Go to the previous, next section.
T-1
would correspond to
the Python class T_1
.
Any place an ISL name appears as part or all of a Python
identifier, this translation occurs.
interface
I
generates two Python modules:
one named I
containing common definitions,
and another named I__skel
containing skeletons (server stubs).
For example,
INTERFACE map-test;
generates the Python modules
map_test
and map_test__skel
, contained in the files
`map_test.py' and `map_test__skel.py', respectively.
ilu.LongReal()
.
CONSTANT pi : real = 3.14159265358979323846;maps to
pi = 3.14159265358979323846e0
SEQUENCE OF SHORT CHARACTER
maps into a Python
string. SEQUENCE OF BYTE
is also mapped into a Python string.
PICKLE
is an instance
of the Python class ilu.Pickle
. Instances of
this class have the following methods:
typecode()
- returns the typecode of the pickle's value as a string.
value()
- returns the Python form of the value in the pickle.
bytes()
- the pickled bytes of the pickled value as a string.
The constructor for this class takes two arguments, typecode and value,
and returns
a new pickle containing the value specified by value of the ISL type
specified by typecode. Pickles may also be created by calling the constructor
with a single argument string, which must be the result of an earlier call on the bytes()
method of another pickle instance.
Typecodes are represented by the Python class ilu.Typecode
. Typecodes are constructed
with a single string argument,
of the form 'interface.type'
, where
interface is the ISL name for the interface, and type is the
ISL name for the type. Instances of the Typecode
class support the method
id()
- return the ILU type ID (CORBA repository ID) for the typecode's type.
name()
- return the ISL name of the typecode's type.
For example,
TYPE color = ENUMERATION red, dark-blue END;maps to
class color: red = 0; dark_blue = 1; __image__ = { red: 'red', dark_blue: 'dark_blue'};
All other ISL sequence types map into Python lists. Tuples as well as lists are accepted as input, but lists are always produced as output from ILU. Sequences of BYTE or SHORT CHARACTER are represented as Python strings.
For example, a record value of the ISL type
TYPE segment = RECORD left-limit : integer, right-limit : integer END;with a left-limit of -3 and a right-limit of 7 would map to
segment(-3, 7) => <segment:{'left-limit' : -3, 'right-limit' : 7}>
OTHERS
attribute,
the second component is None
.
OPTIONAL T
may be None
(indicating the null case) in addition to the values of the
type T.
All surrogate object types inherit from iluRt.IluObjSurr
, which in turn inherits
from iluRt.IluObject
. True object types inherit from IluRt.IluObjTrue
,
which also inherits from iluRt.IluObject
. The method IluTrueP()
will return a true value on true instances, and a false value on surrogate instances.
The string binding handle of an
object instance can be retrieved with the method IluSBH()
. The object-id of
an instance can be retrieved with IluObjectID()
; it returns a tuple containing
a string server ID and a string instance-handle. If support for the
CORBA IIOP
is configured into your ILU build, the
string IOR of an instance can be retrieved by calling the function ilu.IOROfObject()
,
passing the instance as the argument. The type name of the most specific type of an instance
can be retrieved with the method IluTypeName()
; the unique ID of that type can
be retrieve with the method IluTypeID()
.
Object types which inherit from the ISL type ilu.CORBA-Object
(which include
all object types defined with OMG IDL), will inherit from the Python
class
, which is the same as the class
ilu.CORBA_Object
.
CORBA.Object
ISL methods of an object type map to Python methods
of the corresponding class.
IN
and INOUT
parameters appear in the Python method
signature in the same order as they do in ISL.
Let us define a result value to be either
a return value (corresponding to a method's return type) or
an INOUT
or OUT
parameter.
Result values are returned by the Python method as a tuple,
with the return value (if present) appearing before any parameters.
If the method has only one result value, then it is simply returned
(i.e., a tuple of length one is not constructed to hold this value).
If the method has no result values, then None
is returned.
