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2ee650dff6
pywallet-tools/pywallet.py
jackjack-jj 2ee650dff6 fix the warning about global
2013-03-28 00:14:28 +01:00

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#!/usr/bin/env python
pywversion="2.0b8-bt"
never_update=False
#
# jackjack's pywallet.py
# https://github.com/jackjack-jj/pywallet
# forked from Joric's pywallet.py
#
beta_version = ('a' in pywversion.split('-')[0]) or ('b' in pywversion.split('-')[0])
missing_dep = []
try:
from bsddb.db import *
except:
missing_dep.append('bsddb')
import os, sys, time
pyw_filename = sys.argv[0].split('/')[len(sys.argv[0].split('/'))-1]
pyw_path = os.getcwd()
try:
for i in os.listdir('/usr/lib/python2.5/site-packages'):
if 'Twisted' in i:
sys.path.append('/usr/lib/python2.5/site-packages/'+i)
except:
''
try:
import json
except:
try:
import simplejson as json
except:
print("Json or simplejson package is needed")
import logging
import struct
import StringIO
import traceback
import socket
import types
import string
import exceptions
import hashlib
import random
import urllib
import math
try:
from twisted.internet import reactor
from twisted.web import server, resource
from twisted.web.static import File
from twisted.python import log
except:
missing_dep.append('twisted')
from datetime import datetime
from subprocess import *
max_version = 81000
addrtype = 0
json_db = {}
private_keys = []
private_hex_keys = []
passphrase = ""
global_merging_message = ["",""]
balance_site = 'http://bitcoin.site50.net/balance.php?adresse'
aversions = {};
for i in range(256):
aversions[i] = "version %d" % i;
aversions[0] = 'Bitcoin';
aversions[52] = 'Namecoin';
aversions[111] = 'Testnet';
wallet_dir = ""
wallet_name = ""
ko = 1e3
kio = 1024
Mo = 1e6
Mio = 1024 ** 2
Go = 1e9
Gio = 1024 ** 3
To = 1e12
Tio = 1024 ** 4
prekeys = ["308201130201010420".decode('hex'), "308201120201010420".decode('hex')]
postkeys = ["a081a530".decode('hex'), "81a530".decode('hex')]
def iais(a):
if a>= 2:
return 's'
else:
return ''
def determine_db_dir():
import os
import os.path
import platform
if wallet_dir in "":
if platform.system() == "Darwin":
return os.path.expanduser("~/Library/Application Support/Bitcoin/")
elif platform.system() == "Windows":
return os.path.join(os.environ['APPDATA'], "Bitcoin")
return os.path.expanduser("~/.bitcoin")
else:
return wallet_dir
def determine_db_name():
if wallet_name in "":
return "wallet.dat"
else:
return wallet_name
########################
# begin of aes.py code #
########################
# from the SlowAES project, http://code.google.com/p/slowaes (aes.py)
def append_PKCS7_padding(s):
"""return s padded to a multiple of 16-bytes by PKCS7 padding"""
numpads = 16 - (len(s)%16)
return s + numpads*chr(numpads)
def strip_PKCS7_padding(s):
"""return s stripped of PKCS7 padding"""
if len(s)%16 or not s:
raise ValueError("String of len %d can't be PCKS7-padded" % len(s))
numpads = ord(s[-1])
if numpads > 16:
raise ValueError("String ending with %r can't be PCKS7-padded" % s[-1])
return s[:-numpads]
class AES(object):
# valid key sizes
keySize = dict(SIZE_128=16, SIZE_192=24, SIZE_256=32)
# Rijndael S-box
sbox = [0x63, 0x7c, 0x77, 0x7b, 0xf2, 0x6b, 0x6f, 0xc5, 0x30, 0x01, 0x67,
0x2b, 0xfe, 0xd7, 0xab, 0x76, 0xca, 0x82, 0xc9, 0x7d, 0xfa, 0x59,
0x47, 0xf0, 0xad, 0xd4, 0xa2, 0xaf, 0x9c, 0xa4, 0x72, 0xc0, 0xb7,
0xfd, 0x93, 0x26, 0x36, 0x3f, 0xf7, 0xcc, 0x34, 0xa5, 0xe5, 0xf1,
0x71, 0xd8, 0x31, 0x15, 0x04, 0xc7, 0x23, 0xc3, 0x18, 0x96, 0x05,
0x9a, 0x07, 0x12, 0x80, 0xe2, 0xeb, 0x27, 0xb2, 0x75, 0x09, 0x83,
0x2c, 0x1a, 0x1b, 0x6e, 0x5a, 0xa0, 0x52, 0x3b, 0xd6, 0xb3, 0x29,
0xe3, 0x2f, 0x84, 0x53, 0xd1, 0x00, 0xed, 0x20, 0xfc, 0xb1, 0x5b,
0x6a, 0xcb, 0xbe, 0x39, 0x4a, 0x4c, 0x58, 0xcf, 0xd0, 0xef, 0xaa,
0xfb, 0x43, 0x4d, 0x33, 0x85, 0x45, 0xf9, 0x02, 0x7f, 0x50, 0x3c,
0x9f, 0xa8, 0x51, 0xa3, 0x40, 0x8f, 0x92, 0x9d, 0x38, 0xf5, 0xbc,
0xb6, 0xda, 0x21, 0x10, 0xff, 0xf3, 0xd2, 0xcd, 0x0c, 0x13, 0xec,
0x5f, 0x97, 0x44, 0x17, 0xc4, 0xa7, 0x7e, 0x3d, 0x64, 0x5d, 0x19,
0x73, 0x60, 0x81, 0x4f, 0xdc, 0x22, 0x2a, 0x90, 0x88, 0x46, 0xee,
0xb8, 0x14, 0xde, 0x5e, 0x0b, 0xdb, 0xe0, 0x32, 0x3a, 0x0a, 0x49,
0x06, 0x24, 0x5c, 0xc2, 0xd3, 0xac, 0x62, 0x91, 0x95, 0xe4, 0x79,
0xe7, 0xc8, 0x37, 0x6d, 0x8d, 0xd5, 0x4e, 0xa9, 0x6c, 0x56, 0xf4,
0xea, 0x65, 0x7a, 0xae, 0x08, 0xba, 0x78, 0x25, 0x2e, 0x1c, 0xa6,
0xb4, 0xc6, 0xe8, 0xdd, 0x74, 0x1f, 0x4b, 0xbd, 0x8b, 0x8a, 0x70,
0x3e, 0xb5, 0x66, 0x48, 0x03, 0xf6, 0x0e, 0x61, 0x35, 0x57, 0xb9,
0x86, 0xc1, 0x1d, 0x9e, 0xe1, 0xf8, 0x98, 0x11, 0x69, 0xd9, 0x8e,
0x94, 0x9b, 0x1e, 0x87, 0xe9, 0xce, 0x55, 0x28, 0xdf, 0x8c, 0xa1,
0x89, 0x0d, 0xbf, 0xe6, 0x42, 0x68, 0x41, 0x99, 0x2d, 0x0f, 0xb0,
0x54, 0xbb, 0x16]
# Rijndael Inverted S-box
rsbox = [0x52, 0x09, 0x6a, 0xd5, 0x30, 0x36, 0xa5, 0x38, 0xbf, 0x40, 0xa3,
0x9e, 0x81, 0xf3, 0xd7, 0xfb , 0x7c, 0xe3, 0x39, 0x82, 0x9b, 0x2f,
0xff, 0x87, 0x34, 0x8e, 0x43, 0x44, 0xc4, 0xde, 0xe9, 0xcb , 0x54,
0x7b, 0x94, 0x32, 0xa6, 0xc2, 0x23, 0x3d, 0xee, 0x4c, 0x95, 0x0b,
0x42, 0xfa, 0xc3, 0x4e , 0x08, 0x2e, 0xa1, 0x66, 0x28, 0xd9, 0x24,
0xb2, 0x76, 0x5b, 0xa2, 0x49, 0x6d, 0x8b, 0xd1, 0x25 , 0x72, 0xf8,
0xf6, 0x64, 0x86, 0x68, 0x98, 0x16, 0xd4, 0xa4, 0x5c, 0xcc, 0x5d,
0x65, 0xb6, 0x92 , 0x6c, 0x70, 0x48, 0x50, 0xfd, 0xed, 0xb9, 0xda,
0x5e, 0x15, 0x46, 0x57, 0xa7, 0x8d, 0x9d, 0x84 , 0x90, 0xd8, 0xab,
0x00, 0x8c, 0xbc, 0xd3, 0x0a, 0xf7, 0xe4, 0x58, 0x05, 0xb8, 0xb3,
0x45, 0x06 , 0xd0, 0x2c, 0x1e, 0x8f, 0xca, 0x3f, 0x0f, 0x02, 0xc1,
0xaf, 0xbd, 0x03, 0x01, 0x13, 0x8a, 0x6b , 0x3a, 0x91, 0x11, 0x41,
0x4f, 0x67, 0xdc, 0xea, 0x97, 0xf2, 0xcf, 0xce, 0xf0, 0xb4, 0xe6,
0x73 , 0x96, 0xac, 0x74, 0x22, 0xe7, 0xad, 0x35, 0x85, 0xe2, 0xf9,
0x37, 0xe8, 0x1c, 0x75, 0xdf, 0x6e , 0x47, 0xf1, 0x1a, 0x71, 0x1d,
0x29, 0xc5, 0x89, 0x6f, 0xb7, 0x62, 0x0e, 0xaa, 0x18, 0xbe, 0x1b ,
0xfc, 0x56, 0x3e, 0x4b, 0xc6, 0xd2, 0x79, 0x20, 0x9a, 0xdb, 0xc0,
0xfe, 0x78, 0xcd, 0x5a, 0xf4 , 0x1f, 0xdd, 0xa8, 0x33, 0x88, 0x07,
0xc7, 0x31, 0xb1, 0x12, 0x10, 0x59, 0x27, 0x80, 0xec, 0x5f , 0x60,
0x51, 0x7f, 0xa9, 0x19, 0xb5, 0x4a, 0x0d, 0x2d, 0xe5, 0x7a, 0x9f,
0x93, 0xc9, 0x9c, 0xef , 0xa0, 0xe0, 0x3b, 0x4d, 0xae, 0x2a, 0xf5,
0xb0, 0xc8, 0xeb, 0xbb, 0x3c, 0x83, 0x53, 0x99, 0x61 , 0x17, 0x2b,
0x04, 0x7e, 0xba, 0x77, 0xd6, 0x26, 0xe1, 0x69, 0x14, 0x63, 0x55,
0x21, 0x0c, 0x7d]
def getSBoxValue(self,num):
"""Retrieves a given S-Box Value"""
return self.sbox[num]
def getSBoxInvert(self,num):
"""Retrieves a given Inverted S-Box Value"""
return self.rsbox[num]
def rotate(self, word):
""" Rijndael's key schedule rotate operation.
Rotate a word eight bits to the left: eg, rotate(1d2c3a4f) == 2c3a4f1d
Word is an char list of size 4 (32 bits overall).
"""
return word[1:] + word[:1]
# Rijndael Rcon
Rcon = [0x8d, 0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80, 0x1b, 0x36,
0x6c, 0xd8, 0xab, 0x4d, 0x9a, 0x2f, 0x5e, 0xbc, 0x63, 0xc6, 0x97,
0x35, 0x6a, 0xd4, 0xb3, 0x7d, 0xfa, 0xef, 0xc5, 0x91, 0x39, 0x72,
0xe4, 0xd3, 0xbd, 0x61, 0xc2, 0x9f, 0x25, 0x4a, 0x94, 0x33, 0x66,
0xcc, 0x83, 0x1d, 0x3a, 0x74, 0xe8, 0xcb, 0x8d, 0x01, 0x02, 0x04,
0x08, 0x10, 0x20, 0x40, 0x80, 0x1b, 0x36, 0x6c, 0xd8, 0xab, 0x4d,
0x9a, 0x2f, 0x5e, 0xbc, 0x63, 0xc6, 0x97, 0x35, 0x6a, 0xd4, 0xb3,
0x7d, 0xfa, 0xef, 0xc5, 0x91, 0x39, 0x72, 0xe4, 0xd3, 0xbd, 0x61,
0xc2, 0x9f, 0x25, 0x4a, 0x94, 0x33, 0x66, 0xcc, 0x83, 0x1d, 0x3a,
0x74, 0xe8, 0xcb, 0x8d, 0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40,
0x80, 0x1b, 0x36, 0x6c, 0xd8, 0xab, 0x4d, 0x9a, 0x2f, 0x5e, 0xbc,
0x63, 0xc6, 0x97, 0x35, 0x6a, 0xd4, 0xb3, 0x7d, 0xfa, 0xef, 0xc5,
0x91, 0x39, 0x72, 0xe4, 0xd3, 0xbd, 0x61, 0xc2, 0x9f, 0x25, 0x4a,
0x94, 0x33, 0x66, 0xcc, 0x83, 0x1d, 0x3a, 0x74, 0xe8, 0xcb, 0x8d,
0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80, 0x1b, 0x36, 0x6c,
0xd8, 0xab, 0x4d, 0x9a, 0x2f, 0x5e, 0xbc, 0x63, 0xc6, 0x97, 0x35,
0x6a, 0xd4, 0xb3, 0x7d, 0xfa, 0xef, 0xc5, 0x91, 0x39, 0x72, 0xe4,
0xd3, 0xbd, 0x61, 0xc2, 0x9f, 0x25, 0x4a, 0x94, 0x33, 0x66, 0xcc,
0x83, 0x1d, 0x3a, 0x74, 0xe8, 0xcb, 0x8d, 0x01, 0x02, 0x04, 0x08,
0x10, 0x20, 0x40, 0x80, 0x1b, 0x36, 0x6c, 0xd8, 0xab, 0x4d, 0x9a,
0x2f, 0x5e, 0xbc, 0x63, 0xc6, 0x97, 0x35, 0x6a, 0xd4, 0xb3, 0x7d,
0xfa, 0xef, 0xc5, 0x91, 0x39, 0x72, 0xe4, 0xd3, 0xbd, 0x61, 0xc2,
0x9f, 0x25, 0x4a, 0x94, 0x33, 0x66, 0xcc, 0x83, 0x1d, 0x3a, 0x74,
0xe8, 0xcb ]
def getRconValue(self, num):
"""Retrieves a given Rcon Value"""
return self.Rcon[num]
def core(self, word, iteration):
"""Key schedule core."""
# rotate the 32-bit word 8 bits to the left
word = self.rotate(word)
# apply S-Box substitution on all 4 parts of the 32-bit word
for i in range(4):
word[i] = self.getSBoxValue(word[i])
# XOR the output of the rcon operation with i to the first part
# (leftmost) only
word[0] = word[0] ^ self.getRconValue(iteration)
return word
def expandKey(self, key, size, expandedKeySize):
"""Rijndael's key expansion.
Expands an 128,192,256 key into an 176,208,240 bytes key
expandedKey is a char list of large enough size,
key is the non-expanded key.
"""
# current expanded keySize, in bytes
currentSize = 0
rconIteration = 1
expandedKey = [0] * expandedKeySize
# set the 16, 24, 32 bytes of the expanded key to the input key
for j in range(size):
expandedKey[j] = key[j]
currentSize += size
while currentSize < expandedKeySize:
# assign the previous 4 bytes to the temporary value t
t = expandedKey[currentSize-4:currentSize]
# every 16,24,32 bytes we apply the core schedule to t
# and increment rconIteration afterwards
if currentSize % size == 0:
t = self.core(t, rconIteration)
rconIteration += 1
# For 256-bit keys, we add an extra sbox to the calculation
if size == self.keySize["SIZE_256"] and ((currentSize % size) == 16):
for l in range(4): t[l] = self.getSBoxValue(t[l])
# We XOR t with the four-byte block 16,24,32 bytes before the new
# expanded key. This becomes the next four bytes in the expanded
# key.
for m in range(4):
expandedKey[currentSize] = expandedKey[currentSize - size] ^ \
t[m]
currentSize += 1
return expandedKey
def addRoundKey(self, state, roundKey):
"""Adds (XORs) the round key to the state."""
for i in range(16):
state[i] ^= roundKey[i]
return state
def createRoundKey(self, expandedKey, roundKeyPointer):
"""Create a round key.
