lbrycrd/src/test/key_tests.cpp

// Copyright (c) 2012-2015 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.

#include "key.h"

#include "base58.h"
#include "script/script.h"
#include "uint256.h"
#include "util.h"
#include "utilstrencodings.h"
#include "test/test_bitcoin.h"

#include <string>
#include <vector>

#include <boost/test/unit_test.hpp>

using namespace std;

static const string strSecret1     ("5HxWvvfubhXpYYpS3tJkw6fq9jE9j18THftkZjHHfmFiWtmAbrj");
static const string strSecret2     ("5KC4ejrDjv152FGwP386VD1i2NYc5KkfSMyv1nGy1VGDxGHqVY3");
static const string strSecret1C    ("Kwr371tjA9u2rFSMZjTNun2PXXP3WPZu2afRHTcta6KxEUdm1vEw");
static const string strSecret2C    ("L3Hq7a8FEQwJkW1M2GNKDW28546Vp5miewcCzSqUD9kCAXrJdS3g");
static const CBitcoinAddress addr1 ("1QFqqMUD55ZV3PJEJZtaKCsQmjLT6JkjvJ");
static const CBitcoinAddress addr2 ("1F5y5E5FMc5YzdJtB9hLaUe43GDxEKXENJ");
static const CBitcoinAddress addr1C("1NoJrossxPBKfCHuJXT4HadJrXRE9Fxiqs");
static const CBitcoinAddress addr2C("1CRj2HyM1CXWzHAXLQtiGLyggNT9WQqsDs");


static const string strAddressBad("1HV9Lc3sNHZxwj4Zk6fB38tEmBryq2cBiF");


#ifdef KEY_TESTS_DUMPINFO
void dumpKeyInfo(uint256 privkey)
{
    CKey key;
    key.resize(32);
    memcpy(&secret[0], &privkey, 32);
    vector<unsigned char> sec;
    sec.resize(32);
    memcpy(&sec[0], &secret[0], 32);
    printf("  * secret (hex): %s\n", HexStr(sec).c_str());

    for (int nCompressed=0; nCompressed<2; nCompressed++)
    {
        bool fCompressed = nCompressed == 1;
        printf("  * %s:\n", fCompressed ? "compressed" : "uncompressed");
        CBitcoinSecret bsecret;
        bsecret.SetSecret(secret, fCompressed);
        printf("    * secret (base58): %s\n", bsecret.ToString().c_str());
        CKey key;
        key.SetSecret(secret, fCompressed);
        vector<unsigned char> vchPubKey = key.GetPubKey();
        printf("    * pubkey (hex): %s\n", HexStr(vchPubKey).c_str());
        printf("    * address (base58): %s\n", CBitcoinAddress(vchPubKey).ToString().c_str());
    }
}
#endif


BOOST_FIXTURE_TEST_SUITE(key_tests, BasicTestingSetup)

BOOST_AUTO_TEST_CASE(key_test1)
{
    CBitcoinSecret bsecret1, bsecret2, bsecret1C, bsecret2C, baddress1;
    BOOST_CHECK( bsecret1.SetString (strSecret1));
    BOOST_CHECK( bsecret2.SetString (strSecret2));
    BOOST_CHECK( bsecret1C.SetString(strSecret1C));
    BOOST_CHECK( bsecret2C.SetString(strSecret2C));
    BOOST_CHECK(!baddress1.SetString(strAddressBad));

    CKey key1  = bsecret1.GetKey();
    BOOST_CHECK(key1.IsCompressed() == false);
    CKey key2  = bsecret2.GetKey();
    BOOST_CHECK(key2.IsCompressed() == false);
    CKey key1C = bsecret1C.GetKey();
    BOOST_CHECK(key1C.IsCompressed() == true);
    CKey key2C = bsecret2C.GetKey();
    BOOST_CHECK(key2C.IsCompressed() == true);

    CPubKey pubkey1  = key1. GetPubKey();
    CPubKey pubkey2  = key2. GetPubKey();
    CPubKey pubkey1C = key1C.GetPubKey();
    CPubKey pubkey2C = key2C.GetPubKey();

    BOOST_CHECK(key1.VerifyPubKey(pubkey1));
    BOOST_CHECK(!key1.VerifyPubKey(pubkey1C));
    BOOST_CHECK(!key1.VerifyPubKey(pubkey2));
    BOOST_CHECK(!key1.VerifyPubKey(pubkey2C));

