lbcd/rpcserver.go
Olaoluwa Osuntokun 0029905d43 Integrate a valid ECDSA signature cache into btcd
Introduce an ECDSA signature verification into btcd in order to
mitigate a certain DoS attack and as a performance optimization.

The benefits of SigCache are two fold. Firstly, usage of SigCache
mitigates a DoS attack wherein an attacker causes a victim's client to
hang due to worst-case behavior triggered while processing attacker
crafted invalid transactions. A detailed description of the mitigated
DoS attack can be found here: https://bitslog.wordpress.com/2013/01/23/fixed-bitcoin-vulnerability-explanation-why-the-signature-cache-is-a-dos-protection/
Secondly, usage of the SigCache introduces a signature verification
optimization which speeds up the validation of transactions within a
block, if they've already been seen and verified within the mempool.

The server itself manages the sigCache instance. The blockManager and
txMempool respectively now receive pointers to the created sigCache
instance. All read (sig triplet existence) operations on the sigCache
will not block unless a separate goroutine is adding an entry (writing)
to the sigCache. GetBlockTemplate generation now also utilizes the
sigCache in order to avoid unnecessarily double checking signatures
when generating a template after previously accepting a txn to the
mempool. Consequently, the CPU miner now also employs the same
optimization.

The maximum number of entries for the sigCache has been introduced as a
config parameter in order to allow users to configure the amount of
memory consumed by this new additional caching.
2015-10-08 17:31:42 -07:00

3970 lines
127 KiB
Go

// Copyright (c) 2013-2015 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package main
import (
"bytes"
"crypto/subtle"
"crypto/tls"
"encoding/base64"
"encoding/binary"
"encoding/hex"
"encoding/json"
"errors"
"fmt"
"io"
"io/ioutil"
"math/big"
"math/rand"
"net"
"net/http"
"os"
"strconv"
"strings"
"sync"
"sync/atomic"
"time"
"github.com/btcsuite/btcd/blockchain"
"github.com/btcsuite/btcd/btcec"
"github.com/btcsuite/btcd/btcjson"
"github.com/btcsuite/btcd/chaincfg"
"github.com/btcsuite/btcd/database"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
"github.com/btcsuite/fastsha256"
"github.com/btcsuite/websocket"
)
const (
// rpcAuthTimeoutSeconds is the number of seconds a connection to the
// RPC server is allowed to stay open without authenticating before it
// is closed.
rpcAuthTimeoutSeconds = 10
// uint256Size is the number of bytes needed to represent an unsigned
// 256-bit integer.
uint256Size = 32
// getworkDataLen is the length of the data field of the getwork RPC.
// It consists of the serialized block header plus the internal sha256
// padding. The internal sha256 padding consists of a single 1 bit
// followed by enough zeros to pad the message out to 56 bytes followed
// by length of the message in bits encoded as a big-endian uint64
// (8 bytes). Thus, the resulting length is a multiple of the sha256
// block size (64 bytes).
getworkDataLen = (1 + ((wire.MaxBlockHeaderPayload + 8) /
fastsha256.BlockSize)) * fastsha256.BlockSize
// hash1Len is the length of the hash1 field of the getwork RPC. It
// consists of a zero hash plus the internal sha256 padding. See
// the getworkDataLen comment for details about the internal sha256
// padding format.
hash1Len = (1 + ((wire.HashSize + 8) / fastsha256.BlockSize)) *
fastsha256.BlockSize
// gbtNonceRange is two 32-bit big-endian hexadecimal integers which
// represent the valid ranges of nonces returned by the getblocktemplate
// RPC.
gbtNonceRange = "00000000ffffffff"
// gbtRegenerateSeconds is the number of seconds that must pass before
// a new template is generated when the previous block hash has not
// changed and there have been changes to the available transactions
// in the memory pool.
gbtRegenerateSeconds = 60
)
var (
// gbtMutableFields are the manipulations the server allows to be made
// to block templates generated by the getblocktemplate RPC. It is
// declared here to avoid the overhead of creating the slice on every
// invocation for constant data.
gbtMutableFields = []string{
"time", "transactions/add", "prevblock", "coinbase/append",
}
// gbtCoinbaseAux describes additional data that miners should include
// in the coinbase signature script. It is declared here to avoid the
// overhead of creating a new object on every invocation for constant
// data.
gbtCoinbaseAux = &btcjson.GetBlockTemplateResultAux{
Flags: hex.EncodeToString(builderScript(txscript.
NewScriptBuilder().AddData([]byte(coinbaseFlags)))),
}
// gbtCapabilities describes additional capabilities returned with a
// block template generated by the getblocktemplate RPC. It is
// declared here to avoid the overhead of creating the slice on every
// invocation for constant data.
gbtCapabilities = []string{"proposal"}
)
// Errors
var (
// ErrRPCUnimplemented is an error returned to RPC clients when the
// provided command is recognized, but not implemented.
ErrRPCUnimplemented = &btcjson.RPCError{
Code: btcjson.ErrRPCUnimplemented,
Message: "Command unimplemented",
}
// ErrRPCNoWallet is an error returned to RPC clients when the provided
// command is recognized as a wallet command.
ErrRPCNoWallet = &btcjson.RPCError{
Code: btcjson.ErrRPCNoWallet,
Message: "This implementation does not implement wallet commands",
}
)
type commandHandler func(*rpcServer, interface{}, <-chan struct{}) (interface{}, error)
// rpcHandlers maps RPC command strings to appropriate handler functions.
// This is set by init because help references rpcHandlers and thus causes
// a dependency loop.
var rpcHandlers map[string]commandHandler
var rpcHandlersBeforeInit = map[string]commandHandler{
"addnode": handleAddNode,
"createrawtransaction": handleCreateRawTransaction,
"debuglevel": handleDebugLevel,
"decoderawtransaction": handleDecodeRawTransaction,
"decodescript": handleDecodeScript,
"generate": handleGenerate,
"getaddednodeinfo": handleGetAddedNodeInfo,
"getbestblock": handleGetBestBlock,
"getbestblockhash": handleGetBestBlockHash,
"getblock": handleGetBlock,
"getblockcount": handleGetBlockCount,
"getblockhash": handleGetBlockHash,
"getblockheader": handleGetBlockHeader,
"getblocktemplate": handleGetBlockTemplate,
"getconnectioncount": handleGetConnectionCount,
"getcurrentnet": handleGetCurrentNet,
"getdifficulty": handleGetDifficulty,
"getgenerate": handleGetGenerate,
"gethashespersec": handleGetHashesPerSec,
"getinfo": handleGetInfo,
"getmempoolinfo": handleGetMempoolInfo,
"getmininginfo": handleGetMiningInfo,
"getnettotals": handleGetNetTotals,
"getnetworkhashps": handleGetNetworkHashPS,
"getpeerinfo": handleGetPeerInfo,
"getrawmempool": handleGetRawMempool,
"getrawtransaction": handleGetRawTransaction,
"gettxout": handleGetTxOut,
"getwork": handleGetWork,
"help": handleHelp,
"node": handleNode,
"ping": handlePing,
"searchrawtransactions": handleSearchRawTransactions,
"sendrawtransaction": handleSendRawTransaction,
"setgenerate": handleSetGenerate,
"stop": handleStop,
"submitblock": handleSubmitBlock,
"validateaddress": handleValidateAddress,
"verifychain": handleVerifyChain,
"verifymessage": handleVerifyMessage,
}
// list of commands that we recognise, but for which btcd has no support because
// it lacks support for wallet functionality. For these commands the user
// should ask a connected instance of btcwallet.
var rpcAskWallet = map[string]struct{}{
"addmultisigaddress": struct{}{},
"backupwallet": struct{}{},
"createencryptedwallet": struct{}{},
"createmultisig": struct{}{},
"dumpprivkey": struct{}{},
"dumpwallet": struct{}{},
"encryptwallet": struct{}{},
"getaccount": struct{}{},
"getaccountaddress": struct{}{},
"getaddressesbyaccount": struct{}{},
"getbalance": struct{}{},
"getnewaddress": struct{}{},
"getrawchangeaddress": struct{}{},
"getreceivedbyaccount": struct{}{},
"getreceivedbyaddress": struct{}{},
"gettransaction": struct{}{},
"gettxoutsetinfo": struct{}{},
"getunconfirmedbalance": struct{}{},
"getwalletinfo": struct{}{},
"importprivkey": struct{}{},
"importwallet": struct{}{},
"keypoolrefill": struct{}{},
"listaccounts": struct{}{},
"listaddressgroupings": struct{}{},
"listlockunspent": struct{}{},
"listreceivedbyaccount": struct{}{},
"listreceivedbyaddress": struct{}{},
"listsinceblock": struct{}{},
"listtransactions": struct{}{},
"listunspent": struct{}{},
"lockunspent": struct{}{},
"move": struct{}{},
"sendfrom": struct{}{},
"sendmany": struct{}{},
"sendtoaddress": struct{}{},
"setaccount": struct{}{},
"settxfee": struct{}{},
"signmessage": struct{}{},
"signrawtransaction": struct{}{},
"walletlock": struct{}{},
"walletpassphrase": struct{}{},
"walletpassphrasechange": struct{}{},
}
// Commands that are currently unimplemented, but should ultimately be.
var rpcUnimplemented = map[string]struct{}{
"estimatefee": struct{}{},
"estimatepriority": struct{}{},
"getblockchaininfo": struct{}{},
"getchaintips": struct{}{},
"getnetworkinfo": struct{}{},
}
// Commands that are available to a limited user
var rpcLimited = map[string]struct{}{
// Websockets commands
"notifyblocks": struct{}{},
"notifynewtransactions": struct{}{},
"notifyreceived": struct{}{},
"notifyspent": struct{}{},
"rescan": struct{}{},
"session": struct{}{},
// Websockets AND HTTP/S commands
"help": struct{}{},
// HTTP/S-only commands
"createrawtransaction": struct{}{},
"decoderawtransaction": struct{}{},
"decodescript": struct{}{},
"getbestblock": struct{}{},
"getbestblockhash": struct{}{},
"getblock": struct{}{},
"getblockcount": struct{}{},
"getblockhash": struct{}{},
"getcurrentnet": struct{}{},
"getdifficulty": struct{}{},
"getinfo": struct{}{},
"getnettotals": struct{}{},
"getnetworkhashps": struct{}{},
"getrawmempool": struct{}{},
"getrawtransaction": struct{}{},
"gettxout": struct{}{},
"searchrawtransactions": struct{}{},
"sendrawtransaction": struct{}{},
"submitblock": struct{}{},
"validateaddress": struct{}{},
"verifymessage": struct{}{},
}
// builderScript is a convenience function which is used for hard-coded scripts
// built with the script builder. Any errors are converted to a panic since it
// is only, and must only, be used with hard-coded, and therefore, known good,
// scripts.
func builderScript(builder *txscript.ScriptBuilder) []byte {
script, err := builder.Script()
if err != nil {
panic(err)
}
return script
}
// internalRPCError is a convenience function to convert an internal error to
// an RPC error with the appropriate code set. It also logs the error to the
// RPC server subsystem since internal errors really should not occur. The
// context parameter is only used in the log message and may be empty if it's
// not needed.
func internalRPCError(errStr, context string) *btcjson.RPCError {
logStr := errStr
if context != "" {
logStr = context + ": " + errStr
}
rpcsLog.Error(logStr)
return btcjson.NewRPCError(btcjson.ErrRPCInternal.Code, errStr)
}
// rpcDecodeHexError is a convenience function for returning a nicely formatted
// RPC error which indicates the provided hex string failed to decode.
func rpcDecodeHexError(gotHex string) *btcjson.RPCError {
return btcjson.NewRPCError(btcjson.ErrRPCDecodeHexString,
fmt.Sprintf("Argument must be hexadecimal string (not %q)",
gotHex))
}
// workStateBlockInfo houses information about how to reconstruct a block given
// its template and signature script.
type workStateBlockInfo struct {
msgBlock *wire.MsgBlock
signatureScript []byte
}
// workState houses state that is used in between multiple RPC invocations to
// getwork.
type workState struct {
sync.Mutex
lastTxUpdate time.Time
lastGenerated time.Time
prevHash *wire.ShaHash
msgBlock *wire.MsgBlock
extraNonce uint64
blockInfo map[wire.ShaHash]*workStateBlockInfo
}
// newWorkState returns a new instance of a workState with all internal fields
// initialized and ready to use.
func newWorkState() *workState {
return &workState{
blockInfo: make(map[wire.ShaHash]*workStateBlockInfo),
}
}
// gbtWorkState houses state that is used in between multiple RPC invocations to
// getblocktemplate.
type gbtWorkState struct {
sync.Mutex
lastTxUpdate time.Time
lastGenerated time.Time
prevHash *wire.ShaHash
minTimestamp time.Time
template *BlockTemplate
notifyMap map[wire.ShaHash]map[int64]chan struct{}
timeSource blockchain.MedianTimeSource
}
// newGbtWorkState returns a new instance of a gbtWorkState with all internal
// fields initialized and ready to use.
func newGbtWorkState(timeSource blockchain.MedianTimeSource) *gbtWorkState {
return &gbtWorkState{
notifyMap: make(map[wire.ShaHash]map[int64]chan struct{}),
timeSource: timeSource,
}
}
// handleUnimplemented is the handler for commands that should ultimately be
// supported but are not yet implemented.
func handleUnimplemented(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
return nil, ErrRPCUnimplemented
}
// handleAskWallet is the handler for commands that are recognized as valid, but
// are unable to answer correctly since it involves wallet state.
