コード例 #1
0
void
RemoveConstantFoldedValue::handleTheSynthesizedAttribute( SgNode* node, const RemoveConstantFoldedValueSynthesizedAttribute & i )
   {
     SgExpression* value = isSgExpression(i.node);
     if (value != NULL)
        {
          SgExpression* originalExpressionTree = value->get_originalExpressionTree();
          if (originalExpressionTree != NULL)
             {
#if 0
               printf ("Found an originalExpressionTree = %p = %s \n",originalExpressionTree,originalExpressionTree->class_name().c_str());
#endif
               if (node == value->get_parent())
                  {
                 // What kind of IR node are we at presently? Replace the expression representing the SgValueExp with the Expression representing the original subtree.
#if 0
                    printf ("Current IR node with SgExpression child = %p = %s originalExpressionTree = %p = %s \n",node,node->class_name().c_str(),originalExpressionTree,originalExpressionTree->class_name().c_str());
#endif
                    bool traceReplacement = true;
                    ConstantFoldedValueReplacer r(traceReplacement, value);
                    node->processDataMemberReferenceToPointers(&r);
                  }
                 else
                  {
                    printf ("*** Strange case of child attribute not having the current node as a parent child = %p = %s originalExpressionTree = %p = %s \n",node,node->class_name().c_str(),originalExpressionTree,originalExpressionTree->class_name().c_str());
                  }
             }
        }
   }
コード例 #2
0
void
CompassAnalyses::NonAssociativeRelationalOperators::Traversal::
visit(SgNode* node)
   {
     SgBinaryOp *relOperator = isSgBinaryOp(node);

     if( relOperator != NULL && 
         isRelationalOperator(relOperator) )
     {
       SgExpression *lhs = relOperator->get_lhs_operand();
       SgExpression *rhs = relOperator->get_rhs_operand();

       if( lhs != NULL && rhs != NULL )
       {
         CompassAnalyses::NonAssociativeRelationalOperators::ExpressionTraversal expressionTraversal;

         if( expressionTraversal.run(lhs->get_parent()) > 1 ) 
         {
           output->addOutput( new CheckerOutput(relOperator) );
         } //if( expressionTraversal.run(lhs->get_parent()) > 1 ) 

       } //if( lhs != NULL && rhs != NULL )
     } //if( relOperator != NULL && isRelationalOperator(node) )

     return;
   } //End of the visit function.
コード例 #3
0
// Get the statement of an expression.  Somewhat smarter than the standard
// version of this routine, but needs to be merged.
SgStatement* getStatementOfExpression(SgNode* n)
   {
     assert(n);
  // std::cout << "Starting getStatementOfExpression on 0x" << std::hex << (int)n << ", which has type " << n->sage_class_name() << std::endl;

     SgExpression* expression = isSgExpression(n);
     ROSE_ASSERT(expression != NULL);
     SgExpression* rootExpression = getRootOfExpression(expression);
     ROSE_ASSERT(rootExpression->get_parent() != NULL);
     SgInitializedName* initializedName = isSgInitializedName(rootExpression->get_parent());

     SgNode* root = rootExpression;
     if (initializedName != NULL)
        root = initializedName;

     ROSE_ASSERT(root != NULL);
     SgStatement* statement = isSgStatement(root->get_parent());
     ROSE_ASSERT(statement != NULL);
     return statement;
   }
コード例 #4
0
void
RemoveConstantFoldedValueViaParent::visit ( SgNode* node )
   {
  // This is an alternative implementation that allows us to handle expression that are not 
  // traversed in the AST (e.g. types like SgArrayType which can contain expressions).

     ROSE_ASSERT(node != NULL);

  // DQ (3/11/2006): Set NULL pointers where we would like to have none.
#if 0
     printf ("In RemoveConstantFoldedValueViaParent::visit(): node = %p = %s \n",node,node->class_name().c_str());
#endif

  // DQ (10/12/2012): Turn this on so that we can detect failing IR nodes (failing later) that have valid originalExpressionTrees.
  // DQ (10/12/2012): Turn this back off because it appears to fail...
#if 0
     SgExpression* exp = isSgExpression(node);
     if (exp != NULL)
        {
          SgExpression* originalExpressionTree = exp->get_originalExpressionTree();
          if (originalExpressionTree != NULL)
             {
               SgNode* parent = exp->get_parent();
               if (parent != NULL)
                  {
                    printf ("Current IR node with SgExpression parent = %p = %s child = %p = %s originalExpressionTree = %p = %s \n",parent,parent->class_name().c_str(),node,node->class_name().c_str(),originalExpressionTree,originalExpressionTree->class_name().c_str());
                    bool traceReplacement = true;
                    ConstantFoldedValueReplacer r(traceReplacement, exp);
                    parent->processDataMemberReferenceToPointers(&r);
                 // node->processDataMemberReferenceToPointers(&r);
                  }

