protected BoundDecisionDag ShareTempsIfPossibleAndEvaluateInput(
                BoundDecisionDag decisionDag,
                BoundExpression loweredSwitchGoverningExpression,
                ArrayBuilder <BoundStatement> result,
                out BoundExpression savedInputExpression)
            {
                // Note that a when-clause can contain an assignment to a
                // pattern variable declared in a different when-clause (e.g. in the same section, or
                // in a different section via the use of a local function), so we need to analyze all
                // of the when clauses to see if they are all simple enough to conclude that they do
                // not mutate pattern variables.
                var  mightAssignWalker = new WhenClauseMightAssignPatternVariableWalker();
                bool canShareTemps     =
                    !decisionDag.TopologicallySortedNodes
                    .Any(node => node is BoundWhenDecisionDagNode w && mightAssignWalker.MightAssignSomething(w.WhenExpression));

                if (canShareTemps)
                {
                    decisionDag = ShareTempsAndEvaluateInput(loweredSwitchGoverningExpression, decisionDag, expr => result.Add(_factory.ExpressionStatement(expr)), out savedInputExpression);
                }
                else
                {
                    // assign the input expression to its temp.
                    BoundExpression inputTemp = _tempAllocator.GetTemp(BoundDagTemp.ForOriginalInput(loweredSwitchGoverningExpression));
                    Debug.Assert(inputTemp != loweredSwitchGoverningExpression);
                    result.Add(_factory.Assignment(inputTemp, loweredSwitchGoverningExpression));
                    savedInputExpression = inputTemp;
                }

                return(decisionDag);
            }
Пример #2
0
        LearnFromDecisionDag(
            SyntaxNode node,
            BoundDecisionDag decisionDag,
            BoundExpression expression,
            TypeWithState expressionType,
            ref PossiblyConditionalState initialState)
        {
            // We reuse the slot at the beginning of a switch (or is-pattern expression), pretending that we are
            // not copying the input to evaluate the patterns.  In this way we infer non-nullability of the original
            // variable's parts based on matched pattern parts.  Mutations in `when` clauses can show the inaccuracy
            // of analysis based on this choice.
            var rootTemp          = BoundDagTemp.ForOriginalInput(expression);
            int originalInputSlot = MakeSlot(expression);

            if (originalInputSlot <= 0)
            {
                originalInputSlot = makeDagTempSlot(expressionType.ToTypeWithAnnotations(compilation), rootTemp);
            }
            Debug.Assert(originalInputSlot > 0);

            // If the input of the switch (or is-pattern expression) is a tuple literal, we reuse the slots of
            // those expressions (when possible), pretending that we are not copying them into a temporary ValueTuple instance
            // to evaluate the patterns.  In this way we infer non-nullability of the original element's parts.
            // We do not extend such courtesy to nested tuple literals.
            var originalInputElementSlots = expression is BoundTupleExpression tuple
                ? tuple.Arguments.SelectAsArray(static (a, w) => w.MakeSlot(a), this)
Пример #3
0
            /// <summary>
            /// Produce assignment of the input expression. This method is also responsible for assigning
            /// variables for some pattern-matching temps that can be shared with user variables.
            /// </summary>
            protected BoundDecisionDag ShareTempsAndEvaluateInput(
                BoundExpression loweredInput,
                BoundDecisionDag decisionDag,
                Action <BoundExpression> addCode,
                out BoundExpression savedInputExpression)
            {
                var inputDagTemp = BoundDagTemp.ForOriginalInput(loweredInput);

                if ((loweredInput.Kind == BoundKind.Local || loweredInput.Kind == BoundKind.Parameter) &&
                    loweredInput.GetRefKind() == RefKind.None)
                {
                    // If we're switching on a local variable and there is no when clause (checked by the caller),
                    // we assume the value of the local variable does not change during the execution of the
                    // decision automaton and we just reuse the local variable when we need the input expression.
                    // It is possible for this assumption to be violated by a side-effecting Deconstruct that
                    // modifies the local variable which has been captured in a lambda. Since the language assumes
                    // that functions called by pattern-matching are idempotent and not side-effecting, we feel
                    // justified in taking this assumption in the compiler too.
                    bool tempAssigned = _tempAllocator.TrySetTemp(inputDagTemp, loweredInput);
                    Debug.Assert(tempAssigned);
                }

