PostgreSQLcheckpoint中用于刷一个脏page的函数是什么
这篇文章主要讲解了“PostgreSQL checkpoint中用于刷一个脏page的函数是什么”,文中的讲解内容简单清晰,易于学习与理解,下面请大家跟着小编的思路慢慢深入,一起来研究和学习“PostgreSQL checkpoint中用于刷一个脏page的函数是什么”吧!
创新互联专注为客户提供全方位的互联网综合服务,包含不限于网站设计、做网站、老边网络推广、微信小程序、老边网络营销、老边企业策划、老边品牌公关、搜索引擎seo、人物专访、企业宣传片、企业代运营等,从售前售中售后,我们都将竭诚为您服务,您的肯定,是我们最大的嘉奖;创新互联为所有大学生创业者提供老边建站搭建服务,24小时服务热线:028-86922220,官方网址:www.cdcxhl.com
一、数据结构
宏定义
checkpoints request flag bits,检查点请求标记位定义.
/* * OR-able request flag bits for checkpoints. The "cause" bits are used only * for logging purposes. Note: the flags must be defined so that it's * sensible to OR together request flags arising from different requestors. */ /* These directly affect the behavior of CreateCheckPoint and subsidiaries */ #define CHECKPOINT_IS_SHUTDOWN 0x0001 /* Checkpoint is for shutdown */ #define CHECKPOINT_END_OF_RECOVERY 0x0002 /* Like shutdown checkpoint, but * issued at end of WAL recovery */ #define CHECKPOINT_IMMEDIATE 0x0004 /* Do it without delays */ #define CHECKPOINT_FORCE 0x0008 /* Force even if no activity */ #define CHECKPOINT_FLUSH_ALL 0x0010 /* Flush all pages, including those * belonging to unlogged tables */ /* These are important to RequestCheckpoint */ #define CHECKPOINT_WAIT 0x0020 /* Wait for completion */ #define CHECKPOINT_REQUESTED 0x0040 /* Checkpoint request has been made */ /* These indicate the cause of a checkpoint request */ #define CHECKPOINT_CAUSE_XLOG 0x0080 /* XLOG consumption */ #define CHECKPOINT_CAUSE_TIME 0x0100 /* Elapsed time */
二、源码解读
SyncOneBuffer,在syncing期间处理一个buffer,其主要处理逻辑如下:
1.获取buffer描述符
2.锁定buffer
3.根据buffer状态和输入参数执行相关判断/处理
4.钉住脏页,上共享锁,调用FlushBuffer刷盘
5.解锁/解钉和其他收尾工作
/* * SyncOneBuffer -- process a single buffer during syncing. * 在syncing期间处理一个buffer * * If skip_recently_used is true, we don't write currently-pinned buffers, nor * buffers marked recently used, as these are not replacement candidates. * 如skip_recently_used为T,既不写currently-pinned buffers, * 也不写标记为最近使用的buffers,因为这些缓冲区不是可替代的缓冲区. * * Returns a bitmask containing the following flag bits: * BUF_WRITTEN: we wrote the buffer. * BUF_REUSABLE: buffer is available for replacement, ie, it has * pin count 0 and usage count 0. * 返回位掩码: * BUF_WRITTEN: 已写入buffer * BUF_REUSABLE: buffer可用于替代(pin count和usage count均为0) * * (BUF_WRITTEN could be set in error if FlushBuffers finds the buffer clean * after locking it, but we don't care all that much.) * * Note: caller must have done ResourceOwnerEnlargeBuffers. */ static int SyncOneBuffer(int buf_id, bool skip_recently_used, WritebackContext *wb_context) { BufferDesc *bufHdr = GetBufferDescriptor(buf_id); int result = 0; uint32 buf_state; BufferTag tag; ReservePrivateRefCountEntry(); /* * Check whether buffer needs writing. * 检查buffer是否需要写入. * * We can make this check without taking the buffer content lock so long * as we mark pages dirty in access methods *before* logging changes with * XLogInsert(): if someone marks the buffer dirty just after our check we * don't worry because our checkpoint.redo points before log record for * upcoming changes