// These commands will be implemented in btcwallet.
func handleAskWallet(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
return nil, ErrRPCNoWallet
}
// handleAddNode handles addnode commands.
func handleAddNode(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.AddNodeCmd)
addr := normalizeAddress(c.Addr, activeNetParams.DefaultPort)
var err error
switch c.SubCmd {
case "add":
err = s.server.ConnectNode(addr, true)
case "remove":
err = s.server.RemoveNodeByAddr(addr)
case "onetry":
err = s.server.ConnectNode(addr, false)
default:
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: "invalid subcommand for addnode",
}
}
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: err.Error(),
}
}
// no data returned unless an error.
return nil, nil
}
// handleNode handles node commands.
func handleNode(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.NodeCmd)
var addr string
var nodeId uint64
var errN, err error
switch c.SubCmd {
case "disconnect":
// If we have a valid uint disconnect by node id. Otherwise,
// attempt to disconnect by address, returning an error if a
// valid IP address is not supplied.
if nodeId, errN = strconv.ParseUint(c.Target, 10, 32); errN == nil {
err = s.server.DisconnectNodeById(int32(nodeId))
} else {
if _, _, errP := net.SplitHostPort(c.Target); errP == nil || net.ParseIP(c.Target) != nil {
addr = normalizeAddress(c.Target, activeNetParams.DefaultPort)
err = s.server.DisconnectNodeByAddr(addr)
} else {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: "invalid address or node ID",
}
}
}
if err != nil && peerExists(s.server.PeerInfo(), addr, int32(nodeId)) {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCMisc,
Message: "can't disconnect a permanent peer, use remove",
}
}
case "remove":
// If we have a valid uint disconnect by node id. Otherwise,
// attempt to disconnect by address, returning an error if a
// valid IP address is not supplied.
if nodeId, errN = strconv.ParseUint(c.Target, 10, 32); errN == nil {
err = s.server.RemoveNodeById(int32(nodeId))
} else {
if _, _, errP := net.SplitHostPort(c.Target); errP == nil || net.ParseIP(c.Target) != nil {
addr = normalizeAddress(c.Target, activeNetParams.DefaultPort)
err = s.server.RemoveNodeByAddr(addr)
} else {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: "invalid address or node ID",
}
}
}
if err != nil && peerExists(s.server.PeerInfo(), addr, int32(nodeId)) {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCMisc,
Message: "can't remove a temporary peer, use disconnect",
}
}
case "connect":
addr = normalizeAddress(c.Target, activeNetParams.DefaultPort)
// Default to temporary connections.
subCmd := "temp"
if c.ConnectSubCmd != nil {
subCmd = *c.ConnectSubCmd
}
switch subCmd {
case "perm", "temp":
err = s.server.ConnectNode(addr, subCmd == "perm")
default:
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: "invalid subcommand for node connect",
}
}
default:
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: "invalid subcommand for node",
}
}
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: err.Error(),
}
}
// no data returned unless an error.
return nil, nil
}
// peerExists determines if a certain peer is currently connected given
// information about all currently connected peers. Peer existence is
// determined using either a target address or node id.
func peerExists(peerInfos []*btcjson.GetPeerInfoResult, addr string, nodeId int32) bool {
for _, peerInfo := range peerInfos {
if peerInfo.ID == nodeId || peerInfo.Addr == addr {
return true
}
}
return false
}
// messageToHex serializes a message to the wire protocol encoding using the
// latest protocol version and returns a hex-encoded string of the result.
func messageToHex(msg wire.Message) (string, error) {
var buf bytes.Buffer
if err := msg.BtcEncode(&buf, maxProtocolVersion); err != nil {
context := fmt.Sprintf("Failed to encode msg of type %T", msg)
return "", internalRPCError(err.Error(), context)
}
return hex.EncodeToString(buf.Bytes()), nil
}
// handleCreateRawTransaction handles createrawtransaction commands.
func handleCreateRawTransaction(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.CreateRawTransactionCmd)
// Add all transaction inputs to a new transaction after performing
// some validity checks.
mtx := wire.NewMsgTx()
for _, input := range c.Inputs {
txHash, err := wire.NewShaHashFromStr(input.Txid)
if err != nil {
return nil, rpcDecodeHexError(input.Txid)
}
prevOut := wire.NewOutPoint(txHash, uint32(input.Vout))
txIn := wire.NewTxIn(prevOut, []byte{})
mtx.AddTxIn(txIn)
}
// Add all transaction outputs to the transaction after performing
// some validity checks.
for encodedAddr, amount := range c.Amounts {
// Ensure amount is in the valid range for monetary amounts.
if amount <= 0 || amount > btcutil.MaxSatoshi {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCType,
Message: "Invalid amount",
}
}
// Decode the provided address.
addr, err := btcutil.DecodeAddress(encodedAddr,
activeNetParams.Params)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidAddressOrKey,
Message: "Invalid address or key: " + err.Error(),
}
}
// Ensure the address is one of the supported types and that
// the network encoded with the address matches the network the
// server is currently on.
switch addr.(type) {
case *btcutil.AddressPubKeyHash:
case *btcutil.AddressScriptHash:
default:
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidAddressOrKey,
Message: "Invalid address or key",
}
}
if !addr.IsForNet(s.server.chainParams) {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidAddressOrKey,
Message: "Invalid address: " + encodedAddr +
" is for the wrong network",
}
}
// Create a new script which pays to the provided address.
pkScript, err := txscript.PayToAddrScript(addr)
if err != nil {
context := "Failed to generate pay-to-address script"
return nil, internalRPCError(err.Error(), context)
}
// Convert the amount to satoshi.
satoshi, err := btcutil.NewAmount(amount)
if err != nil {
context := "Failed to convert amount"
return nil, internalRPCError(err.Error(), context)
}
txOut := wire.NewTxOut(int64(satoshi), pkScript)
mtx.AddTxOut(txOut)
}
// Return the serialized and hex-encoded transaction. Note that this
// is intentionally not directly returning because the first return
// value is a string and it would result in returning an empty string to
// the client instead of nothing (nil) in the case of an error.
mtxHex, err := messageToHex(mtx)
if err != nil {
return nil, err
}
return mtxHex, nil
}
// handleDebugLevel handles debuglevel commands.
func handleDebugLevel(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.DebugLevelCmd)
// Special show command to list supported subsystems.
if c.LevelSpec == "show" {
return fmt.Sprintf("Supported subsystems %v",
supportedSubsystems()), nil
}
err := parseAndSetDebugLevels(c.LevelSpec)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParams.Code,
Message: err.Error(),
}
}
return "Done.", nil
}
// createVinList returns a slice of JSON objects for the inputs of the passed
// transaction.
func createVinList(mtx *wire.MsgTx) []btcjson.Vin {
// Coinbase transactions only have a single txin by definition.
vinList := make([]btcjson.Vin, len(mtx.TxIn))
if blockchain.IsCoinBaseTx(mtx) {
txIn := mtx.TxIn[0]
vinList[0].Coinbase = hex.EncodeToString(txIn.SignatureScript)
vinList[0].Sequence = txIn.Sequence
return vinList
}
for i, txIn := range mtx.TxIn {
// The disassembled string will contain [error] inline
// if the script doesn't fully parse, so ignore the
// error here.
disbuf, _ := txscript.DisasmString(txIn.SignatureScript)
vinEntry := &vinList[i]
vinEntry.Txid = txIn.PreviousOutPoint.Hash.String()
vinEntry.Vout = txIn.PreviousOutPoint.Index
vinEntry.Sequence = txIn.Sequence
vinEntry.ScriptSig = &btcjson.ScriptSig{
Asm: disbuf,
Hex: hex.EncodeToString(txIn.SignatureScript),
}
}
return vinList
}
// createVinList returns a slice of JSON objects for the inputs of the passed
// transaction.
func createVinListPrevOut(s *rpcServer, mtx *wire.MsgTx, chainParams *chaincfg.Params, vinExtra int) []btcjson.VinPrevOut {
// Coinbase transactions only have a single txin by definition.
vinList := make([]btcjson.VinPrevOut, len(mtx.TxIn))
if blockchain.IsCoinBaseTx(mtx) {
txIn := mtx.TxIn[0]
vinList[0].Coinbase = hex.EncodeToString(txIn.SignatureScript)
vinList[0].Sequence = txIn.Sequence
return vinList
}
// Lookup all of the referenced transactions needed to populate the
// previous output information if requested.
var txStore blockchain.TxStore
if vinExtra != 0 {
tx := btcutil.NewTx(mtx)
txStoreNew, err := s.server.txMemPool.fetchInputTransactions(tx, true)
if err == nil {
txStore = txStoreNew
}
}
for i, txIn := range mtx.TxIn {
// The disassembled string will contain [error] inline
// if the script doesn't fully parse, so ignore the
// error here.
disbuf, _ := txscript.DisasmString(txIn.SignatureScript)
vinEntry := &vinList[i]
vinEntry.Txid = txIn.PreviousOutPoint.Hash.String()
vinEntry.Vout = txIn.PreviousOutPoint.Index
vinEntry.Sequence = txIn.Sequence
vinEntry.ScriptSig = &btcjson.ScriptSig{
Asm: disbuf,
Hex: hex.EncodeToString(txIn.SignatureScript),
}
// Only populate previous output information if requested and
// available.
if vinExtra == 0 || len(txStore) == 0 {
continue
}
txData := txStore[txIn.PreviousOutPoint.Hash]
if txData == nil {
continue
}
originTxOut := txData.Tx.MsgTx().TxOut[txIn.PreviousOutPoint.Index]
// Ignore the error here since an error means the script
// couldn't parse and there is no additional information about
// it anyways.
var strAddrs []string
_, addrs, _, _ := txscript.ExtractPkScriptAddrs(
originTxOut.PkScript, chainParams)
if addrs != nil {
strAddrs = make([]string, len(addrs))
for j, addr := range addrs {
strAddrs[j] = addr.EncodeAddress()
}
}
vinEntry.PrevOut = &btcjson.PrevOut{
Addresses: strAddrs,
Value: btcutil.Amount(originTxOut.Value).ToBTC(),
}
}
return vinList
}
// createVoutList returns a slice of JSON objects for the outputs of the passed
// transaction.
func createVoutList(mtx *wire.MsgTx, chainParams *chaincfg.Params) []btcjson.Vout {
voutList := make([]btcjson.Vout, len(mtx.TxOut))
for i, v := range mtx.TxOut {
voutList[i].N = uint32(i)
voutList[i].Value = btcutil.Amount(v.Value).ToBTC()
// The disassembled string will contain [error] inline if the
// script doesn't fully parse, so ignore the error here.
disbuf, _ := txscript.DisasmString(v.PkScript)
voutList[i].ScriptPubKey.Asm = disbuf
voutList[i].ScriptPubKey.Hex = hex.EncodeToString(v.PkScript)
// Ignore the error here since an error means the script
// couldn't parse and there is no additional information about
// it anyways.
scriptClass, addrs, reqSigs, _ := txscript.ExtractPkScriptAddrs(
v.PkScript, chainParams)
voutList[i].ScriptPubKey.Type = scriptClass.String()
voutList[i].ScriptPubKey.ReqSigs = int32(reqSigs)
if addrs == nil {
voutList[i].ScriptPubKey.Addresses = nil
} else {
voutList[i].ScriptPubKey.Addresses = make([]string, len(addrs))
for j, addr := range addrs {
voutList[i].ScriptPubKey.Addresses[j] = addr.EncodeAddress()
}
}
}
return voutList
}
// createSearchRawTransactionsResult converts the passed transaction and associated parameters
// to a raw transaction JSON object, possibly with vin.PrevOut section.
func createSearchRawTransactionsResult(s *rpcServer, chainParams *chaincfg.Params, mtx *wire.MsgTx,
txHash string, blkHeader *wire.BlockHeader, blkHash string,
blkHeight int32, chainHeight int32, vinExtra int) (*btcjson.SearchRawTransactionsResult, error) {
mtxHex, err := messageToHex(mtx)
if err != nil {
return nil, err
}
txReply := &btcjson.SearchRawTransactionsResult{
Hex: mtxHex,
Txid: txHash,
Vout: createVoutList(mtx, chainParams),
Vin: createVinListPrevOut(s, mtx, chainParams, vinExtra),
Version: mtx.Version,
LockTime: mtx.LockTime,
}
if blkHeader != nil {
// This is not a typo, they are identical in bitcoind as well.
txReply.Time = blkHeader.Timestamp.Unix()
txReply.Blocktime = blkHeader.Timestamp.Unix()
txReply.BlockHash = blkHash
txReply.Confirmations = uint64(1 + chainHeight - blkHeight)
}
return txReply, nil
}
// createTxRawResult converts the passed transaction and associated parameters
// to a raw transaction JSON object.
func createTxRawResult(chainParams *chaincfg.Params, mtx *wire.MsgTx,
txHash string, blkHeader *wire.BlockHeader, blkHash string,
blkHeight int32, chainHeight int32) (*btcjson.TxRawResult, error) {
mtxHex, err := messageToHex(mtx)
if err != nil {
return nil, err
}
txReply := &btcjson.TxRawResult{
Hex: mtxHex,
Txid: txHash,
Vout: createVoutList(mtx, chainParams),
Vin: createVinList(mtx),
Version: mtx.Version,
LockTime: mtx.LockTime,
}
if blkHeader != nil {
// This is not a typo, they are identical in bitcoind as well.
txReply.Time = blkHeader.Timestamp.Unix()
txReply.Blocktime = blkHeader.Timestamp.Unix()
txReply.BlockHash = blkHash
txReply.Confirmations = uint64(1 + chainHeight - blkHeight)
}
return txReply, nil
}
// handleDecodeRawTransaction handles decoderawtransaction commands.
func handleDecodeRawTransaction(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.DecodeRawTransactionCmd)
// Deserialize the transaction.
hexStr := c.HexTx
if len(hexStr)%2 != 0 {
hexStr = "0" + hexStr
}
serializedTx, err := hex.DecodeString(hexStr)
if err != nil {
return nil, rpcDecodeHexError(hexStr)
}
var mtx wire.MsgTx
err = mtx.Deserialize(bytes.NewReader(serializedTx))
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCDeserialization,
Message: "TX decode failed: " + err.Error(),
}
}
// Create and return the result.
txReply := btcjson.TxRawDecodeResult{
Txid: mtx.TxSha().String(),
Version: mtx.Version,
Locktime: mtx.LockTime,
Vin: createVinList(&mtx),
Vout: createVoutList(&mtx, s.server.chainParams),
}
return txReply, nil
}
// handleDecodeScript handles decodescript commands.
func handleDecodeScript(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.DecodeScriptCmd)
// Convert the hex script to bytes.
hexStr := c.HexScript
if len(hexStr)%2 != 0 {
hexStr = "0" + hexStr
}
script, err := hex.DecodeString(hexStr)
if err != nil {
return nil, rpcDecodeHexError(hexStr)
}
// The disassembled string will contain [error] inline if the script
// doesn't fully parse, so ignore the error here.
disbuf, _ := txscript.DisasmString(script)
// Get information about the script.
// Ignore the error here since an error means the script couldn't parse
// and there is no additinal information about it anyways.
scriptClass, addrs, reqSigs, _ := txscript.ExtractPkScriptAddrs(script,
s.server.chainParams)
addresses := make([]string, len(addrs))
for i, addr := range addrs {
addresses[i] = addr.EncodeAddress()
}
// Convert the script itself to a pay-to-script-hash address.
p2sh, err := btcutil.NewAddressScriptHash(script, s.server.chainParams)
if err != nil {
context := "Failed to convert script to pay-to-script-hash"
return nil, internalRPCError(err.Error(), context)
}
// Generate and return the reply.
reply := btcjson.DecodeScriptResult{
Asm: disbuf,
ReqSigs: int32(reqSigs),
Type: scriptClass.String(),
Addresses: addresses,
P2sh: p2sh.EncodeAddress(),
}
return reply, nil
}
// handleGenerate handles generate commands.
func handleGenerate(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
// Respond with an error if there are no addresses to pay the
// created blocks to.
if len(cfg.miningAddrs) == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInternal.Code,
Message: "No payment addresses specified " +
"via --miningaddr",
}
}
c := cmd.(*btcjson.GenerateCmd)
// Respond with an error if the client is requesting 0 blocks to be generated.
if c.NumBlocks == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInternal.Code,
Message: "Please request a nonzero number of blocks to generate.",
}
}
// Create a reply
reply := make([]string, c.NumBlocks)
blockHashes, err := s.server.cpuMiner.GenerateNBlocks(c.NumBlocks)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInternal.Code,
Message: err.Error(),
}
}
// Mine the correct number of blocks, assigning the hex representation of the
// hash of each one to its place in the reply.
for i, hash := range blockHashes {
reply[i] = hash.String()
}
return reply, nil
}
// handleGetAddedNodeInfo handles getaddednodeinfo commands.
func handleGetAddedNodeInfo(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetAddedNodeInfoCmd)
// Retrieve a list of persistent (added) peers from the bitcoin server
// and filter the list of peer per the specified address (if any).
peers := s.server.AddedNodeInfo()
if c.Node != nil {
node := *c.Node
found := false
for i, peer := range peers {
if peer.addr == node {
peers = peers[i : i+1]
found = true
}
}
if !found {
return nil, &btcjson.RPCError{
Code: -24, // TODO: ErrRPCClientNodeNotAdded
Message: "Node has not been added",
}
}
}
// Without the dns flag, the result is just a slice of the addresses as
// strings.
