写在前面
在需求开发中,为了安全起见,我们都会难免遇到需要对一些敏感参数进行加密或者解密。所以,今天给大家分享的就是使用jsencrypt对请求参数进行RSA加密与解密,发这篇文章其实主要因为近期我的一位朋友问我关于jsencrypt的加密问题,记得在很早之前隐约记得整过一次这玩意,所以今天又给整理了一下,把整个的操作流程当做一篇文章给记录下来,以防急时之需!!!
如何使用?
使用之前,需要给项目引入jsencrypt依赖,如果你是工程项目,请给项目中拉取以下依赖
npm install jsencrypt --save
拉取之后可以通过以下方式引入到项目中进行使用
import JSEncrypt from 'jsencrypt'
如果是传统开发的朋友,请不用着急,本次讲解的demo就是使用的传统方式。
jsencrypt在加密或者解密的时候需要用到密钥,所以需要先生成一对密钥:公钥(加密),私钥(解密)。
生成方法
在终端(基于Unix的操作系统)中输入以下命令
openssl genrsa -out rsa_1024_priv.pem 1024
执行这段命令后会生成一个私钥,可以通过执行以下操作进行查看
cat rsa_1024_priv.pem
然后就可以将其复制并粘贴到需要使用私钥的地方即可。
接下来,可以通过执行以下命令获取公钥
openssl rsa -pubout -in rsa_1024_priv.pem -out rsa_1024_pub.pem
同样,可以通过执行以下操作进行查看
cat rsa_1024_pub.pem
如果已经完成了以上操作,那么恭喜你,你现在可以去给参数进行加密了。
如何给参数加密?
给简单的字符串进行加密与解密,可以使用以下方式
//加密获得签名,key公钥,str加密对字符串内容
function getCode(key, str) {
var encrypt = new JSEncrypt()
encrypt.setPublicKey(key)
var data = encrypt.encrypt(str)
return data
}
//解密获得明文,key私钥,str加密后的签名
function deCode(key, str) {
var encrypt = new JSEncrypt()
encrypt.setPrivateKey(key)
var data = encrypt.decrypt(str)
return data
}如果是给一段较长的字符串加密,这里可能就会有坑了,因为长度问题可能会造成加解密失败,如果你遇到了,请使用下面方式进行分段加解密,这样就解决了该问题的出现
//分段加密算法方法
JSEncrypt.prototype.encryptLong = function (string) {
var k = this.getKey(),
maxLength = (((k.n.bitLength()+7)>>3)-11); try { var lt = "",
ct = ""; if (string.length > maxLength) {
lt = string.match(/.{1,50}/g);
lt.forEach(entry => { var t1 = k.encrypt(entry);
ct += t1 ;
}); return hex2b64(ct);
} var t = k.encrypt(string),
y = hex2b64(t); return y;
} catch (ex) { return ex;
}
};
//分段解密算法方法
JSEncrypt.prototype.decryptLong = function (string) {
var k = this.getKey(),
maxLength = (((k.n.bitLength()+7)>>3)-11); try {
var ct = '';
string = b64tohex(string) if (string.length > maxLength) {
var lt = string.match(/.{1,256}/g);
lt.forEach(function(entry) {
var t1 = k.decrypt(entry);
ct += t1;
}); return ct;
}
var y = k.decrypt(b64tohex(string));
return y;
} catch (ex) { return ex;
}
};
//分段加密
function getLongCode(key, str) {
var encrypt = new JSEncrypt()
encrypt.setPublicKey(key)
var data = encrypt.encryptLong(str)
return data
}
//分段解密
function deLongCode(key, str) {
var decryptLong = new JSEncrypt()
decryptLong.setPrivateKey(key)
var data = decryptLong.decryptLong(str)
return /^{.+}$/g.test(data) && JSON.parse(data) || data
}上方代码中出现了几个未定义的方法,hex2b64,b64tohex,这两个方法是base64分段的算法函数,下面是补充的算法封装函数依赖
var dbits;
var canary = 244837814094590;
var j_lm = ((canary & 16777215) == 15715070);
function BigInteger(e, d, f) {
if (e != null) {
if ("number" == typeof e) {
this.fromNumber(e, d, f)
} else {
if (d == null && "string" != typeof e) {
this.fromString(e, 256)
} else {
this.fromString(e, d)
}
}
}
}
function nbi() {
return new BigInteger(null)
}
function am1(f, a, b, e, h, g) {
while (--g >= 0) {
var d = a * this[f++] + b[e] + h;
h = Math.floor(d / 67108864);
b[e++] = d & 67108863
}
return h
}
function am2(f, q, r, e, o, a) {
var k = q & 32767,
