public void TestSimpleSpend()
{
using (var daemon = new TestDaemon())
{
// create a new keypair to spend to
var toKeyPair = daemon.TxManager.CreateKeyPair();
var toPrivateKey = toKeyPair.Item1;
var toPublicKey = toKeyPair.Item2;
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock(daemon.GenesisBlock);
var block2 = daemon.MineAndAddEmptyBlock(block1);
// check
daemon.WaitForUpdate();
AssertMethods.AssertDaemonAtBlock(2, block2.Hash, daemon.CoreDaemon);
// attempt to spend block 2's coinbase in block 3
var spendTx = daemon.TxManager.CreateSpendTransaction(block2.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, 50 * SATOSHI_PER_BTC, daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKey);
var block3Unmined = daemon.CreateEmptyBlock(block2)
.WithAddedTransactions(spendTx);
var block3 = daemon.MineAndAddBlock(block3Unmined);
// check
daemon.WaitForUpdate();
AssertMethods.AssertDaemonAtBlock(3, block3.Hash, daemon.CoreDaemon);
// add a simple block
var block4 = daemon.MineAndAddEmptyBlock(block3);
// check
daemon.WaitForUpdate();
AssertMethods.AssertDaemonAtBlock(4, block4.Hash, daemon.CoreDaemon);
}
}
public void TestShorterChainWins()
{
using (var daemon = new TestDaemon())
{
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock();
var block2 = daemon.MineAndAddEmptyBlock();
var block3a = daemon.MineAndAddEmptyBlock();
var block4a = daemon.MineAndAddEmptyBlock();
var block5a = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(5, block5a.Hash);
// create a split with 3b, but do more work than current height 5 chain
var testBlocksFork = daemon.TestBlocks.Fork(3);
daemon.ChainParams.HighestTarget = UnitTestParams.Target2;
var block3b = daemon.AddBlock(testBlocksFork.MineAndAddEmptyBlock(UnitTestParams.Target2));
// check that blockchain reorganized to shorter chain
daemon.WaitForUpdate();
daemon.AssertAtBlock(3, block3b.Hash);
}
}
public void TestInsufficientBalance()
{
using (var daemon = new TestDaemon())
{
// create a new keypair to spend to
var toKeyPair = daemon.TxManager.CreateKeyPair();
var toPrivateKey = toKeyPair.Item1;
var toPublicKey = toKeyPair.Item2;
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock(daemon.GenesisBlock);
var block2 = daemon.MineAndAddEmptyBlock(block1);
// check
daemon.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(2, block2.Hash, daemon.BlockchainDaemon);
// attempt to spend block 2's coinbase in block 3, using twice its value
var spendTx = daemon.TxManager.CreateSpendTransaction(block2.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, 100 * SATOSHI_PER_BTC, daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKey);
var block3BadUnmined = daemon.CreateEmptyBlock(block2)
.WithAddedTransactions(spendTx);
var block3Bad = daemon.MineAndAddBlock(block3BadUnmined);
// check that bad block wasn't added
daemon.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(2, block2.Hash, daemon.BlockchainDaemon);
// add a simple block
var block3Good = daemon.MineAndAddEmptyBlock(block2);
// check
daemon.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(3, block3Good.Hash, daemon.BlockchainDaemon);
}
}
public void TestDoubleSpend()
{
using (var daemon = new TestDaemon())
{
// create a new keypair to spend to
var toKeyPair = daemon.TxManager.CreateKeyPair();
var toPrivateKey = toKeyPair.Item1;
var toPublicKey = toKeyPair.Item2;
// create a new keypair to double spend to
var toKeyPairBad = daemon.TxManager.CreateKeyPair();
var toPrivateKeyBad = toKeyPair.Item1;
var toPublicKeyBad = toKeyPair.Item2;
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock();
