windows-nt/Source/XPSP1/NT/termsrv/remdsk/rds/as/h/oa.h

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2020-09-26 03:20:57 -05:00
//
// Order Accumulator
//
#ifndef _H_OA
#define _H_OA
#include <osi.h>
//
// Specific values for OSI escape codes
//
#define OA_ESC(code) (OSI_OA_ESC_FIRST + code)
#define OA_ESC_FLOW_CONTROL OA_ESC(0)
//
// Flow control constants for sizes/depths when slow, fast, etc. The
// SLOW/FAST heap sizes are simply for spoiling. OA_HEAP_MAX is really
// the size of the heap.
//
#define OA_FAST_HEAP 50000
#define OA_SLOW_HEAP 20000
//
// NOTE: This is 64K - sizeof OA_SHARED_DATA header
// If you add fields to header, subtract from this value
//
#define OA_HEAP_MAX 65512
//
// Flow control constants for depth of order spoiling
//
#define OA_FAST_SCAN_DEPTH 50
#define OA_SLOW_SCAN_DEPTH 500
//
// Threshold for switching from FAST to SLOW order accum
//
#define OA_FAST_THRESHOLD 20000
//
// Value to indicate that you have reached the end of the order list
//
#define OA_NO_LIST -1
#ifdef DLL_DISP
#define OA_SHM_START_WRITING SHM_StartAccess(SHM_OA_DATA)
#define OA_SHM_STOP_WRITING SHM_StopAccess(SHM_OA_DATA)
#define OA_FST_START_WRITING SHM_StartAccess(SHM_OA_FAST)
#define OA_FST_STOP_WRITING SHM_StopAccess(SHM_OA_FAST)
#else
#define OA_SHM_START_READING g_poaData[\
1 - g_asSharedMemory->displayToCore.newBuffer]
#define OA_SHM_STOP_READING
#define OA_SHM_START_WRITING g_poaData[\
1 - g_asSharedMemory->displayToCore.newBuffer]
#define OA_SHM_STOP_WRITING
#define OA_FST_START_READING &g_asSharedMemory->oaFast[\
1 - g_asSharedMemory->fastPath.newBuffer]
#define OA_FST_STOP_READING
#define OA_FST_START_WRITING &g_asSharedMemory->oaFast[\
1 - g_asSharedMemory->fastPath.newBuffer]
#define OA_FST_STOP_WRITING
#endif
//
// Maximum memory allowed for variable order data.
//
#define MAX_ADDITIONAL_DATA_BYTES 400000
//
// Invalid value to assign to deallocated order header pointers.
//
#define OA_DEAD_ORDER ((void FAR *)0xffffffff)
//
// Define the space to be reserved at the beginning of the segment
// for heap management.
//
#define RESERVED_HEAP_BYTES 16
//
// Define clip function return codes.
//
#define CR_NO_OVERLAP 1
#define CR_COMPLETE_OVERLAP 2
#define CR_SIMPLE_CLIP 3
#define CR_COMPLEX_OVERLAP 4
#define CR_COMPLEX_CLIP 5
//
// Macros that return the width and height of an order.
//
#define ORDER_WIDTH(pOrder) \
( pOrder->OrderHeader.Common.rcsDst.right - \
pOrder->OrderHeader.Common.rcsDst.left + 1 )
#define ORDER_HEIGHT(pOrder) \
( pOrder->OrderHeader.Common.rcsDst.bottom - \
pOrder->OrderHeader.Common.rcsDst.top + 1 )
//
// Define the minimum width and height of an order for us to try to spoil
// previous orders with it. This helps performance, because it saves us
// trying to spoil earlier orders with very small orders. However, if the
// order exceeds the FULL_SPOIL values then we spoil as originally, with
// the proviso that flow control may still prevent it.
//
#define FULL_SPOIL_WIDTH 16
#define FULL_SPOIL_HEIGHT 16
//
// Define a macro that calculates whether a rectangle lies completely
// within another rectangle.
//
#define RECT1_WITHIN_RECT2(rect1, rect2) \
( (rect1.left >= rect2.left ) && \
(rect1.top >= rect2.top ) && \
(rect1.right <= rect2.right ) && \
(rect1.bottom <= rect2.bottom) )
//
// Structure: OA_NEW_PARAMS
//
// Description:
//
// Structure to pass new OA parameters down to the display driver from the
// Share Core.
//
//
enum
{
OAFLOW_FAST = 0,
OAFLOW_SLOW
};
typedef struct tagOA_FLOW_CONTROL
{
OSI_ESCAPE_HEADER header; // Common header
DWORD oaFlow; // Type -- fast, slow, etc.
