// Copyright 2018-2019 Mozilla // // Licensed under the Apache License, Version 2.0 (the "License"); you may not use // this file except in compliance with the License. You may obtain a copy of the // License at http://www.apache.org/licenses/LICENSE-2.0 // Unless required by applicable law or agreed to in writing, software distributed // under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR // CONDITIONS OF ANY KIND, either express or implied. See the License for the // specific language governing permissions and limitations under the License. #![allow(clippy::from_over_into)] // TODO: `Into` implementations in [safe/lmdb]/flags.rs //! A simple, humane, typed key-value storage solution. It supports multiple backend //! engines with varying guarantees, such as [LMDB](http://www.lmdb.tech/doc/) for //! performance, or "SafeMode" for reliability. //! //! It aims to achieve the following: //! //! - Avoid sharp edges (e.g., obscure error codes for common situations). //! - Correctly restrict access to one handle per process via a //! [Manager](struct.Manager.html). //! - Use Rust's type system to make single-typed key stores safe and ergonomic. //! - Encode and decode values via [bincode](https://docs.rs/bincode/)/[serde](https://docs.rs/serde/) //! and type tags, achieving platform-independent storage and input/output flexibility. //! //! It exposes these primary abstractions: //! //! - [Manager](struct.Manager.html): a singleton that controls access to environments //! - [Rkv](struct.Rkv.html): an environment contains a set of key/value databases //! - [SingleStore](store/single/struct.SingleStore.html): a database contains a set of //! key/value pairs //! //! Keys can be anything that implements `AsRef<[u8]>` or integers //! (when accessing an [IntegerStore](store/integer/struct.IntegerStore.html)). //! //! Values can be any of the types defined by the [Value](value/enum.Value.html) enum, //! including: //! //! - booleans (`Value::Bool`) //! - integers (`Value::I64`, `Value::U64`) //! - floats (`Value::F64`) //! - strings (`Value::Str`) //! - blobs (`Value::Blob`) //! //! See [Value](value/enum.Value.html) for the complete list of supported types. //! //! ## Basic Usage //! ``` //! use rkv::{Manager, Rkv, SingleStore, Value, StoreOptions}; //! use rkv::backend::{SafeMode, SafeModeEnvironment}; //! use std::fs; //! use tempfile::Builder; //! //! // First determine the path to the environment, which is represented on disk as a //! // directory containing two files: //! // //! // * a data file containing the key/value stores //! // * a lock file containing metadata about current transactions //! // //! // In this example, we use the `tempfile` crate to create the directory. //! // //! let root = Builder::new().prefix("simple-db").tempdir().unwrap(); //! fs::create_dir_all(root.path()).unwrap(); //! let path = root.path(); //! //! // The `Manager` enforces that each process opens the same environment at most once by //! // caching a handle to each environment that it opens. Use it to retrieve the handle //! // to an opened environment—or create one if it hasn't already been opened: //! let mut manager = Manager::::singleton().write().unwrap(); //! let created_arc = manager.get_or_create(path, Rkv::new::).unwrap(); //! let env = created_arc.read().unwrap(); //! //! // Then you can use the environment handle to get a handle to a datastore: //! let store = env.open_single("mydb", StoreOptions::create()).unwrap(); //! //! { //! // Use a write transaction to mutate the store via a `Writer`. There can be only //! // one writer for a given environment, so opening a second one will block until //! // the first completes. //! let mut writer = env.write().unwrap(); //! //! // Keys are `AsRef<[u8]>`, while values are `Value` enum instances. Use the `Blob` //! // variant to store arbitrary collections of bytes. Putting data returns a //! // `Result<(), StoreError>`, where StoreError is an enum identifying the reason //! // for a failure. //! store.put(&mut writer, "int", &Value::I64(1234)).unwrap(); //! store.put(&mut writer, "uint", &Value::U64(1234_u64)).unwrap(); //! store.put(&mut writer, "float", &Value::F64(1234.0.into())).unwrap(); //! store.put(&mut writer, "instant", &Value::Instant(1528318073700)).unwrap(); //! store.put(&mut writer, "boolean", &Value::Bool(true)).unwrap(); //! store.put(&mut writer, "string", &Value::Str("Héllo, wörld!")).unwrap(); //! store.put(&mut writer, "json", &Value::Json(r#"{"foo":"bar", "number": 1}"#)).unwrap(); //! store.put(&mut writer, "blob", &Value::Blob(b"blob")).unwrap(); //! //! // You must commit a write transaction before the writer goes out of scope, or the //! // transaction will abort and the data won't persist. //! writer.commit().unwrap(); //! } //! //! { //! // Use a read transaction to query the store via a `Reader`. There can be multiple //! // concurrent readers for a store, and readers never block on a writer nor other //! // readers. //! let reader = env.read().expect("reader"); //! //! // Keys are `AsRef`, and the return value is `Result, StoreError>`. //! println!