mirror of
https://github.com/golang/go
synced 2024-11-19 22:04:44 -07:00
5fea2ccc77
The tree's pretty inconsistent about single space vs double space after a period in documentation. Make it consistently a single space, per earlier decisions. This means contributors won't be confused by misleading precedence. This CL doesn't use go/doc to parse. It only addresses // comments. It was generated with: $ perl -i -npe 's,^(\s*// .+[a-z]\.) +([A-Z]),$1 $2,' $(git grep -l -E '^\s*//(.+\.) +([A-Z])') $ go test go/doc -update Change-Id: Iccdb99c37c797ef1f804a94b22ba5ee4b500c4f7 Reviewed-on: https://go-review.googlesource.com/20022 Reviewed-by: Rob Pike <r@golang.org> Reviewed-by: Dave Day <djd@golang.org> Run-TryBot: Brad Fitzpatrick <bradfitz@golang.org> TryBot-Result: Gobot Gobot <gobot@golang.org>
428 lines
12 KiB
Go
428 lines
12 KiB
Go
// Copyright 2011 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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// CPU profiling.
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// Based on algorithms and data structures used in
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// http://code.google.com/p/google-perftools/.
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//
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// The main difference between this code and the google-perftools
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// code is that this code is written to allow copying the profile data
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// to an arbitrary io.Writer, while the google-perftools code always
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// writes to an operating system file.
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//
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// The signal handler for the profiling clock tick adds a new stack trace
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// to a hash table tracking counts for recent traces. Most clock ticks
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// hit in the cache. In the event of a cache miss, an entry must be
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// evicted from the hash table, copied to a log that will eventually be
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// written as profile data. The google-perftools code flushed the
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// log itself during the signal handler. This code cannot do that, because
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// the io.Writer might block or need system calls or locks that are not
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// safe to use from within the signal handler. Instead, we split the log
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// into two halves and let the signal handler fill one half while a goroutine
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// is writing out the other half. When the signal handler fills its half, it
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// offers to swap with the goroutine. If the writer is not done with its half,
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// we lose the stack trace for this clock tick (and record that loss).
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// The goroutine interacts with the signal handler by calling getprofile() to
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// get the next log piece to write, implicitly handing back the last log
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// piece it obtained.
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//
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// The state of this dance between the signal handler and the goroutine
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// is encoded in the Profile.handoff field. If handoff == 0, then the goroutine
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// is not using either log half and is waiting (or will soon be waiting) for
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// a new piece by calling notesleep(&p.wait). If the signal handler
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// changes handoff from 0 to non-zero, it must call notewakeup(&p.wait)
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// to wake the goroutine. The value indicates the number of entries in the
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// log half being handed off. The goroutine leaves the non-zero value in
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// place until it has finished processing the log half and then flips the number
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// back to zero. Setting the high bit in handoff means that the profiling is over,
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// and the goroutine is now in charge of flushing the data left in the hash table
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// to the log and returning that data.
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//
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// The handoff field is manipulated using atomic operations.
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// For the most part, the manipulation of handoff is orderly: if handoff == 0
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// then the signal handler owns it and can change it to non-zero.
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// If handoff != 0 then the goroutine owns it and can change it to zero.
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// If that were the end of the story then we would not need to manipulate
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// handoff using atomic operations. The operations are needed, however,
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// in order to let the log closer set the high bit to indicate "EOF" safely
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// in the situation when normally the goroutine "owns" handoff.
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package runtime
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import (
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"runtime/internal/atomic"
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"unsafe"
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)
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const (
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numBuckets = 1 << 10
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logSize = 1 << 17
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assoc = 4
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maxCPUProfStack = 64
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)
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type cpuprofEntry struct {
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count uintptr
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depth int
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stack [maxCPUProfStack]uintptr
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}
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type cpuProfile struct {
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on bool // profiling is on
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wait note // goroutine waits here
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count uintptr // tick count
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evicts uintptr // eviction count
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lost uintptr // lost ticks that need to be logged
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// Active recent stack traces.
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hash [numBuckets]struct {
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entry [assoc]cpuprofEntry
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}
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// Log of traces evicted from hash.
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// Signal handler has filled log[toggle][:nlog].
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// Goroutine is writing log[1-toggle][:handoff].
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log [2][logSize / 2]uintptr
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nlog int
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toggle int32
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handoff uint32
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// Writer state.
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// Writer maintains its own toggle to avoid races
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// looking at signal handler's toggle.
