I want access a STL based container read-only from parallel running threads. Without using any user implemented locking. The base of the following code is C++11 with a proper implementation of the standard.

http://www.open-std.org/jtc1/sc22/wg21/ (current draft or N3337, which is essentially C++11 with minor errors and typos corrected)

23.2.2 Container data races [container.requirements.dataraces]

For purposes of avoiding data races (, implementations shall consider the following functions to be const: begin, end, rbegin, rend, front, back, data, find, lower_bound, upper_bound, equal_range, at and, except in associative or unordered associative containers, operator[].

Notwithstanding (, implementations are required to avoid data races when the contents of the con- tained object in different elements in the same sequence, excepting vector<bool>, are modified concurrently.

[ Note: For a vector<int> x with a size greater than one, x[1] = 5 and *x.begin() = 10 can be executed concurrently without a data race, but x[0] = 5 and *x.begin() = 10 executed concurrently may result in a data race. As an exception to the general rule, for a vector<bool> y, y[0] = true may race with y[1] = true. — end note ]

and Data race avoidance [res.on.data.races] 1 This section specifies requirements that implementations shall meet to prevent data races (1.10). Every standard library function shall meet each requirement unless otherwise specified. Implementations may prevent data races in cases other than those specified below.

2 A C++ standard library function shall not directly or indirectly access objects (1.10) accessible by threads other than the current thread unless the objects are accessed directly or indirectly via the function’s argu- ments, including this.

3 A C++ standard library function shall not directly or indirectly modify objects (1.10) accessible by threads other than the current thread unless the objects are accessed directly or indirectly via the function’s non-const arguments, including this.

4 [ Note: This means, for example, that implementations can’t use a static object for internal purposes without synchronization because it could cause a data race even in programs that do not explicitly share objects between threads. — end note ]

5 A C++ standard library function shall not access objects indirectly accessible via its arguments or via elements of its container arguments except by invoking functions required by its specification on those container elements.

6 Operations on iterators obtained by calling a standard library container or string member function may
access the underlying container, but shall not modify it. [ Note: In particular, container operations that invalidate iterators conflict with operations on iterators associated with that container. — end note ]

7 Implementations may share their own internal objects between threads if the objects are not visible to users and are protected against data races.

8 Unless otherwise specified, C++ standard library functions shall perform all operations solely within the current thread if those operations have effects that are visible (1.10) to users.

9 [ Note: This allows implementations to parallelize operations if there are no visible side effects. — end note ]

Containers are not thread safe! But it is safe to call const functions on containers from multiple parallel threads. So it is possible to do read-only operations from parallel threads without locking. Am I right?

I pretend that their doesn't exist any faulty implementation and every implementation of the C++11 standard is correct.


// concurrent thread access to a stl container
// g++ -std=gnu++11 -o p_read p_read.cpp -pthread -Wall -pedantic && ./p_read
#include <iostream>
#include <iomanip>
#include <string>
#include <unistd.h>

#include <thread>
#include <mutex>

#include <map>

#include <cstdlib>
#include <ctime>
using namespace std;

// new in C++11
using str_map = map<string, string>;

// thread is new in C++11
// to_string() is new in C++11

mutex m;
const unsigned int MAP_SIZE = 10000;

void fill_map(str_map& store) {
    int key_nr;
    string mapped_value;
    string key;

    while (store.size() < MAP_SIZE) {
        // 0 - 9999
        key_nr = rand() % MAP_SIZE;

        // convert number to string
        mapped_value = to_string(key_nr);
        key = "key_" + mapped_value;

        pair<string, string> value(key, mapped_value);

void print_map(const str_map& store) {
    str_map::const_iterator it = store.begin();

    while (it != store.end()) {
        pair<string, string> value = *it;
        cout << left << setw(10) << value.first << right << setw(5) << value.second << "\n";

void search_map(const str_map& store, int thread_nr) {
    cout << "thread(" << thread_nr << ") launched\n";

    // use a straight search or poke around random
    bool straight = false;
    if ((thread_nr % 2) == 0) {
        straight = true;

    int key_nr;
    string mapped_value;
    string key;
    str_map::const_iterator it;

    string first;
    string second;

    for (unsigned int i = 0; i < MAP_SIZE; i++) {

        if (straight) {
            key_nr = i;
        } else {
            // 0 - 9999, rand is not thread-safe, nrand48 is an alternative             
            key_nr = rand() % MAP_SIZE;

