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

 // Copyright 2014 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"
 	"unsafe"
 )

 // Should be a built-in for unsafe.Pointer?
 //
 //go:nosplit
 func add(p unsafe.Pointer, x uintptr) unsafe.Pointer {
 	return unsafe.Pointer(uintptr(p) + x)
 }

 // getg returns the pointer to the current g.
 // The compiler rewrites calls to this function into instructions
 // that fetch the g directly (from TLS or from the dedicated register).
 func getg() *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).
 //
 // This must NOT be go:noescape: if fn is a stack-allocated closure,
 // fn puts g on a run queue, and g executes before fn returns, the
 // closure will be invalidated while it is still executing.
 func mcall(fn func(*g))

 // systemstack runs fn on a system stack.
 // If systemstack is called from the per-OS-thread (g0) stack, or
 // if systemstack is called from the signal handling (gsignal) stack,
 // systemstack calls fn directly and returns.
 // Otherwise, systemstack is being called from the limited stack
 // of an ordinary goroutine. In this case, systemstack switches
 // to the per-OS-thread stack, calls fn, and switches back.
 // It is common to use a func literal as the argument, in order
 // to share inputs and outputs with the code around the call
 // to system stack:
 //
 //	... set up y ...
 //	systemstack(func() {
 //		x = bigcall(y)
 //	})
 //	... use x ...
 //
 //go:noescape
 func systemstack(fn func())

 //go:nosplit
 //go:nowritebarrierrec
 func badsystemstack() {
 	writeErrStr("fatal: systemstack called from unexpected goroutine")
 }

 // memclrNoHeapPointers clears n bytes starting at ptr.
 //
 // Usually you should use typedmemclr. memclrNoHeapPointers should be
 // used only when the caller knows that *ptr contains no heap pointers
 // because either:
 //
 // *ptr is initialized memory and its type is pointer-free, or
 //
 // *ptr is uninitialized memory (e.g., memory that's being reused
 // for a new allocation) and hence contains only "junk".
 //
 // memclrNoHeapPointers ensures that if ptr is pointer-aligned, and n
 // is a multiple of the pointer size, then any pointer-aligned,
 // pointer-sized portion is cleared atomically. Despite the function
 // name, this is necessary because this function is the underlying
 // implementation of typedmemclr and memclrHasPointers. See the doc of
 // memmove for more details.
 //
 // The (CPU-specific) implementations of this function are in memclr_*.s.
 //
 //go:noescape
 func memclrNoHeapPointers(ptr unsafe.Pointer, n uintptr)

 //go:linkname reflect_memclrNoHeapPointers reflect.memclrNoHeapPointers
 func reflect_memclrNoHeapPointers(ptr unsafe.Pointer, n uintptr) {
 	memclrNoHeapPointers(ptr, n)
 }

 // memmove copies n bytes from "from" to "to".
 //
 // memmove ensures that any pointer in "from" is written to "to" with
 // an indivisible write, so that racy reads cannot observe a
 // half-written pointer. This is necessary to prevent the garbage
 // collector from observing invalid pointers, and differs from memmove
 // in unmanaged languages. However, memmove is only required to do
 // this if "from" and "to" may contain pointers, which can only be the
 // case if "from", "to", and "n" are all be word-aligned.
 //
 // Implementations are in memmove_*.s.
 //
 //go:noescape
 func memmove(to, from unsafe.Pointer, n uintptr)

 // Outside assembly calls memmove. Make sure it has ABI wrappers.
 //
 //go:linkname memmove

 //go:linkname reflect_memmove reflect.memmove
 func reflect_memmove(to, from unsafe.Pointer, n uintptr) {
 	memmove(to, from, n)
 }

 // exported value for testing
 const hashLoad = float32(loadFactorNum) / float32(loadFactorDen)

 // in internal/bytealg/equal_*.s
 //
 //go:noescape
 func memequal(a, b unsafe.Pointer, size uintptr) bool

