windows-nt/Source/XPSP1/NT/multimedia/directx/dplay/dpnathlp/dpnhupnp/upnpdevice.h

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2020-09-26 03:20:57 -05:00
/***************************************************************************
*
* Copyright (C) 2001-2002 Microsoft Corporation. All Rights Reserved.
*
* File: upnpdevice.h
*
* Content: Header for UPnP device object class.
*
* History:
* Date By Reason
* ======== ======== =========
* 02/10/01 VanceO Created.
*
***************************************************************************/
//=============================================================================
// Defines
//=============================================================================
#define MAX_RECEIVE_BUFFER_SIZE (100 * 1024) // 100 K, must be greater than UPNP_STREAM_RECV_BUFFER_INITIAL_SIZE
//=============================================================================
// Object flags
//=============================================================================
#define UPNPDEVICE_WANPPPCONNECTION 0x01 // flag set if the device is a WANPPPConnection device, not set if it is a WANIPConnection device
#define UPNPDEVICE_CONNECTING 0x02 // flag set while the TCP connection is in progress
#define UPNPDEVICE_CONNECTED 0x04 // flag set once the TCP connection has been established
#define UPNPDEVICE_READY 0x08 // flag set once the device is capable of being used
#define UPNPDEVICE_WAITINGFORCONTROLRESPONSE 0x10 // flag set if some function is waiting for a control response
#define UPNPDEVICE_DOESNOTSUPPORTASYMMETRICMAPPINGS 0x20 // flag set when the device has indicated it does not support asymmetric mappings
#define UPNPDEVICE_DOESNOTSUPPORTLEASEDURATIONS 0x40 // flag set when the device has indicated it does not support non-INFINITE lease durations
#define UPNPDEVICE_USINGCHUNKEDTRANSFERENCODING 0x80 // flag set when device is sending current response using chunked transfer encoding
//=============================================================================
// Macros
//=============================================================================
#define UPNPDEVICE_FROM_BILINK(b) (CONTAINING_OBJECT(b, CUPnPDevice, m_blList))
//=============================================================================
// Enums
//=============================================================================
//
// UPnP expected control response enum
//
typedef enum _CONTROLRESPONSETYPE
{
CONTROLRESPONSETYPE_NONE, // no handler
//CONTROLRESPONSETYPE_QUERYSTATEVARIABLE_EXTERNALIPADDRESS, // use the ExternalIPAddress QueryStateVariable handler
CONTROLRESPONSETYPE_GETEXTERNALIPADDRESS, // use the GetExternalIPAddress handler
CONTROLRESPONSETYPE_ADDPORTMAPPING, // use the AddPortMapping handler
CONTROLRESPONSETYPE_GETSPECIFICPORTMAPPINGENTRY, // use the GetSpecificPortMappingEntry handler
CONTROLRESPONSETYPE_DELETEPORTMAPPING // use the DeletePortMapping handler
} CONTROLRESPONSETYPE;
//=============================================================================
// Structures
//=============================================================================
typedef struct _UPNP_CONTROLRESPONSE_INFO
{
HRESULT hrErrorCode; // error code returned by server
DWORD dwInternalClientV4; // internal client address returned by server
WORD wInternalPort; // internal client port returned by server
DWORD dwExternalIPAddressV4; // external IP address returned by server
} UPNP_CONTROLRESPONSE_INFO, * PUPNP_CONTROLRESPONSE_INFO;
