#
# This file is part of pyasn1 software.
#
# Copyright (c) 2005-2019, Ilya Etingof <etingof@gmail.com>
# License: http://snmplabs.com/pyasn1/license.html
#
# Original concept and code by Mike C. Fletcher.
#
import sys

from pyasn1.type import error

__all__ = [
    "SingleValueConstraint",
    "ContainedSubtypeConstraint",
    "ValueRangeConstraint",
    "ValueSizeConstraint",
    "PermittedAlphabetConstraint",
    "InnerTypeConstraint",
    "ConstraintsExclusion",
    "ConstraintsIntersection",
    "ConstraintsUnion",
]


class AbstractConstraint(object):
    def __init__(self, *values):
        self._valueMap = set()
        self._setValues(values)
        self.__hash = hash((self.__class__.__name__, self._values))

    def __call__(self, value, idx=None):
        if not self._values:
            return

        try:
            self._testValue(value, idx)

        except error.ValueConstraintError:
            raise error.ValueConstraintError(
                "%s failed at: %r" % (self, sys.exc_info()[1])
            )

    def __repr__(self):
        representation = "%s object" % (self.__class__.__name__)

        if self._values:
            representation += ", consts %s" % ", ".join([repr(x) for x in self._values])

        return "<%s>" % representation

    def __eq__(self, other):
        return self is other and True or self._values == other

    def __ne__(self, other):
        return self._values != other

    def __lt__(self, other):
        return self._values < other

    def __le__(self, other):
        return self._values <= other

    def __gt__(self, other):
        return self._values > other

    def __ge__(self, other):
        return self._values >= other

    def __bool__(self):
        return self._values and True or False

    def __hash__(self):
        return self.__hash

    def _setValues(self, values):
        self._values = values

    def _testValue(self, value, idx):
        raise error.ValueConstraintError(value)

    # Constraints derivation logic
    def getValueMap(self):
        return self._valueMap

    def isSuperTypeOf(self, otherConstraint):
        # TODO: fix possible comparison of set vs scalars here
        return (
            otherConstraint is self
            or not self._values
            or otherConstraint == self
            or self in otherConstraint.getValueMap()
        )

    def isSubTypeOf(self, otherConstraint):
        return (
            otherConstraint is self
            or not self
            or otherConstraint == self
            or otherConstraint in self._valueMap
        )


class SingleValueConstraint(AbstractConstraint):
    """Create a SingleValueConstraint object.

    The SingleValueConstraint satisfies any value that
    is present in the set of permitted values.

    Objects of this type are iterable (emitting constraint values) and
    can act as operands for some arithmetic operations e.g. addition
    and subtraction. The latter can be used for combining multiple
    SingleValueConstraint objects into one.

    The SingleValueConstraint object can be applied to
    any ASN.1 type.

    Parameters
    ----------
    *values: :class:`int`
        Full set of values permitted by this constraint object.

    Examples
    --------
    .. code-block:: python

        class DivisorOfSix(Integer):
            '''
            ASN.1 specification:

            Divisor-Of-6 ::= INTEGER (1 | 2 | 3 | 6)
            '''
            subtypeSpec = SingleValueConstraint(1, 2, 3, 6)

        # this will succeed
        divisor_of_six = DivisorOfSix(1)

        # this will raise ValueConstraintError
        divisor_of_six = DivisorOfSix(7)
    """

    def _setValues(self, values):
        self._values = values
        self._set = set(values)

    def _testValue(self, value, idx):
        if value not in self._set:
            raise error.ValueConstraintError(value)

    # Constrains can be merged or reduced

    def __contains__(self, item):
        return item in self._set

    def __iter__(self):
        return iter(self._set)

    def __sub__(self, constraint):
        return self.__class__(*(self._set.difference(constraint)))

    def __add__(self, constraint):
        return self.__class__(*(self._set.union(constraint)))

    def __sub__(self, constraint):
        return self.__class__(*(self._set.difference(constraint)))


class ContainedSubtypeConstraint(AbstractConstraint):
    """Create a ContainedSubtypeConstraint object.

