runtime: reject onM calls from gsignal stack

The implementation and use patterns of onM assume that they run on either the m->curg or m->g0 stack. Calling onM from m->gsignal has two problems: (1) When not on g0, onM switches to g0 and then "back" to curg. If we didn't start at curg, bad things happen. (2) The use of scalararg/ptrarg to pass C arguments and results assumes that there is only one onM call at a time. If a gsignal starts running, it may have interrupted the setup/teardown of the args for an onM on the curg or g0 stack. Using scalararg/ptrarg itself would smash those. We can fix (1) by remembering what g was running before the switch. We can fix (2) by requiring that uses of onM that might happen on a signal handling stack must save the old scalararg/ptrarg and restore them after the call, instead of zeroing them. The only sane way to do this is to introduce a separate onM_signalsafe that omits the signal check, and then if you see a call to onM_signalsafe you know the surrounding code must preserve the old scalararg/ptrarg values. (The implementation would be that onM_signalsafe just calls fn if on the signal stack or else jumps to onM. It's not necessary to have two whole copies of the function.) (2) is not a problem if the caller and callee are both Go and a closure is used instead of the scalararg/ptrarg slots. For now, I think we can avoid calling onM from code executing on gsignal stacks, so just reject it. In the long term, (2) goes away (as do the scalararg/ptrarg slots) once everything is in Go, and at that point fixing (1) would be trivial and maybe worth doing just for regularity. LGTM=iant R=golang-codereviews, iant CC=dvyukov, golang-codereviews, khr, r https://golang.org/cl/135400043

runtime: reject onM calls from gsignal stack
The implementation and use patterns of onM assume that they run on either the m->curg or m->g0 stack. Calling onM from m->gsignal has two problems: (1) When not on g0, onM switches to g0 and then "back" to curg. If we didn't start at curg, bad things happen. (2) The use of scalararg/ptrarg to pass C arguments and results assumes that there is only one onM call at a time. If a gsignal starts running, it may have interrupted the setup/teardown of the args for an onM on the curg or g0 stack. Using scalararg/ptrarg itself would smash those. We can fix (1) by remembering what g was running before the switch. We can fix (2) by requiring that uses of onM that might happen on a signal handling stack must save the old scalararg/ptrarg and restore them after the call, instead of zeroing them. The only sane way to do this is to introduce a separate onM_signalsafe that omits the signal check, and then if you see a call to onM_signalsafe you know the surrounding code must preserve the old scalararg/ptrarg values. (The implementation would be that onM_signalsafe just calls fn if on the signal stack or else jumps to onM. It's not necessary to have two whole copies of the function.) (2) is not a problem if the caller and callee are both Go and a closure is used instead of the scalararg/ptrarg slots. For now, I think we can avoid calling onM from code executing on gsignal stacks, so just reject it. In the long term, (2) goes away (as do the scalararg/ptrarg slots) once everything is in Go, and at that point fixing (1) would be trivial and maybe worth doing just for regularity. LGTM=iant R=golang-codereviews, iant CC=dvyukov, golang-codereviews, khr, r https://golang.org/cl/135400043
32ecf57d · Russ Cox · cb767247 · 32ecf57d · 32ecf57d · 32ecf57d
Commit 32ecf57d authored Sep 04, 2014 by Russ Cox
5 changed files
--- a/src/pkg/runtime/asm_386.s
+++ b/src/pkg/runtime/asm_386.s
@@ -205,18 +205,26 @@ TEXT runtime·switchtoM(SB), NOSPLIT, $0-4
 	RET

 // func onM(fn func())
-// calls fn() on the M stack.
-// switches to the M stack if not already on it, and
-// switches back when fn() returns.
 TEXT runtime·onM(SB), NOSPLIT, $0-4
 	MOVL	fn+0(FP), DI	// DI = fn
 	get_tls(CX)
 	MOVL	g(CX), AX	// AX = g
 	MOVL	g_m(AX), BX	// BX = m
+
 	MOVL	m_g0(BX), DX	// DX = g0
 	CMPL	AX, DX
 	JEQ	onm

+	MOVL	m_curg(BX), BP
+	CMPL	AX, BP
+	JEQ	oncurg
+	
+	// Not g0, not curg. Must be gsignal, but that's not allowed.
+	// Hide call from linker nosplit analysis.
+	MOVL	$runtime·badonm(SB), AX
+	CALL	AX
+
+oncurg:
 	// save our state in g->sched.  Pretend to
 	// be switchtoM if the G stack is scanned.
 	MOVL	$runtime·switchtoM(SB), (g_sched+gobuf_pc)(AX)

--- a/src/pkg/runtime/asm_amd64.s
+++ b/src/pkg/runtime/asm_amd64.s
@@ -197,18 +197,26 @@ TEXT runtime·switchtoM(SB), NOSPLIT, $0-8
 	RET

 // func onM(fn func())
-// calls fn() on the M stack.
-// switches to the M stack if not already on it, and
-// switches back when fn() returns.
 TEXT runtime·onM(SB), NOSPLIT, $0-8
 	MOVQ	fn+0(FP), DI	// DI = fn
 	get_tls(CX)
 	MOVQ	g(CX), AX	// AX = g
 	MOVQ	g_m(AX), BX	// BX = m
+
 	MOVQ	m_g0(BX), DX	// DX = g0
 	CMPQ	AX, DX
 	JEQ	onm