//=============================================================================
// UPnP device object class
//=============================================================================
class CUPnPDevice
{
public:
CUPnPDevice(const DWORD dwID)
{
this->m_blList.Initialize();
this->m_Sig[0] = 'U';
this->m_Sig[1] = 'P';
this->m_Sig[2] = 'D';
this->m_Sig[3] = 'V';
this->m_lRefCount = 1; // whoever got a pointer to this has a reference
this->m_dwFlags = 0;
this->m_dwID = dwID;
this->m_pOwningDevice = NULL;
this->m_pszLocationURL = NULL;
ZeroMemory(&this->m_saddrinHost, sizeof(this->m_saddrinHost));
ZeroMemory(&this->m_saddrinControl, sizeof(this->m_saddrinControl));
this->m_pszUSN = NULL;
this->m_pszServiceControlURL = NULL;
this->m_sControl = INVALID_SOCKET;
this->m_pcReceiveBuffer = NULL;
this->m_dwReceiveBufferSize = 0;
this->m_pcReceiveBufferStart = NULL;
this->m_dwUsedReceiveBufferSize = 0;
this->m_dwRemainingReceiveBufferSize = 0;
this->m_dwExternalIPAddressV4 = 0;
this->m_blCachedMaps.Initialize();
this->m_dwExpectedContentLength = 0;
this->m_dwHTTPResponseCode = 0;
this->m_ControlResponseType = CONTROLRESPONSETYPE_NONE;
this->m_pControlResponseInfo = NULL;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::~CUPnPDevice"
~CUPnPDevice(void)
{
DNASSERT(this->m_blList.IsEmpty());
DNASSERT(this->m_lRefCount == 0);
DNASSERT(this->m_pOwningDevice == NULL);
DNASSERT(this->m_pszLocationURL == NULL);
DNASSERT(this->m_pszUSN == NULL);
DNASSERT(this->m_pszServiceControlURL == NULL);
DNASSERT(this->m_sControl == INVALID_SOCKET);
DNASSERT(this->m_pcReceiveBuffer == NULL);
DNASSERT(this->m_blCachedMaps.IsEmpty());
DNASSERT(this->m_ControlResponseType == CONTROLRESPONSETYPE_NONE);
DNASSERT(this->m_pControlResponseInfo == NULL);
};
inline void AddRef(void) { this->m_lRefCount++; };
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::DecRef"
inline void DecRef(void)
{
this->m_lRefCount--;
DNASSERT(this->m_lRefCount >= 0);
if (this->m_lRefCount == 0)
{
delete this;
}
};
inline BOOL IsWANPPPConnection(void) const { return ((this->m_dwFlags & UPNPDEVICE_WANPPPCONNECTION) ? TRUE : FALSE); };
inline BOOL IsConnecting(void) const { return ((this->m_dwFlags & UPNPDEVICE_CONNECTING) ? TRUE : FALSE); };
inline BOOL IsConnected(void) const { return ((this->m_dwFlags & UPNPDEVICE_CONNECTED) ? TRUE : FALSE); };
inline BOOL IsReady(void) const { return ((this->m_dwFlags & UPNPDEVICE_READY) ? TRUE : FALSE); };
inline BOOL DoesNotSupportAsymmetricMappings(void) const { return ((this->m_dwFlags & UPNPDEVICE_DOESNOTSUPPORTASYMMETRICMAPPINGS) ? TRUE : FALSE); };
inline BOOL DoesNotSupportLeaseDurations(void) const { return ((this->m_dwFlags & UPNPDEVICE_DOESNOTSUPPORTLEASEDURATIONS) ? TRUE : FALSE); };
inline BOOL IsUsingChunkedTransferEncoding(void) const { return ((this->m_dwFlags & UPNPDEVICE_USINGCHUNKEDTRANSFERENCODING) ? TRUE : FALSE); };
inline DWORD GetID(void) const { return this->m_dwID; };
inline const char * GetStaticServiceURI(void) const { return ((this->m_dwFlags & UPNPDEVICE_WANPPPCONNECTION) ? URI_SERVICE_WANPPPCONNECTION_A : URI_SERVICE_WANIPCONNECTION_A); };
inline int GetStaticServiceURILength(void) const { return ((this->m_dwFlags & UPNPDEVICE_WANPPPCONNECTION) ? strlen(URI_SERVICE_WANPPPCONNECTION_A) : strlen(URI_SERVICE_WANIPCONNECTION_A)); };
inline SOCKADDR_IN * GetHostAddress(void) { return &this->m_saddrinHost; };
inline SOCKADDR_IN * GetControlAddress(void) { return &this->m_saddrinControl; };
inline SOCKET GetControlSocket(void) const { return this->m_sControl; };
inline DWORD GetExternalIPAddressV4(void) const { return this->m_dwExternalIPAddressV4; };
inline CBilink * GetCachedMaps(void) { return &this->m_blCachedMaps; };
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteWANPPPConnection"
inline void NoteWANPPPConnection(void)
{
DNASSERT(! (this->m_dwFlags & UPNPDEVICE_WANPPPCONNECTION));
this->m_dwFlags |= UPNPDEVICE_WANPPPCONNECTION;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteConnecting"
inline void NoteConnecting(void)
{
DNASSERT(! (this->m_dwFlags & (UPNPDEVICE_CONNECTING | UPNPDEVICE_CONNECTED)));
this->m_dwFlags |= UPNPDEVICE_CONNECTING;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteConnected"
inline void NoteConnected(void)
{
DNASSERT(this->m_dwFlags & UPNPDEVICE_CONNECTING);
DNASSERT(! (this->m_dwFlags & UPNPDEVICE_CONNECTED));
this->m_dwFlags &= ~UPNPDEVICE_CONNECTING;
this->m_dwFlags |= UPNPDEVICE_CONNECTED;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteNotConnected"
inline void NoteNotConnected(void)
{
DNASSERT(this->m_dwFlags & UPNPDEVICE_CONNECTED);
this->m_dwFlags &= ~UPNPDEVICE_CONNECTED;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteReady"
inline void NoteReady(void)
{
DNASSERT(! (this->m_dwFlags & UPNPDEVICE_READY));
this->m_dwFlags |= UPNPDEVICE_READY;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteDoesNotSupportAsymmetricMappings"
inline void NoteDoesNotSupportAsymmetricMappings(void)
{
DNASSERT(! (this->m_dwFlags & UPNPDEVICE_DOESNOTSUPPORTASYMMETRICMAPPINGS));
this->m_dwFlags |= UPNPDEVICE_DOESNOTSUPPORTASYMMETRICMAPPINGS;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteDoesNotSupportLeaseDurations"
inline void NoteDoesNotSupportLeaseDurations(void)
{
DNASSERT(! (this->m_dwFlags & UPNPDEVICE_DOESNOTSUPPORTLEASEDURATIONS));
this->m_dwFlags |= UPNPDEVICE_DOESNOTSUPPORTLEASEDURATIONS;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteUsingChunkedTransferEncoding"
inline void NoteUsingChunkedTransferEncoding(void)
{
DNASSERT(! (this->m_dwFlags & UPNPDEVICE_USINGCHUNKEDTRANSFERENCODING));
this->m_dwFlags |= UPNPDEVICE_USINGCHUNKEDTRANSFERENCODING;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteNotUsingChunkedTransferEncoding"
inline void NoteNotUsingChunkedTransferEncoding(void)
{
DNASSERT(this->m_dwFlags & UPNPDEVICE_USINGCHUNKEDTRANSFERENCODING);
this->m_dwFlags &= ~UPNPDEVICE_USINGCHUNKEDTRANSFERENCODING;
};
inline void SetHostAddress(SOCKADDR_IN * psaddrinHost)
{
CopyMemory(&this->m_saddrinHost, psaddrinHost, sizeof(this->m_saddrinHost));
};
inline void SetControlAddress(SOCKADDR_IN * psaddrinControl)
{
CopyMemory(&this->m_saddrinControl, psaddrinControl, sizeof(this->m_saddrinControl));
};
inline BOOL IsLocal(void) const { return ((this->m_saddrinControl.sin_addr.S_un.S_addr == this->m_pOwningDevice->GetLocalAddressV4()) ? TRUE : FALSE); };
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::SetLocationURL"
inline HRESULT SetLocationURL(const char * const szLocationURL)
{
DNASSERT(this->m_pszLocationURL == NULL);
this->m_pszLocationURL = (char*) DNMalloc((strlen(szLocationURL) + 1) * sizeof(char));
if (this->m_pszLocationURL == NULL)
{
return DPNHERR_OUTOFMEMORY;
}
strcpy(this->m_pszLocationURL, szLocationURL);
return DPNH_OK;
};
inline char * GetLocationURL(void) { return this->m_pszLocationURL; };
inline void ClearLocationURL(void)
{
if (this->m_pszLocationURL != NULL)
{
DNFree(this->m_pszLocationURL);
this->m_pszLocationURL = NULL;
}
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::SetUSN"
inline HRESULT SetUSN(const char * const szUSN)
{