An ISL exception translates to a Python variable
initialized with a string representing the exception.
These variables are used in Python raise
statements
in object implementation code, and in try ... except
statements
in client code.
For example, the declaration
EXCEPTION division-by-zero;in the interface
map-test
maps to the following statement in
`map_test.py':
division = 'map-test: division-by-zero'
ASYNCHRONOUS
methods have no return values and raise no user-specified exceptions.
They may return before the completion of the true method. FUNCTIONAL
methods
that have no parameters are cached so that a surrogate address space makes only
one call to the true address space to retrieve the return value.
All instances of ILU object types are covered by the normal Python garbage collection; i.e., the application program must maintain a reference to the instance, or it will be garbage collected. With true instances of COLLECTIBLE object types, the ILU kernel will maintain an additional reference to the instance as long as it has registered clients using that instance.
Each object exported by an implementation must belong to a true server,
an instance of the Python type ilu_Server
which is
implemented by the ILU runtime.
An ilu_Server
can be created by calling the function
ilu.CreateServer([serverID [, transport [, protocol [, objectTable]]]])
,
which returns a value of type ilu_Server
.
If serverID is a string, it specifies the server ID;
if it is None
, one will be invented automatically.
The transport argument is either a sequence of strings, chosen to
be compatible with the protocol, or None
to let it default.
The protocol argument is either a string specifying a particular
RPC protocol, or None
to choose the default. Additional ports
can be added to a server with the
method,
if an application needs to make it available with via multiple protocols
or addresses.
addPort()
The first time a true server is created, it becomes the default server. The default server is used for an exported object if a server is not otherwise specified. If an object is exported before any servers have been created, one will be created automatically using default parameters and a message to that effect will be written to stderr.
An object of type ilu_Server
has the following methods:
id()
- returns the ILU server ID of the server.
addPort(TINFO, PINFO)
- adds another port to the server with the specified
TINFO and PINFO.
createSerializer()
- creates and returns a serialization context.
The objectTable argument allows specification of a callback function for creating true instances on demand. The callback function should take one argument, a string, which is the object ID of the instance to be created, and return a true instance.
To use threads, you must have configured both ILU and Python with thread
support when building them. If you have done this, your ILU/Python runtime support
will be thread-capable. To have ILU begin using threads, place a call to the
function ilu.ThreadedOperation()
in your Python program before any other
ILU calls are made.
ilu.RunMainLoop()
brings the true servers to life.
This function does not return until ilu.ExitMainLoop()
is called.
If you are using ILU with Tkinter
,
run the main loop by calling ilu_tk.RunMainLoop()
, rather
than using either the ILU or Tkinter
main loops.
ilu_tk.RunMainLoop
sets things up so that both Tk
and ILU events are handled.
ilu_Alarm
may be used.
Objects of this type are created by calling ilu.CreateAlarm()
.
An ilu_Alarm
must be set to have any effect.
The alarm's method set(time, proc, args)
is used to set the alarm.
The int
, float
, or ilu_FineTime
time
argument
is the time at which the alarm will fire;
the proc
argument is the Python function that will be
called when the alarm fires;
and
the args
argument is a tuple of arguments to be passed to proc
.
The tuple args
must match proc
's signature.
For example, if proc
is declared def P(a, b):
then args
must be a two-tuple.
Likewise, if proc
takes only one argument then args
must be
a one-tuple,
or if no arguments then a zero-tuple.
The function ilu.FineTime_Now()
may be called to obtain ILU's
idea of the current time.
A value sec
of type int
or float
in units of seconds
may be converted to type ilu_FineTime
by calling
ilu.FineTime(sec)
.
Values of type ilu_FineTime
may be compared, added, and subtracted.
These operations may be used to construct values representing any relative
time (subject to precision and range limitations), which is what is needed
by an alarm's set
method.
The alarm may be set multiple times with different arguments, in which
case the parameters of the most recent call to set
are in effect.
