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https://github.com/cryb-to/cryb-to.git
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183 lines
5.8 KiB
C
183 lines
5.8 KiB
C
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/* R_KEYGEN.C - key-pair generation for RSAREF
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*/
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/* Copyright (C) RSA Laboratories, a division of RSA Data Security,
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Inc., created 1991. All rights reserved.
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*/
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#include "global.h"
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#include "rsaref.h"
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#include "r_random.h"
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#include "nn.h"
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#include "prime.h"
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static int RSAFilter PROTO_LIST
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((NN_DIGIT *, unsigned int, NN_DIGIT *, unsigned int));
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static int RelativelyPrime PROTO_LIST
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((NN_DIGIT *, unsigned int, NN_DIGIT *, unsigned int));
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/* Generates an RSA key pair with a given length and public exponent.
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*/
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int R_GeneratePEMKeys (publicKey, privateKey, protoKey, randomStruct)
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R_RSA_PUBLIC_KEY *publicKey; /* new RSA public key */
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R_RSA_PRIVATE_KEY *privateKey; /* new RSA private key */
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R_RSA_PROTO_KEY *protoKey; /* RSA prototype key */
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R_RANDOM_STRUCT *randomStruct; /* random structure */
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{
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NN_DIGIT d[MAX_NN_DIGITS], dP[MAX_NN_DIGITS], dQ[MAX_NN_DIGITS],
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e[MAX_NN_DIGITS], n[MAX_NN_DIGITS], p[MAX_NN_DIGITS], phiN[MAX_NN_DIGITS],
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pMinus1[MAX_NN_DIGITS], q[MAX_NN_DIGITS], qInv[MAX_NN_DIGITS],
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qMinus1[MAX_NN_DIGITS], t[MAX_NN_DIGITS], u[MAX_NN_DIGITS],
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v[MAX_NN_DIGITS];
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int status = 0;
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unsigned int nDigits, pBits, pDigits, qBits;
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if ((protoKey->bits < MIN_RSA_MODULUS_BITS) ||
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(protoKey->bits > MAX_RSA_MODULUS_BITS))
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return (RE_MODULUS_LEN);
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nDigits = (protoKey->bits + NN_DIGIT_BITS - 1) / NN_DIGIT_BITS;
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pDigits = (nDigits + 1) / 2;
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pBits = (protoKey->bits + 1) / 2;
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qBits = protoKey->bits - pBits;
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/* NOTE: for 65537, this assumes NN_DIGIT is at least 17 bits. */
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NN_ASSIGN_DIGIT
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(e, protoKey->useFermat4 ? (NN_DIGIT)65537 : (NN_DIGIT)3, nDigits);
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/* Generate prime p between 3*2^(pBits-2) and 2^pBits-1, searching
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in steps of 2, until one satisfies gcd (p-1, e) = 1.
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*/
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NN_Assign2Exp (t, pBits-1, pDigits);
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NN_Assign2Exp (u, pBits-2, pDigits);
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NN_Add (t, t, u, pDigits);
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NN_ASSIGN_DIGIT (v, 1, pDigits);
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NN_Sub (v, t, v, pDigits);
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NN_Add (u, u, v, pDigits);
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NN_ASSIGN_DIGIT (v, 2, pDigits);
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do {
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if ((status = GeneratePrime (p, t, u, v, pDigits, randomStruct)))
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return (status);
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}
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while (! RSAFilter (p, pDigits, e, 1));
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/* Generate prime q between 3*2^(qBits-2) and 2^qBits-1, searching
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in steps of 2, until one satisfies gcd (q-1, e) = 1.
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*/
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NN_Assign2Exp (t, qBits-1, pDigits);
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NN_Assign2Exp (u, qBits-2, pDigits);
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NN_Add (t, t, u, pDigits);
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NN_ASSIGN_DIGIT (v, 1, pDigits);
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NN_Sub (v, t, v, pDigits);
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NN_Add (u, u, v, pDigits);
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NN_ASSIGN_DIGIT (v, 2, pDigits);
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do {
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if ((status = GeneratePrime (q, t, u, v, pDigits, randomStruct)))
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return (status);
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}
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while (! RSAFilter (q, pDigits, e, 1));
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/* Sort so that p > q. (p = q case is extremely unlikely.)
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*/
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if (NN_Cmp (p, q, pDigits) < 0) {
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NN_Assign (t, p, pDigits);
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NN_Assign (p, q, pDigits);
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NN_Assign (q, t, pDigits);
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}
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/* Compute n = pq, qInv = q^{-1} mod p, d = e^{-1} mod (p-1)(q-1),
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dP = d mod p-1, dQ = d mod q-1.
