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7d3b35004b
Since the kernel library no longer depends on the system file, move it to the common library instead in accordance to the diagram in doc/design/libraries.md.
347 lines
18 KiB
C++
347 lines
18 KiB
C++
// Copyright (c) 2012-2022 The Bitcoin Core 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 <common/system.h>
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#include <key_io.h>
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#include <streams.h>
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#include <test/util/random.h>
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#include <test/util/setup_common.h>
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#include <uint256.h>
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#include <util/strencodings.h>
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#include <util/string.h>
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#include <string>
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#include <vector>
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#include <boost/test/unit_test.hpp>
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static const std::string strSecret1 = "5HxWvvfubhXpYYpS3tJkw6fq9jE9j18THftkZjHHfmFiWtmAbrj";
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static const std::string strSecret2 = "5KC4ejrDjv152FGwP386VD1i2NYc5KkfSMyv1nGy1VGDxGHqVY3";
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static const std::string strSecret1C = "Kwr371tjA9u2rFSMZjTNun2PXXP3WPZu2afRHTcta6KxEUdm1vEw";
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static const std::string strSecret2C = "L3Hq7a8FEQwJkW1M2GNKDW28546Vp5miewcCzSqUD9kCAXrJdS3g";
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static const std::string addr1 = "1QFqqMUD55ZV3PJEJZtaKCsQmjLT6JkjvJ";
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static const std::string addr2 = "1F5y5E5FMc5YzdJtB9hLaUe43GDxEKXENJ";
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static const std::string addr1C = "1NoJrossxPBKfCHuJXT4HadJrXRE9Fxiqs";
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static const std::string addr2C = "1CRj2HyM1CXWzHAXLQtiGLyggNT9WQqsDs";
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static const std::string strAddressBad = "1HV9Lc3sNHZxwj4Zk6fB38tEmBryq2cBiF";
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BOOST_FIXTURE_TEST_SUITE(key_tests, BasicTestingSetup)
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BOOST_AUTO_TEST_CASE(key_test1)
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{
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CKey key1 = DecodeSecret(strSecret1);
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BOOST_CHECK(key1.IsValid() && !key1.IsCompressed());
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CKey key2 = DecodeSecret(strSecret2);
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BOOST_CHECK(key2.IsValid() && !key2.IsCompressed());
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CKey key1C = DecodeSecret(strSecret1C);
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BOOST_CHECK(key1C.IsValid() && key1C.IsCompressed());
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CKey key2C = DecodeSecret(strSecret2C);
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BOOST_CHECK(key2C.IsValid() && key2C.IsCompressed());
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CKey bad_key = DecodeSecret(strAddressBad);
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BOOST_CHECK(!bad_key.IsValid());
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CPubKey pubkey1 = key1. GetPubKey();
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CPubKey pubkey2 = key2. GetPubKey();
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CPubKey pubkey1C = key1C.GetPubKey();
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CPubKey pubkey2C = key2C.GetPubKey();
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BOOST_CHECK(key1.VerifyPubKey(pubkey1));
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BOOST_CHECK(!key1.VerifyPubKey(pubkey1C));
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BOOST_CHECK(!key1.VerifyPubKey(pubkey2));
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BOOST_CHECK(!key1.VerifyPubKey(pubkey2C));
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BOOST_CHECK(!key1C.VerifyPubKey(pubkey1));
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BOOST_CHECK(key1C.VerifyPubKey(pubkey1C));
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BOOST_CHECK(!key1C.VerifyPubKey(pubkey2));
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BOOST_CHECK(!key1C.VerifyPubKey(pubkey2C));
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BOOST_CHECK(!key2.VerifyPubKey(pubkey1));
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BOOST_CHECK(!key2.VerifyPubKey(pubkey1C));
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BOOST_CHECK(key2.VerifyPubKey(pubkey2));
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BOOST_CHECK(!key2.VerifyPubKey(pubkey2C));
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BOOST_CHECK(!key2C.VerifyPubKey(pubkey1));
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BOOST_CHECK(!key2C.VerifyPubKey(pubkey1C));
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BOOST_CHECK(!key2C.VerifyPubKey(pubkey2));
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BOOST_CHECK(key2C.VerifyPubKey(pubkey2C));
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BOOST_CHECK(DecodeDestination(addr1) == CTxDestination(PKHash(pubkey1)));
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BOOST_CHECK(DecodeDestination(addr2) == CTxDestination(PKHash(pubkey2)));
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BOOST_CHECK(DecodeDestination(addr1C) == CTxDestination(PKHash(pubkey1C)));
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BOOST_CHECK(DecodeDestination(addr2C) == CTxDestination(PKHash(pubkey2C)));
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for (int n=0; n<16; n++)
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{
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std::string strMsg = strprintf("Very secret message %i: 11", n);
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uint256 hashMsg = Hash(strMsg);
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// normal signatures
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std::vector<unsigned char> sign1, sign2, sign1C, sign2C;
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BOOST_CHECK(key1.Sign (hashMsg, sign1));
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BOOST_CHECK(key2.Sign (hashMsg, sign2));
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BOOST_CHECK(key1C.Sign(hashMsg, sign1C));
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BOOST_CHECK(key2C.Sign(hashMsg, sign2C));
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BOOST_CHECK( pubkey1.Verify(hashMsg, sign1));
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BOOST_CHECK(!pubkey1.Verify(hashMsg, sign2));
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BOOST_CHECK( pubkey1.Verify(hashMsg, sign1C));
