2016-10-15 16:26:56 +00:00
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defmodule RDF.GraphTest do
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use ExUnit.Case
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2016-11-02 02:19:19 +00:00
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defmodule EX, do:
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use RDF.Vocabulary, base_uri: "http://example.com/graph/"
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2016-10-15 16:26:56 +00:00
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doctest RDF.Graph
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alias RDF.Graph
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import RDF, only: [uri: 1]
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def graph, do: unnamed_graph
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def unnamed_graph, do: Graph.new
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def named_graph(name \\ EX.GraphName), do: Graph.new(name)
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def unnamed_graph?(%Graph{name: nil}), do: true
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def unnamed_graph?(_), do: false
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def named_graph?(%Graph{name: %URI{}}), do: true
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def named_graph?(_), do: false
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def named_graph?(%Graph{name: name}, name), do: true
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def named_graph?(_, _), do: false
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def empty_graph?(%Graph{descriptions: descriptions}), do: descriptions == %{}
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def graph_includes_statement?(graph, statement = {subject, _, _}) do
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graph.descriptions
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|> Map.get(uri(subject), %{})
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|> Enum.member?(statement)
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end
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describe "construction" do
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test "creating an empty unnamed graph" do
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assert unnamed_graph?(unnamed_graph)
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end
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test "creating an empty graph with a proper graph name" do
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refute unnamed_graph?(named_graph)
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assert named_graph?(named_graph)
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end
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test "creating an empty graph with a convertible graph name" do
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assert named_graph("http://example.com/graph/GraphName")
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|> named_graph?(uri("http://example.com/graph/GraphName"))
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assert named_graph(EX.Foo) |> named_graph?(uri(EX.Foo))
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end
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test "creating an unnamed graph with an initial triple" do
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g = Graph.new({EX.Subject, EX.predicate, EX.Object})
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assert unnamed_graph?(g)
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assert graph_includes_statement?(g, {EX.Subject, EX.predicate, EX.Object})
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end
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test "creating a named graph with an initial triple" do
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g = Graph.new(EX.GraphName, {EX.Subject, EX.predicate, EX.Object})
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assert named_graph?(g, uri(EX.GraphName))
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assert graph_includes_statement?(g, {EX.Subject, EX.predicate, EX.Object})
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end
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test "creating an unnamed graph with a list of initial triples" do
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g = Graph.new([{EX.Subject1, EX.predicate1, EX.Object1},
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{EX.Subject2, EX.predicate2, EX.Object2}])
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assert unnamed_graph?(g)
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assert graph_includes_statement?(g, {EX.Subject1, EX.predicate1, EX.Object1})
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assert graph_includes_statement?(g, {EX.Subject2, EX.predicate2, EX.Object2})
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end
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test "creating a named graph with a list of initial triples" do
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g = Graph.new(EX.GraphName, [{EX.Subject, EX.predicate1, EX.Object1},
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{EX.Subject, EX.predicate2, EX.Object2}])
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assert named_graph?(g, uri(EX.GraphName))
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assert graph_includes_statement?(g, {EX.Subject, EX.predicate1, EX.Object1})
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assert graph_includes_statement?(g, {EX.Subject, EX.predicate2, EX.Object2})
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end
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end
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describe "adding triples" do
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test "a proper triple" do
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assert Graph.add(graph, {uri(EX.Subject), EX.predicate, uri(EX.Object)})
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|> graph_includes_statement?({EX.Subject, EX.predicate, EX.Object})
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end
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test "a convertiable triple" do
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assert Graph.add(graph,
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{"http://example.com/graph/Subject", EX.predicate, EX.Object})
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|> graph_includes_statement?({EX.Subject, EX.predicate, EX.Object})
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end
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test "a list of triples" do
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g = Graph.add(graph, [
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{EX.Subject1, EX.predicate1, EX.Object1},
