/// <summary>
/// Rewrite an async method into a state machine type.
/// </summary>
internal static BoundStatement Rewrite(
BoundStatement body,
MethodSymbol method,
int methodOrdinal,
VariableSlotAllocator slotAllocatorOpt,
TypeCompilationState compilationState,
DiagnosticBag diagnostics,
out AsyncStateMachine stateMachineType)
{
if (!method.IsAsync)
{
stateMachineType = null;
return body;
}
// The CLR doesn't support adding fields to structs, so in order to enable EnC in an async method we need to generate a class.
var typeKind = compilationState.Compilation.Options.EnableEditAndContinue ? TypeKind.Class : TypeKind.Struct;
var bodyWithAwaitLifted = AwaitExpressionSpiller.Rewrite(body, method, compilationState, diagnostics);
stateMachineType = new AsyncStateMachine(slotAllocatorOpt, compilationState, method, methodOrdinal, typeKind);
compilationState.ModuleBuilderOpt.CompilationState.SetStateMachineType(method, stateMachineType);
var rewriter = new AsyncRewriter(bodyWithAwaitLifted, method, methodOrdinal, stateMachineType, slotAllocatorOpt, compilationState, diagnostics);
if (!rewriter.VerifyPresenceOfRequiredAPIs())
{
return body;
}
return rewriter.Rewrite();
}
internal static BoundStatement AddSequencePoint(BlockSyntax blockSyntax, BoundStatement rewrittenStatement, bool isPrimaryCtor)
{
TextSpan span;
if (isPrimaryCtor)
{
// For a primary constructor block: ... [|{|] ... }
return new BoundSequencePointWithSpan(blockSyntax, rewrittenStatement, blockSyntax.OpenBraceToken.Span);
}
var parent = blockSyntax.Parent as ConstructorDeclarationSyntax;
if (parent != null)
{
span = CreateSpanForConstructorDeclaration(parent);
}
else
{
// This inserts a sequence points to any prologue code for method declarations.
var start = blockSyntax.Parent.SpanStart;
var end = blockSyntax.OpenBraceToken.GetPreviousToken().Span.End;
span = TextSpan.FromBounds(start, end);
}
return new BoundSequencePointWithSpan(blockSyntax, rewrittenStatement, span);
}
/// <summary>
/// Rewrite an async method into a state machine class.
/// </summary>
/// <param name="body">The original body of the method</param>
/// <param name="method">The method's identity</param>
/// <param name="compilationState">The collection of generated methods that result from this transformation and which must be emitted</param>
/// <param name="diagnostics">Diagnostic bag for diagnostics.</param>
/// <param name="generateDebugInfo"></param>
/// <param name="stateMachineType"></param>
internal static BoundStatement Rewrite(
BoundStatement body,
MethodSymbol method,
TypeCompilationState compilationState,
DiagnosticBag diagnostics,
bool generateDebugInfo,
out AsyncStateMachine stateMachineType)
{
if (!method.IsAsync)
{
stateMachineType = null;
return body;
}
// The CLR doesn't support adding fields to structs, so in order to enable EnC in an async method we need to generate a class.
var typeKind = compilationState.Compilation.Options.EnableEditAndContinue ? TypeKind.Class : TypeKind.Struct;
var bodyWithAwaitLifted = AwaitLiftingRewriter.Rewrite(body, method, compilationState, diagnostics);
stateMachineType = new AsyncStateMachine(method, typeKind);
compilationState.ModuleBuilderOpt.CompilationState.SetStateMachineType(method, stateMachineType);
var rewriter = new AsyncRewriter(bodyWithAwaitLifted, method, stateMachineType, compilationState, diagnostics, generateDebugInfo);
if (!rewriter.constructedSuccessfully)
{
return body;
}
return rewriter.Rewrite();
}
/// <summary>
/// Rewrite an iterator method into a state machine class.
/// </summary>
/// <param name="body">The original body of the method</param>
/// <param name="method">The method's identity</param>
/// <param name="compilationState">The collection of generated methods that result from this transformation and which must be emitted</param>
/// <param name="diagnostics">Diagnostic bag for diagnostics.</param>
/// <param name="generateDebugInfo"></param>
internal static BoundStatement Rewrite(
BoundStatement body,
MethodSymbol method,
TypeCompilationState compilationState,
DiagnosticBag diagnostics,
bool generateDebugInfo)
{
TypeSymbol elementType = method.IteratorElementType;
if ((object)elementType == null)
{
return body;
}
// Figure out what kind of iterator we are generating.
bool isEnumerable;
switch (method.ReturnType.OriginalDefinition.SpecialType)
{
case SpecialType.System_Collections_IEnumerable:
case SpecialType.System_Collections_Generic_IEnumerable_T:
isEnumerable = true;
break;
case SpecialType.System_Collections_IEnumerator:
case SpecialType.System_Collections_Generic_IEnumerator_T:
isEnumerable = false;
break;
default:
throw ExceptionUtilities.UnexpectedValue(method.ReturnType.OriginalDefinition.SpecialType);
}
var iteratorClass = new IteratorStateMachine(method, isEnumerable, elementType, compilationState);
return new IteratorRewriter(body, method, isEnumerable, iteratorClass, compilationState, diagnostics, generateDebugInfo).Rewrite();
}
// insert the implicit "return" statement at the end of the method body
// Normally, we wouldn't bother attaching syntax trees to compiler-generated nodes, but these
// ones are going to have sequence points.
internal static BoundBlock AppendImplicitReturn(BoundStatement node, MethodSymbol method = null, CSharpSyntaxNode syntax = null)
{
if (syntax == null)
{
syntax = node.Syntax;
}
BoundStatement ret =
(object)method != null && (object)method.IteratorElementType != null
? BoundYieldBreakStatement.Synthesized(syntax) as BoundStatement
: BoundReturnStatement.Synthesized(syntax, null);
if (syntax.Kind == SyntaxKind.Block)
{
var blockSyntax = (BlockSyntax)syntax;
ret = new BoundSequencePointWithSpan(
blockSyntax,
ret,
blockSyntax.CloseBraceToken.Span)
{ WasCompilerGenerated = true };
}
switch (node.Kind)
{
case BoundKind.Block:
var block = (BoundBlock)node;
return block.Update(block.LocalsOpt, block.Statements.Add(ret));
default:
return new BoundBlock(syntax, ImmutableArray<LocalSymbol>.Empty, ImmutableArray.Create(ret, node));
}
}
protected StateMachineRewriter(
BoundStatement body,
MethodSymbol method,
SynthesizedContainer stateMachineType,
VariableSlotAllocator slotAllocatorOpt,
TypeCompilationState compilationState,
DiagnosticBag diagnostics)
{
Debug.Assert(body != null);
Debug.Assert(method != null);
Debug.Assert(stateMachineType != null);
Debug.Assert(compilationState != null);
Debug.Assert(diagnostics != null);
this.body = body;
this.method = method;
this.stateMachineType = stateMachineType;
this.slotAllocatorOpt = slotAllocatorOpt;
this.synthesizedLocalOrdinals = new SynthesizedLocalOrdinalsDispenser();
this.diagnostics = diagnostics;
this.F = new SyntheticBoundNodeFactory(method, body.Syntax, compilationState, diagnostics);
Debug.Assert(F.CurrentType == method.ContainingType);
Debug.Assert(F.Syntax == body.Syntax);
}
/// <summary>
/// Is there any code to execute in the given statement that could have side-effects,
/// such as throwing an exception? This implementation is conservative, in the sense
/// that it may return true when the statement actually may have no side effects.
