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'm trying to construct a map in shared memory of the following type

I create the shared memory region like this :

 managed_shared_memory segment(create_only ,"MyMap"  ,size);       

ShMemAllocator_t alloc_inst (segment.get_segment_manager());

 map =   segment.construct<MyMap_t>("MyMap")      

The values in the map are as follows:

       typedef pair<MutexType, boost::interprocess::offset_ptr<void> > ValueType ; 

MutexType is itself a structure containing a read and a write mutex (using read_lock and write_lock) ; defined as follows:

typedef struct  mutex_struct{ 
   sharable_lock<interprocess_mutex> read_lock(interprocess_mutex, defer_lock); 
  scoped_lock<interprocess_mutex> write_lock(interprocess_mutex, defer_lock); 
} MutexType;

"size" is the total size of the map (in terms of objects, so the sum of the data size pointed to by all the void pointers).

How can I ensure that this void* data is also located in this memory segment I created, how do I instantiate it within the existing shared memory region). The reason for doing this is that I want to allocate this large buffer once only but repeatedly removing/adding objects to it (the map models a cache) I have yet to find a way in which multiple objects can be allocated within the same memory segment within a map. Furthermore, seeking to allocate the MutexType pair returns a compilation error stating that no "call" operator is provided.

share|improve this question

2 Answers 2

up vote 11 down vote accepted

You are basically already there. Call whatever object type that you are allocating in shared memory SecondValue_t. Instead of ShMemAllocator_t, define a different interprocess allocator type, say SecondValueAllocator_t, for allocating the SecondValue_t objects. Whenever you want to insert a ValueType object into the map, the second value of the ValueType object is allocated with the SecondValueAllocator_t instance.

Here is a complete example, partly using the code in my answer for Interprocess reader/writer lock with Boost:

#include <cstdlib>
#include <functional>
#include <iostream>
#include <string>
#include <utility>

#include <boost/scope_exit.hpp>
#include <boost/interprocess/managed_shared_memory.hpp>
#include <boost/interprocess/allocators/allocator.hpp>
#include <boost/interprocess/allocators/private_node_allocator.hpp>
#include <boost/interprocess/containers/map.hpp>
#include <boost/interprocess/sync/interprocess_upgradable_mutex.hpp>
#include <boost/interprocess/sync/scoped_lock.hpp>
#include <boost/interprocess/sync/sharable_lock.hpp>
#include <boost/interprocess/sync/upgradable_lock.hpp>

#define SHARED_MEMORY_NAME "SO13783012-MyMap"

// http://stackoverflow.com/questions/13783012/map-of-int-void-in-shared-memory-using-boostinterprocess

using namespace boost::interprocess;

typedef int SecondValue_t;
typedef allocator<SecondValue_t, managed_shared_memory::segment_manager> SecondValueAllocator_t;

typedef struct mutex_struct {
} MutexType;

typedef std::pair<MutexType, SecondValueAllocator_t::pointer> ValueType;

typedef map<int, ValueType>::value_type MyMapValueType;
typedef allocator<MyMapValueType, managed_shared_memory::segment_manager> MyMapEntryAllocator_t;
typedef map<int, ValueType, std::less<int>, MyMapEntryAllocator_t> MyMap_t;

struct shared_data {
    typedef boost::interprocess::interprocess_upgradable_mutex upgradable_mutex_type;

    mutable upgradable_mutex_type mutex;
    MyMap_t my_map;

    shared_data(const MyMapEntryAllocator_t& alloc)
        : my_map(MyMap_t::key_compare(), alloc)

    // Tries to get the mapped value for the given key `k'. If successful, the mapped value is
    // copied into `out' and `true' is returned. Otherwise, returns `false' and does not modify
    // `out'.
    bool try_get(MyMap_t::mapped_type& out, MyMap_t::key_type k) const {
        boost::interprocess::sharable_lock<upgradable_mutex_type> lock(mutex);
        MyMap_t::const_iterator pos = my_map.find(k);
        if (pos != my_map.end()) {
            out = pos->second;
            return true;
        return false;

    void put(MyMap_t::key_type k, MyMap_t::mapped_type v) {
        boost::interprocess::scoped_lock<upgradable_mutex_type> lock(mutex);
        my_map.insert(MyMap_t::value_type(my_map.size(), v));

int main(int argc, char *argv[])
    if (argc != 2) {
        std::cerr << "Usage: " << argv[0] << " WHICH\n";
        return EXIT_FAILURE;

    const std::string which = argv[1];

    if (which == "parent") {
        BOOST_SCOPE_EXIT(argc) {
        managed_shared_memory shm(create_only, SHARED_MEMORY_NAME, 65536);

