/* poolmvff.c: First Fit Manual Variable Pool
*
* $Id: //info.ravenbrook.com/project/mps/version/1.111/code/poolmvff.c#1 $
* Copyright (c) 2001 Ravenbrook Limited. See end of file for license.
* Portions copyright (C) 2002 Global Graphics Software.
*
* .purpose: This is a pool class for manually managed objects of
* variable size where address-ordered first fit is an appropriate
* policy. Provision is made to allocate in reverse. This pool
* can allocate across segment boundaries.
*
* .design:
*
*
* TRANSGRESSIONS
*
* .trans.stat: mps_mvff_stat is a temporary hack for measurement purposes,
* see .stat below.
*/
#include "mpscmvff.h"
#include "dbgpool.h"
#include "cbs.h"
#include "mpm.h"
SRCID(poolmvff, "$Id: //info.ravenbrook.com/project/mps/version/1.111/code/poolmvff.c#1 $");
/* Would go in poolmvff.h if the class had any MPS-internal clients. */
extern PoolClass PoolClassMVFF(void);
/* MVFFStruct -- MVFF (Manual Variable First Fit) pool outer structure
*
* The signature is placed at the end, see
*
*/
#define MVFFSig ((Sig)0x5193FFF9) /* SIGnature MVFF */
typedef struct MVFFStruct *MVFF;
typedef struct MVFFStruct { /* MVFF pool outer structure */
PoolStruct poolStruct; /* generic structure */
SegPref segPref; /* the preferences for segments */
Size extendBy; /* segment size to extend pool by */
Size minSegSize; /* minimum size of segment */
Size avgSize; /* client estimate of allocation size */
Size total; /* total bytes in pool */
Size free; /* total free bytes in pool */
CBSStruct cbsStruct; /* free list */
Bool firstFit; /* as opposed to last fit */
Bool slotHigh; /* prefers high part of large block */
Sig sig; /* */
} MVFFStruct;
#define Pool2MVFF(pool) PARENT(MVFFStruct, poolStruct, pool)
#define MVFF2Pool(mvff) (&((mvff)->poolStruct))
#define CBSOfMVFF(mvff) (&((mvff)->cbsStruct))
#define MVFFOfCBS(cbs) PARENT(MVFFStruct, cbsStruct, cbs)
static Bool MVFFCheck(MVFF mvff);
/* MVFFDebug -- MVFFDebug class */
typedef struct MVFFDebugStruct {
MVFFStruct mvffStruct; /* MVFF structure */
PoolDebugMixinStruct debug; /* debug mixin */
} MVFFDebugStruct;
typedef MVFFDebugStruct *MVFFDebug;
#define MVFF2MVFFDebug(mvff) PARENT(MVFFDebugStruct, mvffStruct, mvff)
#define MVFFDebug2MVFF(mvffd) (&((mvffd)->mvffStruct))
/* MVFFAddToFreeList -- Add given range to free list
*
* Updates MVFF counters for additional free space. Returns maximally
* coalesced range containing given range. Does not attempt to free
* segments (see MVFFFreeSegs). Cannot(!) fail.
*/
static void MVFFAddToFreeList(Addr *baseIO, Addr *limitIO, MVFF mvff) {
Res res;
Addr base, limit;
AVER(baseIO != NULL);
AVER(limitIO != NULL);
AVERT(MVFF, mvff);
base = *baseIO;
limit = *limitIO;
AVER(limit > base);
res = CBSInsertReturningRange(baseIO, limitIO, CBSOfMVFF(mvff), base, limit);
AVER(res == ResOK);
mvff->free += AddrOffset(base, limit);
return;
}
/* MVFFFreeSegs -- Free segments from given range
*
* Given a free range, attempts to find entire segments within
* it, and returns them to the arena, updating total size counter.
*
* This is usually called immediately after MVFFAddToFreeList.
* It is not combined with MVFFAddToFreeList because the latter
* is also called when new segments are added under MVFFAlloc.
