IBM Cloudant Python SDK is a client library that interacts with the IBM Cloudant APIs.
Disclaimer: This library is still a 0.x release. We do consider this library production-ready and capable, but there are still some limitations we’re working to resolve, and refinements we want to deliver. We are working really hard to minimise the disruption from now until the 1.0 release, but there may still be some changes that impact applications using this SDK. For now, be sure to pin versions to avoid surprises.
Table of Contents
- Overview
- Features
- Prerequisites
- Installation
- Using the SDK
- Authentication
- Automatic retries
- Request timeout configuration
- Code examples
- Error handling
- Raw IO
- Model classes vs dictionaries
- Further resources
- Changes feed follower (beta)
- Questions
- Issues
- Versioning and LTS support
- Open source at IBM
- Contributing
- License
The IBM Cloudant Python SDK allows developers to programmatically
interact with IBM Cloudant
with the help of the ibmcloudant
package.
The purpose of this Python SDK is to wrap most of the HTTP request APIs provided by Cloudant and supply other functions to ease the usage of Cloudant. This SDK should make life easier for programmers to do what’s really important to them: developing software.
Reasons why you should consider using Cloudant Python SDK in your project:
- Supported by IBM Cloudant.
- Server compatibility with:
- IBM Cloudant.
- Apache CouchDB 3.x for data operations.
- Includes all the most popular and latest supported endpoints for applications.
- Handles the authentication.
- Familiar user experience with IBM Cloud SDKs.
- Flexibility to use either built-in models or byte-based requests and responses for documents.
- Built-in Changes feed follower (beta)
- Instances of the client are unconditionally thread-safe.
To install, use pip
or easy_install
:
pip install --upgrade "ibmcloudant>=0.9.3"
or
easy_install --upgrade "ibmcloudant>=0.9.3"
For fundamental SDK usage information and config options, please see the common IBM Cloud SDK documentation.
This library requires configuration with a service URL and Cloudant service credentials to authenticate with your account.
There are several ways to set these authentication properties:
- As environment variables
- The programmatic approach
- With an external credentials file
The following section describes the different authentication types and provides environment variable examples. Examples for other configuration methods are available by following the provided links.
This library requires credentials to authenticate with IBM Cloudant. These credentials may be:
- IBM Cloud IAM credentials (can be used with authentication types
CONTAINER
,VPC
andIAM
)- IBM Cloud account user, service ID or trusted profile credentials that have been granted access to the IBM Cloud Cloudant resource instance.
- IBM Cloudant service credentials generated by the IBM Cloud Cloudant resource instance.
- Username and password credentials (can be used with authentication types
COUCHDB_SESSION
andBASIC
)- IBM Cloudant service credentials generated for an IBM Cloud Cloudant resource instance not configured as
IAM only
. - IBM Cloudant legacy credentials (i.e. username and password) for instances not in IBM Cloud.
- IBM Cloudant legacy API keys.
- IBM Cloudant service credentials generated for an IBM Cloud Cloudant resource instance not configured as
For other compatible APIs that are not Cloudant accounts (e.g. Apache CouchDB) non-IAM based authentication types must be used.
This table summarizes the available authentication types. The authentication types are listed in order of recommendation, preferably use the authentication type from the first row in the table that is compatible with your environment.
Authentication type | Recommended for | AUTH_TYPE |
Description |
---|---|---|---|
IAM Trusted Profiles compute resource (container) | Cloudant (SDK running in IBM Cloud IKS) |
CONTAINER |
Obtains a compute resource (CR) token from the container. Exchanges the CR token for an IAM access_token .Adds an Authorization: Bearer <access_token> header to each HTTP request.Automatically renews the access token when needed. |
IAM Trusted Profiles compute resource (VPC) | Cloudant (SDK running in IBM Cloud VPC) |
VPC |
Obtains an identity token from the VPC instance metadata. Exchanges the identity token for an IAM access_token .Adds an Authorization: Bearer <access_token> header to each HTTP request.Automatically renews the access token when needed. |
IAM API key | Cloudant | IAM |
Exchanges an IAM API key for an IAM access_token .Adds an Authorization: Bearer <access_token> header to each HTTP request.Automatically renews the access token when needed. |
Session cookie | Cloudant (legacy credentials & instances without IAM) Apache CouchDB |
COUCHDB_SESSION |
Exchanges credentials with /_session endpoint to retrieve a cookie.Adds Cookie header and content to each HTTP request.Automatically renews session when needed. |
Bearer token | Apache CouchDB (using JWT authentication) |
BEARERTOKEN |
Adds an Authorization: Bearer <token> to each HTTP request.No token management or renewal. Also compatible with IAM access tokens managed independently of the SDK. |
Basic | Apache CouchDB (if cookies are not enabled) |
BASIC |
Adds an Authorization: Basic <encoded username and password> header to each HTTP request. |
None | - | NOAUTH |
Note that this authentication type only works for operations against a database allowing access for unauthenticated users. |
The default authentication type for the SDK is CONTAINER
unless APIKEY
configuration is supplied, which changes the default authentication type to IAM
.
