) const { expression } = node as JsxExpression; return !!expression && isContextSensitive(expression); } } return false; } function isContextSensitiveFunctionLikeDeclaration(node: FunctionLikeDeclaration): boolean { // Functions with type parameters are not context sensitive. if (node.typeParameters) { return false; } // Functions with any parameters that lack type annotations are context sensitive. if (some(node.parameters, p => !getEffectiveTypeAnnotationNode(p))) { return true; } if (node.kind !== SyntaxKind.ArrowFunction) { // If the first parameter is not an explicit 'this' parameter, then the function has // an implicit 'this' parameter which is subject to contextual typing. const parameter = firstOrUndefined(node.parameters); if (!(parameter && parameterIsThisKeyword(parameter))) { return true; } } return hasContextSensitiveReturnExpression(node); } function hasContextSensitiveReturnExpression(node: FunctionLikeDeclaration) { // TODO(anhans): A block should be context-sensitive if it has a context-sensitive return value. return !!node.body && node.body.kind !== SyntaxKind.Block && isContextSensitive(node.body); } function isContextSensitiveFunctionOrObjectLiteralMethod(func: Node): func is FunctionExpression | ArrowFunction | MethodDeclaration { return (isInJSFile(func) && isFunctionDeclaration(func) || isFunctionExpressionOrArrowFunction(func) || isObjectLiteralMethod(func)) && isContextSensitiveFunctionLikeDeclaration(func); } function getTypeWithoutSignatures(type: Type): Type { if (type.flags & TypeFlags.Object) { const resolved = resolveStructuredTypeMembers(type); if (resolved.constructSignatures.length || resolved.callSignatures.length) { const result = createObjectType(ObjectFlags.Anonymous, type.symbol); result.members = resolved.members; result.properties = resolved.properties; result.callSignatures = emptyArray; result.constructSignatures = emptyArray; return result; } } else if (type.flags & TypeFlags.Intersection) { return getIntersectionType(map((type).types, getTypeWithoutSignatures)); } return type; } // TYPE CHECKING function isTypeIdenticalTo(source: Type, target: Type): boolean { return isTypeRelatedTo(source, target, identityRelation); } function compareTypesIdentical(source: Type, target: Type): Ternary { return isTypeRelatedTo(source, target, identityRelation) ? Ternary.True : Ternary.False; } function compareTypesAssignable(source: Type, target: Type): Ternary { return isTypeRelatedTo(source, target, assignableRelation) ? Ternary.True : Ternary.False; } function compareTypesSubtypeOf(source: Type, target: Type): Ternary { return isTypeRelatedTo(source, target, subtypeRelation) ? Ternary.True : Ternary.False; } function isTypeSubtypeOf(source: Type, target: Type): boolean { return isTypeRelatedTo(source, target, subtypeRelation); } function isTypeAssignableTo(source: Type, target: Type): boolean { return isTypeRelatedTo(source, target, assignableRelation); } // An object type S is considered to be derived from an object type T if // S is a union type and every constituent of S is derived from T, // T is a union type and S is derived from at least one constituent of T, or // S is a type variable with a base constraint that is derived from T, // T is one of the global types Object and Function and S is a subtype of T, or // T occurs directly or indirectly in an 'extends' clause of S. // Note that this check ignores type parameters and only considers the // inheritance hierarchy. function isTypeDerivedFrom(source: Type, target: Type): boolean { return source.flags & TypeFlags.Union ? every((source).types, t => isTypeDerivedFrom(t, target)) : target.flags & TypeFlags.Union ? some((target).types, t => isTypeDerivedFrom(source, t)) : source.flags & TypeFlags.InstantiableNonPrimitive ? isTypeDerivedFrom(getBaseConstraintOfType(source) || emptyObjectType, target) : target === globalObjectType ? !!(source.flags & (TypeFlags.Object | TypeFlags.NonPrimitive)) : target === globalFunctionType ? !!(source.flags & TypeFlags.Object) && isFunctionObjectType(source as ObjectType) : hasBaseType(source, getTargetType(target)); } /** * This is *not* a bi-directional relationship. * If one needs to check both directions for comparability, use a second call to this function or 'checkTypeComparableTo'. * * A type S is comparable to a type T if some (but not necessarily all) of the possible values of S are also possible values of T. * It is used to check following cases: * - the types of the left and right sides of equality/inequality operators (`===`, `!==`, `==`, `!=`). * - the types of `case` clause expressions and their respective `switch` expressions. * - the type of an expression in a type assertion with the type being asserted. */ function isTypeComparableTo(source: Type, target: Type): boolean { return isTypeRelatedTo(source, target, comparableRelation); } function areTypesComparable(type1: Type, type2: Type): boolean { return isTypeComparableTo(type1, type2) || isTypeComparableTo(type2, type1); } function checkTypeAssignableTo(source: Type, target: Type, errorNode: Node | undefined, headMessage?: DiagnosticMessage, containingMessageChain?: () => DiagnosticMessageChain | undefined, errorOutputObject?: { error?: Diagnostic }): boolean { return checkTypeRelatedTo(source, target, assignableRelation, errorNode, headMessage, containingMessageChain, errorOutputObject); } /** * Like `checkTypeAssignableTo`, but if it would issue an error, instead performs structural comparisons of the types using the given expression node to * attempt to issue more specific errors on, for example, specific object literal properties or tuple members. */ function checkTypeAssignableToAndOptionallyElaborate(source: Type, target: Type, errorNode: Node | undefined, expr: Expression | undefined, headMessage?: DiagnosticMessage, containingMessageChain?: () => DiagnosticMessageChain | undefined): boolean { return checkTypeRelatedToAndOptionallyElaborate(source, target, assignableRelation, errorNode, expr, headMessage, containingMessageChain); } function checkTypeRelatedToAndOptionallyElaborate(source: Type, target: Type, relation: Map, errorNode: Node | undefined, expr: Expression | undefined, headMessage?: DiagnosticMessage, containingMessageChain?: () => DiagnosticMessageChain | undefined): boolean { if (isTypeRelatedTo(source, target, relation)) return true; if (!errorNode || !elaborateError(expr, source, target, relation, headMessage)) { return checkTypeRelatedTo(source, target, relation, errorNode, headMessage, containingMessageChain); } return false; } function isOrHasGenericConditional(type: Type): boolean { return !!(type.flags & TypeFlags.Conditional || (type.flags & TypeFlags.Intersection && some((type as IntersectionType).types, isOrHasGenericConditional))); } function elaborateError(node: Expression | undefined, source: Type, target: Type, relation: Map, headMessage: DiagnosticMessage | undefined): boolean { if (!node || isOrHasGenericConditional(target)) return false; if (!checkTypeRelatedTo(source, target, relation, /*errorNode*/ undefined) && elaborateDidYouMeanToCallOrConstruct(node, source, target, relation, headMessage)) { return true; } switch (node.kind) { case SyntaxKind.JsxExpression: case SyntaxKind.ParenthesizedExpression: return elaborateError((node as ParenthesizedExpression | JsxExpression).expression, source, target, relation, headMessage); case SyntaxKind.BinaryExpression: switch ((node as BinaryExpression).operatorToken.kind) { case SyntaxKind.EqualsToken: case SyntaxKind.CommaToken: return elaborateError((node as BinaryExpression).right, source, target, relation, headMessage); } break; case SyntaxKind.ObjectLiteralExpression: return elaborateObjectLiteral(node as ObjectLiteralExpression, source, target, relation); case SyntaxKind.ArrayLiteralExpression: return elaborateArrayLiteral(node as ArrayLiteralExpression, source, target, relation); case SyntaxKind.JsxAttributes: return elaborateJsxComponents(node as JsxAttributes, source, target, relation); case SyntaxKind.ArrowFunction: return elaborateArrowFunction(node as ArrowFunction, source, target, relation); } return false; } function elaborateDidYouMeanToCallOrConstruct(node: Expression, source: Type, target: Type, relation: Map, headMessage: DiagnosticMessage | undefined): boolean { const callSignatures = getSignaturesOfType(source, SignatureKind.Call); const constructSignatures = getSignaturesOfType(source, SignatureKind.Construct); for (const signatures of [constructSignatures, callSignatures]) { if (some(signatures, s => { const returnType = getReturnTypeOfSignature(s); return !(returnType.flags & (TypeFlags.Any | TypeFlags.Never)) && checkTypeRelatedTo(returnType, target, relation, /*errorNode*/ undefined); })) { const resultObj: { error?: Diagnostic } = {}; checkTypeAssignableTo(source, target, node, headMessage, /*containingChain*/ undefined, resultObj); const diagnostic = resultObj.error!; addRelatedInfo(diagnostic, createDiagnosticForNode( node, signatures === constructSignatures ? Diagnostics.Did_you_mean_to_use_new_with_this_expression : Diagnostics.Did_you_mean_to_call_this_expression )); return true; } } return false; } function elaborateArrowFunction(node: ArrowFunction, source: Type, target: Type, relation: Map): boolean { // Don't elaborate blocks if (isBlock(node.body)) { return false; } // Or functions with annotated parameter types if (some(node.parameters, ts.hasType)) { return false; } const sourceSig = getSingleCallSignature(source); if (!sourceSig) { return false; } const targetSignatures = getSignaturesOfType(target, SignatureKind.Call); if (!length(targetSignatures)) { return false; } const returnExpression = node.body; const sourceReturn = getReturnTypeOfSignature(sourceSig); const targetReturn = getUnionType(map(targetSignatures, getReturnTypeOfSignature)); if (!checkTypeRelatedTo(sourceReturn, targetReturn, relation, /*errorNode*/ undefined)) { const elaborated = returnExpression && elaborateError(returnExpression, sourceReturn, targetReturn, relation, /*headMessage*/ undefined); if (elaborated) { return elaborated; } const resultObj: { error?: Diagnostic } = {}; checkTypeRelatedTo(sourceReturn, targetReturn, relation, returnExpression, /*message*/ undefined, /*chain*/ undefined, resultObj); if (resultObj.error) { if (target.symbol && length(target.symbol.declarations)) { addRelatedInfo(resultObj.error, createDiagnosticForNode( target.symbol.declarations[0], Diagnostics.The_expected_type_comes_from_the_return_type_of_this_signature, )); } return true; } } return false; } type ElaborationIterator = IterableIterator<{ errorNode: Node, innerExpression: Expression | undefined, nameType: Type, errorMessage?: DiagnosticMessage | undefined }>; /** * For every element returned from the iterator, checks that element to issue an error on a property of that element's type * If that element would issue an error, we first attempt to dive into that element's inner expression and issue a more specific error by recuring into `elaborateError` * Otherwise, we issue an error on _every_ element which fail the assignability check */ function elaborateElementwise(iterator: ElaborationIterator, source: Type, target: Type, relation: Map) { // Assignability failure - check each prop individually, and if that fails, fall back on the bad error span let reportedError = false; for (let status = iterator.next(); !status.done; status = iterator.next()) { const { errorNode: prop, innerExpression: next, nameType, errorMessage } = status.value; const targetPropType = getIndexedAccessType(target, nameType, /*accessNode*/ undefined, errorType); if (targetPropType === errorType || targetPropType.flags & TypeFlags.IndexedAccess) continue; // Don't elaborate on indexes on generic variables const sourcePropType = getIndexedAccessType(source, nameType, /*accessNode*/ undefined, errorType); if (sourcePropType !== errorType && targetPropType !== errorType && !checkTypeRelatedTo(sourcePropType, targetPropType, relation, /*errorNode*/ undefined)) { const elaborated = next && elaborateError(next, sourcePropType, targetPropType, relation, /*headMessage*/ undefined); if (elaborated) { reportedError = true; } else { // Issue error on the prop itself, since the prop couldn't elaborate the error const resultObj: { error?: Diagnostic } = {}; // Use the expression type, if available const specificSource = next ? checkExpressionForMutableLocation(next, CheckMode.Normal, sourcePropType) : sourcePropType; const result = checkTypeRelatedTo(specificSource, targetPropType, relation, prop, errorMessage, /*containingChain*/ undefined, resultObj); if (result && specificSource !== sourcePropType) { // If for whatever reason the expression type doesn't yield an error, make sure we still issue an error on the sourcePropType checkTypeRelatedTo(sourcePropType, targetPropType, relation, prop, errorMessage, /*containingChain*/ undefined, resultObj); } if (resultObj.error) { const reportedDiag = resultObj.error; const propertyName = isTypeUsableAsPropertyName(nameType) ? getPropertyNameFromType(nameType) : undefined; const targetProp = propertyName !== undefined ? getPropertyOfType(target, propertyName) : undefined; let issuedElaboration = false; if (!targetProp) { const indexInfo = isTypeAssignableToKind(nameType, TypeFlags.NumberLike) && getIndexInfoOfType(target, IndexKind.Number) || getIndexInfoOfType(target, IndexKind.String) || undefined; if (indexInfo && indexInfo.declaration && !getSourceFileOfNode(indexInfo.declaration).hasNoDefaultLib) { issuedElaboration = true; addRelatedInfo(reportedDiag, createDiagnosticForNode(indexInfo.declaration, Diagnostics.The_expected_type_comes_from_this_index_signature)); } } if (!issuedElaboration && (targetProp && length(targetProp.declarations) || target.symbol && length(target.symbol.declarations))) { const targetNode = targetProp && length(targetProp.declarations) ? targetProp.declarations[0] : target.symbol.declarations[0]; if (!getSourceFileOfNode(targetNode).hasNoDefaultLib) { addRelatedInfo(reportedDiag, createDiagnosticForNode( targetNode, Diagnostics.The_expected_type_comes_from_property_0_which_is_declared_here_on_type_1, propertyName && !(nameType.flags & TypeFlags.UniqueESSymbol) ? unescapeLeadingUnderscores(propertyName) : typeToString(nameType), typeToString(target) )); } } } reportedError = true; } } } return reportedError; } function *generateJsxAttributes(node: JsxAttributes): ElaborationIterator { if (!length(node.properties)) return; for (const prop of node.properties) { if (isJsxSpreadAttribute(prop)) continue; yield { errorNode: prop.name, innerExpression: prop.initializer, nameType: getLiteralType(idText(prop.name)) }; } } function *generateJsxChildren(node: JsxElement, getInvalidTextDiagnostic: () => DiagnosticMessage): ElaborationIterator { if (!length(node.children)) return; let memberOffset = 0; for (let i = 0; i < node.children.length; i++) { const child = node.children[i]; const nameType = getLiteralType(i - memberOffset); const elem = getElaborationElementForJsxChild(child, nameType, getInvalidTextDiagnostic); if (elem) { yield elem; } else { memberOffset++; } } } function getElaborationElementForJsxChild(child: JsxChild, nameType: LiteralType, getInvalidTextDiagnostic: () => DiagnosticMessage) { switch (child.kind) { case SyntaxKind.JsxExpression: // child is of the type of the expression return { errorNode: child, innerExpression: child.expression, nameType }; case SyntaxKind.JsxText: if (child.containsOnlyWhiteSpaces) { break; // Whitespace only jsx text isn't real jsx text } // child is a string return { errorNode: child, innerExpression: undefined, nameType, errorMessage: getInvalidTextDiagnostic() }; case SyntaxKind.JsxElement: case SyntaxKind.JsxSelfClosingElement: case SyntaxKind.JsxFragment: // child is of type JSX.Element return { errorNode: child, innerExpression: child, nameType }; default: return Debug.assertNever(child, "Found invalid jsx child"); } } function elaborateJsxComponents(node: JsxAttributes, source: Type, target: Type, relation: Map) { let result = elaborateElementwise(generateJsxAttributes(node), source, target, relation); let invalidTextDiagnostic: DiagnosticMessage | undefined; if (isJsxOpeningElement(node.parent) && isJsxElement(node.parent.parent)) { const containingElement = node.parent.parent; const childPropName = getJsxElementChildrenPropertyName(getJsxNamespaceAt(node)); const childrenPropName = childPropName === undefined ? "children" : unescapeLeadingUnderscores(childPropName); const childrenNameType = getLiteralType(childrenPropName); const childrenTargetType = getIndexedAccessType(target, childrenNameType); const validChildren = filter(containingElement.children, i => !isJsxText(i) || !i.containsOnlyWhiteSpaces); if (!length(validChildren)) { return result; } const moreThanOneRealChildren = length(validChildren) > 1; const arrayLikeTargetParts = filterType(childrenTargetType, isArrayOrTupleLikeType); const nonArrayLikeTargetParts = filterType(childrenTargetType, t => !isArrayOrTupleLikeType(t)); if (moreThanOneRealChildren) { if (arrayLikeTargetParts !== neverType) { const realSource = createTupleType(checkJsxChildren(containingElement, CheckMode.Normal)); result = elaborateElementwise(generateJsxChildren(containingElement, getInvalidTextualChildDiagnostic), realSource, arrayLikeTargetParts, relation) || result; } else if (!isTypeRelatedTo(getIndexedAccessType(source, childrenNameType), childrenTargetType, relation)) { // arity mismatch result = true; error( containingElement.openingElement.tagName, Diagnostics.This_JSX_tag_s_0_prop_expects_a_single_child_of_type_1_but_multiple_children_were_provided, childrenPropName, typeToString(childrenTargetType) ); } } else { if (nonArrayLikeTargetParts !== neverType) { const child = validChildren[0]; const elem = getElaborationElementForJsxChild(child, childrenNameType, getInvalidTextualChildDiagnostic); if (elem) { result = elaborateElementwise( (function*() { yield elem; })(), source, target, relation ) || result; } } else if (!isTypeRelatedTo(getIndexedAccessType(source, childrenNameType), childrenTargetType, relation)) { // arity mismatch result = true; error( containingElement.openingElement.tagName, Diagnostics.This_JSX_tag_s_0_prop_expects_type_1_which_requires_multiple_children_but_only_a_single_child_was_provided, childrenPropName, typeToString(childrenTargetType) ); } } } return result; function getInvalidTextualChildDiagnostic() { if (!invalidTextDiagnostic) { const tagNameText = getTextOfNode(node.parent.tagName); const childPropName = getJsxElementChildrenPropertyName(getJsxNamespaceAt(node)); const childrenPropName = childPropName === undefined ? "children" : unescapeLeadingUnderscores(childPropName); const childrenTargetType = getIndexedAccessType(target, getLiteralType(childrenPropName)); const diagnostic = Diagnostics._0_components_don_t_accept_text_as_child_elements_Text_in_JSX_has_the_type_string_but_the_expected_type_of_1_is_2; invalidTextDiagnostic = { ...diagnostic, key: "!!ALREADY FORMATTED!!", message: formatMessage(/*_dummy*/ undefined, diagnostic, tagNameText, childrenPropName, typeToString(childrenTargetType)) }; } return invalidTextDiagnostic; } } function *generateLimitedTupleElements(node: ArrayLiteralExpression, target: Type): ElaborationIterator { const len = length(node.elements); if (!len) return; for (let i = 0; i < len; i++) { // Skip elements which do not exist in the target - a length error on the tuple overall is likely better than an error on a mismatched index signature if (isTupleLikeType(target) && !getPropertyOfType(target, ("" + i) as __String)) continue; const elem = node.elements[i]; if (isOmittedExpression(elem)) continue; const nameType = getLiteralType(i); yield { errorNode: elem, innerExpression: elem, nameType }; } } function elaborateArrayLiteral(node: ArrayLiteralExpression, source: Type, target: Type, relation: Map) { if (isTupleLikeType(source)) { return elaborateElementwise(generateLimitedTupleElements(node, target), source, target, relation); } // recreate a tuple from the elements, if possible const tupleizedType = checkArrayLiteral(node, CheckMode.Contextual, /*forceTuple*/ true); if (isTupleLikeType(tupleizedType)) { return elaborateElementwise(generateLimitedTupleElements(node, target), tupleizedType, target, relation); } return false; } function *generateObjectLiteralElements(node: ObjectLiteralExpression): ElaborationIterator { if (!length(node.properties)) return; for (const prop of node.properties) { if (isSpreadAssignment(prop)) continue; const type = getLiteralTypeFromProperty(getSymbolOfNode(prop), TypeFlags.StringOrNumberLiteralOrUnique); if (!type || (type.flags & TypeFlags.Never)) { continue; } switch (prop.kind) { case SyntaxKind.SetAccessor: case SyntaxKind.GetAccessor: case SyntaxKind.MethodDeclaration: case SyntaxKind.ShorthandPropertyAssignment: yield { errorNode: prop.name, innerExpression: undefined, nameType: type }; break; case SyntaxKind.PropertyAssignment: yield { errorNode: prop.name, innerExpression: prop.initializer, nameType: type, errorMessage: isComputedNonLiteralName(prop.name) ? Diagnostics.Type_of_computed_property_s_value_is_0_which_is_not_assignable_to_type_1 : undefined }; break; default: Debug.assertNever(prop); } } } function elaborateObjectLiteral(node: ObjectLiteralExpression, source: Type, target: Type, relation: Map) { return elaborateElementwise(generateObjectLiteralElements(node), source, target, relation); } /** * This is *not* a bi-directional relationship. * If one needs to check both directions for comparability, use a second call to this function or 'isTypeComparableTo'. */ function checkTypeComparableTo(source: Type, target: Type, errorNode: Node, headMessage?: DiagnosticMessage, containingMessageChain?: () => DiagnosticMessageChain | undefined): boolean { return checkTypeRelatedTo(source, target, comparableRelation, errorNode, headMessage, containingMessageChain); } function isSignatureAssignableTo(source: Signature, target: Signature, ignoreReturnTypes: boolean): boolean { return compareSignaturesRelated(source, target, CallbackCheck.None, ignoreReturnTypes, /*reportErrors*/ false, /*errorReporter*/ undefined, compareTypesAssignable) !== Ternary.False; } type ErrorReporter = (message: DiagnosticMessage, arg0?: string, arg1?: string) => void; /** * See signatureRelatedTo, compareSignaturesIdentical */ function compareSignaturesRelated(source: Signature, target: Signature, callbackCheck: CallbackCheck, ignoreReturnTypes: boolean, reportErrors: boolean, errorReporter: ErrorReporter | undefined, compareTypes: TypeComparer): Ternary { // TODO (drosen): De-duplicate code between related functions. if (source === target) { return Ternary.True; } const targetCount = getParameterCount(target); if (!hasEffectiveRestParameter(target) && getMinArgumentCount(source) > targetCount) { return Ternary.False; } if (source.typeParameters && source.typeParameters !== target.typeParameters) { target = getCanonicalSignature(target); source = instantiateSignatureInContextOf(source, target, /*contextualMapper*/ undefined, compareTypes); } const sourceCount = getParameterCount(source); const sourceRestType = getNonArrayRestType(source); const targetRestType = getNonArrayRestType(target); if (sourceRestType && targetRestType && sourceCount !== targetCount) { // We're not able to relate misaligned complex rest parameters return Ternary.False; } const kind = target.declaration ? target.declaration.kind : SyntaxKind.Unknown; const strictVariance = !callbackCheck && strictFunctionTypes && kind !== SyntaxKind.MethodDeclaration && kind !== SyntaxKind.MethodSignature && kind !== SyntaxKind.Constructor; let result = Ternary.True; const sourceThisType = getThisTypeOfSignature(source); if (sourceThisType && sourceThisType !== voidType) { const targetThisType = getThisTypeOfSignature(target); if (targetThisType) { // void sources are assignable to anything. const related = !strictVariance && compareTypes(sourceThisType, targetThisType, /*reportErrors*/ false) || compareTypes(targetThisType, sourceThisType, reportErrors); if (!related) { if (reportErrors) { errorReporter!(Diagnostics.The_this_types_of_each_signature_are_incompatible); } return Ternary.False; } result &= related; } } const paramCount = sourceRestType || targetRestType ? Math.min(sourceCount, targetCount) : Math.max(sourceCount, targetCount); const restIndex = sourceRestType || targetRestType ? paramCount - 1 : -1; for (let i = 0; i < paramCount; i++) { const sourceType = i === restIndex ? getRestTypeAtPosition(source, i) : getTypeAtPosition(source, i); const targetType = i === restIndex ? getRestTypeAtPosition(target, i) : getTypeAtPosition(target, i); // In order to ensure that any generic type Foo is at least co-variant with respect to T no matter // how Foo uses T, we need to relate parameters bi-variantly (given that parameters are input positions, // they naturally relate only contra-variantly). However, if the source and target parameters both have // function types with a single call signature, we know we are relating two callback parameters. In // that case it is sufficient to only relate the parameters of the signatures co-variantly because, // similar to return values, callback parameters are output positions. This means that a Promise, // where T is used only in callback parameter positions, will be co-variant (as opposed to bi-variant) // with respect to T. const sourceSig = callbackCheck ? undefined : getSingleCallSignature(getNonNullableType(sourceType)); const targetSig = callbackCheck ? undefined : getSingleCallSignature(getNonNullableType(targetType)); const callbacks = sourceSig && targetSig && !signatureHasTypePredicate(sourceSig) && !signatureHasTypePredicate(targetSig) && (getFalsyFlags(sourceType) & TypeFlags.Nullable) === (getFalsyFlags(targetType) & TypeFlags.Nullable); const related = callbacks ? // TODO: GH#18217 It will work if they're both `undefined`, but not if only one is compareSignaturesRelated(targetSig!, sourceSig!, strictVariance ? CallbackCheck.Strict : CallbackCheck.Bivariant, /*ignoreReturnTypes*/ false, reportErrors, errorReporter, compareTypes) : !callbackCheck && !strictVariance && compareTypes(sourceType, targetType, /*reportErrors*/ false) || compareTypes(targetType, sourceType, reportErrors); if (!related) { if (reportErrors) { errorReporter!(Diagnostics.Types_of_parameters_0_and_1_are_incompatible, unescapeLeadingUnderscores(getParameterNameAtPosition(source, i)), unescapeLeadingUnderscores(getParameterNameAtPosition(target, i))); } return Ternary.False; } result &= related; } if (!ignoreReturnTypes) { const targetReturnType = (target.declaration && isJSConstructor(target.declaration)) ? getJSClassType(target.declaration.symbol)! : getReturnTypeOfSignature(target); if (targetReturnType === voidType) { return result; } const sourceReturnType = (source.declaration && isJSConstructor(source.declaration)) ? getJSClassType(source.declaration.symbol)! : getReturnTypeOfSignature(source); // The following block preserves behavior forbidding boolean returning functions from being assignable to type guard returning functions const targetTypePredicate = getTypePredicateOfSignature(target); if (targetTypePredicate) { const sourceTypePredicate = getTypePredicateOfSignature(source); if (sourceTypePredicate) { result &= compareTypePredicateRelatedTo(sourceTypePredicate, targetTypePredicate, source.declaration!, target.declaration!, reportErrors, errorReporter, compareTypes); // TODO: GH#18217 } else if (isIdentifierTypePredicate(targetTypePredicate)) { if (reportErrors) { errorReporter!(Diagnostics.Signature_0_must_be_a_type_predicate, signatureToString(source)); } return Ternary.False; } } else { // When relating callback signatures, we still need to relate return types bi-variantly as otherwise // the containing type wouldn't be co-variant. For example, interface Foo { add(cb: () => T): void } // wouldn't be co-variant for T without this rule. result &= callbackCheck === CallbackCheck.Bivariant && compareTypes(targetReturnType, sourceReturnType, /*reportErrors*/ false) || compareTypes(sourceReturnType, targetReturnType, reportErrors); } } return result; } function compareTypePredicateRelatedTo( source: TypePredicate, target: TypePredicate, sourceDeclaration: SignatureDeclaration | JSDocSignature, targetDeclaration: SignatureDeclaration | JSDocSignature, reportErrors: boolean, errorReporter: ErrorReporter | undefined, compareTypes: (s: Type, t: Type, reportErrors?: boolean) => Ternary): Ternary { if (source.kind !== target.kind) { if (reportErrors) { errorReporter!(Diagnostics.A_this_based_type_guard_is_not_compatible_with_a_parameter_based_type_guard); errorReporter!(Diagnostics.Type_predicate_0_is_not_assignable_to_1, typePredicateToString(source), typePredicateToString(target)); } return Ternary.False; } if (source.kind === TypePredicateKind.Identifier) { const targetPredicate = target as IdentifierTypePredicate; const sourceIndex = source.parameterIndex - (getThisParameter(sourceDeclaration) ? 1 : 0); const targetIndex = targetPredicate.parameterIndex - (getThisParameter(targetDeclaration) ? 1 : 0); if (sourceIndex !== targetIndex) { if (reportErrors) { errorReporter!(Diagnostics.Parameter_0_is_not_in_the_same_position_as_parameter_1, source.parameterName, targetPredicate.parameterName); errorReporter!(Diagnostics.Type_predicate_0_is_not_assignable_to_1, typePredicateToString(source), typePredicateToString(target)); } return Ternary.False; } } const related = compareTypes(source.type, target.type, reportErrors); if (related === Ternary.False && reportErrors) { errorReporter!(Diagnostics.Type_predicate_0_is_not_assignable_to_1, typePredicateToString(source), typePredicateToString(target)); } return related; } function isImplementationCompatibleWithOverload(implementation: Signature, overload: Signature): boolean { const erasedSource = getErasedSignature(implementation); const erasedTarget = getErasedSignature(overload); // First see if the return types are compatible in either direction. const sourceReturnType = getReturnTypeOfSignature(erasedSource); const targetReturnType = getReturnTypeOfSignature(erasedTarget); if (targetReturnType === voidType || isTypeRelatedTo(targetReturnType, sourceReturnType, assignableRelation) || isTypeRelatedTo(sourceReturnType, targetReturnType, assignableRelation)) { return isSignatureAssignableTo(erasedSource, erasedTarget, /*ignoreReturnTypes*/ true); } return false; } function isEmptyResolvedType(t: ResolvedType) { return t.properties.length === 0 && t.callSignatures.length === 0 && t.constructSignatures.length === 0 && !t.stringIndexInfo && !t.numberIndexInfo; } function isEmptyObjectType(type: Type): boolean { return type.flags & TypeFlags.Object ? !isGenericMappedType(type) && isEmptyResolvedType(resolveStructuredTypeMembers(type)) : type.flags & TypeFlags.NonPrimitive ? true : type.flags & TypeFlags.Union ? some((type).types, isEmptyObjectType) : type.flags & TypeFlags.Intersection ? every((type).types, isEmptyObjectType) : false; } function isEmptyAnonymousObjectType(type: Type) { return !!(getObjectFlags(type) & ObjectFlags.Anonymous) && isEmptyObjectType(type); } function isEnumTypeRelatedTo(sourceSymbol: Symbol, targetSymbol: Symbol, errorReporter?: ErrorReporter) { if (sourceSymbol === targetSymbol) { return true; } const id = getSymbolId(sourceSymbol) + "," + getSymbolId(targetSymbol); const relation = enumRelation.get(id); if (relation !== undefined && !(relation === RelationComparisonResult.Failed && errorReporter)) { return relation === RelationComparisonResult.Succeeded; } if (sourceSymbol.escapedName !== targetSymbol.escapedName || !(sourceSymbol.flags & SymbolFlags.RegularEnum) || !(targetSymbol.flags & SymbolFlags.RegularEnum)) { enumRelation.set(id, RelationComparisonResult.FailedAndReported); return false; } const targetEnumType = getTypeOfSymbol(targetSymbol); for (const property of getPropertiesOfType(getTypeOfSymbol(sourceSymbol))) { if (property.flags & SymbolFlags.EnumMember) { const targetProperty = getPropertyOfType(targetEnumType, property.escapedName); if (!targetProperty || !(targetProperty.flags & SymbolFlags.EnumMember)) { if (errorReporter) { errorReporter(Diagnostics.Property_0_is_missing_in_type_1, symbolName(property), typeToString(getDeclaredTypeOfSymbol(targetSymbol), /*enclosingDeclaration*/ undefined, TypeFormatFlags.UseFullyQualifiedType)); enumRelation.set(id, RelationComparisonResult.FailedAndReported); } else { enumRelation.set(id, RelationComparisonResult.Failed); } return false; } } } enumRelation.set(id, RelationComparisonResult.Succeeded); return true; } function isSimpleTypeRelatedTo(source: Type, target: Type, relation: Map, errorReporter?: ErrorReporter) { const s = source.flags; const t = target.flags; if (t & TypeFlags.AnyOrUnknown || s & TypeFlags.Never || source === wildcardType) return true; if (t & TypeFlags.Never) return false; if (s & TypeFlags.StringLike && t & TypeFlags.String) return true; if (s & TypeFlags.StringLiteral && s & TypeFlags.EnumLiteral && t & TypeFlags.StringLiteral && !(t & TypeFlags.EnumLiteral) && (source).value === (target).value) return true; if (s & TypeFlags.NumberLike && t & TypeFlags.Number) return true; if (s & TypeFlags.NumberLiteral && s & TypeFlags.EnumLiteral && t & TypeFlags.NumberLiteral && !(t & TypeFlags.EnumLiteral) && (source).value === (target).value) return true; if (s & TypeFlags.BigIntLike && t & TypeFlags.BigInt) return true; if (s & TypeFlags.BooleanLike && t & TypeFlags.Boolean) return true; if (s & TypeFlags.ESSymbolLike && t & TypeFlags.ESSymbol) return true; if (s & TypeFlags.Enum && t & TypeFlags.Enum && isEnumTypeRelatedTo(source.symbol, target.symbol, errorReporter)) return true; if (s & TypeFlags.EnumLiteral && t & TypeFlags.EnumLiteral) { if (s & TypeFlags.Union && t & TypeFlags.Union && isEnumTypeRelatedTo(source.symbol, target.symbol, errorReporter)) return true; if (s & TypeFlags.Literal && t & TypeFlags.Literal && (source).value === (target).value && isEnumTypeRelatedTo(getParentOfSymbol(source.symbol)!, getParentOfSymbol(target.symbol)!, errorReporter)) return true; } if (s & TypeFlags.Undefined && (!strictNullChecks || t & (TypeFlags.Undefined | TypeFlags.Void))) return true; if (s & TypeFlags.Null && (!strictNullChecks || t & TypeFlags.Null)) return true; if (s & TypeFlags.Object && t & TypeFlags.NonPrimitive) return true; if (relation === assignableRelation || relation === comparableRelation) { if (s & TypeFlags.Any) return true; // Type number or any numeric literal type is assignable to any numeric enum type or any // numeric enum literal type. This rule exists for backwards compatibility reasons because // bit-flag enum types sometimes look like literal enum types with numeric literal values. if (s & (TypeFlags.Number | TypeFlags.NumberLiteral) && !(s & TypeFlags.EnumLiteral) && ( t & TypeFlags.Enum || t & TypeFlags.NumberLiteral && t & TypeFlags.EnumLiteral)) return true; } return false; } function isTypeRelatedTo(source: Type, target: Type, relation: Map) { if (isFreshLiteralType(source)) { source = (source).regularType; } if (isFreshLiteralType(target)) { target = (target).regularType; } if (source === target || relation === comparableRelation && !(target.flags & TypeFlags.Never) && isSimpleTypeRelatedTo(target, source, relation) || relation !== identityRelation && isSimpleTypeRelatedTo(source, target, relation)) { return true; } if (source.flags & TypeFlags.Object && target.flags & TypeFlags.Object) { const related = relation.get(getRelationKey(source, target, relation)); if (related !== undefined) { return related === RelationComparisonResult.Succeeded; } } if (source.flags & TypeFlags.StructuredOrInstantiable || target.flags & TypeFlags.StructuredOrInstantiable) { return checkTypeRelatedTo(source, target, relation, /*errorNode*/ undefined); } return false; } function isIgnoredJsxProperty(source: Type, sourceProp: Symbol, targetMemberType: Type | undefined) { return getObjectFlags(source) & ObjectFlags.JsxAttributes && !(isUnhyphenatedJsxName(sourceProp.escapedName) || targetMemberType); } /** * Checks if 'source' is related to 'target' (e.g.: is a assignable to). * @param source The left-hand-side of the relation. * @param target The right-hand-side of the relation. * @param relation The relation considered. One of 'identityRelation', 'subtypeRelation', 'assignableRelation', or 'comparableRelation'. * Used as both to determine which checks are performed and as a cache of previously computed results. * @param errorNode The suggested node upon which all errors will be reported, if defined. This may or may not be the actual node used. * @param headMessage If the error chain should be prepended by a head message, then headMessage will be used. * @param containingMessageChain A chain of errors to prepend any new errors found. */ function checkTypeRelatedTo( source: Type, target: Type, relation: Map, errorNode: Node | undefined, headMessage?: DiagnosticMessage, containingMessageChain?: () => DiagnosticMessageChain | undefined, errorOutputContainer?: { error?: Diagnostic } ): boolean { let errorInfo: DiagnosticMessageChain | undefined; let relatedInfo: [DiagnosticRelatedInformation, ...DiagnosticRelatedInformation[]] | undefined; let maybeKeys: string[]; let sourceStack: Type[]; let targetStack: Type[]; let maybeCount = 0; let depth = 0; let expandingFlags = ExpandingFlags.None; let overflow = false; let suppressNextError = false; Debug.assert(relation !== identityRelation || !errorNode, "no error reporting in identity checking"); const result = isRelatedTo(source, target, /*reportErrors*/ !!errorNode, headMessage); if (overflow) { error(errorNode, Diagnostics.Excessive_stack_depth_comparing_types_0_and_1, typeToString(source), typeToString(target)); } else if (errorInfo) { if (containingMessageChain) { const chain = containingMessageChain(); if (chain) { errorInfo = concatenateDiagnosticMessageChains(chain, errorInfo); } } let relatedInformation: DiagnosticRelatedInformation[] | undefined; // Check if we should issue an extra diagnostic to produce a quickfix for a slightly incorrect import statement if (headMessage && errorNode && !result && source.symbol) { const links = getSymbolLinks(source.symbol); if (links.originatingImport && !isImportCall(links.originatingImport)) { const helpfulRetry = checkTypeRelatedTo(getTypeOfSymbol(links.target!), target, relation, /*errorNode*/ undefined); if (helpfulRetry) { // Likely an incorrect import. Issue a helpful diagnostic to produce a quickfix to change the import const diag = createDiagnosticForNode(links.originatingImport, Diagnostics.Type_originates_at_this_import_A_namespace_style_import_cannot_be_called_or_constructed_and_will_cause_a_failure_at_runtime_Consider_using_a_default_import_or_import_require_here_instead); relatedInformation = append(relatedInformation, diag); // Cause the error to appear with the error that triggered it } } } const diag = createDiagnosticForNodeFromMessageChain(errorNode!, errorInfo, relatedInformation); if (relatedInfo) { addRelatedInfo(diag, ...relatedInfo); } if (errorOutputContainer) { errorOutputContainer.error = diag; } diagnostics.add(diag); // TODO: GH#18217 } return result !== Ternary.False; function reportError(message: DiagnosticMessage, arg0?: string | number, arg1?: string | number, arg2?: string | number, arg3?: string | number): void { Debug.assert(!!errorNode); errorInfo = chainDiagnosticMessages(errorInfo, message, arg0, arg1, arg2, arg3); } function associateRelatedInfo(info: DiagnosticRelatedInformation) { Debug.assert(!!errorInfo); if (!relatedInfo) { relatedInfo = [info]; } else { relatedInfo.push(info); } } function reportRelationError(message: DiagnosticMessage | undefined, source: Type, target: Type) { let sourceType = typeToString(source); let targetType = typeToString(target); if (sourceType === targetType) { sourceType = typeToString(source, /*enclosingDeclaration*/ undefined, TypeFormatFlags.UseFullyQualifiedType); targetType = typeToString(target, /*enclosingDeclaration*/ undefined, TypeFormatFlags.UseFullyQualifiedType); } if (!message) { if (relation === comparableRelation) { message = Diagnostics.Type_0_is_not_comparable_to_type_1; } else if (sourceType === targetType) { message = Diagnostics.Type_0_is_not_assignable_to_type_1_Two_different_types_with_this_name_exist_but_they_are_unrelated; } else { message = Diagnostics.Type_0_is_not_assignable_to_type_1; } } reportError(message, sourceType, targetType); } function tryElaborateErrorsForPrimitivesAndObjects(source: Type, target: Type) { const sourceType = typeToString(source); const targetType = typeToString(target); if ((globalStringType === source && stringType === target) || (globalNumberType === source && numberType === target) || (globalBooleanType === source && booleanType === target) || (getGlobalESSymbolType(/*reportErrors*/ false) === source && esSymbolType === target)) { reportError(Diagnostics._0_is_a_primitive_but_1_is_a_wrapper_object_Prefer_using_0_when_possible, targetType, sourceType); } } function isUnionOrIntersectionTypeWithoutNullableConstituents(type: Type): boolean { if (!(type.flags & TypeFlags.UnionOrIntersection)) { return false; } // at this point we know that this is union or intersection type possibly with nullable constituents. // check if we still will have compound type if we ignore nullable components. let seenNonNullable = false; for (const t of (type).types) { if (t.flags & TypeFlags.Nullable) { continue; } if (seenNonNullable) { return true; } seenNonNullable = true; } return false; } /** * Compare two types and return * * Ternary.True if they are related with no assumptions, * * Ternary.Maybe if they are related with assumptions of other relationships, or * * Ternary.False if they are not related. */ function isRelatedTo(source: Type, target: Type, reportErrors = false, headMessage?: DiagnosticMessage, isApparentIntersectionConstituent?: boolean): Ternary { if (isFreshLiteralType(source)) { source = (source).regularType; } if (isFreshLiteralType(target)) { target = (target).regularType; } if (source.flags & TypeFlags.Substitution) { source = (source).substitute; } if (target.flags & TypeFlags.Substitution) { target = (target).typeVariable; } if (source.flags & TypeFlags.IndexedAccess) { source = getSimplifiedType(source); } if (target.flags & TypeFlags.IndexedAccess) { target = getSimplifiedType(target); } // Try to see if we're relating something like `Foo` -> `Bar | null | undefined`. // If so, reporting the `null` and `undefined` in the type is hardly useful. // First, see if we're even relating an object type to a union. // Then see if the target is stripped down to a single non-union type. // Note // * We actually want to remove null and undefined naively here (rather than using getNonNullableType), // since we don't want to end up with a worse error like "`Foo` is not assignable to `NonNullable`" // when dealing with generics. // * We also don't deal with primitive source types, since we already halt elaboration below. if (target.flags & TypeFlags.Union && source.flags & TypeFlags.Object && (target as UnionType).types.length <= 3 && maybeTypeOfKind(target, TypeFlags.Nullable)) { const nullStrippedTarget = extractTypesOfKind(target, ~TypeFlags.Nullable); if (!(nullStrippedTarget.flags & (TypeFlags.Union | TypeFlags.Never))) { target = nullStrippedTarget; } } // both types are the same - covers 'they are the same primitive type or both are Any' or the same type parameter cases if (source === target) return Ternary.True; if (relation === identityRelation) { return isIdenticalTo(source, target); } if (relation === comparableRelation && !(target.flags & TypeFlags.Never) && isSimpleTypeRelatedTo(target, source, relation) || isSimpleTypeRelatedTo(source, target, relation, reportErrors ? reportError : undefined)) return Ternary.True; const isComparingJsxAttributes = !!(getObjectFlags(source) & ObjectFlags.JsxAttributes); if (isObjectLiteralType(source) && getObjectFlags(source) & ObjectFlags.FreshLiteral) { const discriminantType = target.flags & TypeFlags.Union ? findMatchingDiscriminantType(source, target as UnionType) : undefined; if (hasExcessProperties(source, target, discriminantType, reportErrors)) { if (reportErrors) { reportRelationError(headMessage, source, target); } return Ternary.False; } // Above we check for excess properties with respect to the entire target type. When union // and intersection types are further deconstructed on the target side, we don't want to // make the check again (as it might fail for a partial target type). Therefore we obtain // the regular source type and proceed with that. if (isUnionOrIntersectionTypeWithoutNullableConstituents(target) && !discriminantType) { source = getRegularTypeOfObjectLiteral(source); } } if (relation !== comparableRelation && !isApparentIntersectionConstituent && source.flags & (TypeFlags.Primitive | TypeFlags.Object | TypeFlags.Intersection) && source !== globalObjectType && target.flags & (TypeFlags.Object | TypeFlags.Intersection) && isWeakType(target) && (getPropertiesOfType(source).length > 0 || typeHasCallOrConstructSignatures(source)) && !hasCommonProperties(source, target, isComparingJsxAttributes)) { if (reportErrors) { const calls = getSignaturesOfType(source, SignatureKind.Call); const constructs = getSignaturesOfType(source, SignatureKind.Construct); if (calls.length > 0 && isRelatedTo(getReturnTypeOfSignature(calls[0]), target, /*reportErrors*/ false) || constructs.length > 0 && isRelatedTo(getReturnTypeOfSignature(constructs[0]), target, /*reportErrors*/ false)) { reportError(Diagnostics.Value_of_type_0_has_no_properties_in_common_with_type_1_Did_you_mean_to_call_it, typeToString(source), typeToString(target)); } else { reportError(Diagnostics.Type_0_has_no_properties_in_common_with_type_1, typeToString(source), typeToString(target)); } } return Ternary.False; } let result = Ternary.False; const saveErrorInfo = errorInfo; let isIntersectionConstituent = !!isApparentIntersectionConstituent; // Note that these checks are specifically ordered to produce correct results. In particular, // we need to deconstruct unions before intersections (because unions are always at the top), // and we need to handle "each" relations before "some" relations for the same kind of type. if (source.flags & TypeFlags.Union) { result = relation === comparableRelation ? someTypeRelatedToType(source as UnionType, target, reportErrors && !(source.flags & TypeFlags.Primitive)) : eachTypeRelatedToType(source as UnionType, target, reportErrors && !(source.flags & TypeFlags.Primitive)); } else { if (target.flags & TypeFlags.Union) { result = typeRelatedToSomeType(source, target, reportErrors && !(source.flags & TypeFlags.Primitive) && !