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|
//-----------------------------------------------------------------------------
//
// Copyright (C) Microsoft Corporation. All Rights Reserved.
//
//-----------------------------------------------------------------------------
import scala.util.parsing.input.Position
import scala.util.parsing.input.Positional
object Resolver {
sealed abstract class ResolverOutcome
case class Success() extends ResolverOutcome
case class Errors(ss: List[(Position,String)]) extends ResolverOutcome
var seqClasses = Map[String, SeqClass]();
class ProgramContext(decls: Map[String,TopLevelDecl], currentClass: Class) {
val Decls = decls
val CurrentClass = currentClass
var currentMember = null: Member;
def CurrentMember = currentMember: Member;
var errors: List[(Position,String)] = Nil;
def Error(pos: Position, msg: String) {
errors = errors ::: List((pos, msg))
}
def AddVariable(v: Variable): ProgramContext = {
new LProgramContext(v, this);
}
def LookupVariable(id: String): Option[Variable] = None
def IsVariablePresent(vr: Variable): Boolean = false
private class LProgramContext(v: Variable, parent: ProgramContext) extends ProgramContext(parent.Decls, parent.CurrentClass) {
override def Error(pos: Position, msg: String) = parent.Error(pos, msg)
override def LookupVariable(id: String): Option[Variable] = {
if (id == v.id) Some(v) else parent.LookupVariable(id)
}
override def IsVariablePresent(vr: Variable): Boolean = {
if (vr == v) true else parent.IsVariablePresent(vr)
}
override def CurrentMember() = {
parent.CurrentMember
}
}
}
def Resolve(prog: List[TopLevelDecl]): ResolverOutcome = {
// register the channels as well as the classes and their members
var decls = Map[String,TopLevelDecl]()
for (decl <- BoolClass :: IntClass :: RootClass :: NullClass :: MuClass :: prog) {
if (decls contains decl.id) {
return Errors(List((decl.pos, "duplicate class/channel name: " + decl.id)))
} else {
decl match {
case cl: Class =>
for (m <- cl.members) m match {
case _:MonitorInvariant =>
case m: NamedMember =>
m.Parent = cl
if (cl.mm contains m.Id) {
return Errors(List((m.pos, "duplicate member name " + m.Id + " in class " + cl.id)))
} else {
cl.mm = cl.mm + (m.Id -> m)
}
}
case ch: Channel =>
}
decls = decls + (decl.id -> decl)
}
}
var errors = List[(Position,String)]()
// resolve types of members
val contextNoCurrentClass = new ProgramContext(decls, null)
for (decl <- prog) decl match {
case ch: Channel =>
for (v <- ch.parameters) {
ResolveType(v.t, contextNoCurrentClass)
}
case cl: Class =>
for (m <- cl.asInstanceOf[Class].members) m match {
case _:MonitorInvariant =>
case Field(_, t, _) =>
ResolveType(t, contextNoCurrentClass)
case Method(_, ins, outs, _, _) =>
for (v <- ins ++ outs) {
ResolveType(v.t, contextNoCurrentClass)
}
case _:Condition =>
case _:Predicate =>
case Function(id, ins, out, specs, definition) =>
for (v <- ins) {
ResolveType(v.t, contextNoCurrentClass)
}
ResolveType(out, contextNoCurrentClass)
}
}
errors = errors ++ contextNoCurrentClass.errors;
// now, resolve and typecheck all
// * Field types and Method formal-parameter types
// * Assign, FieldUpdate, and Call statements
// * VariableExpr and FieldSelect expressions
// * Call graph for functions
val calls = new DiGraph[Function];
for (decl <- prog) decl match {
case ch: Channel =>
val context = new ProgramContext(decls, ChannelClass(ch))
var ctx = context
for (v <- ch.parameters) {
ctx = ctx.AddVariable(v)
}
ResolveExpr(ch.where, ctx, false, true)(false)
errors = errors ++ context.errors
case cl: Class =>
val context = new ProgramContext(decls, cl)
for (m <- cl.members) {
context.currentMember = m;
m match {
case MonitorInvariant(e) =>
ResolveExpr(e, context, true, true)(true)
if (!e.typ.IsBool) context.Error(m.pos, "monitor invariant requires a boolean expression (found " + e.typ.FullName + ")")
case _:Field => // nothing more to do
case m@Method(id, ins, outs, spec, body) =>
var ctx = context
for (v <- ins ++ outs) {
ctx = ctx.AddVariable(v)
}
spec foreach {
case Precondition(e) => ResolveExpr(e, ctx, false, true)(false)
case Postcondition(e) => ResolveExpr(e, ctx, true, true)(false)
case lc@LockChange(ee) =>
if(m.id.equals("run")) context.Error(lc.pos, "lockchange not allowed on method run")
ee foreach (e => ResolveExpr(e, ctx, true, false)(false))
}
ResolveStmt(BlockStmt(body), ctx)
case Condition(id, None) =>
case c@Condition(id, Some(e)) =>
ResolveExpr(e, context, false, true)(false)
if (!e.typ.IsBool) context.Error(c.pos, "where clause requires a boolean expression (found " + e.typ.FullName + ")")
case p@Predicate(id, e) =>
var ctx = context;
ResolveExpr(e, ctx, false, true)(true);
if(!e.typ.IsBool) context.Error(e.pos, "predicate requires a boolean expression (found " + e.typ.FullName + ")")
case f@Function(id, ins, out, spec, e) =>
var ctx = context
for (v <- ins) {
ctx = ctx.AddVariable(v)
}
// TODO: disallow credit(...) expressions in function specifications
spec foreach {
case Precondition(e) => ResolveExpr(e, ctx, false, true)(false)
case Postcondition(e) => assert(ctx.CurrentMember != null); ResolveExpr(e, ctx, false, true)(false)
case lc : LockChange => context.Error(lc.pos, "lockchange not allowed on function")
}
ResolveExpr(e, ctx, false, false)(false)
if(! canAssign(out.typ, e.typ)) context.Error(e.pos, "function body does not match declared type (expected: " + out.FullName + ", found: " + e.typ.FullName + ")")
// resolve function calls
calls addNode f;
e visit {
case app : FunctionApplication =>
assert(app.f != null);
calls addNode app.f;
calls.addEdge(f, app.f);
if (app.f == f) f.isRecursive = true; // self-recursion
case _ =>
}
}
}
errors = errors ++ context.errors
}
// fill in SCC
