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Redshift (via Collector method) - v3.1.0

About Collectors

Collectors are extractors that are developed and managed by you (A customer of K).

KADA provides python libraries that customers can use to quickly deploy a Collector.

 

Why you should use a Collector

There are several reasons why you may use a collector vs the direct connect extractor:

  1. You are using the KADA SaaS offering and it cannot connect to your sources due to firewall restrictions

  2. You want to push metadata to KADA rather than allow it pull data for Security reasons

  3. You want to inspect the metadata before pushing it to K

 

Using a collector requires you to manage

  1. Deploying and orchestrating the extract code

  2. Managing a high water mark so the extract only pull the latest metadata

  3. Storing and pushing the extracts to your K instance.


Pre-requisites

Collector Server Minimum Requirements

Redshift Requirements

  • Access to Redshift

Redshift Access

Log into Redshift as a Superuser. Superuser access is required to complete the following steps.

Create a Redshift user. This user MUST be either (one or the other below, we generally recommend 2.)

  1. Be a Superuser. Refer to Superusers - Amazon Redshift to view all required data.

    ALTER USER <kada user> CREATEUSER; -- GRANTS SUPERUSER
  2. Be a Database user with:

    1. Unrestricted SYSLOG ACCESS refer to Introduction to Amazon Redshift - Amazon Redshift. This will allow full access to the STL tables for the user.

      ALTER USER <kada user> SYSLOG ACCESS UNRESTRICTED; -- GRANTS READ ACCESS

       

    2. Select Access to existing and future tables in all Schemas for each Database you want K to ingest.

      1. List all existing Schema in the Database by running

        SELECT DISTINCT schema_name FROM svv_all_tables; -- LIST ALL SCHEMAS

         

      2. For each schema above do the following to allow the user select access to all tables inside the Schema and any new tables created in the schema thereafter.

        You also must do this for ANY new schemas created in the Database to ensure K has view of it.

         

PG Catalog

The PG tables are granted per database but generally all users should have access to them on DB creation. In the event the user doesn’t have access, explicit grants will need to be done per new DB in Redshift.

The user used for the extraction must also be able to connect to the the databases needed for extraction.

PG Tables

These tables are per database in Redshift

  • pg_class

  • pg_user

  • pg_group

  • pg_namespace

  • pg_proc

  • pg_database

System Tables

These tables can be accessed in any database and reads from the leader node in Redshift

  • svv_all_columns

  • svv_all_tables

  • svv_tables

  • svv_external_tables

  • svv_external_schemas

  • stl_query

  • stl_querytext

  • stl_ddltext

  • stl_utilitytext

  • stl_query_metrics

  • stl_sessions

  • stl_connection_log

Databases

  • dev (The extractor uses the dev database as a test access point)

  • All other databases that you want onboarded


Step 1: Create the Source in K

Create a Redshift source in K

  • Go to Settings, Select Sources and click Add Source

  • Select “Load from File” option

  • Give the source a Name - e.g. Redshift Production

  • Add the Host name for the Redshift Server

  • Click Finish Setup


Step 2: Getting Access to the Source Landing Directory

Collector Method

Step 3: Install the Collector

It is recommended to use a python environment such as pyenv or pipenv if you are not intending to install this package at the system level.

Some python packages also have dependencies on the OS level packages, so you may be required to install additional OS packages if the below fails to install.

You can download the latest Core Library and whl via Platform Settings → SourcesDownload Collectors

Run the following command to install the collector.

You will also need to install the common library kada_collectors_lib for this collector to function properly.


Step 4: Configure the Collector

The collector requires a set of parameters to connect to and extract metadata from Redshift.

FIELD

FIELD TYPE

DESCRIPTION

EXAMPLE

FIELD

FIELD TYPE

DESCRIPTION

EXAMPLE

host

string

Redshift host.

This value must to match the host name onboarded in K.

abc123.redshift.amazonaws.com

server

string

Redshift DNS Name / IP address used to construct the connection string.

This allows the collector to connect to Redshift on a different IP / DNS Name to the onboarded host name in K.

In most cases this value will be the same as host, unless you are unable to connect using the host name due to networking configurations.

abc123.redshift.amazonaws.com

OR

10.1.1.2

 

username

string

Username to log into Redshift

“test”

password

string

Password to log into the Redshift

 

databases

list<string>

A list of databases to extract from Redshift

[“dwh”, “adw”]

port

integer

Redshift port, general default is 5439

5439

tunnel

boolean

Are you establishing an SSH tunnel to get to your redshift? If so specify true so it changes the connection to localhost.

The SSH tunnel needs to be established before running the collector.

false

output_path

string

Absolute path to the output location where files are to be written

“/tmp/output”

mask

boolean

To enable masking or not

true

compress

boolean

To gzip the output or not

true

These parameters can be added directly into the run or you can use pass the parameters in via a JSON file. The following is an example you can use that is included in the example run code below.

kada_redshift_extractor_config.json


Step 5: Run the Collector

The following code is an example of how to run the extractor. You may need to uplift this code to meet any code standards at your organisation.

This can be executed in any python environment where the whl has been installed.

This is the wrapper script: kada_redshift_extractor.py

 

Advance options:

If you wish to maintain your own high water mark files elsewhere you can use the above section’s script as a guide on how to call the extractor. The configuration file is simply the keyword arguments in JSON format. Refer to this document for more information Collector Integration General Notes | Storing HWM in another location

If you are handling external arguments of the runner yourself, you’ll need to consider additional items for the run method. Refer to this document for more information Collector Integration General Notes | The run method


username: username to sign into Redshift
password: password to sign into Redshift
host: Host of the Redshift Service as onboarded in K
server: The host value to actually connect to Redshift, this can be an IP Address or the same value as server
databases: list of databases to extract, no spaces
port: redshift port
tunnel: Is a SSH tunnel being used? If yes then it will default to localhost
output_path: full or relative path to where the outputs should go
mask: To mask the META/DATABASE_LOG files or not
compress: To gzip output files or not


Step 6: Check the Collector Outputs

K Extracts

A set of files (eg metadata, databaselog, linkages, events etc) will be generated. These files will appear in the output_path directory you set in the configuration details

High Water Mark File

A high water mark file is created in the same directory as the execution called redshift_hwm.txt and produce files according to the configuration JSON. This file is only produced if you call the publish_hwm method.


Step 7: Push the Extracts to K

Once the files have been validated, you can push the files to the K landing directory.

You can use Azure Storage Explorer if you want to initially do this manually. You can push the files using python as well (see Airflow example below)


Example: Using Airflow to orchestrate the Extract and Push to K