https://github.com/Microsoft/TypeScript
Tip revision: 74f219ed1d42d99d963ba6204474b8b9a6636237 authored by TypeScript Bot on 26 March 2020, 20:56:29 UTC
🤖 Pick PR #37510 (Fix import order) into release-3.9 (#37628)
🤖 Pick PR #37510 (Fix import order) into release-3.9 (#37628)
Tip revision: 74f219e
goToDefinition.ts
/* @internal */
namespace ts.GoToDefinition {
export function getDefinitionAtPosition(program: Program, sourceFile: SourceFile, position: number): readonly DefinitionInfo[] | undefined {
const reference = getReferenceAtPosition(sourceFile, position, program);
if (reference) {
return [getDefinitionInfoForFileReference(reference.fileName, reference.file.fileName)];
}
const node = getTouchingPropertyName(sourceFile, position);
if (node === sourceFile) {
return undefined;
}
const { parent } = node;
const typeChecker = program.getTypeChecker();
// Labels
if (isJumpStatementTarget(node)) {
const label = getTargetLabel(node.parent, node.text);
return label ? [createDefinitionInfoFromName(typeChecker, label, ScriptElementKind.label, node.text, /*containerName*/ undefined!)] : undefined; // TODO: GH#18217
}
const symbol = getSymbol(node, typeChecker);
// Could not find a symbol e.g. node is string or number keyword,
// or the symbol was an internal symbol and does not have a declaration e.g. undefined symbol
if (!symbol) {
return getDefinitionInfoForIndexSignatures(node, typeChecker);
}
const calledDeclaration = tryGetSignatureDeclaration(typeChecker, node);
// Don't go to the component constructor definition for a JSX element, just go to the component definition.
if (calledDeclaration && !(isJsxOpeningLikeElement(node.parent) && isConstructorLike(calledDeclaration))) {
const sigInfo = createDefinitionFromSignatureDeclaration(typeChecker, calledDeclaration);
// For a function, if this is the original function definition, return just sigInfo.
// If this is the original constructor definition, parent is the class.
if (typeChecker.getRootSymbols(symbol).some(s => symbolMatchesSignature(s, calledDeclaration)) ||
// TODO: GH#25533 Following check shouldn't be necessary if 'require' is an alias
symbol.declarations && symbol.declarations.some(d => isVariableDeclaration(d) && !!d.initializer && isRequireCall(d.initializer, /*checkArgumentIsStringLiteralLike*/ false))) {
return [sigInfo];
}
else {
const defs = getDefinitionFromSymbol(typeChecker, symbol, node, calledDeclaration) || emptyArray;
// For a 'super()' call, put the signature first, else put the variable first.
return node.kind === SyntaxKind.SuperKeyword ? [sigInfo, ...defs] : [...defs, sigInfo];
}
}
// Because name in short-hand property assignment has two different meanings: property name and property value,
// using go-to-definition at such position should go to the variable declaration of the property value rather than
// go to the declaration of the property name (in this case stay at the same position). However, if go-to-definition
// is performed at the location of property access, we would like to go to definition of the property in the short-hand
// assignment. This case and others are handled by the following code.
if (node.parent.kind === SyntaxKind.ShorthandPropertyAssignment) {
const shorthandSymbol = typeChecker.getShorthandAssignmentValueSymbol(symbol.valueDeclaration);
return shorthandSymbol ? shorthandSymbol.declarations.map(decl => createDefinitionInfo(decl, typeChecker, shorthandSymbol, node)) : [];
}
// If the node is the name of a BindingElement within an ObjectBindingPattern instead of just returning the
// declaration the symbol (which is itself), we should try to get to the original type of the ObjectBindingPattern
// and return the property declaration for the referenced property.
// For example:
// import('./foo').then(({ b/*goto*/ar }) => undefined); => should get use to the declaration in file "./foo"
//
// function bar<T>(onfulfilled: (value: T) => void) { //....}
// interface Test {
// pr/*destination*/op1: number
// }
// bar<Test>(({pr/*goto*/op1})=>{});
if (isPropertyName(node) && isBindingElement(parent) && isObjectBindingPattern(parent.parent) &&
(node === (parent.propertyName || parent.name))) {
const name = getNameFromPropertyName(node);
const type = typeChecker.getTypeAtLocation(parent.parent);
return name === undefined ? emptyArray : flatMap(type.isUnion() ? type.types : [type], t => {
const prop = t.getProperty(name);
return prop && getDefinitionFromSymbol(typeChecker, prop, node);
});
}
// If the current location we want to find its definition is in an object literal, try to get the contextual type for the
// object literal, lookup the property symbol in the contextual type, and use this for goto-definition.
