Merge pull request #16619 from kielbarry/contractsgolint

contracts/*: golint updates for this or self warning
This commit is contained in:
Péter Szilágyi 2019-02-07 14:07:03 +02:00 committed by GitHub
commit 85b3b1c8d6
No known key found for this signature in database
GPG Key ID: 4AEE18F83AFDEB23
6 changed files with 225 additions and 239 deletions

@ -27,40 +27,40 @@ const Version = "1.0"
var errNoChequebook = errors.New("no chequebook")
type Api struct {
type API struct {
chequebookf func() *Chequebook
}
func NewApi(ch func() *Chequebook) *Api {
return &Api{ch}
func NewAPI(ch func() *Chequebook) *API {
return &API{ch}
}
func (self *Api) Balance() (string, error) {
ch := self.chequebookf()
func (a *API) Balance() (string, error) {
ch := a.chequebookf()
if ch == nil {
return "", errNoChequebook
}
return ch.Balance().String(), nil
}
func (self *Api) Issue(beneficiary common.Address, amount *big.Int) (cheque *Cheque, err error) {
ch := self.chequebookf()
func (a *API) Issue(beneficiary common.Address, amount *big.Int) (cheque *Cheque, err error) {
ch := a.chequebookf()
if ch == nil {
return nil, errNoChequebook
}
return ch.Issue(beneficiary, amount)
}
func (self *Api) Cash(cheque *Cheque) (txhash string, err error) {
ch := self.chequebookf()
func (a *API) Cash(cheque *Cheque) (txhash string, err error) {
ch := a.chequebookf()
if ch == nil {
return "", errNoChequebook
}
return ch.Cash(cheque)
}
func (self *Api) Deposit(amount *big.Int) (txhash string, err error) {
ch := self.chequebookf()
func (a *API) Deposit(amount *big.Int) (txhash string, err error) {
ch := a.chequebookf()
if ch == nil {
return "", errNoChequebook
}

@ -75,8 +75,8 @@ type Cheque struct {
Sig []byte // signature Sign(Keccak256(contract, beneficiary, amount), prvKey)
}
func (self *Cheque) String() string {
return fmt.Sprintf("contract: %s, beneficiary: %s, amount: %v, signature: %x", self.Contract.Hex(), self.Beneficiary.Hex(), self.Amount, self.Sig)
func (ch *Cheque) String() string {
return fmt.Sprintf("contract: %s, beneficiary: %s, amount: %v, signature: %x", ch.Contract.Hex(), ch.Beneficiary.Hex(), ch.Amount, ch.Sig)
}
type Params struct {
@ -109,12 +109,12 @@ type Chequebook struct {
log log.Logger // contextual logger with the contract address embedded
}
func (self *Chequebook) String() string {
return fmt.Sprintf("contract: %s, owner: %s, balance: %v, signer: %x", self.contractAddr.Hex(), self.owner.Hex(), self.balance, self.prvKey.PublicKey)
func (cb *Chequebook) String() string {
return fmt.Sprintf("contract: %s, owner: %s, balance: %v, signer: %x", cb.contractAddr.Hex(), cb.owner.Hex(), cb.balance, cb.prvKey.PublicKey)
}
// NewChequebook creates a new Chequebook.
func NewChequebook(path string, contractAddr common.Address, prvKey *ecdsa.PrivateKey, backend Backend) (self *Chequebook, err error) {
func NewChequebook(path string, contractAddr common.Address, prvKey *ecdsa.PrivateKey, backend Backend) (*Chequebook, error) {
balance := new(big.Int)
sent := make(map[common.Address]*big.Int)
@ -128,7 +128,7 @@ func NewChequebook(path string, contractAddr common.Address, prvKey *ecdsa.Priva
TransactOpts: *transactOpts,
}
self = &Chequebook{
cb := &Chequebook{
prvKey: prvKey,
balance: balance,
contractAddr: contractAddr,
@ -140,42 +140,39 @@ func NewChequebook(path string, contractAddr common.Address, prvKey *ecdsa.Priva
session: session,
log: log.New("contract", contractAddr),
}
if (contractAddr != common.Address{}) {
self.setBalanceFromBlockChain()
self.log.Trace("New chequebook initialised", "owner", self.owner, "balance", self.balance)
cb.setBalanceFromBlockChain()
cb.log.Trace("New chequebook initialised", "owner", cb.owner, "balance", cb.balance)
}
return
return cb, nil
}
func (self *Chequebook) setBalanceFromBlockChain() {
balance, err := self.backend.BalanceAt(context.TODO(), self.contractAddr, nil)
func (cb *Chequebook) setBalanceFromBlockChain() {
balance, err := cb.backend.BalanceAt(context.TODO(), cb.contractAddr, nil)
if err != nil {
log.Error("Failed to retrieve chequebook balance", "err", err)
} else {
self.balance.Set(balance)
cb.balance.Set(balance)
}
}
// LoadChequebook loads a chequebook from disk (file path).
