Exemple #1
0
func IsMultisig(ad *btc.BtcAddr) (yes bool, rec *MultisigAddr) {
	yes = ad.Version == btc.AddrVerScript(common.Testnet)
	if !yes {
		return
	}

	fn := common.GocoinHomeDir + "wallet" +
		string(os.PathSeparator) + "multisig" +
		string(os.PathSeparator) + ad.String() + ".json"

	d, er := ioutil.ReadFile(fn)
	if er != nil {
		//println("fn", fn, er.Error())
		return
	}

	var msa MultisigAddr
	er = json.Unmarshal(d, &msa)
	if er == nil {
		rec = &msa
	} else {
		println(fn, er.Error())
	}

	return
}
Exemple #2
0
func main() {
	var testnet bool
	if len(os.Args) != 2 {
		fmt.Println("Specify one P2KH bitcoin address to see it's P2SH-P2WPKH deposit address")
		fmt.Println("WARNING: Make sure the input address comes from an uncompressed key!!!!!")
		return
	}
	aa, er := btc.NewAddrFromString(os.Args[1])
	if er != nil {
		println(er.Error())
		return
	}

	if btc.AddrVerPubkey(false) == aa.Version {
	} else if btc.AddrVerPubkey(true) == aa.Version {
		testnet = true
	} else {
		fmt.Println("This does nto seem to be P2KH type address")
		return
	}

	h160 := btc.Rimp160AfterSha256(append([]byte{0, 20}, aa.Hash160[:]...))
	aa = btc.NewAddrFromHash160(h160[:], btc.AddrVerScript(testnet))
	fmt.Println(aa.String())
}
Exemple #3
0
func GetAllUnspent(aa *btc.BtcAddr) (thisbal chain.AllUnspentTx) {
	var rec *OneAllAddrBal
	if aa.Version == btc.AddrVerPubkey(common.Testnet) {
		rec = AllBalancesP2KH[aa.Hash160]
	} else if aa.Version == btc.AddrVerScript(common.Testnet) {
		rec = AllBalancesP2SH[aa.Hash160]
	} else {
		return
	}
	if rec != nil {
		for _, v := range rec.Unsp {
			if qr, vout := v.GetRec(); qr != nil {
				if oo := qr.Outs[vout]; oo != nil {
					unsp := &chain.OneUnspentTx{TxPrevOut: btc.TxPrevOut{Hash: qr.TxID, Vout: vout},
						Value: oo.Value, MinedAt: qr.InBlock, Coinbase: qr.Coinbase, BtcAddr: aa}

					if int(vout+1) < len(qr.Outs) {
						var msg []byte
						if qr.Outs[vout+1] != nil && len(qr.Outs[vout+1].PKScr) > 1 && qr.Outs[vout+1].PKScr[0] == 0x6a {
							msg = qr.Outs[vout+1].PKScr[1:]
						} else if int(vout+1) != len(qr.Outs) && qr.Outs[len(qr.Outs)-1] != nil &&
							len(qr.Outs[len(qr.Outs)-1].PKScr) > 1 && qr.Outs[len(qr.Outs)-1].PKScr[0] == 0x6a {
							msg = qr.Outs[len(qr.Outs)-1].PKScr[1:]
						}
						if msg != nil {
							_, unsp.Message, _, _ = btc.GetOpcode(msg)
						}
					}
					thisbal = append(thisbal, unsp)
				}
			}
		}
	}
	return
}
Exemple #4
0
// version byte for P2SH addresses
func ver_script() byte {
	// for litecoin the version is identical
	return btc.AddrVerScript(testnet)
}
Exemple #5
0
func json_balance(w http.ResponseWriter, r *http.Request) {
	if !ipchecker(r) {
		return
	}

	if r.Method != "POST" {
		return
	}

	summary := len(r.Form["summary"]) > 0

	inp, er := ioutil.ReadAll(r.Body)
	if er != nil {
		println(er.Error())
		return
	}

	var addrs []string
	er = json.Unmarshal(inp, &addrs)
	if er != nil {
		println(er.Error())
		return
	}

	type OneOut struct {
		TxId     string
		Vout     uint32
		Value    uint64
		Height   uint32
		Coinbase bool
		Message  string
		Addr     string
	}