Creates a round key from the given expanded key and the
position within the expanded key.
"""
roundKey = [0] * 16
for i in range(4):
for j in range(4):
roundKey[j*4+i] = expandedKey[roundKeyPointer + i*4 + j]
return roundKey
def galois_multiplication(self, a, b):
"""Galois multiplication of 8 bit characters a and b."""
p = 0
for counter in range(8):
if b & 1: p ^= a
hi_bit_set = a & 0x80
a <<= 1
# keep a 8 bit
a &= 0xFF
if hi_bit_set:
a ^= 0x1b
b >>= 1
return p
#
# substitute all the values from the state with the value in the SBox
# using the state value as index for the SBox
#
def subBytes(self, state, isInv):
if isInv: getter = self.getSBoxInvert
else: getter = self.getSBoxValue
for i in range(16): state[i] = getter(state[i])
return state
# iterate over the 4 rows and call shiftRow() with that row
def shiftRows(self, state, isInv):
for i in range(4):
state = self.shiftRow(state, i*4, i, isInv)
return state
# each iteration shifts the row to the left by 1
def shiftRow(self, state, statePointer, nbr, isInv):
for i in range(nbr):
if isInv:
state[statePointer:statePointer+4] = \
state[statePointer+3:statePointer+4] + \
state[statePointer:statePointer+3]
else:
state[statePointer:statePointer+4] = \
state[statePointer+1:statePointer+4] + \
state[statePointer:statePointer+1]
return state
# galois multiplication of the 4x4 matrix
def mixColumns(self, state, isInv):
# iterate over the 4 columns
for i in range(4):
# construct one column by slicing over the 4 rows
column = state[i:i+16:4]
# apply the mixColumn on one column
column = self.mixColumn(column, isInv)
# put the values back into the state
state[i:i+16:4] = column
return state
# galois multiplication of 1 column of the 4x4 matrix
def mixColumn(self, column, isInv):
if isInv: mult = [14, 9, 13, 11]
else: mult = [2, 1, 1, 3]
cpy = list(column)
g = self.galois_multiplication
column[0] = g(cpy[0], mult[0]) ^ g(cpy[3], mult[1]) ^ \
g(cpy[2], mult[2]) ^ g(cpy[1], mult[3])
column[1] = g(cpy[1], mult[0]) ^ g(cpy[0], mult[1]) ^ \
g(cpy[3], mult[2]) ^ g(cpy[2], mult[3])
column[2] = g(cpy[2], mult[0]) ^ g(cpy[1], mult[1]) ^ \
g(cpy[0], mult[2]) ^ g(cpy[3], mult[3])
column[3] = g(cpy[3], mult[0]) ^ g(cpy[2], mult[1]) ^ \
g(cpy[1], mult[2]) ^ g(cpy[0], mult[3])
return column
# applies the 4 operations of the forward round in sequence
def aes_round(self, state, roundKey):
state = self.subBytes(state, False)
state = self.shiftRows(state, False)
state = self.mixColumns(state, False)
state = self.addRoundKey(state, roundKey)
return state
# applies the 4 operations of the inverse round in sequence
def aes_invRound(self, state, roundKey):
state = self.shiftRows(state, True)
state = self.subBytes(state, True)
state = self.addRoundKey(state, roundKey)
state = self.mixColumns(state, True)
return state
# Perform the initial operations, the standard round, and the final
# operations of the forward aes, creating a round key for each round
def aes_main(self, state, expandedKey, nbrRounds):
state = self.addRoundKey(state, self.createRoundKey(expandedKey, 0))
i = 1
while i < nbrRounds:
state = self.aes_round(state,
self.createRoundKey(expandedKey, 16*i))
i += 1
state = self.subBytes(state, False)
state = self.shiftRows(state, False)
state = self.addRoundKey(state,
self.createRoundKey(expandedKey, 16*nbrRounds))
return state
# Perform the initial operations, the standard round, and the final
# operations of the inverse aes, creating a round key for each round
def aes_invMain(self, state, expandedKey, nbrRounds):
state = self.addRoundKey(state,
self.createRoundKey(expandedKey, 16*nbrRounds))
i = nbrRounds - 1
while i > 0:
state = self.aes_invRound(state,
self.createRoundKey(expandedKey, 16*i))
i -= 1
state = self.shiftRows(state, True)
state = self.subBytes(state, True)
state = self.addRoundKey(state, self.createRoundKey(expandedKey, 0))
return state
# encrypts a 128 bit input block against the given key of size specified
def encrypt(self, iput, key, size):
output = [0] * 16
# the number of rounds
nbrRounds = 0
# the 128 bit block to encode
block = [0] * 16
# set the number of rounds
if size == self.keySize["SIZE_128"]: nbrRounds = 10
elif size == self.keySize["SIZE_192"]: nbrRounds = 12
elif size == self.keySize["SIZE_256"]: nbrRounds = 14
else: return None
# the expanded keySize
expandedKeySize = 16*(nbrRounds+1)
# Set the block values, for the block:
# a0,0 a0,1 a0,2 a0,3
# a1,0 a1,1 a1,2 a1,3
# a2,0 a2,1 a2,2 a2,3
# a3,0 a3,1 a3,2 a3,3
# the mapping order is a0,0 a1,0 a2,0 a3,0 a0,1 a1,1 ... a2,3 a3,3
#
# iterate over the columns
for i in range(4):
# iterate over the rows
for j in range(4):
block[(i+(j*4))] = iput[(i*4)+j]
# expand the key into an 176, 208, 240 bytes key
# the expanded key
expandedKey = self.expandKey(key, size, expandedKeySize)
# encrypt the block using the expandedKey
block = self.aes_main(block, expandedKey, nbrRounds)
# unmap the block again into the output
for k in range(4):
# iterate over the rows
for l in range(4):
output[(k*4)+l] = block[(k+(l*4))]
return output
# decrypts a 128 bit input block against the given key of size specified
def decrypt(self, iput, key, size):
output = [0] * 16
# the number of rounds
nbrRounds = 0
# the 128 bit block to decode
block = [0] * 16
# set the number of rounds
if size == self.keySize["SIZE_128"]: nbrRounds = 10
elif size == self.keySize["SIZE_192"]: nbrRounds = 12
elif size == self.keySize["SIZE_256"]: nbrRounds = 14
else: return None
# the expanded keySize
expandedKeySize = 16*(nbrRounds+1)
# Set the block values, for the block:
# a0,0 a0,1 a0,2 a0,3
# a1,0 a1,1 a1,2 a1,3
# a2,0 a2,1 a2,2 a2,3
# a3,0 a3,1 a3,2 a3,3
# the mapping order is a0,0 a1,0 a2,0 a3,0 a0,1 a1,1 ... a2,3 a3,3
# iterate over the columns
for i in range(4):
# iterate over the rows
for j in range(4):
block[(i+(j*4))] = iput[(i*4)+j]
# expand the key into an 176, 208, 240 bytes key
expandedKey = self.expandKey(key, size, expandedKeySize)
# decrypt the block using the expandedKey
block = self.aes_invMain(block, expandedKey, nbrRounds)
# unmap the block again into the output
for k in range(4):
# iterate over the rows
for l in range(4):
output[(k*4)+l] = block[(k+(l*4))]
return output
class AESModeOfOperation(object):
aes = AES()
# structure of supported modes of operation
modeOfOperation = dict(OFB=0, CFB=1, CBC=2)
# converts a 16 character string into a number array
def convertString(self, string, start, end, mode):
if end - start > 16: end = start + 16
if mode == self.modeOfOperation["CBC"]: ar = [0] * 16
else: ar = []
i = start
j = 0
while len(ar) < end - start:
ar.append(0)
while i < end:
ar[j] = ord(string[i])
j += 1
i += 1
return ar
# Mode of Operation Encryption
# stringIn - Input String
# mode - mode of type modeOfOperation
# hexKey - a hex key of the bit length size
# size - the bit length of the key
# hexIV - the 128 bit hex Initilization Vector
def encrypt(self, stringIn, mode, key, size, IV):
if len(key) % size:
return None
if len(IV) % 16:
return None
# the AES input/output
plaintext = []
iput = [0] * 16
output = []
ciphertext = [0] * 16
# the output cipher string
cipherOut = []
# char firstRound
firstRound = True
if stringIn != None:
for j in range(int(math.ceil(float(len(stringIn))/16))):
start = j*16
end = j*16+16
if end > len(stringIn):
end = len(stringIn)
plaintext = self.convertString(stringIn, start, end, mode)
# print 'PT@%s:%s' % (j, plaintext)
if mode == self.modeOfOperation["CFB"]:
if firstRound:
output = self.aes.encrypt(IV, key, size)
firstRound = False
else:
output = self.aes.encrypt(iput, key, size)
for i in range(16):
if len(plaintext)-1 < i:
ciphertext[i] = 0 ^ output[i]
elif len(output)-1 < i:
ciphertext[i] = plaintext[i] ^ 0
elif len(plaintext)-1 < i and len(output) < i:
ciphertext[i] = 0 ^ 0
else:
ciphertext[i] = plaintext[i] ^ output[i]
for k in range(end-start):
cipherOut.append(ciphertext[k])
iput = ciphertext
elif mode == self.modeOfOperation["OFB"]:
if firstRound:
output = self.aes.encrypt(IV, key, size)
firstRound = False
else:
output = self.aes.encrypt(iput, key, size)
for i in range(16):
if len(plaintext)-1 < i:
ciphertext[i] = 0 ^ output[i]
elif len(output)-1 < i:
ciphertext[i] = plaintext[i] ^ 0
elif len(plaintext)-1 < i and len(output) < i:
ciphertext[i] = 0 ^ 0
else:
ciphertext[i] = plaintext[i] ^ output[i]
for k in range(end-start):
cipherOut.append(ciphertext[k])
iput = output
elif mode == self.modeOfOperation["CBC"]:
for i in range(16):
if firstRound:
iput[i] = plaintext[i] ^ IV[i]
else:
iput[i] = plaintext[i] ^ ciphertext[i]
# print 'IP@%s:%s' % (j, iput)
firstRound = False
ciphertext = self.aes.encrypt(iput, key, size)
# always 16 bytes because of the padding for CBC
for k in range(16):
cipherOut.append(ciphertext[k])
return mode, len(stringIn), cipherOut
# Mode of Operation Decryption
# cipherIn - Encrypted String
# originalsize - The unencrypted string length - required for CBC
# mode - mode of type modeOfOperation
# key - a number array of the bit length size
# size - the bit length of the key
# IV - the 128 bit number array Initilization Vector
def decrypt(self, cipherIn, originalsize, mode, key, size, IV):
# cipherIn = unescCtrlChars(cipherIn)
if len(key) % size:
return None
if len(IV) % 16:
return None
# the AES input/output
ciphertext = []
iput = []
output = []
plaintext = [0] * 16
# the output plain text string
stringOut = ''
# char firstRound
firstRound = True
if cipherIn != None:
for j in range(int(math.ceil(float(len(cipherIn))/16))):
start = j*16
end = j*16+16
if j*16+16 > len(cipherIn):
end = len(cipherIn)
ciphertext = cipherIn[start:end]
if mode == self.modeOfOperation["CFB"]:
if firstRound:
output = self.aes.encrypt(IV, key, size)
firstRound = False
else:
output = self.aes.encrypt(iput, key, size)
for i in range(16):
if len(output)-1 < i:
plaintext[i] = 0 ^ ciphertext[i]
elif len(ciphertext)-1 < i:
plaintext[i] = output[i] ^ 0
elif len(output)-1 < i and len(ciphertext) < i:
plaintext[i] = 0 ^ 0
else:
plaintext[i] = output[i] ^ ciphertext[i]
for k in range(end-start):
stringOut += chr(plaintext[k])
iput = ciphertext
elif mode == self.modeOfOperation["OFB"]:
if firstRound:
output = self.aes.encrypt(IV, key, size)
firstRound = False
else:
output = self.aes.encrypt(iput, key, size)
for i in range(16):
if len(output)-1 < i:
plaintext[i] = 0 ^ ciphertext[i]
elif len(ciphertext)-1 < i:
plaintext[i] = output[i] ^ 0
elif len(output)-1 < i and len(ciphertext) < i:
plaintext[i] = 0 ^ 0
else:
plaintext[i] = output[i] ^ ciphertext[i]
for k in range(end-start):
stringOut += chr(plaintext[k])
iput = output
elif mode == self.modeOfOperation["CBC"]:
output = self.aes.decrypt(ciphertext, key, size)
for i in range(16):
if firstRound:
plaintext[i] = IV[i] ^ output[i]
else:
plaintext[i] = iput[i] ^ output[i]
firstRound = False
if originalsize is not None and originalsize < end:
for k in range(originalsize-start):
stringOut += chr(plaintext[k])
else:
for k in range(end-start):
stringOut += chr(plaintext[k])
iput = ciphertext
return stringOut
######################
# end of aes.py code #
######################
###################################
# pywallet crypter implementation #
###################################
crypter = None
try:
from Crypto.Cipher import AES
crypter = 'pycrypto'
except:
pass
class Crypter_pycrypto( object ):
def SetKeyFromPassphrase(self, vKeyData, vSalt, nDerivIterations, nDerivationMethod):
if nDerivationMethod != 0:
return 0
data = vKeyData + vSalt
for i in xrange(nDerivIterations):
data = hashlib.sha512(data).digest()
self.SetKey(data[0:32])
self.SetIV(data[32:32+16])
return len(data)
def SetKey(self, key):
self.chKey = key
def SetIV(self, iv):
self.chIV = iv[0:16]
def Encrypt(self, data):
return AES.new(self.chKey,AES.MODE_CBC,self.chIV).encrypt(data)[0:32]
def Decrypt(self, data):
return AES.new(self.chKey,AES.MODE_CBC,self.chIV).decrypt(data)[0:32]
try:
if not crypter:
import ctypes
import ctypes.util
ssl = ctypes.cdll.LoadLibrary (ctypes.util.find_library ('ssl') or 'libeay32')
crypter = 'ssl'
except:
pass
class Crypter_ssl(object):
def __init__(self):
self.chKey = ctypes.create_string_buffer (32)
self.chIV = ctypes.create_string_buffer (16)
def SetKeyFromPassphrase(self, vKeyData, vSalt, nDerivIterations, nDerivationMethod):
if nDerivationMethod != 0:
return 0
strKeyData = ctypes.create_string_buffer (vKeyData)
chSalt = ctypes.create_string_buffer (vSalt)
return ssl.EVP_BytesToKey(ssl.EVP_aes_256_cbc(), ssl.EVP_sha512(), chSalt, strKeyData,
len(vKeyData), nDerivIterations, ctypes.byref(self.chKey), ctypes.byref(self.chIV))
def SetKey(self, key):
self.chKey = ctypes.create_string_buffer(key)
def SetIV(self, iv):
self.chIV = ctypes.create_string_buffer(iv)
def Encrypt(self, data):
buf = ctypes.create_string_buffer(len(data) + 16)
written = ctypes.c_int(0)
final = ctypes.c_int(0)
ctx = ssl.EVP_CIPHER_CTX_new()
ssl.EVP_CIPHER_CTX_init(ctx)
ssl.EVP_EncryptInit_ex(ctx, ssl.EVP_aes_256_cbc(), None, self.chKey, self.chIV)
ssl.EVP_EncryptUpdate(ctx, buf, ctypes.byref(written), data, len(data))
output = buf.raw[:written.value]
ssl.EVP_EncryptFinal_ex(ctx, buf, ctypes.byref(final))
output += buf.raw[:final.value]
return output
def Decrypt(self, data):
buf = ctypes.create_string_buffer(len(data) + 16)
written = ctypes.c_int(0)
final = ctypes.c_int(0)