val (_, h) = calls.computeSCC;
h.keys foreach {f:Function =>
f.SCC = h(f);
assert(f.SCC contains f);
if (h(f).size > 1)
f.isRecursive = true;
}
if (errors.length == 0) {
Success()
} else {
Errors(errors)
}
}
def ResolveType(t: Type, context: ProgramContext): Unit = {
for(p <- t.params){
ResolveType(p, context);
}
if(t.isInstanceOf[TokenType]){
val tt = t.asInstanceOf[TokenType];
ResolveType(tt.C, context);
if(! tt.C.typ.IsNormalClass) context.Error(t.pos, "Invalid token type. " + tt.C.FullName + " is not a user-defined class.");
tt.C.typ.LookupMember(tt.m) match {
case Some(m: Method) => val tc = TokenClass(tt.C, tt.m); tc.method = m; tt.typ = tc;
case _ => context.Error(t.pos, "Invalid token type. " + tt.C.FullName + " does not declare a method " + tt.m + ".");
}
return;
}
if (context.Decls contains t.FullName) {
context.Decls(t.FullName) match {
case cl: Class => t.typ = cl
case ch: Channel => t.typ = ChannelClass(ch)
case _ =>
context.Error(t.pos, "Invalid class: " + t.FullName + " does not denote a class")
t.typ = IntClass
}
} else {
if(seqClasses.contains(t.FullName)) {
t.typ = seqClasses(t.FullName)
} else if(t.id.equals("seq") && t.params.length == 1) {
val seqt = new SeqClass(t.params(0).typ);
seqClasses = seqClasses + ((seqt.FullName, seqt));
t.typ = seqt;
} else {
context.Error(t.pos, "undeclared type " + t.FullName)
t.typ = IntClass
}
}
}
def getSeqType(param: Class, context: ProgramContext): Class = {
if(seqClasses.contains("seq<" + param.FullName + ">")) {
seqClasses("seq<" + param.FullName + ">")
} else {
val seqt = new SeqClass(param);
seqClasses = seqClasses + ((seqt.FullName, seqt));
seqt
}
}
def ResolveStmt(s: Statement, context: ProgramContext): Unit = s match {
case Assert(e) =>
ResolveExpr(e, context, true, true)(false)
if (!e.typ.IsBool) context.Error(e.pos, "assert statement requires a boolean expression (found " + e.typ.FullName + ")")
case Assume(e) =>
ResolveExpr(e, context, true, true)(false)
if (!e.typ.IsBool) context.Error(e.pos, "assume statement requires a boolean expression (found " + e.typ.FullName + ")")
case BlockStmt(ss) =>
var ctx = context
for (s <- ss) s match {
case l @ LocalVar(id, t, c, g, rhs) =>
ResolveType(l.v.t, ctx)
val oldCtx = ctx
ctx = ctx.AddVariable(l.v)
rhs match {
case None =>
case Some(rhs) =>
val lhs = VariableExpr(id)
lhs.pos = l.pos;
ResolveExpr(lhs, ctx, false, false)(false)
ResolveAssign(lhs, rhs, oldCtx)
}
case c: CallAsync =>
ResolveStmt(c, ctx)
if (c.local != null) {
ctx = ctx.AddVariable(c.local)
}
case c: Call =>
ResolveStmt(c, ctx)
for (v <- c.locals) { ctx = ctx.AddVariable(v) }
case r: Receive =>
ResolveStmt(r, ctx)
for (v <- r.locals) { ctx = ctx.AddVariable(v) }
case s =>
ResolveStmt(s, ctx)
}
case IfStmt(guard, thn, els) =>
ResolveExpr(guard, context, false, false)(false)
if (!guard.typ.IsBool) context.Error(guard.pos, "if statement requires a boolean guard (found " + guard.typ.FullName + ")")
CheckNoGhost(guard, context)
ResolveStmt(thn, context)
els match { case None => case Some(s) => ResolveStmt(s, context) }
case w@ WhileStmt(guard, invs, lkch, body) =>
ResolveExpr(guard, context, false, false)(false)
if (!guard.typ.IsBool) context.Error(guard.pos, "while statement requires a boolean guard (found " + guard.typ.FullName + ")")
CheckNoGhost(guard, context)
for (inv <- invs) {
ResolveExpr(inv, context, true, true)(false)
if (!inv.typ.IsBool) context.Error(inv.pos, "loop invariant must be boolean (found " + inv.typ.FullName + ")")
}
for (l <- lkch) {
ResolveExpr(l, context, true, false)(false)
if (!l.typ.IsRef) context.Error(l.pos, "lockchange expression must be reference (found " + l.typ.FullName + ")")
}
ResolveStmt(body, context)
w.LoopTargets = ComputeLoopTargets(body) filter context.IsVariablePresent
case Assign(lhs, rhs) =>
ResolveExpr(lhs, context, false, false)(false)
ResolveAssign(lhs, rhs, context)
if (lhs.v != null && lhs.v.IsImmutable) {
if (lhs.v.IsGhost)
CheckNoGhost(rhs, context)
else
context.Error(lhs.pos, "cannot assign to immutable variable " + lhs.v.id)
}
case fu@FieldUpdate(lhs, rhs) =>
ResolveExpr(lhs, context, false, false)(false)
if (! lhs.isPredicate && lhs.f != null && !lhs.f.isGhost) CheckNoGhost(lhs.e, context)
if (! lhs.isPredicate && lhs.f.isInstanceOf[SpecialField]) context.Error(lhs.pos, "cannot assign directly to special field: " + lhs.id)
ResolveExpr(rhs, context, false, false)(false)
if (! lhs.isPredicate && !canAssign(lhs.typ, rhs.typ)) context.Error(fu.pos, "type mismatch in assignment, lhs=" + lhs.typ.FullName + " rhs=" + rhs.typ.FullName)
if (! lhs.isPredicate && lhs.f != null && !lhs.f.isGhost) CheckNoGhost(rhs, context)
case lv:LocalVar => throw new Exception("unexpected LocalVar; should have been handled in BlockStmt above")
case c @ Call(declaresLocal, lhs, obj, id, args) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
args foreach { a => ResolveExpr(a, context, false, false)(false); CheckNoGhost(a, context) }
// lookup method
var typ: Class = IntClass
obj.typ.LookupMember(id) match {
case None =>
context.Error(c.pos, "call of undeclared member " + id + " in class " + obj.typ.FullName)
case Some(m: Method) =>
c.m = m
if (args.length != m.ins.length)
context.Error(c.pos, "wrong number of actual in-parameters in call to " + obj.typ.FullName + "." + id +
" (" + args.length + " instead of " + m.ins.length + ")")
else {
for((actual, formal) <- args zip m.ins){
if(! canAssign(formal.t.typ, actual.typ))
context.Error(actual.pos, "the type of the actual argument is not assignable to the formal parameter (expected: " + formal.t.FullName + ", found: " + actual.typ.FullName + ")")
}
}
if (lhs.length != m.outs.length)
context.Error(c.pos, "wrong number of actual out-parameters in call to " + obj.typ.FullName + "." + id +
