/* Copyright 2005-2014 Intel Corporation. All Rights Reserved. This file is part of Threading Building Blocks. Threading Building Blocks is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License version 2 as published by the Free Software Foundation. Threading Building Blocks is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with Threading Building Blocks; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA As a special exception, you may use this file as part of a free software library without restriction. Specifically, if other files instantiate templates or use macros or inline functions from this file, or you compile this file and link it with other files to produce an executable, this file does not by itself cause the resulting executable to be covered by the GNU General Public License. This exception does not however invalidate any other reasons why the executable file might be covered by the GNU General Public License. */ #ifndef __TBB_partitioner_H #define __TBB_partitioner_H #ifndef __TBB_INITIAL_CHUNKS #define __TBB_INITIAL_CHUNKS 2 #endif #ifndef __TBB_RANGE_POOL_CAPACITY #define __TBB_RANGE_POOL_CAPACITY 8 #endif #ifndef __TBB_INIT_DEPTH #define __TBB_INIT_DEPTH 5 #endif #include "task.h" #include "aligned_space.h" #include "atomic.h" #if defined(_MSC_VER) && !defined(__INTEL_COMPILER) // Workaround for overzealous compiler warnings #pragma warning (push) #pragma warning (disable: 4244) #endif namespace tbb { class auto_partitioner; class simple_partitioner; class affinity_partitioner; namespace interface6 { namespace internal { class affinity_partition_type; } } namespace internal { //< @cond INTERNAL size_t __TBB_EXPORTED_FUNC get_initial_auto_partitioner_divisor(); //! Defines entry point for affinity partitioner into tbb run-time library. class affinity_partitioner_base_v3: no_copy { friend class tbb::affinity_partitioner; friend class tbb::interface6::internal::affinity_partition_type; //! Array that remembers affinities of tree positions to affinity_id. /** NULL if my_size==0. */ affinity_id* my_array; //! Number of elements in my_array. size_t my_size; //! Zeros the fields. affinity_partitioner_base_v3() : my_array(NULL), my_size(0) {} //! Deallocates my_array. ~affinity_partitioner_base_v3() {resize(0);} //! Resize my_array. /** Retains values if resulting size is the same. */ void __TBB_EXPORTED_METHOD resize( unsigned factor ); }; //! Provides backward-compatible methods for partition objects without affinity. class partition_type_base { public: void set_affinity( task & ) {} void note_affinity( task::affinity_id ) {} task* continue_after_execute_range() {return NULL;} bool decide_whether_to_delay() {return false;} void spawn_or_delay( bool, task& b ) { task::spawn(b); } }; template class start_scan; } //< namespace internal @endcond namespace serial { namespace interface6 { template class start_for; } } namespace interface6 { //! @cond INTERNAL namespace internal { using namespace tbb::internal; template class start_for; template class start_reduce; //! Join task node that contains shared flag for stealing feedback class flag_task: public task { public: tbb::atomic my_child_stolen; flag_task() { my_child_stolen = false; } task* execute() { return NULL; } static void mark_task_stolen(task &t) { tbb::atomic &flag = static_cast(t.parent())->my_child_stolen; #if TBB_USE_THREADING_TOOLS // Threading tools respect lock prefix but report false-positive data-race via plain store flag.fetch_and_store(true); #else flag = true; #endif //TBB_USE_THREADING_TOOLS } static bool is_peer_stolen(task &t) { return static_cast(t.parent())->my_child_stolen; } }; //! Depth is a relative depth of recursive division inside a range pool. Relative depth allows //! infinite absolute depth of the recursion for heavily imbalanced workloads with range represented //! by a number that cannot fit into machine word. typedef unsigned char depth_t; //! Range pool stores ranges of type T in a circular buffer with MaxCapacity template class range_vector { depth_t my_head; depth_t my_tail; depth_t my_size; depth_t my_depth[MaxCapacity]; // relative depths of stored ranges tbb::aligned_space my_pool; public: //! initialize via first range in pool range_vector(const T& elem) : my_head(0), my_tail(0), my_size(1) { my_depth[0] = 0; new( my_pool.begin() ) T(elem);//TODO: std::move? } ~range_vector() { while( !empty() ) pop_back(); } bool empty() const { return my_size == 0; } depth_t size() const { return my_size; } //! Populates range pool via ranges up to max depth or while divisible //! max_depth starts from 0, e.g. value 2 makes 3 ranges in the pool up to two 1/4 pieces void split_to_fill(depth_t max_depth) { while( my_size < MaxCapacity && my_depth[my_head] < max_depth && my_pool.begin()[my_head].is_divisible() ) { depth_t prev = my_head; my_head = (my_head + 1) % MaxCapacity; new(my_pool.begin()+my_head) T(my_pool.begin()[prev]); // copy TODO: std::move? my_pool.begin()[prev].