src/runtime/signal_linux_s390x.go - go - Git at Google

 // Copyright 2016 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.

 package runtime

 import (
 	"internal/abi"
 	"internal/goarch"
 	"runtime/internal/sys"
 	"unsafe"
 )

 type sigctxt struct {
 	info *siginfo
 	ctxt unsafe.Pointer
 }

 //go:nosplit
 //go:nowritebarrierrec
 func (c *sigctxt) regs() *sigcontext {
 	return (*sigcontext)(unsafe.Pointer(&(*ucontext)(c.ctxt).uc_mcontext))
 }

 func (c *sigctxt) r0() uint64   { return c.regs().gregs[0] }
 func (c *sigctxt) r1() uint64   { return c.regs().gregs[1] }
 func (c *sigctxt) r2() uint64   { return c.regs().gregs[2] }
 func (c *sigctxt) r3() uint64   { return c.regs().gregs[3] }
 func (c *sigctxt) r4() uint64   { return c.regs().gregs[4] }
 func (c *sigctxt) r5() uint64   { return c.regs().gregs[5] }
 func (c *sigctxt) r6() uint64   { return c.regs().gregs[6] }
 func (c *sigctxt) r7() uint64   { return c.regs().gregs[7] }
 func (c *sigctxt) r8() uint64   { return c.regs().gregs[8] }
 func (c *sigctxt) r9() uint64   { return c.regs().gregs[9] }
 func (c *sigctxt) r10() uint64  { return c.regs().gregs[10] }
 func (c *sigctxt) r11() uint64  { return c.regs().gregs[11] }
 func (c *sigctxt) r12() uint64  { return c.regs().gregs[12] }
 func (c *sigctxt) r13() uint64  { return c.regs().gregs[13] }
 func (c *sigctxt) r14() uint64  { return c.regs().gregs[14] }
 func (c *sigctxt) r15() uint64  { return c.regs().gregs[15] }
 func (c *sigctxt) link() uint64 { return c.regs().gregs[14] }
 func (c *sigctxt) sp() uint64   { return c.regs().gregs[15] }

 //go:nosplit
 //go:nowritebarrierrec
 func (c *sigctxt) pc() uint64 { return c.regs().psw_addr }

 func (c *sigctxt) sigcode() uint32 { return uint32(c.info.si_code) }
 func (c *sigctxt) sigaddr() uint64 { return c.info.si_addr }

 func (c *sigctxt) set_r0(x uint64)      { c.regs().gregs[0] = x }
 func (c *sigctxt) set_r13(x uint64)     { c.regs().gregs[13] = x }
 func (c *sigctxt) set_link(x uint64)    { c.regs().gregs[14] = x }
 func (c *sigctxt) set_sp(x uint64)      { c.regs().gregs[15] = x }
 func (c *sigctxt) set_pc(x uint64)      { c.regs().psw_addr = x }
 func (c *sigctxt) set_sigcode(x uint32) { c.info.si_code = int32(x) }
 func (c *sigctxt) set_sigaddr(x uint64) {
 	*(*uintptr)(add(unsafe.Pointer(c.info), 2*goarch.PtrSize)) = uintptr(x)
 }

 func dumpregs(c *sigctxt) {
 	print("r0   ", hex(c.r0()), "\t")
 	print("r1   ", hex(c.r1()), "\n")
 	print("r2   ", hex(c.r2()), "\t")
 	print("r3   ", hex(c.r3()), "\n")
 	print("r4   ", hex(c.r4()), "\t")
 	print("r5   ", hex(c.r5()), "\n")
 	print("r6   ", hex(c.r6()), "\t")
 	print("r7   ", hex(c.r7()), "\n")
 	print("r8   ", hex(c.r8()), "\t")
 	print("r9   ", hex(c.r9()), "\n")
 	print("r10  ", hex(c.r10()), "\t")
 	print("r11  ", hex(c.r11()), "\n")
 	print("r12  ", hex(c.r12()), "\t")
 	print("r13  ", hex(c.r13()), "\n")
 	print("r14  ", hex(c.r14()), "\t")
 	print("r15  ", hex(c.r15()), "\n")
 	print("pc   ", hex(c.pc()), "\t")
 	print("link ", hex(c.link()), "\n")
 }

