a49229384e
and add support for RDF.PropertyMaps on values/2 instead
870 lines
28 KiB
Elixir
870 lines
28 KiB
Elixir
defmodule RDF.Description do
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@moduledoc """
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A set of RDF triples about the same subject.
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`RDF.Description` implements:
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- Elixir's `Access` behaviour
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- Elixir's `Enumerable` protocol
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- Elixir's `Inspect` protocol
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- the `RDF.Data` protocol
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"""
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@enforce_keys [:subject]
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defstruct subject: nil, predications: %{}
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@behaviour Access
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import RDF.Statement,
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only: [coerce_subject: 1, coerce_predicate: 1, coerce_predicate: 2, coerce_object: 1]
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alias RDF.{Statement, Triple, PropertyMap}
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@type t :: %__MODULE__{
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subject: Statement.subject(),
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predications: predications
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}
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@type predications :: %{Statement.predicate() => %{Statement.object() => nil}}
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@type input ::
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Statement.coercible_t()
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| {
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Statement.coercible_predicate(),
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Statement.coercible_object() | [Statement.coercible_object()]
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}
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| %{
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Statement.coercible_predicate() =>
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Statement.coercible_object() | [Statement.coercible_object()]
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}
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| [
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Statement.coercible_t()
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| {
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Statement.coercible_predicate(),
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Statement.coercible_object() | [Statement.coercible_object()]
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}
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| t
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]
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| t
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@doc """
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Creates an `RDF.Description` about the given subject.
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The created `RDF.Description` can be initialized with any form of data which
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`add/2` understands with the `:init` option. Additionally a function returning
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the initialization data in any of these forms can be as the `:init` value.
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## Examples
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RDF.Description.new(EX.S)
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RDF.Description.new(EX.S, init: {EX.S, EX.p, EX.O})
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RDF.Description.new(EX.S, init: {EX.p, [EX.O1, EX.O2]})
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RDF.Description.new(EX.S, init: [{EX.p1, EX.O1}, {EX.p2, EX.O2}])
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RDF.Description.new(EX.S, init: RDF.Description.new(EX.S, init: {EX.P, EX.O}))
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RDF.Description.new(EX.S, init: fn -> {EX.p, EX.O} end)
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"""
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@spec new(Statement.coercible_subject() | t, keyword) :: t
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def new(subject, opts \\ [])
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def new(%__MODULE__{} = description, opts), do: new(description.subject, opts)
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def new(subject, opts) do
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{data, opts} = Keyword.pop(opts, :init)
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%__MODULE__{subject: coerce_subject(subject)}
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|> init(data, opts)
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end
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defp init(description, nil, _), do: description
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defp init(description, fun, opts) when is_function(fun), do: add(description, fun.(), opts)
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defp init(description, data, opts), do: add(description, data, opts)
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@doc """
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Returns the subject IRI or blank node of a description.
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"""
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@spec subject(t) :: Statement.subject()
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def subject(%__MODULE__{} = description), do: description.subject
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@doc """
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Changes the subject of a description.
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"""
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@spec change_subject(t, Statement.coercible_subject()) :: t
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def change_subject(%__MODULE__{} = description, new_subject) do
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%__MODULE__{description | subject: coerce_subject(new_subject)}
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end
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defp context(nil), do: nil
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defp context(opts) do
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if property_map = Keyword.get(opts, :context) do
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PropertyMap.new(property_map)
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end
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end
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@doc """
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Add statements to a `RDF.Description`.
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Note: When the statements to be added are given as another `RDF.Description`,
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the subject must not match subject of the description to which the statements
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are added. As opposed to that `RDF.Data.merge/2` will produce a `RDF.Graph`
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containing both descriptions.
