// Get tx with given id from the balance folder, of from cache
func tx_from_balance(txid *btc.Uint256, error_is_fatal bool) (tx *btc.Tx) {
if tx = loadedTxs[txid.Hash]; tx != nil {
return // we have it in cache already
}
fn := "balance/" + txid.String() + ".tx"
buf, er := ioutil.ReadFile(fn)
if er == nil && buf != nil {
var th [32]byte
btc.ShaHash(buf, th[:])
if txid.Hash == th {
tx, _ = btc.NewTx(buf)
if error_is_fatal && tx == nil {
println("Transaction is corrupt:", txid.String())
cleanExit(1)
}
} else if error_is_fatal {
println("Transaction file is corrupt:", txid.String())
cleanExit(1)
}
} else if error_is_fatal {
println("Error reading transaction file:", fn)
if er != nil {
println(er.Error())
}
cleanExit(1)
}
loadedTxs[txid.Hash] = tx // store it in the cache
return
}
// LTC signing uses different seed string
func HashFromMessage(msg []byte, out []byte) {
const MessageMagic = "Litecoin Signed Message:\n"
b := new(bytes.Buffer)
btc.WriteVlen(b, uint32(len(MessageMagic)))
b.Write([]byte(MessageMagic))
btc.WriteVlen(b, uint32(len(msg)))
b.Write(msg)
btc.ShaHash(b.Bytes(), out)
}
func arm_stealth(p string) {
var buf, b2 [256]byte
create := p != ""
fmt.Print("Enter seed password of the stealth key (empty line to abort) : ")
le := sys.ReadPassword(buf[:])
if le <= 0 {
fmt.Println("Aborted")
return
}
if create {
fmt.Print("Re-enter the seed password : "******"The passwords you entered do not match")
return
}
}
nw := make([]byte, 32)
btc.ShaHash(buf[:le], nw) // seed
sys.ClearBuffer(buf[:le])
btc.ShaHash(nw, nw) // 1st key
wallet.ArmedStealthSecrets = append(wallet.ArmedStealthSecrets, nw)
if create {
fmt.Println("You have created a new stealth scan-key. Make sure to not forget this password!")
pk := btc.PublicFromPrivate(nw, true)
fmt.Println("Public hexdump:", hex.EncodeToString(pk))
fmt.Println(" Go to your wallet machine and execute:")
fmt.Println(" wallet -scankey", hex.EncodeToString(pk), "-prefix 0")
fmt.Println(" (change the prefix to a different value if you want)")
}
fmt.Println("Stealth key number", len(wallet.ArmedStealthSecrets)-1, "has been stored in memory")
fmt.Println("Reloading the current wallet...")
usif.ExecUiReq(&usif.OneUiReq{Handler: func(p string) {
wallet.LoadWallet(wallet.MyWallet.FileName)
}})
show_prompt = false
}
// Input the password (that is the secret seed to your wallet)
func getseed(seed []byte) bool {
var pass [1024]byte
var n int
var e error
var f *os.File
if !*ask4pass {
f, e = os.Open(PassSeedFilename)
if e == nil {
n, e = f.Read(pass[:])
f.Close()
if n <= 0 {
return false
}
goto calc_seed
}
fmt.Println("Seed file", PassSeedFilename, "not found")
}
fmt.Print("Enter your wallet's seed password: "******"" {
if !*singleask {
fmt.Print("Re-enter the seed password (to be sure): ")
var pass2 [1024]byte
p2len := sys.ReadPassword(pass2[:])
if p2len != n || !bytes.Equal(pass[:n], pass2[:p2len]) {
sys.ClearBuffer(pass2[:p2len])
println("The two passwords you entered do not match")
return false
}
sys.ClearBuffer(pass2[:p2len])
}
if *dump {
// Maybe he wants to save the password?
if ask_yes_no("Save the password on disk, so you won't be asked for it later?") {
e = ioutil.WriteFile(PassSeedFilename, pass[:n], 0600)
if e != nil {
fmt.Println("WARNING: Could not save the password", e.Error())
} else {
fmt.Println("The seed password has been stored in", PassSeedFilename)
}
}
}
}
calc_seed:
for i := 0; i < n; i++ {
if pass[i] < ' ' || pass[i] > 126 {
fmt.Println("WARNING: Your secret contains non-printable characters")
break
}
}
if len(secret_seed) > 0 {
x := append(secret_seed, pass[:n]...)
