// Copyright 2009 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. // Cgo call and callback support. // // To call into the C function f from Go, the cgo-generated code calls // runtime.cgocall(_cgo_Cfunc_f, frame), where _cgo_Cfunc_f is a // gcc-compiled function written by cgo. // // runtime.cgocall (below) calls entersyscall so as not to block // other goroutines or the garbage collector, and then calls // runtime.asmcgocall(_cgo_Cfunc_f, frame). // // runtime.asmcgocall (in asm_$GOARCH.s) switches to the m->g0 stack // (assumed to be an operating system-allocated stack, so safe to run // gcc-compiled code on) and calls _cgo_Cfunc_f(frame). // // _cgo_Cfunc_f invokes the actual C function f with arguments // taken from the frame structure, records the results in the frame, // and returns to runtime.asmcgocall. // // After it regains control, runtime.asmcgocall switches back to the // original g (m->curg)'s stack and returns to runtime.cgocall. // // After it regains control, runtime.cgocall calls exitsyscall, which blocks // until this m can run Go code without violating the $GOMAXPROCS limit, // and then unlocks g from m. // // The above description skipped over the possibility of the gcc-compiled // function f calling back into Go. If that happens, we continue down // the rabbit hole during the execution of f. // // To make it possible for gcc-compiled C code to call a Go function p.GoF, // cgo writes a gcc-compiled function named GoF (not p.GoF, since gcc doesn't // know about packages). The gcc-compiled C function f calls GoF. // // GoF initializes "frame", a structure containing all of its // arguments and slots for p.GoF's results. It calls // crosscall2(_cgoexp_GoF, frame, framesize, ctxt) using the gcc ABI. // // crosscall2 (in cgo/asm_$GOARCH.s) is a four-argument adapter from // the gcc function call ABI to the gc function call ABI. At this // point we're in the Go runtime, but we're still running on m.g0's // stack and outside the $GOMAXPROCS limit. crosscall2 calls // runtime.cgocallback(_cgoexp_GoF, frame, ctxt) using the gc ABI. // (crosscall2's framesize argument is no longer used, but there's one // case where SWIG calls crosscall2 directly and expects to pass this // argument. See _cgo_panic.) // // runtime.cgocallback (in asm_$GOARCH.s) switches from m.g0's stack // to the original g (m.curg)'s stack, on which it calls // runtime.cgocallbackg(_cgoexp_GoF, frame, ctxt). As part of the // stack switch, runtime.cgocallback saves the current SP as // m.g0.sched.sp, so that any use of m.g0's stack during the execution // of the callback will be done below the existing stack frames. // Before overwriting m.g0.sched.sp, it pushes the old value on the // m.g0 stack, so that it can be restored later. // // runtime.cgocallbackg (below) is now running on a real goroutine // stack (not an m.g0 stack). First it calls runtime.exitsyscall, which will // block until the $GOMAXPROCS limit allows running this goroutine. // Once exitsyscall has returned, it is safe to do things like call the memory // allocator or invoke the Go callback function. runtime.cgocallbackg // first defers a function to unwind m.g0.sched.sp, so that if p.GoF // panics, m.g0.sched.sp will be restored to its old value: the m.g0 stack // and the m.curg stack will be unwound in lock step. // Then it calls _cgoexp_GoF(frame). // // _cgoexp_GoF, which was generated by cmd/cgo, unpacks the arguments // from frame, calls p.GoF, writes the results back to frame, and // returns. Now we start unwinding this whole process. // // runtime.cgocallbackg pops but does not execute the deferred // function to unwind m.g0.sched.sp, calls runtime.entersyscall, and // returns to runtime.cgocallback. // // After it regains control, runtime.cgocallback switches back to // m.g0's stack (the pointer is still in m.g0.sched.sp), restores the old // m.g0.sched.sp value from the stack, and returns to crosscall2. // // crosscall2 restores