PostgreSQL 源码解读(109)- WAL#5(相关数据结构)

本节简单介绍了WAL相关的数据结构,包括XLogLongPageHeaderData、XLogPageHeaderData和XLogRecord。

一、数据结构

XLogPageHeaderData
每一个事务日志文件(WAL segment file)的page(大小默认为8K)都有头部数据.
注:每个文件第一个page的头部数据是XLogLongPageHeaderData(详见后续描述),而不是XLogPageHeaderData

/*
 * Each page of XLOG file has a header like this:
 * 每一个事务日志文件的page都有头部信息,结构如下:
 */
//可作为WAL版本信息
#define XLOG_PAGE_MAGIC 0xD098  /* can be used as WAL version indicator */

typedef struct XLogPageHeaderData
{
    //WAL版本信息,PG V11.1 --> 0xD98
    uint16      xlp_magic;      /* magic value for correctness checks */
    //标记位(详见下面说明)
    uint16      xlp_info;       /* flag bits, see below */
    //page中第一个XLOG Record的TimeLineID,类型为uint32
    TimeLineID  xlp_tli;        /* TimeLineID of first record on page */
    //page的XLOG地址(在事务日志中的偏移),类型为uint64
    XLogRecPtr  xlp_pageaddr;   /* XLOG address of this page */

    /*
     * When there is not enough space on current page for whole record, we
     * continue on the next page.  xlp_rem_len is the number of bytes
     * remaining from a previous page.
     * 如果当前页的空间不足以存储整个XLOG Record,在下一个页面中存储余下的数据
     * xlp_rem_len表示上一页XLOG Record剩余部分的大小
     *
     * Note that xl_rem_len includes backup-block data; that is, it tracks
     * xl_tot_len not xl_len in the initial header.  Also note that the
     * continuation data isn't necessarily aligned.
     * 注意xl_rem_len包含backup-block data(full-page-write);
     * 也就是说在初始的头部信息中跟踪的是xl_tot_len而不是xl_len.
     * 另外要注意的是剩余的数据不需要对齐.
     */
    //上一页空间不够存储XLOG Record,该Record在本页继续存储占用的空间大小
    uint32      xlp_rem_len;    /* total len of remaining data for record */
} XLogPageHeaderData;

#define SizeOfXLogShortPHD  MAXALIGN(sizeof(XLogPageHeaderData))

typedef XLogPageHeaderData *XLogPageHeader;

XLogLongPageHeaderData
如设置了XLP_LONG_HEADER标记,在page header中存储额外的字段.
(通常在每个事务日志文件也就是segment file的的第一个page中存在).
这些附加的字段用于准确的识别文件。


/*
 * When the XLP_LONG_HEADER flag is set, we store additional fields in the
 * page header.  (This is ordinarily done just in the first page of an
 * XLOG file.)  The additional fields serve to identify the file accurately.
 * 如设置了XLP_LONG_HEADER标记,在page header中存储额外的字段.
 * (通常在每个事务日志文件也就是segment file的的第一个page中存在).
 * 附加字段用于准确识别文件。
 */
typedef struct XLogLongPageHeaderData
{
    //标准的头部域字段
    XLogPageHeaderData std;     /* standard header fields */
    //pg_control中的系统标识码
    uint64      xlp_sysid;      /* system identifier from pg_control */
    //交叉检查
    uint32      xlp_seg_size;   /* just as a cross-check */
    //交叉检查
    uint32      xlp_xlog_blcksz;    /* just as a cross-check */
} XLogLongPageHeaderData;

#define SizeOfXLogLongPHD   MAXALIGN(sizeof(XLogLongPageHeaderData))
//指针
typedef XLogLongPageHeaderData *XLogLongPageHeader;

/* When record crosses page boundary, set this flag in new page's header */
//如果XLOG Record跨越page边界,在新page header中设置该标志位
#define XLP_FIRST_IS_CONTRECORD     0x0001
//该标志位标明是"long"页头
/* This flag indicates a "long" page header */
#define XLP_LONG_HEADER             0x0002
/* This flag indicates backup blocks starting in this page are optional */
//该标志位标明从该页起始的backup blocks是可选的(不一定存在)
#define XLP_BKP_REMOVABLE           0x0004
//xlp_info中所有定义的标志位(用于page header的有效性检查)
/* All defined flag bits in xlp_info (used for validity checking of header) */
#define XLP_ALL_FLAGS               0x0007