" (" + lhs.length + " instead of " + m.outs.length + ")")
else
c.locals = ResolveLHS(declaresLocal, lhs, m.outs, context)
case _ => context.Error(c.pos, "call expression does not denote a method: " + obj.typ.FullName + "." + id)
}
case Install(obj, lowerBounds, upperBounds) =>
ResolveExpr(obj, context, false, false)(false)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in reorder statement must be of a reference type (found " + obj.typ.FullName + ")")
if (obj.typ.IsChannel) context.Error(obj.pos, "object in reorder statement must not be a channel (found " + obj.typ.FullName + ")")
ResolveBounds(lowerBounds, upperBounds, context, "install")
case Share(obj, lowerBounds, upperBounds) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in share statement must be of a reference type (found " + obj.typ.FullName + ")")
if (obj.typ.IsChannel) context.Error(obj.pos, "object in share statement must not be a channel (found " + obj.typ.FullName + ")")
ResolveBounds(lowerBounds, upperBounds, context, "share")
case Unshare(obj) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in unshare statement must be of a reference type (found " + obj.typ.FullName + ")")
if (obj.typ.IsChannel) context.Error(obj.pos, "object in unshare statement must not be a channel (found " + obj.typ.FullName + ")")
case Acquire(obj) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in acquire statement must be of a reference type (found " + obj.typ.FullName + ")")
case Release(obj) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in release statement must be of a reference type (found " + obj.typ.FullName + ")")
case RdAcquire(obj) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in rd acquire statement must be of a reference type (found " + obj.typ.FullName + ")")
case RdRelease(obj) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in rd release statement must be of a reference type (found " + obj.typ.FullName + ")")
case Lock(obj, b, rdLock) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) {
val sname = if (rdLock) "rd lock" else "lock";
context.Error(obj.pos, "object in " + sname + " statement must be of a reference type (found " + obj.typ.FullName + ")")
}
ResolveStmt(b, context)
case Downgrade(obj) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in downgrade statement must be of a reference type (found " + obj.typ.FullName + ")")
case Free(obj) =>
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
if (!obj.typ.IsRef) context.Error(obj.pos, "object in free statement must be of a reference type (found " + obj.typ.FullName + ")")
case fld@Fold(e) =>
ResolveExpr(e, context, false, true)(false);
CheckNoGhost(e, context);
if(!e.ma.isPredicate) context.Error(fld.pos, "Fold can only be applied to predicates.")
case ufld@Unfold(e) =>
ResolveExpr(e, context, false, true)(false);
CheckNoGhost(e, context);
if(!e.ma.isPredicate) context.Error(ufld.pos, "Unfold can only be applied to predicates.")
case c@CallAsync(declaresLocal, token, obj, id, args) =>
// resolve receiver
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
// resolve arguments
args foreach { a => ResolveExpr(a, context, false, false)(false); CheckNoGhost(a, context) }
// lookup method
var typ: Class = IntClass
obj.typ.LookupMember(id) match {
case None =>
context.Error(c.pos, "call of undeclared member " + id + " in class " + obj.typ.FullName)
case Some(m: Method) =>
c.m = m
if (args.length != m.ins.length)
context.Error(c.pos, "wrong number of actual in-parameters in call to " + obj.typ.FullName + "." + id +
" (" + args.length + " instead of " + m.ins.length + ")")
else {
for((actual, formal) <- args zip m.ins){
if(! canAssign(formal.t.typ, actual.typ))
context.Error(actual.pos, "the type of the actual argument is not assignable to the formal parameter (expected: " + formal.t.FullName + ", found: " + actual.typ.FullName + ")")
}
}
case _ => context.Error(c.pos, "call expression does not denote a method: " + obj.typ.FullName + "." + id)
}
// resolve the token
if (declaresLocal) {
c.local = new Variable(token.id, TokenType(new Type(obj.typ), id))
ResolveType(c.local.t, context)
token.Resolve(c.local)
} else if (token != null) {
ResolveExpr(token, context, false, false)(false)
if(! canAssign(token.typ, TokenClass(new Type(obj.typ), id)))
context.Error(token.pos, "wrong token type")
}
case jn@JoinAsync(lhs, token) =>
// resolve the assignees
var vars = Set[Variable]()
for (v <- lhs) {
ResolveExpr(v, context, false, false)(false)
if (v.v != null) {
if (v.v.IsImmutable) context.Error(v.pos, "cannot use immutable variable " + v.id + " as actual out-parameter")
if (vars contains v.v) {
context.Error(v.pos, "duplicate actual out-parameter: " + v.id)
} else {
vars = vars + v.v
}
}
}
// resolve the token
ResolveExpr(token, context, false, false)(false);
if(token.typ == null || ! token.typ.IsToken || ! token.typ.isInstanceOf[TokenClass] || token.typ.asInstanceOf[TokenClass].method == null)
context.Error(token.pos, "the first argument of a join async must be a token")
else {
val m = token.typ.asInstanceOf[TokenClass].method;
jn.m = m
if (lhs.length != m.outs.length)
context.Error(jn.pos, "wrong number of actual out-parameters in join async of " + m.FullName +
" (" + lhs.length + " instead of " + m.outs.length + ")")
else {
for((out, l) <- m.outs zip lhs){
if(! canAssign(l.typ, out.t.typ))
context.Error(l.pos, "the out parameter cannot be assigned to the lhs (expected: " + l.typ.FullName + ", found: " + out.t.FullName + ")")
}
}
}
case w@Wait(obj, id) =>
// resolve receiver
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
// lookup condition
obj.typ.LookupMember(id) match {
case None =>