ctx = ssl.EVP_CIPHER_CTX_new()
ssl.EVP_CIPHER_CTX_init(ctx)
ssl.EVP_DecryptInit_ex(ctx, ssl.EVP_aes_256_cbc(), None, self.chKey, self.chIV)
ssl.EVP_DecryptUpdate(ctx, buf, ctypes.byref(written), data, len(data))
output = buf.raw[:written.value]
ssl.EVP_DecryptFinal_ex(ctx, buf, ctypes.byref(final))
output += buf.raw[:final.value]
return output
class Crypter_pure(object):
def __init__(self):
self.m = AESModeOfOperation()
self.cbc = self.m.modeOfOperation["CBC"]
self.sz = self.m.aes.keySize["SIZE_256"]
def SetKeyFromPassphrase(self, vKeyData, vSalt, nDerivIterations, nDerivationMethod):
if nDerivationMethod != 0:
return 0
data = vKeyData + vSalt
for i in xrange(nDerivIterations):
data = hashlib.sha512(data).digest()
self.SetKey(data[0:32])
self.SetIV(data[32:32+16])
return len(data)
def SetKey(self, key):
self.chKey = [ord(i) for i in key]
def SetIV(self, iv):
self.chIV = [ord(i) for i in iv]
def Encrypt(self, data):
mode, size, cypher = self.m.encrypt(data, self.cbc, self.chKey, self.sz, self.chIV)
return ''.join(map(chr, cypher))
def Decrypt(self, data):
chData = [ord(i) for i in data]
return self.m.decrypt(chData, self.sz, self.cbc, self.chKey, self.sz, self.chIV)
if crypter == 'pycrypto':
crypter = Crypter_pycrypto()
elif crypter == 'ssl':
crypter = Crypter_ssl()
else:
crypter = Crypter_pure()
logging.warning("pycrypto or libssl not found, decryption may be slow")
##########################################
# end of pywallet crypter implementation #
##########################################
# secp256k1
_p = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2FL
_r = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141L
_b = 0x0000000000000000000000000000000000000000000000000000000000000007L
_a = 0x0000000000000000000000000000000000000000000000000000000000000000L
_Gx = 0x79BE667EF9DCBBAC55A06295CE870B07029BFCDB2DCE28D959F2815B16F81798L
_Gy = 0x483ada7726a3c4655da4fbfc0e1108a8fd17b448a68554199c47d08ffb10d4b8L
try:
import ecdsa
from ecdsa import der
curve_secp256k1 = ecdsa.ellipticcurve.CurveFp (_p, _a, _b)
generator_secp256k1 = g = ecdsa.ellipticcurve.Point (curve_secp256k1, _Gx, _Gy, _r)
randrange = random.SystemRandom().randrange
secp256k1 = ecdsa.curves.Curve ( "secp256k1", curve_secp256k1, generator_secp256k1, (1, 3, 132, 0, 10) )
ecdsa.curves.curves.append (secp256k1)
except:
missing_dep.append('ecdsa')
# python-ecdsa code (EC_KEY implementation)
class CurveFp( object ):
def __init__( self, p, a, b ):
self.__p = p
self.__a = a
self.__b = b
def p( self ):
return self.__p
def a( self ):
return self.__a
def b( self ):
return self.__b
def contains_point( self, x, y ):
return ( y * y - ( x * x * x + self.__a * x + self.__b ) ) % self.__p == 0
class Point( object ):
def __init__( self, curve, x, y, order = None ):
self.__curve = curve
self.__x = x
self.__y = y
self.__order = order
if self.__curve: assert self.__curve.contains_point( x, y )
if order: assert self * order == INFINITY
def __add__( self, other ):
if other == INFINITY: return self
if self == INFINITY: return other
assert self.__curve == other.__curve
if self.__x == other.__x:
if ( self.__y + other.__y ) % self.__curve.p() == 0:
return INFINITY
else:
return self.double()
p = self.__curve.p()
l = ( ( other.__y - self.__y ) * \
inverse_mod( other.__x - self.__x, p ) ) % p
x3 = ( l * l - self.__x - other.__x ) % p
y3 = ( l * ( self.__x - x3 ) - self.__y ) % p
return Point( self.__curve, x3, y3 )
def __mul__( self, other ):
def leftmost_bit( x ):
assert x > 0
result = 1L
while result <= x: result = 2 * result
return result / 2
e = other
if self.__order: e = e % self.__order
if e == 0: return INFINITY
if self == INFINITY: return INFINITY
assert e > 0
e3 = 3 * e
negative_self = Point( self.__curve, self.__x, -self.__y, self.__order )
i = leftmost_bit( e3 ) / 2
result = self
while i > 1:
result = result.double()
if ( e3 & i ) != 0 and ( e & i ) == 0: result = result + self
if ( e3 & i ) == 0 and ( e & i ) != 0: result = result + negative_self
i = i / 2
return result
def __rmul__( self, other ):
return self * other
def __str__( self ):
if self == INFINITY: return "infinity"
return "(%d,%d)" % ( self.__x, self.__y )
def double( self ):
if self == INFINITY:
return INFINITY
p = self.__curve.p()
a = self.__curve.a()
l = ( ( 3 * self.__x * self.__x + a ) * \
inverse_mod( 2 * self.__y, p ) ) % p
x3 = ( l * l - 2 * self.__x ) % p
y3 = ( l * ( self.__x - x3 ) - self.__y ) % p
return Point( self.__curve, x3, y3 )
def x( self ):
return self.__x
def y( self ):
return self.__y
def curve( self ):
return self.__curve
def order( self ):
return self.__order
INFINITY = Point( None, None, None )
def inverse_mod( a, m ):
if a < 0 or m <= a: a = a % m
c, d = a, m
uc, vc, ud, vd = 1, 0, 0, 1
while c != 0:
q, c, d = divmod( d, c ) + ( c, )
uc, vc, ud, vd = ud - q*uc, vd - q*vc, uc, vc
assert d == 1
if ud > 0: return ud
else: return ud + m
class Signature( object ):
def __init__( self, r, s ):
self.r = r
self.s = s
class Public_key( object ):
def __init__( self, generator, point ):
self.curve = generator.curve()
self.generator = generator
self.point = point
n = generator.order()
if not n:
raise RuntimeError, "Generator point must have order."
if not n * point == INFINITY:
raise RuntimeError, "Generator point order is bad."
if point.x() < 0 or n <= point.x() or point.y() < 0 or n <= point.y():
raise RuntimeError, "Generator point has x or y out of range."
def verifies( self, hash, signature ):
G = self.generator
n = G.order()
r = signature.r
s = signature.s
if r < 1 or r > n-1: return False
if s < 1 or s > n-1: return False
c = inverse_mod( s, n )
u1 = ( hash * c ) % n
u2 = ( r * c ) % n
xy = u1 * G + u2 * self.point
v = xy.x() % n
return v == r
class Private_key( object ):
def __init__( self, public_key, secret_multiplier ):
self.public_key = public_key
self.secret_multiplier = secret_multiplier
def der( self ):
hex_der_key = '06052b8104000a30740201010420' + \
'%064x' % self.secret_multiplier + \
'a00706052b8104000aa14403420004' + \
'%064x' % self.public_key.point.x() + \
'%064x' % self.public_key.point.y()
return hex_der_key.decode('hex')
def sign( self, hash, random_k ):
G = self.public_key.generator
n = G.order()
k = random_k % n
p1 = k * G
r = p1.x()
if r == 0: raise RuntimeError, "amazingly unlucky random number r"
s = ( inverse_mod( k, n ) * \
( hash + ( self.secret_multiplier * r ) % n ) ) % n
if s == 0: raise RuntimeError, "amazingly unlucky random number s"
return Signature( r, s )
class EC_KEY(object):
def __init__( self, secret ):
curve = CurveFp( _p, _a, _b )
generator = Point( curve, _Gx, _Gy, _r )
self.pubkey = Public_key( generator, generator * secret )
self.privkey = Private_key( self.pubkey, secret )
self.secret = secret
# end of python-ecdsa code
# pywallet openssl private key implementation
def i2d_ECPrivateKey(pkey, compressed=False):#, crypted=True):
part3='a081a53081a2020101302c06072a8648ce3d0101022100' # for uncompressed keys
if compressed:
if True:#not crypted: ## Bitcoin accepts both part3's for crypted wallets...
part3='a08185308182020101302c06072a8648ce3d0101022100' # for compressed keys
key = '3081d30201010420' + \
'%064x' % pkey.secret + \
part3 + \
'%064x' % _p + \
'3006040100040107042102' + \
'%064x' % _Gx + \
'022100' + \
'%064x' % _r + \
'020101a124032200'
else:
key = '308201130201010420' + \
'%064x' % pkey.secret + \
part3 + \
'%064x' % _p + \
'3006040100040107044104' + \
'%064x' % _Gx + \
'%064x' % _Gy + \
'022100' + \
'%064x' % _r + \
'020101a144034200'
return key.decode('hex') + i2o_ECPublicKey(pkey, compressed)
def i2o_ECPublicKey(pkey, compressed=False):
# public keys are 65 bytes long (520 bits)
# 0x04 + 32-byte X-coordinate + 32-byte Y-coordinate
# 0x00 = point at infinity, 0x02 and 0x03 = compressed, 0x04 = uncompressed
# compressed keys: <sign> <x> where <sign> is 0x02 if y is even and 0x03 if y is odd
if compressed:
if pkey.pubkey.point.y() & 1:
key = '03' + '%064x' % pkey.pubkey.point.x()
else:
key = '02' + '%064x' % pkey.pubkey.point.x()
else:
key = '04' + \
'%064x' % pkey.pubkey.point.x() + \
'%064x' % pkey.pubkey.point.y()
return key.decode('hex')
# bitcointools hashes and base58 implementation
def hash_160(public_key):
md = hashlib.new('ripemd160')
md.update(hashlib.sha256(public_key).digest())
return md.digest()
def public_key_to_bc_address(public_key):
h160 = hash_160(public_key)
return hash_160_to_bc_address(h160)
def hash_160_to_bc_address(h160):
vh160 = chr(addrtype) + h160
h = Hash(vh160)
addr = vh160 + h[0:4]
return b58encode(addr)
def bc_address_to_hash_160(addr):
bytes = b58decode(addr, 25)
return bytes[1:21]
__b58chars = '123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz'
__b58base = len(__b58chars)
def b58encode(v):
""" encode v, which is a string of bytes, to base58.
"""
long_value = 0L
for (i, c) in enumerate(v[::-1]):
long_value += (256**i) * ord(c)
result = ''
while long_value >= __b58base:
div, mod = divmod(long_value, __b58base)
result = __b58chars[mod] + result
long_value = div
result = __b58chars[long_value] + result
# Bitcoin does a little leading-zero-compression:
# leading 0-bytes in the input become leading-1s
nPad = 0
for c in v:
if c == '\0': nPad += 1
else: break
return (__b58chars[0]*nPad) + result
def b58decode(v, length):
""" decode v into a string of len bytes
"""
long_value = 0L
for (i, c) in enumerate(v[::-1]):
long_value += __b58chars.find(c) * (__b58base**i)
result = ''
while long_value >= 256:
div, mod = divmod(long_value, 256)
result = chr(mod) + result
long_value = div
result = chr(long_value) + result
nPad = 0
for c in v:
if c == __b58chars[0]: nPad += 1
else: break
result = chr(0)*nPad + result
if length is not None and len(result) != length:
return None
return result
# end of bitcointools base58 implementation
# address handling code
def long_hex(bytes):
return bytes.encode('hex_codec')
def Hash(data):
return hashlib.sha256(hashlib.sha256(data).digest()).digest()
def EncodeBase58Check(secret):
hash = Hash(secret)
return b58encode(secret + hash[0:4])
def DecodeBase58Check(sec):
vchRet = b58decode(sec, None)
secret = vchRet[0:-4]
csum = vchRet[-4:]
hash = Hash(secret)
cs32 = hash[0:4]
if cs32 != csum:
return None
else:
return secret
def str_to_long(b):
res = 0
pos = 1
for a in reversed(b):
res += ord(a) * pos
pos *= 256
return res
def PrivKeyToSecret(privkey):
if len(privkey) == 279:
return privkey[9:9+32]
else:
return privkey[8:8+32]
def SecretToASecret(secret, compressed=False):
vchIn = chr((addrtype+128)&255) + secret
if compressed: vchIn += '\01'
return EncodeBase58Check(vchIn)
def ASecretToSecret(sec):
vch = DecodeBase58Check(sec)
if vch and vch[0] == chr((addrtype+128)&255):
return vch[1:]
else:
return False
def regenerate_key(sec):
b = ASecretToSecret(sec)
if not b:
return False
b = b[0:32]
secret = int('0x' + b.encode('hex'), 16)
return EC_KEY(secret)
def GetPubKey(pkey, compressed=False):
return i2o_ECPublicKey(pkey, compressed)
def GetPrivKey(pkey, compressed=False):
return i2d_ECPrivateKey(pkey, compressed)
def GetSecret(pkey):
return ('%064x' % pkey.secret).decode('hex')
def is_compressed(sec):
b = ASecretToSecret(sec)
return len(b) == 33
# bitcointools wallet.dat handling code
def create_env(db_dir):
db_env = DBEnv(0)
r = db_env.open(db_dir, (DB_CREATE|DB_INIT_LOCK|DB_INIT_LOG|DB_INIT_MPOOL|DB_INIT_TXN|DB_THREAD|DB_RECOVER))
return db_env
def parse_CAddress(vds):
d = {'ip':'0.0.0.0','port':0,'nTime': 0}
try:
d['nVersion'] = vds.read_int32()
d['nTime'] = vds.read_uint32()
d['nServices'] = vds.read_uint64()
d['pchReserved'] = vds.read_bytes(12)
d['ip'] = socket.inet_ntoa(vds.read_bytes(4))
d['port'] = vds.read_uint16()
except:
pass
return d
def deserialize_CAddress(d):
return d['ip']+":"+str(d['port'])
def parse_BlockLocator(vds):
d = { 'hashes' : [] }
nHashes = vds.read_compact_size()
for i in xrange(nHashes):
d['hashes'].append(vds.read_bytes(32))
return d
def deserialize_BlockLocator(d):
result = "Block Locator top: "+d['hashes'][0][::-1].encode('hex_codec')
return result
def parse_setting(setting, vds):
if setting[0] == "f": # flag (boolean) settings
return str(vds.read_boolean())
elif setting[0:4] == "addr": # CAddress
d = parse_CAddress(vds)
return deserialize_CAddress(d)
elif setting == "nTransactionFee":
return vds.read_int64()
elif setting == "nLimitProcessors":
return vds.read_int32()
return 'unknown setting'
class SerializationError(Exception):
""" Thrown when there's a problem deserializing or serializing """
def ts():
return int(time.mktime(datetime.now().timetuple()))
def check_postkeys(key, postkeys):
for i in postkeys:
if key[:len(i)] == i:
return True
return False
def one_element_in(a, string):
for i in a:
if i in string:
return True
return False
def first_read(device, size, prekeys, inc=10000):
t0 = ts()-1
try:
fd = os.open (device, os.O_RDONLY)
except:
print("Can't open %s, check the path or try as root"%device)
exit(0)
prekey = prekeys[0]
data = ""
i = 0
data = os.read (fd, i)
before_contained_key = False
contains_key = False
ranges = []
while i < int(size):
if i%(10*Mio) > 0 and i%(10*Mio) <= inc:
print("\n%.2f/%.2f Go"%(i/1e9, size/1e9))
t = ts()
speed = i/(t-t0)
ETAts = size/speed + t0
d = datetime.fromtimestamp(ETAts)
print(d.strftime(" ETA: %H:%M:%S"))
try:
data = os.read (fd, inc)
