use of org.eclipse.n4js.ts.types.IdentifiableElement in project n4js by eclipse.
the class InternalTypeSystem method applyRuleTypePropertyAccessExpression.
protected Result<TypeRef> applyRuleTypePropertyAccessExpression(final RuleEnvironment G, final RuleApplicationTrace _trace_, final ParameterizedPropertyAccessExpression expr) throws RuleFailedException {
// output parameter
TypeRef T = null;
/* { T = env(G, GUARD_TYPE_PROPERTY_ACCESS_EXPRESSION -> expr, TypeRef) } or { val G2 = G.wrap G2.add(GUARD_TYPE_PROPERTY_ACCESS_EXPRESSION -> expr, G2.anyTypeRef) G2 |- expr.target : var TypeRef receiverTypeRef typeSystemHelper.addSubstitutions(G2,receiverTypeRef) G2.addThisType(receiverTypeRef) if (! (receiverTypeRef instanceof UnknownTypeRef) && (expr.target instanceof SuperLiteral || expr.target instanceof ThisLiteral) ) { var containingClass = EcoreUtil2.getContainerOfType(expr,N4ClassDeclaration)?.definedType; if (containingClass instanceof TClass) { if (containingClass.isStaticPolyfill) { containingClass = containingClass.superClassRef?.declaredType } if (containingClass instanceof TClass) { if (containingClass?.superClassRef!==null) { typeSystemHelper.addSubstitutions(G2, containingClass.superClassRef) } } } } val prop = expr.property; var TypeRef propTypeRef; if(prop instanceof TMethod && (prop as TMethod).isConstructor) { val TypeArgument ctorTypeArg = switch(receiverTypeRef) { TypeTypeRef: G.functionTypeRef ParameterizedTypeRef, BoundThisTypeRef: { val declType = if(receiverTypeRef instanceof BoundThisTypeRef) { receiverTypeRef.actualThisTypeRef?.declaredType } else { receiverTypeRef.declaredType }; val finalCtorSig = if(declType instanceof TClassifier) N4JSLanguageUtils.hasCovariantConstructor(declType); if(finalCtorSig) { declType.ref } else if(declType!==null) { TypeUtils.createWildcardExtends(declType.ref) } else { null } } }; propTypeRef = if(ctorTypeArg!==null) { TypeUtils.createTypeTypeRef(ctorTypeArg, true) } else { TypeRefsFactory.eINSTANCE.createUnknownTypeRef }; } else if(receiverTypeRef.dynamic && prop!==null && prop.eIsProxy) { propTypeRef = G.anyTypeRefDynamic; } else { G2.wrap |- prop : propTypeRef if(expr.parameterized) { typeSystemHelper.addSubstitutions(G2,expr); } } G2 |- propTypeRef ~> T T = versionResolver.resolveVersion(T, receiverTypeRef); if (expr.target instanceof SuperLiteral && T instanceof FunctionTypeExprOrRef ) { val F = T as FunctionTypeExprOrRef; if ((T as FunctionTypeExprOrRef).returnTypeRef instanceof BoundThisTypeRef) { var TypeRef rawT; G |~ expr ~> rawT; val thisTypeRef = TypeUtils.enforceNominalTyping(rawT); if (T instanceof FunctionTypeExpression && T.eContainer===null) { val fte = T as FunctionTypeExpression fte.returnTypeRef = TypeUtils.copyIfContained(thisTypeRef); } else { T = TypeUtils.createFunctionTypeExpression(null, F.typeVars, F.fpars, thisTypeRef); } } } } */
{
RuleFailedException previousFailure = null;
try {
Pair<String, ParameterizedPropertyAccessExpression> _mappedTo = Pair.<String, ParameterizedPropertyAccessExpression>of(RuleEnvironmentExtensions.GUARD_TYPE_PROPERTY_ACCESS_EXPRESSION, expr);
T = this.<TypeRef>env(G, _mappedTo, TypeRef.class);
} catch (Exception e) {
previousFailure = extractRuleFailedException(e);
final RuleEnvironment G2 = RuleEnvironmentExtensions.wrap(G);
Pair<String, ParameterizedPropertyAccessExpression> _mappedTo_1 = Pair.<String, ParameterizedPropertyAccessExpression>of(RuleEnvironmentExtensions.GUARD_TYPE_PROPERTY_ACCESS_EXPRESSION, expr);
boolean _add = G2.add(_mappedTo_1, RuleEnvironmentExtensions.anyTypeRef(G2));
/* G2.add(GUARD_TYPE_PROPERTY_ACCESS_EXPRESSION -> expr, G2.anyTypeRef) */
if (!_add) {
sneakyThrowRuleFailedException("G2.add(GUARD_TYPE_PROPERTY_ACCESS_EXPRESSION -> expr, G2.anyTypeRef)");
}
/* G2 |- expr.target : var TypeRef receiverTypeRef */
Expression _target = expr.getTarget();
