/*------------------------------- phasicFlow --------------------------------- O C enter of O O E ngineering and O O M ultiscale modeling of OOOOOOO F luid flow ------------------------------------------------------------------------------ Copyright (C): www.cemf.ir email: hamid.r.norouzi AT gmail.com ------------------------------------------------------------------------------ Licence: This file is part of phasicFlow code. It is a free software for simulating granular and multiphase flows. You can redistribute it and/or modify it under the terms of GNU General Public License v3 or any other later versions. phasicFlow is distributed to help others in their research in the field of granular and multiphase flows, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. -----------------------------------------------------------------------------*/ #ifndef __unsortedPairs_hpp__ #define __unsortedPairs_hpp__ #include "KokkosTypes.hpp" #include "types.hpp" namespace pFlow { template class unsortedPairs { public: using UnsortedPairs = unsortedPairs; using IdType = idType; using ExecutionSpace = executionSpace; using memory_space = typename ExecutionSpace::memory_space; using PairType = Pair; using ContainerType = unorderedSet; struct pairAccessor { using PairType = typename UnsortedPairs::PairType; ContainerType Container_; INLINE_FUNCTION_HD uint32 size()const { return Container_.size(); } INLINE_FUNCTION_HD uint32 loopCount()const { return Container_.capacity(); } INLINE_FUNCTION_HD bool isValid(uint32 idx)const { return Container_.valid_at(idx); } INLINE_FUNCTION_HD PairType getPair(uint32 idx)const { return Container_.key_at(idx); } INLINE_FUNCTION_HD bool getPair(uint32 idx, PairType& pair)const { if(Container_.valid_at(idx)) { pair = Container_.key_at(idx); return true; } return false; } }; protected: ContainerType container_; public: // - type info TypeInfoNV("unsorderedPairs"); // constructor explicit unsortedPairs(uint32 capacity=1) : container_(capacity) // the minimum capacity would be 128 {} bool beforeBroadSearch() { container_.clear(); return true; } bool afterBroadSearch() { return true; } // - Device call INLINE_FUNCTION_HD uint32 insert(idType i, idType j)const { if(auto insertResult = container_.insert(PairType(i,j)); insertResult.failed()) return static_cast(-1); else return insertResult.index(); } INLINE_FUNCTION_HD uint32 insert(const PairType& p)const { if(auto insertResult = container_.insert(p); insertResult.failed()) return static_cast(-1); else return insertResult.index(); } // - Device call // return the pair at index idx // perform no check for size and existance INLINE_FUNCTION_HD PairType getPair(uint32 idx)const { return container_.key_at(idx); } // - Device call // return the pair at index idx INLINE_FUNCTION_HD bool getPair(uint32 idx, PairType& p)const { if(container_.valid_at(idx)) { p = container_.key_at(idx); return true; } else { return false; } } INLINE_FUNCTION_HD uint32 find(const PairType & p)const { if( auto idx = container_.find(p); idx != Kokkos::UnorderedMapInvalidIndex ) return idx; else return static_cast(-1); } INLINE_FUNCTION_HD bool isValid(uint32 idx)const { return container_.valid_at(idx); } INLINE_FUNCTION_HD uint32 capacity() const { return container_.capacity(); } uint32 loopCount()const { return container_.capacity(); } //use this when the value of size_ is updated INLINE_FUNCTION_H uint32 size()const { return container_.size(); } pairAccessor getPairs()const { return {container_}; } /// increase the capacity of the container by at-least len /// the content will be erased. INLINE_FUNCTION_H void increaseCapacityBy(uint32 len) { uint newCap = container_.capacity()+len; this->clear(); //output<<"----------------before "<