Thus, once an alarm fires, it may be reused by calling set
again.
An alarm may be unset by calling its method unset()
.
ILU generally supports a facility named custom records. This means that an application can declare that the language-specific mapping of a particular record type ISL(A) to lang(A) is to be overridden, and that instead a specific type X will be used in this language to represent values of ISL(A). In Python, this is done by simply replacing the generated class definition with a different class definition.
For example, suppose we had the ISL record type
INTERFACE Ifc; ... TYPE Foo = RECORD color : RGB-tuple, position : XY-pair END;The normal mapping of
Ifc.Foo
to Python would be to a class called Foo
with the following definition:
class Foo (iluRt.IluRecord): __ilu_type_name__ = 'Ifc.Foo' def __init__(self, _color, _position) self.color = _color; self.position = _position; def __getinitargs__(self): return (self.color, self.position)To override this, define a new class in your application that has matching signatures for
__init__
and __getinitargs__
, and a matching
value for __ilu_type_name__
. It must also inherit from IluRt.IluRecord
.
Then assign the class object for this new class to the symbol Foo
in the
Python module Ifc
. So:
class MyFoo (iluRt.IluRecord): __ilu_type_name__ = 'Ifc.Foo' def __init__(self, _color, _position): self.color = _color self.position = _position self.some_other_attr = whatever_I_want call_some_other_code(self) def __getinitargs__(self): return self.color, self.position ...possible other methods... Ifc.Foo = MyFoo
To use object tables properly, it is usually necessary for a client program
to create a surrogate instance for which the true instance does not yet exist.
In Python, this is done by creating a string binding handle for
the object, then calling
on that SBH.
String binding handles may be formed by calling the function ilu.ObjectOfSBH()
.
ilu.FormSBH()
IluPublish()
.
A true instance may be unpublished by calling its method IluWithdraw()
.
A published ILU object may be obtained by calling
ilu.LookupObject(sid, ih, cl)
,
where sid
is object's server's server ID, ih
is the object's instance handle, and cl
is its class.
An ILU passport (see section Security) is represented in
Python by an instance of the
object type. Instances of this type can be obtained by calling
ilu_Passport
. Please see the documentation
of that function for more information on the abilities of this object type.
ilu.CreatePassport()
The passport of the caller may be obtained in the true method by calling
the ILU runtime routine ilu.CallerIdentity()
.
The `native' passport may be obtained by calling
.
In the case of a local call, these two passports may be the same object.
Passports are thread-local; that is, an application may use a different passport
in each thread.
ilu.GetPassport()
python-stubber
.
Two files are generated from each ISL
INTERFACE name
:
Alternatively, for surrogate-side use the stubber can be run automatically
by a hook in the ilu
module. Calling
will establish the stubber as part of the normal Python ilu.AutoImport()
import
machinery, and will cause `.isl' and `.idl' files in directories on your ILUPATH
environment variable path to be automatically stubbed and loaded.
INTERFACE I
also imports from I__skel
.
This gives access to the skeleton classes from which implementation classes
inherit.
I__skel.T
.
If there is inheritance in the ISL, and an implementation of a
subtype wants to inherit from an implementation of a supertype,
the skeleton class must be appear in the list of base types
before the implementation class.
For example, objects for the ISL
INTERFACE j; TYPE c1 = OBJECT METHODS one() END; TYPE c2 = OBJECT METHODS two() END; TYPE c3 = OBJECT SUPERTYPES c1, c2 END METHODS three() END;could be implemented in Python by
import ilu, j, j__skel class c1(j__skel.c1): def one(self): ... class c2(j__skel.c2): def two(self): ... class c3(j__skel.c3, c1, c2): def three(self): ...In this case
c3
's method one
is implemented by c1.one
and
c3
's method two
is implemented by c2.two
.
IluSBH()
and communicating this somehow to a client,
who then turns the handle back into an object by calling
ilu.ObjectOfSBH(cl, sbh)
.
