/// Apply implicit constraints for bitwise OR- and AND-.
/// For unsigned types, bitwise OR with a constant always returns
/// a value greater-or-equal than the constant, and bitwise AND
/// returns a value less-or-equal then the constant.
///
/// Pattern matches the expression \p Sym against those rule,
/// and applies the required constraints.
/// \p Input Previously established expression range set
static RangeSet applyBitwiseConstraints(
    BasicValueFactory &BV,
    RangeSet::Factory &F,
    RangeSet Input,
    const SymIntExpr* SIE) {
  QualType T = SIE->getType();
  bool IsUnsigned = T->isUnsignedIntegerType();
  const llvm::APSInt &RHS = SIE->getRHS();
  const llvm::APSInt &Zero = BV.getAPSIntType(T).getZeroValue();
  BinaryOperator::Opcode Operator = SIE->getOpcode();

  // For unsigned types, the output of bitwise-or is bigger-or-equal than RHS.
  if (Operator == BO_Or && IsUnsigned)
    return Input.Intersect(BV, F, RHS, BV.getMaxValue(T));

  // Bitwise-or with a non-zero constant is always non-zero.
  if (Operator == BO_Or && RHS != Zero)
    return assumeNonZero(BV, F, SIE, Input);

  // For unsigned types, or positive RHS,
  // bitwise-and output is always smaller-or-equal than RHS (assuming two's
  // complement representation of signed types).
  if (Operator == BO_And && (IsUnsigned || RHS >= Zero))
    return Input.Intersect(BV, F, BV.getMinValue(T), RHS);

  return Input;
}
void AnalysisDriver::printLeastProgressedTasks(const RangeSetTable &rsTable,
		const set<size_t> taskStates, const ReducedStateVector &redVector)
{
	if (mpiState.isRoot())
	{
		cout << "Number of states with LP-tasks: " << taskStates.size() << endl;

		set<size_t>::const_iterator it;
		for (it = taskStates.begin(); it != taskStates.end(); ++it) {
			State s = redVector.vec[*it];
			RangeSet rs = rsTable.getRangeOfTasks(*it);
			cout << "STATE " << *it << ", tasks: " << rs.toString() << endl;
		}

		// Print state names
		string name;
		cout << "States: " << endl;
		cout << "-------" << endl;
		for (size_t i=0; i < redVector.vec.size(); ++i) {
			State s = redVector.vec[i];
			factory->findAndGetName(name, s);
			cout << i << ": " << name << endl;
		}

		// Print location of tasks
		cout << "Task locations: " << endl;
		cout << "---------------" << endl;
		for (size_t i=0; i < redVector.vec.size(); ++i) {
			State s = redVector.vec[i];
			RangeSet r = rsTable.getRangeOfTasks(i);
			cout << i << ": " << r.toString() << endl;
		}
	}
}
ProgramStateRef
RangeConstraintManager::assumeSymLE(ProgramStateRef St, SymbolRef Sym,
                                    const llvm::APSInt &Int,
                                    const llvm::APSInt &Adjustment) {
  RangeSet New = getSymLERange(St, Sym, Int, Adjustment);
  return New.isEmpty() ? nullptr : St->set<ConstraintRange>(Sym, New);
}
ProgramStateRef 
RangeConstraintManager::assumeSymLE(ProgramStateRef St, SymbolRef Sym,
                                    const llvm::APSInt &Int,
                                    const llvm::APSInt &Adjustment) {
  // Before we do any real work, see if the value can even show up.
  APSIntType AdjustmentType(Adjustment);
  switch (AdjustmentType.testInRange(Int, true)) {
  case APSIntType::RTR_Below:
    return nullptr;
  case APSIntType::RTR_Within:
    break;
  case APSIntType::RTR_Above:
    return St;
  }

  // Special case for Int == Max. This is always feasible.
  llvm::APSInt ComparisonVal = AdjustmentType.convert(Int);
  llvm::APSInt Max = AdjustmentType.getMaxValue();
  if (ComparisonVal == Max)
    return St;

  llvm::APSInt Min = AdjustmentType.getMinValue();
  llvm::APSInt Lower = Min-Adjustment;
  llvm::APSInt Upper = ComparisonVal-Adjustment;