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BOOST_CHECK(!pubkey1.Verify(hashMsg, sign2C));
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BOOST_CHECK(!pubkey2.Verify(hashMsg, sign1));
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BOOST_CHECK( pubkey2.Verify(hashMsg, sign2));
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BOOST_CHECK(!pubkey2.Verify(hashMsg, sign1C));
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BOOST_CHECK( pubkey2.Verify(hashMsg, sign2C));
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BOOST_CHECK( pubkey1C.Verify(hashMsg, sign1));
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BOOST_CHECK(!pubkey1C.Verify(hashMsg, sign2));
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BOOST_CHECK( pubkey1C.Verify(hashMsg, sign1C));
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BOOST_CHECK(!pubkey1C.Verify(hashMsg, sign2C));
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BOOST_CHECK(!pubkey2C.Verify(hashMsg, sign1));
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BOOST_CHECK( pubkey2C.Verify(hashMsg, sign2));
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BOOST_CHECK(!pubkey2C.Verify(hashMsg, sign1C));
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BOOST_CHECK( pubkey2C.Verify(hashMsg, sign2C));
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// compact signatures (with key recovery)
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std::vector<unsigned char> csign1, csign2, csign1C, csign2C;
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BOOST_CHECK(key1.SignCompact (hashMsg, csign1));
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BOOST_CHECK(key2.SignCompact (hashMsg, csign2));
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BOOST_CHECK(key1C.SignCompact(hashMsg, csign1C));
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BOOST_CHECK(key2C.SignCompact(hashMsg, csign2C));
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CPubKey rkey1, rkey2, rkey1C, rkey2C;
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BOOST_CHECK(rkey1.RecoverCompact (hashMsg, csign1));
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BOOST_CHECK(rkey2.RecoverCompact (hashMsg, csign2));
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BOOST_CHECK(rkey1C.RecoverCompact(hashMsg, csign1C));
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BOOST_CHECK(rkey2C.RecoverCompact(hashMsg, csign2C));
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BOOST_CHECK(rkey1 == pubkey1);
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BOOST_CHECK(rkey2 == pubkey2);
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BOOST_CHECK(rkey1C == pubkey1C);
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BOOST_CHECK(rkey2C == pubkey2C);
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}
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// test deterministic signing
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std::vector<unsigned char> detsig, detsigc;
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std::string strMsg = "Very deterministic message";
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uint256 hashMsg = Hash(strMsg);
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BOOST_CHECK(key1.Sign(hashMsg, detsig));
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BOOST_CHECK(key1C.Sign(hashMsg, detsigc));
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BOOST_CHECK(detsig == detsigc);
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BOOST_CHECK(detsig == ParseHex("304402205dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d022014ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));
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BOOST_CHECK(key2.Sign(hashMsg, detsig));
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BOOST_CHECK(key2C.Sign(hashMsg, detsigc));
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BOOST_CHECK(detsig == detsigc);
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BOOST_CHECK(detsig == ParseHex("3044022052d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd5022061d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));
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BOOST_CHECK(key1.SignCompact(hashMsg, detsig));
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BOOST_CHECK(key1C.SignCompact(hashMsg, detsigc));
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BOOST_CHECK(detsig == ParseHex("1c5dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d14ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));
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BOOST_CHECK(detsigc == ParseHex("205dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d14ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));
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BOOST_CHECK(key2.SignCompact(hashMsg, detsig));
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BOOST_CHECK(key2C.SignCompact(hashMsg, detsigc));
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BOOST_CHECK(detsig == ParseHex("1c52d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd561d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));
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BOOST_CHECK(detsigc == ParseHex("2052d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd561d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));
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}
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BOOST_AUTO_TEST_CASE(key_signature_tests)
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{
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// When entropy is specified, we should see at least one high R signature within 20 signatures
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CKey key = DecodeSecret(strSecret1);
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std::string msg = "A message to be signed";
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uint256 msg_hash = Hash(msg);
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std::vector<unsigned char> sig;
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bool found = false;
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for (int i = 1; i <=20; ++i) {
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sig.clear();
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BOOST_CHECK(key.Sign(msg_hash, sig, false, i));
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found = sig[3] == 0x21 && sig[4] == 0x00;
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if (found) {
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break;
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}
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}
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BOOST_CHECK(found);
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// When entropy is not specified, we should always see low R signatures that are less than or equal to 70 bytes in 256 tries
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// The low R signatures should always have the value of their "length of R" byte less than or equal to 32
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// We should see at least one signature that is less than 70 bytes.
