DEVELOPING.md

Connectors Developer's Guide

• General Configuration
• Installation
• Architecture
• Features
• Syncing
  • Sync Strategy
  • How a full sync works
  • How an incremental sync works
• Runtime dependencies
• Implementing a new source
  • Common patterns
    • Source/Client
    • Async
    • Rich Configurable Fields
  • Other considerations
  • Sync rules
    • Basic rules vs advanced rules
    • How to implement advanced rules
    • How to validate advanced rules
    • How to provide custom basic rule validation
  • Testing the connector
    • Unit tests
    • Integration tests

General Configuration

The details of Elastic instance and other relevant fields such as service and source needs to be provided in the config.yml file. For more details check out the following documentation.

Installation

To install, run:

$ make clean install

The elastic-ingest CLI will be installed on your system:

$ bin/elastic-ingest --help
usage: elastic-ingest [-h] [--action {poll,list}] [-c CONFIG_FILE] [--log-level {DEBUG,INFO,WARNING,ERROR,CRITICAL} | --debug] [--filebeat] [--version] [--uvloop]

options:
  -h, --help            show this help message and exit
  --action {poll,list}  What elastic-ingest should do
  -c CONFIG_FILE, --config-file CONFIG_FILE
                        Configuration file
  --log-level {DEBUG,INFO,WARNING,ERROR,CRITICAL}
                        Set log level for the service.
  --debug               Run the event loop in debug mode (alias for --log-level DEBUG)
  --filebeat            Output in filebeat format.
  --version             Display the version and exit.
  --uvloop              Use uvloop if possible

Users can execute make run command to run the elastic-ingest process in debug mode. For more details check out the following documentation

Architecture

The CLI runs the ConnectorService which is an asynchronous event loop. It calls Elasticsearch on a regular basis to see if some syncs need to happen.

That information is provided by Kibana and follows the connector protocol. That protocol defines a few structures in a couple of dedicated Elasticsearch indices, that are used by Kibana to drive sync jobs, and by the connectors to report on that work.

When a user asks for a sync of a specific source, the service instantiates a class that it uses to reach out the source and collect data.

A source class can be any Python class, and is declared into the config.yml file (See Configuration for detailed explanation). For example:

sources:
  mongodb: connectors.sources.mongo:MongoDataSource
  s3: connectors.sources.s3:S3DataSource

The source class is declared with its Fully Qualified Name(FQN) so the framework knows where the class is located, so it can import it and instantiate it.

Source classes can be located in this project or any other Python project, as long as it can be imported.

For example, if the project mycompany-foo implements the source GoogleDriveDataSource in the package gdrive, run:

$ pip install mycompany-foo

And then add in the Yaml file:

sources:
  gdrive: gdrive:GoogleDriveDataSource

And that source will be available in Kibana.

Features

Connector can support features that extend its functionality, allowing for example to have customizable filtering on the edge, permissions or incremental syncs.

The features are defined as class variables of the data source class, and the available features and default values are:

1. basic_rules_enabled (Default: True) - whether basic sync rules are enabled
2. advanced_rules_enabled (Default: False) - whether advanced rules are enabled
3. dls_enabled (Default: False) - whether document-level security is enabled
4. incremental_sync_enabled (Default: False) - whether incremental sync is enabled

If you want to enable/disable any feature which is different from the default value, you need to provide the class variable in the data source implementation. E.g. to enable incremental sync:

class MyDataSource(BaseDataSource):
    incremental_sync_enabled = True

Syncing

Sync strategy

There are two types of content sync jobs: full sync and incremental sync.

A Full sync ensures full data parity (including deletion), this sync strategy is good enough for some sources like MongoDB where 100,000 documents can be fully synced in less than 30 seconds.

An Incremental sync only syncs documents created, updated and deleted since the last successful content sync.

How a full sync works

Syncing a backend consists of reconciliating an Elasticsearch index with an external data source. It's a read-only mirror of the data located in the 3rd party data source.

To sync both sides, the CLI uses these steps:

• asks the source if something has changed, if not, bail out.
• collects the list of documents IDs and timestamps in Elasticsearch
• iterate on documents provided by the data source class
• for each document
  • if there is a timestamp, and it matches the one in Elasticsearch, ignores it
  • if not, adds it as an upsert operation into a bulk call to Elasticsearch
• for each id from Elasticsearch that is not present in the documents sent by the data source class, adds it as a delete operation into the bulk call
• bulk calls are emitted every 500 operations (this is configurable for slow networks).
• If incremental sync is available for the connector, self._sync_cursor should also be updated in the connector document in the end of the sync, so that when an incremental sync starts, it knows where to start from.

