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from __future__ import division, absolute_import, print_function
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__copyright__ = "Copyright (C) 2012 Andreas Kloeckner"

__license__ = """
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
"""

import six
from six.moves import range
import sys
import numpy as np
import loopy as lp
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import pyopencl.clrandom  # noqa
import pytest
import logging
logger = logging.getLogger(__name__)
try:
    import faulthandler
except ImportError:
    pass
else:
    faulthandler.enable()

from pyopencl.tools import pytest_generate_tests_for_pyopencl \
        as pytest_generate_tests

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__all__ = [
        "pytest_generate_tests",
        "cl"  # 'cl.create_some_context'
from loopy.version import LOOPY_USE_LANGUAGE_VERSION_2018_1  # noqa
def test_globals_decl_once_with_multi_subprogram(ctx_factory):
    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)
    np.random.seed(17)
    a = np.random.randn(16)
    cnst = np.random.randn(16)
    knl = lp.make_kernel(
            "{[i, ii]: 0<=i, ii<n}",
            """
            out[i] = a[i]+cnst[i]{id=first}
            out[ii] = 2*out[ii]+cnst[ii]{id=second}
            """,
            [lp.TemporaryVariable(
                'cnst', shape=('n'), initializer=cnst,
                scope=lp.temp_var_scope.GLOBAL,
    knl = lp.fix_parameters(knl, n=16)
    knl = lp.add_barrier(knl, "id:first", "id:second")

    knl = lp.split_iname(knl, "i", 2, outer_tag="g.0", inner_tag="l.0")
    knl = lp.split_iname(knl, "ii", 2, outer_tag="g.0", inner_tag="l.0")
    evt, (out,) = knl(queue, a=a)
    assert np.linalg.norm(out-((2*(a+cnst)+cnst))) <= 1e-15


    #ctx = ctx_factory()
            "{[i]: 0<=i<n}",
            """
                f(x) := x*a[x]
                g(x) := 12 + f(x)
                h(x) := 1 + g(x) + 20*g$two(x)

                a[i] = h$one(i) * h$two(i)
    knl = lp.expand_subst(knl, "... > id:h and tag:two > id:g and tag:two")
    print(knl)
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    sr_keys = list(knl.substitutions.keys())
    for letter, how_many in [
            ("f", 1),
            ("g", 1),
            ("h", 2)
            ]:
        substs_with_letter = sum(1 for k in sr_keys if k.startswith(letter))
        assert substs_with_letter == how_many


def test_type_inference_no_artificial_doubles(ctx_factory):
    ctx = ctx_factory()

            "{[i]: 0<=i<n}",
            """
                <> bb = a[i] - b[i]
                c[i] = bb
                """,
            [
                lp.GlobalArg("a", np.float32, shape=("n",)),
                lp.GlobalArg("b", np.float32, shape=("n",)),
                lp.GlobalArg("c", np.float32, shape=("n",)),
                lp.ValueArg("n", np.int32),
                ],
    knl = lp.preprocess_kernel(knl, ctx.devices[0])
    for k in lp.generate_loop_schedules(knl):
        code = lp.generate_code(k)
        assert "double" not in code


def test_type_inference_with_type_dependencies():
    knl = lp.make_kernel(
            "{[i]: i=0}",
            """
            <>a = 99
            a = a + 1
            <>b = 0
            <>c = 1
            b = b + c + 1.0
            c = b + c
            <>d = b + 2 + 1j
            """,
    knl = lp.infer_unknown_types(knl)

    from loopy.types import to_loopy_type
    assert knl.temporary_variables["a"].dtype == to_loopy_type(np.int32)
    assert knl.temporary_variables["b"].dtype == to_loopy_type(np.float32)
    assert knl.temporary_variables["c"].dtype == to_loopy_type(np.float32)
    assert knl.temporary_variables["d"].dtype == to_loopy_type(np.complex128)


def test_sized_and_complex_literals(ctx_factory):
    ctx = ctx_factory()

            "{[i]: 0<=i<n}",
            """
                <> aa = 5jf
                <> bb = 5j
                a[i] = imag(aa)
                b[i] = imag(bb)
                c[i] = 5f
                """,
            [
                lp.GlobalArg("a", np.float32, shape=("n",)),
                lp.GlobalArg("b", np.float32, shape=("n",)),
                lp.GlobalArg("c", np.float32, shape=("n",)),
                lp.ValueArg("n", np.int32),
                ],
            assumptions="n>=1")

    lp.auto_test_vs_ref(knl, ctx, knl, parameters=dict(n=5))
def test_simple_side_effect(ctx_factory):
    ctx = ctx_factory()