The default service name is CLOUDANT
so CLOUDANT_
prefixed names are used in these examples.
Any custom service name prefix can be used as long as the matching name is used to instantiate the SDK client and the same prefix is used for all configuration options.
For Cloudant IAM API key authentication, set the following environmental variables by
replacing the <url>
and <apikey>
with your proper
service credentials. There is no need to set
CLOUDANT_AUTH_TYPE
to IAM
because it is the default when an APIKEY
is set.
CLOUDANT_URL=<url>
CLOUDANT_APIKEY=<apikey>
For Cloudant IAM Trusted profile compute resource container authentication, set the following environmental variables by
replacing the <url>
and <id>
with your values. There is no need to set
CLOUDANT_AUTH_TYPE
to CONTAINER
because it is the default.
CLOUDANT_URL=<url>
CLOUDANT_IAM_PROFILE_ID=<id>
Alternatively a profile name may be used instead of an ID by replacing CLOUDANT_IAM_PROFILE_ID
with CLOUDANT_IAM_PROFILE_NAME
.
For Cloudant IAM Trusted profile compute resource vpc authentication, set the following environmental variables by
replacing the <url>
and <id>
with your values.
CLOUDANT_AUTH_TYPE=VPC
CLOUDANT_URL=<url>
CLOUDANT_IAM_PROFILE_ID=<id>
Alternatively a profile CRN may be used instead of an ID by replacing CLOUDANT_IAM_PROFILE_ID
with CLOUDANT_IAM_PROFILE_CRN
.
For COUCHDB_SESSION
authentication, set the following environmental variables
by replacing the <url>
, <username>
and <password>
with your proper
service credentials.
CLOUDANT_AUTH_TYPE=COUCHDB_SESSION
CLOUDANT_URL=<url>
CLOUDANT_USERNAME=<username>
CLOUDANT_PASSWORD=<password>
To use an external configuration file, the Cloudant API docs, or the general SDK usage information will guide you.
To learn more about how to use programmatic authentication, see the related documentation in the Cloudant API docs or in the Python SDK Core document about authentication.
The SDK supports a generalized retry feature that can automatically retry on common errors.
The automatic retries section has details on how to enable the retries with default values and customize the retries programmatically or with external configuration.
No request timeout is defined, but a 2.5m read and a 60s connect timeout are set by default. Be sure to set a request timeout appropriate to your application usage and environment. The request timeout section contains details on how to change the value.
Note: System settings may take precedence over configured timeout values.
The following code examples authenticate with the environment variables.
Note: This example code assumes that orders
database does not exist in your account.
This example code creates orders
database and adds a new document "example"
into it. To connect, you must set your environment variables with
the service url, authentication type and authentication credentials
of your Cloudant service.
Cloudant environment variable naming starts with a service name prefix that identifies your service.
By default, this is CLOUDANT
, see the settings in the
authentication with environment variables section.
If you would like to rename your Cloudant service from CLOUDANT
,
you must use your defined service name as the prefix for all Cloudant related environment variables.
Once the environment variables are set, you can try out the code examples.
from ibm_cloud_sdk_core import ApiException
from ibmcloudant.cloudant_v1 import CloudantV1, Document
# 1. Create a client with `CLOUDANT` default service name =============
client = CloudantV1.new_instance()
# 2. Create a database ================================================
example_db_name = "orders"
# Try to create database if it doesn't exist
try:
put_database_result = client.put_database(
db=example_db_name
).get_result()
if put_database_result["ok"]:
print(f'"{example_db_name}" database created.')
except ApiException as ae:
if ae.status_code == 412:
print(f'Cannot create "{example_db_name}" database, ' +
'it already exists.')
