// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2012 The Bitcoin developers // Distributed under the MIT/X11 software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #ifndef BITCOIN_KEY_H #define BITCOIN_KEY_H #include #include #include #include #include #include "allocators.h" #include "uint256.h" // secp160k1 // const unsigned int PRIVATE_KEY_SIZE = 192; // const unsigned int PUBLIC_KEY_SIZE = 41; // const unsigned int SIGNATURE_SIZE = 48; // // secp192k1 // const unsigned int PRIVATE_KEY_SIZE = 222; // const unsigned int PUBLIC_KEY_SIZE = 49; // const unsigned int SIGNATURE_SIZE = 57; // // secp224k1 // const unsigned int PRIVATE_KEY_SIZE = 250; // const unsigned int PUBLIC_KEY_SIZE = 57; // const unsigned int SIGNATURE_SIZE = 66; // // secp256k1: // const unsigned int PRIVATE_KEY_SIZE = 279; // const unsigned int PUBLIC_KEY_SIZE = 65; // const unsigned int SIGNATURE_SIZE = 72; // // see www.keylength.com // script supports up to 75 for single byte push int extern EC_KEY_regenerate_key(EC_KEY *eckey, BIGNUM *priv_key); int extern ECDSA_SIG_recover_key_GFp(EC_KEY *eckey, ECDSA_SIG *ecsig, const unsigned char *msg, int msglen, int recid, int check); class key_error : public std::runtime_error { public: explicit key_error(const std::string& str) : std::runtime_error(str) {} }; // secure_allocator is defined in serialize.h // CPrivKey is a serialized private key, with all parameters included (279 bytes) typedef std::vector > CPrivKey; // CSecret is a serialization of just the secret parameter (32 bytes) typedef std::vector > CSecret; /** An encapsulated OpenSSL Elliptic Curve key (public and/or private) */ class CKey { protected: EC_KEY* pkey; bool fSet; bool fCompressedPubKey; void SetCompressedPubKey() { EC_KEY_set_conv_form(pkey, POINT_CONVERSION_COMPRESSED); fCompressedPubKey = true; } public: void Reset() { fCompressedPubKey = false; pkey = EC_KEY_new_by_curve_name(NID_secp256k1); if (pkey == NULL) throw key_error("CKey::CKey() : EC_KEY_new_by_curve_name failed"); fSet = false; } CKey() { Reset(); } CKey(const CKey& b) { pkey = EC_KEY_dup(b.pkey); if (pkey == NULL) throw key_error("CKey::CKey(const CKey&) : EC_KEY_dup failed"); fSet = b.fSet; } CKey& operator=(const CKey& b) { if (!EC_KEY_copy(pkey, b.pkey)) throw key_error("CKey::operator=(const CKey&) : EC_KEY_copy failed"); fSet = b.fSet; return (*this); } ~CKey() { EC_KEY_free(pkey); } bool IsNull() const { return !fSet; } bool IsCompressed() const { return fCompressedPubKey; } void MakeNewKey(bool fCompressed) { if (!EC_KEY_generate_key(pkey)) throw key_error("CKey::MakeNewKey() : EC_KEY_generate_key failed"); if (fCompressed) SetCompressedPubKey(); fSet = true; } bool SetPrivKey(const CPrivKey& vchPrivKey) { const unsigned char* pbegin = &vchPrivKey[0]; if (!d2i_ECPrivateKey(&pkey, &pbegin, vchPrivKey.size())) return false; fSet = true; return true; } bool SetSecret(const CSecret& vchSecret, bool fCompressed = false) { EC_KEY_free(pkey); pkey = EC_KEY_new_by_curve_name(NID_secp256k1); if (pkey == NULL) throw key_error("CKey::SetSecret() : EC_KEY_new_by_curve_name failed"); if (vchSecret.size() != 32) throw key_error("CKey::SetSecret() : secret must be 32 bytes"); BIGNUM *bn = BN_bin2bn(&vchSecret[0],32,BN_new()); if (bn == NULL) throw key_error("CKey::SetSecret() : BN_bin2bn failed"); if (!EC_KEY_regenerate_key(pkey,bn)) { BN_clear_free(bn); throw key_error("CKey::SetSecret() : EC_KEY_regenerate_key failed"); } BN_clear_free(bn); fSet = true; if (fCompressed || fCompressedPubKey) SetCompressedPubKey(); return true; } CSecret GetSecret(bool &fCompressed) const { CSecret vchRet; vchRet.resize(32); const BIGNUM *bn = EC_KEY_get0_private_key(pkey); int nBytes = BN_num_bytes(bn); if (bn == NULL) throw key_error("CKey::GetSecret() : EC_KEY_get0_private_key failed"); int n=BN_bn2bin(bn,&vchRet[32 - nBytes]); if (n != nBytes) throw key_error("CKey::GetSecret(): BN_bn2bin failed"); fCompressed = fCompressedPubKey; return vchRet; } CPrivKey