github.com/JimmyHuang454/JLS-go@v0.0.0-20230831150107-90d536585ba0/internal/trace/order.go (about) 1 // Copyright 2016 The Go Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 package trace 6 7 import ( 8 "fmt" 9 "sort" 10 ) 11 12 type eventBatch struct { 13 events []*Event 14 selected bool 15 } 16 17 type orderEvent struct { 18 ev *Event 19 batch int 20 g uint64 21 init gState 22 next gState 23 } 24 25 type gStatus int 26 27 type gState struct { 28 seq uint64 29 status gStatus 30 } 31 32 const ( 33 gDead gStatus = iota 34 gRunnable 35 gRunning 36 gWaiting 37 38 unordered = ^uint64(0) 39 garbage = ^uint64(0) - 1 40 noseq = ^uint64(0) 41 seqinc = ^uint64(0) - 1 42 ) 43 44 // order1007 merges a set of per-P event batches into a single, consistent stream. 45 // The high level idea is as follows. Events within an individual batch are in 46 // correct order, because they are emitted by a single P. So we need to produce 47 // a correct interleaving of the batches. To do this we take first unmerged event 48 // from each batch (frontier). Then choose subset that is "ready" to be merged, 49 // that is, events for which all dependencies are already merged. Then we choose 50 // event with the lowest timestamp from the subset, merge it and repeat. 51 // This approach ensures that we form a consistent stream even if timestamps are 52 // incorrect (condition observed on some machines). 53 func order1007(m map[int][]*Event) (events []*Event, err error) { 54 pending := 0 55 // The ordering of CPU profile sample events in the data stream is based on 56 // when each run of the signal handler was able to acquire the spinlock, 57 // with original timestamps corresponding to when ReadTrace pulled the data 58 // off of the profBuf queue. Re-sort them by the timestamp we captured 59 // inside the signal handler. 60 sort.Stable(eventList(m[ProfileP])) 61 var batches []*eventBatch 62 for _, v := range m { 63 pending += len(v) 64 batches = append(batches, &eventBatch{v, false}) 65 } 66 gs := make(map[uint64]gState) 67 var frontier []orderEvent 68 for ; pending != 0; pending-- { 69 for i, b := range batches { 70 if b.selected || len(b.events) == 0 { 71 continue 72 } 73 ev := b.events[0] 74 g, init, next := stateTransition(ev) 75 if !transitionReady(g, gs[g], init) { 76 continue 77 } 78 frontier = append(frontier, orderEvent{ev, i, g, init, next}) 79 b.events = b.events[1:] 80 b.selected = true 81 // Get rid of "Local" events, they are intended merely for ordering. 82 switch ev.Type { 83 case EvGoStartLocal: 84 ev.Type = EvGoStart 85 case EvGoUnblockLocal: 86 ev.Type = EvGoUnblock 87 case EvGoSysExitLocal: 88 ev.Type = EvGoSysExit 89 } 90 } 91 if len(frontier) == 0 { 92 return nil, fmt.Errorf("no consistent ordering of events possible") 93 } 94 sort.Sort(orderEventList(frontier)) 95 f := frontier[0] 96 frontier[0] = frontier[len(frontier)-1] 97 frontier = frontier[:len(frontier)-1] 98 events = append(events, f.ev) 99 transition(gs, f.g, f.init, f.next) 100 if !batches[f.batch].selected { 101 panic("frontier batch is not selected") 102 } 103 batches[f.batch].selected = false 104 } 105 106 // At this point we have a consistent stream of events. 107 // Make sure time stamps respect the ordering. 108 // The tests will skip (not fail) the test case if they see this error. 109 if !sort.IsSorted(eventList(events)) { 110 return nil, ErrTimeOrder 111 } 112 113 // The last part is giving correct timestamps to EvGoSysExit events. 114 // The problem with EvGoSysExit is that actual syscall exit timestamp (ev.Args[2]) 115 // is potentially acquired long before event emission. So far we've used 116 // timestamp of event emission (ev.Ts). 117 // We could not set ev.Ts = ev.Args[2] earlier, because it would produce 118 // seemingly broken timestamps (misplaced event). 119 // We also can't simply update the timestamp and resort events, because 120 // if timestamps are broken we will misplace the event and later report 121 // logically broken trace (instead of reporting broken timestamps). 