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{EX.Subject1, EX.predicate2, EX.Object2},
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{EX.Subject3, EX.predicate3, EX.Object3}
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])
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assert graph_includes_statement?(g, {EX.Subject1, EX.predicate1, EX.Object1})
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assert graph_includes_statement?(g, {EX.Subject1, EX.predicate2, EX.Object2})
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assert graph_includes_statement?(g, {EX.Subject3, EX.predicate3, EX.Object3})
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end
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test "duplicates are ignored" do
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g = Graph.add(graph, {EX.Subject, EX.predicate, EX.Object})
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assert Graph.add(g, {EX.Subject, EX.predicate, EX.Object}) == g
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end
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test "non-convertible Triple elements are causing an error" do
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assert_raise RDF.InvalidURIError, fn ->
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Graph.add(graph, {"not a URI", EX.predicate, uri(EX.Object)})
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end
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assert_raise RDF.Literal.InvalidLiteralError, fn ->
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Graph.add(graph, {EX.Subject, EX.prop, self})
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end
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end
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end
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test "subject_count" do
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g = Graph.add(graph, [
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{EX.Subject1, EX.predicate1, EX.Object1},
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{EX.Subject1, EX.predicate2, EX.Object2},
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{EX.Subject3, EX.predicate3, EX.Object3}
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])
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assert Graph.subject_count(g) == 2
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end
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test "pop a triple" do
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assert Graph.pop(Graph.new) == {nil, Graph.new}
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{triple, graph} = Graph.new({EX.S, EX.p, EX.O}) |> Graph.pop
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assert {uri(EX.S), uri(EX.p), uri(EX.O)} == triple
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assert Enum.count(graph.descriptions) == 0
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{{subject, predicate, _}, graph} =
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Graph.new([{EX.S, EX.p, EX.O1}, {EX.S, EX.p, EX.O2}])
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|> Graph.pop
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assert {subject, predicate} == {uri(EX.S), uri(EX.p)}
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assert Enum.count(graph.descriptions) == 1
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{{subject, _, _}, graph} =
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Graph.new([{EX.S, EX.p1, EX.O1}, {EX.S, EX.p2, EX.O2}])
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|> Graph.pop
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assert subject == uri(EX.S)
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assert Enum.count(graph.descriptions) == 1
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end
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describe "Enumerable implementation" do
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test "Enum.count" do
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assert Enum.count(Graph.new EX.foo) == 0
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assert Enum.count(Graph.new {EX.S, EX.p, EX.O}) == 1
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assert Enum.count(Graph.new [{EX.S, EX.p, EX.O1}, {EX.S, EX.p, EX.O2}]) == 2
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g = Graph.add(graph, [
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{EX.Subject1, EX.predicate1, EX.Object1},
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{EX.Subject1, EX.predicate2, EX.Object2},
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{EX.Subject3, EX.predicate3, EX.Object3}
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])
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assert Enum.count(g) == 3
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end
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test "Enum.member?" do
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refute Enum.member?(Graph.new, {uri(EX.S), EX.p, uri(EX.O)})
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assert Enum.member?(Graph.new({EX.S, EX.p, EX.O}), {EX.S, EX.p, EX.O})
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g = Graph.add(graph, [
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{EX.Subject1, EX.predicate1, EX.Object1},
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{EX.Subject1, EX.predicate2, EX.Object2},
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{EX.Subject3, EX.predicate3, EX.Object3}
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])
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assert Enum.member?(g, {EX.Subject1, EX.predicate1, EX.Object1})
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assert Enum.member?(g, {EX.Subject1, EX.predicate2, EX.Object2})
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assert Enum.member?(g, {EX.Subject3, EX.predicate3, EX.Object3})
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end
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test "Enum.reduce" do
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g = Graph.add(graph, [
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{EX.Subject1, EX.predicate1, EX.Object1},
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{EX.Subject1, EX.predicate2, EX.Object2},
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{EX.Subject3, EX.predicate3, EX.Object3}
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])
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assert g == Enum.reduce(g, graph,
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fn(triple, acc) -> acc |> Graph.add(triple) end)
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end
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end
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end
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