# 3. Create a document ================================================
# Create a document object with "example" id
example_doc_id = "example"
# Setting `id` for the document is optional when "post_document"
# function is used for CREATE. When `id` is not provided the server
# will generate one for your document.
example_document: Document = Document(id=example_doc_id)
# Add "name" and "joined" fields to the document
example_document.name = "Bob Smith"
example_document.joined = "2019-01-24T10:42:59.000Z"
# Save the document in the database with "post_document" function
create_document_response = client.post_document(
db=example_db_name,
document=example_document
).get_result()
# =====================================================================
# Note: saving the document can also be done with the "put_document"
# function. In this case `doc_id` is required for a CREATE operation:
"""
create_document_response = client.put_document(
db=example_db_name,
doc_id=example_doc_id,
document=example_document
).get_result()
"""
# =====================================================================
# Keeping track of the revision number of the document object
# is necessary for further UPDATE/DELETE operations:
example_document.rev = create_document_response["rev"]
print(f'You have created the document:\n{example_document}')
When you run the code, you see a result similar to the following output.
"orders" database created.
You have created the document:
{
"_id": "example",
"_rev": "1-1b403633540686aa32d013fda9041a5d",
"name": "Bob Smith",
"joined": "2019-01-24T10:42:99.000Z"
}
Note: This example code assumes that you have created both the orders
database and the example
document by
running the previous example code
successfully. Otherwise, the following error message occurs, "Cannot delete document because either 'orders'
database or 'example' document was not found."
Gather database information example
import json
from ibmcloudant.cloudant_v1 import CloudantV1
# 1. Create a client with `CLOUDANT` default service name ============
client = CloudantV1.new_instance()
# 2. Get server information ===========================================
server_information = client.get_server_information(
).get_result()
print(f'Server Version: {server_information["version"]}')
# 3. Get database information for "orders" ==========================
db_name = "orders"
db_information = client.get_database_information(
db=db_name
).get_result()
# 4. Show document count in database ==================================
document_count = db_information["doc_count"]
print(f'Document count in \"{db_information["db_name"]}\" '
f'database is {document_count}.')
# 5. Get "example" document out of the database by document id ============
document_example = client.get_document(
db=db_name,
doc_id="example"
).get_result()
print(f'Document retrieved from database:\n'
f'{json.dumps(document_example, indent=2)}')
Server Version: 2.1.1
Document count in "orders" database is 1.
Document retrieved from database:
{
"_id": "example",
"_rev": "1-1b403633540686aa32d013fda9041a5d",
"name": "Bob Smith",
"joined": "2019-01-24T10:42:99.000Z"
}
Note: This example code assumes that you have created both the orders
database and the example
document by
running the previous example code
successfully. Otherwise, the following error message occurs, "Cannot update document because either 'orders'
database or 'example' document was not found."
Update code example
import json
from ibm_cloud_sdk_core import ApiException
from ibmcloudant.cloudant_v1 import CloudantV1
# 1. Create a client with `CLOUDANT` default service name =============
client = CloudantV1.new_instance()
# 2. Update the document ==============================================
example_db_name = "orders"
example_doc_id = "example"
# Try to get the document if it previously existed in the database
try:
document = client.get_document(
db=example_db_name,
doc_id=example_doc_id
).get_result()
# =================================================================
# Note: for response byte stream use:
"""
document_as_byte_stream = client.get_document_as_stream(
db=example_db_name,
doc_id=example_doc_id
).get_result()
"""
# =================================================================
# Add Bob Smith's address to the document
document["address"] = "19 Front Street, Darlington, DL5 1TY"
# Remove the joined property from document object
if "joined" in document:
document.pop("joined")
# Update the document in the database
update_document_response = client.post_document(
db=example_db_name,
document=document
).get_result()
# =================================================================
# Note 1: for request byte stream use:
"""
update_document_response = client.post_document(
db=example_db_name,
document=document_as_byte_stream
).get_result()
"""
# =================================================================
# =================================================================
# Note 2: updating the document can also be done with the
# "put_document" function. `doc_id` and `rev` are required for an
# UPDATE operation, but `rev` can be provided in the document
# object as `_rev` too:
"""
update_document_response = client.put_document(
db=example_db_name,
doc_id=example_doc_id, # doc_id is a required parameter
rev=document["_rev"],
document=document # _rev in the document object CAN replace above `rev` parameter
).get_result()
"""
# =================================================================
# Keeping track of the latest revision number of the document
# object is necessary for further UPDATE/DELETE operations:
document["_rev"] = update_document_response["rev"]
print(f'You have updated the document:\n' +
json.dumps(document, indent=2))
except ApiException as ae:
if ae.status_code == 404:
print('Cannot delete document because either ' +
f'"{example_db_name}" database or "{example_doc_id}" ' +
'document was not found.')