the callee-save registers for gcc and returns // to GoF, which unpacks any result values and returns to f. package runtime import ( "internal/abi" "internal/goarch" "internal/goexperiment" "internal/runtime/sys" "unsafe" ) // Addresses collected in a cgo backtrace when crashing. // Length must match arg.Max in x_cgo_callers in runtime/cgo/gcc_traceback.c. type cgoCallers [32]uintptr // argset matches runtime/cgo/linux_syscall.c:argset_t type argset struct { args unsafe.Pointer retval uintptr } // wrapper for syscall package to call cgocall for libc (cgo) calls. // //go:linkname syscall_cgocaller syscall.cgocaller //go:nosplit //go:uintptrescapes func syscall_cgocaller(fn unsafe.Pointer, args ...uintptr) uintptr { as := argset{args: unsafe.Pointer(&args[0])} cgocall(fn, unsafe.Pointer(&as)) return as.retval } var ncgocall uint64 // number of cgo calls in total for dead m // Call from Go to C. // // This must be nosplit because it's used for syscalls on some // platforms. Syscalls may have untyped arguments on the stack, so // it's not safe to grow or scan the stack. // // cgocall should be an internal detail, // but widely used packages access it using linkname. // Notable members of the hall of shame include: // - github.com/ebitengine/purego // // Do not remove or change the type signature. // See go.dev/issue/67401. // //go:linkname cgocall //go:nosplit func cgocall(fn, arg unsafe.Pointer) int32 { if !iscgo && GOOS != "solaris" && GOOS != "illumos" && GOOS != "windows" { throw("cgocall unavailable") } if fn == nil { throw("cgocall nil") } if raceenabled { racereleasemerge(unsafe.Pointer(&racecgosync)) } mp := getg().m mp.ncgocall++ // Reset traceback. mp.cgoCallers[0] = 0 // Announce we are entering a system call // so that the scheduler knows to create another // M to run goroutines while we are in the // foreign code. // // The call to asmcgocall is guaranteed not to // grow the stack and does not allocate memory, // so it is safe to call while "in a system call", outside // the $GOMAXPROCS accounting. // // fn may call back into Go code, in which case we'll exit the // "system call", run the Go code (which may grow the stack), // and then re-enter the "system call" reusing the PC and SP // saved by entersyscall here. entersyscall() // Tell asynchronous preemption that we're entering external // code. We do this after entersyscall because this may block // and cause an async preemption to fail, but at this point a // sync preemption will succeed (though this is not a matter // of correctness). osPreemptExtEnter(mp) mp.incgo = true // We use ncgo as a check during execution tracing for whether there is // any C on the call stack, which there will be after this point. If // there isn't, we can use frame pointer unwinding to collect call // stacks efficiently. This will be the case for the first Go-to-C call // on a stack, so it's preferable to update it here, after we emit a // trace event in entersyscall above. mp.ncgo++ errno := asmcgocall(fn, arg) // Update accounting before exitsyscall because exitsyscall may // reschedule us on to a different M. mp.incgo = false mp.ncgo-- osPreemptExtExit(mp) // Save current syscall parameters, so m.winsyscall can be // used again if callback decide to make syscall. winsyscall := mp.winsyscall exitsyscall() getg().m.winsyscall = winsyscall // Note that raceacquire must be called only after exitsyscall has // wired this M to a P. if raceenabled { raceacquire(unsafe.Pointer(&racecgosync)) } // From the garbage collector's perspective, time can move // backwards in the sequence above. If there's a callback into // Go code, GC will see this function at the call to // asmcgocall. When the Go call later returns to C, the // syscall PC/SP is rolled back and the GC sees this function // back at the call to entersyscall. Normally, fn and arg // would be live at entersyscall and dead at asmcgocall, so if // time moved backwards, GC would see these arguments