diff --git a/src/wallet/test/accounting_tests.cpp b/src/wallet/test/accounting_tests.cpp index a639679eb..a3b6ccb79 100644 --- a/src/wallet/test/accounting_tests.cpp +++ b/src/wallet/test/accounting_tests.cpp @@ -1,133 +1,133 @@ // Copyright (c) 2012-2016 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 "wallet/wallet.h" +#include -#include "wallet/test/wallet_test_fixture.h" - -#include +#include #include +#include + extern CWallet *pwalletMain; BOOST_FIXTURE_TEST_SUITE(accounting_tests, WalletTestingSetup) static void GetResults(std::map &results) { std::list aes; results.clear(); BOOST_CHECK(pwalletMain->ReorderTransactions() == DBErrors::LOAD_OK); pwalletMain->ListAccountCreditDebit("", aes); for (CAccountingEntry &ae : aes) { results[ae.nOrderPos * SATOSHI] = ae; } } BOOST_AUTO_TEST_CASE(acc_orderupgrade) { std::vector vpwtx; CWalletTx wtx(nullptr /* pwallet */, MakeTransactionRef()); CAccountingEntry ae; std::map results; LOCK(pwalletMain->cs_wallet); ae.strAccount = ""; ae.nCreditDebit = SATOSHI; ae.nTime = 1333333333; ae.strOtherAccount = "b"; ae.strComment = ""; pwalletMain->AddAccountingEntry(ae); wtx.mapValue["comment"] = "z"; pwalletMain->AddToWallet(wtx); vpwtx.push_back(&pwalletMain->mapWallet.at(wtx.GetId())); vpwtx[0]->nTimeReceived = (unsigned int)1333333335; vpwtx[0]->nOrderPos = -1; ae.nTime = 1333333336; ae.strOtherAccount = "c"; pwalletMain->AddAccountingEntry(ae); GetResults(results); BOOST_CHECK(pwalletMain->nOrderPosNext == 3); BOOST_CHECK(2 == results.size()); BOOST_CHECK(results[Amount::zero()].nTime == 1333333333); BOOST_CHECK(results[Amount::zero()].strComment.empty()); BOOST_CHECK(1 == vpwtx[0]->nOrderPos); BOOST_CHECK(results[2 * SATOSHI].nTime == 1333333336); BOOST_CHECK(results[2 * SATOSHI].strOtherAccount == "c"); ae.nTime = 1333333330; ae.strOtherAccount = "d"; ae.nOrderPos = pwalletMain->IncOrderPosNext(); pwalletMain->AddAccountingEntry(ae); GetResults(results); BOOST_CHECK(results.size() == 3); BOOST_CHECK(pwalletMain->nOrderPosNext == 4); BOOST_CHECK(results[Amount::zero()].nTime == 1333333333); BOOST_CHECK(1 == vpwtx[0]->nOrderPos); BOOST_CHECK(results[2 * SATOSHI].nTime == 1333333336); BOOST_CHECK(results[3 * SATOSHI].nTime == 1333333330); BOOST_CHECK(results[3 * SATOSHI].strComment.empty()); wtx.mapValue["comment"] = "y"; { CMutableTransaction tx(*wtx.tx); // Just to change the hash :) --tx.nLockTime; wtx.SetTx(MakeTransactionRef(std::move(tx))); } pwalletMain->AddToWallet(wtx); vpwtx.push_back(&pwalletMain->mapWallet.at(wtx.GetId())); vpwtx[1]->nTimeReceived = (unsigned int)1333333336; wtx.mapValue["comment"] = "x"; { CMutableTransaction tx(*wtx.tx); // Just to change the hash :) --tx.nLockTime; wtx.SetTx(MakeTransactionRef(std::move(tx))); } pwalletMain->AddToWallet(wtx); vpwtx.push_back(&pwalletMain->mapWallet.at(wtx.GetId())); vpwtx[2]->nTimeReceived = (unsigned int)1333333329; vpwtx[2]->nOrderPos = -1; GetResults(results); BOOST_CHECK(results.size() == 3); BOOST_CHECK(pwalletMain->nOrderPosNext == 6); BOOST_CHECK(0 == vpwtx[2]->nOrderPos); BOOST_CHECK(results[SATOSHI].nTime == 1333333333); BOOST_CHECK(2 == vpwtx[0]->nOrderPos); BOOST_CHECK(results[3 * SATOSHI].nTime == 1333333336); BOOST_CHECK(results[4 * SATOSHI].nTime == 1333333330); BOOST_CHECK(results[4 * SATOSHI].strComment.empty()); BOOST_CHECK(5 == vpwtx[1]->nOrderPos); ae.nTime = 1333333334; ae.strOtherAccount = "e"; ae.nOrderPos = -1; pwalletMain->AddAccountingEntry(ae); GetResults(results); BOOST_CHECK(results.size() == 4); BOOST_CHECK(pwalletMain->nOrderPosNext == 7); BOOST_CHECK(0 == vpwtx[2]->nOrderPos); BOOST_CHECK(results[SATOSHI].nTime == 1333333333); BOOST_CHECK(2 == vpwtx[0]->nOrderPos); BOOST_CHECK(results[3 * SATOSHI].nTime == 1333333336); BOOST_CHECK(results[3 * SATOSHI].strComment.empty()); BOOST_CHECK(results[4 * SATOSHI].nTime == 1333333330); BOOST_CHECK(results[4 * SATOSHI].strComment.empty()); BOOST_CHECK(results[5 * SATOSHI].nTime == 1333333334); BOOST_CHECK(6 == vpwtx[1]->nOrderPos); } BOOST_AUTO_TEST_SUITE_END() diff --git a/src/wallet/test/wallet_crypto_tests.cpp b/src/wallet/test/wallet_crypto_tests.cpp index ff36bf179..b45574af2 100644 --- a/src/wallet/test/wallet_crypto_tests.cpp +++ b/src/wallet/test/wallet_crypto_tests.cpp @@ -1,294 +1,296 @@ // Copyright (c) 2014-2016 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 "test/test_bitcoin.h" -#include "utilstrencodings.h" -#include "wallet/crypter.h" +#include +#include -#include +#include #include + #include #include +#include + BOOST_FIXTURE_TEST_SUITE(wallet_crypto_tests, BasicTestingSetup) bool OldSetKeyFromPassphrase(const SecureString &strKeyData, const std::vector &chSalt, const unsigned int nRounds, const unsigned int nDerivationMethod, uint8_t *chKey, uint8_t *chIV) { if (nRounds < 1 || chSalt.size() != WALLET_CRYPTO_SALT_SIZE) return false; int i = 0; if (nDerivationMethod == 0) i = EVP_BytesToKey(EVP_aes_256_cbc(), EVP_sha512(), &chSalt[0], (uint8_t *)&strKeyData[0], strKeyData.size(), nRounds, chKey, chIV); if (i != (int)WALLET_CRYPTO_KEY_SIZE) { memory_cleanse(chKey, sizeof(chKey)); memory_cleanse(chIV, sizeof(chIV)); return false; } return true; } bool OldEncrypt(const CKeyingMaterial &vchPlaintext, std::vector &vchCiphertext, const uint8_t chKey[32], const uint8_t chIV[16]) { // max ciphertext len for a n bytes of plaintext is // n + AES_BLOCK_SIZE - 1 bytes int nLen = vchPlaintext.size(); int nCLen = nLen + AES_BLOCK_SIZE, nFLen = 0; vchCiphertext = std::vector(nCLen); EVP_CIPHER_CTX *ctx = EVP_CIPHER_CTX_new(); if (!ctx) return false; bool fOk = true; EVP_CIPHER_CTX_init(ctx); if (fOk) fOk = EVP_EncryptInit_ex(ctx, EVP_aes_256_cbc(), nullptr, chKey, chIV) != 