from __future__ import division, absolute_import, print_function import platform import warnings import fnmatch import itertools import pytest import numpy.core.umath as ncu from numpy.core import _umath_tests as ncu_tests import numpy as np from numpy.testing import ( assert_, assert_equal, assert_raises, assert_raises_regex, assert_array_equal, assert_almost_equal, assert_array_almost_equal, assert_allclose, assert_no_warnings, suppress_warnings, _gen_alignment_data ) 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(object): 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(object): 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 TestComparisons(object): def test_ignore_object_identity_in_equal(self): # Check error raised when comparing identical objects whose comparison # is not a simple boolean, e.g., arrays that are compared elementwise. a = np.array([np.array([1, 2, 3]), None], dtype=object) assert_raises(ValueError, np.equal, a, a) # Check error raised when comparing identical non-comparable objects. class FunkyType(object): def __eq__(self, other): raise TypeError("I won't compare") a = np.array([FunkyType()]) assert_raises(TypeError, np.equal, a, a) # Check identity doesn't override comparison mismatch. a = np.array([np.nan], dtype=object) assert_equal(np.equal(a, a), [False]) def test_ignore_object_identity_in_not_equal(self): # Check error raised when comparing identical objects whose comparison # is not a simple boolean, e.g., arrays that are compared elementwise. a = np.array([np.array([1, 2, 3]), None], dtype=object) assert_raises(ValueError, np.not_equal, a, a) # Check error raised when comparing identical non-comparable objects. class FunkyType(object): def __ne__(self, other): raise TypeError("I won't compare") a = np.array([FunkyType()]) assert_raises(TypeError, np.not_equal, a, a) # Check identity doesn't override comparison mismatch. a = np.array([np.nan], dtype=object) assert_equal(np.not_equal(a, a), [True]) class TestAdd(object): def test_reduce_alignment(self): # gh-9876 # make sure arrays with weird strides work with the optimizations in # pairwise_sum_@TYPE@. On x86, the 'b' field will count as aligned at a # 4 byte offset, even though its itemsize is 8. a = np.zeros(2, dtype=[('a', np.int32), ('b', np.float64)]) a['a'] = -1 assert_equal(a['b'].sum(), 0) class TestDivision(object): 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) def test_floor_division_signed_zero(self): # Check that the sign bit is correctly set when dividing positive and # negative zero by one. x = np.zeros(10) assert_equal(np.signbit(x//1), 0) assert_equal(np.signbit((-x)//1), 1) def floor_divide_and_remainder(x, y): return (np.floor_divide(x, y), np.remainder(x, y)) def _signs(dt): if dt in np.typecodes['UnsignedInteger']: return (+1,) else: return (+1, -1) class TestRemainder(object): def test_remainder_basic(self): dt = np.typecodes['AllInteger'] + np.typecodes['Float'] for op in [floor_divide_and_remainder, np.divmod]: for dt1, dt2 in itertools.product(dt, dt): for sg1, sg2 in itertools.product(_signs(dt1), _signs(dt2)): fmt = 'op: %s, dt1: %s, dt2: %s, sg1: %s, sg2: %s' msg = fmt % (op.__name__, dt1, dt2, sg1, sg2) a = np.array(sg1*71, dtype=dt1) b = np.array(sg2*19, dtype=dt2) div, rem = op(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 op in [floor_divide_and_remainder, np.divmod]: for dt in np.typecodes['Float']: msg = 'op: %s, dtype: %s' % (op.__name__, dt) fa = a.astype(dt) fb = b.astype(dt) div, rem = op(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 op in [floor_divide_and_remainder, np.divmod]: for dt1, dt2 in itertools.product(dt, dt): for sg1, sg2 in itertools.product((+1, -1), (+1, -1)): fmt = 'op: %s, dt1: %s, dt2: %s, sg1: %s, sg2: %s' msg = fmt % (op.__name__, dt1, dt2, sg1, sg2) a = np.array(sg1*78*6e-8, dtype=dt1) b = np.array(sg2*6e-8, dtype=dt2) div, rem = op(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 suppress_warnings() as sup: sup.filter(RuntimeWarning, "invalid value encountered in remainder") 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(object): 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(object): 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) res = x**2.0 assert_((x**2.00001).dtype is res.dtype) assert_array_equal(res, [1, 4, 9]) # check the inplace operation on the casted copy doesn't mess with x assert_(not np.may_share_memory(res, x)) assert_array_equal(x, [1, 2, 3]) # Check that the fast path ignores 1-element not 0-d arrays res = x ** np.array([[[2]]]) assert_equal(res.shape, (1, 1, 3)) def test_integer_power(self): a = np.array([15, 15], 'i8') b = np.power(a, a) assert_equal(b, [437893890380859375, 437893890380859375]) def test_integer_power_with_integer_zero_exponent(self): dtypes = np.typecodes['Integer'] for dt in dtypes: arr = np.arange(-10, 10, dtype=dt) assert_equal(np.power(arr, 0), np.ones_like(arr)) dtypes = np.typecodes['UnsignedInteger'] for dt in dtypes: arr = np.arange(10, dtype=dt) assert_equal(np.power(arr, 0), np.ones_like(arr)) def test_integer_power_of_1(self): dtypes = np.typecodes['AllInteger'] for dt in dtypes: arr = np.arange(10, dtype=dt) assert_equal(np.power(1, arr), np.ones_like(arr)) def test_integer_power_of_zero(self): dtypes = np.typecodes['AllInteger'] for dt in dtypes: arr = np.arange(1, 10, dtype=dt) assert_equal(np.power(0, arr), np.zeros_like(arr)) def test_integer_to_negative_power(self): dtypes = np.typecodes['Integer'] for dt in dtypes: a = np.array([0, 1, 2, 3], dtype=dt) b = np.array([0, 1, 2, -3], dtype=dt) one = np.array(1, dtype=dt) minusone = np.array(-1, dtype=dt) assert_raises(ValueError, np.power, a, b) assert_raises(ValueError, np.power, a, minusone) assert_raises(ValueError, np.power, one, b) assert_raises(ValueError, np.power, one, minusone) class TestFloat_power(object): def test_type_conversion(self): arg_type = '?bhilBHILefdgFDG' res_type = 'ddddddddddddgDDG' for dtin, dtout in zip(arg_type, res_type): msg = "dtin: %s, dtout: %s" % (dtin, dtout) arg = np.ones(1, dtype=dtin) res = np.float_power(arg, arg) assert_(res.dtype.name == np.dtype(dtout).name, msg) class TestLog2(object): 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(object): 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(object): 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(object): 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))) def test_reduce(self): assert_equal(np.logaddexp.identity, -np.inf) assert_equal(np.logaddexp.reduce([]), -np.inf) class TestLog1p(object): 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(object): 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(object): def test_simple(self): assert_almost_equal(ncu.hypot(1, 1), ncu.sqrt(2)) assert_almost_equal(ncu.hypot(0, 0), 0) def test_reduce(self): assert_almost_equal(ncu.hypot.reduce([3.0, 4.0]), 5.0) assert_almost_equal(ncu.hypot.reduce([3.0, 4.0, 0]), 5.0) assert_almost_equal(ncu.hypot.reduce([9.0, 12.0, 20.0]), 25.0) assert_equal(ncu.hypot.reduce([]), 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(object): 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(object): 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(object): 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'), object) y = 1.0 z = np.array(float('nan'), 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=complex) arg2 = np.array([cnan, 0, cnan], dtype=complex) out = np.array([nan, nan, nan], dtype=complex) assert_equal(np.maximum(arg1, arg2), out) def test_object_array(self): arg1 = np.arange(5, dtype=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'), object) y = 1.0 z = np.array(float('nan'), 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=complex) arg2 = np.array([cnan, 0, cnan], dtype=complex) out = np.array([nan, nan, nan], dtype=complex) assert_equal(np.minimum(arg1, arg2), out) def test_object_array(self): arg1 = np.arange(5, dtype=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=complex) arg2 = np.array([cnan, 0, cnan], dtype=complex) out = np.array([0, 0, nan], dtype=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=complex) arg2 = np.array([cnan, 0, cnan], dtype=complex) out = np.array([0, 0, nan], dtype=complex) assert_equal(np.fmin(arg1, arg2), out) class TestBool(object): def test_exceptions(self): a = np.ones(1, dtype=np.bool_) assert_raises(TypeError, np.negative, a) assert_raises(TypeError, np.positive, a) assert_raises(TypeError, np.subtract, a, a) 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) def test_reduce(self): none = np.array([0, 0, 0, 0], bool) some = np.array([1, 0, 1, 1], bool) every = np.array([1, 1, 1, 1], bool) empty = np.array([], bool) arrs = [none, some, every, empty] for arr in arrs: assert_equal(np.logical_and.reduce(arr), all(arr)) for arr in arrs: assert_equal(np.logical_or.reduce(arr), any(arr)) for arr in arrs: assert_equal(np.logical_xor.reduce(arr), arr.sum() % 2 == 1) class TestBitwiseUFuncs(object): bitwise_types = [np.dtype(c) for c in '?' + 'bBhHiIlLqQ' + 'O'] def test_values(self): for dt in self.bitwise_types: zeros = np.array([0], dtype=dt) ones = np.array([-1], dtype=dt) msg = "dt = '%s'" % dt.char assert_equal(np.bitwise_not(zeros), ones, err_msg=msg) assert_equal(np.bitwise_not(ones), zeros, err_msg=msg) assert_equal(np.bitwise_or(zeros, zeros), zeros, err_msg=msg) assert_equal(np.bitwise_or(zeros, ones), ones, err_msg=msg) assert_equal(np.bitwise_or(ones, zeros), ones, err_msg=msg) assert_equal(np.bitwise_or(ones, ones), ones, err_msg=msg) assert_equal(np.bitwise_xor(zeros, zeros), zeros, err_msg=msg) assert_equal(np.bitwise_xor(zeros, ones), ones, err_msg=msg) assert_equal(np.bitwise_xor(ones, zeros), ones, err_msg=msg) assert_equal(np.bitwise_xor(ones, ones), zeros, err_msg=msg) assert_equal(np.bitwise_and(zeros, zeros), zeros, err_msg=msg) assert_equal(np.bitwise_and(zeros, ones), zeros, err_msg=msg) assert_equal(np.bitwise_and(ones, zeros), zeros, err_msg=msg) assert_equal(np.bitwise_and(ones, ones), ones, err_msg=msg) def test_types(self): for dt in self.bitwise_types: zeros = np.array([0], dtype=dt) ones = np.array([-1], dtype=dt) msg = "dt = '%s'" % dt.char assert_(np.bitwise_not(zeros).dtype == dt, msg) assert_(np.bitwise_or(zeros, zeros).dtype == dt, msg) assert_(np.bitwise_xor(zeros, zeros).dtype == dt, msg) assert_(np.bitwise_and(zeros, zeros).dtype == dt, msg) def test_identity(self): assert_(np.bitwise_or.identity == 0, 'bitwise_or') assert_(np.bitwise_xor.identity == 0, 