Commit 840ae3d6 authored by Tim Peters's avatar Tim Peters

Prepare to fetch Zope3 code from the same place Zope trunk gets it.

parent bf836026
Metadata-Version: 1.0
Name: zope.interface
Summary: Zope 3 Interface Infrastructure
Author: Zope Corporation and Contributors
Author-email: zope3-dev@zope.org
License: ZPL 2.1
Description:
The implementation of interface definitions for Zope 3.
==========
Interfaces
==========
.. contents::
Interfaces are objects that specify (document) the external behavior
of objects that "provide" them. An interface specifies behavior
through:
- Informal documentation in a doc string
- Attribute definitions
- Invariants, which are conditions that must hold for objects that
provide the interface
Attribute definitions specify specific attributes. They define the
attribute name and provide documentation and constraints of attribute
values. Attribute definitions can take a number of forms, as we'll
see below.
Defining interfaces
===================
Interfaces are defined using Python class statements:
>>> import zope.interface
>>> class IFoo(zope.interface.Interface):
... """Foo blah blah"""
...
... x = zope.interface.Attribute("""X blah blah""")
...
... def bar(q, r=None):
... """bar blah blah"""
In the example above, we've created an interface, `IFoo`. We
subclassed `zope.interface.Interface`, which is an ancestor interface for
all interfaces, much as `object` is an ancestor of all new-style
classes [#create]_. The interface is not a class, it's an Interface,
an instance of `InterfaceClass`::
>>> type(IFoo)
<class 'zope.interface.interface.InterfaceClass'>
We can ask for the interface's documentation::
>>> IFoo.__doc__
'Foo blah blah'
and its name::
>>> IFoo.__name__
'IFoo'
and even its module::
>>> IFoo.__module__
'__main__'
The interface defined two attributes:
`x`
This is the simplest form of attribute definition. It has a name
and a doc string. It doesn't formally specify anything else.
`bar`
This is a method. A method is defined via a function definition. A
method is simply an attribute constrained to be a callable with a
particular signature, as provided by the function definition.
Note that `bar` doesn't take a `self` argument. Interfaces document
how an object is *used*. When calling instance methods, you don't
pass a `self` argument, so a `self` argument isn't included in the
interface signature. The `self` argument in instance methods is
really an implementation detail of Python instances. Other objects,
besides instances can provide interfaces and their methods might not
be instance methods. For example, modules can provide interfaces and
their methods are usually just functions. Even instances can have
methods that are not instance methods.
You can access the attributes defined by an interface using mapping
syntax::
>>> x = IFoo['x']
>>> type(x)
<class 'zope.interface.interface.Attribute'>
>>> x.__name__
'x'
>>> x.__doc__
'X blah blah'
>>> IFoo.get('x').__name__
'x'
>>> IFoo.get('y')
You can use `in` to determine if an interface defines a name::
>>> 'x' in IFoo
True
You can iterate over interfaces to get the names they define::
>>> names = list(IFoo)
>>> names.sort()
>>> names
['bar', 'x']
Remember that interfaces aren't classes. You can't access attribute
definitions as attributes of interfaces::
>>> IFoo.x
Traceback (most recent call last):
File "<stdin>", line 1, in ?
AttributeError: 'InterfaceClass' object has no attribute 'x'
Methods provide access to the method signature::
>>> bar = IFoo['bar']
>>> bar.getSignatureString()
'(q, r=None)'
TODO
Methods really should have a better API. This is something that
needs to be improved.
Declaring interfaces
====================
Having defined interfaces, we can *declare* that objects provide
them. Before we describe the details, lets define some some terms:
*provide*
We say that objects *provide* interfaces. If an object provides an
interface, then the interface specifies the behavior of the
object. In other words, interfaces specify the behavior of the
objects that provide them.
*implement*
We normally say that classes *implement* interfaces. If a class
implements an interface, then the instances of the class provide
the interface. Objects provide interfaces that their classes
implement [#factory]_. (Objects can provide interfaces directly,
in addition to what their classes implement.)
It is important to note that classes don't usually provide the
interfaces that the implement.
We can generalize this to factories. For any callable object we
can declare that it produces objects that provides some interfaces
by saying that the factory implements the interfaces.
Now that we've defined these terms, we can talk about the API for
declaring interfaces.
Declaring implemented interfaces
--------------------------------
The most common way to declare interfaces is using the implements
function in a class statement::
>>> class Foo:
... zope.interface.implements(IFoo)
...
... def __init__(self, x=None):
... self.x = x
...
... def bar(self, q, r=None):
... return q, r, self.x
...
... def __repr__(self):
... return "Foo(%s)" % self.x
In this example, we declared that `Foo` implements `IFoo`. This means
that instances of `Foo` provide `IFoo`. Having made this declaration,
there are several ways we can introspect the declarations. First, we
can ask an interface whether it is implemented by a class::
>>> IFoo.implementedBy(Foo)
True
And we can ask whether an interface is provided by an object::
>>> foo = Foo()
>>> IFoo.providedBy(foo)
True
Of course, `Foo` doesn't provide `IFoo`, it implements it::
>>> IFoo.providedBy(Foo)
False
We can also ask what interfaces are implemented by an object::
>>> list(zope.interface.implementedBy(Foo))
[<InterfaceClass __main__.IFoo>]
It's an error to ask for interfaces implemented by a non-callable
object::
>>> IFoo.implementedBy(foo)
Traceback (most recent call last):
...
TypeError: ('ImplementedBy called for non-factory', Foo(None))
>>> list(zope.interface.implementedBy(foo))
Traceback (most recent call last):
...
TypeError: ('ImplementedBy called for non-factory', Foo(None))
Similarly, we can ask what interfaces are provided by an object::
>>> list(zope.interface.providedBy(foo))
[<InterfaceClass __main__.IFoo>]
>>> list(zope.interface.providedBy(Foo))
[]
We can declare interfaces implemented by other factories (besides
classes). We do this using a Python-2.4-style decorator named
`implementer`. In versions of Python before 2.4, this looks like:
>>> def yfoo(y):
... foo = Foo()
... foo.y = y
... return foo
>>> yfoo = zope.interface.implementer(IFoo)(yfoo)
>>> list(zope.interface.implementedBy(yfoo))
[<InterfaceClass __main__.IFoo>]
Note that the implementer decorator may modify it's argument. Callers
should not assume that a new object is created.
Also note that, at least for now, implementer cannt be used with
classes:
>>> zope.interface.implementer(IFoo)(Foo)
... # doctest: +NORMALIZE_WHITESPACE
Traceback (most recent call last):
...
TypeError: Can't use implementer with classes.
Use one of the class-declaration functions instead.
Declaring provided interfaces
-----------------------------
We can declare interfaces directly provided by objects. Suppose that
we want to document what the `__init__` method of the `Foo` class
does. It's not *really* part of `IFoo`. You wouldn't normally call
the `__init__` method on Foo instances. Rather, the `__init__` method
is part of the `Foo`'s `__call__` method::
>>> class IFooFactory(zope.interface.Interface):
... """Create foos"""
...
... def __call__(x=None):
... """Create a foo
...
... The argument provides the initial value for x ...
... """
It's the class that provides this interface, so we declare the
interface on the class::
>>> zope.interface.directlyProvides(Foo, IFooFactory)
And then, we'll see that Foo provides some interfaces::
>>> list(zope.interface.providedBy(Foo))
[<InterfaceClass __main__.IFooFactory>]
>>> IFooFactory.providedBy(Foo)
True
Declaring class interfaces is common enough that there's a special
declaration function for it, `classProvides`, that allows the
declaration from within a class statement::
>>> class Foo2:
... zope.interface.implements(IFoo)
... zope.interface.classProvides(IFooFactory)
...
... def __init__(self, x=None):
... self.x = x
...
... def bar(self, q, r=None):
... return q, r, self.x
...
... def __repr__(self):
... return "Foo(%s)" % self.x
>>> list(zope.interface.providedBy(Foo2))
[<InterfaceClass __main__.IFooFactory>]
>>> IFooFactory.providedBy(Foo2)
True
There's a similar function, `moduleProvides`, that supports interface
declarations from within module definitions. For example, see the use
of `moduleProvides` call in `zope.interface.__init__`, which declares that
the package `zope.interface` provides `IInterfaceDeclaration`.
Sometimes, we want to declare interfaces on instances, even though
those instances get interfaces from their classes. Suppose we create
a new interface, `ISpecial`::
>>> class ISpecial(zope.interface.Interface):
... reason = zope.interface.Attribute("Reason why we're special")
... def brag():
... "Brag about being special"
We can make a an existing foo instance special by providing `reason`
and `brag` attributes::
>>> foo.reason = 'I just am'
>>> def brag():
... return "I'm special!"
>>> foo.brag = brag
>>> foo.reason
'I just am'
>>> foo.brag()
"I'm special!"
and by declaring the interface::
>>> zope.interface.directlyProvides(foo, ISpecial)
then the new interface is included in the provided interfaces::
>>> ISpecial.providedBy(foo)
True
>>> list(zope.interface.providedBy(foo))
[<InterfaceClass __main__.ISpecial>, <InterfaceClass __main__.IFoo>]
We can find out what interfaces are directly provided by an object::
>>> list(zope.interface.directlyProvidedBy(foo))
[<InterfaceClass __main__.ISpecial>]
>>> newfoo = Foo()
>>> list(zope.interface.directlyProvidedBy(newfoo))
[]
Inherited declarations
----------------------
Normally, declarations are inherited::
>>> class SpecialFoo(Foo):
... zope.interface.implements(ISpecial)
... reason = 'I just am'
... def brag(self):
... return "I'm special because %s" % self.reason
>>> list(zope.interface.implementedBy(SpecialFoo))
[<InterfaceClass __main__.ISpecial>, <InterfaceClass __main__.IFoo>]
>>> list(zope.interface.providedBy(SpecialFoo()))
[<InterfaceClass __main__.ISpecial>, <InterfaceClass __main__.IFoo>]
Sometimes, you don't want to inherit declarations. In that case, you
can use `implementsOnly`, instead of `implements`::
>>> class Special(Foo):
... zope.interface.implementsOnly(ISpecial)
... reason = 'I just am'
... def brag(self):
... return "I'm special because %s" % self.reason
>>> list(zope.interface.implementedBy(Special))
[<InterfaceClass __main__.ISpecial>]
>>> list(zope.interface.providedBy(Special()))
[<InterfaceClass __main__.ISpecial>]
External declarations
---------------------
Normally, we make implementation declarations as part of a class
definition. Sometimes, we may want to make declarations from outside
the class definition. For example, we might want to declare interfaces
for classes that we didn't write. The function `classImplements` can
be used for this purpose::
>>> class C:
... pass
>>> zope.interface.classImplements(C, IFoo)
>>> list(zope.interface.implementedBy(C))
[<InterfaceClass __main__.IFoo>]
We can use `classImplementsOnly` to exclude inherited interfaces::
>>> class C(Foo):
... pass
>>> zope.interface.classImplementsOnly(C, ISpecial)
>>> list(zope.interface.implementedBy(C))
[<InterfaceClass __main__.ISpecial>]
Declaration Objects
-------------------
When we declare interfaces, we create *declaration* objects. When we
query declarations, declaration objects are returned::
>>> type(zope.interface.implementedBy(Special))
<class 'zope.interface.declarations.Implements'>
Declaration objects and interface objects are similar in many ways. In
fact, they share a common base class. The important thing to realize
about them is that they can be used where interfaces are expected in
declarations. Here's a silly example::
>>> class Special2(Foo):
... zope.interface.implementsOnly(
... zope.interface.implementedBy(Foo),
... ISpecial,
... )
... reason = 'I just am'
... def brag(self):
... return "I'm special because %s" % self.reason
The declaration here is almost the same as
``zope.interface.implements(ISpecial)``, except that the order of
interfaces in the resulting declaration is different::
>>> list(zope.interface.implementedBy(Special2))
[<InterfaceClass __main__.IFoo>, <InterfaceClass __main__.ISpecial>]
Interface Inheritance
=====================
Interfaces can extend other interfaces. They do this simply by listing
the other interfaces as base interfaces::
>>> class IBlat(zope.interface.Interface):
... """Blat blah blah"""
...
... y = zope.interface.Attribute("y blah blah")
... def eek():
... """eek blah blah"""
>>> IBlat.__bases__
(<InterfaceClass zope.interface.Interface>,)
>>> class IBaz(IFoo, IBlat):
... """Baz blah"""
... def eek(a=1):
... """eek in baz blah"""
...
>>> IBaz.__bases__
(<InterfaceClass __main__.IFoo>, <InterfaceClass __main__.IBlat>)
>>> names = list(IBaz)
>>> names.sort()
>>> names
['bar', 'eek', 'x', 'y']
Note that `IBaz` overrides eek::
>>> IBlat['eek'].__doc__
'eek blah blah'
>>> IBaz['eek'].__doc__
'eek in baz blah'
We were careful to override eek in a compatible way. When an
extending an interface, the extending interface should be compatible
[#compat]_ with the extended interfaces.
We can ask whether one interface extends another::
>>> IBaz.extends(IFoo)
True
>>> IBlat.extends(IFoo)
False
Note that interfaces don't extend themselves::
>>> IBaz.extends(IBaz)
False
Sometimes we wish they did, but we can, instead use `isOrExtends`::
>>> IBaz.isOrExtends(IBaz)
True
>>> IBaz.isOrExtends(IFoo)
True
>>> IFoo.isOrExtends(IBaz)
False
When we iterate over an interface, we get all of the names it defines,
including names defined by base interfaces. Sometimes, we want *just*
the names defined by the interface directly. We bane use the `names`
method for that::
>>> list(IBaz.names())
['eek']
Inheritance if attribute specifications
---------------------------------------
An interface may override attribute definitions frob base interfaces.
If two base interfaces define the same attribute, the attribute is
inherited from the most specific interface. For example, with:
>>> class IBase(zope.interface.Interface):
...
... def foo():
... "base foo doc"
>>> class IBase1(IBase):
... pass
>>> class IBase2(IBase):
...
... def foo():
... "base2 foo doc"
>>> class ISub(IBase1, IBase2):
... pass
ISub's definition of foo is the one from IBase2, since IBase2 is more
specific that IBase:
>>> ISub['foo'].__doc__
'base2 foo doc'
Note that this differs from a depth-first search.
Sometimes, it's useful to ask whether an interface defines an
attribute directly. You can use the direct method to get a directly
defined definitions:
>>> IBase.direct('foo').__doc__
'base foo doc'
>>> ISub.direct('foo')
Specifications
--------------
Interfaces and declarations are both special cases of specifications.
What we described above for interface inheritence applies to both
declarations and specifications. Declarations actually extend the
interfaces that they declare:
>>> class Baz:
... zope.interface.implements(IBaz)
>>> baz_implements = zope.interface.implementedBy(Baz)
>>> baz_implements.__bases__
(<InterfaceClass __main__.IBaz>,)
>>> baz_implements.extends(IFoo)
True
>>> baz_implements.isOrExtends(IFoo)
True
>>> baz_implements.isOrExtends(baz_implements)
True
Specifications (interfaces and declarations) provide an `__sro__`
that lists the specification and all of it's ancestors:
>>> baz_implements.__sro__
(<implementedBy __main__.Baz>,
<InterfaceClass __main__.IBaz>,
<InterfaceClass __main__.IFoo>,
<InterfaceClass __main__.IBlat>,
<InterfaceClass zope.interface.Interface>)
Tagged Values
=============
Interfaces and attribute descriptions support an extension mechanism,
borrowed from UML, called "tagged values" that lets us store extra
data::
>>> IFoo.setTaggedValue('date-modified', '2004-04-01')
>>> IFoo.setTaggedValue('author', 'Jim Fulton')
>>> IFoo.getTaggedValue('date-modified')
'2004-04-01'
>>> IFoo.queryTaggedValue('date-modified')
'2004-04-01'
>>> IFoo.queryTaggedValue('datemodified')
>>> tags = list(IFoo.getTaggedValueTags())
>>> tags.sort()
>>> tags
['author', 'date-modified']
Function attributes are converted to tagged values when method
attribute definitions are created::
>>> class IBazFactory(zope.interface.Interface):
... def __call__():
... "create one"
... __call__.return_type = IBaz
>>> IBazFactory['__call__'].getTaggedValue('return_type')
<InterfaceClass __main__.IBaz>
Invariants
==========
Interfaces can express conditions that must hold for objects that
provide them. These conditions are expressed using one or more
invariants. Invariants are callable objects that will be called with
an object that provides an interface. An invariant raises an `Invalid`
exception if the condition doesn't hold. Here's an example::
>>> class RangeError(zope.interface.Invalid):
... """A range has invalid limits"""
... def __repr__(self):
... return "RangeError(%r)" % self.args
>>> def range_invariant(ob):
... if ob.max < ob.min:
... raise RangeError(ob)
Given this invariant, we can use it in an interface definition::
>>> class IRange(zope.interface.Interface):
... min = zope.interface.Attribute("Lower bound")
... max = zope.interface.Attribute("Upper bound")
...
... zope.interface.invariant(range_invariant)
Interfaces have a method for checking their invariants::
>>> class Range(object):
... zope.interface.implements(IRange)
...
... def __init__(self, min, max):
... self.min, self.max = min, max
...
... def __repr__(self):
... return "Range(%s, %s)" % (self.min, self.max)
>>> IRange.validateInvariants(Range(1,2))
>>> IRange.validateInvariants(Range(1,1))
>>> IRange.validateInvariants(Range(2,1))
Traceback (most recent call last):
...
RangeError: Range(2, 1)
If you have multiple invariants, you may not want to stop checking
after the first error. If you pass a list to `validateInvariants`,
then a single `Invalid` exception will be raised with the list of
exceptions as it's argument::
>>> errors = []
>>> IRange.validateInvariants(Range(2,1), errors)
Traceback (most recent call last):
...
Invalid: [RangeError(Range(2, 1))]
And the list will be filled with the individual exceptions::
>>> errors
[RangeError(Range(2, 1))]
.. [#create] The main reason we subclass `Interface` is to cause the
Python class statement to create an interface, rather
than a class.
It's possible to create interfaces by calling a special
interface class directly. Doing this, it's possible
(and, on rare occasions, useful) to create interfaces
that don't descend from `Interface`. Using this
technique is beyond the scope of this document.
.. [#factory] Classes are factories. They can be called to create
their instances. We expect that we will eventually
extend the concept of implementation to other kinds of
factories, so that we can declare the interfaces
provided by the objects created.
.. [#compat] The goal is substitutability. An object that provides an
extending interface should be substitutable for an object
that provides the extended interface. In our example, an
object that provides IBaz should be usable whereever an
object that provides IBlat is expected.
The interface implementation doesn't enforce this. XXX
but maybe it should do some checks.
# Extension information for zpkg:
<extension _zope_interface_coptimizations>
source _zope_interface_coptimizations.c
</extension>
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Interfaces
This package implements the Python "scarecrow" proposal.
The package exports two objects, `Interface` and `Attribute` directly. It also
exports several helper methods. Interface is used to create an interface with
a class statement, as in:
class IMyInterface(Interface):
'''Interface documentation
'''
def meth(arg1, arg2):
'''Documentation for meth
'''
# Note that there is no self argument
To find out what you can do with interfaces, see the interface
interface, `IInterface` in the `interfaces` module.
The package has several public modules:
o `declarations` provides utilities to declare interfaces on objects. It
also provides a wide range of helpful utilities that aid in managing
declared interfaces. Most of its public names are however imported here.
o `document` has a utility for documenting an interface as structured text.
o `exceptions` has the interface-defined exceptions
o `interfaces` contains a list of all public interfaces for this package.
o `verify` has utilities for verifying implementations of interfaces.
See the module doc strings for more information.
$Id$
"""
__docformat__ = 'restructuredtext'
from zope.interface.interface import Interface, _wire
# Need to actually get the interface elements to implement the right interfaces
_wire()
del _wire
from zope.interface.interface import Attribute, invariant
from zope.interface.declarations import providedBy, implementedBy
from zope.interface.declarations import classImplements, classImplementsOnly
from zope.interface.declarations import directlyProvidedBy, directlyProvides
from zope.interface.declarations import alsoProvides, implementer
from zope.interface.declarations import implements, implementsOnly
from zope.interface.declarations import classProvides, moduleProvides
from zope.interface.declarations import Declaration
from zope.interface.exceptions import Invalid
# The following are to make spec pickles cleaner
from zope.interface.declarations import Provides
from zope.interface.interfaces import IInterfaceDeclaration
moduleProvides(IInterfaceDeclaration)
__all__ = ('Interface', 'Attribute') + tuple(IInterfaceDeclaration)
##############################################################################
#
# Copyright (c) 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Adapter-style interface registry
See Adapter class.
$Id$
"""
from zope.interface import Declaration
def _flatten(implements, include_None=0):
try:
r = implements.flattened()
except AttributeError:
if implements is None:
r=()
else:
r = Declaration(implements).flattened()
if not include_None:
return r
r = list(r)
r.append(None)
return r
/*###########################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
############################################################################*/
#include "Python.h"
#include "structmember.h"
#define TYPE(O) ((PyTypeObject*)(O))
#define OBJECT(O) ((PyObject*)(O))
#define CLASSIC(O) ((PyClassObject*)(O))
static PyObject *str__dict__, *str__implemented__, *strextends;
static PyObject *BuiltinImplementationSpecifications, *str__provides__;
static PyObject *str__class__, *str__providedBy__, *strisOrExtends;
static PyObject *empty, *fallback, *str_implied, *str_cls, *str_implements;
static PyTypeObject *Implements;
static int imported_declarations = 0;
static int
import_declarations(void)
{
PyObject *declarations, *i;
declarations = PyImport_ImportModule("zope.interface.declarations");
if (declarations == NULL)
return -1;
BuiltinImplementationSpecifications = PyObject_GetAttrString(
declarations, "BuiltinImplementationSpecifications");
if (BuiltinImplementationSpecifications == NULL)
return -1;
empty = PyObject_GetAttrString(declarations, "_empty");
if (empty == NULL)
return -1;
fallback = PyObject_GetAttrString(declarations, "implementedByFallback");
if (fallback == NULL)
return -1;
i = PyObject_GetAttrString(declarations, "Implements");
if (i == NULL)
return -1;
if (! PyType_Check(i))
{
PyErr_SetString(PyExc_TypeError,
"zope.declarations.Implements is not a type");
return -1;
}
Implements = (PyTypeObject *)i;
Py_DECREF(declarations);
imported_declarations = 1;
return 0;
}
static PyTypeObject SpecType; /* Forward */
static PyObject *
implementedByFallback(PyObject *cls)
{
if (imported_declarations == 0 && import_declarations() < 0)
return NULL;
return PyObject_CallFunctionObjArgs(fallback, cls, NULL);
}
static PyObject *
implementedBy(PyObject *ignored, PyObject *cls)
{
/* Fast retrieval of implements spec, if possible, to optimize
common case. Use fallback code if we get stuck.
*/
PyObject *dict = NULL, *spec;
if (PyType_Check(cls))
{
dict = TYPE(cls)->tp_dict;
Py_XINCREF(dict);
}
if (dict == NULL)
dict = PyObject_GetAttr(cls, str__dict__);
if (dict == NULL)
{
/* Probably a security proxied class, use more expensive fallback code */
PyErr_Clear();
return implementedByFallback(cls);
}
spec = PyObject_GetItem(dict, str__implemented__);
Py_DECREF(dict);
if (spec)
{
if (imported_declarations == 0 && import_declarations() < 0)
return NULL;
if (PyObject_TypeCheck(spec, Implements))
return spec;
/* Old-style declaration, use more expensive fallback code */
Py_DECREF(spec);
return implementedByFallback(cls);
}
PyErr_Clear();
/* Maybe we have a builtin */
if (imported_declarations == 0 && import_declarations() < 0)
return NULL;
spec = PyDict_GetItem(BuiltinImplementationSpecifications, cls);
if (spec != NULL)
{
Py_INCREF(spec);
return spec;
}
/* We're stuck, use fallback */
return implementedByFallback(cls);
}
static PyObject *
getObjectSpecification(PyObject *ignored, PyObject *ob)
{
PyObject *cls, *result;
result = PyObject_GetAttr(ob, str__provides__);
if (result != NULL)
return result;
PyErr_Clear();
/* We do a getattr here so as not to be defeated by proxies */
cls = PyObject_GetAttr(ob, str__class__);
if (cls == NULL)
{
PyErr_Clear();
if (imported_declarations == 0 && import_declarations() < 0)
return NULL;
Py_INCREF(empty);
return empty;
}
result = implementedBy(NULL, cls);
Py_DECREF(cls);
return result;
}
static PyObject *
providedBy(PyObject *ignored, PyObject *ob)
{
PyObject *result, *cls, *cp;
result = PyObject_GetAttr(ob, str__providedBy__);
if (result == NULL)
{
PyErr_Clear();
return getObjectSpecification(NULL, ob);
}
/* We want to make sure we have a spec. We can't do a type check
because we may have a proxy, so we'll just try to get the
only attribute.
*/
if (PyObject_HasAttr(result, strextends))
return result;
/*
The object's class doesn't understand descriptors.
Sigh. We need to get an object descriptor, but we have to be
careful. We want to use the instance's __provides__,l if
there is one, but only if it didn't come from the class.
*/
Py_DECREF(result);
cls = PyObject_GetAttr(ob, str__class__);
if (cls == NULL)
return NULL;
result = PyObject_GetAttr(ob, str__provides__);
if (result == NULL)
{
/* No __provides__, so just fall back to implementedBy */
PyErr_Clear();
result = implementedBy(NULL, cls);
Py_DECREF(cls);
return result;
}
cp = PyObject_GetAttr(cls, str__provides__);
if (cp == NULL)
{
/* The the class has no provides, assume we're done: */
PyErr_Clear();
Py_DECREF(cls);
return result;
}
if (cp == result)
{
/*
Oops, we got the provides from the class. This means
the object doesn't have it's own. We should use implementedBy
*/
Py_DECREF(result);
result = implementedBy(NULL, cls);
}
Py_DECREF(cls);
Py_DECREF(cp);
return result;
}
static PyObject *
inst_attr(PyObject *self, PyObject *name)
{
/* Get an attribute from an inst dict. Return a borrowed reference.
*/
PyObject **dictp, *v;
dictp = _PyObject_GetDictPtr(self);
if (dictp && *dictp && (v = PyDict_GetItem(*dictp, name)))
return v;
PyErr_SetObject(PyExc_AttributeError, name);
return NULL;
}
static PyObject *
Spec_extends(PyObject *self, PyObject *other)
{
PyObject *implied;
implied = inst_attr(self, str_implied);
if (implied == NULL)
return NULL;
#ifdef Py_True
if (PyDict_GetItem(implied, other) != NULL)
{
Py_INCREF(Py_True);
return Py_True;
}
Py_INCREF(Py_False);
return Py_False;
#else
return PyInt_FromLong(PyDict_GetItem(implied, other) != NULL);
#endif
}
static char Spec_extends__doc__[] =
"Test whether a specification is or extends another"
;
static char Spec_providedBy__doc__[] =
"Test whether an interface is implemented by the specification"
;
static PyObject *
Spec_providedBy(PyObject *self, PyObject *ob)
{
PyObject *decl, *item;
decl = providedBy(NULL, ob);
if (decl == NULL)
return NULL;
if (PyObject_TypeCheck(ob, &SpecType))
item = Spec_extends(decl, self);
else
/* decl is probably a security proxy. We have to go the long way
around.
*/
item = PyObject_CallMethodObjArgs(decl, strisOrExtends, self, NULL);
Py_DECREF(decl);
return item;
}
static char Spec_implementedBy__doc__[] =
"Test whether the specification is implemented by instances of a class"
;
static PyObject *
Spec_implementedBy(PyObject *self, PyObject *cls)
{
PyObject *decl, *item;
decl = implementedBy(NULL, cls);
if (decl == NULL)
return NULL;
if (PyObject_TypeCheck(decl, &SpecType))
item = Spec_extends(decl, self);
else
item = PyObject_CallMethodObjArgs(decl, strisOrExtends, self, NULL);
Py_DECREF(decl);
return item;
}
static struct PyMethodDef Spec_methods[] = {
{"providedBy",
(PyCFunction)Spec_providedBy, METH_O,
Spec_providedBy__doc__},
{"implementedBy",
(PyCFunction)Spec_implementedBy, METH_O,
Spec_implementedBy__doc__},
{"isOrExtends", (PyCFunction)Spec_extends, METH_O,
Spec_extends__doc__},
{NULL, NULL} /* sentinel */
};
static PyTypeObject SpecType = {
PyObject_HEAD_INIT(NULL)
/* ob_size */ 0,
/* tp_name */ "_interface_coptimizations."
"SpecificationBase",
/* tp_basicsize */ 0,
/* tp_itemsize */ 0,
/* tp_dealloc */ (destructor)0,
/* tp_print */ (printfunc)0,
/* tp_getattr */ (getattrfunc)0,
/* tp_setattr */ (setattrfunc)0,
/* tp_compare */ (cmpfunc)0,
/* tp_repr */ (reprfunc)0,
/* tp_as_number */ 0,
/* tp_as_sequence */ 0,
/* tp_as_mapping */ 0,
/* tp_hash */ (hashfunc)0,
/* tp_call */ (ternaryfunc)0,
/* tp_str */ (reprfunc)0,
/* tp_getattro */ (getattrofunc)0,
/* tp_setattro */ (setattrofunc)0,
/* tp_as_buffer */ 0,
/* tp_flags */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE,
"Base type for Specification objects",
/* tp_traverse */ (traverseproc)0,
/* tp_clear */ (inquiry)0,
/* tp_richcompare */ (richcmpfunc)0,
/* tp_weaklistoffset */ (long)0,
/* tp_iter */ (getiterfunc)0,
/* tp_iternext */ (iternextfunc)0,
/* tp_methods */ Spec_methods,
};
static PyObject *
OSD_descr_get(PyObject *self, PyObject *inst, PyObject *cls)
{
PyObject *provides;
if (inst == NULL)
return getObjectSpecification(NULL, cls);
provides = PyObject_GetAttr(inst, str__provides__);
if (provides != NULL)
return provides;
PyErr_Clear();
return implementedBy(NULL, cls);
}
static PyTypeObject OSDType = {
PyObject_HEAD_INIT(NULL)
/* ob_size */ 0,
/* tp_name */ "_interface_coptimizations."
"ObjectSpecificationDescriptor",
/* tp_basicsize */ 0,
/* tp_itemsize */ 0,
/* tp_dealloc */ (destructor)0,
/* tp_print */ (printfunc)0,
/* tp_getattr */ (getattrfunc)0,
/* tp_setattr */ (setattrfunc)0,
/* tp_compare */ (cmpfunc)0,
/* tp_repr */ (reprfunc)0,
/* tp_as_number */ 0,
/* tp_as_sequence */ 0,
/* tp_as_mapping */ 0,
/* tp_hash */ (hashfunc)0,
/* tp_call */ (ternaryfunc)0,
/* tp_str */ (reprfunc)0,
/* tp_getattro */ (getattrofunc)0,
/* tp_setattro */ (setattrofunc)0,
/* tp_as_buffer */ 0,
/* tp_flags */ Py_TPFLAGS_DEFAULT
| Py_TPFLAGS_BASETYPE ,
"Object Specification Descriptor",
/* tp_traverse */ (traverseproc)0,
/* tp_clear */ (inquiry)0,
/* tp_richcompare */ (richcmpfunc)0,
/* tp_weaklistoffset */ (long)0,
/* tp_iter */ (getiterfunc)0,
/* tp_iternext */ (iternextfunc)0,
/* tp_methods */ 0,
/* tp_members */ 0,
/* tp_getset */ 0,
/* tp_base */ 0,
/* tp_dict */ 0, /* internal use */
/* tp_descr_get */ (descrgetfunc)OSD_descr_get,
};
static PyObject *
CPB_descr_get(PyObject *self, PyObject *inst, PyObject *cls)
{
PyObject *mycls, *implements;
mycls = inst_attr(self, str_cls);
if (mycls == NULL)
return NULL;
if (cls == mycls)
{
if (inst == NULL)
{
Py_INCREF(self);
return OBJECT(self);
}
implements = inst_attr(self, str_implements);
Py_XINCREF(implements);
return implements;
}
PyErr_SetObject(PyExc_AttributeError, str__provides__);
return NULL;
}
static PyTypeObject CPBType = {
PyObject_HEAD_INIT(NULL)
/* ob_size */ 0,
/* tp_name */ "_interface_coptimizations."
"ClassProvidesBase",
/* tp_basicsize */ 0,
/* tp_itemsize */ 0,
/* tp_dealloc */ (destructor)0,
/* tp_print */ (printfunc)0,
/* tp_getattr */ (getattrfunc)0,
/* tp_setattr */ (setattrfunc)0,
/* tp_compare */ (cmpfunc)0,
/* tp_repr */ (reprfunc)0,
/* tp_as_number */ 0,
/* tp_as_sequence */ 0,
/* tp_as_mapping */ 0,
/* tp_hash */ (hashfunc)0,
/* tp_call */ (ternaryfunc)0,
/* tp_str */ (reprfunc)0,
/* tp_getattro */ (getattrofunc)0,
/* tp_setattro */ (setattrofunc)0,
/* tp_as_buffer */ 0,
/* tp_flags */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE,
"C Base class for ClassProvides",
/* tp_traverse */ (traverseproc)0,
/* tp_clear */ (inquiry)0,
/* tp_richcompare */ (richcmpfunc)0,
/* tp_weaklistoffset */ (long)0,
/* tp_iter */ (getiterfunc)0,
/* tp_iternext */ (iternextfunc)0,
/* tp_methods */ 0,
/* tp_members */ 0,
/* tp_getset */ 0,
/* tp_base */ &SpecType,
/* tp_dict */ 0, /* internal use */
/* tp_descr_get */ (descrgetfunc)CPB_descr_get,
};
static struct PyMethodDef m_methods[] = {
{"implementedBy", (PyCFunction)implementedBy, METH_O,
"Interfaces implemented by instances of a class"},
{"getObjectSpecification", (PyCFunction)getObjectSpecification, METH_O,
"Get an object's interfaces (internal api)"},
{"providedBy", (PyCFunction)providedBy, METH_O,
"Get an object's interfaces"},
{NULL, (PyCFunction)NULL, 0, NULL} /* sentinel */
};
#ifndef PyMODINIT_FUNC /* declarations for DLL import/export */
#define PyMODINIT_FUNC void
#endif
PyMODINIT_FUNC
init_zope_interface_coptimizations(void)
{
PyObject *m;
#define DEFINE_STRING(S) \
if(! (str ## S = PyString_FromString(# S))) return
DEFINE_STRING(__dict__);
DEFINE_STRING(__implemented__);
DEFINE_STRING(__provides__);
DEFINE_STRING(__class__);
DEFINE_STRING(__providedBy__);
DEFINE_STRING(isOrExtends);
DEFINE_STRING(extends);
DEFINE_STRING(_implied);
DEFINE_STRING(_implements);
DEFINE_STRING(_cls);
#undef DEFINE_STRING
/* Initialize types: */
SpecType.tp_new = PyBaseObject_Type.tp_new;
if (PyType_Ready(&SpecType) < 0)
return;
OSDType.tp_new = PyBaseObject_Type.tp_new;
if (PyType_Ready(&OSDType) < 0)
return;
CPBType.tp_new = PyBaseObject_Type.tp_new;
if (PyType_Ready(&CPBType) < 0)
return;
/* Create the module and add the functions */
m = Py_InitModule3("_zope_interface_coptimizations", m_methods,
"C optimizations for zope.interface\n\n"
"$Id$");
if (m == NULL)
return;
/* Add types: */
if (PyModule_AddObject(m, "SpecificationBase", (PyObject *)&SpecType) < 0)
return;
if (PyModule_AddObject(m, "ObjectSpecificationDescriptor",
(PyObject *)&OSDType) < 0)
return;
if (PyModule_AddObject(m, "ClassProvidesBase", (PyObject *)&CPBType) < 0)
return;
}
############################################################################
#
# Copyright (c) 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
############################################################################
"""Adapter-style interface registry
This implementation is based on a notion of "surrogate" interfaces.
