mirror of
https://github.com/golang/go
synced 2024-11-20 03:04:40 -07:00
2ae77376f7
The one in misc/makerelease/makerelease.go is particularly bad and probably warrants rotating our keys. I didn't update old weekly notes, and reverted some changes involving test code for now, since we're late in the Go 1.5 freeze. Otherwise, the rest are all auto-generated changes, and all manually reviewed. Change-Id: Ia2753576ab5d64826a167d259f48a2f50508792d Reviewed-on: https://go-review.googlesource.com/12048 Reviewed-by: Rob Pike <r@golang.org>
829 lines
25 KiB
Go
829 lines
25 KiB
Go
// Copyright 2014 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Go execution tracer.
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// The tracer captures a wide range of execution events like goroutine
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// creation/blocking/unblocking, syscall enter/exit/block, GC-related events,
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// changes of heap size, processor start/stop, etc and writes them to a buffer
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// in a compact form. A precise nanosecond-precision timestamp and a stack
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// trace is captured for most events.
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// See https://golang.org/s/go15trace for more info.
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package runtime
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import "unsafe"
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// Event types in the trace, args are given in square brackets.
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const (
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traceEvNone = 0 // unused
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traceEvBatch = 1 // start of per-P batch of events [pid, timestamp]
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traceEvFrequency = 2 // contains tracer timer frequency [frequency (ticks per second)]
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traceEvStack = 3 // stack [stack id, number of PCs, array of PCs]
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traceEvGomaxprocs = 4 // current value of GOMAXPROCS [timestamp, GOMAXPROCS, stack id]
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traceEvProcStart = 5 // start of P [timestamp, thread id]
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traceEvProcStop = 6 // stop of P [timestamp]
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traceEvGCStart = 7 // GC start [timestamp, stack id]
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traceEvGCDone = 8 // GC done [timestamp]
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traceEvGCScanStart = 9 // GC scan start [timestamp]
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traceEvGCScanDone = 10 // GC scan done [timestamp]
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traceEvGCSweepStart = 11 // GC sweep start [timestamp, stack id]
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traceEvGCSweepDone = 12 // GC sweep done [timestamp]
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traceEvGoCreate = 13 // goroutine creation [timestamp, new goroutine id, start PC, stack id]
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traceEvGoStart = 14 // goroutine starts running [timestamp, goroutine id]
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traceEvGoEnd = 15 // goroutine ends [timestamp]
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traceEvGoStop = 16 // goroutine stops (like in select{}) [timestamp, stack]
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traceEvGoSched = 17 // goroutine calls Gosched [timestamp, stack]
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traceEvGoPreempt = 18 // goroutine is preempted [timestamp, stack]
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traceEvGoSleep = 19 // goroutine calls Sleep [timestamp, stack]
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traceEvGoBlock = 20 // goroutine blocks [timestamp, stack]
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traceEvGoUnblock = 21 // goroutine is unblocked [timestamp, goroutine id, stack]
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traceEvGoBlockSend = 22 // goroutine blocks on chan send [timestamp, stack]
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traceEvGoBlockRecv = 23 // goroutine blocks on chan recv [timestamp, stack]
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traceEvGoBlockSelect = 24 // goroutine blocks on select [timestamp, stack]
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traceEvGoBlockSync = 25 // goroutine blocks on Mutex/RWMutex [timestamp, stack]
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traceEvGoBlockCond = 26 // goroutine blocks on Cond [timestamp, stack]
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traceEvGoBlockNet = 27 // goroutine blocks on network [timestamp, stack]
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traceEvGoSysCall = 28 // syscall enter [timestamp, stack]
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traceEvGoSysExit = 29 // syscall exit [timestamp, goroutine id, real timestamp]
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traceEvGoSysBlock = 30 // syscall blocks [timestamp]
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traceEvGoWaiting = 31 // denotes that goroutine is blocked when tracing starts [goroutine id]
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traceEvGoInSyscall = 32 // denotes that goroutine is in syscall when tracing starts [goroutine id]
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traceEvHeapAlloc = 33 // memstats.heap_live change [timestamp, heap_alloc]
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traceEvNextGC = 34 // memstats.next_gc change [timestamp, next_gc]
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traceEvTimerGoroutine = 35 // denotes timer goroutine [timer goroutine id]
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traceEvFutileWakeup = 36 // denotes that the previous wakeup of this goroutine was futile [timestamp]
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traceEvCount = 37
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)
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const (
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// Timestamps in trace are cputicks/traceTickDiv.
