Source code of Windows XP (NT5)
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
 
 
 
 
 
 

586 lines
17 KiB

/*++
Copyright (c) 1993 Microsoft Corporation
Module Name:
vwipxspx.h
Abstract:
Contains manifests, typedefs, structures, macros for NTVDM IPX/SPX support
Author:
Richard L Firth (rfirth) 30-Sep-1993
Environment:
Structures are expected to live in segmented VDM address space, but be
accessible from flat 32-bit protect mode. The VDM can be in real or protect
mode
Revision History:
30-Sep-1993 rfirth
Created
--*/
#ifndef _VWIPXSPX_H_
#define _VWIPXSPX_H_
//
// FREE_OBJECT - in free version, just calls LocalFree. For debug version, fills
// memory with some arbitrary value, then frees the pointer and checks that what
// LocalFree thought that the pointer pointed at a valid, freeable object
//
#if DBG
#define FREE_OBJECT(p) {\
FillMemory(p, sizeof(*p), 0xFF);\
VWASSERT(LocalFree((HLOCAL)(p)), NULL);\
}
#else
#define FREE_OBJECT(p) VWASSERT(LocalFree((HLOCAL)(p)), NULL)
#endif
//
// simple function macros
//
//#define AllocateXecb() (LPXECB)LocalAlloc(LPTR, sizeof(XECB))
//#define DeallocateXecb(p) FREE_OBJECT(p)
#define AllocateBuffer(s) (LPVOID)LocalAlloc(LMEM_FIXED, (s))
#define DeallocateBuffer(p) FREE_OBJECT(p)
//
// pseudo-types for 16-bit addresses
//
#define ESR_ADDRESS DWORD
#define ECB_ADDRESS DWORD
//
// from Novell documentation, the default maximum open sockets. Max max is 150
//
#ifndef DEFAULT_MAX_OPEN_SOCKETS
#define DEFAULT_MAX_OPEN_SOCKETS 20
#endif
#ifndef MAX_OPEN_SOCKETS
#define MAX_OPEN_SOCKETS 150
#endif
#define SPX_INSTALLED 0xFF
#define MAX_LISTEN_QUEUE_SIZE 5 // ?
//
// misc. macros
//
//
// B2LW, L2Bx - big-endian to little-endian macros
//
#define B2LW(w) (WORD)(((WORD)(w) << 8) | ((WORD)(w) >> 8))
#define B2LD(d) (DWORD)(B2LW((DWORD)(d) << 16) | B2LW((DWORD)(d) >> 16))
#define L2BW(w) B2LW(w)
#define L2BD(d) B2LD(d)
//
// miscellaneous manifests
//
#define ONE_TICK (1000/18) // 1/18 sec in milliseconds (55.55 mSec)
#define SLEEP_TIME ONE_TICK // amount of time we Sleep() during IPXRelinquishControl
//
// options for IPXGetInformation
//
#define IPX_ODI 0x0001
#define IPX_CHECKSUM_FUNCTIONS 0x0002
//
// IPX/SPX structures. The following structures are in VDM format, and should
// be packed on a byte-boundary
//
// Netware maintains certain structure fields in network (big-endian) format
//
#include <packon.h>
//
// INTERNET_ADDRESS - structure returned by IPXGetInternetworkAddress
//
typedef struct {
BYTE Net[4];
BYTE Node[6];
} INTERNET_ADDRESS ;
typedef INTERNET_ADDRESS UNALIGNED *LPINTERNET_ADDRESS;
//
// NETWARE_ADDRESS - address of an application on the network, as defined by
// its network segment, node address and socket number
//
typedef struct {
BYTE Net[4]; // hi-lo
BYTE Node[6]; // hi-lo
WORD Socket; // hi-lo
} NETWARE_ADDRESS ;
typedef NETWARE_ADDRESS UNALIGNED *LPNETWARE_ADDRESS;
//
// FRAGMENT - ECB/IPX/SPX buffers are split into 'fragments'
//
typedef struct {
LPVOID Address; // offset-segment
WORD Length; // hi-lo
} FRAGMENT ;
typedef FRAGMENT UNALIGNED *LPFRAGMENT;
//
// IPX_PACKET - format of packet submitted to IPX for sending. The maximum
// size of an IPX packet is 576 bytes, 30 bytes header, 546 bytes data
//
typedef struct {
WORD Checksum; // always set to 0xFFFF
WORD Length; // set by IPX - header + data
BYTE TransportControl; // set by IPX to 0. Used by routers
//
// for IPX, PacketType is 0 (Unknown Packet Type) or 4 (Packet Exchange
// Packet)
//
BYTE PacketType;
NETWARE_ADDRESS Destination;
NETWARE_ADDRESS Source;
BYTE Data[]; // 546 bytes max.