$Id$
"""
# Implementation notes
# We keep a collection of surrogates.
# A surrogate is a surrogate for a specification (interface or
# declaration). We use weak references in order to remove surrogates
# if the corresponding specification goes away.
# Each surrogate keeps track of:
# - The adapters registered directly for that surrogate, and
# - The "implied" adapters, which is the adapters that can be computed
# from instances of that surrogate.
# The later data structure takes into account adapters registered for
# specifications that the registered surrogate extends.
# The registrations are of the form:
# {(subscription, with, name, specification) -> factories}
# where:
# 'subscription' is a flag indicating if this registration is for
# subscription adapters.
# 'with' is a tuple of specs that is non-empty only in the case
# of multi-adapters.
# 'name' is a unicode adapter name. Unnamed adapters have an empty
# name.
# 'specification' is the interface being adapted to.
# 'factories' is normally a tuple of factories, but can be anything.
# (See the "raw" option to the query-adapter calls.) For subscription
# adapters, it is a tuple of tuples of factories.
# The implied adapters are held in a single dictionary. The items in the
# dictionary are of several forms:
# For single adapters:
#
# {specification -> {name -> object}
#
# where object is usually a sequence of factories
# For multiple adapters:
#
# {(specification, order) -> {name -> {with -> object}}}
# For single subscription adapters:
#
# {('s', specification) -> tuple([object])}
# For multiple-subscription adapters:
#
# {('s', specification, order) -> {with -> tuple([object])}}
from __future__ import generators
import weakref
from zope.interface.ro import ro
from zope.interface.declarations import providedBy
from zope.interface.interface import InterfaceClass, Interface
Default = InterfaceClass("Default", (), {})
Null = InterfaceClass("Null", (), {})
# 2.2 backwards compatability
try:
enumerate
except NameError:
def enumerate(l):
i = 0
for o in l:
yield i, o
i += 1
try:
basestring
except NameError:
basestring = (str, unicode)
class ReadProperty(object):
def __init__(self, func):
self.func = func
def __get__(self, inst, class_):
if inst is None:
return self
return self.func(inst)
class Surrogate(object):
"""Specification surrogate
A specification surrogate is used to hold adapter registrations on
behalf of a specification.
"""
def __init__(self, spec, registry):
self.spec = spec.weakref()
spec.subscribe(self)
self.adapters = {}
self.dependents = weakref.WeakKeyDictionary()
self.registry = registry
self.__bases__ = [registry.get(base) for base in spec.__bases__]
for base in self.__bases__:
base.subscribe(self)
def dirty(self):
if 'get' in self.__dict__:
# Not already dirty
del self.selfImplied
del self.multImplied
del self.get
for dependent in self.dependents.keys():
dependent.dirty()
def clean(self):
for base in self.__bases__:
base.unsubscribe(self)
self.__bases__ = [self.registry.get(base)
for base in self.spec().__bases__]
for base in self.__bases__:
base.subscribe(self)
self.selfImplied, self.multImplied = adapterImplied(self.adapters)
implied = {}
ancestors = ro(self)
# Collect implied data in reverse order to have more specific data
# override less-specific data.
ancestors.reverse()
for ancestor in ancestors:
for key, v in ancestor.selfImplied.iteritems():
# key is specification or ('s', specification)
subscription = isinstance(key, tuple) and key[0] == 's'
if subscription:
# v is tuple of subs
implied[key] = implied.get(key, ()) + v
else:
oldbyname = implied.get(key)
if not oldbyname:
implied[key] = oldbyname = {}
# v is name -> object
oldbyname.update(v)
for key, v in ancestor.multImplied.iteritems():
# key is (specification, order)
# or ('s', specification, order)
subscription = key[0] == 's'
if subscription:
oldwithobs = implied.get(key)
if not oldwithobs:
oldwithobs = implied[key] = {}
# v is {with -> tuple([object])}
for with, objects in v.iteritems():
oldwithobs[with] = oldwithobs.get(with, ()) + objects
else:
oldbyname = implied.get(key)
if not oldbyname:
implied[key] = oldbyname = {}
# v is {name -> {with -> ?}}
for name, withobs in v.iteritems():
oldwithobs = oldbyname.get(name)
if not oldwithobs:
oldwithobs = oldbyname[name] = {}
# withobs is {with -> object}
oldwithobs.update(withobs)
# Now flatten with mappings to tuples
for key, v in implied.iteritems():
if isinstance(key, tuple):
if key[0] == 's':
# subscriptions
if isinstance(v, dict):
implied[key] = v.items()
else:
byname = v
for name, value in byname.iteritems():
if isinstance(value, dict):
# We have {with -> value}
# convert it to sorted [(with, value]
byname[name] = orderwith(value)
self.get = implied.get
def get(self, key):
"""Get an implied value
This is only called when the surrogate is dirty
"""
self.clean()
return self.__dict__['get'](key)
def selfImplied(self):
"""Return selfImplied when dirty
"""
self.clean()
return self.__dict__['selfImplied']
selfImplied = ReadProperty(selfImplied)
def multiImplied(self):
"""Return _multiImplied when dirty
"""
self.clean()
return self.__dict__['multiImplied']
multiImplied = ReadProperty(multiImplied)
def subscribe(self, dependent):
self.dependents[dependent] = 1
def unsubscribe(self, dependent):
del self.dependents[dependent]
def _adaptTo(self, specification, object, name='', with=()):
if object is None:
try:
del self.adapters[False, tuple(with), name, specification]
except KeyError:
pass
else:
self.adapters[False, tuple(with), name, specification
] = object
self.dirty()
def _subscriptionAdaptTo(self, specification, object, with=()):
if object is None:
raise TypeError, ("Unregistering subscription adapters"
" isn't implemented")
key = (True, tuple(with), '', specification)
self.adapters[key] = self.adapters.get(key, ()) + (object, )
self.dirty()
def changed(self, which=None):
self.dirty()
def __repr__(self):
return '<%s(%s)>' % (self.__class__.__name__, self.spec())
def orderwith(bywith):
# Convert {with -> adapter} to withs, [(with, value)]
# such that there are no i, j, i < j, such that
# withs[j][0] extends withs[i][0].
withs = []
for with, value in bywith.iteritems():
for i, (w, v) in enumerate(withs):
if withextends(with, w):
withs.insert(i, (with, value))
break
else:
withs.append((with, value))
return withs
def withextends(with1, with2):
for spec1, spec2 in zip(with1, with2):
if spec1.extends(spec2):
return True
if spec1 != spec2:
break
return False
class AdapterLookup(object):
# Adapter lookup support
# We have a class here because we want to provide very
# fast lookup support in C and making this part of the adapter
# registry itself would provide problems if someone wanted
# persistent adapter registries, because we want C slots for fast
# lookup that would clash with persistence-supplied slots.
# so this class acts a little bit like a lookup adapter for the adapter
# registry.
def __init__(self, registry, surrogates, _remove):
self._registry = registry
self._surrogateClass = registry._surrogateClass
self._default = registry._default
self._null = registry._null
self._surrogates = surrogates
self._remove = _remove
def lookup(self, required, provided, name='', default=None):
order = len(required)
if order == 1:
# Simple adapter:
s = self.get(required[0])
byname = s.get(provided)
if byname:
value = byname.get(name)
else:
value = None
if value is None:
byname = self._default.get(provided)
if byname:
value = byname.get(name, default)
else:
return default
return value
elif order == 0:
# null adapter
byname = self._null.get(provided)
if byname:
return byname.get(name, default)
else:
return default
# Multi adapter
with = required[1:]
key = provided, order
for surrogate in self.get(required[0]), self._default:
byname = surrogate.get(key)
if not byname:
continue
bywith = byname.get(name)
if not bywith:
continue
# Selecting multi-adapters is not just a matter of matching the
# required interfaces of the adapter to the ones passed. Several
# adapters might match, but we only want the best one. We use a
# ranking algorithm to determine the best match.
# `best` carries the rank and value of the best found adapter.
best = None
for rwith, value in bywith:
# the `rank` describes how well the found adapter matches.
rank = []
for rspec, spec in zip(rwith, with):
if not spec.isOrExtends(rspec):
break # This one is no good
# Determine the rank of this particular specification.
rank.append(list(spec.__sro__).index(rspec))
else:
# If the new rank is better than the best previously
# recorded one, make the new adapter the best one found.
rank = tuple(rank)
if best is None or rank < best[0]:
best = rank, value
# If any match was found, return the best one.
if best:
return best[1]
return default
def lookup1(self, required, provided, name='', default=None):
return self.lookup((required,), provided, name, default)
def adapter_hook(self, interface, object, name='', default=None):
"""Hook function used when calling interfaces.
When called from Interface.__adapt__, only the interface and
object parameters will be passed.
If the factory produces `None`, then the default is returned. This
allows us to prevent adaptation (if desired) and make the factory
decide whether an adapter will be available.
"""
factory = self.lookup1(providedBy(object), interface, name)
if factory is not None:
adapter = factory(object)
if adapter is not None:
return adapter
return default
def queryAdapter(self, object, interface, name='', default=None):
# Note that we rarely call queryAdapter directly
# We usually end up calling adapter_hook
return self.adapter_hook(interface, object, name, default)
def subscriptions(self, required, provided):
if provided is None:
provided = Null
order = len(required)
if order == 1:
# Simple subscriptions:
s = self.get(required[0])
result = s.get(('s', provided))
if result:
result = list(result)
else:
result = []
default = self._default.get(('s', provided))
if default:
result.extend(default)
return result
elif order == 0:
result = self._null.get(('s', provided))
if result:
return list(result)
else:
return []
# Multi
key = 's', provided, order
with = required[1:]
result = []
for surrogate in self.get(required[0]), self._default:
bywith = surrogate.get(key)
if not bywith:
continue
for rwith, values in bywith:
for rspec, spec in zip(rwith, with):
if not spec.isOrExtends(rspec):
break # This one is no good
else:
# we didn't break, so we have a match
result.extend(values)
return result
def queryMultiAdapter(self, objects, interface, name='', default=None):
factory = self.lookup(map(providedBy, objects), interface, name)
if factory is not None:
return factory(*objects)
return default
def subscribers(self, objects, interface):
subscriptions = self.subscriptions(map(providedBy, objects), interface)
return [subscription(*objects) for subscription in subscriptions]
def get(self, declaration):
if declaration is None:
return self._default
ref = declaration.weakref(self._remove)
surrogate = self._surrogates.get(ref)
if surrogate is None:
surrogate = self._surrogateClass(declaration, self._registry)
self._surrogates[ref] = surrogate
return surrogate
class AdapterRegistry(object):
"""Adapter registry
"""
# Implementation note:
# We are like a weakref dict ourselves. We can't use a weakref
# dict because we have to use spec.weakref() rather than
# weakref.ref(spec) to get weak refs to specs.
_surrogateClass = Surrogate
def __init__(self):
default = self._surrogateClass(Default, self)
self._default = default
null = self._surrogateClass(Null, self)
self._null = null
# Create separate lookup object and copy it's methods
surrogates = {Default.weakref(): default, Null.weakref(): null}
def _remove(k):
try:
del surrogates[k]
except KeyError:
pass
lookup = AdapterLookup(self, surrogates, _remove)
for name in ('lookup', 'lookup1', 'queryAdapter', 'get',
'adapter_hook', 'subscriptions',
'queryMultiAdapter', 'subscribers',
):
setattr(self, name, getattr(lookup, name))
def register(self, required, provided, name, value):
if required:
with = []
for iface in required[1:]:
if iface is None:
iface = Interface
with.append(iface)
with = tuple(with)
required = self.get(required[0])
else:
with = ()
required = self._null
if not isinstance(name, basestring):
raise TypeError("The name provided to provideAdapter "
"must be a string or unicode")
required._adaptTo(provided, value, unicode(name), with)
def lookupAll(self, required, provided):
order = len(required)
if order == 1:
# Simple adapter:
s = self.get(required[0])
byname = s.get(provided)
if byname:
for item in byname.iteritems():
yield item
defbyname = self._default.get(provided)
if defbyname:
for name, value in defbyname.iteritems():
if name in byname:
continue
yield name, value
return
elif order == 0:
# null adapter
byname = self._null.get(provided)
if byname:
for item in byname.iteritems():
yield item
return
# Multi adapter
with = required[1:]
key = provided, order
first = ()
for surrogate in self.get(required[0]), self._default:
byname = surrogate.get(key)
if not byname:
continue
for name, bywith in byname.iteritems():
if not bywith or name in first:
continue
# See comments on lookup() above
best = None
for rwith, value in bywith:
# the `rank` describes how well the found adapter matches.
rank = []
for rspec, spec in zip(rwith, with):
if not spec.isOrExtends(rspec):
break # This one is no good
# Determine the rank of this particular specification.
rank.append(list(spec.__sro__).index(rspec))
else:
# If the new rank is better than the best previously
# recorded one, make the new adapter the best one found.
rank = tuple(rank)
if best is None or rank < best[0]:
best = rank, value
# If any match was found, return the best one.
if best:
yield name, best[1]
first = byname
def subscribe(self, required, provided, value):
if required:
required, with = self.get(required[0]), tuple(required[1:])
else:
required = self._null
with = ()
if provided is None:
provided = Null
required._subscriptionAdaptTo(provided, value, with)
def mextends(with, rwith):
if len(with) == len(rwith):
for w, r in zip(with, rwith):
if not w.isOrExtends(r):
break
else:
return True
return False
def adapterImplied(adapters):
implied = {}
multi = {}
# This dictionary is used to catch situations specific adapters
# override less specific adapters.
# Because subscriptions are cumulative, registered doesn't apply.
registered = {}
# Add adapters and interfaces directly implied by same:
for key, value in adapters.iteritems():
# TODO: Backward compatibility
# BBB ? Don't need to handle 3-tuples some day
try:
(subscription, with, name, target) = key
except ValueError:
(with, name, target) = key
subscription = False
if subscription:
if with:
_add_multi_sub_adapter(with, target, multi, value)
else:
_add_named_sub_adapter(target, implied, value)
else:
if with:
_add_multi_adapter(with, name, target, target, multi,
registered, value)
else:
_add_named_adapter(target, target, name, implied,
registered, value)
return implied, multi
def _add_named_adapter(target, provided, name, implied,
registered, value):
ikey = target
rkey = target, name
byname = implied.get(ikey)
if not byname:
byname = implied[ikey] = {}
if (name not in byname
or
(rkey in registered and registered[rkey].extends(provided))
):
registered[rkey] = provided
byname[name] = value
for b in target.__bases__:
_add_named_adapter(b, provided, name, implied,
registered, value)
def _add_multi_adapter(with, name, target, provided, implied,
registered, object):
ikey = target, (len(with) + 1)
byname = implied.get(ikey)
if not byname:
byname = implied[ikey] = {}
bywith = byname.get(name)
if not bywith:
bywith = byname[name] = {}
rkey = ikey, name, with # The full key has all 4
if (with not in bywith
or
(rkey not in registered or registered[rkey].extends(provided))
):
# This is either a new entry or it is an entry for a more
# general interface that is closer provided than what we had
# before
registered[rkey] = provided
bywith[with] = object
for b in target.__bases__:
_add_multi_adapter(with, name, b, provided, implied,
registered, object)
def _add_named_sub_adapter(target, implied, objects):
key = ('s', target)
implied[key] = implied.get(key, ()) + objects
for b in target.__bases__:
_add_named_sub_adapter(b, implied, objects)
def _add_multi_sub_adapter(with, target, implied, objects):
key = 's', target, (len(with) + 1)
bywith = implied.get(key)
if not bywith:
bywith = implied[key] = {}
bywith[with] = bywith.get(with, ()) + objects
for b in target.__bases__:
_add_multi_sub_adapter(with, b, implied, objects)
================
Adapter Registry
================
Adapter registries provide a way to register objects that depend on
one or more interface specifications and provide (perhaps indirectly)
some interface. In addition, the registrations have names. (You can
think of the names as qualifiers of the provided interfaces.)
The term "interface specification" refers both to interfaces and to
interface declarations, such as declarations of interfaces implemented
by a class.
Single Adapters
===============
Let's look at a simple example, using a single required specification::
>>> from zope.interface.adapter import AdapterRegistry
>>> import zope.interface
>>> class IR1(zope.interface.Interface):
... pass
>>> class IP1(zope.interface.Interface):
... pass
>>> class IP2(IP1):
... pass
>>> registry = AdapterRegistry()
We'll register an object that depends on IR1 and "provides" IP2::
>>> registry.register([IR1], IP2, '', 12)
Given the registration, we can look it up again::
>>> registry.lookup([IR1], IP2, '')
12
Note that we used an integer in the example. In real applications,
one would use some objects that actually depend on or provide
interfaces. The registry doesn't care about what gets registered, so
we'll use integers and strings to keep the examples simple. There is
one exception. Registering a value of None unregisters any
previously-registered value.
If an object depends on a specification, it can be looked up with a
specification that extends the specification that it depends on::
>>> class IR2(IR1):
... pass
>>> registry.lookup([IR2], IP2, '')
12
We can use a class implementation specification to look up the object::
>>> class C2:
... zope.interface.implements(IR2)
>>> registry.lookup([zope.interface.implementedBy(C2)], IP2, '')
12
and it can be looked up for interfaces that its provided interface
extends::
>>> registry.lookup([IR1], IP1, '')
12
>>> registry.lookup([IR2], IP1, '')
12
But if you require a specification that doesn't extend the specification the
object depends on, you won't get anything::
>>> registry.lookup([zope.interface.Interface], IP1, '')
By the way, you can pass a default value to lookup::
>>> registry.lookup([zope.interface.Interface], IP1, '', 42)
42
If you try to get an interface the object doesn't provide, you also
won't get anything::
>>> class IP3(IP2):
... pass
>>> registry.lookup([IR1], IP3, '')
You also won't get anything if you use the wrong name::
>>> registry.lookup([IR1], IP1, 'bob')
>>> registry.register([IR1], IP2, 'bob', "Bob's 12")
>>> registry.lookup([IR1], IP1, 'bob')
"Bob's 12"
You can leave the name off when doing a lookup::
>>> registry.lookup([IR1], IP1)
12
If we register an object that provides IP1::
>>> registry.register([IR1], IP1, '', 11)
then that object will be prefered over O(12)::
>>> registry.lookup([IR1], IP1, '')
11
Also, if we register an object for IR2, then that will be prefered
when using IR2::
>>> registry.register([IR2], IP1, '', 21)
>>> registry.lookup([IR2], IP1, '')
21
lookup1
-------
Lookup of single adapters is common enough that there is a specialized
version of lookup that takes a single required interface::
>>> registry.lookup1(IR2, IP1, '')
21
>>> registry.lookup1(IR2, IP1)
21
Actual Adaptation
-----------------
The adapter registry is intended to support adaptation, where one
object that implements an interface is adapted to another object that
supports a different interface. The adapter registry supports the
computation of adapters. In this case, we have to register adapter
factories::
>>> class IR(zope.interface.Interface):
... pass
>>> class X:
... zope.interface.implements(IR)
>>> class Y:
... zope.interface.implements(IP1)
... def __init__(self, context):
... self.context = context
>>> registry.register([IR], IP1, '', Y)
In this case, we registered a class as the factory. Now we can call
`queryAdapter` to get the adapted object::
>>> x = X()
>>> y = registry.queryAdapter(x, IP1)
>>> y.__class__.__name__
'Y'
>>> y.context is x
True
We can register and lookup by name too::
>>> class Y2(Y):
... pass
>>> registry.register([IR], IP1, 'bob', Y2)
>>> y = registry.queryAdapter(x, IP1, 'bob')
>>> y.__class__.__name__
'Y2'
>>> y.context is x
True
When the adapter factory produces `None`, then this is treated as if no
adapter has been found. This allows us to prevent adaptation (when desired)
and let the adapter factory determine whether adaptation is possible based on
the state of the object being adapted.
>>> def factory(context):
... if context.name == 'object':
... return 'adapter'
... return None
>>> class Object(object):
... zope.interface.implements(IR)
... name = 'object'
>>> registry.register([IR], IP1, 'conditional', factory)
>>> obj = Object()
>>> registry.queryAdapter(obj, IP1, 'conditional')
'adapter'
>>> obj.name = 'no object'
>>> registry.queryAdapter(obj, IP1, 'conditional') is None
True
>>> registry.queryAdapter(obj, IP1, 'conditional', 'default')
'default'
An alternate method that provides the same function as `queryAdapter()` is
`adapter_hook()`::
>>> y = registry.adapter_hook(IP1, x)
>>> y.__class__.__name__
'Y'
>>> y.context is x
True
>>> y = registry.adapter_hook(IP1, x, 'bob')
>>> y.__class__.__name__
'Y2'
>>> y.context is x
True
The `adapter_hook()` simply switches the order of the object and
interface arguments. It is used to hook into the interface call
mechanism.
Default Adapters
----------------
Sometimes, you want to provide an adapter that will adapt anything.
For that, provide None as the required interface::
>>> registry.register([None], IP1, '', 1)
then we can use that adapter for interfaces we don't have specific
adapters for::
>>> class IQ(zope.interface.Interface):
... pass
>>> registry.lookup([IQ], IP1, '')
1
Of course, specific adapters are still used when applicable::
>>> registry.lookup([IR2], IP1, '')
21
Class adapters
--------------
You can register adapters for class declarations, which is almost the
same as registering them for a class::
>>> registry.register([zope.interface.implementedBy(C2)], IP1, '', 'C21')
>>> registry.lookup([zope.interface.implementedBy(C2)], IP1, '')
'C21'
Dict adapters
-------------
At some point it was impossible to register dictionary-based adapters due a
bug. Let's make sure this works now:
>>> adapter = {}
>>> registry.register((), IQ, '', adapter)
>>> registry.lookup((), IQ, '') is adapter
True
Unregistering
-------------
You can unregister by registering None, rather than an object::
>>> registry.register([zope.interface.implementedBy(C2)], IP1, '', None)
>>> registry.lookup([zope.interface.implementedBy(C2)], IP1, '')
21
Of course, this means that None can't be registered. This is an
exception to the statement, made earlier, that the registry doesn't
care what gets registered.
Multi-adapters
==============
You can adapt multiple specifications::
>>> registry.register([IR1, IQ], IP2, '', '1q2')
>>> registry.lookup([IR1, IQ], IP2, '')
'1q2'
>>> registry.lookup([IR2, IQ], IP1, '')
'1q2'
>>> class IS(zope.interface.Interface):
... pass
>>> registry.lookup([IR2, IS], IP1, '')
>>> class IQ2(IQ):
... pass
>>> registry.lookup([IR2, IQ2], IP1, '')
'1q2'
>>> registry.register([IR1, IQ2], IP2, '', '1q22')
>>> registry.lookup([IR2, IQ2], IP1, '')
'1q22'
Multi-adaptation
----------------
You can adapt multiple objects::
>>> class Q:
... zope.interface.implements(IQ)
As with single adapters, we register a factory, which is often a class::
>>> class IM(zope.interface.Interface):
... pass
>>> class M:
... zope.interface.implements(IM)
... def __init__(self, x, q):
... self.x, self.q = x, q
>>> registry.register([IR, IQ], IM, '', M)
And then we can call `queryMultiAdapter` to compute an adapter::
>>> q = Q()
>>> m = registry.queryMultiAdapter((x, q), IM)
>>> m.__class__.__name__
'M'
>>> m.x is x and m.q is q
True
and, of course, we can use names::
>>> class M2(M):
... pass
>>> registry.register([IR, IQ], IM, 'bob', M2)
>>> m = registry.queryMultiAdapter((x, q), IM, 'bob')
>>> m.__class__.__name__
'M2'
>>> m.x is x and m.q is q
True
Default Adapters
----------------
As with single adapters, you can define default adapters by specifying
None for the *first* specification::
>>> registry.register([None, IQ], IP2, '', 'q2')
>>> registry.lookup([IS, IQ], IP2, '')
'q2'
Null Adapters
=============
You can also adapt no specification::
>>> registry.register([], IP2, '', 2)
>>> registry.lookup([], IP2, '')
2
>>> registry.lookup([], IP1, '')
2
Listing named adapters
----------------------
Adapters are named. Sometimes, it's useful to get all of the named
adapters for given interfaces::
>>> adapters = list(registry.lookupAll([IR1], IP1))
>>> adapters.sort()
>>> adapters
[(u'', 11), (u'bob', "Bob's 12")]
This works for multi-adapters too::
>>> registry.register([IR1, IQ2], IP2, 'bob', '1q2 for bob')
>>> adapters = list(registry.lookupAll([IR2, IQ2], IP1))
>>> adapters.sort()
>>> adapters
[(u'', '1q22'), (u'bob', '1q2 for bob')]
And even null adapters::
>>> registry.register([], IP2, 'bob', 3)
>>> adapters = list(registry.lookupAll([], IP1))
>>> adapters.sort()
>>> adapters
[(u'', 2), (u'bob', 3)]
Subscriptions
=============
Normally, we want to look up an object that most-closely matches a
specification. Sometimes, we want to get all of the objects that
match some specification. We use subscriptions for this. We
subscribe objects against specifications and then later find all of
the subscribed objects::
>>> registry.subscribe([IR1], IP2, 'sub12 1')
>>> registry.subscriptions([IR1], IP2)
['sub12 1']
Note that, unlike regular adapters, subscriptions are unnamed.
The order of returned subscriptions is not specified.
You can have multiple subscribers for the same specification::
>>> registry.subscribe([IR1], IP2, 'sub12 2')
>>> subs = registry.subscriptions([IR1], IP2)
>>> subs.sort()
>>> subs
['sub12 1', 'sub12 2']
You can register subscribers for all specifications using None::
>>> registry.subscribe([None], IP1, 'sub_1')
>>> subs = registry.subscriptions([IR2], IP1)
>>> subs.sort()
>>> subs
['sub12 1', 'sub12 2', 'sub_1']
Subscriptions may be combined over multiple compatible specifications::
>>> subs = registry.subscriptions([IR2], IP1)
>>> subs.sort()
>>> subs
['sub12 1', 'sub12 2', 'sub_1']
>>> registry.subscribe([IR1], IP1, 'sub11')
>>> subs = registry.subscriptions([IR2], IP1)
>>> subs.sort()
>>> subs
['sub11', 'sub12 1', 'sub12 2', 'sub_1']
>>> registry.subscribe([IR2], IP2, 'sub22')
>>> subs = registry.subscriptions([IR2], IP1)
>>> subs.sort()
>>> subs
['sub11', 'sub12 1', 'sub12 2', 'sub22', 'sub_1']
>>> subs = registry.subscriptions([IR2], IP2)
>>> subs.sort()
>>> subs
['sub12 1', 'sub12 2', 'sub22']
Subscriptions can be on multiple specifications::
>>> registry.subscribe([IR1, IQ], IP2, 'sub1q2')
>>> registry.subscriptions([IR1, IQ], IP2)
['sub1q2']
As with single subscriptions and non-subscription adapters, you can
specify None for the first required interface, to specify a default::
>>> registry.subscribe([None, IQ], IP2, 'sub_q2')
>>> registry.subscriptions([IS, IQ], IP2)
['sub_q2']
>>> subs = registry.subscriptions([IR1, IQ], IP2)
>>> subs.sort()
>>> subs
['sub1q2', 'sub_q2']
You can have subscriptions that are indepenent of any specifications::
>>> registry.subscriptions([], IP1)
[]
>>> registry.subscribe([], IP2, 'sub2')
>>> registry.subscriptions([], IP1)
['sub2']
>>> registry.subscribe([], IP1, 'sub1')
>>> subs = registry.subscriptions([], IP1)
>>> subs.sort()
>>> subs
['sub1', 'sub2']
>>> registry.subscriptions([], IP2)
['sub2']
Subscription adapters
---------------------
We normally register adapter factories, which then allow us to compute
adapters, but with subscriptions, we get multiple adapters. Here's an
example of multiple-object subscribers::
>>> registry.subscribe([IR, IQ], IM, M)
>>> registry.subscribe([IR, IQ], IM, M2)
>>> subscribers = registry.subscribers((x, q), IM)
>>> len(subscribers)
2
>>> class_names = [s.__class__.__name__ for s in subscribers]
>>> class_names.sort()
>>> class_names
['M', 'M2']
>>> [(s.x is x and s.q is q) for s in subscribers]
[True, True]
Handlers
--------
A handler is a subscriber factory that doesn't produce any normal
output. It returns None. A handler is unlike adapters in that it does
all of its work when the factory is called.
To register a handler, simply provide None as the provided interface::
>>> def handler(event):
... print 'handler', event
>>> registry.subscribe([IR1], None, handler)
>>> registry.subscriptions([IR1], None) == [handler]
True
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Class advice.
This module was adapted from 'protocols.advice', part of the Python
Enterprise Application Kit (PEAK). Please notify the PEAK authors
(pje@telecommunity.com and tsarna@sarna.org) if bugs are found or
Zope-specific changes are required, so that the PEAK version of this module
can be kept in sync.
PEAK is a Python application framework that interoperates with (but does
not require) Zope 3 and Twisted. It provides tools for manipulating UML
models, object-relational persistence, aspect-oriented programming, and more.
Visit the PEAK home page at http://peak.telecommunity.com for more information.
$Id$
"""
from types import ClassType, FunctionType
import sys
def getFrameInfo(frame):
"""Return (kind,module,locals,globals) for a frame
'kind' is one of "exec", "module", "class", "function call", or "unknown".
"""
f_locals = frame.f_locals
f_globals = frame.f_globals
sameNamespace = f_locals is f_globals
hasModule = '__module__' in f_locals
hasName = '__name__' in f_globals
sameName = hasModule and hasName
sameName = sameName and f_globals['__name__']==f_locals['__module__']
module = hasName and sys.modules.get(f_globals['__name__']) or None
namespaceIsModule = module and module.__dict__ is f_globals
if not namespaceIsModule:
# some kind of funky exec
kind = "exec"
elif sameNamespace and not hasModule:
kind = "module"
elif sameName and not sameNamespace:
kind = "class"
elif not sameNamespace:
kind = "function call"
else:
# How can you have f_locals is f_globals, and have '__module__' set?
# This is probably module-level code, but with a '__module__' variable.
kind = "unknown"
return kind, module, f_locals, f_globals
def addClassAdvisor(callback, depth=2):
"""Set up 'callback' to be passed the containing class upon creation
This function is designed to be called by an "advising" function executed
in a class suite. The "advising" function supplies a callback that it
wishes to have executed when the containing class is created. The
callback will be given one argument: the newly created containing class.
The return value of the callback will be used in place of the class, so
the callback should return the input if it does not wish to replace the
class.
The optional 'depth' argument to this function determines the number of
frames between this function and the targeted class suite. 'depth'
defaults to 2, since this skips this function's frame and one calling
function frame. If you use this function from a function called directly
in the class suite, the default will be correct, otherwise you will need
to determine the correct depth yourself.
This function works by installing a special class factory function in
place of the '__metaclass__' of the containing class. Therefore, only
callbacks *after* the last '__metaclass__' assignment in the containing
class will be executed. Be sure that classes using "advising" functions
declare any '__metaclass__' *first*, to ensure all callbacks are run."""
frame = sys._getframe(depth)
kind, module, caller_locals, caller_globals = getFrameInfo(frame)
# This causes a problem when zope interfaces are used from doctest.
# In these cases, kind == "exec".
#
#if kind != "class":
# raise SyntaxError(
# "Advice must be in the body of a class statement"
# )
previousMetaclass = caller_locals.get('__metaclass__')
defaultMetaclass = caller_globals.get('__metaclass__', ClassType)
def advise(name, bases, cdict):
if '__metaclass__' in cdict:
del cdict['__metaclass__']
if previousMetaclass is None:
if bases:
# find best metaclass or use global __metaclass__ if no bases
meta = determineMetaclass(bases)
else:
meta = defaultMetaclass
elif isClassAdvisor(previousMetaclass):
# special case: we can't compute the "true" metaclass here,
# so we need to invoke the previous metaclass and let it
# figure it out for us (and apply its own advice in the process)
meta = previousMetaclass
else:
meta = determineMetaclass(bases, previousMetaclass)
newClass = meta(name,bases,cdict)
# this lets the callback replace the class completely, if it wants to
return callback(newClass)
# introspection data only, not used by inner function
advise.previousMetaclass = previousMetaclass
advise.callback = callback
# install the advisor
caller_locals['__metaclass__'] = advise
def isClassAdvisor(ob):
"""True if 'ob' is a class advisor function"""
return isinstance(ob,FunctionType) and hasattr(ob,'previousMetaclass')
def determineMetaclass(bases, explicit_mc=None):
"""Determine metaclass from 1+ bases and optional explicit __metaclass__"""
meta = [getattr(b,'__class__',type(b)) for b in bases]
if explicit_mc is not None:
# The explicit metaclass needs to be verified for compatibility
# as well, and allowed to resolve the incompatible bases, if any
meta.append(explicit_mc)
if len(meta)==1:
# easy case
return meta[0]
candidates = minimalBases(meta) # minimal set of metaclasses
if not candidates:
# they're all "classic" classes
return ClassType
elif len(candidates)>1:
# We could auto-combine, but for now we won't...
raise TypeError("Incompatible metatypes",bases)
# Just one, return it
return candidates[0]
def minimalBases(classes):
"""Reduce a list of base classes to its ordered minimum equivalent"""
classes = [c for c in classes if c is not ClassType]
candidates = []
for m in classes:
for n in classes:
if issubclass(n,m) and m is not n:
break
else:
# m has no subclasses in 'classes'
if m in candidates:
candidates.remove(m) # ensure that we're later in the list
candidates.append(m)
return candidates
#
# This file is necessary to make this directory a package.
##############################################################################
# Copyright (c) 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
##############################################################################
"""Datetime interfaces.
This module is called idatetime because if it were called datetime the import
of the real datetime would fail.
$Id$
"""
from zope.interface import Interface, Attribute
from zope.interface import classImplements, directlyProvides
from datetime import timedelta, date, datetime, time, tzinfo
class ITimeDeltaClass(Interface):
"""This is the timedelta class interface."""
min = Attribute("The most negative timedelta object")
max = Attribute("The most positive timedelta object")
resolution = Attribute(
"The smallest difference between non-equal timedelta objects")
class ITimeDelta(ITimeDeltaClass):
"""Represent the difference between two datetime objects.
Supported operators:
- add, subtract timedelta
- unary plus, minus, abs
- compare to timedelta
- multiply, divide by int/long
In addition, datetime supports subtraction of two datetime objects
returning a timedelta, and addition or subtraction of a datetime
and a timedelta giving a datetime.
