Exemplo n.º 1
0
    def test_partition_with_fixed_atom_constraints(self):
        """
        test a partitioning with a graph with fixed atom constraint
        """

        # Create a 2x2 machine with 10 cores per chip (so 40 cores),
        # but 1MB off 2MB per chip (so 19MB per chip)
        n_cores_per_chip = 10
        sdram_per_chip = (n_cores_per_chip * 2) - 1
        machine = virtual_machine(
            width=2, height=2, n_cpus_per_chip=n_cores_per_chip,
            sdram_per_chip=sdram_per_chip)

        # Create a vertex where each atom requires 1MB (default) of SDRAM
        # but which can't be subdivided lower than 2 atoms per core.
        # The vertex has 1 atom per MB of SDRAM, and so would fit but will
        # be disallowed by the fixed atoms per core constraint
        vertex = SimpleTestVertex(
            sdram_per_chip * machine.n_chips,
            max_atoms_per_core=2, constraints=[FixedVertexAtomsConstraint(2)])
        vertex.splitter = SplitterSliceLegacy()
        app_graph = ApplicationGraph("Test")
        app_graph.add_vertex(vertex)

        # Do the partitioning - this should result in an error
        with self.assertRaises(PacmanValueError):
            partitioner = SplitterPartitioner()
            partitioner(app_graph, machine, 3000)
Exemplo n.º 2
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    def test_1_chip_pre_allocated_too_much_sdram(self):
        machine = VirtualMachine(width=8, height=8)
        graph = ApplicationGraph("Test")
        partitioner = PartitionAndPlacePartitioner()

        eight_meg = 8 * 1024 * 1024

        # add graph vertices which reside on 0,0
        for _ in range(0, 13):
            graph.add_vertex(
                SimpleTestVertex(constraints=[ChipAndCoreConstraint(x=0, y=0)],
                                 n_atoms=1,
                                 fixed_sdram_value=eight_meg))

        # add pre-allocated resources for cores on 0,0
        twenty_meg = 20 * 1024 * 1024
        core_pre = SpecificChipSDRAMResource(chip=machine.get_chip_at(0, 0),
                                             sdram_usage=twenty_meg)
        pre_allocated_res = PreAllocatedResourceContainer(
            specific_sdram_usage=[core_pre])

        # run partitioner that should go boom
        try:
            partitioner(graph, machine, pre_allocated_res)
            raise Exception("should have blown up here")
        except PacmanPartitionException:
            pass
        except Exception:
            raise Exception("should have blown up here")
    def test_1_chip_pre_allocated_same_core(self):
        machine = VirtualMachine(width=8, height=8)
        graph = ApplicationGraph("Test")
        partitioner = PartitionAndPlacePartitioner()

        # add graph vertices which reside on 0,0
        for p in range(0, 13):
            graph.add_vertex(SimpleTestVertex(
                constraints=[ChipAndCoreConstraint(x=0, y=0, p=p)],
                n_atoms=1))

        # add pre-allocated resources for cores on 0,0
        core_pre = SpecificCoreResource(
            chip=machine.get_chip_at(0, 0), cores=[4])
        pre_allocated_res = PreAllocatedResourceContainer(
            specific_core_resources=[core_pre])

        # run partitioner that should go boom
        try:
            partitioner(graph, machine, plan_n_timesteps=None,
                        preallocated_resources=pre_allocated_res)
            raise Exception("should have blown up here")
        except PacmanValueError:
            pass
        except Exception:
            raise Exception("should have blown up here")
    def test_1_chip_pre_allocated_too_much_sdram(self):
        machine = VirtualMachine(width=8, height=8)
        graph = ApplicationGraph("Test")
        partitioner = PartitionAndPlacePartitioner()

        eight_meg = 8 * 1024 * 1024

        # add graph vertices which reside on 0,0
        for _ in range(0, 13):
            graph.add_vertex(SimpleTestVertex(
                constraints=[ChipAndCoreConstraint(x=0, y=0)],
                n_atoms=1,
                fixed_sdram_value=eight_meg))

        # add pre-allocated resources for cores on 0,0
        twenty_meg = ConstantSDRAM(20 * 1024 * 1024)
        core_pre = SpecificChipSDRAMResource(
            chip=machine.get_chip_at(0, 0), sdram_usage=twenty_meg)
        pre_allocated_res = PreAllocatedResourceContainer(
            specific_sdram_usage=[core_pre])

        # run partitioner that should go boom
        try:
            partitioner(graph, machine, plan_n_timesteps=None,
                        preallocated_resources=pre_allocated_res)
            raise Exception("should have blown up here")
        except PacmanPartitionException:
            pass
        except Exception:
            exc_info = sys.exc_info()
            six.reraise(*exc_info)
    def test_partition_with_fixed_atom_constraints_at_limit(self):
        """
        test a partitioning with a graph with fixed atom constraint which\
        should fit but is close to the limit
        """

        # Create a 2x2 machine with 1 core per chip (so 4 cores),
        # and 8MB SDRAM per chip
        n_cores_per_chip = 1
        sdram_per_chip = 8
        machine = VirtualMachine(
            width=2, height=2, with_monitors=False,
            n_cpus_per_chip=n_cores_per_chip,
            sdram_per_chip=sdram_per_chip)

        # Create a vertex which will need to be split perfectly into 4 cores
        # to work and which max atoms per core must be ignored
        vertex = SimpleTestVertex(
            sdram_per_chip * 2, max_atoms_per_core=sdram_per_chip,
            constraints=[FixedVertexAtomsConstraint(sdram_per_chip // 2)])
        app_graph = ApplicationGraph("Test")
        app_graph.add_vertex(vertex)

        # Do the partitioning - this should just work
        partitioner = PartitionAndPlacePartitioner()
        machine_graph, _, _ = partitioner(
            app_graph, machine, plan_n_timesteps=None)
        self.assert_(len(machine_graph.vertices) == 4)
Exemplo n.º 6
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    def test_partition_with_fixed_atom_constraints_at_limit(self):
        """
        test a partitioning with a graph with fixed atom constraint which\
        should fit but is close to the limit
        """

        # Create a 2x2 machine with 1 core per chip (so 4 cores),
        # and 8MB SDRAM per chip
        n_cores_per_chip = 2  # Remember 1 core is the monitor
        sdram_per_chip = 8
        machine = virtual_machine(
            width=2, height=2, n_cpus_per_chip=n_cores_per_chip,
            sdram_per_chip=sdram_per_chip)

        # Create a vertex which will need to be split perfectly into 4 cores
        # to work and which max atoms per core must be ignored
        vertex = SimpleTestVertex(
            sdram_per_chip * 2, max_atoms_per_core=sdram_per_chip,
            constraints=[FixedVertexAtomsConstraint(sdram_per_chip // 2)])
        vertex.splitter = SplitterSliceLegacy()
        app_graph = ApplicationGraph("Test")
        app_graph.add_vertex(vertex)

        # Do the partitioning - this should just work
        partitioner = SplitterPartitioner()
        machine_graph, _ = partitioner(app_graph, machine, 3000)
        self.assertEqual(4, len(machine_graph.vertices))
Exemplo n.º 7
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    def test_1_chip_pre_allocated_same_core(self):
        machine = VirtualMachine(width=8, height=8)
        graph = ApplicationGraph("Test")
        partitioner = PartitionAndPlacePartitioner()

        # add graph vertices which reside on 0,0
        for p in range(0, 13):
            graph.add_vertex(
                SimpleTestVertex(
                    constraints=[ChipAndCoreConstraint(x=0, y=0, p=p)],
                    n_atoms=1))

        # add pre-allocated resources for cores on 0,0
        core_pre = SpecificCoreResource(chip=machine.get_chip_at(0, 0),
                                        cores=[4])
        pre_allocated_res = PreAllocatedResourceContainer(
            specific_core_resources=[core_pre])