    The ContainedSubtypeConstraint satisfies any value that
    is present in the set of permitted values and also
    satisfies included constraints.

    The ContainedSubtypeConstraint object can be applied to
    any ASN.1 type.

    Parameters
    ----------
    *values:
        Full set of values and constraint objects permitted
        by this constraint object.

    Examples
    --------
    .. code-block:: python

        class DivisorOfEighteen(Integer):
            '''
            ASN.1 specification:

            Divisors-of-18 ::= INTEGER (INCLUDES Divisors-of-6 | 9 | 18)
            '''
            subtypeSpec = ContainedSubtypeConstraint(
                SingleValueConstraint(1, 2, 3, 6), 9, 18
            )

        # this will succeed
        divisor_of_eighteen = DivisorOfEighteen(9)

        # this will raise ValueConstraintError
        divisor_of_eighteen = DivisorOfEighteen(10)
    """

    def _testValue(self, value, idx):
        for constraint in self._values:
            if isinstance(constraint, AbstractConstraint):
                constraint(value, idx)
            elif value not in self._set:
                raise error.ValueConstraintError(value)


class ValueRangeConstraint(AbstractConstraint):
    """Create a ValueRangeConstraint object.

    The ValueRangeConstraint satisfies any value that
    falls in the range of permitted values.

    The ValueRangeConstraint object can only be applied
    to :class:`~pyasn1.type.univ.Integer` and
    :class:`~pyasn1.type.univ.Real` types.

    Parameters
    ----------
    start: :class:`int`
        Minimum permitted value in the range (inclusive)

    end: :class:`int`
        Maximum permitted value in the range (inclusive)

    Examples
    --------
    .. code-block:: python

        class TeenAgeYears(Integer):
            '''
            ASN.1 specification:

            TeenAgeYears ::= INTEGER (13 .. 19)
            '''
            subtypeSpec = ValueRangeConstraint(13, 19)

        # this will succeed
        teen_year = TeenAgeYears(18)

        # this will raise ValueConstraintError
        teen_year = TeenAgeYears(20)
    """

    def _testValue(self, value, idx):
        if value < self.start or value > self.stop:
            raise error.ValueConstraintError(value)

    def _setValues(self, values):
        if len(values) != 2:
            raise error.PyAsn1Error(
                "%s: bad constraint values" % (self.__class__.__name__,)
            )
        self.start, self.stop = values
        if self.start > self.stop:
            raise error.PyAsn1Error(
                "%s: screwed constraint values (start > stop): %s > %s"
                % (self.__class__.__name__, self.start, self.stop)
            )
        AbstractConstraint._setValues(self, values)


class ValueSizeConstraint(ValueRangeConstraint):
    """Create a ValueSizeConstraint object.

    The ValueSizeConstraint satisfies any value for
    as long as its size falls within the range of
    permitted sizes.

    The ValueSizeConstraint object can be applied
    to :class:`~pyasn1.type.univ.BitString`,
    :class:`~pyasn1.type.univ.OctetString` (including
    all :ref:`character ASN.1 types <type.char>`),
    :class:`~pyasn1.type.univ.SequenceOf`
    and :class:`~pyasn1.type.univ.SetOf` types.

    Parameters
    ----------
    minimum: :class:`int`
        Minimum permitted size of the value (inclusive)

    maximum: :class:`int`
        Maximum permitted size of the value (inclusive)

    Examples
    --------
    .. code-block:: python

        class BaseballTeamRoster(SetOf):
            '''
            ASN.1 specification:

            BaseballTeamRoster ::= SET SIZE (1..25) OF PlayerNames
            '''
            componentType = PlayerNames()
            subtypeSpec = ValueSizeConstraint(1, 25)

        # this will succeed
        team = BaseballTeamRoster()
        team.extend(['Jan', 'Matej'])
        encode(team)

        # this will raise ValueConstraintError
        team = BaseballTeamRoster()
        team.extend(['Jan'] * 26)
        encode(team)

