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90154c6074
e306be742932d4ea5aca0ea4768e54b2fc3dc6a0 Use 72 byte dummy signatures when watching only inputs may be used (Andrew Chow) 48b1473c898129a99212e2db36c61cf93625ea17 Use 71 byte signature for DUMMY_SIGNATURE_CREATOR (Andrew Chow) 18dfea0dd082af18dfb02981b7ee1cd44d514388 Always create 70 byte signatures with low R values (Andrew Chow) Pull request description: When creating signatures for transactions, always make one which has a 32 byte or smaller R and 32 byte or smaller S value. This results in signatures that are always less than 71 bytes (32 byte R + 32 byte S + 6 bytes DER + 1 byte sighash) with low R values. In most cases, the signature will be 71 bytes. Because R is not mutable in the same way that S is, a low R value can only be found by trying different nonces. RFC 6979 for deterministic nonce generation has the option to specify additional entropy, so we simply use that and add a uin32_t counter which we increment in order to try different nonces. Nonces are sill deterministically generated as the nonce used will the be the first one where the counter results in a nonce that results in a low R value. Because different nonces need to be tried, time to produce a signature does increase. On average, it takes twice as long to make a signature as two signatures need to be created, on average, to find one with a low R. Having a fixed size signature makes size calculations easier and also saves half a byte of transaction size, on average. DUMMY_SIGNATURE_CREATOR has been modified to produce 71 byte dummy signatures instead of 72 byte signatures. Tree-SHA512: 3cd791505126ce92da7c631856a97ba0b59e87d9c132feff6e0eef1dc47768e81fbb38bfbe970371bedf9714b7f61a13a5fe9f30f962c81734092a4d19a4ef33
368 lines
14 KiB
C++
368 lines
14 KiB
C++
// Copyright (c) 2009-2015 The Bitcoin Core developers
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// Copyright (c) 2017 The Zcash developers
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// Distributed under the MIT software license, see the accompanying
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// file COPYING or http://www.opensource.org/licenses/mit-license.php.
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#include <key.h>
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#include <arith_uint256.h>
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#include <crypto/common.h>
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#include <crypto/hmac_sha512.h>
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#include <random.h>
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#include <secp256k1.h>
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#include <secp256k1_recovery.h>
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static secp256k1_context* secp256k1_context_sign = nullptr;
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/** These functions are taken from the libsecp256k1 distribution and are very ugly. */
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/**
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* This parses a format loosely based on a DER encoding of the ECPrivateKey type from
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* section C.4 of SEC 1 <http://www.secg.org/sec1-v2.pdf>, with the following caveats:
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*
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* * The octet-length of the SEQUENCE must be encoded as 1 or 2 octets. It is not
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* required to be encoded as one octet if it is less than 256, as DER would require.
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* * The octet-length of the SEQUENCE must not be greater than the remaining
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* length of the key encoding, but need not match it (i.e. the encoding may contain
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* junk after the encoded SEQUENCE).
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* * The privateKey OCTET STRING is zero-filled on the left to 32 octets.
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* * Anything after the encoding of the privateKey OCTET STRING is ignored, whether
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* or not it is validly encoded DER.
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*
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* out32 must point to an output buffer of length at least 32 bytes.