        # run partitioner that should go boom
        try:
            partitioner(graph, machine, pre_allocated_res)
            raise Exception("should have blown up here")
        except PacmanValueError:
            pass
        except Exception:
            raise Exception("should have blown up here")
    def test_1_chip_no_pre_allocated_too_much_sdram(self):
        machine = virtual_machine(width=8, height=8)
        graph = ApplicationGraph("Test")
        partitioner = SplitterPartitioner()

        eight_meg = 8 * 1024 * 1024

        # add graph vertices which reside on 0,0
        for _ in range(0, 13):
            vertex = SimpleTestVertex(
                constraints=[ChipAndCoreConstraint(x=0, y=0)],
                n_atoms=1,
                fixed_sdram_value=eight_meg)
            vertex.splitter = SplitterSliceLegacy()
            graph.add_vertex(vertex)

        # add pre-allocated resources for cores on 0,0
        pre_allocated_res = PreAllocatedResourceContainer()

        # run partitioner that should go boom
        try:
            partitioner(graph, machine, plan_n_time_steps=None,
                        pre_allocated_resources=pre_allocated_res)
        except Exception:
            raise Exception("should have blown up here")
    def test_1_chip_over_pre_allocated(self):
        machine = virtual_machine(width=8, height=8)
        graph = ApplicationGraph("Test")
        partitioner = SplitterPartitioner()

        # add graph vertices which reside on 0,0
        for _ in range(0, 13):
            vertex = SimpleTestVertex(
                constraints=[ChipAndCoreConstraint(x=0, y=0)],
                n_atoms=1)
            vertex.splitter = SplitterSliceLegacy()
            graph.add_vertex(vertex)

        # add pre-allocated resources for cores on 0,0
        core_pre = CoreResource(chip=machine.get_chip_at(0, 0), n_cores=5)
        pre_allocated_res = PreAllocatedResourceContainer(
            core_resources=[core_pre])

        # run partitioner that should go boom
        try:
            partitioner(graph, machine, plan_n_time_steps=None,
                        pre_allocated_resources=pre_allocated_res)
            raise Exception("should have blown up here")
        except PacmanInvalidParameterException:
            pass
    def test_create_new_graph(self):
        vert1 = SimpleTestVertex(10, "New AbstractConstrainedVertex 1", 256)
        vert2 = SimpleTestVertex(5, "New AbstractConstrainedVertex 2", 256)
        vert3 = SimpleTestVertex(3, "New AbstractConstrainedVertex 3", 256)
        edge1 = ApplicationEdge(vert1, vert2, label="First edge")
        edge2 = ApplicationEdge(vert2, vert1, label="First edge")
        edge3 = ApplicationEdge(vert1, vert3, label="First edge")
        verts = [vert1, vert2, vert3]
        edges = [edge1, edge2, edge3]
        graph = ApplicationGraph("Graph")
        graph.add_vertices(verts)
        graph.add_edges(edges, "foo")  # Any old partition label
        assert frozenset(verts) == frozenset(graph.vertices)
        assert frozenset(edges) == frozenset(graph.edges)

        assert edge1 not in graph.get_edges_ending_at_vertex(vert1)
        assert edge2 not in graph.get_edges_starting_at_vertex(vert1)
        assert edge3 not in graph.get_edges_ending_at_vertex(vert1)

        second = graph.clone()
        assert frozenset(verts) == frozenset(second.vertices)
        assert frozenset(edges) == frozenset(second.edges)

        third = ApplicationGraphView(graph)
        assert frozenset(verts) == frozenset(third.vertices)
        assert frozenset(edges) == frozenset(third.edges)
        with self.assertRaises(PacmanConfigurationException):
            third.add_edge("mock", "mock")
        with self.assertRaises(PacmanConfigurationException):
            third.add_vertex("mock")
        with self.assertRaises(PacmanConfigurationException):
            third.add_outgoing_edge_partition("mock")
    def test_1_chip_pre_allocated_too_much_sdram(self):
        machine = virtual_machine(width=8, height=8)
        graph = ApplicationGraph("Test")
        partitioner = SplitterPartitioner()

        eight_meg = 8 * 1024 * 1024

        # add graph vertices which reside on 0,0
        for _ in range(0, 13):
            vertex = SimpleTestVertex(
                constraints=[ChipAndCoreConstraint(x=0, y=0)],
                n_atoms=1,
                fixed_sdram_value=eight_meg)
            vertex.splitter = SplitterSliceLegacy()
            graph.add_vertex(vertex)

        # add pre-allocated resources for cores on 0,0
        twenty_meg = ConstantSDRAM(20 * 1024 * 1024)
        core_pre = SpecificChipSDRAMResource(
            chip=machine.get_chip_at(0, 0), sdram_usage=twenty_meg)
        pre_allocated_res = PreAllocatedResourceContainer(
            specific_sdram_usage=[core_pre])

        # run partitioner that should go boom
        try:
            partitioner(graph, machine, plan_n_time_steps=None,
                        pre_allocated_resources=pre_allocated_res)
            raise Exception("should have blown up here")
        except PacmanPartitionException:
            pass
        except Exception:
            exc_info = sys.exc_info()
            six.reraise(*exc_info)
    def test_partition_with_fixed_atom_constraints(self):
        """
        test a partitioning with a graph with fixed atom constraint
        """

        # Create a 2x2 machine with 10 cores per chip (so 40 cores),
        # but 1MB off 2MB per chip (so 19MB per chip)
        n_cores_per_chip = 10
        sdram_per_chip = (n_cores_per_chip * 2) - 1
        machine = VirtualMachine(
            width=2, height=2, with_monitors=False,
            n_cpus_per_chip=n_cores_per_chip,
            sdram_per_chip=sdram_per_chip)

        # Create a vertex where each atom requires 1MB (default) of SDRAM
        # but which can't be subdivided lower than 2 atoms per core.
        # The vertex has 1 atom per MB of SDRAM, and so would fit but will
        # be disallowed by the fixed atoms per core constraint
        vertex = SimpleTestVertex(
            sdram_per_chip * machine.n_chips,
            max_atoms_per_core=2, constraints=[FixedVertexAtomsConstraint(2)])
        app_graph = ApplicationGraph("Test")
        app_graph.add_vertex(vertex)

        # Do the partitioning - this should result in an error
        with self.assertRaises(PacmanPartitionException):
            partitioner = PartitionAndPlacePartitioner()
            partitioner(app_graph, machine, plan_n_timesteps=None)
Exemplo n.º 13
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    def test_get_vertices_from_vertex(self):
        """
        test getting the vertex from a graph mapper via the vertex
        """
        vertices = list()
        app_graph = ApplicationGraph("bacon")
        vert = SimpleTestVertex(10, "Some testing vertex")
        app_graph.add_vertex(vert)
        vertices.append(SimpleMachineVertex(None, ""))
        vertices.append(SimpleMachineVertex(None, ""))
        mac_graph = MachineGraph("cooked bacon", application_graph=app_graph)
        vertex1 = SimpleMachineVertex(None,
                                      "",
                                      vertex_slice=Slice(0, 1),
                                      app_vertex=vert)
        vertex2 = SimpleMachineVertex(None,
                                      "",
                                      vertex_slice=Slice(2, 3),
                                      app_vertex=vert)
        mac_graph.add_vertex(vertex1)
        mac_graph.add_vertex(vertex2)