and so we are not required to write such dirty buffer. * 在使用XLogInsert() logging变化前通过访问方法标记pages为脏时, * 不需要持有锁太长的时间来执行该检查: * 因为如果某个进程在检查后标记buffer为脏, * 在这种情况下checkpoint.redo指向了变化出现前的log位置,因此无需担心,而且不必写这样的脏块. */ buf_state = LockBufHdr(bufHdr); if (BUF_STATE_GET_REFCOUNT(buf_state) == 0 && BUF_STATE_GET_USAGECOUNT(buf_state) == 0) { result |= BUF_REUSABLE; } else if (skip_recently_used) { /* Caller told us not to write recently-used buffers */ //跳过最近使用的buffer UnlockBufHdr(bufHdr, buf_state); return result; } if (!(buf_state & BM_VALID) || !(buf_state & BM_DIRTY)) { /* It's clean, so nothing to do */ //buffer无效或者不是脏块 UnlockBufHdr(bufHdr, buf_state); return result; } /* * Pin it, share-lock it, write it. (FlushBuffer will do nothing if the * buffer is clean by the time we've locked it.) * 钉住它,上共享锁,并刷到盘上. */ PinBuffer_Locked(bufHdr); LWLockAcquire(BufferDescriptorGetContentLock(bufHdr), LW_SHARED); //调用FlushBuffer //If the caller has an smgr reference for the buffer's relation, pass it as the second parameter. //If not, pass NULL. FlushBuffer(bufHdr, NULL); LWLockRelease(BufferDescriptorGetContentLock(bufHdr)); tag = bufHdr->tag; UnpinBuffer(bufHdr, true); ScheduleBufferTagForWriteback(wb_context, &tag); return result | BUF_WRITTEN; }
FlushBuffer
FlushBuffer函数物理上把共享缓存刷盘,主要实现函数还是smgrwrite(storage manager write).
/* * FlushBuffer * Physically write out a shared buffer. * 物理上把共享缓存刷盘. * * NOTE: this actually just passes the buffer contents to the kernel; the * real write to disk won't happen until the kernel feels like it. This * is okay from our point of view since we can redo the changes from WAL. * However, we will need to force the changes to disk via fsync before * we can checkpoint WAL. * 只是把buffer内容发给os内核,何时真正写盘由os来确定. * 在checkpoint WAL前需要通过fsync强制落盘. * * The caller must hold a pin on the buffer and have share-locked the * buffer contents. (Note: a share-lock does not prevent updates of * hint bits in the buffer, so the page could change while the write * is in progress, but we assume that that will not invalidate the data * written.) * 调用者必须钉住了缓存并且持有共享锁. * (注意:共享锁不会buffer中的hint bits的更新,因此在写入期间page可能会出现变化, * 但我假定那样不会让写入的数据无效) * * If the caller has an smgr reference for the buffer's relation, pass it * as the second parameter. If not, pass NULL. */ static void FlushBuffer(BufferDesc *buf, SMgrRelation reln) { XLogRecPtr recptr; ErrorContextCallback errcallback; instr_time io_start, io_time; Block bufBlock; char *bufToWrite; uint32 buf_state; /* * Acquire the buffer's io_in_progress lock. If StartBufferIO returns * false, then someone else flushed the buffer before we could, so we need * not do anything. */ if (!StartBufferIO(buf, false)) return; /* Setup error traceback support for ereport() */ errcallback.callback = shared_buffer_write_error_callback; errcallback.arg = (void *) buf; errcallback.previous = error_context_stack; error_context_stack = &errcallback; /* Find smgr relation for buffer */ if (reln == NULL) reln = smgropen(buf->tag.rnode, InvalidBackendId); TRACE_POSTGRESQL_BUFFER_FLUSH_START(buf->tag.forkNum, buf->tag.blockNum, reln->smgr_rnode.node.spcNode, reln->smgr_rnode.node.dbNode, reln->smgr_rnode.node.relNode); buf_state = LockBufHdr(buf); /* * Run PageGetLSN while holding header lock, since we don't have the * buffer locked exclusively in all cases. */ recptr = BufferGetLSN(buf); /* To check if block content changes while flushing. - vadim 01/17/97 */ buf_state &= ~BM_JUST_DIRTIED; UnlockBufHdr(buf, buf_state); /* * Force XLOG flush up to buffer's LSN. This implements the basic WAL * rule that log updates must hit disk before any of the data-file changes * they describe do. * * However, this rule does not apply to unlogged relations, which will be * lost after a crash anyway. Most unlogged relation pages do not bear * LSNs since we never emit WAL records for them, and therefore flushing * up through the buffer LSN would be useless, but harmless. However, * GiST indexes use LSNs internally to track page-splits, and therefore * unlogged GiST pages bear "fake" LSNs generated by * GetFakeLSNForUnloggedRel. It is unlikely but possible that the fake * LSN counter could advance past the WAL insertion point; and if it did * happen, attempting to flush WAL through that location would fail, with * disastrous system-wide consequences. To make sure that can't happen, * skip the flush if the buffer isn't permanent. */ if (buf_state & BM_PERMANENT) XLogFlush(recptr); /* * Now it's safe to write buffer to disk. Note that no one else should * have been able to write it while we were busy with log flushing because * we have the io_in_progress lock. */ bufBlock = BufHdrGetBlock(buf); /* * Update page checksum if desired. Since we have only shared lock on the * buffer, other processes might be updating hint bits in it, so we must * copy the page to private storage if we do checksumming. */ bufToWrite = PageSetChecksumCopy((Page) bufBlock, buf->tag.blockNum); if (track_io_timing) INSTR_TIME_SET_CURRENT(io_start); /* * bufToWrite is either the shared buffer or a copy, as appropriate. */ smgrwrite(reln, buf->tag.forkNum, buf->tag.blockNum, bufToWrite, false); if (track_io_timing) { INSTR_TIME_SET_CURRENT(io_time); INSTR_TIME_SUBTRACT(io_time, io_start); pgstat_count_buffer_write_time(INSTR_TIME_GET_MICROSEC(io_time)); INSTR_TIME_ADD(pgBufferUsage.blk_write_time, io_time); } pgBufferUsage.shared_blks_written++; /* * Mark the buffer as clean (unless BM_JUST_DIRTIED has become set) and * end the io_in_progress state. */ TerminateBufferIO(buf, true, 0); TRACE_POSTGRESQL_BUFFER_FLUSH_DONE(buf->tag.forkNum, buf->tag.blockNum, reln->smgr_rnode.node.spcNode, reln->smgr_rnode.node.dbNode, reln->smgr_rnode.node.relNode); /* Pop the error context stack */ error_context_stack = errcallback.previous; }
三、跟踪分析
测试脚本
testdb=# update t_wal_ckpt set c2 = 'C4#'||substr(c2,4,40); UPDATE 1 testdb=# checkpoint;
跟踪分析