GetPrivKey() const { int nSize = i2d_ECPrivateKey(pkey, NULL); if (!nSize) throw key_error("CKey::GetPrivKey() : i2d_ECPrivateKey failed"); CPrivKey vchPrivKey(nSize, 0); unsigned char* pbegin = &vchPrivKey[0]; if (i2d_ECPrivateKey(pkey, &pbegin) != nSize) throw key_error("CKey::GetPrivKey() : i2d_ECPrivateKey returned unexpected size"); return vchPrivKey; } bool SetPubKey(const std::vector& vchPubKey) { const unsigned char* pbegin = &vchPubKey[0]; if (!o2i_ECPublicKey(&pkey, &pbegin, vchPubKey.size())) return false; fSet = true; if (vchPubKey.size() == 33) SetCompressedPubKey(); return true; } std::vector GetPubKey() const { int nSize = i2o_ECPublicKey(pkey, NULL); if (!nSize) throw key_error("CKey::GetPubKey() : i2o_ECPublicKey failed"); std::vector vchPubKey(nSize, 0); unsigned char* pbegin = &vchPubKey[0]; if (i2o_ECPublicKey(pkey, &pbegin) != nSize) throw key_error("CKey::GetPubKey() : i2o_ECPublicKey returned unexpected size"); return vchPubKey; } bool Sign(uint256 hash, std::vector& vchSig) { unsigned int nSize = ECDSA_size(pkey); vchSig.resize(nSize); // Make sure it is big enough if (!ECDSA_sign(0, (unsigned char*)&hash, sizeof(hash), &vchSig[0], &nSize, pkey)) { vchSig.clear(); return false; } vchSig.resize(nSize); // Shrink to fit actual size return true; } // create a compact signature (65 bytes), which allows reconstructing the used public key // The format is one header byte, followed by two times 32 bytes for the serialized r and s values. // The header byte: 0x1B = first key with even y, 0x1C = first key with odd y, // 0x1D = second key with even y, 0x1E = second key with odd y bool SignCompact(uint256 hash, std::vector& vchSig) { bool fOk = false; ECDSA_SIG *sig = ECDSA_do_sign((unsigned char*)&hash, sizeof(hash), pkey); if (sig==NULL) return false; vchSig.clear(); vchSig.resize(65,0); int nBitsR = BN_num_bits(sig->r); int nBitsS = BN_num_bits(sig->s); if (nBitsR <= 256 && nBitsS <= 256) { int nRecId = -1; for (int i=0; i<4; i++) { CKey keyRec; keyRec.fSet = true; if (fCompressedPubKey) keyRec.SetCompressedPubKey(); if (ECDSA_SIG_recover_key_GFp(keyRec.pkey, sig, (unsigned char*)&hash, sizeof(hash), i, 1) == 1) if (keyRec.GetPubKey() == this->GetPubKey()) { nRecId = i; break; } } if (nRecId == -1) throw key_error("CKey::SignCompact() : unable to construct recoverable key"); vchSig[0] = nRecId+27+(fCompressedPubKey ? 4 : 0); BN_bn2bin(sig->r,&vchSig[33-(nBitsR+7)/8]); BN_bn2bin(sig->s,&vchSig[65-(nBitsS+7)/8]); fOk = true; } ECDSA_SIG_free(sig); return fOk; } // reconstruct public key from a compact signature // This is only slightly more CPU intensive than just verifying it. // If this function succeeds, the recovered public key is guaranteed to be valid // (the signature is a valid signature of the given data for that key) bool SetCompactSignature(uint256 hash, const std::vector& vchSig) { if (vchSig.size() != 65) return false; int nV = vchSig[0]; if (nV<27 || nV>=35) return false; ECDSA_SIG *sig = ECDSA_SIG_new(); BN_bin2bn(&vchSig[1],32,sig->r); BN_bin2bn(&vchSig[33],32,sig->s); EC_KEY_free(pkey); pkey = EC_KEY_new_by_curve_name(NID_secp256k1); if (nV >= 31) { SetCompressedPubKey(); nV -= 4; } if (ECDSA_SIG_recover_key_GFp(pkey, sig, (unsigned char*)&hash, sizeof(hash), nV - 27, 0) == 1) { fSet = true; ECDSA_SIG_free(sig); return true; } return false; } bool Verify(uint256 hash, const std::vector& vchSig) { // -1 = error, 0 = bad sig, 1 = good if (ECDSA_verify(0, (unsigned char*)&hash, sizeof(hash), &vchSig[0], vchSig.size(), pkey) != 1) return false; return true; } // Verify a compact signature bool VerifyCompact(uint256 hash, const std::vector& vchSig) { CKey key; if (!key.SetCompactSignature(hash, vchSig)) return false; if (GetPubKey() != key.GetPubKey()) return false; return true; } bool IsValid() { if (!fSet) return false; bool fCompr; CSecret secret = GetSecret(fCompr); CKey key2; key2.SetSecret(secret, fCompr); return GetPubKey() == key2.GetPubKey(); } }; #endif