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/*
* RSA
* (C) 1999-2010,2015,2016,2018,2019 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#include <botan/rsa.h>
#include <botan/internal/pk_ops_impl.h>
#include <botan/keypair.h>
#include <botan/blinding.h>
#include <botan/reducer.h>
#include <botan/workfactor.h>
#include <botan/der_enc.h>
#include <botan/ber_dec.h>
#include <botan/monty.h>
#include <botan/divide.h>
#include <botan/internal/monty_exp.h>
#if defined(BOTAN_HAS_OPENSSL)
#include <botan/internal/openssl.h>
#endif
#if defined(BOTAN_HAS_THREAD_UTILS)
#include <botan/internal/thread_pool.h>
#endif
namespace Botan {
class RSA_Public_Data final
{
public:
RSA_Public_Data(BigInt&& n, BigInt&& e) :
m_n(n),
m_e(e),
m_monty_n(std::make_shared<Montgomery_Params>(m_n)),
m_public_modulus_bits(m_n.bits()),
m_public_modulus_bytes(m_n.bytes())
{}
BigInt public_op(const BigInt& m) const
{
const size_t powm_window = 1;
auto powm_m_n = monty_precompute(m_monty_n, m, powm_window, false);
return monty_execute_vartime(*powm_m_n, m_e);
}
const BigInt& get_n() const { return m_n; }
const BigInt& get_e() const { return m_e; }
size_t public_modulus_bits() const { return m_public_modulus_bits; }
size_t public_modulus_bytes() const { return m_public_modulus_bytes; }
private:
BigInt m_n;
BigInt m_e;
std::shared_ptr<const Montgomery_Params> m_monty_n;
size_t m_public_modulus_bits;
size_t m_public_modulus_bytes;
};
class RSA_Private_Data final
{
public:
RSA_Private_Data(BigInt&& d, BigInt&& p, BigInt&& q,
BigInt&& d1, BigInt&& d2, BigInt&& c) :
m_d(d),
m_p(p),
m_q(q),
m_d1(d1),
m_d2(d2),
m_c(c),
m_mod_p(m_p),
m_mod_q(m_q),
m_monty_p(std::make_shared<Montgomery_Params>(m_p, m_mod_p)),
m_monty_q(std::make_shared<Montgomery_Params>(m_q, m_mod_q)),
m_p_bits(m_p.bits()),
m_q_bits(m_q.bits())
{}
const BigInt& get_d() const { return m_d; }
const BigInt& get_p() const { return m_p; }
const BigInt& get_q() const { return m_q; }
const BigInt& get_d1() const { return m_d1; }
const BigInt& get_d2() const { return m_d2; }
const BigInt& get_c() const { return m_c; }
//private:
BigInt m_d;
BigInt m_p;
BigInt m_q;
BigInt m_d1;
BigInt m_d2;
BigInt m_c;
Modular_Reducer m_mod_p;
Modular_Reducer m_mod_q;
std::shared_ptr<const Montgomery_Params> m_monty_p;
std::shared_ptr<const Montgomery_Params> m_monty_q;
size_t m_p_bits;
size_t m_q_bits;
};
std::shared_ptr<const RSA_Public_Data> RSA_PublicKey::public_data() const
{
return m_public;
}
const BigInt& RSA_PublicKey::get_n() const { return m_public->get_n(); }
const BigInt& RSA_PublicKey::get_e() const { return m_public->get_e(); }
void RSA_PublicKey::init(BigInt&& n, BigInt&& e)
{
if(n.is_negative() || n.is_even() || e.is_negative() || e.is_even())
throw Decoding_Error("Invalid RSA public key parameters");
m_public = std::make_shared<RSA_Public_Data>(std::move(n), std::move(e));
}
RSA_PublicKey::RSA_PublicKey(const AlgorithmIdentifier&,
const std::vector<uint8_t>& key_bits)
{
BigInt n, e;
BER_Decoder(key_bits)
.start_cons(SEQUENCE)
.decode(n)
.decode(e)
.end_cons();
init(std::move(n), std::move(e));
}
RSA_PublicKey::RSA_PublicKey(const BigInt& modulus, const BigInt& exponent)
{
BigInt n = modulus;
BigInt e = exponent;
init(std::move(n), std::move(e));
}
size_t RSA_PublicKey::key_length() const
{
return m_public->public_modulus_bits();
}
size_t RSA_PublicKey::estimated_strength() const
