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mariadb/storage/innobase/buf/buf0buddy.cc
Daniel Black b6a2472489 MDEV-27891: SIGSEGV in InnoDB buffer pool resize 
During an increase in resize, the new curr_size got a value
less than old_size.

As n_chunks_new and n_chunks have a strong correlation to the
resizing operation in progress, we can use them and remove the
need for old_size.

For convienece the n_chunks_new < n_chunks is now the is_shrinking
function.

The volatile compiler optimization on n_chunks{,_new} is removed
as real mutex uses are needed.

Other n_chunks_new/n_chunks methods:

n_chunks_new and n_chunks almost always read and altered under
the pool mutex.

Exceptions are:
* i_s_innodb_buffer_page_fill,
* buf_pool_t::is_uncompressed (via is_blocked_field)
These need reexamining for the need of a mutex, however comments
indicates this already.

get_n_pages has uses in buffer pool load, recover log memory
exhaustion estimates and innodb status so take the minimum number
of chunks for safety.

The buf_pool_t::running_out function also uses curr_size/old_size.
We replace this hot function calculation with just n_chunks_new.
This is the new size of the chunks before the resizing occurs.

If we are resizing down, we've already got the case we had previously
(as the minimum). If we are resizing upwards, we are taking an
optimistic view that there will be buffer chunks available for locks.
As this memory allocation is occurring immediately next the resizing
function it seems likely.

Compiler hint UNIV_UNLIKELY removed to leave it to the branch
predictor to make an informed decision.

Added test case of a smaller size than the Marko/Roel original
in JIRA reducing the size to 256M. SEGV hits roughly 1/10 times
but its better than a 21G memory size.