        returned_vertices = vert.machine_vertices

        self.assertIn(vertex1, returned_vertices)
        self.assertIn(vertex2, returned_vertices)
        for v in vertices:
            self.assertNotIn(v, returned_vertices)
Exemplo n.º 14
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 def test_partition_with_empty_graph(self):
     """
     test that the partitioner can work with an empty graph
     """
     self.graph = ApplicationGraph("foo")
     graph, _ = splitter_partitioner(self.graph, self.machine, 3000)
     self.assertEqual(len(list(graph.vertices)), 0)
Exemplo n.º 15
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 def test_partition_with_empty_graph(self):
     """test that the partitioner can work with an empty graph
     """
     self.graph = ApplicationGraph("foo")
     graph, _ = splitter_partitioner(
         self.graph,
         self.machine,
         plan_n_time_steps=100,
         pre_allocated_resources=PreAllocatedResourceContainer())
     self.assertEqual(len(list(graph.vertices)), 0)
Exemplo n.º 16
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 def test_partition_on_target_size_vertex_than_has_to_be_split(self):
     """
     test that fixed partitioning causes correct number of vertices
     """
     self.setup()
     large_vertex = SimpleTestVertex(1000, "Large vertex")
     large_vertex.add_constraint(MaxVertexAtomsConstraint(10))
     self.graph = ApplicationGraph("Graph with large vertex")
     self.graph.add_vertex(large_vertex)
     graph, _, _ = self.bp(self.graph, self.machine)
     self.assertEqual(len(list(graph.vertices)), 100)
Exemplo n.º 17
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 def test_partition_on_large_vertex_than_has_to_be_split(self):
     """
     test that partitioning 1 large vertex can make it into 2 small ones
     """
     self.setup()
     large_vertex = SimpleTestVertex(300, "Large vertex")
     self.graph = ApplicationGraph("Graph with large vertex")
     self.graph.add_vertex(large_vertex)
     self.assertEqual(large_vertex._model_based_max_atoms_per_core, 256)
     graph, _, _ = self.bp(self.graph, self.machine)
     self.assertGreater(len(list(graph.vertices)), 1)
Exemplo n.º 18
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    def setUp(self):
        """
        setup for all basic partitioner tests
        """
        unittest_setup()
        self.vert1 = SimpleTestVertex(10, "New AbstractConstrainedVertex 1")
        self.vert1.splitter = SplitterSliceLegacy()
        self.vert2 = SimpleTestVertex(5, "New AbstractConstrainedVertex 2")
        self.vert2.splitter = SplitterSliceLegacy()
        self.vert3 = SimpleTestVertex(3, "New AbstractConstrainedVertex 3")
        self.vert3.splitter = SplitterSliceLegacy()
        self.edge1 = ApplicationEdge(self.vert1,
                                     self.vert2,
                                     label="First edge")
        self.edge2 = ApplicationEdge(self.vert2,
                                     self.vert1,
                                     label="Second edge")
        self.edge3 = ApplicationEdge(self.vert1,
                                     self.vert3,
                                     label="Third edge")
        self.verts = [self.vert1, self.vert2, self.vert3]
        self.edges = [self.edge1, self.edge2, self.edge3]
        self.graph = ApplicationGraph("Graph")
        self.graph.add_vertices(self.verts)
        self.graph.add_edges(self.edges, "foo")

        n_processors = 18
        (e, ne, n, w, _, _) = range(6)

        links = list()
        links.append(Link(0, 0, e, 0, 1))

        _sdram = SDRAM(128 * (2**20))

        links = list()

        links.append(Link(0, 0, e, 1, 1))
        links.append(Link(0, 1, ne, 1, 0))
        links.append(Link(1, 1, n, 0, 0))
        links.append(Link(1, 0, w, 0, 1))
        r = Router(links, False, 1024)

        ip = TestBasicPartitioner.TheTestAddress
        chips = list()
        for x in range(5):
            for y in range(5):
                if x == y == 0:
                    chips.append(Chip(x, y, n_processors, r, _sdram, 0, 0, ip))
                else:
                    chips.append(Chip(x, y, n_processors, r, _sdram, 0, 0))

        self.machine = machine_from_chips(chips)
Exemplo n.º 19
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 def test_partition_on_very_large_vertex_than_has_to_be_split(self):
     """
     test that partitioning 1 large vertex can make it into multiple small
     ones
     """
     large_vertex = SimpleTestVertex(500, "Large vertex")
     large_vertex.splitter = SplitterSliceLegacy()
     self.assertEqual(large_vertex._model_based_max_atoms_per_core, 256)
     self.graph = ApplicationGraph("Graph with large vertex")
     self.graph.add_vertex(large_vertex)
     graph, _ = splitter_partitioner(self.graph, self.machine, 3000)
     self.assertEqual(large_vertex._model_based_max_atoms_per_core, 256)
     self.assertGreater(len(list(graph.vertices)), 1)
Exemplo n.º 20
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 def test_partition_with_unsupported_constraints(self):
     """
     test that when a vertex has a constraint that is unrecognised,
     it raises an error
     """
     self.setup()
     constrained_vertex = SimpleTestVertex(13, "Constrained")
     constrained_vertex.add_constraint(
         NewPartitionerConstraint("Mock constraint"))
     graph = ApplicationGraph("Graph")
     graph.add_vertex(constrained_vertex)
     partitioner = BasicPartitioner()
     with self.assertRaises(PacmanInvalidParameterException):
         partitioner(graph, self.machine)
 def test_partition_with_unsupported_constraints(self):
     """
     test that when a vertex has a constraint that is unrecognised,
     it raises an error
     """
     self.setup()
     constrained_vertex = SimpleTestVertex(13, "Constrained")
     constrained_vertex.add_constraint(
         NewPartitionerConstraint("Mock constraint"))
     graph = ApplicationGraph("Graph")
     graph.add_vertex(constrained_vertex)
     partitioner = PartitionAndPlacePartitioner()
     with self.assertRaises(PacmanInvalidParameterException):
         partitioner(graph, self.machine, PreAllocatedResourceContainer())
Exemplo n.º 22
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 def test_partition_on_target_size_vertex_than_has_to_be_split(self):
     """
     test that fixed partitioning causes correct number of vertices
     """
     large_vertex = SimpleTestVertex(1000, "Large vertex")
     large_vertex.add_constraint(MaxVertexAtomsConstraint(10))
     large_vertex.splitter = SplitterSliceLegacy()
     self.graph = ApplicationGraph("Graph with large vertex")
     self.graph.add_vertex(large_vertex)
     graph, _ = splitter_partitioner(
         self.graph,
         self.machine,
         plan_n_time_steps=100,
         pre_allocated_resources=PreAllocatedResourceContainer())
     self.assertEqual(len(list(graph.vertices)), 100)
Exemplo n.º 23
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 def test_partition_on_large_vertex_than_has_to_be_split(self):
     """
     test that partitioning 1 large vertex can make it into 2 small ones
     """
     large_vertex = SimpleTestVertex(300, "Large vertex")
     large_vertex.splitter = SplitterSliceLegacy()
     self.graph = ApplicationGraph("Graph with large vertex")
     self.graph.add_vertex(large_vertex)
     graph, _ = splitter_partitioner(
         self.graph,
         self.machine,
         plan_n_time_steps=100,
         pre_allocated_resources=PreAllocatedResourceContainer())
     self.assertEqual(large_vertex._model_based_max_atoms_per_core, 256)
     self.assertGreater(len(list(graph.vertices)), 1)
Exemplo n.º 24
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    def test_many_vertices(self):
        vertices = list()
        for i in range(20 * 17):  # 51 atoms per each processor on 20 chips
            vertices.append(
                SimpleMachineVertex(0, 50,
                                    get_resources_used_by_atoms(0, 50, []),
                                    "vertex " + str(i)))

        self.graph = ApplicationGraph("Graph", vertices)
        self.graph_mapper = GraphMapper()
        self.graph_mapper.add_vertices(vertices)
        self.bp = RadialPlacer(self.machine, self.graph)
        self.graph = MachineGraph(vertices=vertices)
        placements = self.bp.place(self.graph, self.graph_mapper)

        unorderdered_info = list()
        for placement in placements.placements:
            unorderdered_info.append(
                (placement.vertex.label.split(" ")[0],
                 "{:<4}".format(placement.vertex.label.split(" ")[1]),
                 placement.vertex.n_atoms, 'x: ', placement.x, 'y: ',
                 placement.y, 'p: ', placement.p))

        sorted_info = sorted(unorderdered_info, key=itemgetter(4, 6, 8))
        pp(sorted_info)

        pp("{}".format("=" * 50))
        sorted_info = sorted(unorderdered_info, key=lambda x: int(x[1]))
        pp(sorted_info)
Exemplo n.º 25
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    def test_partition_with_barely_sufficient_space(self):
        """
        test that partitioning will work when close to filling the machine
        """
        self.setup()

        n_processors = 18
        (e, ne, n, w, _, _) = range(6)

        links = list()
        links.append(Link(0, 0, e, 0, 1))

