windows-nt/Source/XPSP1/NT/net/tapi/skywalker/h323tsp/callback.c
2020-09-26 16:20:57 +08:00

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/*++
Copyright (c) 1997 Microsoft Corporation
Module Name:
callback.c
Abstract:
Callback routines for Intel Call Control Module.
Environment:
User Mode - Win32
--*/
///////////////////////////////////////////////////////////////////////////////
// //
// Include files //
// //
///////////////////////////////////////////////////////////////////////////////
#include "globals.h"
#include <limits.h>
#include "registry.h"
#include "termcaps.h"
#include "provider.h"
#include "callback.h"
#include "line.h"
#include "apierror.h"
///////////////////////////////////////////////////////////////////////////////
// //
// Global variables //
// //
///////////////////////////////////////////////////////////////////////////////
HANDLE g_hCallbackThread = NULL;
DWORD g_dwCallbackThreadID = UNINITIALIZED;
HANDLE g_WaitableObjects[NUM_WAITABLE_OBJECTS];
///////////////////////////////////////////////////////////////////////////////
// //
// Private procedures //
// //
///////////////////////////////////////////////////////////////////////////////
VOID
H323ComputeVideoChannelBitRates(
IN const DWORD dwReferenceMaxBitRate,
IN const DWORD dwAudioBitRate,
OUT DWORD * pdwFinalBitRate,
OUT DWORD * pdwStartUpBitRate
)
/*++
Routine Description:
caculate the bit rate for opening the local channel and the initial bit
rate for the MSP.
Arguments:
dwReferenceMaxBitRate - The max bit rate we got from capability exchange.
(in 100 bps unit)
dwAudioBitRate - The bit rate of the audio stream.
(in 100 bps unit)
pdwFinalBitRate - the bit rate we are going to use to open the channel.
(in 100 bps unit)
pdwStartUpBitRate - the bit rate the MSP should use to start the stream. It
will adapt to the max bit rate if everything is fine.
(in 1 bps unit)
Return Values:
Returns true if successful.
--*/
{
DWORD dwMaxBitRate = dwReferenceMaxBitRate;
if (dwMaxBitRate < H323_UNADJ_VIDEORATE_THRESHOLD) {
// if the max bit rate is too small, just use it.
*pdwStartUpBitRate = dwMaxBitRate * 100;
} else if (dwMaxBitRate < H323_TRUE_VIDEORATE_THRESHOLD) {
// if the max bit rate is still smaller than our threshold,
// the other side must mean .
*pdwStartUpBitRate = dwMaxBitRate * 80;
if (*pdwStartUpBitRate < H323_UNADJ_VIDEORATE_THRESHOLD * 100) {
*pdwStartUpBitRate = H323_UNADJ_VIDEORATE_THRESHOLD * 100;
}
} else if (dwMaxBitRate < MAXIMUM_BITRATE_28800) {
// We assume the MaxBitRate is the total bandwidth of
// the pipe. We need to substract the bandwidth needed
// by audio from this number.
dwMaxBitRate -= dwAudioBitRate;
// We don't want to use 100% of the bandwidth for RTP packets
// So the video bandwidth is further adjusted.
dwMaxBitRate = dwMaxBitRate * (100 - H323_BANDWIDTH_CUSHION_PERCENT) / 100;
*pdwStartUpBitRate = dwMaxBitRate * 100;
} else if (dwMaxBitRate < MAXIMUM_BITRATE_63000) {
// We assume the MaxBitRate is the total bandwidth of
// the pipe. We need to substract the bandwidth needed
// by audio from this number.
dwMaxBitRate -= dwAudioBitRate;
// We don't want to use 100% of the bandwidth for RTP packets
// So the video bandwidth is further adjusted.
dwMaxBitRate = dwMaxBitRate * (100 - H323_BANDWIDTH_CUSHION_PERCENT) / 100;
*pdwStartUpBitRate = dwMaxBitRate * 80;
if (*pdwStartUpBitRate < H323_UNADJ_VIDEORATE_THRESHOLD * 100) {
*pdwStartUpBitRate = H323_UNADJ_VIDEORATE_THRESHOLD * 100;
}
} else {
*pdwStartUpBitRate = dwMaxBitRate * 80;
}
*pdwFinalBitRate = dwMaxBitRate;
}
BOOL
H323SendNewCallIndication(
PH323_CALL pCall
)
/*++
Routine Description:
Sends NEW_CALL_INDICATION from TSP to MSP.
Arguments:
pCall - Specifies a pointer to the associated call object.
Return Values:
Returns true if successful.
--*/
{
H323TSP_MESSAGE Message;
// set the appropriate message type
Message.Type = H323TSP_NEW_CALL_INDICATION;
// send msp message
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_SENDMSPDATA,
MSP_HANDLE_UNKNOWN,
(DWORD_PTR)&Message,
sizeof(Message)
);
// success
return TRUE;
}
BOOL
H323SendVideoFastUpdatePictureCommand(
PH323_CALL pCall,
PH323_CHANNEL pChannel
)
/*++
Routine Description:
Sends VIDEO_FAST_UPDATE_PICTURE_COMMAND from TSP to MSP.
Arguments:
pCall - Specifies a pointer to the call object.
pChannel - Specifies a pointer to the channel object to open.
Return Values:
Returns TRUE if successful.
--*/
{
H323TSP_MESSAGE Message;
H323DBG((
DEBUG_LEVEL_TRACE,
"TSP->MSP I-Frame request. hmChannel=0x%08lx.\n",
pChannel->hmChannel
));
// set the appropriate message type
Message.Type = H323TSP_VIDEO_FAST_UPDATE_PICTURE_COMMAND;
// initialize tsp channel handle
Message.VideoFastUpdatePictureCommand.hChannel =
pChannel->hmChannel;
// send msp message
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_SENDMSPDATA,
MSP_HANDLE_UNKNOWN,
(DWORD_PTR)&Message,
sizeof(Message)
);
// success
return TRUE;
}
BOOL
H323SendFlowControlCommand(
PH323_CALL pCall,
PH323_CHANNEL pChannel,
DWORD dwBitRate
)
/*++
Routine Description:
Sends FLOW_CONTROL_COMMAND from TSP to MSP.
Arguments:
pCall - Specifies a pointer to the call object.
pChannel - Specifies a pointer to the channel object to open.
dwBitRate - Specifies new media stream bit rate (in bps) for MSP
Return Values:
Returns true if successful.
--*/
{
H323TSP_MESSAGE Message;
H323DBG((
DEBUG_LEVEL_TRACE,
"TSP->MSP Flow Control request. hmChannel=0x%08lx. Req. rate=%08d.\n",
pChannel->hmChannel,
dwBitRate
));
// set the appropriate message type
Message.Type = H323TSP_FLOW_CONTROL_COMMAND;
// initialize tsp channel handle
Message.FlowControlCommand.hChannel = pChannel->hmChannel;
// transfer stream settings
Message.FlowControlCommand.dwBitRate = dwBitRate;
// send msp message
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_SENDMSPDATA,
MSP_HANDLE_UNKNOWN,
(DWORD_PTR)&Message,
sizeof(Message)
);
// success
return TRUE;
}
BOOL
H323UpdateMediaModes(
PH323_CALL pCall
)
/*++
Routine Description:
Updates media modes based on new channel table.
Arguments:
pCall - Pointer to call object to update.
Return Values:
Returns true if successful.
--*/
{
DWORD i;
DWORD dwIncomingModesOld;
DWORD dwOutgoingModesOld;
PH323_CHANNEL_TABLE pChannelTable = pCall->pChannelTable;
// save old media modes
dwIncomingModesOld = pCall->dwIncomingModes;
dwOutgoingModesOld = pCall->dwOutgoingModes;
// clear modia modes
pCall->dwIncomingModes = 0;
pCall->dwOutgoingModes = 0;
// loop through each object in table
for (i = 0; i < pChannelTable->dwNumSlots; i++) {
// see if there are any open channels in table
if (H323IsChannelOpen(pChannelTable->pChannels[i])) {
// see if open channel is incoming
if (H323IsChannelInbound(pChannelTable->pChannels[i])) {
// add media mode to list of media modes
pCall->dwIncomingModes |=
H323IsVideoPayloadType(pChannelTable->pChannels[i]->Settings.dwPayloadType)
? LINEMEDIAMODE_VIDEO
: H323IsInteractiveVoiceRequested(pCall)
? LINEMEDIAMODE_INTERACTIVEVOICE
: LINEMEDIAMODE_AUTOMATEDVOICE
;
} else {
// add media mode to list of media modes
pCall->dwOutgoingModes |=
H323IsVideoPayloadType(pChannelTable->pChannels[i]->Settings.dwPayloadType)
? LINEMEDIAMODE_VIDEO
: H323IsInteractiveVoiceRequested(pCall)
? LINEMEDIAMODE_INTERACTIVEVOICE
: LINEMEDIAMODE_AUTOMATEDVOICE
;
}
}
}
// see if media modes were modified
if ((dwIncomingModesOld | dwOutgoingModesOld) !=
(pCall->dwIncomingModes | pCall->dwOutgoingModes)) {
// announce media change
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_CALLINFO,
LINECALLINFOSTATE_MEDIAMODE,
0,
0
);
}
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx incoming modes 0x%08x (old=0x%08lx).\n",
pCall,
pCall->dwIncomingModes,
dwIncomingModesOld
));
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx outgoing modes 0x%08x (old=0x%08lx).\n",
pCall,
pCall->dwOutgoingModes,
dwOutgoingModesOld
));
// success
return TRUE;
}
BOOL
H323SendAcceptChannelRequest(
PH323_CALL pCall,
PH323_CHANNEL pChannel
)
/*++
Routine Description:
Sends ACCEPT_CHANNEL_REQUEST from TSP to MSP.
Arguments:
pCall - Specifies a pointer to the call object.
pChannel - Specifies a pointer to the channel object to open.
Return Values:
Returns true if successful.
--*/
{
H323TSP_MESSAGE Message;
H323DBG((
DEBUG_LEVEL_TRACE,
"Accept channel request to MSP. htChannel=0x%08lx.\n",
pChannel->hccChannel
));
// set the appropriate message type
Message.Type = H323TSP_ACCEPT_CHANNEL_REQUEST;
// initialize tsp channel handle
Message.AcceptChannelRequest.htChannel = (HANDLE)(DWORD)pChannel->hccChannel;
// transfer stream settings
Message.AcceptChannelRequest.Settings = pChannel->Settings;
// send msp message
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_SENDMSPDATA,
MSP_HANDLE_UNKNOWN,
(DWORD_PTR)&Message,
sizeof(Message)
);
// success
return TRUE;
}
BOOL
H323SendOpenChannelResponse(
PH323_CALL pCall,
PH323_CHANNEL pChannel
)
/*++
Routine Description:
Sends OPEN_CHANNEL_RESPONSE from TSP to MSP.
Arguments:
pCall - Specifies a pointer to the call object.
pChannel - Specifies a pointer to the channel object to open.
Return Values:
Returns true if successful.
--*/
{
H323TSP_MESSAGE Message;
H323DBG((
DEBUG_LEVEL_TRACE,
"Open channel response to MSP. hmChannel=0x%08lx.\n",
pChannel->hmChannel
));
// set the appropriate message type
Message.Type = H323TSP_OPEN_CHANNEL_RESPONSE;
// initialize channel handles
Message.OpenChannelResponse.hmChannel = pChannel->hmChannel;
Message.OpenChannelResponse.htChannel = (HANDLE)(DWORD)pChannel->hccChannel;
// transfer stream settings
Message.OpenChannelResponse.Settings = pChannel->Settings;
// send msp message
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_SENDMSPDATA,
MSP_HANDLE_UNKNOWN,
(DWORD_PTR)&Message,
sizeof(Message)
);
// success
return TRUE;
}
BOOL
H323SendCloseChannelCommand(
PH323_CALL pCall,
HANDLE hmChannel,
DWORD dwReason
)
/*++
Routine Description:
Sends CLOSE_CHANNEL_COMMAND from TSP to MSP.
Arguments:
pCall - Specifies a pointer to the call object.
hmChannel - Specifies a handle to the channel to close.
dwReason - Specifies reason for closing channel.
Return Values:
Returns true if successful.
--*/
{
H323TSP_MESSAGE Message;
H323DBG((
DEBUG_LEVEL_TRACE,
"Close channel command to MSP. hmChannel=0x%08lx.\n",
hmChannel
));
// set the appropriate message type
Message.Type = H323TSP_CLOSE_CHANNEL_COMMAND;
// transfer reason
Message.CloseChannelCommand.dwReason = dwReason;
// initialize channel handles
Message.CloseChannelCommand.hChannel = hmChannel;
// send msp message
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_SENDMSPDATA,
MSP_HANDLE_UNKNOWN,
(DWORD_PTR)&Message,
sizeof(Message)
);
// success
return TRUE;
}
BOOL
H323ProcessOpenChannelRequest(
PH323_CALL pCall,
PH323MSG_OPEN_CHANNEL_REQUEST pRequest
)
/*++
Routine Description:
Process command from MSP.
Arguments:
pCall - Specifies a pointer to the call object to process.
pRequest - Specifies a pointer to the command block.
Return Values:
Returns true if successful.
--*/
{
BOOL fOpened = FALSE;
PH323_CHANNEL pChannel = NULL;
PH323_CHANNEL pAssociatedChannel = NULL;
BYTE bSessionID;
H323DBG((
DEBUG_LEVEL_TRACE,
"open channel reqest from MSP. hmChannel=0x%08lx.\n",
pRequest->hmChannel
));
// determine session id from media type
bSessionID = (pRequest->Settings.MediaType == MEDIA_AUDIO)
? H245_SESSIONID_AUDIO
: H245_SESSIONID_VIDEO
;
// look for existing session
H323LookupChannelBySessionID(
&pAssociatedChannel,
pCall->pChannelTable,
bSessionID
);
// allocate new channel object
if (!H323AllocChannelFromTable(
&pChannel,
&pCall->pChannelTable,
pCall)) {
H323DBG((
DEBUG_LEVEL_WARNING,
"could not allocate channel hmChannel=0x%08lx.\n",
pRequest->hmChannel
));
// close the requested channel
H323SendCloseChannelCommand(
pCall,
pRequest->hmChannel,
ERROR_NOT_ENOUGH_MEMORY
);
// failure
return FALSE;
}
// save msp channel handle
pChannel->hmChannel = pRequest->hmChannel;
// initialize common information
pChannel->bSessionID = bSessionID;
pChannel->pCall = pCall;
// examine existing session
if (pAssociatedChannel != NULL) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"overriding default local RTCP port for session %d\n",
pChannel->bSessionID
));
// override default RTCP port with existing one
pChannel->ccLocalRTCPAddr.Addr.IP_Binary.wPort =
pAssociatedChannel->ccLocalRTCPAddr.Addr.IP_Binary.wPort;
}
// see if outgoing audio requested
if (bSessionID == H245_SESSIONID_AUDIO) {
// transfer capabilities from call object
pChannel->ccTermCaps = pCall->ccRemoteAudioCaps;
// check terminal capabilities for g723
if (pChannel->ccTermCaps.ClientType == H245_CLIENT_AUD_G723) {
// complete stream description structure
pChannel->Settings.MediaType = MEDIA_AUDIO;
pChannel->Settings.dwPayloadType = G723_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType = G723_RTP_PAYLOAD_TYPE;
pChannel->Settings.Audio.dwMillisecondsPerPacket =
G723_MILLISECONDS_PER_PACKET(
pChannel->ccTermCaps.Cap.H245Aud_G723.maxAl_sduAudioFrames
);
pChannel->Settings.Audio.G723Settings.bG723LowSpeed =
H323IsSlowLink(pCall->dwLinkSpeed);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"outgoing G723 stream (%d milliseconds).\n",
pChannel->Settings.Audio.dwMillisecondsPerPacket
));
// open outgoing channel
fOpened = H323OpenChannel(pChannel);
} else if (pChannel->ccTermCaps.ClientType == H245_CLIENT_AUD_G711_ULAW64) {
// complete stream description structure
pChannel->Settings.MediaType = MEDIA_AUDIO;
pChannel->Settings.dwPayloadType = G711U_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType = G711U_RTP_PAYLOAD_TYPE;
pChannel->Settings.Audio.dwMillisecondsPerPacket =
G711_MILLISECONDS_PER_PACKET(
pChannel->ccTermCaps.Cap.H245Aud_G711_ULAW64
);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"outgoing G711U stream (%d milliseconds).\n",
pChannel->Settings.Audio.dwMillisecondsPerPacket
));
// open outgoing channel
fOpened = H323OpenChannel(pChannel);
} else if (pChannel->ccTermCaps.ClientType == H245_CLIENT_AUD_G711_ALAW64) {
// complete stream description structure
pChannel->Settings.MediaType = MEDIA_AUDIO;
pChannel->Settings.dwPayloadType = G711A_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType = G711A_RTP_PAYLOAD_TYPE;
pChannel->Settings.Audio.dwMillisecondsPerPacket =
G711_MILLISECONDS_PER_PACKET(
pChannel->ccTermCaps.Cap.H245Aud_G711_ALAW64
);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"outgoing G711A stream (%d milliseconds).\n",
pChannel->Settings.Audio.dwMillisecondsPerPacket
));
// open outgoing channel
fOpened = H323OpenChannel(pChannel);
}
} else if (bSessionID == H245_SESSIONID_VIDEO) {
// transfer capabilities from call object
pChannel->ccTermCaps = pCall->ccRemoteVideoCaps;
// check terminal capabilities for h263
if (pChannel->ccTermCaps.ClientType == H245_CLIENT_VID_H263) {
DWORD dwFinalMaxBitRate;
DWORD dwStartUpBitRate;
DWORD dwAudioBitRate;
// complete stream description structure
pChannel->Settings.MediaType = MEDIA_VIDEO;
pChannel->Settings.dwPayloadType = H263_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType = H263_RTP_PAYLOAD_TYPE;
pChannel->Settings.Video.bCIF = FALSE;
if (pCall->ccRemoteAudioCaps.ClientType == H245_CLIENT_AUD_G723)
{
DWORD dwFramesPerPacket =
pCall->ccRemoteAudioCaps.Cap.H245Aud_G723.maxAl_sduAudioFrames;
dwAudioBitRate =
(TOTAL_HEADER_SIZE + dwFramesPerPacket * G723_BYTES_PER_FRAME)
* CHAR_BIT * 1000 / (dwFramesPerPacket * G723_MILLISECONDS_PER_FRAME);
}
else
{
// Since for other types of audio encoding the
// call to H323ComputeVideoChannelBitRates will have
// no effect, we set the audio bit rate to a dummy
// value.
dwAudioBitRate = H323_MINIMUM_AUDIO_BANDWIDTH;
}
// ajust three percent to make QOS happy.
dwAudioBitRate = dwAudioBitRate * 103 / 100;
H323ComputeVideoChannelBitRates(
pChannel->ccTermCaps.Cap.H245Vid_H263.maxBitRate,
dwAudioBitRate / 100 + 1,
&dwFinalMaxBitRate,
&dwStartUpBitRate
);
pChannel->ccTermCaps.Cap.H245Vid_H263.maxBitRate = dwFinalMaxBitRate;
pChannel->Settings.Video.dwMaxBitRate = dwFinalMaxBitRate * 100;
pChannel->Settings.Video.dwStartUpBitRate = dwStartUpBitRate;
H323DBG((
DEBUG_LEVEL_VERBOSE,
"outgoing H263 stream (%d bps).\n",
pChannel->Settings.Video.dwMaxBitRate
));
// open outgoing channel
fOpened = H323OpenChannel(pChannel);
} else if (pChannel->ccTermCaps.ClientType == H245_CLIENT_VID_H261) {
DWORD dwFinalMaxBitRate;
DWORD dwStartUpBitRate;
DWORD dwAudioBitRate;
// complete stream description structure
pChannel->Settings.MediaType = MEDIA_VIDEO;
pChannel->Settings.dwPayloadType = H261_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType = H261_RTP_PAYLOAD_TYPE;
pChannel->Settings.Video.bCIF = FALSE;
if (pCall->ccRemoteAudioCaps.ClientType == H245_CLIENT_AUD_G723)
{
DWORD dwFramesPerPacket =
pCall->ccRemoteAudioCaps.Cap.H245Aud_G723.maxAl_sduAudioFrames;
dwAudioBitRate =
(TOTAL_HEADER_SIZE + dwFramesPerPacket * G723_BYTES_PER_FRAME)
* CHAR_BIT * 1000 / (dwFramesPerPacket * G723_MILLISECONDS_PER_FRAME);
}
else
{
// Since for other types of audio encoding the
// call to H323ComputeVideoChannelBitRates will have
// no effect, we set the audio bit rate to a dummy
// value.
dwAudioBitRate = H323_MINIMUM_AUDIO_BANDWIDTH;
}
// ajust three percent to make QOS happy.
dwAudioBitRate = dwAudioBitRate * 103 / 100;
H323ComputeVideoChannelBitRates(
(DWORD)pChannel->ccTermCaps.Cap.H245Vid_H261.maxBitRate,
dwAudioBitRate / 100 + 1,
&dwFinalMaxBitRate,
&dwStartUpBitRate
);
pChannel->ccTermCaps.Cap.H245Vid_H261.maxBitRate = (WORD)dwFinalMaxBitRate;
pChannel->Settings.Video.dwMaxBitRate = dwFinalMaxBitRate * 100;
pChannel->Settings.Video.dwStartUpBitRate = dwStartUpBitRate;
H323DBG((
DEBUG_LEVEL_VERBOSE,
"outgoing H261 stream (%d bps).\n",
pChannel->Settings.Video.dwMaxBitRate
));
// open outgoing channel
fOpened = H323OpenChannel(pChannel);
}
}
// validate
if (!fOpened) {
H323DBG((
DEBUG_LEVEL_WARNING,
"could not open channel hmChannel=0x%08lx.\n",
pRequest->hmChannel
));
// close the requested channel
H323SendCloseChannelCommand(
pCall,
pRequest->hmChannel,
ERROR_GEN_FAILURE
);
// failure
return FALSE;
}
// success
return TRUE;
}
BOOL
H323ProcessAcceptChannelResponse(
PH323_CALL pCall,
PH323MSG_ACCEPT_CHANNEL_RESPONSE pResponse
)
/*++
Routine Description:
Process command from MSP.
Arguments:
pCall - Specifies a pointer to the call object to process.
pResponse - Specifies a pointer to the command block.
Return Values:
Returns true if successful.
--*/
{
PH323_CHANNEL pChannel = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"accept channel response from MSP. hmChannel=0x%08lx. htChannel=0x%08lx.\n",
pResponse->hmChannel,
pResponse->htChannel
));
// retrieve channel given handle
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
(CC_HCHANNEL)PtrToUlong(pResponse->htChannel))) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not accept unknown htChannel 0x%08lx",
pResponse->htChannel
));
// done
return TRUE;
}
// accept channel
CC_AcceptChannel(
pChannel->hccChannel, // hChannel
&pChannel->ccLocalRTPAddr, // pRTPAddr
&pChannel->ccLocalRTCPAddr, // pRTCPAddr
0 // dwChannelBitRate
);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx accepted htChannel 0x%08lx.\n",
pCall,
pChannel->hccChannel
));
// change state to opened
pChannel->nState = H323_CHANNELSTATE_OPENED;
// update media modes
H323UpdateMediaModes(pCall);
// success
return TRUE;
}
BOOL
H323ProcessVideoFastUpdatePictureCommand(
PH323_CALL pCall,
PH323MSG_VIDEO_FAST_UPDATE_PICTURE_COMMAND pCommand
)
/*++
Routine Description:
Process I-frame request command from MSP.
Arguments:
pCall - Specifies a pointer to the call object to process.
pCommand - Specifies a pointer to the command block.
Return Values:
Returns TRUE if successful.
--*/
{
PH323_CHANNEL pChannel = NULL;
MiscellaneousCommand h245miscellaneousCommand;
H323DBG((
DEBUG_LEVEL_TRACE,
"MSP->TSP I-frame request. hChannel=0x%08lx.\n",
pCommand->hChannel
));
h245miscellaneousCommand.type.choice = videoFastUpdatePicture_chosen;
// retrieve channel given handle
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
(CC_HCHANNEL)PtrToUlong(pCommand->hChannel))) {
H323DBG((
DEBUG_LEVEL_ERROR,
"Could not process MSP->TSP I-frame request. Unknown hChannel 0x%08lx.\n",
pCommand->hChannel
));
// done
return TRUE;
}
// send H245 Miscellaneous Command to the remote entity
CC_H245MiscellaneousCommand(
pCall->hccCall, // hCall
pChannel->hccChannel, // hChannel
&h245miscellaneousCommand // Command
);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"MSP->TSP I-frame request processed. call 0x%08lx -- hccChannel 0x%08lx. \n",
pCall,
pChannel->hccChannel
));
// success
return TRUE;
}
BOOL
H323ProcessFlowControlCommand(
PH323_CALL pCall,
PH323MSG_FLOW_CONTROL_COMMAND pCommand
)
/*++
Routine Description:
Process flow control command from MSP.
Arguments:
pCall - Specifies a pointer to the call object to process.
pCommand - Specifies a pointer to the command block.
Return Values:
Returns true if successful.
--*/
{
PH323_CHANNEL pChannel = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"MSP->TSP Flow control cmd. hChannel=0x%08lx. Req. rate=%08d.\n",
pCommand->hChannel,
pCommand->dwBitRate
));
// retrieve channel given handle
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
(CC_HCHANNEL)PtrToUlong(pCommand->hChannel))) {
H323DBG((
DEBUG_LEVEL_ERROR,
"Could not process MSP->TSP flow control cmd. Unknown hChannel 0x%08lx",
pCommand->hChannel
));
// done
return TRUE;
}
// send flow control command to the remote entity
CC_FlowControl(
pChannel->hccChannel, // hChannel
pCommand->dwBitRate // requested bit rate, bps
);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx -- hccChannel 0x%08lx, MSP->TSP flow control cmd processed.\n",
pCall,
pChannel->hccChannel
));
// success
return TRUE;
}
BOOL
H323ProcessQoSEventIndication(
PH323_CALL pCall,
PH323MSG_QOS_EVENT pCommand
)
/*++
Routine Description:
Process QoS event indication from MSP.
Arguments:
pCall - Specifies a pointer to the call object to process.
pCommand - Specifies a pointer to the command block.
Return Values:
Returns true if successful.
--*/
{
PH323_CHANNEL pChannel = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"MSP->TSP QoS event. htChannel=0x%08lx. dwEvent=%08d.\n",
pCommand->htChannel,
pCommand->dwEvent
));
// retrieve channel given handle
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
(CC_HCHANNEL)PtrToUlong(pCommand->htChannel))) {
H323DBG((
DEBUG_LEVEL_ERROR,
"Could not process MSP->TSP QoS event. Unknown htChannel 0x%08lx",
pCommand->htChannel
));
// done
return TRUE;
}
// report qos event
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_QOSINFO,
pCommand->dwEvent,
(pChannel->Settings.MediaType == MEDIA_AUDIO)
? LINEMEDIAMODE_INTERACTIVEVOICE
: LINEMEDIAMODE_VIDEO,
0
);
// success
return TRUE;
}
BOOL
H323ProcessCloseChannelCommand(
PH323_CALL pCall,
PH323MSG_CLOSE_CHANNEL_COMMAND pCommand
)
/*++
Routine Description:
Process command from MSP.
Arguments:
pCall - Specifies a pointer to the call object to process.
pCommand - Specifies a pointer to the command block.
Return Values:
Returns true if successful.
--*/
{
PH323_CHANNEL pChannel = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"close channel command from MSP. htChannel=0x%08lx.\n",
pCommand->hChannel
));
// retrieve channel given handle
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
(CC_HCHANNEL)PtrToUlong(pCommand->hChannel))) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not close unknown htChannel 0x%08lx",
pCommand->hChannel
));
// done
return TRUE;
}
H323DBG((
DEBUG_LEVEL_WARNING,
"closing htChannel 0x%08lx.\n",
pCommand->hChannel
));
// close channel
H323CloseChannel(pChannel);
// release channel resources
H323FreeChannelFromTable(pChannel,pCall->pChannelTable);
// success
return TRUE;
}
VOID
H323ProcessPlaceCallMessage(
HDRVCALL hdCall
)
/*++
Routine Description:
Processes async place call messages.
Arguments:
hdCall - Handle to call to be placed.
Return Values:
None.
--*/
{
PH323_CALL pCall = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"place call message received (hdCall=0x%08lx).\n",
PtrToUlong(hdCall)
));
// retrieve call pointer from handle
if (H323GetCallAndLock(&pCall, hdCall)) {
// place outgoing call
if (!H323PlaceCall(pCall)) {
// drop call using disconnect mode
H323DropCall(pCall, LINEDISCONNECTMODE_TEMPFAILURE);
}
// unlock line device
H323UnlockLine(pCall->pLine);
} else {
H323DBG((
DEBUG_LEVEL_ERROR,
"invalid handle in place call message.\n"
));
}
}
VOID
H323ProcessAcceptCallMessage(
HDRVCALL hdCall
)
/*++
Routine Description:
Processes async accept call messages.
Arguments:
hdCall - Handle to call to be placed.
Return Values:
None.
--*/
{
PH323_CALL pCall = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"accept call message received (hdCall=0x%08lx).\n",
PtrToUlong(hdCall)
));
// retrieve call pointer from handle
if (H323GetCallAndLock(&pCall, hdCall)) {
// place outgoing call
if (!H323AcceptCall(pCall)) {
// drop call using disconnect mode
H323DropCall(pCall, LINEDISCONNECTMODE_TEMPFAILURE);
}
// unlock line device
H323UnlockLine(pCall->pLine);
} else {
H323DBG((
DEBUG_LEVEL_ERROR,
"invalid handle in accept call message.\n"
));
}
}
VOID
H323ProcessDropCallMessage(
HDRVCALL hdCall,
DWORD dwDisconnectMode
)
/*++
Routine Description:
Processes async drop call messages.
Arguments:
hdCall - Handle to call to be hung up.
dwDisconnectMode - Status to be placed in disconnected message.
Return Values:
None.
--*/
{
PH323_CALL pCall = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"drop call message received (hdCall=0x%08lx).\n",
PtrToUlong(hdCall)
));
// retrieve call pointer from handle
if (H323GetCallAndLock(&pCall, hdCall)) {
// drop call using disconnect code
H323DropCall(pCall, dwDisconnectMode);
// unlock line device
H323UnlockLine(pCall->pLine);
} else {
H323DBG((
DEBUG_LEVEL_ERROR,
"invalid handle in place call message.\n"
));
}
}
VOID
H323ProcessCloseCallMessage(
HDRVCALL hdCall
)
/*++
Routine Description:
Processes async close call messages.
Arguments:
hdCall - Handle to call to be closed.
Return Values:
None.
--*/
{
PH323_CALL pCall = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"close call message received (hdCall=0x%08lx).\n",
PtrToUlong(hdCall)
));
// retrieve call pointer from handle
if (H323GetCallAndLock(&pCall, hdCall)) {
// close call
H323CloseCall(pCall);
// unlock line device
H323UnlockLine(pCall->pLine);
} else {
H323DBG((
DEBUG_LEVEL_ERROR,
"invalid handle in place call message.\n"
));
}
}
VOID
H323ProcessCallListenMessage(
HDRVLINE hdLine
)
/*++
Routine Description:
Processes async call listen messages.
Arguments:
hdLine - Line to be placed into listening state.
Return Values:
None.
--*/
{
PH323_LINE pLine = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"call listen message received (hdLine=0x%08lx).\n",
PtrToUlong(hdLine)
));
// retrieve line pointer from handle
if (H323GetLineAndLock(&pLine, hdLine)) {
// start listening for calls
if (!H323CallListen(pLine)) {
// change state to opened
pLine->nState = H323_LINESTATE_OPENED;
}
// unlock line device
H323UnlockLine(pLine);
} else {
H323DBG((
DEBUG_LEVEL_ERROR,
"invalid handle in call listen message.\n"
));
}
}
DWORD
WINAPI
H323CallbackThread(
LPVOID pParam
)
/*++
Routine Description:
Worker thread to handle async operations.
Arguments:
pParam - Pointer to opaque thread parameter (unused).
Return Values:
Win32 error codes.
--*/
{
MSG msg;
DWORD dwStatus;
// associate event with key
H323ListenForRegistryChanges(
g_WaitableObjects[WAIT_OBJECT_REGISTRY_CHANGE]
);
// loop...
for (;;) {
// wait for message or termination
dwStatus = MsgWaitForMultipleObjectsEx(
NUM_WAITABLE_OBJECTS,
g_WaitableObjects,
INFINITE,
QS_ALLINPUT,
MWMO_ALERTABLE
);
// see if new message has arrived
if (dwStatus == WAIT_OBJECT_INCOMING_MESSAGE) {
// retrieve next item in thread message queue
while (PeekMessage(&msg, NULL, 0, 0, PM_REMOVE)) {
// handle service provider messages
if (H323IsPlaceCallMessage(&msg)) {
// process place call message
H323ProcessPlaceCallMessage((HDRVCALL)msg.wParam);
} else if (H323IsAcceptCallMessage(&msg)) {
// process accept call message
H323ProcessAcceptCallMessage((HDRVCALL)msg.wParam);
} else if (H323IsDropCallMessage(&msg)) {
// process drop call message
H323ProcessDropCallMessage((HDRVCALL)msg.wParam,(DWORD)msg.lParam);
} else if (H323IsCloseCallMessage(&msg)) {
// process close call message
H323ProcessCloseCallMessage((HDRVCALL)msg.wParam);
} else if (H323IsCallListenMessage(&msg)) {
// process call listen message
H323ProcessCallListenMessage((HDRVLINE)msg.wParam);
} else {
// translate message
TranslateMessage(&msg);
// dispatch message
DispatchMessage(&msg);
}
}
} else if (dwStatus == WAIT_OBJECT_REGISTRY_CHANGE) {
// lock provider
H323LockProvider();
// refresh registry settings
H323GetConfigFromRegistry();
// associate event with registry key
H323ListenForRegistryChanges(g_WaitableObjects[WAIT_OBJECT_REGISTRY_CHANGE]);
// unlock provider
H323UnlockProvider();
} else if (dwStatus == WAIT_IO_COMPLETION) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"callback thread %x io completion.\n",
g_dwCallbackThreadID
));
} else if (dwStatus == WAIT_OBJECT_TERMINATE_EVENT) {
H323DBG((
DEBUG_LEVEL_TRACE,
"callback thread %x terminating on command.\n",
g_dwCallbackThreadID
));
break; // bail...
} else {
H323DBG((
DEBUG_LEVEL_TRACE,
"callback thread %x terminating (dwStatus=0x%08lx).\n",
g_dwCallbackThreadID,
dwStatus
));
break; // bail...
}
}
// stop listening for registry changes
H323StopListeningForRegistryChanges();
H323DBG((
DEBUG_LEVEL_VERBOSE,
"callback thread %x exiting.\n",
g_dwCallbackThreadID
));
// success
return NOERROR;
}
DWORD
H323RejectReasonToDisconnectMode(
BYTE bRejectReason
)
/*++
Routine Description:
Converts connect reject reason to tapi disconnect mode.
Arguments:
bRejectReason - Specifies reason peer rejected call.
Return Values:
Returns disconnect mode corresponding to reject reason.
--*/
{
H323DBG((
DEBUG_LEVEL_VERBOSE,
"Reject Reason: %s.\n",
CCRejectReasonToString((DWORD)bRejectReason)
));
// determine reject reason
switch (bRejectReason) {
case CC_REJECT_NORMAL_CALL_CLEARING:
// call was terminated normally
return LINEDISCONNECTMODE_NORMAL;
case CC_REJECT_UNREACHABLE_DESTINATION:
// remote user could not be reached
return LINEDISCONNECTMODE_UNREACHABLE;
case CC_REJECT_DESTINATION_REJECTION:
// remote user has rejected the call
return LINEDISCONNECTMODE_REJECT;
case CC_REJECT_USER_BUSY:
// remote user's station is busy
return LINEDISCONNECTMODE_BUSY;
case CC_REJECT_NO_ANSWER:
// remote user's station does not answer
return LINEDISCONNECTMODE_NOANSWER;
case CC_REJECT_BAD_FORMAT_ADDRESS:
// destination address in invalid
return LINEDISCONNECTMODE_BADADDRESS;
default:
// reason for the disconnect is unavailable
return LINEDISCONNECTMODE_UNAVAIL;
}
}
BOOL
H323GetTermCapById(
H245_CAPID_T CapId,
PCC_TERMCAPLIST pTermCapList,
PCC_TERMCAP * ppTermCap
)
/*++
Routine Description:
Retrieve pointer to termcap from list via id.
Arguments:
CapId - Id of termcap of interest.
pTermCapList - Pointer to termcap list.
ppTermCap - Pointer to place to copy termcap pointer.
Return Values:
Returns TRUE if successful.
--*/
{
WORD wIndex;
PCC_TERMCAP pTermCap;
// walk caps
for (wIndex = 0; wIndex < pTermCapList->wLength; wIndex++) {
// compare id with the next item in the list
if (pTermCapList->pTermCapArray[wIndex]->CapId == CapId) {
// return pointer
*ppTermCap = pTermCapList->pTermCapArray[wIndex];
// success
return TRUE;
}
}
// failure
return FALSE;
}
BOOL
H323GetTermCapByType(
H245_DATA_T DataType,
H245_CLIENT_T ClientType,
PCC_TERMCAPLIST pTermCapList,
PCC_TERMCAP * ppTermCap
)
/*++
Routine Description:
Retrieve pointer to termcap from list via id.
Arguments:
DataType - Type of capability.
ClientType - Type of media-specific cabability.
pTermCapList - Pointer to termcap list.
ppTermCap - Pointer to place to copy termcap pointer.
Return Values:
Returns TRUE if successful.
--*/
{
WORD wIndex;
PCC_TERMCAP pTermCap;
// walk caps
for (wIndex = 0; wIndex < pTermCapList->wLength; wIndex++) {
// compare id with the next item in the list
if ((pTermCapList->pTermCapArray[wIndex]->DataType == DataType) &&
(pTermCapList->pTermCapArray[wIndex]->ClientType == ClientType)) {
// return pointer
*ppTermCap = pTermCapList->pTermCapArray[wIndex];
// success
return TRUE;
}
}
// failure
return FALSE;
}
BOOL
H323SavePreferredTermCap(
PH323_CALL pCall,
PCC_TERMCAP pLocalCap,
PCC_TERMCAP pRemoteCap
)
/*++
Routine Description:
Save remote cap adjusted for outgoing settings.
Arguments:
pCall - Pointer to call object.
pLocalCap - Pointer to local capability.
pRemoteCap - Pointer to termcap to save.
Return Values:
Returns TRUE if both audio and video termcaps resolved.
--*/
{
PCC_TERMCAP pPreferredCap;
WORD wMillisecondsPerPacket;
// retrieve pointer to stored termcap preferences
pPreferredCap = H323IsValidAudioClientType(pRemoteCap->ClientType)
? &pCall->ccRemoteAudioCaps
: &pCall->ccRemoteVideoCaps
;
// make sure we have not already saved preferred type
if (H323IsValidClientType(pPreferredCap->ClientType)) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx ignoring remote cap %d\n",
pCall,
pRemoteCap->CapId
));
// failure
return FALSE;
}
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx saving remote cap %d\n",
pCall,
pRemoteCap->CapId
));
// modify preferred caps
*pPreferredCap = *pLocalCap;
// reverse capability direction
pPreferredCap->Dir = H245_CAPDIR_LCLTX;
// determine client type
switch (pPreferredCap->ClientType) {
case H245_CLIENT_AUD_G723:
// determine packet size
wMillisecondsPerPacket =
H323IsSlowLink(pCall->dwLinkSpeed)
? G723_SLOWLNK_MILLISECONDS_PER_PACKET
: G723_DEFAULT_MILLISECONDS_PER_PACKET
;
// adjust default parameters for link speed
pPreferredCap->Cap.H245Aud_G723.maxAl_sduAudioFrames =
G723_FRAMES_PER_PACKET(wMillisecondsPerPacket)
;
// see if remote maximum less than default
if (pRemoteCap->Cap.H245Aud_G723.maxAl_sduAudioFrames <
pPreferredCap->Cap.H245Aud_G723.maxAl_sduAudioFrames) {
// use remote maximum instead of default
pPreferredCap->Cap.H245Aud_G723.maxAl_sduAudioFrames =
pRemoteCap->Cap.H245Aud_G723.maxAl_sduAudioFrames
;
}
break;
case H245_CLIENT_AUD_G711_ULAW64:
// store default parameters
pPreferredCap->Cap.H245Aud_G711_ULAW64 =
G711_FRAMES_PER_PACKET(
G711_DEFAULT_MILLISECONDS_PER_PACKET
);
// see if remote maximum less than default
if (pRemoteCap->Cap.H245Aud_G711_ULAW64 <
pPreferredCap->Cap.H245Aud_G711_ULAW64) {
// use remote maximum instead of default
pPreferredCap->Cap.H245Aud_G711_ULAW64 =
pRemoteCap->Cap.H245Aud_G711_ULAW64
;
}
break;
case H245_CLIENT_AUD_G711_ALAW64:
// store default parameters
pPreferredCap->Cap.H245Aud_G711_ALAW64 =
G711_FRAMES_PER_PACKET(
G711_DEFAULT_MILLISECONDS_PER_PACKET
);
// see if remote maximum less than default
if (pRemoteCap->Cap.H245Aud_G711_ALAW64 <
pPreferredCap->Cap.H245Aud_G711_ALAW64) {
// use remote maximum instead of default
pPreferredCap->Cap.H245Aud_G711_ALAW64 =
pRemoteCap->Cap.H245Aud_G711_ALAW64
;
}
break;
case H245_CLIENT_VID_H263:
// see if remote maximum less than local
if (pRemoteCap->Cap.H245Vid_H263.maxBitRate <
pPreferredCap->Cap.H245Vid_H263.maxBitRate) {
// use remote maximum instead of local
pPreferredCap->Cap.H245Vid_H263.maxBitRate =
pRemoteCap->Cap.H245Vid_H263.maxBitRate
;
}
break;
case H245_CLIENT_VID_H261:
// see if remote maximum less than local
if (pRemoteCap->Cap.H245Vid_H261.maxBitRate <
pPreferredCap->Cap.H245Vid_H261.maxBitRate) {
// use remote maximum instead of local
pPreferredCap->Cap.H245Vid_H261.maxBitRate =
pRemoteCap->Cap.H245Vid_H261.maxBitRate
;
}
break;
}
// return success if we have resolved both audio and video caps
return (H323IsValidClientType(pCall->ccRemoteAudioCaps.ClientType) &&
H323IsValidClientType(pCall->ccRemoteVideoCaps.ClientType));
}
VOID
H323GetPreferedTransmitTypes(
PCC_TERMCAPDESCRIPTORS pTermCapDescriptors,
H245_CLIENT_T *pPreferredAudioType,
H245_CLIENT_T *pPreferredVideoType
)
/*++
Routine Description:
Find the preferred audio and video format in the local terminal capability
descriptors array if they exist.
Arguments:
pTermCapDescriptors - pointer to the local terminal capability descriptor.
pPreferredAudioType - return the preferred audio type.
pPreferredVideoType - return the preferred video type.
Return Values:
NONE
--*/
{
WORD wDescIndex;
WORD wSimCapIndex;
WORD wAltCapIndex;
// process descriptors
for (wDescIndex = 0; wDescIndex < pTermCapDescriptors->wLength; wDescIndex++)
{
H245_TOTCAPDESC_T * pTotCapDesc;
// retrieve pointer to capability structure
pTotCapDesc = pTermCapDescriptors->pTermCapDescriptorArray[wDescIndex];
// process simultaneous caps
for (wSimCapIndex = 0; wSimCapIndex < pTotCapDesc->CapDesc.Length; wSimCapIndex++)
{
H245_SIMCAP_T * pSimCap;
// retrieve pointer to simulateous cap
pSimCap = &pTotCapDesc->CapDesc.SimCapArray[wSimCapIndex];
if (pSimCap->Length > 0)
{
// the first one in the altcaps array is the preferred one.
switch (pSimCap->AltCaps[0])
{
case H245_TERMCAPID_G723:
*pPreferredAudioType = H245_CLIENT_AUD_G723;
break;
case H245_TERMCAPID_H263:
*pPreferredVideoType = H245_CLIENT_VID_H263;
break;
case H245_TERMCAPID_G711_ULAW64:
*pPreferredAudioType = H245_CLIENT_AUD_G711_ULAW64;
break;
case H245_TERMCAPID_G711_ALAW64:
*pPreferredAudioType = H245_CLIENT_AUD_G711_ALAW64;
break;
case H245_TERMCAPID_H261:
*pPreferredVideoType = H245_CLIENT_VID_H261;
break;
}
}
}
}
}
BOOL
H323ProcessRemoteTermCaps(
PH323_CALL pCall,
PCC_TERMCAPLIST pRemoteTermCapList,
PCC_TERMCAPDESCRIPTORS pRemoteTermCapDescriptors
)
/*++
Routine Description:
Process remote capabilities and establish outgoing termcaps.
Arguments:
pCall - Pointer to call object.
pRemoteTermCapList - Pointer to termcap list.
pRemoteTermCapDescriptors - Pointer to descriptor list.
Return Values:
Returns TRUE if successful.
--*/
{
WORD wDescIndex;
WORD wSimCapIndex;
WORD wAltCapIndex;
PCC_TERMCAP pLocalCap = NULL;
PCC_TERMCAP pRemoteCap = NULL;
CC_TERMCAPLIST LocalTermCapList;
CC_TERMCAPDESCRIPTORS LocalTermCapDescriptors;
CC_TERMCAP SavedAudioCap;
CC_TERMCAP SavedVideoCap;
H245_CLIENT_T PreferredAudioType = H245_CLIENT_DONTCARE;
H245_CLIENT_T PreferredVideoType = H245_CLIENT_DONTCARE;
// initialize cached termcaps
memset(&SavedAudioCap,0,sizeof(CC_TERMCAP));
memset(&SavedVideoCap,0,sizeof(CC_TERMCAP));
// retrieve local caps
H323GetTermCapList(pCall,&LocalTermCapList,&LocalTermCapDescriptors);
H323GetPreferedTransmitTypes(
&LocalTermCapDescriptors,
&PreferredAudioType,
&PreferredVideoType
);
// look for our preferred audio format.
if (PreferredAudioType != H245_CLIENT_DONTCARE)
{
// look for match
if (H323GetTermCapByType(H245_DATA_AUDIO, PreferredAudioType,
pRemoteTermCapList, &pRemoteCap )
&& H323GetTermCapByType(H245_DATA_AUDIO, PreferredAudioType,
&LocalTermCapList, &pLocalCap ))
{
// adjust termcaps and save
if (H323SavePreferredTermCap(
pCall,
pLocalCap,
pRemoteCap
))
{
//
// The function above will only return
// true when both audio and video caps
// have been successfully resolved.
//
return TRUE;
}
}
}
// look for our preferred video format.
if (PreferredVideoType != H245_CLIENT_DONTCARE)
{
// look for match
if (H323GetTermCapByType(H245_DATA_VIDEO, PreferredVideoType,
pRemoteTermCapList, &pRemoteCap )
&& H323GetTermCapByType(H245_DATA_VIDEO, PreferredVideoType,
&LocalTermCapList, &pLocalCap ))
{
// adjust termcaps and save
if (H323SavePreferredTermCap(
pCall,
pLocalCap,
pRemoteCap
))
{
//
// The function above will only return
// true when both audio and video caps
// have been successfully resolved.
//
return TRUE;
}
}
}
// process descriptors
for (wDescIndex = 0;
wDescIndex < pRemoteTermCapDescriptors->wLength;
wDescIndex++) {
H245_TOTCAPDESC_T * pTotCapDesc;
// retrieve pointer to capability structure
pTotCapDesc = pRemoteTermCapDescriptors->pTermCapDescriptorArray[wDescIndex];
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx processing CapDescId %d\n",
pCall,
pTotCapDesc->CapDescId
));
// process simultaneous caps
for (wSimCapIndex = 0;
wSimCapIndex < pTotCapDesc->CapDesc.Length;
wSimCapIndex++) {
H245_SIMCAP_T * pSimCap;
// retrieve pointer to simulateous cap
pSimCap = &pTotCapDesc->CapDesc.SimCapArray[wSimCapIndex];
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx processing SimCap %d\n",
pCall,
wSimCapIndex + 1
));
// process alternative caps
for (wAltCapIndex = 0;
wAltCapIndex < pSimCap->Length;
wAltCapIndex++) {
H245_CAPID_T CapId;
// re-initialize
pRemoteCap = NULL;
// retrieve alternative capid
CapId = pSimCap->AltCaps[wAltCapIndex];
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx processing AltCapId %d\n",
pCall,
CapId
));
// lookup termcap from id
if (H323GetTermCapById(
CapId,
pRemoteTermCapList,
&pRemoteCap
)) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx examining remote cap %d:\n\t%s\n\t%s\n\t%s\n",
pCall,
pRemoteCap->CapId,
H323DirToString(pRemoteCap->Dir),
H323DataTypeToString(pRemoteCap->DataType),
H323ClientTypeToString(pRemoteCap->ClientType)
));
// validate remote termcap and check priority
if (H323IsReceiveCapability(pRemoteCap->Dir)) {
// re-initialize
pLocalCap = NULL;
// look for match
if (H323GetTermCapByType(
pRemoteCap->DataType,
pRemoteCap->ClientType,
&LocalTermCapList,
&pLocalCap
)) {
// adjust termcaps and save
if (H323SavePreferredTermCap(
pCall,
pLocalCap,
pRemoteCap
)) {
//
// The function above will only return
// true when both audio and video caps
// have been successfully resolved.
//
return TRUE;
}
}
}
}
}
}
// see if we discovered any audio-only caps we would like to save
if (H323IsValidClientType(pCall->ccRemoteAudioCaps.ClientType) &&
!H323IsValidClientType(SavedAudioCap.ClientType)) {
// save discovered audio-only cap
SavedAudioCap = pCall->ccRemoteAudioCaps;
// reset video-only cap (prefer audio-only)
memset(&SavedVideoCap,0,sizeof(CC_TERMCAP));
}
// see if we discovered any video-only caps we would like to save
if (H323IsValidClientType(pCall->ccRemoteVideoCaps.ClientType) &&
!H323IsValidClientType(SavedAudioCap.ClientType)) {
// save video-only cap (only if no saved audio-only cap)
SavedVideoCap = pCall->ccRemoteVideoCaps;
}
// reset capability stored in call for next iteration
memset(&pCall->ccRemoteAudioCaps,0,sizeof(CC_TERMCAP));
memset(&pCall->ccRemoteVideoCaps,0,sizeof(CC_TERMCAP));
}
// see if we saved any audio-only capabilities
if (H323IsValidClientType(SavedAudioCap.ClientType)) {
// restore saved audio-only capabilities
pCall->ccRemoteAudioCaps = SavedAudioCap;
// success
return TRUE;
}
// see if we saved any video-only capabilities
if (H323IsValidClientType(SavedVideoCap.ClientType)) {
// restore saved video-only capabilities
pCall->ccRemoteVideoCaps = SavedVideoCap;
// success
return TRUE;
}
// failure
return FALSE;
}
HRESULT
H323ConnectCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_CONNECT_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for connect indications.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
DWORD dwDisconnectMode;
PH323_CHANNEL pChannel = NULL;
BOOL bRemoteVideoSupported;
DWORD dwRemoteVideoBitRate;
WORD wRemoteMaxAl_sduAudioFrames;
// validate status
if (hrConf != CC_OK) {
H323DBG((
DEBUG_LEVEL_ERROR,
"error %s (0x%08lx) connecting call 0x%08lx.\n",
H323StatusToString(hrConf), hrConf,
pCall
));
// see if we timed out
if (hrConf == MAKE_WINSOCK_ERROR(WSAETIMEDOUT)) {
// if so, report it as an unreachable destination
dwDisconnectMode = LINEDISCONNECTMODE_UNREACHABLE;
} else if (hrConf == CC_PEER_REJECT) {
// translate reject code into failure
dwDisconnectMode = H323RejectReasonToDisconnectMode(
pCallbackParams->bRejectReason
);
} else {
// default to temp failure
dwDisconnectMode = LINEDISCONNECTMODE_TEMPFAILURE;
}
// drop call using disconnect mode
H323DropCall(pCall, dwDisconnectMode);
// release line device
H323UnlockLine(pCall->pLine);
// processed
return CC_OK;
}
// send msp new call indication
H323SendNewCallIndication(pCall);
// process remote terminal capabilities
if ((pCallbackParams->pTermCapList != NULL) &&
(pCallbackParams->pTermCapDescriptors != NULL)) {
// process capabilirties
H323ProcessRemoteTermCaps(
pCall,
pCallbackParams->pTermCapList,
pCallbackParams->pTermCapDescriptors
);
}
// By this time remote capabilities have been discovered.
// Thus, we can classify the call as a 'FastLink' call, if
// both local and remote links are LAN connections; or as a
// 'SlowLink' call otherwise.
// Using this classification we then determine the length of
// the interval of audio signal to be packed into one IP
// packet.
bRemoteVideoSupported = FALSE;
// Determine remote side video bit rate, in case it
// supports video in one of the recognizable formats
switch (pCall->ccRemoteVideoCaps.ClientType)
{
case H245_CLIENT_VID_H263:
dwRemoteVideoBitRate =
pCall->ccRemoteVideoCaps.Cap.H245Vid_H263.maxBitRate;
bRemoteVideoSupported = TRUE;
break;
case H245_CLIENT_VID_H261:
dwRemoteVideoBitRate =
pCall->ccRemoteVideoCaps.Cap.H245Vid_H261.maxBitRate;
bRemoteVideoSupported = TRUE;
break;
default:
// Remote side either does not support video, or
// supports unrecognizable video format
bRemoteVideoSupported = FALSE;
break;
}
// If the remote end supports video in one of the recognizable
// formats, then we can guess, based on the remote video bit rate
// capability, whether it sits on a slow link or not.
if ( bRemoteVideoSupported
&& H323IsSlowLink(dwRemoteVideoBitRate * 100)){
// Remote end has slow link. Adjust the number of
// milliseconds of audio signal per packet.
// Note that if the local end has slow link, the
// adjustment has already been made, but there is
// no harm in resetting the number.
if (pCall->ccRemoteAudioCaps.ClientType == H245_CLIENT_AUD_G723){
// recalculate new setting
wRemoteMaxAl_sduAudioFrames =
G723_FRAMES_PER_PACKET(G723_SLOWLNK_MILLISECONDS_PER_PACKET);
// see if new setting less than current
if (wRemoteMaxAl_sduAudioFrames <
pCall->ccRemoteAudioCaps.Cap.H245Aud_G723.maxAl_sduAudioFrames){
// use new setting instead of current
pCall->ccRemoteAudioCaps.Cap.H245Aud_G723.maxAl_sduAudioFrames =
wRemoteMaxAl_sduAudioFrames;
}
}
}
// see if user user information specified
if ((pCallbackParams->pNonStandardData != NULL) &&
H323IsValidU2U(pCallbackParams->pNonStandardData)) {
// add user user info
if (H323AddU2U(
&pCall->IncomingU2U,
pCallbackParams->pNonStandardData->sData.wOctetStringLength,
pCallbackParams->pNonStandardData->sData.pOctetString
)) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"user user info available in CONNECT PDU.\n"
));
// signal incoming
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_CALLINFO,
LINECALLINFOSTATE_USERUSERINFO,
0,
0
);
} else {
H323DBG((
DEBUG_LEVEL_WARNING,
"could not save incoming user user info.\n"
));
}
}
H323DBG((
DEBUG_LEVEL_TRACE,
"call 0x%08lx connected to %S.\n",
pCall,
pCallbackParams->pszPeerDisplay
));
// no outgoing channels so connect
H323ChangeCallState(pCall, LINECALLSTATE_CONNECTED, 0);
// release line device
H323UnlockLine(pCall->pLine);
// processed
return CC_OK;
}
HRESULT
H323RingingCallback(
PH323_CALL pCall
)
/*++
Routine Description:
Callback for ringing indications.
Arguments:
pCall - Pointer to call object.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08x ringing.\n",
pCall
));
// change state to ringback
H323ChangeCallState(pCall, LINECALLSTATE_RINGBACK, 0);
// release line device
H323UnlockLine(pCall->pLine);
// processed
return CC_OK;
}
HRESULT
H323TerminationCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_CONFERENCE_TERMINATION_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for termination indications.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
DWORD dwDisconnectMode;
// validate status
if (hrConf == CC_OK) {
H323DBG((
DEBUG_LEVEL_ERROR,
"call 0x%08lx is being terminated.\n",
pCall
));
// set disconnect mode to normal
dwDisconnectMode = LINEDISCONNECTMODE_NORMAL;
} else {
H323DBG((
DEBUG_LEVEL_ERROR,
"call 0x%08lx could not be terminated.\n",
pCall
));
// unable to determine disconnect mode
dwDisconnectMode = LINEDISCONNECTMODE_UNKNOWN;
}
// change call state to disconnected before dropping call
H323ChangeCallState(pCall, LINECALLSTATE_DISCONNECTED, dwDisconnectMode);
// drop call using disconnect mode
H323DropCall(pCall, dwDisconnectMode);
// release line device
H323UnlockLine(pCall->pLine);
// processed
return CC_OK;
}
HRESULT
H323RxChannelRequestCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_RX_CHANNEL_REQUEST_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for channel request indications.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
HRESULT hr;
DWORD dwIndex;
DWORD dwRejectReason;
CC_TERMCAPLIST TermCapList;
CC_TERMCAPDESCRIPTORS TermCapDescriptors;
PCC_TERMCAP pRemoteCap;
PCC_TERMCAP pLocalCap = NULL;
PH323_CHANNEL pChannel = NULL;
PH323_CHANNEL pAssociatedChannel = NULL;
#if DBG
DWORD dwIPAddr;
#endif
// retrieve pointer to capabilities structure
pRemoteCap = pCallbackParams->pChannelCapability;
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx incoming channel:\n\t%s\n\t%s\n\t%s\n",
pCall,
H323DirToString(pRemoteCap->Dir),
H323DataTypeToString(pRemoteCap->DataType),
H323ClientTypeToString(pRemoteCap->ClientType)
));
// validate data and client type
if (!H323IsValidDataType(pRemoteCap->DataType)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"channel rejected invalid type(s).\n"
));
// initialize reject reason
dwRejectReason = H245_REJ_TYPE_UNKNOWN;
// bail...
goto reject;
}
// see whether incoming channel is available
if (H323IsVideoDataType(pRemoteCap->DataType) &&
!H323IsVideoRequested(pCall)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"channel rejected video not enabled.\n"
));
// initialize reject reason
dwRejectReason = H245_REJ_TYPE_NOTAVAIL;
// bail...
goto reject;
} else if (H323IsAudioDataType(pRemoteCap->DataType) &&
!H323IsAudioRequested(pCall)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"channel rejected audio not enabled.\n"
));
// initialize reject reason
dwRejectReason = H245_REJ_TYPE_NOTAVAIL;
// bail...
goto reject;
}
// retrieve local caps
H323GetTermCapList(pCall,&TermCapList,&TermCapDescriptors);
// search term cap list for incoming cap
for (dwIndex = 0; dwIndex < TermCapList.wLength; dwIndex++) {
// see if local cap matchs incoming channel cap
if (TermCapList.pTermCapArray[dwIndex]->ClientType ==
pRemoteCap->ClientType) {
// save pointer to termcap for later use
pLocalCap = TermCapList.pTermCapArray[dwIndex];
// done
break;
}
}
// validate termcap
if (pLocalCap == NULL) {
H323DBG((
DEBUG_LEVEL_ERROR,
"channel rejected unsupported termcap.\n"
));
// initialize reject reason
dwRejectReason = H245_REJ_TYPE_NOTSUPPORT;
// bail...
goto reject;
}
// determine client type
switch (pRemoteCap->ClientType) {
case H245_CLIENT_VID_H263:
// see if incoming bitrate too large
if (pLocalCap->Cap.H245Vid_H263.maxBitRate <
pRemoteCap->Cap.H245Vid_H263.maxBitRate) {
H323DBG((
DEBUG_LEVEL_ERROR,
"incoming H263 bitrate too large (%d bps).\n",
pRemoteCap->Cap.H245Vid_H263.maxBitRate * 100
));
// initialize reject reason
dwRejectReason = H245_REJ_BANDWIDTH;
// bail...
goto reject;
}
break;
case H245_CLIENT_VID_H261:
// see if incoming bitrate too large
if (pLocalCap->Cap.H245Vid_H261.maxBitRate <
pRemoteCap->Cap.H245Vid_H261.maxBitRate) {
H323DBG((
DEBUG_LEVEL_ERROR,
"incoming H261 bitrate too large (%d bps).\n",
pRemoteCap->Cap.H245Vid_H261.maxBitRate * 100
));
// initialize reject reason
dwRejectReason = H245_REJ_BANDWIDTH;
// bail...
goto reject;
}
break;
}
// look for existing session
H323LookupChannelBySessionID(
&pAssociatedChannel,
pCall->pChannelTable,
pCallbackParams->bSessionID
);
// allocate channel object
if (!H323AllocChannelFromTable(
&pChannel,
&pCall->pChannelTable,
pCall)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"channel rejected could not allocate.\n"
));
// initialize reject reason
dwRejectReason = H245_REJ_TYPE_UNKNOWN;
// bail...
goto reject;
}
// transfer peer rtcp address from callback parameters
// fail if the peer address was invalid
if (NULL == pCallbackParams->pPeerRTCPAddr)
{
H323DBG((
DEBUG_LEVEL_ERROR,
"channel rejected: empty peer RTCP address.\n"
));
// initialize reject reason
dwRejectReason = H245_REJ_TYPE_UNKNOWN;
// bail...
goto reject;
}
pChannel->ccRemoteRTCPAddr = *pCallbackParams->pPeerRTCPAddr;
// transfer channel information from callback parameters
pChannel->hccChannel = pCallbackParams->hChannel;
pChannel->bSessionID = pCallbackParams->bSessionID;
// transfer termcap to channel
pChannel->ccTermCaps = *pRemoteCap;
// initialize direction
pChannel->fInbound = TRUE;
// determine payload type from channel capability data type
pChannel->Settings.MediaType = H323IsVideoDataType(pRemoteCap->DataType)
? MEDIA_VIDEO
: MEDIA_AUDIO
;
// examine existing session
if (pAssociatedChannel != NULL) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"overriding default local RTCP port for session %d\n",
pChannel->bSessionID
));
// override default RTCP port with existing one
pChannel->ccLocalRTCPAddr.Addr.IP_Binary.wPort =
pAssociatedChannel->ccLocalRTCPAddr.Addr.IP_Binary.wPort;
}
// complete media stream address information
pChannel->Settings.dwIPLocal = pChannel->ccLocalRTPAddr.Addr.IP_Binary.dwAddr;
pChannel->Settings.wRTPPortLocal = pChannel->ccLocalRTPAddr.Addr.IP_Binary.wPort;
pChannel->Settings.wRTCPPortLocal = pChannel->ccLocalRTCPAddr.Addr.IP_Binary.wPort;
pChannel->Settings.dwIPRemote = pChannel->ccRemoteRTCPAddr.Addr.IP_Binary.dwAddr;
pChannel->Settings.wRTPPortRemote = 0;
pChannel->Settings.wRTCPPortRemote = pChannel->ccRemoteRTCPAddr.Addr.IP_Binary.wPort;
#if DBG
// convert local address to network order
dwIPAddr = htonl(pChannel->Settings.dwIPLocal);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming RTP stream %s:%d\n",
H323AddrToString(dwIPAddr),
pChannel->Settings.wRTPPortLocal
));
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming RTCP stream %s:%d\n",
H323AddrToString(dwIPAddr),
pChannel->Settings.wRTCPPortLocal
));
// convert remote address to network order
dwIPAddr = htonl(pChannel->Settings.dwIPRemote);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"outgoing RTCP stream %s:%d\n",
H323AddrToString(dwIPAddr),
pChannel->Settings.wRTCPPortRemote
));
#endif
// check incoming stream type
switch (pRemoteCap->ClientType) {
case H245_CLIENT_AUD_G723:
// initialize rtp payload type
pChannel->Settings.dwPayloadType = G723_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType =
(pCallbackParams->bRTPPayloadType != 0)
? (DWORD)(BYTE)(pCallbackParams->bRTPPayloadType)
: G723_RTP_PAYLOAD_TYPE
;
pChannel->Settings.Audio.dwMillisecondsPerPacket =
G723_MILLISECONDS_PER_PACKET(
pRemoteCap->Cap.H245Aud_G723.maxAl_sduAudioFrames
);
pChannel->Settings.Audio.G723Settings.bG723LowSpeed =
H323IsSlowLink(pCall->dwLinkSpeed);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming G723 stream (%d milliseconds).\n",
pChannel->Settings.Audio.dwMillisecondsPerPacket
));
break;
case H245_CLIENT_AUD_G711_ULAW64:
// complete audio information
pChannel->Settings.dwPayloadType = G711U_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType =
(pCallbackParams->bRTPPayloadType != 0)
? (DWORD)(BYTE)(pCallbackParams->bRTPPayloadType)
: G711U_RTP_PAYLOAD_TYPE
;
pChannel->Settings.Audio.dwMillisecondsPerPacket =
G711_MILLISECONDS_PER_PACKET(
pRemoteCap->Cap.H245Aud_G711_ULAW64
);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming G711U stream (%d milliseconds).\n",
pChannel->Settings.Audio.dwMillisecondsPerPacket
));
break;
case H245_CLIENT_AUD_G711_ALAW64:
// complete audio information
pChannel->Settings.dwPayloadType = G711A_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType =
(pCallbackParams->bRTPPayloadType != 0)
? (DWORD)(BYTE)(pCallbackParams->bRTPPayloadType)
: G711A_RTP_PAYLOAD_TYPE
;
pChannel->Settings.Audio.dwMillisecondsPerPacket =
G711_MILLISECONDS_PER_PACKET(
pRemoteCap->Cap.H245Aud_G711_ALAW64
);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming G711A stream (%d milliseconds).\n",
pChannel->Settings.Audio.dwMillisecondsPerPacket
));
break;
case H245_CLIENT_VID_H263:
// complete video information
pChannel->Settings.dwPayloadType = H263_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType =
(pCallbackParams->bRTPPayloadType != 0)
? (DWORD)(BYTE)(pCallbackParams->bRTPPayloadType)
: H263_RTP_PAYLOAD_TYPE
;
pChannel->Settings.Video.bCIF = FALSE;
pChannel->Settings.Video.dwMaxBitRate =
pRemoteCap->Cap.H245Vid_H263.maxBitRate * 100
;
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming H263 stream (%d bps).\n",
pChannel->Settings.Video.dwMaxBitRate
));
break;
case H245_CLIENT_VID_H261:
// complete video information
pChannel->Settings.dwPayloadType = H261_RTP_PAYLOAD_TYPE;
pChannel->Settings.dwDynamicType =
(pCallbackParams->bRTPPayloadType != 0)
? (DWORD)(BYTE)(pCallbackParams->bRTPPayloadType)
: H261_RTP_PAYLOAD_TYPE
;
pChannel->Settings.Video.bCIF = FALSE;
pChannel->Settings.Video.dwMaxBitRate =
pRemoteCap->Cap.H245Vid_H261.maxBitRate * 100
;
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming H261 stream (%d bps).\n",
pChannel->Settings.Video.dwMaxBitRate
));
break;
}
// save back pointer
pChannel->pCall = pCall;
// let msp accept incoming channel
H323SendAcceptChannelRequest(pCall, pChannel);
// release line device
H323UnlockLine(pCall->pLine);
// processed
return CC_OK;
reject:
// reject channel
CC_RejectChannel(
pCallbackParams->hChannel,
dwRejectReason
);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"call 0x%08lx incoming channel rejected.\n",
pCall
));
// release line device
H323UnlockLine(pCall->pLine);
// processed
return CC_OK;
}
HRESULT
H323RxChannelCloseCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_RX_CHANNEL_CLOSE_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for channel close indications.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
PH323_CHANNEL pChannel = NULL;
// attempt to retrieve channel
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
pCallbackParams->hChannel
)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not close unknown rx channel 0x%08lx.\n",
pCallbackParams->hChannel
));
// release line device
H323UnlockLine(pCall->pLine);
// could not find channel
return CC_NOT_IMPLEMENTED;
}
// notify msp of channel closure
H323SendCloseChannelCommand(pCall, pChannel->hmChannel,ERROR_SUCCESS);
// release memory for logical channel
H323FreeChannelFromTable(pChannel, pCall->pChannelTable);
// update media modes
H323UpdateMediaModes(pCall);
// release line device
H323UnlockLine(pCall->pLine);
// success
return CC_OK;
}
HRESULT
H323TxChannelOpenCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_TX_CHANNEL_OPEN_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for channel open indications.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
PH323_CHANNEL pChannel = NULL;
// attempt to retrieve channel
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
pCallbackParams->hChannel
)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not open unknown tx channel 0x%08lx.\n",
pCallbackParams->hChannel
));
// release line device
H323UnlockLine(pCall->pLine);
// could not find channel
return CC_NOT_IMPLEMENTED;
}
// validate status
if (hrConf != CC_OK) {
// see if peer rejected
if (hrConf == CC_PEER_REJECT) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"channel 0x%08lx rejected 0x%08lx.\n",
pChannel,
pCallbackParams->dwRejectReason
));
} else {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"channel 0x%08lx unable to be opened.\n",
pChannel
));
}
// close channel (with error)
H323SendCloseChannelCommand(pCall, pChannel->hmChannel,(DWORD)-1);
// release channel object
H323FreeChannelFromTable(pChannel,pCall->pChannelTable);
} else {
// transfer peer rtcp address from callback parameters
pChannel->ccRemoteRTPAddr = *pCallbackParams->pPeerRTPAddr;
// transfer peer rtcp address from callback parameters
pChannel->ccRemoteRTCPAddr = *pCallbackParams->pPeerRTCPAddr;
H323DBG((
DEBUG_LEVEL_VERBOSE,
"channel 0x%08lx accepted by peer.\n",
pChannel
));
// complete media stream address information
pChannel->Settings.dwIPLocal = pChannel->ccLocalRTCPAddr.Addr.IP_Binary.dwAddr;
pChannel->Settings.wRTPPortLocal = 0;
pChannel->Settings.wRTCPPortLocal = pChannel->ccLocalRTCPAddr.Addr.IP_Binary.wPort;
pChannel->Settings.dwIPRemote = pChannel->ccRemoteRTPAddr.Addr.IP_Binary.dwAddr;
pChannel->Settings.wRTPPortRemote = pChannel->ccRemoteRTPAddr.Addr.IP_Binary.wPort;
pChannel->Settings.wRTCPPortRemote = pChannel->ccRemoteRTCPAddr.Addr.IP_Binary.wPort;
#if DBG
{
DWORD dwIPAddr;
// convert local address to network order
dwIPAddr = htonl(pChannel->Settings.dwIPLocal);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming RTCP stream %s:%d\n",
H323AddrToString(dwIPAddr),
pChannel->Settings.wRTCPPortLocal
));
// convert remote address to network order
dwIPAddr = htonl(pChannel->Settings.dwIPRemote);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"outgoing RTP stream %s:%d\n",
H323AddrToString(dwIPAddr),
pChannel->Settings.wRTPPortRemote
));
H323DBG((
DEBUG_LEVEL_VERBOSE,
"outgoing RTCP stream %s:%d\n",
H323AddrToString(dwIPAddr),
pChannel->Settings.wRTCPPortRemote
));
}
#endif
// change state to opened
pChannel->nState = H323_CHANNELSTATE_OPENED;
// notify msp channel is opened
H323SendOpenChannelResponse(pCall, pChannel);
}
// update media modes
H323UpdateMediaModes(pCall);
// release line device
H323UnlockLine(pCall->pLine);
// processed
return CC_OK;
}
HRESULT
H323TxChannelCloseCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_TX_CHANNEL_CLOSE_REQUEST_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for channel close indications.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
PH323_CHANNEL pChannel = NULL;
// attempt to retrieve channel
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
pCallbackParams->hChannel
)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not close unknown tx channel 0x%08lx.\n",
pCallbackParams->hChannel
));
// release line device
H323UnlockLine(pCall->pLine);
// could not find channel
return CC_NOT_IMPLEMENTED;
}
// notify msp channel is closed
H323SendCloseChannelCommand(pCall, pChannel->hmChannel,ERROR_SUCCESS);
// release memory for logical channel
H323FreeChannelFromTable(pChannel, pCall->pChannelTable);
// update media modes
H323UpdateMediaModes(pCall);
// release line device
H323UnlockLine(pCall->pLine);
// success
return CC_OK;
}
HRESULT
H323FlowControlCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_FLOW_CONTROL_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for flow control commands.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns CC_OK.
--*/
{
PH323_CHANNEL pChannel = NULL;
// attempt to retrieve channel
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
pCallbackParams->hChannel
)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not process flow control command for channel 0x%08lx.\n",
pCallbackParams->hChannel
));
// release line device
H323UnlockLine(pCall->pLine);
// could not find channel
return CC_OK;
}
// notify msp that media stream bit rate is to be changed
H323SendFlowControlCommand(
pCall,
pChannel,
pCallbackParams->dwRate
);
// release line device
H323UnlockLine(pCall->pLine);
// success
return CC_OK;
}
HRESULT
H323VideoFastUpdatePictureCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_H245_MISCELLANEOUS_COMMAND_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for Video Fast Update Picture command (a.k.a. I-frame request command)
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns CC_OK.
--*/
{
PH323_CHANNEL pChannel = NULL;
// attempt to retrieve channel
if (!H323LookupChannelByHandle(
&pChannel,
pCall->pChannelTable,
pCallbackParams->hChannel
)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not process I-frame request cmd for channel 0x%08lx.\n",
pCallbackParams->hChannel
));
// release line device
H323UnlockLine(pCall->pLine);
// could not find channel
return CC_OK;
}
// notify msp that media stream bit rate is to be changed
H323SendVideoFastUpdatePictureCommand(
pCall,
pChannel
);
// release line device
H323UnlockLine(pCall->pLine);
// success
return CC_OK;
}
HRESULT
H245MiscellaneousCommandCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_H245_MISCELLANEOUS_COMMAND_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for miscellaneous H.245 commands.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
// retrieve command structure from incoming callback parameters
MiscellaneousCommand * pCommand = pCallbackParams->pMiscellaneousCommand;
switch (pCommand->type.choice) {
case videoFastUpdatePicture_chosen:
// process I-frame request from remote entity
return H323VideoFastUpdatePictureCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
default:
// intentionally left blank
break;
}
H323DBG((
DEBUG_LEVEL_VERBOSE,
"misc command %s ignored.\n",
H323MiscCommandToString((DWORD)(USHORT)pCommand->type.choice)
));
// release line device
H323UnlockLine(pCall->pLine);
// success
return CC_NOT_IMPLEMENTED;
}
HRESULT
H245RxNonStandardMessageCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_RX_NONSTANDARD_MESSAGE_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for miscellaneous H.245 commands.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
// validate status
if (hrConf == CC_OK) {
// validate incoming parameters
if ((pCallbackParams->bH245MessageType == CC_H245_MESSAGE_COMMAND) &&
H323IsValidU2U(&pCallbackParams->NonStandardData)) {
// add user user info
if (H323AddU2U(
&pCall->IncomingU2U,
pCallbackParams->NonStandardData.sData.wOctetStringLength,
pCallbackParams->NonStandardData.sData.pOctetString
)) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"user user info available in NONSTANDARD MESSAGE.\n"
));
// signal incoming
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_CALLINFO,
LINECALLINFOSTATE_USERUSERINFO,
0,
0
);
}
}
} else {
H323DBG((
DEBUG_LEVEL_WARNING,
"error 0x%08lx receiving non-standard message.\n",
hrConf
));
}
// release line device
H323UnlockLine(pCall->pLine);
// success
return CC_OK;
}
HRESULT
H245UserInputCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_USER_INPUT_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Callback for miscellaneous H.245 commands.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
// validate status
if (hrConf == CC_OK) {
// check monitoring mode
if (pCall->fMonitoringDigits == TRUE) {
WCHAR * pwch;
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming user input %S.\n",
pCallbackParams->pUserInput
));
// initialize string pointer
pwch = pCallbackParams->pUserInput;
// process each digit
while (*pwch != L'\0') {
// signal incoming
(*g_pfnLineEventProc)(
pCall->pLine->htLine,
pCall->htCall,
LINE_MONITORDIGITS,
(DWORD_PTR)*pwch,
LINEDIGITMODE_DTMF,
GetTickCount()
);
// next
++pwch;
}
} else {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"ignoring incoming user input message.\n"
));
}
} else {
H323DBG((
DEBUG_LEVEL_WARNING,
"error 0x%08lx receiving user input message.\n",
hrConf
));
}
// release line device
H323UnlockLine(pCall->pLine);
// success
return CC_OK;
}
HRESULT
H245T120ChannelRequestCallback(
PH323_CALL pCall,
HRESULT hrConf,
PCC_T120_CHANNEL_REQUEST_CALLBACK_PARAMS pT120RequestParams
)
/*++
Routine Description:
Callback for a T120 open channel request.
Arguments:
pCall - Pointer to call object.
hrConf - Current status of H.323 conference.
pCallbackParams - Parameters returned by call control module.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
HRESULT hr;
// validate status
if (hrConf == CC_OK) {
CC_ADDR ChannelAddr;
ChannelAddr.nAddrType = CC_IP_BINARY;
ChannelAddr.bMulticast = FALSE;
ChannelAddr.Addr.IP_Binary.wPort = g_wPortT120;
if (g_dwIPT120 != INADDR_ANY)
{
ChannelAddr.Addr.IP_Binary.dwAddr = g_dwIPT120;
}
else
{
ChannelAddr.Addr.IP_Binary.dwAddr =
H323IsCallInbound(pCall)
? pCall->ccCalleeAddr.Addr.IP_Binary.dwAddr
: pCall->ccCallerAddr.Addr.IP_Binary.dwAddr
;
}
hr = CC_AcceptT120Channel(
pT120RequestParams->hChannel,
FALSE, // BOOL bAssociateConference,
NULL, // PCC_OCTETSTRING pExternalReference,
&ChannelAddr
);
if (hr != CC_OK)
{
H323DBG((
DEBUG_LEVEL_WARNING,
"error 0x%08lx accepting T120 channel.\n",
hr
));
}
} else {
H323DBG((
DEBUG_LEVEL_WARNING,
"error 0x%08lx receiving user input message.\n",
hrConf
));
}
// release line device
H323UnlockLine(pCall->pLine);
// success
return CC_OK;
}
///////////////////////////////////////////////////////////////////////////////
// //
// Public procedures //
// //
///////////////////////////////////////////////////////////////////////////////
HRESULT
H323ConferenceCallback(
BYTE bIndication,
HRESULT hrConf,
CC_HCONFERENCE hConference,
DWORD dwConferenceToken,
PCC_CONFERENCE_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Conference callback for Intel Call Control module.
Arguments:
bIndication - indicates the reason for the callback.
hrConf - indicates the asynchronous status of the call.
hConference - conference handle associated with the callback.
dwConferenceToken - conference token specified in the CC_CreateConference().
pCallbackParams - pointer to a structure containing callback
parameters specific for the callback indication.
Return Values:
Returns either CC_OK or CC_NOT_IMPLEMENTED.
--*/
{
HRESULT hr;
HDRVCALL hdCall;
PH323_CALL pCall = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"%s %s (0x%08lx).\n",
H323IndicationToString(bIndication),
H323StatusToString((DWORD)hrConf),
hrConf
));
// retrieve call handle from token
hdCall = (HDRVCALL)dwConferenceToken;
// handle hangup indications separately
if (bIndication == CC_HANGUP_INDICATION) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"hangup confirmed (hdCall=0x%08lx).\n",
hdCall
));
// success
return CC_OK;
} else if (bIndication == CC_ACCEPT_CHANNEL_INDICATION) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"ignoring accept channel indication (hdCall=0x%08lx).\n",
hdCall
));
// success
return CC_OK;
}
// retrieve call pointer from handle
if (!H323GetCallAndLock(&pCall, hdCall)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"invalid call handle in callback.\n"
));
// need to return error
return CC_NOT_IMPLEMENTED;
}
// validate conference handle
if (pCall->hccConf != hConference) {
H323DBG((
DEBUG_LEVEL_ERROR,
"conference handle mismatch.\n"
));
// unlock line device
H323UnlockLine(pCall->pLine);
// need to return error
return CC_NOT_IMPLEMENTED;
}
// determine message
switch (bIndication) {
case CC_CONNECT_INDICATION:
// process connect indication
return H323ConnectCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_RINGING_INDICATION:
// process ringing indication
return H323RingingCallback(
pCall
);
case CC_CONFERENCE_TERMINATION_INDICATION:
// process termination indication
return H323TerminationCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_RX_CHANNEL_REQUEST_INDICATION:
// process termination indication
return H323RxChannelRequestCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_RX_CHANNEL_CLOSE_INDICATION:
// process channel close
return H323RxChannelCloseCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_TX_CHANNEL_OPEN_INDICATION:
// process channel open
return H323TxChannelOpenCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_TX_CHANNEL_CLOSE_REQUEST_INDICATION:
// process channel close
return H323TxChannelCloseCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_FLOW_CONTROL_INDICATION:
// process flow control command
return H323FlowControlCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_H245_MISCELLANEOUS_COMMAND_INDICATION:
// process miscellaneous commands
return H245MiscellaneousCommandCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_RX_NONSTANDARD_MESSAGE_INDICATION:
// process nonstandard commands
return H245RxNonStandardMessageCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_USER_INPUT_INDICATION:
// process nonstandard commands
return H245UserInputCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
case CC_T120_CHANNEL_REQUEST_INDICATION:
// process T120 channel request
return H245T120ChannelRequestCallback(
pCall,
hrConf,
(PVOID)pCallbackParams
);
}
H323DBG((
DEBUG_LEVEL_WARNING,
"conference callback indication not supported.\n"
));
// unlock line device
H323UnlockLine(pCall->pLine);
// not yet supported
return CC_NOT_IMPLEMENTED;
}
VOID
H323ListenCallback(
HRESULT hrListen,
PCC_LISTEN_CALLBACK_PARAMS pCallbackParams
)
/*++
Routine Description:
Conference callback for Intel Call Control module.