Reviewer: Marko
2022-03-07 13:36:18 +11:00

769 lines
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/*****************************************************************************
Copyright (c) 2006, 2016, Oracle and/or its affiliates. All Rights Reserved.
Copyright (c) 2018, 2021, MariaDB Corporation.
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; version 2 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, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1335 USA
*****************************************************************************/
/**************************************************//**
@file buf/buf0buddy.cc
Binary buddy allocator for compressed pages
Created December 2006 by Marko Makela
*******************************************************/
#include "buf0buddy.h"
#include "buf0buf.h"
#include "buf0lru.h"
#include "buf0flu.h"
#include "page0zip.h"
#include "srv0start.h"
/** When freeing a buf we attempt to coalesce by looking at its buddy
and deciding whether it is free or not. To ascertain if the buddy is
free we look for BUF_BUDDY_STAMP_FREE at BUF_BUDDY_STAMP_OFFSET
within the buddy. The question is how we can be sure that it is
safe to look at BUF_BUDDY_STAMP_OFFSET.
The answer lies in following invariants:
* All blocks allocated by buddy allocator are used for compressed
page frame.
* A compressed table always have space_id < SRV_SPACE_ID_UPPER_BOUND
* BUF_BUDDY_STAMP_OFFSET always points to the space_id field in
a frame.
-- The above is true because we look at these fields when the
corresponding buddy block is free which implies that:
* The block we are looking at must have an address aligned at
the same size that its free buddy has. For example, if we have
a free block of 8K then its buddy's address must be aligned at
8K as well.
* It is possible that the block we are looking at may have been
further divided into smaller sized blocks but its starting
address must still remain the start of a page frame i.e.: it
cannot be middle of a block. For example, if we have a free
block of size 8K then its buddy may be divided into blocks
of, say, 1K, 1K, 2K, 4K but the buddy's address will still be
the starting address of first 1K compressed page.
* What is important to note is that for any given block, the
buddy's address cannot be in the middle of a larger block i.e.:
in above example, our 8K block cannot have a buddy whose address
is aligned on 8K but it is part of a larger 16K block.
*/
/** Offset within buf_buddy_free_t where free or non_free stamps
are written.*/
#define BUF_BUDDY_STAMP_OFFSET FIL_PAGE_ARCH_LOG_NO_OR_SPACE_ID
/** Value that we stamp on all buffers that are currently on the zip_free
list. This value is stamped at BUF_BUDDY_STAMP_OFFSET offset */
#define BUF_BUDDY_STAMP_FREE SRV_SPACE_ID_UPPER_BOUND
/** Stamp value for non-free buffers. Will be overwritten by a non-zero
value by the consumer of the block */
#define BUF_BUDDY_STAMP_NONFREE 0XFFFFFFFFUL
/** Return type of buf_buddy_is_free() */
enum buf_buddy_state_t {
BUF_BUDDY_STATE_FREE, /*!< If the buddy to completely free */
BUF_BUDDY_STATE_USED, /*!< Buddy currently in used */
BUF_BUDDY_STATE_PARTIALLY_USED/*!< Some sub-blocks in the buddy
are in use */
};
/**********************************************************************//**
Invalidate memory area that we won't access while page is free */
UNIV_INLINE
void
buf_buddy_mem_invalid(
/*==================*/
buf_buddy_free_t* buf, /*!< in: block to check */
ulint i) /*!< in: index of zip_free[] */
{