p = q >> 15;
while (--a >= 0) {
var d = this[f] & 32767;
var g = this[f++] >> 15;
var b = p * d + g * k;
d = k * d + ((b & 32767) << 15) + r[e] + (o & 1073741823);
o = (d >>> 30) + (b >>> 15) + p * g + (o >>> 30);
r[e++] = d & 1073741823
}
return o
}
function am3(f, q, r, e, o, a) {
var k = q & 16383,
p = q >> 14;
while (--a >= 0) {
var d = this[f] & 16383;
var g = this[f++] >> 14;
var b = p * d + g * k;
d = k * d + ((b & 16383) << 14) + r[e] + o;
o = (d >> 28) + (b >> 14) + p * g;
r[e++] = d & 268435455
}
return o
}
//if (j_lm && (navigator.appName == "Microsoft Internet Explorer")) { //xpp注释
// BigInteger.prototype.am = am2;
// dbits = 30
//} else {
// if (j_lm && (navigator.appName != "Netscape")) {
// BigInteger.prototype.am = am1;
// dbits = 26
// } else {
BigInteger.prototype.am = am3;
dbits = 28
// }
//}
BigInteger.prototype.DB = dbits;
BigInteger.prototype.DM = ((1 << dbits) - 1);
BigInteger.prototype.DV = (1 << dbits);
var BI_FP = 52;
BigInteger.prototype.FV = Math.pow(2, BI_FP);
BigInteger.prototype.F1 = BI_FP - dbits;
BigInteger.prototype.F2 = 2 * dbits - BI_FP;
var BI_RM = "0123456789abcdefghijklmnopqrstuvwxyz";
var BI_RC = new Array();
var rr, vv;
rr = "0".charCodeAt(0);
for (vv = 0; vv <= 9; ++vv) {
BI_RC[rr++] = vv
}
rr = "a".charCodeAt(0);
for (vv = 10; vv < 36; ++vv) {
BI_RC[rr++] = vv
}
rr = "A".charCodeAt(0);
for (vv = 10; vv < 36; ++vv) {
BI_RC[rr++] = vv
}
function int2char(a) {
return BI_RM.charAt(a)
}
function intAt(b, a) {
var d = BI_RC[b.charCodeAt(a)];
return (d == null) ? -1 : d
}
function bnpToRadix(b) {
if (b == null) {
b = 10
}
if (this.signum() == 0 || b < 2 || b > 36) {
return "0"
}
var cs = this.chunkSize(b);
var a = Math.pow(b, cs);
var d = nbv(a),
y = nbi(),
z = nbi(),
r = "";
this.divRemTo(d, y, z);
while (y.signum() > 0) {
r = (a + z.intValue()).toString(b).substr(1) + r;
y.divRemTo(d, y, z)
}
return z.intValue().toString(b) + r
}
function bnSigNum() {
if (this.s < 0) {
return - 1
} else {
if (this.t <= 0 || (this.t == 1 && this[0] <= 0)) {
return 0
} else {
return 1
}
}
}
function bnpChunkSize(r) {
return Math.floor(Math.LN2 * this.DB / Math.log(r))
}
function bnIntValue() {
if (this.s < 0) {
if (this.t == 1) {
return this[0] - this.DV
} else {
if (this.t == 0) {
return - 1
}
}
} else {
if (this.t == 1) {
return this[0]
} else {
if (this.t == 0) {
return 0
}
}
}
return ((this[1] & ((1 << (32 - this.DB)) - 1)) << this.DB) | this[0]
}
function bnpCopyTo(b) {
for (var a = this.t - 1; a >= 0; --a) {
b[a] = this[a]
}
b.t = this.t;
b.s = this.s
}
function bnpFromInt(a) {
this.t = 1;
this.s = (a < 0) ? -1 : 0;
if (a > 0) {
this[0] = a
} else {
if (a < -1) {
this[0] = a + DV
} else {
this.t = 0
}
}
}
function nbv(a) {
var b = nbi();
b.fromInt(a);
return b
}
function bnpFromString(h, c) {
var e;
if (c == 16) {
e = 4
} else {
if (c == 8) {
e = 3
} else {
if (c == 256) {
e = 8
} else {
if (c == 2) {
e = 1
} else {
if (c == 32) {
