func TestSetAnnounced(t *testing.T) {
ut := NewUnconfirmedTxnPool()
assert.Equal(t, len(ut.Txns), 0)
// Unknown should be safe and a noop
assert.NotPanics(t, func() {
ut.SetAnnounced(cipher.SHA256{}, util.Now())
})
assert.Equal(t, len(ut.Txns), 0)
utx := createUnconfirmedTxn()
assert.True(t, utx.Announced.IsZero())
ut.Txns[utx.Hash()] = utx
now := util.Now()
ut.SetAnnounced(utx.Hash(), now)
assert.Equal(t, ut.Txns[utx.Hash()].Announced, now)
}
// Adds a coin.Transaction to the pool, or updates an existing one's timestamps
// Returns an error if txn is invalid, and whether the transaction already
// existed in the pool.
func (self *UnconfirmedTxnPool) RecordTxn(bc *coin.Blockchain,
t coin.Transaction, addrs map[cipher.Address]byte, maxSize int,
burnFactor uint64) (error, bool) {
if err := VerifyTransaction(bc, &t, maxSize, burnFactor); err != nil {
return err, false
}
if err := bc.VerifyTransaction(t); err != nil {
return err, false
}
// Update if we already have this txn
h := t.Hash()
ut, ok := self.Txns[h]
if ok {
now := util.Now()
ut.Received = now
ut.Checked = now
self.Txns[h] = ut
return nil, true
}
// Add txn to index
self.Txns[h] = self.createUnconfirmedTxn(&bc.Unspent, t, addrs)
// Add predicted unspents
self.Unspent[h] = coin.CreateUnspents(bc.Head().Head, t)
return nil, false
}
// InjectTxn adds a coin.Transaction to the pool, or updates an existing one's timestamps
// Returns an error if txn is invalid, and whether the transaction already
// existed in the pool.
func (utp *UnconfirmedTxnPool) InjectTxn(bc *Blockchain,
t coin.Transaction) (error, bool) {
if err := t.Verify(); err != nil {
return err, false
}
if err := VerifyTransactionFee(bc, &t); err != nil {
return err, false
}
if err := bc.VerifyTransaction(t); err != nil {
return err, false
}
// Update if we already have this txn
h := t.Hash()
ut, ok := utp.Txns[h]
if ok {
now := util.Now()
ut.Received = now
ut.Checked = now
utp.Txns[h] = ut
return nil, true
}
// Add txn to index
unspent := bc.GetUnspent()
utp.Txns[h] = utp.createUnconfirmedTxn(unspent, t)
// Add predicted unspents
utp.Unspent[h] = coin.CreateUnspents(bc.Head().Head, t)
return nil, false
}
// Adds a coin.Transaction to the pool, or updates an existing one's timestamps
// Returns an error if txn is invalid, and whether the transaction already
// existed in the pool.
func (self *UnconfirmedTxnPool) RecordTxn(bc *coin.Blockchain,
t coin.Transaction, addrs map[coin.Address]byte, maxSize int,
burnFactor uint64) (error, bool) {
if err := VerifyTransaction(bc, &t, maxSize, burnFactor); err != nil {
return err, false
}
if err := bc.VerifyTransaction(t); err != nil {
return err, false
}
// Update if we already have this txn
ut, ok := self.Txns[t.Hash()]
if ok {
now := util.Now()
ut.Received = now
ut.Checked = now
self.Txns[ut.Txn.Hash()] = ut
return nil, true
}
// Add txn to index
self.Txns[t.Hash()] = self.createUnconfirmedTxn(&bc.Unspent, t, addrs)
// Add predicted unspents
uxs := coin.CreateExpectedUnspents(t)
for i, _ := range uxs {
self.Unspent.Add(uxs[i])
}
return nil, false
}
// Creates an unconfirmed transaction
func (self *UnconfirmedTxnPool) createUnconfirmedTxn(bcUnsp *coin.UnspentPool,
