The statement
All content in this article is only for learning and exchange, strictly prohibited for commercial use and illegal use, otherwise all the consequences have nothing to do with the author, if there is infringement, please contact me immediately delete!
Reverse the target
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Goal: Log in when le net
-
Home page: request, dc n/auth/goLogi…
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Interface: request, dc n/auth/login
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Reverse parameter:
The Query String Parameters:
pwd:26fac08e6b524bef29c09479fdefe604ea7b2c4d7285a3e01f0969a9230a4e9af1b8ed23ca840978f61bf0e7850c72ece07dc95ef3f7484a5086 284f825bd420da19ecd8b832877b113f21181bc9a22cc795c92f8d4c8dc6ca8b21309c674220e365ab67475a299277b0aa7842e09517c7ab3c5e693e 51c4d9d9935f6ec430cbCopy the code
The reverse process
Caught analysis
Enter a password randomly, click login, capture the packet to locate the login interface oauth.d.cn/auth/login, GET request, Query String Parameters, password PWD is encrypted processing.
Parameters of the reverse
If you search the PWD keyword, you can find a function of submitData to submitData on the home page. If you bury the breakpoint for debugging, you can find that the plaintext password is obtained after RSA encryption:
Follow up with this RSA encryption function:
var rsa = function (arg) {
setMaxDigits(130);
var PublicExponent = "10001";
var modulus = "be44aec4d73408f6b60e6fe9e3dc55d0e1dc53a1e171e071b547e2e8e0b7da01c56e8c9bcf0521568eb111adccef4e40124b76e33e7ad75607c227a f8f8e0b759c30ef283be8ab17a84b19a051df5f94c07e6e7be5f77866376322aac944f45f3ab532bb6efc70c1efa524d821d16cafb580c5a901f0def ddea3692a4e68e6cd";
var key = new RSAKeyPair(PublicExponent, "", modulus);
return encryptedString(key, arg);
};
Copy the codeThe setMaxDigits function is found in bigint.js, and RSAKeyPair and encryptedString are both found in RSAKeyPair and RSAKeyPair. Since both are more complex, So directly the two JS source code copy down directly can be called.
BarrettMu is not defined in rsa.js. After debugging, it can be found that this function is in barrett.js. Therefore, you can copy all barrett.js directly.
The complete code
The full code can be downloaded at GitHub: github.com/kuaidaili/c…
d_cn_encrypt.js
var RSAAPP = {};
RSAAPP.NoPadding = "NoPadding";
RSAAPP.PKCS1Padding = "PKCS1Padding";
RSAAPP.RawEncoding = "RawEncoding";
RSAAPP.NumericEncoding = "NumericEncoding"
function RSAKeyPair(encryptionExponent, decryptionExponent, modulus, keylen) {
this.e = biFromHex(encryptionExponent);
this.d = biFromHex(decryptionExponent);
this.m = biFromHex(modulus);
if (typeof(keylen) ! ='number') {
this.chunkSize = 2 * biHighIndex(this.m);
} else {
this.chunkSize = keylen / 8;
}
this.radix = 16;
this.barrett = new BarrettMu(this.m);
}
function encryptedString(key, s, pad, encoding) {
var a = new Array(a);var sl = s.length;
var i, j, k;
var padtype;
var encodingtype;
var rpad;
var al;
var result = "";
var block;
var crypt;
var text;
if (typeof (pad) == 'string') {
if (pad == RSAAPP.NoPadding) {
padtype = 1;
} else if (pad == RSAAPP.PKCS1Padding) {
padtype = 2;
} else {
padtype = 0; }}else {
padtype = 0;
}
if (typeof (encoding) == 'string' && encoding == RSAAPP.RawEncoding) {
encodingtype = 1;
} else {
encodingtype = 0;
}
if (padtype == 1) {
if(sl > key.chunkSize) { sl = key.chunkSize; }}else if (padtype == 2) {
