Awesome
Lens
A utility for working with nested data structures. Take a look at
Nested data structures with functional lenses
for a gentler introduction. Note that the blogpost was written using version 0.3.1
and there have been some API
changes since then - see Upgrading for details.
Installation
The package can be installed by adding lens
to your list of dependencies in mix.exs
:
def deps do
[
{:lens, "~> 1.0.0"}
]
end
Upgrading
From pre-0.6.0
In 0.6.0 the function Lens.get
got removed. The reason was that it was very easy to create a bug where a list was
treated as a single element or vice-versa. Wherever you used Lens.get
you now should either use Lens.one!
if the
invocation should always return exactly one element (this will crash if there is any other number of elements) or
Lens.to_list
and match on the result if you want to behave differently for different numbers of elements.
From pre-0.5.0
In 0.5.0 the function satisfy
got renamed to filter
while the previous version of filter
was removed. The reason
was that with the new arrangement there is a matching pair of filter
/reject
functions, and this should be more
intuitive. Wherever you used Lens.filter(predicate)
you can now use Lens.filter(Lens.all(), predicate)
.
Example
Lens allows you to separate which parts of a complex data structure need to be processed from the actual processing. Take the following:
data = %{
main_widget: %{size: 200.5, subwidgets: [%{size: 120, subwidgets: [%{size: 200, subwidgets: []}]}]},
other_widgets: [
%{size: 16.5, subwidgets: [%{size: 120, subwidgets: []}]},
%{size: 160.5, subwidgets: []},
%{size: 121.9, subwidgets: []},
]
}
Let's say we're interested in the sizes of all widgets (be they the main widget or other widgets) that are larger than 100.
We can construct a Lens
object that describes these locations in the datastructure the following way:
lens = Lens.both(
Lens.key(:main_widget),
Lens.key(:other_widgets) |> Lens.all
)
|> Lens.seq_both(Lens.recur(Lens.key(:subwidgets) |> Lens.all))
|> Lens.key(:size)
|> Lens.filter(&(&1 > 100))
Given that we can:
- Extract all the relevant data
iex> Lens.to_list(lens, data)
[200.5, 160.5, 121.9, 120, 200, 120]
- Update the described locations in the data structure
iex> Lens.map(lens, data, &round/1)
%{main_widget: %{size: 201,
subwidgets: [%{size: 120, subwidgets: [%{size: 200, subwidgets: []}]}]},
other_widgets: [%{size: 16.5, subwidgets: [%{size: 120, subwidgets: []}]},
%{size: 161, subwidgets: []}, %{size: 122, subwidgets: []}]}
- Simultaneously update and return something from every location in the data
iex> Lens.get_and_map(lens, data, fn size -> {size, round(size)} end)
{[200.5, 160.5, 121.9, 120, 200, 120],
%{main_widget: %{size: 201,
subwidgets: [%{size: 120, subwidgets: [%{size: 200, subwidgets: []}]}]},
other_widgets: [%{size: 16.5, subwidgets: [%{size: 120, subwidgets: []}]},
%{size: 161, subwidgets: []}, %{size: 122, subwidgets: []}]}}
Lenses are also compatible with Access
and associated Kernel
functions:
iex> get_in([1, 2, 3], [Lens.all() |> Lens.filter(&Integer.is_odd/1)])
[1, 3]
iex> update_in([1, 2, 3], [Lens.all() |> Lens.filter(&Integer.is_odd/1)], fn x -> x + 1 end)
[2, 2, 4]
iex> get_and_update_in([1, 2, 3], [Lens.all() |> Lens.filter(&Integer.is_odd/1)], fn x -> {x - 1, x + 1} end)
{[0, 2], [2, 2, 4]}
Formatting
Normally, mix format
will change definitions like:
deflens a_lens(), do: some() |> implementation()
deflensp a_private_lens(), do: some() |> implementation()
into:
deflens(a_lens(), do: some() |> implementation())
deflensp(a_private_lens(), do: some() |> implementation())
To avoid this, you can import lens's formatter settings in your formatter.exs
:
# my_app/.formatter.exs
[
import_deps: [:lens]
]