Mithril 2.0.1

route(root, defaultRoute, routes)


Description

Navigate between "pages" within an application

var Home = {
    view: function() {
        return "Welcome"
    }
}

m.route(document.body, "/home", {
    "/home": Home, // defines `https://localhost/#!/home`
})

You can only have one m.route call per application.


Signature

m.route(root, defaultRoute, routes)

Argument Type Required Description
root Element Yes A DOM element that will be the parent node to the subtree
defaultRoute String Yes The route to redirect to if the current URL does not match a route
routes Object Yes An object whose keys are route strings and values are either components or a RouteResolver
returns Returns undefined

How to read signatures

Static members

m.route.set

Redirects to a matching route, or to the default route if no matching routes can be found. Triggers an asynchronous redraw off all mount points.

m.route.set(path, params, options)

Argument Type Required Description
path String Yes The path name to route to, without a prefix. The path may include parameters, interpolated with values from params.
params Object No Routing parameters. If path has routing parameter slots, the properties of this object are interpolated into the path string
options.replace Boolean No Whether to create a new history entry or to replace the current one. Defaults to false
options.state Object No The state object to pass to the underlying history.pushState / history.replaceState call. This state object becomes available in the history.state property, and is merged into the routing parameters object. Note that this option only works when using the pushState API, but is ignored if the router falls back to hashchange mode (i.e. if the pushState API is not available)
options.title String No The title string to pass to the underlying history.pushState / history.replaceState call.
returns Returns undefined

Remember that when using .set with params you also need to define the route:

var Article = {
    view: function(vnode) {
        return "This is article " + vnode.attrs.articleid
    }
}

m.route(document.body, {
    '/article/:articleid': Article
})
m.route.set('/article/:articleid', {articleid: 1})
m.route.get

Returns the last fully resolved routing path, without the prefix. It may differ from the path displayed in the location bar while an asynchronous route is pending resolution.

path = m.route.get()

Argument Type Required Description
returns String Returns the last fully resolved path
m.route.prefix

Defines a router prefix. The router prefix is a fragment of the URL that dictates the underlying strategy used by the router.

m.route.prefix = prefix

Argument Type Required Description
prefix String Yes The prefix that controls the underlying routing strategy used by Mithril.

This is a simple property, so you can both read it and write to it.

This component can create a dynamic routable link:

m(m.route.Link, {href: "/test"})

Using m.route.Link causes the link to behave as a router link - clicking it navigates to the route specified in href, instead of navigating away from the current page to the URL specified in href.

You can also set the options passed to m.route.set when the link is clicked by passing the options attribute:

m(m.route.Link, {href: "/test", options: {replace: true}})

You can pass other attributes, too, and you can also specify the tag name used.

m(m.route.Link, {
    // Any hyperscript selector is valid here - it's literally passed as the
    // first parameter to `m`.
    selector: "span",
    options: {replace: true},
    href: "/test",
    disabled: false,
    class: "nav-link",
    "data-foo": 1,
    // and other attributes
}, "link name")

Magic attributes used by this selector (except href and disabled) are removed while proxying, so you won't have an odd selector="span" or options="[object Object]" attribute show up in your link's DOM node. The above vnode renders to this hyperscript, assuming the prefix is the default #!:

m("span", {
    href: "#!/test",
    onclick: function(e) {
        // ...
    },
    disabled: false, // Only if you specify it
    class: "nav-link",
    "data-foo": 1,
    // and other attributes
})

You can also prevent navigation by, in an onclick handler, invoking ev.preventDefault() or returning false. This is the same way you block other events, so it's pretty natural.

m(m.route.Link, {
    href: "/test",
    onclick: function(e) {
        // Do things...
        if (notReady()) e.preventDefault()
    }
}, "link name")

This supports full accessibility for both a and button, via a disabled attribute. This ensures no href attribute or onclick handler is set and that an "aria-disabled": "true" attribute is set. If you are passing an onclick handler already, that's dropped. (You can work around this by adding it directly in a lifecycle hook.) The disabled attribute is itself proxied to the element or component, so you can disable routed <button>s and the like.