if (sl > (key.chunkSize - 11)) {
sl = key.chunkSize - 11;
}
}
i = 0;
if (padtype == 2) {
j = sl - 1;
} else {
j = key.chunkSize - 1;
}
while (i < sl) {
if (padtype) {
a[j] = s.charCodeAt(i);
} else {
a[i] = s.charCodeAt(i);
}
i++;
j--;
}
if (padtype == 1) {
i = 0;
}
j = key.chunkSize - (sl % key.chunkSize);
while (j > 0) {
if (padtype == 2) {
rpad = Math.floor(Math.random() * 256);
while(! rpad) { rpad =Math.floor(Math.random() * 256);
}
a[i] = rpad;
} else {
a[i] = 0;
}
i++;
j--;
}
if (padtype == 2) {
a[sl] = 0;
a[key.chunkSize - 2] = 2;
a[key.chunkSize - 1] = 0;
}
al = a.length;
for (i = 0; i < al; i += key.chunkSize) {
block = new BigInt(a); j =0;
for (k = i; k < (i + key.chunkSize); ++j) {
block.digits[j] = a[k++];
block.digits[j] += a[k++] << 8;
}
crypt = key.barrett.powMod(block, key.e);
if (encodingtype == 1) {
text = biToBytes(crypt);
} else {
text = (key.radix == 16)? biToHex(crypt) : biToString(crypt, key.radix); } result += text; }return result;
}
function decryptedString(key, c) {
var blocks = c.split("");
var b;
var i, j;
var bi;
var result = "";
for (i = 0; i < blocks.length; ++i) {
if (key.radix == 16) {
bi = biFromHex(blocks[i]);
} else {
bi = biFromString(blocks[i], key.radix);
}
b = key.barrett.powMod(bi, key.d);
for (j = 0; j <= biHighIndex(b); ++j) {
result += String.fromCharCode(b.digits[j] & 255, b.digits[j] >> 8); }}if (result.charCodeAt(result.length - 1) = =0) {
result = result.substring(0, result.length - 1);
}
return (result);
}
var biRadixBase = 2;
var biRadixBits = 16;
var bitsPerDigit = biRadixBits;
var biRadix = 1 << 16; // = 2^16 = 65536
var biHalfRadix = biRadix >>> 1;
var biRadixSquared = biRadix * biRadix;
var maxDigitVal = biRadix - 1;
var maxInteger = 9999999999999998;
var maxDigits;
var ZERO_ARRAY;
var bigZero, bigOne;
function setMaxDigits(value) {
maxDigits = value;
ZERO_ARRAY = new Array(maxDigits);
for (var iza = 0; iza < ZERO_ARRAY.length; iza++) ZERO_ARRAY[iza] = 0;
bigZero = new BigInt(a); bigOne =new BigInt(a); bigOne.digits[0] = 1;
}
setMaxDigits(20);
var dpl10 = 15;
var lr10 = biFromNumber(1000000000000000);
function BigInt(flag) {
if (typeof flag == "boolean" && flag == true) {
this.digits = null;
} else {
this.digits = ZERO_ARRAY.slice(0);
}
this.isNeg = false;
}
function biFromDecimal(s) {
var isNeg = s.charAt(0) = =The '-';
var i = isNeg ? 1 : 0;
var result;
// Skip leading zeros.
while (i < s.length && s.charAt(i) == '0') ++i;
if (i == s.length) {
result = new BigInt(a); }else {
var digitCount = s.length - i;
var fgl = digitCount % dpl10;
if (fgl == 0) fgl = dpl10;
result = biFromNumber(Number(s.substr(i, fgl)));
i += fgl;
while (i < s.length) {
result = biAdd(biMultiply(result, lr10), biFromNumber(Number(s.substr(i, dpl10))));
i += dpl10;
}
result.isNeg = isNeg;
}
return result;
}
function biCopy(bi) {
var result = new BigInt(true);
result.digits = bi.digits.slice(0);
result.isNeg = bi.isNeg;
return result;
}
function biFromNumber(i) {
var result = new BigInt(a); result.isNeg = i <0;
i = Math.abs(i);
var j = 0;
while (i > 0) {
result.digits[j++] = i & maxDigitVal;
i >>= biRadixBits;
}
return result;
}
function reverseStr(s) {
var result = "";
for (var i = s.length - 1; i > -1; --i) {
result += s.charAt(i);
}
return result;
}
var hexatrigesimalToChar = new Array('0'.'1'.'2'.'3'.'4'.'5'.'6'.'7'.'8'.'9'.'a'.'b'.'c'.'d'.'e'.'f'.'g'.'h'.'i'.'j'.'k'.'l'.'m'.'n'.'o'.'p'.'q'.'r'.'s'.'t'.'u'.'v'.'w'.'x'.'y'.'z');
