } resp, err := jsonRpcSend(user, password, server, message, https, certificates, skipverify) if err != nil { err := fmt.Errorf("Error sending json message: " + err.Error()) return result, err } result, err = GetRaw(resp.Body) if err != nil { err := fmt.Errorf("Error getting json reply: %v", err) return result, err } return result, err } // IsValidIdType checks that the Id field (which can go in any of the json // messages) is valid. json rpc 1.0 allows any (json) type, but we still need // to prevent values that cannot be marshalled from going in. json rpc 2.0 // (which bitcoind follows for some parts) only allows string, number, or null, // so we restrict to that list. Ths is only necessary if you manually marshal // a message. The normal btcjson functions only use string ids. func IsValidIdType(id interface{}) bool { switch id.(type) { case int, int8, int16, int32, int64, uint, uint8, uint16, uint32, uint64, float32, float64, string, nil: return true default: return false } } // JSONToAmount Safely converts a floating point value to an int. // Clearly not all floating point numbers can be converted to ints (there // is no one-to-one mapping, but bitcoin's json api returns most numbers as // floats which are not safe to use when handling money. Since bitcoins can // only be divided in a limited way, this methods works for the amounts returned // by the json api. It is not for general use. // This follows the method described at: // https://en.bitcoin.it/wiki/Proper_Money_Handling_%28JSON-RPC%29 func JSONToAmount(jsonAmount float64) (int64, error) { var amount int64 var err error if jsonAmount > 1.797693134862315708145274237317043567981e+300 { err := fmt.Errorf("Error %v is too large to convert", jsonAmount) return amount, err } if jsonAmount < -1.797693134862315708145274237317043567981e+300 { err := fmt.Errorf("Error %v is too small to convert", jsonAmount) return amount, err } tempVal := 1e8 * jsonAmount // So we round properly. float won't == 0 and if it did, that // would be converted fine anyway. if tempVal < 0 { tempVal = tempVal - 0.5 } if tempVal > 0 { tempVal = tempVal + 0.5 } // Then just rely on the integer truncating amount = int64(tempVal) return amount, err }