as dead // and then live. Prevent these undead arguments from crashing // GC by forcing them to stay live across this time warp. KeepAlive(fn) KeepAlive(arg) KeepAlive(mp) return errno } // Set or reset the system stack bounds for a callback on sp. // // Must be nosplit because it is called by needm prior to fully initializing // the M. // //go:nosplit func callbackUpdateSystemStack(mp *m, sp uintptr, signal bool) { g0 := mp.g0 inBound := sp > g0.stack.lo && sp <= g0.stack.hi if mp.ncgo > 0 && !inBound { // ncgo > 0 indicates that this M was in Go further up the stack // (it called C and is now receiving a callback). // // !inBound indicates that we were called with SP outside the // expected system stack bounds (C changed the stack out from // under us between the cgocall and cgocallback?). // // It is not safe for the C call to change the stack out from // under us, so throw. // Note that this case isn't possible for signal == true, as // that is always passing a new M from needm. // Stack is bogus, but reset the bounds anyway so we can print. hi := g0.stack.hi lo := g0.stack.lo g0.stack.hi = sp + 1024 g0.stack.lo = sp - 32*1024 g0.stackguard0 = g0.stack.lo + stackGuard g0.stackguard1 = g0.stackguard0 print("M ", mp.id, " procid ", mp.procid, " runtime: cgocallback with sp=", hex(sp), " out of bounds [", hex(lo), ", ", hex(hi), "]") print("\n") exit(2) } if !mp.isextra { // We allocated the stack for standard Ms. Don't replace the // stack bounds with estimated ones when we already initialized // with the exact ones. return } // This M does not have Go further up the stack. However, it may have // previously called into Go, initializing the stack bounds. Between // that call returning and now the stack may have changed (perhaps the // C thread is running a coroutine library). We need to update the // stack bounds for this case. // // N.B. we need to update the stack bounds even if SP appears to // already be in bounds. Our "bounds" may actually be estimated dummy // bounds (below). The actual stack bounds could have shifted but still // have partial overlap with our dummy bounds. If we failed to update // in that case, we could find ourselves seemingly called near the // bottom of the stack bounds, where we quickly run out of space. // Set the stack bounds to match the current stack. If we don't // actually know how big the stack is, like we don't know how big any // scheduling stack is, but we assume there's at least 32 kB. If we // can get a more accurate stack bound from pthread, use that, provided // it actually contains SP.. g0.stack.hi = sp + 1024 g0.stack.lo = sp - 32*1024 if !signal && _cgo_getstackbound != nil { // Don't adjust if called from the signal handler. // We are on the signal stack, not the pthread stack. // (We could get the stack bounds from sigaltstack, but // we're getting out of the signal handler very soon // anyway. Not worth it.) var bounds [2]uintptr asmcgocall(_cgo_getstackbound, unsafe.Pointer(&bounds)) // getstackbound is an unsupported no-op on Windows. // // Don't use these bounds if they don't contain SP. Perhaps we // were called by something not using the standard thread // stack. if bounds[0] != 0 && sp > bounds[0] && sp <= bounds[1] { g0.stack.lo = bounds[0] g0.stack.hi = bounds[1] } } g0.stackguard0 = g0.stack.lo + stackGuard g0.stackguard1 = g0.stackguard0 } // Call from C back to Go. fn must point to an ABIInternal Go entry-point. // //go:nosplit func cgocallbackg(fn, frame unsafe.Pointer, ctxt uintptr) { gp := getg() if gp != gp.m.curg { println("runtime: bad g in cgocallback") exit(2) } sp := gp.m.g0.sched.sp // system sp saved by cgocallback. callbackUpdateSystemStack(gp.m, sp, false) // The call from C is on gp.m's g0 stack, so we must ensure // that we stay on that M. We have to do this before calling // exitsyscall, since it would otherwise be free to move us to // a different M. The call to unlockOSThread is in this function // after