/* This file is part of TON Blockchain Library. TON Blockchain Library is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 2 of the License, or (at your option) any later version. TON Blockchain Library 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with TON Blockchain Library. If not, see . Copyright 2017-2019 Telegram Systems LLP */ #pragma once #include "td/utils/common.h" #include namespace td { // 1. Allocates all objects in vector. (but vector never shrinks) // 2. Id is safe way to reach this object. // 3. All ids are unique. // 4. All ids are non-zero. template class Container { public: using Id = uint64; DataT *get(Id id) { int32 slot_id = decode_id(id); if (slot_id == -1) { return nullptr; } return &slots_[slot_id].data; } void erase(Id id) { int32 slot_id = decode_id(id); if (slot_id == -1) { return; } release(slot_id); } DataT extract(Id id) { int32 slot_id = decode_id(id); CHECK(slot_id != -1); auto res = std::move(slots_[slot_id].data); release(slot_id); return res; } Id create(DataT &&data = DataT(), uint8 type = 0) { int32 id = store(std::move(data), type); return encode_id(id); } Id reset_id(Id id) { int32 slot_id = decode_id(id); CHECK(slot_id != -1); inc_generation(slot_id); return encode_id(slot_id); } static uint8 type_from_id(Id id) { return static_cast(id); } vector ids() { vector is_bad(slots_.size(), false); for (auto id : empty_slots_) { is_bad[id] = true; } vector res; for (size_t i = 0, n = slots_.size(); i < n; i++) { if (!is_bad[i]) { res.push_back(encode_id(static_cast(i))); } } return res; } template void for_each(const F &f) { auto ids = this->ids(); for (auto id : ids) { f(id, *get(id)); } } size_t size() const { CHECK(empty_slots_.size() <= slots_.size()); return slots_.size() - empty_slots_.size(); } bool empty() const { return size() == 0; } void clear() { *this = Container(); } private: static constexpr uint32 GENERATION_STEP = 1 << 8; static constexpr uint32 TYPE_MASK = (1 << 8) - 1; struct Slot { uint32 generation; DataT data; }; vector slots_; vector empty_slots_; Id encode_id(int32 id) const { return (static_cast(id) << 32) | slots_[id].generation; } int32 decode_id(Id id) const { int32 slot_id = static_cast(id >> 32); uint32 generation = static_cast(id); if (slot_id < 0 || slot_id >= static_cast(slots_.size())) { return -1; } if (generation != slots_[slot_id].generation) { return -1; } return slot_id; } int32 store(DataT &&data, uint8 type) { int32 pos; if (!empty_slots_.empty()) { pos = empty_slots_.back(); empty_slots_.pop_back(); slots_[pos].data = std::move(data); slots_[pos].generation ^= (slots_[pos].generation & TYPE_MASK) ^ type; } else { CHECK(slots_.size() <= static_cast(std::numeric_limits::max())); pos = static_cast(slots_.size()); slots_.push_back(Slot{GENERATION_STEP + type, std::move(data)}); } return pos; } void release(int32 id) { inc_generation(id); slots_[id].data = DataT(); if (slots_[id].generation & ~TYPE_MASK) { // generation overflow. Can't use this id anymore empty_slots_.push_back(id); } } void inc_generation(int32 id) { slots_[id].generation += GENERATION_STEP; } }; } // namespace td