context.Error(w.pos, "wait on undeclared member " + id + " in class " + obj.typ.FullName)
case Some(c: Condition) => w.c = c
case _ =>
context.Error(w.pos, "wait expression does not denote a condition: " + obj.typ.FullName + "." + id)
}
case s@Signal(obj, id, all) =>
// resolve receiver
ResolveExpr(obj, context, false, false)(false)
CheckNoGhost(obj, context)
// lookup condition
obj.typ.LookupMember(id) match {
case None =>
context.Error(s.pos, "signal on undeclared member " + id + " in class " + obj.typ.FullName)
case Some(c: Condition) => s.c = c
case _ =>
context.Error(s.pos, "signal expression does not denote a condition: " + obj.typ.FullName + "." + id)
}
case s@Send(ch, args) =>
ResolveExpr(ch, context, false, false)(false)
CheckNoGhost(ch, context)
args foreach { a => ResolveExpr(a, context, false, false)(false); CheckNoGhost(a, context) }
// match types of arguments
ch.typ match {
case ChannelClass(channel) =>
if (args.length != channel.parameters.length)
context.Error(s.pos, "wrong number of actual in-parameters in send for channel type " + ch.typ.FullName +
" (" + args.length + " instead of " + channel.parameters.length + ")")
else {
for ((actual, formal) <- args zip channel.parameters) {
if (! canAssign(formal.t.typ, actual.typ))
context.Error(actual.pos, "the type of the actual argument is not assignable to the formal parameter (expected: " + formal.t.FullName + ", found: " + actual.typ.FullName + ")")
}
}
case _ => context.Error(s.pos, "send expression (which has type " + ch.typ.FullName + ") does not denote a channel")
}
case r@Receive(declaresLocal, ch, outs) =>
ResolveExpr(ch, context, false, false)(false)
CheckNoGhost(ch, context)
// match types of arguments
ch.typ match {
case ChannelClass(channel) =>
if (outs.length != channel.parameters.length)
context.Error(r.pos, "wrong number of actual out-parameters in receive for channel type " + ch.typ.FullName +
" (" + outs.length + " instead of " + channel.parameters.length + ")")
else
r.locals = ResolveLHS(declaresLocal, outs, channel.parameters, context)
case _ => context.Error(r.pos, "receive expression (which has type " + ch.typ.FullName + ") does not denote a channel")
}
}
def ResolveLHS(declaresLocal: List[Boolean], actuals: List[VariableExpr], formals: List[Variable], context: ProgramContext): List[Variable] = {
var locals = List[Variable]()
var vars = Set[Variable]()
var ctx = context
for (((declareLocal, actual), formal) <- declaresLocal zip actuals zip formals) {
if (declareLocal) {
val local = new Variable(actual.id, new Type(formal.t.typ))
locals = locals ::: List(local)
ResolveType(local.t, ctx)
actual.Resolve(local)
vars = vars + actual.v
ctx = ctx.AddVariable(local)
} else {
ResolveExpr(actual, ctx, false, false)(false)
CheckNoGhost(actual, ctx)
if (actual.v != null) {
if (! canAssign(actual.typ, formal.t.typ))
ctx.Error(actual.pos, "the type of the formal argument is not assignable to the actual parameter (expected: " +
formal.t.FullName + ", found: " + actual.typ.FullName + ")")
if (vars contains actual.v)
ctx.Error(actual.pos, "duplicate actual out-parameter: " + actual.id)
else if (actual.v.IsImmutable)
ctx.Error(actual.pos, "cannot use immutable variable " + actual.id + " as actual out-parameter")
vars = vars + actual.v
}
}
}
locals
}
def ResolveBounds(lowerBounds: List[Expression], upperBounds: List[Expression], context: ProgramContext, descript: String) =
for (b <- lowerBounds ++ upperBounds) {
ResolveExpr(b, context, true, false)(false)
if (!b.typ.IsRef && !b.typ.IsMu)
context.Error(b.pos, descript + " bound must be of a reference type or Mu type (found " + b.typ.FullName + ")")
}
def ComputeLoopTargets(s: Statement): Set[Variable] = s match { // local variables
case BlockStmt(ss) =>
(ss :\ Set[Variable]()) { (s,vars) => vars ++ ComputeLoopTargets(s) }
case IfStmt(guard, thn, els) =>
val vars = ComputeLoopTargets(thn)
els match { case None => vars; case Some(els) => vars ++ ComputeLoopTargets(els) }
case w: WhileStmt =>
// assume w.LoopTargets is non-null and that it was computed with a larger context
w.LoopTargets
case Assign(lhs, rhs) =>
if (lhs.v != null) Set(lhs.v) else Set() // don't assume resolution was successful
case lv: LocalVar =>
lv.rhs match { case None => Set() case Some(_) => Set(lv.v) }
case Call(_, lhs, obj, id, args) =>
(lhs :\ Set[Variable]()) { (ve,vars) => if (ve.v != null) vars + ve.v else vars }
case _ => Set()
}
def ResolveAssign(lhs: VariableExpr, rhs: RValue, context: ProgramContext) = {
rhs match {
case ExplicitSeq(Nil) => rhs.typ = lhs.typ; // if [] appears on the rhs of an assignment, we "infer" its type by looking at the type of the lhs
case _ => ResolveExpr(rhs, context, false, false)(false)
}
if (! canAssign(lhs.typ, rhs.typ))
context.Error(lhs.pos, "type mismatch in assignment, lhs=" + lhs.typ.FullName + " rhs=" + rhs.typ.FullName)
if (lhs.v != null && !lhs.v.IsGhost) CheckNoGhost(rhs, context)
}
// ResolveExpr resolves all parts of an RValue, if possible, and (always) sets the RValue's typ field
def ResolveExpr(e: RValue, context: ProgramContext,
twoStateContext: Boolean, specContext: Boolean)(implicit inPredicate: Boolean): Unit = e match {
case e @ NewRhs(id, initialization, lower, upper) =>
if (context.Decls contains id) {
context.Decls(id) match {
case ch: Channel =>
e.typ = ChannelClass(ch)
case cl: Class =>
e.typ = cl
if (lower != Nil || upper != Nil)
context.Error(e.pos, "A new object of a class type is not allowed to have a wait-order bounds clause (use the share statement instead)")
}
// initialize the fields
var fieldNames = Set[String]()
for(ini@Init(f, init) <- initialization) {
if (fieldNames contains f) {
context.Error(ini.pos, "The field " + f + " occurs more than once in initializer.")
