Esempio n. 1
0
// valueOffsetNode ascertains the node for tuple/struct value v,
// then returns the node for its subfield #index.
//
func (a *analysis) valueOffsetNode(v ssa.Value, index int) nodeid {
	id := a.valueNode(v)
	if id == 0 {
		panic(fmt.Sprintf("cannot offset within n0: %s = %s", v.Name(), v))
	}
	return id + nodeid(a.offsetOf(v.Type(), index))
}
Esempio n. 2
0
func (fr *frame) get(key ssa.Value) value {
	switch key := key.(type) {
	case nil:
		// Hack; simplifies handling of optional attributes
		// such as ssa.Slice.{Low,High}.
		return nil
	case *ssa.Function, *ssa.Builtin:
		return key
	case *ssa.Const:
		return constValue(key)
	case *ssa.Global:
		if r, ok := fr.i.globals[key]; ok {
			return r
		}
	}
	if r, ok := fr.env[key]; ok {
		return r
	}
	panic(fmt.Sprintf("get: no value for %T: %v", key, key.Name()))
}
Esempio n. 3
0
// setValueNode associates node id with the value v.
// cgn identifies the context iff v is a local variable.
//
func (a *analysis) setValueNode(v ssa.Value, id nodeid, cgn *cgnode) {
	if cgn != nil {
		a.localval[v] = id
	} else {
		a.globalval[v] = id
	}
	if a.log != nil {
		fmt.Fprintf(a.log, "\tval[%s] = n%d  (%T)\n", v.Name(), id, v)
	}

	// Due to context-sensitivity, we may encounter the same Value
	// in many contexts. We merge them to a canonical node, since
	// that's what all clients want.

	// Record the (v, id) relation if the client has queried pts(v).
	if _, ok := a.config.Queries[v]; ok {
		t := v.Type()
		ptr, ok := a.result.Queries[v]
		if !ok {
			// First time?  Create the canonical query node.
			ptr = Pointer{a, a.addNodes(t, "query")}
			a.result.Queries[v] = ptr
		}
		a.result.Queries[v] = ptr
		a.copy(ptr.n, id, a.sizeof(t))
	}

	// Record the (*v, id) relation if the client has queried pts(*v).
	if _, ok := a.config.IndirectQueries[v]; ok {
		t := v.Type()
		ptr, ok := a.result.IndirectQueries[v]
		if !ok {
			// First time? Create the canonical indirect query node.
			ptr = Pointer{a, a.addNodes(v.Type(), "query.indirect")}
			a.result.IndirectQueries[v] = ptr
		}
		a.genLoad(cgn, ptr.n, v, 0, a.sizeof(t))
	}
}
Esempio n. 4
0
// objectNode returns the object to which v points, if known.
// In other words, if the points-to set of v is a singleton, it
// returns the sole label, zero otherwise.
//
// We exploit this information to make the generated constraints less
// dynamic.  For example, a complex load constraint can be replaced by
// a simple copy constraint when the sole destination is known a priori.
//
// Some SSA instructions always have singletons points-to sets:
// 	Alloc, Function, Global, MakeChan, MakeClosure,  MakeInterface,  MakeMap,  MakeSlice.
// Others may be singletons depending on their operands:
// 	FreeVar, Const, Convert, FieldAddr, IndexAddr, Slice.
//
// Idempotent.  Objects are created as needed, possibly via recursion
// down the SSA value graph, e.g IndexAddr(FieldAddr(Alloc))).
//
func (a *analysis) objectNode(cgn *cgnode, v ssa.Value) nodeid {
	switch v.(type) {
	case *ssa.Global, *ssa.Function, *ssa.Const, *ssa.FreeVar:
		// Global object.
		obj, ok := a.globalobj[v]
		if !ok {
			switch v := v.(type) {
			case *ssa.Global:
				obj = a.nextNode()
				a.addNodes(mustDeref(v.Type()), "global")
				a.endObject(obj, nil, v)

			case *ssa.Function:
				obj = a.makeFunctionObject(v, nil)

			case *ssa.Const:
				// not addressable

			case *ssa.FreeVar:
				// not addressable
			}

			if a.log != nil {
				fmt.Fprintf(a.log, "\tglobalobj[%s] = n%d\n", v, obj)
			}
			a.globalobj[v] = obj
		}
		return obj
	}

	// Local object.
	obj, ok := a.localobj[v]
	if !ok {
		switch v := v.(type) {
		case *ssa.Alloc:
			obj = a.nextNode()
			a.addNodes(mustDeref(v.Type()), "alloc")
			a.endObject(obj, cgn, v)

		case *ssa.MakeSlice:
			obj = a.nextNode()
			a.addNodes(sliceToArray(v.Type()), "makeslice")
			a.endObject(obj, cgn, v)

		case *ssa.MakeChan:
			obj = a.nextNode()
			a.addNodes(v.Type().Underlying().(*types.Chan).Elem(), "makechan")
			a.endObject(obj, cgn, v)

		case *ssa.MakeMap:
			obj = a.nextNode()
			tmap := v.Type().Underlying().(*types.Map)
			a.addNodes(tmap.Key(), "makemap.key")
			elem := a.addNodes(tmap.Elem(), "makemap.value")

			// To update the value field, MapUpdate
			// generates store-with-offset constraints which
			// the presolver can't model, so we must mark
			// those nodes indirect.
			for id, end := elem, elem+nodeid(a.sizeof(tmap.Elem())); id < end; id++ {
				a.mapValues = append(a.mapValues, id)
			}
			a.endObject(obj, cgn, v)

		case *ssa.MakeInterface:
			tConc := v.X.Type()
			obj = a.makeTagged(tConc, cgn, v)

			// Copy the value into it, if nontrivial.
			if x := a.valueNode(v.X); x != 0 {
				a.copy(obj+1, x, a.sizeof(tConc))
			}

		case *ssa.FieldAddr:
			if xobj := a.objectNode(cgn, v.X); xobj != 0 {
				obj = xobj + nodeid(a.offsetOf(mustDeref(v.X.Type()), v.Field))
			}

		case *ssa.IndexAddr:
			if xobj := a.objectNode(cgn, v.X); xobj != 0 {
				obj = xobj + 1
			}

		case *ssa.Slice:
			obj = a.objectNode(cgn, v.X)

		case *ssa.Convert:
			// TODO(adonovan): opt: handle these cases too:
			// - unsafe.Pointer->*T conversion acts like Alloc
			// - string->[]byte/[]rune conversion acts like MakeSlice
		}

		if a.log != nil {
			fmt.Fprintf(a.log, "\tlocalobj[%s] = n%d\n", v.Name(), obj)
		}
		a.localobj[v] = obj
	}
	return obj
}