            // Set the originalExpressionTree to NULL.
               exp->set_originalExpressionTree(NULL);

            // Set the parent of originalExpressionTree to be the parent of exp.
               originalExpressionTree->set_parent(parent);

            // And then delete the folded constant.
               SageInterface::deleteAST(exp);
             }
        }
#endif

     SgArrayType* arrayType = isSgArrayType(node);
     if (arrayType != NULL)
        {
#if 0
          printf ("Found an array type arrayType = %p arrayType->get_index() = %p \n",arrayType,arrayType->get_index());
#endif
          SgExpression* index = arrayType->get_index();
          if (index != NULL)
             {
#if 0
               printf ("Fixup array index = %p = %s (traverse index AST subtree) \n",index,index->class_name().c_str());
#endif
               RemoveConstantFoldedValue astFixupTraversal;
               astFixupTraversal.traverse(index);
#if 0
               printf ("DONE: Fixup array index = %p (traverse index AST) \n\n\n\n",index);
#endif
#if 0
               printf ("Found an array index = %p (fixup index directly) \n",index);
#endif
            // Handle the case where the original expression tree is at the root of the subtree.
               SgExpression* originalExpressionTree = index->get_originalExpressionTree();
               if (originalExpressionTree != NULL)
                  {
#if 0
                    printf ("Found an originalExpressionTree in the array index originalExpressionTree = %p \n",originalExpressionTree);
#endif
                 // DQ (6/12/2013): This appears to be a problem in EDG 4.7 (see test2011_117.C).
                    std::vector<SgExpression*> redundantChainOfOriginalExpressionTrees;
                    if (originalExpressionTree->get_originalExpressionTree() != NULL)
                       {
#if 0
                         printf ("Detected originalExpressionTree nested directly within the originalExpressionTree \n",
                              originalExpressionTree,originalExpressionTree->class_name().c_str(),
                              originalExpressionTree->get_originalExpressionTree(),originalExpressionTree->get_originalExpressionTree()->class_name().c_str());
#endif
                      // Loop to the end of the chain of original expressions (which EDG 4.7 should never have constructed).
                         while (originalExpressionTree->get_originalExpressionTree() != NULL)
                            {
#if 0
                              printf ("Looping through a chain of originalExpressionTrees \n");
#endif
                           // Save the list of redundnat nodes so that we can delete them properly.
                              redundantChainOfOriginalExpressionTrees.push_back(originalExpressionTree);

                              originalExpressionTree = originalExpressionTree->get_originalExpressionTree();
                            }
#if 0
                         printf ("Exiting as a test! \n");
                         ROSE_ASSERT(false);
#endif
                       }

                    arrayType->set_index(originalExpressionTree);
                    originalExpressionTree->set_parent(arrayType);

                    index->set_originalExpressionTree(NULL);

                 // printf ("DEBUGING: skip delete of index in array type \n");
                    delete index;

                 // DQ (6/12/2013): Delete the nodes that we had to skip over (caused by chain of redundant entries from EDG 4.7).
                    std::vector<SgExpression*>::iterator i = redundantChainOfOriginalExpressionTrees.begin();
                    while (i != redundantChainOfOriginalExpressionTrees.end())
                       {
#if 0
                         printf ("deleting the redundnat originalExpressionTree chain caused by EDG 4.7 (delete %p = %s) \n",*i,(*i)->class_name().c_str());
#endif
                         delete *i;
                         i++;
                       }

                    index = NULL;
                  }
             }
        }

     SgVariableDefinition* variableDefinition = isSgVariableDefinition(node);
     if (variableDefinition != NULL)
        {
#if 0
          printf ("Found a SgVariableDefinition \n");
#endif
          SgExpression* bitfieldExp = variableDefinition->get_bitfield();
          if (bitfieldExp != NULL)
             {
#if 0
               printf ("Fixup bitfieldExp = %p (traverse bitfieldExp AST subtree) \n",bitfieldExp);
#endif
               RemoveConstantFoldedValue astFixupTraversal;
               astFixupTraversal.traverse(bitfieldExp);

