加密算法的Python實現
加密算法的Python實現
資料來源: https://mp.weixin.qq.com/s?__biz=MzI0OTc0MzAwNA==&mid=2247487280&idx=1&sn=7df3d387858fbd7a1038590f092e794e&chksm=e98d9cc3defa15d54afa2105ffe16d8b220c9a4f8b605465451f11b0188ca00b70c2b4e3fc66&scene=126&sessionid=1590656229&key=92af3b4f675ed7b95b9ac578c18e16c5361ce2ce5ce642b4832de5c7f4c467cdfb9ae15593cba4348963bb62acc3999be98a89b6945097d26a6746be1992356d1967e03f3d586a052d9b02d06420ca87&ascene=1&uin=MjIwODk2NDgxNw%3D%3D&devicetype=Windows+10+x64&version=62090070&lang=zh_TW&exportkey=Ag%2FERj3%2BgOHhUIrLp2DIiGs%3D&pass_ticket=f2btuhQtjpwawpmYVZ5nuy81oqKtACunlDAuNeh9SS47I17w1KZHbkl2MIP5tqMa
一、MD5加密
import hashlib
m = hashlib.md5()
m.update(str.encode("utf8"))
print(m.hexdigest())
二、SHA1加密
import hashlib
sha1 = hashlib.sha1()
data = '2333333'
sha1.update(data.encode('utf-8'))
sha1_data = sha1.hexdigest()
print(sha1_data)
三、HMAC加密
import hmac
import hashlib
# 第一个参数是密钥key,第二个参数是待加密的字符串,第三个参数是hash函数
mac = hmac.new('key','hello',hashlib.md5)
mac.digest() # 字符串的ascii格式
mac.hexdigest() # 加密后字符串的十六进制格式
四、DES加密
import binascii
from pyDes import des, CBC, PAD_PKCS5
# 需要安装 pip install pyDes
def des_encrypt(secret_key, s):
iv = secret_key
k = des(secret_key, CBC, iv, pad=None, padmode=PAD_PKCS5)
en = k.encrypt(s, padmode=PAD_PKCS5)
return binascii.b2a_hex(en)
def des_decrypt(secret_key, s):
iv = secret_key
k = des(secret_key, CBC, iv, pad=None, padmode=PAD_PKCS5)
de = k.decrypt(binascii.a2b_hex(s), padmode=PAD_PKCS5)
return de
secret_str = des_encrypt('12345678', 'I love YOU~')
print(secret_str)
clear_str = des_decrypt('12345678', secret_str)
print(clear_str)
五、AES加密
import base64
from Crypto.Cipher import AES
'''
AES对称加密算法
'''
# 需要补位,str不是16的倍数那就补足为16的倍数
def add_to_16(value):
while len(value) % 16 != 0:
value += '\0'
return str.encode(value) # 返回bytes
# 加密方法
def encrypt(key, text):
aes = AES.new(add_to_16(key), AES.MODE_ECB) # 初始化加密器
encrypt_aes = aes.encrypt(add_to_16(text)) # 先进行aes加密
encrypted_text = str(base64.encodebytes(encrypt_aes), encoding='utf-8') # 执行加密并转码返回bytes
return encrypted_text
# 解密方法
def decrypt(key, text):
aes = AES.new(add_to_16(key), AES.MODE_ECB) # 初始化加密器
base64_decrypted = base64.decodebytes(text.encode(encoding='utf-8')) # 优先逆向解密base64成bytes
decrypted_text = str(aes.decrypt(base64_decrypted), encoding='utf-8').replace('\0', '') # 执行解密密并转码返回str
return decrypted_text
六、RSA加密
# -*- coding: UTF-8 -*-
# reference codes: https://www.jianshu.com/p/7a4645691c68
import base64
import rsa
from rsa import common
# 使用 rsa库进行RSA签名和加解密
class RsaUtil(object):
PUBLIC_KEY_PATH = 'xxxxpublic_key.pem' # 公钥
PRIVATE_KEY_PATH = 'xxxxxprivate_key.pem' # 私钥
# 初始化key
def __init__(self,
company_pub_file=PUBLIC_KEY_PATH,
company_pri_file=PRIVATE_KEY_PATH):
if company_pub_file:
self.company_public_key = rsa.PublicKey.load_pkcs1_openssl_pem(open(company_pub_file).read())
if company_pri_file:
self.company_private_key = rsa.PrivateKey.load_pkcs1(open(company_pri_file).read())
def get_max_length(self, rsa_key, encrypt=True):
"""加密内容过长时 需要分段加密 换算每一段的长度.
