public static void Transform(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker)
{
List<Declaration> originalDecls = new List<Declaration>();
Program program = linearTypeChecker.program;
foreach (var decl in program.TopLevelDeclarations)
{
Procedure proc = decl as Procedure;
if (proc != null && civlTypeChecker.procToActionInfo.ContainsKey(proc))
{
originalDecls.Add(proc);
continue;
}
Implementation impl = decl as Implementation;
if (impl != null && civlTypeChecker.procToActionInfo.ContainsKey(impl.Proc))
{
originalDecls.Add(impl);
}
}
List<Declaration> decls = new List<Declaration>();
if (!CommandLineOptions.Clo.TrustAtomicityTypes)
{
MoverCheck.AddCheckers(linearTypeChecker, civlTypeChecker, decls);
}
CivlRefinement.AddCheckers(linearTypeChecker, civlTypeChecker, decls);
foreach (Declaration decl in decls)
{
decl.Attributes = CivlRefinement.RemoveYieldsAttribute(decl.Attributes);
}
program.RemoveTopLevelDeclarations(x => originalDecls.Contains(x));
program.AddTopLevelDeclarations(decls);
}
public static void AddCheckers(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker, List<Declaration> decls)
{
Program program = linearTypeChecker.program;
foreach (int layerNum in civlTypeChecker.AllImplementedLayerNums)
{
if (CommandLineOptions.Clo.TrustLayersDownto <= layerNum || layerNum <= CommandLineOptions.Clo.TrustLayersUpto) continue;
MyDuplicator duplicator = new MyDuplicator(civlTypeChecker, layerNum);
foreach (var proc in program.Procedures)
{
if (!civlTypeChecker.procToActionInfo.ContainsKey(proc)) continue;
Procedure duplicateProc = duplicator.VisitProcedure(proc);
decls.Add(duplicateProc);
}
decls.AddRange(duplicator.impls);
CivlRefinement civlTransform = new CivlRefinement(linearTypeChecker, civlTypeChecker, duplicator);
foreach (var impl in program.Implementations)
{
if (!civlTypeChecker.procToActionInfo.ContainsKey(impl.Proc) || civlTypeChecker.procToActionInfo[impl.Proc].createdAtLayerNum < layerNum)
continue;
Implementation duplicateImpl = duplicator.VisitImplementation(impl);
civlTransform.TransformImpl(duplicateImpl);
decls.Add(duplicateImpl);
}
decls.AddRange(civlTransform.Collect());
}
}
private MoverCheck(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker, List<Declaration> decls)
{
this.linearTypeChecker = linearTypeChecker;
this.civlTypeChecker = civlTypeChecker;
this.decls = decls;
this.commutativityCheckerCache = new HashSet<Tuple<AtomicActionInfo, AtomicActionInfo>>();
this.gatePreservationCheckerCache = new HashSet<Tuple<AtomicActionInfo, AtomicActionInfo>>();
this.failurePreservationCheckerCache = new HashSet<Tuple<AtomicActionInfo, AtomicActionInfo>>();
}
public MyDuplicator(CivlTypeChecker civlTypeChecker, int layerNum)
{
this.civlTypeChecker = civlTypeChecker;
this.layerNum = layerNum;
this.enclosingProc = null;
this.enclosingImpl = null;
this.procMap = new Dictionary<Procedure, Procedure>();
this.absyMap = new Dictionary<Absy, Absy>();
this.implMap = new Dictionary<Implementation, Implementation>();
this.yieldingProcs = new HashSet<Procedure>();
this.impls = new List<Implementation>();
}
private YieldTypeChecker(CivlTypeChecker civlTypeChecker, Implementation impl, int currLayerNum, IEnumerable<Block> loopHeaders)
{
this.civlTypeChecker = civlTypeChecker;
this.impl = impl;
this.currLayerNum = currLayerNum;
this.loopHeaders = loopHeaders;
this.stateCounter = 0;
this.absyToNode = new Dictionary<Absy, int>();
this.initialState = 0;
this.finalStates = new HashSet<int>();
this.edgeLabels = new Dictionary<Tuple<int, int>, int>();
foreach (Block block in impl.Blocks)
{
absyToNode[block] = stateCounter;
stateCounter++;
foreach (Cmd cmd in block.Cmds)
{
absyToNode[cmd] = stateCounter;
stateCounter++;
}
absyToNode[block.TransferCmd] = stateCounter;
stateCounter++;
if (block.TransferCmd is ReturnCmd)
{
finalStates.Add(absyToNode[block.TransferCmd]);
}
}
foreach (Block block in impl.Blocks)
{
Absy blockEntry = block.Cmds.Count == 0 ? (Absy)block.TransferCmd : (Absy)block.Cmds[0];
edgeLabels[new Tuple<int, int>(absyToNode[block], absyToNode[blockEntry])] = 'P';
GotoCmd gotoCmd = block.TransferCmd as GotoCmd;
if (gotoCmd == null) continue;
foreach (Block successor in gotoCmd.labelTargets)
{
edgeLabels[new Tuple<int, int>(absyToNode[gotoCmd], absyToNode[successor])] = 'P';
}
}
this.nodeToAbsy = new Dictionary<int, Absy>();
foreach (KeyValuePair<Absy, int> state in absyToNode)
{
this.nodeToAbsy[state.Value] = state.Key;
}
ComputeGraph();
IsYieldTypeSafe();
}
public CivlRefinement(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker, MyDuplicator duplicator)
{
this.linearTypeChecker = linearTypeChecker;
this.civlTypeChecker = civlTypeChecker;
this.absyMap = duplicator.absyMap;
this.layerNum = duplicator.layerNum;
this.implMap = duplicator.implMap;
this.yieldingProcs = duplicator.yieldingProcs;
Program program = linearTypeChecker.program;
globalMods = new List<IdentifierExpr>();
foreach (Variable g in civlTypeChecker.SharedVariables)
{
globalMods.Add(Expr.Ident(g));
}
asyncAndParallelCallDesugarings = new Dictionary<string, Procedure>();
yieldCheckerProcs = new List<Procedure>();
yieldCheckerImpls = new List<Implementation>();
yieldProc = null;
}
public static void TypeCheck(CivlTypeChecker civlTypeChecker)
{
// Mover procedures can only call other mover procedures on the same layer.
// Thus, the constructed call graph naturally forms disconnected components
// w.r.t. layers and we can keep a single graph instead of one for each layer.
var moverProcedureCallGraph = ConstructMoverProcedureCallGraph(civlTypeChecker);
foreach (var impl in civlTypeChecker.program.Implementations.Where(impl =>
civlTypeChecker.procToYieldingProc.ContainsKey(impl.Proc)))
{
var yieldingProc = civlTypeChecker.procToYieldingProc[impl.Proc];
impl.PruneUnreachableBlocks();
Graph <Block> implGraph = Program.GraphFromImpl(impl);
implGraph.ComputeLoops();
foreach (int layerNum in civlTypeChecker.allRefinementLayers.Where(l => l <= yieldingProc.upperLayer))
{
new PerLayerYieldSufficiencyTypeChecker(civlTypeChecker, yieldingProc, impl, layerNum, implGraph, moverProcedureCallGraph)
.TypeCheckLayer();
}
}
}
public static void Transform(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker)
{
Program program = linearTypeChecker.program;
// Store the original declarations of yielding procedures, which will be removed after desugaring below.
var origProc = program.TopLevelDeclarations.OfType <Procedure>().Where(p => civlTypeChecker.procToYieldingProc.ContainsKey(p));
var origImpl = program.TopLevelDeclarations.OfType <Implementation>().Where(i => civlTypeChecker.procToYieldingProc.ContainsKey(i.Proc));
List <Declaration> originalDecls = Enumerable.Union <Declaration>(origProc, origImpl).ToList();
// Commutativity checks
List <Declaration> decls = new List <Declaration>();
if (!CommandLineOptions.Clo.TrustAtomicityTypes)
{
MoverCheck.AddCheckers(linearTypeChecker, civlTypeChecker, decls);
}
// Desugaring of yielding procedures
YieldingProcChecker.AddCheckers(linearTypeChecker, civlTypeChecker, decls);
// Linear type checks
LinearTypeChecker.AddCheckers(linearTypeChecker, civlTypeChecker, decls);
InductiveSequentializationChecker.AddChecks(civlTypeChecker);
PendingAsyncChecker.AddCheckers(civlTypeChecker);
foreach (AtomicAction action in civlTypeChecker.procToAtomicAction.Values.Union(civlTypeChecker.procToIsAbstraction.Values))
{
action.AddTriggerAssumes(program);
}
// Remove original declarations and add new checkers generated above
program.RemoveTopLevelDeclarations(x => originalDecls.Contains(x));
program.AddTopLevelDeclarations(decls);
BackwardAssignmentSubstituter.SubstituteBackwardAssignments(civlTypeChecker.procToAtomicAction.Values);
}
public static void Transform(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker)
{
Program program = linearTypeChecker.program;
// Store the original declarations of yielding procedures, which will be removed after desugaring below.
