1
0
mirror of https://github.com/golang/go synced 2024-11-19 14:24:47 -07:00
go/src/runtime/trace.go
Austin Clements 22000f5407 runtime: record swept and reclaimed bytes in sweep trace
This extends the GCSweepDone event with counts of swept and reclaimed
bytes. These are useful for understanding the duration and
effectiveness of sweep events.

Change-Id: I3c97a4f0f3aad3adbd188adb264859775f54e2df
Reviewed-on: https://go-review.googlesource.com/40811
Run-TryBot: Austin Clements <austin@google.com>
TryBot-Result: Gobot Gobot <gobot@golang.org>
Reviewed-by: Hyang-Ah Hana Kim <hyangah@gmail.com>
2017-04-19 18:31:14 +00:00

1085 lines
34 KiB
Go

// Copyright 2014 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Go execution tracer.
// The tracer captures a wide range of execution events like goroutine
// creation/blocking/unblocking, syscall enter/exit/block, GC-related events,
// changes of heap size, processor start/stop, etc and writes them to a buffer
// in a compact form. A precise nanosecond-precision timestamp and a stack
// trace is captured for most events.
// See https://golang.org/s/go15trace for more info.
package runtime
import (
"runtime/internal/sys"
"unsafe"
)
// Event types in the trace, args are given in square brackets.
const (
traceEvNone = 0 // unused
traceEvBatch = 1 // start of per-P batch of events [pid, timestamp]
traceEvFrequency = 2 // contains tracer timer frequency [frequency (ticks per second)]
traceEvStack = 3 // stack [stack id, number of PCs, array of {PC, func string ID, file string ID, line}]
traceEvGomaxprocs = 4 // current value of GOMAXPROCS [timestamp, GOMAXPROCS, stack id]
traceEvProcStart = 5 // start of P [timestamp, thread id]
traceEvProcStop = 6 // stop of P [timestamp]
traceEvGCStart = 7 // GC start [timestamp, seq, stack id]
traceEvGCDone = 8 // GC done [timestamp]
traceEvGCScanStart = 9 // GC mark termination start [timestamp]
traceEvGCScanDone = 10 // GC mark termination done [timestamp]
traceEvGCSweepStart = 11 // GC sweep start [timestamp, stack id]
traceEvGCSweepDone = 12 // GC sweep done [timestamp, swept, reclaimed]
traceEvGoCreate = 13 // goroutine creation [timestamp, new goroutine id, new stack id, stack id]
traceEvGoStart = 14 // goroutine starts running [timestamp, goroutine id, seq]
traceEvGoEnd = 15 // goroutine ends [timestamp]
traceEvGoStop = 16 // goroutine stops (like in select{}) [timestamp, stack]
traceEvGoSched = 17 // goroutine calls Gosched [timestamp, stack]
traceEvGoPreempt = 18 // goroutine is preempted [timestamp, stack]
traceEvGoSleep = 19 // goroutine calls Sleep [timestamp, stack]
traceEvGoBlock = 20 // goroutine blocks [timestamp, stack]
traceEvGoUnblock = 21 // goroutine is unblocked [timestamp, goroutine id, seq, stack]
traceEvGoBlockSend = 22 // goroutine blocks on chan send [timestamp, stack]
traceEvGoBlockRecv = 23 // goroutine blocks on chan recv [timestamp, stack]
traceEvGoBlockSelect = 24 // goroutine blocks on select [timestamp, stack]
traceEvGoBlockSync = 25 // goroutine blocks on Mutex/RWMutex [timestamp, stack]
traceEvGoBlockCond = 26 // goroutine blocks on Cond [timestamp, stack]
traceEvGoBlockNet = 27 // goroutine blocks on network [timestamp, stack]
traceEvGoSysCall = 28 // syscall enter [timestamp, stack]
traceEvGoSysExit = 29 // syscall exit [timestamp, goroutine id, seq, real timestamp]
traceEvGoSysBlock = 30 // syscall blocks [timestamp]
traceEvGoWaiting = 31 // denotes that goroutine is blocked when tracing starts [timestamp, goroutine id]
traceEvGoInSyscall = 32 // denotes that goroutine is in syscall when tracing starts [timestamp, goroutine id]
traceEvHeapAlloc = 33 // memstats.heap_live change [timestamp, heap_alloc]
traceEvNextGC = 34 // memstats.next_gc change [timestamp, next_gc]
traceEvTimerGoroutine = 35 // denotes timer goroutine [timer goroutine id]
traceEvFutileWakeup = 36 // denotes that the previous wakeup of this goroutine was futile [timestamp]
traceEvString = 37 // string dictionary entry [ID, length, string]
traceEvGoStartLocal = 38 // goroutine starts running on the same P as the last event [timestamp, goroutine id]
traceEvGoUnblockLocal = 39 // goroutine is unblocked on the same P as the last event [timestamp, goroutine id, stack]
traceEvGoSysExitLocal = 40 // syscall exit on the same P as the last event [timestamp, goroutine id, real timestamp]
traceEvGoStartLabel = 41 // goroutine starts running with label [timestamp, goroutine id, seq, label string id]
traceEvGoBlockGC = 42 // goroutine blocks on GC assist [timestamp, stack]
traceEvGCMarkAssistStart = 43 // GC mark assist start [timestamp, stack]
traceEvGCMarkAssistDone = 44 // GC mark assist done [timestamp]
traceEvCount = 45
)
const (
// Timestamps in trace are cputicks/traceTickDiv.