e = 5
} else {
if (c == 4) {
e = 2
} else {
this.fromRadix(h, c);
return
}
}
}
}
}
}
this.t = 0;
this.s = 0;
var g = h.length,
d = false,
f = 0;
while (--g >= 0) {
var a = (e == 8) ? h[g] & 255 : intAt(h, g);
if (a < 0) {
if (h.charAt(g) == "-") {
d = true
}
continue
}
d = false;
if (f == 0) {
this[this.t++] = a
} else {
if (f + e > this.DB) {
this[this.t - 1] |= (a & ((1 << (this.DB - f)) - 1)) << f;
this[this.t++] = (a >> (this.DB - f))
} else {
this[this.t - 1] |= a << f
}
}
f += e;
if (f >= this.DB) {
f -= this.DB
}
}
if (e == 8 && (h[0] & 128) != 0) {
this.s = -1;
if (f > 0) {
this[this.t - 1] |= ((1 << (this.DB - f)) - 1) << f
}
}
this.clamp();
if (d) {
BigInteger.ZERO.subTo(this, this)
}
}
function bnpClamp() {
var a = this.s & this.DM;
while (this.t > 0 && this[this.t - 1] == a) {--this.t
}
}
function bnToString(c) {
if (this.s < 0) {
return "-" + this.negate().toString(c)
}
var e;
if (c == 16) {
e = 4
} else {
if (c == 8) {
e = 3
} else {
if (c == 2) {
e = 1
} else {
if (c == 32) {
e = 5
} else {
if (c == 4) {
e = 2
} else {
return this.toRadix(c)
}
}
}
}
}
var g = (1 << e) - 1,
l,
a = false,
h = "",
f = this.t;
var j = this.DB - (f * this.DB) % e;
if (f-->0) {
if (j < this.DB && (l = this[f] >> j) > 0) {
a = true;
h = int2char(l)
}
while (f >= 0) {
if (j < e) {
l = (this[f] & ((1 << j) - 1)) << (e - j);
l |= this[--f] >> (j += this.DB - e)
} else {
l = (this[f] >> (j -= e)) & g;
if (j <= 0) {
j += this.DB; --f
}
}
if (l > 0) {
a = true
}
if (a) {
h += int2char(l)
}
}
}
return a ? h: "0"
}
function bnNegate() {
var a = nbi();
BigInteger.ZERO.subTo(this, a);
return a
}
function bnAbs() {
return (this.s < 0) ? this.negate() : this
}
function bnCompareTo(b) {
var d = this.s - b.s;
if (d != 0) {
return d
}
var c = this.t;
d = c - b.t;
if (d != 0) {
return (this.s < 0) ? -d: d
}
while (--c >= 0) {
if ((d = this[c] - b[c]) != 0) {
return d
}
}
return 0
}
function nbits(a) {
var c = 1,
b;
if ((b = a >>> 16) != 0) {
a = b;
c += 16
}
if ((b = a >> 8) != 0) {
a = b;
c += 8
}
if ((b = a >> 4) != 0) {
a = b;
c += 4
}
if ((b = a >> 2) != 0) {
a = b;
c += 2
}
if ((b = a >> 1) != 0) {
a = b;
c += 1
}
return c
}
function bnBitLength() {
if (this.t <= 0) {
return 0
}
return this.DB * (this.t - 1) + nbits(this[this.t - 1] ^ (this.s & this.DM))
}
function bnpDLShiftTo(c, b) {
var a;
for (a = this.t - 1; a >= 0; --a) {
b[a + c] = this[a]
}
for (a = c - 1; a >= 0; --a) {
b[a] = 0
}
b.t = this.t + c;
b.s = this.s
}
function bnpDRShiftTo(c, b) {
for (var a = c; a < this.t; ++a) {
b[a - c] = this[a]
}
b.t = Math.max(this.t - c, 0);
b.s = this.s
}
function bnpLShiftTo(j, e) {
var b = j % this.DB;
var a = this.DB - b;
var g = (1 << a) - 1;
var f = Math.floor(j / this.DB),
h = (this.s << b) & this.DM,
d;
for (d = this.t - 1; d >= 0; --d) {
e[d + f + 1] = (this[d] >> a) | h;
h = (this[d] & g) << b
}
for (d = f - 1; d >= 0; --d) {
e[d] = 0
}
e[f] = h;
e.t = this.t + f + 1;
