418 lines
13 KiB
Elixir
418 lines
13 KiB
Elixir
defmodule RDF.ListTest do
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use RDF.Test.Case
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doctest RDF.List
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import RDF.Sigils
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alias RDF.{BlankNode, Literal, Graph}
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use RDF.Vocabulary.Namespace
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defvocab EX,
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base_uri: "http://example.org/#",
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terms: [], strict: false
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setup do
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{:ok,
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empty: RDF.List.new(RDF.nil, Graph.new),
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one: RDF.List.from([EX.element], head: ~B<one>),
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abc: RDF.List.from(~w[a b c], head: ~B<abc>),
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ten: RDF.List.from(Enum.to_list(1..10), head: ~B<ten>),
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nested: RDF.List.from(["foo", [1, 2], "bar"], head: ~B<nested>),
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}
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end
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describe "new/2" do
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#######################################################################
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# success cases
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test "valid head list node" do
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graph = Graph.new(
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~B<Foo>
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|> RDF.first(1)
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|> RDF.rest(~B<Bar>))
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|> Graph.add(
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~B<Bar>
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|> RDF.first(2)
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|> RDF.rest(RDF.nil))
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assert %RDF.List{} = list = RDF.List.new(~B<Foo>, graph)
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assert list.head == ~B<Foo>
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assert list.graph == graph
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end
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test "with non-blank list nodes" do
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graph = Graph.new(
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EX.Foo
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|> RDF.first(1)
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|> RDF.rest(RDF.nil))
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assert %RDF.List{} = list = RDF.List.new(EX.Foo, graph)
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assert list.head == RDF.uri(EX.Foo)
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end
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test "with other properties on its nodes" do
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assert RDF.List.new(~B<Foo>,
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Graph.new(
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~B<Foo>
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|> EX.other(EX.Property)
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|> RDF.first(1)
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|> RDF.rest(~B<Bar>))
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|> Graph.add(
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~B<Bar>
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|> EX.other(EX.Property2)
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|> RDF.first(2)
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|> RDF.rest(RDF.nil))
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)
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|> RDF.List.valid? == true
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end
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#######################################################################
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# failure cases
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test "when given list node doesn't exist in the given graph" do
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assert RDF.List.new(RDF.bnode, RDF.Graph.new) == nil
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end
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test "When the given head node is not a list" do
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assert RDF.List.new(42, RDF.Graph.new) == nil
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assert RDF.List.new(EX.Foo, RDF.Graph.new({EX.Foo, EX.bar, EX.Baz})) == nil
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assert RDF.List.new(EX.Foo, RDF.Graph.new({EX.Foo, RDF.first, EX.Baz})) == nil
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end
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test "when list nodes are incomplete" do
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assert RDF.List.new(EX.Foo, RDF.Graph.new({EX.Foo, RDF.first, EX.Baz})) == nil
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assert RDF.List.new(EX.Foo, RDF.Graph.new({EX.Foo, RDF.rest, RDF.nil})) == nil
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end
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test "when head node has multiple rdf:first objects" do
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assert RDF.List.new(~B<Foo>,
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Graph.new(
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~B<Foo>
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|> RDF.first(1, 2)
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|> RDF.rest(RDF.nil))
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) == nil
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end
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test "when later list nodes have multiple rdf:first objects" do
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assert RDF.List.new(~B<Foo>,
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Graph.new(
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~B<Foo>
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|> RDF.first(1)
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|> RDF.rest(~B<Bar>))
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|> Graph.add(
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~B<Bar>
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|> RDF.first(2, 3)
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|> RDF.rest(RDF.nil))
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) == nil
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end
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test "when list nodes have multiple rdf:rest objects" do
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assert RDF.List.new(~B<Foo>,
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Graph.new(
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~B<Foo>
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|> RDF.first(1)
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|> RDF.rest(~B<Bar>, ~B<Baz>))
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|> Graph.add(
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~B<Bar>
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|> RDF.first(2)
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|> RDF.rest(RDF.nil))
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|> Graph.add(
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~B<Baz>
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|> RDF.first(3)
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|> RDF.rest(RDF.nil))
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) == nil
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assert RDF.List.new(~B<Foo>,
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Graph.new(
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~B<Foo>
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|> RDF.first(1)
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|> RDF.rest(~B<Bar>))
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|> Graph.add(
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~B<Bar>
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|> RDF.first(2)
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|> RDF.rest(RDF.nil, ~B<Baz>))
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|> Graph.add(
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~B<Baz>
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|> RDF.first(3)
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|> RDF.rest(RDF.nil))
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) == nil
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end
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test "when the list is cyclic" do
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assert RDF.List.new(~B<Foo>,
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Graph.new(
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~B<Foo>
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|> RDF.first(1)