except Exception as exc:
os.lseek(fd, inc, os.SEEK_CUR)
print str(exc)
i += inc
continue
contains_key = one_element_in(prekeys, data)
if not before_contained_key and contains_key:
ranges.append(i)
if before_contained_key and not contains_key:
ranges.append(i)
before_contained_key = contains_key
i += inc
os.close (fd)
return ranges
def shrink_intervals(device, ranges, prekeys, inc=1000):
prekey = prekeys[0]
nranges = []
fd = os.open (device, os.O_RDONLY)
for j in range(len(ranges)/2):
before_contained_key = False
contains_key = False
bi = ranges[2*j]
bf = ranges[2*j+1]
mini_blocks = []
k = bi
while k <= bf + len(prekey) + 1:
mini_blocks.append(k)
k += inc
mini_blocks.append(k)
for k in range(len(mini_blocks)/2):
mini_blocks[2*k] -= len(prekey) +1
mini_blocks[2*k+1] += len(prekey) +1
bi = mini_blocks[2*k]
bf = mini_blocks[2*k+1]
os.lseek(fd, bi, 0)
data = os.read(fd, bf-bi+1)
contains_key = one_element_in(prekeys, data)
if not before_contained_key and contains_key:
nranges.append(bi)
if before_contained_key and not contains_key:
nranges.append(bi+len(prekey) +1+len(prekey) +1)
before_contained_key = contains_key
os.close (fd)
return nranges
def find_offsets(device, ranges, prekeys):
prekey = prekeys[0]
list_offsets = []
to_read = 0
fd = os.open (device, os.O_RDONLY)
for i in range(len(ranges)/2):
bi = ranges[2*i]-len(prekey)-1
os.lseek(fd, bi, 0)
bf = ranges[2*i+1]+len(prekey)+1
to_read += bf-bi+1
buf = ""
for j in range(len(prekey)):
buf += "\x00"
curs = bi
while curs <= bf:
data = os.read(fd, 1)
buf = buf[1:] + data
if buf in prekeys:
list_offsets.append(curs)
curs += 1
os.close (fd)
return [to_read, list_offsets]
def read_keys(device, list_offsets):
found_hexkeys = []
fd = os.open (device, os.O_RDONLY)
for offset in list_offsets:
os.lseek(fd, offset+1, 0)
data = os.read(fd, 40)
hexkey = data[1:33].encode('hex')
after_key = data[33:39].encode('hex')
if hexkey not in found_hexkeys and check_postkeys(after_key.decode('hex'), postkeys):
found_hexkeys.append(hexkey)
os.close (fd)
return found_hexkeys
def read_device_size(size):
if size[-2] == 'i':
unit = size[-3:]
value = float(size[:-3])
else:
unit = size[-2:]
value = float(size[:-2])
exec 'unit = %s' % unit
return int(value * unit)
def md5_2(a):
return hashlib.md5(a).digest()
def md5_file(nf):
fichier = file(nf, 'r').read()[:-1]
return md5_2(fichier)
def md5_onlinefile(add):
page = urllib.urlopen(add).read()
return md5_2(page)
class KEY:
def __init__ (self):
self.prikey = None
self.pubkey = None
def generate (self, secret=None):
if secret:
exp = int ('0x' + secret.encode ('hex'), 16)
self.prikey = ecdsa.SigningKey.from_secret_exponent (exp, curve=secp256k1)
else:
self.prikey = ecdsa.SigningKey.generate (curve=secp256k1)
self.pubkey = self.prikey.get_verifying_key()
return self.prikey.to_der()
def set_privkey (self, key):
if len(key) == 279:
seq1, rest = der.remove_sequence (key)
integer, rest = der.remove_integer (seq1)
octet_str, rest = der.remove_octet_string (rest)
tag1, cons1, rest, = der.remove_constructed (rest)
tag2, cons2, rest, = der.remove_constructed (rest)
point_str, rest = der.remove_bitstring (cons2)
self.prikey = ecdsa.SigningKey.from_string(octet_str, curve=secp256k1)
else:
self.prikey = ecdsa.SigningKey.from_der (key)
def set_pubkey (self, key):
key = key[1:]
self.pubkey = ecdsa.VerifyingKey.from_string (key, curve=secp256k1)
def get_privkey (self):
_p = self.prikey.curve.curve.p ()
_r = self.prikey.curve.generator.order ()
_Gx = self.prikey.curve.generator.x ()
_Gy = self.prikey.curve.generator.y ()
encoded_oid2 = der.encode_oid (*(1, 2, 840, 10045, 1, 1))
encoded_gxgy = "\x04" + ("%64x" % _Gx).decode('hex') + ("%64x" % _Gy).decode('hex')
param_sequence = der.encode_sequence (
ecdsa.der.encode_integer(1),
der.encode_sequence (
encoded_oid2,
der.encode_integer (_p),
),
der.encode_sequence (
der.encode_octet_string("\x00"),
der.encode_octet_string("\x07"),
),
der.encode_octet_string (encoded_gxgy),
der.encode_integer (_r),
der.encode_integer (1),
);
encoded_vk = "\x00\x04" + self.pubkey.to_string ()
return der.encode_sequence (
der.encode_integer (1),
der.encode_octet_string (self.prikey.to_string ()),
der.encode_constructed (0, param_sequence),
der.encode_constructed (1, der.encode_bitstring (encoded_vk)),
)
def get_pubkey (self):
return "\x04" + self.pubkey.to_string()
def sign (self, hash):
sig = self.prikey.sign_digest (hash, sigencode=ecdsa.util.sigencode_der)
return sig.encode('hex')
def verify (self, hash, sig):
return self.pubkey.verify_digest (sig, hash, sigdecode=ecdsa.util.sigdecode_der)
def bool_to_int(b):
if b:
return 1
return 0
class BCDataStream(object):
def __init__(self):
self.input = None
self.read_cursor = 0
def clear(self):
self.input = None
self.read_cursor = 0
def write(self, bytes): # Initialize with string of bytes
if self.input is None:
self.input = bytes
else:
self.input += bytes
def map_file(self, file, start): # Initialize with bytes from file
self.input = mmap.mmap(file.fileno(), 0, access=mmap.ACCESS_READ)
self.read_cursor = start
def seek_file(self, position):
self.read_cursor = position
def close_file(self):
self.input.close()
def read_string(self):
# Strings are encoded depending on length:
# 0 to 252 : 1-byte-length followed by bytes (if any)
# 253 to 65,535 : byte'253' 2-byte-length followed by bytes
# 65,536 to 4,294,967,295 : byte '254' 4-byte-length followed by bytes
# ... and the Bitcoin client is coded to understand:
# greater than 4,294,967,295 : byte '255' 8-byte-length followed by bytes of string
# ... but I don't think it actually handles any strings that big.
if self.input is None:
raise SerializationError("call write(bytes) before trying to deserialize")
try:
length = self.read_compact_size()
except IndexError:
raise SerializationError("attempt to read past end of buffer")
return self.read_bytes(length)
def write_string(self, string):
# Length-encoded as with read-string
self.write_compact_size(len(string))
self.write(string)
def read_bytes(self, length):
try:
result = self.input[self.read_cursor:self.read_cursor+length]
self.read_cursor += length
return result
except IndexError:
raise SerializationError("attempt to read past end of buffer")
return ''
def read_boolean(self): return self.read_bytes(1)[0] != chr(0)
def read_int16(self): return self._read_num('<h')
def read_uint16(self): return self._read_num('<H')
def read_int32(self): return self._read_num('<i')
def read_uint32(self): return self._read_num('<I')
def read_int64(self): return self._read_num('<q')
def read_uint64(self): return self._read_num('<Q')
def write_boolean(self, val): return self.write(chr(bool_to_int(val)))
def write_int16(self, val): return self._write_num('<h', val)
def write_uint16(self, val): return self._write_num('<H', val)
def write_int32(self, val): return self._write_num('<i', val)
def write_uint32(self, val): return self._write_num('<I', val)
def write_int64(self, val): return self._write_num('<q', val)
def write_uint64(self, val): return self._write_num('<Q', val)
def read_compact_size(self):
size = ord(self.input[self.read_cursor])
self.read_cursor += 1
if size == 253:
size = self._read_num('<H')
elif size == 254:
size = self._read_num('<I')
elif size == 255:
size = self._read_num('<Q')
return size
def write_compact_size(self, size):
if size < 0:
raise SerializationError("attempt to write size < 0")
elif size < 253:
self.write(chr(size))
elif size < 2**16:
self.write('\xfd')
self._write_num('<H', size)
elif size < 2**32:
self.write('\xfe')
self._write_num('<I', size)
elif size < 2**64:
self.write('\xff')
self._write_num('<Q', size)
def _read_num(self, format):
(i,) = struct.unpack_from(format, self.input, self.read_cursor)
self.read_cursor += struct.calcsize(format)
return i
def _write_num(self, format, num):
s = struct.pack(format, num)
self.write(s)
def open_wallet(db_env, walletfile, writable=False):
db = DB(db_env)
if writable:
DB_TYPEOPEN = DB_CREATE
else:
DB_TYPEOPEN = DB_RDONLY
flags = DB_THREAD | DB_TYPEOPEN
try:
r = db.open(walletfile, "main", DB_BTREE, flags)
except DBError:
r = True
if r is not None:
logging.error("Couldn't open wallet.dat/main. Try quitting Bitcoin and running this again.")
sys.exit(1)
return db
def inversetxid(txid):
if len(txid) is not 64:
print("Bad txid")
return "CORRUPTEDTXID:"+txid
# exit(0)
new_txid = ""
for i in range(32):
new_txid += txid[62-2*i];
new_txid += txid[62-2*i+1];
return new_txid
def parse_wallet(db, item_callback):
kds = BCDataStream()
vds = BCDataStream()
def parse_TxIn(vds):
d = {}
d['prevout_hash'] = vds.read_bytes(32).encode('hex')
d['prevout_n'] = vds.read_uint32()
d['scriptSig'] = vds.read_bytes(vds.read_compact_size()).encode('hex')
d['sequence'] = vds.read_uint32()
return d
def parse_TxOut(vds):
d = {}
d['value'] = vds.read_int64()/1e8
d['scriptPubKey'] = vds.read_bytes(vds.read_compact_size()).encode('hex')
return d
for (key, value) in db.items():
d = { }
kds.clear(); kds.write(key)
vds.clear(); vds.write(value)
type = kds.read_string()
d["__key__"] = key
d["__value__"] = value
d["__type__"] = type
try:
if type == "tx":
d["tx_id"] = inversetxid(kds.read_bytes(32).encode('hex_codec'))
start = vds.read_cursor
d['version'] = vds.read_int32()
n_vin = vds.read_compact_size()
d['txIn'] = []
for i in xrange(n_vin):
d['txIn'].append(parse_TxIn(vds))
n_vout = vds.read_compact_size()
d['txOut'] = []
for i in xrange(n_vout):
d['txOut'].append(parse_TxOut(vds))
d['lockTime'] = vds.read_uint32()
d['tx'] = vds.input[start:vds.read_cursor].encode('hex_codec')
d['txv'] = value.encode('hex_codec')
d['txk'] = key.encode('hex_codec')
elif type == "name":
d['hash'] = kds.read_string()
d['name'] = vds.read_string()
elif type == "version":
d['version'] = vds.read_uint32()
elif type == "minversion":
d['minversion'] = vds.read_uint32()
elif type == "setting":
d['setting'] = kds.read_string()
d['value'] = parse_setting(d['setting'], vds)
elif type == "key":
d['public_key'] = kds.read_bytes(kds.read_compact_size())
d['private_key'] = vds.read_bytes(vds.read_compact_size())
elif type == "wkey":
d['public_key'] = kds.read_bytes(kds.read_compact_size())
d['private_key'] = vds.read_bytes(vds.read_compact_size())
d['created'] = vds.read_int64()
d['expires'] = vds.read_int64()
d['comment'] = vds.read_string()
elif type == "defaultkey":
d['key'] = vds.read_bytes(vds.read_compact_size())
elif type == "pool":
d['n'] = kds.read_int64()
d['nVersion'] = vds.read_int32()
d['nTime'] = vds.read_int64()
d['public_key'] = vds.read_bytes(vds.read_compact_size())
elif type == "acc":
d['account'] = kds.read_string()
d['nVersion'] = vds.read_int32()
d['public_key'] = vds.read_bytes(vds.read_compact_size())
elif type == "acentry":
d['account'] = kds.read_string()
d['n'] = kds.read_uint64()
d['nVersion'] = vds.read_int32()
d['nCreditDebit'] = vds.read_int64()
d['nTime'] = vds.read_int64()
d['otherAccount'] = vds.read_string()
d['comment'] = vds.read_string()
elif type == "bestblock":
d['nVersion'] = vds.read_int32()
d.update(parse_BlockLocator(vds))
elif type == "ckey":
d['public_key'] = kds.read_bytes(kds.read_compact_size())
d['encrypted_private_key'] = vds.read_bytes(vds.read_compact_size())
elif type == "mkey":
d['nID'] = kds.read_uint32()
d['encrypted_key'] = vds.read_string()
d['salt'] = vds.read_string()
d['nDerivationMethod'] = vds.read_uint32()
d['nDerivationIterations'] = vds.read_uint32()
d['otherParams'] = vds.read_string()
item_callback(type, d)
except Exception, e:
traceback.print_exc()
print("ERROR parsing wallet.dat, type %s" % type)
print("key data: %s"%key)
print("key data in hex: %s"%key.encode('hex_codec'))
print("value data in hex: %s"%value.encode('hex_codec'))
sys.exit(1)
def delete_from_wallet(db_env, walletfile, typedel, keydel):
db = open_wallet(db_env, walletfile, True)
kds = BCDataStream()
vds = BCDataStream()
deleted_items = 0
for (key, value) in db.items():
kds.clear(); kds.write(key)
vds.clear(); vds.write(value)
type = kds.read_string()
if typedel == "tx":
if type == "tx":
if keydel == inversetxid(kds.read_bytes(32).encode('hex_codec')) or keydel == "all":
db.delete(key)
deleted_items+=1
elif typedel == "key":
if type == "key":
if keydel == public_key_to_bc_address(kds.read_bytes(kds.read_compact_size())):
db.delete(key)
deleted_items+=1
elif type == "pool":
vds.read_int32()
vds.read_int64()
if keydel == public_key_to_bc_address(vds.read_bytes(vds.read_compact_size())):
db.delete(key)
deleted_items+=1
elif type == "name":
if keydel == kds.read_string():
db.delete(key)
deleted_items+=1
db.close()
return deleted_items
def merge_keys_lists(la, lb):
lr={}
llr=[]
for k in la:
lr[k[0]]=k[1]
for k in lb:
if k[0] in lr.keys():
lr[k[0]]=lr[k[0]]+" / "+k[1]
else:
lr[k[0]]=k[1]
for k,j in lr.items():
llr.append([k,j])
return llr
def merge_wallets(wadir, wa, wbdir, wb, wrdir, wr, passphrase_a, passphrase_b, passphrase_r):
global passphrase
passphrase_LAST=passphrase
#Read Wallet 1
passphrase=passphrase_a
dba_env = create_env(wadir)
crypted_a = read_wallet(json_db, dba_env, wa, True, True, "", None)['crypted']
list_keys_a=[]
for i in json_db['keys']:
try:
label=i['label']
except:
label="#Reserve"
try:
list_keys_a.append([i['secret'], label])
except:
pass
if len(list_keys_a)==0:
return [False, "Something went wrong with the first wallet."]
