279 lines
10 KiB
Python
279 lines
10 KiB
Python
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import importlib
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import codecs
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import unicodedata
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import pytest
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import numpy as np
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from numpy.f2py.crackfortran import markinnerspaces
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from . import util
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from numpy.f2py import crackfortran
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import textwrap
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class TestNoSpace(util.F2PyTest):
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# issue gh-15035: add handling for endsubroutine, endfunction with no space
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# between "end" and the block name
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sources = [util.getpath("tests", "src", "crackfortran", "gh15035.f")]
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def test_module(self):
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k = np.array([1, 2, 3], dtype=np.float64)
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w = np.array([1, 2, 3], dtype=np.float64)
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self.module.subb(k)
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assert np.allclose(k, w + 1)
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self.module.subc([w, k])
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assert np.allclose(k, w + 1)
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assert self.module.t0("23") == b"2"
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class TestPublicPrivate:
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def test_defaultPrivate(self):
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fpath = util.getpath("tests", "src", "crackfortran", "privatemod.f90")
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mod = crackfortran.crackfortran([str(fpath)])
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assert len(mod) == 1
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mod = mod[0]
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assert "private" in mod["vars"]["a"]["attrspec"]
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assert "public" not in mod["vars"]["a"]["attrspec"]
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assert "private" in mod["vars"]["b"]["attrspec"]
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assert "public" not in mod["vars"]["b"]["attrspec"]
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assert "private" not in mod["vars"]["seta"]["attrspec"]
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assert "public" in mod["vars"]["seta"]["attrspec"]
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def test_defaultPublic(self, tmp_path):
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fpath = util.getpath("tests", "src", "crackfortran", "publicmod.f90")
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mod = crackfortran.crackfortran([str(fpath)])
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assert len(mod) == 1
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mod = mod[0]
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assert "private" in mod["vars"]["a"]["attrspec"]
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assert "public" not in mod["vars"]["a"]["attrspec"]
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assert "private" not in mod["vars"]["seta"]["attrspec"]
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assert "public" in mod["vars"]["seta"]["attrspec"]
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def test_access_type(self, tmp_path):
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fpath = util.getpath("tests", "src", "crackfortran", "accesstype.f90")
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mod = crackfortran.crackfortran([str(fpath)])
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assert len(mod) == 1
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tt = mod[0]['vars']
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assert set(tt['a']['attrspec']) == {'private', 'bind(c)'}
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assert set(tt['b_']['attrspec']) == {'public', 'bind(c)'}
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assert set(tt['c']['attrspec']) == {'public'}
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class TestModuleProcedure():
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def test_moduleOperators(self, tmp_path):
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fpath = util.getpath("tests", "src", "crackfortran", "operators.f90")
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mod = crackfortran.crackfortran([str(fpath)])
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assert len(mod) == 1
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mod = mod[0]
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assert "body" in mod and len(mod["body"]) == 9
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assert mod["body"][1]["name"] == "operator(.item.)"
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assert "implementedby" in mod["body"][1]
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assert mod["body"][1]["implementedby"] == \
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["item_int", "item_real"]
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assert mod["body"][2]["name"] == "operator(==)"
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assert "implementedby" in mod["body"][2]
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assert mod["body"][2]["implementedby"] == ["items_are_equal"]
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assert mod["body"][3]["name"] == "assignment(=)"
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assert "implementedby" in mod["body"][3]
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assert mod["body"][3]["implementedby"] == \
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["get_int", "get_real"]
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def test_notPublicPrivate(self, tmp_path):
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fpath = util.getpath("tests", "src", "crackfortran", "pubprivmod.f90")
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mod = crackfortran.crackfortran([str(fpath)])
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assert len(mod) == 1
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mod = mod[0]
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assert mod['vars']['a']['attrspec'] == ['private', ]
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assert mod['vars']['b']['attrspec'] == ['public', ]
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assert mod['vars']['seta']['attrspec'] == ['public', ]
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class TestExternal(util.F2PyTest):
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# issue gh-17859: add external attribute support
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sources = [util.getpath("tests", "src", "crackfortran", "gh17859.f")]
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def test_external_as_statement(self):
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def incr(x):
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return x + 123
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r = self.module.external_as_statement(incr)
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assert r == 123
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def test_external_as_attribute(self):
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def incr(x):
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return x + 123
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r = self.module.external_as_attribute(incr)
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assert r == 123
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class TestCrackFortran(util.F2PyTest):
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# gh-2848: commented lines between parameters in subroutine parameter lists
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sources = [util.getpath("tests", "src", "crackfortran", "gh2848.f90")]
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def test_gh2848(self):
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r = self.module.gh2848(1, 2)
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assert r == (1, 2)
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class TestMarkinnerspaces:
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# gh-14118: markinnerspaces does not handle multiple quotations
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def test_do_not_touch_normal_spaces(self):
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test_list = ["a ", " a", "a b c", "'abcdefghij'"]
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for i in test_list:
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assert markinnerspaces(i) == i
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def test_one_relevant_space(self):
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assert markinnerspaces("a 'b c' \\' \\'") == "a 'b@_@c' \\' \\'"
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assert markinnerspaces(r'a "b c" \" \"') == r'a "b@_@c" \" \"'
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def test_ignore_inner_quotes(self):
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assert markinnerspaces("a 'b c\" \" d' e") == "a 'b@_@c\"@_@\"@_@d' e"
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assert markinnerspaces("a \"b c' ' d\" e") == "a \"b@_@c'@_@'@_@d\" e"
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def test_multiple_relevant_spaces(self):
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assert markinnerspaces("a 'b c' 'd e'") == "a 'b@_@c' 'd@_@e'"
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assert markinnerspaces(r'a "b c" "d e"') == r'a "b@_@c" "d@_@e"'
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class TestDimSpec(util.F2PyTest):
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"""This test suite tests various expressions that are used as dimension
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specifications.
