defmodule Membrane.Testing.Source do
@moduledoc """
Testing Element for supplying data based on generator function or payloads passed
through options.
## Example usage
As mentioned earlier you can use this element in one of two ways, providing
either a generator function or an `Enumerable.t`.
If you provide an `Enumerable.t` with payloads, then each of those payloads will
be wrapped in a `Membrane.Buffer` and sent through `:output` pad.
```
%Source{output: [0xA1, 0xB2, 0xC3, 0xD4]}
```
In order to specify `Membrane.Testing.Source` with generator function you need
to provide initial state and function that matches `t:generator/0` type. This
function should take state and demand size as its arguments and return
a tuple consisting of actions that element will return during the
`c:Membrane.Element.WithOutputPads.handle_demand/5`
callback and new state.
```
generator_function = fn state, size ->
#generate some buffers
{actions, state + 1}
end
%Source{output: {1, generator_function}}
```
"""
use Membrane.Source
alias Membrane.Buffer
alias Membrane.Element.Action
@type generator ::
(state :: any(), buffers_cnt :: pos_integer -> {[Action.t()], state :: any()})
def_output_pad :output, caps: :any
def_options output: [
spec: {initial_state :: any(), generator} | Enum.t(),
default: {0, &__MODULE__.default_buf_gen/2},
description: """
If `output` is an enumerable with `Membrane.Payload.t()` then
buffer containing those payloads will be sent through the
`:output` pad and followed by `t:Membrane.Element.Action.end_of_stream_t/0`.
If `output` is a `{initial_state, function}` tuple then the
the function will be invoked each time `handle_demand` is called.
It is an action generator that takes two arguments.
The first argument is the state that is initially set to
`initial_state`. The second one defines the size of the demand.
Such function should return `{actions, next_state}` where
`actions` is a list of actions that will be returned from
`handle_demand/4` and `next_state` is the value that will be
used for the next call.
"""
],
caps: [
spec: struct(),
default: %Membrane.RemoteStream{},
description: """
Caps to be sent before the `output`.
"""
]
@impl true
def handle_init(opts) do
opts = Map.from_struct(opts)
case opts.output do
{initial_state, generator} when is_function(generator) ->
{:ok, opts |> Map.merge(%{generator_state: initial_state, output: generator})}
_enumerable_output ->
{:ok, opts}
end
end
@impl true
def handle_prepared_to_playing(_ctx, state) do
{{:ok, caps: {:output, state.caps}}, state}
end
@impl true
def handle_demand(:output, size, :buffers, _ctx, state) do
{actions, state} = get_actions(state, size)
{{:ok, actions}, state}
end
@spec default_buf_gen(integer(), integer()) :: {[Action.t()], integer()}
def default_buf_gen(generator_state, size) do
buffers =
generator_state..(size + generator_state - 1)
|> Enum.map(fn generator_state ->
%Buffer{payload: <<generator_state::16>>}
end)
action = [buffer: {:output, buffers}]
{action, generator_state + size}
end
@doc """
Creates output with generator function from list of buffers.
"""
@spec output_from_buffers([Buffer.t()]) :: {[Buffer.t()], generator()}
def output_from_buffers(data) do
fun = fn state, size ->
{buffers, leftover} = Enum.split(state, size)
buffer_action = [{:buffer, {:output, buffers}}]
event_action = if leftover == [], do: [end_of_stream: :output], else: []
to_send = buffer_action ++ event_action
{to_send, leftover}
end
{data, fun}
end
defp get_actions(%{generator_state: generator_state, output: actions_generator} = state, size)
when is_function(actions_generator) do
{actions, generator_state} = actions_generator.(generator_state, size)
{actions, %{state | generator_state: generator_state}}
end
defp get_actions(%{output: output} = state, size) do
{payloads, output} = Enum.split(output, size)
buffers = Enum.map(payloads, &%Buffer{payload: &1})
actions =
case output do
[] -> [buffer: {:output, buffers}, end_of_stream: :output]
_non_empty -> [buffer: {:output, buffers}]
end
{actions, %{state | output: output}}
end
end
