/* @internal */ namespace ts.NavigationBar { /** * Matches all whitespace characters in a string. Eg: * * "app. * * onactivated" * * matches because of the newline, whereas * * "app.onactivated" * * does not match. */ const whiteSpaceRegex = /\s+/g; /** * Maximum amount of characters to return * The amount was chosen arbitrarily. */ const maxLength = 150; // Keep sourceFile handy so we don't have to search for it every time we need to call `getText`. let curCancellationToken: CancellationToken; let curSourceFile: SourceFile; /** * For performance, we keep navigation bar parents on a stack rather than passing them through each recursion. * `parent` is the current parent and is *not* stored in parentsStack. * `startNode` sets a new parent and `endNode` returns to the previous parent. */ let parentsStack: NavigationBarNode[] = []; let parent: NavigationBarNode; const trackedEs5ClassesStack: (ESMap | undefined)[] = []; let trackedEs5Classes: ESMap | undefined; // NavigationBarItem requires an array, but will not mutate it, so just give it this for performance. let emptyChildItemArray: NavigationBarItem[] = []; /** * Represents a navigation bar item and its children. * The returned NavigationBarItem is more complicated and doesn't include 'parent', so we use these to do work before converting. */ interface NavigationBarNode { node: Node; name: DeclarationName | undefined; additionalNodes: Node[] | undefined; parent: NavigationBarNode | undefined; // Present for all but root node children: NavigationBarNode[] | undefined; indent: number; // # of parents } export function getNavigationBarItems(sourceFile: SourceFile, cancellationToken: CancellationToken): NavigationBarItem[] { curCancellationToken = cancellationToken; curSourceFile = sourceFile; try { return map(primaryNavBarMenuItems(rootNavigationBarNode(sourceFile)), convertToPrimaryNavBarMenuItem); } finally { reset(); } } export function getNavigationTree(sourceFile: SourceFile, cancellationToken: CancellationToken): NavigationTree { curCancellationToken = cancellationToken; curSourceFile = sourceFile; try { return convertToTree(rootNavigationBarNode(sourceFile)); } finally { reset(); } } function reset() { curSourceFile = undefined!; curCancellationToken = undefined!; parentsStack = []; parent = undefined!; emptyChildItemArray = []; } function nodeText(node: Node): string { return cleanText(node.getText(curSourceFile)); } function navigationBarNodeKind(n: NavigationBarNode): SyntaxKind { return n.node.kind; } function pushChild(parent: NavigationBarNode, child: NavigationBarNode): void { if (parent.children) { parent.children.push(child); } else { parent.children = [child]; } } function rootNavigationBarNode(sourceFile: SourceFile): NavigationBarNode { Debug.assert(!parentsStack.length); const root: NavigationBarNode = { node: sourceFile, name: undefined, additionalNodes: undefined, parent: undefined, children: undefined, indent: 0 }; parent = root; for (const statement of sourceFile.statements) { addChildrenRecursively(statement); } endNode(); Debug.assert(!parent && !parentsStack.length); return root; } function addLeafNode(node: Node, name?: DeclarationName): void { pushChild(parent, emptyNavigationBarNode(node, name)); } function emptyNavigationBarNode(node: Node, name?: DeclarationName): NavigationBarNode { return { node, name: name || (isDeclaration(node) || isExpression(node) ? getNameOfDeclaration(node) : undefined), additionalNodes: undefined, parent, children: undefined, indent: parent.indent + 1 }; } function addTrackedEs5Class(name: string) { if (!trackedEs5Classes) { trackedEs5Classes = new Map(); } trackedEs5Classes.set(name, true); } function endNestedNodes(depth: number): void { for (let i = 0; i < depth; i++) endNode(); } function startNestedNodes(targetNode: Node, entityName: BindableStaticNameExpression) { const