// This makes absolute values of timestamp diffs smaller,
// and so they are encoded in less number of bytes.
// 64 on x86 is somewhat arbitrary (one tick is ~20ns on a 3GHz machine).
// The suggested increment frequency for PowerPC's time base register is
// 512 MHz according to Power ISA v2.07 section 6.2, so we use 16 on ppc64
// and ppc64le.
// Tracing won't work reliably for architectures where cputicks is emulated
// by nanotime, so the value doesn't matter for those architectures.
traceTickDiv = 16 + 48*(sys.Goarch386|sys.GoarchAmd64|sys.GoarchAmd64p32)
// Maximum number of PCs in a single stack trace.
// Since events contain only stack id rather than whole stack trace,
// we can allow quite large values here.
traceStackSize = 128
// Identifier of a fake P that is used when we trace without a real P.
traceGlobProc = -1
// Maximum number of bytes to encode uint64 in base-128.
traceBytesPerNumber = 10
// Shift of the number of arguments in the first event byte.
traceArgCountShift = 6
// Flag passed to traceGoPark to denote that the previous wakeup of this
// goroutine was futile. For example, a goroutine was unblocked on a mutex,
// but another goroutine got ahead and acquired the mutex before the first
// goroutine is scheduled, so the first goroutine has to block again.
// Such wakeups happen on buffered channels and sync.Mutex,
// but are generally not interesting for end user.
traceFutileWakeup byte = 128
)
// trace is global tracing context.
var trace struct {
lock mutex // protects the following members
lockOwner *g // to avoid deadlocks during recursive lock locks
enabled bool // when set runtime traces events
shutdown bool // set when we are waiting for trace reader to finish after setting enabled to false
headerWritten bool // whether ReadTrace has emitted trace header
footerWritten bool // whether ReadTrace has emitted trace footer
shutdownSema uint32 // used to wait for ReadTrace completion
seqStart uint64 // sequence number when tracing was started
ticksStart int64 // cputicks when tracing was started
ticksEnd int64 // cputicks when tracing was stopped
timeStart int64 // nanotime when tracing was started
timeEnd int64 // nanotime when tracing was stopped
seqGC uint64 // GC start/done sequencer
reading traceBufPtr // buffer currently handed off to user
empty traceBufPtr // stack of empty buffers
fullHead traceBufPtr // queue of full buffers
fullTail traceBufPtr
reader guintptr // goroutine that called ReadTrace, or nil
stackTab traceStackTable // maps stack traces to unique ids
// Dictionary for traceEvString.
//
// Currently this is used only at trace setup and for
// func/file:line info after tracing session, so we assume
// single-threaded access.
strings map[string]uint64
stringSeq uint64
// markWorkerLabels maps gcMarkWorkerMode to string ID.
markWorkerLabels [len(gcMarkWorkerModeStrings)]uint64
bufLock mutex // protects buf
buf traceBufPtr // global trace buffer, used when running without a p
}
// traceBufHeader is per-P tracing buffer.
type traceBufHeader struct {
link traceBufPtr // in trace.empty/full
lastTicks uint64 // when we wrote the last event
pos int // next write offset in arr
stk [traceStackSize]uintptr // scratch buffer for traceback
}
// traceBuf is per-P tracing buffer.
