示例#1
0
文件: rmq.go 项目: go-binder/rmq
//export ToMsgpack
func ToMsgpack(s C.SEXP) C.SEXP {
	byteSlice := encodeRIntoMsgpack(s)

	if len(byteSlice) == 0 {
		return C.R_NilValue
	}
	rawmsg := C.allocVector(C.RAWSXP, C.R_xlen_t(len(byteSlice)))
	C.Rf_protect(rawmsg)
	C.memcpy(unsafe.Pointer(C.RAW(rawmsg)), unsafe.Pointer(&byteSlice[0]), C.size_t(len(byteSlice)))
	C.Rf_unprotect(1)

	return rawmsg
}
示例#2
0
文件: rmq.go 项目: go-binder/rmq
//export FromMsgpack
func FromMsgpack(s C.SEXP) C.SEXP {
	// starting from within R, we convert a raw byte vector into R structures.

	// s must be a RAWSXP
	if C.TYPEOF(s) != C.RAWSXP {
		C.ReportErrorToR_NoReturn(C.CString("from.msgpack(x) requires x be a RAW vector of bytes."))
	}

	n := int(C.Rf_xlength(s))
	if n == 0 {
		return C.R_NilValue
	}
	bytes := make([]byte, n)

	C.memcpy(unsafe.Pointer(&bytes[0]), unsafe.Pointer(C.RAW(s)), C.size_t(n))

	return decodeMsgpackToR(bytes)
}
示例#3
0
文件: rmq.go 项目: go-binder/rmq
func toIface(s C.SEXP) interface{} {
	// generate a go map or slice or scalar value, then encode it

	n := int(C.Rf_xlength(s))
	if n == 0 {
		return nil // drops type info. Meh.
	}

	switch C.TYPEOF(s) {
	case C.VECSXP:
		// an R generic vector; e.g list()
		VPrintf("encodeRIntoMsgpack sees VECSXP\n")

		// could be a map or a slice. Check out the names.
		rnames := C.Rf_getAttrib(s, C.R_NamesSymbol)
		rnamesLen := int(C.Rf_xlength(rnames))
		VPrintf("namesLen = %d\n", rnamesLen)
		if rnamesLen > 0 {
			myMap := map[string]interface{}{}
			for i := 0; i < rnamesLen; i++ {
				myMap[C.GoString(C.get_string_elt(rnames, C.int(i)))] = toIface(C.VECTOR_ELT(s, C.R_xlen_t(i)))
			}
			VPrintf("VECSXP myMap = '%#v'\n", myMap)
			return myMap
		} else {
			// else: no names, so we treat it as an array instead of as a map
			mySlice := make([]interface{}, n)
			for i := 0; i < n; i++ {
				mySlice[i] = toIface(C.VECTOR_ELT(s, C.R_xlen_t(i)))
			}
			VPrintf("VECSXP mySlice = '%#v'\n", mySlice)
			return mySlice
		}

	case C.REALSXP:
		// a vector of float64 (numeric)
		VPrintf("encodeRIntoMsgpack sees REALSXP\n")
		mySlice := make([]float64, n)
		for i := 0; i < n; i++ {
			mySlice[i] = float64(C.get_real_elt(s, C.int(i)))
		}
		VPrintf("VECSXP mySlice = '%#v'\n", mySlice)
		return mySlice

	case C.INTSXP:
		// a vector of int32
		VPrintf("encodeRIntoMsgpack sees INTSXP\n")
		mySlice := make([]int, n)
		for i := 0; i < n; i++ {
			mySlice[i] = int(C.get_int_elt(s, C.int(i)))
		}
		VPrintf("INTSXP mySlice = '%#v'\n", mySlice)
		return mySlice

	case C.RAWSXP:
		VPrintf("encodeRIntoMsgpack sees RAWSXP\n")
		mySlice := make([]byte, n)
		C.memcpy(unsafe.Pointer(&mySlice[0]), unsafe.Pointer(C.RAW(s)), C.size_t(n))
		VPrintf("RAWSXP mySlice = '%#v'\n", mySlice)
		return mySlice