 // noescape hides a pointer from escape analysis.  noescape is
 // the identity function but escape analysis doesn't think the
 // output depends on the input.  noescape is inlined and currently
 // compiles down to zero instructions.
 // USE CAREFULLY!
 //
 //go:nosplit
 func noescape(p unsafe.Pointer) unsafe.Pointer {
 	x := uintptr(p)
 	return unsafe.Pointer(x ^ 0)
 }

 // noEscapePtr hides a pointer from escape analysis. See noescape.
 // USE CAREFULLY!
 //
 //go:nosplit
 func noEscapePtr[T any](p *T) *T {
 	x := uintptr(unsafe.Pointer(p))
 	return (*T)(unsafe.Pointer(x ^ 0))
 }

 // Not all cgocallback frames are actually cgocallback,
 // so not all have these arguments. Mark them uintptr so that the GC
 // does not misinterpret memory when the arguments are not present.
 // cgocallback is not called from Go, only from crosscall2.
 // This in turn calls cgocallbackg, which is where we'll find
 // pointer-declared arguments.
 //
 // When fn is nil (frame is saved g), call dropm instead,
 // this is used when the C thread is exiting.
 func cgocallback(fn, frame, ctxt uintptr)

 func gogo(buf *gobuf)

 func asminit()
 func setg(gg *g)
 func breakpoint()

 // reflectcall calls fn with arguments described by stackArgs, stackArgsSize,
 // frameSize, and regArgs.
 //
 // Arguments passed on the stack and space for return values passed on the stack
 // must be laid out at the space pointed to by stackArgs (with total length
 // stackArgsSize) according to the ABI.
 //
 // stackRetOffset must be some value <= stackArgsSize that indicates the
 // offset within stackArgs where the return value space begins.
 //
 // frameSize is the total size of the argument frame at stackArgs and must
 // therefore be >= stackArgsSize. It must include additional space for spilling
 // register arguments for stack growth and preemption.
 //
 // TODO(mknyszek): Once we don't need the additional spill space, remove frameSize,
 // since frameSize will be redundant with stackArgsSize.
 //
 // Arguments passed in registers must be laid out in regArgs according to the ABI.
 // regArgs will hold any return values passed in registers after the call.
 //
 // reflectcall copies stack arguments from stackArgs to the goroutine stack, and
 // then copies back stackArgsSize-stackRetOffset bytes back to the return space
 // in stackArgs once fn has completed. It also "unspills" argument registers from
 // regArgs before calling fn, and spills them back into regArgs immediately
 // following the call to fn. If there are results being returned on the stack,
 // the caller should pass the argument frame type as stackArgsType so that
 // reflectcall can execute appropriate write barriers during the copy.
 //
 // reflectcall expects regArgs.ReturnIsPtr to be populated indicating which
 // registers on the return path will contain Go pointers. It will then store
 // these pointers in regArgs.Ptrs such that they are visible to the GC.
 //
 // Package reflect passes a frame type. In package runtime, there is only
 // one call that copies results back, in callbackWrap in syscall_windows.go, and it
 // does NOT pass a frame type, meaning there are no write barriers invoked. See that
 // call site for justification.
 //
 // Package reflect accesses this symbol through a linkname.
 //
 // Arguments passed through to reflectcall do not escape. The type is used
 // only in a very limited callee of reflectcall, the stackArgs are copied, and
 // regArgs is only used in the reflectcall frame.
 //
 //go:noescape
 func reflectcall(stackArgsType *_type, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)

 func procyield(cycles uint32)

 type neverCallThisFunction struct{}

 // goexit is the return stub at the top of every goroutine call stack.
 // Each goroutine stack is constructed as if goexit called the
 // goroutine's entry point function, so that when the entry point
 // function returns, it will return to goexit, which will call goexit1
 // to perform the actual exit.
 //
 // This function must never be called directly. Call goexit1 instead.
 // gentraceback assumes that goexit terminates the stack. A direct
 // call on the stack will cause gentraceback to stop walking the stack
 // prematurely and if there is leftover state it may panic.
 func goexit(neverCallThisFunction)