cgocallbackg1, or in the case of panicking, in unwindm. lockOSThread() checkm := gp.m // Save current syscall parameters, so m.winsyscall can be // used again if callback decide to make syscall. winsyscall := gp.m.winsyscall // entersyscall saves the caller's SP to allow the GC to trace the Go // stack. However, since we're returning to an earlier stack frame and // need to pair with the entersyscall() call made by cgocall, we must // save syscall* and let reentersyscall restore them. savedsp := unsafe.Pointer(gp.syscallsp) savedpc := gp.syscallpc savedbp := gp.syscallbp exitsyscall() // coming out of cgo call gp.m.incgo = false if gp.m.isextra { gp.m.isExtraInC = false } osPreemptExtExit(gp.m) if gp.nocgocallback { panic("runtime: function marked with #cgo nocallback called back into Go") } cgocallbackg1(fn, frame, ctxt) // At this point we're about to call unlockOSThread. // The following code must not change to a different m. // This is enforced by checking incgo in the schedule function. gp.m.incgo = true unlockOSThread() if gp.m.isextra { gp.m.isExtraInC = true } if gp.m != checkm { throw("m changed unexpectedly in cgocallbackg") } osPreemptExtEnter(gp.m) // going back to cgo call reentersyscall(savedpc, uintptr(savedsp), savedbp) gp.m.winsyscall = winsyscall } func cgocallbackg1(fn, frame unsafe.Pointer, ctxt uintptr) { gp := getg() if gp.m.needextram || extraMWaiters.Load() > 0 { gp.m.needextram = false systemstack(newextram) } if ctxt != 0 { s := append(gp.cgoCtxt, ctxt) // Now we need to set gp.cgoCtxt = s, but we could get // a SIGPROF signal while manipulating the slice, and // the SIGPROF handler could pick up gp.cgoCtxt while // tracing up the stack. We need to ensure that the // handler always sees a valid slice, so set the // values in an order such that it always does. p := (*slice)(unsafe.Pointer(&gp.cgoCtxt)) atomicstorep(unsafe.Pointer(&p.array), unsafe.Pointer(&s[0])) p.cap = cap(s) p.len = len(s) defer func(gp *g) { // Decrease the length of the slice by one, safely. p := (*slice)(unsafe.Pointer(&gp.cgoCtxt)) p.len-- }(gp) } if gp.m.ncgo == 0 { // The C call to Go came from a thread not currently running // any Go. In the case of -buildmode=c-archive or c-shared, // this call may be coming in before package initialization // is complete. Wait until it is. <-main_init_done } // Check whether the profiler needs to be turned on or off; this route to // run Go code does not use runtime.execute, so bypasses the check there. hz := sched.profilehz if gp.m.profilehz != hz { setThreadCPUProfiler(hz) } // Add entry to defer stack in case of panic. restore := true defer unwindm(&restore) if raceenabled { raceacquire(unsafe.Pointer(&racecgosync)) } // Invoke callback. This function is generated by cmd/cgo and // will unpack the argument frame and call the Go function. var cb func(frame unsafe.Pointer) cbFV := funcval{uintptr(fn)} *(*unsafe.Pointer)(unsafe.Pointer(&cb)) = noescape(unsafe.Pointer(&cbFV)) cb(frame) if raceenabled { racereleasemerge(unsafe.Pointer(&racecgosync)) } // Do not unwind m->g0->sched.sp. // Our caller, cgocallback, will do that. restore = false } func unwindm(restore *bool) { if *restore { // Restore sp saved by cgocallback during // unwind of g's stack (see comment at top of file). mp := acquirem() sched := &mp.g0.sched sched.sp = *(*uintptr)(unsafe.Pointer(sched.sp + alignUp(sys.MinFrameSize, sys.StackAlign))) // Do the accounting that cgocall will not have a chance to do // during an unwind. // // In the case where a Go call originates from C, ncgo is 0 // and there is no matching cgocall to end. if mp.ncgo > 0 { mp.incgo = false mp.ncgo-- osPreemptExtExit(mp) } // Undo the call to lockOSThread in cgocallbackg, only on the // panicking path. In normal return case cgocallbackg will call // unlockOSThread, ensuring no preemption point after the unlock. // Here we don't need to worry about preemption, because we're // panicking out of the callback and unwinding the