/* Part of the SETTINGS MODULE Copyright (C) 2020 by Maxim Prokhorov Reimplementation of the Embedis storage format: - https://github.com/thingSoC/embedis */ #pragma once #include #include #include #include #include "libs/TypeChecks.h" namespace settings { namespace embedis { // 'optional' type for byte range struct ValueResult { operator bool() { return result; } bool result { false }; String value; }; // Sum total is calculated from: // - 4 bytes to store length of 2 values (stored as big-endian) // - N bytes of values themselves // We can't save empty keys but can save empty values as just 2 length bytes inline size_t estimate(const String& key, const String& value) { if (!key.length()) { return 0; } return (4 + key.length() + value.length()); } // Note: KeyValueStore is templated to avoid having to provide RawStorageBase via virtual inheritance. template class KeyValueStore { // ----------------------------------------------------------------------------------- // Notice: we can only use sfinae checks with the current compiler version // TODO: provide actual benchmark comparison with 'lambda'-list-as-vtable (old Embedis style) // and vtable approach (write(), read() and commit() as pure virtual) // TODO: consider overrides for bulk operations like move (see ::del method) template using storage_can_write_t = decltype(std::declval().write( std::declval(), std::declval())); template using storage_can_write = is_detected; template using storage_can_read_t = decltype(std::declval().read(std::declval())); template using storage_can_read = is_detected; template using storage_can_commit_t = decltype(std::declval().commit()); template using storage_can_commit = is_detected; static_assert( (storage_can_commit{} && storage_can_read{} && storage_can_write{}), "Storage class must implement read(index), write(index, byte) and commit()" ); // ----------------------------------------------------------------------------------- protected: // Tracking state of the parser inside of _raw_read() enum class State { Begin, End, LenByte1, LenByte2, Value }; // Pointer to the region of data that we are using // // XXX: It does not matter right now, but we **will** overflow position when using sizes >= (2^16) - 1 // Note: Implementation is also in the header b/c c++ won't allow us // to have a plain member (not a ptr or ref) of unknown size. // Note: There was a considiration to implement this as 'stashing iterator' to be compatible with stl algorithms. // In such implementation, we would store intermediate index and allow the user to receive a `value_proxy`, // temporary returned by `value_proxy& operator*()' that is bound to Cursor instance. // This **will** cause problems with 'reverse_iterator' or anything like it, as it expects reference to // outlive the iterator object (specifically, result of `return *--tmp`, where `tmp` is created inside of a function block) struct Cursor { Cursor(RawStorageBase& storage, uint16_t position_, uint16_t begin_, uint16_t end_) : position(position_), begin(begin_), end(end_), _storage(storage) {} Cursor(RawStorageBase& storage, uint16_t begin_, uint16_t end_) : Cursor(storage, 0, begin_, end_) {} explicit Cursor(RawStorageBase& storage) : Cursor(storage, 0, 0, 0) {} static Cursor merge(RawStorageBase& storage, const Cursor& key, const Cursor& value) { return Cursor(storage, key.begin, value.end); } static Cursor fromEnd(RawStorageBase& storage, uint16_t begin, uint16_t end) { return Cursor(storage, end - begin, begin, end); } Cursor() = delete; void reset(uint16_t begin_, uint16_t end_) { position = 0; begin = begin_; end = end_; } uint8_t read() { return _storage.read(begin + position); } void write(uint8_t value) { _storage.write(begin + position, value); } void resetBeginning() { position = 0; } void resetEnd() { position = end - begin; } size_t size() { return (end - begin); } bool inRange(uint16_t position_) { return (position_ < (end - begin)); } operator bool() { return inRange(position); } uint8_t operator[](size_t position_) const { return _storage.read(begin + position_); } bool operator ==(const Cursor& other) { return (begin == other.begin) && (end == other.end); } bool operator !=(const Cursor& other) { return !(*this == other); } Cursor& operator++() { ++position; return *this; } Cursor operator++(int) { Cursor other(*this); ++*this; return other; } Cursor& operator--() { --position; return *this; } Cursor operator--(int) { Cursor other(*this); --*this; return other; } uint16_t position; uint16_t begin; uint16_t end; private: RawStorageBase& _storage; }; public: // Store value location in a more reasonable forward-iterator-style manner // Allows us to skip string creation when just searching for specific values // XXX: be cautious that cursor positions **will** break when underlying storage changes struct ReadResult { friend class KeyValueStore; ReadResult(const Cursor& cursor_) : length(0), cursor(cursor_), result(false) {} ReadResult(RawStorageBase& storage) : length(0), cursor(storage), result(false) {} operator bool() { return result; } String read() { String out; out.reserve(length); if (!length) { return out; } decltype(length) index = 0; cursor.resetBeginning(); while (index < length) { out += static_cast(cursor.read()); ++cursor; ++index; } return out; } uint16_t length; private: Cursor cursor; bool result; }; // Internal storage consists of sequences of struct KeyValueResult { operator bool() { return (key) && (value) && (key.length > 0); } bool operator !() { return !(static_cast(*this)); } template KeyValueResult(T&& key_, T&& value_) : key(std::forward(key_)), value(std::forward(value_)) {} KeyValueResult(RawStorageBase& storage) : key(storage), value(storage) {} ReadResult key; ReadResult value; }; // one and only possible constructor, simply move the class object into the // member variable to avoid forcing the user of the API to keep 2 objects alive. KeyValueStore(RawStorageBase&& storage, uint16_t begin, uint16_t end) : _storage(std::move(storage)), _cursor(_storage, begin, end), _state(State::Begin) {} // Try to find the matching key. Datastructure that we use does not specify // any value 'type' inside of it. We expect 'key' to be the first non-empty string, // 'value' can be empty. ValueResult get(const String& key) { return _get(key, true); } bool has(const String& key) { return static_cast(_get(key, false)); } // We going be using this pattern all the time here, because we need 2 consecutive **valid** ranges // TODO: expose _read_kv() and _cursor_reset_end() so we can have 'break' here? // perhaps as a wrapper object, allow something like next() and seekBegin() template void foreach(CallbackType callback) { _cursor_reset_end(); do { auto kv = _read_kv(); if (!kv) { break; } callback(std::move(kv)); } while (_state != State::End); } // read every key into a vector std::vector keys() { std::vector out; out.reserve(count()); foreach([&](KeyValueResult&& kv) { out.push_back(kv.key.read()); }); return out; } // set or update key with value contents. ensure 'key' isn't empty, 'value' can be empty bool set(const String& key, const String& value) { // ref. 'estimate()' implementation in regards to the storage calculation auto need = estimate(key, value); if (!need) { return false; } auto key_len = key.length(); auto value_len = value.length(); Cursor to_erase(_storage); bool need_erase = false; // we need the position at the 'end' of the free space auto start_pos = _cursor_reset_end(); do { auto kv = _read_kv(); if (!kv) { break; } start_pos = kv.value.cursor.begin; // in the very special case we can match the existing key, we either if ((kv.key.length == key_len) && (kv.key.read() == key)) { if (kv.value.length == value.length()) { // - do nothing, as the value is already set if (kv.value.read() == value) { return true; } // - overwrite the space again, with the new kv of the same length start_pos = kv.key.cursor.end; break; } // - or, erase the existing kv and place new kv at the end to_erase.reset(kv.value.cursor.begin, kv.key.cursor.end); need_erase = true; } } while (_state != State::End); if (need_erase) { _raw_erase(start_pos, to_erase); start_pos += to_erase.size(); } // we should only insert when possition is still within possible size if (start_pos && (start_pos >= need)) { auto writer = Cursor::fromEnd(_storage, start_pos - need, start_pos); // put the length of the value as 2 bytes and then write the data (--writer).write(key_len & 0xff); (--writer).write((key_len >> 8) & 0xff); while (key_len--) { (--writer).write(key[key_len]); } (--writer).write(value_len & 0xff); (--writer).write((value_len >> 8) & 0xff); while (value_len--) { (--writer).write(value[value_len]); } // we also need to add an empty key *after* the value // but, only when we still have some space left if (writer.begin >= 2) { _cursor_set_position(writer.begin - _cursor.begin); auto next_kv = _read_kv(); if (!next_kv) { auto empty = Cursor::fromEnd(_storage, writer.begin - 2, writer.begin); (--empty).write(0); (--empty).write(0); } } _storage.commit(); return true; } return false; } // remove key from the storage. will check that 'key' argument isn't empty bool del(const String& key) { size_t key_len = key.length(); if (!key_len) { return false; } // we should only compare strings of equal length. // when matching, record { value ... key } range + 4 bytes for length // continue searching for available keys and set start_pos and the 'end' of the free space size_t start_pos = _cursor_reset_end(); auto to_erase = Cursor::fromEnd(_storage, _cursor.begin, _cursor.end); foreach([&](KeyValueResult&& kv) { start_pos = kv.value.cursor.begin; if (!to_erase && (kv.key.length == key_len) && (kv.key.read() == key)) { to_erase.reset(kv.value.cursor.begin, kv.key.cursor.end); } }); if (to_erase) { _raw_erase(start_pos, to_erase); return true; } return false; } // Simply count key-value pairs that we could parse size_t count() { size_t result = 0; foreach([&result](KeyValueResult&&) { ++result; }); return result; } // Do exactly the same thing as 'keys' does, but return the amount // of bytes to the left of the last kv size_t available() { size_t result = _cursor.size(); foreach([&result](KeyValueResult&& kv) { result -= kv.key.cursor.size(); result -= kv.value.cursor.size(); }); return result; } // How much bytes can be used is directly read from the cursor, based on begin and end values size_t size() { return _cursor.size(); } protected: // Try to find the matching key. Datastructure that we use does not specify // any value 'type' inside of it. We expect 'key' to be the first non-empty string, // 'value' can be empty. // To implement has(), allow to skip reading the value ValueResult _get(const String& key, bool read_value) { ValueResult out; auto len = key.length(); _cursor_reset_end(); do { auto kv = _read_kv(); if (!kv) { break; } // no point in comparing keys when length does not match // (and we also don't want to allocate the string) if (kv.key.length != len) { continue; } auto key_result = kv.key.read(); if (key_result == key) { if (read_value) { out.value = kv.value.read(); } out.result = true; break; } } while (_state != State::End); return out; } // Place cursor at the `end` and resets the parser to expect length byte uint16_t _cursor_reset_end() { _cursor.resetEnd(); _state = State::Begin; return _cursor.end; } uint16_t _cursor_set_position(uint16_t position) { _state = State::Begin; _cursor.position = position; return _cursor.position; } // implementation quirk is that `Cursor::operator=` won't work because of the `RawStorageBase&` member // right now, just construct in place and assume that compiler will inline things KeyValueResult _read_kv() { auto key = _raw_read(); if (!key || !key.length) { return {_storage}; } auto value = _raw_read(); return {key, value}; }; void _raw_erase(size_t start_pos, Cursor& to_erase) { // we either end up to the left or to the right of the boundary size_t new_pos = (start_pos < to_erase.begin) ? (start_pos + to_erase.size()) : (to_erase.end); if (start_pos < to_erase.begin) { // shift storage to the right, overwriting over the now empty space auto from = Cursor::fromEnd(_storage, start_pos, to_erase.begin); auto to = Cursor::fromEnd(_storage, start_pos + to_erase.size(), to_erase.end); while (--from && --to) { to.write(from.read()); from.write(0xff); } } else { // overwrite the now empty space with 0xff to_erase.resetEnd(); while (--to_erase) { to_erase.write(0xff); } } // same as set(), add empty key as padding auto empty = Cursor::fromEnd(_storage, new_pos - 2, new_pos); (--empty).write(0); (--empty).write(0); _storage.commit(); } // Returns Cursor to the region that holds the data // Result object itself does not contain any data, we need to explicitly request it by calling read() // // Cursor object is always expected to point to something, e.g. minimum: // 0x00 0x00 // len2 len1 // Position will be 0, end will be 2. Total length is 2, data length is 0 // // Or, non-empty value: // 0x01 0x00 0x01 // data len2 len1 // Position will be 0, end will be 3. Total length is 3, data length is 1 ReadResult _raw_read() { uint16_t len = 0; ReadResult out(_storage); do { // storage is written right-to-left, cursor is always decreasing switch (_state) { case State::Begin: if (_cursor.position >= 2) { --_cursor; _state = State::LenByte1; } else { _state = State::End; } break; // len is 16 bit uint (bigendian) // special case is 0, which is valid and should be returned when encountered // another special case is 0xffff, meaning we just hit an empty space case State::LenByte1: len = _cursor.read(); _state = State::LenByte2; break; case State::LenByte2: { uint8_t len2 = (--_cursor).read(); if ((0xff == len) && (0xff == len2)) { _state = State::End; } else { len |= len2 << 8; _state = State::Value; } break; } case State::Value: { // ensure we don't go out-of-bounds if (len && _cursor.position < len) { _state = State::End; break; } // and point at the beginning of the value _cursor.position -= len; auto value_start = (_cursor.begin + _cursor.position); out.cursor.reset(value_start, value_start + len + 2); out.length = len; out.result = true; _state = State::Begin; goto return_result; } case State::End: default: break; } } while (_state != State::End); return_result: return out; } RawStorageBase _storage; Cursor _cursor; State _state { State::Begin }; }; } // namespace embedis } // namespace settings