View Source Phoenix.LiveView.Engine (Phoenix LiveView v1.0.0-rc.7)

An EEx template engine that tracks changes.

This is often used by Phoenix.LiveView.TagEngine which also adds HTML validation. In the documentation below, we will explain how it works internally. For user-facing documentation, see Phoenix.LiveView.

Phoenix.LiveView.Rendered

Whenever you render a live template, it returns a Phoenix.LiveView.Rendered structure. This structure has three fields: :static, :dynamic and :fingerprint.

The :static field is a list of literal strings. This allows the Elixir compiler to optimize this list and avoid allocating its strings on every render.

The :dynamic field contains a function that takes a boolean argument (see "Tracking changes" below), and returns a list of dynamic content. Each element in the list is either one of:

  1. iodata - which is the dynamic content
  2. nil - the dynamic content did not change
  3. another Phoenix.LiveView.Rendered struct, see "Nesting and fingerprinting" below
  4. a Phoenix.LiveView.Comprehension struct, see "Comprehensions" below
  5. a Phoenix.LiveView.Component struct, see "Component" below

When you render a live template, you can convert the rendered structure to iodata by alternating the static and dynamic fields, always starting with a static entry followed by a dynamic entry. The last entry will always be static too. So the following structure:

%Phoenix.LiveView.Rendered{
  static: ["foo", "bar", "baz"],
  dynamic: fn track_changes? -> ["left", "right"] end
}

Results in the following content to be sent over the wire as iodata:

["foo", "left", "bar", "right", "baz"]

This is also what calling Phoenix.HTML.Safe.to_iodata/1 with a Phoenix.LiveView.Rendered structure returns.

Of course, the benefit of live templates is exactly that you do not need to send both static and dynamic segments every time. So let's talk about tracking changes.

Tracking changes

By default, a live template does not track changes. Change tracking can be enabled by including a changed map in the assigns with the key __changed__ and passing true to the dynamic parts. The map should contain the name of any changed field as key and the boolean true as value. If a field is not listed in __changed__, then it is always considered unchanged.

If a field is unchanged and live believes a dynamic expression no longer needs to be computed, its value in the dynamic list will be nil. This information can be leveraged to avoid sending data to the client.

Nesting and fingerprinting

Phoenix.LiveView also tracks changes across live templates. Therefore, if your view has this:

<%= render "form.html", assigns %>

Phoenix will be able to track what is static and dynamic across templates, as well as what changed. A rendered nested live template will appear in the dynamic list as another Phoenix.LiveView.Rendered structure, which must be handled recursively.

However, because the rendering of live templates can be dynamic in itself, it is important to distinguish which live template was rendered. For example, imagine this code:

<%= if something?, do: render("one.html", assigns), else: render("other.html", assigns) %>

To solve this, all Phoenix.LiveView.Rendered structs also contain a fingerprint field that uniquely identifies it. If the fingerprints are equal, you have the same template, and therefore it is possible to only transmit its changes.

Comprehensions

Another optimization done by live templates is to track comprehensions. If your code has this:

<%= for point <- @points do %>
  x: <%= point.x %>
  y: <%= point.y %>
<% end %>

Instead of rendering all points with both static and dynamic parts, it returns a Phoenix.LiveView.Comprehension struct with the static parts, that are shared across all points, and a list of dynamics to be interpolated inside the static parts. If @points is a list with %{x: 1, y: 2} and %{x: 3, y: 4}, the above expression would return:

%Phoenix.LiveView.Comprehension{
  static: ["\n  x: ", "\n  y: ", "\n"],
  dynamics: [
    ["1", "2"],
    ["3", "4"]
  ]
}

This allows live templates to drastically optimize the data sent by comprehensions, as the static parts are emitted only once, regardless of the number of items.

The list of dynamics is always a list of iodatas or components, as we don't perform change tracking inside the comprehensions themselves. Similarly, comprehensions do not have fingerprints because they are only optimized at the root, so conditional evaluation, as the one seen in rendering, is not possible. The only possible outcome for a dynamic field that returns a comprehension is nil.

Components

Live also supports stateful components defined with Phoenix.LiveComponent. Since they are stateful, they are always handled lazily by the diff algorithm.