// Copyright 2023 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.
// Trace stack table and acquisition.
package runtime
import (
"internal/abi"
"internal/goarch"
"unsafe"
)
const (
// 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
// logicalStackSentinel is a sentinel value at pcBuf[0] signifying that
// pcBuf[1:] holds a logical stack requiring no further processing. Any other
// value at pcBuf[0] represents a skip value to apply to the physical stack in
// pcBuf[1:] after inline expansion.
logicalStackSentinel = ^uintptr(0)
)
// traceStack captures a stack trace from a goroutine and registers it in the trace
// stack table. It then returns its unique ID. If gp == nil, then traceStack will
// attempt to use the current execution context.
//
// skip controls the number of leaf frames to omit in order to hide tracer internals
// from stack traces, see CL 5523.
//
// Avoid calling this function directly. gen needs to be the current generation
// that this stack trace is being written out for, which needs to be synchronized with
// generations moving forward. Prefer traceEventWriter.stack.
func traceStack(skip int, gp *g, gen uintptr) uint64 {
var pcBuf [traceStackSize]uintptr
// Figure out gp and mp for the backtrace.
var mp *m
if gp == nil {
mp = getg().m
gp = mp.curg
}
// Double-check that we own the stack we're about to trace.
if debug.traceCheckStackOwnership != 0 && gp != nil {
status := readgstatus(gp)
// If the scan bit is set, assume we're the ones that acquired it.
if status&_Gscan == 0 {
// Use the trace status to check this. There are a number of cases
// where a running goroutine might be in _Gwaiting, and these cases
// are totally fine for taking a stack trace. They're captured
// correctly in goStatusToTraceGoStatus.
switch goStatusToTraceGoStatus(status, gp.waitreason) {
case traceGoRunning, traceGoSyscall:
if getg() == gp || mp.curg == gp {
break
}
fallthrough
default:
print("runtime: gp=", unsafe.Pointer(gp), " gp.goid=", gp.goid, " status=", gStatusStrings[status], "\n")
throw("attempted to trace stack of a goroutine this thread does not own")
}
}
}
if gp != nil && mp == nil {
// We're getting the backtrace for a G that's not currently executing.
// It may still have an M, if it's locked to some M.
mp = gp.lockedm.ptr()
}
nstk := 1
if tracefpunwindoff() || (mp != nil && mp.hasCgoOnStack()) {
// Slow path: Unwind using default unwinder. Used when frame pointer
// unwinding is unavailable or disabled (tracefpunwindoff), or might
// produce incomplete results or crashes (hasCgoOnStack). Note that no
// cgo callback related crashes have been observed yet. The main
// motivation is to take advantage of a potentially registered cgo
// symbolizer.
pcBuf[0] = logicalStackSentinel
if getg() == gp {
nstk += callers(skip+1, pcBuf[1:])
} else if gp != nil {
nstk += gcallers(gp, skip, pcBuf[1:])
}
} else {
// Fast path: Unwind using frame pointers.
pcBuf[0] = uintptr(skip)
if getg() == gp {
nstk += fpTracebackPCs(unsafe.Pointer(getfp()), pcBuf[1:])
} else if gp != nil {
// Three cases:
//
// (1) We're called on the g0 stack through mcall(fn) or systemstack(fn). To
// behave like gcallers above, we start unwinding from sched.bp, which
// points to the caller frame of the leaf frame on g's stack. The return
// address of the leaf frame is stored in sched.pc, which we manually
// capture here.
//
// (2) We're called against a gp that we're not currently executing on, but that isn't
// in a syscall, in which case it's currently not executing. gp.sched contains the most
// up-to-date information about where it stopped, and like case (1), we match gcallers
// here.