t coin.Transaction, addrs map[coin.Address]byte) UnconfirmedTxn {
now := util.Now()
ut := UnconfirmedTxn{
Txn: t,
Received: now,
Checked: now,
Announced: util.ZeroTime(),
IsOurReceive: false,
IsOurSpend: false,
}
// Check if this unspent is related to us
if addrs != nil {
// Check if this is one of our receiving txns
for i, _ := range t.Out {
if _, ok := addrs[t.Out[i].Address]; ok {
ut.IsOurReceive = true
break
}
}
// Check if this is one of our spending txns
for i, _ := range t.In {
if ux, ok := bcUnsp.Get(t.In[i]); ok {
if _, ok := addrs[ux.Body.Address]; ok {
ut.IsOurSpend = true
break
}
}
}
}
return ut
}
func main() {
flag.Parse()
if len(*host) == 0 {
log.Fatalf("Missing required -host parameter")
}
var err error
var notBefore time.Time
if len(*validFrom) == 0 {
notBefore = util.Now()
} else {
notBefore, err = time.Parse("Jan 2 15:04:05 2006", *validFrom)
if err != nil {
fmt.Fprintf(os.Stderr, "Failed to parse creation date: %v\n", err)
os.Exit(1)
}
}
err = util.GenerateCert(*certFile, *keyFile, *host, *organization, *rsaBits,
*isCA, notBefore, *validFor)
if err == nil {
fmt.Printf("Created %s and %s\n", *certFile, *keyFile)
} else {
fmt.Fprintln(os.Stderr, "Failed to create cert and key")
fmt.Fprintln(os.Stderr, err)
os.Exit(1)
}
}
// Send a ping if our last message sent was over pingRate ago
func (self *Pool) sendPings() {
now := util.Now()
for _, c := range self.Pool.Pool {
if c.LastSent.Add(self.Config.PingRate).Before(now) {
self.Pool.SendMessage(c, &PingMessage{})
}
}
}
// Removes connections that have not sent a message in too long
func (self *Pool) clearStaleConnections() {
now := util.Now()
for _, c := range self.Pool.Pool {
if c.LastReceived.Add(self.Config.IdleLimit).Before(now) {
self.Pool.Disconnect(c, DisconnectIdle)
}
}
}
func createUnconfirmedTxn() UnconfirmedTxn {
ut := UnconfirmedTxn{}
ut.Txn = coin.Transaction{}
ut.Txn.Head.Hash = randSHA256()
ut.Received = util.Now()
ut.Checked = ut.Received
ut.Announced = util.ZeroTime()
return ut
}
func TestGenerateCert(t *testing.T) {
defer os.Remove("certtest.pem")
defer os.Remove("keytest.pem")
err := GenerateCert("certtest.pem", "keytest.pem", "127.0.0.1", "org",
2048, false, util.Now(), time.Hour*24)
assert.Nil(t, err)
_, err = tls.LoadX509KeyPair("certtest.pem", "keytest.pem")
assert.Nil(t, err)
}
// Creates an unconfirmed transaction
func (utp *UnconfirmedTxnPool) createUnconfirmedTxn(bcUnsp *coin.UnspentPool,
t coin.Transaction) UnconfirmedTxn {
now := util.Now()
return UnconfirmedTxn{
Txn: t,
Received: now,
Checked: now,
Announced: util.ZeroTime(),
}
}
// Creates an unconfirmed transaction
func (self *UnconfirmedTxnPool) createUnconfirmedTxn(bcUnsp *coin.UnspentPool,
t coin.Transaction, addrs map[coin.Address]byte) UnconfirmedTxn {
now := util.Now()
return UnconfirmedTxn{
Txn: t,
Received: now,
Checked: now,
Announced: util.ZeroTime(),
}
}
// Returns transactions in which we are a party and have not been announced
// in ago duration
func (self *UnconfirmedTxnPool) GetOldOwnedTransactions(ago time.Duration) []UnconfirmedTxn {
txns := make([]UnconfirmedTxn, 0)
now := util.Now()
for _, tx := range self.Txns {
// TODO -- don't record IsOurSpend/IsOurReceive and do lookup each time?