	case C.STRSXP:
		// a vector of string (pointers to charsxp that are interned)
		VPrintf("encodeRIntoMsgpack sees STRSXP\n")
		mySlice := make([]string, n)
		for i := 0; i < n; i++ {
			mySlice[i] = C.GoString(C.get_string_elt(s, C.int(i)))
		}
		VPrintf("STRSXP mySlice = '%#v'\n", mySlice)
		return mySlice

	case C.NILSXP:
		// c(); an empty vector
		VPrintf("encodeRIntoMsgpack sees NILSXP\n")
		return nil

	case C.CHARSXP:
		// a single string, interned in a global pool for reuse by STRSXP.
		VPrintf("encodeRIntoMsgpack sees CHARSXP\n")
	case C.SYMSXP:
		VPrintf("encodeRIntoMsgpack sees SYMSXP\n")
	case C.LISTSXP:
		VPrintf("encodeRIntoMsgpack sees LISTSXP\n")
	case C.CLOSXP:
		VPrintf("encodeRIntoMsgpack sees CLOSXP\n")
	case C.ENVSXP:
		VPrintf("encodeRIntoMsgpack sees ENVSXP\n")
	case C.PROMSXP:
		VPrintf("encodeRIntoMsgpack sees PROMSXP\n")
	case C.LANGSXP:
		VPrintf("encodeRIntoMsgpack sees LANGSXP\n")
	case C.SPECIALSXP:
		VPrintf("encodeRIntoMsgpack sees SPECIALSXP\n")
	case C.BUILTINSXP:
		VPrintf("encodeRIntoMsgpack sees BUILTINSXP\n")
	case C.LGLSXP:
		VPrintf("encodeRIntoMsgpack sees LGLSXP\n")
	case C.CPLXSXP:
		VPrintf("encodeRIntoMsgpack sees CPLXSXP\n")
	case C.DOTSXP:
		VPrintf("encodeRIntoMsgpack sees DOTSXP\n")
	case C.ANYSXP:
		VPrintf("encodeRIntoMsgpack sees ANYSXP\n")
	case C.EXPRSXP:
		VPrintf("encodeRIntoMsgpack sees EXPRSXP\n")
	case C.BCODESXP:
		VPrintf("encodeRIntoMsgpack sees BCODESXP\n")
	case C.EXTPTRSXP:
		VPrintf("encodeRIntoMsgpack sees EXTPTRSXP\n")
	case C.WEAKREFSXP:
		VPrintf("encodeRIntoMsgpack sees WEAKREFSXP\n")
	case C.S4SXP:
		VPrintf("encodeRIntoMsgpack sees S4SXP\n")
	default:
		VPrintf("encodeRIntoMsgpack sees <unknown>\n")
	}
	VPrintf("... warning: encodeRIntoMsgpack() ignoring this input.\n")

	return nil
}
示例#4
0
文件: rmq.go 项目: go-binder/rmq
//export ListenAndServe
func ListenAndServe(addr_ C.SEXP, handler_ C.SEXP, rho_ C.SEXP) C.SEXP {

	if C.TYPEOF(addr_) != C.STRSXP {
		fmt.Printf("addr is not a string (STRXSP; instead it is: %d)! addr argument to ListenAndServe() must be a string of form 'ip:port'\n", C.TYPEOF(addr_))
		return C.R_NilValue
	}

	//msglen := 0
	if 0 == int(C.isFunction(handler_)) { // 0 is false
		C.ReportErrorToR_NoReturn(C.CString("‘handler’ must be a function"))
		return C.R_NilValue
	}

	if rho_ != nil && rho_ != C.R_NilValue {
		if 0 == int(C.isEnvironment(rho_)) { // 0 is false
			C.ReportErrorToR_NoReturn(C.CString("‘rho’ should be an environment"))
			return C.R_NilValue
		}
	}

	caddr := C.R_CHAR(C.STRING_ELT(addr_, 0))
	addr := C.GoString(caddr)
	fmt.Printf("ListenAndServe listening on address '%s'...\n", addr)

	webSockHandler := func(w http.ResponseWriter, r *http.Request) {
		if r.URL.Path != "/" {
			http.Error(w, "Not found", 404)
			return
		}
		if r.Method != "GET" {
			http.Error(w, "Method not allowed, only GET allowed.", 405)
			return
		}
		c, err := upgrader.Upgrade(w, r, nil)
		if err != nil {
			fmt.Print("websocket handler upgrade error:", err)
			return
		}
		defer c.Close()

		mt, message, err := c.ReadMessage()
		if err != nil {
			fmt.Println("read error: ", err)
			return
		}