(target.flags & TypeFlags.Primitive)); } else if (target.flags & TypeFlags.Intersection) { isIntersectionConstituent = true; // set here to affect the following trio of checks result = typeRelatedToEachType(source, target as IntersectionType, reportErrors); } else if (source.flags & TypeFlags.Intersection) { // Check to see if any constituents of the intersection are immediately related to the target. // // Don't report errors though. Checking whether a constituent is related to the source is not actually // useful and leads to some confusing error messages. Instead it is better to let the below checks // take care of this, or to not elaborate at all. For instance, // // - For an object type (such as 'C = A & B'), users are usually more interested in structural errors. // // - For a union type (such as '(A | B) = (C & D)'), it's better to hold onto the whole intersection // than to report that 'D' is not assignable to 'A' or 'B'. // // - For a primitive type or type parameter (such as 'number = A & B') there is no point in // breaking the intersection apart. result = someTypeRelatedToType(source, target, /*reportErrors*/ false); } if (!result && (source.flags & TypeFlags.StructuredOrInstantiable || target.flags & TypeFlags.StructuredOrInstantiable)) { if (result = recursiveTypeRelatedTo(source, target, reportErrors, isIntersectionConstituent)) { errorInfo = saveErrorInfo; } } } if (!result && source.flags & TypeFlags.Intersection) { // The combined constraint of an intersection type is the intersection of the constraints of // the constituents. When an intersection type contains instantiable types with union type // constraints, there are situations where we need to examine the combined constraint. One is // when the target is a union type. Another is when the intersection contains types belonging // to one of the disjoint domains. For example, given type variables T and U, each with the // constraint 'string | number', the combined constraint of 'T & U' is 'string | number' and // we need to check this constraint against a union on the target side. Also, given a type // variable V constrained to 'string | number', 'V & number' has a combined constraint of // 'string & number | number & number' which reduces to just 'number'. const constraint = getUnionConstraintOfIntersection(source, !!(target.flags & TypeFlags.Union)); if (constraint) { if (result = isRelatedTo(constraint, target, reportErrors, /*headMessage*/ undefined, isIntersectionConstituent)) { errorInfo = saveErrorInfo; } } } if (!result && reportErrors) { const maybeSuppress = suppressNextError; suppressNextError = false; if (source.flags & TypeFlags.Object && target.flags & TypeFlags.Primitive) { tryElaborateErrorsForPrimitivesAndObjects(source, target); } else if (source.symbol && source.flags & TypeFlags.Object && globalObjectType === source) { reportError(Diagnostics.The_Object_type_is_assignable_to_very_few_other_types_Did_you_mean_to_use_the_any_type_instead); } else if (isComparingJsxAttributes && target.flags & TypeFlags.Intersection) { const targetTypes = (target as IntersectionType).types; const intrinsicAttributes = getJsxType(JsxNames.IntrinsicAttributes, errorNode); const intrinsicClassAttributes = getJsxType(JsxNames.IntrinsicClassAttributes, errorNode); if (intrinsicAttributes !== errorType && intrinsicClassAttributes !== errorType && (contains(targetTypes, intrinsicAttributes) || contains(targetTypes, intrinsicClassAttributes))) { // do not report top error return result; } } if (!headMessage && maybeSuppress) { // Used by, eg, missing property checking to replace the top-level message with a more informative one return result; } reportRelationError(headMessage, source, target); } return result; } function isIdenticalTo(source: Type, target: Type): Ternary { let result: Ternary; const flags = source.flags & target.flags; if (flags & TypeFlags.Object || flags & TypeFlags.IndexedAccess || flags & TypeFlags.Conditional || flags & TypeFlags.Index || flags & TypeFlags.Substitution) { return recursiveTypeRelatedTo(source, target, /*reportErrors*/ false, /*isIntersectionConstituent*/ false); } if (flags & (TypeFlags.Union | TypeFlags.Intersection)) { if (result = eachTypeRelatedToSomeType(source, target)) { if (result &= eachTypeRelatedToSomeType(target, source)) { return result; } } } return Ternary.False; } function hasExcessProperties(source: FreshObjectLiteralType, target: Type, discriminant: Type | undefined, reportErrors: boolean): boolean { if (!noImplicitAny && getObjectFlags(target) & ObjectFlags.JSLiteral) { return false; // Disable excess property checks on JS literals to simulate having an implicit "index signature" - but only outside of noImplicitAny } if (isExcessPropertyCheckTarget(target)) { const isComparingJsxAttributes = !!(getObjectFlags(source) & ObjectFlags.JsxAttributes); if ((relation === assignableRelation || relation === comparableRelation) && (isTypeSubsetOf(globalObjectType, target) || (!isComparingJsxAttributes && isEmptyObjectType(target)))) { return false; } if (discriminant) { // check excess properties against discriminant type only, not the entire union return hasExcessProperties(source, discriminant, /*discriminant*/ undefined, reportErrors); } for (const prop of getPropertiesOfObjectType(source)) { if (shouldCheckAsExcessProperty(prop, source.symbol) && !isKnownProperty(target, prop.escapedName, isComparingJsxAttributes)) { if (reportErrors) { // Report error in terms of object types in the target as those are the only ones // we check in isKnownProperty. const errorTarget = filterType(target, isExcessPropertyCheckTarget); // We know *exactly* where things went wrong when comparing the types. // Use this property as the error node as this will be more helpful in // reasoning about what went wrong. if (!errorNode) return Debug.fail(); if (isJsxAttributes(errorNode) || isJsxOpeningLikeElement(errorNode) || isJsxOpeningLikeElement(errorNode.parent)) { // JsxAttributes has an object-literal flag and undergo same type-assignablity check as normal object-literal. // However, using an object-literal error message will be very confusing to the users so we give different a message. // TODO: Spelling suggestions for excess jsx attributes (needs new diagnostic messages) reportError(Diagnostics.Property_0_does_not_exist_on_type_1, symbolToString(prop), typeToString(errorTarget)); } else { // use the property's value declaration if the property is assigned inside the literal itself const objectLiteralDeclaration = source.symbol && firstOrUndefined(source.symbol.declarations); let suggestion; if (prop.valueDeclaration && findAncestor(prop.valueDeclaration, d => d === objectLiteralDeclaration)) { const propDeclaration = prop.valueDeclaration as ObjectLiteralElementLike; Debug.assertNode(propDeclaration, isObjectLiteralElementLike); errorNode = propDeclaration; const name = propDeclaration.name!; if (isIdentifier(name)) { suggestion = getSuggestionForNonexistentProperty(name, errorTarget); } } if (suggestion !== undefined) { reportError(Diagnostics.Object_literal_may_only_specify_known_properties_but_0_does_not_exist_in_type_1_Did_you_mean_to_write_2, symbolToString(prop), typeToString(errorTarget), suggestion); } else { reportError(Diagnostics.Object_literal_may_only_specify_known_properties_and_0_does_not_exist_in_type_1, symbolToString(prop), typeToString(errorTarget)); } } } return true; } } } return false; } function shouldCheckAsExcessProperty(prop: Symbol, container: Symbol) { return prop.valueDeclaration && container.valueDeclaration && prop.valueDeclaration.parent === container.valueDeclaration; } function eachTypeRelatedToSomeType(source: UnionOrIntersectionType, target: UnionOrIntersectionType): Ternary { let result = Ternary.True; const sourceTypes = source.types; for (const sourceType of sourceTypes) { const related = typeRelatedToSomeType(sourceType, target, /*reportErrors*/ false); if (!related) { return Ternary.False; } result &= related; } return result; } function typeRelatedToSomeType(source: Type, target: UnionOrIntersectionType, reportErrors: boolean): Ternary { const targetTypes = target.types; if (target.flags & TypeFlags.Union && containsType(targetTypes, source)) { return Ternary.True; } for (const type of targetTypes) { const related = isRelatedTo(source, type, /*reportErrors*/ false); if (related) { return related; } } if (reportErrors) { const bestMatchingType = findMatchingDiscriminantType(source, target) || findMatchingTypeReferenceOrTypeAliasReference(source, target) || findBestTypeForObjectLiteral(source, target) || findBestTypeForInvokable(source, target) || findMostOverlappyType(source, target); isRelatedTo(source, bestMatchingType || targetTypes[targetTypes.length - 1], /*reportErrors*/ true); } return Ternary.False; } function findMatchingTypeReferenceOrTypeAliasReference(source: Type, unionTarget: UnionOrIntersectionType) { const sourceObjectFlags = getObjectFlags(source); if (sourceObjectFlags & (ObjectFlags.Reference | ObjectFlags.Anonymous) && unionTarget.flags & TypeFlags.Union) { return find(unionTarget.types, target => { if (target.flags & TypeFlags.Object) { const overlapObjFlags = sourceObjectFlags & getObjectFlags(target); if (overlapObjFlags & ObjectFlags.Reference) { return (source as TypeReference).target === (target as TypeReference).target; } if (overlapObjFlags & ObjectFlags.Anonymous) { return !!(source as AnonymousType).aliasSymbol && (source as AnonymousType).aliasSymbol === (target as AnonymousType).aliasSymbol; } } return false; }); } } function findBestTypeForObjectLiteral(source: Type, unionTarget: UnionOrIntersectionType) { if (getObjectFlags(source) & ObjectFlags.ObjectLiteral && forEachType(unionTarget, isArrayLikeType)) { return find(unionTarget.types, t => !isArrayLikeType(t)); } } function findBestTypeForInvokable(source: Type, unionTarget: UnionOrIntersectionType) { let signatureKind = SignatureKind.Call; const hasSignatures = getSignaturesOfType(source, signatureKind).length > 0 || (signatureKind = SignatureKind.Construct, getSignaturesOfType(source, signatureKind).length > 0); if (hasSignatures) { return find(unionTarget.types, t => getSignaturesOfType(t, signatureKind).length > 0); } } function findMostOverlappyType(source: Type, unionTarget: UnionOrIntersectionType) { let bestMatch: Type | undefined; let matchingCount = 0; for (const target of unionTarget.types) { const overlap = getIntersectionType([getIndexType(source), getIndexType(target)]); if (overlap.flags & TypeFlags.Index) { // perfect overlap of keys bestMatch = target; matchingCount = Infinity; } else if (overlap.flags & TypeFlags.Union) { // We only want to account for literal types otherwise. // If we have a union of index types, it seems likely that we // needed to elaborate between two generic mapped types anyway. const len = length(filter((overlap as UnionType).types, isUnitType)); if (len >= matchingCount) { bestMatch = target; matchingCount = len; } } else if (isUnitType(overlap) && 1 >= matchingCount) { bestMatch = target; matchingCount = 1; } } return bestMatch; } // Keep this up-to-date with the same logic within `getApparentTypeOfContextualType`, since they should behave similarly function findMatchingDiscriminantType(source: Type, target: Type) { if (target.flags & TypeFlags.Union) { const sourceProperties = getPropertiesOfObjectType(source); if (sourceProperties) { const sourcePropertiesFiltered = findDiscriminantProperties(sourceProperties, target); if (sourcePropertiesFiltered) { return discriminateTypeByDiscriminableItems(target, map(sourcePropertiesFiltered, p => ([() => getTypeOfSymbol(p), p.escapedName] as [() => Type, __String])), isRelatedTo); } } } return undefined; } function typeRelatedToEachType(source: Type, target: IntersectionType, reportErrors: boolean): Ternary { let result = Ternary.True; const targetTypes = target.types; for (const targetType of targetTypes) { const related = isRelatedTo(source, targetType, reportErrors, /*headMessage*/ undefined, /*isIntersectionConstituent*/ true); if (!related) { return Ternary.False; } result &= related; } return result; } function someTypeRelatedToType(source: UnionOrIntersectionType, target: Type, reportErrors: boolean): Ternary { const sourceTypes = source.types; if (source.flags & TypeFlags.Union && containsType(sourceTypes, target)) { return Ternary.True; } const len = sourceTypes.length; for (let i = 0; i < len; i++) { const related = isRelatedTo(sourceTypes[i], target, reportErrors && i === len - 1); if (related) { return related; } } return Ternary.False; } function eachTypeRelatedToType(source: UnionOrIntersectionType, target: Type, reportErrors: boolean): Ternary { let result = Ternary.True; const sourceTypes = source.types; for (const sourceType of sourceTypes) { const related = isRelatedTo(sourceType, target, reportErrors); if (!related) { return Ternary.False; } result &= related; } return result; } function typeArgumentsRelatedTo(sources: ReadonlyArray = emptyArray, targets: ReadonlyArray = emptyArray, variances: ReadonlyArray = emptyArray, reportErrors: boolean): Ternary { if (sources.length !== targets.length && relation === identityRelation) { return Ternary.False; } const length = sources.length <= targets.length ? sources.length : targets.length; let result = Ternary.True; for (let i = 0; i < length; i++) { // When variance information isn't available we default to covariance. This happens // in the process of computing variance information for recursive types and when // comparing 'this' type arguments. const variance = i < variances.length ? variances[i] : Variance.Covariant; // We ignore arguments for independent type parameters (because they're never witnessed). if (variance !== Variance.Independent) { const s = sources[i]; const t = targets[i]; let related = Ternary.True; if (variance === Variance.Covariant) { related = isRelatedTo(s, t, reportErrors); } else if (variance === Variance.Contravariant) { related = isRelatedTo(t, s, reportErrors); } else if (variance === Variance.Bivariant) { // In the bivariant case we first compare contravariantly without reporting // errors. Then, if that doesn't succeed, we compare covariantly with error // reporting. Thus, error elaboration will be based on the the covariant check, // which is generally easier to reason about. related = isRelatedTo(t, s, /*reportErrors*/ false); if (!related) { related = isRelatedTo(s, t, reportErrors); } } else { // In the invariant case we first compare covariantly, and only when that // succeeds do we proceed to compare contravariantly. Thus, error elaboration // will typically be based on the covariant check. related = isRelatedTo(s, t, reportErrors); if (related) { related &= isRelatedTo(t, s, reportErrors); } } if (!related) { return Ternary.False; } result &= related; } } return result; } // Determine if possibly recursive types are related. First, check if the result is already available in the global cache. // Second, check if we have already started a comparison of the given two types in which case we assume the result to be true. // Third, check if both types are part of deeply nested chains of generic type instantiations and if so assume the types are // equal and infinitely expanding. Fourth, if we have reached a depth of 100 nested comparisons, assume we have runaway recursion // and issue an error. Otherwise, actually compare the structure of the two types. function recursiveTypeRelatedTo(source: Type, target: Type, reportErrors: boolean, isIntersectionConstituent: boolean): Ternary { if (overflow) { return Ternary.False; } const id = getRelationKey(source, target, relation); const related = relation.get(id); if (related !== undefined) { if (reportErrors && related === RelationComparisonResult.Failed) { // We are elaborating errors and the cached result is an unreported failure. The result will be reported // as a failure, and should be updated as a reported failure by the bottom of this function. } else { return related === RelationComparisonResult.Succeeded ? Ternary.True : Ternary.False; } } if (!maybeKeys) { maybeKeys = []; sourceStack = []; targetStack = []; } else { for (let i = 0; i < maybeCount; i++) { // If source and target are already being compared, consider them related with assumptions if (id === maybeKeys[i]) { return Ternary.Maybe; } } if (depth === 100) { overflow = true; return Ternary.False; } } const maybeStart = maybeCount; maybeKeys[maybeCount] = id; maybeCount++; sourceStack[depth] = source; targetStack[depth] = target; depth++; const saveExpandingFlags = expandingFlags; if (!(expandingFlags & ExpandingFlags.Source) && isDeeplyNestedType(source, sourceStack, depth)) expandingFlags |= ExpandingFlags.Source; if (!(expandingFlags & ExpandingFlags.Target) && isDeeplyNestedType(target, targetStack, depth)) expandingFlags |= ExpandingFlags.Target; const result = expandingFlags !== ExpandingFlags.Both ? structuredTypeRelatedTo(source, target, reportErrors, isIntersectionConstituent) : Ternary.Maybe; expandingFlags = saveExpandingFlags; depth--; if (result) { if (result === Ternary.True || depth === 0) { // If result is definitely true, record all maybe keys as having succeeded for (let i = maybeStart; i < maybeCount; i++) { relation.set(maybeKeys[i], RelationComparisonResult.Succeeded); } maybeCount = maybeStart; } } else { // A false result goes straight into global cache (when something is false under // assumptions it will also be false without assumptions) relation.set(id, reportErrors ? RelationComparisonResult.FailedAndReported : RelationComparisonResult.Failed); maybeCount = maybeStart; } return result; } function structuredTypeRelatedTo(source: Type, target: Type, reportErrors: boolean, isIntersectionConstituent: boolean): Ternary { const flags = source.flags & target.flags; if (relation === identityRelation && !(flags & TypeFlags.Object)) { if (flags & TypeFlags.Index) { return isRelatedTo((source).type, (target).type, /*reportErrors*/ false); } let result = Ternary.False; if (flags & TypeFlags.IndexedAccess) { if (result = isRelatedTo((source).objectType, (target).objectType, /*reportErrors*/ false)) { if (result &= isRelatedTo((source).indexType, (target).indexType, /*reportErrors*/ false)) { return result; } } } if (flags & TypeFlags.Conditional) { if ((source).root.isDistributive === (target).root.isDistributive) { if (result = isRelatedTo((source).checkType, (target).checkType, /*reportErrors*/ false)) { if (result &= isRelatedTo((source).extendsType, (target).extendsType, /*reportErrors*/ false)) { if (result &= isRelatedTo(getTrueTypeFromConditionalType(source), getTrueTypeFromConditionalType(target), /*reportErrors*/ false)) { if (result &= isRelatedTo(getFalseTypeFromConditionalType(source), getFalseTypeFromConditionalType(target), /*reportErrors*/ false)) { return result; } } } } } } if (flags & TypeFlags.Substitution) { return isRelatedTo((source).substitute, (target).substitute, /*reportErrors*/ false); } return Ternary.False; } let result: Ternary; let originalErrorInfo: DiagnosticMessageChain | undefined; const saveErrorInfo = errorInfo; // We limit alias variance probing to only object and conditional types since their alias behavior // is more predictable than other, interned types, which may or may not have an alias depending on // the order in which things were checked. if (source.flags & (TypeFlags.Object | TypeFlags.Conditional) && source.aliasSymbol && source.aliasTypeArguments && source.aliasSymbol === target.aliasSymbol && !(source.aliasTypeArgumentsContainsMarker || target.aliasTypeArgumentsContainsMarker)) { const variances = getAliasVariances(source.aliasSymbol); if (result = typeArgumentsRelatedTo(source.aliasTypeArguments, target.aliasTypeArguments, variances, reportErrors)) { return result; } originalErrorInfo = errorInfo; errorInfo = saveErrorInfo; } if (target.flags & TypeFlags.TypeParameter) { // A source type { [P in Q]: X } is related to a target type T if keyof T is related to Q and X is related to T[Q]. if (getObjectFlags(source) & ObjectFlags.Mapped && isRelatedTo(getIndexType(target), getConstraintTypeFromMappedType(source))) { if (!(getMappedTypeModifiers(source) & MappedTypeModifiers.IncludeOptional)) { const templateType = getTemplateTypeFromMappedType(source); const indexedAccessType = getIndexedAccessType(target, getTypeParameterFromMappedType(source)); if (result = isRelatedTo(templateType, indexedAccessType, reportErrors)) { return result; } } } } else if (target.flags & TypeFlags.Index) { // A keyof S is related to a keyof T if T is related to S. if (source.flags & TypeFlags.Index) { if (result = isRelatedTo((target).type, (source).type, /*reportErrors*/ false)) { return result; } } // A type S is assignable to keyof T if S is assignable to keyof C, where C is the // simplified form of T or, if T doesn't simplify, the constraint of T. const simplified = getSimplifiedType((target).type); const constraint = simplified !== (target).type ? simplified : getConstraintOfType((target).type); if (constraint) { // We require Ternary.True here such that circular constraints don't cause // false positives. For example, given 'T extends { [K in keyof T]: string }', // 'keyof T' has itself as its constraint and produces a Ternary.Maybe when // related to other types. if (isRelatedTo(source, getIndexType(constraint, (target as IndexType).stringsOnly), reportErrors) === Ternary.True) { return Ternary.True; } } } else if (target.flags & TypeFlags.IndexedAccess) { // A type S is related to a type T[K], where T and K aren't both type variables, if S is related to C, // where C is the base constraint of T[K] if (relation !== identityRelation && !(isGenericObjectType((target).objectType) && isGenericIndexType((target).indexType))) { const constraint = getBaseConstraintOfType(target); if (constraint && constraint !== target) { if (result = isRelatedTo(source, constraint, reportErrors)) { return result; } } } } else if (isGenericMappedType(target)) { // A source type T is related to a target type { [P in X]: T[P] } const template = getTemplateTypeFromMappedType(target); const modifiers = getMappedTypeModifiers(target); if (!(modifiers & MappedTypeModifiers.ExcludeOptional)) { if (template.flags & TypeFlags.IndexedAccess && (template).objectType === source && (template).indexType === getTypeParameterFromMappedType(target)) { return Ternary.True; } // A source type T is related to a target type { [P in Q]: X } if Q is related to keyof T and T[Q] is related to X. if (!isGenericMappedType(source) && isRelatedTo(getConstraintTypeFromMappedType(target), getIndexType(source))) { const indexedAccessType = getIndexedAccessType(source, getTypeParameterFromMappedType(target)); const templateType = getTemplateTypeFromMappedType(target); if (result = isRelatedTo(indexedAccessType, templateType, reportErrors)) { return result; } } originalErrorInfo = errorInfo; errorInfo = saveErrorInfo; } } if (source.flags & TypeFlags.TypeVariable) { if (source.flags & TypeFlags.IndexedAccess && target.flags & TypeFlags.IndexedAccess) { // A type S[K] is related to a type T[J] if S is related to T and K is related to J. if (result = isRelatedTo((source).objectType, (target).objectType, reportErrors)) { result &= isRelatedTo((source).indexType, (target).indexType, reportErrors); } if (result) { errorInfo = saveErrorInfo; return result; } } const constraint = getConstraintOfType(source); if (!constraint || (source.flags & TypeFlags.TypeParameter && constraint.flags & TypeFlags.Any)) { // A type variable with no constraint is not related to the non-primitive object type. if (result = isRelatedTo(emptyObjectType, extractTypesOfKind(target, ~TypeFlags.NonPrimitive))) { errorInfo = saveErrorInfo; return result; } } // hi-speed no-this-instantiation check (less accurate, but avoids costly `this`-instantiation when the constraint will suffice), see #28231 for report on why this is needed else if (result = isRelatedTo(constraint, target, /*reportErrors*/ false, /*headMessage*/ undefined, isIntersectionConstituent)) { errorInfo = saveErrorInfo; return result; } // slower, fuller, this-instantiated check (necessary when comparing raw `this` types from base classes), see `subclassWithPolymorphicThisIsAssignable.ts` test for example else if (result = isRelatedTo(getTypeWithThisArgument(constraint, source), target, reportErrors, /*headMessage*/ undefined, isIntersectionConstituent)) { errorInfo = saveErrorInfo; return result; } } else if (source.flags & TypeFlags.Index) { if (result = isRelatedTo(keyofConstraintType, target, reportErrors)) { errorInfo = saveErrorInfo; return result; } } else if (source.flags & TypeFlags.Conditional) { if (target.flags & TypeFlags.Conditional) { // Two conditional types 'T1 extends U1 ? X1 : Y1' and 'T2 extends U2 ? X2 : Y2' are related if // they have the same distributivity, T1 and T2 are identical types, U1 and U2 are identical // types, X1 is related to X2, and Y1 is related to Y2. if ((source).root.isDistributive === (target).root.isDistributive && isTypeIdenticalTo((source).extendsType, (target).extendsType) && isTypeIdenticalTo((source).checkType, (target).checkType)) { if (result = isRelatedTo(getTrueTypeFromConditionalType(source), getTrueTypeFromConditionalType(target), reportErrors)) { result &= isRelatedTo(getFalseTypeFromConditionalType(source), getFalseTypeFromConditionalType(target), reportErrors); } if (result) { errorInfo = saveErrorInfo; return result; } } } else { const distributiveConstraint = getConstraintOfDistributiveConditionalType(source); if (distributiveConstraint) { if (result = isRelatedTo(distributiveConstraint, target, reportErrors)) { errorInfo = saveErrorInfo; return result; } } const defaultConstraint = getDefaultConstraintOfConditionalType(source); if (defaultConstraint) { if (result = isRelatedTo(defaultConstraint, target, reportErrors)) { errorInfo = saveErrorInfo; return result; } } } } else { // An empty object type is related to any mapped type that includes a '?' modifier. if (relation !== subtypeRelation && isPartialMappedType(target) && isEmptyObjectType(source)) { return Ternary.True; } if (isGenericMappedType(target)) { if (isGenericMappedType(source)) { if (result = mappedTypeRelatedTo(source, target, reportErrors)) { errorInfo = saveErrorInfo; return result; } } return Ternary.False; } const sourceIsPrimitive = !!(source.flags & TypeFlags.Primitive); if (relation !== identityRelation) { source = getApparentType(source); } if (getObjectFlags(source) & ObjectFlags.Reference && getObjectFlags(target) & ObjectFlags.Reference && (source).target === (target).target && !(getObjectFlags(source) & ObjectFlags.MarkerType || getObjectFlags(target) & ObjectFlags.MarkerType)) { // We have type references to the same generic type, and the type references are not marker // type references (which are intended by be compared structurally). Obtain the variance // information for the type parameters and relate the type arguments accordingly. const variances = getVariances((source).target); if (result = typeArgumentsRelatedTo((source).typeArguments, (target).typeArguments, variances, reportErrors)) { return result; } // The type arguments did not relate appropriately, but it may be because we have no variance // information (in which case typeArgumentsRelatedTo defaulted to covariance for all type // arguments). It might also be the case that the target type has a 'void' type argument for // a covariant type parameter that is only used in return positions within the generic type // (in which case any type argument is permitted on the source side). In those cases we proceed // with a structural comparison. Otherwise, we know for certain the instantiations aren't // related and we can return here. if (variances !== emptyArray && !hasCovariantVoidArgument(target, variances)) { // In some cases generic types that are covariant in regular type checking mode become // invariant in --strictFunctionTypes mode because one or more type parameters are used in // both co- and contravariant positions. In order to make it easier to diagnose *why* such // types are invariant, if any of the type parameters are invariant we reset the reported // errors and instead force a structural comparison (which will include elaborations that // reveal the reason). if (!(reportErrors && some(variances, v => v === Variance.Invariant))) { return Ternary.False; } // We remember the original error information so we can restore it in case the structural // comparison unexpectedly succeeds. This can happen when the structural comparison result // is a Ternary.Maybe for example caused by the recursion depth limiter. originalErrorInfo = errorInfo; errorInfo = saveErrorInfo; } } else if (isReadonlyArrayType(target) ? isArrayType(source) || isTupleType(source) : isArrayType(target) && isTupleType(source) && !source.target.readonly) { return isRelatedTo(getIndexTypeOfType(source, IndexKind.Number) || anyType, getIndexTypeOfType(target, IndexKind.Number) || anyType, reportErrors); } // Even if relationship doesn't hold for unions, intersections, or generic type references, // it may hold in a structural comparison. // In a check of the form X = A & B, we will have previously checked if A relates to X or B relates // to X. Failing both of those we want to check if the aggregation of A and B's members structurally // relates to X. Thus, we include intersection types on the source side here. if (source.flags & (TypeFlags.Object | TypeFlags.Intersection) && target.flags & TypeFlags.Object) { // Report structural errors only if we haven't reported any errors yet const reportStructuralErrors = reportErrors && errorInfo === saveErrorInfo && !sourceIsPrimitive; result = propertiesRelatedTo(source, target, reportStructuralErrors); if (result) { result &= signaturesRelatedTo(source, target, SignatureKind.Call, reportStructuralErrors); if (result) { result &= signaturesRelatedTo(source, target, SignatureKind.Construct, reportStructuralErrors); if (result) { result &= indexTypesRelatedTo(source, target, IndexKind.String, sourceIsPrimitive, reportStructuralErrors); if (result) { result &= indexTypesRelatedTo(source, target, IndexKind.Number, sourceIsPrimitive, reportStructuralErrors); } } } } if (result) { if (!originalErrorInfo) { errorInfo = saveErrorInfo; return result; } errorInfo = originalErrorInfo; } } } return Ternary.False; } // A type [P in S]: X is related to a type [Q in T]: Y if T is related to S and X' is // related to Y, where X' is an instantiation of X in which P is replaced with Q. Notice // that S and T are contra-variant whereas X and Y are co-variant. function mappedTypeRelatedTo(source: MappedType, target: MappedType, reportErrors: boolean): Ternary { const modifiersRelated = relation === comparableRelation || (relation === identityRelation ? getMappedTypeModifiers(source) === getMappedTypeModifiers(target) : getCombinedMappedTypeOptionality(source) <= getCombinedMappedTypeOptionality(target)); if (modifiersRelated) { let result: Ternary; if (result = isRelatedTo(getConstraintTypeFromMappedType(target), getConstraintTypeFromMappedType(source), reportErrors)) { const mapper = createTypeMapper([getTypeParameterFromMappedType(source)], [getTypeParameterFromMappedType(target)]); return result & isRelatedTo(instantiateType(getTemplateTypeFromMappedType(source), mapper), getTemplateTypeFromMappedType(target), reportErrors); } } return Ternary.False; } function propertiesRelatedTo(source: Type, target: Type, reportErrors: boolean): Ternary { if (relation === identityRelation) { return propertiesIdenticalTo(source, target); } const requireOptionalProperties = relation === subtypeRelation && !isObjectLiteralType(source) && !isEmptyArrayLiteralType(source) && !isTupleType(source); const unmatchedProperty = getUnmatchedProperty(source, target, requireOptionalProperties, /*matchDiscriminantProperties*/ false); if (unmatchedProperty) { if (reportErrors) { const props = arrayFrom(getUnmatchedProperties(source, target, requireOptionalProperties, /*matchDiscriminantProperties*/ false)); if (!headMessage || (headMessage.code !== Diagnostics.Class_0_incorrectly_implements_interface_1.code && headMessage.code !== Diagnostics.Class_0_incorrectly_implements_class_1_Did_you_mean_to_extend_1_and_inherit_its_members_as_a_subclass.code)) { suppressNextError = true; // Retain top-level error for interface implementing issues, otherwise omit it } if (props.length === 1) { const propName = symbolToString(unmatchedProperty); reportError(Diagnostics.Property_0_is_missing_in_type_1_but_required_in_type_2, propName, typeToString(source), typeToString(target)); if (length(unmatchedProperty.declarations)) { associateRelatedInfo(createDiagnosticForNode(unmatchedProperty.declarations[0], Diagnostics._0_is_declared_here, propName)); } } else if (props.length > 5) { // arbitrary cutoff for too-long list form reportError(Diagnostics.Type_0_is_missing_the_following_properties_from_type_1_Colon_2_and_3_more, typeToString(source), typeToString(target), map(props.slice(0, 4), p => symbolToString(p)).join(", "), props.length - 4); } else { reportError(Diagnostics.Type_0_is_missing_the_following_properties_from_type_1_Colon_2, typeToString(source), typeToString(target), map(props, p => symbolToString(p)).join(", ")); } } return Ternary.False; } if (isObjectLiteralType(target)) { for (const sourceProp of getPropertiesOfType(source)) { if (!getPropertyOfObjectType(target, sourceProp.escapedName)) { const sourceType = getTypeOfSymbol(sourceProp); if (!(sourceType === undefinedType || sourceType === undefinedWideningType)) { if (reportErrors) { reportError(Diagnostics.Property_0_does_not_exist_on_type_1, symbolToString(sourceProp), typeToString(target)); } return Ternary.False; } } } } let result = Ternary.True; if (isTupleType(target)) { const targetRestType = getRestTypeOfTupleType(target); if (targetRestType) { if (!isTupleType(source)) { return Ternary.False; } const sourceRestType = getRestTypeOfTupleType(source); if (sourceRestType && !isRelatedTo(sourceRestType, targetRestType, reportErrors)) { if (reportErrors) { reportError(Diagnostics.Rest_signatures_are_incompatible); } return Ternary.False; } const targetCount = getTypeReferenceArity(target) - 1; const sourceCount = getTypeReferenceArity(source) - (sourceRestType ? 1 : 0); for (let i = targetCount; i < sourceCount; i++) { const related = isRelatedTo((source).typeArguments![i], targetRestType, reportErrors); if (!related) { if (reportErrors) { reportError(Diagnostics.Property_0_is_incompatible_with_rest_element_type, "" + i); } return Ternary.False; } result &= related; } } } const properties = getPropertiesOfObjectType(target); for (const targetProp of properties) { if (!(targetProp.flags & SymbolFlags.Prototype)) { const sourceProp = getPropertyOfType(source, targetProp.escapedName); if (sourceProp && sourceProp !== targetProp) { if (isIgnoredJsxProperty(source, sourceProp, getTypeOfSymbol(targetProp))) { continue; } const sourcePropFlags = getDeclarationModifierFlagsFromSymbol(sourceProp); const targetPropFlags = getDeclarationModifierFlagsFromSymbol(targetProp); if (sourcePropFlags & ModifierFlags.Private || targetPropFlags & ModifierFlags.Private) { const hasDifferingDeclarations = sourceProp.valueDeclaration !== targetProp.valueDeclaration; if (getCheckFlags(sourceProp) & CheckFlags.ContainsPrivate && hasDifferingDeclarations) { if (reportErrors) { reportError(Diagnostics.Property_0_has_conflicting_declarations_and_is_inaccessible_in_type_1, symbolToString(sourceProp), typeToString(source)); } return Ternary.False; } if (hasDifferingDeclarations) { if (reportErrors) { if (sourcePropFlags & ModifierFlags.Private && targetPropFlags & ModifierFlags.Private) { reportError(Diagnostics.Types_have_separate_declarations_of_a_private_property_0, symbolToString(targetProp)); } else { reportError(Diagnostics.Property_0_is_private_in_type_1_but_not_in_type_2, symbolToString(targetProp), typeToString(sourcePropFlags & ModifierFlags.Private ? source : target), typeToString(sourcePropFlags & ModifierFlags.Private ? target : source)); } } return Ternary.False; } } else if (targetPropFlags & ModifierFlags.Protected) { if (!isValidOverrideOf(sourceProp, targetProp)) { if (reportErrors) { reportError(Diagnostics.Property_0_is_protected_but_type_1_is_not_a_class_derived_from_2, symbolToString(targetProp), typeToString(getDeclaringClass(sourceProp) || source), typeToString(getDeclaringClass(targetProp) || target)); } return Ternary.False; } } else if (sourcePropFlags & ModifierFlags.Protected) { if (reportErrors) { reportError(Diagnostics.Property_0_is_protected_in_type_1_but_public_in_type_2, symbolToString(targetProp), typeToString(source), typeToString(target)); } return Ternary.False; } const related = isRelatedTo(getTypeOfSymbol(sourceProp), getTypeOfSymbol(targetProp), reportErrors); if (!related) { if (reportErrors) { reportError(Diagnostics.Types_of_property_0_are_incompatible, symbolToString(targetProp)); } return Ternary.False; } result &= related; // When checking for comparability, be more lenient with optional properties. if (relation !== comparableRelation && sourceProp.flags & SymbolFlags.Optional && !(targetProp.flags & SymbolFlags.Optional)) { // TypeScript 1.0 spec (April 2014): 3.8.3 // S is a subtype of a type T, and T is a supertype of S if ... // S' and T are object types and, for each member M in T.. // M is a property and S' contains a property N where // if M is a required property, N is also a required property // (M - property in T) // (N - property in S) if (reportErrors) { reportError(Diagnostics.Property_0_is_optional_in_type_1_but_required_in_type_2, symbolToString(targetProp), typeToString(source), typeToString(target)); } return Ternary.False; } } } } return result; } function propertiesIdenticalTo(source: Type, target: Type): Ternary { if (!(source.flags & TypeFlags.Object && target.flags & TypeFlags.Object)) { return Ternary.False; } const sourceProperties = getPropertiesOfObjectType(source); const targetProperties = getPropertiesOfObjectType(target); if (sourceProperties.length !== targetProperties.length) { return Ternary.False; } let result = Ternary.True; for (const sourceProp of sourceProperties) { const targetProp = getPropertyOfObjectType(target, sourceProp.escapedName); if (!targetProp) { return Ternary.False; } const related = compareProperties(sourceProp, targetProp, isRelatedTo); if (!related) { return Ternary.False; } result &= related; } return result; } function signaturesRelatedTo(source: Type, target: Type, kind: SignatureKind, reportErrors: boolean): Ternary { if (relation === identityRelation) { return signaturesIdenticalTo(source, target, kind); } if (target === anyFunctionType || source === anyFunctionType) { return Ternary.True; } const sourceIsJSConstructor = source.symbol && isJSConstructor(source.symbol.valueDeclaration); const targetIsJSConstructor = target.symbol && isJSConstructor(target.symbol.valueDeclaration); const sourceSignatures = getSignaturesOfType(source, (sourceIsJSConstructor && kind === SignatureKind.Construct) ? SignatureKind.Call : kind); const targetSignatures = getSignaturesOfType(target, (targetIsJSConstructor && kind === SignatureKind.Construct) ? SignatureKind.Call : kind); if (kind === SignatureKind.Construct && sourceSignatures.length && targetSignatures.length) { if (isAbstractConstructorType(source) && !isAbstractConstructorType(target)) { // An abstract constructor type is not assignable to a non-abstract constructor type // as it would otherwise be possible to new an abstract class. Note that the assignability // check we perform for an extends clause excludes construct signatures from the target, // so this check never proceeds. if (reportErrors) { reportError(Diagnostics.Cannot_assign_an_abstract_constructor_type_to_a_non_abstract_constructor_type); } return Ternary.False; } if (!constructorVisibilitiesAreCompatible(sourceSignatures[0], targetSignatures[0], reportErrors)) { return Ternary.False; } } let result = Ternary.True; const saveErrorInfo = errorInfo; if (getObjectFlags(source) & ObjectFlags.Instantiated && getObjectFlags(target) & ObjectFlags.Instantiated && source.symbol === target.symbol) { // We have instantiations of the same anonymous type (which typically will be the type of a // method). Simply do a pairwise comparison of the signatures in the two signature lists instead // of the much more expensive N * M comparison matrix we explore below. We erase type parameters // as they are known to always be the same. for (let i = 0; i < targetSignatures.length; i++) { const related = signatureRelatedTo(sourceSignatures[i], targetSignatures[i], /*erase*/ true, reportErrors); if (!related) { return Ternary.False; } result &= related; } } else if (sourceSignatures.length === 1 && targetSignatures.length === 1) { // For simple functions (functions with a single signature) we only erase type parameters for // the comparable relation. Otherwise, if the source signature is generic, we instantiate it // in the context of the target signature before checking the relationship. Ideally we'd do // this regardless of the number of signatures, but the potential costs are prohibitive due // to the quadratic nature of the logic below. const eraseGenerics = relation === comparableRelation || !!compilerOptions.noStrictGenericChecks; result = signatureRelatedTo(sourceSignatures[0], targetSignatures[0], eraseGenerics, reportErrors); } else { outer: for (const t of targetSignatures) { // Only elaborate errors from the first failure let shouldElaborateErrors = reportErrors; for (const s of sourceSignatures) { const related = signatureRelatedTo(s, t, /*erase*/ true, shouldElaborateErrors); if (related) { result &= related; errorInfo = saveErrorInfo; continue outer; } shouldElaborateErrors = false; } if (shouldElaborateErrors) { reportError(Diagnostics.Type_0_provides_no_match_for_the_signature_1, typeToString(source), signatureToString(t, /*enclosingDeclaration*/ undefined, /*flags*/ undefined, kind)); } return Ternary.False; } } return result; } /** * See signatureAssignableTo, compareSignaturesIdentical */ function signatureRelatedTo(source: Signature, target: Signature, erase: boolean, reportErrors: boolean): Ternary { return compareSignaturesRelated(erase ? getErasedSignature(source) : source, erase ? getErasedSignature(target) : target, CallbackCheck.None, /*ignoreReturnTypes*/ false, reportErrors, reportError, isRelatedTo); } function signaturesIdenticalTo(source: Type, target: Type, kind: SignatureKind): Ternary { const sourceSignatures = getSignaturesOfType(source, kind); const targetSignatures = getSignaturesOfType(target, kind); if (sourceSignatures.length !== targetSignatures.length) { return Ternary.False; } let result = Ternary.True; for (let i = 0; i < sourceSignatures.length; i++) { const related = compareSignaturesIdentical(sourceSignatures[i], targetSignatures[i], /*partialMatch*/ false, /*ignoreThisTypes*/ false, /*ignoreReturnTypes*/ false, isRelatedTo); if (!related) { return Ternary.False; } result &= related; } return result; } function eachPropertyRelatedTo(source: Type, target: Type, kind: IndexKind, reportErrors: boolean): Ternary { let result = Ternary.True; for (const prop of getPropertiesOfObjectType(source)) { if (isIgnoredJsxProperty(source, prop, /*targetMemberType*/ undefined)) { continue; } // Skip over symbol-named members if (prop.nameType && prop.nameType.flags & TypeFlags.UniqueESSymbol) { continue; } if (kind === IndexKind.String || isNumericLiteralName(prop.escapedName)) { const related = isRelatedTo(getTypeOfSymbol(prop), target, reportErrors); if (!related) { if (reportErrors) { reportError(Diagnostics.Property_0_is_incompatible_with_index_signature, symbolToString(prop)); } return Ternary.False; } result &= related; } } return result; } function indexInfoRelatedTo(sourceInfo: IndexInfo, targetInfo: IndexInfo, reportErrors: boolean) { const related = isRelatedTo(sourceInfo.type, targetInfo.type, reportErrors); if (!related && reportErrors) { reportError(Diagnostics.Index_signatures_are_incompatible); } return related; } function indexTypesRelatedTo(source: Type, target: Type, kind: IndexKind, sourceIsPrimitive: boolean, reportErrors: boolean): Ternary { if (relation === identityRelation) { return indexTypesIdenticalTo(source, target, kind); } const targetInfo = getIndexInfoOfType(target, kind); if (!targetInfo || targetInfo.type.flags & TypeFlags.AnyOrUnknown && !sourceIsPrimitive) { // Index signature of type any permits assignment from everything but primitives return Ternary.True; } const sourceInfo = getIndexInfoOfType(source, kind) || kind === IndexKind.Number && getIndexInfoOfType(source, IndexKind.String); if (sourceInfo) { return indexInfoRelatedTo(sourceInfo, targetInfo, reportErrors); } if (isGenericMappedType(source)) { // A generic mapped type { [P in K]: T } is related to an index signature { [x: string]: U } // if T is related to U. return (kind === IndexKind.String && isRelatedTo(getTemplateTypeFromMappedType(source), targetInfo.type, reportErrors)) as any as Ternary; // TODO: GH#18217 } if (isObjectTypeWithInferableIndex(source)) { let related = Ternary.True; if (kind === IndexKind.String) { const sourceNumberInfo = getIndexInfoOfType(source, IndexKind.Number); if (sourceNumberInfo) { related = indexInfoRelatedTo(sourceNumberInfo, targetInfo, reportErrors); } } if (related) { related &= eachPropertyRelatedTo(source, targetInfo.type, kind, reportErrors); } return related; } if (reportErrors) { reportError(Diagnostics.Index_signature_is_missing_in_type_0, typeToString(source)); } return Ternary.False; } function indexTypesIdenticalTo(source: Type, target: Type, indexKind: IndexKind): Ternary { const targetInfo = getIndexInfoOfType(target, indexKind); const sourceInfo = getIndexInfoOfType(source, indexKind); if (!sourceInfo && !targetInfo) { return Ternary.True; } if (sourceInfo && targetInfo && sourceInfo.isReadonly === targetInfo.isReadonly) { return isRelatedTo(sourceInfo.type, targetInfo.type); } return Ternary.False; } function constructorVisibilitiesAreCompatible(sourceSignature: Signature, targetSignature: Signature, reportErrors: boolean) { if (!sourceSignature.declaration || !targetSignature.declaration) { return true; } const sourceAccessibility = getSelectedModifierFlags(sourceSignature.declaration, ModifierFlags.NonPublicAccessibilityModifier); const targetAccessibility = getSelectedModifierFlags(targetSignature.declaration, ModifierFlags.NonPublicAccessibilityModifier); // A public, protected and private signature is assignable to a private signature. if (targetAccessibility === ModifierFlags.Private) { return true; } // A public and protected signature is assignable to a protected signature. if (targetAccessibility === ModifierFlags.Protected && sourceAccessibility !== ModifierFlags.Private) { return true; } // Only a public signature is assignable to public signature. if (targetAccessibility !== ModifierFlags.Protected && !sourceAccessibility) { return true; } if (reportErrors) { reportError(Diagnostics.Cannot_assign_a_0_constructor_type_to_a_1_constructor_type, visibilityToString(sourceAccessibility), visibilityToString(targetAccessibility)); } return false; } } function discriminateTypeByDiscriminableItems(target: UnionType, discriminators: [() => Type, __String][], related: (source: Type, target: Type) => boolean | Ternary): Type | undefined; function discriminateTypeByDiscriminableItems(target: UnionType, discriminators: [() => Type, __String][], related: (source: Type, target: Type) => boolean | Ternary, defaultValue: Type): Type; function discriminateTypeByDiscriminableItems(target: UnionType, discriminators: [() => Type, __String][], related: (source: Type, target: Type) => boolean | Ternary, defaultValue?: Type) { let match: Type | undefined; for (const [getDiscriminatingType, propertyName] of discriminators) { for (const type of target.types) { const targetType = getTypeOfPropertyOfType(type, propertyName); if (targetType && related(getDiscriminatingType(), targetType)) { if (match) { if (type === match) continue; // Finding multiple fields which discriminate to the same type is fine return defaultValue; } match = type; } } } return match || defaultValue; } /** * A type is 'weak' if it is an object type with at least one optional property * and no required properties, call/construct signatures or index signatures */ function isWeakType(type: Type): boolean { if (type.flags & TypeFlags.Object) { const resolved = resolveStructuredTypeMembers(type); return resolved.callSignatures.length === 0 && resolved.constructSignatures.length === 0 && !resolved.stringIndexInfo && !resolved.numberIndexInfo && resolved.properties.length > 0 && every(resolved.properties, p => !!