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## Examples
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iex> RDF.Description.new(EX.S, init: {EX.P1, EX.O1})
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...> |> RDF.Description.add({EX.P2, EX.O2})
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RDF.Description.new(EX.S, init: [{EX.P1, EX.O1}, {EX.P2, EX.O2}])
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iex> RDF.Description.new(EX.S, init: {EX.P, EX.O1})
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...> |> RDF.Description.add({EX.P, [EX.O2, EX.O3]})
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RDF.Description.new(EX.S, init: [{EX.P, EX.O1}, {EX.P, EX.O2}, {EX.P, EX.O3}])
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"""
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@spec add(t, input, keyword) :: t
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def add(description, input, opts \\ [])
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def add(%__MODULE__{} = description, {subject, predicate, objects, _}, opts) do
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add(description, {subject, predicate, objects}, opts)
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end
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def add(%__MODULE__{} = description, {subject, predicate, objects}, opts) do
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if coerce_subject(subject) == description.subject do
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add(description, {predicate, objects}, opts)
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else
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description
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end
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end
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def add(%__MODULE__{} = description, {predicate, objects}, opts) do
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normalized_objects =
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objects
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|> List.wrap()
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|> Map.new(&{coerce_object(&1), nil})
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if Enum.empty?(normalized_objects) do
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description
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else
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%__MODULE__{
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description
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| predications:
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Map.update(
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description.predications,
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coerce_predicate(predicate, context(opts)),
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normalized_objects,
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fn objects ->
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Map.merge(objects, normalized_objects)
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end
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)
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}
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end
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end
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# This implementation is actually unnecessary as the implementation with the is_map clause
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# would work perfectly fine with RDF.Descriptions Enumerable implementation.
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# It exists only for performance reasons, since this version is roughly twice as fast.
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def add(%__MODULE__{} = description, %__MODULE__{} = input_description, _opts) do
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%__MODULE__{
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description
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| predications:
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Map.merge(
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description.predications,
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input_description.predications,
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fn _predicate, objects, new_objects ->
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Map.merge(objects, new_objects)
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end
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)
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}
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end
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if Version.match?(System.version(), "~> 1.10") do
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def add(description, input, opts)
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when is_list(input) or (is_map(input) and not is_struct(input)) do
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Enum.reduce(input, description, &add(&2, &1, opts))
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end
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else
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def add(_, %_{}, _), do: raise(ArgumentError, "structs are not allowed as input")
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def add(description, input, opts) when is_list(input) or is_map(input) do
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Enum.reduce(input, description, &add(&2, &1, opts))
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end
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end
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@doc """
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Adds statements to a `RDF.Description` and overwrites all existing statements with already used predicates.
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Note: As it is a destructive function this function is more strict in its handling of
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`RDF.Description`s than `add/3`. The subject of a `RDF.Description` to be put must
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match. If you want to overwrite existing statements with those from the description of
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another subject, you'll have to explicitly change the subject with `change_subject/2`
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first before using `put/3`.
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## Examples
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iex> RDF.Description.new(EX.S, init: {EX.P, EX.O1})
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...> |> RDF.Description.put({EX.P, EX.O2})
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RDF.Description.new(EX.S, init: {EX.P, EX.O2})
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"""
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@spec put(t, input, keyword) :: t
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def put(description, input, opts \\ [])
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def put(
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%__MODULE__{subject: subject} = description,
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%__MODULE__{subject: subject} = input,
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_opts
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) do
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%__MODULE__{
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description
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| predications:
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Enum.reduce(
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input.predications,
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description.predications,
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fn {predicate, objects}, predications ->
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Map.put(predications, predicate, objects)
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end
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)
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}
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end
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def put(%__MODULE__{} = description, %__MODULE__{}, _opts), do: description
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def put(%__MODULE__{} = description, input, opts) do
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put(description, description.subject |> new() |> add(input, opts), opts)
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end
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@doc """
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Deletes statements from a `RDF.Description`.
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Note: When the statements to be deleted are given as another `RDF.Description`,
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the subject must not match subject of the description from which the statements
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are deleted. If you want to delete only a matching description subject, you can
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use `RDF.Data.delete/2`.
