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|
/* $Id: HGSMIMemAlloc.cpp $ */
/** @file
* VBox Host Guest Shared Memory Interface (HGSMI) - Memory allocator.
*/
/*
* Copyright (C) 2014-2023 Oracle and/or its affiliates.
*
* This file is part of VirtualBox base platform packages, as
* available from https://www.virtualbox.org.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation, in version 3 of the
* License.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see <https://www.gnu.org/licenses>.
*
* SPDX-License-Identifier: GPL-3.0-only
*/
/*
* Memory allocator
* ----------------
*
* Area [0; AreaSize) contains only the data, control structures are separate.
* Block sizes are power of 2: 32B, ..., 1MB
* Area size can be anything and will be divided initially to largest possible free blocks.
*
* The entire area is described by a list of 32 bit block descriptors:
* * bits 0..3 - order, which is log2 size of the block - 5: 2^(0+5) ... 2^(15+5) == 32B .. 1MB
* * bit 4 - 1 for free blocks.
* * bits 5..31 - block offset.
*
* 31 ... 5 | 4 | 3 ... 0
* offset F order
*
* There is a sorted collection of all block descriptors
* (key is the block offset, bits 0...4 do not interfere with sorting).
* Also there are lists of free blocks for each size for fast allocation.
*
*
* Implementation
* --------------
*
* The blocks collection is a sorted linear list.
*
* Initially the entire area consists of one or more largest blocks followed by smaller blocks:
* * 100B area - 64B block with descriptor: 0x00000011
* 32B block with descriptor: 0x00000030
* 4B unused
* * 64K area - one 64K block with descriptor: 0x0000001C
* * 512K area - one 512K block with descriptor: 0x0000001F
*
* When allocating a new block:
* * larger free blocks are splitted when there are no smaller free blocks;
* * smaller free blocks are merged if they can build a requested larger block.
*/
#include <HGSMIMemAlloc.h>
#include <HGSMI.h>
#include <VBoxVideoIPRT.h>
/*
* We do not want assertions in Linux kernel code to reduce symbol dependencies.
*/
#if defined(IN_RING0) && defined(RT_OS_LINUX)
# define HGSMI_ASSERT_RETURN(a, b) if (!(a)) return (b)
# define HGSMI_ASSERT_FAILED() do {} while (0)
# define HGSMI_ASSERT(expr) do {} while (0)
#else
# define HGSMI_ASSERT_RETURN(a, b) AssertReturn(a, b)
# define HGSMI_ASSERT_FAILED() AssertFailed()
# define HGSMI_ASSERT(expr) Assert(expr)
#endif /* !IN_RING0 && RT_OS_LINUX */
DECLINLINE(HGSMIOFFSET) hgsmiMADescriptor(HGSMIOFFSET off, bool fFree, HGSMIOFFSET order)
{
return (off & HGSMI_MA_DESC_OFFSET_MASK) |
(fFree? HGSMI_MA_DESC_FREE_MASK: 0) |