DNASSERT(this->m_pszUSN == NULL);
this->m_pszUSN = (char*) DNMalloc((strlen(szUSN) + 1) * sizeof(char));
if (this->m_pszUSN == NULL)
{
return DPNHERR_OUTOFMEMORY;
}
strcpy(this->m_pszUSN, szUSN);
return DPNH_OK;
};
inline char * GetUSN(void) { return this->m_pszUSN; };
inline void ClearUSN(void)
{
if (this->m_pszUSN != NULL)
{
DNFree(this->m_pszUSN);
this->m_pszUSN = NULL;
}
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::SetServiceControlURL"
inline HRESULT SetServiceControlURL(const char * const szServiceControlURL)
{
DNASSERT(this->m_pszServiceControlURL == NULL);
this->m_pszServiceControlURL = (char*) DNMalloc((strlen(szServiceControlURL) + 1) * sizeof(char));
if (this->m_pszServiceControlURL == NULL)
{
return DPNHERR_OUTOFMEMORY;
}
strcpy(this->m_pszServiceControlURL, szServiceControlURL);
return DPNH_OK;
};
inline char * GetServiceControlURL(void) { return this->m_pszServiceControlURL; };
inline void ClearServiceControlURL(void)
{
if (this->m_pszServiceControlURL != NULL)
{
DNFree(this->m_pszServiceControlURL);
this->m_pszServiceControlURL = NULL;
}
};
inline void SetControlSocket(SOCKET sControl) { this->m_sControl = sControl; };
//
// You must have global object lock to call this function.
//
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::MakeDeviceOwner"
inline void MakeDeviceOwner(CDevice * const pDevice)
{
DNASSERT(pDevice != NULL);
DNASSERT(pDevice->GetUPnPDevice() == NULL);
DNASSERT(this->m_pOwningDevice == NULL);
this->m_pOwningDevice = pDevice;
this->AddRef();
pDevice->SetUPnPDevice(this);
};
//
// You must have global object lock to call this function.
//
inline CDevice * GetOwningDevice(void) { return this->m_pOwningDevice; };
//
// You must have global object lock to call this function.
//
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::ClearDeviceOwner"
inline void ClearDeviceOwner(void)
{
DNASSERT(this->m_pOwningDevice != NULL);
DNASSERT(this->m_pOwningDevice->GetUPnPDevice() == this);
this->m_pOwningDevice->SetUPnPDevice(NULL);
this->m_pOwningDevice = NULL;
this->DecRef();
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::CreateReceiveBuffer"
inline HRESULT CreateReceiveBuffer(const DWORD dwSize)
{
DNASSERT(this->m_pcReceiveBuffer == NULL);
this->m_pcReceiveBuffer = (char*) DNMalloc(dwSize);
if (this->m_pcReceiveBuffer == NULL)
{
return DPNHERR_OUTOFMEMORY;
}
this->m_dwReceiveBufferSize = dwSize;
this->m_pcReceiveBufferStart = this->m_pcReceiveBuffer;
this->m_dwRemainingReceiveBufferSize = dwSize;
return DPNH_OK;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::IncreaseReceiveBufferSize"
inline HRESULT IncreaseReceiveBufferSize(void)
{
DWORD dwNewBufferSize;
char * pcTemp;
DNASSERT(this->m_pcReceiveBuffer != NULL);
//
// Double the buffer size. Don't let the receive buffer get to
// unrealistic sizes to prevent DoS/resource issues, cap the buffer
// size, and if we've already reached that limit, fail.
//
dwNewBufferSize = this->m_dwReceiveBufferSize * 2;
if (dwNewBufferSize > MAX_RECEIVE_BUFFER_SIZE)
{
dwNewBufferSize = MAX_RECEIVE_BUFFER_SIZE;
if (dwNewBufferSize <= this->m_dwReceiveBufferSize)
{
DPFX(DPFPREP, 0, "Maximum buffer size reached (%u bytes), not allocating more room!",
this->m_dwReceiveBufferSize);
return DPNHERR_OUTOFMEMORY;
}
}
pcTemp = (char*) DNMalloc(dwNewBufferSize);
if (pcTemp == NULL)
{
return DPNHERR_OUTOFMEMORY;
}
//
// If the buffer already had data in it, copy it. The data may not
// have come from the front of the old buffer, but it will
// definitely be the front of the new one.