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bool found_small = false;
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bool found_big = false;
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bool bad_sign = false;
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for (int i = 0; i < 256; ++i) {
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sig.clear();
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std::string msg = "A message to be signed" + ToString(i);
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msg_hash = Hash(msg);
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if (!key.Sign(msg_hash, sig)) {
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bad_sign = true;
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break;
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}
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// sig.size() > 70 implies sig[3] > 32, because S is always low.
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// But check both conditions anyway, just in case this implication is broken for some reason
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if (sig[3] > 32 || sig.size() > 70) {
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found_big = true;
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break;
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}
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found_small |= sig.size() < 70;
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}
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BOOST_CHECK(!bad_sign);
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BOOST_CHECK(!found_big);
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BOOST_CHECK(found_small);
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}
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BOOST_AUTO_TEST_CASE(key_key_negation)
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{
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// create a dummy hash for signature comparison
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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);
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uint256 hash{Hash(str, rnd)};
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// import the static test key
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CKey key = DecodeSecret(strSecret1C);
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// create a signature
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std::vector<unsigned char> vch_sig;
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std::vector<unsigned char> vch_sig_cmp;
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key.Sign(hash, vch_sig);
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// negate the key twice
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BOOST_CHECK(key.GetPubKey().data()[0] == 0x03);
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key.Negate();
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// after the first negation, the signature must be different
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key.Sign(hash, vch_sig_cmp);
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BOOST_CHECK(vch_sig_cmp != vch_sig);
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BOOST_CHECK(key.GetPubKey().data()[0] == 0x02);
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key.Negate();
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// after the second negation, we should have the original key and thus the
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// same signature
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key.Sign(hash, vch_sig_cmp);
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BOOST_CHECK(vch_sig_cmp == vch_sig);
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BOOST_CHECK(key.GetPubKey().data()[0] == 0x03);
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}
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static CPubKey UnserializePubkey(const std::vector<uint8_t>& data)
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{
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DataStream stream{};
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stream << data;
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CPubKey pubkey;
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stream >> pubkey;
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return pubkey;
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}
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static unsigned int GetLen(unsigned char chHeader)
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{
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if (chHeader == 2 || chHeader == 3)
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return CPubKey::COMPRESSED_SIZE;
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if (chHeader == 4 || chHeader == 6 || chHeader == 7)
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return CPubKey::SIZE;
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return 0;
