sm2_enc.cpp

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/*
* SM2 Encryption
* (C) 2017 Ribose Inc
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
 
#include <botan/sm2.h>
 
#include <botan/ber_dec.h>
#include <botan/der_enc.h>
#include <botan/hash.h>
#include <botan/kdf.h>
#include <botan/pk_ops.h>
#include <botan/internal/ct_utils.h>
#include <botan/internal/fmt.h>
#include <botan/internal/point_mul.h>
 
namespace Botan {
 
namespace {
 
class SM2_Encryption_Operation final : public PK_Ops::Encryption {
   public:
      SM2_Encryption_Operation(const SM2_Encryption_PublicKey& key,
                               RandomNumberGenerator& rng,
                               std::string_view kdf_hash) :
            m_group(key.domain()), m_ws(EC_Point::WORKSPACE_SIZE), m_mul_public_point(key.public_point(), rng, m_ws) {
         m_hash = HashFunction::create_or_throw(kdf_hash);
 
         const std::string kdf_name = fmt("KDF2({})", kdf_hash);
         m_kdf = KDF::create_or_throw(kdf_name);
      }
 
      size_t max_input_bits() const override {
         // This is arbitrary, but assumes SM2 is used for key encapsulation
         return 512;
      }
 
      size_t ciphertext_length(size_t ptext_len) const override {
         const size_t elem_size = m_group.get_order_bytes();
         const size_t der_overhead = 16;
 
         return der_overhead + 2 * elem_size + m_hash->output_length() + ptext_len;
      }
 
      secure_vector<uint8_t> encrypt(const uint8_t msg[], size_t msg_len, RandomNumberGenerator& rng) override {
         const size_t p_bytes = m_group.get_p_bytes();
 
         const BigInt k = m_group.random_scalar(rng);
 
         const EC_Point C1 = m_group.blinded_base_point_multiply(k, rng, m_ws);
         const BigInt x1 = C1.get_affine_x();
         const BigInt y1 = C1.get_affine_y();
         std::vector<uint8_t> x1_bytes(p_bytes);
         std::vector<uint8_t> y1_bytes(p_bytes);
         BigInt::encode_1363(x1_bytes.data(), x1_bytes.size(), x1);
         BigInt::encode_1363(y1_bytes.data(), y1_bytes.size(), y1);
 
         const EC_Point kPB = m_mul_public_point.mul(k, rng, m_group.get_order(), m_ws);
 
         const BigInt x2 = kPB.get_affine_x();
         const BigInt y2 = kPB.get_affine_y();
         std::vector<uint8_t> x2_bytes(p_bytes);
         std::vector<uint8_t> y2_bytes(p_bytes);
         BigInt::encode_1363(x2_bytes.data(), x2_bytes.size(), x2);
         BigInt::encode_1363(y2_bytes.data(), y2_bytes.size(), y2);
 
         secure_vector<uint8_t> kdf_input;
         kdf_input += x2_bytes;
         kdf_input += y2_bytes;
 
         const secure_vector<uint8_t> kdf_output = m_kdf->derive_key(msg_len, kdf_input.data(), kdf_input.size());
 
         secure_vector<uint8_t> masked_msg(msg_len);
         xor_buf(masked_msg.data(), msg, kdf_output.data(), msg_len);
 
         m_hash->update(x2_bytes);
         m_hash->update(msg, msg_len);
         m_hash->update(y2_bytes);
         std::vector<uint8_t> C3(m_hash->output_length());
         m_hash->final(C3.data());
 
         return DER_Encoder()
            .start_sequence()
            .encode(x1)
            .encode(y1)
            .encode(C3, ASN1_Type::OctetString)
            .encode(masked_msg, ASN1_Type::OctetString)
            .end_cons()
            .get_contents();
      }
 
   private:
      const EC_Group m_group;
      std::unique_ptr<HashFunction> m_hash;
      std::unique_ptr<KDF> m_kdf;
      std::vector<BigInt> m_ws;
      EC_Point_Var_Point_Precompute m_mul_public_point;
};
 
class SM2_Decryption_Operation final : public PK_Ops::Decryption {
   public:
      SM2_Decryption_Operation(const SM2_Encryption_PrivateKey& key,
                               RandomNumberGenerator& rng,
                               std::string_view kdf_hash) :
            m_key(key), m_rng(rng) {
         m_hash = HashFunction::create_or_throw(kdf_hash);
 
         const std::string kdf_name = fmt("KDF2({})", kdf_hash);
         m_kdf = KDF::create_or_throw(kdf_name);
      }
 
      size_t plaintext_length(size_t ptext_len) const override {
         /*
         * This ignores the DER encoding and so overestimates the
         * plaintext length by 12 bytes or so
         */
         const size_t elem_size = m_key.domain().get_order_bytes();
 
         if(ptext_len < 2 * elem_size + m_hash->output_length()) {
            return 0;
         }
 
         return ptext_len - (2 * elem_size + m_hash->output_length());
      }
 
      secure_vector<uint8_t> decrypt(uint8_t& valid_mask, const uint8_t ciphertext[], size_t ciphertext_len) override {
         const EC_Group& group = m_key.domain();
         const BigInt& cofactor = group.get_cofactor();
         const size_t p_bytes = group.get_p_bytes();
 
         valid_mask = 0x00;
 
