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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")      
                             (std::less<int>() 
                             ,alloc_inst); 

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.

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2 Answers 2

up vote 8 down vote accepted
+50

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 {
private:
    typedef boost::interprocess::interprocess_upgradable_mutex upgradable_mutex_type;

    mutable upgradable_mutex_type mutex;
    MyMap_t my_map;

public:
    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") {
        shared_memory_object::remove(SHARED_MEMORY_NAME);
        BOOST_SCOPE_EXIT(argc) {
            shared_memory_object::remove(SHARED_MEMORY_NAME);
        } BOOST_SCOPE_EXIT_END;
        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.
        sleep(60);
    } 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.
        srand(time(NULL));
        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 at 21:07
    
Hi @Steve, I'm not sure I follow. Why would the value of i be undefined? –  Daniel Trebbien Jan 14 at 0:04
1  
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 at 0:50
    
@Steve: Ah! Yes, you are right. Thank you for pointing this out. –  Daniel Trebbien Jan 15 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.

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