SgNode*
SourceLocationInheritedAttribute::
getCurrentStatementInScope( SgScopeStatement* targetScope ) const
   {
     ROSE_ASSERT (targetScope != NULL);

#if 1
     printf ("At top of SourceLocationInheritedAttribute::getCurrentStatementInScope(): targetScope = %p targetScope->sage_class_name() = %s \n",
          targetScope,targetScope->sage_class_name());
#endif

     int scopeDepth = -1;
     unsigned int i;

  // Search the scopeList for the target scope. We no longer use the index of the 
  // scope to compute the index into the statement list. This would be complicated 
  // since the lists are different sizes debending on the details of the traversal 
  // of the AST (what is a child vs. what is a new sort of Sage node).
     for (i = 0; i < scopeList.size(); i++)
        {
          ROSE_ASSERT (scopeList[i] != NULL);
          if (scopeList[i] == targetScope)
               scopeDepth = i;
        }

#if 1
  // error checking (redundent with assert below, but provides better user interface) 
  // printf ("scopeDepth = %d \n",scopeDepth);
     if (scopeDepth < 0)
        {
       // Report an error since no scope was found
          printf ("ERROR: target scope was not found targetScope = %p targetScope->unparseToString() = %s \n",
               targetScope,targetScope->unparseToString().c_str());
          ROSE_ABORT();
        }
#endif

     ROSE_ASSERT (scopeDepth >= 0);

  // Now get the depth of the associated target statement
  // int targetStatementDepth = scopeDepth+1;
  // increment depends upon number of functions (could be more than one with local class definitions).
  // int targetStatementDepth = scopeDepth+1;

#if 1
     printf ("In SourceLocationInheritedAttribute::getCurrentStatementInScope(): scopeDepth = %d  scopeList.size()     = %zu \n",scopeDepth,scopeList.size());
     printf ("In SourceLocationInheritedAttribute::getCurrentStatementInScope(): scopeDepth = %d  statementList.size() = %zu \n",scopeDepth,statementList.size());
     printf ("##### Find the associated current statement in the target scope: \n");
#endif

  // If this is not a query about the deepest scope then we can find the current statement 
  // in scopeList by looking at the next scope.  Else we have to look at the last statement in the 
  // statement list (to find the current statement in the deepest (currently local) scope).
     SgStatement* targetStatement = NULL;
     if (scopeDepth < (int)(scopeList.size()-1))
        {
          printf ("     use the NEXT statement in the scope list \n");
#if 0
          targetStatement = scopeList[scopeDepth+1];
#else
       // We need to find the target statement in the targe scope, this might not be in the
       // list of scopes since only some scopes are saved to avoid redundent accumulation of 
       // multiple nodes that can represent only a single scope (e.g. functions).  The scope
       // that we store are not always the ones that represent the first node representing 
       // that scope (e.g. functions). But the targetStaement must be initialized to the 
       // statement that appears in the target scope (because the insertion mechanism requires 
       // this).
          int indexOfTargetStatement = -1;
          for (i = 0; i < statementList.size(); i++)
             {
               ROSE_ASSERT (statementList[i] != NULL);
               if (statementList[i] == targetScope)
                    indexOfTargetStatement = i+1;
             }
          ROSE_ASSERT (indexOfTargetStatement >= 0);
          ROSE_ASSERT (indexOfTargetStatement < (int)statementList.size());
          targetStatement = statementList[indexOfTargetStatement];
#endif
        }
       else
        {
          printf ("     use the LAST statement in the statement list \n");
          targetStatement = *(statementList.rbegin());
        }

     ROSE_ASSERT (targetStatement != NULL);

#if 0
     if (isSgScopeStatement( *(statementList.rbegin()) ) != NULL)
          targetStatementDepth = scopeDepth;
       else
          targetStatementDepth = scopeDepth+1;
#endif