	type OneOuts struct {
		Value      uint64
		OutCnt     int
		SegWitCnt  int
		SegWitAddr string
		Outs       []OneOut
	}

	out := make(map[string]*OneOuts)

	lck := new(usif.OneLock)
	lck.In.Add(1)
	lck.Out.Add(1)
	usif.LocksChan <- lck
	lck.In.Wait()

	for _, a := range addrs {
		aa, e := btc.NewAddrFromString(a)
		if e != nil {
			continue
		}

		unsp := wallet.GetAllUnspent(aa)
		newrec := new(OneOuts)
		if len(unsp) > 0 {
			newrec.OutCnt = len(unsp)
			for _, u := range unsp {
				newrec.Value += u.Value
				if !summary {
					newrec.Outs = append(newrec.Outs, OneOut{
						TxId: btc.NewUint256(u.TxPrevOut.Hash[:]).String(), Vout: u.Vout,
						Value: u.Value, Height: u.MinedAt, Coinbase: u.Coinbase,
						Message: html.EscapeString(string(u.Message)), Addr: a})
				}
			}
		}
		out[aa.String()] = newrec

		/* Segwit P2WPKH: */
		if aa.Version == btc.AddrVerPubkey(common.Testnet) {
			// SegWit if applicable
			h160 := btc.Rimp160AfterSha256(append([]byte{0, 20}, aa.Hash160[:]...))
			aa = btc.NewAddrFromHash160(h160[:], btc.AddrVerScript(common.Testnet))
			newrec.SegWitAddr = aa.String()
			unsp = wallet.GetAllUnspent(aa)
			if len(unsp) > 0 {
				newrec.OutCnt += len(unsp)
				newrec.SegWitCnt = len(unsp)
				as := aa.String()
				for _, u := range unsp {
					newrec.Value += u.Value
					if !summary {
						newrec.Outs = append(newrec.Outs, OneOut{
							TxId: btc.NewUint256(u.TxPrevOut.Hash[:]).String(), Vout: u.Vout,
							Value: u.Value, Height: u.MinedAt, Coinbase: u.Coinbase,
							Message: html.EscapeString(string(u.Message)), Addr: as})
					}
				}
			}
		}
	}

	lck.Out.Done()

	bx, er := json.Marshal(out)
	if er == nil {
		w.Header()["Content-Type"] = []string{"application/json"}
		w.Write(bx)
	} else {
		println(er.Error())
	}
}
Exemple #6
0
func dl_balance(w http.ResponseWriter, r *http.Request) {
	if !ipchecker(r) {
		return
	}

	if r.Method != "POST" {
		return
	}

	var addrs []string
	var labels []string

	if len(r.Form["addrcnt"]) != 1 {
		println("no addrcnt")
		return
	}
	addrcnt, _ := strconv.ParseUint(r.Form["addrcnt"][0], 10, 32)

	for i := 0; i < int(addrcnt); i++ {
		is := fmt.Sprint(i)
		if len(r.Form["addr"+is]) == 1 {
			addrs = append(addrs, r.Form["addr"+is][0])
			if len(r.Form["label"+is]) == 1 {
				labels = append(labels, r.Form["label"+is][0])
			} else {
				labels = append(labels, "")
			}
		}
	}

	type one_unsp_rec struct {
		btc.TxPrevOut
		Value    uint64
		Addr     string
		MinedAt  uint32
		Coinbase bool
	}

	var thisbal chain.AllUnspentTx

	lck := new(usif.OneLock)
	lck.In.Add(1)
	lck.Out.Add(1)
	usif.LocksChan <- lck
	lck.In.Wait()

	for idx, a := range addrs {
		aa, e := btc.NewAddrFromString(a)
		aa.Extra.Label = labels[idx]
		if e == nil {
			newrecs := wallet.GetAllUnspent(aa)
			if len(newrecs) > 0 {
				thisbal = append(thisbal, newrecs...)
			}

