Esempio n. 1
0
//---------------------------------------------------------------------------
//	@function:
//		CPhysicalMotion::PppsRequired
//
//	@doc:
//		Compute required partition propagation of the n-th child
//
//---------------------------------------------------------------------------
CPartitionPropagationSpec *
CPhysicalMotion::PppsRequired
	(
	IMemoryPool *pmp,
	CExpressionHandle &exprhdl,
	CPartitionPropagationSpec *pppsRequired,
	ULONG 
#ifdef GPOS_DEBUG
	ulChildIndex
#endif // GPOS_DEBUG
	,
	DrgPdp *, //pdrgpdpCtxt,
	ULONG //ulOptReq
	)
{
	GPOS_ASSERT(0 == ulChildIndex);
	GPOS_ASSERT(NULL != pppsRequired);
	
	CPartIndexMap *ppimReqd = pppsRequired->Ppim();
	CPartFilterMap *ppfmReqd = pppsRequired->Ppfm();
	
	DrgPul *pdrgpul = ppimReqd->PdrgpulScanIds(pmp);
	
	CPartIndexMap *ppimResult = GPOS_NEW(pmp) CPartIndexMap(pmp);
	CPartFilterMap *ppfmResult = GPOS_NEW(pmp) CPartFilterMap(pmp);
	
	/// get derived part consumers
	CPartInfo *ppartinfo = exprhdl.Pdprel(0)->Ppartinfo();
	
	const ULONG ulPartIndexSize = pdrgpul->UlLength();
	
	for (ULONG ul = 0; ul < ulPartIndexSize; ul++)
	{
		ULONG ulPartIndexId = *((*pdrgpul)[ul]);

		if (!ppartinfo->FContainsScanId(ulPartIndexId))
		{
			// part index id does not exist in child nodes: do not push it below 
			// the motion
			continue;
		}

		ppimResult->AddRequiredPartPropagation(ppimReqd, ulPartIndexId, CPartIndexMap::EppraPreservePropagators);
		(void) ppfmResult->FCopyPartFilter(m_pmp, ulPartIndexId, ppfmReqd);
	}
		
	pdrgpul->Release();

	return GPOS_NEW(pmp) CPartitionPropagationSpec(ppimResult, ppfmResult);
}
Esempio n. 2
0
//---------------------------------------------------------------------------
//	@function:
//		CPhysical::PppsRequiredPushThruUnresolvedUnary
//
//	@doc:
//		Helper function for pushing unresolved partition propagation in unary
//		operators
//
//---------------------------------------------------------------------------
CPartitionPropagationSpec *
CPhysical::PppsRequiredPushThruUnresolvedUnary
	(
	IMemoryPool *mp,
	CExpressionHandle &exprhdl,
	CPartitionPropagationSpec *pppsRequired,
	EPropogatePartConstraint eppcPropogate
	)
{
	GPOS_ASSERT(NULL != pppsRequired);

	CPartInfo *ppartinfo = exprhdl.GetRelationalProperties(0)->Ppartinfo();
		
	CPartIndexMap *ppimReqd = pppsRequired->Ppim();
	CPartFilterMap *ppfmReqd = pppsRequired->Ppfm();

	ULongPtrArray *pdrgpul = ppimReqd->PdrgpulScanIds(mp);
	
	CPartIndexMap *ppimResult = GPOS_NEW(mp) CPartIndexMap(mp);
	CPartFilterMap *ppfmResult = GPOS_NEW(mp) CPartFilterMap(mp);

	const ULONG ulPartIndexIds = pdrgpul->Size();
		
	// iterate over required part index ids and decide which ones to push through
	for (ULONG ul = 0; ul < ulPartIndexIds; ul++)
	{
		ULONG part_idx_id = *((*pdrgpul)[ul]);
		GPOS_ASSERT(ppimReqd->Contains(part_idx_id));

		// if part index id is defined in child, push it to the child
		if (ppartinfo->FContainsScanId(part_idx_id))
		{
			// push requirements to child node
			ppimResult->AddRequiredPartPropagation(ppimReqd, part_idx_id, CPartIndexMap::EppraPreservePropagators);
			if (CPhysical::EppcAllowed == eppcPropogate)
			{
				// for some logical operators such as limit while we push the part index map, we cannot push the constraints
				// since they are NOT semantically equivalent. So only push the constraints when the operator asks this
				// utility function to do so
				(void) ppfmResult->FCopyPartFilter(mp, part_idx_id, ppfmReqd);
			}
		}
	}
	
	pdrgpul->Release();

	return GPOS_NEW(mp) CPartitionPropagationSpec(ppimResult, ppfmResult);
}
//---------------------------------------------------------------------------
//	@function:
//		CPhysicalPartitionSelector::PppsRequired
//
//	@doc:
//		Compute required partition propagation of the n-th child
//
//---------------------------------------------------------------------------
CPartitionPropagationSpec *
CPhysicalPartitionSelector::PppsRequired
	(
	IMemoryPool *mp,
	CExpressionHandle & exprhdl,
	CPartitionPropagationSpec *pppsRequired,
	ULONG
#ifdef GPOS_DEBUG
	child_index
#endif // GPOS_DEBUG
	,
	CDrvdProp2dArray *, //pdrgpdpCtxt,
	ULONG //ulOptReq
	)
{
	GPOS_ASSERT(0 == child_index);
	GPOS_ASSERT(NULL != pppsRequired);

	CPartIndexMap *ppimInput = pppsRequired->Ppim();
	CPartFilterMap *ppfmInput = pppsRequired->Ppfm();

	ULongPtrArray *pdrgpulInputScanIds = ppimInput->PdrgpulScanIds(mp);

	CPartIndexMap *ppim = GPOS_NEW(mp) CPartIndexMap(mp);
	CPartFilterMap *ppfm = GPOS_NEW(mp) CPartFilterMap(mp);

	CPartInfo *ppartinfo = exprhdl.GetRelationalProperties(0)->Ppartinfo();

	const ULONG ulScanIds = pdrgpulInputScanIds->Size();

	for (ULONG ul = 0; ul < ulScanIds; ul++)
	{
		ULONG scan_id = *((*pdrgpulInputScanIds)[ul]);
		ULONG ulExpectedPropagators = ppimInput->UlExpectedPropagators(scan_id);

		if (scan_id == m_scan_id)
		{
			// partition propagation resolved - do not need to require from children
			continue;
		}

		if (!ppartinfo->FContainsScanId(scan_id) && ppartinfo->FContainsScanId(m_scan_id))
		{
		    // dynamic scan for the required id not defined below, but the current one is: do not push request down
			continue;
		}

		IMDId *mdid = ppimInput->GetRelMdId(scan_id);
		CPartKeysArray *pdrgppartkeys = ppimInput->Pdrgppartkeys(scan_id);
		UlongToPartConstraintMap *ppartcnstrmap = ppimInput->Ppartcnstrmap(scan_id);
		CPartConstraint *ppartcnstr = ppimInput->PpartcnstrRel(scan_id);
		CPartIndexMap::EPartIndexManipulator epim = ppimInput->Epim(scan_id);
		mdid->AddRef();
		pdrgppartkeys->AddRef();
		ppartcnstrmap->AddRef();
		ppartcnstr->AddRef();

		ppim->Insert(scan_id, ppartcnstrmap, epim, ulExpectedPropagators, mdid, pdrgppartkeys, ppartcnstr);
		(void) ppfm->FCopyPartFilter(m_mp, scan_id, ppfmInput);
	}

	// cleanup
	pdrgpulInputScanIds->Release();

	return GPOS_NEW(mp) CPartitionPropagationSpec(ppim, ppfm);
}
Esempio n. 4
0
//---------------------------------------------------------------------------
//	@function:
//		CPhysicalPartitionSelector::PppsRequired
//
//	@doc:
//		Compute required partition propagation of the n-th child
//
//---------------------------------------------------------------------------
CPartitionPropagationSpec *
CPhysicalPartitionSelector::PppsRequired
	(
	IMemoryPool *pmp,
	CExpressionHandle & exprhdl,
	CPartitionPropagationSpec *pppsRequired,
	ULONG
#ifdef GPOS_DEBUG
	ulChildIndex
#endif // GPOS_DEBUG
	,
	DrgPdp *, //pdrgpdpCtxt,
	ULONG //ulOptReq
	)
{
	GPOS_ASSERT(0 == ulChildIndex);
	GPOS_ASSERT(NULL != pppsRequired);

	CPartIndexMap *ppimInput = pppsRequired->Ppim();
	CPartFilterMap *ppfmInput = pppsRequired->Ppfm();

	DrgPul *pdrgpulInputScanIds = ppimInput->PdrgpulScanIds(pmp);

	CPartIndexMap *ppim = GPOS_NEW(pmp) CPartIndexMap(pmp);
	CPartFilterMap *ppfm = GPOS_NEW(pmp) CPartFilterMap(pmp);

	CPartInfo *ppartinfo = exprhdl.Pdprel(0)->Ppartinfo();

	const ULONG ulScanIds = pdrgpulInputScanIds->UlLength();

	for (ULONG ul = 0; ul < ulScanIds; ul++)
	{
		ULONG ulScanId = *((*pdrgpulInputScanIds)[ul]);
		ULONG ulExpectedPropagators = ppimInput->UlExpectedPropagators(ulScanId);

		if (ulScanId == m_ulScanId)
		{
			// partition propagation resolved - do not need to require from children
			continue;
		}

		if (!ppartinfo->FContainsScanId(ulScanId) && ppartinfo->FContainsScanId(m_ulScanId))
		{
		    // dynamic scan for the required id not defined below, but the current one is: do not push request down
			continue;
		}

		IMDId *pmdid = ppimInput->PmdidRel(ulScanId);
		DrgPpartkeys *pdrgppartkeys = ppimInput->Pdrgppartkeys(ulScanId);
		PartCnstrMap *ppartcnstrmap = ppimInput->Ppartcnstrmap(ulScanId);
		CPartConstraint *ppartcnstr = ppimInput->PpartcnstrRel(ulScanId);
		CPartIndexMap::EPartIndexManipulator epim = ppimInput->Epim(ulScanId);
		pmdid->AddRef();
		pdrgppartkeys->AddRef();
		ppartcnstrmap->AddRef();
		ppartcnstr->AddRef();

		ppim->Insert(ulScanId, ppartcnstrmap, epim, ulExpectedPropagators, pmdid, pdrgppartkeys, ppartcnstr);
		(void) ppfm->FCopyPartFilter(m_pmp, ulScanId, ppfmInput);
	}

	// cleanup
	pdrgpulInputScanIds->Release();

	return GPOS_NEW(pmp) CPartitionPropagationSpec(ppim, ppfm);
}