Data Operations
- how-to
Key Value (KV) or data service offers the simplest way to retrieve or mutate data where the key is known. Here we cover CRUD operations, document expiration, and optimistic locking with CAS.
The complete code sample used on this page can be downloaded from the GitHub repo for the Python docs, from which you can see in context how to authenticate and connect to a Couchbase Cluster, then perform these Collection operations.
Documents
A document refers to an entry in the database (other databases may refer to the same concept as a row). A document has an ID (primary key in other databases), which is unique to the document and by which it can be located. The document also has a value which contains the actual application data. See the concept guide to Documents for a deeper dive into documents in the Couchbase Data Platform. Or read on, for a hands-on introduction to working with documents from the Python SDK.
CRUD Operations
The core interface to Couchbase Server is simple KV operations on full documents. Make sure you’re familiar with the basics of authorization and connecting to a Cluster from the Start Using the SDK section. We’re going to expand on the short Upsert example we used there, adding options as we move through the various CRUD operations. Here is the Insert operation at its simplest:
# Insert document
document = {"foo": "bar", "bar": "foo"}
result = collection.insert("document-key", document)
cas = result.cas
Options may be added to operations. It is best practice to use the *Options() class that matches name of the operation (e.g. GetOptions(), InsertOptions(), etc.). However, keyword arguments can be used as an override to a corresponding value within the options.
Options like timeout and expiry are timedelta objects.
# Insert document with options
document = {"foo": "bar", "bar": "foo"}
opts = InsertOptions(timeout=timedelta(seconds=5))
result = collection.insert("document-key-opts",
document,
opts,
expiry=timedelta(seconds=30))
Expiration sets an explicit time to live (TTL) for a document.
We’ll discuss modifying Expiration
in more details below.
For a discussion of item (Document) vs Bucket expiration, see the
Expiration Overview page.
CAS
Setting a Compare and Swap (CAS) value is a form of optimistic locking — dealt with in depth in the CAS page. Here we just note that the CAS is a value representing the current state of an item; each time the item is modified, its CAS changes. The CAS value is returned as part of a document’s metadata whenever a document is accessed. Without explicitly setting it, a newly-created document would have a CAS value of 0.
# Replace document with CAS
document = {"foo": "bar", "bar": "foo"}
result = collection.replace(
"document-key",
document,
cas=cas,
timeout=timedelta(
minutes=1))
Typically we would want to use CAS for something more meaningful like performing a Get, modifying the result and updating the document. By using the CAS value we know that if anyone else modified this document and updated it before our update then ours will error.
# Replace document with CAS
result = collection.get("document-key")
doc = result.content_as[dict]
doc["bar"] = "baz"
opts = ReplaceOptions(cas=result.cas)
result = collection.replace("document-key", doc, opts)
Durability
Writes in Couchbase are written to a single node, and from there the Couchbase Server will take care of sending that mutation to any configured replicas. The optional durability parameter, which all mutating operations accept, allows the application to wait until this replication (or persistence) is successful before proceeding.
In Couchbase Server releases before 6.5, Durability was set with two options — see the 6.0 Durability documentation — covering how many replicas the operation must be propagated to and how many persisted copies of the modified record must exist. Couchbase Data Platform 6.5 refines these two options, with Durable Writes — although they remain essentially the same in use. The Python SDK exposes both of these forms of Durability.
First we will cover the newer durability features available in Couchbase server 6.5 onwards. The SDK exposes three durability levels:
-
Majority
- The server will ensure that the change is available in memory on the majority of configured replicas. -
MajorityAndPersistToActive
- Majority level, plus persisted to disk on the active node. -
PersistToMajority
- Majority level, plus persisted to disk on the majority of configured replicas.
The options are in increasing levels of safety. Note that nothing comes for free - for a given node, waiting for writes to storage is considerably slower than waiting for it to be available in-memory. These trade offs, as well as which settings may be tuned, are discussed in the durability page.
The following example demonstrates using the newer durability features available in Couchbase server 6.5 onwards.