    BOOST_CHECK(!key1C.VerifyPubKey(pubkey1));
    BOOST_CHECK(key1C.VerifyPubKey(pubkey1C));
    BOOST_CHECK(!key1C.VerifyPubKey(pubkey2));
    BOOST_CHECK(!key1C.VerifyPubKey(pubkey2C));

    BOOST_CHECK(!key2.VerifyPubKey(pubkey1));
    BOOST_CHECK(!key2.VerifyPubKey(pubkey1C));
    BOOST_CHECK(key2.VerifyPubKey(pubkey2));
    BOOST_CHECK(!key2.VerifyPubKey(pubkey2C));

    BOOST_CHECK(!key2C.VerifyPubKey(pubkey1));
    BOOST_CHECK(!key2C.VerifyPubKey(pubkey1C));
    BOOST_CHECK(!key2C.VerifyPubKey(pubkey2));
    BOOST_CHECK(key2C.VerifyPubKey(pubkey2C));

    BOOST_CHECK(addr1.Get()  == CTxDestination(pubkey1.GetID()));
    BOOST_CHECK(addr2.Get()  == CTxDestination(pubkey2.GetID()));
    BOOST_CHECK(addr1C.Get() == CTxDestination(pubkey1C.GetID()));
    BOOST_CHECK(addr2C.Get() == CTxDestination(pubkey2C.GetID()));

    for (int n=0; n<16; n++)
    {
        string strMsg = strprintf("Very secret message %i: 11", n);
        uint256 hashMsg = Hash(strMsg.begin(), strMsg.end());

        // normal signatures

        vector<unsigned char> sign1, sign2, sign1C, sign2C;

        BOOST_CHECK(key1.Sign (hashMsg, sign1));
        BOOST_CHECK(key2.Sign (hashMsg, sign2));
        BOOST_CHECK(key1C.Sign(hashMsg, sign1C));
        BOOST_CHECK(key2C.Sign(hashMsg, sign2C));

        BOOST_CHECK( pubkey1.Verify(hashMsg, sign1));
        BOOST_CHECK(!pubkey1.Verify(hashMsg, sign2));
        BOOST_CHECK( pubkey1.Verify(hashMsg, sign1C));
        BOOST_CHECK(!pubkey1.Verify(hashMsg, sign2C));

        BOOST_CHECK(!pubkey2.Verify(hashMsg, sign1));
        BOOST_CHECK( pubkey2.Verify(hashMsg, sign2));
        BOOST_CHECK(!pubkey2.Verify(hashMsg, sign1C));
        BOOST_CHECK( pubkey2.Verify(hashMsg, sign2C));

        BOOST_CHECK( pubkey1C.Verify(hashMsg, sign1));
        BOOST_CHECK(!pubkey1C.Verify(hashMsg, sign2));
        BOOST_CHECK( pubkey1C.Verify(hashMsg, sign1C));
        BOOST_CHECK(!pubkey1C.Verify(hashMsg, sign2C));

        BOOST_CHECK(!pubkey2C.Verify(hashMsg, sign1));
        BOOST_CHECK( pubkey2C.Verify(hashMsg, sign2));
        BOOST_CHECK(!pubkey2C.Verify(hashMsg, sign1C));
        BOOST_CHECK( pubkey2C.Verify(hashMsg, sign2C));

        // compact signatures (with key recovery)

        vector<unsigned char> csign1, csign2, csign1C, csign2C;

        BOOST_CHECK(key1.SignCompact (hashMsg, csign1));
        BOOST_CHECK(key2.SignCompact (hashMsg, csign2));
        BOOST_CHECK(key1C.SignCompact(hashMsg, csign1C));
        BOOST_CHECK(key2C.SignCompact(hashMsg, csign2C));

        CPubKey rkey1, rkey2, rkey1C, rkey2C;

        BOOST_CHECK(rkey1.RecoverCompact (hashMsg, csign1));
        BOOST_CHECK(rkey2.RecoverCompact (hashMsg, csign2));
        BOOST_CHECK(rkey1C.RecoverCompact(hashMsg, csign1C));
        BOOST_CHECK(rkey2C.RecoverCompact(hashMsg, csign2C));