} IPX_PACKET ;
typedef IPX_PACKET UNALIGNED *LPIPX_PACKET;
#define IPX_HEADER_LENGTH sizeof(IPX_PACKET)
#define MAXIMUM_IPX_PACKET_LENGTH 576
#define MAXIMUM_IPX_DATA_LENGTH (MAXIMUM_IPX_PACKET_LENGTH - IPX_HEADER_LENGTH)
#define IPX_PACKET_TYPE 4
//
// SPX_PACKET - format of packet submitted to SPX for sending. The maximum
// size of an SPX packet is 576 bytes, 42 bytes header, 534 bytes data
//
typedef struct {
WORD Checksum; // always set to 0xFFFF
WORD Length; // set by IPX - header + data
BYTE TransportControl; // set by IPX to 0. Used by routers
//
// for SPX, PacketType is set to 5 (Sequenced Packet Protocol Packet)
//
BYTE PacketType;
NETWARE_ADDRESS Destination;
NETWARE_ADDRESS Source;
//
// ConnectionControl is a bitmap which control bi-directional flow over a
// link. The bits are defined (by Xerox SPP) as:
//
// 0-3 undefined
// 4 end-of-message
// This is the only bit which can be directly manipulated by an
// app. The bit is passed through unchanged by SPX
// 5 attention
// Ignored by SPX, but passed through
// 6 acknowledge
// Set by SPX if an ack is required
// 7 system packet
// Set by SPX if the packet is internal control. An app should
// never see this bit (i.e. should never see a system packet)
//
BYTE ConnectionControl;
//
// DataStreamType defines the type of data in the packet:
//
// 0x00 - 0xFD client-defined.
// Ignored by SPX
// 0xFE end-of-connection.
// When active connection is terminated, SPX
// generates and sends a packet with this bit set.
// This will be the last packet sent on the connection
// 0xFF end-of-connection acknowledgement
// SPX generates a system packet to acknowledge an
// end-of-connection packet
//
BYTE DataStreamType;
WORD SourceConnectId; // assigned by SPX
WORD DestinationConnectId;
WORD SequenceNumber; // managed by SPX
WORD AckNumber; // managed by SPX
WORD AllocationNumber; // managed by SPX
BYTE Data[]; // 534 bytes max.
} SPX_PACKET ;
typedef SPX_PACKET UNALIGNED *LPSPX_PACKET;
#define SPX_HEADER_LENGTH sizeof(SPX_PACKET)
#define MAXIMUM_SPX_PACKET_LENGTH MAXIMUM_IPX_PACKET_LENGTH
#define MAXIMUM_SPX_DATA_LENGTH (MAXIMUM_SPX_PACKET_LENGTH - SPX_HEADER_LENGTH)
#define SPX_PACKET_TYPE 5
//
// ConnectionControl flags
//
#define SPX_CONNECTION_RESERVED 0x0F
#define SPX_END_OF_MESSAGE 0x10
#define SPX_ATTENTION 0x20
#define SPX_ACK_REQUIRED 0x40
#define SPX_SYSTEM_PACKET 0x80
//
// DataStreamType values
//
#define SPX_DS_ESTABLISH 0x00
#define SPX_DS_TERMINATE 0xfe
//
// IPX_ECB - Event Control Block. This structure is used by most IPX/SPX APIs,
// especially when deferred IPX/AES processing is required. The following
// structure is a socket-based ECB
//
typedef struct {
//
// LinkAddress is reserved for use by IPX. We use it to link the ECB onto
// a queue. We appropriate the space used for an x86 segmented address
