from __future__ import division, absolute_import, print_function import sys import platform import warnings import itertools from numpy.testing.utils import _gen_alignment_data import numpy.core.umath as ncu import numpy as np from numpy.testing import ( TestCase, run_module_suite, assert_, assert_equal, assert_raises, assert_array_equal, assert_almost_equal, assert_array_almost_equal, dec, assert_allclose, assert_no_warnings ) def on_powerpc(): """ True if we are running on a Power PC platform.""" return platform.processor() == 'powerpc' or \ platform.machine().startswith('ppc') class _FilterInvalids(object): def setUp(self): self.olderr = np.seterr(invalid='ignore') def tearDown(self): np.seterr(**self.olderr) class TestConstants(TestCase): def test_pi(self): assert_allclose(ncu.pi, 3.141592653589793, 1e-15) def test_e(self): assert_allclose(ncu.e, 2.718281828459045, 1e-15) def test_euler_gamma(self): assert_allclose(ncu.euler_gamma, 0.5772156649015329, 1e-15) class TestOut(TestCase): def test_out_subok(self): for subok in (True, False): a = np.array(0.5) o = np.empty(()) r = np.add(a, 2, o, subok=subok) assert_(r is o) r = np.add(a, 2, out=o, subok=subok) assert_(r is o) r = np.add(a, 2, out=(o,), subok=subok) assert_(r is o) d = np.array(5.7) o1 = np.empty(()) o2 = np.empty((), dtype=np.int32) r1, r2 = np.frexp(d, o1, None, subok=subok) assert_(r1 is o1) r1, r2 = np.frexp(d, None, o2, subok=subok) assert_(r2 is o2) r1, r2 = np.frexp(d, o1, o2, subok=subok) assert_(r1 is o1) assert_(r2 is o2) r1, r2 = np.frexp(d, out=(o1, None), subok=subok) assert_(r1 is o1) r1, r2 = np.frexp(d, out=(None, o2), subok=subok) assert_(r2 is o2) r1, r2 = np.frexp(d, out=(o1, o2), subok=subok) assert_(r1 is o1) assert_(r2 is o2) with warnings.catch_warnings(record=True) as w: warnings.filterwarnings('always', '', DeprecationWarning) r1, r2 = np.frexp(d, out=o1, subok=subok) assert_(r1 is o1) assert_(w[0].category is DeprecationWarning) assert_raises(ValueError, np.add, a, 2, o, o, subok=subok) assert_raises(ValueError, np.add, a, 2, o, out=o, subok=subok) assert_raises(ValueError, np.add, a, 2, None, out=o, subok=subok) assert_raises(ValueError, np.add, a, 2, out=(o, o), subok=subok) assert_raises(ValueError, np.add, a, 2, out=(), subok=subok) assert_raises(TypeError, np.add, a, 2, [], subok=subok) assert_raises(TypeError, np.add, a, 2, out=[], subok=subok) assert_raises(TypeError, np.add, a, 2, out=([],), subok=subok) o.flags.writeable = False assert_raises(ValueError, np.add, a, 2, o, subok=subok) assert_raises(ValueError, np.add, a, 2, out=o, subok=subok) assert_raises(ValueError, np.add, a, 2, out=(o,), subok=subok) def test_out_wrap_subok(self): class ArrayWrap(np.ndarray): __array_priority__ = 10 def __new__(cls, arr): return np.asarray(arr).view(cls).copy() def __array_wrap__(self, arr, context): return arr.view(type(self)) for subok in (True, False): a = ArrayWrap([0.5]) r = np.add(a, 2, subok=subok) if subok: assert_(isinstance(r, ArrayWrap)) else: assert_(type(r) == np.ndarray) r = np.add(a, 2, None, subok=subok) if subok: assert_(isinstance(r, ArrayWrap)) else: assert_(type(r) == np.ndarray) r = np.add(a, 2, out=None, subok=subok) if subok: assert_(isinstance(r, ArrayWrap)) else: assert_(type(r) == np.ndarray) r = np.add(a, 2, out=(None,), subok=subok) if subok: assert_(isinstance(r, ArrayWrap)) else: assert_(type(r) == np.ndarray) d = ArrayWrap([5.7]) o1 = np.empty((1,)) o2 = np.empty((1,), dtype=np.int32) r1, r2 = np.frexp(d, o1, subok=subok) if subok: assert_(isinstance(r2, ArrayWrap)) else: assert_(type(r2) == np.ndarray) r1, r2 = np.frexp(d, o1, None, subok=subok) if subok: assert_(isinstance(r2, ArrayWrap)) else: assert_(type(r2) == np.ndarray) r1, r2 = np.frexp(d, None, o2, subok=subok) if subok: assert_(isinstance(r1, ArrayWrap)) else: assert_(type(r1) == np.ndarray) r1, r2 = np.frexp(d, out=(o1, None), subok=subok) if subok: assert_(isinstance(r2, ArrayWrap)) else: assert_(type(r2) == np.ndarray) r1, r2 = np.frexp(d, out=(None, o2), subok=subok) if subok: assert_(isinstance(r1, ArrayWrap)) else: assert_(type(r1) == np.ndarray) with warnings.catch_warnings(record=True) as w: warnings.filterwarnings('always', '', DeprecationWarning) r1, r2 = np.frexp(d, out=o1, subok=subok) if subok: assert_(isinstance(r2, ArrayWrap)) else: assert_(type(r2) == np.ndarray) assert_(w[0].category is DeprecationWarning) class TestDivision(TestCase): def test_division_int(self): # int division should follow Python x = np.array([5, 10, 90, 100, -5, -10, -90, -100, -120]) if 5 / 10 == 0.5: assert_equal(x / 100, [0.05, 0.1, 0.9, 1, -0.05, -0.1, -0.9, -1, -1.2]) else: assert_equal(x / 100, [0, 0, 0, 1, -1, -1, -1, -1, -2]) assert_equal(x // 100, [0, 0, 0, 1, -1, -1, -1, -1, -2]) assert_equal(x % 100, [5, 10, 90, 0, 95, 90, 10, 0, 80]) def test_division_complex(self): # check that implementation is correct msg = "Complex division implementation check" x = np.array([1. + 1.*1j, 1. + .5*1j, 1. + 2.*1j], dtype=np.complex128) assert_almost_equal(x**2/x, x, err_msg=msg) # check overflow, underflow msg = "Complex division overflow/underflow check" x = np.array([1.e+110, 1.e-110], dtype=np.complex128) y = x**2/x assert_almost_equal(y/x, [1, 1], err_msg=msg) def test_zero_division_complex(self): with np.errstate(invalid="ignore", divide="ignore"): x = np.array([0.0], dtype=np.complex128) y = 1.0/x assert_(np.isinf(y)[0]) y = complex(np.inf, np.nan)/x assert_(np.isinf(y)[0]) y = complex(np.nan, np.inf)/x assert_(np.isinf(y)[0]) y = complex(np.inf, np.inf)/x assert_(np.isinf(y)[0]) y = 0.0/x assert_(np.isnan(y)[0]) def test_floor_division_complex(self): # check that implementation is correct msg = "Complex floor division implementation check" x = np.array([.9 + 1j, -.1 + 1j, .9 + .5*1j, .9 + 2.*1j], dtype=np.complex128) y = np.array([0., -1., 0., 0.], dtype=np.complex128) assert_equal(np.floor_divide(x**2, x), y, err_msg=msg) # check overflow, underflow msg = "Complex floor division overflow/underflow check" x = np.array([1.e+110, 1.e-110], dtype=np.complex128) y = np.floor_divide(x**2, x) assert_equal(y, [1.e+110, 0], err_msg=msg) class TestRemainder(TestCase): def test_remainder_basic(self): dt = np.typecodes['AllInteger'] + np.typecodes['Float'] for dt1, dt2 in itertools.product(dt, dt): for sg1, sg2 in itertools.product((+1, -1), (+1, -1)): if sg1 == -1 and dt1 in np.typecodes['UnsignedInteger']: continue if sg2 == -1 and dt2 in np.typecodes['UnsignedInteger']: continue fmt = 'dt1: %s, dt2: %s, sg1: %s, sg2: %s' msg = fmt % (dt1, dt2, sg1, sg2) a = np.array(sg1*71, dtype=dt1) b = np.array(sg2*19, dtype=dt2) div = np.floor_divide(a, b) rem = np.remainder(a, b) assert_equal(div*b + rem, a, err_msg=msg) if sg2 == -1: assert_(b < rem <= 0, msg) else: assert_(b > rem >= 0, msg) def test_float_remainder_exact(self): # test that float results are exact for small integers. This also # holds for the same integers scaled by powers of two. nlst = list(range(-127, 0)) plst = list(range(1, 128)) dividend = nlst + [0] + plst divisor = nlst + plst arg = list(itertools.product(dividend, divisor)) tgt = list(divmod(*t) for t in arg) a, b = np.array(arg, dtype=int).T # convert exact integer results from Python to float so that # signed zero can be used, it is checked. tgtdiv, tgtrem = np.array(tgt, dtype=float).T tgtdiv = np.where((tgtdiv == 0.0) & ((b < 0) ^ (a < 0)), -0.0, tgtdiv) tgtrem = np.where((tgtrem == 0.0) & (b < 0), -0.0, tgtrem) for dt in np.typecodes['Float']: msg = 'dtype: %s' % (dt,) fa = a.astype(dt) fb = b.astype(dt) div = np.floor_divide(fa, fb) rem = np.remainder(fa, fb) assert_equal(div, tgtdiv, err_msg=msg) assert_equal(rem, tgtrem, err_msg=msg) def test_float_remainder_roundoff(self): # gh-6127 dt = np.typecodes['Float'] for dt1, dt2 in itertools.product(dt, dt): for sg1, sg2 in itertools.product((+1, -1), (+1, -1)): fmt = 'dt1: %s, dt2: %s, sg1: %s, sg2: %s' msg = fmt % (dt1, dt2, sg1, sg2) a = np.array(sg1*78*6e-8, dtype=dt1) b = np.array(sg2*6e-8, dtype=dt2) div = np.floor_divide(a, b) rem = np.remainder(a, b) # Equal assertion should hold when fmod is used assert_equal(div*b + rem, a, err_msg=msg) if sg2 == -1: assert_(b < rem <= 0, msg) else: assert_(b > rem >= 0, msg) def test_float_remainder_corner_cases(self): # Check remainder magnitude. for dt in np.typecodes['Float']: b = np.array(1.0, dtype=dt) a = np.nextafter(np.array(0.0, dtype=dt), -b) rem = np.remainder(a, b) assert_(rem <= b, 'dt: %s' % dt) rem = np.remainder(-a, -b) assert_(rem >= -b, 'dt: %s' % dt) # Check nans, inf with warnings.catch_warnings(): warnings.simplefilter('always') warnings.simplefilter('ignore', RuntimeWarning) for dt in np.typecodes['Float']: fone = np.array(1.0, dtype=dt) fzer = np.array(0.0, dtype=dt) finf = np.array(np.inf, dtype=dt) fnan = np.array(np.nan, dtype=dt) rem = np.remainder(fone, fzer) assert_(np.isnan(rem), 'dt: %s, rem: %s' % (dt, rem)) # MSVC 2008 returns NaN here, so disable the check. #rem = np.remainder(fone, finf) #assert_(rem == fone, 'dt: %s, rem: %s' % (dt, rem)) rem = np.remainder(fone, fnan) assert_(np.isnan(rem), 'dt: %s, rem: %s' % (dt, rem)) rem = np.remainder(finf, fone) assert_(np.isnan(rem), 'dt: %s, rem: %s' % (dt, rem)) class TestCbrt(TestCase): def test_cbrt_scalar(self): assert_almost_equal((np.cbrt(np.float32(-2.5)**3)), -2.5) def test_cbrt(self): x = np.array([1., 2., -3., np.inf, -np.inf]) assert_almost_equal(np.cbrt(x**3), x) assert_(np.isnan(np.cbrt(np.nan))) assert_equal(np.cbrt(np.inf), np.inf) assert_equal(np.cbrt(-np.inf), -np.inf) class TestPower(TestCase): def test_power_float(self): x = np.array([1., 2., 3.]) assert_equal(x**0, [1., 1., 1.]) assert_equal(x**1, x) assert_equal(x**2, [1., 4., 9.]) y = x.copy() y **= 2 assert_equal(y, [1., 4., 9.]) assert_almost_equal(x**(-1), [1., 0.5, 1./3]) assert_almost_equal(x**(0.5), [1., ncu.sqrt(2), ncu.sqrt(3)]) for out, inp, msg in _gen_alignment_data(dtype=np.float32, type='unary', max_size=11): exp = [ncu.sqrt(i) for i in inp] assert_almost_equal(inp**(0.5), exp, err_msg=msg) np.sqrt(inp, out=out) assert_equal(out, exp, err_msg=msg) for out, inp, msg in _gen_alignment_data(dtype=np.float64, type='unary', max_size=7): exp = [ncu.sqrt(i) for i in inp] assert_almost_equal(inp**(0.5), exp, err_msg=msg) np.sqrt(inp, out=out) assert_equal(out, exp, err_msg=msg) def test_power_complex(self): x = np.array([1+2j, 2+3j, 3+4j]) assert_equal(x**0, [1., 1., 1.]) assert_equal(x**1, x) assert_almost_equal(x**2, [-3+4j, -5+12j, -7+24j]) assert_almost_equal(x**3, [(1+2j)**3, (2+3j)**3, (3+4j)**3]) assert_almost_equal(x**4, [(1+2j)**4, (2+3j)**4, (3+4j)**4]) assert_almost_equal(x**(-1), [1/(1+2j), 1/(2+3j), 1/(3+4j)]) assert_almost_equal(x**(-2), [1/(1+2j)**2, 1/(2+3j)**2, 1/(3+4j)**2]) assert_almost_equal(x**(-3), [(-11+2j)/125, (-46-9j)/2197, (-117-44j)/15625]) assert_almost_equal(x**(0.5), [ncu.sqrt(1+2j), ncu.sqrt(2+3j), ncu.sqrt(3+4j)]) norm = 1./((x**14)[0]) assert_almost_equal(x**14 * norm, [i * norm for i in [-76443+16124j, 23161315+58317492j, 5583548873 + 2465133864j]]) # Ticket #836 def assert_complex_equal(x, y): assert_array_equal(x.real, y.real) assert_array_equal(x.imag, y.imag) for z in [complex(0, np.inf), complex(1, np.inf)]: z = np.array([z], dtype=np.complex_) with np.errstate(invalid="ignore"): assert_complex_equal(z**1, z) assert_complex_equal(z**2, z*z) assert_complex_equal(z**3, z*z*z) def test_power_zero(self): # ticket #1271 zero = np.array([0j]) one = np.array([1+0j]) cnan = np.array([complex(np.nan, np.nan)]) # FIXME cinf not tested. #cinf = np.array([complex(np.inf, 0)]) def assert_complex_equal(x, y): x, y = np.asarray(x), np.asarray(y) assert_array_equal(x.real, y.real) assert_array_equal(x.imag, y.imag) # positive powers for p in [0.33, 0.5, 1, 1.5, 2, 3, 4, 5, 6.6]: assert_complex_equal(np.power(zero, p), zero) # zero power assert_complex_equal(np.power(zero, 0), one) with np.errstate(invalid="ignore"): assert_complex_equal(np.power(zero, 0+1j), cnan) # negative power for p in [0.33, 0.5, 1, 1.5, 2, 3, 4, 5, 6.6]: assert_complex_equal(np.power(zero, -p), cnan) assert_complex_equal(np.power(zero, -1+0.2j), cnan) def test_fast_power(self): x = np.array([1, 2, 3], np.int16) assert_((x**2.00001).dtype is (x**2.0).dtype) # Check that the fast path ignores 1-element not 0-d arrays res = x ** np.array([[[2]]]) assert_equal(res.shape, (1, 1, 3)) class TestLog2(TestCase): def test_log2_values(self): x = [1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024] y = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10] for dt in ['f', 'd', 'g']: xf = np.array(x, dtype=dt) yf = np.array(y, dtype=dt) assert_almost_equal(np.log2(xf), yf) def test_log2_ints(self): # a good log2 implementation should provide this, # might fail on OS with bad libm for i in range(1, 65): v = np.log2(2.**i) assert_equal(v, float(i), err_msg='at exponent %d' % i) def test_log2_special(self): assert_equal(np.log2(1.), 0.) assert_equal(np.log2(np.inf), np.inf) assert_(np.isnan(np.log2(np.nan))) with warnings.catch_warnings(record=True) as w: warnings.filterwarnings('always', '', RuntimeWarning) assert_(np.isnan(np.log2(-1.))) assert_(np.isnan(np.log2(-np.inf))) assert_equal(np.log2(0.), -np.inf) assert_(w[0].category is RuntimeWarning) assert_(w[1].category is RuntimeWarning) assert_(w[2].category is RuntimeWarning) class TestExp2(TestCase): def test_exp2_values(self): x = [1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024] y = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10] for dt in ['f', 'd', 'g']: xf = np.array(x, dtype=dt) yf = np.array(y, dtype=dt) assert_almost_equal(np.exp2(yf), xf) class TestLogAddExp2(_FilterInvalids): # Need test for intermediate precisions def test_logaddexp2_values(self): x = [1, 2, 3, 4, 5] y = [5, 4, 3, 2, 1] z = [6, 6, 6, 6, 6] for dt, dec_ in zip(['f', 'd', 'g'], [6, 15, 15]): xf = np.log2(np.array(x, dtype=dt)) yf = np.log2(np.array(y, dtype=dt)) zf = np.log2(np.array(z, dtype=dt)) assert_almost_equal(np.logaddexp2(xf, yf), zf, decimal=dec_) def test_logaddexp2_range(self): x = [1000000, -1000000, 1000200, -1000200] y = [1000200, -1000200, 1000000, -1000000] z = [1000200, -1000000, 1000200, -1000000] for dt in ['f', 'd', 'g']: logxf = np.array(x, dtype=dt) logyf = np.array(y, dtype=dt) logzf = np.array(z, dtype=dt) assert_almost_equal(np.logaddexp2(logxf, logyf), logzf) def test_inf(self): inf = np.inf x = [inf, -inf, inf, -inf, inf, 1, -inf, 1] y = [inf, inf, -inf, -inf, 1, inf, 1, -inf] z = [inf, inf, inf, -inf, inf, inf, 1, 1] with np.errstate(invalid='raise'): for dt in ['f', 'd', 'g']: logxf = np.array(x, dtype=dt) logyf = np.array(y, dtype=dt) logzf = np.array(z, dtype=dt) assert_equal(np.logaddexp2(logxf, logyf), logzf) def test_nan(self): assert_(np.isnan(np.logaddexp2(np.nan, np.inf))) assert_(np.isnan(np.logaddexp2(np.inf, np.nan))) assert_(np.isnan(np.logaddexp2(np.nan, 0))) assert_(np.isnan(np.logaddexp2(0, np.nan))) assert_(np.isnan(np.logaddexp2(np.nan, np.nan))) class TestLog(TestCase): def test_log_values(self): x = [1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024] y = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10] for dt in ['f', 'd', 'g']: log2_ = 0.69314718055994530943 xf = np.array(x, dtype=dt) yf = np.array(y, dtype=dt)*log2_ assert_almost_equal(np.log(xf), yf) class TestExp(TestCase): def test_exp_values(self): x = [1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024] y = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10] for dt in ['f', 'd', 'g']: log2_ = 0.69314718055994530943 xf = np.array(x, dtype=dt) yf = np.array(y, dtype=dt)*log2_ assert_almost_equal(np.exp(yf), xf) class TestLogAddExp(_FilterInvalids): def test_logaddexp_values(self): x = [1, 2, 3, 4, 5] y = [5, 4, 3, 2, 1] z = [6, 6, 6, 6, 6] for dt, dec_ in zip(['f', 'd', 'g'], [6, 15, 15]): xf = np.log(np.array(x, dtype=dt)) yf = np.log(np.array(y, dtype=dt)) zf = np.log(np.array(z, dtype=dt)) assert_almost_equal(np.logaddexp(xf, yf), zf, decimal=dec_) def test_logaddexp_range(self): x = [1000000, -1000000, 1000200, -1000200] y = [1000200, -1000200, 1000000, -1000000] z = [1000200, -1000000, 1000200, -1000000] for dt in ['f', 'd', 'g']: logxf = np.array(x, dtype=dt) logyf = np.array(y, dtype=dt) logzf = np.array(z, dtype=dt) assert_almost_equal(np.logaddexp(logxf, logyf), logzf) def test_inf(self): inf = np.inf x = [inf, -inf, inf, -inf, inf, 1, -inf, 1] y = [inf, inf, -inf, -inf, 1, inf, 1, -inf] z = [inf, inf, inf, -inf, inf, inf, 1, 1] with np.errstate(invalid='raise'): for dt in ['f', 'd', 'g']: logxf = np.array(x, dtype=dt) logyf = np.array(y, dtype=dt) logzf = np.array(z, dtype=dt) assert_equal(np.logaddexp(logxf, logyf), logzf) def test_nan(self): assert_(np.isnan(np.logaddexp(np.nan, np.inf))) assert_(np.isnan(np.logaddexp(np.inf, np.nan))) assert_(np.isnan(np.logaddexp(np.nan, 0))) assert_(np.isnan(np.logaddexp(0, np.nan))) assert_(np.isnan(np.logaddexp(np.nan, np.nan))) class TestLog1p(TestCase): def test_log1p(self): assert_almost_equal(ncu.log1p(0.2), ncu.log(1.2)) assert_almost_equal(ncu.log1p(1e-6), ncu.log(1+1e-6)) def test_special(self): with np.errstate(invalid="ignore", divide="ignore"): assert_equal(ncu.log1p(np.nan), np.nan) assert_equal(ncu.log1p(np.inf), np.inf) assert_equal(ncu.log1p(-1.), -np.inf) assert_equal(ncu.log1p(-2.), np.nan) assert_equal(ncu.log1p(-np.inf), np.nan) class TestExpm1(TestCase): def test_expm1(self): assert_almost_equal(ncu.expm1(0.2), ncu.exp(0.2)-1) assert_almost_equal(ncu.expm1(1e-6), ncu.exp(1e-6)-1) def test_special(self): assert_equal(ncu.expm1(np.inf), np.inf) assert_equal(ncu.expm1(0.), 0.) assert_equal(ncu.expm1(-0.), -0.) assert_equal(ncu.expm1(np.inf), np.inf) assert_equal(ncu.expm1(-np.inf), -1.) class TestHypot(TestCase, object): def test_simple(self): assert_almost_equal(ncu.hypot(1, 1), ncu.sqrt(2)) assert_almost_equal(ncu.hypot(0, 0), 0) def assert_hypot_isnan(x, y): with np.errstate(invalid='ignore'): assert_(np.isnan(ncu.hypot(x, y)), "hypot(%s, %s) is %s, not nan" % (x, y, ncu.hypot(x, y))) def assert_hypot_isinf(x, y): with np.errstate(invalid='ignore'): assert_(np.isinf(ncu.hypot(x, y)), "hypot(%s, %s) is %s, not inf" % (x, y, ncu.hypot(x, y))) class TestHypotSpecialValues(TestCase): def test_nan_outputs(self): assert_hypot_isnan(np.nan, np.nan) assert_hypot_isnan(np.nan, 1) def test_nan_outputs2(self): assert_hypot_isinf(np.nan, np.inf) assert_hypot_isinf(np.inf, np.nan) assert_hypot_isinf(np.inf, 0) assert_hypot_isinf(0, np.inf) assert_hypot_isinf(np.inf, np.inf) assert_hypot_isinf(np.inf, 23.0) def test_no_fpe(self): assert_no_warnings(ncu.hypot, np.inf, 0) def assert_arctan2_isnan(x, y): assert_(np.isnan(ncu.arctan2(x, y)), "arctan(%s, %s) is %s, not nan" % (x, y, ncu.arctan2(x, y))) def assert_arctan2_ispinf(x, y): assert_((np.isinf(ncu.arctan2(x, y)) and ncu.arctan2(x, y) > 0), "arctan(%s, %s) is %s, not +inf" % (x, y, ncu.arctan2(x, y))) def assert_arctan2_isninf(x, y): assert_((np.isinf(ncu.arctan2(x, y)) and ncu.arctan2(x, y) < 0), "arctan(%s, %s) is %s, not -inf" % (x, y, ncu.arctan2(x, y))) def assert_arctan2_ispzero(x, y): assert_((ncu.arctan2(x, y) == 0 and not np.signbit(ncu.arctan2(x, y))), "arctan(%s, %s) is %s, not +0" % (x, y, ncu.arctan2(x, y))) def assert_arctan2_isnzero(x, y): assert_((ncu.arctan2(x, y) == 0 and np.signbit(ncu.arctan2(x, y))), "arctan(%s, %s) is %s, not -0" % (x, y, ncu.arctan2(x, y))) class TestArctan2SpecialValues(TestCase): def test_one_one(self): # atan2(1, 1) returns pi/4. assert_almost_equal(ncu.arctan2(1, 1), 0.25 * np.pi) assert_almost_equal(ncu.arctan2(-1, 1), -0.25 * np.pi) assert_almost_equal(ncu.arctan2(1, -1), 0.75 * np.pi) def test_zero_nzero(self): # atan2(+-0, -0) returns +-pi. assert_almost_equal(ncu.arctan2(np.PZERO, np.NZERO), np.pi) assert_almost_equal(ncu.arctan2(np.NZERO, np.NZERO), -np.pi) def test_zero_pzero(self): # atan2(+-0, +0) returns +-0. assert_arctan2_ispzero(np.PZERO, np.PZERO) assert_arctan2_isnzero(np.NZERO, np.PZERO) def test_zero_negative(self): # atan2(+-0, x) returns +-pi for x < 0. assert_almost_equal(ncu.arctan2(np.PZERO, -1), np.pi) assert_almost_equal(ncu.arctan2(np.NZERO, -1), -np.pi) def test_zero_positive(self): # atan2(+-0, x) returns +-0 for x > 0. assert_arctan2_ispzero(np.PZERO, 1) assert_arctan2_isnzero(np.NZERO, 1) def test_positive_zero(self): # atan2(y, +-0) returns +pi/2 for y > 0. assert_almost_equal(ncu.arctan2(1, np.PZERO), 0.5 * np.pi) assert_almost_equal(ncu.arctan2(1, np.NZERO), 0.5 * np.pi) def test_negative_zero(self): # atan2(y, +-0) returns -pi/2 for y < 0. assert_almost_equal(ncu.arctan2(-1, np.PZERO), -0.5 * np.pi) assert_almost_equal(ncu.arctan2(-1, np.NZERO), -0.5 * np.pi) def test_any_ninf(self): # atan2(+-y, -infinity) returns +-pi for finite y > 0. assert_almost_equal(ncu.arctan2(1, np.NINF), np.pi) assert_almost_equal(ncu.arctan2(-1, np.NINF), -np.pi) def test_any_pinf(self): # atan2(+-y, +infinity) returns +-0 for finite y > 0. assert_arctan2_ispzero(1, np.inf) assert_arctan2_isnzero(-1, np.inf) def test_inf_any(self): # atan2(+-infinity, x) returns +-pi/2 for finite x. assert_almost_equal(ncu.arctan2( np.inf, 1), 0.5 * np.pi) assert_almost_equal(ncu.arctan2(-np.inf, 1), -0.5 * np.pi) def test_inf_ninf(self): # atan2(+-infinity, -infinity) returns +-3*pi/4. assert_almost_equal(ncu.arctan2( np.inf, -np.inf), 0.75 * np.pi) assert_almost_equal(ncu.arctan2(-np.inf, -np.inf), -0.75 * np.pi) def test_inf_pinf(self): # atan2(+-infinity, +infinity) returns +-pi/4. assert_almost_equal(ncu.arctan2( np.inf, np.inf), 0.25 * np.pi) assert_almost_equal(ncu.arctan2(-np.inf, np.inf), -0.25 * np.pi) def test_nan_any(self): # atan2(nan, x) returns nan for any x, including inf assert_arctan2_isnan(np.nan, np.inf) assert_arctan2_isnan(np.inf, np.nan) assert_arctan2_isnan(np.nan, np.nan) class TestLdexp(TestCase): def _check_ldexp(self, tp): assert_almost_equal(ncu.ldexp(np.array(2., np.float32), np.array(3, tp)), 16.) assert_almost_equal(ncu.ldexp(np.array(2., np.float64), np.array(3, tp)), 16.) assert_almost_equal(ncu.ldexp(np.array(2., np.longdouble), np.array(3, tp)), 16.) def test_ldexp(self): # The default Python int type should work assert_almost_equal(ncu.ldexp(2., 3), 16.) # The following int types should all be accepted self._check_ldexp(np.int8) self._check_ldexp(np.int16) self._check_ldexp(np.int32) self._check_ldexp('i') self._check_ldexp('l') def test_ldexp_overflow(self): # silence warning emitted on overflow with np.errstate(over="ignore"): imax = np.iinfo(np.dtype('l')).max imin = np.iinfo(np.dtype('l')).min assert_equal(ncu.ldexp(2., imax), np.inf) assert_equal(ncu.ldexp(2., imin), 0) class TestMaximum(_FilterInvalids): def test_reduce(self): dflt = np.typecodes['AllFloat'] dint = np.typecodes['AllInteger'] seq1 = np.arange(11) seq2 = seq1[::-1] func = np.maximum.reduce for dt in dint: tmp1 = seq1.astype(dt) tmp2 = seq2.astype(dt) assert_equal(func(tmp1), 10) assert_equal(func(tmp2), 10) for dt in dflt: tmp1 = seq1.astype(dt) tmp2 = seq2.astype(dt) assert_equal(func(tmp1), 10) assert_equal(func(tmp2), 10) tmp1[::2] = np.nan tmp2[::2] = np.nan assert_equal(func(tmp1), np.nan) assert_equal(func(tmp2), np.nan) def test_reduce_complex(self): assert_equal(np.maximum.reduce([1, 2j]), 1) assert_equal(np.maximum.reduce([1+3j, 2j]), 1+3j) def test_float_nans(self): nan = np.nan arg1 = np.array([0, nan, nan]) arg2 = np.array([nan, 0, nan]) out = np.array([nan, nan, nan]) assert_equal(np.maximum(arg1, arg2), out) def test_object_nans(self): # Multiple checks to give this a chance to # fail if cmp is used instead of rich compare. # Failure cannot be guaranteed. for i in range(1): x = np.array(float('nan'), np.object) y = 1.0 z = np.array(float('nan'), np.object) assert_(np.maximum(x, y) == 1.0) assert_(np.maximum(z, y) == 1.0) def test_complex_nans(self): nan = np.nan for cnan in [complex(nan, 0), complex(0, nan), complex(nan, nan)]: arg1 = np.array([0, cnan, cnan], dtype=np.complex) arg2 = np.array([cnan, 0, cnan], dtype=np.complex) out = np.array([nan, nan, nan], dtype=np.complex) assert_equal(np.maximum(arg1, arg2), out) def test_object_array(self): arg1 = np.arange(5, dtype=np.object) arg2 = arg1 + 1 assert_equal(np.maximum(arg1, arg2), arg2) class TestMinimum(_FilterInvalids): def test_reduce(self): dflt = np.typecodes['AllFloat'] dint = np.typecodes['AllInteger'] seq1 = np.arange(11) seq2 = seq1[::-1] func = np.minimum.reduce for dt in dint: tmp1 = seq1.astype(dt) tmp2 = seq2.astype(dt) assert_equal(func(tmp1), 0) assert_equal(func(tmp2), 0) for dt in dflt: tmp1 = seq1.astype(dt) tmp2 = seq2.astype(dt) assert_equal(func(tmp1), 0) assert_equal(func(tmp2), 0) tmp1[::2] = np.nan tmp2[::2] = np.nan assert_equal(func(tmp1), np.nan) assert_equal(func(tmp2), np.nan) def test_reduce_complex(self): assert_equal(np.minimum.reduce([1, 2j]), 2j) assert_equal(np.minimum.reduce([1+3j, 2j]), 2j) def test_float_nans(self): nan = np.nan arg1 = np.array([0, nan, nan]) arg2 = np.array([nan, 0, nan]) out = np.array([nan, nan, nan]) assert_equal(np.minimum(arg1, arg2), out) def test_object_nans(self): # Multiple checks to give this a chance to # fail if cmp is used instead of rich compare. # Failure cannot be guaranteed. for i in range(1): x = np.array(float('nan'), np.object) y = 1.0 z = np.array(float('nan'), np.object) assert_(np.minimum(x, y) == 1.0) assert_(np.minimum(z, y) == 1.0) def test_complex_nans(self): nan = np.nan for cnan in [complex(nan, 0), complex(0, nan), complex(nan, nan)]: arg1 = np.array([0, cnan, cnan], dtype=np.complex) arg2 = np.array([cnan, 0, cnan], dtype=np.complex) out = np.array([nan, nan, nan], dtype=np.complex) assert_equal(np.minimum(arg1, arg2), out) def test_object_array(self): arg1 = np.arange(5, dtype=np.object) arg2 = arg1 + 1 assert_equal(np.minimum(arg1, arg2), arg1) class TestFmax(_FilterInvalids): def test_reduce(self): dflt = np.typecodes['AllFloat'] dint = np.typecodes['AllInteger'] seq1 = np.arange(11) seq2 = seq1[::-1] func = np.fmax.reduce for dt in dint: tmp1 = seq1.astype(dt) tmp2 = seq2.astype(dt) assert_equal(func(tmp1), 10) assert_equal(func(tmp2), 10) for dt in dflt: tmp1 = seq1.astype(dt) tmp2 = seq2.astype(dt) assert_equal(func(tmp1), 10) assert_equal(func(tmp2), 10) tmp1[::2] = np.nan tmp2[::2] = np.nan assert_equal(func(tmp1), 9) assert_equal(func(tmp2), 9) def test_reduce_complex(self): assert_equal(np.fmax.reduce([1, 2j]), 1) assert_equal(np.fmax.reduce([1+3j, 2j]), 1+3j) def test_float_nans(self): nan = np.nan arg1 = np.array([0, nan, nan]) arg2 = np.array([nan, 0, nan]) out = np.array([0, 0, nan]) assert_equal(np.fmax(arg1, arg2), out) def test_complex_nans(self): nan = np.nan for cnan in [complex(nan, 0), complex(0, nan), complex(nan, nan)]: arg1 = np.array([0, cnan, cnan], dtype=np.complex) arg2 = np.array([cnan, 0, cnan], dtype=np.complex) out = np.array([0, 0, nan], dtype=np.complex) assert_equal(np.fmax(arg1, arg2), out) class TestFmin(_FilterInvalids): def test_reduce(self): dflt = np.typecodes['AllFloat'] dint = np.typecodes['AllInteger'] seq1 = np.arange(11) seq2 = seq1[::-1] func = np.fmin.reduce for dt in dint: tmp1 = seq1.astype(dt) tmp2 = seq2.astype(dt) assert_equal(func(tmp1), 0) assert_equal(func(tmp2), 0) for dt in dflt: tmp1 = seq1.astype(dt) tmp2 = seq2.astype(dt) assert_equal(func(tmp1), 0) assert_equal(func(tmp2), 0) tmp1[::2] = np.nan tmp2[::2] = np.nan assert_equal(func(tmp1), 1) assert_equal(func(tmp2), 1) def test_reduce_complex(self): assert_equal(np.fmin.reduce([1, 2j]), 2j) assert_equal(np.fmin.reduce([1+3j, 2j]), 2j) def test_float_nans(self): nan = np.nan arg1 = np.array([0, nan, nan]) arg2 = np.array([nan, 0, nan]) out = np.array([0, 0, nan]) assert_equal(np.fmin(arg1, arg2), out) def test_complex_nans(self): nan = np.nan for cnan in [complex(nan, 0), complex(0, nan), complex(nan, nan)]: arg1 = np.array([0, cnan, cnan], dtype=np.complex) arg2 = np.array([cnan, 0, cnan], dtype=np.complex) out = np.array([0, 0, nan], dtype=np.complex) assert_equal(np.fmin(arg1, arg2), out) class TestBool(TestCase): def test_truth_table_logical(self): # 2, 3 and 4 serves as true values input1 = [0, 0, 3, 2] input2 = [0, 4, 0, 2] typecodes = (np.typecodes['AllFloat'] + np.typecodes['AllInteger'] + '?') # boolean for dtype in map(np.dtype, typecodes): arg1 = np.asarray(input1, dtype=dtype) arg2 = np.asarray(input2, dtype=dtype) # OR out = [False, True, True, True] for func in (np.logical_or, np.maximum): assert_equal(func(arg1, arg2).astype(bool), out) # AND out = [False, False, False, True] for func in (np.logical_and, np.minimum): assert_equal(func(arg1, arg2).astype(bool), out) # XOR out = [False, True, True, False] for func in (np.logical_xor, np.not_equal): assert_equal(func(arg1, arg2).astype(bool), out) def test_truth_table_bitwise(self): arg1 = [False, False, True, True] arg2 = [False, True, False, True] out = [False, True, True, True] assert_equal(np.bitwise_or(arg1, arg2), out) out = [False, False, False, True] assert_equal(np.bitwise_and(arg1, arg2), out) out = [False, True, True, False] assert_equal(np.bitwise_xor(arg1, arg2), out) class TestInt(TestCase): def test_logical_not(self): x = np.ones(10, dtype=np.int16) o = np.ones(10 * 2, dtype=np.bool) tgt = o.copy() tgt[::2] = False os = o[::2] assert_array_equal(np.logical_not(x, out=os), False) assert_array_equal(o, tgt) class TestFloatingPoint(TestCase): def test_floating_point(self): assert_equal(ncu.FLOATING_POINT_SUPPORT, 1) class TestDegrees(TestCase): def test_degrees(self): assert_almost_equal(ncu.degrees(np.pi), 180.0) assert_almost_equal(ncu.degrees(-0.5*np.pi), -90.0) class TestRadians(TestCase): def test_radians(self): assert_almost_equal(ncu.radians(180.0), np.pi) assert_almost_equal(ncu.radians(-90.0), -0.5*np.pi) class TestSign(TestCase): def test_sign(self): a = np.array([np.inf, -np.inf, np.nan, 0.0, 3.0, -3.0]) out = np.zeros(a.shape) tgt = np.array([1., -1., np.nan, 0.0, 1.0, -1.0]) with np.errstate(invalid='ignore'): res = ncu.sign(a) assert_equal(res, tgt) res = ncu.sign(a, out) assert_equal(res, tgt) assert_equal(out, tgt) def test_sign_dtype_object(self): # In reference to github issue #6229 foo = np.array([-.1, 0, .1]) a = np.sign(foo.astype(np.object)) b = np.sign(foo) assert_array_equal(a, b) def test_sign_dtype_nan_object(self): # In reference to github issue #6229 def test_nan(): foo = np.array([np.nan]) a = np.sign(foo.astype(np.object)) assert_raises(TypeError, test_nan) class TestMinMax(TestCase): def test_minmax_blocked(self): # simd tests on max/min, test all alignments, slow but important # for 2 * vz + 2 * (vs - 1) + 1 (unrolled once) for dt, sz in [(np.float32, 15), (np.float64, 7)]: for out, inp, msg in _gen_alignment_data(dtype=dt, type='unary', max_size=sz): for i in range(inp.size): inp[:] = np.arange(inp.size, dtype=dt) inp[i] = np.nan emsg = lambda: '%r\n%s' % (inp, msg) assert_(np.isnan(inp.max()), msg=emsg) assert_(np.isnan(inp.min()), msg=emsg) inp[i] = 1e10 assert_equal(inp.max(), 1e10, err_msg=msg) inp[i] = -1e10 assert_equal(inp.min(), -1e10, err_msg=msg) def test_lower_align(self): # check data that is not aligned to element size # i.e doubles are aligned to 4 bytes on i386 d = np.zeros(23 * 8, dtype=np.int8)[4:-4].view(np.float64) assert_equal(d.max(), d[0]) assert_equal(d.min(), d[0]) class TestAbsoluteNegative(TestCase): def test_abs_neg_blocked(self): # simd tests on abs, test all alignments for vz + 2 * (vs - 1) + 1 for dt, sz in [(np.float32, 11), (np.float64, 5)]: for out, inp, msg in _gen_alignment_data(dtype=dt, type='unary', max_size=sz): tgt = [ncu.absolute(i) for i in inp] np.absolute(inp, out=out) assert_equal(out, tgt, err_msg=msg) self.assertTrue((out >= 0).all()) tgt = [-1*(i) for i in inp] np.negative(inp, out=out) assert_equal(out, tgt, err_msg=msg) # will throw invalid flag depending on compiler optimizations with np.errstate(invalid='ignore'): for v in [np.nan, -np.inf, np.inf]: for i in range(inp.size): d = np.arange(inp.size, dtype=dt) inp[:] = -d inp[i] = v d[i] = -v if v == -np.inf else v assert_array_equal(np.abs(inp), d, err_msg=msg) np.abs(inp, out=out) assert_array_equal(out, d, err_msg=msg) assert_array_equal(-inp, -1*inp, err_msg=msg) np.negative(inp, out=out) assert_array_equal(out, -1*inp, err_msg=msg) def test_lower_align(self): # check data that is not aligned to element size # i.e doubles are aligned to 4 bytes on i386 d = np.zeros(23 * 8, dtype=np.int8)[4:-4].view(np.float64) assert_equal(np.abs(d), d) assert_equal(np.negative(d), -d) np.negative(d, out=d) np.negative(np.ones_like(d), out=d) np.abs(d, out=d) np.abs(np.ones_like(d), out=d) class TestSpecialMethods(TestCase): def test_wrap(self): class with_wrap(object): def __array__(self): return np.zeros(1) def __array_wrap__(self, arr, context): r = with_wrap() r.arr = arr r.context = context return r a = with_wrap() x = ncu.minimum(a, a) assert_equal(x.arr, np.zeros(1)) func, args, i = x.context self.assertTrue(func is ncu.minimum) self.assertEqual(len(args), 2) assert_equal(args[0], a) assert_equal(args[1], a) self.assertEqual(i, 0) def test_wrap_with_iterable(self): # test fix for bug #1026: class with_wrap(np.ndarray): __array_priority__ = 10 def __new__(cls): return np.asarray(1).view(cls).copy() def __array_wrap__(self, arr, context): return arr.view(type(self)) a = with_wrap() x = ncu.multiply(a, (1, 2, 3)) self.assertTrue(isinstance(x, with_wrap)) assert_array_equal(x, np.array((1, 2, 3))) def test_priority_with_scalar(self): # test fix for bug #826: class A(np.ndarray): __array_priority__ = 10 def __new__(cls): return np.asarray(1.0, 'float64').view(cls).copy() a = A() x = np.float64(1)*a self.assertTrue(isinstance(x, A)) assert_array_equal(x, np.array(1)) def test_old_wrap(self): class with_wrap(object): def __array__(self): return np.zeros(1) def __array_wrap__(self, arr): r = with_wrap() r.arr = arr return r a = with_wrap() x = ncu.minimum(a, a) assert_equal(x.arr, np.zeros(1)) def test_priority(self): class A(object): def __array__(self): return np.zeros(1) def __array_wrap__(self, arr, context): r = type(self)() r.arr = arr r.context = context return r class B(A): __array_priority__ = 20. class C(A): __array_priority__ = 40. x = np.zeros(1) a = A() b = B() c = C() f = ncu.minimum self.assertTrue(type(f(x, x)) is np.ndarray) self.assertTrue(type(f(x, a)) is A) self.assertTrue(type(f(x, b)) is B) self.assertTrue(type(f(x, c)) is C) self.assertTrue(type(f(a, x)) is A) self.assertTrue(type(f(b, x)) is B) self.assertTrue(type(f(c, x)) is C) self.assertTrue(type(f(a, a)) is A) self.assertTrue(type(f(a, b)) is B) self.assertTrue(type(f(b, a)) is B) self.assertTrue(type(f(b, b)) is B) self.assertTrue(type(f(b, c)) is C) self.assertTrue(type(f(c, b)) is C) self.assertTrue(type(f(c, c)) is C) self.assertTrue(type(ncu.exp(a) is A)) self.assertTrue(type(ncu.exp(b) is B)) self.assertTrue(type(ncu.exp(c) is C)) def test_failing_wrap(self): class A(object): def __array__(self): return np.zeros(1) def __array_wrap__(self, arr, context): raise RuntimeError a = A() self.assertRaises(RuntimeError, ncu.maximum, a, a) def test_default_prepare(self): class with_wrap(object): __array_priority__ = 10 def __array__(self): return np.zeros(1) def __array_wrap__(self, arr, context): return arr a = with_wrap() x = ncu.minimum(a, a) assert_equal(x, np.zeros(1)) assert_equal(type(x), np.ndarray) def test_prepare(self): class with_prepare(np.ndarray): __array_priority__ = 10 def __array_prepare__(self, arr, context): # make sure we can return a new return np.array(arr).view(type=with_prepare) a = np.array(1).view(type=with_prepare) x = np.add(a, a) assert_equal(x, np.array(2)) assert_equal(type(x), with_prepare) def test_failing_prepare(self): class A(object): def __array__(self): return np.zeros(1) def __array_prepare__(self, arr, context=None): raise RuntimeError a = A() self.assertRaises(RuntimeError, ncu.maximum, a, a) def test_array_with_context(self): class A(object): def __array__(self, dtype=None, context=None): func, args, i = context self.func = func self.args = args self.i = i return np.zeros(1) class B(object): def __array__(self, dtype=None): return np.zeros(1, dtype) class C(object): def __array__(self): return np.zeros(1) a = A() ncu.maximum(np.zeros(1), a) self.assertTrue(a.func is ncu.maximum) assert_equal(a.args[0], 0) self.assertTrue(a.args[1] is a) self.assertTrue(a.i == 1) assert_equal(ncu.maximum(a, B()), 0) assert_equal(ncu.maximum(a, C()), 0) def