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601 lines
32 KiB
Markdown
601 lines
32 KiB
Markdown
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# Database
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FIXME: This documentation must be updated and moved to the architecture book.
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Cuprate's blockchain implementation.
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- [1. Documentation](#1-documentation)
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- [2. File structure](#2-file-structure)
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- [2.1 `src/`](#21-src)
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- [2.2 `src/backend/`](#22-srcbackend)
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- [2.3 `src/config/`](#23-srcconfig)
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- [2.4 `src/ops/`](#24-srcops)
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- [2.5 `src/service/`](#25-srcservice)
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- [3. Backends](#3-backends)
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- [3.1 heed](#31-heed)
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- [3.2 redb](#32-redb)
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- [3.3 redb-memory](#33-redb-memory)
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- [3.4 sanakirja](#34-sanakirja)
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- [3.5 MDBX](#35-mdbx)
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- [4. Layers](#4-layers)
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- [4.1 Backend](#41-backend)
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- [4.2 Trait](#42-trait)
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- [4.3 ConcreteEnv](#43-concreteenv)
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- [4.4 ops](#44-ops)
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- [4.5 service](#45-service)
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- [5. The service](#5-the-service)
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- [5.1 Initialization](#51-initialization)
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- [5.2 Requests](#53-requests)
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- [5.3 Responses](#54-responses)
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- [5.4 Thread model](#52-thread-model)
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- [5.5 Shutdown](#55-shutdown)
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- [6. Syncing](#6-Syncing)
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- [7. Resizing](#7-resizing)
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- [8. (De)serialization](#8-deserialization)
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- [9. Schema](#9-schema)
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- [9.1 Tables](#91-tables)
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- [9.2 Multimap tables](#92-multimap-tables)
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- [10. Known issues and tradeoffs](#10-known-issues-and-tradeoffs)
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- [10.1 Traits abstracting backends](#101-traits-abstracting-backends)
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- [10.2 Hot-swappable backends](#102-hot-swappable-backends)
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- [10.3 Copying unaligned bytes](#103-copying-unaligned-bytes)
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- [10.4 Endianness](#104-endianness)
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- [10.5 Extra table data](#105-extra-table-data)
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---
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## 1. Documentation
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Documentation for `database/` is split into 3 locations:
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| Documentation location | Purpose |
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|---------------------------|---------|
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| `database/README.md` | High level design of `cuprate-database`
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| `cuprate-database` | Practical usage documentation/warnings/notes/etc
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| Source file `// comments` | Implementation-specific details (e.g, how many reader threads to spawn?)
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This README serves as the implementation design document.
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For actual practical usage, `cuprate-database`'s types and general usage are documented via standard Rust tooling.
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Run:
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```bash
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cargo doc --package cuprate-database --open
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```
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at the root of the repo to open/read the documentation.
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If this documentation is too abstract, refer to any of the source files, they are heavily commented. There are many `// Regular comments` that explain more implementation specific details that aren't present here or in the docs. Use the file reference below to find what you're looking for.
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The code within `src/` is also littered with some `grep`-able comments containing some keywords:
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| Word | Meaning |
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|-------------|---------|
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| `INVARIANT` | This code makes an _assumption_ that must be upheld for correctness
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| `SAFETY` | This `unsafe` code is okay, for `x,y,z` reasons
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| `FIXME` | This code works but isn't ideal
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| `HACK` | This code is a brittle workaround
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| `PERF` | This code is weird for performance reasons
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| `TODO` | This must be implemented; There should be 0 of these in production code
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| `SOMEDAY` | This should be implemented... someday
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## 2. File structure
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A quick reference of the structure of the folders & files in `cuprate-database`.
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Note that `lib.rs/mod.rs` files are purely for re-exporting/visibility/lints, and contain no code. Each sub-directory has a corresponding `mod.rs`.
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### 2.1 `src/`
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The top-level `src/` files.
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| File | Purpose |
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|------------------------|---------|
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| `constants.rs` | General constants used throughout `cuprate-database`
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| `database.rs` | Abstracted database; `trait DatabaseR{o,w}`
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| `env.rs` | Abstracted database environment; `trait Env`
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| `error.rs` | Database error types
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| `free.rs` | General free functions (related to the database)
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| `key.rs` | Abstracted database keys; `trait Key`
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| `resize.rs` | Database resizing algorithms
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| `storable.rs` | Data (de)serialization; `trait Storable`
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| `table.rs` | Database table abstraction; `trait Table`
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| `tables.rs` | All the table definitions used by `cuprate-database`
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| `tests.rs` | Utilities for `cuprate_database` testing
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| `transaction.rs` | Database transaction abstraction; `trait TxR{o,w}`
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| `types.rs` | Database-specific types
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| `unsafe_unsendable.rs` | Marker type to impl `Send` for objects not `Send`
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### 2.2 `src/backend/`
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This folder contains the implementation for actual databases used as the backend for `cuprate-database`.