/// </summary>
private static bool HasSideEffects(BoundStatement statement)
{
if (statement == null) return false;
switch (statement.Kind)
{
case BoundKind.NoOpStatement:
return true;
case BoundKind.Block:
{
var block = (BoundBlock)statement;
foreach (var stmt in block.Statements)
{
if (HasSideEffects(stmt)) return true;
}
return false;
}
case BoundKind.SequencePoint:
{
var sequence = (BoundSequencePoint)statement;
return HasSideEffects(sequence.StatementOpt);
}
case BoundKind.SequencePointWithSpan:
{
var sequence = (BoundSequencePointWithSpan)statement;
return HasSideEffects(sequence.StatementOpt);
}
default:
return true;
}
}
internal static BoundStatement AddSequencePoint(UsingStatementSyntax usingSyntax, BoundStatement rewrittenStatement)
{
int start = usingSyntax.Span.Start;
int end = usingSyntax.CloseParenToken.Span.End;
TextSpan span = TextSpan.FromBounds(start, end);
return new BoundSequencePointWithSpan(usingSyntax, rewrittenStatement, span);
}
public static DynamicAnalysisInjector TryCreate(MethodSymbol method, BoundStatement methodBody, SyntheticBoundNodeFactory methodBodyFactory, DiagnosticBag diagnostics, DebugDocumentProvider debugDocumentProvider, Instrumenter previous)
{
// Do not instrument implicitly-declared methods, except for constructors.
// Instrument implicit constructors in order to instrument member initializers.
if (method.IsImplicitlyDeclared && !method.IsImplicitConstructor)
{
return null;
}
// Do not instrument methods marked with or in scope of ExcludeFromCodeCoverageAttribute.
if (IsExcludedFromCodeCoverage(method))
{
return null;
}
MethodSymbol createPayload = GetCreatePayload(methodBodyFactory.Compilation, methodBody.Syntax, diagnostics);
// Do not instrument any methods if CreatePayload is not present.
if ((object)createPayload == null)
{
return null;
}
// Do not instrument CreatePayload if it is part of the current compilation (which occurs only during testing).
// CreatePayload will fail at run time with an infinite recursion if it is instrumented.
if (method.Equals(createPayload))
{
return null;
}
return new DynamicAnalysisInjector(method, methodBody, methodBodyFactory, createPayload, diagnostics, debugDocumentProvider, previous);
}
private BoundStatement RewriteWhileStatement(
BoundLoopStatement loop,
BoundExpression rewrittenCondition,
BoundStatement rewrittenBody,
GeneratedLabelSymbol breakLabel,
GeneratedLabelSymbol continueLabel,
bool hasErrors)
{
Debug.Assert(loop.Kind == BoundKind.WhileStatement || loop.Kind == BoundKind.ForEachStatement);
// while (condition)
// body;
//
// becomes
//
// goto continue;
// start:
// {
// body
// continue:
// GotoIfTrue condition start;
// }
// break:
SyntaxNode syntax = loop.Syntax;
var startLabel = new GeneratedLabelSymbol("start");
BoundStatement ifConditionGotoStart = new BoundConditionalGoto(rewrittenCondition.Syntax, rewrittenCondition, true, startLabel);
BoundStatement gotoContinue = new BoundGotoStatement(syntax, continueLabel);
if (this.Instrument && !loop.WasCompilerGenerated)
{
switch (loop.Kind)
{
case BoundKind.WhileStatement:
ifConditionGotoStart = _instrumenter.InstrumentWhileStatementConditionalGotoStartOrBreak((BoundWhileStatement)loop, ifConditionGotoStart);
break;
case BoundKind.ForEachStatement:
ifConditionGotoStart = _instrumenter.InstrumentForEachStatementConditionalGotoStart((BoundForEachStatement)loop, ifConditionGotoStart);
break;
default:
throw ExceptionUtilities.UnexpectedValue(loop.Kind);
}
// mark the initial jump as hidden. We do it to tell that this is not a part of previous statement. This
// jump may be a target of another jump (for example if loops are nested) and that would give the
// impression that the previous statement is being re-executed.
gotoContinue = new BoundSequencePoint(null, gotoContinue);
}
return BoundStatementList.Synthesized(syntax, hasErrors,
gotoContinue,
new BoundLabelStatement(syntax, startLabel),
rewrittenBody,
new BoundLabelStatement(syntax, continueLabel),
ifConditionGotoStart,
new BoundLabelStatement(syntax, breakLabel));
}
private static BoundStatement RewriteIfStatement(
CSharpSyntaxNode syntax,
ImmutableArray<LocalSymbol> locals,
BoundExpression rewrittenCondition,
BoundStatement rewrittenConsequence,
BoundStatement rewrittenAlternativeOpt,
bool hasErrors)
{
var afterif = new GeneratedLabelSymbol("afterif");
var builder = ArrayBuilder<BoundStatement>.GetInstance();
if (rewrittenAlternativeOpt == null)
{
// if (condition)
// consequence;
//
// becomes
//
// GotoIfFalse condition afterif;
// consequence;
// afterif:
builder.Add(new BoundConditionalGoto(rewrittenCondition.Syntax, rewrittenCondition, false, afterif));
builder.Add(rewrittenConsequence);
}
else
{
// if (condition)
// consequence;
// else
// alternative
//
// becomes
//
// GotoIfFalse condition alt;
// consequence
// goto afterif;
// alt:
// alternative;
// afterif:
var alt = new GeneratedLabelSymbol("alternative");
builder.Add(new BoundConditionalGoto(rewrittenCondition.Syntax, rewrittenCondition, false, alt));
builder.Add(rewrittenConsequence);
builder.Add(new BoundGotoStatement(syntax, afterif));
builder.Add(new BoundLabelStatement(syntax, alt));
builder.Add(rewrittenAlternativeOpt);
}
builder.Add(new BoundLabelStatement(syntax, afterif));
if (!locals.IsDefaultOrEmpty)
{
return new BoundBlock(syntax, locals, builder.ToImmutableAndFree(), hasErrors);
}
return new BoundStatementList(syntax, builder.ToImmutableAndFree(), hasErrors);
}
internal static BoundStatement AddSequencePoint(VariableDeclaratorSyntax declaratorSyntax, BoundStatement rewrittenStatement)
{
SyntaxNode node;
TextSpan? part;
GetBreakpointSpan(declaratorSyntax, out node, out part);
var result = BoundSequencePoint.Create(declaratorSyntax, part, rewrittenStatement);
result.WasCompilerGenerated = rewrittenStatement.WasCompilerGenerated;
return result;
}
internal MethodWithBody(MethodSymbol method, BoundStatement body, ImportChain importChainOpt)
{
Debug.Assert(method != null);
Debug.Assert(body != null);
this.Method = method;
this.Body = body;
this.ImportChainOpt = importChainOpt;
}
private static BoundStatement RewriteIfStatement(
CSharpSyntaxNode syntax,
BoundExpression rewrittenCondition,
BoundStatement rewrittenConsequence,
BoundStatement rewrittenAlternativeOpt,
bool hasErrors)
{
return RewriteIfStatement(syntax, ImmutableArray<LocalSymbol>.Empty, rewrittenCondition, rewrittenConsequence, rewrittenAlternativeOpt, hasErrors);
}
public override BoundNode VisitFixedStatement(BoundFixedStatement node)
{
int numFixedLocals = node.Locals.Length;
var localBuilder = ArrayBuilder<LocalSymbol>.GetInstance(numFixedLocals);
localBuilder.AddRange(node.Locals);
var statementBuilder = ArrayBuilder<BoundStatement>.GetInstance(numFixedLocals + 1 + 1); //+1 for body, +1 for hidden seq point
var cleanup = new BoundStatement[numFixedLocals];
ImmutableArray<BoundLocalDeclaration> localDecls = node.Declarations.LocalDeclarations;
Debug.Assert(localDecls.Length == numFixedLocals);
for (int i = 0; i < numFixedLocals; i++)
{
BoundLocalDeclaration localDecl = localDecls[i];
LocalSymbol temp;
LocalSymbol localToClear;
statementBuilder.Add(InitializeFixedStatementLocal(localDecl, factory, out temp, out localToClear));
if (!ReferenceEquals(temp, null))
{
localBuilder.Add(temp);
}
// NOTE: Dev10 nulls out the locals in declaration order (as opposed to "popping" them in reverse order).
