示例#1
0
void
unpackMetrics(Prof::CallPath::Profile& profile,
	      const ParallelAnalysis::PackedMetrics& packedMetrics)
{
  Prof::CCT::Tree& cct = *profile.cct();

  // 1. unpack 'packedMetrics' into temporary derived metrics [mBegId,
  //    mEndId) in 'profile'
  uint mBegId = packedMetrics.mBegId(), mEndId = packedMetrics.mEndId();

  DIAG_Assert(packedMetrics.numNodes() == cct.maxDenseId() + 1, "");
  DIAG_Assert(packedMetrics.numMetrics() == mEndId - mBegId, "");

  for (uint nodeId = 1; nodeId < packedMetrics.numNodes(); ++nodeId) {
    for (uint mId1 = 0, mId2 = mBegId; mId2 < mEndId; ++mId1, ++mId2) {
      Prof::CCT::ANode* n = cct.findNode(nodeId);
      n->demandMetric(mId2) = packedMetrics.idx(nodeId, mId1);
    }
  }

  // 2. update derived metrics [mDrvdBeg, mDrvdEnd) based on new
  //    values in [mBegId, mEndId)
  uint mDrvdBeg = packedMetrics.mDrvdBegId();
  uint mDrvdEnd = packedMetrics.mDrvdEndId();
  cct.root()->computeMetricsIncr(*profile.metricMgr(), mDrvdBeg, mDrvdEnd,
				 Prof::Metric::AExprIncr::FnCombine);
}
示例#2
0
// mergeCilkMain: cilk_main is called from two distinct call sites
// within the runtime, resulting in an undesirable bifurcation within
// the CCT.  The easiest way to fix this is to use a normalization
// step.
static void
mergeCilkMain(Prof::CallPath::Profile& prof)
{
  using namespace Prof;

  CCT::ProcFrm* mainFrm = NULL;

  // 1. attempt to find 'CilkNameMgr::cilkmain'
  for (CCT::ANodeIterator it(prof.cct()->root(),
			     &CCT::ANodeTyFilter[CCT::ANode::TyProcFrm]);
       it.Current(); ++it) {
    CCT::ProcFrm* x = static_cast<CCT::ProcFrm*>(it.current());
    if (x->procName() == CilkNameMgr::cilkmain) {
      mainFrm = x;
      break;
    }
  }

  // 2. merge any sibling 'CilkNameMgr::cilkmain'
  if (mainFrm) {
    CCT::ANodeChildIterator it(mainFrm->parent(),
			       &CCT::ANodeTyFilter[CCT::ANode::TyProcFrm]);
    for ( ; it.Current(); /* */) {
      CCT::ProcFrm* x = static_cast<CCT::ProcFrm*>(it.current());
      it++; // advance iterator -- it is pointing at 'x'
      
      if (x->procName() == CilkNameMgr::cilkmain) {
	mainFrm->merge(x); // deletes 'x'
      }
    }
  }
}
示例#3
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void
Analysis::CallPath::
noteStaticStructureOnLeaves(Prof::CallPath::Profile& prof)
{
  const Prof::Struct::Root* rootStrct = prof.structure()->root();

  Prof::CCT::ANodeIterator it(prof.cct()->root(), NULL/*filter*/,
			      true/*leavesOnly*/, IteratorStack::PreOrder);
  for (Prof::CCT::ANode* n = NULL; (n = it.current()); ++it) {
    Prof::CCT::ADynNode* n_dyn = dynamic_cast<Prof::CCT::ADynNode*>(n);
    if (n_dyn) {
      Prof::LoadMap::LMId_t lmId = n_dyn->lmId(); // ok if LoadMap::LMId_NULL
      Prof::LoadMap::LM* loadmap_lm = prof.loadmap()->lm(lmId);
      const string& lm_nm = loadmap_lm->name();

      const Prof::Struct::LM* lmStrct = rootStrct->findLM(lm_nm);
      DIAG_Assert(lmStrct, "failed to find Struct::LM: " << lm_nm);

