///
module ts {
export interface Map {
[index: string]: T;
}
export interface TextRange {
pos: number;
end: number;
}
// token > SyntaxKind.Identifer => token is a keyword
export const enum SyntaxKind {
Unknown,
EndOfFileToken,
SingleLineCommentTrivia,
MultiLineCommentTrivia,
NewLineTrivia,
WhitespaceTrivia,
ConflictMarkerTrivia,
// Literals
NumericLiteral,
StringLiteral,
RegularExpressionLiteral,
NoSubstitutionTemplateLiteral,
// Pseudo-literals
TemplateHead,
TemplateMiddle,
TemplateTail,
// Punctuation
OpenBraceToken,
CloseBraceToken,
OpenParenToken,
CloseParenToken,
OpenBracketToken,
CloseBracketToken,
DotToken,
DotDotDotToken,
SemicolonToken,
CommaToken,
LessThanToken,
GreaterThanToken,
LessThanEqualsToken,
GreaterThanEqualsToken,
EqualsEqualsToken,
ExclamationEqualsToken,
EqualsEqualsEqualsToken,
ExclamationEqualsEqualsToken,
EqualsGreaterThanToken,
PlusToken,
MinusToken,
AsteriskToken,
SlashToken,
PercentToken,
PlusPlusToken,
MinusMinusToken,
LessThanLessThanToken,
GreaterThanGreaterThanToken,
GreaterThanGreaterThanGreaterThanToken,
AmpersandToken,
BarToken,
CaretToken,
ExclamationToken,
TildeToken,
AmpersandAmpersandToken,
BarBarToken,
QuestionToken,
ColonToken,
// Assignments
EqualsToken,
PlusEqualsToken,
MinusEqualsToken,
AsteriskEqualsToken,
SlashEqualsToken,
PercentEqualsToken,
LessThanLessThanEqualsToken,
GreaterThanGreaterThanEqualsToken,
GreaterThanGreaterThanGreaterThanEqualsToken,
AmpersandEqualsToken,
BarEqualsToken,
CaretEqualsToken,
// Identifiers
Identifier,
// Reserved words
BreakKeyword,
CaseKeyword,
CatchKeyword,
ClassKeyword,
ConstKeyword,
ContinueKeyword,
DebuggerKeyword,
DefaultKeyword,
DeleteKeyword,
DoKeyword,
ElseKeyword,
EnumKeyword,
ExportKeyword,
ExtendsKeyword,
FalseKeyword,
FinallyKeyword,
ForKeyword,
FunctionKeyword,
IfKeyword,
ImportKeyword,
InKeyword,
InstanceOfKeyword,
NewKeyword,
NullKeyword,
ReturnKeyword,
SuperKeyword,
SwitchKeyword,
ThisKeyword,
ThrowKeyword,
TrueKeyword,
TryKeyword,
TypeOfKeyword,
VarKeyword,
VoidKeyword,
WhileKeyword,
WithKeyword,
// Strict mode reserved words
ImplementsKeyword,
InterfaceKeyword,
LetKeyword,
PackageKeyword,
PrivateKeyword,
ProtectedKeyword,
PublicKeyword,
StaticKeyword,
YieldKeyword,
// TypeScript keywords
AnyKeyword,
BooleanKeyword,
ConstructorKeyword,
DeclareKeyword,
GetKeyword,
ModuleKeyword,
RequireKeyword,
NumberKeyword,
SetKeyword,
StringKeyword,
TypeKeyword,
// Parse tree nodes
// Names
QualifiedName,
ComputedPropertyName,
// Signature elements
TypeParameter,
Parameter,
// TypeMember
PropertySignature,
PropertyDeclaration,
MethodSignature,
MethodDeclaration,
Constructor,
GetAccessor,
SetAccessor,
CallSignature,
ConstructSignature,
IndexSignature,
// Type
TypeReference,
FunctionType,
ConstructorType,
TypeQuery,
TypeLiteral,
ArrayType,
TupleType,
UnionType,
ParenthesizedType,
// Binding patterns
ObjectBindingPattern,
ArrayBindingPattern,
BindingElement,
// Expression
ArrayLiteralExpression,
ObjectLiteralExpression,
PropertyAccessExpression,
ElementAccessExpression,
CallExpression,
NewExpression,
TaggedTemplateExpression,
TypeAssertionExpression,
ParenthesizedExpression,
FunctionExpression,
ArrowFunction,
DeleteExpression,
TypeOfExpression,
VoidExpression,
PrefixUnaryExpression,
PostfixUnaryExpression,
BinaryExpression,
ConditionalExpression,
TemplateExpression,
YieldExpression,
OmittedExpression,
// Misc
TemplateSpan,
// Element
Block,
VariableStatement,
EmptyStatement,
ExpressionStatement,
IfStatement,
DoStatement,
WhileStatement,
ForStatement,
ForInStatement,
ContinueStatement,
BreakStatement,
ReturnStatement,
WithStatement,
SwitchStatement,
LabeledStatement,
ThrowStatement,
TryStatement,
DebuggerStatement,
VariableDeclaration,
FunctionDeclaration,
ClassDeclaration,
InterfaceDeclaration,
TypeAliasDeclaration,
EnumDeclaration,
ModuleDeclaration,
ModuleBlock,
ImportDeclaration,
ExportAssignment,
// Module references
ExternalModuleReference,
// Clauses
CaseClause,
DefaultClause,
HeritageClause,
CatchClause,
// Property assignments
PropertyAssignment,
ShorthandPropertyAssignment,
// Enum
EnumMember,
// Top-level nodes
SourceFile,
Program,
// Synthesized list
SyntaxList,
// Enum value count
Count,
// Markers
FirstAssignment = EqualsToken,
LastAssignment = CaretEqualsToken,
FirstReservedWord = BreakKeyword,
LastReservedWord = WithKeyword,
FirstKeyword = BreakKeyword,
LastKeyword = TypeKeyword,
FirstFutureReservedWord = ImplementsKeyword,
LastFutureReservedWord = YieldKeyword,
FirstTypeNode = TypeReference,
LastTypeNode = ParenthesizedType,
FirstPunctuation = OpenBraceToken,
LastPunctuation = CaretEqualsToken,
FirstToken = Unknown,
LastToken = TypeKeyword,
FirstTriviaToken = SingleLineCommentTrivia,
LastTriviaToken = ConflictMarkerTrivia,
FirstLiteralToken = NumericLiteral,
LastLiteralToken = NoSubstitutionTemplateLiteral,
FirstTemplateToken = NoSubstitutionTemplateLiteral,
LastTemplateToken = TemplateTail,
FirstOperator = SemicolonToken,
LastOperator = CaretEqualsToken,
FirstBinaryOperator = LessThanToken,
LastBinaryOperator = CaretEqualsToken,
FirstNode = QualifiedName,
}
export const enum NodeFlags {
Export = 0x00000001, // Declarations
Ambient = 0x00000002, // Declarations
Public = 0x00000010, // Property/Method
Private = 0x00000020, // Property/Method
Protected = 0x00000040, // Property/Method
Static = 0x00000080, // Property/Method
MultiLine = 0x00000100, // Multi-line array or object literal
Synthetic = 0x00000200, // Synthetic node (for full fidelity)
DeclarationFile = 0x00000400, // Node is a .d.ts file
Let = 0x00000800, // Variable declaration
Const = 0x00001000, // Variable declaration
OctalLiteral = 0x00002000,
Modifier = Export | Ambient | Public | Private | Protected | Static,
AccessibilityModifier = Public | Private | Protected,
BlockScoped = Let | Const
}
export const enum ParserContextFlags {
// Set if this node was parsed in strict mode. Used for grammar error checks, as well as
// checking if the node can be reused in incremental settings.
