The AMI mapping using the AsyncResult API is deprecated and provided only for backward compatibility. New applications should use the Futures API.
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Basic Asynchronous API in Python
Consider the following simple Slice definition:
module Demo { interface Employees { string getName(int number); } }
Asynchronous Proxy Methods in Python
Besides the synchronous proxy methods, the Python mapping generates the following asynchronous proxy methods:
def begin_getName(self, number, _response=None, _ex=None, _sent=None, _ctx=None) def end_getName(self, result)
As you can see, the single getName
operation results in begin_getName
and end_getName
methods. The begin_ method
optionally accepts a per-invocation context and callbacks.
- The
begin_getName
method sends (or queues) an invocation ofgetName
. This method does not block the calling thread. - The
end_getName
method collects the result of the asynchronous invocation. If, at the time the calling thread callsend_getName
, the result is not yet available, the calling thread blocks until the invocation completes. Otherwise, if the invocation completed some time before the call toend_getName
, the method returns immediately with the result.
A client could call these methods as follows:
e = EmployeePrx.checkedCast(...) r = e.begin_getName(99) # Continue to do other things here... name = e.end_getName(r)
Because begin_getName
does not block, the calling thread can do other things while the operation is in progress.
Note that begin_getName
returns a value of type AsyncResult
. This value contains the state that the Ice run time requires to keep track of the asynchronous invocation. You must pass the AsyncResult
that is returned by the begin_
method to the corresponding end_
method.
The begin_
method has one parameter for each in-parameter of the corresponding Slice operation. The end_
method accepts the AsyncResult
object as its only argument and returns the out-parameters using the same semantics as for regular synchronous invocations. For example, consider the following operation:
double op(int inp1, string inp2, out bool outp1, out long outp2);
The begin_op
and end_op
methods have the following signature:
def begin_op(self, inp1, inp2, ...) def end_op(self, result)
The call to end_op
returns the following tuple:
doubleValue, outp1, outp2 = p.end_op(result)
Asynchronous Exception Semantics in Python
If an invocation raises an exception, the exception is thrown by the end_
method, even if the actual error condition for the exception was encountered during the begin_
method ("on the way out"). The advantage of this behavior is that all exception handling is located with the code that calls the end_
method (instead of being present twice, once where the begin_
method is called, and again where the end_
method is called).
There is one exception to the above rule: if you destroy the communicator and then make an asynchronous invocation, the begin_
method throws CommunicatorDestroyedException
. This is necessary because, once the run time is finalized, it can no longer throw an exception from the end_
method.
The only other exception that is thrown by the begin_
and end_
methods is RuntimeError
. This exception indicates that you have used the API incorrectly. For example, the begin_
method throws this exception if you call an operation that has a return value or out-parameters on a oneway proxy. Similarly, the end_
method throws this exception if you use a different proxy to call the end_
method than the proxy you used to call the begin_
method, or if the AsyncResult
you pass to the end_
method was obtained by calling the begin_
method for a different operation.
AsyncResult
Class in Python
The AsyncResult
that is returned by the begin_
method encapsulates the state of the asynchronous invocation:
class AsyncResult: def cancel() def getCommunicator() def getConnection() def getProxy() def getOperation() def isCompleted() def waitForCompleted() def isSent() def waitForSent() def throwLocalException() def sentSynchronously()
The methods have the following semantics:
cancel()
This method prevents a queued invocation from being sent or, if the invocation has already been sent, ignores a reply if the server sends one.cancel
is a local operation and has no effect on the server. A canceled invocation is considered to be completed, meaningisCompleted
returns true, and the result of the invocation is anIce.InvocationCanceledException
.
getCommunicator()
This method returns the communicator that sent the invocation.
getConnection()
This method returns the connection that was used for the invocation. Note that, for typical asynchronous proxy invocations, this method returns a nil value because the possibility of automatic retries means the connection that is currently in use could change unexpectedly. ThegetConnection
method only returns a non-nil value when theAsyncResult
object is obtained by callingbegin_flushBatchRequests
on aConnection
object.
getProxy()
This method returns the proxy that was used to call thebegin_
method, or nil if theAsyncResult
object was not obtained via an asynchronous proxy invocation.
getOperation()
This method returns the name of the operation.
isCompleted()
This method returns true if, at the time it is called, the result of an invocation is available, indicating that a call to theend_
method will not block the caller. Otherwise, if the result is not yet available, the method returns false.
waitForCompleted()
This method blocks the caller until the result of an invocation becomes available.
isSent()
When you call thebegin_
method, the Ice run time attempts to write the corresponding request to the client-side transport. If the transport cannot accept the request, the Ice run time queues the request for later transmission.isSent
returns true if, at the time it is called, the request has been written to the local transport (whether it was initially queued or not). Otherwise, if the request is still queued or an exception occurred before the request could be sent,isSent
returns false.
waitForSent()
This method blocks the calling thread until a request has been written to the client-side transport, or an exception occurs. AfterwaitForSent
returns,isSent
returns true if the request was successfully written to the client-side transport, or false if an exception occurred. In the case of a failure, you can call the correspondingend_
method orthrowLocalException
to obtain the exception.
throwLocalException()
This method throws the local exception that caused the invocation to fail. If no exception has occurred yet,throwLocalException
does nothing.
sentSynchronously()
This method returns true if a request was written to the client-side transport without first being queued. If the request was initially queued,sentSynchronously
returns false (independent of whether the request is still in the queue or has since been written to the client-side transport).