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"""
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@spec delete(t, input, keyword) :: t
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def delete(description, input, opts \\ [])
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def delete(%__MODULE__{} = description, {subject, predicate, objects}, opts) do
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if coerce_subject(subject) == description.subject do
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delete(description, {predicate, objects}, opts)
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else
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description
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end
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end
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def delete(%__MODULE__{} = description, {subject, predicate, objects, _}, opts) do
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delete(description, {subject, predicate, objects}, opts)
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end
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def delete(%__MODULE__{} = description, {predicate, objects}, opts) do
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predicate = coerce_predicate(predicate, context(opts))
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if current_objects = Map.get(description.predications, predicate) do
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normalized_objects =
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objects
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|> List.wrap()
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|> Enum.map(&coerce_object/1)
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rest = Map.drop(current_objects, normalized_objects)
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%__MODULE__{
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description
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| predications:
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if Enum.empty?(rest) do
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Map.delete(description.predications, predicate)
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else
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Map.put(description.predications, predicate, rest)
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end
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}
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else
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description
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end
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end
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# This implementation is actually unnecessary as the implementation with the is_map clause
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# would work perfectly fine with RDF.Descriptions Enumerable implementation.
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# It exists only for performance reasons.
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def delete(%__MODULE__{} = description, %__MODULE__{} = input_description, _opts) do
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predications = description.predications
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%__MODULE__{
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description
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| predications:
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Enum.reduce(
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input_description.predications,
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predications,
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fn {predicate, objects}, predications ->
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if current_objects = Map.get(description.predications, predicate) do
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rest = Map.drop(current_objects, Map.keys(objects))
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if Enum.empty?(rest) do
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Map.delete(predications, predicate)
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else
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Map.put(predications, predicate, rest)
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end
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else
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predications
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end
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end
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)
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}
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end
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if Version.match?(System.version(), "~> 1.10") do
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def delete(description, input, opts)
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when is_list(input) or (is_map(input) and not is_struct(input)) do
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Enum.reduce(input, description, &delete(&2, &1, opts))
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end
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else
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def delete(_, %_{}, _), do: raise(ArgumentError, "structs are not allowed as input")
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def delete(description, input, opts) when is_list(input) or is_map(input) do
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Enum.reduce(input, description, &delete(&2, &1, opts))
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end
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end
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@doc """
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Deletes all statements with the given properties.
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"""
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@spec delete_predicates(t, Statement.coercible_predicate() | [Statement.coercible_predicate()]) ::
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t
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def delete_predicates(description, properties)
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def delete_predicates(%__MODULE__{} = description, properties) when is_list(properties) do
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Enum.reduce(properties, description, &delete_predicates(&2, &1))
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end
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def delete_predicates(%__MODULE__{} = description, property) do
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%__MODULE__{
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description
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| predications: Map.delete(description.predications, coerce_predicate(property))
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}
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end
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@doc """
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Fetches the objects for the given predicate of a Description.
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When the predicate can not be found `:error` is returned.
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## Examples
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iex> RDF.Description.new(EX.S, init: {EX.p, EX.O}) |> RDF.Description.fetch(EX.p)
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{:ok, [RDF.iri(EX.O)]}
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iex> RDF.Description.new(EX.S, init: [{EX.P, EX.O1}, {EX.P, EX.O2}])
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...> |> RDF.Description.fetch(EX.P)
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{:ok, [RDF.iri(EX.O1), RDF.iri(EX.O2)]}
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iex> RDF.Description.new(EX.S) |> RDF.Description.fetch(EX.foo)
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:error
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"""
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@impl Access
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@spec fetch(t, Statement.coercible_predicate()) :: {:ok, [Statement.object()]} | :error
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def fetch(%__MODULE__{} = description, predicate) do
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with {:ok, objects} <-
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Access.fetch(description.predications, coerce_predicate(predicate)) do
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{:ok, Map.keys(objects)}
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end
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end
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@doc """
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Gets the objects for the given predicate of a Description.
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When the predicate can not be found, the optionally given default value or `nil` is returned.