function biToString(x, radix) {
var b = new BigInt(a); b.digits[0] = radix;
var qr = biDivideModulo(x, b);
var result = hexatrigesimalToChar[qr[1].digits[0]].while (biCompare(qr[0], bigZero) == 1) {
qr = biDivideModulo(qr[0], b);
digit = qr[1].digits[0];
result += hexatrigesimalToChar[qr[1].digits[0]];
}
return (x.isNeg ? "-" : "") + reverseStr(result);
}
function biToDecimal(x) {
var b = new BigInt(a); b.digits[0] = 10;
var qr = biDivideModulo(x, b);
var result = String(qr[1].digits[0]);
while (biCompare(qr[0], bigZero) == 1) {
qr = biDivideModulo(qr[0], b);
result += String(qr[1].digits[0]);
}
return (x.isNeg ? "-" : "") + reverseStr(result);
}
var hexToChar = new Array('0'.'1'.'2'.'3'.'4'.'5'.'6'.'7'.'8'.'9'.'a'.'b'.'c'.'d'.'e'.'f');
function digitToHex(n) {
var mask = 0xf;
var result = "";
for (i = 0; i < 4; ++i) {
result += hexToChar[n & mask];
n >>>= 4;
}
return reverseStr(result);
}
function biToHex(x) {
var result = "";
var n = biHighIndex(x);
for (var i = biHighIndex(x); i > -1; --i) {
result += digitToHex(x.digits[i]);
}
return result;
}
function charToHex(c) {
var ZERO = 48;
var NINE = ZERO + 9;
var littleA = 97;
var littleZ = littleA + 25;
var bigA = 65;
var bigZ = 65 + 25;
var result;
if (c >= ZERO && c <= NINE) {
result = c - ZERO;
} else if (c >= bigA && c <= bigZ) {
result = 10 + c - bigA;
} else if (c >= littleA && c <= littleZ) {
result = 10 + c - littleA;
} else {
result = 0;
}
return result;
}
function hexToDigit(s) {
var result = 0;
var sl = Math.min(s.length, 4);
for (var i = 0; i < sl; ++i) {
result <<= 4;
result |= charToHex(s.charCodeAt(i))
}
return result;
}
function biFromHex(s) {
var result = new BigInt(a);var sl = s.length;
for (var i = sl,
j = 0; i > 0; i -= 4, ++j) {
result.digits[j] = hexToDigit(s.substr(Math.max(i - 4.0), Math.min(i, 4)));
}
return result;
}
function biFromString(s, radix) {
var isNeg = s.charAt(0) = =The '-';
var istop = isNeg ? 1 : 0;
var result = new BigInt(a);var place = new BigInt(a); place.digits[0] = 1; // radix^0
for (var i = s.length - 1; i >= istop; i--) {
var c = s.charCodeAt(i);
var digit = charToHex(c);
var biDigit = biMultiplyDigit(place, digit);
result = biAdd(result, biDigit);
place = biMultiplyDigit(place, radix);
}
result.isNeg = isNeg;
return result;
}
function biToBytes(x) / /Returns a string containing raw bytes.
{
var result = "";
for (var i = biHighIndex(x); i > -1; --i) {
result += digitToBytes(x.digits[i]);
}
return result;
}
function digitToBytes(n) / /Convert two-byte digit to string containing both bytes.
{
var c1 = String.fromCharCode(n & 0xff);
n >>>= 8;
var c2 = String.fromCharCode(n & 0xff);
return c2 + c1;
}
function biDump(b) {
return (b.isNeg ? "-" : "") + b.digits.join("");
}
function biAdd(x, y) {
var result;
if(x.isNeg ! = y.isNeg) { y.isNeg = ! y.isNeg; result = biSubtract(x, y); y.isNeg = ! y.isNeg; }else {
result = new BigInt(a);var c = 0;
var n;
for (var i = 0; i < x.digits.length; ++i) {
n = x.digits[i] + y.digits[i] + c;
result.digits[i] = n & 0xffff;
c = Number(n >= biRadix);
}
result.isNeg = x.isNeg;
}
return result;
}
function biSubtract(x, y) {
var result;
if(x.isNeg ! = y.isNeg) { y.isNeg = ! y.isNeg; result = biAdd(x, y); y.isNeg = ! y.isNeg; }else {
result = new BigInt(a);var n, c;
c = 0;
for (var i = 0; i < x.digits.length; ++i) {
n = x.digits[i] - y.digits[i] + c;
result.digits[i] = n & 0xffff;
// Stupid non-conforming modulus operation.