var block2 = daemon.MineAndAddEmptyBlock();
// add some blocks so coinbase is mature to spend
Block lastBlock = null;
for (var i = 0; i < 100; i++)
{
lastBlock = daemon.MineAndAddEmptyBlock();
}
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(102, lastBlock.Hash);
// spend block 2's coinbase in block 3
var spendTx = daemon.TxManager.CreateSpendTransaction(block2.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, 50 * SATOSHI_PER_BTC, daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKey);
var block3Unmined = daemon.CreateEmptyBlock(lastBlock.Hash)
.CreateWithAddedTransactions(spendTx);
var block3 = daemon.MineAndAddBlock(block3Unmined);
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(103, block3.Hash);
// attempt to spend block 2's coinbase again in block 4
var doubleSpendTx = daemon.TxManager.CreateSpendTransaction(block2.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, 50 * SATOSHI_PER_BTC, daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKeyBad);
var block4BadUmined = daemon.CreateEmptyBlock(block3.Hash)
.CreateWithAddedTransactions(doubleSpendTx);
var block4Bad = daemon.MineAndAddBlock(block4BadUmined);
// check that bad block wasn't added
daemon.WaitForUpdate();
daemon.AssertAtBlock(103, block3.Hash);
// add a simple block
daemon.TestBlocks.Rollback(1);
var block4Good = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(104, block4Good.Hash);
}
}
public void TestAddSingleBlock()
{
using (var daemon = new TestDaemon())
{
var block1 = daemon.MineAndAddEmptyBlock(daemon.GenesisBlock);
daemon.WaitForUpdate();
AssertMethods.AssertDaemonAtBlock(1, block1.Hash, daemon.CoreDaemon);
}
}
public void TestAddSingleBlock()
{
using (var daemon = new TestDaemon())
{
var block1 = daemon.MineAndAddEmptyBlock();
daemon.WaitForUpdate();
daemon.AssertAtBlock(1, block1.Hash);
}
}
public void TestAddSingleBlock()
{
using (var daemon = new TestDaemon())
{
var block1 = daemon.MineAndAddEmptyBlock();
daemon.WaitForUpdate();
daemon.AssertAtBlock(1, block1.Hash);
}
}
public void TestDoubleSpend()
{
using (var daemon = new TestDaemon())
{
// create a new keypair to spend to
var toKeyPair = daemon.TxManager.CreateKeyPair();
var toPrivateKey = toKeyPair.Item1;
var toPublicKey = toKeyPair.Item2;
// create a new keypair to double spend to
var toKeyPairBad = daemon.TxManager.CreateKeyPair();
var toPrivateKeyBad = toKeyPair.Item1;
var toPublicKeyBad = toKeyPair.Item2;
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock();
var block2 = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(2, block2.Hash);
// spend block 2's coinbase in block 3
var spendTx = daemon.TxManager.CreateSpendTransaction(block2.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, 50 * SATOSHI_PER_BTC, daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKey);
var block3Unmined = daemon.CreateEmptyBlock(block2.Hash)
.WithAddedTransactions(spendTx);
var block3 = daemon.MineAndAddBlock(block3Unmined);
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(3, block3.Hash);
// attempt to spend block 2's coinbase again in block 4
var doubleSpendTx = daemon.TxManager.CreateSpendTransaction(block2.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, 50 * SATOSHI_PER_BTC, daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKeyBad);
var block4BadUmined = daemon.CreateEmptyBlock(block3.Hash)
.WithAddedTransactions(doubleSpendTx);
var block4Bad = daemon.MineAndAddBlock(block4BadUmined);
// check that bad block wasn't added
daemon.WaitForUpdate();
daemon.AssertAtBlock(3, block3.Hash);
// add a simple block