        _sdram = SDRAM(2**12)

        links = list()

        links.append(Link(0, 0, e, 1, 1))
        links.append(Link(0, 1, ne, 1, 0))
        links.append(Link(1, 1, n, 0, 0))
        links.append(Link(1, 0, w, 0, 1))
        r = Router(links, False, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                if x == y == 0:
                    chips.append(Chip(x, y, n_processors, r, _sdram, 0, 0, ip))
                else:
                    chips.append(Chip(x, y, n_processors, r, _sdram, 0, 0))

        self.machine = machine_from_chips(chips)
        n_neurons = 17 * 5 * 5
        singular_vertex = SimpleTestVertex(n_neurons,
                                           "Large vertex",
                                           max_atoms_per_core=1)
        singular_vertex.splitter = SplitterSliceLegacy()
        self.assertEqual(singular_vertex._model_based_max_atoms_per_core, 1)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(singular_vertex)
        graph, _ = self.bp(
            self.graph,
            self.machine,
            plan_n_time_steps=100,
            pre_allocated_resources=PreAllocatedResourceContainer())
        self.assertEqual(singular_vertex._model_based_max_atoms_per_core, 1)
        self.assertEqual(len(list(graph.vertices)), n_neurons)
Exemplo n.º 26
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    def setup(self):
        """
        setup for all basic partitioner tests
        """
        self.vert1 = SimpleTestVertex(10, "New AbstractConstrainedVertex 1")
        self.vert2 = SimpleTestVertex(5, "New AbstractConstrainedVertex 2")
        self.vert3 = SimpleTestVertex(3, "New AbstractConstrainedVertex 3")
        self.edge1 = ApplicationEdge(self.vert1, self.vert2, None,
                                     "First edge")
        self.edge2 = ApplicationEdge(self.vert2, self.vert1, None,
                                     "Second edge")
        self.edge3 = ApplicationEdge(self.vert1, self.vert3, None,
                                     "Third edge")
        self.verts = [self.vert1, self.vert2, self.vert3]
        self.edges = [self.edge1, self.edge2, self.edge3]
        self.graph = ApplicationGraph("Graph")
        self.graph.add_vertices(self.verts)
        self.graph.add_edges(self.edges, "foo")

        flops = 200000000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(128 * (2**20))

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = TestBasicPartitioner.TheTestAddress
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        self.bp = BasicPartitioner()
 def test_partition_with_empty_graph(self):
     """test that the partitioner can work with an empty graph
     """
     self.setup()
     self.graph = ApplicationGraph("foo")
     graph, _, _ = self.bp(self.graph, self.machine,
                           PreAllocatedResourceContainer())
     self.assertEqual(len(list(graph.vertices)), 0)
    def test_that_3_lpgs_are_generated_on_3_board_app_graph(self):
        machine = virtual_machine(width=12, height=12)
        app_graph = ApplicationGraph("Test")
        graph = MachineGraph("Test", app_graph)

        default_params = {
            'use_prefix': False,
            'key_prefix': None,
            'prefix_type': None,
            'message_type': EIEIOType.KEY_32_BIT,
            'right_shift': 0,
            'payload_as_time_stamps': True,
            'use_payload_prefix': True,
            'payload_prefix': None,
            'payload_right_shift': 0,
            'number_of_packets_sent_per_time_step': 0,
            'hostname': None,
            'port': None,
            'strip_sdp': None,
            'tag': None,
            'label': "Test"}

        # data stores needed by algorithm
        live_packet_gatherers = dict()
        default_params_holder = LivePacketGatherParameters(**default_params)
        live_packet_gatherers[default_params_holder] = list()

        # run edge inserter that should go boom
        edge_inserter = InsertLivePacketGatherersToGraphs()
        lpg_verts_mapping = edge_inserter(
            live_packet_gatherer_parameters=live_packet_gatherers,
            machine=machine, machine_graph=graph, application_graph=app_graph)

        self.assertEqual(len(lpg_verts_mapping[default_params_holder]), 3)
        locs = list()
        locs.append((0, 0))
        locs.append((4, 8))
        locs.append((8, 4))
        for vertex in itervalues(lpg_verts_mapping[default_params_holder]):
            x = list(vertex.constraints)[0].x
            y = list(vertex.constraints)[0].y
            key = (x, y)
            locs.remove(key)

        self.assertEqual(len(locs), 0)

        verts = lpg_verts_mapping[default_params_holder].values()
        for vertex in graph.vertices:
            self.assertIn(vertex, verts)

        app_verts = set()
        for vertex in itervalues(lpg_verts_mapping[default_params_holder]):
            app_vertex = vertex.app_vertex
            self.assertNotEqual(app_vertex, None)
            self.assertIsInstance(app_vertex, ApplicationVertex)
            app_verts.add(app_vertex)
        self.assertEqual(len(app_verts), 3)
Exemplo n.º 29
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 def test_none_have_app_vertex(self):
     app_graph = ApplicationGraph("Test")
     graph = MachineGraph("foo", app_graph)
     app1 = SimpleTestVertex(12, "app1")
     mach1 = SimpleMachineVertex("mach1", app_vertex=None)
     mach2 = SimpleMachineVertex("mach2", app_vertex=None)
     mach3 = SimpleMachineVertex("mach3", app_vertex=app1)
     graph.add_vertices([mach1, mach2])
     with self.assertRaises(PacmanInvalidParameterException):
         graph.add_vertex(mach3)
    def test_get_vertex_from_vertex(self):
        """
        test that the graph mapper can retrieve a vertex from a given vertex
        """
        app_graph = ApplicationGraph("bacon")
        vert = SimpleTestVertex(10, "Some testing vertex")
        app_graph.add_vertex(vert)
        vertex1 = SimpleMachineVertex(None, "", app_vertex=vert,
                                      vertex_slice=Slice(0, 1))
        vertex2 = SimpleMachineVertex(None, "", app_vertex=vert,
                                      vertex_slice=Slice(2, 3))
        machine_graph = MachineGraph(
            application_graph=app_graph, label="cooked_bacon")
        machine_graph.add_vertex(vertex1)
        machine_graph.add_vertex(vertex2)

        self.assertEqual(vert, vertex1.app_vertex)
        self.assertEqual(vert, vertex2.app_vertex)
        self.assertEqual([vertex1, vertex2], list(vert.machine_vertices))
Exemplo n.º 31
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    def test_partition_with_insufficient_space(self):
        """
        test that if there's not enough space, the test the partitioner will
        raise an error
        """
        self.setup()
        n_processors = 18
        (e, ne, n, w, _, _) = range(6)

        links = list()
        links.append(Link(0, 0, e, 0, 1))

        _sdram = SDRAM(2**11)

        links = list()

        links.append(Link(0, 0, e, 1, 1))
        links.append(Link(0, 1, ne, 1, 0))
        links.append(Link(1, 1, n, 0, 0))
        links.append(Link(1, 0, w, 0, 1))
        r = Router(links, False, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                if x == y == 0:
                    chips.append(Chip(x, y, n_processors, r, _sdram, 0, 0, ip))
                else:
                    chips.append(Chip(x, y, n_processors, r, _sdram, 0, 0))

        self.machine = machine_from_chips(chips)
        large_vertex = SimpleTestVertex(3000,
                                        "Large vertex",
                                        max_atoms_per_core=1)
        large_vertex.splitter = SplitterSliceLegacy()
        self.assertEqual(large_vertex._model_based_max_atoms_per_core, 1)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(large_vertex)
        with self.assertRaises(PacmanValueError):
            self.bp(self.graph, self.machine, 3000,
                    PreAllocatedResourceContainer())
Exemplo n.º 32
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    def test_partition_with_insufficient_space(self):
        """
        test that if there's not enough space, the test the partitioner will
        raise an error
        """
        self.setup()
        flops = 1000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(2**11)

