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.
 
 
 
 
 
 

401 lines
11 KiB

/* Copyright (c) 1998-1999 Microsoft Corporation */
/* @doc DMusic16
*
* @module Alloc.c - Memory allocation routines |
*
* This module provides memory allocation routines for DMusic16.DLL. It allows the MIDI input and
* output modules to allocated and free <c EVENT> structures.
*
* The allocated recognizes two types of events by size. If an event is create with 4 or less bytes
* of data, then it is allocated as a channel message. Channel message events are allocated one
* page at a time and kept in a free list.
*
* If the event size is greater than 4 bytes, then the event is a system exclusive message (or long
* data in the legacy API nomenclature). These events are allocated individually, one per page.
*
* All allocated memory is preceded with a <c SEGHDR>, which is used to identify the size and type
* of the segment and to keep it in a list. Since all events will be accessed at event time (in
* either a MIDI input callback or a timeSetEvent callback), all memory is automatically page
* locked.
*
* @globalv WORD | gsSegList |Selector of first segment in allocated list
* @globalv LPEVENT | glpFreeEventList | List of free 4-byte events
* @globalv LPEVENT | glpFreeBigEventList | List of free 4-byte events
*/
#include <windows.h>
#include <mmsystem.h>
#include <memory.h>
#include "dmusic16.h"
#include "debug.h"
STATIC WORD gsSegList;
STATIC LPEVENT glpFreeEventList;
STATIC LPEVENT glpFreeBigEventList;
/* Given a far pointer, get its selector.
*/
#define SEL_OF(lp) (WORD)((((DWORD)lp) >> 16) & 0xffff)
/* Given a far event pointer, get the far pointer to its segment headear.
*/
#define SEGHDR_OF(lp) ((LPSEGHDR)(((DWORD)lp) & 0xffff0000l))
STATIC BOOL RefillEventList(VOID);
STATIC LPSEGHDR AllocSeg(WORD cbSeg);
STATIC VOID FreeBigEvents(VOID);
STATIC VOID FreeSeg(LPSEGHDR lpSeg);
/* @func Called at DLL LibInit
*
* @comm
* Initializes all free lists to empty.
*
*/
VOID PASCAL
AllocOnLoad(VOID)
{
gsSegList = 0;
glpFreeEventList = NULL;
glpFreeBigEventList = NULL;
}
/* @func Called at DLL LibExit
*
* @comm
* Unlock and free all of the memory allocated.
*
* AllocOnUnload jettisons all memory the allocator has ever allocated.
* It assumes that all pointers to events will no longer ever be touched (i.e. all callbacks must
* have already been disabled by this point).
*/
VOID PASCAL
AllocOnExit(VOID)
{
WORD sSel;
WORD sSelNext;
LPSEGHDR lpSeg;
sSel = gsSegList;
while (sSel)
{
lpSeg = (LPSEGHDR)(((DWORD)sSel) << 16);
sSelNext = lpSeg->selNext;
FreeSeg(lpSeg);
sSel = sSelNext;
}
/* This just invalidated both free lists as well as the segment list
*/
gsSegList = 0;
glpFreeEventList = NULL;
glpFreeBigEventList = NULL;
}
/* @func Allocate an event of a given size
*
* @rdesc Returns a far pointer to the event or NULL if memory could not be allocated.
*
* @comm
*
* This function is not callable at interrupt time.
*
* This function is called to allocate a single event. The event will be allocated from
* page-locked memory and filled with the given event data.
*
* Events are classified as normal events, which contain channel messages, and big events,
* which contain SysEx data. The two are distinguished by their size: any event containing
* a DWORD of data or less is a normal event.
*
* Since channel messages comprise most of the MIDI stream, allocation of these events is optimized.
* A segment is allocated containing approximately one page worth (4k) of 4-byte events. These
* events are doled out of a free pool, which only occasionally needs to be refilled from system
* memory.
*
* Big events are allocated on an as-needed basis. When they have been free'd by a call to FreeEvent,
* they are placed on a special free list. This list is used to find memory for future big events,
* and is occasionally free'd back to Windows on a call to AllocEvent in order to minimize the
* amount of page-locked memory in use.
*/
LPEVENT PASCAL
AllocEvent(
DWORD msTime, /* @parm The absolute time based on timeGetTime() of the event */
QUADWORD rtTime, /* @parm The absolute time based on the IRferenceClock in 100ns units */
WORD cbEvent) /* @parm The number of bytes of event data in pbData */
{
LPEVENT lpEvent;
LPEVENT lpEventPrev;
LPEVENT lpEventCurr;
LPSEGHDR lpSeg;
/* Check for big event first (Sysex)
*/
if (cbEvent > sizeof(DWORD))
{
/* First see if we have an event that will work already
*/
lpEventPrev = NULL;
lpEventCurr = glpFreeBigEventList;
while (lpEventCurr)
{
if (SEGHDR_OF(lpEventCurr)->cbSeg >= sizeof(EVENT) + cbEvent)
{
break;
}
lpEventPrev = lpEventCurr;
lpEventCurr = lpEventCurr->lpNext;
}
if (lpEventCurr)
{
/* Remove this event from the list and use it
*/
if (lpEventPrev)
{
lpEventPrev->lpNext = lpEventCurr->lpNext;