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## Examples
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iex> RDF.Description.new(EX.S, init: {EX.P, EX.O}) |> RDF.Description.get(EX.P)
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[RDF.iri(EX.O)]
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iex> RDF.Description.new(EX.S) |> RDF.Description.get(EX.foo)
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nil
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iex> RDF.Description.new(EX.S) |> RDF.Description.get(EX.foo, :bar)
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:bar
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"""
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@spec get(t, Statement.coercible_predicate(), any) :: [Statement.object()] | any
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def get(%__MODULE__{} = description, predicate, default \\ nil) do
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case fetch(description, predicate) do
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{:ok, value} -> value
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:error -> default
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end
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end
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@doc """
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Gets a single object for the given predicate of a Description.
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When the predicate can not be found, the optionally given default value or `nil` is returned.
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## Examples
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iex> RDF.Description.new(EX.S, init: {EX.P, EX.O}) |> RDF.Description.first(EX.P)
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RDF.iri(EX.O)
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iex> RDF.Description.new(EX.S) |> RDF.Description.first(EX.foo)
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nil
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"""
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@spec first(t, Statement.coercible_predicate()) :: Statement.object() | nil
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def first(%__MODULE__{} = description, predicate) do
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description
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|> get(predicate, [])
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|> List.first()
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end
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@doc """
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Updates the objects of the `predicate` in `description` with the given function.
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If `predicate` is present in `description` with `objects` as value,
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`fun` is invoked with argument `objects` and its result is used as the new
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list of objects of `predicate`. If `predicate` is not present in `description`,
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`initial` is inserted as the objects of `predicate`. The initial value will
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not be passed through the update function.
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The initial value and the returned objects by the update function will automatically
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coerced to proper RDF object values before added.
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## Examples
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iex> RDF.Description.new(EX.S, init: {EX.p, EX.O})
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...> |> RDF.Description.update(EX.p, fn objects -> [EX.O2 | objects] end)
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RDF.Description.new(EX.S, init: [{EX.p, EX.O}, {EX.p, EX.O2}])
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iex> RDF.Description.new(EX.S)
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...> |> RDF.Description.update(EX.p, EX.O, fn _ -> EX.O2 end)
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RDF.Description.new(EX.S, init: {EX.p, EX.O})
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"""
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@spec update(
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t,
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Statement.coercible_predicate(),
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Statement.coercible_object() | nil,
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([Statement.Object] -> [Statement.Object])
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) :: t
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def update(%__MODULE__{} = description, predicate, initial \\ nil, fun) do
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predicate = coerce_predicate(predicate)
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case get(description, predicate) do
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nil ->
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if initial do
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put(description, {predicate, initial})
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else
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description
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end
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objects ->
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objects
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|> fun.()
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|> List.wrap()
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|> case do
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[] -> delete_predicates(description, predicate)
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objects -> put(description, {predicate, objects})
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end
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end
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end
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@doc """
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Gets and updates the objects of the given predicate of a Description, in a single pass.
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Invokes the passed function on the objects of the given predicate; this
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function should return either `{objects_to_return, new_object}` or `:pop`.
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If the passed function returns `{objects_to_return, new_objects}`, the return
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value of `get_and_update` is `{objects_to_return, new_description}` where
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`new_description` is the input `Description` updated with `new_objects` for
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the given predicate.
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If the passed function returns `:pop` the objects for the given predicate are
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removed and a `{removed_objects, new_description}` tuple gets returned.
