static void receiveCapabilityMessage(TransformerCapabilityMessage *message)
{
EMBX_ERROR err;
EMBX_PORT replyPort;
MMEReceiverFactory *factory;
message->result = MME_NOMEM; /* preliminary result */
/* connect to the reply port */
if (EMBX_SUCCESS != EMBX_Connect(manager->transportHandle, message->portName, &replyPort)) {
MME_Assert(0); /* cannot recover */
return;
}
/* TODO: no lock on this list */
for (factory = manager->factoryList; factory; factory = factory->next) {
if (0 == strcmp(factory->transformerType, message->transformerType)) {
break;
}
}
message->capability.TransformerInfo_p = (void *)
(message->capability.TransformerInfoSize ? message + 1 : 0);
message->result = (factory ? factory->getTransformerCapabilityFunc(&message->capability)
: MME_UNKNOWN_TRANSFORMER);
/* post the reply back again */
err = EMBX_SendMessage(replyPort, message, message->messageSize);
MME_Assert(EMBX_SUCCESS == err); /* cannot recover */
err = EMBX_ClosePort(replyPort);
MME_Assert(EMBX_SUCCESS == err); /* cannot recover */
}
static MME_ERROR RemoteTransformer_KillCommand(Transformer_t* transformer, MME_CommandId_t commandId)
{
RemoteTransformer_t *remoteTransformer = (RemoteTransformer_t *) transformer;
MME_ERROR result;
EMBX_ERROR err;
CommandSlot_t *slot;
EMBX_VOID *buffer;
TransformerTransformMessage *message;
EMBX_PORT replyPort;
/* TODO: shouldn't this be asserted! */
if (!remoteTransformer->sendPort.valid) {
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_ERROR_STR "MME port does not exist\n"));
return MME_DRIVER_NOT_INITIALIZED;
}
/* confirm that the command is actually pending on the companion before we
* issue the abort */
slot = &(remoteTransformer->commandSlots[MME_CMDID_GET_COMMAND(commandId)]);
if (slot->status != MME_RUNNING || commandId != slot->command->CmdStatus.CmdId) {
return MME_INVALID_ARGUMENT;
}
/* mark the command as complete */
slot->command->CmdStatus.Error = MME_COMMAND_ABORTED;
slot->command->CmdStatus.State = MME_COMMAND_FAILED;
/* fake up a completed transform request */
result = createTransformMessage(remoteTransformer, slot->command, &buffer);
if (result != MME_SUCCESS) {
return result;
}
/* connect to our own reply port */
err = EMBX_Connect(remoteTransformer->super.info->handle, remoteTransformer->replyPort.name, &replyPort);
if (EMBX_SUCCESS != err) {
return MME_EMBX_ERROR;
}
/* send the message */
message = (TransformerTransformMessage *) buffer;
err = EMBX_SendMessage(replyPort, message, message->messageSize);
if (EMBX_SUCCESS != err) {
return MME_EMBX_ERROR;
}
EMBX_ClosePort(replyPort);
return MME_SUCCESS;
}
static MME_ERROR RemoteTransformer_AbortCommand(Transformer_t* transformer, MME_CommandId_t commandId)
{
RemoteTransformer_t *remoteTransformer = (RemoteTransformer_t *) transformer;
EMBX_ERROR err;
EMBX_VOID *buffer;
TransformerAbortMessage *message;
CommandSlot_t *slot;
/* TODO: shouldn't this be asserted! */
if (!remoteTransformer->sendPort.valid) {
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_ERROR_STR "MME port does not exist\n"));
return MME_DRIVER_NOT_INITIALIZED;
}
/* confirm that the command is actually pending on the companion before we
* issue the abort */
slot = &(remoteTransformer->commandSlots[MME_CMDID_GET_COMMAND(commandId)]);
if (slot->status != MME_RUNNING || commandId != slot->command->CmdStatus.CmdId) {
return MME_INVALID_ARGUMENT;
}
/* Allocate an abort message and send it to the companion side, which disposes the buffer */
buffer = allocBuffer(remoteTransformer, sizeof(TransformerAbortMessage));
if (0 == buffer) {
return MME_NOMEM;
}
/* initialize the message */
message = (TransformerAbortMessage *) buffer;
message->id = TMESSID_ABORT;
message->messageSize = sizeof(TransformerAbortMessage);
message->commandId = commandId;
/* post the message */
err = EMBX_SendMessage(remoteTransformer->sendPort.port, message, message->messageSize);
if (err != EMBX_SUCCESS) {
/* If sending the message did not work, there is nothing we can do. */
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_ERROR_STR "EMBX_SendMessage(TransformerAbortMessage) failed, error=%d\n", err));
freeBuffer(remoteTransformer, buffer);
return MME_NOMEM;
}
/* success does not indicate the command has been aborted only
* that the request has been sent
*/
return MME_SUCCESS;
}
static void receiveIsAliveMessage(TransformerIsAliveMessage * message)
{
EMBX_PORT replyPort = EMBX_INVALID_HANDLE_VALUE;
EMBX_ERROR err;
MMEReceiver **prev = NULL, *receiver = NULL;
int id;
/* Search each receiver list for a matching handle */
for (id=0; id<MME_NUM_EXECUTION_LOOPS; id++) {
if (manager->loopTasksRunning[id]) {
EMBX_OS_MUTEX_TAKE(&(manager->receiverListMutexes[id]));
/* iterate of the receiver list keeping track of the linkage pointer */
