windows-nt/Source/XPSP1/NT/net/dlc/driver/llcmem.h
2020-09-26 16:20:57 +08:00

909 lines
26 KiB
C

/*++
Copyright (c) 1991 Microsoft Corporation
Module Name:
llcmem.h
Abstract:
Contains type and structure definitions and routine prototypes and macros
for llcmem.c. To aid in tracking memory resources, DLC/LLC now delineates
the following memory categories:
Memory
- arbitrary sized blocks allocated out of non-paged pool using
ExAllocatePool(NonPagedPool, ...)
ZeroMemory
- arbitrary sized blocks allocated out of non-paged pool using
ExAllocatePool(NonPagedPool, ...) and initialized to zeroes
Pool
- small sets of (relatively) small packets are allocated in one
block from Memory or ZeroMemory as a Pool and then subdivided
into packets
Object
- structures which may be packets allocated from Pool which have
a known size and initialization values. Pseudo-category mainly
for debugging purposes
Author:
Richard L Firth (rfirth) 10-Mar-1993
Environment:
kernel mode only.
Revision History:
09-Mar-1993 RFirth
Created
--*/
#ifndef _LLCMEM_H_
#define _LLCMEM_H_
#define DLC_POOL_TAG ' CLD'
//
// the following types and defines are for the debug version of the driver, but
// need to be defined for the non-debug version too (not used, just defined)
//
//
// In the DEBUG version of DLC, we treat various chunks of memory as 'objects'.
// This serves the following purposes:
//
// 1. We use a signature DWORD, so that when looking at some DLC structure in
// the debugger, we can quickly check if what we are looking at is what we
// think it is. E.g., if you spot a block of memory with a "BIND" signature
// where an "ADAPTER" signature should be, then there is a good chance a
// list or pointer has gotten messed up. The idea is to try and reduce
// the amount of time it can take to guess what you're looking at
//
// 2. We use consistency checks: If a routine is handed a pointer to a structure
// which is supposed to be a FILE_CONTEXT structure, we can check the
// signature and quickly determine if something has gone wrong (like the
// structure has already been freed and the signature contains 0xDAADF00D
//
// 3. We maintain size, head and tail signature information to determine
// whether we have overwritten any part of an object. This is part of the
// consistency check
//
// The object definitions should occur in one place only, but DLC is such a mess
// that it would be a non-trivial amount of work to clean everything up. Do it
// if there's time... (he said, knowing full well there's never any 'time')
//
typedef enum {
DlcDriverObject = 0xCC002001, // start off with a relatively unique id
FileContextObject, // 0xCC002002
AdapterContextObject, // 0xCC002003
BindingContextObject, // 0xCC002004
DlcSapObject, // 0xCC002005
DlcGroupSapObject, // 0xCC002006
DlcLinkObject, // 0xCC002007
DlcDixObject, // 0xCC002008
LlcDataLinkObject, // 0xCC002009
LLcDirectObject, // 0xCC00200A
LlcSapObject, // 0xCC00200B
LlcGroupSapObject, // 0xCC00200C
DlcBufferPoolObject, // 0xCC00200D
DlcLinkPoolObject, // 0xCC00200E
DlcPacketPoolObject, // 0xCC00200F
LlcLinkPoolObject, // 0xCC002010
LlcPacketPoolObject // 0xCC002011
} DLC_OBJECT_TYPE;
typedef struct {
ULONG Signature; // human-sensible signature when DB'd
DLC_OBJECT_TYPE Type; // object identifier
ULONG Size; // size of this object/structure in bytes
ULONG Extra; // additional size over basic object size
} OBJECT_ID, *POBJECT_ID;
#define SIGNATURE_FILE 0x454C4946 // "FILE"
#define SIGNATURE_ADAPTER 0x50414441 // "ADAP"
#define SIGNATURE_BINDING 0x444E4942 // "BIND"
#define SIGNATURE_DLC_SAP 0x44504153 // "SAPD"
#define SIGNATURE_DLC_LINK 0x4B4E494C // "LINK"
#define SIGNATURE_DIX 0x44584944 // "DIXD"
#define SIGNATURE_LLC_LINK 0x41544144 // "DATA"
#define SIGNATURE_LLC_SAP 0x4C504153 // "SAPL"
#define ZAP_DEALLOC_VALUE 0x5A // "Z"
#define ZAP_EX_FREE_VALUE 0x58 // "X"
//
// we try to keep track of memory allocations by subdividing them into driver
// and handle categories. The first charges memory allocated to the driver -
// e.g. a file context 'object'. Once we have open file handles, then allocations
// are charged to them
//
typedef enum {
ChargeToDriver,
ChargeToHandle
} MEMORY_CHARGE;
//
// MEMORY_USAGE - collection of variables used for charging memory. Accessed
// within spinlock
//
typedef struct _MEMORY_USAGE {
struct _MEMORY_USAGE* List; // pointer to next MEMORY_USAGE structure
KSPIN_LOCK SpinLock; // stop alloc & free clashing?