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wtoggle uint32
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wholding bool // holding & need to release a log half
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flushing bool // flushing hash table - profile is over
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eodSent bool // special end-of-data record sent; => flushing
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}
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var (
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cpuprofLock mutex
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cpuprof *cpuProfile
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eod = [3]uintptr{0, 1, 0}
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)
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func setcpuprofilerate(hz int32) {
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systemstack(func() {
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setcpuprofilerate_m(hz)
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})
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}
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// lostProfileData is a no-op function used in profiles
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// to mark the number of profiling stack traces that were
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// discarded due to slow data writers.
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func lostProfileData() {}
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// SetCPUProfileRate sets the CPU profiling rate to hz samples per second.
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// If hz <= 0, SetCPUProfileRate turns off profiling.
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// If the profiler is on, the rate cannot be changed without first turning it off.
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//
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// Most clients should use the runtime/pprof package or
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// the testing package's -test.cpuprofile flag instead of calling
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// SetCPUProfileRate directly.
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func SetCPUProfileRate(hz int) {
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// Clamp hz to something reasonable.
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if hz < 0 {
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hz = 0
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}
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if hz > 1000000 {
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hz = 1000000
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}
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lock(&cpuprofLock)
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if hz > 0 {
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if cpuprof == nil {
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cpuprof = (*cpuProfile)(sysAlloc(unsafe.Sizeof(cpuProfile{}), &memstats.other_sys))
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if cpuprof == nil {
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print("runtime: cpu profiling cannot allocate memory\n")
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unlock(&cpuprofLock)
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return
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}
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}
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if cpuprof.on || cpuprof.handoff != 0 {
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print("runtime: cannot set cpu profile rate until previous profile has finished.\n")
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unlock(&cpuprofLock)
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return
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}
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cpuprof.on = true
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// pprof binary header format.
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// http://code.google.com/p/google-perftools/source/browse/trunk/src/profiledata.cc#117
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p := &cpuprof.log[0]
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p[0] = 0 // count for header
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p[1] = 3 // depth for header
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p[2] = 0 // version number
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p[3] = uintptr(1e6 / hz) // period (microseconds)
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p[4] = 0
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cpuprof.nlog = 5
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cpuprof.toggle = 0
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cpuprof.wholding = false
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cpuprof.wtoggle = 0
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cpuprof.flushing = false
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cpuprof.eodSent = false
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noteclear(&cpuprof.wait)
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setcpuprofilerate(int32(hz))
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} else if cpuprof != nil && cpuprof.on {
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setcpuprofilerate(0)
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cpuprof.on = false
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// Now add is not running anymore, and getprofile owns the entire log.
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// Set the high bit in cpuprof.handoff to tell getprofile.
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for {
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n := cpuprof.handoff
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if n&0x80000000 != 0 {
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print("runtime: setcpuprofile(off) twice\n")
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}
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if atomic.Cas(&cpuprof.handoff, n, n|0x80000000) {
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if n == 0 {
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// we did the transition from 0 -> nonzero so we wake getprofile
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notewakeup(&cpuprof.wait)
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}
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break
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}
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}
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}
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unlock(&cpuprofLock)
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}
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// add adds the stack trace to the profile.
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// It is called from signal handlers and other limited environments
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// and cannot allocate memory or acquire locks that might be
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// held at the time of the signal, nor can it use substantial amounts
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// of stack. It is allowed to call evict.
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func (p *cpuProfile) add(pc []uintptr) {
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if len(pc) > maxCPUProfStack {
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pc = pc[:maxCPUProfStack]
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}
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// Compute hash.
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h := uintptr(0)
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for _, x := range pc {
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h = h<<8 | (h >> (8 * (unsafe.Sizeof(h) - 1)))
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h += x * 41
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}
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p.count++
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// Add to entry count if already present in table.
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b := &p.hash[h%numBuckets]
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Assoc:
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for i := range b.entry {
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e := &b.entry[i]
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if e.depth != len(pc) {
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continue
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}
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for j := range pc {
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if e.stack[j] != pc[j] {
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continue Assoc
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}
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}
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e.count++
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return
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}
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// Evict entry with smallest count.
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var e *cpuprofEntry
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for i := range b.entry {
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if e == nil || b.entry[i].count < e.count {
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e = &b.entry[i]
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}
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}
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if e.count > 0 {
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if !p.evict(e) {
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// Could not evict entry. Record lost stack.
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p.lost++
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return
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}
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p.evicts++
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}
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// Reuse the newly evicted entry.
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e.depth = len(pc)
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e.count = 1
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copy(e.stack[:], pc)
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}
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// evict copies the given entry's data into the log, so that
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// the entry can be reused. evict is called from add, which
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// is called from the profiling signal handler, so it must not
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// allocate memory or block. It is safe to call flushlog.
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// evict returns true if the entry was copied to the log,
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// false if there was no room available.