        BOOST_CHECK(rkey1  == pubkey1);
        BOOST_CHECK(rkey2  == pubkey2);
        BOOST_CHECK(rkey1C == pubkey1C);
        BOOST_CHECK(rkey2C == pubkey2C);
    }

    // test deterministic signing

    std::vector<unsigned char> detsig, detsigc;
    string strMsg = "Very deterministic message";
    uint256 hashMsg = Hash(strMsg.begin(), strMsg.end());
    BOOST_CHECK(key1.Sign(hashMsg, detsig));
    BOOST_CHECK(key1C.Sign(hashMsg, detsigc));
    BOOST_CHECK(detsig == detsigc);
    BOOST_CHECK(detsig == ParseHex("304402205dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d022014ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));
    BOOST_CHECK(key2.Sign(hashMsg, detsig));
    BOOST_CHECK(key2C.Sign(hashMsg, detsigc));
    BOOST_CHECK(detsig == detsigc);
    BOOST_CHECK(detsig == ParseHex("3044022052d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd5022061d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));
    BOOST_CHECK(key1.SignCompact(hashMsg, detsig));
    BOOST_CHECK(key1C.SignCompact(hashMsg, detsigc));
    BOOST_CHECK(detsig == ParseHex("1c5dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d14ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));
    BOOST_CHECK(detsigc == ParseHex("205dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d14ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));
    BOOST_CHECK(key2.SignCompact(hashMsg, detsig));
    BOOST_CHECK(key2C.SignCompact(hashMsg, detsigc));
    BOOST_CHECK(detsig == ParseHex("1c52d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd561d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));
    BOOST_CHECK(detsigc == ParseHex("2052d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd561d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));
}

BOOST_AUTO_TEST_SUITE_END()
Bump copyright headers to 2015 2015-12-13 17:58:29 +01:00			`// Copyright (c) 2012-2015 The Bitcoin Core developers`
Remove references to X11 licence 2014-12-13 05:09:33 +01:00			`// Distributed under the MIT software license, see the accompanying`
Add licenses for tests and test data - Add license headers to source files (years based on commit dates) in `src/test` as well as `qa` - Add `README.md` to `src/test/data` specifying MIT license Fixes #3848 2014-03-18 10:11:00 +01:00			`// file COPYING or http://www.opensource.org/licenses/mit-license.php.`

Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00			`#include "key.h"`
Cleanup code using forward declarations. Use misc methods of avoiding unnecesary header includes. Replace int typedefs with int##_t from stdint.h. Replace PRI64[xdu] with PRI[xdu]64 from inttypes.h. Normalize QT_VERSION ifs where possible. Resolve some indirect dependencies as direct ones. Remove extern declarations from .cpp files. 2013-04-13 07:13:08 +02:00
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00			`#include "base58.h"`
Move CScript class and dependencies to script/script 2014-08-20 17:37:40 +02:00			`#include "script/script.h"`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00			`#include "uint256.h"`
			`#include "util.h"`
Deterministic signing 2014-11-06 15:54:50 +01:00			`#include "utilstrencodings.h"`
tests: add a BasicTestingSetup and apply to all tests Make sure that chainparams and logging is properly initialized. Doing this for every test may be overkill, but this initialization is so simple that that does not matter. This should fix the travis issues. 2015-03-12 09:34:42 +01:00			`#include "test/test_bitcoin.h"`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
Cleanup code using forward declarations. Use misc methods of avoiding unnecesary header includes. Replace int typedefs with int##_t from stdint.h. Replace PRI64[xdu] with PRI[xdu]64 from inttypes.h. Normalize QT_VERSION ifs where possible. Resolve some indirect dependencies as direct ones. Remove extern declarations from .cpp files. 2013-04-13 07:13:08 +02:00			`#include <string>`
			`#include <vector>`