// For example
// interface Props{
// /*first*/prop1: number
// prop2: boolean
// }
// function Foo(arg: Props) {}
// Foo( { pr/*1*/op1: 10, prop2: true })
const element = getContainingObjectLiteralElement(node);
if (element) {
const contextualType = element && typeChecker.getContextualType(element.parent);
if (contextualType) {
return flatMap(getPropertySymbolsFromContextualType(element, typeChecker, contextualType, /*unionSymbolOk*/ false), propertySymbol =>
getDefinitionFromSymbol(typeChecker, propertySymbol, node));
}
}
return getDefinitionFromSymbol(typeChecker, symbol, node);
}
/**
* True if we should not add definitions for both the signature symbol and the definition symbol.
* True for `const |f = |() => 0`, false for `function |f() {} const |g = f;`.
*/
function symbolMatchesSignature(s: Symbol, calledDeclaration: SignatureDeclaration) {
return s === calledDeclaration.symbol || s === calledDeclaration.symbol.parent ||
!isCallLikeExpression(calledDeclaration.parent) && s === calledDeclaration.parent.symbol;
}
export function getReferenceAtPosition(sourceFile: SourceFile, position: number, program: Program): { fileName: string, file: SourceFile } | undefined {
const referencePath = findReferenceInPosition(sourceFile.referencedFiles, position);
if (referencePath) {
const file = program.getSourceFileFromReference(sourceFile, referencePath);
return file && { fileName: referencePath.fileName, file };
}
const typeReferenceDirective = findReferenceInPosition(sourceFile.typeReferenceDirectives, position);
if (typeReferenceDirective) {
const reference = program.getResolvedTypeReferenceDirectives().get(typeReferenceDirective.fileName);
const file = reference && program.getSourceFile(reference.resolvedFileName!); // TODO:GH#18217
return file && { fileName: typeReferenceDirective.fileName, file };
}
const libReferenceDirective = findReferenceInPosition(sourceFile.libReferenceDirectives, position);
if (libReferenceDirective) {
const file = program.getLibFileFromReference(libReferenceDirective);
return file && { fileName: libReferenceDirective.fileName, file };
}
return undefined;
}
/// Goto type
export function getTypeDefinitionAtPosition(typeChecker: TypeChecker, sourceFile: SourceFile, position: number): readonly DefinitionInfo[] | undefined {
const node = getTouchingPropertyName(sourceFile, position);
if (node === sourceFile) {
return undefined;
}
const symbol = typeChecker.getSymbolAtLocation(node);
if (!symbol) return undefined;
const typeAtLocation = typeChecker.getTypeOfSymbolAtLocation(symbol, node);
const returnType = tryGetReturnTypeOfFunction(symbol, typeAtLocation, typeChecker);
const fromReturnType = returnType && definitionFromType(returnType, typeChecker, node);
// If a function returns 'void' or some other type with no definition, just return the function definition.
return fromReturnType && fromReturnType.length !== 0 ? fromReturnType : definitionFromType(typeAtLocation, typeChecker, node);
}
function definitionFromType(type: Type, checker: TypeChecker, node: Node): readonly DefinitionInfo[] {
return flatMap(type.isUnion() && !(type.flags & TypeFlags.Enum) ? type.types : [type], t =>
t.symbol && getDefinitionFromSymbol(checker, t.symbol, node));
}
function tryGetReturnTypeOfFunction(symbol: Symbol, type: Type, checker: TypeChecker): Type | undefined {
// If the type is just a function's inferred type,
// go-to-type should go to the return type instead, since go-to-definition takes you to the function anyway.
if (type.symbol === symbol ||
// At `const f = () => {}`, the symbol is `f` and the type symbol is at `() => {}`
symbol.valueDeclaration && type.symbol && isVariableDeclaration(symbol.valueDeclaration) && symbol.valueDeclaration.initializer === type.symbol.valueDeclaration as Node) {
const sigs = type.getCallSignatures();
if (sigs.length === 1) return checker.getReturnTypeOfSignature(first(sigs));
}
return undefined;
}
export function getDefinitionAndBoundSpan(program: Program, sourceFile: SourceFile, position: number): DefinitionInfoAndBoundSpan | undefined {
const definitions = getDefinitionAtPosition(program, sourceFile, position);
if (!definitions || definitions.length === 0) {
return undefined;
}
// Check if position is on triple slash reference.