names: (PropertyNameLiteral | WellKnownSymbolExpression)[] = []; while (!isPropertyNameLiteral(entityName)) { const name = getNameOrArgument(entityName); const nameText = getElementOrPropertyAccessName(entityName); entityName = entityName.expression; if (nameText === "prototype" || isPrivateIdentifier(name)) continue; names.push(name); } names.push(entityName); for (let i = names.length - 1; i > 0; i--) { const name = names[i]; startNode(targetNode, name); } return [names.length - 1, names[0]] as const; } /** * Add a new level of NavigationBarNodes. * This pushes to the stack, so you must call `endNode` when you are done adding to this node. */ function startNode(node: Node, name?: DeclarationName): void { const navNode: NavigationBarNode = emptyNavigationBarNode(node, name); pushChild(parent, navNode); // Save the old parent parentsStack.push(parent); trackedEs5ClassesStack.push(trackedEs5Classes); trackedEs5Classes = undefined; parent = navNode; } /** Call after calling `startNode` and adding children to it. */ function endNode(): void { if (parent.children) { mergeChildren(parent.children, parent); sortChildren(parent.children); } parent = parentsStack.pop()!; trackedEs5Classes = trackedEs5ClassesStack.pop(); } function addNodeWithRecursiveChild(node: Node, child: Node | undefined, name?: DeclarationName): void { startNode(node, name); addChildrenRecursively(child); endNode(); } function addNodeWithRecursiveInitializer(node: VariableDeclaration | PropertyAssignment | BindingElement | PropertyDeclaration): void { if (node.initializer && isFunctionOrClassExpression(node.initializer)) { startNode(node); forEachChild(node.initializer, addChildrenRecursively); endNode(); } else { addNodeWithRecursiveChild(node, node.initializer); } } /** Look for navigation bar items in node's subtree, adding them to the current `parent`. */ function addChildrenRecursively(node: Node | undefined): void { curCancellationToken.throwIfCancellationRequested(); if (!node || isToken(node)) { return; } switch (node.kind) { case SyntaxKind.Constructor: // Get parameter properties, and treat them as being on the *same* level as the constructor, not under it. const ctr = node; addNodeWithRecursiveChild(ctr, ctr.body); // Parameter properties are children of the class, not the constructor. for (const param of ctr.parameters) { if (isParameterPropertyDeclaration(param, ctr)) { addLeafNode(param); } } break; case SyntaxKind.MethodDeclaration: case SyntaxKind.GetAccessor: case SyntaxKind.SetAccessor: case SyntaxKind.MethodSignature: if (!hasDynamicName((node))) { addNodeWithRecursiveChild(node, (node).body); } break; case SyntaxKind.PropertyDeclaration: if (!hasDynamicName(node)) { addNodeWithRecursiveInitializer(node); } break; case SyntaxKind.PropertySignature: if (!hasDynamicName(node)) { addLeafNode(node); } break; case SyntaxKind.ImportClause: const importClause = node; // Handle default import case e.g.: // import d from "mod"; if (importClause.name) { addLeafNode(importClause.name); } // Handle named bindings in imports e.g.: // import * as NS from "mod"; // import {a, b as B} from "mod"; const { namedBindings } = importClause; if (namedBindings) { if (namedBindings.kind === SyntaxKind.NamespaceImport) { addLeafNode(namedBindings); } else { for (const element of namedBindings.elements) { addLeafNode(element); } } } break; case SyntaxKind.ShorthandPropertyAssignment: addNodeWithRecursiveChild(node, (node).name); break; case SyntaxKind.SpreadAssignment: const { expression } = node; // Use the expression as the name of the SpreadAssignment, otherwise show as . isIdentifier(expression) ? addLeafNode(node, expression) : addLeafNode(node); break; case SyntaxKind.BindingElement: case SyntaxKind.PropertyAssignment: case SyntaxKind.VariableDeclaration: { const child = node; if (isBindingPattern(child.name)) { addChildrenRecursively(child.name); } else { addNodeWithRecursiveInitializer(child); } break; } case SyntaxKind.FunctionDeclaration: const nameNode = (node).name; // If we see a function declaration track as a possible ES5 class if (nameNode && isIdentifier(nameNode)) { addTrackedEs5Class(nameNode.text); } addNodeWithRecursiveChild(node, (node).body); break; case SyntaxKind.ArrowFunction: case SyntaxKind.FunctionExpression: addNodeWithRecursiveChild(node, (node).body); break; case SyntaxKind.EnumDeclaration: startNode(node); for (const member of (node).members) { if (!isComputedProperty(member)) { addLeafNode(member); } } endNode(); break; case SyntaxKind.ClassDeclaration: case SyntaxKind.ClassExpression: case SyntaxKind.StructDeclaration: case SyntaxKind.InterfaceDeclaration: startNode(node); for (const member of (node).members) { addChildrenRecursively(member); } endNode(); break; case SyntaxKind.ModuleDeclaration: addNodeWithRecursiveChild(node, getInteriorModule(node).body); break; case SyntaxKind.ExportAssignment: { const expression = (node).expression; const child = isObjectLiteralExpression(expression) || isCallExpression(expression) ? expression : isArrowFunction(expression) || isFunctionExpression(expression) ? expression.body : undefined; if (child) { startNode(node); addChildrenRecursively(child); endNode(); } else { addLeafNode(node); } break; } case SyntaxKind.ExportSpecifier: case SyntaxKind.ImportEqualsDeclaration: case SyntaxKind.IndexSignature: case SyntaxKind.CallSignature: case SyntaxKind.ConstructSignature: case SyntaxKind.TypeAliasDeclaration: addLeafNode(node); break; case SyntaxKind.CallExpression: case SyntaxKind.BinaryExpression: { const special = getAssignmentDeclarationKind(node as BinaryExpression); switch (special) { case AssignmentDeclarationKind.ExportsProperty: case AssignmentDeclarationKind.ModuleExports: addNodeWithRecursiveChild(node, (node as BinaryExpression).right); return; case AssignmentDeclarationKind.Prototype: case AssignmentDeclarationKind.PrototypeProperty: { const binaryExpression = (node as BinaryExpression); const assignmentTarget = binaryExpression.left as PropertyAccessExpression; const prototypeAccess = special === AssignmentDeclarationKind.PrototypeProperty ? assignmentTarget.expression as PropertyAccessExpression : assignmentTarget; let depth = 0; let className: PropertyNameLiteral | WellKnownSymbolExpression; // If we see a prototype assignment, start tracking the target as a class // This is only done for simple classes not nested assignments. if (isIdentifier(prototypeAccess.expression)) { addTrackedEs5Class(prototypeAccess.expression.text); className = prototypeAccess.expression; } else { [depth, className] = startNestedNodes(binaryExpression, prototypeAccess.expression as EntityNameExpression); } if (special === AssignmentDeclarationKind.Prototype) { if (isObjectLiteralExpression(binaryExpression.right)) { if (binaryExpression.right.properties.length > 0) { startNode(binaryExpression, className); forEachChild(binaryExpression.right, addChildrenRecursively); endNode(); } } } else if (isFunctionExpression(binaryExpression.right) || isArrowFunction(binaryExpression.right)) { addNodeWithRecursiveChild(node, binaryExpression.right, className); } else { startNode(binaryExpression, className); addNodeWithRecursiveChild(node, binaryExpression.right, assignmentTarget.name); endNode(); } endNestedNodes(depth); return; } case AssignmentDeclarationKind.ObjectDefinePropertyValue: case AssignmentDeclarationKind.ObjectDefinePrototypeProperty: { const defineCall = node as BindableObjectDefinePropertyCall; const className = special === AssignmentDeclarationKind.ObjectDefinePropertyValue ? defineCall.arguments[0] : (defineCall.arguments[0] as PropertyAccessExpression).expression as