*/
static void MVFFFreeSegs(MVFF mvff, Addr base, Addr limit)
{
Seg seg = NULL; /* suppress "may be used uninitialized" */
Arena arena;
Bool b;
Addr segLimit; /* limit of the current segment when iterating */
Addr segBase; /* base of the current segment when iterating */
Res res;
AVERT(MVFF, mvff);
AVER(base < limit);
/* Could profitably AVER that the given range is free, */
/* but the CBS doesn't provide that facility. */
if (AddrOffset(base, limit) < mvff->minSegSize)
return; /* not large enough for entire segments */
arena = PoolArena(MVFF2Pool(mvff));
b = SegOfAddr(&seg, arena, base);
AVER(b);
segBase = SegBase(seg);
segLimit = SegLimit(seg);
while(segLimit <= limit) { /* segment ends in range */
if (segBase >= base) { /* segment starts in range */
/* Must remove from free list first, in case free list */
/* is using inline data structures. */
res = CBSDelete(CBSOfMVFF(mvff), segBase, segLimit);
AVER(res == ResOK);
mvff->free -= AddrOffset(segBase, segLimit);
mvff->total -= AddrOffset(segBase, segLimit);
SegFree(seg);
}
/* Avoid calling SegNext if the next segment would fail */
/* the loop test, mainly because there might not be a */
/* next segment. */
if (segLimit == limit) /* segment ends at end of range */
break;
b = SegNext(&seg, arena, segBase);
AVER(b);
segBase = SegBase(seg);
segLimit = SegLimit(seg);
}
return;
}
/* MVFFAddSeg -- Allocates a new segment from the arena
*
* Allocates a new segment from the arena (with the given
* withReservoirPermit flag) of at least the specified size. The
* specified size should be pool-aligned. Adds it to the free list.
*/
static Res MVFFAddSeg(Seg *segReturn,
MVFF mvff, Size size, Bool withReservoirPermit)
{
Pool pool;
Arena arena;
Size segSize;
Seg seg;
Res res;
Align align;
Addr base, limit;
AVERT(MVFF, mvff);
AVER(size > 0);
AVER(BoolCheck(withReservoirPermit));
pool = MVFF2Pool(mvff);
arena = PoolArena(pool);
align = ArenaAlign(arena);
AVER(SizeIsAligned(size, PoolAlignment(pool)));
/* Use extendBy unless it's too small (see */
/* ). */
if (size <= mvff->extendBy)
segSize = mvff->extendBy;
else
segSize = size;
segSize = SizeAlignUp(segSize, align);
res = SegAlloc(&seg, SegClassGet(), mvff->segPref, segSize, pool,
withReservoirPermit);
if (res != ResOK) {
/* try again for a seg just large enough for object */
/* see */
segSize = SizeAlignUp(size, align);
res = SegAlloc(&seg, SegClassGet(), mvff->segPref, segSize, pool,
withReservoirPermit);
if (res != ResOK) {
return res;
}
}
mvff->total += segSize;
base = SegBase(seg); limit = AddrAdd(base, segSize);
DebugPoolFreeSplat(pool, base, limit);
MVFFAddToFreeList(&base, &limit, mvff);
AVER(base <= SegBase(seg));
if (mvff->minSegSize > segSize) mvff->minSegSize = segSize;
/* Don't call MVFFFreeSegs; that would be silly. */
*segReturn = seg;
return ResOK;
}
/* MVFFFindFirstFree -- Finds the first (or last) suitable free block
*
* Finds a free block of the given (pool aligned) size, according
* to a first (or last) fit policy controlled by the MVFF fields
* firstFit, slotHigh (for whether to allocate the top or bottom
* portion of a larger block).
*
* Will return FALSE if the free list has no large enough block.
* In particular, will not attempt to allocate a new segment.
