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# -*- coding: utf-8 -*-
"This module defines classes representing constant values."

# Copyright (C) 2008-2016 Martin Sandve Alnæs
#
# This file is part of UFL.
#
# UFL is free software: you can redistribute it and/or modify
# it under the terms of the GNU Lesser General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# UFL is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public License
# along with UFL. If not, see <http://www.gnu.org/licenses/>.
#
# Modified by Anders Logg, 2011.
# Modified by Massimiliano Leoni, 2016.

from six.moves import xrange as range
from six import iteritems

from ufl.utils.py23 import as_native_str
from ufl.utils.py23 import as_native_strings
from ufl.log import error, UFLValueError
from ufl.core.expr import Expr
from ufl.core.terminal import Terminal
from ufl.core.multiindex import Index, FixedIndex
from ufl.core.ufl_type import ufl_type

# --- Helper functions imported here for compatibility---
from ufl.checks import is_python_scalar, is_ufl_scalar, is_true_ufl_scalar  # noqa: F401


# Precision for float formatting
precision = None


def format_float(x):
    "Format float value based on global UFL precision."
    if precision is None:
        return "%s" % repr(x)
    else:
        return ("%%.%dg" % precision) % x


# --- Base classes for constant types ---

@ufl_type(is_abstract=True)
class ConstantValue(Terminal):
    __slots__ = ()

    def __init__(self):
        Terminal.__init__(self)

    def is_cellwise_constant(self):
        "Return whether this expression is spatially constant over each cell."
        return True

    def ufl_domains(self):
        "Return tuple of domains related to this terminal object."
        return ()


# --- Class for representing abstract constant symbol only for use internally in form compilers
# @ufl_type()
# class AbstractSymbol(ConstantValue):
#     "UFL literal type: Representation of a constant valued symbol with unknown properties."
#     __slots__ = as_native_strings(("_name", "ufl_shape"))
#     def __init__(self, name, shape):
#         ConstantValue.__init__(self)
#         self._name = name
#         self.ufl_shape = shape
#
#     def __str__(self):
#        return "<Abstract symbol named '%s' with shape %s>" % (self._name, self.ufl_shape)
#
#     def __repr__(self):
#         r = "AbstractSymbol(%s, %s)" % (repr(self._name), repr(self.ufl_shape))
#         return as_native_str(r)
#
#     def __eq__(self, other):
#         return isinstance(other, AbstractSymbol) and self._name == other._name and self.ufl_shape == other.ufl_shape


# --- Class for representing zero tensors of different shapes ---

# TODO: Add geometric dimension/domain and Argument dependencies to
# Zero?
@ufl_type(is_literal=True)
class Zero(ConstantValue):
    "UFL literal type: Representation of a zero valued expression."
    __slots__ = as_native_strings(("ufl_shape", "ufl_free_indices", "ufl_index_dimensions"))

    _cache = {}

    def __getnewargs__(self):
        return (self.ufl_shape, self.ufl_free_indices, self.ufl_index_dimensions)

    def __new__(cls, shape=(), free_indices=(), index_dimensions=None):
        if free_indices:
            self = ConstantValue.__new__(cls)
        else:
            self = Zero._cache.get(shape)
            if self is not None:
                return self
            self = ConstantValue.__new__(cls)
            Zero._cache[shape] = self
        self._init(shape, free_indices, index_dimensions)
        return self

    def __init__(self, shape=(), free_indices=(), index_dimensions=None):
        pass

    def _init(self, shape=(), free_indices=(), index_dimensions=None):
        ConstantValue.__init__(self)

        if not all(isinstance(i, int) for i in shape):
            error("Expecting tuple of int.")
        if not isinstance(free_indices, tuple):
            error("Expecting tuple for free_indices, not %s" % str(free_indices))