EntityNameExpression; const memberName = defineCall.arguments[1]; const [depth, classNameIdentifier] = startNestedNodes(node, className); startNode(node, classNameIdentifier); startNode(node, setTextRange(factory.createIdentifier(memberName.text), memberName)); addChildrenRecursively((node as CallExpression).arguments[2]); endNode(); endNode(); endNestedNodes(depth); return; } case AssignmentDeclarationKind.Property: { const binaryExpression = (node as BinaryExpression); const assignmentTarget = binaryExpression.left as PropertyAccessExpression | BindableElementAccessExpression; const targetFunction = assignmentTarget.expression; if (isIdentifier(targetFunction) && getElementOrPropertyAccessName(assignmentTarget) !== "prototype" && trackedEs5Classes && trackedEs5Classes.has(targetFunction.text)) { if (isFunctionExpression(binaryExpression.right) || isArrowFunction(binaryExpression.right)) { addNodeWithRecursiveChild(node, binaryExpression.right, targetFunction); } else if (isBindableStaticAccessExpression(assignmentTarget)) { startNode(binaryExpression, targetFunction); addNodeWithRecursiveChild(binaryExpression.left, binaryExpression.right, getNameOrArgument(assignmentTarget)); endNode(); } return; } break; } case AssignmentDeclarationKind.ThisProperty: case AssignmentDeclarationKind.None: case AssignmentDeclarationKind.ObjectDefinePropertyExports: break; default: Debug.assertNever(special); } } // falls through default: if (hasJSDocNodes(node)) { forEach(node.jsDoc, jsDoc => { forEach(jsDoc.tags, tag => { if (isJSDocTypeAlias(tag)) { addLeafNode(tag); } }); }); } forEachChild(node, addChildrenRecursively); } } /** Merge declarations of the same kind. */ function mergeChildren(children: NavigationBarNode[], node: NavigationBarNode): void { const nameToItems = new Map(); filterMutate(children, (child, index) => { const declName = child.name || getNameOfDeclaration(child.node); const name = declName && nodeText(declName); if (!name) { // Anonymous items are never merged. return true; } const itemsWithSameName = nameToItems.get(name); if (!itemsWithSameName) { nameToItems.set(name, child); return true; } if (itemsWithSameName instanceof Array) { for (const itemWithSameName of itemsWithSameName) { if (tryMerge(itemWithSameName, child, index, node)) { return false; } } itemsWithSameName.push(child); return true; } else { const itemWithSameName = itemsWithSameName; if (tryMerge(itemWithSameName, child, index, node)) { return false; } nameToItems.set(name, [itemWithSameName, child]); return true; } }); } const isEs5ClassMember: Record = { [AssignmentDeclarationKind.Property]: true, [AssignmentDeclarationKind.PrototypeProperty]: true, [AssignmentDeclarationKind.ObjectDefinePropertyValue]: true, [AssignmentDeclarationKind.ObjectDefinePrototypeProperty]: true, [AssignmentDeclarationKind.None]: false, [AssignmentDeclarationKind.ExportsProperty]: false, [AssignmentDeclarationKind.ModuleExports]: false, [AssignmentDeclarationKind.ObjectDefinePropertyExports]: false, [AssignmentDeclarationKind.Prototype]: true, [AssignmentDeclarationKind.ThisProperty]: false, }; function tryMergeEs5Class(a: NavigationBarNode, b: NavigationBarNode, bIndex: number, parent: NavigationBarNode): boolean | undefined { function isPossibleConstructor(node: Node) { return isFunctionExpression(node) || isFunctionDeclaration(node) || isVariableDeclaration(node); } const bAssignmentDeclarationKind = isBinaryExpression(b.node) || isCallExpression(b.node) ? getAssignmentDeclarationKind(b.node) : AssignmentDeclarationKind.None; const aAssignmentDeclarationKind = isBinaryExpression(a.node) || isCallExpression(a.node) ? getAssignmentDeclarationKind(a.node) : AssignmentDeclarationKind.None; // We treat this as an es5 class and merge the nodes in in one of several cases if ((isEs5ClassMember[bAssignmentDeclarationKind] && isEs5ClassMember[aAssignmentDeclarationKind]) // merge two class elements || (isPossibleConstructor(a.node) && isEs5ClassMember[bAssignmentDeclarationKind]) // ctor function & member || (isPossibleConstructor(b.node) && isEs5ClassMember[aAssignmentDeclarationKind]) // member & ctor function || (isClassDeclaration(a.node) && isSynthesized(a.node) && isEs5ClassMember[bAssignmentDeclarationKind]) // class (generated) & member || (isClassDeclaration(b.node) && isEs5ClassMember[aAssignmentDeclarationKind]) // member & class (generated) || (isClassDeclaration(a.node) && isSynthesized(a.node) && isPossibleConstructor(b.node)) // class (generated) & ctor || (isClassDeclaration(b.node) && isPossibleConstructor(a.node) && isSynthesized(a.node)) // ctor & class (generated) ) { let lastANode = a.additionalNodes && lastOrUndefined(a.additionalNodes) || a.node; if ((!isClassDeclaration(a.node) && !isClassDeclaration(b.node)) // If neither outline node is a class || isPossibleConstructor(a.node) || isPossibleConstructor(b.node) // If either function is a constructor function ) { const ctorFunction = isPossibleConstructor(a.node) ? a.node : isPossibleConstructor(b.node) ? b.node : undefined; if (ctorFunction !== undefined) { const ctorNode = setTextRange( factory.createConstructorDeclaration(/* decorators */ undefined, /* modifiers */ undefined, [], /* body */ undefined), ctorFunction); const ctor = emptyNavigationBarNode(ctorNode); ctor.indent = a.indent + 1; ctor.children = a.node === ctorFunction ? a.children : b.children; a.children = a.node === ctorFunction ? concatenate([ctor], b.children || [b]) : concatenate(a.children || [{ ...a }], [ctor]); } else { if (a.children || b.children) { a.children = concatenate(a.children || [{ ...a }], b.children || [b]); if (a.children) { mergeChildren(a.children, a); sortChildren(a.children); } } } lastANode = a.node = setTextRange(factory.createClassDeclaration( /* decorators */ undefined, /* modifiers */ undefined, a.name as Identifier || factory.createIdentifier("__class__"), /* typeParameters */ undefined, /* heritageClauses */ undefined, [] ), a.node); } else { a.children = concatenate(a.children, b.children); if (a.children) { mergeChildren(a.children, a); } } const bNode = b.node; // We merge if the outline node previous to b (bIndex - 1) is already part of the current class // We do this so that statements between class members that do not generate outline nodes do not split up the class outline: // Ex This should produce one outline node C: // function C() {}; a = 1; C.prototype.m = function () {} // Ex This will produce 3 outline nodes: C, a, C // function C() {}; let a = 1; C.prototype.m = function () {} if (parent.children![bIndex - 1].node.end === lastANode.end) { setTextRange(lastANode, { pos: lastANode.pos, end: bNode.end }); } else { if (!a.additionalNodes) a.additionalNodes = []; a.additionalNodes.push(setTextRange(factory.createClassDeclaration( /* decorators */ undefined, /* modifiers */ undefined, a.name as Identifier || factory.createIdentifier("__class__"), /* typeParameters */ undefined, /* heritageClauses */ undefined, [] ), b.node)); } return true; } return bAssignmentDeclarationKind === AssignmentDeclarationKind.None ? false : true; } function tryMerge(a: NavigationBarNode, b: NavigationBarNode, bIndex: number, parent: NavigationBarNode): boolean { // const v = false as boolean; if (tryMergeEs5Class(a, b, bIndex, parent)) { return true; } if (shouldReallyMerge(a.node, b.node, parent)) { merge(a, b); return true; } return false; } /** a and b have the same name, but they may not be mergeable. */ function shouldReallyMerge(a: Node, b: Node, parent: NavigationBarNode): boolean { if (a.kind !== b.kind || a.parent !== b.parent && !