PVOID Owner; // pointer to owning structure/object
DLC_OBJECT_TYPE OwnerObjectId; // identifies who owns this charge
ULONG OwnerInstance; // instance of type of owner
ULONG NonPagedPoolAllocated; // actual amount of non-paged pool charged
ULONG AllocateCount; // number of calls to allocate non-paged pool
ULONG FreeCount; // number of calls to free non-paged pool
LIST_ENTRY PrivateList; // list of allocated blocks owned by this usage
ULONG Unused[2]; // pad to 16-byte boundary
} MEMORY_USAGE, *PMEMORY_USAGE;
//
// PACKET_POOL - this structure describes a packet pool. A packet pool is a
// collection of same-sized packets. The pool starts off with an initial number
// of packets on the FreeList. As packets are allocated, they are put on the
// BusyList and the reverse happens when the packets are deallocated. If there
// are no packets on the FreeList when an allocation call is made, more memory
// is allocated
//
typedef struct {
SINGLE_LIST_ENTRY FreeList; // list of available packets
SINGLE_LIST_ENTRY BusyList; // list of in-use packets
KSPIN_LOCK PoolLock; // stops simultaneous accesses breaking list(s)
ULONG PacketSize; // size of individual packets
//
// the following 2 fields are here because DLC is a piece of garbage. It
// keeps hold of allocated packets even after the pool as been deleted.
// This leads to pool corruption. So if we determine packets are still
// allocated when the pool is deleted, we remove the pool from whatever
// 'object' it is currently stuck to, lamprey-like, and add it to the
// ZombieList. When we next deallocate packets from this pool (assuming that
// DLC at least bothers to do this), we check the zombie state. If ImAZombie
// is TRUE (actually its true to say for the whole DLC device driver) AND
// we are deallocating the last packet in the pool then we really delete
// the pool
//
// SINGLE_LIST_ENTRY UndeadList;
// BOOLEAN ImAZombie;
#if DBG
//
// keep some metrics in the debug version to let us know if the pool is
// growing
//
ULONG Signature; // 0x4C4F4F50 "POOL"
ULONG Viable; // !0 if this pool is valid
ULONG OriginalPacketCount; // number of packets requested
ULONG CurrentPacketCount; // total number in pool
ULONG Allocations; // number of calls to allocate from this pool
ULONG Frees; // number of calls to free to pool
ULONG NoneFreeCount; // number of times allocate call made when no packets free
ULONG MaxInUse; // maximum number allocated at any one time
ULONG ClashCount; // number of simultaneous accesses to pool
ULONG Flags; // type of pool etc.