Polling for Completion in Python
The AsyncResult
methods allow you to poll for call completion. Polling is useful in a variety of cases. As an example, consider the following simple interface to transfer files from client to server:
interface FileTransfer { void send(int offset, ByteSeq bytes); }
The client repeatedly calls send
to send a chunk of the file, indicating at which offset in the file the chunk belongs. A naïve way to transmit a file would be along the following lines:
file = open(...) ft = FileTransferPrx.checkedCast(...) chunkSize = ... offset = 0 while not file.eof(): bytes = file.read(chunkSize) # Read a chunk ft.send(offset, bytes) # Send the chunk offset += len(bytes.length)
This works, but not very well: because the client makes synchronous calls, it writes each chunk on the wire and then waits for the server to receive the data, process it, and return a reply before writing the next chunk. This means that both client and server spend much of their time doing nothing — the client does nothing while the server processes the data, and the server does nothing while it waits for the client to send the next chunk.
Using asynchronous calls, we can improve on this considerably:
file = open(...) ft = FileTransferPrx.checkedCast(...) chunkSize = ... offset = 0 results = [] numRequests = 5 while not file.eof(): bytes = file.read(chunkSize) # Read a chunk # Send up to numRequests + 1 chunks asynchronously. r = ft.begin_send(offset, bytes) offset += len(bytes) # Wait until this request has been passed to the transport. r.waitForSent() results.append(r) # Once there are more than numRequests, wait for the least # recent one to complete. while len(results) > numRequests: r = results[0] del results[0] r.waitForCompleted() # Wait for any remaining requests to complete. while len(results) > 0: r = results[0] del results[0] r.waitForCompleted()
With this code, the client sends up to numRequests + 1
chunks before it waits for the least recent one of these requests to complete. In other words, the client sends the next request without waiting for the preceding request to complete, up to the limit set by numRequests
. In effect, this allows the client to "keep the pipe to the server full of data": the client keeps sending data, so both client and server continuously do work.
Obviously, the correct chunk size and value of numRequests
depend on the bandwidth of the network as well as the amount of time taken by the server to process each request. However, with a little testing, you can quickly zoom in on the point where making the requests larger or queuing more requests no longer improves performance. With this technique, you can realize the full bandwidth of the link to within a percent or two of the theoretical bandwidth limit of a native socket connection.
Completion Callbacks in Python
The begin_
method accepts three optional callback arguments that allow you to be notified asynchronously when a request completes. Here are the corresponding methods for the getName
operation:
def begin_getName(self, number, _response=None, _ex=None, _sent=None, _ctx=None)
The value you pass for the response callback (_response
), the exception callback (_ex
), or the sent callback (_sent
) argument must be a callable object such as a function or method. The response callback is invoked when the request completes successfully, and the exception callback is invoked when the operation raises an exception. (The sent callback is primarily used for flow control.)
For example, consider the following callbacks for an invocation of the getName
operation:
def getNameCB(name): print "Name is: " + name def failureCB(ex): print "Exception is: " + str(ex)
The response callback parameters depend on the operation signature. If the operation has a non-void
return type, the first parameter of the response callback is the return value. The return value (if any) is followed by a parameter for each out-parameter of the corresponding Slice operation, in the order of declaration.
The exception callback is invoked if the invocation fails because of an Ice run time exception, or if the operation raises a user exception.
To inform the Ice run time that you want to receive callbacks for the completion of the asynchronous call, you pass the callbacks to the begin_
method:
e = EmployeesPrx.checkedCast(...) e.begin_getName(99, getNameCB, failureCB)
Although the signature of an asynchronous proxy method implies that all of the callbacks are optional and therefore can be supplied in any combination, Ice enforces the following semantics at run time:
- If you omit all callbacks, you must call the
end_
method explicitly as described earlier. - If you supply either a response callback or a sent callback (or both), you must also supply an exception callback.
- You may omit the response callback for an operation that returns no data (that is, an operation with a
void
return type and no out-parameters).
Sharing State Between begin_
and end_
Methods in Python
It is common for the end_
method to require access to some state that is established by the code that calls the begin_
method. As an example, consider an application that asynchronously starts a number of operations and, as each operation completes, needs to update different user interface elements with the results. In this case, the begin_
method knows which user interface element should receive the update, and the end_
method needs access to that element.