func LoadChequebook(path string, prvKey *ecdsa.PrivateKey, backend Backend, checkBalance bool) (self *Chequebook, err error) {
var data []byte
data, err = ioutil.ReadFile(path)
if err != nil {
return
}
self, _ = NewChequebook(path, common.Address{}, prvKey, backend)
err = json.Unmarshal(data, self)
func LoadChequebook(path string, prvKey *ecdsa.PrivateKey, backend Backend, checkBalance bool) (*Chequebook, error) {
data, err := ioutil.ReadFile(path)
if err != nil {
return nil, err
}
cb, _ := NewChequebook(path, common.Address{}, prvKey, backend)
if err = json.Unmarshal(data, cb); err != nil {
return nil, err
}
if checkBalance {
self.setBalanceFromBlockChain()
cb.setBalanceFromBlockChain()
}
log.Trace("Loaded chequebook from disk", "path", path)
return
return cb, nil
}
// chequebookFile is the JSON representation of a chequebook.
@ -187,19 +184,19 @@ type chequebookFile struct {
}
// UnmarshalJSON deserialises a chequebook.
func (self *Chequebook) UnmarshalJSON(data []byte) error {
func (cb *Chequebook) UnmarshalJSON(data []byte) error {
var file chequebookFile
err := json.Unmarshal(data, &file)
if err != nil {
return err
}
_, ok := self.balance.SetString(file.Balance, 10)
_, ok := cb.balance.SetString(file.Balance, 10)
if !ok {
return fmt.Errorf("cumulative amount sent: unable to convert string to big integer: %v", file.Balance)
}
self.contractAddr = common.HexToAddress(file.Contract)
cb.contractAddr = common.HexToAddress(file.Contract)
for addr, sent := range file.Sent {
self.sent[common.HexToAddress(addr)], ok = new(big.Int).SetString(sent, 10)
cb.sent[common.HexToAddress(addr)], ok = new(big.Int).SetString(sent, 10)
if !ok {
return fmt.Errorf("beneficiary %v cumulative amount sent: unable to convert string to big integer: %v", addr, sent)
}
@ -208,14 +205,14 @@ func (self *Chequebook) UnmarshalJSON(data []byte) error {
}
// MarshalJSON serialises a chequebook.
func (self *Chequebook) MarshalJSON() ([]byte, error) {
func (cb *Chequebook) MarshalJSON() ([]byte, error) {
var file = &chequebookFile{
Balance: self.balance.String(),
Contract: self.contractAddr.Hex(),
Owner: self.owner.Hex(),
Balance: cb.balance.String(),
Contract: cb.contractAddr.Hex(),
Owner: cb.owner.Hex(),
Sent: make(map[string]string),
}
for addr, sent := range self.sent {
for addr, sent := range cb.sent {
file.Sent[addr.Hex()] = sent.String()
}
return json.Marshal(file)
@ -223,76 +220,78 @@ func (self *Chequebook) MarshalJSON() ([]byte, error) {
// Save persists the chequebook on disk, remembering balance, contract address and
// cumulative amount of funds sent for each beneficiary.
func (self *Chequebook) Save() (err error) {
data, err := json.MarshalIndent(self, "", " ")
func (cb *Chequebook) Save() error {
data, err := json.MarshalIndent(cb, "", " ")
if err != nil {
return err
}
self.log.Trace("Saving chequebook to disk", self.path)
cb.log.Trace("Saving chequebook to disk", cb.path)
return ioutil.WriteFile(self.path, data, os.ModePerm)
return ioutil.WriteFile(cb.path, data, os.ModePerm)
}
// Stop quits the autodeposit go routine to terminate
func (self *Chequebook) Stop() {
defer self.lock.Unlock()
self.lock.Lock()
if self.quit != nil {
close(self.quit)
self.quit = nil
func (cb *Chequebook) Stop() {
defer cb.lock.Unlock()
cb.lock.Lock()
if cb.quit != nil {
close(cb.quit)
cb.quit = nil
}
}
// Issue creates a cheque signed by the chequebook owner's private key. The
// signer commits to a contract (one that they own), a beneficiary and amount.
func (self *Chequebook) Issue(beneficiary common.Address, amount *big.Int) (ch *Cheque, err error) {
defer self.lock.Unlock()
self.lock.Lock()
func (cb *Chequebook) Issue(beneficiary common.Address, amount *big.Int) (*Cheque, error) {
defer cb.lock.Unlock()
cb.lock.Lock()
if amount.Sign() <= 0 {
return nil, fmt.Errorf("amount must be greater than zero (%v)", amount)
}
if self.balance.Cmp(amount) < 0 {
err = fmt.Errorf("insufficient funds to issue cheque for amount: %v. balance: %v", amount, self.balance)
var (
ch *Cheque
err error
)
if cb.balance.Cmp(amount) < 0 {
err = fmt.Errorf("insufficient funds to issue cheque for amount: %v. balance: %v", amount, cb.balance)
} else {
var sig []byte
sent, found := self.sent[beneficiary]
sent, found := cb.sent[beneficiary]
if !found {
sent = new(big.Int)
self.sent[beneficiary] = sent
cb.sent[beneficiary] = sent
}
sum := new(big.Int).Set(sent)
sum.Add(sum, amount)
sig, err = crypto.Sign(sigHash(self.contractAddr, beneficiary, sum), self.prvKey)
sig, err = crypto.Sign(sigHash(cb.contractAddr, beneficiary, sum), cb.prvKey)
if err == nil {
ch = &Cheque{
Contract: self.contractAddr,
Contract: cb.contractAddr,
Beneficiary: beneficiary,
Amount: sum,
Sig: sig,
}
sent.Set(sum)
self.balance.Sub(self.balance, amount) // subtract amount from balance
cb.balance.Sub(cb.balance, amount) // subtract amount from balance
}
}
// auto deposit if threshold is set and balance is less then threshold
// note this is called even if issuing cheque fails
// so we reattempt depositing
if self.threshold != nil {
if self.balance.Cmp(self.threshold) < 0 {
send := new(big.Int).Sub(self.buffer, self.balance)
self.deposit(send)
if cb.threshold != nil {
if cb.balance.Cmp(cb.threshold) < 0 {
send := new(big.Int).Sub(cb.buffer, cb.balance)
cb.deposit(send)
}
}
return
return ch, err
}
// Cash is a convenience method to cash any cheque.