		// make the call, and get a response
		msglen := len(message)
		rawmsg := C.allocVector(C.RAWSXP, C.R_xlen_t(msglen))
		C.Rf_protect(rawmsg)
		C.memcpy(unsafe.Pointer(C.RAW(rawmsg)), unsafe.Pointer(&message[0]), C.size_t(msglen))

		// put msg into env that handler_ is called with.
		C.defineVar(C.install(C.CString("msg")), rawmsg, rho_)

		R_serialize_fun = C.findVar(C.install(C.CString("serialize")), C.R_GlobalEnv)

		// todo: callbacks to R functions here not working. don't really need them if R always acts as a client instead.

		// evaluate
		C.PrintToR(C.CString("listenAndServe: stuffed msg into env rho_.\n"))
		//R_fcall := C.lang3(handler_, rawmsg, C.R_NilValue)
		R_fcall := C.lang3(R_serialize_fun, rawmsg, C.R_NilValue)
		C.Rf_protect(R_fcall)
		C.PrintToR(C.CString("listenAndServe: got msg, just prior to eval.\n"))
		evalres := C.eval(R_fcall, rho_)
		C.Rf_protect(evalres)

		C.PrintToR(C.CString("listenAndServe: after eval.\n"))
		/*
			var s, t C.SEXP
			s = C.allocList(3)
			t = s
			C.Rf_protect(t)
			C.SetTypeToLANGSXP(&s)
			//C.SETCAR(t, R_fcall)
			C.SETCAR(t, handler_)
			t = C.CDR(t)
			C.SETCAR(t, rawmsg)

			evalres := C.eval(s, rho_)
			C.Rf_protect(evalres)
		*/
		C.PrintToR(C.CString("nnListenAndServe: done with eval.\n"))

		if C.TYPEOF(evalres) != C.RAWSXP {
			fmt.Printf("rats! handler result was not RAWSXP raw bytes!\n")
		} else {

			//fmt.Printf("recv: %s\n", message)
			err = c.WriteMessage(mt, message)
			if err != nil {
				fmt.Println("write error: ", err)
			}
		}
		C.Rf_unprotect(3)

	} // end handler func

	http.HandleFunc("/", webSockHandler)
	err := http.ListenAndServe(addr, nil)
	if err != nil {
		fmt.Println("ListenAndServe: ", err)
	}

	return C.R_NilValue
}
示例#5
0
文件: rmq.go 项目: go-binder/rmq
func decodeHelper(r interface{}, depth int) (s C.SEXP) {

	VPrintf("decodeHelper() at depth %d, decoded type is %T\n", depth, r)
	switch val := r.(type) {
	case string:
		VPrintf("depth %d found string case: val = %#v\n", depth, val)
		return C.Rf_mkString(C.CString(val))

	case int:
		VPrintf("depth %d found int case: val = %#v\n", depth, val)
		return C.Rf_ScalarReal(C.double(float64(val)))

	case int32:
		VPrintf("depth %d found int32 case: val = %#v\n", depth, val)
		return C.Rf_ScalarReal(C.double(float64(val)))

	case int64:
		VPrintf("depth %d found int64 case: val = %#v\n", depth, val)
		return C.Rf_ScalarReal(C.double(float64(val)))

	case []interface{}:
		VPrintf("depth %d found []interface{} case: val = %#v\n", depth, val)

		var sxpTy C.SEXPTYPE = C.VECSXP

		lenval := len(val)
		if lenval == 0 {
			emptyvec := C.allocVector(C.NILSXP, C.R_xlen_t(0))

			if depth == 0 {
				C.Rf_protect(emptyvec)
			}
			return emptyvec
		}

		if lenval > 0 {
			first := val[0]
			VPrintf(" ... also at depth %d,   ---> first has type '%T' and value '%v'\n", depth, first, first)

			switch first.(type) {
			case string:
				sxpTy = C.STRSXP

				stringSlice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
				C.Rf_protect(stringSlice)
				for i := range val {
					C.SET_STRING_ELT(stringSlice, C.R_xlen_t(i), C.mkChar(C.CString(val[i].(string))))
				}
				if depth != 0 {
					C.Rf_unprotect(1) // unprotect for stringSlice, now that we are returning it
				}
				return stringSlice