ULONG ObjectSignature; // signature for checking contents if object pool
PMEMORY_USAGE pMemoryUsage; // pointer to memory equivalent of Discover card
MEMORY_USAGE MemoryUsage; // pool's memory usage charge
ULONG FreeCount; // number of entries on FreeList
ULONG BusyCount; // number of entries on BusyList
ULONG Pad1;
ULONG Pad2;
#endif
} PACKET_POOL, *PPACKET_POOL;
//
// PACKET_POOL defines and flags
//
#define PACKET_POOL_SIGNATURE 0x4C4F4F50 // "POOL"
#define POOL_FLAGS_IN_USE 0x00000001
#define POOL_FLAGS_OBJECT 0x00000002
//
// OBJECT_POOL - synonym for PACKET_POOL. Used in debug version (named 'objects'
// in debug version have an object signature as an aide a debugoire and as
// consistency check)
//
#define OBJECT_POOL PACKET_POOL
#define POBJECT_POOL PPACKET_POOL
//
// PACKET_HEAD - each packet which exists in a PACKET_POOL has this header -
// it links the packet onto the Free or Busy lists and the Flags word contains
// the state of the packet
//
typedef struct {
SINGLE_LIST_ENTRY List; // standard single-linked list
ULONG Flags;
#if DBG
ULONG Signature; // 0x44414548 "HEAD"
PVOID pPacketPool; // owning pool
PVOID CallersAddress_A; // caller - allocation
PVOID CallersCaller_A;
PVOID CallersAddress_D; // caller - deallocation
PVOID CallersCaller_D;
#endif
} PACKET_HEAD, *PPACKET_HEAD;
//
// PACKET_HEAD defines and flags
//
#define PACKET_HEAD_SIGNATURE 0x44414548 // "HEAD"
#define PACKET_FLAGS_BUSY 0x00000001 // packet should be on BusyList
#define PACKET_FLAGS_POST_ALLOC 0x00000002 // this packet was allocated because
// the pool was full
#define PACKET_FLAGS_FREE 0x00000080 // packet should be on FreeList
//
// OBJECT_HEAD - synonym for PACKET_HEAD. Used in debug version (named 'objects'
// in debug version have an object signature as an aide a debugoire and as
// consistency check)
//
#define OBJECT_HEAD PACKET_HEAD
#define POBJECT_HEAD PPACKET_HEAD
#if DBG
//
// anything we allocate from non-paged pool gets the following header pre-pended
// to it
//
typedef struct {
ULONG Size; // inclusive size of allocated block (inc head+tail)
ULONG OriginalSize; // requested size
ULONG Flags; // IN_USE flag
ULONG Signature; // for checking validity of header
LIST_ENTRY GlobalList; // all blocks allocated on one list
LIST_ENTRY PrivateList; // blocks owned by MemoryUsage
PVOID Stack[4]; // stack of return addresses
} PRIVATE_NON_PAGED_POOL_HEAD, *PPRIVATE_NON_PAGED_POOL_HEAD;
#define MEM_FLAGS_IN_USE 0x00000001
#define SIGNATURE1 0x41434C44 // "DLCA" when viewed via db/dc
#define SIGNATURE2 0x434F4C4C // "LLOC" " " " "
//
// anything we allocate from non-paged pool has the following tail appended to it
//
typedef struct {
ULONG Size; // inclusive size; must be same as in header
ULONG Signature; // for checking validity of tail
ULONG Pattern1;
ULONG Pattern2;
} PRIVATE_NON_PAGED_POOL_TAIL, *PPRIVATE_NON_PAGED_POOL_TAIL;
#define PATTERN1 0x55AA6699
#define PATTERN2 0x11EECC33
//
// standard object identifier. Expands to nothing on free build
//
#define DBG_OBJECT_ID OBJECT_ID ObjectId
//
// globally accessible memory
//
extern MEMORY_USAGE DriverMemoryUsage;
extern MEMORY_USAGE DriverStringUsage;
//
// debug prototypes
//
VOID
InitializeMemoryPackage(
VOID
);
PSINGLE_LIST_ENTRY
PullEntryList(
IN PSINGLE_LIST_ENTRY List,
IN PSINGLE_LIST_ENTRY Element
);
VOID
LinkMemoryUsage(
IN PMEMORY_USAGE pMemoryUsage
);
VOID
UnlinkMemoryUsage(
IN PMEMORY_USAGE pMemoryUsage
);
//
// the following 2 functions expand to be ExAllocatePoolWithTag(NonPagedPool, ...)