(isOwnChild(a, parent) && isOwnChild(b, parent))) { return false; } switch (a.kind) { case SyntaxKind.PropertyDeclaration: case SyntaxKind.MethodDeclaration: case SyntaxKind.GetAccessor: case SyntaxKind.SetAccessor: return hasSyntacticModifier(a, ModifierFlags.Static) === hasSyntacticModifier(b, ModifierFlags.Static); case SyntaxKind.ModuleDeclaration: return areSameModule(a, b); default: return true; } } function isSynthesized(node: Node) { return !!(node.flags & NodeFlags.Synthesized); } // We want to merge own children like `I` in in `module A { interface I {} } module A { interface I {} }` // We don't want to merge unrelated children like `m` in `const o = { a: { m() {} }, b: { m() {} } };` function isOwnChild(n: Node, parent: NavigationBarNode): boolean { const par = isModuleBlock(n.parent) ? n.parent.parent : n.parent; return par === parent.node || contains(parent.additionalNodes, par); } // We use 1 NavNode to represent 'A.B.C', but there are multiple source nodes. // Only merge module nodes that have the same chain. Don't merge 'A.B.C' with 'A'! function areSameModule(a: ModuleDeclaration, b: ModuleDeclaration): boolean { // TODO: GH#18217 return a.body!.kind === b.body!.kind && (a.body!.kind !== SyntaxKind.ModuleDeclaration || areSameModule(a.body, b.body)); } /** Merge source into target. Source should be thrown away after this is called. */ function merge(target: NavigationBarNode, source: NavigationBarNode): void { target.additionalNodes = target.additionalNodes || []; target.additionalNodes.push(source.node); if (source.additionalNodes) { target.additionalNodes.push(...source.additionalNodes); } target.children = concatenate(target.children, source.children); if (target.children) { mergeChildren(target.children, target); sortChildren(target.children); } } /** Recursively ensure that each NavNode's children are in sorted order. */ function sortChildren(children: NavigationBarNode[]): void { children.sort(compareChildren); } function compareChildren(child1: NavigationBarNode, child2: NavigationBarNode) { return compareStringsCaseSensitiveUI(tryGetName(child1.node)!, tryGetName(child2.node)!) // TODO: GH#18217 || compareValues(navigationBarNodeKind(child1), navigationBarNodeKind(child2)); } /** * This differs from getItemName because this is just used for sorting. * We only sort nodes by name that have a more-or-less "direct" name, as opposed to `new()` and the like. * So `new()` can still come before an `aardvark` method. */ function tryGetName(node: Node): string | undefined { if (node.kind === SyntaxKind.ModuleDeclaration) { return getModuleName(node); } const declName = getNameOfDeclaration(node); if (declName && isPropertyName(declName)) { const propertyName = getPropertyNameForPropertyNameNode(declName); return propertyName && unescapeLeadingUnderscores(propertyName); } switch (node.kind) { case SyntaxKind.FunctionExpression: case SyntaxKind.ArrowFunction: case SyntaxKind.ClassExpression: return getFunctionOrClassName(node); default: return undefined; } } function getItemName(node: Node, name: Node | undefined): string { if (node.kind === SyntaxKind.ModuleDeclaration) { return cleanText(getModuleName(node)); } if (name) { const text = isIdentifier(name) ? name.text : isElementAccessExpression(name) ? `[${nodeText(name.argumentExpression)}]` : nodeText(name); if (text.length > 0) { return cleanText(text); } } switch (node.kind) { case SyntaxKind.SourceFile: const sourceFile = node; return isExternalModule(sourceFile) ? `"${escapeString(getBaseFileName(removeFileExtension(normalizePath(sourceFile.fileName))))}"` : ""; case SyntaxKind.ExportAssignment: return isExportAssignment(node) && node.isExportEquals ? InternalSymbolName.ExportEquals : InternalSymbolName.Default; case SyntaxKind.ArrowFunction: case SyntaxKind.FunctionDeclaration: case SyntaxKind.FunctionExpression: case SyntaxKind.ClassDeclaration: case SyntaxKind.ClassExpression: case SyntaxKind.StructDeclaration: if (getSyntacticModifierFlags(node) & ModifierFlags.Default) { return "default"; } // We may get a string with newlines or other whitespace in the case of an object dereference // (eg: "app\n.onactivated"), so we should remove the whitespace for readability in the // navigation bar. return getFunctionOrClassName(node); case SyntaxKind.Constructor: return "constructor"; case SyntaxKind.ConstructSignature: return "new()"; case SyntaxKind.CallSignature: return "()"; case SyntaxKind.IndexSignature: return "[]"; default: return ""; } } /** Flattens the NavNode tree to a list of items to appear in the primary navbar menu. */ function primaryNavBarMenuItems(root: NavigationBarNode): NavigationBarNode[] { // The primary (middle) navbar menu displays the general code navigation hierarchy, similar to the navtree. // The secondary (right) navbar menu displays the child items of whichever primary item is selected. // Some less interesting items without their own child navigation items (e.g. a local variable declaration) only show up in the secondary menu. const primaryNavBarMenuItems: NavigationBarNode[] = []; function recur(item: NavigationBarNode) { if (shouldAppearInPrimaryNavBarMenu(item)) { primaryNavBarMenuItems.push(item); if (item.children) { for (const child of item.children) { recur(child); } } } } recur(root); return primaryNavBarMenuItems; /** Determines if a node should appear in the primary navbar menu. */ function shouldAppearInPrimaryNavBarMenu(item: NavigationBarNode): boolean { // Items with children should always appear in the primary navbar menu. if (item.children) { return true; } // Some nodes are otherwise important enough to always include in the primary navigation menu. switch (navigationBarNodeKind(item)) { case SyntaxKind.ClassDeclaration: case SyntaxKind.ClassExpression: case SyntaxKind.StructDeclaration: case SyntaxKind.EnumDeclaration: case SyntaxKind.InterfaceDeclaration: case SyntaxKind.ModuleDeclaration: case SyntaxKind.SourceFile: case SyntaxKind.TypeAliasDeclaration: case SyntaxKind.JSDocTypedefTag: case SyntaxKind.JSDocCallbackTag: return true; case SyntaxKind.ArrowFunction: case SyntaxKind.FunctionDeclaration: case SyntaxKind.FunctionExpression: return isTopLevelFunctionDeclaration(item); default: return false; } function isTopLevelFunctionDeclaration(item: NavigationBarNode): boolean { if (!(item.node).body) { return false; } switch (navigationBarNodeKind(item.parent!)) { case SyntaxKind.ModuleBlock: case SyntaxKind.SourceFile: case SyntaxKind.MethodDeclaration: case SyntaxKind.Constructor: return true; default: return false; } } } } function convertToTree(n: NavigationBarNode): NavigationTree { return { text: getItemName(n.node, n.name), kind: getNodeKind(n.node), kindModifiers: getModifiers(n.node), spans: getSpans(n), nameSpan: n.name && getNodeSpan(n.name), childItems: map(n.children, convertToTree) }; } function convertToPrimaryNavBarMenuItem(n: NavigationBarNode): NavigationBarItem { return { text: getItemName(n.node, n.name), kind: getNodeKind(n.node), kindModifiers: getModifiers(n.node), spans: getSpans(n), childItems: map(n.children, convertToSecondaryNavBarMenuItem) || emptyChildItemArray, indent: n.indent, bolded: false, grayed: false }; function convertToSecondaryNavBarMenuItem(n: NavigationBarNode): NavigationBarItem { return { text: getItemName(n.node, n.name), kind: getNodeKind(n.node), kindModifiers: getNodeModifiers(n.node), spans: getSpans(n), childItems: emptyChildItemArray, indent: 0, bolded: false, grayed: false }; } } function getSpans(n: NavigationBarNode): TextSpan[] { const spans = [getNodeSpan(n.node)]; if (n.additionalNodes) { for (const node of n.additionalNodes) { spans.push(getNodeSpan(node)); } } return spans; } function getModuleName(moduleDeclaration: ModuleDeclaration): string { // We want to maintain quotation marks. if (isAmbientModule(moduleDeclaration)) { return getTextOfNode(moduleDeclaration.name); } // Otherwise, we need to aggregate each identifier to build up the qualified name. const result = [getTextOfIdentifierOrLiteral(moduleDeclaration.name)]; while (moduleDeclaration.body && moduleDeclaration.body.kind === SyntaxKind.ModuleDeclaration) { moduleDeclaration = moduleDeclaration.body; result.push(getTextOfIdentifierOrLiteral(moduleDeclaration.name)); } return result.join("."); } /** * For 'module A.B.C', we want to get the node for 'C'. * We store 'A' as associated with a NavNode, and use getModuleName to traverse down again. */ function getInteriorModule(decl: ModuleDeclaration): ModuleDeclaration { return decl.body && isModuleDeclaration(decl.body) ? getInteriorModule(decl.body) : decl; } function isComputedProperty(member: EnumMember): boolean { return !member.name || member.name.kind === SyntaxKind.ComputedPropertyName; } function getNodeSpan(node: Node): TextSpan { return node.kind === SyntaxKind.SourceFile ? createTextSpanFromRange(node) : createTextSpanFromNode(node, curSourceFile); } function getModifiers(node: Node): string { if (node.parent && node.parent.kind === SyntaxKind.VariableDeclaration) { node = node.parent; } return getNodeModifiers(node); } function getFunctionOrClassName(node: FunctionExpression | FunctionDeclaration | ArrowFunction | ClassLikeDeclaration): string { const { parent } = node; if (node.name && getFullWidth(node.name) > 0) { return cleanText(declarationNameToString(node.name)); } // See if it is a var initializer. If so, use the var name. else if (isVariableDeclaration(parent)) { return cleanText(declarationNameToString(parent.name)); } // See if it is of the form " = function(){...}". If so, use the text from the left-hand side. else if (isBinaryExpression(parent) && parent.operatorToken.kind === SyntaxKind.EqualsToken) { return nodeText(parent.left).replace(whiteSpaceRegex, ""); } // See if it is a property assignment, and if so use the property name else if (isPropertyAssignment(parent)) { return nodeText(parent.name); } // Default exports are named "default" else if (getSyntacticModifierFlags(node) & ModifierFlags.Default) { return "default"; } else if (isClassLike(node)) { return ""; } else if (isCallExpression(parent)) { let name = getCalledExpressionName(parent.expression); if (name !== undefined) { name = cleanText(name); if (name.length > maxLength) { return `${name} callback`; } const args = cleanText(mapDefined(parent.arguments, a => isStringLiteralLike(a) ? a.getText(curSourceFile) : undefined).join(", ")); return `${name}(${args}) callback`; } } return ""; } // See also 'tryGetPropertyAccessOrIdentifierToString' function getCalledExpressionName(expr: Expression): string | undefined { if (isIdentifier(expr)) { return expr.text; } else if (isPropertyAccessExpression(expr)) { const left = getCalledExpressionName(expr.expression); const right = expr.name.text; return left === undefined ? right : `${left}.${right}`; } else { return undefined; } } function isFunctionOrClassExpression(node: Node): node is ArrowFunction | FunctionExpression | ClassExpression { switch (node.kind) { case SyntaxKind.ArrowFunction: case SyntaxKind.FunctionExpression: case SyntaxKind.ClassExpression: return true; default: return false; } } function cleanText(text: string): string { // Truncate to maximum amount of characters as we don't want to do a big replace operation. text = text.length > maxLength ? text.substring(0, maxLength) + "..." : text; // Replaces ECMAScript line terminators and removes the trailing `\` from each line: // \n - Line Feed // \r - Carriage Return // \u2028 - Line separator // \u2029 - Paragraph separator return text.replace(/\\?(\r?\n|\r|\u2028|\u2029)/g, ""); } }