/** * @license * Copyright Google LLC All Rights Reserved. * * Use of this source code is governed by an MIT-style license that can be * found in the LICENSE file at https://angular.io/license */ import {ParseSpan, TmplAstBoundEvent} from '@angular/compiler'; import * as e from '@angular/compiler/src/expression_parser/ast'; // e for expression AST import * as t from '@angular/compiler/src/render3/r3_ast'; // t for template AST import {isTemplateNodeWithKeyAndValue, isWithin, isWithinKeyValue} from './utils'; /** * Contextual information for a target position within the template. */ export interface TemplateTarget { /** * Target position within the template. */ position: number; /** * The template (or AST expression) node or nodes closest to the search position. */ context: TargetContext; /** * The `t.Template` which contains the found node or expression (or `null` if in the root * template). */ template: t.Template|null; /** * The immediate parent node of the targeted node. */ parent: t.Node|e.AST|null; } /** * A node or nodes targeted at a given position in the template, including potential contextual * information about the specific aspect of the node being referenced. * * Some nodes have multiple interior contexts. For example, `t.Element` nodes have both a tag name * as well as a body, and a given position definitively points to one or the other. `TargetNode` * captures the node itself, as well as this additional contextual disambiguation. */ export type TargetContext = SingleNodeTarget|MultiNodeTarget; /** Contexts which logically target only a single node in the template AST. */ export type SingleNodeTarget = RawExpression|MethodCallExpressionInArgContext|RawTemplateNode| ElementInBodyContext|ElementInTagContext|AttributeInKeyContext|AttributeInValueContext; /** * Contexts which logically target multiple nodes in the template AST, which cannot be * disambiguated given a single position because they are all equally relavent. For example, in the * banana-in-a-box syntax `[(ngModel)]="formValues.person"`, the position in the template for the * key `ngModel` refers to both the bound event `ngModelChange` and the input `ngModel`. */ export type MultiNodeTarget = TwoWayBindingContext; /** * Differentiates the various kinds of `TargetNode`s. */ export enum TargetNodeKind { RawExpression, MethodCallExpressionInArgContext, RawTemplateNode, ElementInTagContext, ElementInBodyContext, AttributeInKeyContext, AttributeInValueContext, TwoWayBindingContext, } /** * An `e.AST` expression that's targeted at a given position, with no additional context. */ export interface RawExpression { kind: TargetNodeKind.RawExpression; node: e.AST; parents: e.AST[]; } /** * An `e.MethodCall` or `e.SafeMethodCall` expression with the cursor in a position where an * argument could appear. * * This is returned when the only matching node is the method call expression, but the cursor is * within the method call parentheses. For example, in the expression `foo(|)` there is no argument * expression that the cursor could be targeting, but the cursor is in a position where one could * appear. */ export interface MethodCallExpressionInArgContext { kind: TargetNodeKind.MethodCallExpressionInArgContext; node: e.MethodCall|e.SafeMethodCall; } /** * A `t.Node` template node that's targeted at a given position, with no additional context. */ export interface RawTemplateNode { kind: TargetNodeKind.RawTemplateNode; node: t.Node; } /** * A `t.Element` (or `t.Template`) element node that's targeted, where the given position is within * the tag name. */ export interface ElementInTagContext { kind: TargetNodeKind.ElementInTagContext; node: t.Element|t.Template; } /** * A `t.Element` (or `t.Template`) element node that's targeted, where the given position is within * the element body. */ export interface ElementInBodyContext { kind: TargetNodeKind.ElementInBodyContext; node: t.Element|t.Template; } export interface AttributeInKeyContext { kind: TargetNodeKind.AttributeInKeyContext; node: t.TextAttribute|t.BoundAttribute|t.BoundEvent; } export interface AttributeInValueContext { kind: TargetNodeKind.AttributeInValueContext; node: t.TextAttribute|t.BoundAttribute|t.BoundEvent; } /** * A `t.BoundAttribute` and `t.BoundEvent` pair that are targeted, where the given position is * within the key span of both. */ export interface TwoWayBindingContext { kind: TargetNodeKind.TwoWayBindingContext; nodes: [t.BoundAttribute, t.BoundEvent]; } /** * This special marker is added to the path when the cursor is within the sourceSpan but not the key * or value span of a node with key/value spans. */ const OUTSIDE_K_V_MARKER = new e.AST(new ParseSpan(-1, -1), new e.AbsoluteSourceSpan(-1, -1)); /** * Return the template AST node or expression AST node that most accurately * represents the node at the specified cursor `position`. * * @param template AST tree of the template * @param position target cursor position */ export function getTargetAtPosition(template: t.Node[], position: number): TemplateTarget|null { const path = TemplateTargetVisitor.visitTemplate(template, position); if (path.length === 0) { return null; } const candidate = path[path.length - 1]; // Walk up the result nodes to find the nearest `t.Template` which contains the targeted node. let context: t.Template|null = null; for (let i = path.length - 2; i >= 0; i--) { const node = path[i]; if (node instanceof t.Template) { context = node; break; } } // Given the candidate node, determine the full targeted context. let nodeInContext: TargetContext; if ((candidate instanceof e.MethodCall || candidate instanceof e.SafeMethodCall) && isWithin(position, candidate.argumentSpan)) { nodeInContext = { kind: TargetNodeKind.MethodCallExpressionInArgContext, node: candidate, }; } else if (candidate instanceof e.AST) { const parents = path.filter((value: e.AST|t.Node): value is e.AST => value instanceof e.AST); // Remove the current node from the parents list. parents.pop(); nodeInContext = { kind: TargetNodeKind.RawExpression, node: candidate, parents, }; } else if (candidate instanceof t.Element) { // Elements have two contexts: the tag context (position is within the element tag) or the // element body context (position is outside of the tag name, but still in the element). // Calculate the end of the element tag name. Any position beyond this is in the element body. const tagEndPos = candidate.sourceSpan.start.offset + 1 /* '<' element open */ + candidate.name.length; if (position > tagEndPos) { // Position is within the element body nodeInContext = { kind: TargetNodeKind.ElementInBodyContext, node: candidate, }; } else { nodeInContext = { kind: TargetNodeKind.ElementInTagContext, node: candidate, }; } } else if ( (candidate instanceof t.BoundAttribute || candidate instanceof t.BoundEvent || candidate instanceof t.TextAttribute) && candidate.keySpan !== undefined) { const previousCandidate = path[path.length - 2]; if (candidate instanceof t.BoundEvent && previousCandidate instanceof t.BoundAttribute && candidate.name === previousCandidate.name + 'Change') { const boundAttribute: t.BoundAttribute = previousCandidate; const boundEvent: t.BoundEvent = candidate; nodeInContext = { kind: TargetNodeKind.TwoWayBindingContext, nodes: [boundAttribute, boundEvent], }; } else if (isWithin(position, candidate.keySpan)) { nodeInContext = { kind: TargetNodeKind.AttributeInKeyContext, node: candidate, }; } else { nodeInContext = { kind: TargetNodeKind.AttributeInValueContext, node: candidate, }; } } else { nodeInContext = { kind: TargetNodeKind.RawTemplateNode, node: candidate, }; } let parent: t.Node|e.AST|null = null; if (nodeInContext.kind === TargetNodeKind.TwoWayBindingContext && path.length >= 3) { parent = path[path.length - 3]; } else if (path.length >= 2) { parent = path[path.length - 2]; } return {position, context: nodeInContext, template: context, parent}; } /** * Visitor which, given a position and a template, identifies the node within the template at that * position, as well as records the path of increasingly nested nodes that were traversed to reach * that position. */ class TemplateTargetVisitor implements t.Visitor { // We need to keep a path instead of the last node because we might need more // context for the last node, for example what is the parent node? readonly path: Array = []; static visitTemplate(template: t.Node[], position: number): Array { const visitor = new TemplateTargetVisitor(position); visitor.visitAll(template); const {path} = visitor; const strictPath = path.filter(v => v !== OUTSIDE_K_V_MARKER); const candidate = strictPath[strictPath.length - 1]; const matchedASourceSpanButNotAKvSpan = path.some(v => v === OUTSIDE_K_V_MARKER); if (matchedASourceSpanButNotAKvSpan && (candidate instanceof t.Template || candidate instanceof t.Element)) { // Template nodes with key and value spans are always defined on a `t.Template` or // `t.Element`. If we found a node on a template with a `sourceSpan` that includes the cursor, // it is possible that we are outside the k/v spans (i.e. in-between them). If this is the // case and we do not have any other candidate matches on the `t.Element` or `t.Template`, we // want to return no results. Otherwise, the `t.Element`/`t.Template` result is incorrect for // that cursor position. return []; } return strictPath; } // Position must be absolute in the source file. private constructor(private readonly position: number) {} visit(node: t.Node) { const {start, end} = getSpanIncludingEndTag(node); if (end !