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Merge pull request #265 from hermeznetwork/feature/zkinputs1

StateDB group Fee txs and ZKInputs gen of Fee txs & Update tx bytes parsers methods
feature/sql-semaphore1
Eduard S 4 years ago
committed by GitHub
parent
commit
a4886c99ef
No known key found for this signature in database GPG Key ID: 4AEE18F83AFDEB23
7 changed files with 190 additions and 97 deletions
  1. +4
    -1
      common/fee_test.go
  2. +16
    -3
      common/l1tx.go
  3. +1
    -0
      common/l1tx_test.go
  4. +20
    -15
      common/l2tx.go
  5. +51
    -38
      common/zk.go
  6. +5
    -1
      db/statedb/statedb.go
  7. +93
    -39
      db/statedb/txprocessors.go

+ 4
- 1
common/fee_test.go

@ -48,8 +48,11 @@ func TestCalcFeeAmount(t *testing.T) {
}
func TestFeePrintSQLSwitch(t *testing.T) {
debug := false
for i := 0; i < 256; i++ {
f := FeeSelector(i).Percentage()
fmt.Printf(" WHEN $1 = %03d THEN %.6e\n", i, f)
if debug {
fmt.Printf(" WHEN $1 = %03d THEN %.6e\n", i, f)
}
}
}

+ 16
- 3
common/l1tx.go

@ -146,8 +146,11 @@ func (tx L1Tx) Tx() Tx {
return genericTx
}
// BytesUser encodes a L1Tx into []byte
func (tx *L1Tx) BytesUser() ([]byte, error) {
// BytesGeneric returns the generic representation of a L1Tx. This method is
// used to compute the []byte representation of a L1UserTx, and also to compute
// the L1TxData for the ZKInputs (at the HashGlobalInputs), using this method
// for L1CoordinatorTxs & L1UserTxs (for the ZKInputs case).
func (tx *L1Tx) BytesGeneric() ([]byte, error) {
var b [L1UserTxBytesLen]byte
copy(b[0:20], tx.FromEthAddr.Bytes())
pkCompL := tx.FromBJJ.Compress()
@ -177,8 +180,19 @@ func (tx *L1Tx) BytesUser() ([]byte, error) {
return b[:], nil
}
// BytesUser encodes a L1UserTx into []byte
func (tx *L1Tx) BytesUser() ([]byte, error) {
if !tx.UserOrigin {
return nil, fmt.Errorf("Can not calculate BytesUser() for a L1CoordinatorTx")
}
return tx.BytesGeneric()
}
// BytesCoordinatorTx encodes a L1CoordinatorTx into []byte
func (tx *L1Tx) BytesCoordinatorTx(compressedSignatureBytes []byte) ([]byte, error) {
if tx.UserOrigin {
return nil, fmt.Errorf("Can not calculate BytesCoordinatorTx() for a L1UserTx")
}
var b [L1CoordinatorTxBytesLen]byte
v := compressedSignatureBytes[64]
s := compressedSignatureBytes[32:64]
@ -210,7 +224,6 @@ func L1UserTxFromBytes(b []byte) (*L1Tx, error) {
var pkComp babyjub.PublicKeyComp
copy(pkComp[:], pkCompL)
tx.FromBJJ, err = pkComp.Decompress()
if err != nil {
return nil, err
}

+ 1
- 0
common/l1tx_test.go

@ -109,6 +109,7 @@ func TestL1TxByteParsersCompatibility(t *testing.T) {
FromIdx: Idx(29767899),
FromBJJ: pk,
FromEthAddr: ethCommon.HexToAddress("0x85dab5b9e2e361d0c208d77be90efcc0439b0a53"),
UserOrigin: true,
}
expected, err := utils.HexDecode("85dab5b9e2e361d0c208d77be90efcc0439b0a530dd02deb2c81068e7a0f7e327df80b4ab79ee1f41a7def613e73a20c32eece5a000001c638db8be880f00020039c0000053cb88d")

