# NOTE: Please avoid the use of numpy.testing since NPYV intrinsics # may be involved in their functionality. import pytest, math, re import itertools from numpy.core._simd import targets from numpy.core._multiarray_umath import __cpu_baseline__ class _Test_Utility: # submodule of the desired SIMD extension, e.g. targets["AVX512F"] npyv = None # the current data type suffix e.g. 's8' sfx = None # target name can be 'baseline' or one or more of CPU features target_name = None def __getattr__(self, attr): """ To call NPV intrinsics without the attribute 'npyv' and auto suffixing intrinsics according to class attribute 'sfx' """ return getattr(self.npyv, attr + "_" + self.sfx) def _data(self, start=None, count=None, reverse=False): """ Create list of consecutive numbers according to number of vector's lanes. """ if start is None: start = 1 if count is None: count = self.nlanes rng = range(start, start + count) if reverse: rng = reversed(rng) if self._is_fp(): return [x / 1.0 for x in rng] return list(rng) def _is_unsigned(self): return self.sfx[0] == 'u' def _is_signed(self): return self.sfx[0] == 's' def _is_fp(self): return self.sfx[0] == 'f' def _scalar_size(self): return int(self.sfx[1:]) def _int_clip(self, seq): if self._is_fp(): return seq max_int = self._int_max() min_int = self._int_min() return [min(max(v, min_int), max_int) for v in seq] def _int_max(self): if self._is_fp(): return None max_u = self._to_unsigned(self.setall(-1))[0] if self._is_signed(): return max_u // 2 return max_u def _int_min(self): if self._is_fp(): return None if self._is_unsigned(): return 0 return -(self._int_max() + 1) def _true_mask(self): max_unsig = getattr(self.npyv, "setall_u" + self.sfx[1:])(-1) return max_unsig[0] def _to_unsigned(self, vector): if isinstance(vector, (list, tuple)): return getattr(self.npyv, "load_u" + self.sfx[1:])(vector) else: sfx = vector.__name__.replace("npyv_", "") if sfx[0] == "b": cvt_intrin = "cvt_u{0}_b{0}" else: cvt_intrin = "reinterpret_u{0}_{1}" return getattr(self.npyv, cvt_intrin.format(sfx[1:], sfx))(vector) def _pinfinity(self): v = self.npyv.setall_u32(0x7f800000) return self.npyv.reinterpret_f32_u32(v)[0] def _ninfinity(self): v = self.npyv.setall_u32(0xff800000) return self.npyv.reinterpret_f32_u32(v)[0] def _nan(self): v = self.npyv.setall_u32(0x7fc00000) return self.npyv.reinterpret_f32_u32(v)[0] def _cpu_features(self): target = self.target_name if target == "baseline": target = __cpu_baseline__ else: target = target.split('__') # multi-target separator return ' '.join(target) class _SIMD_BOOL(_Test_Utility): """ To test all boolean vector types at once """ def _data(self, start=None, count=None, reverse=False): nlanes = getattr(self.npyv, "nlanes_u" + self.sfx[1:]) true_mask = self._true_mask() rng = range(nlanes) if reverse: rng = reversed(rng) return [true_mask if x % 2 else 0 for x in rng] def _load_b(self, data): len_str = self.sfx[1:] load = getattr(self.npyv, "load_u" + len_str) cvt = getattr(self.npyv, f"cvt_b{len_str}_u{len_str}") return cvt(load(data)) def test_operators_logical(self): """ Logical operations for boolean types. Test intrinsics: npyv_xor_##SFX, npyv_and_##SFX, npyv_or_##SFX, npyv_not_##SFX """ data_a = self._data() data_b = self._data(reverse=True) vdata_a = self._load_b(data_a) vdata_b = self._load_b(data_b) data_and = [a & b for a, b in zip(data_a, data_b)] vand = getattr(self, "and")(vdata_a, vdata_b) assert vand == data_and data_or = [a | b for a, b in