			case int64:
				// we can only realistically hope to preserve 53 bits worth here.
				// todo? unless... can we require bit64 package be available somehow?
				sxpTy = C.REALSXP

				numSlice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
				C.Rf_protect(numSlice)
				size := unsafe.Sizeof(C.double(0))
				naflag := false
				rmax := int64(C.pow(FLT_RADIX, DBL_MANT_DIG) - 1)
				//VPrintf("rmax = %v\n", rmax) //  rmax = 9007199254740991
				rmin := -rmax
				ptrNumSlice := unsafe.Pointer(C.REAL(numSlice))
				var ui uintptr
				var rhs C.double
				for i := range val {
					n := val[i].(int64)
					fmt.Printf("n = %d, rmax = %d, n > rmax = %v\n", n, rmax, n > rmax)

					if n < rmin || n > rmax {
						naflag = true
					}

					ui = uintptr(i)
					rhs = C.double(float64(n))
					// Try to avoid any gc activity by avoiding conversions
					// and hence do pointer arithmetic all at once in one expression. See
					// https://github.com/golang/go/issues/8994 for discussion.
					*((*C.double)(unsafe.Pointer(uintptr(ptrNumSlice) + size*ui))) = rhs
				}
				if naflag {
					C.WarnAndContinue(C.CString("integer precision lost while converting to double"))
				}

				if depth != 0 {
					C.Rf_unprotect(1) // unprotect for numSlice, now that we are returning it
				}
				return numSlice

			case float64:
				sxpTy = C.REALSXP

				numSlice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
				C.Rf_protect(numSlice)
				size := unsafe.Sizeof(C.double(0))

				// unfortunately C.memmove() doesn't work here (I tried). I speculate this is because val[i] is
				// really wrapped in an interface{} rather than being a actual float64. val *is* an
				// []interface{} after all.
				var rhs C.double
				ptrNumSlice := unsafe.Pointer(C.REAL(numSlice))
				for i := range val {
					rhs = C.double(val[i].(float64))
					*((*C.double)(unsafe.Pointer(uintptr(ptrNumSlice) + size*uintptr(i)))) = rhs
				}
				if depth != 0 {
					C.Rf_unprotect(1) // unprotect for numSlice, now that we are returning it
				}
				return numSlice

			}
		}

		intslice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
		C.Rf_protect(intslice)
		for i := range val {
			C.SET_VECTOR_ELT(intslice, C.R_xlen_t(i), decodeHelper(val[i], depth+1))
		}
		if depth != 0 {
			C.Rf_unprotect(1) // unprotect for intslice, now that we are returning it
		}
		return intslice

	case map[string]interface{}:

		s = C.allocVector(C.VECSXP, C.R_xlen_t(len(val)))
		if depth == 0 {
			// only protect the top parent of the returned value, recursively
			// geneated are transitively protected by their parent.
			C.Rf_protect(s)
		}
		names := C.allocVector(C.VECSXP, C.R_xlen_t(len(val)))
		C.Rf_protect(names)

		VPrintf("depth %d found map[string]interface case: val = %#v\n", depth, val)
		sortedMapKey, sortedMapVal := makeSortedSlicesFromMap(val)
		for i := range sortedMapKey {

			ele := decodeHelper(sortedMapVal[i], depth+1)
			C.Rf_protect(ele)
			C.SET_VECTOR_ELT(s, C.R_xlen_t(i), ele)
			C.Rf_unprotect(1) // unprotect for ele, now that it is safely inside s.

			ksexpString := C.Rf_mkString(C.CString(sortedMapKey[i]))
			C.SET_VECTOR_ELT(names, C.R_xlen_t(i), ksexpString)
		}
		C.setAttrib(s, C.R_NamesSymbol, names)
		C.Rf_unprotect(1) // unprotect for names, now that it is attached to s.

