本节继续介绍聚合函数的实现,主要
本节继续介绍聚合函数的实现,主要介绍了不使用Hash算法的情况下聚合函数的实现,在这种情况下会先排序后执行聚合,在ExecAgg节点执行前,已完成排序的操作.下面介绍在已完成排序的情况下聚合的实现,主要实现函数是ExecAgg->agg_retrieve_direct.
下面是不使用HashAggregate情况下GroupAggregate的计划树:
",,,,,"select bh,avg(c1),min(c1),max(c2) from t_agg_simple group by bh;",,,"psql"
2019-05-16 12:04:45.621 CST,"xdb","testdb",1545,"[local]",5cdce11a.609,5,"SELECT",2019-05-16 12:03:38 CST,3/4,0,LOG,00000,"plan:"," {PLANNEDSTMT
:commandType 1
:queryId 0
:hasReturning false
:hasModifyinGCTE false
:canSetTag true
:transientPlan false
:dependsOnRole false
:parallelModeNeeded false
:jitFlags 0
:planTree
{AGG
:startup_cost 52.67
:total_cost 64.42
:plan_rows 200
:plan_width 98
:parallel_aware false
:parallel_safe true
:plan_node_id 0
:targetlist (...
)
:qual <>
:lefttree
{SORT
:startup_cost 52.67
:total_cost 54.52
:plan_rows 740
:plan_width 66
:parallel_aware false
:parallel_safe true
:plan_node_id 1
:targetlist (...
)
:qual <>
:lefttree
{SEQSCAN
:startup_cost 0.00
:total_cost 17.40
:plan_rows 740
:plan_width 66
:parallel_aware false
:parallel_safe true
:plan_node_id 2
:targetlist (...
)
:qual <>
:lefttree <>
:righttree <>
:initPlan <>
:extParam (b)
:allParam (b)
:scanrelid 1
}
:righttree <>
:initPlan <>
:extParam (b)
:allParam (b)
:numCols 1
:sortColIdx 1
:sortOperators 664
:collations 100
:nullsFirst false
}
:righttree <>
:initPlan <>
:extParam (b)
:allParam (b)
:aggstrategy 1
:aggsplit 0
:numCols 1
:grpcolIdx 1
:grpOperators 98
:numGroups 200
:aggParams (b)
:groupingSets <>
:chain <>
}
:rtable (...
)
:resultRelations <>
:nonleafResultRelations <>
:rootResultRelations <>
:subplans <>
:rewindPlanIDs (b)
:rowMarks <>
:relationOids (o 270375)
:invalItems <>
:paramExecTypes <>
:utilityStmt <>
:stmt_location 0
:stmt_len 63
}
可以看到,在ExecAgg前会先执行ExecSort.
AggState
聚合函数执行时状态结构体,内含AggStatePerAgg等结构体
//在nodeAgg.c中私有的结构体
typedef struct AggStatePerAggData *AggStatePerAgg;
typedef struct AggStatePerTransData *AggStatePerTrans;
typedef struct AggStatePerGroupData *AggStatePerGroup;
typedef struct AggStatePerPhaseData *AggStatePerPhase;
typedef struct AggStatePerHashData *AggStatePerHash;
typedef struct AggState
{
//第一个字段是NodeTag(继承自ScanState)
ScanState ss;
//targetlist和quals中所有的Aggref
List *aggs;
//链表的大小(可以为0)
int numaggs;
//pertrans条目大小
int numtrans;
//Agg策略模式
AggStrategy aggstrategy;
//agg-splitting模式,参见nodes.h
AggSplit aggsplit;
//指向当前步骤数据的指针
AggStatePerPhase phase;
//步骤数(包括0)
int numphases;
//当前步骤
int current_phase;
//per-Aggref信息
AggStatePerAgg peragg;
//per-Trans状态信息
AggStatePerTrans pertrans;
//长生命周期数据的ExprContexts(hashtable)
ExprContext *hashcontext;
////长生命周期数据的ExprContexts(每一个GS使用)
ExprContext **aggcontexts;
//输入表达式的ExprContext
ExprContext *tmpcontext;
#define FIELDNO_AGGSTATE_CURAGGCONTEXT 14
//当前活跃的aggcontext
ExprContext *curaggcontext;
//当前活跃的aggregate(如存在)
AggStatePerAgg curperagg;
#define FIELDNO_AGGSTATE_CURPERTRANS 16
//当前活跃的trans state
AggStatePerTrans curpertrans;
//输入结束?
