Source code for pywbem._cim_obj

#
# (C) Copyright 2003-2007 Hewlett-Packard Development Company, L.P.
# (C) Copyright 2006-2007 Novell, Inc.
#
# This library 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 2.1 of the License, or (at your option) any later version.
#
# This program 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 this program; if not, write to the Free Software
# Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
#
# Author: Tim Potter <tpot@hp.com>
# Author: Martin Pool <mbp@hp.com>
# Author: Bart Whiteley <bwhiteley@suse.de>
# Author: Ross Peoples <ross.peoples@gmail.com>
#

# pylint: disable=line-too-long
"""
CIM objects are local representations of CIM instances, classes, properties,
etc., as Python objects. They are used as input to and output from WBEM
operations:

==========================================  ==========================================================================
CIM object                                  Purpose
==========================================  ==========================================================================
:class:`~pywbem.CIMInstanceName`            Instance path of a CIM instance
:class:`~pywbem.CIMInstance`                CIM instance
:class:`~pywbem.CIMClassName`               Name of a CIM class, optionally with class path
:class:`~pywbem.CIMClass`                   CIM class
:class:`~pywbem.CIMProperty`                CIM property, both as property value in a CIM instance and as property
                                            declaration in a CIM class
:class:`~pywbem.CIMMethod`                  CIM method declaration in a CIM class
:class:`~pywbem.CIMParameter`               CIM parameter, both as a parameter value in a method invocation and as a
                                            parameter declaration in a CIM method declaration in a CIM class
:class:`~pywbem.CIMQualifier`               CIM qualifier value
:class:`~pywbem.CIMQualifierDeclaration`    CIM qualifier type/declaration
==========================================  ==========================================================================


.. _`Putting CIM objects in sets`:

Putting CIM objects in sets
---------------------------

Using sets for holding the result of :ref:`WBEM operations` is not uncommon,
because that allows comparison of results without regard to the (undefined)
order in which the objects are returned.

:ref:`CIM objects` are mutable and :term:`unchanged-hashable`. This requires
some caution when putting them in sets, or using them in any other way that
relies on their hash values.

The caution that is needed is that the public attributes, and therefore the
state of the CIM objects, must not change as long as they are a member of a
set, or used in any other way that relies on their hash values.

The following example shows what happens if a CIM object is modified while
being a member of a set:

::

    import pywbem

    s = set()

    # Create CIM object c1 and show its identity and hash value:
    c1 = pywbem.CIMClass('C')
    print(id(c1), hash(c1))  # (140362966049680, -7623128493967117119)

    # Add c1 to the set and verify the set content:
    s.add(c1)
    print([id(c) for c in s])  # [140362966049680]

    # Modify the c1 object; it now has changed its hash value:
    c1.superclass = 'B'
    print(id(c1), hash(c1))  # (140362966049680, 638672161836520435)

    # Create a CIM object c2 with the same attribute values as c1, and show
    # that they compare equal and that c2 has the same hash value as c1 now has:
    c2 = pywbem.CIMClass('C', superclass='B')
    print(c1 == c2)  # True
    print(id(c2), hash(c2))  # (140362970983696, 638672161836520435)

    # Add c2 to the set and verify the set content:
    s.add(c2)
    print([id(c) for c in s])  # [140362966049680, 140362970983696] !!

At the end, the set contains both objects even though they have the same hash
value. This is not what one would expect from
:ref:`set types <py:types-set>`.

The reason is that at the time the object c1 was added to the set, it had a
different hash value, and the set uses the hash value it found at insertion
time of its member for identifying the object. When the second object is added,
it finds it has a yet unknown hash value, and adds it.

While the set type in this particular Python implementation was able to still
look up the first member object even though its hash value has changed
meanwhile, other collection types or other Python implementations may not be as
forgiving and may not even be able to look up the object once its hash value
has changed.

Therefore, always make sure that the public attributes of CIM objects that are
put into a set remain unchanged while the object is in the set. The same
applies to any other usage of CIM objects that relies on their hash values.


.. _`Order of CIM child objects`:

Order of CIM child objects
--------------------------

:ref:`CIM objects` have zero or more lists of child objects. For example, a CIM
class (the parent object) has a list of CIM properties, CIM methods and CIM
qualifiers (the child objects).

In pywbem, the parent CIM object allows initializing each list of child objects
via an init parameter. For example, the :class:`~pywbem.CIMClass` init method
has a parameter named ``properties`` that allows specifying the CIM properties
of the CIM class.

Once the parent CIM object exists, each list of child objects can be modified
via a settable attribute. For example, the :class:`~pywbem.CIMClass` class has
a :attr:`~pywbem.CIMClass.properties` attribute for its list of CIM properties.

For such attributes and init parameters that specify lists of child
objects, pywbem supports a number of different ways the child objects can be
specified.

Some of these ways preserve the order of child objects and some don't.

This section uses CIM properties in CIM classes as an example, but it applies
to all kinds of child objects in CIM objects.

The possible input objects for the ``properties`` init parameter
and for the :attr:`~pywbem.CIMClass.properties` attribute of
:class:`~pywbem.CIMClass` is described in the type
:term:`properties input object`, and must be one of these objects:

* iterable of :class:`~pywbem.CIMProperty`
* iterable of tuple(key, value)
* :class:`~py:collections.OrderedDict` with key and value
* :class:`py:dict` with key and value (will not preserve order)

The keys are always the property names, and the values are always
:class:`~pywbem.CIMProperty` objects (at least when initializing classes).

Even though the :class:`~py:collections.OrderedDict` class preserves the order
of its items, intializing the dictionary with keyword arguments causes the
order of items to be lost before the dictionary is even initialized (before
Python 3.6). The only way to initialize a dictionary without loosing order of
items is by providing a list of tuples(key,value).

The following examples work but loose the order of properties in the class:

::

    # Examples where order of properties in class is not as specified:


    # Using an OrderedDict object, initialized with keyword arguments
    # (before Python 3.6):

    c1_props = OrderedDict(
        Prop1=CIMProperty('Prop1', value='abc'),
        Prop2=CIMProperty('Prop2', value=None, type='string'),
    )


    # Using a dict object, initialized with keyword arguments (This time
    # specified using key:value notation):

    c1_props = {
        'Prop1': CIMProperty('Prop1', value='abc'),
        'Prop2': CIMProperty('Prop2', value=None, type='string'),
    }


    # Using a dict object, initialized with list of tuple(key,value):

    c1_props = dict([
        ('Prop1', CIMProperty('Prop1', value='abc')),
        ('Prop2', CIMProperty('Prop2', value=None, type='string')),
    ])


    # Any of the above objects can be used to initialize the class properties:

    c1 = CIMClass('CIM_Foo', properties=c1_props)

The following examples all preserve the order of properties in the class:

::

    # Examples where order of properties in class is as specified:


    # Using a list of CIMProperty objects (starting with pywbem 0.12):

    c1_props = [
        CIMProperty('Prop1', value='abc'),
        CIMProperty('Prop2', value=None, type='string'),
    ]


    # Using an OrderedDict object, initialized with list of tuple(key,value):

    c1_props = OrderedDict([
        ('Prop1', CIMProperty('Prop1', value='abc')),
        ('Prop2', CIMProperty('Prop2', value=None, type='string')),
    ])


    # Using a list of tuple(key,value):

    c1_props = [
        ('Prop1', CIMProperty('Prop1', value='abc')),
        ('Prop2', CIMProperty('Prop2', value=None, type='string')),
    ]


    # Any of the above objects can be used to initialize the class properties:

    c1 = CIMClass('CIM_Foo', properties=c1_props)
"""  # noqa: E501
# pylint: enable=line-too-long
# Note: When used before module docstrings, Pylint scopes the disable statement
#       to the whole rest of the file, so we need an enable statement.

# This module is meant to be safe for 'import *'.

from __future__ import print_function, absolute_import

import warnings
import copy as copy_
import re
try:
    from collections import OrderedDict
except ImportError:
    from ordereddict import OrderedDict
try:
    from collections.abc import ValuesView, ItemsView
except ImportError:
    # pylint: disable=deprecated-class
    from collections import ValuesView, ItemsView
try:
    from builtins import type as builtin_type
except ImportError:  # py2
    from __builtin__ import type as builtin_type
from xml.dom.minidom import Element
import six

from . import _cim_xml
from .config import SEND_VALUE_NULL
from . import config
from ._cim_types import _CIMComparisonMixin, type_from_name, cimtype, \
    atomic_to_cim_xml, CIMType, CIMDateTime, number_types, CIMInt, \
    CIMFloat, _Longint, Char16, SlottedPickleMixin
from ._nocasedict import NocaseDict
from ._utils import _ensure_unicode, _ensure_bool, \
    _hash_name, _hash_item, _hash_dict, _format, _integerValue_to_int, \
    _realValue_to_float, _to_unicode, _eq_name, _eq_item, _eq_dict, \
    _stacklevel_above_module
from ._warnings import MissingKeybindingsWarning


__all__ = ['CIMClassName', 'CIMProperty', 'CIMInstanceName', 'CIMInstance',
           'CIMClass', 'CIMMethod', 'CIMParameter', 'CIMQualifier',
           'CIMQualifierDeclaration', 'tocimxml', 'tocimxmlstr', 'cimvalue']

# Constants for MOF formatting output
MOF_INDENT = 3
MAX_MOF_LINE = 80

# Patterns for WBEM URI parsing, consistent with DSP0207, except that for a
# local WBEM URI (no namespace type, no authority), the leading slash required
# by DSP0207 is optional for pywbem.
WBEM_URI_CLASSPATH_REGEXP = re.compile(
    r'^(?:([\w\-]+):)?'  # namespace type (URI scheme)
    r'(?://([\w.:@\[\]]*))?'  # authority (host)
    r'(?:/|^/?)(\w+(?:/\w+)*)?'  # namespace name (leading slash optional)
    r'(?::|^:?)(\w+)$',  # class name (leading colon optional)
    flags=re.UNICODE)
WBEM_URI_INSTANCEPATH_REGEXP = re.compile(
    r'^(?:([\w\-]+):)?'  # namespace type (URI scheme)
    r'(?://([\w.:@\[\]]*))?'  # authority (host)
    r'(?:/|^/?)(\w+(?:/\w+)*)?'  # namespace name (leading slash optional)
    r'(?::|^:?)(\w+)'  # class name (leading colon optional)
    r'\.(.+)$',  # key bindings
    flags=re.UNICODE)

# For parsing the key bindings using a regexp, we just distinguish the
# differently quoted forms. The exact types of the key values are determined
# lateron:
_KB_NOT_QUOTED = r'[^,"\'\\]+'
_KB_SINGLE_QUOTED = r"'(?:[^'\\]|\\.)*'"
_KB_DOUBLE_QUOTED = r'"(?:[^"\\]|\\.)*"'
_KB_VAL = r'(?:{0}|{1}|{2})'.format(
    _KB_NOT_QUOTED, _KB_SINGLE_QUOTED, _KB_DOUBLE_QUOTED)

# To get all repetitions, capture a repeated group instead of repeating a
# capturing group: https://www.regular-expressions.info/captureall.html
WBEM_URI_KEYBINDINGS_REGEXP = re.compile(
    r'^(\w+={0})((?:,\w+={0})*)$'.format(_KB_VAL),
    flags=(re.UNICODE | re.IGNORECASE))

WBEM_URI_KB_FINDALL_REGEXP = re.compile(
    r',\w+={0}'.format(_KB_VAL),
    flags=(re.UNICODE | re.IGNORECASE))

# Valid namespace types (URI schemes) for WBEM URI parsing
WBEM_URI_NAMESPACE_TYPES = [
    'http', 'https',
    'cimxml-wbem', 'cimxml-wbems',
]

# CIM data type names, used for checking
ALL_CIMTYPES = set([
    'boolean',
    'string',
    'char16',
    'datetime',
    'uint8',
    'uint16',
    'uint32',
    'uint64',
    'sint8',
    'sint16',
    'sint32',
    'sint64',
    'real32',
    'real64',
    'reference',
])

# CIM data type names, used for checking
QUALIFIER_CIMTYPES = set([
    'boolean',
    'string',
    'char16',
    'datetime',
    'uint8',
    'uint16',
    'uint32',
    'uint64',
    'sint8',
    'sint16',
    'sint32',
    'sint64',
    'real32',
    'real64',
])


class _DictView(object):
    # pylint: disable=too-few-public-methods
    """
    Base class for directory views, with commmon methods.
    """

    def __init__(self, dct):
        self._dict = dct

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

    def __contains__(self, x):
        # pylint: disable=invalid-name
        return x in iter(self)

    def __reversed__(self):
        return reversed(list(iter(self)))

    def __repr__(self):
        return "{t}({d!r})".format(
            t=self.__class__.__name__, d=self._dict)


class propvalue_values(_DictView, ValuesView):
    # pylint: disable=too-few-public-methods,invalid-name
    """
    Dictionary view returned by CIMInstance.values(), returning the `value`
    attribute of the CIMProperty objects that are iterated in the view.

    The objects iterated over are the CIMProperty objects in the
    CIMinstance.properties dictionary.
   """

    def __iter__(self):
        for prop in self._dict.values():
            yield prop.value


class propvalue_items(_DictView, ItemsView):
    # pylint: disable=too-few-public-methods,invalid-name
    """
    Dictionary view returned by CIMInstance.items(), returning the `value`
    attribute of the CIMProperty objects that are iterated in the view.

    The objects iterated over are the CIMProperty objects in the
    CIMinstance.properties dictionary.
    """

    def __iter__(self):
        for pname, prop in self._dict.items():
            yield pname, prop.value


def _qualifiers_tomof(qualifiers, indent, maxline=MAX_MOF_LINE):
    """
    Return a MOF string with the qualifier values, including the surrounding
    square brackets. The qualifiers are ordered by their name.

    Return empty string if no qualifiers.

    Normally multiline output and may fold qualifiers into multiple lines.

    The order of qualifiers is preserved.

    Parameters:

      qualifiers (NocaseDict of CIMQualifier): Qualifiers to format.

      indent (:term:`integer`): Number of spaces to indent each line of
        the returned string, counted to the opening bracket in the first line.

    Returns:

      :term:`unicode string`: MOF string.
    """

    if not qualifiers:
        return u''

    mof = []

    mof.append(_indent_str(indent))
    mof.append(u'[')
    line_pos = indent + 1

    mof_quals = []
    for q in qualifiers.values():
        mof_quals.append(q.tomof(indent + 1 + MOF_INDENT, maxline, line_pos))
    delim = ',\n' + _indent_str(indent + 1)
    mof.append(delim.join(mof_quals))

    mof.append(u']\n')

    return u''.join(mof)


def _indent_str(indent):
    """
    Return a MOF indent pad unicode string from the indent integer variable
    that defines number of spaces to indent. Used to format MOF output.
    """
    return u''.ljust(indent, u' ')


def _mof_escaped(strvalue):
    # Note: This is a raw docstring because it shows many backslashes, and
    # that avoids having to double them.
    r"""
    Return a MOF-escaped string from the input string.

    Parameters:

      strvalue (:term:`unicode string`): The string value. Must not be `None`.
        Special characters must not be backslash-escaped.

    Details on backslash-escaping:

    `DSP0004` defines that the character repertoire for MOF string constants
    is the entire repertoire for the CIM string datatype. That is, the entire
    Unicode character repertoire except for U+0000.

    The only character for which `DSP0004` requires the use of a MOF escape
    sequence in a MOF string constant, is the double quote (because a MOF
    string constant is enclosed in double quotes).

    `DSP0004` defines MOF escape sequences for several more characters, but it
    does not require their use in MOF. For example, it is valid for a MOF
    string constant to contain the (unescaped) characters U+000D (newline) or
    U+0009 (horizontal tab), and others.

    Processing the MOF escape sequences as unescaped characters may not be
    supported by MOF-related tools, and therefore this function plays it safe
    and uses the MOF escape sequences defined in `DSP0004` as much as possible.
    The following table shows the MOF escape sequences defined in `DSP0004`
    and whether they are used (i.e. generated) by this function:

    ========== ==== ===========================================================
    MOF escape Used Character
    sequence
    ========== ==== ===========================================================
    \b         yes  U+0008: Backspace
    \t         yes  U+0009: Horizontal tab
    \n         yes  U+000A: Line feed
    \f         yes  U+000C: Form feed
    \r         yes  U+000D: Carriage return
    \"         yes  U+0022: Double quote (") (required to be used)
    \'         yes  U+0027: Single quote (')
    \\         yes  U+005C: Backslash (\)
    \x<hex>    (1)  U+<hex>: Any UCS-2 character, where <hex> is one to four
                      hex digits, representing its UCS code position (this form
                      is limited to the UCS-2 character repertoire)
    \X<hex>    no   U+<hex>: Any UCS-2 character, where <hex> is one to four
                      hex digits, representing its UCS code position (this form
                      is limited to the UCS-2 character repertoire)
    ========== ==== ===========================================================

    (1) Yes, for all other characters in the so called "control range"
        U+0001..U+001F.
    """

    escaped_str = strvalue

    # Escape backslash (\)
    escaped_str = escaped_str.replace('\\', '\\\\')

    # Escape \b, \t, \n, \f, \r
    # Note, the Python escape sequences happen to be the same as in MOF
    escaped_str = escaped_str.\
        replace('\b', '\\b').\
        replace('\t', '\\t').\
        replace('\n', '\\n').\
        replace('\f', '\\f').\
        replace('\r', '\\r')

    # Escape remaining control characters (U+0001...U+001F), skipping
    # U+0008, U+0009, U+000A, U+000C, U+000D that are already handled.
    # We hard code it to be faster, plus we can easily skip already handled
    # chars.
    # The generic code would be (not skipping already handled chars):
    #     for cp in range(1, 32):
    #         c = six.unichr(cp)
    #         esc = '\\x{0:04X}'.format(cp)
    #         escaped_str = escaped_str.replace(c, esc)
    escaped_str = escaped_str.\
        replace(u'\u0001', '\\x0001').\
        replace(u'\u0002', '\\x0002').\
        replace(u'\u0003', '\\x0003').\
        replace(u'\u0004', '\\x0004').\
        replace(u'\u0005', '\\x0005').\
        replace(u'\u0006', '\\x0006').\
        replace(u'\u0007', '\\x0007').\
        replace(u'\u000B', '\\x000B').\
        replace(u'\u000E', '\\x000E').\
        replace(u'\u000F', '\\x000F').\
        replace(u'\u0010', '\\x0010').\
        replace(u'\u0011', '\\x0011').\
        replace(u'\u0012', '\\x0012').\
        replace(u'\u0013', '\\x0013').\
        replace(u'\u0014', '\\x0014').\
        replace(u'\u0015', '\\x0015').\
        replace(u'\u0016', '\\x0016').\
        replace(u'\u0017', '\\x0017').\
        replace(u'\u0018', '\\x0018').\
        replace(u'\u0019', '\\x0019').\
        replace(u'\u001A', '\\x001A').\
        replace(u'\u001B', '\\x001B').\
        replace(u'\u001C', '\\x001C').\
        replace(u'\u001D', '\\x001D').\
        replace(u'\u001E', '\\x001E').\
        replace(u'\u001F', '\\x001F')

    # Escape single and double quote
    escaped_str = escaped_str.replace('"', '\\"')
    escaped_str = escaped_str.replace("'", "\\'")

    return escaped_str


def mofstr(value, indent=MOF_INDENT, maxline=MAX_MOF_LINE, line_pos=0,
           end_space=0, avoid_splits=False, quote_char=u'"'):
    """
    Low level function that returns the MOF representation of a string value
    (i.e. a value that can be split into multiple parts, for example a string,
    reference or datetime typed value).

    The function performs the backslash-escaping of characters in the string
    (for details, see function _mof_escaped()), handles the splitting into
    multiple string parts if the current line does not have sufficient space
    left, and surrounds the string parts (or the entire string, if it ends up
    having only one part) with the specified quote characters.

    The strategy for starting new lines and for splitting the string into parts
    is:

    * If the string fits into the current line, it is output.
    * If the 'avoid_splits' flag is set, a new line is generating. If the
      string fits onto the new line, it is output. Otherwise, the string is
      split into parts and these are output starting with the new line,
      generating additional new lines as needed.
    * If the 'avoid_splits' flag is not set, the string is split into parts and
      these are output starting with the current line, generating new lines as
      needed.
    * Strings are first tried to split after the rightmost space character that
      would still make it fit onto the line, and only if there is no space
      character in that range, the string is split at a non-space position.

    Parameters:

      value (:term:`unicode string`): The string value. Must not be `None`.
        Special characters must not be backslash-escaped.

      indent (:term:`integer`): Number of spaces to indent any new lines that
        are generated.

      maxline (:term:`integer`): Maximum line length for the generated MOF.

      line_pos (:term:`integer`): Length of content already on the current
        line.

      end_space (:term:`integer`): Length of space to be left free on the last
        line.

      avoid_splits (bool): Avoid splits at the price of starting a new line
        instead of using the current line.

      quote_char (:term:`unicode string`): Character to be used for surrounding
        the string parts with. For CIM string typed values, this must be a
        double quote (the default), and for CIM char16 typed values, this must
        be a single quote.

    Returns:

      tuple of
        * :term:`unicode string`: MOF string.
        * new line_pos
    """

    assert isinstance(value, six.text_type)

    value = _mof_escaped(value)

    quote_len = 2  # length of the quotes surrounding a string part
    new_line = u'\n' + _indent_str(indent)

    mof = []

    while True:

        # Prepare safety check for endless loops
        saved_value = value

        avl_len = maxline - line_pos - quote_len

        # Decide whether to start a new line
        if len(value) > avl_len - end_space:
            if avoid_splits or avl_len < 0:
                # Start a new line
                mof.append(new_line)
                line_pos = indent
                avl_len = maxline - indent - quote_len
            else:
                # Find last fitting blank
                blank_pos = value.rfind(u' ', 0, avl_len)
                if blank_pos < 0:
                    # We cannot split at a blank -> start a new line
                    mof.append(new_line)
                    line_pos = indent
                    avl_len = maxline - indent - quote_len

        # Check whether the entire string fits (that is a last line, then)
        if len(value) <= avl_len - end_space:
            mof.append(quote_char)
            mof.append(value)
            mof.append(quote_char)
            line_pos += quote_len + len(value)
            break

        # Split the string and output the next part
        split_pos = value.rfind(u' ', 0, avl_len)
        if split_pos < 0:
            # We have to split within a word
            split_pos = avl_len - 1
        part_value = value[0:split_pos + 1]
        value = value[split_pos + 1:]
        mof.append(quote_char)
        mof.append(part_value)
        mof.append(quote_char)
        line_pos += quote_len + len(part_value)

        if value == u'':
            break

        # A safety check for endless loops
        assert value != saved_value, \
            _format("Endless loop in mofstr() with state: "
                    "mof_str={0!A}, value={1!A}, avl_len={2}, end_space={3}, "
                    "split_pos={4}",
                    u''.join(mof), value, avl_len, end_space, split_pos)

    mof_str = u''.join(mof)
    return mof_str, line_pos


def mofval(value, indent=MOF_INDENT, maxline=MAX_MOF_LINE, line_pos=0,
           end_space=0):
    """
    Low level function that returns the MOF representation of a non-string
    value (i.e. a value that cannot not be split into multiple parts, for
    example a numeric or boolean value).

    If the MOF representation of the value does not fit into the remaining
    space of the current line, it is put into a new line, considering the
    specified indentation. If it also does not fit on the remaining space of
    the new line, ValueError is raised.

    Parameters:

      value (:term:`unicode string`): The non-string value. Must not be `None`.

      indent (:term:`integer`): Number of spaces to indent any new lines that
        are generated.

      maxline (:term:`integer`): Maximum line length for the generated MOF.

      line_pos (:term:`integer`): Length of content already on the current
        line.

      end_space (:term:`integer`): Length of space to be left free on the last
        line.

    Returns:

      tuple of
        * :term:`unicode string`: MOF string.
        * new line_pos

    Raises:

      ValueError: The value does not fit onto an entire new line.
    """

    assert isinstance(value, six.text_type)

    # Check for output on current line
    avl_len = maxline - line_pos - end_space
    if len(value) <= avl_len:
        line_pos += len(value)
        return value, line_pos

    # Check for output on new line
    avl_len = maxline - indent - end_space
    if len(value) <= avl_len:
        mof_str = u'\n' + _indent_str(indent) + value
        line_pos = indent + len(value)
        return mof_str, line_pos

    raise ValueError(
        _format("Cannot fit value {0!A} onto new MOF line, missing {1} "
                "characters", value, len(value) - avl_len))


def moftype(cim_type, refclass):
    """
    Converts a CIM data type name to MOF syntax.
    """

    return (refclass + ' REF') if cim_type == 'reference' else cim_type


def _scalar_value_tomof(
        value, type, indent=0, maxline=MAX_MOF_LINE, line_pos=0, end_space=0,
        avoid_splits=False):
    # pylint: disable=line-too-long,redefined-builtin
    """
    Return a MOF string representing a scalar CIM-typed value.