var origProc = program.TopLevelDeclarations.OfType <Procedure>().Where(p => civlTypeChecker.procToYieldingProc.ContainsKey(p));
var origImpl = program.TopLevelDeclarations.OfType <Implementation>().Where(i => civlTypeChecker.procToYieldingProc.ContainsKey(i.Proc));
List <Declaration> originalDecls = Enumerable.Union <Declaration>(origProc, origImpl).ToList();
// Commutativity checks
List <Declaration> decls = new List <Declaration>();
if (!CommandLineOptions.Clo.TrustAtomicityTypes)
{
MoverCheck.AddCheckers(linearTypeChecker, civlTypeChecker, decls);
}
// Desugaring of yielding procedures
CivlRefinement.AddCheckers(linearTypeChecker, civlTypeChecker, decls);
// Trigger functions for existential vairables in transition relations
decls.AddRange(civlTypeChecker.procToAtomicAction.Values.SelectMany(a => a.layerToActionCopy.Values.SelectMany(ac => ac.triggerFuns.Values)));
// Linear type checks
LinearTypeChecker.AddCheckers(linearTypeChecker, civlTypeChecker, decls);
// Remove original declarations and add new checkers generated above
program.RemoveTopLevelDeclarations(x => originalDecls.Contains(x));
program.AddTopLevelDeclarations(decls);
foreach (AtomicAction atomicAction in civlTypeChecker.procToAtomicAction.Values)
{
program.RemoveTopLevelDeclaration(atomicAction.proc);
program.RemoveTopLevelDeclaration(atomicAction.impl);
}
}
public static void AddCheckers(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker,
List <Declaration> decls)
{
Program program = linearTypeChecker.program;
// Generate the refinement checks for every layer
foreach (int layerNum in civlTypeChecker.allRefinementLayers)
{
if (CommandLineOptions.Clo.TrustLayersDownto <= layerNum ||
layerNum <= CommandLineOptions.Clo.TrustLayersUpto)
{
continue;
}
YieldingProcDuplicator duplicator = new YieldingProcDuplicator(civlTypeChecker, linearTypeChecker, layerNum);
foreach (var procToYieldingProc in civlTypeChecker.procToYieldingProc)
{
if (procToYieldingProc.Value.upperLayer >= layerNum)
{
duplicator.VisitProcedure(procToYieldingProc.Key);
}
}
foreach (Implementation impl in program.Implementations)
{
if (civlTypeChecker.procToYieldingProc.TryGetValue(impl.Proc, out var yieldingProc) &&
yieldingProc.upperLayer >= layerNum)
{
duplicator.VisitImplementation(impl);
}
}
decls.AddRange(duplicator.Collect());
}
}
public ActionRefinementInstrumentation(
CivlTypeChecker civlTypeChecker,
Implementation impl,
Implementation originalImpl,
Dictionary <Variable, Variable> oldGlobalMap)
{
this.civlTypeChecker = civlTypeChecker;
this.tok = impl.tok;
this.oldGlobalMap = new Dictionary <Variable, Variable>();
ActionProc actionProc = civlTypeChecker.procToYieldingProc[originalImpl.Proc] as ActionProc;
this.layerNum = actionProc.upperLayer;
foreach (Variable v in civlTypeChecker.GlobalVariables)
{
var layerRange = civlTypeChecker.GlobalVariableLayerRange(v);
if (layerRange.lowerLayerNum <= layerNum && layerNum < layerRange.upperLayerNum)
{
this.oldGlobalMap[v] = oldGlobalMap[v];
}
}
this.newLocalVars = new List <Variable>();
pc = civlTypeChecker.LocalVariable("pc", Type.Bool);
newLocalVars.Add(pc);
ok = civlTypeChecker.LocalVariable("ok", Type.Bool);
newLocalVars.Add(ok);
this.transitionRelationCache = new Dictionary <AtomicAction, Expr>();
oldOutputMap = new Dictionary <Variable, Variable>();
foreach (Variable f in impl.OutParams)
{
LocalVariable copy = Old(f);
newLocalVars.Add(copy);
oldOutputMap[f] = copy;
}
Dictionary <Variable, Expr> foroldMap = new Dictionary <Variable, Expr>();
foreach (Variable g in civlTypeChecker.GlobalVariables)
{
foroldMap[g] = Expr.Ident(oldGlobalMap[g]);
}
// The parameters of an atomic action come from the implementation that denotes the atomic action specification.
// To use the transition relation computed below in the context of the yielding procedure of the refinement check,
// we need to substitute the parameters.
AtomicAction atomicAction = actionProc.refinedAction;
Implementation atomicActionImpl = atomicAction.impl;
Dictionary <Variable, Expr> alwaysMap = new Dictionary <Variable, Expr>();
for (int i = 0, j = 0; i < impl.InParams.Count; i++)
{
if (civlTypeChecker.FormalRemainsInAction(actionProc, actionProc.proc.InParams[i]))
{
alwaysMap[atomicActionImpl.InParams[j]] = Expr.Ident(impl.InParams[i]);
j++;
}
}
for (int i = 0, j = 0; i < impl.OutParams.Count; i++)
{
if (civlTypeChecker.FormalRemainsInAction(actionProc, actionProc.proc.OutParams[i]))
{
alwaysMap[atomicActionImpl.OutParams[j]] = Expr.Ident(impl.OutParams[i]);
j++;
}
}
if (atomicAction.HasPendingAsyncs)
{
Variable collectedPAs = civlTypeChecker.implToPendingAsyncCollector[originalImpl];
alwaysMap[atomicActionImpl.OutParams.Last()] = Expr.Ident(collectedPAs);
LocalVariable copy = Old(collectedPAs);
newLocalVars.Add(copy);
oldOutputMap[collectedPAs] = copy;
}
Substitution always = Substituter.SubstitutionFromHashtable(alwaysMap);
Substitution forold = Substituter.SubstitutionFromHashtable(foroldMap);
Expr transitionRelationExpr = GetTransitionRelation(atomicAction);
transitionRelation = Substituter.ApplyReplacingOldExprs(always, forold, transitionRelationExpr);
Expr gateExpr = Expr.And(atomicAction.gate.Select(g => g.Expr));
gateExpr.Type = Type.Bool;
gate = Substituter.Apply(always, gateExpr);
}
public static void PerformYieldSafeCheck(CivlTypeChecker civlTypeChecker)
{
foreach (var impl in civlTypeChecker.program.Implementations)
{
if (!civlTypeChecker.procToActionInfo.ContainsKey(impl.Proc)) continue;
impl.PruneUnreachableBlocks();
Graph<Block> implGraph = Program.GraphFromImpl(impl);
implGraph.ComputeLoops();
int specLayerNum = civlTypeChecker.procToActionInfo[impl.Proc].createdAtLayerNum;
foreach (int layerNum in civlTypeChecker.AllImplementedLayerNums)
{
if (layerNum > specLayerNum) continue;
YieldTypeChecker executor = new YieldTypeChecker(civlTypeChecker, impl, layerNum, implGraph.Headers);
}
}
}
public YieldTypeChecker(CivlTypeChecker civlTypeChecker)
{
this.civlTypeChecker = civlTypeChecker;
this.checkingContext = new CheckingContext(null);
this.moverProcedureCallGraph = new Graph <MoverProc>();
}
public WitnessFunctionVisitor(CivlTypeChecker ctc)
{
this.ctc = ctc;
allWitnessFunctions = new List <WitnessFunction>();
}
private static void AddCheck(CivlTypeChecker civlTypeChecker, Tuple <Procedure, Implementation> t)
{
civlTypeChecker.program.AddTopLevelDeclaration(t.Item1);
civlTypeChecker.program.AddTopLevelDeclaration(t.Item2);
}
public CommutativityHintVisitor(CivlTypeChecker ctc)
{
this.ctc = ctc;
commutativityHints = new CommutativityHints();
}
public static List <Declaration> CreateNoninterferenceCheckers(
CivlTypeChecker civlTypeChecker,
LinearTypeChecker linearTypeChecker,
int layerNum,
Dictionary <Absy, Absy> absyMap,
Implementation impl,
Dictionary <YieldCmd, List <PredicateCmd> > yields)
{
Dictionary <string, Variable> domainNameToHoleVar = new Dictionary <string, Variable>();