(order & HGSMI_MA_DESC_ORDER_MASK);
}
static void hgsmiMABlockFree(HGSMIMADATA *pMA, HGSMIMABLOCK *pBlock)
{
pMA->env.pfnFree(pMA->env.pvEnv, pBlock);
}
static int hgsmiMABlockAlloc(HGSMIMADATA *pMA, HGSMIMABLOCK **ppBlock)
{
int rc = VINF_SUCCESS;
HGSMIMABLOCK *pBlock = (HGSMIMABLOCK *)pMA->env.pfnAlloc(pMA->env.pvEnv, sizeof(HGSMIMABLOCK));
if (pBlock)
{
RT_ZERO(pBlock->nodeBlock);
*ppBlock = pBlock;
}
else
{
rc = VERR_NO_MEMORY;
}
return rc;
}
/* Divide entire area to free blocks. */
static int hgsmiMAFormat(HGSMIMADATA *pMA)
{
int rc = VINF_SUCCESS;
/* Initial value, it will be updated in the loop below. */
pMA->cbMaxBlock = HGSMI_MA_BLOCK_SIZE_MIN;
pMA->cBlocks = 0;
HGSMISIZE cbBlock = HGSMI_MA_BLOCK_SIZE_MAX;
HGSMISIZE cbRemaining = pMA->area.cbArea;
HGSMIOFFSET off = 0;
while (cbBlock >= HGSMI_MA_BLOCK_SIZE_MIN)
{
/* Build a list of free memory blocks with u32BlockSize. */
uint32_t cBlocks = cbRemaining / cbBlock;
if (cBlocks > 0)
{
if (pMA->cbMaxBlock < cbBlock)
{
pMA->cbMaxBlock = cbBlock;
}
HGSMIOFFSET order = HGSMIMASize2Order(cbBlock);
uint32_t i;
for (i = 0; i < cBlocks; ++i)
{
/* A new free block. */
HGSMIMABLOCK *pBlock;
rc = hgsmiMABlockAlloc(pMA, &pBlock);
if (RT_FAILURE(rc))
{
break;
}
pBlock->descriptor = hgsmiMADescriptor(off, true, order);
RTListAppend(&pMA->listBlocks, &pBlock->nodeBlock);
++pMA->cBlocks;
off += cbBlock;
cbRemaining -= cbBlock;
}
}
if (RT_FAILURE(rc))
{
break;
}
cbBlock /= 2;
}
return rc;
}
static int hgsmiMARebuildFreeLists(HGSMIMADATA *pMA)
{
int rc = VINF_SUCCESS;
HGSMIMABLOCK *pIter;
RTListForEach(&pMA->listBlocks, pIter, HGSMIMABLOCK, nodeBlock)
{
if (HGSMI_MA_DESC_IS_FREE(pIter->descriptor))
{
HGSMIOFFSET order = HGSMI_MA_DESC_ORDER(pIter->descriptor);
RTListAppend(&pMA->aListFreeBlocks[order], &pIter->nodeFree);
}
}
return rc;
}
static int hgsmiMARestore(HGSMIMADATA *pMA, HGSMIOFFSET *paDescriptors, uint32_t cDescriptors, HGSMISIZE cbMaxBlock)
{
int rc = VINF_SUCCESS;
pMA->cbMaxBlock = cbMaxBlock;
pMA->cBlocks = 0;
HGSMISIZE cbRemaining = pMA->area.cbArea;
HGSMIOFFSET off = 0;
uint32_t i;
for (i = 0; i < cDescriptors; ++i)
{
/* Verify the descriptor. */
HGSMISIZE cbBlock = HGSMIMAOrder2Size(HGSMI_MA_DESC_ORDER(paDescriptors[i]));
if ( off != HGSMI_MA_DESC_OFFSET(paDescriptors[i])
|| cbBlock > cbRemaining
|| cbBlock > pMA->cbMaxBlock)
{
rc = VERR_INVALID_PARAMETER;
break;
}
/* A new free block. */
HGSMIMABLOCK *pBlock;
rc = hgsmiMABlockAlloc(pMA, &pBlock);
if (RT_FAILURE(rc))
{
break;
}
pBlock->descriptor = paDescriptors[i];
RTListAppend(&pMA->listBlocks, &pBlock->nodeBlock);
