package messagepool import ( "context" "fmt" "math" "math/big" "math/rand" "testing" "github.com/filecoin-project/go-address" "github.com/filecoin-project/lotus/build" "github.com/filecoin-project/lotus/chain/messagepool/gasguess" "github.com/filecoin-project/lotus/chain/types" "github.com/filecoin-project/lotus/chain/types/mock" "github.com/filecoin-project/lotus/chain/wallet" "github.com/filecoin-project/specs-actors/actors/builtin" "github.com/filecoin-project/specs-actors/actors/crypto" "github.com/ipfs/go-cid" "github.com/ipfs/go-datastore" _ "github.com/filecoin-project/lotus/lib/sigs/bls" _ "github.com/filecoin-project/lotus/lib/sigs/secp" logging "github.com/ipfs/go-log" ) func init() { // bump this for the selection tests MaxActorPendingMessages = 1000000 } func makeTestMessage(w *wallet.Wallet, from, to address.Address, nonce uint64, gasLimit int64, gasPrice uint64) *types.SignedMessage { msg := &types.Message{ From: from, To: to, Method: 2, Value: types.FromFil(0), Nonce: nonce, GasLimit: gasLimit, GasFeeCap: types.NewInt(100 + gasPrice), GasPremium: types.NewInt(gasPrice), } sig, err := w.Sign(context.TODO(), from, msg.Cid().Bytes()) if err != nil { panic(err) } return &types.SignedMessage{ Message: *msg, Signature: *sig, } } func makeTestMpool() (*MessagePool, *testMpoolAPI) { tma := newTestMpoolAPI() ds := datastore.NewMapDatastore() mp, err := New(tma, ds, "test") if err != nil { panic(err) } return mp, tma } func TestMessageChains(t *testing.T) { mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] tma.setBalance(a1, 1) // in FIL // test chain aggregations // test1: 10 messages from a1 to a2, with increasing gasPerf; it should // make a single chain with 10 messages given enough balance mset := make(map[uint64]*types.SignedMessage) for i := 0; i < 10; i++ { m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(i+1)) mset[uint64(i)] = m } baseFee := types.NewInt(0) chains := mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 1 { t.Fatal("expected a single chain") } if len(chains[0].msgs) != 10 { t.Fatalf("expected 10 messages in the chain but got %d", len(chains[0].msgs)) } for i, m := range chains[0].msgs { if m.Message.Nonce != uint64(i) { t.Fatalf("expected nonce %d but got %d", i, m.Message.Nonce) } } // test2 : 10 messages from a1 to a2, with decreasing gasPerf; it should // make 10 chains with 1 message each mset = make(map[uint64]*types.SignedMessage) for i := 0; i < 10; i++ { m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(10-i)) mset[uint64(i)] = m } chains = mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 10 { t.Fatal("expected 10 chains") } for i, chain := range chains { if len(chain.msgs) != 1 { t.Fatalf("expected 1 message in chain %d but got %d", i, len(chain.msgs)) } } for i, chain := range chains { m := chain.msgs[0] if m.Message.Nonce != uint64(i) { t.Fatalf("expected nonce %d but got %d", i, m.Message.Nonce) } } // test3a: 10 messages from a1 to a2, with gasPerf increasing in groups of 3; it should // merge them in two chains, one with 9 messages and one with the last message mset = make(map[uint64]*types.SignedMessage) for i := 0; i < 10; i++ { m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(1+i%3)) mset[uint64(i)] = m } chains = mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 2 { t.Fatal("expected 1 chain") } if len(chains[0].msgs) != 9 { t.Fatalf("expected 9 messages in the chain but got %d", len(chains[0].msgs)) } if len(chains[1].msgs) != 1 { t.Fatalf("expected 1 messages in the chain but got %d", len(chains[1].msgs)) } nextNonce := 0 for _, chain := range chains { for _, m := range chain.msgs { if m.Message.Nonce != uint64(nextNonce) { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } } // test3b: 10 messages from a1 to a2, with gasPerf decreasing in groups of 3 with a bias for the // earlier chains; it should make 4 chains, the