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// This makes absolute values of timestamp diffs smaller,
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// and so they are encoded in less number of bytes.
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// 64 on x86 is somewhat arbitrary (one tick is ~20ns on a 3GHz machine).
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// The suggested increment frequency for PowerPC's time base register is
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// 512 MHz according to Power ISA v2.07 section 6.2, so we use 16 on ppc64
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// and ppc64le.
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// Tracing won't work reliably for architectures where cputicks is emulated
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// by nanotime, so the value doesn't matter for those architectures.
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traceTickDiv = 16 + 48*(goarch_386|goarch_amd64|goarch_amd64p32)
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// Maximum number of PCs in a single stack trace.
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// Since events contain only stack id rather than whole stack trace,
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// we can allow quite large values here.
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traceStackSize = 128
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// Identifier of a fake P that is used when we trace without a real P.
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traceGlobProc = -1
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// Maximum number of bytes to encode uint64 in base-128.
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traceBytesPerNumber = 10
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// Shift of the number of arguments in the first event byte.
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traceArgCountShift = 6
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// Flag passed to traceGoPark to denote that the previous wakeup of this
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// goroutine was futile. For example, a goroutine was unblocked on a mutex,
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// but another goroutine got ahead and acquired the mutex before the first
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// goroutine is scheduled, so the first goroutine has to block again.
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// Such wakeups happen on buffered channels and sync.Mutex,
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// but are generally not interesting for end user.
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traceFutileWakeup byte = 128
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)
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// trace is global tracing context.
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var trace struct {
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lock mutex // protects the following members
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lockOwner *g // to avoid deadlocks during recursive lock locks
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enabled bool // when set runtime traces events
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shutdown bool // set when we are waiting for trace reader to finish after setting enabled to false
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headerWritten bool // whether ReadTrace has emitted trace header
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footerWritten bool // whether ReadTrace has emitted trace footer
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shutdownSema uint32 // used to wait for ReadTrace completion
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ticksStart int64 // cputicks when tracing was started
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ticksEnd int64 // cputicks when tracing was stopped
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timeStart int64 // nanotime when tracing was started
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timeEnd int64 // nanotime when tracing was stopped
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reading *traceBuf // buffer currently handed off to user
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empty *traceBuf // stack of empty buffers
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fullHead *traceBuf // queue of full buffers
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fullTail *traceBuf
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reader *g // goroutine that called ReadTrace, or nil
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stackTab traceStackTable // maps stack traces to unique ids
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bufLock mutex // protects buf
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buf *traceBuf // global trace buffer, used when running without a p
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}
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// traceBufHeader is per-P tracing buffer.
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type traceBufHeader struct {
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link *traceBuf // in trace.empty/full
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lastTicks uint64 // when we wrote the last event
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buf []byte // trace data, always points to traceBuf.arr
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stk [traceStackSize]uintptr // scratch buffer for traceback
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}
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// traceBuf is per-P tracing buffer.
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type traceBuf struct {
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traceBufHeader
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arr [64<<10 - unsafe.Sizeof(traceBufHeader{})]byte // underlying buffer for traceBufHeader.buf
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}
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// StartTrace enables tracing for the current process.
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// While tracing, the data will be buffered and available via ReadTrace.
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// StartTrace returns an error if tracing is already enabled.
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// Most clients should use the runtime/pprof package or the testing package's
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// -test.trace flag instead of calling StartTrace directly.
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func StartTrace() error {
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// Stop the world, so that we can take a consistent snapshot
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// of all goroutines at the beginning of the trace.
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stopTheWorld("start tracing")
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// We are in stop-the-world, but syscalls can finish and write to trace concurrently.
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// Exitsyscall could check trace.enabled long before and then suddenly wake up
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// and decide to write to trace at a random point in time.
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// However, such syscall will use the global trace.buf buffer, because we've
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// acquired all p's by doing stop-the-world. So this protects us from such races.