for (prev = &(manager->receiverLists[id]), receiver = *prev;
NULL != receiver;
prev = &(receiver->next), receiver = *prev) {
if (receiver == (void *) (message->mmeHandle)) {
/* even Java lets you use labelled jumps to do this ... */
goto double_break;
}
}
EMBX_OS_MUTEX_RELEASE(&(manager->receiverListMutexes[id]));
} else {
MME_Assert(0 == manager->loopTasks[id]);
MME_Assert(0 == manager->receiverLists[id]);
}
}
double_break:
/* WARNING: if receiver is non-NULL we still own receiverListMutexes[id] */
if (NULL != receiver) {
replyPort = MME_Receiver_GetReplyPort(receiver);
EMBX_OS_MUTEX_RELEASE(&(manager->receiverListMutexes[id]));
/* send the message back to the host */
err = EMBX_SendMessage(replyPort, message, message->messageSize);
MME_Assert(EMBX_SUCCESS == err); /* cannot recover */
} else {
MME_Info(MME_INFO_MANAGER, ("receiveIsAliveMessage could not find receiver, no reply port available!\n"));
}
}
void send_thread(void *param)
{
EMBX_PORT port = (EMBX_PORT)param;
EMBX_ERROR res;
EMBX_VOID *buffer;
EMBX_OS_Delay(5000);
EMBX_Alloc(tp,BUFFER_SIZE,&buffer);
res = EMBX_SendMessage(port,buffer,BUFFER_SIZE);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("port_thread failed, res = %s\n",error_strings[res]));
return;
}
}
static void receiveTransformerRegisteredMessage(TransformerRegisteredMessage* message)
{
EMBX_PORT replyPort;
EMBX_ERROR embxError;
MMEReceiverFactory* factory;
message->result = MME_SUCCESS; /* preliminary result */
/* Connect to the reply port. */
embxError = EMBX_ConnectBlock(manager->transportHandle, message->portName, &replyPort);
if (EMBX_SUCCESS != embxError) {
/* ??? This is a bit of a problem. We cannot connect to the port that we should now send
the error message to. */
MME_Info(MME_INFO_MANAGER, ("EMBX_ConnectBlock() to reply port failed, error=%d\n", embxError));
return;
}
/* Need a lock on this list */
/* Find the right receiver factory. */
factory = manager->factoryList;
while (factory &&
factory->transformerType &&
strcmp(factory->transformerType, message->transformerType) != 0) {
factory = factory->next;
}
if (factory == NULL) {
/* No such factory available. */
MME_Info(MME_INFO_MANAGER, ("No receiver found for %s\n", message->transformerType));
message->result = MME_UNKNOWN_TRANSFORMER;
}
/* Send the message back with the updated result field */
embxError = EMBX_SendMessage(replyPort, message, message->messageSize);
if (EMBX_SUCCESS != embxError) {
MME_Info(MME_INFO_MANAGER, ("EMBX_SendMessage() to reply port failed, error=%d\n", embxError));
return;
}
EMBX_ClosePort(replyPort);
}
static MME_ERROR issueTerminateMMEMessages(TransportInfo_t* tpInfo)
{
EMBX_ERROR err;
MME_ERROR res;
int i;
MME_Assert(manager);
MME_Assert(tpInfo);
for (i=0; i<4; i++) {
char adminPortName[] = "MMECompanionAdmin#0";
EMBX_PORT adminPort;
TransformerTerminateMMEMessage *message = NULL;
/* Generate the port name we want to examine */
adminPortName[sizeof(adminPortName) - 2] = '0' + i;
/* Attempt to connect to the admin port */
err = EMBX_Connect(tpInfo->handle, adminPortName, &adminPort);
if (EMBX_PORT_NOT_BIND == err) {
continue;
};
MME_Assert(EMBX_SUCCESS == err); /* no recovery possible */
/* Allocate the terminate message */
res = createTerminateMMEMessage(tpInfo, &message);
MME_Assert(MME_SUCCESS == res); /* no recovery possible */
/* Send the request and disconnect */
err = EMBX_SendMessage(adminPort, message, message->messageSize);
MME_Assert(MME_SUCCESS == res); /* no recovery possible */
/* Close the admin port */
err = EMBX_ClosePort(adminPort);
MME_Assert(MME_SUCCESS == res); /* no recovery possible */
}
return MME_SUCCESS;
}
int main()
{
EMBX_TRANSPORT hTrans;
EMBX_PORT bufferpool, consumer, mypoolconnection;
EMBX_ERROR err;
int i;
embxRuntimeInit();
err = EMBX_OpenTransport("shm", &hTrans);
assert(EMBX_SUCCESS == err);
/* Create the port which will hold the pool of work buffers */
err = EMBX_CreatePort(hTrans, "bufferpool", &bufferpool);
assert(EMBX_SUCCESS == err);
/* Make a connection to the port we just created so we can inject
* empty buffers onto the port's queue as part of the initialization
*/
err = EMBX_Connect(hTrans, "bufferpool", &mypoolconnection);
assert(EMBX_SUCCESS == err);
/* Now wait for the consumer port to come into existence and
* make a connection to it.
*/
err = EMBX_ConnectBlock(hTrans, "consumer", &consumer);
assert(EMBX_SUCCESS == err);
/* Inject empty buffers into the buffer pool */
for(i=0;i<BUFFER_POOL_SIZE;i++)
{
EMBX_VOID *buffer;
err = EMBX_Alloc(hTrans, BUFFER_SIZE, &buffer);
assert(EMBX_SUCCESS == err);
/* Send empty buffer to the buffer pool port */
err = EMBX_SendMessage(mypoolconnection, buffer, 0);
assert(EMBX_SUCCESS == err);
}
/* We don't need our connection to the buffer pool anymore
* so close it down.