    Note
    ----
    Whenever ValueSizeConstraint is applied to mutable types
    (e.g. :class:`~pyasn1.type.univ.SequenceOf`,
    :class:`~pyasn1.type.univ.SetOf`), constraint
    validation only happens at the serialisation phase rather
    than schema instantiation phase (as it is with immutable
    types).
    """

    def _testValue(self, value, idx):
        valueSize = len(value)
        if valueSize < self.start or valueSize > self.stop:
            raise error.ValueConstraintError(value)


class PermittedAlphabetConstraint(SingleValueConstraint):
    """Create a PermittedAlphabetConstraint object.

    The PermittedAlphabetConstraint satisfies any character
    string for as long as all its characters are present in
    the set of permitted characters.

    Objects of this type are iterable (emitting constraint values) and
    can act as operands for some arithmetic operations e.g. addition
    and subtraction.

    The PermittedAlphabetConstraint object can only be applied
    to the :ref:`character ASN.1 types <type.char>` such as
    :class:`~pyasn1.type.char.IA5String`.

    Parameters
    ----------
    *alphabet: :class:`str`
        Full set of characters permitted by this constraint object.

    Example
    -------
    .. code-block:: python

        class BooleanValue(IA5String):
            '''
            ASN.1 specification:

            BooleanValue ::= IA5String (FROM ('T' | 'F'))
            '''
            subtypeSpec = PermittedAlphabetConstraint('T', 'F')

        # this will succeed
        truth = BooleanValue('T')
        truth = BooleanValue('TF')

        # this will raise ValueConstraintError
        garbage = BooleanValue('TAF')

    ASN.1 `FROM ... EXCEPT ...` clause can be modelled by combining multiple
    PermittedAlphabetConstraint objects into one:

    Example
    -------
    .. code-block:: python

        class Lipogramme(IA5String):
            '''
            ASN.1 specification:

            Lipogramme ::=
                IA5String (FROM (ALL EXCEPT ("e"|"E")))
            '''
            subtypeSpec = (
                PermittedAlphabetConstraint(*string.printable) -
                PermittedAlphabetConstraint('e', 'E')
            )

        # this will succeed
        lipogramme = Lipogramme('A work of fiction?')

        # this will raise ValueConstraintError
        lipogramme = Lipogramme('Eel')

    Note
    ----
    Although `ConstraintsExclusion` object could seemingly be used for this
    purpose, practically, for it to work, it needs to represent its operand
    constraints as sets and intersect one with the other. That would require
    the insight into the constraint values (and their types) that are otherwise
    hidden inside the constraint object.

    Therefore it's more practical to model `EXCEPT` clause at
    `PermittedAlphabetConstraint` level instead.
    """

    def _setValues(self, values):
        self._values = values
        self._set = set(values)

    def _testValue(self, value, idx):
        if not self._set.issuperset(value):
            raise error.ValueConstraintError(value)


class ComponentPresentConstraint(AbstractConstraint):
    """Create a ComponentPresentConstraint object.

    The ComponentPresentConstraint is only satisfied when the value
    is not `None`.

    The ComponentPresentConstraint object is typically used with
    `WithComponentsConstraint`.

    Examples
    --------
    .. code-block:: python

        present = ComponentPresentConstraint()

        # this will succeed
        present('whatever')

        # this will raise ValueConstraintError
        present(None)
    """

    def _setValues(self, values):
        self._values = ("<must be present>",)

        if values:
            raise error.PyAsn1Error("No arguments expected")

    def _testValue(self, value, idx):
        if value is None:
            raise error.ValueConstraintError("Component is not present:")


class ComponentAbsentConstraint(AbstractConstraint):
    """Create a ComponentAbsentConstraint object.

    The ComponentAbsentConstraint is only satisfied when the value
    is `None`.

    The ComponentAbsentConstraint object is typically used with
    `WithComponentsConstraint`.