#define XLogPageHeaderSize(hdr)     \
    (((hdr)->xlp_info & XLP_LONG_HEADER) ? SizeOfXLogLongPHD : SizeOfXLogShortPHD)

XLogRecord
事务日志文件由N个的XLog Record组成,逻辑上对应XLOG Record这一概念的数据结构是XLogRecord.
XLOG Record的整体布局如下:
头部数据(固定大小的XLogRecord结构体)
XLogRecordBlockHeader 结构体
XLogRecordBlockHeader 结构体
...
XLogRecordDataHeader[Short|Long] 结构体
block data
block data
...
main data
XLOG Record按存储的数据内容来划分,大体可以分为三类:
1.Record for backup block:存储full-write-page的block,这种类型Record的目的是为了解决page部分写的问题;
2.Record for (tuple)data block:在full-write-page后,相应的page中的tuple变更,使用这种类型的Record记录;
3.Record for Checkpoint:在checkpoint发生时,在事务日志文件中记录checkpoint信息(其中包括Redo point).

XLOG Record的详细解析后续会解析,这里暂且不提

/*
 * The overall layout of an XLOG record is:
 *      Fixed-size header (XLogRecord struct)
 *      XLogRecordBlockHeader struct
 *      XLogRecordBlockHeader struct
 *      ...
 *      XLogRecordDataHeader[Short|Long] struct
 *      block data
 *      block data
 *      ...
 *      main data
 * XLOG record的整体布局如下:
 *      固定大小的头部(XLogRecord 结构体)
 *      XLogRecordBlockHeader 结构体
 *      XLogRecordBlockHeader 结构体
 *      ...
 *      XLogRecordDataHeader[Short|Long] 结构体
 *      block data
 *      block data
 *      ...
 *      main data
 *
 * There can be zero or more XLogRecordBlockHeaders, and 0 or more bytes of
 * rmgr-specific data not associated with a block.  XLogRecord structs
 * always start on MAXALIGN boundaries in the WAL files, but the rest of
 * the fields are not aligned.
 * 其中,XLogRecordBlockHeaders可能有0或者多个,与block无关的0或多个字节的rmgr-specific数据
 * XLogRecord通常在WAL文件的MAXALIGN边界起写入,但后续的字段并没有对齐
 *
 * The XLogRecordBlockHeader, XLogRecordDataHeaderShort and
 * XLogRecordDataHeaderLong structs all begin with a single 'id' byte. It's
 * used to distinguish between block references, and the main data structs.
 * XLogRecordBlockHeader/XLogRecordDataHeaderShort/XLogRecordDataHeaderLong开头是占用1个字节的"id".
 * 用于区分block引用和main data结构体.
 */
typedef struct XLogRecord
{
    //record的大小
    uint32      xl_tot_len;     /* total len of entire record */
    //xact id
    TransactionId xl_xid;       /* xact id */
    //指向log中的前一条记录
    XLogRecPtr  xl_prev;        /* ptr to previous record in log */
    //标识位,详见下面的说明
    uint8       xl_info;        /* flag bits, see below */
    //该记录的资源管理器
    RmgrId      xl_rmid;        /* resource manager for this record */
    /* 2 bytes of padding here, initialize to zero */
    //2个字节的crc校验位,初始化为0
    pg_crc32c   xl_crc;         /* CRC for this record */

    /* XLogRecordBlockHeaders and XLogRecordDataHeader follow, no padding */
    //接下来是XLogRecordBlockHeaders和XLogRecordDataHeader
} XLogRecord;
//宏定义:XLogRecord大小
#define SizeOfXLogRecord    (offsetof(XLogRecord, xl_crc) + sizeof(pg_crc32c))

