boost/compute/random/linear_congruential_engine.hpp
//---------------------------------------------------------------------------// // Copyright (c) 2014 Roshan <thisisroshansmail@gmail.com> // // Distributed under the Boost Software License, Version 1.0 // See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt // // See http://boostorg.github.com/compute for more information. //---------------------------------------------------------------------------// #ifndef BOOST_COMPUTE_RANDOM_LINEAR_CONGRUENTIAL_ENGINE_HPP #define BOOST_COMPUTE_RANDOM_LINEAR_CONGRUENTIAL_ENGINE_HPP #include <algorithm> #include <boost/compute/types.hpp> #include <boost/compute/buffer.hpp> #include <boost/compute/kernel.hpp> #include <boost/compute/context.hpp> #include <boost/compute/program.hpp> #include <boost/compute/command_queue.hpp> #include <boost/compute/algorithm/transform.hpp> #include <boost/compute/container/vector.hpp> #include <boost/compute/detail/iterator_range_size.hpp> #include <boost/compute/iterator/discard_iterator.hpp> #include <boost/compute/utility/program_cache.hpp> namespace boost { namespace compute { /// /// \class linear_congruential_engine /// \brief 'Quick and Dirty' linear congruential engine /// /// Quick and dirty linear congruential engine to generate low quality /// random numbers very quickly. For uses in which good quality of random /// numbers is required(Monte-Carlo Simulations), use other engines like /// Mersenne Twister instead. /// template<class T = uint_> class linear_congruential_engine { public: typedef T result_type; static const T default_seed = 1; static const T a = 1099087573; static const size_t threads = 1024; /// Creates a new linear_congruential_engine and seeds it with \p value. explicit linear_congruential_engine(command_queue &queue, result_type value = default_seed) : m_context(queue.get_context()), m_multiplicands(m_context, threads * sizeof(result_type)) { // setup program load_program(); // seed state seed(value, queue); // generate multiplicands generate_multiplicands(queue); } /// Creates a new linear_congruential_engine object as a copy of \p other. linear_congruential_engine(const linear_congruential_engine<T> &other) : m_context(other.m_context), m_program(other.m_program), m_seed(other.m_seed), m_multiplicands(other.m_multiplicands) { } /// Copies \p other to \c *this. linear_congruential_engine<T>& operator=(const linear_congruential_engine<T> &other) { if(this != &other){ m_context = other.m_context; m_program = other.m_program; m_seed = other.m_seed; m_multiplicands = other.m_multiplicands; } return *this; } /// Destroys the linear_congruential_engine object. ~linear_congruential_engine() { } /// Seeds the random number generator with \p value. /// /// \param value seed value for the random-number generator /// \param queue command queue to perform the operation /// /// If no seed value is provided, \c default_seed is used. void seed(result_type value, command_queue &queue) { (void) queue; m_seed = value; } /// \overload void seed(command_queue &queue) { seed(default_seed, queue); } /// Generates random numbers and stores them to the range [\p first, \p last). template<class OutputIterator> void generate(OutputIterator first, OutputIterator last, command_queue &queue) { size_t size = detail::iterator_range_size(first, last); kernel fill_kernel(m_program, "fill"); fill_kernel.set_arg(1, m_multiplicands); fill_kernel.set_arg(2, first.get_buffer()); size_t offset = 0; for(;;){ size_t count = 0; if(size > threads){ count = (std::min)(static_cast<size_t>(threads), size - offset); } else { count = size; } fill_kernel.set_arg(0, static_cast<const uint_>(m_seed)); fill_kernel.set_arg(3, static_cast<const uint_>(offset)); queue.enqueue_1d_range_kernel(fill_kernel, 0, count, 0); offset += count; if(offset >= size){ break; } update_seed(queue); } } /// \internal_ void generate(discard_iterator first, discard_iterator last, command_queue &queue) { (void) queue; size_t size = detail::iterator_range_size(first, last); uint_ max_mult = detail::read_single_value<T>(m_multiplicands, threads-1, queue); while(size >= threads) { m_seed *= max_mult; size -= threads; } m_seed *= detail::read_single_value<T>(m_multiplicands, size-1, queue); } /// Generates random numbers, transforms them with \p op, and then stores /// them to the range [\p first, \p last). template<class OutputIterator, class Function> void generate(OutputIterator first, OutputIterator last, Function op, command_queue &queue) { vector<T> tmp(std::distance(first, last), queue.get_context()); generate(tmp.begin(), tmp.end(), queue); transform(tmp.begin(), tmp.end(), first, op, queue); } /// Generates \p z random numbers and discards them. void discard(size_t z, command_queue &queue) { generate(discard_iterator(0), discard_iterator(z), queue); } private: /// \internal_ /// Generates the multiplicands for each thread void generate_multiplicands(command_queue &queue) { kernel multiplicand_kernel = m_program.create_kernel("multiplicand"); multiplicand_kernel.set_arg(0, m_multiplicands); queue.enqueue_task(multiplicand_kernel); } /// \internal_ void update_seed(command_queue &queue) { m_seed *= detail::read_single_value<T>(m_multiplicands, threads-1, queue); } /// \internal_ void load_program() { boost::shared_ptr<program_cache> cache = program_cache::get_global_cache(m_context); std::string cache_key = std::string("__boost_linear_congruential_engine_") + type_name<T>(); const char source[] = "__kernel void multiplicand(__global uint *multiplicands)\n" "{\n" " uint a = 1099087573;\n" " multiplicands[0] = a;\n" " for(uint i = 1; i < 1024; i++){\n" " multiplicands[i] = a * multiplicands[i-1];\n" " }\n" "}\n" "__kernel void fill(const uint seed,\n" " __global uint *multiplicands,\n" " __global uint *result," " const uint offset)\n" "{\n" " const uint i = get_global_id(0);\n" " result[offset+i] = seed * multiplicands[i];\n" "}\n"; m_program = cache->get_or_build(cache_key, std::string(), source, m_context); } private: context m_context; program m_program; T m_seed; buffer m_multiplicands; }; } // end compute namespace } // end boost namespace #endif // BOOST_COMPUTE_RANDOM_LINEAR_CONGRUENTIAL_ENGINE_HPP