#pragma once /* * Copyright (C) 2024 Brett Terpstra * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program 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 this program. If not, see . */ #ifndef BLT_GP_STACK_H #define BLT_GP_STACK_H #include #include #include #include #include #include #include #include #include #include #include #include namespace blt::gp { class stack_allocator { constexpr static blt::size_t PAGE_SIZE = 0x1000; constexpr static blt::size_t MAX_ALIGNMENT = 8; template using NO_REF_T = std::remove_cv_t>; public: struct size_data_t { blt::size_t total_size_bytes = 0; blt::size_t total_used_bytes = 0; blt::size_t total_remaining_bytes = 0; blt::size_t total_no_meta_bytes = 0; blt::size_t total_dealloc = 0; blt::size_t total_dealloc_used = 0; blt::size_t total_dealloc_remaining = 0; blt::size_t total_dealloc_no_meta = 0; blt::size_t blocks = 0; friend std::ostream& operator<<(std::ostream& stream, const size_data_t& data) { stream << "["; stream << data.total_used_bytes << "/"; stream << data.total_size_bytes << "("; stream << (static_cast(data.total_used_bytes) / static_cast(data.total_size_bytes) * 100) << "%), "; stream << data.total_used_bytes << "/"; stream << data.total_no_meta_bytes << "("; stream << (static_cast(data.total_used_bytes) / static_cast(data.total_no_meta_bytes) * 100) << "%), (empty space: "; stream << data.total_remaining_bytes << ") blocks: " << data.blocks << " || unallocated space: "; stream << data.total_dealloc_used << "/"; stream << data.total_dealloc; if (static_cast(data.total_dealloc) > 0) stream << "(" << (static_cast(data.total_dealloc_used) / static_cast(data.total_dealloc) * 100) << "%)"; stream << ", "; stream << data.total_dealloc_used << "/"; stream << data.total_dealloc_no_meta; if (data.total_dealloc_no_meta > 0) stream << "(" << (static_cast(data.total_dealloc_used) / static_cast(data.total_dealloc_no_meta * 100)) << "%)"; stream << ", (empty space: " << data.total_dealloc_remaining << ")]"; return stream; } }; void insert(stack_allocator stack) { if (stack.empty()) return; // take a copy of the pointer to this stack's blocks auto old_head = stack.head; // stack is now empty, we have the last reference to it. stack.head = nullptr; // we don't have any nodes to search through or re-point, we can just assign the head if (head == nullptr) { head = old_head; return; } // find the beginning of the stack auto begin = old_head; while (begin->metadata.prev != nullptr) begin = begin->metadata.prev; // move along blocks with free space, attempt to insert bytes from one stack to another auto insert = head; while (insert->metadata.next != nullptr && begin != nullptr) { if (begin->used_bytes_in_block() <= insert->remaining_bytes_in_block()) { std::memcpy(insert->metadata.offset, begin->buffer, begin->used_bytes_in_block()); insert->metadata.offset += begin->used_bytes_in_block(); auto old_begin = begin; begin = begin->metadata.next; free_block(old_begin); } head = insert; insert = insert->metadata.next; } if (begin == nullptr) return; while (insert->metadata.next != nullptr) insert = insert->metadata.next; // if here is space left we can move the pointers around insert->metadata.next = begin; begin->metadata.prev = insert; // find where the head is now and set the head to this new point. auto new_head = begin; while (new_head->metadata.next != nullptr) new_head = new_head->metadata.next; head = new_head; } /** * Bytes must be the number of bytes to move, all types must have alignment accounted for */ void copy_from(const stack_allocator& stack, blt::size_t bytes) { if (bytes == 0) return; if (stack.empty()) { BLT_WARN("This stack is empty, we will copy no bytes from it!"); return; } auto [start_block, bytes_left, start_point] = get_start_from_bytes(stack, bytes); if (bytes_left > 0) { allocate_block_to_head_for_size(bytes_left); std::memcpy(head->metadata.offset, start_point, bytes_left); head->metadata.offset += bytes_left; start_block = start_block->metadata.next; } // we now copy whole blocks at a time. while (start_block != nullptr) { allocate_block_to_head_for_size(start_block->used_bytes_in_block()); std::memcpy(head->metadata.offset, start_block->buffer, start_block->used_bytes_in_block()); head->metadata.offset += start_block->used_bytes_in_block(); start_block = start_block->metadata.next; } } void copy_from(blt::u8* data, blt::size_t bytes) { if (bytes == 0 || data == nullptr) return; allocate_block_to_head_for_size(bytes); std::memcpy(head->metadata.offset, data, bytes); head->metadata.offset += bytes; } void copy_to(blt::u8* data, blt::size_t bytes) const { if (bytes == 0 || data == nullptr) return; auto [start_block, bytes_left, start_point] = get_start_from_bytes(*this, bytes); blt::size_t write_point = 0; if (bytes_left > 0) { std::memcpy(data + write_point, start_point, bytes_left); write_point += bytes_left; start_block = start_block->metadata.next; } // we now copy whole blocks at a time. while (start_block != nullptr) { std::memcpy(data + write_point, start_block->buffer, start_block->used_bytes_in_block()); write_point += start_block->used_bytes_in_block(); start_block = start_block->metadata.next; } } /** * Pushes an instance of an object on to the stack * @tparam T type to push * @param value universal reference to the object to push */ template void push(T&& value) { using NO_REF_T = std::remove_cv_t>; static_assert(std::is_trivially_copyable_v && "Type must be bitwise copyable!"); static_assert(alignof(NO_REF_T) <= MAX_ALIGNMENT && "Type must not be greater than the max alignment!"); auto ptr = allocate_bytes(); head->metadata.offset = static_cast(ptr) + aligned_size(); new(ptr) NO_REF_T(std::forward(value)); } template T pop() { using NO_REF_T = std::remove_cv_t>; static_assert(std::is_trivially_copyable_v && "Type must be bitwise copyable!"); constexpr static auto TYPE_SIZE = aligned_size(); while (head->used_bytes_in_block() == 0 && move_back()); if (empty()) throw std::runtime_error("Silly boi the stack is empty!"); if (head->used_bytes_in_block() < static_cast(aligned_size())) throw std::runtime_error((std::string("Mismatched Types! Not enough space left in block! Bytes: ") += std::to_string( head->used_bytes_in_block()) += " Size: " + std::to_string(sizeof(NO_REF_T))).c_str()); // make copy NO_REF_T t = *reinterpret_cast(head->metadata.offset - TYPE_SIZE); // call destructor reinterpret_cast(head->metadata.offset - TYPE_SIZE)->~NO_REF_T(); // move offset back head->metadata.offset -= TYPE_SIZE; // moving back allows us to allocate with other data, if there is room. while (head->used_bytes_in_block() == 0 && move_back()); return t; } template T& from(blt::size_t bytes) { using NO_REF_T = std::remove_cv_t>; constexpr static auto TYPE_SIZE = aligned_size(); auto remaining_bytes = static_cast(bytes + TYPE_SIZE); block* blk = head; while (remaining_bytes > 0) { if (blk == nullptr) throw std::runtime_error("Requested size is beyond the scope of this stack!"); auto bytes_available = blk->used_bytes_in_block() - remaining_bytes; if (bytes_available < 0) { remaining_bytes -= blk->used_bytes_in_block(); blk = blk->metadata.prev; } else break; } if (blk == nullptr) throw std::runtime_error("Some nonsense is going on. This function already smells"); if (blk->used_bytes_in_block() < static_cast(TYPE_SIZE)) { BLT_WARN_STREAM << size() << "\n"; throw std::runtime_error((std::string("Mismatched Types! Not enough space left in block! Bytes: ") += std::to_string( blk->used_bytes_in_block()) += " Size: " + std::to_string(sizeof(NO_REF_T))).c_str()); } return *reinterpret_cast(blk->metadata.offset - remaining_bytes); } void pop_bytes(blt::ptrdiff_t bytes) { if (bytes == 0) return; if (empty()) { BLT_WARN("Cannot pop %ld bytes", bytes); BLT_ABORT("Stack is empty, we cannot pop!"); } while (bytes > 0) { if (head == nullptr) { BLT_WARN("The head is null, this stack doesn't contain enough data inside to pop %ld bytes!", bytes); BLT_WARN_STREAM << "Stack State: " << size() << "\n"; BLT_ABORT("Stack doesn't contain enough data to preform a pop!"); } auto diff = head->used_bytes_in_block() - bytes; // if there is not enough room left to pop completely off the block, then move to the next previous block // and pop from it, update the amount of bytes to reflect the amount removed from the current block if (diff < 0) { bytes -= head->used_bytes_in_block(); // reset this head's buffer. head->metadata.offset = head->buffer; move_back(); } else { // otherwise update the offset pointer head->metadata.offset -= bytes; break; } } while (head != nullptr && head->used_bytes_in_block() == 0 && move_back()); } /** * Warning this function should be used to transfer types, not arrays of types! It will produce an error if you attempt to pass more * than one type # of bytes at a time~! * @param to stack to push to * @param bytes number of bytes to transfer out. */ void transfer_bytes(stack_allocator& to, blt::size_t bytes) { while (head->used_bytes_in_block() == 0 && move_back()); if (empty()) throw std::runtime_error("This stack is empty!"); auto type_size = aligned_size(bytes); if (head->used_bytes_in_block() < static_cast(type_size)) { BLT_ERROR_STREAM << "Stack State:\n" << size() << "\n" << "Bytes in head: " << bytes_in_head() << "\n"; BLT_ABORT(("This stack doesn't contain enough data for this type! " + std::to_string(head->used_bytes_in_block()) + " / " + std::to_string(bytes) + " This is an invalid runtime state!").c_str()); } auto ptr = to.allocate_bytes(type_size); to.head->metadata.offset = static_cast(ptr) + type_size; std::memcpy(ptr, head->metadata.offset - type_size, type_size); head->metadata.offset -= type_size; while (head->used_bytes_in_block() == 0 && move_back()); } template void call_destructors() { blt::size_t offset = 0; ((from>(offset).~NO_REF_T(), offset += stack_allocator::aligned_size> ()), ...); } [[nodiscard]] bool empty() const noexcept { if (head == nullptr) return true; if (head->metadata.prev != nullptr) return false; return head->used_bytes_in_block() == 0; } [[nodiscard]] blt::ptrdiff_t bytes_in_head() const noexcept { if (head == nullptr) return 0; return head->used_bytes_in_block(); } /** * Warning this function is slow! * @return the size of the stack allocator in bytes */ [[nodiscard]] size_data_t size() const noexcept { size_data_t size_data; auto* prev = head; while (prev != nullptr) { size_data.total_size_bytes += prev->metadata.size; size_data.total_no_meta_bytes += prev->storage_size(); size_data.total_remaining_bytes += prev->remaining_bytes_in_block(); size_data.total_used_bytes += prev->used_bytes_in_block(); size_data.blocks++; prev = prev->metadata.prev; } if (head != nullptr) { auto next = head->metadata.next; while (next != nullptr) { size_data.total_dealloc += next->metadata.size; size_data.total_dealloc_no_meta += next->storage_size(); size_data.total_dealloc_remaining += next->remaining_bytes_in_block(); size_data.total_dealloc_used += next->used_bytes_in_block(); size_data.blocks++; next = next->metadata.next; } } return size_data; } stack_allocator() = default; // TODO: cleanup this allocator! // if you keep track of type size information you can memcpy between stack allocators as you already only allow trivially copyable types stack_allocator(const stack_allocator& copy) noexcept { if (copy.empty()) return; head = nullptr; block* list_itr = nullptr; // start at the beginning of the list block* current = copy.head; while (current != nullptr) { list_itr = current; current = current->metadata.prev; } // copy all the blocks while (list_itr != nullptr) { push_block(list_itr->metadata.size); std::memcpy(head->buffer, list_itr->buffer, list_itr->storage_size()); head->metadata.size = list_itr->metadata.size; head->metadata.offset = head->buffer + list_itr->used_bytes_in_block(); list_itr = list_itr->metadata.next; } } stack_allocator& operator=(const stack_allocator& copy) = delete; stack_allocator(stack_allocator&& move) noexcept { head = move.head; move.head = nullptr; } stack_allocator& operator=(stack_allocator&& move) noexcept { move.head = std::exchange(head, move.head); return *this; } ~stack_allocator() noexcept { if (head != nullptr) { auto blk = head->metadata.next; while (blk != nullptr) { auto ptr = blk; blk = blk->metadata.next; free_block(ptr); } } free_chain(head); } template static inline constexpr blt::size_t aligned_size() noexcept { return aligned_size(sizeof(NO_REF_T)); } static inline constexpr blt::size_t aligned_size(blt::size_t size) noexcept { return (size + (MAX_ALIGNMENT - 1)) & ~(MAX_ALIGNMENT - 1); } inline static constexpr auto metadata_size() noexcept { return sizeof(typename block::block_metadata_t); } inline static constexpr auto block_size() noexcept { return sizeof(block); } inline static constexpr auto page_size() noexcept { return PAGE_SIZE; } inline static constexpr auto page_size_no_meta() noexcept { return page_size() - metadata_size(); } inline