            // Handle the case where the original expression tree is at the root of the subtree.
               SgExpression* originalExpressionTree = bitfieldExp->get_originalExpressionTree();
               if (originalExpressionTree != NULL)
                  {
#if 0
                 // DQ (9/18/2011): This code will not work since the bitfile data member in SgVariableDefinition is a SgUnsignedLongVal instead of a SgExpression.
                    variableDefinition->set_bitfield(originalExpressionTree);
                    originalExpressionTree->set_parent(variableDefinition);

                    bitfieldExp->set_originalExpressionTree(NULL);
                    delete bitfieldExp;
                    bitfieldExp = NULL;
#else
                 // The ROSE AST needs to be fixed to handle more general expressions for bitfield widths (this does not effect the CFG).
                 // TODO: Change the data type of the bitfield data member in SgVariableDefinition.

                 // DQ (1/20/2014): This has been done now.
                 // printf ("Member data bitfield widths need to be changed (in the ROSE IR) to support more general expressions (can't fix this original expression tree) \n");
#endif
#if 0
                 // This case is not handled yet!
                    printf ("Found an original expression tree in a bitfield expression \n");
                    ROSE_ASSERT(false);
#endif
                  }
             }
        }
   }
コード例 #5
0
// Do finite differencing on one expression within one context.  The expression
// must be defined and valid within the entire body of root.  The rewrite rules
// are used to simplify expressions.  When a variable var is updated from
// old_value to new_value, an expression of the form (var, (old_value,
// new_value)) is created and rewritten.  The rewrite rules may either produce
// an arbitrary expression (which will be used as-is) or one of the form (var,
// (something, value)) (which will be changed to (var = value)).
void doFiniteDifferencingOne(SgExpression* e, 
                             SgBasicBlock* root,
                             RewriteRule* rules)
   {
     SgStatementPtrList& root_stmts = root->get_statements();
     SgStatementPtrList::iterator i;
     for (i = root_stmts.begin(); i != root_stmts.end(); ++i)
        {
          if (expressionComputedIn(e, *i))
               break;
        }
     if (i == root_stmts.end())
          return; // Expression is not used within root, so quit
     vector<SgVariableSymbol*> used_symbols = SageInterface::getSymbolsUsedInExpression(e);
     SgName cachename = "cache_fd__"; cachename << ++SageInterface::gensym_counter;
     SgVariableDeclaration* cachedecl = new SgVariableDeclaration(SgNULL_FILE, cachename, e->get_type(),0 /* new SgAssignInitializer(SgNULL_FILE, e) */);
     SgInitializedName* cachevar = cachedecl->get_variables().back();
     ROSE_ASSERT (cachevar);
     root->get_statements().insert(i, cachedecl);
     cachedecl->set_parent(root);
     cachedecl->set_definingDeclaration(cachedecl);
     cachevar->set_scope(root);
     SgVariableSymbol* sym = new SgVariableSymbol(cachevar);
     root->insert_symbol(cachename, sym);
     SgVarRefExp* vr = new SgVarRefExp(SgNULL_FILE, sym);
     vr->set_endOfConstruct(SgNULL_FILE);
     replaceCopiesOfExpression(e, vr, root);

     vector<SgExpression*> modifications_to_used_symbols;
     FdFindModifyingStatementsVisitor(used_symbols, modifications_to_used_symbols).go(root);

     cachedecl->addToAttachedPreprocessingInfo( 
          new PreprocessingInfo(PreprocessingInfo::CplusplusStyleComment,(string("// Finite differencing: ") + 
               cachename.str() + " is a cache of " + 
               e->unparseToString()).c_str(),"Compiler-Generated in Finite Differencing",0, 0, 0, PreprocessingInfo::before));

     if (modifications_to_used_symbols.size() == 0)
        {
          SgInitializer* cacheinit = new SgAssignInitializer(SgNULL_FILE, e);
          e->set_parent(cacheinit);
          cachevar->set_initializer(cacheinit);
          cacheinit->set_parent(cachevar);
        }
       else
        {
          for (unsigned int i = 0; i < modifications_to_used_symbols.size(); ++i)
             {
               SgExpression* modstmt = modifications_to_used_symbols[i];
#ifdef FD_DEBUG
               cout << "Updating cache after " << modstmt->unparseToString() << endl;
#endif
               SgExpression* updateCache = 0;
               SgVarRefExp* varref = new SgVarRefExp(SgNULL_FILE, sym);
               varref->set_endOfConstruct(SgNULL_FILE);
               SgTreeCopy tc;
               SgExpression* eCopy = isSgExpression(e->copy(tc));
               switch (modstmt->variantT())
                  {
                    case V_SgAssignOp:
                       {
                         SgAssignOp* assignment = isSgAssignOp(modstmt);
                         assert (assignment);
                         SgExpression* lhs = assignment->get_lhs_operand();
                         SgExpression* rhs = assignment->get_rhs_operand();
                         replaceCopiesOfExpression(lhs, rhs, eCopy);
                       }
                    break;