#Read Wallet 2
passphrase=passphrase_b
dbb_env = create_env(wbdir)
crypted_b = read_wallet(json_db, dbb_env, wb, True, True, "", None)['crypted']
list_keys_b=[]
for i in json_db['keys']:
try:
label=i['label']
except:
label="#Reserve"
try:
list_keys_b.append([i['secret'], label])
except:
pass
if len(list_keys_b)==0:
return [False, "Something went wrong with the second wallet."]
m=merge_keys_lists(list_keys_a,list_keys_b)
#Create new wallet
dbr_env = create_env(wrdir)
create_new_wallet(dbr_env, wr, 80100)
dbr = open_wallet(dbr_env, wr, True)
update_wallet(dbr, 'minversion', { 'minversion' : 60000})
if len(passphrase_r)>0:
NPP_salt=random_string(16).decode('hex')
NPP_rounds=int(50000+random.random()*20000)
NPP_method=0
NPP_MK=random_string(64).decode('hex')
crypter.SetKeyFromPassphrase(passphrase_r, NPP_salt, NPP_rounds, NPP_method)
NPP_EMK = crypter.Encrypt(NPP_MK)
update_wallet(dbr, 'mkey', {
"encrypted_key": NPP_EMK,
'nDerivationIterations' : NPP_rounds,
'nDerivationMethod' : NPP_method,
'nID' : 1,
'otherParams' : ''.decode('hex'),
"salt": NPP_salt
})
dbr.close()
t='\n'.join(map(lambda x:';'.join(x), m))
passphrase=passphrase_r
global global_merging_message
global_merging_message=["Merging...","Merging..."]
thread.start_new_thread(import_csv_keys, ("\x00"+t, wrdir, wr,))
t=""
passphrase=passphrase_LAST
return [True]
def random_string(l, alph="0123456789abcdef"):
r=""
la=len(alph)
for i in range(l):
r+=alph[int(la*(random.random()))]
return r
def update_wallet(db, type, data):
"""Write a single item to the wallet.
db must be open with writable=True.
type and data are the type code and data dictionary as parse_wallet would
give to item_callback.
data's __key__, __value__ and __type__ are ignored; only the primary data
fields are used.
"""
d = data
kds = BCDataStream()
vds = BCDataStream()
# Write the type code to the key
kds.write_string(type)
vds.write("") # Ensure there is something
try:
if type == "tx":
# raise NotImplementedError("Writing items of type 'tx'")
kds.write(d['txi'][6:].decode('hex_codec'))
vds.write(d['txv'].decode('hex_codec'))
elif type == "name":
kds.write_string(d['hash'])
vds.write_string(d['name'])
elif type == "version":
vds.write_uint32(d['version'])
elif type == "minversion":
vds.write_uint32(d['minversion'])
elif type == "setting":
raise NotImplementedError("Writing items of type 'setting'")
kds.write_string(d['setting'])
#d['value'] = parse_setting(d['setting'], vds)
elif type == "key":
kds.write_string(d['public_key'])
vds.write_string(d['private_key'])
elif type == "wkey":
kds.write_string(d['public_key'])
vds.write_string(d['private_key'])
vds.write_int64(d['created'])
vds.write_int64(d['expires'])
vds.write_string(d['comment'])
elif type == "defaultkey":
vds.write_string(d['key'])
elif type == "pool":
kds.write_int64(d['n'])
vds.write_int32(d['nVersion'])
vds.write_int64(d['nTime'])
vds.write_string(d['public_key'])
elif type == "acc":
kds.write_string(d['account'])
vds.write_int32(d['nVersion'])
vds.write_string(d['public_key'])
elif type == "acentry":
kds.write_string(d['account'])
kds.write_uint64(d['n'])
vds.write_int32(d['nVersion'])
vds.write_int64(d['nCreditDebit'])
vds.write_int64(d['nTime'])
vds.write_string(d['otherAccount'])
vds.write_string(d['comment'])
elif type == "bestblock":
vds.write_int32(d['nVersion'])
vds.write_compact_size(len(d['hashes']))
for h in d['hashes']:
vds.write(h)
elif type == "ckey":
kds.write_string(d['public_key'])
vds.write_string(d['encrypted_private_key'])
elif type == "mkey":
kds.write_uint32(d['nID'])
vds.write_string(d['encrypted_key'])
vds.write_string(d['salt'])
vds.write_uint32(d['nDerivationMethod'])
vds.write_uint32(d['nDerivationIterations'])
vds.write_string(d['otherParams'])
else:
print "Unknown key type: "+type
# Write the key/value pair to the database
db.put(kds.input, vds.input)
except Exception, e:
print("ERROR writing to wallet.dat, type %s"%type)
print("data dictionary: %r"%data)
traceback.print_exc()
def create_new_wallet(db_env, walletfile, version):
db_out = DB(db_env)
try:
r = db_out.open(walletfile, "main", DB_BTREE, DB_CREATE)
except DBError:
r = True
if r is not None:
logging.error("Couldn't open %s."%walletfile)
sys.exit(1)
db_out.put("0776657273696f6e".decode('hex'), ("%08x"%version).decode('hex')[::-1])
db_out.close()
def rewrite_wallet(db_env, walletfile, destFileName, pre_put_callback=None):
db = open_wallet(db_env, walletfile)
db_out = DB(db_env)
try:
r = db_out.open(destFileName, "main", DB_BTREE, DB_CREATE)
except DBError:
r = True
if r is not None:
logging.error("Couldn't open %s."%destFileName)
sys.exit(1)
def item_callback(type, d):
if (pre_put_callback is None or pre_put_callback(type, d)):
db_out.put(d["__key__"], d["__value__"])
parse_wallet(db, item_callback)
db_out.close()
db.close()
# end of bitcointools wallet.dat handling code
# wallet.dat reader / writer
def read_wallet(json_db, db_env, walletfile, print_wallet, print_wallet_transactions, transaction_filter, include_balance, vers=-1, FillPool=False):
global passphrase
crypted=False
private_keys = []
private_hex_keys = []
if vers > -1:
global addrtype
oldaddrtype = addrtype
addrtype = vers
db = open_wallet(db_env, walletfile, writable=FillPool)
json_db['keys'] = []
json_db['pool'] = []
json_db['tx'] = []
json_db['names'] = {}
json_db['ckey'] = []
json_db['mkey'] = {}
def item_callback(type, d):
if type == "tx":
json_db['tx'].append({"tx_id" : d['tx_id'], "txin" : d['txIn'], "txout" : d['txOut'], "tx_v" : d['txv'], "tx_k" : d['txk']})
elif type == "name":
json_db['names'][d['hash']] = d['name']
elif type == "version":
json_db['version'] = d['version']
elif type == "minversion":
json_db['minversion'] = d['minversion']
elif type == "setting":
if not json_db.has_key('settings'): json_db['settings'] = {}
json_db["settings"][d['setting']] = d['value']
elif type == "defaultkey":
json_db['defaultkey'] = public_key_to_bc_address(d['key'])
elif type == "key":
addr = public_key_to_bc_address(d['public_key'])
compressed = d['public_key'][0] != '\04'
sec = SecretToASecret(PrivKeyToSecret(d['private_key']), compressed)
hexsec = ASecretToSecret(sec).encode('hex')
private_keys.append(sec)
json_db['keys'].append({'addr' : addr, 'sec' : sec, 'hexsec' : hexsec, 'secret' : hexsec, 'pubkey':d['public_key'].encode('hex'), 'compressed':compressed, 'private':d['private_key'].encode('hex')})
elif type == "wkey":
if not json_db.has_key('wkey'): json_db['wkey'] = []
json_db['wkey']['created'] = d['created']
elif type == "pool":
""" d['n'] = kds.read_int64()
d['nVersion'] = vds.read_int32()
d['nTime'] = vds.read_int64()
d['public_key'] = vds.read_bytes(vds.read_compact_size())"""
try:
json_db['pool'].append( {'n': d['n'], 'addr': public_key_to_bc_address(d['public_key']), 'addr2': public_key_to_bc_address(d['public_key'].decode('hex')), 'addr3': public_key_to_bc_address(d['public_key'].encode('hex')), 'nTime' : d['nTime'], 'nVersion' : d['nVersion'], 'public_key_hex' : d['public_key'] } )
except:
json_db['pool'].append( {'n': d['n'], 'addr': public_key_to_bc_address(d['public_key']), 'nTime' : d['nTime'], 'nVersion' : d['nVersion'], 'public_key_hex' : d['public_key'].encode('hex') } )
elif type == "acc":
json_db['acc'] = d['account']
print("Account %s (current key: %s)"%(d['account'], public_key_to_bc_address(d['public_key'])))
elif type == "acentry":
json_db['acentry'] = (d['account'], d['nCreditDebit'], d['otherAccount'], time.ctime(d['nTime']), d['n'], d['comment'])
elif type == "bestblock":
json_db['bestblock'] = d['hashes'][0][::-1].encode('hex_codec')
elif type == "ckey":
crypted=True
compressed = d['public_key'][0] != '\04'
json_db['keys'].append({ 'pubkey': d['public_key'].encode('hex'),'addr': public_key_to_bc_address(d['public_key']), 'encrypted_privkey': d['encrypted_private_key'].encode('hex_codec'), 'compressed':compressed})
elif type == "mkey":
json_db['mkey']['nID'] = d['nID']
json_db['mkey']['encrypted_key'] = d['encrypted_key'].encode('hex_codec')
json_db['mkey']['salt'] = d['salt'].encode('hex_codec')
json_db['mkey']['nDerivationMethod'] = d['nDerivationMethod']
json_db['mkey']['nDerivationIterations'] = d['nDerivationIterations']
json_db['mkey']['otherParams'] = d['otherParams']
if passphrase:
res = crypter.SetKeyFromPassphrase(passphrase, d['salt'], d['nDerivationIterations'], d['nDerivationMethod'])
if res == 0:
logging.error("Unsupported derivation method")
sys.exit(1)
masterkey = crypter.Decrypt(d['encrypted_key'])
crypter.SetKey(masterkey)
else:
json_db[type] = 'unsupported'
print d
list_of_reserve_not_in_pool=[]
parse_wallet(db, item_callback)
nkeys = len(json_db['keys'])
i = 0
for k in json_db['keys']:
i+=1
addr = k['addr']
if include_balance is not None:
# print("%3d/%d %s %s" % (i, nkeys, k["addr"], k["balance"]))
k["balance"] = balance(balance_site, k["addr"])
# print(" %s" % (i, nkeys, k["addr"], k["balance"]))
if addr in json_db['names'].keys():
k["label"] = json_db['names'][addr]
k["reserve"] = 0
else:
k["reserve"] = 1
list_of_reserve_not_in_pool.append(k['pubkey'])
def rnip_callback(a):
list_of_reserve_not_in_pool.remove(a['public_key_hex'])
if FillPool:
map(rnip_callback, json_db['pool'])
cpt=1
for p in list_of_reserve_not_in_pool:
update_wallet(db, 'pool', { 'public_key' : p.decode('hex'), 'n' : cpt, 'nTime' : ts(), 'nVersion':80100 })
cpt+=1
db.close()
crypted = 'salt' in json_db['mkey']
if not crypted:
print "The wallet is not crypted"
if crypted and not passphrase:
print "The wallet is crypted but no passphrase is used"
if crypted and passphrase:
check = True
for k in json_db['keys']:
if 'encrypted_privkey' in k:
ckey = k['encrypted_privkey'].decode('hex')
public_key = k['pubkey'].decode('hex')
crypter.SetIV(Hash(public_key))
secret = crypter.Decrypt(ckey)
compressed = public_key[0] != '\04'
if check:
check = False
pkey = EC_KEY(int('0x' + secret.encode('hex'), 16))
if public_key != GetPubKey(pkey, compressed):
print "The wallet is crypted and the passphrase is incorrect"
break
sec = SecretToASecret(secret, compressed)
k['sec'] = sec
k['secret'] = secret.encode('hex')
k['compressed'] = compressed
# del(k['ckey'])
# del(k['secret'])
# del(k['pubkey'])
private_keys.append(sec)
print "The wallet is crypted and the passphrase is correct"
for k in json_db['keys']:
if k['compressed'] and 'secret' in k:
k['secret']+="01"
# del(json_db['pool'])
# del(json_db['names'])
if vers > -1:
addrtype = oldaddrtype
return {'crypted':crypted}
def importprivkey(db, sec, label, reserve, keyishex, verbose=True):
if keyishex is None:
pkey = regenerate_key(sec)
compressed = is_compressed(sec)
elif len(sec) == 64:
pkey = EC_KEY(str_to_long(sec.decode('hex')))
compressed = False
elif len(sec) == 66:
pkey = EC_KEY(str_to_long(sec[:-2].decode('hex')))
compressed = True
else:
print("Hexadecimal private keys must be 64 or 66 characters long (specified one is "+str(len(sec))+" characters long)")
return False
if not pkey:
return False
secret = GetSecret(pkey)
private_key = GetPrivKey(pkey, compressed)
public_key = GetPubKey(pkey, compressed)
addr = public_key_to_bc_address(public_key)
if verbose:
print "Address: %s" % addr
print "Privkey: %s" % SecretToASecret(secret, compressed)
global crypter, passphrase, json_db
crypted = 'salt' in json_db['mkey']
if crypted:
if passphrase:
cry_master = json_db['mkey']['encrypted_key'].decode('hex')
cry_salt = json_db['mkey']['salt'].decode('hex')
cry_rounds = json_db['mkey']['nDerivationIterations']
cry_method = json_db['mkey']['nDerivationMethod']
crypter.SetKeyFromPassphrase(passphrase, cry_salt, cry_rounds, cry_method)
# if verbose:
# print "Import with", passphrase, "", cry_master.encode('hex'), "", cry_salt.encode('hex')
masterkey = crypter.Decrypt(cry_master)
crypter.SetKey(masterkey)
crypter.SetIV(Hash(public_key))
e = crypter.Encrypt(secret)
ck_epk=e