zip(data_a, data_b)] vor = getattr(self, "or")(vdata_a, vdata_b) assert vor == data_or data_xor = [a ^ b for a, b in zip(data_a, data_b)] vxor = getattr(self, "xor")(vdata_a, vdata_b) assert vxor == data_xor vnot = getattr(self, "not")(vdata_a) assert vnot == data_b def test_tobits(self): data2bits = lambda data: sum([int(x != 0) << i for i, x in enumerate(data, 0)]) for data in (self._data(), self._data(reverse=True)): vdata = self._load_b(data) data_bits = data2bits(data) tobits = bin(self.tobits(vdata)) assert tobits == bin(data_bits) class _SIMD_INT(_Test_Utility): """ To test all integer vector types at once """ def test_operators_shift(self): if self.sfx in ("u8", "s8"): return data_a = self._data(self._int_max() - self.nlanes) data_b = self._data(self._int_min(), reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) for count in range(self._scalar_size()): # load to cast data_shl_a = self.load([a << count for a in data_a]) # left shift shl = self.shl(vdata_a, count) assert shl == data_shl_a # load to cast data_shr_a = self.load([a >> count for a in data_a]) # right shift shr = self.shr(vdata_a, count) assert shr == data_shr_a # shift by zero or max or out-range immediate constant is not applicable and illogical for count in range(1, self._scalar_size()): # load to cast data_shl_a = self.load([a << count for a in data_a]) # left shift by an immediate constant shli = self.shli(vdata_a, count) assert shli == data_shl_a # load to cast data_shr_a = self.load([a >> count for a in data_a]) # right shift by an immediate constant shri = self.shri(vdata_a, count) assert shri == data_shr_a def test_arithmetic_subadd_saturated(self): if self.sfx in ("u32", "s32", "u64", "s64"): return data_a = self._data(self._int_max() - self.nlanes) data_b = self._data(self._int_min(), reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) data_adds = self._int_clip([a + b for a, b in zip(data_a, data_b)]) adds = self.adds(vdata_a, vdata_b) assert adds == data_adds data_subs = self._int_clip([a - b for a, b in zip(data_a, data_b)]) subs = self.subs(vdata_a, vdata_b) assert subs == data_subs def test_math_max_min(self): data_a = self._data() data_b = self._data(self.nlanes) vdata_a, vdata_b = self.load(data_a), self.load(data_b) data_max = [max(a, b) for a, b in zip(data_a, data_b)] simd_max = self.max(vdata_a, vdata_b) assert simd_max == data_max data_min = [min(a, b) for a, b in zip(data_a, data_b)] simd_min = self.min(vdata_a, vdata_b) assert simd_min == data_min class _SIMD_FP32(_Test_Utility): """ To only test single precision """ def test_conversions(self): """ Round to nearest even integer, assume CPU control register is set to rounding. Test intrinsics: npyv_round_s32_##SFX """ features = self._cpu_features() if not self.npyv.simd_f64 and re.match(r".*(NEON|ASIMD)", features): # very costly to emulate nearest even on Armv7 # instead we round halves to up. e.g. 0.5 -> 1, -0.5 -> -1 _round = lambda v: int(v + (0.5 if v >= 0 else -0.5)) else: _round = round vdata_a = self.load(self._data()) vdata_a = self.sub(vdata_a, self.setall(0.5)) data_round = [_round(x) for x in vdata_a] vround = self.round_s32(vdata_a) assert vround == data_round class _SIMD_FP64(_Test_Utility): """ To only test double precision """ def test_conversions(self): """ Round to nearest even integer, assume CPU control register is set to rounding. Test intrinsics: npyv_round_s32_##SFX """ vdata_a = self.load(self._data()) vdata_a = self.sub(vdata_a, self.setall(0.5)) vdata_b = self.mul(vdata_a, self.setall(-1.5)) data_round = [round(x) for x in list(vdata_a) + list(vdata_b)] vround = self.round_s32(vdata_a, vdata_b) assert vround == data_round class _SIMD_FP(_Test_Utility): """ To test all float vector types at once """ def test_arithmetic_fused(self): vdata_a, vdata_b, vdata_c = [self.load(self._data())]*3 vdata_cx2 = self.add(vdata_c, vdata_c) # multiply and add, a*b + c data_fma = self.load([a * b + c for a, b, c in zip(vdata_a, vdata_b, vdata_c)]) fma = self.muladd(vdata_a, vdata_b, vdata_c) assert fma == data_fma # multiply and subtract, a*b - c fms = self.mulsub(vdata_a, vdata_b, vdata_c) data_fms = self.sub(data_fma, vdata_cx2) assert fms == data_fms # negate multiply and add, -(a*b) + c nfma = self.nmuladd(vdata_a, vdata_b, vdata_c) data_nfma = self.sub(vdata_cx2, data_fma) assert nfma == data_nfma # negate multiply and subtract, -(a*b) - c nfms = self.nmulsub(vdata_a, vdata_b, vdata_c) data_nfms = self.mul(data_fma, self.setall(-1)) assert nfms == data_nfms def test_abs(self): pinf, ninf, nan = self._pinfinity(), self._ninfinity(), self._nan() data = self._data() vdata = self.load(self._data()) abs_cases = ((-0, 0), (ninf, pinf), (pinf, pinf), (nan, nan)) for case, desired in abs_cases: data_abs = [desired]*self.nlanes vabs = self.abs(self.setall(case)) assert vabs == pytest.approx(data_abs, nan_ok=True) vabs = self.abs(self.mul(vdata, self.setall(-1))) assert vabs == data def test_sqrt(self): pinf, ninf, nan = self._pinfinity(), self._ninfinity(), self._nan() data = self._data() vdata = self.load(self._data()) sqrt_cases = ((-0.0, -0.0), (0.0, 0.0), (-1.0, nan), (ninf, nan), (pinf, pinf)) for case, desired in sqrt_cases: data_sqrt = [desired]*self.nlanes sqrt = self.sqrt(self.setall(case)) assert sqrt == pytest.approx(data_sqrt, nan_ok=True) data_sqrt = self.load([math.sqrt(x) for x in data]) # load to truncate precision sqrt = self.sqrt(vdata) assert sqrt == data_sqrt def test_square(self): pinf, ninf, nan = self._pinfinity(), self._ninfinity(), self._nan() data = self._data() vdata = self.load(self._data()) # square square_cases = ((nan, nan), (pinf, pinf), (ninf, pinf)) for case, desired in square_cases: data_square = [desired]*self.nlanes square = self.square(self.setall(case)) assert square == pytest.approx(data_square, nan_ok=True) data_square = [x*x for x in data] square = self.square(vdata) assert square == data_square def test_max(self): """ Test intrinsics: npyv_max_##SFX npyv_maxp_##SFX """ data_a = self._data() data_b = self._data(self.nlanes) vdata_a, vdata_b = self.load(data_a), self.load(data_b) data_max = [max(a, b) for a, b in zip(data_a, data_b)] _max = self.max(vdata_a, vdata_b) assert _max == data_max maxp = self.maxp(vdata_a, vdata_b) assert maxp == data_max # test IEEE standards pinf, ninf, nan = self._pinfinity(), self._ninfinity(), self._nan() max_cases = ((nan, nan, nan), (nan, 10, 10), (10, nan, 10), (pinf, pinf, pinf), (pinf, 10, pinf), (10, pinf, pinf), (ninf, ninf, ninf), (ninf, 10, 10), (10, ninf, 10), (10, 0, 10), (10, -10, 10)) for case_operand1, case_operand2, desired in max_cases: data_max = [desired]*self.nlanes vdata_a = self.setall(case_operand1) vdata_b = self.setall(case_operand2) maxp = self.maxp(vdata_a, vdata_b) assert maxp == pytest.approx(data_max, nan_ok=True) if nan in (case_operand1, case_operand2, desired): continue _max = self.max(vdata_a, vdata_b) assert _max == data_max def test_min(self): """ Test intrinsics: npyv_min_##SFX npyv_minp_##SFX """ data_a = self._data() data_b = self._data(self.nlanes) vdata_a, vdata_b = self.load(data_a), self.load(data_b) data_min = [min(a, b) for a, b in zip(data_a, data_b)] _min = self.min(vdata_a, vdata_b) assert _min == data_min minp = self.minp(vdata_a, vdata_b) assert minp == data_min # test IEEE standards pinf, ninf, nan = self._pinfinity(), self._ninfinity(), self._nan() min_cases = ((nan, nan, nan), (nan, 10, 10), (10, nan, 10), (pinf, pinf, pinf), (pinf, 10, 10), (10, pinf, 10), (ninf, ninf, ninf), (ninf, 10, ninf), (10, ninf, ninf), (10, 0, 0), (10, -10, -10)) for case_operand1, case_operand2, desired in min_cases: data_min = [desired]*self.nlanes vdata_a = self.setall(case_operand1) vdata_b = self.setall(case_operand2) minp = self.minp(vdata_a, vdata_b) assert minp == pytest.approx(data_min, nan_ok=True) if nan in (case_operand1, case_operand2, desired): continue _min = self.min(vdata_a, vdata_b) assert _min == data_min def test_reciprocal(self): pinf, ninf, nan = self._pinfinity(), self._ninfinity(), self._nan() data = self._data() vdata = self.load(self._data()) recip_cases = ((nan, nan), (pinf, 0.0), (ninf, -0.0), (0.0, pinf), (-0.0, ninf)) for case, desired in recip_cases: data_recip = [desired]*self.nlanes recip = self.recip(self.setall(case)) assert recip == pytest.approx(data_recip, nan_ok=True) data_recip = self.load([1/x for x in data]) # load to truncate precision recip = self.recip(vdata) assert recip == data_recip def test_special_cases(self): """ Compare Not NaN. Test intrinsics: npyv_notnan_##SFX """ nnan = self.notnan(self.setall(self._nan())) assert nnan == [0]*self.nlanes class _SIMD_ALL(_Test_Utility): """ To test all vector types at once """ def test_memory_load(self): data = self._data() # unaligned load load_data = self.load(data) assert load_data == data # aligned load loada_data = self.loada(data) assert loada_data == data # stream load loads_data = self.loads(data) assert loads_data == data # load lower part loadl = self.loadl(data) loadl_half = list(loadl)[:self.nlanes//2] data_half = data[:self.nlanes//2] assert loadl_half == data_half assert loadl != data # detect overflow def test_memory_store(self): data = self._data() vdata = self.load(data) # unaligned store store = [0] * self.nlanes self.store(store, vdata) assert store == data # aligned store store_a = [0] * self.nlanes self.storea(store_a, vdata) assert store_a == data # stream store store_s = [0] * self.nlanes self.stores(store_s, vdata) assert store_s == data # store lower part store_l = [0] * self.nlanes self.storel(store_l, vdata) assert store_l[:self.nlanes//2] == data[:self.nlanes//2] assert store_l != vdata # detect overflow # store higher part store_h = [0] * self.nlanes self.storeh(store_h, vdata) assert store_h[:self.nlanes//2] == data[self.nlanes//2:] assert store_h != vdata # detect overflow def test_memory_partial_load(self): if self.sfx in ("u8", "s8", "u16", "s16"): return data = self._data() lanes = list(range(1, self.nlanes + 1)) lanes += [self.nlanes**2, self.nlanes**4] # test out of range for n in lanes: load_till = self.load_till(data, n, 15) data_till = data[:n] + [15] * (self.nlanes-n) assert load_till == data_till load_tillz = self.load_tillz(data, n) data_tillz = data[:n] + [0] * (self.nlanes-n) assert load_tillz == data_tillz def test_memory_partial_store(self): if self.sfx in ("u8", "s8", "u16", "s16"): return data = self._data() data_rev = self._data(reverse=True) vdata = self.load(data) lanes = list(range(1, self.nlanes + 1)) lanes += [self.nlanes**2, self.nlanes**4] for n in lanes: data_till = data_rev.copy() data_till[:n] = data[:n] store_till = self._data(reverse=True) self.store_till(store_till, n, vdata) assert store_till == data_till def test_memory_noncont_load(self): if self.sfx in ("u8", "s8", "u16", "s16"): return for stride in range(1, 64): data = self._data(count=stride*self.nlanes) data_stride = data[::stride] loadn = self.loadn(data, stride) assert loadn == data_stride for stride in range(-64, 0): data = self._data(stride, -stride*self.nlanes) data_stride = self.load(data[::stride]) # cast unsigned loadn = self.loadn(data, stride) assert loadn == data_stride def test_memory_noncont_partial_load(self): if self.sfx in ("u8", "s8", "u16", "s16"): return lanes = list(range(1, self.nlanes + 1)) lanes += [self.nlanes**2, self.nlanes**4] for stride in range(1, 64): data = self._data(count=stride*self.nlanes) data_stride = data[::stride] for n in lanes: data_stride_till = data_stride[:n] + [15] * (self.nlanes-n) loadn_till = self.loadn_till(data, stride, n, 15) assert loadn_till == data_stride_till data_stride_tillz = data_stride[:n] + [0] * (self.nlanes-n) loadn_tillz = self.loadn_tillz(data, stride, n) assert loadn_tillz == data_stride_tillz for stride in range(-64, 0): data = self._data(stride, -stride*self.nlanes) data_stride = list(self.load(data[::stride])) # cast unsigned for n in lanes: data_stride_till = data_stride[:n] + [15] * (self.nlanes-n) loadn_till = self.loadn_till(data, stride, n, 15) assert loadn_till == data_stride_till data_stride_tillz = data_stride[:n] + [0] * (self.nlanes-n) loadn_tillz = self.loadn_tillz(data, stride, n) assert loadn_tillz == data_stride_tillz def test_memory_noncont_store(self): if self.sfx in ("u8", "s8", "u16", "s16"): return vdata = self.load(self._data()) for stride in range(1, 64): data = [15] * stride * self.nlanes data[::stride] = vdata storen = [15] * stride * self.nlanes storen += [127]*64 self.storen(storen, stride, vdata) assert storen[:-64] == data assert storen[-64:] == [127]*64 # detect overflow for stride in range(-64, 0): data = [15] * -stride * self.nlanes data[::stride] = vdata storen = [127]*64 storen += [15] * -stride * self.nlanes self.storen(storen, stride, vdata) assert storen[64:] == data assert storen[:64] == [127]*64 # detect overflow def test_memory_noncont_partial_store(self): if self.sfx in ("u8", "s8", "u16", "s16"): return data = self._data() vdata = self.load(data) lanes = list(range(1, self.nlanes + 1)) lanes += [self.nlanes**2, self.nlanes**4] for stride in range(1, 64): for n in lanes: data_till = [15] * stride * self.nlanes data_till[::stride] = data[:n] + [15] * (self.nlanes-n) storen_till = [15] * stride * self.nlanes storen_till += [127]*64 self.storen_till(storen_till, stride, n, vdata) assert storen_till[:-64] == data_till assert storen_till[-64:] == [127]*64 # detect overflow for stride in range(-64, 0): for n in lanes: data_till = [15] * -stride * self.nlanes data_till[::stride] = data[:n] + [15] * (self.nlanes-n) storen_till = [127]*64 storen_till += [15] * -stride * self.nlanes self.storen_till(storen_till, stride, n, vdata) assert storen_till[64:] == data_till assert storen_till[:64] == [127]*64 # detect overflow def test_misc(self): broadcast_zero = self.zero() assert broadcast_zero == [0] * self.nlanes for i in range(1, 10): broadcasti = self.setall(i) assert broadcasti == [i] * self.nlanes data_a, data_b = self._data(), self._data(reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) # py level of npyv_set_* don't support ignoring the extra specified lanes or # fill non-specified lanes with zero. vset = self.set(*data_a) assert vset == data_a # py level of npyv_setf_* don't support ignoring the extra specified lanes or # fill non-specified lanes with the specified scalar. vsetf = self.setf(10, *data_a) assert vsetf == data_a # We're testing the sanity of _simd's type-vector, # reinterpret* intrinsics itself are tested via compiler # during the build of _simd module sfxes = ["u8", "s8", "u16", "s16", "u32", "s32", "u64", "s64", "f32"] if self.npyv.simd_f64: sfxes.append("f64") for sfx in sfxes: vec_name = getattr(self, "reinterpret_" + sfx)(vdata_a).__name__ assert vec_name == "npyv_" + sfx # select & mask operations select_a = self.select(self.cmpeq(self.zero(), self.zero()), vdata_a, vdata_b) assert select_a == data_a select_b = self.select(self.cmpneq(self.zero(), self.zero()), vdata_a, vdata_b) assert select_b == data_b # cleanup intrinsic is only used with AVX for # zeroing registers to avoid the AVX-SSE transition penalty, # so nothing to test here self.npyv.cleanup() def test_reorder(self): data_a, data_b = self._data(), self._data(reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) # lower half part data_a_lo = data_a[:self.nlanes//2] data_b_lo = data_b[:self.nlanes//2] # higher half part data_a_hi = data_a[self.nlanes//2:] data_b_hi = data_b[self.nlanes//2:] # combine two lower parts combinel = self.combinel(vdata_a, vdata_b) assert combinel == data_a_lo + data_b_lo # combine two higher parts combineh = self.combineh(vdata_a, vdata_b) assert combineh == data_a_hi + data_b_hi # combine x2 combine = self.combine(vdata_a, vdata_b) assert combine == (data_a_lo + data_b_lo, data_a_hi + data_b_hi) # zip(interleave) data_zipl = [v for p in zip(data_a_lo, data_b_lo) for v in p] data_ziph = [v for p in zip(data_a_hi, data_b_hi) for v in p] vzip = self.zip(vdata_a, vdata_b) assert vzip == (data_zipl, data_ziph) def test_reorder_rev64(self): # Reverse elements of each 64-bit lane ssize = self._scalar_size() if ssize == 64: return data_rev64 = [ y for x in range(0, self.nlanes, 64//ssize) for y in reversed(range(x, x + 64//ssize)) ] rev64 = self.rev64(self.load(range(self.nlanes))) assert rev64 == data_rev64 def test_operators_comparison(self): if self._is_fp(): data_a = self._data() else: data_a = self._data(self._int_max() - self.nlanes) data_b = self._data(self._int_min(), reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) mask_true = self._true_mask() def to_bool(vector): return [lane == mask_true for lane in vector] # equal data_eq = [a == b for a, b in zip(data_a, data_b)] cmpeq = to_bool(self.cmpeq(vdata_a, vdata_b)) assert cmpeq == data_eq # not equal data_neq = [a != b for a, b in zip(data_a, data_b)] cmpneq = to_bool(self.cmpneq(vdata_a, vdata_b)) assert cmpneq == data_neq # greater than data_gt = [a > b for a, b in zip(data_a, data_b)] cmpgt = to_bool(self.cmpgt(vdata_a, vdata_b)) assert cmpgt == data_gt # greater than and equal data_ge = [a >= b for a, b in zip(data_a, data_b)] cmpge = to_bool(self.cmpge(vdata_a, vdata_b)) assert cmpge == data_ge # less than data_lt = [a < b for a, b in zip(data_a, data_b)] cmplt = to_bool(self.cmplt(vdata_a, vdata_b)) assert cmplt == data_lt # less than and equal data_le = [a <= b for a, b in zip(data_a, data_b)] cmple = to_bool(self.cmple(vdata_a, vdata_b)) assert cmple == data_le def test_operators_logical(self): if self._is_fp(): data_a = self._data() else: data_a = self._data(self._int_max() - self.nlanes) data_b = self._data(self._int_min(), reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) if self._is_fp(): data_cast_a = self._to_unsigned(vdata_a) data_cast_b = self._to_unsigned(vdata_b) cast, cast_data = self._to_unsigned, self._to_unsigned else: data_cast_a, data_cast_b = data_a, data_b cast, cast_data = lambda a: a, self.load data_xor = cast_data([a ^ b for a, b in zip(data_cast_a, data_cast_b)]) vxor = cast(self.xor(vdata_a, vdata_b)) assert vxor == data_xor data_or = cast_data([a | b for a, b in zip(data_cast_a, data_cast_b)]) vor = cast(getattr(self, "or")(vdata_a, vdata_b)) assert vor == data_or data_and = cast_data([a & b for a, b in zip(data_cast_a, data_cast_b)]) vand = cast(getattr(self, "and")(vdata_a, vdata_b)) assert vand == data_and data_not = cast_data([~a for a in data_cast_a]) vnot = cast(getattr(self, "not")(vdata_a)) assert vnot == data_not def test_conversion_boolean(self): bsfx = "b" + self.sfx[1:] to_boolean = getattr(self.npyv, "cvt_%s_%s" % (bsfx, self.sfx)) from_boolean = getattr(self.npyv, "cvt_%s_%s" % (self.sfx, bsfx)) false_vb = to_boolean(self.setall(0)) true_vb = self.cmpeq(self.setall(0), self.setall(0)) assert false_vb != true_vb false_vsfx = from_boolean(false_vb) true_vsfx = from_boolean(true_vb) assert false_vsfx != true_vsfx def test_conversion_expand(self): """ Test expand intrinsics: npyv_expand_u16_u8 npyv_expand_u32_u16 """ if self.sfx not in ("u8", "u16"): return totype = self.sfx[0]+str(int(self.sfx[1:])*2) expand = getattr(self.npyv, f"expand_{totype}_{self.sfx}") # close enough from the edge to detect any deviation data = self._data(self._int_max() - self.nlanes) vdata = self.load(data) edata = expand(vdata) # lower half part data_lo = data[:self.nlanes//2] # higher half part data_hi = data[self.nlanes//2:] assert edata == (data_lo, data_hi) def test_arithmetic_subadd(self): if self._is_fp(): data_a = self._data() else: data_a = self._data(self._int_max() - self.nlanes) data_b = self._data(self._int_min(), reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) # non-saturated data_add = self.load([a + b for a, b in zip(data_a, data_b)]) # load to cast add = self.add(vdata_a, vdata_b) assert add == data_add data_sub = self.load([a - b for a, b in zip(data_a, data_b)]) sub = self.sub(vdata_a, vdata_b) assert sub == data_sub def test_arithmetic_mul(self): if self.sfx in ("u64", "s64"): return if self._is_fp(): data_a = self._data() else: data_a = self._data(self._int_max() - self.nlanes) data_b = self._data(self._int_min(), reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) data_mul = self.load([a * b for a, b in zip(data_a, data_b)]) mul = self.mul(vdata_a, vdata_b) assert mul == data_mul def test_arithmetic_div(self): if not self._is_fp(): return data_a, data_b = self._data(), self._data(reverse=True) vdata_a, vdata_b = self.load(data_a), self.load(data_b) # load to truncate f64 to precision of f32 data_div = self.load([a / b for a, b in zip(data_a, data_b)]) div = self.div(vdata_a, vdata_b) assert div == data_div def test_arithmetic_intdiv(self): """ Test integer division intrinsics: npyv_divisor_##sfx npyv_divc_##sfx """ if self._is_fp(): return int_min = self._int_min() def trunc_div(a, d): """ Divide towards zero works with large integers > 2^53, and wrap around overflow