//
//go:notinheap
type traceBuf struct {
traceBufHeader
arr [64<<10 - unsafe.Sizeof(traceBufHeader{})]byte // underlying buffer for traceBufHeader.buf
}
// traceBufPtr is a *traceBuf that is not traced by the garbage
// collector and doesn't have write barriers. traceBufs are not
// allocated from the GC'd heap, so this is safe, and are often
// manipulated in contexts where write barriers are not allowed, so
// this is necessary.
//
// TODO: Since traceBuf is now go:notinheap, this isn't necessary.
type traceBufPtr uintptr
func (tp traceBufPtr) ptr() *traceBuf { return (*traceBuf)(unsafe.Pointer(tp)) }
func (tp *traceBufPtr) set(b *traceBuf) { *tp = traceBufPtr(unsafe.Pointer(b)) }
func traceBufPtrOf(b *traceBuf) traceBufPtr {
return traceBufPtr(unsafe.Pointer(b))
}
// StartTrace enables tracing for the current process.
// While tracing, the data will be buffered and available via ReadTrace.
// StartTrace returns an error if tracing is already enabled.
// Most clients should use the runtime/trace package or the testing package's
// -test.trace flag instead of calling StartTrace directly.
func StartTrace() error {
// Stop the world, so that we can take a consistent snapshot
// of all goroutines at the beginning of the trace.
stopTheWorld("start tracing")
// We are in stop-the-world, but syscalls can finish and write to trace concurrently.
// Exitsyscall could check trace.enabled long before and then suddenly wake up
// and decide to write to trace at a random point in time.
// However, such syscall will use the global trace.buf buffer, because we've
// acquired all p's by doing stop-the-world. So this protects us from such races.
lock(&trace.bufLock)
if trace.enabled || trace.shutdown {
unlock(&trace.bufLock)
startTheWorld()
return errorString("tracing is already enabled")
}
// Can't set trace.enabled yet. While the world is stopped, exitsyscall could
// already emit a delayed event (see exitTicks in exitsyscall) if we set trace.enabled here.
// That would lead to an inconsistent trace:
// - either GoSysExit appears before EvGoInSyscall,
// - or GoSysExit appears for a goroutine for which we don't emit EvGoInSyscall below.
// To instruct traceEvent that it must not ignore events below, we set startingtrace.
// trace.enabled is set afterwards once we have emitted all preliminary events.
_g_ := getg()
_g_.m.startingtrace = true
// Obtain current stack ID to use in all traceEvGoCreate events below.
mp := acquirem()
stkBuf := make([]uintptr, traceStackSize)
stackID := traceStackID(mp, stkBuf, 2)
releasem(mp)
for _, gp := range allgs {
status := readgstatus(gp)
if status != _Gdead {
gp.traceseq = 0
gp.tracelastp = getg().m.p
// +PCQuantum because traceFrameForPC expects return PCs and subtracts PCQuantum.
id := trace.stackTab.put([]uintptr{gp.startpc + sys.PCQuantum})
traceEvent(traceEvGoCreate, -1, uint64(gp.goid), uint64(id), stackID)
}
if status == _Gwaiting {
// traceEvGoWaiting is implied to have seq=1.
gp.traceseq++
traceEvent(traceEvGoWaiting, -1, uint64(gp.goid))
}
if status == _Gsyscall {
gp.traceseq++
traceEvent(traceEvGoInSyscall, -1, uint64(gp.goid))
} else {
gp.sysblocktraced = false
}
}
traceProcStart()
traceGoStart()
// Note: ticksStart needs to be set after we emit traceEvGoInSyscall events.
// If we do it the other way around, it is possible that exitsyscall will
// query sysexitticks after ticksStart but before traceEvGoInSyscall timestamp.
// It will lead to a false conclusion that cputicks is broken.
trace.ticksStart = cputicks()
trace.timeStart = nanotime()
trace.headerWritten = false
trace.footerWritten = false
trace.strings = make(map[string]uint64)
trace.stringSeq = 0
trace.seqGC = 0
_g_.m.startingtrace = false
trace.enabled = true
// Register runtime goroutine labels.
_, pid, bufp := traceAcquireBuffer()
buf := (*bufp).ptr()
if buf == nil {
buf = traceFlush(0).ptr()
(*bufp).set(buf)
}
for i, label := range gcMarkWorkerModeStrings[:] {
trace.markWorkerLabels[i], buf = traceString(buf, label)
}
traceReleaseBuffer(pid)
unlock(&trace.bufLock)
startTheWorld()
return nil
}
// StopTrace stops tracing, if it was previously enabled.
