bsc/les/test_helper.go
zjubfd 2ce00adb55
[R4R] performance improvement in many aspects (#257)
* focus on performance improvement in many aspects.

1. Do BlockBody verification concurrently;
2. Do calculation of intermediate root concurrently;
3. Preload accounts before processing blocks;
4. Make the snapshot layers configurable.
5. Reuse some object to reduce GC.

add

* rlp: improve decoder stream implementation (#22858)

This commit makes various cleanup changes to rlp.Stream.

* rlp: shrink Stream struct

This removes a lot of unused padding space in Stream by reordering the
fields. The size of Stream changes from 120 bytes to 88 bytes. Stream
instances are internally cached and reused using sync.Pool, so this does
not improve performance.

* rlp: simplify list stack

The list stack kept track of the size of the current list context as
well as the current offset into it. The size had to be stored in the
stack in order to subtract it from the remaining bytes of any enclosing
list in ListEnd. It seems that this can be implemented in a simpler
way: just subtract the size from the enclosing list context in List instead.

* rlp: use atomic.Value for type cache (#22902)

All encoding/decoding operations read the type cache to find the
writer/decoder function responsible for a type. When analyzing CPU
profiles of geth during sync, I found that the use of sync.RWMutex in
cache lookups appears in the profiles. It seems we are running into
CPU cache contention problems when package rlp is heavily used
on all CPU cores during sync.

This change makes it use atomic.Value + a writer lock instead of
sync.RWMutex. In the common case where the typeinfo entry is present in
the cache, we simply fetch the map and lookup the type.

* rlp: optimize byte array handling (#22924)

This change improves the performance of encoding/decoding [N]byte.

    name                     old time/op    new time/op    delta
    DecodeByteArrayStruct-8     336ns ± 0%     246ns ± 0%  -26.98%  (p=0.000 n=9+10)
    EncodeByteArrayStruct-8     225ns ± 1%     148ns ± 1%  -34.12%  (p=0.000 n=10+10)

    name                     old alloc/op   new alloc/op   delta
    DecodeByteArrayStruct-8      120B ± 0%       48B ± 0%  -60.00%  (p=0.000 n=10+10)
    EncodeByteArrayStruct-8     0.00B          0.00B          ~     (all equal)

* rlp: optimize big.Int decoding for size <= 32 bytes (#22927)

This change grows the static integer buffer in Stream to 32 bytes,
making it possible to decode 256bit integers without allocating a
temporary buffer.

In the recent commit 088da24, Stream struct size decreased from 120
bytes down to 88 bytes. This commit grows the struct to 112 bytes again,
but the size change will not degrade performance because Stream
instances are internally cached in sync.Pool.

    name             old time/op    new time/op    delta
    DecodeBigInts-8    12.2µs ± 0%     8.6µs ± 4%  -29.58%  (p=0.000 n=9+10)

    name             old speed      new speed      delta
    DecodeBigInts-8   230MB/s ± 0%   326MB/s ± 4%  +42.04%  (p=0.000 n=9+10)

* eth/protocols/eth, les: avoid Raw() when decoding HashOrNumber (#22841)

Getting the raw value is not necessary to decode this type, and
decoding it directly from the stream is faster.