+	MOVQ	m_curg(BX), BP
+	CMPQ	AX, BP
+	JEQ	oncurg
+	
+	// Not g0, not curg. Must be gsignal, but that's not allowed.
+	// Hide call from linker nosplit analysis.
+	MOVQ	$runtime·badonm(SB), AX
+	CALL	AX
+
+oncurg:
 	// save our state in g->sched.  Pretend to
 	// be switchtoM if the G stack is scanned.
 	MOVQ	$runtime·switchtoM(SB), BP

--- a/src/pkg/runtime/asm_amd64p32.s
+++ b/src/pkg/runtime/asm_amd64p32.s
@@ -175,18 +175,26 @@ TEXT runtime·switchtoM(SB), NOSPLIT, $0-4
 	RET

 // func onM(fn func())
-// calls fn() on the M stack.
-// switches to the M stack if not already on it, and
-// switches back when fn() returns.
 TEXT runtime·onM(SB), NOSPLIT, $0-4
 	MOVL	fn+0(FP), DI	// DI = fn
 	get_tls(CX)
 	MOVL	g(CX), AX	// AX = g
 	MOVL	g_m(AX), BX	// BX = m
+
 	MOVL	m_g0(BX), DX	// DX = g0
 	CMPL	AX, DX
 	JEQ	onm

+	MOVL	m_curg(BX), BP
+	CMPL	AX, BP
+	JEQ	oncurg
+	
+	// Not g0, not curg. Must be gsignal, but that's not allowed.
+	// Hide call from linker nosplit analysis.
+	MOVL	$runtime·badonm(SB), AX
+	CALL	AX
+
+oncurg:
 	// save our state in g->sched.  Pretend to
 	// be switchtoM if the G stack is scanned.
 	MOVL	$runtime·switchtoM(SB), SI

--- a/src/pkg/runtime/asm_arm.s
+++ b/src/pkg/runtime/asm_arm.s
@@ -190,16 +190,24 @@ TEXT runtime·switchtoM(SB), NOSPLIT, $0-4
 	RET

 // func onM(fn func())
-// calls fn() on the M stack.
-// switches to the M stack if not already on it, and
-// switches back when fn() returns.
 TEXT runtime·onM(SB), NOSPLIT, $0-4
 	MOVW	fn+0(FP), R0	// R0 = fn
 	MOVW	g_m(g), R1	// R1 = m
+
 	MOVW	m_g0(R1), R2	// R2 = g0
 	CMP	g, R2
 	B.EQ	onm
-	
+
+	MOVW	m_g0(R1), R3
+	CMP	g, R3
+	B.EQ	oncurg
+
+	// Not g0, not curg. Must be gsignal, but that's not allowed.
+	// Hide call from linker nosplit analysis.
+	MOVW	$runtime·badonm(SB), R0
+	BL	(R0)
+
+oncurg:
 	// save our state in g->sched.  Pretend to
 	// be switchtoM if the G stack is scanned.
 	MOVW	$runtime·switchtoM(SB), R3

--- a/src/pkg/runtime/stubs.go
+++ b/src/pkg/runtime/stubs.go
@@ -58,22 +58,60 @@ func acquirem() *m
 func releasem(mp *m)
 func gomcache() *mcache

-// in asm_*.s
-func mcall(func(*g))
+// mcall switches from the g to the g0 stack and invokes fn(g),
+// where g is the goroutine that made the call.
+// mcall saves g's current PC/SP in g->sched so that it can be restored later.
+// It is up to fn to arrange for that later execution, typically by recording
+// g in a data structure, causing something to call ready(g) later.
+// mcall returns to the original goroutine g later, when g has been rescheduled.
+// fn must not return at all; typically it ends by calling schedule, to let the m
+// run other goroutines.
+//
+// mcall can only be called from g stacks (not g0, not gsignal).
+//go:noescape
+func mcall(fn func(*g))
+
+// onM switches from the g to the g0 stack and invokes fn().
+// When fn returns, onM switches back to the g and returns,
+// continuing execution on the g stack.
+// If arguments must be passed to fn, they can be written to
+// g->m->ptrarg (pointers) and g->m->scalararg (non-pointers)
+// before the call and then consulted during fn.
+// Similarly, fn can pass return values back in those locations.
+// If fn is written in Go, it can be a closure, which avoids the need for
+// ptrarg and scalararg entirely.
+// After reading values out of ptrarg and scalararg it is conventional
+// to zero them to avoid (memory or information) leaks.
+//
+// If onM is called from a g0 stack, it invokes fn and returns,
+// without any stack switches.
+//
+// If onM is called from a gsignal stack, it crashes the program.
+// The implication is that functions used in signal handlers must
+// not use onM.
+//
+// NOTE(rsc): We could introduce a separate onMsignal that is
+// like onM but if called from a gsignal stack would just run fn on
+// that stack. The caller of onMsignal would be required to save the
+// old values of ptrarg/scalararg and restore them when the call
+// was finished, in case the signal interrupted an onM sequence
+// in progress on the g or g0 stacks. Until there is a clear need for this,
+// we just reject onM in signal handling contexts entirely.
+//
+//go:noescape
 func onM(fn func())

+func badonm() {
+	gothrow("onM called from signal goroutine")
+}
+
 // C functions that run on the M stack.
 // Call using mcall.
-// These functions need to be written to arrange explicitly
-// for the goroutine to continue execution.
 func gosched_m(*g)
 func park_m(*g)

 // More C functions that run on the M stack.
 // Call using onM.
-// Arguments should be passed in m->scalararg[x] and m->ptrarg[x].
-// Return values can be passed in those same slots.
-// These functions return to the goroutine when they return.
 func mcacheRefill_m()
 func largeAlloc_m()
 func gc_m()