2016-03-01 15:57:46 -07:00
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// Copyright 2013 The Go Authors. All rights reserved.
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2014-11-11 15:05:55 -07:00
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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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// +build amd64 amd64p32
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// +build darwin dragonfly freebsd linux nacl netbsd openbsd solaris
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package runtime
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2015-01-14 09:18:24 -07:00
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import (
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2015-11-11 10:39:30 -07:00
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"runtime/internal/sys"
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2015-01-14 09:18:24 -07:00
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"unsafe"
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)
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2014-11-11 15:05:55 -07:00
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func dumpregs(c *sigctxt) {
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print("rax ", hex(c.rax()), "\n")
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print("rbx ", hex(c.rbx()), "\n")
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print("rcx ", hex(c.rcx()), "\n")
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print("rdx ", hex(c.rdx()), "\n")
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print("rdi ", hex(c.rdi()), "\n")
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print("rsi ", hex(c.rsi()), "\n")
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print("rbp ", hex(c.rbp()), "\n")
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print("rsp ", hex(c.rsp()), "\n")
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print("r8 ", hex(c.r8()), "\n")
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print("r9 ", hex(c.r9()), "\n")
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print("r10 ", hex(c.r10()), "\n")
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print("r11 ", hex(c.r11()), "\n")
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print("r12 ", hex(c.r12()), "\n")
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print("r13 ", hex(c.r13()), "\n")
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print("r14 ", hex(c.r14()), "\n")
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print("r15 ", hex(c.r15()), "\n")
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print("rip ", hex(c.rip()), "\n")
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print("rflags ", hex(c.rflags()), "\n")
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print("cs ", hex(c.cs()), "\n")
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print("fs ", hex(c.fs()), "\n")
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print("gs ", hex(c.gs()), "\n")
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}
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2015-01-14 09:18:24 -07:00
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var crashing int32
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2015-03-24 09:51:24 -06:00
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// May run during STW, so write barriers are not allowed.
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2015-11-17 15:20:38 -07:00
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//
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//go:nowritebarrierrec
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func sighandler(sig uint32, info *siginfo, ctxt unsafe.Pointer, gp *g) {
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_g_ := getg()
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c := &sigctxt{info, ctxt}
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if sig == _SIGPROF {
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2015-02-24 22:41:21 -07:00
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sigprof(uintptr(c.rip()), uintptr(c.rsp()), 0, gp, _g_.m)
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return
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}
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if GOOS == "darwin" {
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// x86-64 has 48-bit virtual addresses. The top 16 bits must echo bit 47.
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// The hardware delivers a different kind of fault for a malformed address
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// than it does for an attempt to access a valid but unmapped address.
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// OS X 10.9.2 mishandles the malformed address case, making it look like
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// a user-generated signal (like someone ran kill -SEGV ourpid).
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// We pass user-generated signals to os/signal, or else ignore them.
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// Doing that here - and returning to the faulting code - results in an
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// infinite loop. It appears the best we can do is rewrite what the kernel
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// delivers into something more like the truth. The address used below
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// has very little chance of being the one that caused the fault, but it is
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// malformed, it is clearly not a real pointer, and if it does get printed
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// in real life, people will probably search for it and find this code.
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// There are no Google hits for b01dfacedebac1e or 0xb01dfacedebac1e
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// as I type this comment.
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if sig == _SIGSEGV && c.sigcode() == _SI_USER {
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c.set_sigcode(_SI_USER + 1)
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c.set_sigaddr(0xb01dfacedebac1e)
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}
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}
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flags := int32(_SigThrow)
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if sig < uint32(len(sigtable)) {
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flags = sigtable[sig].flags
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}
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if c.sigcode() != _SI_USER && flags&_SigPanic != 0 {
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// Make it look like a call to the signal func.
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// Have to pass arguments out of band since
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// augmenting the stack frame would break
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// the unwinding code.
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gp.sig = sig
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gp.sigcode0 = uintptr(c.sigcode())
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gp.sigcode1 = uintptr(c.sigaddr())
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gp.sigpc = uintptr(c.rip())
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if GOOS == "darwin" {
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// Work around Leopard bug that doesn't set FPE_INTDIV.
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// Look at instruction to see if it is a divide.
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// Not necessary in Snow Leopard (si_code will be != 0).