{
return if_work_factor(key_length());
}
AlgorithmIdentifier RSA_PublicKey::algorithm_identifier() const
{
return AlgorithmIdentifier(get_oid(), AlgorithmIdentifier::USE_NULL_PARAM);
}
std::vector<uint8_t> RSA_PublicKey::public_key_bits() const
{
std::vector<uint8_t> output;
DER_Encoder der(output);
der.start_cons(SEQUENCE)
.encode(get_n())
.encode(get_e())
.end_cons();
return output;
}
/*
* Check RSA Public Parameters
*/
bool RSA_PublicKey::check_key(RandomNumberGenerator&, bool) const
{
if(get_n() < 35 || get_n().is_even() || get_e() < 3 || get_e().is_even())
return false;
return true;
}
std::shared_ptr<const RSA_Private_Data> RSA_PrivateKey::private_data() const
{
return m_private;
}
secure_vector<uint8_t> RSA_PrivateKey::private_key_bits() const
{
return DER_Encoder()
.start_cons(SEQUENCE)
.encode(static_cast<size_t>(0))
.encode(get_n())
.encode(get_e())
.encode(get_d())
.encode(get_p())
.encode(get_q())
.encode(get_d1())
.encode(get_d2())
.encode(get_c())
.end_cons()
.get_contents();
}
const BigInt& RSA_PrivateKey::get_p() const { return m_private->get_p(); }
const BigInt& RSA_PrivateKey::get_q() const { return m_private->get_q(); }
const BigInt& RSA_PrivateKey::get_d() const { return m_private->get_d(); }
const BigInt& RSA_PrivateKey::get_c() const { return m_private->get_c(); }
const BigInt& RSA_PrivateKey::get_d1() const { return m_private->get_d1(); }
const BigInt& RSA_PrivateKey::get_d2() const { return m_private->get_d2(); }
void RSA_PrivateKey::init(BigInt&& d, BigInt&& p, BigInt&& q,
BigInt&& d1, BigInt&& d2, BigInt&& c)
{
m_private = std::make_shared<RSA_Private_Data>(
std::move(d), std::move(p), std::move(q), std::move(d1), std::move(d2), std::move(c));
}
RSA_PrivateKey::RSA_PrivateKey(const AlgorithmIdentifier&,
const secure_vector<uint8_t>& key_bits)
{
BigInt n, e, d, p, q, d1, d2, c;
BER_Decoder(key_bits)
.start_cons(SEQUENCE)
.decode_and_check<size_t>(0, "Unknown PKCS #1 key format version")
.decode(n)
.decode(e)
.decode(d)
.decode(p)
.decode(q)
.decode(d1)
.decode(d2)
.decode(c)
.end_cons();
RSA_PublicKey::init(std::move(n), std::move(e));
RSA_PrivateKey::init(std::move(d), std::move(p), std::move(q),
std::move(d1), std::move(d2), std::move(c));
}
RSA_PrivateKey::RSA_PrivateKey(const BigInt& prime1,
const BigInt& prime2,
const BigInt& exp,
const BigInt& d_exp,
const BigInt& mod)
{
BigInt p = prime1;
BigInt q = prime2;
BigInt n = mod;
if(n.is_zero())
n = p * q;
BigInt e = exp;
BigInt d = d_exp;
const BigInt p_minus_1 = p - 1;
const BigInt q_minus_1 = q - 1;
if(d.is_zero())
{
const BigInt phi_n = lcm(p_minus_1, q_minus_1);
d = inverse_mod(e, phi_n);
}
BigInt d1 = ct_modulo(d, p_minus_1);
BigInt d2 = ct_modulo(d, q_minus_1);
BigInt c = inverse_mod(q, p);
RSA_PublicKey::init(std::move(n), std::move(e));
RSA_PrivateKey::init(std::move(d), std::move(p), std::move(q),
std::move(d1), std::move(d2), std::move(c));
}
/*
* Create a RSA private key
*/
RSA_PrivateKey::RSA_PrivateKey(RandomNumberGenerator& rng,
size_t bits, size_t exp)
{
if(bits < 1024)
throw Invalid_Argument(algo_name() + ": Can't make a key that is only " +
std::to_string(bits) + " bits long");
if(exp < 3 || exp % 2 == 0)
throw Invalid_Argument(algo_name() + ": Invalid encryption exponent");
BigInt n, e, d, p, q, d1, d2, c;
e = exp;
const size_t p_bits = (bits + 1) / 2;
const size_t q_bits = bits - p_bits;
do
{