        self.ufl_shape = shape
        if not free_indices:
            self.ufl_free_indices = ()
            self.ufl_index_dimensions = ()
        elif all(isinstance(i, Index) for i in free_indices):  # Handle old input format
            if not (isinstance(index_dimensions, dict) and
                    all(isinstance(i, Index) for i in index_dimensions.keys())):
                error("Expecting tuple of index dimensions, not %s" % str(index_dimensions))
            self.ufl_free_indices = tuple(sorted(i.count() for i in free_indices))
            self.ufl_index_dimensions = tuple(d for i, d in sorted(iteritems(index_dimensions), key=lambda x: x[0].count()))
        else:  # Handle new input format
            if not all(isinstance(i, int) for i in free_indices):
                error("Expecting tuple of integer free index ids, not %s" % str(free_indices))
            if not (isinstance(index_dimensions, tuple) and
                    all(isinstance(i, int) for i in index_dimensions)):
                error("Expecting tuple of integer index dimensions, not %s" % str(index_dimensions))

            # Assuming sorted now to avoid this cost, enable for debuggin:
            #if sorted(free_indices) != list(free_indices):
            #    error("Expecting sorted input. Remove this check later for efficiency.")

            self.ufl_free_indices = free_indices
            self.ufl_index_dimensions = index_dimensions

    def evaluate(self, x, mapping, component, index_values):
        return 0.0

    def __str__(self):
        if self.ufl_shape == () and self.ufl_free_indices == ():
            return "0"
        if self.ufl_free_indices == ():
            return "0 (shape %s)" % (self.ufl_shape,)
        if self.ufl_shape == ():
            return "0 (index labels %s)" % (self.ufl_free_indices,)
        return "0 (shape %s, index labels %s)" % (self.ufl_shape, self.ufl_free_indices)

    def __repr__(self):
        r = "Zero(%s, %s, %s)" % (
            repr(self.ufl_shape),
            repr(self.ufl_free_indices),
            repr(self.ufl_index_dimensions),
            )
        return as_native_str(r)

    def __eq__(self, other):
        if isinstance(other, Zero):
            if self is other:
                return True
            return (self.ufl_shape == other.ufl_shape and
                    self.ufl_free_indices == other.ufl_free_indices and
                    self.ufl_index_dimensions == other.ufl_index_dimensions)
        elif isinstance(other, (int, float)):
            return other == 0
        else:
            return False

    def __neg__(self):
        return self

    def __abs__(self):
        return self

    def __bool__(self):
        return False
    __nonzero__ = __bool__

    def __float__(self):
        return 0.0

    def __int__(self):
        return 0


def zero(*shape):
    "UFL literal constant: Return a zero tensor with the given shape."
    if len(shape) == 1 and isinstance(shape[0], tuple):
        return Zero(shape[0])
    else:
        return Zero(shape)


# --- Scalar value types ---

@ufl_type(is_abstract=True, is_scalar=True)
class ScalarValue(ConstantValue):
    "A constant scalar value."
    __slots__ = as_native_strings(("_value",))

    def __init__(self, value):
        ConstantValue.__init__(self)
        self._value = value

    def value(self):
        return self._value

    def evaluate(self, x, mapping, component, index_values):
        return self._value

    def __eq__(self, other):
        """This is implemented to allow comparison with python scalars.

        Note that this will make IntValue(1) != FloatValue(1.0),
        but ufl-python comparisons like
            IntValue(1) == 1.0
            FloatValue(1.0) == 1
        can still succeed. These will however not have the same
        hash value and therefore not collide in a dict.
        """
        if isinstance(other, self._ufl_class_):
            return self._value == other._value
        elif isinstance(other, (int, float)):
            # FIXME: Disallow this, require explicit 'expr ==
            # IntValue(3)' instead to avoid ambiguities!
            return other == self._value
        else:
            return False

    def __str__(self):
        return str(self._value)

    def __float__(self):
        return float(self._value)

    def __int__(self):
        return int(self._value)

    def __neg__(self):
        return type(self)(-self._value)

    def __abs__(self):
        return type(self)(abs(self._value))


@ufl_type(wraps_type=float, is_literal=True)
class FloatValue(ScalarValue):
    "UFL literal type: Representation of a constant scalar floating point value."
    __slots__ = ()

    def __getnewargs__(self):
        return (self._value,)

    def __new__(cls, value):
        if value == 0.0:
            # Always represent zero with Zero
            return Zero()
        return ConstantValue.__new__(cls)

    def __init__(self, value):
        ScalarValue.__init__(self, float(value))

    def __repr__(self):
        r = "%s(%s)" % (type(self).__name__, format_float(self._value))
        return as_native_str(r)