(p.flags & SymbolFlags.Optional)); } if (type.flags & TypeFlags.Intersection) { return every((type).types, isWeakType); } return false; } function hasCommonProperties(source: Type, target: Type, isComparingJsxAttributes: boolean) { for (const prop of getPropertiesOfType(source)) { if (isKnownProperty(target, prop.escapedName, isComparingJsxAttributes)) { return true; } } return false; } // Return a type reference where the source type parameter is replaced with the target marker // type, and flag the result as a marker type reference. function getMarkerTypeReference(type: GenericType, source: TypeParameter, target: Type) { const result = createTypeReference(type, map(type.typeParameters, t => t === source ? target : t)); result.objectFlags |= ObjectFlags.MarkerType; return result; } function getAliasVariances(symbol: Symbol) { const links = getSymbolLinks(symbol); return getVariancesWorker(links.typeParameters, links, (_links, param, marker) => { const type = getTypeAliasInstantiation(symbol, instantiateTypes(links.typeParameters!, makeUnaryTypeMapper(param, marker))); type.aliasTypeArgumentsContainsMarker = true; return type; }); } // Return an array containing the variance of each type parameter. The variance is effectively // a digest of the type comparisons that occur for each type argument when instantiations of the // generic type are structurally compared. We infer the variance information by comparing // instantiations of the generic type for type arguments with known relations. The function // returns the emptyArray singleton if we're not in strictFunctionTypes mode or if the function // has been invoked recursively for the given generic type. function getVariancesWorker(typeParameters: ReadonlyArray = emptyArray, cache: TCache, createMarkerType: (input: TCache, param: TypeParameter, marker: Type) => Type): Variance[] { let variances = cache.variances; if (!variances) { // The emptyArray singleton is used to signal a recursive invocation. cache.variances = emptyArray; variances = []; for (const tp of typeParameters) { // We first compare instantiations where the type parameter is replaced with // marker types that have a known subtype relationship. From this we can infer // invariance, covariance, contravariance or bivariance. const typeWithSuper = createMarkerType(cache, tp, markerSuperType); const typeWithSub = createMarkerType(cache, tp, markerSubType); let variance = (isTypeAssignableTo(typeWithSub, typeWithSuper) ? Variance.Covariant : 0) | (isTypeAssignableTo(typeWithSuper, typeWithSub) ? Variance.Contravariant : 0); // If the instantiations appear to be related bivariantly it may be because the // type parameter is independent (i.e. it isn't witnessed anywhere in the generic // type). To determine this we compare instantiations where the type parameter is // replaced with marker types that are known to be unrelated. if (variance === Variance.Bivariant && isTypeAssignableTo(createMarkerType(cache, tp, markerOtherType), typeWithSuper)) { variance = Variance.Independent; } variances.push(variance); } cache.variances = variances; } return variances; } function getVariances(type: GenericType): Variance[] { // Arrays and tuples are known to be covariant, no need to spend time computing this (emptyArray implies covariance for all parameters) if (!strictFunctionTypes || type === globalArrayType || type === globalReadonlyArrayType || type.objectFlags & ObjectFlags.Tuple) { return emptyArray; } return getVariancesWorker(type.typeParameters, type, getMarkerTypeReference); } // Return true if the given type reference has a 'void' type argument for a covariant type parameter. // See comment at call in recursiveTypeRelatedTo for when this case matters. function hasCovariantVoidArgument(type: TypeReference, variances: Variance[]): boolean { for (let i = 0; i < variances.length; i++) { if (variances[i] === Variance.Covariant && type.typeArguments![i].flags & TypeFlags.Void) { return true; } } return false; } function isUnconstrainedTypeParameter(type: Type) { return type.flags & TypeFlags.TypeParameter && !getConstraintOfTypeParameter(type); } function isTypeReferenceWithGenericArguments(type: Type): boolean { return !!(getObjectFlags(type) & ObjectFlags.Reference) && some((type).typeArguments, t => isUnconstrainedTypeParameter(t) || isTypeReferenceWithGenericArguments(t)); } /** * getTypeReferenceId(A) returns "111=0-12=1" * where A.id=111 and number.id=12 */ function getTypeReferenceId(type: TypeReference, typeParameters: Type[], depth = 0) { let result = "" + type.target.id; for (const t of type.typeArguments!) { if (isUnconstrainedTypeParameter(t)) { let index = typeParameters.indexOf(t); if (index < 0) { index = typeParameters.length; typeParameters.push(t); } result += "=" + index; } else if (depth < 4 && isTypeReferenceWithGenericArguments(t)) { result += "<" + getTypeReferenceId(t as TypeReference, typeParameters, depth + 1) + ">"; } else { result += "-" + t.id; } } return result; } /** * To improve caching, the relation key for two generic types uses the target's id plus ids of the type parameters. * For other cases, the types ids are used. */ function getRelationKey(source: Type, target: Type, relation: Map) { if (relation === identityRelation && source.id > target.id) { const temp = source; source = target; target = temp; } if (isTypeReferenceWithGenericArguments(source) && isTypeReferenceWithGenericArguments(target)) { const typeParameters: Type[] = []; return getTypeReferenceId(source, typeParameters) + "," + getTypeReferenceId(target, typeParameters); } return source.id + "," + target.id; } // Invoke the callback for each underlying property symbol of the given symbol and return the first // value that isn't undefined. function forEachProperty(prop: Symbol, callback: (p: Symbol) => T): T | undefined { if (getCheckFlags(prop) & CheckFlags.Synthetic) { for (const t of (prop).containingType!.types) { const p = getPropertyOfType(t, prop.escapedName); const result = p && forEachProperty(p, callback); if (result) { return result; } } return undefined; } return callback(prop); } // Return the declaring class type of a property or undefined if property not declared in class function getDeclaringClass(prop: Symbol) { return prop.parent && prop.parent.flags & SymbolFlags.Class ? getDeclaredTypeOfSymbol(getParentOfSymbol(prop)!) : undefined; } // Return true if some underlying source property is declared in a class that derives // from the given base class. function isPropertyInClassDerivedFrom(prop: Symbol, baseClass: Type | undefined) { return forEachProperty(prop, sp => { const sourceClass = getDeclaringClass(sp); return sourceClass ? hasBaseType(sourceClass, baseClass) : false; }); } // Return true if source property is a valid override of protected parts of target property. function isValidOverrideOf(sourceProp: Symbol, targetProp: Symbol) { return !forEachProperty(targetProp, tp => getDeclarationModifierFlagsFromSymbol(tp) & ModifierFlags.Protected ? !isPropertyInClassDerivedFrom(sourceProp, getDeclaringClass(tp)) : false); } // Return true if the given class derives from each of the declaring classes of the protected // constituents of the given property. function isClassDerivedFromDeclaringClasses(checkClass: Type, prop: Symbol) { return forEachProperty(prop, p => getDeclarationModifierFlagsFromSymbol(p) & ModifierFlags.Protected ? !hasBaseType(checkClass, getDeclaringClass(p)) : false) ? undefined : checkClass; } // Return true if the given type is deeply nested. We consider this to be the case when structural type comparisons // for 5 or more occurrences or instantiations of the type have been recorded on the given stack. It is possible, // though highly unlikely, for this test to be true in a situation where a chain of instantiations is not infinitely // expanding. Effectively, we will generate a false positive when two types are structurally equal to at least 5 // levels, but unequal at some level beyond that. function isDeeplyNestedType(type: Type, stack: Type[], depth: number): boolean { // We track all object types that have an associated symbol (representing the origin of the type) if (depth >= 5 && type.flags & TypeFlags.Object) { const symbol = type.symbol; if (symbol) { let count = 0; for (let i = 0; i < depth; i++) { const t = stack[i]; if (t.flags & TypeFlags.Object && t.symbol === symbol) { count++; if (count >= 5) return true; } } } } return false; } function isPropertyIdenticalTo(sourceProp: Symbol, targetProp: Symbol): boolean { return compareProperties(sourceProp, targetProp, compareTypesIdentical) !== Ternary.False; } function compareProperties(sourceProp: Symbol, targetProp: Symbol, compareTypes: (source: Type, target: Type) => Ternary): Ternary { // Two members are considered identical when // - they are public properties with identical names, optionality, and types, // - they are private or protected properties originating in the same declaration and having identical types if (sourceProp === targetProp) { return Ternary.True; } const sourcePropAccessibility = getDeclarationModifierFlagsFromSymbol(sourceProp) & ModifierFlags.NonPublicAccessibilityModifier; const targetPropAccessibility = getDeclarationModifierFlagsFromSymbol(targetProp) & ModifierFlags.NonPublicAccessibilityModifier; if (sourcePropAccessibility !== targetPropAccessibility) { return Ternary.False; } if (sourcePropAccessibility) { if (getTargetSymbol(sourceProp) !== getTargetSymbol(targetProp)) { return Ternary.False; } } else { if ((sourceProp.flags & SymbolFlags.Optional) !== (targetProp.flags & SymbolFlags.Optional)) { return Ternary.False; } } if (isReadonlySymbol(sourceProp) !== isReadonlySymbol(targetProp)) { return Ternary.False; } return compareTypes(getTypeOfSymbol(sourceProp), getTypeOfSymbol(targetProp)); } function isMatchingSignature(source: Signature, target: Signature, partialMatch: boolean) { const sourceParameterCount = getParameterCount(source); const targetParameterCount = getParameterCount(target); const sourceMinArgumentCount = getMinArgumentCount(source); const targetMinArgumentCount = getMinArgumentCount(target); const sourceHasRestParameter = hasEffectiveRestParameter(source); const targetHasRestParameter = hasEffectiveRestParameter(target); // A source signature matches a target signature if the two signatures have the same number of required, // optional, and rest parameters. if (sourceParameterCount === targetParameterCount && sourceMinArgumentCount === targetMinArgumentCount && sourceHasRestParameter === targetHasRestParameter) { return true; } // A source signature partially matches a target signature if the target signature has no fewer required // parameters if (partialMatch && sourceMinArgumentCount <= targetMinArgumentCount) { return true; } return false; } /** * See signatureRelatedTo, compareSignaturesIdentical */ function compareSignaturesIdentical(source: Signature, target: Signature, partialMatch: boolean, ignoreThisTypes: boolean, ignoreReturnTypes: boolean, compareTypes: (s: Type, t: Type) => Ternary): Ternary { // TODO (drosen): De-duplicate code between related functions. if (source === target) { return Ternary.True; } if (!(isMatchingSignature(source, target, partialMatch))) { return Ternary.False; } // Check that the two signatures have the same number of type parameters. We might consider // also checking that any type parameter constraints match, but that would require instantiating // the constraints with a common set of type arguments to get relatable entities in places where // type parameters occur in the constraints. The complexity of doing that doesn't seem worthwhile, // particularly as we're comparing erased versions of the signatures below. if (length(source.typeParameters) !== length(target.typeParameters)) { return Ternary.False; } // Spec 1.0 Section 3.8.3 & 3.8.4: // M and N (the signatures) are instantiated using type Any as the type argument for all type parameters declared by M and N source = getErasedSignature(source); target = getErasedSignature(target); let result = Ternary.True; if (!ignoreThisTypes) { const sourceThisType = getThisTypeOfSignature(source); if (sourceThisType) { const targetThisType = getThisTypeOfSignature(target); if (targetThisType) { const related = compareTypes(sourceThisType, targetThisType); if (!related) { return Ternary.False; } result &= related; } } } const targetLen = getParameterCount(target); for (let i = 0; i < targetLen; i++) { const s = getTypeAtPosition(source, i); const t = getTypeAtPosition(target, i); const related = compareTypes(t, s); if (!related) { return Ternary.False; } result &= related; } if (!ignoreReturnTypes) { const sourceTypePredicate = getTypePredicateOfSignature(source); const targetTypePredicate = getTypePredicateOfSignature(target); result &= sourceTypePredicate !== undefined || targetTypePredicate !== undefined ? compareTypePredicatesIdentical(sourceTypePredicate, targetTypePredicate, compareTypes) // If they're both type predicates their return types will both be `boolean`, so no need to compare those. : compareTypes(getReturnTypeOfSignature(source), getReturnTypeOfSignature(target)); } return result; } function compareTypePredicatesIdentical(source: TypePredicate | undefined, target: TypePredicate | undefined, compareTypes: (s: Type, t: Type) => Ternary): Ternary { return source === undefined || target === undefined || !typePredicateKindsMatch(source, target) ? Ternary.False : compareTypes(source.type, target.type); } function literalTypesWithSameBaseType(types: Type[]): boolean { let commonBaseType: Type | undefined; for (const t of types) { const baseType = getBaseTypeOfLiteralType(t); if (!commonBaseType) { commonBaseType = baseType; } if (baseType === t || baseType !== commonBaseType) { return false; } } return true; } // When the candidate types are all literal types with the same base type, return a union // of those literal types. Otherwise, return the leftmost type for which no type to the // right is a supertype. function getSupertypeOrUnion(types: Type[]): Type { return literalTypesWithSameBaseType(types) ? getUnionType(types) : reduceLeft(types, (s, t) => isTypeSubtypeOf(s, t) ? t : s)!; } function getCommonSupertype(types: Type[]): Type { if (!strictNullChecks) { return getSupertypeOrUnion(types); } const primaryTypes = filter(types, t => !(t.flags & TypeFlags.Nullable)); return primaryTypes.length ? getNullableType(getSupertypeOrUnion(primaryTypes), getFalsyFlagsOfTypes(types) & TypeFlags.Nullable) : getUnionType(types, UnionReduction.Subtype); } // Return the leftmost type for which no type to the right is a subtype. function getCommonSubtype(types: Type[]) { return reduceLeft(types, (s, t) => isTypeSubtypeOf(t, s) ? t : s)!; } function isArrayType(type: Type): boolean { return !!(getObjectFlags(type) & ObjectFlags.Reference) && ((type).target === globalArrayType || (type).target === globalReadonlyArrayType); } function isReadonlyArrayType(type: Type): boolean { return !!(getObjectFlags(type) & ObjectFlags.Reference) && (type).target === globalReadonlyArrayType; } function getElementTypeOfArrayType(type: Type): Type | undefined { return isArrayType(type) && (type as TypeReference).typeArguments ? (type as TypeReference).typeArguments![0] : undefined; } function isArrayLikeType(type: Type): boolean { // A type is array-like if it is a reference to the global Array or global ReadonlyArray type, // or if it is not the undefined or null type and if it is assignable to ReadonlyArray return isArrayType(type) || !(type.flags & TypeFlags.Nullable) && isTypeAssignableTo(type, anyReadonlyArrayType); } function isEmptyArrayLiteralType(type: Type): boolean { const elementType = isArrayType(type) ? (type).typeArguments![0] : undefined; return elementType === undefinedWideningType || elementType === implicitNeverType; } function isTupleLikeType(type: Type): boolean { return isTupleType(type) || !!getPropertyOfType(type, "0" as __String); } function isArrayOrTupleLikeType(type: Type): boolean { return isArrayLikeType(type) || isTupleLikeType(type); } function getTupleElementType(type: Type, index: number) { const propType = getTypeOfPropertyOfType(type, "" + index as __String); if (propType) { return propType; } if (everyType(type, isTupleType) && !everyType(type, t => !(t).target.hasRestElement)) { return mapType(type, t => getRestTypeOfTupleType(t) || undefinedType); } return undefined; } function isNeitherUnitTypeNorNever(type: Type): boolean { return !(type.flags & (TypeFlags.Unit | TypeFlags.Never)); } function isUnitType(type: Type): boolean { return !!(type.flags & TypeFlags.Unit); } function isLiteralType(type: Type): boolean { return type.flags & TypeFlags.Boolean ? true : type.flags & TypeFlags.Union ? type.flags & TypeFlags.EnumLiteral ? true : every((type).types, isUnitType) : isUnitType(type); } function getBaseTypeOfLiteralType(type: Type): Type { return type.flags & TypeFlags.EnumLiteral ? getBaseTypeOfEnumLiteralType(type) : type.flags & TypeFlags.StringLiteral ? stringType : type.flags & TypeFlags.NumberLiteral ? numberType : type.flags & TypeFlags.BigIntLiteral ? bigintType : type.flags & TypeFlags.BooleanLiteral ? booleanType : type.flags & TypeFlags.Union ? getUnionType(sameMap((type).types, getBaseTypeOfLiteralType)) : type; } function getWidenedLiteralType(type: Type): Type { return type.flags & TypeFlags.EnumLiteral && isFreshLiteralType(type) ? getBaseTypeOfEnumLiteralType(type) : type.flags & TypeFlags.StringLiteral && isFreshLiteralType(type) ? stringType : type.flags & TypeFlags.NumberLiteral && isFreshLiteralType(type) ? numberType : type.flags & TypeFlags.BigIntLiteral && isFreshLiteralType(type) ? bigintType : type.flags & TypeFlags.BooleanLiteral && isFreshLiteralType(type) ? booleanType : type.flags & TypeFlags.Union ? getUnionType(sameMap((type).types, getWidenedLiteralType)) : type; } function getWidenedUniqueESSymbolType(type: Type): Type { return type.flags & TypeFlags.UniqueESSymbol ? esSymbolType : type.flags & TypeFlags.Union ? getUnionType(sameMap((type).types, getWidenedUniqueESSymbolType)) : type; } function getWidenedLiteralLikeTypeForContextualType(type: Type, contextualType: Type | undefined) { if (!isLiteralOfContextualType(type, contextualType)) { type = getWidenedUniqueESSymbolType(getWidenedLiteralType(type)); } return type; } /** * Check if a Type was written as a tuple type literal. * Prefer using isTupleLikeType() unless the use of `elementTypes` is required. */ function isTupleType(type: Type): type is TupleTypeReference { return !!(getObjectFlags(type) & ObjectFlags.Reference && (type).target.objectFlags & ObjectFlags.Tuple); } function getRestTypeOfTupleType(type: TupleTypeReference) { return type.target.hasRestElement ? type.typeArguments![type.target.typeParameters!.length - 1] : undefined; } function getRestArrayTypeOfTupleType(type: TupleTypeReference) { const restType = getRestTypeOfTupleType(type); return restType && createArrayType(restType); } function getLengthOfTupleType(type: TupleTypeReference) { return getTypeReferenceArity(type) - (type.target.hasRestElement ? 1 : 0); } function isZeroBigInt({value}: BigIntLiteralType) { return value.base10Value === "0"; } function getFalsyFlagsOfTypes(types: Type[]): TypeFlags { let result: TypeFlags = 0; for (const t of types) { result |= getFalsyFlags(t); } return result; } // Returns the String, Number, Boolean, StringLiteral, NumberLiteral, BooleanLiteral, Void, Undefined, or Null // flags for the string, number, boolean, "", 0, false, void, undefined, or null types respectively. Returns // no flags for all other types (including non-falsy literal types). function getFalsyFlags(type: Type): TypeFlags { return type.flags & TypeFlags.Union ? getFalsyFlagsOfTypes((type).types) : type.flags & TypeFlags.StringLiteral ? (type).value === "" ? TypeFlags.StringLiteral : 0 : type.flags & TypeFlags.NumberLiteral ? (type).value === 0 ? TypeFlags.NumberLiteral : 0 : type.flags & TypeFlags.BigIntLiteral ? isZeroBigInt(type) ? TypeFlags.BigIntLiteral : 0 : type.flags & TypeFlags.BooleanLiteral ? (type === falseType || type === regularFalseType) ? TypeFlags.BooleanLiteral : 0 : type.flags & TypeFlags.PossiblyFalsy; } function removeDefinitelyFalsyTypes(type: Type): Type { return getFalsyFlags(type) & TypeFlags.DefinitelyFalsy ? filterType(type, t => !(getFalsyFlags(t) & TypeFlags.DefinitelyFalsy)) : type; } function extractDefinitelyFalsyTypes(type: Type): Type { return mapType(type, getDefinitelyFalsyPartOfType); } function getDefinitelyFalsyPartOfType(type: Type): Type { return type.flags & TypeFlags.String ? emptyStringType : type.flags & TypeFlags.Number ? zeroType : type.flags & TypeFlags.BigInt ? zeroBigIntType : type === regularFalseType || type === falseType || type.flags & (TypeFlags.Void | TypeFlags.Undefined | TypeFlags.Null) || type.flags & TypeFlags.StringLiteral && (type).value === "" || type.flags & TypeFlags.NumberLiteral && (type).value === 0 || type.flags & TypeFlags.BigIntLiteral && isZeroBigInt(type) ? type : neverType; } /** * Add undefined or null or both to a type if they are missing. * @param type - type to add undefined and/or null to if not present * @param flags - Either TypeFlags.Undefined or TypeFlags.Null, or both */ function getNullableType(type: Type, flags: TypeFlags): Type { const missing = (flags & ~type.flags) & (TypeFlags.Undefined | TypeFlags.Null); return missing === 0 ? type : missing === TypeFlags.Undefined ? getUnionType([type, undefinedType]) : missing === TypeFlags.Null ? getUnionType([type, nullType]) : getUnionType([type, undefinedType, nullType]); } function getOptionalType(type: Type): Type { Debug.assert(strictNullChecks); return type.flags & TypeFlags.Undefined ? type : getUnionType([type, undefinedType]); } function getGlobalNonNullableTypeInstantiation(type: Type) { if (!deferredGlobalNonNullableTypeAlias) { deferredGlobalNonNullableTypeAlias = getGlobalSymbol("NonNullable" as __String, SymbolFlags.TypeAlias, /*diagnostic*/ undefined) || unknownSymbol; } // Use NonNullable global type alias if available to improve quick info/declaration emit if (deferredGlobalNonNullableTypeAlias !== unknownSymbol) { return getTypeAliasInstantiation(deferredGlobalNonNullableTypeAlias, [type]); } return getTypeWithFacts(type, TypeFacts.NEUndefinedOrNull); // Type alias unavailable, fall back to non-higher-order behavior } function getNonNullableType(type: Type): Type { return strictNullChecks ? getGlobalNonNullableTypeInstantiation(type) : type; } /** * Return true if type was inferred from an object literal, written as an object type literal, or is the shape of a module * with no call or construct signatures. */ function isObjectTypeWithInferableIndex(type: Type) { return type.symbol && (type.symbol.flags & (SymbolFlags.ObjectLiteral | SymbolFlags.TypeLiteral | SymbolFlags.ValueModule)) !== 0 && !typeHasCallOrConstructSignatures(type); } function createSymbolWithType(source: Symbol, type: Type | undefined) { const symbol = createSymbol(source.flags, source.escapedName); symbol.declarations = source.declarations; symbol.parent = source.parent; symbol.type = type; symbol.target = source; if (source.valueDeclaration) { symbol.valueDeclaration = source.valueDeclaration; } if (source.nameType) { symbol.nameType = source.nameType; } return symbol; } function transformTypeOfMembers(type: Type, f: (propertyType: Type) => Type) { const members = createSymbolTable(); for (const property of getPropertiesOfObjectType(type)) { const original = getTypeOfSymbol(property); const updated = f(original); members.set(property.escapedName, updated === original ? property : createSymbolWithType(property, updated)); } return members; } /** * If the the provided object literal is subject to the excess properties check, * create a new that is exempt. Recursively mark object literal members as exempt. * Leave signatures alone since they are not subject to the check. */ function getRegularTypeOfObjectLiteral(type: Type): Type { if (!(isObjectLiteralType(type) && getObjectFlags(type) & ObjectFlags.FreshLiteral)) { return type; } const regularType = (type).regularType; if (regularType) { return regularType; } const resolved = type; const members = transformTypeOfMembers(type, getRegularTypeOfObjectLiteral); const regularNew = createAnonymousType(resolved.symbol, members, resolved.callSignatures, resolved.constructSignatures, resolved.stringIndexInfo, resolved.numberIndexInfo); regularNew.flags = resolved.flags; regularNew.objectFlags |= ObjectFlags.ObjectLiteral | (getObjectFlags(resolved) & ObjectFlags.JSLiteral); (type).regularType = regularNew; return regularNew; } function createWideningContext(parent: WideningContext | undefined, propertyName: __String | undefined, siblings: Type[] | undefined): WideningContext { return { parent, propertyName, siblings, resolvedProperties: undefined }; } function getSiblingsOfContext(context: WideningContext): Type[] { if (!context.siblings) { const siblings: Type[] = []; for (const type of getSiblingsOfContext(context.parent!)) { if (isObjectLiteralType(type)) { const prop = getPropertyOfObjectType(type, context.propertyName!); if (prop) { forEachType(getTypeOfSymbol(prop), t => { siblings.push(t); }); } } } context.siblings = siblings; } return context.siblings; } function getPropertiesOfContext(context: WideningContext): Symbol[] { if (!context.resolvedProperties) { const names = createMap() as UnderscoreEscapedMap; for (const t of getSiblingsOfContext(context)) { if (isObjectLiteralType(t) && !(getObjectFlags(t) & ObjectFlags.ContainsSpread)) { for (const prop of getPropertiesOfType(t)) { names.set(prop.escapedName, prop); } } } context.resolvedProperties = arrayFrom(names.values()); } return context.resolvedProperties; } function getWidenedProperty(prop: Symbol, context: WideningContext | undefined): Symbol { if (!(prop.flags & SymbolFlags.Property)) { // Since get accessors already widen their return value there is no need to // widen accessor based properties here. return prop; } const original = getTypeOfSymbol(prop); const propContext = context && createWideningContext(context, prop.escapedName, /*siblings*/ undefined); const widened = getWidenedTypeWithContext(original, propContext); return widened === original ? prop : createSymbolWithType(prop, widened); } function getUndefinedProperty(prop: Symbol) { const cached = undefinedProperties.get(prop.escapedName); if (cached) { return cached; } const result = createSymbolWithType(prop, undefinedType); result.flags |= SymbolFlags.Optional; undefinedProperties.set(prop.escapedName, result); return result; } function getWidenedTypeOfObjectLiteral(type: Type, context: WideningContext | undefined): Type { const members = createSymbolTable(); for (const prop of getPropertiesOfObjectType(type)) { members.set(prop.escapedName, getWidenedProperty(prop, context)); } if (context) { for (const prop of getPropertiesOfContext(context)) { if (!members.has(prop.escapedName)) { members.set(prop.escapedName, getUndefinedProperty(prop)); } } } const stringIndexInfo = getIndexInfoOfType(type, IndexKind.String); const numberIndexInfo = getIndexInfoOfType(type, IndexKind.Number); const result = createAnonymousType(type.symbol, members, emptyArray, emptyArray, stringIndexInfo && createIndexInfo(getWidenedType(stringIndexInfo.type), stringIndexInfo.isReadonly), numberIndexInfo && createIndexInfo(getWidenedType(numberIndexInfo.type), numberIndexInfo.isReadonly)); result.objectFlags |= (getObjectFlags(type) & ObjectFlags.JSLiteral); // Retain js literal flag through widening return result; } function getWidenedType(type: Type) { return getWidenedTypeWithContext(type, /*context*/ undefined); } function getWidenedTypeWithContext(type: Type, context: WideningContext | undefined): Type { if (type.flags & TypeFlags.RequiresWidening) { if (type.flags & TypeFlags.Nullable) { return anyType; } if (isObjectLiteralType(type)) { return getWidenedTypeOfObjectLiteral(type, context); } if (type.flags & TypeFlags.Union) { const unionContext = context || createWideningContext(/*parent*/ undefined, /*propertyName*/ undefined, (type).types); const widenedTypes = sameMap((type).types, t => t.flags & TypeFlags.Nullable ? t : getWidenedTypeWithContext(t, unionContext)); // Widening an empty object literal transitions from a highly restrictive type to // a highly inclusive one. For that reason we perform subtype reduction here if the // union includes empty object types (e.g. reducing {} | string to just {}). return getUnionType(widenedTypes, some(widenedTypes, isEmptyObjectType) ? UnionReduction.Subtype : UnionReduction.Literal); } if (type.flags & TypeFlags.Intersection) { return getIntersectionType(sameMap((type).types, getWidenedType)); } if (isArrayType(type) || isTupleType(type)) { return createTypeReference((type).target, sameMap((type).typeArguments, getWidenedType)); } } return type; } /** * Reports implicit any errors that occur as a result of widening 'null' and 'undefined' * to 'any'. A call to reportWideningErrorsInType is normally accompanied by a call to * getWidenedType. But in some cases getWidenedType is called without reporting errors * (type argument inference is an example). * * The return value indicates whether an error was in fact reported. The particular circumstances * are on a best effort basis. Currently, if the null or undefined that causes widening is inside * an object literal property (arbitrarily deeply), this function reports an error. If no error is * reported, reportImplicitAnyError is a suitable fallback to report a general error. */ function reportWideningErrorsInType(type: Type): boolean { let errorReported = false; if (type.flags & TypeFlags.ContainsWideningType) { if (type.flags & TypeFlags.Union) { if (some((type).types, isEmptyObjectType)) { errorReported = true; } else { for (const t of (type).types) { if (reportWideningErrorsInType(t)) { errorReported = true; } } } } if (isArrayType(type) || isTupleType(type)) { for (const t of (type).typeArguments!) { if (reportWideningErrorsInType(t)) { errorReported = true; } } } if (isObjectLiteralType(type)) { for (const p of getPropertiesOfObjectType(type)) { const t = getTypeOfSymbol(p); if (t.flags & TypeFlags.ContainsWideningType) { if (!reportWideningErrorsInType(t)) { error(p.valueDeclaration, Diagnostics.Object_literal_s_property_0_implicitly_has_an_1_type, symbolToString(p), typeToString(getWidenedType(t))); } errorReported = true; } } } } return errorReported; } function reportImplicitAny(declaration: Declaration, type: Type) { const typeAsString = typeToString(getWidenedType(type)); if (isInJSFile(declaration) && !isCheckJsEnabledForFile(getSourceFileOfNode(declaration), compilerOptions)) { // Only report implicit any errors/suggestions in TS and ts-check JS files return; } let diagnostic: DiagnosticMessage; switch (declaration.kind) { case SyntaxKind.BinaryExpression: case SyntaxKind.PropertyDeclaration: case SyntaxKind.PropertySignature: diagnostic = noImplicitAny ? Diagnostics.Member_0_implicitly_has_an_1_type : Diagnostics.Member_0_implicitly_has_an_1_type_but_a_better_type_may_be_inferred_from_usage; break; case SyntaxKind.Parameter: const param = declaration as ParameterDeclaration; if (isIdentifier(param.name) && (isCallSignatureDeclaration(param.parent) || isMethodSignature(param.parent) || isFunctionTypeNode(param.parent)) && param.parent.parameters.indexOf(param) > -1 && (resolveName(param, param.name.escapedText, SymbolFlags.Type, undefined, param.name.escapedText, /*isUse*/ true) || param.name.originalKeywordKind && isTypeNodeKind(param.name.originalKeywordKind))) { const newName = "arg" + param.parent.parameters.indexOf(param); errorOrSuggestion(noImplicitAny, declaration, Diagnostics.Parameter_has_a_name_but_no_type_Did_you_mean_0_Colon_1, newName, declarationNameToString(param.name)); return; } diagnostic = (declaration).dotDotDotToken ? noImplicitAny ? Diagnostics.Rest_parameter_0_implicitly_has_an_any_type : Diagnostics.Rest_parameter_0_implicitly_has_an_any_type_but_a_better_type_may_be_inferred_from_usage : noImplicitAny ? Diagnostics.Parameter_0_implicitly_has_an_1_type : Diagnostics.Parameter_0_implicitly_has_an_1_type_but_a_better_type_may_be_inferred_from_usage; break; case SyntaxKind.BindingElement: diagnostic = Diagnostics.Binding_element_0_implicitly_has_an_1_type; if (!noImplicitAny) { // Don't issue a suggestion for binding elements since the codefix doesn't yet support them. return; } break; case SyntaxKind.JSDocFunctionType: error(declaration, Diagnostics.Function_type_which_lacks_return_type_annotation_implicitly_has_an_0_return_type, typeAsString); return; case SyntaxKind.FunctionDeclaration: case SyntaxKind.MethodDeclaration: case SyntaxKind.MethodSignature: case SyntaxKind.GetAccessor: case SyntaxKind.SetAccessor: case SyntaxKind.FunctionExpression: case SyntaxKind.ArrowFunction: if (noImplicitAny && !(declaration as NamedDeclaration).name) { error(declaration, Diagnostics.Function_expression_which_lacks_return_type_annotation_implicitly_has_an_0_return_type, typeAsString); return; } diagnostic = noImplicitAny ? Diagnostics._0_which_lacks_return_type_annotation_implicitly_has_an_1_return_type : Diagnostics._0_implicitly_has_an_1_return_type_but_a_better_type_may_be_inferred_from_usage; break; case SyntaxKind.MappedType: if (noImplicitAny) { error(declaration, Diagnostics.Mapped_object_type_implicitly_has_an_any_template_type); } return; default: diagnostic = noImplicitAny ? Diagnostics.Variable_0_implicitly_has_an_1_type : Diagnostics.Variable_0_implicitly_has_an_1_type_but_a_better_type_may_be_inferred_from_usage; } errorOrSuggestion(noImplicitAny, declaration, diagnostic, declarationNameToString(getNameOfDeclaration(declaration)), typeAsString); } function reportErrorsFromWidening(declaration: Declaration, type: Type) { if (produceDiagnostics && noImplicitAny && type.flags & TypeFlags.ContainsWideningType) { // Report implicit any error within type if possible, otherwise report error on declaration if (!reportWideningErrorsInType(type)) { reportImplicitAny(declaration, type); } } } function forEachMatchingParameterType(source: Signature, target: Signature, callback: (s: Type, t: Type) => void) { const sourceCount = getParameterCount(source); const targetCount = getParameterCount(target); const sourceRestType = getEffectiveRestType(source); const targetRestType = getEffectiveRestType(target); const targetNonRestCount = targetRestType ? targetCount - 1 : targetCount; const paramCount = sourceRestType ? targetNonRestCount : Math.min(sourceCount, targetNonRestCount); const sourceThisType = getThisTypeOfSignature(source); if (sourceThisType) { const targetThisType = getThisTypeOfSignature(target); if (targetThisType) { callback(sourceThisType, targetThisType); } } for (let i = 0; i < paramCount; i++) { callback(getTypeAtPosition(source, i), getTypeAtPosition(target, i)); } if (targetRestType) { callback(getRestTypeAtPosition(source, paramCount), targetRestType); } } function createInferenceContext(typeParameters: ReadonlyArray, signature: Signature | undefined, flags: InferenceFlags, compareTypes?: TypeComparer, baseInferences?: InferenceInfo[]): InferenceContext { const inferences = baseInferences ? baseInferences.map(cloneInferenceInfo) : typeParameters.map(createInferenceInfo); const context = mapper as InferenceContext; context.typeParameters = typeParameters; context.signature = signature; context.inferences = inferences; context.flags = flags; context.compareTypes = compareTypes || compareTypesAssignable; return context; function mapper(t: Type): Type { for (let i = 0; i < inferences.length; i++) { if (t === inferences[i].typeParameter) { if (!(context.flags & InferenceFlags.NoFixing)) { inferences[i].isFixed = true; } return getInferredType(context, i); } } return t; } } function createInferenceInfo(typeParameter: TypeParameter): InferenceInfo { return { typeParameter, candidates: undefined, contraCandidates: undefined, inferredType: undefined, priority: undefined, topLevel: true, isFixed: false }; } function cloneInferenceInfo(inference: InferenceInfo): InferenceInfo { return { typeParameter: inference.typeParameter, candidates: inference.candidates && inference.candidates.slice(), contraCandidates: inference.contraCandidates && inference.contraCandidates.slice(), inferredType: inference.inferredType, priority: inference.priority, topLevel: inference.topLevel, isFixed: inference.isFixed }; } // Return true if the given type could possibly reference a type parameter for which // we perform type inference (i.e. a type parameter of a generic function). We cache // results for union and intersection types for performance reasons. function couldContainTypeVariables(type: Type): boolean { const objectFlags = getObjectFlags(type); return !!(type.flags & TypeFlags.Instantiable || objectFlags & ObjectFlags.Reference && forEach((type).typeArguments, couldContainTypeVariables) || objectFlags & ObjectFlags.Anonymous && type.symbol && type.symbol.flags & (SymbolFlags.Function | SymbolFlags.Method | SymbolFlags.TypeLiteral | SymbolFlags.Class) || objectFlags & ObjectFlags.Mapped || type.flags & TypeFlags.UnionOrIntersection && couldUnionOrIntersectionContainTypeVariables(type)); } function couldUnionOrIntersectionContainTypeVariables(type: UnionOrIntersectionType): boolean { if (type.couldContainTypeVariables === undefined) { type.couldContainTypeVariables = some(type.types, couldContainTypeVariables); } return type.couldContainTypeVariables; } function isTypeParameterAtTopLevel(type: Type, typeParameter: TypeParameter): boolean { return type === typeParameter || !!(type.flags & TypeFlags.UnionOrIntersection) && some((type).types, t => isTypeParameterAtTopLevel(t, typeParameter)); } /** Create an object with properties named in the string literal type. Every property has type `any` */ function createEmptyObjectTypeFromStringLiteral(type: Type) { const members = createSymbolTable(); forEachType(type, t => { if (!(t.flags & TypeFlags.StringLiteral)) { return; } const name = escapeLeadingUnderscores((t as StringLiteralType).value); const literalProp = createSymbol(SymbolFlags.Property, name); literalProp.type = anyType; if (t.symbol) { literalProp.declarations = t.symbol.declarations; literalProp.valueDeclaration = t.symbol.valueDeclaration; } members.set(name, literalProp); }); const indexInfo = type.flags & TypeFlags.String ? createIndexInfo(emptyObjectType, /*isReadonly*/ false) : undefined; return createAnonymousType(undefined, members, emptyArray, emptyArray, indexInfo, undefined); } /** * Infer a suitable input type for a homomorphic mapped type { [P in keyof T]: X }. We construct * an object type with the same set of properties as the source type, where the type of each * property is computed by inferring from the source property type to X for the type * variable T[P] (i.e. we treat the type T[P] as the type variable we're inferring for). */ function inferTypeForHomomorphicMappedType(source: Type, target: MappedType, constraint: IndexType): Type | undefined { const key = source.id + "," + target.id + "," + constraint.id; if (reverseMappedCache.has(key)) { return reverseMappedCache.get(key); } reverseMappedCache.set(key, undefined); const type = createReverseMappedType(source, target, constraint); reverseMappedCache.set(key, type); return type; } function createReverseMappedType(source: Type, target: MappedType, constraint: IndexType) { const properties = getPropertiesOfType(source); if (properties.length === 0 && !getIndexInfoOfType(source, IndexKind.String)) { return undefined; } // If any property contains context sensitive functions that have been skipped, the source type // is incomplete and we can't infer a meaningful input type. for (const prop of properties) { if (getTypeOfSymbol(prop).flags & TypeFlags.ContainsAnyFunctionType) { return undefined; } } // For arrays and tuples we infer new arrays and tuples where the reverse mapping has been // applied to the element type(s). if (isArrayType(source)) { return createArrayType(inferReverseMappedType((source).typeArguments![0], target, constraint), isReadonlyArrayType(source)); } if (isTupleType(source)) { const elementTypes = map(source.typeArguments || emptyArray, t => inferReverseMappedType(t, target, constraint)); const minLength = getMappedTypeModifiers(target) & MappedTypeModifiers.IncludeOptional ? getTypeReferenceArity(source) - (source.target.hasRestElement ? 1 : 0) : source.target.minLength; return createTupleType(elementTypes, minLength, source.target.hasRestElement, source.target.readonly, source.target.associatedNames); } // For all other object types we infer a new object type where the reverse mapping has been // applied to the type of each property. const reversed = createObjectType(ObjectFlags.ReverseMapped | ObjectFlags.Anonymous, /*symbol*/ undefined) as ReverseMappedType; reversed.source = source; reversed.mappedType = target; reversed.constraintType = constraint; return reversed; } function getTypeOfReverseMappedSymbol(symbol: ReverseMappedSymbol) { return inferReverseMappedType(symbol.propertyType, symbol.mappedType, symbol.constraintType); } function inferReverseMappedType(sourceType: Type, target: MappedType, constraint: IndexType): Type { const typeParameter = getIndexedAccessType(constraint.type, getTypeParameterFromMappedType(target)); const templateType = getTemplateTypeFromMappedType(target); const inference = createInferenceInfo(typeParameter); inferTypes([inference], sourceType, templateType); return getTypeFromInference(inference); } function* getUnmatchedProperties(source: Type, target: Type, requireOptionalProperties: boolean, matchDiscriminantProperties: boolean) { const properties = target.flags & TypeFlags.Intersection ? getPropertiesOfUnionOrIntersectionType(target) : getPropertiesOfObjectType(target); for (const targetProp of properties) { if (requireOptionalProperties || !(targetProp.flags & SymbolFlags.Optional)) { const sourceProp = getPropertyOfType(source, targetProp.escapedName); if (!sourceProp) { yield targetProp; } else if (matchDiscriminantProperties) { const targetType = getTypeOfSymbol(targetProp); if (targetType.flags & TypeFlags.Unit) { const sourceType = getTypeOfSymbol(sourceProp); if (!(sourceType.flags & TypeFlags.Any || getRegularTypeOfLiteralType(sourceType) === getRegularTypeOfLiteralType(targetType))) { yield targetProp; } } } } } } function getUnmatchedProperty(source: Type, target: Type, requireOptionalProperties: boolean, matchDiscriminantProperties: boolean): Symbol | undefined { return getUnmatchedProperties(source, target, requireOptionalProperties, matchDiscriminantProperties).next().value; } function tupleTypesDefinitelyUnrelated(source: TupleTypeReference, target: TupleTypeReference) { return target.target.minLength > source.target.minLength || !getRestTypeOfTupleType(target) && (!!getRestTypeOfTupleType(source) || getLengthOfTupleType(target) < getLengthOfTupleType(source)); } function typesDefinitelyUnrelated(source: Type, target: Type) { // Two tuple types with incompatible arities are definitely unrelated. // Two object types that each have a property that is unmatched in the other are definitely unrelated. return isTupleType(source) && isTupleType(target) && tupleTypesDefinitelyUnrelated(source, target) || !!getUnmatchedProperty(source, target, /*requireOptionalProperties*/ false, /*matchDiscriminantProperties*/ true) && !!getUnmatchedProperty(target, source, /*requireOptionalProperties*/ false, /*matchDiscriminantProperties*/ true); } function getTypeFromInference(inference: InferenceInfo) { return inference.candidates ? getUnionType(inference.candidates, UnionReduction.Subtype) : inference.contraCandidates ? getIntersectionType(inference.contraCandidates) : emptyObjectType; } function inferTypes(inferences: InferenceInfo[], originalSource: Type, originalTarget: Type, priority: InferencePriority = 0) { let symbolStack: Symbol[]; let visited: Map; let contravariant = false; let bivariant = false; let propagationType: Type; let allowComplexConstraintInference = true; inferFromTypes(originalSource, originalTarget); function inferFromTypes(source: Type, target: Type): void { if (!couldContainTypeVariables(target)) { return; } if (source === wildcardType) { // We are inferring from an 'any' type. We want to infer this type for every type parameter // referenced in the target type, so we record it as the propagation type and infer from the // target to itself. Then, as we find candidates we substitute the propagation type. const savePropagationType = propagationType; propagationType = source; inferFromTypes(target, target); propagationType = savePropagationType; return; } if (source.aliasSymbol && source.aliasTypeArguments && source.aliasSymbol === target.aliasSymbol) { // Source and target are types originating in the same generic type alias declaration. // Simply infer from source type arguments to target type arguments. const sourceTypes = source.aliasTypeArguments; const targetTypes = target.aliasTypeArguments!; for (let i = 0; i < sourceTypes.length; i++) { inferFromTypes(sourceTypes[i], targetTypes[i]); } return; } if (source.flags & TypeFlags.Union && target.flags & TypeFlags.Union && !