if !c.DNS {
results := make([]string, 0, len(peers))
for _, peer := range peers {
results = append(results, peer.addr)
}
return results, nil
}
// With the dns flag, the result is an array of JSON objects which
// include the result of DNS lookups for each peer.
results := make([]*btcjson.GetAddedNodeInfoResult, 0, len(peers))
for _, peer := range peers {
// Set the "address" of the peer which could be an ip address
// or a domain name.
var result btcjson.GetAddedNodeInfoResult
result.AddedNode = peer.addr
result.Connected = btcjson.Bool(peer.Connected())
// Split the address into host and port portions so we can do
// a DNS lookup against the host. When no port is specified in
// the address, just use the address as the host.
host, _, err := net.SplitHostPort(peer.addr)
if err != nil {
host = peer.addr
}
// Do a DNS lookup for the address. If the lookup fails, just
// use the host.
var ipList []string
ips, err := btcdLookup(host)
if err == nil {
ipList = make([]string, 0, len(ips))
for _, ip := range ips {
ipList = append(ipList, ip.String())
}
} else {
ipList = make([]string, 1)
ipList[0] = host
}
// Add the addresses and connection info to the result.
addrs := make([]btcjson.GetAddedNodeInfoResultAddr, 0, len(ipList))
for _, ip := range ipList {
var addr btcjson.GetAddedNodeInfoResultAddr
addr.Address = ip
addr.Connected = "false"
if ip == host && peer.Connected() {
addr.Connected = directionString(peer.inbound)
}
addrs = append(addrs, addr)
}
result.Addresses = &addrs
results = append(results, &result)
}
return results, nil
}
// handleGetBestBlock implements the getbestblock command.
func handleGetBestBlock(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
// All other "get block" commands give either the height, the
// hash, or both but require the block SHA. This gets both for
// the best block.
sha, height, err := s.server.db.NewestSha()
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCBestBlockHash,
Message: "Error getting best block hash",
}
}
result := &btcjson.GetBestBlockResult{
Hash: sha.String(),
Height: int32(height),
}
return result, nil
}
// handleGetBestBlockHash implements the getbestblockhash command.
func handleGetBestBlockHash(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
sha, _, err := s.server.db.NewestSha()
if err != nil {
rpcsLog.Errorf("Error getting newest sha: %v", err)
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCBestBlockHash,
Message: "Error getting best block hash",
}
}
return sha.String(), nil
}
// getDifficultyRatio returns the proof-of-work difficulty as a multiple of the
// minimum difficulty using the passed bits field from the header of a block.
func getDifficultyRatio(bits uint32) float64 {
// The minimum difficulty is the max possible proof-of-work limit bits
// converted back to a number. Note this is not the same as the the
// proof of work limit directly because the block difficulty is encoded
// in a block with the compact form which loses precision.
max := blockchain.CompactToBig(activeNetParams.PowLimitBits)
target := blockchain.CompactToBig(bits)
difficulty := new(big.Rat).SetFrac(max, target)
outString := difficulty.FloatString(8)
diff, err := strconv.ParseFloat(outString, 64)
if err != nil {
rpcsLog.Errorf("Cannot get difficulty: %v", err)
return 0
}
return diff
}
// handleGetBlock implements the getblock command.
func handleGetBlock(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetBlockCmd)
sha, err := wire.NewShaHashFromStr(c.Hash)
if err != nil {
return nil, rpcDecodeHexError(c.Hash)
}
blk, err := s.server.db.FetchBlockBySha(sha)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCBlockNotFound,
Message: "Block not found",
}
}
// When the verbose flag isn't set, simply return the network-serialized
// block as a hex-encoded string.
if c.Verbose != nil && !*c.Verbose {
// Note that this is intentionally not directly returning
// because the first return value is a string and it would
// result in returning an empty string to the client instead of
// nothing (nil) in the case of an error.
blkHex, err := messageToHex(blk.MsgBlock())
if err != nil {
return nil, err
}
return blkHex, nil
}
// The verbose flag is set, so generate the JSON object and return it.
buf, err := blk.Bytes()
if err != nil {
context := "Failed to get block bytes"
return nil, internalRPCError(err.Error(), context)
}
idx := blk.Height()
_, maxIdx, err := s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
blockHeader := &blk.MsgBlock().Header
blockReply := btcjson.GetBlockVerboseResult{
Hash: c.Hash,
Version: blockHeader.Version,
MerkleRoot: blockHeader.MerkleRoot.String(),
PreviousHash: blockHeader.PrevBlock.String(),
Nonce: blockHeader.Nonce,
Time: blockHeader.Timestamp.Unix(),
Confirmations: uint64(1 + maxIdx - idx),
Height: int64(idx),
Size: int32(len(buf)),
Bits: strconv.FormatInt(int64(blockHeader.Bits), 16),
Difficulty: getDifficultyRatio(blockHeader.Bits),
}
if c.VerboseTx == nil || !*c.VerboseTx {
transactions := blk.Transactions()
txNames := make([]string, len(transactions))
for i, tx := range transactions {
txNames[i] = tx.Sha().String()
}
blockReply.Tx = txNames
} else {
txns := blk.Transactions()
rawTxns := make([]btcjson.TxRawResult, len(txns))
for i, tx := range txns {
rawTxn, err := createTxRawResult(s.server.chainParams,
tx.MsgTx(), tx.Sha().String(), blockHeader,
sha.String(), idx, maxIdx)
if err != nil {
return nil, err
}
rawTxns[i] = *rawTxn
}
blockReply.RawTx = rawTxns
}
// Get next block unless we are already at the top.
if idx < maxIdx {
var shaNext *wire.ShaHash
shaNext, err = s.server.db.FetchBlockShaByHeight(idx + 1)
if err != nil {
context := "No next block"
return nil, internalRPCError(err.Error(), context)
}
blockReply.NextHash = shaNext.String()
}
return blockReply, nil
}
// handleGetBlockCount implements the getblockcount command.
func handleGetBlockCount(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
_, maxIdx, err := s.server.db.NewestSha()
if err != nil {
rpcsLog.Errorf("Error getting newest sha: %v", err)
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCBlockCount,
Message: "Error getting block count: " + err.Error(),
}
}
return maxIdx, nil
}
// handleGetBlockHash implements the getblockhash command.
func handleGetBlockHash(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetBlockHashCmd)
sha, err := s.server.db.FetchBlockShaByHeight(int32(c.Index))
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCOutOfRange,
Message: "Block number out of range",
}
}
return sha.String(), nil
}
// handleGetBlockHeader implements the getblockheader command.
func handleGetBlockHeader(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetBlockHeaderCmd)
sha, err := wire.NewShaHashFromStr(c.Hash)
if err != nil {
return nil, err
}
if c.Verbose == nil || *c.Verbose {
blk, err := s.server.db.FetchBlockBySha(sha)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidAddressOrKey,
Message: "Invalid address or key: " + err.Error(),
}
}
_, maxIdx, err := s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
var shaNextStr string
shaNext, err := s.server.db.FetchBlockShaByHeight(blk.Height() + 1)
if err == nil {
shaNextStr = shaNext.String()
}
msgBlock := blk.MsgBlock()
blockHeaderReply := btcjson.GetBlockHeaderVerboseResult{
Hash: c.Hash,
Confirmations: uint64(1 + maxIdx - blk.Height()),
Height: int32(blk.Height()),
Version: msgBlock.Header.Version,
MerkleRoot: msgBlock.Header.MerkleRoot.String(),
NextHash: shaNextStr,
PreviousHash: msgBlock.Header.PrevBlock.String(),
Nonce: uint64(msgBlock.Header.Nonce),
Time: msgBlock.Header.Timestamp.Unix(),
Bits: strconv.FormatInt(int64(msgBlock.Header.Bits), 16),
Difficulty: getDifficultyRatio(msgBlock.Header.Bits),
}
return blockHeaderReply, nil
}
// Verbose disabled
blkHeader, err := s.server.db.FetchBlockHeaderBySha(sha)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidAddressOrKey,
Message: "Invalid address or key: " + err.Error(),
}
}
buf := bytes.NewBuffer(make([]byte, 0, wire.MaxBlockHeaderPayload))
if err = blkHeader.BtcEncode(buf, maxProtocolVersion); err != nil {
errStr := fmt.Sprintf("Failed to serialize data: %v", err)
return nil, internalRPCError(errStr, "")
}
return hex.EncodeToString(buf.Bytes()), nil
}
// encodeTemplateID encodes the passed details into an ID that can be used to
// uniquely identify a block template.
func encodeTemplateID(prevHash *wire.ShaHash, lastGenerated time.Time) string {
return fmt.Sprintf("%s-%d", prevHash.String(), lastGenerated.Unix())
}
// decodeTemplateID decodes an ID that is used to uniquely identify a block
// template. This is mainly used as a mechanism to track when to update clients
// that are using long polling for block templates. The ID consists of the
// previous block hash for the associated template and the time the associated
// template was generated.
func decodeTemplateID(templateID string) (*wire.ShaHash, int64, error) {
fields := strings.Split(templateID, "-")
if len(fields) != 2 {
return nil, 0, errors.New("invalid longpollid format")
}
prevHash, err := wire.NewShaHashFromStr(fields[0])
if err != nil {
return nil, 0, errors.New("invalid longpollid format")
}
lastGenerated, err := strconv.ParseInt(fields[1], 10, 64)
if err != nil {
return nil, 0, errors.New("invalid longpollid format")
}
return prevHash, lastGenerated, nil
}
// notifyLongPollers notifies any channels that have been registered to be
// notified when block templates are stale.
//
// This function MUST be called with the state locked.
func (state *gbtWorkState) notifyLongPollers(latestHash *wire.ShaHash, lastGenerated time.Time) {
// Notify anything that is waiting for a block template update from a
// hash which is not the hash of the tip of the best chain since their
// work is now invalid.
for hash, channels := range state.notifyMap {
if !hash.IsEqual(latestHash) {
for _, c := range channels {
close(c)
}
delete(state.notifyMap, hash)
}
}
// Return now if the provided last generated timestamp has not been
// initialized.
if lastGenerated.IsZero() {
return
}
// Return now if there is nothing registered for updates to the current
// best block hash.
channels, ok := state.notifyMap[*latestHash]
if !ok {
return
}
// Notify anything that is waiting for a block template update from a
// block template generated before the most recently generated block
// template.
lastGeneratedUnix := lastGenerated.Unix()
for lastGen, c := range channels {
if lastGen < lastGeneratedUnix {
close(c)
delete(channels, lastGen)
}
}
// Remove the entry altogether if there are no more registered
// channels.
if len(channels) == 0 {
delete(state.notifyMap, *latestHash)
}
}
// NotifyBlockConnected uses the newly-connected block to notify any long poll
// clients with a new block template when their existing block template is
// stale due to the newly connected block.
func (state *gbtWorkState) NotifyBlockConnected(blockSha *wire.ShaHash) {
go func() {
state.Lock()
defer state.Unlock()
state.notifyLongPollers(blockSha, state.lastTxUpdate)
}()
}
// NotifyMempoolTx uses the new last updated time for the transaction memory
// pool to notify any long poll clients with a new block template when their
// existing block template is stale due to enough time passing and the contents
// of the memory pool changing.
func (state *gbtWorkState) NotifyMempoolTx(lastUpdated time.Time) {
go func() {
state.Lock()
defer state.Unlock()
// No need to notify anything if no block templates have been generated
// yet.
if state.prevHash == nil || state.lastGenerated.IsZero() {
return
}
if time.Now().After(state.lastGenerated.Add(time.Second *
gbtRegenerateSeconds)) {
state.notifyLongPollers(state.prevHash, lastUpdated)
}
}()
}
// templateUpdateChan returns a channel that will be closed once the block
// template associated with the passed previous hash and last generated time
// is stale. The function will return existing channels for duplicate
// parameters which allows multiple clients to wait for the same block template
// without requiring a different channel for each client.
//
// This function MUST be called with the state locked.
func (state *gbtWorkState) templateUpdateChan(prevHash *wire.ShaHash, lastGenerated int64) chan struct{} {
// Either get the current list of channels waiting for updates about
// changes to block template for the previous hash or create a new one.
channels, ok := state.notifyMap[*prevHash]
if !ok {
m := make(map[int64]chan struct{})
state.notifyMap[*prevHash] = m
channels = m
}
// Get the current channel associated with the time the block template
// was last generated or create a new one.
c, ok := channels[lastGenerated]
if !ok {
c = make(chan struct{})
channels[lastGenerated] = c
}
return c
}
// updateBlockTemplate creates or updates a block template for the work state.
// A new block template will be generated when the current best block has
// changed or the transactions in the memory pool have been updated and it has
// been some time has passed since the last template was generated. Otherwise,
// the timestamp for the existing block template is updated (and possibly the
// difficulty on testnet per the consesus rules). Finally, if the
// useCoinbaseValue flag is flase and the existing block template does not
// already contain a valid payment address, the block template will be updated
// with a randomly selected payment address from the list of configured
// addresses.
//
// This function MUST be called with the state locked.
func (state *gbtWorkState) updateBlockTemplate(s *rpcServer, useCoinbaseValue bool) error {
lastTxUpdate := s.server.txMemPool.LastUpdated()
if lastTxUpdate.IsZero() {
lastTxUpdate = time.Now()
}
// Generate a new block template when the current best block has
// changed or the transactions in the memory pool have been updated and
// it has been at least gbtRegenerateSecond since the last template was
// generated.
var msgBlock *wire.MsgBlock
var targetDifficulty string
latestHash, _ := s.server.blockManager.chainState.Best()
template := state.template
if template == nil || state.prevHash == nil ||
!state.prevHash.IsEqual(latestHash) ||
(state.lastTxUpdate != lastTxUpdate &&
time.Now().After(state.lastGenerated.Add(time.Second*
gbtRegenerateSeconds))) {
// Reset the previous best hash the block template was generated
// against so any errors below cause the next invocation to try
// again.
state.prevHash = nil
// Choose a payment address at random if the caller requests a
// full coinbase as opposed to only the pertinent details needed
// to create their own coinbase.
var payAddr btcutil.Address
if !useCoinbaseValue {
payAddr = cfg.miningAddrs[rand.Intn(len(cfg.miningAddrs))]
}
// Create a new block template that has a coinbase which anyone
// can redeem. This is only acceptable because the returned
// block template doesn't include the coinbase, so the caller
// will ultimately create their own coinbase which pays to the
// appropriate address(es).
blkTemplate, err := NewBlockTemplate(s.server, payAddr)
if err != nil {
return internalRPCError("Failed to create new block "+
"template: "+err.Error(), "")
}
template = blkTemplate
msgBlock = template.block
targetDifficulty = fmt.Sprintf("%064x",
blockchain.CompactToBig(msgBlock.Header.Bits))
// Find the minimum allowed timestamp for the block based on the
// median timestamp of the last several blocks per the chain
// consensus rules.
chainState := &s.server.blockManager.chainState
minTimestamp, err := minimumMedianTime(chainState)
if err != nil {
context := "Failed to get minimum median time"
return internalRPCError(err.Error(), context)
}
// Update work state to ensure another block template isn't
// generated until needed.
state.template = template
state.lastGenerated = time.Now()
state.lastTxUpdate = lastTxUpdate
state.prevHash = latestHash
state.minTimestamp = minTimestamp
rpcsLog.Debugf("Generated block template (timestamp %v, "+
"target %s, merkle root %s)",
msgBlock.Header.Timestamp, targetDifficulty,
msgBlock.Header.MerkleRoot)
// Notify any clients that are long polling about the new
// template.
state.notifyLongPollers(latestHash, lastTxUpdate)
} else {
// At this point, there is a saved block template and another
// request for a template was made, but either the available
// transactions haven't change or it hasn't been long enough to
// trigger a new block template to be generated. So, update the
// existing block template.