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## Examples
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iex> RDF.Description.new(EX.S, init: {EX.P, EX.O})
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...> |> RDF.Description.get_and_update(EX.P, fn current_objects ->
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...> {current_objects, EX.New}
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...> end)
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{[RDF.iri(EX.O)], RDF.Description.new(EX.S, init: {EX.P, EX.New})}
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iex> RDF.Graph.new([{EX.S, EX.P1, EX.O1}, {EX.S, EX.P2, EX.O2}])
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...> |> RDF.Graph.description(EX.S)
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...> |> RDF.Description.get_and_update(EX.P1, fn _ -> :pop end)
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{[RDF.iri(EX.O1)], RDF.Description.new(EX.S, init: {EX.P2, EX.O2})}
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"""
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@impl Access
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@spec get_and_update(
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t,
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Statement.coercible_predicate(),
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([Statement.Object] -> {[Statement.Object], t} | :pop)
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) :: {[Statement.Object], t}
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def get_and_update(%__MODULE__{} = description, predicate, fun) do
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triple_predicate = coerce_predicate(predicate)
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case fun.(get(description, triple_predicate)) do
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{objects_to_return, new_objects} ->
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{objects_to_return, put(description, {triple_predicate, new_objects})}
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:pop ->
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pop(description, triple_predicate)
|
|
end
|
|
end
|
|
|
|
@doc """
|
|
Pops an arbitrary triple from a `RDF.Description`.
|
|
"""
|
|
@spec pop(t) :: {Triple.t() | [Statement.Object] | nil, t}
|
|
def pop(description)
|
|
|
|
def pop(%__MODULE__{predications: predications} = description)
|
|
when map_size(predications) == 0,
|
|
do: {nil, description}
|
|
|
|
def pop(%__MODULE__{predications: predications} = description) do
|
|
[{predicate, objects}] = Enum.take(predications, 1)
|
|
[{object, _}] = Enum.take(objects, 1)
|
|
|
|
popped =
|
|
if Enum.count(objects) == 1,
|
|
do: elem(Map.pop(predications, predicate), 1),
|
|
else: elem(pop_in(predications, [predicate, object]), 1)
|
|
|
|
{
|
|
{description.subject, predicate, object},
|
|
%__MODULE__{description | predications: popped}
|
|
}
|
|
end
|
|
|
|
@doc """
|
|
Pops the objects of the given predicate of a Description.
|
|
|
|
When the predicate can not be found the optionally given default value or `nil` is returned.
|
|
|
|
## Examples
|
|
|
|
iex> RDF.Description.new(EX.S, init: {EX.P, EX.O})
|
|
...> |> RDF.Description.pop(EX.P)
|
|
{[RDF.iri(EX.O)], RDF.Description.new(EX.S)}
|
|
iex> RDF.Description.new(EX.S, init: {EX.P, EX.O})
|
|
...> |> RDF.Description.pop(EX.Missing)
|
|
{nil, RDF.Description.new(EX.S, init: {EX.P, EX.O})}
|
|
"""
|
|
@impl Access
|
|
def pop(%__MODULE__{} = description, predicate) do
|
|
case Access.pop(description.predications, coerce_predicate(predicate)) do
|
|
{nil, _} ->
|
|
{nil, description}
|
|
|
|
{objects, new_predications} ->
|
|
{
|
|
Map.keys(objects),
|
|
%__MODULE__{description | predications: new_predications}
|
|
}
|
|
end
|
|
end
|
|
|
|
@doc """
|
|
The set of all properties used in the predicates within a `RDF.Description`.
|
|
|
|
## Examples
|
|
|
|
iex> RDF.Description.new(EX.S1, init: [
|
|
...> {EX.p1, EX.O1},
|
|
...> {EX.p2, EX.O2},
|
|
...> {EX.p2, EX.O3}])
|
|
...> |> RDF.Description.predicates()
|
|
MapSet.new([EX.p1, EX.p2])
|
|
"""
|
|
@spec predicates(t) :: MapSet.t()
|
|
def predicates(%__MODULE__{} = description) do
|
|
description.predications |> Map.keys() |> MapSet.new()
|
|
end
|
|
|
|
@doc """
|
|
The set of all resources used in the objects within a `RDF.Description`.
|
|
|
|
Note: This function does collect only IRIs and BlankNodes, not Literals.