    `None` is returned as 'NULL'.

    Parameters:

      value (:term:`CIM data type`, :class:`~pywbem.CIMInstance`, :class:`~pywbem.CIMClass`):
        The scalar CIM-typed value. May be `None`.

        Must not be an array/list/tuple. Must not be a :ref:`CIM object` other
        than those listed.

      type (string): CIM data type name.

      indent (:term:`integer`): Number of spaces to indent any new lines that
        are generated.

      maxline (:term:`integer`): Maximum line length for the generated MOF.

      line_pos (:term:`integer`): Length of content already on the current
        line.

      end_space (:term:`integer`): Length of space to be left free on the last
        line.

      avoid_splits (bool): Avoid splits at the price of starting a new line
        instead of using the current line.

    Returns:

      tuple of
        * :term:`unicode string`: MOF string.
        * new line_pos
    """  # noqa: E501

    if value is None:
        return mofval(u'NULL', indent, maxline, line_pos, end_space)

    if type == 'string':
        if isinstance(value, six.string_types):
            return mofstr(value, indent, maxline, line_pos, end_space,
                          avoid_splits)

        if isinstance(value, (CIMInstance, CIMClass)):
            # embedded instance or class
            return mofstr(value.tomof(), indent, maxline, line_pos, end_space,
                          avoid_splits)
        raise TypeError(
            _format("Scalar value of CIM type {0} has invalid Python type "
                    "type {1} for conversion to a MOF string",
                    type, builtin_type(value)))

    if type == 'char16':
        return mofstr(value, indent, maxline, line_pos, end_space, avoid_splits,
                      quote_char=u"'")

    if type == 'boolean':
        val = u'true' if value else u'false'
        return mofval(val, indent, maxline, line_pos, end_space)

    if type == 'datetime':
        val = six.text_type(value)
        return mofstr(val, indent, maxline, line_pos, end_space, avoid_splits)

    if type == 'reference':
        val = value.to_wbem_uri()
        return mofstr(val, indent, maxline, line_pos, end_space, avoid_splits)

    assert isinstance(value, (CIMFloat, CIMInt)), \
        _format("Scalar value of CIM type {0} has invalid Python type {1} "
                "for conversion to a MOF string",
                type, builtin_type(value))
    val = six.text_type(value)
    return mofval(val, indent, maxline, line_pos, end_space)


def _value_tomof(
        value, type, indent=0, maxline=MAX_MOF_LINE, line_pos=0, end_space=0,
        avoid_splits=False):
    # pylint: disable=redefined-builtin
    """
    Return a MOF string representing a CIM-typed value (scalar or array).

    In case of an array, the array items are separated by comma, but the
    surrounding curly braces are not added.

    Parameters:

      value (CIM-typed value or list of CIM-typed values): The value.

      indent (:term:`integer`): Number of spaces to indent any new lines that
        are generated.

      maxline (:term:`integer`): Maximum line length for the generated MOF.

      line_pos (:term:`integer`): Length of content already on the current
        line.

      end_space (:term:`integer`): Length of space to be left free on the last
        line.

      avoid_splits (bool): Avoid splits at the price of starting a new line
        instead of using the current line.

    Returns:

      tuple of
        * :term:`unicode string`: MOF string.
        * new line_pos
    """

    if isinstance(value, list):

        mof = []

        for i, v in enumerate(value):

            if i > 0:
                # Assume we would add comma and space as separator
                line_pos += 2

            val_str, line_pos = _scalar_value_tomof(
                v, type, indent, maxline, line_pos, end_space + 2, avoid_splits)

            if i > 0:
                # Add the actual separator
                mof.append(u',')
                if val_str[0] != '\n':
                    mof.append(u' ')
                else:
                    # Adjust by the space we did not need
                    line_pos -= 1

            mof.append(val_str)

        mof_str = u''.join(mof)

    else:
        mof_str, line_pos = _scalar_value_tomof(
            value, type, indent, maxline, line_pos, end_space, avoid_splits)

    return mof_str, line_pos


def _cim_keybinding(key, value):
    """
    Return a keybinding value, from dict item input (key+value).
    Key may be None (for unnamed keys).

    The returned value will be a CIM-typed value, except if it was provided as
    Python number type (in which case it will remain that type).

    Invalid types or values cause TypeError or ValueError to be raised.
    """

    if key is not None and isinstance(value, CIMProperty):
        if value.name.lower() != key.lower():
            raise ValueError(
                _format("Invalid keybinding name: CIMProperty.name must be "
                        "dictionary key {0!A}, but is {1!A}",
                        key, value.name))
        if value.type == 'char16':
            return Char16(value.value)
        return copy_.copy(value.value)

    if value is None:
        return None

    if isinstance(value, six.text_type):
        return value

    if isinstance(value, six.binary_type):
        return _to_unicode(value)

    if isinstance(value, (bool, CIMInstanceName, CIMType)):
        return value

    # pylint: disable=unidiomatic-typecheck
    if builtin_type(value) in number_types:
        # Note: The CIM data types are derived from the built-in types, so we
        # cannot use isinstance() for this test.

        # Ideally, pywbem won't accept keybinding values specified as Python
        # number typed values, but require a CIM data type (e.g. Uint32 or
        # Real32).
        # However, there are two reasons for continuing to allow that:
        # * It was allowed in earlier versions of pywbem.
        # * Parsing the (untyped) WBEM URI of an instance path, results in
        #   int or float values without size, and the size information
        #   to automatically convert that into numeric CIM data types is
        #   not available.
        return value

    if isinstance(value, (CIMClass, CIMInstance)):
        raise TypeError(
            _format("Value of keybinding {0!A} cannot be an embedded object: "
                    "{1}", key, type(value)))

    if isinstance(value, list):
        raise TypeError(
            _format("Value of keybinding {0!A} cannot be a list", key))

    raise TypeError(
        _format("Value of keybinding {0!A} has an invalid type: {1}",
                key, type(value)))


def _cim_property_value(key, value):
    """
    Return a CIMProperty object for representing a property value, from dict
    item input (key+value), after performing some checks.

    If the input value is a CIMProperty object, it is returned.

    Otherwise, a new CIMProperty object is created from the input value, and
    returned.
    """

    if key is None:
        raise ValueError("Property name must not be None")

    if isinstance(value, CIMProperty):
        if value.name.lower() != key.lower():
            raise ValueError(
                _format("CIMProperty.name must be dictionary key {0!A}, but is"
                        "{1!A}", key, value.name))
        prop = value
    else:
        # We no longer check for the common error to set CIM numeric values as
        # Python number types, because that is done in the CIMProperty
        # init method.
        prop = CIMProperty(key, value)

    return prop


def _cim_property_decl(key, value):
    """
    Return a CIMProperty object for representing a property declaration, from
    dict item input (key+value), after performing some checks.

    The input value must be a CIMProperty object, which is returned.
    """

    if key is None:
        raise ValueError("Property name must not be None")

    try:
        assert isinstance(value, CIMProperty)
    except AssertionError:
        raise TypeError(
            _format("Property must be a CIMProperty object, but is: {0}",
                    type(value)))

    if value.name.lower() != key.lower():
        raise ValueError(
            _format("CIMProperty.name must be dictionary key {0!A}, but is "
                    "{1!A}", key, value.name))

    return value


def _cim_method(key, value):
    """
    Return a CIMMethod object, from dict item input (key+value), after
    performing some checks.

    The input value must be a CIMMethod object, which is returned.
    """

    if key is None:
        raise ValueError("Method name must not be None")

    try:
        assert isinstance(value, CIMMethod)
    except AssertionError:
        raise TypeError(
            _format("Method must be a CIMMethod object, but is: {0}",
                    type(value)))

    if value.name.lower() != key.lower():
        raise ValueError(
            _format("CIMMethod.name must be dictionary key {0!A}, but is ",
                    "{1!A}", key, value.name))

    return value


def _cim_parameter(key, value):
    """
    Return a CIMParameter object, from dict item input (key+value), after
    performing some checks.

    The input value must be a CIMParameter object, which is returned.
    """

    if key is None:
        raise ValueError("Parameter name must not be None")

    try:
        assert isinstance(value, CIMParameter)
    except AssertionError:
        raise TypeError(
            _format("Parameter must be a CIMParameter object, but is: {0}",
                    type(value)))

    if value.name.lower() != key.lower():
        raise ValueError(
            _format("CIMParameter.name must be dictionary key {0!A}, but is ",
                    "{1!A}", key, value.name))

    return value


def _cim_qualifier(key, value):
    """
    Return a CIMQualifier object, from dict item input (key+value), after
    performing some checks.

    If the input value is a CIMQualifier object, it is returned.

    Otherwise, a new CIMQualifier object is created from the input value, and
    returned.
    """

    if key is None:
        raise ValueError("Qualifier name must not be None")

    if isinstance(value, CIMQualifier):
        if value.name.lower() != key.lower():
            raise ValueError(
                _format("CIMQualifier.name must be dictionary key {0!A}, but "
                        "is {1!A}", key, value.name))
        qual = value
    else:
        # We no longer check for the common error to set CIM numeric values as
        # Python number types, because that is done in the CIMQualifier
        # init method.
        qual = CIMQualifier(key, value)