update_wallet(db, 'ckey', { 'public_key' : public_key, 'encrypted_private_key' : ck_epk })
else:
update_wallet(db, 'key', { 'public_key' : public_key, 'private_key' : private_key })
if not reserve:
update_wallet(db, 'name', { 'hash' : addr, 'name' : label })
return True
def balance(site, address):
page=urllib.urlopen("%s=%s" % (site, address))
json_acc = json.loads(page.read().split("<end>")[0])
if json_acc['0'] == 0:
return "Invalid address"
elif json_acc['0'] == 2:
return "Never used"
else:
return json_acc['balance']
def read_jsonfile(filename):
filin = open(filename, 'r')
txdump = filin.read()
filin.close()
return json.loads(txdump)
def write_jsonfile(filename, array):
filout = open(filename, 'w')
filout.write(json.dumps(array, sort_keys=True, indent=0))
filout.close()
def keyinfo(sec, keyishex):
if keyishex is None:
pkey = regenerate_key(sec)
compressed = is_compressed(sec)
elif len(sec) == 64:
pkey = EC_KEY(str_to_long(sec.decode('hex')))
compressed = False
elif len(sec) == 66:
pkey = EC_KEY(str_to_long(sec[:-2].decode('hex')))
compressed = True
else:
print("Hexadecimal private keys must be 64 or 66 characters long (specified one is "+str(len(sec))+" characters long)")
exit(0)
if not pkey:
return False
secret = GetSecret(pkey)
private_key = GetPrivKey(pkey, compressed)
public_key = GetPubKey(pkey, compressed)
addr = public_key_to_bc_address(public_key)
print "Address (%s): %s" % ( aversions[addrtype], addr )
print "Privkey (%s): %s" % ( aversions[addrtype], SecretToASecret(secret, compressed) )
print "Hexprivkey: %s" % secret.encode('hex')
return True
def WI_FormInit(title, action, divname):
return '<style>#h'+divname+':hover{color:red;}</style><h3 id="h'+divname+'" onClick="document.getElementById(\''+divname+'\').style.display=(document.getElementById(\''+divname+'\').style.display==\'none\')?\'block\':\'none\';document.getElementById(\'iconOF_'+divname+'\').innerHTML=image_showdiv(\''+divname+'\');"><span style="width:21px;" id="iconOF_'+divname+'"><img src="http://creation-entreprise.comprendrechoisir.com/img/puce_tab_down.png" /></span>&nbsp;&nbsp;'+title+'</h3><div id="'+divname+'"><form style="margin-left:15px;" action="'+action+'" method=get>'
def WI_InputText(label, name, id, value, size=30):
return '%s<input type=text name="%s" id="%s" value="%s" size=%s /><br />'%(label, name, id, value, size)
def WI_InputPassword(label, name, id, value, size=30):
return '%s<input type=password name="%s" id="%s" value="%s" size=%s /><br />'%(label, name, id, value, size)
def WI_Submit(value, local_block, local_button, function):
return '<input type=submit value="%s" onClick="document.getElementById(\'%s\').style.display=\'block\';document.getElementById(\'%s\').style.display=\'inline\';%s();return false;" />'%(value, local_block, local_button, function)
def WI_CloseButton(local_block, local_button):
return '<input type=button value="Close" onClick="document.getElementById(\'%s\').style.display=\'none\';document.getElementById(\'%s\').style.display=\'none\';" id="%s" style="display:none;" />'%(local_block, local_button, local_button)
def WI_ReturnDiv(local_block):
return '<div id="%s" style="display:none;margin:10px 3%% 10px;padding:10px;overflow:auto;width:90%%;max-height:600px;background-color:#fff8dd;"></div>'%(local_block)
def WI_FormEnd():
return '</form><br /></div>'
def WI_RadioButton(name, value, id, checked, label):
return '&nbsp;&nbsp;&nbsp;<input type="radio" name="%s" value="%s" id="%s" %s >%s<br>'%(name, value, id, checked, label)
def WI_Checkbox(name, value, id, other, label):
return '<input type="checkbox" name="%s" value="%s" id="%s" %s />%s'%(name, value, id, other, label)
def WI_AjaxFunction(name, command_when_ready, query_string, command_until_ready):
return '\n\
function ajax%s(){\n\
var ajaxRequest;\n\
try{\n\
ajaxRequest = new XMLHttpRequest();\n\
} catch (e){\n\
try{\n\
ajaxRequest = new ActiveXObject("Msxml2.XMLHTTP");\n\
} catch (e) {\n\
try{\n\
ajaxRequest = new ActiveXObject("Microsoft.XMLHTTP");\n\
} catch (e){\n\
alert("Your browser broke!");\n\
return false;\n\
}\n\
}\n\
}\n\
ajaxRequest.onreadystatechange = function(){\n\
if(ajaxRequest.readyState == 4){\n\
%s\n\
}\n\
};\n\
var queryString = %s;\n\
ajaxRequest.open("GET", queryString, true);\n\
%s\n\
ajaxRequest.send(null);\n\
}\n\
\n\
'%(name, command_when_ready, query_string, command_until_ready)
def X_if_else(iftrue, cond, iffalse):
if cond:
return iftrue
return iffalse
def export_all_keys(db, ks, filename):
txt=";".join(ks)+"\n"
for i in db['keys']:
try:
j=i.copy()
if 'label' not in j:
j['label']='#Reserve'
t=";".join([str(j[k]) for k in ks])
txt+=t+"\n"
except:
return False
try:
myFile = open(filename, 'w')
myFile.write(txt)
myFile.close()
return True
except:
return False
def import_csv_keys(filename, wdir, wname, nbremax=9999999):
global global_merging_message
if filename[0]=="\x00": #yeah, dirty workaround
content=filename[1:]
else:
filen = open(filename, "r")
content = filen.read()
filen.close()
db_env = create_env(wdir)
read_wallet(json_db, db_env, wname, True, True, "", None)
db = open_wallet(db_env, wname, writable=True)
content=content.split('\n')
content=content[:min(nbremax, len(content))]
for i in range(len(content)):
c=content[i]
global_merging_message = ["Merging: "+str(round(100.0*(i+1)/len(content),1))+"%" for j in range(2)]
if ';' in c and len(c)>0 and c[0]!="#":
sec,label=c.split(';')
reserve=False
if label=="#Reserve":
reserve=True
keyishex=False
if abs(len(sec)-65)==1:
keyishex=True
importprivkey(db, sec, label, reserve, keyishex, verbose=False)
global_merging_message = ["Merging done.", ""]
db.close()
read_wallet(json_db, db_env, wname, True, True, "", None, -1, True) #Fill the pool if empty
return True
if 'twisted' not in missing_dep:
class WIRoot(resource.Resource):
def render_GET(self, request):
try:
request.args['update'][0]
update_pyw()
except:
True
uptodate=md5_last_pywallet[1]==md5_pywallet
uptodate=not uptodate
checking_finished=bool(md5_last_pywallet[0])
checking_finished,uptodate=[True,False]
color="#DDDDFF"
if checking_finished:
if uptodate:
color="#DDFFDD"
else:
color="#FFDDDD"
check_version_text = \
X_if_else(
X_if_else(
'Pywallet is up-to-date',
uptodate,
'Pywallet is <span style="color:red;font-weight:bold;">NOT</span> up-to-date<br /><a href="?update=1">Click to update</a>, then restart Pywallet'),
checking_finished,
'Checking version...'
)
if beta_version:
check_version_text="You are using a beta version<br />Thank you for your help"
color="#DDDDDD"
global pywversion
header = '<h1 title="'+pyw_filename+' in '+pyw_path+'">Pywallet Web Interface v'+pywversion+'</h1><h3>CLOSE BITCOIN BEFORE USE!</h3><div style="position:fixed;top:5px;right:5px;border:solid 1px black;padding:15px;background-color:'+color+';font-weight:bold;text-align:center;">' + check_version_text + '</div><br /><br />'
CPPForm = WI_FormInit('Change passphrase:', 'ChangePP', 'divformcpp') + \
WI_InputPassword('', 'pp', 'cppf-pp', '') + \
WI_Submit('Change', 'CPPDiv', 'cppf-close', 'ajaxCPP') + \
WI_CloseButton('CPPDiv', 'cppf-close') + \
WI_ReturnDiv('CPPDiv') + \
WI_FormEnd()
DWForm = WI_FormInit('Dump your wallet:', 'DumpWallet', 'divformdw') + \
WI_InputText('Wallet Directory: ', 'dir', 'dwf-dir', determine_db_dir()) + \
WI_InputText('Wallet Filename: ', 'name', 'dwf-name', determine_db_name(), 20) + \
WI_InputText('<span style="border: 0 dashed;border-bottom-width:1px;" title="0 for Bitcoin, 52 for Namecoin, 111 for testnets">Version</span>:', 'vers', 'dwf-vers', '0', 1) + \
WI_Submit('Dump wallet', 'DWDiv', 'dwf-close', 'ajaxDW') + \
WI_CloseButton('DWDiv', 'dwf-close') + \
WI_ReturnDiv('DWDiv') + \
WI_FormEnd()
MWForm = WI_FormInit('Merge two wallets:', 'MergeWallets', 'divformmw') + \
WI_InputText('Wallet 1 Directory: ', 'dir1', 'mwf-dir1', determine_db_dir()) + \
WI_InputText('Wallet 1 Filename: ', 'name1', 'mwf-name1', determine_db_name(), 20) + \
WI_InputPassword('<span style="border: 0 dashed;border-bottom-width:1px;" title="empty if none">Wallet 1 Passphrase: </span>', 'pass1', 'mwf-pass1', '') + "<br />" + \
WI_InputText('Wallet 2 Directory: ', 'dir2', 'mwf-dir2', determine_db_dir()) + \
WI_InputText('Wallet 2 Filename: ', 'name2', 'mwf-name2', "", 20) + \
WI_InputPassword('<span style="border: 0 dashed;border-bottom-width:1px;" title="empty if none">Wallet 2 Passphrase: </span>', 'pass2', 'mwf-pass2', '') + "<br />" + \
WI_InputText('Merged Wallet Directory: ', 'dirm', 'mwf-dirm', determine_db_dir()) + \
WI_InputText('Merged Wallet Filename: ', 'namem', 'mwf-namem', "", 20) + \
WI_InputPassword('<span style="border: 0 dashed;border-bottom-width:1px;" title="empty if none">Merged Wallet Passphrase: </span>', 'passm1', 'mwf-passm1', '') + \
WI_InputPassword('Repeat Wallet Passphrase: ', 'passm2', 'mwf-passm2', '') + \
WI_Submit('Merge wallets', 'MWDiv', 'mwf-close', 'ajaxMW') + \
WI_CloseButton('MWDiv', 'mwf-close') + \
WI_ReturnDiv('MWDiv') + \
WI_FormEnd()
DKForm = WI_FormInit('Dump your keys:', 'DumpKeys', 'divformdk') + \
WI_InputText('Wallet Directory: ', 'dir', 'dkf-dir', determine_db_dir()) + \
WI_InputText('Wallet Filename: ', 'name', 'dkf-name', determine_db_name(), 20) + \
WI_InputText('<span style="border: 0 dashed;border-bottom-width:1px;" title="0 for Bitcoin, 52 for Namecoin, 111 for testnets">Version</span>:', 'vers', 'dkf-vers', '0', 1) + \
WI_InputText('Output file: ', 'file', 'dkf-file', '', 60) + \
WI_InputText('<span style="border: 0 dashed;border-bottom-width:1px;" title="to be chosen from the ones in wallet dump, separated with \',\', e.g. \'addr,secret\'">Data to print: </span>', 'keys', 'dkf-keys', '') + \
WI_Submit('Dump keys', 'DKDiv', 'dkf-close', 'ajaxDK') + \
WI_CloseButton('DKDiv', 'dkf-close') + \
WI_ReturnDiv('DKDiv') + \
WI_FormEnd()
IKForm = WI_FormInit('Import keys:', 'ImportKeys', 'divformik') + \
WI_InputText('Wallet Directory: ', 'dir', 'ikf-dir', determine_db_dir()) + \
WI_InputText('Wallet Filename: ', 'name', 'ikf-name', determine_db_name(), 20) + \
WI_InputText('<span style="border: 0 dashed;border-bottom-width:1px;" title="Format: \'privkey;label\', label=\'#Reserve\' to make the key a pool one">CSV file path</span>: ', 'file', 'ikf-file', '', 60) + \
WI_Submit('Import keys', 'IKDiv', 'ikf-close', 'ajaxIK') + \
WI_CloseButton('IKDiv', 'ikf-close') + \
WI_ReturnDiv('IKDiv') + \
WI_FormEnd()
DTxForm = WI_FormInit('Dump your transactions to a file:', 'DumpTx', 'divformdtx') + \
WI_InputText('Wallet Directory: ', 'dir', 'dt-dir', determine_db_dir()) + \
WI_InputText('Wallet Filename: ', 'name', 'dt-name', determine_db_name(), 20) + \
WI_InputText('Output file: ', 'file', 'dt-file', '') + \
WI_Submit('Dump tx\'s', 'DTxDiv', 'dt-close', 'ajaxDTx') + \
WI_CloseButton('DTxDiv', 'dt-close') + \
WI_ReturnDiv('DTxDiv') + \
WI_FormEnd()
prehide_ecdsa=""
posthide_ecdsa=""
if 'ecdsa' in missing_dep:
prehide_ecdsa="<span style='display:none;'>"
posthide_ecdsa="</span>"
InfoForm = WI_FormInit('Get some info about one key'+X_if_else(' and sign/verify messages', 'ecdsa' not in missing_dep,'')+':', 'Info', 'divforminfo') + \
WI_InputText('Key: ', 'key', 'if-key', '', 60) + \
prehide_ecdsa + WI_InputText('Message: ', 'msg', 'if-msg', '', 30) + posthide_ecdsa + \
prehide_ecdsa + WI_InputText('Signature: ', 'sig', 'if-sig', '', 30) + posthide_ecdsa + \
prehide_ecdsa + WI_InputText('Pubkey: ', 'pubkey', 'if-pubkey', '', 30) + posthide_ecdsa + \
WI_InputText('<span style="border: 0 dashed;border-bottom-width:1px;" title="0 for Bitcoin, 52 for Namecoin, 111 for testnets">Version</span>:', 'vers', 'if-vers', '0', 1) + \
"Format:<br />" + \
WI_RadioButton('format', 'reg', 'if-reg', 'CHECKED', ' Regular, base 58') + \
WI_RadioButton('format', 'hex', 'if-hex', '', ' Hexadecimal, 64 characters long') + \
"You want:<br />" + \
WI_RadioButton('i-need', '1', 'if-n-info', 'CHECKED', ' Info') + \