e.s = this.s;
e.clamp()
}
function bnpRShiftTo(g, d) {
d.s = this.s;
var e = Math.floor(g / this.DB);
if (e >= this.t) {
d.t = 0;
return
}
var b = g % this.DB;
var a = this.DB - b;
var f = (1 << b) - 1;
d[0] = this[e] >> b;
for (var c = e + 1; c < this.t; ++c) {
d[c - e - 1] |= (this[c] & f) << a;
d[c - e] = this[c] >> b
}
if (b > 0) {
d[this.t - e - 1] |= (this.s & f) << a
}
d.t = this.t - e;
d.clamp()
}
function bnpSubTo(d, f) {
var e = 0,
g = 0,
b = Math.min(d.t, this.t);
while (e < b) {
g += this[e] - d[e];
f[e++] = g & this.DM;
g >>= this.DB
}
if (d.t < this.t) {
g -= d.s;
while (e < this.t) {
g += this[e];
f[e++] = g & this.DM;
g >>= this.DB
}
g += this.s
} else {
g += this.s;
while (e < d.t) {
g -= d[e];
f[e++] = g & this.DM;
g >>= this.DB
}
g -= d.s
}
f.s = (g < 0) ? -1 : 0;
if (g < -1) {
f[e++] = this.DV + g
} else {
if (g > 0) {
f[e++] = g
}
}
f.t = e;
f.clamp()
}
function bnpMultiplyTo(c, e) {
var b = this.abs(),
f = c.abs();
var d = b.t;
e.t = d + f.t;
while (--d >= 0) {
e[d] = 0
}
for (d = 0; d < f.t; ++d) {
e[d + b.t] = b.am(0, f[d], e, d, 0, b.t)
}
e.s = 0;
e.clamp();
if (this.s != c.s) {
BigInteger.ZERO.subTo(e, e)
}
}
function bnpSquareTo(d) {
var a = this.abs();
var b = d.t = 2 * a.t;
while (--b >= 0) {
d[b] = 0
}
for (b = 0; b < a.t - 1; ++b) {
var e = a.am(b, a[b], d, 2 * b, 0, 1);
if ((d[b + a.t] += a.am(b + 1, 2 * a[b], d, 2 * b + 1, e, a.t - b - 1)) >= a.DV) {
d[b + a.t] -= a.DV;
d[b + a.t + 1] = 1
}
}
if (d.t > 0) {
d[d.t - 1] += a.am(b, a[b], d, 2 * b, 0, 1)
}
d.s = 0;
d.clamp()
}
function bnpDivRemTo(n, h, g) {
var w = n.abs();
if (w.t <= 0) {
return
}
var k = this.abs();
if (k.t < w.t) {
if (h != null) {
h.fromInt(0)
}
if (g != null) {
this.copyTo(g)
}
return
}
if (g == null) {
g = nbi()
}
var d = nbi(),
a = this.s,
l = n.s;
var v = this.DB - nbits(w[w.t - 1]);
if (v > 0) {
w.lShiftTo(v, d);
k.lShiftTo(v, g)
} else {
w.copyTo(d);
k.copyTo(g)
}
var p = d.t;
var b = d[p - 1];
if (b == 0) {
return
}
var o = b * (1 << this.F1) + ((p > 1) ? d[p - 2] >> this.F2: 0);
var A = this.FV / o,
z = (1 << this.F1) / o,
x = 1 << this.F2;
var u = g.t,
s = u - p,
f = (h == null) ? nbi() : h;
d.dlShiftTo(s, f);
if (g.compareTo(f) >= 0) {
g[g.t++] = 1;
g.subTo(f, g)
}
BigInteger.ONE.dlShiftTo(p, f);
f.subTo(d, d);
while (d.t < p) {
d[d.t++] = 0
}
while (--s >= 0) {
var c = (g[--u] == b) ? this.DM: Math.floor(g[u] * A + (g[u - 1] + x) * z);
if ((g[u] += d.am(0, c, g, s, 0, p)) < c) {
d.dlShiftTo(s, f);
g.subTo(f, g);
while (g[u] < --c) {
g.subTo(f, g)
}
}
}
if (h != null) {
g.drShiftTo(p, h);
if (a != l) {
BigInteger.ZERO.subTo(h, h)
}
}
g.t = p;
g.clamp();
if (v > 0) {
g.rShiftTo(v, g)
}
if (a < 0) {
BigInteger.ZERO.subTo(g, g)
}
}
function bnMod(b) {
var c = nbi();
this.abs().divRemTo(b, null, c);
if (this.s < 0 && c.compareTo(BigInteger.ZERO) > 0) {
b.subTo(c, c)
}
return c
}
function Classic(a) {
this.m = a
}
function cConvert(a) {