0; if (fOk) fOk = EVP_EncryptUpdate(ctx, &vchCiphertext[0], &nCLen, &vchPlaintext[0], nLen) != 0; if (fOk) fOk = EVP_EncryptFinal_ex(ctx, (&vchCiphertext[0]) + nCLen, &nFLen) != 0; EVP_CIPHER_CTX_cleanup(ctx); EVP_CIPHER_CTX_free(ctx); if (!fOk) return false; vchCiphertext.resize(nCLen + nFLen); return true; } bool OldDecrypt(const std::vector &vchCiphertext, CKeyingMaterial &vchPlaintext, const uint8_t chKey[32], const uint8_t chIV[16]) { // plaintext will always be equal to or lesser than length of ciphertext int nLen = vchCiphertext.size(); int nPLen = nLen, nFLen = 0; vchPlaintext = CKeyingMaterial(nPLen); EVP_CIPHER_CTX *ctx = EVP_CIPHER_CTX_new(); if (!ctx) return false; bool fOk = true; EVP_CIPHER_CTX_init(ctx); if (fOk) fOk = EVP_DecryptInit_ex(ctx, EVP_aes_256_cbc(), nullptr, chKey, chIV) != 0; if (fOk) fOk = EVP_DecryptUpdate(ctx, &vchPlaintext[0], &nPLen, &vchCiphertext[0], nLen) != 0; if (fOk) fOk = EVP_DecryptFinal_ex(ctx, (&vchPlaintext[0]) + nPLen, &nFLen) != 0; EVP_CIPHER_CTX_cleanup(ctx); EVP_CIPHER_CTX_free(ctx); if (!fOk) return false; vchPlaintext.resize(nPLen + nFLen); return true; } class TestCrypter { public: static void TestPassphraseSingle( const std::vector &vchSalt, const SecureString &passphrase, uint32_t rounds, const std::vector &correctKey = std::vector(), const std::vector &correctIV = std::vector()) { uint8_t chKey[WALLET_CRYPTO_KEY_SIZE]; uint8_t chIV[WALLET_CRYPTO_IV_SIZE]; CCrypter crypt; crypt.SetKeyFromPassphrase(passphrase, vchSalt, rounds, 0); OldSetKeyFromPassphrase(passphrase, vchSalt, rounds, 0, chKey, chIV); BOOST_CHECK_MESSAGE( memcmp(chKey, crypt.vchKey.data(), crypt.vchKey.size()) == 0, HexStr(chKey, chKey + sizeof(chKey)) + std::string(" != ") + HexStr(crypt.vchKey)); BOOST_CHECK_MESSAGE( memcmp(chIV, crypt.vchIV.data(), crypt.vchIV.size()) == 0, HexStr(chIV, chIV + sizeof(chIV)) + std::string(" != ") + HexStr(crypt.vchIV)); if (!correctKey.empty()) BOOST_CHECK_MESSAGE( memcmp(chKey, &correctKey[0], sizeof(chKey)) == 0, HexStr(chKey, chKey + sizeof(chKey)) + std::string(" != ") + HexStr(correctKey.begin(), correctKey.end())); if (!correctIV.empty()) BOOST_CHECK_MESSAGE(memcmp(chIV, &correctIV[0], sizeof(chIV)) == 0, HexStr(chIV, chIV + sizeof(chIV)) + std::string(" != ") + HexStr(correctIV.begin(), correctIV.end())); } static void TestPassphrase( const std::vector &vchSalt, const SecureString &passphrase, uint32_t rounds, const std::vector &correctKey = std::vector(), const std::vector &correctIV = std::vector()) { TestPassphraseSingle(vchSalt, passphrase, rounds, correctKey, correctIV); for (SecureString::const_iterator i(passphrase.begin()); i != passphrase.end(); ++i) TestPassphraseSingle(vchSalt, SecureString(i, passphrase.end()), rounds); } static void TestDecrypt( const CCrypter &crypt, const std::vector &vchCiphertext, const std::vector &vchPlaintext = std::vector()) { CKeyingMaterial vchDecrypted1; CKeyingMaterial vchDecrypted2; int result1, result2; result1 = crypt.Decrypt(vchCiphertext, vchDecrypted1); result2 = OldDecrypt(vchCiphertext, vchDecrypted2, crypt.vchKey.data(), crypt.vchIV.data()); BOOST_CHECK(result1 == result2); // These two should be equal. However, OpenSSL 1.0.1j introduced a // change that would zero all padding except for the last byte for // failed decrypts. // This behavior was reverted for 1.0.1k. if (vchDecrypted1 != vchDecrypted2 && vchDecrypted1.size() >= AES_BLOCK_SIZE && SSLeay() == 0x100010afL) { for (CKeyingMaterial::iterator it = vchDecrypted1.end() - AES_BLOCK_SIZE; it != vchDecrypted1.end() - 1; it++) *it = 0; } BOOST_CHECK_MESSAGE( vchDecrypted1 == vchDecrypted2, HexStr(vchDecrypted1.begin(), vchDecrypted1.end()) + " != " + HexStr(vchDecrypted2.begin(), vchDecrypted2.end())); if (vchPlaintext.size()) BOOST_CHECK(CKeyingMaterial(vchPlaintext.begin(), vchPlaintext.end()) == vchDecrypted2); } static void TestEncryptSingle(const CCrypter &crypt, const CKeyingMaterial &vchPlaintext, const std::vector &vchCiphertextCorrect = std::vector()) { std::vector vchCiphertext1; std::vector vchCiphertext2; int result1 = crypt.Encrypt(vchPlaintext, vchCiphertext1); int result2 = OldEncrypt(vchPlaintext, vchCiphertext2, crypt.vchKey.data(), crypt.vchIV.data()); BOOST_CHECK(result1 == result2); BOOST_CHECK(vchCiphertext1 == vchCiphertext2); if (!vchCiphertextCorrect.empty()) BOOST_CHECK(vchCiphertext2 == vchCiphertextCorrect); const std::vector vchPlaintext2(vchPlaintext.begin(), vchPlaintext.end()); if (vchCiphertext1 == vchCiphertext2) TestDecrypt(crypt, vchCiphertext1, vchPlaintext2); } static void TestEncrypt(const CCrypter &crypt, const std::vector &vchPlaintextIn, const std::vector &vchCiphertextCorrect = std::vector()) { TestEncryptSingle( crypt, CKeyingMaterial(vchPlaintextIn.begin(), vchPlaintextIn.end()), vchCiphertextCorrect); for (std::vector::const_iterator i(vchPlaintextIn.begin()); i != vchPlaintextIn.end(); ++i) TestEncryptSingle(crypt, CKeyingMaterial(i, vchPlaintextIn.end())); } }; BOOST_AUTO_TEST_CASE(passphrase) { // These are expensive. TestCrypter::TestPassphrase( ParseHex("0000deadbeef0000"), "test", 25000, ParseHex( "fc7aba077ad5f4c3a0988d8daa4810d0d4a0e3bcb53af662998898f33df0556a"), ParseHex("cf2f2691526dd1aa220896fb8bf7c369")); std::string hash(GetRandHash().ToString()); std::vector vchSalt(8); GetRandBytes(&vchSalt[0], vchSalt.size()); uint32_t rounds = insecure_rand(); if (rounds > 30000) rounds = 30000; TestCrypter::TestPassphrase(vchSalt, SecureString(hash.begin(), hash.end()), rounds); } BOOST_AUTO_TEST_CASE(encrypt) { std::vector vchSalt = ParseHex("0000deadbeef0000"); BOOST_CHECK(vchSalt.size() == WALLET_CRYPTO_SALT_SIZE); CCrypter