/*
 * The high 4 bits in xl_info may be used freely by rmgr. The
 * XLR_SPECIAL_REL_UPDATE and XLR_CHECK_CONSISTENCY bits can be passed by
 * XLogInsert caller. The rest are set internally by XLogInsert.
 * xl_info的高4位由rmgr自由使用.
 * XLR_SPECIAL_REL_UPDATE和XLR_CHECK_CONSISTENCY由XLogInsert函数的调用者传入.
 * 其余由XLogInsert内部使用.
 */
#define XLR_INFO_MASK           0x0F
#define XLR_RMGR_INFO_MASK      0xF0

/*
 * If a WAL record modifies any relation files, in ways not covered by the
 * usual block references, this flag is set. This is not used for anything
 * by PostgreSQL itself, but it allows external tools that read WAL and keep
 * track of modified blocks to recognize such special record types.
 * 如果WAL记录使用特殊的方式(不涉及通常块引用)更新了关系的存储文件,设置此标记.
 * PostgreSQL本身并不使用这种方法,但它允许外部工具读取WAL并跟踪修改后的块,
 *   以识别这种特殊的记录类型。
 */
#define XLR_SPECIAL_REL_UPDATE  0x01

/*
 * Enforces consistency checks of replayed WAL at recovery. If enabled,
 * each record will log a full-page write for each block modified by the
 * record and will reuse it afterwards for consistency checks. The caller
 * of XLogInsert can use this value if necessary, but if
 * wal_consistency_checking is enabled for a rmgr this is set unconditionally.
 * 在恢复时强制执行一致性检查.
 * 如启用此功能,每个记录将为记录修改的每个块记录一个完整的页面写操作,并在以后重用它进行一致性检查。
 * 在需要时,XLogInsert的调用者可使用此标记,但如果rmgr启用了wal_consistency_checking,
 *   则会无条件执行一致性检查.
 */
#define XLR_CHECK_CONSISTENCY   0x02


/*
 * Header info for block data appended to an XLOG record.
 * 追加到XLOG record中block data的头部信息
 *
 * 'data_length' is the length of the rmgr-specific payload data associated
 * with this block. It does not include the possible full page image, nor
 * XLogRecordBlockHeader struct itself.
 * 'data_length'是与此块关联的rmgr特定payload data的长度。
 * 它不包括可能的full page image,也不包括XLogRecordBlockHeader结构体本身。
 *
 * Note that we don't attempt to align the XLogRecordBlockHeader struct!
 * So, the struct must be copied to aligned local storage before use.
 * 注意:我们不打算尝试对齐XLogRecordBlockHeader结构体!
 * 因此,在使用前,XLogRecordBlockHeader必须拷贝到一队齐的本地存储中.
 */
typedef struct XLogRecordBlockHeader
{
    //块引用ID
    uint8       id;             /* block reference ID */
    //在关系中使用的fork和flags
    uint8       fork_flags;     /* fork within the relation, and flags */
    //payload字节大小
    uint16      data_length;    /* number of payload bytes (not including page
                                 * image) */

    /* If BKPBLOCK_HAS_IMAGE, an XLogRecordBlockImageHeader struct follows */
    //如BKPBLOCK_HAS_IMAGE,后续为XLogRecordBlockImageHeader结构体
    /* If BKPBLOCK_SAME_REL is not set, a RelFileNode follows */
    //如BKPBLOCK_SAME_REL没有设置,则为RelFileNode
    /* BlockNumber follows */
    //后续为BlockNumber
} XLogRecordBlockHeader;
 
#define SizeOfXLogRecordBlockHeader (offsetof(XLogRecordBlockHeader, data_length) + sizeof(uint16))

