225 lines
5.2 KiB
Python
225 lines
5.2 KiB
Python
from sympy.external import import_module
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from sympy.testing.pytest import raises
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import ctypes
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if import_module('llvmlite'):
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import sympy.printing.llvmjitcode as g
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else:
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disabled = True
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import sympy
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from sympy.abc import a, b, n
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# copied from numpy.isclose documentation
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def isclose(a, b):
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rtol = 1e-5
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atol = 1e-8
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return abs(a-b) <= atol + rtol*abs(b)
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def test_simple_expr():
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e = a + 1.0
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f = g.llvm_callable([a], e)
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res = float(e.subs({a: 4.0}).evalf())
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jit_res = f(4.0)
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assert isclose(jit_res, res)
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def test_two_arg():
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e = 4.0*a + b + 3.0
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f = g.llvm_callable([a, b], e)
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res = float(e.subs({a: 4.0, b: 3.0}).evalf())
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jit_res = f(4.0, 3.0)
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assert isclose(jit_res, res)
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def test_func():
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e = 4.0*sympy.exp(-a)
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f = g.llvm_callable([a], e)
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res = float(e.subs({a: 1.5}).evalf())
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jit_res = f(1.5)
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assert isclose(jit_res, res)
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def test_two_func():
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e = 4.0*sympy.exp(-a) + sympy.exp(b)
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f = g.llvm_callable([a, b], e)
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res = float(e.subs({a: 1.5, b: 2.0}).evalf())
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jit_res = f(1.5, 2.0)
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assert isclose(jit_res, res)
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def test_two_sqrt():
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e = 4.0*sympy.sqrt(a) + sympy.sqrt(b)
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f = g.llvm_callable([a, b], e)
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res = float(e.subs({a: 1.5, b: 2.0}).evalf())
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jit_res = f(1.5, 2.0)
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assert isclose(jit_res, res)
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def test_two_pow():
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e = a**1.5 + b**7
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f = g.llvm_callable([a, b], e)
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res = float(e.subs({a: 1.5, b: 2.0}).evalf())
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jit_res = f(1.5, 2.0)
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assert isclose(jit_res, res)
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def test_callback():
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e = a + 1.2
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f = g.llvm_callable([a], e, callback_type='scipy.integrate.test')
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m = ctypes.c_int(1)
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array_type = ctypes.c_double * 1
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inp = {a: 2.2}
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array = array_type(inp[a])
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jit_res = f(m, array)
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res = float(e.subs(inp).evalf())
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assert isclose(jit_res, res)
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def test_callback_cubature():
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e = a + 1.2
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f = g.llvm_callable([a], e, callback_type='cubature')
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m = ctypes.c_int(1)
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array_type = ctypes.c_double * 1
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inp = {a: 2.2}
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array = array_type(inp[a])
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out_array = array_type(0.0)
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jit_ret = f(m, array, None, m, out_array)
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assert jit_ret == 0
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res = float(e.subs(inp).evalf())
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assert isclose(out_array[0], res)
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def test_callback_two():
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e = 3*a*b
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f = g.llvm_callable([a, b], e, callback_type='scipy.integrate.test')
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m = ctypes.c_int(2)
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array_type = ctypes.c_double * 2
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inp = {a: 0.2, b: 1.7}
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array = array_type(inp[a], inp[b])
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jit_res = f(m, array)
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res = float(e.subs(inp).evalf())
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assert isclose(jit_res, res)
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def test_callback_alt_two():
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d = sympy.IndexedBase('d')
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e = 3*d[0]*d[1]
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f = g.llvm_callable([n, d], e, callback_type='scipy.integrate.test')
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m = ctypes.c_int(2)
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array_type = ctypes.c_double * 2
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inp = {d[0]: 0.2, d[1]: 1.7}
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array = array_type(inp[d[0]], inp[d[1]])
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jit_res = f(m, array)
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res = float(e.subs(inp).evalf())
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assert isclose(jit_res, res)
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def test_multiple_statements():
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# Match return from CSE
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e = [[(b, 4.0*a)], [b + 5]]
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f = g.llvm_callable([a], e)
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b_val = e[0][0][1].subs({a: 1.5})
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res = float(e[1][0].subs({b: b_val}).evalf())
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jit_res = f(1.5)
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assert isclose(jit_res, res)
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f_callback = g.llvm_callable([a], e, callback_type='scipy.integrate.test')
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m = ctypes.c_int(1)
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array_type = ctypes.c_double * 1
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array = array_type(1.5)
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jit_callback_res = f_callback(m, array)
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assert isclose(jit_callback_res, res)
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def test_cse():
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e = a*a + b*b + sympy.exp(-a*a - b*b)
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e2 = sympy.cse(e)
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f = g.llvm_callable([a, b], e2)
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res = float(e.subs({a: 2.3, b: 0.1}).evalf())
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jit_res = f(2.3, 0.1)
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assert isclose(jit_res, res)
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def eval_cse(e, sub_dict):
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tmp_dict = {}
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for tmp_name, tmp_expr in e[0]:
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e2 = tmp_expr.subs(sub_dict)
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e3 = e2.subs(tmp_dict)
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tmp_dict[tmp_name] = e3
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return [e.subs(sub_dict).subs(tmp_dict) for e in e[1]]
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def test_cse_multiple():
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e1 = a*a
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e2 = a*a + b*b
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e3 = sympy.cse([e1, e2])
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raises(NotImplementedError,
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lambda: g.llvm_callable([a, b], e3, callback_type='scipy.integrate'))
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f = g.llvm_callable([a, b], e3)
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jit_res = f(0.1, 1.5)
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assert len(jit_res) == 2
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res = eval_cse(e3, {a: 0.1, b: 1.5})
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assert isclose(res[0], jit_res[0])
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assert isclose(res[1], jit_res[1])
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def test_callback_cubature_multiple():
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e1 = a*a
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e2 = a*a + b*b
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e3 = sympy.cse([e1, e2, 4*e2])
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f = g.llvm_callable([a, b], e3, callback_type='cubature')
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# Number of input variables
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ndim = 2
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# Number of output expression values
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outdim = 3
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m = ctypes.c_int(ndim)
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fdim = ctypes.c_int(outdim)
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array_type = ctypes.c_double * ndim
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out_array_type = ctypes.c_double * outdim
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inp = {a: 0.2, b: 1.5}
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array = array_type(inp[a], inp[b])
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out_array = out_array_type()
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jit_ret = f(m, array, None, fdim, out_array)
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assert jit_ret == 0
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res = eval_cse(e3, inp)
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assert isclose(out_array[0], res[0])
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assert isclose(out_array[1], res[1])
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assert isclose(out_array[2], res[2])
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def test_symbol_not_found():
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e = a*a + b
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raises(LookupError, lambda: g.llvm_callable([a], e))
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def test_bad_callback():
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e = a
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raises(ValueError, lambda: g.llvm_callable([a], e, callback_type='bad_callback'))
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