// and ExFreePool(...) resp. in the retail/Free version of the driver
//
PVOID
AllocateMemory(
IN PMEMORY_USAGE pMemoryUsage,
IN ULONG Size
);
PVOID
AllocateZeroMemory(
IN PMEMORY_USAGE pMemoryUsage,
IN ULONG Size
);
VOID
DeallocateMemory(
IN PMEMORY_USAGE pMemoryUsage,
IN PVOID Pointer
);
PPACKET_POOL
CreatePacketPool(
IN PMEMORY_USAGE pMemoryUsage,
IN PVOID pOwner,
IN DLC_OBJECT_TYPE ObjectType,
IN ULONG PacketSize,
IN ULONG NumberOfPackets
);
VOID
DeletePacketPool(
IN PMEMORY_USAGE pMemoryUsage,
IN PPACKET_POOL* pPacketPool
);
PVOID
AllocateObject(
IN PMEMORY_USAGE pMemoryUsage,
IN DLC_OBJECT_TYPE ObjectType,
IN ULONG ObjectSize
);
VOID
FreeObject(
IN PMEMORY_USAGE pMemoryUsage,
IN PVOID pObject,
IN DLC_OBJECT_TYPE ObjectType
);
VOID
ValidateObject(
IN POBJECT_ID pObject,
IN DLC_OBJECT_TYPE ObjectType
);
POBJECT_POOL
CreateObjectPool(
IN PMEMORY_USAGE pMemoryUsage,
IN DLC_OBJECT_TYPE ObjectType,
IN ULONG ObjectSize,
IN ULONG NumberOfObjects
);
VOID
DeleteObjectPool(
IN PMEMORY_USAGE pMemoryUsage,
IN DLC_OBJECT_TYPE ObjectType,
IN POBJECT_POOL pObjectPool
);
POBJECT_HEAD
AllocatePoolObject(
IN POBJECT_POOL pObjectPool
);
VOID
DeallocatePoolObject(
IN POBJECT_POOL pObjectPool,
IN POBJECT_HEAD pObjectHead
);
VOID
CheckMemoryReturned(
IN PMEMORY_USAGE pMemoryUsage
);
VOID
CheckDriverMemoryUsage(
IN BOOLEAN Break
);
//
// CHECK_DRIVER_MEMORY_USAGE - if (b) breaks into debugger if there is still
// memory allocated to driver
//
#define CHECK_DRIVER_MEMORY_USAGE(b) \
CheckDriverMemoryUsage(b)
//
// CHECK_MEMORY_RETURNED_DRIVER - checks if all charged memory allocation has been
// refunded to the driver
//
#define CHECK_MEMORY_RETURNED_DRIVER() \
CheckMemoryReturned(&DriverMemoryUsage)
//
// CHECK_MEMORY_RETURNED_FILE - checks if all charged memory allocation has been
// refunded to the FILE_CONTEXT
//
#define CHECK_MEMORY_RETURNED_FILE() \
CheckMemoryReturned(&pFileContext->MemoryUsage)
//
// CHECK_MEMORY_RETURNED_ADAPTER - checks if all charged memory allocation has been
// refunded to the ADAPTER_CONTEXT
//
#define CHECK_MEMORY_RETURNED_ADAPTER() \
CheckMemoryReturned(&pAdapterContext->MemoryUsage)
//
// CHECK_STRING_RETURNED_DRIVER - checks if all charged string allocation has been
// refunded to the driver
//
#define CHECK_STRING_RETURNED_DRIVER() \
CheckMemoryReturned(&DriverStringUsage)
//
// CHECK_STRING_RETURNED_ADAPTER - checks if all charged string allocation has been
// refunded to the ADAPTER_CONTEXT
//
#define CHECK_STRING_RETURNED_ADAPTER() \
CheckMemoryReturned(&pAdapterContext->StringUsage)
//
// memory allocators which charge memory usage to the driver
//
//
// ALLOCATE_MEMORY_DRIVER - allocates (n) bytes of memory and charges it to the
// driver
//
#define ALLOCATE_MEMORY_DRIVER(n) \
AllocateMemory(&DriverMemoryUsage, (ULONG)(n))
//
// ALLOCATE_ZEROMEMORY_DRIVER - allocates (n) bytes of ZeroMemory and charges
// it to the driver
//
#define ALLOCATE_ZEROMEMORY_DRIVER(n) \
AllocateZeroMemory(&DriverMemoryUsage, (ULONG)(n))
//
// FREE_MEMORY_DRIVER - deallocates memory and refunds it to the driver
//
#define FREE_MEMORY_DRIVER(p) \
DeallocateMemory(&DriverMemoryUsage, (PVOID)(p))
//
// ALLOCATE_STRING_DRIVER - allocate memory for string usage. Charge to
// DriverStringUsage
//
#define ALLOCATE_STRING_DRIVER(n) \
AllocateZeroMemory(&DriverStringUsage, (ULONG)(n))