first 3 with 3 messages and the last with // a single message mset = make(map[uint64]*types.SignedMessage) for i := 0; i < 10; i++ { bias := (12 - i) / 3 m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(1+i%3+bias)) mset[uint64(i)] = m } chains = mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 4 { t.Fatal("expected 4 chains") } for i, chain := range chains { expectedLen := 3 if i > 2 { expectedLen = 1 } if len(chain.msgs) != expectedLen { t.Fatalf("expected %d message in chain %d but got %d", expectedLen, i, len(chain.msgs)) } } nextNonce = 0 for _, chain := range chains { for _, m := range chain.msgs { if m.Message.Nonce != uint64(nextNonce) { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } } // test chain breaks // test4: 10 messages with non-consecutive nonces; it should make a single chain with just // the first message mset = make(map[uint64]*types.SignedMessage) for i := 0; i < 10; i++ { m := makeTestMessage(w1, a1, a2, uint64(i*2), gasLimit, uint64(i+1)) mset[uint64(i)] = m } chains = mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 1 { t.Fatal("expected a single chain") } if len(chains[0].msgs) != 1 { t.Fatalf("expected 1 message in the chain but got %d", len(chains[0].msgs)) } for i, m := range chains[0].msgs { if m.Message.Nonce != uint64(i) { t.Fatalf("expected nonce %d but got %d", i, m.Message.Nonce) } } // test5: 10 messages with increasing gasLimit, except for the 6th message which has less than // the epoch gasLimit; it should create a single chain with the first 5 messages mset = make(map[uint64]*types.SignedMessage) for i := 0; i < 10; i++ { var m *types.SignedMessage if i != 5 { m = makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(i+1)) } else { m = makeTestMessage(w1, a1, a2, uint64(i), 1, uint64(i+1)) } mset[uint64(i)] = m } chains = mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 1 { t.Fatal("expected a single chain") } if len(chains[0].msgs) != 5 { t.Fatalf("expected 5 message in the chain but got %d", len(chains[0].msgs)) } for i, m := range chains[0].msgs { if m.Message.Nonce != uint64(i) { t.Fatalf("expected nonce %d but got %d", i, m.Message.Nonce) } } // test6: one more message than what can fit in a block according to gas limit, with increasing // gasPerf; it should create a single chain with the max messages maxMessages := int(build.BlockGasLimit / gasLimit) nMessages := maxMessages + 1 mset = make(map[uint64]*types.SignedMessage) for i := 0; i < nMessages; i++ { mset[uint64(i)] = makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(i+1)) } chains = mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 1 { t.Fatal("expected a single chain") } if len(chains[0].msgs) != maxMessages { t.Fatalf("expected %d message in the chain but got %d", maxMessages, len(chains[0].msgs)) } for i, m := range chains[0].msgs { if m.Message.Nonce != uint64(i) { t.Fatalf("expected nonce %d but got %d", i, m.Message.Nonce) } } // test5: insufficient balance for all messages tma.setBalanceRaw(a1, types.NewInt(uint64((300)*gasLimit+1))) mset = make(map[uint64]*types.SignedMessage) for i := 0; i < 10; i++ { mset[uint64(i)] = makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(i+1)) } chains = mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 1 { t.Fatalf("expected a single chain: got %d", len(chains)) } if len(chains[0].msgs) != 2 { t.Fatalf("expected %d message in the chain but got %d", 2, len(chains[0].msgs)) } for i, m := range chains[0].msgs { if m.Message.Nonce != uint64(i) { t.Fatalf("expected nonce %d but got %d", i, m.Message.Nonce) } } } func TestMessageChainSkipping(t *testing.T) { // regression test for chain skip bug mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] baseFee := types.NewInt(0) tma.setBalance(a1, 1) // in FIL tma.setStateNonce(a1, 10) mset := make(map[uint64]*types.SignedMessage) for i := 0; i < 20; i++ { bias := (20 - i) / 3 m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(1+i%3+bias)) mset[uint64(i)] = m } chains := mp.createMessageChains(a1, mset, baseFee, ts) if len(chains) != 4 { t.Fatalf("expected 4 chains, got %d", len(chains)) } for i, chain := range chains { var expectedLen int switch { case i == 0: expectedLen = 2 case i > 2: expectedLen = 2 default: expectedLen = 3 } if len(chain.msgs) != expectedLen { t.Fatalf("expected %d message in chain %d but got %d", expectedLen, i, len(chain.msgs)) } } nextNonce := 10 for _, chain := range chains { for _, m := range chain.msgs { if m.Message.Nonce != uint64(nextNonce) { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } } } func TestBasicMessageSelection(t *testing.T) { oldMaxNonceGap := MaxNonceGap MaxNonceGap = 1000 defer func() { MaxNonceGap = oldMaxNonceGap }() mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] tma.setBalance(a1, 1) // in FIL tma.setBalance(a2, 1) // in FIL // we create 10 messages from each actor to another, with the first actor paying higher // gas prices than the second; we expect message selection to order his messages first for i := 0; i < 10; i++ { m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(2*i+1)) mustAdd(t, mp, m) } for i := 0; i < 10; i++ { m := makeTestMessage(w2, a2, a1, uint64(i), gasLimit, uint64(i+1)) mustAdd(t, mp, m) } msgs, err := mp.SelectMessages(ts, 1.0) if err != nil { t.Fatal(err) } if len(msgs) != 20 { t.Fatalf("exptected 20 messages, got %d", len(msgs)) } nextNonce := 0 for i := 0; i < 10; i++ { if msgs[i].Message.From != a1 { t.Fatalf("expected message from actor a1") } if msgs[i].Message.Nonce != uint64(nextNonce) { t.Fatalf("expected nonce %d, got %d", msgs[i].Message.Nonce, nextNonce) } nextNonce++ } nextNonce = 0 for i := 10; i < 20; i++ { if msgs[i].Message.From != a2 { t.Fatalf("expected message from actor a2") } if msgs[i].Message.Nonce != uint64(nextNonce) { t.Fatalf("expected nonce %d, got %d", msgs[i].Message.Nonce, nextNonce) } nextNonce++ } // now we make a block with all the messages and advance the chain block2 := tma.nextBlock() tma.setBlockMessages(block2, msgs...) tma.applyBlock(t, block2) // we should have no pending messages in the mpool pend, _ := mp.Pending() if len(pend) != 0 { t.Fatalf("expected no pending messages, but got %d", len(pend)) } // create a block and advance the chain without applying to the mpool msgs = nil for i := 10; i < 20; i++ { m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(2*i+1)) msgs = append(msgs, m) m = makeTestMessage(w2, a2, a1, uint64(i), gasLimit, uint64(i+1)) msgs = append(msgs, m) } block3 := tma.nextBlock() tma.setBlockMessages(block3, msgs...) ts3 := mock.TipSet(block3) // now create another set of messages and add them to the mpool for i := 20; i < 30; i++ { m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(2*i+200)) mustAdd(t, mp, m) m = makeTestMessage(w2, a2, a1, uint64(i), gasLimit, uint64(i+1)) mustAdd(t, mp, m) } // select messages in the last tipset; this should include the missed messages as well as // the last messages we added, with the first actor's messages first // first we need to update the nonce on the tma tma.setStateNonce(a1, 10) tma.setStateNonce(a2, 10) msgs, err = mp.SelectMessages(ts3, 1.0) if err != nil { t.Fatal(err) } if len(msgs) != 20 { t.Fatalf("expected 20 messages, got %d", len(msgs)) } nextNonce = 20 for i := 0; i < 10; i++ { if msgs[i].Message.From != a1 { t.Fatalf("expected message from actor a1") } if msgs[i].Message.Nonce != uint64(nextNonce) { t.Fatalf("expected nonce %d, got %d", msgs[i].Message.Nonce, nextNonce) } nextNonce++ } nextNonce = 20 for i := 10; i < 20; i++ { if msgs[i].Message.From != a2 { t.Fatalf("expected message from actor a2") } if msgs[i].Message.Nonce != uint64(nextNonce) { t.Fatalf("expected nonce %d, got %d", msgs[i].Message.Nonce, nextNonce) } nextNonce++ } } func