// When the caller requires a full coinbase as opposed to only
// the pertinent details needed to create their own coinbase,
// add a payment address to the output of the coinbase of the
// template if it doesn't already have one. Since this requires
// mining addresses to be specified via the config, an error is
// returned if none have been specified.
if !useCoinbaseValue && !template.validPayAddress {
// Choose a payment address at random.
payToAddr := cfg.miningAddrs[rand.Intn(len(cfg.miningAddrs))]
// Update the block coinbase output of the template to
// pay to the randomly selected payment address.
pkScript, err := txscript.PayToAddrScript(payToAddr)
if err != nil {
context := "Failed to create pay-to-addr script"
return internalRPCError(err.Error(), context)
}
template.block.Transactions[0].TxOut[0].PkScript = pkScript
template.validPayAddress = true
// Update the merkle root.
block := btcutil.NewBlock(template.block)
merkles := blockchain.BuildMerkleTreeStore(block.Transactions())
template.block.Header.MerkleRoot = *merkles[len(merkles)-1]
}
// Set locals for convenience.
msgBlock = template.block
targetDifficulty = fmt.Sprintf("%064x",
blockchain.CompactToBig(msgBlock.Header.Bits))
// Update the time of the block template to the current time
// while accounting for the median time of the past several
// blocks per the chain consensus rules.
UpdateBlockTime(msgBlock, s.server.blockManager)
msgBlock.Header.Nonce = 0
rpcsLog.Debugf("Updated block template (timestamp %v, "+
"target %s)", msgBlock.Header.Timestamp,
targetDifficulty)
}
return nil
}
// blockTemplateResult returns the current block template associated with the
// state as a btcjson.GetBlockTemplateResult that is ready to be encoded to JSON
// and returned to the caller.
//
// This function MUST be called with the state locked.
func (state *gbtWorkState) blockTemplateResult(useCoinbaseValue bool, submitOld *bool) (*btcjson.GetBlockTemplateResult, error) {
// Ensure the timestamps are still in valid range for the template.
// This should really only ever happen if the local clock is changed
// after the template is generated, but it's important to avoid serving
// invalid block templates.
template := state.template
msgBlock := template.block
header := &msgBlock.Header
adjustedTime := state.timeSource.AdjustedTime()
maxTime := adjustedTime.Add(time.Second * blockchain.MaxTimeOffsetSeconds)
if header.Timestamp.After(maxTime) {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCOutOfRange,
Message: fmt.Sprintf("The template time is after the "+
"maximum allowed time for a block - template "+
"time %v, maximum time %v", adjustedTime,
maxTime),
}
}
// Convert each transaction in the block template to a template result
// transaction. The result does not include the coinbase, so notice
// the adjustments to the various lengths and indices.
numTx := len(msgBlock.Transactions)
transactions := make([]btcjson.GetBlockTemplateResultTx, 0, numTx-1)
txIndex := make(map[wire.ShaHash]int64, numTx)
for i, tx := range msgBlock.Transactions {
txHash := tx.TxSha()
txIndex[txHash] = int64(i)
// Skip the coinbase transaction.
if i == 0 {
continue
}
// Create an array of 1-based indices to transactions that come
// before this one in the transactions list which this one
// depends on. This is necessary since the created block must
// ensure proper ordering of the dependencies. A map is used
// before creating the final array to prevent duplicate entries
// when mutiple inputs reference the same transaction.
dependsMap := make(map[int64]struct{})
for _, txIn := range tx.TxIn {
if idx, ok := txIndex[txIn.PreviousOutPoint.Hash]; ok {
dependsMap[idx] = struct{}{}
}
}
depends := make([]int64, 0, len(dependsMap))
for idx := range dependsMap {
depends = append(depends, idx)
}
// Serialize the transaction for later conversion to hex.
txBuf := bytes.NewBuffer(make([]byte, 0, tx.SerializeSize()))
if err := tx.Serialize(txBuf); err != nil {
context := "Failed to serialize transaction"
return nil, internalRPCError(err.Error(), context)
}
resultTx := btcjson.GetBlockTemplateResultTx{
Data: hex.EncodeToString(txBuf.Bytes()),
Hash: txHash.String(),
Depends: depends,
Fee: template.fees[i],
SigOps: template.sigOpCounts[i],
}
transactions = append(transactions, resultTx)
}
// Generate the block template reply. Note that following mutations are
// implied by the included or omission of fields:
// Including MinTime -> time/decrement
// Omitting CoinbaseTxn -> coinbase, generation
targetDifficulty := fmt.Sprintf("%064x", blockchain.CompactToBig(header.Bits))
templateID := encodeTemplateID(state.prevHash, state.lastGenerated)
reply := btcjson.GetBlockTemplateResult{
Bits: strconv.FormatInt(int64(header.Bits), 16),
CurTime: header.Timestamp.Unix(),
Height: int64(template.height),
PreviousHash: header.PrevBlock.String(),
SigOpLimit: blockchain.MaxSigOpsPerBlock,
SizeLimit: wire.MaxBlockPayload,
Transactions: transactions,
Version: header.Version,
LongPollID: templateID,
SubmitOld: submitOld,
Target: targetDifficulty,
MinTime: state.minTimestamp.Unix(),
MaxTime: maxTime.Unix(),
Mutable: gbtMutableFields,
NonceRange: gbtNonceRange,
Capabilities: gbtCapabilities,
}
if useCoinbaseValue {
reply.CoinbaseAux = gbtCoinbaseAux
reply.CoinbaseValue = &msgBlock.Transactions[0].TxOut[0].Value
} else {
// Ensure the template has a valid payment address associated
// with it when a full coinbase is requested.
if !template.validPayAddress {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInternal.Code,
Message: "A coinbase transaction has been " +
"requested, but the server has not " +
"been configured with any payment " +
"addresses via --miningaddr",
}
}
// Serialize the transaction for conversion to hex.
tx := msgBlock.Transactions[0]
txBuf := bytes.NewBuffer(make([]byte, 0, tx.SerializeSize()))
if err := tx.Serialize(txBuf); err != nil {
context := "Failed to serialize transaction"
return nil, internalRPCError(err.Error(), context)
}
resultTx := btcjson.GetBlockTemplateResultTx{
Data: hex.EncodeToString(txBuf.Bytes()),
Hash: tx.TxSha().String(),
Depends: []int64{},
Fee: template.fees[0],
SigOps: template.sigOpCounts[0],
}
reply.CoinbaseTxn = &resultTx
}
return &reply, nil
}
// handleGetBlockTemplateLongPoll a helper for handleGetBlockTemplateRequest
// which deals with handling long polling for block templates. When a caller
// sends a request with a long poll ID that was previously returned, a response
// is not sent until the caller should stop working on the previous block
// template in favor of the new one. In particular, this is the case when the
// old block template is no longer valid due to a solution already being found
// and added to the block chain, or new transactions have shown up and some time
// has passed without finding a solution.
//
// See https://en.bitcoin.it/wiki/BIP_0022 for more details.
func handleGetBlockTemplateLongPoll(s *rpcServer, longPollID string, useCoinbaseValue bool, closeChan <-chan struct{}) (interface{}, error) {
state := s.gbtWorkState
state.Lock()
// The state unlock is intentionally not deferred here since it needs to
// be manually unlocked before waiting for a notification about block
// template changes.
if err := state.updateBlockTemplate(s, useCoinbaseValue); err != nil {
state.Unlock()
return nil, err
}
// Just return the current block template if the the long poll ID
// provided by the caller is invalid.
prevHash, lastGenerated, err := decodeTemplateID(longPollID)
if err != nil {
result, err := state.blockTemplateResult(useCoinbaseValue, nil)
if err != nil {
state.Unlock()
return nil, err
}
state.Unlock()
return result, nil
}
// Return the block template now if the specific block template
// identified by the long poll ID no longer matches the current block
// template as this means the provided template is stale.
prevTemplateHash := &state.template.block.Header.PrevBlock
if !prevHash.IsEqual(prevTemplateHash) ||
lastGenerated != state.lastGenerated.Unix() {
// Include whether or not it is valid to submit work against the
// old block template depending on whether or not a solution has
// already been found and added to the block chain.
submitOld := prevHash.IsEqual(prevTemplateHash)
result, err := state.blockTemplateResult(useCoinbaseValue,
&submitOld)
if err != nil {
state.Unlock()
return nil, err
}
state.Unlock()
return result, nil
}
// Register the previous hash and last generated time for notifications
// Get a channel that will be notified when the template associated with
// the provided ID is is stale and a new block template should be
// returned to the caller.
longPollChan := state.templateUpdateChan(prevHash, lastGenerated)
state.Unlock()
select {
// When the client closes before it's time to send a reply, just return
// now so the goroutine doesn't hang around.
case <-closeChan:
return nil, ErrClientQuit
// Wait until signal received to send the reply.
case <-longPollChan:
// Fallthrough
}
// Get the lastest block template
state.Lock()
defer state.Unlock()
if err := state.updateBlockTemplate(s, useCoinbaseValue); err != nil {
return nil, err
}
// Include whether or not it is valid to submit work against the old
// block template depending on whether or not a solution has already
// been found and added to the block chain.
submitOld := prevHash.IsEqual(&state.template.block.Header.PrevBlock)
result, err := state.blockTemplateResult(useCoinbaseValue, &submitOld)
if err != nil {
return nil, err
}
return result, nil
}
// handleGetBlockTemplateRequest is a helper for handleGetBlockTemplate which
// deals with generating and returning block templates to the caller. It
// handles both long poll requests as specified by BIP 0022 as well as regular
// requests. In addition, it detects the capabilities reported by the caller
// in regards to whether or not it supports creating its own coinbase (the
// coinbasetxn and coinbasevalue capabilities) and modifies the returned block
// template accordingly.
func handleGetBlockTemplateRequest(s *rpcServer, request *btcjson.TemplateRequest, closeChan <-chan struct{}) (interface{}, error) {
// Extract the relevant passed capabilities and restrict the result to
// either a coinbase value or a coinbase transaction object depending on
// the request. Default to only providing a coinbase value.
useCoinbaseValue := true
if request != nil {
var hasCoinbaseValue, hasCoinbaseTxn bool
for _, capability := range request.Capabilities {
switch capability {
case "coinbasetxn":
hasCoinbaseTxn = true
case "coinbasevalue":
hasCoinbaseValue = true
}
}
if hasCoinbaseTxn && !hasCoinbaseValue {
useCoinbaseValue = false
}
}
// When a coinbase transaction has been requested, respond with an error
// if there are no addresses to pay the created block template to.
if !useCoinbaseValue && len(cfg.miningAddrs) == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInternal.Code,
Message: "A coinbase transaction has been requested, " +
"but the server has not been configured with " +
"any payment addresses via --miningaddr",
}
}
// Return an error if there are no peers connected since there is no
// way to relay a found block or receive transactions to work on.
// However, allow this state when running in the regression test or
// simulation test mode.
if !(cfg.RegressionTest || cfg.SimNet) && s.server.ConnectedCount() == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCClientNotConnected,
Message: "Bitcoin is not connected",
}
}
// No point in generating or accepting work before the chain is synced.
_, currentHeight := s.server.blockManager.chainState.Best()
if currentHeight != 0 && !s.server.blockManager.IsCurrent() {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCClientInInitialDownload,
Message: "Bitcoin is downloading blocks...",
}
}
// When a long poll ID was provided, this is a long poll request by the
// client to be notified when block template referenced by the ID should
// be replaced with a new one.
if request != nil && request.LongPollID != "" {
return handleGetBlockTemplateLongPoll(s, request.LongPollID,
useCoinbaseValue, closeChan)
}
// Protect concurrent access when updating block templates.
state := s.gbtWorkState
state.Lock()
defer state.Unlock()
// Get and return a block template. A new block template will be
// generated when the current best block has changed or the transactions
// in the memory pool have been updated and it has been at least five
// seconds since the last template was generated. Otherwise, the
// timestamp for the existing block template is updated (and possibly
// the difficulty on testnet per the consesus rules).
if err := state.updateBlockTemplate(s, useCoinbaseValue); err != nil {
return nil, err
}
return state.blockTemplateResult(useCoinbaseValue, nil)
}
// chainErrToGBTErrString converts an error returned from btcchain to a string
// which matches the reasons and format described in BIP0022 for rejection
// reasons.
func chainErrToGBTErrString(err error) string {
// When the passed error is not a RuleError, just return a generic
// rejected string with the error text.
ruleErr, ok := err.(blockchain.RuleError)
if !ok {
return "rejected: " + err.Error()
}
switch ruleErr.ErrorCode {
case blockchain.ErrDuplicateBlock:
return "duplicate"
case blockchain.ErrBlockTooBig:
return "bad-block-size"
case blockchain.ErrBlockVersionTooOld:
return "bad-version"
case blockchain.ErrInvalidTime:
return "bad-time"
case blockchain.ErrTimeTooOld:
return "time-too-old"
case blockchain.ErrTimeTooNew:
return "time-too-new"
case blockchain.ErrDifficultyTooLow:
return "bad-diffbits"
case blockchain.ErrUnexpectedDifficulty:
return "bad-diffbits"
case blockchain.ErrHighHash:
return "high-hash"
case blockchain.ErrBadMerkleRoot:
return "bad-txnmrklroot"
case blockchain.ErrBadCheckpoint:
return "bad-checkpoint"
case blockchain.ErrForkTooOld:
return "fork-too-old"
case blockchain.ErrCheckpointTimeTooOld:
return "checkpoint-time-too-old"
case blockchain.ErrNoTransactions:
return "bad-txns-none"
case blockchain.ErrTooManyTransactions:
return "bad-txns-toomany"
case blockchain.ErrNoTxInputs:
return "bad-txns-noinputs"
case blockchain.ErrNoTxOutputs:
return "bad-txns-nooutputs"
case blockchain.ErrTxTooBig:
return "bad-txns-size"
case blockchain.ErrBadTxOutValue:
return "bad-txns-outputvalue"
case blockchain.ErrDuplicateTxInputs:
return "bad-txns-dupinputs"
case blockchain.ErrBadTxInput:
return "bad-txns-badinput"
case blockchain.ErrMissingTx:
return "bad-txns-missinginput"
case blockchain.ErrUnfinalizedTx:
return "bad-txns-unfinalizedtx"
case blockchain.ErrDuplicateTx:
return "bad-txns-duplicate"
case blockchain.ErrOverwriteTx:
return "bad-txns-overwrite"
case blockchain.ErrImmatureSpend:
return "bad-txns-maturity"
case blockchain.ErrDoubleSpend:
return "bad-txns-dblspend"
case blockchain.ErrSpendTooHigh:
return "bad-txns-highspend"
case blockchain.ErrBadFees:
return "bad-txns-fees"
case blockchain.ErrTooManySigOps:
return "high-sigops"
case blockchain.ErrFirstTxNotCoinbase:
return "bad-txns-nocoinbase"
case blockchain.ErrMultipleCoinbases:
return "bad-txns-multicoinbase"
case blockchain.ErrBadCoinbaseScriptLen:
return "bad-cb-length"
case blockchain.ErrBadCoinbaseValue:
return "bad-cb-value"
case blockchain.ErrMissingCoinbaseHeight:
return "bad-cb-height"
case blockchain.ErrBadCoinbaseHeight:
return "bad-cb-height"
case blockchain.ErrScriptMalformed:
return "bad-script-malformed"
case blockchain.ErrScriptValidation:
return "bad-script-validate"
}
return "rejected: " + err.Error()
}
// handleGetBlockTemplateProposal is a helper for handleGetBlockTemplate which
// deals with block proposals.