*/
EMBX_ClosePort(mypoolconnection);
for(i=0;i<100;i++)
{
EMBX_RECEIVE_EVENT ev;
EMBX_UINT buffersize;
/* Jabber ... */
printf("producer: Issuing message %d of 100\n", i+1);
/* Get an empty buffer from the pool */
err = EMBX_ReceiveBlock(bufferpool, &ev);
assert(EMBX_SUCCESS == err);
/* The event size field does not represent the actual
* size of the buffer in this case, hence if you need
* to find that out use the following. However in this
* case where all the buffers are the same known size
* it wouldn't be necessary expect as self checking debug.
*/
err = EMBX_GetBufferSize(ev.data, &buffersize);
assert(EMBX_SUCCESS == err);
/* Do something to fill the buffer with stuff to be used
* by the consumer...... use your imagination ......
*/
/* Now send the buffer to the consumer with the real amount
* of data in the buffer as the size argument (this can be
* less than the buffer size). For this example we assume
* the whole buffer contains valid data.
*/
err = EMBX_SendMessage(consumer, ev.data, buffersize);
assert(EMBX_SUCCESS == err);
}
/* Shut the communication system down. This has the side effect
* of causing the consumer to also close down, almost certainly
* before outstanding messages have been processed.
*/
EMBX_ClosePort(bufferpool);
EMBX_ClosePort(consumer);
EMBX_CloseTransport(hTrans);
EMBX_Deinit();
return 0;
}
int run_test(void)
{
EMBX_ERROR res;
EMBX_TPINFO tpinfo1;
EMBX_BOOL bFailed;
EMBX_TRANSPORT tp;
EMBX_PORT localPort,remotePort;
EMBX_VOID *buffer1,*buffer2;
EMBX_FACTORY factory;
bFailed = EMBX_FALSE;
tp = EMBX_INVALID_HANDLE_VALUE;
buffer1 = buffer2 = 0;
/* Test 1 */
res = EMBX_SendMessage(EMBX_INVALID_HANDLE_VALUE, buffer1, 0);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test1 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
res = EMBX_RegisterTransport(EMBXLB_loopback_factory,&loopback_config,sizeof(EMBXLB_Config_t),&factory);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Transport Registration failed, res = %s, exiting\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 2 */
res = EMBX_Init();
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test2 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 3 */
res = EMBX_GetFirstTransport(&tpinfo1);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test3 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 4 */
res = EMBX_OpenTransport(tpinfo1.name, &tp);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test4 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 5 */
res = EMBX_CreatePort(tp, "testport", &localPort);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test5 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 6 */
res = EMBX_Connect(tp, "testport", &remotePort);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test6 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 7 */
res = EMBX_Alloc(tp, BUFFER_SIZE, &buffer1);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test7 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 8 */
res = EMBX_SendMessage(tp, buffer1, 0);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test8 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 9 */
res = EMBX_SendMessage(localPort, buffer1, 0);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test9 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 10 */
res = EMBX_SendMessage(remotePort, 0, 0);
if(res != EMBX_INVALID_ARGUMENT)
{
EMBX_Info(EMBX_TRUE, ("Test10 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 11 */
res = EMBX_SendMessage(remotePort, buffer1, BUFFER_SIZE+1);
if(res != EMBX_INVALID_ARGUMENT)
{
EMBX_Info(EMBX_TRUE, ("Test11 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 12 */
res = EMBX_SendMessage(remotePort, buffer1, BUFFER_SIZE);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test12 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 13 - Ensure this allocation happens before buffer1 gets free'd
* when the port is closed, so buffer1 and buffer2 will not point to
* the same memory which is important for later tests.
*/
res = EMBX_Alloc(tp, BUFFER_SIZE, &buffer2);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test13 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 14 */
res = EMBX_ClosePort(localPort);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test14 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 15 - buffer1 has been freed by test14 so should be garbage */
res = EMBX_SendMessage(remotePort, buffer1, 0);
if(res != EMBX_INVALID_ARGUMENT)
{
EMBX_Info(EMBX_TRUE, ("Test15 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 16 */
res = EMBX_SendMessage(remotePort, buffer2, BUFFER_SIZE);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test16 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 17 */
res = EMBX_ClosePort(remotePort);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test17 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 18 */
res = EMBX_CloseTransport(tp);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test18 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 19 */
res = EMBX_Deinit();
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test19 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* These test a different code path to the identical tests done before
* EMBX_Init.
*/
/* Test 20 - Depends on buffer2 not having been freed so we get through
* to checking the state of the driver.
