// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2015 The Bitcoin Core developers // Distributed under the MIT 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 "pubkey.h" #include "serialize.h" #include "support/allocators/secure.h" #include "uint256.h" #include #include /** * 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 */ /** * secure_allocator is defined in allocators.h * CPrivKey is a serialized private key, with all parameters included (279 bytes) */ typedef std::vector > CPrivKey; /** An encapsulated private key. */ class CKey { private: //! Whether this private key is valid. We check for correctness when modifying the key //! data, so fValid should always correspond to the actual state. bool fValid; //! Whether the public key corresponding to this private key is (to be) compressed. bool fCompressed; //! The actual byte data std::vector > keydata; //! Check whether the 32-byte array pointed to by vch is valid keydata. bool static Check(const unsigned char* vch); public: //! Construct an invalid private key. CKey() : fValid(false), fCompressed(false) { // Important: vch must be 32 bytes in length to not break serialization keydata.resize(32); } friend bool operator==(const CKey& a, const CKey& b) { return a.fCompressed == b.fCompressed && a.size() == b.size() && memcmp(a.keydata.data(), b.keydata.data(), a.size()) == 0; } //! Initialize using begin and end iterators to byte data. template void Set(const T pbegin, const T pend, bool fCompressedIn) { if (size_t(pend - pbegin) != keydata.size()) { fValid = false; } else if (Check(&pbegin[0])) { memcpy(keydata.data(), (unsigned char*)&pbegin[0], keydata.size()); fValid = true; fCompressed = fCompressedIn; } else { fValid = false; } } //! Simple read-only vector-like interface. unsigned int size() const { return (fValid ? keydata.size() : 0); } const unsigned char* begin() const { return keydata.data(); } const unsigned char* end() const { return keydata.data() + size(); } //! Check whether this private key is valid. bool IsValid() const { return fValid; } //! Check whether the public key corresponding to this private key is (to be) compressed. bool IsCompressed() const { return fCompressed; } //! Generate a new private key using a cryptographic PRNG. void MakeNewKey(bool fCompressed); /** * Convert the private key to a CPrivKey (serialized OpenSSL private key data). * This is expensive. */ CPrivKey GetPrivKey() const; /** * Compute the public key from a private key. * This is expensive. */ CPubKey GetPubKey() const; /** * Create a DER-serialized signature. * The test_case parameter tweaks the deterministic nonce. */ bool Sign(const uint256& hash, std::vector& vchSig, uint32_t test_case = 0) const; /** * 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, * add 0x04 for compressed keys. */ bool SignCompact(const uint256& hash, std::vector& vchSig) const; //! Derive BIP32 child key. bool Derive(CKey& keyChild, ChainCode &ccChild, unsigned int nChild, const ChainCode& cc) const; /** * Verify thoroughly whether a private key and a public key match. * This is done using a different mechanism than just regenerating it. */ bool VerifyPubKey(const CPubKey& vchPubKey) const; //! Load private key and check that public key matches. bool Load(const CPrivKey& privkey, const CPubKey& vchPubKey, bool fSkipCheck); }; struct CExtKey { unsigned char nDepth; unsigned char vchFingerprint[4]; unsigned int nChild; ChainCode chaincode; CKey key; friend bool operator==(const CExtKey& a, const CExtKey& b) { return a.nDepth == b.nDepth && memcmp(&a.vchFingerprint[0], &b.vchFingerprint[0], sizeof(vchFingerprint)) == 0 && a.nChild == b.nChild && a.chaincode == b.chaincode && a.key == b.key; } void Encode(unsigned char code[BIP32_EXTKEY_SIZE]) const; void Decode(const unsigned char code[BIP32_EXTKEY_SIZE]); bool Derive(CExtKey& out, unsigned int nChild) const; CExtPubKey Neuter() const; void SetMaster(const unsigned char* seed, unsigned int nSeedLen); template void Serialize(Stream& s) const { unsigned int len = BIP32_EXTKEY_SIZE; ::WriteCompactSize(s, len); unsigned char code[BIP32_EXTKEY_SIZE]; Encode(code); s.write((const char *)&code[0], len); } template void Unserialize(Stream& s) { unsigned int len = ::ReadCompactSize(s); unsigned char code[BIP32_EXTKEY_SIZE]; if (len != BIP32_EXTKEY_SIZE) throw std::runtime_error("Invalid extended key size\n"); s.read((char *)&code[0], len); Decode(code); } }; /** Initialize the elliptic curve support. May not be called twice without calling ECC_Stop first. */ void ECC_Start(void); /** Deinitialize the elliptic curve support. No-op if ECC_Start wasn't called first. */ void ECC_Stop(void); /** Check that required EC support is available at runtime. */ bool ECC_InitSanityCheck(void); #endif // BITCOIN_KEY_H