+ 20
- 15
common/l2tx.go

@ -105,49 +105,54 @@ func L2TxsToPoolL2Txs(txs []L2Tx) []PoolL2Tx {
// Bytes encodes a L2Tx into []byte
func (tx *L2Tx) Bytes(nLevels int) ([]byte, error) {
fromIdxNumBytes := nLevels / 8 //nolint:gomnd
toIdxNumBytes := nLevels / 8 //nolint:gomnd
var b []byte
idxLen := nLevels / 8 //nolint:gomnd
b := make([]byte, ((nLevels*2)+16+8)/8) //nolint:gomnd
fromIdxBytes, err := tx.FromIdx.Bytes()
if err != nil {
return nil, err
}
b = append(b, fromIdxBytes[6-fromIdxNumBytes:]...)
copy(b[0:idxLen], fromIdxBytes[6-idxLen:]) // [6-idxLen:] as is BigEndian
toIdxBytes, err := tx.ToIdx.Bytes()
if err != nil {
return nil, err
}
b = append(b, toIdxBytes[6-toIdxNumBytes:]...)
copy(b[idxLen:idxLen*2], toIdxBytes[6-idxLen:])
amountFloat16, err := NewFloat16(tx.Amount)
if err != nil {
return nil, err
}
b = append(b, amountFloat16.Bytes()...)
b = append(b, byte(tx.Fee))
copy(b[idxLen*2:idxLen*2+2], amountFloat16.Bytes())
b[idxLen*2+2] = byte(tx.Fee)
return b[:], nil
}
// L2TxFromBytes decodes a L1Tx from []byte
func L2TxFromBytes(b []byte, nLevels int) (*L2Tx, error) {
fromIdxNumByte := nLevels / 8 //nolint:gomnd
toIdxNumByte := fromIdxNumByte + nLevels/8 //nolint:gomnd
amountLenBytes := 2
amountNumByte := toIdxNumByte + amountLenBytes
idxLen := nLevels / 8 //nolint:gomnd
tx := &L2Tx{}
var err error
var paddedFromIdxBytes [6]byte
copy(paddedFromIdxBytes[6-len(b[0:fromIdxNumByte]):], b[0:fromIdxNumByte])
copy(paddedFromIdxBytes[6-idxLen:], b[0:idxLen])
tx.FromIdx, err = IdxFromBytes(paddedFromIdxBytes[:])
if err != nil {
return nil, err
}
var paddedToIdxBytes [6]byte
copy(paddedToIdxBytes[6-len(b[fromIdxNumByte:toIdxNumByte]):6], b[fromIdxNumByte:toIdxNumByte])
copy(paddedToIdxBytes[6-idxLen:6], b[idxLen:idxLen*2])
tx.ToIdx, err = IdxFromBytes(paddedToIdxBytes[:])
if err != nil {
return nil, err
}
tx.Amount = Float16FromBytes(b[toIdxNumByte:amountNumByte]).BigInt()
tx.Fee = FeeSelector(b[amountNumByte])
tx.Amount = Float16FromBytes(b[idxLen*2 : idxLen*2+2]).BigInt()
tx.Fee = FeeSelector(b[idxLen*2+2])
return tx, nil
}