if (a.s < 0 || a.compareTo(this.m) >= 0) {
return a.mod(this.m)
} else {
return a
}
}
function cRevert(a) {
return a
}
function cReduce(a) {
a.divRemTo(this.m, null, a)
}
function cMulTo(a, c, b) {
a.multiplyTo(c, b);
this.reduce(b)
}
function cSqrTo(a, b) {
a.squareTo(b);
this.reduce(b)
}
Classic.prototype.convert = cConvert;
Classic.prototype.revert = cRevert;
Classic.prototype.reduce = cReduce;
Classic.prototype.mulTo = cMulTo;
Classic.prototype.sqrTo = cSqrTo;
function bnpInvDigit() {
if (this.t < 1) {
return 0
}
var a = this[0];
if ((a & 1) == 0) {
return 0
}
var b = a & 3;
b = (b * (2 - (a & 15) * b)) & 15;
b = (b * (2 - (a & 255) * b)) & 255;
b = (b * (2 - (((a & 65535) * b) & 65535))) & 65535;
b = (b * (2 - a * b % this.DV)) % this.DV;
return (b > 0) ? this.DV - b: -b
}
function Montgomery(a) {
this.m = a;
this.mp = a.invDigit();
this.mpl = this.mp & 32767;
this.mph = this.mp >> 15;
this.um = (1 << (a.DB - 15)) - 1;
this.mt2 = 2 * a.t
}
function montConvert(a) {
var b = nbi();
a.abs().dlShiftTo(this.m.t, b);
b.divRemTo(this.m, null, b);
if (a.s < 0 && b.compareTo(BigInteger.ZERO) > 0) {
this.m.subTo(b, b)
}
return b
}
function montRevert(a) {
var b = nbi();
a.copyTo(b);
this.reduce(b);
return b
}
function montReduce(a) {
while (a.t <= this.mt2) {
a[a.t++] = 0
}
for (var c = 0; c < this.m.t; ++c) {
var b = a[c] & 32767;
var d = (b * this.mpl + (((b * this.mph + (a[c] >> 15) * this.mpl) & this.um) << 15)) & a.DM;
b = c + this.m.t;
a[b] += this.m.am(0, d, a, c, 0, this.m.t);
while (a[b] >= a.DV) {
a[b] -= a.DV;
a[++b]++
}
}
a.clamp();
a.drShiftTo(this.m.t, a);
if (a.compareTo(this.m) >= 0) {
a.subTo(this.m, a)
}
}
function montSqrTo(a, b) {
a.squareTo(b);
this.reduce(b)
}
function montMulTo(a, c, b) {
a.multiplyTo(c, b);
this.reduce(b)
}
Montgomery.prototype.convert = montConvert;
Montgomery.prototype.revert = montRevert;
Montgomery.prototype.reduce = montReduce;
Montgomery.prototype.mulTo = montMulTo;
Montgomery.prototype.sqrTo = montSqrTo;
function bnpIsEven() {
return ((this.t > 0) ? (this[0] & 1) : this.s) == 0
}
function bnpExp(h, j) {
if (h > 4294967295 || h < 1) {
return BigInteger.ONE
}
var f = nbi(),
a = nbi(),
d = j.convert(this),
c = nbits(h) - 1;
d.copyTo(f);
while (--c >= 0) {
j.sqrTo(f, a);
if ((h & (1 << c)) > 0) {
j.mulTo(a, d, f)
} else {
var b = f;
f = a;
a = b
}
}
return j.revert(f)
}
function bnModPowInt(b, a) {
var c;
if (b < 256 || a.isEven()) {
c = new Classic(a)
} else {
c = new Montgomery(a)
}
return this.exp(b, c)
}
BigInteger.prototype.toRadix = bnpToRadix;
BigInteger.prototype.signum = bnSigNum;
BigInteger.prototype.chunkSize = bnpChunkSize;
BigInteger.prototype.intValue = bnIntValue;
BigInteger.prototype.copyTo = bnpCopyTo;
BigInteger.prototype.fromInt = bnpFromInt;
BigInteger.prototype.fromString = bnpFromString;
BigInteger.prototype.clamp = bnpClamp;
BigInteger.prototype.dlShiftTo = bnpDLShiftTo;