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}
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static void CmpSerializationPubkey(const CPubKey& pubkey)
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{
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DataStream stream{};
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stream << pubkey;
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CPubKey pubkey2;
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stream >> pubkey2;
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BOOST_CHECK(pubkey == pubkey2);
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}
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BOOST_AUTO_TEST_CASE(pubkey_unserialize)
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{
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for (uint8_t i = 2; i <= 7; ++i) {
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CPubKey key = UnserializePubkey({0x02});
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BOOST_CHECK(!key.IsValid());
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CmpSerializationPubkey(key);
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key = UnserializePubkey(std::vector<uint8_t>(GetLen(i), i));
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CmpSerializationPubkey(key);
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if (i == 5) {
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BOOST_CHECK(!key.IsValid());
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} else {
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BOOST_CHECK(key.IsValid());
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}
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}
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}
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BOOST_AUTO_TEST_CASE(bip340_test_vectors)
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{
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static const std::vector<std::pair<std::array<std::string, 3>, bool>> VECTORS = {
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{{"F9308A019258C31049344F85F89D5229B531C845836F99B08601F113BCE036F9", "0000000000000000000000000000000000000000000000000000000000000000", "E907831F80848D1069A5371B402410364BDF1C5F8307B0084C55F1CE2DCA821525F66A4A85EA8B71E482A74F382D2CE5EBEEE8FDB2172F477DF4900D310536C0"}, true},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "6896BD60EEAE296DB48A229FF71DFE071BDE413E6D43F917DC8DCF8C78DE33418906D11AC976ABCCB20B091292BFF4EA897EFCB639EA871CFA95F6DE339E4B0A"}, true},
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{{"DD308AFEC5777E13121FA72B9CC1B7CC0139715309B086C960E18FD969774EB8", "7E2D58D8B3BCDF1ABADEC7829054F90DDA9805AAB56C77333024B9D0A508B75C", "5831AAEED7B44BB74E5EAB94BA9D4294C49BCF2A60728D8B4C200F50DD313C1BAB745879A5AD954A72C45A91C3A51D3C7ADEA98D82F8481E0E1E03674A6F3FB7"}, true},
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{{"25D1DFF95105F5253C4022F628A996AD3A0D95FBF21D468A1B33F8C160D8F517", "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF", "7EB0509757E246F19449885651611CB965ECC1A187DD51B64FDA1EDC9637D5EC97582B9CB13DB3933705B32BA982AF5AF25FD78881EBB32771FC5922EFC66EA3"}, true},
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{{"D69C3509BB99E412E68B0FE8544E72837DFA30746D8BE2AA65975F29D22DC7B9", "4DF3C3F68FCC83B27E9D42C90431A72499F17875C81A599B566C9889B9696703", "00000000000000000000003B78CE563F89A0ED9414F5AA28AD0D96D6795F9C6376AFB1548AF603B3EB45C9F8207DEE1060CB71C04E80F593060B07D28308D7F4"}, true},
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{{"EEFDEA4CDB677750A420FEE807EACF21EB9898AE79B9768766E4FAA04A2D4A34", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "6CFF5C3BA86C69EA4B7376F31A9BCB4F74C1976089B2D9963DA2E5543E17776969E89B4C5564D00349106B8497785DD7D1D713A8AE82B32FA79D5F7FC407D39B"}, false},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "FFF97BD5755EEEA420453A14355235D382F6472F8568A18B2F057A14602975563CC27944640AC607CD107AE10923D9EF7A73C643E166BE5EBEAFA34B1AC553E2"}, false},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "1FA62E331EDBC21C394792D2AB1100A7B432B013DF3F6FF4F99FCB33E0E1515F28890B3EDB6E7189B630448B515CE4F8622A954CFE545735AAEA5134FCCDB2BD"}, false},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "6CFF5C3BA86C69EA4B7376F31A9BCB4F74C1976089B2D9963DA2E5543E177769961764B3AA9B2FFCB6EF947B6887A226E8D7C93E00C5ED0C1834FF0D0C2E6DA6"}, false},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "0000000000000000000000000000000000000000000000000000000000000000123DDA8328AF9C23A94C1FEECFD123BA4FB73476F0D594DCB65C6425BD186051"}, false},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "00000000000000000000000000000000000000000000000000000000000000017615FBAF5AE28864013C099742DEADB4DBA87F11AC6754F93780D5A1837CF197"}, false},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "4A298DACAE57395A15D0795DDBFD1DCB564DA82B0F269BC70A74F8220429BA1D69E89B4C5564D00349106B8497785DD7D1D713A8AE82B32FA79D5F7FC407D39B"}, false},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F69E89B4C5564D00349106B8497785DD7D1D713A8AE82B32FA79D5F7FC407D39B"}, false},