+ 51
- 38
common/zk.go

@ -1,6 +1,5 @@
// Package common contains all the common data structures used at the
// hermez-node, zk.go contains the zkSnark inputs used to generate the proof
//nolint:deadcode,structcheck,unused
package common
import (
@ -11,21 +10,30 @@ import (
"github.com/mitchellh/mapstructure"
)
// circuit parameters
// absolute maximum of L1 or L2 transactions allowed
type nTx uint32
// merkle tree depth
type nLevels uint32
// absolute maximum of L1 transaction allowed
type maxL1Tx uint32
//absolute maximum of fee transactions allowed
type maxFeeTx uint32
// ZKMetadata contains ZKInputs metadata that is not used directly in the
// ZKInputs result, but to calculate values for Hash check
type ZKMetadata struct {
// Circuit parameters
// absolute maximum of L1 or L2 transactions allowed
NTx uint32
// merkle tree depth
NLevels uint32
MaxLevels uint32
// absolute maximum of L1 transaction allowed
MaxL1Tx uint32
// Maximum number of Idxs where Fees can be send in a batch (currently
// is constant for all circuits: 64)
MaxFeeIdxs uint32
L1TxsData [][]byte
L2TxsData [][]byte
ChainID uint16
}
// ZKInputs represents the inputs that will be used to generate the zkSNARK proof
type ZKInputs struct {
Metadata ZKMetadata
//
// General
//
@ -38,11 +46,11 @@ type ZKInputs struct {
// GlobalChainID is the blockchain ID (0 for Ethereum mainnet). This value can be get from the smart contract.
GlobalChainID *big.Int `json:"globalChainID"` // uint16
// FeeIdxs is an array of merkle tree indexes where the coordinator will receive the accumulated fees
FeeIdxs []*big.Int `json:"feeIdxs"` // uint64 (max nLevels bits), len: [maxFeeTx]
FeeIdxs []*big.Int `json:"feeIdxs"` // uint64 (max nLevels bits), len: [maxFeeIdxs]
// accumulate fees
// FeePlanTokens contains all the tokenIDs for which the fees are being accumulated
FeePlanTokens []*big.Int `json:"feePlanTokens"` // uint32 (max 32 bits), len: [maxFeeTx]
FeePlanTokens []*big.Int `json:"feePlanTokens"` // uint32 (max 32 bits), len: [maxFeeIdxs]
//
// Txs (L1&L2)
@ -142,13 +150,13 @@ type ZKInputs struct {
// state 3, value of the account leaf receiver of the Fees
// fee tx
// State fees
TokenID3 []*big.Int `json:"tokenID3"` // uint32, len: [maxFeeTx]
Nonce3 []*big.Int `json:"nonce3"` // uint64 (max 40 bits), len: [maxFeeTx]
Sign3 []*big.Int `json:"sign3"` // bool, len: [maxFeeTx]
Ay3 []*big.Int `json:"ay3"` // big.Int, len: [maxFeeTx]
Balance3 []*big.Int `json:"balance3"` // big.Int (max 192 bits), len: [maxFeeTx]
EthAddr3 []*big.Int `json:"ethAddr3"` // ethCommon.Address, len: [maxFeeTx]
Siblings3 [][]*big.Int `json:"siblings3"` // Hash, len: [maxFeeTx][nLevels + 1]
TokenID3 []*big.Int `json:"tokenID3"` // uint32, len: [maxFeeIdxs]
Nonce3 []*big.Int `json:"nonce3"` // uint64 (max 40 bits), len: [maxFeeIdxs]
Sign3 []*big.Int `json:"sign3"` // bool, len: [maxFeeIdxs]
Ay3 []*big.Int `json:"ay3"` // big.Int, len: [maxFeeIdxs]
Balance3 []*big.Int `json:"balance3"` // big.Int (max 192 bits), len: [maxFeeIdxs]
EthAddr3 []*big.Int `json:"ethAddr3"` // ethCommon.Address, len: [maxFeeIdxs]
Siblings3 [][]*big.Int `json:"siblings3"` // Hash, len: [maxFeeIdxs][nLevels + 1]
//
// Intermediate States
@ -174,14 +182,14 @@ type ZKInputs struct {