    return qual


[docs]class CIMInstanceName(_CIMComparisonMixin, SlottedPickleMixin): """ A CIM instance path (aka *CIM instance name*). A CIM instance path references a CIM instance in a CIM namespace in a WBEM server. Namespace and WBEM server may be unspecified. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_classname', '_keybindings', '_host', '_namespace'] def __init__(self, classname, keybindings=None, host=None, namespace=None): # pylint: disable=line-too-long """ Parameters: classname (:term:`string`): Name of the creation class of the referenced instance. Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. keybindings (:term:`keybindings input object`): Keybindings for the instance path (that is, the key property values of the referenced instance). host (:term:`string`): Host and optionally port of the WBEM server containing the CIM namespace of the referenced instance. The format of the string must be: ``host[:port]`` The host can be specified in any of the usual formats: * a short or fully qualified DNS hostname * a literal (= dotted) IPv4 address * a literal IPv6 address, formatted as defined in :term:`RFC3986` with the extensions for zone identifiers as defined in :term:`RFC6874`, supporting ``-`` (minus) for the delimiter before the zone ID string, as an additional choice to ``%25``. `None` means that the WBEM server is unspecified, and the :attr:`~pywbem.CIMInstanceName.host` attribute will also be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. namespace (:term:`string`): Name of the CIM namespace containing the referenced instance. `None` means that the namespace is unspecified, and the :attr:`~pywbem.CIMInstanceName.namespace` attribute will also be `None`. Leading and trailing slash characters will be stripped. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. Raises: ValueError: An error in the provided argument values. ValueError: A keybinding value is `None` and the config variable pywbem.config.IGNORE_NULL_KEY_VALUE is `False` TypeError: An error in the provided argument types. """ # noqa: E501 # We use the respective setter methods: self.classname = classname self.keybindings = keybindings self.namespace = namespace self.host = host @property def classname(self): """ :term:`unicode string`: Class name of this CIM instance path, identifying the creation class of the referenced instance. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMInstanceName>`. """ return self._classname @classname.setter def classname(self, classname): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._classname = _ensure_unicode(classname) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if classname is None: raise ValueError("Class name in instance path must not be None") @property def keybindings(self): """ `NocaseDict`_: Keybindings of this CIM instance path, identifying the key properties of the referenced instance. Will not be `None`. Each dictionary item specifies one keybinding, with: * key (:term:`unicode string`): Keybinding name. Its lexical case was preserved. * value (:term:`CIM data type` or :term:`number`): Keybinding value. `None` is not allowed by default, consistent with :term:`DSP0004`. This default behavior can be changed via the config variable :attr:`pywbem.config.IGNORE_NULL_KEY_VALUE`. The order of keybindings in the instance path is preserved. The keybinding name may be `None` in objects of this class that are created by pywbem, in the special case a WBEM server has returned an instance path with an unnamed keybinding (i.e. a KEYVALUE or VALUE.REFERENCE element without a parent KEYBINDINGS element). This is allowed as per :term:`DSP0201`. When creating objects of this class, it is not allowed to specify unnamed keybindings, i.e. the keybinding name must not be `None`. This attribute is settable; setting it will cause the current keybindings to be replaced with the new keybindings. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMInstanceName>`. When setting a keybinding value, it will be preserved whether the input value was a :term:`CIM data type`, a :term:`number` or `None`. If the input value was a :term:`CIM data type`, the CIM type of the keybinding value is known and this will cause the TYPE attribute in the KEYVALUE element of the CIM-XML representation to be present. The keybindings can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. The provided input value must be specified as a :term:`CIM data type` or as :term:`number`:: instpath = CIMInstanceName(...) v1 = "abc" # must be a CIM data type or Python number type instpath.keybindings['k1'] = v1 # Set "k1" to v1 (add if needed) v1 = instpath.keybindings['k1'] # Access value of "k1" del instpath.keybindings['k1'] # Delete "k1" from the inst. path In addition, the keybindings can be accessed and manipulated one by one by using the entire :class:`~pywbem.CIMInstanceName` object like a dictionary. Again, the provided input value must be specified as a :term:`CIM data type` or as :term:`number`:: instpath = CIMInstanceName(...) v2 = 42 # must be a CIM data type or Python number type instpath['k2'] = v2 # Set "k2" to v2 (add if needed) v2 = instpath['k2'] # Access value of "k2" del instpath['k2'] # Delete "k2" from the instance path """ if self._keybindings is None: # Lazy initialization self._keybindings = NocaseDict() self._keybindings.allow_unnamed_keys = True return self._keybindings @keybindings.setter def keybindings(self, keybindings): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._keybindings = None # Lazy initialization if keybindings: try: # This is used for iterables: iterator = keybindings.items() except AttributeError: # This is used for dictionaries: iterator = keybindings for item in iterator: if isinstance(item, CIMProperty): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for keybindings has invalid " "item in iterable: {0!A}", item)) if value is None and \ config.IGNORE_NULL_KEY_VALUE is False: raise ValueError( _format("Key {1!A} in the new keybindings ({0!A}) is " "'None' and that is not allowed by default. " "This default behavior can be changed via " "config variable " "'pywbem.config.IGNORE_NULL_KEY_VALUE'.", keybindings, key)) self.keybindings[key] = _cim_keybinding(key, value) @property def namespace(self): """ :term:`unicode string`: Namespace name of this CIM instance path, identifying the namespace of the referenced instance. `None` means that the namespace is unspecified. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMInstanceName>`. """ return self._namespace @namespace.setter def namespace(self, namespace): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._namespace = _ensure_unicode(namespace) if self._namespace is not None: # In Python 3, a byte string cannot be stripped by a unicode char # Therefore, the stripping needs to be done after the unicode # conversion. self._namespace = self._namespace.strip('/') @property def host(self): """ :term:`unicode string`: Host and optionally port of this CIM instance path, identifying the WBEM server of the referenced instance. For details about the string format, see the same-named init parameter of :class:`this class <pywbem.CIMInstanceName>`. `None` means that the host and port are unspecified. This attribute is settable. For details, see the description of the same-named init parameter. """ return self._host @host.setter def host(self, host): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._host = _ensure_unicode(host)
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMInstanceName` objects. The equality is based on their public attributes: * `host` * `namespace` * `classname` * `keybindings` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMInstanceName` object. """ if self is other: return True if not isinstance(other, CIMInstanceName): raise TypeError( _format("other must be CIMInstanceName, but is: {0}", type(other))) return (_eq_name(self.host, other.host) and _eq_name(self.namespace, other.namespace) and _eq_name(self.classname, other.classname) and _eq_dict(self.keybindings, other.keybindings))
[docs] def __hash__(self): """ Return a hash value based on the public attributes of this class, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.host), _hash_name(self.namespace), _hash_name(self.classname), _hash_dict(self.keybindings), ) return hash(hashes)
[docs] def __str__(self): """ Return the WBEM URI string of this CIM instance path. The returned WBEM URI string is in the historical format returned by :meth:`~pywbem.CIMInstanceName.to_wbem_uri`. For new code, it is recommended that the standard format is used; it is returned by :meth:`~pywbem.CIMInstanceName.to_wbem_uri` as the default format. Examples (for the historical format): * With host and namespace:: //acme.com/cimv2/test:CIM_RegisteredProfile.InstanceID="acme.1" * Without host but with namespace:: cimv2/test:CIM_RegisteredProfile.InstanceID="acme.1" * Without host and without namespace:: CIM_RegisteredProfile.InstanceID="acme.1" """ return self.to_wbem_uri(format='historical')
[docs] def __repr__(self): """ Return a string representation of this CIM instance path, that is suitable for debugging. The key bindings will be ordered by their names in the result. """ return _format( "CIMInstanceName(" "classname={s.classname!A}, " "keybindings={s.keybindings!A}, " "namespace={s.namespace!A}, " "host={s.host!A})", s=self)
def __contains__(self, key): "" # Avoids docstring to be inherited return key in self.keybindings def __getitem__(self, key): "" # Avoids docstring to be inherited return self.keybindings[key] def __setitem__(self, key, value): "" # Avoids docstring to be inherited self.keybindings[key] = value def __delitem__(self, key): "" # Avoids docstring to be inherited del self.keybindings[key] def __len__(self): "" # Avoids docstring to be inherited return len(self.keybindings) def __iter__(self): "" # Avoids docstring to be inherited return six.iterkeys(self.keybindings)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMInstanceName` object that is a copy of this CIM instance path. This is a middle-deep copy; any mutable types in attributes except the following are copied, so besides these exceptions, modifications of the original object will not affect the returned copy, and vice versa. The following mutable types are not copied and are therefore shared between original and copy: * Any mutable object types (see :ref:`CIM data types`) in the :attr:`~pywbem.CIMInstanceName.keybindings` dictionary (but not the dictionary object itself) Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ return CIMInstanceName( self.classname, keybindings=self.keybindings, # setter copies host=self.host, namespace=self.namespace)
[docs] def update(self, *args, **kwargs): """ Update the keybindings of this CIM instance path. Existing keybindings will be updated, and new keybindings will be added. Parameters: *args (list): Keybindings for updating the keybindings of the instance path, specified as positional arguments. Each positional argument must be a tuple (key, value), where key and value are described for setting the :attr:`~pywbem.CIMInstanceName.keybindings` property. **kwargs (dict): Keybindings for updating the keybindings of the instance path, specified as keyword arguments. The name and value of the keyword arguments are described as key and value for setting the :attr:`~pywbem.CIMInstanceName.keybindings` property. """ self.keybindings.update(*args, **kwargs)
[docs] def has_key(self, key): """ Return a boolean indicating whether this CIM instance path has a particular keybinding. Parameters: key (:term:`string`): Name of the keybinding (in any lexical case). Returns: :class:`py:bool`: Boolean indicating whether this CIM instance path has the keybinding. """ return key in self.keybindings
[docs] def get(self, key, default=None): """ Return the value of a particular keybinding of this CIM instance path, or a default value. *New in pywbem 0.8.* Parameters: key (:term:`string`): Name of the keybinding (in any lexical case). default (:term:`CIM data type`): Default value that is returned if a keybinding with the specified name does not exist in the instance path. Returns: :term:`CIM data type`: Value of the keybinding, or the default value. """ return self.keybindings.get(key, default)
[docs] def keys(self): # pylint: disable=line-too-long """ Return the keybinding names of this CIM instance path. The type of the returned object is consistent with the behavior of the corresponding method of the built-in dict class: On Python 2, a list is returned; on Python 3, a `dictionary view <https://docs.python.org/3/library/stdtypes.html#dictionary-view-objects>`_ is returned. The keybinding names have their original lexical case and the order of keybindings is preserved. """ # noqa: E501 # pylint: enable=line-too-long return self.keybindings.keys()
[docs] def values(self): # pylint: disable=line-too-long """ Return the keybinding values of this CIM instance path. The type of the returned object is consistent with the behavior of the corresponding method of the built-in dict class: On Python 2, a list is returned; on Python 3, a `dictionary view <https://docs.python.org/3/library/stdtypes.html#dictionary-view-objects>`_ is returned. The order of keybindings is preserved. """ # noqa: E501 # pylint: enable=line-too-long return self.keybindings.values()
[docs] def items(self): # pylint: disable=line-too-long """ Return the keybinding items as a tuple (name, value) of this CIM instance path. The type of the returned object is consistent with the behavior of the corresponding method of the built-in dict class: On Python 2, a list is returned; on Python 3, a `dictionary view <https://docs.python.org/3/library/stdtypes.html#dictionary-view-objects>`_ is returned. The keybinding names have their original lexical case and the order of keybindings is preserved. """ # noqa: E501 # pylint: enable=line-too-long return self.keybindings.items()
[docs] def iterkeys(self): """ Return an iterator through the keybinding names of this CIM instance path. The keybinding names have their original lexical case, and the order of keybindings is preserved. Deprecated: This method is deprecated on Python 3 and will be removed in a future version of pywbem, consistent with the built-in dict class on Python 3. Use the :meth:`keys` method instead. """ if six.PY3: warnings.warn( "The iterkeys() method of pywbem.CIMInstanceName has been " "deprecated on Python 3 and will be removed in a future " "version of pywbem", DeprecationWarning, 2) return six.iterkeys(self.keybindings)
[docs] def itervalues(self): """ Return an iterator through the keybinding values of this CIM instance path. The order of keybindings is preserved. Deprecated: This method is deprecated on Python 3 and will be removed in a future version of pywbem, consistent with the built-in dict class on Python 3. Use the :meth:`values` method instead. """ if six.PY3: warnings.warn( "The itervalues() method of pywbem.CIMInstanceName has been " "deprecated on Python 3 and will be removed in a future " "version of pywbem", DeprecationWarning, 2) return six.itervalues(self.keybindings)
[docs] def iteritems(self): """ Return an iterator through the keybinding items of this CIM instance path, where each item is a tuple of keybinding name and value. The keybinding names have their original lexical case, and the order of keybindings is preserved. Deprecated: This method is deprecated on Python 3 and will be removed in a future version of pywbem, consistent with the built-in dict class on Python 3. Use the :meth:`items` method instead. """ if six.PY3: warnings.warn( "The iteritems() method of pywbem.CIMInstanceName has been " "deprecated on Python 3 and will be removed in a future " "version of pywbem", DeprecationWarning, 2) return six.iteritems(self.keybindings)
# pylint: disable=too-many-branches
[docs] def tocimxml(self, ignore_host=False, ignore_namespace=False): """ Return the CIM-XML representation of this CIM instance path, as an object of an appropriate subclass of :term:`Element`. If the instance path has no namespace specified or if `ignore_namespace` is `True`, the returned CIM-XML representation is an `INSTANCENAME` element consistent with :term:`DSP0201`. Otherwise, if the instance path has no host specified or if `ignore_host` is `True`, the returned CIM-XML representation is a `LOCALINSTANCEPATH` element consistent with :term:`DSP0201`. Otherwise, the returned CIM-XML representation is a `INSTANCEPATH` element consistent with :term:`DSP0201`. The order of keybindings in the returned CIM-XML representation is preserved from the :class:`~pywbem.CIMInstanceName` object. :class:`~pywbem.CIMInstanceName` objects without keybindings cause a UserWarning to be issued, because this is invalid according to :term:`DSP0004` (section 7.7.5). Parameters: ignore_host (:class:`py:bool`): Ignore the host of the instance path, even if a host is specified. ignore_namespace (:class:`py:bool`): Ignore the namespace and host of the instance path, even if a namespace and/or host is specified. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ kbs = [] # We no longer check that the keybindings is a NocaseDict because we # ensure that in the keybindings() property setter method. for key, value in self.keybindings.items(): # Keybindings can be integers, booleans, strings or references. # References can only by instance names. if isinstance(value, CIMInstanceName): kbs.append(_cim_xml.KEYBINDING( key, _cim_xml.VALUE_REFERENCE(value.tocimxml()))) continue if isinstance(value, Char16): value_type = 'string' cim_type = 'char16' elif isinstance(value, six.text_type): value_type = 'string' cim_type = 'string' elif isinstance(value, six.binary_type): value_type = 'string' cim_type = 'string' value = _to_unicode(value) elif isinstance(value, bool): # Note: Bool is a subtype of int, therefore bool is tested # before int. value_type = 'boolean' cim_type = 'boolean' if value: value = 'TRUE' else: value = 'FALSE' elif isinstance(value, CIMDateTime): value_type = 'string' cim_type = value.cimtype value = str(value) elif isinstance(value, (CIMInt, CIMFloat)): # Numeric CIM data types derive from Python number types. value_type = 'numeric' cim_type = value.cimtype value = str(value) elif isinstance(value, number_types): value_type = 'numeric' # Without CIM type information in the keybindings, pywbem cannot # determine the CIM type from the value alone. This will cause # the TYPE attribute not to be set, violating the requirement # to set the TYPE attribute that was introduced in DTD 2.4. cim_type = None value = str(value) else: # Double check the type of the keybindings, because they can be # set individually. raise TypeError( _format("Keybinding {0!A} has invalid type: {1}", key, builtin_type(value))) kbs.append(_cim_xml.KEYBINDING( key, _cim_xml.KEYVALUE(value, value_type, cim_type))) if not kbs: warnings.warn( _format( "Instance path without keybindings encountered for " "classname {0!A} when converting to CIM-XML - this not " "permitted according to DSP0004", self.classname), MissingKeybindingsWarning, _stacklevel_above_module('pywbem')) instancename_xml = _cim_xml.INSTANCENAME(self.classname, kbs) if self.namespace is None or ignore_namespace: return instancename_xml localnsp_xml = _cim_xml.LOCALNAMESPACEPATH( [_cim_xml.NAMESPACE(ns) for ns in self.namespace.split('/')]) if self.host is None or ignore_host: return _cim_xml.LOCALINSTANCEPATH(localnsp_xml, instancename_xml) return _cim_xml.INSTANCEPATH( _cim_xml.NAMESPACEPATH(_cim_xml.HOST(self.host), localnsp_xml), instancename_xml)
[docs] def tocimxmlstr(self, indent=None, ignore_host=False, ignore_namespace=False): """ Return the CIM-XML representation of this CIM instance path, as a :term:`unicode string`. *New in pywbem 0.9.* For the returned CIM-XML representation, see :meth:`~pywbem.CIMInstanceName.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. ignore_host (:class:`py:bool`): Ignore the host of the instance path, even if a host is specified. ignore_namespace (:class:`py:bool`): Ignore the namespace and host of the instance path, even if a namespace and/or host is specified. Returns: The CIM-XML representation of the value, as a :term:`unicode string`. """ xml_elem = self.tocimxml(ignore_host, ignore_namespace) return tocimxmlstr(xml_elem, indent)
@staticmethod def _kbstr_to_cimval(key, val): """ Convert a keybinding value string as found in a WBEM URI into a CIM object or CIM data type, and return it. """ if val[0] == '"' and val[-1] == '"': # A double quoted key value. This could be any of these CIM types: # * string (see stringValue in DSP00004) # * datetime (see datetimeValue in DSP0207) # * reference (see referenceValue in DSP0207) # Note: The actual definition of referenceValue is missing in # DSP0207, see issue #929. Pywbem implements: # referenceValue = WBEM-URI-UntypedInstancePath. # Note: The definition of stringValue in DSP0004 allows multiple # quoted parts (as in MOF), see issue #931. Pywbem implements only # a single quoted part. # We use slicing instead of strip() for removing the surrounding # double quotes, because there could be an escaped double quote # before the terminating double quote. cimval = val[1:-1] # Unescape the backslash-escaped string value cimval = re.sub(r'\\(.)', r'\1', cimval) # Try all possibilities. Note that this means that string-typed # properties that happen to contain a datetime value will be # converted to datetime, and string-typed properties that happen to # contain a reference value will be converted to a reference. # This is a general limitation of untyped WBEM URIs as defined in # DSP0207 and cannot be solved by using a different parsing logic. try: cimval = CIMInstanceName.from_wbem_uri(cimval) except ValueError: try: cimval = CIMDateTime(cimval) except ValueError: cimval = _ensure_unicode(cimval) return cimval if val[0] == "'" and val[-1] == "'": # A single quoted key value. This must be CIM type: # * char16 (see charValue in DSP00004) # Note: The definition of charValue in DSP0004 allows for integer # numbers in addition to single quoted strings, see issue #932. # Pywbem implements only single quoted strings. cimval = val[1:-1] cimval = re.sub(r'\\(.)', r'\1', cimval) cimval = _ensure_unicode(cimval) if len(cimval) != 1: raise ValueError( _format("WBEM URI has a char16 keybinding with an " "incorrect length: {0!A}={1!A}", key, val)) return cimval if val.lower() in ('true', 'false'): # The key value must be CIM type: # * boolean (see booleanValue in DSP00004) cimval = val.lower() == 'true' return cimval # Try CIM types uint<NN> or sint<NN> (see integerValue in DSP00004). # * For integer keybindings in an untyped WBEM URI, it is # not possible to detect the exact CIM data type. Therefore, pywbem # stores the value as a Python int type (or long in Python 2, # if needed). cimval = _integerValue_to_int(val) if cimval is not None: return cimval # Try CIM types real32/64 (see realValue in DSP00004). # * For real/float keybindings in an untyped WBEM URI, it is not # possible to detect the exact CIM data type. Therefore, pywbem # stores the value as a Python float type. cimval = _realValue_to_float(val) if cimval is not None: return cimval # Try datetime types. # At this point, all CIM types have been processed, except: # * datetime, without quotes (see datetimeValue in DSP0207) # DSP0207 requires double quotes around datetime strings, but because # earlier versions of pywbem supported them without double quotes, # pywbem continues to support that, but issues a warning. try: cimval = CIMDateTime(val) except ValueError: raise ValueError( _format("WBEM URI has invalid value format in a keybinding: " "{0!A}={1!A}", key, val)) warnings.warn( _format("Tolerating datetime value without surrounding double " "quotes in WBEM URI keybinding: {0!A}={1!A}", key, val), UserWarning) return cimval
[docs] @staticmethod def from_wbem_uri(wbem_uri): # pylint: disable=line-too-long """ Return a new :class:`~pywbem.CIMInstanceName` object from the specified WBEM URI string. *New in pywbem 0.12.* The WBEM URI string must be a CIM instance path in untyped WBEM URI format, as defined in :term:`DSP0207`, with these extensions: * :term:`DSP0207` restricts the namespace types (URI schemes) to be one of ``http``, ``https``, ``cimxml-wbem``, or ``cimxml-wbems``. Pywbem tolerates any namespace type, but issues a :exc:`py:UserWarning` if it is not one of the namespace types defined in :term:`DSP0207`. * :term:`DSP0207` requires a slash before the namespace name. For local WBEM URIs (no namespace type, no authority), that slash is the first character of the WBEM URI. For historical reasons, pywbem tolerates a missing leading slash for local WBEM URIs. Note that pywbem requires the slash (consistent with :term:`DSP0207`) when the WBEM URI is not local. * :term:`DSP0207` requires a colon before the class name. For historical reasons, pywbem tolerates a missing colon before the class name, if it would have been the first character of the string. * :term:`DSP0207` requires datetime values in keybindings to be surrounded by double quotes. For historical reasons, pywbem tolerates datetime values that are not surrounded by double quotes, but issues a :exc:`py:UserWarning`. * :term:`DSP0207` does not allow the special float values INF, -INF, and NaN in WBEM URIs (according to realValue in :term:`DSP0004`). However, the CIM-XML protocol supports representation of these special values, so to be on the safe side, pywbem supports these special values as keybindings in WBEM URIs. Keybindings that are references are supported, recursively. CIM instance paths in the typed WBEM URI format defined in :term:`DSP0207` are not supported. The untyped WBEM URI format defined in :term:`DSP0207` has the following limitations when interpreting a WBEM URI string: * It cannot distinguish string-typed keys with a value that is a datetime value from datetime-typed keys with such a value. Pywbem treats such values as datetime-typed keys. * It cannot distinguish string-typed keys with a value that is a WBEM URI from reference-typed keys with such a value. Pywbem treats such values as reference-typed keys. Examples:: https://jdd:test@acme.com:5989/cimv2/test:CIM_RegisteredProfile.InstanceID="acme.1" //jdd:test@acme.com:5989/cimv2/test:CIM_RegisteredProfile.InstanceID="acme.1" /cimv2/test:CIM_RegisteredProfile.InstanceID="acme.1" cimv2/test:CIM_RegisteredProfile.InstanceID="acme.1" /:CIM_RegisteredProfile.InstanceID="acme.1" :CIM_RegisteredProfile.InstanceID="acme.1" CIM_RegisteredProfile.InstanceID="acme.1" http://acme.com/root/cimv2:CIM_ComputerSystem.CreationClassName="ACME_CS",Name="sys1" /:CIM_SubProfile.Main="/:CIM_RegisteredProfile.InstanceID=\"acme.1\"",Sub="/:CIM_RegisteredProfile.InstanceID=\"acme.2\"" Parameters: wbem_uri (:term:`string`): WBEM URI for an instance path. Returns: :class:`~pywbem.CIMInstanceName`: The instance path created from the specified WBEM URI string. Raises: ValueError: Invalid WBEM URI format for an instance path. This includes typed WBEM URIs. """ m = WBEM_URI_INSTANCEPATH_REGEXP.match(wbem_uri) if m is None: raise ValueError( _format("Invalid format for an instance path in WBEM URI: " "{0!A}", wbem_uri)) ns_type = m.group(1) or None if ns_type and ns_type.lower() not in WBEM_URI_NAMESPACE_TYPES: warnings.warn( _format("Tolerating unknown namespace type in WBEM URI: {0!A}", wbem_uri), UserWarning) host = m.group(2) or None namespace = m.group(3) or None classname = m.group(4) or None assert classname is not None # should be ensured by regexp keybindings_str = m.group(5) or None m = WBEM_URI_KEYBINDINGS_REGEXP.match(keybindings_str) if m is None: raise ValueError( _format("WBEM URI has an invalid format for its keybindings: " "{0!A}", keybindings_str)) if m.group(1): kb_assigns = [m.group(1)] if m.group(2): for s in WBEM_URI_KB_FINDALL_REGEXP.findall(m.group(2)): if s[0] == ',': s = s[1:] kb_assigns.append(s) keybindings = {} for kb_assign in kb_assigns: key, sep, val = _partition(kb_assign, '=') # the regexp ensures that it's there: assert sep, \ _format("separator missing in kb_assign: {0!A}", kb_assign) keybindings[key] = CIMInstanceName._kbstr_to_cimval(key, val) obj = CIMInstanceName( classname=classname, host=host, namespace=namespace, keybindings=keybindings) return obj