  RangeSet New = GetRange(St, Sym).Intersect(getBasicVals(), F, Lower, Upper);
  return New.isEmpty() ? nullptr : St->set<ConstraintRange>(Sym, New);
}
Exemple #5
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/**
 * Create the masks for sources and targets based on the contiguous
 * ranges given in sources and targets. We need to do some index
 * translation here, as the CG expects indices from 0..n for both
 * source and target populations, while the RangeSets sources and
 * targets contain NEST global indices (gids).
 *
 * The masks for the sources must contain all nodes (local+remote).
 * The skip of the mask was set to 1 in cg_set_masks(). The same
 * source mask is stored n_proc times on each process.
 *
 * The masks for the targets must only contain local nodes. This is
 * achieved by first setting skip to num_processes upon creation of
 * the mask in cg_set_masks(), and second by the fact that for each
 * contiguous range of nodes in a mask, each of them contains the
 * index-translated id of the first local neuron as the first
 * entry. If this renders the range empty (i.e. because the first
 * local id is beyond the last element of the range), the range is
 * not added to the mask.
 *
 * \param masks The std::vector of Masks to populate
 * \param sources The source ranges to create the source masks from
 * \param targets The target ranges to create the target masks from
 *
 * \note Each process computes the full set of source and target
 * masks, i.e. one mask per rank will be created on each rank.
 *
 * \note Setting the masks for all processes on each process might
 * become a memory bottleneck when going to very large numbers of
 * processes. Especially so for the source masks, which are all the
 * same. This could be solved by making the ConnectionGenerator
 * interface MPI aware and communicating the masks during connection
 * setup.
*/
void
cg_create_masks( std::vector< ConnectionGenerator::Mask >* masks,
  RangeSet& sources,
  RangeSet& targets )
{
  // The index of the left border of the currently looked at range
  // (counting from 0). This is used for index translation.
  size_t cg_idx_left = 0;

  // For sources, we only need to translate from NEST to CG indices.
  for ( RangeSet::iterator source = sources.begin(); source != sources.end(); ++source )
  {
    size_t num_elements = source->last - source->first;
    size_t right = cg_idx_left + num_elements;
    for ( size_t proc = 0; proc < static_cast< size_t >( Communicator::get_num_processes() );
          ++proc )
      ( *masks )[ proc ].sources.insert( cg_idx_left, right );
    cg_idx_left += num_elements + 1;
  }

  // Reset the index of the left border of the range for index
  // translation for the targets.
  cg_idx_left = 0;

  for ( RangeSet::iterator target = targets.begin(); target != targets.end(); ++target )
  {
    size_t num_elements = target->last - target->first;
    for ( size_t proc = 0; proc < static_cast< size_t >( Communicator::get_num_processes() );
          ++proc )
    {
      // Make sure that the range is only added on as many ranks as
      // there are elements in the range, or exactly on every rank,
      // if there are more elements in the range.
      if ( proc <= num_elements )
      {
        // For the different ranks, left will take on the CG indices
        // of all first local nodes that are contained in the range.
        // The rank, where this mask is to be used is determined
        // below when inserting the mask.
        size_t left = cg_idx_left + proc;

        // right is set to the CG index of the right border of the
        // range. This is the same for all ranks.
        size_t right = cg_idx_left + num_elements;

        // We index the masks according to the modulo distribution
        // of neurons in NEST. This ensures that the mask is set for
        // the rank where left acutally is the first neuron fromt
        // the currently looked at range.
        ( *masks )[ ( proc + target->first ) % Communicator::get_num_processes() ].targets.insert(
          left, right );
      }
    }