*/
res = EMBX_SendMessage(remotePort, buffer2, 0);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test20 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 21 */
res = EMBX_UnregisterTransport(factory);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test21 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
return bFailed?-1:0;
skip_remaining_tests:
EMBX_Info(EMBX_TRUE, ("Skipping Remaining Tests\n"));
return -1;
}
int run_test(void)
{
EMBX_UINT i;
EMBX_ERROR res;
EMBX_TPINFO tpinfo1;
EMBX_BOOL bFailed;
EMBX_PORT localPort,remotePort;
EMBX_VOID *buffer1;
EMBX_FACTORY factory;
EMBX_RECEIVE_EVENT ev;
bFailed = EMBX_FALSE;
buffer1 = 0;
/* Test 1 */
res = EMBX_ReceiveBlock(EMBX_INVALID_HANDLE_VALUE, &ev);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test1 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
res = EMBX_RegisterTransport(EMBXLB_loopback_factory, &loopback_config, sizeof(EMBXLB_Config_t), &factory);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Transport Registration failed, res = %s, exiting\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 2 */
res = EMBX_Init();
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test2 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 3 */
res = EMBX_GetFirstTransport(&tpinfo1);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test3 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 4 */
res = EMBX_OpenTransport(tpinfo1.name, &tp);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test4 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 5 */
res = EMBX_CreatePort(tp, "testport", &localPort);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test5 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 6 */
res = EMBX_Connect(tp, "testport", &remotePort);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test6 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 7 */
res = EMBX_ReceiveBlock(tp, &ev);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test7 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 8 */
res = EMBX_ReceiveBlock(remotePort, &ev);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test8 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 9 */
res = EMBX_ReceiveBlock(localPort, 0);
if(res != EMBX_INVALID_ARGUMENT)
{
EMBX_Info(EMBX_TRUE, ("Test9 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 10 */
res = EMBX_Alloc(tp, BUFFER_SIZE, &buffer1);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test10 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
for(i=0;i<BUFFER_SIZE;i++)
{
((unsigned char *)buffer1)[i] = (unsigned char)i;
}
/* Test 11 */
res = EMBX_SendMessage(remotePort, buffer1, BUFFER_SIZE);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test11 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 12 */
res = EMBX_ReceiveBlock(localPort, &ev);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test12 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
if(ev.handle != EMBX_INVALID_HANDLE_VALUE ||
ev.offset != 0 ||
ev.type != EMBX_REC_MESSAGE ||
ev.size != BUFFER_SIZE)
{
EMBX_Info(EMBX_TRUE, ("Test13 failed, event structure incorrect\n"));
goto skip_remaining_tests;
}
for(i=0;i<ev.size;i++)
{
if( ((unsigned char *)ev.data)[i] != (unsigned char)i )
{
EMBX_Info(EMBX_TRUE, ("Test13 failed, buffer contents incorrect\n"));
bFailed = EMBX_TRUE;
break;
}
}
/* Test 13 */
res = EMBX_Free(ev.data);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test13 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
if(!EMBX_OS_ThreadCreate(send_thread, (void *)remotePort, EMBX_DEFAULT_THREAD_PRIORITY, "send"))
{
EMBX_Info(EMBX_TRUE, ("Unable to create thread\n"));
goto skip_remaining_tests;
}
/* Test 14 */
res = EMBX_ReceiveBlock(localPort, &ev);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test14 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
if(ev.handle != EMBX_INVALID_HANDLE_VALUE ||
ev.offset != 0 ||
ev.type != EMBX_REC_MESSAGE ||
ev.size != BUFFER_SIZE)
{
EMBX_Info(EMBX_TRUE, ("Test15 failed, event structure incorrect\n"));
goto skip_remaining_tests;
}
/* Test 15 */
res = EMBX_Free(ev.data);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test15 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 16 */
res = EMBX_ClosePort(remotePort);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test16 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 17 */
res = EMBX_ClosePort(localPort);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test17 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 18 */
res = EMBX_CloseTransport(tp);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test18 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* Test 19 */
res = EMBX_Deinit();
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test19 failed, res = %s\n",error_strings[res]));
goto skip_remaining_tests;
}
/* These test a different code path to the identical tests done before
* EMBX_Init
*/
/* Test 20 */
res = EMBX_ReceiveBlock(localPort, &ev);
if(res != EMBX_INVALID_PORT)
{
EMBX_Info(EMBX_TRUE, ("Test20 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
/* Test 21 */
res = EMBX_UnregisterTransport(factory);
if(res != EMBX_SUCCESS)
{
EMBX_Info(EMBX_TRUE, ("Test21 failed, res = %s\n",error_strings[res]));
bFailed = EMBX_TRUE;
}
return bFailed?-1:0;
skip_remaining_tests:
EMBX_Info(EMBX_TRUE, ("Skipping Remaining Tests\n"));
return -1;
}
static MME_ERROR RemoteTransformer_SendCommand(Transformer_t* transformer, MME_Command_t * commandInfo, CommandSlot_t** slot)
{
RemoteTransformer_t *remoteTransformer = (RemoteTransformer_t *) transformer;
EMBX_VOID *buffer;
EMBX_ERROR err;
MME_CommandStatus_t *status;
TransformerTransformMessage *message;
MME_ERROR result;
int i;
MME_CommandCode_t cmdCode = commandInfo->CmdCode;
int newCommandIndex;
if (!remoteTransformer->sendPort.valid) {
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_ERROR_STR "MME port does not exist\n"));
return MME_INVALID_ARGUMENT;
}
status = (MME_CommandStatus_t*) &(commandInfo->CmdStatus);
MME_Assert(cmdCode == MME_TRANSFORM || cmdCode == MME_SEND_BUFFERS ||
cmdCode == MME_SET_GLOBAL_TRANSFORM_PARAMS);
/* Acquire lock on the transformer's command slots */
EMBX_OS_MUTEX_TAKE(&remoteTransformer->commandSlotLock);
if (remoteTransformer->numCommandSlots >= remoteTransformer->maxCommandSlots) {
/* no free slot */
EMBX_OS_MUTEX_RELEASE(&remoteTransformer->commandSlotLock);
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_ERROR_STR "SendCommand: maxCommandSlots overflow\n"));
return MME_NOMEM;
}
/* Find a free command slot so we can memorize parameters */
for (i = 0;
i < remoteTransformer->maxCommandSlots &&
remoteTransformer->commandSlots[remoteTransformer->commandIndex].status
!= MME_COMMAND_COMPLETED_EVT;
i++) {
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_NOTIFY_STR "RemoteTransformer: SendCommand: CommandIndex %d is already used\n", remoteTransformer->commandIndex));
remoteTransformer->commandIndex++;
if (remoteTransformer->commandIndex >= remoteTransformer->maxCommandSlots) {
remoteTransformer->commandIndex = 0;
}
}
if (i >= remoteTransformer->maxCommandSlots) {
EMBX_OS_MUTEX_RELEASE(&remoteTransformer->commandSlotLock);
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_ERROR_STR "SendCommand error: No free command slot found!\n"));
return MME_NOMEM;
}
newCommandIndex = remoteTransformer->commandIndex;
/* Generate a unique command ID per transformer */
status->CmdId = MME_CMDID_PACK(
(remoteTransformer->super.handle)-MME_TRANSFORMER_HANDLE_PREFIX,
newCommandIndex, &(remoteTransformer->commandIDCounter));
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_NOTIFY_STR "RemoteTransformer: SendCommand: code=%d ID=%d slot=%d\n",
cmdCode, status->CmdId, newCommandIndex));
/* In order to avoid sending buffers, but then being unable to allocate the transform message,
we create and fill in the transform message first
*/
result = createTransformMessage(remoteTransformer, commandInfo, &buffer);
if (result != MME_SUCCESS) {
EMBX_OS_MUTEX_RELEASE(&remoteTransformer->commandSlotLock);
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_ERROR_STR "CreateTransformMsg() failed, result=%d\n", result));
return MME_NOMEM;
}
/* Setting the command state to FAILED allows us to identify incomplete SendCommand()s
at our receiver task.