{
"_id": "example",
"_rev": "2-4e2178e85cffb32d38ba4e451f6ca376",
"name": "Bob Smith",
"address": "19 Front Street, Darlington, DL5 1TY"
}
Note: This example code assumes that you have created both the orders
database and the example
document by
running the previous example code
successfully. Otherwise, the following error message occurs, "Cannot delete document because either 'orders'
database or 'example' document was not found."
Delete code example
from ibm_cloud_sdk_core import ApiException
from ibmcloudant.cloudant_v1 import CloudantV1
# 1. Create a client with `CLOUDANT` default service name =============
client = CloudantV1.new_instance()
# 2. Delete the document ==============================================
example_db_name = "orders"
example_doc_id = "example"
# Try to get the document if it previously existed in the database
try:
document = client.get_document(
db=example_db_name,
doc_id=example_doc_id
).get_result()
delete_document_response = client.delete_document(
db=example_db_name,
doc_id=example_doc_id, # `doc_id` is required for DELETE
rev=document["_rev"] # `rev` is required for DELETE
).get_result()
if delete_document_response["ok"]:
print('You have deleted the document.')
except ApiException as ae:
if ae.status_code == 404:
print('Cannot delete document because either ' +
f'"{example_db_name}" database or "{example_doc_id}"' +
'document was not found.')
You have deleted the document.
For a complete list of code examples, see the examples directory.
For sample code on handling errors, see Cloudant API docs.
For endpoints that read or write document content it is possible to bypass usage of the built-in object with byte streams.
Depending on the specific SDK operation it may be possible to:
- accept a user-provided byte stream to send to the server as a request body
- return a byte stream of the server response body to the user
Request byte stream can be supplied for arguments that accept the BinaryIO
type.
For these cases you can pass this byte stream directly to the HTTP request body.
Response byte stream is supported in functions with the suffix of _as_stream
.
The returned byte stream allows the response body to be consumed
without triggering JSON unmarshalling that is typically performed by the SDK.
The update document section contains examples for both request and response byte stream cases.
The API reference contains further examples of using byte streams. They are titled "Example request as stream" and are initially collapsed. Expand them to see examples of:
-
Byte requests:
-
Byte responses:
This SDK supports two possible formats to define an HTTP request. One approach uses only model classes and the other only dictionaries.
Example using model class structure
from ibmcloudant.cloudant_v1 import DesignDocument, CloudantV1, DesignDocumentOptions, SearchIndexDefinition
client = CloudantV1.new_instance()
price_index = SearchIndexDefinition(
index='function (doc) { index("price", doc.price); }'
)
design_document_options = DesignDocumentOptions(
partitioned=True
)
partitioned_design_doc = DesignDocument(
indexes={'findByPrice': price_index},
options=design_document_options
)
response = client.put_design_document(
db='products',
design_document=partitioned_design_doc,
ddoc='appliances'
).get_result()
print(response)
Same example using dictionary structure
from ibmcloudant.cloudant_v1 import CloudantV1
client = CloudantV1.new_instance()
price_index = {
'index': 'function (doc) { index("price", doc.price); }'
}
partitioned_design_doc = {
'indexes': {'findByPrice': price_index},
'options': {'partitioned': True},
}
response = client.put_design_document(
db='products',
design_document=partitioned_design_doc,
ddoc='appliances'
).get_result()
print(response)
Since model classes and dicts are different data structures, they cannot be combined.
This solution will be invalid
from ibmcloudant.cloudant_v1 import CloudantV1, DesignDocument
client = CloudantV1.new_instance()
price_index = {
'index': 'function (doc) { index("price", doc.price); }'
}
partitioned_design_doc = DesignDocument(
indexes={'findByPrice': price_index},
options={'partitioned': True}
)
response = client.put_design_document(
db='products',
design_document=partitioned_design_doc,
ddoc='appliances'
).get_result()
print(response)
- Cloudant API docs: API reference including usage examples for Cloudant Python SDK API.
- Pydoc: Cloudant Python SDK API Documentation.
- Cloudant docs: The official documentation page for Cloudant.
- Cloudant blog: Many useful articles about how to optimize Cloudant for common problems.
The SDK provides a changes feed follower utility (currently beta).
This helper utility connects to the _changes
endpoint and returns the individual change items.
It removes some of the complexity of using the _changes
endpoint by setting some options automatically
and providing error suppression and retries.