TypeRef receiverTypeRef = null;
Result<TypeRef> result = typeInternal(G2, _trace_, _target);
checkAssignableTo(result.getFirst(), TypeRef.class);
receiverTypeRef = (TypeRef) result.getFirst();
this.typeSystemHelper.addSubstitutions(G2, receiverTypeRef);
RuleEnvironmentExtensions.addThisType(G2, receiverTypeRef);
if (((!(receiverTypeRef instanceof UnknownTypeRef)) && ((expr.getTarget() instanceof SuperLiteral) || (expr.getTarget() instanceof ThisLiteral)))) {
N4ClassDeclaration _containerOfType = EcoreUtil2.<N4ClassDeclaration>getContainerOfType(expr, N4ClassDeclaration.class);
Type _definedType = null;
if (_containerOfType != null) {
_definedType = _containerOfType.getDefinedType();
}
Type containingClass = _definedType;
if ((containingClass instanceof TClass)) {
boolean _isStaticPolyfill = ((TClass) containingClass).isStaticPolyfill();
if (_isStaticPolyfill) {
ParameterizedTypeRef _superClassRef = ((TClass) containingClass).getSuperClassRef();
Type _declaredType = null;
if (_superClassRef != null) {
_declaredType = _superClassRef.getDeclaredType();
}
containingClass = _declaredType;
}
if ((containingClass instanceof TClass)) {
ParameterizedTypeRef _superClassRef_1 = null;
if (((TClass) containingClass) != null) {
_superClassRef_1 = ((TClass) containingClass).getSuperClassRef();
}
boolean _tripleNotEquals = (_superClassRef_1 != null);
if (_tripleNotEquals) {
this.typeSystemHelper.addSubstitutions(G2, ((TClass) containingClass).getSuperClassRef());
}
}
}
}
final IdentifiableElement prop = expr.getProperty();
TypeRef propTypeRef = null;
if (((prop instanceof TMethod) && ((TMethod) prop).isConstructor())) {
TypeArgument _switchResult = null;
boolean _matched = false;
if (receiverTypeRef instanceof TypeTypeRef) {
_matched = true;
_switchResult = RuleEnvironmentExtensions.functionTypeRef(G);
}
if (!_matched) {
if (receiverTypeRef instanceof ParameterizedTypeRef) {
_matched = true;
}
if (!_matched) {
if (receiverTypeRef instanceof BoundThisTypeRef) {
_matched = true;
}
}
if (_matched) {
TypeArgument _xblockexpression = null;
{
Type _xifexpression = null;
if ((receiverTypeRef instanceof BoundThisTypeRef)) {
ParameterizedTypeRef _actualThisTypeRef = ((BoundThisTypeRef) receiverTypeRef).getActualThisTypeRef();
Type _declaredType_1 = null;
if (_actualThisTypeRef != null) {
_declaredType_1 = _actualThisTypeRef.getDeclaredType();
}
_xifexpression = _declaredType_1;
} else {
_xifexpression = ((BaseTypeRef) receiverTypeRef).getDeclaredType();
}
final Type declType = _xifexpression;
boolean _xifexpression_1 = false;
if ((declType instanceof TClassifier)) {
_xifexpression_1 = N4JSLanguageUtils.hasCovariantConstructor(((TClassifier) declType));
}
final boolean finalCtorSig = _xifexpression_1;
TypeArgument _xifexpression_2 = null;
if (finalCtorSig) {
_xifexpression_2 = TypeExtensions.ref(declType);
} else {
Wildcard _xifexpression_3 = null;
if ((declType != null)) {
_xifexpression_3 = TypeUtils.createWildcardExtends(TypeExtensions.ref(declType));
} else {
_xifexpression_3 = null;
}
_xifexpression_2 = _xifexpression_3;
}
_xblockexpression = (_xifexpression_2);
}
_switchResult = _xblockexpression;
}
}
final TypeArgument ctorTypeArg = _switchResult;
TypeRef _xifexpression = null;
if ((ctorTypeArg != null)) {
_xifexpression = TypeUtils.createTypeTypeRef(ctorTypeArg, true);
} else {
_xifexpression = TypeRefsFactory.eINSTANCE.createUnknownTypeRef();
}
propTypeRef = _xifexpression;
} else {
if (((receiverTypeRef.isDynamic() && (prop != null)) && prop.eIsProxy())) {
propTypeRef = RuleEnvironmentExtensions.anyTypeRefDynamic(G);
} else {
/* G2.wrap |- prop : propTypeRef */
RuleEnvironment _wrap = RuleEnvironmentExtensions.wrap(G2);
Result<TypeRef> result_1 = typeInternal(_wrap, _trace_, prop);
checkAssignableTo(result_1.getFirst(), TypeRef.class);
propTypeRef = (TypeRef) result_1.getFirst();
boolean _isParameterized = expr.isParameterized();