//
// See https://en.bitcoin.it/wiki/BIP_0023 for more details.
func handleGetBlockTemplateProposal(s *rpcServer, request *btcjson.TemplateRequest) (interface{}, error) {
hexData := request.Data
if hexData == "" {
return false, &btcjson.RPCError{
Code: btcjson.ErrRPCType,
Message: fmt.Sprintf("Data must contain the " +
"hex-encoded serialized block that is being " +
"proposed"),
}
}
// Ensure the provided data is sane and deserialize the proposed block.
if len(hexData)%2 != 0 {
hexData = "0" + hexData
}
dataBytes, err := hex.DecodeString(hexData)
if err != nil {
return false, &btcjson.RPCError{
Code: btcjson.ErrRPCDeserialization,
Message: fmt.Sprintf("Data must be "+
"hexadecimal string (not %q)", hexData),
}
}
var msgBlock wire.MsgBlock
if err := msgBlock.Deserialize(bytes.NewReader(dataBytes)); err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCDeserialization,
Message: "Block decode failed: " + err.Error(),
}
}
block := btcutil.NewBlock(&msgBlock)
// Ensure the block is building from the expected previous block.
expectedPrevHash, _ := s.server.blockManager.chainState.Best()
prevHash := &block.MsgBlock().Header.PrevBlock
if expectedPrevHash == nil || !expectedPrevHash.IsEqual(prevHash) {
return "bad-prevblk", nil
}
flags := blockchain.BFDryRun | blockchain.BFNoPoWCheck
isOrphan, err := s.server.blockManager.ProcessBlock(block, flags)
if err != nil {
if _, ok := err.(blockchain.RuleError); !ok {
err := rpcsLog.Errorf("Failed to process block "+
"proposal: %v", err)
return nil, &btcjson.RPCError{
Code: -25, // TODO: ErrRpcVerify
Message: err.Error(),
}
}
rpcsLog.Infof("Rejected block proposal: %v", err)
return chainErrToGBTErrString(err), nil
}
if isOrphan {
return "orphan", nil
}
return nil, nil
}
// handleGetBlockTemplate implements the getblocktemplate command.
//
// See https://en.bitcoin.it/wiki/BIP_0022 and
// https://en.bitcoin.it/wiki/BIP_0023 for more details.
func handleGetBlockTemplate(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetBlockTemplateCmd)
request := c.Request
// Set the default mode and override it if supplied.
mode := "template"
if request != nil && request.Mode != "" {
mode = request.Mode
}
switch mode {
case "template":
return handleGetBlockTemplateRequest(s, request, closeChan)
case "proposal":
return handleGetBlockTemplateProposal(s, request)
}
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: "Invalid mode",
}
}
// handleGetConnectionCount implements the getconnectioncount command.
func handleGetConnectionCount(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
return s.server.ConnectedCount(), nil
}
// handleGetCurrentNet implements the getcurrentnet command.
func handleGetCurrentNet(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
return s.server.chainParams.Net, nil
}
// handleGetDifficulty implements the getdifficulty command.
func handleGetDifficulty(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
sha, _, err := s.server.db.NewestSha()
if err != nil {
rpcsLog.Errorf("Error getting sha: %v", err)
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCDifficulty,
Message: "Error getting difficulty: " + err.Error(),
}
}
blockHeader, err := s.server.db.FetchBlockHeaderBySha(sha)
if err != nil {
rpcsLog.Errorf("Error getting block: %v", err)
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCDifficulty,
Message: "Error getting difficulty: " + err.Error(),
}
}
return getDifficultyRatio(blockHeader.Bits), nil
}
// handleGetGenerate implements the getgenerate command.
func handleGetGenerate(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
return s.server.cpuMiner.IsMining(), nil
}
// handleGetHashesPerSec implements the gethashespersec command.
func handleGetHashesPerSec(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
return int64(s.server.cpuMiner.HashesPerSecond()), nil
}
// handleGetInfo implements the getinfo command. We only return the fields
// that are not related to wallet functionality.
func handleGetInfo(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
// We require the current block height and sha.
sha, height, err := s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
blkHeader, err := s.server.db.FetchBlockHeaderBySha(sha)
if err != nil {
context := "Failed to get block"
return nil, internalRPCError(err.Error(), context)
}
ret := &btcjson.InfoChainResult{
Version: int32(1000000*appMajor + 10000*appMinor + 100*appPatch),
ProtocolVersion: int32(maxProtocolVersion),
Blocks: int32(height),
TimeOffset: int64(s.server.timeSource.Offset().Seconds()),
Connections: s.server.ConnectedCount(),
Proxy: cfg.Proxy,
Difficulty: getDifficultyRatio(blkHeader.Bits),
TestNet: cfg.TestNet3,
RelayFee: float64(minTxRelayFee) / btcutil.SatoshiPerBitcoin,
}
return ret, nil
}
// handleGetMempoolInfo implements the getmempoolinfo command.
func handleGetMempoolInfo(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
txD := s.server.txMemPool.TxDescs()
var numBytes int64
for _, desc := range txD {
numBytes += int64(desc.Tx.MsgTx().SerializeSize())
}
ret := &btcjson.GetMempoolInfoResult{
Size: int64(len(txD)),
Bytes: numBytes,
}
return ret, nil
}
// handleGetMiningInfo implements the getmininginfo command. We only return the
// fields that are not related to wallet functionality.
func handleGetMiningInfo(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
sha, height, err := s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
block, err := s.server.db.FetchBlockBySha(sha)
if err != nil {
context := "Failed to get block"
return nil, internalRPCError(err.Error(), context)
}
blockBytes, err := block.Bytes()
if err != nil {
context := "Failed to get block bytes"
return nil, internalRPCError(err.Error(), context)
}
// Create a default getnetworkhashps command to use defaults and make
// use of the existing getnetworkhashps handler.
gnhpsCmd := btcjson.NewGetNetworkHashPSCmd(nil, nil)
networkHashesPerSecIface, err := handleGetNetworkHashPS(s, gnhpsCmd,
closeChan)
if err != nil {
return nil, err
}
networkHashesPerSec, ok := networkHashesPerSecIface.(int64)
if !ok {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInternal.Code,
Message: "networkHashesPerSec is not an int64",
}
}
result := btcjson.GetMiningInfoResult{
Blocks: int64(height),
CurrentBlockSize: uint64(len(blockBytes)),
CurrentBlockTx: uint64(len(block.MsgBlock().Transactions)),
Difficulty: getDifficultyRatio(block.MsgBlock().Header.Bits),
Generate: s.server.cpuMiner.IsMining(),
GenProcLimit: s.server.cpuMiner.NumWorkers(),
HashesPerSec: int64(s.server.cpuMiner.HashesPerSecond()),
NetworkHashPS: networkHashesPerSec,
PooledTx: uint64(s.server.txMemPool.Count()),
TestNet: cfg.TestNet3,
}
return &result, nil
}
// handleGetNetTotals implements the getnettotals command.
func handleGetNetTotals(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
totalBytesRecv, totalBytesSent := s.server.NetTotals()
reply := &btcjson.GetNetTotalsResult{
TotalBytesRecv: totalBytesRecv,
TotalBytesSent: totalBytesSent,
TimeMillis: time.Now().UTC().UnixNano() / int64(time.Millisecond),
}
return reply, nil
}
// handleGetNetworkHashPS implements the getnetworkhashps command.
func handleGetNetworkHashPS(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
// Note: All valid error return paths should return an int64.
// Literal zeros are inferred as int, and won't coerce to int64
// because the return value is an interface{}.
c := cmd.(*btcjson.GetNetworkHashPSCmd)
_, newestHeight, err := s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
// When the passed height is too high or zero, just return 0 now
// since we can't reasonably calculate the number of network hashes
// per second from invalid values. When it's negative, use the current
// best block height.
endHeight := int32(-1)
if c.Height != nil {
endHeight = int32(*c.Height)
}
if endHeight > newestHeight || endHeight == 0 {
return int64(0), nil
}
if endHeight < 0 {
endHeight = newestHeight
}
// Calculate the starting block height based on the passed number of
// blocks. When the passed value is negative, use the last block the
// difficulty changed as the starting height. Also make sure the
// starting height is not before the beginning of the chain.
numBlocks := int32(120)
if c.Blocks != nil {
numBlocks = int32(*c.Blocks)
}
var startHeight int32
if numBlocks <= 0 {
startHeight = endHeight - ((endHeight % blockchain.BlocksPerRetarget) + 1)
} else {
startHeight = endHeight - numBlocks
}
if startHeight < 0 {
startHeight = 0
}
rpcsLog.Debugf("Calculating network hashes per second from %d to %d",
startHeight, endHeight)
// Find the min and max block timestamps as well as calculate the total
// amount of work that happened between the start and end blocks.
var minTimestamp, maxTimestamp time.Time
totalWork := big.NewInt(0)
for curHeight := startHeight; curHeight <= endHeight; curHeight++ {
hash, err := s.server.db.FetchBlockShaByHeight(curHeight)
if err != nil {
context := "Failed to fetch block hash"
return nil, internalRPCError(err.Error(), context)
}
header, err := s.server.db.FetchBlockHeaderBySha(hash)
if err != nil {
context := "Failed to fetch block header"
return nil, internalRPCError(err.Error(), context)
}
if curHeight == startHeight {
minTimestamp = header.Timestamp
maxTimestamp = minTimestamp
} else {
totalWork.Add(totalWork, blockchain.CalcWork(header.Bits))
if minTimestamp.After(header.Timestamp) {
minTimestamp = header.Timestamp
}
if maxTimestamp.Before(header.Timestamp) {
maxTimestamp = header.Timestamp
}
}
}
// Calculate the difference in seconds between the min and max block
// timestamps and avoid division by zero in the case where there is no
// time difference.
timeDiff := int64(maxTimestamp.Sub(minTimestamp) / time.Second)
if timeDiff == 0 {
return int64(0), nil
}
hashesPerSec := new(big.Int).Div(totalWork, big.NewInt(timeDiff))
return hashesPerSec.Int64(), nil
}
// handleGetPeerInfo implements the getpeerinfo command.
func handleGetPeerInfo(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
return s.server.PeerInfo(), nil
}
// handleGetRawMempool implements the getrawmempool command.
func handleGetRawMempool(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetRawMempoolCmd)
mp := s.server.txMemPool
descs := mp.TxDescs()
if c.Verbose != nil && *c.Verbose {
result := make(map[string]*btcjson.GetRawMempoolVerboseResult,
len(descs))
_, newestHeight, err := s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
mp.RLock()
defer mp.RUnlock()
for _, desc := range descs {
// Calculate the starting and current priority from the
// the tx's inputs. Use zeros if one or more of the
// input transactions can't be found for some reason.
var startingPriority, currentPriority float64
inputTxs, err := mp.fetchInputTransactions(desc.Tx, false)
if err == nil {
startingPriority = desc.StartingPriority(inputTxs)
currentPriority = desc.CurrentPriority(inputTxs,
newestHeight+1)
}
mpd := &btcjson.GetRawMempoolVerboseResult{
Size: int32(desc.Tx.MsgTx().SerializeSize()),
Fee: btcutil.Amount(desc.Fee).ToBTC(),
Time: desc.Added.Unix(),
Height: int64(desc.Height),
StartingPriority: startingPriority,
CurrentPriority: currentPriority,
Depends: make([]string, 0),
}
for _, txIn := range desc.Tx.MsgTx().TxIn {
hash := &txIn.PreviousOutPoint.Hash
if s.server.txMemPool.haveTransaction(hash) {
mpd.Depends = append(mpd.Depends,
hash.String())
}
}
result[desc.Tx.Sha().String()] = mpd
}
return result, nil
}
// The response is simply an array of the transaction hashes if the
// verbose flag is not set.
hashStrings := make([]string, len(descs))
for i := range hashStrings {
hashStrings[i] = descs[i].Tx.Sha().String()
}
return hashStrings, nil
}
// handleGetRawTransaction implements the getrawtransaction command.
func handleGetRawTransaction(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetRawTransactionCmd)
// Convert the provided transaction hash hex to a ShaHash.
txHash, err := wire.NewShaHashFromStr(c.Txid)
if err != nil {
return nil, rpcDecodeHexError(c.Txid)
}
// Try to fetch the transaction from the memory pool and if that fails,
// try the block database.
var mtx *wire.MsgTx
var blkHash *wire.ShaHash
var blkHeight int32
tx, err := s.server.txMemPool.FetchTransaction(txHash)
if err != nil {
txList, err := s.server.db.FetchTxBySha(txHash)
if err != nil || len(txList) == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCNoTxInfo,
Message: "No information available about transaction",
}
}
lastTx := txList[len(txList)-1]
mtx = lastTx.Tx
blkHash = lastTx.BlkSha
blkHeight = lastTx.Height
} else {
mtx = tx.MsgTx()
}
// When the verbose flag isn't set, simply return the network-serialized
// transaction as a hex-encoded string.
if c.Verbose == nil || *c.Verbose == 0 {
// Note that this is intentionally not directly returning
// because the first return value is a string and it would
// result in returning an empty string to the client instead of
// nothing (nil) in the case of an error.
mtxHex, err := messageToHex(mtx)
if err != nil {
return nil, err
}
return mtxHex, nil
}
var blkHeader *wire.BlockHeader
var blkHashStr string
var chainHeight int32
if blkHash != nil {
blkHeader, err = s.server.db.FetchBlockHeaderBySha(blkHash)
if err != nil {
rpcsLog.Errorf("Error fetching sha: %v", err)
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCBlockNotFound,
Message: "Block not found: " + err.Error(),
}
}
_, chainHeight, err = s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
blkHashStr = blkHash.String()
}
rawTxn, err := createTxRawResult(s.server.chainParams, mtx,
txHash.String(), blkHeader, blkHashStr, blkHeight, chainHeight)
if err != nil {
return nil, err
}
return *rawTxn, nil
}
// bigToLEUint256 returns the passed big integer as an unsigned 256-bit integer
// encoded as little-endian bytes. Numbers which are larger than the max
// unsigned 256-bit integer are truncated.
func bigToLEUint256(n *big.Int) [uint256Size]byte {
// Pad or truncate the big-endian big int to correct number of bytes.
nBytes := n.Bytes()
nlen := len(nBytes)
pad := 0
start := 0
if nlen <= uint256Size {
pad = uint256Size - nlen
} else {
start = nlen - uint256Size
}
var buf [uint256Size]byte
copy(buf[pad:], nBytes[start:])
// Reverse the bytes to little endian and return them.
for i := 0; i < uint256Size/2; i++ {
buf[i], buf[uint256Size-1-i] = buf[uint256Size-1-i], buf[i]
}
return buf
}
// reverseUint32Array treats the passed bytes as a series of uint32s and
// reverses the byte order of each uint32. The passed byte slice must be a
// multiple of 4 for a correct result. The passed bytes slice is modified.
func reverseUint32Array(b []byte) {
blen := len(b)
for i := 0; i < blen; i += 4 {
b[i], b[i+3] = b[i+3], b[i]
b[i+1], b[i+2] = b[i+2], b[i+1]
}
}
// handleGetTxOut handles gettxout commands.
func handleGetTxOut(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetTxOutCmd)
// Convert the provided transaction hash hex to a ShaHash.
txHash, err := wire.NewShaHashFromStr(c.Txid)
if err != nil {
return nil, rpcDecodeHexError(c.Txid)
}
// If requested and the tx is available in the mempool try to fetch it
// from there, otherwise attempt to fetch from the block database.
var mtx *wire.MsgTx
var bestBlockSha string
var confirmations int32
var dbSpentInfo []bool
includeMempool := true
if c.IncludeMempool != nil {
includeMempool = *c.IncludeMempool
}
// TODO: This is racy. It should attempt to fetch it directly and check
// the error.
if includeMempool && s.server.txMemPool.HaveTransaction(txHash) {
tx, err := s.server.txMemPool.FetchTransaction(txHash)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCNoTxInfo,
Message: "No information available about transaction",
}
}
mtx = tx.MsgTx()
confirmations = 0
bestBlockSha = ""
} else {
txList, err := s.server.db.FetchTxBySha(txHash)
if err != nil || len(txList) == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCNoTxInfo,
Message: "No information available about transaction",
}
}
lastTx := txList[len(txList)-1]
mtx = lastTx.Tx
blkHash := lastTx.BlkSha
txHeight := lastTx.Height
dbSpentInfo = lastTx.TxSpent
_, bestHeight, err := s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
confirmations = 1 + bestHeight - txHeight
bestBlockSha = blkHash.String()
}
if c.Vout > uint32(len(mtx.TxOut)-1) {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidTxVout,
Message: "Ouput index number (vout) does not exist " +
"for transaction.",
}
}
txOut := mtx.TxOut[c.Vout]
if txOut == nil {
errStr := fmt.Sprintf("Output index: %d for txid: %s does "+
"not exist", c.Vout, c.Txid)
return nil, internalRPCError(errStr, "")
}
// To match the behavior of the reference client, this handler returns
// nil (JSON null) if the transaction output is spent by another
// transaction already in the database. Unspent transaction outputs
// from transactions in mempool, as well as mined transactions that are
// spent by a mempool transaction, are not affected by this.
if dbSpentInfo != nil && dbSpentInfo[c.Vout] {
return nil, nil
}
// Disassemble script into single line printable format.