// (real or protect mode) as a flat 32-bit pointer
//
ULPVOID LinkAddress; // offset-segment
//
// EsrAddress is non-NULL if an Event Service Routine will be called when
// the event described by the ECB completes. This will always be an x86
// segmented address (real or protect mode)
//
ESR_ADDRESS EsrAddress; // offset-segment
//
// IPX uses the InUse field to mark the ECB as owned by IPX (!0) or by the
// app (0):
//
// 0xF8 App tried to send a packet while IPX was busy; IPX queued
// the ECB
// 0xFA IPX is processing the ECB
// 0xFB IPX has used the ECB for some event and put it on a queue
// for processing
// 0xFC the ECB is waiting for an AES event to occur
// 0xFD the ECB is waiting for an IPX event to occur
// 0xFE IPX is listening on a socket for incoming packets
// 0xFF IPX is using the ECB to send a packet
//
BYTE InUse;
//
// CompletionCode is used to return a status from a deferred request. This
// field is not valid until InUse has been set to 0
//
// NOTE: We have to differentiate between AES and IPX ECBs on callbacks: due
// to their different sizes, we store the 16-bit segment and offset in
// different places. In order to differentiate the ECBs, we use CompletionCode
// field (AesWorkspace[0]) as the owner. The real CompletionCode for IPX ECBs
// goes in IPX_ECB_COMPLETE (DriverWorkspace[7]). But only for completed ECBs
// that have an ESR
//
BYTE CompletionCode;
WORD SocketNumber; // hi-lo
//
// the first word of IpxWorkspace is used to return the connection ID of
// an SPX connection
//
DWORD IpxWorkspace;
BYTE DriverWorkspace[12];
//
// ImmediateAddress is the local network node at the remote end of this
// connection. It is either the node address of the remote machine if it
// is on this LAN, or it is the node address of the router if the remote
// machine is on a different LAN
//
// This field must be initialized when talking over IPX, but not SPX
//
BYTE ImmediateAddress[6];
//
// FragmentCount - number of FRAGMENT structures that comprise the request.
// Must be at least 1
//
WORD FragmentCount;
//
// FragmentCount fragments start here
//
} IPX_ECB ;
typedef IPX_ECB UNALIGNED *LPIPX_ECB;
//
// ECB InUse values
//
#define ECB_IU_NOT_IN_USE 0x00
#define ECB_IU_TEMPORARY 0xCC
#define ECB_IU_LISTENING_SPX 0xF7 // same as win16 (by observation)
#define ECB_IU_SEND_QUEUED 0xF8
#define ECB_IU_AWAITING_CONNECTION 0xF9 // same as win16 (by observation)
#define ECB_IU_BEING_PROCESSED 0xFA
#define ECB_IU_AWAITING_PROCESSING 0xFB
#define ECB_IU_AWAITING_AES_EVENT 0xFC
#define ECB_IU_AWAITING_IPX_EVENT 0xFD
#define ECB_IU_LISTENING 0xFE
#define ECB_IU_SENDING 0xFF
//
// ECB CompletionCode values
//
#define ECB_CC_SUCCESS 0x00
#define ECB_CC_CONNECTION_TERMINATED 0xEC
#define ECB_CC_CONNECTION_ABORTED 0xED
#define ECB_CC_INVALID_CONNECTION 0xEE