 // publicationBarrier performs a store/store barrier (a "publication"
 // or "export" barrier). Some form of synchronization is required
 // between initializing an object and making that object accessible to
 // another processor. Without synchronization, the initialization
 // writes and the "publication" write may be reordered, allowing the
 // other processor to follow the pointer and observe an uninitialized
 // object. In general, higher-level synchronization should be used,
 // such as locking or an atomic pointer write. publicationBarrier is
 // for when those aren't an option, such as in the implementation of
 // the memory manager.
 //
 // There's no corresponding barrier for the read side because the read
 // side naturally has a data dependency order. All architectures that
 // Go supports or seems likely to ever support automatically enforce
 // data dependency ordering.
 func publicationBarrier()

 // getcallerpc returns the program counter (PC) of its caller's caller.
 // getcallersp returns the stack pointer (SP) of its caller's caller.
 // The implementation may be a compiler intrinsic; there is not
 // necessarily code implementing this on every platform.
 //
 // For example:
 //
 //	func f(arg1, arg2, arg3 int) {
 //		pc := getcallerpc()
 //		sp := getcallersp()
 //	}
 //
 // These two lines find the PC and SP immediately following
 // the call to f (where f will return).
 //
 // The call to getcallerpc and getcallersp must be done in the
 // frame being asked about.
 //
 // The result of getcallersp is correct at the time of the return,
 // but it may be invalidated by any subsequent call to a function
 // that might relocate the stack in order to grow or shrink it.
 // A general rule is that the result of getcallersp should be used
 // immediately and can only be passed to nosplit functions.

 //go:noescape
 func getcallerpc() uintptr

 //go:noescape
 func getcallersp() uintptr // implemented as an intrinsic on all platforms

 // getclosureptr returns the pointer to the current closure.
 // getclosureptr can only be used in an assignment statement
 // at the entry of a function. Moreover, go:nosplit directive
 // must be specified at the declaration of caller function,
 // so that the function prolog does not clobber the closure register.
 // for example:
 //
 //	//go:nosplit
 //	func f(arg1, arg2, arg3 int) {
 //		dx := getclosureptr()
 //	}
 //
 // The compiler rewrites calls to this function into instructions that fetch the
 // pointer from a well-known register (DX on x86 architecture, etc.) directly.
 //
 // WARNING: PGO-based devirtualization cannot detect that caller of
 // getclosureptr require closure context, and thus must maintain a list of
 // these functions, which is in
 // cmd/compile/internal/devirtualize/pgo.maybeDevirtualizeFunctionCall.
 func getclosureptr() uintptr

 //go:noescape
 func asmcgocall(fn, arg unsafe.Pointer) int32

 func morestack()
 func morestack_noctxt()
 func rt0_go()

 // return0 is a stub used to return 0 from deferproc.
 // It is called at the very end of deferproc to signal
 // the calling Go function that it should not jump
 // to deferreturn.
 // in asm_*.s
 func return0()

 // in asm_*.s
 // not called directly; definitions here supply type information for traceback.
 // These must have the same signature (arg pointer map) as reflectcall.
 func call16(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call32(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call64(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call128(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call256(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call512(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call1024(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call2048(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call4096(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call8192(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call16384(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call32768(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call65536(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call131072(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call262144(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call524288(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call1048576(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call2097152(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call4194304(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call8388608(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call16777216(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call33554432(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call67108864(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call134217728(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call268435456(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call536870912(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
 func call1073741824(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)

 func systemstack_switch()

 // alignUp rounds n up to a multiple of a. a must be a power of 2.
 //
 //go:nosplit
 func alignUp(n, a uintptr) uintptr {
 	return (n + a - 1) &^ (a - 1)
 }

 // alignDown rounds n down to a multiple of a. a must be a power of 2.
 //
 //go:nosplit
 func alignDown(n, a uintptr) uintptr {
 	return n &^ (a - 1)
 }

 // divRoundUp returns ceil(n / a).
 func divRoundUp(n, a uintptr) uintptr {
 	// a is generally a power of two. This will get inlined and
 	// the compiler will optimize the division.
 	return (n + a - 1) / a
 }