Representation: (days, seconds, microseconds).
"""
days = Attribute("Days between -999999999 and 999999999 inclusive")
seconds = Attribute("Seconds between 0 and 86399 inclusive")
microseconds = Attribute("Microseconds between 0 and 999999 inclusive")
class IDateClass(Interface):
"""This is the date class interface."""
min = Attribute("The earliest representable date")
max = Attribute("The latest representable date")
resolution = Attribute(
"The smallest difference between non-equal date objects")
def today():
"""Return the current local time.
This is equivalent to date.fromtimestamp(time.time())"""
def fromtimestamp(timestamp):
"""Return the local date from a POSIX timestamp (like time.time())
This may raise ValueError, if the timestamp is out of the range of
values supported by the platform C localtime() function. It's common
for this to be restricted to years from 1970 through 2038. Note that
on non-POSIX systems that include leap seconds in their notion of a
timestamp, leap seconds are ignored by fromtimestamp().
"""
def fromordinal(ordinal):
"""Return the date corresponding to the proleptic Gregorian ordinal.
January 1 of year 1 has ordinal 1. ValueError is raised unless
1 <= ordinal <= date.max.toordinal().
For any date d, date.fromordinal(d.toordinal()) == d.
"""
class IDate(IDateClass):
"""Represents a date (year, month and day) in an idealized calendar.
Operators:
__repr__, __str__
__cmp__, __hash__
__add__, __radd__, __sub__ (add/radd only with timedelta arg)
"""
year = Attribute("Between MINYEAR and MAXYEAR inclusive.")
month = Attribute("Between 1 and 12 inclusive")
day = Attribute(
"Between 1 and the number of days in the given month of the given year.")
def replace(year, month, day):
"""Return a date with the same value.
Except for those members given new values by whichever keyword
arguments are specified. For example, if d == date(2002, 12, 31), then
d.replace(day=26) == date(2000, 12, 26).
"""
def timetuple():
"""Return a 9-element tuple of the form returned by time.localtime().
The hours, minutes and seconds are 0, and the DST flag is -1.
d.timetuple() is equivalent to
(d.year, d.month, d.day, 0, 0, 0, d.weekday(), d.toordinal() -
date(d.year, 1, 1).toordinal() + 1, -1)
"""
def toordinal():
"""Return the proleptic Gregorian ordinal of the date
January 1 of year 1 has ordinal 1. For any date object d,
date.fromordinal(d.toordinal()) == d.
"""
def weekday():
"""Return the day of the week as an integer.
Monday is 0 and Sunday is 6. For example,
date(2002, 12, 4).weekday() == 2, a Wednesday.
See also isoweekday().
"""
def isoweekday():
"""Return the day of the week as an integer.
Monday is 1 and Sunday is 7. For example,
date(2002, 12, 4).isoweekday() == 3, a Wednesday.
See also weekday(), isocalendar().
"""
def isocalendar():
"""Return a 3-tuple, (ISO year, ISO week number, ISO weekday).
The ISO calendar is a widely used variant of the Gregorian calendar.
See http://www.phys.uu.nl/~vgent/calendar/isocalendar.htm for a good
explanation.
The ISO year consists of 52 or 53 full weeks, and where a week starts
on a Monday and ends on a Sunday. The first week of an ISO year is the
first (Gregorian) calendar week of a year containing a Thursday. This
is called week number 1, and the ISO year of that Thursday is the same
as its Gregorian year.
For example, 2004 begins on a Thursday, so the first week of ISO year
2004 begins on Monday, 29 Dec 2003 and ends on Sunday, 4 Jan 2004, so
that date(2003, 12, 29).isocalendar() == (2004, 1, 1) and
date(2004, 1, 4).isocalendar() == (2004, 1, 7).
"""
def isoformat():
"""Return a string representing the date in ISO 8601 format.
This is 'YYYY-MM-DD'.
For example, date(2002, 12, 4).isoformat() == '2002-12-04'.
"""
def __str__():
"""For a date d, str(d) is equivalent to d.isoformat()."""
def ctime():
"""Return a string representing the date.
For example date(2002, 12, 4).ctime() == 'Wed Dec 4 00:00:00 2002'.
d.ctime() is equivalent to time.ctime(time.mktime(d.timetuple()))
on platforms where the native C ctime() function
(which time.ctime() invokes, but which date.ctime() does not invoke)
conforms to the C standard.
"""
def strftime(format):
"""Return a string representing the date.
Controlled by an explicit format string. Format codes referring to
hours, minutes or seconds will see 0 values.
"""
class IDateTimeClass(Interface):
"""This is the datetime class interface."""
min = Attribute("The earliest representable datetime")
max = Attribute("The latest representable datetime")
resolution = Attribute(
"The smallest possible difference between non-equal datetime objects")
def today():
"""Return the current local datetime, with tzinfo None.
This is equivalent to datetime.fromtimestamp(time.time()).
See also now(), fromtimestamp().
"""
def now(tz=None):
"""Return the current local date and time.
If optional argument tz is None or not specified, this is like today(),
but, if possible, supplies more precision than can be gotten from going
through a time.time() timestamp (for example, this may be possible on
platforms supplying the C gettimeofday() function).
Else tz must be an instance of a class tzinfo subclass, and the current
date and time are converted to tz's time zone. In this case the result
is equivalent to tz.fromutc(datetime.utcnow().replace(tzinfo=tz)).
See also today(), utcnow().
"""
def utcnow():
"""Return the current UTC date and time, with tzinfo None.
This is like now(), but returns the current UTC date and time, as a
naive datetime object.
See also now().
"""
def fromtimestamp(timestamp, tz=None):
"""Return the local date and time corresponding to the POSIX timestamp.
Same as is returned by time.time(). If optional argument tz is None or
not specified, the timestamp is converted to the platform's local date
and time, and the returned datetime object is naive.
Else tz must be an instance of a class tzinfo subclass, and the
timestamp is converted to tz's time zone. In this case the result is
equivalent to
tz.fromutc(datetime.utcfromtimestamp(timestamp).replace(tzinfo=tz)).
fromtimestamp() may raise ValueError, if the timestamp is out of the
range of values supported by the platform C localtime() or gmtime()
functions. It's common for this to be restricted to years in 1970
through 2038. Note that on non-POSIX systems that include leap seconds
in their notion of a timestamp, leap seconds are ignored by
fromtimestamp(), and then it's possible to have two timestamps
differing by a second that yield identical datetime objects.
See also utcfromtimestamp().
"""
def utcfromtimestamp(timestamp):
"""Return the UTC datetime from the POSIX timestamp with tzinfo None.
This may raise ValueError, if the timestamp is out of the range of
values supported by the platform C gmtime() function. It's common for
this to be restricted to years in 1970 through 2038.
See also fromtimestamp().
"""
def fromordinal(ordinal):
"""Return the datetime from the proleptic Gregorian ordinal.
January 1 of year 1 has ordinal 1. ValueError is raised unless
1 <= ordinal <= datetime.max.toordinal().
The hour, minute, second and microsecond of the result are all 0, and
tzinfo is None.
"""
def combine(date, time):
"""Return a new datetime object.
Its date members are equal to the given date object's, and whose time
and tzinfo members are equal to the given time object's. For any
datetime object d, d == datetime.combine(d.date(), d.timetz()).
If date is a datetime object, its time and tzinfo members are ignored.
"""
class IDateTime(IDate, IDateTimeClass):
"""Object contains all the information from a date object and a time object.
"""
year = Attribute("Year between MINYEAR and MAXYEAR inclusive")
month = Attribute("Month between 1 and 12 inclusive")
day = Attribute(
"Day between 1 and the number of days in the given month of the year")
hour = Attribute("Hour in range(24)")
minute = Attribute("Minute in range(60)")
second = Attribute("Second in range(60)")
microsecond = Attribute("Microsecond in range(1000000)")
tzinfo = Attribute(
"""The object passed as the tzinfo argument to the datetime constructor
or None if none was passed""")
def date():
"""Return date object with same year, month and day."""
def time():
"""Return time object with same hour, minute, second, microsecond.
tzinfo is None. See also method timetz().
"""
def timetz():
"""Return time object with same hour, minute, second, microsecond,
and tzinfo.
See also method time().
"""
def replace(year, month, day, hour, minute, second, microsecond, tzinfo):
"""Return a datetime with the same members, except for those members
given new values by whichever keyword arguments are specified.
Note that tzinfo=None can be specified to create a naive datetime from
an aware datetime with no conversion of date and time members.
"""
def astimezone(tz):
"""Return a datetime object with new tzinfo member tz, adjusting the
date and time members so the result is the same UTC time as self, but
in tz's local time.
tz must be an instance of a tzinfo subclass, and its utcoffset() and
dst() methods must not return None. self must be aware (self.tzinfo
must not be None, and self.utcoffset() must not return None).
If self.tzinfo is tz, self.astimezone(tz) is equal to self: no
adjustment of date or time members is performed. Else the result is
local time in time zone tz, representing the same UTC time as self:
after astz = dt.astimezone(tz), astz - astz.utcoffset()
will usually have the same date and time members as dt - dt.utcoffset().
The discussion of class tzinfo explains the cases at Daylight Saving
Time transition boundaries where this cannot be achieved (an issue only
if tz models both standard and daylight time).
If you merely want to attach a time zone object tz to a datetime dt
without adjustment of date and time members, use dt.replace(tzinfo=tz).
If you merely want to remove the time zone object from an aware
datetime dt without conversion of date and time members, use
dt.replace(tzinfo=None).
Note that the default tzinfo.fromutc() method can be overridden in a
tzinfo subclass to effect the result returned by astimezone().
"""
def utcoffset():
"""Return the timezone offset in minutes east of UTC (negative west of
UTC)."""
def dst():
"""Return 0 if DST is not in effect, or the DST offset (in minutes
eastward) if DST is in effect.
"""
def tzname():
"""Return the timezone name."""
def timetuple():
"""Return a 9-element tuple of the form returned by time.localtime()."""
def utctimetuple():
"""Return UTC time tuple compatilble with time.gmtimr()."""
def toordinal():
"""Return the proleptic Gregorian ordinal of the date.
The same as self.date().toordinal().
"""
def weekday():
"""Return the day of the week as an integer.
Monday is 0 and Sunday is 6. The same as self.date().weekday().
See also isoweekday().
"""
def isoweekday():
"""Return the day of the week as an integer.
Monday is 1 and Sunday is 7. The same as self.date().isoweekday.
See also weekday(), isocalendar().
"""
def isocalendar():
"""Return a 3-tuple, (ISO year, ISO week number, ISO weekday).
The same as self.date().isocalendar().
"""
def isoformat(sep='T'):
"""Return a string representing the date and time in ISO 8601 format.
YYYY-MM-DDTHH:MM:SS.mmmmmm or YYYY-MM-DDTHH:MM:SS if microsecond is 0
If utcoffset() does not return None, a 6-character string is appended,
giving the UTC offset in (signed) hours and minutes:
YYYY-MM-DDTHH:MM:SS.mmmmmm+HH:MM or YYYY-MM-DDTHH:MM:SS+HH:MM
if microsecond is 0.
The optional argument sep (default 'T') is a one-character separator,
placed between the date and time portions of the result.
"""
def __str__():
"""For a datetime instance d, str(d) is equivalent to d.isoformat(' ').
"""
def ctime():
"""Return a string representing the date and time.
datetime(2002, 12, 4, 20, 30, 40).ctime() == 'Wed Dec 4 20:30:40 2002'.
d.ctime() is equivalent to time.ctime(time.mktime(d.timetuple())) on
platforms where the native C ctime() function (which time.ctime()
invokes, but which datetime.ctime() does not invoke) conforms to the
C standard.
"""
def strftime(format):
"""Return a string representing the date and time.
This is controlled by an explicit format string.
"""
class ITimeClass(Interface):
"""This is the time class interface."""
min = Attribute("The earliest representable time")
max = Attribute("The latest representable time")
resolution = Attribute(
"The smallest possible difference between non-equal time objects")
class ITime(ITimeClass):
"""Represent time with time zone.
Operators:
__repr__, __str__
__cmp__, __hash__
"""
hour = Attribute("Hour in range(24)")
minute = Attribute("Minute in range(60)")
second = Attribute("Second in range(60)")
microsecond = Attribute("Microsecond in range(1000000)")
tzinfo = Attribute(
"""The object passed as the tzinfo argument to the time constructor
or None if none was passed.""")
def replace(hour, minute, second, microsecond, tzinfo):
"""Return a time with the same value.
Except for those members given new values by whichever keyword
arguments are specified. Note that tzinfo=None can be specified
to create a naive time from an aware time, without conversion of the
time members.
"""
def isoformat():
"""Return a string representing the time in ISO 8601 format.
That is HH:MM:SS.mmmmmm or, if self.microsecond is 0, HH:MM:SS
If utcoffset() does not return None, a 6-character string is appended,
giving the UTC offset in (signed) hours and minutes:
HH:MM:SS.mmmmmm+HH:MM or, if self.microsecond is 0, HH:MM:SS+HH:MM
"""
def __str__():
"""For a time t, str(t) is equivalent to t.isoformat()."""
def strftime(format):
"""Return a string representing the time.
This is controlled by an explicit format string.
"""
def utcoffset():
"""Return the timezone offset in minutes east of UTC (negative west of
UTC).
If tzinfo is None, returns None, else returns
self.tzinfo.utcoffset(None), and raises an exception if the latter
doesn't return None or a timedelta object representing a whole number
of minutes with magnitude less than one day.
"""
def dst():
"""Return 0 if DST is not in effect, or the DST offset (in minutes
eastward) if DST is in effect.
If tzinfo is None, returns None, else returns self.tzinfo.dst(None),
and raises an exception if the latter doesn't return None, or a
timedelta object representing a whole number of minutes with
magnitude less than one day.
"""
def tzname():
"""Return the timezone name.
If tzinfo is None, returns None, else returns self.tzinfo.tzname(None),
or raises an exception if the latter doesn't return None or a string
object.
"""
class ITZInfo(Interface):
"""Time zone info class.
"""
def utcoffset(dt):
"""Return offset of local time from UTC, in minutes east of UTC.
If local time is west of UTC, this should be negative.
Note that this is intended to be the total offset from UTC;
for example, if a tzinfo object represents both time zone and DST
adjustments, utcoffset() should return their sum. If the UTC offset
isn't known, return None. Else the value returned must be a timedelta
object specifying a whole number of minutes in the range -1439 to 1439
inclusive (1440 = 24*60; the magnitude of the offset must be less
than one day).
"""
def dst(dt):
"""Return the daylight saving time (DST) adjustment, in minutes east
of UTC, or None if DST information isn't known.
"""
def tzname(dt):
"""Return the time zone name corresponding to the datetime object as
a string.
"""
def fromutc(dt):
"""Return an equivalent datetime in self's local time."""
classImplements(timedelta, ITimeDelta)
classImplements(date, IDate)
classImplements(datetime, IDateTime)
classImplements(time, ITime)
classImplements(tzinfo, ITZInfo)
## directlyProvides(timedelta, ITimeDeltaClass)
## directlyProvides(date, IDateClass)
## directlyProvides(datetime, IDateTimeClass)
## directlyProvides(time, ITimeClass)
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Interfaces for standard python exceptions
$Id$
"""
from zope.interface import Interface
from zope.interface import classImplements
class IException(Interface): pass
class IStandardError(IException): pass
class IWarning(IException): pass
class ISyntaxError(IStandardError): pass
class ILookupError(IStandardError): pass
class IValueError(IStandardError): pass
class IRuntimeError(IStandardError): pass
class IArithmeticError(IStandardError): pass
class IAssertionError(IStandardError): pass
class IAttributeError(IStandardError): pass
class IDeprecationWarning(IWarning): pass
class IEOFError(IStandardError): pass
class IEnvironmentError(IStandardError): pass
class IFloatingPointError(IArithmeticError): pass
class IIOError(IEnvironmentError): pass
class IImportError(IStandardError): pass
class IIndentationError(ISyntaxError): pass
class IIndexError(ILookupError): pass
class IKeyError(ILookupError): pass
class IKeyboardInterrupt(IStandardError): pass
class IMemoryError(IStandardError): pass
class INameError(IStandardError): pass
class INotImplementedError(IRuntimeError): pass
class IOSError(IEnvironmentError): pass
class IOverflowError(IArithmeticError): pass
class IOverflowWarning(IWarning): pass
class IReferenceError(IStandardError): pass
class IRuntimeWarning(IWarning): pass
class IStopIteration(IException): pass
class ISyntaxWarning(IWarning): pass
class ISystemError(IStandardError): pass
class ISystemExit(IException): pass
class ITabError(IIndentationError): pass
class ITypeError(IStandardError): pass
class IUnboundLocalError(INameError): pass
class IUnicodeError(IValueError): pass
class IUserWarning(IWarning): pass
class IZeroDivisionError(IArithmeticError): pass
classImplements(ArithmeticError, IArithmeticError)
classImplements(AssertionError, IAssertionError)
classImplements(AttributeError, IAttributeError)
classImplements(DeprecationWarning, IDeprecationWarning)
classImplements(EnvironmentError, IEnvironmentError)
classImplements(EOFError, IEOFError)
classImplements(Exception, IException)
classImplements(FloatingPointError, IFloatingPointError)
classImplements(ImportError, IImportError)
classImplements(IndentationError, IIndentationError)
classImplements(IndexError, IIndexError)
classImplements(IOError, IIOError)
classImplements(KeyboardInterrupt, IKeyboardInterrupt)
classImplements(KeyError, IKeyError)
classImplements(LookupError, ILookupError)
classImplements(MemoryError, IMemoryError)
classImplements(NameError, INameError)
classImplements(NotImplementedError, INotImplementedError)
classImplements(OSError, IOSError)
classImplements(OverflowError, IOverflowError)
classImplements(OverflowWarning, IOverflowWarning)
classImplements(ReferenceError, IReferenceError)
classImplements(RuntimeError, IRuntimeError)
classImplements(RuntimeWarning, IRuntimeWarning)
classImplements(StandardError, IStandardError)
classImplements(StopIteration, IStopIteration)
classImplements(SyntaxError, ISyntaxError)
classImplements(SyntaxWarning, ISyntaxWarning)
classImplements(SystemError, ISystemError)
classImplements(SystemExit, ISystemExit)
classImplements(TabError, ITabError)
classImplements(TypeError, ITypeError)
classImplements(UnboundLocalError, IUnboundLocalError)
classImplements(UnicodeError, IUnicodeError)
classImplements(UserWarning, IUserWarning)
classImplements(ValueError, IValueError)
classImplements(Warning, IWarning)
classImplements(ZeroDivisionError, IZeroDivisionError)
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Mapping Interfaces
$Id$
"""
from zope.interface import Interface
class IItemMapping(Interface):
"""Simplest readable mapping object
"""
def __getitem__(key):
"""Get a value for a key
A KeyError is raised if there is no value for the key.
"""
class IReadMapping(IItemMapping):
"""Basic mapping interface
"""
def get(key, default=None):
"""Get a value for a key
The default is returned if there is no value for the key.
"""
def __contains__(key):
"""Tell if a key exists in the mapping."""
class IWriteMapping(Interface):
"""Mapping methods for changing data"""
def __delitem__(key):
"""Delete a value from the mapping using the key."""
def __setitem__(key, value):
"""Set a new item in the mapping."""
class IEnumerableMapping(IReadMapping):
"""Mapping objects whose items can be enumerated.
"""
def keys():
"""Return the keys of the mapping object.
"""
def __iter__():
"""Return an iterator for the keys of the mapping object.
"""
def values():
"""Return the values of the mapping object.
"""
def items():
"""Return the items of the mapping object.
"""
def __len__():
"""Return the number of items.
"""
class IMapping(IWriteMapping, IEnumerableMapping):
''' Simple mapping interface '''
class IIterableMapping(IEnumerableMapping):
def iterkeys():
"iterate over keys; equivalent to __iter__"
def itervalues():
"iterate over values"
def iteritems():
"iterate over items"
class IClonableMapping(Interface):
def copy():
"return copy of dict"
class IExtendedReadMapping(IIterableMapping):
def has_key(key):
"""Tell if a key exists in the mapping; equivalent to __contains__"""
class IExtendedWriteMapping(IWriteMapping):
def clear():
"delete all items"
def update(d):
" Update D from E: for k in E.keys(): D[k] = E[k]"
def setdefault(key, default=None):
"D.setdefault(k[,d]) -> D.get(k,d), also set D[k]=d if k not in D"
def pop(k, *args):
"""remove specified key and return the corresponding value
*args may contain a single default value, or may not be supplied.
If key is not found, default is returned if given, otherwise
KeyError is raised"""
def popitem():
"""remove and return some (key, value) pair as a
2-tuple; but raise KeyError if mapping is empty"""
class IFullMapping(
IExtendedReadMapping, IExtendedWriteMapping, IClonableMapping, IMapping):
''' Full mapping interface ''' # IMapping included so tests for IMapping
# succeed with IFullMapping
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Sequence Interfaces
$Id$
"""
from zope import interface
class IReadSequence(interface.Interface):
"read interface shared by tuple and list"
def __getitem__(index):
"x.__getitem__(index) <==> x[index]"
def __iter__():
"x.__iter__() <==> iter(x)"
def __contains__(item):
"x.__contains__(item) <==> item in x"
def __lt__(other):
"x.__lt__(other) <==> x<other"
def __le__(other):
"x.__le__(other) <==> x<=other"
def __eq__(other):
"x.__eq__(other) <==> x==other"
def __ne__(other):
"x.__ne__(other) <==> x!=other"
def __gt__(other):
"x.__gt__(other) <==> x>other"
def __ge__(other):
"x.__ge__(other) <==> x>=other"
def __len__():
"x.__len__() <==> len(x)"
def __add__(other):
"x.__add__(other) <==> x+other"
def __mul__(n):
"x.__mul__(n) <==> x*n"
def __rmul__(n):
"x.__rmul__(n) <==> n*x"
def __getslice__(i, j):
"""x.__getslice__(i, j) <==> x[i:j]
Use of negative indices is not supported.
"""
class IExtendedReadSequence(IReadSequence):
"Full read interface for lists"
def count(item):
"return number of occurrences of value"
def index(item, *args):
"""return first index of value
L.index(value, [start, [stop]]) -> integer"""
class IUniqueMemberWriteSequence(interface.Interface):
"The write contract for a sequence that may enforce unique members"
def __setitem__(index, item):
"x.__setitem__(index, item) <==> x[index]=item"
def __delitem__(index):
"x.__delitem__(index) <==> del x[index]"
def __setslice__(i, j, other):
"""x.__setslice__(i, j, other) <==> x[i:j]=other
Use of negative indices is not supported."""
def __delslice__(i, j):
"""x.__delslice__(i, j) <==> del x[i:j]
Use of negative indices is not supported.
"""
def __iadd__(y):
"x.__iadd__(y) <==> x+=y"
def append(item):
"append item to end"
def insert(index, item):
"insert item before index"
def pop(index=-1):
"remove and return item at index (default last)"
def remove(item):
"remove first occurrence of value"
def reverse():
"reverse *IN PLACE*"
def sort(cmpfunc=None):
"""stable sort *IN PLACE*; cmpfunc(x, y) -> -1, 0, 1"""
def extend(iterable):
"extend list by appending elements from the iterable"
class IWriteSequence(IUniqueMemberWriteSequence):
"Full write contract for sequences"
def __imul__(n):
"x.__imul__(n) <==> x*=n"
class ISequence(IReadSequence, IWriteSequence):
"Full sequence contract"
#
# This file is necessary to make this directory a package.
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Base Mapping tests
$Id$
"""
from operator import __getitem__
def testIReadMapping(self, inst, state, absent):
for key in state:
self.assertEqual(inst[key], state[key])
self.assertEqual(inst.get(key, None), state[key])
self.failUnless(key in inst)
for key in absent:
self.assertEqual(inst.get(key, None), None)
self.assertEqual(inst.get(key), None)
self.assertEqual(inst.get(key, self), self)
self.assertRaises(KeyError, __getitem__, inst, key)
def test_keys(self, inst, state):
# Return the keys of the mapping object
inst_keys = list(inst.keys()); inst_keys.sort()
state_keys = list(state.keys()) ; state_keys.sort()
self.assertEqual(inst_keys, state_keys)
def test_iter(self, inst, state):
# Return the keys of the mapping object
inst_keys = list(inst); inst_keys.sort()
state_keys = list(state.keys()) ; state_keys.sort()
self.assertEqual(inst_keys, state_keys)
def test_values(self, inst, state):
# Return the values of the mapping object
inst_values = list(inst.values()); inst_values.sort()
state_values = list(state.values()) ; state_values.sort()
self.assertEqual(inst_values, state_values)
def test_items(self, inst, state):
# Return the items of the mapping object
inst_items = list(inst.items()); inst_items.sort()
state_items = list(state.items()) ; state_items.sort()
self.assertEqual(inst_items, state_items)
def test___len__(self, inst, state):
# Return the number of items
self.assertEqual(len(inst), len(state))
def testIEnumerableMapping(self, inst, state):
test_keys(self, inst, state)
test_items(self, inst, state)
test_values(self, inst, state)
test___len__(self, inst, state)
class BaseTestIReadMapping(object):
def testIReadMapping(self):
inst = self._IReadMapping__sample()
state = self._IReadMapping__stateDict()
absent = self._IReadMapping__absentKeys()
testIReadMapping(self, inst, state, absent)
class BaseTestIEnumerableMapping(BaseTestIReadMapping):
# Mapping objects whose items can be enumerated
def test_keys(self):
# Return the keys of the mapping object
inst = self._IEnumerableMapping__sample()
state = self._IEnumerableMapping__stateDict()
test_keys(self, inst, state)
def test_values(self):
# Return the values of the mapping object
inst = self._IEnumerableMapping__sample()
state = self._IEnumerableMapping__stateDict()
test_values(self, inst, state)
def test_values(self):
# Return the values of the mapping object
inst = self._IEnumerableMapping__sample()
state = self._IEnumerableMapping__stateDict()
test_iter(self, inst, state)
def test_items(self):
# Return the items of the mapping object
inst = self._IEnumerableMapping__sample()
state = self._IEnumerableMapping__stateDict()
test_items(self, inst, state)
def test___len__(self):
# Return the number of items
inst = self._IEnumerableMapping__sample()
state = self._IEnumerableMapping__stateDict()
test___len__(self, inst, state)
def _IReadMapping__stateDict(self):
return self._IEnumerableMapping__stateDict()
def _IReadMapping__sample(self):
return self._IEnumerableMapping__sample()
def _IReadMapping__absentKeys(self):
return self._IEnumerableMapping__absentKeys()
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test for datetime interfaces
$Id$
"""
import unittest
from zope.interface.verify import verifyObject, verifyClass
from zope.interface.common.idatetime import ITimeDelta, ITimeDeltaClass
from zope.interface.common.idatetime import IDate, IDateClass
from zope.interface.common.idatetime import IDateTime, IDateTimeClass
from zope.interface.common.idatetime import ITime, ITimeClass, ITZInfo
from datetime import timedelta, date, datetime, time, tzinfo
class TestDateTimeInterfaces(unittest.TestCase):
def test_interfaces(self):
verifyObject(ITimeDelta, timedelta(minutes=20))
verifyObject(IDate, date(2000, 1, 2))
verifyObject(IDateTime, datetime(2000, 1, 2, 10, 20))
verifyObject(ITime, time(20, 30, 15, 1234))
verifyObject(ITZInfo, tzinfo())
verifyClass(ITimeDeltaClass, timedelta)
verifyClass(IDateClass, date)
verifyClass(IDateTimeClass, datetime)
verifyClass(ITimeClass, time)
def test_suite():
suite = unittest.TestSuite()
suite.addTest(unittest.makeSuite(TestDateTimeInterfaces))
return suite
if __name__ == '__main__':
unittest.main()
##############################################################################
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
##############################################################################
"""Implementation of interface declarations
There are three flavors of declarations:
- Declarations are used to simply name declared interfaces.
- ImplementsDeclarations are used to express the interfaces that a
class implements (that instances of the class provides).
Implements specifications support inheriting interfaces.
- ProvidesDeclarations are used to express interfaces directly
provided by objects.
$Id$
"""
__docformat__ = 'restructuredtext'
import sys
import weakref
from zope.interface.interface import InterfaceClass, Specification
from ro import mergeOrderings, ro
import exceptions
from types import ClassType
from zope.interface.advice import addClassAdvisor
# Registry of class-implementation specifications
BuiltinImplementationSpecifications = {}
class Declaration(Specification):
"""Interface declarations
"""
def __init__(self, *interfaces):
Specification.__init__(self, _normalizeargs(interfaces))
def changed(self):
Specification.changed(self)
try:
del self._v_attrs
except AttributeError:
pass
def __contains__(self, interface):
"""Test whether an interface is in the specification
for example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> spec = Declaration(I2, I3)
>>> spec = Declaration(I4, spec)
>>> int(I1 in spec)
0
>>> int(I2 in spec)
1
>>> int(I3 in spec)
1
>>> int(I4 in spec)
1
"""
return self.extends(interface) and interface in self.interfaces()
def __iter__(self):
"""Return an iterator for the interfaces in the specification
for example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> spec = Declaration(I2, I3)
>>> spec = Declaration(I4, spec)
>>> i = iter(spec)
>>> i.next().getName()
'I4'
>>> i.next().getName()
'I2'
>>> i.next().getName()
'I3'
>>> list(i)
[]
"""
return self.interfaces()
def flattened(self):
"""Return an iterator of all included and extended interfaces
for example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> spec = Declaration(I2, I3)
>>> spec = Declaration(I4, spec)
>>> i = spec.flattened()
>>> i.next().getName()
'I4'
>>> i.next().getName()
'I2'
>>> i.next().getName()
'I1'
>>> i.next().getName()
'I3'
>>> i.next().getName()
'Interface'
>>> list(i)
[]
"""
return iter(self.__iro__)
def __sub__(self, other):
"""Remove interfaces from a specification
Examples::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> spec = Declaration()
>>> [iface.getName() for iface in spec]
[]
>>> spec -= I1
>>> [iface.getName() for iface in spec]
[]
>>> spec -= Declaration(I1, I2)
>>> [iface.getName() for iface in spec]
[]
>>> spec = Declaration(I2, I4)
>>> [iface.getName() for iface in spec]
['I2', 'I4']
>>> [iface.getName() for iface in spec - I4]
['I2']
>>> [iface.getName() for iface in spec - I1]
['I4']
>>> [iface.getName() for iface
... in spec - Declaration(I3, I4)]
['I2']
"""
return Declaration(
*[i for i in self.interfaces()
if not [j for j in other.interfaces()
if i.extends(j, 0)]
]
)
def __add__(self, other):
"""Add two specifications or a specification and an interface
Examples::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> spec = Declaration()
>>> [iface.getName() for iface in spec]
[]
>>> [iface.getName() for iface in spec+I1]
['I1']
>>> [iface.getName() for iface in I1+spec]
['I1']
>>> spec2 = spec
>>> spec += I1
>>> [iface.getName() for iface in spec]
['I1']
>>> [iface.getName() for iface in spec2]
[]
>>> spec2 += Declaration(I3, I4)
>>> [iface.getName() for iface in spec2]
['I3', 'I4']
>>> [iface.getName() for iface in spec+spec2]
['I1', 'I3', 'I4']
>>> [iface.getName() for iface in spec2+spec]
['I3', 'I4', 'I1']
"""
seen = {}
result = []
for i in self.interfaces():
if i not in seen:
seen[i] = 1
result.append(i)
for i in other.interfaces():
if i not in seen:
seen[i] = 1
result.append(i)
return Declaration(*result)
__radd__ = __add__
def __nonzero__(self):
"""Test whether there are any interfaces in a specification.
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> spec = Declaration(I1)
>>> int(bool(spec))
1
>>> spec = Declaration()
>>> int(bool(spec))
0
"""
return bool(self.__iro__)
##############################################################################
#
# Implementation specifications
#
# These specify interfaces implemented by instances of classes
class Implements(Declaration):
inherit = None
declared = ()
__name__ = '?'
def __repr__(self):
return '<implementedBy %s>' % (self.__name__)
def implementedByFallback(cls):
"""Return the interfaces implemented for a class' instances
The value returned is an IDeclaration.
for example:
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> class C1(object):
... implements(I2)
>>> class C2(C1):
... implements(I3)
>>> [i.getName() for i in implementedBy(C2)]
['I3', 'I2']
"""
# This also manages storage of implementation specifications
try:
spec = cls.__dict__.get('__implemented__')
except AttributeError:
# we can't get the class dict. This is probably due to a
# security proxy. If this is the case, then probably no
# descriptor was installed for the class.
# We don't want to depend directly on zope.secury in
# zope.interface, but we'll try to make reasonable
# accommodations in an indirect way.
# We'll check to see if there's an implements:
spec = getattr(cls, '__implemented__', None)
if spec is None:
# There's no spec stred in the class. Maybe its a builtin:
spec = BuiltinImplementationSpecifications.get(cls)
if spec is not None:
return spec
return _empty
if spec.__class__ == Implements:
# we defaulted to _empty or there was a spec. Good enough.
# Return it.
return spec
# TODO: need old style __implements__ compatibility?
# Hm, there's an __implemented__, but it's not a spec. Must be
# an old-style declaration. Just compute a spec for it
return Declaration(*_normalizeargs((spec, )))
if isinstance(spec, Implements):
return spec
if spec is None:
spec = BuiltinImplementationSpecifications.get(cls)
if spec is not None:
return spec
# TODO: need old style __implements__ comptability?
if spec is not None:
# old-style __implemented__ = foo declaration
spec = (spec, ) # tuplefy, as it might be just an int
spec = Implements(*_normalizeargs(spec))
spec.inherit = None # old-style implies no inherit
del cls.__implemented__ # get rid of the old-style declaration
else:
try:
bases = cls.__bases__
except AttributeError:
if not callable(cls):
raise TypeError("ImplementedBy called for non-factory", cls)
bases = ()
spec = Implements(*[implementedBy(c) for c in bases])
spec.inherit = cls
spec.__name__ = (getattr(cls, '__module__', '?') or '?') + \
'.' + cls.__name__
try:
cls.__implemented__ = spec
if not hasattr(cls, '__providedBy__'):
cls.__providedBy__ = objectSpecificationDescriptor
if (isinstance(cls, DescriptorAwareMetaClasses)
and
'__provides__' not in cls.__dict__):
# Make sure we get a __provides__ descriptor
cls.__provides__ = ClassProvides(
cls,
getattr(cls, '__class__', type(cls)),
)
except TypeError:
if not isinstance(cls, type):
raise TypeError("ImplementedBy called for non-type", cls)
BuiltinImplementationSpecifications[cls] = spec
return spec
implementedBy = implementedByFallback
def classImplementsOnly(cls, *interfaces):
"""Declare the only interfaces implemented by instances of a class
The arguments after the class are one or more interfaces or
interface specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) replace any previous declarations.
Consider the following example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(Interface): pass
...
>>> class I3(Interface): pass
...
>>> class I4(Interface): pass
...
>>> class A(object):
... implements(I3)
>>> class B(object):
... implements(I4)
>>> class C(A, B):
... pass
>>> classImplementsOnly(C, I1, I2)
>>> [i.getName() for i in implementedBy(C)]
['I1', 'I2']
Instances of ``C`` provide only ``I1``, ``I2``, and regardless of
whatever interfaces instances of ``A`` and ``B`` implement.