bool input_done;
//Agg扫描结束?
bool agg_done;
//最后一个grouping set
int projected_set;
#define FIELDNO_AGGSTATE_CURRENT_SET 20
//将要解析的当前grouping set
int current_set;
//当前投影操作的分组列
Bitmapset *grouped_cols;
//倒序的分组列链表
List *all_grouped_cols;
//-------- 下面的列用于grouping set步骤数据
//所有步骤中最大的sets大小
int maxsets;
//所有步骤的数组
AggStatePerPhase phases;
//对于phases > 1,已排序的输入信息
Tuplesortstate *sort_in;
//对于下一个步骤,输入已拷贝
Tuplesortstate *sort_out;
//排序结果的slot
TupleTableSlot *sort_slot;
//------- 下面的列用于AGG_PLAIN和AGG_SORTED模式:
//per-group指针的grouping set编号数组
AggStatePerGroup *pergroups;
//当前组的第一个元组拷贝
HeapTuple grp_firstTuple;
//--------- 下面的列用于AGG_HASHED和AGG_MIXED模式:
//是否已填充hash表?
bool table_filled;
//hash桶数?
int num_hashes;
//相应的哈希表数据数组
AggStatePerHash perhash;
//per-group指针的grouping set编号数组
AggStatePerGroup *hash_pergroup;
//---------- agg输入表达式解析支持
#define FIELDNO_AGGSTATE_ALL_PERGROUPS 34
//首先是->pergroups,然后是hash_pergroup
AggStatePerGroup *all_pergroups;
//投影实现机制
ProjectionInfo *combinedproj;
} AggState;
//nodeag .c支持的基本选项
#define AGGSPLITOP_COMBINE 0x01
#define AGGSPLITOP_SKIPFINAL 0x02
#define AGGSPLITOP_SERIALIZE 0x04
#define AGGSPLITOP_DESERIALIZE 0x08
//支持的操作模式
typedef enum AggSplit
{
//基本 : 非split聚合
AGGSPLIT_SIMPLE = 0,
//部分聚合的初始步骤,序列化
AGGSPLIT_INITIAL_SERIAL = AGGSPLITOP_SKIPFINAL | AGGSPLITOP_SERIALIZE,
//部分聚合的最终步骤,反序列化
AGGSPLIT_FINAL_DESERIAL = AGGSPLITOP_COMBINE | AGGSPLITOP_DESERIALIZE
} AggSplit;
//测试AggSplit选择了哪些基本选项
#define DO_AGGSPLIT_COMBINE(as) (((as) & AGGSPLITOP_COMBINE) != 0)
#define DO_AGGSPLIT_SKIPFINAL(as) (((as) & AGGSPLITOP_SKIPFINAL) != 0)
#define DO_AGGSPLIT_SERIALIZE(as) (((as) & AGGSPLITOP_SERIALIZE) != 0)
#define DO_AGGSPLIT_DESERIALIZE(as) (((as) & AGGSPLITOP_DESERIALIZE) != 0)
agg_retrieve_direct
agg_retrieve_direct计算聚合的最终结果,适用于不使用Hash算法的情况.