// This does the right thing and the accessible thing for you.
m(m.route.Link, {disabled: disabled, href: "/test"}, "disabled")

// It renders to this hyperscript, assuming the prefix is the default one:
m("a", {
    href: "#!/test",
    disabled: disabled,
    "aria-disabled": disabled ? "true" : false,
    onclick: disabled ? null : function(e) {
        // ...
    },
})

Do note that this doesn't also disable pointer events for you - you have to do that yourself through CSS - this only does the JS part. Also, the removal of href can break certain style sheets - if you're relying on this to style disabled links, you may need to update your stylesheets accordingly. Chances are, you're probably just looking it up via a, .some-class, or #some-id, and if you are, you're already good to go. If you're using [href] or :link, in most cases you can just remove them and it'll still work - it's pretty common to over-specify selectors. If you can't do either, check for both [href]/:link and the non-standard [disabled] attribute that was implicitly forwarded to the component.

vnode = m(m.route.Link, attributes, children)

Argument Type Required Description
attributes.href Object Yes The target route to navigate to.
attributes.selector String|Object|Function No This sets the tag name to use. Must be a valid selector for m if given, defaults to "a".
attributes.options Object No This sets the options passed to m.route.set.
attributes.disabled Object No This sets the options passed to m.route.set.
attributes Object No Other attributes to apply to the returned vnode may be passed.
children Array<Vnode>|String|Number|Boolean No Child vnodes for this link.
returns Vnode A vnode.
m.route.param

Retrieves a route parameter from the last fully resolved route. A route parameter is a key-value pair. Route parameters may come from a few different places:

value = m.route.param(key)

Argument Type Required Description
key String No A route parameter name (e.g. id in route /users/:id, or page in path /users/1?page=3, or a key in history.state)
returns String|Object Returns a value for the specified key. If a key is not specified, it returns an object that contains all the interpolation keys

Note that in the onmatch function of a RouteResolver, the new route hasn't yet been fully resolved, and m.route.param() will return the parameters of the previous route, if any. onmatch receives the parameters of the new route as an argument.

m.route.SKIP

A special value that can be returned from a route resolver's onmatch to skip to the next route.

RouteResolver

A RouteResolver is a non-component object that contains an onmatch method and/or a render method. Both methods are optional, but at least one must be present.

If an object can be detected as a component (by the presence of a view method or by being a function/class), it will be treated as such even if it has onmatch or render methods. Since a RouteResolver is not a component, it does not have lifecycle methods.

As a rule of thumb, RouteResolvers should be in the same file as the m.route call, whereas component definitions should be in their own modules.

routeResolver = {onmatch, render}

When using components, you could think of them as special sugar for this route resolver, assuming your component is Home:

var routeResolver = {
    onmatch: function() { return Home },
    render: function(vnode) { return [vnode] },
}
routeResolver.onmatch

The onmatch hook is called when the router needs to find a component to render. It is called once per router path changes, but not on subsequent redraws while on the same path. It can be used to run logic before a component initializes (for example authentication logic, data preloading, redirection analytics tracking, etc)

This method also allows you to asynchronously define what component will be rendered, making it suitable for code splitting and asynchronous module loading. To render a component asynchronously return a promise that resolves to a component.

For more information on onmatch, see the advanced component resolution section

routeResolver.onmatch(args, requestedPath, route)

Argument Type Description
args Object The routing parameters
requestedPath String The router path requested by the last routing action, including interpolated routing parameter values, but without the prefix. When onmatch is called, the resolution for this path is not complete and m.route.get() still returns the previous path.
route String The router path requested by the last routing action, excluding interpolated routing parameter values
returns Component|Promise|undefined Returns a component or a promise that resolves to a component

If onmatch returns a component or a promise that resolves to a component, this component is used as the vnode.tag for the first argument in the RouteResolver's render method. Otherwise, vnode.tag is set to "div". Similarly, if the onmatch method is omitted, vnode.tag is also "div".

If onmatch returns a promise that gets rejected, the router redirects back to defaultRoute. You may override this behavior by calling .catch on the promise chain before returning it.

routeResolver.render

The render method is called on every redraw for a matching route. It is similar to the view method in components and it exists to simplify component composition. It also lets you escape from Mithril's normal behavior of replacing the entire subtree.

vnode = routeResolve.render(vnode)

Argument Type Description
vnode Object A vnode whose attributes object contains routing parameters. If onmatch does not return a component or a promise that resolves to a component, the vnode's tag field defaults to "div"
vnode.attrs Object A map of URL parameter values
returns Array<Vnode>|Vnode The vnodes to be rendered

The vnode parameter is just m(Component, m.route.param()) where Component is the resolved component for the route (after routeResolver.onmatch) and m.route.param() is as documented here. If you omit this method, the default return value is [vnode], wrapped in a fragment so you can use key parameters. Combined with a :key parameter, it becomes a single-element keyed fragment, since it ends up rendering to something like [m(Component, {key: m.route.param("key"), ...})].