// The disassembled string will contain [error] inline if the script
// doesn't fully parse, so ignore the error here.
script := txOut.PkScript
disbuf, _ := txscript.DisasmString(script)
// Get further info about the script.
// Ignore the error here since an error means the script couldn't parse
// and there is no additional information about it anyways.
scriptClass, addrs, reqSigs, _ := txscript.ExtractPkScriptAddrs(script,
s.server.chainParams)
addresses := make([]string, len(addrs))
for i, addr := range addrs {
addresses[i] = addr.EncodeAddress()
}
txOutReply := &btcjson.GetTxOutResult{
BestBlock: bestBlockSha,
Confirmations: int64(confirmations),
Value: btcutil.Amount(txOut.Value).ToUnit(btcutil.AmountBTC),
Version: mtx.Version,
ScriptPubKey: btcjson.ScriptPubKeyResult{
Asm: disbuf,
Hex: hex.EncodeToString(script),
ReqSigs: int32(reqSigs),
Type: scriptClass.String(),
Addresses: addresses,
},
Coinbase: blockchain.IsCoinBase(btcutil.NewTx(mtx)),
}
return txOutReply, nil
}
// handleGetWorkRequest is a helper for handleGetWork which deals with
// generating and returning work to the caller.
//
// This function MUST be called with the RPC workstate locked.
func handleGetWorkRequest(s *rpcServer) (interface{}, error) {
state := s.workState
// Generate a new block template when the current best block has
// changed or the transactions in the memory pool have been updated
// and it has been at least one minute since the last template was
// generated.
lastTxUpdate := s.server.txMemPool.LastUpdated()
latestHash, latestHeight := s.server.blockManager.chainState.Best()
msgBlock := state.msgBlock
if msgBlock == nil || state.prevHash == nil ||
!state.prevHash.IsEqual(latestHash) ||
(state.lastTxUpdate != lastTxUpdate &&
time.Now().After(state.lastGenerated.Add(time.Minute))) {
// Reset the extra nonce and clear all cached template
// variations if the best block changed.
if state.prevHash != nil && !state.prevHash.IsEqual(latestHash) {
state.extraNonce = 0
state.blockInfo = make(map[wire.ShaHash]*workStateBlockInfo)
}
// Reset the previous best hash the block template was generated
// against so any errors below cause the next invocation to try
// again.
state.prevHash = nil
// Choose a payment address at random.
payToAddr := cfg.miningAddrs[rand.Intn(len(cfg.miningAddrs))]
template, err := NewBlockTemplate(s.server, payToAddr)
if err != nil {
context := "Failed to create new block template"
return nil, internalRPCError(err.Error(), context)
}
msgBlock = template.block
// Update work state to ensure another block template isn't
// generated until needed.
state.msgBlock = msgBlock
state.lastGenerated = time.Now()
state.lastTxUpdate = lastTxUpdate
state.prevHash = latestHash
rpcsLog.Debugf("Generated block template (timestamp %v, extra "+
"nonce %d, target %064x, merkle root %s, signature "+
"script %x)", msgBlock.Header.Timestamp,
state.extraNonce,
blockchain.CompactToBig(msgBlock.Header.Bits),
msgBlock.Header.MerkleRoot,
msgBlock.Transactions[0].TxIn[0].SignatureScript)
} else {
// At this point, there is a saved block template and a new
// request for work was made, but either the available
// transactions haven't change or it hasn't been long enough to
// trigger a new block template to be generated. So, update the
// existing block template and track the variations so each
// variation can be regenerated if a caller finds an answer and
// makes a submission against it.
// Update the time of the block template to the current time
// while accounting for the median time of the past several
// blocks per the chain consensus rules.
UpdateBlockTime(msgBlock, s.server.blockManager)
// Increment the extra nonce and update the block template
// with the new value by regenerating the coinbase script and
// setting the merkle root to the new value.
state.extraNonce++
err := UpdateExtraNonce(msgBlock, latestHeight+1, state.extraNonce)
if err != nil {
errStr := fmt.Sprintf("Failed to update extra nonce: "+
"%v", err)
return nil, internalRPCError(errStr, "")
}
rpcsLog.Debugf("Updated block template (timestamp %v, extra "+
"nonce %d, target %064x, merkle root %s, signature "+
"script %x)", msgBlock.Header.Timestamp,
state.extraNonce,
blockchain.CompactToBig(msgBlock.Header.Bits),
msgBlock.Header.MerkleRoot,
msgBlock.Transactions[0].TxIn[0].SignatureScript)
}
// In order to efficiently store the variations of block templates that
// have been provided to callers, save a pointer to the block as well as
// the modified signature script keyed by the merkle root. This
// information, along with the data that is included in a work
// submission, is used to rebuild the block before checking the
// submitted solution.
coinbaseTx := msgBlock.Transactions[0]
state.blockInfo[msgBlock.Header.MerkleRoot] = &workStateBlockInfo{
msgBlock: msgBlock,
signatureScript: coinbaseTx.TxIn[0].SignatureScript,
}
// Serialize the block header into a buffer large enough to hold the
// the block header and the internal sha256 padding that is added and
// retuned as part of the data below.
data := make([]byte, 0, getworkDataLen)
buf := bytes.NewBuffer(data)
err := msgBlock.Header.Serialize(buf)
if err != nil {
errStr := fmt.Sprintf("Failed to serialize data: %v", err)
return nil, internalRPCError(errStr, "")
}
// Calculate the midstate for the block header. The midstate here is
// the internal state of the sha256 algorithm for the first chunk of the
// block header (sha256 operates on 64-byte chunks) which is before the
// nonce. This allows sophisticated callers to avoid hashing the first
// chunk over and over while iterating the nonce range.
data = data[:buf.Len()]
midstate := fastsha256.MidState256(data)
// Expand the data slice to include the full data buffer and apply the
// internal sha256 padding which consists of a single 1 bit followed
// by enough zeros to pad the message out to 56 bytes followed by the
// length of the message in bits encoded as a big-endian uint64
// (8 bytes). Thus, the resulting length is a multiple of the sha256
// block size (64 bytes). This makes the data ready for sophisticated
// caller to make use of only the second chunk along with the midstate
// for the first chunk.
data = data[:getworkDataLen]
data[wire.MaxBlockHeaderPayload] = 0x80
binary.BigEndian.PutUint64(data[len(data)-8:],
wire.MaxBlockHeaderPayload*8)
// Create the hash1 field which is a zero hash along with the internal
// sha256 padding as described above. This field is really quite
// useless, but it is required for compatibility with the reference
// implementation.
var hash1 [hash1Len]byte
hash1[wire.HashSize] = 0x80
binary.BigEndian.PutUint64(hash1[len(hash1)-8:], wire.HashSize*8)
// The final result reverses the each of the fields to little endian.
// In particular, the data, hash1, and midstate fields are treated as
// arrays of uint32s (per the internal sha256 hashing state) which are
// in big endian, and thus each 4 bytes is byte swapped. The target is
// also in big endian, but it is treated as a uint256 and byte swapped
// to little endian accordingly.
//
// The fact the fields are reversed in this way is rather odd and likey
// an artifact of some legacy internal state in the reference
// implementation, but it is required for compatibility.
reverseUint32Array(data)
reverseUint32Array(hash1[:])
reverseUint32Array(midstate[:])
target := bigToLEUint256(blockchain.CompactToBig(msgBlock.Header.Bits))
reply := &btcjson.GetWorkResult{
Data: hex.EncodeToString(data),
Hash1: hex.EncodeToString(hash1[:]),
Midstate: hex.EncodeToString(midstate[:]),
Target: hex.EncodeToString(target[:]),
}
return reply, nil
}
// handleGetWorkSubmission is a helper for handleGetWork which deals with
// the calling submitting work to be verified and processed.
//
// This function MUST be called with the RPC workstate locked.
func handleGetWorkSubmission(s *rpcServer, hexData string) (interface{}, error) {
// Ensure the provided data is sane.
if len(hexData)%2 != 0 {
hexData = "0" + hexData
}
data, err := hex.DecodeString(hexData)
if err != nil {
return false, rpcDecodeHexError(hexData)
}
if len(data) != getworkDataLen {
return false, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: fmt.Sprintf("Argument must be "+
"%d bytes (not %d)", getworkDataLen,
len(data)),
}
}
// Reverse the data as if it were an array of 32-bit unsigned integers.
// The fact the getwork request and submission data is reversed in this
// way is rather odd and likey an artifact of some legacy internal state
// in the reference implementation, but it is required for
// compatibility.
reverseUint32Array(data)
// Deserialize the block header from the data.
var submittedHeader wire.BlockHeader
bhBuf := bytes.NewReader(data[0:wire.MaxBlockHeaderPayload])
err = submittedHeader.Deserialize(bhBuf)
if err != nil {
return false, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: fmt.Sprintf("Argument does not "+
"contain a valid block header: %v", err),
}
}
// Look up the full block for the provided data based on the
// merkle root. Return false to indicate the solve failed if
// it's not available.
state := s.workState
blockInfo, ok := state.blockInfo[submittedHeader.MerkleRoot]
if !ok {
rpcsLog.Debugf("Block submitted via getwork has no matching "+
"template for merkle root %s",
submittedHeader.MerkleRoot)
return false, nil
}
// Reconstruct the block using the submitted header stored block info.
msgBlock := blockInfo.msgBlock
block := btcutil.NewBlock(msgBlock)
msgBlock.Header.Timestamp = submittedHeader.Timestamp
msgBlock.Header.Nonce = submittedHeader.Nonce
msgBlock.Transactions[0].TxIn[0].SignatureScript = blockInfo.signatureScript
merkles := blockchain.BuildMerkleTreeStore(block.Transactions())
msgBlock.Header.MerkleRoot = *merkles[len(merkles)-1]
// Ensure the submitted block hash is less than the target difficulty.
err = blockchain.CheckProofOfWork(block, activeNetParams.PowLimit)
if err != nil {
// Anything other than a rule violation is an unexpected error,
// so return that error as an internal error.
if _, ok := err.(blockchain.RuleError); !ok {
return false, internalRPCError("Unexpected error "+
"while checking proof of work: "+err.Error(),
"")
}
rpcsLog.Debugf("Block submitted via getwork does not meet "+
"the required proof of work: %v", err)
return false, nil
}
latestHash, _ := s.server.blockManager.chainState.Best()
if !msgBlock.Header.PrevBlock.IsEqual(latestHash) {
rpcsLog.Debugf("Block submitted via getwork with previous "+
"block %s is stale", msgBlock.Header.PrevBlock)
return false, nil
}
// Process this block using the same rules as blocks coming from other
// nodes. This will in turn relay it to the network like normal.
isOrphan, err := s.server.blockManager.ProcessBlock(block, blockchain.BFNone)
if err != nil || isOrphan {
// Anything other than a rule violation is an unexpected error,
// so return that error as an internal error.
if _, ok := err.(blockchain.RuleError); !ok {
return false, internalRPCError("Unexpected error "+
"while processing block: "+err.Error(), "")
}
rpcsLog.Infof("Block submitted via getwork rejected: %v", err)
return false, nil
}
// The block was accepted.
rpcsLog.Infof("Block submitted via getwork accepted: %s", block.Sha())
return true, nil
}
// handleGetWork implements the getwork command.
func handleGetWork(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.GetWorkCmd)
// Respond with an error if there are no addresses to pay the created
// blocks to.
if len(cfg.miningAddrs) == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInternal.Code,
Message: "No payment addresses specified via --miningaddr",
}
}
// Return an error if there are no peers connected since there is no
// way to relay a found block or receive transactions to work on.
// However, allow this state when running in the regression test or
// simulation test mode.
if !(cfg.RegressionTest || cfg.SimNet) && s.server.ConnectedCount() == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCClientNotConnected,
Message: "Bitcoin is not connected",
}
}
// No point in generating or accepting work before the chain is synced.
_, currentHeight := s.server.blockManager.chainState.Best()
if currentHeight != 0 && !s.server.blockManager.IsCurrent() {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCClientInInitialDownload,
Message: "Bitcoin is downloading blocks...",
}
}
// Protect concurrent access from multiple RPC invocations for work
// requests and submission.
s.workState.Lock()
defer s.workState.Unlock()
// When the caller provides data, it is a submission of a supposedly
// solved block that needs to be checked and submitted to the network
// if valid.
if c.Data != nil && *c.Data != "" {
return handleGetWorkSubmission(s, *c.Data)
}
// No data was provided, so the caller is requesting work.
return handleGetWorkRequest(s)
}
// handleHelp implements the help command.
func handleHelp(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.HelpCmd)
// Provide a usage overview of all commands when no specific command
// was specified.
var command string
if c.Command != nil {
command = *c.Command
}
if command == "" {
usage, err := s.helpCacher.rpcUsage(false)
if err != nil {
context := "Failed to generate RPC usage"
return nil, internalRPCError(err.Error(), context)
}
return usage, nil
}
// Check that the command asked for is supported and implemented. Only
// search the main list of handlers since help should not be provided
// for commands that are unimplemented or related to wallet
// functionality.
if _, ok := rpcHandlers[command]; !ok {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParameter,
Message: "Unknown command: " + command,
}
}
// Get the help for the command.
help, err := s.helpCacher.rpcMethodHelp(command)
if err != nil {
context := "Failed to generate help"
return nil, internalRPCError(err.Error(), context)
}
return help, nil
}
// handlePing implements the ping command.
func handlePing(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
// Ask server to ping \o_
nonce, err := wire.RandomUint64()
if err != nil {
return nil, internalRPCError("Not sending ping - failed to "+
"generate nonce: "+err.Error(), "")
}
s.server.BroadcastMessage(wire.NewMsgPing(nonce))
return nil, nil
}
// getMempoolTxsForAddressRange looks up and returns all transactions from the
// mempool related to the given address. The, `limit` parameter
// should be the max number of transactions to be returned. Additionally, if the
// caller wishes to seek forward in the results some amount, the 'skip' parameter
// represents how many results to skip.