// StopTrace only returns after all the reads for the trace have completed.
func StopTrace() {
// Stop the world so that we can collect the trace buffers from all p's below,
// and also to avoid races with traceEvent.
stopTheWorld("stop tracing")
// See the comment in StartTrace.
lock(&trace.bufLock)
if !trace.enabled {
unlock(&trace.bufLock)
startTheWorld()
return
}
traceGoSched()
for _, p := range &allp {
if p == nil {
break
}
buf := p.tracebuf
if buf != 0 {
traceFullQueue(buf)
p.tracebuf = 0
}
}
if trace.buf != 0 {
buf := trace.buf
trace.buf = 0
if buf.ptr().pos != 0 {
traceFullQueue(buf)
}
}
for {
trace.ticksEnd = cputicks()
trace.timeEnd = nanotime()
// Windows time can tick only every 15ms, wait for at least one tick.
if trace.timeEnd != trace.timeStart {
break
}
osyield()
}
trace.enabled = false
trace.shutdown = true
unlock(&trace.bufLock)
startTheWorld()
// The world is started but we've set trace.shutdown, so new tracing can't start.
// Wait for the trace reader to flush pending buffers and stop.
semacquire(&trace.shutdownSema)
if raceenabled {
raceacquire(unsafe.Pointer(&trace.shutdownSema))
}
// The lock protects us from races with StartTrace/StopTrace because they do stop-the-world.
lock(&trace.lock)
for _, p := range &allp {
if p == nil {
break
}
if p.tracebuf != 0 {
throw("trace: non-empty trace buffer in proc")
}
}
if trace.buf != 0 {
throw("trace: non-empty global trace buffer")
}
if trace.fullHead != 0 || trace.fullTail != 0 {
throw("trace: non-empty full trace buffer")
}
if trace.reading != 0 || trace.reader != 0 {
throw("trace: reading after shutdown")
}
for trace.empty != 0 {
buf := trace.empty
trace.empty = buf.ptr().link
sysFree(unsafe.Pointer(buf), unsafe.Sizeof(*buf.ptr()), &memstats.other_sys)
}
trace.strings = nil
trace.shutdown = false
unlock(&trace.lock)
}
// ReadTrace returns the next chunk of binary tracing data, blocking until data
// is available. If tracing is turned off and all the data accumulated while it
// was on has been returned, ReadTrace returns nil. The caller must copy the
// returned data before calling ReadTrace again.
// ReadTrace must be called from one goroutine at a time.
func ReadTrace() []byte {
// This function may need to lock trace.lock recursively
// (goparkunlock -> traceGoPark -> traceEvent -> traceFlush).
// To allow this we use trace.lockOwner.
// Also this function must not allocate while holding trace.lock:
// allocation can call heap allocate, which will try to emit a trace
// event while holding heap lock.
lock(&trace.lock)
trace.lockOwner = getg()
if trace.reader != 0 {
// More than one goroutine reads trace. This is bad.
// But we rather do not crash the program because of tracing,
// because tracing can be enabled at runtime on prod servers.
trace.lockOwner = nil
unlock(&trace.lock)
println("runtime: ReadTrace called from multiple goroutines simultaneously")
return nil
}
// Recycle the old buffer.
if buf := trace.reading; buf != 0 {
buf.ptr().link = trace.empty
trace.empty = buf
trace.reading = 0
}
// Write trace header.
if !trace.headerWritten {
trace.headerWritten = true
trace.lockOwner = nil
unlock(&trace.lock)
return []byte("go 1.9 trace\x00\x00\x00\x00")
}
// Wait for new data.
if trace.fullHead == 0 && !trace.shutdown {
trace.reader.set(getg())
goparkunlock(&trace.lock, "trace reader (blocked)", traceEvGoBlock, 2)
lock(&trace.lock)
}
// Write a buffer.
if trace.fullHead != 0 {
buf := traceFullDequeue()
trace.reading = buf
trace.lockOwner = nil
unlock(&trace.lock)
return buf.ptr().arr[:buf.ptr().pos]
}
// Write footer with timer frequency.
if !trace.footerWritten {
trace.footerWritten = true
// Use float64 because (trace.ticksEnd - trace.ticksStart) * 1e9 can overflow int64.