static TupleTableSlot *
agg_retrieve_direct(AggState *aggstate)
{
Agg *node = aggstate->phase->aggnode;//aggstate Node
ExprContext *econtext;//表达式解析上下文
ExprContext *tmpcontext;//临时上下文
AggStatePerAgg peragg;//聚合
AggStatePerGroup *pergroups;//分组信息
TupleTableSlot *outerslot;//outer元组slot
TupleTableSlot *firstSlot;//第1个slot
TupleTableSlot *result;//结果元组
bool hasGroupingSets = aggstate->phase->numsets > 0;//是否有grouping set
int numGroupingSets = Max(aggstate->phase->numsets, 1);
int currentSet;
int nextSetSize;
int numReset;
int i;
econtext = aggstate->ss.ps.ps_ExprContext;
tmpcontext = aggstate->tmpcontext;
peragg = aggstate->peragg;
pergroups = aggstate->pergroups;
firstSlot = aggstate->ss.ss_ScanTupleSlot;
while (!aggstate->agg_done)
{
//----------- 循环处理
ReScanExprContext(econtext);
if (aggstate->projected_set >= 0 &&
aggstate->projected_set < numGroupingSets)
numReset = aggstate->projected_set + 1;
else
numReset = numGroupingSets;
for (i = 0; i < numReset; i++)
{
ReScanExprContext(aggstate->aggcontexts[i]);
}
if (aggstate->input_done == true &&
aggstate->projected_set >= (numGroupingSets - 1))
{
if (aggstate->current_phase < aggstate->numphases - 1)
{
//仍在处理中
initialize_phase(aggstate, aggstate->current_phase + 1);
aggstate->input_done = false;
aggstate->projected_set = -1;
numGroupingSets = Max(aggstate->phase->numsets, 1);
node = aggstate->phase->aggnode;
numReset = numGroupingSets;
}
else if (aggstate->aggstrategy == AGG_MIXED)
{
//照理,不会进入这个分支(AGG_MIXED不是Hash才有吗?)
initialize_phase(aggstate, 0);
aggstate->table_filled = true;
ResetTupleHashIterator(aggstate->perhash[0].hashtable,
&aggstate->perhash[0].hashiter);
select_current_set(aggstate, 0, true);
return agg_retrieve_hash_table(aggstate);
}
else
{
//已完成处理
aggstate->agg_done = true;
break;
}
}
if (aggstate->projected_set >= 0 &&
aggstate->projected_set < (numGroupingSets - 1))
nextSetSize = aggstate->phase->gset_lengths[aggstate->projected_set + 1];
else
nextSetSize = 0;
tmpcontext->ecxt_innertuple = econtext->ecxt_outertuple;
if (aggstate->input_done ||
(node->aggstrategy != AGG_PLAIN &&
aggstate->projected_set != -1 &&
aggstate->projected_set < (numGroupingSets - 1) &&
nextSetSize > 0 &&
!ExecQualAndReset(aggstate->phase->eqfunctions[nextSetSize - 1],
tmpcontext)))
{
aggstate->projected_set += 1;
Assert(aggstate->projected_set < numGroupingSets);
Assert(nextSetSize > 0 || aggstate->input_done);
}
else
{
aggstate->projected_set = 0;
if (aggstate->grp_firstTuple == NULL)
{
//提取一行
outerslot = fetch_input_tuple(aggstate);
if (!TupIsNull(outerslot))
{
//成功提取一行
aggstate->grp_firstTuple = ExecCopySlotTuple(outerslot);
}
else
{
//不再产生新行
if (hasGroupingSets)
{
//----------- 存在grouping set
aggstate->input_done = true;
while (aggstate->phase->gset_lengths[aggstate->projected_set] > 0)
{
aggstate->projected_set += 1;
if (aggstate->projected_set >= numGroupingSets)
{
break;
}
}
if (aggstate->projected_set >= numGroupingSets)
continue;
}
else
{
aggstate->agg_done = true;
if (node->aggstrategy != AGG_PLAIN)
return NULL;
}
}
}
initialize_aggregates(aggstate, pergroups, numReset);
if (aggstate->grp_firstTuple != NULL)
{
ExecStoreTuple(aggstate->grp_firstTuple,
firstSlot,
InvalidBuffer,
true);
aggstate->grp_firstTuple = NULL;
//为第一次advance_aggregates调用设置参数
tmpcontext->ecxt_outertuple = firstSlot;
for (;;)
{
if (aggstate->aggstrategy == AGG_MIXED &&
aggstate->current_phase == 1)
{
lookup_hash_entries(aggstate);
}
//推动聚合(或者组合函数)
advance_aggregates(aggstate);
//在每一个元组后重置per-input-tuple上下文
ResetExprContext(tmpcontext);
outerslot = fetch_input_tuple(aggstate);
if (TupIsNull(outerslot))
{
//已无更多可用的outer slot
if (hasGroupingSets)
{
aggstate->input_done = true;
break;
}
else
{
aggstate->agg_done = true;
break;
}
}
//为下一次advance_aggregates调用作准备
tmpcontext->ecxt_outertuple = outerslot;
if (node->aggstrategy != AGG_PLAIN)
{
tmpcontext->ecxt_innertuple = firstSlot;
if (!ExecQual(aggstate->phase->eqfunctions[node->numCols - 1],
tmpcontext))
{
aggstate->grp_firstTuple = ExecCopySlotTuple(outerslot);
break;
}
}
}
}
econtext->ecxt_outertuple = firstSlot;
}
Assert(aggstate->projected_set >= 0);
currentSet = aggstate->projected_set;
//投影处理
prepare_projection_slot(aggstate, econtext->ecxt_outertuple, currentSet);
select_current_set(aggstate, currentSet, false);
finalize_aggregates(aggstate,
peragg,
pergroups[currentSet]);
result = project_aggregates(aggstate);
if (result)
return result;
}
//DONE!