IluPublish()
.
In order for this to be effective, the object must have a well-known
object ID, or the object ID must be communicated to clients, so clients can
know what to pass to ilu.LookupObject
.
The object ID is a function of the object's instance handle and
its server's server ID.
INOUT
or OUT
parameter.
An object's instance handle can be controlled by setting the
instance variable IluInstHandle
before the object is first exported.
If this instance variable is not set, and instance handle will be
invented automatically.
An object's server can be controlled by setting the instance or class variable
IluServer
to a value of type ilu_Server
.
The value of this variable at the time an object is first exported will be
used as the server for that object.
If such a variable is not set, the default server is used.
ilu
.
Python definitions for ISL
INTERFACE I
are in the Python module
I
.
As with any other modules in Python, these modules are imported
using the import
statement.
A client program may create an ILU object in one of three ways:
sbh
and class cl
of an
object,
call ilu.ObjectOfSBH(cl, sbh)
which returns an instance of that class.
For example, to obtain an instance of ISL type square
from
INTERFACE shapes
whose string binding handle is sbh
,
one would call ilu.ObjectOfSBH(shapes.square, sbh)
.
(sid, ih)
and class cl
of an object that
has been published using the simple binding service,
call ilu.LookupObject(sid, ih, cl)
which returns an instance of that class
(or None
if the lookup fails).
INOUT
or OUT
parameter.
This release of ILU has several nods to an eventual CORBA mapping
for the Python language. The Python CORBA
module
contains support for the classes
and CORBA::ORB
, and the CORBA::Object
function.
See the Python/ILU API Reference for more information on these.
CORBA::ORB_init()
ilu
Function: AutoImport ([path=() [verbose=0]])
If called, enables the auto-loading of `.isl' and, if OMG IDL support is
configured into ILU, `.idl', files that are on the user's ILUPATH
environment variable. The python-stubber
program is run to generate the
Python surrogate stubs for the interface description into a temporary directory, and those stubs are
loaded into the current program. The stubber is re-run every time the interface is imported.
If an error occurs while producing the Python stubs, an exception is raised
and the import process stops. The path parameter has no effect; the
verbose parameter will cause various messages to be written to the
standard output during the process of importing, if set to a non-false value.
Returns the passport containing identities of the caller. This routine is only valid inside the code of a true method.
Creates an object of type ilu_Alarm
.
Creates and returns an instance of a "loop handle" object, which can
be passed to ilu.RunMainLoop
and ilu.ExitMainLoop()
.
Creates and returns an empty instance of a
object.
The ilu_Passport
object is used to provide a sense of identity
in the ILU system. It can hold any number of different identities,
each of which is represented with an appropriate data structure that varies
from identity type to identity type.
ilu_Passport
The
object type has the following methods:
ilu_Passport
lookupIdentity (IDENTITY-TYPE-NAME)
- returns
the data structure for the specified identity, if the passport contains one;
Returns None
otherwise. Raises ilu.IluGeneralError
if the
named identity type does not exist. The identity type 'ConnectionIdentity'
is always supported; the identity type 'SunRPCAuthUnixIdentity'
will be supported if support for the sunrpc
protocol has been configured
into ILU.
addSunRPCAuthUnix (HOSTNAME, UID, GID, TUPLE-OF-GROUPS)
-
adds an identity of type 'SunRPCAuthUnixIdentity'
to the passport
with the specified HOSTNAME, UID, GID, and TUPLE-OF-GROUPS.
See Appendix A of RFC 1831 at http://info.internet.isi.edu:80/in-notes/rfc/files/rfc1831.txt for details on the meaning of these parameters. This method will only be available if support for
the sunrpc
protocol has been configured into ILU.
Creates and returns an empty instance of a
object.
The ilu_Pipeline
object is used to allow
multiple requests to be outstanding on non-concurrent protocol streams.
