25 Algorithms library [algorithms]

25.2 Parallel algorithms [algorithms.parallel]

25.2.3 Effect of execution policies on algorithm execution [algorithms.parallel.exec]

Parallel algorithms have template parameters named ExecutionPolicy ([execpol]) which describe the manner in which the execution of these algorithms may be parallelized and the manner in which they apply the element access functions.

The invocations of element access functions in parallel algorithms invoked with an execution policy object of type execution::sequenced_policy all occur in the calling thread of execution. [ Note: The invocations are not interleaved; see [intro.execution].  — end note ]

The invocations of element access functions in parallel algorithms invoked with an execution policy object of type execution::parallel_policy are permitted to execute in either the invoking thread of execution or in a thread of execution implicitly created by the library to support parallel algorithm execution. If the threads of execution created by thread ([thread.thread.class]) provide concurrent forward progress guarantees ([intro.progress]), then a thread of execution implicitly created by the library will provide parallel forward progress guarantees; otherwise, the provided forward progress guarantee is implementation-defined. Any such invocations executing in the same thread of execution are indeterminately sequenced with respect to each other. [ Note: It is the caller's responsibility to ensure that the invocation does not introduce data races or deadlocks.  — end note ] [ Example:

int a[] = {0,1};
std::vector<int> v;
std::for_each(std::execution::par, std::begin(a), std::end(a), [&](int i) {
  v.push_back(i*2+1); // incorrect: data race
});

The program above has a data race because of the unsynchronized access to the container v.  — end example ] [ Example:

std::atomic<int> x{0};
int a[] = {1,2};
std::for_each(std::execution::par, std::begin(a), std::end(a), [&](int) {
  x.fetch_add(1, std::memory_order_relaxed);
  // spin wait for another iteration to change the value of x
  while (x.load(std::memory_order_relaxed) == 1) { } // incorrect: assumes execution order
});

The above example depends on the order of execution of the iterations, and will not terminate if both iterations are executed sequentially on the same thread of execution.  — end example ] [ Example:

int x = 0;
std::mutex m;
int a[] = {1,2};
std::for_each(std::execution::par, std::begin(a), std::end(a), [&](int) {
  std::lock_guard<mutex> guard(m);
  ++x;
});

The above example synchronizes access to object x ensuring that it is incremented correctly.  — end example ]

The invocations of element access functions in parallel algorithms invoked with an execution policy of type execution::parallel_unsequenced_policy are permitted to execute in an unordered fashion in unspecified threads of execution, and unsequenced with respect to one another within each thread of execution. These threads of execution are either the invoking thread of execution or threads of execution implicitly created by the library; the latter will provide weakly parallel forward progress guarantees. [ Note: This means that multiple function object invocations may be interleaved on a single thread of execution, which overrides the usual guarantee from [intro.execution] that function executions do not interleave with one another.  — end note ] Since execution::parallel_unsequenced_policy allows the execution of element access functions to be interleaved on a single thread of execution, blocking synchronization, including the use of mutexes, risks deadlock. Thus, the synchronization with execution::parallel_unsequenced_policy is restricted as follows: A standard library function is vectorization-unsafe if it is specified to synchronize with another function invocation, or another function invocation is specified to synchronize with it, and if it is not a memory allocation or deallocation function. Vectorization-unsafe standard library functions may not be invoked by user code called from execution::parallel_unsequenced_policy algorithms. [ Note: Implementations must ensure that internal synchronization inside standard library routines does not prevent forward progress when those routines are executed by threads of execution with weakly parallel forward progress guarantees.  — end note ] [ Example:

int x = 0;
std::mutex m;
int a[] = {1,2};
std::for_each(std::execution::par_unseq, std::begin(a), std::end(a), [&](int) {
  std::lock_guard<mutex> guard(m); // incorrect: lock_guard constructor calls m.lock()
  ++x;
});

The above program may result in two consecutive calls to m.lock() on the same thread of execution (which may deadlock), because the applications of the function object are not guaranteed to run on different threads of execution.  — end example ] [ Note: The semantics of the execution::parallel_policy or the execution::parallel_unsequenced_policy invocation allow the implementation to fall back to sequential execution if the system cannot parallelize an algorithm invocation due to lack of resources.  — end note ]

If an invocation of a parallel algorithm uses threads of execution implicitly created by the library, then the invoking thread of execution will either

  • temporarily block with forward progress guarantee delegation ([intro.progress]) on the completion of these library-managed threads of execution, or

  • eventually execute an element access function;

the thread of execution will continue to do so until the algorithm is finished. [ Note: In blocking with forward progress guarantee delegation in this context, a thread of execution created by the library is considered to have finished execution as soon as it has finished the execution of the particular element access function that the invoking thread of execution logically depends on.  — end note ]

The semantics of parallel algorithms invoked with an execution policy object of implementation-defined type are implementation-defined.