crypt; crypt.SetKeyFromPassphrase("passphrase", vchSalt, 25000, 0); TestCrypter::TestEncrypt(crypt, ParseHex("22bcade09ac03ff6386914359cfe885cfeb5f77f" "f0d670f102f619687453b29d")); for (int i = 0; i != 100; i++) { uint256 hash(GetRandHash()); TestCrypter::TestEncrypt( crypt, std::vector(hash.begin(), hash.end())); } } BOOST_AUTO_TEST_CASE(decrypt) { std::vector vchSalt = ParseHex("0000deadbeef0000"); BOOST_CHECK(vchSalt.size() == WALLET_CRYPTO_SALT_SIZE); CCrypter crypt; crypt.SetKeyFromPassphrase("passphrase", vchSalt, 25000, 0); // Some corner cases the came up while testing TestCrypter::TestDecrypt(crypt, ParseHex("795643ce39d736088367822cdc50535ec6f10371" "5e3e48f4f3b1a60a08ef59ca")); TestCrypter::TestDecrypt(crypt, ParseHex("de096f4a8f9bd97db012aa9d90d74de8cdea779c" "3ee8bc7633d8b5d6da703486")); TestCrypter::TestDecrypt(crypt, ParseHex("32d0a8974e3afd9c6c3ebf4d66aa4e6419f8c173" "de25947f98cf8b7ace49449c")); TestCrypter::TestDecrypt(crypt, ParseHex("e7c055cca2faa78cb9ac22c9357a90b4778ded9b" "2cc220a14cea49f931e596ea")); TestCrypter::TestDecrypt(crypt, ParseHex("b88efddd668a6801d19516d6830da4ae9811988c" "cbaf40df8fbb72f3f4d335fd")); TestCrypter::TestDecrypt(crypt, ParseHex("8cae76aa6a43694e961ebcb28c8ca8f8540b8415" "3d72865e8561ddd93fa7bfa9")); for (int i = 0; i != 100; i++) { uint256 hash(GetRandHash()); TestCrypter::TestDecrypt( crypt, std::vector(hash.begin(), hash.end())); } } BOOST_AUTO_TEST_SUITE_END() diff --git a/src/wallet/test/wallet_test_fixture.cpp b/src/wallet/test/wallet_test_fixture.cpp index 9065eeac7..64f3d4d7e 100644 --- a/src/wallet/test/wallet_test_fixture.cpp +++ b/src/wallet/test/wallet_test_fixture.cpp @@ -1,36 +1,36 @@ // Copyright (c) 2016 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 "wallet/test/wallet_test_fixture.h" -#include "chainparams.h" +#include -#include "rpc/server.h" -#include "wallet/db.h" -#include "wallet/rpcdump.h" -#include "wallet/wallet.h" +#include +#include +#include +#include +#include std::unique_ptr pwalletMain; WalletTestingSetup::WalletTestingSetup(const std::string &chainName) : TestingSetup(chainName) { bitdb.MakeMock(); bool fFirstRun; std::unique_ptr dbw( new CWalletDBWrapper(&bitdb, "wallet_test.dat")); pwalletMain = std::make_unique(Params(), std::move(dbw)); pwalletMain->LoadWallet(fFirstRun); RegisterValidationInterface(pwalletMain.get()); RegisterWalletRPCCommands(tableRPC); RegisterDumpRPCCommands(tableRPC); } WalletTestingSetup::~WalletTestingSetup() { UnregisterValidationInterface(pwalletMain.get()); pwalletMain.reset(); bitdb.Flush(true); bitdb.Reset(); } diff --git a/src/wallet/test/wallet_test_fixture.h b/src/wallet/test/wallet_test_fixture.h index cdab76c09..871b4dd75 100644 --- a/src/wallet/test/wallet_test_fixture.h +++ b/src/wallet/test/wallet_test_fixture.h @@ -1,19 +1,19 @@ // Copyright (c) 2016 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_WALLET_TEST_FIXTURE_H #define BITCOIN_WALLET_TEST_FIXTURE_H -#include "test/test_bitcoin.h" +#include /** * Testing setup and teardown for wallet. */ struct WalletTestingSetup : public TestingSetup { explicit WalletTestingSetup( const std::string &chainName = CBaseChainParams::MAIN); ~WalletTestingSetup(); }; #endif diff --git a/src/wallet/test/wallet_tests.cpp b/src/wallet/test/wallet_tests.cpp index c3a79daa5..f7f2b0a50 100644 --- a/src/wallet/test/wallet_tests.cpp +++ b/src/wallet/test/wallet_tests.cpp @@ -1,805 +1,804 @@ // Copyright (c) 2012-2016 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 "wallet/wallet.h" - -#include "chainparams.h" -#include "config.h" - -#include "consensus/validation.h" -#include "rpc/server.h" -#include "test/test_bitcoin.h" -#include "validation.h" -#include "wallet/coincontrol.h" -#include "wallet/rpcdump.h" -#include "wallet/test/wallet_test_fixture.h" +#include +#include +#include +#include +#include +#include +#include +#include + +#include +#include #include #include #include #include #include #include extern CWallet *pwalletMain; // how many times to run all the tests to have a chance to catch errors that // only show up with particular random shuffles #define RUN_TESTS 100 // some tests fail 1% of the time due to bad luck. We repeat those tests this // many times and only complain if all iterations of the test fail. #define RANDOM_REPEATS 5 std::vector> wtxn; typedef std::set CoinSet; BOOST_FIXTURE_TEST_SUITE(wallet_tests, WalletTestingSetup) // Critical section is used to prevent concurrent execution of // tests in this fixture static CCriticalSection walletCriticalSection; static std::vector vCoins; static void add_coin(const CWallet &wallet, const Amount nValue, int nAge = 6 * 24, bool fIsFromMe = false, int nInput = 0) { static int nextLockTime = 0; CMutableTransaction tx; // So all transactions get different hashes. tx.nLockTime = nextLockTime++; tx.vout.resize(nInput + 1); tx.vout[nInput].nValue = nValue; if (fIsFromMe) { // IsFromMe() returns (GetDebit() > 0), and GetDebit() is 0 if // vin.empty(), so stop vin being empty, and cache a non-zero Debit to // fake out IsFromMe() tx.vin.resize(1); } std::unique_ptr wtx( new CWalletTx(&wallet, MakeTransactionRef(std::move(tx)))); if (fIsFromMe) { wtx->fDebitCached = true; wtx->nDebitCached = SATOSHI; } COutput output(wtx.get(), nInput, nAge, true /* spendable */, true /* solvable */, true /* safe */); vCoins.push_back(output); wtxn.emplace_back(std::move(wtx)); } static void empty_wallet(void) { vCoins.clear(); wtxn.clear(); } static bool equal_sets(CoinSet a, CoinSet b) { std::pair ret = mismatch(a.begin(), a.end(), b.begin()); return ret.first == a.end() && ret.second == b.end(); } BOOST_AUTO_TEST_CASE(coin_selection_tests) { CoinSet setCoinsRet, setCoinsRet2; Amount nValueRet; const CWallet wallet(Params()); LOCK(walletCriticalSection); // test multiple times to allow for differences in the shuffle order for (int i = 0; i < RUN_TESTS; i++) { empty_wallet(); // with an empty wallet we can't even pay one cent BOOST_CHECK(!wallet.SelectCoinsMinConf(1 * CENT, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); // add a new 1 cent coin add_coin(wallet, 1 * CENT, 4); // with a new 1 cent coin, we still can't find a mature 1 cent BOOST_CHECK(!wallet.SelectCoinsMinConf(1 * CENT, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); // but we can find a new 1 cent BOOST_CHECK(wallet.SelectCoinsMinConf(1 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 1 * CENT); // add a mature 2 cent coin add_coin(wallet, 2 * CENT); // we can't make 3 cents of mature coins BOOST_CHECK(!wallet.SelectCoinsMinConf(3 * CENT, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); // we can make 3 cents of new coins BOOST_CHECK(wallet.SelectCoinsMinConf(3 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 3 * CENT); // add a mature 5 cent coin, add_coin(wallet, 5 * CENT); // a new 10 cent coin sent from one of our own addresses add_coin(wallet, 10 * CENT, 3, true); // and a mature 20 cent coin add_coin(wallet, 20 * CENT); // now we have new: 1+10=11 (of which 10 was self-sent), and mature: // 2+5+20=27. total = 38 // we can't make 38 cents only if we disallow new coins: BOOST_CHECK(!wallet.SelectCoinsMinConf(38 * CENT, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); // we can't even make 37 cents if we don't allow new coins even if // they're from us BOOST_CHECK(!wallet.SelectCoinsMinConf(38 * CENT, 6, 6, 0, vCoins, setCoinsRet, nValueRet)); // but we can make 37 cents if we accept new coins from ourself BOOST_CHECK(wallet.SelectCoinsMinConf(37 * CENT, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 37 * CENT); // and we can make 38 cents if we accept all new coins BOOST_CHECK(wallet.SelectCoinsMinConf(38 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 38 * CENT); // try making 34 cents from 1,2,5,10,20 - we can't do it exactly BOOST_CHECK(wallet.SelectCoinsMinConf(34 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // but 35 cents is closest BOOST_CHECK_EQUAL(nValueRet, 35 * CENT); // the best should be 20+10+5. it's incredibly unlikely the 1 or 2 got // included (but possible) BOOST_CHECK_EQUAL(setCoinsRet.size(), 3U); // when we try making 7 cents, the smaller coins (1,2,5) are enough. We // should see just 2+5 BOOST_CHECK(wallet.SelectCoinsMinConf(7 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 7 * CENT); BOOST_CHECK_EQUAL(setCoinsRet.size(), 2U); // when we try making 8 cents, the smaller coins (1,2,5) are exactly // enough. BOOST_CHECK(wallet.SelectCoinsMinConf(8 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK(nValueRet == 8 * CENT); BOOST_CHECK_EQUAL(setCoinsRet.size(), 3U); // when we try making 9 cents, no subset of smaller coins is enough, and // we get the next bigger coin (10) BOOST_CHECK(wallet.SelectCoinsMinConf(9 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 10 * CENT); BOOST_CHECK_EQUAL(setCoinsRet.size(), 1U); // now clear out the wallet and start again to test choosing between // subsets of smaller coins and the next biggest coin empty_wallet(); add_coin(wallet, 6 * CENT); add_coin(wallet, 7 * CENT); add_coin(wallet, 8 * CENT); add_coin(wallet, 20 * CENT); // now we have 6+7+8+20+30 = 71 cents total add_coin(wallet, 30 * CENT); // check that we have 71 and not 72 BOOST_CHECK(wallet.SelectCoinsMinConf(71 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK(!wallet.SelectCoinsMinConf(72 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // now try making 16 cents. the best smaller coins can do is 6+7+8 = // 21; not as good at the next biggest coin, 20 BOOST_CHECK(wallet.SelectCoinsMinConf(16 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get 20 in one coin BOOST_CHECK_EQUAL(nValueRet, 20 * CENT); BOOST_CHECK_EQUAL(setCoinsRet.size(), 1U); // now we have 5+6+7+8+20+30 = 75 cents total add_coin(wallet, 5 * CENT); // now if we try making 16 cents again, the smaller coins can make 5+6+7 // = 18 cents, better than the next biggest coin, 20 BOOST_CHECK(wallet.SelectCoinsMinConf(16 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get 18 in 3 coins BOOST_CHECK_EQUAL(nValueRet, 18 * CENT); BOOST_CHECK_EQUAL(setCoinsRet.size(), 3U); // now we have 5+6+7+8+18+20+30 add_coin(wallet, 18 * CENT); // and now if we try making 16 cents again, the smaller coins can make // 5+6+7 = 18 cents, the same as the next biggest coin, 18 BOOST_CHECK(wallet.SelectCoinsMinConf(16 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get 18 in 1 coin BOOST_CHECK_EQUAL(nValueRet, 18 * CENT); // because in the event of a tie, the biggest coin wins BOOST_CHECK_EQUAL(setCoinsRet.size(), 1U); // now try making 11 cents. we should get 5+6 BOOST_CHECK(wallet.SelectCoinsMinConf(11 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 11 * CENT); BOOST_CHECK_EQUAL(setCoinsRet.size(), 2U); // check that the smallest bigger coin is used add_coin(wallet, 1 * COIN); add_coin(wallet, 2 * COIN); add_coin(wallet, 3 * COIN); // now we have 5+6+7+8+18+20+30+100+200+300+400 = 1094 cents add_coin(wallet, 4 * COIN); BOOST_CHECK(wallet.SelectCoinsMinConf(95 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get 1 BCH in 1 coin BOOST_CHECK_EQUAL(nValueRet, 1 * COIN); BOOST_CHECK_EQUAL(setCoinsRet.size(), 1U); BOOST_CHECK(wallet.SelectCoinsMinConf(195 * CENT, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get 