if (result.digits[i] < 0) result.digits[i] += biRadix;
c = 0 - Number(n < 0);
}
// Fix up the negative sign, if any.
if (c == -1) {
c = 0;
for (var i = 0; i < x.digits.length; ++i) {
n = 0 - result.digits[i] + c;
result.digits[i] = n & 0xffff;
// Stupid non-conforming modulus operation.
if (result.digits[i] < 0) result.digits[i] += biRadix;
c = 0 - Number(n < 0);
}
// Result is opposite sign of arguments.result.isNeg = ! x.isNeg; }else {
// Result is same sign.result.isNeg = x.isNeg; }}return result;
}
function biHighIndex(x) {
var result = x.digits.length - 1;
while (result > 0 && x.digits[result] == 0) --result;
return result;
}
function biNumBits(x) {
var n = biHighIndex(x);
var d = x.digits[n];
var m = (n + 1) * bitsPerDigit;
var result;
for (result = m; result > m - bitsPerDigit; --result) {
if ((d & 0x8000) != 0) break;
d <<= 1;
}
return result;
}
function biMultiply(x, y) {
var result = new BigInt(a);var c;
var n = biHighIndex(x);
var t = biHighIndex(y);
var u, uv, k;
for (var i = 0; i <= t; ++i) {
c = 0;
k = i;
for (j = 0; j <= n; ++j, ++k) {
uv = result.digits[k] + x.digits[j] * y.digits[i] + c;
result.digits[k] = uv & maxDigitVal;
c = uv >>> biRadixBits;
}
result.digits[i + n + 1] = c;
}
// Someone give me a logical xor, please.result.isNeg = x.isNeg ! = y.isNeg;return result;
}
function biMultiplyDigit(x, y) {
var n, c, uv;
result = new BigInt(a); n = biHighIndex(x); c =0;
for (var j = 0; j <= n; ++j) {
uv = result.digits[j] + x.digits[j] * y + c;
result.digits[j] = uv & maxDigitVal;
c = uv >>> biRadixBits;
}
result.digits[1 + n] = c;
return result;
}
function arrayCopy(src, srcStart, dest, destStart, n) {
var m = Math.min(srcStart + n, src.length);
for (vari = srcStart, j = destStart; i < m; ++i, ++j) { dest[j] = src[i]; }}var highBitMasks = new Array(0x0000.0x8000.0xC000.0xE000.0xF000.0xF800.0xFC00.0xFE00.0xFF00.0xFF80.0xFFC0.0xFFE0.0xFFF0.0xFFF8.0xFFFC.0xFFFE.0xFFFF);
function biShiftLeft(x, n) {
var digitCount = Math.floor(n / bitsPerDigit);
var result = new BigInt(a); arrayCopy(x.digits,0, result.digits, digitCount, result.digits.length - digitCount);
var bits = n % bitsPerDigit;
var rightBits = bitsPerDigit - bits;
for (var i = result.digits.length - 1,
i1 = i - 1; i > 0; --i, --i1) {
result.digits[i] = ((result.digits[i] << bits) & maxDigitVal) | ((result.digits[i1] & highBitMasks[bits]) >>> (rightBits));
}
result.digits[0] = ((result.digits[i] << bits) & maxDigitVal);
result.isNeg = x.isNeg;
return result;
}
var lowBitMasks = new Array(0x0000.0x0001.0x0003.0x0007.0x000F.0x001F.0x003F.0x007F.0x00FF.0x01FF.0x03FF.0x07FF.0x0FFF.0x1FFF.0x3FFF.0x7FFF.0xFFFF);
function biShiftRight(x, n) {
var digitCount = Math.floor(n / bitsPerDigit);
var result = new BigInt(a); arrayCopy(x.digits, digitCount, result.digits,0, x.digits.length - digitCount);
var bits = n % bitsPerDigit;
var leftBits = bitsPerDigit - bits;
for (var i = 0,
i1 = i + 1; i < result.digits.length - 1; ++i, ++i1) {
result.digits[i] = (result.digits[i] >>> bits) | ((result.digits[i1] & lowBitMasks[bits]) << leftBits);
}
result.digits[result.digits.length - 1] >>>= bits;
result.isNeg = x.isNeg;
return result;
}
function biMultiplyByRadixPower(x, n) {
var result = new BigInt(a); arrayCopy(x.digits,0, result.digits, n, result.digits.length - n);
return result;
}
function biDivideByRadixPower(x, n) {
var result = new BigInt(a); arrayCopy(x.digits, n, result.digits,0, result.digits.length - n);
return result;
}
function biModuloByRadixPower(x, n) {
var result = new BigInt(a); arrayCopy(x.digits,0, result.digits, 0, n);
return result;
}
function biCompare(x, y) {
if(x.isNeg ! = y.isNeg) {return 1 - 2 * Number(x.isNeg);
}
for (var i = x.digits.length - 1; i >= 0; --i) {
if(x.digits[i] ! = y.digits[i]) {if (x.isNeg) {
return 1 - 2 * Number(x.digits[i] > y.digits[i]);
} else {
return 1 - 2 * Number(x.digits[i] < y.digits[i]); }}}return 0;
}
function biDivideModulo(x, y) {
var nb = biNumBits(x);
var tb = biNumBits(y);
var origYIsNeg = y.isNeg;
var q, r;
if (nb < tb) {
// |x| < |y|
if(x.isNeg) { q = biCopy(bigOne); q.isNeg = ! y.isNeg; x.isNeg =false;
y.isNeg = false;
r = biSubtract(y, x);
// Restore signs, 'cause they're references.
