private void TransformBody(AstGenerator/*!*/ gen) {
ScopeBuilder scope = DefineLocals();
var scopeVariable = gen.TopLevelScope.Builder.DefineHiddenVariable("#scope", typeof(RubyScope));
gen.EnterFileInitializer(
scope,
gen.TopLevelScope.SelfVariable,
scopeVariable
);
// visit nested initializers depth-first:
var body = gen.TransformStatements(_statements, ResultOperation.Ignore);
gen.LeaveFileInitializer();
gen.AddFileInitializer(
scope.CreateScope(
scopeVariable,
Methods.CreateFileInitializerScope.OpCall(
scope.MakeLocalsStorage(),
scope.GetVariableNamesExpression(),
gen.TopLevelScope.RuntimeScopeVariable
),
body
)
);
}
internal static MSA.Expression/*!*/ TransformConcatentation(AstGenerator/*!*/ gen, List<Expression>/*!*/ parts,
Func<string, MethodInfo>/*!*/ opFactory, MSA.Expression additionalArg) {
var opSuffix = new StringBuilder(Math.Min(parts.Count, 4));
List<MSA.Expression> merged = ConcatLiteralsAndTransform(gen, parts, opSuffix);
if (merged.Count <= RubyOps.MakeStringParamCount) {
if (merged.Count == 0) {
merged.Add(Ast.Constant(String.Empty));
opSuffix.Append(RubyOps.SuffixBinary);
}
if (opSuffix.IndexOf(RubyOps.SuffixEncoded) != -1) {
merged.Add(Ast.Constant(RubyEncoding.GetCodePage(gen.Encoding)));
}
if (additionalArg != null) {
merged.Add(additionalArg);
}
return opFactory(opSuffix.ToString()).OpCall(merged);
} else {
var paramArray = Ast.NewArrayInit(typeof(object), merged);
var codePage = Ast.Constant(RubyEncoding.GetCodePage(gen.Encoding));
return (additionalArg != null) ?
opFactory("N").OpCall(paramArray, codePage, additionalArg) :
opFactory("N").OpCall(paramArray, codePage);
}
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
return Methods.MatchString.OpCall(
Ast.Dynamic(ConvertToStrAction.Make(gen.Context), typeof(MutableString), _expression.Transform(gen)),
_regex.Transform(gen),
gen.CurrentScopeVariable
);
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
return AstFactory.Condition(
Methods.IsFalse.OpCall(AstFactory.Box(_condition.TransformRead(gen))),
gen.TransformStatementsToExpression(_statements),
gen.TransformStatementsToExpression(_elseClause != null ? _elseClause.Statements : null)
);
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
string setterName = _memberName + "=";
MSA.Expression transformedLeftTarget = _leftTarget.TransformRead(gen);
MSA.Expression transformedRight = _right.TransformRead(gen);
MSA.Expression leftTemp = gen.CurrentScope.DefineHiddenVariable(String.Empty, transformedLeftTarget.Type);
bool leftIsSelf = _leftTarget.NodeType == NodeTypes.SelfReference;
// lhs &&= rhs --> left.member && (left.member = rhs)
// lhs ||= rhs --> left.member || (left.member = rhs)
if (Operation == Symbols.And || Operation == Symbols.Or) {
MSA.Expression leftMemberRead = MethodCall.TransformRead(this, gen, false, _memberName, Ast.Assign(leftTemp, transformedLeftTarget), null, null, null, null);
MSA.Expression transformedWrite = MethodCall.TransformRead(this, gen, leftIsSelf, setterName, leftTemp, null, null, null, transformedRight);
if (Operation == Symbols.And) {
return AndExpression.TransformRead(gen, leftMemberRead, transformedWrite);
} else {
return OrExpression.TransformRead(gen, leftMemberRead, transformedWrite);
}
} else {
// left.member= left.member().op(right)
MSA.Expression leftMemberRead = MethodCall.TransformRead(this, gen, false, _memberName, leftTemp, null, null, null, null);
MSA.Expression operationCall = MethodCall.TransformRead(this, gen, false, Operation, leftMemberRead, null, null, transformedRight, null);
MSA.Expression transformedWrite = MethodCall.TransformRead(this, gen, leftIsSelf, setterName, Ast.Assign(leftTemp, transformedLeftTarget), null, null, null, operationCall);
return transformedWrite;
}
}
internal override MSA.Expression/*!*/ Transform(AstGenerator/*!*/ gen) {
return AstUtils.IfThenElse(
_condition.TransformCondition(gen, !_negateCondition),
_body.Transform(gen),
_elseStatement != null ? _elseStatement.Transform(gen) : AstUtils.Empty()
);
}
internal MSA.Expression/*!*/ TransformOptionalsInitialization(AstGenerator/*!*/ gen) {
Assert.NotNull(gen);
if (_optional.Length == 0) {
return AstUtils.Empty();
}
MSA.Expression singleton = gen.CurrentScope.DefineHiddenVariable("#default", typeof(object));
MSA.Expression result = AstUtils.Empty();
for (int i = 0; i < _optional.Length; i++) {
result = AstUtils.IfThen(
Ast.Equal(_optional[i].Left.TransformRead(gen), singleton),
Ast.Block(
result,
_optional[i].TransformRead(gen) // assignment
)
);
}
return Ast.Block(
Ast.Assign(singleton, Ast.Field(null, Fields.DefaultArgument)),
result,
AstUtils.Empty()
);
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
MSA.Expression result;
int i = _elseIfClauses.Count - 1;
if (i >= 0 && _elseIfClauses[i].Condition == null) {
// ... else body end
result = gen.TransformStatementsToExpression(_elseIfClauses[i].Statements);
i--;
} else {
// no else clause => the result of the if-expression is nil:
result = AstUtils.Constant(null);
}
while (i >= 0) {
// emit: else (if (condition) body else result)
result = AstFactory.Condition(