|
|
|
|
## Examples
|
|
|
|
iex> RDF.Description.new(EX.S1, init: [
|
|
...> {EX.p1, EX.O1},
|
|
...> {EX.p2, EX.O2},
|
|
...> {EX.p3, EX.O2},
|
|
...> {EX.p4, RDF.bnode(:bnode)},
|
|
...> {EX.p3, "foo"}])
|
|
...> |> RDF.Description.objects()
|
|
MapSet.new([RDF.iri(EX.O1), RDF.iri(EX.O2), RDF.bnode(:bnode)])
|
|
"""
|
|
@spec objects(t) :: MapSet.t()
|
|
def objects(%__MODULE__{} = description) do
|
|
objects(description, &RDF.resource?/1)
|
|
end
|
|
|
|
@doc """
|
|
The set of all resources used in the objects within a `RDF.Description` satisfying the given filter criterion.
|
|
"""
|
|
@spec objects(t, (Statement.object() -> boolean)) :: MapSet.t()
|
|
def objects(%__MODULE__{} = description, filter_fn) do
|
|
Enum.reduce(description.predications, MapSet.new(), fn {_, objects}, acc ->
|
|
objects
|
|
|> Map.keys()
|
|
|> Enum.filter(filter_fn)
|
|
|> MapSet.new()
|
|
|> MapSet.union(acc)
|
|
end)
|
|
end
|
|
|
|
@doc """
|
|
The set of all resources used within a `RDF.Description`.
|
|
|
|
## Examples
|
|
|
|
iex> RDF.Description.new(EX.S1, init: [
|
|
...> {EX.p1, EX.O1},
|
|
...> {EX.p2, EX.O2},
|
|
...> {EX.p1, EX.O2},
|
|
...> {EX.p2, RDF.bnode(:bnode)},
|
|
...> {EX.p3, "foo"}])
|
|
...> |> RDF.Description.resources()
|
|
MapSet.new([RDF.iri(EX.O1), RDF.iri(EX.O2), RDF.bnode(:bnode), EX.p1, EX.p2, EX.p3])
|
|
"""
|
|
@spec resources(t) :: MapSet.t()
|
|
def resources(%__MODULE__{} = description) do
|
|
description
|
|
|> objects()
|
|
|> MapSet.union(predicates(description))
|
|
end
|
|
|
|
@doc """
|
|
The list of all triples within a `RDF.Description`.
|
|
"""
|
|
@spec triples(t) :: keyword
|
|
def triples(%__MODULE__{} = description), do: Enum.to_list(description)
|
|
|
|
defdelegate statements(description), to: __MODULE__, as: :triples
|
|
|
|
@doc """
|
|
Returns the number of statements of a `RDF.Description`.
|
|
"""
|
|
@spec count(t) :: non_neg_integer
|
|
def count(%__MODULE__{} = description) do
|
|
Enum.reduce(description.predications, 0, fn {_, objects}, count ->
|
|
count + Enum.count(objects)
|
|
end)
|
|
end
|
|
|
|
@doc """
|
|
Checks if the given `input` statements exist within `description`.