test_ufunc_override_disabled(self): # 2016-01-29: NUMPY_UFUNC_DISABLED # This test should be removed when __numpy_ufunc__ is re-enabled. class MyArray(object): def __numpy_ufunc__(self, *args, **kwargs): self._numpy_ufunc_called = True my_array = MyArray() real_array = np.ones(10) assert_raises(TypeError, lambda: real_array + my_array) assert_raises(TypeError, np.add, real_array, my_array) assert not hasattr(my_array, "_numpy_ufunc_called") def test_ufunc_override(self): # 2016-01-29: NUMPY_UFUNC_DISABLED return class A(object): def __numpy_ufunc__(self, func, method, pos, inputs, **kwargs): return self, func, method, pos, inputs, kwargs a = A() b = np.matrix([1]) res0 = np.multiply(a, b) res1 = np.dot(a, b) # self assert_equal(res0[0], a) assert_equal(res1[0], a) assert_equal(res0[1], np.multiply) assert_equal(res1[1], np.dot) assert_equal(res0[2], '__call__') assert_equal(res1[2], '__call__') assert_equal(res0[3], 0) assert_equal(res1[3], 0) assert_equal(res0[4], (a, b)) assert_equal(res1[4], (a, b)) assert_equal(res0[5], {}) assert_equal(res1[5], {}) def test_ufunc_override_mro(self): # 2016-01-29: NUMPY_UFUNC_DISABLED return # Some multi arg functions for testing. def tres_mul(a, b, c): return a * b * c def quatro_mul(a, b, c, d): return a * b * c * d # Make these into ufuncs. three_mul_ufunc = np.frompyfunc(tres_mul, 3, 1) four_mul_ufunc = np.frompyfunc(quatro_mul, 4, 1) class A(object): def __numpy_ufunc__(self, func, method, pos, inputs, **kwargs): return "A" class ASub(A): def __numpy_ufunc__(self, func, method, pos, inputs, **kwargs): return "ASub" class B(object): def __numpy_ufunc__(self, func, method, pos, inputs, **kwargs): return "B" class C(object): def __numpy_ufunc__(self, func, method, pos, inputs, **kwargs): return NotImplemented class CSub(object): def __numpy_ufunc__(self, func, method, pos, inputs, **kwargs): return NotImplemented a = A() a_sub = ASub() b = B() c = C() c_sub = CSub() # Standard res = np.multiply(a, a_sub) assert_equal(res, "ASub") res = np.multiply(a_sub, b) assert_equal(res, "ASub") # With 1 NotImplemented res = np.multiply(c, a) assert_equal(res, "A") # Both NotImplemented. assert_raises(TypeError, np.multiply, c, c_sub) assert_raises(TypeError, np.multiply, c_sub, c) assert_raises(TypeError, np.multiply, 2, c) # Ternary testing. assert_equal(three_mul_ufunc(a, 1, 2), "A") assert_equal(three_mul_ufunc(1, a, 2), "A") assert_equal(three_mul_ufunc(1, 2, a), "A") assert_equal(three_mul_ufunc(a, a, 6), "A") assert_equal(three_mul_ufunc(a, 2, a), "A") assert_equal(three_mul_ufunc(a, 2, b), "A") assert_equal(three_mul_ufunc(a, 2, a_sub), "ASub") assert_equal(three_mul_ufunc(a, a_sub, 3), "ASub") assert_equal(three_mul_ufunc(c, a_sub, 3), "ASub") assert_equal(three_mul_ufunc(1, a_sub, c), "ASub") assert_equal(three_mul_ufunc(a, b, c), "A") assert_equal(three_mul_ufunc(a, b, c_sub), "A") assert_equal(three_mul_ufunc(1, 2, b), "B") assert_raises(TypeError, three_mul_ufunc, 1, 2, c) assert_raises(TypeError, three_mul_ufunc, c_sub, 2, c) assert_raises(TypeError, three_mul_ufunc, c_sub, 2, 3) # Quaternary testing. assert_equal(four_mul_ufunc(a, 1, 2, 3), "A") assert_equal(four_mul_ufunc(1, a, 2, 3), "A") assert_equal(four_mul_ufunc(1, 1, a, 3), "A") assert_equal(four_mul_ufunc(1, 1, 2, a), "A") assert_equal(four_mul_ufunc(a, b, 2, 3), "A") assert_equal(four_mul_ufunc(1, a, 2, b), "A") assert_equal(four_mul_ufunc(b, 1, a, 3), "B") assert_equal(four_mul_ufunc(a_sub, 1, 2, a), "ASub") assert_equal(four_mul_ufunc(a, 1, 2, a_sub), "ASub") assert_raises(TypeError, four_mul_ufunc, 1, 2, 3, c) assert_raises(TypeError, four_mul_ufunc, 1, 2, c_sub, c) assert_raises(TypeError, four_mul_ufunc, 1, c, c_sub, c) def test_ufunc_override_methods(self): # 2016-01-29: NUMPY_UFUNC_DISABLED return class A(object): def __numpy_ufunc__(self, ufunc, method, pos, inputs, **kwargs): return self, ufunc, method, pos, inputs, kwargs # __call__ a = A() res = np.multiply.__call__(1, a, foo='bar', answer=42) assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], '__call__') assert_equal(res[3], 1) assert_equal(res[4], (1, a)) assert_equal(res[5], {'foo': 'bar', 'answer': 42}) # reduce, positional args res = np.multiply.reduce(a, 'axis0', 'dtype0', 'out0', 'keep0') assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'reduce') assert_equal(res[3], 0) assert_equal(res[4], (a,)) assert_equal(res[5], {'dtype':'dtype0', 'out': 'out0', 'keepdims': 'keep0', 'axis': 'axis0'}) # reduce, kwargs res = np.multiply.reduce(a, axis='axis0', dtype='dtype0', out='out0', keepdims='keep0') assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'reduce') assert_equal(res[3], 0) assert_equal(res[4], (a,)) assert_equal(res[5], {'dtype':'dtype0', 'out': 'out0', 'keepdims': 'keep0', 'axis': 'axis0'}) # accumulate, pos args res = np.multiply.accumulate(a, 'axis0', 'dtype0', 'out0') assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'accumulate') assert_equal(res[3], 0) assert_equal(res[4], (a,)) assert_equal(res[5], {'dtype':'dtype0', 'out': 'out0', 'axis': 'axis0'}) # accumulate, kwargs res = np.multiply.accumulate(a, axis='axis0', dtype='dtype0', out='out0') assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'accumulate') assert_equal(res[3], 0) assert_equal(res[4], (a,)) assert_equal(res[5], {'dtype':'dtype0', 'out': 'out0', 'axis': 'axis0'}) # reduceat, pos args res = np.multiply.reduceat(a, [4, 2], 'axis0', 'dtype0', 'out0') assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'reduceat') assert_equal(res[3], 0) assert_equal(res[4], (a, [4, 2])) assert_equal(res[5], {'dtype':'dtype0', 'out': 'out0', 'axis': 'axis0'}) # reduceat, kwargs res = np.multiply.reduceat(a, [4, 2], axis='axis0', dtype='dtype0', out='out0') assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'reduceat') assert_equal(res[3], 0) assert_equal(res[4], (a, [4, 2])) assert_equal(res[5], {'dtype':'dtype0', 'out': 'out0', 'axis': 'axis0'}) # outer res = np.multiply.outer(a, 42) assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'outer') assert_equal(res[3], 0) assert_equal(res[4], (a, 42)) assert_equal(res[5], {}) # at res = np.multiply.at(a, [4, 2], 'b0') assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'at') assert_equal(res[3], 0) assert_equal(res[4], (a, [4, 2], 'b0')) def test_ufunc_override_out(self): # 2016-01-29: NUMPY_UFUNC_DISABLED return class A(object): def __numpy_ufunc__(self, ufunc, method, pos, inputs, **kwargs): return kwargs class B(object): def __numpy_ufunc__(self, ufunc, method, pos, inputs, **kwargs): return kwargs a = A() b = B() res0 = np.multiply(a, b, 'out_arg') res1 = np.multiply(a, b, out='out_arg') res2 = np.multiply(2, b, 'out_arg') res3 = np.multiply(3, b, out='out_arg') res4 = np.multiply(a, 4, 'out_arg') res5 = np.multiply(a, 5, out='out_arg') assert_equal(res0['out'], 'out_arg') assert_equal(res1['out'], 'out_arg') assert_equal(res2['out'], 'out_arg') assert_equal(res3['out'], 'out_arg') assert_equal(res4['out'], 'out_arg') assert_equal(res5['out'], 'out_arg') # ufuncs with multiple output modf and frexp. res6 = np.modf(a, 'out0', 'out1') res7 = np.frexp(a, 'out0', 'out1') assert_equal(res6['out'][0], 'out0') assert_equal(res6['out'][1], 'out1') assert_equal(res7['out'][0], 'out0') assert_equal(res7['out'][1], 'out1') def