 // checkASM reports whether assembly runtime checks have passed.
 func checkASM() bool

 func memequal_varlen(a, b unsafe.Pointer) bool

 // bool2int returns 0 if x is false or 1 if x is true.
 func bool2int(x bool) int {
 	// Avoid branches. In the SSA compiler, this compiles to
 	// exactly what you would want it to.
 	return int(*(*uint8)(unsafe.Pointer(&x)))
 }

 // abort crashes the runtime in situations where even throw might not
 // work. In general it should do something a debugger will recognize
 // (e.g., an INT3 on x86). A crash in abort is recognized by the
 // signal handler, which will attempt to tear down the runtime
 // immediately.
 func abort()

 // Called from compiled code; declared for vet; do NOT call from Go.
 func gcWriteBarrier1()
 func gcWriteBarrier2()
 func gcWriteBarrier3()
 func gcWriteBarrier4()
 func gcWriteBarrier5()
 func gcWriteBarrier6()
 func gcWriteBarrier7()
 func gcWriteBarrier8()
 func duffzero()
 func duffcopy()

 // Called from linker-generated .initarray; declared for go vet; do NOT call from Go.
 func addmoduledata()

 // Injected by the signal handler for panicking signals.
 // Initializes any registers that have fixed meaning at calls but
 // are scratch in bodies and calls sigpanic.
 // On many platforms it just jumps to sigpanic.
 func sigpanic0()

 // intArgRegs is used by the various register assignment
 // algorithm implementations in the runtime. These include:.
 // - Finalizers (mfinal.go)
 // - Windows callbacks (syscall_windows.go)
 //
 // Both are stripped-down versions of the algorithm since they
 // only have to deal with a subset of cases (finalizers only
 // take a pointer or interface argument, Go Windows callbacks
 // don't support floating point).
 //
 // It should be modified with care and are generally only
 // modified when testing this package.
 //
 // It should never be set higher than its internal/abi
 // constant counterparts, because the system relies on a
 // structure that is at least large enough to hold the
 // registers the system supports.
 //
 // Protected by finlock.
 var intArgRegs = abi.IntArgRegs
	// Copyright 2014 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"
	"unsafe"
	)

	// Should be a built-in for unsafe.Pointer?
	//
	//go:nosplit
	func add(p unsafe.Pointer, x uintptr) unsafe.Pointer {
	return unsafe.Pointer(uintptr(p) + x)
	}

	// getg returns the pointer to the current g.
	// The compiler rewrites calls to this function into instructions
	// that fetch the g directly (from TLS or from the dedicated register).
	func getg() *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).
	//
	// This must NOT be go:noescape: if fn is a stack-allocated closure,
	// fn puts g on a run queue, and g executes before fn returns, the
	// closure will be invalidated while it is still executing.
	func mcall(fn func(*g))

	// systemstack runs fn on a system stack.
	// If systemstack is called from the per-OS-thread (g0) stack, or
	// if systemstack is called from the signal handling (gsignal) stack,
	// systemstack calls fn directly and returns.
	// Otherwise, systemstack is being called from the limited stack
	// of an ordinary goroutine. In this case, systemstack switches
	// to the per-OS-thread stack, calls fn, and switches back.
	// It is common to use a func literal as the argument, in order
	// to share inputs and outputs with the code around the call
	// to system stack:
	//
	// ... set up y ...
	// systemstack(func() {
	// x = bigcall(y)
	// })
	// ... use x ...
	//
	//go:noescape
	func systemstack(fn func())

	//go:nosplit
	//go:nowritebarrierrec
	func badsystemstack() {
	writeErrStr("fatal: systemstack called from unexpected goroutine")
	}

	// memclrNoHeapPointers clears n bytes starting at ptr.
	//
	// Usually you should use typedmemclr. memclrNoHeapPointers should be
	// used only when the caller knows that *ptr contains no heap pointers
	// because either:
	//
	// *ptr is initialized memory and its type is pointer-free, or
	//
	// *ptr is uninitialized memory (e.g., memory that's being reused
	// for a new allocation) and hence contains only "junk".
	//
	// memclrNoHeapPointers ensures that if ptr is pointer-aligned, and n
	// is a multiple of the pointer size, then any pointer-aligned,
	// pointer-sized portion is cleared atomically. Despite the function
	// name, this is necessary because this function is the underlying
	// implementation of typedmemclr and memclrHasPointers. See the doc of
	// memmove for more details.
	//
	// The (CPU-specific) implementations of this function are in memclr_*.s.
	//
	//go:noescape
	func memclrNoHeapPointers(ptr unsafe.Pointer, n uintptr)