See implementing a new source.

How an incremental sync works

If a connector supports incremental sync, you should first enable it. Check Features.

You have to implement get_docs_incrementally method of the data source class, which will take sync_cursor as a parameter, and yield

1. document - a json representation of an item in the remote source.
2. lazy_download - a function to download attachment, if available.
3. operation - operation to be applied to this document.

The possible values of the operation are:

1. index - the document will be re-indexed.
2. update - the document will be partially updated.
3. delete - the document will be deleted.

async def get_docs_incrementally(self, sync_cursor, filtering=None):
    # start syncing from sync_cursor
    async for doc in self.delta_change(sync_cursor, filtering):
        yield doc["document"], doc["lazy_download"], doc["operation"]

    # update sync_cursor
    self._sync_cursor = ...

sync_cursor is a dictionary object to record where the last sync job is left off, so that increment sync will know where to start from. The structure of the sync_cursor is connector dependent. E.g. in Sharepoint Online connector, we want to sync site drives incrementally, we could design the sync cursor to be like:

{
  "site_drives": {
    "{site_drive_id}" : "{delta_link}",
    ...
  }
}

If increment sync is enabled for a connector, you need to make sure self._sync_cursor is updated at the end of both full and incremental sync. Take a look at Sharepoint Online connector implementation as an example.

Implementing a new source

Implementing a new source is done by creating a new class whose responsibility is to send back documents from the targeted source.

If you want to add a new connector source, the following requirements are mandatory for the initial patch:

1. Add a module or a directory in connectors/sources
2. Create a class that implements the required methods described in connectors.source.BaseDataSource
3. Add a unit test in connectors/sources/tests with +92% coverage. Test coverage is run as part of unit tests. Look for your file at the end of the console output.
4. Declare your connector in config.py in the sources section of _default_config()
5. Declare your dependencies in requirements.txt. Make sure you pin these dependencies.
6. For each dependency you add (including indirect dependencies) list all licences and provide the list in your patch.
7. Make sure you use an async lib for your source. See our async guidelines. If not possible, make sure you don't block the loop.
8. When possible, provide a docker image that runs the backend service, so we can test the connector. If you can't provide a docker image, provide the credentials needed to run against an online service.
9. Your test backend needs to return more than 10k documents as this is the default size limit for Elasticsearch pagination. Having more than 10k documents returned from the test backend will help test the connector more thoroughly.

Source classes are not required to use any base class as long as it follows the API signature defined in BaseDataSource.

Check out an example in directory.py for a basic example.

Take a look at the MongoDB connector for more inspiration. It's pretty straightforward and has that nice little extra feature some other connectors can't implement easily: the Changes stream API allows it to detect when something has changed in the MongoDB collection. After a first sync, and as long as the connector runs, it will skip any sync if nothing changed.

Each connector will have their own specific behaviors and implementations. When a connector is loaded, it stays in memory, so you can come up with any strategy you want to make it more efficient. You just need to be careful not to blow memory.

Common Patterns

Source/Client

Many connector implementations will need to interface with some 3rd-party API in order to retrieve data from a remote system. In most instances, it is helpful to separate concerns inside your connector code into two classes. One class for the business logic of the connector (this class usually extends BaseDataSource), and one class (usually called something like <3rd-party>Client) for the API interactions with the 3rd-party. By keeping a Client class separate, it is much easier to read the business logic of your connector, without having to get hung up on extraneous details like authentication, request headers, error response handling, retries, pagination, etc.

Logging

Logging in connector implementation needs to be done via the instance variable _logger of BaseDataSource, e.g. self._logger.info(...), which will automatically include the context of the sync job, e.g. sync job id, connector id.

If there are other classes, e.g. <3rd-party>Client, you need to implement a _set_internal_logger method in the source class, to pass the logger to client class. Example of Confluence connector:

def _set_internal_logger(self):
    self.confluence_client.set_logger(self._logger)

Async

The CLI uses asyncio and makes the assumption that all the code that has been called should not block the event loop. This makes syncs extremely fast with no memory overhead. In order to achieve this asynchronicity, source classes should use async libs for their backend.