'bitwise_xor') assert_(np.bitwise_and.identity == -1, 'bitwise_and') def test_reduction(self): binary_funcs = (np.bitwise_or, np.bitwise_xor, np.bitwise_and) for dt in self.bitwise_types: zeros = np.array([0], dtype=dt) ones = np.array([-1], dtype=dt) for f in binary_funcs: msg = "dt: '%s', f: '%s'" % (dt, f) assert_equal(f.reduce(zeros), zeros, err_msg=msg) assert_equal(f.reduce(ones), ones, err_msg=msg) # Test empty reduction, no object dtype for dt in self.bitwise_types[:-1]: # No object array types empty = np.array([], dtype=dt) for f in binary_funcs: msg = "dt: '%s', f: '%s'" % (dt, f) tgt = np.array(f.identity, dtype=dt) res = f.reduce(empty) assert_equal(res, tgt, err_msg=msg) assert_(res.dtype == tgt.dtype, msg) # Empty object arrays use the identity. Note that the types may # differ, the actual type used is determined by the assign_identity # function and is not the same as the type returned by the identity # method. for f in binary_funcs: msg = "dt: '%s'" % (f,) empty = np.array([], dtype=object) tgt = f.identity res = f.reduce(empty) assert_equal(res, tgt, err_msg=msg) # Non-empty object arrays do not use the identity for f in binary_funcs: msg = "dt: '%s'" % (f,) btype = np.array([True], dtype=object) assert_(type(f.reduce(btype)) is bool, msg) class TestInt(object): def test_logical_not(self): x = np.ones(10, dtype=np.int16) o = np.ones(10 * 2, dtype=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(object): def test_floating_point(self): assert_equal(ncu.FLOATING_POINT_SUPPORT, 1) class TestDegrees(object): 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(object): 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 TestHeavside(object): def test_heaviside(self): x = np.array([[-30.0, -0.1, 0.0, 0.2], [7.5, np.nan, np.inf, -np.inf]]) expectedhalf = np.array([[0.0, 0.0, 0.5, 1.0], [1.0, np.nan, 1.0, 0.0]]) expected1 = expectedhalf.copy() expected1[0, 2] = 1 h = ncu.heaviside(x, 0.5) assert_equal(h, expectedhalf) h = ncu.heaviside(x, 1.0) assert_equal(h, expected1) x = x.astype(np.float32) h = ncu.heaviside(x, np.float32(0.5)) assert_equal(h, expectedhalf.astype(np.float32)) h = ncu.heaviside(x, np.float32(1.0)) assert_equal(h, expected1.astype(np.float32)) class TestSign(object): 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(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]) # FIXME: a not used a = np.sign(foo.astype(object)) assert_raises(TypeError, test_nan) class TestMinMax(object): 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) with suppress_warnings() as sup: sup.filter(RuntimeWarning, "invalid value encountered in reduce") 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]) def test_reduce_reorder(self): # gh 10370, 11029 Some compilers reorder the call to npy_getfloatstatus # and put it before the call to an intrisic function that causes # invalid status to be set. Also make sure warnings are not emitted for n in (2, 4, 8, 16, 32): for dt in (np.float32, np.float16, np.complex64): for r in np.diagflat(np.array([np.nan] * n, dtype=dt)): assert_equal(np.min(r), np.nan) def test_minimize_no_warns(self): a = np.minimum(np.nan, 1) assert_equal(a, np.nan) class TestAbsoluteNegative(object): 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) assert_((out >= 0).all()) tgt = [-1*(i) for i in inp] np.negative(inp, out=out) assert_equal(out, tgt, err_msg=msg) 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) d = -1 * inp np.negative(inp, out=out) assert_array_equal(out, d, 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 TestPositive(object): def test_valid(self): valid_dtypes = [int, float, complex, object] for dtype in valid_dtypes: x = np.arange(5, dtype=dtype) result = np.positive(x) assert_equal(x, result, err_msg=str(dtype)) def test_invalid(self): with assert_raises(TypeError): np.positive(True) with assert_raises(TypeError): np.positive(np.datetime64('2000-01-01')) with assert_raises(TypeError): np.positive(np.array(['foo'], dtype=str)) with assert_raises(TypeError): np.positive(np.array(['bar'], dtype=object)) class TestSpecialMethods(object): 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 assert_(func is ncu.minimum) assert_equal(len(args), 2) assert_equal(args[0], a) assert_equal(args[1], a) assert_equal(i, 0) def test_wrap_and_prepare_out(self): # Calling convention for out should not affect how special methods are # called class StoreArrayPrepareWrap(np.ndarray): _wrap_args = None _prepare_args = None def __new__(cls): return np.empty(()).view(cls) def __array_wrap__(self, obj, context): self._wrap_args = context[1] return obj def __array_prepare__(self, obj, context): self._prepare_args = context[1] return obj @property def args(self): # We need to ensure these are fetched at the same time, before # any other ufuncs are calld by the assertions return (self._prepare_args, self._wrap_args) def __repr__(self): return "a" # for short test output def do_test(f_call, f_expected): a = StoreArrayPrepareWrap() f_call(a) p, w = a.args expected = f_expected(a) try: assert_equal(p, expected) assert_equal(w, expected) except AssertionError as e: # assert_equal produces truly useless error messages raise AssertionError("\n".join([ "Bad arguments passed in ufunc call", " expected: {}".format(expected), " __array_prepare__ got: {}".format(p), " __array_wrap__ got: {}".format(w) ])) # method not on the out argument do_test(lambda a: np.add(a, 0), lambda a: (a, 0)) do_test(lambda a: np.add(a, 0, None), lambda a: (a, 0)) do_test(lambda a: np.add(a, 0, out=None), lambda a: (a, 0)) do_test(lambda a: np.add(a, 0, out=(None,)), lambda a: (a, 0)) # method on the out argument do_test(lambda a: np.add(0, 0, a), lambda a: (0, 0, a)) do_test(lambda a: np.add(0, 0, out=a), lambda a: (0, 0, a)) do_test(lambda a: np.add(0, 0, out=(a,)), lambda a: (0, 0, a)) 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)) assert_(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 assert_(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 assert_(type(f(x, x)) is np.ndarray) assert_(type(f(x, a)) is A) assert_(type(f(x, b)) is B) assert_(type(f(x, c)) is C) assert_(type(f(a, x)) is A) assert_(type(f(b, x)) is B) assert_(type(f(c, x)) is C) assert_(type(f(a, a)) is A) assert_(type(f(a, b)) is B) assert_(type(f(b, a)) is B) assert_(type(f(b, b)) is B) assert_(type(f(b, c)) is C) assert_(type(f(c, b)) is C) assert_(type(f(c, c)) is C) assert_(type(ncu.exp(a) is A)) assert_(type(ncu.exp(b) is B)) assert_(type(ncu.exp(c) is C)) def test_failing_wrap(self): class A(object): def __array__(self): return np.zeros(2) def __array_wrap__(self, arr, context): raise RuntimeError a = A() assert_raises(RuntimeError, ncu.maximum, a, a) assert_raises(RuntimeError, ncu.maximum.reduce, a) def test_failing_out_wrap(self): singleton = np.array([1.0]) class Ok(np.ndarray): def __array_wrap__(self, obj): return singleton class Bad(np.ndarray): def __array_wrap__(self, obj): raise RuntimeError ok = np.empty(1).view(Ok) bad = np.empty(1).view(Bad) # double-free (segfault) of "ok" if "bad" raises an exception for i in range(10): assert_raises(RuntimeError, ncu.frexp, 1, ok, bad) def test_none_wrap(self): # Tests that issue #8507 is resolved. Previously, this would segfault class A(object): def __array__(self): return np.zeros(1) def __array_wrap__(self, arr, context=None): return None a = A() assert_equal(ncu.maximum(a, a), None) 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_prepare_out(self): class with_prepare(np.ndarray): __array_priority__ = 10 def __array_prepare__(self, arr, context): return np.array(arr).view(type=with_prepare) a = np.array([1]).view(type=with_prepare) x = np.add(a, a, a) # Returned array is new, because of the strange # __array_prepare__ above assert_(not np.shares_memory(x, 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() assert_raises(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) assert_(a.func is ncu.maximum) assert_equal(a.args[0], 0) assert_(a.args[1] is a) assert_(a.i == 1) assert_equal(ncu.maximum(a, B()), 0) assert_equal(ncu.maximum(a, C()), 0) def test_ufunc_override(self): # check override works even with instance with high priority. class A(object): def __array_ufunc__(self, func, method, *inputs, **kwargs): return self, func, method, inputs, kwargs class MyNDArray(np.ndarray): __array_priority__ = 100 a = A() b = np.array([1]).view(MyNDArray) res0 = np.multiply(a, b) res1 = np.multiply(b, b, out=a) # self assert_equal(res0[0], a) assert_equal(res1[0], a) assert_equal(res0[1], np.multiply) assert_equal(res1[1], np.multiply) assert_equal(res0[2], '__call__') assert_equal(res1[2], '__call__') assert_equal(res0[3], (a, b)) assert_equal(res1[3], (b, b)) assert_equal(res0[4], {}) assert_equal(res1[4], {'out': (a,)}) def test_ufunc_override_mro(self): # 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 __array_ufunc__(self, func, method, *inputs, **kwargs): return "A" class ASub(A): def __array_ufunc__(self, func, method, *inputs, **kwargs): return "ASub" class B(object): def __array_ufunc__(self, func, method, *inputs, **kwargs): return "B" class C(object): def __init__(self): self.count = 0 def __array_ufunc__(self, func, method, *inputs, **kwargs): self.count += 1 return NotImplemented class CSub(C): def __array_ufunc__(self, func, method, *inputs, **kwargs): self.count += 1 return NotImplemented a = A() a_sub = ASub() b = B() c = C() # 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") assert_equal(c.count, 1) # Check our counter works, so we can trust tests below. res = np.multiply(c, a) assert_equal(c.count, 2) # Both NotImplemented. c = C() c_sub = CSub() assert_raises(TypeError, np.multiply, c, c_sub) assert_equal(c.count, 1) assert_equal(c_sub.count, 1) c.count = c_sub.count = 0 assert_raises(TypeError, np.multiply, c_sub, c) assert_equal(c.count, 1) assert_equal(c_sub.count, 1) c.count = 0 assert_raises(TypeError, np.multiply, c, c) assert_equal(c.count, 1) c.count = 0 assert_raises(TypeError, np.multiply, 2, c) assert_equal(c.count, 1) # 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") c.count = 0 assert_equal(three_mul_ufunc(c, a_sub, 3), "ASub") assert_equal(c.count, 1) c.count = 0 assert_equal(three_mul_ufunc(1, a_sub, c), "ASub") assert_equal(c.count, 0) c.count = 0 assert_equal(three_mul_ufunc(a, b, c), "A") assert_equal(c.count, 0) c_sub.count = 0 assert_equal(three_mul_ufunc(a, b, c_sub), "A") assert_equal(c_sub.count, 0) 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") c = C() c_sub = CSub() assert_raises(TypeError, four_mul_ufunc, 1, 2, 3, c) assert_equal(c.count, 1) c.count = 0 assert_raises(TypeError, four_mul_ufunc, 1, 2, c_sub, c) assert_equal(c_sub.count, 1) assert_equal(c.count, 1) c2 = C() c.count = c_sub.count = 0 assert_raises(TypeError, four_mul_ufunc, 1, c, c_sub, c2) assert_equal(c_sub.count, 1) assert_equal(c.count, 1) assert_equal(c2.count, 0) c.count = c2.count = c_sub.count = 0 assert_raises(TypeError, four_mul_ufunc, c2, c, c_sub, c) assert_equal(c_sub.count, 1) assert_equal(c.count, 0) assert_equal(c2.count, 1) def test_ufunc_override_methods(self): class A(object): def __array_ufunc__(self, ufunc, method, *inputs, **kwargs): return self, ufunc, method, 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, a)) assert_equal(res[4], {'foo': 'bar', 'answer': 42}) # __call__, wrong args assert_raises(TypeError, np.multiply, a) assert_raises(TypeError, np.multiply, a, a, a, a) assert_raises(TypeError, np.multiply, a, a, sig='a', signature='a') assert_raises(TypeError, ncu_tests.inner1d, a, a, axis=0, axes=[0, 0]) # 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], (a,)) assert_equal(res[4], {'dtype':'dtype0', 'out': ('out0',), 'keepdims': 'keep0', 'axis': 'axis0'}) # reduce, kwargs res = np.multiply.reduce(a, axis='axis0', dtype='dtype0', out='out0', keepdims='keep0', initial='init0') assert_equal(res[0], a) assert_equal(res[1], np.multiply) assert_equal(res[2], 'reduce') assert_equal(res[3], (a,)) assert_equal(res[4], {'dtype':'dtype0', 'out': ('out0',), 'keepdims': 'keep0', 'axis': 'axis0', 'initial': 'init0'}) # reduce, output equal to None removed, but not other explicit ones, # even if they are at their default value. res = np.multiply.reduce(a, 0, None, None, False) assert_equal(res[4], {'axis': 0, 'dtype': None, 'keepdims': False}) res = np.multiply.reduce(a, out=None, axis=0, keepdims=True) assert_equal(res[4], {'axis': 0, 'keepdims': True}) res = np.multiply.reduce(a, None, out=(None,), dtype=None) assert_equal(res[4], {'axis': None, 'dtype': None}) res = np.multiply.reduce(a, 0, None, None, False, 2) assert_equal(res[4], {'axis': 0, 'dtype': None, 'keepdims': False, 'initial': 2}) # np._NoValue ignored for initial. res = np.multiply.reduce(a, 0, None, None, False, np._NoValue) assert_equal(res[4], {'axis': 0, 'dtype': None, 'keepdims': False}) # None kept for initial. res = np.multiply.reduce(a, 0, None, None, False, None) assert_equal(res[4], {'axis': 0, 'dtype': None, 'keepdims': False, 'initial': None}) # reduce, wrong args assert_raises(ValueError, np.multiply.reduce, a, out=()) assert_raises(ValueError, np.multiply.reduce, a, out=('out0', 'out1')) assert_raises(TypeError, np.multiply.reduce, a, 'axis0', 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], (a,)) assert_equal(res[4], {'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], (a,)) assert_equal(res[4], {'dtype':'dtype0', 'out': ('out0',), 'axis': 'axis0'}) # accumulate, output equal to None removed. res = np.multiply.accumulate(a, 0, None, None) assert_equal(res[4], {'axis': 0, 'dtype': None}) res = np.multiply.accumulate(a, out=None, axis=0, dtype='dtype1') assert_equal(res[4], {'axis': 0, 'dtype': 'dtype1'}) res = np.multiply.accumulate(a, None, out=(None,), dtype=None) assert_equal(res[4], {'axis': None, 'dtype': None}) # accumulate, wrong args assert_raises(ValueError, np.multiply.accumulate, a, out=()) assert_raises(ValueError, np.multiply.accumulate, a, out=('out0', 'out1')) assert_raises(TypeError, np.multiply.accumulate, a, 'axis0', 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], (a, [4, 2])) assert_equal(res[4], {'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], (a, [4, 2])) assert_equal(res[4], {'dtype':'dtype0', 'out': ('out0',), 'axis': 'axis0'}) # reduceat, output equal to None removed. res = np.multiply.reduceat(a, [4, 2], 0, None, None) assert_equal(res[4], {'axis': 0, 'dtype': None}) res = np.multiply.reduceat(a, [4, 2], axis=None, out=None, dtype='dt') assert_equal(res[4], {'axis': None, 'dtype': 'dt'}) res = np.multiply.reduceat(a, [4, 2], None, None, out=(None,)) assert_equal(res[4], {'axis': None, 'dtype': None}) # reduceat, wrong args assert_raises(ValueError, np.multiply.reduce, a, [4, 2], out=()) assert_raises(ValueError, np.multiply.reduce, a, [4, 2], out=('out0', 'out1')) assert_raises(TypeError, np.multiply.reduce, a, [4, 2], 'axis0', 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], (a, 42)) assert_equal(res[4], {}) # outer, wrong args assert_raises(TypeError, np.multiply.outer, a) assert_raises(TypeError, np.multiply.outer, a, a, a, a) assert_raises(TypeError, np.multiply.outer, a, a, sig='a', signature='a') # 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], (a, [4, 2], 'b0')) # at, wrong args assert_raises(TypeError, np.multiply.at, a) assert_raises(TypeError, np.multiply.at, a, a, a, a) def test_ufunc_override_out(self): class A(object): def __array_ufunc__(self, ufunc, method, *inputs, **kwargs): return kwargs class B(object): def __array_ufunc__(self, ufunc, method, *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'][0], 'out_arg') assert_equal(res1['out'][0], 'out_arg') assert_equal(res2['out'][0], 'out_arg') assert_equal(res3['out'][0], 