// TODO could generate primes in thread pool
p = generate_rsa_prime(rng, rng, p_bits, e);
q = generate_rsa_prime(rng, rng, q_bits, e);
n = p * q;
} while(n.bits() != bits);
const BigInt p_minus_1 = p - 1;
const BigInt q_minus_1 = q - 1;
const BigInt phi_n = lcm(p_minus_1, q_minus_1);
d = inverse_mod(e, phi_n);
d1 = ct_modulo(d, p_minus_1);
d2 = ct_modulo(d, q_minus_1);
c = inverse_mod(q, p);
RSA_PublicKey::init(std::move(n), std::move(e));
RSA_PrivateKey::init(std::move(d), std::move(p), std::move(q),
std::move(d1), std::move(d2), std::move(c));
}
/*
* Check Private RSA Parameters
*/
bool RSA_PrivateKey::check_key(RandomNumberGenerator& rng, bool strong) const
{
if(get_n() < 35 || get_n().is_even() || get_e() < 3 || get_e().is_even())
return false;
if(get_d() < 2 || get_p() < 3 || get_q() < 3)
return false;
if(get_p() * get_q() != get_n())
return false;
if(get_d1() != ct_modulo(get_d(), get_p() - 1))
return false;
if(get_d2() != ct_modulo(get_d(), get_q() - 1))
return false;
if(get_c() != inverse_mod(get_q(), get_p()))
return false;
const size_t prob = (strong) ? 128 : 12;
if(!is_prime(get_p(), rng, prob))
return false;
if(!is_prime(get_q(), rng, prob))
return false;
if(strong)
{
if(ct_modulo(get_e() * get_d(), lcm(get_p() - 1, get_q() - 1)) != 1)
return false;
return KeyPair::signature_consistency_check(rng, *this, "EMSA4(SHA-256)");
}
return true;
}
namespace {
/**
* RSA private (decrypt/sign) operation
*/
class RSA_Private_Operation
{
protected:
size_t public_modulus_bits() const { return m_public->public_modulus_bits(); }
size_t public_modulus_bytes() const { return m_public->public_modulus_bytes(); }
explicit RSA_Private_Operation(const RSA_PrivateKey& rsa, RandomNumberGenerator& rng) :
m_public(rsa.public_data()),
m_private(rsa.private_data()),
m_blinder(m_public->get_n(), rng,
[this](const BigInt& k) { return m_public->public_op(k); },
[this](const BigInt& k) { return inverse_mod(k, m_public->get_n()); }),
m_blinding_bits(64),
m_max_d1_bits(m_private->m_p_bits + m_blinding_bits),
m_max_d2_bits(m_private->m_q_bits + m_blinding_bits)
{
}
secure_vector<uint8_t> raw_op(const uint8_t input[], size_t input_len)
{
const BigInt input_bn(input, input_len);
if(input_bn >= m_public->get_n())
throw Invalid_Argument("RSA private op - input is too large");
// TODO: This should be a function on blinder
// BigInt Blinder::run_blinded_function(std::function<BigInt, BigInt> fn, const BigInt& input);
const BigInt recovered = m_blinder.unblind(rsa_private_op(m_blinder.blind(input_bn)));
BOTAN_ASSERT(input_bn == m_public->public_op(recovered), "RSA consistency check");
return BigInt::encode_1363(recovered, m_public->public_modulus_bytes());
}
private:
BigInt rsa_private_op(const BigInt& m) const
{
/*
TODO
Consider using Montgomery reduction instead of Barrett, using
the "Smooth RSA-CRT" method. https://eprint.iacr.org/2007/039.pdf
*/
static constexpr size_t powm_window = 4;
// Compute this in main thread to avoid racing on the rng
const BigInt d1_mask(m_blinder.rng(), m_blinding_bits);
#if defined(BOTAN_HAS_THREAD_UTILS) && !defined(BOTAN_HAS_VALGRIND)
#define BOTAN_RSA_USE_ASYNC
#endif
#if defined(BOTAN_RSA_USE_ASYNC)
/*
* Precompute m.sig_words in the main thread before calling async. Otherwise
* the two threads race (during Modular_Reducer::reduce) and while the output
* is correct in both threads, helgrind warns.