cleanup[i] = factory.Assignment(factory.Local(localToClear), factory.Null(localToClear.Type));
}
BoundStatement rewrittenBody = VisitStatement(node.Body);
statementBuilder.Add(rewrittenBody);
statementBuilder.Add(factory.HiddenSequencePoint());
Debug.Assert(statementBuilder.Count == numFixedLocals + 1 + 1);
// In principle, the cleanup code (i.e. nulling out the pinned variables) is always
// in a finally block. However, we can optimize finally away (keeping the cleanup
// code) in cases where both of the following are true:
// 1) there are no branches out of the fixed statement; and
// 2) the fixed statement is not in a try block (syntactic or synthesized).
if (IsInTryBlock(node) || HasGotoOut(rewrittenBody))
{
return factory.Block(
localBuilder.ToImmutableAndFree(),
new BoundTryStatement(
factory.Syntax,
factory.Block(statementBuilder.ToImmutableAndFree()),
ImmutableArray<BoundCatchBlock>.Empty,
factory.Block(cleanup)));
}
else
{
statementBuilder.AddRange(cleanup);
return factory.Block(localBuilder.ToImmutableAndFree(), statementBuilder.ToImmutableAndFree());
}
}
protected override void ResolveBranch(PendingBranch pending, LabelSymbol label, BoundStatement target, ref bool labelStateChanged)
{
// branches into a region are considered entry points
if (IsInside && pending.Branch != null && !RegionContains(pending.Branch.Syntax.Span))
{
pending.State = pending.State.Reachable ? ReachableState() : UnreachableState();
}
base.ResolveBranch(pending, label, target, ref labelStateChanged);
}
internal static BoundStatement AddSequencePoint(PropertyDeclarationSyntax declarationSyntax, BoundStatement rewrittenStatement)
{
Debug.Assert(declarationSyntax.Initializer != null);
int start = declarationSyntax.Initializer.Value.SpanStart;
int end = declarationSyntax.Initializer.Span.End;
TextSpan part = TextSpan.FromBounds(start, end);
var result = BoundSequencePoint.Create(declarationSyntax, part, rewrittenStatement);
result.WasCompilerGenerated = rewrittenStatement.WasCompilerGenerated;
return result;
}
public static BoundStatement Create(CSharpSyntaxNode syntax, TextSpan? part, BoundStatement statement, bool hasErrors = false)
{
if (part.HasValue)
{
return new BoundSequencePointWithSpan(syntax, statement, part.Value, hasErrors);
}
else
{
return new BoundSequencePoint(syntax, statement, hasErrors);
}
}
private BoundStatement AddLocalDeclarationSequencePointIfNecessary(CSharpSyntaxNode syntax, LocalSymbol localSymbol, BoundStatement rewrittenLocalDeclaration, bool wasCompilerGenerated = false)
{
// Add sequence points, if necessary.
if (this.GenerateDebugInfo && !wasCompilerGenerated && !localSymbol.IsConst && syntax.Kind() == SyntaxKind.VariableDeclarator)
{
Debug.Assert(syntax.SyntaxTree != null);
rewrittenLocalDeclaration = AddSequencePoint((VariableDeclaratorSyntax)syntax, rewrittenLocalDeclaration);
}
return rewrittenLocalDeclaration;
}
protected override void NoteBranch(
PendingBranch pending,
BoundNode gotoStmt,
BoundStatement targetStmt)
{
targetStmt.AssertIsLabeledStatement();
if (!gotoStmt.WasCompilerGenerated && !targetStmt.WasCompilerGenerated && !RegionContains(gotoStmt.Syntax.Span) && RegionContains(targetStmt.Syntax.Span))
{
pending.State = ResetState(pending.State);
}
base.NoteBranch(pending, gotoStmt, targetStmt);
}
private BoundStatement InstrumentLocalDeclarationIfNecessary(BoundLocalDeclaration originalOpt, LocalSymbol localSymbol, BoundStatement rewrittenLocalDeclaration)
{
// Add sequence points, if necessary.
if (this.Instrument && originalOpt?.WasCompilerGenerated == false && !localSymbol.IsConst &&
(originalOpt.Syntax.Kind() == SyntaxKind.VariableDeclarator ||
(originalOpt.Syntax.Kind() == SyntaxKind.LocalDeclarationStatement &&
((LocalDeclarationStatementSyntax)originalOpt.Syntax).Declaration.Variables.Count == 1)))
{
rewrittenLocalDeclaration = _instrumenter.InstrumentLocalInitialization(originalOpt, rewrittenLocalDeclaration);
}
return rewrittenLocalDeclaration;
}
private IteratorRewriter(
BoundStatement body,
MethodSymbol method,
bool isEnumerable,
IteratorStateMachine iteratorClass,
TypeCompilationState compilationState,
DiagnosticBag diagnostics)
: base(body, method, iteratorClass, compilationState, diagnostics)
{
// the element type may contain method type parameters, which are now alpha-renamed into type parameters of the generated class
this.elementType = iteratorClass.ElementType;
this.isEnumerable = isEnumerable;
}
private AsyncRewriter(
BoundStatement body,
MethodSymbol method,
int methodOrdinal,
AsyncStateMachine stateMachineType,
VariableSlotAllocator slotAllocatorOpt,
TypeCompilationState compilationState,
DiagnosticBag diagnostics)
: base(body, method, stateMachineType, slotAllocatorOpt, compilationState, diagnostics)
{
_constructedSuccessfully = AsyncMethodBuilderMemberCollection.TryCreate(F, method, this.stateMachineType.TypeMap, out _asyncMethodBuilderMemberCollection);
_methodOrdinal = methodOrdinal;
_ignoreAccessibility = compilationState.ModuleBuilderOpt.IgnoreAccessibility;
}
internal static ImmutableArray<BoundStatement> ConstructScriptConstructorBody(
BoundStatement loweredBody,
MethodSymbol constructor,
SynthesizedSubmissionFields previousSubmissionFields,
CSharpCompilation compilation)
{
// Script field initializers have to be emitted after the call to the base constructor because they can refer to "this" instance.
//
// Unlike regular field initializers, initializers of global script variables can access "this" instance.
// If the base class had a constructor that initializes its state a global variable would access partially initialized object.
// For this reason Script class must always derive directly from a class that has no state (System.Object).