daemon.TestBlocks.Rollback(1);
var block4Good = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(4, block4Good.Hash);
}
}
public void TestLongBlockchain()
{
using (var daemon = new TestDaemon())
{
var count = 1.THOUSAND();
var height = 0;
var block = daemon.GenesisBlock;
for (var i = 0; i < count; i++)
{
height++;
block = daemon.MineAndAddEmptyBlock();
}
daemon.WaitForUpdate();
daemon.AssertAtBlock(height, block.Hash);
}
}
public void TestLongBlockchain()
{
using (var daemon = new TestDaemon())
{
var count = 1.THOUSAND();
var height = 0;
var block = daemon.GenesisBlock;
for (var i = 0; i < count; i++)
{
height++;
block = daemon.MineAndAddEmptyBlock();
}
daemon.WaitForUpdate();
daemon.AssertAtBlock(height, block.Hash);
}
}
public void TestSimpleSpend()
{
using (var daemon = new TestDaemon())
{
// create a new keypair to spend to
var toKeyPair = daemon.TxManager.CreateKeyPair();
var toPrivateKey = toKeyPair.Item1;
var toPublicKey = toKeyPair.Item2;
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock();
var block2 = daemon.MineAndAddEmptyBlock();
// add some blocks so coinbase is mature to spend
Block lastBlock = null;
for (var i = 0; i < 100; i++)
lastBlock = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(102, lastBlock.Hash);
// attempt to spend block 2's coinbase in block 3
var spendTx = daemon.TxManager.CreateSpendTransaction(block2.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, 50 * SATOSHI_PER_BTC, daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKey);
var block3Unmined = daemon.CreateEmptyBlock(lastBlock.Hash)
.CreateWithAddedTransactions(spendTx);
var block3 = daemon.MineAndAddBlock(block3Unmined);
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(103, block3.Hash);
// add a simple block
var block4 = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(104, block4.Hash);
}
}
public void TestLongBlockchain()
{
if (Debugger.IsAttached)
{
Assert.Inconclusive();
}
using (var daemon = new TestDaemon())
{
var count = 1.THOUSAND();
var height = 0;
var block = daemon.GenesisBlock;
for (var i = 0; i < count; i++)
{
Debug.WriteLine("TestLongBlockchain mining block {0:#,##0}".Format2(i));
height++;
block = daemon.MineAndAddEmptyBlock(block);
}
daemon.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(height, block.Hash, daemon.BlockchainDaemon);
}
}
public void TestShorterChainWins()
{
using (var daemon = new TestDaemon())
{
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock(daemon.GenesisBlock);
var block2 = daemon.MineAndAddEmptyBlock(block1);
var block3a = daemon.MineAndAddEmptyBlock(block2);
var block4a = daemon.MineAndAddEmptyBlock(block3a);
var block5a = daemon.MineAndAddEmptyBlock(block4a);
// check
daemon.WaitForUpdate();
AssertMethods.AssertDaemonAtBlock(5, block5a.Hash, daemon.CoreDaemon);
// create a split with 3b, but do more work than current height 5 chain
daemon.Rules.SetHighestTarget(UnitTestRules.Target2);
var block3b = daemon.MineAndAddEmptyBlock(block2, UnitTestRules.Target2);
// check that blockchain reorganized to shorter chain
daemon.WaitForUpdate();
AssertMethods.AssertDaemonAtBlock(3, block3b.Hash, daemon.CoreDaemon);
}
}
public void TestSimpleBlockchainSplit()
{
using (var daemon1 = new TestDaemon())
{
// add some simple blocks
var block1 = daemon1.MineAndAddEmptyBlock();
var block2 = daemon1.MineAndAddEmptyBlock();
var block3a = daemon1.MineAndAddEmptyBlock();
daemon1.WaitForUpdate();
// create a fork test block chain, starting at block2
var testBlocksFork = daemon1.TestBlocks.Fork(1);
// wait for daemon
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(3, block3a.Hash);