//
if (this->m_dwUsedReceiveBufferSize > 0)
{
CopyMemory(pcTemp, this->m_pcReceiveBufferStart,
this->m_dwUsedReceiveBufferSize);
}
DNFree(this->m_pcReceiveBuffer);
this->m_pcReceiveBuffer = NULL;
this->m_pcReceiveBuffer = pcTemp;
this->m_dwReceiveBufferSize = dwNewBufferSize;
//
// The buffer now starts at the beginning of the allocated memory
// (we may have just freed up a bunch of wasted space).
//
this->m_pcReceiveBufferStart = this->m_pcReceiveBuffer;
this->m_dwRemainingReceiveBufferSize = this->m_dwReceiveBufferSize - this->m_dwUsedReceiveBufferSize;
return DPNH_OK;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::UpdateUsedReceiveBufferSize"
inline void UpdateUsedReceiveBufferSize(const DWORD dwAdditionalSizeUsed)
{
DNASSERT(dwAdditionalSizeUsed <= this->m_dwRemainingReceiveBufferSize);
DNASSERT((this->m_dwUsedReceiveBufferSize + dwAdditionalSizeUsed) <= this->m_dwReceiveBufferSize);
this->m_dwUsedReceiveBufferSize += dwAdditionalSizeUsed;
this->m_dwRemainingReceiveBufferSize -= dwAdditionalSizeUsed;
};
inline void ClearReceiveBuffer(void)
{
this->m_pcReceiveBufferStart = this->m_pcReceiveBuffer;
this->m_dwUsedReceiveBufferSize = 0;
this->m_dwRemainingReceiveBufferSize = this->m_dwReceiveBufferSize;
};
inline char * GetReceiveBufferStart(void) { return this->m_pcReceiveBufferStart; };
inline char * GetCurrentReceiveBufferPtr(void) { return (this->m_pcReceiveBufferStart + this->m_dwUsedReceiveBufferSize); };
inline DWORD GetUsedReceiveBufferSize(void) const { return this->m_dwUsedReceiveBufferSize; };
inline DWORD GetRemainingReceiveBufferSize(void) const { return this->m_dwRemainingReceiveBufferSize; };
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::UpdateReceiveBufferStart"
inline void UpdateReceiveBufferStart(char * pszNewStart)
{
DNASSERT(pszNewStart > this->m_pcReceiveBufferStart);
DNASSERT((DWORD) ((DWORD_PTR) (pszNewStart - this->m_pcReceiveBufferStart)) < this->m_dwRemainingReceiveBufferSize);
this->m_dwUsedReceiveBufferSize -= (DWORD) ((DWORD_PTR) (pszNewStart - this->m_pcReceiveBufferStart));
this->m_pcReceiveBufferStart = pszNewStart;
};
inline void DestroyReceiveBuffer(void)
{
if (this->m_pcReceiveBuffer != NULL)
{
DNFree(this->m_pcReceiveBuffer);
this->m_pcReceiveBuffer = NULL;
this->m_dwReceiveBufferSize = 0;
this->m_pcReceiveBufferStart = NULL;
this->m_dwUsedReceiveBufferSize = 0;
this->m_dwRemainingReceiveBufferSize = 0;
}
};
inline void SetExternalIPAddressV4(const DWORD dwExternalIPAddressV4)
{
this->m_dwExternalIPAddressV4 = dwExternalIPAddressV4;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::RemoveAllCachedMappings"
inline void RemoveAllCachedMappings(void)
{
CBilink * pCachedMaps;
CBilink * pBilink;
CCacheMap * pCacheMap;
pCachedMaps = this->GetCachedMaps();
pBilink = pCachedMaps->GetNext();
while (pBilink != pCachedMaps)
{
DNASSERT(! pBilink->IsEmpty());
pCacheMap = CACHEMAP_FROM_BILINK(pBilink);
pBilink = pBilink->GetNext();
DPFX(DPFPREP, 5, "Removing UPnP device 0x%p cached mapping 0x%p.",
this, pCacheMap);
pCacheMap->m_blList.RemoveFromList();
delete pCacheMap;
}
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteWaitingForContent"
inline void NoteWaitingForContent(const DWORD dwContentLength, const DWORD dwHTTPResponseCode)
{
DNASSERT(this->m_dwExpectedContentLength == 0);
this->m_dwExpectedContentLength = dwContentLength;
this->m_dwHTTPResponseCode = dwHTTPResponseCode;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::NoteNotWaitingForContent"
inline void NoteNotWaitingForContent(void)
{
DNASSERT(this->m_dwExpectedContentLength != 0);
this->m_dwExpectedContentLength = 0;
this->m_dwHTTPResponseCode = 0;
};
inline BOOL IsWaitingForContent(void) const { return ((this->m_dwExpectedContentLength != 0) ? TRUE : FALSE); };
inline DWORD GetExpectedContentSize(void) const { return this->m_dwExpectedContentLength; };
inline DWORD GetHTTPResponseCode(void) const { return this->m_dwHTTPResponseCode; };
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::StartWaitingForControlResponse"
inline void StartWaitingForControlResponse(CONTROLRESPONSETYPE ControlResponseType,
PUPNP_CONTROLRESPONSE_INFO pControlResponseInfo)
{
DNASSERT(ControlResponseType != CONTROLRESPONSETYPE_NONE);
DNASSERT(! (this->m_dwFlags & UPNPDEVICE_WAITINGFORCONTROLRESPONSE));
this->m_dwFlags |= UPNPDEVICE_WAITINGFORCONTROLRESPONSE;
this->m_ControlResponseType = ControlResponseType;
this->m_pControlResponseInfo = pControlResponseInfo;
};
#undef DPF_MODNAME
#define DPF_MODNAME "CUPnPDevice::StopWaitingForControlResponse"
inline void StopWaitingForControlResponse(void)
{
this->m_dwFlags &= ~UPNPDEVICE_WAITINGFORCONTROLRESPONSE;
this->m_ControlResponseType = CONTROLRESPONSETYPE_NONE;
this->m_pControlResponseInfo = NULL;
};
inline BOOL IsWaitingForControlResponse(void) const { return ((this->m_dwFlags & UPNPDEVICE_WAITINGFORCONTROLRESPONSE) ? TRUE : FALSE); };
inline CONTROLRESPONSETYPE GetControlResponseType(void) const { return this->m_ControlResponseType; };
inline PUPNP_CONTROLRESPONSE_INFO GetControlResponseInfo(void) { return this->m_pControlResponseInfo; };
CBilink m_blList; // list of all the UPnP devices known
private:
BYTE m_Sig[4]; // debugging signature ('UPDV')
LONG m_lRefCount; // reference count for this object
DWORD m_dwFlags; // flags indicating current state of UPnP device
DWORD m_dwID; // unique identifier used to correlate crash registry entries with UPnP devices
CDevice * m_pOwningDevice; // pointer to owning device object
char * m_pszLocationURL; // control location URL string
SOCKADDR_IN m_saddrinHost; // UPnP device host address
SOCKADDR_IN m_saddrinControl; // UPnP device control address
char * m_pszUSN; // device's Unique Service Name
char * m_pszServiceControlURL; // URL used to control WANIPConnectionService
SOCKET m_sControl; // TCP socket with connection to the UPnP device
char * m_pcReceiveBuffer; // pointer to receive buffer
DWORD m_dwReceiveBufferSize; // size of receive buffer
char * m_pcReceiveBufferStart; // pointer to start of actual data in receive buffer (anything before this is just wasted space)
DWORD m_dwUsedReceiveBufferSize; // size of receive buffer actually filled with data (beginning at m_pcReceiveBufferStart)
DWORD m_dwRemainingReceiveBufferSize; // size of receive buffer that can hold more data (after m_pcReceiveBufferStart + m_dwUsedReceiveBufferSize)
DWORD m_dwExternalIPAddressV4; // IP v4 external IP address of this UPnP device
CBilink m_blCachedMaps; // list of cached mappings for query addresses performed on this UPnP device
DWORD m_dwExpectedContentLength; // expected size of message content, or 0 if no headers have been read
DWORD m_dwHTTPResponseCode; // HTTP response code previously parsed, if waiting for content
CONTROLRESPONSETYPE m_ControlResponseType; // type of response expected
PUPNP_CONTROLRESPONSE_INFO m_pControlResponseInfo; // place to store info from a received response
};