View Source Bindings
Phoenix supports DOM element bindings for client-server interaction. For example, to react to a click on a button, you would render the element:
<button phx-click="inc_temperature">+</button>
Then on the server, all LiveView bindings are handled with the handle_event
callback, for example:
def handle_event("inc_temperature", _value, socket) do
{:ok, new_temp} = Thermostat.inc_temperature(socket.assigns.id)
{:noreply, assign(socket, :temperature, new_temp)}
end
Binding | Attributes |
---|---|
Params | phx-value-* |
Click Events | phx-click , phx-click-away |
Form Events | phx-change , phx-submit , phx-feedback-for , phx-disable-with , phx-trigger-action , phx-auto-recover |
Focus Events | phx-blur , phx-focus , phx-window-blur , phx-window-focus |
Key Events | phx-keydown , phx-keyup , phx-window-keydown , phx-window-keyup , phx-key |
Scroll Events | phx-viewport-top , phx-viewport-bottom |
DOM Patching | phx-mounted , phx-update , phx-remove |
JS Interop | phx-hook |
Lifecycle Events | phx-mounted , phx-disconnected , phx-connected |
Rate Limiting | phx-debounce , phx-throttle |
Static tracking | phx-track-static |
Click Events
The phx-click
binding is used to send click events to the server.
When any client event, such as a phx-click
click is pushed, the value
sent to the server will be chosen with the following priority:
The
:value
specified inPhoenix.LiveView.JS.push/3
, such as:<div phx-click={JS.push("inc", value: %{myvar1: @val1})}>
Any number of optional
phx-value-
prefixed attributes, such as:<div phx-click="inc" phx-value-myvar1="val1" phx-value-myvar2="val2">
will send the following map of params to the server:
def handle_event("inc", %{"myvar1" => "val1", "myvar2" => "val2"}, socket) do
If the
phx-value-
prefix is used, the server payload will also contain a"value"
if the element's value attribute exists.The payload will also include any additional user defined metadata of the client event. For example, the following
LiveSocket
client option would send the coordinates andaltKey
information for all clicks:let liveSocket = new LiveSocket("/live", Socket, { params: {_csrf_token: csrfToken}, metadata: { click: (e, el) => { return { altKey: e.altKey, clientX: e.clientX, clientY: e.clientY } } } })
The phx-click-away
event is fired when a click event happens outside of the element.
This is useful for hiding toggled containers like drop-downs.
Focus and Blur Events
Focus and blur events may be bound to DOM elements that emit
such events, using the phx-blur
, and phx-focus
bindings, for example:
<input name="email" phx-focus="myfocus" phx-blur="myblur"/>
To detect when the page itself has received focus or blur,
phx-window-focus
and phx-window-blur
may be specified. These window
level events may also be necessary if the element in consideration
(most often a div
with no tabindex) cannot receive focus. Like other
bindings, phx-value-*
can be provided on the bound element, and those
values will be sent as part of the payload. For example:
<div class="container"
phx-window-focus="page-active"
phx-window-blur="page-inactive"
phx-value-page="123">
...
</div>
Key Events
The onkeydown
, and onkeyup
events are supported via the phx-keydown
,
and phx-keyup
bindings. Each binding supports a phx-key
attribute, which triggers
the event for the specific key press. If no phx-key
is provided, the event is triggered
for any key press. When pushed, the value sent to the server will contain the "key"
that was pressed, plus any user-defined metadata. For example, pressing the
Escape key looks like this:
%{"key" => "Escape"}
To capture additional user-defined metadata, the metadata
option for keydown events
may be provided to the LiveSocket
constructor. For example:
let liveSocket = new LiveSocket("/live", Socket, {
params: {_csrf_token: csrfToken},
metadata: {
keydown: (e, el) => {
return {
key: e.key,
metaKey: e.metaKey,
repeat: e.repeat
}
}
}
})
To determine which key has been pressed you should use key
value. The
available options can be found on
MDN
or via the Key Event Viewer.