_elseIfClauses[i].Condition.TransformCondition(gen, true),
gen.TransformStatementsToExpression(_elseIfClauses[i].Statements),
result
);
i--;
}
// if (condition) body else result
return AstFactory.Condition(
_condition.TransformCondition(gen, true),
gen.TransformStatementsToExpression(_body),
result
);
}
MSA.Expression/*!*/ StringConstructor.IFactory.CreateExpressionN(AstGenerator/*!*/ gen, IEnumerable<MSA.Expression>/*!*/ args) {
return Methods.CreateRegex("N").OpCall(
Ast.NewArrayInit(typeof(MutableString), args),
AstUtils.Constant(_options),
AstUtils.Constant(new StrongBox<RubyRegex>(null))
);
}
// see Ruby Language.doc/Runtime/Control Flow Implementation/Break
internal override MSA.Expression/*!*/ Transform(AstGenerator/*!*/ gen) {
MSA.Expression transformedReturnValue = TransformReturnValue(gen);
// eval:
if (gen.CompilerOptions.IsEval) {
return Methods.EvalBreak.OpCall(gen.CurrentRfcVariable, AstFactory.Box(transformedReturnValue));
}
// loop:
if (gen.CurrentLoop != null) {
return Ast.Block(
Ast.Assign(
gen.CurrentLoop.ResultVariable,
Ast.Convert(transformedReturnValue, gen.CurrentLoop.ResultVariable.Type)
),
Ast.Break(gen.CurrentLoop.BreakLabel),
Ast.Empty()
);
}
// block:
if (gen.CurrentBlock != null) {
return gen.Return(Methods.BlockBreak.OpCall(gen.CurrentBlock.BfcVariable, AstFactory.Box(transformedReturnValue)));
}
// primary frame:
return Methods.MethodBreak.OpCall(AstFactory.Box(transformedReturnValue));
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
return AstFactory.Condition(
_condition.TransformReadBoolean(gen, true),
_trueExpression.TransformRead(gen),
_falseExpression.TransformRead(gen)
);
}
// see Ruby Language.doc/Runtime/Control Flow Implementation/Next
/*!*/
internal override MSA.Expression Transform(AstGenerator/*!*/ gen)
{
MSA.Expression transformedReturnValue = TransformReturnValue(gen);
// eval:
if (gen.CompilerOptions.IsEval) {
return Methods.EvalNext.OpCall(gen.CurrentScopeVariable, AstUtils.Box(transformedReturnValue));
}
// loop:
if (gen.CurrentLoop != null) {
return Ast.Block(
transformedReturnValue, // evaluate for side-effects
Ast.Continue(gen.CurrentLoop.ContinueLabel),
AstUtils.Empty()
);
}
// block:
if (gen.CurrentBlock != null) {
return gen.Return(transformedReturnValue);
}
// method:
return Methods.MethodNext.OpCall(gen.CurrentScopeVariable, AstUtils.Box(transformedReturnValue));
}
// see Ruby Language.doc/Runtime/Control Flow Implementation/Yield
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
MSA.Expression bfcVariable = gen.CurrentScope.DefineHiddenVariable("#yielded-bfc", typeof(BlockParam));
MSA.Expression resultVariable = gen.CurrentScope.DefineHiddenVariable("#result", typeof(object));
MSA.Expression postYield;
if (gen.CompilerOptions.IsEval) {
// eval:
postYield = Methods.EvalYield.OpCall(gen.CurrentScopeVariable, bfcVariable, resultVariable);
} else if (gen.CurrentBlock != null) {
// block:
postYield = Methods.BlockYield.OpCall(gen.CurrentScopeVariable, gen.CurrentBlock.BfcVariable, bfcVariable, resultVariable);
} else {
// method:
postYield = Methods.MethodYield.OpCall(gen.CurrentScopeVariable, bfcVariable, resultVariable);
}
return new AstBlock {
gen.DebugMarker("#RB: yield begin"),
Ast.Assign(bfcVariable, Methods.CreateBfcForYield.OpCall(gen.MakeMethodBlockParameterRead())),
Ast.Assign(
resultVariable,
(Arguments ?? Arguments.Empty).TransformToYield(gen, bfcVariable, gen.MakeMethodBlockParameterSelfRead())
),
AstUtils.IfThen(postYield, gen.Return(resultVariable)),
gen.DebugMarker("#RB: yield end"),
resultVariable
};
}
private MSA.Expression/*!*/ TransformBody(AstGenerator/*!*/ gen, MSA.Expression/*!*/ methodDefinitionVariable) {
string encodedName = RubyExceptionData.EncodeMethodName(gen.SourceUnit, _name, Location);
ScopeBuilder scope = new ScopeBuilder();
MSA.Expression parentScope = gen.CurrentScopeVariable;
MSA.ParameterExpression[] parameters = DefineParameters(gen, scope);
MSA.Expression currentMethodVariable = scope.DefineHiddenVariable("#method", typeof(RubyMethodInfo));
MSA.Expression rfcVariable = scope.DefineHiddenVariable("#rfc", typeof(RuntimeFlowControl));
MSA.Expression scopeVariable = scope.DefineHiddenVariable("#scope", typeof(RubyMethodScope));
MSA.Expression selfParameter = parameters[0];
MSA.Expression blockParameter = parameters[1];
gen.EnterMethodDefinition(
scope,
selfParameter,
scopeVariable,
blockParameter,
rfcVariable,
currentMethodVariable,
_name,
_parameters
);
DefinedScope.TransformLocals(scope);
MSA.ParameterExpression unwinder = scope.DefineHiddenVariable("#unwinder", typeof(MethodUnwinder));
MSA.Expression body = AstFactory.MakeUserMethodBody(
gen, Location.End.Line,
blockParameter,
rfcVariable,
unwinder,
Ast.Block(
Ast.Assign(currentMethodVariable, methodDefinitionVariable),
Ast.Assign(scopeVariable, Methods.CreateMethodScope.OpCall(
scope.VisibleVariables(), parentScope, currentMethodVariable, rfcVariable, selfParameter, blockParameter)
),
_parameters.TransformOptionalsInitialization(gen),
gen.TraceEnabled ? Methods.TraceMethodCall.OpCall(scopeVariable, Ast.Convert(AstUtils.Constant(gen.SourceUnit.Path), typeof(string)), AstUtils.Constant(Location.Start.Line)) : AstUtils.Empty(),