StrictMode = 1 << 0,
// If this node was parsed in a context where 'in-expressions' are not allowed.
DisallowIn = 1 << 1,
// If this node was parsed in the 'yield' context created when parsing a generator.
Yield = 1 << 2,
// If this node was parsed in the parameters of a generator.
GeneratorParameter = 1 << 3,
// If the parser encountered an error when parsing the code that created this node. Note
// the parser only sets this directly on the node it creates right after encountering the
// error. We then propagate that flag upwards to parent nodes during incremental parsing.
ContainsError = 1 << 4,
// Used during incremental parsing to determine if we need to visit this node to see if
// any of its children had an error. Once we compute that once, we can set this bit on the
// node to know that we never have to do it again. From that point on, we can just check
// the node directly for 'ContainsError'.
HasPropagatedChildContainsErrorFlag = 1 << 5
}
export interface Node extends TextRange {
kind: SyntaxKind;
flags: NodeFlags;
// Specific context the parser was in when this node was created. Normally undefined.
// Only set when the parser was in some interesting context (like async/yield).
parserContextFlags?: ParserContextFlags;
id?: number; // Unique id (used to look up NodeLinks)
parent?: Node; // Parent node (initialized by binding)
symbol?: Symbol; // Symbol declared by node (initialized by binding)
locals?: SymbolTable; // Locals associated with node (initialized by binding)
nextContainer?: Node; // Next container in declaration order (initialized by binding)
localSymbol?: Symbol; // Local symbol declared by node (initialized by binding only for exported nodes)
modifiers?: ModifiersArray; // Array of modifiers
}
export interface NodeArray extends Array, TextRange {
hasTrailingComma?: boolean;
}
export interface ModifiersArray extends NodeArray {
flags: number;
}
export interface Identifier extends PrimaryExpression {
text: string; // Text of identifier (with escapes converted to characters)
}
export interface QualifiedName extends Node {
// Must have same layout as PropertyAccess
left: EntityName;
right: Identifier;
}
export type EntityName = Identifier | QualifiedName;
export type DeclarationName = Identifier | LiteralExpression | ComputedPropertyName | BindingPattern;
export interface Declaration extends Node {
_declarationBrand: any;
name?: DeclarationName;
}
export interface ComputedPropertyName extends Node {
expression: Expression;
}
export interface TypeParameterDeclaration extends Declaration {
name: Identifier;
constraint?: TypeNode;
// For error recovery purposes.
expression?: Expression;
}
export interface SignatureDeclaration extends Declaration {
typeParameters?: NodeArray;
parameters: NodeArray;
type?: TypeNode;
}
// SyntaxKind.VariableDeclaration
export interface VariableDeclaration extends Declaration {
name: Identifier | BindingPattern; // Declared variable name
type?: TypeNode; // Optional type annotation
initializer?: Expression; // Optional initializer
}
// SyntaxKind.Parameter
export interface ParameterDeclaration extends Declaration {
dotDotDotToken?: Node; // Present on rest parameter
name: Identifier | BindingPattern; // Declared parameter name
questionToken?: Node; // Present on optional parameter
type?: TypeNode; // Optional type annotation
initializer?: Expression; // Optional initializer
}
// SyntaxKind.BindingElement
export interface BindingElement extends Declaration {
propertyName?: Identifier; // Binding property name (in object binding pattern)
dotDotDotToken?: Node; // Present on rest binding element
name: Identifier | BindingPattern; // Declared binding element name
initializer?: Expression; // Optional initializer
}
// SyntaxKind.Property
export interface PropertyDeclaration extends Declaration, ClassElement {
name: DeclarationName; // Declared property name
questionToken?: Node; // Present on optional property
type?: TypeNode; // Optional type annotation
initializer?: Expression; // Optional initializer
}
export interface ObjectLiteralElement extends Declaration {
_objectLiteralBrandBrand: any;
}
// SyntaxKind.PropertyAssignment
export interface PropertyAssignment extends ObjectLiteralElement {
_propertyAssignmentBrand: any;
name: DeclarationName;
questionToken?: Node;
initializer: Expression;
}
// SyntaxKind.ShorthandPropertyAssignment
export interface ShorthandPropertyAssignment extends ObjectLiteralElement {
name: Identifier;
questionToken?: Node;
}
// SyntaxKind.VariableDeclaration
// SyntaxKind.Parameter
// SyntaxKind.BindingElement
// SyntaxKind.Property
// SyntaxKind.PropertyAssignment
// SyntaxKind.ShorthandPropertyAssignment
// SyntaxKind.EnumMember
export interface VariableLikeDeclaration extends Declaration {
propertyName?: Identifier;
dotDotDotToken?: Node;
name: DeclarationName;
questionToken?: Node;
type?: TypeNode;
initializer?: Expression;
}
export interface BindingPattern extends Node {
elements: NodeArray;
}
/**
* Several node kinds share function-like features such as a signature,
* a name, and a body. These nodes should extend FunctionLikeDeclaration.
* Examples:
* FunctionDeclaration
* MethodDeclaration
* AccessorDeclaration
*/
export interface FunctionLikeDeclaration extends SignatureDeclaration {
_functionLikeDeclarationBrand: any;
asteriskToken?: Node;
questionToken?: Node;
body?: Block | Expression;
}
export interface FunctionDeclaration extends FunctionLikeDeclaration, Statement {
name: Identifier;
body?: Block;
}
// Note that a MethodDeclaration is considered both a ClassElement and an ObjectLiteralElement.
// Both the grammars for ClassDeclaration and ObjectLiteralExpression allow for MethodDeclarations
// as child elements, and so a MethodDeclaration satisfies both interfaces. This avoids the
// alternative where we would need separate kinds/types for ClassMethodDeclaration and
// ObjectLiteralMethodDeclaration, which would look identical.