            "{[i,j]: 0<=i,j<100}",
            """
                a[i] = a[i] + 1
                """,
            [lp.GlobalArg("a", np.float32, shape=(100,))]
            )

    knl = lp.preprocess_kernel(knl, ctx.devices[0])
    kernel_gen = lp.generate_loop_schedules(knl)

    for gen_knl in kernel_gen:
        print(gen_knl)
        compiled = lp.CompiledKernel(ctx, gen_knl)
        print(compiled.get_code())
def test_owed_barriers(ctx_factory):
    ctx = ctx_factory()

            [lp.GlobalArg("a", np.float32, shape=(100,))]
    knl = lp.preprocess_kernel(knl, ctx.devices[0])
    kernel_gen = lp.generate_loop_schedules(knl)

    for gen_knl in kernel_gen:
        compiled = lp.CompiledKernel(ctx, gen_knl)
        print(compiled.get_code())
            [lp.GlobalArg("a", np.float32, shape=(100,))],
    knl = lp.preprocess_kernel(knl, ctx.devices[0])
            lp.CompiledKernel(ctx, gen_knl).get_code()
def test_multi_cse(ctx_factory):
    ctx = ctx_factory()

            [lp.GlobalArg("a", np.float32, shape=(100,))],
    knl = lp.split_iname(knl, "i", 16, inner_tag="l.0")
    knl = lp.add_prefetch(knl, "a", [])
    knl = lp.preprocess_kernel(knl, ctx.devices[0])
    kernel_gen = lp.generate_loop_schedules(knl)

    for gen_knl in kernel_gen:
        compiled = lp.CompiledKernel(ctx, gen_knl)
        print(compiled.get_code())
# {{{ code generator fuzzing

def make_random_value():
    from random import randrange, uniform
    v = randrange(3)
    if v == 0:
        while True:
            z = randrange(-1000, 1000)
            if z:
                return z

    elif v == 1:
        return uniform(-10, 10)
    else:
        cval = uniform(-10, 10) + 1j*uniform(-10, 10)
        if randrange(0, 2) == 0:
            return np.complex128(cval)
        else:
            return np.complex128(cval)


def make_random_expression(var_values, size):
    from random import randrange
    import pymbolic.primitives as p
    v = randrange(1500)
    size[0] += 1
    if v < 500 and size[0] < 40:
        term_count = randrange(2, 5)
        if randrange(2) < 1:
            cls = p.Sum
        else:
            cls = p.Product
        return cls(tuple(
            make_random_expression(var_values, size)
            for i in range(term_count)))
    elif v < 750:
        return make_random_value()
    elif v < 1000:
        var_name = "var_%d" % len(var_values)
        assert var_name not in var_values
        var_values[var_name] = make_random_value()
        return p.Variable(var_name)
    elif v < 1250:
        # Cannot use '-' because that destroys numpy constants.
        return p.Sum((
            make_random_expression(var_values, size),
            - make_random_expression(var_values, size)))
        # Cannot use '/' because that destroys numpy constants.
        return p.Quotient(
                make_random_expression(var_values, size),
                make_random_expression(var_values, size))
def generate_random_fuzz_examples(count):
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    for i in range(count):
        size = [0]
        var_values = {}
        expr = make_random_expression(var_values, size)
        yield expr, var_values

def test_fuzz_code_generator(ctx_factory):
    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)

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    if ctx.devices[0].platform.vendor.startswith("Advanced Micro"):
        pytest.skip("crashes on AMD 15.12")

    #from expr_fuzz import get_fuzz_examples
    #for expr, var_values in get_fuzz_examples():
    for expr, var_values in generate_random_fuzz_examples(50):
        from pymbolic import evaluate
        try:
            true_value = evaluate(expr, var_values)
        except ZeroDivisionError:
            continue
            if isinstance(x, (complex, np.complexfloating)):
                return np.complex128
            else:
                return np.float64

        knl = lp.make_kernel("{ : }",
                [lp.Assignment("value", expr)],
                [lp.GlobalArg("value", np.complex128, shape=())]
                + [
                    lp.ValueArg(name, get_dtype(val))
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                    for name, val in six.iteritems(var_values)
                    ])
        ck = lp.CompiledKernel(ctx, knl)
        evt, (lp_value,) = ck(queue, out_host=True, **var_values)
        err = abs(true_value-lp_value)/abs(true_value)
        if abs(err) > 1e-10:
            print(80*"-")
            print("WRONG: rel error=%g" % err)
            print("true=%r" % true_value)
            print("loopy=%r" % lp_value)
            print(80*"-")
            print(ck.get_code())
            print(80*"-")
            print(var_values)
            print(80*"-")
            print(repr(expr))
            print(80*"-")
            print(expr)
            print(80*"-")
def test_bare_data_dependency(ctx_factory):
    dtype = np.dtype(np.float32)
    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)