[docs] def to_wbem_uri(self, format='standard'): # pylint: disable=redefined-builtin """ Return the (untyped) WBEM URI string of this CIM instance path. The returned WBEM URI contains its components as follows: * it does not contain a namespace type (URI scheme). * it contains an authority (host) component according to the :attr:`~pywbem.CIMInstanceName.host` attribute, if that is not `None`. Otherwise, it does not contain the authority component. * it contains a namespace component according to the :attr:`~pywbem.CIMInstanceName.namespace` attribute, if that is not `None`. Otherwise, it does not contain the namespace component. * it contains a class name component according to the :attr:`~pywbem.CIMInstanceName.classname` attribute. * it contains keybindings according to the :attr:`~pywbem.CIMInstanceName.keybindings` attribute, with the order of keybindings in alphabetical order of the keybinding names, and the lexical case of keybinding names preserved (except when using the format "canonical"). Note that when you do not want some of these components to show up in the resulting WBEM URI string, you can set them to `None` before calling this method. Except when using the format "canonical", this method should not be used to compare instance paths for equality: :term:`DSP0004` defines defines several components of an instance path to be compared case insensitively, including the names of keybindings. In addition, it defines that the order of keybindings in instance paths does not matter for the comparison. Therefore, two instance paths that are considered equal according to :term:`DSP0004` may not have equal WBEM URI strings as returned by this method. Instead, equality of instance paths represented by :class:`~pywbem.CIMInstanceName` objects should be determined by using the ``==`` operator, which performs the comparison conformant to :term:`DSP0004`. If you have WBEM URI strings without the corresponding :class:`~pywbem.CIMInstanceName` object, such an object can be created by using the static method :meth:`~pywbem.CIMInstanceName.from_wbem_uri`. Parameters: format (:term:`string`): Format for the generated WBEM URI string, using one of the following values: * ``"standard"`` - Standard format that is conformant to untyped WBEM URIs for instance paths defined in :term:`DSP0207`. The order of keybindings is in alphabetical order of the original keybinding names. * ``"canonical"`` - Like ``"standard"``, except that the following items have been converted to lower case: host, namespace, classname, and the names of any keybindings. The order of keybindings is in alphabetical order of the lower-cased keybinding names. This format guarantees that two instance paths that are considered equal according to :term:`DSP0004` result in equal WBEM URI strings. Therefore, the returned WBEM URI is suitable to be used as a key in dictionaries of CIM instances. * ``"cimobject"`` - Format for the `CIMObject` header field in CIM-XML messages for representing instance paths (used internally, see :term:`DSP0200`). * ``"historical"`` - Historical format for WBEM URIs (used by :meth:`~pywbem.CIMInstanceName.__str__`; should not be used by new code). The historical format has the following differences to the standard format: - If the host component is not present, the slash after the host is also omitted. In the standard format, that slash is always present. - If the namespace component is not present, the colon after the namespace is also omitted. In the standard format, that colon is always present. Keybindings that are references use the specified format recursively. Examples: * With host and namespace, standard format:: //ACME.com/cimv2/Test:CIM_RegisteredProfile.InstanceID="Acme.1" * With host and namespace, canonical format:: //acme.com/cimv2/test:cim_registeredprofile.instanceid="Acme.1" * Without host but with namespace, standard format:: /cimv2/Test:CIM_RegisteredProfile.InstanceID="Acme.1" * Without host but with namespace, canonical format:: /cimv2/test:cim_registeredprofile.instanceid="Acme.1" * Without host and without namespace, standard format:: /:CIM_RegisteredProfile.InstanceID="Acme.1" Returns: :term:`unicode string`: Untyped WBEM URI of the CIM instance path, in the specified format. Raises: TypeError: Invalid type in keybindings ValueError: Invalid format argument """ ret = [] def case(str_): """Return the string in the correct lexical case for the format.""" if format == 'canonical': str_ = str_.lower() return str_ def case_sorted(keys): """Return the keys in the correct order for the format.""" return sorted([case(k) for k in keys]) if format not in ('standard', 'canonical', 'cimobject', 'historical'): raise ValueError( _format("Invalid format argument: {0}", format)) if not self.keybindings: warnings.warn( _format( "Instance path without keybindings encountered for " "classname {0!A} when converting to WBEM URI - this not " "permitted according to DSP0004", self.classname), MissingKeybindingsWarning, _stacklevel_above_module('pywbem')) if self.host is not None and format != 'cimobject': # The CIMObject format assumes there is no host component ret.append('//') ret.append(case(self.host)) if self.host is not None or format not in ('cimobject', 'historical'): ret.append('/') if self.namespace is not None: ret.append(case(self.namespace)) if self.namespace is not None or format != 'historical': ret.append(':') ret.append(case(self.classname)) ret.append('.') for key in case_sorted(self.keybindings.keys()): value = self.keybindings[key] ret.append(key) ret.append('=') if isinstance(value, six.binary_type): value = _to_unicode(value) if isinstance(value, six.text_type): # string, char16 ret.append('"') ret.append(value. replace('\\', '\\\\'). replace('"', '\\"')) ret.append('"') elif isinstance(value, bool): # boolean # Note that in Python a bool is an int, so test for bool first ret.append(str(value).upper()) elif isinstance(value, (CIMFloat, float)): # realNN # Since Python 2.7 and Python 3.1, repr() prints float numbers # with the shortest representation that does not change its # value. When needed, it shows up to 17 significant digits, # which is the precision needed to round-trip double precision # IEE-754 floating point numbers between decimal and binary # without loss. ret.append(repr(value)) elif isinstance(value, (CIMInt, int, _Longint)): # intNN ret.append(str(value)) elif isinstance(value, CIMInstanceName): # reference ret.append('"') ret.append(value.to_wbem_uri(format=format). replace('\\', '\\\\'). replace('"', '\\"')) ret.append('"') elif isinstance(value, CIMDateTime): # datetime ret.append('"') ret.append(str(value)) ret.append('"') else: raise TypeError( _format("Invalid type {0} in keybinding value: {1!A}={2!A}", type(value), key, value)) ret.append(',') del ret[-1] return _ensure_unicode(''.join(ret))
[docs] @staticmethod def from_instance(class_, instance, namespace=None, host=None, strict=False): """ Return a new :class:`~pywbem.CIMInstanceName` object from the key property values in a CIM instance and the key property definitions in a CIM class. If the `strict` parameter is `False`, and a property value does not exist in the `instance` that entry is not included in the constructed CIMInstanceName If the `strict` parameter is `True` all key properties in the `class_` must exist in the `instance` or a ValueError exception is raised. Parameters: `class_` (:class:`~pywbem.CIMClass`): The CIM class with the key properties. In strict mode, that class and the instance must contain all key properties that are required to create the :class:`~pywbem.CIMInstanceName` object. Thus, for example, if the class were retrieved from a server, generally, the `LocalOnly` parameter in the request should be `False` to assure that superclass properties are retrieved and `IncludeQualifiers` parameter should be set to `True` to assure that qualifiers are retrieved. In non-strict mode, that class and instance may have missing key properties. Any missing key properties will result in missing key bindings in the created :class:`~pywbem.CIMInstanceName` object. The specified class does not need to be the creation class of the instance. Thus, it could be a superclass as long as it has the required key properties. instance (:class:`~pywbem.CIMInstance`): The CIM instance with the key property values. namespace (:term:`string`): Namespace to include in the created :class:`~pywbem.CIMInstanceName` or `None`. host (:term:`string`): Host name to include in created :class:`~pywbem.CIMInstanceName` or `None`. strict (:class:`py:bool`): Strict mode (see description of `class_` parameter). Returns: :class:`~pywbem.CIMInstanceName`: :class:`~pywbem.CIMInstanceName` built from the key properties in the `class_` parameter using the key property values in the `instance` parameter. Raises: ValueError: The `strict` attribute is `True` and a key property does not exist in the instance. """ keybindings = NocaseDict() for prop in class_.properties: if 'key' in class_.properties[prop].qualifiers: pname = class_.properties[prop].name # get original name if prop in instance: keybindings[pname] = instance[prop] else: if strict: raise ValueError( _format("Key property {0!A} of class {1!A} missing " "in instance.", pname, class_.classname)) return CIMInstanceName(class_.classname, keybindings, namespace=namespace, host=host)
[docs]class CIMInstance(_CIMComparisonMixin, SlottedPickleMixin): """ A representation of a CIM instance in a CIM namespace in a WBEM server, optionally including its instance path. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_classname', '_properties', '_qualifiers', '_path'] # pylint: disable=too-many-arguments def __init__(self, classname, properties=None, qualifiers=None, path=None): """ Parameters: classname (:term:`string`): Name of the creation class for the instance. Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. properties (:term:`properties input object`): The property values for the instance. Deprecated: Providing key property values will cause the corresponding keybindings in the instance path (if set) to be updated accordingly. This behavior has been deprecated in pywbem 1.1.0 and will be removed in a future version of pywbem. qualifiers (:term:`qualifiers input object`): The qualifiers for the instance. Note that :term:`DSP0200` has deprecated the presence of qualifiers on CIM instances. path (:class:`~pywbem.CIMInstanceName`): Instance path for the instance. The provided object will be copied before being stored in the :class:`~pywbem.CIMInstance` object. `None` means that the instance path is unspecified, and the :attr:`~pywbem.CIMInstance.path` attribute will also be `None`. Raises: ValueError: classname is `None`, a property or qualifier name is `None`, or a property or qualifier name does not match its dictionary key. TypeError: a numeric Python type was used for a property or qualifier value. """ # We use the respective setter methods: self.classname = classname self.path = path self.properties = properties self.qualifiers = qualifiers @property def classname(self): """ :term:`unicode string`: Name of the creation class of this CIM instance. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMInstance>`. """ return self._classname @classname.setter def classname(self, classname): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._classname = _ensure_unicode(classname) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if classname is None: raise ValueError("Class name in instance must not be None") @property def properties(self): """ `NocaseDict`_: Properties of this CIM instance. Will not be `None`. Each dictionary item specifies one property value, with: * key (:term:`unicode string`): Property name. Its lexical case was preserved. * value (:class:`~pywbem.CIMProperty`): Property value. The order of properties in the CIM instance is preserved. This attribute is settable; setting it will cause the current CIM properties to be replaced with the new properties. Deprecated: Updating a key property will cause the corresponding keybinding in the instance path (if set) to be updated accordingly. This behavior has been deprecated in pywbem 1.1.0 and will be removed in a future version of pywbem. For details, see the description of the same-named init parameter. Note that the property value may be specified as a :term:`CIM data type` or as a :class:`~pywbem.CIMProperty` object. The CIM property values can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. In that case, the provided input value must be a :class:`~pywbem.CIMProperty` object. A corresponding keybinding in the instance path (if set) will not (!) be updated in this case:: inst = CIMInstance(...) p1 = CIMProperty('p1', ...) # must be CIMProperty inst.properties['p1'] = p1 # Set "p1" to p1 (add if needed) p1 = inst.properties['p1'] # Access "p1" del inst.properties['p1'] # Delete "p1" from the instance In addition, the CIM properties can be accessed and manipulated one by one by using the entire :class:`~pywbem.CIMInstance` object like a dictionary. In that case, the provided input value may be specified as a :term:`CIM data type` or as a :class:`~pywbem.CIMProperty` object:: inst = CIMInstance(...) p2 = Uint32(...) # may be CIM data type or CIMProperty inst['p2'] = p2 # Set "p2" to p2 (add if needed) p2 = inst['p2'] # Access "p2" del inst['p2'] # Delete "p2" from the instance """ if self._properties is None: # Lazy initialization self._properties = NocaseDict() return self._properties @properties.setter def properties(self, properties): """Setter method; for a description see the getter method.""" # We make sure that the dictionary is a NocaseDict object, and that the # property values are CIMProperty objects: # pylint: disable=attribute-defined-outside-init self._properties = None # Lazy initialization if properties: try: # This is used for iterables: iterator = properties.items() except AttributeError: # This is used for dictionaries: iterator = properties for item in iterator: if isinstance(item, CIMProperty): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for properties has invalid item " "in iterable: {0!A}", item)) self[key] = value @property def qualifiers(self): """ `NocaseDict`_: Qualifiers (qualifier values) of this CIM instance. Will not be `None`. Each dictionary item specifies one qualifier value, with: * key (:term:`unicode string`): Qualifier name. Its lexical case was preserved. * value (:class:`~pywbem.CIMQualifier`): Qualifier value. The order of qualifiers in the CIM instance is preserved. This attribute is settable; setting it will cause the current qualifiers to be replaced with the new qualifiers. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMInstance>`. The qualifier values can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. Note that :term:`DSP0200` has deprecated the presence of qualifier values on CIM instances. """ if self._qualifiers is None: # Lazy initialization self._qualifiers = NocaseDict() return self._qualifiers @qualifiers.setter def qualifiers(self, qualifiers): """Setter method; for a description see the getter method.""" # We make sure that the dictionary is a NocaseDict object, and that the # property values are CIMQualifier objects: # pylint: disable=attribute-defined-outside-init self._qualifiers = None # Lazy initialization if qualifiers: try: # This is used for iterables: iterator = qualifiers.items() except AttributeError: # This is used for dictionaries: iterator = qualifiers for item in iterator: if isinstance(item, CIMQualifier): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for qualifiers has invalid item " "in iterable: {0!A}", item)) self.qualifiers[key] = _cim_qualifier(key, value) @property def path(self): """ :class:`~pywbem.CIMInstanceName`: Instance path of this CIM instance. `None` means that the instance path is unspecified. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMInstance>`. """ return self._path @path.setter def path(self, path): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init if path is None: self._path = None else: # The provided path is deep copied because its keybindings may be # updated when setting properties (in __setitem__()). self._path = path.copy() # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). assert isinstance(path, CIMInstanceName)
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMInstance` objects. The equality is based on some of their public attributes: * `classname` * `path` * `properties` * `qualifiers` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMInstance` object. """ if self is other: return True if not isinstance(other, CIMInstance): raise TypeError( _format("other must be CIMInstance, but is: {0}", type(other))) return (_eq_name(self.classname, other.classname) and _eq_item(self.path, other.path) and _eq_dict(self.properties, other.properties) and _eq_dict(self.qualifiers, other.qualifiers))
[docs] def __hash__(self): """ Return a hash value based on the same public attributes of this class as used for equality comparison, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.classname), _hash_item(self.path), _hash_dict(self.properties), _hash_dict(self.qualifiers), ) return hash(hashes)
[docs] def __str__(self): """ Return a short string representation of this CIM instance, for human consumption. """ return _format( "CIMInstance(" "classname={s.classname!A}, " "path={s.path!A}, ...)", s=self)
[docs] def __repr__(self): """ Return a string representation of this CIM instance, that is suitable for debugging. The properties and qualifiers will be ordered by their names in the result. """ return _format( "CIMInstance(" "classname={s.classname!A}, " "path={s.path!A}, " "properties={s.properties!A}, " "qualifiers={s.qualifiers!A})", s=self)
def __contains__(self, key): return key in self.properties def __getitem__(self, key): return self.properties[key].value def __setitem__(self, key, value): prop = _cim_property_value(key, value) self.properties[key] = prop if self.path is not None and key in self.path.keybindings and \ self.path[key] != prop.value: warnings.warn( "The propagation of key property values of pywbem.CIMInstance " "to its path keybindings is deprecated and will be removed in " "a future version of pywbem", DeprecationWarning, _stacklevel_above_module(__name__)) self.path[key] = prop.value def __delitem__(self, key): del self.properties[key] def __len__(self): return len(self.properties) def __iter__(self): return six.iterkeys(self.properties)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMInstance` object that is a copy of this CIM instance. This is a middle-deep copy; any mutable types in attributes except the following are copied, so besides these exceptions, modifications of the original object will not affect the returned copy, and vice versa. The following mutable types are not copied and are therefore shared between original and copy: * The :class:`~pywbem.CIMProperty` objects in the :attr:`~pywbem.CIMInstance.properties` dictionary (but not the dictionary object itself) * The :class:`~pywbem.CIMQualifier` objects in the :attr:`~pywbem.CIMInstance.qualifiers` dictionary (but not the dictionary object itself) Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ result = CIMInstance( self.classname, properties=self.properties, # setter copies qualifiers=self.qualifiers) # setter copies # The path is set after the init method, because the init method # would overwrite the values of keybindings that have corresponding # properties. In order to be consistent with the behavior of the # original version of pywbem (0.7.0), this copy() method preserves # the provided input path. result.path = self.path # setter copies deep return result
[docs] def update(self, *args, **kwargs): """ Update the properties of this CIM instance. Existing properties will be updated, and new properties will be added. Parameters: *args (list): Properties for updating the properties of the instance, specified as positional arguments. Each positional argument must be a tuple (key, value), where key and value are described for setting the :attr:`~pywbem.CIMInstance.properties` property. **kwargs (dict): Properties for updating the properties of the instance, specified as keyword arguments. The name and value of the keyword arguments are described as key and value for setting the :attr:`~pywbem.CIMInstance.properties` property. """ for mapping in args: if hasattr(mapping, 'items'): for key, value in mapping.items(): self[key] = value else: for (key, value) in mapping: self[key] = value for key, value in kwargs.items(): self[key] = value
[docs] def update_existing(self, *args, **kwargs): """ Update the values of already existing properties of this CIM instance. From the specified new properties, only properties that already exist in the instance will be updated. New properties will not be added to the instance; they will be ignored without further notice. Parameters: *args (list): New properties, specified as positional arguments. Each positional argument must be one of: - an iterable of tuple (name, value), where each tuple specifies the name of the property to be updated and its new value. - an object with an ``items()`` method that iterates through tuple (name, value), where each tuple specifies the name of the property to be updated and its new value. Examples of such objects are :attr:`~pywbem.CIMInstanceName` (where its keybindings will be used as new properties) or :attr:`~pywbem.CIMInstance` (where its properties will be used as new properties). **kwargs (dict): New properties, specified as keyword arguments. Each keyword argument specifies one new property, where the argument name is the name of the property to be updated and the argument value is its new value. """ for mapping in args: if hasattr(mapping, 'items'): # CIMInstanceName, etc. for key, value in mapping.items(): try: prop = self.properties[key] except KeyError: continue prop.value = value else: for (key, value) in mapping: try: prop = self.properties[key] except KeyError: continue prop.value = value for key, value in kwargs.items(): try: prop = self.properties[key] except KeyError: continue prop.value = value
[docs] def has_key(self, key): """ Return a boolean indicating whether this CIM instance has a particular property. Parameters: key (:term:`string`): Name of the property (in any lexical case). Returns: :class:`py:bool`: Boolean indicating whether the instance has the property. """ return key in self.properties
[docs] def get(self, key, default=None): """ Return the value of a particular property of this CIM instance, or a default value. *New in pywbem 0.8.* Parameters: key (:term:`string`): Name of the property (in any lexical case). default (:term:`CIM data type`): Default value that is returned if a property with the specified name does not exist in the instance. Returns: :term:`CIM data type`: Value of the property, or the default value. """ prop = self.properties.get(key, None) return default if prop is None else prop.value
[docs] def keys(self): # pylint: disable=line-too-long """ Return the property names of this CIM instance. The type of the returned object is consistent with the behavior of the corresponding method of the built-in dict class: On Python 2, a list is returned; on Python 3, a `dictionary view <https://docs.python.org/3/library/stdtypes.html#dictionary-view-objects>`_ is returned. The property names have their original lexical case, and the order of properties is preserved. """ # noqa: E501 # pylint: enable=line-too-long return self.properties.keys()
[docs] def values(self): # pylint: disable=line-too-long """ Return the property values (the ``value`` attribute of the :class:`~pywbem.CIMProperty` object) of this CIM instance. The type of the returned object is consistent with the behavior of the corresponding method of the built-in dict class: On Python 2, a list is returned; on Python 3, a `dictionary view <https://docs.python.org/3/library/stdtypes.html#dictionary-view-objects>`_ is returned. The order of properties is preserved. """ # noqa: E501 # pylint: enable=line-too-long if six.PY2: return [val.value for val in self.properties.values()] return propvalue_values(self.properties)
[docs] def items(self): # pylint: disable=line-too-long """ Return the properties of this CIM instance, where each item is a tuple of property name and value (the ``value`` attribute of the :class:`~pywbem.CIMProperty` object). The type of the returned object is consistent with the behavior of the corresponding method of the built-in dict class: On Python 2, a list is returned; on Python 3, a `dictionary view <https://docs.python.org/3/library/stdtypes.html#dictionary-view-objects>`_ is returned. The property names have their original lexical case, and the order of properties is preserved. """ # noqa: E501 # pylint: enable=line-too-long if six.PY2: return [(key, val.value) for key, val in self.properties.items()] return propvalue_items(self.properties)
[docs] def iterkeys(self): """ Return an iterator through the property names of this CIM instance. The property names have their original lexical case, and the order of properties is preserved. Deprecated: This method is deprecated on Python 3 and will be removed in a future version of pywbem, consistent with the built-in dict class on Python 3. Use the :meth:`keys` method instead. """ if six.PY3: warnings.warn( "The iterkeys() method of pywbem.CIMInstance has been " "deprecated on Python 3 and will be removed in a future " "version of pywbem", DeprecationWarning, 2) return six.iterkeys(self.properties)
[docs] def itervalues(self): """ Return an iterator through the property values of this CIM instance. The property values are the ``value`` attributes of the :class:`~pywbem.CIMProperty` objects. The order of properties is preserved. Deprecated: This method is deprecated on Python 3 and will be removed in a future version of pywbem, consistent with the built-in dict class on Python 3. Use the :meth:`values` method instead. """ if six.PY3: warnings.warn( "The itervalues() method of pywbem.CIMInstance has been " "deprecated on Python 3 and will be removed in a future " "version of pywbem", DeprecationWarning, 2) for val in six.itervalues(self.properties): yield val.value
[docs] def iteritems(self): """ Return an iterator through the properties of this CIM instance, where each item is a tuple of property name and value. The property values are the ``value`` attributes of the :class:`~pywbem.CIMProperty` objects. The property names have their original lexical case, and the order of properties is preserved. Deprecated: This method is deprecated on Python 3 and will be removed in a future version of pywbem, consistent with the built-in dict class on Python 3. Use the :meth:`items` method instead. """ if six.PY3: warnings.warn( "The iteritems() method of pywbem.CIMInstance has been " "deprecated on Python 3 and will be removed in a future " "version of pywbem", DeprecationWarning, 2) for key, val in six.iteritems(self.properties): yield (key, val.value)
[docs] def tocimxml(self, ignore_path=False): """ Return the CIM-XML representation of this CIM instance, as an object of an appropriate subclass of :term:`Element`. If the instance has no instance path specified or if `ignore_path` is `True`, the returned CIM-XML representation is an `INSTANCE` element consistent with :term:`DSP0201`. This is the required element for representing embedded instances. Otherwise, if the instance path of the instance has no namespace specified, the returned CIM-XML representation is an `VALUE.NAMEDINSTANCE` element consistent with :term:`DSP0201`. Otherwise, if the instance path of the instance has no host specified, the returned CIM-XML representation is a `VALUE.OBJECTWITHLOCALPATH` element consistent with :term:`DSP0201`. Otherwise, the returned CIM-XML representation is a `VALUE.INSTANCEWITHPATH` element consistent with :term:`DSP0201`. The order of properties and qualifiers in the returned CIM-XML representation is preserved from the :class:`~pywbem.CIMInstance` object. Parameters: ignore_path (:class:`py:bool`): Ignore the path of the instance, even if a path is specified. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ # The items in the self.properties dictionary are required to be # CIMProperty objects and that is ensured when initializing a # CIMInstance object and when setting the entire self.properties # attribute. However, even though the items in the dictionary are # required to be CIMProperty objects, the user technically can set # them to anything. # Before pywbem 0.12, the dictionary items were converted to # CIMProperty objects. This was only done for properties of # CIMinstance, but not for any other CIM object attribute. # In pywbem 0.12, this conversion was removed because it worked only # for bool and string types anyway. Because that conversion had been # implemented, we still check that the items are CIMProperty objects. for key, value in self.properties.items(): try: assert isinstance(value, CIMProperty) except AssertionError: raise TypeError( _format("Property {0!A} has invalid type: {1} (must be " "CIMProperty)", key, builtin_type(value))) instance_xml = _cim_xml.INSTANCE( self.classname, properties=[p.tocimxml() for p in self.properties.values()], qualifiers=[q.tocimxml() for q in self.qualifiers.values()]) if self.path is None or ignore_path: return instance_xml if self.path.namespace is None: return _cim_xml.VALUE_NAMEDINSTANCE( self.path.tocimxml(), instance_xml) if self.path.host is None: return _cim_xml.VALUE_OBJECTWITHLOCALPATH( self.path.tocimxml(), instance_xml) return _cim_xml.VALUE_INSTANCEWITHPATH( self.path.tocimxml(), instance_xml)
[docs] def tocimxmlstr(self, indent=None, ignore_path=False): """ Return the CIM-XML representation of this CIM instance, as a :term:`unicode string`. *New in pywbem 0.9.* For the returned CIM-XML representation, see :meth:`~pywbem.CIMInstance.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. ignore_path (:class:`py:bool`): Ignore the path of the instance, even if a path is specified. Returns: The CIM-XML representation of the object, as a :term:`unicode string`. """ xml_elem = self.tocimxml(ignore_path) return tocimxmlstr(xml_elem, indent)
[docs] def tomof(self, maxline=MAX_MOF_LINE): """ Return a MOF string with the specification of this CIM instance. The returned MOF string conforms to the ``instanceDeclaration`` ABNF rule defined in :term:`DSP0004`, with the following limitations: * Pywbem does not support instance aliases, so the returned MOF string does not define an alias name for the instance. * Even though pywbem supports qualifiers on :class:`~pywbem.CIMInstance` objects, and on :class:`~pywbem.CIMProperty` objects that are used as property values within an instance, the returned MOF string does not contain any qualifier values on the instance or on its property values. The order of properties and qualifiers is preserved. Parameters: maxline (:term:`integer`): Maximum line length. Returns: :term:`unicode string`: MOF string. """ mof = [] mof.append(u'instance of ') mof.append(self.classname) mof.append(u' {\n') for p in self.properties.values(): mof.append(p.tomof(True, MOF_INDENT, maxline)) mof.append(u'};\n') return u''.join(mof)
[docs] @staticmethod def from_class(klass, namespace=None, property_values=None, include_missing_properties=True, include_path=True, include_class_origin=False): """ Return a new :class:`~pywbem.CIMInstance` object from specified key property values and from the key property definitions in a class. The properties in the returned instance do not have any qualifiers. Parameters: klass (:class:`~pywbem.CIMClass`): CIM class from which the instance will be constructed. This class must include qualifiers and should include properties from any superclasses in the model insure it includes all properties that are to be built into the instance, in particular any key properties if the `include_path` parameter is `True`. namespace (:term:`string`): Namespace to be included in the path component of the returned CIMInstance if `include_path` parameter is `True`. property_values (:class:`py:dict` or `NocaseDict`_): Dictionary containing name/value pairs where the names are the names of properties in the class and the properties are the property values to be set into the instance properties. The values must match the type defined for the property in the class. If a property is in the property_values dictionary but not in the class a ValueError exception is raised. Not all properties in the class need to be defined in `property_values`. include_missing_properties (:class:`py:bool`): Determines if properties not in the `property_values` parameter are included in the instance. If `True` all properties from the class are included in the new instance including those not defined in `property_values` parameter with with the default value defined in the class if one is defined, or otherwise None". If `False` only properties in the `property_values` parameter are included in the new instance. include_class_origin (:class:`py:bool`): Determines if class origin information from the class is included in the returned instance. If `None` or `False`, class origin information is not included. If `True`, class origin information is included. include_path (:class:`py:bool`:): Controls creation of a path element in the new instance. If `True` a :class:`~pywbem.CIMInstanceName` path is created from the key properties in the new instance and inserted into the new instance based on properties in the new instance. All properties with key qualifier in the class defined by the `klass` parameter must exist in the new instance and have non-null values or the path creation fails with a ValueError exception. If `None` or `False` no path element is created and the new instance is returned with the path element `None`. Returns: :class:`~pywbem.CIMInstance`: A CIM instance created from `klass` and `property_values` parameters with the defined properties and optionally the path component set. No qualifiers are included in the returned instance and the existence of the class origin attribute depends on the `include_class_origin` parameter. All other attributes of each property are the same as the corresponding class property. Raises: ValueError: Conflicts between the class properties and `property_values` parameter or the instance does not include all key properties defined in the class. TypeError: Mismatch between types of the property values in `property_values` parameter and the property type in the corresponding class property """ class_name = klass.classname inst = CIMInstance(class_name) if property_values is None: property_values = NocaseDict() # if not a NocaseDict, map the input to NocaseDict if not isinstance(property_values, NocaseDict): if isinstance(property_values, dict): property_values = NocaseDict(property_values.items()) else: raise TypeError( _format("property_values param must be a dictionary. " "Type is {0}", type(property_values))) for pname in property_values: if pname not in klass.properties: raise ValueError( _format("Property name {0!A} in property_values param but " "not in class {1!A}", pname, class_name)) for cp in klass.properties.values(): co = cp.class_origin if include_class_origin else None if cp.name in property_values: ip = CIMProperty(cp.name, property_values[cp.name], type=cp.type, class_origin=co, array_size=cp.array_size, propagated=cp.propagated, is_array=cp.is_array, reference_class=cp.reference_class, qualifiers=OrderedDict(), embedded_object=cp.embedded_object) inst[ip.name] = ip else: if include_missing_properties: cpc = cp.copy() cpc.class_origin = co cpc.qualifiers = OrderedDict() inst[cp.name] = cpc if include_path: # Uses strict so all key properties in klass must exist in # the instance or a ValueError is generated by from_instance inst.path = CIMInstanceName.from_instance(klass, inst, namespace, strict=True) return inst