(source.flags & TypeFlags.EnumLiteral && target.flags & TypeFlags.EnumLiteral) || source.flags & TypeFlags.Intersection && target.flags & TypeFlags.Intersection) { // Source and target are both unions or both intersections. If source and target // are the same type, just relate each constituent type to itself. if (source === target) { for (const t of (source).types) { inferFromTypes(t, t); } return; } // Find each source constituent type that has an identically matching target constituent // type, and for each such type infer from the type to itself. When inferring from a // type to itself we effectively find all type parameter occurrences within that type // and infer themselves as their type arguments. We have special handling for numeric // and string literals because the number and string types are not represented as unions // of all their possible values. let matchingTypes: Type[] | undefined; for (const t of (source).types) { if (typeIdenticalToSomeType(t, (target).types)) { (matchingTypes || (matchingTypes = [])).push(t); inferFromTypes(t, t); } else if (t.flags & (TypeFlags.NumberLiteral | TypeFlags.StringLiteral)) { const b = getBaseTypeOfLiteralType(t); if (typeIdenticalToSomeType(b, (target).types)) { (matchingTypes || (matchingTypes = [])).push(t, b); } } } // Next, to improve the quality of inferences, reduce the source and target types by // removing the identically matched constituents. For example, when inferring from // 'string | string[]' to 'string | T' we reduce the types to 'string[]' and 'T'. if (matchingTypes) { source = removeTypesFromUnionOrIntersection(source, matchingTypes); target = removeTypesFromUnionOrIntersection(target, matchingTypes); } } if (target.flags & TypeFlags.TypeVariable) { // If target is a type parameter, make an inference, unless the source type contains // the anyFunctionType (the wildcard type that's used to avoid contextually typing functions). // Because the anyFunctionType is internal, it should not be exposed to the user by adding // it as an inference candidate. Hopefully, a better candidate will come along that does // not contain anyFunctionType when we come back to this argument for its second round // of inference. Also, we exclude inferences for silentNeverType (which is used as a wildcard // when constructing types from type parameters that had no inference candidates). if (source.flags & TypeFlags.ContainsAnyFunctionType || source === silentNeverType || (priority & InferencePriority.ReturnType && (source === autoType || source === autoArrayType))) { return; } const inference = getInferenceInfoForType(target); if (inference) { if (!inference.isFixed) { if (inference.priority === undefined || priority < inference.priority) { inference.candidates = undefined; inference.contraCandidates = undefined; inference.priority = priority; } if (priority === inference.priority) { const candidate = propagationType || source; // We make contravariant inferences only if we are in a pure contravariant position, // i.e. only if we have not descended into a bivariant position. if (contravariant && !bivariant) { inference.contraCandidates = appendIfUnique(inference.contraCandidates, candidate); } else { inference.candidates = appendIfUnique(inference.candidates, candidate); } } if (!(priority & InferencePriority.ReturnType) && target.flags & TypeFlags.TypeParameter && !isTypeParameterAtTopLevel(originalTarget, target)) { inference.topLevel = false; } } return; } else { // Infer to the simplified version of an indexed access, if possible, to (hopefully) expose more bare type parameters to the inference engine const simplified = getSimplifiedType(target); if (simplified !== target) { inferFromTypesOnce(source, simplified); } else if (target.flags & TypeFlags.IndexedAccess) { const indexType = getSimplifiedType((target as IndexedAccessType).indexType); // Generally simplifications of instantiable indexes are avoided to keep relationship checking correct, however if our target is an access, we can consider // that key of that access to be "instantiated", since we're looking to find the infernce goal in any way we can. if (indexType.flags & TypeFlags.Instantiable) { const simplified = distributeIndexOverObjectType(getSimplifiedType((target as IndexedAccessType).objectType), indexType); if (simplified && simplified !== target) { inferFromTypesOnce(source, simplified); } } } } } if (getObjectFlags(source) & ObjectFlags.Reference && getObjectFlags(target) & ObjectFlags.Reference && (source).target === (target).target) { // If source and target are references to the same generic type, infer from type arguments const sourceTypes = (source).typeArguments || emptyArray; const targetTypes = (target).typeArguments || emptyArray; const count = sourceTypes.length < targetTypes.length ? sourceTypes.length : targetTypes.length; const variances = getVariances((source).target); for (let i = 0; i < count; i++) { if (i < variances.length && variances[i] === Variance.Contravariant) { inferFromContravariantTypes(sourceTypes[i], targetTypes[i]); } else { inferFromTypes(sourceTypes[i], targetTypes[i]); } } } else if (source.flags & TypeFlags.Index && target.flags & TypeFlags.Index) { contravariant = !contravariant; inferFromTypes((source).type, (target).type); contravariant = !contravariant; } else if ((isLiteralType(source) || source.flags & TypeFlags.String) && target.flags & TypeFlags.Index) { const empty = createEmptyObjectTypeFromStringLiteral(source); contravariant = !contravariant; const savePriority = priority; priority |= InferencePriority.LiteralKeyof; inferFromTypes(empty, (target as IndexType).type); priority = savePriority; contravariant = !contravariant; } else if (source.flags & TypeFlags.IndexedAccess && target.flags & TypeFlags.IndexedAccess) { inferFromTypes((source).objectType, (target).objectType); inferFromTypes((source).indexType, (target).indexType); } else if (source.flags & TypeFlags.Conditional && target.flags & TypeFlags.Conditional) { inferFromTypes((source).checkType, (target).checkType); inferFromTypes((source).extendsType, (target).extendsType); inferFromTypes(getTrueTypeFromConditionalType(source), getTrueTypeFromConditionalType(target)); inferFromTypes(getFalseTypeFromConditionalType(source), getFalseTypeFromConditionalType(target)); } else if (target.flags & TypeFlags.Conditional) { inferFromTypes(source, getUnionType([getTrueTypeFromConditionalType(target), getFalseTypeFromConditionalType(target)])); } else if (target.flags & TypeFlags.UnionOrIntersection) { for (const t of (target).types) { const savePriority = priority; // Inferences directly to naked type variables are given lower priority as they are // less specific. For example, when inferring from Promise to T | Promise, // we want to infer string for T, not Promise | string. if (getInferenceInfoForType(t)) { priority |= InferencePriority.NakedTypeVariable; } inferFromTypes(source, t); priority = savePriority; } } else if (source.flags & TypeFlags.Union) { // Source is a union or intersection type, infer from each constituent type const sourceTypes = (source).types; for (const sourceType of sourceTypes) { inferFromTypes(sourceType, target); } } else { if (!(priority & InferencePriority.NoConstraints && source.flags & (TypeFlags.Intersection | TypeFlags.Instantiable))) { const apparentSource = getApparentType(source); // getApparentType can return _any_ type, since an indexed access or conditional may simplify to any other type. // If that occurs and it doesn't simplify to an object or intersection, we'll need to restart `inferFromTypes` // with the simplified source. if (apparentSource !== source && allowComplexConstraintInference && !(apparentSource.flags & (TypeFlags.Object | TypeFlags.Intersection))) { // TODO: The `allowComplexConstraintInference` flag is a hack! This forbids inference from complex constraints within constraints! // This isn't required algorithmically, but rather is used to lower the memory burden caused by performing inference // that is _too good_ in projects with complicated constraints (eg, fp-ts). In such cases, if we did not limit ourselves // here, we might produce more valid inferences for types, causing us to do more checks and perform more instantiations // (in addition to the extra stack depth here) which, in turn, can push the already close process over its limit. // TL;DR: If we ever become generally more memory efficient (or our resource budget ever increases), we should just // remove this `allowComplexConstraintInference` flag. allowComplexConstraintInference = false; return inferFromTypes(apparentSource, target); } source = apparentSource; } if (source.flags & (TypeFlags.Object | TypeFlags.Intersection)) { const key = source.id + "," + target.id; if (visited && visited.get(key)) { return; } (visited || (visited = createMap())).set(key, true); // If we are already processing another target type with the same associated symbol (such as // an instantiation of the same generic type), we do not explore this target as it would yield // no further inferences. We exclude the static side of classes from this check since it shares // its symbol with the instance side which would lead to false positives. const isNonConstructorObject = target.flags & TypeFlags.Object && !(getObjectFlags(target) & ObjectFlags.Anonymous && target.symbol && target.symbol.flags & SymbolFlags.Class); const symbol = isNonConstructorObject ? target.symbol : undefined; if (symbol) { if (contains(symbolStack, symbol)) { return; } (symbolStack || (symbolStack = [])).push(symbol); inferFromObjectTypes(source, target); symbolStack.pop(); } else { inferFromObjectTypes(source, target); } } } function inferFromTypesOnce(source: Type, target: Type) { const key = source.id + "," + target.id; if (!visited || !visited.get(key)) { (visited || (visited = createMap())).set(key, true); inferFromTypes(source, target); } } } function inferFromContravariantTypes(source: Type, target: Type) { if (strictFunctionTypes || priority & InferencePriority.AlwaysStrict) { contravariant = !contravariant; inferFromTypes(source, target); contravariant = !contravariant; } else { inferFromTypes(source, target); } } function getInferenceInfoForType(type: Type) { if (type.flags & TypeFlags.TypeVariable) { for (const inference of inferences) { if (type === inference.typeParameter) { return inference; } } } return undefined; } function inferToMappedType(source: Type, target: MappedType, constraintType: Type): boolean { if (constraintType.flags & TypeFlags.Union) { let result = false; for (const type of (constraintType as UnionType).types) { result = inferToMappedType(source, target, type) || result; } return result; } if (constraintType.flags & TypeFlags.Index) { // We're inferring from some source type S to a homomorphic mapped type { [P in keyof T]: X }, // where T is a type variable. Use inferTypeForHomomorphicMappedType to infer a suitable source // type and then make a secondary inference from that type to T. We make a secondary inference // such that direct inferences to T get priority over inferences to Partial, for example. const inference = getInferenceInfoForType((constraintType).type); if (inference && !inference.isFixed) { const inferredType = inferTypeForHomomorphicMappedType(source, target, constraintType); if (inferredType) { const savePriority = priority; priority |= InferencePriority.HomomorphicMappedType; inferFromTypes(inferredType, inference.typeParameter); priority = savePriority; } } return true; } if (constraintType.flags & TypeFlags.TypeParameter) { // We're inferring from some source type S to a mapped type { [P in K]: X }, where K is a type // parameter. First infer from 'keyof S' to K. const savePriority = priority; priority |= InferencePriority.MappedTypeConstraint; inferFromTypes(getIndexType(source), constraintType); priority = savePriority; // If K is constrained to a type C, also infer to C. Thus, for a mapped type { [P in K]: X }, // where K extends keyof T, we make the same inferences as for a homomorphic mapped type // { [P in keyof T]: X }. This enables us to make meaningful inferences when the target is a // Pick. const extendedConstraint = getConstraintOfType(constraintType); if (extendedConstraint && inferToMappedType(source, target, extendedConstraint)) { return true; } // If no inferences can be made to K's constraint, infer from a union of the property types // in the source to the template type X. const valueTypes = compact([ getIndexTypeOfType(source, IndexKind.String), getIndexTypeOfType(source, IndexKind.Number), ...map(getPropertiesOfType(source), getTypeOfSymbol) ]); inferFromTypes(getUnionType(valueTypes), getTemplateTypeFromMappedType(target)); return true; } return false; } function inferFromObjectTypes(source: Type, target: Type) { if (isGenericMappedType(source) && isGenericMappedType(target)) { // The source and target types are generic types { [P in S]: X } and { [P in T]: Y }, so we infer // from S to T and from X to Y. inferFromTypes(getConstraintTypeFromMappedType(source), getConstraintTypeFromMappedType(target)); inferFromTypes(getTemplateTypeFromMappedType(source), getTemplateTypeFromMappedType(target)); } if (getObjectFlags(target) & ObjectFlags.Mapped) { const constraintType = getConstraintTypeFromMappedType(target); if (inferToMappedType(source, target, constraintType)) { return; } } // Infer from the members of source and target only if the two types are possibly related if (!typesDefinitelyUnrelated(source, target)) { inferFromProperties(source, target); inferFromSignatures(source, target, SignatureKind.Call); inferFromSignatures(source, target, SignatureKind.Construct); inferFromIndexTypes(source, target); } } function inferFromProperties(source: Type, target: Type) { if (isArrayType(source) || isTupleType(source)) { if (isTupleType(target)) { const sourceLength = isTupleType(source) ? getLengthOfTupleType(source) : 0; const targetLength = getLengthOfTupleType(target); const sourceRestType = isTupleType(source) ? getRestTypeOfTupleType(source) : getElementTypeOfArrayType(source); const targetRestType = getRestTypeOfTupleType(target); const fixedLength = targetLength < sourceLength || sourceRestType ? targetLength : sourceLength; for (let i = 0; i < fixedLength; i++) { inferFromTypes(i < sourceLength ? (source).typeArguments![i] : sourceRestType!, target.typeArguments![i]); } if (targetRestType) { const types = fixedLength < sourceLength ? (source).typeArguments!.slice(fixedLength, sourceLength) : []; if (sourceRestType) { types.push(sourceRestType); } if (types.length) { inferFromTypes(getUnionType(types), targetRestType); } } return; } if (isArrayType(target)) { inferFromIndexTypes(source, target); return; } } const properties = getPropertiesOfObjectType(target); for (const targetProp of properties) { const sourceProp = getPropertyOfType(source, targetProp.escapedName); if (sourceProp) { inferFromTypes(getTypeOfSymbol(sourceProp), getTypeOfSymbol(targetProp)); } } } function inferFromSignatures(source: Type, target: Type, kind: SignatureKind) { const sourceSignatures = getSignaturesOfType(source, kind); const targetSignatures = getSignaturesOfType(target, kind); const sourceLen = sourceSignatures.length; const targetLen = targetSignatures.length; const len = sourceLen < targetLen ? sourceLen : targetLen; const skipParameters = !!(source.flags & TypeFlags.ContainsAnyFunctionType); for (let i = 0; i < len; i++) { inferFromSignature(getBaseSignature(sourceSignatures[sourceLen - len + i]), getBaseSignature(targetSignatures[targetLen - len + i]), skipParameters); } } function inferFromSignature(source: Signature, target: Signature, skipParameters: boolean) { if (!skipParameters) { const saveBivariant = bivariant; const kind = target.declaration ? target.declaration.kind : SyntaxKind.Unknown; // Once we descend into a bivariant signature we remain bivariant for all nested inferences bivariant = bivariant || kind === SyntaxKind.MethodDeclaration || kind === SyntaxKind.MethodSignature || kind === SyntaxKind.Constructor; forEachMatchingParameterType(source, target, inferFromContravariantTypes); bivariant = saveBivariant; } const sourceTypePredicate = getTypePredicateOfSignature(source); const targetTypePredicate = getTypePredicateOfSignature(target); if (sourceTypePredicate && targetTypePredicate && sourceTypePredicate.kind === targetTypePredicate.kind) { inferFromTypes(sourceTypePredicate.type, targetTypePredicate.type); } else { inferFromTypes(getReturnTypeOfSignature(source), getReturnTypeOfSignature(target)); } } function inferFromIndexTypes(source: Type, target: Type) { const targetStringIndexType = getIndexTypeOfType(target, IndexKind.String); if (targetStringIndexType) { const sourceIndexType = getIndexTypeOfType(source, IndexKind.String) || getImplicitIndexTypeOfType(source, IndexKind.String); if (sourceIndexType) { inferFromTypes(sourceIndexType, targetStringIndexType); } } const targetNumberIndexType = getIndexTypeOfType(target, IndexKind.Number); if (targetNumberIndexType) { const sourceIndexType = getIndexTypeOfType(source, IndexKind.Number) || getIndexTypeOfType(source, IndexKind.String) || getImplicitIndexTypeOfType(source, IndexKind.Number); if (sourceIndexType) { inferFromTypes(sourceIndexType, targetNumberIndexType); } } } } function typeIdenticalToSomeType(type: Type, types: Type[]): boolean { for (const t of types) { if (isTypeIdenticalTo(t, type)) { return true; } } return false; } /** * Return a new union or intersection type computed by removing a given set of types * from a given union or intersection type. */ function removeTypesFromUnionOrIntersection(type: UnionOrIntersectionType, typesToRemove: Type[]) { const reducedTypes: Type[] = []; for (const t of type.types) { if (!typeIdenticalToSomeType(t, typesToRemove)) { reducedTypes.push(t); } } return type.flags & TypeFlags.Union ? getUnionType(reducedTypes) : getIntersectionType(reducedTypes); } function hasPrimitiveConstraint(type: TypeParameter): boolean { const constraint = getConstraintOfTypeParameter(type); return !!constraint && maybeTypeOfKind(constraint.flags & TypeFlags.Conditional ? getDefaultConstraintOfConditionalType(constraint as ConditionalType) : constraint, TypeFlags.Primitive | TypeFlags.Index); } function isObjectLiteralType(type: Type) { return !!(getObjectFlags(type) & ObjectFlags.ObjectLiteral); } function widenObjectLiteralCandidates(candidates: Type[]): Type[] { if (candidates.length > 1) { const objectLiterals = filter(candidates, isObjectLiteralType); if (objectLiterals.length) { const objectLiteralsType = getWidenedType(getUnionType(objectLiterals, UnionReduction.Subtype)); return concatenate(filter(candidates, t => !isObjectLiteralType(t)), [objectLiteralsType]); } } return candidates; } function getContravariantInference(inference: InferenceInfo) { return inference.priority! & InferencePriority.PriorityImpliesCombination ? getIntersectionType(inference.contraCandidates!) : getCommonSubtype(inference.contraCandidates!); } function getCovariantInference(inference: InferenceInfo, signature: Signature) { // Extract all object literal types and replace them with a single widened and normalized type. const candidates = widenObjectLiteralCandidates(inference.candidates!); // We widen inferred literal types if // all inferences were made to top-level occurrences of the type parameter, and // the type parameter has no constraint or its constraint includes no primitive or literal types, and // the type parameter was fixed during inference or does not occur at top-level in the return type. const primitiveConstraint = hasPrimitiveConstraint(inference.typeParameter); const widenLiteralTypes = !primitiveConstraint && inference.topLevel && (inference.isFixed || !isTypeParameterAtTopLevel(getReturnTypeOfSignature(signature), inference.typeParameter)); const baseCandidates = primitiveConstraint ? sameMap(candidates, getRegularTypeOfLiteralType) : widenLiteralTypes ? sameMap(candidates, getWidenedLiteralType) : candidates; // If all inferences were made from a position that implies a combined result, infer a union type. // Otherwise, infer a common supertype. const unwidenedType = inference.priority! & InferencePriority.PriorityImpliesCombination ? getUnionType(baseCandidates, UnionReduction.Subtype) : getCommonSupertype(baseCandidates); return getWidenedType(unwidenedType); } function getInferredType(context: InferenceContext, index: number): Type { const inference = context.inferences[index]; let inferredType = inference.inferredType; if (!inferredType) { const signature = context.signature; if (signature) { const inferredCovariantType = inference.candidates ? getCovariantInference(inference, signature) : undefined; if (inference.contraCandidates) { const inferredContravariantType = getContravariantInference(inference); // If we have both co- and contra-variant inferences, we prefer the contra-variant inference // unless the co-variant inference is a subtype and not 'never'. inferredType = inferredCovariantType && !(inferredCovariantType.flags & TypeFlags.Never) && isTypeSubtypeOf(inferredCovariantType, inferredContravariantType) ? inferredCovariantType : inferredContravariantType; } else if (inferredCovariantType) { inferredType = inferredCovariantType; } else if (context.flags & InferenceFlags.NoDefault) { // We use silentNeverType as the wildcard that signals no inferences. inferredType = silentNeverType; } else { // Infer either the default or the empty object type when no inferences were // made. It is important to remember that in this case, inference still // succeeds, meaning there is no error for not having inference candidates. An // inference error only occurs when there are *conflicting* candidates, i.e. // candidates with no common supertype. const defaultType = getDefaultFromTypeParameter(inference.typeParameter); if (defaultType) { // Instantiate the default type. Any forward reference to a type // parameter should be instantiated to the empty object type. inferredType = instantiateType(defaultType, combineTypeMappers( createBackreferenceMapper(context.signature!.typeParameters!, index), context)); } else { inferredType = getDefaultTypeArgumentType(!!(context.flags & InferenceFlags.AnyDefault)); } } } else { inferredType = getTypeFromInference(inference); } inference.inferredType = inferredType; const constraint = getConstraintOfTypeParameter(inference.typeParameter); if (constraint) { context.flags |= InferenceFlags.NoFixing; const instantiatedConstraint = instantiateType(constraint, context); if (!context.compareTypes(inferredType, getTypeWithThisArgument(instantiatedConstraint, inferredType))) { inference.inferredType = inferredType = instantiatedConstraint; } context.flags &= ~InferenceFlags.NoFixing; } } return inferredType; } function getDefaultTypeArgumentType(isInJavaScriptFile: boolean): Type { return isInJavaScriptFile ? anyType : emptyObjectType; } function getInferredTypes(context: InferenceContext): Type[] { const result: Type[] = []; for (let i = 0; i < context.inferences.length; i++) { result.push(getInferredType(context, i)); } return result; } // EXPRESSION TYPE CHECKING function getCannotFindNameDiagnosticForName(name: __String): DiagnosticMessage { switch (name) { case "document": case "console": return Diagnostics.Cannot_find_name_0_Do_you_need_to_change_your_target_library_Try_changing_the_lib_compiler_option_to_include_dom; case "$": return compilerOptions.types ? Diagnostics.Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_jQuery_Try_npm_i_types_Slashjquery_and_then_add_jquery_to_the_types_field_in_your_tsconfig : Diagnostics.Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_jQuery_Try_npm_i_types_Slashjquery; case "describe": case "suite": case "it": case "test": return compilerOptions.types ? Diagnostics.Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_a_test_runner_Try_npm_i_types_Slashjest_or_npm_i_types_Slashmocha_and_then_add_jest_or_mocha_to_the_types_field_in_your_tsconfig : Diagnostics.Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_a_test_runner_Try_npm_i_types_Slashjest_or_npm_i_types_Slashmocha; case "process": case "require": case "Buffer": case "module": return compilerOptions.types ? Diagnostics.Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_node_Try_npm_i_types_Slashnode_and_then_add_node_to_the_types_field_in_your_tsconfig : Diagnostics.Cannot_find_name_0_Do_you_need_to_install_type_definitions_for_node_Try_npm_i_types_Slashnode; case "Map": case "Set": case "Promise": case "Symbol": case "WeakMap": case "WeakSet": case "Iterator": case "AsyncIterator": return Diagnostics.Cannot_find_name_0_Do_you_need_to_change_your_target_library_Try_changing_the_lib_compiler_option_to_es2015_or_later; default: return Diagnostics.Cannot_find_name_0; } } function getResolvedSymbol(node: Identifier): Symbol { const links = getNodeLinks(node); if (!links.resolvedSymbol) { links.resolvedSymbol = !nodeIsMissing(node) && resolveName( node, node.escapedText, SymbolFlags.Value | SymbolFlags.ExportValue, getCannotFindNameDiagnosticForName(node.escapedText), node, !isWriteOnlyAccess(node), /*excludeGlobals*/ false, Diagnostics.Cannot_find_name_0_Did_you_mean_1) || unknownSymbol; } return links.resolvedSymbol; } function isInTypeQuery(node: Node): boolean { // TypeScript 1.0 spec (April 2014): 3.6.3 // A type query consists of the keyword typeof followed by an expression. // The expression is restricted to a single identifier or a sequence of identifiers separated by periods return !!findAncestor( node, n => n.kind === SyntaxKind.TypeQuery ? true : n.kind === SyntaxKind.Identifier || n.kind === SyntaxKind.QualifiedName ? false : "quit"); } // Return the flow cache key for a "dotted name" (i.e. a sequence of identifiers // separated by dots). The key consists of the id of the symbol referenced by the // leftmost identifier followed by zero or more property names separated by dots. // The result is undefined if the reference isn't a dotted name. We prefix nodes // occurring in an apparent type position with '@' because the control flow type // of such nodes may be based on the apparent type instead of the declared type. function getFlowCacheKey(node: Node): string | undefined { switch (node.kind) { case SyntaxKind.Identifier: const symbol = getResolvedSymbol(node); return symbol !== unknownSymbol ? (isConstraintPosition(node) ? "@" : "") + getSymbolId(symbol) : undefined; case SyntaxKind.ThisKeyword: return "0"; case SyntaxKind.NonNullExpression: case SyntaxKind.ParenthesizedExpression: return getFlowCacheKey((node).expression); case SyntaxKind.PropertyAccessExpression: case SyntaxKind.ElementAccessExpression: const propName = getAccessedPropertyName(node); if (propName !== undefined) { const key = getFlowCacheKey((node).expression); return key && key + "." + propName; } } return undefined; } function isMatchingReference(source: Node, target: Node): boolean { switch (target.kind) { case SyntaxKind.ParenthesizedExpression: case SyntaxKind.NonNullExpression: return isMatchingReference(source, (target as NonNullExpression | ParenthesizedExpression).expression); } switch (source.kind) { case SyntaxKind.Identifier: return target.kind === SyntaxKind.Identifier && getResolvedSymbol(source) === getResolvedSymbol(target) || (target.kind === SyntaxKind.VariableDeclaration || target.kind === SyntaxKind.BindingElement) && getExportSymbolOfValueSymbolIfExported(getResolvedSymbol(source)) === getSymbolOfNode(target); case SyntaxKind.ThisKeyword: return target.kind === SyntaxKind.ThisKeyword; case SyntaxKind.SuperKeyword: return target.kind === SyntaxKind.SuperKeyword; case SyntaxKind.NonNullExpression: case SyntaxKind.ParenthesizedExpression: return isMatchingReference((source as NonNullExpression | ParenthesizedExpression).expression, target); case SyntaxKind.PropertyAccessExpression: case SyntaxKind.ElementAccessExpression: return isAccessExpression(target) && getAccessedPropertyName(source) === getAccessedPropertyName(target) && isMatchingReference((source).expression, target.expression); } return false; } function getAccessedPropertyName(access: AccessExpression): __String | undefined { return access.kind === SyntaxKind.PropertyAccessExpression ? access.name.escapedText : isStringLiteral(access.argumentExpression) || isNumericLiteral(access.argumentExpression) ? escapeLeadingUnderscores(access.argumentExpression.text) : undefined; } function containsMatchingReference(source: Node, target: Node) { while (isAccessExpression(source)) { source = source.expression; if (isMatchingReference(source, target)) { return true; } } return false; } // Return true if target is a property access xxx.yyy, source is a property access xxx.zzz, the declared // type of xxx is a union type, and yyy is a property that is possibly a discriminant. We consider a property // a possible discriminant if its type differs in the constituents of containing union type, and if every // choice is a unit type or a union of unit types. function containsMatchingReferenceDiscriminant(source: Node, target: Node) { let name; return isAccessExpression(target) && containsMatchingReference(source, target.expression) && (name = getAccessedPropertyName(target)) !== undefined && isDiscriminantProperty(getDeclaredTypeOfReference(target.expression), name); } function getDeclaredTypeOfReference(expr: Node): Type | undefined { if (expr.kind === SyntaxKind.Identifier) { return getTypeOfSymbol(getResolvedSymbol(expr)); } if (isAccessExpression(expr)) { const type = getDeclaredTypeOfReference(expr.expression); if (type) { const propName = getAccessedPropertyName(expr); return propName !== undefined ? getTypeOfPropertyOfType(type, propName) : undefined; } } return undefined; } function isDiscriminantType(type: Type): boolean { return !!(type.flags & TypeFlags.Union && (type.flags & (TypeFlags.Boolean | TypeFlags.EnumLiteral) || !isGenericIndexType(type))); } function isDiscriminantProperty(type: Type | undefined, name: __String) { if (type && type.flags & TypeFlags.Union) { const prop = getUnionOrIntersectionProperty(type, name); if (prop && getCheckFlags(prop) & CheckFlags.SyntheticProperty) { if ((prop).isDiscriminantProperty === undefined) { (prop).isDiscriminantProperty = ((prop).checkFlags & CheckFlags.Discriminant) === CheckFlags.Discriminant && isDiscriminantType(getTypeOfSymbol(prop)); } return !!(prop).isDiscriminantProperty; } } return false; } function isSyntheticThisPropertyAccess(expr: Node) { return isAccessExpression(expr) && expr.expression.kind === SyntaxKind.ThisKeyword && !!(expr.expression.flags & NodeFlags.Synthesized); } function findDiscriminantProperties(sourceProperties: Symbol[], target: Type): Symbol[] | undefined { let result: Symbol[] | undefined; for (const sourceProperty of sourceProperties) { if (isDiscriminantProperty(target, sourceProperty.escapedName)) { if (result) { result.push(sourceProperty); continue; } result = [sourceProperty]; } } return result; } function isOrContainsMatchingReference(source: Node, target: Node) { return isMatchingReference(source, target) || containsMatchingReference(source, target); } function hasMatchingArgument(callExpression: CallExpression, reference: Node) { if (callExpression.arguments) { for (const argument of callExpression.arguments) { if (isOrContainsMatchingReference(reference, argument)) { return true; } } } if (callExpression.expression.kind === SyntaxKind.PropertyAccessExpression && isOrContainsMatchingReference(reference, (callExpression.expression).expression)) { return true; } return false; } function getFlowNodeId(flow: FlowNode): number { if (!flow.id) { flow.id = nextFlowId; nextFlowId++; } return flow.id; } function typeMaybeAssignableTo(source: Type, target: Type) { if (!(source.flags & TypeFlags.Union)) { return isTypeAssignableTo(source, target); } for (const t of (source).types) { if (isTypeAssignableTo(t, target)) { return true; } } return false; } // Remove those constituent types of declaredType to which no constituent type of assignedType is assignable. // For example, when a variable of type number | string | boolean is assigned a value of type number | boolean, // we remove type string. function getAssignmentReducedType(declaredType: UnionType, assignedType: Type) { if (declaredType !== assignedType) { if (assignedType.flags & TypeFlags.Never) { return assignedType; } let reducedType = filterType(declaredType, t => typeMaybeAssignableTo(assignedType, t)); if (assignedType.flags & TypeFlags.BooleanLiteral && isFreshLiteralType(assignedType)) { reducedType = mapType(reducedType, getFreshTypeOfLiteralType); // Ensure that if the assignment is a fresh type, that we narrow to fresh types } // Our crude heuristic produces an invalid result in some cases: see GH#26130. // For now, when that happens, we give up and don't narrow at all. (This also // means we'll never narrow for erroneous assignments where the assigned type // is not assignable to the declared type.) if (isTypeAssignableTo(assignedType, reducedType)) { return reducedType; } } return declaredType; } function getTypeFactsOfTypes(types: Type[]): TypeFacts { let result: TypeFacts = TypeFacts.None; for (const t of types) { result |= getTypeFacts(t); } return result; } function isFunctionObjectType(type: ObjectType): boolean { // We do a quick check for a "bind" property before performing the more expensive subtype // check. This gives us a quicker out in the common case where an object type is not a function. const resolved = resolveStructuredTypeMembers(type); return !!(resolved.callSignatures.length || resolved.constructSignatures.length || resolved.members.get("bind" as __String) && isTypeSubtypeOf(type, globalFunctionType)); } function getTypeFacts(type: Type): TypeFacts { const flags = type.flags; if (flags & TypeFlags.String) { return strictNullChecks ? TypeFacts.StringStrictFacts : TypeFacts.StringFacts; } if (flags & TypeFlags.StringLiteral) { const isEmpty = (type).value === ""; return strictNullChecks ? isEmpty ? TypeFacts.EmptyStringStrictFacts : TypeFacts.NonEmptyStringStrictFacts : isEmpty ? TypeFacts.EmptyStringFacts : TypeFacts.NonEmptyStringFacts; } if (flags & (TypeFlags.Number | TypeFlags.Enum)) { return strictNullChecks ? TypeFacts.NumberStrictFacts : TypeFacts.NumberFacts; } if (flags & TypeFlags.NumberLiteral) { const isZero = (type).value === 0; return strictNullChecks ? isZero ? TypeFacts.ZeroNumberStrictFacts : TypeFacts.NonZeroNumberStrictFacts : isZero ? TypeFacts.ZeroNumberFacts : TypeFacts.NonZeroNumberFacts; } if (flags & TypeFlags.BigInt) { return strictNullChecks ? TypeFacts.BigIntStrictFacts : TypeFacts.BigIntFacts; } if (flags & TypeFlags.BigIntLiteral) { const isZero = isZeroBigInt(type); return strictNullChecks ? isZero ? TypeFacts.ZeroBigIntStrictFacts : TypeFacts.NonZeroBigIntStrictFacts : isZero ? TypeFacts.ZeroBigIntFacts : TypeFacts.NonZeroBigIntFacts; } if (flags & TypeFlags.Boolean) { return strictNullChecks ? TypeFacts.BooleanStrictFacts : TypeFacts.BooleanFacts; } if (flags & TypeFlags.BooleanLike) { return strictNullChecks ? (type === falseType || type === regularFalseType) ? TypeFacts.FalseStrictFacts : TypeFacts.TrueStrictFacts : (type === falseType || type === regularFalseType) ? TypeFacts.FalseFacts : TypeFacts.TrueFacts; } if (flags & TypeFlags.Object) { return getObjectFlags(type) & ObjectFlags.Anonymous && isEmptyObjectType(type) ? strictNullChecks ? TypeFacts.EmptyObjectStrictFacts : TypeFacts.EmptyObjectFacts : isFunctionObjectType(type) ? strictNullChecks ? TypeFacts.FunctionStrictFacts : TypeFacts.FunctionFacts : strictNullChecks ? TypeFacts.ObjectStrictFacts : TypeFacts.ObjectFacts; } if (flags & (TypeFlags.Void | TypeFlags.Undefined)) { return TypeFacts.UndefinedFacts; } if (flags & TypeFlags.Null) { return TypeFacts.NullFacts; } if (flags & TypeFlags.ESSymbolLike) { return strictNullChecks ? TypeFacts.SymbolStrictFacts : TypeFacts.SymbolFacts; } if (flags & TypeFlags.NonPrimitive) { return strictNullChecks ? TypeFacts.ObjectStrictFacts : TypeFacts.ObjectFacts; } if (flags & TypeFlags.Instantiable) { return getTypeFacts(getBaseConstraintOfType(type) || emptyObjectType); } if (flags & TypeFlags.UnionOrIntersection) { return getTypeFactsOfTypes((type).types); } return TypeFacts.All; } function getTypeWithFacts(type: Type, include: TypeFacts) { return filterType(type, t => (getTypeFacts(t) & include) !== 0); } function getTypeWithDefault(type: Type, defaultExpression: Expression) { if (defaultExpression) { const defaultType = getTypeOfExpression(defaultExpression); return getUnionType([getTypeWithFacts(type, TypeFacts.NEUndefined), defaultType]); } return type; } function getTypeOfDestructuredProperty(type: Type, name: PropertyName) { const nameType = getLiteralTypeFromPropertyName(name); if (!isTypeUsableAsPropertyName(nameType)) return errorType; const text = getPropertyNameFromType(nameType); return getConstraintForLocation(getTypeOfPropertyOfType(type, text), name) || isNumericLiteralName(text) && getIndexTypeOfType(type, IndexKind.Number) || getIndexTypeOfType(type, IndexKind.String) || errorType; } function getTypeOfDestructuredArrayElement(type: Type, index: number) { return everyType(type, isTupleLikeType) && getTupleElementType(type, index) || checkIteratedTypeOrElementType(type, /*errorNode*/ undefined, /*allowStringInput*/ false, /*allowAsyncIterables*/ false) || errorType; } function getTypeOfDestructuredSpreadExpression(type: Type) { return createArrayType(checkIteratedTypeOrElementType(type, /*errorNode*/ undefined, /*allowStringInput*/ false, /*allowAsyncIterables*/ false) || errorType); } function getAssignedTypeOfBinaryExpression(node: BinaryExpression): Type { const isDestructuringDefaultAssignment = node.parent.kind === SyntaxKind.ArrayLiteralExpression && isDestructuringAssignmentTarget(node.parent) || node.parent.kind === SyntaxKind.PropertyAssignment && isDestructuringAssignmentTarget(node.parent.parent); return isDestructuringDefaultAssignment ? getTypeWithDefault(getAssignedType(node), node.right) : getTypeOfExpression(node.right); } function isDestructuringAssignmentTarget(parent: Node) { return parent.parent.kind === SyntaxKind.BinaryExpression && (parent.parent as BinaryExpression).left === parent || parent.parent.kind === SyntaxKind.ForOfStatement && (parent.parent as ForOfStatement).initializer === parent; } function getAssignedTypeOfArrayLiteralElement(node: ArrayLiteralExpression, element: Expression): Type { return getTypeOfDestructuredArrayElement(getAssignedType(node), node.elements.indexOf(element)); } function getAssignedTypeOfSpreadExpression(node: SpreadElement): Type { return getTypeOfDestructuredSpreadExpression(getAssignedType(node.parent)); } function getAssignedTypeOfPropertyAssignment(node: PropertyAssignment | ShorthandPropertyAssignment): Type { return getTypeOfDestructuredProperty(getAssignedType(node.parent), node.name); } function getAssignedTypeOfShorthandPropertyAssignment(node: ShorthandPropertyAssignment): Type { return getTypeWithDefault(getAssignedTypeOfPropertyAssignment(node), node.objectAssignmentInitializer!); } function getAssignedType(node: Expression): Type { const { parent } = node; switch (parent.kind) { case SyntaxKind.ForInStatement: return stringType; case SyntaxKind.ForOfStatement: return checkRightHandSideOfForOf((parent).expression, (parent).awaitModifier) || errorType; case SyntaxKind.BinaryExpression: return getAssignedTypeOfBinaryExpression(parent); case SyntaxKind.DeleteExpression: return undefinedType; case SyntaxKind.ArrayLiteralExpression: return getAssignedTypeOfArrayLiteralElement(parent, node); case SyntaxKind.SpreadElement: return getAssignedTypeOfSpreadExpression(parent); case SyntaxKind.PropertyAssignment: return getAssignedTypeOfPropertyAssignment(parent); case SyntaxKind.ShorthandPropertyAssignment: return getAssignedTypeOfShorthandPropertyAssignment(parent); } return errorType; } function getInitialTypeOfBindingElement(node: BindingElement): Type { const pattern = node.parent; const parentType = getInitialType(pattern.parent); const type = pattern.kind === SyntaxKind.ObjectBindingPattern ? getTypeOfDestructuredProperty(parentType, node.propertyName || node.name) : !node.dotDotDotToken ? getTypeOfDestructuredArrayElement(parentType, pattern.elements.indexOf(node)) : getTypeOfDestructuredSpreadExpression(parentType); return getTypeWithDefault(type, node.initializer!); } function getTypeOfInitializer(node: Expression) { // Return the cached type if one is available. If the type of the variable was inferred // from its initializer, we'll already have cached the type. Otherwise we compute it now // without caching such that transient types are reflected. const links = getNodeLinks(node); return links.resolvedType || getTypeOfExpression(node); } function getInitialTypeOfVariableDeclaration(node: VariableDeclaration) { if (node.initializer) { return getTypeOfInitializer(node.initializer); } if (node.parent.parent.kind === SyntaxKind.ForInStatement) { return stringType; } if (node.parent.parent.kind === SyntaxKind.ForOfStatement) { return checkRightHandSideOfForOf(node.parent.parent.expression, node.parent.parent.awaitModifier) || errorType; } return errorType; } function getInitialType(node: VariableDeclaration | BindingElement) { return node.kind === SyntaxKind.VariableDeclaration ? getInitialTypeOfVariableDeclaration(node) : getInitialTypeOfBindingElement(node); } function getInitialOrAssignedType(node: VariableDeclaration | BindingElement | Expression, reference: Node) { return getConstraintForLocation(node.kind === SyntaxKind.VariableDeclaration || node.kind === SyntaxKind.BindingElement ? getInitialType(node) : getAssignedType(node), reference); } function isEmptyArrayAssignment(node: VariableDeclaration | BindingElement | Expression) { return node.kind === SyntaxKind.VariableDeclaration && (node).initializer && isEmptyArrayLiteral((node).initializer!) || node.kind !== SyntaxKind.BindingElement && node.parent.kind === SyntaxKind.BinaryExpression && isEmptyArrayLiteral((node.parent).right); } function getReferenceCandidate(node: Expression): Expression { switch (node.kind) { case SyntaxKind.ParenthesizedExpression: return getReferenceCandidate((node).expression); case SyntaxKind.BinaryExpression: switch ((node).operatorToken.kind) { case SyntaxKind.EqualsToken: return getReferenceCandidate((node).left); case SyntaxKind.CommaToken: return getReferenceCandidate((node).right); } } return node; } function getReferenceRoot(node: Node): Node { const { parent } = node; return parent.kind === SyntaxKind.ParenthesizedExpression || parent.kind === SyntaxKind.BinaryExpression && (parent).operatorToken.kind === SyntaxKind.EqualsToken && (parent).left === node || parent.kind === SyntaxKind.BinaryExpression && (parent).operatorToken.kind === SyntaxKind.CommaToken && (parent).right === node ? getReferenceRoot(parent) : node; } function getTypeOfSwitchClause(clause: CaseClause | DefaultClause) { if (clause.kind === SyntaxKind.CaseClause) { return getRegularTypeOfLiteralType(getTypeOfExpression(clause.expression)); } return neverType; } function getSwitchClauseTypes(switchStatement: SwitchStatement): Type[] { const links = getNodeLinks(switchStatement); if (!links.switchTypes) { links.switchTypes = []; for (const clause of switchStatement.caseBlock.clauses) { links.switchTypes.push(getTypeOfSwitchClause(clause)); } } return links.switchTypes; } // Get the types from all cases in a switch on `typeof`. An // `undefined` element denotes an explicit `default` clause. function getSwitchClauseTypeOfWitnesses(switchStatement: SwitchStatement): (string | undefined)[] { const witnesses: (string | undefined)[] = []; for (const clause of switchStatement.caseBlock.clauses) { if (clause.kind === SyntaxKind.CaseClause) { if (clause.expression.kind === SyntaxKind.StringLiteral) { witnesses.push((clause.expression as StringLiteral).text); continue; } return emptyArray; } witnesses.push(/*explicitDefaultStatement*/ undefined); } return witnesses; } function eachTypeContainedIn(source: Type, types: Type[]) { return source.flags & TypeFlags.Union ? !forEach((source).types, t => !contains(types, t)) : contains(types, source); } function isTypeSubsetOf(source: Type, target: Type) { return source === target || target.flags & TypeFlags.Union && isTypeSubsetOfUnion(source, target); } function isTypeSubsetOfUnion(source: Type, target: UnionType) { if (source.flags & TypeFlags.Union) { for (const t of (source).types) { if (!containsType(target.types, t)) { return false; } } return true; } if (source.flags & TypeFlags.EnumLiteral && getBaseTypeOfEnumLiteralType(source) === target) { return true; } return containsType(target.types, source); } function forEachType(type: Type, f: (t: Type) => T | undefined): T | undefined { return type.flags & TypeFlags.Union ? forEach((type).types, f) : f(type); } function everyType(type: Type, f: (t: Type) => boolean): boolean { return type.flags & TypeFlags.Union ? every((type).types, f) : f(type); } function filterType(type: Type, f: (t: Type) => boolean): Type { if (type.flags & TypeFlags.Union) { const types = (type).types; const filtered = filter(types, f); return filtered === types ? type : getUnionTypeFromSortedList(filtered, (type).primitiveTypesOnly); } return f(type) ? type : neverType; } // Apply a mapping function to a type and return the resulting type. If the source type // is a union type, the mapping function is applied to each constituent type and a union // of the resulting types is returned. function mapType(type: Type, mapper: (t: Type) => Type, noReductions?: boolean): Type; function mapType(type: Type, mapper: (t: Type) => Type | undefined, noReductions?: boolean): Type | undefined; function mapType(type: Type, mapper: (t: Type) => Type | undefined, noReductions?: boolean): Type | undefined { if (type.flags & TypeFlags.Never) { return type; } if (!(type.flags & TypeFlags.Union)) { return mapper(type); } const types = (type).types; let mappedType: Type | undefined; let mappedTypes: Type[] | undefined; for (const current of types) { const t = mapper(current); if (t) { if (!mappedType) { mappedType = t; } else if (!mappedTypes) { mappedTypes = [mappedType, t]; } else { mappedTypes.push(t); } } } return mappedTypes ? getUnionType(mappedTypes, noReductions ? UnionReduction.None : UnionReduction.Literal) : mappedType; } function extractTypesOfKind(type: Type, kind: TypeFlags) { return filterType(type, t => (t.flags & kind) !== 0); } // Return a new type in which occurrences of the string and number primitive types in // typeWithPrimitives have been replaced with occurrences of string literals and numeric // literals in typeWithLiterals, respectively. function replacePrimitivesWithLiterals(typeWithPrimitives: Type, typeWithLiterals: Type) { if (isTypeSubsetOf(stringType, typeWithPrimitives) && maybeTypeOfKind(typeWithLiterals, TypeFlags.StringLiteral) || isTypeSubsetOf(numberType, typeWithPrimitives) && maybeTypeOfKind(typeWithLiterals, TypeFlags.NumberLiteral) || isTypeSubsetOf(bigintType, typeWithPrimitives) && maybeTypeOfKind(typeWithLiterals, TypeFlags.BigIntLiteral)) { return mapType(typeWithPrimitives, t => t.flags & TypeFlags.String ? extractTypesOfKind(typeWithLiterals, TypeFlags.String | TypeFlags.StringLiteral) : t.flags & TypeFlags.Number ? extractTypesOfKind(typeWithLiterals, TypeFlags.Number | TypeFlags.NumberLiteral) : t.flags & TypeFlags.BigInt ? extractTypesOfKind(typeWithLiterals, TypeFlags.BigInt | TypeFlags.BigIntLiteral) : t); } return typeWithPrimitives; } function isIncomplete(flowType: FlowType) { return flowType.flags === 0; } function getTypeFromFlowType(flowType: FlowType) { return flowType.flags === 0 ? (flowType).type : flowType; } function createFlowType(type: Type, incomplete: boolean): FlowType { return incomplete ? { flags: 0, type } : type; } // An evolving array type tracks the element types that have so far been seen in an // 'x.push(value)' or 'x[n] = value' operation along the control flow graph. Evolving // array types are ultimately converted into manifest array types (using getFinalArrayType) // and never escape the getFlowTypeOfReference function. function createEvolvingArrayType(elementType: Type): EvolvingArrayType { const result = createObjectType(ObjectFlags.EvolvingArray); result.elementType = elementType; return result; } function getEvolvingArrayType(elementType: Type): EvolvingArrayType { return evolvingArrayTypes[elementType.id] || (evolvingArrayTypes[elementType.id] = createEvolvingArrayType(elementType)); } // When adding evolving array element types we do not perform subtype reduction. Instead, // we defer subtype reduction until the evolving array type is finalized into a manifest // array type. function addEvolvingArrayElementType(evolvingArrayType: EvolvingArrayType, node: Expression): EvolvingArrayType { const elementType = getBaseTypeOfLiteralType(getContextFreeTypeOfExpression(node)); return isTypeSubsetOf(elementType, evolvingArrayType.elementType) ? evolvingArrayType : getEvolvingArrayType(getUnionType([evolvingArrayType.elementType, elementType])); } function createFinalArrayType(elementType: Type) { return elementType.flags & TypeFlags.Never ? autoArrayType : createArrayType(elementType.flags & TypeFlags.Union ? getUnionType((elementType).types, UnionReduction.Subtype) : elementType); } // We perform subtype reduction upon obtaining the final array type from an evolving array type. function getFinalArrayType(evolvingArrayType: EvolvingArrayType): Type { return evolvingArrayType.finalArrayType || (evolvingArrayType.finalArrayType = createFinalArrayType(evolvingArrayType.elementType)); } function finalizeEvolvingArrayType(type: Type): Type { return getObjectFlags(type) & ObjectFlags.EvolvingArray ? getFinalArrayType(type) : type; } function getElementTypeOfEvolvingArrayType(type: Type) { return getObjectFlags(type) & ObjectFlags.EvolvingArray ? (type).elementType : neverType; } function isEvolvingArrayTypeList(types: Type[]) { let hasEvolvingArrayType = false; for (const t of types) { if (!