api: add shift and fd order option to all FD operators:

devitocodes · Nov 3, 2023 · 034687a · 034687a
1 parent 40d9fbc
commit 034687a
Show file tree

Hide file tree

Showing 5 changed files with 185 additions and 73 deletions.
diff --git a/devito/finite_differences/differentiable.py b/devito/finite_differences/differentiable.py
@@ -269,21 +269,32 @@ def laplace(self):
         Generates a symbolic expression for the Laplacian, the second
         derivative w.r.t all spatial Dimensions.
         """
+        return self.laplacian()
+
+    def laplacian(self, shift=None, order=None):
+        order = order or self.space_order
         space_dims = [d for d in self.dimensions if d.is_Space]
+        shift_x0 = make_shift_x0(shift, (len(space_dims),))
         derivs = tuple('d%s2' % d.name for d in space_dims)
-        return Add(*[getattr(self, d) for d in derivs])
+        return Add(*[getattr(self, d)(x0=shift_x0(shift, space_dims[i], None, i),
+                                      fd_order=order)
+                     for i, d in enumerate(derivs)])
 
-    def div(self, shift=None):
+    def div(self, shift=None, order=None):
         space_dims = [d for d in self.dimensions if d.is_Space]
         shift_x0 = make_shift_x0(shift, (len(space_dims),))
-        return Add(*[getattr(self, 'd%s' % d.name)(x0=shift_x0(shift, d, None, i))
+        order = order or self.space_order
+        return Add(*[getattr(self, 'd%s' % d.name)(x0=shift_x0(shift, d, None, i),
+                                                   fd_order=order)
                      for i, d in enumerate(space_dims)])
 
-    def grad(self, shift=None):
+    def grad(self, shift=None, order=None):
         from devito.types.tensor import VectorFunction, VectorTimeFunction
         space_dims = [d for d in self.dimensions if d.is_Space]
         shift_x0 = make_shift_x0(shift, (len(space_dims),))
-        comps = [getattr(self, 'd%s' % d.name)(x0=shift_x0(shift, d, None, i))
+        order = order or self.space_order
+        comps = [getattr(self, 'd%s' % d.name)(x0=shift_x0(shift, d, None, i),
+                                               fd_order=order)
                  for i, d in enumerate(space_dims)]
         vec_func = VectorTimeFunction if self.is_TimeDependent else VectorFunction
         return vec_func(name='grad_%s' % self.name, time_order=self.time_order,

diff --git a/devito/finite_differences/operators.py b/devito/finite_differences/operators.py
@@ -1,4 +1,4 @@
-def div(func, shift=None):
+def div(func, shift=None, order=None):
     """
     Divergence of the input Function.
 
@@ -7,12 +7,12 @@ def div(func, shift=None):
     func : Function or TensorFunction
     """
     try:
-        return func.div(shift=shift)
+        return func.div(shift=shift, order=order)
     except AttributeError:
         return 0
 
 
-def grad(func, shift=None):
+def grad(func, shift=None, order=None):
     """
     Gradient of the input Function.
 
@@ -21,12 +21,12 @@ def grad(func, shift=None):
     func : Function or VectorFunction
     """
     try:
-        return func.grad(shift=shift)
+        return func.grad(shift=shift, order=order)
     except AttributeError:
         raise AttributeError("Gradient not supported for class %s" % func.__class__)
 
 
-def curl(func):
+def curl(func, shift=None, order=None):
     """
     Curl of the input Function.
 
@@ -35,12 +35,12 @@ def curl(func):
     func : VectorFunction
     """
     try:
-        return func.curl
+        return func.curl(shift=shift, order=order)
     except AttributeError:
         raise AttributeError("Curl only supported for 3D VectorFunction")
 
 
-def laplace(func):
+def laplace(func, shift=None, order=None):
     """
     Laplacian of the input Function.
 