Body.TransformResult(gen, ResultOperation.Return),
AstUtils.Empty()
),
ResultOperation.Return,
(gen.Profiler != null) ? gen.Profiler.GetTickIndex(encodedName) : -1,
(gen.Profiler != null) ? scope.DefineHiddenVariable("#stamp", typeof(long)) : null,
gen.ReturnLabel
);
body = gen.AddReturnTarget(scope.CreateScope(body));
gen.LeaveMethodDefinition();
return CreateLambda(
encodedName,
parameters,
body
);
}
MSA.Expression/*!*/ StringConstructor.IFactory.CreateExpressionM(AstGenerator/*!*/ gen, MSAst.ExpressionCollectionBuilder/*!*/ args) {
string suffix = new String('M', args.Count);
args.Add(gen.Encoding.Expression);
args.Add(AstUtils.Constant(_options));
args.Add(AstUtils.Constant(new StrongBox<RubyRegex>(null)));
return Methods.CreateRegex(suffix).OpCall(args);
}
/*!*/
internal override MSA.Expression TransformWriteVariable(AstGenerator/*!*/ gen, MSA.Expression/*!*/ rightValue)
{
Assert.NotNull(gen, rightValue);
// no-op
return rightValue;
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
return AstFactory.Condition(
_condition.TransformCondition(gen, false),
gen.TransformStatementsToExpression(_statements),
gen.TransformStatementsToExpression(_elseClause != null ? _elseClause.Statements : null)
);
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
return Ast.Condition(
_condition.TransformReadBoolean(gen, !_negateCondition),
AstUtils.Box(_body.TransformRead(gen)),
(_elseStatement != null) ? AstUtils.Box(_elseStatement.TransformRead(gen)) : (MSA.Expression)AstUtils.Constant(null)
);
}
internal override MSA.Expression/*!*/ TransformWriteVariable(AstGenerator/*!*/ gen, MSA.Expression/*!*/ rightValue) {
if (gen.CompilerOptions.IsEval || gen.GetCurrentNonSingletonModule() != null) {
return Methods.SetClassVariable.OpCall(AstFactory.Box(rightValue), gen.CurrentScopeVariable, AstUtils.Constant(Name));
} else {
return Methods.SetObjectClassVariable.OpCall(AstFactory.Box(rightValue), gen.CurrentScopeVariable, AstUtils.Constant(Name));
}
}
// arguments: complex arguments (expressions, maplets, splat, block)
// singleArgument: siple argument (complex are not used)
// assignmentRhsArgument: rhs of the assignment: target.method=(rhs)
internal static MSA.Expression/*!*/ TransformRead(Expression/*!*/ node, AstGenerator/*!*/ gen, bool hasImplicitSelf,
string/*!*/ methodName, MSA.Expression/*!*/ transformedTarget,
Arguments arguments, Block block, MSA.Expression singleArgument, MSA.Expression assignmentRhsArgument) {
Debug.Assert(assignmentRhsArgument == null || block == null, "Block not allowed in assignment");
Debug.Assert(singleArgument == null || arguments == null && assignmentRhsArgument == null);
Assert.NotNull(gen, transformedTarget);
Assert.NotEmpty(methodName);
// Pass args in this order:
// 1. instance
// 2. block (if present)
// 3. passed args: normal args, maplets, array
// 4. RHS of assignment (if present)
MSA.Expression blockArgVariable;
MSA.Expression transformedBlock;
if (block != null) {
blockArgVariable = gen.CurrentScope.DefineHiddenVariable("#block-def", typeof(Proc));
transformedBlock = block.Transform(gen);
} else {
blockArgVariable = transformedBlock = null;
}
var siteBuilder = new CallSiteBuilder(gen, transformedTarget, blockArgVariable);
if (arguments != null) {
arguments.TransformToCall(gen, siteBuilder);
} else if (singleArgument != null) {
siteBuilder.Add(singleArgument);
}
MSA.Expression rhsVariable = null;
if (assignmentRhsArgument != null) {
rhsVariable = gen.CurrentScope.DefineHiddenVariable("#rhs", assignmentRhsArgument.Type);
siteBuilder.RhsArgument = Ast.Assign(rhsVariable, assignmentRhsArgument);
}
var dynamicSite = siteBuilder.MakeCallAction(methodName, hasImplicitSelf);
#if FEATURE_CALL_SITE_TRACER
if (gen.Context.CallSiteCreated != null) {
gen.Context.CallSiteCreated(node, dynamicSite);
}
#endif
MSA.Expression result = gen.DebugMark(dynamicSite, methodName);
if (block != null) {
result = gen.DebugMark(MakeCallWithBlockRetryable(gen, result, blockArgVariable, transformedBlock, block.IsDefinition),
"#RB: method call with a block ('" + methodName + "')");
}
if (assignmentRhsArgument != null) {
result = Ast.Block(result, rhsVariable);
}
return result;
}
private static MethodInfo/*!*/ GetOp(AstGenerator/*!*/ gen, int/*!*/ opKind) {
switch (opKind) {
case OpTryGet: return Methods.TryGetClassVariable;
case OpGet: return Methods.GetClassVariable;
case OpIsDefined: return Methods.IsDefinedClassVariable;
default: throw Assert.Unreachable;
}
}
private MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen, int/*!*/ opKind) {
// eval or in a non-singleton module/class declaration
// -> we find the right scope at runtime by walking the hierarchy
// otherwise
// -> variable is on Object
return GetOp(gen, opKind).OpCall(gen.CurrentScopeVariable, AstUtils.Constant(Name));
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
if (_isCondition) {
return TransformReadCondition(gen);
} else {
return (_isExclusive ? Methods.CreateExclusiveRange : Methods.CreateInclusiveRange).