} else {
fieldNames = fieldNames + f
e.typ.LookupMember(f) match {
case Some(field@Field(name, tp, _)) =>
if(field.isInstanceOf[SpecialField]) context.Error(init.pos, "Initializer cannot assign to special field " + name + ".");
ResolveExpr(init, context, false, false);
if(! canAssign(tp.typ, init.typ)) context.Error(init.pos, "The field " + name + " cannot be initialized with an expression of type " + init.typ.id + ".");
ini.f = field;
case _ =>
context.Error(e.pos, "The type " + id + " does not declare a field " + f + ".");
}
}
}
// resolve the bounds
ResolveBounds(lower, upper, context, "new")
} else {
context.Error(e.pos, "undefined class or channel " + id + " used in new expression")
e.typ = IntClass
}
case i:IntLiteral =>
i.typ = IntClass
case b:BoolLiteral =>
b.typ = BoolClass
case n:NullLiteral =>
n.typ = NullClass
case mx:MaxLockLiteral =>
mx.typ = MuClass
case mx:LockBottomLiteral =>
mx.typ = MuClass
case r:Result =>
assert(context.CurrentMember!=null);
r.typ = IntClass
if(context.CurrentMember==null || ! context.CurrentMember.isInstanceOf[Function]){
context.Error(r.pos, "The variable result can only be used in the postcondition of a function.");
} else {
r.typ = context.CurrentMember.asInstanceOf[Function].out.typ;
}
case ve @ VariableExpr(id) =>
context.LookupVariable(id) match {
case None => context.Error(ve.pos, "undefined local variable " + id); ve.typ = IntClass
case Some(v) => ve.Resolve(v) }
case v:ThisExpr => v.typ = context.CurrentClass
case sel @ MemberAccess(e, id) =>
ResolveExpr(e, context, twoStateContext, false)
var typ: Class = IntClass
e.typ.LookupMember(id) match {
case None =>
context.Error(sel.pos, "undeclared member " + id + " in class " + e.typ.FullName)
case Some(f: Field) => sel.f = f; typ = f.typ.typ
case Some(pred@Predicate(id, body)) =>
if(! specContext)
context.Error(sel.pos, "predicate can only be used in positive predicate contexts")
sel.predicate = pred;
sel.isPredicate = true;
typ = BoolClass
case _ => context.Error(sel.pos, "field-select expression does not denote a field: " + e.typ.FullName + "." + id);
}
sel.typ = typ
case Frac(perm) => ResolveExpr(perm, context, twoStateContext, false);
case Epsilons(perm) => ResolveExpr(perm, context, twoStateContext, false);
case Full | Epsilon | Star => ;
case expr @ Access(e, perm) =>
if (!specContext) context.Error(expr.pos, (perm match {case _:Read => "rd"; case _:Write => "acc"}) + " expression is allowed only in positive predicate contexts")
ResolveExpr(e, context, twoStateContext, true)
ResolveExpr(perm, context, twoStateContext, false);
expr.typ = BoolClass
case expr @ AccessAll(obj, perm) =>
if (!specContext) context.Error(expr.pos, (perm match {case _:Read => "rd"; case _:Write => "acc"}) + " expression is allowed only in positive predicate contexts")
ResolveExpr(obj, context, twoStateContext, false)
if(!obj.typ.IsRef) context.Error(expr.pos, "Target of .* must be object reference.")
ResolveExpr(perm, context, twoStateContext, false);
expr.typ = BoolClass
case expr @ AccessSeq(s, f, perm) =>
if (!specContext) context.Error(expr.pos, (perm match {case _:Read => "rd"; case _:Write => "acc"}) + " expression is allowed only in positive predicate contexts")
ResolveExpr(s, context, twoStateContext, false)
if(!s.typ.IsSeq) context.Error(expr.pos, "Target of [*] must be sequence.")
ResolveExpr(perm, context, twoStateContext, false);
f match {
case Some(x) =>
ResolveExpr(x, context, twoStateContext, true);
case _ => }
expr.typ = BoolClass
case expr@ Credit(e,n) =>
if (!specContext) context.Error(expr.pos, "credit expression is allowed only in positive predicate contexts")
ResolveExpr(e, context, twoStateContext, false)
if(!e.typ.IsChannel) context.Error(expr.pos, "credit argument must denote a channel.")
