Пример #1
0
    def test07_write_builtin(self):
        """Test writing of builtins"""

        from cppyy import gbl  # bootstraps, only needed for tests
        from cppyy.gbl import TFile, TTree
        from cppyy.gbl.std import vector

        f = TFile(self.fname, "RECREATE")
        mytree = TTree(self.tname, self.title)
        mytree._python_owns = False

        import array
        mytree.ba = array.array('c', [chr(0)])
        mytree.ia = array.array('i', [0])
        mytree.da = array.array('d', [0.])

        mytree.Branch("my_bool", mytree.ba, "my_bool/O")
        mytree.Branch("my_int", mytree.ia, "my_int/I")
        mytree.Branch("my_int2", mytree.ia, "my_int2/I")
        mytree.Branch("my_double", mytree.da, "my_double/D")

        for i in range(self.N):
            # make sure value is different from default (0)
            mytree.ba[0] = i % 2 and chr(0) or chr(1)
            mytree.ia[0] = i + 1
            mytree.da[0] = (i + 1) / 2.
            mytree.Fill()
        f.Write()
        f.Close()
Пример #2
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    def test05_read_some_data_object(self):
        """Test reading of a complex data object"""

        from cppyy import gbl
        from cppyy.gbl import TFile

        f = TFile(self.fname)
        mytree = f.Get(self.tname)

        j = 1
        for event in mytree:
            i = 0
            assert len(event.data.get_floats()) == j * self.M
            for entry in event.data.get_floats():
                assert i == int(entry)
                i += 1

            k = 1
            assert len(event.data.get_tuples()) == j
            for mytuple in event.data.get_tuples():
                i = 0
                assert len(mytuple) == k * self.M
                for entry in mytuple:
                    assert i == int(entry)
                    i += 1
                k += 1
            j += 1
        assert j - 1 == self.N
        #
        f.Close()
Пример #3
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    def test01_write_stdvector(self):
        """Test writing of a single branched TTree with an std::vector<double>"""

        from cppyy import gbl  # bootstraps, only needed for tests
        from cppyy.gbl import TFile, TTree
        from cppyy.gbl.std import vector

        f = TFile(self.fname, "RECREATE")
        mytree = TTree(self.tname, self.title)
        mytree._python_owns = False

        v = vector("double")()
        raises(TypeError, TTree.Branch, None, "mydata", v.__class__.__name__,
               v)
        raises(TypeError, TTree.Branch, v, "mydata", v.__class__.__name__, v)

        mytree.Branch("mydata", v.__class__.__name__, v)

        for i in range(self.N):
            for j in range(self.M):
                v.push_back(i * self.M + j)
            mytree.Fill()
            v.clear()
        f.Write()
        f.Close()
Пример #4
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    def test09_user_read_builtin(self):
        """Test user-directed reading of builtins"""

        from cppyy import gbl
        from cppyy.gbl import TFile

        f = TFile(self.fname)
        mytree = f.Get(self.tname)

        # note, this is an old, annoted tree from test08
        for i in range(3, mytree.GetEntriesFast()):
            mytree.GetEntry(i)
            assert mytree.my_int == i + 1
            assert mytree.my_int2 == i + 1

        f.Close()
Пример #5
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    def test06_branch_activation(self):
        """Test of automatic branch activation"""

        from cppyy import gbl
        from cppyy.gbl import TFile, TTree
        from cppyy.gbl.std import vector

        L = 5

        # writing
        f = TFile(self.fname, "RECREATE")
        mytree = TTree(self.tname, self.title)
        mytree._python_owns = False

        for i in range(L):
            v = vector("double")()
            mytree.Branch("mydata_%d" % i, v.__class__.__name__, v)
            mytree.__dict__["v_%d" % i] = v

        for i in range(self.N):
            for k in range(L):
                v = mytree.__dict__["v_%d" % k]
                for j in range(self.M):
                    mytree.__dict__["v_%d" % k].push_back(i * self.M + j * L +
                                                          k)
            mytree.Fill()
            for k in range(L):
                v = mytree.__dict__["v_%d" % k]
                v.clear()
        f.Write()
        f.Close()

        del mytree, f
        import gc
        gc.collect()

        # reading
        f = TFile(self.fname)
        mytree = f.Get(self.tname)

        # force (initial) disabling of all branches
        mytree.SetBranchStatus("*", 0)

        i = 0
        for event in mytree:
            for k in range(L):
                j = 0
                data = getattr(mytree, "mydata_%d" % k)
                assert len(data) == self.M
                for entry in data:
                    assert entry == i * self.M + j * L + k
                    j += 1
                assert j == self.M
            i += 1
        assert i == self.N

        f.Close()
Пример #6
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    def test03_read_stdvector(self):
        """Test reading of a single branched TTree with an std::vector<double>"""

        from cppyy import gbl
        from cppyy.gbl import TFile

        f = TFile(self.fname)
        mytree = f.Get(self.tname)

        i = 0
        for event in mytree:
            assert len(event.mydata) == self.M
            for entry in event.mydata:
                assert i == int(entry)
                i += 1
        assert i == self.N * self.M

        f.Close()
Пример #7
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    def test08_read_builtin(self):
        """Test reading of builtins"""

        from cppyy import gbl
        from cppyy.gbl import TFile

        f = TFile(self.fname)
        mytree = f.Get(self.tname)

        raises(AttributeError, getattr, mytree, "does_not_exist")

        i = 1
        for event in mytree:
            assert event.my_bool == (i - 1) % 2 and 0 or 1
            assert event.my_int == i
            assert event.my_double == i / 2.
            i += 1
        assert (i - 1) == self.N

        f.Close()
Пример #8
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    def test04_write_some_data_object(self):
        """Test writing of a complex data object"""

        from cppyy import gbl
        from cppyy.gbl import TFile, TTree, IO
        from cppyy.gbl.IO import SomeDataObject

        f = TFile(self.fname, "RECREATE")
        mytree = TTree(self.tname, self.title)

        d = SomeDataObject()
        b = mytree.Branch("data", d)
        mytree._python_owns = False
        assert b

        for i in range(self.N):
            for j in range(self.M):
                d.add_float(i * self.M + j)
            d.add_tuple(d.get_floats())

            mytree.Fill()

        f.Write()
        f.Close()