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Operations

The Deno KV API provides a set of operations that can be performed on the store.

There are two operations that read data from the store, and five operations that write data to the store.

Read operations can either be performed in strong or eventual consistency mode. Strong consistency mode guarantees that the read operation will return the most recently written value. Eventual consistency mode may return a stale value, but is faster.

Write operations are always performed in strong consistency mode.

get

The get operation returns the value and versionstamp associated with a given key. If a value does not exist, get returns a null value and versionstamp.

There are two APIs that can be used to perform a get operation. The Deno.Kv.prototype.get(key, options?) API, which can be used to read a single key, and the Deno.Kv.prototype.getMany(keys, options?) API, which can be used to read multiple keys at once.

Get operations are performed as a "snapshot read" in all consistency modes. This means that when retrieving multiple keys at once, the values returned will be consistent with each other.

const res = await kv.get<string>(["config"]);
console.log(res); // { key: ["config"], value: "value", versionstamp: "000002fa526aaccb0000" }

const res = await kv.get<string>(["config"], { consistency: "eventual" });
console.log(res); // { key: ["config"], value: "value", versionstamp: "000002fa526aaccb0000" }

const [res1, res2, res3] = await kv.getMany<[string, string, string]>([
  ["users", "sam"],
  ["users", "taylor"],
  ["users", "alex"],
]);
console.log(res1); // { key: ["users", "sam"], value: "sam", versionstamp: "00e0a2a0f0178b270000" }
console.log(res2); // { key: ["users", "taylor"], value: "taylor", versionstamp: "0059e9035e5e7c5e0000" }
console.log(res3); // { key: ["users", "alex"], value: "alex", versionstamp: "00a44a3c3e53b9750000" }

list

The list operation returns a list of keys that match a given selector. The associated values and versionstamps for these keys are also returned. There are 2 different selectors that can be used to filter the keys matched.

The prefix selector matches all keys that start with the given prefix key parts. The prefix selector may optionally be given a start OR end key to limit the range of keys returned. The start key is inclusive, and the end key is exclusive.

The range selector matches all keys that are lexographically between the given start and end keys. The start key is inclusive, and the end key is exclusive.

Note: In the case of the prefix selector, the prefix key must consist only of full (not partial) key parts. For example, if the key ["foo", "bar"] exists in the store, then the prefix selector ["foo"] will match it, but the prefix selector ["f"] will not.

The list operation may optionally be given a limit to limit the number of keys returned.

List operations can be performed using the Deno.Kv.prototype.list<string>(selector, options?) method. This method returns a Deno.KvListIterator that can be used to iterate over the keys returned. This is an async iterator, and can be used with for await loops.

// Return all users
const iter = await kv.list<string>({ prefix: ["users"] });
const users = [];
for await (const res of iter) users.push(res);
console.log(users[0]); // { key: ["users", "alex"], value: "alex", versionstamp: "00a44a3c3e53b9750000" }
console.log(users[1]); // { key: ["users", "sam"], value: "sam", versionstamp: "00e0a2a0f0178b270000" }
console.log(users[2]); // { key: ["users", "taylor"], value: "taylor", versionstamp: "0059e9035e5e7c5e0000" }

// Return the first 2 users
const iter = await kv.list<string>({ prefix: ["users"] }, { limit: 2 });
const users = [];
for await (const res of iter) users.push(res);
console.log(users[0]); // { key: ["users", "alex"], value: "alex", versionstamp: "00a44a3c3e53b9750000" }
console.log(users[1]); // { key: ["users", "sam"], value: "sam", versionstamp: "00e0a2a0f0178b270000" }

// Return all users lexicographically after "taylor"
const iter = await kv.list<string>({ prefix: ["users"], start: ["users", "taylor"] });
const users = [];
for await (const res of iter) users.push(res);
console.log(users[0]); // { key: ["users", "taylor"], value: "taylor", versionstamp: "0059e9035e5e7c5e0000" }

// Return all users lexicographically before "taylor"
const iter = await kv.list<string>({ prefix: ["users"], end: ["users", "taylor"] });
const users = [];
for await (const res of iter) users.push(res);
console.log(users[0]); // { key: ["users", "alex"], value: "alex", versionstamp: "00a44a3c3e53b9750000" }
console.log(users[1]); // { key: ["users", "sam"], value: "sam", versionstamp: "00e0a2a0f0178b270000" }

// Return all users starting with characters between "a" and "n"
const iter = await kv.list<string>({ start: ["users", "a"], end: ["users", "n"] });
const users = [];
for await (const res of iter) users.push(res);
console.log(users[0]); // { key: ["users", "alex"], value: "alex", versionstamp: "00a44a3c3e53b9750000" }

The list operation reads data from the store in batches. The size of each batch can be controlled using the batchSize option. The default batch size is 500 keys. Data within a batch is read in a single snapshot read, so the values are consistent with each other. Consistency modes apply to each batch of data read. Across batches, data is not consistent. The borders between batches is not visible from the API as the iterator returns individual keys.