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{{"DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "6CFF5C3BA86C69EA4B7376F31A9BCB4F74C1976089B2D9963DA2E5543E177769FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141"}, false},
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{{"FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC30", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "6CFF5C3BA86C69EA4B7376F31A9BCB4F74C1976089B2D9963DA2E5543E17776969E89B4C5564D00349106B8497785DD7D1D713A8AE82B32FA79D5F7FC407D39B"}, false}
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};
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|
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for (const auto& test : VECTORS) {
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auto pubkey = ParseHex(test.first[0]);
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auto msg = ParseHex(test.first[1]);
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auto sig = ParseHex(test.first[2]);
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BOOST_CHECK_EQUAL(XOnlyPubKey(pubkey).VerifySchnorr(uint256(msg), sig), test.second);
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}
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|
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static const std::vector<std::array<std::string, 5>> SIGN_VECTORS = {
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{{"0000000000000000000000000000000000000000000000000000000000000003", "F9308A019258C31049344F85F89D5229B531C845836F99B08601F113BCE036F9", "0000000000000000000000000000000000000000000000000000000000000000", "0000000000000000000000000000000000000000000000000000000000000000", "E907831F80848D1069A5371B402410364BDF1C5F8307B0084C55F1CE2DCA821525F66A4A85EA8B71E482A74F382D2CE5EBEEE8FDB2172F477DF4900D310536C0"}},
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|
{{"B7E151628AED2A6ABF7158809CF4F3C762E7160F38B4DA56A784D9045190CFEF", "DFF1D77F2A671C5F36183726DB2341BE58FEAE1DA2DECED843240F7B502BA659", "0000000000000000000000000000000000000000000000000000000000000001", "243F6A8885A308D313198A2E03707344A4093822299F31D0082EFA98EC4E6C89", "6896BD60EEAE296DB48A229FF71DFE071BDE413E6D43F917DC8DCF8C78DE33418906D11AC976ABCCB20B091292BFF4EA897EFCB639EA871CFA95F6DE339E4B0A"}},
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|
{{"C90FDAA22168C234C4C6628B80DC1CD129024E088A67CC74020BBEA63B14E5C9", "DD308AFEC5777E13121FA72B9CC1B7CC0139715309B086C960E18FD969774EB8", "C87AA53824B4D7AE2EB035A2B5BBBCCC080E76CDC6D1692C4B0B62D798E6D906", "7E2D58D8B3BCDF1ABADEC7829054F90DDA9805AAB56C77333024B9D0A508B75C", "5831AAEED7B44BB74E5EAB94BA9D4294C49BCF2A60728D8B4C200F50DD313C1BAB745879A5AD954A72C45A91C3A51D3C7ADEA98D82F8481E0E1E03674A6F3FB7"}},
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|
{{"0B432B2677937381AEF05BB02A66ECD012773062CF3FA2549E44F58ED2401710", "25D1DFF95105F5253C4022F628A996AD3A0D95FBF21D468A1B33F8C160D8F517", "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF", "FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF", "7EB0509757E246F19449885651611CB965ECC1A187DD51B64FDA1EDC9637D5EC97582B9CB13DB3933705B32BA982AF5AF25FD78881EBB32771FC5922EFC66EA3"}},
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|
};
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|
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for (const auto& [sec_hex, pub_hex, aux_hex, msg_hex, sig_hex] : SIGN_VECTORS) {
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|
auto sec = ParseHex(sec_hex);
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|
auto pub = ParseHex(pub_hex);
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|
uint256 aux256(ParseHex(aux_hex));
|
|
uint256 msg256(ParseHex(msg_hex));
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|
auto sig = ParseHex(sig_hex);
|
|
unsigned char sig64[64];
|
|
|
|
// Run the untweaked test vectors above, comparing with exact expected signature.
|
|
CKey key;
|
|
key.Set(sec.begin(), sec.end(), true);
|
|
XOnlyPubKey pubkey(key.GetPubKey());
|
|
BOOST_CHECK(std::equal(pubkey.begin(), pubkey.end(), pub.begin(), pub.end()));
|
|
bool ok = key.SignSchnorr(msg256, sig64, nullptr, aux256);
|
|
BOOST_CHECK(ok);
|
|
BOOST_CHECK(std::vector<unsigned char>(sig64, sig64 + 64) == sig);
|
|
// Verify those signatures for good measure.
|
|
BOOST_CHECK(pubkey.VerifySchnorr(msg256, sig64));
|
|
|
|
// Do 10 iterations where we sign with a random Merkle root to tweak,
|
|
// and compare against the resulting tweaked keys, with random aux.
|
|
// In iteration i=0 we tweak with empty Merkle tree.
|
|
for (int i = 0; i < 10; ++i) {
|
|
uint256 merkle_root;
|
|
if (i) merkle_root = InsecureRand256();
|
|
auto tweaked = pubkey.CreateTapTweak(i ? &merkle_root : nullptr);
|
|
BOOST_CHECK(tweaked);
|
|
XOnlyPubKey tweaked_key = tweaked->first;
|
|
aux256 = InsecureRand256();
|
|
bool ok = key.SignSchnorr(msg256, sig64, &merkle_root, aux256);
|
|
BOOST_CHECK(ok);
|
|
BOOST_CHECK(tweaked_key.VerifySchnorr(msg256, sig64));
|
|
}
|
|
}
|
|
}
|
|
|
|
BOOST_AUTO_TEST_SUITE_END()
|