Assuming that we have a Widget
class that designates a particular user interface element, you could pass different widgets by storing the widget to be used as a member of a callback class:
class MyCallback(object): def __init__(self, w): self._w = w def getNameCB(self, name): self._w.writeString(name) def failureCB(self, ex): print "Exception is: " + str(ex)
For this example, we assume that widgets have a writeString
method that updates the relevant UI element.
When you call the begin_
method, you pass the appropriate callback instance to inform the end_
method how to update the display:
e = EmployeesPrx.checkedCast(...) widget1 = ... widget2 = ... # Invoke the getName operation with different widget callbacks. cb1 = MyCallback(widget1) e.begin_getName(99, cb1.getNameCB, cb1.failureCB) cb2 = MyCallback(widget2) e.begin_getName(24, cb2.getNameCB, cb2.failureCB)
The callback class provides a simple and effective way for you to pass state between the point where an operation is invoked and the point where its results are processed. Moreover, if you have a number of operations that share common state, you can pass the same callback instance to multiple invocations. (If you do this, your callback methods may need to use synchronization.)
For those situations in which a stateless callback is preferred, you can use a lambda function to pass state to a callback. Consider the following example:
def getNameCB(name, w): w.writeString(name) def failureCB(ex): print "Exception is: " + str(ex) e = EmployeesPrx.checkedCast(...) widget1 = ... widget2 = ... # Use lambda functions to pass state. e.begin_getName(99, lambda name: getNameCB(name, widget1), failureCB) e.begin_getName(24, lambda name: getNameCB(name, widget2), failureCB)
This strategy eliminates the need to encapsulate shared state in a callback class. Since lambda functions can refer to variables in the enclosing scope, they provide a convenient way to pass state directly to your callback.
Asynchronous Oneway Invocations in Python
You can invoke operations via oneway proxies asynchronously, provided the operation has void
return type, does not have any out-parameters, and does not raise user exceptions. If you call the begin_
method on a oneway proxy for an operation that returns values or raises a user exception, the begin_
method throws a RuntimeError
.
The callback signatures look exactly as for a twoway invocation, but the response method is never called and may be omitted.
Flow Control in Python
Asynchronous method invocations never block the thread that calls the begin_
method: the Ice run time checks to see whether it can write the request to the local transport. If it can, it does so immediately in the caller's thread. (In that case, AsyncResult.sentSynchronously
returns true.) Alternatively, if the local transport does not have sufficient buffer space to accept the request, the Ice run time queues the request internally for later transmission in the background. (In that case, AsyncResult.sentSynchronously
returns false.)
This creates a potential problem: if a client sends many asynchronous requests at the time the server is too busy to keep up with them, the requests pile up in the client-side run time until, eventually, the client runs out of memory.
The API provides a way for you to implement flow control by counting the number of requests that are queued so, if that number exceeds some threshold, the client stops invoking more operations until some of the queued operations have drained out of the local transport.
You can supply a sent callback to be notified when the request was successfully sent:
def response(name): # ... def exception(ex): # ... def sent(sentSynchronously): # ...
You inform the Ice run time that you want to be informed when a call has been passed to the local transport as usual:
e.begin_getName(99, response, exception, sent)
If the Ice run time can immediately pass the request to the local transport, it does so and invokes the sent callback from the thread that calls the begin_
method. On the other hand, if the run time has to queue the request, it calls the sent callback from a different thread once it has written the request to the local transport. The boolean sentSynchronously
parameter indicates whether the request was sent synchronously or was queued.
The sent callback allows you to limit the number of queued requests by counting the number of requests that are queued and decrementing the count when the Ice run time passes a request to the local transport.
Asynchronous Batch Requests in Python
You can invoke operations via oneway proxies asynchronously, provided the operation has void
return type, does not have any out-parameters, and does not raise user exceptions. If you call the begin_
method on a oneway proxy for an operation that returns values or raises a user exception, the begin_
method throws a RuntimeError
.
A batch oneway invocation never calls the callbacks unless an error occurs before the request is queued. The returned AsyncResult
for a batch oneway invocation is always completed and indicates the successful queuing of the batch invocation. The returned result can also be marked completed if an error occurs before the request is queued.
Applications that send batched requests can either flush a batch explicitly or allow the Ice run time to flush automatically. The proxy method ice_flushBatchRequests
performs an immediate flush using the synchronous invocation model and may block the calling thread until the entire message can be sent. Ice also provides asynchronous versions of this method so you can flush batch requests asynchronously.
begin_ice_flushBatchRequests
and end_ice_flushBatchRequests
are proxy methods that flush any batch requests queued by that proxy.
In addition, similar methods are available on the communicator and the Connection
object that is returned by AsyncResult.getConnection
. These methods flush batch requests sent via the same communicator and via the same connection, respectively.
Concurrency Semantics for AMI in Python
The Ice run time always invokes your callback methods from a separate thread, with one exception: it calls the sent callback from the thread calling the begin_
method if the request could be sent synchronously. In the sent
callback, you know which thread is calling the callback by looking at the sentSynchronously
parameter.