[docs]class CIMClassName(_CIMComparisonMixin, SlottedPickleMixin): """ A CIM class path (aka *CIM class name*). A CIM class path references a CIM class in a CIM namespace in a WBEM server. Namespace and WBEM server may be unspecified. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_classname', '_host', '_namespace'] def __init__(self, classname, host=None, namespace=None): """ Parameters: classname (:term:`string`): Class name of the referenced class. Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. host (:term:`string`): Host and optionally port of the WBEM server containing the CIM namespace of the referenced class. The format of the string must be: ``host[:port]`` The host can be specified in any of the usual formats: * a short or fully qualified DNS hostname * a literal (= dotted) IPv4 address * a literal IPv6 address, formatted as defined in :term:`RFC3986` with the extensions for zone identifiers as defined in :term:`RFC6874`, supporting ``-`` (minus) for the delimiter before the zone ID string, as an additional choice to ``%25``. `None` means that the WBEM server is unspecified, and the :attr:`~pywbem.CIMClassName.host` attribute will also be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. namespace (:term:`string`): Name of the CIM namespace containing the referenced class. `None` means that the namespace is unspecified, and the :attr:`~pywbem.CIMClassName.namespace` attribute will also be `None`. Leading and trailing slash characters will be stripped. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. Raises: ValueError: classname is `None`. """ # We use the respective setter methods: self.classname = classname self.namespace = namespace self.host = host @property def classname(self): """ :term:`unicode string`: Class name of this CIM class path, identifying the referenced class. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMClassName>`. """ return self._classname @classname.setter def classname(self, classname): """Setter method; for a description see the getter method.""" # DSP0004 defines a certain format of CIM class names, but we don't # check that in pywbem because we don't parse the class name anywhere. # Also, some WBEM servers implement special classes that deviate from # that format. # pylint: disable=attribute-defined-outside-init self._classname = _ensure_unicode(classname) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if classname is None: raise ValueError("Class name in class path must not be None") @property def namespace(self): """ :term:`unicode string`: Namespace name of this CIM class path, identifying the namespace of the referenced class. `None` means that the namespace is unspecified. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMClassName>`. """ return self._namespace @namespace.setter def namespace(self, namespace): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._namespace = _ensure_unicode(namespace) if self._namespace is not None: # In Python 3, a byte string cannot be stripped by a unicode char # Therefore, the stripping needs to be done after the unicode # conversion. self._namespace = self._namespace.strip('/') @property def host(self): """ :term:`unicode string`: Host and optionally port of this CIM class path, identifying the WBEM server of the referenced class. For details about the string format, see the same-named init parameter of :class:`this class <pywbem.CIMClassName>`. `None` means that the host and port are unspecified. This attribute is settable. For details, see the description of the same-named init parameter. """ return self._host @host.setter def host(self, host): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._host = _ensure_unicode(host)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMClassName` object that is a copy of this CIM class path. Objects of this class have no mutable types in any attributes, so modifications of the original object will not affect the returned copy, and vice versa. Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ return CIMClassName( self.classname, host=self.host, namespace=self.namespace)
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMClassName` objects. The equality is based on their public attributes: * `host` * `namespace` * `classname` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMClassName` object. """ if self is other: return True if not isinstance(other, CIMClassName): raise TypeError( _format("other must be CIMClassName, but is: {0}", type(other))) return (_eq_name(self.host, other.host) and _eq_name(self.namespace, other.namespace) and _eq_name(self.classname, other.classname))
[docs] def __hash__(self): """ Return a hash value based on the public attributes of this class, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.host), _hash_name(self.namespace), _hash_name(self.classname), ) return hash(hashes)
[docs] def __str__(self): """ Return a WBEM URI string of this CIM class path. The returned WBEM URI string is in the historical format returned by :meth:`~pywbem.CIMClassName.to_wbem_uri`. For new code, it is recommended that the standard format is used; it is returned by :meth:`~pywbem.CIMClassName.to_wbem_uri` as the default format. If you want to access the class name, use the :attr:`~pywbem.CIMClassName.classname` attribute, instead of relying on the coincidence that the historical format of a WBEM URI without host and namespace happens to be the class name. Examples (for the historical format): * With host and namespace:: //acme.com/cimv2/test:CIM_RegisteredProfile * Without host but with namespace:: cimv2/test:CIM_RegisteredProfile * Without host and without namespace:: CIM_RegisteredProfile """ return self.to_wbem_uri(format='historical')
[docs] def __repr__(self): """ Return a string representation of this CIM class path, that is suitable for debugging. """ return _format( "CIMClassName(" "classname={s.classname!A}, " "namespace={s.namespace!A}, " "host={s.host!A})", s=self)
[docs] def tocimxml(self, ignore_host=False, ignore_namespace=False): """ Return the CIM-XML representation of this CIM class path, as an object of an appropriate subclass of :term:`Element`. If the class path has no namespace specified or if `ignore_namespace` is `True`, the returned CIM-XML representation is a `CLASSNAME` element consistent with :term:`DSP0201`. Otherwise, if the class path has no host specified or if `ignore_host` is `True`, the returned CIM-XML representation is a `LOCALCLASSPATH` element consistent with :term:`DSP0201`. Otherwise, the returned CIM-XML representation is a `CLASSPATH` element consistent with :term:`DSP0201`. Parameters: ignore_host (:class:`py:bool`): Ignore the host of the class path, even if a host is specified. ignore_namespace (:class:`py:bool`): Ignore the namespace and host of the class path, even if a namespace and/or host is specified. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ classname_xml = _cim_xml.CLASSNAME(self.classname) if self.namespace is None or ignore_namespace: return classname_xml localnsp_xml = _cim_xml.LOCALNAMESPACEPATH( [_cim_xml.NAMESPACE(ns) for ns in self.namespace.split('/')]) if self.host is None or ignore_host: return _cim_xml.LOCALCLASSPATH(localnsp_xml, classname_xml) return _cim_xml.CLASSPATH( _cim_xml.NAMESPACEPATH(_cim_xml.HOST(self.host), localnsp_xml), classname_xml)
[docs] def tocimxmlstr(self, indent=None, ignore_host=False, ignore_namespace=False): """ Return the CIM-XML representation of this CIM class path, as a :term:`unicode string`. *New in pywbem 0.9.* For the returned CIM-XML representation, see :meth:`~pywbem.CIMClassName.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. ignore_host (:class:`py:bool`): Ignore the host of the class path, even if a host is specified. ignore_namespace (:class:`py:bool`): Ignore the namespace and host of the class path, even if a namespace and/or host is specified. Returns: The CIM-XML representation of the object, as a :term:`unicode string`. """ xml_elem = self.tocimxml(ignore_host, ignore_namespace) return tocimxmlstr(xml_elem, indent)
[docs] @staticmethod def from_wbem_uri(wbem_uri): """ Return a new :class:`~pywbem.CIMClassName` object from the specified WBEM URI string. *New in pywbem 0.12.* The WBEM URI string must be a CIM class path in untyped WBEM URI format, as defined in :term:`DSP0207`, with these extensions: * :term:`DSP0207` restricts the namespace types (URI schemes) to be one of ``http``, ``https``, ``cimxml-wbem``, or ``cimxml-wbems``. Pywbem tolerates any namespace type, but issues a :exc:`py:UserWarning` if it is not one of the namespace types defined in :term:`DSP0207`. * :term:`DSP0207` requires a slash before the namespace name. For local WBEM URIs (no namespace type, no authority), that slash is the first character of the WBEM URI. For historical reasons, pywbem tolerates a missing leading slash for local WBEM URIs. Note that pywbem requires the slash (consistent with :term:`DSP0207`) when the WBEM URI is not local. * :term:`DSP0207` requires a colon before the class name. For historical reasons, pywbem tolerates a missing colon before the class name, if it would have been the first character of the string. CIM class paths in the typed WBEM URI format defined in :term:`DSP0207` are not supported. Examples:: https://jdd:test@acme.com:5989/cimv2/test:CIM_RegisteredProfile http://acme.com/root/cimv2:CIM_ComputerSystem http:/root/cimv2:CIM_ComputerSystem /root/cimv2:CIM_ComputerSystem root/cimv2:CIM_ComputerSystem /:CIM_ComputerSystem :CIM_ComputerSystem CIM_ComputerSystem Parameters: wbem_uri (:term:`string`): WBEM URI for a class path. Returns: :class:`~pywbem.CIMClassName`: The class path created from the specified WBEM URI string. Raises: ValueError: Invalid WBEM URI format for a class path. This includes typed WBEM URIs. """ m = WBEM_URI_CLASSPATH_REGEXP.match(wbem_uri) if m is None: raise ValueError( _format("Invalid format for a class path in WBEM URI: {0!A}", wbem_uri)) ns_type = m.group(1) or None if ns_type and ns_type.lower() not in WBEM_URI_NAMESPACE_TYPES: warnings.warn( _format("Tolerating unknown namespace type in WBEM URI: {0!A}", wbem_uri), UserWarning) host = m.group(2) or None namespace = m.group(3) or None classname = m.group(4) or None assert classname is not None # should be ensured by regexp obj = CIMClassName( classname=classname, host=host, namespace=namespace) return obj
[docs] def to_wbem_uri(self, format='standard'): # pylint: disable=redefined-builtin """ Return the (untyped) WBEM URI string of this CIM class path. The returned WBEM URI contains its components as follows: * it does not contain a namespace type (URI scheme). * it contains an authority (host) component according to the :attr:`~pywbem.CIMClassName.host` attribute, if that is not `None`. Otherwise, it does not contain the authority component. * it contains a namespace component according to the :attr:`~pywbem.CIMClassName.namespace` attribute, if that is not `None`. Otherwise, it does not contain the namespace component. * it contains a class name component according to the :attr:`~pywbem.CIMClassName.classname` attribute. Note that when you do not want some of these components to show up in the resulting WBEM URI string, you can set them to `None` before calling this method. Except when using the format "canonical", this method should not be used to compare class paths for equality: :term:`DSP0004` defines several components of a class path to be compared case insensitively. All WBEM URI formats returned by this method except for the format "canonical" return a WBEM URI string that preserves the lexical case of any components. Therefore, two class paths that are considered equal according to :term:`DSP0004` may not have equal WBEM URI strings as as returned by this method. Instead, equality of class paths represented by :class:`~pywbem.CIMClassName` objects should be determined by using the ``==`` operator, which performs the comparison conformant to :term:`DSP0004`. If you have WBEM URI strings without the corresponding :class:`~pywbem.CIMClassName` object, such an object can be created by using the static method :meth:`~pywbem.CIMClassName.from_wbem_uri`. Parameters: format (:term:`string`): Format for the generated WBEM URI string, using one of the following values: * ``"standard"`` - Standard format that is conformant to untyped WBEM URIs for class paths defined in :term:`DSP0207`. * ``"canonical"`` - Like ``"standard"``, except that the following items have been converted to lower case: host, namespace, and classname. This format guarantees that two class paths that are considered equal according to :term:`DSP0004` result in equal WBEM URI strings. Therefore, the returned WBEM URI is suitable to be used as a key in dictionaries of CIM classes. * ``"cimobject"`` - Format for the `CIMObject` header field in CIM-XML messages for representing class paths (used internally, see :term:`DSP0200`). * ``"historical"`` - Historical format for WBEM URIs (used by :meth:`~pywbem.CIMClassName.__str__`; should not be used by new code). The historical format has the following differences to the standard format: - If the host component is not present, the slash after the host is also omitted. In the standard format, that slash is always present. - If the namespace component is not present, the colon after the namespace is also omitted. In the standard format, that colon is always present. Examples: * With host and namespace, standard format:: //ACME.com/cimv2/Test:CIM_RegisteredProfile * With host and namespace, canonical format:: //acme.com/cimv2/test:cim_registeredprofile * Without host but with namespace, standard format:: /cimv2/Test:CIM_RegisteredProfile * Without host but with namespace, canonical format:: /cimv2/test:cim_registeredprofile * Without host and without namespace, standard format:: /:CIM_RegisteredProfile Returns: :term:`unicode string`: Untyped WBEM URI of the CIM class path, in the specified format. Raises: ValueError: Invalid format """ def case(str_): """Return the string in the correct lexical case for the format.""" if format == 'canonical': str_ = str_.lower() return str_ if format not in ('standard', 'canonical', 'cimobject', 'historical'): raise ValueError( _format("Invalid format argument: {0}", format)) ret = [] if self.host is not None and format != 'cimobject': # The CIMObject format assumes there is no host component ret.append('//') ret.append(case(self.host)) if self.host is not None or format not in ('cimobject', 'historical'): ret.append('/') if self.namespace is not None: ret.append(case(self.namespace)) if self.namespace is not None or format != 'historical': ret.append(':') ret.append(case(self.classname)) return _ensure_unicode(''.join(ret))
[docs]class CIMClass(_CIMComparisonMixin, SlottedPickleMixin): """ A representation of a CIM class in a CIM namespace in a WBEM server, optionally including its class path. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_classname', '_properties', '_methods', '_superclass', '_qualifiers', '_path'] # pylint: disable=too-many-arguments def __init__(self, classname, properties=None, methods=None, superclass=None, qualifiers=None, path=None): """ Parameters: classname (:term:`string`): Class name of the class. Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. properties (:term:`properties input object`): The property declarations for the class. methods (:term:`methods input object`): The method declarations for the class. superclass (:term:`string`): Name of the superclass for the class. `None` means that the class is a top-level class, and the :attr:`~pywbem.CIMClass.superclass` attribute will also be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. qualifiers (:term:`qualifiers input object`): The qualifiers for the class. path (:class:`~pywbem.CIMClassName`): Class path for the class. *New in pywbem 0.11.* The provided object will be copied before being stored in the :class:`~pywbem.CIMClass` object. `None` means that the instance path is unspecified, and the :attr:`~pywbem.CIMClass.path` attribute will also be `None`. This parameter has been added in pywbem 0.11 as a convenience for the user in order so that :class:`~pywbem.CIMClass` objects can be self-contained w.r.t. their class path. Raises: ValueError: classname is `None`, a property, method or qualifier name is `None`, or a property, method or qualifier name does not match its dictionary key. TypeError: a numeric Python type was used for a qualifier value. """ # We use the respective setter methods: self.classname = classname self.superclass = superclass self.path = path self.properties = properties self.methods = methods self.qualifiers = qualifiers @property def classname(self): """ :term:`unicode string`: Class name of this CIM class. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMClass>`. """ return self._classname @classname.setter def classname(self, classname): """Setter method; for a description see the getter method.""" # DSP0004 defines a certain format of CIM class names, but we don't # check that in pywbem because we don't parse the class name anywhere. # Also, some WBEM servers implement special classes that deviate from # that format. # pylint: disable=attribute-defined-outside-init self._classname = _ensure_unicode(classname) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if classname is None: raise ValueError("Class name in class must not be None") @property def superclass(self): """ :term:`unicode string`: Class name of the superclass of this CIM class. `None` means that the class is a top-level class. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMClass>`. """ return self._superclass @superclass.setter def superclass(self, superclass): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._superclass = _ensure_unicode(superclass) @property def properties(self): """ `NocaseDict`_: Properties (declarations) of this CIM class. Will not be `None`. Each dictionary item specifies one property declaration, with: * key (:term:`unicode string`): Property name. Its lexical case was preserved. * value (:class:`~pywbem.CIMProperty`): Property declaration. The order of properties in the CIM class is preserved. This attribute is settable; setting it will cause the current CIM properties to be replaced with the new properties. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMClass>`. The CIM properties can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. The provided input value must be a :class:`~pywbem.CIMProperty` object:: cls = CIMClass(...) p1 = CIMProperty('p1', ...) # must be a CIMProperty cls.properties['p1'] = p1 # Set "p1" to p1 (add if needed) p1 = cls.properties['p1'] # Access "p1" del cls.properties['p1'] # Delete "p1" from the class """ if self._properties is None: # Lazy initialization self._properties = NocaseDict() return self._properties @properties.setter def properties(self, properties): """Setter method; for a description see the getter method.""" # We make sure that the dictionary is a NocaseDict object, and that the # property values are CIMProperty objects: # pylint: disable=attribute-defined-outside-init self._properties = None # Lazy initialization if properties: try: # This is used for iterables: iterator = properties.items() except AttributeError: # This is used for dictionaries: iterator = properties for item in iterator: if isinstance(item, CIMProperty): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for properties has invalid item " "in iterable: {0!A}", item)) self.properties[key] = _cim_property_decl(key, value) @property def methods(self): """ `NocaseDict`_: Methods (declarations) of this CIM class. Will not be `None`. Each dictionary item specifies one method, with: * key (:term:`unicode string`): Method name. Its lexical case was preserved. * value (:class:`~pywbem.CIMMethod`): Method declaration. The order of methods in the CIM class is preserved. This attribute is settable; setting it will cause the current CIM methods to be replaced with the new methods. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMClass>`. The CIM methods can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. The provided input value must be a :class:`~pywbem.CIMMethod` object:: cls = CIMClass(...) m1 = CIMMethod('m1', ...) # must be a CIMMethod cls.methods['m1'] = m1 # Set "m1" to m1 (add if needed) m1 = cls.methods['m1'] # Access "m1" del cls.methods['m1'] # Delete "m1" from the class """ if self._methods is None: # Lazy initialization self._methods = NocaseDict() return self._methods @methods.setter def methods(self, methods): """Setter method; for a description see the getter method.""" # We make sure that the dictionary is a NocaseDict object, and that the # property values are CIMMethod objects: # pylint: disable=attribute-defined-outside-init self._methods = None # Lazy initialization if methods: try: # This is used for iterables: iterator = methods.items() except AttributeError: # This is used for dictionaries: iterator = methods for item in iterator: if isinstance(item, CIMMethod): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for methods has invalid item in " "iterable: {0!A}", item)) self.methods[key] = _cim_method(key, value) @property def qualifiers(self): """ `NocaseDict`_: Qualifiers (qualifier values) of this CIM class. Will not be `None`. Each dictionary item specifies one qualifier value, with: * key (:term:`unicode string`): Qualifier name. Its lexical case was preserved. * value (:class:`~pywbem.CIMQualifier`): Qualifier value. The order of qualifiers in the CIM class is preserved. This attribute is settable; setting it will cause the current qualifiers to be replaced with the new qualifiers. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMClass>`. The qualifier values can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. The provided input value may be specified as a :term:`CIM data type` or as a :class:`~pywbem.CIMQualifier` object:: cls = CIMClass(...) q1 = Uint32(...) # may be CIM data type or CIMQualifier cls.qualifiers['q1'] = q1 # Set "q1" to q1 (add if needed) q1 = cls.qualifiers['q1'] # Access "q1" del cls.qualifiers['q1'] # Delete "q1" from the class """ if self._qualifiers is None: # Lazy initialization self._qualifiers = NocaseDict() return self._qualifiers @qualifiers.setter def qualifiers(self, qualifiers): """Setter method; for a description see the getter method.""" # We make sure that the dictionary is a NocaseDict object, and that the # property values are CIMQualifier objects: # pylint: disable=attribute-defined-outside-init self._qualifiers = None # Lazy initialization if qualifiers: try: # This is used for iterables: iterator = qualifiers.items() except AttributeError: # This is used for dictionaries: iterator = qualifiers for item in iterator: if isinstance(item, CIMQualifier): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for qualifiers has invalid item " "in iterable: {0!A}", item)) self.qualifiers[key] = _cim_qualifier(key, value) @property def path(self): """ :class:`~pywbem.CIMClassName`: Class path of this CIM class. *New in pywbem 0.11.* `None` means that the class path is unspecified. This attribute has been added in pywbem 0.11 as a convenience for the user in order so that :class:`~pywbem.CIMClass` objects can be self-contained w.r.t. their class path. This attribute will be set in in any :class:`~pywbem.CIMClass` objects returned by :class:`~pywbem.WBEMConnection` methods, based on information in the response from the WBEM server. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMClass>`. """ return self._path @path.setter def path(self, path): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._path = copy_.copy(path) # The provided path is shallow copied; it does not have any attributes # with mutable types. # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). assert isinstance(path, CIMClassName) or path is None
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMClass` objects. The equality is based on their public attributes: * `classname` * `superclass` * `qualifiers` * `properties` * `methods` * `path` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMClass` object. """ if self is other: return True if not isinstance(other, CIMClass): raise TypeError( _format("other must be CIMClass, but is: {0}", type(other))) return (_eq_name(self.classname, other.classname) and _eq_name(self.superclass, other.superclass) and _eq_dict(self.qualifiers, other.qualifiers) and _eq_dict(self.properties, other.properties) and _eq_dict(self.methods, other.methods) and _eq_item(self.path, other.path))
[docs] def __hash__(self): """ Return a hash value based on the public attributes of this class, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.classname), _hash_name(self.superclass), _hash_dict(self.qualifiers), _hash_dict(self.properties), _hash_dict(self.methods), _hash_item(self.path), ) return hash(hashes)
[docs] def __str__(self): """ Return a short string representation of this CIM class, for human consumption. """ return _format( "CIMClass(" "classname={s.classname!A}, ...)", s=self)
[docs] def __repr__(self): """ Return a string representation of this CIM class, that is suitable for debugging. The order of properties, method and qualifiers will be preserved in the result. """ return _format( "CIMClass(" "classname={s.classname!A}, " "superclass={s.superclass!A}, " "properties={s.properties!A}, " "methods={s.methods!A}, " "qualifiers={s.qualifiers!A}, " "path={s.path!A})", s=self)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMClass` object that is a copy of this CIM class. This is a middle-deep copy; any mutable types in attributes except the following are copied, so besides these exceptions, modifications of the original object will not affect the returned copy, and vice versa. The following mutable types are not copied and are therefore shared between original and copy: * The :class:`~pywbem.CIMProperty` objects in the :attr:`~pywbem.CIMClass.properties` dictionary (but not the dictionary object itself) * The :class:`~pywbem.CIMMethod` objects in the :attr:`~pywbem.CIMClass.methods` dictionary (but not the dictionary object itself) * The :class:`~pywbem.CIMQualifier` objects in the :attr:`~pywbem.CIMClass.qualifiers` dictionary (but not the dictionary object itself) Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ return CIMClass( self.classname, properties=self.properties, # setter copies methods=self.methods, # setter copies superclass=self.superclass, qualifiers=self.qualifiers, # setter copies path=self.path) # setter copies
[docs] def tocimxml(self): """ Return the CIM-XML representation of this CIM class, as an object of an appropriate subclass of :term:`Element`. The returned CIM-XML representation is a `CLASS` element consistent with :term:`DSP0201`. This is the required element for representing embedded classes. If the class has a class path specified, it will be ignored. The order of properties, methods, parameters, and qualifiers in the returned CIM-XML representation is preserved from the :class:`~pywbem.CIMClass` object. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ return _cim_xml.CLASS( self.classname, properties=[p.tocimxml() for p in self.properties.values()], methods=[m.tocimxml() for m in self.methods.values()], qualifiers=[q.tocimxml() for q in self.qualifiers.values()], superclass=self.superclass)
[docs] def tocimxmlstr(self, indent=None): """ Return the CIM-XML representation of this CIM class, as a :term:`unicode string`. *New in pywbem 0.9.* For the returned CIM-XML representation, see :meth:`~pywbem.CIMClass.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. Returns: The CIM-XML representation of the object, as a :term:`unicode string`. """ xml_elem = self.tocimxml() return tocimxmlstr(xml_elem, indent)
[docs] def tomof(self, maxline=MAX_MOF_LINE): """ Return a MOF string with the declaration of this CIM class. The returned MOF string conforms to the ``classDeclaration`` ABNF rule defined in :term:`DSP0004`. The order of properties, methods, parameters, and qualifiers is preserved. The :attr:`~pywbem.CIMClass.path` attribute of this object will not be included in the returned MOF string. Consistent with that, class path information is not included in the returned MOF string. Returns: :term:`unicode string`: MOF string. """ mof = [] mof.append(_qualifiers_tomof(self.qualifiers, MOF_INDENT, maxline)) mof.append(u'class ') mof.append(self.classname) mof.append(u' ') if self.superclass is not None: mof.append(u': ') mof.append(self.superclass) mof.append(u' ') mof.append(u'{\n') for p in self.properties.values(): mof.append(u'\n') mof.append(p.tomof(False, MOF_INDENT, maxline)) for m in self.methods.values(): mof.append(u'\n') mof.append(m.tomof(MOF_INDENT, maxline)) mof.append(u'\n};\n') return u''.join(mof)