"""
spec = implementedBy(cls)
spec.__bases__ = tuple(_normalizeargs(interfaces))
spec.inherit = None
def classImplements(cls, *interfaces):
"""Declare additional interfaces implemented for instances of a class
The arguments after the class are one or more interfaces or
interface specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) are added to any interfaces previously
declared.
Consider the following example::
for example:
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(Interface): pass
...
>>> class I3(Interface): pass
...
>>> class I4(Interface): pass
...
>>> class I5(Interface): pass
...
>>> class A(object):
... implements(I3)
>>> class B(object):
... implements(I4)
>>> class C(A, B):
... pass
>>> classImplements(C, I1, I2)
>>> [i.getName() for i in implementedBy(C)]
['I1', 'I2', 'I3', 'I4']
>>> classImplements(C, I5)
>>> [i.getName() for i in implementedBy(C)]
['I1', 'I2', 'I5', 'I3', 'I4']
Instances of ``C`` provide ``I1``, ``I2``, ``I5``, and whatever
interfaces instances of ``A`` and ``B`` provide.
"""
spec = implementedBy(cls)
spec.declared += tuple(_normalizeargs(interfaces))
# compute the bases
bases = []
seen = {}
for b in spec.declared:
if b not in seen:
seen[b] = 1
bases.append(b)
if spec.inherit is not None:
for c in spec.inherit.__bases__:
b = implementedBy(c)
if b not in seen:
seen[b] = 1
bases.append(b)
spec.__bases__ = tuple(bases)
def _implements_advice(cls):
interfaces, classImplements = cls.__dict__['__implements_advice_data__']
del cls.__implements_advice_data__
classImplements(cls, *interfaces)
return cls
class implementer:
def __init__(self, *interfaces):
self.interfaces = interfaces
def __call__(self, ob):
if isinstance(ob, DescriptorAwareMetaClasses):
raise TypeError("Can't use implementer with classes. Use one of "
"the class-declaration functions instead."
)
spec = Implements(*self.interfaces)
try:
ob.__implemented__ = spec
except AttributeError:
raise TypeError("Can't declare implements", ob)
return ob
def _implements(name, interfaces, classImplements):
frame = sys._getframe(2)
locals = frame.f_locals
# Try to make sure we were called from a class def. In 2.2.0 we can't
# check for __module__ since it doesn't seem to be added to the locals
# until later on.
if (locals is frame.f_globals) or (
('__module__' not in locals) and sys.version_info[:3] > (2, 2, 0)):
raise TypeError(name+" can be used only from a class definition.")
if '__implements_advice_data__' in locals:
raise TypeError(name+" can be used only once in a class definition.")
locals['__implements_advice_data__'] = interfaces, classImplements
addClassAdvisor(_implements_advice, depth=3)
def implements(*interfaces):
"""Declare interfaces implemented by instances of a class
This function is called in a class definition.
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) are added to any interfaces previously
declared.
Previous declarations include declarations for base classes
unless implementsOnly was used.
This function is provided for convenience. It provides a more
convenient way to call classImplements. For example::
implements(I1)
is equivalent to calling::
classImplements(C, I1)
after the class has been created.
Consider the following example::
>>> from zope.interface import Interface
>>> class IA1(Interface): pass
...
>>> class IA2(Interface): pass
...
>>> class IB(Interface): pass
...
>>> class IC(Interface): pass
...
>>> class A(object): implements(IA1, IA2)
...
>>> class B(object): implements(IB)
...
>>> class C(A, B):
... implements(IC)
>>> ob = C()
>>> int(IA1 in providedBy(ob))
1
>>> int(IA2 in providedBy(ob))
1
>>> int(IB in providedBy(ob))
1
>>> int(IC in providedBy(ob))
1
Instances of ``C`` implement ``I1``, ``I2``, and whatever interfaces
instances of ``A`` and ``B`` implement.
"""
_implements("implements", interfaces, classImplements)
def implementsOnly(*interfaces):
"""Declare the only interfaces implemented by instances of a class
This function is called in a class definition.
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
Previous declarations including declarations for base classes
are overridden.
This function is provided for convenience. It provides a more
convenient way to call classImplementsOnly. For example::
implementsOnly(I1)
is equivalent to calling::
classImplementsOnly(I1)
after the class has been created.
Consider the following example::
>>> from zope.interface import Interface
>>> class IA1(Interface): pass
...
>>> class IA2(Interface): pass
...
>>> class IB(Interface): pass
...
>>> class IC(Interface): pass
...
>>> class A(object): implements(IA1, IA2)
...
>>> class B(object): implements(IB)
...
>>> class C(A, B):
... implementsOnly(IC)
>>> ob = C()
>>> int(IA1 in providedBy(ob))
0
>>> int(IA2 in providedBy(ob))
0
>>> int(IB in providedBy(ob))
0
>>> int(IC in providedBy(ob))
1
Instances of ``C`` implement ``IC``, regardless of what
instances of ``A`` and ``B`` implement.
"""
_implements("implementsOnly", interfaces, classImplementsOnly)
##############################################################################
#
# Instance declarations
class Provides(Declaration): # Really named ProvidesClass
"""Implement __provides__, the instance-specific specification
When an object is pickled, we pickle the interfaces that it implements.
"""
def __init__(self, cls, *interfaces):
self.__args = (cls, ) + interfaces
self._cls = cls
Declaration.__init__(self, *(interfaces + (implementedBy(cls), )))
def __reduce__(self):
return Provides, self.__args
__module__ = 'zope.interface'
def __get__(self, inst, cls):
"""Make sure that a class __provides__ doesn't leak to an instance
For example::
>>> from zope.interface import Interface
>>> class IFooFactory(Interface): pass
...
>>> class C(object):
... pass
>>> C.__provides__ = ProvidesClass(C, IFooFactory)
>>> [i.getName() for i in C.__provides__]
['IFooFactory']
>>> getattr(C(), '__provides__', 0)
0
"""
if inst is None and cls is self._cls:
# We were accessed through a class, so we are the class'
# provides spec. Just return this object, but only if we are
# being called on the same class that we were defined for:
return self
raise AttributeError, '__provides__'
ProvidesClass = Provides
# Registry of instance declarations
# This is a memory optimization to allow objects to share specifications.
InstanceDeclarations = weakref.WeakValueDictionary()
def Provides(*interfaces):
"""Cache instance declarations
Instance declarations are shared among instances that have the
same declaration. The declarations are cached in an weak value
dictionary.
(Note that, in the examples below, we are going to make
assertions about the size of the weakvalue dictionary. For the
assertions to be meaningful, we need to force garbage
collection to make sure garbage objects are, indeed, removed
from the system. Depending on how Python is run, we may need to
make multiple calls to be sure. We provide a collect function
to help with this:
>>> import gc
>>> def collect():
... for i in range(4):
... gc.collect()
)
>>> collect()
>>> before = len(InstanceDeclarations)
>>> class C(object):
... pass
>>> from zope.interface import Interface
>>> class I(Interface):
... pass
>>> c1 = C()
>>> c2 = C()
>>> len(InstanceDeclarations) == before
1
>>> directlyProvides(c1, I)
>>> len(InstanceDeclarations) == before + 1
1
>>> directlyProvides(c2, I)
>>> len(InstanceDeclarations) == before + 1
1
>>> del c1
>>> collect()
>>> len(InstanceDeclarations) == before + 1
1
>>> del c2
>>> collect()
>>> len(InstanceDeclarations) == before
1
"""
spec = InstanceDeclarations.get(interfaces)
if spec is None:
spec = ProvidesClass(*interfaces)
InstanceDeclarations[interfaces] = spec
return spec
Provides.__safe_for_unpickling__ = True
DescriptorAwareMetaClasses = ClassType, type
def directlyProvides(object, *interfaces):
"""Declare interfaces declared directly for an object
The arguments after the object are one or more interfaces or
interface specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) replace interfaces previously
declared for the object.
Consider the following example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(Interface): pass
...
>>> class IA1(Interface): pass
...
>>> class IA2(Interface): pass
...
>>> class IB(Interface): pass
...
>>> class IC(Interface): pass
...
>>> class A(object): implements(IA1, IA2)
...
>>> class B(object): implements(IB)
...
>>> class C(A, B):
... implements(IC)
>>> ob = C()
>>> directlyProvides(ob, I1, I2)
>>> int(I1 in providedBy(ob))
1
>>> int(I2 in providedBy(ob))
1
>>> int(IA1 in providedBy(ob))
1
>>> int(IA2 in providedBy(ob))
1
>>> int(IB in providedBy(ob))
1
>>> int(IC in providedBy(ob))
1
The object, ``ob`` provides ``I1``, ``I2``, and whatever interfaces
instances have been declared for instances of ``C``.
To remove directly provided interfaces, use ``directlyProvidedBy`` and
subtract the unwanted interfaces. For example::
>>> directlyProvides(ob, directlyProvidedBy(ob)-I2)
>>> int(I1 in providedBy(ob))
1
>>> int(I2 in providedBy(ob))
0
removes I2 from the interfaces directly provided by
``ob``. The object, ``ob`` no longer directly provides ``I2``,
although it might still provide ``I2`` if it's class
implements ``I2``.
To add directly provided interfaces, use ``directlyProvidedBy`` and
include additional interfaces. For example::
>>> int(I2 in providedBy(ob))
0
>>> directlyProvides(ob, directlyProvidedBy(ob), I2)
adds I2 to the interfaces directly provided by ob::
>>> int(I2 in providedBy(ob))
1
"""
# We need to avoid setting this attribute on meta classes that
# don't support descriptors.
# We can do away with this check when we get rid of the old EC
cls = getattr(object, '__class__', None)
if cls is not None and getattr(cls, '__class__', None) is cls:
# It's a meta class (well, at least it it could be an extension class)
if not isinstance(object, DescriptorAwareMetaClasses):
raise TypeError("Attempt to make an interface declaration on a "
"non-descriptor-aware class")
interfaces = _normalizeargs(interfaces)
if cls is None:
cls = type(object)
issub = False
for damc in DescriptorAwareMetaClasses:
if issubclass(cls, damc):
issub = True
break
if issub:
# we have a class or type. We'll use a special descriptor
# that provides some extra caching
object.__provides__ = ClassProvides(object, cls, *interfaces)
else:
object.__provides__ = Provides(cls, *interfaces)
def alsoProvides(object, *interfaces):
"""Declare interfaces declared directly for an object
The arguments after the object are one or more interfaces or
interface specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) are added to the interfaces previously
declared for the object.
Consider the following example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(Interface): pass
...
>>> class IA1(Interface): pass
...
>>> class IA2(Interface): pass
...
>>> class IB(Interface): pass
...
>>> class IC(Interface): pass
...
>>> class A(object): implements(IA1, IA2)
...
>>> class B(object): implements(IB)
...
>>> class C(A, B):
... implements(IC)
>>> ob = C()
>>> directlyProvides(ob, I1)
>>> int(I1 in providedBy(ob))
1
>>> int(I2 in providedBy(ob))
0
>>> int(IA1 in providedBy(ob))
1
>>> int(IA2 in providedBy(ob))
1
>>> int(IB in providedBy(ob))
1
>>> int(IC in providedBy(ob))
1
>>> alsoProvides(ob, I2)
>>> int(I1 in providedBy(ob))
1
>>> int(I2 in providedBy(ob))
1
>>> int(IA1 in providedBy(ob))
1
>>> int(IA2 in providedBy(ob))
1
>>> int(IB in providedBy(ob))
1
>>> int(IC in providedBy(ob))
1
The object, ``ob`` provides ``I1``, ``I2``, and whatever interfaces
instances have been declared for instances of ``C``. Notice that the
alsoProvides just extends the provided interfaces.
"""
directlyProvides(object, directlyProvidedBy(object), *interfaces)
class ClassProvidesBasePy(object):
def __get__(self, inst, cls):
if cls is self._cls:
# We only work if called on the class we were defined for
if inst is None:
# We were accessed through a class, so we are the class'
# provides spec. Just return this object as is:
return self
return self._implements
raise AttributeError, '__provides__'
ClassProvidesBase = ClassProvidesBasePy
# Try to get C base:
try:
import _zope_interface_coptimizations
except ImportError:
pass
else:
from _zope_interface_coptimizations import ClassProvidesBase
class ClassProvides(Declaration, ClassProvidesBase):
"""Special descriptor for class __provides__
The descriptor caches the implementedBy info, so that
we can get declarations for objects without instance-specific
interfaces a bit quicker.
For example::
>>> from zope.interface import Interface
>>> class IFooFactory(Interface):
... pass
>>> class IFoo(Interface):
... pass
>>> class C(object):
... implements(IFoo)
... classProvides(IFooFactory)
>>> [i.getName() for i in C.__provides__]
['IFooFactory']
>>> [i.getName() for i in C().__provides__]
['IFoo']
"""
def __init__(self, cls, metacls, *interfaces):
self._cls = cls
self._implements = implementedBy(cls)
self.__args = (cls, metacls, ) + interfaces
Declaration.__init__(self, *(interfaces + (implementedBy(metacls), )))
def __reduce__(self):
return self.__class__, self.__args
# Copy base-class method for speed
__get__ = ClassProvidesBase.__get__
def directlyProvidedBy(object):
"""Return the interfaces directly provided by the given object
The value returned is an IDeclaration.
"""
provides = getattr(object, "__provides__", None)
if (provides is None # no spec
or
# We might have gotten the implements spec, as an
# optimization. If so, it's like having only one base, that we
# lop off to exclude class-supplied declarations:
isinstance(provides, Implements)
):
return _empty
# Strip off the class part of the spec:
return Declaration(provides.__bases__[:-1])
def classProvides(*interfaces):
"""Declare interfaces provided directly by a class
This function is called in a class definition.
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
The given interfaces (including the interfaces in the
specifications) are used to create the class's direct-object
interface specification. An error will be raised if the module
class has an direct interface specification. In other words, it is
an error to call this function more than once in a class
definition.
Note that the given interfaces have nothing to do with the
interfaces implemented by instances of the class.
This function is provided for convenience. It provides a more
convenient way to call directlyProvidedByProvides for a class. For
example::
classProvides(I1)
is equivalent to calling::
directlyProvides(theclass, I1)
after the class has been created.
For example::
>>> from zope.interface import Interface
>>> class IFoo(Interface): pass
...
>>> class IFooFactory(Interface): pass
...
>>> class C(object):
... implements(IFoo)
... classProvides(IFooFactory)
>>> [i.getName() for i in C.__providedBy__]
['IFooFactory']
>>> [i.getName() for i in C().__providedBy__]
['IFoo']
if equivalent to::
>>> from zope.interface import Interface
>>> class IFoo(Interface): pass
...
>>> class IFooFactory(Interface): pass
...
>>> class C(object):
... implements(IFoo)
>>> directlyProvides(C, IFooFactory)
>>> [i.getName() for i in C.__providedBy__]
['IFooFactory']
>>> [i.getName() for i in C().__providedBy__]
['IFoo']
"""
frame = sys._getframe(1)
locals = frame.f_locals
# Try to make sure we were called from a class def
if (locals is frame.f_globals) or ('__module__' not in locals):
raise TypeError(name+" can be used only from a class definition.")
if '__provides__' in locals:
raise TypeError(
"classProvides can only be used once in a class definition.")
locals["__provides__"] = _normalizeargs(interfaces)
addClassAdvisor(_classProvides_advice, depth=2)
def _classProvides_advice(cls):
interfaces = cls.__dict__['__provides__']
del cls.__provides__
directlyProvides(cls, *interfaces)
return cls
def moduleProvides(*interfaces):
"""Declare interfaces provided by a module
This function is used in a module definition.
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
The given interfaces (including the interfaces in the
specifications) are used to create the module's direct-object
interface specification. An error will be raised if the module
already has an interface specification. In other words, it is
an error to call this function more than once in a module
definition.
This function is provided for convenience. It provides a more
convenient way to call directlyProvides. For example::
moduleImplements(I1)
is equivalent to::
directlyProvides(sys.modules[__name__], I1)
"""
frame = sys._getframe(1)
locals = frame.f_locals
# Try to make sure we were called from a class def
if (locals is not frame.f_globals) or ('__name__' not in locals):
raise TypeError(
"moduleProvides can only be used from a module definition.")
if '__provides__' in locals:
raise TypeError(
"moduleProvides can only be used once in a module definition.")
module = sys.modules[__name__]
locals["__provides__"] = Provides(type(module),
*_normalizeargs(interfaces))
##############################################################################
#
# Declaration querying support
def ObjectSpecification(direct, cls):
"""Provide object specifications
These combine information for the object and for it's classes.
For example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(Interface): pass
...
>>> class I3(Interface): pass
...
>>> class I31(I3): pass
...
>>> class I4(Interface): pass
...
>>> class I5(Interface): pass
...
>>> class A(object): implements(I1)
...
>>> class B(object): __implemented__ = I2
...
>>> class C(A, B): implements(I31)
...
>>> c = C()
>>> directlyProvides(c, I4)
>>> [i.getName() for i in providedBy(c)]
['I4', 'I31', 'I1', 'I2']
>>> [i.getName() for i in providedBy(c).flattened()]
['I4', 'I31', 'I3', 'I1', 'I2', 'Interface']
>>> int(I1 in providedBy(c))
1
>>> int(I3 in providedBy(c))
0
>>> int(providedBy(c).extends(I3))
1
>>> int(providedBy(c).extends(I31))
1
>>> int(providedBy(c).extends(I5))
0
>>> class COnly(A, B): implementsOnly(I31)
...
>>> class D(COnly): implements(I5)
...
>>> c = D()
>>> directlyProvides(c, I4)
>>> [i.getName() for i in providedBy(c)]
['I4', 'I5', 'I31']
>>> [i.getName() for i in providedBy(c).flattened()]
['I4', 'I5', 'I31', 'I3', 'Interface']
>>> int(I1 in providedBy(c))
0
>>> int(I3 in providedBy(c))
0
>>> int(providedBy(c).extends(I3))
1
>>> int(providedBy(c).extends(I1))
0
>>> int(providedBy(c).extends(I31))
1
>>> int(providedBy(c).extends(I5))
1
nonzero:
>>> from zope.interface import Interface
>>> class I1(Interface):
... pass
>>> class I2(Interface):
... pass
>>> class C(object):
... implements(I1)
>>> c = C()
>>> int(bool(providedBy(c)))
1
>>> directlyProvides(c, I2)
>>> int(bool(providedBy(c)))
1
>>> class C(object):
... pass
>>> c = C()
>>> int(bool(providedBy(c)))
0
>>> directlyProvides(c, I2)
>>> int(bool(providedBy(c)))
1
"""
return Provides(cls, direct)
def getObjectSpecification(ob):
provides = getattr(ob, '__provides__', None)
if provides is not None:
return provides
try:
cls = ob.__class__
except AttributeError:
# We can't get the class, so just consider provides
return _empty
return implementedBy(cls)
def providedBy(ob):
# Here we have either a special object, an old-style declaration
# or a descriptor
# Try to get __providedBy__
try:
r = ob.__providedBy__
except AttributeError:
# Not set yet. Fall back to lower-level thing that computes it
return getObjectSpecification(ob)
try:
# We might have gotten a descriptor from an instance of a
# class (like an ExtensionClass) that doesn't support
# descriptors. We'll make sure we got one by trying to get
# the only attribute, which all specs have.
r.extends
except AttributeError:
# The object's class doesn't understand descriptors.
# Sigh. We need to get an object descriptor, but we have to be
# careful. We want to use the instance's __provides__, if
# there is one, but only if it didn't come from the class.
try:
r = ob.__provides__
except AttributeError:
# No __provides__, so just fall back to implementedBy
return implementedBy(ob.__class__)
# We need to make sure we got the __provides__ from the
# instance. We'll do this by making sure we don't get the same
# thing from the class:
try:
cp = ob.__class__.__provides__
except AttributeError:
# The ob doesn't have a class or the class has no
# provides, assume we're done:
return r
if r is cp:
# Oops, we got the provides from the class. This means
# the object doesn't have it's own. We should use implementedBy
return implementedBy(ob.__class__)
return r
class ObjectSpecificationDescriptorPy(object):
"""Implement the __providedBy__ attribute
The __providedBy__ attribute computes the interfaces peovided by
an object.
"""
def __get__(self, inst, cls):
"""Get an object specification for an object
For example::
>>> from zope.interface import Interface
>>> class IFoo(Interface): pass
...
>>> class IFooFactory(Interface): pass
...
>>> class C(object):
... implements(IFoo)
... classProvides(IFooFactory)
>>> [i.getName() for i in C.__providedBy__]
['IFooFactory']
>>> [i.getName() for i in C().__providedBy__]
['IFoo']
"""
# Get an ObjectSpecification bound to either an instance or a class,
# depending on how we were accessed.
if inst is None:
return getObjectSpecification(cls)
provides = getattr(inst, '__provides__', None)
if provides is not None:
return provides
return implementedBy(cls)
ObjectSpecificationDescriptor = ObjectSpecificationDescriptorPy
##############################################################################
def _normalizeargs(sequence, output = None):
"""Normalize declaration arguments
Normalization arguments might contain Declarions, tuples, or single
interfaces.
Anything but individial interfaces or implements specs will be expanded.
"""
if output is None:
output = []
cls = sequence.__class__
if InterfaceClass in cls.__mro__ or Implements in cls.__mro__:
output.append(sequence)
else:
for v in sequence:
_normalizeargs(v, output)
return output
_empty = Declaration()
try:
import _zope_interface_coptimizations
except ImportError:
pass
else:
from _zope_interface_coptimizations import implementedBy, providedBy
from _zope_interface_coptimizations import getObjectSpecification
from _zope_interface_coptimizations import ObjectSpecificationDescriptor
objectSpecificationDescriptor = ObjectSpecificationDescriptor()
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
""" Pretty-Print an Interface object as structured text (Yum)
This module provides a function, asStructuredText, for rendering an
interface as structured text.
$Id$
"""
from string import maketrans
import zope.interface
def asStructuredText(I, munge=0):
""" Output structured text format. Note, this will wack any existing
'structured' format of the text. """
r = ["%s\n\n" % I.getName()]
outp = r.append
level = 1
if I.getDoc():
outp(_justify_and_indent(_trim_doc_string(I.getDoc()), level)+ "\n\n")
bases = [base
for base in I.__bases__
if base is not zope.interface.Interface
]
if bases:
outp((" " * level) + "This interface extends:\n\n")
level = level + 1
for b in bases:
item = "o %s" % b.getName()
outp(_justify_and_indent(_trim_doc_string(item), level, munge)
+ "\n\n")
level = level - 1
outp(_justify_and_indent("Attributes:", level, munge)+'\n\n')
level = level + 1
namesAndDescriptions = I.namesAndDescriptions()
namesAndDescriptions.sort()
for name, desc in namesAndDescriptions:
if not hasattr(desc, 'getSignatureString'): # ugh...
item = "%s -- %s" % (desc.getName(),
desc.getDoc() or 'no documentation')
outp(_justify_and_indent(_trim_doc_string(item), level, munge)
+ "\n\n")
level = level - 1
outp(_justify_and_indent("Methods:", level, munge)+'\n\n')
level = level + 1
for name, desc in namesAndDescriptions:
if hasattr(desc, 'getSignatureString'): # ugh...
item = "%s%s -- %s" % (desc.getName(),
desc.getSignatureString(),
desc.getDoc() or 'no documentation')
outp(_justify_and_indent(_trim_doc_string(item), level, munge)
+ "\n\n")
return "".join(r)
def _trim_doc_string(text):
"""
Trims a doc string to make it format
correctly with structured text.
"""
text = text.strip().replace('\r\n', '\n')
lines = text.split('\n')
nlines = [lines[0]]
if len(lines) > 1:
min_indent=None
for line in lines[1:]:
indent=len(line) - len(line.lstrip())
if indent < min_indent or min_indent is None:
min_indent=indent
for line in lines[1:]:
nlines.append(line[min_indent:])
return '\n'.join(nlines)
_trans = maketrans("\r\n", " ")
def _justify_and_indent(text, level, munge=0, width=72):
""" indent and justify text, rejustify (munge) if specified """
lines = []
if munge:
line = " " * level
text = text.translate(text, _trans).strip().split()
for word in text:
line = ' '.join([line, word])
if len(line) > width:
lines.append(line)
line = " " * level
else:
lines.append(line)
return "\n".join(lines)
else:
text = text.replace("\r\n", "\n").split("\n")
for line in text:
lines.append((" " * level) + line)
return '\n'.join(lines)
##############################################################################
#
# Copyright (c) 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Interface-specific exceptions
$Id$
"""
class Invalid(Exception):
"""An specification is violated
"""
class DoesNotImplement(Invalid):
""" This object does not implement """
def __init__(self, interface):
self.interface = interface
def __str__(self):
return """An object does not implement interface %(interface)s
""" % self.__dict__
class BrokenImplementation(Invalid):
"""An attribute is not completely implemented.
"""
def __init__(self, interface, name):
self.interface=interface
self.name=name
def __str__(self):
return """An object has failed to implement interface %(interface)s
The %(name)s attribute was not provided.
""" % self.__dict__
class BrokenMethodImplementation(Invalid):
"""An method is not completely implemented.
"""
def __init__(self, method, mess):
self.method=method
self.mess=mess
def __str__(self):
return """The implementation of %(method)s violates its contract
because %(mess)s.
""" % self.__dict__
class InvalidInterface(Exception):
"""The interface has invalid contents
"""
class BadImplements(TypeError):
"""An implementation assertion is invalid
because it doesn't contain an interface or a sequence of valid
implementation assertions.
"""
==========================
Using the Adapter Registry
==========================
This is a small demonstration of the zope.interface package including its
adapter registry. It is intended to provide a concrete but narrow example on
how to use interfaces and adapters outside of Zope 3.
First we have to import the interface package.
>>> import zope.interface
We now develop an interface for our object, which is a simple file in this
case. For now we simply support one attribute, the body, which contains the
actual file contents.
>>> class IFile(zope.interface.Interface):
...
... body = zope.interface.Attribute('Contents of the file.')
...
For statistical reasons we often want to know the size of a file. However, it
would be clumsy to implement the size directly in the file object, since the
size really represents meta-data. Thus we create another interface that
provides the size of something.
>>> class ISize(zope.interface.Interface):
...
... def getSize():
... 'Return the size of an object.'
...
Now we need to implement the file. It is essential that the object states
that it implements the `IFile` interface. We also provide a default body
value (just to make things simpler for this example).
>>> class File(object):
...
... zope.interface.implements(IFile)
... body = 'foo bar'
...
Next we implement an adapter that can provide the `ISize` interface given any
object providing `IFile`. By convention we use `__used_for__` to specify the
interface that we expect the adapted object to provide, in our case
`IFile`. However, this attribute is not used for anything. If you have
multiple interfaces for which an adapter is used, just specify the interfaces
via a tuple.
Again by convention, the constructor of an adapter takes one argument, the
context. The context in this case is an instance of `File` (providing `IFile`)
that is used to extract the size from. Also by convention the context is
stored in an attribute named `context` on the adapter. The twisted community
refers to the context as the `original` object. However, you may feel free to
use a specific argument name, such as `file`.
>>> class FileSize(object):
...
... zope.interface.implements(ISize)
... __used_for__ = IFile
...
... def __init__(self, context):
... self.context = context
...
... def getSize(self):
... return len(self.context.body)
...
Now that we have written our adapter, we have to register it with an adapter
registry, so that it can be looked up when needed. There is no such thing as a
global registry; thus we have to instantiate one for our example manually.
>>> from zope.interface.adapter import AdapterRegistry
>>> registry = AdapterRegistry()
The registry keeps a map of what adapters implement based on another
interface, the object already provides. Therefore, we next have to register an
adapter that adapts from `IFile` to `ISize`. The first argument to
the registry's `register()` method is a list of original interfaces.In our
cause we have only one original interface, `IFile`. A list makes sense, since
the interface package has the concept of multi-adapters, which are adapters
that require multiple objects to adapt to a new interface. In these
situations, your adapter constructor will require an argument for each
specified interface.
The second argument is the interface the adapter provides, in our case
`ISize`. The third argument in the name of the adapter. Since we do not care
about names, we simply leave it as an empty string. Names are commonly useful,
if you have adapters for the same set of interfaces, but they are useful in
different situations. The last argument is simply the adapter class.
>>> registry.register([IFile], ISize, '', FileSize)
You can now use the the registry to lookup the adapter.
>>> registry.lookup1(IFile, ISize, '')
<class '__main__.FileSize'>
Let's get a little bit more practical. Let's create a `File` instance and
create the adapter using a registry lookup. Then we see whether the adapter
returns the correct size by calling `getSize()`.
>>> file = File()
>>> size = registry.lookup1(IFile, ISize, '')(file)
>>> size.getSize()
7
However, this is not very practical, since I have to manually pass in the
arguments to the lookup method. There is some syntactic candy that will allow
us to get an adapter instance by simply calling `ISize(file)`. To make use of
this functionality, we need to add our registry to the adapter_hooks list,
which is a member of the adapters module. This list stores a collection of
callables that are automatically invoked when IFoo(obj) is called; their
purpose is to locate adapters that implement an interface for a certain
context instance.
You are required to implement your own adapter hook; this example covers one
of the simplest hooks that use the registry, but you could implement one that
used an adapter cache or persistent adapters, for instance. The helper hook is
required to expect as first argument the desired output interface (for us
`ISize`) and as the second argument the context of the adapter (here
`file`). The function returns an adapter, i.e. a `FileSize` instance.
>>> def hook(provided, object):
... adapter = registry.lookup1(zope.interface.providedBy(object),
... provided, '')
... return adapter(object)
...
We now just add the hook to an `adapter_hooks` list.
>>> from zope.interface.interface import adapter_hooks
>>> adapter_hooks.append(hook)
Once the hook is registered, you can use the desired syntax.
>>> size = ISize(file)
>>> size.getSize()
7
Now we have to cleanup after ourselves, so that others after us have a clean
`adapter_hooks` list.
>>> adapter_hooks.remove(hook)
That's it. I have intentionally left out a discussion of named adapters and
multi-adapters, since this text is intended as a practical and simple
introduction to Zope 3 interfaces and adapters. You might want to read the
`adapter.txt` in the `zope.interface` package for a more formal, referencial
and complete treatment of the package. Warning: People have reported that
`adapter.txt` makes their brain feel soft!
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Interface object implementation
$Id$
"""
from __future__ import generators
import sys
import warnings
import weakref
from types import FunctionType
from ro import ro
from zope.interface.exceptions import Invalid
CO_VARARGS = 4
CO_VARKEYWORDS = 8
TAGGED_DATA = '__interface_tagged_values__'
def invariant(call):
f_locals = sys._getframe(1).f_locals
tags = f_locals.get(TAGGED_DATA)
if tags is None:
tags = f_locals[TAGGED_DATA] = {}
invariants = tags.get('invariants')
if invariants is None:
invariants = tags['invariants'] = []
invariants.append(call)
class Element(object):
# We can't say this yet because we don't have enough
# infrastructure in place.
#
#implements(IElement)
def __init__(self, __name__, __doc__=''):
"""Create an 'attribute' description
"""
if not __doc__ and __name__.find(' ') >= 0:
__doc__ = __name__
__name__ = None
self.__name__=__name__
self.__doc__=__doc__
self.__tagged_values = {}
def getName(self):
""" Returns the name of the object. """
return self.__name__
def getDoc(self):
""" Returns the documentation for the object. """
return self.__doc__
def getTaggedValue(self, tag):
""" Returns the value associated with 'tag'. """
return self.__tagged_values[tag]
def queryTaggedValue(self, tag, default=None):
""" Returns the value associated with 'tag'. """
return self.__tagged_values.get(tag, default)
def getTaggedValueTags(self):
""" Returns a list of all tags. """
return self.__tagged_values.keys()
def setTaggedValue(self, tag, value):
""" Associates 'value' with 'key'. """
self.__tagged_values[tag] = value
class SpecificationBasePy(object):
def providedBy(self, ob):
"""Is the interface implemented by an object
>>> from zope.interface import *
>>> class I1(Interface):
... pass
>>> class C(object):
... implements(I1)
>>> c = C()
>>> class X(object):
... pass
>>> x = X()
>>> I1.providedBy(x)
False
>>> I1.providedBy(C)
False
>>> I1.providedBy(c)
True
>>> directlyProvides(x, I1)
>>> I1.providedBy(x)
True
>>> directlyProvides(C, I1)
>>> I1.providedBy(C)
True
"""
spec = providedBy(ob)
return self in spec._implied
def implementedBy(self, cls):
"""Do instances of the given class implement the interface?"""
spec = implementedBy(cls)
return self in spec._implied
def isOrExtends(self, interface):
"""Is the interface the same as or extend the given interface
Examples::
>>> from zope.interface import Interface
>>> from zope.interface.declarations import Declaration
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> spec = Declaration()
>>> int(spec.extends(Interface))
0
>>> spec = Declaration(I2)
>>> int(spec.extends(Interface))
1
>>> int(spec.extends(I1))
1
>>> int(spec.extends(I2))
1
>>> int(spec.extends(I3))
0
>>> int(spec.extends(I4))
0
"""
return interface in self._implied
SpecificationBase = SpecificationBasePy
try:
from _zope_interface_coptimizations import SpecificationBase
except ImportError:
pass
class Specification(SpecificationBase):
"""Specifications
An interface specification is used to track interface declarations
and component registrations.
This class is a base class for both interfaces themselves and for
interface specifications (declarations).
Specifications are mutable. If you reassign their cases, their
relations with other specifications are adjusted accordingly.
For example:
>>> from zope.interface import Interface
>>> class I1(Interface):
... pass
>>> class I2(I1):
... pass
>>> class I3(I2):
... pass
>>> [i.__name__ for i in I1.__bases__]
['Interface']
>>> [i.__name__ for i in I2.__bases__]
['I1']
>>> I3.extends(I1)
1
>>> I2.__bases__ = (Interface, )
>>> [i.__name__ for i in I2.__bases__]
['Interface']
>>> I3.extends(I1)
0
"""
# Copy some base class methods for speed
isOrExtends = SpecificationBase.isOrExtends
providedBy = SpecificationBase.providedBy
#########################################################################
# BBB 2004-07-13: Backward compatabilty. These methods have been
# deprecated in favour of providedBy and implementedBy.
def isImplementedByInstancesOf(self, cls):
warnings.warn(
"isImplementedByInstancesOf has been renamed to implementedBy",
DeprecationWarning, stacklevel=2,
)
return self.implementedBy(cls)
def isImplementedBy(self, ob):
warnings.warn(
"isImplementedBy has been renamed to providedBy",
DeprecationWarning, stacklevel=2,
)
return self.providedBy(ob)
#
#########################################################################
def __init__(self, bases=()):
self._implied = {}
self.dependents = weakref.WeakKeyDictionary()
self.__bases__ = tuple(bases)
def subscribe(self, dependent):
self.dependents[dependent] = 1
def unsubscribe(self, dependent):
del self.dependents[dependent]
def __setBases(self, bases):
# Register ourselves as a dependent of our old bases
for b in self.__bases__:
b.unsubscribe(self)
# Register ourselves as a dependent of our bases
self.__dict__['__bases__'] = bases
for b in bases:
b.subscribe(self)
self.changed()
__bases__ = property(
lambda self: self.__dict__.get('__bases__', ()),
__setBases,
)
def changed(self):
"""We, or something we depend on, have changed
"""
implied = self._implied
implied.clear()
ancestors = ro(self)
self.__sro__ = tuple(ancestors)
self.__iro__ = tuple([ancestor for ancestor in ancestors
if isinstance(ancestor, InterfaceClass)
])
for ancestor in ancestors:
# We directly imply our ancestors:
implied[ancestor] = ()
# Now, advise our dependents of change:
for dependent in self.dependents.keys():
dependent.changed()
def interfaces(self):
"""Return an iterator for the interfaces in the specification
for example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> spec = Specification((I2, I3))
>>> spec = Specification((I4, spec))
>>> i = spec.interfaces()
>>> i.next().getName()
'I4'
>>> i.next().getName()
'I2'
>>> i.next().getName()
'I3'
>>> list(i)
[]
"""
seen = {}
for base in self.__bases__:
for interface in base.interfaces():
if interface not in seen:
seen[interface] = 1
yield interface
def extends(self, interface, strict=True):
"""Does the specification extend the given interface?