      VMA lm_ip = n_dyn->lmIP();
      const Prof::Struct::ACodeNode* strct = lmStrct->findByVMA(lm_ip);
      DIAG_Assert(strct, "Analysis::CallPath::noteStaticStructureOnLeaves: failed to find structure for: " << n_dyn->toStringMe(Prof::CCT::Tree::OFlg_DebugAll));

      n->structure(strct);
    }
  }
}
示例#4
0
// overlayStaticStructure: Create frames for CCT::Call and CCT::Stmt
// nodes using a preorder walk over the CCT.
void
Analysis::CallPath::
overlayStaticStructure(Prof::CallPath::Profile& prof,
		       Prof::LoadMap::LM* loadmap_lm,
		       Prof::Struct::LM* lmStrct, BinUtil::LM* lm)
{
  overlayStaticStructure(prof.cct()->root(), loadmap_lm, lmStrct, lm);
}
示例#5
0
void
Analysis::CallPath::pruneBySummaryMetrics(Prof::CallPath::Profile& prof,
					  uint8_t* prunedNodes)
{
  VMAIntervalSet ivalset;
  
  const Prof::Metric::Mgr& mMgrGbl = *(prof.metricMgr());
  for (uint mId = 0; mId < mMgrGbl.size(); ++mId) {
    const Prof::Metric::ADesc* m = mMgrGbl.metric(mId);
    if (m->isVisible()
	&& m->type() == Prof::Metric::ADesc::TyIncl
	&& (m->nameBase().find("Sum") != string::npos)) {
      ivalset.insert(VMAInterval(mId, mId + 1)); // [ )
    }
  }
  
  prof.cct()->root()->pruneByMetrics(*prof.metricMgr(), ivalset,
				     prof.cct()->root(), 0.001,
				     prunedNodes);
}
示例#6
0
static void
noteStaticStructure(Prof::CallPath::Profile& prof)
{
  using namespace Prof;

  const Prof::CCT::ANode* cct_root = prof.cct()->root();

  for (CCT::ANodeIterator it(cct_root); it.Current(); ++it) {
    CCT::ANode* x = it.current();

    Prof::Struct::ACodeNode* strct = x->structure();
    if (strct) {
      strct->demandMetric(CallPath::Profile::StructMetricIdFlg) += 1.0;
    }
  }
}
// Assumes: metrics are of type Metric::SampledDesc and values are
// only at leaves (CCT::Stmt)
void
MetricComponentsFact::make(Prof::CallPath::Profile& prof)
{
  using namespace Prof;
  
  // ------------------------------------------------------------
  // Create destination metric descriptors and mapping from source
  //   metrics to destination metrics
  // ------------------------------------------------------------
  std::vector<uint> metricSrcIds;
  std::vector<uint> metricDstIds;
  
  Metric::Mgr* metricMgr = prof.metricMgr();

  uint numMetrics_orig = metricMgr->size();
  for (uint mId = 0; mId < numMetrics_orig; ++mId) {
    Metric::ADesc* m = metricMgr->metric(mId);
    if (MetricComponentsFact::isTimeMetric(m)) {
      DIAG_Assert(typeid(*m) == typeid(Metric::SampledDesc), DIAG_UnexpectedInput << "temporary sanity check");
      
      MetricComponentsFact::convertToWorkMetric(m);
      metricSrcIds.push_back(m->id());

      Metric::ADesc* m_new = m->clone();
      m_new->nameBase("overhead");
      m_new->description("parallel overhead");

      metricMgr->insert(m_new);
      DIAG_Assert(m_new->id() >= numMetrics_orig, "Currently, we assume new metrics are added at the end of the metric vector.");
      
      metricDstIds.push_back(m_new->id());
    }
  }

  if (metricSrcIds.empty()) {
    return;
  }

  // ------------------------------------------------------------
  // Create values for metric components
  // ------------------------------------------------------------
  make(prof.cct()->root(), metricSrcIds, metricDstIds, false);
}
示例#8
0
void
packMetrics(const Prof::CallPath::Profile& profile,
	    ParallelAnalysis::PackedMetrics& packedMetrics)
{
  Prof::CCT::Tree& cct = *profile.cct();

  // pack derived metrics [mDrvdBeg, mDrvdEnd) from 'profile' into
  // 'packedMetrics'
  uint mDrvdBeg = packedMetrics.mDrvdBegId();
  uint mDrvdEnd = packedMetrics.mDrvdEndId();