                "[znirp] -> {[i]: 0<=i<znirp}",
                "<> znirp = n",
                "a[i] = 1",
                lp.GlobalArg("a", dtype, shape=("n"), order="C"),
                lp.ValueArg("n", np.int32),
    n = 20000
    evt, (a,) = cknl(queue, n=n, out_host=True)
    assert a.shape == (n,)
    assert (a == 1).all()
# {{{ test race detection
@pytest.mark.skipif("sys.version_info < (2,6)")
def test_ilp_write_race_detection_global(ctx_factory):
            "[n] -> {[i,j]: 0<=i,j<n }",
                "a[i] = 5+i+j",
                lp.GlobalArg("a", np.float32),
                lp.ValueArg("n", np.int32, approximately=1000),
            assumptions="n>=1")
    knl = lp.tag_inames(knl, dict(j="ilp"))
    knl = lp.preprocess_kernel(knl, ctx.devices[0])

    with lp.CacheMode(False):
        from loopy.diagnostic import WriteRaceConditionWarning
        from warnings import catch_warnings
        with catch_warnings(record=True) as warn_list:
            list(lp.generate_loop_schedules(knl))
            assert any(isinstance(w.message, WriteRaceConditionWarning)
                    for w in warn_list)
def test_ilp_write_race_avoidance_local(ctx_factory):
    ctx = ctx_factory()

            "{[i,j]: 0<=i<16 and 0<=j<17 }",
                "<> a[i] = 5+i+j",
    knl = lp.tag_inames(knl, dict(i="l.0", j="ilp"))

    knl = lp.preprocess_kernel(knl, ctx.devices[0])
    for k in lp.generate_loop_schedules(knl):
        assert k.temporary_variables["a"].shape == (16, 17)
def test_ilp_write_race_avoidance_private(ctx_factory):
    ctx = ctx_factory()

            "{[j]: 0<=j<16 }",
                "<> a = 5+j",
    knl = lp.tag_inames(knl, dict(j="ilp"))
    knl = lp.preprocess_kernel(knl, ctx.devices[0])
    for k in lp.generate_loop_schedules(knl):
        assert k.temporary_variables["a"].shape == (16,)
def test_write_parameter(ctx_factory):
    dtype = np.float32
            "{[i,j]: 0<=i,j<n }",
                a = sum((i,j), i*j)
                b = sum(i, sum(j, i*j))
                n = 15
                """,
                lp.GlobalArg("a", dtype, shape=()),
                lp.GlobalArg("b", dtype, shape=()),
                lp.ValueArg("n", np.int32, approximately=1000),
            assumptions="n>=1")
    import pytest
    with pytest.raises(RuntimeError):
        lp.CompiledKernel(ctx, knl).get_code()
# {{{ arg guessing
def test_arg_shape_guessing(ctx_factory):
            "{[i,j]: 0<=i,j<n }",
                a = 1.5 + sum((i,j), i*j)
                b[i, j] = i*j
                c[i+j, j] = b[j,i]
                """,
                lp.GlobalArg("a", shape=lp.auto),
                lp.GlobalArg("b", shape=lp.auto),
                lp.GlobalArg("c", shape=lp.auto),
                lp.ValueArg("n"),
            assumptions="n>=1")
    print(knl)
    print(lp.CompiledKernel(ctx, knl).get_highlighted_code())
def test_arg_guessing(ctx_factory):
    ctx = ctx_factory()
            "{[i,j]: 0<=i,j<n }",
            """
                a = 1.5 + sum((i,j), i*j)
                b[i, j] = i*j
                c[i+j, j] = b[j,i]
                """,
            assumptions="n>=1")

    print(knl)
    print(lp.CompiledKernel(ctx, knl).get_highlighted_code())
def test_arg_guessing_with_reduction(ctx_factory):
    #logging.basicConfig(level=logging.DEBUG)
    ctx = ctx_factory()