*/
status->State = MME_COMMAND_FAILED;
/* New command slot entry. Initially, assume that the transform message can't be sent */
status->Error = MME_SUCCESS;
remoteTransformer->commandSlots[newCommandIndex].endType = commandInfo->CmdEnd;
/* In the moment that the status is not zero, the receiver task regards it as valid */
remoteTransformer->commandSlots[newCommandIndex].command = commandInfo;
remoteTransformer->commandSlots[newCommandIndex].waitor = NULL;
remoteTransformer->commandSlots[newCommandIndex].status = MME_RUNNING;
remoteTransformer->numCommandSlots++;
EMBX_OS_MUTEX_RELEASE(&remoteTransformer->commandSlotLock);
/* TODO: Should we move the state here or on the companion once the command is
* scheduled - I think the latter
*/
status->State = MME_COMMAND_EXECUTING;
message = (TransformerTransformMessage *) buffer;
/* Send the message */
err = EMBX_SendMessage(remoteTransformer->sendPort.port, message, message->messageSize);
if (err != EMBX_SUCCESS) {
/* The message could not be sent. Mark the command slot as incomplete */
MME_Info(MME_INFO_TRANSFORMER, (DEBUG_ERROR_STR "EMBX_SendMessage() failed, error=%d\n", err));
/* Mark incomplete command */
status->State = MME_COMMAND_FAILED;
freeBuffer(remoteTransformer, buffer);
return MME_NOMEM;
} else {
/* Lost ownership */
buffer = NULL;
}
*slot = &(remoteTransformer->commandSlots[newCommandIndex]);
return MME_SUCCESS;
}
static MME_ERROR RemoteTransformer_GetTransformerCapability(
Transformer_t *transformer,
const char *name, MME_TransformerCapability_t * capability)
{
RemoteTransformer_t *remoteTransformer = (RemoteTransformer_t *) transformer;
MME_ERROR res = MME_NOMEM;
EMBX_TRANSPORT hdl;
EMBX_PORT replyPort;
int n, messageSize;
TransformerCapabilityMessage *message;
EMBX_RECEIVE_EVENT event;
MME_Assert(remoteTransformer);
MME_Assert(name);
MME_Assert(capability);
hdl = remoteTransformer->super.info->handle;
MME_Assert(hdl);
/* calculate the size of the capability message */
messageSize = sizeof(*message) + capability->TransformerInfoSize;
/* allocate somewhere to store the message we are about to send */
message = allocBuffer(remoteTransformer, messageSize);
if (0 == message) {
return MME_NOMEM;
}
/* create a port to be used to reply to this message */
n = sprintf(message->portName, "MMECapability_0x%x", (unsigned) message);
MME_Assert(n < EMBX_MAX_PORT_NAME);
if (EMBX_SUCCESS != EMBX_CreatePort(hdl, message->portName, &replyPort)) {
goto error_recovery_alloc;
}
/* populate the rest of the message */
message->id = TMESSID_CAPABILITY;
message->messageSize = messageSize;
strncpy(message->transformerType, name, MME_MAX_TRANSFORMER_NAME);
message->transformerType[MME_MAX_TRANSFORMER_NAME - 1] = '\0';
message->capability = *capability;
/* send the message and wait for a reply */
if (EMBX_SUCCESS != EMBX_SendMessage(remoteTransformer->adminPort,
message, sizeof(*message)) ||
EMBX_SUCCESS != EMBX_ReceiveBlock(replyPort, &event)) {
goto error_recovery_createport;
}
message = event.data;
MME_Assert(event.type == EMBX_REC_MESSAGE);
MME_Assert(event.size >= messageSize);
MME_Assert(message->id == TMESSID_CAPABILITY);
MME_Assert(message->messageSize == messageSize);
/* fill in the rest of the message */
res = message->result;
message->capability.TransformerInfo_p = capability->TransformerInfo_p;
*capability = message->capability;
memcpy(capability->TransformerInfo_p, message+1, capability->TransformerInfoSize);
/* fall into the clean up code */
error_recovery_createport:
(void) EMBX_ClosePort(replyPort);
error_recovery_alloc:
(void) freeBuffer(remoteTransformer, message);
return res;
}
static MME_ERROR RemoteTransformer_TermOrKill(Transformer_t* transformer, int doKill)