#define ECB_CC_CONNECTION_TABLE_FULL 0xEF
#define ECB_CC_CANNOT_CANCEL 0xF9
#define ECB_CC_CANCELLED 0xFC
#define ECB_CC_BAD_REQUEST 0xFD
#define ECB_CC_BAD_SEND_REQUEST 0xFD
#define ECB_CC_PACKET_OVERFLOW 0xFD
#define ECB_CC_UNDELIVERABLE 0xFE
#define ECB_CC_SOCKET_TABLE_FULL 0xFE
#define ECB_CC_BAD_LISTEN_REQUEST 0xFF
#define ECB_CC_HARDWARE_ERROR 0xFF
#define ECB_CC_NON_EXISTENT_SOCKET 0xFF
//
// we commandeer certain (reserved) fields for our own internal use:
//
// LPECB EcbLink LinkAddress
// PVOID Buffer32 DriverWorkspace[0]
// WORD Length32 DriverWorkspace[4]
// WORD Flags32 DriverWorkspace[6]
// WORD OriginalEs DriverWorkspace[8]
// WORD OriginalSi DriverWorkspace[10]
//
#define ECB_TYPE(p) (((LPIPX_ECB)(p))->CompletionCode)
#define IPX_ECB_SEGMENT(p) (WORD)*((ULPWORD)&(((LPIPX_ECB)(p))->IpxWorkspace)+0)
#define IPX_ECB_OFFSET(p) (WORD)*((ULPWORD)&(((LPIPX_ECB)(p))->IpxWorkspace)+2)
#define IPX_ECB_BUFFER32(p) (ULPVOID)*(ULPVOID*)&(((LPIPX_ECB)(p))->DriverWorkspace[0])
#define IPX_ECB_LENGTH32(p) (WORD)*(ULPWORD)&(((LPIPX_ECB)(p))->DriverWorkspace[4])
#define IPX_ECB_FLAGS32(p) (((LPIPX_ECB)(p))->DriverWorkspace[6])
#define IPX_ECB_COMPLETE(p) (((LPIPX_ECB)(p))->DriverWorkspace[7])
#define SPX_ECB_CONNECTION_ID(p) (WORD)*(ULPWORD)&(((LPIPX_ECB)(p))->IpxWorkspace)
//
// ECB Flags32 flags
//
#define ECB_FLAG_BUFFER_ALLOCATED 0x01
//
// ECB types
//
#define ECB_TYPE_AES 0
#define ECB_TYPE_IPX 1
#define ECB_TYPE_SPX 2
//
// ECB owners
//
#define ECB_OWNER_IPX 0xFF
#define ECB_OWNER_AES 0x00
//
// ECB_FRAGMENT - macro which gives the address of the first fragment structure
// within a socket-based ECB
//
#define ECB_FRAGMENT(p, n) ((LPFRAGMENT)(((LPIPX_ECB)(p) + 1)) + (n))
//
// AES_ECB - used by AES, these socket-less ECBs are used to schedule events
//
typedef struct {
ULPVOID LinkAddress; // offset-segment
ESR_ADDRESS EsrAddress; // offset-segment
BYTE InUse;
//
// first 3 bytes overlay CompletionCode (1) and SocketNumber (2) fields of
// IPX_ECB. Last 2 bytes overlay first 2 bytes of IpxWorkspace (4) field of
// IPX_ECB. We use the 1st byte of the common unused fields as the ECB type
// (send/receive/timed-event)
//
BYTE AesWorkspace[5];
} AES_ECB ;
typedef AES_ECB UNALIGNED *LPAES_ECB;
//
// as with IPX_ECB, we 'borrow' some of the reserved fields for our own use
//
#define AES_ECB_SEGMENT(p) (WORD)*(ULPWORD)&(((LPAES_ECB)(p))->AesWorkspace[1])
#define AES_ECB_OFFSET(p) (WORD)*(ULPWORD)&(((LPAES_ECB)(p))->AesWorkspace[3])
//
// LPECB - points to either IPX_ECB or AES_ECB. Both in VDM workspace
//
#define LPECB LPIPX_ECB
//
// SPX_CONNECTION_STATS - returned by SPXGetConnectionStatus. All WORD fields
// are to be returned HiLo (ie to Hawaii). All fields come back from NT SPX
// transport in HiLo format also (this was changed recently, used to be in
// Intel order).