x.isNeg = true;
y.isNeg = origYIsNeg;
} else {
q = new BigInt(a); r = biCopy(x); }return new Array(q, r);
}
q = new BigInt(a); r = x;// Normalize Y.
var t = Math.ceil(tb / bitsPerDigit) - 1;
var lambda = 0;
while (y.digits[t] < biHalfRadix) {
y = biShiftLeft(y, 1);
++lambda;
++tb;
t = Math.ceil(tb / bitsPerDigit) - 1;
}
// Shift r over to keep the quotient constant. We'll shift the
// remainder back at the end.
r = biShiftLeft(r, lambda);
nb += lambda; // Update the bit count for x.
var n = Math.ceil(nb / bitsPerDigit) - 1;
var b = biMultiplyByRadixPower(y, n - t);
while(biCompare(r, b) ! = -1) {
++q.digits[n - t];
r = biSubtract(r, b);
}
for (var i = n; i > t; --i) {
var ri = (i >= r.digits.length) ? 0 : r.digits[i];
var ri1 = (i - 1 >= r.digits.length) ? 0 : r.digits[i - 1];
var ri2 = (i - 2 >= r.digits.length) ? 0 : r.digits[i - 2];
var yt = (t >= y.digits.length) ? 0 : y.digits[t];
var yt1 = (t - 1 >= y.digits.length) ? 0 : y.digits[t - 1];
if (ri == yt) {
q.digits[i - t - 1] = maxDigitVal;
} else {
q.digits[i - t - 1] = Math.floor((ri * biRadix + ri1) / yt);
}
var c1 = q.digits[i - t - 1] * ((yt * biRadix) + yt1);
var c2 = (ri * biRadixSquared) + ((ri1 * biRadix) + ri2);
while (c1 > c2) {
--q.digits[i - t - 1];
c1 = q.digits[i - t - 1] * ((yt * biRadix) | yt1);
c2 = (ri * biRadix * biRadix) + ((ri1 * biRadix) + ri2);
}
b = biMultiplyByRadixPower(y, i - t - 1);
r = biSubtract(r, biMultiplyDigit(b, q.digits[i - t - 1]));
if (r.isNeg) {
r = biAdd(r, b);
--q.digits[i - t - 1];
}
}
r = biShiftRight(r, lambda);
// Fiddle with the signs and stuff to make sure that 0 <= r < y.q.isNeg = x.isNeg ! = origYIsNeg;if (x.isNeg) {
if (origYIsNeg) {
q = biAdd(q, bigOne);
} else {
q = biSubtract(q, bigOne);
}
y = biShiftRight(y, lambda);
r = biSubtract(y, r);
}
// Check for the unbelievably stupid degenerate case of r == -0.
