def test_ndim(self): """Test that the behaviour of 'ndim' optional parameter""" # 'ndim' is an optional integer parameter, specifying the length # of the 'shape', passed as a keyword argument. # ndim not specified, OK m1 = Module() m1.random = RandomStreams(utt.fetch_seed()) m1.fn = Method([], m1.random.uniform((2,2))) made1 = m1.make() made1.random.initialize() # ndim specified, consistent with shape, OK m2 = Module() m2.random = RandomStreams(utt.fetch_seed()) m2.fn = Method([], m2.random.uniform((2,2), ndim=2)) made2 = m2.make() made2.random.initialize() val1 = made1.fn() val2 = made2.fn() assert numpy.all(val1 == val2) # ndim specified, inconsistent with shape, should raise ValueError m3 = Module() m3.random = RandomStreams(utt.fetch_seed()) self.assertRaises(ValueError, m3.random.uniform, (2,2), ndim=1)
def test_setitem(self): m = Module() m.random = RandomStreams(234) out = m.random.uniform((2, 2)) m.fn = Method([], out) made = m.make() #as a distraction, install various seeds made.random.initialize(seed=789) made.random.seed(888) # then replace the rng of the stream we care about via setitem realseed = utt.fetch_seed() rng = numpy.random.RandomState(realseed) made.random[out.rng] = numpy.random.RandomState(realseed) print made.fn() print rng.uniform(size=(2, 2)) fn_val0 = made.fn() fn_val1 = made.fn() numpy_val0 = rng.uniform(size=(2, 2)) numpy_val1 = rng.uniform(size=(2, 2)) assert numpy.allclose(fn_val0, numpy_val0) assert numpy.allclose(fn_val1, numpy_val1)
def test_setitem(self): m = Module() m.random = RandomStreams(234) out = m.random.uniform((2,2)) m.fn = Method([], out) made = m.make() #as a distraction, install various seeds made.random.initialize(seed=789) made.random.seed(888) # then replace the rng of the stream we care about via setitem realseed = utt.fetch_seed() rng = numpy.random.RandomState(realseed) made.random[out.rng] = numpy.random.RandomState(realseed) print made.fn() print rng.uniform(size=(2,2)) fn_val0 = made.fn() fn_val1 = made.fn() numpy_val0 = rng.uniform(size=(2,2)) numpy_val1 = rng.uniform(size=(2,2)) assert numpy.allclose(fn_val0, numpy_val0) assert numpy.allclose(fn_val1, numpy_val1)
def test_normal_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) avg = tensor.vector() std = tensor.vector() out = m.random.normal(avg=avg, std=std) assert out.ndim == 1 m.f = Method([avg, std], out) # Specifying the size explicitly m.g = Method([avg, std], m.random.normal(avg=avg, std=std, size=(3,))) made = m.make() made.random.initialize() avg_val = [1, 2, 3] std_val = numpy.asarray([.1, .2, .3], dtype=config.floatX) seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(avg_val, std_val) numpy_val0 = numpy_rng.normal(loc=avg_val, scale=std_val) assert numpy.allclose(val0, numpy_val0) # arguments of size (2,) val1 = made.f(avg_val[:-1], std_val[:-1]) numpy_val1 = numpy_rng.normal(loc=avg_val[:-1], scale=std_val[:-1]) assert numpy.allclose(val1, numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(avg_val, std_val) numpy_val2 = numpy_rng.normal(loc=avg_val, scale=std_val, size=(3,)) assert numpy.allclose(val2, numpy_val2) self.assertRaises(ValueError, made.g, avg_val[:-1], std_val[:-1])
def test_uniform_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.vector() high = tensor.vector() out = m.random.uniform(low=low, high=high) assert out.ndim == 1 m.f = Method([low, high], out) # Specifying the size explicitly m.g = Method([low, high], m.random.uniform(low=low, high=high, size=(3,))) made = m.make() made.random.initialize() low_val = numpy.asarray([.1, .2, .3], dtype=config.floatX) high_val = numpy.asarray([1.1, 2.2, 3.3], dtype=config.floatX) seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(low_val, high_val) numpy_val0 = numpy_rng.uniform(low=low_val, high=high_val) assert numpy.allclose(val0, numpy_val0) # arguments of size (2,) val1 = made.f(low_val[:-1], high_val[:-1]) numpy_val1 = numpy_rng.uniform(low=low_val[:-1], high=high_val[:-1]) assert numpy.allclose(val1, numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(low_val, high_val) numpy_val2 = numpy_rng.uniform(low=low_val, high=high_val, size=(3,)) assert numpy.allclose(val2, numpy_val2) self.assertRaises(ValueError, made.g, low_val[:-1], high_val[:-1])