//
// FREE_STRING_DRIVER - deallocates memory and refunds it to driver string usage
//
#define FREE_STRING_DRIVER(p) \
DeallocateMemory(&DriverStringUsage, (PVOID)(p))
//
// CREATE_PACKET_POOL_DRIVER - calls CreatePacketPool and charges the pool
// structure to the driver
//
#if !defined(NO_POOLS)
#define CREATE_PACKET_POOL_DRIVER(t, s, n) \
CreatePacketPool(&DriverMemoryUsage,\
NULL,\
(t),\
(ULONG)(s),\
(ULONG)(n))
//
// DELETE_PACKET_POOL_DRIVER - calls DeletePacketPool and refunds the pool
// structure to the driver
//
#define DELETE_PACKET_POOL_DRIVER(p) \
DeletePacketPool(&DriverMemoryUsage, (PPACKET_POOL*)(p))
#endif // NO_POOLS
//
// memory allocators which charge memory usage to an ADAPTER_CONTEXT
//
//
// ALLOCATE_MEMORY_ADAPTER - allocates (n) bytes of memory and charges it to the
// ADAPTER_CONTEXT
//
#define ALLOCATE_MEMORY_ADAPTER(n) \
AllocateMemory(&pAdapterContext->MemoryUsage, (ULONG)(n))
//
// ALLOCATE_ZEROMEMORY_ADAPTER - allocates (n) bytes of ZeroMemory and charges
// it to the ADAPTER_CONTEXT
//
#define ALLOCATE_ZEROMEMORY_ADAPTER(n) \
AllocateZeroMemory(&pAdapterContext->MemoryUsage, (ULONG)(n))
//
// FREE_MEMORY_ADAPTER - deallocates memory and refunds it to the ADAPTER_CONTEXT
//
#define FREE_MEMORY_ADAPTER(p) \
DeallocateMemory(&pAdapterContext->MemoryUsage, (PVOID)(p))
//
// ALLOCATE_STRING_ADAPTER - allocate memory for string usage. Charge to
// pAdapterContext StringUsage
//
#define ALLOCATE_STRING_ADAPTER(n) \
AllocateZeroMemory(&pAdapterContext->StringUsage, (ULONG)(n))
//
// CREATE_PACKET_POOL_ADAPTER - calls CreatePacketPool and charges the pool
// structure to the adapter structure
//
#if !defined(NO_POOLS)
#define CREATE_PACKET_POOL_ADAPTER(t, s, n) \
CreatePacketPool(&pAdapterContext->MemoryUsage,\
(PVOID)pAdapterContext,\
(t),\
(ULONG)(s),\
(ULONG)(n))
//
// DELETE_PACKET_POOL_ADAPTER - calls DeletePacketPool and refunds the pool
// structure to the adapter structure
//
#define DELETE_PACKET_POOL_ADAPTER(p) \
DeletePacketPool(&pAdapterContext->MemoryUsage, (PPACKET_POOL*)(p))
#endif // NO_POOLS
//
// memory allocators which charge memory usage to a FILE_CONTEXT
//
//
// ALLOCATE_MEMORY_FILE - allocates (n) bytes of memory and charges it to the file
// handle
//
#define ALLOCATE_MEMORY_FILE(n) \
AllocateMemory(&pFileContext->MemoryUsage, (ULONG)(n))
//
// ALLOCATE_ZEROMEMORY_FILE - allocates (n) bytes ZeroMemory and charges it to the
// file handle
//
#define ALLOCATE_ZEROMEMORY_FILE(n) \
AllocateZeroMemory(&pFileContext->MemoryUsage, (ULONG)(n))
//
// FREE_MEMORY_FILE - deallocates memory and refunds it to the file handle
//
#define FREE_MEMORY_FILE(p) \
DeallocateMemory(&pFileContext->MemoryUsage, (PVOID)(p))
//
// CREATE_PACKET_POOL_FILE - calls CreatePacketPool and charges the pool structure
// to the file handle
//
#if !defined(NO_POOLS)
#define CREATE_PACKET_POOL_FILE(t, s, n) \
CreatePacketPool(&pFileContext->MemoryUsage,\
(PVOID)pFileContext,\
(t),\
(ULONG)(s),\
(ULONG)(n))
//
// DELETE_PACKET_POOL_FILE - calls DeletePacketPool and refunds the pool structure
// to the file handle
//
#define DELETE_PACKET_POOL_FILE(p) \
DeletePacketPool(&pFileContext->MemoryUsage, (PPACKET_POOL*)(p))
#endif // NO_POOLS
//
// VALIDATE_OBJECT - check that an 'object' is really what it supposed to be.