++pMA->cBlocks;
off += cbBlock;
cbRemaining -= cbBlock;
}
return rc;
}
static HGSMIMABLOCK *hgsmiMAGetFreeBlock(HGSMIMADATA *pMA, HGSMIOFFSET order)
{
HGSMIMABLOCK *pBlock = NULL;
HGSMIOFFSET i;
for (i = order; i < RT_ELEMENTS(pMA->aListFreeBlocks); ++i)
{
pBlock = RTListGetFirst(&pMA->aListFreeBlocks[i], HGSMIMABLOCK, nodeFree);
if (pBlock)
{
break;
}
}
if (pBlock)
{
HGSMI_ASSERT_RETURN(HGSMI_MA_DESC_IS_FREE(pBlock->descriptor), NULL);
/* Where the block starts. */
HGSMIOFFSET off = HGSMI_MA_DESC_OFFSET(pBlock->descriptor);
/* 'i' is the order of the block. */
while (i != order)
{
/* A larger block was found and need to be split to 2 smaller blocks. */
HGSMIMABLOCK *pBlock2;
int rc = hgsmiMABlockAlloc(pMA, &pBlock2);
if (RT_FAILURE(rc))
{
pBlock = NULL;
break;
}
/* Create 2 blocks with descreased order. */
--i;
/* Remove from the free list. */
RTListNodeRemove(&pBlock->nodeFree);
pBlock->descriptor = hgsmiMADescriptor(off, true, i);
pBlock2->descriptor = hgsmiMADescriptor(off + HGSMIMAOrder2Size(i), true, i);
/* Update list of all blocks by inserting pBlock2 after pBlock. */
RTListNodeInsertAfter(&pBlock->nodeBlock, &pBlock2->nodeBlock);
++pMA->cBlocks;
/* Update the free list. */
RTListAppend(&pMA->aListFreeBlocks[i], &pBlock->nodeFree);
RTListAppend(&pMA->aListFreeBlocks[i], &pBlock2->nodeFree);
}
}
return pBlock;
}
static void hgsmiMAReformatFreeBlocks(HGSMIMADATA *pMA, HGSMIOFFSET maxId,
HGSMIMABLOCK *pStart, HGSMIMABLOCK *pEnd, HGSMISIZE cbBlocks)
{
int rc = VINF_SUCCESS;
/*
* Blocks starting from pStart until pEnd will be replaced with
* another set of blocks.
*
* The new set will include the block with the required order.
* Since the required order is larger than any existing block,
* it will replace at least two existing blocks.
* The new set will also have minimal possible number of blocks.
* Therefore the new set will have at least one block less.
* Blocks will be updated in place and remaining blocks will be
* deallocated.
*/
HGSMISIZE u32BlockSize = HGSMIMAOrder2Size(maxId);
HGSMISIZE cbRemaining = cbBlocks;
HGSMIOFFSET off = HGSMI_MA_DESC_OFFSET(pStart->descriptor);
HGSMIMABLOCK *pBlock = pStart;
while (u32BlockSize >= HGSMI_MA_BLOCK_SIZE_MIN && cbRemaining)
{
/* Build a list of free memory blocks with u32BlockSize. */
uint32_t cBlocks = cbRemaining / u32BlockSize;
if (cBlocks > 0)
{
HGSMIOFFSET order = HGSMIMASize2Order(u32BlockSize);
uint32_t i;
for (i = 0; i < cBlocks; ++i)
{
if (pBlock == pEnd)
{
/* Should never happen because the new set of blocks is supposed to be smaller. */
HGSMI_ASSERT_FAILED();