OpCall(gen.CurrentScopeVariable, AstFactory.Box(_begin.TransformRead(gen)), AstFactory.Box(_end.TransformRead(gen)));
}
}
/*!*/
internal MSA.Expression Transform(AstGenerator/*!*/ gen)
{
if (_value is string) {
return Ast.Constant(_value, typeof(string));
} else {
return Methods.ConvertSymbolToClrString.OpCall(((StringConstructor)_value).TransformRead(gen));
}
}
internal override MSA.Expression/*!*/ Transform(AstGenerator/*!*/ gen) {
Assert.NotNull(gen);
return Ast.Dynamic(
ConvertToProcAction.Instance,
typeof(Proc),
gen.CurrentScopeVariable, _expression.TransformRead(gen)
);
}
internal override MSA.Expression/*!*/ Transform(AstGenerator/*!*/ gen) {
MSA.Expression[] result = new MSA.Expression[_items.Count + 1];
for (int i = 0; i < _items.Count; i++) {
result[i] = Methods.UndefineMethod.OpCall(gen.CurrentScopeVariable, AstUtils.Constant(_items[i].Name));
}
result[_items.Count] = AstUtils.Empty();
return Ast.Block(result);
}
internal override MSA.Expression/*!*/ TransformRead(AstGenerator/*!*/ gen) {
var result = StringConstructor.TransformConcatentation(gen, _pattern, Methods.CreateRegex, Ast.Constant(_options));
if (_isCondition) {
result = Methods.MatchLastInputLine.OpCall(result, gen.CurrentScopeVariable);
}
return result;
}
internal override MSA.Expression/*!*/ TransformWriteVariable(AstGenerator/*!*/ gen, MSA.Expression/*!*/ rightValue) {
if (_transformed != null) {
// static lookup:
return Ast.Assign(_transformed, AstUtils.Convert(rightValue, _transformed.Type));
} else {
// dynamic lookup:
return Methods.SetLocalVariable.OpCall(AstFactory.Box(rightValue), gen.CurrentScopeVariable, AstUtils.Constant(Name));
}
}
internal override string/*!*/ GetNodeName(AstGenerator/*!*/ gen) {
if (_value == null) {
return "nil";
} else if (_value is bool) {
return (bool)_value ? "true" : "false";
} else {
return base.GetNodeName(gen);
}
}
internal override MSA.Expression/*!*/ TransformReadVariable(AstGenerator/*!*/ gen, bool tryRead) {
if (_transformed != null) {
// static lookup:
return _transformed;
} else {
// dynamic lookup:
return Methods.GetLocalVariable.OpCall(gen.CurrentScopeVariable, AstUtils.Constant(Name));
}
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
Assert.NotNull(gen);
if (_maplets != null)
{
return(gen.MakeHashOpCall(gen.TransformMapletsToExpressions(_maplets)));
}
else if (_expressions != null)
{
return(gen.MakeHashOpCall(gen.TranformExpressions(_expressions)));
}
else
{
return(Methods.MakeHash0.OpCall(gen.CurrentScopeVariable));
}
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
MSA.Expression transformedTarget;
bool hasImplicitSelf;
if (_target != null)
{
transformedTarget = _target.TransformRead(gen);
hasImplicitSelf = false;
}
else
{
transformedTarget = gen.CurrentSelfVariable;
hasImplicitSelf = true;
}
return(TransformRead(this, gen, hasImplicitSelf, _methodName, transformedTarget, Arguments, Block, null, null));
}
private MSA.Expression /*!*/ MakeParametersInitialization(AstGenerator /*!*/ gen, AstParameters /*!*/ parameters)
{
var result = new AstExpressions(
ParameterCount +
(_parameters.Optional.Length > 0 ? 1 : 0) +
(_parameters.Unsplat != null ? 1 : 0) +
1
);
// TODO: we can skip parameters that are locals (need to be defined as parameters, not as #n):
var paramsArray = HasFormalParametersInArray ? parameters[HiddenParameterCount] : null;
int parameterIndex = 0;
for (int i = 0; i < _parameters.Mandatory.Length; i++)
{
result.Add(_parameters.Mandatory[i].TransformWrite(gen, GetParameterAccess(parameters, paramsArray, parameterIndex)));
parameterIndex++;
}
if (_parameters.Optional.Length > 0)
{
for (int i = 0; i < _parameters.Optional.Length; i++)
{
result.Add(_parameters.Optional[i].Left.TransformWrite(gen, GetParameterAccess(parameters, paramsArray, parameterIndex)));
parameterIndex++;
}
result.Add(_parameters.TransformOptionalsInitialization(gen));
}
if (_parameters.Block != null)
{
result.Add(_parameters.Block.TransformWrite(gen, GetParameterAccess(parameters, paramsArray, parameterIndex)));
parameterIndex++;
}
if (_parameters.Unsplat != null)
{
// the last parameter is unsplat:
result.Add(_parameters.Unsplat.TransformWrite(gen, parameters[parameters.Count - 1]));
}
result.Add(AstUtils.Empty());
return(Ast.Block(result));
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
if (IsAscii || gen.Encoding == BinaryEncoding.Instance)
{
return(Methods.CreateMutableStringB.OpCall(Ast.Constant(_value)));
}
else if (IsUTF8 || gen.Encoding == BinaryEncoding.UTF8)
{
return(Methods.CreateMutableStringU.OpCall(Ast.Constant(_value)));
}
else
{
return(Methods.CreateMutableStringE.OpCall(
Ast.Constant(_value), Ast.Constant(RubyEncoding.GetCodePage(gen.Encoding))
));
}
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
Assert.NotNull(gen);
MSA.Expression transformedBlock = _block.Transform(gen);
MSA.Expression blockArgVariable = gen.CurrentScope.DefineHiddenVariable("#forloop-block", typeof(Proc));
MSA.Expression result = CallSiteBuilder.InvokeMethod(gen.Context, "each", RubyCallSignature.WithScopeAndBlock(0),
gen.CurrentScopeVariable,