def test_binomial_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) n = tensor.lvector() prob = tensor.vector() out = m.random.binomial(n=n, p=prob) assert out.ndim == 1 m.f = Method([n, prob], out) # Specifying the size explicitly m.g = Method([n, prob], m.random.binomial(n=n, p=prob, size=(3,))) made = m.make() made.random.initialize() n_val = [1, 2, 3] prob_val = numpy.asarray([.1, .2, .3], dtype=config.floatX) seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(n_val, prob_val) numpy_val0 = numpy_rng.binomial(n=n_val, p=prob_val) assert numpy.all(val0 == numpy_val0) # arguments of size (2,) val1 = made.f(n_val[:-1], prob_val[:-1]) numpy_val1 = numpy_rng.binomial(n=n_val[:-1], p=prob_val[:-1]) assert numpy.all(val1 == numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(n_val, prob_val) numpy_val2 = numpy_rng.binomial(n=n_val, p=prob_val, size=(3,)) assert numpy.all(val2 == numpy_val2) self.assertRaises(ValueError, made.g, n_val[:-1], prob_val[:-1])
def test_broadcast_arguments(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.vector() high = tensor.col() out = m.random.uniform(low=low, high=high) assert out.ndim == 2 m.f = Method([low, high], out) made = m.make() made.random.initialize() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) numpy_rng = numpy.random.RandomState(int(rng_seed)) low_vals = [ numpy.asarray([-5, .5, 0, 1], dtype=config.floatX), numpy.asarray([.9], dtype=config.floatX), numpy.asarray([-5, .5, 0, 1], dtype=config.floatX) ] high_vals = [ numpy.asarray([[1.]], dtype=config.floatX), numpy.asarray([[1.], [1.1], [1.5]], dtype=config.floatX), numpy.asarray([[1.], [1.1], [1.5]], dtype=config.floatX) ] val0 = made.f(low_vals[0], high_vals[0]) val1 = made.f(low_vals[1], high_vals[1]) val2 = made.f(low_vals[2], high_vals[2]) numpy_val0 = numpy_rng.uniform(low=low_vals[0], high=high_vals[0]) numpy_val1 = numpy_rng.uniform(low=low_vals[1], high=high_vals[1]) numpy_val2 = numpy_rng.uniform(low=low_vals[2], high=high_vals[2]) assert numpy.allclose(val0, numpy_val0) assert numpy.allclose(val1, numpy_val1) assert numpy.allclose(val2, numpy_val2)
def test_multiple(self): M = Module() M.random = RandomStreams(utt.fetch_seed()) out = M.random.uniform((2,2)) M.m2 = Module() M.m2.random = M.random out2 = M.m2.random.uniform((2,2)) M.fn = Method([], out) M.m2.fn2 = Method([], out2) m = M.make() m.random.initialize() m.m2.initialize() assert m.random is m.m2.random
def test_symbolic_shape(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) shape = tensor.lvector() out = m.random.uniform(size=shape, ndim=2) m.f = Method([shape], out) made = m.make() made.random.initialize() assert made.f([2, 3]).shape == (2, 3) assert made.f([4, 8]).shape == (4, 8) self.assertRaises(ValueError, made.f, [4]) self.assertRaises(ValueError, made.f, [4, 3, 4, 5])
def test_symbolic_shape(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) shape = tensor.lvector() out = m.random.uniform(size=shape, ndim=2) m.f = Method([shape], out) made = m.make() made.random.initialize() assert made.f([2,3]).shape == (2,3) assert made.f([4,8]).shape == (4,8) self.assertRaises(ValueError, made.f, [4]) self.assertRaises(ValueError, made.f, [4,3,4,5])
def test_dtype(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.lscalar() high = tensor.lscalar() out = m.random.random_integers(low=low, high=high, size=(20,), dtype='int8') assert out.dtype == 'int8' m.f = Method([low, high], out) made = m.make() made.random.initialize() val0 = made.f(0, 9) assert val0.dtype == 'int8' val1 = made.f(255, 257) assert val1.dtype == 'int8' assert numpy.all(abs(val1) <= 1)
def test_normal(self): """Test that RandomStreams.normal generates the same results as numpy""" # Check over two calls to see if the random state is correctly updated. m = Module() m.random = RandomStreams(utt.fetch_seed()) m.fn = Method([], m.random.normal((2, 2), -1, 2)) made = m.make() made.random.initialize() fn_val0 = made.fn() fn_val1 = made.fn() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) #int() is for 32bit numpy_val0 = rng.normal(-1, 2, size=(2, 2)) numpy_val1 = rng.normal(-1, 2, size=(2, 2)) assert numpy.allclose(fn_val0, numpy_val0) assert numpy.allclose(fn_val1, numpy_val1)