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lock(&trace.bufLock)
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if trace.enabled || trace.shutdown {
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unlock(&trace.bufLock)
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startTheWorld()
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return errorString("tracing is already enabled")
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}
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trace.ticksStart = cputicks()
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trace.timeStart = nanotime()
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trace.headerWritten = false
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trace.footerWritten = false
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// Can't set trace.enabled yet. While the world is stopped, exitsyscall could
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// already emit a delayed event (see exitTicks in exitsyscall) if we set trace.enabled here.
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// That would lead to an inconsistent trace:
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// - either GoSysExit appears before EvGoInSyscall,
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// - or GoSysExit appears for a goroutine for which we don't emit EvGoInSyscall below.
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// To instruct traceEvent that it must not ignore events below, we set startingtrace.
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// trace.enabled is set afterwards once we have emitted all preliminary events.
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_g_ := getg()
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_g_.m.startingtrace = true
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for _, gp := range allgs {
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status := readgstatus(gp)
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if status != _Gdead {
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traceGoCreate(gp, gp.startpc)
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}
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if status == _Gwaiting {
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traceEvent(traceEvGoWaiting, -1, uint64(gp.goid))
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}
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if status == _Gsyscall {
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traceEvent(traceEvGoInSyscall, -1, uint64(gp.goid))
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} else {
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gp.sysblocktraced = false
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}
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}
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traceProcStart()
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traceGoStart()
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_g_.m.startingtrace = false
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trace.enabled = true
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unlock(&trace.bufLock)
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startTheWorld()
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return nil
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}
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// StopTrace stops tracing, if it was previously enabled.
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// StopTrace only returns after all the reads for the trace have completed.
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func StopTrace() {
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// Stop the world so that we can collect the trace buffers from all p's below,
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// and also to avoid races with traceEvent.
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stopTheWorld("stop tracing")
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// See the comment in StartTrace.
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lock(&trace.bufLock)
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if !trace.enabled {
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unlock(&trace.bufLock)
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startTheWorld()
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return
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}
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traceGoSched()
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for _, p := range &allp {
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if p == nil {
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break
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}
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buf := p.tracebuf
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if buf != nil {
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traceFullQueue(buf)
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p.tracebuf = nil
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}
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}
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if trace.buf != nil && len(trace.buf.buf) != 0 {
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buf := trace.buf
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trace.buf = nil
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traceFullQueue(buf)
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}
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for {
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trace.ticksEnd = cputicks()
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trace.timeEnd = nanotime()
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// Windows time can tick only every 15ms, wait for at least one tick.
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if trace.timeEnd != trace.timeStart {
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break
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}
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osyield()
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}
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trace.enabled = false
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trace.shutdown = true
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trace.stackTab.dump()
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unlock(&trace.bufLock)
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startTheWorld()
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// The world is started but we've set trace.shutdown, so new tracing can't start.
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// Wait for the trace reader to flush pending buffers and stop.
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semacquire(&trace.shutdownSema, false)
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if raceenabled {
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raceacquire(unsafe.Pointer(&trace.shutdownSema))
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}
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// The lock protects us from races with StartTrace/StopTrace because they do stop-the-world.
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lock(&trace.lock)
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for _, p := range &allp {
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if p == nil {
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break
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}
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if p.tracebuf != nil {
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throw("trace: non-empty trace buffer in proc")
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}
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}
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if trace.buf != nil {
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throw("trace: non-empty global trace buffer")
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}
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if trace.fullHead != nil || trace.fullTail != nil {
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throw("trace: non-empty full trace buffer")
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}
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if trace.reading != nil || trace.reader != nil {
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throw("trace: reading after shutdown")
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}
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for trace.empty != nil {
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buf := trace.empty
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trace.empty = buf.link
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sysFree(unsafe.Pointer(buf), unsafe.Sizeof(*buf), &memstats.other_sys)
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}
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trace.shutdown = false
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unlock(&trace.lock)
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}
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// ReadTrace returns the next chunk of binary tracing data, blocking until data
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// is available. If tracing is turned off and all the data accumulated while it
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// was on has been returned, ReadTrace returns nil. The caller must copy the
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// returned data before calling ReadTrace again.
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// ReadTrace must be called from one goroutine at a time.