return NULL;
}
测试脚本
-- 禁用并行
set max_parallel_workers_per_gather=0;
-- 禁用hashagg
set enable_hashagg = off;
select bh,avg(c1),min(c1),max(c2) from t_agg_simple group by bh;
跟踪分析
(gdb) b agg_retrieve_direct
Breakpoint 1 at 0x6ee511: file nodeAgg.c, line 1572.
(gdb) c
Continuing.
Breakpoint 1, agg_retrieve_direct (aggstate=0x268f640) at nodeAgg.c:1572
1572 Agg *node = aggstate->phase->aggnode;
输入参数
(gdb) p *aggstate
$1 = {ss = {ps = {type = T_AggState, plan = 0x25af578, state = 0x268f428, ExecProcNode = 0x6ee438 <ExecAgg>,
ExecProcNodeReal = 0x6ee438 <ExecAgg>, instrument = 0x0, worker_instrument = 0x0, worker_jit_instrument = 0x0,
qual = 0x0, lefttree = 0x268faf0, righttree = 0x0, initPlan = 0x0, subPlan = 0x0, chgParam = 0x0,
ps_ResultTupleSlot = 0x2690d50, ps_ExprContext = 0x268fa30, ps_ProjInfo = 0x2690e90, scandesc = 0x26907a0},
ss_currentRelation = 0x0, ss_currentScanDesc = 0x0, ss_ScanTupleSlot = 0x2690a78}, aggs = 0x25d4290, numaggs = 3,
numtrans = 3, aggstrategy = AGG_SORTED, aggsplit = AGGSPLIT_SIMPLE, phase = 0x2691290, numphases = 2, current_phase = 1,
peragg = 0x2690f28, pertrans = 0x26b24d0, hashcontext = 0x0, aggcontexts = 0x268f858, tmpcontext = 0x268f878,
curaggcontext = 0x268f970, curperagg = 0x0, curpertrans = 0x0, input_done = false, agg_done = false, projected_set = -1,
current_set = 0, grouped_cols = 0x0, all_grouped_cols = 0x0, maxsets = 1, phases = 0x2691258, sort_in = 0x0,
sort_out = 0x0, sort_slot = 0x0, pergroups = 0x25d4da0, grp_firstTuple = 0x0, table_filled = false, num_hashes = 0,
perhash = 0x0, hash_pergroup = 0x0, all_pergroups = 0x25d4da0, combinedproj = 0x0}
需要2个阶段,分别是AGG_PLAIN/AGG_SORTED
(gdb) p aggstate->phases[0]
$2 = {aggstrategy = AGG_PLAIN, numsets = 0, gset_lengths = 0x0, grouped_cols = 0x0, eqfunctions = 0x0, aggnode = 0x0,
sortnode = 0x0, evaltrans = 0x0}
(gdb) p aggstate->phases[1]
$3 = {aggstrategy = AGG_SORTED, numsets = 0, gset_lengths = 0x0, grouped_cols = 0x0, eqfunctions = 0x25d4388,
aggnode = 0x25af578, sortnode = 0x0, evaltrans = 0x25d5488}
不存在grouping set.