#if 1
     printf ("targetScope     = %p targetScope->sage_class_name()     = %s \n",
          targetScope,targetScope->sage_class_name());
     printf ("targetScope = %p targetScope->unparseToString() = %s \n",
          targetScope,targetScope->unparseToString().c_str());
     printf ("targetStatement = %p targetStatement->sage_class_name() = %s \n",
          targetStatement,targetStatement->sage_class_name());
     printf ("targetStatement = %p targetStatement->unparseToString() = %s \n",
          targetStatement,targetStatement->unparseToString().c_str());
#endif

#if ROSE_INTERNAL_DEBUG
  // Error checking: search for targetStatement within the targetScope
     bool found = false;
     if (targetScope->containsOnlyDeclarations() == true)
        {
          printf ("Looking in a scope containing only declarations ... \n");
          SgDeclarationStatementPtrList & declarationList = targetScope->getDeclarationList();
          ROSE_ASSERT (declarationList.size() > 0);
          SgDeclarationStatementPtrList::iterator j;
          for (j = declarationList.begin(); j != declarationList.end(); j++)
             {
               ROSE_ASSERT ((*j) != NULL);
#if 0
               printf ("Testing against declaration: (*j) = %p (*j)->unparseToString() = %s \n",
                    (*j),(*j)->unparseToString().c_str());
#endif
               if ( (*j) == targetStatement )
                    found = true;
             }
        }
       else
        {
          printf ("Looking in a scope containing any statement nodes ... \n");
          SgStatementPtrList & statementList = targetScope->getStatementList();
          ROSE_ASSERT (statementList.size() > 0);
          SgStatementPtrList::iterator j;
          for (j = statementList.begin(); j != statementList.end(); j++)
             {
               ROSE_ASSERT ((*j) != NULL);
#if 0
               printf ("Testing against statement: (*j) = %p (*j)->unparseToString() = %s \n",
                    (*j),(*j)->unparseToString().c_str());
#endif
               if ( (*j) == targetStatement )
                    found = true;
             }
        }

     if (found == false)
          display("At base of SourceLocationInheritedAttribute::getCurrentStatementInScope()");

     ROSE_ASSERT (found == true);
#endif

#if 0
     printf ("Exiting at base of SourceLocationInheritedAttribute::getCurrentStatementInScope() \n");
     ROSE_ABORT();
#endif

     ROSE_ASSERT (targetStatement != NULL);

     return targetStatement;
   }
void
FunctionCallNormalization::visit( SgNode *astNode )
   {
     SgStatement *stm = isSgStatement( astNode );

     // visiting all statements which may contain function calls;
     // Note 1: we do not look at the body of loops, or sequences of statements, but only
     // at statements which may contain directly function calls; all other statements will have their component parts visited in turn
     if ( isSgEnumDeclaration( astNode ) || isSgVariableDeclaration( astNode ) || isSgVariableDefinition( astNode ) ||
                               isSgExprStatement( astNode ) || isSgForStatement( astNode ) || isSgReturnStmt( astNode ) ||
                               isSgSwitchStatement( astNode ) )
        {
       // maintain the mappings from function calls to expressions (variables or dereferenced variables)
          map<SgFunctionCallExp *, SgExpression *> fct2Var;

       // list of Declaration structures, one structure per function call
          DeclarationPtrList declarations;
          bool variablesDefined = false;
             
       // list of function calls, in correnspondence with the inForTest list below
          list<SgNode*> functionCallExpList;
          list<bool> inForTest;

          SgForStatement *forStm = isSgForStatement( stm );
          SgSwitchStatement *swStm = isSgSwitchStatement( stm );
          list<SgNode*> temp1, temp2;