test_ufunc_override_exception(self): # 2016-01-29: NUMPY_UFUNC_DISABLED return class A(object): def __numpy_ufunc__(self, *a, **kwargs): raise ValueError("oops") a = A() for func in [np.divide, np.dot]: assert_raises(ValueError, func, a, a) class TestChoose(TestCase): def test_mixed(self): c = np.array([True, True]) a = np.array([True, True]) assert_equal(np.choose(c, (a, 1)), np.array([1, 1])) def is_longdouble_finfo_bogus(): info = np.finfo(np.longcomplex) return not np.isfinite(np.log10(info.tiny/info.eps)) class TestComplexFunctions(object): funcs = [np.arcsin, np.arccos, np.arctan, np.arcsinh, np.arccosh, np.arctanh, np.sin, np.cos, np.tan, np.exp, np.exp2, np.log, np.sqrt, np.log10, np.log2, np.log1p] def test_it(self): for f in self.funcs: if f is np.arccosh: x = 1.5 else: x = .5 fr = f(x) fz = f(np.complex(x)) assert_almost_equal(fz.real, fr, err_msg='real part %s' % f) assert_almost_equal(fz.imag, 0., err_msg='imag part %s' % f) def test_precisions_consistent(self): z = 1 + 1j for f in self.funcs: fcf = f(np.csingle(z)) fcd = f(np.cdouble(z)) fcl = f(np.clongdouble(z)) assert_almost_equal(fcf, fcd, decimal=6, err_msg='fch-fcd %s' % f) assert_almost_equal(fcl, fcd, decimal=15, err_msg='fch-fcl %s' % f) def test_branch_cuts(self): # check branch cuts and continuity on them yield _check_branch_cut, np.log, -0.5, 1j, 1, -1, True yield _check_branch_cut, np.log2, -0.5, 1j, 1, -1, True yield _check_branch_cut, np.log10, -0.5, 1j, 1, -1, True yield _check_branch_cut, np.log1p, -1.5, 1j, 1, -1, True yield _check_branch_cut, np.sqrt, -0.5, 1j, 1, -1, True yield _check_branch_cut, np.arcsin, [ -2, 2], [1j, 1j], 1, -1, True yield _check_branch_cut, np.arccos, [ -2, 2], [1j, 1j], 1, -1, True yield _check_branch_cut, np.arctan, [0-2j, 2j], [1, 1], -1, 1, True yield _check_branch_cut, np.arcsinh, [0-2j, 2j], [1, 1], -1, 1, True yield _check_branch_cut, np.arccosh, [ -1, 0.5], [1j, 1j], 1, -1, True yield _check_branch_cut, np.arctanh, [ -2, 2], [1j, 1j], 1, -1, True # check against bogus branch cuts: assert continuity between quadrants yield _check_branch_cut, np.arcsin, [0-2j, 2j], [ 1, 1], 1, 1 yield _check_branch_cut, np.arccos, [0-2j, 2j], [ 1, 1], 1, 1 yield _check_branch_cut, np.arctan, [ -2, 2], [1j, 1j], 1, 1 yield _check_branch_cut, np.arcsinh, [ -2, 2, 0], [1j, 1j, 1], 1, 1 yield _check_branch_cut, np.arccosh, [0-2j, 2j, 2], [1, 1, 1j], 1, 1 yield _check_branch_cut, np.arctanh, [0-2j, 2j, 0], [1, 1, 1j], 1, 1 def test_branch_cuts_complex64(self): # check branch cuts and continuity on them yield _check_branch_cut, np.log, -0.5, 1j, 1, -1, True, np.complex64 yield _check_branch_cut, np.log2, -0.5, 1j, 1, -1, True, np.complex64 yield _check_branch_cut, np.log10, -0.5, 1j, 1, -1, True, np.complex64 yield _check_branch_cut, np.log1p, -1.5, 1j, 1, -1, True, np.complex64 yield _check_branch_cut, np.sqrt, -0.5, 1j, 1, -1, True, np.complex64 yield _check_branch_cut, np.arcsin, [ -2, 2], [1j, 1j], 1, -1, True, np.complex64 yield _check_branch_cut, np.arccos, [ -2, 2], [1j, 1j], 1, -1, True, np.complex64 yield _check_branch_cut, np.arctan, [0-2j, 2j], [1, 1], -1, 1, True, np.complex64 yield _check_branch_cut, np.arcsinh, [0-2j, 2j], [1, 1], -1, 1, True, np.complex64 yield _check_branch_cut, np.arccosh, [ -1, 0.5], [1j, 1j], 1, -1, True, np.complex64 yield _check_branch_cut, np.arctanh, [ -2, 2], [1j, 1j], 1, -1, True, np.complex64 # check against bogus branch cuts: assert continuity between quadrants yield _check_branch_cut, np.arcsin, [0-2j, 2j], [ 1, 1], 1, 1, False, np.complex64 yield _check_branch_cut, np.arccos, [0-2j, 2j], [ 1, 1], 1, 1, False, np.complex64 yield _check_branch_cut, np.arctan, [ -2, 2], [1j, 1j], 1, 1, False, np.complex64 yield _check_branch_cut, np.arcsinh, [ -2, 2, 0], [1j, 1j, 1], 1, 1, False, np.complex64 yield _check_branch_cut, np.arccosh, [0-2j, 2j, 2], [1, 1, 1j], 1, 1, False, np.complex64 yield _check_branch_cut, np.arctanh, [0-2j, 2j, 0], [1, 1, 1j], 1, 1, False, np.complex64 def test_against_cmath(self): import cmath points = [-1-1j, -1+1j, +1-1j, +1+1j] name_map = {'arcsin': 'asin', 'arccos': 'acos', 'arctan': 'atan', 'arcsinh': 'asinh', 'arccosh': 'acosh', 'arctanh': 'atanh'} atol = 4*np.finfo(np.complex).eps for func in self.funcs: fname = func.__name__.split('.')[-1] cname = name_map.get(fname, fname) try: cfunc = getattr(cmath, cname) except AttributeError: continue for p in points: a = complex(func(np.complex_(p))) b = cfunc(p) assert_(abs(a - b) < atol, "%s %s: %s; cmath: %s" % (fname, p, a, b)) def check_loss_of_precision(self, dtype): """Check loss of precision in complex arc* functions""" # Check against known-good functions info = np.finfo(dtype) real_dtype = dtype(0.).real.dtype eps = info.eps def check(x, rtol): x = x.astype(real_dtype) z = x.astype(dtype) d = np.absolute(np.arcsinh(x)/np.arcsinh(z).real - 1) assert_(np.all(d < rtol), (np.argmax(d), x[np.argmax(d)], d.max(), 'arcsinh')) z = (1j*x).astype(dtype) d = np.absolute(np.arcsinh(x)/np.arcsin(z).imag - 1) assert_(np.all(d < rtol), (np.argmax(d), x[np.argmax(d)], d.max(), 'arcsin')) z = x.astype(dtype) d = np.absolute(np.arctanh(x)/np.arctanh(z).real - 1) assert_(np.all(d < rtol), (np.argmax(d), x[np.argmax(d)], d.max(), 'arctanh')) z = (1j*x).astype(dtype) d = np.absolute(np.arctanh(x)/np.arctan(z).imag - 1) assert_(np.all(d < rtol), (np.argmax(d), x[np.argmax(d)], d.max(), 'arctan')) # The switchover was chosen as 1e-3; hence there can be up to # ~eps/1e-3 of relative cancellation error before it x_series = np.logspace(-20, -3.001, 200) x_basic = np.logspace(-2.999, 0, 10, endpoint=False) if dtype is np.longcomplex: # It's not guaranteed that the system-provided arc functions # are accurate down to a few epsilons. (Eg. on Linux 64-bit) # So, give more leeway for long complex tests here: check(x_series, 50*eps) else: check(x_series, 2.1*eps) check(x_basic, 2*eps/1e-3) # Check a few points z = np.array([1e-5*(1+1j)], dtype=dtype) p = 9.999999999333333333e-6 + 1.000000000066666666e-5j d = np.absolute(1-np.arctanh(z)/p) assert_(np.all(d < 1e-15)) p = 1.0000000000333333333e-5 + 9.999999999666666667e-6j d = np.absolute(1-np.arcsinh(z)/p) assert_(np.all(d < 1e-15)) p = 9.999999999333333333e-6j + 1.000000000066666666e-5 d = np.absolute(1-np.arctan(z)/p) assert_(np.all(d < 1e-15)) p = 1.0000000000333333333e-5j + 9.999999999666666667e-6 d = np.absolute(1-np.arcsin(z)/p) assert_(np.all(d < 1e-15)) # Check continuity across switchover points def check(func, z0, d=1): z0 = np.asarray(z0, dtype=dtype) zp = z0 + abs(z0) * d * eps * 2 zm = z0 - abs(z0) * d * eps * 2 assert_(np.all(zp != zm), (zp, zm)) # NB: the cancellation error at the switchover is at least eps good = (abs(func(zp) - func(zm)) < 2*eps) assert_(np.all(good), (func, z0[~good])) for func in (np.arcsinh, np.arcsinh, np.arcsin, np.arctanh, np.arctan): pts = [rp+1j*ip for rp in (-1e-3, 0, 1e-3) for ip in(-1e-3, 0, 1e-3) if rp != 0 or ip != 0] check(func, pts, 1) check(func, pts, 1j) check(func, pts, 1+1j) def test_loss_of_precision(self): for dtype in [np.complex64, np.complex_]: yield self.check_loss_of_precision, dtype @dec.knownfailureif(is_longdouble_finfo_bogus(), "Bogus long double finfo") def test_loss_of_precision_longcomplex(self): self.check_loss_of_precision(np.longcomplex) class TestAttributes(TestCase): def test_attributes(self): add = ncu.add assert_equal(add.