if (r.digits[0] = =0 && biHighIndex(r) == 0) r.isNeg = false;
return new Array(q, r);
}
function biDivide(x, y) {
return biDivideModulo(x, y)[0];
}
function biModulo(x, y) {
return biDivideModulo(x, y)[1];
}
function biMultiplyMod(x, y, m) {
return biModulo(biMultiply(x, y), m);
}
function biPow(x, y) {
var result = bigOne;
var a = x;
while (true) {
if ((y & 1) != 0) result = biMultiply(result, a);
y >>= 1;
if (y == 0) break;
a = biMultiply(a, a);
}
return result;
}
function biPowMod(x, y, m) {
var result = bigOne;
var a = x;
var k = y;
while (true) {
if ((k.digits[0] & 1) != 0) result = biMultiplyMod(result, a, m);
k = biShiftRight(k, 1);
if (k.digits[0] = =0 && biHighIndex(k) == 0) break;
a = biMultiplyMod(a, a, m);
}
return result;
}
function BarrettMu(m) {
this.modulus = biCopy(m);
this.k = biHighIndex(this.modulus) + 1;
var b2k = new BigInt(a); b2k.digits[2 * this.k] = 1; // b2k = b^(2k)
this.mu = biDivide(b2k, this.modulus);
this.bkplus1 = new BigInt(a);this.bkplus1.digits[this.k + 1] = 1; // bkplus1 = b^(k+1)
this.modulo = BarrettMu_modulo;
this.multiplyMod = BarrettMu_multiplyMod;
this.powMod = BarrettMu_powMod;
}
function BarrettMu_modulo(x) {
var q1 = biDivideByRadixPower(x, this.k - 1);
var q2 = biMultiply(q1, this.mu);
var q3 = biDivideByRadixPower(q2, this.k + 1);
var r1 = biModuloByRadixPower(x, this.k + 1);
var r2term = biMultiply(q3, this.modulus);
var r2 = biModuloByRadixPower(r2term, this.k + 1);
var r = biSubtract(r1, r2);
if (r.isNeg) {
r = biAdd(r, this.bkplus1);
}
var rgtem = biCompare(r, this.modulus) >= 0;
while (rgtem) {
r = biSubtract(r, this.modulus);
rgtem = biCompare(r, this.modulus) >= 0;
}
return r;
}
function BarrettMu_multiplyMod(x, y) {
/* x = this.modulo(x); y = this.modulo(y); * /
var xy = biMultiply(x, y);
return this.modulo(xy);
}
function BarrettMu_powMod(x, y) {
var result = new BigInt(a); result.digits[0] = 1;
var a = x;
var k = y;
while (true) {
if ((k.digits[0] & 1) != 0) result = this.multiplyMod(result, a);
k = biShiftRight(k, 1);
if (k.digits[0] = =0 && biHighIndex(k) == 0) break;
a = this.multiplyMod(a, a);
}
return result;
}
function getEncryptedPassword (arg) {
setMaxDigits(130);
var PublicExponent = "10001";
var modulus = "be44aec4d73408f6b60e6fe9e3dc55d0e1dc53a1e171e071b547e2e8e0b7da01c56e8c9bcf0521568eb111adccef4e40124b76e33e7ad75607c227a f8f8e0b759c30ef283be8ab17a84b19a051df5f94c07e6e7be5f77866376322aac944f45f3ab532bb6efc70c1efa524d821d16cafb580c5a901f0def ddea3692a4e68e6cd";
var key = new RSAKeyPair(PublicExponent, "", modulus);
return encryptedString(key, arg);
}
// Test example
// console.log(getEncryptedPassword("2543534534"))
Copy the coded_cn_login.py
#! /usr/bin/env python3
# -*- coding: utf-8 -*-
import execjs
import requests
def get_encrypted_password(password) :
with open('d_cn_encrypt.js'.'r', encoding='utf-8') as f:
weibo_js = f.read()
encrypted_password = execjs.compile(weibo_js).call('getEncryptedPassword', password)
return encrypted_password
def login(encrypted_password, username) :
login_url = 'https://oauth.d.cn/auth/login'
headers = {
'Host': 'oauth.d.cn'.'Referer': 'https://oauth.d.cn/auth/goLogin.html'.'sec-ch-ua': '" Not; A Brand"; v="99", "Google Chrome"; v="91", "Chromium"; v="91"'.'User-Agent': 'the Mozilla / 5.0 (Windows NT 10.0; Win64; X64) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/91.0.4472.124 Safari/537.36'
}
params = {
'display': 'web'.'name': username,
'pwd': encrypted_password,
'to': 'https%3A%2F%2Fwww.d.cn%2F'
}
response = requests.get(url=login_url, params=params, headers=headers).json()
print(response)
def main() :
username = input('Please enter login account:')
password = input('Please enter login password:')
encrypted_password = get_encrypted_password(password)
login(encrypted_password, username)
if __name__ == '__main__':
main()
Copy the code