CSharpSyntaxNode syntax = loweredBody.Syntax;
// base constructor call:
Debug.Assert((object)constructor.ContainingType.BaseTypeNoUseSiteDiagnostics == null || constructor.ContainingType.BaseTypeNoUseSiteDiagnostics.SpecialType == SpecialType.System_Object);
var objectType = constructor.ContainingAssembly.GetSpecialType(SpecialType.System_Object);
BoundExpression receiver = new BoundThisReference(syntax, constructor.ContainingType) { WasCompilerGenerated = true };
BoundStatement baseConstructorCall =
new BoundExpressionStatement(syntax,
new BoundCall(syntax,
receiverOpt: receiver,
method: objectType.InstanceConstructors[0],
arguments: ImmutableArray<BoundExpression>.Empty,
argumentNamesOpt: ImmutableArray<string>.Empty,
argumentRefKindsOpt: ImmutableArray<RefKind>.Empty,
isDelegateCall: false,
expanded: false,
invokedAsExtensionMethod: false,
argsToParamsOpt: ImmutableArray<int>.Empty,
resultKind: LookupResultKind.Viable,
type: objectType)
{ WasCompilerGenerated = true })
{ WasCompilerGenerated = true };
var statements = ArrayBuilder<BoundStatement>.GetInstance();
statements.Add(baseConstructorCall);
if (constructor.IsSubmissionConstructor)
{
// submission initialization:
MakeSubmissionInitialization(statements, syntax, constructor, previousSubmissionFields, compilation);
}
statements.Add(loweredBody);
return statements.ToImmutableAndFree();
}
private static BoundStatement RewriteIfStatement(
CSharpSyntaxNode syntax,
BoundExpression rewrittenCondition,
BoundStatement rewrittenConsequence,
BoundStatement rewrittenAlternativeOpt,
bool hasErrors)
{
var afterif = new GeneratedLabelSymbol("afterif");
// if (condition)
// consequence;
//
// becomes
//
// GotoIfFalse condition afterif;
// consequence;
// afterif:
if (rewrittenAlternativeOpt == null)
{
return BoundStatementList.Synthesized(syntax,
new BoundConditionalGoto(rewrittenCondition.Syntax, rewrittenCondition, false, afterif),
rewrittenConsequence,
new BoundLabelStatement(syntax, afterif));
}
// if (condition)
// consequence;
// else
// alternative
//
// becomes
//
// GotoIfFalse condition alt;
// consequence
// goto afterif;
// alt:
// alternative;
// afterif:
var alt = new GeneratedLabelSymbol("alternative");
return BoundStatementList.Synthesized(syntax, hasErrors,
new BoundConditionalGoto(rewrittenCondition.Syntax, rewrittenCondition, false, alt),
rewrittenConsequence,
new BoundGotoStatement(syntax, afterif),
new BoundLabelStatement(syntax, alt),
rewrittenAlternativeOpt,
new BoundLabelStatement(syntax, afterif));
}
private IteratorRewriter(
BoundStatement body,
MethodSymbol method,
bool isEnumerable,
IteratorStateMachine stateMachineType,
VariableSlotAllocator slotAllocatorOpt,
TypeCompilationState compilationState,
DiagnosticBag diagnostics)
: base(body, method, stateMachineType, slotAllocatorOpt, compilationState, diagnostics)
{
// the element type may contain method type parameters, which are now alpha-renamed into type parameters of the generated class
_elementType = stateMachineType.ElementType;
_isEnumerable = isEnumerable;
}
private BoundStatement RewriteWhileStatement(
CSharpSyntaxNode syntax,
BoundExpression rewrittenCondition,
TextSpan conditionSequencePointSpan,
BoundStatement rewrittenBody,
GeneratedLabelSymbol breakLabel,
GeneratedLabelSymbol continueLabel,
bool hasErrors)
{
var startLabel = new GeneratedLabelSymbol("start");
BoundStatement ifConditionGotoStart = new BoundConditionalGoto(rewrittenCondition.Syntax, rewrittenCondition, true, startLabel);
if (this.GenerateDebugInfo)
{
ifConditionGotoStart = new BoundSequencePointWithSpan(syntax, ifConditionGotoStart, conditionSequencePointSpan);
}
// while (condition)
// body;
//
// becomes
//
// goto continue;
// start:
// {
// body
// continue:
// GotoIfTrue condition start;
// }
// break:
BoundStatement gotoContinue = new BoundGotoStatement(syntax, continueLabel);
if (this.GenerateDebugInfo)
{
// mark the initial jump as hidden. We do it to tell that this is not a part of previous statement. This
// jump may be a target of another jump (for example if loops are nested) and that would give the
// impression that the previous statement is being re-executed.
gotoContinue = new BoundSequencePoint(null, gotoContinue);
}
return BoundStatementList.Synthesized(syntax, hasErrors,
gotoContinue,
new BoundLabelStatement(syntax, startLabel),
rewrittenBody,
new BoundLabelStatement(syntax, continueLabel),
ifConditionGotoStart,
new BoundLabelStatement(syntax, breakLabel));
}
protected StateMachineRewriter(
BoundStatement body,
MethodSymbol method,
SynthesizedContainer stateMachineClass,
TypeCompilationState compilationState,
DiagnosticBag diagnostics)
{
this.body = body;
this.method = method;
this.stateMachineClass = stateMachineClass;
this.compilationState = compilationState;
this.diagnostics = diagnostics;
this.F = new SyntheticBoundNodeFactory(method, body.Syntax, compilationState, diagnostics);
Debug.Assert(F.CurrentClass == method.ContainingType);
Debug.Assert(F.Syntax == body.Syntax);
}
private DynamicAnalysisInjector(MethodSymbol method, BoundStatement methodBody, SyntheticBoundNodeFactory methodBodyFactory, MethodSymbol createPayload, DiagnosticBag diagnostics, DebugDocumentProvider debugDocumentProvider, Instrumenter previous)
: base(previous)
{
_createPayload = createPayload;
_method = method;
_methodBody = methodBody;
_spansBuilder = ArrayBuilder<SourceSpan>.GetInstance();
TypeSymbol payloadElementType = methodBodyFactory.SpecialType(SpecialType.System_Boolean);
_payloadType = ArrayTypeSymbol.CreateCSharpArray(methodBodyFactory.Compilation.Assembly, payloadElementType);
_methodPayload = methodBodyFactory.SynthesizedLocal(_payloadType, kind: SynthesizedLocalKind.InstrumentationPayload, syntax: methodBody.Syntax);
_diagnostics = diagnostics;
_debugDocumentProvider = debugDocumentProvider;
_methodHasExplicitBlock = MethodHasExplicitBlock(method);
_methodBodyFactory = methodBodyFactory;
// The first point indicates entry into the method and has the span of the method definition.