Dictionary <Variable, Variable> localVarMap = new Dictionary <Variable, Variable>();
Dictionary <Variable, Expr> map = new Dictionary <Variable, Expr>();
List <Variable> locals = new List <Variable>();
List <Variable> inputs = new List <Variable>();
foreach (var domainName in linearTypeChecker.linearDomains.Keys)
{
var inParam = linearTypeChecker.LinearDomainInFormal(domainName);
inputs.Add(inParam);
domainNameToHoleVar[domainName] = inParam;
}
foreach (Variable local in impl.LocVars.Union(impl.InParams).Union(impl.OutParams))
{
var copy = CopyLocal(local);
locals.Add(copy);
localVarMap[local] = copy;
map[local] = Expr.Ident(copy);
}
Dictionary <Variable, Expr> oldLocalMap = new Dictionary <Variable, Expr>();
Dictionary <Variable, Expr> assumeMap = new Dictionary <Variable, Expr>(map);
foreach (Variable g in civlTypeChecker.GlobalVariables)
{
var copy = OldLocalLocal(g);
locals.Add(copy);
oldLocalMap[g] = Expr.Ident(copy);
Formal f = OldGlobalFormal(g);
inputs.Add(f);
assumeMap[g] = Expr.Ident(f);
}
var linearPermissionInstrumentation = new LinearPermissionInstrumentation(civlTypeChecker, linearTypeChecker, layerNum, absyMap, domainNameToHoleVar, localVarMap);
Substitution assumeSubst = Substituter.SubstitutionFromHashtable(assumeMap);
Substitution oldSubst = Substituter.SubstitutionFromHashtable(oldLocalMap);
Substitution subst = Substituter.SubstitutionFromHashtable(map);
List <Block> noninterferenceCheckerBlocks = new List <Block>();
List <String> labels = new List <String>();
List <Block> labelTargets = new List <Block>();
Block noninterferenceCheckerBlock = new Block(Token.NoToken, "exit", new List <Cmd>(), new ReturnCmd(Token.NoToken));
labels.Add(noninterferenceCheckerBlock.Label);
labelTargets.Add(noninterferenceCheckerBlock);
noninterferenceCheckerBlocks.Add(noninterferenceCheckerBlock);
int yieldCount = 0;
foreach (var kv in yields)
{
var yieldCmd = kv.Key;
var yieldPredicates = kv.Value;
List <Cmd> newCmds = linearPermissionInstrumentation.DisjointnessAssumeCmds(yieldCmd, false);
foreach (var predCmd in yieldPredicates)
{
var newExpr = Substituter.ApplyReplacingOldExprs(assumeSubst, oldSubst, predCmd.Expr);
newCmds.Add(new AssumeCmd(Token.NoToken, newExpr));
}
foreach (var predCmd in yieldPredicates)
{
if (predCmd is AssertCmd)
{
var newExpr = Substituter.ApplyReplacingOldExprs(subst, oldSubst, predCmd.Expr);
AssertCmd assertCmd = new AssertCmd(predCmd.tok, newExpr, predCmd.Attributes);
assertCmd.ErrorData = "Non-interference check failed";
newCmds.Add(assertCmd);
}
}
newCmds.Add(new AssumeCmd(Token.NoToken, Expr.False));
noninterferenceCheckerBlock = new Block(Token.NoToken, "L" + yieldCount++, newCmds, new ReturnCmd(Token.NoToken));
labels.Add(noninterferenceCheckerBlock.Label);
labelTargets.Add(noninterferenceCheckerBlock);
noninterferenceCheckerBlocks.Add(noninterferenceCheckerBlock);
}
noninterferenceCheckerBlocks.Insert(0,
new Block(Token.NoToken, "enter", new List <Cmd>(), new GotoCmd(Token.NoToken, labels, labelTargets)));
// Create the yield checker procedure
var noninterferenceCheckerName = $"NoninterferenceChecker_{impl.Name}";
var noninterferenceCheckerProc = new Procedure(Token.NoToken, noninterferenceCheckerName, impl.TypeParameters, inputs,
new List <Variable>(), new List <Requires>(), new List <IdentifierExpr>(), new List <Ensures>());
CivlUtil.AddInlineAttribute(noninterferenceCheckerProc);
// Create the yield checker implementation
var noninterferenceCheckerImpl = new Implementation(Token.NoToken, noninterferenceCheckerName, impl.TypeParameters, inputs,
new List <Variable>(), locals, noninterferenceCheckerBlocks);
noninterferenceCheckerImpl.Proc = noninterferenceCheckerProc;
CivlUtil.AddInlineAttribute(noninterferenceCheckerImpl);
return(new List <Declaration> {
noninterferenceCheckerProc, noninterferenceCheckerImpl
});
}
public YieldSufficiencyTypeChecker(CivlTypeChecker civlTypeChecker)
{
this.civlTypeChecker = civlTypeChecker;
this.checkingContext = civlTypeChecker.checkingContext;
this.moverProcedureCallGraph = new Graph <MoverProc>();
}
public static List <Declaration> CreateNoninterferenceCheckers(
CivlTypeChecker civlTypeChecker,
LinearTypeChecker linearTypeChecker,
int layerNum,
Dictionary <Absy, Absy> absyMap,
DeclWithFormals decl,
List <Variable> declLocalVariables)
{
Dictionary <string, Variable> domainNameToHoleVar = new Dictionary <string, Variable>();
Dictionary <Variable, Variable> localVarMap = new Dictionary <Variable, Variable>();
Dictionary <Variable, Expr> map = new Dictionary <Variable, Expr>();
List <Variable> locals = new List <Variable>();
List <Variable> inputs = new List <Variable>();
foreach (var domainName in linearTypeChecker.linearDomains.Keys)
{
var inParam = linearTypeChecker.LinearDomainInFormal(domainName);
inputs.Add(inParam);
domainNameToHoleVar[domainName] = inParam;
}
foreach (Variable local in declLocalVariables.Union(decl.InParams).Union(decl.OutParams))
{
var copy = CopyLocal(local);
locals.Add(copy);
localVarMap[local] = copy;
map[local] = Expr.Ident(copy);
}
Dictionary <Variable, Expr> oldLocalMap = new Dictionary <Variable, Expr>();
Dictionary <Variable, Expr> assumeMap = new Dictionary <Variable, Expr>(map);
foreach (Variable g in civlTypeChecker.GlobalVariables)
{
var copy = OldLocalLocal(g);
locals.Add(copy);
oldLocalMap[g] = Expr.Ident(copy);
Formal f = OldGlobalFormal(g);
inputs.Add(f);
assumeMap[g] = Expr.Ident(f);
}
var linearPermissionInstrumentation = new LinearPermissionInstrumentation(civlTypeChecker, linearTypeChecker, layerNum, absyMap, domainNameToHoleVar, localVarMap);
List <Tuple <List <Cmd>, List <PredicateCmd> > > yieldInfo = null;
if (decl is Implementation impl)
{
yieldInfo = CollectYields(civlTypeChecker, absyMap, layerNum, impl).Select(kv => new Tuple <List <Cmd>, List <PredicateCmd> >(linearPermissionInstrumentation.DisjointnessAssumeCmds(kv.Key, false), kv.Value)).ToList();
}
else if (decl is Procedure proc)
{
yieldInfo = new List <Tuple <List <Cmd>, List <PredicateCmd> > >();
if (civlTypeChecker.procToYieldInvariant.ContainsKey(proc))
{
if (proc.Requires.Count > 0)
{
var disjointnessCmds = linearPermissionInstrumentation.ProcDisjointnessAssumeCmds(proc, true);
var yieldPredicates = proc.Requires.Select(requires =>
requires.Free
? (PredicateCmd) new AssumeCmd(requires.tok, requires.Condition)
: (PredicateCmd) new AssertCmd(requires.tok, requires.Condition)).ToList();
yieldInfo.Add(new Tuple <List <Cmd>, List <PredicateCmd> >(disjointnessCmds, yieldPredicates));
}
}
else
{
if (proc.Requires.Count > 0)
{
var entryDisjointnessCmds =
linearPermissionInstrumentation.ProcDisjointnessAssumeCmds(proc, true);
var entryYieldPredicates = proc.Requires.Select(requires =>
requires.Free
? (PredicateCmd) new AssumeCmd(requires.tok, requires.Condition)
: (PredicateCmd) new AssertCmd(requires.tok, requires.Condition)).ToList();