    Examples
    --------
    .. code-block:: python

        absent = ComponentAbsentConstraint()

        # this will succeed
        absent(None)

        # this will raise ValueConstraintError
        absent('whatever')
    """

    def _setValues(self, values):
        self._values = ("<must be absent>",)

        if values:
            raise error.PyAsn1Error("No arguments expected")

    def _testValue(self, value, idx):
        if value is not None:
            raise error.ValueConstraintError("Component is not absent: %r" % value)


class WithComponentsConstraint(AbstractConstraint):
    """Create a WithComponentsConstraint object.

    The `WithComponentsConstraint` satisfies any mapping object that has
    constrained fields present or absent, what is indicated by
    `ComponentPresentConstraint` and `ComponentAbsentConstraint`
    objects respectively.

    The `WithComponentsConstraint` object is typically applied
    to  :class:`~pyasn1.type.univ.Set` or
    :class:`~pyasn1.type.univ.Sequence` types.

    Parameters
    ----------
    *fields: :class:`tuple`
        Zero or more tuples of (`field`, `constraint`) indicating constrained
        fields.

    Notes
    -----
    On top of the primary use of `WithComponentsConstraint` (ensuring presence
    or absence of particular components of a :class:`~pyasn1.type.univ.Set` or
    :class:`~pyasn1.type.univ.Sequence`), it is also possible to pass any other
    constraint objects or their combinations. In case of scalar fields, these
    constraints will be verified in addition to the constraints belonging to
    scalar components themselves. However, formally, these additional
    constraints do not change the type of these ASN.1 objects.

    Examples
    --------

    .. code-block:: python

        class Item(Sequence):  #  Set is similar
            '''
            ASN.1 specification:

            Item ::= SEQUENCE {
                id    INTEGER OPTIONAL,
                name  OCTET STRING OPTIONAL
            } WITH COMPONENTS id PRESENT, name ABSENT | id ABSENT, name PRESENT
            '''
            componentType = NamedTypes(
                OptionalNamedType('id', Integer()),
                OptionalNamedType('name', OctetString())
            )
            withComponents = ConstraintsUnion(
                WithComponentsConstraint(
                    ('id', ComponentPresentConstraint()),
                    ('name', ComponentAbsentConstraint())
                ),
                WithComponentsConstraint(
                    ('id', ComponentAbsentConstraint()),
                    ('name', ComponentPresentConstraint())
                )
            )

        item = Item()

        # This will succeed
        item['id'] = 1

        # This will succeed
        item.reset()
        item['name'] = 'John'

        # This will fail (on encoding)
        item.reset()
        descr['id'] = 1
        descr['name'] = 'John'
    """

    def _testValue(self, value, idx):
        for field, constraint in self._values:
            constraint(value.get(field))

    def _setValues(self, values):
        AbstractConstraint._setValues(self, values)


# This is a bit kludgy, meaning two op modes within a single constraint
class InnerTypeConstraint(AbstractConstraint):
    """Value must satisfy the type and presence constraints"""

    def _testValue(self, value, idx):
        if self.__singleTypeConstraint:
            self.__singleTypeConstraint(value)
        elif self.__multipleTypeConstraint:
            if idx not in self.__multipleTypeConstraint:
                raise error.ValueConstraintError(value)
            constraint, status = self.__multipleTypeConstraint[idx]
            if status == "ABSENT":  # XXX presence is not checked!
                raise error.ValueConstraintError(value)
            constraint(value)

    def _setValues(self, values):
        self.__multipleTypeConstraint = {}
        self.__singleTypeConstraint = None
        for v in values:
            if isinstance(v, tuple):
                self.__multipleTypeConstraint[v[0]] = v[1], v[2]
            else:
                self.__singleTypeConstraint = v
        AbstractConstraint._setValues(self, values)


# Logic operations on constraints


class ConstraintsExclusion(AbstractConstraint):
    """Create a ConstraintsExclusion logic operator object.

    The ConstraintsExclusion logic operator succeeds when the
    value does *not* satisfy the operand constraint.

    The ConstraintsExclusion object can be applied to
    any constraint and logic operator object.

    Parameters
    ----------
    *constraints:
        Constraint or logic operator objects.