sys.ClearBuffer(secret_seed)
btc.ShaHash(x, seed)
sys.ClearBuffer(x)
} else {
btc.ShaHash(pass[:n], seed)
}
sys.ClearBuffer(pass[:n])
return true
}
// Get the secret seed and generate "keycnt" key pairs (both private and public)
func make_wallet() {
var lab string
load_others()
var seed_key []byte
var hdwal *btc.HDWallet
defer func() {
sys.ClearBuffer(seed_key)
if hdwal != nil {
sys.ClearBuffer(hdwal.Key)
sys.ClearBuffer(hdwal.ChCode)
}
}()
pass := getpass()
if pass == nil {
cleanExit(0)
}
if waltype >= 1 && waltype <= 3 {
seed_key = make([]byte, 32)
btc.ShaHash(pass, seed_key)
sys.ClearBuffer(pass)
lab = fmt.Sprintf("Typ%c", 'A'+waltype-1)
if waltype == 1 {
println("WARNING: Wallet Type 1 is obsolete")
} else if waltype == 2 {
if type2sec != "" {
d, e := hex.DecodeString(type2sec)
if e != nil {
println("t2sec error:", e.Error())
cleanExit(1)
}
type2_secret = d
} else {
type2_secret = make([]byte, 20)
btc.RimpHash(seed_key, type2_secret)
}
}
} else if waltype == 4 {
lab = "TypHD"
hdwal = btc.MasterKey(pass, testnet)
sys.ClearBuffer(pass)
} else {
sys.ClearBuffer(pass)
println("ERROR: Unsupported wallet type", waltype)
cleanExit(1)
}
if *verbose {
fmt.Println("Generating", keycnt, "keys, version", ver_pubkey(), "...")
}
first_determ_idx = len(keys)
for i := uint(0); i < keycnt; {
prv_key := make([]byte, 32)
if waltype == 3 {
btc.ShaHash(seed_key, prv_key)
seed_key = append(seed_key, byte(i))
} else if waltype == 2 {
seed_key = btc.DeriveNextPrivate(seed_key, type2_secret)
copy(prv_key, seed_key)
} else if waltype == 1 {
btc.ShaHash(seed_key, prv_key)
copy(seed_key, prv_key)
} else /*if waltype==4*/ {
// HD wallet
_hd := hdwal.Child(uint32(0x80000000 | i))
copy(prv_key, _hd.Key[1:])
sys.ClearBuffer(_hd.Key)
sys.ClearBuffer(_hd.ChCode)
}
if *scankey != "" {
new_stealth_address(prv_key)
return
}
rec := btc.NewPrivateAddr(prv_key, ver_secret(), !uncompressed)
if *pubkey != "" && *pubkey == rec.BtcAddr.String() {
fmt.Println("Public address:", rec.BtcAddr.String())
fmt.Println("Public hexdump:", hex.EncodeToString(rec.BtcAddr.Pubkey))
return
}
rec.BtcAddr.Extra.Label = fmt.Sprint(lab, " ", i+1)
keys = append(keys, rec)
i++
}
if *verbose {
fmt.Println("Private keys re-generated")
}
// Calculate SegWit addresses
segwit = make([]*btc.BtcAddr, len(keys))
for i, pk := range keys {
if len(pk.Pubkey) != 33 {
continue
}
h160 := btc.Rimp160AfterSha256(append([]byte{0, 20}, pk.Hash160[:]...))
segwit[i] = btc.NewAddrFromHash160(h160[:], btc.AddrVerScript(testnet))
}
}
// Get the secret seed and generate "keycnt" key pairs (both private and public)
func make_wallet() {
var lab string
load_others()
seed_key := make([]byte, 32)
if !getseed(seed_key) {
os.Exit(0)
}
defer func() {
sys.ClearBuffer(seed_key)
}()
switch waltype {
case 1:
lab = "TypA"
println("WARNING: Wallet Type 1 is obsolete")
case 2:
lab = "TypB"
if type2sec != "" {
d, e := hex.DecodeString(type2sec)
if e != nil {
println("t2sec error:", e.Error())
os.Exit(1)
}
type2_secret = d
} else {
type2_secret = make([]byte, 20)
btc.RimpHash(seed_key, type2_secret)
}
case 3:
lab = "TypC"
default:
println("ERROR: Unsupported wallet type", waltype)
os.Exit(0)
}
if *verbose {
fmt.Println("Generating", keycnt, "keys, version", AddrVerPubkey(), "...")
}
for i := uint(0); i < keycnt; {
prv_key := make([]byte, 32)
if waltype == 3 {
btc.ShaHash(seed_key, prv_key)
seed_key = append(seed_key, byte(i))
} else if waltype == 2 {
seed_key = btc.DeriveNextPrivate(seed_key, type2_secret)
copy(prv_key, seed_key)
} else {
btc.ShaHash(seed_key, prv_key)
copy(seed_key, prv_key)
}
priv_keys = append(priv_keys, prv_key)
if *scankey != "" {
new_stealth_address(prv_key)
return
}
// for stealth keys
if i == 0 {
copy(first_seed[:], prv_key)
}
compressed_key = append(compressed_key, !uncompressed)
pub := btc.PublicFromPrivate(prv_key, !uncompressed)
if pub != nil {
adr := btc.NewAddrFromPubkey(pub, AddrVerPubkey())
if *pubkey != "" && *pubkey == adr.String() {
fmt.Println("Public address:", adr.String())
fmt.Println("Public hexdump:", hex.EncodeToString(pub))
return
}
publ_addrs = append(publ_addrs, adr)
labels = append(labels, fmt.Sprint(lab, " ", i+1))
i++
} else {
println("PublicFromPrivate error 3")
}
}
if *verbose {
fmt.Println("Private keys re-generated")
}
}