    // Update the CG index of the left border of the next range to
    // be one after the current range.
    cg_idx_left += num_elements + 1;
  }
}
ProgramStateRef RangeConstraintManager::assumeSymOutsideInclusiveRange(
    ProgramStateRef State, SymbolRef Sym, const llvm::APSInt &From,
    const llvm::APSInt &To, const llvm::APSInt &Adjustment) {
  RangeSet RangeLT = getSymLTRange(State, Sym, From, Adjustment);
  RangeSet RangeGT = getSymGTRange(State, Sym, To, Adjustment);
  RangeSet New(RangeLT.addRange(F, RangeGT));
  return New.isEmpty() ? nullptr : State->set<ConstraintRange>(Sym, New);
}
ProgramStateRef RangeConstraintManager::assumeSymWithinInclusiveRange(
    ProgramStateRef State, SymbolRef Sym, const llvm::APSInt &From,
    const llvm::APSInt &To, const llvm::APSInt &Adjustment) {
  RangeSet New = getSymGERange(State, Sym, From, Adjustment);
  if (New.isEmpty())
    return nullptr;
  RangeSet Out = getSymLERange([&] { return New; }, To, Adjustment);
  return Out.isEmpty() ? nullptr : State->set<ConstraintRange>(Sym, Out);
}
const ProgramState*
RangeConstraintManager::assumeSymEQ(const ProgramState *state, SymbolRef sym,
                                    const llvm::APSInt& Int,
                                    const llvm::APSInt& Adjustment) {
  // [Int-Adjustment, Int-Adjustment]
  BasicValueFactory &BV = state->getBasicVals();
  llvm::APSInt AdjInt = Int-Adjustment;
  RangeSet New = GetRange(state, sym).Intersect(BV, F, AdjInt, AdjInt);
  return New.isEmpty() ? NULL : state->set<ConstraintRange>(sym, New);
}
ProgramStateRef
RangeConstraintManager::assumeSymEQ(ProgramStateRef St, SymbolRef Sym,
                                    const llvm::APSInt &Int,
                                    const llvm::APSInt &Adjustment) {
  // Before we do any real work, see if the value can even show up.
  APSIntType AdjustmentType(Adjustment);
  if (AdjustmentType.testInRange(Int, true) != APSIntType::RTR_Within)
    return nullptr;

  // [Int-Adjustment, Int-Adjustment]
  llvm::APSInt AdjInt = AdjustmentType.convert(Int) - Adjustment;
  RangeSet New = getRange(St, Sym).Intersect(getBasicVals(), F, AdjInt, AdjInt);
  return New.isEmpty() ? nullptr : St->set<ConstraintRange>(Sym, New);
}
Exemple #10
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    RangeSet createPredefinedSet ()
    {
        RangeSet set;

        // Set will include:
        // [ 0, 5]
        // [10,15]
        // [20,25]
        // etc...

        for (int i = 0; i < 10; ++i)
            set.setRange (10 * i, 10 * i + 5);

        return set;
    }
const ProgramState*
RangeConstraintManager::assumeSymNE(const ProgramState *state, SymbolRef sym,
                                    const llvm::APSInt& Int,
                                    const llvm::APSInt& Adjustment) {
  BasicValueFactory &BV = state->getBasicVals();

  llvm::APSInt Lower = Int-Adjustment;
  llvm::APSInt Upper = Lower;
  --Lower;
  ++Upper;

  // [Int-Adjustment+1, Int-Adjustment-1]
  // Notice that the lower bound is greater than the upper bound.
  RangeSet New = GetRange(state, sym).Intersect(BV, F, Upper, Lower);
  return New.isEmpty() ? NULL : state->set<ConstraintRange>(sym, New);
}
Exemple #12
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    void testPrevMissing ()
    {
        testcase ("prevMissing");

        RangeSet const set = createPredefinedSet ();

        for (int i = 0; i < 100; ++i)
        {
            int const oneBelowRange = (10*(i/10))-1;

            int const expectedPrevMissing =
                ((i % 10) > 6) ? (i-1) : oneBelowRange;