const comment = findReferenceInPosition(sourceFile.referencedFiles, position) ||
findReferenceInPosition(sourceFile.typeReferenceDirectives, position) ||
findReferenceInPosition(sourceFile.libReferenceDirectives, position);
if (comment) {
return { definitions, textSpan: createTextSpanFromRange(comment) };
}
const node = getTouchingPropertyName(sourceFile, position);
const textSpan = createTextSpan(node.getStart(), node.getWidth());
return { definitions, textSpan };
}
// At 'x.foo', see if the type of 'x' has an index signature, and if so find its declarations.
function getDefinitionInfoForIndexSignatures(node: Node, checker: TypeChecker): DefinitionInfo[] | undefined {
if (!isPropertyAccessExpression(node.parent) || node.parent.name !== node) return;
const type = checker.getTypeAtLocation(node.parent.expression);
return mapDefined(type.isUnionOrIntersection() ? type.types : [type], nonUnionType => {
const info = checker.getIndexInfoOfType(nonUnionType, IndexKind.String);
return info && info.declaration && createDefinitionFromSignatureDeclaration(checker, info.declaration);
});
}
function getSymbol(node: Node, checker: TypeChecker): Symbol | undefined {
const symbol = checker.getSymbolAtLocation(node);
// If this is an alias, and the request came at the declaration location
// get the aliased symbol instead. This allows for goto def on an import e.g.
// import {A, B} from "mod";
// to jump to the implementation directly.
if (symbol && symbol.flags & SymbolFlags.Alias && shouldSkipAlias(node, symbol.declarations[0])) {
const aliased = checker.getAliasedSymbol(symbol);
if (aliased.declarations) {
return aliased;
}
}
if (symbol && isInJSFile(node)) {
const requireCall = forEach(symbol.declarations, d => isVariableDeclaration(d) && !!d.initializer && isRequireCall(d.initializer, /*checkArgumentIsStringLiteralLike*/ true) ? d.initializer : undefined);
if (requireCall) {
const moduleSymbol = checker.getSymbolAtLocation(requireCall.arguments[0]);
if (moduleSymbol) {
return checker.resolveExternalModuleSymbol(moduleSymbol);
}
}
}
return symbol;
}
// Go to the original declaration for cases:
//
// (1) when the aliased symbol was declared in the location(parent).
// (2) when the aliased symbol is originating from an import.
//
function shouldSkipAlias(node: Node, declaration: Node): boolean {
if (node.kind !== SyntaxKind.Identifier) {
return false;
}
if (node.parent === declaration) {
return true;
}
switch (declaration.kind) {
case SyntaxKind.ImportClause:
case SyntaxKind.ImportEqualsDeclaration:
return true;
case SyntaxKind.ImportSpecifier:
return declaration.parent.kind === SyntaxKind.NamedImports;
default:
return false;
}
}
function getDefinitionFromSymbol(typeChecker: TypeChecker, symbol: Symbol, node: Node, declarationNode?: Node): DefinitionInfo[] | undefined {
// There are cases when you extend a function by adding properties to it afterwards,
// we want to strip those extra properties.
// For deduping purposes, we also want to exclude any declarationNodes if provided.
const filteredDeclarations = filter(symbol.declarations, d => d !== declarationNode && (!isAssignmentDeclaration(d) || d === symbol.valueDeclaration)) || undefined;
return getConstructSignatureDefinition() || getCallSignatureDefinition() || map(filteredDeclarations, declaration => createDefinitionInfo(declaration, typeChecker, symbol, node));
function getConstructSignatureDefinition(): DefinitionInfo[] | undefined {
// Applicable only if we are in a new expression, or we are on a constructor declaration
// and in either case the symbol has a construct signature definition, i.e. class
if (symbol.flags & SymbolFlags.Class && !(symbol.flags & (SymbolFlags.Function | SymbolFlags.Variable)) && (isNewExpressionTarget(node) || node.kind === SyntaxKind.ConstructorKeyword)) {
const cls = find(filteredDeclarations, isClassLike) || Debug.fail("Expected declaration to have at least one class-like declaration");
return getSignatureDefinition(cls.members, /*selectConstructors*/ true);
}
}
function getCallSignatureDefinition(): DefinitionInfo[] | undefined {
return isCallOrNewExpressionTarget(node) || isNameOfFunctionDeclaration(node)
? getSignatureDefinition(filteredDeclarations, /*selectConstructors*/ false)
: undefined;
}
function getSignatureDefinition(signatureDeclarations: readonly Declaration[] | undefined, selectConstructors: boolean): DefinitionInfo[] | undefined {
if (!signatureDeclarations) {
return undefined;
}
const declarations = signatureDeclarations.filter(selectConstructors ? isConstructorDeclaration : isFunctionLike);
const declarationsWithBody = declarations.filter(d => !!(<FunctionLikeDeclaration>d).body);
// declarations defined on the global scope can be defined on multiple files. Get all of them.