            "{[i,j]: 0<=i,j<n }",
            """
                a = 1.5 + simul_reduce(sum, (i,j), i*j)
                d = 1.5 + simul_reduce(sum, (i,j), b[i,j])
                b[i, j] = i*j
                c[i+j, j] = b[j,i]
                """,
            assumptions="n>=1")

    print(knl)
    print(lp.CompiledKernel(ctx, knl).get_highlighted_code())

def test_unknown_arg_shape(ctx_factory):
    ctx = ctx_factory()
    from loopy.target.pyopencl import PyOpenCLTarget
    from loopy.compiled import CompiledKernel
    bsize = [256, 0]

    knl = lp.make_kernel(
        "{[i,j]: 0<=i<n and 0<=j<m}",
        """
        for i
            <int32> gid = i/256
            <int32> start = gid*256
            for j
                a[start + j] = a[start + j] + j
            end
        end
        """,
        seq_dependencies=True,
        name="uniform_l",
        target=PyOpenCLTarget(),
        assumptions="m<=%d and m>=1 and n mod %d = 0" % (bsize[0], bsize[0]))

    knl = lp.add_and_infer_dtypes(knl, dict(a=np.float32))
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    kernel_info = CompiledKernel(ctx, knl).kernel_info(frozenset())  # noqa
def test_nonlinear_index(ctx_factory):
    ctx = ctx_factory()

            "{[i,j]: 0<=i,j<n }",
            """
                a[i*i] = 17
                """,
            [
                lp.GlobalArg("a", shape="n"),
                lp.ValueArg("n"),
                ],
            assumptions="n>=1")

    print(knl)
    print(lp.CompiledKernel(ctx, knl).get_highlighted_code())
def test_offsets_and_slicing(ctx_factory):
    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)

            "{[i,j]: 0<=i<n and 0<=j<m }",
            """
                b[i,j] = 2*a[i,j]
                """,
            assumptions="n>=1 and m>=1",
            default_offset=lp.auto)
    knl = lp.tag_data_axes(knl, "a,b", "stride:auto,stride:1")

    cknl = lp.CompiledKernel(ctx, knl)

    a_full = cl.clrandom.rand(queue, (n, n), np.float64)
    a_full_h = a_full.get()
    b_full = cl.clrandom.rand(queue, (n, n), np.float64)
    b_full_h = b_full.get()

    a_sub = (slice(3, 10), slice(5, 10))
    a = a_full[a_sub]

    b_sub = (slice(3+3, 10+3), slice(5+4, 10+4))
    b = b_full[b_sub]

    b_full_h[b_sub] = 2*a_full_h[a_sub]
    print(cknl.get_highlighted_code({"a": a.dtype}))
    cknl(queue, a=a, b=b)

    import numpy.linalg as la
    assert la.norm(b_full.get() - b_full_h) < 1e-13
def test_vector_ilp_with_prefetch(ctx_factory):
    ctx = ctx_factory()

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                # Tests that comma'd arguments interoperate with
                # argument guessing.
                lp.GlobalArg("out,a", np.float32, shape=lp.auto),
                "..."
                ])
    knl = lp.split_iname(knl, "i", 128, inner_tag="l.0")
    knl = lp.split_iname(knl, "i_outer", 4, outer_tag="g.0", inner_tag="ilp")
    knl = lp.add_prefetch(knl, "a", ["i_inner", "i_outer_inner"])
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    cknl = lp.CompiledKernel(ctx, knl)
    cknl.kernel_info()
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    code = cknl.get_code()
    assert len(list(re.finditer("barrier", code))) == 1
def test_c_instruction(ctx_factory):
    #logging.basicConfig(level=logging.DEBUG)
                lp.CInstruction("i,j", """
                    x = sin((float) i*j);
                lp.GlobalArg("a", shape=lp.auto, dtype=np.float32),
                lp.TemporaryVariable("x", np.float32),
                ],
            assumptions="n>=1")

    knl = lp.split_iname(knl, "i", 128, outer_tag="g.0", inner_tag="l.0")

    print(knl)
    print(lp.CompiledKernel(ctx, knl).get_highlighted_code())
def test_dependent_domain_insn_iname_finding(ctx_factory):
    ctx = ctx_factory()

