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92ebf4afe5
This commit adds unstable "Deno.openKv()" API that allows to open a key-value database at a specified path. --------- Co-authored-by: Luca Casonato <hello@lcas.dev> Co-authored-by: Bartek Iwańczuk <biwanczuk@gmail.com>
294 lines
9.5 KiB
Rust
294 lines
9.5 KiB
Rust
// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license.
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use std::cell::RefCell;
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use std::cmp::Ordering;
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use std::num::NonZeroU32;
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use std::rc::Rc;
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use async_trait::async_trait;
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use deno_core::error::AnyError;
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use deno_core::OpState;
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use num_bigint::BigInt;
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use crate::codec::canonicalize_f64;
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#[async_trait(?Send)]
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pub trait DatabaseHandler {
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type DB: Database + 'static;
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async fn open(
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&self,
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state: Rc<RefCell<OpState>>,
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path: Option<String>,
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) -> Result<Self::DB, AnyError>;
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}
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#[async_trait(?Send)]
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pub trait Database {
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async fn snapshot_read(
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&self,
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requests: Vec<ReadRange>,
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options: SnapshotReadOptions,
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) -> Result<Vec<ReadRangeOutput>, AnyError>;
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async fn atomic_write(&self, write: AtomicWrite) -> Result<bool, AnyError>;
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}
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/// Options for a snapshot read.
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pub struct SnapshotReadOptions {
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pub consistency: Consistency,
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}
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/// The consistency of a read.
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#[derive(Eq, PartialEq, Copy, Clone, Debug)]
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pub enum Consistency {
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Strong,
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Eventual,
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}
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/// A key is for a KV pair. It is a vector of KeyParts.
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///
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/// The ordering of the keys is defined by the ordering of the KeyParts. The
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/// first KeyPart is the most significant, and the last KeyPart is the least
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/// significant.
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#[derive(Eq, PartialEq, Ord, PartialOrd, Clone, Debug)]
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pub struct Key(pub Vec<KeyPart>);
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/// A key part is single item in a key. It can be a boolean, a double float, a
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/// variable precision signed integer, a UTF-8 string, or an arbitrary byte
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/// array.
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///
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/// The ordering of a KeyPart is dependent on the type of the KeyPart.
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///
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/// Between different types, the ordering is as follows: arbitrary byte array <
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/// UTF-8 string < variable precision signed integer < double float < false < true.
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///
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/// Within a type, the ordering is as follows:
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/// - For a **boolean**, false is less than true.
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/// - For a **double float**, the ordering must follow -NaN < -Infinity < -100.0 < -1.0 < -0.5 < -0.0 < 0.0 < 0.5 < 1.0 < 100.0 < Infinity < NaN.
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/// - For a **variable precision signed integer**, the ordering must follow mathematical ordering.
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/// - For a **UTF-8 string**, the ordering must follow the UTF-8 byte ordering.
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/// - For an **arbitrary byte array**, the ordering must follow the byte ordering.
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///
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/// This means that the key part `1.0` is less than the key part `2.0`, but is
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/// greater than the key part `0n`, because `1.0` is a double float and `0n`
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/// is a variable precision signed integer, and the ordering types obviously has
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/// precedence over the ordering within a type.
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#[derive(Clone, Debug)]
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pub enum KeyPart {
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Bytes(Vec<u8>),
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String(String),
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Int(BigInt),
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Float(f64),
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False,
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True,
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}
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impl KeyPart {
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fn tag_ordering(&self) -> u8 {
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match self {
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KeyPart::Bytes(_) => 0,
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KeyPart::String(_) => 1,
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KeyPart::Int(_) => 2,
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KeyPart::Float(_) => 3,
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KeyPart::False => 4,
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KeyPart::True => 5,
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}
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}
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}
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impl Eq for KeyPart {}
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impl PartialEq for KeyPart {
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fn eq(&self, other: &Self) -> bool {
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self.cmp(other) == Ordering::Equal
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}
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}
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impl Ord for KeyPart {
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fn cmp(&self, other: &Self) -> Ordering {
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match (self, other) {
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(KeyPart::Bytes(b1), KeyPart::Bytes(b2)) => b1.cmp(b2),
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(KeyPart::String(s1), KeyPart::String(s2)) => {
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s1.as_bytes().cmp(s2.as_bytes())
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}
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(KeyPart::Int(i1), KeyPart::Int(i2)) => i1.cmp(i2),
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(KeyPart::Float(f1), KeyPart::Float(f2)) => {
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canonicalize_f64(*f1).total_cmp(&canonicalize_f64(*f2))
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}
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_ => self.tag_ordering().cmp(&other.tag_ordering()),
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}
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}
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}
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impl PartialOrd for KeyPart {
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fn partial_cmp(&self, other: &Self) -> Option<std::cmp::Ordering> {
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Some(self.cmp(other))
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}
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}
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/// A request to read a range of keys from the database. If `end` is `None`,
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/// then the range is from `start` shall also be used as the end of the range.
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///
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/// The range is inclusive of the start and exclusive of the end. The start may
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/// not be greater than the end.
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///
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/// The range is limited to `limit` number of entries.
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pub struct ReadRange {
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pub start: Vec<u8>,
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pub end: Vec<u8>,
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pub limit: NonZeroU32,
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pub reverse: bool,
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}
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/// A response to a `ReadRange` request.
