from __future__ import division, absolute_import __copyright__ = "Copyright (C) 2015 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 sys import numpy as np import loopy as lp import pyopencl as cl import pyopencl.clrandom # noqa import pytest import logging logger = logging.getLogger(__name__) from pyopencl.tools import pytest_generate_tests_for_pyopencl \ as pytest_generate_tests __all__ = [ "pytest_generate_tests", "cl" # 'cl.create_some_context' ] pytestmark = pytest.mark.importorskip("fparser") def test_fill(ctx_factory): fortran_src = """ subroutine fill(out, a, n) implicit none real*8 a, out(n) integer n, i do i = 1, n out(i) = a end do end !$loopy begin ! ! fill, = lp.parse_fortran(SOURCE) ! fill = lp.split_iname(fill, "i", split_amount, ! outer_tag="g.0", inner_tag="l.0") ! RESULT = [fill] ! !$loopy end """ knl, = lp.parse_transformed_fortran(fortran_src, pre_transform_code="split_amount = 128") assert "i_inner" in knl.all_inames() ctx = ctx_factory() lp.auto_test_vs_ref(knl, ctx, knl, parameters=dict(n=5, a=5)) def test_fill_const(ctx_factory): fortran_src = """ subroutine fill(out, a, n) implicit none real*8 a, out(n) integer n, i do i = 1, n out(i) = 3.45 end do end """ knl, = lp.parse_fortran(fortran_src) ctx = ctx_factory() lp.auto_test_vs_ref(knl, ctx, knl, parameters=dict(n=5, a=5)) def test_asterisk_in_shape(ctx_factory): fortran_src = """ subroutine fill(out, out2, inp, n) implicit none real*8 a, out(n), out2(n), inp(*) integer n, i do i = 1, n a = inp(n) out(i) = 5*a out2(i) = 6*a end do end """ knl, = lp.parse_fortran(fortran_src) ctx = ctx_factory() queue = cl.CommandQueue(ctx) knl(queue, inp=np.array([1, 2, 3.]), n=3) def test_assignment_to_subst(ctx_factory): fortran_src = """ subroutine fill(out, out2, inp, n) implicit none real*8 a, out(n), out2(n), inp(n) integer n, i do i = 1, n a = inp(i) out(i) = 5*a out2(i) = 6*a end do end """ knl, = lp.parse_fortran(fortran_src) ref_knl = knl knl = lp.assignment_to_subst(knl, "a", "i") ctx = ctx_factory() lp.auto_test_vs_ref(ref_knl, ctx, knl, parameters=dict(n=5)) def test_assignment_to_subst_two_defs(ctx_factory): fortran_src = """ subroutine fill(out, out2, inp, n) implicit none real*8 a, out(n), out2(n), inp(n) integer n, i do i = 1, n a = inp(i) out(i) = 5*a a = 3*inp(n) out2(i) = 6*a end do end """ knl, = lp.parse_fortran(fortran_src) ref_knl = knl knl = lp.assignment_to_subst(knl, "a") ctx = ctx_factory() lp.auto_test_vs_ref(ref_knl, ctx, knl, parameters=dict(n=5)) def test_assignment_to_subst_indices(ctx_factory): fortran_src = """ subroutine fill(out, out2, inp, n) implicit none real*8 a(n), out(n), out2(n), inp(n) integer n, i do i = 1, n a(i) = 6*inp(i) enddo do i = 1, n out(i) = 5*a(i) end do end """ knl, = lp.parse_fortran(fortran_src) knl = lp.fix_parameters(knl, n=5) ref_knl = knl assert "a" in knl.temporary_variables knl = lp.assignment_to_subst(knl, "a") assert "a" not in knl.temporary_variables ctx = ctx_factory() lp.auto_test_vs_ref(ref_knl, ctx, knl) def