@@ -49,7 +49,7 @@ def laplace(func):
     func : Function or TensorFunction
     """
     try:
-        return func.laplace
+        return func.laplacian(shift=shift, order=order)
     except AttributeError:
         return 0
 

diff --git a/devito/types/tensor.py b/devito/types/tensor.py
@@ -129,6 +129,8 @@ def __getattr__(self, name):
         -----
         This method acts as a fallback for __getattribute__
         """
+        if name in ['_sympystr', '_pretty', '_latex']:
+            return super().__getattr__(self, name)
         try:
             return self.applyfunc(lambda x: x if x == 0 else getattr(x, name))
         except:
@@ -190,33 +192,44 @@ def values(self):
         else:
             return super(TensorFunction, self).values()
 
-    def div(self, shift=None):
+    def div(self, shift=None, order=None):
         """
         Divergence of the TensorFunction (is a VectorFunction).
         """
         comps = []
         func = vec_func(self)
         ndim = len(self.space_dimensions)
         shift_x0 = make_shift_x0(shift, (ndim, ndim))
+        order = order or self.space_order
         for i in range(len(self.space_dimensions)):
             comps.append(sum([getattr(self[j, i], 'd%s' % d.name)
-                              (x0=shift_x0(shift, d, i, j))
+                              (x0=shift_x0(shift, d, i, j), fd_order=order)
                               for j, d in enumerate(self.space_dimensions)]))
         return func._new(comps)
 
     @property
     def laplace(self):
+        """
+        Laplacian of the TensorFunction.
+        """
+        return self.laplacian()
+
+    def laplacian(self, shift=None, order=None):
         """
         Laplacian of the TensorFunction.
         """
         comps = []
         func = vec_func(self)
-        for j, d in enumerate(self.space_dimensions):
+        order = order or self.space_order
+        ndim = len(self.space_dimensions)
+        shift_x0 = make_shift_x0(shift, (ndim, ndim))
+        for j in range(ndim):
             comps.append(sum([getattr(self[j, i], 'd%s2' % d.name)
+                              (x0=shift_x0(shift, d, j, i), fd_order=order)
                               for i, d in enumerate(self.space_dimensions)]))
         return func._new(comps)
 
-    def grad(self, shift=None):
+    def grad(self, shift=None, order=None):
         raise AttributeError("Gradient of a second order tensor not supported")
 
     def new_from_mat(self, mat):
@@ -282,49 +295,72 @@ def __str__(self):
 
     __repr__ = __str__
 
-    def div(self, shift=None):
+    def div(self, shift=None, order=None):
         """
         Divergence of the VectorFunction, creates the divergence Function.
         """
         shift_x0 = make_shift_x0(shift, (len(self.space_dimensions),))
-        return sum([getattr(self[i], 'd%s' % d.name)(x0=shift_x0(shift, d, None, i))
+        order = order or self.space_order
+        return sum([getattr(self[i], 'd%s' % d.name)(x0=shift_x0(shift, d, None, i),
+                                                     fd_order=order)
                     for i, d in enumerate(self.space_dimensions)])
 
     @property
     def laplace(self):
+        """
+        Laplacian of the VectorFunction, creates the Laplacian VectorFunction.
+        """
+        return self.laplacian()
+
+    def laplacian(self, shift=None, order=None):
         """
         Laplacian of the VectorFunction, creates the Laplacian VectorFunction.
         """
         func = vec_func(self)
-        comps = [sum([getattr(s, 'd%s2' % d.name) for d in self.space_dimensions])
+        shift_x0 = make_shift_x0(shift, (len(self.space_dimensions),))
+        order = order or self.space_order
+        comps = [sum([getattr(s, 'd%s2' % d.name)(x0=shift_x0(shift, d, None, i),
+                                                  fd_order=order)
+                      for i, d in enumerate(self.space_dimensions)])
                  for s in self]
         return func._new(comps)
 
-    @property
-    def curl(self):
+    def curl(self, shift=None, order=None):
         """
         Gradient of the (3D) VectorFunction, creates the curl VectorFunction.
         """
-
         if len(self.space_dimensions) != 3:
             raise AttributeError("Curl only supported for 3D VectorFunction")
         # The curl of a VectorFunction is a VectorFunction
-        derivs = ['d%s' % d.name for d in self.space_dimensions]
-        comp1 = getattr(self[2], derivs[1]) - getattr(self[1], derivs[2])
-        comp2 = getattr(self[0], derivs[2]) - getattr(self[2], derivs[0])
-        comp3 = getattr(self[1], derivs[0]) - getattr(self[0], derivs[1])
-
+        dims = self.space_dimensions
+        derivs = ['d%s' % d.name for d in dims]
+        shift_x0 = make_shift_x0(shift, (len(dims), len(dims)))
+        order = order or self.space_order
+        comp1 = (getattr(self[2], derivs[1])(x0=shift_x0(shift, dims[1], 2, 1),
+                                             fd_order=order) -
+                 getattr(self[1], derivs[2])(x0=shift_x0(shift, dims[2], 1, 2),
+                                             fd_order=order))
+        comp2 = (getattr(self[0], derivs[2])(x0=shift_x0(shift, dims[2], 0, 2),
+                                             fd_order=order) -
+                 getattr(self[2], derivs[0])(x0=shift_x0(shift, dims[0], 2, 0),
+                                             fd_order=order))
+        comp3 = (getattr(self[1], derivs[0])(x0=shift_x0(shift, dims[0], 1, 0),
+                                             fd_order=order) -
+                 getattr(self[0], derivs[1])(x0=shift_x0(shift, dims[1], 0, 1),
+                                             fd_order=order))
         func = vec_func(self)
         return func._new(3, 1, [comp1, comp2, comp3])
 
