Unique Lookup Vindexes

Certain application features may require you to point-select orders by their id with a query like this:

select * from corder where corder_id=1;

However, issuing this query to Vitess will cause it to scatter this query across all shards because there is no way to know which shard contains that order id. This would be inefficient if the QPS of this query or the number of shards is too high.

Vitess supports the concept of lookup vindexes, also known as cross-shard indexes. You can instruct Vitess to create and manage a lookup vindex for the corder_id column. Such a vindex needs to maintain a mapping from corder_id to the keyspace_id of the row, which will be stored in a lookup table.

This lookup table can be created in any keyspace, and it may or may not be sharded. In this particular case, we are going to create the table in the unsharded product keyspace even though the lookup vindex itself is going to be in the customer keyspace:

create table corder_keyspace_idx(corder_id bigint, keyspace_id varbinary(10), primary key(corder_id));

The primary key is corder_id. The unique constraint on corder_id makes the Lookup Vindex unique: for a given corder_id as input, at most one keyspace_id can be produced. It is not necessary to name the column as corder_id, but it is less confusing to do so.

Since the table is not sharded, we have a trivial VSchema addition:

    "corder_keyspace_idx": {}

We can now instantiate the Lookup Vindex in the VSchema of the customer keyspace:

    "corder_keyspace_idx": {
      "type": "consistent_lookup_unique",
      "params": {
        "table": "product.corder_keyspace_idx",
        "from": "corder_id",
        "to": "keyspace_id"
      },
      "owner": "corder"
    }
  • The vindex is given a distinctive name corder_keyspace_idx because of its specific input parameters.
  • The vindex type is consistent_lookup_unique. We expect this lookup vindex to yield at most one keyspace id for a given input. The consistent qualifier is explained below.
  • The params section of a Vindex is a set of key-value strings. Each vindex expects a different set of parameters depending on the implementation. A lookup vindex requires the following three parameters:
    • table should be the name of the lookup table. It is recommended that it is fully qualified.

    • The from and to fields must reference the column names of the lookup table.

    • An optional fourth parameter will be available in Vitess 12.0:

      • batch_lookup: Set this to "true" if you want lookups for key values in the lookup vindex table to be batched (i.e. all values that match to a shard of the lookup backing table will be done in a single query). This can be important if you have queries with multiple point lookup values in the WHERE clause (e.g. using IN). This is not enabled by default, since it only supports binary equality, i.e. does not take collation into account. You should therefore only use it with lookup vindexes where the from key is binary or binary equivalent (e.g. integer or a character field where you are sure that collation matching is not required). Without this option, lookups of multiple values in the shards backing the lookup table will be performed one-by-one, and can have a significant latency overhead if you have a large number of values to lookup per query, relative to your number of shards.
  • The owner field indicates that corder is responsible for populating the lookup table and keeping it up-to-date. This means that an insert into corder will result in a corresponding lookup row being inserted in the lookup table, etc. Lookup vindexes can also be shared, but they can have only one owner each. We will later see an example about how to share lookup vindexes.
Since corder_keyspace_idx and corder are in different keyspaces, any change that affects the lookup column results in a distributed transaction between the customer shard and the product keyspace. Usually, a two-phase commit (2PC) protocol would need to be used for the distributed transaction. However, the consistent lookup vindex utilizes a special algorithm that orders the commits in such a way that a commit failure resulting in partial commits does not result in inconsistent data. This avoids the extra overheads associated with 2PC.

Finally, we must associate customer.corder_id with the lookup vindex:

      "column_vindexes": [{
          "column": "customer_id",
          "name": "hash"
        }, {
          "column": "corder_id",
          "name": "corder_keyspace_idx"
        }]

Note that corder_id comes after customer_id implying that customer_id is the Primary Vindex for this table.