func (self *Chequebook) Cash(ch *Cheque) (txhash string, err error) {
return ch.Cash(self.session)
func (cb *Chequebook) Cash(ch *Cheque) (string, error) {
return ch.Cash(cb.session)
}
// data to sign: contract address, beneficiary, cumulative amount of funds ever sent
@ -309,73 +308,73 @@ func sigHash(contract, beneficiary common.Address, sum *big.Int) []byte {
}
// Balance returns the current balance of the chequebook.
func (self *Chequebook) Balance() *big.Int {
defer self.lock.Unlock()
self.lock.Lock()
return new(big.Int).Set(self.balance)
func (cb *Chequebook) Balance() *big.Int {
defer cb.lock.Unlock()
cb.lock.Lock()
return new(big.Int).Set(cb.balance)
}
// Owner returns the owner account of the chequebook.
func (self *Chequebook) Owner() common.Address {
return self.owner
func (cb *Chequebook) Owner() common.Address {
return cb.owner
}
// Address returns the on-chain contract address of the chequebook.
func (self *Chequebook) Address() common.Address {
return self.contractAddr
func (cb *Chequebook) Address() common.Address {
return cb.contractAddr
}
// Deposit deposits money to the chequebook account.
func (self *Chequebook) Deposit(amount *big.Int) (string, error) {
defer self.lock.Unlock()
self.lock.Lock()
return self.deposit(amount)
func (cb *Chequebook) Deposit(amount *big.Int) (string, error) {
defer cb.lock.Unlock()
cb.lock.Lock()
return cb.deposit(amount)
}
// deposit deposits amount to the chequebook account.
// The caller must hold self.lock.
func (self *Chequebook) deposit(amount *big.Int) (string, error) {
// The caller must hold lock.
func (cb *Chequebook) deposit(amount *big.Int) (string, error) {
// since the amount is variable here, we do not use sessions
depositTransactor := bind.NewKeyedTransactor(self.prvKey)
depositTransactor := bind.NewKeyedTransactor(cb.prvKey)
depositTransactor.Value = amount
chbookRaw := &contract.ChequebookRaw{Contract: self.contract}
chbookRaw := &contract.ChequebookRaw{Contract: cb.contract}
tx, err := chbookRaw.Transfer(depositTransactor)
if err != nil {
self.log.Warn("Failed to fund chequebook", "amount", amount, "balance", self.balance, "target", self.buffer, "err", err)
cb.log.Warn("Failed to fund chequebook", "amount", amount, "balance", cb.balance, "target", cb.buffer, "err", err)
return "", err
}
// assume that transaction is actually successful, we add the amount to balance right away
self.balance.Add(self.balance, amount)
self.log.Trace("Deposited funds to chequebook", "amount", amount, "balance", self.balance, "target", self.buffer)
cb.balance.Add(cb.balance, amount)
cb.log.Trace("Deposited funds to chequebook", "amount", amount, "balance", cb.balance, "target", cb.buffer)
return tx.Hash().Hex(), nil
}
// AutoDeposit (re)sets interval time and amount which triggers sending funds to the
// chequebook. Contract backend needs to be set if threshold is not less than buffer, then
// deposit will be triggered on every new cheque issued.
func (self *Chequebook) AutoDeposit(interval time.Duration, threshold, buffer *big.Int) {
defer self.lock.Unlock()
self.lock.Lock()
self.threshold = threshold
self.buffer = buffer
self.autoDeposit(interval)
func (cb *Chequebook) AutoDeposit(interval time.Duration, threshold, buffer *big.Int) {
defer cb.lock.Unlock()
cb.lock.Lock()
cb.threshold = threshold
cb.buffer = buffer
cb.autoDeposit(interval)
}
// autoDeposit starts a goroutine that periodically sends funds to the chequebook
// contract caller holds the lock the go routine terminates if Chequebook.quit is closed.