_methodEntryInstrumentation = AddAnalysisPoint(MethodDeclarationIfAvailable(methodBody.Syntax), methodBodyFactory);
}
private AsyncRewriter(
BoundStatement body,
MethodSymbol method,
AsyncStateMachine stateMachineClass,
TypeCompilationState compilationState,
DiagnosticBag diagnostics)
: base(body, method, stateMachineClass, compilationState, diagnostics)
{
try
{
constructedSuccessfully = AsyncMethodBuilderMemberCollection.TryCreate(F, method, this.stateMachineClass.TypeMap, out this.asyncMethodBuilderMemberCollection);
}
catch (SyntheticBoundNodeFactory.MissingPredefinedMember ex)
{
diagnostics.Add(ex.Diagnostic);
constructedSuccessfully = false;
}
}
public override BoundStatement InstrumentForEachStatementDeconstructionVariablesDeclaration(BoundForEachStatement original, BoundStatement iterationVarDecl)
{
return(Previous.InstrumentForEachStatementDeconstructionVariablesDeclaration(original, iterationVarDecl));
}
public override BoundNode VisitTryStatement(BoundTryStatement node)
{
var oldDispatches = _dispatches;
var oldFinalizerState = _currentFinalizerState;
var oldHasFinalizerState = _hasFinalizerState;
_dispatches = null;
_currentFinalizerState = -1;
_hasFinalizerState = false;
BoundBlock tryBlock = F.Block((BoundStatement)this.Visit(node.TryBlock));
GeneratedLabelSymbol dispatchLabel = null;
if (_dispatches != null)
{
dispatchLabel = F.GenerateLabel("tryDispatch");
if (_hasFinalizerState)
{
// cause the current finalizer state to arrive here and then "return false"
var finalizer = F.GenerateLabel("finalizer");
_dispatches.Add(finalizer, new List <int>()
{
_currentFinalizerState
});
var skipFinalizer = F.GenerateLabel("skipFinalizer");
tryBlock = F.Block(
F.HiddenSequencePoint(),
Dispatch(),
F.Goto(skipFinalizer),
F.Label(finalizer), // code for the finalizer here
GenerateSetBothStates(StateMachineStates.NotStartedStateMachine),
GenerateReturn(false),
F.Label(skipFinalizer),
tryBlock);
}
else
{
tryBlock = F.Block(
F.HiddenSequencePoint(),
Dispatch(),
tryBlock);
}
if (oldDispatches == null)
{
Debug.Assert(!oldHasFinalizerState);
oldDispatches = new Dictionary <LabelSymbol, List <int> >();
}
oldDispatches.Add(dispatchLabel, new List <int>(from kv in _dispatches.Values from n in kv orderby n select n));
}
_hasFinalizerState = oldHasFinalizerState;
_currentFinalizerState = oldFinalizerState;
_dispatches = oldDispatches;
ImmutableArray <BoundCatchBlock> catchBlocks = this.VisitList(node.CatchBlocks);
BoundBlock finallyBlockOpt = node.FinallyBlockOpt == null ? null : F.Block(
F.HiddenSequencePoint(),
F.If(
condition: ShouldEnterFinallyBlock(),
thenClause: VisitFinally(node.FinallyBlockOpt)
),
F.HiddenSequencePoint());
BoundStatement result = node.Update(tryBlock, catchBlocks, finallyBlockOpt, node.FinallyLabelOpt, node.PreferFaultHandler);
if ((object)dispatchLabel != null)
{
result = F.Block(
F.HiddenSequencePoint(),
F.Label(dispatchLabel),
result);
}
return(result);
}
public override BoundNode VisitFixedStatement(BoundFixedStatement node)
{
ImmutableArray <BoundLocalDeclaration> localDecls = node.Declarations.LocalDeclarations;
int numFixedLocals = localDecls.Length;
var localBuilder = ArrayBuilder <LocalSymbol> .GetInstance(node.Locals.Length);
localBuilder.AddRange(node.Locals);
var statementBuilder = ArrayBuilder <BoundStatement> .GetInstance(numFixedLocals + 1 + 1); //+1 for body, +1 for hidden seq point
var cleanup = new BoundStatement[numFixedLocals];
for (int i = 0; i < numFixedLocals; i++)
{
BoundLocalDeclaration localDecl = localDecls[i];
LocalSymbol pinnedTemp;
statementBuilder.Add(InitializeFixedStatementLocal(localDecl, _factory, out pinnedTemp));
localBuilder.Add(pinnedTemp);
// NOTE: Dev10 nulls out the locals in declaration order (as opposed to "popping" them in reverse order).
if (pinnedTemp.RefKind == RefKind.None)
{
// temp = null;
cleanup[i] = _factory.Assignment(_factory.Local(pinnedTemp), _factory.Null(pinnedTemp.Type));
}
else
{
Debug.Assert(!pinnedTemp.Type.IsManagedType);
// temp = ref *default(T*);
cleanup[i] = _factory.Assignment(_factory.Local(pinnedTemp), new BoundPointerIndirectionOperator(
_factory.Syntax,
_factory.Default(new PointerTypeSymbol(pinnedTemp.Type)),
pinnedTemp.Type),
refKind: RefKind.Ref);
}
}
BoundStatement rewrittenBody = VisitStatement(node.Body);
statementBuilder.Add(rewrittenBody);
statementBuilder.Add(_factory.HiddenSequencePoint());
Debug.Assert(statementBuilder.Count == numFixedLocals + 1 + 1);
// In principle, the cleanup code (i.e. nulling out the pinned variables) is always
// in a finally block. However, we can optimize finally away (keeping the cleanup
// code) in cases where both of the following are true:
// 1) there are no branches out of the fixed statement; and
// 2) the fixed statement is not in a try block (syntactic or synthesized).
if (IsInTryBlock(node) || HasGotoOut(rewrittenBody))
{
return(_factory.Block(
localBuilder.ToImmutableAndFree(),
new BoundTryStatement(
_factory.Syntax,
_factory.Block(statementBuilder.ToImmutableAndFree()),
ImmutableArray <BoundCatchBlock> .Empty,
_factory.Block(cleanup))));
}
else
{
statementBuilder.AddRange(cleanup);
return(_factory.Block(localBuilder.ToImmutableAndFree(), statementBuilder.ToImmutableAndFree()));
}
}
/// <summary>
/// fixed(int* ptr = arr){ ... } == becomes ===>
///
/// pinned int[] pinnedTemp = arr; // pinning managed ref
/// int* ptr = pinnedTemp != null && pinnedTemp.Length != 0
/// (int*)&pinnedTemp[0]: // unsafe cast to unmanaged ptr
/// 0;
/// . . .
/// </summary>
private BoundStatement InitializeFixedStatementArrayLocal(
BoundLocalDeclaration localDecl,
LocalSymbol localSymbol,
BoundFixedLocalCollectionInitializer fixedInitializer,
SyntheticBoundNodeFactory factory,
out LocalSymbol pinnedTemp)
{
TypeSymbol localType = localSymbol.Type;
BoundExpression initializerExpr = VisitExpression(fixedInitializer.Expression);
TypeSymbol initializerType = initializerExpr.Type;
pinnedTemp = factory.SynthesizedLocal(initializerType, isPinned: true);
ArrayTypeSymbol arrayType = (ArrayTypeSymbol)pinnedTemp.Type;
TypeSymbol arrayElementType = arrayType.ElementType;
// NOTE: we pin the array, not the pointer.