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There exists two usage cases where analyzing dimensions
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specifications are important.
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In the first case, the size of output arrays must be defined based
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on the inputs to a Fortran function. Because Fortran supports
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arbitrary bases for indexing, for instance, `arr(lower:upper)`,
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f2py has to evaluate an expression `upper - lower + 1` where
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`lower` and `upper` are arbitrary expressions of input parameters.
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The evaluation is performed in C, so f2py has to translate Fortran
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expressions to valid C expressions (an alternative approach is
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that a developer specifies the corresponding C expressions in a
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.pyf file).
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In the second case, when user provides an input array with a given
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size but some hidden parameters used in dimensions specifications
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need to be determined based on the input array size. This is a
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harder problem because f2py has to solve the inverse problem: find
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a parameter `p` such that `upper(p) - lower(p) + 1` equals to the
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size of input array. In the case when this equation cannot be
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solved (e.g. because the input array size is wrong), raise an
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error before calling the Fortran function (that otherwise would
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likely crash Python process when the size of input arrays is
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wrong). f2py currently supports this case only when the equation
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is linear with respect to unknown parameter.
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"""
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suffix = ".f90"
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code_template = textwrap.dedent("""
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function get_arr_size_{count}(a, n) result (length)
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integer, intent(in) :: n
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integer, dimension({dimspec}), intent(out) :: a
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integer length
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length = size(a)
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end function
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subroutine get_inv_arr_size_{count}(a, n)
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integer :: n
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! the value of n is computed in f2py wrapper
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!f2py intent(out) n
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integer, dimension({dimspec}), intent(in) :: a
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if (a({first}).gt.0) then
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print*, "a=", a
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endif
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end subroutine
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""")
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linear_dimspecs = [
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"n", "2*n", "2:n", "n/2", "5 - n/2", "3*n:20", "n*(n+1):n*(n+5)",
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"2*n, n"
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]
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nonlinear_dimspecs = ["2*n:3*n*n+2*n"]
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all_dimspecs = linear_dimspecs + nonlinear_dimspecs
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code = ""
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for count, dimspec in enumerate(all_dimspecs):
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lst = [(d.split(":")[0] if ":" in d else "1") for d in dimspec.split(',')]
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code += code_template.format(
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count=count,
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dimspec=dimspec,
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first=", ".join(lst),
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)
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@pytest.mark.parametrize("dimspec", all_dimspecs)
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def test_array_size(self, dimspec):
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count = self.all_dimspecs.index(dimspec)
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get_arr_size = getattr(self.module, f"get_arr_size_{count}")
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for n in [1, 2, 3, 4, 5]:
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sz, a = get_arr_size(n)
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assert a.size == sz
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@pytest.mark.parametrize("dimspec", all_dimspecs)
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def test_inv_array_size(self, dimspec):
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count = self.all_dimspecs.index(dimspec)
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get_arr_size = getattr(self.module, f"get_arr_size_{count}")
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get_inv_arr_size = getattr(self.module, f"get_inv_arr_size_{count}")
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for n in [1, 2, 3, 4, 5]:
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sz, a = get_arr_size(n)
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if dimspec in self.nonlinear_dimspecs:
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# one must specify n as input, the call we'll ensure
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# that a and n are compatible:
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n1 = get_inv_arr_size(a, n)
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else:
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# in case of linear dependence, n can be determined
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# from the shape of a:
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n1 = get_inv_arr_size(a)
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# n1 may be different from n (for instance, when `a` size
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# is a function of some `n` fraction) but it must produce
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# the same sized array
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sz1, _ = get_arr_size(n1)
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assert sz == sz1, (n, n1, sz, sz1)
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class TestModuleDeclaration:
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def test_dependencies(self, tmp_path):
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fpath = util.getpath("tests", "src", "crackfortran", "foo_deps.f90")
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mod = crackfortran.crackfortran([str(fpath)])
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assert len(mod) == 1
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assert mod[0]["vars"]["abar"]["="] == "bar('abar')"
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class TestEval(util.F2PyTest):
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def test_eval_scalar(self):
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eval_scalar = crackfortran._eval_scalar
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assert eval_scalar('123', {}) == '123'
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assert eval_scalar('12 + 3', {}) == '15'
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assert eval_scalar('a + b', dict(a=1, b=2)) == '3'
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assert eval_scalar('"123"', {}) == "'123'"
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class TestFortranReader(util.F2PyTest):
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@pytest.mark.parametrize("encoding",
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['ascii', 'utf-8', 'utf-16', 'utf-32'])
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def test_input_encoding(self, tmp_path, encoding):
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# gh-635
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f_path = tmp_path / f"input_with_{encoding}_encoding.f90"
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with f_path.open('w', encoding=encoding) as ff:
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ff.write("""
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subroutine foo()
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end subroutine foo
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""")
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mod = crackfortran.crackfortran([str(f_path)])
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assert mod[0]['name'] == 'foo'
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class TestUnicodeComment(util.F2PyTest):
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sources = [util.getpath("tests", "src", "crackfortran", "unicode_comment.f90")]
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@pytest.mark.skipif(
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(importlib.util.find_spec("charset_normalizer") is None),
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reason="test requires charset_normalizer which is not installed",
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)
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def test_encoding_comment(self):
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self.module.foo(3)
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