func (self *Chequebook) autoDeposit(interval time.Duration) {
if self.quit != nil {
close(self.quit)
self.quit = nil
func (cb *Chequebook) autoDeposit(interval time.Duration) {
if cb.quit != nil {
close(cb.quit)
cb.quit = nil
}
// if threshold >= balance autodeposit after every cheque issued
if interval == time.Duration(0) || self.threshold != nil && self.buffer != nil && self.threshold.Cmp(self.buffer) >= 0 {
if interval == time.Duration(0) || cb.threshold != nil && cb.buffer != nil && cb.threshold.Cmp(cb.buffer) >= 0 {
return
}
ticker := time.NewTicker(interval)
self.quit = make(chan bool)
quit := self.quit
cb.quit = make(chan bool)
quit := cb.quit
go func() {
for {
@ -383,15 +382,15 @@ func (self *Chequebook) autoDeposit(interval time.Duration) {
case <-quit:
return
case <-ticker.C:
self.lock.Lock()
if self.balance.Cmp(self.buffer) < 0 {
amount := new(big.Int).Sub(self.buffer, self.balance)
txhash, err := self.deposit(amount)
cb.lock.Lock()
if cb.balance.Cmp(cb.buffer) < 0 {
amount := new(big.Int).Sub(cb.buffer, cb.balance)
txhash, err := cb.deposit(amount)
if err == nil {
self.txhash = txhash
cb.txhash = txhash
}
}
self.lock.Unlock()
cb.lock.Unlock()
}
}
}()
@ -404,26 +403,26 @@ type Outbox struct {
}
// NewOutbox creates an outbox.
func NewOutbox(chbook *Chequebook, beneficiary common.Address) *Outbox {
return &Outbox{chbook, beneficiary}
func NewOutbox(cb *Chequebook, beneficiary common.Address) *Outbox {
return &Outbox{cb, beneficiary}
}
// Issue creates cheque.
func (self *Outbox) Issue(amount *big.Int) (swap.Promise, error) {
return self.chequeBook.Issue(self.beneficiary, amount)
func (o *Outbox) Issue(amount *big.Int) (swap.Promise, error) {
return o.chequeBook.Issue(o.beneficiary, amount)
}
// AutoDeposit enables auto-deposits on the underlying chequebook.
func (self *Outbox) AutoDeposit(interval time.Duration, threshold, buffer *big.Int) {
self.chequeBook.AutoDeposit(interval, threshold, buffer)
func (o *Outbox) AutoDeposit(interval time.Duration, threshold, buffer *big.Int) {
o.chequeBook.AutoDeposit(interval, threshold, buffer)
}
// Stop helps satisfy the swap.OutPayment interface.
func (self *Outbox) Stop() {}
func (o *Outbox) Stop() {}
// String implements fmt.Stringer.
func (self *Outbox) String() string {
return fmt.Sprintf("chequebook: %v, beneficiary: %s, balance: %v", self.chequeBook.Address().Hex(), self.beneficiary.Hex(), self.chequeBook.Balance())
func (o *Outbox) String() string {
return fmt.Sprintf("chequebook: %v, beneficiary: %s, balance: %v", o.chequeBook.Address().Hex(), o.beneficiary.Hex(), o.chequeBook.Balance())
}
// Inbox can deposit, verify and cash cheques from a single contract to a single
@ -445,7 +444,7 @@ type Inbox struct {
// NewInbox creates an Inbox. An Inboxes is not persisted, the cumulative sum is updated
// from blockchain when first cheque is received.
func NewInbox(prvKey *ecdsa.PrivateKey, contractAddr, beneficiary common.Address, signer *ecdsa.PublicKey, abigen bind.ContractBackend) (self *Inbox, err error) {
func NewInbox(prvKey *ecdsa.PrivateKey, contractAddr, beneficiary common.Address, signer *ecdsa.PublicKey, abigen bind.ContractBackend) (*Inbox, error) {
if signer == nil {
return nil, fmt.Errorf("signer is null")
}
@ -461,7 +460,7 @@ func NewInbox(prvKey *ecdsa.PrivateKey, contractAddr, beneficiary common.Address
}
sender := transactOpts.From
self = &Inbox{
inbox := &Inbox{
contract: contractAddr,
beneficiary: beneficiary,
sender: sender,
@ -470,59 +469,61 @@ func NewInbox(prvKey *ecdsa.PrivateKey, contractAddr, beneficiary common.Address
cashed: new(big.Int).Set(common.Big0),
log: log.New("contract", contractAddr),
}
self.log.Trace("New chequebook inbox initialized", "beneficiary", self.beneficiary, "signer", hexutil.Bytes(crypto.FromECDSAPub(signer)))
return
inbox.log.Trace("New chequebook inbox initialized", "beneficiary", inbox.beneficiary, "signer", hexutil.Bytes(crypto.FromECDSAPub(signer)))
return inbox, nil
}
func (self *Inbox) String() string {
return fmt.Sprintf("chequebook: %v, beneficiary: %s, balance: %v", self.contract.Hex(), self.beneficiary.Hex(), self.cheque.Amount)
func (i *Inbox) String() string {
return fmt.Sprintf("chequebook: %v, beneficiary: %s, balance: %v", i.contract.Hex(), i.beneficiary.Hex(), i.cheque.Amount)
}
// Stop quits the autocash goroutine.