rc = VERR_OUT_OF_RESOURCES;
break;
}
/* Remove from the free list. */
RTListNodeRemove(&pBlock->nodeFree);
pBlock->descriptor = hgsmiMADescriptor(off, true, order);
RTListAppend(&pMA->aListFreeBlocks[order], &pBlock->nodeFree);
off += u32BlockSize;
cbRemaining -= u32BlockSize;
pBlock = RTListGetNext(&pMA->listBlocks, pBlock, HGSMIMABLOCK, nodeBlock);
}
}
if (RT_FAILURE(rc))
{
break;
}
u32BlockSize /= 2;
}
HGSMI_ASSERT(cbRemaining == 0);
if (RT_SUCCESS(rc))
{
/* Remove remaining free blocks from pBlock until pEnd */
for (;;)
{
bool fEnd = (pBlock == pEnd);
HGSMIMABLOCK *pNext = RTListGetNext(&pMA->listBlocks, pBlock, HGSMIMABLOCK, nodeBlock);
RTListNodeRemove(&pBlock->nodeFree);
RTListNodeRemove(&pBlock->nodeBlock);
--pMA->cBlocks;
hgsmiMABlockFree(pMA, pBlock);
if (fEnd)
{
break;
}
pBlock = pNext;
}
}
}
static void hgsmiMAQueryFreeRange(HGSMIMADATA *pMA, HGSMIMABLOCK *pBlock, HGSMISIZE cbRequired,
HGSMIMABLOCK **ppStart, HGSMIMABLOCK **ppEnd, HGSMISIZE *pcbBlocks)
{
HGSMI_ASSERT(HGSMI_MA_DESC_IS_FREE(pBlock->descriptor));
*pcbBlocks = HGSMIMAOrder2Size(HGSMI_MA_DESC_ORDER(pBlock->descriptor));
*ppStart = pBlock;
*ppEnd = pBlock;
HGSMIMABLOCK *p;
for (;;)
{
p = RTListGetNext(&pMA->listBlocks, *ppEnd, HGSMIMABLOCK, nodeBlock);
if (!p || !HGSMI_MA_DESC_IS_FREE(p->descriptor))
{
break;
}
*pcbBlocks += HGSMIMAOrder2Size(HGSMI_MA_DESC_ORDER(p->descriptor));
*ppEnd = p;
if (cbRequired && *pcbBlocks >= cbRequired)
{
return;
}
}
for (;;)
{
p = RTListGetPrev(&pMA->listBlocks, *ppStart, HGSMIMABLOCK, nodeBlock);
if (!p || !HGSMI_MA_DESC_IS_FREE(p->descriptor))
{
break;
}
*pcbBlocks += HGSMIMAOrder2Size(HGSMI_MA_DESC_ORDER(p->descriptor));
*ppStart = p;
if (cbRequired && *pcbBlocks >= cbRequired)
{
return;
}
}
}
static void hgsmiMAMergeFreeBlocks(HGSMIMADATA *pMA, HGSMIOFFSET order)
{
/* Try to create a free block with the order from smaller free blocks. */
if (order == 0)
{
/* No smaller blocks. */
return;
}
HGSMISIZE cbRequired = HGSMIMAOrder2Size(order);
/* Scan all free lists of smaller blocks.
*
* Get the sequence of free blocks before and after each free block.
* If possible, re-split the sequence to get the required block and other free block(s).
* If not possible, try the next free block.
*
* Free blocks are scanned from i to 0 orders.
*/
HGSMIOFFSET i = order - 1;
for (;;)
{
HGSMIMABLOCK *pIter;
RTListForEach(&pMA->aListFreeBlocks[i], pIter, HGSMIMABLOCK, nodeFree)
{
HGSMI_ASSERT(HGSMI_MA_DESC_ORDER(pIter->descriptor) == i);
HGSMISIZE cbBlocks;
HGSMIMABLOCK *pFreeStart;
HGSMIMABLOCK *pFreeEnd;
hgsmiMAQueryFreeRange(pMA, pIter, cbRequired, &pFreeStart, &pFreeEnd, &cbBlocks);