122 lastSysBlock := make(map[uint64]int64) 123 for _, ev := range events { 124 switch ev.Type { 125 case EvGoSysBlock, EvGoInSyscall: 126 lastSysBlock[ev.G] = ev.Ts 127 case EvGoSysExit: 128 ts := int64(ev.Args[2]) 129 if ts == 0 { 130 continue 131 } 132 block := lastSysBlock[ev.G] 133 if block == 0 { 134 return nil, fmt.Errorf("stray syscall exit") 135 } 136 if ts < block { 137 return nil, ErrTimeOrder 138 } 139 ev.Ts = ts 140 } 141 } 142 sort.Stable(eventList(events)) 143 144 return 145 } 146 147 // stateTransition returns goroutine state (sequence and status) when the event 148 // becomes ready for merging (init) and the goroutine state after the event (next). 149 func stateTransition(ev *Event) (g uint64, init, next gState) { 150 switch ev.Type { 151 case EvGoCreate: 152 g = ev.Args[0] 153 init = gState{0, gDead} 154 next = gState{1, gRunnable} 155 case EvGoWaiting, EvGoInSyscall: 156 g = ev.G 157 init = gState{1, gRunnable} 158 next = gState{2, gWaiting} 159 case EvGoStart, EvGoStartLabel: 160 g = ev.G 161 init = gState{ev.Args[1], gRunnable} 162 next = gState{ev.Args[1] + 1, gRunning} 163 case EvGoStartLocal: 164 // noseq means that this event is ready for merging as soon as 165 // frontier reaches it (EvGoStartLocal is emitted on the same P 166 // as the corresponding EvGoCreate/EvGoUnblock, and thus the latter 167 // is already merged). 168 // seqinc is a stub for cases when event increments g sequence, 169 // but since we don't know current seq we also don't know next seq. 170 g = ev.G 171 init = gState{noseq, gRunnable} 172 next = gState{seqinc, gRunning} 173 case EvGoBlock, EvGoBlockSend, EvGoBlockRecv, EvGoBlockSelect, 174 EvGoBlockSync, EvGoBlockCond, EvGoBlockNet, EvGoSleep, 175 EvGoSysBlock, EvGoBlockGC: 176 g = ev.G 177 init = gState{noseq, gRunning} 178 next = gState{noseq, gWaiting} 179 case EvGoSched, EvGoPreempt: 180 g = ev.G 181 init = gState{noseq, gRunning} 182 next = gState{noseq, gRunnable} 183 case EvGoUnblock, EvGoSysExit: 184 g = ev.Args[0] 185 init = gState{ev.Args[1], gWaiting} 186 next = gState{ev.Args[1] + 1, gRunnable} 187 case EvGoUnblockLocal, EvGoSysExitLocal: 188 g = ev.Args[0] 189 init = gState{noseq, gWaiting} 190 next = gState{seqinc, gRunnable} 191 case EvGCStart: 192 g = garbage 193 init = gState{ev.Args[0], gDead} 194 next = gState{ev.Args[0] + 1, gDead} 195 default: 196 // no ordering requirements 197 g = unordered 198 } 199 return 200 } 201 202 func transitionReady(g uint64, curr, init gState) bool { 203 return g == unordered || (init.seq == noseq || init.seq == curr.seq) && init.status == curr.status 204 } 205 206 func transition(gs map[uint64]gState, g uint64, init, next gState) { 207 if g == unordered { 208 return 209 } 210 curr := gs[g] 211 if !transitionReady(g, curr, init) { 212 panic("event sequences are broken") 213 } 214 switch next.seq { 215 case noseq: 216 next.seq = curr.seq 217 case seqinc: 218 next.seq = curr.seq + 1 219 } 220 gs[g] = next 221 } 222 223 // order1005 merges a set of per-P event batches into a single, consistent stream. 224 func order1005(m map[int][]*Event) (events []*Event, err error) { 225 for _, batch := range m { 226 events = append(events, batch...) 227 } 228 for _, ev := range events { 229 if ev.Type == EvGoSysExit { 230 // EvGoSysExit emission is delayed until the thread has a P. 231 // Give it the real sequence number and time stamp. 232 ev.seq = int64(ev.Args[1]) 233 if ev.Args[2] != 0 { 234 ev.Ts = int64(ev.Args[2]) 235 } 236 } 237 } 238 sort.Sort(eventSeqList(events)) 239 if !sort.IsSorted(eventList(events)) { 240 return nil, ErrTimeOrder 241 } 242 return 243 } 244 245 type orderEventList []orderEvent 246 247 func (l orderEventList) Len() int { 248 return len(l) 249 } 250 251 func (l orderEventList) Less(i, j int) bool { 252 return l[i].ev.Ts < l[j].ev.Ts 253 } 254 255 func (l orderEventList) Swap(i, j int) { 256 l[i], l[j] = l[j], l[i] 257 } 258 259 type eventList []*Event 260 261 func (l eventList) Len() int { 262 return len(l) 263 } 264 265 func (l eventList) Less(i, j int) bool { 266 return l[i].Ts < l[j].Ts 267 } 268 269 func (l eventList) Swap(i, j int) { 270 l[i], l[j] = l[j], l[i] 271 } 272 273 type eventSeqList []*Event 274 275 func (l eventSeqList) Len() int { 276 return len(l) 277 } 278 279 func (l eventSeqList) Less(i, j int) bool { 280 return l[i].seq < l[j].seq 281 } 282 283 func (l eventSeqList) Swap(i, j int) { 284 l[i], l[j] = l[j], l[i] 285 }