|
|
"""
|
|
@spec include?(t, input, keyword) :: boolean
|
|
def include?(description, input, opts \\ [])
|
|
|
|
def include?(%__MODULE__{} = description, {subject, predicate, objects}, opts) do
|
|
coerce_subject(subject) == description.subject &&
|
|
include?(description, {predicate, objects}, opts)
|
|
end
|
|
|
|
def include?(%__MODULE__{} = description, {subject, predicate, objects, _}, opts) do
|
|
include?(description, {subject, predicate, objects}, opts)
|
|
end
|
|
|
|
def include?(%__MODULE__{} = description, {predicate, objects}, opts) do
|
|
if existing_objects = description.predications[coerce_predicate(predicate, context(opts))] do
|
|
objects
|
|
|> List.wrap()
|
|
|> Enum.map(&coerce_object/1)
|
|
|> Enum.all?(fn object -> Map.has_key?(existing_objects, object) end)
|
|
else
|
|
false
|
|
end
|
|
end
|
|
|
|
def include?(
|
|
%__MODULE__{subject: subject, predications: predications},
|
|
%__MODULE__{subject: subject} = input,
|
|
_opts
|
|
) do
|
|
Enum.all?(input.predications, fn {predicate, objects} ->
|
|
if existing_objects = predications[predicate] do
|
|
Enum.all?(objects, fn {object, _} ->
|
|
Map.has_key?(existing_objects, object)
|
|
end)
|
|
else
|
|
false
|
|
end
|
|
end)
|
|
end
|
|
|
|
def include?(%__MODULE__{}, %__MODULE__{}, _), do: false
|
|
|
|
if Version.match?(System.version(), "~> 1.10") do
|
|
def include?(description, input, opts)
|
|
when is_list(input) or (is_map(input) and not is_struct(input)) do
|
|
Enum.all?(input, &include?(description, &1, opts))
|
|
end
|
|
else
|
|
def include?(_, %_{}, _), do: raise(ArgumentError, "structs are not allowed as input")
|
|
|
|
def include?(description, input, opts) when is_list(input) or is_map(input) do
|
|
Enum.all?(input, &include?(description, &1, opts))
|
|
end
|
|
end
|
|
|
|
@doc """
|
|
Checks if a `RDF.Description` has the given resource as subject.
|
|
|
|
## Examples
|
|
|
|
iex> RDF.Description.new(EX.S1, init: {EX.p1, EX.O1})
|
|
...> |> RDF.Description.describes?(EX.S1)
|
|
true
|
|
iex> RDF.Description.new(EX.S1, init: {EX.p1, EX.O1})
|
|
...> |> RDF.Description.describes?(EX.S2)
|
|
false
|
|
"""
|
|
@spec describes?(t, Statement.subject()) :: boolean
|
|
def describes?(%__MODULE__{subject: subject}, other_subject) do
|
|
subject == coerce_subject(other_subject)
|
|
end
|
|
|
|
@doc """
|
|
Returns a map of the native Elixir values of a `RDF.Description`.
|
|
|
|
The subject is not part of the result. It can be converted separately with
|
|
`RDF.Term.value/1`, or, if you want the subject in an outer map, just put the
|
|
the description in a graph and use `RDF.Graph.values/2`.
|
|
|
|
When the optional `property_map` argument is given, predicates will be mapped
|
|
to the terms defined in the `RDF.PropertyMap` if present.
|
|
|
|
## Examples
|
|
|
|
iex> RDF.Description.new(~I<http://example.com/S>, init: {~I<http://example.com/p>, ~L"Foo"})
|
|
...> |> RDF.Description.values()
|
|
%{"http://example.com/p" => ["Foo"]}
|
|
|
|
iex> RDF.Description.new(~I<http://example.com/S>, init: {~I<http://example.com/p>, ~L"Foo"})
|
|
...> |> RDF.Description.values(PropertyMap.new(p: ~I<http://example.com/p>))
|
|
%{p: ["Foo"]}
|
|
|
|
"""
|
|
@spec values(t, PropertyMap.t() | nil) :: map
|
|
def values(description, property_map \\ nil)
|
|
|
|
def values(%__MODULE__{} = description, nil) do
|
|
map(description, &Statement.default_term_mapping/1)
|
|
end
|
|
|
|
def values(%__MODULE__{} = description, %PropertyMap{} = property_map) do
|
|
map(description, Statement.default_property_mapping(property_map))
|
|
end
|
|
|
|
@doc """
|
|
Returns a map of a `RDF.Description` where each element from its triples is mapped with the given function.
|
|
|
|
The subject is not part of the result. If you want the subject in an outer map,
|
|
just put the the description in a graph and use `RDF.Graph.map/2`.
|
|
|
|
The function `fun` will receive a tuple `{statement_position, rdf_term}` where
|
|
`statement_position` is one of the atoms `:predicate` or `:object`, while
|
|
`rdf_term` is the RDF term to be mapped. When the given function returns
|
|
`nil` this will be interpreted as an error and will become the overhaul result
|
|
of the `map/2` call.