When not possible, the class should use run_in_executor and run the blocking code in another thread or process.

When you send work in the background, you will have two options:

• if the work is I/O-bound, the class should use threads
• if there's some heavy CPU-bound computation (encryption work, etc), processes should be used to avoid GIL contention

When building async I/O-bound connectors, make sure that you provide a way to recycle connections and that you can throttle calls to the backends. This is very important to avoid file descriptors exhaustion and hammering the backend service.

Rich Configurable Fields

Each connector needs to define the get_default_configuration() method, that returns a list of Rich Configurable Fields (RCF). Those fields are used by Kibana to:

• render user-friendly connector configuration section that includes informative labels, tooltips and dedicated UI components (display)
• obfuscate sensitive fields
• perform user input validation with type and validations

The connector configuration, expressed as list of RCFs, is stored in the Connector index .elastic-connectors and is governed by the Connector Protocol.

Rich Configurable Fields are defined as JSON objects with the following key-value pairs:

Key	Description	Value
default_value	The value used if value is empty (only for non-required fields)	any
depends_on	Array of dependencies, field will not be validated and displayed in UI unless dependencies are met. Each dependency is represented as an object with field and value keys, where: field: The key for the field that this will depend on value: The value required to have this dependency met	field: string value: string | number | boolean
display	What UI element this field should use	'dropdown' | 'numeric' | 'text' | 'textarea' | 'toggle'
label	The label to be displayed for the field in Kibana	string
order	The order the configurable field will appear in the UI	number
required	Whether or not the field needs a value	boolean
sensitive	Whether or not to obfuscate the field in Kibana	boolean
tooltip	Text for populating the Kibana tooltip element	string
type	The field value type	'str' | 'int' | 'bool' | 'list'
ui_restrictions	List of places in the UI to restrict the field to	string[], note: only 'advanced' place is supported for now
validations	Array of rules to validate the field's value against. Each rule is represented as an object with type and constraint keys, where: type: The validation type constraint: The rule to use for this validation	type: 'less_than' | 'greater_than' | 'list_type' | 'included_in' | 'regex' constraint: string | number | list
value	The value of the field configured in Kibana	any

Explanation of possible validation rules, where value refers to validated value:

• less_than - The constraint has to be numeric. Validator checks for value < constraint.
• greater_than - The constraint has to be numeric. Validator checks for value > constraint.
• list_type - The constraint has to be either int or str. The value has to be of list type. The validator checks the type of each element in the value list.
• included_in - The constraint has to be of list type and include allowed values. The value has to be of list type. The validator checks if value is subset of constraint
• regex - The constrain has to be a valid regex expression. The value has to be str. The validator checks if value matches the constraint regular expression.

Other considerations

When creating a new connector, there are a number of topics to thoughtfully consider before you begin coding. Below, we'll walk through each with the example of Sharepoint Online. However, the answers to these topics will differ from connector to connector. Do not just assume! Always consider each of the below for every new connector you develop.

• How is the data fetched from the 3rd-party?
  • what credentials will a client need?
    • if these credentials expire, how will they be refreshed?
  • does the API have rate limits/throttling/quotas that the connector will need to respect?
  • What is the API's default page size?
  • When should failure responses be retried?
  • What is the permission model used by the 3rd-party?
• What is the expected performance for the connector?
  • how much memory should it require?
  • will it require local file (disk) caching?

How is the data fetched from the 3rd-party?

Perhaps there is one main "documents API" that returns all the data. This type of API is common for document stores that are relatively flat, or for APIs that are focused on time-series data. Other APIs are more graph-like, where a top-level list of entities must be retrieved, and then the children of each of those must be retrieved. This type of API can sometimes be treated as a kind of recursive graph traversal. Other times, each type of entity needs to be explicitly retrieved and handled with separate logic.

In the case of Sharepoint Online, the data inside is a tree structure:

Site Collection
    └── Site
         ├─── Drive
         │    └── Drive Item - - - Drive Item (recursive, optional)
         ├─── List
         │    └── List Item - - - Drive Item (optional)
         └── Site Page

Unfortunately, some of the features available in the Sharepoint REST API are not yet available in Graph API - namely access to Page content. Going through this exercise allows you to identify the need to use two different APIs in order to fetch data.