// Slower but more correct
if (tx.IsOurSpend || tx.IsOurReceive) && now.Sub(tx.Announced) > ago {
txns = append(txns, tx)
}
}
return txns
}
func TestVisorSetAnnounced(t *testing.T) {
defer cleanupVisor()
vc := newMasterVisorConfig(t)
v := NewVisor(vc)
now := util.Now()
utx := addUnconfirmedTxn(v)
assert.True(t, utx.Announced.IsZero())
assert.True(t, v.Unconfirmed.Txns[utx.Hash()].Announced.IsZero())
v.SetAnnounced(utx.Hash(), now)
assert.False(t, v.Unconfirmed.Txns[utx.Hash()].Announced.IsZero())
assert.Equal(t, v.Unconfirmed.Txns[utx.Hash()].Announced, now)
}
func createUnconfirmedTxn() visor.UnconfirmedTxn {
now := util.Now()
return visor.UnconfirmedTxn{
Txn: coin.Transaction{
Head: coin.TransactionHeader{
Hash: coin.SumSHA256([]byte("cascas")),
},
},
Received: now,
Checked: now,
Announced: util.ZeroTime(),
}
}
// Checks all unconfirmed txns against the blockchain. maxAge is how long
// we'll hold a txn regardless of whether it has been invalidated.
// checkPeriod is how often we check the txn against the blockchain.
func (self *UnconfirmedTxnPool) Refresh(bc *coin.Blockchain,
checkPeriod, maxAge time.Duration) {
now := util.Now()
toRemove := make([]coin.SHA256, 0)
for k, t := range self.Txns {
if now.Sub(t.Received) >= maxAge {
toRemove = append(toRemove, k)
} else if now.Sub(t.Checked) >= checkPeriod {
if bc.VerifyTransaction(t.Txn) == nil {
t.Checked = now
self.Txns[k] = t
} else {
toRemove = append(toRemove, k)
}
}
}
self.removeTxns(bc, toRemove)
}
// Checks that certFile and keyFile exist and are files, and if not,
// returns a slice of errors indicating status.
// If neither certFile nor keyFile exist, they are automatically created
// for host
func CreateCertIfNotExists(host, certFile, keyFile string) []error {
// check that cert/key both exist, or dont
exist, errs := certKeyXor(certFile, keyFile)
// Automatically create a new cert if neither files exist
if !exist && len(errs) == 0 {
logger.Info("Creating certificate %s", certFile)
logger.Info("Creating key %s", keyFile)
err := util.GenerateCert(certFile, keyFile, host, "Skycoind", 2048,
false, util.Now(), 365*24*time.Hour)
if err == nil {
logger.Info("Created certificate %s for host %s", certFile, host)
logger.Info("Created key %s for host %s", keyFile, host)
} else {
errs = append(errs, err)
}
}
return errs
}
// Refresh checks all unconfirmed txns against the blockchain. maxAge is how long
// we'll hold a txn regardless of whether it has been invalidated.
// checkPeriod is how often we check the txn against the blockchain.
func (utp *UnconfirmedTxnPool) Refresh(bc *Blockchain,
checkPeriod, maxAge time.Duration) {
now := util.Now()
var toRemove []cipher.SHA256
for k, t := range utp.Txns {
if now.Sub(t.Received) >= maxAge {
toRemove = append(toRemove, k)
} else if now.Sub(t.Checked) >= checkPeriod {
if bc.VerifyTransaction(t.Txn) == nil {
t.Checked = now
utp.Txns[k] = t
} else {
toRemove = append(toRemove, k)
}
}
}
utp.removeTxns(bc, toRemove)
}
// Called when a ConnectEvent is processed off the onConnectEvent channel
func (self *Daemon) onConnect(e ConnectEvent) {
a := e.Addr
if e.Solicited {
logger.Info("Connected to %s as we requested", a)
} else {
logger.Info("Received unsolicited connection to %s", a)
}
delete(self.pendingConnections, a)
c := self.Pool.Pool.Addresses[a]
if c == nil {
logger.Warning("While processing an onConnect event, no pool " +
"connection was found")
return
}
blacklisted := self.Peers.Peers.IsBlacklisted(a)
if blacklisted {
logger.Info("%s is blacklisted, disconnecting", a)