func (self *Inbox) Stop() {
defer self.lock.Unlock()
self.lock.Lock()
if self.quit != nil {
close(self.quit)
self.quit = nil
func (i *Inbox) Stop() {
defer i.lock.Unlock()
i.lock.Lock()
if i.quit != nil {
close(i.quit)
i.quit = nil
}
}
// Cash attempts to cash the current cheque.
func (self *Inbox) Cash() (txhash string, err error) {
if self.cheque != nil {
txhash, err = self.cheque.Cash(self.session)
self.log.Trace("Cashing in chequebook cheque", "amount", self.cheque.Amount, "beneficiary", self.beneficiary)
self.cashed = self.cheque.Amount
func (i *Inbox) Cash() (string, error) {
if i.cheque == nil {
return "", nil
}
return
txhash, err := i.cheque.Cash(i.session)
i.log.Trace("Cashing in chequebook cheque", "amount", i.cheque.Amount, "beneficiary", i.beneficiary)
i.cashed = i.cheque.Amount
return txhash, err
}
// AutoCash (re)sets maximum time and amount which triggers cashing of the last uncashed
// cheque if maxUncashed is set to 0, then autocash on receipt.
func (self *Inbox) AutoCash(cashInterval time.Duration, maxUncashed *big.Int) {
defer self.lock.Unlock()
self.lock.Lock()
self.maxUncashed = maxUncashed
self.autoCash(cashInterval)
func (i *Inbox) AutoCash(cashInterval time.Duration, maxUncashed *big.Int) {
defer i.lock.Unlock()
i.lock.Lock()
i.maxUncashed = maxUncashed
i.autoCash(cashInterval)
}
// autoCash starts a loop that periodically clears the last cheque
// if the peer is trusted. Clearing period could be 24h or a week.
// The caller must hold self.lock.
func (self *Inbox) autoCash(cashInterval time.Duration) {
if self.quit != nil {
close(self.quit)
self.quit = nil
// The caller must hold lock.
func (i *Inbox) autoCash(cashInterval time.Duration) {
if i.quit != nil {
close(i.quit)
i.quit = nil
}
// if maxUncashed is set to 0, then autocash on receipt
if cashInterval == time.Duration(0) || self.maxUncashed != nil && self.maxUncashed.Sign() == 0 {
if cashInterval == time.Duration(0) || i.maxUncashed != nil && i.maxUncashed.Sign() == 0 {
return
}
ticker := time.NewTicker(cashInterval)
self.quit = make(chan bool)
quit := self.quit
i.quit = make(chan bool)
quit := i.quit
go func() {
for {
@ -530,14 +531,14 @@ func (self *Inbox) autoCash(cashInterval time.Duration) {
case <-quit:
return
case <-ticker.C:
self.lock.Lock()
if self.cheque != nil && self.cheque.Amount.Cmp(self.cashed) != 0 {
txhash, err := self.Cash()
i.lock.Lock()
if i.cheque != nil && i.cheque.Amount.Cmp(i.cashed) != 0 {
txhash, err := i.Cash()
if err == nil {
self.txhash = txhash
i.txhash = txhash
}
}
self.lock.Unlock()
i.lock.Unlock()
}
}
}()
@ -545,56 +546,56 @@ func (self *Inbox) autoCash(cashInterval time.Duration) {
// Receive is called to deposit the latest cheque to the incoming Inbox.
// The given promise must be a *Cheque.
func (self *Inbox) Receive(promise swap.Promise) (*big.Int, error) {
func (i *Inbox) Receive(promise swap.Promise) (*big.Int, error) {
ch := promise.(*Cheque)
defer self.lock.Unlock()
self.lock.Lock()
defer i.lock.Unlock()
i.lock.Lock()
var sum *big.Int
if self.cheque == nil {
if i.cheque == nil {
// the sum is checked against the blockchain once a cheque is received
tally, err := self.session.Sent(self.beneficiary)
tally, err := i.session.Sent(i.beneficiary)
if err != nil {
return nil, fmt.Errorf("inbox: error calling backend to set amount: %v", err)
}
sum = tally
} else {
sum = self.cheque.Amount
sum = i.cheque.Amount
}
amount, err := ch.Verify(self.signer, self.contract, self.beneficiary, sum)
amount, err := ch.Verify(i.signer, i.contract, i.beneficiary, sum)
var uncashed *big.Int
if err == nil {
self.cheque = ch
i.cheque = ch
if self.maxUncashed != nil {
uncashed = new(big.Int).Sub(ch.Amount, self.cashed)
if self.maxUncashed.Cmp(uncashed) < 0 {
self.Cash()
if i.maxUncashed != nil {
uncashed = new(big.Int).Sub(ch.Amount, i.cashed)
if i.maxUncashed.Cmp(uncashed) < 0 {
i.Cash()
}
}
self.log.Trace("Received cheque in chequebook inbox", "amount", amount, "uncashed", uncashed)
i.log.Trace("Received cheque in chequebook inbox", "amount", amount, "uncashed", uncashed)
}
return amount, err
}
// Verify verifies cheque for signer, contract, beneficiary, amount, valid signature.