|
|
|
|
## Examples
|
|
|
|
iex> RDF.Description.new(~I<http://example.com/S>, init: {~I<http://example.com/p>, ~L"Foo"})
|
|
...> |> RDF.Description.map(fn
|
|
...> {:predicate, predicate} ->
|
|
...> predicate
|
|
...> |> to_string()
|
|
...> |> String.split("/")
|
|
...> |> List.last()
|
|
...> |> String.to_atom()
|
|
...> {_, term} ->
|
|
...> RDF.Term.value(term)
|
|
...> end)
|
|
%{p: ["Foo"]}
|
|
|
|
"""
|
|
@spec map(t, Statement.term_mapping()) :: map
|
|
def map(description, fun)
|
|
|
|
def map(%__MODULE__{} = description, fun) do
|
|
Map.new(description.predications, fn {predicate, objects} ->
|
|
{
|
|
fun.({:predicate, predicate}),
|
|
objects |> Map.keys() |> Enum.map(&fun.({:object, &1}))
|
|
}
|
|
end)
|
|
end
|
|
|
|
@doc """
|
|
Creates a description from another one by limiting its statements to those using one of the given `predicates`.
|
|
|
|
If `predicates` contains properties that are not used in the `description`, they're simply ignored.
|
|
|
|
If `nil` is passed, the description is left untouched.
|
|
"""
|
|
@spec take(t, [Statement.coercible_predicate()] | Enum.t() | nil) :: t
|
|
def take(description, predicates)
|
|
|
|
def take(%__MODULE__{} = description, nil), do: description
|
|
|
|
def take(%__MODULE__{} = description, predicates) do
|
|
%__MODULE__{
|
|
description
|
|
| predications:
|
|
Map.take(description.predications, Enum.map(predicates, &coerce_predicate/1))
|
|
}
|
|
end
|
|
|
|
@doc """
|
|
Checks if two `RDF.Description`s are equal.
|
|
|
|
Two `RDF.Description`s are considered to be equal if they contain the same triples.
|
|
"""
|
|
@spec equal?(t, t) :: boolean
|
|
def equal?(description1, description2)
|
|
|
|
def equal?(%__MODULE__{} = description1, %__MODULE__{} = description2) do
|
|
description1 == description2
|
|
end
|
|
|
|
def equal?(_, _), do: false
|
|
|
|
defimpl Enumerable do
|
|
alias RDF.Description
|
|
|
|
def member?(desc, triple), do: {:ok, Description.include?(desc, triple)}
|
|
def count(desc), do: {:ok, Description.count(desc)}
|
|
def slice(_desc), do: {:error, __MODULE__}
|
|
|
|
def reduce(%Description{predications: predications}, {:cont, acc}, _fun)
|
|
when map_size(predications) == 0,
|
|
do: {:done, acc}
|
|
|
|
def reduce(%Description{} = description, {:cont, acc}, fun) do
|
|
{triple, rest} = Description.pop(description)
|
|
reduce(rest, fun.(triple, acc), fun)
|
|
end
|
|
|
|
def reduce(_, {:halt, acc}, _fun), do: {:halted, acc}
|
|
|
|
def reduce(%Description{} = description, {:suspend, acc}, fun) do
|
|
{:suspended, acc, &reduce(description, &1, fun)}
|
|
end
|
|
end
|
|
|
|
defimpl Collectable do
|
|
alias RDF.Description
|
|
|
|
def into(original) do
|
|
collector_fun = fn
|
|
description, {:cont, list} when is_list(list) ->
|
|
Description.add(description, List.to_tuple(list))
|
|
|
|
description, {:cont, elem} ->
|
|
Description.add(description, elem)
|
|
|
|
description, :done ->
|
|
description
|
|
|
|
_description, :halt ->
|
|
:ok
|
|
end
|
|
|
|
{original, collector_fun}
|
|
end
|
|
end
|
|
end
|