BigInteger.prototype.drShiftTo = bnpDRShiftTo;
BigInteger.prototype.lShiftTo = bnpLShiftTo;
BigInteger.prototype.rShiftTo = bnpRShiftTo;
BigInteger.prototype.subTo = bnpSubTo;
BigInteger.prototype.multiplyTo = bnpMultiplyTo;
BigInteger.prototype.squareTo = bnpSquareTo;
BigInteger.prototype.divRemTo = bnpDivRemTo;
BigInteger.prototype.invDigit = bnpInvDigit;
BigInteger.prototype.isEven = bnpIsEven;
BigInteger.prototype.exp = bnpExp;
BigInteger.prototype.toString = bnToString;
BigInteger.prototype.negate = bnNegate;
BigInteger.prototype.abs = bnAbs;
BigInteger.prototype.compareTo = bnCompareTo;
BigInteger.prototype.bitLength = bnBitLength;
BigInteger.prototype.mod = bnMod;
BigInteger.prototype.modPowInt = bnModPowInt;
BigInteger.ZERO = nbv(0);
BigInteger.ONE = nbv(1);
function Arcfour() {
this.i = 0;
this.j = 0;
this.S = new Array()
}
function ARC4init(d) {
var c, a, b;
for (c = 0; c < 256; ++c) {
this.S[c] = c
}
a = 0;
for (c = 0; c < 256; ++c) {
a = (a + this.S[c] + d[c % d.length]) & 255;
b = this.S[c];
this.S[c] = this.S[a];
this.S[a] = b
}
this.i = 0;
this.j = 0
}
function ARC4next() {
var a;
this.i = (this.i + 1) & 255;
this.j = (this.j + this.S[this.i]) & 255;
a = this.S[this.i];
this.S[this.i] = this.S[this.j];
this.S[this.j] = a;
return this.S[(a + this.S[this.i]) & 255]
}
Arcfour.prototype.init = ARC4init;
Arcfour.prototype.next = ARC4next;
function prng_newstate() {
return new Arcfour()
}
var rng_psize = 256;
var rng_state;
var rng_pool;
var rng_pptr;
function rng_seed_int(a) {
rng_pool[rng_pptr++] ^= a & 255;
rng_pool[rng_pptr++] ^= (a >> 8) & 255;
rng_pool[rng_pptr++] ^= (a >> 16) & 255;
rng_pool[rng_pptr++] ^= (a >> 24) & 255;
if (rng_pptr >= rng_psize) {
rng_pptr -= rng_psize
}
}
function rng_seed_time() {
rng_seed_int(new Date().getTime())
}
if (rng_pool == null) { //注释
rng_pool = new Array();
rng_pptr = 0;
var t;
// if (navigator.appName == "Netscape" && navigator.appVersion < "5" && window.crypto) {
// var z = window.crypto.random(32);
// for (t = 0; t < z.length; ++t) {
// rng_pool[rng_pptr++] = z.charCodeAt(t) & 255
// }
// }
// while (rng_pptr < rng_psize) {
// t = Math.floor(65536 * Math.random());
// rng_pool[rng_pptr++] = t >>> 8;
// rng_pool[rng_pptr++] = t & 255
// }
// rng_pptr = 0;
// rng_seed_time()
}
function rng_get_byte() {
if (rng_state == null) {
rng_seed_time();
rng_state = prng_newstate();
rng_state.init(rng_pool);
for (rng_pptr = 0; rng_pptr < rng_pool.length; ++rng_pptr) {
rng_pool[rng_pptr] = 0
}
rng_pptr = 0
}
return rng_state.next()
}
function rng_get_bytes(b) {
var a;
for (a = 0; a < b.length; ++a) {
b[a] = rng_get_byte()
}
}
function SecureRandom() {}
SecureRandom.prototype.nextBytes = rng_get_bytes;
function parseBigInt(b, a) {
return new BigInteger(b, a)
}
function linebrk(c, d) {
var a = "";
var b = 0;
while (b + d < c.length) {
a += c.substring(b, b + d) + "\n";
b += d
}
return a + c.substring(b, c.length)
}
function byte2Hex(a) {
