dd931d9b48
Reviewed-on: https://go-review.googlesource.com/136435 gotools/: * Makefile.am (mostlyclean-local): Run chmod on check-go-dir to make sure it is writable. (check-go-tools): Likewise. (check-vet): Copy internal/objabi to check-vet-dir. * Makefile.in: Rebuild. From-SVN: r264546
461 lines
10 KiB
Go
461 lines
10 KiB
Go
// Copyright 2009 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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// Time-related runtime and pieces of package time.
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package runtime
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import (
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"runtime/internal/sys"
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"unsafe"
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)
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// Package time knows the layout of this structure.
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// If this struct changes, adjust ../time/sleep.go:/runtimeTimer.
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// For GOOS=nacl, package syscall knows the layout of this structure.
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// If this struct changes, adjust ../syscall/net_nacl.go:/runtimeTimer.
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type timer struct {
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tb *timersBucket // the bucket the timer lives in
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i int // heap index
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// Timer wakes up at when, and then at when+period, ... (period > 0 only)
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// each time calling f(arg, now) in the timer goroutine, so f must be
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// a well-behaved function and not block.
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when int64
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period int64
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f func(interface{}, uintptr)
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arg interface{}
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seq uintptr
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}
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// timersLen is the length of timers array.
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//
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// Ideally, this would be set to GOMAXPROCS, but that would require
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// dynamic reallocation
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//
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// The current value is a compromise between memory usage and performance
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// that should cover the majority of GOMAXPROCS values used in the wild.
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const timersLen = 64
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// timers contains "per-P" timer heaps.
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//
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// Timers are queued into timersBucket associated with the current P,
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// so each P may work with its own timers independently of other P instances.
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//
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// Each timersBucket may be associated with multiple P
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// if GOMAXPROCS > timersLen.
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var timers [timersLen]struct {
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timersBucket
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// The padding should eliminate false sharing
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// between timersBucket values.
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pad [sys.CacheLineSize - unsafe.Sizeof(timersBucket{})%sys.CacheLineSize]byte
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}
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func (t *timer) assignBucket() *timersBucket {
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id := uint8(getg().m.p.ptr().id) % timersLen
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t.tb = &timers[id].timersBucket
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return t.tb
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}
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//go:notinheap
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type timersBucket struct {
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lock mutex
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gp *g
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created bool
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sleeping bool
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rescheduling bool
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sleepUntil int64
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waitnote note
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t []*timer
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}
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// nacl fake time support - time in nanoseconds since 1970
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var faketime int64
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// Package time APIs.
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// Godoc uses the comments in package time, not these.
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// time.now is implemented in assembly.
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// timeSleep puts the current goroutine to sleep for at least ns nanoseconds.
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//go:linkname timeSleep time.Sleep
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func timeSleep(ns int64) {
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if ns <= 0 {
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return
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}
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gp := getg()
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t := gp.timer
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if t == nil {
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t = new(timer)
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gp.timer = t
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}
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*t = timer{}
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t.when = nanotime() + ns
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t.f = goroutineReady
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t.arg = gp
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tb := t.assignBucket()
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lock(&tb.lock)
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if !tb.addtimerLocked(t) {
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unlock(&tb.lock)
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badTimer()
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}
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goparkunlock(&tb.lock, waitReasonSleep, traceEvGoSleep, 2)
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}
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// startTimer adds t to the timer heap.
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//go:linkname startTimer time.startTimer
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func startTimer(t *timer) {
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if raceenabled {
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racerelease(unsafe.Pointer(t))
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}
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addtimer(t)
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}
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// stopTimer removes t from the timer heap if it is there.
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// It returns true if t was removed, false if t wasn't even there.
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//go:linkname stopTimer time.stopTimer
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func stopTimer(t *timer) bool {
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return deltimer(t)
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}
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// Go runtime.
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// Ready the goroutine arg.
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func goroutineReady(arg interface{}, seq uintptr) {
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goready(arg.(*g), 0)
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}
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func addtimer(t *timer) {
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tb := t.assignBucket()
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lock(&tb.lock)
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ok := tb.addtimerLocked(t)
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unlock(&tb.lock)
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if !ok {
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badTimer()
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}
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}
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// Add a timer to the heap and start or kick timerproc if the new timer is
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// earlier than any of the others.