            "{[isrc_box]: 0<=isrc_box<nsrc_boxes}",
            "{[isrc,idim]: isrc_start<=isrc<isrc_end and 0<=idim<dim}",
            ],
            """
                <> src_ibox = source_boxes[isrc_box]
                <> isrc_start = box_source_starts[src_ibox]
                <> isrc_end = isrc_start+box_source_counts_nonchild[src_ibox]
                <> strength = strengths[isrc] {id=set_strength}
                """,
            [
                lp.GlobalArg("box_source_starts,box_source_counts_nonchild",
                    None, shape=None),
                lp.GlobalArg("strengths",
                    None, shape="nsources"),
    print(knl)
    assert "isrc_box" in knl.insn_inames("set_strength")

    print(lp.CompiledKernel(ctx, knl).get_highlighted_code(
            dict(
                source_boxes=np.int32,
                box_source_starts=np.int32,
                box_source_counts_nonchild=np.int32,
                strengths=np.float64,
                nsources=np.int32,
def test_inames_deps_from_write_subscript(ctx_factory):
            "{[i,j]: 0<=i,j<n}",
            """
                <> src_ibox = source_boxes[i]
                <int32> something = 5
                a[src_ibox] = sum(j, something) {id=myred}
                """,
            [
                lp.GlobalArg("box_source_starts,box_source_counts_nonchild,a",
                    None, shape=None),
                "..."])

    print(knl)
    assert "i" in knl.insn_inames("myred")


def test_modulo_indexing(ctx_factory):
    ctx = ctx_factory()

            "{[i,j]: 0<=i<n and 0<=j<5}",
            """
                b[i] = sum(j, a[(i+j)%n])
                """,
            [
                lp.GlobalArg("a", None, shape="n"),
                "..."
                ]
            )

    print(knl)
    print(lp.CompiledKernel(ctx, knl).get_highlighted_code(
            dict(
                a=np.float32,
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@pytest.mark.parametrize("vec_len", [2, 3, 4, 8, 16])
def test_vector_types(ctx_factory, vec_len):
    ctx = ctx_factory()
            "{ [i,j]: 0<=i<n and 0<=j<vec_len }",
            "out[i,j] = 2*a[i,j]",
            [
                lp.GlobalArg("a", np.float32, shape=lp.auto),
                lp.GlobalArg("out", np.float32, shape=lp.auto),
                "..."
    knl = lp.fix_parameters(knl, vec_len=vec_len)

    ref_knl = knl

    knl = lp.tag_data_axes(knl, "out", "c,vec")
    knl = lp.tag_inames(knl, dict(j="unr"))

    knl = lp.split_iname(knl, "i", 128, outer_tag="g.0", inner_tag="l.0")

    lp.auto_test_vs_ref(ref_knl, ctx, knl,
            parameters=dict(
                n=20000
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def test_conditional(ctx_factory):
    #logging.basicConfig(level=logging.DEBUG)
    ctx = ctx_factory()
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    knl = lp.make_kernel(
            "{ [i,j]: 0<=i,j<n }",
            """
                <> my_a = a[i,j] {id=read_a}
                <> a_less_than_zero = my_a < 0 {dep=read_a,inames=i:j}
                my_a = 2*my_a {id=twice_a,dep=read_a,if=a_less_than_zero}
                my_a = my_a+1 {id=aplus,dep=twice_a,if=a_less_than_zero}
                out[i,j] = 2*my_a {dep=aplus}
                """,
            [
                lp.GlobalArg("a", np.float32, shape=lp.auto),
                lp.GlobalArg("out", np.float32, shape=lp.auto),
                "..."
                ])

    ref_knl = knl

    lp.auto_test_vs_ref(ref_knl, ctx, knl,
            parameters=dict(
                n=200
                ))


def test_ilp_loop_bound(ctx_factory):
    # The salient bit of this test is that a joint bound on (outer, inner)
    # from a split occurs in a setting where the inner loop has been ilp'ed.
    # In 'normal' parallel loops, the inner index is available for conditionals
    # throughout. In ILP'd loops, not so much.

    ctx = ctx_factory()
            "{ [i,j,k]: 0<=i,j,k<n }",
            """
            out[i,k] = sum(j, a[i,j]*b[j,k])
            """,
            [
                lp.GlobalArg("a,b", np.float32, shape=lp.auto),
                "...",
                ],
            assumptions="n>=1")

    ref_knl = knl

    knl = lp.prioritize_loops(knl, "j,i,k")
    knl = lp.split_iname(knl,  "k", 4, inner_tag="ilp")

    lp.auto_test_vs_ref(ref_knl, ctx, knl,
            parameters=dict(
                n=200
                ))


def test_arg_shape_uses_assumptions(ctx_factory):
    # If arg shape determination does not use assumptions, then it won't find a
    # static shape for out, which is at least 1 x 1 in size, but otherwise of
    # size n x n.
            "{ [i,j]: 0<=i,j<n }",
            """
            out[i,j] = 2*a[i,j]
            out[0,0] = 13.0
            """, assumptions="n>=1")


def test_slab_decomposition_does_not_double_execute(ctx_factory):
    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)