ResolveExpr(expr.N, context, twoStateContext, false)
expr.typ = BoolClass
case expr@ Holds(e) =>
if(inPredicate) context.Error(expr.pos, "holds cannot be mentioned in monitor invariants or predicates")
ResolveExpr(e, context, twoStateContext, false)
expr.typ = BoolClass
case expr@ RdHolds(e) =>
if(inPredicate) context.Error(expr.pos, "rdholds cannot be mentioned in monitor invariants or predicates")
ResolveExpr(e, context, twoStateContext, false)
expr.typ = BoolClass
case expr@ Assigned(id) =>
context.LookupVariable(id) match {
case None => context.Error(expr.pos, "undefined local variable " + id)
case Some(v) =>
expr.v = v
if (!(v.IsImmutable && v.IsGhost))
context.Error(expr.pos, "assigned can only be used with ghost consts")
}
expr.typ = BoolClass
case expr@ Old(e) =>
if (! twoStateContext) { context.Error(expr.pos, "old expression is not allowed here") }
ResolveExpr(e, context, twoStateContext, false)
expr.typ = e.typ
case ite@IfThenElse(con, then, els) =>
ResolveExpr(con, context, twoStateContext, false); ResolveExpr(then, context, twoStateContext, specContext); ResolveExpr(els, context, twoStateContext, specContext);
if (!con.typ.IsBool) context.Error(con.pos, "condition of if-then-else expression must be a boolean");
if (! canAssign(then.typ, els.typ)) context.Error(ite.pos, "the then and else branch of an if-then-else expression must have compatible types");
ite.typ = then.typ;
case expr@ Not(e) =>
ResolveExpr(e, context, twoStateContext, false)
if (!e.typ.IsBool) context.Error(expr.pos, "not-expression requires boolean operand")
expr.typ = BoolClass
case appl@FunctionApplication(obj, id, args) =>
ResolveExpr(obj, context, twoStateContext, false);
args foreach { arg => ResolveExpr(arg, context, twoStateContext, false)};
// lookup function
appl.typ = IntClass
obj.typ.LookupMember(id) match {
case None =>
context.Error(appl.pos, "function " + id + " not found in class " + obj.typ.FullName)
case Some(func@Function(f, ins, out, specs, body)) =>
appl.f = func
appl.typ = func.out.typ;
if (args.length != ins.length)
context.Error(appl.pos, "wrong number of actual arguments in function application of " + obj.typ.FullName + "." + id +
" (" + args.length + " instead of " + ins.length + ")")
else {
for((actual, formal) <- args zip func.ins){
if(! canAssign(formal.t.typ, actual.typ))
context.Error(actual.pos, "the type of the actual argument is not assignable to the formal parameter (expected: " + formal.t.FullName + ", found: " + actual.typ.FullName + ")")
}
}
case _ => context.Error(appl.pos, obj.typ.id + "." + id + " is not a function")
}
case uf@Unfolding(pred, e) =>
ResolveExpr(pred, context, twoStateContext, true);
ResolveExpr(e, context, twoStateContext, false);
if(! pred.ma.isPredicate) context.Error(uf.pos, "Only predicates can be unfolded.")
uf.typ = e.typ;
case bin: EqualityCompareExpr =>
ResolveExpr(bin.E0, context, twoStateContext, false)
ResolveExpr(bin.E1, context, twoStateContext, false)
if (bin.E0.typ == bin.E1.typ) { /* all is well */ }
else if (bin.E0.typ.IsRef && bin.E1.typ.IsNull) { /* all is well */ }
else if (bin.E0.typ.IsNull && bin.E1.typ.IsRef) { /* all is well */ }
else
context.Error(bin.pos, bin.OpName + " requires operands of the same type, found " + bin.E0.typ.FullName + " and " + bin.E1.typ.FullName)
bin.typ = BoolClass
case bin: LockBelow =>
ResolveExpr(bin.E0, context, twoStateContext, false)
ResolveExpr(bin.E1, context, twoStateContext, false)
if (!(bin.E0.typ.IsRef || bin.E0.typ.IsMu))
context.Error(bin.pos, "type of " + bin.OpName + " LHS operand must be a reference or Mu type (found " + bin.E0.typ.FullName + ")")
if (!(bin.E1.typ.IsRef || bin.E1.typ.IsMu))
context.Error(bin.pos, "type of " + bin.OpName + " RHS operand must be a reference or Mu type (found " + bin.E1.typ.FullName + ")")
bin.typ = BoolClass
case app@Append(e0, e1) =>
ResolveExpr(e0, context, twoStateContext, false);
ResolveExpr(e1, context, twoStateContext, false);
if(! e0.typ.IsSeq) context.Error(app.pos, "LHS operand of ++ must be sequence (found: " + e0.typ.FullName + ").");
if(! e1.typ.IsSeq) context.Error(app.pos, "RHS operand of ++ must be sequence (found: " + e1.typ.FullName + ").");
if(e0.typ != e1.typ) context.Error(app.pos, "++ can only be applied to sequences of the same type.");
app.typ = e0.typ;
case at@At(e0, e1) =>
ResolveExpr(e0, context, twoStateContext, false);
ResolveExpr(e1, context, twoStateContext, false);
if(! e0.typ.IsSeq) context.Error(at.pos, "LHS operand of @ must be sequence. (found: " + e0.typ.FullName + ").");
if(! e1.typ.IsInt) context.Error(at.pos, "RHS operand of @ must be an integer (found: " + e1.typ.FullName + ").");
if(e0.typ.IsSeq) at.typ = e0.typ.parameters(0) else at.typ = IntClass;
case drop@Drop(e0, e1) =>
ResolveExpr(e0, context, twoStateContext, false);
ResolveExpr(e1, context, twoStateContext, false);
if(! e0.typ.IsSeq) context.Error(drop.pos, "LHS operand of drop must be sequence. (found: " + e0.typ.FullName + ").");
if(! e1.typ.IsInt) context.Error(drop.pos, "RHS operand of drop must be an integer (found: " + e1.typ.FullName + ").");
drop.typ = e0.typ;
case take@Take(e0, e1) =>
ResolveExpr(e0, context, twoStateContext, false);
ResolveExpr(e1, context, twoStateContext, false);
if(! e0.typ.IsSeq) context.Error(take.pos, "LHS operand of take must be sequence. (found: " + e0.typ.FullName + ").");