ut_ad(i <= BUF_BUDDY_SIZES);
MEM_CHECK_ADDRESSABLE(buf, BUF_BUDDY_LOW << i);
MEM_UNDEFINED(buf, BUF_BUDDY_LOW << i);
}
/**********************************************************************//**
Check if a buddy is stamped free.
@return whether the buddy is free */
UNIV_INLINE MY_ATTRIBUTE((warn_unused_result))
bool
buf_buddy_stamp_is_free(
/*====================*/
const buf_buddy_free_t* buf) /*!< in: block to check */
{
compile_time_assert(BUF_BUDDY_STAMP_FREE < BUF_BUDDY_STAMP_NONFREE);
return(mach_read_from_4(buf->stamp.bytes + BUF_BUDDY_STAMP_OFFSET)
== BUF_BUDDY_STAMP_FREE);
}
/**********************************************************************//**
Stamps a buddy free. */
UNIV_INLINE
void
buf_buddy_stamp_free(
/*=================*/
buf_buddy_free_t* buf, /*!< in/out: block to stamp */
ulint i) /*!< in: block size */
{
ut_d(memset(&buf->stamp.bytes, int(i), BUF_BUDDY_LOW << i));
buf_buddy_mem_invalid(buf, i);
mach_write_to_4(buf->stamp.bytes + BUF_BUDDY_STAMP_OFFSET,
BUF_BUDDY_STAMP_FREE);
buf->stamp.size = i;
}
/**********************************************************************//**
Stamps a buddy nonfree.
@param[in,out] buf block to stamp
@param[in] i block size */
static inline void buf_buddy_stamp_nonfree(buf_buddy_free_t* buf, ulint i)
{
buf_buddy_mem_invalid(buf, i);
compile_time_assert(BUF_BUDDY_STAMP_NONFREE == 0xffffffffU);
memset(buf->stamp.bytes + BUF_BUDDY_STAMP_OFFSET, 0xff, 4);
}
/**********************************************************************//**
Get the offset of the buddy of a compressed page frame.
@return the buddy relative of page */
UNIV_INLINE
void*
buf_buddy_get(
/*==========*/
byte* page, /*!< in: compressed page */
ulint size) /*!< in: page size in bytes */
{
ut_ad(ut_is_2pow(size));
ut_ad(size >= BUF_BUDDY_LOW);
ut_ad(BUF_BUDDY_LOW <= UNIV_ZIP_SIZE_MIN);
ut_ad(size < BUF_BUDDY_HIGH);
ut_ad(BUF_BUDDY_HIGH == srv_page_size);
ut_ad(!ut_align_offset(page, size));
if (((ulint) page) & size) {
return(page - size);
} else {
return(page + size);
}
}
#ifdef UNIV_DEBUG
/** Validate a given zip_free list. */
struct CheckZipFree {
CheckZipFree(ulint i) : m_i(i) {}
void operator()(const buf_buddy_free_t* elem) const
{
ut_ad(buf_buddy_stamp_is_free(elem));
ut_ad(elem->stamp.size <= m_i);
}
const ulint m_i;
};
/** Validate a buddy list.
@param[in] i buddy size to validate */
static void buf_buddy_list_validate(ulint i)
{
ut_list_validate(buf_pool.zip_free[i], CheckZipFree(i));
}
/**********************************************************************//**
Debug function to validate that a buffer is indeed free i.e.: in the
zip_free[].
@param[in] buf block to check
@param[in] i index of buf_pool.zip_free[]
@return true if free */
static bool buf_buddy_check_free(const buf_buddy_free_t* buf, ulint i)
{
const ulint size = BUF_BUDDY_LOW << i;
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_ad(!ut_align_offset(buf, size));
ut_ad(i >= buf_buddy_get_slot(UNIV_ZIP_SIZE_MIN));
buf_buddy_free_t* itr;
for (itr = UT_LIST_GET_FIRST(buf_pool.zip_free[i]);
itr && itr != buf;
itr = UT_LIST_GET_NEXT(list, itr)) {
}
return(itr == buf);
}
#endif /* UNIV_DEBUG */
/**********************************************************************//**
Checks if a buf is free i.e.: in the zip_free[].
@retval BUF_BUDDY_STATE_FREE if fully free
@retval BUF_BUDDY_STATE_USED if currently in use
@retval BUF_BUDDY_STATE_PARTIALLY_USED if partially in use. */
static MY_ATTRIBUTE((warn_unused_result))
buf_buddy_state_t
buf_buddy_is_free(
/*==============*/
buf_buddy_free_t* buf, /*!< in: block to check */
