// Copyright 2021 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 . package vflux import ( "bytes" "encoding/binary" "io" "math" "math/big" "time" "github.com/ethereum/go-ethereum/common/mclock" "github.com/ethereum/go-ethereum/ethdb/memorydb" "github.com/ethereum/go-ethereum/les/vflux" vfs "github.com/ethereum/go-ethereum/les/vflux/server" "github.com/ethereum/go-ethereum/log" "github.com/ethereum/go-ethereum/p2p/enode" "github.com/ethereum/go-ethereum/p2p/enr" "github.com/ethereum/go-ethereum/rlp" ) var ( debugMode = false doLog = func(msg string, ctx ...interface{}) { if !debugMode { return } log.Info(msg, ctx...) } ) type fuzzer struct { peers [256]*clientPeer disconnectList []*clientPeer input io.Reader exhausted bool activeCount, activeCap uint64 maxCount, maxCap uint64 } type clientPeer struct { fuzzer *fuzzer node *enode.Node freeID string timeout time.Duration balance vfs.ConnectedBalance capacity uint64 } func (p *clientPeer) Node() *enode.Node { return p.node } func (p *clientPeer) FreeClientId() string { return p.freeID } func (p *clientPeer) InactiveAllowance() time.Duration { return p.timeout } func (p *clientPeer) UpdateCapacity(newCap uint64, requested bool) { origin, originTotal := p.capacity, p.fuzzer.activeCap p.fuzzer.activeCap -= p.capacity if p.capacity != 0 { p.fuzzer.activeCount-- } p.capacity = newCap p.fuzzer.activeCap += p.capacity if p.capacity != 0 { p.fuzzer.activeCount++ } doLog("Update capacity", "peer", p.node.ID(), "origin", origin, "cap", newCap, "origintotal", originTotal, "total", p.fuzzer.activeCap, "requested", requested) } func (p *clientPeer) Disconnect() { origin, originTotal := p.capacity, p.fuzzer.activeCap p.fuzzer.disconnectList = append(p.fuzzer.disconnectList, p) p.fuzzer.activeCap -= p.capacity if p.capacity != 0 { p.fuzzer.activeCount-- } p.capacity = 0 p.balance = nil doLog("Disconnect", "peer", p.node.ID(), "origin", origin, "origintotal", originTotal, "total", p.fuzzer.activeCap) } func newFuzzer(input []byte) *fuzzer { f := &fuzzer{ input: bytes.NewReader(input), } for i := range f.peers { f.peers[i] = &clientPeer{ fuzzer: f, node: enode.SignNull(new(enr.Record), enode.ID{byte(i)}), freeID: string([]byte{byte(i)}), timeout: f.randomDelay(), } } return f } func (f *fuzzer) read(size int) []byte { out := make([]byte, size) if _, err := f.input.Read(out); err != nil { f.exhausted = true } return out } func (f *fuzzer) randomByte() byte { d := f.read(1) return d[0] } func (f *fuzzer) randomBool() bool { d := f.read(1) return d[0]&1 == 1 } func (f *fuzzer) randomInt(max int) int { if max == 0 { return 0 } if max <= 256 { return int(f.randomByte()) % max } var a uint16 if err := binary.Read(f.input, binary.LittleEndian, &a); err != nil { f.exhausted = true } return int(a % uint16(max)) } func (f *fuzzer) randomTokenAmount(signed bool) int64 { x := uint64(f.randomInt(65000)) x = x * x * x * x if signed && (x&1) == 1 { if x <= math.MaxInt64 { return -int64(x) } return math.MinInt64 } if x <= math.MaxInt64 { return int64(x) } return math.MaxInt64 } func (f *fuzzer) randomDelay() time.Duration { delay := f.randomByte() if delay < 128 { return time.Duration(delay) * time.Second } return 0 } func (f *fuzzer) randomFactors() vfs.PriceFactors { return vfs.PriceFactors{ TimeFactor: float64(f.randomByte()) / 25500, CapacityFactor: float64(f.randomByte()) / 255, RequestFactor: float64(f.randomByte()) / 255, } } func (f *fuzzer) connectedBalanceOp(balance vfs.ConnectedBalance, id enode.ID) { switch f.randomInt(3) { case 0: cost := uint64(f.randomTokenAmount(false)) balance.RequestServed(cost) doLog("Serve request cost", "id", id, "amount", cost) case 1: posFactor, negFactor := f.randomFactors(), f.randomFactors() balance.SetPriceFactors(posFactor, negFactor) doLog("Set price factor", "pos", posFactor, "neg", negFactor) case 2: balance.GetBalance() balance.GetRawBalance() balance.GetPriceFactors() } } func (f *fuzzer) atomicBalanceOp(balance vfs.AtomicBalanceOperator, id enode.ID) { switch f.randomInt(3) { case 0: amount := f.randomTokenAmount(true) balance.AddBalance(amount) doLog("Add balance", "id", id, "amount", amount) case 1: pos, neg := uint64(f.randomTokenAmount(false)), uint64(f.randomTokenAmount(false)) balance.SetBalance(pos, neg) doLog("Set balance", "id", id, "pos", pos, "neg", neg) case 2: balance.GetBalance() balance.GetRawBalance() balance.GetPriceFactors() } } func FuzzClientPool(input []byte) int { if len(input) > 10000 { return -1 } f := newFuzzer(input) if f.exhausted { return 0 } clock := &mclock.Simulated{} db := memorydb.New() pool := vfs.NewClientPool(db, 10, f.randomDelay(), clock, func() bool { return true }) pool.Start() defer pool.Stop() count := 0 for !f.exhausted && count < 1000 { count++ switch f.randomInt(11) { case 0: i := int(f.randomByte()) f.peers[i].balance = pool.Register(f.peers[i]) doLog("Register peer", "id", f.peers[i].node.ID()) case 1: i := int(f.randomByte()) f.peers[i].Disconnect() doLog("Disconnect peer", "id", f.peers[i].node.ID()) case 2: f.maxCount = uint64(f.randomByte()) f.maxCap = uint64(f.randomByte()) f.maxCap *= f.maxCap count, cap := pool.Limits() pool.SetLimits(f.maxCount, f.maxCap) doLog("Set limits", "maxcount", f.maxCount, "maxcap", f.maxCap, "origincount", count, "oricap", cap) case 3: bias := f.randomDelay() pool.SetConnectedBias(f.randomDelay()) doLog("Set connection bias", "bias", bias) case 4: pos, neg := f.randomFactors(), f.randomFactors() pool.SetDefaultFactors(pos, neg) doLog("Set default factors", "pos", pos, "neg", neg) case 5: pos, neg := uint64(f.randomInt(50000)), uint64(f.randomInt(50000)) pool.SetExpirationTCs(pos, neg) doLog("Set expiration constants", "pos", pos, "neg", neg) case 6: var ( index = f.randomByte() reqCap = uint64(f.randomByte()) bias = f.randomDelay() requested = f.randomBool() ) if _, err := pool.SetCapacity(f.peers[index].node, reqCap, bias, requested); err == vfs.ErrCantFindMaximum { panic(nil) } doLog("Set capacity", "id", f.peers[index].node.ID(), "reqcap", reqCap, "bias", bias, "requested", requested) case 7: index := f.randomByte() if balance := f.peers[index].balance; balance != nil { f.connectedBalanceOp(balance, f.peers[index].node.ID()) } case 8: index := f.randomByte() pool.BalanceOperation(f.peers[index].node.ID(), f.peers[index].freeID, func(balance vfs.AtomicBalanceOperator) { count := f.randomInt(4) for i := 0; i < count; i++ { f.atomicBalanceOp(balance, f.peers[index].node.ID()) } }) case 9: pool.TotalTokenAmount() pool.GetExpirationTCs() pool.Active() pool.Limits() pool.GetPosBalanceIDs(f.peers[f.randomByte()].node.ID(), f.peers[f.randomByte()].node.ID(), f.randomInt(100)) case 10: req := vflux.CapacityQueryReq{ Bias: uint64(f.randomByte()), AddTokens: make([]vflux.IntOrInf, f.randomInt(vflux.CapacityQueryMaxLen+1)), } for i := range req.AddTokens { v := vflux.IntOrInf{Type: uint8(f.randomInt(4))} if v.Type < 2 { v.Value = *big.NewInt(f.randomTokenAmount(false)) } req.AddTokens[i] = v } reqEnc, err := rlp.EncodeToBytes(&req) if err != nil { panic(err) } p := int(f.randomByte()) if p < len(reqEnc) { reqEnc[p] = f.randomByte() } pool.Handle(f.peers[f.randomByte()].node.ID(), f.peers[f.randomByte()].freeID, vflux.CapacityQueryName, reqEnc) } for _, peer := range f.disconnectList { pool.Unregister(peer) doLog("Unregister peer", "id", peer.node.ID()) } f.disconnectList = nil if d := f.randomDelay(); d > 0 { clock.Run(d) } doLog("Clientpool stats in fuzzer", "count", f.activeCap, "maxcount", f.maxCount, "cap", f.activeCap, "maxcap", f.maxCap) activeCount, activeCap := pool.Active() doLog("Clientpool stats in pool", "count", activeCount, "cap", activeCap) if activeCount != f.activeCount || activeCap != f.activeCap { panic(nil) } if f.activeCount > f.maxCount || f.activeCap > f.maxCap { panic(nil) } } return 0 }