def test_multinomial(self): """Test that RandomStreams.multinomial generates the same results as numpy""" # Check over two calls to see if the random state is correctly updated. m = Module() m.random = RandomStreams(utt.fetch_seed()) m.fn = Method([], m.random.multinomial((20, 20), 1, [0.1] * 10)) made = m.make() made.random.initialize() fn_val0 = made.fn() fn_val1 = made.fn() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) #int() is for 32bit numpy_val0 = rng.multinomial(1, [0.1] * 10, size=(20, 20)) numpy_val1 = rng.multinomial(1, [0.1] * 10, size=(20, 20)) assert numpy.all(fn_val0 == numpy_val0) assert numpy.all(fn_val1 == numpy_val1)
def test_multinomial(self): """Test that RandomStreams.multinomial generates the same results as numpy""" # Check over two calls to see if the random state is correctly updated. m = Module() m.random = RandomStreams(utt.fetch_seed()) m.fn = Method([], m.random.multinomial((20,20), 1, [0.1]*10)) made = m.make() made.random.initialize() fn_val0 = made.fn() fn_val1 = made.fn() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) #int() is for 32bit numpy_val0 = rng.multinomial(1, [0.1]*10, size=(20,20)) numpy_val1 = rng.multinomial(1, [0.1]*10, size=(20,20)) assert numpy.all(fn_val0 == numpy_val0) assert numpy.all(fn_val1 == numpy_val1)
def test_normal(self): """Test that RandomStreams.normal generates the same results as numpy""" # Check over two calls to see if the random state is correctly updated. m = Module() m.random = RandomStreams(utt.fetch_seed()) m.fn = Method([], m.random.normal((2,2), -1, 2)) made = m.make() made.random.initialize() fn_val0 = made.fn() fn_val1 = made.fn() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) #int() is for 32bit numpy_val0 = rng.normal(-1, 2, size=(2,2)) numpy_val1 = rng.normal(-1, 2, size=(2,2)) assert numpy.allclose(fn_val0, numpy_val0) assert numpy.allclose(fn_val1, numpy_val1)
def test_seed_in_initialize(self): m = Module() m.random = RandomStreams(234) m.fn = Method([], m.random.uniform((2,2))) made = m.make() made.random.initialize(seed=utt.fetch_seed()) fn_val0 = made.fn() fn_val1 = made.fn() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) #int() is for 32bit #print fn_val0 numpy_val0 = rng.uniform(size=(2,2)) numpy_val1 = rng.uniform(size=(2,2)) #print numpy_val0 assert numpy.allclose(fn_val0, numpy_val0) assert numpy.allclose(fn_val1, numpy_val1)
def test_getitem(self): m = Module() m.random = RandomStreams(234) out = m.random.uniform((2,2)) m.fn = Method([], out) made = m.make() made.random.initialize(seed=789) made.random.seed(utt.fetch_seed()) rng = numpy.random.RandomState() rng.set_state(made.random[out.rng].get_state()) fn_val0 = made.fn() fn_val1 = made.fn() numpy_val0 = rng.uniform(size=(2,2)) numpy_val1 = rng.uniform(size=(2,2)) assert numpy.allclose(fn_val0, numpy_val0) assert numpy.allclose(fn_val1, numpy_val1)
def test_getitem(self): m = Module() m.random = RandomStreams(234) out = m.random.uniform((2, 2)) m.fn = Method([], out) made = m.make() made.random.initialize(seed=789) made.random.seed(utt.fetch_seed()) rng = numpy.random.RandomState() rng.set_state(made.random[out.rng].get_state()) fn_val0 = made.fn() fn_val1 = made.fn() numpy_val0 = rng.uniform(size=(2, 2)) numpy_val1 = rng.uniform(size=(2, 2)) assert numpy.allclose(fn_val0, numpy_val0) assert numpy.allclose(fn_val1, numpy_val1)
def test_dtype(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.lscalar() high = tensor.lscalar() out = m.random.random_integers(low=low, high=high, size=(20, ), dtype='int8') assert out.dtype == 'int8' m.f = Method([low, high], out) made = m.make() made.random.initialize() val0 = made.f(0, 9) assert val0.dtype == 'int8' val1 = made.f(255, 257) assert val1.dtype == 'int8' assert numpy.all(abs(val1) <= 1)