_list.TransformRead(gen),
blockArgVariable
);
return(gen.DebugMark(MethodCall.MakeCallWithBlockRetryable(gen, result, blockArgVariable, transformedBlock, true),
"#RB: method call with a block ('for-loop')"));
}
internal static MSA.Expression /*!*/ MakeCallWithBlockRetryable(AstGenerator /*!*/ gen, MSA.Expression /*!*/ invoke,
MSA.Expression blockArgVariable, MSA.Expression transformedBlock, bool isBlockDefinition)
{
Assert.NotNull(invoke);
Debug.Assert((blockArgVariable == null) == (transformedBlock == null));
// see Ruby Language.doc/Control Flow Implementation/Method Call With a Block
MSA.Expression resultVariable = gen.CurrentScope.DefineHiddenVariable("#method-result", typeof(object));
MSA.ParameterExpression evalUnwinder;
MSA.LabelTarget retryLabel = Ast.Label("retry");
var result = new AstBlock {
Ast.Assign(blockArgVariable, Ast.Convert(transformedBlock, blockArgVariable.Type)),
Ast.Label(retryLabel),
(isBlockDefinition) ? Methods.InitializeBlock.OpCall(blockArgVariable) : null,
AstUtils.Try(
Ast.Assign(resultVariable, invoke)
).Catch(evalUnwinder = Ast.Parameter(typeof(EvalUnwinder), "#u"),
Ast.Assign(
resultVariable,
Ast.Field(evalUnwinder, EvalUnwinder.ReturnValueField)
)
),
Ast.IfThen(Ast.TypeEqual(resultVariable, typeof(BlockReturnResult)),
Ast.IfThenElse(Methods.IsRetrySingleton.OpCall(resultVariable),
// retry:
AstUtils.IfThenElse(Ast.Equal(gen.MakeMethodBlockParameterRead(), blockArgVariable),
RetryStatement.TransformRetry(gen),
Ast.Goto(retryLabel)
),
// return:
gen.Return(ReturnStatement.Propagate(gen, resultVariable))
)
),
resultVariable
};
return(result);
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
Assert.NotNull(gen);
if (HasExceptionHandling)
{
MSA.Expression resultVariable = gen.CurrentScope.DefineHiddenVariable("#block-result", typeof(object));
return(Ast.Block(
TransformExceptionHandling(gen, ResultOperation.Store(resultVariable)),
resultVariable
));
}
else
{
return(gen.TransformStatementsToExpression(_statements));
}
}
private static List <MSA.Expression> /*!*/ ConcatLiteralsAndTransform(AstGenerator /*!*/ gen, List <Expression> /*!*/ parts, StringBuilder /*!*/ opName)
{
var result = new List <MSA.Expression>();
var literals = new List <string>();
int concatLength = 0;
var concatEncoding = StringLiteralEncoding.Ascii;
ConcatLiteralsAndTransformRecursive(gen, parts, literals, ref concatLength, ref concatEncoding, result, opName);
// finish trailing literals:
if (literals.Count > 0)
{
result.Add(Ast.Constant(Concat(literals, concatLength)));
opName.Append(OpSuffix(gen, concatEncoding));
}
return(result);
}
internal MSA.Expression /*!*/ TransformToYield(AstGenerator /*!*/ gen, MSA.Expression /*!*/ bfcVariable, MSA.Expression /*!*/ selfExpression)
{
var args = (_expressions != null) ? gen.TranformExpressions(_expressions) : new AstExpressions();
if (_maplets != null)
{
args.Add(gen.TransformToHashConstructor(_maplets));
}
return(AstFactory.YieldExpression(
gen.Context,
args,
(_array != null) ? _array.TransformRead(gen) : null, // splatted argument
null, // rhs argument
bfcVariable,
selfExpression
));
}
// when <expr0>, *<expr1>, ..., <exprN>
// generates:
// <MakeTest>(<expr0>) || <MakeArrayTest>(<expr1>) || ... [ || <MakeTest>(<exprN>) ]
internal static MSA.Expression /*!*/ TransformWhenCondition(AstGenerator /*!*/ gen, Expression /*!*/[] /*!*/ comparisons, MSA.Expression value)
{
MSA.Expression result;
if (comparisons.Length > 0)
{
result = MakeTest(gen, comparisons[comparisons.Length - 1], value);
for (int i = comparisons.Length - 2; i >= 0; i--)
{
result = Ast.OrElse(MakeTest(gen, comparisons[i], value), result);
}
}
else
{
result = Ast.Constant(false);
}
return(result);
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
MSA.Expression result;
if (_elseStatements != null)
{
// ... else body end
result = gen.TransformStatementsToExpression(_elseStatements);
}
else
{
// no else clause => the result of the if-expression is nil:
result = AstUtils.Constant(null);
}
MSA.Expression value;
if (_value != null)
{
value = gen.CurrentScope.DefineHiddenVariable("#case-compare-value", typeof(object));
}
else
{
value = null;
}
for (int i = _whenClauses.Length - 1; i >= 0; i--)
{
// emit: else (if (condition) body else result)
result = AstFactory.Condition(
TransformWhenCondition(gen, _whenClauses[i].Comparisons, value),
gen.TransformStatementsToExpression(_whenClauses[i].Statements),
result
);
}
if (_value != null)
{
result = Ast.Block(
Ast.Assign(value, Ast.Convert(_value.TransformRead(gen), typeof(object))),
result
);
}
return(result);
}
private MSA.Expression /*!*/ TransformWrite(AstGenerator /*!*/ gen, MSA.Expression /*!*/ transformedRight, bool isSimpleRhs)
{
var writes = new AstBlock();
MSA.Expression rightList = gen.CurrentScope.DefineHiddenVariable("#rhs", typeof(IList));
MSA.Expression result;
if (isSimpleRhs)
{
// 1.9 returns the RHS, not an unsplatted array, if there is just a single RHS:
result = gen.CurrentScope.DefineHiddenVariable("#pr", transformedRight.Type);
writes.Add(Ast.Assign(result, transformedRight));
