arnaucube
/
hermez-node
mirror of https://github.com/arnaucube/hermez-node.git


								package test


								import (

									"crypto/ecdsa"

									"math/big"

									"strconv"

									"strings"

									"testing"

									"time"


									ethCommon "github.com/ethereum/go-ethereum/common"

									ethCrypto "github.com/ethereum/go-ethereum/crypto"

									"github.com/hermeznetwork/hermez-node/common"

									"github.com/iden3/go-iden3-crypto/babyjub"

									"github.com/stretchr/testify/require"

								)


								// Account contains the data related to a testing account

								type Account struct {

									BJJ   *babyjub.PrivateKey

									Addr  ethCommon.Address

									Idx   common.Idx

									Nonce common.Nonce

								}


								// GenerateKeys generates BabyJubJub & Address keys for the given list of

								// account names in a deterministic way. This means, that for the same given

								// 'accNames' the keys will be always the same.

								func GenerateKeys(t *testing.T, accNames []string) map[string]*Account {

									acc := make(map[string]*Account)

									for i := 1; i < len(accNames)+1; i++ {

										// babyjubjub key

										var sk babyjub.PrivateKey

										copy(sk[:], []byte(strconv.Itoa(i))) // only for testing


										// eth address

										var key ecdsa.PrivateKey

										key.D = big.NewInt(int64(i)) // only for testing

										key.PublicKey.X, key.PublicKey.Y = ethCrypto.S256().ScalarBaseMult(key.D.Bytes())

										key.Curve = ethCrypto.S256()

										addr := ethCrypto.PubkeyToAddress(key.PublicKey)


										a := Account{

											BJJ:   &sk,

											Addr:  addr,

											Nonce: 0,

										}

										acc[accNames[i-1]] = &a

									}

									return acc

								}


								// GenerateTestTxs generates L1Tx & PoolL2Tx in a deterministic way for the

								// given Instructions.

								func GenerateTestTxs(t *testing.T, instructions Instructions) ([][]*common.L1Tx, [][]*common.L1Tx, [][]*common.PoolL2Tx, []common.Token) {

									accounts := GenerateKeys(t, instructions.Accounts)

									l1CreatedAccounts := make(map[string]*Account)


									var batchL1Txs []*common.L1Tx

									var batchCoordinatorL1Txs []*common.L1Tx

									var batchPoolL2Txs []*common.PoolL2Tx

									var l1Txs [][]*common.L1Tx

									var coordinatorL1Txs [][]*common.L1Tx

									var poolL2Txs [][]*common.PoolL2Tx

									idx := 1

									for i, inst := range instructions.Instructions {

										switch inst.Type {

										case common.TxTypeCreateAccountDeposit:

											tx := common.L1Tx{

												// TxID

												FromEthAddr: accounts[idxTokenIDToString(inst.From, inst.TokenID)].Addr,

												FromBJJ:     accounts[idxTokenIDToString(inst.From, inst.TokenID)].BJJ.Public(),

												TokenID:     inst.TokenID,

												LoadAmount:  big.NewInt(int64(inst.Amount)),

												Type:        common.TxTypeCreateAccountDeposit,

											}

											batchL1Txs = append(batchL1Txs, &tx)

											if accounts[idxTokenIDToString(inst.From, inst.TokenID)].Idx == common.Idx(0) { // if account.Idx is not set yet, set it and increment idx

												accounts[idxTokenIDToString(inst.From, inst.TokenID)].Idx = common.Idx(idx)


												l1CreatedAccounts[idxTokenIDToString(inst.From, inst.TokenID)] = accounts[idxTokenIDToString(inst.From, inst.TokenID)]

												idx++

											}

										case common.TxTypeTransfer:

											// if account of receiver does not exist, create a new CoordinatorL1Tx creating the account

											if _, ok := l1CreatedAccounts[idxTokenIDToString(inst.To, inst.TokenID)]; !ok {

												tx := common.L1Tx{

													FromEthAddr: accounts[idxTokenIDToString(inst.To, inst.TokenID)].Addr,

													FromBJJ:     accounts[idxTokenIDToString(inst.To, inst.TokenID)].BJJ.Public(),

													TokenID:     inst.TokenID,

													LoadAmount:  big.NewInt(int64(inst.Amount)),

													Type:        common.TxTypeCreateAccountDeposit,

												}

												accounts[idxTokenIDToString(inst.To, inst.TokenID)].Idx = common.Idx(idx)

												l1CreatedAccounts[idxTokenIDToString(inst.To, inst.TokenID)] = accounts[idxTokenIDToString(inst.To, inst.TokenID)]

												batchCoordinatorL1Txs = append(batchCoordinatorL1Txs, &tx)

												idx++

											}


											tx := common.PoolL2Tx{

												TxID:        common.TxID([]byte{byte(i)}), // TODO this is for the moment, once TxID Hash is implemented use it