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func ReadTrace() []byte {
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// This function may need to lock trace.lock recursively
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// (goparkunlock -> traceGoPark -> traceEvent -> traceFlush).
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// To allow this we use trace.lockOwner.
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// Also this function must not allocate while holding trace.lock:
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// allocation can call heap allocate, which will try to emit a trace
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// event while holding heap lock.
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lock(&trace.lock)
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trace.lockOwner = getg()
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if trace.reader != nil {
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// More than one goroutine reads trace. This is bad.
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// But we rather do not crash the program because of tracing,
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// because tracing can be enabled at runtime on prod servers.
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trace.lockOwner = nil
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unlock(&trace.lock)
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println("runtime: ReadTrace called from multiple goroutines simultaneously")
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return nil
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}
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// Recycle the old buffer.
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if buf := trace.reading; buf != nil {
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buf.link = trace.empty
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trace.empty = buf
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trace.reading = nil
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}
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// Write trace header.
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if !trace.headerWritten {
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trace.headerWritten = true
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trace.lockOwner = nil
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unlock(&trace.lock)
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return []byte("gotrace\x00")
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}
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// Wait for new data.
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if trace.fullHead == nil && !trace.shutdown {
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trace.reader = getg()
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goparkunlock(&trace.lock, "trace reader (blocked)", traceEvGoBlock, 2)
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lock(&trace.lock)
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}
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// Write a buffer.
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if trace.fullHead != nil {
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buf := traceFullDequeue()
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trace.reading = buf
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trace.lockOwner = nil
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unlock(&trace.lock)
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return buf.buf
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}
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// Write footer with timer frequency.
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if !trace.footerWritten {
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trace.footerWritten = true
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// Use float64 because (trace.ticksEnd - trace.ticksStart) * 1e9 can overflow int64.
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freq := float64(trace.ticksEnd-trace.ticksStart) * 1e9 / float64(trace.timeEnd-trace.timeStart) / traceTickDiv
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trace.lockOwner = nil
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unlock(&trace.lock)
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var data []byte
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data = append(data, traceEvFrequency|0<<traceArgCountShift)
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data = traceAppend(data, uint64(freq))
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if timers.gp != nil {
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data = append(data, traceEvTimerGoroutine|0<<traceArgCountShift)
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data = traceAppend(data, uint64(timers.gp.goid))
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}
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return data
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}
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// Done.
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if trace.shutdown {
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trace.lockOwner = nil
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unlock(&trace.lock)
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if raceenabled {
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// Model synchronization on trace.shutdownSema, which race
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// detector does not see. This is required to avoid false
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// race reports on writer passed to pprof.StartTrace.
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racerelease(unsafe.Pointer(&trace.shutdownSema))
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}
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// trace.enabled is already reset, so can call traceable functions.
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semrelease(&trace.shutdownSema)
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return nil
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}
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// Also bad, but see the comment above.
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trace.lockOwner = nil
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unlock(&trace.lock)
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println("runtime: spurious wakeup of trace reader")
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return nil
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}
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// traceReader returns the trace reader that should be woken up, if any.
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func traceReader() *g {
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if trace.reader == nil || (trace.fullHead == nil && !trace.shutdown) {
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return nil
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}
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lock(&trace.lock)
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if trace.reader == nil || (trace.fullHead == nil && !trace.shutdown) {
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unlock(&trace.lock)
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return nil
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}
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gp := trace.reader
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trace.reader = nil
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unlock(&trace.lock)
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return gp
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}
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// traceProcFree frees trace buffer associated with pp.
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func traceProcFree(pp *p) {
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buf := pp.tracebuf
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pp.tracebuf = nil
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if buf == nil {
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return
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}
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lock(&trace.lock)
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traceFullQueue(buf)
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unlock(&trace.lock)
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}
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// traceFullQueue queues buf into queue of full buffers.
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func traceFullQueue(buf *traceBuf) {
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buf.link = nil
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if trace.fullHead == nil {
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trace.fullHead = buf
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} else {
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trace.fullTail.link = buf
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}
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trace.fullTail = buf
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}
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// traceFullDequeue dequeues from queue of full buffers.