}
OA_FLOW_CONTROL;
typedef OA_FLOW_CONTROL FAR * LPOA_FLOW_CONTROL;
//
// Structure used to store orders in the shared memory
//
// totalHeapOrderBytes - Total bytes used in the order heap
//
// totalOrderBytes - Total bytes used by order data
//
// totalAdditionalOrderBytes - Total bytes used as additional order data
//
// nextOrder - Offset for start of next new order
//
// orderListHead - Order list head (uses standard BASEDLIST
// manipulation code)
//
// orderHeap - Order heap
//
typedef struct tagOA_SHARED_DATA
{
DWORD totalHeapOrderBytes;
DWORD totalOrderBytes;
DWORD totalAdditionalOrderBytes;
LONG nextOrder;
BASEDLIST orderListHead;
BYTE orderHeap[OA_HEAP_MAX];
}
OA_SHARED_DATA;
typedef OA_SHARED_DATA FAR * LPOA_SHARED_DATA;
//
// Structure used to store orders in the shared memory
//
// ordersAccumulated - number of orders accumulated in the heap
// since the last double buffer swap.
//
//
typedef struct tagOA_FAST_DATA
{
DWORD ordersAccumulated;
} OA_FAST_DATA;
typedef OA_FAST_DATA FAR * LPOA_FAST_DATA;
//
//
// INT_ORDER_HEADER
//
// This structure contains the Common header (containing the fields which
// are sent over the network) and some additional fields which are only
// used on the host side)
//
// list
// Offset to next and previous orders in the list
// This field does not need to be transmitted across the network.
//
// additionalOrderData
// Offset to the additional data for this order.
// This field does not need to be transmitted across the network.
//
// cbAdditionalOrderData
// Size of the additional data for this order.
// This field does not need to be transmitted across the network.
//
// Common
// Common header (which IS sent over the network)
//
// N.B. If you change this structure, please make sure that you haven't
// broken the code in SBCInitInternalOrders.
//
//
typedef struct INT_ORDER_HEADER
{
BASEDLIST list;
LONG additionalOrderData;
WORD cbAdditionalOrderDataLength;
WORD pad1;
COM_ORDER_HEADER Common;
} INT_ORDER_HEADER;
typedef INT_ORDER_HEADER FAR *LPINT_ORDER_HEADER;
//
// Define an order with the internal only fields defined (this is only used
// on the sending end)
//
typedef struct _INT_ORDER
{
INT_ORDER_HEADER OrderHeader;
BYTE abOrderData[1];
} INT_ORDER;
typedef INT_ORDER FAR *LPINT_ORDER;
// Structure: INT_COLORTABLE_ORDER_xBPP
//
// Description: Internal structures used to pass color table data to the
// share core. These are never sent across the wire.
//
typedef struct tagINT_COLORTABLE_HEADER
{
TSHR_UINT16 type; // holds "CT" - INTORD_COLORTABLE
TSHR_UINT16 bpp; // 1, 4 or 8
} INT_COLORTABLE_HEADER, FAR * LPINT_COLORTABLE_HEADER;
typedef struct tagINT_COLORTABLE_ORDER_1BPP
{
INT_COLORTABLE_HEADER header;
TSHR_RGBQUAD colorData[2];
} INT_COLORTABLE_ORDER_1BPP, FAR * LPINT_COLORTABLE_ORDER_1BPP;
typedef struct tagINT_COLORTABLE_ORDER_4BPP
{
INT_COLORTABLE_HEADER header;
TSHR_RGBQUAD colorData[16];
} INT_COLORTABLE_ORDER_4BPP, FAR * LPINT_COLORTABLE_ORDER_4BPP;
typedef struct tagINT_COLORTABLE_ORDER_8BPP
{
INT_COLORTABLE_HEADER header;
TSHR_RGBQUAD colorData[256];
} INT_COLORTABLE_ORDER_8BPP, FAR * LPINT_COLORTABLE_ORDER_8BPP;
//
// Macro to calculate a basic internal order size (including the Order
// Header).
//
#define INT_ORDER_SIZE(pOrder) \
(pOrder->OrderHeader.Common.cbOrderDataLength + sizeof(INT_ORDER_HEADER))
//
// Macro to calculate the maximum possible size of an order, including
// any Additional Order Data.
//
#define MAX_ORDER_SIZE(pOrder) \
(INT_ORDER_SIZE(pOrder) + (pOrder->OrderHeader.cbAdditionalOrderDataLength))
//
// Macro to determine whether an order is SCRBLT_ORDER.
//
#define ORDER_IS_SCRBLT(pOrder) \
(((LPSCRBLT_ORDER)&pOrder->abOrderData)->type == LOWORD(ORD_SCRBLT))
//
// Macro to determine whether an order is MEMBLT_ORDER.