'out_arg') assert_equal(res4['out'][0], 'out_arg') assert_equal(res5['out'][0], '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') # While we're at it, check that default output is never passed on. assert_(np.sin(a, None) == {}) assert_(np.sin(a, out=None) == {}) assert_(np.sin(a, out=(None,)) == {}) assert_(np.modf(a, None) == {}) assert_(np.modf(a, None, None) == {}) assert_(np.modf(a, out=(None, None)) == {}) with warnings.catch_warnings(record=True) as w: warnings.filterwarnings('always', '', DeprecationWarning) assert_(np.modf(a, out=None) == {}) assert_(w[0].category is DeprecationWarning) # don't give positional and output argument, or too many arguments. # wrong number of arguments in the tuple is an error too. assert_raises(TypeError, np.multiply, a, b, 'one', out='two') assert_raises(TypeError, np.multiply, a, b, 'one', 'two') assert_raises(ValueError, np.multiply, a, b, out=('one', 'two')) assert_raises(ValueError, np.multiply, a, out=()) assert_raises(TypeError, np.modf, a, 'one', out=('two', 'three')) assert_raises(TypeError, np.modf, a, 'one', 'two', 'three') assert_raises(ValueError, np.modf, a, out=('one', 'two', 'three')) assert_raises(ValueError, np.modf, a, out=('one',)) def test_ufunc_override_exception(self): class A(object): def __array_ufunc__(self, *a, **kwargs): raise ValueError("oops") a = A() assert_raises(ValueError, np.negative, 1, out=a) assert_raises(ValueError, np.negative, a) assert_raises(ValueError, np.divide, 1., a) def test_ufunc_override_not_implemented(self): class A(object): def __array_ufunc__(self, *args, **kwargs): return NotImplemented msg = ("operand type(s) all returned NotImplemented from " "__array_ufunc__(, '__call__', <*>): 'A'") with assert_raises_regex(TypeError, fnmatch.translate(msg)): np.negative(A()) msg = ("operand type(s) all returned NotImplemented from " "__array_ufunc__(, '__call__', <*>, , " "out=(1,)): 'A', 'object', 'int'") with assert_raises_regex(TypeError, fnmatch.translate(msg)): np.add(A(), object(), out=1) def test_ufunc_override_disabled(self): class OptOut(object): __array_ufunc__ = None opt_out = OptOut() # ufuncs always raise msg = "operand 'OptOut' does not support ufuncs" with assert_raises_regex(TypeError, msg): np.add(opt_out, 1) with assert_raises_regex(TypeError, msg): np.add(1, opt_out) with assert_raises_regex(TypeError, msg): np.negative(opt_out) # opt-outs still hold even when other arguments have pathological # __array_ufunc__ implementations class GreedyArray(object): def __array_ufunc__(self, *args, **kwargs): return self greedy = GreedyArray() assert_(np.negative(greedy) is greedy) with assert_raises_regex(TypeError, msg): np.add(greedy, opt_out) with assert_raises_regex(TypeError, msg): np.add(greedy, 1, out=opt_out) def test_gufunc_override(self): # gufunc are just ufunc instances, but follow a different path, # so check __array_ufunc__ overrides them properly. class A(object): def __array_ufunc__(self, ufunc, method, *inputs, **kwargs): return self, ufunc, method, inputs, kwargs inner1d = ncu_tests.inner1d a = A() res = inner1d(a, a) assert_equal(res[0], a) assert_equal(res[1], inner1d) assert_equal(res[2], '__call__') assert_equal(res[3], (a, a)) assert_equal(res[4], {}) res = inner1d(1, 1, out=a) assert_equal(res[0], a) assert_equal(res[1], inner1d) assert_equal(res[2], '__call__') assert_equal(res[3], (1, 1)) assert_equal(res[4], {'out': (a,)}) # wrong number of arguments in the tuple is an error too. assert_raises(TypeError, inner1d, a, out='two') assert_raises(TypeError, inner1d, a, a, 'one', out='two') assert_raises(TypeError, inner1d, a, a, 'one', 'two') assert_raises(ValueError, inner1d, a, a, out=('one', 'two')) assert_raises(ValueError, inner1d, a, a, out=()) def test_ufunc_override_with_super(self): # NOTE: this class is given as an example in doc/subclassing.py; # if you make any changes here, do update it there too. class A(np.ndarray): def __array_ufunc__(self, ufunc, method, *inputs, **kwargs): args = [] in_no = [] for i, input_ in enumerate(inputs): if isinstance(input_, A): in_no.append(i) args.append(input_.view(np.ndarray)) else: args.append(input_) outputs = kwargs.pop('out', None) out_no = [] if outputs: out_args = [] for j, output in enumerate(outputs): if isinstance(output, A): out_no.append(j) out_args.append(output.view(np.ndarray)) else: out_args.append(output) kwargs['out'] = tuple(out_args) else: outputs = (None,) * ufunc.nout info = {} if in_no: info['inputs'] = in_no if out_no: info['outputs'] = out_no results = super(A, self).