Triple-slash directives are single-line comments containing a single XML tag. The contents of the comment are used as compiler directives.
Triple-slash directives are only valid at the top of their containing file. A triple-slash directive can only be preceded by single or multi-line comments, including other triple-slash directives. If they are encountered following a statement or a declaration they are treated as regular single-line comments, and hold no special meaning.
/// <reference path="..." />
#
The /// <reference path="..." />
directive is the most common of this group.
It serves as a declaration of dependency between files.
Triple-slash references instruct the compiler to include additional files in the compilation process.
They also serve as a method to order the output when using --out
or --outFile
.
Files are emitted to the output file location in the same order as the input after preprocessing pass.
Preprocessing input files #
The compiler performs a preprocessing pass on input files to resolve all triple-slash reference directives. During this process, additional files are added to the compilation.
The process starts with a set of root files;
these are the file names specified on the command-line or in the "files"
list in the tsconfig.json
file.
These root files are preprocessed in the same order they are specified.
Before a file is added to the list, all triple-slash references in it are processed, and their targets included.
Triple-slash references are resolved in a depth first manner, in the order they have been seen in the file.
A triple-slash reference path is resolved relative to the containing file, if unrooted.
Errors #
It is an error to reference a file that does not exist. It is an error for a file to have a triple-slash reference to itself.
Using --noResolve
#
If the compiler flag --noResolve
is specified, triple-slash references are ignored; they neither result in adding new files, nor change the order of the files provided.
/// <reference types="..." />
#
Similar to a /// <reference path="..." />
directive, which serves as a declaration of dependency, a /// <reference types="..." />
directive declares a dependency on a package.
The process of resolving these package names is similar to the process of resolving module names in an import
statement.
An easy way to think of triple-slash-reference-types directives are as an import
for declaration packages.
For example, including /// <reference types="node" />
in a declaration file declares that this file uses names declared in @types/node/index.d.ts
;
and thus, this package needs to be included in the compilation along with the declaration file.
Use these directives only when you’re authoring a d.ts
file by hand.
For declaration files generated during compilation, the compiler will automatically add /// <reference types="..." />
for you;
A /// <reference types="..." />
in a generated declaration file is added if and only if the resulting file uses any declarations from the referenced package.
For declaring a dependency on an @types
package in a .ts
file, use --types
on the command line or in your tsconfig.json
instead.
See using @types
, typeRoots
and types
in tsconfig.json
files for more details.
/// <reference lib="..." />
#
This directive allows a file to explicitly include an existing built-in lib file.
Built-in lib files are referenced in the same fashion as the "lib"
compiler option in tsconfig.json (e.g. use lib="es2015"
and not lib="lib.es2015.d.ts"
, etc.).
For declaration file authors who rely on built-in types, e.g. DOM APIs or built-in JS run-time constructors like Symbol
or Iterable
, triple-slash-reference lib directives are recommended. Previously these .d.ts files had to add forward/duplicate declarations of such types.
For example, adding /// <reference lib="es2017.string" />
to one of the files in a compilation is equivalent to compiling with --lib es2017.string
.
/// <reference lib="es2017.string" />
"foo".padStart(4);
/// <reference no-default-lib="true"/>
#
This directive marks a file as a default library.
You will see this comment at the top of lib.d.ts
and its different variants.
This directive instructs the compiler to not include the default library (i.e. lib.d.ts
) in the compilation.
The impact here is similar to passing --noLib
on the command line.
Also note that when passing --skipDefaultLibCheck
, the compiler will only skip checking files with /// <reference no-default-lib="true"/>
.
/// <amd-module />
#
By default AMD modules are generated anonymous.
This can lead to problems when other tools are used to process the resulting modules, such as bundlers (e.g. r.js
).
The amd-module
directive allows passing an optional module name to the compiler:
amdModule.ts #
///<amd-module name="NamedModule"/>
export class C {
}
Will result in assigning the name NamedModule
to the module as part of calling the AMD define
:
amdModule.js #
define("NamedModule", ["require", "exports"], function (require, exports) {
var C = (function () {
function C() {
}
return C;
})();
exports.C = C;
});
/// <amd-dependency />
#
Note: this directive has been deprecated. Use
import "moduleName";
statements instead.
/// <amd-dependency path="x" />
informs the compiler about a non-TS module dependency that needs to be injected in the resulting module’s require call.
The amd-dependency
directive can also have an optional name
property; this allows passing an optional name for an amd-dependency:
/// <amd-dependency path="legacy/moduleA" name="moduleA"/>
declare var moduleA:MyType
moduleA.callStuff()
Generated JS code:
define(["require", "exports", "legacy/moduleA"], function (require, exports, moduleA) {
moduleA.callStuff()
});