The list operation can be performed in reverse order by setting the reverse option to true. This will return the keys in lexicographically descending order. The start and end keys are still inclusive and exclusive respectively, and are still interpreted as lexicographically ascending.

// Return all users in reverse order, ending with "sam"
const iter = await kv.list<string>({ prefix: ["users"], start: ["users", "sam"] }, {
  reverse: true,
});
const users = [];
for await (const res of iter) users.push(res);
console.log(users[0]); // { key: ["users", "taylor"], value: "taylor", versionstamp: "0059e9035e5e7c5e0000" }
console.log(users[1]); // { key: ["users", "sam"], value: "sam", versionstamp: "00e0a2a0f0178b270000" }

Note: in the above example we set the start key to ["users", "sam"], even though the first key returned is ["users", "taylor"]. This is because the start and end keys are always evaluated in lexicographically ascending order, even when the list operation is performed in reverse order (which returns the keys in lexicographically descending order).

set

The set operation sets the value of a key in the store. If the key does not exist, it is created. If the key already exists, its value is overwritten.

The set operation can be performed using the Deno.Kv.prototype.set(key, value) method. This method returns a Promise that resolves to a Deno.KvCommitResult object, which contains the versionstamp of the commit.

Set operations are always performed in strong consistency mode.

const res = await kv.set(["users", "alex"], "alex");
console.log(res.versionstamp); // "00a44a3c3e53b9750000"

delete

The delete operation deletes a key from the store. If the key does not exist, the operation is a no-op.

The delete operation can be performed using the Deno.Kv.prototype.delete(key) method.

Delete operations are always performed in strong consistency mode.

await kv.delete(["users", "alex"]);

sum

The sum operation atomically adds a value to a key in the store. If the key does not exist, it is created with the value of the sum. If the key already exists, its value is added to the sum.

The sum operation can only be performed as part of an atomic operation. The Deno.AtomicOperation.prototype.mutate({ type: "sum", value }) method can be used to add a sum mutation to an atomic operation.

The sum operation can only be performed on values of type Deno.KvU64. Both the operand and the value in the store must be of type Deno.KvU64.

If the new value of the key is greater than 2^64 - 1 or less than 0, the sum operation wraps around. For example, if the value in the store is 2^64 - 1 and the operand is 1, the new value will be 0.

Sum operations are always performed in strong consistency mode.

await kv.atomic()
  .mutate({
    type: "sum",
    key: ["accounts", "alex"],
    value: new Deno.KvU64(100n),
  })
  .commit();

min

The min operation atomically sets a key to the minimum of its current value and a given value. If the key does not exist, it is created with the given value. If the key already exists, its value is set to the minimum of its current value and the given value.

The min operation can only be performed as part of an atomic operation. The Deno.AtomicOperation.prototype.mutate({ type: "min", value }) method can be used to add a min mutation to an atomic operation.

The min operation can only be performed on values of type Deno.KvU64. Both the operand and the value in the store must be of type Deno.KvU64.

Min operations are always performed in strong consistency mode.

await kv.atomic()
  .mutate({
    type: "min",
    key: ["accounts", "alex"],
    value: new Deno.KvU64(100n),
  })
  .commit();

max

The max operation atomically sets a key to the maximum of its current value and a given value. If the key does not exist, it is created with the given value. If the key already exists, its value is set to the maximum of its current value and the given value.

The max operation can only be performed as part of an atomic operation. The Deno.AtomicOperation.prototype.mutate({ type: "max", value }) method can be used to add a max mutation to an atomic operation.

The max operation can only be performed on values of type Deno.KvU64. Both the operand and the value in the store must be of type Deno.KvU64.

Max operations are always performed in strong consistency mode.

await kv.atomic()
  .mutate({
    type: "max",
    key: ["accounts", "alex"],
    value: new Deno.KvU64(100n),
  })
  .commit();