                foreach (BoundDecisionDagNode node in decisionDag.TopologicallySortedNodes)
                {
                    if (node is BoundWhenDecisionDagNode w)
                    {
                        // We share a slot for a user-declared pattern-matching variable with a pattern temp if there
                        // is no user-written when-clause that could modify the variable before the matching
                        // automaton is done with it (checked by the caller).
                        foreach (BoundPatternBinding binding in w.Bindings)
                        {
                            if (binding.VariableAccess is BoundLocal l)
                            {
                                Debug.Assert(l.LocalSymbol.DeclarationKind == LocalDeclarationKind.PatternVariable);
                                _ = _tempAllocator.TrySetTemp(binding.TempContainingValue, binding.VariableAccess);
                            }
                        }
                    }
                }

                if (loweredInput.Type.IsTupleType &&
                    loweredInput.Syntax.Kind() == SyntaxKind.TupleExpression &&
                    loweredInput is BoundObjectCreationExpression expr &&
                    !decisionDag.TopologicallySortedNodes.Any(n => usesOriginalInput(n)))
                {
                    // If the switch governing expression is a tuple literal whose whole value is not used anywhere,
                    // (though perhaps its component parts are used), then we can save the component parts
                    // and assign them into temps (or perhaps user variables) to avoid the creation of
                    // the tuple altogether.
                    decisionDag = RewriteTupleInput(decisionDag, expr, addCode, out savedInputExpression);
                }
            protected BoundDecisionDag ShareTempsIfPossibleAndEvaluateInput(
                BoundDecisionDag decisionDag,
                BoundExpression loweredSwitchGoverningExpression,
                ArrayBuilder <BoundStatement> result,
                out BoundExpression savedInputExpression)
            {
                // Note that a when-clause can contain an assignment to a
                // pattern variable declared in a different when-clause (e.g. in the same section, or
                // in a different section via the use of a local function), so we need to analyze all
                // of the when clauses to see if they are all simple enough to conclude that they do
                // not mutate pattern variables.
                var  mightAssignWalker = new WhenClauseMightAssignWalker();
                bool canShareTemps     =
                    !decisionDag.TopologicallySortedNodes
                    .Any(node => node is BoundWhenDecisionDagNode w && mightAssignWalker.MightAssignSomething(w.WhenExpression));

                if (canShareTemps)
                {
                    decisionDag = ShareTempsAndEvaluateInput(loweredSwitchGoverningExpression, decisionDag, expr => result.Add(_factory.ExpressionStatement(expr)), out savedInputExpression);
                }
                else
                {
                    // assign the input expression to its temp.
                    BoundExpression inputTemp = _tempAllocator.GetTemp(BoundDagTemp.ForOriginalInput(loweredSwitchGoverningExpression));
                    Debug.Assert(inputTemp != loweredSwitchGoverningExpression);
                    result.Add(_factory.Assignment(inputTemp, loweredSwitchGoverningExpression));
                    savedInputExpression = inputTemp;
                }

                // In a switch statement, there is a hidden sequence point after evaluating the input at the start of
                // the code to handle the decision dag. This is necessary so that jumps back from a `when` clause into
                // the decision dag do not appear to jump back up to the enclosing construct.
                if (IsSwitchStatement)
                {
                    result.Add(_factory.HiddenSequencePoint());
                }

                return(decisionDag);
            }
Пример #5
0
        LearnFromDecisionDag(
            SyntaxNode node,
            BoundDecisionDag decisionDag,
            BoundExpression expression,
            TypeWithState expressionType,
            ref LocalState initialState)
        {
            // We reuse the slot at the beginning of a switch (or is-pattern expression), pretending that we are
            // not copying the input to evaluate the patterns.  In this way we infer non-nullability of the original
            // variable's parts based on matched pattern parts.  Mutations in `when` clauses can show the inaccuracy
            // of analysis based on this choice.
            var rootTemp          = BoundDagTemp.ForOriginalInput(expression);
            int originalInputSlot = MakeSlot(expression);

            if (originalInputSlot <= 0)
            {
                originalInputSlot = makeDagTempSlot(expressionType.ToTypeWithAnnotations(), rootTemp);
                initialState[originalInputSlot] = expressionType.State;
            }

            var tempMap = PooledDictionary <BoundDagTemp, (int slot, TypeSymbol type)> .GetInstance();