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Each backend has its own folder.
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| Folder/File | Purpose |
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|-------------|---------|
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| `heed/` | Backend using using [`heed`](https://github.com/meilisearch/heed) (LMDB)
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| `redb/` | Backend using [`redb`](https://github.com/cberner/redb)
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| `tests.rs` | Backend-agnostic tests
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All backends follow the same file structure:
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| File | Purpose |
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|------------------|---------|
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| `database.rs` | Implementation of `trait DatabaseR{o,w}`
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| `env.rs` | Implementation of `trait Env`
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| `error.rs` | Implementation of backend's errors to `cuprate_database`'s error types
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| `storable.rs` | Compatibility layer between `cuprate_database::Storable` and backend-specific (de)serialization
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| `transaction.rs` | Implementation of `trait TxR{o,w}`
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| `types.rs` | Type aliases for long backend-specific types
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### 2.3 `src/config/`
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This folder contains the `cupate_database::config` module; configuration options for the database.
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| File | Purpose |
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|---------------------|---------|
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| `config.rs` | Main database `Config` struct
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| `reader_threads.rs` | Reader thread configuration for `service` thread-pool
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| `sync_mode.rs` | Disk sync configuration for backends
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### 2.4 `src/ops/`
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This folder contains the `cupate_database::ops` module.
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These are higher-level functions abstracted over the database, that are Monero-related.
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| File | Purpose |
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|-----------------|---------|
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| `block.rs` | Block related (main functions)
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| `blockchain.rs` | Blockchain related (height, cumulative values, etc)
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| `key_image.rs` | Key image related
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| `macros.rs` | Macros specific to `ops/`
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| `output.rs` | Output related
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| `property.rs` | Database properties (pruned, version, etc)
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| `tx.rs` | Transaction related
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### 2.5 `src/service/`
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This folder contains the `cupate_database::service` module.
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The `async`hronous request/response API other Cuprate crates use instead of managing the database directly themselves.
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| File | Purpose |
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|----------------|---------|
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| `free.rs` | General free functions used (related to `cuprate_database::service`)
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| `read.rs` | Read thread-pool definitions and logic
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| `tests.rs` | Thread-pool tests and test helper functions
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| `types.rs` | `cuprate_database::service`-related type aliases
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| `write.rs` | Writer thread definitions and logic
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## 3. Backends
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`cuprate-database`'s `trait`s allow abstracting over the actual database, such that any backend in particular could be used.
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Each database's implementation for those `trait`'s are located in its respective folder in `src/backend/${DATABASE_NAME}/`.
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### 3.1 heed
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The default database used is [`heed`](https://github.com/meilisearch/heed) (LMDB). The upstream versions from [`crates.io`](https://crates.io/crates/heed) are used. `LMDB` should not need to be installed as `heed` has a build script that pulls it in automatically.
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`heed`'s filenames inside Cuprate's database folder (`~/.local/share/cuprate/database/`) are:
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| Filename | Purpose |
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|------------|---------|
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| `data.mdb` | Main data file
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| `lock.mdb` | Database lock file
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`heed`-specific notes:
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- [There is a maximum reader limit](https://github.com/monero-project/monero/blob/059028a30a8ae9752338a7897329fe8012a310d5/src/blockchain_db/lmdb/db_lmdb.cpp#L1372). Other potential processes (e.g. `xmrblocks`) that are also reading the `data.mdb` file need to be accounted for
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- [LMDB does not work on remote filesystem](https://github.com/LMDB/lmdb/blob/b8e54b4c31378932b69f1298972de54a565185b1/libraries/liblmdb/lmdb.h#L129)
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### 3.2 redb
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The 2nd database backend is the 100% Rust [`redb`](https://github.com/cberner/redb).
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The upstream versions from [`crates.io`](https://crates.io/crates/redb) are used.