freq := float64(trace.ticksEnd-trace.ticksStart) * 1e9 / float64(trace.timeEnd-trace.timeStart) / traceTickDiv
trace.lockOwner = nil
unlock(&trace.lock)
var data []byte
data = append(data, traceEvFrequency|0<<traceArgCountShift)
data = traceAppend(data, uint64(freq))
if timers.gp != nil {
data = append(data, traceEvTimerGoroutine|0<<traceArgCountShift)
data = traceAppend(data, uint64(timers.gp.goid))
}
// This will emit a bunch of full buffers, we will pick them up
// on the next iteration.
trace.stackTab.dump()
return data
}
// Done.
if trace.shutdown {
trace.lockOwner = nil
unlock(&trace.lock)
if raceenabled {
// Model synchronization on trace.shutdownSema, which race
// detector does not see. This is required to avoid false
// race reports on writer passed to trace.Start.
racerelease(unsafe.Pointer(&trace.shutdownSema))
}
// trace.enabled is already reset, so can call traceable functions.
semrelease(&trace.shutdownSema)
return nil
}
// Also bad, but see the comment above.
trace.lockOwner = nil
unlock(&trace.lock)
println("runtime: spurious wakeup of trace reader")
return nil
}
// traceReader returns the trace reader that should be woken up, if any.
func traceReader() *g {
if trace.reader == 0 || (trace.fullHead == 0 && !trace.shutdown) {
return nil
}
lock(&trace.lock)
if trace.reader == 0 || (trace.fullHead == 0 && !trace.shutdown) {
unlock(&trace.lock)
return nil
}
gp := trace.reader.ptr()
trace.reader.set(nil)
unlock(&trace.lock)
return gp
}
// traceProcFree frees trace buffer associated with pp.
func traceProcFree(pp *p) {
buf := pp.tracebuf
pp.tracebuf = 0
if buf == 0 {
return
}
lock(&trace.lock)
traceFullQueue(buf)
unlock(&trace.lock)
}
// traceFullQueue queues buf into queue of full buffers.
func traceFullQueue(buf traceBufPtr) {
buf.ptr().link = 0
if trace.fullHead == 0 {
trace.fullHead = buf
} else {
trace.fullTail.ptr().link = buf
}
trace.fullTail = buf
}
// traceFullDequeue dequeues from queue of full buffers.
func traceFullDequeue() traceBufPtr {
buf := trace.fullHead
if buf == 0 {
return 0
}
trace.fullHead = buf.ptr().link
if trace.fullHead == 0 {
trace.fullTail = 0
}
buf.ptr().link = 0
return buf
}
// traceEvent writes a single event to trace buffer, flushing the buffer if necessary.
// ev is event type.
// If skip > 0, write current stack id as the last argument (skipping skip top frames).
// If skip = 0, this event type should contain a stack, but we don't want
// to collect and remember it for this particular call.
func traceEvent(ev byte, skip int, args ...uint64) {
mp, pid, bufp := traceAcquireBuffer()
// Double-check trace.enabled now that we've done m.locks++ and acquired bufLock.
// This protects from races between traceEvent and StartTrace/StopTrace.
// The caller checked that trace.enabled == true, but trace.enabled might have been
// turned off between the check and now. Check again. traceLockBuffer did mp.locks++,
// StopTrace does stopTheWorld, and stopTheWorld waits for mp.locks to go back to zero,
// so if we see trace.enabled == true now, we know it's true for the rest of the function.
// Exitsyscall can run even during stopTheWorld. The race with StartTrace/StopTrace
// during tracing in exitsyscall is resolved by locking trace.bufLock in traceLockBuffer.
if !trace.enabled && !mp.startingtrace {
traceReleaseBuffer(pid)
return
}
buf := (*bufp).ptr()
const maxSize = 2 + 5*traceBytesPerNumber // event type, length, sequence, timestamp, stack id and two add params
if buf == nil || len(buf.arr)-buf.pos < maxSize {
buf = traceFlush(traceBufPtrOf(buf)).ptr()
(*bufp).set(buf)
}
ticks := uint64(cputicks()) / traceTickDiv
tickDiff := ticks - buf.lastTicks
if buf.pos == 0 {
buf.byte(traceEvBatch | 1<<traceArgCountShift)
buf.varint(uint64(pid))
buf.varint(ticks)
tickDiff = 0
}
buf.lastTicks = ticks
narg := byte(len(args))
if skip >= 0 {
narg++
}
// We have only 2 bits for number of arguments.