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*/
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static int ec_privkey_import_der(const secp256k1_context* ctx, unsigned char *out32, const unsigned char *privkey, size_t privkeylen) {
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const unsigned char *end = privkey + privkeylen;
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memset(out32, 0, 32);
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/* sequence header */
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if (end - privkey < 1 || *privkey != 0x30u) {
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return 0;
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}
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privkey++;
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/* sequence length constructor */
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if (end - privkey < 1 || !(*privkey & 0x80u)) {
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return 0;
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}
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ptrdiff_t lenb = *privkey & ~0x80u; privkey++;
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if (lenb < 1 || lenb > 2) {
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return 0;
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}
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if (end - privkey < lenb) {
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return 0;
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}
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/* sequence length */
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ptrdiff_t len = privkey[lenb-1] | (lenb > 1 ? privkey[lenb-2] << 8 : 0u);
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privkey += lenb;
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if (end - privkey < len) {
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return 0;
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}
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/* sequence element 0: version number (=1) */
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if (end - privkey < 3 || privkey[0] != 0x02u || privkey[1] != 0x01u || privkey[2] != 0x01u) {
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return 0;
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}
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privkey += 3;
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/* sequence element 1: octet string, up to 32 bytes */
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if (end - privkey < 2 || privkey[0] != 0x04u) {
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return 0;
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}
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ptrdiff_t oslen = privkey[1];
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privkey += 2;
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if (oslen > 32 || end - privkey < oslen) {
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return 0;
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}
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memcpy(out32 + (32 - oslen), privkey, oslen);
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if (!secp256k1_ec_seckey_verify(ctx, out32)) {
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memset(out32, 0, 32);
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return 0;
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}
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return 1;
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}
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/**
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* This serializes to a DER encoding of the ECPrivateKey type from section C.4 of SEC 1
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* <http://www.secg.org/sec1-v2.pdf>. The optional parameters and publicKey fields are
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* included.
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*
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* privkey must point to an output buffer of length at least CKey::PRIVATE_KEY_SIZE bytes.
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* privkeylen must initially be set to the size of the privkey buffer. Upon return it
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* will be set to the number of bytes used in the buffer.
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* key32 must point to a 32-byte raw private key.
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*/
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static int ec_privkey_export_der(const secp256k1_context *ctx, unsigned char *privkey, size_t *privkeylen, const unsigned char *key32, bool compressed) {
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assert(*privkeylen >= CKey::PRIVATE_KEY_SIZE);
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secp256k1_pubkey pubkey;
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size_t pubkeylen = 0;
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if (!secp256k1_ec_pubkey_create(ctx, &pubkey, key32)) {
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*privkeylen = 0;
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return 0;
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}
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if (compressed) {
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static const unsigned char begin[] = {
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0x30,0x81,0xD3,0x02,0x01,0x01,0x04,0x20
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};
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static const unsigned char middle[] = {
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0xA0,0x81,0x85,0x30,0x81,0x82,0x02,0x01,0x01,0x30,0x2C,0x06,0x07,0x2A,0x86,0x48,
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0xCE,0x3D,0x01,0x01,0x02,0x21,0x00,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,
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0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,
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0xFF,0xFF,0xFE,0xFF,0xFF,0xFC,0x2F,0x30,0x06,0x04,0x01,0x00,0x04,0x01,0x07,0x04,
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0x21,0x02,0x79,0xBE,0x66,0x7E,0xF9,0xDC,0xBB,0xAC,0x55,0xA0,0x62,0x95,0xCE,0x87,
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0x0B,0x07,0x02,0x9B,0xFC,0xDB,0x2D,0xCE,0x28,0xD9,0x59,0xF2,0x81,0x5B,0x16,0xF8,
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0x17,0x98,0x02,0x21,0x00,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,
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0xFF,0xFF,0xFF,0xFF,0xFE,0xBA,0xAE,0xDC,0xE6,0xAF,0x48,0xA0,0x3B,0xBF,0xD2,0x5E,
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0x8C,0xD0,0x36,0x41,0x41,0x02,0x01,0x01,0xA1,0x24,0x03,0x22,0x00
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};
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unsigned char *ptr = privkey;
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memcpy(ptr, begin, sizeof(begin)); ptr += sizeof(begin);
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memcpy(ptr, key32, 32); ptr += 32;
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memcpy(ptr, middle, sizeof(middle)); ptr += sizeof(middle);