Note: it is possible for certain browser features like autofill to trigger key events
with no "key"
field present in the value map sent to the server. For this reason, we
recommend always having a fallback catch-all event handler for LiveView key bindings.
By default, the bound element will be the event listener, but a
window-level binding may be provided via phx-window-keydown
or phx-window-keyup
,
for example:
def render(assigns) do
~H"""
<div id="thermostat" phx-window-keyup="update_temp">
Current temperature: <%= @temperature %>
</div>
"""
end
def handle_event("update_temp", %{"key" => "ArrowUp"}, socket) do
{:ok, new_temp} = Thermostat.inc_temperature(socket.assigns.id)
{:noreply, assign(socket, :temperature, new_temp)}
end
def handle_event("update_temp", %{"key" => "ArrowDown"}, socket) do
{:ok, new_temp} = Thermostat.dec_temperature(socket.assigns.id)
{:noreply, assign(socket, :temperature, new_temp)}
end
def handle_event("update_temp", _, socket) do
{:noreply, socket}
end
Scroll Events and Infinite Stream pagination
The phx-viewport-top
and phx-viewport-bottom
bindings allow you to detect when a container's
first child reaches the top of the viewport, or the last child reaches the bottom of the viewport.
This is useful for infinite scrolling where you want to send paging events for the next results set or previous results set as the user is scrolling up and down and reaches the top or bottom of the viewport.
Generally, applications will add padding above and below a container when performing infinite scrolling to allow smooth scrolling as results are loaded. Combined with Phoenix.LiveView.stream/3
, the phx-viewport-top
and phx-viewport-bottom
allow for infinite virtualized list that only keeps a small set of actual elements in the DOM. For example:
def mount(_, _, socket) do
{:ok,
socket
|> assign(page: 1, per_page: 20)
|> paginate_posts(1)}
end
defp paginate_posts(socket, new_page) when new_page >= 1 do
%{per_page: per_page, page: cur_page} = socket.assigns
posts = Blog.list_posts(offset: (new_page - 1) * per_page, limit: per_page)
{posts, at, limit} =
if new_page >= cur_page do
{posts, -1, per_page * 3 * -1}
else
{Enum.reverse(posts), 0, per_page * 3}
end
case posts do
[] ->
assign(socket, end_of_timeline?: at == -1)
[_ | _] = posts ->
socket
|> assign(end_of_timeline?: false) socket
|> assign(:page, new_page)
|> stream(:posts, posts, at: at, limit: limit)
end
end
Our paginate_posts
function fetches a page of posts, and determines if the user is paging to a previous page or next page. Based on the direction of paging, the stream is either prepended to, or appended to with at
of 0
or -1
respectively. We also set the limit
of the stream to three times the per_page
to allow enough posts in the UI to appear as an infinite list, but small enough to maintain UI performance. We also set an @end_of_timeline?
assign to track whether the user is at the end of results or not. Finally, we update the @page
assign and posts stream. We can then wire up our container to support the viewport events:
<ul
id="posts"
phx-update="stream"
phx-viewport-top={@page > 1 && "prev-page"}
phx-viewport-bottom={!@end_of_timeline? && "next-page"}
phx-page-loading
class={[
if(@end_of_timeline?, do: "pb-10", else: "pb-[calc(200vh)]"),
if(@page == 1, do: "pt-10", else: "pt-[calc(200vh)]")
]}
>
<li :for={{id, post} <- @streams.posts} id={id}>
<.post_card post={post}>
</li>
</ul>
<div :if={@end_of_timeline?} class="mt-5 text-[50px] text-center">
🎉 You made it to the beginning of time 🎉
</div>
There's not much here, but that's the point! This little snippet of UI is driving a fully virtualized list with bidirectional infinite scrolling. We use the phx-viewport-top
binding to send the "prev-page"
event to the LiveView, but only if the user is beyond the first page. It doesn't make sense to load negative page results, so we remove the binding entirely in those cases. Next, we wire up phx-viewport-bottom
to send the "next-page"
event, but only if we've yet to reach the end of the timeline. Finally, we conditionally apply some css classes which sets a large top and bottom padding to twice the viewport height based on the current pagination for smooth scrolling.