similar to what C does. """ if d == -1 and a == int_min: return a sign_a, sign_d = a < 0, d < 0 if a == 0 or sign_a == sign_d: return a // d return (a + sign_d - sign_a) // d + 1 data = [1, -int_min] # to test overflow data += range(0, 2**8, 2**5) data += range(0, 2**8, 2**5-1) bsize = self._scalar_size() if bsize > 8: data += range(2**8, 2**16, 2**13) data += range(2**8, 2**16, 2**13-1) if bsize > 16: data += range(2**16, 2**32, 2**29) data += range(2**16, 2**32, 2**29-1) if bsize > 32: data += range(2**32, 2**64, 2**61) data += range(2**32, 2**64, 2**61-1) # negate data += [-x for x in data] for dividend, divisor in itertools.product(data, data): divisor = self.setall(divisor)[0] # cast if divisor == 0: continue dividend = self.load(self._data(dividend)) data_divc = [trunc_div(a, divisor) for a in dividend] divisor_parms = self.divisor(divisor) divc = self.divc(dividend, divisor_parms) assert divc == data_divc def test_arithmetic_reduce_sum(self): """ Test reduce sum intrinsics: npyv_sum_##sfx """ if self.sfx not in ("u32", "u64", "f32", "f64"): return # reduce sum data = self._data() vdata = self.load(data) data_sum = sum(data) vsum = self.sum(vdata) assert vsum == data_sum def test_arithmetic_reduce_sumup(self): """ Test extend reduce sum intrinsics: npyv_sumup_##sfx """ if self.sfx not in ("u8", "u16"): return rdata = (0, self.nlanes, self._int_min(), self._int_max()-self.nlanes) for r in rdata: data = self._data(r) vdata = self.load(data) data_sum = sum(data) vsum = self.sumup(vdata) assert vsum == data_sum def test_mask_conditional(self): """ Conditional addition and subtraction for all supported data types. Test intrinsics: npyv_ifadd_##SFX, npyv_ifsub_##SFX """ vdata_a = self.load(self._data()) vdata_b = self.load(self._data(reverse=True)) true_mask = self.cmpeq(self.zero(), self.zero()) false_mask = self.cmpneq(self.zero(), self.zero()) data_sub = self.sub(vdata_b, vdata_a) ifsub = self.ifsub(true_mask, vdata_b, vdata_a, vdata_b) assert ifsub == data_sub ifsub = self.ifsub(false_mask, vdata_a, vdata_b, vdata_b) assert ifsub == vdata_b data_add = self.add(vdata_b, vdata_a) ifadd = self.ifadd(true_mask, vdata_b, vdata_a, vdata_b) assert ifadd == data_add ifadd = self.ifadd(false_mask, vdata_a, vdata_b, vdata_b) assert ifadd == vdata_b bool_sfx = ("b8", "b16", "b32", "b64") int_sfx = ("u8", "s8", "u16", "s16", "u32", "s32", "u64", "s64") fp_sfx = ("f32", "f64") all_sfx = int_sfx + fp_sfx tests_registry = { bool_sfx: _SIMD_BOOL, int_sfx : _SIMD_INT, fp_sfx : _SIMD_FP, ("f32",): _SIMD_FP32, ("f64",): _SIMD_FP64, all_sfx : _SIMD_ALL } for target_name, npyv in targets.items(): simd_width = npyv.simd if npyv else '' pretty_name = target_name.split('__') # multi-target separator if len(pretty_name) > 1: # multi-target pretty_name = f"({' '.join(pretty_name)})" else: pretty_name = pretty_name[0] skip = "" skip_sfx = dict() if not npyv: skip = f"target '{pretty_name}' isn't supported by current machine" elif not npyv.simd: skip = f"target '{pretty_name}' isn't supported by NPYV" elif not npyv.simd_f64: skip_sfx["f64"] = f"target '{pretty_name}' doesn't support double-precision" for sfxes, cls in tests_registry.items(): for sfx in sfxes: skip_m = skip_sfx.get(sfx, skip) inhr = (cls,) attr = dict(npyv=targets[target_name], sfx=sfx, target_name=target_name) tcls = type(f"Test{cls.__name__}_{simd_width}_{target_name}_{sfx}", inhr, attr) if skip_m: pytest.mark.skip(reason=skip_m)(tcls) globals()[tcls.__name__] = tcls