yieldInfo.Add(
new Tuple <List <Cmd>, List <PredicateCmd> >(entryDisjointnessCmds, entryYieldPredicates));
}
if (proc.Ensures.Count > 0)
{
var exitDisjointnessCmds =
linearPermissionInstrumentation.ProcDisjointnessAssumeCmds(proc, false);
var exitYieldPredicates = proc.Ensures.Select(ensures =>
ensures.Free
? (PredicateCmd) new AssumeCmd(ensures.tok, ensures.Condition)
: (PredicateCmd) new AssertCmd(ensures.tok, ensures.Condition)).ToList();
yieldInfo.Add(
new Tuple <List <Cmd>, List <PredicateCmd> >(exitDisjointnessCmds, exitYieldPredicates));
}
}
}
else
{
Debug.Assert(false);
}
Substitution assumeSubst = Substituter.SubstitutionFromHashtable(assumeMap);
Substitution oldSubst = Substituter.SubstitutionFromHashtable(oldLocalMap);
Substitution subst = Substituter.SubstitutionFromHashtable(map);
List <Block> noninterferenceCheckerBlocks = new List <Block>();
List <String> labels = new List <String>();
List <Block> labelTargets = new List <Block>();
Block noninterferenceCheckerBlock = new Block(Token.NoToken, "exit", new List <Cmd>(), new ReturnCmd(Token.NoToken));
labels.Add(noninterferenceCheckerBlock.Label);
labelTargets.Add(noninterferenceCheckerBlock);
noninterferenceCheckerBlocks.Add(noninterferenceCheckerBlock);
int yieldCount = 0;
foreach (var kv in yieldInfo)
{
var disjointnessCmds = kv.Item1;
var yieldPredicates = kv.Item2;
var newCmds = new List <Cmd>(disjointnessCmds);
foreach (var predCmd in yieldPredicates)
{
var newExpr = Substituter.ApplyReplacingOldExprs(assumeSubst, oldSubst, predCmd.Expr);
newCmds.Add(new AssumeCmd(Token.NoToken, newExpr));
}
foreach (var predCmd in yieldPredicates)
{
if (predCmd is AssertCmd)
{
var newExpr = Substituter.ApplyReplacingOldExprs(subst, oldSubst, predCmd.Expr);
AssertCmd assertCmd = new AssertCmd(predCmd.tok, newExpr, predCmd.Attributes);
assertCmd.ErrorData = "Non-interference check failed";
newCmds.Add(assertCmd);
}
}
newCmds.Add(new AssumeCmd(Token.NoToken, Expr.False));
noninterferenceCheckerBlock = new Block(Token.NoToken, "L" + yieldCount++, newCmds, new ReturnCmd(Token.NoToken));
labels.Add(noninterferenceCheckerBlock.Label);
labelTargets.Add(noninterferenceCheckerBlock);
noninterferenceCheckerBlocks.Add(noninterferenceCheckerBlock);
}
noninterferenceCheckerBlocks.Insert(0,
new Block(Token.NoToken, "enter", new List <Cmd>(), new GotoCmd(Token.NoToken, labels, labelTargets)));
// Create the yield checker procedure
var noninterferenceCheckerName = decl is Procedure ? $"NoninterferenceChecker_proc_{decl.Name}" : $"NoninterferenceChecker_impl_{decl.Name}";
var noninterferenceCheckerProc = new Procedure(Token.NoToken, noninterferenceCheckerName, decl.TypeParameters, inputs,
new List <Variable>(), new List <Requires>(), new List <IdentifierExpr>(), new List <Ensures>());
CivlUtil.AddInlineAttribute(noninterferenceCheckerProc);
// Create the yield checker implementation
var noninterferenceCheckerImpl = new Implementation(Token.NoToken, noninterferenceCheckerName, decl.TypeParameters, inputs,
new List <Variable>(), locals, noninterferenceCheckerBlocks);
noninterferenceCheckerImpl.Proc = noninterferenceCheckerProc;
CivlUtil.AddInlineAttribute(noninterferenceCheckerImpl);
return(new List <Declaration> {
noninterferenceCheckerProc, noninterferenceCheckerImpl
});
}
public SomeRefinementInstrumentation(
CivlTypeChecker civlTypeChecker,
Implementation impl,
Implementation originalImpl,
Dictionary <Variable, Variable> oldGlobalMap,
HashSet <Block> yieldingLoopHeaders)
{
newLocalVars = new List <Variable>();
YieldingProc yieldingProc = civlTypeChecker.procToYieldingProc[originalImpl.Proc];
int layerNum = yieldingProc.upperLayer;
pc = Pc();
newLocalVars.Add(pc);
ok = Ok();
newLocalVars.Add(ok);
this.transitionRelationCache = new Dictionary <AtomicAction, Expr>();
this.oldGlobalMap = new Dictionary <Variable, Variable>();
foreach (Variable v in civlTypeChecker.sharedVariables)
{
var layerRange = civlTypeChecker.GlobalVariableLayerRange(v);
if (layerRange.lowerLayerNum <= yieldingProc.upperLayer && yieldingProc.upperLayer < layerRange.upperLayerNum)
{
this.oldGlobalMap[v] = oldGlobalMap[v];
}
}
oldOutputMap = new Dictionary <Variable, Variable>();
foreach (Variable f in impl.OutParams)
{
LocalVariable copy = Old(f);
newLocalVars.Add(copy);
oldOutputMap[f] = copy;
}
Dictionary <Variable, Expr> foroldMap = new Dictionary <Variable, Expr>();
foreach (Variable g in civlTypeChecker.sharedVariables)
{
foroldMap[g] = Expr.Ident(oldGlobalMap[g]);
}
if (yieldingProc is ActionProc actionProc)
{
// The parameters of an atomic action come from the implementation that denotes the atomic action specification.
// To use the transition relation computed below in the context of the yielding procedure of the refinement check,
// we need to substitute the parameters.
AtomicAction atomicAction = actionProc.refinedAction;
Implementation atomicActionImpl = atomicAction.impl;
Dictionary <Variable, Expr> alwaysMap = new Dictionary <Variable, Expr>();
for (int i = 0; i < impl.InParams.Count; i++)
{
alwaysMap[atomicActionImpl.InParams[i]] = Expr.Ident(impl.InParams[i]);
}
for (int i = 0; i < impl.OutParams.Count; i++)
{
alwaysMap[atomicActionImpl.OutParams[i]] = Expr.Ident(impl.OutParams[i]);
}
if (atomicAction.HasPendingAsyncs)
{
Variable collectedPAs = civlTypeChecker.implToPendingAsyncCollector[originalImpl];
alwaysMap[atomicActionImpl.OutParams.Last()] = Expr.Ident(collectedPAs);
LocalVariable copy = Old(collectedPAs);
newLocalVars.Add(copy);
oldOutputMap[collectedPAs] = copy;
}
Substitution always = Substituter.SubstitutionFromHashtable(alwaysMap);
Substitution forold = Substituter.SubstitutionFromHashtable(foroldMap);
Expr betaExpr = GetTransitionRelation(atomicAction);
beta = Substituter.ApplyReplacingOldExprs(always, forold, betaExpr);
Expr alphaExpr = Expr.And(atomicAction.gate.Select(g => g.Expr));
alphaExpr.Type = Type.Bool;
alpha = Substituter.Apply(always, alphaExpr);
}
else
{
beta = Expr.And(this.oldGlobalMap.Keys.Select(v => Expr.Eq(Expr.Ident(v), foroldMap[v])));
alpha = Expr.True;
}
pcsForYieldingLoopsHeaders = new Dictionary <Block, Variable>();
oksForYieldingLoopHeaders = new Dictionary <Block, Variable>();
foreach (Block header in yieldingLoopHeaders)
{
var pcForYieldingLoopHeader = PcForYieldingLoopHeader(header);
newLocalVars.Add(pcForYieldingLoopHeader);
pcsForYieldingLoopsHeaders[header] = pcForYieldingLoopHeader;
var okForYieldingLoopHeader = OkForYieldingLoopHeader(header);
newLocalVars.Add(okForYieldingLoopHeader);
oksForYieldingLoopHeaders[header] = okForYieldingLoopHeader;
}
}
private static void AddChecker(CivlTypeChecker civlTypeChecker, Action action, List<Declaration> decls)
{
var linearTypeChecker = civlTypeChecker.linearTypeChecker;
// Note: The implementation should be used as the variables in the
// gate are bound to implementation and not to the procedure.