# pylint: disable=too-many-statements,too-many-instance-attributes
[docs]class CIMProperty(_CIMComparisonMixin, SlottedPickleMixin): """ A CIM property (value or declaration). This object can be used in a :class:`~pywbem.CIMInstance` object for representing a property value, or in a :class:`~pywbem.CIMClass` object for representing a property declaration. For property values in CIM instances: * The `value` attribute is the actual value of the property. * Qualifiers are not allowed. For property declarations in CIM classes: * The `value` attribute is the default value of the property declaration. * Qualifiers are allowed. Scalar (=non-array) properties may have a value of NULL (= `None`), any primitive CIM data type, reference type, and string type with embedded instance or embedded object. Array properties may be Null or may have elements with a value of NULL, any primitive CIM data type, and string type with embedded instance or embedded object. Reference types are not allowed in property arrays in CIM, as per :term:`DSP0004`. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_name', '_value', '_type', '_class_origin', '_array_size', '_propagated', '_is_array', '_reference_class', '_qualifiers', '_embedded_object'] # pylint: disable=too-many-statements def __init__(self, name, value, type=None, class_origin=None, array_size=None, propagated=None, is_array=None, reference_class=None, qualifiers=None, embedded_object=None): # pylint: disable=redefined-builtin,too-many-arguments,too-many-branches # pylint: disable=too-many-statements,too-many-instance-attributes """ The init method infers optional parameters that are not specified (for example, it infers `type` from the Python type of `value` and other information). If the specified parameters are inconsistent, an exception is raised. If an optional parameter is needed for some reason, an exception is raised. Parameters: name (:term:`string`): Name of the property. Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. value (:term:`CIM data type` or other suitable types): Value of the property. The property value is interpreted as an actual property value when the CIM property is used in a CIM instance, and as default value when the CIM property is used in a CIM class. `None` means that the property is Null, and the same-named attribute in the :class:`~pywbem.CIMProperty` object will also be `None`. The specified value will be converted to a :term:`CIM data type` using the rules documented in the description of :func:`~pywbem.cimvalue`, taking into account the `type` parameter. type (:term:`string`): Name of the CIM data type of the property (e.g. ``"uint8"``). `None` will cause the type to be inferred from the `value` parameter, raising :exc:`py:ValueError` if it cannot be inferred (for example when `value` is `None` or a Python integer). :exc:`py:ValueError` is raised if the type is not a valid CIM data type (see :ref:`CIM data types`). class_origin (:term:`string`): The CIM class origin of the property (the name of the most derived class that defines or overrides the property in the class hierarchy of the class owning the property). `None` means that class origin information is not available, and :attr:`~pywbem.CIMProperty.class_origin` attribute will also be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. array_size (:term:`integer`): The size of the array property, for fixed-size arrays. `None` means that the array property has variable size, and :attr:`~pywbem.CIMProperty.array_size` attribute will also be `None`. propagated (:class:`py:bool`): If not `None`, specifies whether the property declaration has been propagated from a superclass, or the property value has been propagated from the creation class. `None` means that propagation information is not available, and :attr:`~pywbem.CIMProperty.propagated` attribute will also be `None`. is_array (:class:`py:bool`): A boolean indicating whether the property is an array (`True`) or a scalar (`False`). If `None`, the :attr:`~pywbem.CIMProperty.is_array` attribute will be inferred from the `value` parameter. If the `value` parameter is `None`, a scalar is assumed. reference_class (:term:`string`): For reference properties, the name of the class referenced by the property, or `None` indicating that the referenced class is unspecified. For non-reference properties, must be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. Note: Prior to pywbem 0.11, the corresponding attribute was inferred from the creation class name of a referenced instance. This was incorrect and has been fixed in pywbem 0.11. qualifiers (:term:`qualifiers input object`): The qualifiers for the property declaration. Has no meaning for property values. embedded_object (:term:`string`): A string value indicating the kind of embedded object represented by the property value. Has no meaning for property declarations. For details about the possible values, see the corresponding attribute. `None` means that the value is unspecified, causing the same-named attribute in the :class:`~pywbem.CIMProperty` object to be inferred. An exception is raised if it cannot be inferred. `False` means the property value is not an embedded object, and is stored as `None`. Examples: :: # a string property: CIMProperty("MyString", "abc") # a uint8 property: CIMProperty("MyNum", 42, "uint8") # a uint8 property: CIMProperty("MyNum", Uint8(42)) # a uint8 array property: CIMProperty("MyNumArray", [1, 2, 3], "uint8") # a reference property: CIMProperty("MyRef", CIMInstanceName("Foo")) # an embedded object property containing a class: CIMProperty("MyEmbObj", CIMClass("Foo")) # an embedded object property containing an instance: CIMProperty("MyEmbObj", CIMInstance("Foo"), embedded_object="object") # an embedded instance property: CIMProperty("MyEmbInst", CIMInstance("Foo")) # a string property that is Null: CIMProperty("MyString", None, "string") # a uint8 property that is Null: CIMProperty("MyNum", None, "uint8") # a reference property that is Null: CIMProperty("MyRef", None, "reference", reference_class="MyClass") # an embedded object property that is Null: CIMProperty("MyEmbObj", None, "string", embedded_object="object") # an embedded instance property that is Null: CIMProperty("MyEmbInst", None, "string", embedded_object="instance") """ # We use the respective setter methods: self.name = name if type is None: type = _infer_type(value, "property", name) if is_array is None: is_array = _infer_is_array(value) else: # For performance reasons, we check only if not inferred. # This leaves the incorrect combination of is_array=False and # array_size=5 undetected, which seems acceptable because # array_size is ignored anyway when is_array=False. _check_array_parms(is_array, array_size, value, "property", name) if embedded_object is None: embedded_object = _infer_embedded_object(value) if embedded_object: _check_embedded_object(embedded_object, type, value, "property", name) if reference_class is not None: if is_array: raise ValueError( _format("Property {0!A} specifies reference_class {1!A} " "but is an array property", name, reference_class)) # The check for valid types of the input value will be performed # in the value setter. # We use the respective setter methods: self.type = type self.value = value # value setter relies on self.type being set self.class_origin = class_origin self.array_size = array_size self.propagated = propagated self.is_array = is_array self.reference_class = reference_class self.qualifiers = qualifiers self.embedded_object = embedded_object @property def name(self): """ :term:`unicode string`: Name of this CIM property. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._name @name.setter def name(self, name): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._name = _ensure_unicode(name) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if name is None: raise ValueError("CIMProperty 'name' parameter must not be None") @property def value(self): """ :term:`CIM data type`: Value of this CIM property. The property value is interpreted as an actual property value when this CIM property is used in a CIM instance, and as default value when this CIM property is used in a CIM class. `None` means that the value is Null. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._value @value.setter def value(self, value): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._value = cimvalue(value, self.type) @property def type(self): """ :term:`unicode string`: Name of the CIM data type of this CIM property. Example: ``"uint8"`` Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._type @type.setter def type(self, type): # pylint: disable=redefined-builtin """Setter method; for a description see the getter method.""" type = _ensure_unicode(type) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if type not in ALL_CIMTYPES: raise ValueError( _format("Invalid CIM type: {0}", type)) # pylint: disable=attribute-defined-outside-init self._type = type @property def reference_class(self): """ :term:`unicode string`: The name of the class referenced by this CIM reference property. Will be `None` for non-reference properties or if the referenced class is unspecified in reference properties. Note that in CIM instances returned from a WBEM server, :term:`DSP0201` recommends this attribute not to be set. For CIM classes returned from a WBEM server, :term:`DSP0201` requires this attribute to be set. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._reference_class @reference_class.setter def reference_class(self, reference_class): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._reference_class = _ensure_unicode(reference_class) @property def embedded_object(self): """ :term:`unicode string`: A string value indicating the kind of embedded object represented by this CIM property value. Has no meaning for CIM property declarations. The following values are defined for this parameter: * ``"instance"``: The property is declared with the ``EmbeddedInstance`` qualifier, indicating that the property value is an embedded instance of the class specified as the value of the ``EmbeddedInstance`` qualifier. The property value must be a :class:`~pywbem.CIMInstance` object, or `None`. * ``"object"``: The property is declared with the ``EmbeddedObject`` qualifier, indicating that the property value is an embedded object (instance or class) of which the class name is not known. The property value must be a :class:`~pywbem.CIMInstance` or :class:`~pywbem.CIMClass` object, or `None`. * `None`, for properties not representing embedded objects. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._embedded_object @embedded_object.setter def embedded_object(self, embedded_object): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init if embedded_object is False: self._embedded_object = None else: self._embedded_object = _ensure_unicode(embedded_object) @property def is_array(self): """ :class:`py:bool`: Boolean indicating that this CIM property is an array (as opposed to a scalar). Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._is_array @is_array.setter def is_array(self, is_array): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._is_array = _ensure_bool(is_array) @property def array_size(self): """ :term:`integer`: The size of the fixed-size array of this CIM property. `None` means that the array has variable size, or that the property is a scalar. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._array_size @array_size.setter def array_size(self, array_size): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._array_size = array_size @property def class_origin(self): """ :term:`unicode string`: The class origin of this CIM property, identifying the most derived class that defines or overrides the property in the class hierarchy of the class owning the property. `None` means that class origin information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._class_origin @class_origin.setter def class_origin(self, class_origin): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._class_origin = _ensure_unicode(class_origin) @property def propagated(self): """ :class:`py:bool`: Boolean indicating that the property declaration has been propagated from a superclass, or that the property value has been propagated from the creation class. `None` means that propagation information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. """ return self._propagated @propagated.setter def propagated(self, propagated): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._propagated = _ensure_bool(propagated) @property def qualifiers(self): """ `NocaseDict`_: Qualifiers (qualifier values) of this CIM property declaration. Will not be `None`. Each dictionary item specifies one qualifier value, with: * key (:term:`unicode string`): Qualifier name. Its lexical case was preserved. * value (:class:`~pywbem.CIMQualifier`): Qualifier value. The order of qualifiers in the property is preserved. This attribute is settable; setting it will cause the current qualifiers to be replaced with the new qualifiers. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMProperty>`. The qualifier values can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. The provided input value may be specified as a :term:`CIM data type` or as a :class:`~pywbem.CIMQualifier` object:: prop = CIMProperty(...) q1 = CIMQualifier('q1', ...) # may be CIM data type or CIMQualifier prop.qualifiers['q1'] = q1 # Set "q1" to q1 (add if needed) q1 = prop.qualifiers['q1'] # Access "q1" del prop.qualifiers['q1'] # Delete "q1" from the class """ if self._qualifiers is None: # Lazy initialization self._qualifiers = NocaseDict() return self._qualifiers @qualifiers.setter def qualifiers(self, qualifiers): """Setter method; for a description see the getter method.""" # We make sure that the dictionary is a NocaseDict object, and that the # property values are CIMQualifier objects: # pylint: disable=attribute-defined-outside-init self._qualifiers = None # Lazy initialization if qualifiers: try: # This is used for iterables: iterator = qualifiers.items() except AttributeError: # This is used for dictionaries: iterator = qualifiers for item in iterator: if isinstance(item, CIMQualifier): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for qualifiers has invalid item " "in iterable: {0!A}", item)) self.qualifiers[key] = _cim_qualifier(key, value)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMProperty` object that is a copy of this CIM property. This is a middle-deep copy; any mutable types in attributes except the following are copied, so besides these exceptions, modifications of the original object will not affect the returned copy, and vice versa. The following mutable types are not copied and are therefore shared between original and copy: * The :class:`~pywbem.CIMQualifier` objects in the :attr:`~pywbem.CIMProperty.qualifiers` dictionary (but not the dictionary object itself) Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ return CIMProperty( self.name, self.value, type=self.type, class_origin=self.class_origin, array_size=self.array_size, propagated=self.propagated, is_array=self.is_array, reference_class=self.reference_class, embedded_object=self.embedded_object, qualifiers=self.qualifiers) # setter copies
[docs] def __str__(self): """ Return a short string representation of this CIM property, for human consumption. """ return _format( "CIMProperty(" "name={s.name!A}, " "value={s.value!A}, " "type={s.type!A}, " "reference_class={s.reference_class!A}, " "embedded_object={s.embedded_object!A}, " "is_array={s.is_array!A}, ...)", s=self)
[docs] def __repr__(self): """ Return a string representation of this CIM property, that is suitable for debugging. The order of qualifiers will be preserved in the result. """ return _format( "CIMProperty(" "name={s.name!A}, " "value={s.value!A}, " "type={s.type!A}, " "reference_class={s.reference_class!A}, " "embedded_object={s.embedded_object!A}, " "is_array={s.is_array!A}, " "array_size={s.array_size!A}, " "class_origin={s.class_origin!A}, " "propagated={s.propagated!A}, " "qualifiers={s.qualifiers!A})", s=self)
[docs] def tocimxml(self): """ Return the CIM-XML representation of this CIM property, as an object of an appropriate subclass of :term:`Element`. The returned CIM-XML representation is a `PROPERTY`, `PROPERTY.REFERENCE`, or `PROPERTY.ARRAY` element dependent on the property type, and consistent with :term:`DSP0201`. Note that array properties cannot be of reference type. The order of qualifiers in the returned CIM-XML representation is preserved from the :class:`~pywbem.CIMProperty` object. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ qualifiers = [q.tocimxml() for q in self.qualifiers.values()] if self.is_array: # pylint: disable=no-else-return assert self.type != 'reference' if self.value is None: value_xml = None else: array_xml = [] for v in self.value: if v is None: if SEND_VALUE_NULL: array_xml.append(_cim_xml.VALUE_NULL()) else: array_xml.append(_cim_xml.VALUE(None)) elif self.embedded_object is not None: assert isinstance(v, (CIMInstance, CIMClass)) array_xml.append(_cim_xml.VALUE(v.tocimxml().toxml())) else: array_xml.append(_cim_xml.VALUE(atomic_to_cim_xml(v))) value_xml = _cim_xml.VALUE_ARRAY(array_xml) return _cim_xml.PROPERTY_ARRAY( self.name, self.type, value_xml, self.array_size, self.class_origin, self.propagated, embedded_object=self.embedded_object, qualifiers=qualifiers) elif self.type == 'reference': # scalar if self.value is None: value_xml = None else: value_xml = _cim_xml.VALUE_REFERENCE(self.value.tocimxml()) return _cim_xml.PROPERTY_REFERENCE( self.name, value_xml, reference_class=self.reference_class, class_origin=self.class_origin, propagated=self.propagated, qualifiers=qualifiers) else: # scalar non-reference if self.value is None: value_xml = None else: if self.embedded_object is not None: assert isinstance(self.value, (CIMInstance, CIMClass)) value_xml = _cim_xml.VALUE(self.value.tocimxml().toxml()) else: value_xml = _cim_xml.VALUE(atomic_to_cim_xml(self.value)) return _cim_xml.PROPERTY( self.name, self.type, value_xml, class_origin=self.class_origin, propagated=self.propagated, embedded_object=self.embedded_object, qualifiers=qualifiers)
[docs] def tocimxmlstr(self, indent=None): """ Return the CIM-XML representation of this CIM property, as a :term:`unicode string`. *New in pywbem 0.9.* For the returned CIM-XML representation, see :meth:`~pywbem.CIMProperty.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. Returns: The CIM-XML representation of the object, as a :term:`unicode string`. """ xml_elem = self.tocimxml() return tocimxmlstr(xml_elem, indent)
[docs] def tomof( self, is_instance=True, indent=0, maxline=MAX_MOF_LINE, line_pos=0): """ Return a MOF string with the declaration of this CIM property for use in a CIM class, or the specification of this CIM property for use in a CIM instance. *New in pywbem 0.9.* Even though pywbem supports qualifiers on :class:`~pywbem.CIMProperty` objects that are used as property values within an instance, the returned MOF string for property values in instances does not contain any qualifier values. The order of qualifiers is preserved. Parameters: is_instance (bool): If `True`, return MOF for a property value in a CIM instance. Else, return MOF for a property definition in a CIM class. indent (:term:`integer`): Number of spaces to indent each line of the returned string, counted in the line with the property name. Returns: :term:`unicode string`: MOF string. """ mof = [] if is_instance: # Property value in an instance mof.append(_indent_str(indent)) mof.append(self.name) else: # Property declaration in a class if self.qualifiers: mof.append(_qualifiers_tomof(self.qualifiers, indent + MOF_INDENT, maxline)) mof.append(_indent_str(indent)) mof.append(moftype(self.type, self.reference_class)) mof.append(u' ') mof.append(self.name) if self.is_array: mof.append(u'[') if self.array_size is not None: mof.append(six.text_type(self.array_size)) mof.append(u']') # Generate the property value (nearly common for property values and # property declarations). if self.value is not None or is_instance: mof.append(u' =') if isinstance(self.value, list): mof.append(u' {') mof_str = u''.join(mof) line_pos = len(mof_str) - mof_str.rfind('\n') - 1 # Assume in line_pos that the extra space would be needed val_str, line_pos = _value_tomof( self.value, self.type, indent + MOF_INDENT, maxline, line_pos + 1, 1, True) # Empty arrays are represented as val_str='' if val_str and val_str[0] != '\n': # The extra space was actually needed mof.append(u' ') else: # Adjust by the extra space that was not needed line_pos -= 1 mof.append(val_str) mof.append(u' }') else: mof_str = u''.join(mof) line_pos = len(mof_str) - mof_str.rfind('\n') - 1 # Assume in line_pos that the extra space would be needed val_str, line_pos = _value_tomof( self.value, self.type, indent + MOF_INDENT, maxline, line_pos + 1, 1, True) # Scalars cannot be represented as val_str='' if val_str[0] != '\n': # The extra space was actually needed mof.append(u' ') else: # Adjust by the extra space that was not needed line_pos -= 1 mof.append(val_str) mof.append(';\n') return u''.join(mof)
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMProperty` objects. The equality is based on their public attributes: * `name` * `value` * `type` * `reference_class` * `embedded_object` * `is_array` * `array_size` * `propagated` * `class_origin` * `qualifiers` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMProperty` object. """ if self is other: return True if not isinstance(other, CIMProperty): raise TypeError( _format("other must be CIMProperty, but is: {0}", type(other))) return (_eq_name(self.name, other.name) and _eq_item(self.value, other.value) and _eq_item(self.type, other.type) and _eq_name(self.reference_class, other.reference_class) and _eq_item(self.embedded_object, other.embedded_object) and _eq_item(self.is_array, other.is_array) and _eq_item(self.array_size, other.array_size) and _eq_item(self.propagated, other.propagated) and _eq_name(self.class_origin, other.class_origin) and _eq_dict(self.qualifiers, other.qualifiers))
[docs] def __hash__(self): """ Return a hash value based on the public attributes of this class, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.name), _hash_item(self.value), _hash_item(self.type), _hash_name(self.reference_class), _hash_item(self.embedded_object), _hash_item(self.is_array), _hash_item(self.array_size), _hash_item(self.propagated), _hash_name(self.class_origin), _hash_dict(self.qualifiers), ) return hash(hashes)
[docs]class CIMMethod(_CIMComparisonMixin, SlottedPickleMixin): """ A method (declaration) in a CIM class. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_name', '_return_type', '_parameters', '_class_origin', '_propagated', '_qualifiers'] # pylint: disable=too-many-arguments def __init__(self, name=None, return_type=None, parameters=None, class_origin=None, propagated=None, qualifiers=None): """ The init method stores the input parameters as-is and does not infer unspecified parameters from the others (like :class:`~pywbem.CIMProperty` does). Parameters: name (:term:`string`): Name of this CIM method (just the method name, without class name or parenthesis). Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. return_type (:term:`string`): Name of the CIM data type of the method return type (e.g. ``"uint32"``). Must not be `None` or ``"reference"``. :exc:`py:ValueError` is raised if the type is `None`, ``"reference"``, or not a valid CIM data type (see :ref:`CIM data types`). Support for void return types: Pywbem also does not support void return types, consistent with the CIM architecture and MOF syntax (see :term:`DSP0004`). Note that void return types could be represented in CIM-XML (see :term:`DSP0201`). Support for reference return types: Pywbem does not support reference return types of methods. The CIM architecture and MOF syntax support reference return types, and the CIM-XML protocol supports the invocation of methods with reference return types. However, CIM-XML does not support the representation of class declarations with methods that have reference return types. Support for array return types: Pywbem does not support array return types of methods, consistent with the CIM architecture, MOF syntax and CIM-XML. parameters (:term:`parameters input object`): Parameter declarations for the method. class_origin (:term:`string`): The CIM class origin of the method (the name of the most derived class that defines or overrides the method in the class hierarchy of the class owning the method). `None` means that class origin information is not available, and the :attr:`~pywbem.CIMMethod.class_origin` attribute will also be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. propagated (:class:`py:bool`): If not `None`, specifies whether the method has been propagated from a superclass. `None` means that propagation information is not available, and the the :attr:`~pywbem.CIMMethod.propagated` attribute will also be `None`. qualifiers (:term:`qualifiers input object`): The qualifiers for the method. """ # We use the respective setter methods: self.name = name self.return_type = return_type self.parameters = parameters self.class_origin = class_origin self.propagated = propagated self.qualifiers = qualifiers @property def name(self): """ :term:`unicode string`: Name of this CIM method. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMMethod>`. """ return self._name @name.setter def name(self, name): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._name = _ensure_unicode(name) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if name is None: raise ValueError("CIMMethod 'name' parameter must not be None") @property def return_type(self): """ :term:`unicode string`: Name of the CIM data type of the return type of this CIM method. Example: ``"uint32"`` Will not be `None` or ``"reference"``. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMMethod>`. """ return self._return_type @return_type.setter def return_type(self, return_type): """Setter method; for a description see the getter method.""" return_type = _ensure_unicode(return_type) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if return_type not in ALL_CIMTYPES: raise ValueError( _format("Invalid CIM type: {0}", return_type)) if return_type == 'reference': raise ValueError("Method cannot have a reference return type") # pylint: disable=attribute-defined-outside-init self._return_type = return_type @property def class_origin(self): """ :term:`unicode string`: The class origin of this CIM method, identifying the most derived class that defines or overrides the method in the class hierarchy of the class owning the method. `None` means that class origin information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMMethod>`. """ return self._class_origin @class_origin.setter def class_origin(self, class_origin): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._class_origin = _ensure_unicode(class_origin) @property def propagated(self): """ :class:`py:bool`: Boolean indicating that this CIM method has been propagated from a superclass. `None` means that propagation information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMMethod>`. """ return self._propagated @propagated.setter def propagated(self, propagated): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._propagated = _ensure_bool(propagated) @property def parameters(self): """ `NocaseDict`_: Parameters of this CIM method. Will not be `None`. Each dictionary item specifies one parameter, with: * key (:term:`unicode string`): Parameter name. Its lexical case was preserved. * value (:class:`~pywbem.CIMParameter`): Parameter declaration. The order of parameters in the method is preserved. This attribute is settable; setting it will cause the current parameters to be replaced with the new parameters. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMMethod>`. The parameters can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. The provided input value must be a :class:`~pywbem.CIMParameter` object:: meth = CIMMethod(...) p1 = CIMParameter('p1', ...) # must be a CIMParameter meth.parameters['p1'] = p1 # Set "p1" to p1 (add if needed) p1 = meth.parameters['p1'] # Access "p1" del meth.parameters['p1'] # Delete "p1" from the class """ if self._parameters is None: # Lazy initialization self._parameters = NocaseDict() return self._parameters @parameters.setter def parameters(self, parameters): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._parameters = None # Lazy initialization if parameters: try: # This is used for iterables: iterator = parameters.items() except AttributeError: # This is used for dictionaries: iterator = parameters for item in iterator: if isinstance(item, CIMParameter): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for parameters has invalid item " "in iterable: {0!A}", item)) self.parameters[key] = _cim_parameter(key, value) @property def qualifiers(self): """ `NocaseDict`_: Qualifiers (qualifier values) of this CIM method. Will not be `None`. Each dictionary item specifies one qualifier value, with: * key (:term:`unicode string`): Qualifier name. Its lexical case was preserved. * value (:class:`~pywbem.CIMQualifier`): Qualifier value. The order of qualifiers in the method is preserved. This attribute is settable; setting it will cause the current qualifiers to be replaced with the new qualifiers. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMMethod>`. The qualifier values can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. The provided input value may be specified as a :term:`CIM data type` or as a :class:`~pywbem.CIMQualifier` object:: meth = CIMMethod(...) q1 = "..." # may be CIM data type or CIMQualifier meth.qualifiers['q1'] = q1 # Set "q1" to q1 (add if needed) q1 = meth.qualifiers['q1'] # Access "q1" del meth.qualifiers['q1'] # Delete "q1" from the class """ if self._qualifiers is None: # Lazy initialization self._qualifiers = NocaseDict() return self._qualifiers @qualifiers.setter def qualifiers(self, qualifiers): """Setter method; for a description see the getter method.""" # We make sure that the dictionary is a NocaseDict object, and that the # property values are CIMQualifier objects: # pylint: disable=attribute-defined-outside-init self._qualifiers = None # Lazy initialization if qualifiers: try: # This is used for iterables: iterator = qualifiers.items() except AttributeError: # This is used for dictionaries: iterator = qualifiers for item in iterator: if isinstance(item, CIMQualifier): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for qualifiers has invalid item " "in iterable: {0!A}", item)) self.qualifiers[key] = _cim_qualifier(key, value)
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMMethod` objects. The equality is based on their public attributes: * `name` * `qualifiers` * `parameters` * `return_type` * `class_origin` * `propagated` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMMethod` object. """ if self is other: return True if not isinstance(other, CIMMethod): raise TypeError( _format("other must be CIMMethod, but is: {0}", type(other))) return (_eq_name(self.name, other.name) and _eq_dict(self.qualifiers, other.qualifiers) and _eq_dict(self.parameters, other.parameters) and _eq_item(self.return_type, other.return_type) and _eq_name(self.class_origin, other.class_origin) and _eq_item(self.propagated, other.propagated))
[docs] def __hash__(self): """ Return a hash value based on the public attributes of this class, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.name), _hash_dict(self.qualifiers), _hash_dict(self.parameters), _hash_item(self.return_type), _hash_name(self.class_origin), _hash_item(self.propagated), ) return hash(hashes)
[docs] def __str__(self): """ Return a short string representation of this CIM method, for human consumption. """ return _format( "CIMMethod(" "name={s.name!A}, " "return_type={s.return_type!A}, ...)", s=self)
[docs] def __repr__(self): """ Return a string representation of this CIM method, that is suitable for debugging. The order of parameters and qualifiers will be preserved in the result. """ return _format( "CIMMethod(" "name={s.name!A}, " "return_type={s.return_type!A}, " "class_origin={s.class_origin!A}, " "propagated={s.propagated!A}, " "parameters={s.parameters!A}, " "qualifiers={s.qualifiers!A})", s=self)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMMethod` object that is a copy of this CIM method. This is a middle-deep copy; any mutable types in attributes except the following are copied, so besides these exceptions, modifications of the original object will not affect the returned copy, and vice versa. The following mutable types are not copied and are therefore shared between original and copy: * The :class:`~pywbem.CIMParameter` objects in the :attr:`~pywbem.CIMMethod.parameters` dictionary (but not the dictionary object itself) * The :class:`~pywbem.CIMQualifier` objects in the :attr:`~pywbem.CIMMethod.qualifiers` dictionary (but not the dictionary object itself) Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ return CIMMethod( self.name, return_type=self.return_type, class_origin=self.class_origin, propagated=self.propagated, parameters=self.parameters, # setter copies qualifiers=self.qualifiers) # setter copies