ulint i) /*!< in: index of
buf_pool.zip_free[] */
{
#ifdef UNIV_DEBUG
const ulint size = BUF_BUDDY_LOW << i;
ut_ad(!ut_align_offset(buf, size));
ut_ad(i >= buf_buddy_get_slot(UNIV_ZIP_SIZE_MIN));
#endif /* UNIV_DEBUG */
/* We assume that all memory from buf_buddy_alloc()
is used for compressed page frames. */
/* We look inside the allocated objects returned by
buf_buddy_alloc() and assume that each block is a compressed
page that contains one of the following in space_id.
* BUF_BUDDY_STAMP_FREE if the block is in a zip_free list or
* BUF_BUDDY_STAMP_NONFREE if the block has been allocated but
not initialized yet or
* A valid space_id of a compressed tablespace
The call below attempts to read from free memory. The memory
is "owned" by the buddy allocator (and it has been allocated
from the buffer pool), so there is nothing wrong about this. */
if (!buf_buddy_stamp_is_free(buf)) {
return(BUF_BUDDY_STATE_USED);
}
/* A block may be free but a fragment of it may still be in use.
To guard against that we write the free block size in terms of
zip_free index at start of stamped block. Note that we can
safely rely on this value only if the buf is free. */
ut_ad(buf->stamp.size <= i);
return(buf->stamp.size == i
? BUF_BUDDY_STATE_FREE
: BUF_BUDDY_STATE_PARTIALLY_USED);
}
/** Add a block to the head of the appropriate buddy free list.
@param[in,out] buf block to be freed
@param[in] i index of buf_pool.zip_free[] */
UNIV_INLINE
void
buf_buddy_add_to_free(buf_buddy_free_t* buf, ulint i)
{
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_ad(buf_pool.zip_free[i].start != buf);
buf_buddy_stamp_free(buf, i);
UT_LIST_ADD_FIRST(buf_pool.zip_free[i], buf);
ut_d(buf_buddy_list_validate(i));
}
/** Remove a block from the appropriate buddy free list.
@param[in,out] buf block to be freed
@param[in] i index of buf_pool.zip_free[] */
UNIV_INLINE
void
buf_buddy_remove_from_free(buf_buddy_free_t* buf, ulint i)
{
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_ad(buf_buddy_check_free(buf, i));
UT_LIST_REMOVE(buf_pool.zip_free[i], buf);
buf_buddy_stamp_nonfree(buf, i);
}
/** Try to allocate a block from buf_pool.zip_free[].
@param[in] i index of buf_pool.zip_free[]
@return allocated block, or NULL if buf_pool.zip_free[] was empty */
static buf_buddy_free_t* buf_buddy_alloc_zip(ulint i)
{
buf_buddy_free_t* buf;
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_a(i < BUF_BUDDY_SIZES);
ut_a(i >= buf_buddy_get_slot(UNIV_ZIP_SIZE_MIN));
ut_d(buf_buddy_list_validate(i));
buf = UT_LIST_GET_FIRST(buf_pool.zip_free[i]);
if (buf_pool.is_shrinking()
&& UT_LIST_GET_LEN(buf_pool.withdraw)
< buf_pool.withdraw_target) {
while (buf != NULL
&& buf_pool.will_be_withdrawn(
reinterpret_cast<byte*>(buf))) {
/* This should be withdrawn, not to be allocated */
buf = UT_LIST_GET_NEXT(list, buf);
}
}
if (buf) {
buf_buddy_remove_from_free(buf, i);
} else if (i + 1 < BUF_BUDDY_SIZES) {
/* Attempt to split. */
buf = buf_buddy_alloc_zip(i + 1);
if (buf) {
buf_buddy_free_t* buddy =
reinterpret_cast<buf_buddy_free_t*>(
reinterpret_cast<byte*>(buf)
+ (BUF_BUDDY_LOW << i));
ut_ad(!buf_pool.contains_zip(buddy));
buf_buddy_add_to_free(buddy, i);
}
}
if (buf) {
/* Trash the page other than the BUF_BUDDY_STAMP_NONFREE. */
MEM_UNDEFINED(buf, BUF_BUDDY_STAMP_OFFSET);
MEM_UNDEFINED(BUF_BUDDY_STAMP_OFFSET + 4 + buf->stamp.bytes,
(BUF_BUDDY_LOW << i)
- (BUF_BUDDY_STAMP_OFFSET + 4));
ut_ad(mach_read_from_4(buf->stamp.bytes
+ BUF_BUDDY_STAMP_OFFSET)
== BUF_BUDDY_STAMP_NONFREE);
}
return(buf);
}