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`redb`'s filenames inside Cuprate's database folder (`~/.local/share/cuprate/database/`) are:
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| Filename | Purpose |
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|-------------|---------|
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| `data.redb` | Main data file
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<!-- TODO: document DB on remote filesystem (does redb allow this?) -->
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### 3.3 redb-memory
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This backend is 100% the same as `redb`, although, it uses `redb::backend::InMemoryBackend` which is a database that completely resides in memory instead of a file.
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All other details about this should be the same as the normal `redb` backend.
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### 3.4 sanakirja
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[`sanakirja`](https://docs.rs/sanakirja) was a candidate as a backend, however there were problems with maximum value sizes.
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The default maximum value size is [1012 bytes](https://docs.rs/sanakirja/1.4.1/sanakirja/trait.Storable.html) which was too small for our requirements. Using [`sanakirja::Slice`](https://docs.rs/sanakirja/1.4.1/sanakirja/union.Slice.html) and [sanakirja::UnsizedStorage](https://docs.rs/sanakirja/1.4.1/sanakirja/trait.UnsizedStorable.html) was attempted, but there were bugs found when inserting a value in-between `512..=4096` bytes.
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As such, it is not implemented.
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### 3.5 MDBX
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[`MDBX`](https://erthink.github.io/libmdbx) was a candidate as a backend, however MDBX deprecated the custom key/value comparison functions, this makes it a bit trickier to implement [`9.2 Multimap tables`](#92-multimap-tables). It is also quite similar to the main backend LMDB (of which it was originally a fork of).
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As such, it is not implemented (yet).
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## 4. Layers
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`cuprate_database` is logically abstracted into 5 layers, with each layer being built upon the last.
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Starting from the lowest:
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1. Backend
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2. Trait
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3. ConcreteEnv
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4. `ops`
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5. `service`
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<!-- TODO: insert image here after database/ split -->
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### 4.1 Backend
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This is the actual database backend implementation (or a Rust shim over one).
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Examples:
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- `heed` (LMDB)
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- `redb`
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`cuprate_database` itself just uses a backend, it does not implement one.
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All backends have the following attributes:
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- [Embedded](https://en.wikipedia.org/wiki/Embedded_database)
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- [Multiversion concurrency control](https://en.wikipedia.org/wiki/Multiversion_concurrency_control)
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- [ACID](https://en.wikipedia.org/wiki/ACID)
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- Are `(key, value)` oriented and have the expected API (`get()`, `insert()`, `delete()`)
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- Are table oriented (`"table_name" -> (key, value)`)
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- Allows concurrent readers
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### 4.2 Trait
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`cuprate_database` provides a set of `trait`s that abstract over the various database backends.
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This allows the function signatures and behavior to stay the same but allows for swapping out databases in an easier fashion.
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All common behavior of the backend's are encapsulated here and used instead of using the backend directly.
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Examples:
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- [`trait Env`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/env.rs)
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- [`trait {TxRo, TxRw}`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/transaction.rs)
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- [`trait {DatabaseRo, DatabaseRw}`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/database.rs)
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For example, instead of calling `LMDB` or `redb`'s `get()` function directly, `DatabaseRo::get()` is called.
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### 4.3 ConcreteEnv
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This is the non-generic, concrete `struct` provided by `cuprate_database` that contains all the data necessary to operate the database. The actual database backend `ConcreteEnv` will use internally depends on which backend feature is used.
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`ConcreteEnv` implements `trait Env`, which opens the door to all the other traits.
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The equivalent objects in the backends themselves are:
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- [`heed::Env`](https://docs.rs/heed/0.20.0/heed/struct.Env.html)
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- [`redb::Database`](https://docs.rs/redb/2.1.0/redb/struct.Database.html)
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This is the main object used when handling the database directly, although that is not strictly necessary as a user if the [`4.5 service`](#45-service) layer is used.
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### 4.4 ops
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These are Monero-specific functions that use the abstracted `trait` forms of the database.
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Instead of dealing with the database directly:
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- `get()`
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- `delete()`
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the `ops` layer provides more abstract functions that deal with commonly used Monero operations:
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- `add_block()`
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- `pop_block()`
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### 4.5 service
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The final layer abstracts the database completely into a [Monero-specific `async` request/response API](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/types/src/service.rs#L18-L78) using [`tower::Service`](https://docs.rs/tower/latest/tower/trait.Service.html).
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For more information on this layer, see the next section: [`5. The service`](#5-the-service).
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## 5. The service
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The main API `cuprate_database` exposes for other crates to use is the `cuprate_database::service` module.
