gcc/libgo/go/runtime/cpuprof.go
Ian Lance Taylor 34489eb2af compiler: improve name mangling for packpaths
The current implementation of Gogo::pkgpath_for_symbol was written in
    a way that allowed two distinct package paths to map to the same
    symbol, which could cause collisions at link- time or compile-time.
    
    Switch to a better mangling scheme to insure that we get a unique
    packagepath symbol for each package. In the new scheme instead of having
    separate mangling schemes for identifiers and package paths, the
    main identifier mangler ("go_encode_id") now handles mangling of
    both packagepath characters and identifier characters.
    
    The new mangling scheme is more intrusive: "foo/bar.Baz" is mangled as
    "foo..z2fbar.Baz" instead of "foo_bar.Baz". To mitigate this, this
    patch also adds a demangling capability so that function names
    returned from runtime.CallersFrames are converted back to their
    original unmangled form.
    
    Changing the pkgpath_for_symbol scheme requires updating a number of
    //go:linkname directives and C "__asm__" directives to match the new
    scheme, as well as updating the 'gotest' driver (which makes
    assumptions about the correct mapping from pkgpath symbol to package
    name).
    
    Fixes golang/go#27534.
    
    Reviewed-on: https://go-review.googlesource.com/c/135455

From-SVN: r265510
2018-10-25 22:18:08 +00:00

213 lines
6.5 KiB
Go

// Copyright 2011 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.
// CPU profiling.
//
// The signal handler for the profiling clock tick adds a new stack trace
// to a log of recent traces. The log is read by a user goroutine that
// turns it into formatted profile data. If the reader does not keep up
// with the log, those writes will be recorded as a count of lost records.
// The actual profile buffer is in profbuf.go.
package runtime
import (
"runtime/internal/atomic"
"runtime/internal/sys"
"unsafe"
)
const maxCPUProfStack = 64
type cpuProfile struct {
lock mutex
on bool // profiling is on
log *profBuf // profile events written here
// extra holds extra stacks accumulated in addNonGo
// corresponding to profiling signals arriving on
// non-Go-created threads. Those stacks are written
// to log the next time a normal Go thread gets the
// signal handler.
// Assuming the stacks are 2 words each (we don't get
// a full traceback from those threads), plus one word
// size for framing, 100 Hz profiling would generate
// 300 words per second.
// Hopefully a normal Go thread will get the profiling
// signal at least once every few seconds.
extra [1000]uintptr
numExtra int
lostExtra uint64 // count of frames lost because extra is full
}
var cpuprof cpuProfile
// SetCPUProfileRate sets the CPU profiling rate to hz samples per second.
// If hz <= 0, SetCPUProfileRate turns off profiling.
// If the profiler is on, the rate cannot be changed without first turning it off.
//
// Most clients should use the runtime/pprof package or
// the testing package's -test.cpuprofile flag instead of calling
// SetCPUProfileRate directly.
func SetCPUProfileRate(hz int) {
// Clamp hz to something reasonable.
if hz < 0 {
hz = 0
}
if hz > 1000000 {
hz = 1000000
}
lock(&cpuprof.lock)
if hz > 0 {
if cpuprof.on || cpuprof.log != nil {
print("runtime: cannot set cpu profile rate until previous profile has finished.\n")
unlock(&cpuprof.lock)
return
}
cpuprof.on = true
cpuprof.log = newProfBuf(1, 1<<17, 1<<14)
hdr := [1]uint64{uint64(hz)}
cpuprof.log.write(nil, nanotime(), hdr[:], nil)
setcpuprofilerate(int32(hz))
} else if cpuprof.on {
setcpuprofilerate(0)
cpuprof.on = false
cpuprof.addExtra()
cpuprof.log.close()
}
unlock(&cpuprof.lock)
}
// add adds the stack trace to the profile.
// It is called from signal handlers and other limited environments
// and cannot allocate memory or acquire locks that might be
// held at the time of the signal, nor can it use substantial amounts
