src/runtime/signal_riscv64.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.

 //go:build linux && riscv64

 package runtime

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

 func dumpregs(c *sigctxt) {
 	print("ra  ", hex(c.ra()), "\t")
 	print("sp  ", hex(c.sp()), "\n")
 	print("gp  ", hex(c.gp()), "\t")
 	print("tp  ", hex(c.tp()), "\n")
 	print("t0  ", hex(c.t0()), "\t")
 	print("t1  ", hex(c.t1()), "\n")
 	print("t2  ", hex(c.t2()), "\t")
 	print("s0  ", hex(c.s0()), "\n")
 	print("s1  ", hex(c.s1()), "\t")
 	print("a0  ", hex(c.a0()), "\n")
 	print("a1  ", hex(c.a1()), "\t")
 	print("a2  ", hex(c.a2()), "\n")
 	print("a3  ", hex(c.a3()), "\t")
 	print("a4  ", hex(c.a4()), "\n")
 	print("a5  ", hex(c.a5()), "\t")
 	print("a6  ", hex(c.a6()), "\n")
 	print("a7  ", hex(c.a7()), "\t")
 	print("s2  ", hex(c.s2()), "\n")
 	print("s3  ", hex(c.s3()), "\t")
 	print("s4  ", hex(c.s4()), "\n")
 	print("s5  ", hex(c.s5()), "\t")
 	print("s6  ", hex(c.s6()), "\n")
 	print("s7  ", hex(c.s7()), "\t")
 	print("s8  ", hex(c.s8()), "\n")
 	print("s9  ", hex(c.s9()), "\t")
 	print("s10 ", hex(c.s10()), "\n")
 	print("s11 ", hex(c.s11()), "\t")
 	print("t3  ", hex(c.t3()), "\n")
 	print("t4  ", hex(c.t4()), "\t")
 	print("t5  ", hex(c.t5()), "\n")
 	print("t6  ", hex(c.t6()), "\t")
 	print("pc  ", hex(c.pc()), "\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.ra()) }
 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 RA, and pc to pretend the panicking
 	// function calls sigpanic directly.
 	// Always save RA 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() - goarch.PtrSize
 	c.set_sp(sp)
 	*(*uint64)(unsafe.Pointer(uintptr(sp))) = c.ra()

 	pc := gp.sigpc

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

 	// In case we are panicking from external C code
 	c.set_gp(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() - goarch.PtrSize
 	c.set_sp(sp)
 	*(*uint64)(unsafe.Pointer(uintptr(sp))) = c.ra()
 	// Set up PC and LR to pretend the function being signaled
 	// calls targetPC at resumePC.
 	c.set_ra(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.

	//go:build linux && riscv64

	package runtime

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

	func dumpregs(c *sigctxt) {
	print("ra ", hex(c.ra()), "\t")
	print("sp ", hex(c.sp()), "\n")
	print("gp ", hex(c.gp()), "\t")
	print("tp ", hex(c.tp()), "\n")
	print("t0 ", hex(c.t0()), "\t")
	print("t1 ", hex(c.t1()), "\n")
	print("t2 ", hex(c.t2()), "\t")
	print("s0 ", hex(c.s0()), "\n")
	print("s1 ", hex(c.s1()), "\t")
	print("a0 ", hex(c.a0()), "\n")
	print("a1 ", hex(c.a1()), "\t")
	print("a2 ", hex(c.a2()), "\n")
	print("a3 ", hex(c.a3()), "\t")
	print("a4 ", hex(c.a4()), "\n")
	print("a5 ", hex(c.a5()), "\t")
	print("a6 ", hex(c.a6()), "\n")
	print("a7 ", hex(c.a7()), "\t")
	print("s2 ", hex(c.s2()), "\n")
	print("s3 ", hex(c.s3()), "\t")
	print("s4 ", hex(c.s4()), "\n")
	print("s5 ", hex(c.s5()), "\t")
	print("s6 ", hex(c.s6()), "\n")
	print("s7 ", hex(c.s7()), "\t")
	print("s8 ", hex(c.s8()), "\n")
	print("s9 ", hex(c.s9()), "\t")
	print("s10 ", hex(c.s10()), "\n")
	print("s11 ", hex(c.s11()), "\t")
	print("t3 ", hex(c.t3()), "\n")
	print("t4 ", hex(c.t4()), "\t")
	print("t5 ", hex(c.t5()), "\n")
	print("t6 ", hex(c.t6()), "\t")
	print("pc ", hex(c.pc()), "\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.ra()) }
	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 RA, and pc to pretend the panicking
	// function calls sigpanic directly.
	// Always save RA 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() - goarch.PtrSize
	c.set_sp(sp)
	(uint64)(unsafe.Pointer(uintptr(sp))) = c.ra()

	pc := gp.sigpc

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

	// In case we are panicking from external C code
	c.set_gp(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() - goarch.PtrSize
	c.set_sp(sp)
	(uint64)(unsafe.Pointer(uintptr(sp))) = c.ra()
	// Set up PC and LR to pretend the function being signaled
	// calls targetPC at resumePC.
	c.set_ra(uint64(resumePC))
	c.set_pc(uint64(targetPC))
	}