       // for-loops and Switch statements have conditions ( and increment ) expressed as expressions
       // and not as standalone statements; this will change in future Sage versions
       // TODO: when for-loops and switch statements have conditions expressed via SgStatements
       // these cases won't be treated separately; however, do-while will have condition expressed via expression
       // so that will be the only exceptional case to be treated separately
          if (forStm != NULL)
             {
            // create a list of function calls in the condition and increment expression
            // the order is important, the condition is evaluated after the increment expression
            // temp1 = FEOQueryForNodes( forStm->get_increment_expr_root(), V_SgFunctionCallExp );
            // temp2 = FEOQueryForNodes( forStm->get_test_expr_root(), V_SgFunctionCallExp );
               temp1 = FEOQueryForNodes( forStm->get_increment(), V_SgFunctionCallExp );
               temp2 = FEOQueryForNodes( forStm->get_test_expr(), V_SgFunctionCallExp );
               functionCallExpList = temp1;
               functionCallExpList.splice( functionCallExpList.end(), temp2 );
             }
            else
             {
               if (swStm != NULL)
                  {
                 // create a list of function calls in the condition in the order of function evaluation
                 // DQ (11/23/2005): Fixed SgSwitchStmt to have SgStatement for conditional.
                 // list<SgNode*> temp1 = FEOQueryForNodes( swStm->get_item_selector_root(), V_SgFunctionCallExp );
                    list<SgNode*> temp1 = FEOQueryForNodes( swStm->get_item_selector(), V_SgFunctionCallExp );
                    functionCallExpList = temp1;
                  }
                 else
                  {
                 // create a list of function calls in the statement in the order of function evaluation
                    functionCallExpList = FEOQueryForNodes( stm, V_SgFunctionCallExp );
                  }
             }

         // all function calls get replaced: this is because they can occur in expressions (e.g. for-loops)
         // which makes it difficult to build control flow graphs
         if ( functionCallExpList.size() > 0 )
           {
             cout << "--------------------------------------\nStatement ";
             cout << stm->unparseToString() << "\n";;
             
             // traverse the list of function calls in the current statement, generate a structure  Declaration for each call
             // put these structures in a list to be inserted in the code later
             for ( list<SgNode *>::iterator i = functionCallExpList.begin(); i != functionCallExpList.end(); i++ )
               {
                 variablesDefined = true;

                 // get function call exp
                 SgFunctionCallExp *exp = isSgFunctionCallExp( *i );
                 ROSE_ASSERT ( exp );
                 
                 // get type of expression, generate unique variable name
                 SgType *expType = exp->get_type();
                 ROSE_ASSERT ( expType );
                 Sg_File_Info *location = Sg_File_Info::generateDefaultFileInfoForTransformationNode();
                 ROSE_ASSERT ( location );
                 ostringstream os;
                 os << "__tempVar__" << location;
                 SgName name = os.str().c_str();

                 // replace previous variable bindings in the AST
                 SgExprListExp *paramsList = exp->get_args();
                 SgExpression *function = exp->get_function();
                 ROSE_ASSERT ( paramsList && function );
                 replaceFunctionCallsInExpression( paramsList, fct2Var );
                 replaceFunctionCallsInExpression( function, fct2Var );

                 // duplicate function call expression, for the initialization declaration and the assignment
                 SgTreeCopy treeCopy;
                 SgFunctionCallExp *newExpInit = isSgFunctionCallExp( exp->copy( treeCopy ) );
                 ROSE_ASSERT ( newExpInit );
                 SgFunctionCallExp *newExpAssign = isSgFunctionCallExp( exp->copy( treeCopy ) );
                 ROSE_ASSERT ( newExpAssign );

                 // variables
                 Sg_File_Info *initLoc = Sg_File_Info::generateDefaultFileInfoForTransformationNode(),
                   *nonInitLoc = Sg_File_Info::generateDefaultFileInfoForTransformationNode(),
                   *assignLoc = Sg_File_Info::generateDefaultFileInfoForTransformationNode();
                 Declaration *newDecl = new Declaration();
                 SgStatement *nonInitVarDeclaration, *initVarDeclaration, *assignStmt;
                 SgExpression *varRefExp;
                 SgVariableSymbol *varSymbol;
                 SgAssignOp *assignOp;
                 SgInitializedName *initName;

                 bool pointerTypeNeeded = false;