 //go:nosplit
 //go:nowritebarrierrec
 func (c *sigctxt) sigpc() uintptr { return uintptr(c.pc()) }

 func (c *sigctxt) sigsp() uintptr { return uintptr(c.sp()) }
 func (c *sigctxt) siglr() uintptr { return uintptr(c.link()) }
 func (c *sigctxt) fault() uintptr { return uintptr(c.sigaddr()) }

 // preparePanic sets up the stack to look like a call to sigpanic.
 func (c *sigctxt) preparePanic(sig uint32, gp *g) {
 	// We arrange link, and pc to pretend the panicking
 	// function calls sigpanic directly.
 	// Always save LINK to stack so that panics in leaf
 	// functions are correctly handled. This smashes
 	// the stack frame but we're not going back there
 	// anyway.
 	sp := c.sp() - sys.MinFrameSize
 	c.set_sp(sp)
 	*(*uint64)(unsafe.Pointer(uintptr(sp))) = c.link()

 	pc := uintptr(gp.sigpc)

 	if shouldPushSigpanic(gp, pc, uintptr(c.link())) {
 		// Make it look the like faulting PC called sigpanic.
 		c.set_link(uint64(pc))
 	}

 	// In case we are panicking from external C code
 	c.set_r0(0)
 	c.set_r13(uint64(uintptr(unsafe.Pointer(gp))))
 	c.set_pc(uint64(abi.FuncPCABIInternal(sigpanic)))
 }

 func (c *sigctxt) pushCall(targetPC, resumePC uintptr) {
 	// Push the LR to stack, as we'll clobber it in order to
 	// push the call. The function being pushed is responsible
 	// for restoring the LR and setting the SP back.
 	// This extra slot is known to gentraceback.
 	sp := c.sp() - 8
 	c.set_sp(sp)
 	*(*uint64)(unsafe.Pointer(uintptr(sp))) = c.link()
 	// Set up PC and LR to pretend the function being signaled
 	// calls targetPC at resumePC.
 	c.set_link(uint64(resumePC))
 	c.set_pc(uint64(targetPC))
 }
	// Copyright 2016 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.

	package runtime

	import (
	"internal/abi"
	"internal/goarch"
	"runtime/internal/sys"
	"unsafe"
	)

	type sigctxt struct {
	info *siginfo
	ctxt unsafe.Pointer
	}

	//go:nosplit
	//go:nowritebarrierrec
	func (c sigctxt) regs() sigcontext {
	return (sigcontext)(unsafe.Pointer(&(ucontext)(c.ctxt).uc_mcontext))
	}

	func (c *sigctxt) r0() uint64 { return c.regs().gregs[0] }
	func (c *sigctxt) r1() uint64 { return c.regs().gregs[1] }
	func (c *sigctxt) r2() uint64 { return c.regs().gregs[2] }
	func (c *sigctxt) r3() uint64 { return c.regs().gregs[3] }
	func (c *sigctxt) r4() uint64 { return c.regs().gregs[4] }
	func (c *sigctxt) r5() uint64 { return c.regs().gregs[5] }
	func (c *sigctxt) r6() uint64 { return c.regs().gregs[6] }
	func (c *sigctxt) r7() uint64 { return c.regs().gregs[7] }
	func (c *sigctxt) r8() uint64 { return c.regs().gregs[8] }
	func (c *sigctxt) r9() uint64 { return c.regs().gregs[9] }
	func (c *sigctxt) r10() uint64 { return c.regs().gregs[10] }
	func (c *sigctxt) r11() uint64 { return c.regs().gregs[11] }
	func (c *sigctxt) r12() uint64 { return c.regs().gregs[12] }
	func (c *sigctxt) r13() uint64 { return c.regs().gregs[13] }
	func (c *sigctxt) r14() uint64 { return c.regs().gregs[14] }
	func (c *sigctxt) r15() uint64 { return c.regs().gregs[15] }
	func (c *sigctxt) link() uint64 { return c.regs().gregs[14] }
	func (c *sigctxt) sp() uint64 { return c.regs().gregs[15] }