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This module exposes an `async` request/response API with `tower::Service`, backed by a threadpool, that allows reading/writing Monero-related data from/to the database.
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`cuprate_database::service` itself manages the database using a separate writer thread & reader thread-pool, and uses the previously mentioned [`4.4 ops`](#44-ops) functions when responding to requests.
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### 5.1 Initialization
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The service is started simply by calling: [`cuprate_database::service::init()`](https://github.com/Cuprate/cuprate/blob/d0ac94a813e4cd8e0ed8da5e85a53b1d1ace2463/database/src/service/free.rs#L23).
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This function initializes the database, spawns threads, and returns a:
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- Read handle to the database (cloneable)
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- Write handle to the database (not cloneable)
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These "handles" implement the `tower::Service` trait, which allows sending requests and receiving responses `async`hronously.
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### 5.2 Requests
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Along with the 2 handles, there are 2 types of requests:
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- [`ReadRequest`](https://github.com/Cuprate/cuprate/blob/d0ac94a813e4cd8e0ed8da5e85a53b1d1ace2463/types/src/service.rs#L23-L90)
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- [`WriteRequest`](https://github.com/Cuprate/cuprate/blob/d0ac94a813e4cd8e0ed8da5e85a53b1d1ace2463/types/src/service.rs#L93-L105)
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`ReadRequest` is for retrieving various types of information from the database.
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`WriteRequest` currently only has 1 variant: to write a block to the database.
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### 5.3 Responses
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After sending one of the above requests using the read/write handle, the value returned is _not_ the response, yet an `async`hronous channel that will eventually return the response:
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```rust,ignore
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// Send a request.
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// tower::Service::call()
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// V
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let response_channel: Channel = read_handle.call(ReadResponse::ChainHeight)?;
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// Await the response.
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let response: ReadResponse = response_channel.await?;
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// Assert the response is what we expected.
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assert_eq!(matches!(response), Response::ChainHeight(_));
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```
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After `await`ing the returned channel, a `Response` will eventually be returned when the `service` threadpool has fetched the value from the database and sent it off.
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Both read/write requests variants match in name with `Response` variants, i.e.
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- `ReadRequest::ChainHeight` leads to `Response::ChainHeight`
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- `WriteRequest::WriteBlock` leads to `Response::WriteBlockOk`
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### 5.4 Thread model
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As mentioned in the [`4. Layers`](#4-layers) section, the base database abstractions themselves are not concerned with parallelism, they are mostly functions to be called from a single-thread.
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However, the `cuprate_database::service` API, _does_ have a thread model backing it.
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When [`cuprate_database::service`'s initialization function](https://github.com/Cuprate/cuprate/blob/9c27ba5791377d639cb5d30d0f692c228568c122/database/src/service/free.rs#L33-L44) is called, threads will be spawned and maintained until the user drops (disconnects) the returned handles.
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The current behavior for thread count is:
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- [1 writer thread](https://github.com/Cuprate/cuprate/blob/9c27ba5791377d639cb5d30d0f692c228568c122/database/src/service/write.rs#L52-L66)
|
||
|
- [As many reader threads as there are system threads](https://github.com/Cuprate/cuprate/blob/9c27ba5791377d639cb5d30d0f692c228568c122/database/src/service/read.rs#L104-L126)
|
||
|
|
||
|
For example, on a system with 32-threads, `cuprate_database` will spawn:
|
||
|
- 1 writer thread
|
||
|
- 32 reader threads
|
||
|
|
||
|
whose sole responsibility is to listen for database requests, access the database (potentially in parallel), and return a response.
|
||
|
|
||
|
Note that the `1 system thread = 1 reader thread` model is only the default setting, the reader thread count can be configured by the user to be any number between `1 .. amount_of_system_threads`.
|
||
|
|
||
|
The reader threads are managed by [`rayon`](https://docs.rs/rayon).
|
||
|
|
||
|
For an example of where multiple reader threads are used: given a request that asks if any key-image within a set already exists, `cuprate_database` will [split that work between the threads with `rayon`](https://github.com/Cuprate/cuprate/blob/9c27ba5791377d639cb5d30d0f692c228568c122/database/src/service/read.rs#L490-L503).
|
||
|
|
||
|
### 5.5 Shutdown
|
||
|
Once the read/write handles are `Drop`ed, the backing thread(pool) will gracefully exit, automatically.