(t.flags & TypeFlags.Never)) { if (!(getObjectFlags(t) & ObjectFlags.EvolvingArray)) { return false; } hasEvolvingArrayType = true; } } return hasEvolvingArrayType; } // At flow control branch or loop junctions, if the type along every antecedent code path // is an evolving array type, we construct a combined evolving array type. Otherwise we // finalize all evolving array types. function getUnionOrEvolvingArrayType(types: Type[], subtypeReduction: UnionReduction) { return isEvolvingArrayTypeList(types) ? getEvolvingArrayType(getUnionType(map(types, getElementTypeOfEvolvingArrayType))) : getUnionType(sameMap(types, finalizeEvolvingArrayType), subtypeReduction); } // Return true if the given node is 'x' in an 'x.length', x.push(value)', 'x.unshift(value)' or // 'x[n] = value' operation, where 'n' is an expression of type any, undefined, or a number-like type. function isEvolvingArrayOperationTarget(node: Node) { const root = getReferenceRoot(node); const parent = root.parent; const isLengthPushOrUnshift = parent.kind === SyntaxKind.PropertyAccessExpression && ( (parent).name.escapedText === "length" || parent.parent.kind === SyntaxKind.CallExpression && isPushOrUnshiftIdentifier((parent).name)); const isElementAssignment = parent.kind === SyntaxKind.ElementAccessExpression && (parent).expression === root && parent.parent.kind === SyntaxKind.BinaryExpression && (parent.parent).operatorToken.kind === SyntaxKind.EqualsToken && (parent.parent).left === parent && !isAssignmentTarget(parent.parent) && isTypeAssignableToKind(getTypeOfExpression((parent).argumentExpression), TypeFlags.NumberLike); return isLengthPushOrUnshift || isElementAssignment; } function maybeTypePredicateCall(node: CallExpression) { const links = getNodeLinks(node); if (links.maybeTypePredicate === undefined) { links.maybeTypePredicate = getMaybeTypePredicate(node); } return links.maybeTypePredicate; } function getMaybeTypePredicate(node: CallExpression) { if (node.expression.kind !== SyntaxKind.SuperKeyword) { const funcType = checkNonNullExpression(node.expression); if (funcType !== silentNeverType) { const apparentType = getApparentType(funcType); return apparentType !== errorType && some(getSignaturesOfType(apparentType, SignatureKind.Call), signatureHasTypePredicate); } } return false; } function reportFlowControlError(node: Node) { const block = findAncestor(node, isFunctionOrModuleBlock); const sourceFile = getSourceFileOfNode(node); const span = getSpanOfTokenAtPosition(sourceFile, block.statements.pos); diagnostics.add(createFileDiagnostic(sourceFile, span.start, span.length, Diagnostics.The_containing_function_or_module_body_is_too_large_for_control_flow_analysis)); } function getFlowTypeOfReference(reference: Node, declaredType: Type, initialType = declaredType, flowContainer?: Node, couldBeUninitialized?: boolean) { let key: string | undefined; let flowDepth = 0; if (flowAnalysisDisabled) { return errorType; } if (!reference.flowNode || !couldBeUninitialized && !(declaredType.flags & TypeFlags.Narrowable)) { return declaredType; } const sharedFlowStart = sharedFlowCount; const evolvedType = getTypeFromFlowType(getTypeAtFlowNode(reference.flowNode)); sharedFlowCount = sharedFlowStart; // When the reference is 'x' in an 'x.length', 'x.push(value)', 'x.unshift(value)' or x[n] = value' operation, // we give type 'any[]' to 'x' instead of using the type determined by control flow analysis such that operations // on empty arrays are possible without implicit any errors and new element types can be inferred without // type mismatch errors. const resultType = getObjectFlags(evolvedType) & ObjectFlags.EvolvingArray && isEvolvingArrayOperationTarget(reference) ? autoArrayType : finalizeEvolvingArrayType(evolvedType); if (reference.parent && reference.parent.kind === SyntaxKind.NonNullExpression && getTypeWithFacts(resultType, TypeFacts.NEUndefinedOrNull).flags & TypeFlags.Never) { return declaredType; } return resultType; function getTypeAtFlowNode(flow: FlowNode): FlowType { if (flowDepth === 2000) { // We have made 2000 recursive invocations. To avoid overflowing the call stack we report an error // and disable further control flow analysis in the containing function or module body. flowAnalysisDisabled = true; reportFlowControlError(reference); return errorType; } flowDepth++; while (true) { const flags = flow.flags; if (flags & FlowFlags.Shared) { // We cache results of flow type resolution for shared nodes that were previously visited in // the same getFlowTypeOfReference invocation. A node is considered shared when it is the // antecedent of more than one node. for (let i = sharedFlowStart; i < sharedFlowCount; i++) { if (sharedFlowNodes[i] === flow) { flowDepth--; return sharedFlowTypes[i]; } } } let type: FlowType | undefined; if (flags & FlowFlags.AfterFinally) { // block flow edge: finally -> pre-try (for larger explanation check comment in binder.ts - bindTryStatement (flow).locked = true; type = getTypeAtFlowNode((flow).antecedent); (flow).locked = false; } else if (flags & FlowFlags.PreFinally) { // locked pre-finally flows are filtered out in getTypeAtFlowBranchLabel // so here just redirect to antecedent flow = (flow).antecedent; continue; } else if (flags & FlowFlags.Assignment) { type = getTypeAtFlowAssignment(flow); if (!type) { flow = (flow).antecedent; continue; } } else if (flags & FlowFlags.Condition) { type = getTypeAtFlowCondition(flow); } else if (flags & FlowFlags.SwitchClause) { type = getTypeAtSwitchClause(flow); } else if (flags & FlowFlags.Label) { if ((flow).antecedents!.length === 1) { flow = (flow).antecedents![0]; continue; } type = flags & FlowFlags.BranchLabel ? getTypeAtFlowBranchLabel(flow) : getTypeAtFlowLoopLabel(flow); } else if (flags & FlowFlags.ArrayMutation) { type = getTypeAtFlowArrayMutation(flow); if (!type) { flow = (flow).antecedent; continue; } } else if (flags & FlowFlags.Start) { // Check if we should continue with the control flow of the containing function. const container = (flow).container; if (container && container !== flowContainer && reference.kind !== SyntaxKind.PropertyAccessExpression && reference.kind !== SyntaxKind.ElementAccessExpression && reference.kind !== SyntaxKind.ThisKeyword) { flow = container.flowNode!; continue; } // At the top of the flow we have the initial type. type = initialType; } else { // Unreachable code errors are reported in the binding phase. Here we // simply return the non-auto declared type to reduce follow-on errors. type = convertAutoToAny(declaredType); } if (flags & FlowFlags.Shared) { // Record visited node and the associated type in the cache. sharedFlowNodes[sharedFlowCount] = flow; sharedFlowTypes[sharedFlowCount] = type; sharedFlowCount++; } flowDepth--; return type; } } function getTypeAtFlowAssignment(flow: FlowAssignment) { const node = flow.node; // Assignments only narrow the computed type if the declared type is a union type. Thus, we // only need to evaluate the assigned type if the declared type is a union type. if (isMatchingReference(reference, node)) { if (getAssignmentTargetKind(node) === AssignmentKind.Compound) { const flowType = getTypeAtFlowNode(flow.antecedent); return createFlowType(getBaseTypeOfLiteralType(getTypeFromFlowType(flowType)), isIncomplete(flowType)); } if (declaredType === autoType || declaredType === autoArrayType) { if (isEmptyArrayAssignment(node)) { return getEvolvingArrayType(neverType); } const assignedType = getBaseTypeOfLiteralType(getInitialOrAssignedType(node, reference)); return isTypeAssignableTo(assignedType, declaredType) ? assignedType : anyArrayType; } if (declaredType.flags & TypeFlags.Union) { return getAssignmentReducedType(declaredType, getInitialOrAssignedType(node, reference)); } return declaredType; } // We didn't have a direct match. However, if the reference is a dotted name, this // may be an assignment to a left hand part of the reference. For example, for a // reference 'x.y.z', we may be at an assignment to 'x.y' or 'x'. In that case, // return the declared type. if (containsMatchingReference(reference, node)) { // A matching dotted name might also be an expando property on a function *expression*, // in which case we continue control flow analysis back to the function's declaration if (isVariableDeclaration(node) && (isInJSFile(node) || isVarConst(node))) { const init = getDeclaredExpandoInitializer(node); if (init && (init.kind === SyntaxKind.FunctionExpression || init.kind === SyntaxKind.ArrowFunction)) { return getTypeAtFlowNode(flow.antecedent); } } return declaredType; } // for (const _ in ref) acts as a nonnull on ref if (isVariableDeclaration(node) && node.parent.parent.kind === SyntaxKind.ForInStatement && isMatchingReference(reference, node.parent.parent.expression)) { return getNonNullableTypeIfNeeded(getTypeFromFlowType(getTypeAtFlowNode(flow.antecedent))); } // Assignment doesn't affect reference return undefined; } function getTypeAtFlowArrayMutation(flow: FlowArrayMutation): FlowType | undefined { if (declaredType === autoType || declaredType === autoArrayType) { const node = flow.node; const expr = node.kind === SyntaxKind.CallExpression ? (node.expression).expression : (node.left).expression; if (isMatchingReference(reference, getReferenceCandidate(expr))) { const flowType = getTypeAtFlowNode(flow.antecedent); const type = getTypeFromFlowType(flowType); if (getObjectFlags(type) & ObjectFlags.EvolvingArray) { let evolvedType = type; if (node.kind === SyntaxKind.CallExpression) { for (const arg of node.arguments) { evolvedType = addEvolvingArrayElementType(evolvedType, arg); } } else { // We must get the context free expression type so as to not recur in an uncached fashion on the LHS (which causes exponential blowup in compile time) const indexType = getContextFreeTypeOfExpression((node.left).argumentExpression); if (isTypeAssignableToKind(indexType, TypeFlags.NumberLike)) { evolvedType = addEvolvingArrayElementType(evolvedType, node.right); } } return evolvedType === type ? flowType : createFlowType(evolvedType, isIncomplete(flowType)); } return flowType; } } return undefined; } function getTypeAtFlowCondition(flow: FlowCondition): FlowType { const flowType = getTypeAtFlowNode(flow.antecedent); const type = getTypeFromFlowType(flowType); if (type.flags & TypeFlags.Never) { return flowType; } // If we have an antecedent type (meaning we're reachable in some way), we first // attempt to narrow the antecedent type. If that produces the never type, and if // the antecedent type is incomplete (i.e. a transient type in a loop), then we // take the type guard as an indication that control *could* reach here once we // have the complete type. We proceed by switching to the silent never type which // doesn't report errors when operators are applied to it. Note that this is the // *only* place a silent never type is ever generated. const assumeTrue = (flow.flags & FlowFlags.TrueCondition) !== 0; const nonEvolvingType = finalizeEvolvingArrayType(type); const narrowedType = narrowType(nonEvolvingType, flow.expression, assumeTrue); if (narrowedType === nonEvolvingType) { return flowType; } const incomplete = isIncomplete(flowType); const resultType = incomplete && narrowedType.flags & TypeFlags.Never ? silentNeverType : narrowedType; return createFlowType(resultType, incomplete); } function getTypeAtSwitchClause(flow: FlowSwitchClause): FlowType { const expr = flow.switchStatement.expression; const flowType = getTypeAtFlowNode(flow.antecedent); let type = getTypeFromFlowType(flowType); if (isMatchingReference(reference, expr)) { type = narrowTypeBySwitchOnDiscriminant(type, flow.switchStatement, flow.clauseStart, flow.clauseEnd); } else if (isMatchingReferenceDiscriminant(expr, type)) { type = narrowTypeByDiscriminant( type, expr as AccessExpression, t => narrowTypeBySwitchOnDiscriminant(t, flow.switchStatement, flow.clauseStart, flow.clauseEnd)); } else if (expr.kind === SyntaxKind.TypeOfExpression && isMatchingReference(reference, (expr as TypeOfExpression).expression)) { type = narrowBySwitchOnTypeOf(type, flow.switchStatement, flow.clauseStart, flow.clauseEnd); } else if (containsMatchingReferenceDiscriminant(reference, expr)) { type = declaredType; } return createFlowType(type, isIncomplete(flowType)); } function getTypeAtFlowBranchLabel(flow: FlowLabel): FlowType { const antecedentTypes: Type[] = []; let subtypeReduction = false; let seenIncomplete = false; for (const antecedent of flow.antecedents!) { if (antecedent.flags & FlowFlags.PreFinally && (antecedent).lock.locked) { // if flow correspond to branch from pre-try to finally and this branch is locked - this means that // we initially have started following the flow outside the finally block. // in this case we should ignore this branch. continue; } const flowType = getTypeAtFlowNode(antecedent); const type = getTypeFromFlowType(flowType); // If the type at a particular antecedent path is the declared type and the // reference is known to always be assigned (i.e. when declared and initial types // are the same), there is no reason to process more antecedents since the only // possible outcome is subtypes that will be removed in the final union type anyway. if (type === declaredType && declaredType === initialType) { return type; } pushIfUnique(antecedentTypes, type); // If an antecedent type is not a subset of the declared type, we need to perform // subtype reduction. This happens when a "foreign" type is injected into the control // flow using the instanceof operator or a user defined type predicate. if (!isTypeSubsetOf(type, declaredType)) { subtypeReduction = true; } if (isIncomplete(flowType)) { seenIncomplete = true; } } return createFlowType(getUnionOrEvolvingArrayType(antecedentTypes, subtypeReduction ? UnionReduction.Subtype : UnionReduction.Literal), seenIncomplete); } function getTypeAtFlowLoopLabel(flow: FlowLabel): FlowType { // If we have previously computed the control flow type for the reference at // this flow loop junction, return the cached type. const id = getFlowNodeId(flow); const cache = flowLoopCaches[id] || (flowLoopCaches[id] = createMap()); if (!key) { key = getFlowCacheKey(reference); // No cache key is generated when binding patterns are in unnarrowable situations if (!key) { return declaredType; } } const cached = cache.get(key); if (cached) { return cached; } // If this flow loop junction and reference are already being processed, return // the union of the types computed for each branch so far, marked as incomplete. // It is possible to see an empty array in cases where loops are nested and the // back edge of the outer loop reaches an inner loop that is already being analyzed. // In such cases we restart the analysis of the inner loop, which will then see // a non-empty in-process array for the outer loop and eventually terminate because // the first antecedent of a loop junction is always the non-looping control flow // path that leads to the top. for (let i = flowLoopStart; i < flowLoopCount; i++) { if (flowLoopNodes[i] === flow && flowLoopKeys[i] === key && flowLoopTypes[i].length) { return createFlowType(getUnionOrEvolvingArrayType(flowLoopTypes[i], UnionReduction.Literal), /*incomplete*/ true); } } // Add the flow loop junction and reference to the in-process stack and analyze // each antecedent code path. const antecedentTypes: Type[] = []; let subtypeReduction = false; let firstAntecedentType: FlowType | undefined; flowLoopNodes[flowLoopCount] = flow; flowLoopKeys[flowLoopCount] = key; flowLoopTypes[flowLoopCount] = antecedentTypes; for (const antecedent of flow.antecedents!) { flowLoopCount++; const flowType = getTypeAtFlowNode(antecedent); flowLoopCount--; if (!firstAntecedentType) { firstAntecedentType = flowType; } const type = getTypeFromFlowType(flowType); // If we see a value appear in the cache it is a sign that control flow analysis // was restarted and completed by checkExpressionCached. We can simply pick up // the resulting type and bail out. const cached = cache.get(key); if (cached) { return cached; } pushIfUnique(antecedentTypes, type); // If an antecedent type is not a subset of the declared type, we need to perform // subtype reduction. This happens when a "foreign" type is injected into the control // flow using the instanceof operator or a user defined type predicate. if (!isTypeSubsetOf(type, declaredType)) { subtypeReduction = true; } // If the type at a particular antecedent path is the declared type there is no // reason to process more antecedents since the only possible outcome is subtypes // that will be removed in the final union type anyway. if (type === declaredType) { break; } } // The result is incomplete if the first antecedent (the non-looping control flow path) // is incomplete. const result = getUnionOrEvolvingArrayType(antecedentTypes, subtypeReduction ? UnionReduction.Subtype : UnionReduction.Literal); if (isIncomplete(firstAntecedentType!)) { return createFlowType(result, /*incomplete*/ true); } cache.set(key, result); return result; } function isMatchingReferenceDiscriminant(expr: Expression, computedType: Type) { if (!(computedType.flags & TypeFlags.Union) || !isAccessExpression(expr)) { return false; } const name = getAccessedPropertyName(expr); if (name === undefined) { return false; } return isMatchingReference(reference, expr.expression) && isDiscriminantProperty(computedType, name); } function narrowTypeByDiscriminant(type: Type, access: AccessExpression, narrowType: (t: Type) => Type): Type { const propName = getAccessedPropertyName(access); if (propName === undefined) { return type; } const propType = getTypeOfPropertyOfType(type, propName); const narrowedPropType = propType && narrowType(propType); return propType === narrowedPropType ? type : filterType(type, t => isTypeComparableTo(getTypeOfPropertyOrIndexSignature(t, propName), narrowedPropType!)); } function narrowTypeByTruthiness(type: Type, expr: Expression, assumeTrue: boolean): Type { if (isMatchingReference(reference, expr)) { return getTypeWithFacts(type, assumeTrue ? TypeFacts.Truthy : TypeFacts.Falsy); } if (isMatchingReferenceDiscriminant(expr, declaredType)) { return narrowTypeByDiscriminant(type, expr, t => getTypeWithFacts(t, assumeTrue ? TypeFacts.Truthy : TypeFacts.Falsy)); } if (containsMatchingReferenceDiscriminant(reference, expr)) { return declaredType; } return type; } function isTypePresencePossible(type: Type, propName: __String, assumeTrue: boolean) { if (getIndexInfoOfType(type, IndexKind.String)) { return true; } const prop = getPropertyOfType(type, propName); if (prop) { return prop.flags & SymbolFlags.Optional ? true : assumeTrue; } return !assumeTrue; } function narrowByInKeyword(type: Type, literal: LiteralExpression, assumeTrue: boolean) { if ((type.flags & (TypeFlags.Union | TypeFlags.Object)) || (type.flags & TypeFlags.TypeParameter && (type as TypeParameter).isThisType)) { const propName = escapeLeadingUnderscores(literal.text); return filterType(type, t => isTypePresencePossible(t, propName, assumeTrue)); } return type; } function narrowTypeByBinaryExpression(type: Type, expr: BinaryExpression, assumeTrue: boolean): Type { switch (expr.operatorToken.kind) { case SyntaxKind.EqualsToken: return narrowTypeByTruthiness(type, expr.left, assumeTrue); case SyntaxKind.EqualsEqualsToken: case SyntaxKind.ExclamationEqualsToken: case SyntaxKind.EqualsEqualsEqualsToken: case SyntaxKind.ExclamationEqualsEqualsToken: const operator = expr.operatorToken.kind; const left = getReferenceCandidate(expr.left); const right = getReferenceCandidate(expr.right); if (left.kind === SyntaxKind.TypeOfExpression && isStringLiteralLike(right)) { return narrowTypeByTypeof(type, left, operator, right, assumeTrue); } if (right.kind === SyntaxKind.TypeOfExpression && isStringLiteralLike(left)) { return narrowTypeByTypeof(type, right, operator, left, assumeTrue); } if (isMatchingReference(reference, left)) { return narrowTypeByEquality(type, operator, right, assumeTrue); } if (isMatchingReference(reference, right)) { return narrowTypeByEquality(type, operator, left, assumeTrue); } if (isMatchingReferenceDiscriminant(left, declaredType)) { return narrowTypeByDiscriminant(type, left, t => narrowTypeByEquality(t, operator, right, assumeTrue)); } if (isMatchingReferenceDiscriminant(right, declaredType)) { return narrowTypeByDiscriminant(type, right, t => narrowTypeByEquality(t, operator, left, assumeTrue)); } if (containsMatchingReferenceDiscriminant(reference, left) || containsMatchingReferenceDiscriminant(reference, right)) { return declaredType; } break; case SyntaxKind.InstanceOfKeyword: return narrowTypeByInstanceof(type, expr, assumeTrue); case SyntaxKind.InKeyword: const target = getReferenceCandidate(expr.right); if (isStringLiteralLike(expr.left) && isMatchingReference(reference, target)) { return narrowByInKeyword(type, expr.left, assumeTrue); } break; case SyntaxKind.CommaToken: return narrowType(type, expr.right, assumeTrue); } return type; } function narrowTypeByEquality(type: Type, operator: SyntaxKind, value: Expression, assumeTrue: boolean): Type { if (type.flags & TypeFlags.Any) { return type; } if (operator === SyntaxKind.ExclamationEqualsToken || operator === SyntaxKind.ExclamationEqualsEqualsToken) { assumeTrue = !assumeTrue; } const valueType = getTypeOfExpression(value); if ((type.flags & TypeFlags.Unknown) && (operator === SyntaxKind.EqualsEqualsEqualsToken) && assumeTrue) { if (valueType.flags & (TypeFlags.Primitive | TypeFlags.NonPrimitive)) { return valueType; } if (valueType.flags & TypeFlags.Object) { return nonPrimitiveType; } return type; } if (valueType.flags & TypeFlags.Nullable) { if (!strictNullChecks) { return type; } const doubleEquals = operator === SyntaxKind.EqualsEqualsToken || operator === SyntaxKind.ExclamationEqualsToken; const facts = doubleEquals ? assumeTrue ? TypeFacts.EQUndefinedOrNull : TypeFacts.NEUndefinedOrNull : valueType.flags & TypeFlags.Null ? assumeTrue ? TypeFacts.EQNull : TypeFacts.NENull : assumeTrue ? TypeFacts.EQUndefined : TypeFacts.NEUndefined; return getTypeWithFacts(type, facts); } if (type.flags & TypeFlags.NotUnionOrUnit) { return type; } if (assumeTrue) { const narrowedType = filterType(type, t => areTypesComparable(t, valueType)); return narrowedType.flags & TypeFlags.Never ? type : replacePrimitivesWithLiterals(narrowedType, valueType); } if (isUnitType(valueType)) { const regularType = getRegularTypeOfLiteralType(valueType); return filterType(type, t => getRegularTypeOfLiteralType(t) !== regularType); } return type; } function narrowTypeByTypeof(type: Type, typeOfExpr: TypeOfExpression, operator: SyntaxKind, literal: LiteralExpression, assumeTrue: boolean): Type { // We have '==', '!=', '====', or !==' operator with 'typeof xxx' and string literal operands const target = getReferenceCandidate(typeOfExpr.expression); if (!isMatchingReference(reference, target)) { // For a reference of the form 'x.y', a 'typeof x === ...' type guard resets the // narrowed type of 'y' to its declared type. if (containsMatchingReference(reference, target)) { return declaredType; } return type; } if (operator === SyntaxKind.ExclamationEqualsToken || operator === SyntaxKind.ExclamationEqualsEqualsToken) { assumeTrue = !assumeTrue; } if (type.flags & TypeFlags.Any && literal.text === "function") { return type; } const facts = assumeTrue ? typeofEQFacts.get(literal.text) || TypeFacts.TypeofEQHostObject : typeofNEFacts.get(literal.text) || TypeFacts.TypeofNEHostObject; return getTypeWithFacts(assumeTrue ? mapType(type, narrowTypeForTypeof) : type, facts); function narrowTypeForTypeof(type: Type) { if (type.flags & TypeFlags.Unknown && literal.text === "object") { return getUnionType([nonPrimitiveType, nullType]); } // We narrow a non-union type to an exact primitive type if the non-union type // is a supertype of that primitive type. For example, type 'any' can be narrowed // to one of the primitive types. const targetType = literal.text === "function" ? globalFunctionType : typeofTypesByName.get(literal.text); if (targetType) { if (isTypeSubtypeOf(type, targetType)) { return type; } if (isTypeSubtypeOf(targetType, type)) { return targetType; } if (type.flags & TypeFlags.Instantiable) { const constraint = getBaseConstraintOfType(type) || anyType; if (isTypeSubtypeOf(targetType, constraint)) { return getIntersectionType([type, targetType]); } } } return type; } } function narrowTypeBySwitchOnDiscriminant(type: Type, switchStatement: SwitchStatement, clauseStart: number, clauseEnd: number) { // We only narrow if all case expressions specify // values with unit types, except for the case where // `type` is unknown. In this instance we map object // types to the nonPrimitive type and narrow with that. const switchTypes = getSwitchClauseTypes(switchStatement); if (!switchTypes.length) { return type; } const clauseTypes = switchTypes.slice(clauseStart, clauseEnd); const hasDefaultClause = clauseStart === clauseEnd || contains(clauseTypes, neverType); if ((type.flags & TypeFlags.Unknown) && !hasDefaultClause) { let groundClauseTypes: Type[] | undefined; for (let i = 0; i < clauseTypes.length; i += 1) { const t = clauseTypes[i]; if (t.flags & (TypeFlags.Primitive | TypeFlags.NonPrimitive)) { if (groundClauseTypes !== undefined) { groundClauseTypes.push(t); } } else if (t.flags & TypeFlags.Object) { if (groundClauseTypes === undefined) { groundClauseTypes = clauseTypes.slice(0, i); } groundClauseTypes.push(nonPrimitiveType); } else { return type; } } return getUnionType(groundClauseTypes === undefined ? clauseTypes : groundClauseTypes); } const discriminantType = getUnionType(clauseTypes); const caseType = discriminantType.flags & TypeFlags.Never ? neverType : replacePrimitivesWithLiterals(filterType(type, t => areTypesComparable(discriminantType, t)), discriminantType); if (!hasDefaultClause) { return caseType; } const defaultType = filterType(type, t => !(isUnitType(t) && contains(switchTypes, getRegularTypeOfLiteralType(t)))); return caseType.flags & TypeFlags.Never ? defaultType : getUnionType([caseType, defaultType]); } function getImpliedTypeFromTypeofCase(type: Type, text: string) { switch (text) { case "function": return type.flags & TypeFlags.Any ? type : globalFunctionType; case "object": return type.flags & TypeFlags.Unknown ? getUnionType([nonPrimitiveType, nullType]) : type; default: return typeofTypesByName.get(text) || type; } } function narrowTypeForTypeofSwitch(candidate: Type) { return (type: Type) => { if (isTypeSubtypeOf(candidate, type)) { return candidate; } if (type.flags & TypeFlags.Instantiable) { const constraint = getBaseConstraintOfType(type) || anyType; if (isTypeSubtypeOf(candidate, constraint)) { return getIntersectionType([type, candidate]); } } return type; }; } function narrowBySwitchOnTypeOf(type: Type, switchStatement: SwitchStatement, clauseStart: number, clauseEnd: number): Type { const switchWitnesses = getSwitchClauseTypeOfWitnesses(switchStatement); if (!switchWitnesses.length) { return type; } // Equal start and end denotes implicit fallthrough; undefined marks explicit default clause const defaultCaseLocation = findIndex(switchWitnesses, elem => elem === undefined); const hasDefaultClause = clauseStart === clauseEnd || (defaultCaseLocation >= clauseStart && defaultCaseLocation < clauseEnd); let clauseWitnesses: string[]; let switchFacts: TypeFacts; if (defaultCaseLocation > -1) { // We no longer need the undefined denoting an // explicit default case. Remove the undefined and // fix-up clauseStart and clauseEnd. This means // that we don't have to worry about undefined // in the witness array. const witnesses = switchWitnesses.filter(witness => witness !== undefined); // The adjusted clause start and end after removing the `default` statement. const fixedClauseStart = defaultCaseLocation < clauseStart ? clauseStart - 1 : clauseStart; const fixedClauseEnd = defaultCaseLocation < clauseEnd ? clauseEnd - 1 : clauseEnd; clauseWitnesses = witnesses.slice(fixedClauseStart, fixedClauseEnd); switchFacts = getFactsFromTypeofSwitch(fixedClauseStart, fixedClauseEnd, witnesses, hasDefaultClause); } else { clauseWitnesses = switchWitnesses.slice(clauseStart, clauseEnd); switchFacts = getFactsFromTypeofSwitch(clauseStart, clauseEnd, switchWitnesses, hasDefaultClause); } if (hasDefaultClause) { return filterType(type, t => (getTypeFacts(t) & switchFacts) === switchFacts); } /* The implied type is the raw type suggested by a value being caught in this clause. When the clause contains a default case we ignore the implied type and try to narrow using any facts we can learn: see `switchFacts`. Example: switch (typeof x) { case 'number': case 'string': break; default: break; case 'number': case 'boolean': break } In the first clause (case `number` and `string`) the implied type is number | string. In the default clause we de not compute an implied type. In the third clause (case `number` and `boolean`) the naive implied type is number | boolean, however we use the type facts to narrow the implied type to boolean. We know that number cannot be selected because it is caught in the first clause. */ let impliedType = getTypeWithFacts(getUnionType(clauseWitnesses.map(text => getImpliedTypeFromTypeofCase(type, text))), switchFacts); if (impliedType.flags & TypeFlags.Union) { impliedType = getAssignmentReducedType(impliedType as UnionType, getBaseConstraintOrType(type)); } return getTypeWithFacts(mapType(type, narrowTypeForTypeofSwitch(impliedType)), switchFacts); } function narrowTypeByInstanceof(type: Type, expr: BinaryExpression, assumeTrue: boolean): Type { const left = getReferenceCandidate(expr.left); if (!isMatchingReference(reference, left)) { // For a reference of the form 'x.y', an 'x instanceof T' type guard resets the // narrowed type of 'y' to its declared type. We do this because preceding 'x.y' // references might reference a different 'y' property. However, we make an exception // for property accesses where x is a synthetic 'this' expression, indicating that we // were called from isPropertyInitializedInConstructor. Without this exception, // initializations of 'this' properties that occur before a 'this instanceof XXX' // check would not be considered. if (containsMatchingReference(reference, left) && !isSyntheticThisPropertyAccess(reference)) { return declaredType; } return type; } // Check that right operand is a function type with a prototype property const rightType = getTypeOfExpression(expr.right); if (!isTypeDerivedFrom(rightType, globalFunctionType)) { return type; } let targetType: Type | undefined; const prototypeProperty = getPropertyOfType(rightType, "prototype" as __String); if (prototypeProperty) { // Target type is type of the prototype property const prototypePropertyType = getTypeOfSymbol(prototypeProperty); if (!isTypeAny(prototypePropertyType)) { targetType = prototypePropertyType; } } // Don't narrow from 'any' if the target type is exactly 'Object' or 'Function' if (isTypeAny(type) && (targetType === globalObjectType || targetType === globalFunctionType)) { return type; } if (!targetType) { const constructSignatures = getSignaturesOfType(rightType, SignatureKind.Construct); targetType = constructSignatures.length ? getUnionType(map(constructSignatures, signature => getReturnTypeOfSignature(getErasedSignature(signature)))) : emptyObjectType; } return getNarrowedType(type, targetType, assumeTrue, isTypeDerivedFrom); } function getNarrowedType(type: Type, candidate: Type, assumeTrue: boolean, isRelated: (source: Type, target: Type) => boolean) { if (!assumeTrue) { return filterType(type, t => !isRelated(t, candidate)); } // If the current type is a union type, remove all constituents that couldn't be instances of // the candidate type. If one or more constituents remain, return a union of those. if (type.flags & TypeFlags.Union) { const assignableType = filterType(type, t => isRelated(t, candidate)); if (!(assignableType.flags & TypeFlags.Never)) { return assignableType; } } // If the candidate type is a subtype of the target type, narrow to the candidate type. // Otherwise, if the target type is assignable to the candidate type, keep the target type. // Otherwise, if the candidate type is assignable to the target type, narrow to the candidate // type. Otherwise, the types are completely unrelated, so narrow to an intersection of the // two types. return isTypeSubtypeOf(candidate, type) ? candidate : isTypeAssignableTo(type, candidate) ? type : isTypeAssignableTo(candidate, type) ? candidate : getIntersectionType([type, candidate]); } function narrowTypeByTypePredicate(type: Type, callExpression: CallExpression, assumeTrue: boolean): Type { if (!hasMatchingArgument(callExpression, reference) || !maybeTypePredicateCall(callExpression)) { return type; } const signature = getResolvedSignature(callExpression); const predicate = getTypePredicateOfSignature(signature); if (!predicate) { return type; } // Don't narrow from 'any' if the predicate type is exactly 'Object' or 'Function' if (isTypeAny(type) && (predicate.type === globalObjectType || predicate.type === globalFunctionType)) { return type; } if (isIdentifierTypePredicate(predicate)) { const predicateArgument = callExpression.arguments[predicate.parameterIndex - (signature.thisParameter ? 1 : 0)]; if (predicateArgument) { if (isMatchingReference(reference, predicateArgument)) { return getNarrowedType(type, predicate.type, assumeTrue, isTypeSubtypeOf); } if (containsMatchingReference(reference, predicateArgument)) { return declaredType; } } } else { const invokedExpression = skipParentheses(callExpression.expression); if (isAccessExpression(invokedExpression)) { const possibleReference = skipParentheses(invokedExpression.expression); if (isMatchingReference(reference, possibleReference)) { return getNarrowedType(type, predicate.type, assumeTrue, isTypeSubtypeOf); } if (containsMatchingReference(reference, possibleReference)) { return declaredType; } } } return type; } // Narrow the given type based on the given expression having the assumed boolean value. The returned type // will be a subtype or the same type as the argument. function narrowType(type: Type, expr: Expression, assumeTrue: boolean): Type { switch (expr.kind) { case SyntaxKind.Identifier: case SyntaxKind.ThisKeyword: case SyntaxKind.SuperKeyword: case SyntaxKind.PropertyAccessExpression: case SyntaxKind.ElementAccessExpression: return narrowTypeByTruthiness(type, expr, assumeTrue); case SyntaxKind.CallExpression: return narrowTypeByTypePredicate(type, expr, assumeTrue); case SyntaxKind.ParenthesizedExpression: return narrowType(type, (expr).expression, assumeTrue); case SyntaxKind.BinaryExpression: return narrowTypeByBinaryExpression(type, expr, assumeTrue); case SyntaxKind.PrefixUnaryExpression: if ((expr).operator === SyntaxKind.ExclamationToken) { return narrowType(type, (expr).operand, !assumeTrue); } break; } return type; } } function getTypeOfSymbolAtLocation(symbol: Symbol, location: Node) { symbol = symbol.exportSymbol || symbol; // If we have an identifier or a property access at the given location, if the location is // an dotted name expression, and if the location is not an assignment target, obtain the type // of the expression (which will reflect control flow analysis). If the expression indeed // resolved to the given symbol, return the narrowed type. if (location.kind === SyntaxKind.Identifier) { if (isRightSideOfQualifiedNameOrPropertyAccess(location)) { location = location.parent; } if (isExpressionNode(location) && !isAssignmentTarget(location)) { const type = getTypeOfExpression(location); if (getExportSymbolOfValueSymbolIfExported(getNodeLinks(location).resolvedSymbol) === symbol) { return type; } } } // The location isn't a reference to the given symbol, meaning we're being asked // a hypothetical question of what type the symbol would have if there was a reference // to it at the given location. Since we have no control flow information for the // hypothetical reference (control flow information is created and attached by the // binder), we simply return the declared type of the symbol. return getTypeOfSymbol(symbol); } function getControlFlowContainer(node: Node): Node { return findAncestor(node.parent, node => isFunctionLike(node) && !getImmediatelyInvokedFunctionExpression(node) || node.kind === SyntaxKind.ModuleBlock || node.kind === SyntaxKind.SourceFile || node.kind === SyntaxKind.PropertyDeclaration)!; } // Check if a parameter is assigned anywhere within its declaring function. function isParameterAssigned(symbol: Symbol) { const func = getRootDeclaration(symbol.valueDeclaration).parent; const links = getNodeLinks(func); if (!(links.flags & NodeCheckFlags.AssignmentsMarked)) { links.flags |= NodeCheckFlags.AssignmentsMarked; if (!hasParentWithAssignmentsMarked(func)) { markParameterAssignments(func); } } return symbol.isAssigned || false; } function hasParentWithAssignmentsMarked(node: Node) { return !!findAncestor(node.parent, node => isFunctionLike(node) && !!(getNodeLinks(node).flags & NodeCheckFlags.AssignmentsMarked)); } function markParameterAssignments(node: Node) { if (node.kind === SyntaxKind.Identifier) { if (isAssignmentTarget(node)) { const symbol = getResolvedSymbol(node); if (symbol.valueDeclaration && getRootDeclaration(symbol.valueDeclaration).kind === SyntaxKind.Parameter) { symbol.isAssigned = true; } } } else { forEachChild(node, markParameterAssignments); } } function isConstVariable(symbol: Symbol) { return symbol.flags & SymbolFlags.Variable && (getDeclarationNodeFlagsFromSymbol(symbol) & NodeFlags.Const) !== 0 && getTypeOfSymbol(symbol) !== autoArrayType; } /** remove undefined from the annotated type of a parameter when there is an initializer (that doesn't include undefined) */ function removeOptionalityFromDeclaredType(declaredType: Type, declaration: VariableLikeDeclaration): Type { const annotationIncludesUndefined = strictNullChecks && declaration.kind === SyntaxKind.Parameter && declaration.initializer && getFalsyFlags(declaredType) & TypeFlags.Undefined && !(getFalsyFlags(checkExpression(declaration.initializer)) & TypeFlags.Undefined); return annotationIncludesUndefined ? getTypeWithFacts(declaredType, TypeFacts.NEUndefined) : declaredType; } function isConstraintPosition(node: Node) { const parent = node.parent; return parent.kind === SyntaxKind.PropertyAccessExpression || parent.kind === SyntaxKind.CallExpression && (parent).expression === node || parent.kind === SyntaxKind.ElementAccessExpression && (parent).expression === node || parent.kind === SyntaxKind.BindingElement && (parent).name === node && !!(parent).initializer; } function typeHasNullableConstraint(type: Type) { return type.flags & TypeFlags.InstantiableNonPrimitive && maybeTypeOfKind(getBaseConstraintOfType(type) || emptyObjectType, TypeFlags.Nullable); } function getConstraintForLocation(type: Type, node: Node): Type; function getConstraintForLocation(type: Type | undefined, node: Node): Type | undefined; function getConstraintForLocation(type: Type, node: Node): Type | undefined { // When a node is the left hand expression of a property access, element access, or call expression, // and the type of the node includes type variables with constraints that are nullable, we fetch the // apparent type of the node *before* performing control flow analysis such that narrowings apply to // the constraint type. if (type && isConstraintPosition(node) && forEachType(type, typeHasNullableConstraint)) { return mapType(getWidenedType(type), getBaseConstraintOrType); } return type; } function markAliasReferenced(symbol: Symbol, location: Node) { if (isNonLocalAlias(symbol, /*excludes*/ SymbolFlags.Value) && !isInTypeQuery(location) && !isConstEnumOrConstEnumOnlyModule(resolveAlias(symbol))) { markAliasSymbolAsReferenced(symbol); } } function checkIdentifier(node: Identifier): Type { const symbol = getResolvedSymbol(node); if (symbol === unknownSymbol) { return errorType; } // As noted in ECMAScript 6 language spec, arrow functions never have an arguments objects. // Although in down-level emit of arrow function, we emit it using function expression which means that // arguments objects will be bound to the inner object; emitting arrow function natively in ES6, arguments objects // will be bound to non-arrow function that contain this arrow function. This results in inconsistent behavior. // To avoid that we will give an error to users if they use arguments objects in arrow function so that they // can explicitly bound arguments objects if (symbol === argumentsSymbol) { const container = getContainingFunction(node)!; if (languageVersion < ScriptTarget.ES2015) { if (container.kind === SyntaxKind.ArrowFunction) { error(node, Diagnostics.The_arguments_object_cannot_be_referenced_in_an_arrow_function_in_ES3_and_ES5_Consider_using_a_standard_function_expression); } else if (hasModifier(container, ModifierFlags.Async)) { error(node, Diagnostics.The_arguments_object_cannot_be_referenced_in_an_async_function_or_method_in_ES3_and_ES5_Consider_using_a_standard_function_or_method); } } getNodeLinks(container).flags |= NodeCheckFlags.CaptureArguments; return getTypeOfSymbol(symbol); } // We should only mark aliases as referenced if there isn't a local value declaration // for the symbol. Also, don't mark any property access expression LHS - checkPropertyAccessExpression will handle that if (!(node.parent && isPropertyAccessExpression(node.parent) && node.parent.expression === node)) { markAliasReferenced(symbol, node); } const localOrExportSymbol = getExportSymbolOfValueSymbolIfExported(symbol); let declaration: Declaration | undefined = localOrExportSymbol.valueDeclaration; if (localOrExportSymbol.flags & SymbolFlags.Class) { // Due to the emit for class decorators, any reference to the class from inside of the class body // must instead be rewritten to point to a temporary variable to avoid issues with the double-bind // behavior of class names in ES6. if (declaration.kind === SyntaxKind.ClassDeclaration && nodeIsDecorated(declaration as ClassDeclaration)) { let container = getContainingClass(node); while (container !== undefined) { if (container === declaration && container.name !== node) { getNodeLinks(declaration).flags |= NodeCheckFlags.ClassWithConstructorReference; getNodeLinks(node).flags |= NodeCheckFlags.ConstructorReferenceInClass; break; } container = getContainingClass(container); } } else if (declaration.kind === SyntaxKind.ClassExpression) { // When we emit a class expression with static members that contain a reference // to the constructor in the initializer, we will need to substitute that // binding with an alias as the class name is not in scope. let container = getThisContainer(node, /*includeArrowFunctions*/ false); while (container.kind !== SyntaxKind.SourceFile) { if (container.parent === declaration) { if (container.kind === SyntaxKind.PropertyDeclaration && hasModifier(container, ModifierFlags.Static)) { getNodeLinks(declaration).flags |= NodeCheckFlags.ClassWithConstructorReference; getNodeLinks(node).flags |= NodeCheckFlags.ConstructorReferenceInClass; } break; } container = getThisContainer(container, /*includeArrowFunctions*/ false); } } } checkNestedBlockScopedBinding(node, symbol); const type = getConstraintForLocation(getTypeOfSymbol(localOrExportSymbol), node); const assignmentKind = getAssignmentTargetKind(node); if (assignmentKind) { if (!(localOrExportSymbol.flags & SymbolFlags.Variable) && !(isInJSFile(node) && localOrExportSymbol.flags & SymbolFlags.ValueModule)) { error(node, Diagnostics.Cannot_assign_to_0_because_it_is_not_a_variable, symbolToString(symbol)); return errorType; } if (isReadonlySymbol(localOrExportSymbol)) { if (localOrExportSymbol.flags & SymbolFlags.Variable) { error(node, Diagnostics.Cannot_assign_to_0_because_it_is_a_constant, symbolToString(symbol)); } else { error(node, Diagnostics.Cannot_assign_to_0_because_it_is_a_read_only_property, symbolToString(symbol)); } return errorType; } } const isAlias = localOrExportSymbol.flags & SymbolFlags.Alias; // We only narrow variables and parameters occurring in a non-assignment position. For all other // entities we simply return the declared type. if (localOrExportSymbol.flags & SymbolFlags.Variable) { if (assignmentKind === AssignmentKind.Definite) { return type; } } else if (isAlias) { declaration = find(symbol.declarations, isSomeImportDeclaration); } else { return type; } if (!declaration) { return type; } // The declaration container is the innermost function that encloses the declaration of the variable // or parameter. The flow container is the innermost function starting with which we analyze the control // flow graph to determine the control flow based type. const isParameter = getRootDeclaration(declaration).kind === SyntaxKind.Parameter; const declarationContainer = getControlFlowContainer(declaration); let flowContainer = getControlFlowContainer(node); const isOuterVariable = flowContainer !== declarationContainer; const isSpreadDestructuringAssignmentTarget = node.parent && node.parent.parent && isSpreadAssignment(node.parent) && isDestructuringAssignmentTarget(node.parent.parent); const isModuleExports = symbol.flags & SymbolFlags.ModuleExports; // When the control flow originates in a function expression or arrow function and we are referencing // a const variable or parameter from an outer function, we extend the origin of the control flow // analysis to include the immediately enclosing function. while (flowContainer !== declarationContainer && (flowContainer.kind === SyntaxKind.FunctionExpression || flowContainer.kind === SyntaxKind.ArrowFunction || isObjectLiteralOrClassExpressionMethod(flowContainer)) && (isConstVariable(localOrExportSymbol) || isParameter && !isParameterAssigned(localOrExportSymbol))) { flowContainer = getControlFlowContainer(flowContainer); } // We only look for uninitialized variables in strict null checking mode, and only when we can analyze // the entire control flow graph from the variable's declaration (i.e. when the flow container and // declaration container are the same). const assumeInitialized = isParameter || isAlias || isOuterVariable || isSpreadDestructuringAssignmentTarget || isModuleExports || type !== autoType && type !== autoArrayType && (!strictNullChecks || (type.flags & TypeFlags.AnyOrUnknown) !