}
else
{
glpFreeBigEventList = lpEventCurr->lpNext;
}
lpEventCurr->lpNext = NULL;
}
else
{
/* Nope, need to allocate one
*/
lpSeg = AllocSeg(sizeof(EVENT) + cbEvent);
if (NULL == lpSeg)
{
return NULL;
}
lpEventCurr = (LPEVENT)(lpSeg + 1);
}
lpEventCurr->msTime = msTime;
lpEventCurr->rtTime = rtTime;
lpEventCurr->wFlags = 0;
lpEventCurr->cbEvent = cbEvent;
return lpEventCurr;
}
/* BUGBUG How often???
*/
FreeBigEvents();
/* Normal event. Pull it off the free list (refill if needed) and fill it in.
*/
if (NULL == glpFreeEventList)
{
if (!RefillEventList())
{
return NULL;
}
}
lpEvent = glpFreeEventList;
glpFreeEventList = lpEvent->lpNext;
lpEvent->msTime = msTime;
lpEvent->rtTime = rtTime;
lpEvent->wFlags = 0;
lpEvent->cbEvent = cbEvent;
return lpEvent;
}
/* @func Free an event back to its appropriate free list
*
* @comm
*
* FreeEvent makes no system calls; it simply places the given event back on the correct
* free list. If the event needs to be actually free'd, that will be done at a later time
* in user mode.
*/
VOID PASCAL
FreeEvent(
LPEVENT lpEvent) /* @parm The event to free */
{
LPSEGHDR lpSeg;
lpSeg = SEGHDR_OF(lpEvent);
if (lpSeg->wFlags & SEG_F_4BYTE_EVENTS)
{
lpEvent->lpNext = glpFreeEventList;
glpFreeEventList = lpEvent;
}
else
{
lpEvent->lpNext = glpFreeBigEventList;
glpFreeBigEventList = lpEvent;
}
}
/* @func Refill the free list of normal events
*
* @rdesc Returns TRUE if the list was refilled or FALSE if there was no memory.
*
* @comm
*
* This routine is not callable from interrupt time.
*
* Allocate one page-sized segment of normal events and add them to the free list.
*
*/
STATIC BOOL
RefillEventList(VOID)
{
LPSEGHDR lpSeg;
LPEVENT lpEvent;
UINT cbEvent;
UINT idx;
cbEvent = sizeof(EVENT) + sizeof(DWORD);
lpSeg = AllocSeg(C_PER_SEG * cbEvent);
if (NULL == lpSeg)
{
return FALSE;
}
lpSeg->wFlags = SEG_F_4BYTE_EVENTS;
/* Put the events into the free pool
*/
lpEvent = (LPEVENT)(lpSeg + 1);
for (idx = C_PER_SEG - 1; idx; --idx)
{
lpEvent->lpNext = (LPEVENT)(((LPBYTE)lpEvent) + cbEvent);
lpEvent = lpEvent->lpNext;
}
lpEvent->lpNext = glpFreeEventList;
glpFreeEventList = (LPEVENT)(lpSeg + 1);
return TRUE;
}
/* @func Free all big events
*
* @comm
*
* This function is not callable at interrupt time.
*
* This function frees all big events on the free big event list. Free big events are those
* with event data sizes of more than one DWORD; they are allocated one event per segment
* as needed rather than being pooled like channel messages.
*
* This function is called every now and then as a side effect of AllocEvent in order to
* free up the page-locked memory associated with completed big events.
*
*/
STATIC VOID
FreeBigEvents(VOID)
{
LPEVENT lpEvent;
LPEVENT lpEventNext;
LPSEGHDR lpSeg;
lpEvent = glpFreeBigEventList;
while (lpEvent)
{
lpEventNext = lpEvent->lpNext;
lpSeg = SEGHDR_OF(lpEvent);
FreeSeg(lpSeg);
lpEvent = lpEventNext;
}
glpFreeBigEventList = NULL;
}
/* @func Allocate a segment and put it into the list of allocated segments.
*
* @rdesc A far pointer to the segment header or NULL if the memory could not be allocated.
*
* @comm
*
* This function is not callable at interrupt time.
*
* This is the lowest-level allocation routine which actually calls Windows to allocate the memory.
* The caller is responsible for carving the memory into one or more events.
*
* The data area of the segment will be filled with zeroes.
*
* Since events are accessed at interrupt time (timeSetEvent callback), the memory is allocated and
* page locked.
*
* This routine also inserts the segment into the global list of allocated segments for cleanup.
*/
STATIC LPSEGHDR
AllocSeg(
WORD cbSeg) /* @parm The size of data needed in the segment, excluding the segment header */
{
HANDLE hSeg;
WORD sSegHdr;
LPSEGHDR lpSeg;
/* Allocate and page-lock a segment
* NOTE: GPTR contains zero-init
*/
cbSeg += sizeof(SEGHDR);
hSeg = GlobalAlloc(GPTR | GMEM_SHARE, cbSeg);
if (0 == hSeg)
{
return NULL;
}
lpSeg = (LPSEGHDR)GlobalLock(hSeg);
if (NULL == lpSeg)
{
GlobalFree(sSegHdr);
return NULL;
}
sSegHdr = SEL_OF(lpSeg);
if (!GlobalSmartPageLock(sSegHdr))
{
GlobalUnlock(sSegHdr);
GlobalFree(sSegHdr);
return NULL;
}
lpSeg->hSeg = hSeg;
lpSeg->cbSeg = cbSeg;
lpSeg->selNext = gsSegList;
gsSegList = sSegHdr;
return lpSeg;
}
/* @func Free a segment back to Windows
*
* @comm
*
* This function is not callable at interrupt time.
*
* Just unlock the segment and free it. The calling cleanup code is assumed to have removed
* the segment from the global list of allocated segments.
*
*/
STATIC VOID FreeSeg(
LPSEGHDR lpSeg) /* @parm The segment to free */
{
WORD sSel = SEL_OF(lpSeg);
HANDLE hSeg;
hSeg = lpSeg->hSeg;
GlobalSmartPageUnlock(sSel);
GlobalUnlock(hSeg);
GlobalFree(hSeg);
}