# Upsert with Durability (Couchbase Server >= 6.5) level Majority
document = dict(foo="bar", bar="foo")
opts = UpsertOptions(durability=ServerDurability(Durability.MAJORITY))
result = collection.upsert("document-key", document, opts)
If a version of Couchbase Server lower than 6.5 is being used then the application can fall-back to 'client verified' durability. The older type of durability, also known as observe based durability, works by monitoring the server to ensure that the change has been replicated or persisted to the required number of nodes within the timeout specified on the operation. Here we can see how that is set:
# Upsert with observe based durability (Couchbase Server < 6.5)
document = {"foo": "bar", "bar": "foo"}
opts = UpsertOptions(
durability=ClientDurability(
ReplicateTo.ONE,
PersistTo.ONE))
result = collection.upsert("document-key", document, opts)
To stress, durability is a useful feature but should not be the default for most applications, as there is a performance consideration, and the default level of safety provided by Couchbase will be reasonable for the majority of situations.
Sub-Document Operations
All of these operations involve fetching the complete document from the Cluster. Where the number of operations or other circumstances make bandwidth a significant issue, the SDK can work on just a specific path of the document with Sub-Document Operations. |
Retrieving full documents
Using the get()
method with the document key can be done in a similar fashion to the other operations:
result = collection.get("document-key")
print(result.content_as[dict])
Timeout can also be set, as in the earlier Insert
operation example:
opts = GetOptions(timeout=timedelta(seconds=5))
result = collection.get("document-key", opts)
print(result.content_as[dict])
Removing
When removing a document, you will have the same concern for durability as with any additive modification to the Bucket:
# remove document with options
result = collection.remove(
"document-key",
RemoveOptions(
cas=12345,
durability=ServerDurability(
Durability.MAJORITY)))
Expiration / TTL
We already touched on how to set Expiry
on an operation but we didn’t discuss how to handle extending that expiry time.
By default, Couchbase documents do not expire, but transient or temporary data may be needed for user sessions, caches, or other temporary documents.
You can use expiration values on documents to handle transient data.
To prevent a document that already has expiry from expiring you can use Touch
operations which will extend the expiry by the time specified.
result = collection.touch("document-key", timedelta(seconds=10))
When getting a document, the expiry is not provided automatically by Couchbase Server but it can be requested:
result = collection.get("document-key", GetOptions(with_expiry=True))
print("Expiry of result: {}".format(result.expiryTime))
Some applications may find get_and_touch
useful, which fetches a document while updating its expiry field. It can be used like this:
result = collection.get_and_touch("document-key", timedelta(seconds=10))
Atomic Counters
The value of a document can be increased or decreased atomically using .increment()
and .decrement()
.
Increment & Decrement are considered part of the ‘binary’ API, and as such may still be subject to change. |
# Increment binary value by 1
collection.binary().increment(
"counter-key",
IncrementOptions(
delta=DeltaValue(1)))
# Increment binary value by 5, if key doesn't exist, seed it at 1000
collection.binary().increment(
"counter-key",
IncrementOptions(
delta=DeltaValue(5),
initial=SignedInt64(1000)))
# Decrement binary value by 1
collection.binary().decrement(
"counter-key",
DecrementOptions(
delta=DeltaValue(1)))
# Decrement binary value by 2, if key doesn't exist, seed it at 1000
collection.binary().decrement(
"counter-key",
DecrementOptions(
delta=DeltaValue(2),
initial=SignedInt64(1000)))
Setting the document expiry time only works when a document is created, and it is not possible to update the expiry time of an existing counter document with the Increment method — to do this during an increment, use with the Touch() method.
|
Atomicity Across Data Centers
If you are using Cross Data Center Replication (XDCR), be sure to avoid modifying the same counter in more than one datacenter. If the same counter is modified in multiple datacenters between replications, the counter will no longer be atomic, and its value can change in unspecified ways.
A counter must be incremented or decremented by only a single datacenter. Each datacenter must have its own set of counters that it uses — a possible implementation would be including a datacenter name in the counter document ID.
Scoped KV Operations
It is possible to perform scoped key-value operations on named
Collections
with Couchbase Server release 7.0. See the API docs for more information.
Here is an example showing an upsert in the users
collection, which lives in the travel-sample.tenant_agent_00
keyspace:
agent_scope = bucket.scope("tenant_agent_00");
users_collection = agent_scope.collection("users");
content = {"name": "John Doe", "preferred_email": "johndoe111@test123.test" }
result = users_collection.upsert("user-key", content);
Additional Resources
A complete Caching example for the Python 3.x SDK, using Flask, is worked through here.
Working on just a specific path within a JSON document will reduce network bandwidth requirements - see the Sub-Document pages.
For another way of increasing performance, reference our asynchronous programmaing options.
Our Query Engine enables retrieval of information using the SQL-like syntax of SQL++ (formerly N1QL).