See: Description
Interface | Description |
---|---|
Constraint |
Apply a
Constraint (in traditional database terminology) to a HTable. |
Class | Description |
---|---|
BaseConstraint |
Base class to use when actually implementing a
Constraint . |
ConstraintProcessor |
Processes multiple
Constraints on a given table. |
Constraints |
Utilities for adding/removing constraints from a table.
|
Exception | Description |
---|---|
ConstraintException |
Exception that a user defined constraint throws on failure of a
Put . |
Puts
on a given table, you can enforce very specific data policies.
For instance, you can ensure that a certain column family-column qualifier pair always has a value between 1 and 10.
Otherwise, the Put
is rejected and the data integrity is maintained.
Constraints are designed to be configurable, so a constraint can be used across different tables, but implement different behavior depending on the specific configuration given to that constraint.
By adding a constraint to a table (see Example Usage), constraints will automatically enabled.
You also then have the option of to disable (just 'turn off') or remove (delete all associated information) all constraints on a table.
If you remove all constraints
(see Constraints.remove(org.apache.hadoop.hbase.HTableDescriptor)
,
you must re-add any Constraint
you want on that table.
However, if they are just disabled (see Constraints.disable(org.apache.hadoop.hbase.HTableDescriptor)
,
all you need to do is enable constraints again, and everything will be turned back on as it was configured.
Individual constraints can also be individually enabled, disabled or removed without affecting other constraints.
By default, constraints are disabled on a table. This means you will not see any slow down on a table if constraints are not enabled.
Constraints
, to the the HTableDescriptor
.
This is particularly important when adding a constraint(s) to the HTableDescriptor
as it first retrieves the next priority from a custom value set in the descriptor,
adds each constraint (with increasing priority) to the descriptor, and then the next available priority is re-stored
back in the HTableDescriptor
.
Locking is recommended around each of Constraints add methods:
Constraints.add(org.apache.hadoop.hbase.HTableDescriptor, Class...)
,
Constraints.add(org.apache.hadoop.hbase.HTableDescriptor, org.apache.hadoop.hbase.util.Pair...)
,
and Constraints.add(org.apache.hadoop.hbase.HTableDescriptor, Class, org.apache.hadoop.conf.Configuration)
.
Any changes on a single HTableDescriptor should be serialized, either within a single thread or via external mechanisms.
Note that having a higher priority means that a constraint will run later; e.g. a constraint with priority 1 will run before a constraint with priority 2.
Since Constraints currently are designed to just implement simple checks (e.g. is the value in the right range), there will be no atomicity conflicts. Even if one of the puts finishes the constraint first, the single row will not be corrupted and the 'fastest' write will win; the underlying region takes care of breaking the tie and ensuring that writes get serialized to the table. So yes, this doesn't ensure that we are going to get specific ordering or even a fully consistent view of the underlying data.
Each constraint should only use local/instance variables, unless doing more advanced usage. Static variables could cause difficulties when checking concurrent writes to the same region, leading to either highly locked situations (decreasing through-put) or higher probability of errors. However, as long as each constraint just uses local variables, each thread interacting with the constraint will execute correctly and efficiently.
Puts
/second possible on a table. This is because to check the referential integrity
when making a Put
, one must block on a scan for the 'remote' table, checking for the valid reference.
For millions of Puts
a second, this will breakdown very quickly.
There are several options around the blocking behavior including, but not limited to:
Constraints
will make modifications to the
HTableDescriptor
for a given table. As such, the usual renabling of tables should be used for
propagating changes to the table. When at all possible, Constraints should be added to the table before the table is created.HTableDescriptor
via the usual method.
Under the hood, constraints are implemented as a Coprocessor (see ConstraintProcessor
if you are interested).
Constraint
.
The best way to do this is to extend BaseConstraint
, which takes care of some of the more
mundane details of using a Constraint
.
Let's look at one possible implementation of a constraint - an IntegerConstraint(there are also several simple examples in the tests).
The IntegerConstraint checks to make sure that the value is a String-encoded int
.