Alternate VSchema DDL:

alter vschema add table product.corder_keyspace_idx;
alter vschema on customer.corder add vindex corder_keyspace_idx(corder_id) using consistent_lookup_unique with owner=`corder`, table=`product.corder_keyspace_idx`, from=`corder_id`, to=`keyspace_id`;
An owned lookup vindex (even if unique) cannot be a Primary Vindex because it creates an association against a keyspace id after one has been assigned to the row. The job of computing the keyspace id must therefore be performed by a different unique vindex.

Bringing up the demo application again, you can now see the lookup table being automatically populated when rows are inserted in corder:

mysql> insert into corder(customer_id, product_id, oname) values (1,1,'gift'),(1,2,'gift'),(2,1,'work'),(3,2,'personal'),(4,1,'personal');
Query OK, 5 rows affected (0.00 sec)

mysql> select corder_id, hex(keyspace_id) from corder_keyspace_idx;
+-----------+------------------+
| corder_id | hex(keyspace_id) |
+-----------+------------------+
|         1 | 166B40B44ABA4BD6 |
|         2 | 166B40B44ABA4BD6 |
|         3 | 06E7EA22CE92708F |
|         4 | 4EB190C9A2FA169C |
|         5 | D2FD8867D50D2DFE |
+-----------+------------------+
5 rows in set (0.01 sec)

And then, issuing a query like select * from corder where corder_id=1 results in two single-shard round-trips instead of a full scatter.

Reversible Vindexes #

Looking at the rows in corder_keyspace_idx reveals a few things. We get to now see actual keyspace id values that were previously invisible. We can also notice that two different inputs 1 and 2 map to the same keyspace id 166B40B44ABA4BD6. In other words, a unique vindex does not necessarily guarantee that two different values yield different keyspace ids. In fact, this is derived from the fact that there are two order rows for customer id 1.

Vindexes that do have a one-to-one correspondence between the input value and keyspace id , like hash, are known as reversible vindexes: Given a keyspace id, the input value can be back-computed. This property will be used in a later example.

Backfill #

Creating a lookup vindex after the main table already contains rows does not automatically backfill the lookup table for the existing entries. Only newer inserts cause automatic population of the lookup table. This backfill can be set up using the CreateLookupVindex command covered below.

Checklist #

Creating a unique lookup Vindex is an elaborate process. It is good to use the following checklist if this is done manually:

  • Create the lookup table as sharded or unsharded. Make the from column the primary key.
  • Create a VSchema entry for the lookup table. If sharded, assign a Primary Vindex for the from column.
  • Create the lookup vindex in the VSchema of the sharded keyspace:
    • Give it a distinct name
    • Specify the type as consistent_lookup_unique
    • Under params: specify the properties of the lookup table
    • Specify the Owner as the main table
  • Associate the column of the owner table with the new Vindex.

CreateLookupVindex command #

vtctld supports the CreateLookupVindex command that can perform all the above steps as well as the backfill.

This will not work against the vtcombo based demo app because it does not support vreplication. You can only try this against a real Vitess cluster.

Save the following json into a file, say corder_keyspace_idx.json:

{
  "sharded": true,
  "vindexes": {
    "corder_keyspace_idx": {
      "type": "consistent_lookup_unique",
      "params": {
        "table": "product.corder_keyspace_idx",
        "from": "corder_id",
        "to": "keyspace_id"
      },
      "owner": "corder"
    }
  },
  "tables": {
    "corder": {
      "column_vindexes": [{
          "column": "corder_id",
          "name": "corder_keyspace_idx"
      }],
    }
  }
}

And issue the vtctlclient command:

$ vtctlclient -server <vtctld_grpc_address> CreateLookupVindex -tablet_types=REPLICA customer "$(cat corder_keyspace_idx.json)"

The workflow automatically infers the schema and vschema for the lookup table and creates it. It also sets up the necessary VReplication streams to backfill the lookup table.

After the backfill is done, you should clean up the workflow. More detailed instructions are available in the CreateLookupVindex Reference