std::experimental::parallel::transform_reduce (3) Linux Manual Page
std::experimental::parallel::transform_reduce – std::experimental::parallel::transform_reduce
Synopsis
Defined in header <experimental/numeric>
template<class InputIt, class UnaryOp, class T, class BinaryOp>
T transform_reduce(InputIt first, InputIt last, (1) (parallelism TS)
UnaryOp unary_op, T init, BinaryOp binary_op);
template<class ExecutionPolicy,
class InputIt, class UnaryOp, class T, class BinaryOp>
T transform_reduce(ExecutionPolicy&& policy, (2) (parallelism TS)
InputIt first, InputIt last,
UnaryOp unary_op, T init, BinaryOp binary_op);Applies unary_op to each element in the range [first; last) and reduces the results (possibly permuted and aggregated in unspecified manner) along with the initial value init over binary_op.
The behavior is non-deterministic if binary_op is not associative or not commutative.
The behavior is undefined if unary_op or binary_op modifies any element or invalidates any iterator in [first; last).
Parameters
first, last – the range of elements to apply the algorithm to
init – the initial value of the generalized sum
policy – the execution_policy
unary_op – unary FunctionObject that will be applied to each element of the input range. The return type must be acceptable as input to binary_op
binary_op – binary FunctionObject that will be applied in unspecified order to the results of unary_op, the results of other binary_op and init.
Type requirements
–
InputIt must meet the requirements of LegacyInputIterator.
Return value
Generalized sum of init and unary_op(*first), unary_op(*(first+1)), … unary_op(*(last-1)) over binary_op,
where generalized sum GSUM(op, a
1, …, a
N) is defined as follows:
* if N=1, a
1
* if N > 1, op(GSUM(op, b
1, ..., b
K), GSUM(op, b
M, ..., b
N)) where
* b
1, ..., b
N may be any permutation of a1, ..., aN and
* 1 < K+1 = M ≤ N
in other words, the results of unary_op may be grouped and arranged in arbitrary order.
Complexity
O(last – first) applications each of unary_op and binary_op.
Exceptions
* If execution of a function invoked as part of the algorithm throws an exception,
* If the algorithm fails to allocate memory (either for itself or to construct an exception_list when handling a user exception), std::bad_alloc is thrown.
Notes
unary_op is not applied to init
If the range is empty, init is returned, unmodified
* If policy is an instance of sequential_execution_policy, all operations are performed in the calling thread.
* If policy is an instance of parallel_execution_policy, operations may be performed in unspecified number of threads, indeterminately sequenced with each other
* If policy is an instance of parallel_vector_execution_policy, execution may be both parallelized and vectorized: function body boundaries are not respected and user code may be overlapped and combined in arbitrary manner (in particular, this implies that a user-provided Callable must not acquire a mutex to access a shared resource)
Example
transform_reduce can be used to parallelize std::inner_product:
// Run this code
#include <vector>
#include <iterator>
#include <functional>
#include <iostream>
#include <experimental/numeric>
#include <experimental/execution_policy>
#include <boost/iterator/zip_iterator.hpp>
#include <boost/tuple.hpp>
int main()
{
std::vector<double> xvalues(10007, 1.0), yvalues(10007, 1.0);
double result = std::experimental::parallel::transform_reduce(
std::experimental::parallel::par,
boost::iterators::make_zip_iterator(
boost::make_tuple(std::begin(xvalues), std::begin(yvalues))),
boost::iterators::make_zip_iterator(
boost::make_tuple(std::end(xvalues), std::end(yvalues))),
[](auto r) { return boost::get<0>(r) * boost::get<1>(r); } 0.0,
std::plus<>());
std::cout << result << '\n';
}
Output:
See also
accumulate (function template)
transform (function template)
reduce similar to std::accumulate, except out of order
(parallelism TS)