self.Pool.Pool.Disconnect(c, DisconnectIsBlacklisted)
return
}
if self.ipCountMaxed(a) {
logger.Info("Max connections for %s reached, disconnecting", a)
self.Pool.Pool.Disconnect(c, DisconnectIPLimitReached)
return
}
self.recordIPCount(a)
if e.Solicited {
self.OutgoingConnections[a] = c
}
self.ExpectingIntroductions[a] = util.Now()
logger.Debug("Sending introduction message to %s", a)
m := NewIntroductionMessage(self.Messages.Mirror, self.Config.Version,
self.Pool.Pool.Config.Port)
self.Pool.Pool.SendMessage(c, m)
}
// Removes unsolicited connections who haven't sent a version
func (self *Daemon) cullInvalidConnections() {
// This method only handles the erroneous people from the DHT, but not
// malicious nodes
now := util.Now()
for a, t := range self.ExpectingIntroductions {
// Forget about anyone that already disconnected
if self.Pool.Pool.Addresses[a] == nil {
delete(self.ExpectingIntroductions, a)
continue
}
// Remove anyone that fails to send a version within introductionWait time
if t.Add(self.Config.IntroductionWait).Before(now) {
logger.Info("Removing %s for not sending a version", a)
delete(self.ExpectingIntroductions, a)
self.Pool.Pool.Disconnect(self.Pool.Pool.Addresses[a],
DisconnectIntroductionTimeout)
self.Peers.RemovePeer(a)
}
}
}
func TestRecordMessageEventNeedsIntroduction(t *testing.T) {
// Needs Introduction but didn't get it first
d := newDefaultDaemon()
m := &PingMessage{}
m.c = messageContext(addr)
d.Pool.Pool.Addresses[addr] = m.c.Conn
d.Pool.Pool.Pool[m.c.Conn.Id] = m.c.Conn
assert.Equal(t, len(d.messageEvents), 0)
d.ExpectingIntroductions[addr] = util.Now()
d.processMessageEvent(MessageEvent{m, m.c})
assert.Equal(t, len(d.Pool.Pool.DisconnectQueue), 1)
if len(d.Pool.Pool.DisconnectQueue) == 0 {
t.Fatal("DisconnectQueue empty, would block")
}
de := <-d.Pool.Pool.DisconnectQueue
assert.Equal(t, de.ConnId, m.c.Conn.Id)
assert.Equal(t, de.Reason, DisconnectNoIntroduction)
delete(d.ExpectingIntroductions, addr)
shutdown(d)
}
func TestRecordMessageEventIsIntroduction(t *testing.T) {
// Needs Introduction and thats what it has received
d := newDefaultDaemon()
d.ExpectingIntroductions[addr] = util.Now()
assert.Equal(t, len(d.messageEvents), 0)
m := NewIntroductionMessage(d.Messages.Mirror, d.Config.Version,
d.Pool.Pool.Config.Port)
m.c = messageContext(addr)
err := d.recordMessageEvent(m, m.c)
assert.Nil(t, err)
assert.Equal(t, len(d.messageEvents), 1)
if len(d.messageEvents) == 0 {
t.Fatal("d.messageEvents empty, would block")
}
me := <-d.messageEvents
_, ok := me.Message.(*IntroductionMessage)
assert.Equal(t, len(d.Pool.Pool.DisconnectQueue), 0)
assert.True(t, ok)
delete(d.ExpectingIntroductions, addr)
shutdown(d)
}
// Called when a ConnectEvent is processed off the onConnectEvent channel
func (self *Daemon) onConnect(c *gnet.Connection, solicited bool) {
a := c.Addr()
if solicited {
logger.Info("Connected to %s as we requested", a)
} else {
logger.Info("Received unsolicited connection to %s", a)
}
serviceConList := self.pendingConnections[a] //list of services to connect to
delete(self.pendingConnections, a)
blacklisted := self.Peers.Peers.IsBlacklisted(a)
if blacklisted {
logger.Info("%s is blacklisted, disconnecting", a)
self.Pool.Disconnect(c, DisconnectIsBlacklisted)
return
}
if self.Pool.Addresses[a] != nil {
logger.Info("Already connected to %s, disconnecting", a)
self.Pool.Disconnect(c, DisconnectConnectedTwice)
}
if solicited {
self.OutgoingConnections[a] = c
}
self.ExpectingIntroductions[a] = util.Now()
logger.Debug("Sending introduction message to %s", a)