// If number is >= 3, then the event type is followed by event length in bytes.
if narg > 3 {
narg = 3
}
startPos := buf.pos
buf.byte(ev | narg<<traceArgCountShift)
var lenp *byte
if narg == 3 {
// Reserve the byte for length assuming that length < 128.
buf.varint(0)
lenp = &buf.arr[buf.pos-1]
}
buf.varint(tickDiff)
for _, a := range args {
buf.varint(a)
}
if skip == 0 {
buf.varint(0)
} else if skip > 0 {
buf.varint(traceStackID(mp, buf.stk[:], skip))
}
evSize := buf.pos - startPos
if evSize > maxSize {
throw("invalid length of trace event")
}
if lenp != nil {
// Fill in actual length.
*lenp = byte(evSize - 2)
}
traceReleaseBuffer(pid)
}
func traceStackID(mp *m, buf []uintptr, skip int) uint64 {
_g_ := getg()
gp := mp.curg
var nstk int
if gp == _g_ {
nstk = callers(skip+1, buf[:])
} else if gp != nil {
gp = mp.curg
nstk = gcallers(gp, skip, buf[:])
}
if nstk > 0 {
nstk-- // skip runtime.goexit
}
if nstk > 0 && gp.goid == 1 {
nstk-- // skip runtime.main
}
id := trace.stackTab.put(buf[:nstk])
return uint64(id)
}
// traceAcquireBuffer returns trace buffer to use and, if necessary, locks it.
func traceAcquireBuffer() (mp *m, pid int32, bufp *traceBufPtr) {
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 traceBufPtr) traceBufPtr {
owner := trace.lockOwner
dolock := owner == nil || owner != getg().m.curg
if dolock {
lock(&trace.lock)
}
if buf != 0 {
traceFullQueue(buf)
}
if trace.empty != 0 {
buf = trace.empty
trace.empty = buf.ptr().link
} else {
buf = traceBufPtr(sysAlloc(unsafe.Sizeof(traceBuf{}), &memstats.other_sys))
if buf == 0 {
throw("trace: out of memory")
}
}
bufp := buf.ptr()
bufp.link.set(nil)
bufp.pos = 0
bufp.lastTicks = 0
if dolock {
unlock(&trace.lock)
}
return buf
}
func traceString(buf *traceBuf, s string) (uint64, *traceBuf) {
if s == "" {
return 0, buf
}
if id, ok := trace.strings[s]; ok {
return id, buf
}
trace.stringSeq++
id := trace.stringSeq
trace.strings[s] = id
size := 1 + 2*traceBytesPerNumber + len(s)
if len(buf.arr)-buf.pos < size {
buf = traceFlush(traceBufPtrOf(buf)).ptr()
}
buf.byte(traceEvString)
buf.varint(id)
buf.varint(uint64(len(s)))
buf.pos += copy(buf.arr[buf.pos:], s)
return id, 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
}
// varint appends v to buf in little-endian-base-128 encoding.
func (buf *traceBuf) varint(v uint64) {
pos := buf.pos
for ; v >= 0x80; v >>= 7 {
buf.arr[pos] = 0x80 | byte(v)
pos++
}
buf.arr[pos] = byte(v)
pos++
buf.pos = pos
}
// byte appends v to buf.
func (buf *traceBuf) byte(v byte) {
buf.arr[buf.pos] = v
buf.pos++
}
// 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]traceStackPtr
}
// traceStack is a single stack in traceStackTable.
type traceStack struct {
link traceStackPtr
hash uintptr
id uint32
n int
stk [0]uintptr // real type [n]uintptr
}
type traceStackPtr uintptr
func (tp traceStackPtr) ptr() *traceStack { return (*traceStack)(unsafe.Pointer(tp)) }
// 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]), 0, uintptr(len(pcs))*unsafe.Sizeof(pcs[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].ptr(); stk != nil; stk = stk.link.ptr() {
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)*sys.PtrSize))
}
// allFrames returns all of the Frames corresponding to pcs.
func allFrames(pcs []uintptr) []Frame {
frames := make([]Frame, 0, len(pcs))
ci := CallersFrames(pcs)
for {
f, more := ci.Next()
frames = append(frames, f)
if !more {
return frames
}
}
}
// dump writes all previously cached stacks to trace buffers,
// releases all memory and resets state.