// ISExitTree root at the moment of the Tx the value once the Tx is processed into the exit tree
ISExitRoot []*big.Int `json:"imExitRoot"` // Hash, len: [nTx - 1]
// ISAccFeeOut accumulated fees once the Tx is processed
ISAccFeeOut [][]*big.Int `json:"imAccFeeOut"` // big.Int, len: [nTx - 1][maxFeeTx]
ISAccFeeOut [][]*big.Int `json:"imAccFeeOut"` // big.Int, len: [nTx - 1][maxFeeIdxs]
// fee-tx
// ISStateRootFee root at the moment of the Tx, the state root value once the Tx is processed into the state tree
ISStateRootFee []*big.Int `json:"imStateRootFee"` // Hash, len: [maxFeeTx - 1]
ISStateRootFee []*big.Int `json:"imStateRootFee"` // Hash, len: [maxFeeIdxs - 1]
// ISInitStateRootFee state root once all L1-L2 tx are processed (before computing the fees-tx)
ISInitStateRootFee *big.Int `json:"imInitStateRootFee"` // Hash
// ISFinalAccFee final accumulated fees (before computing the fees-tx)
ISFinalAccFee []*big.Int `json:"imFinalAccFee"` // big.Int, len: [maxFeeTx - 1]
ISFinalAccFee []*big.Int `json:"imFinalAccFee"` // big.Int, len: [maxFeeIdxs - 1]
}
func bigIntsToStrings(v interface{}) interface{} {
@ -212,6 +220,8 @@ func bigIntsToStrings(v interface{}) interface{} {
r[i] = bigIntsToStrings(c[i])
}
return r
case map[string]interface{}:
// avoid printing a warning when there is a struct type
default:
log.Warnf("bigIntsToStrings unexpected type: %T\n", v)
}
@ -240,15 +250,18 @@ func (z ZKInputs) MarshalJSON() ([]byte, error) {
}
// NewZKInputs returns a pointer to an initialized struct of ZKInputs
func NewZKInputs(nTx, maxFeeTx, nLevels int) *ZKInputs {
func NewZKInputs(nTx, maxFeeIdxs, nLevels int) *ZKInputs {
zki := &ZKInputs{}
zki.Metadata.NTx = uint32(nTx)
zki.Metadata.MaxFeeIdxs = uint32(maxFeeIdxs)
zki.Metadata.NLevels = uint32(nLevels)
// General
zki.OldLastIdx = big.NewInt(0)
zki.OldStateRoot = big.NewInt(0)
zki.GlobalChainID = big.NewInt(0)
zki.FeeIdxs = newSlice(maxFeeTx)
zki.FeePlanTokens = newSlice(maxFeeTx)
zki.FeeIdxs = newSlice(maxFeeIdxs)
zki.FeePlanTokens = newSlice(maxFeeIdxs)
// Txs
zki.TxCompressedData = newSlice(nTx)
@ -312,13 +325,13 @@ func NewZKInputs(nTx, maxFeeTx, nLevels int) *ZKInputs {
zki.OldKey2 = newSlice(nTx)
zki.OldValue2 = newSlice(nTx)
zki.TokenID3 = newSlice(maxFeeTx)
zki.Nonce3 = newSlice(maxFeeTx)
zki.Sign3 = newSlice(maxFeeTx)
zki.Ay3 = newSlice(maxFeeTx)
zki.Balance3 = newSlice(maxFeeTx)
zki.EthAddr3 = newSlice(maxFeeTx)
zki.Siblings3 = make([][]*big.Int, maxFeeTx)
zki.TokenID3 = newSlice(maxFeeIdxs)
zki.Nonce3 = newSlice(maxFeeIdxs)
zki.Sign3 = newSlice(maxFeeIdxs)
zki.Ay3 = newSlice(maxFeeIdxs)
zki.Balance3 = newSlice(maxFeeIdxs)
zki.EthAddr3 = newSlice(maxFeeIdxs)
zki.Siblings3 = make([][]*big.Int, maxFeeIdxs)
for i := 0; i < len(zki.Siblings3); i++ {
zki.Siblings3[i] = newSlice(nLevels + 1)
}
@ -330,11 +343,11 @@ func NewZKInputs(nTx, maxFeeTx, nLevels int) *ZKInputs {
zki.ISExitRoot = newSlice(nTx - 1)
zki.ISAccFeeOut = make([][]*big.Int, nTx-1)
for i := 0; i < len(zki.ISAccFeeOut); i++ {
zki.ISAccFeeOut[i] = newSlice(maxFeeTx)
zki.ISAccFeeOut[i] = newSlice(maxFeeIdxs)
}
zki.ISStateRootFee = newSlice(maxFeeTx - 1)
zki.ISStateRootFee = newSlice(maxFeeIdxs - 1)
zki.ISInitStateRootFee = big.NewInt(0)
zki.ISFinalAccFee = newSlice(maxFeeTx - 1)
zki.ISFinalAccFee = newSlice(maxFeeIdxs - 1)
return zki
}