HGSMI_ASSERT((cbBlocks / HGSMI_MA_BLOCK_SIZE_MIN) * HGSMI_MA_BLOCK_SIZE_MIN == cbBlocks);
/* Verify whether cbBlocks is enough for the requested block. */
if (cbBlocks >= cbRequired)
{
/* Build new free blocks starting from the requested. */
hgsmiMAReformatFreeBlocks(pMA, order, pFreeStart, pFreeEnd, cbBlocks);
i = 0; /* Leave the loop. */
break;
}
}
if (i == 0)
{
break;
}
--i;
}
}
static HGSMIOFFSET hgsmiMAAlloc(HGSMIMADATA *pMA, HGSMISIZE cb)
{
if (cb > pMA->cbMaxBlock)
{
return HGSMIOFFSET_VOID;
}
if (cb < HGSMI_MA_BLOCK_SIZE_MIN)
{
cb = HGSMI_MA_BLOCK_SIZE_MIN;
}
HGSMIOFFSET order = HGSMIPopCnt32(cb - 1) - HGSMI_MA_DESC_ORDER_BASE;
HGSMI_ASSERT_RETURN(HGSMIMAOrder2Size(order) >= cb, HGSMIOFFSET_VOID);
HGSMI_ASSERT_RETURN(order < RT_ELEMENTS(pMA->aListFreeBlocks), HGSMIOFFSET_VOID);
HGSMIMABLOCK *pBlock = hgsmiMAGetFreeBlock(pMA, order);
if (RT_UNLIKELY(pBlock == NULL))
{
/* No free block with large enough size. Merge smaller free blocks and try again. */
hgsmiMAMergeFreeBlocks(pMA, order);
pBlock = hgsmiMAGetFreeBlock(pMA, order);
}
if (RT_LIKELY(pBlock != NULL))
{
RTListNodeRemove(&pBlock->nodeFree);
pBlock->descriptor &= ~HGSMI_MA_DESC_FREE_MASK;
return HGSMI_MA_DESC_OFFSET(pBlock->descriptor);
}
return HGSMIOFFSET_VOID;
}
static void hgsmiMAFree(HGSMIMADATA *pMA, HGSMIOFFSET off)
{
if (off == HGSMIOFFSET_VOID)
{
return;
}
/* Find the block corresponding to the offset. */
HGSMI_ASSERT((off / HGSMI_MA_BLOCK_SIZE_MIN) * HGSMI_MA_BLOCK_SIZE_MIN == off);
HGSMIMABLOCK *pBlock = HGSMIMASearchOffset(pMA, off);
if (pBlock)
{
if (HGSMI_MA_DESC_OFFSET(pBlock->descriptor) == off)
{
/* Found the right block, mark it as free. */
pBlock->descriptor |= HGSMI_MA_DESC_FREE_MASK;
RTListAppend(&pMA->aListFreeBlocks[HGSMI_MA_DESC_ORDER(pBlock->descriptor)], &pBlock->nodeFree);
return;
}
}
HGSMI_ASSERT_FAILED();
}
int HGSMIMAInit(HGSMIMADATA *pMA, const HGSMIAREA *pArea,
HGSMIOFFSET *paDescriptors, uint32_t cDescriptors, HGSMISIZE cbMaxBlock,
const HGSMIENV *pEnv)
{
HGSMI_ASSERT_RETURN(pArea->cbArea < UINT32_C(0x80000000), VERR_INVALID_PARAMETER);
HGSMI_ASSERT_RETURN(pArea->cbArea >= HGSMI_MA_BLOCK_SIZE_MIN, VERR_INVALID_PARAMETER);
RT_ZERO(*pMA);
HGSMISIZE cb = (pArea->cbArea / HGSMI_MA_BLOCK_SIZE_MIN) * HGSMI_MA_BLOCK_SIZE_MIN;
int rc = HGSMIAreaInitialize(&pMA->area, pArea->pu8Base, cb, 0);
if (RT_SUCCESS(rc))
{
pMA->env = *pEnv;
uint32_t i;
for (i = 0; i < RT_ELEMENTS(pMA->aListFreeBlocks); ++i)
{
RTListInit(&pMA->aListFreeBlocks[i]);
}
RTListInit(&pMA->listBlocks);
if (cDescriptors)
{
