/* rsa.c - RSA implementation * Copyright (C) 1997, 1998, 1999 by Werner Koch (dd9jn) * Copyright (C) 2000, 2001, 2002, 2003, 2008 Free Software Foundation, Inc. * * This file is part of Libgcrypt. * * Libgcrypt is free software; you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as * published by the Free Software Foundation; either version 2.1 of * the License, or (at your option) any later version. * * Libgcrypt is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this program; if not, see . */ /* This code uses an algorithm protected by U.S. Patent #4,405,829 which expired on September 20, 2000. The patent holder placed that patent into the public domain on Sep 6th, 2000. */ #include #include #include #include #include #include "g10lib.h" #include "mpi.h" #include "cipher.h" #include "pubkey-internal.h" typedef struct { gcry_mpi_t n; /* modulus */ gcry_mpi_t e; /* exponent */ } RSA_public_key; typedef struct { gcry_mpi_t n; /* public modulus */ gcry_mpi_t e; /* public exponent */ gcry_mpi_t d; /* exponent */ gcry_mpi_t p; /* prime p. */ gcry_mpi_t q; /* prime q. */ gcry_mpi_t u; /* inverse of p mod q. */ } RSA_secret_key; static const char *rsa_names[] = { "rsa", "openpgp-rsa", "oid.1.2.840.113549.1.1.1", NULL, }; /* A sample 1024 bit RSA key used for the selftests. */ static const char sample_secret_key[] = "(private-key" " (rsa" " (n #00e0ce96f90b6c9e02f3922beada93fe50a875eac6bcc18bb9a9cf2e84965caa" " 2d1ff95a7f542465c6c0c19d276e4526ce048868a7a914fd343cc3a87dd74291" " ffc565506d5bbb25cbac6a0e2dd1f8bcaab0d4a29c2f37c950f363484bf269f7" " 891440464baf79827e03a36e70b814938eebdc63e964247be75dc58b014b7ea251#)" " (e #010001#)" " (d #046129f2489d71579be0a75fe029bd6cdb574ebf57ea8a5b0fda942cab943b11" " 7d7bb95e5d28875e0f9fc5fcc06a72f6d502464dabded78ef6b716177b83d5bd" " c543dc5d3fed932e59f5897e92e6f58a0f33424106a3b6fa2cbf877510e4ac21" " c3ee47851e97d12996222ac3566d4ccb0b83d164074abf7de655fc2446da1781#)" " (p #00e861b700e17e8afe6837e7512e35b6ca11d0ae47d8b85161c67baf64377213" " fe52d772f2035b3ca830af41d8a4120e1c1c70d12cc22f00d28d31dd48a8d424f1#)" " (q #00f7a7ca5367c661f8e62df34f0d05c10c88e5492348dd7bddc942c9a8f369f9" " 35a07785d2db805215ed786e4285df1658eed3ce84f469b81b50d358407b4ad361#)" " (u #304559a9ead56d2309d203811a641bb1a09626bc8eb36fffa23c968ec5bd891e" " ebbafc73ae666e01ba7c8990bae06cc2bbe10b75e69fcacb353a6473079d8e9b#)))"; /* A sample 1024 bit RSA key used for the selftests (public only). */ static const char sample_public_key[] = "(public-key" " (rsa" " (n #00e0ce96f90b6c9e02f3922beada93fe50a875eac6bcc18bb9a9cf2e84965caa" " 2d1ff95a7f542465c6c0c19d276e4526ce048868a7a914fd343cc3a87dd74291" " ffc565506d5bbb25cbac6a0e2dd1f8bcaab0d4a29c2f37c950f363484bf269f7" " 891440464baf79827e03a36e70b814938eebdc63e964247be75dc58b014b7ea251#)" " (e #010001#)))"; static int test_keys (RSA_secret_key *sk, unsigned nbits); static int check_secret_key (RSA_secret_key *sk); static void public (gcry_mpi_t output, gcry_mpi_t input, RSA_public_key *skey); static void secret (gcry_mpi_t output, gcry_mpi_t input, RSA_secret_key *skey); static unsigned int rsa_get_nbits (gcry_sexp_t parms); /* Check that a freshly generated key actually works. Returns 0 on success. */ static int test_keys (RSA_secret_key *sk, unsigned int nbits) { int result = -1; /* Default to failure. */ RSA_public_key pk; gcry_mpi_t plaintext = mpi_new (nbits); gcry_mpi_t ciphertext = mpi_new (nbits); gcry_mpi_t decr_plaintext = mpi_new (nbits); gcry_mpi_t signature = mpi_new (nbits); /* Put the relevant parameters into a public key structure. */ pk.n = sk->n; pk.e = sk->e; /* Create a random plaintext. */ _gcry_mpi_randomize (plaintext, nbits, GCRY_WEAK_RANDOM); /* Encrypt using the public key. */ public (ciphertext, plaintext, &pk); /* Check that the cipher text does not match the plaintext. */ if (!mpi_cmp (ciphertext, plaintext)) goto leave; /* Ciphertext is identical to the plaintext. */ /* Decrypt using the secret key. */ secret (decr_plaintext, ciphertext, sk); /* Check that the decrypted plaintext matches the original plaintext. */ if (mpi_cmp (decr_plaintext, plaintext)) goto leave; /* Plaintext does not match. */ /* Create another random plaintext as data for signature checking. */ _gcry_mpi_randomize (plaintext, nbits, GCRY_WEAK_RANDOM); /* Use the RSA secret function to create a signature of the plaintext. */ secret (signature, plaintext, sk); /* Use the RSA public function to verify this signature. */ public (decr_plaintext, signature, &pk); if (mpi_cmp (decr_plaintext, plaintext)) goto leave; /* Signature does not match. */ /* Modify the signature and check that the signing fails. */ mpi_add_ui (signature, signature, 1); public (decr_plaintext, signature, &pk); if (!mpi_cmp (decr_plaintext, plaintext)) goto leave; /* Signature matches but should not. */ result = 0; /* All tests succeeded. */ leave: _gcry_mpi_release (signature); _gcry_mpi_release (decr_plaintext); _gcry_mpi_release (ciphertext); _gcry_mpi_release (plaintext); return result; } /* Callback used by the prime generation to test whether the exponent is suitable. Returns 0 if the test has been passed. */ static int check_exponent (void *arg, gcry_mpi_t a) { gcry_mpi_t e = arg; gcry_mpi_t tmp; int result; mpi_sub_ui (a, a, 1); tmp = _gcry_mpi_alloc_like (a); result = !mpi_gcd(tmp, e, a); /* GCD is not 1. */ _gcry_mpi_release (tmp); mpi_add_ui (a, a, 1); return result; } /**************** * Generate a key pair with a key of size NBITS. * USE_E = 0 let Libcgrypt decide what exponent to use. * = 1 request the use of a "secure" exponent; this is required by some * specification to be 65537. * > 2 Use this public exponent. If the given exponent * is not odd one is internally added to it. * TRANSIENT_KEY: If true, generate the primes using the standard RNG. * Returns: 2 structures filled with all needed values */ static gpg_err_code_t generate_std (RSA_secret_key *sk, unsigned int nbits, unsigned long use_e, int transient_key) { gcry_mpi_t p, q; /* the two primes */ gcry_mpi_t d; /* the private key */ gcry_mpi_t u; gcry_mpi_t t1, t2; gcry_mpi_t n; /* the public key */ gcry_mpi_t e; /* the exponent */ gcry_mpi_t phi; /* helper: (p-1)(q-1) */ gcry_mpi_t g; gcry_mpi_t f; gcry_random_level_t random_level; if (fips_mode ()) { if (nbits < 1024) return GPG_ERR_INV_VALUE; if (transient_key) return GPG_ERR_INV_VALUE; } /* The random quality depends on the transient_key flag. */ random_level = transient_key ? GCRY_STRONG_RANDOM : GCRY_VERY_STRONG_RANDOM; /* Make sure that nbits is even so that we generate p, q of equal size. */ if ( (nbits&1) ) nbits++; if (use_e == 1) /* Alias for a secure value */ use_e = 65537; /* as demanded by Sphinx. */ /* Public exponent: In general we use 41 as this is quite fast and more secure than the commonly used 17. Benchmarking the RSA verify function with a 1024 bit key yields (2001-11-08): e=17 0.54 ms e=41 0.75 ms e=257 0.95 ms e=65537 1.80 ms */ e = mpi_alloc( (32+BITS_PER_MPI_LIMB-1)/BITS_PER_MPI_LIMB ); if (!use_e) mpi_set_ui (e, 41); /* This is a reasonable secure and fast value */ else { use_e |= 1; /* make sure this is odd */ mpi_set_ui (e, use_e); } n = mpi_new (nbits); p = q = NULL; do { /* select two (very secret) primes */ if (p) _gcry_mpi_release (p); if (q) _gcry_mpi_release (q); if (use_e) { /* Do an extra test to ensure that the given exponent is suitable. */ p = _gcry_generate_secret_prime (nbits/2, random_level, check_exponent, e); q = _gcry_generate_secret_prime (nbits/2, random_level, check_exponent, e); } else { /* We check the exponent later. */ p = _gcry_generate_secret_prime (nbits/2, random_level, NULL, NULL); q = _gcry_generate_secret_prime (nbits/2, random_level, NULL, NULL); } if (mpi_cmp (p, q) > 0 ) /* p shall be smaller than q (for calc of u)*/ mpi_swap(p,q); /* calculate the modulus */ mpi_mul( n, p, q ); } while ( mpi_get_nbits(n) != nbits ); /* calculate Euler totient: phi = (p-1)(q-1) */ t1 = mpi_alloc_secure( mpi_get_nlimbs(p) ); t2 = mpi_alloc_secure( mpi_get_nlimbs(p) ); phi = mpi_snew ( nbits ); g = mpi_snew ( nbits ); f = mpi_snew ( nbits ); mpi_sub_ui( t1, p, 1 ); mpi_sub_ui( t2, q, 1 ); mpi_mul( phi, t1, t2 ); mpi_gcd (g, t1, t2); mpi_fdiv_q(f, phi, g); while (!mpi_gcd(t1, e, phi)) /* (while gcd is not 1) */ { if (use_e) BUG (); /* The prime generator already made sure that we never can get to here. */ mpi_add_ui (e, e, 2); } /* calculate the secret key d = e^1 mod phi */ d = mpi_snew ( nbits ); mpi_invm (d, e, f ); /* calculate the inverse of p and q (used for chinese remainder theorem)*/ u = mpi_snew ( nbits ); mpi_invm(u, p, q ); if( DBG_CIPHER ) { log_mpidump(" p= ", p ); log_mpidump(" q= ", q ); log_mpidump("phi= ", phi ); log_mpidump(" g= ", g ); log_mpidump(" f= ", f ); log_mpidump(" n= ", n ); log_mpidump(" e= ", e ); log_mpidump(" d= ", d ); log_mpidump(" u= ", u ); } _gcry_mpi_release (t1); _gcry_mpi_release (t2); _gcry_mpi_release (phi); _gcry_mpi_release (f); _gcry_mpi_release (g); sk->n = n; sk->e = e; sk->p = p; sk->q = q; sk->d = d; sk->u = u; /* Now we can test our keys. */ if (test_keys (sk, nbits - 64)) { _gcry_mpi_release (sk->n); sk->n = NULL; _gcry_mpi_release (sk->e); sk->e = NULL; _gcry_mpi_release (sk->p); sk->p = NULL; _gcry_mpi_release (sk->q); sk->q = NULL; _gcry_mpi_release (sk->d); sk->d = NULL; _gcry_mpi_release (sk->u); sk->u = NULL; fips_signal_error ("self-test after key generation failed"); return GPG_ERR_SELFTEST_FAILED; } return 0; } /* Helper for generate_x931. */ static gcry_mpi_t gen_x931_parm_xp (unsigned int nbits) { gcry_mpi_t xp; xp = mpi_snew (nbits); _gcry_mpi_randomize (xp, nbits, GCRY_VERY_STRONG_RANDOM); /* The requirement for Xp is: sqrt{2}*2^{nbits-1} <= xp <= 2^{nbits} - 1 We set the two high order bits to 1 to satisfy the lower bound. By using mpi_set_highbit we make sure that the upper bound is satisfied as well. */ mpi_set_highbit (xp, nbits-1); mpi_set_bit (xp, nbits-2); gcry_assert ( mpi_get_nbits (xp) == nbits ); return xp; } /* Helper for generate_x931. */ static gcry_mpi_t gen_x931_parm_xi (void) { gcry_mpi_t xi; xi = mpi_snew (101); _gcry_mpi_randomize (xi, 101, GCRY_VERY_STRONG_RANDOM); mpi_set_highbit (xi, 100); gcry_assert ( mpi_get_nbits (xi) == 101 ); return xi; } /* Variant of the standard key generation code using the algorithm from X9.31. Using this algorithm has the advantage that the generation can be made deterministic which is required for CAVS testing. */ static gpg_err_code_t generate_x931 (RSA_secret_key *sk, unsigned int nbits, unsigned long e_value, gcry_sexp_t deriveparms, int *swapped) { gcry_mpi_t p, q; /* The two primes. */ gcry_mpi_t e; /* The public exponent. */ gcry_mpi_t n; /* The public key. */ gcry_mpi_t d; /* The private key */ gcry_mpi_t u; /* The inverse of p and q. */ gcry_mpi_t pm1; /* p - 1 */ gcry_mpi_t qm1; /* q - 1 */ gcry_mpi_t phi; /* Euler totient. */ gcry_mpi_t f, g; /* Helper. */ *swapped = 0; if (e_value == 1) /* Alias for a secure value. */ e_value = 65537; /* Point 1 of section 4.1: k = 1024 + 256s with S >= 0 */ if (nbits < 1024 || (nbits % 256)) return GPG_ERR_INV_VALUE; /* Point 2: 2 <= bitlength(e) < 2^{k-2} Note that we do not need to check the upper bound because we use an unsigned long for E and thus there is no way for E to reach that limit. */ if (e_value < 3) return GPG_ERR_INV_VALUE; /* Our implementaion requires E to be odd. */ if (!(e_value & 1)) return GPG_ERR_INV_VALUE; /* Point 3: e > 0 or e 0 if it is to be randomly generated. We support only a fixed E and thus there is no need for an extra test. */ /* Compute or extract the derive parameters. */ { gcry_mpi_t xp1 = NULL; gcry_mpi_t xp2 = NULL; gcry_mpi_t xp = NULL; gcry_mpi_t xq1 = NULL; gcry_mpi_t xq2 = NULL; gcry_mpi_t xq = NULL; gcry_mpi_t tmpval; if (!deriveparms) { /* Not given: Generate them. */ xp = gen_x931_parm_xp (nbits/2); /* Make sure that |xp - xq| > 2^{nbits - 100} holds. */ tmpval = mpi_snew (nbits/2); do { _gcry_mpi_release (xq); xq = gen_x931_parm_xp (nbits/2); mpi_sub (tmpval, xp, xq); } while (mpi_get_nbits (tmpval) <= (nbits/2 - 100)); _gcry_mpi_release (tmpval); xp1 = gen_x931_parm_xi (); xp2 = gen_x931_parm_xi (); xq1 = gen_x931_parm_xi (); xq2 = gen_x931_parm_xi (); } else { /* Parameters to derive the key are given. */ /* Note that we explicitly need to setup the values of tbl because some compilers (e.g. OpenWatcom, IRIX) don't allow to initialize a structure with automatic variables. */ struct { const char *name; gcry_mpi_t *value; } tbl[] = { { "Xp1" }, { "Xp2" }, { "Xp" }, { "Xq1" }, { "Xq2" }, { "Xq" }, { NULL } }; int idx; gcry_sexp_t oneparm; tbl[0].value = &xp1; tbl[1].value = &xp2; tbl[2].value = &xp; tbl[3].value = &xq1; tbl[4].value = &xq2; tbl[5].value = &xq; for (idx=0; tbl[idx].name; idx++) { oneparm = sexp_find_token (deriveparms, tbl[idx].name, 0); if (oneparm) { *tbl[idx].value = sexp_nth_mpi (oneparm, 1, GCRYMPI_FMT_USG); sexp_release (oneparm); } } for (idx=0; tbl[idx].name; idx++) if (!*tbl[idx].value) break; if (tbl[idx].name) { /* At least one parameter is missing. */ for (idx=0; tbl[idx].name; idx++) _gcry_mpi_release (*tbl[idx].value); return GPG_ERR_MISSING_VALUE; } } e = mpi_alloc_set_ui (e_value); /* Find two prime numbers. */ p = _gcry_derive_x931_prime (xp, xp1, xp2, e, NULL, NULL); q = _gcry_derive_x931_prime (xq, xq1, xq2, e, NULL, NULL); _gcry_mpi_release (xp); xp = NULL; _gcry_mpi_release (xp1); xp1 = NULL; _gcry_mpi_release (xp2); xp2 = NULL; _gcry_mpi_release (xq); xq = NULL; _gcry_mpi_release (xq1); xq1 = NULL; _gcry_mpi_release (xq2); xq2 = NULL; if (!p || !q) { _gcry_mpi_release (p); _gcry_mpi_release (q); _gcry_mpi_release (e); return GPG_ERR_NO_PRIME; } } /* Compute the public modulus. We make sure that p is smaller than q to allow the use of the CRT. */ if (mpi_cmp (p, q) > 0 ) { mpi_swap (p, q); *swapped = 1; } n = mpi_new (nbits); mpi_mul (n, p, q); /* Compute the Euler totient: phi = (p-1)(q-1) */ pm1 = mpi_snew (nbits/2); qm1 = mpi_snew (nbits/2); phi = mpi_snew (nbits); mpi_sub_ui (pm1, p, 1); mpi_sub_ui (qm1, q, 1); mpi_mul (phi, pm1, qm1); g = mpi_snew (nbits); gcry_assert (mpi_gcd (g, e, phi)); /* Compute: f = lcm(p-1,q-1) = phi / gcd(p-1,q-1) */ mpi_gcd (g, pm1, qm1); f = pm1; pm1 = NULL; _gcry_mpi_release (qm1); qm1 = NULL; mpi_fdiv_q (f, phi, g); _gcry_mpi_release (phi); phi = NULL; d = g; g = NULL; /* Compute the secret key: d = e^{-1} mod lcm(p-1,q-1) */ mpi_invm (d, e, f); /* Compute the inverse of p and q. */ u = f; f = NULL; mpi_invm (u, p, q ); if( DBG_CIPHER ) { if (*swapped) log_debug ("p and q are swapped\n"); log_mpidump(" p", p ); log_mpidump(" q", q ); log_mpidump(" n", n ); log_mpidump(" e", e ); log_mpidump(" d", d ); log_mpidump(" u", u ); } sk->n = n; sk->e = e; sk->p = p; sk->q = q; sk->d = d; sk->u = u; /* Now we can test our keys. */ if (test_keys (sk, nbits - 64)) { _gcry_mpi_release (sk->n); sk->n = NULL; _gcry_mpi_release (sk->e); sk->e = NULL; _gcry_mpi_release (sk->p); sk->p = NULL; _gcry_mpi_release (sk->q); sk->q = NULL; _gcry_mpi_release (sk->d); sk->d = NULL; _gcry_mpi_release (sk->u); sk->u = NULL; fips_signal_error ("self-test after key generation failed"); return GPG_ERR_SELFTEST_FAILED; } return 0; } /**************** * Test whether the secret key is valid. * Returns: true if this is a valid key. */ static int check_secret_key( RSA_secret_key *sk ) { int rc; gcry_mpi_t temp = mpi_alloc( mpi_get_nlimbs(sk->p)*2 ); mpi_mul(temp, sk->p, sk->q ); rc = mpi_cmp( temp, sk->n ); mpi_free(temp); return !rc; } /**************** * Public key operation. Encrypt INPUT with PKEY and put result into OUTPUT. * * c = m^e mod n * * Where c is OUTPUT, m is INPUT and e,n are elements of PKEY. */ static void public(gcry_mpi_t output, gcry_mpi_t input, RSA_public_key *pkey ) { if( output == input ) /* powm doesn't like output and input the same */ { gcry_mpi_t x = mpi_alloc( mpi_get_nlimbs(input)*2 ); mpi_powm( x, input, pkey->e, pkey->n ); mpi_set(output, x); mpi_free(x); } else mpi_powm( output, input, pkey->e, pkey->n ); } #if 0 static void stronger_key_check ( RSA_secret_key *skey ) { gcry_mpi_t t = mpi_alloc_secure ( 0 ); gcry_mpi_t t1 = mpi_alloc_secure ( 0 ); gcry_mpi_t t2 = mpi_alloc_secure ( 0 ); gcry_mpi_t phi = mpi_alloc_secure ( 0 ); /* check that n == p * q */ mpi_mul( t, skey->p, skey->q); if (mpi_cmp( t, skey->n) ) log_info ( "RSA Oops: n != p * q\n" ); /* check that p is less than q */ if( mpi_cmp( skey->p, skey->q ) > 0 ) { log_info ("RSA Oops: p >= q - fixed\n"); _gcry_mpi_swap ( skey->p, skey->q); } /* check that e divides neither p-1 nor q-1 */ mpi_sub_ui(t, skey->p, 1 ); mpi_fdiv_r(t, t, skey->e ); if ( !mpi_cmp_ui( t, 0) ) log_info ( "RSA Oops: e divides p-1\n" ); mpi_sub_ui(t, skey->q, 1 ); mpi_fdiv_r(t, t, skey->e ); if ( !mpi_cmp_ui( t, 0) ) log_info ( "RSA Oops: e divides q-1\n" ); /* check that d is correct */ mpi_sub_ui( t1, skey->p, 1 ); mpi_sub_ui( t2, skey->q, 1 ); mpi_mul( phi, t1, t2 ); gcry_mpi_gcd(t, t1, t2); mpi_fdiv_q(t, phi, t); mpi_invm(t, skey->e, t ); if ( mpi_cmp(t, skey->d ) ) { log_info ( "RSA Oops: d is wrong - fixed\n"); mpi_set (skey->d, t); log_printmpi (" fixed d", skey->d); } /* check for correctness of u */ mpi_invm(t, skey->p, skey->q ); if ( mpi_cmp(t, skey->u ) ) { log_info ( "RSA Oops: u is wrong - fixed\n"); mpi_set (skey->u, t); log_printmpi (" fixed u", skey->u); } log_info ( "RSA secret key check finished\n"); mpi_free (t); mpi_free (t1); mpi_free (t2); mpi_free (phi); } #endif /**************** * Secret key operation. Encrypt INPUT with SKEY and put result into OUTPUT. * * m = c^d mod n * * Or faster: * * m1 = c ^ (d mod (p-1)) mod p * m2 = c ^ (d mod (q-1)) mod q * h = u * (m2 - m1) mod q * m = m1 + h * p * * Where m is OUTPUT, c is INPUT and d,n,p,q,u are elements of SKEY. */ static void secret (gcry_mpi_t output, gcry_mpi_t input, RSA_secret_key *skey ) { /* Remove superfluous leading zeroes from INPUT. */ mpi_normalize (input); if (!skey->p || !skey->q || !skey->u) { mpi_powm (output, input, skey->d, skey->n); } else { gcry_mpi_t m1 = mpi_alloc_secure( mpi_get_nlimbs(skey->n)+1 ); gcry_mpi_t m2 = mpi_alloc_secure( mpi_get_nlimbs(skey->n)+1 ); gcry_mpi_t h = mpi_alloc_secure( mpi_get_nlimbs(skey->n)+1 ); /* m1 = c ^ (d mod (p-1)) mod p */ mpi_sub_ui( h, skey->p, 1 ); mpi_fdiv_r( h, skey->d, h ); mpi_powm( m1, input, h, skey->p ); /* m2 = c ^ (d mod (q-1)) mod q */ mpi_sub_ui( h, skey->q, 1 ); mpi_fdiv_r( h, skey->d, h ); mpi_powm( m2, input, h, skey->q ); /* h = u * ( m2 - m1 ) mod q */ mpi_sub( h, m2, m1 ); if ( mpi_has_sign ( h ) ) mpi_add ( h, h, skey->q ); mpi_mulm( h, skey->u, h, skey->q ); /* m = m2 + h * p */ mpi_mul ( h, h, skey->p ); mpi_add ( output, m1, h ); mpi_free ( h ); mpi_free ( m1 ); mpi_free ( m2 ); } } /********************************************* ************** interface ****************** *********************************************/ static gcry_err_code_t rsa_generate (const gcry_sexp_t genparms, gcry_sexp_t *r_skey) { gpg_err_code_t