变量numGroupingSets设置为1
(gdb) n
1580 bool hasGroupingSets = aggstate->phase->numsets > 0;
(gdb) p aggstate->phase->numsets
$5 = 0
(gdb) n
1581 int numGroupingSets = Max(aggstate->phase->numsets, 1);
(gdb) n
1594 econtext = aggstate->ss.ps.ps_ExprContext;
(gdb) p numGroupingSets
$6 = 1
设置内存上下文
(gdb) n
1595 tmpcontext = aggstate->tmpcontext;
(gdb)
1597 peragg = aggstate->peragg;
(gdb) p *econtext
$7 = {type = T_ExprContext, ecxt_scantuple = 0x0, ecxt_innertuple = 0x0, ecxt_outertuple = 0x0,
ecxt_per_query_memory = 0x268f310, ecxt_per_tuple_memory = 0x26a6370, ecxt_param_exec_vals = 0x0,
ecxt_param_list_info = 0x0, ecxt_aggvalues = 0x25d4d48, ecxt_aggnulls = 0x25d4d80, caseValue_datum = 0,
caseValue_isNull = true, domainValue_datum = 0, domainValue_isNull = true, ecxt_estate = 0x268f428, ecxt_callbacks = 0x0}
(gdb) p *tmpcontext
$8 = {type = T_ExprContext, ecxt_scantuple = 0x0, ecxt_innertuple = 0x0, ecxt_outertuple = 0x0,
ecxt_per_query_memory = 0x268f310, ecxt_per_tuple_memory = 0x2691320, ecxt_param_exec_vals = 0x0,
ecxt_param_list_info = 0x0, ecxt_aggvalues = 0x0, ecxt_aggnulls = 0x0, caseValue_datum = 0, caseValue_isNull = true,
domainValue_datum = 0, domainValue_isNull = true, ecxt_estate = 0x268f428, ecxt_callbacks = 0x0}
(gdb)
获取聚合信息,一共有3个
(gdb) n
1598 pergroups = aggstate->pergroups;
(gdb)
1599 firstSlot = aggstate->ss.ss_ScanTupleSlot;
(gdb) p *peragg
$9 = {aggref = 0x26a02d0, transno = 0, finalfn_oid = 0, finalfn = {fn_addr = 0x0, fn_oid = 0, fn_nargs = 0,
fn_strict = false, fn_retset = false, fn_stats = 0 '\000', fn_extra = 0x0, fn_mcxt = 0x0, fn_expr = 0x0},
numFinalArgs = 1, aggdirectargs = 0x0, resulttypeLen = 4, resulttypeByVal = true, shareable = true}
(gdb) p peragg[0]
$10 = {aggref = 0x26a02d0, transno = 0, finalfn_oid = 0, finalfn = {fn_addr = 0x0, fn_oid = 0, fn_nargs = 0,
fn_strict = false, fn_retset = false, fn_stats = 0 '\000', fn_extra = 0x0, fn_mcxt = 0x0, fn_expr = 0x0},
numFinalArgs = 1, aggdirectargs = 0x0, resulttypeLen = 4, resulttypeByVal = true, shareable = true}
(gdb) p peragg[1]
$11 = {aggref = 0x26a0048, transno = 1, finalfn_oid = 0, finalfn = {fn_addr = 0x0, fn_oid = 0, fn_nargs = 0,
fn_strict = false, fn_retset = false, fn_stats = 0 '\000', fn_extra = 0x0, fn_mcxt = 0x0, fn_expr = 0x0},
numFinalArgs = 1, aggdirectargs = 0x0, resulttypeLen = 4, resulttypeByVal = true, shareable = true}
(gdb) p peragg[2]