//
// (3) We're called against a gp that we're not currently executing on, but that is in
// a syscall, in which case gp.syscallsp != 0. gp.syscall* contains the most up-to-date
// information about where it stopped, and like case (1), we match gcallers here.
if gp.syscallsp != 0 {
pcBuf[1] = gp.syscallpc
nstk += 1 + fpTracebackPCs(unsafe.Pointer(gp.syscallbp), pcBuf[2:])
} else {
pcBuf[1] = gp.sched.pc
nstk += 1 + fpTracebackPCs(unsafe.Pointer(gp.sched.bp), pcBuf[2:])
}
}
}
if nstk > 0 {
nstk-- // skip runtime.goexit
}
if nstk > 0 && gp.goid == 1 {
nstk-- // skip runtime.main
}
id := trace.stackTab[gen%2].put(pcBuf[:nstk])
return id
}
// traceStackTable maps stack traces (arrays of PC's) to unique uint32 ids.
// It is lock-free for reading.
type traceStackTable struct {
tab traceMap
}
// 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 (t *traceStackTable) put(pcs []uintptr) uint64 {
if len(pcs) == 0 {
return 0
}
id, _ := t.tab.put(noescape(unsafe.Pointer(&pcs[0])), uintptr(len(pcs))*unsafe.Sizeof(uintptr(0)))
return id
}
// dump writes all previously cached stacks to trace buffers,
// releases all memory and resets state. It must only be called once the caller
// can guarantee that there are no more writers to the table.
func (t *traceStackTable) dump(gen uintptr) {
stackBuf := make([]uintptr, traceStackSize)
w := unsafeTraceWriter(gen, nil)
if root := (*traceMapNode)(t.tab.root.Load()); root != nil {
w = dumpStacksRec(root, w, stackBuf)
}
w.flush().end()
t.tab.reset()
}
func dumpStacksRec(node *traceMapNode, w traceWriter, stackBuf []uintptr) traceWriter {
stack := unsafe.Slice((*uintptr)(unsafe.Pointer(&node.data[0])), uintptr(len(node.data))/unsafe.Sizeof(uintptr(0)))
// N.B. This might allocate, but that's OK because we're not writing to the M's buffer,
// but one we're about to create (with ensure).
n := fpunwindExpand(stackBuf, stack)
frames := makeTraceFrames(w.gen, stackBuf[:n])
// The maximum number of bytes required to hold the encoded stack, given that
// it contains N frames.
maxBytes := 1 + (2+4*len(frames))*traceBytesPerNumber
// Estimate the size of this record. This
// bound is pretty loose, but avoids counting
// lots of varint sizes.
//
// Add 1 because we might also write traceEvStacks.
var flushed bool
w, flushed = w.ensure(1 + maxBytes)
if flushed {
w.byte(byte(traceEvStacks))
}
// Emit stack event.
w.byte(byte(traceEvStack))
w.varint(uint64(node.id))
w.varint(uint64(len(frames)))
for _, frame := range frames {
w.varint(uint64(frame.PC))
w.varint(frame.funcID)
w.varint(frame.fileID)
w.varint(frame.line)
}
// Recursively walk all child nodes.
for i := range node.children {
child := node.children[i].Load()
if child == nil {
continue
}
w = dumpStacksRec((*traceMapNode)(child), w, stackBuf)
}
return w
}
// makeTraceFrames returns the frames corresponding to pcs. It may
// allocate and may emit trace events.
func makeTraceFrames(gen uintptr, pcs []uintptr) []traceFrame {
frames := make([]traceFrame, 0, len(pcs))
ci := CallersFrames(pcs)
for {
f, more := ci.Next()
frames = append(frames, makeTraceFrame(gen, f))
if !more {
return frames
}
}
}
type traceFrame struct {
PC uintptr
funcID uint64
fileID uint64
line uint64
}
// makeTraceFrame sets up a traceFrame for a frame.