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|> RDF.rest(~B<Bar>))
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|> Graph.add(
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~B<Bar>
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|> RDF.first(2)
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|> RDF.rest(~B<Foo>))
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) == nil
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end
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end
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describe "from/1" do
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test "an empty list", %{empty: empty} do
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assert RDF.List.from([]) == empty
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end
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test "an empty list with named head node", %{empty: empty} do
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assert RDF.List.from([], name: ~B<foo>) == empty
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end
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%{
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"URI" => RDF.uri(EX.Foo),
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"blank node" => ~B<Foo>,
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"literal" => ~L<Foo>,
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"string" => "Foo",
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"integer" => 42,
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"float" => 3.14,
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"true" => true,
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"false" => false,
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"unresolved namespace-qualified name" => EX.Foo,
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}
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|> Enum.each(fn {type, element} ->
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@tag element: element
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test "list with #{type} element", %{element: element} do
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with {bnode, graph_with_list} = one_element_list(element) do
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assert RDF.List.from([element], head: bnode) ==
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RDF.List.new(bnode, graph_with_list)
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end
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end
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end)
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test "nested list" do
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assert %RDF.List{head: bnode, graph: graph_with_list} =
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RDF.List.from([[1]])
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assert [nested] = get_in(graph_with_list, [bnode, RDF.first])
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assert get_in(graph_with_list, [bnode, RDF.rest]) == [RDF.nil]
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assert get_in(graph_with_list, [nested, RDF.first]) == [RDF.Integer.new(1)]
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assert get_in(graph_with_list, [nested, RDF.rest]) == [RDF.nil]
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assert %RDF.List{head: bnode, graph: graph_with_list} =
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RDF.List.from(["foo", [1, 2], "bar"])
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assert get_in(graph_with_list, [bnode, RDF.first]) == [~L"foo"]
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assert [second] = get_in(graph_with_list, [bnode, RDF.rest])
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assert [nested] = get_in(graph_with_list, [second, RDF.first])
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assert get_in(graph_with_list, [nested, RDF.first]) == [RDF.Integer.new(1)]
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assert [nested_second] = get_in(graph_with_list, [nested, RDF.rest])
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assert get_in(graph_with_list, [nested_second, RDF.first]) == [RDF.Integer.new(2)]
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assert get_in(graph_with_list, [nested_second, RDF.rest]) == [RDF.nil]
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assert [third] = get_in(graph_with_list, [second, RDF.rest])
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assert get_in(graph_with_list, [third, RDF.first]) == [~L"bar"]
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assert get_in(graph_with_list, [third, RDF.rest]) == [RDF.nil]
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end
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%{
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"preserve order" => [3, 2, 1],
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"different types" => [1, "foo", true, false, 3.14, EX.foo, EX.Foo, ~B<Foo>],
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}
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|> Enum.each(fn {desc, list} ->
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@tag list: list
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test "list with multiple elements: #{desc}", %{list: list} do
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assert %RDF.List{head: bnode, graph: graph_with_list} =
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RDF.List.from(list)
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assert RDF.nil ==
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Enum.reduce list, bnode, fn element, list_node ->
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case element do
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%URI{} ->
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assert get_in(graph_with_list, [list_node, RDF.first]) == [element]
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%BlankNode{} ->
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assert get_in(graph_with_list, [list_node, RDF.first]) == [element]
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%Literal{} ->
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assert get_in(graph_with_list, [list_node, RDF.first]) == [element]
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element when is_boolean(element) ->
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assert get_in(graph_with_list, [list_node, RDF.first]) == [RDF.Literal.new(element)]
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element when is_atom(element) ->
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assert get_in(graph_with_list, [list_node, RDF.first]) == [RDF.uri(element)]
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_ ->
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assert get_in(graph_with_list, [list_node, RDF.first]) == [RDF.Literal.new(element)]
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end
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[next] = get_in(graph_with_list, [list_node, RDF.rest])
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unless next == RDF.nil do
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assert %BlankNode{} = next
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end
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next
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end
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end
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end)
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test "an enumerable" do
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assert RDF.List.from(MapSet.new([42]), head: ~B<foo>) ==
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RDF.List.from([42], head: ~B<foo>)
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end
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test "head option with unresolved namespace-qualified name" do
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assert RDF.List.from([42], head: EX.Foo).head == RDF.uri(EX.Foo)
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end
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end
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describe "values/1" do
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test "the empty list", %{empty: empty} do
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assert RDF.List.values(empty) == []
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end
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test "list with one element", %{one: one} do
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assert RDF.List.values(one) == [EX.element]
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end
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test "list with multiple elements", %{abc: abc, ten: ten} do
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assert RDF.List.values(abc) == ~w[a b c] |> Enum.map(&Literal.new/1)
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assert RDF.List.values(ten) == 1..10 |> Enum.to_list |> Enum.map(&Literal.new/1)
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end
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test "list with non-blank list nodes" do
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assert RDF.List.from([EX.element], head: EX.Foo)
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|> RDF.List.values == [EX.element]