// introduce a tie split
var block3b = daemon1.AddBlock(testBlocksFork.MineAndAddEmptyBlock());
// check that 3a is still current as it was first
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(3, block3a.Hash);
// continue with currently winning branch
var block4a = daemon1.MineAndAddEmptyBlock();
// wait for daemon
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(4, block4a.Hash);
// continue with tied branch
var block4b = daemon1.AddBlock(testBlocksFork.MineAndAddEmptyBlock());
// check that 4a is still current as it was first
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(4, block4a.Hash);
// resolve tie split, with other chain winning
var block5b = daemon1.AddBlock(testBlocksFork.MineAndAddEmptyBlock());
// check that blockchain reorged to the winning chain
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(5, block5b.Hash);
// continue on winning fork
var block6b = daemon1.AddBlock(testBlocksFork.MineAndAddEmptyBlock());
// check that blockchain continued on the winning chain
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(6, block6b.Hash);
// create a second blockchain, reusing the genesis from the first
using (var daemon2 = new TestDaemon(daemon1.GenesisBlock))
{
// add only the winning blocks to the second blockchain
daemon2.AddBlock(block1);
daemon2.AddBlock(block2);
daemon2.AddBlock(block3b);
daemon2.AddBlock(block4b);
daemon2.AddBlock(block5b);
daemon2.AddBlock(block6b);
// check second blockchain
daemon2.WaitForUpdate();
daemon2.AssertAtBlock(6, block6b.Hash);
// verify that re-organized blockchain matches winning-only blockchain
using (var expectedChainState = daemon2.CoreDaemon.GetChainState())
using (var actualChainState = daemon1.CoreDaemon.GetChainState())
{
var expectedUtxo = expectedChainState.ReadUnspentTransactions().ToList();
var actualUtxo = actualChainState.ReadUnspentTransactions().ToList();
CollectionAssert.AreEqual(expectedUtxo, actualUtxo);
}
}
}
}
public void TestSimpleBlockchainSplit()
{
using (var daemon1 = new TestDaemon())
{
// add some simple blocks
var block1 = daemon1.MineAndAddEmptyBlock();
var block2 = daemon1.MineAndAddEmptyBlock();
var block3a = daemon1.MineAndAddEmptyBlock();
daemon1.WaitForUpdate();
// create a fork test block chain, starting at block2
var testBlocksFork = daemon1.TestBlocks.Fork(1);
// wait for daemon
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(3, block3a.Hash);
// introduce a tie split
var block3b = daemon1.AddBlock(testBlocksFork.MineAndAddEmptyBlock());
// check that 3a is still current as it was first
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(3, block3a.Hash);
// continue with currently winning branch
var block4a = daemon1.MineAndAddEmptyBlock();
// wait for daemon
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(4, block4a.Hash);
// continue with tied branch
var block4b = daemon1.AddBlock(testBlocksFork.MineAndAddEmptyBlock());
// check that 4a is still current as it was first
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(4, block4a.Hash);
// resolve tie split, with other chain winning
var block5b = daemon1.AddBlock(testBlocksFork.MineAndAddEmptyBlock());
// check that blockchain reorged to the winning chain
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(5, block5b.Hash);
// continue on winning fork
var block6b = daemon1.AddBlock(testBlocksFork.MineAndAddEmptyBlock());
// check that blockchain continued on the winning chain
daemon1.WaitForUpdate();
daemon1.AssertAtBlock(6, block6b.Hash);
// create a second blockchain, reusing the genesis from the first