                 // mark whether to replace inside or outside of ForStatement due to the
                 // function call being inside the test or the increment for a for-loop statement
                 // the 'inForTest' list is in 1:1  ordered correpondence with the 'declarations' list
                 if ( forStm )
                   {
        // SgExpressionRoot
                  //   *testExp = isSgForStatement( astNode )->get_test_expr_root(),
                  //   *incrExp = isSgForStatement( astNode )->get_increment_expr_root();
                     SgExpression
                       *testExp = isSgForStatement( astNode )->get_test_expr(),
                       *incrExp = isSgForStatement( astNode )->get_increment();
                     SgNode *up = exp;
                     while ( up && up != testExp && up != incrExp )
                       up = up->get_parent();
                     ROSE_ASSERT ( up );

                     // function call is in the condition of the for-loop
                     if ( up == testExp )
                       inForTest.push_back( true );
                     // function call is in the increment expression
                     else
                       {
                         inForTest.push_back( false );

                         // for increment expressions we need to be able to reassign the return value
                         // of the function; if the ret value is a reference, we need to generate a
                         // pointer of that type (to be able to reassign it later)
                         if ( isSgReferenceType( expType ) )
                           pointerTypeNeeded = true;
                       }
                   }

                 // for do-while statements:  we need to generate declaration of type pointer to be able to have
                 // non-assigned references when looping and assign them at the end of the body of the loop
                 if ( isSgDoWhileStmt( stm->get_parent() ) && isSgReferenceType( expType ) )
                   pointerTypeNeeded = true;

                 // we have a function call returning a reference and we can't initialize the variable
                 // at the point of declaration; we need to define the variable as a pointer
                 if ( pointerTypeNeeded )
                   {
                     // create 'address of' term for function expression, so we can assign it to the pointer
                     SgAddressOfOp *addressOp = new SgAddressOfOp( assignLoc, newExpAssign, expType );

                     // create noninitialized declaration
                     SgType *base = isSgReferenceType( expType )->get_base_type();
                     ROSE_ASSERT( base );
                     SgPointerType *ptrType = SgPointerType::createType( isSgReferenceType( expType )->get_base_type() );
                     ROSE_ASSERT ( ptrType );
                     nonInitVarDeclaration = new SgVariableDeclaration ( nonInitLoc, name, ptrType );

                     // create assignment (symbol, varRefExp, assignment)
                     initName = isSgVariableDeclaration( nonInitVarDeclaration )->get_decl_item( name );
                     ROSE_ASSERT ( initName );

                     varSymbol = new SgVariableSymbol( initName );
                     ROSE_ASSERT ( varSymbol );
                     varRefExp = new SgVarRefExp( assignLoc, varSymbol );

                     SgPointerDerefExp *ptrDeref= new SgPointerDerefExp( assignLoc, varRefExp, expType );
                     ROSE_ASSERT ( isSgExpression( varRefExp ) && ptrDeref );
                     assignOp = new SgAssignOp( assignLoc, varRefExp, addressOp, ptrType );
                     assignStmt = new SgExprStatement( assignLoc, assignOp );
                     ROSE_ASSERT ( assignStmt &&  nonInitVarDeclaration );
           
                     // we don't need initialized declarations in this case
                     initVarDeclaration = NULL;

                     // save new mapping
                     fct2Var.insert( Fct2Var( exp, ptrDeref ) );
                   }
                 else
                   {
                     // create (non- &)initialized declarations, initialized name & symbol
                     SgAssignInitializer *declInit = new SgAssignInitializer( initLoc, newExpInit, expType );
                     ROSE_ASSERT ( declInit );
                     initVarDeclaration = new SgVariableDeclaration ( initLoc, name, expType, declInit );
                     nonInitVarDeclaration = new SgVariableDeclaration ( nonInitLoc, name, expType );
                     ROSE_ASSERT ( initVarDeclaration && nonInitVarDeclaration );

                     initName = isSgVariableDeclaration( nonInitVarDeclaration )->get_decl_item( name );
                     ROSE_ASSERT ( initName );
                     newExpInit->set_parent( initName );
                     varSymbol = new SgVariableSymbol( initName );
                     ROSE_ASSERT ( varSymbol );

                     // create variable ref exp
                     varRefExp = new SgVarRefExp( assignLoc, varSymbol );
                     ROSE_ASSERT ( isSgVarRefExp( varRefExp ) );