TestMessageSelectionTrimming(t *testing.T) { mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] tma.setBalance(a1, 1) // in FIL tma.setBalance(a2, 1) // in FIL // make many small chains for the two actors nMessages := int((build.BlockGasLimit / gasLimit) + 1) for i := 0; i < nMessages; i++ { bias := (nMessages - i) / 3 m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(1+i%3+bias)) mustAdd(t, mp, m) m = makeTestMessage(w2, a2, a1, uint64(i), gasLimit, uint64(1+i%3+bias)) mustAdd(t, mp, m) } msgs, err := mp.SelectMessages(ts, 1.0) if err != nil { t.Fatal(err) } expected := int(build.BlockGasLimit / gasLimit) if len(msgs) != expected { t.Fatalf("expected %d messages, bug got %d", expected, len(msgs)) } mGasLimit := int64(0) for _, m := range msgs { mGasLimit += m.Message.GasLimit } if mGasLimit > build.BlockGasLimit { t.Fatal("selected messages gas limit exceeds block gas limit!") } } func TestPriorityMessageSelection(t *testing.T) { mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] tma.setBalance(a1, 1) // in FIL tma.setBalance(a2, 1) // in FIL mp.cfg.PriorityAddrs = []address.Address{a1} nMessages := 10 for i := 0; i < nMessages; i++ { bias := (nMessages - i) / 3 m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(1+i%3+bias)) mustAdd(t, mp, m) m = makeTestMessage(w2, a2, a1, uint64(i), gasLimit, uint64(1+i%3+bias)) mustAdd(t, mp, m) } msgs, err := mp.SelectMessages(ts, 1.0) if err != nil { t.Fatal(err) } if len(msgs) != 20 { t.Fatalf("expected 20 messages but got %d", len(msgs)) } // messages from a1 must be first nextNonce := uint64(0) for i := 0; i < 10; i++ { m := msgs[i] if m.Message.From != a1 { t.Fatal("expected messages from a1 before messages from a2") } if m.Message.Nonce != nextNonce { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } nextNonce = 0 for i := 10; i < 20; i++ { m := msgs[i] if m.Message.From != a2 { t.Fatal("expected messages from a2 after messages from a1") } if m.Message.Nonce != nextNonce { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } } func TestPriorityMessageSelection2(t *testing.T) { mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] tma.setBalance(a1, 1) // in FIL tma.setBalance(a2, 1) // in FIL mp.cfg.PriorityAddrs = []address.Address{a1} nMessages := int(2 * build.BlockGasLimit / gasLimit) for i := 0; i < nMessages; i++ { bias := (nMessages - i) / 3 m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(1+i%3+bias)) mustAdd(t, mp, m) m = makeTestMessage(w2, a2, a1, uint64(i), gasLimit, uint64(1+i%3+bias)) mustAdd(t, mp, m) } msgs, err := mp.SelectMessages(ts, 1.0) if err != nil { t.Fatal(err) } expectedMsgs := int(build.BlockGasLimit / gasLimit) if len(msgs) != expectedMsgs { t.Fatalf("expected %d messages but got %d", expectedMsgs, len(msgs)) } // all messages must be from a1 nextNonce := uint64(0) for _, m := range msgs { if m.Message.From != a1 { t.Fatal("expected messages from a1 before messages from a2") } if m.Message.Nonce != nextNonce { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } } func TestPriorityMessageSelection3(t *testing.T) { mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] tma.setBalance(a1, 1) // in FIL tma.setBalance(a2, 1) // in FIL mp.cfg.PriorityAddrs = []address.Address{a1} tma.baseFee = types.NewInt(1000) nMessages := 10 for i := 0; i < nMessages; i++ { bias := (nMessages - i) / 3 m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(1000+i%3+bias)) mustAdd(t, mp, m) // messages from a2 have negative performance m = makeTestMessage(w2, a2, a1, uint64(i), gasLimit, 100) mustAdd(t, mp, m) } // test greedy selection msgs, err := mp.SelectMessages(ts, 1.0) if err != nil { t.Fatal(err) } expectedMsgs := 10 if len(msgs) != expectedMsgs { t.Fatalf("expected %d messages but got %d", expectedMsgs, len(msgs)) } // all messages must be from a1 nextNonce := uint64(0) for _, m := range msgs { if m.Message.From != a1 { t.Fatal("expected messages from a1 before messages from a2") } if m.Message.Nonce != nextNonce { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } // test optimal selection msgs, err = mp.SelectMessages(ts, 0.1) if err != nil { t.Fatal(err) } expectedMsgs = 10 if len(msgs) != expectedMsgs { t.Fatalf("expected %d messages but got %d", expectedMsgs, len(msgs)) } // all messages must be from a1 nextNonce = uint64(0) for _, m := range msgs { if m.Message.From != a1 { t.Fatal("expected messages from a1 before messages from a2") } if m.Message.Nonce != nextNonce { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } } func TestOptimalMessageSelection1(t *testing.T) { // this test uses just a single actor sending messages with a low tq // the chain depenent merging algorithm should pick messages from the actor // from the start mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] tma.setBalance(a1, 1) // in FIL tma.setBalance(a2, 1) // in FIL nMessages := int(10 * build.BlockGasLimit / gasLimit) for i := 0; i < nMessages; i++ { bias := (nMessages - i) / 3 m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(1+i%3+bias)) mustAdd(t, mp, m) } msgs, err := mp.SelectMessages(ts, 0.25) if err != nil { t.Fatal(err) } expectedMsgs := int(build.BlockGasLimit / gasLimit) if len(msgs) != expectedMsgs { t.Fatalf("expected %d messages, but got %d", expectedMsgs, len(msgs)) } nextNonce := uint64(0) for _, m := range msgs { if m.Message.From != a1 { t.Fatal("expected message from a1") } if m.Message.Nonce != nextNonce { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nextNonce++ } } func TestOptimalMessageSelection2(t *testing.T) { // this test uses two actors sending messages to each other, with the first // actor paying (much) higher gas premium than the second. // We select with a low ticket quality; the chain depenent merging algorithm should pick // messages from the second actor from the start mp, tma := makeTestMpool() // the actors w1, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a1, err := w1.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } w2, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a2, err := w2.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] tma.setBalance(a1, 1) // in FIL tma.setBalance(a2, 1) // in FIL nMessages := int(5 * build.BlockGasLimit / gasLimit) for i := 0; i < nMessages; i++ { bias := (nMessages - i) / 3 m := makeTestMessage(w1, a1, a2, uint64(i), gasLimit, uint64(200000+i%3+bias)) mustAdd(t, mp, m) m = makeTestMessage(w2, a2, a1, uint64(i), gasLimit, uint64(190000+i%3+bias)) mustAdd(t, mp, m) } msgs, err := mp.SelectMessages(ts, 0.1) if err != nil { t.Fatal(err) } expectedMsgs := int(build.BlockGasLimit / gasLimit) if len(msgs) != expectedMsgs { t.Fatalf("expected %d messages, but got %d", expectedMsgs, len(msgs)) } var nFrom1, nFrom2 int var nextNonce1, nextNonce2 uint64 for _, m := range msgs { if m.Message.From == a1 { if m.Message.Nonce != nextNonce1 { t.Fatalf("expected nonce %d but got %d", nextNonce1, m.Message.Nonce) } nextNonce1++ nFrom1++ } else { if m.Message.Nonce != nextNonce2 { t.Fatalf("expected nonce %d but got %d", nextNonce2, m.Message.Nonce) } nextNonce2++ nFrom2++ } } if nFrom1 > nFrom2 { t.Fatalf("expected more messages from a2 than a1; nFrom1=%d nFrom2=%d", nFrom1, nFrom2) } } func TestOptimalMessageSelection3(t *testing.T) { // this test uses 10 actors sending a block of messages to each other, with the the first // actors paying higher gas premium than the subsequent actors. // We select with a low ticket quality; the chain depenent merging algorithm should pick // messages from the median actor from the start mp, tma := makeTestMpool() nActors := 10 // the actors var actors []address.Address var wallets []*wallet.Wallet for i := 0; i < nActors; i++ { w, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a, err := w.