{
RemoteTransformer_t *remoteTransformer = (RemoteTransformer_t *) transformer;
EMBX_ERROR err;
EMBX_VOID *buffer;
TransformerTerminateMessage *message;
MME_ERROR result, res;
result = MME_NOMEM;
if (!remoteTransformer->sendPort.valid) {
DP("MME port does not exist\n");
return MME_INVALID_ARGUMENT;
}
/* No command must be pending on the companion side */
if (remoteTransformer->numCommandSlots > 0) {
DP("RemoteTransformer::Terminate() failed, commands pending\n");
return MME_COMMAND_STILL_EXECUTING;
}
res = createTerminateMessage(remoteTransformer, 0, &buffer);
if (res != MME_SUCCESS) {
DP("CreateTerminateMsg() failed, error=%d\n", res);
return res;
}
/* Send the message */
message = (TransformerTerminateMessage *) buffer;
DP("Sending %s message @$%08x...\n", message, (doKill ? "kill" : "terminate"));
if (doKill) {
EMBX_PORT replyPort;
/* connect to our own reply port */
err = EMBX_Connect(remoteTransformer->super.info->handle, remoteTransformer->replyPort.name, &replyPort);
if (EMBX_SUCCESS != err) {
DP("RemoteTransformer_Term(): failed to connect to self\n");
cleanupTerminateMessage(remoteTransformer, message);
return MME_EMBX_ERROR;
}
err = EMBX_SendMessage(replyPort, message, message->messageSize);
if (EMBX_SUCCESS != err) {
DP("RemoteTransformer_Term(): failed to send message to self\n");
cleanupTerminateMessage(remoteTransformer, message);
return MME_EMBX_ERROR;
}
EMBX_ClosePort(replyPort);
} else {
err = EMBX_SendMessage(remoteTransformer->adminPort, message, message->messageSize);
if (EMBX_SUCCESS != err) {
DP("RemoteTransformer_Term(): failed to send message to coprocessor\n");
cleanupTerminateMessage(remoteTransformer, message);
return MME_EMBX_ERROR;
}
}
/* lost ownership */
message = NULL;
/* Wait for ReceiverThread to terminate itself after receiving the reply message */
DP("Waiting for ReceiverThread to terminate itself...\n");
DP("terminateWasReplied 0x%08x\n", remoteTransformer->terminateWasReplied);
EMBX_OS_EVENT_WAIT(&remoteTransformer->terminateWasReplied);
if (remoteTransformer->terminationResult != MME_SUCCESS) {
DP("Failed to terminate receiver thread properly\n");
return MME_INTERNAL_ERROR;
}
err = EMBX_OS_ThreadDelete(remoteTransformer->receiverThread);
if (err != EMBX_SUCCESS) {
DP("EMBX_OS_ThreadDelete() failed, error=d\n", err);
}
remoteTransformer->receiverThread = NULL;
/* Close the MME port */
DP("Close mmePort...\n");
err = EMBX_ClosePort(remoteTransformer->sendPort.port);
if (err != EMBX_SUCCESS) {
DP("EMBX_ClosePort(mmePort) failed, error=d\n", err);
}
/* Close the reply port */
DP("Invalidate replyPort...\n");
err = EMBX_InvalidatePort(remoteTransformer->replyPort.port);
if (err != EMBX_SUCCESS) {
DP("EMBX_InvalidatePort(replyPort) failed, error=%d\n", err);
}
DP("Close replyPort...\n");
err = EMBX_ClosePort(remoteTransformer->replyPort.port);
if (err != EMBX_SUCCESS) {
DP("EMBX_ClosePort(replyPort) failed, error=%d\n", err);
}
remoteTransformer->replyPort.valid = EMBX_FALSE;
return MME_SUCCESS;
}
static MME_ERROR RemoteTransformer_Init(Transformer_t* transformer,
const char* name,
MME_TransformerInitParams_t * params,
MME_TransformerHandle_t handle,
EMBX_BOOL createThread)
{
RemoteTransformer_t *remoteTransformer = (RemoteTransformer_t *) transformer;
EMBX_ERROR err;
EMBX_RECEIVE_EVENT event;
TransformerInitMessage *message = NULL;
char receiverThreadName[EMBX_MAX_PORT_NAME+1];
int messageSize,n;
MME_ERROR result, res;
result = MME_NOMEM;
remoteTransformer->super.handle = handle;
/* TODO: We should take a copy of our (transformer specific) parameters. These might
* be deallocated once the transformer is initialized.