                     // create the assignment
                     assignOp = new SgAssignOp( assignLoc, varRefExp, newExpAssign, expType );
                     assignStmt = new SgExprStatement( assignLoc, assignOp );
                     ROSE_ASSERT ( assignStmt );

                     initVarDeclaration->set_parent( stm->get_parent() );
                     isSgVariableDeclaration( initVarDeclaration )->set_definingDeclaration( isSgDeclarationStatement( initVarDeclaration ) );

                     // save new mapping
                     fct2Var.insert( Fct2Var( exp, varRefExp ) );
                   }

                 // save the 'declaration' structure, with all 3 statements and the variable name
                 newDecl->nonInitVarDeclaration = nonInitVarDeclaration;
                 newDecl->initVarDeclaration = initVarDeclaration;
                 newDecl->assignment = assignStmt;
                 newDecl->name = name;
                 nonInitVarDeclaration->set_parent( stm->get_parent() );
                 isSgVariableDeclaration( nonInitVarDeclaration )->set_definingDeclaration( isSgVariableDeclaration( nonInitVarDeclaration ) );
                 assignStmt->set_parent( stm->get_parent() );
                 declarations.push_back( newDecl );
               } // end for
           } // end if  fct calls in crt stmt > 1

         SgScopeStatement *scope = stm->get_scope();
         ROSE_ASSERT ( scope );
         
         // insert function bindings to variables; each 'declaration' structure in the list
         // corresponds to one function call
         for ( DeclarationPtrList::iterator i = declarations.begin(); i != declarations.end(); i++ )
           {
             Declaration *d = *i;
             ROSE_ASSERT ( d && d->assignment && d->nonInitVarDeclaration );

             // if the current statement is a for-loop, we insert Declarations before & in the loop body, depending on the case
             if ( forStm )
               {
                 SgStatement *parentScope = isSgStatement( stm->get_scope() );
                 SgBasicBlock *body = SageInterface::ensureBasicBlockAsBodyOfFor(forStm);
                 ROSE_ASSERT ( !inForTest.empty() && body && parentScope );
                 // SgStatementPtrList &list = body->get_statements();

                 // if function call is in loop condition, we add initialized variable before the loop and at its end
                 // hoist initialized variable declarations outside the loop
                 if ( inForTest.front() )
                   {
                     ROSE_ASSERT ( d->initVarDeclaration );
                     parentScope->insert_statement( stm, d->initVarDeclaration );

                     // set the scope of the initializedName
                     SgInitializedName *initName = isSgVariableDeclaration( d->initVarDeclaration )->get_decl_item( d->name );
                     ROSE_ASSERT ( initName );
                     initName->set_scope( isSgScopeStatement( parentScope ) );
                     ROSE_ASSERT ( initName->get_scope() );
                   }
                 // function call is in loop post increment so add noninitialized variable decls above the loop
                 else
                   {
                     parentScope->insert_statement( stm, d->nonInitVarDeclaration );

                     // set the scope of the initializedName
                     SgInitializedName *initName = isSgVariableDeclaration( d->nonInitVarDeclaration )->get_decl_item( d->name );
                     ROSE_ASSERT ( initName );
                     initName->set_scope( isSgScopeStatement( parentScope ) );
                     ROSE_ASSERT ( initName->get_scope() );
                   }

                 // in a for-loop, always insert assignments at the end of the loop
                 body->get_statements().push_back( d->assignment );
                 d->assignment->set_parent( body );

                 // remove marker
                 inForTest.pop_front();
               }
             else
               {
                 // look at the type of the enclosing scope
                 switch ( scope->variantT() )
                   {

                     // while stmts have to repeat the function calls at the end of the loop;
                     // note there is no "break" statement, since we want to also add initialized
                     // declarations before the while-loop
                   case V_SgWhileStmt:
                     {
                       // assignments need to be inserted at the end of each while loop
                       SgBasicBlock *body = SageInterface::ensureBasicBlockAsBodyOfWhile(isSgWhileStmt( scope ) );
                       ROSE_ASSERT ( body );
                       d->assignment->set_parent( body );
                       body->get_statements().push_back( d->assignment );
                     }