static constexpr auto page_size_no_block() noexcept { return page_size() - block_size(); } private: struct block { struct block_metadata_t { blt::size_t size = 0; block* next = nullptr; block* prev = nullptr; blt::u8* offset = nullptr; } metadata; blt::u8 buffer[8]{}; explicit block(blt::size_t size) noexcept { #if BLT_DEBUG_LEVEL > 0 if (size < PAGE_SIZE) { BLT_WARN("Hey this block is too small, who allocated it?"); std::abort(); } #endif metadata.size = size; metadata.offset = buffer; } void reset() noexcept { metadata.offset = buffer; } [[nodiscard]] blt::ptrdiff_t storage_size() const noexcept { return static_cast(metadata.size - sizeof(typename block::block_metadata_t)); } [[nodiscard]] blt::ptrdiff_t used_bytes_in_block() const noexcept { return static_cast(metadata.offset - buffer); } [[nodiscard]] blt::ptrdiff_t remaining_bytes_in_block() const noexcept { return storage_size() - used_bytes_in_block(); } }; struct copy_start_point { block* start_block; blt::ptrdiff_t bytes_left; blt::u8* start_point; }; template void* allocate_bytes() { return allocate_bytes(sizeof(NO_REF_T)); } void* allocate_bytes(blt::size_t size) { auto ptr = get_aligned_pointer(size); if (ptr == nullptr) allocate_block_to_head_for_size(aligned_size(size)); ptr = get_aligned_pointer(size); if (ptr == nullptr) throw std::bad_alloc(); return ptr; } /** * Moves forward through the list of "deallocated" blocks, if none meet size requirements it'll allocate a new block. * This function will take into account the size of the block metadata, but requires the size input to be aligned. * It will perform no modification to the size value. * * The block which allows for size is now at head. */ void allocate_block_to_head_for_size(const blt::size_t size) noexcept { while (head != nullptr && head->metadata.next != nullptr) { head = head->metadata.next; if (head != nullptr) head->reset(); if (head->remaining_bytes_in_block() >= static_cast(size)) break; } if (head == nullptr || head->remaining_bytes_in_block() < static_cast(size)) push_block(size + sizeof(typename block::block_metadata_t)); } void* get_aligned_pointer(blt::size_t bytes) noexcept { if (head == nullptr) return nullptr; blt::size_t remaining_bytes = head->remaining_bytes_in_block(); auto* pointer = static_cast(head->metadata.offset); return std::align(MAX_ALIGNMENT, bytes, pointer, remaining_bytes); } void push_block(blt::size_t size) noexcept { auto blk = allocate_block(size); if (head == nullptr) { head = blk; return; } head->metadata.next = blk; blk->metadata.prev = head; head = blk; } static size_t to_nearest_page_size(blt::size_t bytes) noexcept { constexpr static blt::size_t MASK = ~(PAGE_SIZE - 1); return (bytes & MASK) + PAGE_SIZE; } static block* allocate_block(blt::size_t bytes) noexcept { auto size = to_nearest_page_size(bytes); auto* data = std::aligned_alloc(PAGE_SIZE, size); //auto* data = get_allocator().allocate(size); new(data) block{size}; return reinterpret_cast(data); } static void free_chain(block* current) noexcept { while (current != nullptr) { block* ptr = current; current = current->metadata.prev; free_block(ptr); //get_allocator().deallocate(ptr); } } static void free_block(block* ptr) noexcept { std::free(ptr); } inline bool move_back() noexcept { auto old = head; head = head->metadata.prev; if (head == nullptr) { head = old; return false; } return true; } [[nodiscard]] inline static copy_start_point get_start_from_bytes(const stack_allocator& stack, blt::size_t bytes) { auto start_block = stack.head; auto bytes_left = static_cast(bytes); blt::u8* start_point = nullptr; while (bytes_left > 0) { if (start_block == nullptr) { BLT_WARN("This stack doesn't contain enough space to copy %ld bytes!", bytes); BLT_WARN_STREAM << "State: " << stack.size() << "\n"; BLT_ABORT("Stack doesn't contain enough data for this copy operation!"); } if (start_block->used_bytes_in_block() < bytes_left) { bytes_left -= start_block->used_bytes_in_block(); start_block = start_block->metadata.prev; } else if (start_block->used_bytes_in_block() == bytes_left) { start_point = start_block->buffer; break; } else { start_point = start_block->metadata.offset - bytes_left; break; } } return copy_start_point{start_block, bytes_left, start_point}; } private: block* head = nullptr; }; } #endif //BLT_GP_STACK_H