        // convert number to string
        mapped_value = to_string(key_nr);
        key = "key_" + mapped_value;

        it = store.find(key);

        // check result
        if (it != store.end()) {
            // pair
            first = it->first;
            second = it->second;

            // m.lock();
            // cout << "thread(" << thread_nr << ") " << key << ": "
            //      << right << setw(10) << first << setw(5) << second << "\n"; 
            // m.unlock();

            // check mismatch
            if (key != first || mapped_value != second) {
                cerr << key << ": " << first << second << "\n"
                     << "Mismatch in thread(" << thread_nr << ")!\n";

                // never reached
        } else {
            cerr << "Warning: key(" << key << ") not found in thread("
                 << thread_nr << ")\n";

            // never reached

int main() {
    clock_t start, end;
    start = clock();

    str_map store;

    cout << "fill_map finished\n";

    // print_map(store);
    // cout << "print_map finished\n";

    // copy for check
    str_map copy_store = store;

    // launch threads
    thread t[10];
    for (int i = 0; i < 10; i++) {
        t[i] = thread(search_map, store, i);

    // wait for finish
    for (int i = 0; i < 10; i++) {
    cout << "search_map threads finished\n";

    if (store == copy_store) {
        cout << "equal\n";
    } else {
        cout << "not equal\n";

    end = clock();
    cout << "CLOCKS_PER_SEC " << CLOCKS_PER_SEC << "\n";
    cout << "CPU-TIME START " << start << "\n";
    cout << "CPU-TIME END " << end << "\n";
    cout << "CPU-TIME END - START " << end - start << "\n";
    cout << "TIME(SEC) " << static_cast<double>(end - start) / CLOCKS_PER_SEC << "\n";

    return 0;

This code can be compiled with GCC 4.7 and runs fine on my machine.

$ echo $?
$ 0

  • In a nutshell: If you never mutate the container itself, and if each thread accesses a distinct container element, then you're fine. If you don't have the latter guarantee, you need to equip each element with its own synchronization mechanics. – Kerrek SB May 31 '12 at 12:25
  • 1
    A const method is still allowed to write to fields with the mutable keyword, no? – mkb May 31 '12 at 12:26
  • 3
    @mkb Yes, but the idea behind the STL containers is that there shouldn't be any "state" variables like that, and if there are, that there is then an explicit synchronization mechanism in-place to protect the underlying mutable variables. In other words the end-user should be able to use the container as a "black-box", and assume that if there are no data-races on the "black-box" container, then there are no data-races in the container itself. – Jason May 31 '12 at 12:32
  • 2
    @Jason explains it nicely, I would only add two points: (1) the requirements don't only apply to containers, but to all standard library types; (2) not only must the library use appropriate synchronisation to ensure any modification to mutable state done by const operations is race-free, but must also synchronise any modifications to static data and other state shared between distinct objects, so that writes to distinct objects are race-free, even if they happen to share state behind the scenes. – Jonathan Wakely May 31 '12 at 18:16

A data-race, from the C++11 specification in sections 1.10/4 and 1.10/21, requires at least two threads with non-atomic access to the same set of memory locations, the two threads are not synchronized with regards to accessing the set of memory locations, and at least one thread writes to or modifies an element in the set of memory locations. So in your case, if the threads are only reading, you are fine ... by definition since none of the threads write to the same set of memory locations, there are no data-races even though there is no explicit synchronization mechanism between the threads.

  • Thanks you! Glad to hear this :-) – Peter Jun 1 '12 at 7:34
  • Jason, who is to say that a const method won't write to anything? – Mehrdad Jul 2 '15 at 11:19
  • A const method is not supposed to modify the object ... that being said, it can write to something, but to avoid a data-race you can't write to same memory "location". Two different threads writing to two completely different memory locations (what that exactly entails is dependent on the hardware architecture) does not define a data-race. – Jason Jul 2 '15 at 15:24

Yes, you are right. You are safe as long as the thread that populates your vector finishes doing so before the reader threads start. There was a similar question recently.

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