== 0 || isInTypeQuery(node) || node.parent.kind === SyntaxKind.ExportSpecifier) || node.parent.kind === SyntaxKind.NonNullExpression || declaration.kind === SyntaxKind.VariableDeclaration && (declaration).exclamationToken || declaration.flags & NodeFlags.Ambient; const initialType = assumeInitialized ? (isParameter ? removeOptionalityFromDeclaredType(type, declaration as VariableLikeDeclaration) : type) : type === autoType || type === autoArrayType ? undefinedType : getOptionalType(type); const flowType = getFlowTypeOfReference(node, type, initialType, flowContainer, !assumeInitialized); // A variable is considered uninitialized when it is possible to analyze the entire control flow graph // from declaration to use, and when the variable's declared type doesn't include undefined but the // control flow based type does include undefined. if (!isEvolvingArrayOperationTarget(node) && (type === autoType || type === autoArrayType)) { if (flowType === autoType || flowType === autoArrayType) { if (noImplicitAny) { error(getNameOfDeclaration(declaration), Diagnostics.Variable_0_implicitly_has_type_1_in_some_locations_where_its_type_cannot_be_determined, symbolToString(symbol), typeToString(flowType)); error(node, Diagnostics.Variable_0_implicitly_has_an_1_type, symbolToString(symbol), typeToString(flowType)); } return convertAutoToAny(flowType); } } else if (!assumeInitialized && !(getFalsyFlags(type) & TypeFlags.Undefined) && getFalsyFlags(flowType) & TypeFlags.Undefined) { error(node, Diagnostics.Variable_0_is_used_before_being_assigned, symbolToString(symbol)); // Return the declared type to reduce follow-on errors return type; } return assignmentKind ? getBaseTypeOfLiteralType(flowType) : flowType; } function isInsideFunction(node: Node, threshold: Node): boolean { return !!findAncestor(node, n => n === threshold ? "quit" : isFunctionLike(n)); } function getPartOfForStatementContainingNode(node: Node, container: ForStatement) { return findAncestor(node, n => n === container ? "quit" : n === container.initializer || n === container.condition || n === container.incrementor || n === container.statement); } function checkNestedBlockScopedBinding(node: Identifier, symbol: Symbol): void { if (languageVersion >= ScriptTarget.ES2015 || (symbol.flags & (SymbolFlags.BlockScopedVariable | SymbolFlags.Class)) === 0 || symbol.valueDeclaration.parent.kind === SyntaxKind.CatchClause) { return; } // 1. walk from the use site up to the declaration and check // if there is anything function like between declaration and use-site (is binding/class is captured in function). // 2. walk from the declaration up to the boundary of lexical environment and check // if there is an iteration statement in between declaration and boundary (is binding/class declared inside iteration statement) const container = getEnclosingBlockScopeContainer(symbol.valueDeclaration); const usedInFunction = isInsideFunction(node.parent, container); let current = container; let containedInIterationStatement = false; while (current && !nodeStartsNewLexicalEnvironment(current)) { if (isIterationStatement(current, /*lookInLabeledStatements*/ false)) { containedInIterationStatement = true; break; } current = current.parent; } if (containedInIterationStatement) { if (usedInFunction) { // mark iteration statement as containing block-scoped binding captured in some function let capturesBlockScopeBindingInLoopBody = true; if (isForStatement(container) && getAncestor(symbol.valueDeclaration, SyntaxKind.VariableDeclarationList)!.parent === container) { const part = getPartOfForStatementContainingNode(node.parent, container); if (part) { const links = getNodeLinks(part); links.flags |= NodeCheckFlags.ContainsCapturedBlockScopeBinding; const capturedBindings = links.capturedBlockScopeBindings || (links.capturedBlockScopeBindings = []); pushIfUnique(capturedBindings, symbol); if (part === container.initializer) { capturesBlockScopeBindingInLoopBody = false; // Initializer is outside of loop body } } } if (capturesBlockScopeBindingInLoopBody) { getNodeLinks(current).flags |= NodeCheckFlags.LoopWithCapturedBlockScopedBinding; } } // mark variables that are declared in loop initializer and reassigned inside the body of ForStatement. // if body of ForStatement will be converted to function then we'll need a extra machinery to propagate reassigned values back. if (container.kind === SyntaxKind.ForStatement && getAncestor(symbol.valueDeclaration, SyntaxKind.VariableDeclarationList)!.parent === container && isAssignedInBodyOfForStatement(node, container)) { getNodeLinks(symbol.valueDeclaration).flags |= NodeCheckFlags.NeedsLoopOutParameter; } // set 'declared inside loop' bit on the block-scoped binding getNodeLinks(symbol.valueDeclaration).flags |= NodeCheckFlags.BlockScopedBindingInLoop; } if (usedInFunction) { getNodeLinks(symbol.valueDeclaration).flags |= NodeCheckFlags.CapturedBlockScopedBinding; } } function isBindingCapturedByNode(node: Node, decl: VariableDeclaration | BindingElement) { const links = getNodeLinks(node); return !!links && contains(links.capturedBlockScopeBindings, getSymbolOfNode(decl)); } function isAssignedInBodyOfForStatement(node: Identifier, container: ForStatement): boolean { // skip parenthesized nodes let current: Node = node; while (current.parent.kind === SyntaxKind.ParenthesizedExpression) { current = current.parent; } // check if node is used as LHS in some assignment expression let isAssigned = false; if (isAssignmentTarget(current)) { isAssigned = true; } else if ((current.parent.kind === SyntaxKind.PrefixUnaryExpression || current.parent.kind === SyntaxKind.PostfixUnaryExpression)) { const expr = current.parent; isAssigned = expr.operator === SyntaxKind.PlusPlusToken || expr.operator === SyntaxKind.MinusMinusToken; } if (!isAssigned) { return false; } // at this point we know that node is the target of assignment // now check that modification happens inside the statement part of the ForStatement return !!findAncestor(current, n => n === container ? "quit" : n === container.statement); } function captureLexicalThis(node: Node, container: Node): void { getNodeLinks(node).flags |= NodeCheckFlags.LexicalThis; if (container.kind === SyntaxKind.PropertyDeclaration || container.kind === SyntaxKind.Constructor) { const classNode = container.parent; getNodeLinks(classNode).flags |= NodeCheckFlags.CaptureThis; } else { getNodeLinks(container).flags |= NodeCheckFlags.CaptureThis; } } function findFirstSuperCall(n: Node): SuperCall | undefined { if (isSuperCall(n)) { return n; } else if (isFunctionLike(n)) { return undefined; } return forEachChild(n, findFirstSuperCall); } /** * Return a cached result if super-statement is already found. * Otherwise, find a super statement in a given constructor function and cache the result in the node-links of the constructor * * @param constructor constructor-function to look for super statement */ function getSuperCallInConstructor(constructor: ConstructorDeclaration): SuperCall | undefined { const links = getNodeLinks(constructor); // Only trying to find super-call if we haven't yet tried to find one. Once we try, we will record the result if (links.hasSuperCall === undefined) { links.superCall = findFirstSuperCall(constructor.body!); links.hasSuperCall = links.superCall ? true : false; } return links.superCall!; } /** * Check if the given class-declaration extends null then return true. * Otherwise, return false * @param classDecl a class declaration to check if it extends null */ function classDeclarationExtendsNull(classDecl: ClassDeclaration): boolean { const classSymbol = getSymbolOfNode(classDecl); const classInstanceType = getDeclaredTypeOfSymbol(classSymbol); const baseConstructorType = getBaseConstructorTypeOfClass(classInstanceType); return baseConstructorType === nullWideningType; } function checkThisBeforeSuper(node: Node, container: Node, diagnosticMessage: DiagnosticMessage) { const containingClassDecl = container.parent; const baseTypeNode = getClassExtendsHeritageElement(containingClassDecl); // If a containing class does not have extends clause or the class extends null // skip checking whether super statement is called before "this" accessing. if (baseTypeNode && !classDeclarationExtendsNull(containingClassDecl)) { const superCall = getSuperCallInConstructor(container); // We should give an error in the following cases: // - No super-call // - "this" is accessing before super-call. // i.e super(this) // this.x; super(); // We want to make sure that super-call is done before accessing "this" so that // "this" is not accessed as a parameter of the super-call. if (!superCall || superCall.end > node.pos) { // In ES6, super inside constructor of class-declaration has to precede "this" accessing error(node, diagnosticMessage); } } } function checkThisExpression(node: Node): Type { // Stop at the first arrow function so that we can // tell whether 'this' needs to be captured. let container = getThisContainer(node, /* includeArrowFunctions */ true); let capturedByArrowFunction = false; if (container.kind === SyntaxKind.Constructor) { checkThisBeforeSuper(node, container, Diagnostics.super_must_be_called_before_accessing_this_in_the_constructor_of_a_derived_class); } // Now skip arrow functions to get the "real" owner of 'this'. if (container.kind === SyntaxKind.ArrowFunction) { container = getThisContainer(container, /* includeArrowFunctions */ false); capturedByArrowFunction = true; } switch (container.kind) { case SyntaxKind.ModuleDeclaration: error(node, Diagnostics.this_cannot_be_referenced_in_a_module_or_namespace_body); // do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks break; case SyntaxKind.EnumDeclaration: error(node, Diagnostics.this_cannot_be_referenced_in_current_location); // do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks break; case SyntaxKind.Constructor: if (isInConstructorArgumentInitializer(node, container)) { error(node, Diagnostics.this_cannot_be_referenced_in_constructor_arguments); // do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks } break; case SyntaxKind.PropertyDeclaration: case SyntaxKind.PropertySignature: if (hasModifier(container, ModifierFlags.Static)) { error(node, Diagnostics.this_cannot_be_referenced_in_a_static_property_initializer); // do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks } break; case SyntaxKind.ComputedPropertyName: error(node, Diagnostics.this_cannot_be_referenced_in_a_computed_property_name); break; } // When targeting es6, mark that we'll need to capture `this` in its lexically bound scope. if (capturedByArrowFunction && languageVersion < ScriptTarget.ES2015) { captureLexicalThis(node, container); } const type = tryGetThisTypeAt(node, container); if (!type && noImplicitThis) { // With noImplicitThis, functions may not reference 'this' if it has type 'any' const diag = error( node, capturedByArrowFunction && container.kind === SyntaxKind.SourceFile ? Diagnostics.The_containing_arrow_function_captures_the_global_value_of_this_which_implicitly_has_type_any : Diagnostics.this_implicitly_has_type_any_because_it_does_not_have_a_type_annotation); if (!isSourceFile(container)) { const outsideThis = tryGetThisTypeAt(container); if (outsideThis) { addRelatedInfo(diag, createDiagnosticForNode(container, Diagnostics.An_outer_value_of_this_is_shadowed_by_this_container)); } } } return type || anyType; } function tryGetThisTypeAt(node: Node, container = getThisContainer(node, /*includeArrowFunctions*/ false)): Type | undefined { const isInJS = isInJSFile(node); if (isFunctionLike(container) && (!isInParameterInitializerBeforeContainingFunction(node) || getThisParameter(container))) { // Note: a parameter initializer should refer to class-this unless function-this is explicitly annotated. // If this is a function in a JS file, it might be a class method. const className = getClassNameFromPrototypeMethod(container); if (isInJS && className) { const classSymbol = checkExpression(className).symbol; if (classSymbol && classSymbol.members && (classSymbol.flags & SymbolFlags.Function)) { const classType = getJSClassType(classSymbol); if (classType) { return getFlowTypeOfReference(node, classType); } } } // Check if it's a constructor definition, can be either a variable decl or function decl // i.e. // * /** @constructor */ function [name]() { ... } // * /** @constructor */ var x = function() { ... } else if (isInJS && (container.kind === SyntaxKind.FunctionExpression || container.kind === SyntaxKind.FunctionDeclaration) && getJSDocClassTag(container)) { const classType = getJSClassType(getMergedSymbol(container.symbol)); if (classType) { return getFlowTypeOfReference(node, classType); } } const thisType = getThisTypeOfDeclaration(container) || getContextualThisParameterType(container); if (thisType) { return getFlowTypeOfReference(node, thisType); } } if (isClassLike(container.parent)) { const symbol = getSymbolOfNode(container.parent); const type = hasModifier(container, ModifierFlags.Static) ? getTypeOfSymbol(symbol) : (getDeclaredTypeOfSymbol(symbol)).thisType!; return getFlowTypeOfReference(node, type); } if (isInJS) { const type = getTypeForThisExpressionFromJSDoc(container); if (type && type !== errorType) { return getFlowTypeOfReference(node, type); } } } function getClassNameFromPrototypeMethod(container: Node) { // Check if it's the RHS of a x.prototype.y = function [name]() { .... } if (container.kind === SyntaxKind.FunctionExpression && isBinaryExpression(container.parent) && getAssignmentDeclarationKind(container.parent) === AssignmentDeclarationKind.PrototypeProperty) { // Get the 'x' of 'x.prototype.y = container' return ((container.parent // x.prototype.y = container .left as PropertyAccessExpression) // x.prototype.y .expression as PropertyAccessExpression) // x.prototype .expression; // x } // x.prototype = { method() { } } else if (container.kind === SyntaxKind.MethodDeclaration && container.parent.kind === SyntaxKind.ObjectLiteralExpression && isBinaryExpression(container.parent.parent) && getAssignmentDeclarationKind(container.parent.parent) === AssignmentDeclarationKind.Prototype) { return (container.parent.parent.left as PropertyAccessExpression).expression; } // x.prototype = { method: function() { } } else if (container.kind === SyntaxKind.FunctionExpression && container.parent.kind === SyntaxKind.PropertyAssignment && container.parent.parent.kind === SyntaxKind.ObjectLiteralExpression && isBinaryExpression(container.parent.parent.parent) && getAssignmentDeclarationKind(container.parent.parent.parent) === AssignmentDeclarationKind.Prototype) { return (container.parent.parent.parent.left as PropertyAccessExpression).expression; } // Object.defineProperty(x, "method", { value: function() { } }); // Object.defineProperty(x, "method", { set: (x: () => void) => void }); // Object.defineProperty(x, "method", { get: () => function() { }) }); else if (container.kind === SyntaxKind.FunctionExpression && isPropertyAssignment(container.parent) && isIdentifier(container.parent.name) && (container.parent.name.escapedText === "value" || container.parent.name.escapedText === "get" || container.parent.name.escapedText === "set") && isObjectLiteralExpression(container.parent.parent) && isCallExpression(container.parent.parent.parent) && container.parent.parent.parent.arguments[2] === container.parent.parent && getAssignmentDeclarationKind(container.parent.parent.parent) === AssignmentDeclarationKind.ObjectDefinePrototypeProperty) { return (container.parent.parent.parent.arguments[0] as PropertyAccessExpression).expression; } // Object.defineProperty(x, "method", { value() { } }); // Object.defineProperty(x, "method", { set(x: () => void) {} }); // Object.defineProperty(x, "method", { get() { return () => {} } }); else if (isMethodDeclaration(container) && isIdentifier(container.name) && (container.name.escapedText === "value" || container.name.escapedText === "get" || container.name.escapedText === "set") && isObjectLiteralExpression(container.parent) && isCallExpression(container.parent.parent) && container.parent.parent.arguments[2] === container.parent && getAssignmentDeclarationKind(container.parent.parent) === AssignmentDeclarationKind.ObjectDefinePrototypeProperty) { return (container.parent.parent.arguments[0] as PropertyAccessExpression).expression; } } function getTypeForThisExpressionFromJSDoc(node: Node) { const jsdocType = getJSDocType(node); if (jsdocType && jsdocType.kind === SyntaxKind.JSDocFunctionType) { const jsDocFunctionType = jsdocType; if (jsDocFunctionType.parameters.length > 0 && jsDocFunctionType.parameters[0].name && (jsDocFunctionType.parameters[0].name as Identifier).escapedText === InternalSymbolName.This) { return getTypeFromTypeNode(jsDocFunctionType.parameters[0].type!); } } const thisTag = getJSDocThisTag(node); if (thisTag && thisTag.typeExpression) { return getTypeFromTypeNode(thisTag.typeExpression); } } function isInConstructorArgumentInitializer(node: Node, constructorDecl: Node): boolean { return !!findAncestor(node, n => isFunctionLikeDeclaration(n) ? "quit" : n.kind === SyntaxKind.Parameter && n.parent === constructorDecl); } function checkSuperExpression(node: Node): Type { const isCallExpression = node.parent.kind === SyntaxKind.CallExpression && (node.parent).expression === node; let container = getSuperContainer(node, /*stopOnFunctions*/ true); let needToCaptureLexicalThis = false; // adjust the container reference in case if super is used inside arrow functions with arbitrarily deep nesting if (!isCallExpression) { while (container && container.kind === SyntaxKind.ArrowFunction) { container = getSuperContainer(container, /*stopOnFunctions*/ true); needToCaptureLexicalThis = languageVersion < ScriptTarget.ES2015; } } const canUseSuperExpression = isLegalUsageOfSuperExpression(container); let nodeCheckFlag: NodeCheckFlags = 0; if (!canUseSuperExpression) { // issue more specific error if super is used in computed property name // class A { foo() { return "1" }} // class B { // [super.foo()]() {} // } const current = findAncestor(node, n => n === container ? "quit" : n.kind === SyntaxKind.ComputedPropertyName); if (current && current.kind === SyntaxKind.ComputedPropertyName) { error(node, Diagnostics.super_cannot_be_referenced_in_a_computed_property_name); } else if (isCallExpression) { error(node, Diagnostics.Super_calls_are_not_permitted_outside_constructors_or_in_nested_functions_inside_constructors); } else if (!container || !container.parent || !(isClassLike(container.parent) || container.parent.kind === SyntaxKind.ObjectLiteralExpression)) { error(node, Diagnostics.super_can_only_be_referenced_in_members_of_derived_classes_or_object_literal_expressions); } else { error(node, Diagnostics.super_property_access_is_permitted_only_in_a_constructor_member_function_or_member_accessor_of_a_derived_class); } return errorType; } if (!isCallExpression && container.kind === SyntaxKind.Constructor) { checkThisBeforeSuper(node, container, Diagnostics.super_must_be_called_before_accessing_a_property_of_super_in_the_constructor_of_a_derived_class); } if (hasModifier(container, ModifierFlags.Static) || isCallExpression) { nodeCheckFlag = NodeCheckFlags.SuperStatic; } else { nodeCheckFlag = NodeCheckFlags.SuperInstance; } getNodeLinks(node).flags |= nodeCheckFlag; // Due to how we emit async functions, we need to specialize the emit for an async method that contains a `super` reference. // This is due to the fact that we emit the body of an async function inside of a generator function. As generator // functions cannot reference `super`, we emit a helper inside of the method body, but outside of the generator. This helper // uses an arrow function, which is permitted to reference `super`. // // There are two primary ways we can access `super` from within an async method. The first is getting the value of a property // or indexed access on super, either as part of a right-hand-side expression or call expression. The second is when setting the value // of a property or indexed access, either as part of an assignment expression or destructuring assignment. // // The simplest case is reading a value, in which case we will emit something like the following: // // // ts // ... // async asyncMethod() { // let x = await super.asyncMethod(); // return x; // } // ... // // // js // ... // asyncMethod() { // const _super = Object.create(null, { // asyncMethod: { get: () => super.asyncMethod }, // }); // return __awaiter(this, arguments, Promise, function *() { // let x = yield _super.asyncMethod.call(this); // return x; // }); // } // ... // // The more complex case is when we wish to assign a value, especially as part of a destructuring assignment. As both cases // are legal in ES6, but also likely less frequent, we only emit setters if there is an assignment: // // // ts // ... // async asyncMethod(ar: Promise) { // [super.a, super.b] = await ar; // } // ... // // // js // ... // asyncMethod(ar) { // const _super = Object.create(null, { // a: { get: () => super.a, set: (v) => super.a = v }, // b: { get: () => super.b, set: (v) => super.b = v } // }; // return __awaiter(this, arguments, Promise, function *() { // [_super.a, _super.b] = yield ar; // }); // } // ... // // Creating an object that has getter and setters instead of just an accessor function is required for destructuring assignments // as a call expression cannot be used as the target of a destructuring assignment while a property access can. // // For element access expressions (`super[x]`), we emit a generic helper that forwards the element access in both situations. if (container.kind === SyntaxKind.MethodDeclaration && hasModifier(container, ModifierFlags.Async)) { if (isSuperProperty(node.parent) && isAssignmentTarget(node.parent)) { getNodeLinks(container).flags |= NodeCheckFlags.AsyncMethodWithSuperBinding; } else { getNodeLinks(container).flags |= NodeCheckFlags.AsyncMethodWithSuper; } } if (needToCaptureLexicalThis) { // call expressions are allowed only in constructors so they should always capture correct 'this' // super property access expressions can also appear in arrow functions - // in this case they should also use correct lexical this captureLexicalThis(node.parent, container); } if (container.parent.kind === SyntaxKind.ObjectLiteralExpression) { if (languageVersion < ScriptTarget.ES2015) { error(node, Diagnostics.super_is_only_allowed_in_members_of_object_literal_expressions_when_option_target_is_ES2015_or_higher); return errorType; } else { // for object literal assume that type of 'super' is 'any' return anyType; } } // at this point the only legal case for parent is ClassLikeDeclaration const classLikeDeclaration = container.parent; if (!getClassExtendsHeritageElement(classLikeDeclaration)) { error(node, Diagnostics.super_can_only_be_referenced_in_a_derived_class); return errorType; } const classType = getDeclaredTypeOfSymbol(getSymbolOfNode(classLikeDeclaration)); const baseClassType = classType && getBaseTypes(classType)[0]; if (!baseClassType) { return errorType; } if (container.kind === SyntaxKind.Constructor && isInConstructorArgumentInitializer(node, container)) { // issue custom error message for super property access in constructor arguments (to be aligned with old compiler) error(node, Diagnostics.super_cannot_be_referenced_in_constructor_arguments); return errorType; } return nodeCheckFlag === NodeCheckFlags.SuperStatic ? getBaseConstructorTypeOfClass(classType) : getTypeWithThisArgument(baseClassType, classType.thisType); function isLegalUsageOfSuperExpression(container: Node): boolean { if (!container) { return false; } if (isCallExpression) { // TS 1.0 SPEC (April 2014): 4.8.1 // Super calls are only permitted in constructors of derived classes return container.kind === SyntaxKind.Constructor; } else { // TS 1.0 SPEC (April 2014) // 'super' property access is allowed // - In a constructor, instance member function, instance member accessor, or instance member variable initializer where this references a derived class instance // - In a static member function or static member accessor // topmost container must be something that is directly nested in the class declaration\object literal expression if (isClassLike(container.parent) || container.parent.kind === SyntaxKind.ObjectLiteralExpression) { if (hasModifier(container, ModifierFlags.Static)) { return container.kind === SyntaxKind.MethodDeclaration || container.kind === SyntaxKind.MethodSignature || container.kind === SyntaxKind.GetAccessor || container.kind === SyntaxKind.SetAccessor; } else { return container.kind === SyntaxKind.MethodDeclaration || container.kind === SyntaxKind.MethodSignature || container.kind === SyntaxKind.GetAccessor || container.kind === SyntaxKind.SetAccessor || container.kind === SyntaxKind.PropertyDeclaration || container.kind === SyntaxKind.PropertySignature || container.kind === SyntaxKind.Constructor; } } } return false; } } function getContainingObjectLiteral(func: SignatureDeclaration): ObjectLiteralExpression | undefined { return (func.kind === SyntaxKind.MethodDeclaration || func.kind === SyntaxKind.GetAccessor || func.kind === SyntaxKind.SetAccessor) && func.parent.kind === SyntaxKind.ObjectLiteralExpression ? func.parent : func.kind === SyntaxKind.FunctionExpression && func.parent.kind === SyntaxKind.PropertyAssignment ? func.parent.parent : undefined; } function getThisTypeArgument(type: Type): Type | undefined { return getObjectFlags(type) & ObjectFlags.Reference && (type).target === globalThisType ? (type).typeArguments![0] : undefined; } function getThisTypeFromContextualType(type: Type): Type | undefined { return mapType(type, t => { return t.flags & TypeFlags.Intersection ? forEach((t).types, getThisTypeArgument) : getThisTypeArgument(t); }); } function getContextualThisParameterType(func: SignatureDeclaration): Type | undefined { if (func.kind === SyntaxKind.ArrowFunction) { return undefined; } if (isContextSensitiveFunctionOrObjectLiteralMethod(func)) { const contextualSignature = getContextualSignature(func); if (contextualSignature) { const thisParameter = contextualSignature.thisParameter; if (thisParameter) { return getTypeOfSymbol(thisParameter); } } } const inJs = isInJSFile(func); if (noImplicitThis || inJs) { const containingLiteral = getContainingObjectLiteral(func); if (containingLiteral) { // We have an object literal method. Check if the containing object literal has a contextual type // that includes a ThisType. If so, T is the contextual type for 'this'. We continue looking in // any directly enclosing object literals. const contextualType = getApparentTypeOfContextualType(containingLiteral); let literal = containingLiteral; let type = contextualType; while (type) { const thisType = getThisTypeFromContextualType(type); if (thisType) { return instantiateType(thisType, getContextualMapper(containingLiteral)); } if (literal.parent.kind !== SyntaxKind.PropertyAssignment) { break; } literal = literal.parent.parent; type = getApparentTypeOfContextualType(literal); } // There was no contextual ThisType for the containing object literal, so the contextual type // for 'this' is the non-null form of the contextual type for the containing object literal or // the type of the object literal itself. return contextualType ? getNonNullableType(contextualType) : checkExpressionCached(containingLiteral); } // In an assignment of the form 'obj.xxx = function(...)' or 'obj[xxx] = function(...)', the // contextual type for 'this' is 'obj'. const parent = func.parent; if (parent.kind === SyntaxKind.BinaryExpression && (parent).operatorToken.kind === SyntaxKind.EqualsToken) { const target = (parent).left; if (target.kind === SyntaxKind.PropertyAccessExpression || target.kind === SyntaxKind.ElementAccessExpression) { const { expression } = target as AccessExpression; // Don't contextually type `this` as `exports` in `exports.Point = function(x, y) { this.x = x; this.y = y; }` if (inJs && isIdentifier(expression)) { const sourceFile = getSourceFileOfNode(parent); if (sourceFile.commonJsModuleIndicator && getResolvedSymbol(expression) === sourceFile.symbol) { return undefined; } } return checkExpressionCached(expression); } } } return undefined; } // Return contextual type of parameter or undefined if no contextual type is available function getContextuallyTypedParameterType(parameter: ParameterDeclaration): Type | undefined { const func = parameter.parent; if (!isContextSensitiveFunctionOrObjectLiteralMethod(func)) { return undefined; } const iife = getImmediatelyInvokedFunctionExpression(func); if (iife && iife.arguments) { const args = getEffectiveCallArguments(iife); const indexOfParameter = func.parameters.indexOf(parameter); if (parameter.dotDotDotToken) { return getSpreadArgumentType(args, indexOfParameter, args.length, anyType, /*context*/ undefined); } const links = getNodeLinks(iife); const cached = links.resolvedSignature; links.resolvedSignature = anySignature; const type = indexOfParameter < args.length ? getWidenedLiteralType(checkExpression(args[indexOfParameter])) : parameter.initializer ? undefined : undefinedWideningType; links.resolvedSignature = cached; return type; } const contextualSignature = getContextualSignature(func); if (contextualSignature) { const index = func.parameters.indexOf(parameter) - (getThisParameter(func) ? 1 : 0); return parameter.dotDotDotToken && lastOrUndefined(func.parameters) === parameter ? getRestTypeAtPosition(contextualSignature, index) : tryGetTypeAtPosition(contextualSignature, index); } } function getContextualTypeForVariableLikeDeclaration(declaration: VariableLikeDeclaration): Type | undefined { const typeNode = getEffectiveTypeAnnotationNode(declaration); if (typeNode) { return getTypeFromTypeNode(typeNode); } switch (declaration.kind) { case SyntaxKind.Parameter: return getContextuallyTypedParameterType(declaration); case SyntaxKind.BindingElement: return getContextualTypeForBindingElement(declaration); // By default, do nothing and return undefined - only parameters and binding elements have context implied by a parent } } function getContextualTypeForBindingElement(declaration: BindingElement): Type | undefined { const parentDeclaration = declaration.parent.parent; const name = declaration.propertyName || declaration.name; const parentType = getContextualTypeForVariableLikeDeclaration(parentDeclaration); if (parentType && !isBindingPattern(name) && !isComputedNonLiteralName(name)) { const nameType = getLiteralTypeFromPropertyName(name); if (isTypeUsableAsPropertyName(nameType)) { const text = getPropertyNameFromType(nameType); return getTypeOfPropertyOfType(parentType, text); } } } // In a variable, parameter or property declaration with a type annotation, // the contextual type of an initializer expression is the type of the variable, parameter or property. // Otherwise, in a parameter declaration of a contextually typed function expression, // the contextual type of an initializer expression is the contextual type of the parameter. // Otherwise, in a variable or parameter declaration with a binding pattern name, // the contextual type of an initializer expression is the type implied by the binding pattern. // Otherwise, in a binding pattern inside a variable or parameter declaration, // the contextual type of an initializer expression is the type annotation of the containing declaration, if present. function getContextualTypeForInitializerExpression(node: Expression): Type | undefined { const declaration = node.parent; if (hasInitializer(declaration) && node === declaration.initializer) { const result = getContextualTypeForVariableLikeDeclaration(declaration); if (result) { return result; } if (isBindingPattern(declaration.name)) { // This is less a contextual type and more an implied shape - in some cases, this may be undesirable return getTypeFromBindingPattern(declaration.name, /*includePatternInType*/ true, /*reportErrors*/ false); } } return undefined; } function getContextualTypeForReturnExpression(node: Expression): Type | undefined { const func = getContainingFunction(node); if (func) { const functionFlags = getFunctionFlags(func); if (functionFlags & FunctionFlags.Generator) { // AsyncGenerator function or Generator function return undefined; } const contextualReturnType = getContextualReturnType(func); if (contextualReturnType) { if (functionFlags & FunctionFlags.Async) { // Async function const contextualAwaitedType = getAwaitedTypeOfPromise(contextualReturnType); return contextualAwaitedType && getUnionType([contextualAwaitedType, createPromiseLikeType(contextualAwaitedType)]); } return contextualReturnType; // Regular function } } return undefined; } function getContextualTypeForAwaitOperand(node: AwaitExpression): Type | undefined { const contextualType = getContextualType(node); if (contextualType) { const contextualAwaitedType = getAwaitedType(contextualType); return contextualAwaitedType && getUnionType([contextualAwaitedType, createPromiseLikeType(contextualAwaitedType)]); } return undefined; } function getContextualTypeForYieldOperand(node: YieldExpression): Type | undefined { const func = getContainingFunction(node); if (func) { const functionFlags = getFunctionFlags(func); const contextualReturnType = getContextualReturnType(func); if (contextualReturnType) { return node.asteriskToken ? contextualReturnType : getIteratedTypeOfGenerator(contextualReturnType, (functionFlags & FunctionFlags.Async) !== 0); } } return undefined; } function isInParameterInitializerBeforeContainingFunction(node: Node) { let inBindingInitializer = false; while (node.parent && !isFunctionLike(node.parent)) { if (isParameter(node.parent) && (inBindingInitializer || node.parent.initializer === node)) { return true; } if (isBindingElement(node.parent) && node.parent.initializer === node) { inBindingInitializer = true; } node = node.parent; } return false; } function getContextualReturnType(functionDecl: SignatureDeclaration): Type | undefined { // If the containing function has a return type annotation, is a constructor, or is a get accessor whose // corresponding set accessor has a type annotation, return statements in the function are contextually typed const returnType = getReturnTypeFromAnnotation(functionDecl); if (returnType) { return returnType; } // Otherwise, if the containing function is contextually typed by a function type with exactly one call signature // and that call signature is non-generic, return statements are contextually typed by the return type of the signature const signature = getContextualSignatureForFunctionLikeDeclaration(functionDecl); if (signature && !isResolvingReturnTypeOfSignature(signature)) { return getReturnTypeOfSignature(signature); } return undefined; } // In a typed function call, an argument or substitution expression is contextually typed by the type of the corresponding parameter. function getContextualTypeForArgument(callTarget: CallLikeExpression, arg: Expression): Type | undefined { const args = getEffectiveCallArguments(callTarget); const argIndex = args.indexOf(arg); // -1 for e.g. the expression of a CallExpression, or the tag of a TaggedTemplateExpression return argIndex === -1 ? undefined : getContextualTypeForArgumentAtIndex(callTarget, argIndex); } function getContextualTypeForArgumentAtIndex(callTarget: CallLikeExpression, argIndex: number): Type { // If we're already in the process of resolving the given signature, don't resolve again as // that could cause infinite recursion. Instead, return anySignature. const signature = getNodeLinks(callTarget).resolvedSignature === resolvingSignature ? resolvingSignature : getResolvedSignature(callTarget); if (isJsxOpeningLikeElement(callTarget) && argIndex === 0) { return getEffectiveFirstArgumentForJsxSignature(signature, callTarget); } return getTypeAtPosition(signature, argIndex); } function getContextualTypeForSubstitutionExpression(template: TemplateExpression, substitutionExpression: Expression) { if (template.parent.kind === SyntaxKind.TaggedTemplateExpression) { return getContextualTypeForArgument(template.parent, substitutionExpression); } return undefined; } function getContextualTypeForBinaryOperand(node: Expression): Type | undefined { const binaryExpression = node.parent; const { left, operatorToken, right } = binaryExpression; switch (operatorToken.kind) { case SyntaxKind.EqualsToken: if (node !== right) { return undefined; } const contextSensitive = getIsContextSensitiveAssignmentOrContextType(binaryExpression); if (!contextSensitive) { return undefined; } return contextSensitive === true ? getTypeOfExpression(left) : contextSensitive; case SyntaxKind.BarBarToken: // When an || expression has a contextual type, the operands are contextually typed by that type. When an || // expression has no contextual type, the right operand is contextually typed by the type of the left operand, // except for the special case of Javascript declarations of the form `namespace.prop = namespace.prop || {}` const type = getContextualType(binaryExpression); return !type && node === right && !isDefaultedExpandoInitializer(binaryExpression) ? getTypeOfExpression(left) : type; case SyntaxKind.AmpersandAmpersandToken: case SyntaxKind.CommaToken: return node === right ? getContextualType(binaryExpression) : undefined; default: return undefined; } } // In an assignment expression, the right operand is contextually typed by the type of the left operand. // Don't do this for assignment declarations unless there is a type tag on the assignment, to avoid circularity from checking the right operand. function getIsContextSensitiveAssignmentOrContextType(binaryExpression: BinaryExpression): boolean | Type { const kind = getAssignmentDeclarationKind(binaryExpression); switch (kind) { case AssignmentDeclarationKind.None: return true; case AssignmentDeclarationKind.Property: case AssignmentDeclarationKind.ExportsProperty: case AssignmentDeclarationKind.Prototype: case AssignmentDeclarationKind.PrototypeProperty: // If `binaryExpression.left` was assigned a symbol, then this is a new declaration; otherwise it is an assignment to an existing declaration. // See `bindStaticPropertyAssignment` in `binder.ts`. if (!binaryExpression.left.symbol) { return true; } else { const decl = binaryExpression.left.symbol.valueDeclaration; if (!decl) { return false; } const lhs = binaryExpression.left as PropertyAccessExpression; const overallAnnotation = getEffectiveTypeAnnotationNode(decl); if (overallAnnotation) { return getTypeFromTypeNode(overallAnnotation); } else if (isIdentifier(lhs.expression)) { const id = lhs.expression; const parentSymbol = resolveName(id, id.escapedText, SymbolFlags.Value, undefined, id.escapedText, /*isUse*/ true); if (parentSymbol) { const annotated = getEffectiveTypeAnnotationNode(parentSymbol.valueDeclaration); if (annotated) { const type = getTypeOfPropertyOfContextualType(getTypeFromTypeNode(annotated), lhs.name.escapedText); return type || false; } return false; } } return !isInJSFile(decl); } case AssignmentDeclarationKind.ModuleExports: case AssignmentDeclarationKind.ThisProperty: if (!binaryExpression.symbol) return true; if (binaryExpression.symbol.valueDeclaration) { const annotated = getEffectiveTypeAnnotationNode(binaryExpression.symbol.valueDeclaration); if (annotated) { const type = getTypeFromTypeNode(annotated); if (type) { return type; } } } if (kind === AssignmentDeclarationKind.ModuleExports) return false; const thisAccess = binaryExpression.left as PropertyAccessExpression; if (!isObjectLiteralMethod(getThisContainer(thisAccess.expression, /*includeArrowFunctions*/ false))) { return false; } const thisType = checkThisExpression(thisAccess.expression); return thisType && getTypeOfPropertyOfContextualType(thisType, thisAccess.name.escapedText) || false; case AssignmentDeclarationKind.ObjectDefinePropertyValue: case AssignmentDeclarationKind.ObjectDefinePropertyExports: case AssignmentDeclarationKind.ObjectDefinePrototypeProperty: return Debug.fail("Does not apply"); default: return Debug.assertNever(kind); } } function getTypeOfPropertyOfContextualType(type: Type, name: __String) { return mapType(type, t => { if (t.flags & TypeFlags.StructuredType) { const prop = getPropertyOfType(t, name); if (prop) { return getTypeOfSymbol(prop); } if (isTupleType(t)) { const restType = getRestTypeOfTupleType(t); if (restType && isNumericLiteralName(name) && +name >= 0) { return restType; } } return isNumericLiteralName(name) && getIndexTypeOfContextualType(t, IndexKind.Number) || getIndexTypeOfContextualType(t, IndexKind.String); } return undefined; }, /*noReductions*/ true); } function getIndexTypeOfContextualType(type: Type, kind: IndexKind) { return mapType(type, t => getIndexTypeOfStructuredType(t, kind), /*noReductions*/ true); } // In an object literal contextually typed by a type T, the contextual type of a property assignment is the type of // the matching property in T, if one exists. Otherwise, it is the type of the numeric index signature in T, if one // exists. Otherwise, it is the type of the string index signature in T, if one exists. function getContextualTypeForObjectLiteralMethod(node: MethodDeclaration): Type | undefined { Debug.assert(isObjectLiteralMethod(node)); if (node.flags & NodeFlags.InWithStatement) { // We cannot answer semantic questions within a with block, do not proceed any further return undefined; } return getContextualTypeForObjectLiteralElement(node); } function getContextualTypeForObjectLiteralElement(element: ObjectLiteralElementLike) { const objectLiteral = element.parent; const type = getApparentTypeOfContextualType(objectLiteral); if (type) { if (!hasNonBindableDynamicName(element)) { // For a (non-symbol) computed property, there is no reason to look up the name // in the type. It will just be "__computed", which does not appear in any // SymbolTable. const symbolName = getSymbolOfNode(element).escapedName; const propertyType = getTypeOfPropertyOfContextualType(type, symbolName); if (propertyType) { return propertyType; } } return isNumericName(element.name!) && getIndexTypeOfContextualType(type, IndexKind.Number) || getIndexTypeOfContextualType(type, IndexKind.String); } return undefined; } // In an array literal contextually typed by a type T, the contextual type of an element expression at index N is // the type of the property with the numeric name N in T, if one exists. Otherwise, if T has a numeric index signature, // it is the type of the numeric index signature in T. Otherwise, in ES6 and higher, the contextual type is the iterated // type of T. function getContextualTypeForElementExpression(arrayContextualType: Type | undefined, index: number): Type | undefined { return arrayContextualType && ( getTypeOfPropertyOfContextualType(arrayContextualType, "" + index as __String) || getIteratedTypeOrElementType(arrayContextualType, /*errorNode*/ undefined, /*allowStringInput*/ false, /*allowAsyncIterables*/ false, /*checkAssignability*/ false)); } // In a contextually typed conditional expression, the true/false expressions are contextually typed by the same type. function getContextualTypeForConditionalOperand(node: Expression): Type | undefined { const conditional = node.parent; return node === conditional.whenTrue || node === conditional.whenFalse ? getContextualType(conditional) : undefined; } function getContextualTypeForChildJsxExpression(node: JsxElement, child: JsxChild) { const attributesType = getApparentTypeOfContextualType(node.openingElement.tagName); // JSX expression is in children of JSX Element, we will look for an "children" atttribute (we get the name from JSX.ElementAttributesProperty) const jsxChildrenPropertyName = getJsxElementChildrenPropertyName(getJsxNamespaceAt(node)); if (!(attributesType && !isTypeAny(attributesType) && jsxChildrenPropertyName && jsxChildrenPropertyName !== "")) { return undefined; } const childIndex = node.children.indexOf(child); const childFieldType = getTypeOfPropertyOfContextualType(attributesType, jsxChildrenPropertyName); return childFieldType && mapType(childFieldType, t => { if (isArrayLikeType(t)) { return getIndexedAccessType(t, getLiteralType(childIndex)); } else { return t; } }, /*noReductions*/ true); } function getContextualTypeForJsxExpression(node: JsxExpression): Type | undefined { const exprParent = node.parent; return isJsxAttributeLike(exprParent) ? getContextualType(node) : isJsxElement(exprParent) ? getContextualTypeForChildJsxExpression(exprParent, node) : undefined; } function getContextualTypeForJsxAttribute(attribute: JsxAttribute | JsxSpreadAttribute): Type | undefined { // When we trying to resolve JsxOpeningLikeElement as a stateless function element, we will already give its attributes a contextual type // which is a type of the parameter of the signature we are trying out. // If there is no contextual type (e.g. we are trying to resolve stateful component), get attributes type from resolving element's tagName if (isJsxAttribute(attribute)) { const attributesType = getApparentTypeOfContextualType(attribute.parent); if (!attributesType || isTypeAny(attributesType)) { return undefined; } return getTypeOfPropertyOfContextualType(attributesType, attribute.name.escapedText); } else { return getContextualType(attribute.parent); } } // Return true if the given expression is possibly a discriminant value. We limit the kinds of // expressions we check to those that don't depend on their contextual type in order not to cause // recursive (and possibly infinite) invocations of getContextualType. function isPossiblyDiscriminantValue(node: Expression): boolean { switch (node.kind) { case SyntaxKind.StringLiteral: case SyntaxKind.NumericLiteral: case SyntaxKind.BigIntLiteral: case SyntaxKind.NoSubstitutionTemplateLiteral: case SyntaxKind.TrueKeyword: case SyntaxKind.FalseKeyword: case SyntaxKind.NullKeyword: case SyntaxKind.Identifier: case SyntaxKind.UndefinedKeyword: return true; case SyntaxKind.PropertyAccessExpression: case SyntaxKind.ParenthesizedExpression: return isPossiblyDiscriminantValue((node).expression); case SyntaxKind.JsxExpression: return !(node as JsxExpression).expression || isPossiblyDiscriminantValue((node as JsxExpression).expression!); } return false; } function discriminateContextualTypeByObjectMembers(node: ObjectLiteralExpression, contextualType: UnionType) { return discriminateTypeByDiscriminableItems(contextualType, map( filter(node.properties, p => !!p.symbol && p.kind === SyntaxKind.PropertyAssignment && isPossiblyDiscriminantValue(p.initializer) && isDiscriminantProperty(contextualType, p.symbol.escapedName)), prop => ([() => checkExpression((prop as PropertyAssignment).initializer), prop.symbol.escapedName] as [() => Type, __String]) ), isTypeAssignableTo, contextualType ); } function discriminateContextualTypeByJSXAttributes(node: JsxAttributes, contextualType: UnionType) { return discriminateTypeByDiscriminableItems(contextualType, map( filter(node.properties, p => !!p.symbol && p.kind === SyntaxKind.JsxAttribute && isDiscriminantProperty(contextualType, p.symbol.escapedName) && (!p.initializer || isPossiblyDiscriminantValue(p.initializer))), prop => ([!