//
typedef struct {
BYTE State;
BYTE WatchDog;
WORD LocalConnectionId;
WORD RemoteConnectionId;
WORD LocalSequenceNumber;
WORD LocalAckNumber;
WORD LocalAllocNumber;
WORD RemoteAckNumber;
WORD RemoteAllocNumber;
WORD LocalSocket;
BYTE ImmediateAddress[6];
BYTE RemoteNetwork[4];
BYTE RemoteNode[6];
WORD RemoteSocket;
WORD RetransmissionCount;
WORD EstimatedRoundTripDelay;
WORD RetransmittedPackets;
WORD SuppressedPackets;
} SPX_CONNECTION_STATS ;
typedef SPX_CONNECTION_STATS UNALIGNED* LPSPX_CONNECTION_STATS;
#include <packoff.h>
//
// 16-bit parameter get/set macros. These may change depending on requirements
// of real/protect mode parameters (e.g. stack based vs. register based)
//
#define IPX_GET_AES_ECB(p) (p) = (LPAES_ECB)POINTER_FROM_WORDS(getES(), getSI(), sizeof(AES_ECB))
#define IPX_GET_IPX_ECB(p) (p) = (LPIPX_ECB)POINTER_FROM_WORDS(getES(), getSI(), sizeof(IPX_ECB))
#define IPX_GET_SOCKET(s) (s) = (WORD)getDX()
#define IPX_GET_SOCKET_LIFE(l) (l) = (BYTE)getBP()
#define IPX_GET_SOCKET_OWNER(o) (o) = (WORD)getCX()
#define IPX_GET_BUFFER(p, s) (p) = (ULPBYTE)POINTER_FROM_WORDS(getES(), getSI(), (s))
#define IPX_GET_ECB_SEGMENT() getES()
#define IPX_GET_ECB_OFFSET() getSI()
#define IPX_SET_STATUS(s) setAL((BYTE)(s))
#define IPX_SET_SOCKET(s) setDX((WORD)(s))
#define IPX_SET_INFORMATION(v) setDX((WORD)(v))
#define SPX_SET_STATUS(s) setAL((BYTE)(s))
#define SPX_SET_CONNECTION_ID(i) setDX((WORD)(i))
//
// macros returning 16-bit API parameters - may fetch register contents or values
// from stack/memory
//
#define ECB_PARM_SEGMENT() getES()
#define ECB_PARM_OFFSET() getSI()
#define ECB_PARM_ADDRESS() (ECB_ADDRESS)MAKELONG(getSI(), getES())
#define AES_ECB_PARM() RetrieveEcb(ECB_TYPE_AES)
#define IPX_ECB_PARM() RetrieveEcb(ECB_TYPE_IPX)
#define IPX_SOCKET_PARM() getDX()
#define IPX_SOCKET_LIFE_PARM() (BYTE)getBP()
#define IPX_SOCKET_OWNER_PARM() getCX()
#define IPX_BUFFER_PARM(s) (ULPBYTE)POINTER_FROM_WORDS(getES(), getSI(), (s))
#define IPX_TICKS_PARM() getBP()
#define SPX_RETRY_COUNT_PARM() (BYTE)getBP()
#define SPX_WATCHDOG_FLAG_PARM() ((BYTE)(getBP() >> 8))
#define SPX_ECB_PARM() RetrieveEcb(ECB_TYPE_IPX)
#define SPX_CONNECTION_PARM() getDX()
#define SPX_BUFFER_PARM(s) (ULPBYTE)POINTER_FROM_WORDS(getES(), getSI(), (s))
//
// IPX error codes - same codes used in different circumstances
//
#define IPX_SUCCESS 0x00
#define IPX_CANNOT_CANCEL 0xF9
#define IPX_NO_PATH_TO_DESTINATION 0xFA
#define IPX_CANCELLED 0xFC
#define IPX_BAD_REQUEST 0xFD
#define IPX_SOCKET_TABLE_FULL 0xFE
#define IPX_UNDELIVERABLE 0xFE
#define IPX_SOCKET_ALREADY_OPEN 0xFF
#define IPX_HARDWARE_ERROR 0xFF
#define IPX_NON_EXISTENT_SOCKET 0xFF
#define IPX_ECB_NOT_IN_USE 0xFF
//
// SPX error codes - same codes used in different circumstances
//
#define SPX_SUCCESS 0x00
#define SPX_CONNECTION_TERMINATED 0xEC
#define SPX_CONNECTION_ABORTED 0xED
#define SPX_INVALID_CONNECTION 0xEE
#define SPX_CONNECTION_TABLE_FULL 0xEF
#define SPX_SOCKET_CLOSED 0xFC
#define SPX_PACKET_OVERFLOW 0xFD
#define SPX_BAD_SEND_REQUEST 0xFD // malformed packet
#define SPX_BAD_LISTEN_REQUEST 0xFF
#define SPX_NON_EXISTENT_SOCKET 0xFF
#endif // _VWIPXSPX_H_