/*
 * Additional header information when a full-page image is included
 * (i.e. when BKPBLOCK_HAS_IMAGE is set).
 * 当包含完整页图像时(即当设置BKPBLOCK_HAS_IMAGE时),附加的头部信息。
 *
 * The XLOG code is aware that PG data pages usually contain an unused "hole"
 * in the middle, which contains only zero bytes.  Since we know that the
 * "hole" is all zeros, we remove it from the stored data (and it's not counted
 * in the XLOG record's CRC, either).  Hence, the amount of block data actually
 * present is (BLCKSZ - ).
 * XLOG代码知道PG数据页通常在中间包含一个未使用的“hole”(空闲空间),
 *   大小为零字节。
 * 因为我们知道“hole”都是零,
 *   以我们从存储的数据中删除它(而且它也没有被计入XLOG记录的CRC中)。
 * 因此,实际呈现的块数据量为(BLCKSZ - <“hole”的大小>)。
 *
 * Additionally, when wal_compression is enabled, we will try to compress full
 * page images using the PGLZ compression algorithm, after removing the "hole".
 * This can reduce the WAL volume, but at some extra cost of CPU spent
 * on the compression during WAL logging. In this case, since the "hole"
 * length cannot be calculated by subtracting the number of page image bytes
 * from BLCKSZ, basically it needs to be stored as an extra information.
 * But when no "hole" exists, we can assume that the "hole" length is zero
 * and no such an extra information needs to be stored. Note that
 * the original version of page image is stored in WAL instead of the
 * compressed one if the number of bytes saved by compression is less than
 * the length of extra information. Hence, when a page image is successfully
 * compressed, the amount of block data actually present is less than
 * BLCKSZ - the length of "hole" bytes - the length of extra information.
 * 另外,在启用wal_compression时,会在去掉“hole”后,尝试使用PGLZ压缩算法压缩full page image。
 * 这可以简化WAL大小,但会增加额外的解压缩CPU时间.
 * 在这种情况下,由于“hole”的长度不能通过从BLCKSZ中减去page image字节数来计算,
 *   所以它基本上需要作为额外的信息来存储。
 * 但如果"hole"不存在,我们可以假设"hole"的大小为0,不需要存储额外的信息.
 * 请注意,如果压缩节省的字节数小于额外信息的长度,
 *   那么page image的原始版本存储在WAL中,而不是压缩后的版本。
 * 因此,当一个page image被成功压缩时,
 *   实际的块数据量小于BLCKSZ - “hole”的大小 - 额外信息的大小。
 */
typedef struct XLogRecordBlockImageHeader
{
    uint16      length;         /* number of page image bytes */
    uint16      hole_offset;    /* number of bytes before "hole" */
    uint8       bimg_info;      /* flag bits, see below */

    /*
     * If BKPIMAGE_HAS_HOLE and BKPIMAGE_IS_COMPRESSED, an
     * XLogRecordBlockCompressHeader struct follows.
     * 如标记BKPIMAGE_HAS_HOLE和BKPIMAGE_IS_COMPRESSED设置,则后跟XLogRecordBlockCompressHeader
     */
} XLogRecordBlockImageHeader;

#define SizeOfXLogRecordBlockImageHeader    \
    (offsetof(XLogRecordBlockImageHeader, bimg_info) + sizeof(uint8))

/* Information stored in bimg_info */
//------------ bimg_info标记位
//存在"hole"
#define BKPIMAGE_HAS_HOLE       0x01    /* page image has "hole" */
//压缩存储
#define BKPIMAGE_IS_COMPRESSED      0x02    /* page image is compressed */
//在回放时,page image需要恢复
#define BKPIMAGE_APPLY      0x04    /* page image should be restored during
                                     * replay */

/*
 * Extra header information used when page image has "hole" and
 * is compressed.
 * page image存在"hole"和压缩存储时,额外的头部信息
 */
typedef struct XLogRecordBlockCompressHeader
{
    //"hole"的大小
    uint16      hole_length;    /* number of bytes in "hole" */
} XLogRecordBlockCompressHeader;

#define SizeOfXLogRecordBlockCompressHeader \
    sizeof(XLogRecordBlockCompressHeader)

/*
 * Maximum size of the header for a block reference. This is used to size a
 * temporary buffer for constructing the header.
 * 块引用的header的最大大小。
 * 它用于设置用于构造头部临时缓冲区的大小。
 */
#define MaxSizeOfXLogRecordBlockHeader \
    (SizeOfXLogRecordBlockHeader + \
     SizeOfXLogRecordBlockImageHeader + \
     SizeOfXLogRecordBlockCompressHeader + \
     sizeof(RelFileNode) + \
     sizeof(BlockNumber))