//
// Because of this, it may be necessary to determine what sort of MethodDeclaration you have
// at later stages of the compiler pipeline. In that case, you can either check the parent kind
// of the method, or use helpers like isObjectLiteralMethodDeclaration
export interface MethodDeclaration extends FunctionLikeDeclaration, ClassElement, ObjectLiteralElement {
body?: Block;
}
export interface ConstructorDeclaration extends FunctionLikeDeclaration, ClassElement {
body?: Block;
}
// See the comment on MethodDeclaration for the intuition behind AccessorDeclaration being a
// ClassElement and an ObjectLiteralElement.
export interface AccessorDeclaration extends FunctionLikeDeclaration, ClassElement, ObjectLiteralElement {
_accessorDeclarationBrand: any;
body: Block;
}
export interface IndexSignatureDeclaration extends SignatureDeclaration, ClassElement {
_indexSignatureDeclarationBrand: any;
}
export interface TypeNode extends Node {
_typeNodeBrand: any;
}
export interface FunctionOrConstructorTypeNode extends TypeNode, SignatureDeclaration {
_functionOrConstructorTypeNodeBrand: any;
}
export interface TypeReferenceNode extends TypeNode {
typeName: EntityName;
typeArguments?: NodeArray;
}
export interface TypeQueryNode extends TypeNode {
exprName: EntityName;
}
// A TypeLiteral is the declaration node for an anonymous symbol.
export interface TypeLiteralNode extends TypeNode, Declaration {
members: NodeArray;
}
export interface ArrayTypeNode extends TypeNode {
elementType: TypeNode;
}
export interface TupleTypeNode extends TypeNode {
elementTypes: NodeArray;
}
export interface UnionTypeNode extends TypeNode {
types: NodeArray;
}
export interface ParenthesizedTypeNode extends TypeNode {
type: TypeNode;
}
export interface StringLiteralTypeNode extends LiteralExpression, TypeNode { }
// Note: 'brands' in our syntax nodes serve to give us a small amount of nominal typing.
// Consider 'Expression'. Without the brand, 'Expression' is actually no different
// (structurally) than 'Node'. Because of this you can pass any Node to a function that
// takes an Expression without any error. By using the 'brands' we ensure that the type
// checker actually thinks you have something of the right type. Note: the brands are
// never actually given values. At runtime they have zero cost.
export interface Expression extends Node {
_expressionBrand: any;
contextualType?: Type; // Used to temporarily assign a contextual type during overload resolution
}
export interface UnaryExpression extends Expression {
_unaryExpressionBrand: any;
}
export interface PrefixUnaryExpression extends UnaryExpression {
operator: SyntaxKind;
operand: UnaryExpression;
}
export interface PostfixUnaryExpression extends PostfixExpression {
operand: LeftHandSideExpression;
operator: SyntaxKind;
}
export interface PostfixExpression extends UnaryExpression {
_postfixExpressionBrand: any;
}
export interface LeftHandSideExpression extends PostfixExpression {
_leftHandSideExpressionBrand: any;
}
export interface MemberExpression extends LeftHandSideExpression {
_memberExpressionBrand: any;
}
export interface PrimaryExpression extends MemberExpression {
_primaryExpressionBrand: any;
}
export interface DeleteExpression extends UnaryExpression {
expression: UnaryExpression;
}
export interface TypeOfExpression extends UnaryExpression {
expression: UnaryExpression;
}
export interface VoidExpression extends UnaryExpression {
expression: UnaryExpression;
}
export interface YieldExpression extends Expression {
asteriskToken?: Node;
expression: Expression;
}
export interface BinaryExpression extends Expression {
left: Expression;
operator: SyntaxKind;
right: Expression;
}
export interface ConditionalExpression extends Expression {
condition: Expression;
whenTrue: Expression;
whenFalse: Expression;
}
export interface FunctionExpression extends PrimaryExpression, FunctionLikeDeclaration {
name?: Identifier;
body: Block | Expression; // Required, whereas the member inherited from FunctionDeclaration is optional
}
// The text property of a LiteralExpression stores the interpreted value of the literal in text form. For a StringLiteral,
// or any literal of a template, this means quotes have been removed and escapes have been converted to actual characters.
// For a NumericLiteral, the stored value is the toString() representation of the number. For example 1, 1.00, and 1e0 are all stored as just "1".
export interface LiteralExpression extends PrimaryExpression {
text: string;
isUnterminated?: boolean;
}
export interface StringLiteralExpression extends LiteralExpression {
_stringLiteralExpressionBrand: any;
}
export interface TemplateExpression extends PrimaryExpression {
head: LiteralExpression;
templateSpans: NodeArray;
}
// Each of these corresponds to a substitution expression and a template literal, in that order.
// The template literal must have kind TemplateMiddleLiteral or TemplateTailLiteral.
export interface TemplateSpan extends Node {
expression: Expression;
literal: LiteralExpression;
}
export interface ParenthesizedExpression extends PrimaryExpression {
expression: Expression;
}
export interface ArrayLiteralExpression extends PrimaryExpression {
elements: NodeArray;
}
// An ObjectLiteralExpression is the declaration node for an anonymous symbol.