	//go:linkname reflect_memclrNoHeapPointers reflect.memclrNoHeapPointers
	func reflect_memclrNoHeapPointers(ptr unsafe.Pointer, n uintptr) {
	memclrNoHeapPointers(ptr, n)
	}

	// memmove copies n bytes from "from" to "to".
	//
	// memmove ensures that any pointer in "from" is written to "to" with
	// an indivisible write, so that racy reads cannot observe a
	// half-written pointer. This is necessary to prevent the garbage
	// collector from observing invalid pointers, and differs from memmove
	// in unmanaged languages. However, memmove is only required to do
	// this if "from" and "to" may contain pointers, which can only be the
	// case if "from", "to", and "n" are all be word-aligned.
	//
	// Implementations are in memmove_*.s.
	//
	//go:noescape
	func memmove(to, from unsafe.Pointer, n uintptr)

	// Outside assembly calls memmove. Make sure it has ABI wrappers.
	//
	//go:linkname memmove

	//go:linkname reflect_memmove reflect.memmove
	func reflect_memmove(to, from unsafe.Pointer, n uintptr) {
	memmove(to, from, n)
	}

	// exported value for testing
	const hashLoad = float32(loadFactorNum) / float32(loadFactorDen)

	// in internal/bytealg/equal_*.s
	//
	//go:noescape
	func memequal(a, b unsafe.Pointer, size uintptr) bool

	// noescape hides a pointer from escape analysis. noescape is
	// the identity function but escape analysis doesn't think the
	// output depends on the input. noescape is inlined and currently
	// compiles down to zero instructions.
	// USE CAREFULLY!
	//
	//go:nosplit
	func noescape(p unsafe.Pointer) unsafe.Pointer {
	x := uintptr(p)
	return unsafe.Pointer(x ^ 0)
	}

	// noEscapePtr hides a pointer from escape analysis. See noescape.
	// USE CAREFULLY!
	//
	//go:nosplit
	func noEscapePtr[T any](p T) T {
	x := uintptr(unsafe.Pointer(p))
	return (*T)(unsafe.Pointer(x ^ 0))
	}

	// Not all cgocallback frames are actually cgocallback,
	// so not all have these arguments. Mark them uintptr so that the GC
	// does not misinterpret memory when the arguments are not present.
	// cgocallback is not called from Go, only from crosscall2.
	// This in turn calls cgocallbackg, which is where we'll find
	// pointer-declared arguments.
	//
	// When fn is nil (frame is saved g), call dropm instead,
	// this is used when the C thread is exiting.
	func cgocallback(fn, frame, ctxt uintptr)

	func gogo(buf *gobuf)

	func asminit()
	func setg(gg *g)
	func breakpoint()