  DIAG_Assert(packedMetrics.numNodes() == cct.maxDenseId() + 1, "");
  DIAG_Assert(packedMetrics.numMetrics() == mDrvdEnd - mDrvdBeg, "");

  for (Prof::CCT::ANodeIterator it(cct.root()); it.Current(); ++it) {
    Prof::CCT::ANode* n = it.current();
    for (uint mId1 = 0, mId2 = mDrvdBeg; mId2 < mDrvdEnd; ++mId1, ++mId2) {
      packedMetrics.idx(n->id(), mId1) = n->metric(mId2);
    }
  }
}
示例#9
0
// makeReturnCountMetric: A return count refers to the number of times
// a given CCT node is called by its parent context.  However, when
// hpcrun records return counts, there is no structure (e.g. procedure
// frames) in the CCT.  An an example, in the CCT fragment below, the
// return count [3] at 0xc means that 0xc returned to 0xbeef 3 times.
// Simlarly, 0xbeef returned to its caller 5 times.
//
//              |               |
//       ip: 0xbeef [5]         |
//       /      |      \        |
//   0xa [1]  0xb [2]  0xc [3]  |
//      |       |       |       |
//
// To be able to say procedure F is called by procedure G x times
// within this context, it is necessary to aggregate these counts at
// the newly added procedure frames (Struct::ProcFrm).
static void
makeReturnCountMetric(Prof::CallPath::Profile& prof)
{
  std::vector<uint> retCntId;

  // -------------------------------------------------------
  // find return count metrics, if any
  // -------------------------------------------------------
  Prof::Metric::Mgr* metricMgr = prof.metricMgr();
  for (uint i = 0; i < metricMgr->size(); ++i) {
    Prof::Metric::ADesc* m = metricMgr->metric(i);
    if (m->nameBase().find(HPCRUN_METRIC_RetCnt) != string::npos) {
      retCntId.push_back(m->id());
      m->computedType(Prof::Metric::ADesc::ComputedTy_Final);
      m->type(Prof::Metric::ADesc::TyExcl);
    }
  }

  if (retCntId.empty()) {
    return;
  }

  // -------------------------------------------------------
  // propagate and aggregate return counts
  // -------------------------------------------------------
  Prof::CCT::ANode* cct_root = prof.cct()->root();
  Prof::CCT::ANodeIterator it(cct_root, NULL/*filter*/, false/*leavesOnly*/,
			      IteratorStack::PostOrder);
  for (Prof::CCT::ANode* n = NULL; (n = it.current()); ++it) {
    if (typeid(*n) != typeid(Prof::CCT::ProcFrm) && n != cct_root) {
      Prof::CCT::ANode* n_parent = n->parent();
      for (uint i = 0; i < retCntId.size(); ++i) {
	uint mId = retCntId[i];
	n_parent->demandMetric(mId) += n->demandMetric(mId);
	n->metric(mId) = 0.0;
      }
    }
  }
}
示例#10
0
static void
pruneTrivialNodes(Prof::CallPath::Profile& prof)
{
  pruneTrivialNodes(prof.cct()->root());
}
示例#11
0
static void
coalesceStmts(Prof::CallPath::Profile& prof)
{
  coalesceStmts(prof.cct()->root());
}
// make: ...temporary holding pattern...
void
MPIBlameShiftIdlenessFact::make(Prof::CallPath::Profile& prof)
{
  using namespace Prof;

  // ------------------------------------------------------------
  // Create destination metric descriptors and mapping from source
  //   metrics to destination metrics
  // ------------------------------------------------------------
  std::vector<uint> metricSrcIds;
  std::vector<uint> metricBalanceIds;
  std::vector<uint> metricImbalInclIds, metricImbalExclIds;
  std::vector<uint> metricIdleInclIds;

  Metric::Mgr* metricMgr = prof.metricMgr();

  uint numMetrics_orig = metricMgr->size();
  for (uint mId = 0; mId < numMetrics_orig; ++mId) {
    Metric::ADesc* m = metricMgr->metric(mId);

    // find main source metric
    if (MetricComponentsFact::isTimeMetric(m)
	&& MetricComponentsFact::isDerivedMetric(m, s_sum)
	&& m->type() == Metric::ADesc::TyIncl
	&& m->isVisible() /* not a temporary */) {

      DIAG_Assert(m->computedType() == Prof::Metric::ADesc::ComputedTy_NonFinal,
		  DIAG_UnexpectedInput);
      metricSrcIds.push_back(m->id());