+ 5
- 1
db/statedb/statedb.go

@ -78,7 +78,11 @@ type StateDB struct {
// idx holds the current Idx that the BatchBuilder is using
idx common.Idx
zki *common.ZKInputs
i int // i is the current transaction index in the ZKInputs generation (zki)
// i is the current transaction index in the ZKInputs generation (zki)
i int
// accumulatedFees contains the accumulated fees for each token (Coord
// Idx) in the processed batch
accumulatedFees map[common.Idx]*big.Int
}
// NewStateDB creates a new StateDB, allowing to use an in-memory or in-disk

+ 93
- 39
db/statedb/txprocessors.go

@ -64,6 +64,8 @@ func (s *StateDB) ProcessTxs(coordIdxs []common.Idx, l1usertxs, l1coordinatortxs
}
defer s.resetZKInputs()
s.accumulatedFees = make(map[common.Idx]*big.Int)
nTx := len(l1usertxs) + len(l1coordinatortxs) + len(l2txs)
if nTx == 0 {
// TODO return ZKInputs of batch without txs
@ -77,22 +79,8 @@ func (s *StateDB) ProcessTxs(coordIdxs []common.Idx, l1usertxs, l1coordinatortxs
}
exits := make([]processedExit, nTx)
// get TokenIDs of coordIdxs
coordIdxsMap, err := s.getTokenIDsFromIdxs(coordIdxs)
if err != nil {
return nil, err
}
var collectedFees map[common.TokenID]*big.Int
if s.typ == TypeSynchronizer {
collectedFees = make(map[common.TokenID]*big.Int)
for tokenID := range coordIdxsMap {
collectedFees[tokenID] = big.NewInt(0)
}
}
if s.typ == TypeBatchBuilder {
maxFeeTx := 2 // TODO this value will be a parameter
maxFeeTx := 64 // TODO this value will be a parameter
s.zki = common.NewZKInputs(nTx, maxFeeTx, s.mt.MaxLevels())
s.zki.OldLastIdx = (s.idx - 1).BigInt()
s.zki.OldStateRoot = s.mt.Root().BigInt()
@ -120,8 +108,9 @@ func (s *StateDB) ProcessTxs(coordIdxs []common.Idx, l1usertxs, l1coordinatortxs
}
}
// assumption: l1usertx are sorted by L1Tx.Position
// Process L1UserTxs
for i := 0; i < len(l1usertxs); i++ {
// assumption: l1usertx are sorted by L1Tx.Position
exitIdx, exitAccount, newExit, createdAccount, err := s.processL1Tx(exitTree, &l1usertxs[i])
if err != nil {
return nil, err
@ -140,7 +129,17 @@ func (s *StateDB) ProcessTxs(coordIdxs []common.Idx, l1usertxs, l1coordinatortxs
if s.typ == TypeSynchronizer && createdAccount != nil {
createdAccounts = append(createdAccounts, *createdAccount)
}
if s.zki != nil {
l1TxData, err := l1usertxs[i].BytesGeneric()
if err != nil {
return nil, err
}
s.zki.Metadata.L1TxsData = append(s.zki.Metadata.L1TxsData, l1TxData)
}
}
// Process L1CoordinatorTxs
for i := 0; i < len(l1coordinatortxs); i++ {
exitIdx, _, _, createdAccount, err := s.processL1Tx(exitTree, &l1coordinatortxs[i])
if err != nil {
@ -152,7 +151,36 @@ func (s *StateDB) ProcessTxs(coordIdxs []common.Idx, l1usertxs, l1coordinatortxs
if s.typ == TypeSynchronizer && createdAccount != nil {
createdAccounts = append(createdAccounts, *createdAccount)
}
if s.zki != nil {
l1TxData, err := l1coordinatortxs[i].BytesGeneric()
if err != nil {
return nil, err
}
s.zki.Metadata.L1TxsData = append(s.zki.Metadata.L1TxsData, l1TxData)
}
}
s.accumulatedFees = make(map[common.Idx]*big.Int)
for _, idx := range coordIdxs {
s.accumulatedFees[idx] = big.NewInt(0)
}
// once L1UserTxs & L1CoordinatorTxs are processed, get TokenIDs of
// coordIdxs. In this way, if a coordIdx uses an Idx that is being
// created in the current batch, at this point the Idx will be created
coordIdxsMap, err := s.getTokenIDsFromIdxs(coordIdxs)
if err != nil {
return nil, err
}
var collectedFees map[common.TokenID]*big.Int
if s.typ == TypeSynchronizer {
collectedFees = make(map[common.TokenID]*big.Int)
for tokenID := range coordIdxsMap {
collectedFees[tokenID] = big.NewInt(0)
}
}
// Process L2Txs
for i := 0; i < len(l2txs); i++ {
exitIdx, exitAccount, newExit, err := s.processL2Tx(coordIdxsMap, collectedFees, exitTree, &l2txs[i])
if err != nil {
@ -171,6 +199,39 @@ func (s *StateDB) ProcessTxs(coordIdxs []common.Idx, l1usertxs, l1coordinatortxs
}
}
// distribute the AccumulatedFees from the processed L2Txs into the
// Coordinator Idxs
iFee := 0
for idx, accumulatedFee := range s.accumulatedFees {