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } actors = append(actors, a) wallets = append(wallets, w) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] for _, a := range actors { tma.setBalance(a, 1) // in FIL } nMessages := int(build.BlockGasLimit/gasLimit) + 1 for i := 0; i < nMessages; i++ { for j := 0; j < nActors; j++ { premium := 500000 + 10000*(nActors-j) + (nMessages+2-i)/(30*nActors) + i%3 m := makeTestMessage(wallets[j], actors[j], actors[j%nActors], uint64(i), gasLimit, uint64(premium)) mustAdd(t, mp, m) } } msgs, err := mp.SelectMessages(ts, 0.1) if err != nil { t.Fatal(err) } expectedMsgs := int(build.BlockGasLimit / gasLimit) if len(msgs) != expectedMsgs { t.Fatalf("expected %d messages, but got %d", expectedMsgs, len(msgs)) } whoIs := func(a address.Address) int { for i, aa := range actors { if a == aa { return i } } return -1 } nonces := make([]uint64, nActors) for _, m := range msgs { who := whoIs(m.Message.From) if who < 3 { t.Fatalf("got message from %dth actor", who) } nextNonce := nonces[who] if m.Message.Nonce != nextNonce { t.Fatalf("expected nonce %d but got %d", nextNonce, m.Message.Nonce) } nonces[who]++ } } func testCompetitiveMessageSelection(t *testing.T, rng *rand.Rand, getPremium func() uint64) (float64, float64, float64) { // in this test we use 300 actors and send 10 blocks of messages. // actors send with an randomly distributed premium dictated by the getPremium function. // a number of miners select with varying ticket quality and we compare the // capacity and rewards of greedy selection -vs- optimal selection mp, tma := makeTestMpool() nActors := 300 // the actors var actors []address.Address var wallets []*wallet.Wallet for i := 0; i < nActors; i++ { w, err := wallet.NewWallet(wallet.NewMemKeyStore()) if err != nil { t.Fatal(err) } a, err := w.GenerateKey(crypto.SigTypeSecp256k1) if err != nil { t.Fatal(err) } actors = append(actors, a) wallets = append(wallets, w) } block := tma.nextBlock() ts := mock.TipSet(block) tma.applyBlock(t, block) gasLimit := gasguess.Costs[gasguess.CostKey{Code: builtin.StorageMarketActorCodeID, M: 2}] baseFee := types.NewInt(0) for _, a := range actors { tma.setBalance(a, 1) // in FIL } nMessages := 10 * int(build.BlockGasLimit/gasLimit) t.Log("nMessages", nMessages) nonces := make([]uint64, nActors) for i := 0; i < nMessages; i++ { from := rng.Intn(nActors) to := rng.Intn(nActors) nonce := nonces[from] nonces[from]++ premium := getPremium() m := makeTestMessage(wallets[from], actors[from], actors[to], nonce, gasLimit, premium) mustAdd(t, mp, m) } logging.SetLogLevel("messagepool", "error") // 1. greedy selection greedyMsgs, err := mp.selectMessagesGreedy(ts, ts) if err != nil { t.Fatal(err) } totalGreedyCapacity := 0.0 totalGreedyReward := 0.0 totalOptimalCapacity := 0.0 totalOptimalReward := 0.0 totalBestTQReward := 0.0 const runs = 1 for i := 0; i < runs; i++ { // 2. optimal selection minersRand := rng.Float64() winerProba := noWinnersProb() i := 0 for ; i < MaxBlocks && minersRand > 0; i++ { minersRand -= winerProba[i] } nMiners := i - 1 if nMiners < 1 { nMiners = 1 } optMsgs := make(map[cid.Cid]*types.SignedMessage) bestTq := 0.0 var bestMsgs []*types.SignedMessage for j := 0; j < nMiners; j++ { tq := rng.Float64() msgs, err := mp.SelectMessages(ts, tq) if err != nil { t.Fatal(err) } if tq > bestTq { bestMsgs = msgs } for _, m := range msgs { optMsgs[m.Cid()] = m } } totalGreedyCapacity += float64(len(greedyMsgs)) totalOptimalCapacity += float64(len(optMsgs)) boost := float64(len(optMsgs)) / float64(len(greedyMsgs)) t.Logf("nMiners: %d", nMiners) t.Logf("greedy capacity %d, optimal capacity %d (x %.1f )", len(greedyMsgs), len(optMsgs), boost) if len(greedyMsgs) > len(optMsgs) { t.Errorf("greedy capacity higher than optimal capacity; wtf") } greedyReward := big.NewInt(0) for _, m := range greedyMsgs { greedyReward.Add(greedyReward, mp.getGasReward(m, baseFee)) } optReward := big.NewInt(0) for _, m := range optMsgs { optReward.Add(optReward, mp.getGasReward(m, baseFee)) } bestTqReward := big.NewInt(0) for _, m := range bestMsgs { bestTqReward.Add(bestTqReward, mp.getGasReward(m, baseFee)) } totalBestTQReward += float64(bestTqReward.Uint64()) nMinersBig := big.NewInt(int64(nMiners)) greedyAvgReward, _ := new(big.Rat).SetFrac(greedyReward, nMinersBig).Float64() totalGreedyReward += greedyAvgReward optimalAvgReward, _ := new(big.Rat).SetFrac(optReward, nMinersBig).Float64() totalOptimalReward += optimalAvgReward boost = optimalAvgReward / greedyAvgReward t.Logf("greedy reward: %.0f, optimal reward: %.0f (x %.1f )", greedyAvgReward, optimalAvgReward, boost) } capacityBoost := totalOptimalCapacity / totalGreedyCapacity rewardBoost := totalOptimalReward / totalGreedyReward t.Logf("Average capacity boost: %f", capacityBoost) t.Logf("Average reward boost: %f", rewardBoost) t.Logf("Average best tq reward: %f", totalBestTQReward/runs/1e12) logging.SetLogLevel("messagepool", "info") return capacityBoost, rewardBoost, totalBestTQReward / runs / 1e12 } func makeExpPremiumDistribution(rng *rand.Rand) func() uint64 { return func() uint64 { premium := 20000*math.Exp(-3.*rng.Float64()) + 5000 return uint64(premium) } } func makeZipfPremiumDistribution(rng *rand.Rand) func() uint64 { zipf := rand.NewZipf(rng, 1.001, 1, 40000) return func() uint64 { return zipf.Uint64() + 10000 } } func TestCompetitiveMessageSelectionExp(t *testing.T) { var capacityBoost, rewardBoost, tqReward float64 seeds := []int64{1947, 1976, 2020, 2100, 10000, 143324, 432432, 131, 32, 45} for _, seed := range seeds { t.Log("running competitive message selection with Exponential premium distribution and seed", seed) rng := rand.New(rand.NewSource(seed)) cb, rb, tqR := testCompetitiveMessageSelection(t, rng, makeExpPremiumDistribution(rng)) capacityBoost += cb rewardBoost += rb tqReward += tqR } capacityBoost /= float64(len(seeds)) rewardBoost /= float64(len(seeds)) tqReward /= float64(len(seeds)) t.Logf("Average capacity boost across all seeds: %f", capacityBoost) t.Logf("Average reward boost across all seeds: %f", rewardBoost) t.Logf("Average reward of best ticket across all seeds: %f", tqReward) } func TestCompetitiveMessageSelectionZipf(t *testing.T) { var capacityBoost, rewardBoost, tqReward float64 seeds := []int64{1947, 1976, 2020, 2100, 10000, 143324, 432432, 131, 32, 45} for _, seed := range seeds { t.Log("running competitive message selection with Zipf premium distribution and seed", seed) rng := rand.New(rand.NewSource(seed)) cb, rb, tqR := testCompetitiveMessageSelection(t, rng, makeZipfPremiumDistribution(rng)) capacityBoost += cb rewardBoost += rb tqReward += tqR } tqReward /= float64(len(seeds)) capacityBoost /= float64(len(seeds)) rewardBoost /= float64(len(seeds)) t.Logf("Average capacity boost across all seeds: %f", capacityBoost) t.Logf("Average reward boost across all seeds: %f", rewardBoost) t.Logf("Average reward of best ticket across all seeds: %f", tqReward) } func TestGasReward(t *testing.T) { tests := []struct { Premium uint64 FeeCap uint64 BaseFee uint64 GasReward int64 }{ {Premium: 100, FeeCap: 200, BaseFee: 100, GasReward: 100}, {Premium: 100, FeeCap: 200, BaseFee: 210, GasReward: -10}, {Premium: 200, FeeCap: 250, BaseFee: 210, GasReward: 40}, {Premium: 200, FeeCap: 250, BaseFee: 2000, GasReward: -1750}, } mp := new(MessagePool) for _, test := range tests { test := test t.Run(fmt.Sprintf("%v", test), func(t *testing.T) { msg := &types.SignedMessage{ Message: types.Message{ GasLimit: 10, GasFeeCap: types.NewInt(test.FeeCap), GasPremium: types.NewInt(test.Premium), }, } rew := mp.getGasReward(msg, types.NewInt(test.BaseFee)) if rew.Cmp(big.NewInt(test.GasReward*10)) != 0 { t.Errorf("bad reward: expected %d, got %s", test.GasReward*10, rew) } }) } }