			`#include <boost/test/unit_test.hpp>`

Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00			`using namespace std;`

Refactor: split CKeyID/CScriptID/CTxDestination from CBitcoinAddress This introduces internal types: * CKeyID: reference (hash160) of a key * CScriptID: reference (hash160) of a script * CTxDestination: a boost::variant of the former two CBitcoinAddress is retrofitted to be a Base58 encoding of a CTxDestination. This allows all internal code to only use the internal types, and only have RPC and GUI depend on the base58 code. Furthermore, the header dependencies are a lot saner now. base58.h is at the top (right below rpc and gui) instead of at the bottom. For the rest: wallet -> script -> keystore -> key. Only keystore still requires a forward declaration of CScript. Solving that would require splitting script into two layers. 2012-05-14 23:44:52 +02:00			`static const string strSecret1 ("5HxWvvfubhXpYYpS3tJkw6fq9jE9j18THftkZjHHfmFiWtmAbrj");`
			`static const string strSecret2 ("5KC4ejrDjv152FGwP386VD1i2NYc5KkfSMyv1nGy1VGDxGHqVY3");`
			`static const string strSecret1C ("Kwr371tjA9u2rFSMZjTNun2PXXP3WPZu2afRHTcta6KxEUdm1vEw");`
			`static const string strSecret2C ("L3Hq7a8FEQwJkW1M2GNKDW28546Vp5miewcCzSqUD9kCAXrJdS3g");`
			`static const CBitcoinAddress addr1 ("1QFqqMUD55ZV3PJEJZtaKCsQmjLT6JkjvJ");`
			`static const CBitcoinAddress addr2 ("1F5y5E5FMc5YzdJtB9hLaUe43GDxEKXENJ");`
			`static const CBitcoinAddress addr1C("1NoJrossxPBKfCHuJXT4HadJrXRE9Fxiqs");`
			`static const CBitcoinAddress addr2C("1CRj2HyM1CXWzHAXLQtiGLyggNT9WQqsDs");`


			`static const string strAddressBad("1HV9Lc3sNHZxwj4Zk6fB38tEmBryq2cBiF");`

Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
			`#ifdef KEY_TESTS_DUMPINFO`
			`void dumpKeyInfo(uint256 privkey)`
			`{`
CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`CKey key;`
			`key.resize(32);`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00			`memcpy(&secret[0], &privkey, 32);`
			`vector<unsigned char> sec;`
			`sec.resize(32);`
			`memcpy(&sec[0], &secret[0], 32);`
			`printf(" * secret (hex): %s\n", HexStr(sec).c_str());`

			`for (int nCompressed=0; nCompressed<2; nCompressed++)`
			`{`
			`bool fCompressed = nCompressed == 1;`
			`printf(" * %s:\n", fCompressed ? "compressed" : "uncompressed");`
			`CBitcoinSecret bsecret;`
			`bsecret.SetSecret(secret, fCompressed);`
			`printf(" * secret (base58): %s\n", bsecret.ToString().c_str());`
			`CKey key;`
			`key.SetSecret(secret, fCompressed);`
			`vector<unsigned char> vchPubKey = key.GetPubKey();`
			`printf(" * pubkey (hex): %s\n", HexStr(vchPubKey).c_str());`
			`printf(" * address (base58): %s\n", CBitcoinAddress(vchPubKey).ToString().c_str());`
			`}`
			`}`
			`#endif`


tests: add a BasicTestingSetup and apply to all tests Make sure that chainparams and logging is properly initialized. Doing this for every test may be overkill, but this initialization is so simple that that does not matter. This should fix the travis issues. 2015-03-12 09:34:42 +01:00			`BOOST_FIXTURE_TEST_SUITE(key_tests, BasicTestingSetup)`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
			`BOOST_AUTO_TEST_CASE(key_test1)`
			`{`
CBitcoinSecret::SetString() now calls IsValid() to make sure it was passed something with the correct version. 2012-04-12 22:13:08 +02:00			`CBitcoinSecret bsecret1, bsecret2, bsecret1C, bsecret2C, baddress1;`
			`BOOST_CHECK( bsecret1.SetString (strSecret1));`
			`BOOST_CHECK( bsecret2.SetString (strSecret2));`
			`BOOST_CHECK( bsecret1C.SetString(strSecret1C));`
			`BOOST_CHECK( bsecret2C.SetString(strSecret2C));`
Refactor: split CKeyID/CScriptID/CTxDestination from CBitcoinAddress This introduces internal types: * CKeyID: reference (hash160) of a key * CScriptID: reference (hash160) of a script * CTxDestination: a boost::variant of the former two CBitcoinAddress is retrofitted to be a Base58 encoding of a CTxDestination. This allows all internal code to only use the internal types, and only have RPC and GUI depend on the base58 code. Furthermore, the header dependencies are a lot saner now. base58.h is at the top (right below rpc and gui) instead of at the bottom. For the rest: wallet -> script -> keystore -> key. Only keystore still requires a forward declaration of CScript. Solving that would require splitting script into two layers. 2012-05-14 23:44:52 +02:00			`BOOST_CHECK(!baddress1.SetString(strAddressBad));`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`CKey key1 = bsecret1.GetKey();`
			`BOOST_CHECK(key1.IsCompressed() == false);`
			`CKey key2 = bsecret2.GetKey();`
			`BOOST_CHECK(key2.IsCompressed() == false);`
			`CKey key1C = bsecret1C.GetKey();`
			`BOOST_CHECK(key1C.IsCompressed() == true);`
			`CKey key2C = bsecret2C.GetKey();`
Typo in test 2014-10-13 17:57:09 +02:00			`BOOST_CHECK(key2C.IsCompressed() == true);`
CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00
			`CPubKey pubkey1 = key1. GetPubKey();`
			`CPubKey pubkey2 = key2. GetPubKey();`
			`CPubKey pubkey1C = key1C.GetPubKey();`
			`CPubKey pubkey2C = key2C.GetPubKey();`