def test_seed_in_initialize(self): m = Module() m.random = RandomStreams(234) m.fn = Method([], m.random.uniform((2, 2))) made = m.make() made.random.initialize(seed=utt.fetch_seed()) fn_val0 = made.fn() fn_val1 = made.fn() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) #int() is for 32bit #print fn_val0 numpy_val0 = rng.uniform(size=(2, 2)) numpy_val1 = rng.uniform(size=(2, 2)) #print numpy_val0 assert numpy.allclose(fn_val0, numpy_val0) assert numpy.allclose(fn_val1, numpy_val1)
def test_permutation(self): """Test that RandomStreams.permutation generates the same results as numpy""" # Check over two calls to see if the random state is correctly updated. m = Module() m.random = RandomStreams(utt.fetch_seed()) m.fn = Method([], m.random.permutation((20,), 10)) made = m.make() made.random.initialize() fn_val0 = made.fn() fn_val1 = made.fn() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) #int() is for 32bit # rng.permutation outputs one vector at a time, so we iterate. numpy_val0 = numpy.asarray([rng.permutation(10) for i in range(20)]) numpy_val1 = numpy.asarray([rng.permutation(10) for i in range(20)]) assert numpy.all(fn_val0 == numpy_val0) assert numpy.all(fn_val1 == numpy_val1)
def test_permutation(self): """Test that RandomStreams.permutation generates the same results as numpy""" # Check over two calls to see if the random state is correctly updated. m = Module() m.random = RandomStreams(utt.fetch_seed()) m.fn = Method([], m.random.permutation((20, ), 10)) made = m.make() made.random.initialize() fn_val0 = made.fn() fn_val1 = made.fn() rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) #int() is for 32bit # rng.permutation outputs one vector at a time, so we iterate. numpy_val0 = numpy.asarray([rng.permutation(10) for i in range(20)]) numpy_val1 = numpy.asarray([rng.permutation(10) for i in range(20)]) assert numpy.all(fn_val0 == numpy_val0) assert numpy.all(fn_val1 == numpy_val1)
def test_default_shape(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) m.f = Method([], m.random.uniform()) m.g = Method([], m.random.multinomial()) made = m.make() made.random.initialize() #seed_rng is generator for generating *seeds* for RandomStates seed_rng = numpy.random.RandomState(utt.fetch_seed()) uniform_rng = numpy.random.RandomState(int(seed_rng.randint(2**30))) multinomial_rng = numpy.random.RandomState(int(seed_rng.randint( 2**30))) val0 = made.f() val1 = made.f() numpy_val0 = uniform_rng.uniform() numpy_val1 = uniform_rng.uniform() assert numpy.allclose(val0, numpy_val0) assert numpy.allclose(val1, numpy_val1) for i in range( 10 ): # every test has 50% chance of passing even with non-matching random states val2 = made.g() numpy_val2 = multinomial_rng.multinomial(n=1, pvals=[.5, .5]) assert numpy.all(val2 == numpy_val2)
def test_uniform_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.vector() high = tensor.vector() out = m.random.uniform(low=low, high=high) assert out.ndim == 1 m.f = Method([low, high], out) # Specifying the size explicitly m.g = Method([low, high], m.random.uniform(low=low, high=high, size=(3, ))) made = m.make() made.random.initialize() low_val = numpy.asarray([.1, .2, .3], dtype=config.floatX) high_val = numpy.asarray([1.1, 2.2, 3.3], dtype=config.floatX) seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(low_val, high_val) numpy_val0 = numpy_rng.uniform(low=low_val, high=high_val) assert numpy.allclose(val0, numpy_val0) # arguments of size (2,) val1 = made.f(low_val[:-1], high_val[:-1]) numpy_val1 = numpy_rng.uniform(low=low_val[:-1], high=high_val[:-1]) assert numpy.allclose(val1, numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(low_val, high_val) numpy_val2 = numpy_rng.uniform(low=low_val, high=high_val, size=(3, )) assert numpy.allclose(val2, numpy_val2) self.assertRaises(ValueError, made.g, low_val[:-1], high_val[:-1])