// It will return the array of fetched transactions, along with the amount
// of transactions that were actually skipped.
func getMempoolTxsForAddressRange(s *rpcServer, addr btcutil.Address, skip int,
limit int) ([]*database.TxListReply, int, error) {
memPoolTxs, err := s.server.txMemPool.FilterTransactionsByAddress(addr)
if err != nil {
return nil, 0, err
}
// If we're asked to skip more transactions than we have,
// we skip them all and return an empty slice.
if skip >= len(memPoolTxs) {
return nil, len(memPoolTxs), nil
}
var result []*database.TxListReply
// Otherwise, calculate the range we have to return and return it.
rangeEnd := skip + limit
if rangeEnd > len(memPoolTxs) {
rangeEnd = len(memPoolTxs)
}
for _, tx := range memPoolTxs[skip:rangeEnd] {
txReply := &database.TxListReply{Tx: tx.MsgTx(), Sha: tx.Sha()}
result = append(result, txReply)
}
return result, skip, nil
}
// handleSearchRawTransaction implements the searchrawtransactions command.
func handleSearchRawTransactions(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
if !cfg.AddrIndex {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCMisc,
Message: "Address index must be enabled (--addrindex)",
}
}
if !s.server.addrIndexer.IsCaughtUp() {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCMisc,
Message: "Address index has not yet caught up to the " +
"current best height",
}
}
c := cmd.(*btcjson.SearchRawTransactionsCmd)
// Attempt to decode the supplied address.
addr, err := btcutil.DecodeAddress(c.Address, s.server.chainParams)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidAddressOrKey,
Message: "Invalid address or key: " + err.Error(),
}
}
var addressTxs []*database.TxListReply
var numRequested, numToSkip, skipped int
if c.Count != nil {
numRequested = *c.Count
if numRequested < 0 {
numRequested = 1
}
}
if c.Skip != nil {
numToSkip = *c.Skip
if numToSkip < 0 {
numToSkip = 0
}
}
var reverse bool
if c.Reverse != nil {
reverse = *c.Reverse
}
// Add txs from mempool first if client asked for reverse order, otherwise
// add them last.
// This code (and txMemPool.FilterTransactionsByAddress()) doesn't sort by
// dependency. This might be something we want to do in the future when we
// return results for the client's convenience, or leave it to the client.
if reverse && len(addressTxs) < numRequested {
memPoolTxs, memPoolSkipped, err := getMempoolTxsForAddressRange(s, addr,
numToSkip-skipped, numRequested-len(addressTxs))
if err == nil {
skipped += memPoolSkipped
for _, txReply := range memPoolTxs {
addressTxs = append(addressTxs, txReply)
}
}
}
// Fetch transactions from the database in the desired order if we need more.
if len(addressTxs) < numRequested {
dbTxs, dbSkipped, err := s.server.db.FetchTxsForAddr(addr,
numToSkip-skipped, numRequested-len(addressTxs), reverse)
if err == nil {
skipped += dbSkipped
for _, txReply := range dbTxs {
addressTxs = append(addressTxs, txReply)
}
}
}
// Add txs from mempool last if the client didn't ask for reverse order.
if !reverse && len(addressTxs) < numRequested {
memPoolTxs, memPoolSkipped, err := getMempoolTxsForAddressRange(s, addr,
numToSkip-skipped, numRequested-len(addressTxs))
if err == nil {
skipped += memPoolSkipped
for _, txReply := range memPoolTxs {
addressTxs = append(addressTxs, txReply)
}
}
}
// If neither source yielded any results, then the address has never
// been used.
if len(addressTxs) == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCNoTxInfo,
Message: "No information available about transaction",
}
}
// When not in verbose mode, simply return a list of serialized txs.
if c.Verbose != nil && *c.Verbose == 0 {
serializedTxs := make([]string, len(addressTxs), len(addressTxs))
for i, txReply := range addressTxs {
serializedTxs[i], err = messageToHex(txReply.Tx)
if err != nil {
return nil, err
}
}
return serializedTxs, nil
}
// Otherwise, we'll need to populate raw tx results.
// Grab the current best height for tx confirmation calculation.
_, maxIdx, err := s.server.db.NewestSha()
if err != nil {
context := "Failed to get newest hash"
return nil, internalRPCError(err.Error(), context)
}
rawTxns := make([]btcjson.SearchRawTransactionsResult, len(addressTxs), len(addressTxs))
for i, txReply := range addressTxs {
txHash := txReply.Sha.String()
mtx := txReply.Tx
// Transactions grabbed from the mempool aren't yet
// within a block. So we conditionally fetch a txs
// embedded block here. This will be reflected in the
// final JSON output (mempool won't have confirmations).
var blkHeader *wire.BlockHeader
var blkHashStr string
var blkHeight int32
if txReply.BlkSha != nil {
blkHeader, err = s.server.db.FetchBlockHeaderBySha(txReply.BlkSha)
if err != nil {
rpcsLog.Errorf("Error fetching sha: %v", err)
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCBlockNotFound,
Message: "Block not found",
}
}
blkHashStr = txReply.BlkSha.String()
blkHeight = txReply.Height
}
rawTxn, err := createSearchRawTransactionsResult(s, s.server.chainParams, mtx,
txHash, blkHeader, blkHashStr, blkHeight, maxIdx, *c.VinExtra)
if err != nil {
return nil, err
}
rawTxns[i] = *rawTxn
}
return rawTxns, nil
}
// handleSendRawTransaction implements the sendrawtransaction command.
func handleSendRawTransaction(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.SendRawTransactionCmd)
// Deserialize and send off to tx relay
hexStr := c.HexTx
if len(hexStr)%2 != 0 {
hexStr = "0" + hexStr
}
serializedTx, err := hex.DecodeString(hexStr)
if err != nil {
return nil, rpcDecodeHexError(hexStr)
}
msgtx := wire.NewMsgTx()
err = msgtx.Deserialize(bytes.NewReader(serializedTx))
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCDeserialization,
Message: "TX decode failed: " + err.Error(),
}
}
tx := btcutil.NewTx(msgtx)
err = s.server.txMemPool.ProcessTransaction(tx, false, false)
if err != nil {
// When the error is a rule error, it means the transaction was
// simply rejected as opposed to something actually going wrong,
// so log it as such. Otherwise, something really did go wrong,
// so log it as an actual error. In both cases, a JSON-RPC
// error is returned to the client with the deserialization
// error code (to match bitcoind behavior).
if _, ok := err.(RuleError); ok {
rpcsLog.Debugf("Rejected transaction %v: %v", tx.Sha(),
err)
} else {
rpcsLog.Errorf("Failed to process transaction %v: %v",
tx.Sha(), err)
}
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCDeserialization,
Message: "TX rejected: " + err.Error(),
}
}
// Keep track of all the sendrawtransaction request txns so that they
// can be rebroadcast if they don't make their way into a block.
iv := wire.NewInvVect(wire.InvTypeTx, tx.Sha())
s.server.AddRebroadcastInventory(iv, tx)
return tx.Sha().String(), nil
}
// handleSetGenerate implements the setgenerate command.
func handleSetGenerate(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.SetGenerateCmd)
// Disable generation regardless of the provided generate flag if the
// maximum number of threads (goroutines for our purposes) is 0.
// Otherwise enable or disable it depending on the provided flag.
generate := c.Generate
genProcLimit := -1
if c.GenProcLimit != nil {
genProcLimit = *c.GenProcLimit
}
if genProcLimit == 0 {
generate = false
}
if !generate {
s.server.cpuMiner.Stop()
} else {
// Respond with an error if there are no addresses to pay the
// created blocks to.
if len(cfg.miningAddrs) == 0 {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInternal.Code,
Message: "No payment addresses specified " +
"via --miningaddr",
}
}
// It's safe to call start even if it's already started.
s.server.cpuMiner.SetNumWorkers(int32(genProcLimit))
s.server.cpuMiner.Start()
}
return nil, nil
}
// handleStop implements the stop command.
func handleStop(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
s.server.Stop()
return "btcd stopping.", nil
}
// handleSubmitBlock implements the submitblock command.
func handleSubmitBlock(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.SubmitBlockCmd)
// Deserialize the submitted block.
hexStr := c.HexBlock
if len(hexStr)%2 != 0 {
hexStr = "0" + c.HexBlock
}
serializedBlock, err := hex.DecodeString(hexStr)
if err != nil {
return nil, rpcDecodeHexError(hexStr)
}
block, err := btcutil.NewBlockFromBytes(serializedBlock)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCDeserialization,
Message: "Block decode failed: " + err.Error(),
}
}
_, err = s.server.blockManager.ProcessBlock(block, blockchain.BFNone)
if err != nil {
return fmt.Sprintf("rejected: %s", err.Error()), nil
}
rpcsLog.Infof("Accepted block %s via submitblock", block.Sha())
return nil, nil
}
// handleValidateAddress implements the validateaddress command.
func handleValidateAddress(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.ValidateAddressCmd)
result := btcjson.ValidateAddressChainResult{}
addr, err := btcutil.DecodeAddress(c.Address, activeNetParams.Params)
if err != nil {
// Return the default value (false) for IsValid.
return result, nil
}
result.Address = addr.EncodeAddress()
result.IsValid = true
return result, nil
}
func verifyChain(db database.Db, level, depth int32, timeSource blockchain.MedianTimeSource) error {
_, curHeight64, err := db.NewestSha()
if err != nil {
rpcsLog.Errorf("Verify is unable to fetch current block "+
"height: %v", err)
}
curHeight := int32(curHeight64)
finishHeight := curHeight - depth
if finishHeight < 0 {
finishHeight = 0
}
rpcsLog.Infof("Verifying chain for %d blocks at level %d",
curHeight-finishHeight, level)
for height := curHeight; height > finishHeight; height-- {
// Level 0 just looks up the block.
sha, err := db.FetchBlockShaByHeight(height)
if err != nil {
rpcsLog.Errorf("Verify is unable to fetch block at "+
"height %d: %v", height, err)
return err
}
block, err := db.FetchBlockBySha(sha)
if err != nil {
rpcsLog.Errorf("Verify is unable to fetch block at "+
"sha %v height %d: %v", sha, height, err)
return err
}
// Level 1 does basic chain sanity checks.
if level > 0 {
err := blockchain.CheckBlockSanity(block,
activeNetParams.PowLimit, timeSource)
if err != nil {
rpcsLog.Errorf("Verify is unable to "+
"validate block at sha %v height "+
"%d: %v", sha, height, err)
return err
}
}
}
rpcsLog.Infof("Chain verify completed successfully")
return nil
}
// handleVerifyChain implements the verifychain command.
func handleVerifyChain(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.VerifyChainCmd)
var checkLevel, checkDepth int32
if c.CheckLevel != nil {
checkLevel = *c.CheckLevel
}
if c.CheckDepth != nil {
checkDepth = *c.CheckDepth
}
err := verifyChain(s.server.db, checkLevel, checkDepth,
s.server.timeSource)
return err == nil, nil
}
// handleVerifyMessage implements the verifymessage command.
func handleVerifyMessage(s *rpcServer, cmd interface{}, closeChan <-chan struct{}) (interface{}, error) {
c := cmd.(*btcjson.VerifyMessageCmd)
// Decode the provided address.
addr, err := btcutil.DecodeAddress(c.Address, activeNetParams.Params)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidAddressOrKey,
Message: "Invalid address or key: " + err.Error(),
}
}
// Only P2PKH addresses are valid for signing.
if _, ok := addr.(*btcutil.AddressPubKeyHash); !ok {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCType,
Message: "Address is not a pay-to-pubkey-hash address",
}
}
// Decode base64 signature.
sig, err := base64.StdEncoding.DecodeString(c.Signature)
if err != nil {
return nil, &btcjson.RPCError{
Code: btcjson.ErrRPCParse.Code,
Message: "Malformed base64 encoding: " + err.Error(),
}
}
// Validate the signature - this just shows that it was valid at all.
// we will compare it with the key next.
pk, wasCompressed, err := btcec.RecoverCompact(btcec.S256(), sig,
wire.DoubleSha256([]byte("Bitcoin Signed Message:\n"+c.Message)))
if err != nil {
// Mirror Bitcoin Core behavior, which treats error in
// RecoverCompact as invalid signature.
return false, nil
}
// Reconstruct the pubkey hash.
btcPK := (*btcec.PublicKey)(pk)
var serializedPK []byte
if wasCompressed {
serializedPK = btcPK.SerializeCompressed()
} else {
serializedPK = btcPK.SerializeUncompressed()
}
address, err := btcutil.NewAddressPubKey(serializedPK,
activeNetParams.Params)
if err != nil {
// Again mirror Bitcoin Core behavior, which treats error in public key
// reconstruction as invalid signature.
return false, nil
}
// Return boolean if addresses match.
return address.EncodeAddress() == c.Address, nil
}
// rpcServer holds the items the rpc server may need to access (config,
// shutdown, main server, etc.)
type rpcServer struct {
started int32
shutdown int32
server *server
authsha [fastsha256.Size]byte
limitauthsha [fastsha256.Size]byte
ntfnMgr *wsNotificationManager
numClients int32
statusLines map[int]string
statusLock sync.RWMutex
wg sync.WaitGroup
listeners []net.Listener
workState *workState
gbtWorkState *gbtWorkState
helpCacher *helpCacher
quit chan int
}
// httpStatusLine returns a response Status-Line (RFC 2616 Section 6.1)
// for the given request and response status code. This function was lifted and
// adapted from the standard library HTTP server code since it's not exported.
func (s *rpcServer) httpStatusLine(req *http.Request, code int) string {
// Fast path:
key := code
proto11 := req.ProtoAtLeast(1, 1)
if !proto11 {
key = -key
}
s.statusLock.RLock()
line, ok := s.statusLines[key]
s.statusLock.RUnlock()
if ok {
return line
}
// Slow path:
proto := "HTTP/1.0"
if proto11 {
proto = "HTTP/1.1"
}
codeStr := strconv.Itoa(code)
text := http.StatusText(code)
if text != "" {
line = proto + " " + codeStr + " " + text + "\r\n"
s.statusLock.Lock()
s.statusLines[key] = line
s.statusLock.Unlock()
} else {
text = "status code " + codeStr
line = proto + " " + codeStr + " " + text + "\r\n"
}
return line
}
// writeHTTPResponseHeaders writes the necessary response headers prior to
// writing an HTTP body given a request to use for protocol negotiation, headers
// to write, a status code, and a writer.
func (s *rpcServer) writeHTTPResponseHeaders(req *http.Request, headers http.Header, code int, w io.Writer) error {
_, err := io.WriteString(w, s.httpStatusLine(req, code))
if err != nil {
return err
}
err = headers.Write(w)
if err != nil {
return err
}
_, err = io.WriteString(w, "\r\n")
if err != nil {
return err
}
return nil
}
// Stop is used by server.go to stop the rpc listener.
func (s *rpcServer) Stop() error {
if atomic.AddInt32(&s.shutdown, 1) != 1 {
rpcsLog.Infof("RPC server is already in the process of shutting down")
return nil
}
rpcsLog.Warnf("RPC server shutting down")
for _, listener := range s.listeners {
err := listener.Close()
if err != nil {
rpcsLog.Errorf("Problem shutting down rpc: %v", err)
return err
}
}
s.ntfnMgr.Shutdown()
s.ntfnMgr.WaitForShutdown()
close(s.quit)
s.wg.Wait()
rpcsLog.Infof("RPC server shutdown complete")
return nil
}
// limitConnections responds with a 503 service unavailable and returns true if
// adding another client would exceed the maximum allow RPC clients.