            expect (set.prevMissing (i) == expectedPrevMissing);
        }
    }
Exemple #13
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	NodePtr parsePrimitive()
	{
		NodePtr p = nullptr;
		RangeSet st;
		// lookahead
		switch (reader.peek())
		{
		case '\\':
			reader.next();
			switch (reader.peek())
			{
			case 'd':
				st.insert({ '0', '9' });
				reader.next();
				return std::make_shared<CharsetNode>(st);
				break;
			case '{': case '}': case '|':
			case '(': case ')': case '.':
			case '+': case '*': case '?':
			case '\\': case 'n': case 't':
				return std::make_shared<CharNode>(reader.next());
				break;
			default:
				throw ParseError();
			}
			reader.next();
			break;
		case '(':
			reader.next();
			p = parseRE();
			if (reader.peek() != ')')
			{
				throw ParseError();
			}
			reader.next();
			return p;
		case '\0': case '*': case '|':
			throw ParseError();
			break;
		case '.':
			reader.next();
			return std::make_shared<WildcardNode>();
			break;
		default:
			return std::make_shared<CharNode>(reader.next());
		}
	}
/// Return a range set subtracting zero from \p Domain.
static RangeSet assumeNonZero(
    BasicValueFactory &BV,
    RangeSet::Factory &F,
    SymbolRef Sym,
    RangeSet Domain) {
  APSIntType IntType = BV.getAPSIntType(Sym->getType());
  return Domain.Intersect(BV, F, ++IntType.getZeroValue(),
      --IntType.getZeroValue());
}
ProgramStateRef
RangeConstraintManager::assumeSymNE(ProgramStateRef St, SymbolRef Sym,
                                    const llvm::APSInt &Int,
                                    const llvm::APSInt &Adjustment) {
  // Before we do any real work, see if the value can even show up.
  APSIntType AdjustmentType(Adjustment);
  if (AdjustmentType.testInRange(Int, true) != APSIntType::RTR_Within)
    return St;

  llvm::APSInt Lower = AdjustmentType.convert(Int) - Adjustment;
  llvm::APSInt Upper = Lower;
  --Lower;
  ++Upper;

  // [Int-Adjustment+1, Int-Adjustment-1]
  // Notice that the lower bound is greater than the upper bound.
  RangeSet New = getRange(St, Sym).Intersect(getBasicVals(), F, Upper, Lower);
  return New.isEmpty() ? nullptr : St->set<ConstraintRange>(Sym, New);
}
const ProgramState*
RangeConstraintManager::assumeSymGT(const ProgramState *state, SymbolRef sym,
                                    const llvm::APSInt& Int,
                                    const llvm::APSInt& Adjustment) {
  BasicValueFactory &BV = state->getBasicVals();

  QualType T = state->getSymbolManager().getType(sym);
  const llvm::APSInt &Max = BV.getMaxValue(T);

  // Special case for Int == Max. This is always false.
  if (Int == Max)
    return NULL;

  llvm::APSInt Lower = Int-Adjustment;
  llvm::APSInt Upper = Max-Adjustment;
  ++Lower;

  RangeSet New = GetRange(state, sym).Intersect(BV, F, Lower, Upper);
  return New.isEmpty() ? NULL : state->set<ConstraintRange>(sym, New);
}
Exemple #17
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    bool VisitDecl(clang::Decl *decl)
    {
        if (markedAsSuppress(decl, _rule))
        {
            clang::SourceLocation startLocation = decl->getLocStart();
            clang::SourceLocation endLocation = decl->getLocEnd();
            unsigned startLineNumber = _sourceManager->getPresumedLineNumber(startLocation);
            unsigned endLineNumber = _sourceManager->getPresumedLineNumber(endLocation);
            _range.insert(std::make_pair(startLineNumber, endLineNumber));
        }

        return true;
    }
Exemple #18
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 void cg_get_ranges(RangeSet& ranges, std::vector<long>& gids)
 {
   index right = 0, left = 0;
   while(true)
   {
     right = cg_get_right_border(left, (gids.size() - left) / 2, gids);
     ranges.push_back(Range(gids[left], gids[right]));
     if (right == gids.size() - 1)
       break;
     else
       left = right + 1;
   }
 }
Exemple #19
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/**
 * Splits the selected segments by inserting new nodes in the middle. The
 * selected segments are defined by each pair of consecutive \a indexRanges.
 *
 * This method can deal with both polygons as well as polylines. For polygons,
 * pass <code>true</code> for \a closed.
 */
static QPolygonF splitPolygonSegments(const QPolygonF &polygon,
                                      const RangeSet<int> &indexRanges,
                                      bool closed)
{
    if (indexRanges.isEmpty())
        return polygon;

    const int n = polygon.size();

    QPolygonF result = polygon;

    RangeSet<int>::Range firstRange = indexRanges.begin();
    RangeSet<int>::Range it = indexRanges.end();
    // assert: firstRange != it

    if (closed) {
        RangeSet<int>::Range lastRange = it;
        --lastRange; // We know there is at least one range