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func traceFullDequeue() *traceBuf {
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buf := trace.fullHead
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if buf == nil {
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return nil
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}
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trace.fullHead = buf.link
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if trace.fullHead == nil {
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trace.fullTail = nil
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}
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buf.link = nil
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return buf
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}
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// traceEvent writes a single event to trace buffer, flushing the buffer if necessary.
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// ev is event type.
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// If skip > 0, write current stack id as the last argument (skipping skip top frames).
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// If skip = 0, this event type should contain a stack, but we don't want
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// to collect and remember it for this particular call.
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func traceEvent(ev byte, skip int, args ...uint64) {
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mp, pid, bufp := traceAcquireBuffer()
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// Double-check trace.enabled now that we've done m.locks++ and acquired bufLock.
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// This protects from races between traceEvent and StartTrace/StopTrace.
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// The caller checked that trace.enabled == true, but trace.enabled might have been
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// turned off between the check and now. Check again. traceLockBuffer did mp.locks++,
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// StopTrace does stopTheWorld, and stopTheWorld waits for mp.locks to go back to zero,
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// so if we see trace.enabled == true now, we know it's true for the rest of the function.
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// Exitsyscall can run even during stopTheWorld. The race with StartTrace/StopTrace
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// during tracing in exitsyscall is resolved by locking trace.bufLock in traceLockBuffer.
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if !trace.enabled && !mp.startingtrace {
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traceReleaseBuffer(pid)
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return
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}
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buf := *bufp
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const maxSize = 2 + 4*traceBytesPerNumber // event type, length, timestamp, stack id and two add params
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if buf == nil || cap(buf.buf)-len(buf.buf) < maxSize {
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buf = traceFlush(buf)
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*bufp = buf
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}
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ticks := uint64(cputicks()) / traceTickDiv
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tickDiff := ticks - buf.lastTicks
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if len(buf.buf) == 0 {
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data := buf.buf
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data = append(data, traceEvBatch|1<<traceArgCountShift)
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data = traceAppend(data, uint64(pid))
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data = traceAppend(data, ticks)
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buf.buf = data
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tickDiff = 0
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}
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buf.lastTicks = ticks
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narg := byte(len(args))
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if skip >= 0 {
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narg++
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}
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// We have only 2 bits for number of arguments.
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// If number is >= 3, then the event type is followed by event length in bytes.
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if narg > 3 {
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narg = 3
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}
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data := buf.buf
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data = append(data, ev|narg<<traceArgCountShift)
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var lenp *byte
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if narg == 3 {
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// Reserve the byte for length assuming that length < 128.
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data = append(data, 0)
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lenp = &data[len(data)-1]
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}
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data = traceAppend(data, tickDiff)
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for _, a := range args {
|
|
data = traceAppend(data, a)
|
|
}
|
|
if skip == 0 {
|
|
data = append(data, 0)
|
|
} else if skip > 0 {
|
|
_g_ := getg()
|
|
gp := mp.curg
|
|
var nstk int
|
|
if gp == _g_ {
|
|
nstk = callers(skip, buf.stk[:])
|
|
} else if gp != nil {
|
|
gp = mp.curg
|
|
nstk = gcallers(gp, skip, buf.stk[:])
|
|
}
|
|
if nstk > 0 {
|
|
nstk-- // skip runtime.goexit
|
|
}
|
|
if nstk > 0 && gp.goid == 1 {
|
|
nstk-- // skip runtime.main
|
|
}
|
|
id := trace.stackTab.put(buf.stk[:nstk])
|
|
data = traceAppend(data, uint64(id))
|
|
}
|
|
evSize := len(data) - len(buf.buf)
|
|
if evSize > maxSize {
|
|
throw("invalid length of trace event")
|
|
}
|
|
if lenp != nil {
|
|
// Fill in actual length.
|
|
*lenp = byte(evSize - 2)
|
|
}
|
|
buf.buf = data
|
|
traceReleaseBuffer(pid)
|
|
}
|
|
|
|
// traceAcquireBuffer returns trace buffer to use and, if necessary, locks it.