$12 = {aggref = 0x269fdc0, transno = 2, finalfn_oid = 1964, finalfn = {fn_addr = 0x978251 <int8_avg>, fn_oid = 1964,
fn_nargs = 1, fn_strict = true, fn_retset = false, fn_stats = 2 '\002', fn_extra = 0x0, fn_mcxt = 0x268f310,
fn_expr = 0x25d5190}, numFinalArgs = 1, aggdirectargs = 0x0, resulttypeLen = -1, resulttypeByVal = false,
shareable = true}
分组只有一个
(gdb) p pergroups[0]
$14 = (AggStatePerGroup) 0x25d4dc0
(gdb) p *pergroups[0]
$15 = {transValue = 0, transValueIsNull = false, noTransValue = false}
进入循环
(gdb) n
1610 while (!aggstate->agg_done)
(gdb)
1624 ReScanExprContext(econtext);
(gdb)
重置内存上下文
(gdb)
1629 if (aggstate->projected_set >= 0 &&
(gdb)
1633 numReset = numGroupingSets;
(gdb)
1642 for (i = 0; i < numReset; i++)
(gdb)
1644 ReScanExprContext(aggstate->aggcontexts[i]);
(gdb)
1642 for (i = 0; i < numReset; i++)
(gdb)
检查输入是否已完成处理/本组已完成投影(实际不满足条件)
(gdb)
1651 if (aggstate->input_done == true &&
(gdb)
1688 if (aggstate->projected_set >= 0 &&
(gdb) p aggstate->input_done
$16 = false
(gdb) p aggstate->projected_set
$17 = -1
设置待处理的元组,为NULL
(gdb)
1711 tmpcontext->ecxt_innertuple = econtext->ecxt_outertuple;
(gdb)
1712 if (aggstate->input_done ||
(gdb)
(gdb) p *tmpcontext->ecxt_innertuple
Cannot access memory at address 0x0
如果子分组已存在,则执行投影(实际不满足条件).
(gdb) n
1713 (node->aggstrategy != AGG_PLAIN &&
(gdb) p node->aggstrategy
$18 = AGG_SORTED
(gdb) n
1712 if (aggstate->input_done ||
(gdb)
1714 aggstate->projected_set != -1 &&
(gdb)
1713 (node->aggstrategy != AGG_PLAIN &&
(gdb)
1732 aggstate->projected_set = 0;
(gdb) p aggstate->input_done
$19 = false
(gdb) p aggstate->projected_set
$20 = -1
(gdb) p node->aggstrategy
$21 = AGG_SORTED
(gdb)
从outer plan中提取一行,并拷贝为首行
(gdb) n
1738 if (aggstate->grp_firstTuple == NULL)
(gdb) p aggstate->grp_firstTuple
$22 = (HeapTuple) 0x0
(gdb) n
1740 outerslot = fetch_input_tuple(aggstate);
(gdb)
1741 if (!TupIsNull(outerslot))
(gdb) p *outerslot
$23 = {type = T_TupleTableSlot, tts_isempty = false, tts_shouldFree = false, tts_shouldFreeMin = false, tts_slow = false,
tts_tuple = 0x26909f8, tts_tupleDescriptor = 0x26907a0, tts_mcxt = 0x268f310, tts_buffer = 0, tts_nvalid = 0,
tts_values = 0x2690a18, tts_isnull = 0x2690a30, tts_mintuple = 0x26b8ad8, tts_minhdr = {t_len = 40, t_self = {ip_blkid = {
bi_hi = 0, bi_lo = 0}, ip_posid = 0}, t_tableOid = 0, t_data = 0x26b8ad0}, tts_off = 0,
tts_fixedTupleDescriptor = true}
(gdb)
(gdb) n
1747 aggstate->grp_firstTuple = ExecCopySlotTuple(outerslot);
(gdb)
为新输入的元组组初始化工作状态.