												FromIdx:     accounts[idxTokenIDToString(inst.From, inst.TokenID)].Idx,

												ToIdx:       accounts[idxTokenIDToString(inst.To, inst.TokenID)].Idx,

												ToEthAddr:   accounts[idxTokenIDToString(inst.To, inst.TokenID)].Addr,

												ToBJJ:       accounts[idxTokenIDToString(inst.To, inst.TokenID)].BJJ.Public(),

												TokenID:     inst.TokenID,

												Amount:      big.NewInt(int64(inst.Amount)),

												Fee:         common.FeeSelector(inst.Fee),

												Nonce:       accounts[idxTokenIDToString(inst.From, inst.TokenID)].Nonce,

												State:       common.PoolL2TxStatePending,

												Timestamp:   time.Now(),

												BatchNum:    common.BatchNum(0),

												RqToEthAddr: accounts[idxTokenIDToString(inst.To, inst.TokenID)].Addr,

												RqToBJJ:     accounts[idxTokenIDToString(inst.To, inst.TokenID)].BJJ.Public(),

												Type:        common.TxTypeTransfer,

											}

											// perform signature and set it to tx.Signature

											toSign, err := tx.HashToSign()

											if err != nil {

												panic(err)

											}

											sig := accounts[idxTokenIDToString(inst.To, inst.TokenID)].BJJ.SignPoseidon(toSign)

											tx.Signature = sig


											accounts[idxTokenIDToString(inst.From, inst.TokenID)].Nonce++

											batchPoolL2Txs = append(batchPoolL2Txs, &tx)


										case common.TxTypeExit, common.TxTypeForceExit:

											tx := common.L1Tx{

												FromIdx: accounts[idxTokenIDToString(inst.From, inst.TokenID)].Idx,

												ToIdx:   common.Idx(1), // as is an Exit

												TokenID: inst.TokenID,

												Amount:  big.NewInt(int64(inst.Amount)),

												Type:    common.TxTypeExit,

											}

											batchL1Txs = append(batchL1Txs, &tx)

										case TypeNewBatch:

											l1Txs = append(l1Txs, batchL1Txs)

											coordinatorL1Txs = append(coordinatorL1Txs, batchCoordinatorL1Txs)

											poolL2Txs = append(poolL2Txs, batchPoolL2Txs)

											batchL1Txs = []*common.L1Tx{}

											batchCoordinatorL1Txs = []*common.L1Tx{}

											batchPoolL2Txs = []*common.PoolL2Tx{}

										default:

											continue

										}

									}

									l1Txs = append(l1Txs, batchL1Txs)

									coordinatorL1Txs = append(coordinatorL1Txs, batchCoordinatorL1Txs)

									poolL2Txs = append(poolL2Txs, batchPoolL2Txs)

									tokens := []common.Token{}

									for i := 0; i < len(poolL2Txs); i++ {

										for j := 0; j < len(poolL2Txs[i]); j++ {

											id := poolL2Txs[i][j].TokenID

											found := false

											for k := 0; k < len(tokens); k++ {

												if tokens[k].TokenID == id {

													found = true

													break

												}

											}

											if !found {

												tokens = append(tokens, common.Token{

													TokenID:     id,

													EthBlockNum: 1,

													EthAddr:     ethCommon.BigToAddress(big.NewInt(int64(i*10000 + j))),

												})

											}

										}

									}

									return l1Txs, coordinatorL1Txs, poolL2Txs, tokens

								}


								// GenerateTestTxsFromSet reurns the L1 & L2 transactions for a given Set of

								// Instructions code

								func GenerateTestTxsFromSet(t *testing.T, set string) ([][]*common.L1Tx, [][]*common.L1Tx, [][]*common.PoolL2Tx, []common.Token) {

									parser := NewParser(strings.NewReader(set))

									instructions, err := parser.Parse()

									require.Nil(t, err)


									return GenerateTestTxs(t, instructions)

								}