2 BCH in 1 coin BOOST_CHECK_EQUAL(nValueRet, 2 * COIN); BOOST_CHECK_EQUAL(setCoinsRet.size(), 1U); // empty the wallet and start again, now with fractions of a cent, to // test small change avoidance empty_wallet(); add_coin(wallet, 1 * MIN_CHANGE / 10); add_coin(wallet, 2 * MIN_CHANGE / 10); add_coin(wallet, 3 * MIN_CHANGE / 10); add_coin(wallet, 4 * MIN_CHANGE / 10); add_coin(wallet, 5 * MIN_CHANGE / 10); // try making 1 * MIN_CHANGE from the 1.5 * MIN_CHANGE we'll get change // smaller than MIN_CHANGE whatever happens, so can expect MIN_CHANGE // exactly BOOST_CHECK(wallet.SelectCoinsMinConf(MIN_CHANGE, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, MIN_CHANGE); // but if we add a bigger coin, small change is avoided add_coin(wallet, 1111 * MIN_CHANGE); // try making 1 from 0.1 + 0.2 + 0.3 + 0.4 + 0.5 + 1111 = 1112.5 BOOST_CHECK(wallet.SelectCoinsMinConf(1 * MIN_CHANGE, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get the exact amount BOOST_CHECK_EQUAL(nValueRet, 1 * MIN_CHANGE); // if we add more small coins: add_coin(wallet, 6 * MIN_CHANGE / 10); add_coin(wallet, 7 * MIN_CHANGE / 10); // and try again to make 1.0 * MIN_CHANGE BOOST_CHECK(wallet.SelectCoinsMinConf(1 * MIN_CHANGE, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get the exact amount BOOST_CHECK_EQUAL(nValueRet, 1 * MIN_CHANGE); // run the 'mtgox' test (see // http://blockexplorer.com/tx/29a3efd3ef04f9153d47a990bd7b048a4b2d213daaa5fb8ed670fb85f13bdbcf) // they tried to consolidate 10 50k coins into one 500k coin, and ended // up with 50k in change empty_wallet(); for (int j = 0; j < 20; j++) { add_coin(wallet, 50000 * COIN); } BOOST_CHECK(wallet.SelectCoinsMinConf(500000 * COIN, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get the exact amount BOOST_CHECK_EQUAL(nValueRet, 500000 * COIN); // in ten coins BOOST_CHECK_EQUAL(setCoinsRet.size(), 10U); // if there's not enough in the smaller coins to make at least 1 * // MIN_CHANGE change (0.5+0.6+0.7 < 1.0+1.0), we need to try finding an // exact subset anyway // sometimes it will fail, and so we use the next biggest coin: empty_wallet(); add_coin(wallet, 5 * MIN_CHANGE / 10); add_coin(wallet, 6 * MIN_CHANGE / 10); add_coin(wallet, 7 * MIN_CHANGE / 10); add_coin(wallet, 1111 * MIN_CHANGE); BOOST_CHECK(wallet.SelectCoinsMinConf(1 * MIN_CHANGE, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we get the bigger coin BOOST_CHECK_EQUAL(nValueRet, 1111 * MIN_CHANGE); BOOST_CHECK_EQUAL(setCoinsRet.size(), 1U); // but sometimes it's possible, and we use an exact subset (0.4 + 0.6 = // 1.0) empty_wallet(); add_coin(wallet, 4 * MIN_CHANGE / 10); add_coin(wallet, 6 * MIN_CHANGE / 10); add_coin(wallet, 8 * MIN_CHANGE / 10); add_coin(wallet, 1111 * MIN_CHANGE); BOOST_CHECK(wallet.SelectCoinsMinConf(MIN_CHANGE, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get the exact amount BOOST_CHECK_EQUAL(nValueRet, MIN_CHANGE); // in two coins 0.4+0.6 BOOST_CHECK_EQUAL(setCoinsRet.size(), 2U); // test avoiding small change empty_wallet(); add_coin(wallet, 5 * MIN_CHANGE / 100); add_coin(wallet, 1 * MIN_CHANGE); add_coin(wallet, 100 * MIN_CHANGE); // trying to make 100.01 from these three coins BOOST_CHECK(wallet.SelectCoinsMinConf(10001 * MIN_CHANGE / 100, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); // we should get all coins BOOST_CHECK_EQUAL(nValueRet, 10105 * MIN_CHANGE / 100); BOOST_CHECK_EQUAL(setCoinsRet.size(), 3U); // but if we try to make 99.9, we should take the bigger of the two // small coins to avoid small change BOOST_CHECK(wallet.SelectCoinsMinConf(9990 * MIN_CHANGE / 100, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 101 * MIN_CHANGE); BOOST_CHECK_EQUAL(setCoinsRet.size(), 2U); // test with many inputs for (Amount amt = 1500 * SATOSHI; amt < COIN; amt = 10 * amt) { empty_wallet(); // Create 676 inputs (= (old MAX_STANDARD_TX_SIZE == 100000) / 148 // bytes per input) for (uint16_t j = 0; j < 676; j++) { add_coin(wallet, amt); } BOOST_CHECK(wallet.SelectCoinsMinConf( 2000 * SATOSHI, 1, 1, 0, vCoins, setCoinsRet, nValueRet)); if (amt - 2000 * SATOSHI < MIN_CHANGE) { // needs more than one input: uint16_t returnSize = std::ceil( double(2000 + (MIN_CHANGE / SATOSHI)) / (amt / SATOSHI)); Amount returnValue = returnSize * amt; BOOST_CHECK_EQUAL(nValueRet, returnValue); BOOST_CHECK_EQUAL(setCoinsRet.size(), returnSize); } else { // one input is sufficient: BOOST_CHECK_EQUAL(nValueRet, amt); BOOST_CHECK_EQUAL(setCoinsRet.size(), 1U); } } // test randomness { empty_wallet(); for (int i2 = 0; i2 < 100; i2++) { add_coin(wallet, COIN); } // picking 50 from 100 coins doesn't depend on the shuffle, but does // depend on randomness in the stochastic approximation code BOOST_CHECK(wallet.SelectCoinsMinConf(50 * COIN, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK(wallet.SelectCoinsMinConf(50 * COIN, 1, 6, 0, vCoins, setCoinsRet2, nValueRet)); BOOST_CHECK(!equal_sets(setCoinsRet, setCoinsRet2)); int fails = 0; for (int j = 0; j < RANDOM_REPEATS; j++) { // selecting 1 from 100 identical coins depends on the shuffle; // this test will fail 1% of the time run the test // RANDOM_REPEATS times and only complain if all of them fail BOOST_CHECK(wallet.SelectCoinsMinConf(COIN, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK(wallet.SelectCoinsMinConf(COIN, 1, 6, 0, vCoins, setCoinsRet2, nValueRet)); if (equal_sets(setCoinsRet, setCoinsRet2)) { fails++; } } BOOST_CHECK_NE(fails, RANDOM_REPEATS); // add 75 cents in small change. not enough to make 90 cents, then // try making 90 cents. there are multiple competing "smallest // bigger" coins, one of which should be picked