      // FIXME: For now we use only Metric::ADesc::DerivedIncrDesc()
      //   We should also support Metric::ADesc::DerivedDesc()
      DIAG_Assert(typeid(*m) == typeid(Metric::DerivedIncrDesc), DIAG_UnexpectedInput);

      Metric::DerivedIncrDesc* m_imbalIncl =
	static_cast<Metric::DerivedIncrDesc*>(m->clone());
      m_imbalIncl->nameBase("imbalance" + s_sum);
      m_imbalIncl->description("imbalance for MPI SPMD executions");
      m_imbalIncl->expr(new Metric::SumIncr(Metric::IData::npos, // FIXME:Sum
					    Metric::IData::npos));

      Metric::DerivedIncrDesc* m_imbalExcl =
	static_cast<Metric::DerivedIncrDesc*>(m_imbalIncl->clone());
      m_imbalExcl->type(Metric::ADesc::TyExcl);
      m_imbalExcl->expr(new Metric::SumIncr(Metric::IData::npos,
					    Metric::IData::npos));
      m_imbalIncl->partner(m_imbalExcl);
      m_imbalExcl->partner(m_imbalIncl);

      Metric::DerivedIncrDesc* m_idleIncl =
	static_cast<Metric::DerivedIncrDesc*>(m->clone());
      m_idleIncl->nameBase("idleness" + s_sum);
      m_idleIncl->description("idleness for MPI executions");
      m_idleIncl->partner(NULL);
      m_idleIncl->expr(new Metric::SumIncr(Metric::IData::npos, // FIXME:Sum
					   Metric::IData::npos));

      metricMgr->insert(m_imbalIncl);
      metricMgr->insert(m_imbalExcl);
      metricMgr->insert(m_idleIncl);

      m_imbalIncl->expr()->accumId(m_imbalIncl->id());
      m_imbalExcl->expr()->accumId(m_imbalExcl->id());
      m_idleIncl->expr()->accumId(m_idleIncl->id());

      DIAG_Assert(m_imbalIncl->id() >= numMetrics_orig && m_imbalExcl->id() >= numMetrics_orig, "Currently, we assume new metrics are added at the end of the metric vector.");
      
      metricImbalInclIds.push_back(m_imbalIncl->id());
      metricImbalExclIds.push_back(m_imbalExcl->id());
      metricIdleInclIds.push_back(m_idleIncl->id());
    }

    // find secondary source metric
    if (MetricComponentsFact::isTimeMetric(m)
	&& MetricComponentsFact::isDerivedMetric(m, s_cfvar)
	&& m->type() == Metric::ADesc::TyIncl
	&& m->isVisible() /* not a temporary */) {
      DIAG_Assert(m->computedType() == Prof::Metric::ADesc::ComputedTy_NonFinal,
		  DIAG_UnexpectedInput);
      metricBalanceIds.push_back(m->id());
    }
  }

  DIAG_Assert(metricSrcIds.size() == metricBalanceIds.size(), DIAG_UnexpectedInput);

  if (metricSrcIds.empty()) {
    return;
  }
  
  // ------------------------------------------------------------
  // Create values for metric components
  // ------------------------------------------------------------

  // Note that metrics are non-finalized!
  CCT::ANode* cctRoot = prof.cct()->root();

  uint metricBalancedId = metricBalanceIds[0];
  Metric::AExprIncr* metricBalancedExpr = dynamic_cast<Metric::DerivedIncrDesc*>(metricMgr->metric(metricBalancedId))->expr();

  Metric::IData cctRoot_mdata(*cctRoot);
  metricBalancedExpr->finalize(cctRoot_mdata);
  
  double balancedThreshold = 1.2 * cctRoot_mdata.demandMetric(metricBalancedId);

  makeMetrics(cctRoot, metricSrcIds,
	      metricImbalInclIds, metricImbalExclIds, metricIdleInclIds,
	      metricBalancedId, metricBalancedExpr, balancedThreshold,
	      NULL, NULL);


  VMAIntervalSet metricDstInclIdSet;
  for (uint i = 0; i < metricImbalInclIds.size(); ++i) {
    uint mId = metricImbalInclIds[i];
    metricDstInclIdSet.insert(VMAInterval(mId, mId + 1)); // [ )

    mId = metricIdleInclIds[i];
    metricDstInclIdSet.insert(VMAInterval(mId, mId + 1)); // [ )
  }

  cctRoot->aggregateMetricsIncl(metricDstInclIdSet);
}