/** Deallocate a buffer frame of srv_page_size.
@param[in] buf buffer frame to deallocate */
static
void
buf_buddy_block_free(void* buf)
{
const ulint fold = BUF_POOL_ZIP_FOLD_PTR(buf);
buf_page_t* bpage;
buf_block_t* block;
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_a(!ut_align_offset(buf, srv_page_size));
HASH_SEARCH(hash, &buf_pool.zip_hash, fold, buf_page_t*, bpage,
ut_ad(bpage->state() == buf_page_t::MEMORY
&& bpage->in_zip_hash),
bpage->frame == buf);
ut_a(bpage);
ut_a(bpage->state() == buf_page_t::MEMORY);
ut_ad(bpage->in_zip_hash);
ut_d(bpage->in_zip_hash = false);
HASH_DELETE(buf_page_t, hash, &buf_pool.zip_hash, fold, bpage);
bpage->hash = nullptr;
ut_d(memset(buf, 0, srv_page_size));
MEM_UNDEFINED(buf, srv_page_size);
block = (buf_block_t*) bpage;
buf_LRU_block_free_non_file_page(block);
ut_ad(buf_pool.buddy_n_frames > 0);
ut_d(buf_pool.buddy_n_frames--);
}
/**********************************************************************//**
Allocate a buffer block to the buddy allocator. */
static
void
buf_buddy_block_register(
/*=====================*/
buf_block_t* block) /*!< in: buffer frame to allocate */
{
const ulint fold = BUF_POOL_ZIP_FOLD(block);
ut_ad(block->page.state() == buf_page_t::MEMORY);
ut_a(block->page.frame);
ut_a(!ut_align_offset(block->page.frame, srv_page_size));
ut_ad(!block->page.in_zip_hash);
ut_d(block->page.in_zip_hash = true);
HASH_INSERT(buf_page_t, hash, &buf_pool.zip_hash, fold, &block->page);
ut_d(buf_pool.buddy_n_frames++);
}
/** Allocate a block from a bigger object.
@param[in] buf a block that is free to use
@param[in] i index of buf_pool.zip_free[]
@param[in] j size of buf as an index of buf_pool.zip_free[]
@return allocated block */
static
void*
buf_buddy_alloc_from(void* buf, ulint i, ulint j)
{
ulint offs = BUF_BUDDY_LOW << j;
ut_ad(j <= BUF_BUDDY_SIZES);
ut_ad(i >= buf_buddy_get_slot(UNIV_ZIP_SIZE_MIN));
ut_ad(j >= i);
ut_ad(!ut_align_offset(buf, offs));
/* Add the unused parts of the block to the free lists. */
while (j > i) {
buf_buddy_free_t* zip_buf;
offs >>= 1;
j--;
zip_buf = reinterpret_cast<buf_buddy_free_t*>(
reinterpret_cast<byte*>(buf) + offs);
buf_buddy_add_to_free(zip_buf, j);
}
buf_buddy_stamp_nonfree(reinterpret_cast<buf_buddy_free_t*>(buf), i);
return(buf);
}
/** Allocate a ROW_FORMAT=COMPRESSED block.
@param i index of buf_pool.zip_free[] or BUF_BUDDY_SIZES
@param lru assigned to true if buf_pool.mutex was temporarily released
@return allocated block, never NULL */
byte *buf_buddy_alloc_low(ulint i, bool *lru)
{
buf_block_t* block;
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_ad(i >= buf_buddy_get_slot(UNIV_ZIP_SIZE_MIN));
if (i < BUF_BUDDY_SIZES) {
/* Try to allocate from the buddy system. */
block = (buf_block_t*) buf_buddy_alloc_zip(i);
if (block) {
goto func_exit;
}
}
/* Try allocating from the buf_pool.free list. */
block = buf_LRU_get_free_only();
if (block) {
goto alloc_big;
}
/* Try replacing an uncompressed page in the buffer pool. */
block = buf_LRU_get_free_block(true);
if (lru) {
*lru = true;
}
alloc_big:
buf_buddy_block_register(block);
block = reinterpret_cast<buf_block_t*>(
buf_buddy_alloc_from(block->page.frame, i, BUF_BUDDY_SIZES));
func_exit:
buf_pool.buddy_stat[i].used++;
return reinterpret_cast<byte*>(block);
}
/** Try to relocate a block. The caller must hold zip_free_mutex, and this
function will release and lock it again.
@param[in] src block to relocate
@param[in] dst free block to relocated to
@param[in] i index of buf_pool.zip_free[]
@param[in] force true if we must relocated always