How it works

Routing is a system that allows creating Single Page Applications (SPA), i.e. applications that can go from a "page" to another without causing a full browser refresh.

It enables seamless navigability while preserving the ability to bookmark each page individually, and the ability to navigate the application via the browser's history mechanism.

Routing without page refreshes is made partially possible by the history.pushState API. Using this API, it's possible to programmatically change the URL displayed by the browser after a page has loaded, but it's the application developer's responsibility to ensure that navigating to any given URL from a cold state (e.g. a new tab) will render the appropriate markup.

Routing strategies

The routing strategy dictates how a library might actually implement routing. There are three general strategies that can be used to implement a SPA routing system, and each has different caveats:

Using the hash strategy is guaranteed to work in browsers that don't support history.pushState, because it can fall back to using onhashchange. Use this strategy if you want to keep the hashes purely local.

The querystring strategy allows server-side detection, but it doesn't appear as a normal path. Use this strategy if you want to support and potentially detect anchored links server-side and you are not able to make the changes necessary to support the pathname strategy (like if you're using Apache and can't modify your .htaccess).

The pathname strategy produces the cleanest looking URLs, but requires setting up the server to serve the single page application code from every URL that the application can route to. Use this strategy if you want cleaner-looking URLs.

Single page applications that use the hash strategy often use the convention of having an exclamation mark after the hash to indicate that they're using the hash as a routing mechanism and not for the purposes of linking to anchors. The #! string is known as a hashbang.

The default strategy uses the hashbang.


Typical usage

Normally, you need to create a few components to map routes to:

var Home = {
    view: function() {
        return [
            m(Menu),
            m("h1", "Home")
        ]
    }
}

var Page1 = {
    view: function() {
        return [
            m(Menu),
            m("h1", "Page 1")
        ]
    }
}

In the example above, there are two components: Home and Page1. Each contains a menu and some text. The menu is itself being defined as a component to avoid repetition:

var Menu = {
    view: function() {
        return m("nav", [
            m(m.route.Link, {href: "/"}, "Home"),
            m(m.route.Link, {href: "/page1"}, "Page 1"),
        ])
    }
}

Now we can define routes and map our components to them:

m.route(document.body, "/", {
    "/": Home,
    "/page1": Page1,
})

Here we specify two routes: / and /page1, which render their respective components when the user navigates to each URL.


In the example above, the Menu component has two m.route.Links. That creates an element, by default an <a>, and sets it up to where if the user clicks on it, it navigates to another route on its own. It doesn't navigate remotely, just locally.

You can also navigate programmatically, via m.route.set(route). For example, m.route.set("/page1").

When navigating between routes, the router prefix is handled for you. In other words, leave out the hashbang #! (or whatever prefix you set m.route.prefix to) when linking Mithril routes, including in both m.route.set and in m.route.Link.

Do note that when navigating between components, the entire subtree is replaced. Use a route resolver with a render method if you want to just patch the subtree.


Routing parameters

Sometimes we want to have a variable id or similar data appear in a route, but we don't want to explicitly specify a separate route for every possible id. In order to achieve that, Mithril supports parameterized routes:

var Edit = {
    view: function(vnode) {
        return [
            m(Menu),
            m("h1", "Editing " + vnode.attrs.id)
        ]
    }
}
m.route(document.body, "/edit/1", {
    "/edit/:id": Edit,
})

In the example above, we defined a route /edit/:id. This creates a dynamic route that matches any URL that starts with /edit/ and is followed by some data (e.g. /edit/1, edit/234, etc). The id value is then mapped as an attribute of the component's vnode (vnode.attrs.id)

It's possible to have multiple arguments in a route, for example /edit/:projectID/:userID would yield the properties projectID and userID on the component's vnode attributes object.

Key parameter

When a user navigates from a parameterized route to the same route with a different parameter (e.g. going from /page/1 to /page/2 given a route /page/:id, the component would not be recreated from scratch since both routes resolve to the same component, and thus result in a virtual dom in-place diff. This has the side-effect of triggering the onupdate hook, rather than oninit/oncreate. However, it's relatively common for a developer to want to synchronize the recreation of the component to the route change event.