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*/
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NN_Mult (n, p, q, pDigits);
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NN_ModInv (qInv, q, p, pDigits);
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NN_ASSIGN_DIGIT (t, 1, pDigits);
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NN_Sub (pMinus1, p, t, pDigits);
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NN_Sub (qMinus1, q, t, pDigits);
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NN_Mult (phiN, pMinus1, qMinus1, pDigits);
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NN_ModInv (d, e, phiN, nDigits);
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NN_Mod (dP, d, nDigits, pMinus1, pDigits);
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NN_Mod (dQ, d, nDigits, qMinus1, pDigits);
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publicKey->bits = privateKey->bits = protoKey->bits;
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NN_Encode (publicKey->modulus, MAX_RSA_MODULUS_LEN, n, nDigits);
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NN_Encode (publicKey->exponent, MAX_RSA_MODULUS_LEN, e, 1);
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R_memcpy
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((POINTER)privateKey->modulus, (POINTER)publicKey->modulus,
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MAX_RSA_MODULUS_LEN);
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R_memcpy
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((POINTER)privateKey->publicExponent, (POINTER)publicKey->exponent,
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MAX_RSA_MODULUS_LEN);
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NN_Encode (privateKey->exponent, MAX_RSA_MODULUS_LEN, d, nDigits);
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NN_Encode (privateKey->prime[0], MAX_RSA_PRIME_LEN, p, pDigits);
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NN_Encode (privateKey->prime[1], MAX_RSA_PRIME_LEN, q, pDigits);
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NN_Encode (privateKey->primeExponent[0], MAX_RSA_PRIME_LEN, dP, pDigits);
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NN_Encode (privateKey->primeExponent[1], MAX_RSA_PRIME_LEN, dQ, pDigits);
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NN_Encode (privateKey->coefficient, MAX_RSA_PRIME_LEN, qInv, pDigits);
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/* Zeroize sensitive information.
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*/
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R_memset ((POINTER)d, 0, sizeof (d));
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R_memset ((POINTER)dP, 0, sizeof (dP));
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R_memset ((POINTER)dQ, 0, sizeof (dQ));
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R_memset ((POINTER)p, 0, sizeof (p));
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R_memset ((POINTER)phiN, 0, sizeof (phiN));
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R_memset ((POINTER)pMinus1, 0, sizeof (pMinus1));
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R_memset ((POINTER)q, 0, sizeof (q));
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R_memset ((POINTER)qInv, 0, sizeof (qInv));
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R_memset ((POINTER)qMinus1, 0, sizeof (qMinus1));
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R_memset ((POINTER)t, 0, sizeof (t));
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return (0);
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}
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/* Returns nonzero iff GCD (a-1, b) = 1.
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Lengths: a[aDigits], b[bDigits].
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Assumes aDigits < MAX_NN_DIGITS, bDigits < MAX_NN_DIGITS.
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*/
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static int RSAFilter (a, aDigits, b, bDigits)
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NN_DIGIT *a, *b;
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unsigned int aDigits, bDigits;
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{
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int status;
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NN_DIGIT aMinus1[MAX_NN_DIGITS], t[MAX_NN_DIGITS];
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NN_ASSIGN_DIGIT (t, 1, aDigits);
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NN_Sub (aMinus1, a, t, aDigits);
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status = RelativelyPrime (aMinus1, aDigits, b, bDigits);
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/* Zeroize sensitive information.
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*/
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R_memset ((POINTER)aMinus1, 0, sizeof (aMinus1));
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return (status);
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}
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/* Returns nonzero iff a and b are relatively prime.
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Lengths: a[aDigits], b[bDigits].
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Assumes aDigits >= bDigits, aDigits < MAX_NN_DIGITS.
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*/
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static int RelativelyPrime (a, aDigits, b, bDigits)
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NN_DIGIT *a, *b;
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unsigned int aDigits, bDigits;
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{
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int status;
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NN_DIGIT t[MAX_NN_DIGITS], u[MAX_NN_DIGITS];
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NN_AssignZero (t, aDigits);
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NN_Assign (t, b, bDigits);
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NN_Gcd (t, a, t, aDigits);
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NN_ASSIGN_DIGIT (u, 1, aDigits);
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status = NN_EQUAL (t, u, aDigits);
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/* Zeroize sensitive information.
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*/
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R_memset ((POINTER)t, 0, sizeof (t));
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return (status);
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}
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