/*
 * The fork number fits in the lower 4 bits in the fork_flags field. The upper
 * bits are used for flags.
 * fork号适合于fork_flags字段的低4位。
 * 高4位用于标记。
 */
#define BKPBLOCK_FORK_MASK  0x0F
#define BKPBLOCK_FLAG_MASK  0xF0
//块数据是XLogRecordBlockImage
#define BKPBLOCK_HAS_IMAGE  0x10    /* block data is an XLogRecordBlockImage */
#define BKPBLOCK_HAS_DATA   0x20
//重做时重新初始化page
#define BKPBLOCK_WILL_INIT  0x40    /* redo will re-init the page */
//重做时重新初始化page,但会省略RelFileNode
#define BKPBLOCK_SAME_REL   0x80    /* RelFileNode omitted, same as previous */

/*
 * XLogRecordDataHeaderShort/Long are used for the "main data" portion of
 * the record. If the length of the data is less than 256 bytes, the short
 * form is used, with a single byte to hold the length. Otherwise the long
 * form is used.
 * XLogRecordDataHeaderShort/Long用于记录的“main data”部分。
 * 如果数据的长度小于256字节,则使用短格式,用一个字节保存长度。
 * 否则使用长形式。
 *
 * (These structs are currently not used in the code, they are here just for
 * documentation purposes).
 * (这些结构体不会再代码中使用,在这里是为了文档记录的目的)
 */
typedef struct XLogRecordDataHeaderShort
{
    uint8       id;             /* XLR_BLOCK_ID_DATA_SHORT */
    uint8       data_length;    /* number of payload bytes */
}           XLogRecordDataHeaderShort;

#define SizeOfXLogRecordDataHeaderShort (sizeof(uint8) * 2)

typedef struct XLogRecordDataHeaderLong
{
    uint8       id;             /* XLR_BLOCK_ID_DATA_LONG */
    /* followed by uint32 data_length, unaligned */
    //接下来是无符号32位整型的data_length(未对齐)
}           XLogRecordDataHeaderLong;

#define SizeOfXLogRecordDataHeaderLong (sizeof(uint8) + sizeof(uint32))

/*
 * Block IDs used to distinguish different kinds of record fragments. Block
 * references are numbered from 0 to XLR_MAX_BLOCK_ID. A rmgr is free to use
 * any ID number in that range (although you should stick to small numbers,
 * because the WAL machinery is optimized for that case). A couple of ID
 * numbers are reserved to denote the "main" data portion of the record.
 * 块id用于区分不同类型的记录片段。
 * 块引用编号从0到XLR_MAX_BLOCK_ID。
 * rmgr可以自由使用该范围内的任何ID号
 *   (尽管您应该坚持使用较小的数字,因为WAL机制针对这种情况进行了优化)。
 * 保留两个ID号来表示记录的“main”数据部分。
 *
 * The maximum is currently set at 32, quite arbitrarily. Most records only
 * need a handful of block references, but there are a few exceptions that
 * need more.
 * 目前的最大值是32,非常随意。
 * 大多数记录只需要少数块引用,但也有少数例外需要更多。
 */
#define XLR_MAX_BLOCK_ID            32

#define XLR_BLOCK_ID_DATA_SHORT     255
#define XLR_BLOCK_ID_DATA_LONG      254
#define XLR_BLOCK_ID_ORIGIN         253

#endif                          /* XLOGRECORD_H */

这些数据结构在WAL segment file文件中如何布局,请参见后续的章节

二、参考资料

Write Ahead Logging — WAL
PostgreSQL 源码解读(4)- 插入数据#3(heap_insert)
PG Source Code

来自 “ ITPUB博客 ” ,链接:http://blog.itpub.net/6906/viewspace-2374778/,如需转载,请注明出处,否则将追究法律责任。

转载于:http://blog.itpub.net/6906/viewspace-2374778/

你可能感兴趣的:(数据结构与算法,数据库,人工智能)