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = TestBasicPartitioner.TheTestAddress
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        large_vertex = SimpleTestVertex(3000,
                                        "Large vertex",
                                        max_atoms_per_core=1)
        self.assertEqual(large_vertex._model_based_max_atoms_per_core, 1)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(large_vertex)
        with self.assertRaises(PacmanPartitionException):
            self.bp(self.graph, self.machine)
Exemplo n.º 33
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    def test_partition_with_barely_sufficient_space(self):
        """
        test that partitioning will work when close to filling the machine
        """
        self.setup()
        flops = 20000000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(2**12)

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = TestBasicPartitioner.TheTestAddress
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        singular_vertex = SimpleTestVertex(450,
                                           "Large vertex",
                                           max_atoms_per_core=1)
        self.assertEqual(singular_vertex._model_based_max_atoms_per_core, 1)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(singular_vertex)
        graph, _, _ = self.bp(self.graph, self.machine)
        self.assertEqual(singular_vertex._model_based_max_atoms_per_core, 1)
        self.assertEqual(len(list(graph.vertices)), 450)
 def test_partition_on_large_vertex_than_has_to_be_split(self):
     """
     test that partitioning 1 large vertex can make it into 2 small ones
     """
     self.setup()
     large_vertex = SimpleTestVertex(300, "Large vertex")
     self.graph = ApplicationGraph("Graph with large vertex")
     self.graph.add_vertex(large_vertex)
     graph, _, _ = self.bp(self.graph, self.machine,
                           PreAllocatedResourceContainer())
     self.assertEqual(large_vertex._model_based_max_atoms_per_core, 256)
     self.assertGreater(len(list(graph.vertices)), 1)
 def test_partition_on_target_size_vertex_than_has_to_be_split(self):
     """
     test that fixed partitioning causes correct number of vertices
     """
     self.setup()
     large_vertex = SimpleTestVertex(1000, "Large vertex")
     large_vertex.add_constraint(MaxVertexAtomsConstraint(10))
     self.graph = ApplicationGraph("Graph with large vertex")
     self.graph.add_vertex(large_vertex)
     graph, _, _ = self.bp(self.graph, self.machine,
                           PreAllocatedResourceContainer())
     self.assertEqual(len(list(graph.vertices)), 100)
Exemplo n.º 36
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 def test_place_vertex_too_big_with_vertex(self):
     large_vertex = T_AppVertex(500, "Large vertex 500")
     large_machine_vertex = large_vertex.create_machine_vertex(
         0, 499, get_resources_used_by_atoms(0, 499, []))
     self.graph.add_vertex(large_vertex)
     self.graph = ApplicationGraph("Graph", [large_vertex])
     self.graph_mapper = GraphMapper()
     self.graph_mapper.add_vertices([large_machine_vertex], large_vertex)
     self.bp = RadialPlacer(self.machine, self.graph)
     self.graph = MachineGraph(vertices=[large_machine_vertex])
     with self.assertRaises(PacmanPlaceException):
         self.bp.place(self.graph, self.graph_mapper)
 def test_operation_with_same_size_as_vertex_constraint_chain(self):
     """ Test that a chain of same size constraints works even when the\
         order of vertices is not correct for the chain
     """
     graph = ApplicationGraph("Test")
     vertex_1 = SimpleTestVertex(10, "Vertex_1", 5)
     vertex_2 = SimpleTestVertex(10, "Vertex_2", 4)
     vertex_3 = SimpleTestVertex(10, "Vertex_3", 2)
     vertex_3.add_constraint(SameAtomsAsVertexConstraint(
         vertex_2))
     vertex_2.add_constraint(SameAtomsAsVertexConstraint(
         vertex_1))
     graph.add_vertices([vertex_1, vertex_2, vertex_3])
     machine = VirtualMachine(version=3, with_wrap_arounds=None)
     partitioner = PartitionAndPlacePartitioner()
     _, graph_mapper, _ = partitioner(graph, machine, plan_n_timesteps=None)
     subvertices_1 = list(graph_mapper.get_machine_vertices(vertex_1))
     subvertices_2 = list(graph_mapper.get_machine_vertices(vertex_2))
     subvertices_3 = list(graph_mapper.get_machine_vertices(vertex_3))
     self.assertEqual(len(subvertices_1), len(subvertices_2))
     self.assertEqual(len(subvertices_2), len(subvertices_3))
Exemplo n.º 38
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    def test_create_new_graph(self):
        vert1 = SimpleTestVertex(10, "New AbstractConstrainedVertex 1", 256)
        vert2 = SimpleTestVertex(5, "New AbstractConstrainedVertex 2", 256)
        vert3 = SimpleTestVertex(3, "New AbstractConstrainedVertex 3", 256)
        edge1 = ApplicationEdge(vert1, vert2, None, "First edge")
        edge2 = ApplicationEdge(vert2, vert1, None, "First edge")
        edge3 = ApplicationEdge(vert1, vert3, None, "First edge")
        verts = [vert1, vert2, vert3]
        edges = [edge1, edge2, edge3]
        graph = ApplicationGraph("Graph")
        graph.add_vertices(verts)
        graph.add_edges(edges, "foo")  # Any old partition label
        assert frozenset(verts) == frozenset(graph.vertices)
        assert frozenset(edges) == frozenset(graph.edges)

        assert edge1 not in graph.get_edges_ending_at_vertex(vert1)
        assert edge2 not in graph.get_edges_starting_at_vertex(vert1)
        assert edge3 not in graph.get_edges_ending_at_vertex(vert1)
Exemplo n.º 39
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 def test_operation_with_same_size_as_vertex_constraint_chain(self):
     """ Test that a chain of same size constraints works even when the\
         order of vertices is not correct for the chain
     """
     with self.assertRaises(NotImplementedError):
         graph = ApplicationGraph("Test")
         vertex_1 = SimpleTestVertex(10, "Vertex_1", 5)
         vertex_1.splitter_object = SplitterSliceLegacy()
         vertex_2 = SimpleTestVertex(10, "Vertex_2", 4)
         vertex_3 = SimpleTestVertex(10, "Vertex_3", 2)
         vertex_3.add_constraint(SameAtomsAsVertexConstraint(vertex_2))
         vertex_2.add_constraint(SameAtomsAsVertexConstraint(vertex_1))
         vertex_2.splitter_object = SplitterSliceLegacy()
         vertex_3.splitter_object = SplitterSliceLegacy()
         graph.add_vertices([vertex_1, vertex_2, vertex_3])
         machine = virtual_machine(width=2, height=2)
         splitter_partitioner(graph, machine, plan_n_time_steps=None)
         subvertices_1 = list(vertex_1.machine_vertices)
         subvertices_2 = list(vertex_2.machine_vertices)
         subvertices_3 = list(vertex_3.machine_vertices)
         self.assertEqual(len(subvertices_1), len(subvertices_2))
         self.assertEqual(len(subvertices_2), len(subvertices_3))
    def test_1_chip_no_pre_allocated_too_much_sdram(self):
        machine = VirtualMachine(width=8, height=8)
        graph = ApplicationGraph("Test")
        partitioner = PartitionAndPlacePartitioner()

        eight_meg = 8 * 1024 * 1024

        # add graph vertices which reside on 0,0
        for _ in range(0, 13):
            graph.add_vertex(SimpleTestVertex(
                constraints=[ChipAndCoreConstraint(x=0, y=0)],
                n_atoms=1,
                fixed_sdram_value=eight_meg))