using (var daemon2 = new TestDaemon(daemon1.GenesisBlock))
{
// add only the winning blocks to the second blockchain
daemon2.AddBlock(block1);
daemon2.AddBlock(block2);
daemon2.AddBlock(block3b);
daemon2.AddBlock(block4b);
daemon2.AddBlock(block5b);
daemon2.AddBlock(block6b);
// check second blockchain
daemon2.WaitForUpdate();
daemon2.AssertAtBlock(6, block6b.Hash);
// verify that re-organized blockchain matches winning-only blockchain
using (var expectedChainState = daemon2.CoreDaemon.GetChainState())
using (var actualChainState = daemon1.CoreDaemon.GetChainState())
{
var expectedUtxo = expectedChainState.ReadUnspentTransactions().ToList();
var actualUtxo = actualChainState.ReadUnspentTransactions().ToList();
CollectionAssert.AreEqual(expectedUtxo, actualUtxo);
}
}
}
}
public void TestShorterChainWins()
{
using (var daemon = new TestDaemon())
{
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock();
var block2 = daemon.MineAndAddEmptyBlock();
var block3a = daemon.MineAndAddEmptyBlock();
var block4a = daemon.MineAndAddEmptyBlock();
var block5a = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(5, block5a.Hash);
// create a split with 3b, but do more work than current height 5 chain
var testBlocksFork = daemon.TestBlocks.Fork(3);
daemon.ChainParams.HighestTarget = UnitTestParams.Target2;
var block3b = daemon.AddBlock(testBlocksFork.MineAndAddEmptyBlock(UnitTestParams.Target2));
// check that blockchain reorganized to shorter chain
daemon.WaitForUpdate();
daemon.AssertAtBlock(3, block3b.Hash);
}
}
public void TestReplayBlockRollback()
{
var logger = LogManager.CreateNullLogger();
using (var daemon = new TestDaemon())
{
// create a new keypair to spend to
var toKeyPair = daemon.TxManager.CreateKeyPair();
var toPrivateKey = toKeyPair.Item1;
var toPublicKey = toKeyPair.Item2;
// add block 1
var block0 = daemon.GenesisBlock;
var block1 = daemon.MineAndAddEmptyBlock();
// add block 2, spending from block 1
var spendTx1 = daemon.TxManager.CreateSpendTransaction(block1.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, block1.Transactions[0].OutputValue(), daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKey);
var block2Unmined = daemon.CreateEmptyBlock(block1.Hash)
.WithAddedTransactions(spendTx1);
var block2 = daemon.MineAndAddBlock(block2Unmined);
// add block 3, spending from block 2
var spendTx2 = daemon.TxManager.CreateSpendTransaction(block2.Transactions[1], 0, (byte)ScriptHashType.SIGHASH_ALL, block2.Transactions[1].OutputValue(), toPrivateKey, toPublicKey, toPublicKey);
var block3Unmined = daemon.CreateEmptyBlock(block2.Hash)
.WithAddedTransactions(spendTx2);
var block3 = daemon.MineAndAddBlock(block3Unmined);
// replay all blocks up to block 3
daemon.WaitForUpdate();
using (var chainState = daemon.CoreDaemon.GetChainState())
{
Assert.AreEqual(3, chainState.Chain.Height);
var replayTransactions = new List<LoadedTx>();
foreach (var blockHash in chainState.Chain.Blocks.Select(x => x.Hash))
{
replayTransactions.AddRange(BlockReplayer.ReplayBlock(daemon.CoreStorage, chainState, blockHash, replayForward: true)
.ToEnumerable());
}
// verify all transactions were replayed
Assert.AreEqual(6, replayTransactions.Count);
Assert.AreEqual(block0.Transactions[0].Hash, replayTransactions[0].Transaction.Hash);
Assert.AreEqual(block1.Transactions[0].Hash, replayTransactions[1].Transaction.Hash);
Assert.AreEqual(block2.Transactions[0].Hash, replayTransactions[2].Transaction.Hash);
Assert.AreEqual(block2.Transactions[1].Hash, replayTransactions[3].Transaction.Hash);