|
|
func traceAcquireBuffer() (mp *m, pid int32, bufp **traceBuf) {
|
|
mp = acquirem()
|
|
if p := mp.p.ptr(); p != nil {
|
|
return mp, p.id, &p.tracebuf
|
|
}
|
|
lock(&trace.bufLock)
|
|
return mp, traceGlobProc, &trace.buf
|
|
}
|
|
|
|
// traceReleaseBuffer releases a buffer previously acquired with traceAcquireBuffer.
|
|
func traceReleaseBuffer(pid int32) {
|
|
if pid == traceGlobProc {
|
|
unlock(&trace.bufLock)
|
|
}
|
|
releasem(getg().m)
|
|
}
|
|
|
|
// traceFlush puts buf onto stack of full buffers and returns an empty buffer.
|
|
func traceFlush(buf *traceBuf) *traceBuf {
|
|
owner := trace.lockOwner
|
|
dolock := owner == nil || owner != getg().m.curg
|
|
if dolock {
|
|
lock(&trace.lock)
|
|
}
|
|
if buf != nil {
|
|
if &buf.buf[0] != &buf.arr[0] {
|
|
throw("trace buffer overflow")
|
|
}
|
|
traceFullQueue(buf)
|
|
}
|
|
if trace.empty != nil {
|
|
buf = trace.empty
|
|
trace.empty = buf.link
|
|
} else {
|
|
buf = (*traceBuf)(sysAlloc(unsafe.Sizeof(traceBuf{}), &memstats.other_sys))
|
|
if buf == nil {
|
|
throw("trace: out of memory")
|
|
}
|
|
}
|
|
buf.link = nil
|
|
buf.buf = buf.arr[:0]
|
|
buf.lastTicks = 0
|
|
if dolock {
|
|
unlock(&trace.lock)
|
|
}
|
|
return buf
|
|
}
|
|
|
|
// traceAppend appends v to buf in little-endian-base-128 encoding.
|
|
func traceAppend(buf []byte, v uint64) []byte {
|
|
for ; v >= 0x80; v >>= 7 {
|
|
buf = append(buf, 0x80|byte(v))
|
|
}
|
|
buf = append(buf, byte(v))
|
|
return buf
|
|
}
|
|
|
|
// traceStackTable maps stack traces (arrays of PC's) to unique uint32 ids.
|
|
// It is lock-free for reading.
|
|
type traceStackTable struct {
|
|
lock mutex
|
|
seq uint32
|
|
mem traceAlloc
|
|
tab [1 << 13]*traceStack
|
|
}
|
|
|
|
// traceStack is a single stack in traceStackTable.
|
|
type traceStack struct {
|
|
link *traceStack
|
|
hash uintptr
|
|
id uint32
|
|
n int
|
|
stk [0]uintptr // real type [n]uintptr
|
|
}
|
|
|
|
// stack returns slice of PCs.
|
|
func (ts *traceStack) stack() []uintptr {
|
|
return (*[traceStackSize]uintptr)(unsafe.Pointer(&ts.stk))[:ts.n]
|
|
}
|
|
|
|
// put returns a unique id for the stack trace pcs and caches it in the table,
|
|
// if it sees the trace for the first time.
|
|
func (tab *traceStackTable) put(pcs []uintptr) uint32 {
|
|
if len(pcs) == 0 {
|
|
return 0
|
|
}
|
|
hash := memhash(unsafe.Pointer(&pcs[0]), uintptr(len(pcs))*unsafe.Sizeof(pcs[0]), 0)
|
|
// First, search the hashtable w/o the mutex.
|
|
if id := tab.find(pcs, hash); id != 0 {
|
|
return id
|
|
}
|
|
// Now, double check under the mutex.
|
|
lock(&tab.lock)
|
|
if id := tab.find(pcs, hash); id != 0 {
|
|
unlock(&tab.lock)
|
|
return id
|
|
}
|
|
// Create new record.
|
|
tab.seq++
|
|
stk := tab.newStack(len(pcs))
|
|
stk.hash = hash
|
|
stk.id = tab.seq
|
|
stk.n = len(pcs)
|
|
stkpc := stk.stack()
|
|
for i, pc := range pcs {
|
|
stkpc[i] = pc
|
|
}
|
|
part := int(hash % uintptr(len(tab.tab)))
|
|
stk.link = tab.tab[part]
|
|
atomicstorep(unsafe.Pointer(&tab.tab[part]), unsafe.Pointer(stk))
|
|
unlock(&tab.lock)
|
|
return stk.id
|
|
}
|
|
|
|
// find checks if the stack trace pcs is already present in the table.