~T(); // instead of assignment new(my_pool.begin()+prev) T(my_pool.begin()[my_head], split()); // do 'inverse' split my_depth[my_head] = ++my_depth[prev]; my_size++; } } void pop_back() { __TBB_ASSERT(my_size > 0, "range_vector::pop_back() with empty size"); my_pool.begin()[my_head].~T(); my_size--; my_head = (my_head + MaxCapacity - 1) % MaxCapacity; } void pop_front() { __TBB_ASSERT(my_size > 0, "range_vector::pop_front() with empty size"); my_pool.begin()[my_tail].~T(); my_size--; my_tail = (my_tail + 1) % MaxCapacity; } T& back() { __TBB_ASSERT(my_size > 0, "range_vector::back() with empty size"); return my_pool.begin()[my_head]; } T& front() { __TBB_ASSERT(my_size > 0, "range_vector::front() with empty size"); return my_pool.begin()[my_tail]; } //! similarly to front(), returns depth of the first range in the pool depth_t front_depth() { __TBB_ASSERT(my_size > 0, "range_vector::front_depth() with empty size"); return my_depth[my_tail]; } }; //! Provides default methods for partition objects and common algorithm blocks. template struct partition_type_base { // decision makers void set_affinity( task & ) {} void note_affinity( task::affinity_id ) {} bool check_being_stolen(task &) { return false; } // part of old should_execute_range() bool check_for_demand(task &) { return false; } bool is_divisible() { return true; } // part of old should_execute_range() depth_t max_depth() { return 0; } void align_depth(depth_t) { } // common function blocks Partition& self() { return *static_cast(this); } // CRTP helper template void execute(StartType &start, Range &range) { // The algorithm in a few words ([]-denotes calls to decision methods of partitioner): // [If this task is stolen, adjust depth and divisions if necessary, set flag]. // If range is divisible { // Spread the work while [initial divisions left]; // Create trap task [if necessary]; // } // If not divisible or [max depth is reached], execute, else do the range pool part if ( range.is_divisible() ) { if ( self().is_divisible() ) do start.offer_work( split() ); // split until is divisible while ( range.is_divisible() && self().is_divisible() ); } if( !range.is_divisible() || !self().max_depth() ) start.run_body( range ); // simple partitioner goes always here else { // do range pool internal::range_vector range_pool(range); do { range_pool.split_to_fill(self().max_depth()); // fill range pool if( self().check_for_demand( start ) ) { if( range_pool.size() > 1 ) { start.offer_work( range_pool.front(), range_pool.front_depth() ); range_pool.pop_front(); continue; } if( range_pool.back().is_divisible() ) // was not enough depth to fork a task continue; // note: check_for_demand() should guarantee increasing max_depth() next time } start.run_body( range_pool.back() ); range_pool.pop_back(); } while( !range_pool.empty() && !start.is_cancelled() ); } } }; //! Provides default methods for auto (adaptive) partition objects. template struct auto_partition_type_base : partition_type_base { size_t my_divisor; depth_t my_max_depth; auto_partition_type_base() : my_max_depth(__TBB_INIT_DEPTH) { my_divisor = tbb::internal::get_initial_auto_partitioner_divisor()*__TBB_INITIAL_CHUNKS/4; __TBB_ASSERT(my_divisor, "initial value of get_initial_auto_partitioner_divisor() is not valid"); } auto_partition_type_base(auto_partition_type_base &src, split) { my_max_depth = src.my_max_depth; #if __TBB_INITIAL_TASK_IMBALANCE if( src.my_divisor <= 1 ) my_divisor = 0; else my_divisor = src.my_divisor = (src.my_divisor+1u) / 2u; #else my_divisor = src.my_divisor / 2u; src.my_divisor = src.my_divisor - my_divisor; // TODO: check the effect separately if(my_divisor) src.my_max_depth += static_cast(__TBB_Log2(src.my_divisor/my_divisor)); #endif } bool check_being_stolen( task &t) { // part of old should_execute_range() if( !my_divisor ) { // if not from the top P tasks of binary tree my_divisor = 1; // TODO: replace by on-stack flag (partition_state's member)? if( t.is_stolen_task() ) { #if TBB_USE_EXCEPTIONS // RTTI is available, check whether the cast is valid __TBB_ASSERT(dynamic_cast(t.parent()), 0); // correctness of the cast relies on avoiding the root task for which: // - initial value of my_divisor != 0 (protected by separate assertion) // - is_stolen_task() always returns false for the root task. #endif flag_task::mark_task_stolen(t); my_max_depth++; return true; } } return false; } bool is_divisible() { // part of old should_execute_range() if( my_divisor > 1 ) return true; if( my_divisor && my_max_depth > 1 ) { // can split the task and once more internally. TODO: on-stack flag instead // keep same fragmentation while splitting for the local