def test_binomial_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) n = tensor.lvector() prob = tensor.vector() out = m.random.binomial(n=n, p=prob) assert out.ndim == 1 m.f = Method([n, prob], out) # Specifying the size explicitly m.g = Method([n, prob], m.random.binomial(n=n, p=prob, size=(3, ))) made = m.make() made.random.initialize() n_val = [1, 2, 3] prob_val = numpy.asarray([.1, .2, .3], dtype=config.floatX) seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(n_val, prob_val) numpy_val0 = numpy_rng.binomial(n=n_val, p=prob_val) assert numpy.all(val0 == numpy_val0) # arguments of size (2,) val1 = made.f(n_val[:-1], prob_val[:-1]) numpy_val1 = numpy_rng.binomial(n=n_val[:-1], p=prob_val[:-1]) assert numpy.all(val1 == numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(n_val, prob_val) numpy_val2 = numpy_rng.binomial(n=n_val, p=prob_val, size=(3, )) assert numpy.all(val2 == numpy_val2) self.assertRaises(ValueError, made.g, n_val[:-1], prob_val[:-1])
def test_normal_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) avg = tensor.vector() std = tensor.vector() out = m.random.normal(avg=avg, std=std) assert out.ndim == 1 m.f = Method([avg, std], out) # Specifying the size explicitly m.g = Method([avg, std], m.random.normal(avg=avg, std=std, size=(3, ))) made = m.make() made.random.initialize() avg_val = [1, 2, 3] std_val = numpy.asarray([.1, .2, .3], dtype=config.floatX) seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(avg_val, std_val) numpy_val0 = numpy_rng.normal(loc=avg_val, scale=std_val) assert numpy.allclose(val0, numpy_val0) # arguments of size (2,) val1 = made.f(avg_val[:-1], std_val[:-1]) numpy_val1 = numpy_rng.normal(loc=avg_val[:-1], scale=std_val[:-1]) assert numpy.allclose(val1, numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(avg_val, std_val) numpy_val2 = numpy_rng.normal(loc=avg_val, scale=std_val, size=(3, )) assert numpy.allclose(val2, numpy_val2) self.assertRaises(ValueError, made.g, avg_val[:-1], std_val[:-1])
def test_multinomial_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) n = tensor.lvector() pvals = tensor.matrix() out = m.random.multinomial(n=n, pvals=pvals) assert out.ndim == 2 m.f = Method([n, pvals], out) # Specifying the size explicitly m.g = Method([n, pvals], m.random.multinomial(n=n, pvals=pvals, size=(3,))) made = m.make() made.random.initialize() n_val = [1, 2, 3] pvals_val = numpy.asarray([[.1, .9], [.2, .8], [.3, .7]], dtype=config.floatX) seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(n_val, pvals_val) numpy_val0 = numpy.asarray([numpy_rng.multinomial(n=nv, pvals=pv) for nv, pv in zip(n_val, pvals_val)]) assert numpy.all(val0 == numpy_val0) # arguments of size (2,) val1 = made.f(n_val[:-1], pvals_val[:-1]) numpy_val1 = numpy.asarray([numpy_rng.multinomial(n=nv, pvals=pv) for nv, pv in zip(n_val[:-1], pvals_val[:-1])]) assert numpy.all(val1 == numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(n_val, pvals_val) numpy_val2 = numpy.asarray([numpy_rng.multinomial(n=nv, pvals=pv) for nv, pv in zip(n_val, pvals_val)]) assert numpy.all(val2 == numpy_val2) self.assertRaises(ValueError, made.g, n_val[:-1], pvals_val[:-1])
def test_random_integers_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.lvector() high = tensor.lvector() out = m.random.random_integers(low=low, high=high) assert out.ndim == 1 m.f = Method([low, high], out) # Specifying the size explicitly m.g = Method([low, high], m.random.random_integers(low=low, high=high, size=(3,))) made = m.make() made.random.initialize() low_val = [100, 200, 300] high_val = [110, 220, 330] seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(low_val, high_val) numpy_val0 = numpy.asarray([numpy_rng.random_integers(low=lv, high=hv) for lv, hv in zip(low_val, high_val)]) assert numpy.all(val0 == numpy_val0) # arguments of size (2,) val1 = made.f(low_val[:-1], high_val[:-1]) numpy_val1 = numpy.asarray([numpy_rng.random_integers(low=lv, high=hv) for lv, hv in zip(low_val[:-1], high_val[:-1])]) assert numpy.all(val1 == numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(low_val, high_val) numpy_val2 = numpy.asarray([numpy_rng.random_integers(low=lv, high=hv) for lv, hv in zip(low_val, high_val)]) assert numpy.all(val2 == numpy_val2) self.assertRaises(ValueError, made.g, low_val[:-1], high_val[:-1])