Test whether an interface in the specification extends the
given interface
Examples::
>>> from zope.interface import Interface
>>> from zope.interface.declarations import Declaration
>>> class I1(Interface): pass
...
>>> class I2(I1): pass
...
>>> class I3(Interface): pass
...
>>> class I4(I3): pass
...
>>> spec = Declaration()
>>> int(spec.extends(Interface))
0
>>> spec = Declaration(I2)
>>> int(spec.extends(Interface))
1
>>> int(spec.extends(I1))
1
>>> int(spec.extends(I2))
1
>>> int(spec.extends(I3))
0
>>> int(spec.extends(I4))
0
>>> I2.extends(I2)
0
>>> I2.extends(I2, False)
1
>>> I2.extends(I2, strict=False)
1
"""
return ((interface in self._implied)
and
((not strict) or (self != interface))
)
def weakref(self, callback=None):
if callback is None:
return weakref.ref(self)
else:
return weakref.ref(self, callback)
def get(self, name, default=None):
"""Query for an attribute description
"""
try:
attrs = self._v_attrs
except AttributeError:
attrs = self._v_attrs = {}
attr = attrs.get(name)
if attr is None:
for iface in self.__iro__:
attr = iface.direct(name)
if attr is not None:
attrs[name] = attr
break
if attr is None:
return default
else:
return attr
class InterfaceClass(Element, Specification):
"""Prototype (scarecrow) Interfaces Implementation."""
# We can't say this yet because we don't have enough
# infrastructure in place.
#
#implements(IInterface)
def __init__(self, name, bases=(), attrs=None, __doc__=None,
__module__=None):
if __module__ is None:
if (attrs is not None and
('__module__' in attrs) and
isinstance(attrs['__module__'], str)
):
__module__ = attrs['__module__']
del attrs['__module__']
else:
try:
# Figure out what module defined the interface.
# This is how cPython figures out the module of
# a class, but of course it does it in C. :-/
__module__ = sys._getframe(1).f_globals['__name__']
except (AttributeError, KeyError):
pass
self.__module__ = __module__
if attrs is None:
attrs = {}
d = attrs.get('__doc__')
if d is not None:
if not isinstance(d, Attribute):
if __doc__ is None:
__doc__ = d
del attrs['__doc__']
if __doc__ is None:
__doc__ = ''
Element.__init__(self, name, __doc__)
if attrs.has_key(TAGGED_DATA):
tagged_data = attrs[TAGGED_DATA]
del attrs[TAGGED_DATA]
else:
tagged_data = None
if tagged_data is not None:
for key, val in tagged_data.items():
self.setTaggedValue(key, val)
for base in bases:
if not isinstance(base, InterfaceClass):
raise TypeError, 'Expected base interfaces'
Specification.__init__(self, bases)
# Make sure that all recorded attributes (and methods) are of type
# `Attribute` and `Method`
for name, attr in attrs.items():
if isinstance(attr, Attribute):
attr.interface = self
if not attr.__name__:
attr.__name__ = name
elif isinstance(attr, FunctionType):
attrs[name] = fromFunction(attr, self, name=name)
else:
raise InvalidInterface("Concrete attribute, %s" %name)
self.__attrs = attrs
self.__identifier__ = "%s.%s" % (self.__module__, self.__name__)
def interfaces(self):
"""Return an iterator for the interfaces in the specification
for example::
>>> from zope.interface import Interface
>>> class I1(Interface): pass
...
>>>
>>> i = I1.interfaces()
>>> i.next().getName()
'I1'
>>> list(i)
[]
"""
yield self
def getBases(self):
return self.__bases__
def isEqualOrExtendedBy(self, other):
"""Same interface or extends?"""
if self == other:
return True
return other.extends(self)
def names(self, all=False):
"""Return the attribute names defined by the interface."""
if not all:
return self.__attrs.keys()
r = {}
for name in self.__attrs.keys():
r[name] = 1
for base in self.__bases__:
for name in base.names(all):
r[name] = 1
return r.keys()
def __iter__(self):
return iter(self.names(all=True))
def namesAndDescriptions(self, all=False):
"""Return attribute names and descriptions defined by interface."""
if not all:
return self.__attrs.items()
r = {}
for name, d in self.__attrs.items():
r[name] = d
for base in self.__bases__:
for name, d in base.namesAndDescriptions(all):
if name not in r:
r[name] = d
return r.items()
def getDescriptionFor(self, name):
"""Return the attribute description for the given name."""
r = self.get(name)
if r is not None:
return r
raise KeyError, name
__getitem__ = getDescriptionFor
def __contains__(self, name):
return self.get(name) is not None
def direct(self, name):
return self.__attrs.get(name)
def queryDescriptionFor(self, name, default=None):
return self.get(name, default)
def deferred(self):
"""Return a defered class corresponding to the interface."""
if hasattr(self, "_deferred"): return self._deferred
klass={}
exec "class %s: pass" % self.__name__ in klass
klass=klass[self.__name__]
self.__d(klass.__dict__)
self._deferred=klass
return klass
def validateInvariants(self, obj, errors=None):
"""validate object to defined invariants."""
for call in self.queryTaggedValue('invariants', []):
try:
call(obj)
except Invalid, e:
if errors is None:
raise
else:
errors.append(e)
for base in self.__bases__:
try:
base.validateInvariants(obj, errors)
except Invalid:
if errors is None:
raise
pass
if errors:
raise Invalid(errors)
def _getInterface(self, ob, name):
"""Retrieve a named interface."""
return None
def __d(self, dict):
for k, v in self.__attrs.items():
if isinstance(v, Method) and not (k in dict):
dict[k]=v
for b in self.__bases__: b.__d(dict)
def __repr__(self):
r = getattr(self, '_v_repr', self)
if r is self:
name = self.__name__
m = self.__module__
if m:
name = '%s.%s' % (m, name)
r = "<%s %s>" % (self.__class__.__name__, name)
self._v_repr = r
return r
def __call__():
# TRICK! Create the call method
#
# An embedded function is used to allow an optional argument to
# __call__ without resorting to a global marker.
#
# The evility of this trick is a reflection of the underlying
# evility of "optional" arguments, arguments whose presense or
# absense changes the behavior of the methods.
#
# I think the evil is necessary, and perhaps desireable to
# provide some consistencey with the PEP 246 adapt method.
marker = object()
def __call__(self, obj, alternate=marker):
"""Adapt an object to the interface
The sematics based on those of the PEP 246 adapt function.
If an object cannot be adapted, then a TypeError is raised::
>>> import zope.interface
>>> class I(zope.interface.Interface):
... pass
>>> I(0)
Traceback (most recent call last):
...
TypeError: ('Could not adapt', 0, """ \
"""<InterfaceClass zope.interface.interface.I>)
unless an alternate value is provided as a second
positional argument::
>>> I(0, 'bob')
'bob'
If an object already implements the interface, then it will be
returned::
>>> class C(object):
... zope.interface.implements(I)
>>> obj = C()
>>> I(obj) is obj
True
If an object implements __conform__, then it will be used::
>>> class C(object):
... zope.interface.implements(I)
... def __conform__(self, proto):
... return 0
>>> I(C())
0
Adapter hooks (see __adapt__) will also be used, if present:
>>> from zope.interface.interface import adapter_hooks
>>> def adapt_0_to_42(iface, obj):
... if obj == 0:
... return 42
>>> adapter_hooks.append(adapt_0_to_42)
>>> I(0)
42
>>> adapter_hooks.remove(adapt_0_to_42)
>>> I(0)
Traceback (most recent call last):
...
TypeError: ('Could not adapt', 0, """ \
"""<InterfaceClass zope.interface.interface.I>)
"""
conform = getattr(obj, '__conform__', None)
if conform is not None:
try:
adapter = conform(self)
except TypeError:
# We got a TypeError. It might be an error raised by
# the __conform__ implementation, or *we* may have
# made the TypeError by calling an unbound method
# (object is a class). In the later case, we behave
# as though there is no __conform__ method. We can
# detect this case by checking whether there is more
# than one traceback object in the traceback chain:
if sys.exc_info()[2].tb_next is not None:
# There is more than one entry in the chain, so
# reraise the error:
raise
# This clever trick is from Phillip Eby
else:
if adapter is not None:
return adapter
adapter = self.__adapt__(obj)
if adapter is None:
if alternate is not marker:
return alternate
raise TypeError("Could not adapt", obj, self)
return adapter
return __call__
__call__ = __call__() # TRICK! Make the *real* __call__ method
def __adapt__(self, obj):
"""Adapt an object to the reciever
This method is normally not called directly. It is called by
the PEP 246 adapt framework and by the interface __call__
operator.
The adapt method is responsible for adapting an object to
the reciever.
The default version returns None::
>>> import zope.interface
>>> class I(zope.interface.Interface):
... pass
>>> I.__adapt__(0)
unless the object given provides the interface::
>>> class C(object):
... zope.interface.implements(I)
>>> obj = C()
>>> I.__adapt__(obj) is obj
True
Adapter hooks can be provided (or removed) to provide custom
adaptation. We'll install a silly hook that adapts 0 to 42.
We install a hook by simply adding it to the adapter_hooks
list::
>>> from zope.interface.interface import adapter_hooks
>>> def adapt_0_to_42(iface, obj):
... if obj == 0:
... return 42
>>> adapter_hooks.append(adapt_0_to_42)
>>> I.__adapt__(0)
42
Hooks must either return an adapter, or None if no adapter can
be found.
Hooks can be uninstalled by removing them from the list::
>>> adapter_hooks.remove(adapt_0_to_42)
>>> I.__adapt__(0)
"""
if self.providedBy(obj):
return obj
for hook in adapter_hooks:
adapter = hook(self, obj)
if adapter is not None:
return adapter
def __reduce__(self):
return self.__name__
def __cmp(self, o1, o2):
# Yes, I did mean to name this __cmp, rather than __cmp__.
# It is a private method used by __lt__ and __gt__.
# I don't want to override __eq__ because I want the default
# __eq__, which is really fast.
"""Make interfaces sortable
TODO: It would ne nice if:
More specific interfaces should sort before less specific ones.
Otherwise, sort on name and module.
But this is too complicated, and we're going to punt on it
for now.
For now, sort on interface and module name.
None is treated as a pseudo interface that implies the loosest
contact possible, no contract. For that reason, all interfaces
sort before None.
"""
if o1 == o2:
return 0
if o1 is None:
return 1
if o2 is None:
return -1
n1 = (getattr(o1, '__name__', ''),
getattr(getattr(o1, '__module__', None), '__name__', ''))
n2 = (getattr(o2, '__name__', ''),
getattr(getattr(o2, '__module__', None), '__name__', ''))
return cmp(n1, n2)
def __lt__(self, other):
c = self.__cmp(self, other)
#print '<', self, other, c < 0, c
return c < 0
def __gt__(self, other):
c = self.__cmp(self, other)
#print '>', self, other, c > 0, c
return c > 0
adapter_hooks = []
Interface = InterfaceClass("Interface", __module__ = 'zope.interface')
class Attribute(Element):
"""Attribute descriptions
"""
# We can't say this yet because we don't have enough
# infrastructure in place.
#
# implements(IAttribute)
interface = None
class Method(Attribute):
"""Method interfaces
The idea here is that you have objects that describe methods.
This provides an opportunity for rich meta-data.
"""
# We can't say this yet because we don't have enough
# infrastructure in place.
#
# implements(IMethod)
def __call__(self, *args, **kw):
raise BrokenImplementation(self.interface, self.__name__)
def getSignatureInfo(self):
return {'positional': self.positional,
'required': self.required,
'optional': self.optional,
'varargs': self.varargs,
'kwargs': self.kwargs,
}
def getSignatureString(self):
sig = "("
for v in self.positional:
sig = sig + v
if v in self.optional.keys():
sig = sig + "=%s" % `self.optional[v]`
sig = sig + ", "
if self.varargs:
sig = sig + ("*%s, " % self.varargs)
if self.kwargs:
sig = sig + ("**%s, " % self.kwargs)
# slice off the last comma and space
if self.positional or self.varargs or self.kwargs:
sig = sig[:-2]
sig = sig + ")"
return sig
def fromFunction(func, interface=None, imlevel=0, name=None):
name = name or func.__name__
method = Method(name, func.__doc__)
defaults = func.func_defaults or ()
code = func.func_code
# Number of positional arguments
na = code.co_argcount-imlevel
names = code.co_varnames[imlevel:]
opt = {}
# Number of required arguments
nr = na-len(defaults)
if nr < 0:
defaults=defaults[-nr:]
nr = 0
# Determine the optional arguments.
for i in range(len(defaults)):
opt[names[i+nr]] = defaults[i]
method.positional = names[:na]
method.required = names[:nr]
method.optional = opt
argno = na
# Determine the function's variable argument's name (i.e. *args)
if code.co_flags & CO_VARARGS:
method.varargs = names[argno]
argno = argno + 1
else:
method.varargs = None
# Determine the function's keyword argument's name (i.e. **kw)
if code.co_flags & CO_VARKEYWORDS:
method.kwargs = names[argno]
else:
method.kwargs = None
method.interface = interface
for key, value in func.__dict__.items():
method.setTaggedValue(key, value)
return method
def fromMethod(meth, interface=None, name=None):
func = meth.im_func
return fromFunction(func, interface, imlevel=1, name=name)
# Now we can create the interesting interfaces and wire them up:
def _wire():
from zope.interface.declarations import classImplements
from zope.interface.interfaces import IAttribute
classImplements(Attribute, IAttribute)
from zope.interface.interfaces import IMethod
classImplements(Method, IMethod)
from zope.interface.interfaces import IInterface
classImplements(InterfaceClass, IInterface)
# We import this here to deal with module dependencies.
from zope.interface.declarations import providedBy, implementedBy
from zope.interface.exceptions import InvalidInterface
from zope.interface.exceptions import BrokenImplementation
##############################################################################
#
# Copyright (c) 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Interface Package Interfaces
$Id$
"""
__docformat__ = 'restructuredtext'
from zope.interface import Interface
from zope.interface.interface import Attribute
class IElement(Interface):
"""Objects that have basic documentation and tagged values.
"""
__name__ = Attribute('__name__', 'The object name')
__doc__ = Attribute('__doc__', 'The object doc string')
def getTaggedValue(tag):
"""Returns the value associated with 'tag'.
Raise a KeyError of the tag isn't set
"""
def queryTaggedValue(tag, default=None):
"""Returns the value associated with 'tag'.
Return the default value of the tag isn't set.
"""
def getTaggedValueTags():
"""Returns a list of all tags."""
def setTaggedValue(tag, value):
"""Associates 'value' with 'key'."""
class IAttribute(IElement):
"""Attribute descriptors"""
interface = Attribute('interface',
'Stores the interface instance in which the '
'attribute is located.')
class IMethod(IAttribute):
"""Method attributes
"""
def getSignatureInfo():
"""Returns the signature information.
This method returns a dictionary with the following keys:
o `positional` - All positional arguments.
o `required` - A list of all required arguments.
o `optional` - A list of all optional arguments.
o `varargs' - The name of the varargs argument.
o `kwargs` - The name of the kwargs argument.
"""
def getSignatureString():
"""Return a signature string suitable for inclusion in documentation.
This method returns the function signature string. For example, if you
have `func(a, b, c=1, d='f')`, then the signature string is `(a, b,
c=1, d='f')`.
"""
class ISpecification(Interface):
"""Object Behavioral specifications
"""
def extends(other, strict=True):
"""Test whether a specification extends another
The specification extends other if it has other as a base
interface or if one of it's bases extends other.
If strict is false, then the specification extends itself.
"""
def isOrExtends(other):
"""Test whether the specification is or extends another
"""
def weakref(callback=None):
"""Return a weakref to the specification
This method is, regrettably, needed to allow weakrefs to be
computed to security-proxied specifications. While the
zope.interface package does not require zope.security or
zope.proxy, it has to be able to coexist with it.
"""
__bases__ = Attribute("""Base specifications
A tuple if specifications from which this specification is
directly derived.
""")
__sro__ = Attribute("""Specification-resolution order
A tuple of the specification and all of it's ancestor
specifications from most specific to least specific.
(This is similar to the method-resolution order for new-style classes.)
""")
def get(name, default=None):
"""Look up the description for a name
If the named attribute is not defined, the default is
returned.
"""
class IInterface(ISpecification, IElement):
"""Interface objects
Interface objects describe the behavior of an object by containing
useful information about the object. This information includes:
o Prose documentation about the object. In Python terms, this
is called the "doc string" of the interface. In this element,
you describe how the object works in prose language and any
other useful information about the object.
o Descriptions of attributes. Attribute descriptions include
the name of the attribute and prose documentation describing
the attributes usage.
o Descriptions of methods. Method descriptions can include:
o Prose "doc string" documentation about the method and its
usage.
o A description of the methods arguments; how many arguments
are expected, optional arguments and their default values,
the position or arguments in the signature, whether the
method accepts arbitrary arguments and whether the method
accepts arbitrary keyword arguments.
o Optional tagged data. Interface objects (and their attributes and
methods) can have optional, application specific tagged data
associated with them. Examples uses for this are examples,
security assertions, pre/post conditions, and other possible
information you may want to associate with an Interface or its
attributes.
Not all of this information is mandatory. For example, you may
only want the methods of your interface to have prose
documentation and not describe the arguments of the method in
exact detail. Interface objects are flexible and let you give or
take any of these components.
Interfaces are created with the Python class statement using
either Interface.Interface or another interface, as in::
from zope.interface import Interface
class IMyInterface(Interface):
'''Interface documentation
'''
def meth(arg1, arg2):
'''Documentation for meth
'''
# Note that there is no self argument
class IMySubInterface(IMyInterface):
'''Interface documentation
'''
def meth2():
'''Documentation for meth2
'''
You use interfaces in two ways:
o You assert that your object implement the interfaces.
There are several ways that you can assert that an object
implements an interface::
1. Call zope.interface.implements in your class definition.
2. Call zope.interfaces.directlyProvides on your object.
3. Call 'zope.interface.classImplements' to assert that instances
of a class implement an interface.
For example::
from zope.interface import classImplements
classImplements(some_class, some_interface)
This approach is useful when it is not an option to modify
the class source. Note that this doesn't affect what the
class itself implements, but only what its instances
implement.
o You query interface meta-data. See the IInterface methods and
attributes for details.
"""
def providedBy(object):
"""Test whether the interface is implemented by the object
Return true of the object asserts that it implements the
interface, including asserting that it implements an extended
interface.
"""
def implementedBy(class_):
"""Test whether the interface is implemented by instances of the class
Return true of the class asserts that its instances implement the
interface, including asserting that they implement an extended
interface.
"""
def names(all=False):
"""Get the interface attribute names
Return a sequence of the names of the attributes, including
methods, included in the interface definition.
Normally, only directly defined attributes are included. If
a true positional or keyword argument is given, then
attributes defined by base classes will be included.
"""
def namesAndDescriptions(all=False):
"""Get the interface attribute names and descriptions
Return a sequence of the names and descriptions of the
attributes, including methods, as name-value pairs, included
in the interface definition.
Normally, only directly defined attributes are included. If
a true positional or keyword argument is given, then
attributes defined by base classes will be included.
"""
def __getitem__(name):
"""Get the description for a name
If the named attribute is not defined, a KeyError is raised.
"""
def direct(name):
"""Get the description for the name if it was defined by the interface
If the interface doesn't define the name, returns None.
"""
def validateInvariants(obj, errors=None):
"""Validate invariants
Validate object to defined invariants. If errors is None,
raises first Invalid error; if errors is a list, appends all errors
to list, then raises Invalid with the errors as the first element
of the "args" tuple."""
def __contains__(name):
"""Test whether the name is defined by the interface"""
def __iter__():
"""Return an iterator over the names defined by the interface
The names iterated include all of the names defined by the
interface directly and indirectly by base interfaces.
"""
__module__ = Attribute("""The name of the module defining the interface""")
class IDeclaration(ISpecification):
"""Interface declaration
Declarations are used to express the interfaces implemented by
classes or provided by objects.
"""
def __contains__(interface):
"""Test whether an interface is in the specification
Return true if the given interface is one of the interfaces in
the specification and false otherwise.
"""
def __iter__():
"""Return an iterator for the interfaces in the specification
"""
def flattened():
"""Return an iterator of all included and extended interfaces
An iterator is returned for all interfaces either included in
or extended by interfaces included in the specifications
without duplicates. The interfaces are in "interface
resolution order". The interface resolution order is such that
base interfaces are listed after interfaces that extend them
and, otherwise, interfaces are included in the order that they
were defined in the specification.
"""
def __sub__(interfaces):
"""Create an interface specification with some interfaces excluded
The argument can be an interface or an interface
specifications. The interface or interfaces given in a
specification are subtracted from the interface specification.
Removing an interface that is not in the specification does
not raise an error. Doing so has no effect.
Removing an interface also removes sub-interfaces of the interface.
"""
def __add__(interfaces):
"""Create an interface specification with some interfaces added
The argument can be an interface or an interface
specifications. The interface or interfaces given in a
specification are added to the interface specification.
Adding an interface that is already in the specification does
not raise an error. Doing so has no effect.
"""
def __nonzero__():
"""Return a true value of the interface specification is non-empty
"""
class IInterfaceDeclaration(Interface):
"""Declare and check the interfaces of objects
The functions defined in this interface are used to declare the
interfaces that objects provide and to query the interfaces that have
been declared.
Interfaces can be declared for objects in two ways:
- Interfaces are declared for instances of the object's class
- Interfaces are declared for the object directly.
The interfaces declared for an object are, therefore, the union of
interfaces declared for the object directly and the interfaces
declared for instances of the object's class.
Note that we say that a class implements the interfaces provided
by it's instances. An instance can also provide interfaces
directly. The interfaces provided by an object are the union of
the interfaces provided directly and the interfaces implemented by
the class.
"""
def providedBy(ob):
"""Return the interfaces provided by an object
This is the union of the interfaces directly provided by an
object and interfaces implemented by it's class.
The value returned is an IDeclaration.
"""
def implementedBy(class_):
"""Return the interfaces implemented for a class' instances
The value returned is an IDeclaration.
"""
def classImplements(class_, *interfaces):
"""Declare additional interfaces implemented for instances of a class
The arguments after the class are one or more interfaces or
interface specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) are added to any interfaces previously
declared.
Consider the following example::
class C(A, B):
...
classImplements(C, I1, I2)
Instances of ``C`` provide ``I1``, ``I2``, and whatever interfaces
instances of ``A`` and ``B`` provide.
"""
def implementer(*interfaces):
"""Create a decorator for declaring interfaces implemented by a facory
A callable is returned that makes an implements declaration on
objects passed to it.
"""
def classImplementsOnly(class_, *interfaces):
"""Declare the only interfaces implemented by instances of a class
The arguments after the class are one or more interfaces or
interface specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) replace any previous declarations.
Consider the following example::
class C(A, B):
...
classImplements(C, IA, IB. IC)
classImplementsOnly(C. I1, I2)
Instances of ``C`` provide only ``I1``, ``I2``, and regardless of
whatever interfaces instances of ``A`` and ``B`` implement.
"""
def directlyProvidedBy(object):
"""Return the interfaces directly provided by the given object
The value returned is an IDeclaration.
"""
def directlyProvides(object, *interfaces):
"""Declare interfaces declared directly for an object
The arguments after the object are one or more interfaces or
interface specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) replace interfaces previously
declared for the object.
Consider the following example::
class C(A, B):
...
ob = C()
directlyProvides(ob, I1, I2)
The object, ``ob`` provides ``I1``, ``I2``, and whatever interfaces
instances have been declared for instances of ``C``.
To remove directly provided interfaces, use ``directlyProvidedBy`` and
subtract the unwanted interfaces. For example::
directlyProvides(ob, directlyProvidedBy(ob)-I2)
removes I2 from the interfaces directly provided by
``ob``. The object, ``ob`` no longer directly provides ``I2``,
although it might still provide ``I2`` if it's class
implements ``I2``.
To add directly provided interfaces, use ``directlyProvidedBy`` and
include additional interfaces. For example::
directlyProvides(ob, directlyProvidedBy(ob), I2)
adds I2 to the interfaces directly provided by ob.
"""
def implements(*interfaces):
"""Declare interfaces implemented by instances of a class
This function is called in a class definition.
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
The interfaces given (including the interfaces in the
specifications) are added to any interfaces previously
declared.
Previous declarations include declarations for base classes
unless implementsOnly was used.
This function is provided for convenience. It provides a more
convenient way to call classImplements. For example::
implements(I1)
is equivalent to calling::
classImplements(C, I1)
after the class has been created.
Consider the following example::
class C(A, B):
implements(I1, I2)
Instances of ``C`` implement ``I1``, ``I2``, and whatever interfaces
instances of ``A`` and ``B`` implement.
"""
def implementsOnly(*interfaces):
"""Declare the only interfaces implemented by instances of a class
This function is called in a class definition.
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
Previous declarations including declarations for base classes
are overridden.
This function is provided for convenience. It provides a more
convenient way to call classImplementsOnly. For example::
implementsOnly(I1)
is equivalent to calling::
classImplementsOnly(I1)
after the class has been created.
Consider the following example::
class C(A, B):
implementsOnly(I1, I2)
Instances of ``C`` implement ``I1``, ``I2``, regardless of what
instances of ``A`` and ``B`` implement.
"""
def classProvides(*interfaces):
"""Declare interfaces provided directly by a class
This function is called in a class definition.
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
The given interfaces (including the interfaces in the
specifications) are used to create the class's direct-object
interface specification. An error will be raised if the module
class has an direct interface specification. In other words, it is
an error to call this function more than once in a class
definition.
Note that the given interfaces have nothing to do with the
interfaces implemented by instances of the class.
This function is provided for convenience. It provides a more
convenient way to call directlyProvides for a class. For example::
classProvides(I1)
is equivalent to calling::
directlyProvides(theclass, I1)
after the class has been created.
"""
def moduleProvides(*interfaces):
"""Declare interfaces provided by a module
This function is used in a module definition.
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
The given interfaces (including the interfaces in the
specifications) are used to create the module's direct-object
interface specification. An error will be raised if the module
already has an interface specification. In other words, it is
an error to call this function more than once in a module
definition.
This function is provided for convenience. It provides a more
convenient way to call directlyProvides for a module. For example::
moduleImplements(I1)
is equivalent to::
directlyProvides(sys.modules[__name__], I1)
"""
def Declaration(*interfaces):
"""Create an interface specification
The arguments are one or more interfaces or interface
specifications (IDeclaration objects).
A new interface specification (IDeclaration) with
the given interfaces is returned.
"""
class IAdapterRegistry(Interface):
"""Provide an interface-based registry for adapters
This registry registers objects that are in some sense "from" a
sequence of specification to an interface and a name.
No specific semantics are assumed for the registered objects,
however, the most common application will be to register factories
that adapt objects providing required specifications to a provided
interface.
"""
def register(required, provided, name, value):
"""Register a value
A value is registered for a *sequence* of required specifications, a
provided interface, and a name.
"""
def lookup(required, provided, name, default=None):
"""Lookup a value
A value is looked up based on a *sequence* of required
specifications, a provided interface, and a name.
"""
def lookupAll(required, provided):
"""Find all adapters from the required to the provided interfaces
An iterable object is returned that provides name-value two-tuples.
"""
def names(required, provided):
"""Return the names for which there are registered objects
"""
def subscribe(required, provided, subscriber):
"""Register a subscriber
A subscriber is registered for a *sequence* of required
specifications, a provided interface, and a name.
Multiple subscribers may be registered for the same (or
equivalent) interfaces.
"""
def subscriptions(required, provided):
"""Get a sequence of subscribers
Subscribers for a *sequence* of required interfaces, and a provided
interface are returned.
"""
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Compute a resolution order for an object and it's bases
$Id$
"""
def ro(object):
"""Compute a "resolution order" for an object
"""
return mergeOrderings([_flatten(object, [])])
def mergeOrderings(orderings, seen=None):
"""Merge multiple orderings so that within-ordering order is preserved
Orderings are constrained in such a way that if an object appears
in two or more orderings, then the suffix that begins with the
object must be in both orderings.
For example:
>>> _mergeOrderings([
... ['x', 'y', 'z'],
... ['q', 'z'],
... [1, 3, 5],
... ['z']
... ])
['x', 'y', 'q', 1, 3, 5, 'z']
"""
if seen is None:
seen = {}
result = []
orderings.reverse()
for ordering in orderings:
ordering = list(ordering)
ordering.reverse()
for o in ordering:
if o not in seen:
seen[o] = 1
result.append(o)
result.reverse()
return result
def _flatten(ob, result):
result.append(ob)
for base in ob.__bases__:
_flatten(base, result)
return result
#
# This file is necessary to make this directory a package.
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Dummy Module
$Id$
"""
from zope.interface import moduleProvides
from zope.interface.tests.ifoo import IFoo
from zope.interface import moduleProvides
moduleProvides(IFoo)
def bar(baz):
pass
================================
Food-based subscription examples
================================
This file gives more subscription examples using a cooking-based example::
>>> from zope.interface.adapter import AdapterRegistry
>>> registry = AdapterRegistry()
>>> import zope.interface
>>> class IAnimal(zope.interface.Interface):
... pass
>>> class IPoultry(IAnimal):
... pass
>>> class IChicken(IPoultry):
... pass
>>> class ISeafood(IAnimal):
... pass
Adapting to some other interface for which there is no
subscription adapter returns an empty sequence::
>>> class IRecipe(zope.interface.Interface):
... pass
>>> class ISausages(IRecipe):
... pass
>>> class INoodles(IRecipe):
... pass
>>> class IKFC(IRecipe):
... pass
>>> list(registry.subscriptions([IPoultry], IRecipe))
[]
unless we define a subscription::
>>> registry.subscribe([IAnimal], ISausages, 'sausages')
>>> list(registry.subscriptions([IPoultry], ISausages))
['sausages']
And define another subscription adapter::
>>> registry.subscribe([IPoultry], INoodles, 'noodles')
>>> meals = list(registry.subscriptions([IPoultry], IRecipe))
>>> meals.sort()
>>> meals
['noodles', 'sausages']
>>> registry.subscribe([IChicken], IKFC, 'kfc')
>>> meals = list(registry.subscriptions([IChicken], IRecipe))
>>> meals.sort()
>>> meals
['kfc', 'noodles', 'sausages']
And the answer for poultry hasn't changed::
>>> meals = list(registry.subscriptions([IPoultry], IRecipe))
>>> meals.sort()
>>> meals
['noodles', 'sausages']
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""IFoo test module
$Id$
"""
from zope.interface import Interface
class IFoo(Interface):
"""
Dummy interface for unit tests.
"""
def bar(baz):
"""
Just a note.
"""
##############################################################################
#
# Copyright (c) 2004 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test module that declares an interface
$Id$
"""
from zope.interface import Interface, moduleProvides
class I1(Interface): pass
class I2(Interface): pass
moduleProvides(I1, I2)
##############################################################################
#
# Copyright (c) 2004 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test module that doesn't declare an interface
$Id$
"""
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Odd meta class that doesn't subclass type.
This is used for testing support for ExtensionClass in new interfaces.
>>> class A(object):
... __metaclass__ = MetaClass
... a = 1
...
>>> A.__name__
'A'
>>> A.__bases__
()
>>> class B(object):
... __metaclass__ = MetaClass
... b = 1
...
>>> class C(A, B): pass
...
