package state import ( . "github.com/tendermint/tendermint/account" . "github.com/tendermint/tendermint/binary" . "github.com/tendermint/tendermint/block" . "github.com/tendermint/tendermint/config" "bytes" "testing" "time" ) func TestCopyState(t *testing.T) { // Generate a random state s0, privAccounts, _ := RandGenesisState(10, true, 1000, 5, true, 1000) s0Hash := s0.Hash() if len(s0Hash) == 0 { t.Error("Expected state hash") } // Check hash of copy s0Copy := s0.Copy() if !bytes.Equal(s0Hash, s0Copy.Hash()) { t.Error("Expected state copy hash to be the same") } // Mutate the original; hash should change. acc0Address := privAccounts[0].PubKey.Address() acc := s0.GetAccount(acc0Address) acc.Balance += 1 // The account balance shouldn't have changed yet. if s0.GetAccount(acc0Address).Balance == acc.Balance { t.Error("Account balance changed unexpectedly") } // Setting, however, should change the balance. s0.SetAccount(acc) if s0.GetAccount(acc0Address).Balance != acc.Balance { t.Error("Account balance wasn't set") } // Now that the state changed, the hash should change too. if bytes.Equal(s0Hash, s0.Hash()) { t.Error("Expected state hash to have changed") } // The s0Copy shouldn't have changed though. if !bytes.Equal(s0Hash, s0Copy.Hash()) { t.Error("Expected state copy hash to have not changed") } } func TestGenesisSaveLoad(t *testing.T) { // Generate a state, save & load it. s0, _, _ := RandGenesisState(10, true, 1000, 5, true, 1000) // Mutate the state to append one empty block. block := &Block{ Header: &Header{ Network: Config.Network, Height: 1, Time: s0.LastBlockTime.Add(time.Minute), Fees: 0, NumTxs: 0, LastBlockHash: s0.LastBlockHash, LastBlockParts: s0.LastBlockParts, StateHash: nil, }, Validation: &Validation{}, Data: &Data{ Txs: []Tx{}, }, } blockParts := NewPartSetFromData(BinaryBytes(block)) // The last argument to AppendBlock() is `false`, // which sets Block.Header.StateHash. err := s0.Copy().AppendBlock(block, blockParts.Header(), false) if err != nil { t.Error("Error appending initial block:", err) } if len(block.Header.StateHash) == 0 { t.Error("Expected StateHash but got nothing.") } // Now append the block to s0. // This time we also check the StateHash (as computed above). err = s0.AppendBlock(block, blockParts.Header(), true) if err != nil { t.Error("Error appending initial block:", err) } // Save s0 s0.Save() // Sanity check s0 //s0.DB.(*db_.MemDB).Print() if s0.BondedValidators.TotalVotingPower() == 0 { t.Error("s0 BondedValidators TotalVotingPower should not be 0") } if s0.LastBlockHeight != 1 { t.Error("s0 LastBlockHeight should be 1, got", s0.LastBlockHeight) } // Load s1 s1 := LoadState(s0.DB) // Compare height & blockHash if s0.LastBlockHeight != s1.LastBlockHeight { t.Error("LastBlockHeight mismatch") } if !bytes.Equal(s0.LastBlockHash, s1.LastBlockHash) { t.Error("LastBlockHash mismatch") } // Compare state merkle trees if s0.BondedValidators.Size() != s1.BondedValidators.Size() { t.Error("BondedValidators Size mismatch") } if s0.BondedValidators.TotalVotingPower() != s1.BondedValidators.TotalVotingPower() { t.Error("BondedValidators TotalVotingPower mismatch") } if !bytes.Equal(s0.BondedValidators.Hash(), s1.BondedValidators.Hash()) { t.Error("BondedValidators hash mismatch") } if s0.UnbondingValidators.Size() != s1.UnbondingValidators.Size() { t.Error("UnbondingValidators Size mismatch") } if s0.UnbondingValidators.TotalVotingPower() != s1.UnbondingValidators.TotalVotingPower() { t.Error("UnbondingValidators TotalVotingPower mismatch") } if !bytes.Equal(s0.UnbondingValidators.Hash(), s1.UnbondingValidators.Hash()) { t.Error("UnbondingValidators hash mismatch") } if !bytes.Equal(s0.accounts.Hash(), s1.accounts.Hash()) { t.Error("Accounts mismatch") } if !bytes.Equal(s0.validatorInfos.Hash(), s1.validatorInfos.Hash()) { t.Error("Accounts mismatch") } } func TestTxSequence(t *testing.T) { state, privAccounts, _ := RandGenesisState(3, true, 1000, 1, true, 1000) acc0 := state.GetAccount(privAccounts[0].PubKey.Address()) acc0PubKey := privAccounts[0].PubKey acc1 := state.GetAccount(privAccounts[1].PubKey.Address()) // Try executing a SendTx with various sequence numbers. makeSendTx := func(sequence uint) *SendTx { return &SendTx{ Inputs: []*TxInput{ &TxInput{ Address: acc0.Address, Amount: 1, Sequence: sequence, PubKey: acc0PubKey, }, }, Outputs: []*TxOutput{ &TxOutput{ Address: acc1.Address, Amount: 1, }, }, } } // Test a variety of sequence numbers for the tx. // The tx should only pass when i == 1. for i := -1; i < 3; i++ { sequence := acc0.Sequence + uint(i) tx := makeSendTx(sequence) tx.Inputs[0].Signature = privAccounts[0].Sign(tx) stateCopy := state.Copy() err := stateCopy.ExecTx(tx) if i == 1 { // Sequence is good. if err != nil { t.Errorf("Expected good sequence to pass: %v", err) } // Check acc.Sequence. newAcc0 := stateCopy.GetAccount(acc0.Address) if newAcc0.Sequence != sequence { t.Errorf("Expected account sequence to change to %v, got %v", sequence, newAcc0.Sequence) } } else { // Sequence is bad. if err == nil { t.Errorf("Expected bad sequence to fail") } // Check acc.Sequence. (shouldn't have changed) newAcc0 := stateCopy.GetAccount(acc0.Address) if newAcc0.Sequence != acc0.Sequence { t.Errorf("Expected account sequence to not change from %v, got %v", acc0.Sequence, newAcc0.Sequence) } } } } // TODO: test overflows. // TODO: test for unbonding validators. func TestTxs(t *testing.T) { state, privAccounts, _ := RandGenesisState(3, true, 1000, 1, true, 1000) //val0 := state.GetValidatorInfo(privValidators[0].Address) acc0 := state.GetAccount(privAccounts[0].PubKey.Address()) acc0PubKey := privAccounts[0].PubKey acc1 := state.GetAccount(privAccounts[1].PubKey.Address()) // SendTx. { state := state.Copy() tx := &SendTx{ Inputs: []*TxInput{ &TxInput{ Address: acc0.Address, Amount: 1, Sequence: acc0.Sequence + 1, PubKey: acc0PubKey, }, }, Outputs: []*TxOutput{ &TxOutput{ Address: acc1.Address, Amount: 1, }, }, } tx.Inputs[0].Signature = privAccounts[0].Sign(tx) err := state.ExecTx(tx) if err != nil { t.Errorf("Got error in executing send transaction, %v", err) } newAcc0 := state.GetAccount(acc0.Address) if acc0.Balance-1 != newAcc0.Balance { t.Errorf("Unexpected newAcc0 balance. Expected %v, got %v", acc0.Balance-1, newAcc0.Balance) } newAcc1 := state.GetAccount(acc1.Address) if acc1.Balance+1 != newAcc1.Balance { t.Errorf("Unexpected newAcc1 balance. Expected %v, got %v", acc1.Balance+1, newAcc1.Balance) } } // BondTx. { state := state.Copy() tx := &BondTx{ PubKey: acc0PubKey.(PubKeyEd25519), Inputs: []*TxInput{ &TxInput{ Address: acc0.Address, Amount: 1, Sequence: acc0.Sequence + 1, PubKey: acc0PubKey, }, }, UnbondTo: []*TxOutput{ &TxOutput{ Address: acc0.Address, Amount: 1, }, }, } tx.Inputs[0].Signature = privAccounts[0].Sign(tx) err := state.ExecTx(tx) if err != nil { t.Errorf("Got error in executing bond transaction, %v", err) } newAcc0 := state.GetAccount(acc0.Address) if newAcc0.Balance != acc0.Balance-1 { t.Errorf("Unexpected newAcc0 balance. Expected %v, got %v", acc0.Balance-1, newAcc0.Balance) } _, acc0Val := state.BondedValidators.GetByAddress(acc0.Address) if acc0Val == nil { t.Errorf("acc0Val not present") } if acc0Val.BondHeight != state.LastBlockHeight+1 { t.Errorf("Unexpected bond height. Expected %v, got %v", state.LastBlockHeight, acc0Val.BondHeight) } if acc0Val.VotingPower != 1 { t.Errorf("Unexpected voting power. Expected %v, got %v", acc0Val.VotingPower, acc0.Balance) } if acc0Val.Accum != 0 { t.Errorf("Unexpected accum. Expected 0, got %v", acc0Val.Accum) } } // TODO UnbondTx. }