SgType* Fortran_to_C::translateType(SgType* oldType)
{
switch(oldType->variantT())
{
case V_SgTypeString:
{
SgExpression* stringLength = deepCopy(isSgTypeString(oldType)->get_lengthExpression());
SgArrayType* newType = buildArrayType(buildCharType(),NULL);
newType->set_rank(1);
newType->set_dim_info(buildExprListExp(stringLength));
return newType;
}
case V_SgTypeFloat:
{
SgIntVal* typeKind = isSgIntVal(oldType->get_type_kind());
if(typeKind == NULL)
{
// TODO: we just return original type. Might need to fix this in the future
return oldType;
}
switch(typeKind->get_value())
{
case 4:
return buildFloatType();
case 8:
return buildDoubleType();
default:
ROSE_ASSERT(false);
}
}
case V_SgTypeInt:
{
SgIntVal* typeKind = isSgIntVal(oldType->get_type_kind());
if(typeKind == NULL)
{
// TODO: we just return original type. Might need to fix this in the future
return oldType;
}
switch(typeKind->get_value())
{
case 2:
return buildShortType();
case 4:
return buildIntType();
case 8:
return buildLongType();
default:
ROSE_ASSERT(false);
}
}
default:
return oldType;
}
}
int main( int argc, char * argv[] )
{
// Option to linearize the array.
Rose_STL_Container<std::string> localCopy_argv = CommandlineProcessing::generateArgListFromArgcArgv(argc, argv);
int newArgc;
char** newArgv = NULL;
vector<string> argList = localCopy_argv;
if (CommandlineProcessing::isOption(argList,"-f2c:","linearize",true) == true)
{
isLinearlizeArray = true;
}
CommandlineProcessing::generateArgcArgvFromList(argList,newArgc, newArgv);
// Build the AST used by ROSE
SgProject* project = frontend(newArgc,newArgv);
AstTests::runAllTests(project);
if (SgProject::get_verbose() > 2)
generateAstGraph(project,8000,"_orig");
// Traversal with Memory Pool to search for variableDeclaration
variableDeclTraversal translateVariableDeclaration;
traverseMemoryPoolVisitorPattern(translateVariableDeclaration);
for(vector<SgVariableDeclaration*>::iterator dec=variableDeclList.begin(); dec!=variableDeclList.end(); ++dec)
{
/*
For the Fortran AST, a single variableDeclaration can be shared by multiple variables.
This violated the normalization rules for C unparser. Therefore, we have to transform it.
*/
SgVariableDeclaration* variableDeclaration = isSgVariableDeclaration(*dec);
ROSE_ASSERT(variableDeclaration);
if((variableDeclaration->get_variables()).size() != 1)
{
updateVariableDeclarationList(variableDeclaration);
statementList.push_back(variableDeclaration);
removeList.push_back(variableDeclaration);
}
}
// reset the vector that collects all variable declaration. We need to walk through memory pool again to find types
variableDeclList.clear();
traverseMemoryPoolVisitorPattern(translateVariableDeclaration);
for(vector<SgVariableDeclaration*>::iterator dec=variableDeclList.begin(); dec!=variableDeclList.end(); ++dec)
{
SgVariableDeclaration* variableDeclaration = isSgVariableDeclaration(*dec);
ROSE_ASSERT(variableDeclaration);
SgInitializedNamePtrList initializedNameList = variableDeclaration->get_variables();
for(SgInitializedNamePtrList::iterator i=initializedNameList.begin(); i!=initializedNameList.end();++i)
{
SgInitializedName* initiallizedName = isSgInitializedName(*i);
SgType* baseType = initiallizedName->get_type();
if(baseType->variantT() == V_SgArrayType)
{
SgArrayType* arrayBase = isSgArrayType(baseType);
// At this moment, we are still working on the Fortran-stype AST. Therefore, there is no nested types for multi-dim array.