*/
static Bool MVFFFindFirstFree(Addr *baseReturn, Addr *limitReturn,
MVFF mvff, Size size)
{
Bool foundBlock;
CBSFindDelete findDelete;
AVER(baseReturn != NULL);
AVER(limitReturn != NULL);
AVERT(MVFF, mvff);
AVER(size > 0);
AVER(SizeIsAligned(size, PoolAlignment(MVFF2Pool(mvff))));
findDelete = mvff->slotHigh ? CBSFindDeleteHIGH : CBSFindDeleteLOW;
foundBlock =
(mvff->firstFit ? CBSFindFirst : CBSFindLast)
(baseReturn, limitReturn, CBSOfMVFF(mvff), size, findDelete);
if (foundBlock)
mvff->free -= size;
return foundBlock;
}
/* MVFFAlloc -- Allocate a block */
static Res MVFFAlloc(Addr *aReturn, Pool pool, Size size,
Bool withReservoirPermit)
{
Res res;
MVFF mvff;
Addr base, limit;
Bool foundBlock;
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
AVER(aReturn != NULL);
AVER(size > 0);
AVER(BoolCheck(withReservoirPermit));
size = SizeAlignUp(size, PoolAlignment(pool));
foundBlock = MVFFFindFirstFree(&base, &limit, mvff, size);
if (!foundBlock) {
Seg seg;
res = MVFFAddSeg(&seg, mvff, size, withReservoirPermit);
if (res != ResOK)
return res;
foundBlock = MVFFFindFirstFree(&base, &limit, mvff, size);
/* We know that the found range must intersect the new segment. */
/* In particular, it doesn't necessarily lie entirely within it. */
/* The next three AVERs test for intersection of two intervals. */
AVER(base >= SegBase(seg) || limit <= SegLimit(seg));
AVER(base < SegLimit(seg));
AVER(SegBase(seg) < limit);
/* We also know that the found range is no larger than the segment. */
AVER(SegSize(seg) >= AddrOffset(base, limit));
}
AVER(foundBlock);
AVER(AddrOffset(base, limit) == size);
*aReturn = base;
return ResOK;
}
/* MVFFFree -- free the given block */
static void MVFFFree(Pool pool, Addr old, Size size)
{
Addr base, limit;
MVFF mvff;
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
AVER(old != (Addr)0);
AVER(AddrIsAligned(old, PoolAlignment(pool)));
AVER(size > 0);
size = SizeAlignUp(size, PoolAlignment(pool));
base = old;
limit = AddrAdd(base, size);
MVFFAddToFreeList(&base, &limit, mvff);
MVFFFreeSegs(mvff, base, limit);
}
/* MVFFBufferFill -- Fill the buffer
*
* Fill it with the largest block we can find.
*/
static Res MVFFBufferFill(Addr *baseReturn, Addr *limitReturn,
Pool pool, Buffer buffer, Size size,
Bool withReservoirPermit)
{
Res res;
MVFF mvff;
Addr base, limit;
Bool foundBlock;
Seg seg = NULL;
AVER(baseReturn != NULL);
AVER(limitReturn != NULL);
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
AVERT(Buffer, buffer);
AVER(size > 0);
AVER(SizeIsAligned(size, PoolAlignment(pool)));
AVERT(Bool, withReservoirPermit);
/* Hoping the largest is big enough, delete it and return if small. */
foundBlock = CBSFindLargest(&base, &limit, CBSOfMVFF(mvff),
CBSFindDeleteENTIRE);
if (foundBlock && AddrOffset(base, limit) < size) {
foundBlock = FALSE;
res = CBSInsert(CBSOfMVFF(mvff), base, limit);
AVER(res == ResOK);
}
if (!foundBlock) {
res = MVFFAddSeg(&seg, mvff, size, withReservoirPermit);
if (res != ResOK)
return res;
foundBlock = CBSFindLargest(&base, &limit, CBSOfMVFF(mvff),
CBSFindDeleteENTIRE);
AVER(foundBlock); /* We will find the new segment. */
}
AVER(AddrOffset(base, limit) >= size);
mvff->free -= AddrOffset(base, limit);
*baseReturn = base;
*limitReturn = limit;
return ResOK;
}
/* MVFFBufferEmpty -- return unused portion of this buffer */
static void MVFFBufferEmpty(Pool pool, Buffer buffer,
Addr base, Addr limit)
{
MVFF mvff;
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
AVERT(Buffer, buffer);
AVER(BufferIsReady(buffer));
AVER(base <= limit);
if (base == limit)
return;
MVFFAddToFreeList(&base, &limit, mvff);
MVFFFreeSegs(mvff, base, limit);
return;
}
/* MVFFInit -- initialize method for MVFF */