(prop as JsxAttribute).initializer ? (() => trueType) : (() => checkExpression((prop as JsxAttribute).initializer!)), prop.symbol.escapedName] as [() => Type, __String]) ), isTypeAssignableTo, contextualType ); } // Return the contextual type for a given expression node. During overload resolution, a contextual type may temporarily // be "pushed" onto a node using the contextualType property. function getApparentTypeOfContextualType(node: Expression): Type | undefined { const contextualType = instantiateContextualType(getContextualType(node), node); if (contextualType) { const apparentType = mapType(contextualType, getApparentType, /*noReductions*/ true); if (apparentType.flags & TypeFlags.Union) { if (isObjectLiteralExpression(node)) { return discriminateContextualTypeByObjectMembers(node, apparentType as UnionType); } else if (isJsxAttributes(node)) { return discriminateContextualTypeByJSXAttributes(node, apparentType as UnionType); } } return apparentType; } } // If the given contextual type contains instantiable types and if a mapper representing // return type inferences is available, instantiate those types using that mapper. function instantiateContextualType(contextualType: Type | undefined, node: Expression): Type | undefined { if (contextualType && maybeTypeOfKind(contextualType, TypeFlags.Instantiable)) { const returnMapper = (getContextualMapper(node)).returnMapper; if (returnMapper) { return instantiateInstantiableTypes(contextualType, returnMapper); } } return contextualType; } // This function is similar to instantiateType, except that (a) it only instantiates types that // are classified as instantiable (i.e. it doesn't instantiate object types), and (b) it performs // no reductions on instantiated union types. function instantiateInstantiableTypes(type: Type, mapper: TypeMapper): Type { if (type.flags & TypeFlags.Instantiable) { return instantiateType(type, mapper); } if (type.flags & TypeFlags.Union) { return getUnionType(map((type).types, t => instantiateInstantiableTypes(t, mapper)), UnionReduction.None); } if (type.flags & TypeFlags.Intersection) { return getIntersectionType(map((type).types, t => instantiateInstantiableTypes(t, mapper))); } return type; } /** * Woah! Do you really want to use this function? * * Unless you're trying to get the *non-apparent* type for a * value-literal type or you're authoring relevant portions of this algorithm, * you probably meant to use 'getApparentTypeOfContextualType'. * Otherwise this may not be very useful. * * In cases where you *are* working on this function, you should understand * when it is appropriate to use 'getContextualType' and 'getApparentTypeOfContextualType'. * * - Use 'getContextualType' when you are simply going to propagate the result to the expression. * - Use 'getApparentTypeOfContextualType' when you're going to need the members of the type. * * @param node the expression whose contextual type will be returned. * @returns the contextual type of an expression. */ function getContextualType(node: Expression): Type | undefined { if (node.flags & NodeFlags.InWithStatement) { // We cannot answer semantic questions within a with block, do not proceed any further return undefined; } if (node.contextualType) { return node.contextualType; } const { parent } = node; switch (parent.kind) { case SyntaxKind.VariableDeclaration: case SyntaxKind.Parameter: case SyntaxKind.PropertyDeclaration: case SyntaxKind.PropertySignature: case SyntaxKind.BindingElement: return getContextualTypeForInitializerExpression(node); case SyntaxKind.ArrowFunction: case SyntaxKind.ReturnStatement: return getContextualTypeForReturnExpression(node); case SyntaxKind.YieldExpression: return getContextualTypeForYieldOperand(parent); case SyntaxKind.AwaitExpression: return getContextualTypeForAwaitOperand(parent); case SyntaxKind.CallExpression: case SyntaxKind.NewExpression: return getContextualTypeForArgument(parent, node); case SyntaxKind.TypeAssertionExpression: case SyntaxKind.AsExpression: return isConstTypeReference((parent).type) ? undefined : getTypeFromTypeNode((parent).type); case SyntaxKind.BinaryExpression: return getContextualTypeForBinaryOperand(node); case SyntaxKind.PropertyAssignment: case SyntaxKind.ShorthandPropertyAssignment: return getContextualTypeForObjectLiteralElement(parent); case SyntaxKind.SpreadAssignment: return getApparentTypeOfContextualType(parent.parent as ObjectLiteralExpression); case SyntaxKind.ArrayLiteralExpression: { const arrayLiteral = parent; const type = getApparentTypeOfContextualType(arrayLiteral); return getContextualTypeForElementExpression(type, indexOfNode(arrayLiteral.elements, node)); } case SyntaxKind.ConditionalExpression: return getContextualTypeForConditionalOperand(node); case SyntaxKind.TemplateSpan: Debug.assert(parent.parent.kind === SyntaxKind.TemplateExpression); return getContextualTypeForSubstitutionExpression(parent.parent, node); case SyntaxKind.ParenthesizedExpression: { // Like in `checkParenthesizedExpression`, an `/** @type {xyz} */` comment before a parenthesized expression acts as a type cast. const tag = isInJSFile(parent) ? getJSDocTypeTag(parent) : undefined; return tag ? getTypeFromTypeNode(tag.typeExpression!.type) : getContextualType(parent); } case SyntaxKind.JsxExpression: return getContextualTypeForJsxExpression(parent); case SyntaxKind.JsxAttribute: case SyntaxKind.JsxSpreadAttribute: return getContextualTypeForJsxAttribute(parent); case SyntaxKind.JsxOpeningElement: case SyntaxKind.JsxSelfClosingElement: return getContextualJsxElementAttributesType(parent); } return undefined; } function getContextualMapper(node: Node) { const ancestor = findAncestor(node, n => !!n.contextualMapper); return ancestor ? ancestor.contextualMapper! : identityMapper; } function getContextualJsxElementAttributesType(node: JsxOpeningLikeElement) { if (isJsxOpeningElement(node) && node.parent.contextualType) { // Contextually applied type is moved from attributes up to the outer jsx attributes so when walking up from the children they get hit // _However_ to hit them from the _attributes_ we must look for them here; otherwise we'll used the declared type // (as below) instead! return node.parent.contextualType; } return getContextualTypeForArgumentAtIndex(node, 0); } function getEffectiveFirstArgumentForJsxSignature(signature: Signature, node: JsxOpeningLikeElement) { return getJsxReferenceKind(node) !== JsxReferenceKind.Component ? getJsxPropsTypeFromCallSignature(signature, node) : getJsxPropsTypeFromClassType(signature, node); } function getJsxPropsTypeFromCallSignature(sig: Signature, context: JsxOpeningLikeElement) { let propsType = getTypeOfFirstParameterOfSignatureWithFallback(sig, emptyObjectType); propsType = getJsxManagedAttributesFromLocatedAttributes(context, getJsxNamespaceAt(context), propsType); const intrinsicAttribs = getJsxType(JsxNames.IntrinsicAttributes, context); if (intrinsicAttribs !== errorType) { propsType = intersectTypes(intrinsicAttribs, propsType); } return propsType; } function getJsxPropsTypeForSignatureFromMember(sig: Signature, forcedLookupLocation: __String) { if (sig.unionSignatures) { // JSX Elements using the legacy `props`-field based lookup (eg, react class components) need to treat the `props` member as an input // instead of an output position when resolving the signature. We need to go back to the input signatures of the composite signature, // get the type of `props` on each return type individually, and then _intersect them_, rather than union them (as would normally occur // for a union signature). It's an unfortunate quirk of looking in the output of the signature for the type we want to use for the input. // The default behavior of `getTypeOfFirstParameterOfSignatureWithFallback` when no `props` member name is defined is much more sane. const results: Type[] = []; for (const signature of sig.unionSignatures) { const instance = getReturnTypeOfSignature(signature); if (isTypeAny(instance)) { return instance; } const propType = getTypeOfPropertyOfType(instance, forcedLookupLocation); if (!propType) { return; } results.push(propType); } return getIntersectionType(results); } const instanceType = getReturnTypeOfSignature(sig); return isTypeAny(instanceType) ? instanceType : getTypeOfPropertyOfType(instanceType, forcedLookupLocation); } function getStaticTypeOfReferencedJsxConstructor(context: JsxOpeningLikeElement) { if (isJsxIntrinsicIdentifier(context.tagName)) { const result = getIntrinsicAttributesTypeFromJsxOpeningLikeElement(context); const fakeSignature = createSignatureForJSXIntrinsic(context, result); return getOrCreateTypeFromSignature(fakeSignature); } const tagType = checkExpressionCached(context.tagName); if (tagType.flags & TypeFlags.StringLiteral) { const result = getIntrinsicAttributesTypeFromStringLiteralType(tagType as StringLiteralType, context); if (!result) { return errorType; } const fakeSignature = createSignatureForJSXIntrinsic(context, result); return getOrCreateTypeFromSignature(fakeSignature); } return tagType; } function getJsxManagedAttributesFromLocatedAttributes(context: JsxOpeningLikeElement, ns: Symbol, attributesType: Type) { const managedSym = getJsxLibraryManagedAttributes(ns); if (managedSym) { const declaredManagedType = getDeclaredTypeOfSymbol(managedSym); const ctorType = getStaticTypeOfReferencedJsxConstructor(context); if (length((declaredManagedType as GenericType).typeParameters) >= 2) { const args = fillMissingTypeArguments([ctorType, attributesType], (declaredManagedType as GenericType).typeParameters, 2, isInJSFile(context)); return createTypeReference((declaredManagedType as GenericType), args); } else if (length(declaredManagedType.aliasTypeArguments) >= 2) { const args = fillMissingTypeArguments([ctorType, attributesType], declaredManagedType.aliasTypeArguments!, 2, isInJSFile(context)); return getTypeAliasInstantiation(declaredManagedType.aliasSymbol!, args); } } return attributesType; } function getJsxPropsTypeFromClassType(sig: Signature, context: JsxOpeningLikeElement) { const ns = getJsxNamespaceAt(context); const forcedLookupLocation = getJsxElementPropertiesName(ns); let attributesType = forcedLookupLocation === undefined // If there is no type ElementAttributesProperty, return the type of the first parameter of the signature, which should be the props type ? getTypeOfFirstParameterOfSignatureWithFallback(sig, emptyObjectType) : forcedLookupLocation === "" // If there is no e.g. 'props' member in ElementAttributesProperty, use the element class type instead ? getReturnTypeOfSignature(sig) // Otherwise get the type of the property on the signature return type : getJsxPropsTypeForSignatureFromMember(sig, forcedLookupLocation); if (!attributesType) { // There is no property named 'props' on this instance type if (!!forcedLookupLocation && !!length(context.attributes.properties)) { error(context, Diagnostics.JSX_element_class_does_not_support_attributes_because_it_does_not_have_a_0_property, unescapeLeadingUnderscores(forcedLookupLocation)); } return emptyObjectType; } attributesType = getJsxManagedAttributesFromLocatedAttributes(context, ns, attributesType); if (isTypeAny(attributesType)) { // Props is of type 'any' or unknown return attributesType; } else { // Normal case -- add in IntrinsicClassElements and IntrinsicElements let apparentAttributesType = attributesType; const intrinsicClassAttribs = getJsxType(JsxNames.IntrinsicClassAttributes, context); if (intrinsicClassAttribs !== errorType) { const typeParams = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(intrinsicClassAttribs.symbol); const hostClassType = getReturnTypeOfSignature(sig); apparentAttributesType = intersectTypes( typeParams ? createTypeReference(intrinsicClassAttribs, fillMissingTypeArguments([hostClassType], typeParams, getMinTypeArgumentCount(typeParams), isInJSFile(context))) : intrinsicClassAttribs, apparentAttributesType ); } const intrinsicAttribs = getJsxType(JsxNames.IntrinsicAttributes, context); if (intrinsicAttribs !== errorType) { apparentAttributesType = intersectTypes(intrinsicAttribs, apparentAttributesType); } return apparentAttributesType; } } // If the given type is an object or union type with a single signature, and if that signature has at // least as many parameters as the given function, return the signature. Otherwise return undefined. function getContextualCallSignature(type: Type, node: SignatureDeclaration): Signature | undefined { const signatures = getSignaturesOfType(type, SignatureKind.Call); if (signatures.length === 1) { const signature = signatures[0]; if (!isAritySmaller(signature, node)) { return signature; } } } /** If the contextual signature has fewer parameters than the function expression, do not use it */ function isAritySmaller(signature: Signature, target: SignatureDeclaration) { let targetParameterCount = 0; for (; targetParameterCount < target.parameters.length; targetParameterCount++) { const param = target.parameters[targetParameterCount]; if (param.initializer || param.questionToken || param.dotDotDotToken || isJSDocOptionalParameter(param)) { break; } } if (target.parameters.length && parameterIsThisKeyword(target.parameters[0])) { targetParameterCount--; } return !hasEffectiveRestParameter(signature) && getParameterCount(signature) < targetParameterCount; } function isFunctionExpressionOrArrowFunction(node: Node): node is FunctionExpression | ArrowFunction { return node.kind === SyntaxKind.FunctionExpression || node.kind === SyntaxKind.ArrowFunction; } function getContextualSignatureForFunctionLikeDeclaration(node: FunctionLikeDeclaration): Signature | undefined { // Only function expressions, arrow functions, and object literal methods are contextually typed. return isFunctionExpressionOrArrowFunction(node) || isObjectLiteralMethod(node) ? getContextualSignature(node) : undefined; } function getContextualTypeForFunctionLikeDeclaration(node: FunctionExpression | ArrowFunction | MethodDeclaration) { return isObjectLiteralMethod(node) ? getContextualTypeForObjectLiteralMethod(node) : getApparentTypeOfContextualType(node); } // Return the contextual signature for a given expression node. A contextual type provides a // contextual signature if it has a single call signature and if that call signature is non-generic. // If the contextual type is a union type, get the signature from each type possible and if they are // all identical ignoring their return type, the result is same signature but with return type as // union type of return types from these signatures function getContextualSignature(node: FunctionExpression | ArrowFunction | MethodDeclaration): Signature | undefined { Debug.assert(node.kind !== SyntaxKind.MethodDeclaration || isObjectLiteralMethod(node)); const typeTagSignature = getSignatureOfTypeTag(node); if (typeTagSignature) { return typeTagSignature; } const type = getContextualTypeForFunctionLikeDeclaration(node); if (!type) { return undefined; } if (!(type.flags & TypeFlags.Union)) { return getContextualCallSignature(type, node); } let signatureList: Signature[] | undefined; const types = (type).types; for (const current of types) { const signature = getContextualCallSignature(current, node); if (signature) { if (!signatureList) { // This signature will contribute to contextual union signature signatureList = [signature]; } else if (!compareSignaturesIdentical(signatureList[0], signature, /*partialMatch*/ false, /*ignoreThisTypes*/ true, /*ignoreReturnTypes*/ true, compareTypesIdentical)) { // Signatures aren't identical, do not use return undefined; } else { // Use this signature for contextual union signature signatureList.push(signature); } } } // Result is union of signatures collected (return type is union of return types of this signature set) let result: Signature | undefined; if (signatureList) { result = cloneSignature(signatureList[0]); result.unionSignatures = signatureList; } return result; } function checkSpreadExpression(node: SpreadElement, checkMode?: CheckMode): Type { if (languageVersion < ScriptTarget.ES2015 && compilerOptions.downlevelIteration) { checkExternalEmitHelpers(node, ExternalEmitHelpers.SpreadIncludes); } const arrayOrIterableType = checkExpression(node.expression, checkMode); return checkIteratedTypeOrElementType(arrayOrIterableType, node.expression, /*allowStringInput*/ false, /*allowAsyncIterables*/ false); } function hasDefaultValue(node: BindingElement | Expression): boolean { return (node.kind === SyntaxKind.BindingElement && !!(node).initializer) || (node.kind === SyntaxKind.BinaryExpression && (node).operatorToken.kind === SyntaxKind.EqualsToken); } function checkArrayLiteral(node: ArrayLiteralExpression, checkMode: CheckMode | undefined, forceTuple: boolean | undefined): Type { const elements = node.elements; const elementCount = elements.length; let hasNonEndingSpreadElement = false; const elementTypes: Type[] = []; const inDestructuringPattern = isAssignmentTarget(node); const contextualType = getApparentTypeOfContextualType(node); const inConstContext = isConstContext(node); for (let index = 0; index < elementCount; index++) { const e = elements[index]; if (inDestructuringPattern && e.kind === SyntaxKind.SpreadElement) { // Given the following situation: // var c: {}; // [...c] = ["", 0]; // // c is represented in the tree as a spread element in an array literal. // But c really functions as a rest element, and its purpose is to provide // a contextual type for the right hand side of the assignment. Therefore, // instead of calling checkExpression on "...c", which will give an error // if c is not iterable/array-like, we need to act as if we are trying to // get the contextual element type from it. So we do something similar to // getContextualTypeForElementExpression, which will crucially not error // if there is no index type / iterated type. const restArrayType = checkExpression((e).expression, checkMode, forceTuple); const restElementType = getIndexTypeOfType(restArrayType, IndexKind.Number) || getIteratedTypeOrElementType(restArrayType, /*errorNode*/ undefined, /*allowStringInput*/ false, /*allowAsyncIterables*/ false, /*checkAssignability*/ false); if (restElementType) { elementTypes.push(restElementType); } } else { const elementContextualType = getContextualTypeForElementExpression(contextualType, index); const type = checkExpressionForMutableLocation(e, checkMode, elementContextualType, forceTuple); elementTypes.push(type); } if (index < elementCount - 1 && e.kind === SyntaxKind.SpreadElement) { hasNonEndingSpreadElement = true; } } if (!hasNonEndingSpreadElement) { const hasRestElement = elementCount > 0 && elements[elementCount - 1].kind === SyntaxKind.SpreadElement; const minLength = elementCount - (hasRestElement ? 1 : 0); // If array literal is actually a destructuring pattern, mark it as an implied type. We do this such // that we get the same behavior for "var [x, y] = []" and "[x, y] = []". let tupleResult: Type | undefined; if (inDestructuringPattern && minLength > 0) { const type = cloneTypeReference(createTupleType(elementTypes, minLength, hasRestElement)); type.pattern = node; return type; } else if (tupleResult = getArrayLiteralTupleTypeIfApplicable(elementTypes, contextualType, hasRestElement, elementCount, inConstContext)) { return tupleResult; } else if (forceTuple) { return createTupleType(elementTypes, minLength, hasRestElement); } } return createArrayType(elementTypes.length ? getUnionType(elementTypes, UnionReduction.Subtype) : strictNullChecks ? implicitNeverType : undefinedWideningType, inConstContext); } function getArrayLiteralTupleTypeIfApplicable(elementTypes: Type[], contextualType: Type | undefined, hasRestElement: boolean, elementCount = elementTypes.length, readonly = false) { // Infer a tuple type when the contextual type is or contains a tuple-like type if (readonly || (contextualType && forEachType(contextualType, isTupleLikeType))) { const minLength = elementCount - (hasRestElement ? 1 : 0); const pattern = contextualType && contextualType.pattern; // If array literal is contextually typed by a binding pattern or an assignment pattern, pad the resulting // tuple type with the corresponding binding or assignment element types to make the lengths equal. if (!hasRestElement && pattern && (pattern.kind === SyntaxKind.ArrayBindingPattern || pattern.kind === SyntaxKind.ArrayLiteralExpression)) { const patternElements = (pattern).elements; for (let i = elementCount; i < patternElements.length; i++) { const e = patternElements[i]; if (hasDefaultValue(e)) { elementTypes.push((contextualType).typeArguments![i]); } else if (i < patternElements.length - 1 || !(e.kind === SyntaxKind.BindingElement && (e).dotDotDotToken || e.kind === SyntaxKind.SpreadElement)) { if (e.kind !== SyntaxKind.OmittedExpression) { error(e, Diagnostics.Initializer_provides_no_value_for_this_binding_element_and_the_binding_element_has_no_default_value); } elementTypes.push(strictNullChecks ? implicitNeverType : undefinedWideningType); } } } return createTupleType(elementTypes, minLength, hasRestElement, readonly); } } function isNumericName(name: DeclarationName): boolean { switch (name.kind) { case SyntaxKind.ComputedPropertyName: return isNumericComputedName(name); case SyntaxKind.Identifier: return isNumericLiteralName(name.escapedText); case SyntaxKind.NumericLiteral: case SyntaxKind.StringLiteral: return isNumericLiteralName(name.text); default: return false; } } function isNumericComputedName(name: ComputedPropertyName): boolean { // It seems odd to consider an expression of type Any to result in a numeric name, // but this behavior is consistent with checkIndexedAccess return isTypeAssignableToKind(checkComputedPropertyName(name), TypeFlags.NumberLike); } function isInfinityOrNaNString(name: string | __String): boolean { return name === "Infinity" || name === "-Infinity" || name === "NaN"; } function isNumericLiteralName(name: string | __String) { // The intent of numeric names is that // - they are names with text in a numeric form, and that // - setting properties/indexing with them is always equivalent to doing so with the numeric literal 'numLit', // acquired by applying the abstract 'ToNumber' operation on the name's text. // // The subtlety is in the latter portion, as we cannot reliably say that anything that looks like a numeric literal is a numeric name. // In fact, it is the case that the text of the name must be equal to 'ToString(numLit)' for this to hold. // // Consider the property name '"0xF00D"'. When one indexes with '0xF00D', they are actually indexing with the value of 'ToString(0xF00D)' // according to the ECMAScript specification, so it is actually as if the user indexed with the string '"61453"'. // Thus, the text of all numeric literals equivalent to '61543' such as '0xF00D', '0xf00D', '0170015', etc. are not valid numeric names // because their 'ToString' representation is not equal to their original text. // This is motivated by ECMA-262 sections 9.3.1, 9.8.1, 11.1.5, and 11.2.1. // // Here, we test whether 'ToString(ToNumber(name))' is exactly equal to 'name'. // The '+' prefix operator is equivalent here to applying the abstract ToNumber operation. // Applying the 'toString()' method on a number gives us the abstract ToString operation on a number. // // Note that this accepts the values 'Infinity', '-Infinity', and 'NaN', and that this is intentional. // This is desired behavior, because when indexing with them as numeric entities, you are indexing // with the strings '"Infinity"', '"-Infinity"', and '"NaN"' respectively. return (+name).toString() === name; } function checkComputedPropertyName(node: ComputedPropertyName): Type { const links = getNodeLinks(node.expression); if (!links.resolvedType) { links.resolvedType = checkExpression(node.expression); // This will allow types number, string, symbol or any. It will also allow enums, the unknown // type, and any union of these types (like string | number). if (links.resolvedType.flags & TypeFlags.Nullable || !isTypeAssignableToKind(links.resolvedType, TypeFlags.StringLike | TypeFlags.NumberLike | TypeFlags.ESSymbolLike) && !isTypeAssignableTo(links.resolvedType, stringNumberSymbolType)) { error(node, Diagnostics.A_computed_property_name_must_be_of_type_string_number_symbol_or_any); } else { checkThatExpressionIsProperSymbolReference(node.expression, links.resolvedType, /*reportError*/ true); } } return links.resolvedType; } function getObjectLiteralIndexInfo(node: ObjectLiteralExpression, offset: number, properties: Symbol[], kind: IndexKind): IndexInfo { const propTypes: Type[] = []; for (let i = 0; i < properties.length; i++) { if (kind === IndexKind.String || isNumericName(node.properties[i + offset].name!)) { propTypes.push(getTypeOfSymbol(properties[i])); } } const unionType = propTypes.length ? getUnionType(propTypes, UnionReduction.Subtype) : undefinedType; return createIndexInfo(unionType, isConstContext(node)); } function getImmediateAliasedSymbol(symbol: Symbol): Symbol | undefined { Debug.assert((symbol.flags & SymbolFlags.Alias) !== 0, "Should only get Alias here."); const links = getSymbolLinks(symbol); if (!links.immediateTarget) { const node = getDeclarationOfAliasSymbol(symbol); if (!node) return Debug.fail(); links.immediateTarget = getTargetOfAliasDeclaration(node, /*dontRecursivelyResolve*/ true); } return links.immediateTarget; } function checkObjectLiteral(node: ObjectLiteralExpression, checkMode?: CheckMode): Type { const inDestructuringPattern = isAssignmentTarget(node); // Grammar checking checkGrammarObjectLiteralExpression(node, inDestructuringPattern); let propertiesTable: SymbolTable; let propertiesArray: Symbol[] = []; let spread: Type = emptyObjectType; let propagatedFlags: TypeFlags = 0; const contextualType = getApparentTypeOfContextualType(node); const contextualTypeHasPattern = contextualType && contextualType.pattern && (contextualType.pattern.kind === SyntaxKind.ObjectBindingPattern || contextualType.pattern.kind === SyntaxKind.ObjectLiteralExpression); const inConstContext = isConstContext(node); const checkFlags = inConstContext ? CheckFlags.Readonly : 0; const isInJavascript = isInJSFile(node) && !isInJsonFile(node); const enumTag = getJSDocEnumTag(node); const isJSObjectLiteral = !contextualType && isInJavascript && !enumTag; let typeFlags: TypeFlags = 0; let patternWithComputedProperties = false; let hasComputedStringProperty = false; let hasComputedNumberProperty = false; propertiesTable = createSymbolTable(); let offset = 0; for (let i = 0; i < node.properties.length; i++) { const memberDecl = node.properties[i]; let member = getSymbolOfNode(memberDecl); const computedNameType = memberDecl.name && memberDecl.name.kind === SyntaxKind.ComputedPropertyName && !isWellKnownSymbolSyntactically(memberDecl.name.expression) ? checkComputedPropertyName(memberDecl.name) : undefined; if (memberDecl.kind === SyntaxKind.PropertyAssignment || memberDecl.kind === SyntaxKind.ShorthandPropertyAssignment || isObjectLiteralMethod(memberDecl)) { let type = memberDecl.kind === SyntaxKind.PropertyAssignment ? checkPropertyAssignment(memberDecl, checkMode) : memberDecl.kind === SyntaxKind.ShorthandPropertyAssignment ? checkExpressionForMutableLocation(memberDecl.name, checkMode) : checkObjectLiteralMethod(memberDecl, checkMode); if (isInJavascript) { const jsDocType = getTypeForDeclarationFromJSDocComment(memberDecl); if (jsDocType) { checkTypeAssignableTo(type, jsDocType, memberDecl); type = jsDocType; } else if (enumTag && enumTag.typeExpression) { checkTypeAssignableTo(type, getTypeFromTypeNode(enumTag.typeExpression), memberDecl); } } typeFlags |= type.flags; const nameType = computedNameType && isTypeUsableAsPropertyName(computedNameType) ? computedNameType : undefined; const prop = nameType ? createSymbol(SymbolFlags.Property | member.flags, getPropertyNameFromType(nameType), checkFlags | CheckFlags.Late) : createSymbol(SymbolFlags.Property | member.flags, member.escapedName, checkFlags); if (nameType) { prop.nameType = nameType; } if (inDestructuringPattern) { // If object literal is an assignment pattern and if the assignment pattern specifies a default value // for the property, make the property optional. const isOptional = (memberDecl.kind === SyntaxKind.PropertyAssignment && hasDefaultValue(memberDecl.initializer)) || (memberDecl.kind === SyntaxKind.ShorthandPropertyAssignment && memberDecl.objectAssignmentInitializer); if (isOptional) { prop.flags |= SymbolFlags.Optional; } } else if (contextualTypeHasPattern && !(getObjectFlags(contextualType!) & ObjectFlags.ObjectLiteralPatternWithComputedProperties)) { // If object literal is contextually typed by the implied type of a binding pattern, and if the // binding pattern specifies a default value for the property, make the property optional. const impliedProp = getPropertyOfType(contextualType!, member.escapedName); if (impliedProp) { prop.flags |= impliedProp.flags & SymbolFlags.Optional; } else if (!compilerOptions.suppressExcessPropertyErrors && !getIndexInfoOfType(contextualType!, IndexKind.String)) { error(memberDecl.name, Diagnostics.Object_literal_may_only_specify_known_properties_and_0_does_not_exist_in_type_1, symbolToString(member), typeToString(contextualType!)); } } prop.declarations = member.declarations; prop.parent = member.parent; if (member.valueDeclaration) { prop.valueDeclaration = member.valueDeclaration; } prop.type = type; prop.target = member; member = prop; } else if (memberDecl.kind === SyntaxKind.SpreadAssignment) { if (languageVersion < ScriptTarget.ES2015) { checkExternalEmitHelpers(memberDecl, ExternalEmitHelpers.Assign); } if (propertiesArray.length > 0) { spread = getSpreadType(spread, createObjectLiteralType(), node.symbol, propagatedFlags, ObjectFlags.FreshLiteral, inConstContext); propertiesArray = []; propertiesTable = createSymbolTable(); hasComputedStringProperty = false; hasComputedNumberProperty = false; typeFlags = 0; } const type = checkExpression(memberDecl.expression); if (!isValidSpreadType(type)) { error(memberDecl, Diagnostics.Spread_types_may_only_be_created_from_object_types); return errorType; } spread = getSpreadType(spread, type, node.symbol, propagatedFlags, ObjectFlags.FreshLiteral, inConstContext); offset = i + 1; continue; } else { // TypeScript 1.0 spec (April 2014) // A get accessor declaration is processed in the same manner as // an ordinary function declaration(section 6.1) with no parameters. // A set accessor declaration is processed in the same manner // as an ordinary function declaration with a single parameter and a Void return type. Debug.assert(memberDecl.kind === SyntaxKind.GetAccessor || memberDecl.kind === SyntaxKind.SetAccessor); checkNodeDeferred(memberDecl); } if (computedNameType && !(computedNameType.flags & TypeFlags.StringOrNumberLiteralOrUnique)) { if (isTypeAssignableTo(computedNameType, stringNumberSymbolType)) { if (isTypeAssignableTo(computedNameType, numberType)) { hasComputedNumberProperty = true; } else { hasComputedStringProperty = true; } if (inDestructuringPattern) { patternWithComputedProperties = true; } } } else { propertiesTable.set(member.escapedName, member); } propertiesArray.push(member); } // If object literal is contextually typed by the implied type of a binding pattern, augment the result // type with those properties for which the binding pattern specifies a default value. if (contextualTypeHasPattern) { for (const prop of getPropertiesOfType(contextualType!)) { if (!propertiesTable.get(prop.escapedName) && !(spread && getPropertyOfType(spread, prop.escapedName))) { if (!(prop.flags & SymbolFlags.Optional)) { error(prop.valueDeclaration || (prop).bindingElement, Diagnostics.Initializer_provides_no_value_for_this_binding_element_and_the_binding_element_has_no_default_value); } propertiesTable.set(prop.escapedName, prop); propertiesArray.push(prop); } } } if (spread !== emptyObjectType) { if (propertiesArray.length > 0) { spread = getSpreadType(spread, createObjectLiteralType(), node.symbol, propagatedFlags, ObjectFlags.FreshLiteral, inConstContext); } return spread; } return createObjectLiteralType(); function createObjectLiteralType() { const stringIndexInfo = hasComputedStringProperty ? getObjectLiteralIndexInfo(node, offset, propertiesArray, IndexKind.String) : undefined; const numberIndexInfo = hasComputedNumberProperty ? getObjectLiteralIndexInfo(node, offset, propertiesArray, IndexKind.Number) : undefined; const result = createAnonymousType(node.symbol, propertiesTable, emptyArray, emptyArray, stringIndexInfo, numberIndexInfo); result.flags |= TypeFlags.ContainsObjectLiteral | typeFlags & TypeFlags.PropagatingFlags; result.objectFlags |= ObjectFlags.ObjectLiteral | freshObjectLiteralFlag; if (isJSObjectLiteral) { result.objectFlags |= ObjectFlags.JSLiteral; } if (patternWithComputedProperties) { result.objectFlags |= ObjectFlags.ObjectLiteralPatternWithComputedProperties; } if (inDestructuringPattern) { result.pattern = node; } propagatedFlags |= result.flags & TypeFlags.PropagatingFlags; return result; } } function isValidSpreadType(type: Type): boolean { return !!(type.flags & (TypeFlags.AnyOrUnknown | TypeFlags.NonPrimitive | TypeFlags.Object | TypeFlags.InstantiableNonPrimitive) || getFalsyFlags(type) & TypeFlags.DefinitelyFalsy && isValidSpreadType(removeDefinitelyFalsyTypes(type)) || type.flags & TypeFlags.UnionOrIntersection && every((type).types, isValidSpreadType)); } function checkJsxSelfClosingElementDeferred(node: JsxSelfClosingElement) { checkJsxOpeningLikeElementOrOpeningFragment(node); } function checkJsxSelfClosingElement(node: JsxSelfClosingElement, _checkMode: CheckMode | undefined): Type { checkNodeDeferred(node); return getJsxElementTypeAt(node) || anyType; } function checkJsxElementDeferred(node: JsxElement) { // Check attributes checkJsxOpeningLikeElementOrOpeningFragment(node.openingElement); // Perform resolution on the closing tag so that rename/go to definition/etc work if (isJsxIntrinsicIdentifier(node.closingElement.tagName)) { getIntrinsicTagSymbol(node.closingElement); } else { checkExpression(node.closingElement.tagName); } checkJsxChildren(node); } function checkJsxElement(node: JsxElement, _checkMode: CheckMode | undefined): Type { checkNodeDeferred(node); return getJsxElementTypeAt(node) || anyType; } function checkJsxFragment(node: JsxFragment): Type { checkJsxOpeningLikeElementOrOpeningFragment(node.openingFragment); if (compilerOptions.jsx === JsxEmit.React && (compilerOptions.jsxFactory || getSourceFileOfNode(node).pragmas.has("jsx"))) { error(node, compilerOptions.jsxFactory ? Diagnostics.JSX_fragment_is_not_supported_when_using_jsxFactory : Diagnostics.JSX_fragment_is_not_supported_when_using_an_inline_JSX_factory_pragma); } checkJsxChildren(node); return getJsxElementTypeAt(node) || anyType; } /** * Returns true iff the JSX element name would be a valid JS identifier, ignoring restrictions about keywords not being identifiers */ function isUnhyphenatedJsxName(name: string | __String) { // - is the only character supported in JSX attribute names that isn't valid in JavaScript identifiers return !stringContains(name as string, "-"); } /** * Returns true iff React would emit this tag name as a string rather than an identifier or qualified name */ function isJsxIntrinsicIdentifier(tagName: JsxTagNameExpression): boolean { return tagName.kind === SyntaxKind.Identifier && isIntrinsicJsxName(tagName.escapedText); } function checkJsxAttribute(node: JsxAttribute, checkMode?: CheckMode) { return node.initializer ? checkExpressionForMutableLocation(node.initializer, checkMode) : trueType; // is sugar for } /** * Get attributes type of the JSX opening-like element. The result is from resolving "attributes" property of the opening-like element. * * @param openingLikeElement a JSX opening-like element * @param filter a function to remove attributes that will not participate in checking whether attributes are assignable * @return an anonymous type (similar to the one returned by checkObjectLiteral) in which its properties are attributes property. * @remarks Because this function calls getSpreadType, it needs to use the same checks as checkObjectLiteral, * which also calls getSpreadType. */ function createJsxAttributesTypeFromAttributesProperty(openingLikeElement: JsxOpeningLikeElement, checkMode: CheckMode | undefined) { const attributes = openingLikeElement.attributes; let attributesTable = createSymbolTable(); let spread: Type = emptyJsxObjectType; let hasSpreadAnyType = false; let typeToIntersect: Type | undefined; let explicitlySpecifyChildrenAttribute = false; let typeFlags: TypeFlags = 0; let objectFlags: ObjectFlags = ObjectFlags.JsxAttributes; const jsxChildrenPropertyName = getJsxElementChildrenPropertyName(getJsxNamespaceAt(openingLikeElement)); for (const attributeDecl of attributes.properties) { const member = attributeDecl.symbol; if (isJsxAttribute(attributeDecl)) { const exprType = checkJsxAttribute(attributeDecl, checkMode); typeFlags |= exprType.flags & TypeFlags.PropagatingFlags; const attributeSymbol = createSymbol(SymbolFlags.Property | SymbolFlags.Transient | member.flags, member.escapedName); attributeSymbol.declarations = member.declarations; attributeSymbol.parent = member.parent; if (member.valueDeclaration) { attributeSymbol.valueDeclaration = member.valueDeclaration; } attributeSymbol.type = exprType; attributeSymbol.target = member; attributesTable.set(attributeSymbol.escapedName, attributeSymbol); if (attributeDecl.name.escapedText === jsxChildrenPropertyName) { explicitlySpecifyChildrenAttribute = true; } } else { Debug.assert(attributeDecl.kind === SyntaxKind.JsxSpreadAttribute); if (attributesTable.size > 0) { spread = getSpreadType(spread, createJsxAttributesType(), attributes.symbol, typeFlags, objectFlags, /*readonly*/ false); attributesTable = createSymbolTable(); } const exprType = checkExpressionCached(attributeDecl.expression, checkMode); if (isTypeAny(exprType)) { hasSpreadAnyType = true; } if (isValidSpreadType(exprType)) { spread = getSpreadType(spread, exprType, attributes.symbol, typeFlags, objectFlags, /*readonly*/ false); } else { typeToIntersect = typeToIntersect ? getIntersectionType([typeToIntersect, exprType]) : exprType; } } } if (!hasSpreadAnyType) { if (attributesTable.size > 0) { spread = getSpreadType(spread, createJsxAttributesType(), attributes.symbol, typeFlags, objectFlags, /*readonly*/ false); } } // Handle children attribute const parent = openingLikeElement.parent.kind === SyntaxKind.JsxElement ? openingLikeElement.parent as JsxElement : undefined; // We have to check that openingElement of the parent is the one we are visiting as this may not be true for selfClosingElement if (parent && parent.openingElement === openingLikeElement && parent.children.length > 0) { const childrenTypes: Type[] = checkJsxChildren(parent, checkMode); if (!hasSpreadAnyType && jsxChildrenPropertyName && jsxChildrenPropertyName !== "") { // Error if there is a attribute named "children" explicitly specified and children element. // This is because children element will overwrite the value from attributes. // Note: we will not warn "children" attribute overwritten if "children" attribute is specified in object spread. if (explicitlySpecifyChildrenAttribute) { error(attributes, Diagnostics._0_are_specified_twice_The_attribute_named_0_will_be_overwritten, unescapeLeadingUnderscores(jsxChildrenPropertyName)); } const contextualType = getApparentTypeOfContextualType(openingLikeElement.attributes); const childrenContextualType = contextualType && getTypeOfPropertyOfContextualType(contextualType, jsxChildrenPropertyName); // If there are children in the body of JSX element, create dummy attribute "children" with the union of children types so that it will pass the attribute checking process const childrenPropSymbol = createSymbol(SymbolFlags.Property | SymbolFlags.Transient, jsxChildrenPropertyName); childrenPropSymbol.type = childrenTypes.length === 1 ? childrenTypes[0] : (getArrayLiteralTupleTypeIfApplicable(childrenTypes, childrenContextualType, /*hasRestElement*/ false) || createArrayType(getUnionType(childrenTypes))); // Fake up a property declaration for the children childrenPropSymbol.valueDeclaration = createPropertySignature(/*modifiers*/ undefined, unescapeLeadingUnderscores(jsxChildrenPropertyName), /*questionToken*/ undefined, /*type*/ undefined, /*initializer*/ undefined); childrenPropSymbol.valueDeclaration.parent = attributes; childrenPropSymbol.valueDeclaration.symbol = childrenPropSymbol; const childPropMap = createSymbolTable(); childPropMap.set(jsxChildrenPropertyName, childrenPropSymbol); spread = getSpreadType(spread, createAnonymousType(attributes.symbol, childPropMap, emptyArray, emptyArray, /*stringIndexInfo*/ undefined, /*numberIndexInfo*/ undefined), attributes.symbol, typeFlags, objectFlags, /*readonly*/ false); } } if (hasSpreadAnyType) { return anyType; } if (typeToIntersect && spread !== emptyJsxObjectType) { return getIntersectionType([typeToIntersect, spread]); } return typeToIntersect || (spread === emptyJsxObjectType ? createJsxAttributesType() : spread); /** * Create anonymous type from given attributes symbol table. * @param symbol a symbol of JsxAttributes containing attributes corresponding to attributesTable * @param attributesTable a symbol table of attributes property */ function createJsxAttributesType() { objectFlags |= freshObjectLiteralFlag; const result = createAnonymousType(attributes.symbol, attributesTable, emptyArray, emptyArray, /*stringIndexInfo*/ undefined, /*numberIndexInfo*/ undefined); result.flags |= TypeFlags.ContainsObjectLiteral | typeFlags; result.objectFlags |= ObjectFlags.ObjectLiteral | objectFlags; return result; } } function checkJsxChildren(node: JsxElement | JsxFragment, checkMode?: CheckMode) { const childrenTypes: Type[] = []; for (const child of node.children) { // In React, JSX text that contains only whitespaces will be ignored so we don't want to type-check that // because then type of children property will have constituent of string type. if (child.kind === SyntaxKind.JsxText) { if (!child.containsOnlyWhiteSpaces) { childrenTypes.push(stringType); } } else { childrenTypes.push(checkExpressionForMutableLocation(child, checkMode)); } } return childrenTypes; } /** * Check attributes property of opening-like element. This function is called during chooseOverload to get call signature of a JSX opening-like element. * (See "checkApplicableSignatureForJsxOpeningLikeElement" for how the function is used) * @param node a JSXAttributes to be resolved of its type */ function checkJsxAttributes(node: JsxAttributes, checkMode: CheckMode | undefined) { return createJsxAttributesTypeFromAttributesProperty(node.parent, checkMode); } function getJsxType(name: __String, location: Node | undefined) { const namespace = getJsxNamespaceAt(location); const exports = namespace && getExportsOfSymbol(namespace); const typeSymbol = exports && getSymbol(exports, name, SymbolFlags.Type); return typeSymbol ? getDeclaredTypeOfSymbol(typeSymbol) : errorType; } /** * Looks up an intrinsic tag name and returns a symbol that either points to an intrinsic * property (in which case nodeLinks.jsxFlags will be IntrinsicNamedElement) or an intrinsic * string index signature (in which case nodeLinks.jsxFlags will be IntrinsicIndexedElement). * May also return unknownSymbol if both of these lookups fail. */ function getIntrinsicTagSymbol(node: JsxOpeningLikeElement | JsxClosingElement): Symbol { const links = getNodeLinks(node); if (!links.resolvedSymbol) { const intrinsicElementsType = getJsxType(JsxNames.IntrinsicElements, node); if (intrinsicElementsType !== errorType) { // Property case if (!isIdentifier(node.tagName)) return Debug.fail(); const intrinsicProp = getPropertyOfType(intrinsicElementsType, node.tagName.escapedText); if (intrinsicProp) { links.jsxFlags |= JsxFlags.IntrinsicNamedElement; return links.resolvedSymbol = intrinsicProp; } // Intrinsic string indexer case const indexSignatureType = getIndexTypeOfType(intrinsicElementsType, IndexKind.String); if (indexSignatureType) { links.jsxFlags |= JsxFlags.IntrinsicIndexedElement; return links.resolvedSymbol = intrinsicElementsType.symbol; } // Wasn't found error(node, Diagnostics.Property_0_does_not_exist_on_type_1, idText(node.tagName), "JSX." + JsxNames.IntrinsicElements); return links.resolvedSymbol = unknownSymbol; } else { if (noImplicitAny) { error(node, Diagnostics.JSX_element_implicitly_has_type_any_because_no_interface_JSX_0_exists, unescapeLeadingUnderscores(JsxNames.IntrinsicElements)); } return links.resolvedSymbol = unknownSymbol; } } return links.resolvedSymbol; } function getJsxNamespaceAt(location: Node | undefined): Symbol { const links = location && getNodeLinks(location); if (links && links.jsxNamespace) { return links.jsxNamespace; } if (!links || links.jsxNamespace !== false) { const namespaceName = getJsxNamespace(location); const resolvedNamespace = resolveName(location, namespaceName, SymbolFlags.Namespace, /*diagnosticMessage*/ undefined, namespaceName, /*isUse*/ false); if (resolvedNamespace) { const candidate = getSymbol(getExportsOfSymbol(resolveSymbol(resolvedNamespace)), JsxNames.JSX, SymbolFlags.Namespace); if (candidate) { if (links) { links.jsxNamespace = candidate; } return candidate; } if (links) { links.jsxNamespace = false; } } } // JSX global fallback return getGlobalSymbol(JsxNames.JSX, SymbolFlags.Namespace, /*diagnosticMessage*/ undefined)!; // TODO: GH#18217 } /** * Look into JSX namespace and then look for container with matching name as nameOfAttribPropContainer. * Get a single property from that container if existed. Report an error if there are more than one property. * * @param nameOfAttribPropContainer a string of value JsxNames.ElementAttributesPropertyNameContainer or JsxNames.ElementChildrenAttributeNameContainer * if other string is given or the container doesn't exist, return undefined. */ function getNameFromJsxElementAttributesContainer(nameOfAttribPropContainer: __String, jsxNamespace: Symbol): __String | undefined { // JSX.ElementAttributesProperty | JSX.ElementChildrenAttribute [symbol] const jsxElementAttribPropInterfaceSym = jsxNamespace && getSymbol(jsxNamespace.exports!, nameOfAttribPropContainer, SymbolFlags.Type); // JSX.ElementAttributesProperty | JSX.ElementChildrenAttribute [type] const jsxElementAttribPropInterfaceType = jsxElementAttribPropInterfaceSym && getDeclaredTypeOfSymbol(jsxElementAttribPropInterfaceSym); // The properties of JSX.ElementAttributesProperty | JSX.ElementChildrenAttribute const propertiesOfJsxElementAttribPropInterface = jsxElementAttribPropInterfaceType && getPropertiesOfType(jsxElementAttribPropInterfaceType); if (propertiesOfJsxElementAttribPropInterface) { // Element Attributes has zero properties, so the element attributes type will be the class instance type if (propertiesOfJsxElementAttribPropInterface.length === 0) { return "" as __String; } // Element Attributes has one property, so the element attributes type will be the type of the corresponding // property of the class instance type else if (propertiesOfJsxElementAttribPropInterface.length === 1) { return propertiesOfJsxElementAttribPropInterface[0].escapedName; } else if (propertiesOfJsxElementAttribPropInterface.length > 1) { // More than one property on ElementAttributesProperty is an error error(jsxElementAttribPropInterfaceSym!.declarations[0], Diagnostics.The_global_type_JSX_0_may_not_have_more_than_one_property, unescapeLeadingUnderscores(nameOfAttribPropContainer)); } } return undefined; } function getJsxLibraryManagedAttributes(jsxNamespace: Symbol) { // JSX.LibraryManagedAttributes [symbol] return jsxNamespace && getSymbol(jsxNamespace.exports!, JsxNames.LibraryManagedAttributes, SymbolFlags.Type); } /// e.g. "props" for React.d.ts, /// or 'undefined' if ElementAttributesProperty doesn't exist (which means all /// non-intrinsic elements' attributes type is 'any'), /// or '' if it has 0 properties (which means every /// non-intrinsic elements' attributes type is the element instance type) function getJsxElementPropertiesName(jsxNamespace: Symbol) { return getNameFromJsxElementAttributesContainer(JsxNames.ElementAttributesPropertyNameContainer, jsxNamespace); } function getJsxElementChildrenPropertyName(jsxNamespace: Symbol): __String | undefined { return getNameFromJsxElementAttributesContainer(JsxNames.ElementChildrenAttributeNameContainer, jsxNamespace); } function getUninstantiatedJsxSignaturesOfType(elementType: Type, caller: JsxOpeningLikeElement): ReadonlyArray { if (elementType.flags & TypeFlags.String) { return [anySignature]; } else if (elementType.flags & TypeFlags.StringLiteral) { const intrinsicType = getIntrinsicAttributesTypeFromStringLiteralType(elementType as StringLiteralType, caller); if (!intrinsicType) { error(caller, Diagnostics.Property_0_does_not_exist_on_type_1, (elementType as StringLiteralType).value, "JSX." + JsxNames.IntrinsicElements); return emptyArray; } else { const fakeSignature = createSignatureForJSXIntrinsic(caller, intrinsicType); return [fakeSignature]; } } const apparentElemType = getApparentType(elementType); // Resolve the signatures, preferring constructor let signatures = getSignaturesOfType(apparentElemType, SignatureKind.Construct); if (signatures.length === 0) { // No construct signatures, try call signatures signatures = getSignaturesOfType(apparentElemType, SignatureKind.Call); } if (signatures.length === 0 && apparentElemType.flags & TypeFlags.Union) { // If each member has some combination of new/call signatures; make a union signature list for those signatures = getUnionSignatures(map((apparentElemType as UnionType).types, t => getUninstantiatedJsxSignaturesOfType(t, caller))); } return signatures; } function getIntrinsicAttributesTypeFromStringLiteralType(type: StringLiteralType, location: Node): Type | undefined { // If the elemType is a stringLiteral type, we can then provide a check to make sure that the string literal type is one of the Jsx intrinsic element type // For example: // var CustomTag: "h1" = "h1"; // Hello World const intrinsicElementsType = getJsxType(JsxNames.IntrinsicElements, location); if (intrinsicElementsType !