PostgreSQL数据页Page中的行数据分析
这篇文章主要介绍“PostgreSQL数据页Page中的行数据分析”,在日常操作中,相信很多人在PostgreSQL数据页Page中的行数据分析问题上存在疑惑,小编查阅了各式资料,整理出简单好用的操作方法,希望对大家解答”PostgreSQL数据页Page中的行数据分析”的疑惑有所帮助!接下来,请跟着小编一起来学习吧!
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一、测试数据
详见上一节,数据文件中的内容如下:
[xdb@localhost utf8db]$ hexdump -C $PGDATA/base/16477/24801 00000000 01 00 00 00 88 20 2a 12 00 00 00 00 28 00 60 1f |..... *.....(.`.| 00000010 00 20 04 20 00 00 00 00 d8 9f 4e 00 b0 9f 4e 00 |. . ......N...N.| 00000020 88 9f 4e 00 60 9f 4e 00 00 00 00 00 00 00 00 00 |..N.`.N.........| 00000030 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 |................| * 00001f60 e5 1b 18 00 00 00 00 00 00 00 00 00 00 00 00 00 |................| 00001f70 04 00 03 00 02 08 18 00 04 00 00 00 13 34 20 20 |.............4 | 00001f80 20 20 20 20 20 05 64 00 e4 1b 18 00 00 00 00 00 | .d.........| 00001f90 00 00 00 00 00 00 00 00 03 00 03 00 02 08 18 00 |................| 00001fa0 03 00 00 00 13 33 20 20 20 20 20 20 20 05 63 00 |.....3 .c.| 00001fb0 e3 1b 18 00 00 00 00 00 00 00 00 00 00 00 00 00 |................| 00001fc0 02 00 03 00 02 08 18 00 02 00 00 00 13 32 20 20 |.............2 | 00001fd0 20 20 20 20 20 05 62 00 e2 1b 18 00 00 00 00 00 | .b.........| 00001fe0 00 00 00 00 00 00 00 00 01 00 03 00 02 08 18 00 |................| 00001ff0 01 00 00 00 13 31 20 20 20 20 20 20 20 05 61 00 |.....1 .a.| 00002000
二、Items(Tuples)
每个Tuple包括两部分,第一部分是Tuple头部信息,第二部分是实际的数据。
相关数据结构如下:
//--------------------- src/include/storage/off.h /* * OffsetNumber: * * this is a 1-based index into the linp (ItemIdData) array in the * header of each disk page. */ typedef uint16 OffsetNumber; //--------------------- src/include/storage/block.h /* * BlockId: * * this is a storage type for BlockNumber. in other words, this type * is used for on-disk structures (e.g., in HeapTupleData) whereas * BlockNumber is the type on which calculations are performed (e.g., * in access method code). * * there doesn't appear to be any reason to have separate types except * for the fact that BlockIds can be SHORTALIGN'd (and therefore any * structures that contains them, such as ItemPointerData, can also be * SHORTALIGN'd). this is an important consideration for reducing the * space requirements of the line pointer (ItemIdData) array on each * page and the header of each heap or index tuple, so it doesn't seem * wise to change this without good reason. */ typedef struct BlockIdData { uint16 bi_hi; uint16 bi_lo; } BlockIdData; typedef BlockIdData *BlockId; /* block identifier */ //--------------------- src/include/storage/itemptr.h /* * ItemPointer: * * This is a pointer to an item within a disk page of a known file * (for example, a cross-link from an index to its parent table). * blkid tells us which block, posid tells us which entry in the linp * (ItemIdData) array we want. * * Note: because there is an item pointer in each tuple header and index * tuple header on disk, it's very important not to waste space with * structure padding bytes. The struct is designed to be six bytes long * (it contains three int16 fields) but a few compilers will pad it to * eight bytes unless coerced. We apply appropriate persuasion where * possible. If your compiler can't be made to play along, you'll waste * lots of space. */ typedef struct ItemPointerData { BlockIdData ip_blkid; OffsetNumber ip_posid; } //--------------------- src/include/access/htup_details.h typedef struct HeapTupleFields { TransactionId t_xmin; /* inserting xact ID */ TransactionId t_xmax; /* deleting or locking xact ID */ union { CommandId t_cid; /* inserting or deleting command ID, or both */ TransactionId t_xvac; /* old-style VACUUM FULL xact ID */ } t_field3; } HeapTupleFields; typedef struct DatumTupleFields { int32 datum_len_; /* varlena header (do not touch directly!) */ int32 datum_typmod; /* -1, or identifier of a record type */ Oid datum_typeid; /* composite type OID, or RECORDOID */ /* * datum_typeid cannot be a domain over composite, only plain composite, * even if the datum is meant as a value of a domain-over-composite type. * This is in line with the general principle that CoerceToDomain does not * change the physical representation of the base type value. * * Note: field ordering is chosen with thought that Oid might someday * widen to 64 bits. */ } DatumTupleFields; struct HeapTupleHeaderData { union { HeapTupleFields t_heap; DatumTupleFields t_datum; } t_choice; ItemPointerData t_ctid; /* current TID of this or newer tuple (or a * speculative insertion token) */ /* Fields below here must match MinimalTupleData! */ #define FIELDNO_HEAPTUPLEHEADERDATA_INFOMASK2 2 uint16 t_infomask2; /* number of attributes + various flags */ #define FIELDNO_HEAPTUPLEHEADERDATA_INFOMASK 3 uint16 t_infomask; /* various flag bits, see below */ #define FIELDNO_HEAPTUPLEHEADERDATA_HOFF 4 uint8 t_hoff; /* sizeof header incl. bitmap, padding */ /* ^ - 23 bytes - ^ */ #define FIELDNO_HEAPTUPLEHEADERDATA_BITS 5 bits8 t_bits[FLEXIBLE_ARRAY_MEMBER]; /* bitmap of NULLs */ /* MORE DATA FOLLOWS AT END OF STRUCT */ };
结构体展开,详见下表:
Field Type Length Offset Description t_xmin TransactionId 4 bytes 0 insert XID stamp t_xmax TransactionId 4 bytes 4 delete XID stamp t_cid CommandId 4 bytes 8 insert and/or delete CID stamp (overlays with t_xvac) t_xvac TransactionId 4 bytes 8 XID for VACUUM operation moving a row version t_ctid ItemPointerData 6 bytes 12 current TID of this or newer row version t_infomask2 uint16 2 bytes 18 number of attributes, plus various flag bits t_infomask uint16 2 bytes 20 various flag bits t_hoff uint8 1 byte 22 offset to user data //注意:t_cid和t_xvac为联合体,共用存储空间
从上一节我们已经得出第1个Tuple的偏移为8152,下面使用hexdump对其中的数据逐个解析:
t_xmin
[xdb@localhost ~]$ hexdump -C $PGDATA/base/16477/24801 -s 8152 -n 4 00001fd8 e2 1b 18 00 |....| 00001fdc [xdb@localhost ~]$ echo $((0x00181be2)) 1580002
t_xmax
[xdb@localhost ~]$ hexdump -C $PGDATA/base/16477/24801 -s 8156 -n 4 00001fdc 00 00 00 00 |....| 00001fe0
t_cid/t_xvac
[xdb@localhost ~]$ hexdump -C $PGDATA/base/16477/24801 -s 8160 -n 4 00001fe0 00 00 00 00 |....| 00001fe4
t_ctid
[xdb@localhost ~]$ hexdump -C $PGDATA/base/16477/24801 -s 8164 -n 6 00001fe4 00 00 00 00 01 00 |......| 00001fea //ip_blkid=\x0000,即blockid=0 //ip_posid=\x0001,即posid=1,第1个tuple
t_infomask2