export interface ObjectLiteralExpression extends PrimaryExpression, Declaration {
properties: NodeArray;
}
export interface PropertyAccessExpression extends MemberExpression {
expression: LeftHandSideExpression;
name: Identifier;
}
export interface ElementAccessExpression extends MemberExpression {
expression: LeftHandSideExpression;
argumentExpression?: Expression;
}
export interface CallExpression extends LeftHandSideExpression {
expression: LeftHandSideExpression;
typeArguments?: NodeArray;
arguments: NodeArray;
}
export interface NewExpression extends CallExpression, PrimaryExpression { }
export interface TaggedTemplateExpression extends MemberExpression {
tag: LeftHandSideExpression;
template: LiteralExpression | TemplateExpression;
}
export type CallLikeExpression = CallExpression | NewExpression | TaggedTemplateExpression;
export interface TypeAssertion extends UnaryExpression {
type: TypeNode;
expression: UnaryExpression;
}
export interface Statement extends Node, ModuleElement {
_statementBrand: any;
}
export interface Block extends Statement {
statements: NodeArray;
}
export interface VariableStatement extends Statement {
declarations: NodeArray;
}
export interface ExpressionStatement extends Statement {
expression: Expression;
}
export interface IfStatement extends Statement {
expression: Expression;
thenStatement: Statement;
elseStatement?: Statement;
}
export interface IterationStatement extends Statement {
statement: Statement;
}
export interface DoStatement extends IterationStatement {
expression: Expression;
}
export interface WhileStatement extends IterationStatement {
expression: Expression;
}
export interface ForStatement extends IterationStatement {
declarations?: NodeArray;
initializer?: Expression;
condition?: Expression;
iterator?: Expression;
}
export interface ForInStatement extends IterationStatement {
declarations?: NodeArray;
variable?: Expression;
expression: Expression;
}
export interface BreakOrContinueStatement extends Statement {
label?: Identifier;
}
export interface ReturnStatement extends Statement {
expression?: Expression;
}
export interface WithStatement extends Statement {
expression: Expression;
statement: Statement;
}
export interface SwitchStatement extends Statement {
expression: Expression;
clauses: NodeArray;
}
export interface CaseClause extends Node {
expression?: Expression;
statements: NodeArray;
}
export interface DefaultClause extends Node {
statements: NodeArray;
}
export type CaseOrDefaultClause = CaseClause | DefaultClause;
export interface LabeledStatement extends Statement {
label: Identifier;
statement: Statement;
}
export interface ThrowStatement extends Statement {
expression: Expression;
}
export interface TryStatement extends Statement {
tryBlock: Block;
catchClause?: CatchClause;
finallyBlock?: Block;
}
export interface CatchClause extends Declaration {
name: Identifier;
type?: TypeNode;
block: Block;
}
export interface ModuleElement extends Node {
_moduleElementBrand: any;
}
export interface ClassDeclaration extends Declaration, ModuleElement {
name: Identifier;
typeParameters?: NodeArray;
heritageClauses?: NodeArray;
members: NodeArray;
}
export interface ClassElement extends Declaration {
_classElementBrand: any;
}
export interface InterfaceDeclaration extends Declaration, ModuleElement {
name: Identifier;
typeParameters?: NodeArray;
heritageClauses?: NodeArray;
members: NodeArray;
}
export interface HeritageClause extends Node {
token: SyntaxKind;
types?: NodeArray;
}
export interface TypeAliasDeclaration extends Declaration, ModuleElement {
name: Identifier;
type: TypeNode;
}
export interface EnumMember extends Declaration {
// This does include ComputedPropertyName, but the parser will give an error
// if it parses a ComputedPropertyName in an EnumMember
name: DeclarationName;
initializer?: Expression;
}
export interface EnumDeclaration extends Declaration, ModuleElement {
name: Identifier;
members: NodeArray;
}
export interface ModuleDeclaration extends Declaration, ModuleElement {
name: Identifier | LiteralExpression;
body: ModuleBlock | ModuleDeclaration;
}
export interface ModuleBlock extends Node, ModuleElement {
statements: NodeArray
}
export interface ImportDeclaration extends Declaration, ModuleElement {
name: Identifier;
// 'EntityName' for an internal module reference, 'ExternalModuleReference' for an external
// module reference.
moduleReference: EntityName | ExternalModuleReference;
}
export interface ExternalModuleReference extends Node {
expression?: Expression;
}
export interface ExportAssignment extends Statement, ModuleElement {
exportName: Identifier;
}
export interface FileReference extends TextRange {
filename: string;
}
export interface CommentRange extends TextRange {
hasTrailingNewLine?: boolean;
}
// Source files are declarations when they are external modules.
export interface SourceFile extends Declaration {
statements: NodeArray;
endOfFileToken: Node;
filename: string;
text: string;
getLineAndCharacterFromPosition(position: number): LineAndCharacter;
getPositionFromLineAndCharacter(line: number, character: number): number;
getLineStarts(): number[];
// Produces a new SourceFile for the 'newText' provided. The 'textChangeRange' parameter
// indicates what changed between the 'text' that this SourceFile has and the 'newText'.
// The SourceFile will be created with the compiler attempting to reuse as many nodes from
// this file as possible.
//
// Note: this function mutates nodes from this SourceFile. That means any existing nodes
// from this SourceFile that are being held onto may change as a result (including
// becoming detached from any SourceFile). It is recommended that this SourceFile not
// be used once 'update' is called on it.
update(newText: string, textChangeRange: TextChangeRange): SourceFile;
amdDependencies: string[];
amdModuleName: string;
referencedFiles: FileReference[];
// Diagnostics reported about the "///;
}
export interface Program {
getSourceFile(filename: string): SourceFile;
getSourceFiles(): SourceFile[];
getCompilerOptions(): CompilerOptions;
getCompilerHost(): CompilerHost;
getDiagnostics(sourceFile?: SourceFile): Diagnostic[];
getGlobalDiagnostics(): Diagnostic[];
getTypeChecker(fullTypeCheckMode: boolean): TypeChecker;
getCommonSourceDirectory(): string;
}
export interface SourceMapSpan {
emittedLine: number; // Line number in the .js file
emittedColumn: number; // Column number in the .js file
sourceLine: number; // Line number in the .ts file
sourceColumn: number; // Column number in the .ts file
nameIndex?: number; // Optional name (index into names array) associated with this span
sourceIndex: number; // .ts file (index into sources array) associated with this span*/
}
export interface SourceMapData {
sourceMapFilePath: string; // Where the sourcemap file is written
jsSourceMappingURL: string; // source map URL written in the .js file
sourceMapFile: string; // Source map's file field - .js file name
sourceMapSourceRoot: string; // Source map's sourceRoot field - location where the sources will be present if not ""