return declarations.length
? declarationsWithBody.length !== 0
? declarationsWithBody.map(x => createDefinitionInfo(x, typeChecker, symbol, node))
: [createDefinitionInfo(last(declarations), typeChecker, symbol, node)]
: undefined;
}
}
/** Creates a DefinitionInfo from a Declaration, using the declaration's name if possible. */
function createDefinitionInfo(declaration: Declaration, checker: TypeChecker, symbol: Symbol, node: Node): DefinitionInfo {
const symbolName = checker.symbolToString(symbol); // Do not get scoped name, just the name of the symbol
const symbolKind = SymbolDisplay.getSymbolKind(checker, symbol, node);
const containerName = symbol.parent ? checker.symbolToString(symbol.parent, node) : "";
return createDefinitionInfoFromName(checker, declaration, symbolKind, symbolName, containerName);
}
/** Creates a DefinitionInfo directly from the name of a declaration. */
function createDefinitionInfoFromName(checker: TypeChecker, declaration: Declaration, symbolKind: ScriptElementKind, symbolName: string, containerName: string): DefinitionInfo {
const name = getNameOfDeclaration(declaration) || declaration;
const sourceFile = name.getSourceFile();
const textSpan = createTextSpanFromNode(name, sourceFile);
return {
fileName: sourceFile.fileName,
textSpan,
kind: symbolKind,
name: symbolName,
containerKind: undefined!, // TODO: GH#18217
containerName,
...FindAllReferences.toContextSpan(
textSpan,
sourceFile,
FindAllReferences.getContextNode(declaration)
),
isLocal: !checker.isDeclarationVisible(declaration)
};
}
function createDefinitionFromSignatureDeclaration(typeChecker: TypeChecker, decl: SignatureDeclaration): DefinitionInfo {
return createDefinitionInfo(decl, typeChecker, decl.symbol, decl);
}
export function findReferenceInPosition(refs: readonly FileReference[], pos: number): FileReference | undefined {
return find(refs, ref => textRangeContainsPositionInclusive(ref, pos));
}
function getDefinitionInfoForFileReference(name: string, targetFileName: string): DefinitionInfo {
return {
fileName: targetFileName,
textSpan: createTextSpanFromBounds(0, 0),
kind: ScriptElementKind.scriptElement,
name,
containerName: undefined!,
containerKind: undefined!, // TODO: GH#18217
};
}
/** Returns a CallLikeExpression where `node` is the target being invoked. */
function getAncestorCallLikeExpression(node: Node): CallLikeExpression | undefined {
const target = climbPastManyPropertyAccesses(node);
const callLike = target.parent;
return callLike && isCallLikeExpression(callLike) && getInvokedExpression(callLike) === target ? callLike : undefined;
}
function climbPastManyPropertyAccesses(node: Node): Node {
return isRightSideOfPropertyAccess(node) ? climbPastManyPropertyAccesses(node.parent) : node;
}
function tryGetSignatureDeclaration(typeChecker: TypeChecker, node: Node): SignatureDeclaration | undefined {
const callLike = getAncestorCallLikeExpression(node);
const signature = callLike && typeChecker.getResolvedSignature(callLike);
// Don't go to a function type, go to the value having that type.
return tryCast(signature && signature.declaration, (d): d is SignatureDeclaration => isFunctionLike(d) && !isFunctionTypeNode(d));
}
function isConstructorLike(node: Node): boolean {
switch (node.kind) {
case SyntaxKind.Constructor:
case SyntaxKind.ConstructorType:
case SyntaxKind.ConstructSignature:
return true;
default:
return false;
}
}
}