[tl;dr A single data lake, data warehouse or data pipeline to “rule them all” is less useful in hybrid cloud environments, where it can be feasible to query ‘serverless’ cloud-native data sources directly rather than rely on traditional orchestrated batch extracts. Pipeline complexity can be reduced by open extensions to SQL such as the recently announced AWS PartiQL language. