nsresult
GMPVideoDecoderParent::Reset()
{
LOGD(("GMPVideoDecoderParent[%p]::Reset()", this));
if (!mIsOpen) {
NS_WARNING("Trying to use an dead GMP video decoder");
return NS_ERROR_FAILURE;
}
MOZ_ASSERT(mPlugin->GMPThread() == NS_GetCurrentThread());
if (!SendReset()) {
return NS_ERROR_FAILURE;
}
mIsAwaitingResetComplete = true;
RefPtr<GMPVideoDecoderParent> self(this);
nsCOMPtr<nsIRunnable> task = NS_NewRunnableFunction([self]() -> void
{
LOGD(("GMPVideoDecoderParent[%p]::ResetCompleteTimeout() timed out waiting for ResetComplete", self.get()));
self->mResetCompleteTimeout = nullptr;
LogToBrowserConsole(NS_LITERAL_STRING("GMPVideoDecoderParent timed out waiting for ResetComplete()"));
});
CancelResetCompleteTimeout();
mResetCompleteTimeout = SimpleTimer::Create(task, 5000, mPlugin->GMPThread());
// Async IPC, we don't have access to a return value.
return NS_OK;
}
nsresult
GMPAudioDecoderParent::Reset()
{
if (!mIsOpen) {
NS_WARNING("Trying to use a dead GMP Audio decoder!");
return NS_ERROR_FAILURE;
}
MOZ_ASSERT(mPlugin->GMPThread() == NS_GetCurrentThread());
if (!SendReset()) {
return NS_ERROR_FAILURE;
}
// Async IPC, we don't have access to a return value.
return NS_OK;
}
nsresult
GMPVideoDecoderParent::Reset()
{
if (!mCanSendMessages) {
NS_WARNING("Trying to use an invalid GMP video decoder!");
return NS_ERROR_FAILURE;
}
MOZ_ASSERT(mPlugin->GMPThread() == NS_GetCurrentThread());
if (!SendReset()) {
return NS_ERROR_FAILURE;
}
// Async IPC, we don't have access to a return value.
return NS_OK;
}
LRESULT CBTTestDlg::OnInitialise(WPARAM wParam, LPARAM lParam)
{
// Start listening for HCI events from the HW
if (StartEventListener()!=ERROR_SUCCESS)
{
MessageBox(_T("Failed to start HCI Event Listener!"));
exit(0);
}
// Send a reset command and wait for it to complete
SendReset();
// Wait a bit to make sure the device is ready...
Sleep(1000);
FBT_HCI_READ_LOCAL_VERSION_INFORMATION_COMPLETE CommandComplete;
if (FBT_HCI_SUCCESS(SendReadLocalVersionInformation(CommandComplete)))
{
fbtLog(fbtLog_Notice, "HCI Version=%d, HCI Revsion=%d, LMP Version=%d, LMP SubVersion=%d, Manufacturer=%s",
CommandComplete.HCIVersion,
CommandComplete.HCIRevision,
CommandComplete.LMPVersion,
CommandComplete.LMPSubVersion,
GetManufacturerName(CommandComplete.Manufacturer));
m_stManufacturer.SetWindowText(GetManufacturerName(CommandComplete.Manufacturer));
CString szTemp;
szTemp.Format("%d, %d", CommandComplete.HCIVersion, CommandComplete.HCIRevision);
m_stHCIVersion.SetWindowText(szTemp);
szTemp.Format("%d, %d", CommandComplete.LMPVersion, CommandComplete.LMPSubVersion);
m_stLMPVersion.SetWindowText(szTemp);
}
// Make the device discoverable
SendWriteScanEnable(3);
// Set default connect timeout
SendWritePageTimeout(0x2000);
// Set the the class of device
BYTE ClassOfDeviceBytes[FBT_HCI_DEVICE_CLASS_SIZE]={0};
// PC
ClassOfDeviceBytes[0]=0x10;
ClassOfDeviceBytes[1]=0x01;
ClassOfDeviceBytes[2]=0x02;
fbtLog(fbtLog_Notice, _T("CBTTestDlg::OnInitDialog: Calling SendWriteClassOfDevice"));
SendWriteClassOfDevice(ClassOfDeviceBytes);
fbtLog(fbtLog_Notice, _T("CBTTestDlg::OnInitDialog: Calling SendSetEventFilter"));
// Enable connection auto-accept
BYTE Condition[FBT_HCI_MAX_CONDITION_SIZE]={0};
Condition[0]=2;
SendSetEventFilter(
FBT_HCI_FILTER_CONNECTION_SETUP,
FBT_HCI_FILTER_ALL,
Condition,
1);
// Set the Device Name
TCHAR szDeviceName[80]={0};
ZeroMemory(szDeviceName, 80);
DWORD dwLength=80;
if (GetComputerName(szDeviceName, &dwLength))
{
BYTE szLocalName[FBT_HCI_NAME_SIZE]={0};
strcpy((char*)szLocalName, szDeviceName);
SendChangeLocalName(szLocalName);
}
// Read the local BD_ADDR
BYTE BD_ADDR[FBT_HCI_BDADDR_SIZE];
if (ReadBDADDR(BD_ADDR)==ERROR_SUCCESS)
{
CString szDevice;
szDevice.Format(_T("%02X:%02X:%02X:%02X:%02X:%02X"),
BD_ADDR[5],
BD_ADDR[4],
BD_ADDR[3],
BD_ADDR[2],
BD_ADDR[1],
BD_ADDR[0]);
m_stAddress.SetWindowText(szDevice);
}
else
fbtLog(fbtLog_Notice, _T("CBTTestDlg::OnInitDialog: Failed to read BDADDR"));
// Start the reader thread
HANDLE hThread = CreateThread( NULL, 0, Reader, (LPVOID)this, 0, NULL );
CloseHandle( hThread );
return TRUE;
}
void Client::HandleUdpReceive(Message &aMessage, const Ip6::MessageInfo &aMessageInfo)
{
Header responseHeader;
Header requestHeader;
RequestMetadata requestMetadata;
Message *message = NULL;
ThreadError error;
SuccessOrExit(error = responseHeader.FromMessage(aMessage));
aMessage.MoveOffset(responseHeader.GetLength());
message = FindRelatedRequest(responseHeader, aMessageInfo, requestHeader, requestMetadata);
if (message == NULL)
{
ExitNow();
}
switch (responseHeader.GetType())
{
case kCoapTypeReset:
if (responseHeader.IsEmpty())
{
FinalizeCoapTransaction(*message, requestMetadata, NULL, NULL, kThreadError_Abort);
}
// Silently ignore non-empty reset messages (RFC 7252, p. 4.2).
break;
case kCoapTypeAcknowledgment:
if (responseHeader.IsEmpty())
{
// Empty acknowledgment.
if (requestMetadata.mConfirmable)
{
requestMetadata.mAcknowledged = true;
requestMetadata.UpdateIn(*message);
}
// Remove the message if response is not expected, otherwise await response.
if (requestMetadata.mResponseHandler == NULL)
{
DequeueMessage(*message);
}
}
else if (responseHeader.IsResponse() && responseHeader.IsTokenEqual(requestHeader))
{
// Piggybacked response.
FinalizeCoapTransaction(*message, requestMetadata, &responseHeader, &aMessage, kThreadError_None);
}
// Silently ignore acknowledgments carrying requests (RFC 7252, p. 4.2)
// or with no token match (RFC 7252, p. 5.3.2)
break;
case kCoapTypeConfirmable:
case kCoapTypeNonConfirmable:
if (responseHeader.IsConfirmable())
{
// Send empty ACK if it is a CON message.
SendEmptyAck(aMessageInfo.GetPeerAddr(), aMessageInfo.mPeerPort, responseHeader.GetMessageId());
}
FinalizeCoapTransaction(*message, requestMetadata, &responseHeader, &aMessage, kThreadError_None);
break;
}
exit:
if (error == kThreadError_None && message == NULL)
{
if (responseHeader.IsConfirmable() || responseHeader.IsNonConfirmable())
{
// Successfully parsed a header but no matching request was found - reject the message by sending reset.
SendReset(aMessageInfo.GetPeerAddr(), aMessageInfo.mPeerPort, responseHeader.GetMessageId());
}
}
}
bool CSMTPClientInstance::SendRelayMessageFromFile( const char *pszFileName )
{
// Check mode
if ( m_state != STATE_DOMAIL )
{
if ( m_state == STATE_DOHELO )
{
SendHelo();
}
else
{
// It is in MAIL somewhere... send reset
SendReset();
}
}
// Now check state
if ( m_state != STATE_DOMAIL )
{
m_state = STATE_ERROR;
return false;
}
// Open file for relay...
FILE *pFile = fopen( pszFileName, "r" );
if ( !pFile )
{
m_state = STATE_ERROR;
return false;
}
CIOFileConnection oFileConnection;
oFileConnection.SetFile( pFile );
for (;;)
{
// Now read in the file and send it
char szLineBuffer[1024];
char szResponseMessage[1024];
uint32_t readLen = 0;
uint32_t responseCode = 0;
// Read in a line and send it
readLen = oFileConnection.ReadLine( (uint8_t*)szLineBuffer, 1024 );
if ( readLen == 0 )
break;
m_pIOConnection->WriteLine( (uint8_t*)szLineBuffer, readLen );
// Now read response
m_pIOConnection->ReadLine( (uint8_t*)szLineBuffer, 1024 );
// Parse response
sscanf( szLineBuffer, "%d %s\r\n", &responseCode, szResponseMessage );
if ( responseCode == 354 )
break;
if ( responseCode != 250 )
{
m_state = STATE_ERROR;
SendReset();
return false;
}
}
// DATA MODE
for (;;)
{
// Now read in the file and send it
char szLineBuffer[1024];
uint32_t readLen = 0;
// Read in a line and send it
readLen = oFileConnection.ReadLine( (uint8_t*)szLineBuffer, 1024 );
if ( readLen == 0 )
break;
m_pIOConnection->WriteLine( (uint8_t*)szLineBuffer, readLen );
}
// Close the file
fclose( pFile );
// Now read the response
{
char szLineBuffer[1024];
char szResponseMessage[1024];
uint32_t readLen = 0;
uint32_t responseCode = 0;
// Now read response
m_pIOConnection->ReadLine( (uint8_t*)szLineBuffer, 1024 );
// Parse response
sscanf( szLineBuffer, "%d %s\r\n", &responseCode, szResponseMessage );
if ( responseCode != 250 )
{
m_state = STATE_ERROR;
SendReset();
return false;
}
}
return true;
}