            Debug.Assert(originalInputSlot > 0);
            tempMap.Add(rootTemp, (originalInputSlot, expressionType.Type));

            var nodeStateMap = PooledDictionary <BoundDecisionDagNode, (LocalState state, bool believedReachable)> .GetInstance();

            nodeStateMap.Add(decisionDag.RootNode, (state: initialState.Clone(), believedReachable: true));

            var labelStateMap = PooledDictionary <LabelSymbol, (LocalState state, bool believedReachable)> .GetInstance();

            foreach (var dagNode in decisionDag.TopologicallySortedNodes)
            {
                bool found = nodeStateMap.TryGetValue(dagNode, out var nodeStateAndBelievedReachable);
                Debug.Assert(found); // the topologically sorted nodes should contain only reachable nodes
                (LocalState nodeState, bool nodeBelievedReachable) = nodeStateAndBelievedReachable;
                SetState(nodeState);

                switch (dagNode)
                {
                case BoundEvaluationDecisionDagNode p:
                {
                    var evaluation = p.Evaluation;
                    (int inputSlot, TypeSymbol inputType) = tempMap.TryGetValue(evaluation.Input, out var slotAndType) ? slotAndType : throw ExceptionUtilities.Unreachable;
                    Debug.Assert(inputSlot > 0);
                    var inputState = this.State[inputSlot];

                    switch (evaluation)
                    {
                    case BoundDagDeconstructEvaluation e:
                    {
                        // https://github.com/dotnet/roslyn/issues/34232
                        // We may need to recompute the Deconstruct method for a deconstruction if
                        // the receiver type has changed (e.g. its nested nullability).
                        var method         = e.DeconstructMethod;
                        int extensionExtra = method.IsStatic ? 1 : 0;
                        for (int i = 0; i < method.ParameterCount - extensionExtra; i++)
                        {
                            var parameterType = method.Parameters[i + extensionExtra].TypeWithAnnotations;
                            var output        = new BoundDagTemp(e.Syntax, parameterType.Type, e, i);
                            int outputSlot    = makeDagTempSlot(parameterType, output);
                            Debug.Assert(outputSlot > 0);
                            addToTempMap(output, outputSlot, parameterType.Type);
                        }
                        break;
                    }

                    case BoundDagTypeEvaluation e:
                    {
                        var output = new BoundDagTemp(e.Syntax, e.Type, e);
                        HashSet <DiagnosticInfo> discardedDiagnostics = null;
                        int outputSlot;
                        switch (_conversions.WithNullability(false).ClassifyConversionFromType(inputType, e.Type, ref discardedDiagnostics).Kind)
                        {
                        case ConversionKind.Identity:
                        case ConversionKind.ImplicitReference:
                        case ConversionKind.NoConversion:
                        case ConversionKind.ExplicitReference:
                            outputSlot = inputSlot;
                            break;

                        case ConversionKind.ExplicitNullable when AreNullableAndUnderlyingTypes(inputType, e.Type, out _):
                            outputSlot = GetNullableOfTValueSlot(inputType, inputSlot, out _, forceSlotEvenIfEmpty: true);

                            if (outputSlot < 0)
                            {
                                goto default;
                            }
                            break;

                        default:
                            outputSlot = makeDagTempSlot(TypeWithAnnotations.Create(e.Type, NullableAnnotation.NotAnnotated), output);
                            break;
                        }
                        State[outputSlot] = NullableFlowState.NotNull;
                        var outputType = TypeWithState.Create(e.Type, inputState);
                        addToTempMap(output, outputSlot, outputType.Type);
                        break;
                    }

                    case BoundDagFieldEvaluation e:
                    {
                        Debug.Assert(inputSlot > 0);
                        var field      = (FieldSymbol)AsMemberOfType(inputType, e.Field);
                        int outputSlot = GetOrCreateSlot(field, inputSlot, forceSlotEvenIfEmpty: true);
                        Debug.Assert(outputSlot > 0);
                        var type   = field.Type;
                        var output = new BoundDagTemp(e.Syntax, type, e);
                        addToTempMap(output, outputSlot, type);
                        break;
                    }