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        "a[i] = 2*a[i]",
        assumptions="n>=1")
    for outer_tag in ["for", "g.0"]:
        knl = ref_knl
        knl = lp.split_iname(knl, "i", 4, slabs=(0, 1), inner_tag="unr",
                outer_tag=outer_tag)
        knl = lp.prioritize_loops(knl, "i_outer")
        a = cl.array.empty(queue, 20, np.float32)
        a.fill(17)
        knl = lp.set_options(knl, write_cl=True)
        print("TEST-----------------------------------------")
        knl(queue, a=a_knl)
        print("REF-----------------------------------------")
        ref_knl(queue, a=a_ref)
        print("DONE-----------------------------------------")
        print("REF", a_ref)
        print("KNL", a_knl)
        print("_________________________________")

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def test_multiple_writes_to_local_temporary():
    # Loopy would previously only handle barrier insertion correctly if exactly
    # one instruction wrote to each local temporary. This tests that multiple
    # writes are OK.

        "{[i,e]: 0<=i<5 and 0<=e<nelements}",
        """
    knl = lp.tag_inames(knl, dict(i="l.0"))

    knl = lp.preprocess_kernel(knl)
    for k in lp.generate_loop_schedules(knl):
        code, _ = lp.generate_code(k)
        print(code)
def test_make_copy_kernel(ctx_factory):
    queue = cl.CommandQueue(ctx)
    intermediate_format = "f,f,sep"
    a1 = np.random.randn(1024, 4, 3)
    cknl1 = lp.make_copy_kernel(intermediate_format)
    cknl1 = lp.fix_parameters(cknl1, n2=3)
    cknl1 = lp.set_options(cknl1, write_cl=True)
    evt, a2 = cknl1(queue, input=a1)
    cknl2 = lp.make_copy_kernel("c,c,c", intermediate_format)
    cknl2 = lp.fix_parameters(cknl2, n2=3)
    evt, a3 = cknl2(queue, input=a2)
    assert (a1 == a3).all()
def test_auto_test_can_detect_problems(ctx_factory):
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    ref_knl = lp.make_kernel(
        "{[i,j]: 0<=i,j<n}",
        a[i,j] = 25
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    knl = lp.make_kernel(
        "{[i]: 0<=i<n}",
        """
        a[i,i] = 25
        """)
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    ref_knl = lp.add_and_infer_dtypes(ref_knl, dict(a=np.float32))
    knl = lp.add_and_infer_dtypes(knl, dict(a=np.float32))
    from loopy.diagnostic import AutomaticTestFailure
    with pytest.raises(AutomaticTestFailure):
        lp.auto_test_vs_ref(
                ref_knl, ctx, knl,
                parameters=dict(n=123))
def test_sci_notation_literal(ctx_factory):
    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)

    set_kernel = lp.make_kernel(
         ''' { [i]: 0<=i<12 } ''',
         ''' out[i] = 1e-12''')

    set_kernel = lp.set_options(set_kernel, write_cl=True)

    evt, (out,) = set_kernel(queue)

    assert (np.abs(out.get() - 1e-12) < 1e-20).all()


def test_variable_size_temporary():
    knl = lp.make_kernel(
         ''' { [i,j]: 0<=i,j<n } ''',
         ''' out[i] = sum(j, a[i,j])''')

    knl = lp.add_and_infer_dtypes(knl, {"a": np.float32})

    knl = lp.add_prefetch(
            knl, "a[:,:]", default_tag=None)

    # Make sure that code generation succeeds even if
    # there are variable-length arrays.
    knl = lp.preprocess_kernel(knl)
    for k in lp.generate_loop_schedules(knl):
        lp.generate_code(k)


def test_indexof(ctx_factory):
    ctx = ctx_factory()
    queue = cl.CommandQueue(ctx)

    knl = lp.make_kernel(
         ''' { [i,j]: 0<=i,j<5 } ''',
         ''' out[i,j] = indexof(out[i,j])''')

    knl = lp.set_options(knl, write_cl=True)

    (evt, (out,)) = knl(queue)
    out = out.get()

    assert np.array_equal(out.ravel(order="C"), np.arange(25))