|
|
func (tab *traceStackTable) find(pcs []uintptr, hash uintptr) uint32 {
|
|
part := int(hash % uintptr(len(tab.tab)))
|
|
Search:
|
|
for stk := tab.tab[part]; stk != nil; stk = stk.link {
|
|
if stk.hash == hash && stk.n == len(pcs) {
|
|
for i, stkpc := range stk.stack() {
|
|
if stkpc != pcs[i] {
|
|
continue Search
|
|
}
|
|
}
|
|
return stk.id
|
|
}
|
|
}
|
|
return 0
|
|
}
|
|
|
|
// newStack allocates a new stack of size n.
|
|
func (tab *traceStackTable) newStack(n int) *traceStack {
|
|
return (*traceStack)(tab.mem.alloc(unsafe.Sizeof(traceStack{}) + uintptr(n)*ptrSize))
|
|
}
|
|
|
|
// dump writes all previously cached stacks to trace buffers,
|
|
// releases all memory and resets state.
|
|
func (tab *traceStackTable) dump() {
|
|
var tmp [(2 + traceStackSize) * traceBytesPerNumber]byte
|
|
buf := traceFlush(nil)
|
|
for _, stk := range tab.tab {
|
|
for ; stk != nil; stk = stk.link {
|
|
maxSize := 1 + (3+stk.n)*traceBytesPerNumber
|
|
if cap(buf.buf)-len(buf.buf) < maxSize {
|
|
buf = traceFlush(buf)
|
|
}
|
|
// Form the event in the temp buffer, we need to know the actual length.
|
|
tmpbuf := tmp[:0]
|
|
tmpbuf = traceAppend(tmpbuf, uint64(stk.id))
|
|
tmpbuf = traceAppend(tmpbuf, uint64(stk.n))
|
|
for _, pc := range stk.stack() {
|
|
tmpbuf = traceAppend(tmpbuf, uint64(pc))
|
|
}
|
|
// Now copy to the buffer.
|
|
data := buf.buf
|
|
data = append(data, traceEvStack|3<<traceArgCountShift)
|
|
data = traceAppend(data, uint64(len(tmpbuf)))
|
|
data = append(data, tmpbuf...)
|
|
buf.buf = data
|
|
}
|
|
}
|
|
|
|
lock(&trace.lock)
|
|
traceFullQueue(buf)
|
|
unlock(&trace.lock)
|
|
|
|
tab.mem.drop()
|
|
*tab = traceStackTable{}
|
|
}
|
|
|
|
// traceAlloc is a non-thread-safe region allocator.
|
|
// It holds a linked list of traceAllocBlock.
|
|
type traceAlloc struct {
|
|
head *traceAllocBlock
|
|
off uintptr
|
|
}
|
|
|
|
// traceAllocBlock is a block in traceAlloc.
|
|
type traceAllocBlock struct {
|
|
next *traceAllocBlock
|
|
data [64<<10 - ptrSize]byte
|
|
}
|
|
|
|
// alloc allocates n-byte block.
|
|
func (a *traceAlloc) alloc(n uintptr) unsafe.Pointer {
|
|
n = round(n, ptrSize)
|
|
if a.head == nil || a.off+n > uintptr(len(a.head.data)) {
|
|
if n > uintptr(len(a.head.data)) {
|
|
throw("trace: alloc too large")
|
|
}
|
|
block := (*traceAllocBlock)(sysAlloc(unsafe.Sizeof(traceAllocBlock{}), &memstats.other_sys))
|
|
if block == nil {
|
|
throw("trace: out of memory")
|
|
}
|
|
block.next = a.head
|
|
a.head = block
|
|
a.off = 0
|
|
}
|
|
p := &a.head.data[a.off]
|
|
a.off += n
|
|
return unsafe.Pointer(p)
|
|
}
|
|
|
|
// drop frees all previously allocated memory and resets the allocator.