*/
m.sig_words();
auto future_j1 = Thread_Pool::global_instance().run([this, &m, &d1_mask]() {
#endif
const BigInt masked_d1 = m_private->get_d1() + (d1_mask * (m_private->get_p() - 1));
auto powm_d1_p = monty_precompute(m_private->m_monty_p, m_private->m_mod_p.reduce(m), powm_window);
BigInt j1 = monty_execute(*powm_d1_p, masked_d1, m_max_d1_bits);
#if defined(BOTAN_RSA_USE_ASYNC)
return j1;
});
#endif
const BigInt d2_mask(m_blinder.rng(), m_blinding_bits);
const BigInt masked_d2 = m_private->get_d2() + (d2_mask * (m_private->get_q() - 1));
auto powm_d2_q = monty_precompute(m_private->m_monty_q, m_private->m_mod_q.reduce(m), powm_window);
const BigInt j2 = monty_execute(*powm_d2_q, masked_d2, m_max_d2_bits);
#if defined(BOTAN_RSA_USE_ASYNC)
BigInt j1 = future_j1.get();
#endif
/*
* To recover the final value from the CRT representation (j1,j2)
* we use Garner's algorithm:
* c = q^-1 mod p (this is precomputed)
* h = c*(j1-j2) mod p
* m = j2 + h*q
*
* We must avoid leaking if j1 >= j2 or not, as doing so allows deriving
* information about the secret prime. Do this by first adding p to j1,
* which should ensure the subtraction of j2 does not underflow. But
* this may still underflow if p and q are imbalanced in size.
*/
j1 = m_private->m_mod_p.multiply(m_private->m_mod_p.reduce((m_private->get_p() + j1) - j2), m_private->get_c());
return mul_add(j1, m_private->get_q(), j2);
}
std::shared_ptr<const RSA_Public_Data> m_public;
std::shared_ptr<const RSA_Private_Data> m_private;
// XXX could the blinder starting pair be shared?