sourceMapSources: string[]; // Source map's sources field - list of sources that can be indexed in this source map
inputSourceFileNames: string[]; // Input source file (which one can use on program to get the file), 1:1 mapping with the sourceMapSources list
sourceMapNames?: string[]; // Source map's names field - list of names that can be indexed in this source map
sourceMapMappings: string; // Source map's mapping field - encoded source map spans
sourceMapDecodedMappings: SourceMapSpan[]; // Raw source map spans that were encoded into the sourceMapMappings
}
// Return code used by getEmitOutput function to indicate status of the function
export enum EmitReturnStatus {
Succeeded = 0, // All outputs generated as requested (.js, .map, .d.ts), no errors reported
AllOutputGenerationSkipped = 1, // No .js generated because of syntax errors, nothing generated
JSGeneratedWithSemanticErrors = 2, // .js and .map generated with semantic errors
DeclarationGenerationSkipped = 3, // .d.ts generation skipped because of semantic errors or declaration emitter specific errors; Output .js with semantic errors
EmitErrorsEncountered = 4, // Emitter errors occurred during emitting process
CompilerOptionsErrors = 5, // Errors occurred in parsing compiler options, nothing generated
}
export interface EmitResult {
emitResultStatus: EmitReturnStatus;
diagnostics: Diagnostic[];
sourceMaps: SourceMapData[]; // Array of sourceMapData if compiler emitted sourcemaps
}
export interface TypeChecker {
getProgram(): Program;
getDiagnostics(sourceFile?: SourceFile): Diagnostic[];
getDeclarationDiagnostics(sourceFile: SourceFile): Diagnostic[];
getGlobalDiagnostics(): Diagnostic[];
getNodeCount(): number;
getIdentifierCount(): number;
getSymbolCount(): number;
getTypeCount(): number;
emitFiles(targetSourceFile?: SourceFile): EmitResult;
getTypeOfSymbolAtLocation(symbol: Symbol, node: Node): Type;
getDeclaredTypeOfSymbol(symbol: Symbol): Type;
getPropertiesOfType(type: Type): Symbol[];
getPropertyOfType(type: Type, propertyName: string): Symbol;
getSignaturesOfType(type: Type, kind: SignatureKind): Signature[];
getIndexTypeOfType(type: Type, kind: IndexKind): Type;
getReturnTypeOfSignature(signature: Signature): Type;
getSymbolsInScope(location: Node, meaning: SymbolFlags): Symbol[];
getSymbolAtLocation(node: Node): Symbol;
getShorthandAssignmentValueSymbol(location: Node): Symbol;
getTypeAtLocation(node: Node): Type;
typeToString(type: Type, enclosingDeclaration?: Node, flags?: TypeFormatFlags): string;
symbolToString(symbol: Symbol, enclosingDeclaration?: Node, meaning?: SymbolFlags): string;
getSymbolDisplayBuilder(): SymbolDisplayBuilder;
getFullyQualifiedName(symbol: Symbol): string;
getAugmentedPropertiesOfType(type: Type): Symbol[];
getRootSymbols(symbol: Symbol): Symbol[];
getContextualType(node: Expression): Type;
getResolvedSignature(node: CallLikeExpression, candidatesOutArray?: Signature[]): Signature;
getSignatureFromDeclaration(declaration: SignatureDeclaration): Signature;
isImplementationOfOverload(node: FunctionLikeDeclaration): boolean;
isUndefinedSymbol(symbol: Symbol): boolean;
isArgumentsSymbol(symbol: Symbol): boolean;
isEmitBlocked(sourceFile?: SourceFile): boolean;
// Returns the constant value of this enum member, or 'undefined' if the enum member has a computed value.
getEnumMemberValue(node: EnumMember): number;
isValidPropertyAccess(node: PropertyAccessExpression | QualifiedName, propertyName: string): boolean;
getAliasedSymbol(symbol: Symbol): Symbol;
}
export interface SymbolDisplayBuilder {
buildTypeDisplay(type: Type, writer: SymbolWriter, enclosingDeclaration?: Node, flags?: TypeFormatFlags): void;
buildSymbolDisplay(symbol: Symbol, writer: SymbolWriter, enclosingDeclaration?: Node, meaning?: SymbolFlags, flags?: SymbolFormatFlags): void;
buildSignatureDisplay(signatures: Signature, writer: SymbolWriter, enclosingDeclaration?: Node, flags?: TypeFormatFlags): void;
buildParameterDisplay(parameter: Symbol, writer: SymbolWriter, enclosingDeclaration?: Node, flags?: TypeFormatFlags): void;
buildTypeParameterDisplay(tp: TypeParameter, writer: SymbolWriter, enclosingDeclaration?: Node, flags?: TypeFormatFlags): void;
buildTypeParameterDisplayFromSymbol(symbol: Symbol, writer: SymbolWriter, enclosingDeclaraiton?: Node, flags?: TypeFormatFlags): void;
buildDisplayForParametersAndDelimiters(parameters: Symbol[], writer: SymbolWriter, enclosingDeclaration?: Node, flags?: TypeFormatFlags): void;
buildDisplayForTypeParametersAndDelimiters(typeParameters: TypeParameter[], writer: SymbolWriter, enclosingDeclaration?: Node, flags?: TypeFormatFlags): void;
buildReturnTypeDisplay(signature: Signature, writer: SymbolWriter, enclosingDeclaration?: Node, flags?: TypeFormatFlags): void;
}
export interface SymbolWriter {
writeKeyword(text: string): void;
writeOperator(text: string): void;
writePunctuation(text: string): void;
writeSpace(text: string): void;
writeStringLiteral(text: string): void;
writeParameter(text: string): void;
writeSymbol(text: string, symbol: Symbol): void;
writeLine(): void;
increaseIndent(): void;
decreaseIndent(): void;
clear(): void;
// Called when the symbol writer encounters a symbol to write. Currently only used by the
// declaration emitter to help determine if it should patch up the final declaration file
// with import statements it previously saw (but chose not to emit).
trackSymbol(symbol: Symbol, enclosingDeclaration?: Node, meaning?: SymbolFlags): void;
}
export const enum TypeFormatFlags {
None = 0x00000000,
WriteArrayAsGenericType = 0x00000001, // Write Array instead T[]
UseTypeOfFunction = 0x00000002, // Write typeof instead of function type literal
NoTruncation = 0x00000004, // Don't truncate typeToString result
WriteArrowStyleSignature = 0x00000008, // Write arrow style signature
WriteOwnNameForAnyLike = 0x00000010, // Write symbol's own name instead of 'any' for any like types (eg. unknown, __resolving__ etc)
WriteTypeArgumentsOfSignature = 0x00000020, // Write the type arguments instead of type parameters of the signature
InElementType = 0x00000040, // Writing an array or union element type
}
export const enum SymbolFormatFlags {
None = 0x00000000,
WriteTypeParametersOrArguments = 0x00000001, // Write symbols's type argument if it is instantiated symbol
// eg. class C { p: T } <-- Show p as C.p here
// var a: C;
// var p = a.p; <--- Here p is property of C so show it as C.p instead of just C.p
UseOnlyExternalAliasing = 0x00000002, // Use only external alias information to get the symbol name in the given context
// eg. module m { export class c { } } import x = m.c;
// When this flag is specified m.c will be used to refer to the class instead of alias symbol x
}
export const enum SymbolAccessibility {
Accessible,
NotAccessible,
CannotBeNamed
}
export interface SymbolVisibilityResult {
accessibility: SymbolAccessibility;
aliasesToMakeVisible?: ImportDeclaration[]; // aliases that need to have this symbol visible
errorSymbolName?: string; // Optional symbol name that results in error
errorNode?: Node; // optional node that results in error
}