test_if(ctx_factory): fortran_src = """ subroutine fill(out, out2, inp, n) implicit none real*8 a, b, out(n), out2(n), inp(n) integer n, i, j do i = 1, n a = inp(i) if (a.ge.3) then b = 2*a do j = 1,3 b = 3 * b end do out(i) = 5*b else out(i) = 4*a endif end do end """ knl, = lp.parse_fortran(fortran_src) ref_knl = knl knl = lp.assignment_to_subst(knl, "a") ctx = ctx_factory() lp.auto_test_vs_ref(ref_knl, ctx, knl, parameters=dict(n=5)) def test_tagged(ctx_factory): fortran_src = """ subroutine rot_norm(out, alpha, out2, inp, inp2, n) implicit none real*8 a, b, r, out(n), out2(n), inp(n), inp2(n) real*8 alpha integer n, i do i = 1, n !$loopy begin tagged: input a = cos(alpha)*inp(i) + sin(alpha)*inp2(i) b = -sin(alpha)*inp(i) + cos(alpha)*inp2(i) !$loopy end tagged: input r = sqrt(a**2 + b**2) a = a/r b = b/r out(i) = a out2(i) = b end do end """ knl, = lp.parse_fortran(fortran_src) assert sum(1 for insn in lp.find_instructions(knl, "tag:input")) == 2 @pytest.mark.parametrize("buffer_inames", [ "", "i_inner,j_inner", ]) def test_matmul(ctx_factory, buffer_inames): logging.basicConfig(level=logging.INFO) fortran_src = """ subroutine dgemm(m,n,l,a,b,c) implicit none real*8 a(m,l),b(l,n),c(m,n) integer m,n,k,i,j,l do j = 1,n do i = 1,m do k = 1,l c(i,j) = c(i,j) + b(k,j)*a(i,k) end do end do end do end subroutine """ knl, = lp.parse_fortran(fortran_src) assert len(knl.domains) == 1 ref_knl = knl knl = lp.split_iname(knl, "i", 16, outer_tag="g.0", inner_tag="l.1") knl = lp.split_iname(knl, "j", 8, outer_tag="g.1", inner_tag="l.0") knl = lp.split_iname(knl, "k", 32) knl = lp.assume(knl, "n mod 32 = 0") knl = lp.assume(knl, "m mod 32 = 0") knl = lp.assume(knl, "l mod 16 = 0") knl = lp.extract_subst(knl, "a_acc", "a[i1,i2]", parameters="i1, i2") knl = lp.extract_subst(knl, "b_acc", "b[i1,i2]", parameters="i1, i2") knl = lp.precompute(knl, "a_acc", "k_inner,i_inner") knl = lp.precompute(knl, "b_acc", "j_inner,k_inner") knl = lp.buffer_array(knl, "c", buffer_inames=buffer_inames, init_expression="0", store_expression="base+buffer") ctx = ctx_factory() lp.auto_test_vs_ref(ref_knl, ctx, knl, parameters=dict(n=128, m=128, l=128)) @pytest.mark.xfail def test_batched_sparse(): fortran_src = """ subroutine sparse(rowstarts, colindices, values, m, n, nvecs, nvals, x, y) implicit none integer rowstarts(m+1), colindices(nvals) real*8 values(nvals) real*8 x(n, nvecs), y(n, nvecs), rowsum(nvecs) integer m, n, rowstart, rowend, length, nvals, nvecs integer i, j, k do i = 1, m rowstart = rowstarts(i) rowend = rowstarts(i+1) length = rowend - rowstart do k = 1, nvecs rowsum(k) = 0 enddo do k = 1, nvecs do j = 1, length rowsum(k) = rowsum(k) + & x(colindices(rowstart+j-1),k)*values(rowstart+j-1) end do end do do k = 1, nvecs y(i,k) = rowsum(k) end do end do end """ knl, = lp.parse_fortran(fortran_src) knl = lp.split_iname(knl, "i", 128) knl = lp.tag_inames(knl, {"i_outer": "g.0"}) knl = lp.tag_inames(knl, {"i_inner": "l.0"}) knl = lp.add_prefetch(knl, "values") knl = lp.add_prefetch(knl, "colindices") knl = lp.fix_parameters(knl, nvecs=4) def test_fuse_kernels(ctx_factory): fortran_template = """ subroutine {name}(nelements, ndofs, result, d, q) implicit none integer e, i, j, k integer nelements, ndofs real*8 result(nelements, ndofs, ndofs) real*8 q(nelements, ndofs, ndofs) real*8 d(ndofs, ndofs) real*8 prev do e = 1,nelements do i = 1,ndofs do j = 1,ndofs do k = 1,ndofs {inner} end do end do end do end do end subroutine """ xd_line = """ prev = result(e,i,j) result(e,i,j) = prev + d(i,k)*q(e,i,k) """ yd_line = """ prev = result(e,i,j) result(e,i,j) = prev + d(i,k)*q(e,k,j) """ xderiv, = lp.parse_fortran( fortran_template.format(inner=xd_line, name="xderiv")) yderiv, = lp.parse_fortran( fortran_template.format(inner=yd_line, name="yderiv")) xyderiv, = lp.parse_fortran( fortran_template.format( inner=(xd_line + "\n" + yd_line), name="xyderiv")) knl = lp.fuse_kernels((xderiv, yderiv)) knl = lp.set_loop_priority(knl, "e,i,j,k") assert len(knl.temporary_variables) == 2 # This is needed for correctness, otherwise ordering could foul things up. knl = lp.assignment_to_subst(knl, "prev") knl = lp.assignment_to_subst(knl, "prev_0") ctx = ctx_factory() lp.auto_test_vs_ref(xyderiv, ctx, knl, parameters=dict(nelements=20, ndofs=4)) def test_parse_and_fuse_two_kernels(): fortran_src = """ subroutine fill(out, a, n) implicit none real*8 a, out(n) integer n, i do i = 1, n out(i) = a end do end subroutine twice(out, n) implicit none real*8 out(n) integer n, i do i = 1, n out(i) = 2*out(i) end do end !$loopy begin ! ! fill, twice = lp.parse_fortran(SOURCE) ! knl = lp.fuse_kernels((fill, twice)) ! print(knl) ! RESULT = [knl] ! !$loopy end """ knl, = lp.parse_transformed_fortran(fortran_src) def test_precompute_some_exist(ctx_factory): fortran_src = """ subroutine dgemm(m,n,l,a,b,c) implicit none real*8 a(m,l),b(l,n),c(m,n) integer m,n,k,i,j,l do j = 1,n do i = 1,m do k = 1,l c(i,j) = c(i,j) + b(k,j)*a(i,k) end do end do end do end subroutine """ knl, = lp.parse_fortran(fortran_src) assert len(knl.domains) == 1 knl = lp.split_iname(knl, "i", 8, outer_tag="g.0", inner_tag="l.1") knl = lp.split_iname(knl, "j", 8, outer_tag="g.1", inner_tag="l.0") knl = lp.split_iname(knl, "k", 8) knl = lp.assume(knl, "n mod 8 = 0") knl = lp.assume(knl, "m mod 8 = 0") knl = lp.assume(knl, "l mod 8 = 0") knl = lp.extract_subst(knl, "a_acc", "a[i1,i2]", parameters="i1, i2") knl = lp.extract_subst(knl, "b_acc", "b[i1,i2]", parameters="i1, i2") knl = lp.precompute(knl, "a_acc", "k_inner,i_inner", precompute_inames="ktemp,itemp") knl = lp.precompute(knl, "b_acc", "j_inner,k_inner", precompute_inames="itemp,k2temp") ref_knl = knl ctx = ctx_factory() lp.auto_test_vs_ref(ref_knl, ctx, knl, parameters=dict(n=128, m=128, l=128)) if __name__ == "__main__": if len(sys.argv) > 1: exec(sys.argv[1]) else: from py.test.cmdline import main main([__file__]) # vim: foldmethod=marker