Tip: the changes feed often does not meet user expectations or assumptions.
Consult the Cloudant changes feed FAQ to get a better understanding of the limitations and suitable use-cases before using the changes feed in your application.
There are two modes of operation:
- Start mode
- Fetches the changes from the supplied
since
sequence (by default the feed will start fromnow
). - Fetches all available changes and then continues listening for new changes indefinitely unless encountering an end condition.
- An example use case for this mode is event driven workloads.
- Fetches the changes from the supplied
- Start one-off mode
- Fetches the changes from the supplied
since
sequence (by default the feed will start from the beginning). - Fetches all available changes and then stops when either there are no further changes pending or encountering an end condition.
- An example use case for this mode is ETL style workloads.
- Fetches the changes from the supplied
The SDK's model of changes feed options is also used to configure the follower. However, a subset of the options are invalid as they are configured internally by the implementation. Supplying these options when instantiating the follower causes an error. The invalid options are:
descending
feed
heartbeat
lastEventId
- usesince
insteadtimeout
- Only the value of
_selector
is permitted for thefilter
option. This restriction is because selector based filters perform better than JavaScript backed filters. Configuring a non-selector based filter will cause the follower to error.
Note that the limit
parameter will terminate the follower at the given number of changes in either
operating mode.
The changes follower requires the client to have HTTP timeouts of at least 1 minute and will error during instantiation if it is insufficient. The default client configuration has sufficiently long timeouts.
For use-cases where these configuration limitations are deemed too restrictive then it is recommended to
write code to use the SDK's POST _changes
API instead of the follower.
By default, the changes follower will suppress transient errors indefinitely and attempt to run to completion or listen forever as dictated by the operating mode. For applications where that is not desirable an optional error tolerance duration may be specified to control the time since the last successful response that transient errors will be suppressed. This can be used, for example, by applications as a grace period before reporting an error and requiring intervention.
There are some additional points to consider for error suppression:
- Errors considered terminal, for example, the database not existing or invalid credentials are never suppressed and will error immediately.
- The error suppression duration is not guaranteed to fire immediately after lapsing and should be considered a minimum suppression time.
- The changes follower will back-off between retries and as such may remain paused for a short while after the transient errors have resolved.
- If the underlying SDK client used to initialize the follower also has retries configured then errors could be suppressed for significantly longer than the follower's configured error tolerance duration depending on the configuration options.
For both modes:
- The end conditions are:
- A terminal error (HTTP codes
400
,401
,403
404
). - Transient errors occur for longer than the error tolerance duration. Transient errors are all other HTTP status codes and connection errors.
- The number of changes received reaches the configured
limit
. - The feed is terminated early by calling stop.
- A terminal error (HTTP codes
As is true for the _changes
endpoint change items have at least once delivery and an individual item
may be received multiple times. When using the follower change items may be repeated even within a limited
number of changes (i.e. using the limit
option) this is a minor difference from using limit
on the HTTP native API.
The follower is not optimized for some use cases and it is not recommended to use it in cases where:
- Setting
include_docs
and larger document sizes (for example > 10 kiB). - The volume of changes is very high (if the rate of changes in the database exceeds the follower's rate of pulling them it will never catch-up).
In these cases use-case specific control over the number of change requests made and the content size of the responses
may be achieved by using the SDK's POST _changes
API.
The changes follower does not checkpoint since it has no information about whether a change item has been
processed by the consuming application after being received. It is the application developer's responsibility
to store the sequence IDs to have appropriate checkpoints and to re-initialize the follower with the required
since
value after, for example, the application restarts.
The frequency and conditions for checkpointing are application specific and some applications may be tolerant of dropped changes. This section is intended only to provide general guidance on how to avoid missing changes.
To guarantee processing of all changes the sequence ID from a change item must not be persisted until after
the processing of the change item by the application has completed. As indicated previously change items are
delivered at least once so application code must be able to handle repeated changes already and it is
preferable to restart from an older since
value and receive changes again than risk missing them.
The sequence IDs are available on each change item by default, but may be omitted from some change items when
using the seq_interval
configuration option. Infrequent sequence IDs may improve performance by reducing
the amount of data that needs to be transferred, but the trade-off is that more changes will be repeated if
it is necessary to resume the changes follower.
Extreme care should be taken with persisting sequences if choosing to process change items in parallel as there is a considerable risk of missing changes on a restart if the sequence is recorded out of order.
import ChangesFollower
from ibmcloudant.cloudant_v1 import CloudantV1
client = CloudantV1.new_instance()
cf_params = {
'db': 'example', # Required: the database name.
'limit': 100, # Optional: return only 100 changes (including duplicates).
'since': '3-g1AG3...' # Optional: start from this sequence ID (e.g. with a value read from persistent storage).
}
changes_follower = ChangesFollower(
service=client, # Required: the Cloudant service client instance.
error_tolerance=10000, # Optional: suppress transient errors for at least 10 seconds before terminating.
**cf_params # Required: changes feed configuration options dict.
)
import Iterable
from ibmcloudant import ChangesFollower
from ibmcloudant.cloudant_v1 import CloudantV1, ChangesResultItem
client = CloudantV1.new_instance()
changes_follower = ChangesFollower(
service=client,
**{'db': 'example'})
changes_items: Iterable[ChangesResultItem] = changes_follower.start()
# Note: iterable will not do anything until it is iterated
# Create a for loop to iterate over the flow of changes
# for changes_item in changes_items: ...
import Iterable
from ibmcloudant import ChangesFollower
from ibmcloudant.cloudant_v1 import CloudantV1, ChangesResultItem
client = CloudantV1.new_instance()
changes_follower = ChangesFollower(
service=client,
**{'db': 'example'})
changes_items: Iterable[ChangesResultItem] = changes_follower.start_one_off()
# Note: iterable will not do anything until it is iterated
# Create a for loop to iterate over the flow of changes
# for changes_item in changes_items: ...
import ChangesFollower
from ibmcloudant.cloudant_v1 import CloudantV1
client = CloudantV1.new_instance()
# Start from a previously persisted seq
# Normally this would be read by the app from persistent storage
# e.g. previously_persisted_seq = your_app_persistence_read_func()
previously_persisted_seq = '3-g1AG3...'
changes_follower = ChangesFollower(
service=client,
**{'db': 'example', 'since': previously_persisted_seq})
changes_items = changes_follower.start()
for changes_item in changes_items:
# do something with changes
print(changes_item.id)
for change in changes_item.changes:
print(change.rev)
# when change item processing is complete app can store seq
seq = changes_item.seq
# write seq to persistent storage for use as since if required to resume later
# e.g. your_app_persistence_write_func(seq)
# keep processing changes until the application is terminated or some other stop condition is reached
# Note: iterator above is blocking, code here will be unreachable
# until the iteration is stopped or another stop condition is reached.
# For long running followers careful consideration should be made of where to call stop on the iterator.
import ChangesFollower
from ibmcloudant.cloudant_v1 import CloudantV1
client = CloudantV1.new_instance()
# Start from a previously persisted seq
# Normally this would be read by the app from persistent storage
# e.g. previously_persisted_seq = your_app_persistence_read_func()
previously_persisted_seq = '3-g1AG3...'
changes_follower = ChangesFollower(
service=client,
**{'db': 'example', 'since': previously_persisted_seq})
changes_items = changes_follower.start_one_off()
for changes_item in changes_items:
# do something with changes
print(changes_item.id)
for change in changes_item.changes:
print(change.rev)
# when change item processing is complete app can store seq
seq = changes_item.seq
# write seq to persistent storage for use as since if required to resume later
# e.g. your_app_persistence_write_func(seq)
# Note: iterator above is blocking, code here will be unreachable
# until all changes are processed (or another stop condition is reached).
import ChangesFollower
from ibmcloudant.cloudant_v1 import CloudantV1
client = CloudantV1.new_instance()
changes_follower = ChangesFollower(
service=client,
**{'db': 'example'})
changes_items = changes_follower.start()
for changes_item in changes_items:
# Option 1: call stop after some condition
# Note that since the iterator is blocking at least one item
# must be returned from it to reach to this point.
# Additional changes may be processed before the iterator stops.
changes_follower.stop()
# Option 2: call stop method when you want to end the continuous loop from
# outside the iterator. For example, you've put the changes follower in a
# separate thread and need to call stop on the main thread.
# Note: in this context the call must be made from a different thread because
# code immediately following the iterator is unreachable until the iterator
# has stopped.
changes_follower.stop()
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This SDK follows semantic versioning with respect to the definition of user facing APIs. This means under some circumstances breaking changes may occur within a major or minor version of the SDK related to changes in supported language platforms.
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- New language features may be added in subsequent SDK releases that will cause breaking changes if the new releases of the SDK are used with older, now unsupported, language levels.
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