To achieve that, it's possible to combine route parameterization with the virtual dom key reconciliation feature:

m.route(document.body, "/edit/1", {
    "/edit/:key": Edit,
})

This means that the vnode that is created for the root component of the route has a route parameter object key. Route parameters become attrs in the vnode. Thus, when jumping from one page to another, the key changes and causes the component to be recreated from scratch (since the key tells the virtual dom engine that old and new components are different entities).

You can take that idea further to create components that recreate themselves when reloaded:

m.route.set(m.route.get(), {key: Date.now()})

Or even use the history state feature to achieve reloadable components without polluting the URL:

m.route.set(m.route.get(), null, {state: {key: Date.now()}})

Note that the key parameter works only for component routes. If you're using a route resolver, you'll need to use a single-child keyed fragment, passing key: m.route.param("key"), to accomplish the same.

Variadic routes

It's also possible to have variadic routes, i.e. a route with an argument that contains URL pathnames that contain slashes:

m.route(document.body, "/edit/pictures/image.jpg", {
    "/edit/:file...": Edit,
})

Handling 404s

For isomorphic / universal JavaScript app, an url param and a variadic route combined is very useful to display custom 404 error page.

In a case of 404 Not Found error, the server send back the custom page to client. When Mithril is loaded, it will redirect client to the default route because it can't know that route.

m.route(document.body, "/", {
  "/": homeComponent,
  // [...]
  "/:404...": errorPageComponent
});

History state

It's possible to take full advantage of the underlying history.pushState API to improve user's navigation experience. For example, an application could "remember" the state of a large form when the user leaves a page by navigating away, such that if the user pressed the back button in the browser, they'd have the form filled rather than a blank form.

For example, you could create a form like this:

var state = {
    term: "",
    search: function() {
        // save the state for this route
        // this is equivalent to `history.replaceState({term: state.term}, null, location.href)`
        m.route.set(m.route.get(), null, {replace: true, state: {term: state.term}})

        // navigate away
        location.href = "https://google.com/?q=" + state.term
    }
}

var Form = {
    oninit: function(vnode) {
        state.term = vnode.attrs.term || "" // populated from the `history.state` property if the user presses the back button
    },
    view: function() {
        return m("form", [
            m("input[placeholder='Search']", {
                oninput: function (e) { state.term = e.target.value },
                value: state.term
            }),
            m("button", {onclick: state.search}, "Search")
        ])
    }
}

m.route(document.body, "/", {
    "/": Form,
})

This way, if the user searches and presses the back button to return to the application, the input will still be populated with the search term. This technique can improve the user experience of large forms and other apps where non-persisted state is laborious for a user to produce.


Changing router prefix

The router prefix is a fragment of the URL that dictates the underlying strategy used by the router.

// set to pathname strategy
m.route.prefix = ""

// set to querystring strategy
m.route.prefix = "?"

// set to hash without bang
m.route.prefix = "#"

// set to pathname strategy on a non-root URL
// e.g. if the app lives under `https://localhost/my-app` and something else
// lives under `https://localhost`
m.route.prefix = "/my-app"

Advanced component resolution

Instead of mapping a component to a route, you can specify a RouteResolver object. A RouteResolver object contains a onmatch() and/or a render() method. Both methods are optional but at least one of them must be present.

m.route(document.body, "/", {
    "/": {
        onmatch: function(args, requestedPath, route) {
            return Home
        },
        render: function(vnode) {
            return vnode // equivalent to m(Home)
        },
    }
})

RouteResolvers are useful for implementing a variety of advanced routing use cases.


Wrapping a layout component

It's often desirable to wrap all or most of the routed components in a reusable shell (often called a "layout"). In order to do that, you first need to create a component that contains the common markup that will wrap around the various different components:

var Layout = {
    view: function(vnode) {
        return m(".layout", vnode.children)
    }
}

In the example above, the layout merely consists of a <div class="layout"> that contains the children passed to the component, but in a real life scenario it could be as complex as needed.