static Res MVFFInit(Pool pool, va_list arg)
{
Size extendBy, avgSize, align;
Bool slotHigh, arenaHigh, firstFit;
MVFF mvff;
Arena arena;
Res res;
void *p;
ZoneSet zones;
AVERT(Pool, pool);
/* .arg: class-specific additional arguments; see */
/* */
/* .arg.check: we do the same checks here and in MVFFCheck */
/* except for arenaHigh, which is stored only in the segPref. */
extendBy = va_arg(arg, Size);
avgSize = va_arg(arg, Size);
align = va_arg(arg, Size);
slotHigh = va_arg(arg, Bool);
arenaHigh = va_arg(arg, Bool);
firstFit = va_arg(arg, Bool);
AVER(extendBy > 0); /* .arg.check */
AVER(avgSize > 0); /* .arg.check */
AVER(avgSize <= extendBy); /* .arg.check */
AVER(BoolCheck(slotHigh));
AVER(BoolCheck(arenaHigh));
AVER(BoolCheck(firstFit));
mvff = Pool2MVFF(pool);
arena = PoolArena(pool);
mvff->extendBy = extendBy;
if (extendBy < ArenaAlign(arena))
mvff->minSegSize = ArenaAlign(arena);
else
mvff->minSegSize = extendBy;
mvff->avgSize = avgSize;
pool->alignment = align;
mvff->slotHigh = slotHigh;
mvff->firstFit = firstFit;
res = ControlAlloc(&p, arena, sizeof(SegPrefStruct), FALSE);
if (res != ResOK)
return res;
mvff->segPref = (SegPref)p;
*mvff->segPref = *SegPrefDefault();
SegPrefExpress(mvff->segPref, arenaHigh ? SegPrefHigh : SegPrefLow, NULL);
/* If using zoneset placement, just put it apart from the others. */
zones = ZoneSetComp(ArenaDefaultZONESET);
SegPrefExpress(mvff->segPref, SegPrefZoneSet, (void *)&zones);
mvff->total = 0;
mvff->free = 0;
res = CBSInit(arena, CBSOfMVFF(mvff), (void *)mvff, NULL, NULL, NULL, NULL,
mvff->extendBy, align, TRUE, TRUE);
if (res != ResOK)
goto failInit;
mvff->sig = MVFFSig;
AVERT(MVFF, mvff);
EVENT8(PoolInitMVFF, pool, arena, extendBy, avgSize, align,
slotHigh, arenaHigh, firstFit);
return ResOK;
failInit:
ControlFree(arena, p, sizeof(SegPrefStruct));
return res;
}
/* MVFFFinish -- finish method for MVFF */
static void MVFFFinish(Pool pool)
{
MVFF mvff;
Arena arena;
Seg seg;
Ring ring, node, nextNode;
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
ring = PoolSegRing(pool);
RING_FOR(node, ring, nextNode) {
seg = SegOfPoolRing(node);
AVER(SegPool(seg) == pool);
SegFree(seg);
}
/* Could maintain mvff->total here and check it falls to zero, */
/* but that would just make the function slow. If only we had */
/* a way to do operations only if AVERs are turned on. */
arena = PoolArena(pool);
ControlFree(arena, mvff->segPref, sizeof(SegPrefStruct));
CBSFinish(CBSOfMVFF(mvff));
mvff->sig = SigInvalid;
}
/* MVFFDebugMixin - find debug mixin in class MVFFDebug */
static PoolDebugMixin MVFFDebugMixin(Pool pool)
{
MVFF mvff;
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
/* Can't check MVFFDebug, because this is called during init */
return &(MVFF2MVFFDebug(mvff)->debug);
}
/* MVFFDescribe -- describe an MVFF pool */
static Res MVFFDescribe(Pool pool, mps_lib_FILE *stream)
{
Res res;
MVFF mvff;
if (!TESTT(Pool, pool)) return ResFAIL;
mvff = Pool2MVFF(pool);
if (!TESTT(MVFF, mvff)) return ResFAIL;
if (stream == NULL) return ResFAIL;
res = WriteF(stream,
"MVFF $P {\n", (WriteFP)mvff,
" pool $P ($U)\n",
(WriteFP)pool, (WriteFU)pool->serial,
" extendBy $W\n", (WriteFW)mvff->extendBy,
" avgSize $W\n", (WriteFW)mvff->avgSize,
" total $U\n", (WriteFU)mvff->total,
" free $U\n", (WriteFU)mvff->free,
NULL);
if (res != ResOK)
return res;
res = CBSDescribe(CBSOfMVFF(mvff), stream);
if (res != ResOK)
return res;
res = WriteF(stream, "}\n", NULL);
return res;
}
DEFINE_POOL_CLASS(MVFFPoolClass, this)
{
INHERIT_CLASS(this, AbstractAllocFreePoolClass);
PoolClassMixInBuffer(this);
this->name = "MVFF";
this->size = sizeof(MVFFStruct);
this->offset = offsetof(MVFFStruct, poolStruct);
