// stm: #unit package market import ( "bytes" "context" "sync" "testing" "time" "github.com/ipfs/go-cid" ds "github.com/ipfs/go-datastore" ds_sync "github.com/ipfs/go-datastore/sync" "github.com/stretchr/testify/require" "github.com/filecoin-project/go-address" "github.com/filecoin-project/go-state-types/abi" markettypes "github.com/filecoin-project/go-state-types/builtin/v9/market" tutils "github.com/filecoin-project/specs-actors/v2/support/testing" "github.com/filecoin-project/lotus/api" "github.com/filecoin-project/lotus/chain/actors/builtin/market" "github.com/filecoin-project/lotus/chain/types" "github.com/filecoin-project/lotus/chain/wallet" ) // TestFundManagerBasic verifies that the basic fund manager operations work func TestFundManagerBasic(t *testing.T) { //stm: @MARKET_RESERVE_FUNDS_001, @MARKET_RELEASE_FUNDS_001, @MARKET_WITHDRAW_FUNDS_001 s := setup(t) defer s.fm.Stop() // Reserve 10 // balance: 0 -> 10 // reserved: 0 -> 10 amt := abi.NewTokenAmount(10) sentinel, err := s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) msg := s.mockApi.getSentMessage(sentinel) checkAddMessageFields(t, msg, s.walletAddr, s.acctAddr, amt) s.mockApi.completeMsg(sentinel) // Reserve 7 // balance: 10 -> 17 // reserved: 10 -> 17 amt = abi.NewTokenAmount(7) sentinel, err = s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) msg = s.mockApi.getSentMessage(sentinel) checkAddMessageFields(t, msg, s.walletAddr, s.acctAddr, amt) s.mockApi.completeMsg(sentinel) // Release 5 // balance: 17 // reserved: 17 -> 12 amt = abi.NewTokenAmount(5) err = s.fm.Release(s.acctAddr, amt) require.NoError(t, err) // Withdraw 2 // balance: 17 -> 15 // reserved: 12 amt = abi.NewTokenAmount(2) sentinel, err = s.fm.Withdraw(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) msg = s.mockApi.getSentMessage(sentinel) checkWithdrawMessageFields(t, msg, s.walletAddr, s.acctAddr, amt) s.mockApi.completeMsg(sentinel) // Reserve 3 // balance: 15 // reserved: 12 -> 15 // Note: reserved (15) is <= balance (15) so should not send on-chain // message msgCount := s.mockApi.messageCount() amt = abi.NewTokenAmount(3) sentinel, err = s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) require.Equal(t, msgCount, s.mockApi.messageCount()) require.Equal(t, sentinel, cid.Undef) // Reserve 1 // balance: 15 -> 16 // reserved: 15 -> 16 // Note: reserved (16) is above balance (15) so *should* send on-chain // message to top up balance amt = abi.NewTokenAmount(1) topUp := abi.NewTokenAmount(1) sentinel, err = s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) s.mockApi.completeMsg(sentinel) msg = s.mockApi.getSentMessage(sentinel) checkAddMessageFields(t, msg, s.walletAddr, s.acctAddr, topUp) // Withdraw 1 // balance: 16 // reserved: 16 // Note: Expect failure because there is no available balance to withdraw: // balance - reserved = 16 - 16 = 0 amt = abi.NewTokenAmount(1) _, err = s.fm.Withdraw(s.ctx, s.walletAddr, s.acctAddr, amt) require.Error(t, err) } // TestFundManagerParallel verifies that operations can be run in parallel func TestFundManagerParallel(t *testing.T) { //stm: @MARKET_RESERVE_FUNDS_001, @MARKET_RELEASE_FUNDS_001, @MARKET_WITHDRAW_FUNDS_001 s := setup(t) defer s.fm.Stop() // Reserve 10 amt := abi.NewTokenAmount(10) sentinelReserve10, err := s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) // Wait until all the subsequent requests are queued up queueReady := make(chan struct{}) fa := s.fm.getFundedAddress(s.acctAddr) fa.onProcessStart(func() bool { if len(fa.withdrawals) == 1 && len(fa.reservations) == 2 && len(fa.releases) == 1 { close(queueReady) return true } return false }) // Withdraw 5 (should not run until after reserves / releases) withdrawReady := make(chan error) go func() { amt = abi.NewTokenAmount(5) _, err := s.fm.Withdraw(s.ctx, s.walletAddr, s.acctAddr, amt) withdrawReady <- err }() reserveSentinels := make(chan cid.Cid) // Reserve 3 go func() { amt := abi.NewTokenAmount(3) sentinelReserve3, err := s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) reserveSentinels <- sentinelReserve3 }() // Reserve 5 go func() { amt := abi.NewTokenAmount(5) sentinelReserve5, err := s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) reserveSentinels <- sentinelReserve5 }() // Release 2 go func() { amt := abi.NewTokenAmount(2) err = s.fm.Release(s.acctAddr, amt) require.NoError(t, err) }() // Everything is queued up <-queueReady // Complete the "Reserve 10" message s.mockApi.completeMsg(sentinelReserve10) msg := s.mockApi.getSentMessage(sentinelReserve10) checkAddMessageFields(t, msg, s.walletAddr, s.acctAddr, abi.NewTokenAmount(10)) // The other requests should now be combined and be submitted on-chain as // a single message rs1 := <-reserveSentinels rs2 := <-reserveSentinels require.Equal(t, rs1, rs2) // Withdraw should not have been called yet, because reserve / release // requests run first select { case <-withdrawReady: require.Fail(t, "Withdraw should run after reserve / release") default: } // Complete the message s.mockApi.completeMsg(rs1) msg = s.mockApi.getSentMessage(rs1) // "Reserve 3" +3 // "Reserve 5" +5 // "Release 2" -2 // Result: 6 checkAddMessageFields(t, msg, s.walletAddr, s.acctAddr, abi.NewTokenAmount(6)) // Expect withdraw to fail because not enough available funds err = <-withdrawReady require.Error(t, err) } // TestFundManagerReserveByWallet verifies that reserve requests are grouped by wallet func TestFundManagerReserveByWallet(t *testing.T) { //stm: @MARKET_RESERVE_FUNDS_001 s := setup(t) defer s.fm.Stop() walletAddrA, err := s.wllt.WalletNew(context.Background(), types.KTSecp256k1) require.NoError(t, err) walletAddrB, err := s.wllt.WalletNew(context.Background(), types.KTSecp256k1) require.NoError(t, err) // Wait until all the reservation requests are queued up walletAQueuedUp := make(chan struct{}) queueReady := make(chan struct{}) fa := s.fm.getFundedAddress(s.acctAddr) fa.onProcessStart(func() bool { if len(fa.reservations) == 1 { close(walletAQueuedUp) } if len(fa.reservations) == 3 { close(queueReady) return true } return false }) type reserveResult struct { ws cid.Cid err error } results := make(chan *reserveResult) amtA1 := abi.NewTokenAmount(1) go func() { // Wallet A: Reserve 1 sentinelA1, err := s.fm.Reserve(s.ctx, walletAddrA, s.acctAddr, amtA1) results <- &reserveResult{ ws: sentinelA1, err: err, } }() amtB1 := abi.NewTokenAmount(2) amtB2 := abi.NewTokenAmount(3) go func() { // Wait for reservation for wallet A to be queued up <-walletAQueuedUp // Wallet B: Reserve 2 go func() { sentinelB1, err := s.fm.Reserve(s.ctx, walletAddrB, s.acctAddr, amtB1) results <- &reserveResult{ ws: sentinelB1, err: err, } }() // Wallet B: Reserve 3 sentinelB2, err := s.fm.Reserve(s.ctx, walletAddrB, s.acctAddr, amtB2) results <- &reserveResult{ ws: sentinelB2, err: err, } }() // All reservation requests are queued up <-queueReady resA := <-results sentinelA1 := resA.ws // Should send to wallet A msg := s.mockApi.getSentMessage(sentinelA1) checkAddMessageFields(t, msg, walletAddrA, s.acctAddr, amtA1) // Complete wallet A message s.mockApi.completeMsg(sentinelA1) resB1 := <-results resB2 := <-results require.NoError(t, resB1.err) require.NoError(t, resB2.err) sentinelB1 := resB1.ws sentinelB2 := resB2.ws // Should send different message to wallet B require.NotEqual(t, sentinelA1, sentinelB1) // Should be single message combining amount 1 and 2 require.Equal(t, sentinelB1, sentinelB2) msg = s.mockApi.getSentMessage(sentinelB1) checkAddMessageFields(t, msg, walletAddrB, s.acctAddr, types.BigAdd(amtB1, amtB2)) } // TestFundManagerWithdrawalLimit verifies that as many withdraw operations as // possible are processed func TestFundManagerWithdrawalLimit(t *testing.T) { //stm: @MARKET_RESERVE_FUNDS_001, @MARKET_RELEASE_FUNDS_001, @MARKET_WITHDRAW_FUNDS_001 s := setup(t) defer s.fm.Stop() // Reserve 10 amt := abi.NewTokenAmount(10) sentinelReserve10, err := s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) // Complete the "Reserve 10" message s.mockApi.completeMsg(sentinelReserve10) // Release 10 err = s.fm.Release(s.acctAddr, amt) require.NoError(t, err) // Queue up withdraw requests queueReady := make(chan struct{}) fa := s.fm.getFundedAddress(s.acctAddr) withdrawalReqTotal := 3 withdrawalReqEnqueued := 0 withdrawalReqQueue := make(chan func(), withdrawalReqTotal) fa.onProcessStart(func() bool { // If a new withdrawal request was enqueued if len(fa.withdrawals) > withdrawalReqEnqueued { withdrawalReqEnqueued++ // Pop the next request and run it select { case fn := <-withdrawalReqQueue: go fn() default: } } // Once all the requests have arrived, we're ready to process the queue if withdrawalReqEnqueued == withdrawalReqTotal { close(queueReady) return true } return false }) type withdrawResult struct { reqIndex int ws cid.Cid err error } withdrawRes := make(chan *withdrawResult) // Queue up three "Withdraw 5" requests enqueuedCount := 0 for i := 0; i < withdrawalReqTotal; i++ { withdrawalReqQueue <- func() { idx := enqueuedCount enqueuedCount++ amt := abi.NewTokenAmount(5) ws, err := s.fm.Withdraw(s.ctx, s.walletAddr, s.acctAddr, amt) withdrawRes <- &withdrawResult{reqIndex: idx, ws: ws, err: err} } } // Start the first request fn := <-withdrawalReqQueue go fn() // All withdrawal requests are queued up and ready to be processed <-queueReady // Organize results in request order results := make([]*withdrawResult, withdrawalReqTotal) for i := 0; i < 3; i++ { res := <-withdrawRes results[res.reqIndex] = res } // Available 10 // Withdraw 5 // Expect Success require.NoError(t, results[0].err) // Available 5 // Withdraw 5 // Expect Success require.NoError(t, results[1].err) // Available 0 // Withdraw 5 // Expect FAIL require.Error(t, results[2].err) // Expect withdrawal requests that fit under reserved amount to be combined // into a single message on-chain require.Equal(t, results[0].ws, results[1].ws) } // TestFundManagerWithdrawByWallet verifies that withdraw requests are grouped by wallet func TestFundManagerWithdrawByWallet(t *testing.T) { //stm: @MARKET_RESERVE_FUNDS_001, @MARKET_RELEASE_FUNDS_001, @MARKET_WITHDRAW_FUNDS_001 s := setup(t) defer s.fm.Stop() walletAddrA, err := s.wllt.WalletNew(context.Background(), types.KTSecp256k1) require.NoError(t, err) walletAddrB, err := s.wllt.WalletNew(context.Background(), types.KTSecp256k1) require.NoError(t, err) // Reserve 10 reserveAmt := abi.NewTokenAmount(10) sentinelReserve, err := s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, reserveAmt) require.NoError(t, err) s.mockApi.completeMsg(sentinelReserve) time.Sleep(10 * time.Millisecond) // Release 10 err = s.fm.Release(s.acctAddr, reserveAmt) require.NoError(t, err) type withdrawResult struct { ws cid.Cid err error } results := make(chan *withdrawResult) // Wait until withdrawals are queued up walletAQueuedUp := make(chan struct{}) queueReady := make(chan struct{}) withdrawalCount := 0 fa := s.fm.getFundedAddress(s.acctAddr) fa.onProcessStart(func() bool { if len(fa.withdrawals) == withdrawalCount { return false } withdrawalCount = len(fa.withdrawals) if withdrawalCount == 1 { close(walletAQueuedUp) } else if withdrawalCount == 3 { close(queueReady) return true } return false }) amtA1 := abi.NewTokenAmount(1) go func() { // Wallet A: Withdraw 1 sentinelA1, err := s.fm.Withdraw(s.ctx, walletAddrA, s.acctAddr, amtA1) results <- &withdrawResult{ ws: sentinelA1, err: err, } }() amtB1 := abi.NewTokenAmount(2) amtB2 := abi.NewTokenAmount(3) go func() { // Wait until withdraw for wallet A is queued up <-walletAQueuedUp // Wallet B: Withdraw 2 go func() { sentinelB1, err := s.fm.Withdraw(s.ctx, walletAddrB, s.acctAddr, amtB1) results <- &withdrawResult{ ws: sentinelB1, err: err, } }() // Wallet B: Withdraw 3 sentinelB2, err := s.fm.Withdraw(s.ctx, walletAddrB, s.acctAddr, amtB2) results <- &withdrawResult{ ws: sentinelB2, err: err, } }() // Withdrawals are queued up <-queueReady // Should withdraw from wallet A first resA1 := <-results sentinelA1 := resA1.ws msg := s.mockApi.getSentMessage(sentinelA1) checkWithdrawMessageFields(t, msg, walletAddrA, s.acctAddr, amtA1) // Complete wallet A message s.mockApi.completeMsg(sentinelA1) resB1 := <-results resB2 := <-results require.NoError(t, resB1.err) require.NoError(t, resB2.err) sentinelB1 := resB1.ws sentinelB2 := resB2.ws // Should send different message for wallet B from wallet A require.NotEqual(t, sentinelA1, sentinelB1) // Should be single message combining amount 1 and 2 require.Equal(t, sentinelB1, sentinelB2) msg = s.mockApi.getSentMessage(sentinelB1) checkWithdrawMessageFields(t, msg, walletAddrB, s.acctAddr, types.BigAdd(amtB1, amtB2)) } // TestFundManagerRestart verifies that waiting for incomplete requests resumes // on restart func TestFundManagerRestart(t *testing.T) { //stm: @MARKET_RESERVE_FUNDS_001 s := setup(t) defer s.fm.Stop() acctAddr2 := tutils.NewActorAddr(t, "addr2") // Address 1: Reserve 10 amt := abi.NewTokenAmount(10) sentinelAddr1, err := s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) msg := s.mockApi.getSentMessage(sentinelAddr1) checkAddMessageFields(t, msg, s.walletAddr, s.acctAddr, amt) // Address 2: Reserve 7 amt2 := abi.NewTokenAmount(7) sentinelAddr2Res7, err := s.fm.Reserve(s.ctx, s.walletAddr, acctAddr2, amt2) require.NoError(t, err) msg2 := s.mockApi.getSentMessage(sentinelAddr2Res7) checkAddMessageFields(t, msg2, s.walletAddr, acctAddr2, amt2) // Complete "Address 1: Reserve 10" s.mockApi.completeMsg(sentinelAddr1) // Give the completed state a moment to be stored before restart time.Sleep(time.Millisecond * 10) // Restart mockApiAfter := s.mockApi fmAfter := newFundManager(mockApiAfter, s.ds) err = fmAfter.Start() require.NoError(t, err) amt3 := abi.NewTokenAmount(9) reserveSentinel := make(chan cid.Cid) go func() { // Address 2: Reserve 9 sentinel3, err := fmAfter.Reserve(s.ctx, s.walletAddr, acctAddr2, amt3) require.NoError(t, err) reserveSentinel <- sentinel3 }() // Expect no message to be sent, because still