|
||
|
|
||
|
Note the writer thread and reader threadpool aren't connected whatsoever; dropping the write handle will make the writer thread exit, however, the reader handle is free to be held onto and can be continued to be read from - and vice-versa for the write handle.
|
||
|
|
||
|
## 6. Syncing
|
||
|
`cuprate_database`'s database has 5 disk syncing modes.
|
||
|
|
||
|
1. FastThenSafe
|
||
|
1. Safe
|
||
|
1. Async
|
||
|
1. Threshold
|
||
|
1. Fast
|
||
|
|
||
|
The default mode is `Safe`.
|
||
|
|
||
|
This means that upon each transaction commit, all the data that was written will be fully synced to disk. This is the slowest, but safest mode of operation.
|
||
|
|
||
|
Note that upon any database `Drop`, whether via `service` or dropping the database directly, the current implementation will sync to disk regardless of any configuration.
|
||
|
|
||
|
For more information on the other modes, read the documentation [here](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/config/sync_mode.rs#L63-L144).
|
||
|
|
||
|
## 7. Resizing
|
||
|
Database backends that require manually resizing will, by default, use a similar algorithm as `monerod`'s.
|
||
|
|
||
|
Note that this only relates to the `service` module, where the database is handled by `cuprate_database` itself, not the user. In the case of a user directly using `cuprate_database`, it is up to them on how to resize.
|
||
|
|
||
|
Within `service`, the resizing logic defined [here](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/service/write.rs#L139-L201) does the following:
|
||
|
|
||
|
- If there's not enough space to fit a write request's data, start a resize
|
||
|
- Each resize adds around [`1_073_745_920`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/resize.rs#L104-L160) bytes to the current map size
|
||
|
- A resize will be attempted `3` times before failing
|
||
|
|
||
|
There are other [resizing algorithms](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/resize.rs#L38-L47) that define how the database's memory map grows, although currently the behavior of [`monerod`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/resize.rs#L104-L160) is closely followed.
|
||
|
|
||
|
## 8. (De)serialization
|
||
|
All types stored inside the database are either bytes already, or are perfectly bitcast-able.
|
||
|
|
||
|
As such, they do not incur heavy (de)serialization costs when storing/fetching them from the database. The main (de)serialization used is [`bytemuck`](https://docs.rs/bytemuck)'s traits and casting functions.
|
||
|
|
||
|
The size & layout of types is stable across compiler versions, as they are set and determined with [`#[repr(C)]`](https://doc.rust-lang.org/nomicon/other-reprs.html#reprc) and `bytemuck`'s derive macros such as [`bytemuck::Pod`](https://docs.rs/bytemuck/latest/bytemuck/derive.Pod.html).
|
||
|
|
||
|
Note that the data stored in the tables are still type-safe; we still refer to the key and values within our tables by the type.
|
||
|
|
||
|
The main deserialization `trait` for database storage is: [`cuprate_database::Storable`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/storable.rs#L16-L115).
|
||
|
|
||
|
- Before storage, the type is [simply cast into bytes](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/storable.rs#L125)
|
||
|
- When fetching, the bytes are [simply cast into the type](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/storable.rs#L130)
|
||
|
|
||
|
When a type is casted into bytes, [the reference is casted](https://docs.rs/bytemuck/latest/bytemuck/fn.bytes_of.html), i.e. this is zero-cost serialization.
|
||
|
|
||
|
However, it is worth noting that when bytes are casted into the type, [it is copied](https://docs.rs/bytemuck/latest/bytemuck/fn.pod_read_unaligned.html). This is due to byte alignment guarantee issues with both backends, see:
|
||
|
- https://github.com/AltSysrq/lmdb-zero/issues/8
|
||
|
- https://github.com/cberner/redb/issues/360
|
||
|
|
||
|
Without this, `bytemuck` will panic with [`TargetAlignmentGreaterAndInputNotAligned`](https://docs.rs/bytemuck/latest/bytemuck/enum.PodCastError.html#variant.TargetAlignmentGreaterAndInputNotAligned) when casting.
|
||
|
|
||
|
Copying the bytes fixes this problem, although it is more costly than necessary. However, in the main use-case for `cuprate_database` (the `service` module) the bytes would need to be owned regardless as the `Request/Response` API uses owned data types (`T`, `Vec<T>`, `HashMap<K, V>`, etc).