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end
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test "nested list", %{nested: nested} do
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assert RDF.List.values(nested) ==
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[~L"foo", [RDF.Integer.new(1), RDF.Integer.new(2)], ~L"bar"]
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assert RDF.list(["foo", [1, 2]]) |> RDF.List.values ==
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[~L"foo", [RDF.Integer.new(1), RDF.Integer.new(2)]]
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assert RDF.list([[1, 2], "foo"]) |> RDF.List.values ==
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[[RDF.Integer.new(1), RDF.Integer.new(2)], ~L"foo"]
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inner_list = RDF.list([1, 2], head: ~B<inner>)
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assert RDF.list(["foo", ~B<inner>], graph: inner_list.graph)
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|> RDF.List.values == [~L"foo", [RDF.Integer.new(1), RDF.Integer.new(2)]]
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end
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end
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describe "nodes/1" do
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test "the empty list", %{empty: empty} do
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assert RDF.List.nodes(empty) == []
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end
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test "non-empty list", %{one: one} do
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assert RDF.List.nodes(one) == [~B<one>]
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end
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test "nested list", %{nested: nested} do
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assert RDF.list([[1, 2, 3]], head: ~B<outer>)
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|> RDF.List.nodes == [~B<outer>]
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assert [~B<nested>, _, _] = RDF.List.nodes(nested)
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end
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end
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describe "valid?/2" do
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test "the empty list", %{empty: empty} do
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assert RDF.List.valid?(empty)
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end
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test "valid list with one element", %{one: one} do
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assert RDF.List.valid?(one) == true
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end
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test "valid list with multiple elements", %{abc: abc, ten: ten} do
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assert RDF.List.valid?(abc) == true
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assert RDF.List.valid?(ten) == true
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end
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test "valid nested list", %{nested: nested} do
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assert RDF.List.valid?(nested) == true
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end
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test "a non-blank list node is not valid" do
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assert RDF.list([EX.element], head: EX.Foo) |> RDF.List.valid? == false
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end
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test "a non-blank list node on later nodes makes the whole list invalid" do
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assert RDF.List.new(~B<Foo>,
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Graph.new(
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~B<Foo>
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|> RDF.first(1)
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|> RDF.rest(EX.Foo))
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|> Graph.add(
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EX.Foo
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|> RDF.first(2)
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|> RDF.rest(RDF.nil))
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)
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|> RDF.List.valid? == false
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end
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end
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describe "node?" do
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test "the empty list", %{empty: empty} do
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assert RDF.List.node?(empty.head, empty.graph) == true
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end
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test "list with one element", %{one: one} do
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assert RDF.List.node?(one.head, one.graph) == true
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end
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test "list with multiple elements", %{abc: abc, ten: ten} do
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assert RDF.List.node?(abc.head, abc.graph) == true
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assert RDF.List.node?(ten.head, ten.graph) == true
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end
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test "nested list", %{nested: nested} do
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assert RDF.List.node?(nested.head, nested.graph) == true
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end
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test "unresolved namespace-qualified name" do
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assert RDF.List.node?(EX.Foo,
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RDF.List.from([EX.element], head: EX.Foo).graph) == true
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end
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test "when given list node doesn't exist in the given graph" do
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assert RDF.List.node?(RDF.bnode, RDF.Graph.new) == false
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end
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test "literal" do
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assert RDF.List.node?(~L"Foo", RDF.Graph.new) == false
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assert RDF.List.node?(42, RDF.Graph.new) == false
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assert RDF.List.node?(true, RDF.Graph.new) == false
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assert RDF.List.node?(false, RDF.Graph.new) == false
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assert RDF.List.node?(nil, RDF.Graph.new) == false
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end
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test "non-list node" do
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assert RDF.List.node?(EX.Foo, RDF.Graph.new({EX.Foo, EX.bar, EX.Baz})) == false
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end
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test "incomplete list nodes" do
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assert RDF.List.node?(EX.Foo, RDF.Graph.new({EX.Foo, RDF.first, EX.Baz})) == false
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assert RDF.List.node?(EX.Foo, RDF.Graph.new({EX.Foo, RDF.rest, RDF.nil})) == false
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end
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end
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describe "Enumerable.reduce" do
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test "the empty list", %{empty: empty} do
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assert Enum.reduce(empty, [], fn description, acc -> [description | acc] end) == []
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end
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test "a valid list", %{one: one} do
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assert [one.graph[one.head]] ==
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Enum.reduce(one, [], fn description, acc -> [description | acc] end)
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end
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end
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defp one_element_list(element),
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do: one_element_list(element, RDF.bnode)
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defp one_element_list(element, bnode) do
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{bnode,
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Graph.new(
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bnode
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|> RDF.first(element)
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|> RDF.rest(RDF.nil)
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)
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}
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end
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end
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