The ilu_Pipeline
object has no methods.
ilu_Pipeline
Function: CreateServer ( [serverID [transport [protocol [objtable]]]] )
Used to create an ilu_Server
object with the specified
serverID, transport, and protocol.
If serverID is unspecified or None
, an identifier will be invented automatically.
If transport or protocol are unspecified or None
, they will default to
('sunrpcrm', 'tcp_0_0')
and 'sunrpc'
, respectively. (Other combinations that
would work are transport of ('tcp_0_0')
and protocol of 'iiop_1_0_1'
,
transport of ('sunrpcrm', 'tcp_0_0')
and protocol of 'courier'
, and
transport of ('tcp_0_0')
and protocol of 'http'
,
depending on the configuration of your ILU system.)
The first time
is called, the server so created becomes
the default server.
If there is no default server when one is required, one will be created
using default parameters and a message will be issued on stderr.
The objtable argument allows specification of a callback
function for creating true instances on demand. The callback function
should take one argument, a string, which is the object ID of the
instance to be created, and return a true instance.
CreateServer
An ilu_Server
object has the following methods:
id ()
- returns the string identifier of that server.
addPort (TRANSPORT, PROTOCOL)
- adds
a port with the specified TRANSPORT and PROTOCOL (described above) to the
server instance.
createSerializer()
- creates and returns a new serialization
context object.
Returns the default server.
Function: DoSoon (FUNCTION, ARGS-TUPLE, STRING-DESCRIPTION)
Causes the function FUNCTION to be run with args ARGS-TUPLE to be run at some point in the future, when the system finds it to be convenient. In the threaded world, a new thread is forked to run the function; in the non-threaded world, the function is executed at some point by the event loop as a background task.
Function: ExitMainLoop (loophandle)
Exits the ILU main loop, assuming it is running. The loophandle
is created by a call to ilu.CreateLoopHandle()
, and must have been
previously used as an argument to a call to ilu.RunMainLoop()
.
A value which evaluates to Python boolean False.
Converts its int
or float
argument seconds in units of seconds
to type ilu_FineTime
.
Objects of this type can be compared, added, subtracted, and converted to
int
or float
.
The main use of objects of this type is in setting alarms.
Function: FormSBH (sid, ih, type, pinfo, tinfo_vec)
Forms a valid ILU string binding handle from the arguments and returns it. The sid and ih arguments are strings containing the server ID and instance handle for the desired instance. The type argument should be the Python class for the most specific object type of the desired object. The pinfo argument is a tuple containing the protocol information describing the object implementation's preferred communication protocol. The tinfo_vec argument is a tuple of tuples, specifying the transport stack needed to connect to the implementation. Each sub-tuple in the tinfo_vec is a tuple describing a particular transport layer.
For instance, to create a string binding handle for an instance of type Foo.Bar
,
with server id "some-server-id"
and instance handle "some-instance-handle"
,
exported via Sun RPC
, version 2, with program number 1000007, version 3, via TCP/IP
from host "foobar.somewhere.com"
, port 3456, we'd say
sbh = ilu.FormSBH('some-server-id', 'some-instance-handle', Foo.Bar,
('sunrpc_2', 1000007, 3), (('sunrpcrm',), ('tcp', 'foobar.somewhere.com', 3456)))
Note the comma used after 'sunrpcrm'
to create a true tuple; note also that use of this procedure requires some specialized knowledge, such as knowing that use of Sun RPC
also requires use of the Sun RPC
record-marking transport layer when used over TCP/IP
.
The precision of type ilu_FineTime
in seconds is the reciprocal of
this constant.
Returns the current time as an ilu_FineTime
object.
Function: FormSBH (objectID, contactInfo)
Returns the string binding handle corresponding to the
object id objectID
and contact info contactInfo.
This is the inverse of
.
ParseSBH
Returns the current passport for this thread. See also
and CreatePassport()
.
SetPassport()
Returns the current pipeline context for this thread. See also
and CreatePipeline()
.