                    case BoundDagPropertyEvaluation e:
                    {
                        Debug.Assert(inputSlot > 0);
                        var property   = (PropertySymbol)AsMemberOfType(inputType, e.Property);
                        var type       = property.TypeWithAnnotations;
                        var output     = new BoundDagTemp(e.Syntax, type.Type, e);
                        int outputSlot = GetOrCreateSlot(property, inputSlot, forceSlotEvenIfEmpty: true);
                        if (outputSlot <= 0)
                        {
                            // This is needed due to https://github.com/dotnet/roslyn/issues/29619
                            outputSlot = makeDagTempSlot(type, output);
                        }
                        Debug.Assert(outputSlot > 0);
                        addToTempMap(output, outputSlot, type.Type);
                        break;
                    }

                    case BoundDagIndexEvaluation e:
                    {
                        var type       = TypeWithAnnotations.Create(e.Property.Type, NullableAnnotation.Annotated);
                        var output     = new BoundDagTemp(e.Syntax, type.Type, e);
                        int outputSlot = makeDagTempSlot(type, output);
                        Debug.Assert(outputSlot > 0);
                        addToTempMap(output, outputSlot, type.Type);
                        break;
                    }

                    default:
                        throw ExceptionUtilities.UnexpectedValue(p.Evaluation.Kind);
                    }
                    gotoNode(p.Next, this.State, nodeBelievedReachable);
                    break;
                }

                case BoundTestDecisionDagNode p:
                {
                    var  test      = p.Test;
                    bool foundTemp = tempMap.TryGetValue(test.Input, out var slotAndType);
                    Debug.Assert(foundTemp);

                    (int inputSlot, TypeSymbol inputType) = slotAndType;
                    var inputState = this.State[inputSlot];
                    Split();
                    switch (test)
                    {
                    case BoundDagTypeTest t:
                        if (inputSlot > 0)
                        {
                            learnFromNonNullTest(inputSlot, ref this.StateWhenTrue);
                        }
                        gotoNode(p.WhenTrue, this.StateWhenTrue, nodeBelievedReachable);
                        gotoNode(p.WhenFalse, this.StateWhenFalse, nodeBelievedReachable);
                        break;

                    case BoundDagNonNullTest t:
                        if (inputSlot > 0)
                        {
                            learnFromNonNullTest(inputSlot, ref this.StateWhenTrue);
                        }
                        gotoNode(p.WhenTrue, this.StateWhenTrue, nodeBelievedReachable);
                        gotoNode(p.WhenFalse, this.StateWhenFalse, nodeBelievedReachable & inputState.MayBeNull());
                        break;

                    case BoundDagExplicitNullTest t:
                        if (inputSlot > 0)
                        {
                            LearnFromNullTest(inputSlot, inputType, ref this.StateWhenTrue);
                            learnFromNonNullTest(inputSlot, ref this.StateWhenFalse);
                        }
                        gotoNode(p.WhenTrue, this.StateWhenTrue, nodeBelievedReachable);
                        gotoNode(p.WhenFalse, this.StateWhenFalse, nodeBelievedReachable);
                        break;

                    case BoundDagValueTest t:
                        Debug.Assert(t.Value != ConstantValue.Null);
                        if (inputSlot > 0)
                        {
                            learnFromNonNullTest(inputSlot, ref this.StateWhenTrue);
                        }
                        gotoNode(p.WhenTrue, this.StateWhenTrue, nodeBelievedReachable);
                        gotoNode(p.WhenFalse, this.StateWhenFalse, nodeBelievedReachable);
                        break;

                    default:
                        throw ExceptionUtilities.UnexpectedValue(test.Kind);
                    }
                    break;
                }

                case BoundLeafDecisionDagNode d:
                    // We have one leaf decision dag node per reachable label
                    labelStateMap.Add(d.Label, (this.State, nodeBelievedReachable));
                    break;