Implementation impl = action.impl;
List<Variable> inputs = impl.InParams;
List<Variable> outputs = impl.OutParams;
List<Variable> locals = new List<Variable>(2);
var paLocal1 = civlTypeChecker.LocalVariable("pa1", civlTypeChecker.pendingAsyncType);
var paLocal2 = civlTypeChecker.LocalVariable("pa2", civlTypeChecker.pendingAsyncType);
var pa1 = Expr.Ident(paLocal1);
var pa2 = Expr.Ident(paLocal2);
if (civlTypeChecker.pendingAsyncType != null)
{
locals.Add(paLocal1);
locals.Add(paLocal2);
}
List<Requires> requires = action.gate.Select(a => new Requires(false, a.Expr)).ToList();
List<LinearityCheck> linearityChecks = new List<LinearityCheck>();
foreach (var domain in linearTypeChecker.linearDomains.Values)
{
// Linear in vars
var inVars = inputs.Union(action.modifiedGlobalVars)
.Where(x => linearTypeChecker.FindDomainName(x) == domain.domainName)
.Where(x => InKinds.Contains(linearTypeChecker.FindLinearKind(x)))
.Select(Expr.Ident)
.ToList();
// Linear out vars
var outVars = inputs.Union(outputs).Union(action.modifiedGlobalVars)
.Where(x => linearTypeChecker.FindDomainName(x) == domain.domainName)
.Where(x => OutKinds.Contains(linearTypeChecker.FindLinearKind(x)))
.Select(Expr.Ident)
.ToList();
// First kind
// Permissions in linear output variables are a subset of permissions in linear input variables.
if (outVars.Count > 0)
{
linearityChecks.Add(new LinearityCheck(
null,
OutPermsSubsetInPerms(domain, inVars, outVars),
$"Potential linearity violation in outputs for domain {domain.domainName}.",
"variables"));
}
if (action is AtomicAction atomicAction && atomicAction.HasPendingAsyncs)
{
var PAs = Expr.Ident(atomicAction.impl.OutParams.Last());
foreach (var pendingAsync in atomicAction.pendingAsyncs)
{
var pendingAsyncLinearParams = PendingAsyncLinearParams(linearTypeChecker, domain, pendingAsync, pa1);
if (pendingAsyncLinearParams.Count == 0) continue;
// Second kind
// Permissions in linear output variables + linear inputs of a single pending async
// are a subset of permissions in linear input variables.
var exactlyOnePA = Expr.And(
ExprHelper.FunctionCall(pendingAsync.pendingAsyncCtor.membership, pa1),
Expr.Eq(Expr.Select(PAs, pa1), Expr.Literal(1)));
var outSubsetInExpr = OutPermsSubsetInPerms(domain, inVars, pendingAsyncLinearParams.Union(outVars));
linearityChecks.Add(new LinearityCheck(
exactlyOnePA,
outSubsetInExpr,
$"Potential linearity violation in outputs and pending async of {pendingAsync.proc.Name} for domain {domain.domainName}.",
$"single_{pendingAsync.proc.Name}"));
// Third kind
// If there are two identical pending asyncs, then their input permissions mut be empty.
var twoIdenticalPAs = Expr.And(
ExprHelper.FunctionCall(pendingAsync.pendingAsyncCtor.membership, pa1),
Expr.Ge(Expr.Select(PAs, pa1), Expr.Literal(2)));
var emptyPerms = OutPermsSubsetInPerms(domain, Enumerable.Empty<Expr>(), pendingAsyncLinearParams);
linearityChecks.Add(new LinearityCheck(
twoIdenticalPAs,
emptyPerms,
$"Potential linearity violation in identical pending asyncs of {pendingAsync.proc.Name} for domain {domain.domainName}.",
$"identical_{pendingAsync.proc.Name}"));
}
var pendingAsyncs = atomicAction.pendingAsyncs.ToList();
for (int i = 0; i < pendingAsyncs.Count; i++)
{
var pendingAsync1 = pendingAsyncs[i];
for (int j = i; j < pendingAsyncs.Count; j++)
{
var pendingAsync2 = pendingAsyncs[j];
var pendingAsyncLinearParams1 = PendingAsyncLinearParams(linearTypeChecker, domain, pendingAsync1, pa1);
var pendingAsyncLinearParams2 = PendingAsyncLinearParams(linearTypeChecker, domain, pendingAsync2, pa2);
if (pendingAsyncLinearParams1.Count == 0 || pendingAsyncLinearParams2.Count == 0) continue;
// Fourth kind
// Input permissions of two non-identical pending asyncs (possibly of the same action)
// are a subset of permissions in linear input variables.
var membership = Expr.And(
Expr.Neq(pa1, pa2),
Expr.And(
ExprHelper.FunctionCall(pendingAsync1.pendingAsyncCtor.membership, pa1),
ExprHelper.FunctionCall(pendingAsync2.pendingAsyncCtor.membership, pa2)));
var existing = Expr.And(
Expr.Ge(Expr.Select(PAs, pa1), Expr.Literal(1)),
Expr.Ge(Expr.Select(PAs, pa2), Expr.Literal(1)));
var noDuplication = OutPermsSubsetInPerms(domain, inVars, pendingAsyncLinearParams1.Union(pendingAsyncLinearParams2));
linearityChecks.Add(new LinearityCheck(
Expr.And(membership, existing),
noDuplication,
$"Potential lnearity violation in pending asyncs of {pendingAsync1.proc.Name} and {pendingAsync2.proc.Name} for domain {domain.domainName}.",
$"distinct_{pendingAsync1.proc.Name}_{pendingAsync2.proc.Name}"));
}
}
}
}
if (linearityChecks.Count == 0) return;
// Create checker blocks
List<Block> checkerBlocks = new List<Block>(linearityChecks.Count);
foreach (var lc in linearityChecks)
{
List<Cmd> cmds = new List<Cmd>(2);
if (lc.assume != null)
{
cmds.Add(CmdHelper.AssumeCmd(lc.assume));
}
cmds.Add(new AssertCmd(action.proc.tok, lc.assert) { ErrorData = lc.message });
var block = new Block(Token.NoToken, lc.name, cmds, CmdHelper.ReturnCmd);
CivlUtil.ResolveAndTypecheck(block, ResolutionContext.State.Two);
checkerBlocks.Add(block);
}
// Create init blocks
List<Block> blocks = new List<Block>(linearityChecks.Count + 1);
blocks.Add(
new Block(
Token.NoToken,
"init",
new List<Cmd> { CmdHelper.CallCmd(action.proc, inputs, outputs) },
new GotoCmd(Token.NoToken, checkerBlocks)));
blocks.AddRange(checkerBlocks);
// Create the whole check procedure
string checkerName = civlTypeChecker.AddNamePrefix($"LinearityChecker_{action.proc.Name}");
Procedure linCheckerProc = new Procedure(Token.NoToken, checkerName, new List<TypeVariable>(),
inputs, outputs, requires, action.proc.Modifies, new List<Ensures>());
Implementation linCheckImpl = new Implementation(Token.NoToken, checkerName,
new List<TypeVariable>(), inputs, outputs, locals, blocks);
linCheckImpl.Proc = linCheckerProc;
decls.Add(linCheckImpl);
decls.Add(linCheckerProc);
}
public ActionRefinementInstrumentation(
CivlTypeChecker civlTypeChecker,
Implementation impl,
Implementation originalImpl,
Dictionary <Variable, Variable> oldGlobalMap) :
base(civlTypeChecker, civlTypeChecker.procToYieldingProc[originalImpl.Proc] as ActionProc, oldGlobalMap)
{
newLocalVars = new List <Variable>();
ActionProc actionProc = civlTypeChecker.procToYieldingProc[originalImpl.Proc] as ActionProc;
int layerNum = actionProc.upperLayer;
pc = new LocalVariable(Token.NoToken, new TypedIdent(Token.NoToken, "og_pc", Type.Bool));
newLocalVars.Add(pc);
ok = new LocalVariable(Token.NoToken, new TypedIdent(Token.NoToken, "og_ok", Type.Bool));
newLocalVars.Add(ok);
this.transitionRelationCache = new Dictionary <AtomicAction, Expr>();
oldOutputMap = new Dictionary <Variable, Variable>();
foreach (Variable f in impl.OutParams)
{
LocalVariable copy = Old(f);
newLocalVars.Add(copy);
oldOutputMap[f] = copy;
}
Dictionary <Variable, Expr> foroldMap = new Dictionary <Variable, Expr>();
foreach (Variable g in civlTypeChecker.sharedVariables)
{
foroldMap[g] = Expr.Ident(oldGlobalMap[g]);
}
// The parameters of an atomic action come from the implementation that denotes the atomic action specification.