What credentials will a client need?

3rd-party APIs nearly always require authentication. This authentication can differ between the username/password used by a human interacting with the software through a user experience built by the 3rd-party and the programmatic credentials necessary to use their API. Understanding if the connector will use basic auth, API keys, OAuth, or something else, is critical to deciding what types of configuration options need to be exposed in Kibana.

Sharepoint Online uses an OAuth2 Client Credentials Flow. This requires initial values for:

• client_id
• client_secret
• tenant_id
• scopes

so that these can be exchanged for an OAuth2 Access Token with logic like:

    authority = f"https://login.microsoftonline.com/{tenant_id}"

    app = msal.ConfidentialClientApplication(
        client_id=client_id,
        client_credential=client_secret,
        authority=authority)

    result = app.acquire_token_for_client(scopes=scopes)

    access_token = result["access_token"]

scopes is a value that will not change from one connection to another, so it can be hardcoded in the connector. All the others, however, will need to be exposed to the customer as configurations, and will need to be treated sensitively. Do not log the values of credentials!

If these credentials expire, how will they be refreshed?

It is modern best-practice to assume that any credential can and will be revoked. Even passwords in basic-auth should be rotated on occasion. Connectors should be designed to accommodate this. Find out what types of errors the 3rd-party will raise if invalid or expired credentials are submitted, and be sure to recognize these types of errors for what they are. Handling these errors so that they display in Kibana like, "Your configured credentials have expired, please re-configure" is significantly preferable over, "Sync failed, see logs for details: Error: 401 Unauthorized". Even better than that is to not issue an error at all, but to instead automatically refresh the credentails and retry.

Sharepoint Online, using the OAuth2 Client Credentials Flow, expects the access_token to frequently expire. When it does, the relevant exception can be caught, analyzed to ensure that the root cause is an expired access_token, the token can be refreshed using the configured credentials, and then any requests that have failed in the mean time can be retried.

If the client_secret is revoked, however, automatic recovery is not possible. Instead, you should catch the relevant exception, ensure that refreshing the access_token is not possible, and raise an error with an actionable error message that an operator will see in Kibana and/or the logs.

Does the API have rate limits/throttling/quotas that the connector will need to respect?

Often times, 3rd-party APIs (especially those of SaaS products) have API "quotas" or "rate limits" which prevent a given client from issuing too many requests too fast. This protects the service's general health and responsiveness, and can be a security practice to protect against bad actors.

When writing your connector, this is important to keep in mind, that non-200 responses may not mean that anything is wrong, but merely that you're sending too many requests, too fast.

There are two things you should do to deal with this:

1. Be as efficient in your traffic as possible.

• Use bulk requests over individual requests
• Increase your page sizes
• Cache records in-memory rather than looking them up multiple times

2. Respect the rate limit errors

• handle (don't crash on) 429 errors
• read the Retry-After header
• know if the API uses mechanisms other than 429 codes and Retry-After

For Sharepoint Online, there are two important limits for the Sharepoint API:

• Per minute app can consume between 1,200 to 6,000 Resource Units.
• Per day app can consume between 1,200,000 to 6,000,000 Resource Units.

These quotas are shared between Graph API and Sharepoint REST API - the latter consumes more resource units.

If the quotas are exceeded, some endpoints return 503 responses which contain the Retry-After header, and are used instead of 429 codes.

Putting all this together, you now know that you must specially handle 503 and 429 responses, looking for Retry-After headers, and design your connector knowing that you must make the absolute most out of each request, since you will nearly always run up on the per-minute and per-day limits.

What is the API's default page size?

Related to the above section, many developers are surprised at how small default page sizes may be. If your goal is to reduce the number of requests you make to a 3rd-party, page sizes of 10 or 20 rarely make sense.

However, page sizes of 1,000,000,000,000 likely aren't a good idea either, no matter how small a given record is. It's important to consider how large of a response payload you can reasonably handle at once, and craft your page size accordingly.

Sharepoint Online has a default page size of 100. For smaller-payload resources like Users and Groups, this can probably be safely increased by an order of magnitude or more.

When should failure responses be retried?

As discussed above, many APIs utilize rate limits and will issue 429 responses for requests that should be retried later. However, sometimes there are other cases that warrant retries.