                    case V_SgPlusAssignOp:
                    case V_SgMinusAssignOp:
                    case V_SgAndAssignOp:
                    case V_SgIorAssignOp:
                    case V_SgMultAssignOp:
                    case V_SgDivAssignOp:
                    case V_SgModAssignOp:
                    case V_SgXorAssignOp:
                    case V_SgLshiftAssignOp:
                    case V_SgRshiftAssignOp:
                       {
                         SgBinaryOp* assignment = isSgBinaryOp(modstmt);
                         assert (assignment);
                         SgExpression* lhs = assignment->get_lhs_operand();
                         SgExpression* rhs = assignment->get_rhs_operand();
                         SgTreeCopy tc;
                         SgExpression* rhsCopy = isSgExpression(rhs->copy(tc));
                         SgExpression* newval = 0;
                         switch (modstmt->variantT())
                            {
#define DO_OP(op, nonassignment) \
                              case V_##op: { \
                                   newval = new nonassignment(SgNULL_FILE, lhs, rhsCopy); \
                                   newval->set_endOfConstruct(SgNULL_FILE); \
                              } \
                              break

                              DO_OP(SgPlusAssignOp, SgAddOp);
                              DO_OP(SgMinusAssignOp, SgSubtractOp);
                              DO_OP(SgAndAssignOp, SgBitAndOp);
                              DO_OP(SgIorAssignOp, SgBitOrOp);
                              DO_OP(SgMultAssignOp, SgMultiplyOp);
                              DO_OP(SgDivAssignOp, SgDivideOp);
                              DO_OP(SgModAssignOp, SgModOp);
                              DO_OP(SgXorAssignOp, SgBitXorOp);
                              DO_OP(SgLshiftAssignOp, SgLshiftOp);
                              DO_OP(SgRshiftAssignOp, SgRshiftOp);
#undef DO_OP

                              default: break;
                            }
                         assert (newval);
                         replaceCopiesOfExpression(lhs, newval, eCopy);
                       }
                    break;

                    case V_SgPlusPlusOp:
                       {
                         SgExpression* lhs = isSgPlusPlusOp(modstmt)->get_operand();
                         SgIntVal* one = new SgIntVal(SgNULL_FILE, 1);
                         one->set_endOfConstruct(SgNULL_FILE);
                         SgAddOp* add = new SgAddOp(SgNULL_FILE, lhs, one);
                         add->set_endOfConstruct(SgNULL_FILE);
                         lhs->set_parent(add);
                         one->set_parent(add);
                         replaceCopiesOfExpression(lhs,add,eCopy);
                            }
                    break;

                    case V_SgMinusMinusOp:
                       {
                         SgExpression* lhs = isSgMinusMinusOp(modstmt)->get_operand();
                         SgIntVal* one = new SgIntVal(SgNULL_FILE, 1);
                         one->set_endOfConstruct(SgNULL_FILE);
                         SgSubtractOp* sub = new SgSubtractOp(SgNULL_FILE, lhs, one);
                         sub->set_endOfConstruct(SgNULL_FILE);
                         lhs->set_parent(sub);
                         one->set_parent(sub);
                         replaceCopiesOfExpression(lhs,sub,eCopy);
                       }
                    break;

                    default:
                         cerr << modstmt->sage_class_name() << endl;
                         assert (false);
                         break;
                  }