One way to wrap the layout is to define an anonymous component in the routes map:

// example 1
m.route(document.body, "/", {
    "/": {
        view: function() {
            return m(Layout, m(Home))
        },
    },
    "/form": {
        view: function() {
            return m(Layout, m(Form))
        },
    }
})

However, note that because the top level component is an anonymous component, jumping from the / route to the /form route (or vice-versa) will tear down the anonymous component and recreate the DOM from scratch. If the Layout component had lifecycle methods defined, the oninit and oncreate hooks would fire on every route change. Depending on the application, this may or may not be desirable.

If you would prefer to have the Layout component be diffed and maintained intact rather than recreated from scratch, you should instead use a RouteResolver as the root object:

// example 2
m.route(document.body, "/", {
    "/": {
        render: function() {
            return m(Layout, m(Home))
        },
    },
    "/form": {
        render: function() {
            return m(Layout, m(Form))
        },
    }
})

Note that in this case, if the Layout component has oninit and oncreate lifecycle methods, they would only fire on the first route change (assuming all routes use the same layout).

To clarify the difference between the two examples, example 1 is equivalent to this code:

// functionally equivalent to example 1
var Anon1 = {
    view: function() {
        return m(Layout, m(Home))
    },
}
var Anon2 = {
    view: function() {
        return m(Layout, m(Form))
    },
}

m.route(document.body, "/", {
    "/": {
        render: function() {
            return m(Anon1)
        }
    },
    "/form": {
        render: function() {
            return m(Anon2)
        }
    },
})

Since Anon1 and Anon2 are different components, their subtrees (including Layout) are recreated from scratch. This is also what happens when components are used directly without a RouteResolver.

In example 2, since Layout is the top-level component in both routes, the DOM for the Layout component is diffed (i.e. left intact if it has no changes), and only the change from Home to Form triggers a recreation of that subsection of the DOM.


Authentication

The RouteResolver's onmatch hook can be used to run logic before the top level component in a route is initialized. The example below shows how to implement a login wall that prevents users from seeing the /secret page unless they login.

var isLoggedIn = false

var Login = {
    view: function() {
        return m("form", [
            m("button[type=button]", {
                onclick: function() {
                    isLoggedIn = true
                    m.route.set("/secret")
                }
            }, "Login")
        ])
    }
}

m.route(document.body, "/secret", {
    "/secret": {
        onmatch: function() {
            if (!isLoggedIn) m.route.set("/login")
            else return Home
        }
    },
    "/login": Login
})

When the application loads, onmatch is called and since isLoggedIn is false, the application redirects to /login. Once the user pressed the login button, isLoggedIn would be set to true, and the application would redirect to /secret. The onmatch hook would run once again, and since isLoggedIn is true this time, the application would render the Home component.

For the sake of simplicity, in the example above, the user's logged in status is kept in a global variable, and that flag is merely toggled when the user clicks the login button. In a real life application, a user would obviously have to supply proper login credentials, and clicking the login button would trigger a request to a server to authenticate the user:

var Auth = {
    username: "",
    password: "",

    setUsername: function(value) {
        Auth.username = value
    },
    setPassword: function(value) {
        Auth.password = value
    },
    login: function() {
        m.request({
            url: "/api/v1/auth",
            params: {username: Auth.username, password: Auth.password}
        }).then(function(data) {
            localStorage.setItem("auth-token", data.token)
            m.route.set("/secret")
        })
    }
}

var Login = {
    view: function() {
        return m("form", [
            m("input[type=text]", {
                oninput: function (e) { Auth.setUsername(e.target.value) },
                value: Auth.username
            }),
            m("input[type=password]", {
                oninput: function (e) { Auth.setPassword(e.target.value) },
                value: Auth.password
            }),
            m("button[type=button]", {onclick: Auth.login}, "Login")
        ])
    }
}

m.route(document.body, "/secret", {
    "/secret": {
        onmatch: function() {
            if (!localStorage.getItem("auth-token")) m.route.set("/login")
            else return Home
        }
    },
    "/login": Login
})

Preloading data

Typically, a component can load data upon initialization. Loading data this way renders the component twice. The first render pass occurs upon routing, and the second fires after the request completes. Take care to note that loadUsers() returns a Promise, but any Promise returned by oninit is currently ignored. The second render pass comes from the background option for m.request.

var state = {
    users: [],
    loadUsers: function() {
        return m.request("/api/v1/users").then(function(users) {
            state.users = users
        })
    }
}

m.route(document.body, "/user/list", {
    "/user/list": {
        oninit: state.loadUsers,
        view: function() {
            return state.users.length > 0 ? state.users.map(function(user) {
                return m("div", user.id)
            }) : "loading"
        }
    },
})

In the example above, on the first render, the UI displays "loading" since state.users is an empty array before the request completes. Then, once data is available, the UI redraws and a list of user ids is shown.