Some services experience frequent-but-transient timeout issues. Some services experiencing a large volume of write operations may sometimes respond with 409 "conflict" codes. Sometimes downloading large files encounter packet loss, and while the response is a 200 OK, the checksum of the downloaded file does not match.

All of these are operations that may make sense to retry a time or two.

A note on retries - do not retry infinitely, and use backoff. A service may block your connector or specific features if you retry too aggressively.

What is the permission model used by the 3rd-party?

Whether or not you plan to support Document Level Security with your connector, it is important to understand how the 3rd-party system protects data and restricts access. This allows you to ensure that synced documents contain the relevant metadata to indicate ownership/permissions so that any consumer of your connector can choose to implement their own DLS if they so desire.

For Sharepoint Online, for example, this involves syncing the groups and users that own a document or to whom a document has been shared to. Sometimes these ownership models can be complex. For Sharepoint Online, you must consider:

• the individual creator of the document
• the "owners" of any site where the document lives
• the "members" of any site where the document lives
• the "visitors" of any site where the document lives
• Any Office365 groups that this document has been shared with
• Any Sharepoint groups that this document has been shared with
• Any Azure AD groups that this document has been shared with
• Any individuals (email addresses) that this document has been shared with

How this information is serialized onto a document is less important than ensuring that it is included. One common pattern is to put all permissions information in an _allow_permissions field with an array of text values. But it would be equally valid to split each of the above bullets into their own fields. Or to have two fields, one for "individuals" and one for "groups".

What is the expected performance for the connector?

There are no hard-and-fast rules here, unless you're building a connector with a specific customer in mind, who has specific requirements. However, it is good to ensure that any connector you build has comparable performance to that of other connectors. To measure this, you can simply utilize the make ftest (functional tests) and look at the generated performance dashboards to compare apples-to-apples. Pay particular attention to memory, CPU, and file handle metrics.

See Integration tests for more details.

How much memory should it require?

In order to understand if your connector is consuming more memory than it really should, you need to understand how big various objects are when they are retrieved from a 3rd-party.

In Sharepoint Online, the object sizes could be thought of like:

• Site Collection - small objects less than a KB
• Site - small objects less than a KB
• Drive - small objects less than a KB
• Drive Item - small objects less than a KB, but require binary download + subextraction and binary content can be as large as file systems allow
• List - small objects less than a KB
• List Item - small objects less than a KB
• Site Page - various size HTML objects that can get large

Therefore, if you have binary content extraction disabled and are seeing this connector take up GB of memory, there's likely a bug. Conversely, if you are processing and downloading many binary files, it is perfectly reasonable to see memory spike in proportion to the size of said files.

It's also important to note that connectors will store all IDs in memory while performing a sync. This allows the connector to then remove any documents from the Elasticsearch index which were not part of the batch just ingested. On large scale syncs, these IDs can consume a significant amount of RAM, especially if they are large. Be careful to design your document IDs to not be longer than necessary.

Will it require local file (disk) caching?

Some connectors require writing to disk in order to utilize OS-level utils (base64, for example), or to buffer large structures to avoid holding them all in memory. Understanding these requirements can help you to anticipate how many file handles a connector might reasonably need to maintain.

Sharepoint Online, for example, needs to download Site Page and Drive Item objects. This results in a relatively high number of overall file handles being utilized during the sync, but should not lead to an ever-increasing number of currently active file handles. Seeing any of none, ever-decreasing, or ever-increasing file handles while monitoring a sync would be indicative of a bug in this case.

Sync rules

Basic rules vs advanced rules

Sync rules are made up of basic and advanced rules. Basic rules are implemented generically on the framework-level and work out-of-the-box for every new connector. Advanced rules are specific to each data source. Learn more about sync rules in the Enterprise Search documentation.

Example:

For MySQL we've implemented advanced rules to pass custom SQL queries directly to the corresponding MySQL instance. This offloads a lot of the filtering to the data source, which helps reduce data transfer size. Also, data sources usually have highly optimized and specific filtering capabilities you may want to expose to the users of your connector. Take a look at the get_docs method in the MySQL connector to see an advanced rules implementation.

How to implement advanced rules

When implementing a new connector follow the API of the BaseDataSource.

To implement advanced rules, you should first enable them. Check Features.