Debug.Assert(pinnedTemp.IsPinned);
Debug.Assert(!localSymbol.IsPinned);
//(pinnedTemp = array)
BoundExpression arrayTempInit = factory.AssignmentExpression(factory.Local(pinnedTemp), initializerExpr);
//(pinnedTemp = array) != null
BoundExpression notNullCheck = MakeNullCheck(factory.Syntax, arrayTempInit, BinaryOperatorKind.NotEqual);
BoundExpression lengthCall;
if (arrayType.IsSZArray)
{
lengthCall = factory.ArrayLength(factory.Local(pinnedTemp));
}
else
{
MethodSymbol lengthMethod;
if (TryGetWellKnownTypeMember(fixedInitializer.Syntax, WellKnownMember.System_Array__get_Length, out lengthMethod))
{
lengthCall = factory.Call(factory.Local(pinnedTemp), lengthMethod);
}
else
{
lengthCall = new BoundBadExpression(fixedInitializer.Syntax, LookupResultKind.NotInvocable, ImmutableArray <Symbol> .Empty, ImmutableArray.Create <BoundExpression>(factory.Local(pinnedTemp)), ErrorTypeSymbol.UnknownResultType);
}
}
// NOTE: dev10 comment says ">", but code actually checks "!="
//temp.Length != 0
BoundExpression lengthCheck = factory.Binary(BinaryOperatorKind.IntNotEqual, factory.SpecialType(SpecialType.System_Boolean), lengthCall, factory.Literal(0));
//((temp = array) != null && temp.Length != 0)
BoundExpression condition = factory.Binary(BinaryOperatorKind.LogicalBoolAnd, factory.SpecialType(SpecialType.System_Boolean), notNullCheck, lengthCheck);
//temp[0]
BoundExpression firstElement = factory.ArrayAccessFirstElement(factory.Local(pinnedTemp));
// NOTE: this is a fixed statement address-of in that it's the initial value of the pointer.
//&temp[0]
BoundExpression firstElementAddress = new BoundAddressOfOperator(factory.Syntax, firstElement, type: new PointerTypeSymbol(arrayElementType));
BoundExpression convertedFirstElementAddress = factory.Convert(
localType,
firstElementAddress,
fixedInitializer.ElementPointerTypeConversion);
//loc = &temp[0]
BoundExpression consequenceAssignment = factory.AssignmentExpression(factory.Local(localSymbol), convertedFirstElementAddress);
//loc = null
BoundExpression alternativeAssignment = factory.AssignmentExpression(factory.Local(localSymbol), factory.Null(localType));
//(((temp = array) != null && temp.Length != 0) ? loc = &temp[0] : loc = null)
BoundStatement localInit = factory.ExpressionStatement(
new BoundConditionalOperator(factory.Syntax, false, condition, consequenceAssignment, alternativeAssignment, ConstantValue.NotAvailable, localType));
return(InstrumentLocalDeclarationIfNecessary(localDecl, localSymbol, localInit));
}
public override BoundStatement CreateBlockPrologue(BoundBlock original, out LocalSymbol synthesizedLocal)
{
BoundStatement previousPrologue = base.CreateBlockPrologue(original, out synthesizedLocal);
if (_methodBody == original)
{
_dynamicAnalysisSpans = _spansBuilder.ToImmutableAndFree();
// In the future there will be multiple analysis kinds.
const int analysisKind = 0;
ArrayTypeSymbol modulePayloadType =
ArrayTypeSymbol.CreateCSharpArray(_methodBodyFactory.Compilation.Assembly, _payloadType);
// Synthesize the initialization of the instrumentation payload array, using concurrency-safe code:
//
// var payload = PID.PayloadRootField[methodIndex];
// if (payload == null)
// payload = Instrumentation.CreatePayload(mvid, methodIndex, fileIndexOrIndices, ref PID.PayloadRootField[methodIndex], payloadLength);
BoundStatement payloadInitialization =
_methodBodyFactory.Assignment(
_methodBodyFactory.Local(_methodPayload),
_methodBodyFactory.ArrayAccess(
_methodBodyFactory.InstrumentationPayloadRoot(analysisKind, modulePayloadType),
ImmutableArray.Create(_methodBodyFactory.MethodDefIndex(_method))));
BoundExpression mvid = _methodBodyFactory.ModuleVersionId();
BoundExpression methodToken = _methodBodyFactory.MethodDefIndex(_method);
BoundExpression payloadSlot =
_methodBodyFactory.ArrayAccess(
_methodBodyFactory.InstrumentationPayloadRoot(analysisKind, modulePayloadType),
ImmutableArray.Create(_methodBodyFactory.MethodDefIndex(_method)));
BoundStatement createPayloadCall =
GetCreatePayloadStatement(
_dynamicAnalysisSpans,
_methodBody.Syntax,
_methodPayload,
_createPayloadForMethodsSpanningSingleFile,
_createPayloadForMethodsSpanningMultipleFiles,
mvid,
methodToken,
payloadSlot,
_methodBodyFactory,
_debugDocumentProvider);
BoundExpression payloadNullTest =
_methodBodyFactory.Binary(
BinaryOperatorKind.ObjectEqual,
_methodBodyFactory.SpecialType(SpecialType.System_Boolean),
_methodBodyFactory.Local(_methodPayload),
_methodBodyFactory.Null(_payloadType));
BoundStatement payloadIf = _methodBodyFactory.If(payloadNullTest, createPayloadCall);
Debug.Assert(synthesizedLocal == null);
synthesizedLocal = _methodPayload;
ArrayBuilder <BoundStatement> prologueStatements = ArrayBuilder <BoundStatement> .GetInstance(previousPrologue == null? 3 : 4);
prologueStatements.Add(payloadInitialization);
prologueStatements.Add(payloadIf);
if (_methodEntryInstrumentation != null)
{
prologueStatements.Add(_methodEntryInstrumentation);
}
if (previousPrologue != null)
{
prologueStatements.Add(previousPrologue);
}
return(_methodBodyFactory.StatementList(prologueStatements.ToImmutableAndFree()));
}
return(previousPrologue);
}
public override BoundStatement InstrumentExpressionStatement(BoundExpressionStatement original, BoundStatement rewritten)
{
return(Previous.InstrumentExpressionStatement(original, rewritten));
}
public override BoundStatement InstrumentLockTargetCapture(BoundLockStatement original, BoundStatement lockTargetCapture)
{
return(AddDynamicAnalysis(original, base.InstrumentLockTargetCapture(original, lockTargetCapture)));
}
public override BoundStatement InstrumentLockTargetCapture(BoundLockStatement original, BoundStatement lockTargetCapture)
{
return(Previous.InstrumentLockTargetCapture(original, lockTargetCapture));
}
public override BoundStatement InstrumentSwitchWhenClauseConditionalGotoBody(BoundExpression original, BoundStatement ifConditionGotoBody)
{
return(Previous.InstrumentSwitchWhenClauseConditionalGotoBody(original, ifConditionGotoBody));
}
public override BoundStatement InstrumentUsingTargetCapture(BoundUsingStatement original, BoundStatement usingTargetCapture)
{
return(Previous.InstrumentUsingTargetCapture(original, usingTargetCapture));
}
public override BoundStatement InstrumentWhileStatementConditionalGotoStartOrBreak(BoundWhileStatement original, BoundStatement ifConditionGotoStart)
{
return(Previous.InstrumentWhileStatementConditionalGotoStartOrBreak(original, ifConditionGotoStart));
}
public override BoundExpression InstrumentSwitchStatementExpression(BoundStatement original, BoundExpression rewrittenExpression, SyntheticBoundNodeFactory factory)
{
return(Previous.InstrumentSwitchStatementExpression(original, rewrittenExpression, factory));
}
public override BoundStatement InstrumentDoStatementConditionalGotoStart(BoundDoStatement original, BoundStatement ifConditionGotoStart)
{
return(Previous.InstrumentDoStatementConditionalGotoStart(original, ifConditionGotoStart));
}
public override BoundStatement InstrumentWhileStatementConditionalGotoStartOrBreak(BoundWhileStatement original, BoundStatement ifConditionGotoStart)
{
return(AddDynamicAnalysis(original, base.InstrumentWhileStatementConditionalGotoStartOrBreak(original, ifConditionGotoStart)));
}
public override BoundStatement InstrumentReturnStatement(BoundReturnStatement original, BoundStatement rewritten)
{
rewritten = base.InstrumentReturnStatement(original, rewritten);
// A synthesized return statement that does not return a value never requires instrumentation.