It is really simple to implement this kind of constraint, the only method needs to be implemented is
Constraint.check(org.apache.hadoop.hbase.client.Put)
:
public class IntegerConstraint extends BaseConstraint { public void check(Put p) throws ConstraintException { Map<byte[], List<KeyValue>> familyMap = p.getFamilyMap(); for (List <KeyValue> kvs : familyMap.values()) { for (KeyValue kv : kvs) { // just make sure that we can actually pull out an int // this will automatically throw a NumberFormatException if we try to // store something that isn't an Integer. try { Integer.parseInt(new String(kv.getValue())); } catch (NumberFormatException e) { throw new ConstraintException("Value in Put (" + p + ") was not a String-encoded integer", e); } } }
Note that all exceptions that you expect to be thrown must be caught and then rethrown as a
ConstraintException
. This way, you can be sure that a
Put
fails for an expected reason, rather than for any reason.
For example, an OutOfMemoryError
is probably indicative of an inherent problem in
the Constraint
, rather than a failed Put
.
If an unexpected exception is thrown (for example, any kind of uncaught RuntimeException
),
constraint-checking will be 'unloaded' from the regionserver where that error occurred.
This means no further Constraints
will be checked on that server
until it is reloaded. This is done to ensure the system remains as available as possible.
Therefore, be careful when writing your own Constraint.
So now that we have a Constraint, we want to add it to a table. It's as easy as:
HTableDescriptor desc = new HTableDescriptor(TABLE_NAME); ... Constraints.add(desc, IntegerConstraint.class);
Once we added the IntegerConstraint, constraints will be enabled on the table (once it is created) and we will always check to make sure that the value is an String-encoded integer.
However, suppose we also write our own constraint, MyConstraint.java
.
First, you need to make sure this class-files are in the classpath (in a jar) on the regionserver where
that constraint will be run (this could require a rolling restart on the region server - see Caveats above)
Suppose that MyConstraint also uses a Configuration (see Configurable.getConf()
).
Then adding MyConstraint looks like this:
HTableDescriptor desc = new HTableDescriptor(TABLE_NAME); Configuration conf = new Configuration(false); ... (add values to the conf) (modify the table descriptor) ... Constraints.add(desc, new Pair(MyConstraint.class, conf));
At this point we added both the IntegerConstraint and MyConstraint to the table, the IntegerConstraint will be run first, followed by MyConstraint.
Suppose we realize that the Configuration
for MyConstraint is actually wrong
when it was added to the table. Note, when it is added to the table, it is not added by reference,
but is instead copied into the HTableDescriptor
.
Thus, to change the Configuration
we are using for MyConstraint, we need to do this:
(add/modify the conf) ... Constraints.setConfiguration(desc, MyConstraint.class, conf);
This will overwrite the previous configuration for MyConstraint, but not change the order of the constraint nor if it is enabled/disabled.
Note that the same constraint class can be added multiple times to a table without repercussion. A use case for this is the same constraint working differently based on its configuration.
Suppose then we want to disable just MyConstraint. Its as easy as:
Constraints.disable(desc, MyConstraint.class);
This just turns off MyConstraint, but retains the position and the configuration associated with MyConstraint. Now, if we want to re-enable the constraint, its just another one-liner:
Constraints.enable(desc, MyConstraint.class);
Similarly, constraints on the entire table are disabled via:
Constraints.disable(desc);
Or enabled via:
Constraints.enable(desc);
Lastly, suppose you want to remove MyConstraint from the table, including with position it should be run at and its configuration. This is similarly simple:
Constraints.remove(desc, MyConstraint.class);
Also, removing all constraints from a table is similarly simple:
Constraints.remove(desc);
NOTE
It is important to note the use above of
Configuration conf = new Configuration(false);
new Configuration()
, then the Configuration will be loaded with the default
properties. While in the simple case, this is not going to be an issue, it will cause pain down the road.
First, these extra properties are going to cause serious bloat in your HTableDescriptor
,
meaning you are keeping around a ton of redundant information. Second, it is going to make examining
your table in the shell, via describe 'table'
, a huge pain as you will have to dig through
a ton of irrelevant config values to find the ones you set. In short, just do it the right way.Copyright © 2007–2019 Cloudera. All rights reserved.