if (_isParameterized) {
this.typeSystemHelper.addSubstitutions(G2, expr);
}
}
}
/* G2 |- propTypeRef ~> T */
Result<TypeArgument> result_2 = substTypeVariablesInternal(G2, _trace_, propTypeRef);
checkAssignableTo(result_2.getFirst(), TypeRef.class);
T = (TypeRef) result_2.getFirst();
T = this.versionResolver.<TypeRef, TypeRef>resolveVersion(T, receiverTypeRef);
if (((expr.getTarget() instanceof SuperLiteral) && (T instanceof FunctionTypeExprOrRef))) {
final FunctionTypeExprOrRef F = ((FunctionTypeExprOrRef) T);
TypeRef _returnTypeRef = ((FunctionTypeExprOrRef) T).getReturnTypeRef();
if ((_returnTypeRef instanceof BoundThisTypeRef)) {
TypeRef rawT = null;
/* G |~ expr ~> rawT */
Result<TypeRef> result_3 = thisTypeRefInternal(G, _trace_, expr);
checkAssignableTo(result_3.getFirst(), TypeRef.class);
rawT = (TypeRef) result_3.getFirst();
final TypeRef thisTypeRef = TypeUtils.enforceNominalTyping(rawT);
if (((T instanceof FunctionTypeExpression) && (T.eContainer() == null))) {
final FunctionTypeExpression fte = ((FunctionTypeExpression) T);
fte.setReturnTypeRef(TypeUtils.<TypeRef>copyIfContained(thisTypeRef));
} else {
T = TypeUtils.createFunctionTypeExpression(null, F.getTypeVars(), F.getFpars(), thisTypeRef);
}
}
}
}
}
return new Result<TypeRef>(T);
}
use of org.eclipse.n4js.ts.types.IdentifiableElement in project n4js by eclipse.
the class InternalTypeSystem method applyRuleExpectedTypeInForStatement.
protected Result<TypeRef> applyRuleExpectedTypeInForStatement(final RuleEnvironment G, final RuleApplicationTrace _trace_, final ForStatement forStmnt, final Expression expression) throws RuleFailedException {
// output parameter
TypeRef T = null;
if ((forStmnt.isForOf() && (expression == forStmnt.getExpression()))) {
final Wildcard wildThing = TypeRefsFactory.eINSTANCE.createWildcard();
boolean _isTopOfDestructuringForStatement = DestructureUtils.isTopOfDestructuringForStatement(forStmnt);
if (_isTopOfDestructuringForStatement) {
} else {
VariableDeclaration _xifexpression = null;
boolean _isEmpty = forStmnt.getVarDecl().isEmpty();
boolean _not = (!_isEmpty);
if (_not) {
_xifexpression = forStmnt.getVarDecl().get(0);
}
final VariableDeclaration varDeclInFor = _xifexpression;
VariableDeclaration _xifexpression_1 = null;
if (((forStmnt.getInitExpr() instanceof IdentifierRef) && (((IdentifierRef) forStmnt.getInitExpr()).getId() instanceof VariableDeclaration))) {
Expression _initExpr = forStmnt.getInitExpr();
IdentifiableElement _id = ((IdentifierRef) _initExpr).getId();
_xifexpression_1 = ((VariableDeclaration) _id);
}
final VariableDeclaration varDeclOutside = _xifexpression_1;
boolean _or = false;
TypeRef _declaredTypeRef = null;
if (varDeclInFor != null) {
_declaredTypeRef = varDeclInFor.getDeclaredTypeRef();
}
boolean _tripleNotEquals = (_declaredTypeRef != null);
if (_tripleNotEquals) {
_or = true;
} else {
_or = (varDeclOutside != null);
}
if (_or) {
VariableDeclaration _xifexpression_2 = null;
if ((varDeclOutside != null)) {
_xifexpression_2 = varDeclOutside;
} else {
_xifexpression_2 = varDeclInFor;
}
final VariableDeclaration varDecl = _xifexpression_2;
/* G |- varDecl : var TypeRef varTypeRef */
TypeRef varTypeRef = null;
Result<TypeRef> result = typeInternal(G, _trace_, varDecl);
checkAssignableTo(result.getFirst(), TypeRef.class);
varTypeRef = (TypeRef) result.getFirst();
wildThing.setDeclaredUpperBound(TypeUtils.<TypeRef>copyIfContained(varTypeRef));
}
}
T = RuleEnvironmentExtensions.iterableTypeRef(G, wildThing);
} else {
if ((forStmnt.isForIn() && (expression == forStmnt.getExpression()))) {
T = TypeUtils.createNonSimplifiedUnionType(RuleEnvironmentExtensions.objectTypeRef(G), RuleEnvironmentExtensions.stringTypeRef(G), RuleEnvironmentExtensions.argumentsTypeRef(G));
}
}
return new Result<TypeRef>(T);
}
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