Blinder m_blinder;
const size_t m_blinding_bits;
const size_t m_max_d1_bits;
const size_t m_max_d2_bits;
};
class RSA_Signature_Operation final : public PK_Ops::Signature_with_EMSA,
private RSA_Private_Operation
{
public:
size_t max_input_bits() const override { return public_modulus_bits() - 1; }
size_t signature_length() const override { return public_modulus_bytes(); }
RSA_Signature_Operation(const RSA_PrivateKey& rsa, const std::string& emsa, RandomNumberGenerator& rng) :
PK_Ops::Signature_with_EMSA(emsa),
RSA_Private_Operation(rsa, rng)
{
}
secure_vector<uint8_t> raw_sign(const uint8_t input[], size_t input_len,
RandomNumberGenerator&) override
{
return raw_op(input, input_len);
}
};
class RSA_Decryption_Operation final : public PK_Ops::Decryption_with_EME,
private RSA_Private_Operation
{
public:
RSA_Decryption_Operation(const RSA_PrivateKey& rsa, const std::string& eme, RandomNumberGenerator& rng) :
PK_Ops::Decryption_with_EME(eme),
RSA_Private_Operation(rsa, rng)
{
}
size_t plaintext_length(size_t) const override { return public_modulus_bytes(); }
secure_vector<uint8_t> raw_decrypt(const uint8_t input[], size_t input_len) override
{
return raw_op(input, input_len);
}
};
class RSA_KEM_Decryption_Operation final : public PK_Ops::KEM_Decryption_with_KDF,
private RSA_Private_Operation
{
public:
RSA_KEM_Decryption_Operation(const RSA_PrivateKey& key,
const std::string& kdf,
RandomNumberGenerator& rng) :
PK_Ops::KEM_Decryption_with_KDF(kdf),
RSA_Private_Operation(key, rng)
{}
secure_vector<uint8_t>
raw_kem_decrypt(const uint8_t encap_key[], size_t len) override
{
return raw_op(encap_key, len);
}
};
/**
* RSA public (encrypt/verify) operation
*/
class RSA_Public_Operation
{
public:
explicit RSA_Public_Operation(const RSA_PublicKey& rsa) :
m_public(rsa.public_data())
{}
size_t get_max_input_bits() const
{
const size_t n_bits = m_public->public_modulus_bits();
/*
Make Coverity happy that n_bits - 1 won't underflow
5 bit minimum: smallest possible RSA key is 3*5
*/
BOTAN_ASSERT_NOMSG(n_bits >= 5);
return n_bits - 1;
}
protected:
BigInt public_op(const BigInt& m) const
{
if(m >= m_public->get_n())
throw Invalid_Argument("RSA public op - input is too large");
return m_public->public_op(m);
}
size_t public_modulus_bytes() const { return m_public->public_modulus_bytes(); }
const BigInt& get_n() const { return m_public->get_n(); }
std::shared_ptr<const RSA_Public_Data> m_public;
};
class RSA_Encryption_Operation final : public PK_Ops::Encryption_with_EME,
private RSA_Public_Operation
{
public:
RSA_Encryption_Operation(const RSA_PublicKey& rsa, const std::string& eme) :
PK_Ops::Encryption_with_EME(eme),
RSA_Public_Operation(rsa)
{
}
size_t ciphertext_length(size_t) const override { return public_modulus_bytes(); }
size_t max_raw_input_bits() const override { return get_max_input_bits(); }
secure_vector<uint8_t> raw_encrypt(const uint8_t input[], size_t input_len,
RandomNumberGenerator&) override
{
BigInt input_bn(input, input_len);
return BigInt::encode_1363(public_op(input_bn), public_modulus_bytes());
}
};
class RSA_Verify_Operation final : public PK_Ops::Verification_with_EMSA,
private RSA_Public_Operation
{
public:
size_t max_input_bits() const override { return get_max_input_bits(); }
RSA_Verify_Operation(const RSA_PublicKey& rsa, const std::string& emsa) :
PK_Ops::Verification_with_EMSA(emsa),
RSA_Public_Operation(rsa)
{
}
bool with_recovery() const override { return true; }
secure_vector<uint8_t> verify_mr(const uint8_t input[], size_t input_len) override
{
BigInt input_bn(input, input_len);
return BigInt::encode_locked(public_op(input_bn));
}
};
class RSA_KEM_Encryption_Operation final : public PK_Ops::KEM_Encryption_with_KDF,
private RSA_Public_Operation
{
public:
RSA_KEM_Encryption_Operation(const RSA_PublicKey& key,
const std::string& kdf) :
PK_Ops::KEM_Encryption_with_KDF(kdf),
RSA_Public_Operation(key) {}
private:
void raw_kem_encrypt(secure_vector<uint8_t>& out_encapsulated_key,
secure_vector<uint8_t>& raw_shared_key,
Botan::RandomNumberGenerator& rng) override
{
const BigInt r = BigInt::random_integer(rng, 1, get_n());
const BigInt c = public_op(r);
out_encapsulated_key = BigInt::encode_locked(c);
raw_shared_key = BigInt::encode_locked(r);
}
};
}
std::unique_ptr<PK_Ops::Encryption>
RSA_PublicKey::create_encryption_op(RandomNumberGenerator& /*rng*/,
const std::string& params,
const std::string& provider) const
{
#if defined(BOTAN_HAS_OPENSSL)
if(provider == "openssl" || provider.empty())
{
try
{
return make_openssl_rsa_enc_op(*this, params);
}
catch(Exception& e)
{
/*
* If OpenSSL for some reason could not handle this (eg due to OAEP params),
* throw if openssl was specifically requested but otherwise just fall back
* to the normal version.