// Rudimentary check based on object signature and object type fields
//
#define VALIDATE_OBJECT(p, t) ValidateObject(p, t)
#define LINK_MEMORY_USAGE(p) LinkMemoryUsage(&(p)->MemoryUsage)
#define UNLINK_MEMORY_USAGE(p) UnlinkMemoryUsage(&(p)->MemoryUsage)
#define UNLINK_STRING_USAGE(p) UnlinkMemoryUsage(&(p)->StringUsage)
#else // !DBG
//
// DBG_OBJECT_ID in retail version structures is non-existent
//
#define DBG_OBJECT_ID
//
// the non-zero-initialized memory allocator is just a call to ExAllocatePoolWithTag
//
#define AllocateMemory(n) ExAllocatePoolWithTag(NonPagedPool, (n), DLC_POOL_TAG)
//
// AllocateZeroMemory doesn't count memory usage in non-debug version
//
PVOID
AllocateZeroMemory(
IN ULONG Size
);
//
// the memory deallocator is just a call to ExFreePool
//
#define DeallocateMemory(p) ExFreePool(p)
//
// CreatePacketPool doesn't count memory usage in non-debug version
//
PPACKET_POOL
CreatePacketPool(
IN ULONG PacketSize,
IN ULONG NumberOfPackets
);
VOID
DeletePacketPool(
IN PPACKET_POOL* pPacketPool
);
//
// solitary objects in debug version are non-paged pool in retail version
//
#define AllocateObject(n) AllocateZeroMemory(n)
#define DeallocateObject(p) DeallocateMemory(p)
//
// pooled objects in debug version are pooled packets in retail version
//
#define CreateObjectPool(o, s, n) CreatePacketPool(s, n)
#define DeleteObjectPool(p) DeletePacketPool(p)
#define AllocatePoolObject(p) AllocatePacket(p)
#define DeallocatePoolObject(p, h) DeallocatePacket(p)
//
// non-debug build no-op macros
//
#define CHECK_MEMORY_RETURNED_DRIVER()
#define CHECK_MEMORY_RETURNED_FILE()
#define CHECK_MEMORY_RETURNED_ADAPTER()
#define CHECK_STRING_RETURNED_DRIVER()
#define CHECK_STRING_RETURNED_ADAPTER()
#define CHECK_DRIVER_MEMORY_USAGE(b)
//
// non-memory-charging versions of allocation/free macros
//
#define ALLOCATE_MEMORY_DRIVER(n) AllocateMemory((ULONG)(n))
#define ALLOCATE_ZEROMEMORY_DRIVER(n) AllocateZeroMemory((ULONG)(n))
#define FREE_MEMORY_DRIVER(p) DeallocateMemory((PVOID)(p))
#define ALLOCATE_STRING_DRIVER(n) AllocateZeroMemory((ULONG)(n))
#define FREE_STRING_DRIVER(p) DeallocateMemory((PVOID)(p))
#if !defined(NO_POOLS)
#define CREATE_PACKET_POOL_DRIVER(t, s, n) CreatePacketPool((ULONG)(s), (ULONG)(n))
#define DELETE_PACKET_POOL_DRIVER(p) DeletePacketPool((PPACKET_POOL*)(p))
#endif // NO_POOLS
#define ALLOCATE_MEMORY_ADAPTER(n) AllocateMemory((ULONG)(n))