>>> C.__name__
'C'
>>> int(C.__bases__ == (A, B))
1
>>> a = A()
>>> aa = A()
>>> a.a
1
>>> aa.a
1
>>> aa.a = 2
>>> a.a
1
>>> aa.a
2
>>> c = C()
>>> c.a
1
>>> c.b
1
>>> c.b = 2
>>> c.b
2
>>> C.c = 1
>>> c.c
1
>>> from types import ClassType
>>> int(isinstance(C, (type, ClassType)))
0
>>> int(C.__class__.__class__ is C.__class__)
1
$Id$
"""
# class OddClass is an odd meta class
class MetaMetaClass(type):
def __getattribute__(self, name):
if name == '__class__':
return self
return type.__getattribute__(self, name)
class MetaClass(object):
"""Odd classes
"""
__metaclass__ = MetaMetaClass
def __init__(self, name, bases, dict):
self.__name__ = name
self.__bases__ = bases
self.__dict__.update(dict)
def __call__(self):
return OddInstance(self)
def __getattr__(self, name):
for b in self.__bases__:
v = getattr(b, name, self)
if v is not self:
return v
raise AttributeError, name
def __repr__(self):
return "<odd class %s at %s>" % (self.__name__, hex(id(self)))
class OddInstance(object):
def __init__(self, cls):
self.__dict__['__class__'] = cls
def __getattribute__(self, name):
dict = object.__getattribute__(self, '__dict__')
if name == '__dict__':
return dict
v = dict.get(name, self)
if v is not self:
return v
return getattr(dict['__class__'], name)
def __setattr__(self, name, v):
self.__dict__[name] = v
def __delattr__(self, name):
del self.__dict__[name]
def __repr__(self):
return "<odd %s instance at %s>" % (
self.__class__.__name__, hex(id(self)))
# DocTest:
if __name__ == "__main__":
import doctest, __main__
doctest.testmod(__main__, isprivate=lambda *a: False)
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Adapter registry tests
$Id$
"""
import unittest
import zope.interface
from zope.interface.adapter import AdapterRegistry
import zope.interface
class IF0(zope.interface.Interface):
pass
class IF1(IF0):
pass
class IB0(zope.interface.Interface):
pass
class IB1(IB0):
pass
class IR0(zope.interface.Interface):
pass
class IR1(IR0):
pass
def test_orderwith():
"""
>>> Interface = zope.interface.Interface
>>> bywith = {(Interface, Interface): 'A0',
... (IF0, Interface): 'A1',
... (Interface, IB0): 'A2',
... (IF0, IB0): 'A3',
... (IF1, IB0): 'A4',
... (IF0, IB1): 'A5',
... (IF1, IB1): 'A6',
... }
>>> [value for spec, value in zope.interface.adapter.orderwith(bywith)]
['A6', 'A4', 'A5', 'A3', 'A1', 'A2', 'A0']
"""
def test_multi_adapter_get_best_match():
"""
>>> registry = AdapterRegistry()
>>> class IB2(IB0):
... pass
>>> class IB3(IB2, IB1):
... pass
>>> class IB4(IB1, IB2):
... pass
>>> registry.register([None, IB1], IR0, '', 'A1')
>>> registry.register([None, IB0], IR0, '', 'A0')
>>> registry.register([None, IB2], IR0, '', 'A2')
>>> registry.lookup((IF1, IB1), IR0, '')
'A1'
>>> registry.lookup((IF1, IB2), IR0, '')
'A2'
>>> registry.lookup((IF1, IB0), IR0, '')
'A0'
>>> registry.lookup((IF1, IB3), IR0, '')
'A2'
>>> registry.lookup((IF1, IB4), IR0, '')
'A1'
"""
def test_multi_adapter_lookupAll_get_best_matches():
"""
>>> registry = AdapterRegistry()
>>> class IB2(IB0):
... pass
>>> class IB3(IB2, IB1):
... pass
>>> class IB4(IB1, IB2):
... pass
>>> registry.register([None, IB1], IR0, '', 'A1')
>>> registry.register([None, IB0], IR0, '', 'A0')
>>> registry.register([None, IB2], IR0, '', 'A2')
>>> registry.lookupAll((IF1, IB1), IR0).next()[1]
'A1'
>>> registry.lookupAll((IF1, IB2), IR0).next()[1]
'A2'
>>> registry.lookupAll((IF1, IB0), IR0).next()[1]
'A0'
>>> registry.lookupAll((IF1, IB3), IR0).next()[1]
'A2'
>>> registry.lookupAll((IF1, IB4), IR0).next()[1]
'A1'
"""
def test_multi_adapter_w_default():
"""
>>> registry = AdapterRegistry()
>>> registry.register([None, None], IB1, 'bob', 'A0')
>>> registry.lookup((IF1, IR1), IB0, 'bob')
'A0'
>>> registry.register([None, IR0], IB1, 'bob', 'A1')
>>> registry.lookup((IF1, IR1), IB0, 'bob')
'A1'
>>> registry.lookup((IF1, IR1), IB0, 'bruce')
>>> registry.register([None, IR1], IB1, 'bob', 'A2')
>>> registry.lookup((IF1, IR1), IB0, 'bob')
'A2'
"""
def test_multi_adapter_w_inherited_and_multiple_registrations():
"""
>>> registry = AdapterRegistry()
>>> class IX(zope.interface.Interface):
... pass
>>> registry.register([IF0, IR0], IB1, 'bob', 'A1')
>>> registry.register([IF1, IX], IB1, 'bob', 'AX')
>>> registry.lookup((IF1, IR1), IB0, 'bob')
'A1'
"""
def test_named_adapter_with_default():
"""Query a named simple adapter
>>> registry = AdapterRegistry()
If we ask for a named adapter, we won't get a result unless there
is a named adapter, even if the object implements the interface:
>>> registry.lookup([IF1], IF0, 'bob')
>>> registry.register([None], IB1, 'bob', 'A1')
>>> registry.lookup([IF1], IB0, 'bob')
'A1'
>>> registry.lookup([IF1], IB0, 'bruce')
>>> registry.register([None], IB0, 'bob', 'A2')
>>> registry.lookup([IF1], IB0, 'bob')
'A2'
"""
def test_multi_adapter_gets_closest_provided():
"""
>>> registry = AdapterRegistry()
>>> registry.register([IF1, IR0], IB0, 'bob', 'A1')
>>> registry.register((IF1, IR0), IB1, 'bob', 'A2')
>>> registry.lookup((IF1, IR1), IB0, 'bob')
'A1'
>>> registry = AdapterRegistry()
>>> registry.register([IF1, IR0], IB1, 'bob', 'A2')
>>> registry.register([IF1, IR0], IB0, 'bob', 'A1')
>>> registry.lookup([IF1, IR0], IB0, 'bob')
'A1'
>>> registry = AdapterRegistry()
>>> registry.register([IF1, IR0], IB0, 'bob', 'A1')
>>> registry.register([IF1, IR1], IB1, 'bob', 'A2')
>>> registry.lookup([IF1, IR1], IB0, 'bob')
'A2'
>>> registry = AdapterRegistry()
>>> registry.register([IF1, IR1], IB1, 'bob', 2)
>>> registry.register([IF1, IR0], IB0, 'bob', 1)
>>> registry.lookup([IF1, IR1], IB0, 'bob')
2
"""
def test_multi_adapter_check_non_default_dont_hide_default():
"""
>>> registry = AdapterRegistry()
>>> class IX(zope.interface.Interface):
... pass
>>> registry.register([None, IR0], IB0, 'bob', 1)
>>> registry.register([IF1, IX], IB0, 'bob', 2)
>>> registry.lookup([IF1, IR1], IB0, 'bob')
1
"""
def test_adapter_hook_with_factory_producing_None():
"""
>>> registry = AdapterRegistry()
>>> default = object()
>>> class Object1(object):
... zope.interface.implements(IF0)
>>> class Object2(object):
... zope.interface.implements(IF0)
>>> def factory(context):
... if isinstance(context, Object1):
... return 'adapter'
... return None
>>> registry.register([IF0], IB0, '', factory)
>>> registry.adapter_hook(IB0, Object1())
'adapter'
>>> registry.adapter_hook(IB0, Object2()) is None
True
>>> registry.adapter_hook(IB0, Object2(), default=default) is default
True
"""
def test_adapter_registry_update_upon_interface_bases_change():
"""
Let's first create a adapter registry and a simple adaptation hook:
>>> globalRegistry = AdapterRegistry()
>>> def _hook(iface, ob, lookup=globalRegistry.lookup1):
... factory = lookup(zope.interface.providedBy(ob), iface)
... if factory is None:
... return None
... else:
... return factory(ob)
>>> zope.interface.interface.adapter_hooks.append(_hook)
Now we create some interfaces and an implementation:
>>> class IX(zope.interface.Interface):
... pass
>>> class IY(zope.interface.Interface):
... pass
>>> class X(object):
... pass
>>> class Y(object):
... zope.interface.implements(IY)
... def __init__(self, original):
... self.original=original
and register an adapter:
>>> globalRegistry.register((IX,), IY, '', Y)
at first, we still expect the adapter lookup from `X` to `IY` to fail:
>>> IY(X()) #doctest: +NORMALIZE_WHITESPACE +ELLIPSIS
Traceback (most recent call last):
...
TypeError: ('Could not adapt',
<zope.interface.tests.test_adapter.X object at ...>,
<InterfaceClass zope.interface.tests.test_adapter.IY>)
But after we declare an interface on the class `X`, it should pass:
>>> zope.interface.classImplementsOnly(X, IX)
>>> IY(X()) #doctest: +ELLIPSIS
<zope.interface.tests.test_adapter.Y object at ...>
>>> hook = zope.interface.interface.adapter_hooks.pop()
"""
def test_suite():
from zope.testing import doctest, doctestunit
return unittest.TestSuite((
doctestunit.DocFileSuite('../adapter.txt', '../human.txt',
'foodforthought.txt',
globs={'__name__': '__main__'}),
doctest.DocTestSuite(),
))
if __name__ == '__main__':
unittest.main(defaultTest='test_suite')
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Tests for advice
This module was adapted from 'protocols.tests.advice', part of the Python
Enterprise Application Kit (PEAK). Please notify the PEAK authors
(pje@telecommunity.com and tsarna@sarna.org) if bugs are found or
Zope-specific changes are required, so that the PEAK version of this module
can be kept in sync.
PEAK is a Python application framework that interoperates with (but does
not require) Zope 3 and Twisted. It provides tools for manipulating UML
models, object-relational persistence, aspect-oriented programming, and more.
Visit the PEAK home page at http://peak.telecommunity.com for more information.
$Id$
"""
from unittest import TestCase, makeSuite, TestSuite
from zope.interface.advice import *
from types import ClassType
import sys
def ping(log, value):
def pong(klass):
log.append((value,klass))
return [klass]
addClassAdvisor(pong)
class ClassicClass:
__metaclass__ = ClassType
classLevelFrameInfo = getFrameInfo(sys._getframe())
class NewStyleClass:
__metaclass__ = type
classLevelFrameInfo = getFrameInfo(sys._getframe())
moduleLevelFrameInfo = getFrameInfo(sys._getframe())
class FrameInfoTest(TestCase):
classLevelFrameInfo = getFrameInfo(sys._getframe())
def checkModuleInfo(self):
kind, module, f_locals, f_globals = moduleLevelFrameInfo
self.assertEquals(kind, "module")
for d in module.__dict__, f_locals, f_globals:
self.assert_(d is globals())
def checkClassicClassInfo(self):
kind, module, f_locals, f_globals = ClassicClass.classLevelFrameInfo
self.assertEquals(kind, "class")
self.assert_(f_locals is ClassicClass.__dict__) # ???
for d in module.__dict__, f_globals:
self.assert_(d is globals())
def checkNewStyleClassInfo(self):
kind, module, f_locals, f_globals = NewStyleClass.classLevelFrameInfo
self.assertEquals(kind, "class")
for d in module.__dict__, f_globals:
self.assert_(d is globals())
def checkCallInfo(self):
kind, module, f_locals, f_globals = getFrameInfo(sys._getframe())
self.assertEquals(kind, "function call")
self.assert_(f_locals is locals()) # ???
for d in module.__dict__, f_globals:
self.assert_(d is globals())
class AdviceTests(TestCase):
def checkOrder(self):
log = []
class Foo(object):
ping(log, 1)
ping(log, 2)
ping(log, 3)
# Strip the list nesting
for i in 1,2,3:
self.assert_(isinstance(Foo, list))
Foo, = Foo
self.assertEquals(log, [(1, Foo), (2, [Foo]), (3, [[Foo]])])
def XXXcheckOutside(self):
# Disabled because the check does not work with doctest tests.
try:
ping([], 1)
except SyntaxError:
pass
else:
raise AssertionError(
"Should have detected advice outside class body"
)
def checkDoubleType(self):
if sys.hexversion >= 0x02030000:
return # you can't duplicate bases in 2.3
class aType(type,type):
ping([],1)
aType, = aType
self.assert_(aType.__class__ is type)
def checkSingleExplicitMeta(self):
class M(type):
pass
class C(M):
__metaclass__ = M
ping([],1)
C, = C
self.assert_(C.__class__ is M)
def checkMixedMetas(self):
class M1(type): pass
class M2(type): pass
class B1: __metaclass__ = M1
class B2: __metaclass__ = M2
try:
class C(B1,B2):
ping([],1)
except TypeError:
pass
else:
raise AssertionError("Should have gotten incompatibility error")
class M3(M1,M2): pass
class C(B1,B2):
__metaclass__ = M3
ping([],1)
self.assert_(isinstance(C,list))
C, = C
self.assert_(isinstance(C,M3))
def checkMetaOfClass(self):
class metameta(type):
pass
class meta(type):
__metaclass__ = metameta
self.assertEquals(determineMetaclass((meta, type)), metameta)
TestClasses = (AdviceTests, FrameInfoTest)
def test_suite():
return TestSuite([makeSuite(t,'check') for t in TestClasses])
if __name__ == '__main__':
unittest.main(defaultTest=test_suite)
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test the new API for making and checking interface declarations
$Id$
"""
import unittest
from zope.interface import *
from zope.testing.doctestunit import DocTestSuite
from zope.interface import Interface
class I1(Interface): pass
class I2(Interface): pass
class I3(Interface): pass
class I4(Interface): pass
class I5(Interface): pass
class A(object):
implements(I1)
class B(object):
implements(I2)
class C(A, B):
implements(I3)
class COnly(A, B):
implementsOnly(I3)
class COnly_old(A, B):
__implemented__ = I3
class D(COnly):
implements(I5)
def test_ObjectSpecification_Simple():
"""
>>> c = C()
>>> directlyProvides(c, I4)
>>> [i.__name__ for i in providedBy(c)]
['I4', 'I3', 'I1', 'I2']
"""
def test_ObjectSpecification_Simple_w_only():
"""
>>> c = COnly()
>>> directlyProvides(c, I4)
>>> [i.__name__ for i in providedBy(c)]
['I4', 'I3']
"""
def test_ObjectSpecification_Simple_old_style():
"""
>>> c = COnly_old()
>>> directlyProvides(c, I4)
>>> [i.__name__ for i in providedBy(c)]
['I4', 'I3']
"""
class Test(unittest.TestCase):
# Note that most of the tests are in the doc strings of the
# declarations module.
def test_backward_compat(self):
class C1(object): __implemented__ = I1
class C2(C1): __implemented__ = I2, I5
class C3(C2): __implemented__ = I3, C2.__implemented__
self.assert_(C3.__implemented__.__class__ is tuple)
self.assertEqual(
[i.getName() for i in providedBy(C3())],
['I3', 'I2', 'I5'],
)
class C4(C3):
implements(I4)
self.assertEqual(
[i.getName() for i in providedBy(C4())],
['I4', 'I3', 'I2', 'I5'],
)
self.assertEqual(
[i.getName() for i in C4.__implemented__],
['I4', 'I3', 'I2', 'I5'],
)
# Note that C3.__implemented__ should now be a sequence of interfaces
self.assertEqual(
[i.getName() for i in C3.__implemented__],
['I3', 'I2', 'I5'],
)
self.failIf(C3.__implemented__.__class__ is tuple)
def test_module(self):
import zope.interface.tests.m1
import zope.interface.tests.m2
directlyProvides(zope.interface.tests.m2,
zope.interface.tests.m1.I1,
zope.interface.tests.m1.I2,
)
self.assertEqual(list(providedBy(zope.interface.tests.m1)),
list(providedBy(zope.interface.tests.m2)),
)
def test_builtins(self):
# Setup
intspec = implementedBy(int)
olddeclared = intspec.declared
classImplements(int, I1)
class myint(int):
implements(I2)
x = 42
self.assertEqual([i.getName() for i in providedBy(x)],
['I1'])
x = myint(42)
directlyProvides(x, I3)
self.assertEqual([i.getName() for i in providedBy(x)],
['I3', 'I2', 'I1'])
# cleanup
intspec.declared = olddeclared
classImplements(int)
x = 42
self.assertEqual([i.getName() for i in providedBy(x)],
[])
def test_signature_w_no_class_interfaces():
"""
>>> from zope.interface import *
>>> class C(object):
... pass
>>> c = C()
>>> list(providedBy(c))
[]
>>> class I(Interface):
... pass
>>> directlyProvides(c, I)
>>> list(providedBy(c)) == list(directlyProvidedBy(c))
1
"""
def test_classImplement_on_deeply_nested_classes():
"""This test is in response to a bug found, which is why it's a bit
contrived
>>> from zope.interface import *
>>> class B1(object):
... pass
>>> class B2(B1):
... pass
>>> class B3(B2):
... pass
>>> class D(object):
... implements()
>>> class S(B3, D):
... implements()
This failed due to a bug in the code for finding __providedBy__
descriptors for old-style classes.
"""
def test_pickle_provides_specs():
"""
>>> from pickle import dumps, loads
>>> a = A()
>>> I2.providedBy(a)
0
>>> directlyProvides(a, I2)
>>> I2.providedBy(a)
1
>>> a2 = loads(dumps(a))
>>> I2.providedBy(a2)
1
"""
def test_that_we_dont_inherit_class_provides():
"""
>>> class X(object):
... classProvides(I1)
>>> class Y(X):
... pass
>>> [i.__name__ for i in X.__provides__]
['I1']
>>> Y.__provides__
Traceback (most recent call last):
...
AttributeError: __provides__
"""
def test_that_we_dont_inherit_provides_optimizations():
"""
When we make a declaration for a class, we install a __provides__
descriptors that provides a default for instances that don't have
instance-specific declarations:
>>> class A(object):
... implements(I1)
>>> class B(object):
... implements(I2)
>>> [i.__name__ for i in A().__provides__]
['I1']
>>> [i.__name__ for i in B().__provides__]
['I2']
But it's important that we don't use this for subclasses without
declarations. This would cause incorrect results:
>>> class X(A, B):
... pass
>>> X().__provides__
Traceback (most recent call last):
...
AttributeError: __provides__
However, if we "induce" a declaration, by calling implementedBy
(even indirectly through providedBy):
>>> [i.__name__ for i in providedBy(X())]
['I1', 'I2']
then the optimization will work:
>>> [i.__name__ for i in X().__provides__]
['I1', 'I2']
"""
def test_classProvides_before_implements():
"""Special descriptor for class __provides__
The descriptor caches the implementedBy info, so that
we can get declarations for objects without instance-specific
interfaces a bit quicker.
For example::
>>> from zope.interface import Interface
>>> class IFooFactory(Interface):
... pass
>>> class IFoo(Interface):
... pass
>>> class C(object):
... classProvides(IFooFactory)
... implements(IFoo)
>>> [i.getName() for i in C.__provides__]
['IFooFactory']
>>> [i.getName() for i in C().__provides__]
['IFoo']
"""
def test_getting_spec_for_proxied_builtin_class():
"""
In general, we should be able to get a spec
for a proxied class if someone has declared or
asked for a spec before.
We don't want to depend on proxies in this (zope.interface)
package, but we do want to work with proxies. Proxies have the
effect that a class's __dict__ cannot be gotten. Further, for
built-in classes, we can't save, and thus, cannot get, any class
attributes. We'll emulate this by treating a plain object as a class:
>>> cls = object()
We'll create an implements specification:
>>> import zope.interface.declarations
>>> impl = zope.interface.declarations.Implements(I1, I2)
Now, we'll emulate a declaration for a built-in type by putting
it in BuiltinImplementationSpecifications:
>>> zope.interface.declarations.BuiltinImplementationSpecifications[
... cls] = impl
Now, we should be able to get it back:
>>> implementedBy(cls) is impl
True
"""
def test_declaration_get():
"""
We can get definitions from a declaration:
>>> import zope.interface
>>> class I1(zope.interface.Interface):
... a11 = zope.interface.Attribute('a11')
... a12 = zope.interface.Attribute('a12')
>>> class I2(zope.interface.Interface):
... a21 = zope.interface.Attribute('a21')
... a22 = zope.interface.Attribute('a22')
... a12 = zope.interface.Attribute('a212')
>>> class I11(I1):
... a11 = zope.interface.Attribute('a111')
>>> decl = Declaration(I11, I2)
>>> decl.get('a11') is I11.get('a11')
True
>>> decl.get('a12') is I1.get('a12')
True
>>> decl.get('a21') is I2.get('a21')
True
>>> decl.get('a22') is I2.get('a22')
True
>>> decl.get('a')
>>> decl.get('a', 42)
42
We get None even with no interfaces:
>>> decl = Declaration()
>>> decl.get('a11')
>>> decl.get('a11', 42)
42
We get new data if e change interface bases:
>>> decl.__bases__ = I11, I2
>>> decl.get('a11') is I11.get('a11')
True
"""
def test_suite():
suite = unittest.TestSuite()
suite.addTest(unittest.makeSuite(Test))
suite.addTest(DocTestSuite("zope.interface.declarations"))
suite.addTest(DocTestSuite())
return suite
if __name__ == '__main__':
unittest.main()
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Documentation tests.
$Id$
"""
from unittest import TestCase, main, makeSuite
from zope.interface import Interface, Attribute
class Test(TestCase):
def testBlech(self):
from zope.interface.document import asStructuredText
self.assertEqual(asStructuredText(I2), '''\
I2
I2 doc
This interface extends:
o _I1
Attributes:
a1 -- no documentation
a2 -- a2 doc
Methods:
f21() -- f21 doc
f22() -- no documentation
f23() -- f23 doc
''')
def test_suite():
return makeSuite(Test)
class _I1(Interface):
def f11(): pass
def f12(): pass
class I2(_I1):
"I2 doc"
a1 = Attribute('a1')
a2 = Attribute('a2', 'a2 doc')
def f21(): "f21 doc"
def f22(): pass
def f23(): "f23 doc"
if __name__=='__main__':
main(defaultTest='test_suite')
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test Element meta-class.
$Id$
"""
import unittest
from zope.interface.interface import Element
class TestElement(unittest.TestCase):
def test_taggedValues(self):
"""Test that we can update tagged values of more than one element
"""
e1 = Element("foo")
e2 = Element("bar")
e1.setTaggedValue("x", 1)
e2.setTaggedValue("x", 2)
self.assertEqual(e1.getTaggedValue("x"), 1)
self.assertEqual(e2.getTaggedValue("x"), 2)
def test_suite():
suite = unittest.TestSuite()
suite.addTest(unittest.makeSuite(TestElement))
return suite
if __name__ == '__main__':
unittest.main(defaultTest=test_suite)
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test Interface implementation
$Id$
"""
import unittest
from zope.testing.doctestunit import DocTestSuite
from zope.interface.tests.unitfixtures import * # hehehe
from zope.interface.exceptions import BrokenImplementation, Invalid
from zope.interface import implementedBy, providedBy
from zope.interface import Interface, directlyProvides, Attribute
class InterfaceTests(unittest.TestCase):
def testInterfaceSetOnAttributes(self):
self.assertEqual(FooInterface['foobar'].interface,
FooInterface)
self.assertEqual(FooInterface['aMethod'].interface,
FooInterface)
def testClassImplements(self):
self.assert_(IC.implementedBy(C))
self.assert_(I1.implementedBy(A))
self.assert_(I1.implementedBy(B))
self.assert_(not I1.implementedBy(C))
self.assert_(I1.implementedBy(D))
self.assert_(I1.implementedBy(E))
self.assert_(not I2.implementedBy(A))
self.assert_(I2.implementedBy(B))
self.assert_(not I2.implementedBy(C))
# No longer after interfacegeddon
# self.assert_(not I2.implementedBy(D))
self.assert_(not I2.implementedBy(E))
def testUtil(self):
self.assert_(IC in implementedBy(C))
self.assert_(I1 in implementedBy(A))
self.assert_(not I1 in implementedBy(C))
self.assert_(I2 in implementedBy(B))
self.assert_(not I2 in implementedBy(C))
self.assert_(IC in providedBy(C()))
self.assert_(I1 in providedBy(A()))
self.assert_(not I1 in providedBy(C()))
self.assert_(I2 in providedBy(B()))
self.assert_(not I2 in providedBy(C()))
def testObjectImplements(self):
self.assert_(IC.providedBy(C()))
self.assert_(I1.providedBy(A()))
self.assert_(I1.providedBy(B()))
self.assert_(not I1.providedBy(C()))
self.assert_(I1.providedBy(D()))
self.assert_(I1.providedBy(E()))
self.assert_(not I2.providedBy(A()))
self.assert_(I2.providedBy(B()))
self.assert_(not I2.providedBy(C()))
# Not after interface geddon
# self.assert_(not I2.providedBy(D()))
self.assert_(not I2.providedBy(E()))
def testDeferredClass(self):
a = A()
self.assertRaises(BrokenImplementation, a.ma)
def testInterfaceExtendsInterface(self):
self.assert_(BazInterface.extends(BobInterface))
self.assert_(BazInterface.extends(BarInterface))
self.assert_(BazInterface.extends(FunInterface))
self.assert_(not BobInterface.extends(FunInterface))
self.assert_(not BobInterface.extends(BarInterface))
self.assert_(BarInterface.extends(FunInterface))
self.assert_(not BarInterface.extends(BazInterface))
def testVerifyImplementation(self):
from zope.interface.verify import verifyClass
self.assert_(verifyClass(FooInterface, Foo))
self.assert_(Interface.providedBy(I1))
def test_names(self):
names = list(_I2.names()); names.sort()
self.assertEqual(names, ['f21', 'f22', 'f23'])
names = list(_I2.names(all=True)); names.sort()
self.assertEqual(names, ['a1', 'f11', 'f12', 'f21', 'f22', 'f23'])
def test_namesAndDescriptions(self):
names = [nd[0] for nd in _I2.namesAndDescriptions()]; names.sort()
self.assertEqual(names, ['f21', 'f22', 'f23'])
names = [nd[0] for nd in _I2.namesAndDescriptions(1)]; names.sort()
self.assertEqual(names, ['a1', 'f11', 'f12', 'f21', 'f22', 'f23'])
for name, d in _I2.namesAndDescriptions(1):
self.assertEqual(name, d.__name__)
def test_getDescriptionFor(self):
self.assertEqual(_I2.getDescriptionFor('f11').__name__, 'f11')
self.assertEqual(_I2.getDescriptionFor('f22').__name__, 'f22')
self.assertEqual(_I2.queryDescriptionFor('f33', self), self)
self.assertRaises(KeyError, _I2.getDescriptionFor, 'f33')
def test___getitem__(self):
self.assertEqual(_I2['f11'].__name__, 'f11')
self.assertEqual(_I2['f22'].__name__, 'f22')
self.assertEqual(_I2.get('f33', self), self)
self.assertRaises(KeyError, _I2.__getitem__, 'f33')
def test___contains__(self):
self.failUnless('f11' in _I2)
self.failIf('f33' in _I2)
def test___iter__(self):
names = list(iter(_I2))
names.sort()
self.assertEqual(names, ['a1', 'f11', 'f12', 'f21', 'f22', 'f23'])
def testAttr(self):
description = _I2.getDescriptionFor('a1')
self.assertEqual(description.__name__, 'a1')
self.assertEqual(description.__doc__, 'This is an attribute')
def testFunctionAttributes(self):
# Make sure function attributes become tagged values.
meth = _I1['f12']
self.assertEqual(meth.getTaggedValue('optional'), 1)
def testInvariant(self):
# set up
o = InvariantC()
directlyProvides(o, IInvariant)
# a helper
def errorsEqual(self, o, error_len, error_msgs, interface=None):
if interface is None:
interface = IInvariant
self.assertRaises(Invalid, interface.validateInvariants, o)
e = []
try:
interface.validateInvariants(o, e)
except Invalid, error:
self.assertEquals(error.args[0], e)
else:
self._assert(0) # validateInvariants should always raise
# Invalid
self.assertEquals(len(e), error_len)
msgs = [error.args[0] for error in e]
msgs.sort()
for msg in msgs:
self.assertEquals(msg, error_msgs.pop(0))
# the tests
self.assertEquals(IInvariant.getTaggedValue('invariants'),
[ifFooThenBar])
self.assertEquals(IInvariant.validateInvariants(o), None)
o.bar = 27
self.assertEquals(IInvariant.validateInvariants(o), None)
o.foo = 42
self.assertEquals(IInvariant.validateInvariants(o), None)
del o.bar
errorsEqual(self, o, 1, ['If Foo, then Bar!'])
# nested interfaces with invariants:
self.assertEquals(ISubInvariant.getTaggedValue('invariants'),
[BarGreaterThanFoo])
o = InvariantC()
directlyProvides(o, ISubInvariant)
o.foo = 42
# even though the interface has changed, we should still only have one
# error.
errorsEqual(self, o, 1, ['If Foo, then Bar!'], ISubInvariant)
# however, if we set foo to 0 (Boolean False) and bar to a negative
# number then we'll get the new error
o.foo = 2
o.bar = 1
errorsEqual(self, o, 1, ['Please, Boo MUST be greater than Foo!'],
ISubInvariant)
# and if we set foo to a positive number and boo to 0, we'll
# get both errors!
o.foo = 1
o.bar = 0
errorsEqual(self, o, 2, ['If Foo, then Bar!',
'Please, Boo MUST be greater than Foo!'],
ISubInvariant)
# for a happy ending, we'll make the invariants happy
o.foo = 1
o.bar = 2
self.assertEquals(IInvariant.validateInvariants(o), None) # woohoo
# now we'll do two invariants on the same interface,
# just to make sure that a small
# multi-invariant interface is at least minimally tested.
o = InvariantC()
directlyProvides(o, IInvariant)
o.foo = 42
old_invariants = IInvariant.getTaggedValue('invariants')
invariants = old_invariants[:]
invariants.append(BarGreaterThanFoo) # if you really need to mutate,
# then this would be the way to do it. Probably a bad idea, though. :-)
IInvariant.setTaggedValue('invariants', invariants)
#
# even though the interface has changed, we should still only have one
# error.
errorsEqual(self, o, 1, ['If Foo, then Bar!'])
# however, if we set foo to 0 (Boolean False) and bar to a negative
# number then we'll get the new error
o.foo = 2
o.bar = 1
errorsEqual(self, o, 1, ['Please, Boo MUST be greater than Foo!'])
# and if we set foo to a positive number and boo to 0, we'll
# get both errors!
o.foo = 1
o.bar = 0
errorsEqual(self, o, 2, ['If Foo, then Bar!',
'Please, Boo MUST be greater than Foo!'])
# for another happy ending, we'll make the invariants happy again
o.foo = 1
o.bar = 2
self.assertEquals(IInvariant.validateInvariants(o), None) # bliss
# clean up
IInvariant.setTaggedValue('invariants', old_invariants)
def test___doc___element(self):
class I(Interface):
"xxx"
self.assertEqual(I.__doc__, "xxx")
self.assertEqual(list(I), [])
class I(Interface):
"xxx"
__doc__ = Attribute('the doc')
self.assertEqual(I.__doc__, "")
self.assertEqual(list(I), ['__doc__'])
def testIssue228(self):
# Test for http://collector.zope.org/Zope3-dev/228
class I(Interface):
"xxx"
class Bad:
__providedBy__ = None
# Old style classes don't have a '__class__' attribute
self.failUnlessRaises(AttributeError, I.providedBy, Bad)
class _I1(Interface):
a1 = Attribute("This is an attribute")
def f11(): pass
def f12(): pass
f12.optional = 1
class _I1_(_I1): pass
class _I1__(_I1_): pass
class _I2(_I1__):
def f21(): pass
def f22(): pass
f23 = f22
def test_suite():
from zope.testing import doctest
suite = unittest.makeSuite(InterfaceTests)
suite.addTest(doctest.DocTestSuite("zope.interface.interface"))
suite.addTest(doctest.DocFileSuite(
'../README.txt',
globs={'__name__': '__main__'},
optionflags=doctest.NORMALIZE_WHITESPACE,
))
return suite
def main():
unittest.TextTestRunner().run(test_suite())
if __name__=="__main__":
main()
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test interface declarations against ExtensionClass-like classes.
These tests are to make sure we do something sane in the presense of
classic ExtensionClass classes and instances.
$Id$
"""
import unittest, odd
from zope.interface import Interface, implements, implementsOnly
from zope.interface import directlyProvides, providedBy, directlyProvidedBy
from zope.interface import classImplements, classImplementsOnly, implementedBy
class I1(Interface): pass
class I2(Interface): pass
class I3(Interface): pass
class I31(I3): pass
class I4(Interface): pass
class I5(Interface): pass
class Odd(object): __metaclass__ = odd.MetaClass
class B(Odd): __implemented__ = I2
# TODO: We are going to need more magic to make classProvides work with odd
# classes. This will work in the next iteration. For now, we'll use
# a different mechanism.
# from zope.interface import classProvides
class A(Odd):
implements(I1)
class C(A, B):
implements(I31)
class Test(unittest.TestCase):
def test_ObjectSpecification(self):
c = C()
directlyProvides(c, I4)
self.assertEqual([i.getName() for i in providedBy(c)],
['I4', 'I31', 'I1', 'I2']
)
self.assertEqual([i.getName() for i in providedBy(c).flattened()],
['I4', 'I31', 'I3', 'I1', 'I2', 'Interface']
)
self.assert_(I1 in providedBy(c))
self.failIf(I3 in providedBy(c))
self.assert_(providedBy(c).extends(I3))
self.assert_(providedBy(c).extends(I31))
self.failIf(providedBy(c).extends(I5))
class COnly(A, B):
implementsOnly(I31)
class D(COnly):
implements(I5)
classImplements(D, I5)
c = D()
directlyProvides(c, I4)
self.assertEqual([i.getName() for i in providedBy(c)],
['I4', 'I5', 'I31'])
self.assertEqual([i.getName() for i in providedBy(c).flattened()],
['I4', 'I5', 'I31', 'I3', 'Interface'])
self.failIf(I1 in providedBy(c))
self.failIf(I3 in providedBy(c))
self.assert_(providedBy(c).extends(I3))
self.failIf(providedBy(c).extends(I1))
self.assert_(providedBy(c).extends(I31))
self.assert_(providedBy(c).extends(I5))
class COnly(A, B): __implemented__ = I31
class D(COnly):
implements(I5)
classImplements(D, I5)
c = D()
directlyProvides(c, I4)
self.assertEqual([i.getName() for i in providedBy(c)],
['I4', 'I5', 'I31'])
self.assertEqual([i.getName() for i in providedBy(c).flattened()],
['I4', 'I5', 'I31', 'I3', 'Interface'])
self.failIf(I1 in providedBy(c))
self.failIf(I3 in providedBy(c))
self.assert_(providedBy(c).extends(I3))
self.failIf(providedBy(c).extends(I1))
self.assert_(providedBy(c).extends(I31))
self.assert_(providedBy(c).extends(I5))
def test_classImplements(self):
class A(Odd):
implements(I3)
class B(Odd):
implements(I4)
class C(A, B):
pass
classImplements(C, I1, I2)
self.assertEqual([i.getName() for i in implementedBy(C)],
['I1', 'I2', 'I3', 'I4'])
classImplements(C, I5)
self.assertEqual([i.getName() for i in implementedBy(C)],
['I1', 'I2', 'I5', 'I3', 'I4'])
def test_classImplementsOnly(self):
class A(Odd):
implements(I3)
class B(Odd):
implements(I4)
class C(A, B):
pass
classImplementsOnly(C, I1, I2)
self.assertEqual([i.__name__ for i in implementedBy(C)],
['I1', 'I2'])
def test_directlyProvides(self):
class IA1(Interface): pass
class IA2(Interface): pass
class IB(Interface): pass
class IC(Interface): pass
class A(Odd):
implements(IA1, IA2)
class B(Odd):
implements(IB)
class C(A, B):
implements(IC)
ob = C()
directlyProvides(ob, I1, I2)
self.assert_(I1 in providedBy(ob))
self.assert_(I2 in providedBy(ob))
self.assert_(IA1 in providedBy(ob))
self.assert_(IA2 in providedBy(ob))
self.assert_(IB in providedBy(ob))
self.assert_(IC in providedBy(ob))
directlyProvides(ob, directlyProvidedBy(ob)-I2)
self.assert_(I1 in providedBy(ob))
self.failIf(I2 in providedBy(ob))
self.failIf(I2 in providedBy(ob))
directlyProvides(ob, directlyProvidedBy(ob), I2)
self.assert_(I2 in providedBy(ob))
def test_directlyProvides_fails_for_odd_class(self):
self.assertRaises(TypeError, directlyProvides, C, I5)
# XXX see above
def XXX_test_classProvides_fails_for_odd_class(self):
try:
class A(Odd):
classProvides(I1)
except TypeError:
pass # Sucess
self.assert_(False,
"Shouldn't be able to use directlyProvides on odd class."