@return true if relocated */
static bool buf_buddy_relocate(void* src, void* dst, ulint i, bool force)
{
buf_page_t* bpage;
const ulint size = BUF_BUDDY_LOW << i;
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_ad(!ut_align_offset(src, size));
ut_ad(!ut_align_offset(dst, size));
ut_ad(i >= buf_buddy_get_slot(UNIV_ZIP_SIZE_MIN));
MEM_CHECK_ADDRESSABLE(dst, size);
uint32_t space = mach_read_from_4(static_cast<const byte*>(src)
+ FIL_PAGE_ARCH_LOG_NO_OR_SPACE_ID);
uint32_t offset = mach_read_from_4(static_cast<const byte*>(src)
+ FIL_PAGE_OFFSET);
/* Suppress Valgrind or MSAN warnings. */
MEM_MAKE_DEFINED(&space, sizeof space);
MEM_MAKE_DEFINED(&offset, sizeof offset);
ut_ad(space != BUF_BUDDY_STAMP_FREE);
const page_id_t page_id(space, offset);
/* FIXME: we are computing this while holding buf_pool.mutex */
auto &cell= buf_pool.page_hash.cell_get(page_id.fold());
bpage = buf_pool.page_hash.get(page_id, cell);
if (!bpage || bpage->zip.data != src) {
/* The block has probably been freshly
allocated by buf_LRU_get_free_block() but not
added to buf_pool.page_hash yet. Obviously,
it cannot be relocated. */
if (!force || space != 0 || offset != 0) {
return(false);
}
/* It might be just uninitialized page.
We should search from LRU list also. */
bpage = UT_LIST_GET_FIRST(buf_pool.LRU);
while (bpage != NULL) {
if (bpage->zip.data == src) {
ut_ad(bpage->id() == page_id);
break;
}
bpage = UT_LIST_GET_NEXT(LRU, bpage);
}
if (bpage == NULL) {
return(false);
}
}
if (page_zip_get_size(&bpage->zip) != size) {
/* The block is of different size. We would
have to relocate all blocks covered by src.
For the sake of simplicity, give up. */
ut_ad(page_zip_get_size(&bpage->zip) < size);
return(false);
}
/* The block must have been allocated, but it may
contain uninitialized data. */
MEM_CHECK_ADDRESSABLE(src, size);
if (!bpage->can_relocate()) {
return false;
}
page_hash_latch &hash_lock = buf_pool.page_hash.lock_get(cell);
/* It does not make sense to use transactional_lock_guard here,
because the memcpy() of 1024 to 16384 bytes would likely make the
memory transaction too large. */
hash_lock.lock();
if (bpage->can_relocate()) {
/* Relocate the compressed page. */
const ulonglong ns = my_interval_timer();
ut_a(bpage->zip.data == src);
memcpy(dst, src, size);
bpage->zip.data = reinterpret_cast<page_zip_t*>(dst);
hash_lock.unlock();
buf_buddy_mem_invalid(
reinterpret_cast<buf_buddy_free_t*>(src), i);
buf_buddy_stat_t* buddy_stat = &buf_pool.buddy_stat[i];
buddy_stat->relocated++;
buddy_stat->relocated_usec+= (my_interval_timer() - ns) / 1000;
return(true);
}
hash_lock.unlock();
return(false);
}
/** Deallocate a block.
@param[in] buf block to be freed, must not be pointed to
by the buffer pool
@param[in] i index of buf_pool.zip_free[], or BUF_BUDDY_SIZES */
void buf_buddy_free_low(void* buf, ulint i)
{
buf_buddy_free_t* buddy;
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_ad(i <= BUF_BUDDY_SIZES);
ut_ad(i >= buf_buddy_get_slot(UNIV_ZIP_SIZE_MIN));
ut_ad(buf_pool.buddy_stat[i].used > 0);
buf_pool.buddy_stat[i].used--;
recombine:
MEM_UNDEFINED(buf, BUF_BUDDY_LOW << i);
if (i == BUF_BUDDY_SIZES) {
buf_buddy_block_free(buf);
return;
}
ut_ad(i < BUF_BUDDY_SIZES);
ut_ad(buf == ut_align_down(buf, BUF_BUDDY_LOW << i));
ut_ad(!buf_pool.contains_zip(buf));
/* Do not recombine blocks if there are few free blocks.
We may waste up to 15360*max_len bytes to free blocks
(1024 + 2048 + 4096 + 8192 = 15360) */
if (UT_LIST_GET_LEN(buf_pool.zip_free[i]) < 16
&& !buf_pool.is_shrinking()) {