Assert.AreEqual(block3.Transactions[0].Hash, replayTransactions[4].Transaction.Hash);
Assert.AreEqual(block3.Transactions[1].Hash, replayTransactions[5].Transaction.Hash);
}
// mark blocks 2-3 invalid, they will be rolled back
daemon.CoreStorage.MarkBlockInvalid(block3.Hash);
daemon.CoreStorage.MarkBlockInvalid(block2.Hash);
daemon.WaitForUpdate();
// replay rollback of block 3
using (var chainState = daemon.CoreDaemon.GetChainState())
{
Assert.AreEqual(1, chainState.Chain.Height);
var replayTransactions = new List<LoadedTx>(
BlockReplayer.ReplayBlock(daemon.CoreStorage, chainState, block3.Hash, replayForward: false)
.ToEnumerable());
// verify transactions were replayed
Assert.AreEqual(2, replayTransactions.Count);
Assert.AreEqual(block3.Transactions[1].Hash, replayTransactions[0].Transaction.Hash);
Assert.AreEqual(block3.Transactions[0].Hash, replayTransactions[1].Transaction.Hash);
// verify correct previous output was replayed (block 3 tx 1 spent block 2 tx 1)
Assert.AreEqual(1, replayTransactions[0].InputTxes.Length);
CollectionAssert.AreEqual(block2.Transactions[1].Outputs[0].ScriptPublicKey, replayTransactions[0].GetInputPrevTxOutput(0).ScriptPublicKey);
// verify correct previous output was replayed (block 3 tx 0 spends nothing, coinbase)
Assert.AreEqual(0, replayTransactions[1].InputTxes.Length);
}
// replay rollback of block 2
using (var chainState = daemon.CoreDaemon.GetChainState())
{
Assert.AreEqual(1, chainState.Chain.Height);
var replayTransactions = new List<LoadedTx>(
BlockReplayer.ReplayBlock(daemon.CoreStorage, chainState, block2.Hash, replayForward: false)
.ToEnumerable());
// verify transactions were replayed
Assert.AreEqual(2, replayTransactions.Count);
Assert.AreEqual(block2.Transactions[1].Hash, replayTransactions[0].Transaction.Hash);
Assert.AreEqual(block2.Transactions[0].Hash, replayTransactions[1].Transaction.Hash);
// verify correct previous output was replayed (block 2 tx 1 spent block 1 tx 0)
Assert.AreEqual(1, replayTransactions[0].InputTxes.Length);
CollectionAssert.AreEqual(block1.Transactions[0].Outputs[0].ScriptPublicKey, replayTransactions[0].GetInputPrevTxOutput(0).ScriptPublicKey);
// verify correct previous output was replayed (block 2 tx 0 spends nothing, coinbase)
Assert.AreEqual(0, replayTransactions[1].InputTxes.Length);
}
}
}
public void TestInsufficientBalance()
{
using (var daemon = new TestDaemon())
{
// create a new keypair to spend to
var toKeyPair = daemon.TxManager.CreateKeyPair();
var toPrivateKey = toKeyPair.Item1;
var toPublicKey = toKeyPair.Item2;
// add some simple blocks
var block1 = daemon.MineAndAddEmptyBlock();
var block2 = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(2, block2.Hash);
// attempt to spend block 2's coinbase in block 3, using twice its value
var spendTx = daemon.TxManager.CreateSpendTransaction(block2.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, 100 * SATOSHI_PER_BTC, daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKey);
var block3BadUnmined = daemon.CreateEmptyBlock(block2.Hash)
.CreateWithAddedTransactions(spendTx);
var block3Bad = daemon.MineAndAddBlock(block3BadUnmined);
// check that bad block wasn't added
daemon.WaitForUpdate();
daemon.AssertAtBlock(2, block2.Hash);
// add a simple block
daemon.TestBlocks.Rollback(1);
var block3Good = daemon.MineAndAddEmptyBlock();
// check
daemon.WaitForUpdate();
daemon.AssertAtBlock(3, block3Good.Hash);
}
}
public void TestSimpleBlockchainSplit()
{
using (var daemon1 = new TestDaemon())
{
// add some simple blocks
var block1 = daemon1.MineAndAddEmptyBlock(daemon1.GenesisBlock);