if (a < 16) {
return "0" + a.toString(16)
} else {
return a.toString(16)
}
}
function pkcs1pad2(e, h) {
if (h < e.length + 11) {
// alert("Message too long for RSA");
return null
}
var g = new Array();
var d = e.length - 1;
while (d >= 0 && h > 0) {
var f = e.charCodeAt(d--);
if (f < 128) {
g[--h] = f
} else {
if ((f > 127) && (f < 2048)) {
g[--h] = (f & 63) | 128;
g[--h] = (f >> 6) | 192
} else {
g[--h] = (f & 63) | 128;
g[--h] = ((f >> 6) & 63) | 128;
g[--h] = (f >> 12) | 224
}
}
}
g[--h] = 0;
var b = new SecureRandom();
var a = new Array();
while (h > 2) {
a[0] = 0;
while (a[0] == 0) {
b.nextBytes(a)
}
g[--h] = a[0]
}
g[--h] = 2;
g[--h] = 0;
return new BigInteger(g)
}
function RSAKey() {
this.n = null;
this.e = 0;
this.d = null;
this.p = null;
this.q = null;
this.dmp1 = null;
this.dmq1 = null;
this.coeff = null
}
function RSASetPublic(b, a) {
if (b != null && a != null && b.length > 0 && a.length > 0) {
this.n = parseBigInt(b, 16);
this.e = parseInt(a, 16);
return this.n.toString();
} else {
// alert("Invalid RSA public key")
return 0;
}
}
function RSADoPublic(a) {
return a.modPowInt(this.e, this.n)
}
function RSAEncrypt(d) {
var a = pkcs1pad2(d, (this.n.bitLength() + 7) >> 3);
if (a == null) {
return null
}
var e = this.doPublic(a);
if (e == null) {
return null
}
var b = e.toString(16);
if ((b.length & 1) == 0) {
return b
} else {
return "0" + b
}
return a;
}
RSAKey.prototype.doPublic = RSADoPublic;
RSAKey.prototype.setPublic = RSASetPublic;
RSAKey.prototype.encrypt = RSAEncrypt;
var b64map = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";
var b64pad = "=";
function hex2b64(d) {
var b;
var e;
var a = "";
for (b = 0; b + 3 <= d.length; b += 3) {
e = parseInt(d.substring(b, b + 3), 16);
a += b64map.charAt(e >> 6) + b64map.charAt(e & 63)
}
if (b + 1 == d.length) {
e = parseInt(d.substring(b, b + 1), 16);
a += b64map.charAt(e << 2)
} else {
if (b + 2 == d.length) {
e = parseInt(d.substring(b, b + 2), 16);
a += b64map.charAt(e >> 2) + b64map.charAt((e & 3) << 4)
}
}
while ((a.length & 3) > 0) {
a += b64pad
}
return a
}
function b64tohex(e) {
var c = "";
var d;
var a = 0;
var b;
var v;
for (d = 0; d < e.length; ++d) {
if (e.charAt(d) == b64pad) {
break
}
v = b64map.indexOf(e.charAt(d));
if (v < 0) {
continue
}
if (a == 0) {
c += int2char(v >> 2);
b = v & 3;
a = 1
} else {
if (a == 1) {
c += int2char((b << 2) | (v >> 4));
b = v & 15;
a = 2
} else {
if (a == 2) {
c += int2char(b);
c += int2char(v >> 2);
b = v & 3;
a = 3
} else {
c += int2char((b << 2) | (v >> 4));
c += int2char(v & 15);
a = 0
}
}
}
}
if (a == 1) {
c += int2char(b << 2)
}
return c
}
function b64toBA(e) {
var d = b64tohex(e);
var c;
var b = new Array();
for (c = 0; 2 * c < d.length; ++c) {
b[c] = parseInt(d.substring(2 * c, 2 * c + 2), 16)
}
return b
};至此,关于使用jsencrypt对参数进行RSA加密的内容就讲解完了,如果各位有什么问题可以在评论区域给我留言。
具体使用请移步 jsencrypt demo
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