def test_vector_arguments(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.vector() out = m.random.uniform(low=low, high=1) assert out.ndim == 1 m.f = Method([low], out) high = tensor.vector() outb = m.random.uniform(low=low, high=high) assert outb.ndim == 1 m.fb = Method([low, high], outb) size = tensor.lvector() outc = m.random.uniform(low=low, high=high, size=size, ndim=1) m.fc = Method([low, high, size], outc) made = m.make() made.random.initialize() seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) low_val0 = numpy.asarray([-5, .5, 0, 1], dtype=config.floatX) low_val1 = numpy.asarray([.9], dtype=config.floatX) val0 = made.f(low_val0) val1 = made.f(low_val1) numpy_val0 = numpy_rng.uniform(low=low_val0, high=1) numpy_val1 = numpy_rng.uniform(low=low_val1, high=1) assert numpy.allclose(val0, numpy_val0) assert numpy.allclose(val1, numpy_val1) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val0b = made.fb([-4., -2], [-1, 0]) val1b = made.fb([-4.], [-1]) numpy_val0b = numpy_rng.uniform(low=[-4., -2], high=[-1, 0]) numpy_val1b = numpy_rng.uniform(low=[-4.], high=[-1]) assert numpy.allclose(val0b, numpy_val0b) assert numpy.allclose(val1b, numpy_val1b) self.assertRaises(ValueError, made.fb, [-4., -2], [-1, 0, 1]) #TODO: do we want that? #self.assertRaises(ValueError, made.fb, [-4., -2], [-1]) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val0c = made.fc([-4., -2], [-1, 0], [2]) val1c = made.fc([-4.], [-1], [1]) numpy_val0c = numpy_rng.uniform(low=[-4., -2], high=[-1, 0]) numpy_val1c = numpy_rng.uniform(low=[-4.], high=[-1]) assert numpy.allclose(val0c, numpy_val0c) assert numpy.allclose(val1c, numpy_val1c) self.assertRaises(ValueError, made.fc, [-4., -2], [-1, 0], [1]) self.assertRaises(ValueError, made.fc, [-4., -2], [-1, 0], [1, 2]) self.assertRaises(ValueError, made.fc, [-4., -2], [-1, 0], [2, 1]) self.assertRaises(ValueError, made.fc, [-4., -2], [-1], [1])
def test_default_shape(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) m.f = Method([], m.random.uniform()) m.g = Method([], m.random.multinomial()) made = m.make() made.random.initialize() #seed_rng is generator for generating *seeds* for RandomStates seed_rng = numpy.random.RandomState(utt.fetch_seed()) uniform_rng = numpy.random.RandomState(int(seed_rng.randint(2**30))) multinomial_rng = numpy.random.RandomState(int(seed_rng.randint(2**30))) val0 = made.f() val1 = made.f() numpy_val0 = uniform_rng.uniform() numpy_val1 = uniform_rng.uniform() assert numpy.allclose(val0, numpy_val0) assert numpy.allclose(val1, numpy_val1) for i in range(10): # every test has 50% chance of passing even with non-matching random states val2 = made.g() numpy_val2 = multinomial_rng.multinomial(n=1, pvals=[.5, .5]) assert numpy.all(val2 == numpy_val2)
def test_multiple(self): M = Module() M.random = RandomStreams(utt.fetch_seed()) out = M.random.uniform((2, 2)) M.m2 = Module() M.m2.random = M.random out2 = M.m2.random.uniform((2, 2)) M.fn = Method([], out) M.m2.fn2 = Method([], out2) m = M.make() m.random.initialize() m.m2.initialize() assert m.random is m.m2.random
def test_vector_arguments(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.vector() out = m.random.uniform(low=low, high=1) assert out.ndim == 1 m.f = Method([low], out) high = tensor.vector() outb = m.random.uniform(low=low, high=high) assert outb.ndim == 1 m.fb = Method([low, high], outb) size = tensor.lvector() outc = m.random.uniform(low=low, high=high, size=size, ndim=1) m.fc = Method([low, high, size], outc) made = m.make() made.random.initialize() seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) low_val0 = numpy.asarray([-5, .5, 0, 1], dtype=config.floatX) low_val1 = numpy.asarray([.9], dtype=config.floatX) val0 = made.f(low_val0) val1 = made.f(low_val1) numpy_val0 = numpy_rng.uniform(low=low_val0, high=1) numpy_val1 = numpy_rng.uniform(low=low_val1, high=1) assert numpy.allclose(val0, numpy_val0) assert numpy.allclose(val1, numpy_val1) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val0b = made.fb([-4., -2], [-1, 0]) val1b = made.fb([-4.], [-1]) numpy_val0b = numpy_rng.uniform(low=[-4., -2], high=[-1, 0]) numpy_val1b = numpy_rng.uniform(low=[-4.], high=[-1]) assert numpy.allclose(val0b, numpy_val0b) assert