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pubkeylen = CPubKey::COMPRESSED_PUBLIC_KEY_SIZE;
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secp256k1_ec_pubkey_serialize(ctx, ptr, &pubkeylen, &pubkey, SECP256K1_EC_COMPRESSED);
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ptr += pubkeylen;
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*privkeylen = ptr - privkey;
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assert(*privkeylen == CKey::COMPRESSED_PRIVATE_KEY_SIZE);
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} else {
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static const unsigned char begin[] = {
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0x30,0x82,0x01,0x13,0x02,0x01,0x01,0x04,0x20
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};
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static const unsigned char middle[] = {
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0xA0,0x81,0xA5,0x30,0x81,0xA2,0x02,0x01,0x01,0x30,0x2C,0x06,0x07,0x2A,0x86,0x48,
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0xCE,0x3D,0x01,0x01,0x02,0x21,0x00,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,
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0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,
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0xFF,0xFF,0xFE,0xFF,0xFF,0xFC,0x2F,0x30,0x06,0x04,0x01,0x00,0x04,0x01,0x07,0x04,
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0x41,0x04,0x79,0xBE,0x66,0x7E,0xF9,0xDC,0xBB,0xAC,0x55,0xA0,0x62,0x95,0xCE,0x87,
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0x0B,0x07,0x02,0x9B,0xFC,0xDB,0x2D,0xCE,0x28,0xD9,0x59,0xF2,0x81,0x5B,0x16,0xF8,
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0x17,0x98,0x48,0x3A,0xDA,0x77,0x26,0xA3,0xC4,0x65,0x5D,0xA4,0xFB,0xFC,0x0E,0x11,
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0x08,0xA8,0xFD,0x17,0xB4,0x48,0xA6,0x85,0x54,0x19,0x9C,0x47,0xD0,0x8F,0xFB,0x10,
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0xD4,0xB8,0x02,0x21,0x00,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,
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0xFF,0xFF,0xFF,0xFF,0xFE,0xBA,0xAE,0xDC,0xE6,0xAF,0x48,0xA0,0x3B,0xBF,0xD2,0x5E,
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0x8C,0xD0,0x36,0x41,0x41,0x02,0x01,0x01,0xA1,0x44,0x03,0x42,0x00
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};
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unsigned char *ptr = privkey;
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memcpy(ptr, begin, sizeof(begin)); ptr += sizeof(begin);
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memcpy(ptr, key32, 32); ptr += 32;
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memcpy(ptr, middle, sizeof(middle)); ptr += sizeof(middle);
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pubkeylen = CPubKey::PUBLIC_KEY_SIZE;
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secp256k1_ec_pubkey_serialize(ctx, ptr, &pubkeylen, &pubkey, SECP256K1_EC_UNCOMPRESSED);
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ptr += pubkeylen;
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*privkeylen = ptr - privkey;
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assert(*privkeylen == CKey::PRIVATE_KEY_SIZE);
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}
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return 1;
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}
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bool CKey::Check(const unsigned char *vch) {
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return secp256k1_ec_seckey_verify(secp256k1_context_sign, vch);
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}
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void CKey::MakeNewKey(bool fCompressedIn) {
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do {
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GetStrongRandBytes(keydata.data(), keydata.size());
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} while (!Check(keydata.data()));
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fValid = true;
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fCompressed = fCompressedIn;
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}
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CPrivKey CKey::GetPrivKey() const {
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assert(fValid);
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CPrivKey privkey;
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int ret;
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size_t privkeylen;
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privkey.resize(PRIVATE_KEY_SIZE);
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privkeylen = PRIVATE_KEY_SIZE;
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ret = ec_privkey_export_der(secp256k1_context_sign, privkey.data(), &privkeylen, begin(), fCompressed);
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assert(ret);
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privkey.resize(privkeylen);
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return privkey;
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}
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CPubKey CKey::GetPubKey() const {
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assert(fValid);
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secp256k1_pubkey pubkey;
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size_t clen = CPubKey::PUBLIC_KEY_SIZE;
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CPubKey result;
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int ret = secp256k1_ec_pubkey_create(secp256k1_context_sign, &pubkey, begin());
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assert(ret);
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secp256k1_ec_pubkey_serialize(secp256k1_context_sign, (unsigned char*)result.begin(), &clen, &pubkey, fCompressed ? SECP256K1_EC_COMPRESSED : SECP256K1_EC_UNCOMPRESSED);
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assert(result.size() == clen);
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assert(result.IsValid());
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return result;
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}
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// Check that the sig has a low R value and will be less than 71 bytes
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bool SigHasLowR(const secp256k1_ecdsa_signature* sig)
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{
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unsigned char compact_sig[64];
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secp256k1_ecdsa_signature_serialize_compact(secp256k1_context_sign, compact_sig, sig);
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// In DER serialization, all values are interpreted as big-endian, signed integers. The highest bit in the integer indicates
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// its signed-ness; 0 is positive, 1 is negative. When the value is interpreted as a negative integer, it must be converted
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// to a positive value by prepending a 0x00 byte so that the highest bit is 0. We can avoid this prepending by ensuring that
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// our highest bit is always 0, and thus we must check that the first byte is less than 0x80.