== null && !isWithin(this.position, {start, end})) { return; } const last: t.Node|e.AST|undefined = this.path[this.path.length - 1]; const withinKeySpanOfLastNode = last && isTemplateNodeWithKeyAndValue(last) && isWithin(this.position, last.keySpan); const withinKeySpanOfCurrentNode = isTemplateNodeWithKeyAndValue(node) && isWithin(this.position, node.keySpan); if (withinKeySpanOfLastNode && !withinKeySpanOfCurrentNode) { // We've already identified that we are within a `keySpan` of a node. // Unless we are _also_ in the `keySpan` of the current node (happens with two way bindings), // we should stop processing nodes at this point to prevent matching any other nodes. This can // happen when the end span of a different node touches the start of the keySpan for the // candidate node. Because our `isWithin` logic is inclusive on both ends, we can match both // nodes. return; } if (isTemplateNodeWithKeyAndValue(node) && !isWithinKeyValue(this.position, node)) { // If cursor is within source span but not within key span or value span, // do not return the node. this.path.push(OUTSIDE_K_V_MARKER); } else { this.path.push(node); node.visit(this); } } visitElement(element: t.Element) { this.visitElementOrTemplate(element); } visitTemplate(template: t.Template) { this.visitElementOrTemplate(template); } visitElementOrTemplate(element: t.Template|t.Element) { this.visitAll(element.attributes); this.visitAll(element.inputs); this.visitAll(element.outputs); if (element instanceof t.Template) { this.visitAll(element.templateAttrs); } this.visitAll(element.references); if (element instanceof t.Template) { this.visitAll(element.variables); } // If we get here and have not found a candidate node on the element itself, proceed with // looking for a more specific node on the element children. if (this.path[this.path.length - 1] !== element) { return; } this.visitAll(element.children); } visitContent(content: t.Content) { t.visitAll(this, content.attributes); } visitVariable(variable: t.Variable) { // Variable has no template nodes or expression nodes. } visitReference(reference: t.Reference) { // Reference has no template nodes or expression nodes. } visitTextAttribute(attribute: t.TextAttribute) { // Text attribute has no template nodes or expression nodes. } visitBoundAttribute(attribute: t.BoundAttribute) { const visitor = new ExpressionVisitor(this.position); visitor.visit(attribute.value, this.path); } visitBoundEvent(event: t.BoundEvent) { // An event binding with no value (e.g. `(event|)`) parses to a `BoundEvent` with a // `LiteralPrimitive` handler with value `'ERROR'`, as opposed to a property binding with no // value which has an `EmptyExpr` as its value. This is a synthetic node created by the binding // parser, and is not suitable to use for Language Service analysis. Skip it. // // TODO(alxhub): modify the parser to generate an `EmptyExpr` instead. let handler: e.AST = event.handler; if (handler instanceof e.ASTWithSource) { handler = handler.ast; } if (handler instanceof e.LiteralPrimitive && handler.value === 'ERROR') { return; } const visitor = new ExpressionVisitor(this.position); visitor.visit(event.handler, this.path); } visitText(text: t.Text) { // Text has no template nodes or expression nodes. } visitBoundText(text: t.BoundText) { const visitor = new ExpressionVisitor(this.position); visitor.visit(text.value, this.path); } visitIcu(icu: t.Icu) { for (const boundText of Object.values(icu.vars)) { this.visit(boundText); } for (const boundTextOrText of Object.values(icu.placeholders)) { this.visit(boundTextOrText); } } visitAll(nodes: t.Node[]) { for (const node of nodes) { this.visit(node); } } } class ExpressionVisitor extends e.RecursiveAstVisitor { // Position must be absolute in the source file. constructor(private readonly position: number) { super(); } visit(node: e.AST, path: Array) { if (node instanceof e.ASTWithSource) { // In order to reduce noise, do not include `ASTWithSource` in the path. // For the purpose of source spans, there is no difference between // `ASTWithSource` and and underlying node that it wraps. node = node.ast; } // The third condition is to account for the implicit receiver, which should // not be visited. if (isWithin(this.position, node.sourceSpan) && !(node instanceof e.ImplicitReceiver)) { path.push(node); node.visit(this, path); } } } function getSpanIncludingEndTag(ast: t.Node) { const result = { start: ast.sourceSpan.start.offset, end: ast.sourceSpan.end.offset, }; // For Element and Template node, sourceSpan.end is the end of the opening // tag. For the purpose of language service, we need to actually recognize // the end of the closing tag. Otherwise, for situation like // where the cursor is in the closing tag // we will not be able to return any information. if (ast instanceof t.Element || ast instanceof t.Template) { if (ast.endSourceSpan) { result.end = ast.endSourceSpan.end.offset; } else if (ast.children.length > 0) { // If the AST has children but no end source span, then it is an unclosed element with an end // that should be the end of the last child. result.end = getSpanIncludingEndTag(ast.children[ast.children.length - 1]).end; } else { // This is likely a self-closing tag with no children so the `sourceSpan.end` is correct. } } return result; }