:param rsa_key: 钥匙.
:param encrypt: 是否是加密.
"""
blocksize = common.byte_size(rsa_key.n)
reserve_size = 11 # 预留位为11
if not encrypt: # 解密时不需要考虑预留位
reserve_size = 0
maxlength = blocksize - reserve_size
return maxlength
# 加密 支付方公钥
def encrypt_by_public_key(self, message):
"""使用公钥加密.
:param message: 需要加密的内容.
加密之后需要对接过进行base64转码
"""
encrypt_result = b''
max_length = self.get_max_length(self.company_public_key)
while message:
input = message[:max_length]
message = message[max_length:]
out = rsa.encrypt(input, self.company_public_key)
encrypt_result += out
encrypt_result = base64.b64encode(encrypt_result)
return encrypt_result
def decrypt_by_private_key(self, message):
"""使用私钥解密.
:param message: 需要加密的内容.
解密之后的内容直接是字符串,不需要在进行转义
"""
decrypt_result = b""
max_length = self.get_max_length(self.company_private_key, False)
decrypt_message = base64.b64decode(message)
while decrypt_message:
input = decrypt_message[:max_length]
decrypt_message = decrypt_message[max_length:]
out = rsa.decrypt(input, self.company_private_key)
decrypt_result += out
return decrypt_result
# 签名 商户私钥 base64转码
def sign_by_private_key(self, data):
"""私钥签名.
:param data: 需要签名的内容.
使用SHA-1 方法进行签名(也可以使用MD5)
签名之后,需要转义后输出
"""
signature = rsa.sign(str(data), priv_key=self.company_private_key, hash='SHA-1')
return base64.b64encode(signature)
def verify_by_public_key(self, message, signature):
"""公钥验签.
:param message: 验签的内容.
:param signature: 对验签内容签名的值(签名之后,会进行b64encode转码,所以验签前也需转码).
"""
signature = base64.b64decode(signature)
return rsa.verify(message, signature, self.company_public_key)
七、ECC加密
# -*- coding:utf-8 *-
# author: DYBOY
# reference codes: https://blog.dyboy.cn/websecurity/121.html
# description: ECC椭圆曲线加密算法实现
"""
考虑K=kG ,其中K、G为椭圆曲线Ep(a,b)上的点,n为G的阶(nG=O∞ ),k为小于n的整数。
则给定k和G,根据加法法则,计算K很容易但反过来,给定K和G,求k就非常困难。
因为实际使用中的ECC原则上把p取得相当大,n也相当大,要把n个解点逐一算出来列成上表是不可能的。
这就是椭圆曲线加密算法的数学依据
点G称为基点(base point)
k(k<n)为私有密钥(privte key)
K为公开密钥(public key)
"""
def get_inverse(mu, p):
"""
获取y的负元
"""
for i in range(1, p):
if (i*mu)%p == 1:
return i
return -1
def get_gcd(zi, mu):
"""
获取最大公约数
"""
if mu:
return get_gcd(mu, zi%mu)
else:
return zi
def get_np(x1, y1, x2, y2, a, p):
"""
获取n*p,每次+p,直到求解阶数np=-p
"""
flag = 1 # 定义符号位(+/-)
# 如果 p=q k=(3x2+a)/2y1mod p
if x1 == x2 and y1 == y2:
zi = 3 * (x1 ** 2) + a # 计算分子 【求导】
mu = 2 * y1 # 计算分母
# 若P≠Q,则k=(y2-y1)/(x2-x1) mod p
else:
zi = y2 - y1
mu = x2 - x1
if zi* mu < 0:
flag = 0 # 符号0为-(负数)
zi = abs(zi)
mu = abs(mu)
# 将分子和分母化为最简
gcd_value = get_gcd(zi, mu) # 最大公約數
zi = zi // gcd_value # 整除
mu = mu // gcd_value
# 求分母的逆元 逆元: ∀a ∈G ,ョb∈G 使得 ab = ba = e
# P(x,y)的负元是 (x,-y mod p)= (x,p-y) ,有P+(-P)= O∞
inverse_value = get_inverse(mu, p)
k = (zi * inverse_value)
if flag == 0: # 斜率负数 flag==0
k = -k
k = k % p
# 计算x3,y3 P+Q
"""
x3≡k2-x1-x2(mod p)
y3≡k(x1-x3)-y1(mod p)
"""