("Get int {:?}", store.get(&reader, "int").unwrap()); //! println!("Get uint {:?}", store.get(&reader, "uint").unwrap()); //! println!("Get float {:?}", store.get(&reader, "float").unwrap()); //! println!("Get instant {:?}", store.get(&reader, "instant").unwrap()); //! println!("Get boolean {:?}", store.get(&reader, "boolean").unwrap()); //! println!("Get string {:?}", store.get(&reader, "string").unwrap()); //! println!("Get json {:?}", store.get(&reader, "json").unwrap()); //! println!("Get blob {:?}", store.get(&reader, "blob").unwrap()); //! //! // Retrieving a non-existent value returns `Ok(None)`. //! println!("Get non-existent value {:?}", store.get(&reader, "non-existent").unwrap()); //! //! // A read transaction will automatically close once the reader goes out of scope, //! // so isn't necessary to close it explicitly, although you can do so by calling //! // `Reader.abort()`. //! } //! //! { //! // Aborting a write transaction rolls back the change(s). //! let mut writer = env.write().unwrap(); //! store.put(&mut writer, "foo", &Value::Str("bar")).unwrap(); //! writer.abort(); //! let reader = env.read().expect("reader"); //! println!("It should be None! ({:?})", store.get(&reader, "foo").unwrap()); //! } //! //! { //! // Explicitly aborting a transaction is not required unless an early abort is //! // desired, since both read and write transactions will implicitly be aborted once //! // they go out of scope. //! { //! let mut writer = env.write().unwrap(); //! store.put(&mut writer, "foo", &Value::Str("bar")).unwrap(); //! } //! let reader = env.read().expect("reader"); //! println!("It should be None! ({:?})", store.get(&reader, "foo").unwrap()); //! } //! //! { //! // Deleting a key/value pair also requires a write transaction. //! let mut writer = env.write().unwrap(); //! store.put(&mut writer, "foo", &Value::Str("bar")).unwrap(); //! store.put(&mut writer, "bar", &Value::Str("baz")).unwrap(); //! store.delete(&mut writer, "foo").unwrap(); //! //! // A write transaction also supports reading, and the version of the store that it //! // reads includes the changes it has made regardless of the commit state of that //! // transaction. //! // In the code above, "foo" and "bar" were put into the store, then "foo" was //! // deleted so only "bar" will return a result when the database is queried via the //! // writer. //! println!("It should be None! ({:?})", store.get(&writer, "foo").unwrap()); //! println!("Get bar ({:?})", store.get(&writer, "bar").unwrap()); //! //! // But a reader won't see that change until the write transaction is committed. //! { //! let reader = env.read().expect("reader"); //! println!("Get foo {:?}", store.get(&reader, "foo").unwrap()); //! println!("Get bar {:?}", store.get(&reader, "bar").unwrap()); //! } //! writer.commit().unwrap(); //! { //! let reader = env.read().expect("reader"); //! println!("It should be None! ({:?})", store.get(&reader, "foo").unwrap()); //! println!("Get bar {:?}", store.get(&reader, "bar").unwrap()); //! } //! //! // Committing a transaction consumes the writer, preventing you from reusing it by //! // failing at compile time with an error. This line would report "error[E0382]: //! // borrow of moved value: `writer`". //! // store.put(&mut writer, "baz", &Value::Str("buz")).unwrap(); //! } //! //! { //! // Clearing all the entries in the store with a write transaction. //! { //! let mut writer = env.write().unwrap(); //! store.put(&mut writer, "foo", &Value::Str("bar")).unwrap(); //! store.put(&mut writer, "bar", &Value::Str("baz")).unwrap(); //! writer.commit().unwrap(); //! } //! //! { //! let mut writer = env.write().unwrap(); //! store.clear(&mut writer).unwrap(); //! writer.commit().unwrap(); //! } //! //! { //! let reader = env.read().expect("reader"); //! println!("It should be None! ({:?})", store.get(&reader, "foo").unwrap()); //! println!("It should be None! ({:?})", store.get(&reader, "bar").unwrap()); //! } //! //! } //! //! ``` mod env; mod error; mod helpers; mod manager; mod readwrite; pub mod backend; #[cfg(feature = "lmdb")] pub mod migrator; pub mod store; pub mod value; pub use backend::{DatabaseFlags, EnvironmentFlags, WriteFlags}; pub use env::Rkv; pub use error::{DataError, MigrateError, StoreError}; pub use manager::Manager; #[cfg(feature = "lmdb")] pub use migrator::Migrator; pub use readwrite::{Readable, Reader, Writer}; pub use store::{keys::EncodableKey, single::SingleStore, CloseOptions, Options as StoreOptions}; pub use value::{OwnedValue, Value}; #[cfg(feature = "db-dup-sort")] pub use store::multi::MultiStore; #[cfg(feature = "db-int-key")] pub use store::integer::IntegerStore; #[cfg(feature = "db-int-key")] pub use store::keys::PrimitiveInt; #[cfg(all(feature = "db-dup-sort", feature = "db-int-key"))] pub use store::integermulti::MultiIntegerStore;