#define ALLOCATE_ZEROMEMORY_ADAPTER(n) AllocateZeroMemory((ULONG)(n))
#define FREE_MEMORY_ADAPTER(p) DeallocateMemory((PVOID)(p))
#define ALLOCATE_STRING_ADAPTER(n) AllocateZeroMemory((ULONG)(n))
#if !defined(NO_POOLS)
#define CREATE_PACKET_POOL_ADAPTER(t, s, n) CreatePacketPool((s), (n))
#define DELETE_PACKET_POOL_ADAPTER(p) DeletePacketPool((PPACKET_POOL*)(p))
#endif // NO_POOLS
#define ALLOCATE_MEMORY_FILE(n) AllocateMemory((ULONG)(n))
#define ALLOCATE_ZEROMEMORY_FILE(n) AllocateZeroMemory((ULONG)(n))
#define FREE_MEMORY_FILE(p) DeallocateMemory((PVOID)(p))
#if !defined(NO_POOLS)
#define CREATE_PACKET_POOL_FILE(t, s, n) CreatePacketPool((ULONG)(s), (ULONG)(n))
#define DELETE_PACKET_POOL_FILE(p) DeletePacketPool((PPACKET_POOL*)(p))
#endif // NO_POOLS
#define VALIDATE_OBJECT(p, t)
#define LINK_MEMORY_USAGE(p)
#define UNLINK_MEMORY_USAGE(p)
#define UNLINK_STRING_USAGE(p)
#endif // DBG
//
// Prototypes for memory allocators and pool and object functions
//
PVOID
AllocatePacket(
IN PPACKET_POOL pPacketPool
);
VOID
DeallocatePacket(
IN PPACKET_POOL pPacketPool,
IN PVOID pPacket
);
#if defined(NO_POOLS)
#define CREATE_PACKET_POOL_DRIVER(t, s, n) (PVOID)0x12345678
#define CREATE_PACKET_POOL_ADAPTER(t, s, n) (PVOID)0x12345679
#define CREATE_PACKET_POOL_FILE(t, s, n) (PVOID)0x1234567A
#define DELETE_PACKET_POOL_DRIVER(p) *p = NULL
#define DELETE_PACKET_POOL_ADAPTER(p) *p = NULL
#define DELETE_PACKET_POOL_FILE(p) *p = NULL
#if defined(BUF_USES_POOL)
#if DBG
#define CREATE_BUFFER_POOL_FILE(t, s, n) \
CreatePacketPool(&pFileContext->MemoryUsage,\
(PVOID)pFileContext,\
(t),\
(ULONG)(s),\
(ULONG)(n))
#define DELETE_BUFFER_POOL_FILE(p) \
DeletePacketPool(&pFileContext->MemoryUsage, (PPACKET_POOL*)(p))
#define ALLOCATE_PACKET_DLC_BUF(p) AllocatePacket(p)
#define DEALLOCATE_PACKET_DLC_BUF(pool, p) DeallocatePacket(pool, p)
#else // !DBG
#define CREATE_BUFFER_POOL_FILE(t, s, n) CreatePacketPool((ULONG)(s), (ULONG)(n))
#define DELETE_BUFFER_POOL_FILE(p) DeletePacketPool((PPACKET_POOL*)(p))
#define ALLOCATE_PACKET_DLC_BUF(p) ALLOCATE_ZEROMEMORY_FILE(sizeof(DLC_BUFFER_HEADER))
#define DEALLOCATE_PACKET_DLC_BUF(pool, p) FREE_MEMORY_FILE(p)
#endif // DBG
#else // !BUF_USES_POOL
#define CREATE_BUFFER_POOL_FILE(t, s, n) (PVOID)0x1234567B
#define DELETE_BUFFER_POOL_FILE(p) *p = NULL
#define ALLOCATE_PACKET_DLC_BUF(p) AllocateZeroMemory(sizeof(DLC_BUFFER_HEADER))