	//go:nosplit
	//go:nowritebarrierrec
	func (c *sigctxt) pc() uint64 { return c.regs().psw_addr }

	func (c *sigctxt) sigcode() uint32 { return uint32(c.info.si_code) }
	func (c *sigctxt) sigaddr() uint64 { return c.info.si_addr }

	func (c *sigctxt) set_r0(x uint64) { c.regs().gregs[0] = x }
	func (c *sigctxt) set_r13(x uint64) { c.regs().gregs[13] = x }
	func (c *sigctxt) set_link(x uint64) { c.regs().gregs[14] = x }
	func (c *sigctxt) set_sp(x uint64) { c.regs().gregs[15] = x }
	func (c *sigctxt) set_pc(x uint64) { c.regs().psw_addr = x }
	func (c *sigctxt) set_sigcode(x uint32) { c.info.si_code = int32(x) }
	func (c *sigctxt) set_sigaddr(x uint64) {
	(uintptr)(add(unsafe.Pointer(c.info), 2*goarch.PtrSize)) = uintptr(x)
	}

	func dumpregs(c *sigctxt) {
	print("r0 ", hex(c.r0()), "\t")
	print("r1 ", hex(c.r1()), "\n")
	print("r2 ", hex(c.r2()), "\t")
	print("r3 ", hex(c.r3()), "\n")
	print("r4 ", hex(c.r4()), "\t")
	print("r5 ", hex(c.r5()), "\n")
	print("r6 ", hex(c.r6()), "\t")
	print("r7 ", hex(c.r7()), "\n")
	print("r8 ", hex(c.r8()), "\t")
	print("r9 ", hex(c.r9()), "\n")
	print("r10 ", hex(c.r10()), "\t")
	print("r11 ", hex(c.r11()), "\n")
	print("r12 ", hex(c.r12()), "\t")
	print("r13 ", hex(c.r13()), "\n")
	print("r14 ", hex(c.r14()), "\t")
	print("r15 ", hex(c.r15()), "\n")
	print("pc ", hex(c.pc()), "\t")
	print("link ", hex(c.link()), "\n")
	}

	//go:nosplit
	//go:nowritebarrierrec
	func (c *sigctxt) sigpc() uintptr { return uintptr(c.pc()) }

	func (c *sigctxt) sigsp() uintptr { return uintptr(c.sp()) }
	func (c *sigctxt) siglr() uintptr { return uintptr(c.link()) }
	func (c *sigctxt) fault() uintptr { return uintptr(c.sigaddr()) }

	// preparePanic sets up the stack to look like a call to sigpanic.
	func (c sigctxt) preparePanic(sig uint32, gp g) {
	// We arrange link, and pc to pretend the panicking
	// function calls sigpanic directly.
	// Always save LINK to stack so that panics in leaf
	// functions are correctly handled. This smashes
	// the stack frame but we're not going back there
	// anyway.
	sp := c.sp() - sys.MinFrameSize
	c.set_sp(sp)
	(uint64)(unsafe.Pointer(uintptr(sp))) = c.link()

	pc := uintptr(gp.sigpc)

	if shouldPushSigpanic(gp, pc, uintptr(c.link())) {
	// Make it look the like faulting PC called sigpanic.
	c.set_link(uint64(pc))
	}

	// In case we are panicking from external C code
	c.set_r0(0)
	c.set_r13(uint64(uintptr(unsafe.Pointer(gp))))
	c.set_pc(uint64(abi.FuncPCABIInternal(sigpanic)))
	}

	func (c *sigctxt) pushCall(targetPC, resumePC uintptr) {
	// Push the LR to stack, as we'll clobber it in order to
	// push the call. The function being pushed is responsible
	// for restoring the LR and setting the SP back.
	// This extra slot is known to gentraceback.
	sp := c.sp() - 8
	c.set_sp(sp)
	(uint64)(unsafe.Pointer(uintptr(sp))) = c.link()
	// Set up PC and LR to pretend the function being signaled
	// calls targetPC at resumePC.
	c.set_link(uint64(resumePC))
	c.set_pc(uint64(targetPC))
	}