The custom implementation for advanced rules is usually located inside the get_docs (and get_docs_incrementally if incremental sync is enabled) function:

async def get_docs(self, filtering=None):
    if filtering and filtering.has_advanced_rules():
        advanced_rules = filtering.get_advanced_rules()
        # your custom advanced rules implementation
    else:
        # default fetch all data implementation

For example, here you could pass custom queries to a database. The structure of the advanced rules depends on your implementation and your concrete use case. For MySQL the advanced rules structure looks like this: You specify databases on the top level, which contain tables, which specify a custom query.

Example:

{
  "database_1": {
    "table_1": "SELECT ... FROM ...;",
    "table_2": "SELECT ... FROM ...;"
  },
  "database_2": {
    "table_1": "SELECT ... FROM ...;"
  }
}

Note that the framework calls get_docs with the parameter filtering of type Filter, which is located in byoc.py. The Filter class provides convenient methods to extract advanced rules from the filter and to check whether advanced rules are present.

How to validate advanced rules

To validate advanced rules the framework takes the list of validators returned by the method advanced_rules_validators and calls them in the order they appear in that list. By default, this list is empty in the BaseDataSource as advanced rules are always specific to the connector implementation. Plug in custom validators by implementing a class containing a validate method, which accepts one parameter. The framework expects the custom validators to return a SyncRuleValidationResult, which can be found in validation.py.

class MyValidator(AdvancedRulesValidator):

    def validate(self, advanced_rules):
        # custom validation logic
        return SyncRuleValidationResult(...)

Note that the framework will call validate with the parameter advanced_rules of type dict. Now you can return a list of validator instances in advanced_rules_validators:

class MyDataSource(BaseDataSource):

    def advanced_rules_validators(self):
        return [MyValidator()]

The framework will handle the rest: scheduling validation, calling the custom validators and storing the corresponding results.

How to provide custom basic rule validation

Overriding basic_rule_validators is not recommended, because you'll lose the default validations.

The framework already provides default validations for basic rules. To extend the default validation, provide custom basic rules validators. There are two possible ways to validate basic rules:

• Every rule gets validated in isolation. Extend the class BasicRuleValidator located in validation.py:

  class MyBasicRuleValidator(BasicRuleValidator):
  
      @classmethod
      def validate(cls, rule):
          # custom validation logic
          return SyncRuleValidationResult(...)

• Validate the whole set of basic rules. If you want to validate constraints on the set of rules, for example to detect duplicate or conflicting rules. Extend the class BasicRulesSetValidator located in validation.py:

  class MyBasicRulesSetValidator(BasicRulesSetValidator):
  
      @classmethod
      def validate(cls, set_of_rules):
          # custom validation logic
          return SyncRuleValidationResult(...)

To preserve the default basic rule validations and extend these with your custom logic, override basic_rules_validators like this:

class MyDataSource(BaseDataSource):

    @classmethod
    def basic_rules_validators(self):
        return BaseDataSource.basic_rule_validators()
                + [MyBasicRuleValidator, MyBasicRulesSetValidator]

Again the framework will handle the rest: scheduling validation, calling the custom validators and storing the corresponding results.

Testing the connector

Unit Tests

To test the connectors, run:

make test

All connectors are required to have unit tests and to have a 90% coverage reported by this command

Integration Tests

If the above tests pass, start your Docker instance or configure your backend, then run:

make ftest NAME={service type}

This will configure the connector in Elasticsearch to run a full sync. The script will verify that the Elasticsearch index receives documents.

Runtime dependencies

• MacOS or Linux server. The connector has been tested with CentOS 7, MacOS Monterey v12.0.1.
• Python version 3.10 or later.
• To fix SSL certificate verification failed error, users have to run this to connect with Amazon S3:

  $ System/Volumes/Data/Applications/Python\ 3.10/Install\ Certificates.command

Customize a connector

ℹ️ Please note that customized connectors are not supported by Elastic.

To customize an existing connector, follow these steps:

1. Customize the source file for your data source from connectors/sources
2. Declare your dependencies in requirements.txt. Make sure you pin these dependencies.
3. For each dependency you add (including indirect dependencies) list all licences and provide the list in your patch.
4. Your test backend needs to return more than 10k documents as this is the default size limit for Elasticsearch pagination. Having more than 10k documents returned from the test backend will help test the connector more thoroughly.