//
// This function is safe for concurrent access.
func (s *rpcServer) limitConnections(w http.ResponseWriter, remoteAddr string) bool {
if int(atomic.LoadInt32(&s.numClients)+1) > cfg.RPCMaxClients {
rpcsLog.Infof("Max RPC clients exceeded [%d] - "+
"disconnecting client %s", cfg.RPCMaxClients,
remoteAddr)
http.Error(w, "503 Too busy. Try again later.",
http.StatusServiceUnavailable)
return true
}
return false
}
// incrementClients adds one to the number of connected RPC clients. Note
// this only applies to standard clients. Websocket clients have their own
// limits and are tracked separately.
//
// This function is safe for concurrent access.
func (s *rpcServer) incrementClients() {
atomic.AddInt32(&s.numClients, 1)
}
// decrementClients subtracts one from the number of connected RPC clients.
// Note this only applies to standard clients. Websocket clients have their own
// limits and are tracked separately.
//
// This function is safe for concurrent access.
func (s *rpcServer) decrementClients() {
atomic.AddInt32(&s.numClients, -1)
}
// checkAuth checks the HTTP Basic authentication supplied by a wallet
// or RPC client in the HTTP request r. If the supplied authentication
// does not match the username and password expected, a non-nil error is
// returned.
//
// This check is time-constant.
//
// The first bool return value signifies auth success (true if successful) and
// the second bool return value specifies whether the user can change the state
// of the server (true) or whether the user is limited (false). The second is
// always false if the first is.
func (s *rpcServer) checkAuth(r *http.Request, require bool) (bool, bool,
error) {
authhdr := r.Header["Authorization"]
if len(authhdr) <= 0 {
if require {
rpcsLog.Warnf("RPC authentication failure from %s",
r.RemoteAddr)
return false, false, errors.New("auth failure")
}
return false, false, nil
}
authsha := fastsha256.Sum256([]byte(authhdr[0]))
// Check for limited auth first as in environments with limited users, those
// are probably expected to have a higher volume of calls
limitcmp := subtle.ConstantTimeCompare(authsha[:], s.limitauthsha[:])
if limitcmp == 1 {
return true, false, nil
}
// Check for admin-level auth
cmp := subtle.ConstantTimeCompare(authsha[:], s.authsha[:])
if cmp == 1 {
return true, true, nil
}
// Request's auth doesn't match either user
rpcsLog.Warnf("RPC authentication failure from %s", r.RemoteAddr)
return false, false, errors.New("auth failure")
}
// parsedRPCCmd represents a JSON-RPC request object that has been parsed into
// a known concrete command along with any error that might have happened while
// parsing it.
type parsedRPCCmd struct {
id interface{}
method string
cmd interface{}
err *btcjson.RPCError
}
// standardCmdResult checks that a parsed command is a standard Bitcoin JSON-RPC
// command and runs the appropriate handler to reply to the command. Any
// commands which are not recognized or not implemented will return an error
// suitable for use in replies.
func (s *rpcServer) standardCmdResult(cmd *parsedRPCCmd, closeChan <-chan struct{}) (interface{}, error) {
handler, ok := rpcHandlers[cmd.method]
if ok {
goto handled
}
_, ok = rpcAskWallet[cmd.method]
if ok {
handler = handleAskWallet
goto handled
}
_, ok = rpcUnimplemented[cmd.method]
if ok {
handler = handleUnimplemented
goto handled
}
return nil, btcjson.ErrRPCMethodNotFound
handled:
return handler(s, cmd.cmd, closeChan)
}
// parseCmd parses a JSON-RPC request object into known concrete command. The
// err field of the returned parsedRPCCmd struct will contain an RPC error that
// is suitable for use in replies if the command is invalid in some way such as
// an unregistered command or invalid parameters.
func parseCmd(request *btcjson.Request) *parsedRPCCmd {
var parsedCmd parsedRPCCmd
parsedCmd.id = request.ID
parsedCmd.method = request.Method
cmd, err := btcjson.UnmarshalCmd(request)
if err != nil {
// When the error is because the method is not registered,
// produce a method not found RPC error.
if jerr, ok := err.(btcjson.Error); ok &&
jerr.ErrorCode == btcjson.ErrUnregisteredMethod {
parsedCmd.err = btcjson.ErrRPCMethodNotFound
return &parsedCmd
}
// Otherwise, some type of invalid parameters is the
// cause, so produce the equivalent RPC error.
parsedCmd.err = btcjson.NewRPCError(
btcjson.ErrRPCInvalidParams.Code, err.Error())
return &parsedCmd
}
parsedCmd.cmd = cmd
return &parsedCmd
}
// createMarshalledReply returns a new marshalled JSON-RPC response given the
// passed parameters. It will automatically convert errors that are not of
// the type *btcjson.RPCError to the appropriate type as needed.
func createMarshalledReply(id, result interface{}, replyErr error) ([]byte, error) {
var jsonErr *btcjson.RPCError
if replyErr != nil {
if jErr, ok := replyErr.(*btcjson.RPCError); ok {
jsonErr = jErr
} else {
jsonErr = internalRPCError(replyErr.Error(), "")
}
}
return btcjson.MarshalResponse(id, result, jsonErr)
}
// jsonRPCRead handles reading and responding to RPC messages.
func (s *rpcServer) jsonRPCRead(w http.ResponseWriter, r *http.Request,
isAdmin bool) {
if atomic.LoadInt32(&s.shutdown) != 0 {
return
}
// Read and close the JSON-RPC request body from the caller.
body, err := ioutil.ReadAll(r.Body)
r.Body.Close()
if err != nil {
errMsg := fmt.Sprintf("error reading JSON message: %v", err)
errCode := http.StatusBadRequest
http.Error(w, strconv.FormatInt(int64(errCode), 10)+" "+errMsg,
errCode)
return
}
// Unfortunately, the http server doesn't provide the ability to
// change the read deadline for the new connection and having one breaks
// long polling. However, not having a read deadline on the initial
// connection would mean clients can connect and idle forever. Thus,
// hijack the connecton from the HTTP server, clear the read deadline,
// and handle writing the response manually.
hj, ok := w.(http.Hijacker)
if !ok {
errMsg := "webserver doesn't support hijacking"
rpcsLog.Warnf(errMsg)
errCode := http.StatusInternalServerError
http.Error(w, strconv.FormatInt(int64(errCode), 10)+" "+errMsg,
errCode)
return
}
conn, buf, err := hj.Hijack()
if err != nil {
rpcsLog.Warnf("Failed to hijack HTTP connection: %v", err)
errCode := http.StatusInternalServerError
http.Error(w, strconv.FormatInt(int64(errCode), 10)+" "+
err.Error(), errCode)
return
}
defer conn.Close()
defer buf.Flush()
conn.SetReadDeadline(timeZeroVal)
// Attempt to parse the raw body into a JSON-RPC request.
var responseID interface{}
var jsonErr error
var result interface{}
var request btcjson.Request
if err := json.Unmarshal(body, &request); err != nil {
jsonErr = &btcjson.RPCError{
Code: btcjson.ErrRPCParse.Code,
Message: "Failed to parse request: " + err.Error(),
}
}
if jsonErr == nil {
// Requests with no ID (notifications) must not have a response
// per the JSON-RPC spec.
if request.ID == nil {
return
}
// The parse was at least successful enough to have an ID so
// set it for the response.
responseID = request.ID
// Setup a close notifier. Since the connection is hijacked,
// the CloseNotifer on the ResponseWriter is not available.
closeChan := make(chan struct{}, 1)
go func() {
_, err := conn.Read(make([]byte, 1))
if err != nil {
close(closeChan)
}
}()
// Check if the user is limited and set error if method unauthorized
if !isAdmin {
if _, ok := rpcLimited[request.Method]; !ok {
jsonErr = &btcjson.RPCError{
Code: btcjson.ErrRPCInvalidParams.Code,
Message: "limited user not authorized for this method",
}
}
}
if jsonErr == nil {
// Attempt to parse the JSON-RPC request into a known concrete
// command.
parsedCmd := parseCmd(&request)
if parsedCmd.err != nil {
jsonErr = parsedCmd.err
} else {
result, jsonErr = s.standardCmdResult(parsedCmd, closeChan)
}
}
}
// Marshal the response.
msg, err := createMarshalledReply(responseID, result, jsonErr)
if err != nil {
rpcsLog.Errorf("Failed to marshal reply: %v", err)
return
}
// Write the response.
err = s.writeHTTPResponseHeaders(r, w.Header(), http.StatusOK, buf)
if err != nil {
rpcsLog.Error(err)
return
}
if _, err := buf.Write(msg); err != nil {
rpcsLog.Errorf("Failed to write marshalled reply: %v", err)
}
}
// jsonAuthFail sends a message back to the client if the http auth is rejected.
func jsonAuthFail(w http.ResponseWriter) {
w.Header().Add("WWW-Authenticate", `Basic realm="btcd RPC"`)
http.Error(w, "401 Unauthorized.", http.StatusUnauthorized)
}
// Start is used by server.go to start the rpc listener.
func (s *rpcServer) Start() {
if atomic.AddInt32(&s.started, 1) != 1 {
return
}
rpcsLog.Trace("Starting RPC server")
rpcServeMux := http.NewServeMux()
httpServer := &http.Server{
Handler: rpcServeMux,
// Timeout connections which don't complete the initial
// handshake within the allowed timeframe.
ReadTimeout: time.Second * rpcAuthTimeoutSeconds,
}
rpcServeMux.HandleFunc("/", func(w http.ResponseWriter, r *http.Request) {
w.Header().Set("Connection", "close")
w.Header().Set("Content-Type", "application/json")
r.Close = true
// Limit the number of connections to max allowed.
if s.limitConnections(w, r.RemoteAddr) {
return
}
// Keep track of the number of connected clients.
s.incrementClients()
defer s.decrementClients()
_, isAdmin, err := s.checkAuth(r, true)
if err != nil {
jsonAuthFail(w)
return
}
// Read and respond to the request.
s.jsonRPCRead(w, r, isAdmin)
})
// Websocket endpoint.
rpcServeMux.HandleFunc("/ws", func(w http.ResponseWriter, r *http.Request) {
authenticated, isAdmin, err := s.checkAuth(r, false)
if err != nil {
jsonAuthFail(w)
return
}
// Attempt to upgrade the connection to a websocket connection
// using the default size for read/write buffers.
ws, err := websocket.Upgrade(w, r, nil, 0, 0)
if err != nil {
if _, ok := err.(websocket.HandshakeError); !ok {
rpcsLog.Errorf("Unexpected websocket error: %v",
err)
}
http.Error(w, "400 Bad Request.", http.StatusBadRequest)
return
}
s.WebsocketHandler(ws, r.RemoteAddr, authenticated, isAdmin)
})
for _, listener := range s.listeners {
s.wg.Add(1)
go func(listener net.Listener) {
rpcsLog.Infof("RPC server listening on %s", listener.Addr())
httpServer.Serve(listener)
rpcsLog.Tracef("RPC listener done for %s", listener.Addr())
s.wg.Done()
}(listener)
}
s.ntfnMgr.Start()
}
// genCertPair generates a key/cert pair to the paths provided.
func genCertPair(certFile, keyFile string) error {
rpcsLog.Infof("Generating TLS certificates...")
org := "btcd autogenerated cert"
validUntil := time.Now().Add(10 * 365 * 24 * time.Hour)
cert, key, err := btcutil.NewTLSCertPair(org, validUntil, nil)
if err != nil {
return err
}
// Write cert and key files.
if err = ioutil.WriteFile(certFile, cert, 0666); err != nil {
return err
}
if err = ioutil.WriteFile(keyFile, key, 0600); err != nil {
os.Remove(certFile)
return err
}
rpcsLog.Infof("Done generating TLS certificates")
return nil
}
// newRPCServer returns a new instance of the rpcServer struct.
func newRPCServer(listenAddrs []string, s *server) (*rpcServer, error) {
rpc := rpcServer{
server: s,
statusLines: make(map[int]string),
workState: newWorkState(),
gbtWorkState: newGbtWorkState(s.timeSource),
helpCacher: newHelpCacher(),
quit: make(chan int),
}
if cfg.RPCUser != "" && cfg.RPCPass != "" {
login := cfg.RPCUser + ":" + cfg.RPCPass
auth := "Basic " + base64.StdEncoding.EncodeToString([]byte(login))
rpc.authsha = fastsha256.Sum256([]byte(auth))
}
if cfg.RPCLimitUser != "" && cfg.RPCLimitPass != "" {
login := cfg.RPCLimitUser + ":" + cfg.RPCLimitPass
auth := "Basic " + base64.StdEncoding.EncodeToString([]byte(login))
rpc.limitauthsha = fastsha256.Sum256([]byte(auth))
}
rpc.ntfnMgr = newWsNotificationManager(&rpc)
// Setup TLS if not disabled.
listenFunc := net.Listen
if !cfg.DisableTLS {
// Generate the TLS cert and key file if both don't already
// exist.
if !fileExists(cfg.RPCKey) && !fileExists(cfg.RPCCert) {
err := genCertPair(cfg.RPCCert, cfg.RPCKey)
if err != nil {
return nil, err
}
}
keypair, err := tls.LoadX509KeyPair(cfg.RPCCert, cfg.RPCKey)
if err != nil {
return nil, err
}
tlsConfig := tls.Config{
Certificates: []tls.Certificate{keypair},
MinVersion: tls.VersionTLS12,
}
// Change the standard net.Listen function to the tls one.
listenFunc = func(net string, laddr string) (net.Listener, error) {
return tls.Listen(net, laddr, &tlsConfig)
}
}
// TODO(oga) this code is similar to that in server, should be
// factored into something shared.
ipv4ListenAddrs, ipv6ListenAddrs, _, err := parseListeners(listenAddrs)
if err != nil {
return nil, err
}
listeners := make([]net.Listener, 0,
len(ipv6ListenAddrs)+len(ipv4ListenAddrs))
for _, addr := range ipv4ListenAddrs {
listener, err := listenFunc("tcp4", addr)
if err != nil {
rpcsLog.Warnf("Can't listen on %s: %v", addr, err)
continue
}
listeners = append(listeners, listener)
}
for _, addr := range ipv6ListenAddrs {
listener, err := listenFunc("tcp6", addr)
if err != nil {
rpcsLog.Warnf("Can't listen on %s: %v", addr, err)
continue
}
listeners = append(listeners, listener)
}
if len(listeners) == 0 {
return nil, errors.New("RPCS: No valid listen address")
}
rpc.listeners = listeners
return &rpc, nil
}
func init() {
rpcHandlers = rpcHandlersBeforeInit
rand.Seed(time.Now().UnixNano())
}