package mempool import ( "sort" "testing" "github.com/CityOfZion/neo-go/pkg/core/transaction" "github.com/CityOfZion/neo-go/pkg/internal/random" "github.com/CityOfZion/neo-go/pkg/util" "github.com/stretchr/testify/assert" "github.com/stretchr/testify/require" ) type FeerStub struct { lowPriority bool sysFee util.Fixed8 netFee util.Fixed8 perByteFee util.Fixed8 } func (fs *FeerStub) NetworkFee(*transaction.Transaction) util.Fixed8 { return fs.netFee } func (fs *FeerStub) IsLowPriority(util.Fixed8) bool { return fs.lowPriority } func (fs *FeerStub) FeePerByte(*transaction.Transaction) util.Fixed8 { return fs.perByteFee } func (fs *FeerStub) SystemFee(*transaction.Transaction) util.Fixed8 { return fs.sysFee } func testMemPoolAddRemoveWithFeer(t *testing.T, fs Feer) { mp := NewMemPool(10) tx := newMinerTX(0) _, _, ok := mp.TryGetValue(tx.Hash()) require.Equal(t, false, ok) require.NoError(t, mp.Add(tx, fs)) // Re-adding should fail. require.Error(t, mp.Add(tx, fs)) tx2, _, ok := mp.TryGetValue(tx.Hash()) require.Equal(t, true, ok) require.Equal(t, tx, tx2) mp.Remove(tx.Hash()) _, _, ok = mp.TryGetValue(tx.Hash()) require.Equal(t, false, ok) // Make sure nothing left in the mempool after removal. assert.Equal(t, 0, len(mp.verifiedMap)) assert.Equal(t, 0, len(mp.verifiedTxes)) } func TestMemPoolAddRemove(t *testing.T) { var fs = &FeerStub{lowPriority: false} t.Run("low priority", func(t *testing.T) { testMemPoolAddRemoveWithFeer(t, fs) }) fs.lowPriority = true t.Run("high priority", func(t *testing.T) { testMemPoolAddRemoveWithFeer(t, fs) }) } func TestMemPoolVerify(t *testing.T) { mp := NewMemPool(10) tx := newMinerTX(1) inhash1 := random.Uint256() tx.Inputs = append(tx.Inputs, transaction.Input{PrevHash: inhash1, PrevIndex: 0}) require.Equal(t, true, mp.Verify(tx)) require.NoError(t, mp.Add(tx, &FeerStub{})) tx2 := newMinerTX(2) inhash2 := random.Uint256() tx2.Inputs = append(tx2.Inputs, transaction.Input{PrevHash: inhash2, PrevIndex: 0}) require.Equal(t, true, mp.Verify(tx2)) require.NoError(t, mp.Add(tx2, &FeerStub{})) tx3 := newMinerTX(3) // Different index number, but the same PrevHash as in tx1. tx3.Inputs = append(tx3.Inputs, transaction.Input{PrevHash: inhash1, PrevIndex: 1}) require.Equal(t, true, mp.Verify(tx3)) // The same input as in tx2. tx3.Inputs = append(tx3.Inputs, transaction.Input{PrevHash: inhash2, PrevIndex: 0}) require.Equal(t, false, mp.Verify(tx3)) require.Error(t, mp.Add(tx3, &FeerStub{})) } func newMinerTX(i uint32) *transaction.Transaction { return &transaction.Transaction{ Type: transaction.MinerType, Data: &transaction.MinerTX{Nonce: i}, } } func TestOverCapacity(t *testing.T) { var fs = &FeerStub{lowPriority: true} const mempoolSize = 10 mp := NewMemPool(mempoolSize) for i := 0; i < mempoolSize; i++ { tx := newMinerTX(uint32(i)) require.NoError(t, mp.Add(tx, fs)) } txcnt := uint32(mempoolSize) require.Equal(t, mempoolSize, mp.Count()) require.Equal(t, true, sort.IsSorted(sort.Reverse(mp.verifiedTxes))) // Claim TX has more priority than ordinary lowprio, so it should easily // fit into the pool. claim := &transaction.Transaction{ Type: transaction.ClaimType, Data: &transaction.ClaimTX{}, } require.NoError(t, mp.Add(claim, fs)) require.Equal(t, mempoolSize, mp.Count()) require.Equal(t, true, sort.IsSorted(sort.Reverse(mp.verifiedTxes))) // Fees are also prioritized. fs.netFee = util.Fixed8FromFloat(0.0001) for i := 0; i < mempoolSize-1; i++ { tx := newMinerTX(txcnt) txcnt++ require.NoError(t, mp.Add(tx, fs)) require.Equal(t, mempoolSize, mp.Count()) require.Equal(t, true, sort.IsSorted(sort.Reverse(mp.verifiedTxes))) } // Less prioritized txes are not allowed anymore. fs.netFee = util.Fixed8FromFloat(0.00001) tx := newMinerTX(txcnt) txcnt++ require.Error(t, mp.Add(tx, fs)) require.Equal(t, mempoolSize, mp.Count()) require.Equal(t, true, sort.IsSorted(sort.Reverse(mp.verifiedTxes))) // But claim tx should still be there. require.True(t, mp.ContainsKey(claim.Hash())) // Low net fee, but higher per-byte fee is still a better combination. fs.perByteFee = util.Fixed8FromFloat(0.001) tx = newMinerTX(txcnt) txcnt++ require.NoError(t, mp.Add(tx, fs)) require.Equal(t, mempoolSize, mp.Count()) require.Equal(t, true, sort.IsSorted(sort.Reverse(mp.verifiedTxes))) // High priority always wins over low priority. fs.lowPriority = false for i := 0; i < mempoolSize; i++ { tx := newMinerTX(txcnt) txcnt++ require.NoError(t, mp.Add(tx, fs)) require.Equal(t, mempoolSize, mp.Count()) require.Equal(t, true, sort.IsSorted(sort.Reverse(mp.verifiedTxes))) } // Good luck with low priority now. fs.lowPriority = true tx = newMinerTX(txcnt) require.Error(t, mp.Add(tx, fs)) require.Equal(t, mempoolSize, mp.Count()) require.Equal(t, true, sort.IsSorted(sort.Reverse(mp.verifiedTxes))) } func TestGetVerified(t *testing.T) { var fs = &FeerStub{lowPriority: true} const mempoolSize = 10 mp := NewMemPool(mempoolSize) txes := make([]*transaction.Transaction, 0, mempoolSize) for i := 0; i < mempoolSize; i++ { tx := newMinerTX(uint32(i)) txes = append(txes, tx) require.NoError(t, mp.Add(tx, fs)) } require.Equal(t, mempoolSize, mp.Count()) verTxes := mp.GetVerifiedTransactions() require.Equal(t, mempoolSize, len(verTxes)) for _, txf := range verTxes { require.Contains(t, txes, txf.Tx) } for _, tx := range txes { mp.Remove(tx.Hash()) } verTxes = mp.GetVerifiedTransactions() require.Equal(t, 0, len(verTxes)) } func TestRemoveStale(t *testing.T) { var fs = &FeerStub{lowPriority: true} const mempoolSize = 10 mp := NewMemPool(mempoolSize) txes1 := make([]*transaction.Transaction, 0, mempoolSize/2) txes2 := make([]*transaction.Transaction, 0, mempoolSize/2) for i := 0; i < mempoolSize; i++ { tx := newMinerTX(uint32(i)) if i%2 == 0 { txes1 = append(txes1, tx) } else { txes2 = append(txes2, tx) } require.NoError(t, mp.Add(tx, fs)) } require.Equal(t, mempoolSize, mp.Count()) mp.RemoveStale(func(t *transaction.Transaction) bool { for _, tx := range txes2 { if tx == t { return true } } return false }) require.Equal(t, mempoolSize/2, mp.Count()) verTxes := mp.GetVerifiedTransactions() for _, txf := range verTxes { require.NotContains(t, txes1, txf.Tx) require.Contains(t, txes2, txf.Tx) } }