ec; unsigned int nbits; unsigned long evalue; RSA_secret_key sk; gcry_sexp_t deriveparms; int flags = 0; gcry_sexp_t l1; gcry_sexp_t swap_info = NULL; memset (&sk, 0, sizeof sk); ec = _gcry_pk_util_get_nbits (genparms, &nbits); if (ec) return ec; ec = _gcry_pk_util_get_rsa_use_e (genparms, &evalue); if (ec) return ec; /* Parse the optional flags list. */ l1 = sexp_find_token (genparms, "flags", 0); if (l1) { ec = _gcry_pk_util_parse_flaglist (l1, &flags, NULL); sexp_release (l1); if (ec) return ec; } deriveparms = (genparms? sexp_find_token (genparms, "derive-parms", 0) : NULL); if (!deriveparms) { /* Parse the optional "use-x931" flag. */ l1 = sexp_find_token (genparms, "use-x931", 0); if (l1) { flags |= PUBKEY_FLAG_USE_X931; sexp_release (l1); } } if (deriveparms || (flags & PUBKEY_FLAG_USE_X931) || fips_mode ()) { int swapped; ec = generate_x931 (&sk, nbits, evalue, deriveparms, &swapped); sexp_release (deriveparms); if (!ec && swapped) ec = sexp_new (&swap_info, "(misc-key-info(p-q-swapped))", 0, 1); } else { /* Parse the optional "transient-key" flag. */ if (!(flags & PUBKEY_FLAG_TRANSIENT_KEY)) { l1 = sexp_find_token (genparms, "transient-key", 0); if (l1) { flags |= PUBKEY_FLAG_TRANSIENT_KEY; sexp_release (l1); } } /* Generate. */ ec = generate_std (&sk, nbits, evalue, !!(flags & PUBKEY_FLAG_TRANSIENT_KEY)); } if (!ec) { ec = sexp_build (r_skey, NULL, "(key-data" " (public-key" " (rsa(n%m)(e%m)))" " (private-key" " (rsa(n%m)(e%m)(d%m)(p%m)(q%m)(u%m)))" " %S)", sk.n, sk.e, sk.n, sk.e, sk.d, sk.p, sk.q, sk.u, swap_info); } mpi_free (sk.n); mpi_free (sk.e); mpi_free (sk.p); mpi_free (sk.q); mpi_free (sk.d); mpi_free (sk.u); sexp_release (swap_info); return ec; } static gcry_err_code_t rsa_check_secret_key (gcry_sexp_t keyparms) { gcry_err_code_t rc; RSA_secret_key sk = {NULL, NULL, NULL, NULL, NULL, NULL}; /* To check the key we need the optional parameters. */ rc = sexp_extract_param (keyparms, NULL, "nedpqu", &sk.n, &sk.e, &sk.d, &sk.p, &sk.q, &sk.u, NULL); if (rc) goto leave; if (!check_secret_key (&sk)) rc = GPG_ERR_BAD_SECKEY; leave: _gcry_mpi_release (sk.n); _gcry_mpi_release (sk.e); _gcry_mpi_release (sk.d); _gcry_mpi_release (sk.p); _gcry_mpi_release (sk.q); _gcry_mpi_release (sk.u); if (DBG_CIPHER) log_debug ("rsa_testkey => %s\n", gpg_strerror (rc)); return rc; } static gcry_err_code_t rsa_encrypt (gcry_sexp_t *r_ciph, gcry_sexp_t s_data, gcry_sexp_t keyparms) { gcry_err_code_t rc; struct pk_encoding_ctx ctx; gcry_mpi_t data = NULL; RSA_public_key pk = {NULL, NULL}; gcry_mpi_t ciph = NULL; _gcry_pk_util_init_encoding_ctx (&ctx, PUBKEY_OP_ENCRYPT, rsa_get_nbits (keyparms)); /* Extract the data. */ rc = _gcry_pk_util_data_to_mpi (s_data, &data, &ctx); if (rc) goto leave; if (DBG_CIPHER) log_mpidump ("rsa_encrypt data", data); if (mpi_is_opaque (data)) { rc = GPG_ERR_INV_DATA; goto leave; } /* Extract the key. */ rc = sexp_extract_param (keyparms, NULL, "ne", &pk.n, &pk.e, NULL); if (rc) goto leave; if (DBG_CIPHER) { log_mpidump ("rsa_encrypt n", pk.n); log_mpidump ("rsa_encrypt e", pk.e); } /* Do RSA computation and build result. */ ciph = mpi_new (0); public (ciph, data, &pk); if (DBG_CIPHER) log_mpidump ("rsa_encrypt res", ciph); if ((ctx.flags & PUBKEY_FLAG_FIXEDLEN)) { /* We need to make sure to return the correct length to avoid problems with missing leading zeroes. */ unsigned char *em; size_t emlen = (mpi_get_nbits (pk.n)+7)/8; rc = _gcry_mpi_to_octet_string (&em, NULL, ciph, emlen); if (!rc) { rc = sexp_build (r_ciph, NULL, "(enc-val(rsa(a%b)))", (int)emlen, em); xfree (em); } } else rc = sexp_build (r_ciph, NULL, "(enc-val(rsa(a%m)))", ciph); leave: _gcry_mpi_release (ciph); _gcry_mpi_release (pk.n); _gcry_mpi_release (pk.e); _gcry_mpi_release (data); _gcry_pk_util_free_encoding_ctx (&ctx); if (DBG_CIPHER) log_debug ("rsa_encrypt => %s\n", gpg_strerror (rc)); return rc; } static gcry_err_code_t rsa_decrypt (gcry_sexp_t *r_plain, gcry_sexp_t s_data, gcry_sexp_t keyparms) { gpg_err_code_t rc; struct pk_encoding_ctx ctx; gcry_sexp_t l1 = NULL; gcry_mpi_t data = NULL; RSA_secret_key sk = {NULL, NULL, NULL, NULL, NULL, NULL}; gcry_mpi_t plain = NULL; gcry_mpi_t r = NULL; /* Random number needed for blinding. */ gcry_mpi_t ri = NULL; /* Modular multiplicative inverse of r. */ gcry_mpi_t bldata = NULL;/* Blinded data to decrypt. */ unsigned char *unpad = NULL; size_t unpadlen = 0; _gcry_pk_util_init_encoding_ctx (&ctx, PUBKEY_OP_DECRYPT, rsa_get_nbits (keyparms)); /* Extract the data. */ rc = _gcry_pk_util_preparse_encval (s_data, rsa_names, &l1, &ctx); if (rc) goto leave; rc = sexp_extract_param (l1, NULL, "a", &data, NULL); if (rc) goto leave; if (DBG_CIPHER) log_printmpi ("rsa_decrypt data", data); if (mpi_is_opaque (data)) { rc = GPG_ERR_INV_DATA; goto leave; } /* Extract the key. */ rc = sexp_extract_param (keyparms, NULL, "nedp?q?u?", &sk.n, &sk.e, &sk.d, &sk.p, &sk.q, &sk.u, NULL); if (rc) goto leave; if (DBG_CIPHER) { log_printmpi ("rsa_decrypt n", sk.n); log_printmpi ("rsa_decrypt e", sk.e); if (!fips_mode ()) { log_printmpi ("rsa_decrypt d", sk.d); log_printmpi ("rsa_decrypt p", sk.p); log_printmpi ("rsa_decrypt q", sk.q); log_printmpi ("rsa_decrypt u", sk.u); } } /* Better make sure that there are no superfluous leading zeroes in the input and it has not been "padded" using multiples of N. This mitigates side-channel attacks (CVE-2013-4576). */ mpi_normalize (data); mpi_fdiv_r (data, data, sk.n); /* Allocate MPI for the plaintext. */ plain = mpi_snew (ctx.nbits); /* We use blinding by default to mitigate timing attacks which can be practically mounted over the network as shown by Brumley and Boney in 2003. */ if (!(ctx.flags & PUBKEY_FLAG_NO_BLINDING)) { /* First, we need a random number r between 0 and n - 1, which is relatively prime to n (i.e. it is neither p nor q). The random number needs to be only unpredictable, thus we employ the gcry_create_nonce function by using GCRY_WEAK_RANDOM with gcry_mpi_randomize. */ r = mpi_snew (ctx.nbits); ri = mpi_snew (ctx.nbits); bldata = mpi_snew (ctx.nbits); do { _gcry_mpi_randomize (r, ctx.nbits, GCRY_WEAK_RANDOM); mpi_mod (r, r, sk.n); } while (!mpi_invm (ri, r, sk.n)); /* Do blinding. We calculate: y = (x * r^e) mod n, where r is the random number, e is the public exponent, x is the non-blinded data and n is the RSA modulus. */ mpi_powm (bldata, r, sk.e, sk.n); mpi_mulm (bldata, bldata, data, sk.n); /* Perform decryption. */ secret (plain, bldata, &sk); _gcry_mpi_release (bldata); bldata = NULL; /* Undo blinding. Here we calculate: y = (x * r^-1) mod n, where x is the blinded decrypted data, ri is the modular multiplicative inverse of r and n is the RSA modulus. */ mpi_mulm (plain, plain, ri, sk.n); _gcry_mpi_release (r); r = NULL; _gcry_mpi_release (ri); ri = NULL; } else secret (plain, data, &sk); if (DBG_CIPHER) log_printmpi ("rsa_decrypt res", plain); /* Reverse the encoding and build the s-expression. */ switch (ctx.encoding) { case PUBKEY_ENC_PKCS1: rc = _gcry_rsa_pkcs1_decode_for_enc (&unpad, &unpadlen, ctx.nbits, plain); mpi_free (plain); plain = NULL; if (!rc) rc = sexp_build (r_plain, NULL, "(value %b)", (int)unpadlen, unpad); break; case PUBKEY_ENC_OAEP: rc = _gcry_rsa_oaep_decode (&unpad, &unpadlen, ctx.nbits, ctx.hash_algo, plain, ctx.label, ctx.labellen); mpi_free (plain); plain = NULL; if (!rc) rc = sexp_build (r_plain, NULL, "(value %b)", (int)unpadlen, unpad); break; default: /* Raw format. For backward compatibility we need to assume a signed mpi by using the sexp format string "%m". */ rc = sexp_build (r_plain, NULL, (ctx.flags & PUBKEY_FLAG_LEGACYRESULT) ? "%m":"(value %m)", plain); break; } leave: xfree (unpad); _gcry_mpi_release (plain); _gcry_mpi_release (sk.n); _gcry_mpi_release (sk.e); _gcry_mpi_release (sk.d); _gcry_mpi_release (sk.p); _gcry_mpi_release (sk.q); _gcry_mpi_release (sk.u); _gcry_mpi_release (data); _gcry_mpi_release (r); _gcry_mpi_release (ri); _gcry_mpi_release (bldata); sexp_release (l1); _gcry_pk_util_free_encoding_ctx (&ctx); if (DBG_CIPHER) log_debug ("rsa_decrypt => %s\n", gpg_strerror (rc)); return rc; } static gcry_err_code_t rsa_sign (gcry_sexp_t *r_sig, gcry_sexp_t s_data, gcry_sexp_t keyparms) { gpg_err_code_t rc; struct pk_encoding_ctx ctx; gcry_mpi_t data = NULL; RSA_secret_key sk = {NULL, NULL, NULL, NULL, NULL, NULL}; RSA_public_key pk; gcry_mpi_t sig = NULL; gcry_mpi_t result = NULL; _gcry_pk_util_init_encoding_ctx (&ctx, PUBKEY_OP_SIGN, rsa_get_nbits (keyparms)); /* Extract the data. */ rc = _gcry_pk_util_data_to_mpi (s_data, &data, &ctx); if (rc) goto leave; if (DBG_CIPHER) log_printmpi ("rsa_sign data", data); if (mpi_is_opaque (data)) { rc = GPG_ERR_INV_DATA; goto leave; } /* Extract the key. */ rc = sexp_extract_param (keyparms, NULL, "nedp?q?u?", &sk.n, &sk.e, &sk.d, &sk.p, &sk.q, &sk.u, NULL); if (rc) goto leave; if (DBG_CIPHER) { log_printmpi ("rsa_sign n", sk.n); log_printmpi ("rsa_sign e", sk.e); if (!fips_mode ()) { log_printmpi ("rsa_sign d", sk.d); log_printmpi ("rsa_sign p", sk.p); log_printmpi ("rsa_sign q", sk.q); log_printmpi ("rsa_sign u", sk.u); } } /* Do RSA computation. */ sig = mpi_new (0); secret (sig, data, &sk); if (DBG_CIPHER) log_printmpi ("rsa_sign res", sig); /* Check that the created signature is good. This detects a failure of the CRT algorithm (Lenstra's attack on RSA's use of the CRT). */ result = mpi_new (0); pk.n = sk.n; pk.e = sk.e; public (result, sig, &pk); if (mpi_cmp (result, data)) { rc = GPG_ERR_BAD_SIGNATURE; goto