// send the fee to the Idx of the Coordinator for the TokenID
accCoord, err := s.GetAccount(idx)
if err != nil {
log.Errorw("Can not distribute accumulated fees to coordinator account: No coord Idx to receive fee", "idx", idx)
return nil, err
}
accCoord.Balance = new(big.Int).Add(accCoord.Balance, accumulatedFee)
pFee, err := s.UpdateAccount(idx, accCoord)
if err != nil {
log.Error(err)
return nil, err
}
if s.zki != nil {
s.zki.TokenID3[iFee] = accCoord.TokenID.BigInt()
s.zki.Nonce3[iFee] = accCoord.Nonce.BigInt()
if babyjub.PointCoordSign(accCoord.PublicKey.X) {
s.zki.Sign3[iFee] = big.NewInt(1)
}
s.zki.Ay3[iFee] = accCoord.PublicKey.Y
s.zki.Balance3[iFee] = accCoord.Balance
s.zki.EthAddr3[iFee] = common.EthAddrToBigInt(accCoord.EthAddr)
s.zki.Siblings3[iFee] = siblingsToZKInputFormat(pFee.Siblings)
// add Coord Idx to ZKInputs.FeeTxsData
s.zki.FeeIdxs[iFee] = idx.BigInt()
}
iFee++
}
if s.typ == TypeTxSelector {
return nil, nil
}
@ -178,7 +239,6 @@ func (s *StateDB) ProcessTxs(coordIdxs []common.Idx, l1usertxs, l1coordinatortxs
// once all txs processed (exitTree root frozen), for each Exit,
// generate common.ExitInfo data
var exitInfos []common.ExitInfo
// exitInfos := []common.ExitInfo{}
for i := 0; i < nTx; i++ {
if !exits[i].exit {
continue
@ -245,9 +305,6 @@ func (s *StateDB) ProcessTxs(coordIdxs []common.Idx, l1usertxs, l1coordinatortxs
// s.zki.ISInitStateRootFee = s.mt.Root().BigInt()
// TODO once the Node Config sets the Accounts where to send the Fees
// compute fees & update ZKInputs
// return ZKInputs as the BatchBuilder will return it to forge the Batch
return &ProcessTxOutput{
ZKInputs: s.zki,
@ -606,10 +663,10 @@ func (s *StateDB) applyTransfer(coordIdxsMap map[common.TokenID]common.Idx, coll
return err
}
// increment nonce
accSender.Nonce++
if !tx.IsL1 {
// increment nonce
accSender.Nonce++
// compute fee and subtract it from the accSender
fee, err := common.CalcFeeAmount(tx.Amount, *tx.Fee)
if err != nil {
@ -618,19 +675,16 @@ func (s *StateDB) applyTransfer(coordIdxsMap map[common.TokenID]common.Idx, coll
feeAndAmount := new(big.Int).Add(tx.Amount, fee)
accSender.Balance = new(big.Int).Sub(accSender.Balance, feeAndAmount)
// send the fee to the Idx of the Coordinator for the TokenID
accCoord, err := s.GetAccount(coordIdxsMap[accSender.TokenID])
if err != nil {
log.Debugw("No coord Idx to receive fee", "tx", tx)
} else {
accCoord.Balance = new(big.Int).Add(accCoord.Balance, fee)
_, err = s.UpdateAccount(coordIdxsMap[accSender.TokenID], accCoord)
if err != nil {
log.Error(err)
return err
}
// accumulate the fee for the Coord account
accumulated := s.accumulatedFees[accCoord.Idx]
accumulated.Add(accumulated, fee)
if s.typ == TypeSynchronizer {
collected := collectedFees[accSender.TokenID]
collected := collectedFees[accCoord.TokenID]
collected.Add(collected, fee)
}
}
@ -753,6 +807,9 @@ func (s *StateDB) applyExit(coordIdxsMap map[common.TokenID]common.Idx, collecte
}
if !tx.IsL1 {
// increment nonce
acc.Nonce++
// compute fee and subtract it from the accSender
fee, err := common.CalcFeeAmount(tx.Amount, *tx.Fee)
if err != nil {
@ -761,19 +818,16 @@ func (s *StateDB) applyExit(coordIdxsMap map[common.TokenID]common.Idx, collecte
feeAndAmount := new(big.Int).Add(tx.Amount, fee)
acc.Balance = new(big.Int).Sub(acc.Balance, feeAndAmount)
// send the fee to the Idx of the Coordinator for the TokenID
accCoord, err := s.GetAccount(coordIdxsMap[acc.TokenID])
if err != nil {
log.Debugw("No coord Idx to receive fee", "tx", tx)
} else {
accCoord.Balance = new(big.Int).Add(accCoord.Balance, fee)
_, err = s.UpdateAccount(coordIdxsMap[acc.TokenID], accCoord)
if err != nil {
log.Error(err)
return nil, false, err
}
// accumulate the fee for the Coord account
accumulated := s.accumulatedFees[accCoord.Idx]
accumulated.Add(accumulated, fee)
if s.typ == TypeSynchronizer {
collected := collectedFees[acc.TokenID]
collected := collectedFees[accCoord.TokenID]
collected.Add(collected, fee)
}
}

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