[docs] def tocimxml(self): """ Return the CIM-XML representation of this CIM method, as an object of an appropriate subclass of :term:`Element`. The returned CIM-XML representation is a `METHOD` element consistent with :term:`DSP0201`. The order of parameters and qualifiers in the returned CIM-XML representation is preserved from the :class:`~pywbem.CIMMethod` object. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ return _cim_xml.METHOD( self.name, parameters=[p.tocimxml() for p in self.parameters.values()], return_type=self.return_type, class_origin=self.class_origin, propagated=self.propagated, qualifiers=[q.tocimxml() for q in self.qualifiers.values()])
[docs] def tocimxmlstr(self, indent=None): """ Return the CIM-XML representation of this CIM method, as a :term:`unicode string`. *New in pywbem 0.9.* For the returned CIM-XML representation, see :meth:`~pywbem.CIMMethod.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. Returns: The CIM-XML representation of the object, as a :term:`unicode string`. """ xml_elem = self.tocimxml() return tocimxmlstr(xml_elem, indent)
[docs] def tomof(self, indent=0, maxline=MAX_MOF_LINE): """ Return a MOF string with the declaration of this CIM method for use in a CIM class declaration. The order of parameters and qualifiers is preserved. Parameters: indent (:term:`integer`): Number of spaces to indent each line of the returned string, counted in the line with the method name. Returns: :term:`unicode string`: MOF string. """ mof = [] if self.qualifiers: mof.append(_qualifiers_tomof(self.qualifiers, indent + MOF_INDENT, maxline)) mof.append(_indent_str(indent)) # return_type is ensured not to be None or reference mof.append(moftype(self.return_type, None)) mof.append(u' ') mof.append(self.name) if self.parameters.values(): mof.append(u'(\n') mof_parms = [] for p in self.parameters.values(): mof_parms.append(p.tomof(indent + MOF_INDENT, maxline)) mof.append(u',\n'.join(mof_parms)) mof.append(u');\n') else: mof.append(u'();\n') return u''.join(mof)
[docs]class CIMParameter(_CIMComparisonMixin, SlottedPickleMixin): """ A CIM parameter (value or declaration). This object can be used as parameter value in the :meth:`~pywbem.WBEMConnection.InvokeMethod` operation, and as a parameter declaration in a :class:`~pywbem.CIMMethod` object. For parameter values in method invocations: * The `value` attribute is the actual value of the parameter. * Qualifiers are not allowed. For parameter declarations in method declarations: * The `value` attribute is ignored. * Qualifiers are allowed. Scalar (=non-array) parameters and items in array parameters may have a value of NULL (= `None`), any primitive CIM data type, reference type, or string type with embedded instance or embedded object. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_name', '_type', '_reference_class', '_is_array', '_array_size', '_qualifiers', '_value', '_embedded_object'] # pylint: disable=too-many-arguments def __init__(self, name, type, reference_class=None, is_array=None, array_size=None, qualifiers=None, value=None, embedded_object=None): # pylint: disable=redefined-builtin """ The init method stores the input parameters as-is and does not infer unspecified parameters from the others (like :class:`~pywbem.CIMProperty` does). Parameters: name (:term:`string`): Name of this CIM parameter. Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. type (:term:`string`): Name of the CIM data type of this CIM parameter. Example: ``"uint8"`` Must not be `None`. :exc:`py:ValueError` is raised if the type is `None` or not a valid CIM data type (see :ref:`CIM data types`). reference_class (:term:`string`): For reference parameters, the name of the class referenced by the parameter, or `None` indicating that the referenced class is unspecified. For non-reference parameters, must be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. is_array (:class:`py:bool`): A boolean indicating whether the parameter is an array (`True`) or a scalar (`False`). If `None`, the :attr:`~pywbem.CIMParameter.is_array` attribute will be inferred from the `value` parameter. If the `value` parameter is `None`, a scalar is assumed. array_size (:term:`integer`): The size of the array parameter, for fixed-size arrays. `None` means that the array parameter has variable size, and the :attr:`~pywbem.CIMParameter.array_size` attribute will also be `None`. qualifiers (:term:`qualifiers input object`): The qualifiers for the parameter. value: The value of the CIM method parameter for the method invocation. Has no meaning for parameter declarations. The specified value will be converted to a :term:`CIM data type` using the rules documented in the description of :func:`~pywbem.cimvalue`, taking into account the `type` parameter. embedded_object (:term:`string`): A string value indicating the kind of embedded object represented by the parameter value (i.e. the `value` parameter). Has no meaning for parameter declarations. For details about the possible values, see the corresponding attribute. `None` means that the value is unspecified, causing the same-named attribute in the :class:`~pywbem.CIMParameter` object to be inferred from the parameter value (i.e. the `value` parameter). An exception is raised if it cannot be inferred. `False` means the parameter value is not an embedded object, and is stored as `None`. """ # We use the respective setter methods: self.name = name if is_array is None: is_array = _infer_is_array(value) else: # For performance reasons, we check only if not inferred. # This leaves the incorrect combination of is_array=False and # array_size=5 undetected, which seems acceptable because # array_size is ignored anyway when is_array=False. _check_array_parms(is_array, array_size, value, "parameter", name) if embedded_object is None: embedded_object = _infer_embedded_object(value) if embedded_object: _check_embedded_object(embedded_object, type, value, "parameter", name) # We use the respective setter methods: self.type = type self.reference_class = reference_class self.is_array = is_array self.array_size = array_size self.qualifiers = qualifiers self.value = value # value setter relies on self.type being set self.embedded_object = embedded_object @property def name(self): """ :term:`unicode string`: Name of this CIM parameter. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMParameter>`. """ return self._name @name.setter def name(self, name): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._name = _ensure_unicode(name) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if name is None: raise ValueError("CIMParameter 'name' parameter must not be None") @property def type(self): """ :term:`unicode string`: Name of the CIM data type of this CIM parameter. Example: ``"uint8"`` Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMParameter>`. """ return self._type @type.setter def type(self, type): # pylint: disable=redefined-builtin """Setter method; for a description see the getter method.""" type = _ensure_unicode(type) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if type not in ALL_CIMTYPES: raise ValueError( _format("Invalid CIM type: {0}", type)) # pylint: disable=attribute-defined-outside-init self._type = type @property def reference_class(self): """ :term:`unicode string`: The name of the class referenced by this CIM reference parameter. Will be `None` for non-reference parameters or if the referenced class is unspecified in reference parameters. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMParameter>`. """ return self._reference_class @reference_class.setter def reference_class(self, reference_class): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._reference_class = _ensure_unicode(reference_class) @property def is_array(self): """ :class:`py:bool`: Boolean indicating that this CIM parameter is an array (as opposed to a scalar). Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMParameter>`. """ return self._is_array @is_array.setter def is_array(self, is_array): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._is_array = _ensure_bool(is_array) @property def array_size(self): """ :term:`integer`: The size of the fixed-size array of this CIM parameter. `None` means that the array has variable size, or that the parameter is a scalar. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMParameter>`. """ return self._array_size @array_size.setter def array_size(self, array_size): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._array_size = array_size @property def qualifiers(self): """ `NocaseDict`_: Qualifiers (qualifier values) of this CIM parameter. Will not be `None`. Each dictionary item specifies one qualifier value, with: * key (:term:`unicode string`): Qualifier name. Its lexical case was preserved. * value (:class:`~pywbem.CIMQualifier`): Qualifier value. The order of qualifiers in the parameter is preserved. This attribute is settable; setting it will cause the current qualifiers to be replaced with the new qualifiers. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMParameter>`. The qualifier values can also be accessed and manipulated one by one because the attribute value is a modifiable dictionary. The provided input value may be specified as a :term:`CIM data type` or as a :class:`~pywbem.CIMQualifier` object:: parm = CIMParameter(...) q1 = True # may be CIM data type or CIMQualifier parm.qualifiers['q1'] = q1 # Set "q1" to q1 (add if needed) q1 = parm.qualifiers['q1'] # Access "q1" del parm.qualifiers['q1'] # Delete "q1" from the class """ if self._qualifiers is None: # Lazy initialization self._qualifiers = NocaseDict() return self._qualifiers @qualifiers.setter def qualifiers(self, qualifiers): """Setter method; for a description see the getter method.""" # We make sure that the dictionary is a NocaseDict object, and that the # property values are CIMQualifier objects: # pylint: disable=attribute-defined-outside-init self._qualifiers = None # Lazy initialization if qualifiers: try: # This is used for iterables: iterator = qualifiers.items() except AttributeError: # This is used for dictionaries: iterator = qualifiers for item in iterator: if isinstance(item, CIMQualifier): key = item.name value = item elif isinstance(item, tuple): key, value = item else: raise TypeError( _format("Input object for qualifiers has invalid item " "in iterable: {0!A}", item)) self.qualifiers[key] = _cim_qualifier(key, value) @property def value(self): """ The value of this CIM parameter for the method invocation. Has no meaning for parameter declarations. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMParameter>`. """ return self._value @value.setter def value(self, value): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._value = cimvalue(value, self.type) @property def embedded_object(self): """ :term:`unicode string`: A string value indicating the kind of embedded object represented by this CIM parameter value. Has no meaning for CIM parameter declarations. The following values are defined for this parameter: * ``"instance"``: The parameter is declared with the ``EmbeddedInstance`` qualifier, indicating that the parameter value is an embedded instance of the class specified as the value of the ``EmbeddedInstance`` qualifier. The property value must be a :class:`~pywbem.CIMInstance` object, or `None`. * ``"object"``: The parameter is declared with the ``EmbeddedObject`` qualifier, indicating that the parameter value is an embedded object (instance or class) of which the class name is not known. The parameter value must be a :class:`~pywbem.CIMInstance` or :class:`~pywbem.CIMClass` object, or `None`. * `None`, for parameters not representing embedded objects. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMParameter>`. """ return self._embedded_object @embedded_object.setter def embedded_object(self, embedded_object): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init if embedded_object is False: self._embedded_object = None else: self._embedded_object = _ensure_unicode(embedded_object)
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMParameter` objects. The equality is based on their public attributes: * `name` * `type` * `reference_class` * `is_array` * `array_size` * `qualifiers` * `value` * `embedded_object` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMParameter` object. """ if self is other: return True if not isinstance(other, CIMParameter): raise TypeError( _format("other must be CIMParameter, but is: {0}", type(other))) return (_eq_name(self.name, other.name) and _eq_item(self.type, other.type) and _eq_name(self.reference_class, other.reference_class) and _eq_item(self.is_array, other.is_array) and _eq_item(self.array_size, other.array_size) and _eq_dict(self.qualifiers, other.qualifiers) and _eq_item(self.value, other.value) and _eq_item(self.embedded_object, other.embedded_object))
[docs] def __hash__(self): """ Return a hash value based on the public attributes of this class, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.name), _hash_item(self.type), _hash_name(self.reference_class), _hash_item(self.is_array), _hash_item(self.array_size), _hash_dict(self.qualifiers), _hash_item(self.value), _hash_item(self.embedded_object), ) return hash(hashes)
[docs] def __str__(self): """ Return a short string representation of this CIM parameter, for human consumption. """ return _format( "CIMParameter(" "name={s.name!A}, " "type={s.type!A}, " "reference_class={s.reference_class!A}, " "is_array={s.is_array!A}, ...)", s=self)
[docs] def __repr__(self): """ Return a string representation of this CIM parameter, that is suitable for debugging. The order of qualifiers will be preserved in the result. """ return _format( "CIMParameter(" "name={s.name!A}, " "type={s.type!A}, " "reference_class={s.reference_class!A}, " "is_array={s.is_array!A}, " "array_size={s.array_size!A}, " "qualifiers={s.qualifiers!A}, " "value={s.value!A}, " "embedded_object={s.embedded_object!A})", s=self)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMParameter` object that is a copy of this CIM parameter. This is a middle-deep copy; any mutable types in attributes except the following are copied, so besides these exceptions, modifications of the original object will not affect the returned copy, and vice versa. The following mutable types are not copied and are therefore shared between original and copy: * The :class:`~pywbem.CIMQualifier` objects in the :attr:`~pywbem.CIMParameter.qualifiers` dictionary (but not the dictionary object itself) Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ return CIMParameter( self.name, self.type, reference_class=self.reference_class, is_array=self.is_array, array_size=self.array_size, value=self.value, embedded_object=self.embedded_object, qualifiers=self.qualifiers) # setter copies
[docs] def tocimxml(self, as_value=False): """ Return the CIM-XML representation of this CIM parameter, as an object of an appropriate subclass of :term:`Element`. The returned CIM-XML representation can be created either as a parameter declaration for use in a method declaration, or as a parameter value for use in a method invocation. If a parameter value is to be returned, the returned CIM-XML representation is a `PARAMVALUE` element with child elements dependent on the parameter type, and consistent with :term:`DSP0201`. If a parameter declaration is to be returned, the returned CIM-XML representation is a `PARAMETER`, `PARAMETER.REFERENCE`, `PARAMETER.ARRAY`, or `PARAMETER.REFARRAY` element dependent on the parameter type, and consistent with :term:`DSP0201`. The order of qualifiers in the returned CIM-XML representation of a parameter declaration is preserved from the :class:`~pywbem.CIMParameter` object. Parameters: as_value (bool): If `True`, return the object as a parameter value. Otherwise, return the object as a parameter declaration. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ if as_value: # pylint: disable=no-else-return if self.value is None: value_xml = None elif self.is_array: if self.type == 'reference': array_xml = [] for v in self.value: if v is None: if SEND_VALUE_NULL: array_xml.append(_cim_xml.VALUE_NULL()) else: array_xml.append(_cim_xml.VALUE(None)) else: array_xml.append( _cim_xml.VALUE_REFERENCE(v.tocimxml())) value_xml = _cim_xml.VALUE_REFARRAY(array_xml) else: # array non-reference array_xml = [] for v in self.value: if v is None: if SEND_VALUE_NULL: array_xml.append(_cim_xml.VALUE_NULL()) else: array_xml.append(_cim_xml.VALUE(None)) elif self.embedded_object is not None: array_xml.append( _cim_xml.VALUE(v.tocimxml().toxml())) else: array_xml.append( _cim_xml.VALUE(atomic_to_cim_xml(v))) value_xml = _cim_xml.VALUE_ARRAY(array_xml) else: # scalar if self.type == 'reference': value_xml = _cim_xml.VALUE_REFERENCE(self.value.tocimxml()) elif self.embedded_object is not None: value_xml = _cim_xml.VALUE(self.value.tocimxml().toxml()) else: value_xml = _cim_xml.VALUE(atomic_to_cim_xml(self.value)) return _cim_xml.PARAMVALUE( self.name, value_xml, paramtype=self.type, embedded_object=self.embedded_object) else: # as declaration qualifiers = [q.tocimxml() for q in self.qualifiers.values()] if self.is_array: # pylint: disable=no-else-return if self.array_size is None: array_size = None else: array_size = str(self.array_size) if self.type == 'reference': return _cim_xml.PARAMETER_REFARRAY( self.name, self.reference_class, array_size, qualifiers=qualifiers) # For non-reference array types: return _cim_xml.PARAMETER_ARRAY( self.name, self.type, array_size, qualifiers=qualifiers) else: # scalar if self.type == 'reference': return _cim_xml.PARAMETER_REFERENCE( self.name, self.reference_class, qualifiers=qualifiers) # For non-reference types: return _cim_xml.PARAMETER( self.name, self.type, qualifiers=qualifiers)
[docs] def tocimxmlstr(self, indent=None, as_value=False): """ Return the CIM-XML representation of this CIM parameter, as a :term:`unicode string`. *New in pywbem 0.9.* The returned CIM-XML representation can be created either as a parameter declaration for use in a method declaration, or as a parameter value for use in a method invocation. For the returned CIM-XML representation, see :meth:`~pywbem.CIMParameter.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. as_value (bool): If `True`, return the object as a parameter value. Otherwise, return the object as a parameter declaration. Returns: The CIM-XML representation of the object, as a :term:`unicode string`. """ xml_elem = self.tocimxml(as_value) return tocimxmlstr(xml_elem, indent)
[docs] def tomof(self, indent=0, maxline=MAX_MOF_LINE): """ Return a MOF string with the declaration of this CIM parameter for use in a CIM method declaration. The object is always interpreted as a parameter declaration; so the :attr:`~pywbem.CIMParameter.value` and :attr:`~pywbem.CIMParameter.embedded_object` attributes are ignored. The order of qualifiers is preserved. Parameters: indent (:term:`integer`): Number of spaces to indent each line of the returned string, counted in the line with the parameter name. Returns: :term:`unicode string`: MOF string. """ mof = [] if self.qualifiers: mof.append(_qualifiers_tomof(self.qualifiers, indent + MOF_INDENT, maxline)) mof.append(_indent_str(indent)) mof.append(moftype(self.type, self.reference_class)) mof.append(u' ') mof.append(self.name) if self.is_array: mof.append(u'[') if self.array_size is not None: mof.append(six.text_type(self.array_size)) mof.append(u']') return u''.join(mof)
# pylint: disable=too-many-instance-attributes
[docs]class CIMQualifier(_CIMComparisonMixin, SlottedPickleMixin): """ A CIM qualifier value. A qualifier represents metadata on a class, method, property, etc., and specifies information such as a documentation string or whether a property is a key. :class:`~pywbem.CIMQualifier` objects can be used to represent the qualifier values that are specified on a CIM element (e.g. on a CIM class). In that case, the :attr:`propagated` property is always `False`, and the effective values of applicable but unspecified qualifiers need to be determined by users, by considering the default value of the corresponding qualifier type, the propagation and override flavors of the qualifier, and the qualifier values that have been specified in the class ancestry of the CIM element in question. :class:`~pywbem.CIMQualifier` objects can also be used to represent the effective values of all applicable qualifiers on a CIM element, including those that have not been specified, e.g. in the MOF declaration of the CIM element. In this case, the :class:`CIMQualifier` objects for qualifier values that are specified in MOF represent the specified values, and their :attr:`propagated` property is `False`. The :class:`CIMQualifier` objects for qualifier values that are not specified in MOF represent the effective values, and their :attr:`propagated` property is `True`. Whether a set of :class:`CIMQualifier` objects on a CIM object represents just the specified qualifiers or all applicable qualifiers needs to be known from the context. :class:`~pywbem.CIMQualifier` has properties that represent qualifier flavors (:attr:`tosubclass`, :attr:`toinstance`, :attr:`overridable`, and :attr:`translatable`). If any of these flavor properties is not `None`, the qualifier value represented by the :class:`~pywbem.CIMQualifier` object implicitly defines a qualifier type. Implicitly defined qualifier types have been deprecated in :term:`DSP0004`. The implicitly defined qualifier type is conceptual and is not materialized as a :class:`~pywbem.CIMQualifierDeclaration` object. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_name', '_value', '_type', '_propagated', '_overridable', '_tosubclass', '_toinstance', '_translatable'] # pylint: disable=too-many-arguments def __init__(self, name, value, type=None, propagated=None, overridable=None, tosubclass=None, toinstance=None, translatable=None): # pylint: disable=redefined-builtin """ The init method infers optional parameters that are not specified (for example, it infers `type` from the Python type of `value` and other information). If the specified parameters are inconsistent, an exception is raised. If an optional parameter is needed for some reason, an exception is raised. Parameters: name (:term:`string`): Name of the qualifier. Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. value (:term:`CIM data type` or other suitable types): Value of the qualifier. `None` means that the qualifier is Null, and the same-named attribute in the :class:`~pywbem.CIMQualifier` object will also be `None`. The specified value will be converted to a :term:`CIM data type` using the rules documented in the description of :func:`~pywbem.cimvalue`, taking into account the `type` parameter. type (:term:`string`): Name of the CIM data type of the qualifier (e.g. ``"uint8"``). `None` will cause the type to be inferred from the `value` parameter, raising :exc:`py:ValueError` if it cannot be inferred (for example when `value` is `None` or a Python integer). :exc:`py:ValueError` is raised if the type is not a valid CIM data type (see :ref:`CIM data types`). propagated (:class:`py:bool`): If not `None`, specifies whether the qualifier value has been propagated from a superclass. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifier.propagated` attribute will also be `None`. overridable (:class:`py:bool`): If not `None`, specifies whether the qualifier value is overridable in subclasses. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifier.overridable` attribute will also be `None`. tosubclass (:class:`py:bool`): If not `None`, specifies whether the qualifier value propagates to subclasses. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifier.tosubclass` attribute will also be `None`. toinstance (:class:`py:bool`): If not `None`, specifies whether the qualifier value propagates to instances. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifier.toinstance` attribute will also be `None`. Note that :term:`DSP0200` has deprecated the presence of qualifier values on CIM instances. translatable (:class:`py:bool`): If not `None`, specifies whether the qualifier is translatable. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifier.translatable` attribute will also be `None`. Examples: :: # a string qualifier: CIMQualifier("MyString", "abc") # a uint8 qualifier: CIMQualifier("MyNum", 42, "uint8") # a uint8 qualifier: CIMQualifier("MyNum", Uint8(42)) # a uint8 array qualifier: CIMQualifier("MyNumArray", [1, 2, 3], "uint8") # a string qualifier that is Null: CIMQualifier("MyString", None, "string") # a uint8 qualifier that is Null: CIMQualifier("MyNum", None, "uint8") """ # We use the respective setter methods: self.name = name if type is None: type = _infer_type(value, "qualifier", name) # We use the respective setter methods: self.type = type self.value = value # value setter relies on self.type being set self.propagated = propagated self.overridable = overridable self.tosubclass = tosubclass self.toinstance = toinstance self.translatable = translatable @property def name(self): """ :term:`unicode string`: Name of this CIM qualifier. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifier>`. """ return self._name @name.setter def name(self, name): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._name = _ensure_unicode(name) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if name is None: raise ValueError("CIMQualifier 'name' parameter must not be None") @property def type(self): """ :term:`unicode string`: Name of the CIM data type of this CIM qualifier. Example: ``"uint8"`` Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifier>`. """ return self._type @type.setter def type(self, type): # pylint: disable=redefined-builtin """Setter method; for a description see the getter method.""" type = _ensure_unicode(type) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if type not in QUALIFIER_CIMTYPES: raise ValueError( _format("Invalid CIM type for a qualifier: {0}", type)) # pylint: disable=attribute-defined-outside-init self._type = type @property def value(self): """ :term:`CIM data type`: Value of this CIM qualifier. `None` means that the value is Null. For CIM data types string and char16, this attribute will be a :term:`unicode string`, even when specified as a :term:`byte string`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifier>`. """ return self._value @value.setter def value(self, value): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._value = cimvalue(value, self.type) @property def propagated(self): """ :class:`py:bool`: Boolean indicating that the qualifier value has been propagated from a superclass. `None` means that propagation information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifier>`. """ return self._propagated @propagated.setter def propagated(self, propagated): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._propagated = _ensure_bool(propagated) @property def tosubclass(self): """ :class:`py:bool`: If not `None`, causes an implicit qualifier type to be defined for this qualifier that has the specified flavor. If `True`, specifies the ToSubclass flavor (the qualifier value propagates to subclasses); if `False` specifies the Restricted flavor (the qualifier values does not propagate to subclasses). `None` means that this information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifier>`. """ return self._tosubclass @tosubclass.setter def tosubclass(self, tosubclass): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._tosubclass = _ensure_bool(tosubclass) @property def toinstance(self): """ :class:`py:bool`: If not `None`, causes an implicit qualifier type to be defined for this qualifier that has the specified flavor. If `True` specifies the ToInstance flavor(the qualifier value propagates to instances. If `False`, specifies that qualifier values do not propagate to instances. There is no flavor corresponding to `toinstance=False`. `None` means that this information is not available. Note that :term:`DSP0200` has deprecated the presence of qualifier values on CIM instances. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifier>`. """ return self._toinstance @toinstance.setter def toinstance(self, toinstance): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._toinstance = _ensure_bool(toinstance) @property def overridable(self): """ :class:`py:bool`: If not `None`, causes an implicit qualifier type to be defined for this qualifier that has the specified flavor. If `True`, specifies the EnableOverride flavor(the qualifier value is overridable in subclasses); if `False` specifies the DisableOverride flavor(the qualifier value is not overridable in subclasses). `None` means that this information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifier>`. """ return self._overridable @overridable.setter def overridable(self, overridable): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._overridable = _ensure_bool(overridable) @property def translatable(self): """ :class:`py:bool`: If not `None`, causes an implicit qualifier type to be defined for this qualifier that has the specified flavor. If `True`, specifies the Translatable flavor (the qualifier is translatable); if `False` specifies that the qualfier is not translatable. There is no flavor corresponding to translatable=False. `None` means that this information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifier>`. """ return self._translatable @translatable.setter def translatable(self, translatable): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._translatable = _ensure_bool(translatable)
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMQualifier` objects. The equality is based on their public attributes: * `name` * `type` * `value` * `propagated` * `overridable` * `tosubclass` * `toinstance` * `translatable` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMQualifier` object. """ if self is other: return True if not isinstance(other, CIMQualifier): raise TypeError( _format("other must be CIMQualifier, but is: {0}", type(other))) return (_eq_name(self.name, other.name) and _eq_item(self.type, other.type) and _eq_item(self.value, other.value) and _eq_item(self.propagated, other.propagated) and _eq_item(self.overridable, other.overridable) and _eq_item(self.tosubclass, other.tosubclass) and _eq_item(self.toinstance, other.toinstance) and _eq_item(self.translatable, other.translatable))
[docs] def __hash__(self): """ Return a hash value based on the public attributes of this class, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.name), _hash_item(self.type), _hash_item(self.value), _hash_item(self.propagated), _hash_item(self.overridable), _hash_item(self.tosubclass), _hash_item(self.toinstance), _hash_item(self.translatable), ) return hash(hashes)
[docs] def __str__(self): """ Return a short string representation of this CIM qualifier, for human consumption. """ return _format( "CIMQualifier(" "name={s.name!A}, " "value={s.value!A}, " "type={s.type!A}, ...)", s=self)
[docs] def __repr__(self): """ Return a string representation of this CIM qualifier, that is suitable for debugging. """ return _format( "CIMQualifier(" "name={s.name!A}, " "value={s.value!A}, " "type={s.type!A}, " "tosubclass={s.tosubclass!A}, " "overridable={s.overridable!A}, " "translatable={s.translatable!A}, " "toinstance={s.toinstance!A}, " "propagated={s.propagated!A})", s=self)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMQualifier` object that is a copy of this CIM qualifier. Objects of this class have no mutable types in any attributes, so modifications of the original object will not affect the returned copy, and vice versa. Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ return CIMQualifier( self.name, self.value, type=self.type, propagated=self.propagated, overridable=self.overridable, tosubclass=self.tosubclass, toinstance=self.toinstance, translatable=self.translatable)