To complete our solution, we only need to handle the "prev-page"
and "next-page"
events in the LiveView:
def handle_event("next-page", _, socket) do
{:noreply, paginate_posts(socket, socket.assigns.page + 1)}
end
def handle_event("prev-page", %{"_overran" => true}, socket) do
{:noreply, paginate_posts(socket, 1)}
end
def handle_event("prev-page", _, socket) do
if socket.assigns.page > 1 do
{:noreply, paginate_posts(socket, socket.assigns.page - 1)}
else
{:noreply, socket}
end
end
This code simply calls the paginate_posts
function we defined as our first step, using the current or next page to drive the results. Notice that we match on a special "_overran" => true
parameter in our "prev-page"
event. The viewport events send this parameter when the user has "overran" the viewport top or bottom. Imagine the case where the user is scrolling back up through many pages of results, but grabs the scrollbar and returns immediately to the top of the page. This means our <ul id="posts">
container was overrun by the top of the viewport, and we need to reset the the UI to page the first page.
Rate limiting events with Debounce and Throttle
All events can be rate-limited on the client by using the
phx-debounce
and phx-throttle
bindings, with the exception of the phx-blur
binding, which is fired immediately.
Rate limited and debounced events have the following behavior:
phx-debounce
- Accepts either an integer timeout value (in milliseconds), or"blur"
. When an integer is provided, emitting the event is delayed by the specified milliseconds. When"blur"
is provided, emitting the event is delayed until the field is blurred by the user. When the value is omitted a default of 300ms is used. Debouncing is typically used for input elements.phx-throttle
- Accepts an integer timeout value to throttle the event in milliseconds. Unlike debounce, throttle will immediately emit the event, then rate limit it at once per provided timeout. When the value is omitted a default of 300ms is used. Throttling is typically used to rate limit clicks, mouse and keyboard actions.
For example, to avoid validating an email until the field is blurred, while validating the username at most every 2 seconds after a user changes the field:
<form phx-change="validate" phx-submit="save">
<input type="text" name="user[email]" phx-debounce="blur"/>
<input type="text" name="user[username]" phx-debounce="2000"/>
</form>
And to rate limit a volume up click to once every second:
<button phx-click="volume_up" phx-throttle="1000">+</button>
Likewise, you may throttle held-down keydown:
<div phx-window-keydown="keydown" phx-throttle="500">
...
</div>
Unless held-down keys are required, a better approach is generally to use
phx-keyup
bindings which only trigger on key up, thereby being self-limiting.
However, phx-keydown
is useful for games and other use cases where a constant
press on a key is desired. In such cases, throttle should always be used.
Debounce and Throttle special behavior
The following specialized behavior is performed for forms and keydown bindings:
When a
phx-submit
, or aphx-change
for a different input is triggered, any current debounce or throttle timers are reset for existing inputs.A
phx-keydown
binding is only throttled for key repeats. Unique keypresses back-to-back will dispatch the pressed key events.
JS Commands
LiveView bindings support a JavaScript command interface via the Phoenix.LiveView.JS
module, which allows you to specify utility operations that execute on the client when firing phx-
binding events, such as phx-click
, phx-change
, etc. Commands compose together to allow you to push events, add classes to elements, transition elements in and out, and more.
See the Phoenix.LiveView.JS
documentation for full usage.