numpy.allclose(val1b, numpy_val1b) self.assertRaises(ValueError, made.fb, [-4., -2], [-1, 0, 1]) #TODO: do we want that? #self.assertRaises(ValueError, made.fb, [-4., -2], [-1]) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val0c = made.fc([-4., -2], [-1, 0], [2]) val1c = made.fc([-4.], [-1], [1]) numpy_val0c = numpy_rng.uniform(low=[-4., -2], high=[-1, 0]) numpy_val1c = numpy_rng.uniform(low=[-4.], high=[-1]) assert numpy.allclose(val0c, numpy_val0c) assert numpy.allclose(val1c, numpy_val1c) self.assertRaises(ValueError, made.fc, [-4., -2], [-1, 0], [1]) self.assertRaises(ValueError, made.fc, [-4., -2], [-1, 0], [1,2]) self.assertRaises(ValueError, made.fc, [-4., -2], [-1, 0], [2,1]) self.assertRaises(ValueError, made.fc, [-4., -2], [-1], [1])
def test_multinomial_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) n = tensor.lvector() pvals = tensor.matrix() out = m.random.multinomial(n=n, pvals=pvals) assert out.ndim == 2 m.f = Method([n, pvals], out) # Specifying the size explicitly m.g = Method([n, pvals], m.random.multinomial(n=n, pvals=pvals, size=(3, ))) made = m.make() made.random.initialize() n_val = [1, 2, 3] pvals_val = numpy.asarray([[.1, .9], [.2, .8], [.3, .7]], dtype=config.floatX) seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(n_val, pvals_val) numpy_val0 = numpy.asarray([ numpy_rng.multinomial(n=nv, pvals=pv) for nv, pv in zip(n_val, pvals_val) ]) assert numpy.all(val0 == numpy_val0) # arguments of size (2,) val1 = made.f(n_val[:-1], pvals_val[:-1]) numpy_val1 = numpy.asarray([ numpy_rng.multinomial(n=nv, pvals=pv) for nv, pv in zip(n_val[:-1], pvals_val[:-1]) ]) assert numpy.all(val1 == numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(n_val, pvals_val) numpy_val2 = numpy.asarray([ numpy_rng.multinomial(n=nv, pvals=pv) for nv, pv in zip(n_val, pvals_val) ]) assert numpy.all(val2 == numpy_val2) self.assertRaises(ValueError, made.g, n_val[:-1], pvals_val[:-1])
def test_random_integers_vector(self): m = Module() m.random = RandomStreams(utt.fetch_seed()) low = tensor.lvector() high = tensor.lvector() out = m.random.random_integers(low=low, high=high) assert out.ndim == 1 m.f = Method([low, high], out) # Specifying the size explicitly m.g = Method([low, high], m.random.random_integers(low=low, high=high, size=(3, ))) made = m.make() made.random.initialize() low_val = [100, 200, 300] high_val = [110, 220, 330] seed_gen = numpy.random.RandomState(utt.fetch_seed()) numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) # Arguments of size (3,) val0 = made.f(low_val, high_val) numpy_val0 = numpy.asarray([ numpy_rng.random_integers(low=lv, high=hv) for lv, hv in zip(low_val, high_val) ]) assert numpy.all(val0 == numpy_val0) # arguments of size (2,) val1 = made.f(low_val[:-1], high_val[:-1]) numpy_val1 = numpy.asarray([ numpy_rng.random_integers(low=lv, high=hv) for lv, hv in zip(low_val[:-1], high_val[:-1]) ]) assert numpy.all(val1 == numpy_val1) # Specifying the size explicitly numpy_rng = numpy.random.RandomState(int(seed_gen.randint(2**30))) val2 = made.g(low_val, high_val) numpy_val2 = numpy.asarray([ numpy_rng.random_integers(low=lv, high=hv) for lv, hv in zip(low_val, high_val) ]) assert numpy.all(val2 == numpy_val2) self.assertRaises(ValueError, made.g, low_val[:-1], high_val[:-1])
def test_ndim(self): """Test that the behaviour of 'ndim' optional parameter""" # 'ndim' is an optional integer parameter, specifying the length # of the 'shape', passed as a keyword argument. # ndim not specified, OK m1 = Module() m1.random = RandomStreams(utt.fetch_seed()) m1.fn = Method([], m1.random.uniform((2, 2))) made1 = m1.make() made1.random.initialize() # ndim specified, consistent with shape, OK m2 = Module() m2.random = RandomStreams(utt.fetch_seed()) m2.fn = Method([], m2.random.uniform((2, 2), ndim=2)) made2 = m2.make() made2.random.initialize() val1 = made1.fn() val2 = made2.fn() assert numpy.all(val1 == val2) # ndim specified, inconsistent with shape, should raise ValueError m3 = Module() m3.random = RandomStreams(utt.fetch_seed()) self.assertRaises(ValueError, m3.random.uniform, (2, 2), ndim=1)