(gdb) handle SIGINT print nostop pass SIGINT is used by the debugger. Are you sure you want to change it? (y or n) y Signal Stop Print Pass to program Description SIGINT No Yes Yes Interrupt (gdb) b SyncOneBuffer Breakpoint 1 at 0x8a7167: file bufmgr.c, line 2357. (gdb) c Continuing. Program received signal SIGINT, Interrupt. Breakpoint 1, SyncOneBuffer (buf_id=0, skip_recently_used=false, wb_context=0x7fff27f5ae00) at bufmgr.c:2357 2357 BufferDesc *bufHdr = GetBufferDescriptor(buf_id); (gdb) n 2358 int result = 0; (gdb) p *bufHdr $1 = {tag = {rnode = {spcNode = 1663, dbNode = 16384, relNode = 221290}, forkNum = MAIN_FORKNUM, blockNum = 0}, buf_id = 0, state = {value = 3548905472}, wait_backend_pid = 0, freeNext = -2, content_lock = {tranche = 53, state = { value = 536870912}, waiters = {head = 2147483647, tail = 2147483647}}} (gdb) n 2362 ReservePrivateRefCountEntry(); (gdb) 2373 buf_state = LockBufHdr(bufHdr); (gdb) 2375 if (BUF_STATE_GET_REFCOUNT(buf_state) == 0 && (gdb) 2376 BUF_STATE_GET_USAGECOUNT(buf_state) == 0) (gdb) 2375 if (BUF_STATE_GET_REFCOUNT(buf_state) == 0 && (gdb) 2380 else if (skip_recently_used) (gdb) 2387 if (!(buf_state & BM_VALID) || !(buf_state & BM_DIRTY)) (gdb) 2398 PinBuffer_Locked(bufHdr); (gdb) p buf_state $2 = 3553099776 (gdb) n 2399 LWLockAcquire(BufferDescriptorGetContentLock(bufHdr), LW_SHARED); (gdb) 2401 FlushBuffer(bufHdr, NULL); (gdb) step FlushBuffer (buf=0x7fedc4a68300, reln=0x0) at bufmgr.c:2687 2687 if (!StartBufferIO(buf, false)) (gdb) n 2691 errcallback.callback = shared_buffer_write_error_callback; (gdb) 2692 errcallback.arg = (void *) buf; (gdb) 2693 errcallback.previous = error_context_stack; (gdb) 2694 error_context_stack = &errcallback; (gdb) 2697 if (reln == NULL) (gdb) 2698 reln = smgropen(buf->tag.rnode, InvalidBackendId); (gdb) 2700 TRACE_POSTGRESQL_BUFFER_FLUSH_START(buf->tag.forkNum, (gdb) 2706 buf_state = LockBufHdr(buf); (gdb) 2712 recptr = BufferGetLSN(buf); (gdb) 2715 buf_state &= ~BM_JUST_DIRTIED; (gdb) p recptr $3 = 16953421760 (gdb) n 2716 UnlockBufHdr(buf, buf_state); (gdb) 2735 if (buf_state & BM_PERMANENT) (gdb) 2736 XLogFlush(recptr); (gdb) 2743 bufBlock = BufHdrGetBlock(buf); (gdb) 2750 bufToWrite = PageSetChecksumCopy((Page) bufBlock, buf->tag.blockNum); (gdb) p bufBlock $4 = (Block) 0x7fedc4e68300 (gdb) n 2752 if (track_io_timing) (gdb) 2758 smgrwrite(reln, (gdb) 2764 if (track_io_timing) (gdb) 2772 pgBufferUsage.shared_blks_written++; (gdb) 2778 TerminateBufferIO(buf, true, 0); (gdb) 2780 TRACE_POSTGRESQL_BUFFER_FLUSH_DONE(buf->tag.forkNum, (gdb) 2787 error_context_stack = errcallback.previous; (gdb) 2788 } (gdb) SyncOneBuffer (buf_id=0, skip_recently_used=false, wb_context=0x7fff27f5ae00) at bufmgr.c:2403 2403 LWLockRelease(BufferDescriptorGetContentLock(bufHdr)); (gdb) 2405 tag = bufHdr->tag; (gdb) 2407 UnpinBuffer(bufHdr, true); (gdb) 2409 ScheduleBufferTagForWriteback(wb_context, &tag); (gdb) 2411 return result | BUF_WRITTEN; (gdb) 2412 } (gdb)
感谢各位的阅读,以上就是“PostgreSQL checkpoint中用于刷一个脏page的函数是什么”的内容了,经过本文的学习后,相信大家对PostgreSQL checkpoint中用于刷一个脏page的函数是什么这一问题有了更深刻的体会,具体使用情况还需要大家实践验证。这里是创新互联,小编将为大家推送更多相关知识点的文章,欢迎关注!
文章名称:PostgreSQLcheckpoint中用于刷一个脏page的函数是什么
本文URL:http://hbruida.cn/article/jgscpc.html