leave; } /* Convert the result. */ if ((ctx.flags & PUBKEY_FLAG_FIXEDLEN)) { /* We need to make sure to return the correct length to avoid problems with missing leading zeroes. */ unsigned char *em; size_t emlen = (mpi_get_nbits (sk.n)+7)/8; rc = _gcry_mpi_to_octet_string (&em, NULL, sig, emlen); if (!rc) { rc = sexp_build (r_sig, NULL, "(sig-val(rsa(s%b)))", (int)emlen, em); xfree (em); } } else rc = sexp_build (r_sig, NULL, "(sig-val(rsa(s%M)))", sig); leave: _gcry_mpi_release (result); _gcry_mpi_release (sig); _gcry_mpi_release (sk.n); _gcry_mpi_release (sk.e); _gcry_mpi_release (sk.d); _gcry_mpi_release (sk.p); _gcry_mpi_release (sk.q); _gcry_mpi_release (sk.u); _gcry_mpi_release (data); _gcry_pk_util_free_encoding_ctx (&ctx); if (DBG_CIPHER) log_debug ("rsa_sign => %s\n", gpg_strerror (rc)); return rc; } static gcry_err_code_t rsa_verify (gcry_sexp_t s_sig, gcry_sexp_t s_data, gcry_sexp_t keyparms) { gcry_err_code_t rc; struct pk_encoding_ctx ctx; gcry_sexp_t l1 = NULL; gcry_mpi_t sig = NULL; gcry_mpi_t data = NULL; RSA_public_key pk = { NULL, NULL }; gcry_mpi_t result = NULL; _gcry_pk_util_init_encoding_ctx (&ctx, PUBKEY_OP_VERIFY, rsa_get_nbits (keyparms)); /* Extract the data. */ rc = _gcry_pk_util_data_to_mpi (s_data, &data, &ctx); if (rc) goto leave; if (DBG_CIPHER) log_printmpi ("rsa_verify data", data); if (mpi_is_opaque (data)) { rc = GPG_ERR_INV_DATA; goto leave; } /* Extract the signature value. */ rc = _gcry_pk_util_preparse_sigval (s_sig, rsa_names, &l1, NULL); if (rc) goto leave; rc = sexp_extract_param (l1, NULL, "s", &sig, NULL); if (rc) goto leave; if (DBG_CIPHER) log_printmpi ("rsa_verify sig", sig); /* Extract the key. */ rc = sexp_extract_param (keyparms, NULL, "ne", &pk.n, &pk.e, NULL); if (rc) goto leave; if (DBG_CIPHER) { log_printmpi ("rsa_verify n", pk.n); log_printmpi ("rsa_verify e", pk.e); } /* Do RSA computation and compare. */ result = mpi_new (0); public (result, sig, &pk); if (DBG_CIPHER) log_printmpi ("rsa_verify cmp", result); if (ctx.verify_cmp) rc = ctx.verify_cmp (&ctx, result); else rc = mpi_cmp (result, data) ? GPG_ERR_BAD_SIGNATURE : 0; leave: _gcry_mpi_release (result); _gcry_mpi_release (pk.n); _gcry_mpi_release (pk.e); _gcry_mpi_release (data); _gcry_mpi_release (sig); sexp_release (l1); _gcry_pk_util_free_encoding_ctx (&ctx); if (DBG_CIPHER) log_debug ("rsa_verify => %s\n", rc?gpg_strerror (rc):"Good"); return rc; } /* Return the number of bits for the key described by PARMS. On error * 0 is returned. The format of PARMS starts with the algorithm name; * for example: * * (rsa * (n ) * (e )) * * More parameters may be given but we only need N here. */ static unsigned int rsa_get_nbits (gcry_sexp_t parms) { gcry_sexp_t l1; gcry_mpi_t n; unsigned int nbits; l1 = sexp_find_token (parms, "n", 1); if (!l1) return 0; /* Parameter N not found. */ n = sexp_nth_mpi (l1, 1, GCRYMPI_FMT_USG); sexp_release (l1); nbits = n? mpi_get_nbits (n) : 0; _gcry_mpi_release (n); return nbits; } /* Compute a keygrip. MD is the hash context which we are going to update. KEYPARAM is an S-expression with the key parameters, this is usually a public key but may also be a secret key. An example of such an S-expression is: (rsa (n #00B...#) (e #010001#)) PKCS-15 says that for RSA only the modulus should be hashed - however, it is not clear whether this is meant to use the raw bytes (assuming this is an unsigned integer) or whether the DER required 0 should be prefixed. We hash the raw bytes. */ static gpg_err_code_t compute_keygrip (gcry_md_hd_t md, gcry_sexp_t keyparam) { gcry_sexp_t l1; const char *data; size_t datalen; l1 = sexp_find_token (keyparam, "n", 1); if (!l1) return GPG_ERR_NO_OBJ; data = sexp_nth_data (l1, 1, &datalen); if (!data) { sexp_release (l1); return GPG_ERR_NO_OBJ; } _gcry_md_write (md, data, datalen); sexp_release (l1); return 0; } /* Self-test section. */ static const char * selftest_sign_1024 (gcry_sexp_t pkey, gcry_sexp_t skey) { static const char sample_data[] = "(data (flags pkcs1)" " (hash sha1 #11223344556677889900aabbccddeeff10203040#))"; static const char sample_data_bad[] = "(data (flags pkcs1)" " (hash sha1 #11223344556677889900aabbccddeeff80203040#))"; const char *errtxt = NULL; gcry_error_t err; gcry_sexp_t data = NULL; gcry_sexp_t data_bad = NULL; gcry_sexp_t sig = NULL; err = sexp_sscan (&data, NULL, sample_data, strlen (sample_data)); if (!err) err = sexp_sscan (&data_bad, NULL, sample_data_bad, strlen (sample_data_bad)); if (err) { errtxt = "converting data failed"; goto leave; } err = _gcry_pk_sign (&sig, data, skey); if (err) { errtxt = "signing failed"; goto leave; } err = _gcry_pk_verify (sig, data, pkey); if (err) { errtxt = "verify failed"; goto leave; } err = _gcry_pk_verify (sig, data_bad, pkey); if (gcry_err_code (err) != GPG_ERR_BAD_SIGNATURE) { errtxt = "bad signature not detected"; goto leave; } leave: sexp_release (sig); sexp_release (data_bad); sexp_release (data); return errtxt; } /* Given an S-expression ENCR_DATA of the form: (enc-val (rsa (a a-value))) as returned by gcry_pk_decrypt, return the the A-VALUE. On error, return NULL. */ static gcry_mpi_t extract_a_from_sexp (gcry_sexp_t encr_data) { gcry_sexp_t l1, l2, l3; gcry_mpi_t a_value; l1 = sexp_find_token (encr_data, "enc-val", 0); if (!l1) return NULL; l2 = sexp_find_token (l1, "rsa", 0); sexp_release (l1); if (!l2) return NULL; l3 = sexp_find_token (l2, "a", 0); sexp_release (l2); if (!l3) return NULL; a_value = sexp_nth_mpi (l3, 1, 0); sexp_release (l3); return a_value; } static const char * selftest_encr_1024 (gcry_sexp_t pkey, gcry_sexp_t skey) { const char *errtxt = NULL; gcry_error_t err; const unsigned int nbits = 1000; /* Encrypt 1000 random bits. */ gcry_mpi_t plaintext = NULL; gcry_sexp_t plain = NULL; gcry_sexp_t encr = NULL; gcry_mpi_t ciphertext = NULL; gcry_sexp_t decr = NULL; gcry_mpi_t decr_plaintext = NULL; gcry_sexp_t tmplist = NULL; /* Create plaintext. The plaintext is actually a big integer number. */ plaintext = mpi_new (nbits); _gcry_mpi_randomize (plaintext, nbits, GCRY_WEAK_RANDOM); /* Put the plaintext into an S-expression. */ err = sexp_build (&plain, NULL, "(data (flags raw) (value %m))", plaintext); if (err) { errtxt = "converting data failed"; goto leave; } /* Encrypt. */ err = _gcry_pk_encrypt (&encr, plain, pkey); if (err) { errtxt = "encrypt failed"; goto leave; } /* Extraxt the ciphertext from the returned S-expression. */ /*sexp_dump (encr);*/ ciphertext = extract_a_from_sexp (encr); if (!ciphertext) { errtxt = "gcry_pk_decrypt returned garbage"; goto leave; } /* Check that the ciphertext does no match the plaintext. */ /* _gcry_log_printmpi ("plaintext", plaintext); */ /* _gcry_log_printmpi ("ciphertxt", ciphertext); */ if (!mpi_cmp (plaintext, ciphertext)) { errtxt = "ciphertext matches plaintext"; goto leave; } /* Decrypt. */ err = _gcry_pk_decrypt (&decr, encr, skey); if (err) { errtxt = "decrypt failed"; goto leave; } /* Extract the decrypted data from the S-expression. Note that the output of gcry_pk_decrypt depends on whether a flags lists occurs in its input data. Because we passed the output of gcry_pk_encrypt directly to gcry_pk_decrypt, such a flag value won't be there as of today. To be prepared for future changes we take care of it anyway. */ tmplist = sexp_find_token (decr, "value", 0); if (tmplist) decr_plaintext = sexp_nth_mpi (tmplist, 1, GCRYMPI_FMT_USG); else decr_plaintext = sexp_nth_mpi (decr, 0, GCRYMPI_FMT_USG); if (!decr_plaintext) { errtxt = "decrypt returned no plaintext"; goto leave; } /* Check that the decrypted plaintext matches the original plaintext. */ if (mpi_cmp (plaintext, decr_plaintext)) { errtxt = "mismatch"; goto leave; } leave: sexp_release (tmplist); _gcry_mpi_release (decr_plaintext); sexp_release (decr); _gcry_mpi_release (ciphertext); sexp_release (encr); sexp_release (plain); _gcry_mpi_release (plaintext); return errtxt; } static gpg_err_code_t selftests_rsa (selftest_report_func_t report) { const char *what; const char *errtxt; gcry_error_t err; gcry_sexp_t skey = NULL; gcry_sexp_t pkey = NULL; /* Convert the S-expressions into the internal representation. */ what = "convert"; err = sexp_sscan (&skey, NULL, sample_secret_key, strlen (sample_secret_key)); if (!err) err = sexp_sscan (&pkey, NULL, sample_public_key, strlen (sample_public_key)); if (err) { errtxt = _gcry_strerror (err); goto failed; } what = "key consistency"; err = _gcry_pk_testkey (skey); if (err) { errtxt = _gcry_strerror (err); goto failed; } what = "sign"; errtxt = selftest_sign_1024 (pkey, skey); if (errtxt) goto failed; what = "encrypt"; errtxt = selftest_encr_1024 (pkey, skey); if (errtxt) goto failed; sexp_release (pkey); sexp_release (skey); return 0; /* Succeeded. */ failed: sexp_release (pkey); sexp_release (skey); if (report) report ("pubkey", GCRY_PK_RSA, what, errtxt); return GPG_ERR_SELFTEST_FAILED; } /* Run a full self-test for ALGO and return 0 on success. */ static gpg_err_code_t run_selftests (int algo, int extended, selftest_report_func_t report) { gpg_err_code_t ec; (void)extended; switch (algo) { case GCRY_PK_RSA: ec = selftests_rsa (report); break; default: ec = GPG_ERR_PUBKEY_ALGO; break; } return ec; } gcry_pk_spec_t _gcry_pubkey_spec_rsa = { GCRY_PK_RSA, { 0, 1 }, (GCRY_PK_USAGE_SIGN | GCRY_PK_USAGE_ENCR), "RSA", rsa_names, "ne", "nedpqu", "a", "s", "n", rsa_generate, rsa_check_secret_key, rsa_encrypt, rsa_decrypt, rsa_sign, rsa_verify, rsa_get_nbits, run_selftests, compute_keygrip };