func (tab *traceStackTable) dump() {
var tmp [(2 + 4*traceStackSize) * traceBytesPerNumber]byte
buf := traceFlush(0).ptr()
for _, stk := range tab.tab {
stk := stk.ptr()
for ; stk != nil; stk = stk.link.ptr() {
tmpbuf := tmp[:0]
tmpbuf = traceAppend(tmpbuf, uint64(stk.id))
frames := allFrames(stk.stack())
tmpbuf = traceAppend(tmpbuf, uint64(len(frames)))
for _, f := range frames {
var frame traceFrame
frame, buf = traceFrameForPC(buf, f)
tmpbuf = traceAppend(tmpbuf, uint64(f.PC))
tmpbuf = traceAppend(tmpbuf, uint64(frame.funcID))
tmpbuf = traceAppend(tmpbuf, uint64(frame.fileID))
tmpbuf = traceAppend(tmpbuf, uint64(frame.line))
}
// Now copy to the buffer.
size := 1 + traceBytesPerNumber + len(tmpbuf)
if len(buf.arr)-buf.pos < size {
buf = traceFlush(traceBufPtrOf(buf)).ptr()
}
buf.byte(traceEvStack | 3<<traceArgCountShift)
buf.varint(uint64(len(tmpbuf)))
buf.pos += copy(buf.arr[buf.pos:], tmpbuf)
}
}
lock(&trace.lock)
traceFullQueue(traceBufPtrOf(buf))
unlock(&trace.lock)
tab.mem.drop()
*tab = traceStackTable{}
}
type traceFrame struct {
funcID uint64
fileID uint64
line uint64
}
func traceFrameForPC(buf *traceBuf, f Frame) (traceFrame, *traceBuf) {
var frame traceFrame
fn := f.Function
const maxLen = 1 << 10
if len(fn) > maxLen {
fn = fn[len(fn)-maxLen:]
}
frame.funcID, buf = traceString(buf, fn)
frame.line = uint64(f.Line)
file := f.File
if len(file) > maxLen {
file = file[len(file)-maxLen:]
}
frame.fileID, buf = traceString(buf, file)
return frame, buf
}
// traceAlloc is a non-thread-safe region allocator.
// It holds a linked list of traceAllocBlock.
type traceAlloc struct {
head traceAllocBlockPtr
off uintptr
}
// traceAllocBlock is a block in traceAlloc.
//
// traceAllocBlock is allocated from non-GC'd memory, so it must not
// contain heap pointers. Writes to pointers to traceAllocBlocks do
// not need write barriers.
//
//go:notinheap
type traceAllocBlock struct {
next traceAllocBlockPtr
data [64<<10 - sys.PtrSize]byte
}
// TODO: Since traceAllocBlock is now go:notinheap, this isn't necessary.
type traceAllocBlockPtr uintptr
func (p traceAllocBlockPtr) ptr() *traceAllocBlock { return (*traceAllocBlock)(unsafe.Pointer(p)) }
func (p *traceAllocBlockPtr) set(x *traceAllocBlock) { *p = traceAllocBlockPtr(unsafe.Pointer(x)) }
// alloc allocates n-byte block.
func (a *traceAlloc) alloc(n uintptr) unsafe.Pointer {
n = round(n, sys.PtrSize)
if a.head == 0 || a.off+n > uintptr(len(a.head.ptr().data)) {
if n > uintptr(len(a.head.ptr().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.set(a.head.ptr())
a.head.set(block)
a.off = 0
}
p := &a.head.ptr().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 != 0 {
block := a.head.ptr()
a.head.set(block.next.ptr())
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, 3, trace.seqGC)
trace.seqGC++
}
func traceGCDone() {
traceEvent(traceEvGCDone, -1)
}
func traceGCScanStart() {
traceEvent(traceEvGCScanStart, -1)
}
func traceGCScanDone() {
traceEvent(traceEvGCScanDone, -1)
}
// traceGCSweepStart prepares to trace a sweep loop. This does not
// emit any events until traceGCSweepSpan is called.
//
// traceGCSweepStart must be paired with traceGCSweepDone and there
// must be no preemption points between these two calls.
func traceGCSweepStart() {
// Delay the actual GCSweepStart event until the first span
// sweep. If we don't sweep anything, don't emit any events.