__name__, 'add') assert_(add.__doc__.startswith('add(x1, x2[, out])\n\n')) self.assertTrue(add.ntypes >= 18) # don't fail if types added self.assertTrue('ii->i' in add.types) assert_equal(add.nin, 2) assert_equal(add.nout, 1) assert_equal(add.identity, 0) class TestSubclass(TestCase): def test_subclass_op(self): class simple(np.ndarray): def __new__(subtype, shape): self = np.ndarray.__new__(subtype, shape, dtype=object) self.fill(0) return self a = simple((3, 4)) assert_equal(a+a, a) def _check_branch_cut(f, x0, dx, re_sign=1, im_sign=-1, sig_zero_ok=False, dtype=np.complex): """ Check for a branch cut in a function. Assert that `x0` lies on a branch cut of function `f` and `f` is continuous from the direction `dx`. Parameters ---------- f : func Function to check x0 : array-like Point on branch cut dx : array-like Direction to check continuity in re_sign, im_sign : {1, -1} Change of sign of the real or imaginary part expected sig_zero_ok : bool Whether to check if the branch cut respects signed zero (if applicable) dtype : dtype Dtype to check (should be complex) """ x0 = np.atleast_1d(x0).astype(dtype) dx = np.atleast_1d(dx).astype(dtype) if np.dtype(dtype).char == 'F': scale = np.finfo(dtype).eps * 1e2 atol = np.float32(1e-2) else: scale = np.finfo(dtype).eps * 1e3 atol = 1e-4 y0 = f(x0) yp = f(x0 + dx*scale*np.absolute(x0)/np.absolute(dx)) ym = f(x0 - dx*scale*np.absolute(x0)/np.absolute(dx)) assert_(np.all(np.absolute(y0.real - yp.real) < atol), (y0, yp)) assert_(np.all(np.absolute(y0.imag - yp.imag) < atol), (y0, yp)) assert_(np.all(np.absolute(y0.real - ym.real*re_sign) < atol), (y0, ym)) assert_(np.all(np.absolute(y0.imag - ym.imag*im_sign) < atol), (y0, ym)) if sig_zero_ok: # check that signed zeros also work as a displacement jr = (x0.real == 0) & (dx.real != 0) ji = (x0.imag == 0) & (dx.imag != 0) if np.any(jr): x = x0[jr] x.real = np.NZERO ym = f(x) assert_(np.all(np.absolute(y0[jr].real - ym.real*re_sign) < atol), (y0[jr], ym)) assert_(np.all(np.absolute(y0[jr].imag - ym.imag*im_sign) < atol), (y0[jr], ym)) if np.any(ji): x = x0[ji] x.imag = np.NZERO ym = f(x) assert_(np.all(np.absolute(y0[ji].real - ym.real*re_sign) < atol), (y0[ji], ym)) assert_(np.all(np.absolute(y0[ji].imag - ym.imag*im_sign) < atol), (y0[ji], ym)) def test_copysign(): assert_(np.copysign(1, -1) == -1) with np.errstate(divide="ignore"): assert_(1 / np.copysign(0, -1) < 0) assert_(1 / np.copysign(0, 1) > 0) assert_(np.signbit(np.copysign(np.nan, -1))) assert_(not np.signbit(np.copysign(np.nan, 1))) def _test_nextafter(t): one = t(1) two = t(2) zero = t(0) eps = np.finfo(t).eps assert_(np.nextafter(one, two) - one == eps) assert_(np.nextafter(one, zero) - one < 0) assert_(np.isnan(np.nextafter(np.nan, one))) assert_(np.isnan(np.nextafter(one, np.nan))) assert_(np.nextafter(one, one) == one) def test_nextafter(): return _test_nextafter(np.float64) def test_nextafterf(): return _test_nextafter(np.float32) @dec.knownfailureif(sys.platform == 'win32' or on_powerpc(), "Long double support buggy on win32 and PPC, ticket 1664.") def test_nextafterl(): return _test_nextafter(np.longdouble) def _test_spacing(t): one = t(1) eps = np.finfo(t).eps nan = t(np.nan) inf = t(np.inf) with np.errstate(invalid='ignore'): assert_(np.spacing(one) == eps) assert_(np.isnan(np.spacing(nan))) assert_(np.isnan(np.spacing(inf))) assert_(np.isnan(np.spacing(-inf))) assert_(np.spacing(t(1e30)) != 0) def test_spacing(): return _test_spacing(np.float64) def test_spacingf(): return _test_spacing(np.float32) @dec.knownfailureif(sys.platform == 'win32' or on_powerpc(), "Long double support buggy on win32 and PPC, ticket 1664.") def test_spacingl(): return _test_spacing(np.longdouble) def test_spacing_gfortran(): # Reference from this fortran file, built with gfortran 4.3.3 on linux # 32bits: # PROGRAM test_spacing # INTEGER, PARAMETER :: SGL = SELECTED_REAL_KIND(p=6, r=37) # INTEGER, PARAMETER :: DBL = SELECTED_REAL_KIND(p=13, r=200) # # WRITE(*,*) spacing(0.00001_DBL) # WRITE(*,*) spacing(1.0_DBL) # WRITE(*,*) spacing(1000._DBL) # WRITE(*,*) spacing(10500._DBL) # # WRITE(*,*) spacing(0.00001_SGL) # WRITE(*,*) spacing(1.0_SGL) # WRITE(*,*) spacing(1000._SGL) # WRITE(*,*) spacing(10500._SGL) # END PROGRAM ref = {np.float64: [1.69406589450860068E-021, 2.22044604925031308E-016, 1.13686837721616030E-013, 1.81898940354585648E-012], np.float32: [9.09494702E-13, 1.19209290E-07, 6.10351563E-05, 9.76562500E-04]} for dt, dec_ in zip([np.float32, np.float64], (10, 20)): x = np.array([1e-5, 1, 1000, 10500], dtype=dt) assert_array_almost_equal(np.spacing(x), ref[dt], decimal=dec_) def test_nextafter_vs_spacing(): # XXX: spacing does not handle long double yet for t in [np.float32, np.float64]: for _f in [1, 1e-5, 1000]: f = t(_f) f1 = t(_f + 1) assert_(np.nextafter(f, f1) - f == np.spacing(f)) def test_pos_nan(): """Check np.nan is a positive nan.""" assert_(np.signbit(np.nan) == 0) def test_reduceat(): """Test bug in reduceat when structured arrays are not copied.""" db = np.dtype([('name', 'S11'), ('time', np.int64), ('value', np.float32)]) a = np.empty([100], dtype=db) a['name'] = 'Simple' a['time'] = 10 a['value'] = 100 indx = [0, 7, 15, 25] h2 = [] val1 = indx[0] for val2 in indx[1:]: h2.append(np.add.reduce(a['value'][val1:val2])) val1 = val2 h2.append(np.add.reduce(a['value'][val1:])) h2 = np.array(h2) # test buffered -- this should work h1 = np.add.reduceat(a['value'], indx) assert_array_almost_equal(h1, h2) # This is when the error occurs. # test no buffer np.setbufsize(32) h1 = np.add.reduceat(a['value'], indx) np.setbufsize(np.UFUNC_BUFSIZE_DEFAULT) assert_array_almost_equal(h1, h2) def test_reduceat_empty(): """Reduceat should work with empty arrays""" indices = np.array([], 'i4') x = np.array([], 'f8') result = np.add.reduceat(x, indices) assert_equal(result.dtype, x.dtype) assert_equal(result.shape, (0,)) # Another case with a slightly different zero-sized shape x = np.ones((5, 2)) result = np.add.reduceat(x, [], axis=0) assert_equal(result.dtype, x.dtype) assert_equal(result.shape, (0, 2)) result = np.add.reduceat(x, [], axis=1) assert_equal(result.dtype, x.dtype) assert_equal(result.shape, (5, 0)) def test_complex_nan_comparisons(): nans = [complex(np.nan, 0), complex(0, np.nan), complex(np.nan, np.nan)] fins = [complex(1, 0), complex(-1, 0), complex(0, 1), complex(0, -1), complex(1, 1), complex(-1, -1), complex(0, 0)] with np.errstate(invalid='ignore'): for x in nans + fins: x = np.array([x]) for y in nans + fins: y = np.array([y]) if np.isfinite(x) and np.isfinite(y): continue assert_equal(x < y, False, err_msg="%r < %r" % (x, y)) assert_equal(x > y, False, err_msg="%r > %r" % (x, y)) assert_equal(x <= y, False, err_msg="%r <= %r" % (x, y)) assert_equal(x >= y, False, err_msg="%r >= %r" % (x, y)) assert_equal(x == y, False, err_msg="%r == %r" % (x, y)) def test_rint_big_int(): # np.rint bug for large integer values on Windows 32-bit and MKL # https://github.com/numpy/numpy/issues/6685 val = 4607998452777363968 # This is exactly representable in floating point assert_equal(val, int(float(val))) # Rint should not change the value assert_equal(val, np.rint(val)) if __name__ == "__main__": run_module_suite()