g0 stack, // instead of reentering cgo (which requires the same thread). unlockOSThread() releasem(mp) } } // called from assembly. func badcgocallback() { throw("misaligned stack in cgocallback") } // called from (incomplete) assembly. func cgounimpl() { throw("cgo not implemented") } var racecgosync uint64 // represents possible synchronization in C code // Pointer checking for cgo code. // We want to detect all cases where a program that does not use // unsafe makes a cgo call passing a Go pointer to memory that // contains an unpinned Go pointer. Here a Go pointer is defined as a // pointer to memory allocated by the Go runtime. Programs that use // unsafe can evade this restriction easily, so we don't try to catch // them. The cgo program will rewrite all possibly bad pointer // arguments to call cgoCheckPointer, where we can catch cases of a Go // pointer pointing to an unpinned Go pointer. // Complicating matters, taking the address of a slice or array // element permits the C program to access all elements of the slice // or array. In that case we will see a pointer to a single element, // but we need to check the entire data structure. // The cgoCheckPointer call takes additional arguments indicating that // it was called on an address expression. An additional argument of // true means that it only needs to check a single element. An // additional argument of a slice or array means that it needs to // check the entire slice/array, but nothing else. Otherwise, the // pointer could be anything, and we check the entire heap object, // which is conservative but safe. // When and if we implement a moving garbage collector, // cgoCheckPointer will pin the pointer for the duration of the cgo // call. (This is necessary but not sufficient; the cgo program will // also have to change to pin Go pointers that cannot point to Go // pointers.) // cgoCheckPointer checks if the argument contains a Go pointer that // points to an unpinned Go pointer, and panics if it does. func cgoCheckPointer(ptr any, arg any) { if !goexperiment.CgoCheck2 && debug.cgocheck == 0 { return } ep := efaceOf(&ptr) t := ep._type top := true if arg != nil && (t.Kind_&abi.KindMask == abi.Pointer || t.Kind_&abi.KindMask == abi.UnsafePointer) { p := ep.data if t.Kind_&abi.KindDirectIface == 0 { p = *(*unsafe.Pointer)(p) } if p == nil || !cgoIsGoPointer(p) { return } aep := efaceOf(&arg) switch aep._type.Kind_ & abi.KindMask { case abi.Bool: if t.Kind_&abi.KindMask == abi.UnsafePointer { // We don't know the type of the element. break } pt := (*ptrtype)(unsafe.Pointer(t)) cgoCheckArg(pt.Elem, p, true, false, cgoCheckPointerFail) return case abi.Slice: // Check the slice rather than the pointer. ep = aep t = ep._type case abi.Array: // Check the array rather than the pointer. // Pass top as false since we have a pointer // to the array. ep = aep t = ep._type top = false default: throw("can't happen") } } cgoCheckArg(t, ep.data, t.Kind_&abi.KindDirectIface == 0, top, cgoCheckPointerFail) } const cgoCheckPointerFail = "cgo argument has Go pointer to unpinned Go pointer" const cgoResultFail = "cgo result is unpinned Go pointer or points to unpinned Go pointer" // cgoCheckArg is the real work of cgoCheckPointer. The argument p // is either a pointer to the value (of type t), or the value itself, // depending on indir. The top parameter is whether we are at the top // level, where Go pointers are allowed. Go pointers to pinned objects are // allowed as long as they don't reference other unpinned pointers. func cgoCheckArg(t *_type, p unsafe.Pointer, indir, top bool, msg string) { if !t.Pointers() || p == nil { // If the type has no pointers there is nothing to do. return } switch t.Kind_ & abi.KindMask { default: throw("can't happen") case abi.Array: at := (*arraytype)(unsafe.Pointer(t)) if !indir { if at.Len != 1 { throw("can't happen") } cgoCheckArg(at.Elem, p, at.Elem.Kind_&abi.KindDirectIface == 0, top, msg) return } for i := uintptr(0); i < at.Len; i++ { cgoCheckArg(at.Elem, p, true, top, msg) p = add(p, at.Elem.Size_) } case abi.Chan, abi.Map: // These types contain internal pointers that will // always be allocated in the Go heap. It's never OK // to pass them to C. panic(errorString(msg)) case abi.Func: if indir { p = *(*unsafe.Pointer)(p) } if !cgoIsGoPointer(p) { return } panic(errorString(msg)) case abi.Interface: it := *(**_type)(p) if it == nil { return } // A type known at compile time is OK since it's // constant. A type not known at compile time will be // in the heap and will not be OK. if inheap(uintptr(unsafe.Pointer(it))) { panic(errorString(msg)) } p = *(*unsafe.Pointer)(add(p, goarch.PtrSize)) if !cgoIsGoPointer(p) { return } if !top && !isPinned(p) { panic(errorString(msg)) } cgoCheckArg(it, p, it.Kind_&abi.KindDirectIface == 0, false, msg) case abi.Slice: st := (*slicetype)(unsafe.Pointer(t)) s := (*slice)(p) p = s.array if p == nil || !cgoIsGoPointer(p) { return } if !top && !isPinned(p) { panic(errorString(msg)) } if !st.Elem.Pointers() { return } for i := 0; i < s.cap; i++ { cgoCheckArg(st.Elem, p, true, false, msg) p = add(p, st.Elem.Size_) } case abi.String: ss := (*stringStruct)(p) if !cgoIsGoPointer(ss.str) { return } if !top && !isPinned(ss.str) { panic(errorString(msg)) } case abi.Struct: st := (*structtype)(unsafe.Pointer(t)) if !indir { if len(st.Fields) != 1 { throw("can't happen") } cgoCheckArg(st.Fields[0].Typ, p, st.Fields[0].Typ.Kind_&abi.KindDirectIface == 0, top, msg) return } for _, f := range st.Fields { if !f.Typ.Pointers() { continue } cgoCheckArg(f.Typ, add(p, f.Offset), true, top, msg) } case abi.Pointer, abi.UnsafePointer: if indir { p = *(*unsafe.Pointer)(p) if p == nil { return } } if !cgoIsGoPointer(p) { return } if !top && !isPinned(p) { panic(errorString(msg)) } cgoCheckUnknownPointer(p, msg) } } // cgoCheckUnknownPointer is called for an arbitrary pointer into Go // memory. It checks whether that Go memory contains any other // pointer into unpinned Go memory. If it does, we panic. // The return values are unused but useful to see in panic tracebacks. func cgoCheckUnknownPointer(p unsafe.Pointer, msg string) (base, i uintptr) { if inheap(uintptr(p)) { b, span, _ := findObject(uintptr(p), 0, 0) base = b if base == 0 { return } tp := span.typePointersOfUnchecked(base) for { var addr uintptr if tp, addr = tp.next(base + span.elemsize); addr == 0 { break } pp := *(*unsafe.Pointer)(unsafe.Pointer(addr)) if cgoIsGoPointer(pp) && !isPinned(pp) { panic(errorString(msg)) } } return } for _, datap := range activeModules() { if cgoInRange(p, datap.data, datap.edata) || cgoInRange(p, datap.bss, datap.ebss) { // We have no way to know the size of the object. // We have to assume that it might contain a pointer. panic(errorString(msg)) } // In the text or noptr sections, we know that the // pointer does not point to a Go pointer. } return } // cgoIsGoPointer reports whether the pointer is a Go pointer--a // pointer to Go memory. We only care about Go memory that might // contain pointers. // //go:nosplit //go:nowritebarrierrec func cgoIsGoPointer(p unsafe.Pointer) bool { if p == nil { return false } if inHeapOrStack(uintptr(p)) { return true } for _, datap := range activeModules() { if cgoInRange(p, datap.data, datap.edata) || cgoInRange(p, datap.bss, datap.ebss) { return true } } return false } // cgoInRange reports whether p is between start and end. // //go:nosplit //go:nowritebarrierrec func cgoInRange(p unsafe.Pointer, start, end uintptr) bool { return start <= uintptr(p) && uintptr(p) < end } // cgoCheckResult is called to check the result parameter of an // exported Go function. It panics if the result is or contains any // other pointer into unpinned Go memory. func cgoCheckResult(val any) { if !goexperiment.CgoCheck2 && debug.cgocheck == 0 { return } ep := efaceOf(&val) t := ep._type cgoCheckArg(t, ep.data, t.Kind_&abi.KindDirectIface == 0, false, cgoResultFail) }