at random add_coin(wallet, 5 * CENT); add_coin(wallet, 10 * CENT); add_coin(wallet, 15 * CENT); add_coin(wallet, 20 * CENT); add_coin(wallet, 25 * CENT); fails = 0; for (int j = 0; j < RANDOM_REPEATS; j++) { // selecting 1 from 100 identical coins depends on the shuffle; // this test will fail 1% of the time run the test // RANDOM_REPEATS times and only complain if all of them fail BOOST_CHECK(wallet.SelectCoinsMinConf( 90 * CENT, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK(wallet.SelectCoinsMinConf( 90 * CENT, 1, 6, 0, vCoins, setCoinsRet2, nValueRet)); if (equal_sets(setCoinsRet, setCoinsRet2)) { fails++; } } BOOST_CHECK_NE(fails, RANDOM_REPEATS); } } empty_wallet(); } BOOST_AUTO_TEST_CASE(ApproximateBestSubset) { CoinSet setCoinsRet; Amount nValueRet; const CWallet wallet(Params()); LOCK(walletCriticalSection); empty_wallet(); // Test vValue sort order for (int i = 0; i < 1000; i++) { add_coin(wallet, 1000 * COIN); } add_coin(wallet, 3 * COIN); BOOST_CHECK(wallet.SelectCoinsMinConf(1003 * COIN, 1, 6, 0, vCoins, setCoinsRet, nValueRet)); BOOST_CHECK_EQUAL(nValueRet, 1003 * COIN); BOOST_CHECK_EQUAL(setCoinsRet.size(), 2U); empty_wallet(); } static void AddKey(CWallet &wallet, const CKey &key) { LOCK(wallet.cs_wallet); wallet.AddKeyPubKey(key, key.GetPubKey()); } BOOST_FIXTURE_TEST_CASE(rescan, TestChain100Setup) { // Cap last block file size, and mine new block in a new block file. CBlockIndex *const nullBlock = nullptr; CBlockIndex *oldTip = chainActive.Tip(); GetBlockFileInfo(oldTip->GetBlockPos().nFile)->nSize = MAX_BLOCKFILE_SIZE; CreateAndProcessBlock({}, GetScriptForRawPubKey(coinbaseKey.GetPubKey())); CBlockIndex *newTip = chainActive.Tip(); LOCK(cs_main); // Verify ScanForWalletTransactions picks up transactions in both the old // and new block files. { CWallet wallet(Params()); AddKey(wallet, coinbaseKey); BOOST_CHECK_EQUAL(nullBlock, wallet.ScanForWalletTransactions(oldTip, nullptr)); BOOST_CHECK_EQUAL(wallet.GetImmatureBalance(), 100 * COIN); } // Prune the older block file. PruneOneBlockFile(oldTip->GetBlockPos().nFile); UnlinkPrunedFiles({oldTip->GetBlockPos().nFile}); // Verify ScanForWalletTransactions only picks transactions in the new block // file. { CWallet wallet(Params()); AddKey(wallet, coinbaseKey); BOOST_CHECK_EQUAL(oldTip, wallet.ScanForWalletTransactions(oldTip, nullptr)); BOOST_CHECK_EQUAL(wallet.GetImmatureBalance(), 50 * COIN); } // Verify importmulti RPC returns failure for a key whose creation time is // before the missing block, and success for a key whose creation time is // after. { CWallet wallet(Params()); vpwallets.insert(vpwallets.begin(), &wallet); UniValue keys; keys.setArray(); UniValue key; key.setObject(); key.pushKV("scriptPubKey", HexStr(GetScriptForRawPubKey(coinbaseKey.GetPubKey()))); key.pushKV("timestamp", 0); key.pushKV("internal", UniValue(true)); keys.push_back(key); key.clear(); key.setObject(); CKey futureKey; futureKey.MakeNewKey(true); key.pushKV("scriptPubKey", HexStr(GetScriptForRawPubKey(futureKey.GetPubKey()))); key.pushKV("timestamp", newTip->GetBlockTimeMax() + TIMESTAMP_WINDOW + 1); key.pushKV("internal", UniValue(true)); keys.push_back(key); JSONRPCRequest request; request.params.setArray(); request.params.push_back(keys); UniValue response = importmulti(GetConfig(), request); BOOST_CHECK_EQUAL( response.write(), strprintf("[{\"success\":false,\"error\":{\"code\":-1,\"message\":" "\"Rescan failed for key with creation timestamp %d. " "There was an error reading a block from time %d, which " "is after or within %d seconds of key creation, and " "could contain transactions pertaining to the key. As a " "result, transactions and coins using this key may not " "appear in the wallet. This error could be caused by " "pruning or data corruption (see bitcoind log for " "details) and could be dealt with by downloading and " "rescanning the relevant blocks (see -reindex and " "-rescan options).\"}},{\"success\":true}]", 0, oldTip->GetBlockTimeMax(), TIMESTAMP_WINDOW)); vpwallets.erase(vpwallets.begin()); } } // Verify importwallet RPC starts rescan at earliest block with timestamp // greater or equal than key birthday. Previously there was a bug where // importwallet RPC would start the scan at the latest block with timestamp less // than or equal to key birthday. BOOST_FIXTURE_TEST_CASE(importwallet_rescan, TestChain100Setup) { // Create two blocks with same timestamp to verify that importwallet rescan // will pick up both blocks, not just the first. const int64_t BLOCK_TIME = chainActive.Tip()->GetBlockTimeMax() + 5; SetMockTime(BLOCK_TIME); coinbaseTxns.emplace_back( *CreateAndProcessBlock({}, GetScriptForRawPubKey(coinbaseKey.GetPubKey())) .vtx[0]); coinbaseTxns.emplace_back( *CreateAndProcessBlock({}, GetScriptForRawPubKey(coinbaseKey.GetPubKey())) .vtx[0]); // Set key birthday to block time increased by the timestamp window, so // rescan will start at the block time. const int64_t KEY_TIME = BLOCK_TIME + TIMESTAMP_WINDOW; SetMockTime(KEY_TIME); coinbaseTxns.emplace_back( *CreateAndProcessBlock({}, GetScriptForRawPubKey(coinbaseKey.GetPubKey())) .vtx[0]); LOCK(cs_main); // Import key into wallet and call dumpwallet to create backup file. { CWallet wallet(Params()); LOCK(wallet.cs_wallet); wallet.mapKeyMetadata[coinbaseKey.GetPubKey().GetID()].nCreateTime = KEY_TIME; wallet.AddKeyPubKey(coinbaseKey, coinbaseKey.GetPubKey()); JSONRPCRequest request; request.params.setArray(); request.params.push_back((pathTemp / "wallet.backup").string()); vpwallets.insert(vpwallets.begin(), &wallet); ::dumpwallet(GetConfig(), request); } // Call importwallet RPC and verify all