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return compact_sig[0] < 0x80;
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}
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bool CKey::Sign(const uint256 &hash, std::vector<unsigned char>& vchSig, bool grind, uint32_t test_case) const {
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if (!fValid)
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return false;
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vchSig.resize(CPubKey::SIGNATURE_SIZE);
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size_t nSigLen = CPubKey::SIGNATURE_SIZE;
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unsigned char extra_entropy[32] = {0};
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WriteLE32(extra_entropy, test_case);
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secp256k1_ecdsa_signature sig;
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uint32_t counter = 0;
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int ret = secp256k1_ecdsa_sign(secp256k1_context_sign, &sig, hash.begin(), begin(), secp256k1_nonce_function_rfc6979, (!grind && test_case) ? extra_entropy : nullptr);
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// Grind for low R
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while (ret && !SigHasLowR(&sig) && grind) {
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WriteLE32(extra_entropy, ++counter);
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ret = secp256k1_ecdsa_sign(secp256k1_context_sign, &sig, hash.begin(), begin(), secp256k1_nonce_function_rfc6979, extra_entropy);
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}
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assert(ret);
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secp256k1_ecdsa_signature_serialize_der(secp256k1_context_sign, vchSig.data(), &nSigLen, &sig);
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vchSig.resize(nSigLen);
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return true;
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}
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bool CKey::VerifyPubKey(const CPubKey& pubkey) const {
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if (pubkey.IsCompressed() != fCompressed) {
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return false;
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}
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unsigned char rnd[8];
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std::string str = "Bitcoin key verification\n";
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GetRandBytes(rnd, sizeof(rnd));
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uint256 hash;
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CHash256().Write(MakeUCharSpan(str)).Write(rnd).Finalize(hash);
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std::vector<unsigned char> vchSig;
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Sign(hash, vchSig);
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return pubkey.Verify(hash, vchSig);
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}
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bool CKey::SignCompact(const uint256 &hash, std::vector<unsigned char>& vchSig) const {
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if (!fValid)
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return false;
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vchSig.resize(CPubKey::COMPACT_SIGNATURE_SIZE);
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int rec = -1;
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secp256k1_ecdsa_recoverable_signature sig;
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int ret = secp256k1_ecdsa_sign_recoverable(secp256k1_context_sign, &sig, hash.begin(), begin(), secp256k1_nonce_function_rfc6979, nullptr);
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assert(ret);
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ret = secp256k1_ecdsa_recoverable_signature_serialize_compact(secp256k1_context_sign, &vchSig[1], &rec, &sig);
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assert(ret);
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assert(rec != -1);
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vchSig[0] = 27 + rec + (fCompressed ? 4 : 0);
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return true;
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}
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bool CKey::Load(const CPrivKey &privkey, const CPubKey &vchPubKey, bool fSkipCheck=false) {
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if (!ec_privkey_import_der(secp256k1_context_sign, (unsigned char*)begin(), privkey.data(), privkey.size()))
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return false;
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fCompressed = vchPubKey.IsCompressed();
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fValid = true;
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if (fSkipCheck)
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return true;
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return VerifyPubKey(vchPubKey);
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}
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bool CKey::Derive(CKey& keyChild, ChainCode &ccChild, unsigned int nChild, const ChainCode& cc) const {
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assert(IsValid());
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assert(IsCompressed());
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std::vector<unsigned char, secure_allocator<unsigned char>> vout(64);
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if ((nChild >> 31) == 0) {
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CPubKey pubkey = GetPubKey();
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assert(pubkey.size() == CPubKey::COMPRESSED_PUBLIC_KEY_SIZE);
