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/*
* RSA operations provided by OpenSSL
* (C) 2015 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#include <botan/internal/openssl.h>
#if defined(BOTAN_HAS_RSA)
#include <botan/rsa.h>
#include <botan/internal/pk_utils.h>
#include <botan/internal/ct_utils.h>
#include <functional>
#include <memory>
#include <openssl/rsa.h>
#include <openssl/x509.h>
#include <openssl/err.h>
namespace Botan {
namespace {
std::pair<int, size_t> get_openssl_enc_pad(const std::string& eme)
{
ERR_load_crypto_strings();
if(eme == "Raw")
return std::make_pair(RSA_NO_PADDING, 0);
else if(eme == "EME-PKCS1-v1_5")
return std::make_pair(RSA_PKCS1_PADDING, 11);
else if(eme == "OAEP(SHA-1)")
return std::make_pair(RSA_PKCS1_OAEP_PADDING, 41);
else
throw Lookup_Error("OpenSSL RSA does not support EME " + eme);
}
class OpenSSL_RSA_Encryption_Operation : public PK_Ops::Encryption
{
public:
typedef RSA_PublicKey Key_Type;
static OpenSSL_RSA_Encryption_Operation* make(const Spec& spec)
{
try
{
if(auto* key = dynamic_cast<const RSA_PublicKey*>(&spec.key()))
{
auto pad_info = get_openssl_enc_pad(spec.padding());
return new OpenSSL_RSA_Encryption_Operation(*key, pad_info.first, pad_info.second);
}
}
catch(...) {}
return nullptr;
}
OpenSSL_RSA_Encryption_Operation(const RSA_PublicKey& rsa, int pad, size_t pad_overhead) :
m_openssl_rsa(nullptr, ::RSA_free), m_padding(pad)
{
const std::vector<byte> der = rsa.x509_subject_public_key();
const byte* der_ptr = der.data();
m_openssl_rsa.reset(::d2i_RSAPublicKey(nullptr, &der_ptr, der.size()));
if(!m_openssl_rsa)
throw OpenSSL_Error("d2i_RSAPublicKey");
m_bits = 8 * (n_size() - pad_overhead) - 1;
}
size_t max_input_bits() const override { return m_bits; };
secure_vector<byte> encrypt(const byte msg[], size_t msg_len,
RandomNumberGenerator&) override
{
const size_t mod_sz = n_size();
if(msg_len > mod_sz)
throw Invalid_Argument("Input too large for RSA key");
secure_vector<byte> outbuf(mod_sz);
secure_vector<byte> inbuf;
if(m_padding == RSA_NO_PADDING)
{
inbuf.resize(mod_sz);
copy_mem(&inbuf[mod_sz - msg_len], msg, msg_len);
}
else
{
inbuf.assign(msg, msg + msg_len);
}
int rc = ::RSA_public_encrypt(inbuf.size(), inbuf.data(), outbuf.data(),
m_openssl_rsa.get(), m_padding);
if(rc < 0)
throw OpenSSL_Error("RSA_public_encrypt");
return outbuf;
}
private:
size_t n_size() const { return ::RSA_size(m_openssl_rsa.get()); }
std::unique_ptr<RSA, std::function<void (RSA*)>> m_openssl_rsa;
size_t m_bits = 0;
int m_padding = 0;
};
class OpenSSL_RSA_Decryption_Operation : public PK_Ops::Decryption
{
public:
typedef RSA_PrivateKey Key_Type;
static OpenSSL_RSA_Decryption_Operation* make(const Spec& spec)
{
try
{
if(auto* key = dynamic_cast<const RSA_PrivateKey*>(&spec.key()))
{
auto pad_info = get_openssl_enc_pad(spec.padding());
return new OpenSSL_RSA_Decryption_Operation(*key, pad_info.first);
}
}
catch(...) {}
return nullptr;
}
OpenSSL_RSA_Decryption_Operation(const RSA_PrivateKey& rsa, int pad) :
m_openssl_rsa(nullptr, ::RSA_free), m_padding(pad)
{
const secure_vector<byte> der = rsa.pkcs8_private_key();
const byte* der_ptr = der.data();
m_openssl_rsa.reset(d2i_RSAPrivateKey(nullptr, &der_ptr, der.size()));
if(!m_openssl_rsa)
throw OpenSSL_Error("d2i_RSAPrivateKey");
}
size_t max_input_bits() const override { return ::BN_num_bits(m_openssl_rsa->n) - 1; }
secure_vector<byte> decrypt(byte& valid_mask,
const byte msg[], size_t msg_len) override
{
secure_vector<byte> buf(::RSA_size(m_openssl_rsa.get()));
int rc = ::RSA_private_decrypt(msg_len, msg, buf.data(), m_openssl_rsa.get(), m_padding);
if(rc < 0 || static_cast<size_t>(rc) > buf.size())
{
valid_mask = 0;
buf.resize(0);
}
else
{
valid_mask = 0xFF;
buf.resize(rc);
}
if(m_padding == RSA_NO_PADDING)