func (self *Cheque) Verify(signerKey *ecdsa.PublicKey, contract, beneficiary common.Address, sum *big.Int) (*big.Int, error) {
log.Trace("Verifying chequebook cheque", "cheque", self, "sum", sum)
func (ch *Cheque) Verify(signerKey *ecdsa.PublicKey, contract, beneficiary common.Address, sum *big.Int) (*big.Int, error) {
log.Trace("Verifying chequebook cheque", "cheque", ch, "sum", sum)
if sum == nil {
return nil, fmt.Errorf("invalid amount")
}
if self.Beneficiary != beneficiary {
return nil, fmt.Errorf("beneficiary mismatch: %v != %v", self.Beneficiary.Hex(), beneficiary.Hex())
if ch.Beneficiary != beneficiary {
return nil, fmt.Errorf("beneficiary mismatch: %v != %v", ch.Beneficiary.Hex(), beneficiary.Hex())
}
if self.Contract != contract {
return nil, fmt.Errorf("contract mismatch: %v != %v", self.Contract.Hex(), contract.Hex())
if ch.Contract != contract {
return nil, fmt.Errorf("contract mismatch: %v != %v", ch.Contract.Hex(), contract.Hex())
}
amount := new(big.Int).Set(self.Amount)
amount := new(big.Int).Set(ch.Amount)
if sum != nil {
amount.Sub(amount, sum)
if amount.Sign() <= 0 {
@ -602,7 +603,7 @@ func (self *Cheque) Verify(signerKey *ecdsa.PublicKey, contract, beneficiary com
}
}
pubKey, err := crypto.SigToPub(sigHash(self.Contract, beneficiary, self.Amount), self.Sig)
pubKey, err := crypto.SigToPub(sigHash(ch.Contract, beneficiary, ch.Amount), ch.Sig)
if err != nil {
return nil, fmt.Errorf("invalid signature: %v", err)
}
@ -621,9 +622,9 @@ func sig2vrs(sig []byte) (v byte, r, s [32]byte) {
}
// Cash cashes the cheque by sending an Ethereum transaction.
func (self *Cheque) Cash(session *contract.ChequebookSession) (string, error) {
v, r, s := sig2vrs(self.Sig)
tx, err := session.Cash(self.Beneficiary, self.Amount, v, r, s)
func (ch *Cheque) Cash(session *contract.ChequebookSession) (string, error) {
v, r, s := sig2vrs(ch.Sig)
tx, err := session.Cash(ch.Beneficiary, ch.Amount, v, r, s)
if err != nil {
return "", err
}
@ -632,7 +633,7 @@ func (self *Cheque) Cash(session *contract.ChequebookSession) (string, error) {
// ValidateCode checks that the on-chain code at address matches the expected chequebook
// contract code. This is used to detect suicided chequebooks.
func ValidateCode(ctx context.Context, b Backend, address common.Address) (ok bool, err error) {
func ValidateCode(ctx context.Context, b Backend, address common.Address) (bool, error) {
code, err := b.CodeAt(ctx, address, nil)
if err != nil {
return false, err

@ -205,22 +205,22 @@ func (_Chequebook *ChequebookCallerSession) Sent(arg0 common.Address) (*big.Int,
// Cash is a paid mutator transaction binding the contract method 0xfbf788d6.
//
// Solidity: function cash(beneficiary address, amount uint256, sig_v uint8, sig_r bytes32, sig_s bytes32) returns()
func (_Chequebook *ChequebookTransactor) Cash(opts *bind.TransactOpts, beneficiary common.Address, amount *big.Int, sig_v uint8, sig_r [32]byte, sig_s [32]byte) (*types.Transaction, error) {
return _Chequebook.contract.Transact(opts, "cash", beneficiary, amount, sig_v, sig_r, sig_s)
func (_Chequebook *ChequebookTransactor) Cash(opts *bind.TransactOpts, beneficiary common.Address, amount *big.Int, sigV uint8, sigR [32]byte, sigS [32]byte) (*types.Transaction, error) {
return _Chequebook.contract.Transact(opts, "cash", beneficiary, amount, sigV, sigR, sigS)
}
// Cash is a paid mutator transaction binding the contract method 0xfbf788d6.
//
// Solidity: function cash(beneficiary address, amount uint256, sig_v uint8, sig_r bytes32, sig_s bytes32) returns()
func (_Chequebook *ChequebookSession) Cash(beneficiary common.Address, amount *big.Int, sig_v uint8, sig_r [32]byte, sig_s [32]byte) (*types.Transaction, error) {
return _Chequebook.Contract.Cash(&_Chequebook.TransactOpts, beneficiary, amount, sig_v, sig_r, sig_s)
func (_Chequebook *ChequebookSession) Cash(beneficiary common.Address, amount *big.Int, sigV uint8, sigR [32]byte, sigS [32]byte) (*types.Transaction, error) {
return _Chequebook.Contract.Cash(&_Chequebook.TransactOpts, beneficiary, amount, sigV, sigR, sigS)
}
// Cash is a paid mutator transaction binding the contract method 0xfbf788d6.