			/* Segwit P2WPKH: */
			if aa.Version == btc.AddrVerPubkey(common.Testnet) {
				// SegWit if applicable
				h160 := btc.Rimp160AfterSha256(append([]byte{0, 20}, aa.Hash160[:]...))
				aa = btc.NewAddrFromHash160(h160[:], btc.AddrVerScript(common.Testnet))
				newrecs = wallet.GetAllUnspent(aa)
				if len(newrecs) > 0 {
					thisbal = append(thisbal, newrecs...)
				}
			}
		}
	}
	lck.Out.Done()

	buf := new(bytes.Buffer)
	zi := zip.NewWriter(buf)
	was_tx := make(map[[32]byte]bool)

	sort.Sort(thisbal)
	for i := range thisbal {
		if was_tx[thisbal[i].TxPrevOut.Hash] {
			continue
		}
		was_tx[thisbal[i].TxPrevOut.Hash] = true
		txid := btc.NewUint256(thisbal[i].TxPrevOut.Hash[:])
		fz, _ := zi.Create("balance/" + txid.String() + ".tx")
		if dat, er := common.BlockChain.GetRawTx(thisbal[i].MinedAt, txid); er == nil {
			fz.Write(dat)
		} else {
			println(er.Error())
		}
	}

	fz, _ := zi.Create("balance/unspent.txt")
	for i := range thisbal {
		fmt.Fprintln(fz, thisbal[i].UnspentTextLine())
	}

	zi.Close()
	w.Header()["Content-Type"] = []string{"application/zip"}
	w.Write(buf.Bytes())

}
Exemple #7
0
// 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))
	}
}
Exemple #8
0
/*
{
"address" : "2NAHUDSC1EmbTBwQQp4VQ2FNzWDqHtmk1i6",
"redeemScript" : "512102cdc4fff0ad031ea5f2d0d4337e2bf976b84334f8f80b08fe3f69886d58bc5a8a2102ebf54926d3edaae51bde71f2976948559a8d43fce52f5e7ed9ed85dbaa449d7f52ae"
}
*/
func main() {
	var testnet bool
	if len(os.Args) < 3 {
		fmt.Println("Specify one integer and at least one public key.")
		fmt.Println("For Testent, make the integer negative.")
		return
	}
	cnt, er := strconv.ParseInt(os.Args[1], 10, 32)
	if er != nil {
		println("Count value:", er.Error())
		return
	}
	if cnt < 0 {
		testnet = true
		cnt = -cnt
	}
	if cnt < 1 || cnt > 16 {
		println("The integer (required number of keys) must be between 1 and 16")
		return
	}
	buf := new(bytes.Buffer)
	buf.WriteByte(byte(0x50 + cnt))
	fmt.Println("Trying to prepare multisig address for", cnt, "out of", len(os.Args)-2, "public keys ...")
	var pkeys byte
	var ads string
	for i := 2; i < len(os.Args); i++ {
		if pkeys == 16 {
			println("Oh, give me a break. You don't need more than 16 public keys - stopping here!")
			break
		}
		d, er := hex.DecodeString(os.Args[i])
		if er != nil {
			println("pubkey", i, er.Error())
		}
		_, er = btc.NewPublicKey(d)
		if er != nil {
			println("pubkey", i, er.Error())
			return
		}
		pkeys++
		buf.WriteByte(byte(len(d)))
		buf.Write(d)
		if ads != "" {
			ads += ", "
		}
		ads += "\"" + btc.NewAddrFromPubkey(d, btc.AddrVerPubkey(testnet)).String() + "\""
	}
	buf.WriteByte(0x50 + pkeys)
	buf.WriteByte(0xae)

	p2sh := buf.Bytes()
	addr := btc.NewAddrFromPubkey(p2sh, btc.AddrVerScript(testnet))

	rec := "{\n"
	rec += fmt.Sprintf("\t\"multiAddress\" : \"%s\",\n", addr.String())
	rec += fmt.Sprintf("\t\"scriptPubKey\" : \"a914%s87\",\n", hex.EncodeToString(addr.Hash160[:]))
	rec += fmt.Sprintf("\t\"keysRequired\" : %d,\n", cnt)
	rec += fmt.Sprintf("\t\"keysProvided\" : %d,\n", pkeys)
	rec += fmt.Sprintf("\t\"redeemScript\" : \"%s\",\n", hex.EncodeToString(p2sh))
	rec += fmt.Sprintf("\t\"listOfAddres\" : [%s]\n", ads)
	rec += "}\n"
	fname := addr.String() + ".json"
	ioutil.WriteFile(fname, []byte(rec), 0666)
	fmt.Println("The address record stored in", fname)
}