|
||
|
|
||
|
Practically speaking, this means lower-level database functions that normally look like such:
|
||
|
```rust
|
||
|
fn get(key: &Key) -> &Value;
|
||
|
```
|
||
|
end up looking like this in `cuprate_database`:
|
||
|
```rust
|
||
|
fn get(key: &Key) -> Value;
|
||
|
```
|
||
|
|
||
|
Since each backend has its own (de)serialization methods, our types are wrapped in compatibility types that map our `Storable` functions into whatever is required for the backend, e.g:
|
||
|
- [`StorableHeed<T>`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/backend/heed/storable.rs#L11-L45)
|
||
|
- [`StorableRedb<T>`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/backend/redb/storable.rs#L11-L30)
|
||
|
|
||
|
Compatibility structs also exist for any `Storable` containers:
|
||
|
- [`StorableVec<T>`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/storable.rs#L135-L191)
|
||
|
- [`StorableBytes`](https://github.com/Cuprate/cuprate/blob/2ac90420c658663564a71b7ecb52d74f3c2c9d0f/database/src/storable.rs#L208-L241)
|
||
|
|
||
|
Again, it's unfortunate that these must be owned, although in `service`'s use-case, they would have to be owned anyway.
|
||
|
|
||
|
## 9. Schema
|
||
|
This following section contains Cuprate's database schema, it may change throughout the development of Cuprate, as such, nothing here is final.
|
||
|
|
||
|
### 9.1 Tables
|
||
|
The `CamelCase` names of the table headers documented here (e.g. `TxIds`) are the actual type name of the table within `cuprate_database`.
|
||
|
|
||
|
Note that words written within `code blocks` mean that it is a real type defined and usable within `cuprate_database`. Other standard types like u64 and type aliases (TxId) are written normally.
|
||
|
|
||
|
Within `cuprate_database::tables`, the below table is essentially defined as-is with [a macro](https://github.com/Cuprate/cuprate/blob/31ce89412aa174fc33754f22c9a6d9ef5ddeda28/database/src/tables.rs#L369-L470).
|
||
|
|
||
|
Many of the data types stored are the same data types, although are different semantically, as such, a map of aliases used and their real data types is also provided below.
|
||
|
|
||
|
| Alias | Real Type |
|
||
|
|----------------------------------------------------|-----------|
|
||
|
| BlockHeight, Amount, AmountIndex, TxId, UnlockTime | u64
|
||
|
| BlockHash, KeyImage, TxHash, PrunableHash | [u8; 32]
|
||
|
|
||
|
| Table | Key | Value | Description |
|
||
|
|-------------------|----------------------|--------------------|-------------|
|
||
|
| `BlockBlobs` | BlockHeight | `StorableVec<u8>` | Maps a block's height to a serialized byte form of a block
|
||
|
| `BlockHeights` | BlockHash | BlockHeight | Maps a block's hash to its height
|
||
|
| `BlockInfos` | BlockHeight | `BlockInfo` | Contains metadata of all blocks
|
||
|
| `KeyImages` | KeyImage | () | This table is a set with no value, it stores transaction key images
|
||
|
| `NumOutputs` | Amount | u64 | Maps an output's amount to the number of outputs with that amount
|
||
|
| `Outputs` | `PreRctOutputId` | `Output` | This table contains legacy CryptoNote outputs which have clear amounts. This table will not contain an output with 0 amount.
|
||
|
| `PrunedTxBlobs` | TxId | `StorableVec<u8>` | Contains pruned transaction blobs (even if the database is not pruned)
|
||
|
| `PrunableTxBlobs` | TxId | `StorableVec<u8>` | Contains the prunable part of a transaction
|
||
|
| `PrunableHashes` | TxId | PrunableHash | Contains the hash of the prunable part of a transaction
|
||
|
| `RctOutputs` | AmountIndex | `RctOutput` | Contains RingCT outputs mapped from their global RCT index
|
||
|
| `TxBlobs` | TxId | `StorableVec<u8>` | Serialized transaction blobs (bytes)
|
||
|
| `TxIds` | TxHash | TxId | Maps a transaction's hash to its index/ID
|
||
|
| `TxHeights` | TxId | BlockHeight | Maps a transaction's ID to the height of the block it comes from
|
||
|
| `TxOutputs` | TxId | `StorableVec<u64>` | Gives the amount indices of a transaction's outputs
|
||
|
| `TxUnlockTime` | TxId | UnlockTime | Stores the unlock time of a transaction (only if it has a non-zero lock time)
|
||
|
|
||
|
The definitions for aliases and types (e.g. `RctOutput`) are within the [`cuprate_database::types`](https://github.com/Cuprate/cuprate/blob/31ce89412aa174fc33754f22c9a6d9ef5ddeda28/database/src/types.rs#L51) module.