	case []byte:
		VPrintf("depth %d found []byte case: val = %#v\n", depth, val)

		rawmsg := C.allocVector(C.RAWSXP, C.R_xlen_t(len(val)))

		if depth == 0 {
			C.Rf_protect(rawmsg)
		}
		C.memcpy(unsafe.Pointer(C.RAW(rawmsg)), unsafe.Pointer(&val[0]), C.size_t(len(val)))
		return rawmsg

	case nil:
		return C.R_NilValue

	default:
		fmt.Printf("unknown type in type switch, val = %#v.  type = %T.\n", val, val)
	}

	return s
}
示例#6
0
文件: rmq.go 项目: glycerine/rmq
// new policy: decodeHelper should always return a protected s,
// and the user/client/caller of decodeHelper() is responsible
// for unprotecting s if they are embedding it. This is
// much easier to audit for correctness.
//
// if jsonHeuristicDecode then we'll treat raw []byte that
// start with '{' as JSON and try to decode them too.
//
func decodeHelper(r interface{}, depth int, jsonHeuristicDecode bool) (s C.SEXP) {

	defer func() {
		r := recover()
		if r != nil {
			// truncated or mal-formed msgpack can cause us problems...
			err, isErr := r.(error)
			if !isErr {
				err = fmt.Errorf("'%v'", r)
			}
			C.ReportErrorToR_NoReturn(C.CString(panicErrIntro + err.Error() + "\n" + string(debug.Stack())))
		}
	}()

	VPrintf("decodeHelper() at depth %d, decoded type is %T\n", depth, r)
	switch val := r.(type) {
	case string:
		VPrintf("depth %d found string case: val = %#v\n", depth, val)
		s = C.Rf_mkString(C.CString(val))
		C.Rf_protect(s)
		return s

	case int:
		VPrintf("depth %d found int case: val = %#v\n", depth, val)
		s = C.Rf_ScalarReal(C.double(float64(val)))
		C.Rf_protect(s)
		return s

	case int32:
		VPrintf("depth %d found int32 case: val = %#v\n", depth, val)
		s = C.Rf_ScalarReal(C.double(float64(val)))
		C.Rf_protect(s)
		return s

	case int64:
		VPrintf("depth %d found int64 case: val = %#v\n", depth, val)
		s = C.Rf_ScalarReal(C.double(float64(val)))
		C.Rf_protect(s)
		return s

	case float64:
		VPrintf("depth %d found float64 case: val = %#v\n", depth, val)
		s = C.Rf_ScalarReal(C.double(val))
		C.Rf_protect(s)
		return s

	case []interface{}:
		VPrintf("depth %d found []interface{} case: val = %#v\n", depth, val)

		var sxpTy C.SEXPTYPE = C.VECSXP

		lenval := len(val)
		if lenval == 0 {
			emptyvec := C.allocVector(C.NILSXP, C.R_xlen_t(0))
			C.Rf_protect(emptyvec)
			return emptyvec
		}

		if lenval > 0 {
			first := val[0]
			VPrintf(" ... also at depth %d,   ---> first has type '%T' and value '%v'\n", depth, first, first)

			switch first.(type) {
			case string:
				sxpTy = C.STRSXP

				stringSlice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
				C.Rf_protect(stringSlice)
				for i := range val {
					C.SET_STRING_ELT(stringSlice, C.R_xlen_t(i), C.mkChar(C.CString(val[i].(string))))
				}
				return stringSlice

			case bool:
				sxpTy = C.LGLSXP
				boolSlice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
				C.Rf_protect(boolSlice)
				for i := range val {
					switch val[i].(bool) {
					case true:
						C.set_lglsxp_true(boolSlice, C.ulonglong(i))
					case false:
						C.set_lglsxp_false(boolSlice, C.ulonglong(i))
					}
				}
				return boolSlice

			case int64:
				// we can only realistically hope to preserve 53 bits worth here.
				// todo? unless... can we require bit64 package be available somehow?
				sxpTy = C.REALSXP

				numSlice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
				C.Rf_protect(numSlice)
				size := unsafe.Sizeof(C.double(0))
				naflag := false
				rmax := int64(C.pow(FLT_RADIX, DBL_MANT_DIG) - 1)
				//VPrintf("rmax = %v\n", rmax) //  rmax = 9007199254740991
				rmin := -rmax
				ptrNumSlice := unsafe.Pointer(C.REAL(numSlice))
				var ui uintptr
				var rhs C.double
				for i := range val {
					n := val[i].(int64)
					VPrintf("n = %d, rmax = %d, n > rmax = %v\n", n, rmax, n > rmax)