	// reflectcall calls fn with arguments described by stackArgs, stackArgsSize,
	// frameSize, and regArgs.
	//
	// Arguments passed on the stack and space for return values passed on the stack
	// must be laid out at the space pointed to by stackArgs (with total length
	// stackArgsSize) according to the ABI.
	//
	// stackRetOffset must be some value <= stackArgsSize that indicates the
	// offset within stackArgs where the return value space begins.
	//
	// frameSize is the total size of the argument frame at stackArgs and must
	// therefore be >= stackArgsSize. It must include additional space for spilling
	// register arguments for stack growth and preemption.
	//
	// TODO(mknyszek): Once we don't need the additional spill space, remove frameSize,
	// since frameSize will be redundant with stackArgsSize.
	//
	// Arguments passed in registers must be laid out in regArgs according to the ABI.
	// regArgs will hold any return values passed in registers after the call.
	//
	// reflectcall copies stack arguments from stackArgs to the goroutine stack, and
	// then copies back stackArgsSize-stackRetOffset bytes back to the return space
	// in stackArgs once fn has completed. It also "unspills" argument registers from
	// regArgs before calling fn, and spills them back into regArgs immediately
	// following the call to fn. If there are results being returned on the stack,
	// the caller should pass the argument frame type as stackArgsType so that
	// reflectcall can execute appropriate write barriers during the copy.
	//
	// reflectcall expects regArgs.ReturnIsPtr to be populated indicating which
	// registers on the return path will contain Go pointers. It will then store
	// these pointers in regArgs.Ptrs such that they are visible to the GC.
	//
	// Package reflect passes a frame type. In package runtime, there is only
	// one call that copies results back, in callbackWrap in syscall_windows.go, and it
	// does NOT pass a frame type, meaning there are no write barriers invoked. See that
	// call site for justification.
	//
	// Package reflect accesses this symbol through a linkname.
	//
	// Arguments passed through to reflectcall do not escape. The type is used
	// only in a very limited callee of reflectcall, the stackArgs are copied, and
	// regArgs is only used in the reflectcall frame.
	//
	//go:noescape
	func reflectcall(stackArgsType _type, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs abi.RegArgs)

	func procyield(cycles uint32)

	type neverCallThisFunction struct{}

	// goexit is the return stub at the top of every goroutine call stack.
	// Each goroutine stack is constructed as if goexit called the
	// goroutine's entry point function, so that when the entry point
	// function returns, it will return to goexit, which will call goexit1
	// to perform the actual exit.
	//
	// This function must never be called directly. Call goexit1 instead.
	// gentraceback assumes that goexit terminates the stack. A direct
	// call on the stack will cause gentraceback to stop walking the stack
	// prematurely and if there is leftover state it may panic.
	func goexit(neverCallThisFunction)

	// publicationBarrier performs a store/store barrier (a "publication"
	// or "export" barrier). Some form of synchronization is required
	// between initializing an object and making that object accessible to
	// another processor. Without synchronization, the initialization
	// writes and the "publication" write may be reordered, allowing the
	// other processor to follow the pointer and observe an uninitialized
	// object. In general, higher-level synchronization should be used,
	// such as locking or an atomic pointer write. publicationBarrier is
	// for when those aren't an option, such as in the implementation of
	// the memory manager.
	//
	// There's no corresponding barrier for the read side because the read
	// side naturally has a data dependency order. All architectures that
	// Go supports or seems likely to ever support automatically enforce
	// data dependency ordering.
	func publicationBarrier()

	// getcallerpc returns the program counter (PC) of its caller's caller.
	// getcallersp returns the stack pointer (SP) of its caller's caller.
	// The implementation may be a compiler intrinsic; there is not
	// necessarily code implementing this on every platform.
	//
	// For example:
	//
	// func f(arg1, arg2, arg3 int) {
	// pc := getcallerpc()
	// sp := getcallersp()
	// }
	//
	// These two lines find the PC and SP immediately following
	// the call to f (where f will return).
	//
	// The call to getcallerpc and getcallersp must be done in the
	// frame being asked about.
	//
	// The result of getcallersp is correct at the time of the return,
	// but it may be invalidated by any subsequent call to a function
	// that might relocate the stack in order to grow or shrink it.
	// A general rule is that the result of getcallersp should be used
	// immediately and can only be passed to nosplit functions.

	//go:noescape
	func getcallerpc() uintptr

	//go:noescape
	func getcallersp() uintptr // implemented as an intrinsic on all platforms

	// getclosureptr returns the pointer to the current closure.
	// getclosureptr can only be used in an assignment statement
	// at the entry of a function. Moreover, go:nosplit directive
	// must be specified at the declaration of caller function,
	// so that the function prolog does not clobber the closure register.
	// for example:
	//
	// //go:nosplit
	// func f(arg1, arg2, arg3 int) {
	// dx := getclosureptr()
	// }
	//
	// The compiler rewrites calls to this function into instructions that fetch the
	// pointer from a well-known register (DX on x86 architecture, etc.) directly.
	//
	// WARNING: PGO-based devirtualization cannot detect that caller of
	// getclosureptr require closure context, and thus must maintain a list of
	// these functions, which is in
	// cmd/compile/internal/devirtualize/pgo.maybeDevirtualizeFunctionCall.
	func getclosureptr() uintptr