SetPipeline()
Returns the current serialization context for this thread. See also the
method on the createSerializer()
class, and the ilu_Server
function.
SetSerializer()
An exception that may be returned from the ILU runtime. This exception is used to return all `standard' exceptions, with a string value to indicate the specific type of standard exception that occurred.
An exception that may be returned from the ILU runtime. This exception is raised for all on-the-wire exceptions, with a value that indicates which kind of protocol exception occurred.
Exception: IluUnimplementedMethodError
An exception that may be returned from the ILU runtime. Raised when an unimplemented method is called, typically on a true instance.
Exception: IluUnknownTypeIDError
An exception that may be raised from the ILU runtime. It indicates that the associated type ID value is unknown in this address space.
If the IIOP
protocol has been configured in, returns the string IOR
of the object, as specified in the CORBA 2 IIOP specification. If
the IIOP
protocol has not been configured in, throws an
error.
Converts its int
, float
, or sixteen-integer list
or
tuple
argument to type ilu_LongReal
.
In case of a list or tuple, the elements encode the bytes of the
IEEE long real value, from most significant to least.
Function: LookupObject (sid, ih, cl)
Returns the object with object server ID sid, object instance handle ih,
and Python class cl
,
assuming it was previously published using the simple binding service.
If the lookup fails, None
is returned.
Function: ObjectOfSBH (cl, sbh)
Returns the object corresponding to the Python class cl and string binding handle sbh.
Returns the pair (object id, contact info) corresponding to the string binding handle sbh.
Function: RegisterCustomSurrogate (class)
Registers class as the object type to create when receiving a surrogate of the
type indicated by the _IluClass
field of class. class must
be a subtype of the default surrogate type for this ILU type. This allows custom
surrogates, with implications for caching and other object-type-specific functions.
Function: RegisterInputHandler (file, handler_fn)
Sets up an association between the file (which must be a file object
opened for reading), and the handler_fn (which must be a callable function
with no arguments) so that handler_fn is called whenever input is available
on file. This is useful for implementing a server that also responds
to commands typed to its standard input, for example. Passing a value of
None
for the handler_fn removes the association.
Function: RunMainLoop (loophandle)
Runs the ILU main loop. The argument loophandle is a "handle" on that loop invocation,
created by a call to ilu.CreateLoopHandle()
.
Function: SetCalloutExceptionHandler (handler-fn)
This function can be used to define a function handler-fn which is called when an internal Python
exception is signalled in code called from the ILU C code. The handler function receives
four arguments: a string indicating where in the ILU runtime the exception was encountered, the exception
type, the exception value, and a traceback object. This function is typically used to note the exception
to a file or stderr; see the example usage in `ILUSRC/runtime/python/iluRt.py'. If a parameter
of None
is passed to SetCalloutExceptionHandler
, it cancels any handler function in use,
and a default built-in one is used.
Function: SetDebugLevel (flags-or-switches)
Sets the ILU kernel debugging flags according to its int
argument, if an int is specified, or via the colon-separated list of
debug switches, if a string is specified. See the Debugging section of the
ILU Manual for more information on these switches.
Function: SetMainLoop (DoEvent, RegisterInput, CancelInput, RegisterOutput, CancelOutput, CreateAlarm, SetAlarm, CancelAlarm)
The purpose of this function is to be able to use a foreign main loop
(such as for a user interface toolkit)
with an ILU server.
The details will not be described here.
Look at the runtime module
for an example of its use.
ilu_tk
Function: SetPassport (passport)
Sets the current passport identity for this thread, and returns the passport active before this call.
Either of these can be None
. Also see the function
,
and the function CreatePassport
.
GetPassport
Function: SetPipeline (pipeline)
Sets the current pipelining context for this thread, and returns the context active before this call.
Either of these can be None
. Also see the function
,
and the function CreatePipeline
.
GetPipeline
Function: SetSerializer (serializer)
Sets the current serialization context for this thread, and returns the context active before this call.
