Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a library with C++ python extensions (C++ calls python which in turn calls C++) using boost::python and python libraries (this is messy, but a lot of it is legacy) which when tested standalone works correctly. In particular, a certain dynamic_cast works correctly.

But when the library is packaged for use as a plugin on RHEL5 using gcc 4.1.2 with an external application, the dynamic_cast returns NULL resulting in the application not working as expected. On Windows (tested Vista 64 bit using Visual Studio 2005 and 2008) it works fine. When I debugged using ddd for instance, I am able to see that the pointer before casting has the right type_name (slightly mangled by compiler as is usual, I suppose?). Any specific debugging tips here will also be of help.

A reinterpret_cast solved the problem. While this will be certainly baulked at, I am at a loss about how to proceed, esp. since this could be due to issues with the external app. It is a convoluted mess and almost seems futile, but if it can help here is some sample code. The following C++ snippet creates a "smart_handle" to queue certain python commands stored in string "input". The string IMPORT imports locations and definitions of some functions that are called by boost::python::exec(..) in the function call py_api::execute_py_command:

         processor(new my_derived_class());
std::map<std::string, smart_handle> context;
context.insert(std::make_pair<std::string, smart_handle>("default_queue", 
const std::string py_command =
       IMPORT + 
       "namesp.dialects.cpython.set_command_queue('default', default_queue)\n" + 
if( !py_api::execute_py_command(py_command, context) ) {
  return false; 

The make_smart_handle is defined as:

template <typename type_t> 
const smart_handle make_smart_handle(const boost::shared_ptr<type_t>& ptr) {
   if( !ptr ) {
      return smart_handle();
   return smart_handle(new detail::smart_handle_weak_impl<type_t>(ptr));

The function set_command_queue is defined in a python __init__.py as:

import func1 
import func2
import func3
import func4

def set_command_queue(queue_name, object):
COMMAND_QUEUE_MAP[queue_name] = object
def get_command_queue(queue_name = 'default'):
return COMMAND_QUEUE_MAP[queue_name]

Now the actual python functions func1, func2, etc. defined in separate python files calls C++ functions defined under namespace "namesp". The very first line of these C++ functions is to recover the "smart_handle" to the "queue" by:

boost::shared_ptr<my_base_class> queue = smart_handle_cast<my_base_class>(handle).lock();

It is in the above function smart_handle_cast that the dynamic_cast is used which returns NULL, when the library is used as a plugin in an external app. Using reinterpret_cast allows it to work correctly. The smart_handle_cast returns a const boost::weak_ptr. For those interested, here is the defintion of the smart_handle_cast<..>() function:

template <typename type_t> 
const boost::weak_ptr<type_t> smart_handle_cast(const smart_handle& handle, bool 
      throw_if_failure) {
   if( !handle.is_valid() ) {
       if( throw_if_failure ) {
          throw smart_handle::bad_handle("Bad handle, attempting to access an invalid 
       //-No throw version returns a non-initialized weak pointer
       return boost::weak_ptr<type_t>();
   //-This line fails at run time and returns null.
   const detail::smart_handle_weak_impl<type_t>* casted = dynamic_cast<const 
                   detail::smart_handle_weak_impl<type_t>* >(handle.impl());
   if( !casted ) {
       if( throw_if_failure ) {
           throw smart_handle::bad_handle_cast("Bad handle cast, attempting to \
              convert to incorrect pointee type");
       //-No throw version returns a non-initialized weak pointer
       return boost::weak_ptr<type_t>();
   return casted->pointee;
share|improve this question

1 Answer 1

up vote 0 down vote accepted

Take a look at similar question and GCC FAQ

If you use dlopen to explicitly load code from a shared library, you must do several things. First, export global symbols from the executable by linking it with the "-E" flag (you will have to specify this as "-Wl,-E" if you are invoking the linker in the usual manner from the compiler driver, g++). You must also make the external symbols in the loaded library available for subsequent libraries by providing the RTLD_GLOBAL flag to dlopen. The symbol resolution can be immediate or lazy.

share|improve this answer
Thanks very much. Under the circumstances, this is very useful information. –  squashed.bugaboo Feb 26 '11 at 20:48
Update.. it worked! Thanks a lot! –  squashed.bugaboo Mar 1 '11 at 2:42

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.