#ifdef FD_DEBUG
            cout << "e is " << e->unparseToString() << endl;
            cout << "eCopy is " << eCopy->unparseToString() << endl;
#endif
               updateCache = doFdVariableUpdate(rules, varref, e, eCopy);
#ifdef FD_DEBUG
            cout << "updateCache is " << updateCache->unparseToString() << endl;
#endif
               if (updateCache)
                  {
                    ROSE_ASSERT(modstmt != NULL);
                    SgNode* ifp = modstmt->get_parent();
                    SgCommaOpExp* comma = new SgCommaOpExp(SgNULL_FILE, updateCache, modstmt);
                    modstmt->set_parent(comma);
                    updateCache->set_parent(comma);

                    if (ifp == NULL)
                       {
                         printf ("modstmt->get_parent() == NULL modstmt = %p = %s \n",modstmt,modstmt->class_name().c_str());
                         modstmt->get_startOfConstruct()->display("modstmt->get_parent() == NULL: debug");
                       }
                    ROSE_ASSERT(ifp != NULL);
#ifdef FD_DEBUG
                 cout << "New expression is " << comma->unparseToString() << endl;
                 cout << "IFP is " << ifp->sage_class_name() << ": " << ifp->unparseToString() << endl;
#endif
                    if (isSgExpression(ifp))
                       {
                         isSgExpression(ifp)->replace_expression(modstmt, comma);
                         comma->set_parent(ifp);
                       }
                      else
                       {
                      // DQ (12/16/2006): Need to handle cases that are not SgExpression (now that SgExpressionRoot is not used!)
                      // cerr << ifp->sage_class_name() << endl;
                      // assert (!"Bad parent type for inserting comma expression");
                         SgStatement* statement = isSgStatement(ifp);
                         if (statement != NULL)
                            {
#ifdef FD_DEBUG
                              printf ("Before statement->replace_expression(): statement = %p = %s modstmt = %p = %s \n",statement,statement->class_name().c_str(),modstmt,modstmt->class_name().c_str());
                              SgExprStatement* expresionStatement = isSgExprStatement(statement);
                              if (expresionStatement != NULL)
                                 {
                                   SgExpression* expression = expresionStatement->get_expression();
                                   printf ("expressionStatement expression = %p = %s \n",expression,expression->class_name().c_str());
                                 }
#endif
                              statement->replace_expression(modstmt, comma);
                              comma->set_parent(statement);
                            }
                           else
                            {
                              ROSE_ASSERT(ifp != NULL);
                              printf ("Error: parent is neither a SgExpression nor a SgStatement ifp = %p = %s \n",ifp,ifp->class_name().c_str());
                              ROSE_ASSERT(false);
                            }
                       }

#ifdef FD_DEBUG
                    cout << "IFP is now " << ifp->unparseToString() << endl;
#endif
                  }
             }
        }
   }
コード例 #6
0
ファイル: mlm.cpp プロジェクト: 8l/rose
bool mlmTransform::loopTiling(SgForStatement* loopNest, size_t tileDims, size_t tileSize)
{
  ROSE_ASSERT(loopNest != NULL);
  ROSE_ASSERT(tileDims >0);
 // ROSE_ASSERT(tileSize>0);// 1 is allowed
 // skip tiling if tiling size is 0 (no tiling), we allow 0 to get a reference value for the original code being tuned
 // 1 (no need to tile)
  if (tileSize<=1)
    return true;
  // Locate the target loop at level n
  std::vector<SgForStatement* > loops= SageInterface::querySubTree<SgForStatement>(loopNest,V_SgForStatement);
  ROSE_ASSERT(loops.size()>=tileDims);
  for(int id = 0; id < tileDims; id++)
  {
  SgForStatement* target_loop = loops[id]; // adjust to numbering starting from 0

  // normalize the target loop first
  if (!forLoopNormalization(target_loop));
  {// the return value is not reliable
//    cerr<<"Error in SageInterface::loopTiling(): target loop cannot be normalized."<<endl;
//    dumpInfo(target_loop);
//    return false;
  }
   // grab the target loop's essential header information
   SgInitializedName* ivar = NULL;
   SgExpression* lb = NULL;
   SgExpression* ub = NULL;
   SgExpression* step = NULL;
   if (!isCanonicalForLoop(target_loop, &ivar, &lb, &ub, &step, NULL))
   {
     cerr<<"Error in SageInterface::loopTiling(): target loop is not canonical."<<endl;
     dumpInfo(target_loop);
     return false;
   }
   ROSE_ASSERT(ivar&& lb && ub && step);

  // Add a controlling loop around the top loop nest
  // Ensure the parent can hold more than one children
  SgLocatedNode* parent = NULL; //SageInterface::ensureBasicBlockAsParent(loopNest)
  if (isBodyStatement(loopNest)) // if it is a single body statement (Already a for statement, not a basic block)
   parent = makeSingleStatementBodyToBlock (loopNest);
  else
    parent = isSgLocatedNode(loopNest ->get_parent());