__array_ufunc__(ufunc, method, *args, **kwargs) if results is NotImplemented: return NotImplemented if method == 'at': if isinstance(inputs[0], A): inputs[0].info = info return if ufunc.nout == 1: results = (results,) results = tuple((np.asarray(result).view(A) if output is None else output) for result, output in zip(results, outputs)) if results and isinstance(results[0], A): results[0].info = info return results[0] if len(results) == 1 else results class B(object): def __array_ufunc__(self, ufunc, method, *inputs, **kwargs): if any(isinstance(input_, A) for input_ in inputs): return "A!" else: return NotImplemented d = np.arange(5.) # 1 input, 1 output a = np.arange(5.).view(A) b = np.sin(a) check = np.sin(d) assert_(np.all(check == b)) assert_equal(b.info, {'inputs': [0]}) b = np.sin(d, out=(a,)) assert_(np.all(check == b)) assert_equal(b.info, {'outputs': [0]}) assert_(b is a) a = np.arange(5.).view(A) b = np.sin(a, out=a) assert_(np.all(check == b)) assert_equal(b.info, {'inputs': [0], 'outputs': [0]}) # 1 input, 2 outputs a = np.arange(5.).view(A) b1, b2 = np.modf(a) assert_equal(b1.info, {'inputs': [0]}) b1, b2 = np.modf(d, out=(None, a)) assert_(b2 is a) assert_equal(b1.info, {'outputs': [1]}) a = np.arange(5.).view(A) b = np.arange(5.).view(A) c1, c2 = np.modf(a, out=(a, b)) assert_(c1 is a) assert_(c2 is b) assert_equal(c1.info, {'inputs': [0], 'outputs': [0, 1]}) # 2 input, 1 output a = np.arange(5.).view(A) b = np.arange(5.).view(A) c = np.add(a, b, out=a) assert_(c is a) assert_equal(c.info, {'inputs': [0, 1], 'outputs': [0]}) # some tests with a non-ndarray subclass a = np.arange(5.) b = B() assert_(a.__array_ufunc__(np.add, '__call__', a, b) is NotImplemented) assert_(b.__array_ufunc__(np.add, '__call__', a, b) is NotImplemented) assert_raises(TypeError, np.add, a, b) a = a.view(A) assert_(a.__array_ufunc__(np.add, '__call__', a, b) is NotImplemented) assert_(b.__array_ufunc__(np.add, '__call__', a, b) == "A!") assert_(np.add(a, b) == "A!") # regression check for gh-9102 -- tests ufunc.reduce implicitly. d = np.array([[1, 2, 3], [1, 2, 3]]) a = d.view(A) c = a.any() check = d.any() assert_equal(c, check) assert_(c.info, {'inputs': [0]}) c = a.max() check = d.max() assert_equal(c, check) assert_(c.info, {'inputs': [0]}) b = np.array(0).view(A) c = a.max(out=b) assert_equal(c, check) assert_(c is b) assert_(c.info, {'inputs': [0], 'outputs': [0]}) check = a.max(axis=0) b = np.zeros_like(check).view(A) c = a.max(axis=0, out=b) assert_equal(c, check) assert_(c is b) assert_(c.info, {'inputs': [0], 'outputs': [0]}) # simple explicit tests of reduce, accumulate, reduceat check = np.add.reduce(d, axis=1) c = np.add.reduce(a, axis=1) assert_equal(c, check) assert_(c.info, {'inputs': [0]}) b = np.zeros_like(c) c = np.add.reduce(a, 1, None, b) assert_equal(c, check) assert_(c is b) assert_(c.info, {'inputs': [0], 'outputs': [0]}) check = np.add.accumulate(d, axis=0) c = np.add.accumulate(a, axis=0) assert_equal(c, check) assert_(c.info, {'inputs': [0]}) b = np.zeros_like(c) c = np.add.accumulate(a, 0, None, b) assert_equal(c, check) assert_(c is b) assert_(c.info, {'inputs': [0], 'outputs': [0]}) indices = [0, 2, 1] check = np.add.reduceat(d, indices, axis=1) c = np.add.reduceat(a, indices, axis=1) assert_equal(c, check) assert_(c.info, {'inputs': [0]}) b = np.zeros_like(c) c = np.add.reduceat(a, indices, 1, None, b) assert_equal(c, check) assert_(c is b) assert_(c.info, {'inputs': [0], 'outputs': [0]}) # and a few tests for at d = np.array([[1, 2, 3], [1, 2, 3]]) check = d.copy() a = d.copy().view(A) np.add.at(check, ([0, 1], [0, 2]), 1.) np.add.at(a, ([0, 1], [0, 2]), 1.) assert_equal(a, check) assert_(a.info, {'inputs': [0]}) b = np.array(1.).view(A) a = d.copy().view(A) np.add.at(a, ([0, 1], [0, 2]), b) assert_equal(a, check) assert_(a.info, {'inputs': [0, 2]}) class TestChoose(object): 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])) class TestRationalFunctions(object): def test_lcm(self): self._test_lcm_inner(np.int16) self._test_lcm_inner(np.uint16) def test_lcm_object(self): self._test_lcm_inner(np.object_) def test_gcd(self): self._test_gcd_inner(np.int16) self._test_lcm_inner(np.uint16) def test_gcd_object(self): self._test_gcd_inner(np.object_) def _test_lcm_inner(self, dtype): # basic use a = np.array([12, 120], dtype=dtype) b = np.array([20, 200], dtype=dtype) assert_equal(np.lcm(a, b), [60, 600]) if not issubclass(dtype, np.unsignedinteger): # negatives are ignored a = np.array([12, -12, 12, -12], dtype=dtype) b = np.array([20, 20, -20, -20], dtype=dtype) assert_equal(np.lcm(a, b), [60]*4) # reduce a = np.array([3, 12, 20], dtype=dtype) assert_equal(np.lcm.reduce([3, 12, 20]), 60) # broadcasting, and a test including 0 a = np.arange(6).astype(dtype) b = 20 assert_equal(np.lcm(a, b), [0, 20, 20, 60, 20, 20]) def _test_gcd_inner(self, dtype): # basic use a = np.array([12, 120], dtype=dtype) b = np.array([20, 200], dtype=dtype) assert_equal(np.gcd(a, b), [4, 40]) if not issubclass(dtype, np.unsignedinteger): # negatives are ignored a = np.array([12, -12, 12, -12], dtype=dtype) b = np.array([20, 20, -20, -20], dtype=dtype) assert_equal(np.gcd(a, b), [4]*4) # reduce a = np.array([15, 25, 35], dtype=dtype) assert_equal(np.gcd.reduce(a), 5) # broadcasting, and a test including 0 a = np.arange(6).astype(dtype) b = 20 assert_equal(np.gcd(a, b), [20, 1, 2, 1, 4, 5]) def test_lcm_overflow(self): # verify that we don't overflow when a*b does overflow big = np.int32(np.iinfo(np.int32).max // 11) a = 2*big b = 5*big assert_equal(np.lcm(a, b), 10*big) def test_gcd_overflow(self): for dtype in (np.int32, np.int64): # verify that we don't overflow when taking abs(x) # not relevant for lcm, where the result is unrepresentable anyway a = dtype(np.iinfo(dtype).min) # negative power of two q = -(a // 4) assert_equal(np.gcd(a, q*3), q) assert_equal(np.gcd(a, -q*3), q) def test_decimal(self): from decimal import Decimal a = np.array([1, 