m := NewIntroductionMessage(MirrorConstant, self.Config.Version,
self.Pool.Config.Port)
self.Service.Send(c, m)
//send connection message to each service in list
for _, service := range serviceConList {
self.ConnectToService(c, service)
}
}
func TestGetOldOwnedTransactions(t *testing.T) {
mv := setupMasterVisor()
up := mv.Unconfirmed
// Setup txns
notOursNew, err := makeValidTxn(mv)
assert.Nil(t, err)
notOursOld, err := makeValidTxn(mv)
assert.Nil(t, err)
ourSpendNew, err := makeValidTxn(mv)
assert.Nil(t, err)
ourSpendOld, err := makeValidTxn(mv)
assert.Nil(t, err)
ourReceiveNew, err := makeValidTxn(mv)
assert.Nil(t, err)
ourReceiveOld, err := makeValidTxn(mv)
assert.Nil(t, err)
ourBothNew, err := makeValidTxn(mv)
assert.Nil(t, err)
ourBothOld, err := makeValidTxn(mv)
assert.Nil(t, err)
// Add a transaction that is not ours, both new and old
err, known := up.RecordTxn(mv.blockchain, notOursNew, nil, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
up.SetAnnounced(notOursNew.Hash(), util.Now())
err, known = up.RecordTxn(mv.blockchain, notOursOld, nil, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
// Add a transaction that is our spend, both new and old
addrs := make(map[cipher.Address]byte, 1)
ux, ok := mv.blockchain.Unspent.Get(ourSpendNew.In[0])
assert.True(t, ok)
addrs[ux.Body.Address] = byte(1)
err, known = up.RecordTxn(mv.blockchain, ourSpendNew, addrs, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
up.SetAnnounced(ourSpendNew.Hash(), util.Now())
addrs = make(map[cipher.Address]byte, 1)
ux, ok = mv.blockchain.Unspent.Get(ourSpendNew.In[0])
assert.True(t, ok)
addrs[ux.Body.Address] = byte(1)
err, known = up.RecordTxn(mv.blockchain, ourSpendOld, addrs, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
// Add a transaction that is our receive, both new and old
addrs = make(map[cipher.Address]byte, 1)
addrs[ourReceiveNew.Out[1].Address] = byte(1)
err, known = up.RecordTxn(mv.blockchain, ourReceiveNew, addrs,
testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
up.SetAnnounced(ourReceiveNew.Hash(), util.Now())
addrs = make(map[cipher.Address]byte, 1)
addrs[ourReceiveOld.Out[1].Address] = byte(1)
err, known = up.RecordTxn(mv.blockchain, ourReceiveOld, addrs,
testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
// Add a transaction that is both our spend and receive, both new and old
addrs = make(map[cipher.Address]byte, 2)
ux, ok = mv.blockchain.Unspent.Get(ourBothNew.In[0])
assert.True(t, ok)
addrs[ux.Body.Address] = byte(1)
addrs[ourBothNew.Out[1].Address] = byte(1)
assert.Equal(t, len(addrs), 2)
err, known = up.RecordTxn(mv.blockchain, ourBothNew, addrs, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
up.SetAnnounced(ourBothNew.Hash(), util.Now())
addrs = make(map[cipher.Address]byte, 1)
ux, ok = mv.blockchain.Unspent.Get(ourBothOld.In[0])
assert.True(t, ok)
addrs[ux.Body.Address] = byte(1)
addrs[ourBothOld.Out[1].Address] = byte(1)
assert.Equal(t, len(addrs), 2)
err, known = up.RecordTxn(mv.blockchain, ourBothOld, addrs, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
}
func testRefresh(t *testing.T, mv *Visor,
refresh func(checkPeriod, maxAge time.Duration)) {
up := mv.Unconfirmed
// Add a transaction that is invalid, but will not be checked yet
// Add a transaction that is invalid, and will be checked and removed
invalidTxUnchecked, err := makeValidTxn(mv)
assert.Nil(t, err)
invalidTxChecked, err := makeValidTxn(mv)
assert.Nil(t, err)
assert.Nil(t, invalidTxUnchecked.Verify())
assert.Nil(t, invalidTxChecked.Verify())