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// Timers are locked.
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// Returns whether all is well: false if the data structure is corrupt
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// due to user-level races.
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func (tb *timersBucket) addtimerLocked(t *timer) bool {
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// when must never be negative; otherwise timerproc will overflow
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// during its delta calculation and never expire other runtime timers.
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if t.when < 0 {
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t.when = 1<<63 - 1
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}
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t.i = len(tb.t)
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tb.t = append(tb.t, t)
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if !siftupTimer(tb.t, t.i) {
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return false
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}
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if t.i == 0 {
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// siftup moved to top: new earliest deadline.
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if tb.sleeping {
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tb.sleeping = false
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notewakeup(&tb.waitnote)
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}
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if tb.rescheduling {
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tb.rescheduling = false
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goready(tb.gp, 0)
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}
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}
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if !tb.created {
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tb.created = true
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expectSystemGoroutine()
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go timerproc(tb)
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}
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return true
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}
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// Delete timer t from the heap.
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// Do not need to update the timerproc: if it wakes up early, no big deal.
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func deltimer(t *timer) bool {
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if t.tb == nil {
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// t.tb can be nil if the user created a timer
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// directly, without invoking startTimer e.g
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// time.Ticker{C: c}
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// In this case, return early without any deletion.
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// See Issue 21874.
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return false
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}
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tb := t.tb
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lock(&tb.lock)
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// t may not be registered anymore and may have
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// a bogus i (typically 0, if generated by Go).
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// Verify it before proceeding.
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i := t.i
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last := len(tb.t) - 1
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if i < 0 || i > last || tb.t[i] != t {
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unlock(&tb.lock)
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return false
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}
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if i != last {
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tb.t[i] = tb.t[last]
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tb.t[i].i = i
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}
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tb.t[last] = nil
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tb.t = tb.t[:last]
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ok := true
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if i != last {
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if !siftupTimer(tb.t, i) {
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ok = false
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}
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if !siftdownTimer(tb.t, i) {
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ok = false
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}
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}
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unlock(&tb.lock)
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if !ok {
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badTimer()
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}
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return true
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}
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// Timerproc runs the time-driven events.
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// It sleeps until the next event in the tb heap.
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// If addtimer inserts a new earlier event, it wakes timerproc early.
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func timerproc(tb *timersBucket) {
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setSystemGoroutine()
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tb.gp = getg()
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for {
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lock(&tb.lock)
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tb.sleeping = false
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now := nanotime()
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delta := int64(-1)
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for {
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if len(tb.t) == 0 {
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delta = -1
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break
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}
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t := tb.t[0]
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delta = t.when - now
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if delta > 0 {
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break
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}
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ok := true
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if t.period > 0 {
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// leave in heap but adjust next time to fire
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t.when += t.period * (1 + -delta/t.period)
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if !siftdownTimer(tb.t, 0) {
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ok = false
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}
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} else {
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// remove from heap
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last := len(tb.t) - 1
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if last > 0 {
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tb.t[0] = tb.t[last]
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tb.t[0].i = 0
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}
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tb.t[last] = nil
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tb.t = tb.t[:last]
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if last > 0 {
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if !siftdownTimer(tb.t, 0) {
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ok = false
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}
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}
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t.i = -1 // mark as removed
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}
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f := t.f
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arg := t.arg
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seq := t.seq
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unlock(&tb.lock)
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if !ok {
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badTimer()
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}
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if raceenabled {
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raceacquire(unsafe.Pointer(t))
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}
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f(arg, seq)
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lock(&tb.lock)
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}
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if delta < 0 || faketime > 0 {
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// No timers left - put goroutine to sleep.
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tb.rescheduling = true
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goparkunlock(&tb.lock, waitReasonTimerGoroutineIdle, traceEvGoBlock, 1)
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continue
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}
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// At least one timer pending. Sleep until then.