    Examples
    --------
    .. code-block:: python

        class LuckyNumber(Integer):
            subtypeSpec = ConstraintsExclusion(
                SingleValueConstraint(13)
            )

        # this will succeed
        luckyNumber = LuckyNumber(12)

        # this will raise ValueConstraintError
        luckyNumber = LuckyNumber(13)

    Note
    ----
    The `FROM ... EXCEPT ...` ASN.1 clause should be modeled by combining
    constraint objects into one. See `PermittedAlphabetConstraint` for more
    information.
    """

    def _testValue(self, value, idx):
        for constraint in self._values:
            try:
                constraint(value, idx)

            except error.ValueConstraintError:
                continue

            raise error.ValueConstraintError(value)

    def _setValues(self, values):
        AbstractConstraint._setValues(self, values)


class AbstractConstraintSet(AbstractConstraint):
    def __getitem__(self, idx):
        return self._values[idx]

    def __iter__(self):
        return iter(self._values)

    def __add__(self, value):
        return self.__class__(*(self._values + (value,)))

    def __radd__(self, value):
        return self.__class__(*((value,) + self._values))

    def __len__(self):
        return len(self._values)

    # Constraints inclusion in sets

    def _setValues(self, values):
        self._values = values
        for constraint in values:
            if constraint:
                self._valueMap.add(constraint)
                self._valueMap.update(constraint.getValueMap())


class ConstraintsIntersection(AbstractConstraintSet):
    """Create a ConstraintsIntersection logic operator object.

    The ConstraintsIntersection logic operator only succeeds
    if *all* its operands succeed.

    The ConstraintsIntersection object can be applied to
    any constraint and logic operator objects.

    The ConstraintsIntersection object duck-types the immutable
    container object like Python :py:class:`tuple`.

    Parameters
    ----------
    *constraints:
        Constraint or logic operator objects.

    Examples
    --------
    .. code-block:: python

        class CapitalAndSmall(IA5String):
            '''
            ASN.1 specification:

            CapitalAndSmall ::=
                IA5String (FROM ("A".."Z"|"a".."z"))
            '''
            subtypeSpec = ConstraintsIntersection(
                PermittedAlphabetConstraint('A', 'Z'),
                PermittedAlphabetConstraint('a', 'z')
            )

        # this will succeed
        capital_and_small = CapitalAndSmall('Hello')

        # this will raise ValueConstraintError
        capital_and_small = CapitalAndSmall('hello')
    """

    def _testValue(self, value, idx):
        for constraint in self._values:
            constraint(value, idx)


class ConstraintsUnion(AbstractConstraintSet):
    """Create a ConstraintsUnion logic operator object.

    The ConstraintsUnion logic operator succeeds if
    *at least* a single operand succeeds.

    The ConstraintsUnion object can be applied to
    any constraint and logic operator objects.

    The ConstraintsUnion object duck-types the immutable
    container object like Python :py:class:`tuple`.

    Parameters
    ----------
    *constraints:
        Constraint or logic operator objects.

    Examples
    --------
    .. code-block:: python

        class CapitalOrSmall(IA5String):
            '''
            ASN.1 specification:

            CapitalOrSmall ::=
                IA5String (FROM ("A".."Z") | FROM ("a".."z"))
            '''
            subtypeSpec = ConstraintsUnion(
                PermittedAlphabetConstraint('A', 'Z'),
                PermittedAlphabetConstraint('a', 'z')
            )

        # this will succeed
        capital_or_small = CapitalAndSmall('Hello')

        # this will raise ValueConstraintError
        capital_or_small = CapitalOrSmall('hello!')
    """

    def _testValue(self, value, idx):
        for constraint in self._values:
            try:
                constraint(value, idx)
            except error.ValueConstraintError:
                pass
            else:
                return

        raise error.ValueConstraintError(
            'all of %s failed for "%s"' % (self._values, value)
        )


# TODO:
# refactor InnerTypeConstraint
# add tests for type check
# implement other constraint types
# make constraint validation easy to skip