goto func_exit;
}
/* Try to combine adjacent blocks. */
buddy = reinterpret_cast<buf_buddy_free_t*>(
buf_buddy_get(reinterpret_cast<byte*>(buf),
BUF_BUDDY_LOW << i));
switch (buf_buddy_is_free(buddy, i)) {
case BUF_BUDDY_STATE_FREE:
/* The buddy is free: recombine */
buf_buddy_remove_from_free(buddy, i);
buddy_is_free:
ut_ad(!buf_pool.contains_zip(buddy));
i++;
buf = ut_align_down(buf, BUF_BUDDY_LOW << i);
goto recombine;
case BUF_BUDDY_STATE_USED:
ut_d(buf_buddy_list_validate(i));
/* The buddy is not free. Is there a free block of
this size? */
if (buf_buddy_free_t* zip_buf =
UT_LIST_GET_FIRST(buf_pool.zip_free[i])) {
/* Remove the block from the free list, because
a successful buf_buddy_relocate() will overwrite
zip_free->list. */
buf_buddy_remove_from_free(zip_buf, i);
/* Try to relocate the buddy of buf to the free
block. */
if (buf_buddy_relocate(buddy, zip_buf, i, false)) {
goto buddy_is_free;
}
buf_buddy_add_to_free(zip_buf, i);
}
break;
case BUF_BUDDY_STATE_PARTIALLY_USED:
/* Some sub-blocks in the buddy are still in use.
Relocation will fail. No need to try. */
break;
}
func_exit:
/* Free the block to the buddy list. */
buf_buddy_add_to_free(reinterpret_cast<buf_buddy_free_t*>(buf), i);
}
/** Try to reallocate a block.
@param[in] buf buf_pool block to be reallocated
@param[in] size block size, up to srv_page_size
@return whether the reallocation succeeded */
bool
buf_buddy_realloc(void* buf, ulint size)
{
buf_block_t* block = NULL;
ulint i = buf_buddy_get_slot(size);
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_ad(i <= BUF_BUDDY_SIZES);
ut_ad(i >= buf_buddy_get_slot(UNIV_ZIP_SIZE_MIN));
if (i < BUF_BUDDY_SIZES) {
/* Try to allocate from the buddy system. */
block = reinterpret_cast<buf_block_t*>(buf_buddy_alloc_zip(i));
}
if (block == NULL) {
/* Try allocating from the buf_pool.free list. */
block = buf_LRU_get_free_only();
if (block == NULL) {
return(false); /* free_list was not enough */
}
buf_buddy_block_register(block);
block = reinterpret_cast<buf_block_t*>(
buf_buddy_alloc_from(
block->page.frame, i, BUF_BUDDY_SIZES));
}
buf_pool.buddy_stat[i].used++;
/* Try to relocate the buddy of buf to the free block. */
if (buf_buddy_relocate(buf, block, i, true)) {
/* succeeded */
buf_buddy_free_low(buf, i);
} else {
/* failed */
buf_buddy_free_low(block, i);
}
return(true); /* free_list was enough */
}
/** Combine all pairs of free buddies. */
void buf_buddy_condense_free()
{
mysql_mutex_assert_owner(&buf_pool.mutex);
ut_ad(buf_pool.is_shrinking());
for (ulint i = 0; i < UT_ARR_SIZE(buf_pool.zip_free); ++i) {
buf_buddy_free_t* buf =
UT_LIST_GET_FIRST(buf_pool.zip_free[i]);
/* seek to withdraw target */
while (buf != NULL
&& !buf_pool.will_be_withdrawn(
reinterpret_cast<byte*>(buf))) {
buf = UT_LIST_GET_NEXT(list, buf);
}
while (buf != NULL) {
buf_buddy_free_t* next =
UT_LIST_GET_NEXT(list, buf);
buf_buddy_free_t* buddy =
reinterpret_cast<buf_buddy_free_t*>(
buf_buddy_get(
reinterpret_cast<byte*>(buf),
BUF_BUDDY_LOW << i));
/* seek to the next withdraw target */
while (true) {
while (next != NULL
&& !buf_pool.will_be_withdrawn(
reinterpret_cast<byte*>(next))) {
next = UT_LIST_GET_NEXT(list, next);
}
if (buddy != next) {
break;
}
next = UT_LIST_GET_NEXT(list, next);
}
if (buf_buddy_is_free(buddy, i)
== BUF_BUDDY_STATE_FREE) {
/* Both buf and buddy are free.
Try to combine them. */
buf_buddy_remove_from_free(buf, i);
buf_pool.buddy_stat[i].used++;
buf_buddy_free_low(buf, i);
}
buf = next;
}
}
}
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