export interface SymbolAccessiblityResult extends SymbolVisibilityResult {
errorModuleName?: string // If the symbol is not visible from module, module's name
}
export interface EmitResolver {
getProgram(): Program;
getLocalNameOfContainer(container: ModuleDeclaration | EnumDeclaration): string;
getExpressionNamePrefix(node: Identifier): string;
getExportAssignmentName(node: SourceFile): string;
isReferencedImportDeclaration(node: ImportDeclaration): boolean;
isTopLevelValueImportWithEntityName(node: ImportDeclaration): boolean;
getNodeCheckFlags(node: Node): NodeCheckFlags;
getEnumMemberValue(node: EnumMember): number;
hasSemanticErrors(sourceFile?: SourceFile): boolean;
isDeclarationVisible(node: Declaration): boolean;
isImplementationOfOverload(node: FunctionLikeDeclaration): boolean;
writeTypeOfDeclaration(declaration: AccessorDeclaration | VariableLikeDeclaration, enclosingDeclaration: Node, flags: TypeFormatFlags, writer: SymbolWriter): void;
writeReturnTypeOfSignatureDeclaration(signatureDeclaration: SignatureDeclaration, enclosingDeclaration: Node, flags: TypeFormatFlags, writer: SymbolWriter): void;
isSymbolAccessible(symbol: Symbol, enclosingDeclaration: Node, meaning: SymbolFlags): SymbolAccessiblityResult;
isEntityNameVisible(entityName: EntityName, enclosingDeclaration: Node): SymbolVisibilityResult;
// Returns the constant value this property access resolves to, or 'undefined' for a non-constant
getConstantValue(node: PropertyAccessExpression | ElementAccessExpression): number;
isEmitBlocked(sourceFile?: SourceFile): boolean;
isUnknownIdentifier(location: Node, name: string): boolean;
}
export const enum SymbolFlags {
FunctionScopedVariable = 0x00000001, // Variable (var) or parameter
BlockScopedVariable = 0x00000002, // A block-scoped variable (let or const)
Property = 0x00000004, // Property or enum member
EnumMember = 0x00000008, // Enum member
Function = 0x00000010, // Function
Class = 0x00000020, // Class
Interface = 0x00000040, // Interface
ConstEnum = 0x00000080, // Const enum
RegularEnum = 0x00000100, // Enum
ValueModule = 0x00000200, // Instantiated module
NamespaceModule = 0x00000400, // Uninstantiated module
TypeLiteral = 0x00000800, // Type Literal
ObjectLiteral = 0x00001000, // Object Literal
Method = 0x00002000, // Method
Constructor = 0x00004000, // Constructor
GetAccessor = 0x00008000, // Get accessor
SetAccessor = 0x00010000, // Set accessor
Signature = 0x00020000, // Call, construct, or index signature
TypeParameter = 0x00040000, // Type parameter
TypeAlias = 0x00080000, // Type alias
// Export markers (see comment in declareModuleMember in binder)
ExportValue = 0x00100000, // Exported value marker
ExportType = 0x00200000, // Exported type marker
ExportNamespace = 0x00400000, // Exported namespace marker
Import = 0x00800000, // Import
Instantiated = 0x01000000, // Instantiated symbol
Merged = 0x02000000, // Merged symbol (created during program binding)
Transient = 0x04000000, // Transient symbol (created during type check)
Prototype = 0x08000000, // Prototype property (no source representation)
UnionProperty = 0x10000000, // Property in union type
Optional = 0x20000000, // Optional property
Enum = RegularEnum | ConstEnum,
Variable = FunctionScopedVariable | BlockScopedVariable,
Value = Variable | Property | EnumMember | Function | Class | Enum | ValueModule | Method | GetAccessor | SetAccessor,
Type = Class | Interface | Enum | TypeLiteral | ObjectLiteral | TypeParameter | TypeAlias,
Namespace = ValueModule | NamespaceModule,
Module = ValueModule | NamespaceModule,
Accessor = GetAccessor | SetAccessor,
// Variables can be redeclared, but can not redeclare a block-scoped declaration with the
// same name, or any other value that is not a variable, e.g. ValueModule or Class
FunctionScopedVariableExcludes = Value & ~FunctionScopedVariable,
// Block-scoped declarations are not allowed to be re-declared
// they can not merge with anything in the value space
BlockScopedVariableExcludes = Value,
ParameterExcludes = Value,
PropertyExcludes = Value,
EnumMemberExcludes = Value,
FunctionExcludes = Value & ~(Function | ValueModule),
ClassExcludes = (Value | Type) & ~ValueModule,
InterfaceExcludes = Type & ~Interface,
RegularEnumExcludes = (Value | Type) & ~(RegularEnum | ValueModule), // regular enums merge only with regular enums and modules
ConstEnumExcludes = (Value | Type) & ~ConstEnum, // const enums merge only with const enums
ValueModuleExcludes = Value & ~(Function | Class | RegularEnum | ValueModule),
NamespaceModuleExcludes = 0,
MethodExcludes = Value & ~Method,
GetAccessorExcludes = Value & ~SetAccessor,
SetAccessorExcludes = Value & ~GetAccessor,
TypeParameterExcludes = Type & ~TypeParameter,
TypeAliasExcludes = Type,
ImportExcludes = Import, // Imports collide with all other imports with the same name
ModuleMember = Variable | Function | Class | Interface | Enum | Module | TypeAlias | Import,
ExportHasLocal = Function | Class | Enum | ValueModule,
HasLocals = Function | Module | Method | Constructor | Accessor | Signature,
HasExports = Class | Enum | Module,
HasMembers = Class | Interface | TypeLiteral | ObjectLiteral,
IsContainer = HasLocals | HasExports | HasMembers,
PropertyOrAccessor = Property | Accessor,
Export = ExportNamespace | ExportType | ExportValue,
}
export interface Symbol {
flags: SymbolFlags; // Symbol flags
name: string; // Name of symbol
id?: number; // Unique id (used to look up SymbolLinks)
mergeId?: number; // Merge id (used to look up merged symbol)
declarations?: Declaration[]; // Declarations associated with this symbol
parent?: Symbol; // Parent symbol
members?: SymbolTable; // Class, interface or literal instance members
exports?: SymbolTable; // Module exports
exportSymbol?: Symbol; // Exported symbol associated with this symbol
valueDeclaration?: Declaration // First value declaration of the symbol,
constEnumOnlyModule?: boolean // For modules - if true - module contains only const enums or other modules with only const enums.
}
export interface SymbolLinks {
target?: Symbol; // Resolved (non-alias) target of an alias
type?: Type; // Type of value symbol
declaredType?: Type; // Type of class, interface, enum, or type parameter
mapper?: TypeMapper; // Type mapper for instantiation alias
referenced?: boolean; // True if alias symbol has been referenced as a value
exportAssignSymbol?: Symbol; // Symbol exported from external module
unionType?: UnionType; // Containing union type for union property
}
export interface TransientSymbol extends Symbol, SymbolLinks { }
export interface SymbolTable {
[index: string]: Symbol;
}
export const enum NodeCheckFlags {
TypeChecked = 0x00000001, // Node has been type checked
LexicalThis = 0x00000002, // Lexical 'this' reference
CaptureThis = 0x00000004, // Lexical 'this' used in body
EmitExtends = 0x00000008, // Emit __extends
SuperInstance = 0x00000010, // Instance 'super' reference
SuperStatic = 0x00000020, // Static 'super' reference
ContextChecked = 0x00000040, // Contextual types have been assigned
// Values for enum members have been computed, and any errors have been reported for them.