	//go:noescape
	func asmcgocall(fn, arg unsafe.Pointer) int32

	func morestack()
	func morestack_noctxt()
	func rt0_go()

	// return0 is a stub used to return 0 from deferproc.
	// It is called at the very end of deferproc to signal
	// the calling Go function that it should not jump
	// to deferreturn.
	// in asm_*.s
	func return0()

	// in asm_*.s
	// not called directly; definitions here supply type information for traceback.
	// These must have the same signature (arg pointer map) as reflectcall.
	func call16(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call32(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call64(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call128(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call256(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call512(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call1024(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call2048(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call4096(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call8192(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call16384(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call32768(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call65536(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call131072(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call262144(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call524288(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call1048576(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call2097152(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call4194304(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call8388608(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call16777216(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call33554432(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call67108864(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call134217728(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call268435456(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call536870912(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)
	func call1073741824(typ, fn, stackArgs unsafe.Pointer, stackArgsSize, stackRetOffset, frameSize uint32, regArgs *abi.RegArgs)

	func systemstack_switch()

	// alignUp rounds n up to a multiple of a. a must be a power of 2.
	//
	//go:nosplit
	func alignUp(n, a uintptr) uintptr {
	return (n + a - 1) &^ (a - 1)
	}

	// alignDown rounds n down to a multiple of a. a must be a power of 2.
	//
	//go:nosplit
	func alignDown(n, a uintptr) uintptr {
	return n &^ (a - 1)
	}

	// divRoundUp returns ceil(n / a).
	func divRoundUp(n, a uintptr) uintptr {
	// a is generally a power of two. This will get inlined and
	// the compiler will optimize the division.
	return (n + a - 1) / a
	}

	// checkASM reports whether assembly runtime checks have passed.
	func checkASM() bool

	func memequal_varlen(a, b unsafe.Pointer) bool

	// bool2int returns 0 if x is false or 1 if x is true.
	func bool2int(x bool) int {
	// Avoid branches. In the SSA compiler, this compiles to
	// exactly what you would want it to.
	return int((uint8)(unsafe.Pointer(&x)))
	}

	// abort crashes the runtime in situations where even throw might not
	// work. In general it should do something a debugger will recognize
	// (e.g., an INT3 on x86). A crash in abort is recognized by the
	// signal handler, which will attempt to tear down the runtime
	// immediately.
	func abort()

	// Called from compiled code; declared for vet; do NOT call from Go.
	func gcWriteBarrier1()
	func gcWriteBarrier2()
	func gcWriteBarrier3()
	func gcWriteBarrier4()
	func gcWriteBarrier5()
	func gcWriteBarrier6()
	func gcWriteBarrier7()
	func gcWriteBarrier8()
	func duffzero()
	func duffcopy()

	// Called from linker-generated .initarray; declared for go vet; do NOT call from Go.
	func addmoduledata()

	// Injected by the signal handler for panicking signals.
	// Initializes any registers that have fixed meaning at calls but
	// are scratch in bodies and calls sigpanic.
	// On many platforms it just jumps to sigpanic.
	func sigpanic0()

	// intArgRegs is used by the various register assignment
	// algorithm implementations in the runtime. These include:.
	// - Finalizers (mfinal.go)
	// - Windows callbacks (syscall_windows.go)
	//
	// Both are stripped-down versions of the algorithm since they
	// only have to deal with a subset of cases (finalizers only
	// take a pointer or interface argument, Go Windows callbacks
	// don't support floating point).
	//
	// It should be modified with care and are generally only
	// modified when testing this package.
	//
	// It should never be set higher than its internal/abi
	// constant counterparts, because the system relies on a
	// structure that is at least large enough to hold the
	// registers the system supports.
	//
	// Protected by finlock.
	var intArgRegs = abi.IntArgRegs