Arguments:
hrListen - indicates the asynchronous status of the call.
pCallbackParams - pointer to a structure containing callback
parameters specific for the callback indication.
Return Values:
None.
--*/
{
HRESULT hr;
HDRVLINE hdLine;
PH323_LINE pLine = NULL;
PH323_CALL pCall = NULL;
H323DBG((
DEBUG_LEVEL_TRACE,
"INCOMING CALL %s (0x%08lx).\n",
H323StatusToString(hrListen),
hrListen
));
// retrieve line handle from token
hdLine = (HDRVLINE)pCallbackParams->dwListenToken;
// retrieve line pointer from handle
if (!H323GetLineAndLock(&pLine, hdLine)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"invalid line handle in listen callback.\n"
));
// failure
return ;
}
// validate status
if (hrListen != CC_OK) {
// check for active call
if (H323GetCallByHCall(
&pCall,
pLine,
pCallbackParams->hCall)) {
// drop offering call
H323DropCall(pCall,LINEDISCONNECTMODE_CANCELLED);
}
// release line device
H323UnlockLine(pLine);
// done
return;
}
H323DBG((
DEBUG_LEVEL_TRACE,
"line %d receiving call request from %S.\n",
pLine->dwDeviceID,
pCallbackParams->pszDisplay
));
// allocate outgoing call from line call table
if (!H323AllocCallFromTable(&pCall,&pLine->pCallTable,pLine)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not allocate call object.\n"
));
// release line device
H323UnlockLine(pLine);
// failure
return;
}
// save back pointer
pCall->pLine = pLine;
// clear incoming modes
pCall->dwIncomingModes = 0;
// outgoing modes will be finalized during H.245 phase
pCall->dwOutgoingModes = pLine->dwMediaModes | LINEMEDIAMODE_UNKNOWN;
// save media modes specified
pCall->dwRequestedModes = pLine->dwMediaModes;
// specify incoming call direction
pCall->dwOrigin = LINECALLORIGIN_INBOUND;
// save incoming call handle
pCall->hccCall = pCallbackParams->hCall;
// save caller transport address
pCall->ccCallerAddr = *pCallbackParams->pCallerAddr;
// save callee transport address
pCall->ccCalleeAddr = *pCallbackParams->pCalleeAddr;
#if DBG
{
DWORD dwIPAddr;
// retrieve ip address in network byte order
dwIPAddr = htonl(pCall->ccCalleeAddr.Addr.IP_Binary.dwAddr);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"callee address resolved to %s.\n",
H323AddrToString(dwIPAddr)
));
// retrieve ip address in network byte order
dwIPAddr = htonl(pCall->ccCallerAddr.Addr.IP_Binary.dwAddr);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"caller address resolved to %s.\n",
H323AddrToString(dwIPAddr)
));
}
#endif
// determine link speed for local interface
pCall->dwLinkSpeed = H323DetermineLinkSpeed(
pCall->ccCalleeAddr.Addr.IP_Binary.dwAddr
);
// bind incoming call
if (!H323BindCall(pCall,NULL)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not bind call object.\n"
));
// failure
goto cleanup;
}
// see if caller alias was specified
if ((pCallbackParams->pCallerAliasNames != NULL) &&
(pCallbackParams->pCallerAliasNames->wCount > 0)) {
PCC_ALIASITEM pCallerAlias;
// retrieve pointer to caller alias
pCallerAlias = pCallbackParams->pCallerAliasNames->pItems;
// validate alias type
if ((pCallerAlias->wDataLength > 0) &&
((pCallerAlias->wType == CC_ALIAS_H323_ID) ||
(pCallerAlias->wType == CC_ALIAS_H323_PHONE))) {
// initialize alias
pCall->ccCallerAlias.wType = pCallerAlias->wType;
pCall->ccCallerAlias.wDataLength = pCallerAlias->wDataLength;
pCall->ccCallerAlias.wPrefixLength = 0;
pCall->ccCallerAlias.pPrefix = NULL;
// allocate memory for caller string
pCall->ccCallerAlias.pData = H323HeapAlloc(
(pCallerAlias->wDataLength + 1) * sizeof(WCHAR)
);
// validate pointer
if (pCall->ccCallerAlias.pData == NULL) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not allocate caller name.\n"
));
// failure
goto cleanup;
}
// transfer string information
memcpy(pCall->ccCallerAlias.pData,
pCallerAlias->pData,
pCallerAlias->wDataLength * sizeof(WCHAR)
);
// terminate incoming string
pCall->ccCallerAlias.pData[pCallerAlias->wDataLength] = L'\0';
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming caller alias is %S.\n",
pCall->ccCallerAlias.pData
));
}
}
// see if callee alias was specified
if ((pCallbackParams->pCalleeAliasNames != NULL) &&
(pCallbackParams->pCalleeAliasNames->wCount > 0)) {
PCC_ALIASITEM pCalleeAlias;
// retrieve pointer to callee alias
pCalleeAlias = pCallbackParams->pCalleeAliasNames->pItems;
// validate alias type
if ((pCalleeAlias->wDataLength > 0) &&
((pCalleeAlias->wType == CC_ALIAS_H323_ID) ||
(pCalleeAlias->wType == CC_ALIAS_H323_PHONE))) {
// initialize alias
pCall->ccCalleeAlias.wType = pCalleeAlias->wType;
pCall->ccCalleeAlias.wDataLength = pCalleeAlias->wDataLength;
pCall->ccCalleeAlias.wPrefixLength = 0;
pCall->ccCalleeAlias.pPrefix = NULL;
// allocate memory for caller string
pCall->ccCalleeAlias.pData = H323HeapAlloc(
(pCalleeAlias->wDataLength + 1) * sizeof(WCHAR)
);
// validate pointer
if (pCall->ccCalleeAlias.pData == NULL) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not allocate callee name.\n"
));
// failure
goto cleanup;
}
// transfer string information
memcpy(pCall->ccCalleeAlias.pData,
pCalleeAlias->pData,
pCalleeAlias->wDataLength * sizeof(WCHAR)
);
// terminate incoming string
pCall->ccCalleeAlias.pData[pCalleeAlias->wDataLength] = L'\0';
H323DBG((
DEBUG_LEVEL_VERBOSE,
"incoming callee alias is %S.\n",
pCall->ccCalleeAlias.pData
));
}
}
// validate user user info specified
if ((pCallbackParams->pNonStandardData != NULL) &&
H323IsValidU2U(pCallbackParams->pNonStandardData)) {
// add user user info
if (!H323AddU2U(
&pCall->IncomingU2U,
pCallbackParams->pNonStandardData->sData.wOctetStringLength,
pCallbackParams->pNonStandardData->sData.pOctetString
)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not save incoming user user info.\n"
));
// failure
goto cleanup;
}
}
// signal incoming call
(*g_pfnLineEventProc)(
pLine->htLine,
(HTAPICALL)NULL,
LINE_NEWCALL,
(DWORD_PTR)pCall->hdCall,
(DWORD_PTR)&pCall->htCall,
0
);
// see if user user info specified
if (!IsListEmpty(&pCall->IncomingU2U)) {
H323DBG((
DEBUG_LEVEL_VERBOSE,
"user user info available in SETUP PDU.\n"
));
// signal incoming
(*g_pfnLineEventProc)(
pLine->htLine,
pCall->htCall,
LINE_CALLINFO,
LINECALLINFOSTATE_USERUSERINFO,
0,
0
);
}
// change state to offering
H323ChangeCallState(pCall, LINECALLSTATE_OFFERING, 0);
// release line device
H323UnlockLine(pLine);
// success
return;
cleanup:
// unbind call
H323UnbindCall(pCall);
// release outgoing call from line call table
H323FreeCallFromTable(pCall,pLine->pCallTable);
// release line device
H323UnlockLine(pLine);
// failure
return;
}
BOOL
H323StartCallbackThread(
)
/*++
Routine Description:
Creates thread which handles async processing.
Arguments:
None.
Return Values:
Returns true if successful.
--*/
{
// transfer registry key change event to waitable object array
g_WaitableObjects[WAIT_OBJECT_REGISTRY_CHANGE] = CreateEvent(
NULL, // lpEventAttributes
FALSE, // bManualReset
FALSE, // bInitialState
NULL // lpName
);
// transfer termination event to waitable object array
g_WaitableObjects[WAIT_OBJECT_TERMINATE_EVENT] = CreateEvent(
NULL, // lpEventAttributes
TRUE, // bManualReset
FALSE, // bInitialState
NULL // lpName
);
// validate waitable object handles
if ((g_WaitableObjects[WAIT_OBJECT_REGISTRY_CHANGE] == NULL) ||
(g_WaitableObjects[WAIT_OBJECT_TERMINATE_EVENT] == NULL)) {
H323DBG((
DEBUG_LEVEL_ERROR,
"could not allocate waitable objects.\n"
));
// cleanup resources
H323StopCallbackThread();
// failure
return FALSE;
}
// attempt to start thread
g_hCallbackThread = CreateThread(
NULL, // lpThreadAttributes
0, // dwStackSize
H323CallbackThread,
NULL, // lpParameter
0, // dwCreationFlags
&g_dwCallbackThreadID
);
// validate thread handle
if (g_hCallbackThread == NULL) {
H323DBG((
DEBUG_LEVEL_ERROR,
"error 0x%08lx creating callback thread.\n",
GetLastError()
));
// cleanup resources
H323StopCallbackThread();
// failure
return FALSE;
}
H323DBG((
DEBUG_LEVEL_VERBOSE,
"callback thread %x started.\n",
g_dwCallbackThreadID
));
// success
return TRUE;
}
BOOL
H323StopCallbackThread(
)
/*++
Routine Description:
Destroys thread which handles async processing.
Arguments:
None.
Return Values:
Returns true if successful.
--*/
{
HRESULT hr;
DWORD dwStatus;
// validate thread handle
if (g_hCallbackThread != NULL) {
// signal termination event
SetEvent(g_WaitableObjects[WAIT_OBJECT_TERMINATE_EVENT]);
H323DBG((
DEBUG_LEVEL_VERBOSE,
"callback thread %x stopping.\n",
g_dwCallbackThreadID
));
// unlock temporarily
H323UnlockProvider();
// wait for callback thread to terminate
dwStatus = WaitForSingleObject(g_hCallbackThread, INFINITE);
// relock provider
H323LockProvider();
H323DBG((
DEBUG_LEVEL_VERBOSE,
"callback thread %x stopped (dwStatus=0x%08lx).\n",
g_dwCallbackThreadID,
dwStatus
));
// close thread handle
CloseHandle(g_hCallbackThread);
// re-initialize callback thread id
g_dwCallbackThreadID = UNINITIALIZED;
g_hCallbackThread = NULL;
}
// validate waitable object handle
if (g_WaitableObjects[WAIT_OBJECT_REGISTRY_CHANGE] != NULL) {
// release waitable object handle
CloseHandle(g_WaitableObjects[WAIT_OBJECT_REGISTRY_CHANGE]);
// re-initialize waitable object handle
g_WaitableObjects[WAIT_OBJECT_REGISTRY_CHANGE] = NULL;
}
// validate waitable object handle
if (g_WaitableObjects[WAIT_OBJECT_TERMINATE_EVENT] != NULL) {
// release waitable object handle
CloseHandle(g_WaitableObjects[WAIT_OBJECT_TERMINATE_EVENT]);
// re-initialize waitable object handle
g_WaitableObjects[WAIT_OBJECT_TERMINATE_EVENT] = NULL;
}
// success
return TRUE;
}