prehide_ecdsa + WI_RadioButton('i-need', '2', 'if-n-sv', '', ' Sign and verify') + posthide_ecdsa +\
prehide_ecdsa + WI_RadioButton('i-need', '3', 'if-n-both', '', ' Both') + posthide_ecdsa + \
WI_Submit('Get info', 'InfoDiv', 'if-close', 'ajaxInfo') + \
WI_CloseButton('InfoDiv', 'if-close') + \
WI_ReturnDiv('InfoDiv') + \
WI_FormEnd()
ImportForm = WI_FormInit('Import a key into your wallet:', 'Import', 'divformimport') + \
WI_InputText('Wallet Directory: ', 'dir', 'impf-dir', determine_db_dir(), 30) + \
WI_InputText('Wallet Filename:', 'name', 'impf-name', determine_db_name(), 20) + \
WI_InputText('Key:', 'key', 'impf-key', '', 65) + \
WI_InputText('Label:', 'label', 'impf-label', '') + \
WI_Checkbox('reserve', 'true', 'impf-reserve', 'onClick="document.getElementById(\'impf-label\').disabled=document.getElementById(\'impf-reserve\').checked"', ' Reserve') + "<br />" + \
WI_InputText('<span style="border: 0 dashed;border-bottom-width:1px;" title="0 for Bitcoin, 52 for Namecoin, 111 for testnets">Version</span>:', 'vers', 'impf-vers', '0', 1) + \
"Format:<br />" + \
WI_Checkbox('format', 'hex', 'impf-hex', '', ' Hexadecimal, instead of base58') + "<br />" + \
WI_Checkbox('format', 'cry', 'impf-cry', 'hidden=true', '<!-- Crypt-->') + \
WI_Checkbox('format', 'com', 'impf-com', 'hidden=true', '<!--Compressed key-->') + \
WI_Submit('Import key', 'ImportDiv', 'impf-close', 'ajaxImport') + \
WI_CloseButton('ImportDiv', 'impf-close') + \
WI_ReturnDiv('ImportDiv') + \
WI_FormEnd()
# WI_RadioButton('format', 'reg', 'impf-reg', 'CHECKED', ' Regular, base 58') + \
# WI_RadioButton('format', 'hex', 'impf-hex', '', ' Hexadecimal, 64 characters long') + \
DeleteForm = WI_FormInit('Delete a key from your wallet:', 'Delete', 'divformdelete') + \
WI_InputText('Wallet Directory: ', 'dir', 'd-dir', determine_db_dir(), 40) + \
WI_InputText('Wallet Filename:', 'name', 'd-name', determine_db_name()) + \
WI_InputText('Key:', 'key', 'd-key', '', 65) + \
"Type:<br />" + \
WI_RadioButton('d-type', 'tx', 'd-r-tx', 'CHECKED', ' Transaction (type "all" in "Key" to delete them all)') + \
WI_RadioButton('d-type', 'key', 'd-r-key', '', ' Bitcoin address') + \
WI_Submit('Delete', 'DeleteDiv', 'd-close', 'ajaxDelete') + \
WI_CloseButton('DeleteDiv', 'd-close') + \
WI_ReturnDiv('DeleteDiv') + \
WI_FormEnd()
ImportTxForm = WI_FormInit('Import a transaction into your wallet:', 'ImportTx', 'divformimporttx') + \
WI_InputText('Wallet Directory: ', 'dir', 'it-dir', determine_db_dir(), 40) + \
WI_InputText('Wallet Filename:', 'name', 'it-name', determine_db_name()) + \
WI_InputText('Txk:', 'key', 'it-txk', '', 65) + \
WI_InputText('Txv:', 'label', 'it-txv', '', 65) + \
WI_Submit('Import', 'ImportTxDiv', 'it-close', 'ajaxImportTx') + \
WI_CloseButton('ImportTxDiv', 'it-close') + \
WI_ReturnDiv('ImportTxDiv') + \
WI_FormEnd()
BalanceForm = WI_FormInit('Print the balance of a Bitcoin address:', 'Balance', 'divformbalance') + \
WI_InputText('Key:', 'key', 'bf-key', '', 35) + \
'<input type=submit value="Get balance" onClick="ajaxBalance();return false;" /><div id="BalanceDiv"></div>' + \
WI_FormEnd()
Misc = ''
Javascript = '<script language="javascript" type="text/javascript">interv1=0;\
function image_showdiv(a){\
if(document.getElementById(a).style.display!="none")r="http://creation-entreprise.comprendrechoisir.com/img/puce_tab_down.png";\
else{\
r="http://creation-entreprise.comprendrechoisir.com/img/puce_tab.png";}\
\
return "<img src=\'"+r+"\' />";\
\
}\
function get_radio_value(radioform){\
var rad_val;\
for (var i=0; i < radioform.length; i++){\
if (radioform[i].checked){\
rad_val = radioform[i].value;\
}\
}\
return rad_val;\
}' + \
WI_AjaxFunction('CPP', 'document.getElementById("CPPDiv").innerHTML = ajaxRequest.responseText;', '"/ChangePP?pp="+document.getElementById("cppf-pp").value', 'document.getElementById("CPPDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('DW', 'document.getElementById("DWDiv").innerHTML = ajaxRequest.responseText;', '"/DumpWallet?dir="+document.getElementById("dwf-dir").value+"&name="+document.getElementById("dwf-name").value+"&version="+document.getElementById("dwf-vers").value', 'document.getElementById("DWDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('MW', 'document.getElementById("MWDiv").innerHTML = ajaxRequest.responseText;', '"/MergeWallets?dir1="+document.getElementById("mwf-dir1").value+"&name1="+document.getElementById("mwf-name1").value+"&pass1="+document.getElementById("mwf-pass1").value+"&dir2="+document.getElementById("mwf-dir2").value+"&name2="+document.getElementById("mwf-name2").value+"&pass2="+document.getElementById("mwf-pass2").value+"&dirm="+document.getElementById("mwf-dirm").value+"&namem="+document.getElementById("mwf-namem").value+"&passm1="+document.getElementById("mwf-passm1").value+"&passm2="+document.getElementById("mwf-passm2").value+""', 'document.getElementById("MWDiv").innerHTML = "Merging wallets... This may take a few minutes.";interv1=setInterval(ajaxUpdateMW,300);') + \
WI_AjaxFunction('UpdateMW', 'if(ajaxRequest.responseText.length>0){document.getElementById("MWDiv").innerHTML = ajaxRequest.responseText;}else{clearInterval(interv1);}', '"/Others?action=update_mwdiv"', '') + \
WI_AjaxFunction('DK', 'document.getElementById("DKDiv").innerHTML = ajaxRequest.responseText;', '"/DumpWallet?dir="+document.getElementById("dkf-dir").value+"&filetw="+document.getElementById("dkf-file").value+"&keys="+document.getElementById("dkf-keys").value+"&name="+document.getElementById("dkf-name").value+"&version="+document.getElementById("dkf-vers").value', 'document.getElementById("DKDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('IK', 'document.getElementById("IKDiv").innerHTML = ajaxRequest.responseText;', '"/Import?dir="+document.getElementById("ikf-dir").value+"&file="+document.getElementById("ikf-file").value+"&name="+document.getElementById("ikf-name").value', 'document.getElementById("IKDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('DTx', 'document.getElementById("DTxDiv").innerHTML = ajaxRequest.responseText;', '"/DumpTx?dir="+document.getElementById("dt-dir").value+"&name="+document.getElementById("dt-name").value+"&file="+document.getElementById("dt-file").value', 'document.getElementById("DTxDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('Info', 'document.getElementById("InfoDiv").innerHTML = ajaxRequest.responseText;', '"/Info?key="+document.getElementById("if-key").value+"&msg="+document.getElementById("if-msg").value+"&pubkey="+document.getElementById("if-pubkey").value+"&sig="+document.getElementById("if-sig").value+"&vers="+document.getElementById("if-vers").value+"&format="+(document.getElementById("if-hex").checked?"hex":"reg")+"&need="+get_radio_value(document.getElementsByName("i-need"))', 'document.getElementById("InfoDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('Import', 'document.getElementById("ImportDiv").innerHTML = ajaxRequest.responseText;', '"/Import?dir="+document.getElementById("impf-dir").value+"&name="+document.getElementById("impf-name").value+"&key="+document.getElementById("impf-key").value+"&label="+document.getElementById("impf-label").value+"&vers="+document.getElementById("impf-vers").value+"&com="+document.getElementById("impf-com").checked+"&cry="+document.getElementById("impf-cry").checked+"&format="+document.getElementById("impf-hex").checked+(document.getElementById("impf-reserve").checked?"&reserve=1":"")', 'document.getElementById("ImportDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('Balance', 'document.getElementById("BalanceDiv").innerHTML = "Balance of " + document.getElementById("bf-key").value + ": " + ajaxRequest.responseText;', '"/Balance?key="+document.getElementById("bf-key").value', 'document.getElementById("BalanceDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('Delete', 'document.getElementById("DeleteDiv").innerHTML = ajaxRequest.responseText;', '"/Delete?dir="+document.getElementById("d-dir").value+"&name="+document.getElementById("d-name").value+"&keydel="+document.getElementById("d-key").value+"&typedel="+get_radio_value(document.getElementsByName("d-type"))', 'document.getElementById("DeleteDiv").innerHTML = "Loading...";') + \
WI_AjaxFunction('ImportTx', 'document.getElementById("ImportTxDiv").innerHTML = ajaxRequest.responseText;', '"/ImportTx?dir="+document.getElementById("it-dir").value+"&name="+document.getElementById("it-name").value+"&txk="+document.getElementById("it-txk").value+"&txv="+document.getElementById("it-txv").value', 'document.getElementById("ImportTxDiv").innerHTML = "Loading...";') + \
'</script>'
# WI_AjaxFunction('Import', 'document.getElementById("ImportDiv").innerHTML = ajaxRequest.responseText;', '"/Import?dir="+document.getElementById("impf-dir").value+"&name="+document.getElementById("impf-name").value+"&key="+document.getElementById("impf-key").value+"&label="+document.getElementById("impf-label").value+"&vers="+document.getElementById("impf-vers").value+"&format="+(document.getElementById("impf-hex").checked?"hex":"reg")+(document.getElementById("impf-reserve").checked?"&reserve=1":"")', 'document.getElementById("ImportDiv").innerHTML = "Loading...";') + \
page = '<html><head><title>Pywallet Web Interface</title></head><body>' + header + Javascript + CPPForm + DWForm + MWForm + DKForm + IKForm + DTxForm + InfoForm + ImportForm + ImportTxForm + DeleteForm + BalanceForm + Misc + '</body></html>'
return page
def getChild(self, name, request):
if name == '':
return self
else:
if name in VIEWS.keys():
return resource.Resource.getChild(self, name, request)
else:
return WI404()
class WIDumpWallet(resource.Resource):
def render_GET(self, request):
try:
wdir=request.args['dir'][0]
wname=request.args['name'][0]
version = int(request.args['version'][0])
log.msg('Wallet Dir: %s' %(wdir))
log.msg('Wallet Name: %s' %(wname))
if not os.path.isfile(wdir+"/"+wname):
return '%s/%s doesn\'t exist'%(wdir, wname)
read_wallet(json_db, create_env(wdir), wname, True, True, "", None, version)
# print wdir
# print wname
# print json_db #json.dumps(json_db, sort_keys=True, indent=4)
try:
kfile=request.args['filetw'][0]
kkeys=request.args['keys'][0]
# print kkeys.split(',')
reteak=export_all_keys(json_db, kkeys.split(','), kfile)
return 'File'+X_if_else("",reteak," not")+' written'
except:
return 'Wallet: %s/%s<br />Dump:<pre>%s</pre>'%(wdir, wname, json.dumps(json_db, sort_keys=True, indent=4))
except:
log.err()
return 'Error in dump page'
def render_POST(self, request):
return self.render_GET(request)
class WIDumpTx(resource.Resource):
def render_GET(self, request):
try:
wdir=request.args['dir'][0]
wname=request.args['name'][0]
jsonfile=request.args['file'][0]
log.msg('Wallet Dir: %s' %(wdir))
log.msg('Wallet Name: %s' %(wname))
if not os.path.isfile(wdir+"/"+wname):
return '%s/%s doesn\'t exist'%(wdir, wname)
if os.path.isfile(jsonfile):
return '%s exists'%(jsonfile)
read_wallet(json_db, create_env(wdir), wname, True, True, "", None)
write_jsonfile(jsonfile, json_db['tx'])
return 'Wallet: %s/%s<br />Transations dumped in %s'%(wdir, wname, jsonfile)
except:
log.err()
return 'Error in dumptx page'
def render_POST(self, request):
return self.render_GET(request)
class WIMergeWallets(resource.Resource):
def render_GET(self, request):
try:
dir1=request.args['dir1'][0]
name1=request.args['name1'][0]
pass1=request.args['pass1'][0]
dir2=request.args['dir2'][0]
name2=request.args['name2'][0]
pass2=request.args['pass2'][0]
dirm=request.args['dirm'][0]
namem=request.args['namem'][0]
passm1=request.args['passm1'][0]
passm2=request.args['passm2'][0]
if passm1!=passm2:
return 'The passphrases for the merged wallet don\'t match. Aborted.'
r=merge_wallets(dir1, name1, dir2, name2, dirm, namem, pass1, pass2, passm1)
if r[0]:
return "Merging in progress..."