					if n < rmin || n > rmax {
						naflag = true
					}

					ui = uintptr(i)
					rhs = C.double(float64(n))
					// Try to avoid any gc activity (from the Go runtime) while
					// in the middle of uintptr <-> unsafe.Pointer conversion, as
					// if the gc were to catch us in the middle of that conversion
					// it might crash.
					// Hence we do pointer arithmetic all at once in one expression,
					// which is at present (Oct 2015) is the recommended safe way
					// to do pointer arithmetic in Go. See
					// https://github.com/golang/go/issues/8994 for discussion.
					*((*C.double)(unsafe.Pointer(uintptr(ptrNumSlice) + size*ui))) = rhs
				}
				if naflag {
					C.WarnAndContinue(C.CString("integer precision lost while converting to double"))
				}
				return numSlice

			case float64:
				sxpTy = C.REALSXP

				numSlice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
				C.Rf_protect(numSlice)
				size := unsafe.Sizeof(C.double(0))

				// unfortunately C.memmove() doesn't work here (I tried). I speculate this is because val[i] is
				// really wrapped in an interface{} rather than being a actual float64. val *is* an
				// []interface{} after all.
				var rhs C.double
				ptrNumSlice := unsafe.Pointer(C.REAL(numSlice))
				for i := range val {
					rhs = C.double(val[i].(float64))
					*((*C.double)(unsafe.Pointer(uintptr(ptrNumSlice) + size*uintptr(i)))) = rhs
				}
				return numSlice

			}
		}

		intslice := C.allocVector(sxpTy, C.R_xlen_t(lenval))
		C.Rf_protect(intslice)
		for i := range val {
			elt := decodeHelper(val[i], depth+1, jsonHeuristicDecode)
			C.SET_VECTOR_ELT(intslice, C.R_xlen_t(i), elt)
			C.Rf_unprotect_ptr(elt) // safely inside intslice now
		}
		return intslice

	case map[string]interface{}:

		s = C.allocVector(C.VECSXP, C.R_xlen_t(len(val)))
		C.Rf_protect(s)
		names := C.allocVector(C.VECSXP, C.R_xlen_t(len(val)))
		C.Rf_protect(names)

		VPrintf("depth %d found map[string]interface case: val = %#v\n", depth, val)
		sortedMapKey, sortedMapVal := makeSortedSlicesFromMap(val)
		for i := range sortedMapKey {

			ele := decodeHelper(sortedMapVal[i], depth+1, jsonHeuristicDecode)
			C.SET_VECTOR_ELT(s, C.R_xlen_t(i), ele)
			C.Rf_unprotect_ptr(ele) // unprotect ele now that it is safely inside s.

			ksexpString := C.Rf_mkString(C.CString(sortedMapKey[i]))
			C.Rf_protect(ksexpString)
			C.SET_VECTOR_ELT(names, C.R_xlen_t(i), ksexpString)
			C.Rf_unprotect_ptr(ksexpString) // safely inside names
		}
		C.setAttrib(s, C.R_NamesSymbol, names)
		C.Rf_unprotect_ptr(names) // safely attached to s.

	case []byte:
		VPrintf("depth %d found []byte case: val = %#v\n", depth, val)

		if jsonHeuristicDecode {
			if len(val) > 0 && val[0] == '{' {
				jsonToR := decodeJsonToR(val)
				C.Rf_protect(jsonToR)
				return jsonToR
			}
		}
		rawmsg := C.allocVector(C.RAWSXP, C.R_xlen_t(len(val)))
		C.Rf_protect(rawmsg)
		if len(val) > 0 {
			C.memcpy(unsafe.Pointer(C.RAW(rawmsg)), unsafe.Pointer(&val[0]), C.size_t(len(val)))
		}
		return rawmsg

	case nil:
		s = C.R_NilValue
		C.Rf_protect(s) // must, for uniformly consistency. else we get protect imbalances.
		return s

	case bool:
		boolmsg := C.allocVector(C.LGLSXP, C.R_xlen_t(1))
		C.Rf_protect(boolmsg)
		if val {
			C.set_lglsxp_true(boolmsg, 0)
		} else {
			C.set_lglsxp_false(boolmsg, 0)
		}
		return boolmsg

	default:
		fmt.Printf("unknown type in type switch, val = %#v.  type = %T.\n", val, val)
	}

	return s
}