== errorType) { const stringLiteralTypeName = type.value; const intrinsicProp = getPropertyOfType(intrinsicElementsType, escapeLeadingUnderscores(stringLiteralTypeName)); if (intrinsicProp) { return getTypeOfSymbol(intrinsicProp); } const indexSignatureType = getIndexTypeOfType(intrinsicElementsType, IndexKind.String); if (indexSignatureType) { return indexSignatureType; } return undefined; } // If we need to report an error, we already done so here. So just return any to prevent any more error downstream return anyType; } function checkJsxReturnAssignableToAppropriateBound(refKind: JsxReferenceKind, elemInstanceType: Type, openingLikeElement: Node) { if (refKind === JsxReferenceKind.Function) { const sfcReturnConstraint = getJsxStatelessElementTypeAt(openingLikeElement); if (sfcReturnConstraint) { checkTypeRelatedTo(elemInstanceType, sfcReturnConstraint, assignableRelation, openingLikeElement, Diagnostics.JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements); } } else if (refKind === JsxReferenceKind.Component) { const classConstraint = getJsxElementClassTypeAt(openingLikeElement); if (classConstraint) { // Issue an error if this return type isn't assignable to JSX.ElementClass or JSX.Element, failing that checkTypeRelatedTo(elemInstanceType, classConstraint, assignableRelation, openingLikeElement, Diagnostics.JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements); } } else { // Mixed const sfcReturnConstraint = getJsxStatelessElementTypeAt(openingLikeElement); const classConstraint = getJsxElementClassTypeAt(openingLikeElement); if (!sfcReturnConstraint || !classConstraint) { return; } const combined = getUnionType([sfcReturnConstraint, classConstraint]); checkTypeRelatedTo(elemInstanceType, combined, assignableRelation, openingLikeElement, Diagnostics.JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements); } } /** * Get attributes type of the given intrinsic opening-like Jsx element by resolving the tag name. * The function is intended to be called from a function which has checked that the opening element is an intrinsic element. * @param node an intrinsic JSX opening-like element */ function getIntrinsicAttributesTypeFromJsxOpeningLikeElement(node: JsxOpeningLikeElement): Type { Debug.assert(isJsxIntrinsicIdentifier(node.tagName)); const links = getNodeLinks(node); if (!links.resolvedJsxElementAttributesType) { const symbol = getIntrinsicTagSymbol(node); if (links.jsxFlags & JsxFlags.IntrinsicNamedElement) { return links.resolvedJsxElementAttributesType = getTypeOfSymbol(symbol); } else if (links.jsxFlags & JsxFlags.IntrinsicIndexedElement) { return links.resolvedJsxElementAttributesType = getIndexInfoOfSymbol(symbol, IndexKind.String)!.type; } else { return links.resolvedJsxElementAttributesType = errorType; } } return links.resolvedJsxElementAttributesType; } function getJsxElementClassTypeAt(location: Node): Type | undefined { const type = getJsxType(JsxNames.ElementClass, location); if (type === errorType) return undefined; return type; } function getJsxElementTypeAt(location: Node): Type { return getJsxType(JsxNames.Element, location); } function getJsxStatelessElementTypeAt(location: Node): Type | undefined { const jsxElementType = getJsxElementTypeAt(location); if (jsxElementType) { return getUnionType([jsxElementType, nullType]); } } /** * Returns all the properties of the Jsx.IntrinsicElements interface */ function getJsxIntrinsicTagNamesAt(location: Node): Symbol[] { const intrinsics = getJsxType(JsxNames.IntrinsicElements, location); return intrinsics ? getPropertiesOfType(intrinsics) : emptyArray; } function checkJsxPreconditions(errorNode: Node) { // Preconditions for using JSX if ((compilerOptions.jsx || JsxEmit.None) === JsxEmit.None) { error(errorNode, Diagnostics.Cannot_use_JSX_unless_the_jsx_flag_is_provided); } if (getJsxElementTypeAt(errorNode) === undefined) { if (noImplicitAny) { error(errorNode, Diagnostics.JSX_element_implicitly_has_type_any_because_the_global_type_JSX_Element_does_not_exist); } } } function checkJsxOpeningLikeElementOrOpeningFragment(node: JsxOpeningLikeElement | JsxOpeningFragment) { const isNodeOpeningLikeElement = isJsxOpeningLikeElement(node); if (isNodeOpeningLikeElement) { checkGrammarJsxElement(node); } checkJsxPreconditions(node); // The reactNamespace/jsxFactory's root symbol should be marked as 'used' so we don't incorrectly elide its import. // And if there is no reactNamespace/jsxFactory's symbol in scope when targeting React emit, we should issue an error. const reactRefErr = diagnostics && compilerOptions.jsx === JsxEmit.React ? Diagnostics.Cannot_find_name_0 : undefined; const reactNamespace = getJsxNamespace(node); const reactLocation = isNodeOpeningLikeElement ? (node).tagName : node; const reactSym = resolveName(reactLocation, reactNamespace, SymbolFlags.Value, reactRefErr, reactNamespace, /*isUse*/ true); if (reactSym) { // Mark local symbol as referenced here because it might not have been marked // if jsx emit was not react as there wont be error being emitted reactSym.isReferenced = SymbolFlags.All; // If react symbol is alias, mark it as referenced if (reactSym.flags & SymbolFlags.Alias && !isConstEnumOrConstEnumOnlyModule(resolveAlias(reactSym))) { markAliasSymbolAsReferenced(reactSym); } } if (isNodeOpeningLikeElement) { const sig = getResolvedSignature(node as JsxOpeningLikeElement); checkJsxReturnAssignableToAppropriateBound(getJsxReferenceKind(node as JsxOpeningLikeElement), getReturnTypeOfSignature(sig), node); } } /** * Check if a property with the given name is known anywhere in the given type. In an object type, a property * is considered known if * 1. the object type is empty and the check is for assignability, or * 2. if the object type has index signatures, or * 3. if the property is actually declared in the object type * (this means that 'toString', for example, is not usually a known property). * 4. In a union or intersection type, * a property is considered known if it is known in any constituent type. * @param targetType a type to search a given name in * @param name a property name to search * @param isComparingJsxAttributes a boolean flag indicating whether we are searching in JsxAttributesType */ function isKnownProperty(targetType: Type, name: __String, isComparingJsxAttributes: boolean): boolean { if (targetType.flags & TypeFlags.Object) { const resolved = resolveStructuredTypeMembers(targetType as ObjectType); if (resolved.stringIndexInfo || resolved.numberIndexInfo && isNumericLiteralName(name) || getPropertyOfObjectType(targetType, name) || isComparingJsxAttributes && !isUnhyphenatedJsxName(name)) { // For JSXAttributes, if the attribute has a hyphenated name, consider that the attribute to be known. return true; } } else if (targetType.flags & TypeFlags.UnionOrIntersection && isExcessPropertyCheckTarget(targetType)) { for (const t of (targetType as UnionOrIntersectionType).types) { if (isKnownProperty(t, name, isComparingJsxAttributes)) { return true; } } } return false; } function isExcessPropertyCheckTarget(type: Type): boolean { return !!(type.flags & TypeFlags.Object && !(getObjectFlags(type) & ObjectFlags.ObjectLiteralPatternWithComputedProperties) || type.flags & TypeFlags.NonPrimitive || type.flags & TypeFlags.Union && some((type).types, isExcessPropertyCheckTarget) || type.flags & TypeFlags.Intersection && every((type).types, isExcessPropertyCheckTarget)); } function checkJsxExpression(node: JsxExpression, checkMode?: CheckMode) { if (node.expression) { const type = checkExpression(node.expression, checkMode); if (node.dotDotDotToken && type !== anyType && !isArrayType(type)) { error(node, Diagnostics.JSX_spread_child_must_be_an_array_type); } return type; } else { return errorType; } } function getDeclarationNodeFlagsFromSymbol(s: Symbol): NodeFlags { return s.valueDeclaration ? getCombinedNodeFlags(s.valueDeclaration) : 0; } /** * Return whether this symbol is a member of a prototype somewhere * Note that this is not tracked well within the compiler, so the answer may be incorrect. */ function isPrototypeProperty(symbol: Symbol) { if (symbol.flags & SymbolFlags.Method || getCheckFlags(symbol) & CheckFlags.SyntheticMethod) { return true; } if (isInJSFile(symbol.valueDeclaration)) { const parent = symbol.valueDeclaration.parent; return parent && isBinaryExpression(parent) && getAssignmentDeclarationKind(parent) === AssignmentDeclarationKind.PrototypeProperty; } } /** * Check whether the requested property access is valid. * Returns true if node is a valid property access, and false otherwise. * @param node The node to be checked. * @param isSuper True if the access is from `super.`. * @param type The type of the object whose property is being accessed. (Not the type of the property.) * @param prop The symbol for the property being accessed. */ function checkPropertyAccessibility( node: PropertyAccessExpression | QualifiedName | PropertyAccessExpression | VariableDeclaration | ParameterDeclaration | ImportTypeNode | PropertyAssignment | ShorthandPropertyAssignment | BindingElement, isSuper: boolean, type: Type, prop: Symbol): boolean { const flags = getDeclarationModifierFlagsFromSymbol(prop); const errorNode = node.kind === SyntaxKind.QualifiedName ? node.right : node.kind === SyntaxKind.ImportType ? node : node.name; if (getCheckFlags(prop) & CheckFlags.ContainsPrivate) { // Synthetic property with private constituent property error(errorNode, Diagnostics.Property_0_has_conflicting_declarations_and_is_inaccessible_in_type_1, symbolToString(prop), typeToString(type)); return false; } if (isSuper) { // TS 1.0 spec (April 2014): 4.8.2 // - In a constructor, instance member function, instance member accessor, or // instance member variable initializer where this references a derived class instance, // a super property access is permitted and must specify a public instance member function of the base class. // - In a static member function or static member accessor // where this references the constructor function object of a derived class, // a super property access is permitted and must specify a public static member function of the base class. if (languageVersion < ScriptTarget.ES2015) { if (symbolHasNonMethodDeclaration(prop)) { error(errorNode, Diagnostics.Only_public_and_protected_methods_of_the_base_class_are_accessible_via_the_super_keyword); return false; } } if (flags & ModifierFlags.Abstract) { // A method cannot be accessed in a super property access if the method is abstract. // This error could mask a private property access error. But, a member // cannot simultaneously be private and abstract, so this will trigger an // additional error elsewhere. error(errorNode, Diagnostics.Abstract_method_0_in_class_1_cannot_be_accessed_via_super_expression, symbolToString(prop), typeToString(getDeclaringClass(prop)!)); return false; } } // Referencing abstract properties within their own constructors is not allowed if ((flags & ModifierFlags.Abstract) && isThisProperty(node) && symbolHasNonMethodDeclaration(prop)) { const declaringClassDeclaration = getClassLikeDeclarationOfSymbol(getParentOfSymbol(prop)!); if (declaringClassDeclaration && isNodeUsedDuringClassInitialization(node)) { error(errorNode, Diagnostics.Abstract_property_0_in_class_1_cannot_be_accessed_in_the_constructor, symbolToString(prop), getTextOfIdentifierOrLiteral(declaringClassDeclaration.name!)); // TODO: GH#18217 return false; } } // Public properties are otherwise accessible. if (!(flags & ModifierFlags.NonPublicAccessibilityModifier)) { return true; } // Property is known to be private or protected at this point // Private property is accessible if the property is within the declaring class if (flags & ModifierFlags.Private) { const declaringClassDeclaration = getClassLikeDeclarationOfSymbol(getParentOfSymbol(prop)!)!; if (!isNodeWithinClass(node, declaringClassDeclaration)) { error(errorNode, Diagnostics.Property_0_is_private_and_only_accessible_within_class_1, symbolToString(prop), typeToString(getDeclaringClass(prop)!)); return false; } return true; } // Property is known to be protected at this point // All protected properties of a supertype are accessible in a super access if (isSuper) { return true; } // Find the first enclosing class that has the declaring classes of the protected constituents // of the property as base classes let enclosingClass = forEachEnclosingClass(node, enclosingDeclaration => { const enclosingClass = getDeclaredTypeOfSymbol(getSymbolOfNode(enclosingDeclaration)!); return isClassDerivedFromDeclaringClasses(enclosingClass, prop) ? enclosingClass : undefined; }); // A protected property is accessible if the property is within the declaring class or classes derived from it if (!enclosingClass) { // allow PropertyAccessibility if context is in function with this parameter // static member access is disallow let thisParameter: ParameterDeclaration | undefined; if (flags & ModifierFlags.Static || !(thisParameter = getThisParameterFromNodeContext(node)) || !thisParameter.type) { error(errorNode, Diagnostics.Property_0_is_protected_and_only_accessible_within_class_1_and_its_subclasses, symbolToString(prop), typeToString(getDeclaringClass(prop) || type)); return false; } const thisType = getTypeFromTypeNode(thisParameter.type); enclosingClass = ((thisType.flags & TypeFlags.TypeParameter) ? getConstraintOfTypeParameter(thisType) : thisType) as InterfaceType; } // No further restrictions for static properties if (flags & ModifierFlags.Static) { return true; } if (type.flags & TypeFlags.TypeParameter) { // get the original type -- represented as the type constraint of the 'this' type type = (type as TypeParameter).isThisType ? getConstraintOfTypeParameter(type)! : getBaseConstraintOfType(type)!; // TODO: GH#18217 Use a different variable that's allowed to be undefined } if (!type || !hasBaseType(type, enclosingClass)) { error(errorNode, Diagnostics.Property_0_is_protected_and_only_accessible_through_an_instance_of_class_1, symbolToString(prop), typeToString(enclosingClass)); return false; } return true; } function getThisParameterFromNodeContext (node: Node) { const thisContainer = getThisContainer(node, /* includeArrowFunctions */ false); return thisContainer && isFunctionLike(thisContainer) ? getThisParameter(thisContainer) : undefined; } function symbolHasNonMethodDeclaration(symbol: Symbol) { return !!forEachProperty(symbol, prop => !(prop.flags & SymbolFlags.Method)); } function checkNonNullExpression( node: Expression | QualifiedName, nullDiagnostic?: DiagnosticMessage, undefinedDiagnostic?: DiagnosticMessage, nullOrUndefinedDiagnostic?: DiagnosticMessage, ) { return checkNonNullType( checkExpression(node), node, nullDiagnostic, undefinedDiagnostic, nullOrUndefinedDiagnostic ); } function getNonNullableTypeIfNeeded(type: Type) { const kind = (strictNullChecks ? getFalsyFlags(type) : type.flags) & TypeFlags.Nullable; if (kind) { return getNonNullableType(type); } return type; } function checkNonNullType( type: Type, node: Node, nullDiagnostic?: DiagnosticMessage, undefinedDiagnostic?: DiagnosticMessage, nullOrUndefinedDiagnostic?: DiagnosticMessage ): Type { if (type.flags & TypeFlags.Unknown) { error(node, Diagnostics.Object_is_of_type_unknown); return errorType; } const kind = (strictNullChecks ? getFalsyFlags(type) : type.flags) & TypeFlags.Nullable; if (kind) { error(node, kind & TypeFlags.Undefined ? kind & TypeFlags.Null ? (nullOrUndefinedDiagnostic || Diagnostics.Object_is_possibly_null_or_undefined) : (undefinedDiagnostic || Diagnostics.Object_is_possibly_undefined) : (nullDiagnostic || Diagnostics.Object_is_possibly_null) ); const t = getNonNullableType(type); return t.flags & (TypeFlags.Nullable | TypeFlags.Never) ? errorType : t; } return type; } function checkPropertyAccessExpression(node: PropertyAccessExpression) { return checkPropertyAccessExpressionOrQualifiedName(node, node.expression, node.name); } function checkQualifiedName(node: QualifiedName) { return checkPropertyAccessExpressionOrQualifiedName(node, node.left, node.right); } function checkPropertyAccessExpressionOrQualifiedName(node: PropertyAccessExpression | QualifiedName, left: Expression | QualifiedName, right: Identifier) { let propType: Type; const leftType = checkNonNullExpression(left); const parentSymbol = getNodeLinks(left).resolvedSymbol; const apparentType = getApparentType(getWidenedType(leftType)); if (isTypeAny(apparentType) || apparentType === silentNeverType) { if (isIdentifier(left) && parentSymbol) { markAliasReferenced(parentSymbol, node); } return apparentType; } const assignmentKind = getAssignmentTargetKind(node); const prop = getPropertyOfType(apparentType, right.escapedText); if (isIdentifier(left) && parentSymbol && !(prop && isConstEnumOrConstEnumOnlyModule(prop))) { markAliasReferenced(parentSymbol, node); } if (!prop) { const indexInfo = getIndexInfoOfType(apparentType, IndexKind.String); if (!(indexInfo && indexInfo.type)) { if (isJSLiteralType(leftType)) { return anyType; } if (right.escapedText && !checkAndReportErrorForExtendingInterface(node)) { reportNonexistentProperty(right, leftType.flags & TypeFlags.TypeParameter && (leftType as TypeParameter).isThisType ? apparentType : leftType); } return errorType; } if (indexInfo.isReadonly && (isAssignmentTarget(node) || isDeleteTarget(node))) { error(node, Diagnostics.Index_signature_in_type_0_only_permits_reading, typeToString(apparentType)); } propType = indexInfo.type; } else { checkPropertyNotUsedBeforeDeclaration(prop, node, right); markPropertyAsReferenced(prop, node, left.kind === SyntaxKind.ThisKeyword); getNodeLinks(node).resolvedSymbol = prop; checkPropertyAccessibility(node, left.kind === SyntaxKind.SuperKeyword, apparentType, prop); if (assignmentKind) { if (isReferenceToReadonlyEntity(node, prop) || isReferenceThroughNamespaceImport(node)) { error(right, Diagnostics.Cannot_assign_to_0_because_it_is_a_read_only_property, idText(right)); return errorType; } } propType = getConstraintForLocation(getTypeOfSymbol(prop), node); } // Only compute control flow type if this is a property access expression that isn't an // assignment target, and the referenced property was declared as a variable, property, // accessor, or optional method. if (node.kind !== SyntaxKind.PropertyAccessExpression || assignmentKind === AssignmentKind.Definite || prop && !(prop.flags & (SymbolFlags.Variable | SymbolFlags.Property | SymbolFlags.Accessor)) && !(prop.flags & SymbolFlags.Method && propType.flags & TypeFlags.Union)) { return propType; } // If strict null checks and strict property initialization checks are enabled, if we have // a this.xxx property access, if the property is an instance property without an initializer, // and if we are in a constructor of the same class as the property declaration, assume that // the property is uninitialized at the top of the control flow. let assumeUninitialized = false; if (strictNullChecks && strictPropertyInitialization && left.kind === SyntaxKind.ThisKeyword) { const declaration = prop && prop.valueDeclaration; if (declaration && isInstancePropertyWithoutInitializer(declaration)) { const flowContainer = getControlFlowContainer(node); if (flowContainer.kind === SyntaxKind.Constructor && flowContainer.parent === declaration.parent) { assumeUninitialized = true; } } } else if (strictNullChecks && prop && prop.valueDeclaration && isPropertyAccessExpression(prop.valueDeclaration) && getAssignmentDeclarationPropertyAccessKind(prop.valueDeclaration) && getControlFlowContainer(node) === getControlFlowContainer(prop.valueDeclaration)) { assumeUninitialized = true; } const flowType = getFlowTypeOfReference(node, propType, assumeUninitialized ? getOptionalType(propType) : propType); if (assumeUninitialized && !(getFalsyFlags(propType) & TypeFlags.Undefined) && getFalsyFlags(flowType) & TypeFlags.Undefined) { error(right, Diagnostics.Property_0_is_used_before_being_assigned, symbolToString(prop!)); // TODO: GH#18217 // Return the declared type to reduce follow-on errors return propType; } return assignmentKind ? getBaseTypeOfLiteralType(flowType) : flowType; } function checkPropertyNotUsedBeforeDeclaration(prop: Symbol, node: PropertyAccessExpression | QualifiedName, right: Identifier): void { const { valueDeclaration } = prop; if (!valueDeclaration) { return; } let diagnosticMessage; const declarationName = idText(right); if (isInPropertyInitializer(node) && !isBlockScopedNameDeclaredBeforeUse(valueDeclaration, right) && !isPropertyDeclaredInAncestorClass(prop)) { diagnosticMessage = error(right, Diagnostics.Property_0_is_used_before_its_initialization, declarationName); } else if (valueDeclaration.kind === SyntaxKind.ClassDeclaration && node.parent.kind !== SyntaxKind.TypeReference && !(valueDeclaration.flags & NodeFlags.Ambient) && !isBlockScopedNameDeclaredBeforeUse(valueDeclaration, right)) { diagnosticMessage = error(right, Diagnostics.Class_0_used_before_its_declaration, declarationName); } if (diagnosticMessage) { addRelatedInfo(diagnosticMessage, createDiagnosticForNode(valueDeclaration, Diagnostics._0_is_declared_here, declarationName) ); } } function isInPropertyInitializer(node: Node): boolean { return !!findAncestor(node, node => { switch (node.kind) { case SyntaxKind.PropertyDeclaration: return true; case SyntaxKind.PropertyAssignment: case SyntaxKind.MethodDeclaration: case SyntaxKind.GetAccessor: case SyntaxKind.SetAccessor: case SyntaxKind.SpreadAssignment: case SyntaxKind.ComputedPropertyName: case SyntaxKind.TemplateSpan: case SyntaxKind.JsxExpression: case SyntaxKind.JsxAttribute: case SyntaxKind.JsxAttributes: case SyntaxKind.JsxSpreadAttribute: case SyntaxKind.JsxOpeningElement: case SyntaxKind.ExpressionWithTypeArguments: case SyntaxKind.HeritageClause: return false; default: return isExpressionNode(node) ? false : "quit"; } }); } /** * It's possible that "prop.valueDeclaration" is a local declaration, but the property was also declared in a superclass. * In that case we won't consider it used before its declaration, because it gets its value from the superclass' declaration. */ function isPropertyDeclaredInAncestorClass(prop: Symbol): boolean { if (!(prop.parent!.flags & SymbolFlags.Class)) { return false; } let classType: InterfaceType | undefined = getTypeOfSymbol(prop.parent!) as InterfaceType; while (true) { classType = classType.symbol && getSuperClass(classType) as InterfaceType | undefined; if (!classType) { return false; } const superProperty = getPropertyOfType(classType, prop.escapedName); if (superProperty && superProperty.valueDeclaration) { return true; } } } function getSuperClass(classType: InterfaceType): Type | undefined { const x = getBaseTypes(classType); if (x.length === 0) { return undefined; } return getIntersectionType(x); } function reportNonexistentProperty(propNode: Identifier, containingType: Type) { let errorInfo: DiagnosticMessageChain | undefined; let relatedInfo: Diagnostic | undefined; if (containingType.flags & TypeFlags.Union && !(containingType.flags & TypeFlags.Primitive)) { for (const subtype of (containingType as UnionType).types) { if (!getPropertyOfType(subtype, propNode.escapedText)) { errorInfo = chainDiagnosticMessages(errorInfo, Diagnostics.Property_0_does_not_exist_on_type_1, declarationNameToString(propNode), typeToString(subtype)); break; } } } if (typeHasStaticProperty(propNode.escapedText, containingType)) { errorInfo = chainDiagnosticMessages(errorInfo, Diagnostics.Property_0_is_a_static_member_of_type_1, declarationNameToString(propNode), typeToString(containingType)); } else { const promisedType = getPromisedTypeOfPromise(containingType); if (promisedType && getPropertyOfType(promisedType, propNode.escapedText)) { errorInfo = chainDiagnosticMessages(errorInfo, Diagnostics.Property_0_does_not_exist_on_type_1_Did_you_forget_to_use_await, declarationNameToString(propNode), typeToString(containingType)); } else { const suggestion = getSuggestedSymbolForNonexistentProperty(propNode, containingType); if (suggestion !== undefined) { const suggestedName = symbolName(suggestion); errorInfo = chainDiagnosticMessages(errorInfo, Diagnostics.Property_0_does_not_exist_on_type_1_Did_you_mean_2, declarationNameToString(propNode), typeToString(containingType), suggestedName); relatedInfo = suggestion.valueDeclaration && createDiagnosticForNode(suggestion.valueDeclaration, Diagnostics._0_is_declared_here, suggestedName); } else { errorInfo = chainDiagnosticMessages(errorInfo, Diagnostics.Property_0_does_not_exist_on_type_1, declarationNameToString(propNode), typeToString(containingType)); } } } const resultDiagnostic = createDiagnosticForNodeFromMessageChain(propNode, errorInfo); if (relatedInfo) { addRelatedInfo(resultDiagnostic, relatedInfo); } diagnostics.add(resultDiagnostic); } function typeHasStaticProperty(propName: __String, containingType: Type): boolean { const prop = containingType.symbol && getPropertyOfType(getTypeOfSymbol(containingType.symbol), propName); return prop !== undefined && prop.valueDeclaration && hasModifier(prop.valueDeclaration, ModifierFlags.Static); } function getSuggestedSymbolForNonexistentProperty(name: Identifier | string, containingType: Type): Symbol | undefined { return getSpellingSuggestionForName(isString(name) ? name : idText(name), getPropertiesOfType(containingType), SymbolFlags.Value); } function getSuggestionForNonexistentProperty(name: Identifier | string, containingType: Type): string | undefined { const suggestion = getSuggestedSymbolForNonexistentProperty(name, containingType); return suggestion && symbolName(suggestion); } function getSuggestedSymbolForNonexistentSymbol(location: Node | undefined, outerName: __String, meaning: SymbolFlags): Symbol | undefined { Debug.assert(outerName !== undefined, "outername should always be defined"); const result = resolveNameHelper(location, outerName, meaning, /*nameNotFoundMessage*/ undefined, outerName, /*isUse*/ false, /*excludeGlobals*/ false, (symbols, name, meaning) => { Debug.assertEqual(outerName, name, "name should equal outerName"); const symbol = getSymbol(symbols, name, meaning); // Sometimes the symbol is found when location is a return type of a function: `typeof x` and `x` is declared in the body of the function // So the table *contains* `x` but `x` isn't actually in scope. // However, resolveNameHelper will continue and call this callback again, so we'll eventually get a correct suggestion. return symbol || getSpellingSuggestionForName(unescapeLeadingUnderscores(name), arrayFrom(symbols.values()), meaning); }); return result; } function getSuggestionForNonexistentSymbol(location: Node | undefined, outerName: __String, meaning: SymbolFlags): string | undefined { const symbolResult = getSuggestedSymbolForNonexistentSymbol(location, outerName, meaning); return symbolResult && symbolName(symbolResult); } function getSuggestedSymbolForNonexistentModule(name: Identifier, targetModule: Symbol): Symbol | undefined { return targetModule.exports && getSpellingSuggestionForName(idText(name), getExportsOfModuleAsArray(targetModule), SymbolFlags.ModuleMember); } function getSuggestionForNonexistentExport(name: Identifier, targetModule: Symbol): string | undefined { const suggestion = getSuggestedSymbolForNonexistentModule(name, targetModule); return suggestion && symbolName(suggestion); } /** * Given a name and a list of symbols whose names are *not* equal to the name, return a spelling suggestion if there is one that is close enough. * Names less than length 3 only check for case-insensitive equality, not levenshtein distance. * * If there is a candidate that's the same except for case, return that. * If there is a candidate that's within one edit of the name, return that. * Otherwise, return the candidate with the smallest Levenshtein distance, * except for candidates: * * With no name * * Whose meaning doesn't match the `meaning` parameter. * * Whose length differs from the target name by more than 0.34 of the length of the name. * * Whose levenshtein distance is more than 0.4 of the length of the name * (0.4 allows 1 substitution/transposition for every 5 characters, * and 1 insertion/deletion at 3 characters) */ function getSpellingSuggestionForName(name: string, symbols: Symbol[], meaning: SymbolFlags): Symbol | undefined { return getSpellingSuggestion(name, symbols, getCandidateName); function getCandidateName(candidate: Symbol) { const candidateName = symbolName(candidate); return !startsWith(candidateName, "\"") && candidate.flags & meaning ? candidateName : undefined; } } function markPropertyAsReferenced(prop: Symbol, nodeForCheckWriteOnly: Node | undefined, isThisAccess: boolean) { if (!prop || !(prop.flags & SymbolFlags.ClassMember) || !prop.valueDeclaration || !hasModifier(prop.valueDeclaration, ModifierFlags.Private)) { return; } if (nodeForCheckWriteOnly && isWriteOnlyAccess(nodeForCheckWriteOnly) && !(prop.flags & SymbolFlags.SetAccessor && !(prop.flags & SymbolFlags.GetAccessor))) { return; } if (isThisAccess) { // Find any FunctionLikeDeclaration because those create a new 'this' binding. But this should only matter for methods (or getters/setters). const containingMethod = findAncestor(nodeForCheckWriteOnly, isFunctionLikeDeclaration); if (containingMethod && containingMethod.symbol === prop) { return; } } (getCheckFlags(prop) & CheckFlags.Instantiated ? getSymbolLinks(prop).target : prop)!.isReferenced = SymbolFlags.All; } function isValidPropertyAccess(node: PropertyAccessExpression | QualifiedName | ImportTypeNode, propertyName: __String): boolean { switch (node.kind) { case SyntaxKind.PropertyAccessExpression: return isValidPropertyAccessWithType(node, node.expression.kind === SyntaxKind.SuperKeyword, propertyName, getWidenedType(checkExpression(node.expression))); case SyntaxKind.QualifiedName: return isValidPropertyAccessWithType(node, /*isSuper*/ false, propertyName, getWidenedType(checkExpression(node.left))); case SyntaxKind.ImportType: return isValidPropertyAccessWithType(node, /*isSuper*/ false, propertyName, getTypeFromTypeNode(node)); } } function isValidPropertyAccessForCompletions(node: PropertyAccessExpression | ImportTypeNode | QualifiedName, type: Type, property: Symbol): boolean { return isValidPropertyAccessWithType(node, node.kind === SyntaxKind.PropertyAccessExpression && node.expression.kind === SyntaxKind.SuperKeyword, property.escapedName, type) && (!(property.flags & SymbolFlags.Method) || isValidMethodAccess(property, type)); } function isValidMethodAccess(method: Symbol, actualThisType: Type): boolean { const propType = getTypeOfPropertyOfType(actualThisType, method.escapedName)!; const signatures = getSignaturesOfType(getNonNullableType(propType), SignatureKind.Call); Debug.assert(signatures.length !== 0); return signatures.some(sig => { const signatureThisType = getThisTypeOfSignature(sig); return !signatureThisType || isTypeAssignableTo(actualThisType, getInstantiatedSignatureThisType(sig, signatureThisType, actualThisType)); }); } function getInstantiatedSignatureThisType(sig: Signature, signatureThisType: Type, actualThisType: Type): Type { if (!sig.typeParameters) { return signatureThisType; } const context = createInferenceContext(sig.typeParameters, sig, InferenceFlags.None); inferTypes(context.inferences, actualThisType, signatureThisType); return instantiateType(signatureThisType, createSignatureTypeMapper(sig, getInferredTypes(context))); } function isValidPropertyAccessWithType( node: PropertyAccessExpression | QualifiedName | ImportTypeNode, isSuper: boolean, propertyName: __String, type: Type): boolean { if (type === errorType || isTypeAny(type)) { return true; } const prop = getPropertyOfType(type, propertyName); return prop ? checkPropertyAccessibility(node, isSuper, type, prop) // In js files properties of unions are allowed in completion : isInJSFile(node) && (type.flags & TypeFlags.Union) !== 0 && (type).types.some(elementType => isValidPropertyAccessWithType(node, isSuper, propertyName, elementType)); } /** * Return the symbol of the for-in variable declared or referenced by the given for-in statement. */ function getForInVariableSymbol(node: ForInStatement): Symbol | undefined { const initializer = node.initializer; if (initializer.kind === SyntaxKind.VariableDeclarationList) { const variable = (initializer).declarations[0]; if (variable && !isBindingPattern(variable.name)) { return getSymbolOfNode(variable); } } else if (initializer.kind === SyntaxKind.Identifier) { return getResolvedSymbol(initializer); } return undefined; } /** * Return true if the given type is considered to have numeric property names. */ function hasNumericPropertyNames(type: Type) { return getIndexTypeOfType(type, IndexKind.Number) && !getIndexTypeOfType(type, IndexKind.String); } /** * Return true if given node is an expression consisting of an identifier (possibly parenthesized) * that references a for-in variable for an object with numeric property names. */ function isForInVariableForNumericPropertyNames(expr: Expression) { const e = skipParentheses(expr); if (e.kind === SyntaxKind.Identifier) { const symbol = getResolvedSymbol(e); if (symbol.flags & SymbolFlags.Variable) { let child: Node = expr; let node = expr.parent; while (node) { if (node.kind === SyntaxKind.ForInStatement && child === (node).statement && getForInVariableSymbol(node) === symbol && hasNumericPropertyNames(getTypeOfExpression((node).expression))) { return true; } child = node; node = node.parent; } } } return false; } function checkIndexedAccess(node: ElementAccessExpression): Type { const objectType = checkNonNullExpression(node.expression); const indexExpression = node.argumentExpression; if (!indexExpression) { const sourceFile = getSourceFileOfNode(node); if (node.parent.kind === SyntaxKind.NewExpression && (node.parent).expression === node) { const start = skipTrivia(sourceFile.text, node.expression.end); const end = node.end; grammarErrorAtPos(sourceFile, start, end - start, Diagnostics.new_T_cannot_be_used_to_create_an_array_Use_new_Array_T_instead); } else { const start = node.end - "]".length; const end = node.end; grammarErrorAtPos(sourceFile, start, end - start, Diagnostics.Expression_expected); } return errorType; } const indexType = checkExpression(indexExpression); if (objectType === errorType || objectType === silentNeverType) { return objectType; } if (isConstEnumObjectType(objectType) && indexExpression.kind !== SyntaxKind.StringLiteral) { error(indexExpression, Diagnostics.A_const_enum_member_can_only_be_accessed_using_a_string_literal); return errorType; } return checkIndexedAccessIndexType(getIndexedAccessType(objectType, isForInVariableForNumericPropertyNames(indexExpression) ? numberType : indexType, node), node); } function checkThatExpressionIsProperSymbolReference(expression: Expression, expressionType: Type, reportError: boolean): boolean { if (expressionType === errorType) { // There is already an error, so no need to report one. return false; } if (!isWellKnownSymbolSyntactically(expression)) { return false; } // Make sure the property type is the primitive symbol type if ((expressionType.flags & TypeFlags.ESSymbolLike) === 0) { if (reportError) { error(expression, Diagnostics.A_computed_property_name_of_the_form_0_must_be_of_type_symbol, getTextOfNode(expression)); } return false; } // The name is Symbol., so make sure Symbol actually resolves to the // global Symbol object const leftHandSide = (expression).expression; const leftHandSideSymbol = getResolvedSymbol(leftHandSide); if (!leftHandSideSymbol) { return false; } const globalESSymbol = getGlobalESSymbolConstructorSymbol(/*reportErrors*/ true); if (!globalESSymbol) { // Already errored when we tried to look up the symbol return false; } if (leftHandSideSymbol !== globalESSymbol) { if (reportError) { error(leftHandSide, Diagnostics.Symbol_reference_does_not_refer_to_the_global_Symbol_constructor_object); } return false; } return true; } function callLikeExpressionMayHaveTypeArguments(node: CallLikeExpression): node is CallExpression | NewExpression | TaggedTemplateExpression | JsxOpeningElement { return isCallOrNewExpression(node) || isTaggedTemplateExpression(node) || isJsxOpeningLikeElement(node); } function resolveUntypedCall(node: CallLikeExpression): Signature { if (callLikeExpressionMayHaveTypeArguments(node)) { // Check type arguments even though we will give an error that untyped calls may not accept type arguments. // This gets us diagnostics for the type arguments and marks them as referenced. forEach(node.typeArguments, checkSourceElement); } if (node.kind === SyntaxKind.TaggedTemplateExpression) { checkExpression(node.template); } else if (isJsxOpeningLikeElement(node)) { checkExpression(node.attributes); } else if (node.kind !== SyntaxKind.Decorator) { forEach((node).arguments, argument => { checkExpression(argument); }); } return anySignature; } function resolveErrorCall(node: CallLikeExpression): Signature { resolveUntypedCall(node); return unknownSignature; } // Re-order candidate signatures into the result array. Assumes the result array to be empty. // The candidate list orders groups in reverse, but within a group signatures are kept in declaration order // A nit here is that we reorder only signatures that belong to the same symbol, // so order how inherited signatures are processed is still preserved. // interface A { (x: string): void } // interface B extends A { (x: 'foo'): string } // const b: B; // b('foo') // <- here overloads should be processed as [(x:'foo'): string, (x: string): void] function reorderCandidates(signatures: ReadonlyArray, result: Signature[]): void { let lastParent: Node | undefined; let lastSymbol: Symbol | undefined; let cutoffIndex = 0; let index: number | undefined; let specializedIndex = -1; let spliceIndex: number; Debug.assert(!result.length); for (const signature of signatures) { const symbol = signature.declaration && getSymbolOfNode(signature.declaration); const parent = signature.declaration && signature.declaration.parent; if (!lastSymbol || symbol === lastSymbol) { if (lastParent && parent === lastParent) { index = index! + 1; } else { lastParent = parent; index = cutoffIndex; } } else { // current declaration belongs to a different symbol // set cutoffIndex so re-orderings in the future won't change result set from 0 to cutoffIndex index = cutoffIndex = result.length; lastParent = parent; } lastSymbol = symbol; // specialized signatures always need to be placed before non-specialized signatures regardless // of the cutoff position; see GH#1133 if (signature.hasLiteralTypes) { specializedIndex++; spliceIndex = specializedIndex; // The cutoff index always needs to be greater than or equal to the specialized signature index // in order to prevent non-specialized signatures from being added before a specialized // signature. cutoffIndex++; } else { spliceIndex = index; } result.splice(spliceIndex, 0, signature); } } function isSpreadArgument(arg: Expression | undefined): arg is Expression { return !!arg && (arg.kind === SyntaxKind.SpreadElement || arg.kind === SyntaxKind.SyntheticExpression && (arg).isSpread); } function getSpreadArgumentIndex(args: ReadonlyArray): number { return findIndex(args, isSpreadArgument); } function acceptsVoid(t: Type): boolean { return !!(t.flags & TypeFlags.Void); } function hasCorrectArity(node: CallLikeExpression, args: ReadonlyArray, signature: Signature, signatureHelpTrailingComma = false) { let argCount: number; let callIsIncomplete = false; // In incomplete call we want to be lenient when we have too few arguments let effectiveParameterCount = getParameterCount(signature); let effectiveMinimumArguments = getMinArgumentCount(signature); if (node.kind === SyntaxKind.TaggedTemplateExpression) { argCount = args.length; if (node.template.kind === SyntaxKind.TemplateExpression) { // If a tagged template expression lacks a tail literal, the call is incomplete. // Specifically, a template only can end in a TemplateTail or a Missing literal. const lastSpan = last(node.template.templateSpans); // we should always have at least one span. callIsIncomplete = nodeIsMissing(lastSpan.literal) || !!lastSpan.literal.isUnterminated; } else { // If the template didn't end in a backtick, or its beginning occurred right prior to EOF, // then this might actually turn out to be a TemplateHead in the future; // so we consider the call to be incomplete. const templateLiteral = node.template; Debug.assert(templateLiteral.kind === SyntaxKind.NoSubstitutionTemplateLiteral); callIsIncomplete = !!templateLiteral.isUnterminated; } } else if (node.kind === SyntaxKind.Decorator) { argCount = getDecoratorArgumentCount(node, signature); } else if (isJsxOpeningLikeElement(node)) { callIsIncomplete = node.attributes.end === node.end; if (callIsIncomplete) { return true; } argCount = effectiveMinimumArguments === 0 ? args.length : 1; effectiveParameterCount = args.length === 0 ? effectiveParameterCount : 1; // class may have argumentless ctor functions - still resolve ctor and compare vs props member type effectiveMinimumArguments = Math.min(effectiveMinimumArguments, 1); // sfc may specify context argument - handled by framework and not typechecked } else { if (!node.arguments) { // This only happens when we have something of the form: 'new C' Debug.assert(node.kind === SyntaxKind.NewExpression); return getMinArgumentCount(signature) === 0; } argCount = signatureHelpTrailingComma ? args.length + 1 : args.length; // If we are missing the close parenthesis, the call is incomplete. callIsIncomplete = node.arguments.end === node.end; // If a spread argument is present, check that it corresponds to a rest parameter or at least that it's in the valid range. const spreadArgIndex = getSpreadArgumentIndex(args); if (spreadArgIndex >= 0) { return spreadArgIndex >= getMinArgumentCount(signature) && (hasEffectiveRestParameter(signature) || spreadArgIndex < getParameterCount(signature)); } } // Too many arguments implies incorrect arity. if (!hasEffectiveRestParameter(signature) && argCount > effectiveParameterCount) { return false; } // If the call is incomplete, we should skip the lower bound check. // JSX signatures can have extra parameters provided by the library which we don't check if (callIsIncomplete || argCount >= effectiveMinimumArguments) { return true; } for (let i = argCount; i < effectiveMinimumArguments; i++) { const type = getTypeAtPosition(signature, i); if (filterType(type, acceptsVoid).flags & TypeFlags.Never) { return false; } } return true; } function hasCorrectTypeArgumentArity(signature: Signature, typeArguments: NodeArray | undefined) { // If the user supplied type arguments, but the number of type arguments does not match // the declared number of type parameters, the call has an incorrect arity. const numTypeParameters = length(signature.typeParameters); const minTypeArgumentCount = getMinTypeArgumentCount(signature.typeParameters); return !typeArguments || (typeArguments.length >= minTypeArgumentCount && typeArguments.length <= numTypeParameters); } // If type has a single call signature and no other members, return that signature. Otherwise, return undefined. function getSingleCallSignature(type: Type): Signature | undefined { if (type.flags & TypeFlags.Object) { const resolved = resolveStructuredTypeMembers(type); if (resolved.callSignatures.length === 1 && resolved.constructSignatures.length === 0 && resolved.properties.length === 0 && !resolved.stringIndexInfo && !resolved.numberIndexInfo) { return resolved.callSignatures[0]; } } return undefined; } // Instantiate a generic signature in the context of a non-generic signature (section 3.8.5 in TypeScript spec) function instantiateSignatureInContextOf(signature: Signature, contextualSignature: Signature, contextualMapper?: TypeMapper, compareTypes?: TypeComparer): Signature { const context = createInferenceContext(signature.typeParameters!, signature, InferenceFlags.None, compareTypes); const sourceSignature = contextualMapper ? instantiateSignature(contextualSignature, contextualMapper) : contextualSignature; forEachMatchingParameterType(sourceSignature, signature, (source, target) => { // Type parameters from outer context referenced by source type are fixed by instantiation of the source type inferTypes(context.inferences, source, target); }); if (!contextualMapper) { inferTypes(context.inferences, getReturnTypeOfSignature(contextualSignature), getReturnTypeOfSignature(signature), InferencePriority.ReturnType); } return getSignatureInstantiation(signature, getInferredTypes(context), isInJSFile(contextualSignature.declaration)); } function inferJsxTypeArguments(node: JsxOpeningLikeElement, signature: Signature, excludeArgument: ReadonlyArray | undefined, context: InferenceContext): Type[] { const paramType = getEffectiveFirstArgumentForJsxSignature(signature, node); const checkAttrType = checkExpressionWithContextualType(node.attributes, paramType, excludeArgument && excludeArgument[0] !== undefined ? identityMapper : context); inferTypes(context.inferences, checkAttrType, paramType); return getInferredTypes(context); } function inferTypeArguments(node: CallLikeExpression, signature: Signature, args: ReadonlyArray