waiting for previous // message "Address 2: Reserve 7" to complete on-chain select { case <-reserveSentinel: require.Fail(t, "Expected no message to be sent") case <-time.After(10 * time.Millisecond): } // Complete "Address 2: Reserve 7" mockApiAfter.completeMsg(sentinelAddr2Res7) // Expect waiting message to now be sent sentinel3 := <-reserveSentinel msg3 := mockApiAfter.getSentMessage(sentinel3) checkAddMessageFields(t, msg3, s.walletAddr, acctAddr2, amt3) } // TestFundManagerReleaseAfterPublish verifies that release is successful in // the following scenario: // 1. Deal A adds 5 to addr1: reserved 0 -> 5 available 0 -> 5 // 2. Deal B adds 7 to addr1: reserved 5 -> 12 available 5 -> 12 // 3. Deal B completes, reducing addr1 by 7: reserved 12 available 12 -> 5 // 4. Deal A releases 5 from addr1: reserved 12 -> 7 available 5 func TestFundManagerReleaseAfterPublish(t *testing.T) { //stm: @MARKET_RESERVE_FUNDS_001, @MARKET_RELEASE_FUNDS_001 s := setup(t) defer s.fm.Stop() // Deal A: Reserve 5 // balance: 0 -> 5 // reserved: 0 -> 5 amt := abi.NewTokenAmount(5) sentinel, err := s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) s.mockApi.completeMsg(sentinel) // Deal B: Reserve 7 // balance: 5 -> 12 // reserved: 5 -> 12 amt = abi.NewTokenAmount(7) sentinel, err = s.fm.Reserve(s.ctx, s.walletAddr, s.acctAddr, amt) require.NoError(t, err) s.mockApi.completeMsg(sentinel) // Deal B: Publish (removes Deal B amount from balance) // balance: 12 -> 5 // reserved: 12 amt = abi.NewTokenAmount(7) s.mockApi.publish(s.acctAddr, amt) // Deal A: Release 5 // balance: 5 // reserved: 12 -> 7 amt = abi.NewTokenAmount(5) err = s.fm.Release(s.acctAddr, amt) require.NoError(t, err) // Deal B: Release 7 // balance: 5 // reserved: 12 -> 7 amt = abi.NewTokenAmount(5) err = s.fm.Release(s.acctAddr, amt) require.NoError(t, err) } type scaffold struct { ctx context.Context ds *ds_sync.MutexDatastore wllt *wallet.LocalWallet walletAddr address.Address acctAddr address.Address mockApi *mockFundManagerAPI fm *FundManager } func setup(t *testing.T) *scaffold { ctx := context.Background() wllt, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } walletAddr, err := wllt.WalletNew(context.Background(), types.KTSecp256k1) if err != nil { t.Fatal(err) } acctAddr := tutils.NewActorAddr(t, "addr") mockApi := newMockFundManagerAPI(walletAddr) dstore := ds_sync.MutexWrap(ds.NewMapDatastore()) fm := newFundManager(mockApi, dstore) return &scaffold{ ctx: ctx, ds: dstore, wllt: wllt, walletAddr: walletAddr, acctAddr: acctAddr, mockApi: mockApi, fm: fm, } } func checkAddMessageFields(t *testing.T, msg *types.Message, from address.Address, to address.Address, amt abi.TokenAmount) { require.Equal(t, from, msg.From) require.Equal(t, market.Address, msg.To) require.Equal(t, amt, msg.Value) var paramsTo address.Address err := paramsTo.UnmarshalCBOR(bytes.NewReader(msg.Params)) require.NoError(t, err) require.Equal(t, to, paramsTo) } func checkWithdrawMessageFields(t *testing.T, msg *types.Message, from address.Address, addr address.Address, amt abi.TokenAmount) { require.Equal(t, from, msg.From) require.Equal(t, market.Address, msg.To) require.Equal(t, abi.NewTokenAmount(0), msg.Value) var params markettypes.WithdrawBalanceParams err := params.UnmarshalCBOR(bytes.NewReader(msg.Params)) require.NoError(t, err) require.Equal(t, addr, params.ProviderOrClientAddress) require.Equal(t, amt, params.Amount) } type sentMsg struct { msg *types.SignedMessage ready chan struct{} } type