*/
if(provider == "openssl")
throw Lookup_Error("OpenSSL RSA provider rejected key:" + std::string(e.what()));
}
}
#endif
if(provider == "base" || provider.empty())
return std::unique_ptr<PK_Ops::Encryption>(new RSA_Encryption_Operation(*this, params));
throw Provider_Not_Found(algo_name(), provider);
}
std::unique_ptr<PK_Ops::KEM_Encryption>
RSA_PublicKey::create_kem_encryption_op(RandomNumberGenerator& /*rng*/,
const std::string& params,
const std::string& provider) const
{
if(provider == "base" || provider.empty())
return std::unique_ptr<PK_Ops::KEM_Encryption>(new RSA_KEM_Encryption_Operation(*this, params));
throw Provider_Not_Found(algo_name(), provider);
}
std::unique_ptr<PK_Ops::Verification>
RSA_PublicKey::create_verification_op(const std::string& params,
const std::string& provider) const
{
#if defined(BOTAN_HAS_OPENSSL)
if(provider == "openssl" || provider.empty())
{
std::unique_ptr<PK_Ops::Verification> res = make_openssl_rsa_ver_op(*this, params);
if(res)
return res;
}
#endif
if(provider == "base" || provider.empty())
return std::unique_ptr<PK_Ops::Verification>(new RSA_Verify_Operation(*this, params));
throw Provider_Not_Found(algo_name(), provider);
}
std::unique_ptr<PK_Ops::Decryption>
RSA_PrivateKey::create_decryption_op(RandomNumberGenerator& rng,
const std::string& params,
const std::string& provider) const
{
#if defined(BOTAN_HAS_OPENSSL)
if(provider == "openssl" || provider.empty())
{
try
{
return make_openssl_rsa_dec_op(*this, params);
}
catch(Exception& e)
{
if(provider == "openssl")
throw Lookup_Error("OpenSSL RSA provider rejected key:" + std::string(e.what()));
}
}
#endif
if(provider == "base" || provider.empty())
return std::unique_ptr<PK_Ops::Decryption>(new RSA_Decryption_Operation(*this, params, rng));
throw Provider_Not_Found(algo_name(), provider);
}
std::unique_ptr<PK_Ops::KEM_Decryption>
RSA_PrivateKey::create_kem_decryption_op(RandomNumberGenerator& rng,
const std::string& params,
const std::string& provider) const
{
if(provider == "base" || provider.empty())
return std::unique_ptr<PK_Ops::KEM_Decryption>(new RSA_KEM_Decryption_Operation(*this, params, rng));
throw Provider_Not_Found(algo_name(), provider);
}
std::unique_ptr<PK_Ops::Signature>
RSA_PrivateKey::create_signature_op(RandomNumberGenerator& rng,
const std::string& params,
const std::string& provider) const
{
#if defined(BOTAN_HAS_OPENSSL)
if(provider == "openssl" || provider.empty())
{
std::unique_ptr<PK_Ops::Signature> res = make_openssl_rsa_sig_op(*this, params);
if(res)
return res;
}
#endif
if(provider == "base" || provider.empty())
return std::unique_ptr<PK_Ops::Signature>(new RSA_Signature_Operation(*this, params, rng));
throw Provider_Not_Found(algo_name(), provider);
}
}
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