For a small example of what's possible, imagine you want to show and hide a modal on the page without needing to make the round trip to the server to render the content:
<div id="modal" class="modal">
My Modal
</div>
<button phx-click={JS.show(to: "#modal", transition: "fade-in")}>
show modal
</button>
<button phx-click={JS.hide(to: "#modal", transition: "fade-out")}>
hide modal
</button>
<button phx-click={JS.toggle(to: "#modal", in: "fade-in", out: "fade-out")}>
toggle modal
</button>
Or if your UI library relies on classes to perform the showing or hiding:
<div id="modal" class="modal">
My Modal
</div>
<button phx-click={JS.add_class("show", to: "#modal", transition: "fade-in")}>
show modal
</button>
<button phx-click={JS.remove_class("show", to: "#modal", transition: "fade-out")}>
hide modal
</button>
Commands compose together. For example, you can push an event to the server and immediately hide the modal on the client:
<div id="modal" class="modal">
My Modal
</div>
<button phx-click={JS.push("modal-closed") |> JS.remove_class("show", to: "#modal", transition: "fade-out")}>
hide modal
</button>
It is also useful to extract commands into their own functions:
alias Phoenix.LiveView.JS
def hide_modal(js \\ %JS{}, selector) do
js
|> JS.push("modal-closed")
|> JS.remove_class("show", to: selector, transition: "fade-out")
end
<button phx-click={hide_modal("#modal")}>hide modal</button>
The Phoenix.LiveView.JS.push/3
command is particularly powerful in allowing you to customize the event being pushed to the server. For example, imagine you start with a familiar phx-click
which pushes a message to the server when clicked:
<button phx-click="clicked">click</button>
Now imagine you want to customize what happens when the "clicked"
event is pushed, such as which component should be targeted, which element should receive css loading state classes, etc. This can be accomplished with options on the JS push command. For example:
<button phx-click={JS.push("clicked", target: @myself, loading: ".container")}>click</button>
See Phoenix.LiveView.JS.push/3
for all supported options.
Lifecycle Events
LiveView supports the phx-mounted
, phx-connected
, and phx-disconnected
events to react to
different lifecycle events with JS commands.
To execute commands when an element first appears on the page, you can leverage phx-mounted
,
such as to animate a notice into view:
<div id="flash" class="hidden" phx-mounted={JS.show(transition: ...)}>
Welcome back!
</div>
If phx-mounted
is used on the initial page render, it will be invoked only after the initial WebSocket connection is established.
To manage the connection lifecycle, you can combine phx-disconnected
and phx-connected
to show an element when the LiveView has lost its connection, and hide it when the connection recovers:
<div id="status" class="hidden" phx-disconnected={JS.show()} phx-connected={JS.hide()}>
Attempting to reconnect...
</div>
LiveView vs static view
phx-connected
and phx-disconnected
are only executed when operating
inside a LiveView container. For static templates, they will have no effect.
For LiveView, the phx-mounted
binding is executed as soon as the LiveView is
mounted with a connection. When using phx-mounted
in static views, it is executed
as soon as the DOM is ready.
LiveView Specific Events
The lv:
event prefix supports LiveView specific features that are handled
by LiveView without calling the user's handle_event/3
callbacks. Today,
the following events are supported:
lv:clear-flash
– clears the flash when sent to the server. If aphx-value-key
is provided, the specific key will be removed from the flash.
For example:
<p class="alert" phx-click="lv:clear-flash" phx-value-key="info">
<%= live_flash(@flash, :info) %>
</p>
Loading states and errors
All phx-
event bindings apply their own css classes when pushed. For example
the following markup:
<button phx-click="clicked" phx-window-keydown="key">...</button>
On click, would receive the phx-click-loading
class, and on keydown would receive
the phx-keydown-loading
class. The css loading classes are maintained until an
acknowledgement is received on the client for the pushed event.
In the case of forms, when a phx-change
is sent to the server, the input element
which emitted the change receives the phx-change-loading
class, along with the
parent form tag. The following events receive css loading classes:
phx-click
-phx-click-loading
phx-change
-phx-change-loading
phx-submit
-phx-submit-loading
phx-focus
-phx-focus-loading
phx-blur
-phx-blur-loading
phx-window-keydown
-phx-keydown-loading
phx-window-keyup
-phx-keyup-loading
Additionally, the following classes are applied to the LiveView's parent container:
"phx-connected"
- applied when the view has connected to the server"phx-loading"
- applied when the view is not connected to the server"phx-error"
- applied when an error occurs on the server. Note, this class will be applied in conjunction with"phx-loading"
if connection to the server is lost.
For navigation related loading states (both automatic and manual), see phx-page-loading
as described in
JavaScript interoperability: Live navigation events.