(gdb)
1797 initialize_aggregates(aggstate, pergroups, numReset);
把元组拷贝到内存上下文中,并执行聚合运算(advance_aggregates)
(gdb) n
1799 if (aggstate->grp_firstTuple != NULL)
(gdb)
1806 ExecStoreTuple(aggstate->grp_firstTuple,
(gdb)
1810 aggstate->grp_firstTuple = NULL;
(gdb)
1813 tmpcontext->ecxt_outertuple = firstSlot;
(gdb)
1825 if (aggstate->aggstrategy == AGG_MIXED &&
(gdb)
1832 advance_aggregates(aggstate);
(gdb)
1835 ResetExprContext(tmpcontext);
(gdb)
继续提取行,拷贝到内存上下文中
(gdb) n
1837 outerslot = fetch_input_tuple(aggstate);
(gdb)
1838 if (TupIsNull(outerslot))
(gdb)
1853 tmpcontext->ecxt_outertuple = outerslot;
(gdb)
1859 if (node->aggstrategy != AGG_PLAIN)
(gdb)
1861 tmpcontext->ecxt_innertuple = firstSlot;
(gdb)
1862 if (!ExecQual(aggstate->phase->eqfunctions[node->numCols - 1],
(gdb)
1869 }
执行聚合运算,并继续提取下一行
825 if (aggstate->aggstrategy == AGG_MIXED &&
(gdb)
1832 advance_aggregates(aggstate);
(gdb)
1835 ResetExprContext(tmpcontext);
(gdb)
1837 outerslot = fetch_input_tuple(aggstate);
(gdb)
1838 if (TupIsNull(outerslot))
(gdb)
1853 tmpcontext->ecxt_outertuple = outerslot;
(gdb)
1859 if (node->aggstrategy != AGG_PLAIN)
(gdb)
1861 tmpcontext->ecxt_innertuple = firstSlot;
(gdb)
如果是分组,检查是否已跨越分组边界,如已越界在跳出循环.
1862 if (!ExecQual(aggstate->phase->eqfunctions[node->numCols - 1],
(gdb)
1865 aggstate->grp_firstTuple = ExecCopySlotTuple(outerslot);
(gdb)
1866 break;
已获得一行结果行,返回结果
(gdb)
1880 econtext->ecxt_outertuple = firstSlot;
(gdb) n
1883 Assert(aggstate->projected_set >= 0);
(gdb)
1885 currentSet = aggstate->projected_set;
(gdb)
1887 prepare_projection_slot(aggstate, econtext->ecxt_outertuple, currentSet);
(gdb) p aggstate->projected_set
$24 = 0
(gdb) n
1889 select_current_set(aggstate, currentSet, false);
(gdb)
1893 pergroups[currentSet]);
(gdb)
1891 finalize_aggregates(aggstate,
(gdb)
1899 result = project_aggregates(aggstate);
(gdb)
1900 if (result)
(gdb)
1901 return result;
(gdb) p *result
$25 = {type = T_TupleTableSlot, tts_isempty = false, tts_shouldFree = false, tts_shouldFreeMin = false, tts_slow = false,
tts_tuple = 0x0, tts_tupleDescriptor = 0x2690b38, tts_mcxt = 0x268f310, tts_buffer = 0, tts_nvalid = 4,
tts_values = 0x2690db0, tts_isnull = 0x2690dd0, tts_mintuple = 0x0, tts_minhdr = {t_len = 0, t_self = {ip_blkid = {
bi_hi = 0, bi_lo = 0}, ip_posid = 0}, t_tableOid = 0, t_data = 0x0}, tts_off = 0, tts_fixedTupleDescriptor = true}
(gdb)
DONE!
postgresql 源码解读(178)- 查询#95(聚合函数)#1相关数据结构
PostgreSQL 源码解读(186)- 查询#102(聚合函数#7-advance_aggregates)
--结束END--
本文标题: PostgreSQL 源码解读(191)- 查询#107(聚合函数#12 - agg_retrieve_direct)
本文链接: https://www.lsjlt.com/news/47803.html(转载时请注明来源链接)
有问题或投稿请发送至: 邮箱/279061341@qq.com QQ/279061341
下载Word文档到电脑,方便收藏和打印~
2024-06-06
2024-06-06
2024-06-05
2024-06-04
2024-06-04
2024-06-03
2024-06-03
2024-06-03
2024-06-04
2024-06-03
回答
回答
回答
回答
回答
回答
回答
回答
回答
回答
官方手机版
微信公众号
商务合作
0