        // Handle the case where the first and last nodes are selected
        if (firstRange.first() == 0 && lastRange.last() == n - 1) {
            const QPointF splitPoint = (result.first() + result.last()) / 2;
            result.append(splitPoint);
        }
    }

    do {
        --it;

        for (int i = it.last(); i > it.first(); --i) {
            const QPointF splitPoint = (result.at(i) + result.at(i - 1)) / 2;
            result.insert(i, splitPoint);
        }
    } while (it != firstRange);

    return result;
}
Exemple #20
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  void cg_create_masks(std::vector<ConnectionGenerator::Mask>* masks, RangeSet& sources, RangeSet& targets)
  {
    // We need to do some index translation here as the CG expects
    // indices from 0..n for both source and target populations.

    size_t length = 0;
    for (RangeSet::iterator source = sources.begin(); source != sources.end(); ++source)
    {
      for (size_t proc = 0; proc < static_cast<size_t>(Communicator::get_num_processes()); ++proc)
      {
        size_t last = source->last - source->first;
        if (proc <= last)
        {
          size_t left = proc + length;
          size_t right = last + length;
          (*masks)[(proc + source->first) % Communicator::get_num_processes()].sources.insert(left, right);
        }
      }
      length += source->last - source->first + 1;
    }

    length = 0;
    for (RangeSet::iterator target = targets.begin(); target != targets.end(); ++target)
    {
      for (size_t proc = 0; proc < static_cast<size_t>(Communicator::get_num_processes()); ++proc)
      {
        size_t last = target->last - target->first;
        if (proc <= last)
        {
          size_t left = proc + length;
          size_t right = last + length;
          (*masks)[(proc + target->first) % Communicator::get_num_processes()].targets.insert(left, right);
        }
      }
      length += target->last - target->first + 1;
    }
  }
Exemple #21
0
/**
 * Determine all contiguous ranges found in a given vector of gids
 * and add the ranges to the given RangeSet.
 *
 * \param ranges A reference to the RangeSet to add to
 * \param gids The std::vector<long> of gids
 *
 * \note We do not store the indices into the given range, but
 * instead we store the actual gids. This allows us to use CG
 * generated indices as indices into the ranges spanned by the
 * RangeSet. Index translation is done in cg_create_masks().
 */
void
cg_get_ranges( RangeSet& ranges, std::vector< long >& gids )
{
  index right, left = 0;
  while ( true )
  {
    // Determine the right border of the contiguous range starting
    // at left. The initial step is set to half the length of the
    // interval between left and the end of gids.
    right = cg_get_right_border( left, ( gids.size() - left ) / 2, gids );
    ranges.push_back( Range( gids[ left ], gids[ right ] ) );
    if ( right == gids.size() - 1 ) // We're at the end of gids and stop
      break;
    else
      left = right + 1; // The new left border is one after the old right
  }
}
Exemple #22
0
    RangeSet collect(clang::ASTContext &astContext, oclint::RuleBase *rule)
    {
        _rule = rule;
        _sourceManager = &astContext.getSourceManager();
        _range.clear();

        clang::DeclContext *decl = astContext.getTranslationUnitDecl();
        for (clang::DeclContext::decl_iterator declIt = decl->decls_begin(),
            declEnd = decl->decls_end(); declIt != declEnd; ++declIt)
        {
            clang::SourceLocation startLocation = (*declIt)->getLocStart();
            if (startLocation.isValid() &&
                _sourceManager->getMainFileID() == _sourceManager->getFileID(startLocation))
            {
                (void) /* explicitly ignore the return of this function */
                    clang::RecursiveASTVisitor<DeclAnnotationRangeCollector>::TraverseDecl(*declIt);
            }
        }

        return _range;
    }
Exemple #23
0
void GraphBuilder::update_node_constraints(IRList::iterator it,
                                           const RangeSet& range_set,
                                           Graph* graph) {
  auto insn = it->insn;
  auto op = insn->opcode();
  if (insn->dests_size()) {
    auto dest = insn->dest();
    auto& node = graph->m_nodes[dest];
    if (opcode::is_load_param(op)) {
      node.m_props.set(Node::PARAM);
    }
    node.m_type_domain.meet_with(RegisterTypeDomain(dest_reg_type(insn)));
    auto max_vreg = max_unsigned_value(dest_bit_width(it));
    node.m_max_vreg = std::min(node.m_max_vreg, max_vreg);
    node.m_width = insn->dest_is_wide() ? 2 : 1;
    if (max_vreg < max_unsigned_value(16)) {
      ++node.m_spill_cost;
    }
  }