_p_ := getg().m.p.ptr()
if _p_.traceSweep {
throw("double traceGCSweepStart")
}
_p_.traceSweep, _p_.traceSwept, _p_.traceReclaimed = true, 0, 0
}
// traceGCSweepSpan traces the sweep of a single page.
//
// This may be called outside a traceGCSweepStart/traceGCSweepDone
// pair; however, it will not emit any trace events in this case.
func traceGCSweepSpan(bytesSwept uintptr) {
_p_ := getg().m.p.ptr()
if _p_.traceSweep {
if _p_.traceSwept == 0 {
traceEvent(traceEvGCSweepStart, 1)
}
_p_.traceSwept += bytesSwept
}
}
func traceGCSweepDone() {
_p_ := getg().m.p.ptr()
if !_p_.traceSweep {
throw("missing traceGCSweepStart")
}
if _p_.traceSwept != 0 {
traceEvent(traceEvGCSweepDone, -1, uint64(_p_.traceSwept), uint64(_p_.traceReclaimed))
}
_p_.traceSweep = false
}
func traceGCMarkAssistStart() {
traceEvent(traceEvGCMarkAssistStart, 1)
}
func traceGCMarkAssistDone() {
traceEvent(traceEvGCMarkAssistDone, -1)
}
func traceGoCreate(newg *g, pc uintptr) {
newg.traceseq = 0
newg.tracelastp = getg().m.p
// +PCQuantum because traceFrameForPC expects return PCs and subtracts PCQuantum.
id := trace.stackTab.put([]uintptr{pc + sys.PCQuantum})
traceEvent(traceEvGoCreate, 2, uint64(newg.goid), uint64(id))
}
func traceGoStart() {
_g_ := getg().m.curg
_p_ := _g_.m.p
_g_.traceseq++
if _g_ == _p_.ptr().gcBgMarkWorker.ptr() {
traceEvent(traceEvGoStartLabel, -1, uint64(_g_.goid), _g_.traceseq, trace.markWorkerLabels[_p_.ptr().gcMarkWorkerMode])
} else if _g_.tracelastp == _p_ {
traceEvent(traceEvGoStartLocal, -1, uint64(_g_.goid))
} else {
_g_.tracelastp = _p_
traceEvent(traceEvGoStart, -1, uint64(_g_.goid), _g_.traceseq)
}
}
func traceGoEnd() {
traceEvent(traceEvGoEnd, -1)
}
func traceGoSched() {
_g_ := getg()
_g_.tracelastp = _g_.m.p
traceEvent(traceEvGoSched, 1)
}
func traceGoPreempt() {
_g_ := getg()
_g_.tracelastp = _g_.m.p
traceEvent(traceEvGoPreempt, 1)
}
func traceGoPark(traceEv byte, skip int) {
if traceEv&traceFutileWakeup != 0 {
traceEvent(traceEvFutileWakeup, -1)
}
traceEvent(traceEv & ^traceFutileWakeup, skip)
}
func traceGoUnpark(gp *g, skip int) {
_p_ := getg().m.p
gp.traceseq++
if gp.tracelastp == _p_ {
traceEvent(traceEvGoUnblockLocal, skip, uint64(gp.goid))
} else {
gp.tracelastp = _p_
traceEvent(traceEvGoUnblock, skip, uint64(gp.goid), gp.traceseq)
}
}
func traceGoSysCall() {
traceEvent(traceEvGoSysCall, 1)
}
func traceGoSysExit(ts int64) {
if ts != 0 && ts < trace.ticksStart {
// There is a race between the code that initializes sysexitticks
// (in exitsyscall, which runs without a P, and therefore is not
// stopped with the rest of the world) and the code that initializes
// a new trace. The recorded sysexitticks must therefore be treated
// as "best effort". If they are valid for this trace, then great,
// use them for greater accuracy. But if they're not valid for this
// trace, assume that the trace was started after the actual syscall
// exit (but before we actually managed to start the goroutine,
// aka right now), and assign a fresh time stamp to keep the log consistent.
ts = 0
}
_g_ := getg().m.curg
_g_.traceseq++
_g_.tracelastp = _g_.m.p
traceEvent(traceEvGoSysExit, -1, uint64(_g_.goid), _g_.traceseq, 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() {
if memstats.next_gc == ^uint64(0) {
// Heap-based triggering is disabled.
traceEvent(traceEvNextGC, -1, 0)
} else {
traceEvent(traceEvNextGC, -1, memstats.next_gc)
}
}