blocks with timestamps >= BLOCK_TIME // were scanned, and no prior blocks were scanned. { CWallet wallet(Params()); JSONRPCRequest request; request.params.setArray(); request.params.push_back((pathTemp / "wallet.backup").string()); vpwallets[0] = &wallet; ::importwallet(GetConfig(), request); LOCK(wallet.cs_wallet); BOOST_CHECK_EQUAL(wallet.mapWallet.size(), 3); BOOST_CHECK_EQUAL(coinbaseTxns.size(), 103); for (size_t i = 0; i < coinbaseTxns.size(); ++i) { bool found = wallet.GetWalletTx(coinbaseTxns[i].GetId()); bool expected = i >= 100; BOOST_CHECK_EQUAL(found, expected); } } SetMockTime(0); vpwallets.erase(vpwallets.begin()); } // Check that GetImmatureCredit() returns a newly calculated value instead of // the cached value after a MarkDirty() call. // // This is a regression test written to verify a bugfix for the immature credit // function. Similar tests probably should be written for the other credit and // debit functions. BOOST_FIXTURE_TEST_CASE(coin_mark_dirty_immature_credit, TestChain100Setup) { CWallet wallet(Params()); CWalletTx wtx(&wallet, MakeTransactionRef(coinbaseTxns.back())); LOCK2(cs_main, wallet.cs_wallet); wtx.hashBlock = chainActive.Tip()->GetBlockHash(); wtx.nIndex = 0; // Call GetImmatureCredit() once before adding the key to the wallet to // cache the current immature credit amount, which is 0. BOOST_CHECK_EQUAL(wtx.GetImmatureCredit(), Amount::zero()); // Invalidate the cached value, add the key, and make sure a new immature // credit amount is calculated. wtx.MarkDirty(); wallet.AddKeyPubKey(coinbaseKey, coinbaseKey.GetPubKey()); BOOST_CHECK_EQUAL(wtx.GetImmatureCredit(), 50 * COIN); } static int64_t AddTx(CWallet &wallet, uint32_t lockTime, int64_t mockTime, int64_t blockTime) { CMutableTransaction tx; tx.nLockTime = lockTime; SetMockTime(mockTime); CBlockIndex *block = nullptr; if (blockTime > 0) { LOCK(cs_main); auto inserted = mapBlockIndex.emplace(GetRandHash(), new CBlockIndex); assert(inserted.second); const uint256 &hash = inserted.first->first; block = inserted.first->second; block->nTime = blockTime; block->phashBlock = &hash; } CWalletTx wtx(&wallet, MakeTransactionRef(tx)); if (block) { wtx.SetMerkleBranch(block, 0); } wallet.AddToWallet(wtx); LOCK(wallet.cs_wallet); return wallet.mapWallet.at(wtx.GetId()).nTimeSmart; } // Simple test to verify assignment of CWalletTx::nSmartTime value. Could be // expanded to cover more corner cases of smart time logic. BOOST_AUTO_TEST_CASE(ComputeTimeSmart) { CWallet wallet(Params()); // New transaction should use clock time if lower than block time. BOOST_CHECK_EQUAL(AddTx(wallet, 1, 100, 120), 100); // Test that updating existing transaction does not change smart time. BOOST_CHECK_EQUAL(AddTx(wallet, 1, 200, 220), 100); // New transaction should use clock time if there's no block time. BOOST_CHECK_EQUAL(AddTx(wallet, 2, 300, 0), 300); // New transaction should use block time if lower than clock time. BOOST_CHECK_EQUAL(AddTx(wallet, 3, 420, 400), 400); // New transaction should use latest entry time if higher than // min(block time, clock time). BOOST_CHECK_EQUAL(AddTx(wallet, 4, 500, 390), 400); // If there are future entries, new transaction should use time of the // newest entry that is no more than 300 seconds ahead of the clock time. BOOST_CHECK_EQUAL(AddTx(wallet, 5, 50, 600), 300); // Reset mock time for other tests. SetMockTime(0); } BOOST_AUTO_TEST_CASE(LoadReceiveRequests) { CTxDestination dest = CKeyID(); LOCK(pwalletMain->cs_wallet); pwalletMain->AddDestData(dest, "misc", "val_misc"); pwalletMain->AddDestData(dest, "rr0", "val_rr0"); pwalletMain->AddDestData(dest, "rr1", "val_rr1"); auto values = pwalletMain->GetDestValues("rr"); BOOST_CHECK_EQUAL(values.size(), 2); BOOST_CHECK_EQUAL(values[0], "val_rr0"); BOOST_CHECK_EQUAL(values[1], "val_rr1"); } class ListCoinsTestingSetup : public TestChain100Setup { public: ListCoinsTestingSetup() { CreateAndProcessBlock({}, GetScriptForRawPubKey(coinbaseKey.GetPubKey())); ::bitdb.MakeMock(); wallet.reset(new CWallet( Params(), std::unique_ptr( new CWalletDBWrapper(&bitdb, "wallet_test.dat")))); bool firstRun; wallet->LoadWallet(firstRun); AddKey(*wallet, coinbaseKey); wallet->ScanForWalletTransactions(chainActive.Genesis(), nullptr); } ~ListCoinsTestingSetup() { wallet.reset(); ::bitdb.Flush(true); ::bitdb.Reset(); } CWalletTx &AddTx(CRecipient recipient) { CTransactionRef tx; CReserveKey reservekey(wallet.get()); Amount fee; int changePos = -1; std::string error; CCoinControl dummy; BOOST_CHECK(wallet->CreateTransaction({recipient}, tx, reservekey, fee, changePos, error, dummy)); CValidationState state; BOOST_CHECK(wallet->CommitTransaction(tx, {}, {}, {}, reservekey, nullptr, state)); CMutableTransaction blocktx; { LOCK(wallet->cs_wallet); blocktx = CMutableTransaction(*wallet->mapWallet.at(tx->GetId()).tx); } CreateAndProcessBlock({CMutableTransaction(blocktx)}, GetScriptForRawPubKey(coinbaseKey.GetPubKey())); LOCK(wallet->cs_wallet); auto it = wallet->mapWallet.find(tx->GetId()); BOOST_CHECK(it != wallet->mapWallet.end()); it->second.SetMerkleBranch(chainActive.Tip(), 1); return it->second; } std::unique_ptr wallet; }; BOOST_FIXTURE_TEST_CASE(ListCoins, ListCoinsTestingSetup) { std::string coinbaseAddress = coinbaseKey.GetPubKey().GetID().ToString(); // Confirm ListCoins initially returns 1 coin grouped under coinbaseKey // address. auto list = wallet->ListCoins(); BOOST_CHECK_EQUAL(list.size(), 1); BOOST_CHECK_EQUAL(boost::get(list.begin()->first).ToString(), coinbaseAddress); BOOST_CHECK_EQUAL(list.begin()->second.size(), 1); // Check initial balance from one mature coinbase transaction. BOOST_CHECK_EQUAL(50 * COIN, wallet->GetAvailableBalance()); // Add a transaction creating a change address, and confirm ListCoins still // returns the coin associated with the change address underneath the // coinbaseKey pubkey, even though the change address has a different // pubkey. AddTx(CRecipient{GetScriptForRawPubKey({}), 1 * COIN, false /* subtract fee */}); list = wallet->ListCoins(); BOOST_CHECK_EQUAL(list.size(), 1); BOOST_CHECK_EQUAL(boost::get(list.begin()->first).ToString(), coinbaseAddress); BOOST_CHECK_EQUAL(list.begin()->second.size(), 2); // Lock both coins. Confirm number of available coins drops to 0. std::vector available; wallet->AvailableCoins(available); BOOST_CHECK_EQUAL(available.size(), 2); for (const auto &group : list) { for (const auto &coin : group.second) { LOCK(wallet->cs_wallet); wallet->LockCoin(COutPoint(coin.tx->GetId(), coin.i)); } } wallet->AvailableCoins(available); BOOST_CHECK_EQUAL(available.size(), 0); // Confirm ListCoins still returns same result as before, despite coins // being locked. list = wallet->ListCoins(); BOOST_CHECK_EQUAL(list.size(), 1); BOOST_CHECK_EQUAL(boost::get(list.begin()->first).ToString(), coinbaseAddress); BOOST_CHECK_EQUAL(list.begin()->second.size(), 2); } BOOST_AUTO_TEST_SUITE_END() diff --git a/src/wallet/test/walletdb_tests.cpp b/src/wallet/test/walletdb_tests.cpp index ccb8fcd2c..97fdc271c 100644 --- a/src/wallet/test/walletdb_tests.cpp +++ b/src/wallet/test/walletdb_tests.cpp @@ -1,143 +1,144 @@ // Copyright (c) 2017 The Bitcoin developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. -#include "chainparams.h" -#include "test/test_bitcoin.h" +#include -#include "wallet/wallet.h" -#include "wallet/walletdb.h" +#include +#include + +#include #include namespace { struct WalletDBTestingSetup : public TestingSetup { WalletDBTestingSetup( const std::string &chainName = CBaseChainParams::MAIN) { bitdb.MakeMock(); } ~WalletDBTestingSetup() { bitdb.Flush(true); bitdb.Reset(); } }; static std::unique_ptr TmpDB(const fs::path &pathTemp, const std::string &testname) { fs::path dir = pathTemp / testname; BOOST_CHECK_MESSAGE(fs::create_directory(dir), "Unable to create a directory for test " + testname); fs::path path = dir / strprintf("testwallet%i", static_cast(GetRand(1000000))); return std::unique_ptr( new CWalletDBWrapper(&bitdb, path.string())); } static std::unique_ptr LoadWallet(CWalletDB *db) { std::unique_ptr wallet(new CWallet(Params())); DBErrors res = db->LoadWallet(wallet.get()); BOOST_CHECK(res == DBErrors::LOAD_OK); return wallet; } } // namespace BOOST_FIXTURE_TEST_SUITE(walletdb_tests, WalletDBTestingSetup) BOOST_AUTO_TEST_CASE(write_erase_name) { auto walletdbwrapper = TmpDB(pathTemp, "write_erase_name"); CWalletDB walletdb(*walletdbwrapper, "cr+"); CTxDestination dst1 = CKeyID(uint160S("c0ffee")); CTxDestination dst2 = CKeyID(uint160S("f00d")); BOOST_CHECK(walletdb.WriteName(dst1, "name1")); BOOST_CHECK(walletdb.WriteName(dst2, "name2")); { auto w = LoadWallet(&walletdb); BOOST_CHECK_EQUAL(1, w->mapAddressBook.count(dst1)); BOOST_CHECK_EQUAL("name1", w->mapAddressBook[dst1].name); BOOST_CHECK_EQUAL("name2", w->mapAddressBook[dst2].name); } walletdb.EraseName(dst1); { auto w = LoadWallet(&walletdb); BOOST_CHECK_EQUAL(0, w->mapAddressBook.count(dst1)); BOOST_CHECK_EQUAL(1, w->mapAddressBook.count(dst2)); } } BOOST_AUTO_TEST_CASE(write_erase_purpose) { auto walletdbwrapper = TmpDB(pathTemp, "write_erase_purpose"); CWalletDB walletdb(*walletdbwrapper, "cr+"); CTxDestination dst1 = CKeyID(uint160S("c0ffee")); CTxDestination dst2 = CKeyID(uint160S("f00d")); BOOST_CHECK(walletdb.WritePurpose(dst1, "purpose1")); BOOST_CHECK(walletdb.WritePurpose(dst2, "purpose2")); { auto w = LoadWallet(&walletdb); BOOST_CHECK_EQUAL(1, w->mapAddressBook.count(dst1)); BOOST_CHECK_EQUAL("purpose1", w->mapAddressBook[dst1].purpose); BOOST_CHECK_EQUAL("purpose2", w->mapAddressBook[dst2].purpose); } walletdb.ErasePurpose(dst1); { auto w = LoadWallet(&walletdb); BOOST_CHECK_EQUAL(0, w->mapAddressBook.count(dst1)); BOOST_CHECK_EQUAL(1, w->mapAddressBook.count(dst2)); } } BOOST_AUTO_TEST_CASE(write_erase_destdata) { auto walletdbwrapper = TmpDB(pathTemp, "write_erase_destdata"); CWalletDB walletdb(*walletdbwrapper, "cr+"); CTxDestination dst1 = CKeyID(uint160S("c0ffee")); CTxDestination dst2 = CKeyID(uint160S("f00d")); BOOST_CHECK(walletdb.WriteDestData(dst1, "key1", "value1")); BOOST_CHECK(walletdb.WriteDestData(dst1, "key2", "value2")); BOOST_CHECK(walletdb.WriteDestData(dst2, "key1", "value3")); BOOST_CHECK(walletdb.WriteDestData(dst2, "key2", "value4")); { auto w = LoadWallet(&walletdb); std::string val; BOOST_CHECK(w->GetDestData(dst1, "key1", &val)); BOOST_CHECK_EQUAL("value1", val); BOOST_CHECK(w->GetDestData(dst1, "key2", &val)); BOOST_CHECK_EQUAL("value2", val); BOOST_CHECK(w->GetDestData(dst2, "key1", &val)); BOOST_CHECK_EQUAL("value3", val); BOOST_CHECK(w->GetDestData(dst2, "key2", &val)); BOOST_CHECK_EQUAL("value4", val); } walletdb.EraseDestData(dst1, "key2"); { auto w = LoadWallet(&walletdb); std::string dummy; BOOST_CHECK(w->GetDestData(dst1, "key1", &dummy)); BOOST_CHECK(!w->GetDestData(dst1, "key2", &dummy)); BOOST_CHECK(w->GetDestData(dst2, "key1", &dummy)); BOOST_CHECK(w->GetDestData(dst2, "key2", &dummy)); } } BOOST_AUTO_TEST_CASE(no_dest_fails) { auto walletdbwrapper = TmpDB(pathTemp, "no_dest_fails"); CWalletDB walletdb(*walletdbwrapper, "cr+"); CTxDestination dst = CNoDestination{}; BOOST_CHECK(!walletdb.WriteName(dst, "name")); BOOST_CHECK(!walletdb.WritePurpose(dst, "purpose")); BOOST_CHECK(!walletdb.WriteDestData(dst, "key", "value")); } BOOST_AUTO_TEST_SUITE_END()