// Invalidate it by spending the output that this txn references
invalidator, err := makeValidTxn(mv)
assert.Nil(t, err)
assert.Nil(t, up.InjectTxn(mv.blockchain, invalidator, nil, false))
assert.Equal(t, len(up.Txns), 1)
_, err = mv.CreateAndExecuteBlock()
assert.Nil(t, err)
assert.Equal(t, len(up.Txns), 0)
assert.NotNil(t, mv.blockchain.VerifyTransaction(invalidTxUnchecked))
assert.NotNil(t, mv.blockchain.VerifyTransaction(invalidTxChecked))
invalidUtxUnchecked := UnconfirmedTxn{
Txn: invalidTxUnchecked,
Received: util.Now(),
Checked: util.Now(),
Announced: util.ZeroTime(),
}
invalidUtxChecked := invalidUtxUnchecked
invalidUtxChecked.Txn = invalidTxChecked
invalidUtxUnchecked.Checked = util.Now().Add(time.Hour)
invalidUtxChecked.Checked = util.Now().Add(-time.Hour)
up.Txns[invalidUtxUnchecked.Hash()] = invalidUtxUnchecked
up.Txns[invalidUtxChecked.Hash()] = invalidUtxChecked
assert.Equal(t, len(up.Txns), 2)
bh := coin.BlockHeader{}
for _, ux := range mv.blockchain.TxUxOut(invalidTxUnchecked, bh) {
up.Unspent.Add(ux)
}
for _, ux := range mv.blockchain.TxUxOut(invalidTxChecked, bh) {
up.Unspent.Add(ux)
}
// Add a transaction that is valid, and will not be checked yet
validTxUnchecked, err := makeValidTxn(mv)
assert.Nil(t, err)
assert.Nil(t, up.InjectTxn(mv.blockchain, validTxUnchecked, nil, false))
assert.Equal(t, len(up.Txns), 3)
validUtxUnchecked := up.Txns[validTxUnchecked.Hash()]
validUtxUnchecked.Checked = util.Now().Add(time.Hour)
up.Txns[validUtxUnchecked.Hash()] = validUtxUnchecked
// Add a transaction that is valid, and will be checked
validTxChecked, err := makeValidTxn(mv)
assert.Nil(t, err)
assert.Nil(t, up.InjectTxn(mv.blockchain, validTxChecked, nil, false))
assert.Equal(t, len(up.Txns), 4)
validUtxChecked := up.Txns[validTxChecked.Hash()]
validUtxChecked.Checked = util.Now().Add(-time.Hour)
up.Txns[validUtxChecked.Hash()] = validUtxChecked
// Add a transaction that is expired
validTxExpired, err := makeValidTxn(mv)
assert.Nil(t, err)
assert.Nil(t, up.InjectTxn(mv.blockchain, validTxExpired, nil, false))
assert.Equal(t, len(up.Txns), 5)
validUtxExpired := up.Txns[validTxExpired.Hash()]
validUtxExpired.Received = util.Now().Add(-time.Hour)
up.Txns[validTxExpired.Hash()] = validUtxExpired
// Pre-sanity check
assert.Equal(t, len(up.Unspent.Arr), 2*5)
assert.Equal(t, len(up.Txns), 5)
// Refresh
checkPeriod := time.Second * 2
maxAge := time.Second * 4
refresh(checkPeriod, maxAge)
// All utxns that are unchecked should be exactly the same
assert.Equal(t, up.Txns[validUtxUnchecked.Hash()], validUtxUnchecked)
assert.Equal(t, up.Txns[invalidUtxUnchecked.Hash()], invalidUtxUnchecked)
// The valid one that is checked should have its checked status updated
validUtxCheckedUpdated := up.Txns[validUtxChecked.Hash()]
assert.True(t, validUtxCheckedUpdated.Checked.After(validUtxChecked.Checked))
validUtxChecked.Checked = validUtxCheckedUpdated.Checked
assert.Equal(t, validUtxChecked, validUtxCheckedUpdated)
// The invalid checked one and the expired one should be removed
_, ok := up.Txns[invalidUtxChecked.Hash()]
assert.False(t, ok)
_, ok = up.Txns[validUtxExpired.Hash()]
assert.False(t, ok)
// Also, the unspents should have 2 * nRemaining
assert.Equal(t, len(up.Unspent.Arr), 2*3)
assert.Equal(t, len(up.Txns), 3)
}
func NewMessages(c MessagesConfig) *Messages {
return &Messages{
Config: c,
Mirror: rand.New(rand.NewSource(util.Now().UnixNano())).Uint32(),
}
}
// Sets all txns as announced
func (self *Visor) SetTxnsAnnounced(txns []coin.SHA256) {
now := util.Now()
for _, h := range txns {