|
||
|
|
||
|
<!-- TODO(Boog900): We could split this table again into `RingCT (non-miner) Outputs` and `RingCT (miner) Outputs` as for miner outputs we can store the amount instead of commitment saving 24 bytes per miner output. -->
|
||
|
|
||
|
### 9.2 Multimap tables
|
||
|
When referencing outputs, Monero will [use the amount and the amount index](https://github.com/monero-project/monero/blob/c8214782fb2a769c57382a999eaf099691c836e7/src/blockchain_db/lmdb/db_lmdb.cpp#L3447-L3449). This means 2 keys are needed to reach an output.
|
||
|
|
||
|
With LMDB you can set the `DUP_SORT` flag on a table and then set the key/value to:
|
||
|
```rust
|
||
|
Key = KEY_PART_1
|
||
|
```
|
||
|
```rust
|
||
|
Value = {
|
||
|
KEY_PART_2,
|
||
|
VALUE // The actual value we are storing.
|
||
|
}
|
||
|
```
|
||
|
|
||
|
Then you can set a custom value sorting function that only takes `KEY_PART_2` into account; this is how `monerod` does it.
|
||
|
|
||
|
This requires that the underlying database supports:
|
||
|
- multimap tables
|
||
|
- custom sort functions on values
|
||
|
- setting a cursor on a specific key/value
|
||
|
|
||
|
---
|
||
|
|
||
|
Another way to implement this is as follows:
|
||
|
```rust
|
||
|
Key = { KEY_PART_1, KEY_PART_2 }
|
||
|
```
|
||
|
```rust
|
||
|
Value = VALUE
|
||
|
```
|
||
|
|
||
|
Then the key type is simply used to look up the value; this is how `cuprate_database` does it.
|
||
|
|
||
|
For example, the key/value pair for outputs is:
|
||
|
```rust
|
||
|
PreRctOutputId => Output
|
||
|
```
|
||
|
where `PreRctOutputId` looks like this:
|
||
|
```rust
|
||
|
struct PreRctOutputId {
|
||
|
amount: u64,
|
||
|
amount_index: u64,
|
||
|
}
|
||
|
```
|
||
|
|
||
|
## 10. Known issues and tradeoffs
|
||
|
`cuprate_database` takes many tradeoffs, whether due to:
|
||
|
- Prioritizing certain values over others
|
||
|
- Not having a better solution
|
||
|
- Being "good enough"
|
||
|
|
||
|
This is a list of the larger ones, along with issues that don't have answers yet.
|
||
|
|
||
|
### 10.1 Traits abstracting backends
|
||
|
Although all database backends used are very similar, they have some crucial differences in small implementation details that must be worked around when conforming them to `cuprate_database`'s traits.
|
||
|
|
||
|
Put simply: using `cuprate_database`'s traits is less efficient and more awkward than using the backend directly.
|
||
|
|
||
|
For example:
|
||
|
- [Data types must be wrapped in compatibility layers when they otherwise wouldn't be](https://github.com/Cuprate/cuprate/blob/d0ac94a813e4cd8e0ed8da5e85a53b1d1ace2463/database/src/backend/heed/env.rs#L101-L116)
|
||
|
- [There are types that only apply to a specific backend, but are visible to all](https://github.com/Cuprate/cuprate/blob/d0ac94a813e4cd8e0ed8da5e85a53b1d1ace2463/database/src/error.rs#L86-L89)
|
||
|
- [There are extra layers of abstraction to smoothen the differences between all backends](https://github.com/Cuprate/cuprate/blob/d0ac94a813e4cd8e0ed8da5e85a53b1d1ace2463/database/src/env.rs#L62-L68)
|
||
|
- [Existing functionality of backends must be taken away, as it isn't supported in the others](https://github.com/Cuprate/cuprate/blob/d0ac94a813e4cd8e0ed8da5e85a53b1d1ace2463/database/src/database.rs#L27-L34)
|
||
|
|
||
|
This is a _tradeoff_ that `cuprate_database` takes, as:
|
||
|
- The backend itself is usually not the source of bottlenecks in the greater system, as such, small inefficiencies are OK
|
||
|
- None of the lost functionality is crucial for operation
|
||
|
- The ability to use, test, and swap between multiple database backends is [worth it](https://github.com/Cuprate/cuprate/pull/35#issuecomment-1952804393)
|
||
|
|
||
|
### 10.2 Hot-swappable backends
|
||
|
Using a different backend is really as simple as re-building `cuprate_database` with a different feature flag:
|
||
|
```bash
|
||
|
# Use LMDB.
|
||
|
cargo build --package cuprate-database --features heed
|
||
|
|
||
|
# Use redb.
|
||
|
cargo build --package cuprate-database --features redb
|
||
|
```
|
||
|
|
||
|
This is "good enough" for now, however ideally, this hot-swapping of backends would be able to be done at _runtime_.
|
||
|
|
||
|
As it is now, `cuprate_database` cannot compile both backends and swap based on user input at runtime; it must be compiled with a certain backend, which will produce a binary with only that backend.
|
||
|
|
||
|
This also means things like [CI testing multiple backends is awkward](https://github.com/Cuprate/cuprate/blob/main/.github/workflows/ci.yml#L132-L136), as we must re-compile with different feature flags instead.
|
||
|
|
||
|
### 10.3 Copying unaligned bytes
|
||
|
As mentioned in [`8. (De)serialization`](#8-deserialization), bytes are _copied_ when they are turned into a type `T` due to unaligned bytes being returned from database backends.
|
||
|
|
||
|
Using a regular reference cast results in an improperly aligned type `T`; [such a type even existing causes undefined behavior](https://doc.rust-lang.org/reference/behavior-considered-undefined.html). In our case, `bytemuck` saves us by panicking before this occurs.
|
||
|
|
||
|
Thus, when using `cuprate_database`'s database traits, an _owned_ `T` is returned.
|
||
|
|
||
|
This is doubly unfortunately for `&[u8]` as this does not even need deserialization.
|
||
|
|
||
|
For example, `StorableVec` could have been this:
|
||
|
```rust
|
||
|
enum StorableBytes<'a, T: Storable> {
|
||
|
Owned(T),
|
||
|
Ref(&'a T),
|
||
|
}
|
||
|
```
|
||
|
but this would require supporting types that must be copied regardless with the occasional `&[u8]` that can be returned without casting. This was hard to do so in a generic way, thus all `[u8]`'s are copied and returned as owned `StorableVec`s.
|
||
|
|
||
|
This is a _tradeoff_ `cuprate_database` takes as:
|
||
|
- `bytemuck::pod_read_unaligned` is cheap enough
|
||
|
- The main API, `service`, needs to return owned value anyway
|
||
|
- Having no references removes a lot of lifetime complexity
|
||
|
|
||
|
The alternative is either:
|
||
|
- Using proper (de)serialization instead of casting (which comes with its own costs)
|
||
|
- Somehow fixing the alignment issues in the backends mentioned previously
|
||
|
|
||
|
### 10.4 Endianness
|
||
|
`cuprate_database`'s (de)serialization and storage of bytes are native-endian, as in, byte storage order will depend on the machine it is running on.
|
||
|
|
||
|
As Cuprate's build-targets are all little-endian ([big-endian by default machines barely exist](https://en.wikipedia.org/wiki/Endianness#Hardware)), this doesn't matter much and the byte ordering can be seen as a constant.
|
||
|
|
||
|
Practically, this means `cuprated`'s database files can be transferred across computers, as can `monerod`'s.
|
||
|
|
||
|
### 10.5 Extra table data
|
||
|
Some of `cuprate_database`'s tables differ from `monerod`'s tables, for example, the way [`9.2 Multimap tables`](#92-multimap-tables) tables are done requires that the primary key is stored _for all_ entries, compared to `monerod` only needing to store it once.
|
||
|
|
||
|
For example:
|
||
|
```rust
|
||
|
// `monerod` only stores `amount: 1` once,
|
||
|
// `cuprated` stores it each time it appears.
|
||
|
struct PreRctOutputId { amount: 1, amount_index: 0 }
|
||
|
struct PreRctOutputId { amount: 1, amount_index: 1 }
|
||
|
```
|
||
|
|
||
|
This means `cuprated`'s database will be slightly larger than `monerod`'s.
|
||
|
|
||
|
The current method `cuprate_database` uses will be "good enough" until usage shows that it must be optimized as multimap tables are tricky to implement across all backends.
|