        MyMapEntryAllocator_t entry_alloc(shm.get_segment_manager());
        shared_data& d = *shm.construct<shared_data>("theSharedData")(entry_alloc);

        SecondValueAllocator_t second_value_alloc(shm.get_segment_manager());

        // Insert some test data.
        SecondValueAllocator_t::pointer p;
        p = second_value_alloc.allocate(1);
        second_value_alloc.construct(p, -3);
        d.put(0, std::make_pair(MutexType(), p));
        p = second_value_alloc.allocate(1);
        second_value_alloc.construct(p, 70);
        d.put(1, std::make_pair(MutexType(), p));
        p = second_value_alloc.allocate(1);
        second_value_alloc.construct(p, -18);
        d.put(2, std::make_pair(MutexType(), p));
        p = second_value_alloc.allocate(1);
        second_value_alloc.construct(p, 44);
        d.put(3, std::make_pair(MutexType(), p));
        p = second_value_alloc.allocate(1);
        second_value_alloc.construct(p, 0);
        d.put(4, std::make_pair(MutexType(), p));

        // Go to sleep for a minute - gives us a chance to start a child process.
    } else {
        managed_shared_memory shm(open_only, SHARED_MEMORY_NAME);
        std::pair<shared_data *, std::size_t> find_res = shm.find<shared_data>("theSharedData");
        if (!find_res.first) {
            std::cerr << "Failed to find `theSharedData'.\n";
            return EXIT_FAILURE;
        shared_data& d = *find_res.first;

        MyMap_t::mapped_type v;
        int i = 0;
        for (; d.try_get(v, i); ++i) {
            std::cout << i << ": " << *v.second << '\n';

        // Add an entry.
        SecondValueAllocator_t second_value_alloc(shm.get_segment_manager());
        SecondValueAllocator_t::pointer p = second_value_alloc.allocate(1);
        second_value_alloc.construct(p, (rand() % 200) - 100);
        d.put(i, v = std::make_pair(MutexType(), p));
        std::cout << "placed " << *v.second << " into the map.\n";

    return EXIT_SUCCESS;

Test it out by starting the parent process first:

./SO13783012 parent

Then some children:

./SO13783012 child

Sample output:

> ./SO13783012 child
0: -3
1: 70
2: -18
3: 44
4: 0
placed 5: -63 into the map.
> ./SO13783012 child
0: -3
1: 70
2: -18
3: 44
4: 0
5: -63
placed 6: -42 into the map.
> ./SO13783012 child
0: -3
1: 70
2: -18
3: 44
4: 0
5: -63
6: -42
placed 7: -28 into the map.
share|improve this answer
(I know this is a bit old but) I noticed that the writer lock does not really work in your example. If you spawn multiple writer childs the value of i could be undefined and you would try to insert a pair using the same value, due concurrency issues - If that example just should show adding another entry after the last key - than the put method should gather the current size of the map and insert the element at size+1. –  Steve Jan 13 '14 at 21:07
Hi @Steve, I'm not sure I follow. Why would the value of i be undefined? –  Daniel Trebbien Jan 14 '14 at 0:04
In the for loop - you count ++i till no value is returned from d.try_get - lets assume i is now 10. Later on, you try to put the key i=10 with d.put(i, v = std::make_pair(MutexType(), p));. If meanwhile another child write process already put something into the map - 10 would be a duplicate. Just assume 2 child writers - each executing one line at a time - both arrive at i=10, but child1 puts a new entry first with i=10 - thus the second child will fail. Thats because i=10 is outside of any write/read lock –  Steve Jan 14 '14 at 0:50
@Steve: Ah! Yes, you are right. Thank you for pointing this out. –  Daniel Trebbien Jan 15 '14 at 12:16

You can use rebind in allocator<>

//    convert an allocator<T> to allocator<U>
template<typename U>
struct rebind {
    typedef Allocator<U> other;

to make an

typedef std::allocator< char, managed_shared_memory::segment_manager > char_alloc;

then allocate your memory like this

char_alloc char_alloc_obj;
char * ptr = new (char_alloc_obj.allocate(size)) char[size];
void * vptr = (void *) ptr;

The default std::allocator<> is state less. The shared memory allocator will have state so you need to figure out how to copy the state between allocators of different types.

share|improve this answer

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.