// To use the transition relation computed below in the context of the yielding procedure of the refinement check,
// we need to substitute the parameters.
AtomicAction atomicAction = actionProc.refinedAction;
Implementation atomicActionImpl = atomicAction.impl;
Dictionary <Variable, Expr> alwaysMap = new Dictionary <Variable, Expr>();
for (int i = 0; i < impl.InParams.Count; i++)
{
alwaysMap[atomicActionImpl.InParams[i]] = Expr.Ident(impl.InParams[i]);
}
for (int i = 0; i < impl.OutParams.Count; i++)
{
alwaysMap[atomicActionImpl.OutParams[i]] = Expr.Ident(impl.OutParams[i]);
}
if (atomicAction.HasPendingAsyncs)
{
Variable collectedPAs = civlTypeChecker.implToPendingAsyncCollector[originalImpl];
alwaysMap[atomicActionImpl.OutParams.Last()] = Expr.Ident(collectedPAs);
LocalVariable copy = Old(collectedPAs);
newLocalVars.Add(copy);
oldOutputMap[collectedPAs] = copy;
}
Substitution always = Substituter.SubstitutionFromHashtable(alwaysMap);
Substitution forold = Substituter.SubstitutionFromHashtable(foroldMap);
Expr transitionRelationExpr = GetTransitionRelation(atomicAction);
transitionRelation = Substituter.ApplyReplacingOldExprs(always, forold, transitionRelationExpr);
Expr gateExpr = Expr.And(atomicAction.gate.Select(g => g.Expr));
gateExpr.Type = Type.Bool;
gate = Substituter.Apply(always, gateExpr);
}
public static void AddCheckers(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker, List<Declaration> decls)
{
if (civlTypeChecker.procToActionInfo.Count == 0)
return;
List<ActionInfo> sortedByCreatedLayerNum = new List<ActionInfo>(civlTypeChecker.procToActionInfo.Values.Where(x => x is AtomicActionInfo && !x.isExtern));
sortedByCreatedLayerNum.Sort((x, y) => { return (x.createdAtLayerNum == y.createdAtLayerNum) ? 0 : (x.createdAtLayerNum < y.createdAtLayerNum) ? -1 : 1; });
List<ActionInfo> sortedByAvailableUptoLayerNum = new List<ActionInfo>(civlTypeChecker.procToActionInfo.Values.Where(x => x is AtomicActionInfo && !x.isExtern));
sortedByAvailableUptoLayerNum.Sort((x, y) => { return (x.availableUptoLayerNum == y.availableUptoLayerNum) ? 0 : (x.availableUptoLayerNum < y.availableUptoLayerNum) ? -1 : 1; });
Dictionary<int, HashSet<AtomicActionInfo>> pools = new Dictionary<int, HashSet<AtomicActionInfo>>();
int indexIntoSortedByCreatedLayerNum = 0;
int indexIntoSortedByAvailableUptoLayerNum = 0;
HashSet<AtomicActionInfo> currPool = new HashSet<AtomicActionInfo>();
while (indexIntoSortedByCreatedLayerNum < sortedByCreatedLayerNum.Count)
{
var currLayerNum = sortedByCreatedLayerNum[indexIntoSortedByCreatedLayerNum].createdAtLayerNum;
pools[currLayerNum] = new HashSet<AtomicActionInfo>(currPool);
while (indexIntoSortedByCreatedLayerNum < sortedByCreatedLayerNum.Count)
{
var actionInfo = sortedByCreatedLayerNum[indexIntoSortedByCreatedLayerNum] as AtomicActionInfo;
if (actionInfo.createdAtLayerNum > currLayerNum) break;
pools[currLayerNum].Add(actionInfo);
indexIntoSortedByCreatedLayerNum++;
}
while (indexIntoSortedByAvailableUptoLayerNum < sortedByAvailableUptoLayerNum.Count)
{
var actionInfo = sortedByAvailableUptoLayerNum[indexIntoSortedByAvailableUptoLayerNum] as AtomicActionInfo;
if (actionInfo.availableUptoLayerNum > currLayerNum) break;
pools[currLayerNum].Remove(actionInfo);
indexIntoSortedByAvailableUptoLayerNum++;
}
currPool = pools[currLayerNum];
}
// No atomic action has mover type Top
Debug.Assert(pools.All(l => l.Value.All(a => a.moverType != MoverType.Top)));
Program program = civlTypeChecker.program;
MoverCheck moverChecking = new MoverCheck(linearTypeChecker, civlTypeChecker, decls);
var moverChecks =
from layer in pools.Keys
from first in pools[layer]
from second in pools[layer]
where first.moverType != MoverType.Atomic
select new { First = first, Second = second };
foreach (var moverCheck in moverChecks)
{
var first = moverCheck.First;
var second = moverCheck.Second;
if (first.IsRightMover)
{
moverChecking.CreateCommutativityChecker(program, first, second);
moverChecking.CreateGatePreservationChecker(program, second, first);
}
if (first.IsLeftMover)
{
moverChecking.CreateCommutativityChecker(program, second, first);
moverChecking.CreateGatePreservationChecker(program, first, second);
moverChecking.CreateFailurePreservationChecker(program, second, first);
}
}
foreach (AtomicActionInfo atomicActionInfo in sortedByCreatedLayerNum)
{
if (atomicActionInfo.IsLeftMover && atomicActionInfo.hasAssumeCmd)
{
moverChecking.CreateNonBlockingChecker(program, atomicActionInfo);
}
}
}
public PurityChecker(CivlTypeChecker civlTypeChecker)
{
this.civlTypeChecker = civlTypeChecker;
}
private static Formal SnapshotGlobalFormal(CivlTypeChecker civlTypeChecker, Variable v)
{
return(civlTypeChecker.Formal($"snapshot_{v.Name}", v.TypedIdent.Type, true));
}
/// <summary>
/// Resolves and type checks the given Boogie program. Any errors are reported to the
/// console. Returns:
/// - Done if no errors occurred, and command line specified no resolution or no type checking.