*/
remoteTransformer->super.initParams = *params;
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: initialising '%s'\n", name));
/* Create the reply port. We use the unique handle to create a unique reply port name.*/
n = sprintf(remoteTransformer->replyPort.name, "MMEReply_0x%x", handle);
MME_Assert(n < EMBX_MAX_PORT_NAME);
err = EMBX_CreatePort(remoteTransformer->super.info->handle,
remoteTransformer->replyPort.name, &remoteTransformer->replyPort.port);
if (EMBX_SUCCESS != err) {
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Cannot create port '%s'\n",
remoteTransformer->replyPort.name));
goto embx_error_recovery;
}
remoteTransformer->replyPort.valid = 1;
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Created port '%s', port 0x%08x\n",
remoteTransformer->replyPort.name,
(unsigned) remoteTransformer->replyPort.port));
/* Create the init message */
res = createInitMessage(remoteTransformer, name, params, (EMBX_VOID **) &message);
if (MME_SUCCESS != res) {
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Cannot create initialisation message\n"));
goto error_recovery;
}
/* Remember size for check of reply message */
messageSize = message->messageSize;
/* Send the message */
err = EMBX_SendMessage(remoteTransformer->adminPort, message, messageSize);
if (err != EMBX_SUCCESS) {
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Cannot set initialisation message\n"));
goto embx_error_recovery;
}
/* Record ownership tranfer (see error_recovery) */
message = NULL;
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Waiting for initialisation reply\n"));
/* Wait for an answer from the companion */
err = EMBX_ReceiveBlock(remoteTransformer->replyPort.port, &event);
if (EMBX_SUCCESS != err) {
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Error while waiting for initialisation reply\n"));
goto embx_error_recovery;
}
/* Check if the message is as expected */
message = (TransformerInitMessage *) event.data;
MME_Assert(EMBX_REC_MESSAGE == event.type);
MME_Assert(event.size >= messageSize);
MME_Assert(message && message->id == TMESSID_INIT);
if (MME_SUCCESS != message->result) {
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Error initialising remote transformer\n"));
res = message->result;
goto error_recovery;
}
/* The MME successfully created its transformer */
strncpy(remoteTransformer->sendPort.name, message->portName, EMBX_MAX_PORT_NAME);
remoteTransformer->sendPort.name[EMBX_MAX_PORT_NAME] = '\0';
remoteTransformer->mmeHandle = message->mmeHandle;
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Connecting to transformer port '%s'\n",
remoteTransformer->sendPort.name));
/* Connect to the MME port */
err = EMBX_ConnectBlock(remoteTransformer->super.info->handle,
remoteTransformer->sendPort.name,
&remoteTransformer->sendPort.port);
if (EMBX_SUCCESS != err) {
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Cannot connect to port '%s'\n",
remoteTransformer->sendPort.name));
goto embx_error_recovery;
}
remoteTransformer->sendPort.valid = 1;
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Connected to port '%s', port 0x%08x\n",
remoteTransformer->sendPort.name,
(unsigned) remoteTransformer->sendPort.port));
if (createThread) {
/* Create our receiver task for the reply port */
sprintf(receiverThreadName, "HostRec%x", handle);
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Creating receiver thread '%s'\n",
receiverThreadName));
/* TODO: think about whether we want all the receiver threads to have the same priority */
remoteTransformer->receiverThread = EMBX_OS_ThreadCreate(receiverThread,
(void *) remoteTransformer, RECEIVER_TASK_PRIORITY, receiverThreadName);
if (EMBX_INVALID_THREAD == remoteTransformer->receiverThread) {
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Cannot create receiver thread '%s'\n",
receiverThreadName));
res = MME_NOMEM;
goto error_recovery;
}
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: Created receiver thread '%s', thread 0x%08x\n",
receiverThreadName, (unsigned) remoteTransformer->receiverThread));
}
/* Cleanup and exit */
cleanupInitMessage(remoteTransformer, message);
MME_Info(MME_INFO_TRANSFORMER, ("RemoteTransformer_Init: SUCCESS\n"));
return MME_SUCCESS;
embx_error_recovery:
/* As normal error recovery but map the EMBX error code to a MME error code first */
res = (EMBX_NOMEM == err ? MME_NOMEM : MME_EMBX_ERROR);
error_recovery:
if (remoteTransformer->mmeHandle) {
MME_Assert(message);
message->id = TMESSID_TERMINATE;
err = EMBX_SendMessage(remoteTransformer->adminPort, message, message->messageSize);
if (EMBX_SUCCESS == err) {
/* TODO: is blocking really a good idea during error recovery? */
err = EMBX_ReceiveBlock(remoteTransformer->replyPort.port, &event);
message = (EMBX_SUCCESS == err ? event.data : NULL);
}
remoteTransformer->mmeHandle = 0;
}
if (remoteTransformer->sendPort.valid) {
EMBX_ClosePort(remoteTransformer->sendPort.port);
remoteTransformer->sendPort.valid = 0;
}
if (remoteTransformer->replyPort.valid) {
EMBX_ClosePort(remoteTransformer->replyPort.port);
remoteTransformer->replyPort.valid = 0;
}
if (message) {
cleanupInitMessage(remoteTransformer, message);
}
return res;
}
static MME_ERROR findTransformerWithinTransport(TransportInfo_t *tpInfo, const char *name,
EMBX_PORT *adminPort_p)
{
MME_ERROR res;
EMBX_ERROR err;
TransformerRegisteredMessage *msg = 0;