transformedRight = AstUtils.LightDynamic(ImplicitSplatAction.Make(gen.Context), typeof(IList), result);
}
else
{
result = rightList;
}
writes.Add(Ast.Assign(rightList, transformedRight));
for (int i = 0; i < _unsplattedValueIndex; i++)
{
writes.Add(_leftValues[i].TransformWrite(gen, Methods.GetArrayItem.OpCall(rightList, AstUtils.Constant(i))));
}
if (HasUnsplattedValue)
{
MSA.Expression explicitCount = AstUtils.Constant(_leftValues.Length - 1);
// remaining RHS values:
MSA.Expression array = Methods.GetArrayRange.OpCall(rightList, AstUtils.Constant(_unsplattedValueIndex), explicitCount);
writes.Add(_leftValues[_unsplattedValueIndex].TransformWrite(gen, array));
for (int i = _unsplattedValueIndex + 1; i < _leftValues.Length; i++)
{
writes.Add(_leftValues[i].TransformWrite(gen, Methods.GetTrailingArrayItem.OpCall(rightList, AstUtils.Constant(_leftValues.Length - i), explicitCount)));
}
}
writes.Add(result);
return(writes);
}
/// <code>
/// End-exclusive range:
/// if state
/// state = IsFalse({end})
/// true
/// else
/// state = IsTrue({begin})
/// end
///
/// End-inclusive range:
/// if state || IsTrue({begin})
/// state = IsFalse({end})
/// true
/// else
/// false
/// end
/// </code>
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
var begin = AstUtils.Box(_range.Begin.TransformRead(gen));
var end = AstUtils.Box(_range.End.TransformRead(gen));
// state:
// false <=> null
// true <=> non-null
if (_range.IsExclusive)
{
return(Ast.Condition(
Ast.ReferenceNotEqual(
_stateVariable.TransformReadVariable(gen, false),
AstUtils.Constant(null)
),
Ast.Block(
_stateVariable.TransformWriteVariable(gen, Methods.NullIfTrue.OpCall(end)),
AstUtils.Constant(true)
),
Ast.ReferenceNotEqual(
_stateVariable.TransformWriteVariable(gen, Methods.NullIfFalse.OpCall(begin)),
AstUtils.Constant(null)
)
));
}
else
{
return(Ast.Condition(
Ast.OrElse(
Ast.ReferenceNotEqual(
_stateVariable.TransformReadVariable(gen, false),
AstUtils.Constant(null)
),
Methods.IsTrue.OpCall(begin)
),
Ast.Block(
_stateVariable.TransformWriteVariable(gen, Methods.NullIfTrue.OpCall(end)),
AstUtils.Constant(true)
),
AstUtils.Constant(false)
));
}
}
// see Ruby Language.doc/Runtime/Control Flow Implementation/Return
internal override MSA.Expression /*!*/ Transform(AstGenerator /*!*/ gen)
{
MSA.Expression transformedReturnValue = TransformReturnValue(gen);
// eval:
if (gen.CompilerOptions.IsEval)
{
return(gen.Return(Methods.EvalReturn.OpCall(gen.CurrentScopeVariable, AstUtils.Box(transformedReturnValue))));
}
// block:
if (gen.CurrentBlock != null)
{
return(gen.Return(Methods.BlockReturn.OpCall(gen.CurrentBlock.BfcVariable, AstUtils.Box(transformedReturnValue))));
}
// method:
return(gen.Return(transformedReturnValue));
}
internal virtual MSA.Expression /*!*/ MakeDefinitionExpression(AstGenerator /*!*/ gen)
{
MSA.Expression transformedQualifier;
MSA.Expression name = QualifiedName.TransformName(gen);
switch (QualifiedName.TransformQualifier(gen, out transformedQualifier))
{
case StaticScopeKind.Global:
return(Methods.DefineGlobalModule.OpCall(gen.CurrentScopeVariable, name));
case StaticScopeKind.EnclosingModule:
return(Methods.DefineNestedModule.OpCall(gen.CurrentScopeVariable, name));
case StaticScopeKind.Explicit:
return(Methods.DefineModule.OpCall(gen.CurrentScopeVariable, AstUtils.Box(transformedQualifier), name));
}
throw Assert.Unreachable;
}
private static char OpSuffix(AstGenerator /*!*/ gen, StringLiteralEncoding encoding)
{
if (encoding == StringLiteralEncoding.Ascii)
{
return(RubyOps.SuffixBinary);
}
else if (encoding == StringLiteralEncoding.UTF8 || gen.Encoding == Encoding.UTF8)
{
return(RubyOps.SuffixUTF8);
}
else if (gen.Encoding == BinaryEncoding.Instance)
{
return(RubyOps.SuffixBinary);
}
else
{
return(RubyOps.SuffixEncoded);
}
}
internal override MSA.Expression /*!*/ TransformWriteVariable(AstGenerator /*!*/ gen, MSA.Expression /*!*/ rightValue)
{
MSA.Expression transformedName = TransformName(gen);
MSA.Expression transformedQualifier;
switch (TransformQualifier(gen, out transformedQualifier))
{
case StaticScopeKind.Global:
return(Methods.SetGlobalConstant.OpCall(AstUtils.Box(rightValue), gen.CurrentScopeVariable, transformedName));
case StaticScopeKind.EnclosingModule:
return(Methods.SetUnqualifiedConstant.OpCall(AstUtils.Box(rightValue), gen.CurrentScopeVariable, transformedName));
case StaticScopeKind.Explicit:
return(Methods.SetQualifiedConstant.OpCall(AstUtils.Box(rightValue), transformedQualifier, gen.CurrentScopeVariable, transformedName));
}
throw Assert.Unreachable;
}
//
// Traverses expressions in "parts" and concats all contiguous literal strings.
// Notes:
// - Instead of usign StringBuilder we place the string values that can be concatenated so far in to "literals" list and keep track
// of their total length in "concatLength" and encoding in "concatEncoding".
// If we reach a non-literal expression and we have some literals ready in "literals" array we do the concat and clear the list
// and "concatLength" and "concatEncoding".
// - "result" list contains argument expressions to the CreateMutableString* overloads.