RouteResolvers can be used as a mechanism to preload data before rendering a component in order to avoid UI flickering and thus bypassing the need for a loading indicator:

var state = {
    users: [],
    loadUsers: function() {
        return m.request("/api/v1/users").then(function(users) {
            state.users = users
        })
    }
}

m.route(document.body, "/user/list", {
    "/user/list": {
        onmatch: state.loadUsers,
        render: function() {
            return state.users.map(function(user) {
                return m("div", user.id)
            })
        }
    },
})

Above, render only runs after the request completes, making the ternary operator redundant.


Code splitting

In a large application, it may be desirable to download the code for each route on demand, rather than upfront. Dividing the codebase this way is known as code splitting or lazy loading. In Mithril, this can be accomplished by returning a promise from the onmatch hook:

At its most basic form, one could do the following:

// Home.js
module.export = {
    view: function() {
        return [
            m(Menu),
            m("h1", "Home")
        ]
    }
}
// index.js
function load(file) {
    return m.request({
        method: "GET",
        url: file,
        extract: function(xhr) {
            return new Function("var module = {};" + xhr.responseText + ";return module.exports;")
        }
    })
}

m.route(document.body, "/", {
    "/": {
        onmatch: function() {
            return load("Home.js")
        },
    },
})

However, realistically, in order for that to work on a production scale, it would be necessary to bundle all of the dependencies for the Home.js module into the file that is ultimately served by the server.

Fortunately, there are a number of tools that facilitate the task of bundling modules for lazy loading. Here's an example using webpack's code splitting system:

m.route(document.body, "/", {
    "/": {
        onmatch: function() {
            // using Webpack async code splitting
            return new Promise(function(resolve) {
                require(['./Home.js'], resolve)
            })
        },
    },
})

Typed routes

In certain advanced routing cases, you may want to constrain a value further than just the path itself, only matching something like a numeric ID. You can do that pretty easily by returning m.route.SKIP from a route.

m.route(document.body, "/", {
    "/view/:id": {
        onmatch: function(args) {
            if (!/^\d+$/.test(args.id)) return m.route.SKIP
            return ItemView
        },
    },
    "/view/:name": UserView,
})

Hidden routes

In rare circumstances, you may want to hide certain routes for some users, but not all. For instance, a user might be prohibited from viewing a particular user, and instead of showing a permission error, you'd rather pretend it doesn't exist and redirect to a 404 view instead. In this case, you can use m.route.SKIP to just pretend the route doesn't exist.

m.route(document.body, "/", {
    "/user/:id": {
        onmatch: function(args) {
            return Model.checkViewable(args.id).then(function(viewable) {
                return viewable ? UserView : m.route.SKIP
            })
        },
    },
    "/:404...": PageNotFound,
})

Third-party integration

In certain situations, you may find yourself needing to interoperate with another framework like React. Here's how you do it:

Here's an example with React:

class Child extends React.Component {
    constructor(props) {
        super(props)
        this.root = React.createRef()
    }

    componentDidMount() {
        m.route(this.root, "/", {
            // ...
        })
    }

    componentDidUnmount() {
        m.mount(this.root, null)
    }

    render() {
        return <div ref={this.root} />
    }
}

And here's the rough equivalent with Vue:

<div ref="root"></div>
Vue.component("my-child", {
    template: `<div ref="root"></div>`,
    mounted: function() {
        m.route(this.$refs.root, "/", {
            // ...
        })
    },
    destroyed: function() {
        m.mount(this.$refs.root, null)
    },
})

Technically, there's nothing stopping you from even doing it in a Mithril component, even.

// Don't do this. Use a proper global layout component for each route instead,
// passing your child vnode/component in the attributes or children.
function Child() {
    return {
        oncreate: function(vnode) {
            m.route(vnode.dom, "/", {
                // ...
            })
        },

        onremove: function() {
            m.mount(vnode.dom, null)
        },

        view: function() {
            return m("div")
        },
    }
}

License: MIT. © Leo Horie.