        # add pre-allocated resources for cores on 0,0
        pre_allocated_res = PreAllocatedResourceContainer()

        # run partitioner that should go boom
        try:
            partitioner(graph, machine, pre_allocated_res)
        except Exception:
            raise Exception("should have blown up here")
    def test_create_new_graph(self):
        vert1 = SimpleTestVertex(10, "New AbstractConstrainedVertex 1", 256)
        vert2 = SimpleTestVertex(5, "New AbstractConstrainedVertex 2", 256)
        vert3 = SimpleTestVertex(3, "New AbstractConstrainedVertex 3", 256)
        edge1 = ApplicationEdge(vert1, vert2, None, "First edge")
        edge2 = ApplicationEdge(vert2, vert1, None, "First edge")
        edge3 = ApplicationEdge(vert1, vert3, None, "First edge")
        verts = [vert1, vert2, vert3]
        edges = [edge1, edge2, edge3]
        graph = ApplicationGraph("Graph")
        graph.add_vertices(verts)
        graph.add_edges(edges, "foo")  # Any old partition label
        assert frozenset(verts) == frozenset(graph.vertices)
        assert frozenset(edges) == frozenset(graph.edges)

        assert edge1 not in graph.get_edges_ending_at_vertex(vert1)
        assert edge2 not in graph.get_edges_starting_at_vertex(vert1)
        assert edge3 not in graph.get_edges_ending_at_vertex(vert1)
    def setup(self):
        """setup for all basic partitioner tests
        """
        self.vert1 = SimpleTestVertex(10, "New AbstractConstrainedVertex 1")
        self.vert2 = SimpleTestVertex(5, "New AbstractConstrainedVertex 2")
        self.vert3 = SimpleTestVertex(3, "New AbstractConstrainedVertex 3")
        self.edge1 = ApplicationEdge(self.vert1, self.vert2, None,
                                     "First edge")
        self.edge2 = ApplicationEdge(self.vert2, self.vert1, None,
                                     "Second edge")
        self.edge3 = ApplicationEdge(self.vert1, self.vert3, None,
                                     "Third edge")
        self.verts = [self.vert1, self.vert2, self.vert3]
        self.edges = [self.edge1, self.edge2, self.edge3]
        self.graph = ApplicationGraph("Graph")
        self.graph.add_vertices(self.verts)
        self.graph.add_edges(self.edges, "foo")

        flops = 200000000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(128 * (2**20))

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        self.bp = PartitionAndPlacePartitioner()
    def test_partition_with_barely_sufficient_space(self):
        """
        test that partitioning will work when close to filling the machine
        """
        self.setup()
        flops = 200000000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(2**12)

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        singular_vertex = SimpleTestVertex(450, "Large vertex",
                                           max_atoms_per_core=1)
        self.assertEqual(singular_vertex._model_based_max_atoms_per_core, 1)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(singular_vertex)
        graph, _, _ = self.bp(self.graph, self.machine,
                              PreAllocatedResourceContainer())
        self.assertEqual(singular_vertex._model_based_max_atoms_per_core, 1)
        self.assertEqual(len(list(graph.vertices)), 450)
    def test_partition_with_insufficient_space(self):
        """
        test that if there's not enough space, the test the partitioner will
        raise an error
        """
        self.setup()
        flops = 1000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(2**11)

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        large_vertex = SimpleTestVertex(3000, "Large vertex",
                                        max_atoms_per_core=1)
        self.assertEqual(large_vertex._model_based_max_atoms_per_core, 1)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(large_vertex)
        with self.assertRaises(PacmanValueError):
            self.bp(self.graph, self.machine, PreAllocatedResourceContainer())
    def test_local_verts_go_to_local_lpgs_app_graph(self):
        machine = VirtualMachine(width=12, height=12, with_wrap_arounds=True)
        graph = MachineGraph("Test")
        app_graph = ApplicationGraph("Test")
        app_graph_mapper = GraphMapper()

        default_params = {
            'use_prefix': False,
            'key_prefix': None,
            'prefix_type': None,
            'message_type': EIEIOType.KEY_32_BIT,
            'right_shift': 0,
            'payload_as_time_stamps': True,
            'use_payload_prefix': True,
            'payload_prefix': None,
            'payload_right_shift': 0,
            'number_of_packets_sent_per_time_step': 0,
            'hostname': None,
            'port': None,
            'strip_sdp': None,
            'board_address': None,
            'tag': None}

        # data stores needed by algorithm
        live_packet_gatherers = dict()
        extended = dict(default_params)
        extended.update({'partition_id': "EVENTS"})
        default_params_holder = LivePacketGatherParameters(**extended)
        live_packet_gatherers[default_params_holder] = list()

        live_packet_gatherers_to_vertex_mapping = defaultdict(dict)

        placements = Placements()

        # add LPG's (1 for each Ethernet connected chip
        for chip in machine.ethernet_connected_chips:
            vertex = LivePacketGather(**default_params)
            app_graph.add_vertex(vertex)
            vertex_slice = Slice(0, 0)
            resources_required = vertex.get_resources_used_by_atoms(
                vertex_slice)
            mac_vertex = vertex.create_machine_vertex(
                vertex_slice, resources_required)
            graph.add_vertex(mac_vertex)
            app_graph_mapper.add_vertex_mapping(
                mac_vertex, Slice(0, 0), vertex)
            placements.add_placement(
                Placement(x=chip.x, y=chip.y, p=2, vertex=mac_vertex))
            live_packet_gatherers_to_vertex_mapping[
                default_params_holder][chip.x, chip.y] = mac_vertex

        # tracker of wirings
        verts_expected = defaultdict(list)

        positions = list()
        positions.append([0, 0, 0, 0])
        positions.append([4, 4, 0, 0])
        positions.append([1, 1, 0, 0])
        positions.append([2, 2, 0, 0])
        positions.append([8, 4, 8, 4])
        positions.append([11, 4, 8, 4])
        positions.append([4, 11, 4, 8])
        positions.append([4, 8, 4, 8])
        positions.append([0, 11, 8, 4])
        positions.append([11, 11, 4, 8])
        positions.append([8, 8, 4, 8])
        positions.append([4, 0, 0, 0])
        positions.append([7, 7, 0, 0])

        # add graph vertices which reside on areas of the machine to ensure
        #  spread over boards.
        for x, y, eth_x, eth_y in positions:
            vertex = SimpleTestVertex(1)
            app_graph.add_vertex(vertex)
            vertex_slice = Slice(0, 0)
            resources_required = vertex.get_resources_used_by_atoms(
                vertex_slice)
            mac_vertex = vertex.create_machine_vertex(
                vertex_slice, resources_required)
            graph.add_vertex(mac_vertex)
            app_graph_mapper.add_vertex_mapping(
                mac_vertex, vertex_slice, vertex)
            live_packet_gatherers[default_params_holder].append(vertex)
            verts_expected[eth_x, eth_y].append(mac_vertex)
            placements.add_placement(
                Placement(x=x, y=y, p=5, vertex=mac_vertex))

        # run edge inserter that should go boom
        edge_inserter = InsertEdgesToLivePacketGatherers()
        edge_inserter(
            live_packet_gatherer_parameters=live_packet_gatherers,
            placements=placements,
            live_packet_gatherers_to_vertex_mapping=(
                live_packet_gatherers_to_vertex_mapping),
            machine=machine, machine_graph=graph, application_graph=app_graph,
            graph_mapper=app_graph_mapper)

        # verify edges are in the right place
        for chip in machine.ethernet_connected_chips:
            edges = graph.get_edges_ending_at_vertex(
                live_packet_gatherers_to_vertex_mapping[
                    default_params_holder][chip.x, chip.y])
            for edge in edges:
                self.assertIn(edge.pre_vertex, verts_expected[chip.x, chip.y])