// - "opName" contains the name of the operation. This method appends suffix based on the argument types (see RubyOps.Suffix*).
//
private static void ConcatLiteralsAndTransformRecursive(AstGenerator /*!*/ gen, List <Expression> /*!*/ parts,
List <string> /*!*/ literals, ref int concatLength, ref StringLiteralEncoding concatEncoding, List <MSA.Expression> /*!*/ result,
StringBuilder /*!*/ opName)
{
for (int i = 0; i < parts.Count; i++)
{
Expression part = parts[i];
StringLiteral literal;
StringConstructor ctor;
if ((literal = part as StringLiteral) != null)
{
literals.Add(literal.Value);
concatEncoding = CombineEncoding(concatEncoding, literal);
concatLength += literal.Value.Length;
}
else if ((ctor = part as StringConstructor) != null)
{
ConcatLiteralsAndTransformRecursive(gen, ctor.Parts, literals, ref concatLength, ref concatEncoding, result, opName);
}
else
{
if (literals.Count > 0)
{
result.Add(Ast.Constant(Concat(literals, concatLength)));
opName.Append(OpSuffix(gen, concatEncoding));
concatLength = 0;
concatEncoding = StringLiteralEncoding.Ascii;
literals.Clear();
}
result.Add(
Ast.Dynamic(
ConvertToSAction.Instance,
typeof(MutableString),
gen.CurrentScopeVariable, part.TransformRead(gen)
)
);
opName.Append(RubyOps.SuffixMutable);
}
}
}
internal override MSA.Expression /*!*/ MakeDefinitionExpression(AstGenerator /*!*/ gen)
{
MSA.Expression transformedQualifier;
MSA.Expression name = QualifiedName.TransformName(gen);
MSA.Expression transformedSuper = (_superClass != null) ? AstUtils.Box(_superClass.TransformRead(gen)) : AstUtils.Constant(null);
switch (QualifiedName.TransformQualifier(gen, out transformedQualifier))
{
case StaticScopeKind.Global:
return(Methods.DefineGlobalClass.OpCall(gen.CurrentScopeVariable, name, transformedSuper));
case StaticScopeKind.EnclosingModule:
return(Methods.DefineNestedClass.OpCall(gen.CurrentScopeVariable, name, transformedSuper));
case StaticScopeKind.Explicit:
return(Methods.DefineClass.OpCall(gen.CurrentScopeVariable, transformedQualifier, name, transformedSuper));
}
throw Assert.Unreachable;
}
private MSA.ParameterExpression[] /*!*/ DefineParameters(AstGenerator /*!*/ gen, ScopeBuilder /*!*/ scope)
{
// user defined locals/args:
MSA.ParameterExpression[] parameters = DefinedScope.TransformParameters(_parameters, HiddenParameterCount);
scope.AddVisibleParameters(parameters, HiddenParameterCount);
parameters[0] = Ast.Parameter(typeof(object), "#self");
if (_parameters.Block != null)
{
// map user defined proc parameter to the special param #1:
parameters[1] = _parameters.Block.TransformBlockParameterDefinition();
}
else
{
parameters[1] = Ast.Parameter(typeof(Proc), "#block");
}
return(parameters);
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
switch (_index)
{
case MatchData:
return(Methods.GetCurrentMatchData.OpCall(gen.CurrentScopeVariable));
case MatchLastGroup:
return(Methods.GetCurrentMatchLastGroup.OpCall(gen.CurrentScopeVariable));
case PreMatch:
return(Methods.GetCurrentPreMatch.OpCall(gen.CurrentScopeVariable));
case PostMatch:
return(Methods.GetCurrentPostMatch.OpCall(gen.CurrentScopeVariable));
default:
return(Methods.GetCurrentMatchGroup.OpCall(gen.CurrentScopeVariable, AstUtils.Constant(_index)));
}
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
switch (_kind)
{
case StringKind.Mutable:
return(TransformConcatentation(gen, _parts, Methods.CreateMutableString, null));
case StringKind.Immutable:
return(TransformConcatentation(gen, _parts, Methods.CreateSymbol, null));
case StringKind.Command:
return(Ast.Dynamic(RubyCallAction.Make("`", new RubyCallSignature(1, RubyCallFlags.HasScope | RubyCallFlags.HasImplicitSelf)), typeof(object),
gen.CurrentScopeVariable,
gen.CurrentSelfVariable,
TransformConcatentation(gen, _parts, Methods.CreateMutableString, null)
));
}
throw Assert.Unreachable;
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
switch (_kind)
{
case StringKind.Mutable:
return(TransformConcatentation(gen, _parts, StringFactory.Instance));
case StringKind.Symbol:
return(TransformConcatentation(gen, _parts, SymbolFactory.Instance));
case StringKind.Command:
return(CallSiteBuilder.InvokeMethod(gen.Context, "`", new RubyCallSignature(1, RubyCallFlags.HasScope | RubyCallFlags.HasImplicitSelf),
gen.CurrentScopeVariable,
gen.CurrentSelfVariable,
TransformConcatentation(gen, _parts, StringFactory.Instance)
));
}
throw Assert.Unreachable;
}
internal void TransformToCall(AstGenerator /*!*/ gen, CallBuilder callBuilder)
{
if (_expressions != null)
{
foreach (var arg in _expressions)
{
callBuilder.Add(arg.TransformRead(gen));
}
}
if (_maplets != null)
{
callBuilder.Add(gen.TransformToHashConstructor(_maplets));
}
if (_array != null)
{
callBuilder.SplattedArgument = _array.TransformRead(gen);
}
}
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
int intBegin, intEnd;
if (IsIntegerRange(out intBegin, out intEnd))
{
return((_isExclusive ? Methods.CreateExclusiveIntegerRange : Methods.CreateInclusiveIntegerRange).OpCall(
AstUtils.Constant(intBegin), AstUtils.Constant(intEnd)
));