* fix testcase

* debug no lazy

* fix can not repair

* address comments

Co-authored-by: Felix Lange <fjl@twurst.com>
2021-07-29 17:16:53 +08:00

679 lines
23 KiB
Go

// 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 <http://www.gnu.org/licenses/>.
// This file contains some shares testing functionality, common to multiple
// different files and modules being tested. Client based network and Server
// based network can be created easily with available APIs.
package les
import (
"context"
"crypto/rand"
"fmt"
"math/big"
"sync/atomic"
"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/forkid"
"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/ethconfig"
"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"
vfs "github.com/ethereum/go-ethereum/les/vflux/server"
"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 oracle relative fields
oracleAddr 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:
// Builtin-block
// number: 1
// txs: 2
// deploy checkpoint contract
auth, _ := bind.NewKeyedTransactorWithChainID(bankKey, big.NewInt(1337))
oracleAddr, _, _, _ = contract.DeployCheckpointOracle(auth, 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:
// Builtin-block
// number: 2
// txs: 4
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:
// Builtin-block
// number: 3
// txs: 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:
// Builtin-block
// number: 4
// txs: 1
// 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, disablePruning bool) []*core.ChainIndexer {
var indexers [3]*core.ChainIndexer
indexers[0] = light.NewChtIndexer(db, odr, config.ChtSize, config.ChtConfirms, disablePruning)
indexers[1] = core.NewBloomIndexer(db, config.BloomSize, config.BloomConfirms)
indexers[2] = light.NewBloomTrieIndexer(db, odr, config.BloomSize, config.BloomTrieSize, disablePruning)
// 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, func()) {
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 := &params.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: &ethconfig.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)
}
client.handler.start()
return client.handler, func() {
client.handler.stop()
}
}
func newTestServerHandler(blocks int, indexers []*core.ChainIndexer, db ethdb.Database, clock mclock.Clock) (*serverHandler, *backends.SimulatedBackend, func()) {
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 := &params.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: &ethconfig.Config{LightPeers: 100, NetworkId: NetworkId},
chainConfig: params.AllEthashProtocolChanges,
iConfig: light.TestServerIndexerConfig,
chainDb: db,
chainReader: simulation.Blockchain(),
oracle: oracle,
closeCh: make(chan struct{}),
},
peers: newClientPeerSet(),
servingQueue: newServingQueue(int64(time.Millisecond*10), 1),
defParams: flowcontrol.ServerParams{
BufLimit: testBufLimit,
MinRecharge: testBufRecharge,
},
fcManager: flowcontrol.NewClientManager(nil, clock),
}
server.costTracker, server.minCapacity = newCostTracker(db, server.config)
server.costTracker.testCostList = testCostList(0) // Disable flow control mechanism.
server.clientPool = vfs.NewClientPool(db, testBufRecharge, defaultConnectedBias, clock, alwaysTrueFn)
server.clientPool.Start()
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()
closer := func() { server.Stop() }
return server.handler, simulation, closer
}
func alwaysTrueFn() bool {
return true
}
// 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
}
// handshakeWithServer executes the handshake with the remote server peer.
func (p *testPeer) handshakeWithServer(t *testing.T, td *big.Int, head common.Hash, headNum uint64, genesis common.Hash, forkID forkid.ID) {
// It only works for the simulated client peer
if p.cpeer == nil {
t.Fatal("handshake for client peer only")
}
var sendList keyValueList
sendList = sendList.add("protocolVersion", uint64(p.cpeer.version))
sendList = sendList.add("networkId", uint64(NetworkId))
sendList = sendList.add("headTd", td)
sendList = sendList.add("headHash", head)
sendList = sendList.add("headNum", headNum)
sendList = sendList.add("genesisHash", genesis)
if p.cpeer.version >= lpv4 {
sendList = sendList.add("forkID", &forkID)
}
if err := p2p.ExpectMsg(p.app, StatusMsg, nil); err != nil {
t.Fatalf("status recv: %v", err)
}
if err := p2p.Send(p.app, StatusMsg, sendList); err != nil {
t.Fatalf("status send: %v", err)
}
}
// handshakeWithClient executes the handshake with the remote client peer.
func (p *testPeer) handshakeWithClient(t *testing.T, td *big.Int, head common.Hash, headNum uint64, genesis common.Hash, forkID forkid.ID, costList RequestCostList, recentTxLookup uint64) {
// It only works for the simulated client peer
if p.speer == nil {
t.Fatal("handshake for server peer only")
}
var sendList keyValueList
sendList = sendList.add("protocolVersion", uint64(p.speer.version))
sendList = sendList.add("networkId", uint64(NetworkId))
sendList = sendList.add("headTd", td)
sendList = sendList.add("headHash", head)
sendList = sendList.add("headNum", headNum)
sendList = sendList.add("genesisHash", genesis)
sendList = sendList.add("serveHeaders", nil)
sendList = sendList.add("serveChainSince", uint64(0))
sendList = sendList.add("serveStateSince", uint64(0))
sendList = sendList.add("serveRecentState", uint64(128-4))
sendList = sendList.add("txRelay", nil)
sendList = sendList.add("flowControl/BL", testBufLimit)
sendList = sendList.add("flowControl/MRR", testBufRecharge)
sendList = sendList.add("flowControl/MRC", costList)
if p.speer.version >= lpv4 {
sendList = sendList.add("forkID", &forkID)
sendList = sendList.add("recentTxLookup", recentTxLookup)
}
if err := p2p.ExpectMsg(p.app, StatusMsg, nil); err != nil {
t.Fatalf("status recv: %v", err)
}
if err := p2p.Send(p.app, StatusMsg, sendList); err != nil {
t.Fatalf("status send: %v", err)