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pub struct ReadRangeOutput {
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pub entries: Vec<KvEntry>,
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}
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/// A versionstamp is a 10 byte array that is used to represent the version of
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/// a key in the database.
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type Versionstamp = [u8; 10];
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/// A key-value entry with a versionstamp.
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pub struct KvEntry {
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pub key: Vec<u8>,
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pub value: Value,
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pub versionstamp: Versionstamp,
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}
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/// A serialized value for a KV pair as stored in the database. All values
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/// **can** be serialized into the V8 representation, but not all values are.
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///
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/// The V8 representation is an opaque byte array that is only meaningful to
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/// the V8 engine. It is guaranteed to be backwards compatible. Because this
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/// representation is opaque, it is not possible to inspect or modify the value
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/// without deserializing it.
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///
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/// The inability to inspect or modify the value without deserializing it means
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/// that these values can not be quickly modified when performing atomic
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/// read-modify-write operations on the database (because the database may not
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/// have the ability to deserialize the V8 value into a modifiable value).
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///
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/// Because of this constraint, there are more specialized representations for
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/// certain types of values that can be used in atomic read-modify-write
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/// operations. These specialized representations are:
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///
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/// - **Bytes**: an arbitrary byte array.
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/// - **U64**: a 64-bit unsigned integer.
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pub enum Value {
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V8(Vec<u8>),
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Bytes(Vec<u8>),
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U64(u64),
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}
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/// A request to perform an atomic check-modify-write operation on the database.
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///
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/// The operation is performed atomically, meaning that the operation will
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/// either succeed or fail. If the operation fails, then the database will be
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/// left in the same state as before the operation was attempted. If the
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/// operation succeeds, then the database will be left in a new state.
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///
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/// The operation is performed by first checking the database for the current
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/// state of the keys, defined by the `checks` field. If the current state of
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/// the keys does not match the expected state, then the operation fails. If
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/// the current state of the keys matches the expected state, then the
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/// mutations are applied to the database.
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///
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/// All checks and mutations are performed atomically.
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///
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/// The mutations are performed in the order that they are specified in the
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/// `mutations` field. The order of checks is not specified, and is also not
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/// important because this ordering is un-observable.
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pub struct AtomicWrite {
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pub checks: Vec<KvCheck>,
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pub mutations: Vec<KvMutation>,
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pub enqueues: Vec<Enqueue>,
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}
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/// A request to perform a check on a key in the database. The check is not
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/// performed on the value of the key, but rather on the versionstamp of the
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/// key.
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pub struct KvCheck {
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pub key: Vec<u8>,
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pub versionstamp: Option<Versionstamp>,
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}
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/// A request to perform a mutation on a key in the database. The mutation is
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/// performed on the value of the key.
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///
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/// The type of mutation is specified by the `kind` field. The action performed
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/// by each mutation kind is specified in the docs for [MutationKind].
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pub struct KvMutation {
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pub key: Vec<u8>,
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pub kind: MutationKind,
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}
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/// A request to enqueue a message to the database. This message is delivered
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/// to a listener of the queue at least once.
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///
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/// ## Retry
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///
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/// When the delivery of a message fails, it is retried for a finite number
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/// of times. Each retry happens after a backoff period. The backoff periods
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/// are specified by the `backoff_schedule` field in milliseconds. If
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/// unspecified, the default backoff schedule of the platform (CLI or Deploy)
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/// is used.
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///
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/// If all retry attempts failed, the message is written to the KV under all
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/// keys specified in `keys_if_undelivered`.
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pub struct Enqueue {
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pub payload: Vec<u8>,
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pub deadline_ms: u64,
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pub keys_if_undelivered: Vec<Vec<u8>>,
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pub backoff_schedule: Option<Vec<u32>>,
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}
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/// The type of mutation to perform on a key in the database.
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///
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/// ## Set
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///
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/// The set mutation sets the value of the key to the specified value. It
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/// discards the previous value of the key, if any.
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///
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/// This operand supports all [Value] types.
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///
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/// ## Delete
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///
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/// The delete mutation deletes the value of the key.
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///
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/// ## Sum
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///
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/// The sum mutation adds the specified value to the existing value of the key.
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///
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/// This operand supports only value types [Value::U64]. The existing value in
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/// the database must match the type of the value specified in the mutation. If
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/// the key does not exist in the database, then the value specified in the
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/// mutation is used as the new value of the key.
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///
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/// ## Min
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///
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/// The min mutation sets the value of the key to the minimum of the existing
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/// value of the key and the specified value.
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///
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/// This operand supports only value types [Value::U64]. The existing value in
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/// the database must match the type of the value specified in the mutation. If
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/// the key does not exist in the database, then the value specified in the
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/// mutation is used as the new value of the key.
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///
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/// ## Max
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///
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/// The max mutation sets the value of the key to the maximum of the existing
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/// value of the key and the specified value.
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///
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/// This operand supports only value types [Value::U64]. The existing value in
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/// the database must match the type of the value specified in the mutation. If
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/// the key does not exist in the database, then the value specified in the
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/// mutation is used as the new value of the key.
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pub enum MutationKind {
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Set(Value),
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Delete,
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Sum(Value),
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Min(Value),
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Max(Value),
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}
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