)
def test_implementedBy(self):
class I2(I1): pass
class C1(Odd):
implements(I2)
class C2(C1):
implements(I3)
self.assertEqual([i.getName() for i in implementedBy(C2)],
['I3', 'I2'])
def test_suite():
suite = unittest.TestSuite()
suite.addTest(unittest.makeSuite(Test))
return suite
if __name__ == '__main__':
unittest.main()
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test interface sorting
$Id$
"""
from unittest import TestCase, TestSuite, main, makeSuite
from zope.interface import Interface
class I1(Interface): pass
class I2(I1): pass
class I3(I1): pass
class I4(Interface): pass
class I5(I4): pass
class I6(I2): pass
class Test(TestCase):
def test(self):
l = [I1, I3, I5, I6, I4, I2]
l.sort()
self.assertEqual(l, [I1, I2, I3, I4, I5, I6])
def test_w_None(self):
l = [I1, None, I3, I5, None, I6, I4, I2]
l.sort()
self.assertEqual(l, [I1, I2, I3, I4, I5, I6, None, None])
def test_suite():
return TestSuite((
makeSuite(Test),
))
if __name__=='__main__':
main(defaultTest='test_suite')
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Interface Verify tests
$Id$
"""
from zope.interface import Interface, implements, classImplements, Attribute
from zope.interface.verify import verifyClass, verifyObject
from zope.interface.exceptions import DoesNotImplement, BrokenImplementation
from zope.interface.exceptions import BrokenMethodImplementation
import unittest
class Test(unittest.TestCase):
def testNotImplemented(self):
class C(object): pass
class I(Interface): pass
self.assertRaises(DoesNotImplement, verifyClass, I, C)
classImplements(C, I)
verifyClass(I, C)
def testMissingAttr(self):
class I(Interface):
def f(): pass
class C(object):
implements(I)
self.assertRaises(BrokenImplementation, verifyClass, I, C)
C.f=lambda self: None
verifyClass(I, C)
def testMissingAttr_with_Extended_Interface(self):
class II(Interface):
def f():
pass
class I(II):
pass
class C(object):
implements(I)
self.assertRaises(BrokenImplementation, verifyClass, I, C)
C.f=lambda self: None
verifyClass(I, C)
def testWrongArgs(self):
class I(Interface):
def f(a): pass
class C(object):
def f(self, b): pass
implements(I)
# We no longer require names to match.
#self.assertRaises(BrokenMethodImplementation, verifyClass, I, C)
C.f=lambda self, a: None
verifyClass(I, C)
C.f=lambda self, **kw: None
self.assertRaises(BrokenMethodImplementation, verifyClass, I, C)
C.f=lambda self, a, *args: None
verifyClass(I, C)
C.f=lambda self, a, *args, **kw: None
verifyClass(I, C)
C.f=lambda self, *args: None
verifyClass(I, C)
def testExtraArgs(self):
class I(Interface):
def f(a): pass
class C(object):
def f(self, a, b): pass
implements(I)
self.assertRaises(BrokenMethodImplementation, verifyClass, I, C)
C.f=lambda self, a: None
verifyClass(I, C)
C.f=lambda self, a, b=None: None
verifyClass(I, C)
def testNoVar(self):
class I(Interface):
def f(a, *args): pass
class C(object):
def f(self, a): pass
implements(I)
self.assertRaises(BrokenMethodImplementation, verifyClass, I, C)
C.f=lambda self, a, *foo: None
verifyClass(I, C)
def testNoKW(self):
class I(Interface):
def f(a, **args): pass
class C(object):
def f(self, a): pass
implements(I)
self.assertRaises(BrokenMethodImplementation, verifyClass, I, C)
C.f=lambda self, a, **foo: None
verifyClass(I, C)
def testModule(self):
from zope.interface.tests.ifoo import IFoo
from zope.interface.tests import dummy
verifyObject(IFoo, dummy)
def testMethodForAttr(self):
class IFoo(Interface):
foo = Attribute("The foo Attribute")
class Foo:
implements(IFoo)
def foo(self):
pass
verifyClass(IFoo, Foo)
def testNonMethodForMethod(self):
class IBar(Interface):
def foo():
pass
class Bar:
implements(IBar)
foo = 1
self.assertRaises(BrokenMethodImplementation, verifyClass, IBar, Bar)
def test_suite():
loader=unittest.TestLoader()
return loader.loadTestsFromTestCase(Test)
if __name__=='__main__':
unittest.TextTestRunner().run(test_suite())
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Unit Test Fixtures
$Id$
"""
from zope.interface import Interface, invariant
from zope.interface.interface import Attribute
from zope.interface.exceptions import Invalid
class mytest(Interface):
pass
class C(object):
def m1(self, a, b):
"return 1"
return 1
def m2(self, a, b):
"return 2"
return 2
# testInstancesOfClassImplements
# YAGNI IC=Interface.impliedInterface(C)
class IC(Interface):
def m1(a, b):
"return 1"
def m2(a, b):
"return 2"
C.__implemented__=IC
class I1(Interface):
def ma():
"blah"
class I2(I1): pass
class I3(Interface): pass
class I4(Interface): pass
class A(I1.deferred()):
__implemented__=I1
class B(object):
__implemented__=I2, I3
class D(A, B): pass
class E(A, B):
__implemented__ = A.__implemented__, C.__implemented__
class FooInterface(Interface):
""" This is an Abstract Base Class """
foobar = Attribute("fuzzed over beyond all recognition")
def aMethod(foo, bar, bingo):
""" This is aMethod """
def anotherMethod(foo=6, bar="where you get sloshed", bingo=(1,3,)):
""" This is anotherMethod """
def wammy(zip, *argues):
""" yadda yadda """
def useless(**keywords):
""" useless code is fun! """
class Foo(object):
""" A concrete class """
__implemented__ = FooInterface,
foobar = "yeah"
def aMethod(self, foo, bar, bingo):
""" This is aMethod """
return "barf!"
def anotherMethod(self, foo=6, bar="where you get sloshed", bingo=(1,3,)):
""" This is anotherMethod """
return "barf!"
def wammy(self, zip, *argues):
""" yadda yadda """
return "barf!"
def useless(self, **keywords):
""" useless code is fun! """
return "barf!"
foo_instance = Foo()
class Blah(object):
pass
new = Interface.__class__
FunInterface = new('FunInterface')
BarInterface = new('BarInterface', [FunInterface])
BobInterface = new('BobInterface')
BazInterface = new('BazInterface', [BobInterface, BarInterface])
# fixtures for invariant tests
def ifFooThenBar(obj):
if getattr(obj, 'foo', None) and not getattr(obj, 'bar', None):
raise Invalid('If Foo, then Bar!')
class IInvariant(Interface):
foo = Attribute('foo')
bar = Attribute('bar; must eval to Boolean True if foo does')
invariant(ifFooThenBar)
def BarGreaterThanFoo(obj):
foo = getattr(obj, 'foo', None)
bar = getattr(obj, 'bar', None)
if foo is not None and isinstance(foo, type(bar)):
# type checking should be handled elsewhere (like, say,
# schema); these invariants should be intra-interface
# constraints. This is a hacky way to do it, maybe, but you
# get the idea
if not bar > foo:
raise Invalid('Please, Boo MUST be greater than Foo!')
class ISubInvariant(IInvariant):
invariant(BarGreaterThanFoo)
class InvariantC(object):
pass
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Verify interface implementations
$Id$
"""
from zope.interface.exceptions import BrokenImplementation, DoesNotImplement
from zope.interface.exceptions import BrokenMethodImplementation
from types import FunctionType, MethodType
from zope.interface.interface import fromMethod, fromFunction, Method
# This will be monkey-patched when running under Zope 2, so leave this
# here:
MethodTypes = (MethodType, )
def _verify(iface, candidate, tentative=0, vtype=None):
"""Verify that 'candidate' might correctly implements 'iface'.
This involves:
o Making sure the candidate defines all the necessary methods
o Making sure the methods have the correct signature
o Making sure the candidate asserts that it implements the interface
Note that this isn't the same as verifying that the class does
implement the interface.
If optional tentative is true, suppress the "is implemented by" test.
"""
if vtype == 'c':
tester = iface.implementedBy
else:
tester = iface.providedBy
if not tentative and not tester(candidate):
raise DoesNotImplement(iface)
# Here the `desc` is either an `Attribute` or `Method` instance
for name, desc in iface.namesAndDescriptions(1):
if not hasattr(candidate, name):
if (not isinstance(desc, Method)) and vtype == 'c':
# We can't verify non-methods on classes, since the
# class may provide attrs in it's __init__.
continue
raise BrokenImplementation(iface, name)
attr = getattr(candidate, name)
if not isinstance(desc, Method):
# If it's not a method, there's nothing else we can test
continue
if isinstance(attr, FunctionType):
# should never get here, since classes should not provide functions
meth = fromFunction(attr, iface, name=name)
elif (isinstance(attr, MethodTypes)
and type(attr.im_func) is FunctionType):
meth = fromMethod(attr, iface, name)
else:
if not callable(attr):
raise BrokenMethodImplementation(name, "Not a method")
# sigh, it's callable, but we don't know how to intrspect it, so
# we have to give it a pass.
continue
# Make sure that the required and implemented method signatures are
# the same.
desc = desc.getSignatureInfo()
meth = meth.getSignatureInfo()
mess = _incompat(desc, meth)
if mess:
raise BrokenMethodImplementation(name, mess)
return True
def verifyClass(iface, candidate, tentative=0):
return _verify(iface, candidate, tentative, vtype='c')
def verifyObject(iface, candidate, tentative=0):
return _verify(iface, candidate, tentative, vtype='o')
def _incompat(required, implemented):
#if (required['positional'] !=
# implemented['positional'][:len(required['positional'])]
# and implemented['kwargs'] is None):
# return 'imlementation has different argument names'
if len(implemented['required']) > len(required['required']):
return 'implementation requires too many arguments'
if ((len(implemented['positional']) < len(required['positional']))
and not implemented['varargs']):
return "implementation doesn't allow enough arguments"
if required['kwargs'] and not implemented['kwargs']:
return "implementation doesn't support keyword arguments"
if required['varargs'] and not implemented['varargs']:
return "implementation doesn't support variable arguments"
# Packaging information for zpkg.
header proxy.h
<extension _zope_proxy_proxy>
source _zope_proxy_proxy.c
depends-on proxy.h
</extension>
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""More convenience functions for dealing with proxies.
$Id$
"""
from zope.interface import moduleProvides
from zope.proxy.interfaces import IProxyIntrospection
from types import ClassType
from zope.proxy._zope_proxy_proxy import *
from zope.proxy._zope_proxy_proxy import _CAPI
moduleProvides(IProxyIntrospection)
__all__ = tuple(IProxyIntrospection)
def ProxyIterator(p):
yield p
while isProxy(p):
p = getProxiedObject(p)
yield p
/*############################################################################
#
# Copyright (c) 2004 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
############################################################################*/
/*
* This file is also used as a really extensive macro in
* ../app/container/_zope_app_container_contained.c. If you need to
* change this file, you need to "svn copy" it to ../app/container/.
*
* This approach is taken to allow the sources for the two packages
* to be compilable when the relative locations of these aren't
* related in the same way as they are in a checkout.
*
* This will be revisited in the future, but works for now.
*/
#include "Python.h"
#include "modsupport.h"
#define PROXY_MODULE
#include "proxy.h"
static PyTypeObject ProxyType;
#define Proxy_Check(wrapper) (PyObject_TypeCheck((wrapper), &ProxyType))
static PyObject *
empty_tuple = NULL;
/*
* Slot methods.
*/
static PyObject *
wrap_new(PyTypeObject *type, PyObject *args, PyObject *kwds)
{
PyObject *result = NULL;
PyObject *object;
if (PyArg_UnpackTuple(args, "__new__", 1, 1, &object)) {
if (kwds != NULL && PyDict_Size(kwds) != 0) {
PyErr_SetString(PyExc_TypeError,
"proxy.__new__ does not accept keyword args");
return NULL;
}
result = PyType_GenericNew(type, args, kwds);
if (result != NULL) {
ProxyObject *wrapper = (ProxyObject *) result;
Py_INCREF(object);
wrapper->proxy_object = object;
}
}
return result;
}
static int
wrap_init(PyObject *self, PyObject *args, PyObject *kwds)
{
int result = -1;
PyObject *object;
if (PyArg_UnpackTuple(args, "__init__", 1, 1, &object)) {
ProxyObject *wrapper = (ProxyObject *)self;
if (kwds != NULL && PyDict_Size(kwds) != 0) {
PyErr_SetString(PyExc_TypeError,
"proxy.__init__ does not accept keyword args");
return -1;
}
/* If the object in this proxy is not the one we
* received in args, replace it with the new one.
*/
if (wrapper->proxy_object != object) {
PyObject *temp = wrapper->proxy_object;
Py_INCREF(object);
wrapper->proxy_object = object;
Py_DECREF(temp);
}
result = 0;
}
return result;
}
static int
wrap_traverse(PyObject *self, visitproc visit, void *arg)
{
PyObject *ob = Proxy_GET_OBJECT(self);
if (ob != NULL)
return visit(ob, arg);
else
return 0;
}
static int
wrap_clear(PyObject *self)
{
ProxyObject *proxy = (ProxyObject *)self;
PyObject *temp = proxy->proxy_object;
if (temp != NULL) {
proxy->proxy_object = NULL;
Py_DECREF(temp);
}
return 0;
}
static PyObject *
wrap_richcompare(PyObject* self, PyObject* other, int op)
{
if (Proxy_Check(self)) {
self = Proxy_GET_OBJECT(self);
}
else {
other = Proxy_GET_OBJECT(other);
}
return PyObject_RichCompare(self, other, op);
}
static PyObject *
wrap_iter(PyObject *self)
{
return PyObject_GetIter(Proxy_GET_OBJECT(self));
}
static PyObject *
wrap_iternext(PyObject *self)
{
return PyIter_Next(Proxy_GET_OBJECT(self));
}
static void
wrap_dealloc(PyObject *self)
{
(void) wrap_clear(self);
self->ob_type->tp_free(self);
}
/* A variant of _PyType_Lookup that doesn't look in ProxyType.
*
* If argument search_wrappertype is nonzero, we can look in WrapperType.
*/
PyObject *
WrapperType_Lookup(PyTypeObject *type, PyObject *name)
{
int i, n;
PyObject *mro, *res, *base, *dict;
/* Look in tp_dict of types in MRO */
mro = type->tp_mro;
/* If mro is NULL, the type is either not yet initialized
by PyType_Ready(), or already cleared by type_clear().
Either way the safest thing to do is to return NULL. */
if (mro == NULL)
return NULL;
assert(PyTuple_Check(mro));
n = PyTuple_GET_SIZE(mro)
- 1; /* We don't want to look at the last item, which is object. */
for (i = 0; i < n; i++) {
base = PyTuple_GET_ITEM(mro, i);
if (((PyTypeObject *)base) != &ProxyType) {
if (PyClass_Check(base))
dict = ((PyClassObject *)base)->cl_dict;
else {
assert(PyType_Check(base));
dict = ((PyTypeObject *)base)->tp_dict;
}
assert(dict && PyDict_Check(dict));
res = PyDict_GetItem(dict, name);
if (res != NULL)
return res;
}
}
return NULL;
}
static PyObject *
wrap_getattro(PyObject *self, PyObject *name)
{
PyObject *wrapped;
PyObject *descriptor;
PyObject *res = NULL;
char *name_as_string;
int maybe_special_name;
#ifdef Py_USING_UNICODE
/* The Unicode to string conversion is done here because the
existing tp_getattro slots expect a string object as name
and we wouldn't want to break those. */
if (PyUnicode_Check(name)) {
name = PyUnicode_AsEncodedString(name, NULL, NULL);
if (name == NULL)
return NULL;
}
else
#endif
if (!PyString_Check(name)){
PyErr_SetString(PyExc_TypeError, "attribute name must be string");
return NULL;
}
else
Py_INCREF(name);
name_as_string = PyString_AS_STRING(name);
wrapped = Proxy_GET_OBJECT(self);
if (wrapped == NULL) {
PyErr_Format(PyExc_RuntimeError,
"object is NULL; requested to get attribute '%s'",
name_as_string);
goto finally;
}
maybe_special_name = name_as_string[0] == '_' && name_as_string[1] == '_';
if (!(maybe_special_name && strcmp(name_as_string, "__class__") == 0)) {
descriptor = WrapperType_Lookup(self->ob_type, name);
if (descriptor != NULL) {
if (PyType_HasFeature(descriptor->ob_type, Py_TPFLAGS_HAVE_CLASS)
&& descriptor->ob_type->tp_descr_get != NULL) {
res = descriptor->ob_type->tp_descr_get(
descriptor,
self,
(PyObject *)self->ob_type);
} else {
Py_INCREF(descriptor);
res = descriptor;
}
goto finally;
}
}
res = PyObject_GetAttr(wrapped, name);
finally:
Py_DECREF(name);
return res;
}
static int
wrap_setattro(PyObject *self, PyObject *name, PyObject *value)
{
PyObject *wrapped;
PyObject *descriptor;
int res = -1;
#ifdef Py_USING_UNICODE
/* The Unicode to string conversion is done here because the
existing tp_setattro slots expect a string object as name
and we wouldn't want to break those. */
if (PyUnicode_Check(name)) {
name = PyUnicode_AsEncodedString(name, NULL, NULL);
if (name == NULL)
return -1;
}
else
#endif
if (!PyString_Check(name)){
PyErr_SetString(PyExc_TypeError, "attribute name must be string");
return -1;
}
else
Py_INCREF(name);
descriptor = WrapperType_Lookup(self->ob_type, name);
if (descriptor != NULL) {
if (PyType_HasFeature(descriptor->ob_type, Py_TPFLAGS_HAVE_CLASS) &&
descriptor->ob_type->tp_descr_set != NULL) {
res = descriptor->ob_type->tp_descr_set(descriptor, self, value);
} else {
PyErr_Format(PyExc_TypeError,
"Tried to set attribute '%s' on wrapper, but it is not"
" a data descriptor", PyString_AS_STRING(name));
}
goto finally;
}
wrapped = Proxy_GET_OBJECT(self);
if (wrapped == NULL) {
PyErr_Format(PyExc_RuntimeError,
"object is NULL; requested to set attribute '%s'",
PyString_AS_STRING(name));
goto finally;
}
res = PyObject_SetAttr(wrapped, name, value);
finally:
Py_DECREF(name);
return res;
}
static int
wrap_print(PyObject *wrapper, FILE *fp, int flags)
{
return PyObject_Print(Proxy_GET_OBJECT(wrapper), fp, flags);
}
static PyObject *
wrap_str(PyObject *wrapper) {
return PyObject_Str(Proxy_GET_OBJECT(wrapper));
}
static PyObject *
wrap_repr(PyObject *wrapper)
{
return PyObject_Repr(Proxy_GET_OBJECT(wrapper));
}
static int
wrap_compare(PyObject *wrapper, PyObject *v)
{
return PyObject_Compare(Proxy_GET_OBJECT(wrapper), v);
}
static long
wrap_hash(PyObject *self)
{
return PyObject_Hash(Proxy_GET_OBJECT(self));
}
static PyObject *
wrap_call(PyObject *self, PyObject *args, PyObject *kw)
{
if (kw)
return PyEval_CallObjectWithKeywords(Proxy_GET_OBJECT(self),
args, kw);
else
return PyObject_CallObject(Proxy_GET_OBJECT(self), args);
}
/*
* Number methods
*/
/*
* Number methods.
*/
static PyObject *
call_int(PyObject *self)
{
PyNumberMethods *nb = self->ob_type->tp_as_number;
if (nb == NULL || nb->nb_int == NULL) {
PyErr_SetString(PyExc_TypeError,
"object can't be converted to int");
return NULL;
}
return nb->nb_int(self);
}
static PyObject *
call_long(PyObject *self)
{
PyNumberMethods *nb = self->ob_type->tp_as_number;
if (nb == NULL || nb->nb_long == NULL) {
PyErr_SetString(PyExc_TypeError,
"object can't be converted to long");
return NULL;
}
return nb->nb_long(self);
}
static PyObject *
call_float(PyObject *self)
{
PyNumberMethods *nb = self->ob_type->tp_as_number;
if (nb == NULL || nb->nb_float== NULL) {
PyErr_SetString(PyExc_TypeError,
"object can't be converted to float");
return NULL;
}
return nb->nb_float(self);
}
static PyObject *
call_oct(PyObject *self)
{
PyNumberMethods *nb = self->ob_type->tp_as_number;
if (nb == NULL || nb->nb_oct== NULL) {
PyErr_SetString(PyExc_TypeError,
"object can't be converted to oct");
return NULL;
}
return nb->nb_oct(self);
}
static PyObject *
call_hex(PyObject *self)
{
PyNumberMethods *nb = self->ob_type->tp_as_number;
if (nb == NULL || nb->nb_hex == NULL) {
PyErr_SetString(PyExc_TypeError,
"object can't be converted to hex");
return NULL;
}
return nb->nb_hex(self);
}
static PyObject *
call_ipow(PyObject *self, PyObject *other)
{
/* PyNumber_InPlacePower has three args. How silly. :-) */
return PyNumber_InPlacePower(self, other, Py_None);
}
typedef PyObject *(*function1)(PyObject *);
static PyObject *
check1(ProxyObject *self, char *opname, function1 operation)
{
PyObject *result = NULL;
result = operation(Proxy_GET_OBJECT(self));
#if 0
if (result != NULL)
/* XXX create proxy for result? */
;
#endif
return result;
}
static PyObject *
check2(PyObject *self, PyObject *other,
char *opname, char *ropname, binaryfunc operation)
{
PyObject *result = NULL;
PyObject *object;
if (Proxy_Check(self)) {
object = Proxy_GET_OBJECT(self);
result = operation(object, other);
}
else if (Proxy_Check(other)) {
object = Proxy_GET_OBJECT(other);
result = operation(self, object);
}
else {
Py_INCREF(Py_NotImplemented);
return Py_NotImplemented;
}
#if 0
if (result != NULL)
/* XXX create proxy for result? */
;
#endif
return result;
}
static PyObject *
check2i(ProxyObject *self, PyObject *other,
char *opname, binaryfunc operation)
{
PyObject *result = NULL;
PyObject *object = Proxy_GET_OBJECT(self);
result = operation(object, other);
if (result == object) {
/* If the operation was really carried out inplace,
don't create a new proxy, but use the old one. */
Py_INCREF(self);
Py_DECREF(object);
result = (PyObject *)self;
}
#if 0
else if (result != NULL)
/* XXX create proxy for result? */
;
#endif
return result;
}
#define UNOP(NAME, CALL) \
static PyObject *wrap_##NAME(PyObject *self) \
{ return check1((ProxyObject *)self, "__"#NAME"__", CALL); }
#define BINOP(NAME, CALL) \
static PyObject *wrap_##NAME(PyObject *self, PyObject *other) \
{ return check2(self, other, "__"#NAME"__", "__r"#NAME"__", CALL); }
#define INPLACE(NAME, CALL) \
static PyObject *wrap_i##NAME(PyObject *self, PyObject *other) \
{ return check2i((ProxyObject *)self, other, "__i"#NAME"__", CALL); }
BINOP(add, PyNumber_Add)
BINOP(sub, PyNumber_Subtract)
BINOP(mul, PyNumber_Multiply)
BINOP(div, PyNumber_Divide)
BINOP(mod, PyNumber_Remainder)
BINOP(divmod, PyNumber_Divmod)
static PyObject *
wrap_pow(PyObject *self, PyObject *other, PyObject *modulus)
{
PyObject *result = NULL;
PyObject *object;
if (Proxy_Check(self)) {
object = Proxy_GET_OBJECT(self);
result = PyNumber_Power(object, other, modulus);
}
else if (Proxy_Check(other)) {
object = Proxy_GET_OBJECT(other);
result = PyNumber_Power(self, object, modulus);
}
else if (modulus != NULL && Proxy_Check(modulus)) {
object = Proxy_GET_OBJECT(modulus);
result = PyNumber_Power(self, other, modulus);
}
else {
Py_INCREF(Py_NotImplemented);
return Py_NotImplemented;
}
return result;
}
BINOP(lshift, PyNumber_Lshift)
BINOP(rshift, PyNumber_Rshift)
BINOP(and, PyNumber_And)
BINOP(xor, PyNumber_Xor)
BINOP(or, PyNumber_Or)
static int
wrap_coerce(PyObject **p_self, PyObject **p_other)
{
PyObject *self = *p_self;
PyObject *other = *p_other;
PyObject *object;
PyObject *left;
PyObject *right;
int r;
assert(Proxy_Check(self));
object = Proxy_GET_OBJECT(self);
left = object;
right = other;
r = PyNumber_CoerceEx(&left, &right);
if (r != 0)
return r;
/* Now left and right have been INCREF'ed. Any new value that
comes out is proxied; any unchanged value is left unchanged. */
if (left == object) {
/* Keep the old proxy */
Py_INCREF(self);
Py_DECREF(left);
left = self;
}
#if 0
else {
/* XXX create proxy for left? */
}
if (right != other) {
/* XXX create proxy for right? */
}
#endif
*p_self = left;
*p_other = right;
return 0;
}
UNOP(neg, PyNumber_Negative)
UNOP(pos, PyNumber_Positive)
UNOP(abs, PyNumber_Absolute)
UNOP(invert, PyNumber_Invert)
UNOP(int, call_int)
UNOP(long, call_long)
UNOP(float, call_float)
UNOP(oct, call_oct)
UNOP(hex, call_hex)
INPLACE(add, PyNumber_InPlaceAdd)
INPLACE(sub, PyNumber_InPlaceSubtract)
INPLACE(mul, PyNumber_InPlaceMultiply)
INPLACE(div, PyNumber_InPlaceDivide)
INPLACE(mod, PyNumber_InPlaceRemainder)
INPLACE(pow, call_ipow)
INPLACE(lshift, PyNumber_InPlaceLshift)
INPLACE(rshift, PyNumber_InPlaceRshift)
INPLACE(and, PyNumber_InPlaceAnd)
INPLACE(xor, PyNumber_InPlaceXor)
INPLACE(or, PyNumber_InPlaceOr)
BINOP(floordiv, PyNumber_FloorDivide)
BINOP(truediv, PyNumber_TrueDivide)
INPLACE(floordiv, PyNumber_InPlaceFloorDivide)
INPLACE(truediv, PyNumber_InPlaceTrueDivide)
static int
wrap_nonzero(PyObject *self)
{
return PyObject_IsTrue(Proxy_GET_OBJECT(self));
}
/*
* Sequence methods
*/
static int
wrap_length(PyObject *self)
{
return PyObject_Length(Proxy_GET_OBJECT(self));
}
static PyObject *
wrap_slice(PyObject *self, int start, int end)
{
return PySequence_GetSlice(Proxy_GET_OBJECT(self), start, end);
}
static int
wrap_ass_slice(PyObject *self, int i, int j, PyObject *value)
{
return PySequence_SetSlice(Proxy_GET_OBJECT(self), i, j, value);
}
static int
wrap_contains(PyObject *self, PyObject *value)
{
return PySequence_Contains(Proxy_GET_OBJECT(self), value);
}
/*
* Mapping methods
*/
static PyObject *
wrap_getitem(PyObject *wrapper, PyObject *v) {
return PyObject_GetItem(Proxy_GET_OBJECT(wrapper), v);
}
static int
wrap_setitem(PyObject *self, PyObject *key, PyObject *value)
{
if (value == NULL)
return PyObject_DelItem(Proxy_GET_OBJECT(self), key);
else
return PyObject_SetItem(Proxy_GET_OBJECT(self), key, value);
}
/*
* Normal methods
*/
static char
reduce__doc__[] =
"__reduce__()\n"
"Raise an exception; this prevents proxies from being picklable by\n"
"default, even if the underlying object is picklable.";
static PyObject *
wrap_reduce(PyObject *self)
{
PyObject *pickle_error = NULL;
PyObject *pickle = PyImport_ImportModule("pickle");
if (pickle == NULL)
PyErr_Clear();
else {
pickle_error = PyObject_GetAttrString(pickle, "PicklingError");
if (pickle_error == NULL)
PyErr_Clear();
}
if (pickle_error == NULL) {
pickle_error = PyExc_RuntimeError;
Py_INCREF(pickle_error);
}
PyErr_SetString(pickle_error,
"proxy instances cannot be pickled");
Py_DECREF(pickle_error);
return NULL;
}
static PyNumberMethods
wrap_as_number = {
wrap_add, /* nb_add */
wrap_sub, /* nb_subtract */
wrap_mul, /* nb_multiply */
wrap_div, /* nb_divide */
wrap_mod, /* nb_remainder */
wrap_divmod, /* nb_divmod */
wrap_pow, /* nb_power */
wrap_neg, /* nb_negative */
wrap_pos, /* nb_positive */
wrap_abs, /* nb_absolute */
wrap_nonzero, /* nb_nonzero */
wrap_invert, /* nb_invert */
wrap_lshift, /* nb_lshift */
wrap_rshift, /* nb_rshift */
wrap_and, /* nb_and */
wrap_xor, /* nb_xor */
wrap_or, /* nb_or */
wrap_coerce, /* nb_coerce */
wrap_int, /* nb_int */
wrap_long, /* nb_long */
wrap_float, /* nb_float */
wrap_oct, /* nb_oct */
wrap_hex, /* nb_hex */
/* Added in release 2.0 */
/* These require the Py_TPFLAGS_HAVE_INPLACEOPS flag */
wrap_iadd, /* nb_inplace_add */
wrap_isub, /* nb_inplace_subtract */
wrap_imul, /* nb_inplace_multiply */
wrap_idiv, /* nb_inplace_divide */
wrap_imod, /* nb_inplace_remainder */
(ternaryfunc)wrap_ipow, /* nb_inplace_power */
wrap_ilshift, /* nb_inplace_lshift */
wrap_irshift, /* nb_inplace_rshift */
wrap_iand, /* nb_inplace_and */
wrap_ixor, /* nb_inplace_xor */
wrap_ior, /* nb_inplace_or */
/* Added in release 2.2 */
/* These require the Py_TPFLAGS_HAVE_CLASS flag */
wrap_floordiv, /* nb_floor_divide */
wrap_truediv, /* nb_true_divide */
wrap_ifloordiv, /* nb_inplace_floor_divide */
wrap_itruediv, /* nb_inplace_true_divide */
};
static PySequenceMethods
wrap_as_sequence = {
wrap_length, /* sq_length */
0, /* sq_concat */
0, /* sq_repeat */
0, /* sq_item */
wrap_slice, /* sq_slice */
0, /* sq_ass_item */
wrap_ass_slice, /* sq_ass_slice */
wrap_contains, /* sq_contains */
};
static PyMappingMethods
wrap_as_mapping = {
wrap_length, /* mp_length */
wrap_getitem, /* mp_subscript */
wrap_setitem, /* mp_ass_subscript */
};
static PyMethodDef
wrap_methods[] = {
{"__reduce__", (PyCFunction)wrap_reduce, METH_NOARGS, reduce__doc__},
{NULL, NULL},
};
/*
* Note that the numeric methods are not supported. This is primarily
* because of the way coercion-less operations are performed with
* new-style numbers; since we can't tell which side of the operation
* is 'self', we can't ensure we'd unwrap the right thing to perform
* the actual operation. We also can't afford to just unwrap both
* sides the way weakrefs do, since we don't know what semantics will
* be associated with the wrapper itself.
*/
statichere PyTypeObject
ProxyType = {
PyObject_HEAD_INIT(NULL) /* PyObject_HEAD_INIT(&PyType_Type) */
0,
"zope.proxy.ProxyBase",
sizeof(ProxyObject),
0,
wrap_dealloc, /* tp_dealloc */
wrap_print, /* tp_print */
0, /* tp_getattr */
0, /* tp_setattr */
wrap_compare, /* tp_compare */
wrap_repr, /* tp_repr */
&wrap_as_number, /* tp_as_number */
&wrap_as_sequence, /* tp_as_sequence */
&wrap_as_mapping, /* tp_as_mapping */
wrap_hash, /* tp_hash */
wrap_call, /* tp_call */
wrap_str, /* tp_str */
wrap_getattro, /* tp_getattro */
wrap_setattro, /* tp_setattro */
0, /* tp_as_buffer */
Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HAVE_GC
| Py_TPFLAGS_CHECKTYPES | Py_TPFLAGS_BASETYPE, /* tp_flags */
0, /* tp_doc */
wrap_traverse, /* tp_traverse */
wrap_clear, /* tp_clear */
wrap_richcompare, /* tp_richcompare */
0, /* tp_weaklistoffset */
wrap_iter, /* tp_iter */
wrap_iternext, /* tp_iternext */
wrap_methods, /* tp_methods */
0, /* tp_members */
0, /* tp_getset */
0, /* tp_base */
0, /* tp_dict */
0, /* tp_descr_get */
0, /* tp_descr_set */
0, /* tp_dictoffset */
wrap_init, /* tp_init */
0, /* tp_alloc */
wrap_new, /* tp_new */
0, /*_PyObject_GC_Del,*/ /* tp_free */
};
static PyObject *
create_proxy(PyObject *object)
{
PyObject *result = NULL;
PyObject *args;
args = PyTuple_New(1);
if (args != NULL) {
Py_INCREF(object);
PyTuple_SET_ITEM(args, 0, object);
result = PyObject_CallObject((PyObject *)&ProxyType, args);
Py_DECREF(args);
}
return result;
}
static int
api_check(PyObject *obj)
{
return obj ? Proxy_Check(obj) : 0;
}
static PyObject *
api_create(PyObject *object)
{
if (object == NULL) {
PyErr_SetString(PyExc_ValueError,
"cannot create proxy around NULL");
return NULL;
}
return create_proxy(object);
}
static PyObject *
api_getobject(PyObject *proxy)
{
if (proxy == NULL) {
PyErr_SetString(PyExc_RuntimeError,
"cannot pass NULL to ProxyAPI.getobject()");
return NULL;
}
if (Proxy_Check(proxy))
return Proxy_GET_OBJECT(proxy);
else {
PyErr_Format(PyExc_TypeError, "expected proxy object, got %s",
proxy->ob_type->tp_name);
return NULL;
}
}
static ProxyInterface
wrapper_capi = {
&ProxyType,
api_check,
api_create,
api_getobject,
};
static PyObject *api_object = NULL;
static char
getobject__doc__[] =
"getProxiedObject(proxy) --> object\n"
"\n"
"Get the underlying object for proxy, or the object itself, if it is\n"
"not a proxy.";
static PyObject *
wrapper_getobject(PyObject *unused, PyObject *obj)
{
if (Proxy_Check(obj))
obj = Proxy_GET_OBJECT(obj);
if (obj == NULL)
obj = Py_None;
Py_INCREF(obj);
return obj;
}
static char
isProxy__doc__[] =
"Check whether the given object is a proxy\n"
"\n"
"If proxytype is not None, checkes whether the object is\n"
"proxied by the given proxytype.\n"
;
static PyObject *
wrapper_isProxy(PyObject *unused, PyObject *args)
{
PyObject *obj, *result;
PyTypeObject *proxytype=&ProxyType;
if (! PyArg_ParseTuple(args, "O|O!:isProxy",
&obj, &PyType_Type, &proxytype)
)
return NULL;
while (obj && Proxy_Check(obj))
{
if (PyObject_TypeCheck(obj, proxytype))
{
result = Py_True;
Py_INCREF(result);
return result;
}
obj = Proxy_GET_OBJECT(obj);
}
result = Py_False;
Py_INCREF(result);
return result;
}
static char
removeAllProxies__doc__[] =
"removeAllProxies(proxy) --> object\n"
"\n"
"Get the proxied object with no proxies\n"
"\n"
"If obj is not a proxied object, return obj.\n"
"\n"
"The returned object has no proxies.\n"
;
static PyObject *
wrapper_removeAllProxies(PyObject *unused, PyObject *obj)
{
while (obj && Proxy_Check(obj))
obj = Proxy_GET_OBJECT(obj);
if (obj == NULL)
obj = Py_None;
Py_INCREF(obj);
return obj;
}
static char
sameProxiedObjects__doc__[] =
"Check whether two objects are the same or proxies of the same object";
static PyObject *
wrapper_sameProxiedObjects(PyObject *unused, PyObject *args)
{
PyObject *ob1, *ob2;
if (! PyArg_ParseTuple(args, "OO:sameProxiedObjects", &ob1, &ob2))
return NULL;
while (ob1 && Proxy_Check(ob1))
ob1 = Proxy_GET_OBJECT(ob1);
while (ob2 && Proxy_Check(ob2))
ob2 = Proxy_GET_OBJECT(ob2);
if (ob1 == ob2)
ob1 = Py_True;
else
ob1 = Py_False;
Py_INCREF(ob1);
return ob1;
}
static char
queryProxy__doc__[] =
"Look for a proxy of the given type around the object\n"
"\n"
"If no such proxy can be found, return the default.\n"
;
static PyObject *
wrapper_queryProxy(PyObject *unused, PyObject *args)
{
PyObject *obj, *result=Py_None;
PyTypeObject *proxytype=&ProxyType;
if (! PyArg_ParseTuple(args, "O|O!O:queryProxy",
&obj, &PyType_Type, &proxytype, &result)
)
return NULL;
while (obj && Proxy_Check(obj))
{
if (PyObject_TypeCheck(obj, proxytype))
{
Py_INCREF(obj);
return obj;
}
obj = Proxy_GET_OBJECT(obj);
}
Py_INCREF(result);
return result;
}
static char
queryInnerProxy__doc__[] =
"Look for the inner-most proxy of the given type around the object\n"
"\n"
"If no such proxy can be found, return the default.\n"
"\n"
"If there is such a proxy, return the inner-most one.\n"
;
static PyObject *
wrapper_queryInnerProxy(PyObject *unused, PyObject *args)
{
PyObject *obj, *result=Py_None;
PyTypeObject *proxytype=&ProxyType;
if (! PyArg_ParseTuple(args, "O|O!O:queryInnerProxy",
&obj, &PyType_Type, &proxytype, &result)
)
return NULL;
while (obj && Proxy_Check(obj))
{
if (PyObject_TypeCheck(obj, proxytype))
result = obj;
obj = Proxy_GET_OBJECT(obj);
}
Py_INCREF(result);
return result;
}
static char
module___doc__[] =
"Association between an object, a context object, and a dictionary.\n\
\n\
The context object and dictionary give additional context information\n\
associated with a reference to the basic object. The wrapper objects\n\
act as proxies for the original object.";
static PyMethodDef
module_functions[] = {
{"getProxiedObject", wrapper_getobject, METH_O, getobject__doc__},
{"isProxy", wrapper_isProxy, METH_VARARGS, isProxy__doc__},
{"sameProxiedObjects", wrapper_sameProxiedObjects, METH_VARARGS,
sameProxiedObjects__doc__},
{"queryProxy", wrapper_queryProxy, METH_VARARGS, queryProxy__doc__},
{"queryInnerProxy", wrapper_queryInnerProxy, METH_VARARGS,
queryInnerProxy__doc__},
{"removeAllProxies", wrapper_removeAllProxies, METH_O,
removeAllProxies__doc__},
{NULL}
};
void
init_zope_proxy_proxy(void)
{
PyObject *m = Py_InitModule3("_zope_proxy_proxy",
module_functions, module___doc__);
if (m == NULL)
return;
if (empty_tuple == NULL)
empty_tuple = PyTuple_New(0);
ProxyType.tp_free = _PyObject_GC_Del;
if (PyType_Ready(&ProxyType) < 0)
return;
Py_INCREF(&ProxyType);
PyModule_AddObject(m, "ProxyBase", (PyObject *)&ProxyType);
if (api_object == NULL) {
api_object = PyCObject_FromVoidPtr(&wrapper_capi, NULL);
if (api_object == NULL)
return;
}
Py_INCREF(api_object);
PyModule_AddObject(m, "_CAPI", api_object);
}
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE
#
##############################################################################
"""Proxy-related interfaces.