if(arrayBase->findBaseType()->variantT() == V_SgTypeString)
{
arrayBase->reset_base_type(translateType(arrayBase->findBaseType()));
arrayBase->set_rank(arrayBase->get_rank()+1);
}
}
else
{
initiallizedName->set_type(translateType(baseType));
}
}
}
// replace the AttributeSpecificationStatement
Rose_STL_Container<SgNode*> AttributeSpecificationStatement = NodeQuery::querySubTree (project,V_SgAttributeSpecificationStatement);
for (Rose_STL_Container<SgNode*>::iterator i = AttributeSpecificationStatement.begin(); i != AttributeSpecificationStatement.end(); i++)
{
SgAttributeSpecificationStatement* attributeSpecificationStatement = isSgAttributeSpecificationStatement(*i);
ROSE_ASSERT(attributeSpecificationStatement);
translateAttributeSpecificationStatement(attributeSpecificationStatement);
statementList.push_back(attributeSpecificationStatement);
removeList.push_back(attributeSpecificationStatement);
}
// replace the parameter reference
parameterTraversal translateParameterRef;
traverseMemoryPoolVisitorPattern(translateParameterRef);
for(vector<SgVarRefExp*>::iterator i=parameterRefList.begin(); i!=parameterRefList.end(); ++i)
{
SgVarRefExp* parameterRef = isSgVarRefExp(*i);
if(parameterSymbolList.find(parameterRef->get_symbol()) != parameterSymbolList.end())
{
SgExpression* newExpr = isSgExpression(deepCopy(parameterSymbolList.find(parameterRef->get_symbol())->second));
ROSE_ASSERT(newExpr);
newExpr->set_parent(parameterRef->get_parent());
replaceExpression(parameterRef,
newExpr,
false);
}
}
/*
Parameters will be replaced by #define, all the declarations should be removed
*/
for(map<SgVariableSymbol*,SgExpression*>::iterator i=parameterSymbolList.begin();i!=parameterSymbolList.end();++i)
{
SgVariableSymbol* symbol = i->first;
SgInitializedName* initializedName = symbol->get_declaration();
SgVariableDeclaration* decl = isSgVariableDeclaration(initializedName->get_parent());
statementList.push_back(decl);
removeList.push_back(decl);
}
// Traversal with Memory Pool to search for arrayType
arrayTypeTraversal translateArrayType;
traverseMemoryPoolVisitorPattern(translateArrayType);
for(vector<SgArrayType*>::iterator i=arrayTypeList.begin(); i!=arrayTypeList.end(); ++i)
{
if(isLinearlizeArray)
{
linearizeArrayDeclaration(*i);
}
else
{
translateArrayDeclaration(*i);
}
}
// Traversal with Memory Pool to search for pntrArrRefExp
pntrArrRefTraversal translatePntrArrRefExp;
traverseMemoryPoolVisitorPattern(translatePntrArrRefExp);
for(vector<SgPntrArrRefExp*>::iterator i=pntrArrRefList.begin(); i!=pntrArrRefList.end(); ++i)
{
if(isLinearlizeArray)
{
linearizeArraySubscript(*i);
}
else
{
translateArraySubscript(*i);
}
}
Rose_STL_Container<SgNode*> functionList = NodeQuery::querySubTree (project,V_SgFunctionDeclaration);
for (Rose_STL_Container<SgNode*>::iterator i = functionList.begin(); i != functionList.end(); i++)
{
if((isSgProcedureHeaderStatement(*i) != NULL) ||
(isSgProgramHeaderStatement(*i) != NULL)){
SgFunctionDeclaration* functionBody = isSgFunctionDeclaration(*i);
bool hasReturnVal = false;
if(isSgProcedureHeaderStatement(functionBody))
{
hasReturnVal = isSgProcedureHeaderStatement(functionBody)->isFunction();
}
fixFortranSymbolTable(functionBody->get_definition(),hasReturnVal);
}
}
// Traversal with Memory Pool to search for equivalenceStatement
equivalencelTraversal translateEquivalenceStmt;
traverseMemoryPoolVisitorPattern(translateEquivalenceStmt);
for(vector<SgEquivalenceStatement*>::iterator i=equivalenceList.begin(); i!=equivalenceList.end(); ++i)
{
SgEquivalenceStatement* equivalenceStatement = isSgEquivalenceStatement(*i);
ROSE_ASSERT(equivalenceStatement);
translateEquivalenceStatement(equivalenceStatement);
statementList.push_back(equivalenceStatement);
removeList.push_back(equivalenceStatement);
}
// Simple traversal, bottom-up, to translate the rest
f2cTraversal f2c;
f2c.traverseInputFiles(project,postorder);
// removing all the unsed statement from AST
for(vector<SgStatement*>::iterator i=statementList.begin(); i!=statementList.end(); ++i)
{
removeStatement(*i);
(*i)->set_parent(NULL);
}
// deepDelete the removed nodes
for(vector<SgNode*>::iterator i=removeList.begin(); i!=removeList.end(); ++i)
{
deepDelete(*i);
}
/*
1. There should be no Fortran-specific AST nodes in the whole
AST graph after the translation.
TODO: make sure translator generating clean AST
*/
//generateDOT(*project);
if (SgProject::get_verbose() > 2)
generateAstGraph(project,8000);
return backend(project);
}