func makeTraceFrame(gen uintptr, f Frame) traceFrame {
var frame traceFrame
frame.PC = f.PC
fn := f.Function
const maxLen = 1 << 10
if len(fn) > maxLen {
fn = fn[len(fn)-maxLen:]
}
frame.funcID = trace.stringTab[gen%2].put(gen, fn)
frame.line = uint64(f.Line)
file := f.File
if len(file) > maxLen {
file = file[len(file)-maxLen:]
}
frame.fileID = trace.stringTab[gen%2].put(gen, file)
return frame
}
// tracefpunwindoff returns true if frame pointer unwinding for the tracer is
// disabled via GODEBUG or not supported by the architecture.
func tracefpunwindoff() bool {
return debug.tracefpunwindoff != 0 || (goarch.ArchFamily != goarch.AMD64 && goarch.ArchFamily != goarch.ARM64)
}
// fpTracebackPCs populates pcBuf with the return addresses for each frame and
// returns the number of PCs written to pcBuf. The returned PCs correspond to
// "physical frames" rather than "logical frames"; that is if A is inlined into
// B, this will return a PC for only B.
func fpTracebackPCs(fp unsafe.Pointer, pcBuf []uintptr) (i int) {
for i = 0; i < len(pcBuf) && fp != nil; i++ {
// return addr sits one word above the frame pointer
pcBuf[i] = *(*uintptr)(unsafe.Pointer(uintptr(fp) + goarch.PtrSize))
// follow the frame pointer to the next one
fp = unsafe.Pointer(*(*uintptr)(fp))
}
return i
}
//go:linkname pprof_fpunwindExpand
func pprof_fpunwindExpand(dst, src []uintptr) int {
return fpunwindExpand(dst, src)
}
// fpunwindExpand expands a call stack from pcBuf into dst,
// returning the number of PCs written to dst.
// pcBuf and dst should not overlap.
//
// fpunwindExpand checks if pcBuf contains logical frames (which include inlined
// frames) or physical frames (produced by frame pointer unwinding) using a
// sentinel value in pcBuf[0]. Logical frames are simply returned without the
// sentinel. Physical frames are turned into logical frames via inline unwinding
// and by applying the skip value that's stored in pcBuf[0].
func fpunwindExpand(dst, pcBuf []uintptr) int {
if len(pcBuf) == 0 {
return 0
} else if len(pcBuf) > 0 && pcBuf[0] == logicalStackSentinel {
// pcBuf contains logical rather than inlined frames, skip has already been
// applied, just return it without the sentinel value in pcBuf[0].
return copy(dst, pcBuf[1:])
}
var (
n int
lastFuncID = abi.FuncIDNormal
skip = pcBuf[0]
// skipOrAdd skips or appends retPC to newPCBuf and returns true if more
// pcs can be added.
skipOrAdd = func(retPC uintptr) bool {
if skip > 0 {
skip--
} else if n < len(dst) {
dst[n] = retPC
n++
}
return n < len(dst)
}
)
outer:
for _, retPC := range pcBuf[1:] {
callPC := retPC - 1
fi := findfunc(callPC)
if !fi.valid() {
// There is no funcInfo if callPC belongs to a C function. In this case
// we still keep the pc, but don't attempt to expand inlined frames.
if more := skipOrAdd(retPC); !more {
break outer
}
continue
}
u, uf := newInlineUnwinder(fi, callPC)
for ; uf.valid(); uf = u.next(uf) {
sf := u.srcFunc(uf)
if sf.funcID == abi.FuncIDWrapper && elideWrapperCalling(lastFuncID) {
// ignore wrappers
} else if more := skipOrAdd(uf.pc + 1); !more {
break outer
}
lastFuncID = sf.funcID
}
}
return n
}
// startPCForTrace returns the start PC of a goroutine for tracing purposes.
// If pc is a wrapper, it returns the PC of the wrapped function. Otherwise it
// returns pc.
func startPCForTrace(pc uintptr) uintptr {
f := findfunc(pc)
if !f.valid() {
return pc // may happen for locked g in extra M since its pc is 0.
}
w := funcdata(f, abi.FUNCDATA_WrapInfo)
if w == nil {
return pc // not a wrapper
}
return f.datap.textAddr(*(*uint32)(w))
}