[docs] def tocimxml(self): """ Return the CIM-XML representation of this CIM qualifier, as an object of an appropriate subclass of :term:`Element`. The returned CIM-XML representation is a `QUALIFIER` element consistent with :term:`DSP0201`. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ if self.value is None: value_xml = None elif isinstance(self.value, (tuple, list)): array_xml = [] for v in self.value: if v is None: if SEND_VALUE_NULL: array_xml.append(_cim_xml.VALUE_NULL()) else: array_xml.append(_cim_xml.VALUE(None)) else: array_xml.append(_cim_xml.VALUE(atomic_to_cim_xml(v))) value_xml = _cim_xml.VALUE_ARRAY(array_xml) else: value_xml = _cim_xml.VALUE(atomic_to_cim_xml(self.value)) return _cim_xml.QUALIFIER( self.name, self.type, value_xml, propagated=self.propagated, overridable=self.overridable, tosubclass=self.tosubclass, toinstance=self.toinstance, translatable=self.translatable)
[docs] def tocimxmlstr(self, indent=None): """ Return the CIM-XML representation of this CIM qualifier, as a :term:`unicode string`. *New in pywbem 0.9.* For the returned CIM-XML representation, see :meth:`~pywbem.CIMQualifier.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. Returns: The CIM-XML representation of the object, as a :term:`unicode string`. """ xml_elem = self.tocimxml() return tocimxmlstr(xml_elem, indent)
[docs] def tomof(self, indent=MOF_INDENT, maxline=MAX_MOF_LINE, line_pos=0): """ Return a MOF string with the specification of this CIM qualifier as a qualifier value. The items of array values are tried to keep on the same line. If the generated line would exceed the maximum MOF line length, the value is split into multiple lines, on array item boundaries, and/or within long strings on word boundaries. If a string value (of a scalar value, or of an array item) is split into multiple lines, the first line of the value is put onto a line on its own. Parameters: indent (:term:`integer`): For a multi-line result, the number of spaces to indent each line except the first line (on which the qualifier name appears). For a single-line result, ignored. Returns: :term:`unicode string`: MOF string. """ mof = [] mof.append(self.name) mof.append(u' ') if isinstance(self.value, list): mof.append(u'{') else: mof.append(u'(') line_pos += len(u''.join(mof)) # Assume in line_pos that the extra space would be needed val_str, line_pos = _value_tomof( self.value, self.type, indent, maxline, line_pos + 1, 3, True) # Empty arrays are represented as val_str='' if val_str and val_str[0] != '\n': # The extra space was actually needed mof.append(u' ') else: # Adjust by the extra space that was not needed line_pos -= 1 mof.append(val_str) if isinstance(self.value, list): mof.append(u' }') else: mof.append(u' )') mof_str = u''.join(mof) return mof_str
# pylint: disable=too-many-instance-attributes
[docs]class CIMQualifierDeclaration(_CIMComparisonMixin, SlottedPickleMixin): """ A CIM qualifier type is the declaration of a qualifier and defines the attributes of qualifier name, qualifier type, value, scopes, and flavors for the qualifier. The scope of a qualifer determines the kinds of schema elements on which it can be specified. Value specifies the default value for the qualifier. Flavors specify certain characteristics of the qualifier such as its value propagation from the ancestry of the qualified element and its translatability. Flavors attributes must be specifically set on construction of the :class:`CIMQualifierDeclaration` or they will be set to `None`. This differs from the DMTF specification :term:`DSP0004` where default values are defined as follows: - Has the EnableOverride flavor; ``overridable = True`` - Has the ToSubClass flavor; ``tosubclass = True`` - Does not have theTranslatable flavor; ``translatable = False`` - Does not have ToInstance flavor; ``toinstance = False.`` Not defined in :term:`DSP0004` and deprecated in the DMTF protocol specification :term:`DSP0200` Because `None` is allowed as a value for the flavors attributes in constructing a :class:`CIMQualifierDeclaration`, the user must insure that any flavor which has the value `None` is set to its default value if required for subsequent processing. The pywbem MOF compiler supplies all of the flavor values so that those which were not specified in the MOF are set to the DMTF defined default values. Two objects of this class compare equal if their public attributes compare equal. Objects of this class are :term:`unchanged-hashable`, with the hash value being based on its public attributes. Therefore, objects of this class can be used as members in a set (or as dictionary keys) only during periods in which their public attributes remain unchanged. """ __slots__ = ['_name', '_type', '_value', '_is_array', '_array_size', '_scopes', '_overridable', '_tosubclass', '_toinstance', '_translatable'] # Order of scopes when externalizing the qualifier declaration _ordered_scopes = ["CLASS", "ASSOCIATION", "INDICATION", "PROPERTY", "REFERENCE", "METHOD", "PARAMETER", "ANY"] # pylint: disable=too-many-arguments def __init__(self, name, type, value=None, is_array=False, array_size=None, scopes=None, overridable=None, tosubclass=None, toinstance=None, translatable=None): # pylint: disable=redefined-builtin """ Parameters: name (:term:`string`): Name of the qualifier. Must not be `None`. The lexical case of the string is preserved. Object comparison and hash value calculation are performed case-insensitively. type (:term:`string`): Name of the CIM data type of the qualifier (e.g. ``"uint8"``). Must not be `None`. :exc:`py:ValueError` is raised if the type is `None` or not a valid CIM data type (see :ref:`CIM data types`). value (:term:`CIM data type` or other suitable types): Default value of the qualifier. `None` means a default value of Null, and the :attr:`~pywbem.CIMQualifierDeclaration.value` attribute will also be `None`. The specified value will be converted to a :term:`CIM data type` using the rules documented in the description of :func:`~pywbem.cimvalue`, taking into account the `type` parameter. is_array (:class:`py:bool`): A boolean indicating whether the qualifier is an array (`True`) or a scalar (`False`). If `None`, the :attr:`~pywbem.CIMQualifierDeclaration.is_array` attribute will be inferred from the `value` parameter. If the `value` parameter is `None`, a scalar is assumed. array_size (:term:`integer`): The size of the array qualifier, for fixed-size arrays. `None` means that the array qualifier has variable size, and the :attr:`~pywbem.CIMQualifierDeclaration.array_size` attribute will also be `None`. scopes (:class:`py:dict` or `NocaseDict`_): Scopes of the qualifier. A shallow copy of the provided dictionary will be stored in the :class:`~pywbem.CIMQualifierDeclaration` object. Each dictionary item specifies one scope value, with: * key (:term:`string`): Scope name, in upper case. Must not be `None`. * value (:class:`py:bool`): Scope value, specifying whether the qualifier has that scope (i.e. can be applied to a CIM element of that kind). Valid scope names are "CLASS", "ASSOCIATION", "REFERENCE", "PROPERTY", "METHOD", "PARAMETER", "INDICATION", and "ANY". `None` is interpreted as an empty set of scopes. For details about the dictionary items, see the corresponding attribute. overridable (:class:`py:bool`): If not `None`, defines the flavor that defines whether the qualifier value is overridable in subclasses. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifierDeclaration.overridable` attribute will also be `None`. tosubclass (:class:`py:bool`): If not `None`, specifies the flavor that defines whether the qualifier value propagates to subclasses. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifierDeclaration.tosubclass` attribute will also be `None`. toinstance (:class:`py:bool`): If not `None`, specifies the flavor that defines whether the qualifier value propagates to instances. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifierDeclaration.toinstance` attribute will also be `None`. Note that :term:`DSP0200` has deprecated the presence of qualifier values on CIM instances and this flavor is not defined in :term:`DSP0004` translatable (:class:`py:bool`): If not `None`, specifies the flavor that defines whether the qualifier is translatable. `None` means that this information is not available, and the :attr:`~pywbem.CIMQualifierDeclaration.translatable` attribute will also be `None`. """ # We use the respective setter methods: self.name = name if is_array is None: is_array = _infer_is_array(value) else: # For performance reasons, we check only if not inferred. # This leaves the incorrect combination of is_array=False and # array_size=5 undetected, which seems acceptable because # array_size is ignored anyway when is_array=False. _check_array_parms(is_array, array_size, value, "qualifier declaration", name) # We use the respective setter methods: self.type = type self.value = value # value setter relies on self.type being set self.is_array = is_array self.array_size = array_size self.scopes = scopes self.overridable = overridable self.tosubclass = tosubclass self.toinstance = toinstance self.translatable = translatable @property def name(self): """ :term:`unicode string`: Name of this CIM qualifier type. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._name @name.setter def name(self, name): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._name = _ensure_unicode(name) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if name is None: raise ValueError("CIMQualifierDeclaration 'name' parameter must " "not be None") @property def type(self): """ :term:`unicode string`: Name of the CIM data type of this CIM qualifier type. Example: ``"uint8"``. Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._type @type.setter def type(self, type): # pylint: disable=redefined-builtin """Setter method; for a description see the getter method.""" type = _ensure_unicode(type) # We perform this check after the initialization to avoid errors # in test tools that show the object with repr(). if type not in QUALIFIER_CIMTYPES: raise ValueError( _format("Invalid CIM type for a qualifier: {0}", type)) # pylint: disable=attribute-defined-outside-init self._type = type @property def value(self): """ :term:`CIM data type`: Default value of this CIM qualifier type. `None` means that the value is Null. For CIM data types string and char16, this attribute will be a :term:`unicode string`, even when specified as a :term:`byte string`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._value @value.setter def value(self, value): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._value = cimvalue(value, self.type) @property def is_array(self): """ :class:`py:bool`: Boolean indicating that this CIM qualifier type is an array (as opposed to a scalar). Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._is_array @is_array.setter def is_array(self, is_array): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._is_array = _ensure_bool(is_array) @property def array_size(self): """ :term:`integer`: The size of the fixed-size array of this CIM qualifier type. `None` means that the array has variable size (or that the qualifier type is not an array). This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._array_size @array_size.setter def array_size(self, array_size): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._array_size = array_size @property def scopes(self): """ `NocaseDict`_: Scopes of this CIM qualifier type. Each dictionary item specifies one scope value, with: * key (:term:`unicode string`): Scope name, in upper case. * value (:class:`py:bool`): Scope value, specifying whether the qualifier has that scope (i.e. can be applied to a CIM element of that kind). Valid scope names are "CLASS", "ASSOCIATION", "INDICATION", "PROPERTY", "REFERENCE", "METHOD", "PARAMETER", and "ANY". Will not be `None`. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ if self._scopes is None: # Lazy initialization self._scopes = NocaseDict() return self._scopes @scopes.setter def scopes(self, scopes): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._scopes = None # Lazy initialization if scopes: self.scopes.update(scopes) @property def tosubclass(self): """ :class:`py:bool`: If `True` specifies the ToSubclass flavor (the qualifier value propagates to subclasses); if `False` specifies the Restricted flavor (the qualifier value does not propagate to subclasses). `None` means that this information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._tosubclass @tosubclass.setter def tosubclass(self, tosubclass): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._tosubclass = _ensure_bool(tosubclass) @property def toinstance(self): """ :class:`py:bool`: If `True`, specifies the ToInstance flavor. This flavor specifies that the qualifier value propagates to instances. If `False`, specifies that qualifier values do not propagate to instances. There is no flavor corresponding to `toinstance=False`. `None` means that this information is not available. Note that :term:`DSP0200` has deprecated the presence of qualifier values on CIM instances. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._toinstance @toinstance.setter def toinstance(self, toinstance): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._toinstance = _ensure_bool(toinstance) @property def overridable(self): """ :class:`py:bool`: If `True`, specifies the EnableOverride flavor (the qualifier value is overridable in subclasses); if `False` specifies the DisableOverride flavor (the qualifier value is not overridable in subclasses). `None` means that this information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._overridable @overridable.setter def overridable(self, overridable): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._overridable = _ensure_bool(overridable) @property def translatable(self): """ :class:`py:bool`: If `True`, specifies the Translatable flavor. This flavor specifies that the qualifier is translatable. If `False`, specifies that the qualfier is not translatable. There is no flavor corresponding to `translatable=False`. `None` means that this information is not available. This attribute is settable. For details, see the description of the same-named init parameter of :class:`this class <pywbem.CIMQualifierDeclaration>`. """ return self._translatable @translatable.setter def translatable(self, translatable): """Setter method; for a description see the getter method.""" # pylint: disable=attribute-defined-outside-init self._translatable = _ensure_bool(translatable)
[docs] def __eq__(self, other): """ Equality test function for two :class:`~pywbem.CIMQualifierDeclaration` objects. The equality is based on their public attributes: * `name` * `type` * `value` * `is_array` * `array_size` * `scopes` * `overridable` * `tosubclass` * `toinstance` * `translatable` The equality test takes into account any case insensitivities described for these attributes. Raises :exc:`TypeError`, if the `other` object is not a :class:`~pywbem.CIMQualifierDeclaration` object. """ if self is other: return True if not isinstance(other, CIMQualifierDeclaration): raise TypeError( _format("other must be CIMQualifierDeclaration, but is: {0}", type(other))) return (_eq_name(self.name, other.name) and _eq_item(self.type, other.type) and _eq_item(self.value, other.value) and _eq_item(self.is_array, other.is_array) and _eq_item(self.array_size, other.array_size) and _eq_dict(self.scopes, other.scopes) and _eq_item(self.overridable, other.overridable) and _eq_item(self.tosubclass, other.tosubclass) and _eq_item(self.toinstance, other.toinstance) and _eq_item(self.translatable, other.translatable))
[docs] def __hash__(self): """ Return a hash value based on the public attributes of this class, taking into account any case insensitivities described for these attributes. This approach causes this class to be :term:`unchanged-hashable`. """ hashes = ( _hash_name(self.name), _hash_item(self.type), _hash_item(self.value), _hash_item(self.is_array), _hash_item(self.array_size), _hash_dict(self.scopes), _hash_item(self.overridable), _hash_item(self.tosubclass), _hash_item(self.toinstance), _hash_item(self.translatable), ) return hash(hashes)
[docs] def __str__(self): """ Return a short string representation of this CIM qualifier type, for human consumption. """ return _format( "CIMQualifierDeclaration(" "name={s.name!A}, " "value={s.value!A}, " "type={s.type!A}, " "is_array={s.is_array!A}, ...)", s=self)
[docs] def __repr__(self): """ Return a string representation of this CIM qualifier type, that is suitable for debugging. The scopes will be ordered by their names in the result. """ return _format( "CIMQualifierDeclaration(" "name={s.name!A}, " "value={s.value!A}, " "type={s.type!A}, " "is_array={s.is_array!A}, " "array_size={s.array_size!A}, " "scopes={s.scopes!A}, " "tosubclass={s.tosubclass!A}, " "overridable={s.overridable!A}, " "translatable={s.translatable!A}, " "toinstance={s.toinstance!A})", s=self)
[docs] def copy(self): """ Return a new :class:`~pywbem.CIMQualifierDeclaration` object that is a copy of this CIM qualifier type. Objects of this class have no mutable types in any attributes, so modifications of the original object will not affect the returned copy, and vice versa. Note that the Python functions :func:`py:copy.copy` and :func:`py:copy.deepcopy` can be used to create completely shallow or completely deep copies of objects of this class. """ return CIMQualifierDeclaration( self.name, self.type, value=self.value, is_array=self.is_array, array_size=self.array_size, scopes=self.scopes, # setter copies overridable=self.overridable, tosubclass=self.tosubclass, toinstance=self.toinstance, translatable=self.translatable)
[docs] def tocimxml(self): """ Return the CIM-XML representation of this CIM qualifier type, as an object of an appropriate subclass of :term:`Element`. The returned CIM-XML representation is a `QUALIFIER.DECLARATION` element consistent with :term:`DSP0201`. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. """ if self.value is None: value_xml = None elif isinstance(self.value, (tuple, list)): array_xml = [] for v in self.value: if v is None: if SEND_VALUE_NULL: array_xml.append(_cim_xml.VALUE_NULL()) else: array_xml.append(_cim_xml.VALUE(None)) else: array_xml.append(_cim_xml.VALUE(atomic_to_cim_xml(v))) value_xml = _cim_xml.VALUE_ARRAY(array_xml) else: value_xml = _cim_xml.VALUE(atomic_to_cim_xml(self.value)) return _cim_xml.QUALIFIER_DECLARATION( self.name, self.type, value_xml, is_array=self.is_array, array_size=self.array_size, qualifier_scopes=self.scopes, overridable=self.overridable, tosubclass=self.tosubclass, toinstance=self.toinstance, translatable=self.translatable)
[docs] def tocimxmlstr(self, indent=None): """ Return the CIM-XML representation of this CIM qualifier type, as a :term:`unicode string`. *New in pywbem 0.9.* For the returned CIM-XML representation, see :meth:`~pywbem.CIMQualifierDeclaration.tocimxml`. Parameters: indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. Returns: The CIM-XML representation of the object, as a :term:`unicode string`. """ xml_elem = self.tocimxml() return tocimxmlstr(xml_elem, indent)
[docs] def tomof(self, maxline=MAX_MOF_LINE): """ Return a MOF string with the declaration of this CIM qualifier type. The returned MOF string conforms to the ``qualifierDeclaration`` ABNF rule defined in :term:`DSP0004`. Qualifier flavors are included in the returned MOF string only when the information is available (i.e. the value of the corresponding attribute is not `None`). Because :term:`DSP0004` does not support instance qualifiers, and thus does not define a flavor keyword for the :attr:`~pywbem.CIMQualifierDeclaration.toinstance` attribute, that flavor is not included in the returned MOF string. Returns: :term:`unicode string`: MOF string. """ mof = [] mof.append(u'Qualifier ') mof.append(self.name) mof.append(u' : ') mof.append(self.type) if self.is_array: mof.append(u'[') if self.array_size is not None: mof.append(six.text_type(self.array_size)) mof.append(u']') if self.value is not None: mof.append(u' = ') if isinstance(self.value, list): mof.append(u'{ ') mof_str = u''.join(mof) line_pos = len(mof_str) - mof_str.rfind('\n') - 1 val_str, line_pos = _value_tomof( self.value, self.type, MOF_INDENT, maxline, line_pos, 3, False) mof.append(val_str) if isinstance(self.value, list): mof.append(u' }') mof.append(u',\n') mof.append(_indent_str(MOF_INDENT + 1)) mof.append(u'Scope(') mof_scopes = [] for scope in self._ordered_scopes: if self.scopes.get(scope, False): mof_scopes.append(scope.lower()) mof.append(u', '.join(mof_scopes)) mof.append(u')') # toinstance flavor not included here because not part of DSP0004 mof_flavors = [] if self.overridable is True: mof_flavors.append('EnableOverride') elif self.overridable is False: mof_flavors.append('DisableOverride') if self.tosubclass is True: mof_flavors.append('ToSubclass') elif self.tosubclass is False: mof_flavors.append('Restricted') if self.translatable: mof_flavors.append('Translatable') if mof_flavors: mof.append(u',\n') mof.append(_indent_str(MOF_INDENT + 1)) mof.append(u'Flavor(') mof.append(u', '.join(mof_flavors)) mof.append(u')') mof.append(u';\n') return u''.join(mof)
[docs]def tocimxml(value): # pylint: disable=line-too-long """ Return the CIM-XML representation of the input object, as an object of an appropriate subclass of :term:`Element`. The returned CIM-XML representation is consistent with :term:`DSP0201`. Parameters: value (:term:`CIM object`, :term:`CIM data type`, :term:`number`, :class:`py:datetime.datetime`, or tuple/list thereof): The input object. Must not be `None`. Returns: The CIM-XML representation, as an object of an appropriate subclass of :term:`Element`. Raises: ValueError: Invalid input value. """ # noqa: E501 if value is None: raise ValueError("The value parameter must not be None") if isinstance(value, (tuple, list)): array_xml = [] for v in value: if v is None: if SEND_VALUE_NULL: array_xml.append(_cim_xml.VALUE_NULL()) else: array_xml.append(_cim_xml.VALUE(None)) else: array_xml.append(_cim_xml.VALUE(atomic_to_cim_xml(v))) value_xml = _cim_xml.VALUE_ARRAY(array_xml) return value_xml if hasattr(value, 'tocimxml'): return value.tocimxml() return _cim_xml.VALUE(atomic_to_cim_xml(value))
[docs]def tocimxmlstr(value, indent=None): """ Return the CIM-XML representation of the CIM object or CIM data type, as a :term:`unicode string`. *New in pywbem 0.9.* The returned CIM-XML representation is consistent with :term:`DSP0201`. Parameters: value (:term:`CIM object` or :term:`CIM data type` or :term:`Element`): The CIM object or CIM data type to be converted to CIM-XML, or an :term:`Element` object that already is the CIM-XML representation. indent (:term:`string` or :term:`integer`): `None` indicates that a single-line version of the XML should be returned, without any whitespace between the XML elements. Other values indicate that a prettified, multi-line version of the XML should be returned. A string value specifies the indentation string to be used for each level of nested XML elements. An integer value specifies an indentation string of so many blanks. Returns: The CIM-XML representation of the value, as a :term:`unicode string`. """ if isinstance(value, Element): xml_elem = value else: xml_elem = tocimxml(value) if indent is None: xml_str = xml_elem.toxml() else: if isinstance(indent, six.string_types): pass # use indent, as specified elif isinstance(indent, six.integer_types): indent = ' ' * indent else: raise TypeError( _format("Type of indent must be string or integer, but is: {0}", type(indent))) xml_str = xml_elem.toprettyxml(indent=indent) # xml_str is a unicode string if required based upon its content. return _ensure_unicode(xml_str)
[docs]def cimvalue(value, type): # pylint: disable=redefined-builtin """ Return a :term:`CIM data type` representing the specified value in the specified CIM type. *New in pywbem 0.12.* This function guarantees that the returned object is a valid :term:`CIM data type`. If the input parameters are not sufficient to construct a CIM data type, an exception is raised. If the provided value is already a CIM data type (or `None`), the input value is returned. Otherwise, the value is converted to a CIM data type as described below. If the provided value is a list, a new list is returned with this function being invoked recursively on the items of the input list. Embedded objects and embedded instances are not handled by this function. Parameters: `type` (:term:`string`): The CIM data type name for the CIM object. See :ref:`CIM data types` for valid type names. If `value` is a list, `type` must specify the CIM data type name of an item in the list. value (:term:`CIM data type` and other suitable types): The value to be represented as a CIM object. If `None`, the returned object will be `None`. The following other suitable types are supported (in addition to the respective :term:`CIM data type`): * If `type` is ``'string'`` or ``'char16'``: - Objects of type :term:`byte string`; they will be converted to :term:`unicode string`. * If `type` specifies one of the CIM integer data types (e.g. ``'uint8'``): - Any object supported as an init parameter for :class:`py:int` or :class:`py2:long` (Python 2 only). This includes :term:`string` values with decimal integer numbers. If the value is not supported, `ValueError` will be raised. * If `type` specifies one of the CIM float data types (e.g. ``'real32'``): - Any object supported as an init parameter for :class:`py:float`. This includes :term:`string` values with decimal integer or float numbers. If the value is not supported, `ValueError` will be raised. * If `type` is ``'boolean'``: - Any object. The value is converted to bool using the standard Python truth testing procedure. * If `type` is ``'datetime'``: - Any object supported as an init parameter for :class:`~pywbem.CIMDateTime` . * If `type` is ``'reference'``: - :term:`string`. The string must be an untyped WBEM URI representing an instance path (see :term:`DSP0207`). - :class:`~pywbem.CIMInstanceName`. An instance path. - :class:`~pywbem.CIMClassName`. A class path. Returns: A :term:`CIM data type` object, representing the specified value and type. Raises: ValueError: An input parameter has an invalid value. TypeError: An input parameter has an invalid Python type. """ if value is None: return None if type is None: # The following may raise TypeError or ValueError. This ensures that # Python number typed values cannot be provided without specifing # their CIM type. type = cimtype(value) # Arrays if isinstance(value, list): return [cimvalue(v, type) for v in value] # Boolean type if type == 'boolean': return bool(value) # String and char16 types if type in ('string', 'char16'): return _ensure_unicode(value) # REF type if type == 'reference': if isinstance(value, (CIMInstanceName, CIMClassName)): return value if isinstance(value, six.string_types): return CIMInstanceName.from_wbem_uri(value) raise TypeError( _format("Input value has invalid type for a CIM reference: {0!A}", value)) # Other types (integers, floats, datetime) type_obj = type_from_name(type) # Raises ValueError if invalid type if isinstance(value, type_obj): return value return type_obj(value)
def _partition(str_arg, sep): """ _partition(str_arg, sep) -> (head, sep, tail) Searches for the first occurrence of the separator sep in str_arg, and returns the, part before it, the separator itself, and the part after it. If the separator is not found, returns str_arg and two empty strings. """ try: return str_arg.partition(sep) except AttributeError: try: idx = str_arg.index(sep) except ValueError: return (str_arg, '', '') return (str_arg[:idx], sep, str_arg[idx + len(sep):]) def _infer_type(value, element_kind, element_name): """ Infer the CIM type name of the value, based upon its Python type. """ if value is None: raise ValueError( _format("Cannot infer CIM type of {0} {1!A} from its value when " "the value is None", element_kind, element_name)) try: return cimtype(value) except TypeError as exc: raise ValueError( _format("Cannot infer CIM type of {0} {1!A} from its value: {2!A}", element_kind, element_name, exc)) def _infer_is_array(value): """ Infer whether the value is an array, based upon its Python type. A value of None defaults to be considered a scalar. """ if value is None: return False return isinstance(value, list) def _check_array_parms(is_array, array_size, value, element_kind, element_name): # pylint: disable=unused-argument # The array_size argument is unused. """ Check whether array-related parameters are ok. """ # The following case has been disabled because it cannot happen given # how this check function is used: # if array_size and is_array is False: # raise ValueError( # _format("The array_size parameter of {0} {1!A} is {2!A} but the " # "is_array parameter is False.", # element_kind, element_name, array_size)) if value is not None: value_is_array = isinstance(value, (list, tuple)) if not is_array and value_is_array: raise ValueError( _format("The is_array parameter of {0} {1!A} is False but " "value {2!A} is an array.", element_kind, element_name, value)) if is_array and not value_is_array: raise ValueError( _format("The is_array parameter of {0} {1!A} is True but " "value {2!A} is not an array.", element_kind, element_name, value)) def _infer_embedded_object(value): """ Infer CIMProperty/CIMParameter.embedded_object from the CIM value. """ if value is None: # The default behavior is to assume that a value of None is not # an embedded object. If the user wants that, they must specify # the embedded_object parameter. return False if isinstance(value, list): if not value: # The default behavior is to assume that an empty array value # is not an embedded object. If the user wants that, they must # specify the embedded_object parameter. return False value = value[0] if isinstance(value, CIMInstance): # The default behavior is to produce 'instance', although 'object' # would also be valid. return 'instance' if isinstance(value, CIMClass): return 'object' return False def _check_embedded_object(embedded_object, type, value, element_kind, element_name): # pylint: disable=redefined-builtin """ Check whether embedded-object-related parameters are ok. """ if embedded_object not in ('instance', 'object'): raise ValueError( _format("{0} {1!A} specifies an invalid value for " "embedded_object: {2!A} (must be 'instance' or 'object')", element_kind, element_name, embedded_object)) if type != 'string': raise ValueError( _format("{0} {1!A} specifies embedded_object {2!A} but its CIM " "type is invalid: {3!A} (must be 'string')", element_kind, element_name, embedded_object, type)) if value is not None: if isinstance(value, list): if value: v0 = value[0] # Check the first array element if v0 is not None and \ not isinstance(v0, (CIMInstance, CIMClass)): raise ValueError( _format("Array {0} {1!A} specifies embedded_object " "{2!A} but the Python type of its first array " "value is invalid: {3} (must be CIMInstance " "or CIMClass)", element_kind, element_name, embedded_object, builtin_type(v0))) else: if not isinstance(value, (CIMInstance, CIMClass)): raise ValueError( _format("{0} {1!A} specifies embedded_object {2!A} but " "the Python type of its value is invalid: {3} " "(must be CIMInstance or CIMClass)", element_kind, element_name, embedded_object, builtin_type(value)))