var block2 = daemon1.MineAndAddEmptyBlock(block1);
// introduce a tie split
var block3a = daemon1.MineAndAddEmptyBlock(block2);
var block3b = daemon1.MineAndAddEmptyBlock(block2);
// check that 3a is current as it was first
daemon1.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(3, block3a.Hash, daemon1.BlockchainDaemon);
// continue split
var block4a = daemon1.MineAndAddEmptyBlock(block3a);
var block4b = daemon1.MineAndAddEmptyBlock(block3b);
// check that 4a is current as it was first
daemon1.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(4, block4a.Hash, daemon1.BlockchainDaemon);
// resolve tie split, with other chain winning
var block5b = daemon1.MineAndAddEmptyBlock(block4b);
// check that blockchain reorged to the winning chain
daemon1.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(5, block5b.Hash, daemon1.BlockchainDaemon);
// continue on winning fork
var block6b = daemon1.MineAndAddEmptyBlock(block5b);
// check that blockchain continued on the winning chain
daemon1.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(6, block6b.Hash, daemon1.BlockchainDaemon);
// create a second blockchain, reusing the genesis from the first
using (var daemon2 = new TestDaemon(daemon1.GenesisBlock))
{
// add only the winning blocks to the second blockchain
daemon2.AddBlock(block1);
daemon2.AddBlock(block2);
daemon2.AddBlock(block3b);
daemon2.AddBlock(block4b);
daemon2.AddBlock(block5b);
daemon2.AddBlock(block6b);
// check second blockchain
daemon2.WaitForDaemon();
AssertMethods.AssertDaemonAtBlock(6, block6b.Hash, daemon2.BlockchainDaemon);
// verify that re-organized blockchain matches winning-only blockchain
using (var expectedChainSate = daemon2.BlockchainDaemon.GetChainState())
using (var actualChainSate = daemon1.BlockchainDaemon.GetChainState())
{
var expectedUtxo = expectedChainSate.Utxo;
var expectedUnspentTransactions = ImmutableDictionary.CreateRange <UInt256, UnspentTx>(expectedUtxo.GetUnspentTransactions());
var expectedUnspentOutputs = ImmutableDictionary.CreateRange <TxOutputKey, TxOutput>(expectedUtxo.GetUnspentOutputs());
var actualUtxo = actualChainSate.Utxo;
var actualUnspentTransactions = ImmutableDictionary.CreateRange <UInt256, UnspentTx>(actualUtxo.GetUnspentTransactions());
var actualUnspentOutputs = ImmutableDictionary.CreateRange <TxOutputKey, TxOutput>(actualUtxo.GetUnspentOutputs());
CollectionAssert.AreEquivalent(expectedUnspentTransactions, actualUnspentTransactions);
CollectionAssert.AreEquivalent(expectedUnspentOutputs, actualUnspentOutputs);
}
}
}
}
public void TestReplayBlockRollback()
{
using (var daemon = new TestDaemon())
{
// create a new keypair to spend to
var toKeyPair = daemon.TxManager.CreateKeyPair();
var toPrivateKey = toKeyPair.Item1;
var toPublicKey = toKeyPair.Item2;
// add block 1
var block0 = daemon.GenesisBlock;
var block1 = daemon.MineAndAddEmptyBlock();
// add some blocks so coinbase is mature to spend
Block lastBlock = null;
for (var i = 0; i < 100; i++)
{
lastBlock = daemon.MineAndAddEmptyBlock();
}
// add block 2, spending from block 1
var spendTx1 = daemon.TxManager.CreateSpendTransaction(block1.Transactions[0], 0, (byte)ScriptHashType.SIGHASH_ALL, block1.Transactions[0].OutputValue(), daemon.CoinbasePrivateKey, daemon.CoinbasePublicKey, toPublicKey);
var block2Unmined = daemon.CreateEmptyBlock(lastBlock.Hash)
.CreateWithAddedTransactions(spendTx1);
var block2 = daemon.MineAndAddBlock(block2Unmined);
// add some blocks so coinbase is mature to spend
for (var i = 0; i < 100; i++)
{
lastBlock = daemon.MineAndAddEmptyBlock();