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func (p *cpuProfile) evict(e *cpuprofEntry) bool {
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d := e.depth
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nslot := d + 2
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log := &p.log[p.toggle]
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if p.nlog+nslot > len(log) {
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if !p.flushlog() {
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return false
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}
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log = &p.log[p.toggle]
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}
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q := p.nlog
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log[q] = e.count
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q++
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log[q] = uintptr(d)
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q++
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copy(log[q:], e.stack[:d])
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q += d
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p.nlog = q
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e.count = 0
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return true
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}
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// flushlog tries to flush the current log and switch to the other one.
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// flushlog is called from evict, called from add, called from the signal handler,
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// so it cannot allocate memory or block. It can try to swap logs with
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// the writing goroutine, as explained in the comment at the top of this file.
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func (p *cpuProfile) flushlog() bool {
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if !atomic.Cas(&p.handoff, 0, uint32(p.nlog)) {
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return false
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}
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notewakeup(&p.wait)
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p.toggle = 1 - p.toggle
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log := &p.log[p.toggle]
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q := 0
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if p.lost > 0 {
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lostPC := funcPC(lostProfileData)
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log[0] = p.lost
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log[1] = 1
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log[2] = lostPC
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q = 3
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p.lost = 0
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}
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p.nlog = q
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return true
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}
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// getprofile blocks until the next block of profiling data is available
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// and returns it as a []byte. It is called from the writing goroutine.
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func (p *cpuProfile) getprofile() []byte {
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if p == nil {
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return nil
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}
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if p.wholding {
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// Release previous log to signal handling side.
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// Loop because we are racing against SetCPUProfileRate(0).
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for {
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n := p.handoff
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if n == 0 {
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print("runtime: phase error during cpu profile handoff\n")
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return nil
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}
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if n&0x80000000 != 0 {
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p.wtoggle = 1 - p.wtoggle
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p.wholding = false
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p.flushing = true
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goto Flush
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}
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if atomic.Cas(&p.handoff, n, 0) {
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break
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}
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}
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p.wtoggle = 1 - p.wtoggle
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p.wholding = false
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}
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if p.flushing {
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goto Flush
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}
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if !p.on && p.handoff == 0 {
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return nil
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}
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// Wait for new log.
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notetsleepg(&p.wait, -1)
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noteclear(&p.wait)
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switch n := p.handoff; {
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case n == 0:
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print("runtime: phase error during cpu profile wait\n")
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return nil
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case n == 0x80000000:
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p.flushing = true
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goto Flush
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default:
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n &^= 0x80000000
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// Return new log to caller.
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p.wholding = true
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return uintptrBytes(p.log[p.wtoggle][:n])
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}
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// In flush mode.
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// Add is no longer being called. We own the log.
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// Also, p.handoff is non-zero, so flushlog will return false.
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// Evict the hash table into the log and return it.
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Flush:
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for i := range p.hash {
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b := &p.hash[i]
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for j := range b.entry {
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e := &b.entry[j]
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if e.count > 0 && !p.evict(e) {
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// Filled the log. Stop the loop and return what we've got.
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break Flush
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}
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}
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}
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// Return pending log data.
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if p.nlog > 0 {
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// Note that we're using toggle now, not wtoggle,
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// because we're working on the log directly.
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n := p.nlog
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p.nlog = 0
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return uintptrBytes(p.log[p.toggle][:n])
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}
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// Made it through the table without finding anything to log.
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if !p.eodSent {
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// We may not have space to append this to the partial log buf,
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// so we always return a new slice for the end-of-data marker.
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p.eodSent = true
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return uintptrBytes(eod[:])
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}
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// Finally done. Clean up and return nil.
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p.flushing = false
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if !atomic.Cas(&p.handoff, p.handoff, 0) {
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print("runtime: profile flush racing with something\n")
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}
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return nil
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}
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func uintptrBytes(p []uintptr) (ret []byte) {
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pp := (*slice)(unsafe.Pointer(&p))
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rp := (*slice)(unsafe.Pointer(&ret))
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rp.array = pp.array
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rp.len = pp.len * int(unsafe.Sizeof(p[0]))
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rp.cap = rp.len
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return
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}
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// CPUProfile returns the next chunk of binary CPU profiling stack trace data,
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// blocking until data is available. If profiling is turned off and all the profile
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// data accumulated while it was on has been returned, CPUProfile returns nil.
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// The caller must save the returned data before calling CPUProfile again.
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//
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// Most clients should use the runtime/pprof package or
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// the testing package's -test.cpuprofile flag instead of calling
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// CPUProfile directly.
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func CPUProfile() []byte {
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return cpuprof.getprofile()
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}
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//go:linkname runtime_pprof_runtime_cyclesPerSecond runtime/pprof.runtime_cyclesPerSecond
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func runtime_pprof_runtime_cyclesPerSecond() int64 {
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return tickspersecond()
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}
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