// Copyright 2016 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . // This file contains some shares testing functionality, common to multiple // different files and modules being tested. package les import ( "context" "crypto/rand" "math/big" "testing" "time" "github.com/ethereum/go-ethereum/accounts/abi/bind" "github.com/ethereum/go-ethereum/accounts/abi/bind/backends" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/common/mclock" "github.com/ethereum/go-ethereum/consensus/ethash" "github.com/ethereum/go-ethereum/contracts/checkpointoracle/contract" "github.com/ethereum/go-ethereum/core" "github.com/ethereum/go-ethereum/core/rawdb" "github.com/ethereum/go-ethereum/core/types" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/eth" "github.com/ethereum/go-ethereum/ethdb" "github.com/ethereum/go-ethereum/event" "github.com/ethereum/go-ethereum/les/checkpointoracle" "github.com/ethereum/go-ethereum/les/flowcontrol" "github.com/ethereum/go-ethereum/light" "github.com/ethereum/go-ethereum/p2p" "github.com/ethereum/go-ethereum/p2p/enode" "github.com/ethereum/go-ethereum/params" ) var ( bankKey, _ = crypto.GenerateKey() bankAddr = crypto.PubkeyToAddress(bankKey.PublicKey) bankFunds = big.NewInt(1000000000000000000) userKey1, _ = crypto.GenerateKey() userKey2, _ = crypto.GenerateKey() userAddr1 = crypto.PubkeyToAddress(userKey1.PublicKey) userAddr2 = crypto.PubkeyToAddress(userKey2.PublicKey) testContractAddr common.Address testContractCode = common.Hex2Bytes("606060405260cc8060106000396000f360606040526000357c01000000000000000000000000000000000000000000000000000000009004806360cd2685146041578063c16431b914606b57603f565b005b6055600480803590602001909190505060a9565b6040518082815260200191505060405180910390f35b60886004808035906020019091908035906020019091905050608a565b005b80600060005083606481101560025790900160005b50819055505b5050565b6000600060005082606481101560025790900160005b5054905060c7565b91905056") testContractCodeDeployed = testContractCode[16:] testContractDeployed = uint64(2) testEventEmitterCode = common.Hex2Bytes("60606040523415600e57600080fd5b7f57050ab73f6b9ebdd9f76b8d4997793f48cf956e965ee070551b9ca0bb71584e60405160405180910390a160358060476000396000f3006060604052600080fd00a165627a7a723058203f727efcad8b5811f8cb1fc2620ce5e8c63570d697aef968172de296ea3994140029") // Checkpoint registrar relative registrarAddr common.Address signerKey, _ = crypto.GenerateKey() signerAddr = crypto.PubkeyToAddress(signerKey.PublicKey) ) var ( // The block frequency for creating checkpoint(only used in test) sectionSize = big.NewInt(128) // The number of confirmations needed to generate a checkpoint(only used in test). processConfirms = big.NewInt(1) // The token bucket buffer limit for testing purpose. testBufLimit = uint64(1000000) // The buffer recharging speed for testing purpose. testBufRecharge = uint64(1000) ) /* contract test { uint256[100] data; function Put(uint256 addr, uint256 value) { data[addr] = value; } function Get(uint256 addr) constant returns (uint256 value) { return data[addr]; } } */ // prepare pre-commits specified number customized blocks into chain. func prepare(n int, backend *backends.SimulatedBackend) { var ( ctx = context.Background() signer = types.HomesteadSigner{} ) for i := 0; i < n; i++ { switch i { case 0: // deploy checkpoint contract registrarAddr, _, _, _ = contract.DeployCheckpointOracle(bind.NewKeyedTransactor(bankKey), backend, []common.Address{signerAddr}, sectionSize, processConfirms, big.NewInt(1)) // bankUser transfers some ether to user1 nonce, _ := backend.PendingNonceAt(ctx, bankAddr) tx, _ := types.SignTx(types.NewTransaction(nonce, userAddr1, big.NewInt(10000), params.TxGas, nil, nil), signer, bankKey) backend.SendTransaction(ctx, tx) case 1: bankNonce, _ := backend.PendingNonceAt(ctx, bankAddr) userNonce1, _ := backend.PendingNonceAt(ctx, userAddr1) // bankUser transfers more ether to user1 tx1, _ := types.SignTx(types.NewTransaction(bankNonce, userAddr1, big.NewInt(1000), params.TxGas, nil, nil), signer, bankKey) backend.SendTransaction(ctx, tx1) // user1 relays ether to user2 tx2, _ := types.SignTx(types.NewTransaction(userNonce1, userAddr2, big.NewInt(1000), params.TxGas, nil, nil), signer, userKey1) backend.SendTransaction(ctx, tx2) // user1 deploys a test contract tx3, _ := types.SignTx(types.NewContractCreation(userNonce1+1, big.NewInt(0), 200000, big.NewInt(0), testContractCode), signer, userKey1) backend.SendTransaction(ctx, tx3) testContractAddr = crypto.CreateAddress(userAddr1, userNonce1+1) // user1 deploys a event contract tx4, _ := types.SignTx(types.NewContractCreation(userNonce1+2, big.NewInt(0), 200000, big.NewInt(0), testEventEmitterCode), signer, userKey1) backend.SendTransaction(ctx, tx4) case 2: // bankUser transfer some ether to signer bankNonce, _ := backend.PendingNonceAt(ctx, bankAddr) tx1, _ := types.SignTx(types.NewTransaction(bankNonce, signerAddr, big.NewInt(1000000000), params.TxGas, nil, nil), signer, bankKey) backend.SendTransaction(ctx, tx1) // invoke test contract data := common.Hex2Bytes("C16431B900000000000000000000000000000000000000000000000000000000000000010000000000000000000000000000000000000000000000000000000000000001") tx2, _ := types.SignTx(types.NewTransaction(bankNonce+1, testContractAddr, big.NewInt(0), 100000, nil, data), signer, bankKey) backend.SendTransaction(ctx, tx2) case 3: // invoke test contract bankNonce, _ := backend.PendingNonceAt(ctx, bankAddr) data := common.Hex2Bytes("C16431B900000000000000000000000000000000000000000000000000000000000000020000000000000000000000000000000000000000000000000000000000000002") tx, _ := types.SignTx(types.NewTransaction(bankNonce, testContractAddr, big.NewInt(0), 100000, nil, data), signer, bankKey) backend.SendTransaction(ctx, tx) } backend.Commit() } } // testIndexers creates a set of indexers with specified params for testing purpose. func testIndexers(db ethdb.Database, odr light.OdrBackend, config *light.IndexerConfig) []*core.ChainIndexer { var indexers [3]*core.ChainIndexer indexers[0] = light.NewChtIndexer(db, odr, config.ChtSize, config.ChtConfirms) indexers[1] = eth.NewBloomIndexer(db, config.BloomSize, config.BloomConfirms) indexers[2] = light.NewBloomTrieIndexer(db, odr, config.BloomSize, config.BloomTrieSize) // make bloomTrieIndexer as a child indexer of bloom indexer. indexers[1].AddChildIndexer(indexers[2]) return indexers[:] } func newTestClientHandler(backend *backends.SimulatedBackend, odr *LesOdr, indexers []*core.ChainIndexer, db ethdb.Database, peers *serverPeerSet, ulcServers []string, ulcFraction int) *clientHandler { var ( evmux = new(event.TypeMux) engine = ethash.NewFaker() gspec = core.Genesis{ Config: params.AllEthashProtocolChanges, Alloc: core.GenesisAlloc{bankAddr: {Balance: bankFunds}}, GasLimit: 100000000, } oracle *checkpointoracle.CheckpointOracle ) genesis := gspec.MustCommit(db) chain, _ := light.NewLightChain(odr, gspec.Config, engine, nil) if indexers != nil { checkpointConfig := ¶ms.CheckpointOracleConfig{ Address: crypto.CreateAddress(bankAddr, 0), Signers: []common.Address{signerAddr}, Threshold: 1, } getLocal := func(index uint64) params.TrustedCheckpoint { chtIndexer := indexers[0] sectionHead := chtIndexer.SectionHead(index) return params.TrustedCheckpoint{ SectionIndex: index, SectionHead: sectionHead, CHTRoot: light.GetChtRoot(db, index, sectionHead), BloomRoot: light.GetBloomTrieRoot(db, index, sectionHead), } } oracle = checkpointoracle.New(checkpointConfig, getLocal) } client := &LightEthereum{ lesCommons: lesCommons{ genesis: genesis.Hash(), config: ð.Config{LightPeers: 100, NetworkId: NetworkId}, chainConfig: params.AllEthashProtocolChanges, iConfig: light.TestClientIndexerConfig, chainDb: db, oracle: oracle, chainReader: chain, closeCh: make(chan struct{}), }, peers: peers, reqDist: odr.retriever.dist, retriever: odr.retriever, odr: odr, engine: engine, blockchain: chain, eventMux: evmux, } client.handler = newClientHandler(ulcServers, ulcFraction, nil, client) if client.oracle != nil { client.oracle.Start(backend) } return client.handler } func newTestServerHandler(blocks int, indexers []*core.ChainIndexer, db ethdb.Database, peers *clientPeerSet, clock mclock.Clock) (*serverHandler, *backends.SimulatedBackend) { var ( gspec = core.Genesis{ Config: params.AllEthashProtocolChanges, Alloc: core.GenesisAlloc{bankAddr: {Balance: bankFunds}}, GasLimit: 100000000, } oracle *checkpointoracle.CheckpointOracle ) genesis := gspec.MustCommit(db) // create a simulation backend and pre-commit several customized block to the database. simulation := backends.NewSimulatedBackendWithDatabase(db, gspec.Alloc, 100000000) prepare(blocks, simulation) txpoolConfig := core.DefaultTxPoolConfig txpoolConfig.Journal = "" txpool := core.NewTxPool(txpoolConfig, gspec.Config, simulation.Blockchain()) if indexers != nil { checkpointConfig := ¶ms.CheckpointOracleConfig{ Address: crypto.CreateAddress(bankAddr, 0), Signers: []common.Address{signerAddr}, Threshold: 1, } getLocal := func(index uint64) params.TrustedCheckpoint { chtIndexer := indexers[0] sectionHead := chtIndexer.SectionHead(index) return params.TrustedCheckpoint{ SectionIndex: index, SectionHead: sectionHead, CHTRoot: light.GetChtRoot(db, index, sectionHead), BloomRoot: light.GetBloomTrieRoot(db, index, sectionHead), } } oracle = checkpointoracle.New(checkpointConfig, getLocal) } server := &LesServer{ lesCommons: lesCommons{ genesis: genesis.Hash(), config: ð.Config{LightPeers: 100, NetworkId: NetworkId}, chainConfig: params.AllEthashProtocolChanges, iConfig: light.TestServerIndexerConfig, chainDb: db, chainReader: simulation.Blockchain(), oracle: oracle, closeCh: make(chan struct{}), }, peers: peers, servingQueue: newServingQueue(int64(time.Millisecond*10), 1), defParams: flowcontrol.ServerParams{ BufLimit: testBufLimit, MinRecharge: testBufRecharge, }, fcManager: flowcontrol.NewClientManager(nil, clock), } server.costTracker, server.freeCapacity = newCostTracker(db, server.config) server.costTracker.testCostList = testCostList(0) // Disable flow control mechanism. server.clientPool = newClientPool(db, 1, clock, nil) server.clientPool.setLimits(10000, 10000) // Assign enough capacity for clientpool server.handler = newServerHandler(server, simulation.Blockchain(), db, txpool, func() bool { return true }) if server.oracle != nil { server.oracle.Start(simulation) } server.servingQueue.setThreads(4) server.handler.start() return server.handler, simulation } // testPeer is a simulated peer to allow testing direct network calls. type testPeer struct { cpeer *clientPeer speer *serverPeer net p2p.MsgReadWriter // Network layer reader/writer to simulate remote messaging app *p2p.MsgPipeRW // Application layer reader/writer to simulate the local side } // newTestPeer creates a new peer registered at the given protocol manager. func newTestPeer(t *testing.T, name string, version int, handler *serverHandler, shake bool, testCost uint64) (*testPeer, <-chan error) { // Create a message pipe to communicate through app, net := p2p.MsgPipe() // Generate a random id and create the peer var id enode.ID rand.Read(id[:]) peer := newClientPeer(version, NetworkId, p2p.NewPeer(id, name, nil), net) // Start the peer on a new thread errCh := make(chan error, 1) go func() { select { case <-handler.closeCh: errCh <- p2p.DiscQuitting case errCh <- handler.handle(peer): } }() tp := &testPeer{ app: app, net: net, cpeer: peer, } // Execute any implicitly requested handshakes and return if shake { // Customize the cost table if required. if testCost != 0 { handler.server.costTracker.testCostList = testCostList(testCost) } var ( genesis = handler.blockchain.Genesis() head = handler.blockchain.CurrentHeader() td = handler.blockchain.GetTd(head.Hash(), head.Number.Uint64()) ) tp.handshake(t, td, head.Hash(), head.Number.Uint64(), genesis.Hash(), testCostList(testCost)) } return tp, errCh } // close terminates the local side of the peer, notifying the remote protocol // manager of termination. func (p *testPeer) close() { p.app.Close() } func newTestPeerPair(name string, version int, server *serverHandler, client *clientHandler) (*testPeer, <-chan error, *testPeer, <-chan error) { // Create a message pipe to communicate through app, net := p2p.MsgPipe() // Generate a random id and create the peer var id enode.ID rand.Read(id[:]) peer1 := newClientPeer(version, NetworkId, p2p.NewPeer(id, name, nil), net) peer2 := newServerPeer(version, NetworkId, false, p2p.NewPeer(id, name, nil), app) // Start the peer on a new thread errc1 := make(chan error, 1) errc2 := make(chan error, 1) go func() { select { case <-server.closeCh: errc1 <- p2p.DiscQuitting case errc1 <- server.handle(peer1): } }() go func() { select { case <-client.closeCh: errc1 <- p2p.DiscQuitting case errc1 <- client.handle(peer2): } }() return &testPeer{cpeer: peer1, net: net, app: app}, errc1, &testPeer{speer: peer2, net: app, app: net}, errc2 } // handshake simulates a trivial handshake that expects the same state from the // remote side as we are simulating locally. func (p *testPeer) handshake(t *testing.T, td *big.Int, head common.Hash, headNum uint64, genesis common.Hash, costList RequestCostList) { var expList keyValueList expList = expList.add("protocolVersion", uint64(p.cpeer.version)) expList = expList.add("networkId", uint64(NetworkId)) expList = expList.add("headTd", td) expList = expList.add("headHash", head) expList = expList.add("headNum", headNum) expList = expList.add("genesisHash", genesis) sendList := make(keyValueList, len(expList)) copy(sendList, expList) expList = expList.add("serveHeaders", nil) expList = expList.add("serveChainSince", uint64(0)) expList = expList.add("serveStateSince", uint64(0)) expList = expList.add("serveRecentState", uint64(core.TriesInMemory-4)) expList = expList.add("txRelay", nil) expList = expList.add("flowControl/BL", testBufLimit) expList = expList.add("flowControl/MRR", testBufRecharge) expList = expList.add("flowControl/MRC", costList) if err := p2p.ExpectMsg(p.app, StatusMsg, expList); err != nil { t.Fatalf("status recv: %v", err) } if err := p2p.Send(p.app, StatusMsg, sendList); err != nil { t.Fatalf("status send: %v", err) } p.cpeer.fcParams = flowcontrol.ServerParams{ BufLimit: testBufLimit, MinRecharge: testBufRecharge, } } type indexerCallback func(*core.ChainIndexer, *core.ChainIndexer, *core.ChainIndexer) // testClient represents a client for testing with necessary auxiliary fields. type testClient struct { clock mclock.Clock db ethdb.Database peer *testPeer handler *clientHandler chtIndexer *core.ChainIndexer bloomIndexer *core.ChainIndexer bloomTrieIndexer *core.ChainIndexer } // testServer represents a server for testing with necessary auxiliary fields. type testServer struct { clock mclock.Clock backend *backends.SimulatedBackend db ethdb.Database peer *testPeer handler *serverHandler chtIndexer *core.ChainIndexer bloomIndexer *core.ChainIndexer bloomTrieIndexer *core.ChainIndexer } func newServerEnv(t *testing.T, blocks int, protocol int, callback indexerCallback, simClock bool, newPeer bool, testCost uint64) (*testServer, func()) { db := rawdb.NewMemoryDatabase() indexers := testIndexers(db, nil, light.TestServerIndexerConfig) var clock mclock.Clock = &mclock.System{} if simClock { clock = &mclock.Simulated{} } handler, b := newTestServerHandler(blocks, indexers, db, newClientPeerSet(), clock) var peer *testPeer if newPeer { peer, _ = newTestPeer(t, "peer", protocol, handler, true, testCost) } cIndexer, bIndexer, btIndexer := indexers[0], indexers[1], indexers[2] cIndexer.Start(handler.blockchain) bIndexer.Start(handler.blockchain) // Wait until indexers generate enough index data. if callback != nil { callback(cIndexer, bIndexer, btIndexer) } server := &testServer{ clock: clock, backend: b, db: db, peer: peer, handler: handler, chtIndexer: cIndexer, bloomIndexer: bIndexer, bloomTrieIndexer: btIndexer, } teardown := func() { if newPeer { peer.close() peer.cpeer.close() b.Close() } cIndexer.Close() bIndexer.Close() } return server, teardown } func newClientServerEnv(t *testing.T, blocks int, protocol int, callback indexerCallback, ulcServers []string, ulcFraction int, simClock bool, connect bool) (*testServer, *testClient, func()) { sdb, cdb := rawdb.NewMemoryDatabase(), rawdb.NewMemoryDatabase() speers, cpeers := newServerPeerSet(), newClientPeerSet() var clock mclock.Clock = &mclock.System{} if simClock { clock = &mclock.Simulated{} } dist := newRequestDistributor(speers, clock) rm := newRetrieveManager(speers, dist, nil) odr := NewLesOdr(cdb, light.TestClientIndexerConfig, rm) sindexers := testIndexers(sdb, nil, light.TestServerIndexerConfig) cIndexers := testIndexers(cdb, odr, light.TestClientIndexerConfig) scIndexer, sbIndexer, sbtIndexer := sindexers[0], sindexers[1], sindexers[2] ccIndexer, cbIndexer, cbtIndexer := cIndexers[0], cIndexers[1], cIndexers[2] odr.SetIndexers(ccIndexer, cbIndexer, cbtIndexer) server, b := newTestServerHandler(blocks, sindexers, sdb, cpeers, clock) client := newTestClientHandler(b, odr, cIndexers, cdb, speers, ulcServers, ulcFraction) scIndexer.Start(server.blockchain) sbIndexer.Start(server.blockchain) ccIndexer.Start(client.backend.blockchain) cbIndexer.Start(client.backend.blockchain) if callback != nil { callback(scIndexer, sbIndexer, sbtIndexer) } var ( speer, cpeer *testPeer err1, err2 <-chan error ) if connect { cpeer, err1, speer, err2 = newTestPeerPair("peer", protocol, server, client) select { case <-time.After(time.Millisecond * 300): case err := <-err1: t.Fatalf("peer 1 handshake error: %v", err) case err := <-err2: t.Fatalf("peer 2 handshake error: %v", err) } } s := &testServer{ clock: clock, backend: b, db: sdb, peer: cpeer, handler: server, chtIndexer: scIndexer, bloomIndexer: sbIndexer, bloomTrieIndexer: sbtIndexer, } c := &testClient{ clock: clock, db: cdb, peer: speer, handler: client, chtIndexer: ccIndexer, bloomIndexer: cbIndexer, bloomTrieIndexer: cbtIndexer, } teardown := func() { if connect { speer.close() cpeer.close() cpeer.cpeer.close() speer.speer.close() } ccIndexer.Close() cbIndexer.Close() scIndexer.Close() sbIndexer.Close() b.Close() } return s, c, teardown }