EMBX_PORT adminPort = 0;
MME_UINT i;
MME_Assert(manager);
MME_Assert(name);
MME_Assert(tpInfo);
res = createRegisteredMessage(tpInfo, name, &msg);
if (MME_SUCCESS != res) {
return res;
}
for (i=0; i<4; i++) {
char adminPortName[] = "MMECompanionAdmin#0";
EMBX_RECEIVE_EVENT event;
/* generate the port name we want to examine */
adminPortName[sizeof(adminPortName) - 2] = '0' + i;
/* attempt to connect to the admin port */
err = EMBX_Connect(tpInfo->handle, adminPortName, &adminPort);
if (EMBX_PORT_NOT_BIND == err) {
continue;
} else if (EMBX_SUCCESS != err) {
goto error_recovery;
}
/* send the request and disconnect from the port */
err = EMBX_SendMessage(adminPort, msg, sizeof(*msg));
if (EMBX_SUCCESS != err) {
goto error_recovery;
}
msg = 0;
/* wait for the reply */
/* TIMEOUT SUPPORT: Allow the receive to timeout */
err = EMBX_ReceiveBlockTimeout(tpInfo->replyPort, &event, MME_TRANSFORMER_TIMEOUT);
if (EMBX_SUCCESS != err) {
goto error_recovery;
}
MME_Assert(event.type == EMBX_REC_MESSAGE);
MME_Assert(event.size == sizeof(*msg));
/* interpret said reply */
msg = event.data;
MME_Assert(msg->messageSize == sizeof(*msg));
if (MME_SUCCESS == msg->result) {
break;
}
err = EMBX_ClosePort(adminPort);
if (EMBX_SUCCESS != err) {
goto error_recovery;
}
adminPort = 0;
}
cleanupRegisteredMessage(tpInfo, msg);
if (i < 4) {
*adminPort_p = adminPort;
return MME_SUCCESS;
} else {
return MME_UNKNOWN_TRANSFORMER;
}
error_recovery:
/* TIMEOUT SUPPORT: Return MME_TRANSFORMER_NOT_RESPONDING if timeout occurs */
res = (EMBX_NOMEM == err ? MME_NOMEM : (EMBX_SYSTEM_TIMEOUT == err ? MME_TRANSFORMER_NOT_RESPONDING : MME_EMBX_ERROR));
if (adminPort) {
err = EMBX_ClosePort(adminPort);
MME_Assert(EMBX_SUCCESS == err);
}
if (msg) {
cleanupRegisteredMessage(tpInfo, msg);
}
return res;
}
static void receiveInitMessage(TransformerInitMessage * message)
{
EMBX_ERROR err;
EMBX_PORT replyPort;
MMEReceiverFactory *factory;
MMEReceiver *receiver;
MME_ERROR res;
message->result = MME_NOMEM; /* preliminary result */
/* Connect to the reply port. */
err = EMBX_ConnectBlock(manager->transportHandle, message->portName, &replyPort);
if (err != EMBX_SUCCESS) {
/* ??? This is a bit of a problem. We cannot connect to the port that we should now send
the error message to. */
MME_Info(MME_INFO_MANAGER, ("EMBX_ConnectBlock() to reply port failed, error=%d\n", err));
return;
}
/* Need a lock on this list */
/* Find the right receiver factory. */
factory = manager->factoryList;
while (factory != NULL && strcmp(factory->transformerType, message->transformerType) != 0) {
factory = factory->next;
}
if (factory == NULL) {
/* No such factory available. */
MME_Info(MME_INFO_MANAGER, ("No receiver factory found\n"));
res = MME_UNKNOWN_TRANSFORMER;
} else {
/* Create a receiver object. This will result in the constructors being called as well. */
res = MME_Receiver_Create(factory, &receiver);
if (MME_SUCCESS == res) {
int id = MME_PRIORITY_TO_ID(message->priority);
res = createExecutionLoop(manager, id);
assert(MME_SUCCESS == res); /* TODO: proper error handling */
/* Initialize the receiver. */
/* This call will also fail if an existing transformer does not support multi-instantiation. */
res = MME_Receiver_Init(receiver, manager, manager->transportHandle, message, replyPort,
&(manager->commandEvents[id]));
if (res == MME_SUCCESS) {
/* Add the new receiver to the list. */
EMBX_OS_MUTEX_TAKE(&(manager->receiverListMutexes[id]));
receiver->next = manager->receiverLists[id];
manager->receiverLists[id] = receiver;
EMBX_OS_MUTEX_RELEASE(&(manager->receiverListMutexes[id]));
/* We are successfully done. */
message->result = res;
EMBX_SendMessage(replyPort, message, message->messageSize);
return;
}
/* Could not initialize receiver. Clean up and return error. */
MME_Receiver_Destroy(receiver);
}
}
/* Send the message back to the host with an error. */
message->result = res;
EMBX_SendMessage(replyPort, message, message->messageSize);
EMBX_ClosePort(replyPort);
}
int main()
{
EMBX_TRANSPORT hTrans;
EMBX_PORT consumer, bufferpool;
EMBX_ERROR err;
embxRuntimeInit();
err = EMBX_OpenTransport("shm", &hTrans);
assert(err == EMBX_SUCCESS);
/* Create the port which the consumer will receive work
* messages on.
*/
err = EMBX_CreatePort(hTrans, "consumer", &consumer);
assert(err == EMBX_SUCCESS);
/* Connect to the buffer pool on the producer, we will send
* back finished message buffers to this so the producer can
* re-use them.
*/
err = EMBX_ConnectBlock(hTrans, "bufferpool", &bufferpool);
assert(err == EMBX_SUCCESS);
while(1)
{
EMBX_RECEIVE_EVENT ev;
/* Wait for some work to do */
err = EMBX_ReceiveBlock(consumer, &ev);
if(err != EMBX_SUCCESS)
{
/* Assume, for the purposes of this example
* that this means the producer wants to close
* down. Hence clean up the transport and close
* down EMBX.
*/
EMBX_ClosePort(bufferpool);
EMBX_ClosePort(consumer);
EMBX_CloseTransport(hTrans);
EMBX_Deinit();
exit(1);
}
/* Do some work with the received message data here */
printf("consumer: Processing message\n");
/* Now send the message buffer back, note the zero size
* for the message length, this will prevent any data copying
* on a non shared memory transport.
*/
err = EMBX_SendMessage(bufferpool, ev.data, 0);
if(err != EMBX_SUCCESS)
{
EMBX_ClosePort(bufferpool);
EMBX_ClosePort(consumer);
EMBX_CloseTransport(hTrans);
EMBX_Deinit();
exit(1);
}
}
return 0;
}