@ufl_type(wraps_type=int, is_literal=True)
class IntValue(ScalarValue):
    "UFL literal type: Representation of a constant scalar integer value."
    __slots__ = ()

    _cache = {}

    def __getnewargs__(self):
        return (self._value,)

    def __new__(cls, value):
        if value == 0:
            # Always represent zero with Zero
            return Zero()
        elif abs(value) < 100:
            # Small numbers are cached to reduce memory usage
            # (fly-weight pattern)
            self = IntValue._cache.get(value)
            if self is not None:
                return self
            self = ScalarValue.__new__(cls)
            IntValue._cache[value] = self
        else:
            self = ScalarValue.__new__(cls)
        self._init(value)
        return self

    def _init(self, value):
        ScalarValue.__init__(self, int(value))

    def __init__(self, value):
        pass

    def __repr__(self):
        r = "%s(%s)" % (type(self).__name__, repr(self._value))
        return as_native_str(r)


# --- Identity matrix ---

@ufl_type()
class Identity(ConstantValue):
    "UFL literal type: Representation of an identity matrix."
    __slots__ = as_native_strings(("_dim", "ufl_shape"))

    def __init__(self, dim):
        ConstantValue.__init__(self)
        self._dim = dim
        self.ufl_shape = (dim, dim)

    def evaluate(self, x, mapping, component, index_values):
        "Evaluates the identity matrix on the given components."
        a, b = component
        return 1 if a == b else 0

    def __getitem__(self, key):
        if len(key) != 2:
            error("Size mismatch for Identity.")
        if all(isinstance(k, (int, FixedIndex)) for k in key):
            return IntValue(1) if (int(key[0]) == int(key[1])) else Zero()
        return Expr.__getitem__(self, key)

    def __str__(self):
        return "I"

    def __repr__(self):
        r = "Identity(%d)" % self._dim
        return as_native_str(r)

    def __eq__(self, other):
        return isinstance(other, Identity) and self._dim == other._dim


# --- Permutation symbol ---

@ufl_type()
class PermutationSymbol(ConstantValue):
    """UFL literal type: Representation of a permutation symbol.

    This is also known as the Levi-Civita symbol, antisymmetric symbol,
    or alternating symbol."""
    __slots__ = as_native_strings(("ufl_shape", "_dim"))

    def __init__(self, dim):
        ConstantValue.__init__(self)
        self._dim = dim
        self.ufl_shape = (dim,)*dim

    def evaluate(self, x, mapping, component, index_values):
        "Evaluates the permutation symbol."
        return self.__eps(component)

    def __getitem__(self, key):
        if len(key) != self._dim:
            error("Size mismatch for PermutationSymbol.")
        if all(isinstance(k, (int, FixedIndex)) for k in key):
            return self.__eps(key)
        return Expr.__getitem__(self, key)

    def __str__(self):
        return "eps"

    def __repr__(self):
        r = "PermutationSymbol(%d)" % self._dim
        return as_native_str(r)

    def __eq__(self, other):
        return isinstance(other, PermutationSymbol) and self._dim == other._dim

    def __eps(self, x):
        """This function body is taken from
        http://www.mathkb.com/Uwe/Forum.aspx/math/29865/N-integer-Levi-Civita

        """
        result = IntValue(1)
        for i, x1 in enumerate(x):
            for j in range(i + 1, len(x)):
                x2 = x[j]
                if x1 > x2:
                    result = -result
                elif x1 == x2:
                    return Zero()
        return result


def as_ufl(expression):
    "Converts expression to an Expr if possible."
    if isinstance(expression, Expr):
        return expression
    elif isinstance(expression, float):
        return FloatValue(expression)
    elif isinstance(expression, int):
        return IntValue(expression)
    else:
        raise UFLValueError("Invalid type conversion: %s can not be converted"
                            " to any UFL type." % str(expression))