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tb.sleeping = true
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tb.sleepUntil = now + delta
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noteclear(&tb.waitnote)
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unlock(&tb.lock)
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notetsleepg(&tb.waitnote, delta)
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}
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}
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func timejump() *g {
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if faketime == 0 {
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return nil
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}
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for i := range timers {
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lock(&timers[i].lock)
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}
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gp := timejumpLocked()
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for i := range timers {
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unlock(&timers[i].lock)
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}
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return gp
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}
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func timejumpLocked() *g {
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// Determine a timer bucket with minimum when.
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var minT *timer
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for i := range timers {
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tb := &timers[i]
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if !tb.created || len(tb.t) == 0 {
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continue
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}
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t := tb.t[0]
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if minT == nil || t.when < minT.when {
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minT = t
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}
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}
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if minT == nil || minT.when <= faketime {
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return nil
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}
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faketime = minT.when
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tb := minT.tb
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if !tb.rescheduling {
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return nil
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}
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tb.rescheduling = false
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return tb.gp
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}
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func timeSleepUntil() int64 {
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next := int64(1<<63 - 1)
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// Determine minimum sleepUntil across all the timer buckets.
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//
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// The function can not return a precise answer,
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// as another timer may pop in as soon as timers have been unlocked.
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// So lock the timers one by one instead of all at once.
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for i := range timers {
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tb := &timers[i]
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lock(&tb.lock)
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if tb.sleeping && tb.sleepUntil < next {
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next = tb.sleepUntil
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}
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unlock(&tb.lock)
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}
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return next
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}
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// Heap maintenance algorithms.
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// These algorithms check for slice index errors manually.
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// Slice index error can happen if the program is using racy
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// access to timers. We don't want to panic here, because
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// it will cause the program to crash with a mysterious
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// "panic holding locks" message. Instead, we panic while not
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// holding a lock.
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// The races can occur despite the bucket locks because assignBucket
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// itself is called without locks, so racy calls can cause a timer to
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// change buckets while executing these functions.
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func siftupTimer(t []*timer, i int) bool {
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if i >= len(t) {
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return false
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}
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when := t[i].when
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tmp := t[i]
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for i > 0 {
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p := (i - 1) / 4 // parent
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if when >= t[p].when {
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break
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}
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t[i] = t[p]
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t[i].i = i
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i = p
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}
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if tmp != t[i] {
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t[i] = tmp
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t[i].i = i
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}
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return true
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}
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func siftdownTimer(t []*timer, i int) bool {
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n := len(t)
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if i >= n {
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return false
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}
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when := t[i].when
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tmp := t[i]
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for {
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c := i*4 + 1 // left child
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c3 := c + 2 // mid child
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if c >= n {
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break
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}
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w := t[c].when
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if c+1 < n && t[c+1].when < w {
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w = t[c+1].when
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c++
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}
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if c3 < n {
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w3 := t[c3].when
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if c3+1 < n && t[c3+1].when < w3 {
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w3 = t[c3+1].when
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c3++
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}
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if w3 < w {
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w = w3
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c = c3
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}
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}
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if w >= when {
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break
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}
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t[i] = t[c]
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t[i].i = i
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i = c
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}
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if tmp != t[i] {
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t[i] = tmp
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t[i].i = i
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}
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return true
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}
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// badTimer is called if the timer data structures have been corrupted,
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// presumably due to racy use by the program. We panic here rather than
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// panicing due to invalid slice access while holding locks.
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// See issue #25686.
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func badTimer() {
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panic(errorString("racy use of timers"))
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}
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// Entry points for net, time to call nanotime.
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//go:linkname poll_runtimeNano internal_poll.runtimeNano
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func poll_runtimeNano() int64 {
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return nanotime()
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}
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//go:linkname time_runtimeNano time.runtimeNano
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func time_runtimeNano() int64 {
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return nanotime()
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}
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// Monotonic times are reported as offsets from startNano.
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// We initialize startNano to nanotime() - 1 so that on systems where
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// monotonic time resolution is fairly low (e.g. Windows 2008
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// which appears to have a default resolution of 15ms),
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// we avoid ever reporting a nanotime of 0.
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// (Callers may want to use 0 as "time not set".)
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var startNano int64 = nanotime() - 1
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