/* Copyright 2005-2009 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. */ #include "concurrent_vector_v2.h" #include "tbb/tbb_machine.h" #include #include "../tbb/itt_notify.h" #include "tbb/task.h" #include #if defined(_MSC_VER) && defined(_Wp64) // Workaround for overzealous compiler warnings in /Wp64 mode #pragma warning (disable: 4267) #endif namespace tbb { namespace internal { void concurrent_vector_base::internal_grow_to_at_least( size_type new_size, size_type element_size, internal_array_op1 init ) { size_type e = my_early_size; while( e=pointers_per_short_segment && v.my_segment==v.my_storage ) { extend_segment(v); } } }; void concurrent_vector_base::helper::extend_segment( concurrent_vector_base& v ) { const size_t pointers_per_long_segment = sizeof(void*)==4 ? 32 : 64; segment_t* s = (segment_t*)NFS_Allocate( pointers_per_long_segment, sizeof(segment_t), NULL ); std::memset( s, 0, pointers_per_long_segment*sizeof(segment_t) ); // If other threads are trying to set pointers in the short segment, wait for them to finish their // assigments before we copy the short segment to the long segment. atomic_backoff backoff; while( !v.my_storage[0].array || !v.my_storage[1].array ) { backoff.pause(); } s[0] = v.my_storage[0]; s[1] = v.my_storage[1]; if( v.my_segment.compare_and_swap( s, v.my_storage )!=v.my_storage ) NFS_Free(s); } concurrent_vector_base::size_type concurrent_vector_base::internal_capacity() const { return segment_base( helper::find_segment_end(*this) ); } void concurrent_vector_base::internal_reserve( size_type n, size_type element_size, size_type max_size ) { if( n>max_size ) { throw std::length_error("argument to ConcurrentVector::reserve exceeds ConcurrentVector::max_size()"); } for( segment_index_t k = helper::find_segment_end(*this); segment_base(k)n-b ) m = n-b; copy( my_segment[k].array, src.my_segment[k].array, m ); } } } void concurrent_vector_base::internal_assign( const concurrent_vector_base& src, size_type element_size, internal_array_op1 destroy, internal_array_op2 assign, internal_array_op2 copy ) { size_type n = src.my_early_size; while( my_early_size>n ) { segment_index_t k = segment_index_of( my_early_size-1 ); size_type b=segment_base(k); size_type new_end = b>=n ? b : n; __TBB_ASSERT( my_early_size>new_end, NULL ); destroy( (char*)my_segment[k].array+element_size*(new_end-b), my_early_size-new_end ); my_early_size = new_end; } size_type dst_initialized_size = my_early_size; my_early_size = n; size_type b; for( segment_index_t k=0; (b=segment_base(k))n-b ) m = n-b; size_type a = 0; if( dst_initialized_size>b ) { a = dst_initialized_size-b; if( a>m ) a = m; assign( my_segment[k].array, src.my_segment[k].array, a ); m -= a; a *= element_size; } if( m>0 ) copy( (char*)my_segment[k].array+a, (char*)src.my_segment[k].array+a, m ); } __TBB_ASSERT( src.my_early_size==n, "detected use of ConcurrentVector::operator= with right side that was concurrently modified" ); } void* concurrent_vector_base::internal_push_back( size_type element_size, size_type& index ) { __TBB_ASSERT( sizeof(my_early_size)==sizeof(reference_count), NULL ); //size_t tmp = __TBB_FetchAndIncrementWacquire(*(tbb::internal::reference_count*)&my_early_size); size_t tmp = __TBB_FetchAndIncrementWacquire((tbb::internal::reference_count*)&my_early_size); index = tmp; segment_index_t k_old = segment_index_of( tmp ); size_type base = segment_base(k_old); helper::extend_segment_if_necessary(*this,k_old); segment_t& s = my_segment[k_old]; void* array = s.array; if( !array ) { // FIXME - consider factoring this out and share with internal_grow_by if( base==tmp ) { __TBB_ASSERT( !s.array, NULL ); size_t n = segment_size(k_old); array = NFS_Allocate( n, element_size, NULL ); ITT_NOTIFY( sync_releasing, &s.array ); s.array = array; } else { ITT_NOTIFY(sync_prepare, &s.array); spin_wait_while_eq( s.array, (void*)0 ); ITT_NOTIFY(sync_acquired, &s.array); array = s.array; } } size_type j_begin = tmp-base; return (void*)((char*)array+element_size*j_begin); } concurrent_vector_base::size_type concurrent_vector_base::internal_grow_by( size_type delta, size_type element_size, internal_array_op1 init ) { size_type result = my_early_size.fetch_and_add(delta); internal_grow( result, result+delta, element_size, init ); return result; } void concurrent_vector_base::internal_grow( const size_type start, size_type finish, size_type element_size, internal_array_op1 init ) { __TBB_ASSERT( start finish-base ? finish-base : n; (*init)( (void*)((char*)array+element_size*j_begin), j_end-j_begin ); tmp = base+j_end; } while( tmp0 ) { segment_index_t k_old = segment_index_of(finish-1); segment_t& s = my_segment[k_old]; __TBB_ASSERT( s.array, NULL ); size_type base = segment_base(k_old); size_type j_end = finish-base; __TBB_ASSERT( j_end, NULL ); (*destroy)( s.array, j_end ); finish = base; } // Free the arrays if( reclaim_storage ) { size_t k = helper::find_segment_end(*this); while( k>0 ) { --k; segment_t& s = my_segment[k]; void* array = s.array; s.array = NULL; NFS_Free( array ); } // Clear short segment. my_storage[0].array = NULL; my_storage[1].array = NULL; segment_t* s = my_segment; if( s!=my_storage ) { my_segment = my_storage; NFS_Free( s ); } } } } // namespace internal } // tbb