// of stack.
//go:nowritebarrierrec
func (p *cpuProfile) add(gp *g, stk []uintptr) {
// Simple cas-lock to coordinate with setcpuprofilerate.
for !atomic.Cas(&prof.signalLock, 0, 1) {
osyield()
}
if prof.hz != 0 { // implies cpuprof.log != nil
if p.numExtra > 0 || p.lostExtra > 0 {
p.addExtra()
}
hdr := [1]uint64{1}
// Note: write "knows" that the argument is &gp.labels,
// because otherwise its write barrier behavior may not
// be correct. See the long comment there before
// changing the argument here.
cpuprof.log.write(&gp.labels, nanotime(), hdr[:], stk)
}
atomic.Store(&prof.signalLock, 0)
}
// addNonGo adds the non-Go stack trace to the profile.
// It is called from a non-Go thread, so we cannot use much stack at all,
// nor do anything that needs a g or an m.
// In particular, we can't call cpuprof.log.write.
// Instead, we copy the stack into cpuprof.extra,
// which will be drained the next time a Go thread
// gets the signal handling event.
//go:nosplit
//go:nowritebarrierrec
func (p *cpuProfile) addNonGo(stk []uintptr) {
// Simple cas-lock to coordinate with SetCPUProfileRate.
// (Other calls to add or addNonGo should be blocked out
// by the fact that only one SIGPROF can be handled by the
// process at a time. If not, this lock will serialize those too.)
for !atomic.Cas(&prof.signalLock, 0, 1) {
osyield()
}
if cpuprof.numExtra+1+len(stk) < len(cpuprof.extra) {
i := cpuprof.numExtra
cpuprof.extra[i] = uintptr(1 + len(stk))
copy(cpuprof.extra[i+1:], stk)
cpuprof.numExtra += 1 + len(stk)
} else {
cpuprof.lostExtra++
}
atomic.Store(&prof.signalLock, 0)
}
// addExtra adds the "extra" profiling events,
// queued by addNonGo, to the profile log.
// addExtra is called either from a signal handler on a Go thread
// or from an ordinary goroutine; either way it can use stack
// and has a g. The world may be stopped, though.
func (p *cpuProfile) addExtra() {
// Copy accumulated non-Go profile events.
hdr := [1]uint64{1}
for i := 0; i < p.numExtra; {
p.log.write(nil, 0, hdr[:], p.extra[i+1:i+int(p.extra[i])])
i += int(p.extra[i])
}
p.numExtra = 0
// Report any lost events.
if p.lostExtra > 0 {
hdr := [1]uint64{p.lostExtra}
lostStk := [2]uintptr{
_LostExternalCodePC + sys.PCQuantum,
_ExternalCodePC + sys.PCQuantum,
}
cpuprof.log.write(nil, 0, hdr[:], lostStk[:])
p.lostExtra = 0
}
}
func (p *cpuProfile) addLostAtomic64(count uint64) {
hdr := [1]uint64{count}
lostStk := [2]uintptr{
_LostSIGPROFDuringAtomic64PC + sys.PCQuantum,
_SystemPC + sys.PCQuantum,
}
cpuprof.log.write(nil, 0, hdr[:], lostStk[:])
}
// CPUProfile panics.
// It formerly provided raw access to chunks of
// a pprof-format profile generated by the runtime.
// The details of generating that format have changed,
// so this functionality has been removed.
//
// Deprecated: use the runtime/pprof package,
// or the handlers in the net/http/pprof package,
// or the testing package's -test.cpuprofile flag instead.
func CPUProfile() []byte {
panic("CPUProfile no longer available")
}
//go:linkname runtime_pprof_runtime_cyclesPerSecond runtime..z2fpprof.runtime_cyclesPerSecond
func runtime_pprof_runtime_cyclesPerSecond() int64 {
return tickspersecond()
}
// readProfile, provided to runtime/pprof, returns the next chunk of
// binary CPU profiling stack trace data, blocking until data is available.
// If profiling is turned off and all the profile data accumulated while it was
// on has been returned, readProfile returns eof=true.
// The caller must save the returned data and tags before calling readProfile again.
//
//go:linkname runtime_pprof_readProfile runtime..z2fpprof.readProfile
func runtime_pprof_readProfile() ([]uint64, []unsafe.Pointer, bool) {
lock(&cpuprof.lock)
log := cpuprof.log
unlock(&cpuprof.lock)
data, tags, eof := log.read(profBufBlocking)
if len(data) == 0 && eof {
lock(&cpuprof.lock)
cpuprof.log = nil
unlock(&cpuprof.lock)
}
return data, tags, eof
}