  for (size_t i = 0; i < insn->srcs_size(); ++i) {
    auto src = insn->src(i);
    auto& node = graph->m_nodes[src];
    auto type = src_reg_type(insn, i);
    node.m_type_domain.meet_with(RegisterTypeDomain(type));
    reg_t max_vreg;
    if (range_set.contains(insn)) {
      max_vreg = max_unsigned_value(16);
      node.m_props.set(Node::RANGE);
    } else {
      max_vreg = max_value_for_src(insn, i, type == RegisterType::WIDE);
    }
    node.m_max_vreg = std::min(node.m_max_vreg, max_vreg);
    if (max_vreg < max_unsigned_value(16)) {
      ++node.m_spill_cost;
    }
  }
}
Exemple #24
0
 void append(int n) { m_list.append(n,n+1); }
Exemple #25
0
 SelRangesNode(int n) { m_list.append(n,n+1); }
Exemple #26
0
 void append(int nstart, int nend) {
   if (nstart<=nend)
     m_list.append(nstart, nend+1);
   else
     m_list.append(nend, nstart+1);
 }
Exemple #27
0
/**
 * Joins the nodes at the given \a indexRanges. Each consecutive sequence
 * of nodes will be joined into a single node at the average location.
 *
 * This method can deal with both polygons as well as polylines. For polygons,
 * pass <code>true</code> for \a closed.
 */
static QPolygonF joinPolygonNodes(const QPolygonF &polygon,
                                  const RangeSet<int> &indexRanges,
                                  bool closed)
{
    if (indexRanges.isEmpty())
        return polygon;

    // Do nothing when dealing with a polygon with less than 3 points
    // (we'd no longer have a polygon)
    const int n = polygon.size();
    if (n < 3)
        return polygon;

    RangeSet<int>::Range firstRange = indexRanges.begin();
    RangeSet<int>::Range it = indexRanges.end();

    RangeSet<int>::Range lastRange = it;
    --lastRange; // We know there is at least one range

    QPolygonF result = polygon;

    // Indexes need to be offset when first and last range are joined.
    int indexOffset = 0;

    // Check whether the first and last ranges connect
    if (firstRange.first() == 0 && lastRange.last() == n - 1) {
        // Do nothing when the selection spans the whole polygon
        if (firstRange == lastRange)
            return polygon;

        // Join points of the first and last range when the polygon is closed
        if (closed) {
            QPointF averagePoint;
            for (int i = firstRange.first(); i <= firstRange.last(); i++)
                averagePoint += polygon.at(i);
            for (int i = lastRange.first(); i <= lastRange.last(); i++)
                averagePoint += polygon.at(i);
            averagePoint /= firstRange.length() + lastRange.length();

            result.remove(lastRange.first(), lastRange.length());
            result.remove(1, firstRange.length() - 1);
            result.replace(0, averagePoint);

            indexOffset = firstRange.length() - 1;

            // We have dealt with these ranges now
            // assert: firstRange != lastRange
            ++firstRange;
            --it;
        }
    }

    while (it != firstRange) {
        --it;

        // Merge the consecutive nodes into a single average point
        QPointF averagePoint;
        for (int i = it.first(); i <= it.last(); i++)
            averagePoint += polygon.at(i - indexOffset);
        averagePoint /= it.length();

        result.remove(it.first() + 1 - indexOffset, it.length() - 1);
        result.replace(it.first() - indexOffset, averagePoint);
    }

    return result;
}
void AnalysisDriver::dumpOutputForGUI(const DependencyMatrix &matrix,
		const ReducedStateVector &redVector,
		const RangeSetTable &rsTable)
{

	bool doNotDump = false;
        bool r = false;
        r = AUTConfig::getBoolParameter("AUT_DO_NOT_DUMP", doNotDump);
        if(doNotDump)
        {
             // to resolve problem in BGQ - in BGQ we can not execute shell command to resolve functionname and address
             return;