        # check app graph
        for chip in machine.ethernet_connected_chips:
            app_verts_expected = [
                app_graph_mapper.get_application_vertex(vert)
                for vert in verts_expected[chip.x, chip.y]]
            lpg_machine = live_packet_gatherers_to_vertex_mapping[
                default_params_holder][chip.x, chip.y]
            lpg_app = app_graph_mapper.get_application_vertex(lpg_machine)
            edges = app_graph.get_edges_ending_at_vertex(lpg_app)
            for edge in edges:
                self.assertIn(edge.pre_vertex, app_verts_expected)
class TestBasicPartitioner(unittest.TestCase):
    """
    test for basic partitioning algorithm
    """

    def setup(self):
        """setup for all basic partitioner tests
        """
        self.vert1 = SimpleTestVertex(10, "New AbstractConstrainedVertex 1")
        self.vert2 = SimpleTestVertex(5, "New AbstractConstrainedVertex 2")
        self.vert3 = SimpleTestVertex(3, "New AbstractConstrainedVertex 3")
        self.edge1 = ApplicationEdge(self.vert1, self.vert2, None,
                                     "First edge")
        self.edge2 = ApplicationEdge(self.vert2, self.vert1, None,
                                     "Second edge")
        self.edge3 = ApplicationEdge(self.vert1, self.vert3, None,
                                     "Third edge")
        self.verts = [self.vert1, self.vert2, self.vert3]
        self.edges = [self.edge1, self.edge2, self.edge3]
        self.graph = ApplicationGraph("Graph")
        self.graph.add_vertices(self.verts)
        self.graph.add_edges(self.edges, "foo")

        flops = 200000000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(128 * (2**20))

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        self.bp = PartitionAndPlacePartitioner()

    def test_partition_with_no_additional_constraints(self):
        """test a partitioning with a graph with no extra constraints
        """
        self.setup()
        graph, mapper, _ = self.bp(self.graph, self.machine,
                                   PreAllocatedResourceContainer())
        self.assertEqual(len(list(graph.vertices)), 3)
        vert_sizes = []
        for vert in self.verts:
            vert_sizes.append(vert.n_atoms)
        self.assertEqual(len(list(graph.edges)), 3)
        for vertex in graph.vertices:
            self.assertIn(mapper.get_slice(vertex).n_atoms, vert_sizes)

    def test_partition_with_no_additional_constraints_extra_edge(self):
        """test that the basic form with an extra edge works
        """
        self.setup()
        self.graph.add_edge(
            ApplicationEdge(self.vert3, self.vert1), "TEST")
        graph, _, _ = self.bp(self.graph, self.machine,
                              PreAllocatedResourceContainer())
        self.assertEqual(len(list(graph.vertices)), 3)
        self.assertEqual(len(list(graph.edges)), 4)

    def test_partition_on_large_vertex_than_has_to_be_split(self):
        """
        test that partitioning 1 large vertex can make it into 2 small ones
        """
        self.setup()
        large_vertex = SimpleTestVertex(300, "Large vertex")
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(large_vertex)
        graph, _, _ = self.bp(self.graph, self.machine,
                              PreAllocatedResourceContainer())
        self.assertEqual(large_vertex._model_based_max_atoms_per_core, 256)
        self.assertGreater(len(list(graph.vertices)), 1)

    def test_partition_on_very_large_vertex_than_has_to_be_split(self):
        """
        test that partitioning 1 large vertex can make it into multiple small
        ones
        """
        self.setup()
        large_vertex = SimpleTestVertex(500, "Large vertex")
        self.assertEqual(large_vertex._model_based_max_atoms_per_core, 256)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(large_vertex)
        graph, _, _ = self.bp(self.graph, self.machine,
                              PreAllocatedResourceContainer())
        self.assertEqual(large_vertex._model_based_max_atoms_per_core, 256)
        self.assertGreater(len(list(graph.vertices)), 1)

    def test_partition_on_target_size_vertex_than_has_to_be_split(self):
        """
        test that fixed partitioning causes correct number of vertices
        """
        self.setup()
        large_vertex = SimpleTestVertex(1000, "Large vertex")
        large_vertex.add_constraint(MaxVertexAtomsConstraint(10))
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(large_vertex)
        graph, _, _ = self.bp(self.graph, self.machine,
                              PreAllocatedResourceContainer())
        self.assertEqual(len(list(graph.vertices)), 100)

    def test_partition_with_barely_sufficient_space(self):
        """
        test that partitioning will work when close to filling the machine
        """
        self.setup()
        flops = 200000000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(2**12)

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        singular_vertex = SimpleTestVertex(450, "Large vertex",
                                           max_atoms_per_core=1)
        self.assertEqual(singular_vertex._model_based_max_atoms_per_core, 1)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(singular_vertex)
        graph, _, _ = self.bp(self.graph, self.machine,
                              PreAllocatedResourceContainer())
        self.assertEqual(singular_vertex._model_based_max_atoms_per_core, 1)
        self.assertEqual(len(list(graph.vertices)), 450)

    def test_partition_with_insufficient_space(self):
        """
        test that if there's not enough space, the test the partitioner will
        raise an error
        """
        self.setup()
        flops = 1000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(2**11)

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        large_vertex = SimpleTestVertex(3000, "Large vertex",
                                        max_atoms_per_core=1)
        self.assertEqual(large_vertex._model_based_max_atoms_per_core, 1)
        self.graph = ApplicationGraph("Graph with large vertex")
        self.graph.add_vertex(large_vertex)
        with self.assertRaises(PacmanValueError):
            self.bp(self.graph, self.machine, PreAllocatedResourceContainer())

    def test_partition_with_less_sdram_than_default(self):
        """
        test that the partitioner works when its machine is slightly malformed
        in that it has less SDRAM available
        """
        self.setup()
        flops = 200000000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(128 * (2**19))

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        self.bp(self.graph, self.machine, PreAllocatedResourceContainer())

    def test_partition_with_more_sdram_than_default(self):
        """
        test that the partitioner works when its machine is slightly malformed
        in that it has more SDRAM available
        """
        self.setup()
        flops = 200000000
        (e, _, n, w, _, s) = range(6)

        processors = list()
        for i in range(18):
            processors.append(Processor(i, flops))

        links = list()
        links.append(Link(0, 0, 0, 0, 1, s, s))

        _sdram = SDRAM(128 * (2**21))

        links = list()

        links.append(Link(0, 0, 0, 1, 1, n, n))
        links.append(Link(0, 1, 1, 1, 0, s, s))
        links.append(Link(1, 1, 2, 0, 0, e, e))
        links.append(Link(1, 0, 3, 0, 1, w, w))
        r = Router(links, False, 100, 1024)

        ip = "192.162.240.253"
        chips = list()
        for x in range(5):
            for y in range(5):
                chips.append(Chip(x, y, processors, r, _sdram, 0, 0, ip))

        self.machine = Machine(chips, 0, 0)
        self.bp(self.graph, self.machine, PreAllocatedResourceContainer())

    def test_partition_with_unsupported_constraints(self):
        """
        test that when a vertex has a constraint that is unrecognised,
        it raises an error
        """
        self.setup()
        constrained_vertex = SimpleTestVertex(13, "Constrained")
        constrained_vertex.add_constraint(
            NewPartitionerConstraint("Mock constraint"))
        graph = ApplicationGraph("Graph")
        graph.add_vertex(constrained_vertex)
        partitioner = PartitionAndPlacePartitioner()
        with self.assertRaises(PacmanInvalidParameterException):
            partitioner(graph, self.machine, PreAllocatedResourceContainer())

    def test_partition_with_empty_graph(self):
        """test that the partitioner can work with an empty graph
        """
        self.setup()
        self.graph = ApplicationGraph("foo")
        graph, _, _ = self.bp(self.graph, self.machine,
                              PreAllocatedResourceContainer())
        self.assertEqual(len(list(graph.vertices)), 0)

    def test_operation_with_same_size_as_vertex_constraint(self):
        """
        test that the partition and place partitioner can handle same size as
        constraints on a vertex that is split into one core
        """
        self.setup()
        constrained_vertex = SimpleTestVertex(5, "Constrained")
        constrained_vertex.add_constraint(
            SameAtomsAsVertexConstraint(self.vert2))
        self.graph.add_vertex(constrained_vertex)
        partitioner = PartitionAndPlacePartitioner()
        graph, _, _ = partitioner(self.graph, self.machine,
                                  PreAllocatedResourceContainer())
        self.assertEqual(len(list(graph.vertices)), 4)