//
// Solidity: function cash(beneficiary address, amount uint256, sig_v uint8, sig_r bytes32, sig_s bytes32) returns()
func (_Chequebook *ChequebookTransactorSession) Cash(beneficiary common.Address, amount *big.Int, sig_v uint8, sig_r [32]byte, sig_s [32]byte) (*types.Transaction, error) {
return _Chequebook.Contract.Cash(&_Chequebook.TransactOpts, beneficiary, amount, sig_v, sig_r, sig_s)
func (_Chequebook *ChequebookTransactorSession) Cash(beneficiary common.Address, amount *big.Int, sigV uint8, sigR [32]byte, sigS [32]byte) (*types.Transaction, error) {
return _Chequebook.Contract.Cash(&_Chequebook.TransactOpts, beneficiary, amount, sigV, sigR, sigS)
}
// Kill is a paid mutator transaction binding the contract method 0x41c0e1b5.

@ -227,10 +227,10 @@ func (_ENS *ENSCallerSession) Resolver(node [32]byte) (common.Address, error) {
return _ENS.Contract.Resolver(&_ENS.CallOpts, node)
}
// Ttl is a free data retrieval call binding the contract method 0x16a25cbd.
// TTL is a free data retrieval call binding the contract method 0x16a25cbd.
//
// Solidity: function ttl(node bytes32) constant returns(uint64)
func (_ENS *ENSCaller) Ttl(opts *bind.CallOpts, node [32]byte) (uint64, error) {
func (_ENS *ENSCaller) TTL(opts *bind.CallOpts, node [32]byte) (uint64, error) {
var (
ret0 = new(uint64)
)
@ -239,18 +239,18 @@ func (_ENS *ENSCaller) Ttl(opts *bind.CallOpts, node [32]byte) (uint64, error) {
return *ret0, err
}
// Ttl is a free data retrieval call binding the contract method 0x16a25cbd.
// TTL is a free data retrieval call binding the contract method 0x16a25cbd.
//
// Solidity: function ttl(node bytes32) constant returns(uint64)
func (_ENS *ENSSession) Ttl(node [32]byte) (uint64, error) {
return _ENS.Contract.Ttl(&_ENS.CallOpts, node)
func (_ENS *ENSSession) TTL(node [32]byte) (uint64, error) {
return _ENS.Contract.TTL(&_ENS.CallOpts, node)
}
// Ttl is a free data retrieval call binding the contract method 0x16a25cbd.
// TTL is a free data retrieval call binding the contract method 0x16a25cbd.
//
// Solidity: function ttl(node bytes32) constant returns(uint64)
func (_ENS *ENSCallerSession) Ttl(node [32]byte) (uint64, error) {
return _ENS.Contract.Ttl(&_ENS.CallOpts, node)
func (_ENS *ENSCallerSession) TTL(node [32]byte) (uint64, error) {
return _ENS.Contract.TTL(&_ENS.CallOpts, node)
}
// SetOwner is a paid mutator transaction binding the contract method 0x5b0fc9c3.
@ -682,7 +682,7 @@ func (it *ENSNewTTLIterator) Close() error {
// ENSNewTTL represents a NewTTL event raised by the ENS contract.
type ENSNewTTL struct {
Node [32]byte
Ttl uint64
TTL uint64
Raw types.Log // Blockchain specific contextual infos
}

@ -35,7 +35,7 @@ var (
TestNetAddress = common.HexToAddress("0x112234455c3a32fd11230c42e7bccd4a84e02010")
)
// swarm domain name registry and resolver
// ENS is the swarm domain name registry and resolver
type ENS struct {
*contract.ENSSession
contractBackend bind.ContractBackend
@ -48,7 +48,6 @@ func NewENS(transactOpts *bind.TransactOpts, contractAddr common.Address, contra
if err != nil {
return nil, err
}
return &ENS{
&contract.ENSSession{
Contract: ens,
@ -60,27 +59,24 @@ func NewENS(transactOpts *bind.TransactOpts, contractAddr common.Address, contra
// DeployENS deploys an instance of the ENS nameservice, with a 'first-in, first-served' root registrar.
func DeployENS(transactOpts *bind.TransactOpts, contractBackend bind.ContractBackend) (common.Address, *ENS, error) {
// Deploy the ENS registry.
// Deploy the ENS registry
ensAddr, _, _, err := contract.DeployENS(transactOpts, contractBackend)
if err != nil {
return ensAddr, nil, err
}
ens, err := NewENS(transactOpts, ensAddr, contractBackend)
if err != nil {
return ensAddr, nil, err
}
// Deploy the registrar.
// Deploy the registrar
regAddr, _, _, err := contract.DeployFIFSRegistrar(transactOpts, contractBackend, ensAddr, [32]byte{})
if err != nil {
return ensAddr, nil, err
}
// Set the registrar as owner of the ENS root.