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BIP32Hash(cc, nChild, *pubkey.begin(), pubkey.begin()+1, vout.data());
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} else {
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assert(size() == 32);
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BIP32Hash(cc, nChild, 0, begin(), vout.data());
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}
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memcpy(ccChild.begin(), vout.data()+32, 32);
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memcpy((unsigned char*)keyChild.begin(), begin(), 32);
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bool ret = secp256k1_ec_privkey_tweak_add(secp256k1_context_sign, (unsigned char*)keyChild.begin(), vout.data());
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keyChild.fCompressed = true;
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keyChild.fValid = ret;
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return ret;
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}
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bool CExtKey::Derive(CExtKey &out, unsigned int _nChild) const {
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out.nDepth = nDepth + 1;
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CKeyID id = key.GetPubKey().GetID();
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memcpy(&out.vchFingerprint[0], &id, 4);
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out.nChild = _nChild;
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return key.Derive(out.key, out.chaincode, _nChild, chaincode);
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}
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void CExtKey::SetSeed(const unsigned char *seed, unsigned int nSeedLen) {
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static const unsigned char hashkey[] = {'B','i','t','c','o','i','n',' ','s','e','e','d'};
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std::vector<unsigned char, secure_allocator<unsigned char>> vout(64);
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CHMAC_SHA512(hashkey, sizeof(hashkey)).Write(seed, nSeedLen).Finalize(vout.data());
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key.Set(vout.data(), vout.data() + 32, true);
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memcpy(chaincode.begin(), vout.data() + 32, 32);
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nDepth = 0;
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nChild = 0;
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memset(vchFingerprint, 0, sizeof(vchFingerprint));
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}
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CExtPubKey CExtKey::Neuter() const {
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CExtPubKey ret;
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ret.nDepth = nDepth;
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memcpy(&ret.vchFingerprint[0], &vchFingerprint[0], 4);
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ret.nChild = nChild;
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ret.pubkey = key.GetPubKey();
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ret.chaincode = chaincode;
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return ret;
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}
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void CExtKey::Encode(unsigned char code[BIP32_EXTKEY_SIZE]) const {
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code[0] = nDepth;
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memcpy(code+1, vchFingerprint, 4);
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code[5] = (nChild >> 24) & 0xFF; code[6] = (nChild >> 16) & 0xFF;
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code[7] = (nChild >> 8) & 0xFF; code[8] = (nChild >> 0) & 0xFF;
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memcpy(code+9, chaincode.begin(), 32);
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code[41] = 0;
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assert(key.size() == 32);
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memcpy(code+42, key.begin(), 32);
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}
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void CExtKey::Decode(const unsigned char code[BIP32_EXTKEY_SIZE]) {
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nDepth = code[0];
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memcpy(vchFingerprint, code+1, 4);
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nChild = (code[5] << 24) | (code[6] << 16) | (code[7] << 8) | code[8];
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memcpy(chaincode.begin(), code+9, 32);
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key.Set(code+42, code+BIP32_EXTKEY_SIZE, true);
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}
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bool ECC_InitSanityCheck() {
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CKey key;
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key.MakeNewKey(true);
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CPubKey pubkey = key.GetPubKey();
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return key.VerifyPubKey(pubkey);
|
|
}
|
|
|
|
void ECC_Start() {
|
|
assert(secp256k1_context_sign == nullptr);
|
|
|
|
secp256k1_context *ctx = secp256k1_context_create(SECP256K1_CONTEXT_SIGN);
|
|
assert(ctx != nullptr);
|
|
|
|
{
|
|
// Pass in a random blinding seed to the secp256k1 context.
|
|
std::vector<unsigned char, secure_allocator<unsigned char>> vseed(32);
|
|
GetRandBytes(vseed.data(), 32);
|
|
bool ret = secp256k1_context_randomize(ctx, vseed.data());
|
|
assert(ret);
|
|
}
|
|
|
|
secp256k1_context_sign = ctx;
|
|
}
|
|
|
|
void ECC_Stop() {
|
|
secp256k1_context *ctx = secp256k1_context_sign;
|
|
secp256k1_context_sign = nullptr;
|
|
|
|
if (ctx) {
|
|
secp256k1_context_destroy(ctx);
|
|
}
|
|
}
|