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if sig == _SIGFPE && gp.sigcode0 == 0 {
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pc := (*[4]byte)(unsafe.Pointer(gp.sigpc))
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i := 0
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if pc[i]&0xF0 == 0x40 { // 64-bit REX prefix
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i++
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} else if pc[i] == 0x66 { // 16-bit instruction prefix
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i++
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}
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if pc[i] == 0xF6 || pc[i] == 0xF7 {
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gp.sigcode0 = _FPE_INTDIV
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}
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}
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}
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2015-07-10 10:32:03 -06:00
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pc := uintptr(c.rip())
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sp := uintptr(c.rsp())
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// If we don't recognize the PC as code
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// but we do recognize the top pointer on the stack as code,
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// then assume this was a call to non-code and treat like
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// pc == 0, to make unwinding show the context.
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if pc != 0 && findfunc(pc) == nil && findfunc(*(*uintptr)(unsafe.Pointer(sp))) != nil {
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pc = 0
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}
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// Only push runtime.sigpanic if pc != 0.
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// If pc == 0, probably panicked because of a
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// call to a nil func. Not pushing that onto sp will
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// make the trace look like a call to runtime.sigpanic instead.
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// (Otherwise the trace will end at runtime.sigpanic and we
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// won't get to see who faulted.)
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if pc != 0 {
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if sys.RegSize > sys.PtrSize {
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sp -= sys.PtrSize
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*(*uintptr)(unsafe.Pointer(sp)) = 0
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}
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sp -= sys.PtrSize
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*(*uintptr)(unsafe.Pointer(sp)) = pc
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c.set_rsp(uint64(sp))
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}
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c.set_rip(uint64(funcPC(sigpanic)))
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return
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}
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if c.sigcode() == _SI_USER || flags&_SigNotify != 0 {
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if sigsend(sig) {
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return
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}
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}
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2016-01-07 08:19:55 -07:00
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if c.sigcode() == _SI_USER && signal_ignored(sig) {
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return
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}
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2014-11-11 15:05:55 -07:00
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if flags&_SigKill != 0 {
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2016-01-01 16:44:12 -07:00
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dieFromSignal(int32(sig))
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}
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if flags&_SigThrow == 0 {
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return
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}
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_g_.m.throwing = 1
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2015-04-16 22:21:30 -06:00
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_g_.m.caughtsig.set(gp)
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2015-01-14 09:18:24 -07:00
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if crashing == 0 {
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startpanic()
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}
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if sig < uint32(len(sigtable)) {
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print(sigtable[sig].name, "\n")
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} else {
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print("Signal ", sig, "\n")
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}
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2015-01-14 09:18:24 -07:00
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print("PC=", hex(c.rip()), " m=", _g_.m.id, "\n")
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if _g_.m.lockedg != nil && _g_.m.ncgo > 0 && gp == _g_.m.g0 {
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print("signal arrived during cgo execution\n")
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gp = _g_.m.lockedg
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}
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print("\n")
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2015-10-30 09:03:02 -06:00
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level, _, docrash := gotraceback()
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if level > 0 {
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2014-11-11 15:05:55 -07:00
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goroutineheader(gp)
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tracebacktrap(uintptr(c.rip()), uintptr(c.rsp()), 0, gp)
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if crashing > 0 && gp != _g_.m.curg && _g_.m.curg != nil && readgstatus(_g_.m.curg)&^_Gscan == _Grunning {
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// tracebackothers on original m skipped this one; trace it now.
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goroutineheader(_g_.m.curg)
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traceback(^uintptr(0), ^uintptr(0), 0, gp)
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} else if crashing == 0 {
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tracebackothers(gp)
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print("\n")
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}
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dumpregs(c)
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}
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if docrash {
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2015-07-24 17:16:39 -06:00
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crashing++
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if crashing < sched.mcount {
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// There are other m's that need to dump their stacks.
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// Relay SIGQUIT to the next m by sending it to the current process.
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// All m's that have already received SIGQUIT have signal masks blocking
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// receipt of any signals, so the SIGQUIT will go to an m that hasn't seen it yet.
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// When the last m receives the SIGQUIT, it will fall through to the call to
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// crash below. Just in case the relaying gets botched, each m involved in
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// the relay sleeps for 5 seconds and then does the crash/exit itself.
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// In expected operation, the last m has received the SIGQUIT and run
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// crash/exit and the process is gone, all long before any of the
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// 5-second sleeps have finished.
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print("\n-----\n\n")
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raiseproc(_SIGQUIT)
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usleep(5 * 1000 * 1000)
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}
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2014-11-11 15:05:55 -07:00
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crash()
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}
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exit(2)
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}
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