1, -1, -1]) * Decimal('0.20') b = np.array([1, -1, 1, -1]) * Decimal('0.12') assert_equal(np.gcd(a, b), 4*[Decimal('0.04')]) assert_equal(np.lcm(a, b), 4*[Decimal('0.60')]) def test_float(self): # not well-defined on float due to rounding errors assert_raises(TypeError, np.gcd, 0.3, 0.4) assert_raises(TypeError, np.lcm, 0.3, 0.4) def test_builtin_long(self): # sanity check that array coercion is alright for builtin longs assert_equal(np.array(2**200).item(), 2**200) # expressed as prime factors a = np.array(2**100 * 3**5) b = np.array([2**100 * 5**7, 2**50 * 3**10]) assert_equal(np.gcd(a, b), [2**100, 2**50 * 3**5]) assert_equal(np.lcm(a, b), [2**100 * 3**5 * 5**7, 2**100 * 3**10]) assert_equal(np.gcd(2**100, 3**100), 1) 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(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 _check_branch_cut(np.log, -0.5, 1j, 1, -1, True) _check_branch_cut(np.log2, -0.5, 1j, 1, -1, True) _check_branch_cut(np.log10, -0.5, 1j, 1, -1, True) _check_branch_cut(np.log1p, -1.5, 1j, 1, -1, True) _check_branch_cut(np.sqrt, -0.5, 1j, 1, -1, True) _check_branch_cut(np.arcsin, [ -2, 2], [1j, 1j], 1, -1, True) _check_branch_cut(np.arccos, [ -2, 2], [1j, 1j], 1, -1, True) _check_branch_cut(np.arctan, [0-2j, 2j], [1, 1], -1, 1, True) _check_branch_cut(np.arcsinh, [0-2j, 2j], [1, 1], -1, 1, True) _check_branch_cut(np.arccosh, [ -1, 0.5], [1j, 1j], 1, -1, True) _check_branch_cut(np.arctanh, [ -2, 2], [1j, 1j], 1, -1, True) # check against bogus branch cuts: assert continuity between quadrants _check_branch_cut(np.arcsin, [0-2j, 2j], [ 1, 1], 1, 1) _check_branch_cut(np.arccos, [0-2j, 2j], [ 1, 1], 1, 1) _check_branch_cut(np.arctan, [ -2, 2], [1j, 1j], 1, 1) _check_branch_cut(np.arcsinh, [ -2, 2, 0], [1j, 1j, 1], 1, 1) _check_branch_cut(np.arccosh, [0-2j, 2j, 2], [1, 1, 1j], 1, 1) _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 _check_branch_cut(np.log, -0.5, 1j, 1, -1, True, np.complex64) _check_branch_cut(np.log2, -0.5, 1j, 1, -1, True, np.complex64) _check_branch_cut(np.log10, -0.5, 1j, 1, -1, True, np.complex64) _check_branch_cut(np.log1p, -1.5, 1j, 1, -1, True, np.complex64) _check_branch_cut(np.sqrt, -0.5, 1j, 1, -1, True, np.complex64) _check_branch_cut(np.arcsin, [ -2, 2], [1j, 1j], 1, -1, True, np.complex64) _check_branch_cut(np.arccos, [ -2, 2], [1j, 1j], 1, -1, True, np.complex64) _check_branch_cut(np.arctan, [0-2j, 2j], [1, 1], -1, 1, True, np.complex64) _check_branch_cut(np.arcsinh, [0-2j, 2j], [1, 1], -1, 1, True, np.complex64) _check_branch_cut(np.arccosh, [ -1, 0.5], [1j, 1j], 1, -1, True, np.complex64) _check_branch_cut(np.arctanh, [ -2, 2], [1j, 1j], 1, -1, True, np.complex64) # check against bogus branch cuts: assert continuity between quadrants _check_branch_cut(np.arcsin, [0-2j, 2j], [ 1, 1], 1, 1, False, np.complex64) _check_branch_cut(np.arccos, [0-2j, 2j], [ 1, 1], 1, 1, False, np.complex64) _check_branch_cut(np.arctan, [ -2, 2], [1j, 1j], 1, 1, False, np.complex64) _check_branch_cut(np.arcsinh, [ -2, 2, 0], [1j, 1j, 1], 1, 1, False, np.complex64) _check_branch_cut(np.arccosh, [0-2j, 2j, 2], [1, 1, 1j], 1, 1, False, np.complex64) _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(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)) @pytest.mark.parametrize('dtype', [np.complex64, np.complex_, np.longcomplex]) def test_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: # Can use 2.1 for > Ubuntu LTS Trusty (2014), glibc = 2.19. check(x_series, 50.0*eps) else: check(x_series, 2.1*eps) check(x_basic, 2.0*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) class TestAttributes(object): def test_attributes(self): add = ncu.add assert_equal(add.__name__, 'add') assert_(add.ntypes >= 18) # don't fail if types added assert_('ii->i' in add.types) assert_equal(add.nin, 2) assert_equal(add.nout, 1) assert_equal(add.identity, 0) def test_doc(self): # don't bother checking the long list of kwargs, which are likely to # change assert_(ncu.add.__doc__.startswith( "add(x1, x2, /, out=None, *, where=True")) assert_(ncu.frexp.__doc__.startswith( "frexp(x[, out1, out2], / [, out=(None, None)], *, where=True")) class TestSubclass(object): 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=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) @pytest.mark.skipif(np.finfo(np.double) == np.finfo(np.longdouble), reason="long double is same as double") @pytest.mark.xfail(condition=platform.machine().startswith("ppc64"), reason="IBM double double") def test_nextafterl(): return _test_nextafter(np.longdouble) def test_nextafter_0(): for t, direction in itertools.product(np.sctypes['float'], (1, -1)): tiny = np.finfo(t).tiny assert_(0. < direction * np.nextafter(t(0), t(direction)) < tiny) assert_equal(np.nextafter(t(0), t(direction)) / t(2.1), direction * 0.0) 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) @pytest.mark.skipif(np.finfo(np.double) == np.finfo(np.longdouble), reason="long double is same as double") @pytest.mark.xfail(condition=platform.machine().startswith("ppc64"), reason="IBM double double") 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)) def test_signaling_nan_exceptions(): with assert_no_warnings(): a = np.ndarray(shape=(), dtype='float32', buffer=b'\x00\xe0\xbf\xff') np.isnan(a)