[xdb@localhost ~]$ hexdump -C $PGDATA/base/16477/24801 -s 8170 -n 2 00001fea 03 00 |..| 00001fec //t_infomask2=\x0003,3代表什么意思?我们看看t_infomask2的说明 /* * information stored in t_infomask2: */ #define HEAP_NATTS_MASK 0x07FF /* 11 bits for number of attributes */ /* bits 0x1800 are available */ #define HEAP_KEYS_UPDATED 0x2000 /* tuple was updated and key cols * modified, or tuple deleted */ #define HEAP_HOT_UPDATED 0x4000 /* tuple was HOT-updated */ #define HEAP_ONLY_TUPLE 0x8000 /* this is heap-only tuple */ #define HEAP2_XACT_MASK 0xE000 /* visibility-related bits */ //根把十六进制值转换为二进制显示 11111111111 #define HEAP_NATTS_MASK 0x07FF 10000000000000 #define HEAP_KEYS_UPDATED 0x2000 100000000000000 #define HEAP_HOT_UPDATED 0x4000 1000000000000000 #define HEAP_ONLY_TUPLE 0x8000 1110000000000000 #define HEAP2_XACT_MASK 0xE000 1111111111111110 #define SpecTokenOffsetNumber 0xfffe //前(低)11位为属性的个数,3意味着有3个属性(字段)
t_infomask
[xdb@localhost ~]$ hexdump -C $PGDATA/base/16477/24801 -s 8172 -n 2 00001fec 02 08 |..| 00001fee [xdb@localhost ~]$ echo $((0x0802)) 2050 [xdb@localhost ~]$ echo "obase=2;2050"|bc 100000000010 //t_infomask=\x0802,十进制值为2050,二进制值为100000000010 //t_infomask说明 1 #define HEAP_HASNULL 0x0001 /* has null attribute(s) */ 10 #define HEAP_HASVARWIDTH 0x0002 /* has variable-width attribute(s) */ 100 #define HEAP_HASEXTERNAL 0x0004 /* has external stored attribute(s) */ 1000 #define HEAP_HASOID 0x0008 /* has an object-id field */ 10000 #define HEAP_XMAX_KEYSHR_LOCK 0x0010 /* xmax is a key-shared locker */ 100000 #define HEAP_COMBOCID 0x0020 /* t_cid is a combo cid */ 1000000 #define HEAP_XMAX_EXCL_LOCK 0x0040 /* xmax is exclusive locker */ 10000000 #define HEAP_XMAX_LOCK_ONLY 0x0080 /* xmax, if valid, is only a locker */ /* xmax is a shared locker */ #define HEAP_XMAX_SHR_LOCK (HEAP_XMAX_EXCL_LOCK | HEAP_XMAX_KEYSHR_LOCK) #define HEAP_LOCK_MASK (HEAP_XMAX_SHR_LOCK | HEAP_XMAX_EXCL_LOCK | \ HEAP_XMAX_KEYSHR_LOCK) 100000000 #define HEAP_XMIN_COMMITTED 0x0100 /* t_xmin committed */ 1000000000 #define HEAP_XMIN_INVALID 0x0200 /* t_xmin invalid/aborted */ #define HEAP_XMIN_FROZEN (HEAP_XMIN_COMMITTED|HEAP_XMIN_INVALID) 10000000000 #define HEAP_XMAX_COMMITTED 0x0400 /* t_xmax committed */ 100000000000 #define HEAP_XMAX_INVALID 0x0800 /* t_xmax invalid/aborted */ 1000000000000 #define HEAP_XMAX_IS_MULTI 0x1000 /* t_xmax is a MultiXactId */ 10000000000000 #define HEAP_UPDATED 0x2000 /* this is UPDATEd version of row */ 100000000000000 #define HEAP_MOVED_OFF 0x4000 /* moved to another place by pre-9.0 * VACUUM FULL; kept for binary * upgrade support */ 1000000000000000 #define HEAP_MOVED_IN 0x8000 /* moved from another place by pre-9.0 * VACUUM FULL; kept for binary * upgrade support */ #define HEAP_MOVED (HEAP_MOVED_OFF | HEAP_MOVED_IN) 1111111111110000 #define HEAP_XACT_MASK 0xFFF0 /* visibility-related bits */ //\x0802,二进制100000000010表示第2位和第12位为1, //意味着存在可变长属性(HEAP_HASVARWIDTH),XMAX无效(HEAP_XMAX_INVALID)
t_hoff
[xdb@localhost ~]$ hexdump -C $PGDATA/base/16477/24801 -s 8174 -n 1 00001fee 18 |.| 00001fef [xdb@localhost ~]$ echo $((0x18)) 24 //用户数据开始偏移为24,即8152+24
说完了Tuple的头部数据,接下来我们看看实际的数据存储。上一节我们得到Tuple总的长度是39,计算得到数据大小为39-24=15。
[xdb@localhost ~]$ hexdump -C $PGDATA/base/16477/24801 -s 8176 -n 15 00001ff0 01 00 00 00 13 31 20 20 20 20 20 20 20 05 61 |.....1 .a| 00001fff 回顾我们的表结构: create table t_page (id int,c1 char(8),c2 varchar(16)); 第1个字段为int,第2个字段为定长字符,第3个字段为变长字符。 相应的数据: id=\x00000001,数字1 c1=\x133120202020202020,字符串,无需高低位变换,第1个字节\x13为标志位,后面是字符'1'+7个空格 c2=\x0561,字符串,第1个字节\x05为标志位,后面是字符'a'
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本文标题:PostgreSQL数据页Page中的行数据分析
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