if(! e1.typ.IsInt) context.Error(take.pos, "RHS operand of take must be an integer (found: " + e1.typ.FullName + ").");
take.typ = e0.typ;
case contains@Contains(e0, e1) =>
ResolveExpr(e0, context, twoStateContext, false);
ResolveExpr(e1, context, twoStateContext, false);
if(! e1.typ.IsSeq) context.Error(contains.pos, "RHS operand of 'in' must be sequence. (found: " + e1.typ.FullName + ").");
else if(e0.typ ne e1.typ.parameters(0)) context.Error(contains.pos, "LHS operand's type must be element type of sequence. (found: " + e0.typ.FullName + ", expected: " + e1.typ.parameters(0).FullName + ").");
contains.typ = BoolClass;
case bin: BinaryExpr =>
ResolveExpr(bin.E0, context, twoStateContext, specContext && bin.isInstanceOf[And])
ResolveExpr(bin.E1, context, twoStateContext, specContext && (bin.isInstanceOf[And] || bin.isInstanceOf[Implies]))
if (bin.E0.typ != bin.ExpectedLhsType)
context.Error(bin.E0.pos, "incorrect type of " + bin.OpName + " LHS" +
" (expected " + bin.ExpectedLhsType.FullName +
", found " + bin.E0.typ.FullName + ")")
if (bin.E1.typ != bin.ExpectedRhsType)
context.Error(bin.E1.pos, "incorrect type of " + bin.OpName + " RHS" +
" (expected " + bin.ExpectedRhsType.FullName + ", found " + bin.E1.typ.FullName + ")")
bin.typ = bin.ResultType
case q: Quantification =>
q.Is foreach { i => if(context.LookupVariable(i).isDefined) context.Error(q.pos, "The variable " + i + " hides another local.") };
val typ = q match {
case q: SeqQuantification =>
ResolveExpr(q.seq, context, twoStateContext, false);
if(! q.seq.typ.IsSeq) {
context.Error(q.seq.pos, "A quantification must range over a sequence. (found: " + q.seq.typ.FullName + ").");
None;
} else
Some(q.seq.typ.parameters(0));
case q: TypeQuantification =>
ResolveType(q.t, context);
if (q.t.typ == null) None else Some(q.t.typ);
};
if (typ.isDefined) {
val vartype = typ.get;
var bodyContext = context;
var bvariables = Nil: List[Variable];
q.Is foreach { i =>
val variable = new Variable(i, new Type(vartype));
bodyContext = bodyContext.AddVariable(variable);
bvariables = bvariables ::: List(variable);
}
ResolveExpr(q.E, bodyContext, twoStateContext, true);
if(! q.E.typ.IsBool) context.Error(q.E.pos, "Body of quantification must be a boolean. (found: " + q.E.typ.FullName + ").");
q.variables = bvariables;
}
q.typ = BoolClass
case seq@EmptySeq(t) =>
ResolveType(t, context)
seq.typ = getSeqType(t.typ, context);
case seq@ExplicitSeq(es) =>
es foreach { e => ResolveExpr(e, context, twoStateContext, false) }
es match {
case Nil => seq.typ = getSeqType(IntClass, context);
case h :: t =>
t foreach { e => if(! (e.typ == h.typ)) context.Error(e.pos, "The elements of the sequence expression have different types.")};
seq.typ = getSeqType(h.typ, context);
}
case ran@Range(min, max) =>
ResolveExpr(min, context, twoStateContext, false);
if(! min.typ.IsInt) context.Error(min.pos, "The mininum of a range expression must be an integer (found: " + min.typ.FullName + ").");
ResolveExpr(max, context, twoStateContext, false);
if(! max.typ.IsInt) context.Error(max.pos, "The maximum of a range expression must be an integer (found: " + max.typ.FullName + ").");
ran.typ = getSeqType(IntClass, context);
case len@Length(e) =>
ResolveExpr(e, context, twoStateContext, false);
if(! e.typ.IsSeq) context.Error(len.pos, "The operand of a length expression must be sequence. (found: " + e.typ.FullName + ").");
len.typ = IntClass;
case ev@Eval(h, e) =>
if(inPredicate) context.Error(ev.pos, "eval cannot be used in monitor invariants or predicates")
h match {
case AcquireState(obj) =>
ResolveExpr(obj, context, twoStateContext, false)
if(! obj.typ.IsRef) context.Error(ev.pos, "The target of acquire must be a reference.");
case ReleaseState(obj) => ResolveExpr(obj, context, twoStateContext, false)
if(! obj.typ.IsRef) context.Error(ev.pos, "The target of acquire must be a reference.");
case c@CallState(token, obj, id, args) =>
ResolveExpr(token, context, twoStateContext, false);
if( ! token.typ.IsToken) context.Error(token.pos, "joinable is only applicable to tokens");
ResolveExpr(obj, context, false, false)
CheckNoGhost(obj, context)
args foreach { a => ResolveExpr(a, context, false, false); CheckNoGhost(a, context) }
// lookup method
var typ: Class = IntClass
obj.typ.LookupMember(id) match {
case None =>
context.Error(obj.pos, "call of undeclared member " + id + " in class " + obj.typ.FullName)
case Some(m: Method) =>
c.m = m
if (args.length != m.ins.length)
context.Error(obj.pos, "wrong number of actual in-parameters in call to " + obj.typ.FullName + "." + id +
" (" + args.length + " instead of " + m.ins.length + ")")
else {
for((actual, formal) <- args zip m.ins){
if(! canAssign(formal.t.typ, actual.typ))
context.Error(actual.pos, "the type of the actual argument is not assignable to the formal parameter (expected: " + formal.t.FullName + ", found: " + actual.typ.FullName + ")")
}
}
case _ => context.Error(obj.pos, "call expression does not denote a method: " + obj.typ.FullName + "." + id)
}
}
ResolveExpr(e, context, false, specContext)
ev.typ = e.typ;
}
def LookupRunMethod(cl: Class, context: ProgramContext, op: String, pos: Position): Option[Method] = {
cl.LookupMember("run") match {
case None =>
context.Error(pos, "object given in " + op + " statement must be of a type with a parameter-less run method" +