$Id$
"""
from zope.interface import Interface
class IProxyIntrospection(Interface):
"""Provides methods for indentifying proxies and extracting proxied objects
"""
def isProxy(obj, proxytype=None):
"""Check whether the given object is a proxy
If proxytype is not None, checkes whether the object is
proxied by the given proxytype.
"""
def sameProxiedObjects(ob1, ob2):
"""Check whether ob1 and ob2 are the same or proxies of the same object
"""
def getProxiedObject(obj):
"""Get the proxied Object
If the object isn't proxied, then just return the object.
"""
def removeAllProxies(obj):
"""Get the proxied object with no proxies
If obj is not a proxied object, return obj.
The returned object has no proxies.
"""
def queryProxy(obj, proxytype, default=None):
"""Look for a proxy of the given type around the object
If no such proxy can be found, return the default.
"""
def queryInnerProxy(obj, proxytype, default=None):
"""Look for the inner-most proxy of the given type around the object
If no such proxy can be found, return the default.
If there is such a proxy, return the inner-most one.
"""
#ifndef _proxy_H_
#define _proxy_H_ 1
typedef struct {
PyObject_HEAD
PyObject *proxy_object;
} ProxyObject;
#define Proxy_GET_OBJECT(ob) (((ProxyObject *)(ob))->proxy_object)
typedef struct {
PyTypeObject *proxytype;
int (*check)(PyObject *obj);
PyObject *(*create)(PyObject *obj);
PyObject *(*getobject)(PyObject *proxy);
} ProxyInterface;
#ifndef PROXY_MODULE
/* These are only defined in the public interface, and are not
* available within the module implementation. There we use the
* classic Python/C API only.
*/
static ProxyInterface *_proxy_api = NULL;
static int
Proxy_Import(void)
{
if (_proxy_api == NULL) {
PyObject *m = PyImport_ImportModule("zope.proxy");
if (m != NULL) {
PyObject *tmp = PyObject_GetAttrString(m, "_CAPI");
if (tmp != NULL) {
if (PyCObject_Check(tmp))
_proxy_api = (ProxyInterface *)
PyCObject_AsVoidPtr(tmp);
Py_DECREF(tmp);
}
}
}
return (_proxy_api == NULL) ? -1 : 0;
}
#define ProxyType (*_proxy_api->proxytype)
#define Proxy_Check(obj) (_proxy_api->check((obj)))
#define Proxy_CheckExact(obj) ((obj)->ob_type == ProxyType)
#define Proxy_New(obj) (_proxy_api->create((obj)))
#define Proxy_GetObject(proxy) (_proxy_api->getobject((proxy)))
#endif /* PROXY_MODULE */
#endif /* _proxy_H_ */
#
# This file is necessary to make this directory a package.
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Test base proxy class.
$Id$
"""
import pickle
import sys
import unittest
from zope.testing.doctestunit import DocTestSuite
from zope.proxy import ProxyBase
class Thing:
"""This class is expected to be a classic class."""
class Comparable(object):
def __init__(self, value):
self.value = value
def __eq__(self, other):
if hasattr(other, "value"):
other = other.value
return self.value == other
def __ne__(self, other):
return not self.__eq__(other)
def __lt__(self, other):
if hasattr(other, "value"):
other = other.value
return self.value < other
def __ge__(self, other):
return not self.__lt__(other)
def __le__(self, other):
if hasattr(other, "value"):
other = other.value
return self.value <= other
def __gt__(self, other):
return not self.__le__(other)
def __repr__(self):
return "<Comparable: %r>" % self.value
class ProxyTestCase(unittest.TestCase):
proxy_class = ProxyBase
def setUp(self):
self.x = Thing()
self.p = self.new_proxy(self.x)
def new_proxy(self, o):
return self.proxy_class(o)
def test_constructor(self):
o = object()
self.assertRaises(TypeError, self.proxy_class, o, o)
self.assertRaises(TypeError, self.proxy_class, o, key='value')
self.assertRaises(TypeError, self.proxy_class, key='value')
def test_subclass_constructor(self):
class MyProxy(self.proxy_class):
def __new__(cls, *args, **kwds):
return super(MyProxy, cls).__new__(cls, *args, **kwds)
def __init__(self, *args, **kwds):
super(MyProxy, self).__init__(*args, **kwds)
o1 = object()
o2 = object()
o = MyProxy((o1, o2))
self.assertEquals(o1, o[0])
self.assertEquals(o2, o[1])
self.assertRaises(TypeError, MyProxy, o1, o2)
self.assertRaises(TypeError, MyProxy, o1, key='value')
self.assertRaises(TypeError, MyProxy, key='value')
# Check that are passed to __init__() overrides what's passed
# to __new__().
class MyProxy2(self.proxy_class):
def __new__(cls, *args, **kwds):
return super(MyProxy2, cls).__new__(cls, 'value')
p = MyProxy2('splat!')
self.assertEquals(list(p), list('splat!'))
class MyProxy3(MyProxy2):
def __init__(self, arg):
if list(self) != list('value'):
raise AssertionError("list(self) != list('value')")
super(MyProxy3, self).__init__('another')
p = MyProxy3('notused')
self.assertEquals(list(p), list('another'))
def test_proxy_attributes(self):
o = Thing()
o.foo = 1
w = self.new_proxy(o)
self.assert_(w.foo == 1)
def test___class__(self):
o = object()
w = self.new_proxy(o)
self.assert_(w.__class__ is o.__class__)
def test_pickle_prevention(self):
w = self.new_proxy(Thing())
self.assertRaises(pickle.PicklingError,
pickle.dumps, w)
def test_proxy_equality(self):
w = self.new_proxy('foo')
self.assertEquals(w, 'foo')
o1 = Comparable(1)
o2 = Comparable(1.0)
o3 = Comparable("splat!")
w1 = self.new_proxy(o1)
w2 = self.new_proxy(o2)
w3 = self.new_proxy(o3)
self.assertEquals(o1, w1)
self.assertEquals(o1, w2)
self.assertEquals(o2, w1)
self.assertEquals(w1, o2)
self.assertEquals(w2, o1)
self.assertNotEquals(o3, w1)
self.assertNotEquals(w1, o3)
self.assertNotEquals(w3, o1)
self.assertNotEquals(o1, w3)
def test_proxy_ordering_lt(self):
o1 = Comparable(1)
o2 = Comparable(2.0)
w1 = self.new_proxy(o1)
w2 = self.new_proxy(o2)
self.assert_(w1 < w2)
self.assert_(w1 <= w2)
self.assert_(o1 < w2)
self.assert_(o1 <= w2)
self.assert_(w1 < o2)
self.assert_(w2 <= o2)
def test_proxy_callable(self):
w = self.new_proxy({}.get)
self.assert_(callable(w))
def test_proxy_item_protocol(self):
w = self.new_proxy({})
self.assertRaises(KeyError, lambda: w[1])
w[1] = 'a'
self.assertEquals(w[1], 'a')
del w[1]
self.assertRaises(KeyError, lambda: w[1])
def del_w_1():
del w[1]
self.assertRaises(KeyError, del_w_1)
def test_wrapped_iterable(self):
a = [1, 2, 3]
b = []
for x in self.new_proxy(a):
b.append(x)
self.assertEquals(a, b)
def test_iteration_over_proxy(self):
# Wrap an iterator before starting iteration.
# PyObject_GetIter() will still be called on the proxy.
a = [1, 2, 3]
b = []
for x in self.new_proxy(iter(a)):
b.append(x)
self.assertEquals(a, b)
t = tuple(self.new_proxy(iter(a)))
self.assertEquals(t, (1, 2, 3))
def test_iteration_using_proxy(self):
# Wrap an iterator within the iteration protocol, expecting it
# still to work. PyObject_GetIter() will not be called on the
# proxy, so the tp_iter slot won't unwrap it.
class Iterable(object):
def __init__(self, test, data):
self.test = test
self.data = data
def __iter__(self):
return self.test.new_proxy(iter(self.data))
a = [1, 2, 3]
b = []
for x in Iterable(self, a):
b.append(x)
self.assertEquals(a, b)
def test_bool_wrapped_None(self):
w = self.new_proxy(None)
self.assertEquals(not w, 1)
# Numeric ops.
unops = [
"-x", "+x", "abs(x)", "~x",
"int(x)", "long(x)", "float(x)",
]
def test_unops(self):
P = self.new_proxy
for expr in self.unops:
x = 1
y = eval(expr)
x = P(1)
z = eval(expr)
self.assertEqual(z, y,
"x=%r; expr=%r" % (x, expr))
def test_odd_unops(self):
# unops that don't return a proxy
P = self.new_proxy
for func in hex, oct, lambda x: not x:
self.assertEqual(func(P(100)), func(100))
binops = [
"x+y", "x-y", "x*y", "x/y", "divmod(x, y)", "x**y", "x//y",
"x<<y", "x>>y", "x&y", "x|y", "x^y",
]
def test_binops(self):
P = self.new_proxy
for expr in self.binops:
first = 1
for x in [1, P(1)]:
for y in [2, P(2)]:
if first:
z = eval(expr)
first = 0
else:
self.assertEqual(eval(expr), z,
"x=%r; y=%r; expr=%r" % (x, y, expr))
def test_inplace(self):
# TODO: should test all inplace operators...
P = self.new_proxy
pa = P(1)
pa += 2
self.assertEqual(pa, 3)
a = [1, 2, 3]
pa = qa = P(a)
pa += [4, 5, 6]
self.failUnless(pa is qa)
self.assertEqual(a, [1, 2, 3, 4, 5, 6])
pa = P(2)
pa **= 2
self.assertEqual(pa, 4)
def test_coerce(self):
P = self.new_proxy
# Before 2.3, coerce() of two proxies returns them unchanged
fixed_coerce = sys.version_info >= (2, 3, 0)
x = P(1)
y = P(2)
a, b = coerce(x, y)
self.failUnless(a is x and b is y)
x = P(1)
y = P(2.1)
a, b = coerce(x, y)
self.failUnless(a == 1.0)
self.failUnless(b is y)
if fixed_coerce:
self.failUnless(a.__class__ is float, a.__class__)
x = P(1.1)
y = P(2)
a, b = coerce(x, y)
self.failUnless(a is x)
self.failUnless(b == 2.0)
if fixed_coerce:
self.failUnless(b.__class__ is float, b.__class__)
x = P(1)
y = 2
a, b = coerce(x, y)
self.failUnless(a is x)
self.failUnless(b is y)
x = P(1)
y = 2.1
a, b = coerce(x, y)
self.failUnless(a.__class__ is float, a.__class__)
self.failUnless(b is y)
x = P(1.1)
y = 2
a, b = coerce(x, y)
self.failUnless(a is x)
self.failUnless(b.__class__ is float, b.__class__)
x = 1
y = P(2)
a, b = coerce(x, y)
self.failUnless(a is x)
self.failUnless(b is y)
x = 1.1
y = P(2)
a, b = coerce(x, y)
self.failUnless(a is x)
self.failUnless(b.__class__ is float, b.__class__)
x = 1
y = P(2.1)
a, b = coerce(x, y)
self.failUnless(a.__class__ is float, a.__class__)
self.failUnless(b is y)
def test_isProxy():
"""
>>> from zope.proxy import ProxyBase, isProxy
>>> class P1(ProxyBase):
... pass
>>> class P2(ProxyBase):
... pass
>>> class C(object):
... pass
>>> c = C()
>>> int(isProxy(c))
0
>>> p = P1(c)
>>> int(isProxy(p))
1
>>> int(isProxy(p, P1))
1
>>> int(isProxy(p, P2))
0
>>> p = P2(p)
>>> int(isProxy(p, P1))
1
>>> int(isProxy(p, P2))
1
"""
def test_getProxiedObject():
"""
>>> from zope.proxy import ProxyBase, getProxiedObject
>>> class C(object):
... pass
>>> c = C()
>>> int(getProxiedObject(c) is c)
1
>>> p = ProxyBase(c)
>>> int(getProxiedObject(p) is c)
1
>>> p2 = ProxyBase(p)
>>> int(getProxiedObject(p2) is p)
1
"""
def test_ProxyIterator():
"""
>>> from zope.proxy import ProxyBase, ProxyIterator
>>> class C(object):
... pass
>>> c = C()
>>> p1 = ProxyBase(c)
>>> class P(ProxyBase):
... pass
>>> p2 = P(p1)
>>> p3 = ProxyBase(p2)
>>> list(ProxyIterator(p3)) == [p3, p2, p1, c]
1
"""
def test_removeAllProxies():
"""
>>> from zope.proxy import ProxyBase, removeAllProxies
>>> class C(object):
... pass
>>> c = C()
>>> int(removeAllProxies(c) is c)
1
>>> p = ProxyBase(c)
>>> int(removeAllProxies(p) is c)
1
>>> p2 = ProxyBase(p)
>>> int(removeAllProxies(p2) is c)
1
"""
def test_queryProxy():
"""
>>> from zope.proxy import ProxyBase, queryProxy
>>> class P1(ProxyBase):
... pass
>>> class P2(ProxyBase):
... pass
>>> class C(object):
... pass
>>> c = C()
>>> queryProxy(c, P1)
>>> queryProxy(c, P1, 42)
42
>>> p1 = P1(c)
>>> int(queryProxy(p1, P1) is p1)
1
>>> queryProxy(c, P2)
>>> queryProxy(c, P2, 42)
42
>>> p2 = P2(p1)
>>> int(queryProxy(p2, P1) is p1)
1
>>> int(queryProxy(p2, P2) is p2)
1
>>> int(queryProxy(p2, ProxyBase) is p2)
1
"""
def test_queryInnerProxy():
"""
>>> from zope.proxy import ProxyBase, queryProxy, queryInnerProxy
>>> class P1(ProxyBase):
... pass
>>> class P2(ProxyBase):
... pass
>>> class C(object):
... pass
>>> c = C()
>>> queryInnerProxy(c, P1)
>>> queryInnerProxy(c, P1, 42)
42
>>> p1 = P1(c)
>>> int(queryProxy(p1, P1) is p1)
1
>>> queryInnerProxy(c, P2)
>>> queryInnerProxy(c, P2, 42)
42
>>> p2 = P2(p1)
>>> int(queryInnerProxy(p2, P1) is p1)
1
>>> int(queryInnerProxy(p2, P2) is p2)
1
>>> int(queryInnerProxy(p2, ProxyBase) is p1)
1
>>> p3 = P1(p2)
>>> int(queryProxy(p3, P1) is p3)
1
>>> int(queryInnerProxy(p3, P1) is p1)
1
>>> int(queryInnerProxy(p3, P2) is p2)
1
"""
def test_sameProxiedObjects():
"""
>>> from zope.proxy import ProxyBase, sameProxiedObjects
>>> class C(object):
... pass
>>> c1 = C()
>>> c2 = C()
>>> int(sameProxiedObjects(c1, c1))
1
>>> int(sameProxiedObjects(ProxyBase(c1), c1))
1
>>> int(sameProxiedObjects(ProxyBase(c1), ProxyBase(c1)))
1
>>> int(sameProxiedObjects(ProxyBase(ProxyBase(c1)), c1))
1
>>> int(sameProxiedObjects(c1, ProxyBase(c1)))
1
>>> int(sameProxiedObjects(c1, ProxyBase(ProxyBase(c1))))
1
>>> int(sameProxiedObjects(c1, c2))
0
>>> int(sameProxiedObjects(ProxyBase(c1), c2))
0
>>> int(sameProxiedObjects(ProxyBase(c1), ProxyBase(c2)))
0
>>> int(sameProxiedObjects(ProxyBase(ProxyBase(c1)), c2))
0
>>> int(sameProxiedObjects(c1, ProxyBase(c2)))
0
>>> int(sameProxiedObjects(c1, ProxyBase(ProxyBase(c2))))
0
"""
def test_subclassing_proxies():
"""You can subclass ProxyBase
If you subclass a proxy, instances of the subclass have access to
data defined in the class, including descriptors.
Your subclass instances don't get instance dictionaries, but they
can have slots.
>>> class MyProxy(ProxyBase):
... __slots__ = 'x', 'y'
...
... def f(self):
... return self.x
>>> l = [1, 2, 3]
>>> p = MyProxy(l)
I can use attributes defined by the class, including slots:
>>> p.x = 'x'
>>> p.x
'x'
>>> p.f()
'x'
I can also use attributes of the proxied object:
>>> p
[1, 2, 3]
>>> p.pop()
3
>>> p
[1, 2]
"""
def test_suite():
suite = unittest.makeSuite(ProxyTestCase)
suite.addTest(DocTestSuite())
return suite
if __name__ == "__main__":
runner = unittest.TextTestRunner(sys.stdout)
result = runner.run(test_suite())
newerrs = len(result.errors) + len(result.failures)
sys.exit(newerrs and 1 or 0)
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Set up testing environment
$Id$
"""
import os
def patchTracebackModule():
"""Use the ExceptionFormatter to show more info in tracebacks.
"""
from zope.exceptions.exceptionformatter import format_exception
import traceback
traceback.format_exception = format_exception
# Don't use the new exception formatter by default, since it
# doesn't show filenames.
if os.environ.get('NEW_ZOPE_EXCEPTION_FORMATTER', 0):
patchTracebackModule()
##############################################################################
#
# Copyright (c) 2001, 2002 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Provide a standard cleanup registry
Unit tests that change global data should include the CleanUp base
class, which provides simpler setUp and tearDown methods that call
global-data cleanup routines::
class Test(CleanUp, unittest.TestCase):
....
If custom setUp or tearDown are needed, then the base routines should
be called, as in::
def tearDown(self):
super(Test, self).tearDown()
....
Cleanup routines for global data should be registered by passing them to
addCleanup::
addCleanUp(pigRegistry._clear)
$Id$
"""
_cleanups = []
def addCleanUp(func, args=(), kw={}):
"""Register a cleanup routines
Pass a function to be called to cleanup global data.
Optional argument tuple and keyword arguments may be passed.
"""
_cleanups.append((func, args, kw))
class CleanUp(object):
"""Mix-in class providing clean-up setUp and tearDown routines."""
def cleanUp(self):
"""Clean up global data."""
cleanUp()
setUp = tearDown = cleanUp
def cleanUp():
"""Clean up global data."""
for func, args, kw in _cleanups:
func(*args, **kw)
setUp = tearDown = cleanUp
This source diff could not be displayed because it is too large. You can view the blob instead.
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Extension to use doctest tests as unit tests
This module provides a DocTestSuite contructor for converting doctest
tests to unit tests.
$Id$
"""
from doctest import DocFileSuite, DocTestSuite
from doctest import debug_src, debug
def pprint():
from pprint import PrettyPrinter
def pprint(ob, **opts):
if 'width' not in opts:
opts['width'] = 1
return PrettyPrinter(**opts).pprint(ob)
return pprint
pprint = pprint()
"""HTML parser that extracts form information.
This is intended to support functional tests that need to extract
information from HTML forms returned by the publisher.
See *formparser.txt* for documentation.
"""
__docformat__ = "reStructuredText"
import HTMLParser
import urlparse
def parse(data, base=None):
"""Return a form collection parsed from `data`.
`base` should be the URL from which `data` was retrieved.
"""
parser = FormParser(data, base)
return parser.parse()
class FormParser(object):
def __init__(self, data, base=None):
self.data = data
self.base = base
self._parser = HTMLParser.HTMLParser()
self._parser.handle_data = self._handle_data
self._parser.handle_endtag = self._handle_endtag
self._parser.handle_starttag = self._handle_starttag
self._parser.handle_startendtag = self._handle_starttag
self._buffer = []
self.current = None
self.forms = FormCollection()
def parse(self):
"""Parse the document, returning the collection of forms."""
self._parser.feed(self.data)
self._parser.close()
return self.forms
# HTMLParser handlers
def _handle_data(self, data):
self._buffer.append(data)
def _handle_endtag(self, tag):
if tag == "textarea":
self.textarea.value = "".join(self._buffer)
self.textarea = None
elif tag == "select":
self.select = None
elif tag == "option":
option = self.select.options[-1]
label = "".join(self._buffer)
if not option.label:
option.label = label
if not option.value:
option.value = label
if option.selected:
if self.select.multiple:
self.select.value.append(option.value)
else:
self.select.value = option.value
def _handle_starttag(self, tag, attrs):
del self._buffer[:]
d = {}
for name, value in attrs:
d[name] = value
name = d.get("name")
id = d.get("id") or d.get("xml:id")
if tag == "form":
method = kwattr(d, "method", "get")
action = d.get("action", "").strip() or None
if self.base and action:
action = urlparse.urljoin(self.base, action)
enctype = kwattr(d, "enctype", "application/x-www-form-urlencoded")
self.current = Form(name, id, method, action, enctype)
self.forms.append(self.current)
elif tag == "input":
type = kwattr(d, "type", "text")
checked = "checked" in d
disabled = "disabled" in d
readonly = "readonly" in d
src = d.get("src", "").strip() or None
if self.base and src:
src = urlparse.urljoin(self.base, src)
value = d.get("value")
size = intattr(d, "size")
maxlength = intattr(d, "maxlength")
self.current[name] = Input(name, id, type, value,
checked, disabled, readonly,
src, size, maxlength)
elif tag == "button":
pass
elif tag == "textarea":
disabled = "disabled" in d
readonly = "readonly" in d
self.textarea = Input(name, id, "textarea", None,
None, disabled, readonly,
None, None, None)
self.textarea.rows = intattr(d, "rows")
self.textarea.cols = intattr(d, "cols")
self.current[name] = self.textarea
# The value will be set when the </textarea> is seen.
elif tag == "base":
href = d.get("href", "").strip()
if href and self.base:
href = urlparse.urljoin(self.base, href)
self.base = href
elif tag == "select":
disabled = "disabled" in d
multiple = "multiple" in d
size = intattr(d, "size")
self.select = Select(name, id, disabled, multiple, size)
self.current[name] = self.select
elif tag == "option":
disabled = "disabled" in d
selected = "selected" in d
value = d.get("value")
label = d.get("label")
option = Option(id, value, selected, label, disabled)
self.select.options.append(option)
def kwattr(d, name, default=None):
"""Return attribute, converted to lowercase."""
v = d.get(name, default)
if v != default and v is not None:
v = v.strip().lower()
v = v or default
return v
def intattr(d, name):
"""Return attribute as an integer, or None."""
if name in d:
v = d[name].strip()
return int(v)
else:
return None
class FormCollection(list):
"""Collection of all forms from a page."""
def __getattr__(self, name):
for form in self:
if form.name == name:
return form
raise AttributeError, name
class Form(dict):
"""A specific form within a page."""
def __init__(self, name, id, method, action, enctype):
super(Form, self).__init__()
self.name = name
self.id = id
self.method = method
self.action = action
self.enctype = enctype
class Input(object):
"""Input element."""
rows = None
cols = None
def __init__(self, name, id, type, value, checked, disabled, readonly,
src, size, maxlength):
super(Input, self).__init__()
self.name = name
self.id = id
self.type = type
self.value = value
self.checked = checked
self.disabled = disabled
self.readonly = readonly
self.src = src
self.size = size
self.maxlength = maxlength
class Select(Input):
"""Select element."""
def __init__(self, name, id, disabled, multiple, size):
super(Select, self).__init__(name, id, "select", None, None,
disabled, None, None, size, None)
self.options = []
self.multiple = multiple
if multiple:
self.value = []
class Option(object):
"""Individual value representation for a select element."""
def __init__(self, id, value, selected, label, disabled):
super(Option, self).__init__()
self.id = id
self.value = value
self.selected = selected
self.label = label
self.disabled = disabled
==================
Parsing HTML Forms
==================
Sometimes in functional tests, information from a generated form must
be extracted in order to re-submit it as part of a subsequent request.
The `zope.testing.formparser` module can be used for this purpose.
The scanner is implemented using the `FormParser` class. The
constructor arguments are the page data containing the form and
(optionally) the URL from which the page was retrieved:
>>> import zope.testing.formparser
>>> page_text = '''\
... <html><body>
... <form name="form1" action="/cgi-bin/foobar.py" method="POST">
... <input type="hidden" name="f1" value="today" />
... <input type="submit" name="do-it-now" value="Go for it!" />
... <input type="IMAGE" name="not-really" value="Don't."
... src="dont.png" />
... <select name="pick-two" size="3" multiple>
... <option value="one" selected>First</option>
... <option value="two" label="Second">Another</option>
... <optgroup>
... <option value="three">Third</option>
... <option selected="selected">Fourth</option>
... </optgroup>
... </select>
... </form>
...
... Just for fun, a second form, after specifying a base:
... <base href="http://www.example.com/base/" />
... <form action = 'sproing/sprung.html' enctype="multipart/form">
... <textarea name="sometext" rows="5">Some text.</textarea>
... <input type="Image" name="action" value="Do something."
... src="else.png" />
... </form>
... </body></html>
... '''
>>> parser = zope.testing.formparser.FormParser(page_text)
>>> forms = parser.parse()
>>> len(forms)
2
>>> forms.form1 is forms[0]
True
>>> forms.form1 is forms[1]
False
More often, the `parse()` convenience function is all that's needed:
>>> forms = zope.testing.formparser.parse(
... page_text, "http://cgi.example.com/somewhere/form.html")
>>> len(forms)
2
>>> forms.form1 is forms[0]
True
>>> forms.form1 is forms[1]
False
Once we have the form we're interested in, we can check form
attributes and individual field values:
>>> form = forms.form1
>>> form.enctype
'application/x-www-form-urlencoded'
>>> form.method
'post'
>>> keys = form.keys()
>>> keys.sort()
>>> keys
['do-it-now', 'f1', 'not-really', 'pick-two']
>>> not_really = form["not-really"]
>>> not_really.type
'image'
>>> not_really.value
"Don't."
>>> not_really.readonly
False
>>> not_really.disabled
False
Note that relative URLs are converted to absolute URLs based on the
``<base>`` element (if present) or using the base passed in to the
constructor.
>>> form.action
'http://cgi.example.com/cgi-bin/foobar.py'
>>> not_really.src
'http://cgi.example.com/somewhere/dont.png'
>>> forms[1].action
'http://www.example.com/base/sproing/sprung.html'
>>> forms[1]["action"].src
'http://www.example.com/base/else.png'
The ``<textarea>`` element provides some additional attributes:
>>> ta = forms[1]["sometext"]
>>> print ta.rows
5
>>> print ta.cols
None
>>> ta.value
'Some text.'
The ``<select>`` element provides access to the options as well:
>>> select = form["pick-two"]
>>> select.multiple
True
>>> select.size
3
>>> select.type
'select'
>>> select.value
['one', 'Fourth']
>>> options = select.options
>>> len(options)
4
>>> [opt.label for opt in options]
['First', 'Second', 'Third', 'Fourth']
>>> [opt.value for opt in options]
['one', 'two', 'three', 'Fourth']
##############################################################################
#
# Copyright (c) 2004 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Support for testing logging code
If you want to test that your code generates proper log output, you
can create and install a handler that collects output:
>>> handler = InstalledHandler('foo.bar')
The handler is installed into loggers for all of the names passed. In
addition, the logger level is set to 1, which means, log
everything. If you want to log less than everything, you can provide a
level keyword argument. The level setting effects only the named
loggers.
Then, any log output is collected in the handler:
>>> logging.getLogger('foo.bar').exception('eek')
>>> logging.getLogger('foo.bar').info('blah blah')
>>> for record in handler.records:
... print record.name, record.levelname
... print ' ', record.getMessage()
foo.bar ERROR
eek
foo.bar INFO
blah blah
A similar effect can be gotten by just printing the handler:
>>> print handler
foo.bar ERROR
eek
foo.bar INFO
blah blah
After checking the log output, you need to uninstall the handler:
>>> handler.uninstall()
At which point, the handler won't get any more log output.
Let's clear the handler:
>>> handler.clear()
>>> handler.records
[]
And then log something:
>>> logging.getLogger('foo.bar').info('blah')
and, sure enough, we still have no output:
>>> handler.records
[]
$Id$
"""
import logging
class Handler(logging.Handler):
def __init__(self, *names, **kw):
logging.Handler.__init__(self)
self.names = names
self.records = []
self.setLoggerLevel(**kw)
def setLoggerLevel(self, level=1):
self.level = level
self.oldlevels = {}
def emit(self, record):
self.records.append(record)
def clear(self):
del self.records[:]
def install(self):
for name in self.names:
logger = logging.getLogger(name)
self.oldlevels[name] = logger.level
logger.setLevel(self.level)
logger.addHandler(self)
def uninstall(self):
for name in self.names:
logger = logging.getLogger(name)
logger.setLevel(self.oldlevels[name])
logger.removeHandler(self)
def __str__(self):
return '\n'.join(
[("%s %s\n %s" %
(record.name, record.levelname,
'\n'.join([line
for line in record.getMessage().split('\n')
if line.strip()])
)
)
for record in self.records]
)
class InstalledHandler(Handler):
def __init__(self, *names):
Handler.__init__(self, *names)
self.install()
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""logging handler for tests that check logging output.
$Id$
"""
import logging
class Handler(logging.Handler):
"""Handler for use with unittest.TestCase objects.
The handler takes a TestCase instance as a constructor argument.
It can be registered with one or more loggers and collects log
records they generate.
The assertLogsMessage() and failIfLogsMessage() methods can be
used to check the logger output and causes the test to fail as
appropriate.
"""
def __init__(self, testcase, propagate=False):
logging.Handler.__init__(self)
self.records = []
# loggers stores (logger, propagate) tuples
self.loggers = []
self.closed = False
self.propagate = propagate
self.testcase = testcase
def close(self):
"""Remove handler from any loggers it was added to."""
if self.closed:
return
for logger, propagate in self.loggers:
logger.removeHandler(self)
logger.propagate = propagate
self.closed = True
def add(self, name):
"""Add handler to logger named name."""
logger = logging.getLogger(name)
old_prop = logger.propagate
logger.addHandler(self)
if self.propagate:
logger.propagate = 1
else:
logger.propagate = 0
self.loggers.append((logger, old_prop))
def emit(self, record):
self.records.append(record)
def assertLogsMessage(self, msg, level=None):
for r in self.records:
if r.getMessage() == msg:
if level is not None and r.levelno == level:
return
msg = "No log message contained %r" % msg
if level is not None:
msg += " at level %d" % level
self.testcase.fail(msg)
def failIfLogsMessage(self, msg):
for r in self.records:
if r.getMessage() == msg:
self.testcase.fail("Found log message %r" % msg)
##############################################################################
#
# Copyright (c) 2004 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Fake module support
$Id$
"""
import sys
class FakeModule:
def __init__(self, dict):
self.__dict = dict
def __getattr__(self, name):
try:
return self.__dict[name]
except KeyError:
raise AttributeError, name
def setUp(test, name='README.txt'):
dict = test.globs
dict['__name__'] = name
sys.modules[name] = FakeModule(dict)
def tearDown(test, name='README.txt'):
del sys.modules[name]
##############################################################################
#
# Copyright (c) 2004 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.1 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE.
#
##############################################################################
"""Tests for the testing framework.
$Id$
"""
import unittest
from zope.testing.doctestunit import DocTestSuite, DocFileSuite
def test_suite():
return unittest.TestSuite((
DocFileSuite('formparser.txt'),
DocTestSuite('zope.testing.loggingsupport'),
))
if __name__ == '__main__':
unittest.main(defaultTest='test_suite')
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