this->init = MVFFInit;
this->finish = MVFFFinish;
this->alloc = MVFFAlloc;
this->free = MVFFFree;
this->bufferFill = MVFFBufferFill;
this->bufferEmpty = MVFFBufferEmpty;
this->describe = MVFFDescribe;
}
PoolClass PoolClassMVFF(void)
{
return MVFFPoolClassGet();
}
/* Pool class MVFFDebug */
DEFINE_POOL_CLASS(MVFFDebugPoolClass, this)
{
INHERIT_CLASS(this, MVFFPoolClass);
PoolClassMixInDebug(this);
this->name = "MVFFDBG";
this->size = sizeof(MVFFDebugStruct);
this->debugMixin = MVFFDebugMixin;
}
/* MPS Interface Extensions. */
mps_class_t mps_class_mvff(void)
{
return (mps_class_t)(MVFFPoolClassGet());
}
mps_class_t mps_class_mvff_debug(void)
{
return (mps_class_t)(MVFFDebugPoolClassGet());
}
/* Total free bytes. See */
size_t mps_mvff_free_size(mps_pool_t mps_pool)
{
Pool pool;
MVFF mvff;
pool = (Pool)mps_pool;
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
return (size_t)mvff->free;
}
/* Total owned bytes. See */
size_t mps_mvff_size(mps_pool_t mps_pool)
{
Pool pool;
MVFF mvff;
pool = (Pool)mps_pool;
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
return (size_t)mvff->total;
}
/* MVFFCheck -- check the consistency of an MVFF structure */
static Bool MVFFCheck(MVFF mvff)
{
CHECKS(MVFF, mvff);
CHECKD(Pool, MVFF2Pool(mvff));
CHECKL(IsSubclassPoly(MVFF2Pool(mvff)->class, MVFFPoolClassGet()));
CHECKD(SegPref, mvff->segPref);
CHECKL(mvff->extendBy > 0); /* see .arg.check */
CHECKL(mvff->minSegSize >= ArenaAlign(PoolArena(MVFF2Pool(mvff))));
CHECKL(mvff->avgSize > 0); /* see .arg.check */
CHECKL(mvff->avgSize <= mvff->extendBy); /* see .arg.check */
CHECKL(mvff->total >= mvff->free);
CHECKL(SizeIsAligned(mvff->free, PoolAlignment(MVFF2Pool(mvff))));
CHECKL(SizeIsAligned(mvff->total, ArenaAlign(PoolArena(MVFF2Pool(mvff)))));
CHECKD(CBS, CBSOfMVFF(mvff));
CHECKL(BoolCheck(mvff->slotHigh));
CHECKL(BoolCheck(mvff->firstFit));
return TRUE;
}
/* mps_mvff_stat -- a hack to get statistics emitted
*
* .stat: The SW temp pool cannot be destroyed, so we're providing this
* to get the statistics. It breaks modularity to access CBS internals.
*/
#include "meter.h"
extern void mps_mvff_stat(mps_pool_t pool);
void mps_mvff_stat(mps_pool_t mps_pool)
{
Pool pool;
MVFF mvff;
pool = (Pool)mps_pool;
AVERT(Pool, pool);
mvff = Pool2MVFF(pool);
AVERT(MVFF, mvff);
METER_EMIT(&CBSOfMVFF(mvff)->splaySearch);
METER_EMIT(&CBSOfMVFF(mvff)->eblSearch);
METER_EMIT(&CBSOfMVFF(mvff)->eglSearch);
}
/* C. COPYRIGHT AND LICENSE
*
* Copyright (C) 2001-2002 Ravenbrook Limited .
* All rights reserved. This is an open source license. Contact
* Ravenbrook for commercial licensing options.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* 3. Redistributions in any form must be accompanied by information on how
* to obtain complete source code for this software and any accompanying
* software that uses this software. The source code must either be
* included in the distribution or be available for no more than the cost
* of distribution plus a nominal fee, and must be freely redistributable
* under reasonable conditions. For an executable file, complete source
* code means the source code for all modules it contains. It does not
* include source code for modules or files that typically accompany the
* major components of the operating system on which the executable file
* runs.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
* IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR
* PURPOSE, OR NON-INFRINGEMENT, ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT HOLDERS AND CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF
* USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
* ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/