EnumValuesComputed = 0x00000080,
}
export interface NodeLinks {
resolvedType?: Type; // Cached type of type node
resolvedSignature?: Signature; // Cached signature of signature node or call expression
resolvedSymbol?: Symbol; // Cached name resolution result
flags?: NodeCheckFlags; // Set of flags specific to Node
enumMemberValue?: number; // Constant value of enum member
isIllegalTypeReferenceInConstraint?: boolean; // Is type reference in constraint refers to the type parameter from the same list
isVisible?: boolean; // Is this node visible
localModuleName?: string; // Local name for module instance
assignmentChecks?: Map; // Cache of assignment checks
}
export const enum TypeFlags {
Any = 0x00000001,
String = 0x00000002,
Number = 0x00000004,
Boolean = 0x00000008,
Void = 0x00000010,
Undefined = 0x00000020,
Null = 0x00000040,
Enum = 0x00000080, // Enum type
StringLiteral = 0x00000100, // String literal type
TypeParameter = 0x00000200, // Type parameter
Class = 0x00000400, // Class
Interface = 0x00000800, // Interface
Reference = 0x00001000, // Generic type reference
Tuple = 0x00002000, // Tuple
Union = 0x00004000, // Union
Anonymous = 0x00008000, // Anonymous
FromSignature = 0x00010000, // Created for signature assignment check
Unwidened = 0x00020000, // Unwidened type (is or contains Undefined or Null type)
Intrinsic = Any | String | Number | Boolean | Void | Undefined | Null,
StringLike = String | StringLiteral,
NumberLike = Number | Enum,
ObjectType = Class | Interface | Reference | Tuple | Anonymous,
}
// Properties common to all types
export interface Type {
flags: TypeFlags; // Flags
id: number; // Unique ID
symbol?: Symbol; // Symbol associated with type (if any)
}
// Intrinsic types (TypeFlags.Intrinsic)
export interface IntrinsicType extends Type {
intrinsicName: string; // Name of intrinsic type
}
// String literal types (TypeFlags.StringLiteral)
export interface StringLiteralType extends Type {
text: string; // Text of string literal
}
// Object types (TypeFlags.ObjectType)
export interface ObjectType extends Type { }
// Class and interface types (TypeFlags.Class and TypeFlags.Interface)
export interface InterfaceType extends ObjectType {
typeParameters: TypeParameter[]; // Type parameters (undefined if non-generic)
baseTypes: ObjectType[]; // Base types
declaredProperties: Symbol[]; // Declared members
declaredCallSignatures: Signature[]; // Declared call signatures
declaredConstructSignatures: Signature[]; // Declared construct signatures
declaredStringIndexType: Type; // Declared string index type
declaredNumberIndexType: Type; // Declared numeric index type
}
// Type references (TypeFlags.Reference)
export interface TypeReference extends ObjectType {
target: GenericType; // Type reference target
typeArguments: Type[]; // Type reference type arguments
}
// Generic class and interface types
export interface GenericType extends InterfaceType, TypeReference {
instantiations: Map; // Generic instantiation cache
openReferenceTargets: GenericType[]; // Open type reference targets
openReferenceChecks: Map; // Open type reference check cache
}
export interface TupleType extends ObjectType {
elementTypes: Type[]; // Element types
baseArrayType: TypeReference; // Array where T is best common type of element types
}
export interface UnionType extends Type {
types: Type[]; // Constituent types
resolvedProperties: SymbolTable; // Cache of resolved properties
}
// Resolved object or union type
export interface ResolvedType extends ObjectType, UnionType {
members: SymbolTable; // Properties by name
properties: Symbol[]; // Properties
callSignatures: Signature[]; // Call signatures of type
constructSignatures: Signature[]; // Construct signatures of type
stringIndexType: Type; // String index type
numberIndexType: Type; // Numeric index type
}
// Type parameters (TypeFlags.TypeParameter)
export interface TypeParameter extends Type {
constraint: Type; // Constraint
target?: TypeParameter; // Instantiation target
mapper?: TypeMapper; // Instantiation mapper
}
export const enum SignatureKind {
Call,
Construct,
}
export interface Signature {
declaration: SignatureDeclaration; // Originating declaration
typeParameters: TypeParameter[]; // Type parameters (undefined if non-generic)
parameters: Symbol[]; // Parameters
resolvedReturnType: Type; // Resolved return type
minArgumentCount: number; // Number of non-optional parameters
hasRestParameter: boolean; // True if last parameter is rest parameter
hasStringLiterals: boolean; // True if specialized
target?: Signature; // Instantiation target
mapper?: TypeMapper; // Instantiation mapper
unionSignatures?: Signature[]; // Underlying signatures of a union signature
erasedSignatureCache?: Signature; // Erased version of signature (deferred)
isolatedSignatureType?: ObjectType; // A manufactured type that just contains the signature for purposes of signature comparison
}
export const enum IndexKind {
String,
Number,
}
export interface TypeMapper {
(t: Type): Type;
}
export interface TypeInferences {
primary: Type[]; // Inferences made directly to a type parameter
secondary: Type[]; // Inferences made to a type parameter in a union type
}
export interface InferenceContext {
typeParameters: TypeParameter[]; // Type parameters for which inferences are made
inferUnionTypes: boolean; // Infer union types for disjoint candidates (otherwise undefinedType)
inferences: TypeInferences[]; // Inferences made for each type parameter
inferredTypes: Type[]; // Inferred type for each type parameter
failedTypeParameterIndex?: number; // Index of type parameter for which inference failed
// It is optional because in contextual signature instantiation, nothing fails
}
export interface DiagnosticMessage {
key: string;
category: DiagnosticCategory;
code: number;
isEarly?: boolean;
}
// A linked list of formatted diagnostic messages to be used as part of a multiline message.
// It is built from the bottom up, leaving the head to be the "main" diagnostic.