Either of these can be None
. Also see the
method on
the class createSerializer
, and the function ilu_Server
.
GetSerializer
Function: ThreadedOperation ()
Enables thread use in both the ILU kernel and the ILU/Python runtime. This routine should be called before any other ILU calls are made.
A value which evaluates to Python boolean True.
Returns the ILU unique type identifier corresponding to the Python class cl.
Returns the ILU type name corresponding to the Python class cl.
The ILU version string.
CORBA
Module
A dictionary with string keys, and values of type
.
It is used to resolve strings passed as parameters to CORBA.Object
.
The following names are supported automatically by Python runtime:
CORBA.ORB.resolve_initial_references()
ILU_COS_NAMING_IOR
is bound to a string IOR
for a OMG IDL CosNaming::NamingContext
object instance,
the Python runtime will attempt to create a surrogate for that
instance locally, ping it, and if successful will bind it to the string "NameService"
.
Raised when an invalid name is passed to
.
Has the associated bad name as its value.
CORBA.ORB.resolve_initial_references()
Class: Object (ilu.IluObjSurr)
A type which all object types defined in OMG IDL, or inheriting
from ilu.CORBA-Object
in ISL, participate in. It supports
the following methods:
_is_a(type_uid)
- returns True
if the object is
of the specified type, False
otherwise; raises ilu.IluUnknownTypeIDError
if the type_uid is unknown in this address space;
_is_nil()
- returns False
; raises TypeError
if called
via CORBA.Object._is_nil()
on a non-Python-object type;
_non_existent()
- returns the logical inverse of the result of calling
ilu.PingObject()
on the object;
_is_equivalent(other)
- returns the result of comparing
self and other with the Python ==
operator;
_duplicate()
- does nothing, returns self;
_release()
- does nothing, returns nothing;
_hash(max_value)
- returns (hash(self) % (max_value + 1))
;
_get_implementation()
- raises IluUnimplementedMethodError
;
_get_interface()
- raises IluUnimplementedMethodError
;
CORBA.Object
class is actually implemented in iluRt.CORBA_Object
,
so all classes which inherit from ilu.CORBA_Object
will have access to these
methods.
The general class for manipulating the object request broker. There is typically
only one instance of this class per address space. It is retrieved with the
function
; it supports the following methods:
CORBA.ORB_init()
object_to_string(instance)
- returns
a string which can be used in a subsequent string_to_object()
call;
string_to_object(string)
- if the specified string
is well formed and specifies an object, the object is created locally and a reference is returned; the
reference may be to a true instance if the string names a true instance; if the string
is poorly formed, the Python exception ilu.IluGeneralError
is raised. This method does not test for the existence of the instance.
resolve_initial_references(string)
- If the
string argument is bound in the dictionary CORBA.InitialReferences
,
the value is returned. Otherwise, the exception CORBA.InvalidName
is raised.
See the documentation of CORBA.InitialReferences
for a listing of the
names that are bound automatically, if any.
Function: ORB_init (argv=(), orb_id='ilu')
Returns an instance of
with the specified orb_id (currently
only the ORB ID CORBA.ORB
'ilu'
is supported). The arguments which may be passed
in via argv are ignored.
IluObjectID()
returns the object ID of the object.
IluPublish()
publishes the object using the simple binding service.
IluSBH()
returns the object's string binding handle.
IluTypeID()
returns the unique type identifier of the
object's ILU type.
IluTypeName()
returns the type name of the object's ILU type.
IluWithdraw()
undoes the effect of IluPublish().
Special attributes of ILU true objects: One or more of the following attributes may be set in a true (implementation) object of an ISL object type to control certain aspects of that object.
IluInstHandle
, a string instance variable,
gives the object's instance handle.
If not present, an instance handle is invented automatically.
IluServer
, a variable of type ilu_Server
,
determines the object's server.
This can be an instance or a class variable.
If not present, the default server is used.
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