// A property set defined without a block has such a synthesized return statement.
// A synthesized return statement that does return a value does require instrumentation.
// A method, property get, or lambda defined without a block has such a synthesized return statement.
if (ReturnsValueWithinExpressionBodiedConstruct(original))
{
// The return statement for value-returning methods defined without a block is compiler generated, but requires instrumentation.
return(CollectDynamicAnalysis(original, rewritten));
}
return(AddDynamicAnalysis(original, rewritten));
}
public override BoundStatement InstrumentYieldReturnStatement(BoundYieldReturnStatement original, BoundStatement rewritten)
{
return(AddDynamicAnalysis(original, base.InstrumentYieldReturnStatement(original, rewritten)));
}
public override BoundStatement InstrumentLocalInitialization(BoundLocalDeclaration original, BoundStatement rewritten)
{
return(AddDynamicAnalysis(original, base.InstrumentLocalInitialization(original, rewritten)));
}
public override BoundStatement InstrumentFieldOrPropertyInitializer(BoundStatement original, BoundStatement rewritten)
{
return(Previous.InstrumentFieldOrPropertyInitializer(original, rewritten));
}
public override BoundStatement InstrumentForEachStatementDeconstructionVariablesDeclaration(BoundForEachStatement original, BoundStatement iterationVarDecl)
{
return(AddDynamicAnalysis(original, base.InstrumentForEachStatementDeconstructionVariablesDeclaration(original, iterationVarDecl)));
}
public override BoundStatement InstrumentLocalInitialization(BoundLocalDeclaration original, BoundStatement rewritten)
{
return(Previous.InstrumentLocalInitialization(original, rewritten));
}
public override BoundStatement InstrumentFieldOrPropertyInitializer(BoundStatement original, BoundStatement rewritten)
{
return(AddDynamicAnalysis(original, base.InstrumentFieldOrPropertyInitializer(original, rewritten)));
}
public override BoundStatement InstrumentForEachStatementConditionalGotoStart(BoundForEachStatement original, BoundStatement branchBack)
{
return(Previous.InstrumentForEachStatementConditionalGotoStart(original, branchBack));
}
private void GenerateEnumerableImplementation(ref BoundExpression managedThreadId)
{
var IEnumerable_GetEnumerator = F.SpecialMethod(SpecialMember.System_Collections_IEnumerable__GetEnumerator);
var IEnumerableOfElementType = F.SpecialType(SpecialType.System_Collections_Generic_IEnumerable_T).Construct(elementType);
var IEnumerableOfElementType_GetEnumerator = F.SpecialMethod(SpecialMember.System_Collections_Generic_IEnumerable_T__GetEnumerator).AsMember(IEnumerableOfElementType);
// generate the code for GetEnumerator()
// .NET Core has removed the Thread class. We can the managed thread id by making a call to
// Environment.CurrentManagedThreadId. If that method is not present (pre 4.5) fall back to the old behavior.
// IEnumerable<elementType> result;
// if (this.initialThreadId == Thread.CurrentThread.ManagedThreadId && this.state == -2)
// {
// this.state = 0;
// result = this;
// }
// else
// {
// result = new Ints0_Impl(0);
// }
// result.parameter = this.parameterProxy; // copy all of the parameter proxies
// Add IEnumerator<elementType> IEnumerable<elementType>.GetEnumerator()
// The implementation doesn't depend on the method body of the iterator method.
// Only on it's parameters and staticness.
var getEnumeratorGeneric = OpenMethodImplementation(IEnumerableOfElementType_GetEnumerator, debuggerHidden: true, hasMethodBodyDependency: false);
var bodyBuilder = ArrayBuilder <BoundStatement> .GetInstance();
var resultVariable = F.SynthesizedLocal(stateMachineClass, null); // iteratorClass result;
BoundStatement makeIterator = F.Assignment(F.Local(resultVariable), F.New(stateMachineClass.Constructor, F.Literal(0))); // result = new IteratorClass(0)
var thisInitialized = F.GenerateLabel("thisInitialized");
if ((object)initialThreadIdField != null)
{
MethodSymbol currentManagedThreadIdMethod = null;
PropertySymbol currentManagedThreadIdProperty = F.WellKnownMember(WellKnownMember.System_Environment__CurrentManagedThreadId, isOptional: true) as PropertySymbol;
if ((object)currentManagedThreadIdProperty != null)
{
currentManagedThreadIdMethod = currentManagedThreadIdProperty.GetMethod;
}
if ((object)currentManagedThreadIdMethod != null)
{
managedThreadId = F.Call(null, currentManagedThreadIdMethod);
}
else
{
managedThreadId = F.Property(F.Property(WellKnownMember.System_Threading_Thread__CurrentThread), WellKnownMember.System_Threading_Thread__ManagedThreadId);
}
makeIterator = F.If(
condition: F.LogicalAnd( // if (this.state == -2 && this.initialThreadId == Thread.CurrentThread.ManagedThreadId)
F.IntEqual(F.Field(F.This(), stateField), F.Literal(StateMachineStates.FinishedStateMachine)),
F.IntEqual(F.Field(F.This(), initialThreadIdField), managedThreadId)),
thenClause: F.Block( // then
F.Assignment(F.Field(F.This(), stateField), F.Literal(StateMachineStates.FirstUnusedState)), // this.state = 0;
F.Assignment(F.Local(resultVariable), F.This()), // result = this;
method.IsStatic || method.ThisParameter.Type.IsReferenceType ? // if this is a reference type, no need to copy it since it is not assignable
F.Goto(thisInitialized) : // goto thisInitialized
(BoundStatement)F.Block()),
elseClause:
makeIterator // else result = new IteratorClass(0)
);
}
bodyBuilder.Add(makeIterator);
// Initialize all the parameter copies
var copySrc = initialParameters;
var copyDest = variableProxies;
if (!method.IsStatic)
{
// starting with "this"
CapturedSymbolReplacement proxy;
if (copyDest.TryGetValue(method.ThisParameter, out proxy))
{
bodyBuilder.Add(
F.Assignment(
proxy.Replacement(F.Syntax, stateMachineType => F.Local(resultVariable)),
copySrc[method.ThisParameter].Replacement(F.Syntax, stateMachineType => F.This())));
}
}
bodyBuilder.Add(F.Label(thisInitialized));
foreach (var parameter in method.Parameters)
{
CapturedSymbolReplacement proxy;
if (copyDest.TryGetValue(parameter, out proxy))
{
bodyBuilder.Add(
F.Assignment(
proxy.Replacement(F.Syntax, stateMachineType => F.Local(resultVariable)),
copySrc[parameter].Replacement(F.Syntax, stateMachineType => F.This())));
}
}
bodyBuilder.Add(F.Return(F.Local(resultVariable)));
F.CloseMethod(F.Block(ImmutableArray.Create(resultVariable), bodyBuilder.ToImmutableAndFree()));
// Generate IEnumerable.GetEnumerator
var getEnumerator = OpenMethodImplementation(IEnumerable_GetEnumerator, debuggerHidden: true);
F.CloseMethod(F.Return(F.Call(F.This(), getEnumeratorGeneric)));
}
public override BoundStatement InstrumentUsingTargetCapture(BoundUsingStatement original, BoundStatement usingTargetCapture)
{
return(AddDynamicAnalysis(original, base.InstrumentUsingTargetCapture(original, usingTargetCapture)));
}
/// <summary>
/// fixed(char* ptr = stringVar){ ... } == becomes ===>
///
/// pinned string pinnedTemp = stringVar; // pinning managed ref
/// char* ptr = (char*)pinnedTemp; // unsafe cast to unmanaged ptr
/// if (pinnedTemp != null) ptr += OffsetToStringData();
/// . . .