else:
return r[1]
return ret
except:
log.err()
return 'Error in mergewallets page'
def render_POST(self, request):
return self.render_GET(request)
class WIChangePP(resource.Resource):
def render_GET(self, request):
try:
global passphrase
passphrase=request.args['pp'][0]
return 'Done'
except:
log.err()
return 'Error while changing passphrase'
def render_POST(self, request):
return self.render_GET(request)
class WIOthers(resource.Resource):
def render_GET(self, request):
try:
global passphrase
global global_merging_message
action=request.args['action'][0]
if action=="update_mwdiv":
ret=global_merging_message[0]
global_merging_message[0]=global_merging_message[1]
global_merging_message[1]=""
return ret
return 'Done'
except:
log.err()
return 'Error while WIOthers'
def render_POST(self, request):
return self.render_GET(request)
class WIBalance(resource.Resource):
def render_GET(self, request):
try:
return "%s"%str(balance(balance_site, request.args['key'][0]).encode('utf-8'))
except:
log.err()
return 'Error in balance page'
def render_POST(self, request):
return self.render_GET(request)
class WIDelete(resource.Resource):
def render_GET(self, request):
try:
wdir=request.args['dir'][0]
wname=request.args['name'][0]
keydel=request.args['keydel'][0]
typedel=request.args['typedel'][0]
db_env = create_env(wdir)
if not os.path.isfile(wdir+"/"+wname):
return '%s/%s doesn\'t exist'%(wdir, wname)
deleted_items = delete_from_wallet(db_env, wname, typedel, keydel)
return "%s:%s has been successfully deleted from %s/%s, resulting in %d deleted item%s"%(typedel, keydel, wdir, wname, deleted_items, iais(deleted_items))
except:
log.err()
return 'Error in delete page'
def render_POST(self, request):
return self.render_GET(request)
def message_to_hash(msg, msgIsHex=False):
str = ""
# str += '04%064x%064x'%(pubkey.point.x(), pubkey.point.y())
# str += "Padding text - "
str += msg
if msgIsHex:
str = str.decode('hex')
hash = Hash(str)
return hash
def sign_message(secret, msg, msgIsHex=False):
k = KEY()
k.generate(secret)
return k.sign(message_to_hash(msg, msgIsHex))
def verify_message_signature(pubkey, sign, msg, msgIsHex=False):
k = KEY()
k.set_pubkey(pubkey.decode('hex'))
return k.verify(message_to_hash(msg, msgIsHex), sign.decode('hex'))
OP_DUP = 118;
OP_HASH160 = 169;
OP_EQUALVERIFY = 136;
OP_CHECKSIG = 172;
XOP_DUP = "%02x"%OP_DUP;
XOP_HASH160 = "%02x"%OP_HASH160;
XOP_EQUALVERIFY = "%02x"%OP_EQUALVERIFY;
XOP_CHECKSIG = "%02x"%OP_CHECKSIG;
BTC = 1e8
def ct(l_prevh, l_prevn, l_prevsig, l_prevpubkey, l_value_out, l_pubkey_out, is_msg_to_sign=-1, oldScriptPubkey=""):
scriptSig = True
if is_msg_to_sign is not -1:
scriptSig = False
index = is_msg_to_sign
ret = ""
ret += inverse_str("%08x"%1)
nvin = len(l_prevh)
ret += "%02x"%nvin
for i in range(nvin):
txin_ret = ""
txin_ret2 = ""
txin_ret += inverse_str(l_prevh[i])
txin_ret += inverse_str("%08x"%l_prevn[i])
if scriptSig:
txin_ret2 += "%02x"%(len(l_prevsig[i])/2)
txin_ret2 += l_prevsig[i]
txin_ret2 += "%02x"%(len(l_prevpubkey[i])/2)
txin_ret2 += l_prevpubkey[i]
txin_ret += "%02x"%(len(txin_ret2)/2)
txin_ret += txin_ret2
elif index == i:
txin_ret += "%02x"%(len(oldScriptPubkey)/2)
txin_ret += oldScriptPubkey
ret += txin_ret
ret += "ffffffff"
nvout = len(l_value_out)
ret += "%02x"%nvout
for i in range(nvout):
txout_ret = ""
txout_ret += inverse_str("%016x"%(l_value_out[i]))
txout_ret += "%02x"%(len(l_pubkey_out[i])/2+5)
txout_ret += "%02x"%OP_DUP
txout_ret += "%02x"%OP_HASH160
txout_ret += "%02x"%(len(l_pubkey_out[i])/2)
txout_ret += l_pubkey_out[i]
txout_ret += "%02x"%OP_EQUALVERIFY
txout_ret += "%02x"%OP_CHECKSIG
ret += txout_ret
ret += "00000000"
if not scriptSig:
ret += "01000000"
return ret
def inverse_str(string):
ret = ""
for i in range(len(string)/2):
ret += string[len(string)-2-2*i];
ret += string[len(string)-2-2*i+1];
return ret
if 'twisted' not in missing_dep:
class WIInfo(resource.Resource):
def render_GET(self, request):
global addrtype
try:
sec = request.args['key'][0]
format = request.args['format'][0]
addrtype = int(request.args['vers'][0])
msgIsHex = False
msgIsFile = False
try:
msg = request.args['msg'][0]
if msg[0:4] == "Hex:":
msg = msg[4:]
msgIsHex = True
elif msg[0:5] == "File:":
msg = msg[5:]
if not os.path.isfile(msg):
return '%s doesn\'t exist'%(msg)
filin = open(msg, 'r')
msg = filin.read()
filin.close()
msgIsFile = True
sig = request.args['sig'][0]
pubkey = request.args['pubkey'][0]
need = int(request.args['need'][0])
except:
need = 1
ret = ""
if sec is not '':
if format in 'reg':
pkey = regenerate_key(sec)
compressed = is_compressed(sec)
elif len(sec) == 64:
pkey = EC_KEY(str_to_long(sec.decode('hex')))
compressed = False
elif len(sec) == 66:
pkey = EC_KEY(str_to_long(sec[:-2].decode('hex')))
compressed = True
else:
return "Hexadecimal private keys must be 64 characters long"
if not pkey:
return "Bad private key"
secret = GetSecret(pkey)
private_key = GetPrivKey(pkey)
public_key = GetPubKey(pkey)
addr = public_key_to_bc_address(public_key)
if need & 1:
ret += "Address (%s): %s<br />"%(aversions[addrtype], addr)
ret += "Privkey (%s): %s<br />"%(aversions[addrtype], SecretToASecret(secret))
ret += "Hexprivkey: %s<br />"%(secret.encode('hex'))
ret += "Hash160: %s<br />"%(bc_address_to_hash_160(addr).encode('hex'))
# ret += "Inverted hexprivkey: %s<br />"%(inversetxid(secret.encode('hex')))
ret += "Pubkey: <span style='font-size:60%%;'>04%.64x%.64x</span><br />"%(pkey.pubkey.point.x(), pkey.pubkey.point.y())
ret += X_if_else('<br /><br /><b>Beware, 0x%s is equivalent to 0x%.33x</b>'%(secret.encode('hex'), int(secret.encode('hex'), 16)-_r), (int(secret.encode('hex'), 16)>_r), '')
if 'ecdsa' not in missing_dep and need & 2:
if sec is not '' and msg is not '':
if need & 1:
ret += "<br />"
ret += "Signature of '%s' by %s: <span style='font-size:60%%;'>%s</span><br />Pubkey: <span style='font-size:60%%;'>04%.64x%.64x</span><br />"%(X_if_else(msg, not msgIsFile, request.args['msg'][0]), addr, sign_message(secret, msg, msgIsHex), pkey.pubkey.point.x(), pkey.pubkey.point.y())
if sig is not '' and msg is not '' and pubkey is not '':
addr = public_key_to_bc_address(pubkey.decode('hex'))
try:
verify_message_signature(pubkey, sig, msg, msgIsHex)
ret += "<br /><span style='color:#005500;'>Signature of '%s' by %s is <span style='font-size:60%%;'>%s</span></span><br />"%(X_if_else(msg, not msgIsFile, request.args['msg'][0]), addr, sig)
except:
ret += "<br /><span style='color:#990000;'>Signature of '%s' by %s is NOT <span style='font-size:60%%;'>%s</span></span><br />"%(X_if_else(msg, not msgIsFile, request.args['msg'][0]), addr, sig)
return ret
except:
log.err()
return 'Error in info page'
def render_POST(self, request):
return self.render_GET(request)
class WIImportTx(resource.Resource):
def render_GET(self, request):
global addrtype
try:
wdir=request.args['dir'][0]
wname=request.args['name'][0]
txk=request.args['txk'][0]
txv=request.args['txv'][0]
d = {}
if not os.path.isfile(wdir+"/"+wname):
return '%s/%s doesn\'t exist'%(wdir, wname)
if txk not in "file":
dd = [{'tx_k':txk, 'tx_v':txv}]
else:
if not os.path.isfile(txv):
return '%s doesn\'t exist'%(txv)
dd = read_jsonfile(txv)
db_env = create_env(wdir)
read_wallet(json_db, db_env, wname, True, True, "", None)
db = open_wallet(db_env, wname, writable=True)
i=0
for tx in dd:
d = {'txi':tx['tx_k'], 'txv':tx['tx_v']}
print(d)
update_wallet(db, "tx", d)
i+=1
db.close()
return "<pre>hash: %s\n%d transaction%s imported in %s/%s<pre>" % (inverse_str(txk[6:]), i, iais(i), wdir, wname)
except:
log.err()
return 'Error in importtx page'
def render_POST(self, request):
return self.render_GET(request)
class WIImport(resource.Resource):
def render_GET(self, request):
global addrtype
try:
wdir=request.args['dir'][0]
wname=request.args['name'][0]
try: #Import a single key
addrtype = int(request.args['vers'][0])
format = X_if_else('hex', request.args['format'][0]=='true', 'reg')
reserve=request.args.has_key('reserve')
label=request.args['label'][0]
compressed=request.args['com'][0]=='true'
tocrypt=request.args['cry'][0]=='true'
sec = request.args['key'][0]
except: #Import csv file
ret=import_csv_keys(request.args['file'][0],wdir,wname)
return "File "+X_if_else("", ret, "not ")+"imported"
if format in 'reg':
pkey = regenerate_key(sec)
compressed = is_compressed(sec)
elif len(sec) == 64:
pkey = EC_KEY(str_to_long(sec.decode('hex')))
compressed = False
elif len(sec) == 66:
pkey = EC_KEY(str_to_long(sec[:-2].decode('hex')))
compressed = True
else:
return "Hexadecimal private keys must be 64 or 66 characters long"
if not pkey:
return "Bad private key"
if not os.path.isfile(wdir+"/"+wname):
return '%s/%s doesn\'t exist'%(wdir, wname)
db_env = create_env(wdir)
ret_read = read_wallet(json_db, db_env, wname, True, True, "", None)
tocrypt = ret_read['crypted']
db = open_wallet(db_env, wname, writable=True)
secret = GetSecret(pkey)
private_key = GetPrivKey(pkey, compressed)
public_key = GetPubKey(pkey, compressed)
addr = public_key_to_bc_address(public_key)
if (format in 'reg' and sec in private_keys) or (format not in 'reg' and sec in private_hex_keys):
return "Already exists"
if not tocrypt:
update_wallet(db, 'key', { 'public_key' : public_key, 'private_key' : private_key })
else:
cry_master = json_db['mkey']['encrypted_key'].decode('hex')
cry_salt = json_db['mkey']['salt'].decode('hex')
cry_rounds = json_db['mkey']['nDerivationIterations']
cry_method = json_db['mkey']['nDerivationMethod']
crypter.SetKeyFromPassphrase(passphrase, cry_salt, cry_rounds, cry_method)
masterkey = crypter.Decrypt(cry_master)
crypter.SetKey(masterkey)
crypter.SetIV(Hash(public_key))
e = crypter.Encrypt(secret)
ck_epk=e
update_wallet(db, 'ckey', { 'public_key' : public_key, 'encrypted_private_key' : ck_epk })
if not reserve:
update_wallet(db, 'name', { 'hash' : addr, 'name' : label })
db.close()
return "<pre>Address: %s\nPrivkey: %s\nHexkey: %s\nKey (%scrypted, %scompressed) imported in %s/%s<pre>" % (addr, SecretToASecret(secret, compressed), secret.encode('hex'), X_if_else("",tocrypt,"un"), X_if_else("",compressed,"un"), wdir, wname)
except:
log.err()
return 'Error in import page'
def render_POST(self, request):
return self.render_GET(request)
class WI404(resource.Resource):
def render_GET(self, request):
return 'Page Not Found'
def update_pyw():
if md5_last_pywallet[0] and md5_last_pywallet[1] not in md5_pywallet:
filout = open(pyw_filename, 'w')
filout.write(urllib.urlopen('https://raw.github.com/jackjack-jj/pywallet/master/pywallet.py').read())
filout.close()
reactor.stop()
import thread
md5_last_pywallet = [False, ""]
def retrieve_last_pywallet_md5():
global md5_last_pywallet
md5_last_pywallet = [True, md5_onlinefile('https://raw.github.com/jackjack-jj/pywallet/master/pywallet.py')]
def zzz(a):
global pywversion
pywversion=a
from optparse import OptionParser
if __name__ == '__main__':
md5_pywallet = md5_file(pyw_filename)
thread.start_new_thread(retrieve_last_pywallet_md5, ())
parser = OptionParser(usage="%prog [options]", version="%prog 1.1")
parser.add_option("--passphrase", dest="passphrase",
help="passphrase for the encrypted wallet")
parser.add_option("--dumpwallet", dest="dump", action="store_true",
help="dump wallet in json format")
parser.add_option("--dumpwithbalance", dest="dumpbalance", action="store_true",
help="includes balance of each address in the json dump, takes about 2 minutes per 100 addresses")
parser.add_option("--importprivkey", dest="key",
help="import private key from vanitygen")
parser.add_option("--importhex", dest="keyishex", action="store_true",
help="KEY is in hexadecimal format")
parser.add_option("--datadir", dest="datadir",
help="wallet directory (defaults to bitcoin default)")
parser.add_option("--wallet", dest="walletfile",
help="wallet filename (defaults to wallet.dat)",
default="wallet.dat")
parser.add_option("--label", dest="label",
help="label shown in the adress book (defaults to '')",
default="")
parser.add_option("--testnet", dest="testnet", action="store_true",
help="use testnet subdirectory and address type")
parser.add_option("--namecoin", dest="namecoin", action="store_true",
help="use namecoin address type")
parser.add_option("--otherversion", dest="otherversion",
help="use other network address type, whose version is OTHERVERSION")
parser.add_option("--info", dest="keyinfo", action="store_true",
help="display pubkey, privkey (both depending on the network) and hexkey")
parser.add_option("--reserve", dest="reserve", action="store_true",
help="import as a reserve key, i.e. it won't show in the adress book")
parser.add_option("--balance", dest="key_balance",
help="prints balance of KEY_BALANCE")
parser.add_option("--web", dest="web", action="store_true",
help="run pywallet web interface")
parser.add_option("--port", dest="port",
help="port of web interface (defaults to 8989)")
parser.add_option("--recover", dest="recover", action="store_true",
help="recover your deleted keys, use with recov_size and recov_device")
parser.add_option("--recov_device", dest="recov_device",
help="device to read (e.g. /dev/sda1)")
parser.add_option("--recov_size", dest="recov_size",
help="number of bytes to read (e.g. 20Mo or 50Gio)")
parser.add_option("--recov_outputdir", dest="recov_outputdir",
help="output directory where the recovered wallet will be put")
parser.add_option("--dont_check_walletversion", dest="dcv", action="store_true",
help="don't check if wallet version > %d before running (WARNING: this may break your wallet, be sure you know what you do)"%max_version)
# parser.add_option("--forcerun", dest="forcerun",
# action="store_true",
# help="run even if pywallet detects bitcoin is running")
(options, args) = parser.parse_args()
# a=Popen("ps xa | grep ' bitcoin'", shell=True, bufsize=-1, stdout=PIPE).stdout
# aread=a.read()
# nl = aread.count("\n")
# a.close()
# if nl > 2:
# print('Bitcoin seems to be running: \n"%s"'%(aread))
# if options.forcerun is None:
# exit(0)
if options.passphrase:
passphrase = options.passphrase
if options.recover:
if options.recov_size is None or options.recov_device is None or options.recov_outputdir is None:
print("You must provide the device, the number of bytes to read and the output directory")
exit(0)
device = options.recov_device
size = read_device_size(options.recov_size)
r = first_read(device, size, prekeys, 10000)
r = shrink_intervals(device, r, prekeys, 1000)
[to_read, o] = find_offsets(device, r, prekeys)
print("%dko to read"%(to_read/1000))
keys = read_keys(device, o)
print("%d key%s found"%(len(keys), iais(len(keys))))
db_env = create_env(options.recov_outputdir)
recov_wallet_name = "recovered_wallet_%s.dat"%ts()
create_new_wallet(db_env, recov_wallet_name, 32500)
db = open_wallet(db_env, recov_wallet_name, True)
i = 0
for sec in keys:
print("\nImporting key %4d/%d:"%(i+1, len(keys)))
importprivkey(db, sec, "recovered: %s"%sec, None, True)
i += 1
db.close()
print("\n\nThe new wallet %s/%s contains the %d recovered key%s\n"%(options.recov_outputdir, recov_wallet_name, len(keys), iais(len(keys))))
exit(0)
if 'bsddb' in missing_dep:
print("pywallet needs 'bsddb' package to run, please install it")
exit(0)
if 'twisted' in missing_dep and options.web is not None:
print("'twisted' package is not installed, pywallet web interface can't be launched")
exit(0)
if 'ecdsa' in missing_dep:
print("'ecdsa' package is not installed, pywallet won't be able to sign/verify messages")
if 'twisted' not in missing_dep:
VIEWS = {
'DumpWallet': WIDumpWallet(),
'MergeWallets': WIMergeWallets(),
'Import': WIImport(),
'ImportTx': WIImportTx(),
'DumpTx': WIDumpTx(),
'Info': WIInfo(),
'Delete': WIDelete(),
'Balance': WIBalance(),
'ChangePP': WIChangePP(),
'Others': WIOthers()
}
if options.dcv is not None:
max_version = 10 ** 9
if options.datadir is not None:
wallet_dir = options.datadir
if options.datadir is not None:
wallet_name = options.walletfile
if 'twisted' not in missing_dep and options.web is not None:
webport = 8989
if options.port is not None:
webport = int(options.port)
root = WIRoot()
for viewName, className in VIEWS.items():
root.putChild(viewName, className)
log.startLogging(sys.stdout)
log.msg('Starting server: %s' %str(datetime.now()))
server = server.Site(root)
reactor.listenTCP(webport, server)
reactor.run()
exit(0)
if options.key_balance is not None:
print(balance(balance_site, options.key_balance))
exit(0)
if options.dump is None and options.key is None:
print "A mandatory option is missing\n"
parser.print_help()
exit(0)
if options.testnet:
db_dir += "/testnet"
addrtype = 111
if options.namecoin or options.otherversion is not None:
if options.datadir is None and options.keyinfo is None:
print("You must provide your wallet directory")
exit(0)
else:
if options.namecoin:
addrtype = 52
else:
addrtype = int(options.otherversion)
if options.keyinfo is not None:
if not keyinfo(options.key, options.keyishex):
print "Bad private key"
exit(0)
db_dir = determine_db_dir()
db_env = create_env(db_dir)
read_wallet(json_db, db_env, determine_db_name(), True, True, "", options.dumpbalance is not None)
if json_db.get('minversion') > max_version:
print "Version mismatch (must be <= %d)" % max_version
#exit(1)
if options.dump:
print json.dumps(json_db, sort_keys=True, indent=4)
elif options.key:
if json_db['version'] > max_version:
print "Version mismatch (must be <= %d)" % max_version
elif (options.keyishex is None and options.key in private_keys) or (options.keyishex is not None and options.key in private_hex_keys):
print "Already exists"
else:
db = open_wallet(db_env, determine_db_name(), writable=True)
if importprivkey(db, options.key, options.label, options.reserve, options.keyishex):
print "Imported successfully"
else:
print "Bad private key"
db.close()
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