}
}
// 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, *testPeer, 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:
errc2 <- p2p.DiscQuitting
case errc2 <- client.handle(peer2):
}
}()
// Ensure the connection is established or exits when any error occurs
for {
select {
case err := <-errc1:
return nil, nil, fmt.Errorf("Failed to establish protocol connection %v", err)
case err := <-errc2:
return nil, nil, fmt.Errorf("Failed to establish protocol connection %v", err)
default:
}
if atomic.LoadUint32(&peer1.serving) == 1 && atomic.LoadUint32(&peer2.serving) == 1 {
break
}
time.Sleep(50 * time.Millisecond)
}
return &testPeer{cpeer: peer1, net: net, app: app}, &testPeer{speer: peer2, net: app, app: net}, nil
}
type indexerCallback func(*core.ChainIndexer, *core.ChainIndexer, *core.ChainIndexer)
// testClient represents a client object 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
}
// newRawPeer creates a new server peer connects to the server and do the handshake.
func (client *testClient) newRawPeer(t *testing.T, name string, version int, recentTxLookup uint64) (*testPeer, func(), <-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 := newServerPeer(version, NetworkId, false, p2p.NewPeer(id, name, nil), net)
// Start the peer on a new thread
errCh := make(chan error, 1)
go func() {
select {
case <-client.handler.closeCh:
errCh <- p2p.DiscQuitting
case errCh <- client.handler.handle(peer):
}
}()
tp := &testPeer{
app: app,
net: net,
speer: peer,
}
var (
genesis = client.handler.backend.blockchain.Genesis()
head = client.handler.backend.blockchain.CurrentHeader()
td = client.handler.backend.blockchain.GetTd(head.Hash(), head.Number.Uint64())
)
forkID := forkid.NewID(client.handler.backend.blockchain.Config(), genesis.Hash(), head.Number.Uint64())
tp.handshakeWithClient(t, td, head.Hash(), head.Number.Uint64(), genesis.Hash(), forkID, testCostList(0), recentTxLookup) // disable flow control by default
// Ensure the connection is established or exits when any error occurs
for {
select {
case <-errCh:
return nil, nil, nil
default:
}
if atomic.LoadUint32(&peer.serving) == 1 {
break
}
time.Sleep(50 * time.Millisecond)
}
closePeer := func() {
tp.speer.close()
tp.close()
}
return tp, closePeer, errCh
}
// testServer represents a server object 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
}
// newRawPeer creates a new client peer connects to the server and do the handshake.
func (server *testServer) newRawPeer(t *testing.T, name string, version int) (*testPeer, func(), <-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 <-server.handler.closeCh:
errCh <- p2p.DiscQuitting
case errCh <- server.handler.handle(peer):
}
}()
tp := &testPeer{
app: app,
net: net,
cpeer: peer,
}
var (
genesis = server.handler.blockchain.Genesis()
head = server.handler.blockchain.CurrentHeader()
td = server.handler.blockchain.GetTd(head.Hash(), head.Number.Uint64())
)
forkID := forkid.NewID(server.handler.blockchain.Config(), genesis.Hash(), head.Number.Uint64())
tp.handshakeWithServer(t, td, head.Hash(), head.Number.Uint64(), genesis.Hash(), forkID)
// Ensure the connection is established or exits when any error occurs
for {
select {
case <-errCh:
return nil, nil, nil
default:
}
if atomic.LoadUint32(&peer.serving) == 1 {
break
}
time.Sleep(50 * time.Millisecond)
}
closePeer := func() {
tp.cpeer.close()
tp.close()
}
return tp, closePeer, errCh
}
// testnetConfig wraps all the configurations for testing network.
type testnetConfig struct {
blocks int
protocol int
indexFn indexerCallback
ulcServers []string
ulcFraction int
simClock bool
connect bool
nopruning bool
}
func newClientServerEnv(t *testing.T, config testnetConfig) (*testServer, *testClient, func()) {
var (
sdb = rawdb.NewMemoryDatabase()
cdb = rawdb.NewMemoryDatabase()
speers = newServerPeerSet()
)
var clock mclock.Clock = &mclock.System{}
if config.simClock {
clock = &mclock.Simulated{}
}
dist := newRequestDistributor(speers, clock)
rm := newRetrieveManager(speers, dist, func() time.Duration { return time.Millisecond * 500 })
odr := NewLesOdr(cdb, light.TestClientIndexerConfig, speers, rm)
sindexers := testIndexers(sdb, nil, light.TestServerIndexerConfig, true)
cIndexers := testIndexers(cdb, odr, light.TestClientIndexerConfig, config.nopruning)
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, serverClose := newTestServerHandler(config.blocks, sindexers, sdb, clock)
client, clientClose := newTestClientHandler(b, odr, cIndexers, cdb, speers, config.ulcServers, config.ulcFraction)
scIndexer.Start(server.blockchain)
sbIndexer.Start(server.blockchain)
ccIndexer.Start(client.backend.blockchain)
cbIndexer.Start(client.backend.blockchain)
if config.indexFn != nil {
config.indexFn(scIndexer, sbIndexer, sbtIndexer)
}
var (
err error
speer, cpeer *testPeer
)
if config.connect {
done := make(chan struct{})
client.syncEnd = func(_ *types.Header) { close(done) }
cpeer, speer, err = newTestPeerPair("peer", config.protocol, server, client)
if err != nil {
t.Fatalf("Failed to connect testing peers %v", err)
}
select {
case <-done:
case <-time.After(10 * time.Second):
t.Fatal("test peer did not connect and sync within 3s")
}
}
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 config.connect {
speer.close()
cpeer.close()
cpeer.cpeer.close()
speer.speer.close()
}
ccIndexer.Close()
cbIndexer.Close()
scIndexer.Close()
sbIndexer.Close()
dist.close()
serverClose()
b.Close()
clientClose()
}
return s, c, teardown
}
// NewFuzzerPeer creates a client peer for test purposes, and also returns
// a function to close the peer: this is needed to avoid goroutine leaks in the
// exec queue.
func NewFuzzerPeer(version int) (p *clientPeer, closer func()) {
p = newClientPeer(version, 0, p2p.NewPeer(enode.ID{}, "", nil), nil)
return p, func() { p.peerCommons.close() }
}