         // Too short to be valid - no timing problem from early return
         if(ciphertext_len < 1 + p_bytes * 2 + m_hash->output_length()) {
            return secure_vector<uint8_t>();
         }
 
         BigInt x1, y1;
         secure_vector<uint8_t> C3, masked_msg;
 
         BER_Decoder(ciphertext, ciphertext_len)
            .start_sequence()
            .decode(x1)
            .decode(y1)
            .decode(C3, ASN1_Type::OctetString)
            .decode(masked_msg, ASN1_Type::OctetString)
            .end_cons()
            .verify_end();
 
         std::vector<uint8_t> recode_ctext;
         DER_Encoder(recode_ctext)
            .start_sequence()
            .encode(x1)
            .encode(y1)
            .encode(C3, ASN1_Type::OctetString)
            .encode(masked_msg, ASN1_Type::OctetString)
            .end_cons();
 
         if(recode_ctext.size() != ciphertext_len) {
            return secure_vector<uint8_t>();
         }
 
         if(CT::is_equal(recode_ctext.data(), ciphertext, ciphertext_len).as_bool() == false) {
            return secure_vector<uint8_t>();
         }
 
         EC_Point C1 = group.point(x1, y1);
         C1.randomize_repr(m_rng);
 
         // Here C1 is publically invalid, so no problem with early return:
         if(!C1.on_the_curve()) {
            return secure_vector<uint8_t>();
         }
 
         if(cofactor > 1 && (C1 * cofactor).is_zero()) {
            return secure_vector<uint8_t>();
         }
 
         const EC_Point dbC1 = group.blinded_var_point_multiply(C1, m_key.private_value(), m_rng, m_ws);
 
         const BigInt x2 = dbC1.get_affine_x();
         const BigInt y2 = dbC1.get_affine_y();
 
         secure_vector<uint8_t> x2_bytes(p_bytes);
         secure_vector<uint8_t> y2_bytes(p_bytes);
         BigInt::encode_1363(x2_bytes.data(), x2_bytes.size(), x2);
         BigInt::encode_1363(y2_bytes.data(), y2_bytes.size(), y2);
 
         secure_vector<uint8_t> kdf_input;
         kdf_input += x2_bytes;
         kdf_input += y2_bytes;
 
         const secure_vector<uint8_t> kdf_output =
            m_kdf->derive_key(masked_msg.size(), kdf_input.data(), kdf_input.size());
 
         xor_buf(masked_msg.data(), kdf_output.data(), kdf_output.size());
 
         m_hash->update(x2_bytes);
         m_hash->update(masked_msg);
         m_hash->update(y2_bytes);
         secure_vector<uint8_t> u = m_hash->final();
 
         if(!CT::is_equal(u.data(), C3.data(), m_hash->output_length()).as_bool()) {
            return secure_vector<uint8_t>();
         }
 
         valid_mask = 0xFF;
         return masked_msg;
      }
 
   private:
      const SM2_Encryption_PrivateKey& m_key;
      RandomNumberGenerator& m_rng;
      std::vector<BigInt> m_ws;
      std::unique_ptr<HashFunction> m_hash;
      std::unique_ptr<KDF> m_kdf;
};
 
}  // namespace
 
std::unique_ptr<PK_Ops::Encryption> SM2_PublicKey::create_encryption_op(RandomNumberGenerator& rng,
                                                                        std::string_view params,
                                                                        std::string_view provider) const {
   if(provider == "base" || provider.empty()) {
      if(params.empty()) {
         return std::make_unique<SM2_Encryption_Operation>(*this, rng, "SM3");
      } else {
         return std::make_unique<SM2_Encryption_Operation>(*this, rng, params);
      }
   }
 
   throw Provider_Not_Found(algo_name(), provider);
}
 
std::unique_ptr<PK_Ops::Decryption> SM2_PrivateKey::create_decryption_op(RandomNumberGenerator& rng,
                                                                         std::string_view params,
                                                                         std::string_view provider) const {
   if(provider == "base" || provider.empty()) {
      if(params.empty()) {
         return std::make_unique<SM2_Decryption_Operation>(*this, rng, "SM3");
      } else {
         return std::make_unique<SM2_Decryption_Operation>(*this, rng, params);
      }
   }
 
   throw Provider_Not_Found(algo_name(), provider);
}
 
}  // namespace Botan