mockFundManagerAPI struct { wallet address.Address lk sync.Mutex escrow map[address.Address]abi.TokenAmount sentMsgs map[cid.Cid]*sentMsg completedMsgs map[cid.Cid]struct{} waitingFor map[cid.Cid]chan struct{} } func newMockFundManagerAPI(wallet address.Address) *mockFundManagerAPI { return &mockFundManagerAPI{ wallet: wallet, escrow: make(map[address.Address]abi.TokenAmount), sentMsgs: make(map[cid.Cid]*sentMsg), completedMsgs: make(map[cid.Cid]struct{}), waitingFor: make(map[cid.Cid]chan struct{}), } } func (mapi *mockFundManagerAPI) MpoolPushMessage(ctx context.Context, message *types.Message, spec *api.MessageSendSpec) (*types.SignedMessage, error) { mapi.lk.Lock() defer mapi.lk.Unlock() smsg := &types.SignedMessage{Message: *message} mapi.sentMsgs[smsg.Cid()] = &sentMsg{msg: smsg, ready: make(chan struct{})} return smsg, nil } func (mapi *mockFundManagerAPI) getSentMessage(c cid.Cid) *types.Message { mapi.lk.Lock() defer mapi.lk.Unlock() for i := 0; i < 1000; i++ { if pending, ok := mapi.sentMsgs[c]; ok { return &pending.msg.Message } time.Sleep(time.Millisecond) } panic("expected message to be sent") } func (mapi *mockFundManagerAPI) messageCount() int { mapi.lk.Lock() defer mapi.lk.Unlock() return len(mapi.sentMsgs) } func (mapi *mockFundManagerAPI) completeMsg(msgCid cid.Cid) { mapi.lk.Lock() pmsg, ok := mapi.sentMsgs[msgCid] if ok { if pmsg.msg.Message.Method == market.Methods.AddBalance { var escrowAcct address.Address err := escrowAcct.UnmarshalCBOR(bytes.NewReader(pmsg.msg.Message.Params)) if err != nil { panic(err) } escrow := mapi.getEscrow(escrowAcct) before := escrow escrow = types.BigAdd(escrow, pmsg.msg.Message.Value) mapi.escrow[escrowAcct] = escrow log.Debugf("%s: escrow %d -> %d", escrowAcct, before, escrow) } else { var params markettypes.WithdrawBalanceParams err := params.UnmarshalCBOR(bytes.NewReader(pmsg.msg.Message.Params)) if err != nil { panic(err) } escrowAcct := params.ProviderOrClientAddress escrow := mapi.getEscrow(escrowAcct) before := escrow escrow = types.BigSub(escrow, params.Amount) mapi.escrow[escrowAcct] = escrow log.Debugf("%s: escrow %d -> %d", escrowAcct, before, escrow) } } mapi.completedMsgs[msgCid] = struct{}{} ready, ok := mapi.waitingFor[msgCid] mapi.lk.Unlock() if ok { close(ready) } } func (mapi *mockFundManagerAPI) StateMarketBalance(ctx context.Context, a address.Address, key types.TipSetKey) (api.MarketBalance, error) { mapi.lk.Lock() defer mapi.lk.Unlock() return api.MarketBalance{ Locked: abi.NewTokenAmount(0), Escrow: mapi.getEscrow(a), }, nil } func (mapi *mockFundManagerAPI) getEscrow(a address.Address) abi.TokenAmount { escrow := mapi.escrow[a] if escrow.Nil() { return abi.NewTokenAmount(0) } return escrow } func (mapi *mockFundManagerAPI) publish(addr address.Address, amt abi.TokenAmount) { mapi.lk.Lock() defer mapi.lk.Unlock() escrow := mapi.escrow[addr] if escrow.Nil() { return } escrow = types.BigSub(escrow, amt) if escrow.LessThan(abi.NewTokenAmount(0)) { escrow = abi.NewTokenAmount(0) } mapi.escrow[addr] = escrow } func (mapi *mockFundManagerAPI) StateWaitMsg(ctx context.Context, c cid.Cid, confidence uint64, limit abi.ChainEpoch, allowReplaced bool) (*api.MsgLookup, error) { res := &api.MsgLookup{ Message: c, Receipt: types.MessageReceipt{ ExitCode: 0, Return: nil, }, } ready := make(chan struct{}) mapi.lk.Lock() _, ok := mapi.completedMsgs[c] if !ok { mapi.waitingFor[c] = ready } mapi.lk.Unlock() if !ok { select { case <-ctx.Done(): case <-ready: } } return res, nil }