/// - ResolutionError if a resolution error occurred
/// - TypeCheckingError if a type checking error occurred
/// - ResolvedAndTypeChecked if both resolution and type checking succeeded
/// </summary>
public static PipelineOutcome ResolveAndTypecheck(Program program, string bplFileName, out LinearTypeChecker linearTypeChecker, out CivlTypeChecker civlTypeChecker)
{
Contract.Requires(program != null);
Contract.Requires(bplFileName != null);
linearTypeChecker = null;
civlTypeChecker = null;
// ---------- Resolve ------------------------------------------------------------
if (CommandLineOptions.Clo.NoResolve)
{
return PipelineOutcome.Done;
}
int errorCount = program.Resolve();
if (errorCount != 0)
{
Console.WriteLine("{0} name resolution errors detected in {1}", errorCount, GetFileNameForConsole(bplFileName));
return PipelineOutcome.ResolutionError;
}
// ---------- Type check ------------------------------------------------------------
if (CommandLineOptions.Clo.NoTypecheck)
{
return PipelineOutcome.Done;
}
errorCount = program.Typecheck();
if (errorCount != 0)
{
Console.WriteLine("{0} type checking errors detected in {1}", errorCount, GetFileNameForConsole(bplFileName));
return PipelineOutcome.TypeCheckingError;
}
if (PolymorphismChecker.IsMonomorphic(program))
{
CommandLineOptions.Clo.TypeEncodingMethod = CommandLineOptions.TypeEncoding.Monomorphic;
}
CollectModSets(program);
civlTypeChecker = new CivlTypeChecker(program);
civlTypeChecker.TypeCheck();
if (civlTypeChecker.errorCount != 0)
{
Console.WriteLine("{0} type checking errors detected in {1}", civlTypeChecker.errorCount, GetFileNameForConsole(bplFileName));
return PipelineOutcome.TypeCheckingError;
}
linearTypeChecker = new LinearTypeChecker(program);
linearTypeChecker.TypeCheck();
if (linearTypeChecker.errorCount == 0)
{
linearTypeChecker.Transform();
}
else
{
Console.WriteLine("{0} type checking errors detected in {1}", linearTypeChecker.errorCount, GetFileNameForConsole(bplFileName));
return PipelineOutcome.TypeCheckingError;
}
if (CommandLineOptions.Clo.PrintFile != null && CommandLineOptions.Clo.PrintDesugarings)
{
// if PrintDesugaring option is engaged, print the file here, after resolution and type checking
PrintBplFile(CommandLineOptions.Clo.PrintFile, program, true, true, CommandLineOptions.Clo.PrettyPrint);
}
return PipelineOutcome.ResolvedAndTypeChecked;
}
private static LocalVariable OldGlobalLocal(CivlTypeChecker civlTypeChecker, Variable v)
{
return(civlTypeChecker.LocalVariable($"old_{v.Name}", v.TypedIdent.Type));
}
internal static int Check(Function node, CivlTypeChecker ctc, WitnessFunction witnessFunction)
{
var checker = new WitnessFunctionChecker(node, ctc, witnessFunction);
return(checker.errorCount);
}
public static List <Declaration> CreateNoninterferenceCheckers(
CivlTypeChecker civlTypeChecker,
int layerNum,
AbsyMap absyMap,
DeclWithFormals decl,
List <Variable> declLocalVariables)
{
var linearTypeChecker = civlTypeChecker.linearTypeChecker;
Dictionary <string, Variable> domainNameToHoleVar = new Dictionary <string, Variable>();
Dictionary <Variable, Variable> localVarMap = new Dictionary <Variable, Variable>();
Dictionary <Variable, Expr> map = new Dictionary <Variable, Expr>();
List <Variable> locals = new List <Variable>();
List <Variable> inputs = new List <Variable>();
foreach (var domainName in linearTypeChecker.linearDomains.Keys)
{
var inParam = linearTypeChecker.LinearDomainInFormal(domainName);
inputs.Add(inParam);
domainNameToHoleVar[domainName] = inParam;
}
foreach (Variable local in declLocalVariables.Union(decl.InParams).Union(decl.OutParams))
{
var copy = CopyLocal(local);
locals.Add(copy);
localVarMap[local] = copy;
map[local] = Expr.Ident(copy);
}
Dictionary <Variable, Expr> oldLocalMap = new Dictionary <Variable, Expr>();
Dictionary <Variable, Expr> assumeMap = new Dictionary <Variable, Expr>(map);
foreach (Variable g in civlTypeChecker.GlobalVariables)
{
var copy = OldGlobalLocal(civlTypeChecker, g);
locals.Add(copy);
oldLocalMap[g] = Expr.Ident(copy);
Formal f = SnapshotGlobalFormal(civlTypeChecker, g);
inputs.Add(f);
assumeMap[g] = Expr.Ident(f);
}
var linearPermissionInstrumentation = new LinearPermissionInstrumentation(civlTypeChecker,
layerNum, absyMap, domainNameToHoleVar, localVarMap);
List <YieldInfo> yieldInfos = null;
string noninterferenceCheckerName = null;
if (decl is Implementation impl)
{
noninterferenceCheckerName = $"impl_{absyMap.Original(impl).Name}_{layerNum}";
yieldInfos = CollectYields(civlTypeChecker, absyMap, layerNum, impl).Select(kv =>
new YieldInfo(linearPermissionInstrumentation.DisjointnessAssumeCmds(kv.Key, false), kv.Value)).ToList();
}
else if (decl is Procedure proc)
{
yieldInfos = new List <YieldInfo>();
if (civlTypeChecker.procToYieldInvariant.ContainsKey(proc))
{
noninterferenceCheckerName = $"yield_{proc.Name}";
if (proc.Requires.Count > 0)
{
var disjointnessCmds = linearPermissionInstrumentation.ProcDisjointnessAssumeCmds(proc, true);
var yieldPredicates = proc.Requires.Select(requires =>
requires.Free
? (PredicateCmd) new AssumeCmd(requires.tok, requires.Condition)
: (PredicateCmd) new AssertCmd(requires.tok, requires.Condition)).ToList();
yieldInfos.Add(new YieldInfo(disjointnessCmds, yieldPredicates));
}
}
else
{
noninterferenceCheckerName = $"proc_{absyMap.Original(proc).Name}_{layerNum}";
if (proc.Requires.Count > 0)
{
var entryDisjointnessCmds =
linearPermissionInstrumentation.ProcDisjointnessAssumeCmds(proc, true);
var entryYieldPredicates = proc.Requires.Select(requires =>
requires.Free
? (PredicateCmd) new AssumeCmd(requires.tok, requires.Condition)
: (PredicateCmd) new AssertCmd(requires.tok, requires.Condition)).ToList();
yieldInfos.Add(new YieldInfo(entryDisjointnessCmds, entryYieldPredicates));
}
if (proc.Ensures.Count > 0)
{
var exitDisjointnessCmds =
linearPermissionInstrumentation.ProcDisjointnessAssumeCmds(proc, false);
var exitYieldPredicates = proc.Ensures.Select(ensures =>
ensures.Free
? (PredicateCmd) new AssumeCmd(ensures.tok, ensures.Condition)
: (PredicateCmd) new AssertCmd(ensures.tok, ensures.Condition)).ToList();
yieldInfos.Add(new YieldInfo(exitDisjointnessCmds, exitYieldPredicates));
}
}
}
else
{
Debug.Assert(false);
}
var filteredYieldInfos = yieldInfos.Where(info =>
info.invariantCmds.Any(predCmd => new GlobalAccessChecker().AccessesGlobal(predCmd.Expr)));
if (filteredYieldInfos.Count() == 0)
{
return(new List <Declaration>());
}
Substitution assumeSubst = Substituter.SubstitutionFromDictionary(assumeMap);
Substitution oldSubst = Substituter.SubstitutionFromDictionary(oldLocalMap);
Substitution subst = Substituter.SubstitutionFromDictionary(map);
List <Block> noninterferenceCheckerBlocks = new List <Block>();
List <Block> labelTargets = new List <Block>();
Block noninterferenceCheckerBlock = BlockHelper.Block("exit", new List <Cmd>());
labelTargets.Add(noninterferenceCheckerBlock);
noninterferenceCheckerBlocks.Add(noninterferenceCheckerBlock);
int yieldCount = 0;
foreach (var kv in filteredYieldInfos)
{
var newCmds = new List <Cmd>(kv.disjointnessCmds);
foreach (var predCmd in kv.invariantCmds)