def test_shuffle_row_elements(self): """Test that RandomStreams.shuffle_row_elements generates the right results""" # Check over two calls to see if the random state is correctly updated. # On matrices, for each row, the elements of that row should be # shuffled. # Note that this differs from numpy.random.shuffle, where all the # elements of the matrix are shuffled. mm = Module() mm.random = RandomStreams(utt.fetch_seed()) m_input = tensor.dmatrix() mm.f = Method([m_input], mm.random.shuffle_row_elements(m_input)) mmade = mm.make() mmade.random.initialize() # Generate the elements to be shuffled val_rng = numpy.random.RandomState(utt.fetch_seed() + 42) in_mval = val_rng.uniform(-2, 2, size=(20, 5)) fn_mval0 = mmade.f(in_mval) fn_mval1 = mmade.f(in_mval) print in_mval[0] print fn_mval0[0] print fn_mval1[0] assert not numpy.all(in_mval == fn_mval0) assert not numpy.all(in_mval == fn_mval1) assert not numpy.all(fn_mval0 == fn_mval1) rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) numpy_mval0 = in_mval.copy() numpy_mval1 = in_mval.copy() for row in numpy_mval0: rng.shuffle(row) for row in numpy_mval1: rng.shuffle(row) assert numpy.all(numpy_mval0 == fn_mval0) assert numpy.all(numpy_mval1 == fn_mval1) # On vectors, the behaviour is the same as numpy.random.shuffle, # except that it does not work in place, but returns a shuffled vector. vm = Module() vm.random = RandomStreams(utt.fetch_seed()) v_input = tensor.dvector() vm.f = Method([v_input], vm.random.shuffle_row_elements(v_input)) vmade = vm.make() vmade.random.initialize() in_vval = val_rng.uniform(-3, 3, size=(12, )) fn_vval = vmade.f(in_vval) numpy_vval = in_vval.copy() vrng = numpy.random.RandomState(int(rng_seed)) vrng.shuffle(numpy_vval) print in_vval print fn_vval print numpy_vval assert numpy.all(numpy_vval == fn_vval) # Trying to shuffle a vector with function that should shuffle # matrices, or vice versa, raises a TypeError self.assertRaises(TypeError, vmade.f, in_mval) self.assertRaises(TypeError, mmade.f, in_vval)
def test_shuffle_row_elements(self): """Test that RandomStreams.shuffle_row_elements generates the right results""" # Check over two calls to see if the random state is correctly updated. # On matrices, for each row, the elements of that row should be # shuffled. # Note that this differs from numpy.random.shuffle, where all the # elements of the matrix are shuffled. mm = Module() mm.random = RandomStreams(utt.fetch_seed()) m_input = tensor.dmatrix() mm.f = Method([m_input], mm.random.shuffle_row_elements(m_input)) mmade = mm.make() mmade.random.initialize() # Generate the elements to be shuffled val_rng = numpy.random.RandomState(utt.fetch_seed()+42) in_mval = val_rng.uniform(-2, 2, size=(20,5)) fn_mval0 = mmade.f(in_mval) fn_mval1 = mmade.f(in_mval) print in_mval[0] print fn_mval0[0] print fn_mval1[0] assert not numpy.all(in_mval == fn_mval0) assert not numpy.all(in_mval == fn_mval1) assert not numpy.all(fn_mval0 == fn_mval1) rng_seed = numpy.random.RandomState(utt.fetch_seed()).randint(2**30) rng = numpy.random.RandomState(int(rng_seed)) numpy_mval0 = in_mval.copy() numpy_mval1 = in_mval.copy() for row in numpy_mval0: rng.shuffle(row) for row in numpy_mval1: rng.shuffle(row) assert numpy.all(numpy_mval0 == fn_mval0) assert numpy.all(numpy_mval1 == fn_mval1) # On vectors, the behaviour is the same as numpy.random.shuffle, # except that it does not work in place, but returns a shuffled vector. vm = Module() vm.random = RandomStreams(utt.fetch_seed()) v_input = tensor.dvector() vm.f = Method([v_input], vm.random.shuffle_row_elements(v_input)) vmade = vm.make() vmade.random.initialize() in_vval = val_rng.uniform(-3, 3, size=(12,)) fn_vval = vmade.f(in_vval) numpy_vval = in_vval.copy() vrng = numpy.random.RandomState(int(rng_seed)) vrng.shuffle(numpy_vval) print in_vval print fn_vval print numpy_vval assert numpy.all(numpy_vval == fn_vval) # Trying to shuffle a vector with function that should shuffle # matrices, or vice versa, raises a TypeError self.assertRaises(TypeError, vmade.f, in_mval) self.assertRaises(TypeError, mmade.f, in_vval)