    def test_operation_with_same_size_as_vertex_constraint_large_vertices(
            self):
        """
        test that the partition and place partitioner can handle same size as
        constraints on a vertex which has to be split over many cores
        """
        self.setup()
        constrained_vertex = SimpleTestVertex(300, "Constrained")
        new_large_vertex = SimpleTestVertex(300, "Non constrained")
        constrained_vertex.add_constraint(
            SameAtomsAsVertexConstraint(new_large_vertex))
        self.graph.add_vertices([new_large_vertex, constrained_vertex])
        partitioner = PartitionAndPlacePartitioner()
        graph, _, _ = partitioner(self.graph, self.machine,
                                  PreAllocatedResourceContainer())
        self.assertEqual(len(list(graph.vertices)), 7)

    def test_operation_same_size_as_vertex_constraint_different_order(self):
        """
        test that the partition and place partitioner can handle same size as
        constraints on a vertex which has to be split over many cores where
        the order of the vertices being added is different.
        """
        self.setup()
        constrained_vertex = SimpleTestVertex(300, "Constrained")
        new_large_vertex = SimpleTestVertex(300, "Non constrained")
        constrained_vertex.add_constraint(
            SameAtomsAsVertexConstraint(new_large_vertex))
        self.graph.add_vertices([constrained_vertex, new_large_vertex])
        partitioner = PartitionAndPlacePartitioner()
        graph, _, _ = partitioner(self.graph, self.machine,
                                  PreAllocatedResourceContainer())
        # split in 256 each, so 4 machine vertices
        self.assertEqual(len(list(graph.vertices)), 7)

    def test_operation_with_same_size_as_vertex_constraint_exception(self):
        """
        test that a partition same as constraint with different size atoms
        causes errors
        """
        self.setup()
        constrained_vertex = SimpleTestVertex(100, "Constrained")
        constrained_vertex.add_constraint(
            SameAtomsAsVertexConstraint(self.vert2))
        self.graph.add_vertex(constrained_vertex)
        partitioner = PartitionAndPlacePartitioner()
        self.assertRaises(PacmanPartitionException, partitioner,
                          self.graph, self.machine,
                          PreAllocatedResourceContainer())

    def test_operation_with_same_size_as_vertex_constraint_chain(self):
        """ Test that a chain of same size constraints works even when the\
            order of vertices is not correct for the chain
        """
        graph = ApplicationGraph("Test")
        vertex_1 = SimpleTestVertex(10, "Vertex_1", 5)
        vertex_2 = SimpleTestVertex(10, "Vertex_2", 4)
        vertex_3 = SimpleTestVertex(10, "Vertex_3", 2)
        vertex_3.add_constraint(SameAtomsAsVertexConstraint(
            vertex_2))
        vertex_2.add_constraint(SameAtomsAsVertexConstraint(
            vertex_1))
        graph.add_vertices([vertex_1, vertex_2, vertex_3])
        machine = VirtualMachine(version=3, with_wrap_arounds=None)
        partitioner = PartitionAndPlacePartitioner()
        _, graph_mapper, _ = partitioner(graph, machine, plan_n_timesteps=None)
        subvertices_1 = list(graph_mapper.get_machine_vertices(vertex_1))
        subvertices_2 = list(graph_mapper.get_machine_vertices(vertex_2))
        subvertices_3 = list(graph_mapper.get_machine_vertices(vertex_3))
        self.assertEqual(len(subvertices_1), len(subvertices_2))
        self.assertEqual(len(subvertices_2), len(subvertices_3))

    def test_partitioning_with_2_massive_pops(self):
        self.setup()
        constrained_vertex = SimpleTestVertex(16000, "Constrained")
        self.graph.add_vertex(constrained_vertex)
        constrained_vertex = SimpleTestVertex(16000, "Constrained")
        self.graph.add_vertex(constrained_vertex)
        partitioner = PartitionAndPlacePartitioner()
        partitioner(self.graph, self.machine, PreAllocatedResourceContainer())

    @unittest.skip("Test not implemented yet")
    def test_detect_subclass_hierarchy(self):
        self.assertEqual(True, False, "Test not implemented yet")

    @unittest.skip("Test not implemented yet")
    def test_partition_by_atoms(self):
        self.assertEqual(True, False, "Test not implemented yet")

    @unittest.skip("Test not implemented yet")
    def test_scale_down_resource_usage(self):
        self.assertEqual(True, False, "Test not implemented yet")

    @unittest.skip("Test not implemented yet")
    def test_scale_up_resource_usage(self):
        self.assertEqual(True, False, "Test not implemented yet")

    @unittest.skip("Test not implemented yet")
    def test_find_max_ratio(self):
        self.assertEqual(True, False, "Test not implemented yet")

    @unittest.skip("Test not implemented yet")
    def test_locate_vertices_to_partition_now(self):
        self.assertEqual(True, False, "Test not implemented yet")

    @unittest.skip("Test not implemented yet")
    def test_partition_with_supported_constraints_enough_space(self):
        self.assertEqual(True, False, "Test not implemented yet")

    @unittest.skip("Test not implemented yet")
    def test_partition_with_supported_constraints_not_enough_space(self):
        self.assertEqual(True, False, "Test not implemented yet")

    def test_partition_with_fixed_atom_constraints(self):
        """
        test a partitioning with a graph with fixed atom constraint
        """

        # Create a 2x2 machine with 10 cores per chip (so 40 cores),
        # but 1MB off 2MB per chip (so 19MB per chip)
        n_cores_per_chip = 10
        sdram_per_chip = (n_cores_per_chip * 2) - 1
        machine = VirtualMachine(
            width=2, height=2, with_monitors=False,
            n_cpus_per_chip=n_cores_per_chip,
            sdram_per_chip=sdram_per_chip)

        # Create a vertex where each atom requires 1MB (default) of SDRAM
        # but which can't be subdivided lower than 2 atoms per core.
        # The vertex has 1 atom per MB of SDRAM, and so would fit but will
        # be disallowed by the fixed atoms per core constraint
        vertex = SimpleTestVertex(
            sdram_per_chip * machine.n_chips,
            max_atoms_per_core=2, constraints=[FixedVertexAtomsConstraint(2)])
        app_graph = ApplicationGraph("Test")
        app_graph.add_vertex(vertex)

        # Do the partitioning - this should result in an error
        with self.assertRaises(PacmanPartitionException):
            partitioner = PartitionAndPlacePartitioner()
            partitioner(app_graph, machine, plan_n_timesteps=None)

    def test_partition_with_fixed_atom_constraints_at_limit(self):
        """
        test a partitioning with a graph with fixed atom constraint which\
        should fit but is close to the limit
        """

        # Create a 2x2 machine with 1 core per chip (so 4 cores),
        # and 8MB SDRAM per chip
        n_cores_per_chip = 1
        sdram_per_chip = 8
        machine = VirtualMachine(
            width=2, height=2, with_monitors=False,
            n_cpus_per_chip=n_cores_per_chip,
            sdram_per_chip=sdram_per_chip)

        # Create a vertex which will need to be split perfectly into 4 cores
        # to work and which max atoms per core must be ignored
        vertex = SimpleTestVertex(
            sdram_per_chip * 2, max_atoms_per_core=sdram_per_chip,
            constraints=[FixedVertexAtomsConstraint(sdram_per_chip // 2)])
        app_graph = ApplicationGraph("Test")
        app_graph.add_vertex(vertex)

        # Do the partitioning - this should just work
        partitioner = PartitionAndPlacePartitioner()
        machine_graph, _, _ = partitioner(
            app_graph, machine, plan_n_timesteps=None)
        self.assert_(len(machine_graph.vertices) == 4)