                case BoundWhenDecisionDagNode w:
                    // bind the pattern variables, inferring their types as well
                    foreach (var binding in w.Bindings)
                    {
                        var variableAccess = binding.VariableAccess;
                        var tempSource     = binding.TempContainingValue;
                        var foundTemp      = tempMap.TryGetValue(tempSource, out var tempSlotAndType);
                        Debug.Assert(foundTemp);
                        var(tempSlot, tempType) = tempSlotAndType;
                        var tempState = this.State[tempSlot];
                        if (variableAccess is BoundLocal {
                            LocalSymbol: SourceLocalSymbol {
                                IsVar: true
                            } local
                        })
                        {
                            var inferredType = TypeWithState.Create(tempType, tempState).ToTypeWithAnnotations();
                            if (_variableTypes.TryGetValue(local, out var existingType))
                            {
                                // merge inferred nullable annotation from different branches of the decision tree
                                _variableTypes[local] = TypeWithAnnotations.Create(existingType.Type, existingType.NullableAnnotation.Join(inferredType.NullableAnnotation));
                            }
                            else
                            {
                                _variableTypes[local] = inferredType;
                            }

                            int localSlot = GetOrCreateSlot(local, forceSlotEvenIfEmpty: true);
                            this.State[localSlot] = tempState;
                        }
Пример #6
0
        private bool CheckSwitchExpressionExhaustive(
            SwitchExpressionSyntax node,
            BoundExpression boundInputExpression,
            ImmutableArray <BoundSwitchExpressionArm> switchArms,
            out BoundDecisionDag decisionDag,
            out LabelSymbol defaultLabel,
            BindingDiagnosticBag diagnostics)
        {
            defaultLabel = new GeneratedLabelSymbol("default");
            decisionDag  = DecisionDagBuilder.CreateDecisionDagForSwitchExpression(this.Compilation, node, boundInputExpression, switchArms, defaultLabel, diagnostics);
            var  reachableLabels = decisionDag.ReachableLabels;
            bool hasErrors       = false;

            foreach (BoundSwitchExpressionArm arm in switchArms)
            {
                hasErrors |= arm.HasErrors;
                if (!hasErrors && !reachableLabels.Contains(arm.Label))
                {
                    diagnostics.Add(ErrorCode.ERR_SwitchArmSubsumed, arm.Pattern.Syntax.Location);
                }
            }

            if (!reachableLabels.Contains(defaultLabel))
            {
                // switch expression is exhaustive; no default label needed.
                defaultLabel = null;
                return(false);
            }

            if (hasErrors)
            {
                return(true);
            }

            // We only report exhaustive warnings when the default label is reachable through some series of
            // tests that do not include a test in which the value is known to be null.  Handling paths with
            // nulls is the job of the nullable walker.
            bool wasAcyclic = TopologicalSort.TryIterativeSort <BoundDecisionDagNode>(new[] { decisionDag.RootNode }, nonNullSuccessors, out var nodes);

            // Since decisionDag.RootNode is acyclic by construction, its subset of nodes sorted here cannot be cyclic
            Debug.Assert(wasAcyclic);
            foreach (var n in nodes)
            {
                if (n is BoundLeafDecisionDagNode leaf && leaf.Label == defaultLabel)
                {
                    var samplePattern = PatternExplainer.SamplePatternForPathToDagNode(
                        BoundDagTemp.ForOriginalInput(boundInputExpression), nodes, n, nullPaths: false, out bool requiresFalseWhenClause, out bool unnamedEnumValue);
                    ErrorCode warningCode =
                        requiresFalseWhenClause ? ErrorCode.WRN_SwitchExpressionNotExhaustiveWithWhen :
                        unnamedEnumValue ? ErrorCode.WRN_SwitchExpressionNotExhaustiveWithUnnamedEnumValue :
                        ErrorCode.WRN_SwitchExpressionNotExhaustive;
                    diagnostics.Add(
                        warningCode,
                        node.SwitchKeyword.GetLocation(),
                        samplePattern);
                    return(true);
                }
            }

            return(false);

            ImmutableArray <BoundDecisionDagNode> nonNullSuccessors(BoundDecisionDagNode n)
            {
                switch (n)
                {
                case BoundTestDecisionDagNode p:
                    switch (p.Test)
                    {
                    case BoundDagNonNullTest t:         // checks that the input is not null
                        return(ImmutableArray.Create(p.WhenTrue));

                    case BoundDagExplicitNullTest t:         // checks that the input is null
                        return(ImmutableArray.Create(p.WhenFalse));

                    default:
                        return(BoundDecisionDag.Successors(n));
                    }

                default:
                    return(BoundDecisionDag.Successors(n));
                }
            }
        }