task pool my_max_depth--; my_divisor = 0; // decrease max_depth once per task return true; } else return false; } bool check_for_demand(task &t) { if( flag_task::is_peer_stolen(t) ) { my_max_depth++; return true; } else return false; } void align_depth(depth_t base) { __TBB_ASSERT(base <= my_max_depth, 0); my_max_depth -= base; } depth_t max_depth() { return my_max_depth; } }; //! Provides default methods for affinity (adaptive) partition objects. class affinity_partition_type : public auto_partition_type_base { static const unsigned factor_power = 4; static const unsigned factor = 1< factor ) d &= 0u-factor; map_mid = map_end - d; } public: affinity_partition_type( tbb::internal::affinity_partitioner_base_v3& ap ) { __TBB_ASSERT( (factor&(factor-1))==0, "factor must be power of two" ); ap.resize(factor); my_array = ap.my_array; map_begin = 0; map_end = unsigned(ap.my_size); set_mid(); my_delay = true; my_divisor /= __TBB_INITIAL_CHUNKS; // let exactly P tasks to be distributed across workers my_max_depth = factor_power+1; // the first factor_power ranges will be spawned, and >=1 ranges should be left __TBB_ASSERT( my_max_depth < __TBB_RANGE_POOL_CAPACITY, 0 ); } affinity_partition_type(affinity_partition_type& p, split) : auto_partition_type_base(p, split()), my_array(p.my_array) { __TBB_ASSERT( p.map_end-p.map_begin__TBB_Log2(map_end-map_mid), 0); return true;// do not do my_max_depth++ here, but be sure my_max_depth is big enough } if( flag_task::is_peer_stolen(t) ) { my_max_depth++; return true; } } else my_delay = false; return false; } bool is_divisible() { return my_divisor > 1; } static const unsigned range_pool_size = __TBB_RANGE_POOL_CAPACITY; }; class auto_partition_type: public auto_partition_type_base { public: auto_partition_type( const auto_partitioner& ) {} auto_partition_type( auto_partition_type& src, split) : auto_partition_type_base(src, split()) {} static const unsigned range_pool_size = __TBB_RANGE_POOL_CAPACITY; }; class simple_partition_type: public partition_type_base { public: simple_partition_type( const simple_partitioner& ) {} simple_partition_type( const simple_partition_type&, split ) {} //! simplified algorithm template void execute(StartType &start, Range &range) { while( range.is_divisible() ) start.offer_work( split() ); start.run_body( range ); } //static const unsigned range_pool_size = 1; - not necessary because execute() is overridden }; //! Backward-compatible partition for auto and affinity partition objects. class old_auto_partition_type: public tbb::internal::partition_type_base { size_t num_chunks; static const size_t VICTIM_CHUNKS = 4; public: bool should_execute_range(const task &t) { if( num_chunks friend class serial::interface6::start_for; template friend class interface6::internal::start_for; template friend class interface6::internal::start_reduce; template friend class internal::start_scan; // backward compatibility class partition_type: public internal::partition_type_base { public: bool should_execute_range(const task& ) {return false;} partition_type( const simple_partitioner& ) {} partition_type( const partition_type&, split ) {} }; // new implementation just extends existing interface typedef interface6::internal::simple_partition_type task_partition_type; }; //! An auto partitioner /** The range is initial divided into several large chunks. Chunks are further subdivided into smaller pieces if demand detected and they are divisible. @ingroup algorithms */ class auto_partitioner { public: auto_partitioner() {} private: template friend class serial::interface6::start_for; template friend class interface6::internal::start_for; template friend class interface6::internal::start_reduce; template friend class internal::start_scan; // backward compatibility typedef interface6::internal::old_auto_partition_type partition_type; // new implementation just extends existing interface typedef interface6::internal::auto_partition_type task_partition_type; }; //! An affinity partitioner class affinity_partitioner: internal::affinity_partitioner_base_v3 { public: affinity_partitioner() {} private: template friend class serial::interface6::start_for; template friend class interface6::internal::start_for; template friend class interface6::internal::start_reduce; template friend class internal::start_scan; // backward compatibility - for parallel_scan only typedef interface6::internal::old_auto_partition_type partition_type; // new implementation just extends existing interface typedef interface6::internal::affinity_partition_type task_partition_type; }; } // namespace tbb #if defined(_MSC_VER) && !defined(__INTEL_COMPILER) #pragma warning (pop) #endif // warning 4244 is back #undef __TBB_INITIAL_CHUNKS #undef __TBB_RANGE_POOL_CAPACITY #undef __TBB_INIT_DEPTH #endif /* __TBB_partitioner_H */