}
// add block 3, spending from block 2
var spendTx2 = daemon.TxManager.CreateSpendTransaction(block2.Transactions[1], 0, (byte)ScriptHashType.SIGHASH_ALL, block2.Transactions[1].OutputValue(), toPrivateKey, toPublicKey, toPublicKey);
var block3Unmined = daemon.CreateEmptyBlock(lastBlock.Hash)
.CreateWithAddedTransactions(spendTx2);
var block3 = daemon.MineAndAddBlock(block3Unmined);
// replay all blocks up to block 3
daemon.WaitForUpdate();
using (var chainState = daemon.CoreDaemon.GetChainState())
{
Assert.AreEqual(203, chainState.Chain.Height);
var replayTransactions = new List <ValidatableTx>();
foreach (var blockHash in chainState.Chain.Blocks.Select(x => x.Hash))
{
replayTransactions.AddRange(BlockReplayer.ReplayBlock(daemon.CoreStorage, chainState, blockHash, replayForward: true)
.ToEnumerable());
}
// verify all transactions were replayed
Assert.AreEqual(206, replayTransactions.Count);
Assert.AreEqual(block0.Transactions[0].Hash, replayTransactions[0].Transaction.Hash);
Assert.AreEqual(block1.Transactions[0].Hash, replayTransactions[1].Transaction.Hash);
Assert.AreEqual(block2.Transactions[0].Hash, replayTransactions[102].Transaction.Hash);
Assert.AreEqual(block2.Transactions[1].Hash, replayTransactions[103].Transaction.Hash);
Assert.AreEqual(block3.Transactions[0].Hash, replayTransactions[204].Transaction.Hash);
Assert.AreEqual(block3.Transactions[1].Hash, replayTransactions[205].Transaction.Hash);
}
// mark block 2 invalid, it will be rolled back
daemon.CoreStorage.MarkBlockInvalid(block2.Hash, daemon.CoreDaemon.TargetChain);
daemon.WaitForUpdate();
// replay rollback of block 3
using (var chainState = daemon.CoreDaemon.GetChainState())
{
Assert.AreEqual(101, chainState.Chain.Height);
var replayTransactions = new List <ValidatableTx>(
BlockReplayer.ReplayBlock(daemon.CoreStorage, chainState, block3.Hash, replayForward: false)
.ToEnumerable());
// verify transactions were replayed
Assert.AreEqual(2, replayTransactions.Count);
Assert.AreEqual(block3.Transactions[1].Hash, replayTransactions[0].Transaction.Hash);
Assert.AreEqual(block3.Transactions[0].Hash, replayTransactions[1].Transaction.Hash);
// verify correct previous output was replayed (block 3 tx 1 spent block 2 tx 1)
Assert.AreEqual(1, replayTransactions[0].PrevTxOutputs.Length);
CollectionAssert.AreEqual(block2.Transactions[1].Outputs[0].ScriptPublicKey, replayTransactions[0].PrevTxOutputs[0].ScriptPublicKey);
// verify correct previous output was replayed (block 3 tx 0 spends nothing, coinbase)
Assert.AreEqual(0, replayTransactions[1].PrevTxOutputs.Length);
}
// replay rollback of block 2
using (var chainState = daemon.CoreDaemon.GetChainState())
{
Assert.AreEqual(101, chainState.Chain.Height);
var replayTransactions = new List <ValidatableTx>(
BlockReplayer.ReplayBlock(daemon.CoreStorage, chainState, block2.Hash, replayForward: false)
.ToEnumerable());
// verify transactions were replayed
Assert.AreEqual(2, replayTransactions.Count);
Assert.AreEqual(block2.Transactions[1].Hash, replayTransactions[0].Transaction.Hash);
Assert.AreEqual(block2.Transactions[0].Hash, replayTransactions[1].Transaction.Hash);
// verify correct previous output was replayed (block 2 tx 1 spent block 1 tx 0)
Assert.AreEqual(1, replayTransactions[0].PrevTxOutputs.Length);
CollectionAssert.AreEqual(block1.Transactions[0].Outputs[0].ScriptPublicKey, replayTransactions[0].PrevTxOutputs[0].ScriptPublicKey);
// verify correct previous output was replayed (block 2 tx 0 spends nothing, coinbase)
Assert.AreEqual(0, replayTransactions[1].PrevTxOutputs.Length);
}
}
}