        }
	bool usedcallpath = AUTConfig::getBoolParameter("AUT_USE_CALL_PATH", usedcallpath);
	if(usedcallpath)
	{
		cout<< "Stack created using callpath, support for filename and line number will be provided later" << endl;
		return;
	}
#if STATE_TRACKER_DEBUG
	cout << "Writing dump file..." << endl;
#endif

	string fileData("");

	fileData += "#START_DEPENDENCY_GRAPH\n";
	fileData += matrix.toCSVFormat();
	fileData += "#END_DEPENDENCY_GRAPH\n";

	fileData += "#START_STATES\n";
	string name;
	for (size_t i=0; i < redVector.vec.size(); ++i) {
		State s = redVector.vec[i];
		factory->findAndGetName(name, s);

		// eliminate first '|'
		name.erase(0,1);

		// get state id
		char stateId[5];
		itoa((int)i, stateId);

		fileData += string(stateId) + string(":") + name + string("\n");
	}
	fileData += "#END_STATES\n";

	fileData += "#START_TASK_LOC\n";
	for (size_t i=0; i < redVector.vec.size(); ++i) {
		State s = redVector.vec[i];
		RangeSet r = rsTable.getRangeOfTasks(i);
                //cout << "Original state was: " << s.getId() << "\n";
		// get state id
		char stateId[5];
		itoa((int)i, stateId);

		// get range set
		string rSet(r.toString());
		rSet.erase(0,1);
		rSet.erase(rSet.length()-1, 1);
		
		// get number of tasks
		unsigned int n = r.getNumberOfTasks();
		char tasks[128];
		sprintf(tasks, "%d", n);

		fileData += string(stateId) + string(":") + rSet + string(":") + string(tasks) + string("\n");
	}
	fileData += "#END_TASK_LOC\n";
	fileData += "#START_SOURCE_CODE_LINES\n";
	name = "";
	for (size_t i=0; i < redVector.vec.size(); ++i) {
		State s = redVector.vec[i];
		factory->findAndGetName(name, s);
		// eliminate first '|'
		name.erase(0,1);
		vector<string> tokens;
		Tokenize(name, tokens, "|");
		string setOfLines("");
		for (size_t j=0; j < tokens.size(); ++j) {
			//cout << tokens[j] << endl;
			FileAndFunction f = Backtrace::findFileAndFunctionFromObject(tokens[j]);
			if(f.fileNameAndLine.empty())
			{
				continue;
			}
			string line = f.fileNameAndLine.substr(0, f.fileNameAndLine.size()-1);
			setOfLines += line + "|" + f.functionName;
			if (f.fromTool)
				setOfLines += "|*\n";
			else
				setOfLines += "\n";
		}

		// get state id
		char stateId[5];
		itoa((int)i, stateId);

		fileData += string(stateId) + string(",") + setOfLines;
	}
	fileData += "#END_SOURCE_CODE_LINES\n";

	fileData += "#START_STATE_TYPES\n";
        name = "";
        for (size_t i=0; i < redVector.vec.size(); ++i) {
                State s = redVector.vec[i];
                factory->findAndGetName(name, s);

                name.erase(0,1);
                vector<string> tokens;
                Tokenize(name, tokens, "|");
                bool compState = false;

                for (size_t j=0; j < tokens.size(); ++j) {
                        FileAndFunction f = Backtrace::findFileAndFunctionFromObject(tokens[j]);
			if(f.functionName.empty())
			{
			      continue;
			}

			if (f.functionName.find("transitionAfterMPICall") != string::npos) {
				compState = true;
				break;
			}
                }

                char stateId[5];
                itoa((int)i, stateId);

                fileData += string(stateId) + string(":");
		if (compState)
			fileData += "COMPUTATION_CODE\n";
		else
			fileData += "COMMUNICATION_CODE\n";

        }
        fileData += "#END_STATE_TYPES\n";

	string fileName = writeFile(fileData, "dump");
        cout << "Name of the output file: " << fileName << endl;

	//printf("Pointer of _r_debug.r_map: %p\n",_r_debug.r_map);
        //struct link_map *map = _r_debug.r_map;
        //while(map)
        //{
        //        printf("Name: '%s' l_addr: %lx l_ld: %lx\n", map->l_name, map->l_addr, map->l_ld);
        //        map = map->l_next;
        //}

}
Exemple #29
0
 SelRangesNode(int n1, int n2) { m_list.append(n1,n2+1); }