-    def grad(self, shift=None):
+    def grad(self, shift=None, order=None):
         """
         Gradient of the VectorFunction, creates the gradient TensorFunction.
         """
         func = tens_func(self)
         ndim = len(self.space_dimensions)
         shift_x0 = make_shift_x0(shift, (ndim, ndim))
-        comps = [[getattr(f, 'd%s' % d.name)(x0=shift_x0(shift, d, i, j))
+        order = order or self.space_order
+        comps = [[getattr(f, 'd%s' % d.name)(x0=shift_x0(shift, d, i, j),
+                                             fd_order=order)
                   for j, d in enumerate(self.space_dimensions)]
                  for i, f in enumerate(self)]
         return func._new(comps)

diff --git a/tests/test_derivatives.py b/tests/test_derivatives.py
@@ -523,24 +523,27 @@ def test_fd_adjoint(self, so, ndim, derivative, adjoint_name):
     def test_shifted_div(self, shift, ndim):
         grid = Grid(tuple([11]*ndim))
         f = Function(name="f", grid=grid, space_order=4)
-        df = div(f, shift=shift).evaluate
-        ref = 0
-        for i, d in enumerate(grid.dimensions):
-            x0 = (None if shift is None else d + shift[i] * d.spacing if
-                  type(shift) is tuple else d + shift * d.spacing)
-            ref += getattr(f, 'd%s' % d.name)(x0=x0)
-        assert df == ref.evaluate
+        for order in [None, 2]:
+            df = div(f, shift=shift, order=order).evaluate
+            ref = 0
+            for i, d in enumerate(grid.dimensions):
+                x0 = (None if shift is None else d + shift[i] * d.spacing if
+                      type(shift) is tuple else d + shift * d.spacing)
+                ref += getattr(f, 'd%s' % d.name)(x0=x0, fd_order=order)
+            assert df == ref.evaluate
 
     @pytest.mark.parametrize('shift, ndim', [(None, 2), (.5, 2), (.5, 3),
                                              ((.5, .5, .5), 3)])
     def test_shifted_grad(self, shift, ndim):
         grid = Grid(tuple([11]*ndim))
         f = Function(name="f", grid=grid, space_order=4)
-        g = grad(f, shift=shift).evaluate
-        for i, (d, gi) in enumerate(zip(grid.dimensions, g)):
-            x0 = (None if shift is None else d + shift[i] * d.spacing if
-                  type(shift) is tuple else d + shift * d.spacing)
-            assert gi == getattr(f, 'd%s' % d.name)(x0=x0).evaluate
+        for order in [None, 2]:
+            g = grad(f, shift=shift, order=order).evaluate
+            for i, (d, gi) in enumerate(zip(grid.dimensions, g)):
+                x0 = (None if shift is None else d + shift[i] * d.spacing if
+                      type(shift) is tuple else d + shift * d.spacing)
+                gk = getattr(f, 'd%s' % d.name)(x0=x0, fd_order=order).evaluate
+                assert gi == gk
 
     def test_substitution(self):
         grid = Grid((11, 11))
@@ -791,6 +794,18 @@ def test_tensor_algebra(self):
         assert all(isinstance(i, IndexDerivative) for i in v)
         assert all(zip([Add(*i.args) for i in grad(f).evaluate], v.evaluate))
 
+    def test_laplacian_opt(self):
+        grid = Grid(shape=(4, 4))
+        f = Function(name='f', grid=grid, space_order=4)
+
+        assert f.laplacian() == f.laplace
+        df = f.laplacian(order=2, shift=.5)
+        for (v, d) in zip(df.args, grid.dimensions):
+            assert v.dims[0] == d
+            assert v.fd_order == 2
+            assert v.deriv_order == 2
+            assert d in v.x0
+
 
 def bypass_uneval(expr):
     unevals = expr.find(EvalDerivative)