// While it seems that DiagnosticMessageChain is structurally similar to DiagnosticMessage,
// the difference is that messages are all preformatted in DMC.
export interface DiagnosticMessageChain {
messageText: string;
category: DiagnosticCategory;
code: number;
next?: DiagnosticMessageChain;
}
export interface Diagnostic {
file: SourceFile;
start: number;
length: number;
messageText: string;
category: DiagnosticCategory;
code: number;
/**
* Early error - any error (can be produced at parsing\binding\typechecking step) that blocks emit
*/
isEarly?: boolean;
}
export enum DiagnosticCategory {
Warning,
Error,
Message,
}
export interface CompilerOptions {
allowNonTsExtensions?: boolean;
charset?: string;
codepage?: number;
declaration?: boolean;
diagnostics?: boolean;
emitBOM?: boolean;
help?: boolean;
locale?: string;
mapRoot?: string;
module?: ModuleKind;
noEmitOnError?: boolean;
noErrorTruncation?: boolean;
noImplicitAny?: boolean;
noLib?: boolean;
noLibCheck?: boolean;
noResolve?: boolean;
out?: string;
outDir?: string;
preserveConstEnums?: boolean;
removeComments?: boolean;
sourceMap?: boolean;
sourceRoot?: string;
suppressImplicitAnyIndexErrors?: boolean;
target?: ScriptTarget;
version?: boolean;
watch?: boolean;
[option: string]: string | number | boolean;
}
export const enum ModuleKind {
None = 0,
CommonJS = 1,
AMD = 2,
}
export interface LineAndCharacter {
line: number;
/*
* This value denotes the character position in line and is different from the 'column' because of tab characters.
*/
character: number;
}
export const enum ScriptTarget {
ES3 = 0,
ES5 = 1,
ES6 = 2,
Latest = ES6,
}
export interface ParsedCommandLine {
options: CompilerOptions;
filenames: string[];
errors: Diagnostic[];
}
export interface CommandLineOption {
name: string;
type: string | Map; // "string", "number", "boolean", or an object literal mapping named values to actual values
shortName?: string; // A short mnemonic for convenience - for instance, 'h' can be used in place of 'help'.
description?: DiagnosticMessage; // The message describing what the command line switch does
paramType?: DiagnosticMessage; // The name to be used for a non-boolean option's parameter.
error?: DiagnosticMessage; // The error given when the argument does not fit a customized 'type'.
}
export const enum CharacterCodes {
nullCharacter = 0,
maxAsciiCharacter = 0x7F,
lineFeed = 0x0A, // \n
carriageReturn = 0x0D, // \r
lineSeparator = 0x2028,
paragraphSeparator = 0x2029,
nextLine = 0x0085,
// Unicode 3.0 space characters
space = 0x0020, // " "
nonBreakingSpace = 0x00A0, //
enQuad = 0x2000,
emQuad = 0x2001,
enSpace = 0x2002,
emSpace = 0x2003,
threePerEmSpace = 0x2004,
fourPerEmSpace = 0x2005,
sixPerEmSpace = 0x2006,
figureSpace = 0x2007,
punctuationSpace = 0x2008,
thinSpace = 0x2009,
hairSpace = 0x200A,
zeroWidthSpace = 0x200B,
narrowNoBreakSpace = 0x202F,
ideographicSpace = 0x3000,
mathematicalSpace = 0x205F,
ogham = 0x1680,
_ = 0x5F,
$ = 0x24,
_0 = 0x30,
_1 = 0x31,
_2 = 0x32,
_3 = 0x33,
_4 = 0x34,
_5 = 0x35,
_6 = 0x36,
_7 = 0x37,
_8 = 0x38,
_9 = 0x39,
a = 0x61,
b = 0x62,
c = 0x63,
d = 0x64,
e = 0x65,
f = 0x66,
g = 0x67,
h = 0x68,
i = 0x69,
j = 0x6A,
k = 0x6B,
l = 0x6C,
m = 0x6D,
n = 0x6E,
o = 0x6F,
p = 0x70,
q = 0x71,
r = 0x72,
s = 0x73,
t = 0x74,
u = 0x75,
v = 0x76,
w = 0x77,
x = 0x78,
y = 0x79,
z = 0x7A,
A = 0x41,
B = 0x42,
C = 0x43,
D = 0x44,
E = 0x45,
F = 0x46,
G = 0x47,
H = 0x48,
I = 0x49,
J = 0x4A,
K = 0x4B,
L = 0x4C,
M = 0x4D,
N = 0x4E,
O = 0x4F,
P = 0x50,
Q = 0x51,
R = 0x52,
S = 0x53,
T = 0x54,
U = 0x55,
V = 0x56,
W = 0x57,
X = 0x58,
Y = 0x59,
Z = 0x5a,
ampersand = 0x26, // &
asterisk = 0x2A, // *
at = 0x40, // @
backslash = 0x5C, // \
backtick = 0x60, // `
bar = 0x7C, // |
caret = 0x5E, // ^
closeBrace = 0x7D, // }
closeBracket = 0x5D, // ]
closeParen = 0x29, // )
colon = 0x3A, // :
comma = 0x2C, // ,
dot = 0x2E, // .
doubleQuote = 0x22, // "
equals = 0x3D, // =
exclamation = 0x21, // !
greaterThan = 0x3E, // >
lessThan = 0x3C, // <
minus = 0x2D, // -
openBrace = 0x7B, // {
openBracket = 0x5B, // [
openParen = 0x28, // (
percent = 0x25, // %
plus = 0x2B, // +
question = 0x3F, // ?
semicolon = 0x3B, // ;
singleQuote = 0x27, // '
slash = 0x2F, // /
tilde = 0x7E, // ~
backspace = 0x08, // \b
formFeed = 0x0C, // \f
byteOrderMark = 0xFEFF,
tab = 0x09, // \t
verticalTab = 0x0B, // \v
}
export interface CancellationToken {
isCancellationRequested(): boolean;
}
export interface CompilerHost {
getSourceFile(filename: string, languageVersion: ScriptTarget, onError?: (message: string) => void): SourceFile;
getDefaultLibFilename(options: CompilerOptions): string;
getCancellationToken? (): CancellationToken;
writeFile(filename: string, data: string, writeByteOrderMark: boolean, onError?: (message: string) => void): void;
getCurrentDirectory(): string;
getCanonicalFileName(fileName: string): string;
useCaseSensitiveFileNames(): boolean;
getNewLine(): string;
}
export interface TextSpan {
start(): number;
length(): number;
end(): number;
isEmpty(): boolean;
containsPosition(position: number): boolean;
containsTextSpan(span: TextSpan): boolean;
overlapsWith(span: TextSpan): boolean;
overlap(span: TextSpan): TextSpan;
intersectsWithTextSpan(span: TextSpan): boolean;
intersectsWith(start: number, length: number): boolean;
intersectsWithPosition(position: number): boolean;
intersection(span: TextSpan): TextSpan;
}
export interface TextChangeRange {
span(): TextSpan;
newLength(): number;
newSpan(): TextSpan;
isUnchanged(): boolean;
}
}