//
#define ORDER_IS_MEMBLT(pOrder) \
(((LPMEMBLT_ORDER)&pOrder->abOrderData)->type == LOWORD(ORD_MEMBLT) || \
((LPMEMBLT_ORDER)&pOrder->abOrderData)->type == LOWORD(ORD_MEMBLT_R2))
//
// Macro to determine whether an order is MEM3BLT_ORDER.
//
#define ORDER_IS_MEM3BLT(pOrder) \
(((LPMEM3BLT_ORDER)&pOrder->abOrderData)->type == LOWORD(ORD_MEM3BLT) || \
((LPMEM3BLT_ORDER)&pOrder->abOrderData)->type == LOWORD(ORD_MEM3BLT_R2))
//
// PROTOTYPES
//
#ifdef DLL_DISP
//
// FUNCTION: OA_DDProcessRequest
//
// DESCRIPTION:
//
// Called by the display driver to process an OA specific request
//
// PARAMETERS: pso - pointer to surface object
// cjIn - (IN) size of request block
// pvIn - (IN) pointer to request block
// cjOut - (IN) size of response block
// pvOut - (OUT) pointer to response block
//
// RETURNS: None
//
//
BOOL OA_DDProcessRequest(UINT fnEscape, LPOSI_ESCAPE_HEADER pResult,
DWORD cbResult);
//
//
// FUNCTION: OA_DDAllocOrderMem
//
// DESCRIPTION:
//
// Allocates memory for an internal order structure from our own private
// Order Heap.
//
// Allocates any Additional Order Memory from global memory. A pointer to
// the Additional Order Memory is stored within the allocated order's
// header (pOrder->OrderHeader.pAdditionalOrderData).
//
//
// PARAMETERS:
//
// cbOrderDataLength - length in bytes of the order data to be allocated
// from the Order Heap.
//
// cbAdditionalOrderDataLength - length in bytes of additional order data
// to be allocated from Global Memory. If this parameter is zero no
// additional order memory is allocated.
//
//
// RETURNS:
//
// A pointer to the allocated order memory. NULL if the memory allocation
// failed.
//
//
//
LPINT_ORDER OA_DDAllocOrderMem(UINT cbOrderDataLength, UINT cbAdditionalOrderDataLength );
//
//
// OA_DDFreeOrderMem(..)
//
// Frees order memory allocated by OA_AllocOrderMem(..).
// Frees order memory from our own private heap.
// Frees any Additional Order Memory associated with this order.
//
// Order memory is normally freed when the order is transmitted.
//
// This will be used if order memory has been allocated, and
// subsequently, before the order is passed to AddOrder(..), the
// allocator decides that the order should not be sent (e.g. if it
// is completely clipped out).
//
//
void OA_DDFreeOrderMem(LPINT_ORDER pOrder);
void OA_DDResetOrderList(void);
LPINT_ORDER OA_DDRemoveListOrder(LPINT_ORDER pCondemnedOrder);
void OA_DDSyncUpdatesNow(void);
//
// Name: OA_DDSpoilOrdersByRect
//
// Purpose: Try to spoil orders by a given rectangle.
//
// Returns: Nothing
//
// Params: IN pRect - Pointer to the spoiling rectangle
//
// Operation: This function will start at the end of the order heap (from
// the newest order) and work towards the start of the heap.
//
void OA_DDSpoilOrdersByRect(LPRECT pRect);
//
//
// OA_DDAddOrder(..)
//
// Adds an order to the queue for transmission.
//
// If the new order is completely covered by the current SDA then
// it is spoilt.
//
// If the order is opaque and overlaps earlier orders it may clip
// or spoil them.
//
// Called by the GDI interception code.
//
//
void OA_DDAddOrder(LPINT_ORDER pNewOrder, void FAR * pExtraInfo);
void OADDAppendToOrderList(LPOA_SHARED_DATA lpoaShared, LPINT_ORDER pNewOrder);
LPINT_ORDER OADDAllocOrderMemInt(LPOA_SHARED_DATA lpoaShared, UINT cbOrderDataLength, UINT cbAdditionalOrderDataLength);
void OADDFreeOrderMemInt(LPOA_SHARED_DATA lpoaShared, LPINT_ORDER pOrder);
void OADDFreeAllOrders(LPOA_SHARED_DATA lpoaShared);
BOOL OADDCompleteOverlapRect(LPTSHR_RECT16 prcsSrc, LPRECT prcsOverlap);
void OATrySpoilingByOrders(void);
void OADDSpoilFromOrder(LPOA_SHARED_DATA lpoaShared, LPINT_ORDER pOrder, LPRECT pRect);
#ifdef DEBUG
void CheckOaHeap(LPOA_SHARED_DATA);
#else
#define CheckOaHeap(lpoaShared)
#endif
#endif // !DLL_DISP
#endif // _H_OA