{
return CT::strip_leading_zeros(buf);
}
return buf;
}
private:
std::unique_ptr<RSA, std::function<void (RSA*)>> m_openssl_rsa;
int m_padding = 0;
};
class OpenSSL_RSA_Verification_Operation : public PK_Ops::Verification_with_EMSA
{
public:
typedef RSA_PublicKey Key_Type;
static OpenSSL_RSA_Verification_Operation* make(const Spec& spec)
{
if(const RSA_PublicKey* rsa = dynamic_cast<const RSA_PublicKey*>(&spec.key()))
{
return new OpenSSL_RSA_Verification_Operation(*rsa, spec.padding());
}
return nullptr;
}
OpenSSL_RSA_Verification_Operation(const RSA_PublicKey& rsa, const std::string& emsa) :
PK_Ops::Verification_with_EMSA(emsa),
m_openssl_rsa(nullptr, ::RSA_free)
{
const std::vector<byte> der = rsa.x509_subject_public_key();
const byte* der_ptr = der.data();
m_openssl_rsa.reset(::d2i_RSAPublicKey(nullptr, &der_ptr, der.size()));
}
size_t max_input_bits() const override { return ::BN_num_bits(m_openssl_rsa->n) - 1; }
bool with_recovery() const override { return true; }
secure_vector<byte> verify_mr(const byte msg[], size_t msg_len) override
{
const size_t mod_sz = ::RSA_size(m_openssl_rsa.get());
if(msg_len > mod_sz)
throw Invalid_Argument("OpenSSL RSA verify input too large");
secure_vector<byte> inbuf(mod_sz);
copy_mem(&inbuf[mod_sz - msg_len], msg, msg_len);
secure_vector<byte> outbuf(mod_sz);
int rc = ::RSA_public_decrypt(inbuf.size(), inbuf.data(), outbuf.data(),
m_openssl_rsa.get(), RSA_NO_PADDING);
if(rc < 0)
throw Invalid_Argument("RSA_public_decrypt");
return CT::strip_leading_zeros(outbuf);
}
private:
std::unique_ptr<RSA, std::function<void (RSA*)>> m_openssl_rsa;
};
class OpenSSL_RSA_Signing_Operation : public PK_Ops::Signature_with_EMSA
{
public:
typedef RSA_PrivateKey Key_Type;
static OpenSSL_RSA_Signing_Operation* make(const Spec& spec)
{
if(const RSA_PrivateKey* rsa = dynamic_cast<const RSA_PrivateKey*>(&spec.key()))
{
return new OpenSSL_RSA_Signing_Operation(*rsa, spec.padding());
}
return nullptr;
}
OpenSSL_RSA_Signing_Operation(const RSA_PrivateKey& rsa, const std::string& emsa) :
PK_Ops::Signature_with_EMSA(emsa),
m_openssl_rsa(nullptr, ::RSA_free)
{
const secure_vector<byte> der = rsa.pkcs8_private_key();
const byte* der_ptr = der.data();
m_openssl_rsa.reset(d2i_RSAPrivateKey(nullptr, &der_ptr, der.size()));
if(!m_openssl_rsa)
throw OpenSSL_Error("d2i_RSAPrivateKey");
}
secure_vector<byte> raw_sign(const byte msg[], size_t msg_len,
RandomNumberGenerator&) override
{
const size_t mod_sz = ::RSA_size(m_openssl_rsa.get());
if(msg_len > mod_sz)
throw Invalid_Argument("OpenSSL RSA sign input too large");
secure_vector<byte> inbuf(mod_sz);
copy_mem(&inbuf[mod_sz - msg_len], msg, msg_len);
secure_vector<byte> outbuf(mod_sz);
int rc = ::RSA_private_encrypt(inbuf.size(), inbuf.data(), outbuf.data(),
m_openssl_rsa.get(), RSA_NO_PADDING);
if(rc < 0)
throw OpenSSL_Error("RSA_private_encrypt");
return outbuf;
}
size_t max_input_bits() const override { return ::BN_num_bits(m_openssl_rsa->n) - 1; }
private:
std::unique_ptr<RSA, std::function<void (RSA*)>> m_openssl_rsa;
};
BOTAN_REGISTER_TYPE(PK_Ops::Verification, OpenSSL_RSA_Verification_Operation, "RSA",
OpenSSL_RSA_Verification_Operation::make, "openssl", BOTAN_OPENSSL_RSA_PRIO);
BOTAN_REGISTER_TYPE(PK_Ops::Signature, OpenSSL_RSA_Signing_Operation, "RSA",
OpenSSL_RSA_Signing_Operation::make, "openssl", BOTAN_OPENSSL_RSA_PRIO);
BOTAN_REGISTER_TYPE(PK_Ops::Encryption, OpenSSL_RSA_Encryption_Operation, "RSA",
OpenSSL_RSA_Encryption_Operation::make, "openssl", BOTAN_OPENSSL_RSA_PRIO);
BOTAN_REGISTER_TYPE(PK_Ops::Decryption, OpenSSL_RSA_Decryption_Operation, "RSA",
OpenSSL_RSA_Decryption_Operation::make, "openssl", BOTAN_OPENSSL_RSA_PRIO);
}
}
#endif // BOTAN_HAS_RSA
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