                     // SgForInitStatement has scope SgForStatement, move declarations before the for loop;
                     // same thing if the enclosing scope is an If, or Switch statement
                   case V_SgForStatement:
                   case V_SgIfStmt:
                   case V_SgSwitchStatement:
                     {
                       // adding bindings (initialized variable declarations only, not assignments)
                       // outside the statement, in the parent scope
                       SgStatement *parentScope = isSgStatement( scope->get_parent() );
                       ROSE_ASSERT ( parentScope );
                       parentScope->insert_statement( scope, d->initVarDeclaration, true );\

                       // setting the scope of the initializedName
                       SgInitializedName *initName = isSgVariableDeclaration( d->initVarDeclaration )->get_decl_item( d->name );
                       ROSE_ASSERT ( initName );
                       initName->set_scope( scope->get_scope() );
                       ROSE_ASSERT ( initName->get_scope() );
                     }
                     break;

                     // do-while needs noninitialized declarations before the loop, with assignments inside the loop
                   case V_SgDoWhileStmt:
                     {
                       // adding noninitialized variable declarations before the body of the loop
                       SgStatement *parentScope = isSgStatement( scope->get_parent() );
                       ROSE_ASSERT ( parentScope );
                       parentScope->insert_statement( scope, d->nonInitVarDeclaration, true );

                       // initialized name scope setting
                       SgInitializedName *initName = isSgVariableDeclaration( d->nonInitVarDeclaration )->get_decl_item( d->name );
                       ROSE_ASSERT ( initName );
                       initName->set_scope( scope->get_scope() );
                       ROSE_ASSERT ( initName->get_scope() );

                       // adding assignemts at the end of the do-while loop
                       SgBasicBlock *body = SageInterface::ensureBasicBlockAsBodyOfDoWhile( isSgDoWhileStmt(scope) );
                       ROSE_ASSERT ( body );
                       body->get_statements().push_back( d->assignment );
                       d->assignment->set_parent(body);
                     }
                     break;

                     // for all other scopes, add bindings ( initialized declarations ) before the statement, in the same scope
                   default:
                     scope->insert_statement( stm, d->initVarDeclaration, true );

                     // initialized name scope setting
                     SgInitializedName *initName = isSgVariableDeclaration( d->initVarDeclaration )->get_decl_item( d->name );
                     ROSE_ASSERT ( initName );
                     initName->set_scope( scope->get_scope() );
                     ROSE_ASSERT ( initName->get_scope() );
                   }
               }
           }
         
         // once we have inserted all variable declarations, we need to replace top-level calls in the original statement
         if ( variablesDefined )
           {
             cout << "\tReplacing in the expression " << stm->unparseToString() << "\n";

             // for ForStatements, replace expressions in condition and increment expressions,
             // not in the body, since those get replace later
             if ( forStm )
               {
         // SgExpressionRoot *testExp = forStm->get_test_expr_root(), *incrExp = forStm->get_increment_expr_root();
            SgExpression *testExp = forStm->get_test_expr(), *incrExp = forStm->get_increment();
            replaceFunctionCallsInExpression( incrExp, fct2Var );
            replaceFunctionCallsInExpression( testExp, fct2Var );
               }
             else
               if ( swStm )
             {
            // DQ (11/23/2005): Fixed SgSwitch to permit use of declaration for conditional
            // replaceFunctionCallsInExpression( swStm->get_item_selector_root(), fct2Var );
               replaceFunctionCallsInExpression( swStm->get_item_selector(), fct2Var );
             }
               else
             replaceFunctionCallsInExpression( stm, fct2Var );
           }
       } // end if isSgStatement block
   }
Exemplo n.º 3
0
/*
 * returns test condition of for loop
 */
string MigrationOutliner::getForloopTest(SgForStatement *forstmt){
        SgStatement* testcondition = forstmt->get_test();
        return testcondition->unparseToString();
}//end getFunctionName