" (found type " + cl.id + ")")
None
case Some(m: Method) =>
m.spec foreach {
case Precondition(e) => CheckRunSpecification(e, context, true)
case Postcondition(e) => CheckRunSpecification(e, context, false)
case lc: LockChange => context.Error(lc.pos, "lockchange is not allowed in specification of run method")
}
if(0<m.ins.length || 0<m.outs.length) {
context.Error(pos, "object given in " + op + " statement must be of a type with a parameter-less run method" +
" (found " + m.ins.length + " in-parameters and " + m.outs.length + " out-parameters)"); None
} else
Some(m)
case _ =>
context.Error(pos, "object given in " + op + " statement must be of a type with a parameter-less run method" +
" (found non-method member)")
None
}
}
// assumes that lhs and rhs are resolved
def canAssign(lhs: Class, rhs: Class): Boolean = {
(lhs, rhs) match {
case (TokenClass(c1, m1), TokenClass(c2, m2)) => c1.id.equals(c2.id) && m1.equals(m2)
case (TokenClass(c1, m1), _) => false
case (_, TokenClass(c2, m2)) => false
case (lhs, rhs) => lhs == rhs || (lhs.IsRef && rhs.IsNull)
}
}
def CheckNoGhost(expr: RValue, context: ProgramContext): Unit = {
def specOk(e: RValue): Unit = {
e match {
case ve: VariableExpr =>
if (ve.v != null && ve.v.IsGhost) context.Error(ve.pos, "ghost variable not allowed here")
case fs@ MemberAccess(e, id) =>
if (!fs.isPredicate && fs.f != null && fs.f.isGhost) context.Error(fs.pos, "ghost fields not allowed here")
case a: Assigned =>
if (a.v != null && a.v.IsGhost) context.Error(a.pos, "ghost variable not allowed here")
case _ => // do nothing
}
}
AST.visit(expr, specOk);
}
def CheckNoImmutableGhosts(expr: RValue, context: ProgramContext): Unit = {
def specOk(e: RValue): Unit = {
e match {
case ve: VariableExpr =>
if (ve.v != null && ve.v.IsGhost && ve.v.IsImmutable) context.Error(ve.pos, "ghost const not allowed here")
case a: Assigned =>
if (a.v != null && a.v.IsGhost && a.v.IsImmutable) context.Error(a.pos, "ghost const not allowed here")
case _ => // do nothing
}
}
AST.visit(expr, specOk);
}
def CheckRunSpecification(e: Expression, context: ProgramContext, allowMaxLock: Boolean): Unit = e match {
case _:MaxLockLiteral =>
if (!allowMaxLock) context.Error(e.pos, "specification of run method is not allowed to mention waitlevel here")
case _:Literal =>
case _:VariableExpr =>
case _:ThisExpr =>
case _:Result =>
case MemberAccess(e, id) =>
CheckRunSpecification(e, context, false)
case Frac(perm) => CheckRunSpecification(perm, context, false)
case Epsilons(perm) => CheckRunSpecification(perm, context, false)
case Full | Epsilon | Star =>
case Access(e, perm) =>
CheckRunSpecification(e, context, false);
CheckRunSpecification(perm, context, false);
case AccessAll(obj, perm) =>
CheckRunSpecification(obj, context, false);
CheckRunSpecification(perm, context, false);
case AccessSeq(s, f, perm) =>
CheckRunSpecification(s, context, false);
CheckRunSpecification(perm, context, false);
case expr@ Credit(e, n) =>
CheckRunSpecification(e, context, false)
CheckRunSpecification(expr.N, context, false)
case Holds(e) =>
context.Error(e.pos, "holds is not allowed in specification of run method")
case RdHolds(e) =>
context.Error(e.pos, "rd holds is not allowed in specification of run method")
case _:Assigned =>
case Old(e) =>
CheckRunSpecification(e, context, false) // OLD occurs only in postconditions and monitor invariants, where waitlevel is not allowed anyhow
case IfThenElse(con, then, els) =>
CheckRunSpecification(con, context, false);
CheckRunSpecification(con, context, allowMaxLock);
CheckRunSpecification(con, context, allowMaxLock);
case Not(e) =>
CheckRunSpecification(e, context, false)
case FunctionApplication(obj, id, args) =>
obj :: args foreach { arg => CheckRunSpecification(arg, context, false)}
case Unfolding(pred, e) =>
CheckRunSpecification(pred, context, true);
CheckRunSpecification(e, context, allowMaxLock);
case LockBelow(e0,e1) =>
CheckRunSpecification(e0, context, allowMaxLock)
CheckRunSpecification(e1, context, false)
case And(e0,e1) =>
CheckRunSpecification(e0, context, allowMaxLock)
CheckRunSpecification(e1, context, allowMaxLock)
case Implies(e0,e1) =>
CheckRunSpecification(e0, context, false)
CheckRunSpecification(e1, context, allowMaxLock)
case bin: BinaryExpr =>
CheckRunSpecification(bin.E0, context, false)
CheckRunSpecification(bin.E1, context, false)
case q: SeqQuantification =>
CheckRunSpecification(q.seq, context, false)
CheckRunSpecification(q.E, context, true)
case q: TypeQuantification =>
CheckRunSpecification(q.E, context, true)
case Length(e) =>
CheckRunSpecification(e, context, false);
case ExplicitSeq(es) =>
es foreach { e => CheckRunSpecification(e, context, false) }
case Range(min, max) =>
CheckRunSpecification(min, context, false)
CheckRunSpecification(max, context, false)
case Eval(h, e) =>
h match {
case AcquireState(obj) => CheckRunSpecification(obj, context, false);
case ReleaseState(obj) => CheckRunSpecification(obj, context, false);
case CallState(token, obj, id, args) => CheckRunSpecification(token, context, false); CheckRunSpecification(obj, context, false); args foreach { a: Expression => CheckRunSpecification(a, context, false)};
}
CheckRunSpecification(e, context, allowMaxLock)
}
}
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