rc = hgsmiMARestore(pMA, paDescriptors, cDescriptors, cbMaxBlock);
}
else
{
rc = hgsmiMAFormat(pMA);
}
if (RT_SUCCESS(rc))
{
rc = hgsmiMARebuildFreeLists(pMA);
}
}
return rc;
}
void HGSMIMAUninit(HGSMIMADATA *pMA)
{
HGSMIMABLOCK *pIter;
HGSMIMABLOCK *pNext;
/* If it has been initialized. */
if (pMA->listBlocks.pNext)
{
RTListForEachSafe(&pMA->listBlocks, pIter, pNext, HGSMIMABLOCK, nodeBlock)
{
RTListNodeRemove(&pIter->nodeBlock);
hgsmiMABlockFree(pMA, pIter);
}
}
RT_ZERO(*pMA);
}
HGSMIOFFSET HGSMIMAPointerToOffset(const HGSMIMADATA *pMA, const void RT_UNTRUSTED_VOLATILE_GUEST *pv)
{
uintptr_t off = (uintptr_t)pv - (uintptr_t)pMA->area.pu8Base;
if (off < pMA->area.cbArea)
return pMA->area.offBase + off;
HGSMI_ASSERT_FAILED();
return HGSMIOFFSET_VOID;
}
static void RT_UNTRUSTED_VOLATILE_HSTGST *HGSMIMAOffsetToPointer(const HGSMIMADATA *pMA, HGSMIOFFSET off)
{
if (HGSMIAreaContainsOffset(&pMA->area, off))
{
return HGSMIOffsetToPointer(&pMA->area, off);
}
HGSMI_ASSERT_FAILED();
return NULL;
}
void RT_UNTRUSTED_VOLATILE_HSTGST *HGSMIMAAlloc(HGSMIMADATA *pMA, HGSMISIZE cb)
{
HGSMIOFFSET off = hgsmiMAAlloc(pMA, cb);
return HGSMIMAOffsetToPointer(pMA, off);
}
void HGSMIMAFree(HGSMIMADATA *pMA, void RT_UNTRUSTED_VOLATILE_GUEST *pv)
{
HGSMIOFFSET off = HGSMIMAPointerToOffset(pMA, pv);
if (off != HGSMIOFFSET_VOID)
{
hgsmiMAFree(pMA, off);
}
else
{
HGSMI_ASSERT_FAILED();
}
}
HGSMIMABLOCK *HGSMIMASearchOffset(HGSMIMADATA *pMA, HGSMIOFFSET off)
{
/* Binary search in the block list for the offset. */
HGSMIMABLOCK *pStart = RTListGetFirst(&pMA->listBlocks, HGSMIMABLOCK, nodeBlock);
HGSMIMABLOCK *pEnd = RTListGetLast(&pMA->listBlocks, HGSMIMABLOCK, nodeBlock);
HGSMIMABLOCK *pMiddle;
uint32_t iStart = 0;
uint32_t iEnd = pMA->cBlocks;
uint32_t iMiddle;
for (;;)
{
pMiddle = pStart;
iMiddle = iStart + (iEnd - iStart) / 2;
if (iMiddle == iStart)
{
break;
}
/* Find the block with the iMiddle index. Never go further than pEnd. */
uint32_t i;
for (i = iStart; i < iMiddle && pMiddle != pEnd; ++i)
{
pMiddle = RTListNodeGetNext(&pMiddle->nodeBlock, HGSMIMABLOCK, nodeBlock);
}
HGSMIOFFSET offMiddle = HGSMI_MA_DESC_OFFSET(pMiddle->descriptor);
if (offMiddle > off)
{
pEnd = pMiddle;
iEnd = iMiddle;
}
else
{
pStart = pMiddle;
iStart = iMiddle;
}
}
return pMiddle;
}
/*
* Helper.
*/
uint32_t HGSMIPopCnt32(uint32_t u32)
{
uint32_t c = 0;
if (u32 > 0xFFFF) { c += 16; u32 >>= 16; }
if (u32 > 0xFF) { c += 8; u32 >>= 8; }
if (u32 > 0xF) { c += 4; u32 >>= 4; }
if (u32 > 0x3) { c += 2; u32 >>= 2; }
if (u32 > 0x1) { c += 1; u32 >>= 1; }
return c + u32;
}
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