self.Visor.Unconfirmed.SetAnnounced(h, now)
}
}
func TestGetOldOwnedTransactions(t *testing.T) {
mv := setupMasterVisor()
up := mv.Unconfirmed
// Setup txns
notOursNew, err := makeValidTxn(mv)
assert.Nil(t, err)
notOursOld, err := makeValidTxn(mv)
assert.Nil(t, err)
ourSpendNew, err := makeValidTxn(mv)
assert.Nil(t, err)
ourSpendOld, err := makeValidTxn(mv)
assert.Nil(t, err)
ourReceiveNew, err := makeValidTxn(mv)
assert.Nil(t, err)
ourReceiveOld, err := makeValidTxn(mv)
assert.Nil(t, err)
ourBothNew, err := makeValidTxn(mv)
assert.Nil(t, err)
ourBothOld, err := makeValidTxn(mv)
assert.Nil(t, err)
// Add a transaction that is not ours, both new and old
err, known := up.RecordTxn(mv.blockchain, notOursNew, nil, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
up.SetAnnounced(notOursNew.Hash(), util.Now())
err, known = up.RecordTxn(mv.blockchain, notOursOld, nil, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
// Add a transaction that is our spend, both new and old
addrs := make(map[coin.Address]byte, 1)
ux, ok := mv.blockchain.Unspent.Get(ourSpendNew.In[0])
assert.True(t, ok)
addrs[ux.Body.Address] = byte(1)
err, known = up.RecordTxn(mv.blockchain, ourSpendNew, addrs, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
up.SetAnnounced(ourSpendNew.Hash(), util.Now())
addrs = make(map[coin.Address]byte, 1)
ux, ok = mv.blockchain.Unspent.Get(ourSpendNew.In[0])
assert.True(t, ok)
addrs[ux.Body.Address] = byte(1)
err, known = up.RecordTxn(mv.blockchain, ourSpendOld, addrs, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
// Add a transaction that is our receive, both new and old
addrs = make(map[coin.Address]byte, 1)
addrs[ourReceiveNew.Out[1].Address] = byte(1)
err, known = up.RecordTxn(mv.blockchain, ourReceiveNew, addrs,
testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
up.SetAnnounced(ourReceiveNew.Hash(), util.Now())
addrs = make(map[coin.Address]byte, 1)
addrs[ourReceiveOld.Out[1].Address] = byte(1)
err, known = up.RecordTxn(mv.blockchain, ourReceiveOld, addrs,
testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
// Add a transaction that is both our spend and receive, both new and old
addrs = make(map[coin.Address]byte, 2)
ux, ok = mv.blockchain.Unspent.Get(ourBothNew.In[0])
assert.True(t, ok)
addrs[ux.Body.Address] = byte(1)
addrs[ourBothNew.Out[1].Address] = byte(1)
assert.Equal(t, len(addrs), 2)
err, known = up.RecordTxn(mv.blockchain, ourBothNew, addrs, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
up.SetAnnounced(ourBothNew.Hash(), util.Now())
addrs = make(map[coin.Address]byte, 1)
ux, ok = mv.blockchain.Unspent.Get(ourBothOld.In[0])
assert.True(t, ok)
addrs[ux.Body.Address] = byte(1)
addrs[ourBothOld.Out[1].Address] = byte(1)
assert.Equal(t, len(addrs), 2)
err, known = up.RecordTxn(mv.blockchain, ourBothOld, addrs, testBlockSize, 0)
assert.Nil(t, err)
assert.False(t, known)
// Get the old owned txns
utxns := up.GetOldOwnedTransactions(time.Hour)
// Check that the 3 txns are ones we are interested in and old enough
assert.Equal(t, len(utxns), 3)
mapTxns := make(map[coin.SHA256]bool)
txns := make(coin.Transactions, len(utxns))
for i, utx := range utxns {
txns[i] = utx.Txn
assert.True(t, utx.IsOurSpend || utx.IsOurReceive)
assert.True(t, utx.Announced.IsZero())
mapTxns[utx.Hash()] = true
}
assert.Equal(t, len(mapTxns), 3)
txns = coin.SortTransactions(txns, getFee)
expectTxns := coin.Transactions{ourSpendOld, ourReceiveOld, ourBothOld}
expectTxns = coin.SortTransactions(expectTxns, getFee)
assert.Equal(t, txns, expectTxns)
}