/// </summary>
private BoundStatement InitializeFixedStatementStringLocal(
BoundLocalDeclaration localDecl,
LocalSymbol localSymbol,
BoundFixedLocalCollectionInitializer fixedInitializer,
SyntheticBoundNodeFactory factory,
out LocalSymbol pinnedTemp)
{
TypeSymbol localType = localSymbol.Type;
BoundExpression initializerExpr = VisitExpression(fixedInitializer.Expression);
TypeSymbol initializerType = initializerExpr.Type;
// intervening parens may have been skipped by the binder; find the declarator
VariableDeclaratorSyntax declarator = fixedInitializer.Syntax.FirstAncestorOrSelf <VariableDeclaratorSyntax>();
Debug.Assert(declarator != null);
pinnedTemp = factory.SynthesizedLocal(
initializerType,
syntax: declarator,
isPinned: true,
kind: SynthesizedLocalKind.FixedReference);
// NOTE: we pin the string, not the pointer.
Debug.Assert(pinnedTemp.IsPinned);
Debug.Assert(!localSymbol.IsPinned);
BoundStatement stringTempInit = factory.Assignment(factory.Local(pinnedTemp), initializerExpr);
// (char*)pinnedTemp;
var addr = factory.Convert(
fixedInitializer.ElementPointerType,
factory.Local(pinnedTemp),
Conversion.PinnedObjectToPointer);
var convertedStringTemp = factory.Convert(
localType,
addr,
fixedInitializer.ElementPointerTypeConversion);
BoundStatement localInit = InstrumentLocalDeclarationIfNecessary(localDecl, localSymbol,
factory.Assignment(factory.Local(localSymbol), convertedStringTemp));
BoundExpression notNullCheck = MakeNullCheck(factory.Syntax, factory.Local(localSymbol), BinaryOperatorKind.NotEqual);
BoundExpression helperCall;
MethodSymbol offsetMethod;
if (TryGetWellKnownTypeMember(fixedInitializer.Syntax, WellKnownMember.System_Runtime_CompilerServices_RuntimeHelpers__get_OffsetToStringData, out offsetMethod))
{
helperCall = factory.Call(receiver: null, method: offsetMethod);
}
else
{
helperCall = new BoundBadExpression(fixedInitializer.Syntax, LookupResultKind.NotInvocable, ImmutableArray <Symbol> .Empty, ImmutableArray <BoundExpression> .Empty, ErrorTypeSymbol.UnknownResultType);
}
BoundExpression addition = factory.Binary(BinaryOperatorKind.PointerAndIntAddition, localType, factory.Local(localSymbol), helperCall);
BoundStatement conditionalAdd = factory.If(notNullCheck, factory.Assignment(factory.Local(localSymbol), addition));
return(factory.Block(stringTempInit, localInit, conditionalAdd));
}
public override BoundStatement InstrumentPatternSwitchWhenClauseConditionalGotoBody(BoundExpression original, BoundStatement ifConditionGotoBody)
{
ifConditionGotoBody = base.InstrumentPatternSwitchWhenClauseConditionalGotoBody(original, ifConditionGotoBody);
WhenClauseSyntax whenClause = original.Syntax.FirstAncestorOrSelf <WhenClauseSyntax>();
Debug.Assert(whenClause != null);
// Instrument the statement using a factory with the same syntax as the clause, so that the instrumentation appears to be part of the clause.
SyntheticBoundNodeFactory statementFactory = new SyntheticBoundNodeFactory(_method, whenClause, _methodBodyFactory.CompilationState, _diagnostics);
// Instrument using the span of the expression
return(statementFactory.StatementList(AddAnalysisPoint(whenClause, statementFactory), ifConditionGotoBody));
}
public override BoundNode VisitTypeOrInstanceInitializers(BoundTypeOrInstanceInitializers node)
{
ImmutableArray <BoundStatement> originalStatements = node.Statements;
ArrayBuilder <BoundStatement> statements = ArrayBuilder <BoundStatement> .GetInstance(node.Statements.Length);
foreach (var initializer in originalStatements)
{
if (IsFieldOrPropertyInitializer(initializer))
{
if (initializer.Kind == BoundKind.Block)
{
var block = (BoundBlock)initializer;
statements.Add(block.Update(block.Locals, block.LocalFunctions,
ImmutableArray.Create(RewriteExpressionStatement((BoundExpressionStatement)block.Statements.Single(),
suppressInstrumentation: true))));
}
else
{
statements.Add(RewriteExpressionStatement((BoundExpressionStatement)initializer, suppressInstrumentation: true));
}
}
else
{
statements.Add(VisitStatement(initializer));
}
}
int optimizedInitializers = 0;
bool optimize = _compilation.Options.OptimizationLevel == OptimizationLevel.Release;
for (int i = 0; i < statements.Count; i++)
{
if (statements[i] == null || (optimize && IsFieldOrPropertyInitializer(originalStatements[i]) && ShouldOptimizeOutInitializer(statements[i])))
{
optimizedInitializers++;
if (!_factory.CurrentFunction.IsStatic)
{
// NOTE: Dev11 removes static initializers if ONLY all of them are optimized out
statements[i] = null;
}
}
}
ImmutableArray <BoundStatement> rewrittenStatements;
if (optimizedInitializers == statements.Count)
{
// all are optimized away
rewrittenStatements = ImmutableArray <BoundStatement> .Empty;
statements.Free();
}
else
{
// instrument remaining statements
int remaining = 0;
for (int i = 0; i < statements.Count; i++)
{
BoundStatement rewritten = statements[i];
if (rewritten != null)
{
if (IsFieldOrPropertyInitializer(originalStatements[i]))
{
BoundStatement original = originalStatements[i];
if (Instrument && !original.WasCompilerGenerated)
{
rewritten = _instrumenter.InstrumentFieldOrPropertyInitializer(original, rewritten);
}
}
statements[remaining] = rewritten;
remaining++;
}
}
statements.Count = remaining;
rewrittenStatements = statements.ToImmutableAndFree();
}
return(new BoundStatementList(node.Syntax, rewrittenStatements, node.HasErrors));
}
public override BoundStatement InstrumentPatternSwitchStatement(BoundPatternSwitchStatement original, BoundStatement rewritten)
{
return(AddDynamicAnalysis(original, base.InstrumentPatternSwitchStatement(original, rewritten)));
}
public override BoundStatement InstrumentBreakStatement(BoundBreakStatement original, BoundStatement rewritten)
{
return(Previous.InstrumentBreakStatement(original, rewritten));
}
public override BoundStatement InstrumentSwitchBindCasePatternVariables(BoundStatement bindings)
{
return(Previous.InstrumentSwitchBindCasePatternVariables(bindings));
}