#define DEALLOCATE_PACKET_DLC_BUF(pool, p) DeallocateMemory(p)
#endif // BUF_USES_POOL
#if DBG
#define ALLOCATE_PACKET_DLC_PKT(p) ALLOCATE_ZEROMEMORY_FILE(sizeof(DLC_PACKET))
#define ALLOCATE_PACKET_DLC_OBJ(p) ALLOCATE_ZEROMEMORY_FILE(sizeof(DLC_OBJECT))
#define ALLOCATE_PACKET_LLC_PKT(p) ALLOCATE_ZEROMEMORY_ADAPTER(sizeof(UNITED_PACKETS))
#define ALLOCATE_PACKET_LLC_LNK(p) ALLOCATE_ZEROMEMORY_ADAPTER(sizeof(DATA_LINK) + 32)
#define DEALLOCATE_PACKET_DLC_PKT(pool, p) FREE_MEMORY_FILE(p)
#define DEALLOCATE_PACKET_DLC_OBJ(pool, p) FREE_MEMORY_FILE(p)
#define DEALLOCATE_PACKET_LLC_PKT(pool, p) FREE_MEMORY_ADAPTER(p)
#define DEALLOCATE_PACKET_LLC_LNK(pool, p) FREE_MEMORY_ADAPTER(p)
#else // !DBG
#define CREATE_BUFFER_POOL_FILE(t, s, n) CREATE_PACKET_POOL_FILE(t, s, n)
#define DELETE_BUFFER_POOL_FILE(p) DELETE_PACKET_POOL_FILE(p)
#define ALLOCATE_PACKET_DLC_BUF(p) AllocateZeroMemory(sizeof(DLC_BUFFER_HEADER))
#define ALLOCATE_PACKET_DLC_PKT(p) AllocateZeroMemory(sizeof(DLC_PACKET))
#define ALLOCATE_PACKET_DLC_OBJ(p) AllocateZeroMemory(sizeof(DLC_OBJECT))
#define ALLOCATE_PACKET_LLC_PKT(p) AllocateZeroMemory(sizeof(UNITED_PACKETS))
#define ALLOCATE_PACKET_LLC_LNK(p) AllocateZeroMemory(sizeof(DATA_LINK) + 32)
#define DEALLOCATE_PACKET_DLC_BUF(pool, p) DeallocateMemory(p)
#define DEALLOCATE_PACKET_DLC_PKT(pool, p) DeallocateMemory(p)
#define DEALLOCATE_PACKET_DLC_OBJ(pool, p) DeallocateMemory(p)
#define DEALLOCATE_PACKET_LLC_PKT(pool, p) DeallocateMemory(p)
#define DEALLOCATE_PACKET_LLC_LNK(pool, p) DeallocateMemory(p)
#endif // DBG
#else // !NO_POOLS
#define CREATE_BUFFER_POOL_FILE(t, s, n) CREATE_PACKET_POOL_FILE(t, s, n)
#define DELETE_BUFFER_POOL_FILE(p) DELETE_PACKET_POOL_FILE(p)
#define ALLOCATE_PACKET_DLC_BUF(p) AllocatePacket(p)
#define ALLOCATE_PACKET_DLC_PKT(p) AllocatePacket(p)
#define ALLOCATE_PACKET_DLC_OBJ(p) AllocatePacket(p)
#define ALLOCATE_PACKET_LLC_PKT(p) AllocatePacket(p)
#define ALLOCATE_PACKET_LLC_LNK(p) AllocatePacket(p)
#define DEALLOCATE_PACKET_DLC_BUF(pool, p) DeallocatePacket(pool, p)
#define DEALLOCATE_PACKET_DLC_PKT(pool, p) DeallocatePacket(pool, p)
#define DEALLOCATE_PACKET_DLC_OBJ(pool, p) DeallocatePacket(pool, p)
#define DEALLOCATE_PACKET_LLC_PKT(pool, p) DeallocatePacket(pool, p)
#define DEALLOCATE_PACKET_LLC_LNK(pool, p) DeallocatePacket(pool, p)
#endif // NO_POOLS
#endif // _LLCMEM_H_