  ROSE_ASSERT(parent!= NULL);
     // Now we can prepend a controlling loop index variable: __lt_var_originalIndex
  string ivar2_name = "_lt_var_"+ivar->get_name().getString();
  SgScopeStatement* scope = loopNest->get_scope();
  SgVariableDeclaration* loop_index_decl = buildVariableDeclaration
  (ivar2_name, buildIntType(),NULL, scope);
  insertStatementBefore(loopNest, loop_index_decl);
   // init statement of the loop header, copy the lower bound
   SgStatement* init_stmt = buildAssignStatement(buildVarRefExp(ivar2_name,scope), copyExpression(lb));
   //two cases <= or >= for a normalized loop
   SgExprStatement* cond_stmt = NULL;
   SgExpression* orig_test = target_loop->get_test_expr();
   if (isSgBinaryOp(orig_test))
   {
     if (isSgLessOrEqualOp(orig_test))
       cond_stmt = buildExprStatement(buildLessOrEqualOp(buildVarRefExp(ivar2_name,scope),copyExpression(ub)));
     else if (isSgGreaterOrEqualOp(orig_test))
     {
       cond_stmt = buildExprStatement(buildGreaterOrEqualOp(buildVarRefExp(ivar2_name,scope),copyExpression(ub)));
       }
     else
     {
       cerr<<"Error: illegal condition operator for a canonical loop"<<endl;
       dumpInfo(orig_test);
       ROSE_ASSERT(false);
     }
   }
   else
   {
     cerr<<"Error: illegal condition expression for a canonical loop"<<endl;
     dumpInfo(orig_test);
     ROSE_ASSERT(false);
   }
   ROSE_ASSERT(cond_stmt != NULL);

   // build loop incremental  I
   // expression var+=up*tilesize or var-=upper * tilesize
   SgExpression* incr_exp = NULL;
   SgExpression* orig_incr_exp = target_loop->get_increment();
   if( isSgPlusAssignOp(orig_incr_exp))
   {
     incr_exp = buildPlusAssignOp(buildVarRefExp(ivar2_name,scope), buildMultiplyOp(copyExpression(step), buildIntVal(tileSize)));
   }
    else if (isSgMinusAssignOp(orig_incr_exp))
    {
      incr_exp = buildMinusAssignOp(buildVarRefExp(ivar2_name,scope), buildMultiplyOp(copyExpression(step), buildIntVal(tileSize)));
    }
    else
    {
      cerr<<"Error: illegal increment expression for a canonical loop"<<endl;
      dumpInfo(orig_incr_exp);
      ROSE_ASSERT(false);
    }
    SgForStatement* control_loop = buildForStatement(init_stmt, cond_stmt,incr_exp, buildBasicBlock());
  insertStatementBefore(loopNest, control_loop);
  // move loopNest into the control loop
  removeStatement(loopNest);
  appendStatement(loopNest,isSgBasicBlock(control_loop->get_loop_body()));

  if(id == tileDims-1)
  {
    allocSubdomain(loopNest, tileSize);
  } 

  // rewrite the lower (i=lb), upper bounds (i<=/>= ub) of the target loop
//  SgAssignOp* assign_op  = isSgAssignOp(lb->get_parent());
//  ROSE_ASSERT(assign_op);
//  assign_op->set_rhs_operand(buildVarRefExp(ivar2_name,scope));
    // ub< var_i+tileSize-1? ub:var_i+tileSize-1
  SgBinaryOp* bin_op = isSgBinaryOp(ub->get_parent());
  ROSE_ASSERT(bin_op);
//  SgExpression* ub2 = buildSubtractOp(buildAddOp(buildVarRefExp(ivar2_name,scope), buildIntVal(tileSize)), buildIntVal(1));
  SgExpression* ub2 = buildIntVal(tileSize);
//  SgExpression* test_exp = buildLessThanOp(copyExpression(ub),ub2);
//  test_exp->set_need_paren(true);
//  ub->set_need_paren(true);
//  ub2->set_need_paren(true);
//  SgConditionalExp * triple_exp = buildConditionalExp(test_exp,copyExpression(ub), copyExpression(ub2));
//  bin_op->set_rhs_operand(triple_exp);
  bin_op->set_rhs_operand(ub2);
  // constant folding
  // folding entire loop may decrease the accuracy of floating point calculation
  // we fold loop control expressions only
  //constantFolding(control_loop->get_scope());
  constantFolding(control_loop->get_test());
  constantFolding(control_loop->get_increment());
  }
  return true;
}