{
var newExpr = Substituter.ApplyReplacingOldExprs(assumeSubst, oldSubst, predCmd.Expr);
newCmds.Add(new AssumeCmd(predCmd.tok, newExpr));
}
foreach (var predCmd in kv.invariantCmds)
{
if (predCmd is AssertCmd)
{
var newExpr = Substituter.ApplyReplacingOldExprs(subst, oldSubst, predCmd.Expr);
AssertCmd assertCmd = new AssertCmd(predCmd.tok, newExpr, predCmd.Attributes);
assertCmd.ErrorData = "Non-interference check failed";
newCmds.Add(assertCmd);
}
}
newCmds.Add(CmdHelper.AssumeCmd(Expr.False));
noninterferenceCheckerBlock = BlockHelper.Block("L" + yieldCount++, newCmds);
labelTargets.Add(noninterferenceCheckerBlock);
noninterferenceCheckerBlocks.Add(noninterferenceCheckerBlock);
}
noninterferenceCheckerBlocks.Insert(0, BlockHelper.Block("enter", new List <Cmd>(), labelTargets));
// Create the yield checker procedure
noninterferenceCheckerName = civlTypeChecker.AddNamePrefix($"NoninterferenceChecker_{noninterferenceCheckerName}");
var noninterferenceCheckerProc = DeclHelper.Procedure(noninterferenceCheckerName,
inputs, new List <Variable>(), new List <Requires>(), new List <IdentifierExpr>(), new List <Ensures>());
CivlUtil.AddInlineAttribute(noninterferenceCheckerProc);
// Create the yield checker implementation
var noninterferenceCheckerImpl = DeclHelper.Implementation(noninterferenceCheckerProc,
inputs, new List <Variable>(), locals, noninterferenceCheckerBlocks);
CivlUtil.AddInlineAttribute(noninterferenceCheckerImpl);
return(new List <Declaration> {
noninterferenceCheckerProc, noninterferenceCheckerImpl
});
}
public static void AddCheckers(LinearTypeChecker linearTypeChecker, CivlTypeChecker civlTypeChecker, List <Declaration> decls)
{
if (civlTypeChecker.procToActionInfo.Count == 0)
{
return;
}
List <ActionInfo> sortedByCreatedLayerNum = new List <ActionInfo>(civlTypeChecker.procToActionInfo.Values.Where(x => x is AtomicActionInfo && !x.isExtern));
sortedByCreatedLayerNum.Sort((x, y) => { return((x.createdAtLayerNum == y.createdAtLayerNum) ? 0 : (x.createdAtLayerNum < y.createdAtLayerNum) ? -1 : 1); });
List <ActionInfo> sortedByAvailableUptoLayerNum = new List <ActionInfo>(civlTypeChecker.procToActionInfo.Values.Where(x => x is AtomicActionInfo && !x.isExtern));
sortedByAvailableUptoLayerNum.Sort((x, y) => { return((x.availableUptoLayerNum == y.availableUptoLayerNum) ? 0 : (x.availableUptoLayerNum < y.availableUptoLayerNum) ? -1 : 1); });
Dictionary <int, HashSet <AtomicActionInfo> > pools = new Dictionary <int, HashSet <AtomicActionInfo> >();
int indexIntoSortedByCreatedLayerNum = 0;
int indexIntoSortedByAvailableUptoLayerNum = 0;
HashSet <AtomicActionInfo> currPool = new HashSet <AtomicActionInfo>();
while (indexIntoSortedByCreatedLayerNum < sortedByCreatedLayerNum.Count)
{
var currLayerNum = sortedByCreatedLayerNum[indexIntoSortedByCreatedLayerNum].createdAtLayerNum;
pools[currLayerNum] = new HashSet <AtomicActionInfo>(currPool);
while (indexIntoSortedByCreatedLayerNum < sortedByCreatedLayerNum.Count)
{
var actionInfo = sortedByCreatedLayerNum[indexIntoSortedByCreatedLayerNum] as AtomicActionInfo;
if (actionInfo.createdAtLayerNum > currLayerNum)
{
break;
}
pools[currLayerNum].Add(actionInfo);
indexIntoSortedByCreatedLayerNum++;
}
while (indexIntoSortedByAvailableUptoLayerNum < sortedByAvailableUptoLayerNum.Count)
{
var actionInfo = sortedByAvailableUptoLayerNum[indexIntoSortedByAvailableUptoLayerNum] as AtomicActionInfo;
if (actionInfo.availableUptoLayerNum > currLayerNum)
{
break;
}
pools[currLayerNum].Remove(actionInfo);
indexIntoSortedByAvailableUptoLayerNum++;
}
currPool = pools[currLayerNum];
}
// No atomic action has mover type Top
Debug.Assert(pools.All(l => l.Value.All(a => a.moverType != MoverType.Top)));
Program program = civlTypeChecker.program;
MoverCheck moverChecking = new MoverCheck(linearTypeChecker, civlTypeChecker, decls);
var moverChecks =
from layer in pools.Keys
from first in pools[layer]
from second in pools[layer]
where first.moverType != MoverType.Atomic
select new { First = first, Second = second };
foreach (var moverCheck in moverChecks)
{
var first = moverCheck.First;
var second = moverCheck.Second;
if (first.IsRightMover)
{
moverChecking.CreateCommutativityChecker(program, first, second);
moverChecking.CreateGatePreservationChecker(program, second, first);
}
if (first.IsLeftMover)
{
moverChecking.CreateCommutativityChecker(program, second, first);
moverChecking.CreateGatePreservationChecker(program, first, second);
moverChecking.CreateFailurePreservationChecker(program, second, first);
}
}
foreach (AtomicActionInfo atomicActionInfo in sortedByCreatedLayerNum)
{
if (atomicActionInfo.IsLeftMover && atomicActionInfo.hasAssumeCmd)
{
moverChecking.CreateNonBlockingChecker(program, atomicActionInfo);
}
}
}
public static void AddChecks(CivlTypeChecker ctc)
{
foreach (var x in ctc.inductiveSequentializations)
{
var t = x.GenerateBaseCaseChecker();
ctc.program.AddTopLevelDeclaration(t.Item1);
ctc.program.AddTopLevelDeclaration(t.Item2);
t = x.GenerateConclusionChecker();
ctc.program.AddTopLevelDeclaration(t.Item1);
ctc.program.AddTopLevelDeclaration(t.Item2);
t = x.GenerateStepChecker(ctc.pendingAsyncAdd);
ctc.program.AddTopLevelDeclaration(t.Item1);
ctc.program.AddTopLevelDeclaration(t.Item2);
}
var absChecks = ctc.inductiveSequentializations.SelectMany(x => x.elim).Where(kv => kv.Key != kv.Value)
.Distinct();
foreach (var absCheck in absChecks)
{
var action = absCheck.Key;
var abs = absCheck.Value;
var requires = abs.gate.Select(g => new Requires(false, g.Expr)).ToList();
// TODO: check frame computation
var frame = new HashSet <Variable>(action.modifiedGlobalVars.Union(action.gateUsedGlobalVars)
.Union(abs.modifiedGlobalVars).Union(abs.gateUsedGlobalVars));
var tr = TransitionRelationComputation.Refinement(abs, frame);
var ensures = new List <Ensures>
{
new Ensures(false, tr)
{
ErrorData = $"Abstraction {abs.proc.Name} does not summarize {action.proc.Name}"
}
};
var subst = InductiveSequentialization.GetSubstitution(action, abs);
List <Cmd> cmds = InductiveSequentialization.GetGateAsserts(action, subst,
$"Abstraction {abs.proc.Name} fails gate of {action.proc.Name}").ToList <Cmd>();
cmds.Add(
CmdHelper.CallCmd(
action.proc,
abs.impl.InParams.Select(Expr.Ident).ToList <Expr>(),
abs.impl.OutParams.Select(Expr.Ident).ToList()
));
var blocks = new List <Block> {
new Block(Token.NoToken, "init", cmds, CmdHelper.ReturnCmd)
};
var proc = new Procedure(Token.NoToken, $"AbstractionCheck_{action.proc.Name}_{abs.proc.Name}",
new List <TypeVariable>(),
abs.impl.InParams, abs.impl.OutParams, requires, action.proc.Modifies, ensures);
var impl = new Implementation(Token.NoToken, proc.Name, new List <TypeVariable>(),
proc.InParams, proc.OutParams, new List <Variable>(), blocks)
{
Proc = proc
};
ctc.program.AddTopLevelDeclaration(proc);
ctc.program.AddTopLevelDeclaration(impl);
}
}
public CommutativityHintVisitor(CivlTypeChecker civlTypeChecker)
{
this.civlTypeChecker = civlTypeChecker;
commutativityHints = new CommutativityHints();
}
public PurityChecker(CivlTypeChecker civlTypeChecker)
{
this.civlTypeChecker = civlTypeChecker;
}