}
else
{
return((_isExclusive ? Methods.CreateExclusiveRange : Methods.CreateInclusiveRange).OpCall(
AstUtils.Box(_begin.TransformRead(gen)),
AstUtils.Box(_end.TransformRead(gen)),
gen.CurrentScopeVariable,
AstUtils.Constant(new BinaryOpStorage(gen.Context))
));
}
}
internal void TransformToCall(AstGenerator /*!*/ gen, CallSiteBuilder /*!*/ siteBuilder)
{
if (_expressions != null)
{
foreach (var arg in _expressions)
{
siteBuilder.Add(arg.TransformRead(gen));
}
}
if (_maplets != null)
{
siteBuilder.Add(gen.TransformToHashConstructor(_maplets));
}
if (_array != null)
{
siteBuilder.SplattedArgument =
AstUtils.LightDynamic(SplatAction.Make(gen.Context), typeof(IList), _array.TransformRead(gen));
}
}
// see Ruby Language.doc/Runtime/Control Flow Implementation/Yield
internal override MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen)
{
MSA.Expression bfcVariable = gen.CurrentScope.DefineHiddenVariable("#yielded-bfc", typeof(BlockParam));
MSA.Expression resultVariable = gen.CurrentScope.DefineHiddenVariable("#result", typeof(object));
MSA.Expression evalUnwinder = gen.CurrentScope.DefineHiddenVariable("#unwinder", typeof(EvalUnwinder));
MSA.Expression postYield;
if (gen.CompilerOptions.IsEval)
{
// eval:
postYield = Methods.EvalYield.OpCall(gen.CurrentRfcVariable, bfcVariable, resultVariable);
}
else if (gen.CurrentBlock != null)
{
// block:
postYield = Methods.BlockYield.OpCall(gen.CurrentRfcVariable, gen.CurrentBlock.BfcVariable, bfcVariable, resultVariable);
}
else
{
// method:
postYield = Methods.MethodYield.OpCall(gen.CurrentRfcVariable, bfcVariable, resultVariable);
}
return(AstFactory.Block(
gen.DebugMarker("#RB: yield begin"),
Ast.Assign(bfcVariable, Methods.CreateBfcForYield.OpCall(gen.MakeMethodBlockParameterRead())),
Ast.Assign(resultVariable, (Arguments ?? Arguments.Empty).TransformToYield(gen, bfcVariable,
Ast.Property(AstUtils.Convert(gen.MakeMethodBlockParameterRead(), typeof(Proc)), Proc.SelfProperty)
)),
AstUtils.IfThen(postYield, gen.Return(resultVariable)),
gen.DebugMarker("#RB: yield end"),
resultVariable
));
}
// when <expr>
// generates into:
// RubyOps.IsTrue(<expr>) if the case has no value, otherise:
// RubyOps.IsTrue(Call("===", <expr>, <value>))
private static MSA.Expression /*!*/ MakeTest(AstGenerator /*!*/ gen, Expression /*!*/ expr, MSA.Expression value)
{
MSA.Expression transformedExpr = expr.TransformRead(gen);
if (expr is SplattedArgument)
{
if (value != null)
{
return(Methods.ExistsUnsplatCompare.OpCall(
Ast.Constant(CallSite <Func <CallSite, object, object, object> > .Create(
RubyCallAction.Make(gen.Context, "===", RubyCallSignature.WithImplicitSelf(2))
)),
AstUtils.LightDynamic(ExplicitTrySplatAction.Make(gen.Context), transformedExpr),
AstUtils.Box(value)
));
}
else
{
return(Methods.ExistsUnsplat.OpCall(
AstUtils.LightDynamic(ExplicitTrySplatAction.Make(gen.Context), transformedExpr)
));
}
}
else
{
if (value != null)
{
return(AstFactory.IsTrue(
CallSiteBuilder.InvokeMethod(gen.Context, "===", RubyCallSignature.WithScope(1),
gen.CurrentScopeVariable,
transformedExpr,
value
)
));
}
else
{
return(AstFactory.IsTrue(transformedExpr));
}
}
}
internal static MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen, AstExpressions /*!*/ rightValues,
MSA.Expression splattedValue, bool doSplat)
{
Assert.NotNull(gen, rightValues);
MSA.Expression result;
// We need to distinguish various special cases here.
// For parallel assignment specification, see "Ruby Language.docx/Runtime/Parallel Assignment".
// R(0,*)?
bool rightNoneSplat = rightValues.Count == 0 && splattedValue != null;
// R(1,-)?
bool rightOneNone = rightValues.Count == 1 && splattedValue == null;
if (rightNoneSplat)
{
result = AstUtils.LightDynamic(SplatAction.Make(gen.Context), typeof(IList), splattedValue);
if (doSplat)
{
result = Methods.Splat.OpCall(result);
}
}
else if (rightOneNone && doSplat)
{
result = rightValues[0];
}
else
{
result = Methods.MakeArrayOpCall(rightValues);
if (splattedValue != null)
{
result = Methods.SplatAppend.OpCall(result, AstUtils.LightDynamic(SplatAction.Make(gen.Context), typeof(IList), splattedValue));
}
}
return(result);
}
private MSA.Expression /*!*/ TransformRead(AstGenerator /*!*/ gen, int opKind)
{
ConstantVariable constantQualifier = _qualifier as ConstantVariable;
if (constantQualifier != null)
{
ConstantVariable constant;
List <string> names = new List <string>();
names.Add(Name);
do
{
names.Add(constantQualifier.Name);
constant = constantQualifier;
constantQualifier = constantQualifier.Qualifier as ConstantVariable;
} while (constantQualifier != null);
if (constant.Qualifier != null)
{
// {expr}::A::B
return(constant.MakeExpressionQualifiedRead(gen, opKind, names.ToReverseArray()));
}
else
{
// A::B
return(MakeCachedRead(gen, opKind, constant.IsGlobal, true, Ast.Constant(names.ToReverseArray())));
}
}
else if (_qualifier != null)
{
// {expr}::A
return(MakeExpressionQualifiedRead(gen, opKind, new[] { Name }));
}
else
{
// A
// ::A
return(MakeCachedRead(gen, opKind, IsGlobal, false, Ast.Constant(Name)));
}
}