Add sanity check after key generation Add a sanity check to prevent cosmic rays from flipping a bit in the generated public key, or bugs in the elliptic curve code. This is simply done by signing a (randomized) message, and verifying the result. 2014-11-06 10:17:48 +01:00			`BOOST_CHECK(key1.VerifyPubKey(pubkey1));`
			`BOOST_CHECK(!key1.VerifyPubKey(pubkey1C));`
			`BOOST_CHECK(!key1.VerifyPubKey(pubkey2));`
			`BOOST_CHECK(!key1.VerifyPubKey(pubkey2C));`

			`BOOST_CHECK(!key1C.VerifyPubKey(pubkey1));`
			`BOOST_CHECK(key1C.VerifyPubKey(pubkey1C));`
			`BOOST_CHECK(!key1C.VerifyPubKey(pubkey2));`
			`BOOST_CHECK(!key1C.VerifyPubKey(pubkey2C));`

			`BOOST_CHECK(!key2.VerifyPubKey(pubkey1));`
			`BOOST_CHECK(!key2.VerifyPubKey(pubkey1C));`
			`BOOST_CHECK(key2.VerifyPubKey(pubkey2));`
			`BOOST_CHECK(!key2.VerifyPubKey(pubkey2C));`

			`BOOST_CHECK(!key2C.VerifyPubKey(pubkey1));`
			`BOOST_CHECK(!key2C.VerifyPubKey(pubkey1C));`
			`BOOST_CHECK(!key2C.VerifyPubKey(pubkey2));`
			`BOOST_CHECK(key2C.VerifyPubKey(pubkey2C));`

CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`BOOST_CHECK(addr1.Get() == CTxDestination(pubkey1.GetID()));`
			`BOOST_CHECK(addr2.Get() == CTxDestination(pubkey2.GetID()));`
			`BOOST_CHECK(addr1C.Get() == CTxDestination(pubkey1C.GetID()));`
			`BOOST_CHECK(addr2C.Get() == CTxDestination(pubkey2C.GetID()));`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
			`for (int n=0; n<16; n++)`
			`{`
			`string strMsg = strprintf("Very secret message %i: 11", n);`
			`uint256 hashMsg = Hash(strMsg.begin(), strMsg.end());`

			`// normal signatures`

			`vector<unsigned char> sign1, sign2, sign1C, sign2C;`

			`BOOST_CHECK(key1.Sign (hashMsg, sign1));`
			`BOOST_CHECK(key2.Sign (hashMsg, sign2));`
			`BOOST_CHECK(key1C.Sign(hashMsg, sign1C));`
			`BOOST_CHECK(key2C.Sign(hashMsg, sign2C));`

CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`BOOST_CHECK( pubkey1.Verify(hashMsg, sign1));`
			`BOOST_CHECK(!pubkey1.Verify(hashMsg, sign2));`
			`BOOST_CHECK( pubkey1.Verify(hashMsg, sign1C));`
			`BOOST_CHECK(!pubkey1.Verify(hashMsg, sign2C));`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`BOOST_CHECK(!pubkey2.Verify(hashMsg, sign1));`
			`BOOST_CHECK( pubkey2.Verify(hashMsg, sign2));`
			`BOOST_CHECK(!pubkey2.Verify(hashMsg, sign1C));`
			`BOOST_CHECK( pubkey2.Verify(hashMsg, sign2C));`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`BOOST_CHECK( pubkey1C.Verify(hashMsg, sign1));`
			`BOOST_CHECK(!pubkey1C.Verify(hashMsg, sign2));`
			`BOOST_CHECK( pubkey1C.Verify(hashMsg, sign1C));`
			`BOOST_CHECK(!pubkey1C.Verify(hashMsg, sign2C));`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`BOOST_CHECK(!pubkey2C.Verify(hashMsg, sign1));`
			`BOOST_CHECK( pubkey2C.Verify(hashMsg, sign2));`
			`BOOST_CHECK(!pubkey2C.Verify(hashMsg, sign1C));`
			`BOOST_CHECK( pubkey2C.Verify(hashMsg, sign2C));`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
			`// compact signatures (with key recovery)`

			`vector<unsigned char> csign1, csign2, csign1C, csign2C;`

			`BOOST_CHECK(key1.SignCompact (hashMsg, csign1));`
			`BOOST_CHECK(key2.SignCompact (hashMsg, csign2));`
			`BOOST_CHECK(key1C.SignCompact(hashMsg, csign1C));`
			`BOOST_CHECK(key2C.SignCompact(hashMsg, csign2C));`

CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`CPubKey rkey1, rkey2, rkey1C, rkey2C;`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`BOOST_CHECK(rkey1.RecoverCompact (hashMsg, csign1));`
			`BOOST_CHECK(rkey2.RecoverCompact (hashMsg, csign2));`
			`BOOST_CHECK(rkey1C.RecoverCompact(hashMsg, csign1C));`
			`BOOST_CHECK(rkey2C.RecoverCompact(hashMsg, csign2C));`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00
CSecret/CKey -> CKey/CPubKey split/refactor 2013-05-01 06:52:05 +02:00			`BOOST_CHECK(rkey1 == pubkey1);`
			`BOOST_CHECK(rkey2 == pubkey2);`
			`BOOST_CHECK(rkey1C == pubkey1C);`
			`BOOST_CHECK(rkey2C == pubkey2C);`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00			`}`
Deterministic signing 2014-11-06 15:54:50 +01:00
			`// test deterministic signing`

			`std::vector<unsigned char> detsig, detsigc;`
			`string strMsg = "Very deterministic message";`
			`uint256 hashMsg = Hash(strMsg.begin(), strMsg.end());`
			`BOOST_CHECK(key1.Sign(hashMsg, detsig));`
			`BOOST_CHECK(key1C.Sign(hashMsg, detsigc));`
			`BOOST_CHECK(detsig == detsigc);`
			`BOOST_CHECK(detsig == ParseHex("304402205dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d022014ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));`
			`BOOST_CHECK(key2.Sign(hashMsg, detsig));`
			`BOOST_CHECK(key2C.Sign(hashMsg, detsigc));`
			`BOOST_CHECK(detsig == detsigc);`
			`BOOST_CHECK(detsig == ParseHex("3044022052d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd5022061d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));`
			`BOOST_CHECK(key1.SignCompact(hashMsg, detsig));`
			`BOOST_CHECK(key1C.SignCompact(hashMsg, detsigc));`
			`BOOST_CHECK(detsig == ParseHex("1c5dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d14ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));`
			`BOOST_CHECK(detsigc == ParseHex("205dbbddda71772d95ce91cd2d14b592cfbc1dd0aabd6a394b6c2d377bbe59d31d14ddda21494a4e221f0824f0b8b924c43fa43c0ad57dccdaa11f81a6bd4582f6"));`
			`BOOST_CHECK(key2.SignCompact(hashMsg, detsig));`
			`BOOST_CHECK(key2C.SignCompact(hashMsg, detsigc));`
			`BOOST_CHECK(detsig == ParseHex("1c52d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd561d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));`
			`BOOST_CHECK(detsigc == ParseHex("2052d8a32079c11e79db95af63bb9600c5b04f21a9ca33dc129c2bfa8ac9dc1cd561d8ae5e0f6c1a16bde3719c64c2fd70e404b6428ab9a69566962e8771b5944d"));`
Unit tests for EC key routines This tests: * creation of keys from base58-encoded strings * extracting public keys and addresses * compressed public keys * compact signatures and key recovery 2012-01-08 16:59:34 +01:00			`}`

			`BOOST_AUTO_TEST_SUITE_END()`