|
|
func (a *traceAlloc) drop() {
|
|
for a.head != nil {
|
|
block := a.head
|
|
a.head = block.next
|
|
sysFree(unsafe.Pointer(block), unsafe.Sizeof(traceAllocBlock{}), &memstats.other_sys)
|
|
}
|
|
}
|
|
|
|
// The following functions write specific events to trace.
|
|
|
|
func traceGomaxprocs(procs int32) {
|
|
traceEvent(traceEvGomaxprocs, 1, uint64(procs))
|
|
}
|
|
|
|
func traceProcStart() {
|
|
traceEvent(traceEvProcStart, -1, uint64(getg().m.id))
|
|
}
|
|
|
|
func traceProcStop(pp *p) {
|
|
// Sysmon and stopTheWorld can stop Ps blocked in syscalls,
|
|
// to handle this we temporary employ the P.
|
|
mp := acquirem()
|
|
oldp := mp.p
|
|
mp.p.set(pp)
|
|
traceEvent(traceEvProcStop, -1)
|
|
mp.p = oldp
|
|
releasem(mp)
|
|
}
|
|
|
|
func traceGCStart() {
|
|
traceEvent(traceEvGCStart, 4)
|
|
}
|
|
|
|
func traceGCDone() {
|
|
traceEvent(traceEvGCDone, -1)
|
|
}
|
|
|
|
func traceGCScanStart() {
|
|
traceEvent(traceEvGCScanStart, -1)
|
|
}
|
|
|
|
func traceGCScanDone() {
|
|
traceEvent(traceEvGCScanDone, -1)
|
|
}
|
|
|
|
func traceGCSweepStart() {
|
|
traceEvent(traceEvGCSweepStart, 1)
|
|
}
|
|
|
|
func traceGCSweepDone() {
|
|
traceEvent(traceEvGCSweepDone, -1)
|
|
}
|
|
|
|
func traceGoCreate(newg *g, pc uintptr) {
|
|
traceEvent(traceEvGoCreate, 2, uint64(newg.goid), uint64(pc))
|
|
}
|
|
|
|
func traceGoStart() {
|
|
traceEvent(traceEvGoStart, -1, uint64(getg().m.curg.goid))
|
|
}
|
|
|
|
func traceGoEnd() {
|
|
traceEvent(traceEvGoEnd, -1)
|
|
}
|
|
|
|
func traceGoSched() {
|
|
traceEvent(traceEvGoSched, 1)
|
|
}
|
|
|
|
func traceGoPreempt() {
|
|
traceEvent(traceEvGoPreempt, 1)
|
|
}
|
|
|
|
func traceGoPark(traceEv byte, skip int, gp *g) {
|
|
if traceEv&traceFutileWakeup != 0 {
|
|
traceEvent(traceEvFutileWakeup, -1)
|
|
}
|
|
traceEvent(traceEv & ^traceFutileWakeup, skip)
|
|
}
|
|
|
|
func traceGoUnpark(gp *g, skip int) {
|
|
traceEvent(traceEvGoUnblock, skip, uint64(gp.goid))
|
|
}
|
|
|
|
func traceGoSysCall() {
|
|
traceEvent(traceEvGoSysCall, 4)
|
|
}
|
|
|
|
func traceGoSysExit(ts int64) {
|
|
if ts != 0 && ts < trace.ticksStart {
|
|
// The timestamp was obtained during a previous tracing session, ignore.
|
|
return
|
|
}
|
|
traceEvent(traceEvGoSysExit, -1, uint64(getg().m.curg.goid), uint64(ts)/traceTickDiv)
|
|
}
|
|
|
|
func traceGoSysBlock(pp *p) {
|
|
// Sysmon and stopTheWorld can declare syscalls running on remote Ps as blocked,
|
|
// to handle this we temporary employ the P.
|
|
mp := acquirem()
|
|
oldp := mp.p
|
|
mp.p.set(pp)
|
|
traceEvent(traceEvGoSysBlock, -1)
|
|
mp.p = oldp
|
|
releasem(mp)
|
|
}
|
|
|
|
func traceHeapAlloc() {
|
|
traceEvent(traceEvHeapAlloc, -1, memstats.heap_live)
|
|
}
|
|
|
|
func traceNextGC() {
|
|
traceEvent(traceEvNextGC, -1, memstats.next_gc)
|
|
}
|