x3 = (k ** 2 - x1 - x2) % p
y3 = (k * (x1 - x3) - y1) % p
return x3,y3
def get_rank(x0, y0, a, b, p):
"""
获取椭圆曲线的阶
"""
x1 = x0 #-p的x坐标
y1 = (-1*y0)%p #-p的y坐标
tempX = x0
tempY = y0
n = 1
while True:
n += 1
# 求p+q的和,得到n*p,直到求出阶
p_x,p_y = get_np(tempX, tempY, x0, y0, a, p)
# 如果 == -p,那么阶数+1,返回
if p_x == x1 and p_y == y1:
return n+1
tempX = p_x
tempY = p_y
def get_param(x0, a, b, p):
"""
计算p与-p
"""
y0 = -1
for i in range(p):
# 满足取模约束条件,椭圆曲线Ep(a,b),p为质数,x,y∈[0,p-1]
if i**2%p == (x0**3 + a*x0 + b)%p:
y0 = i
break
# 如果y0没有,返回false
if y0 == -1:
return False
# 计算-y(负数取模)
x1 = x0
y1 = (-1*y0) % p
return x0,y0,x1,y1
def get_graph(a, b, p):
"""
输出椭圆曲线散点图
"""
x_y = []
# 初始化二维数组
for i in range(p):
x_y.append(['-' for i in range(p)])
for i in range(p):
val =get_param(i, a, b, p) # 椭圆曲线上的点
if(val != False):
x0,y0,x1,y1 = val
x_y[x0][y0] = 1
x_y[x1][y1] = 1
print("椭圆曲线的散列图为:")
for i in range(p): # i= 0-> p-1
temp = p-1-i # 倒序
# 格式化输出1/2位数,y坐标轴
if temp >= 10:
print(temp, end=" ")
else:
print(temp, end=" ")
# 输出具体坐标的值,一行
for j in range(p):
print(x_y[j][temp], end=" ")
print("") #换行
# 输出 x 坐标轴
print(" ", end="")
for i in range(p):
if i >=10:
print(i, end=" ")
else:
print(i, end=" ")
print('\n')
def get_ng(G_x, G_y, key, a, p):
"""
计算nG
"""
temp_x = G_x
temp_y = G_y
while key != 1:
temp_x,temp_y = get_np(temp_x,temp_y, G_x, G_y, a, p)
key -= 1
return temp_x,temp_y
def ecc_main():
while True:
a = int(input("请输入椭圆曲线参数a(a>0)的值:"))
b = int(input("请输入椭圆曲线参数b(b>0)的值:"))
p = int(input("请输入椭圆曲线参数p(p为素数)的值:")) #用作模运算
# 条件满足判断
if (4*(a**3)+27*(b**2))%p == 0:
print("您输入的参数有误,请重新输入!!!\n")
else:
break
# 输出椭圆曲线散点图
get_graph(a, b, p)
# 选点作为G点
print("user1:在如上坐标系中选一个值为G的坐标")
G_x = int(input("user1:请输入选取的x坐标值:"))
G_y = int(input("user1:请输入选取的y坐标值:"))
# 获取椭圆曲线的阶
n = get_rank(G_x, G_y, a, b, p)
# user1生成私钥,小key
key = int(input("user1:请输入私钥小key(<{}):".format(n)))
# user1生成公钥,大KEY
KEY_x,kEY_y = get_ng(G_x, G_y, key, a, p)
# user2阶段
# user2拿到user1的公钥KEY,Ep(a,b)阶n,加密需要加密的明文数据
# 加密准备
k = int(input("user2:请输入一个整数k(<{})用于求kG和kQ:".format(n)))
k_G_x,k_G_y = get_ng(G_x, G_y, k, a, p) # kG
k_Q_x,k_Q_y = get_ng(KEY_x, kEY_y, k, a, p) # kQ
# 加密
plain_text = input("user2:请输入需要加密的字符串:")
plain_text = plain_text.strip()
#plain_text = int(input("user1:请输入需要加密的密文:"))
c = []
print("密文为:",end="")
for char in plain_text:
intchar = ord(char)
cipher_text = intchar*k_Q_x
c.append([k_G_x, k_G_y, cipher_text])
print("({},{}),{}".format(k_G_x, k_G_y, cipher_text),end="-")
# user1阶段
# 拿到user2加密的数据进行解密
# 知道 k_G_x,k_G_y,key情况下,求解k_Q_x,k_Q_y是容易的,然后plain_text = cipher_text/k_Q_x
print("\nuser1解密得到明文:",end="")
for charArr in c:
decrypto_text_x,decrypto_text_y = get_ng(charArr[0], charArr[1], key, a, p)
print(chr(charArr[2]//decrypto_text_x),end="")
if __name__ == "__main__":
print("*************ECC椭圆曲线加密*************")
ecc_main()