205 lines
6.6 KiB
Python
205 lines
6.6 KiB
Python
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from sympy.core.expr import ExprBuilder
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from sympy.core.function import (Function, FunctionClass, Lambda)
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from sympy.core.symbol import Dummy
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from sympy.core.sympify import sympify, _sympify
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from sympy.matrices.expressions import MatrixExpr
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from sympy.matrices.matrices import MatrixBase
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class ElementwiseApplyFunction(MatrixExpr):
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r"""
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Apply function to a matrix elementwise without evaluating.
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Examples
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========
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It can be created by calling ``.applyfunc(<function>)`` on a matrix
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expression:
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>>> from sympy import MatrixSymbol
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>>> from sympy.matrices.expressions.applyfunc import ElementwiseApplyFunction
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>>> from sympy import exp
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>>> X = MatrixSymbol("X", 3, 3)
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>>> X.applyfunc(exp)
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Lambda(_d, exp(_d)).(X)
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Otherwise using the class constructor:
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>>> from sympy import eye
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>>> expr = ElementwiseApplyFunction(exp, eye(3))
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>>> expr
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Lambda(_d, exp(_d)).(Matrix([
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[1, 0, 0],
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[0, 1, 0],
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[0, 0, 1]]))
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>>> expr.doit()
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Matrix([
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[E, 1, 1],
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[1, E, 1],
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[1, 1, E]])
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Notice the difference with the real mathematical functions:
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>>> exp(eye(3))
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Matrix([
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[E, 0, 0],
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[0, E, 0],
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[0, 0, E]])
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"""
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def __new__(cls, function, expr):
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expr = _sympify(expr)
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if not expr.is_Matrix:
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raise ValueError("{} must be a matrix instance.".format(expr))
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if expr.shape == (1, 1):
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# Check if the function returns a matrix, in that case, just apply
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# the function instead of creating an ElementwiseApplyFunc object:
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ret = function(expr)
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if isinstance(ret, MatrixExpr):
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return ret
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if not isinstance(function, (FunctionClass, Lambda)):
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d = Dummy('d')
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function = Lambda(d, function(d))
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function = sympify(function)
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if not isinstance(function, (FunctionClass, Lambda)):
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raise ValueError(
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"{} should be compatible with SymPy function classes."
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.format(function))
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if 1 not in function.nargs:
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raise ValueError(
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'{} should be able to accept 1 arguments.'.format(function))
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if not isinstance(function, Lambda):
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d = Dummy('d')
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function = Lambda(d, function(d))
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obj = MatrixExpr.__new__(cls, function, expr)
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return obj
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@property
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def function(self):
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return self.args[0]
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@property
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def expr(self):
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return self.args[1]
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@property
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def shape(self):
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return self.expr.shape
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def doit(self, **hints):
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deep = hints.get("deep", True)
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expr = self.expr
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if deep:
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expr = expr.doit(**hints)
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function = self.function
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if isinstance(function, Lambda) and function.is_identity:
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# This is a Lambda containing the identity function.
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return expr
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if isinstance(expr, MatrixBase):
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return expr.applyfunc(self.function)
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elif isinstance(expr, ElementwiseApplyFunction):
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return ElementwiseApplyFunction(
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lambda x: self.function(expr.function(x)),
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expr.expr
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).doit(**hints)
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else:
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return self
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def _entry(self, i, j, **kwargs):
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return self.function(self.expr._entry(i, j, **kwargs))
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def _get_function_fdiff(self):
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d = Dummy("d")
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function = self.function(d)
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fdiff = function.diff(d)
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if isinstance(fdiff, Function):
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fdiff = type(fdiff)
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else:
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fdiff = Lambda(d, fdiff)
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return fdiff
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def _eval_derivative(self, x):
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from sympy.matrices.expressions.hadamard import hadamard_product
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dexpr = self.expr.diff(x)
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fdiff = self._get_function_fdiff()
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return hadamard_product(
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dexpr,
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ElementwiseApplyFunction(fdiff, self.expr)
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)
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def _eval_derivative_matrix_lines(self, x):
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from sympy.matrices.expressions.special import Identity
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from sympy.tensor.array.expressions.array_expressions import ArrayContraction
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from sympy.tensor.array.expressions.array_expressions import ArrayDiagonal
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from sympy.tensor.array.expressions.array_expressions import ArrayTensorProduct
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fdiff = self._get_function_fdiff()
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lr = self.expr._eval_derivative_matrix_lines(x)
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ewdiff = ElementwiseApplyFunction(fdiff, self.expr)
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if 1 in x.shape:
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# Vector:
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iscolumn = self.shape[1] == 1
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for i in lr:
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if iscolumn:
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ptr1 = i.first_pointer
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ptr2 = Identity(self.shape[1])
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else:
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ptr1 = Identity(self.shape[0])
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ptr2 = i.second_pointer
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subexpr = ExprBuilder(
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ArrayDiagonal,
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[
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ExprBuilder(
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ArrayTensorProduct,
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[
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ewdiff,
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ptr1,
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ptr2,
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]
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),
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(0, 2) if iscolumn else (1, 4)
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],
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validator=ArrayDiagonal._validate
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)
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i._lines = [subexpr]
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i._first_pointer_parent = subexpr.args[0].args
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i._first_pointer_index = 1
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i._second_pointer_parent = subexpr.args[0].args
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i._second_pointer_index = 2
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else:
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# Matrix case:
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for i in lr:
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ptr1 = i.first_pointer
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ptr2 = i.second_pointer
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newptr1 = Identity(ptr1.shape[1])
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newptr2 = Identity(ptr2.shape[1])
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subexpr = ExprBuilder(
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ArrayContraction,
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[
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ExprBuilder(
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ArrayTensorProduct,
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[ptr1, newptr1, ewdiff, ptr2, newptr2]
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),
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(1, 2, 4),
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(5, 7, 8),
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],
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validator=ArrayContraction._validate
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)
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i._first_pointer_parent = subexpr.args[0].args
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i._first_pointer_index = 1
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i._second_pointer_parent = subexpr.args[0].args
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i._second_pointer_index = 4
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i._lines = [subexpr]
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return lr
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def _eval_transpose(self):
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from sympy.matrices.expressions.transpose import Transpose
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return self.func(self.function, Transpose(self.expr).doit())
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