// Set the registrar as owner of the ENS root
if _, err = ens.SetOwner([32]byte{}, regAddr); err != nil {
return ensAddr, nil, err
}
return ensAddr, ens, nil
}
@ -89,10 +85,9 @@ func ensParentNode(name string) (common.Hash, common.Hash) {
label := crypto.Keccak256Hash([]byte(parts[0]))
if len(parts) == 1 {
return [32]byte{}, label
} else {
parentNode, parentLabel := ensParentNode(parts[1])
return crypto.Keccak256Hash(parentNode[:], parentLabel[:]), label
}
parentNode, parentLabel := ensParentNode(parts[1])
return crypto.Keccak256Hash(parentNode[:], parentLabel[:]), label
}
func EnsNode(name string) common.Hash {
@ -100,111 +95,101 @@ func EnsNode(name string) common.Hash {
return crypto.Keccak256Hash(parentNode[:], parentLabel[:])
}
func (self *ENS) getResolver(node [32]byte) (*contract.PublicResolverSession, error) {
resolverAddr, err := self.Resolver(node)
func (ens *ENS) getResolver(node [32]byte) (*contract.PublicResolverSession, error) {
resolverAddr, err := ens.Resolver(node)
if err != nil {
return nil, err
}
resolver, err := contract.NewPublicResolver(resolverAddr, self.contractBackend)
resolver, err := contract.NewPublicResolver(resolverAddr, ens.contractBackend)
if err != nil {
return nil, err
}
return &contract.PublicResolverSession{
Contract: resolver,
TransactOpts: self.TransactOpts,
TransactOpts: ens.TransactOpts,
}, nil
}
func (self *ENS) getRegistrar(node [32]byte) (*contract.FIFSRegistrarSession, error) {
registrarAddr, err := self.Owner(node)
func (ens *ENS) getRegistrar(node [32]byte) (*contract.FIFSRegistrarSession, error) {
registrarAddr, err := ens.Owner(node)
if err != nil {
return nil, err
}
registrar, err := contract.NewFIFSRegistrar(registrarAddr, self.contractBackend)
registrar, err := contract.NewFIFSRegistrar(registrarAddr, ens.contractBackend)
if err != nil {
return nil, err
}
return &contract.FIFSRegistrarSession{
Contract: registrar,
TransactOpts: self.TransactOpts,
TransactOpts: ens.TransactOpts,
}, nil
}
// Resolve is a non-transactional call that returns the content hash associated with a name.
func (self *ENS) Resolve(name string) (common.Hash, error) {
func (ens *ENS) Resolve(name string) (common.Hash, error) {
node := EnsNode(name)
resolver, err := self.getResolver(node)
resolver, err := ens.getResolver(node)
if err != nil {
return common.Hash{}, err
}
ret, err := resolver.Content(node)
if err != nil {
return common.Hash{}, err
}
return common.BytesToHash(ret[:]), nil
}
// Addr is a non-transactional call that returns the address associated with a name.
func (self *ENS) Addr(name string) (common.Address, error) {
func (ens *ENS) Addr(name string) (common.Address, error) {
node := EnsNode(name)
resolver, err := self.getResolver(node)
resolver, err := ens.getResolver(node)
if err != nil {
return common.Address{}, err
}
ret, err := resolver.Addr(node)
if err != nil {
return common.Address{}, err
}
return common.BytesToAddress(ret[:]), nil
}
// SetAddress sets the address associated with a name. Only works if the caller
// owns the name, and the associated resolver implements a `setAddress` function.
func (self *ENS) SetAddr(name string, addr common.Address) (*types.Transaction, error) {
func (ens *ENS) SetAddr(name string, addr common.Address) (*types.Transaction, error) {
node := EnsNode(name)
resolver, err := self.getResolver(node)
resolver, err := ens.getResolver(node)
if err != nil {
return nil, err
}
opts := self.TransactOpts
opts := ens.TransactOpts
opts.GasLimit = 200000
return resolver.Contract.SetAddr(&opts, node, addr)
}
// Register registers a new domain name for the caller, making them the owner of the new name.
// Only works if the registrar for the parent domain implements the FIFS registrar protocol.
func (self *ENS) Register(name string) (*types.Transaction, error) {
func (ens *ENS) Register(name string) (*types.Transaction, error) {
parentNode, label := ensParentNode(name)
registrar, err := self.getRegistrar(parentNode)
registrar, err := ens.getRegistrar(parentNode)
if err != nil {
return nil, err
}
return registrar.Contract.Register(&self.TransactOpts, label, self.TransactOpts.From)
return registrar.Contract.Register(&ens.TransactOpts, label, ens.TransactOpts.From)
}
// SetContentHash sets the content hash associated with a name. Only works if the caller
// owns the name, and the associated resolver implements a `setContent` function.
func (self *ENS) SetContentHash(name string, hash common.Hash) (*types.Transaction, error) {
func (ens *ENS) SetContentHash(name string, hash common.Hash) (*types.Transaction, error) {
node := EnsNode(name)
resolver, err := self.getResolver(node)
resolver, err := ens.getResolver(node)
if err != nil {
return nil, err
}
opts := self.TransactOpts
opts := ens.TransactOpts
opts.GasLimit = 200000
return resolver.Contract.SetContent(&opts, node, hash)
}

@ -491,7 +491,7 @@ func (self *Swarm) APIs() []rpc.API {
{
Namespace: "chequebook",
Version: chequebook.Version,
Service: chequebook.NewApi(self.config.Swap.Chequebook),
Service: chequebook.NewAPI(self.config.Swap.Chequebook),
Public: false,
},
{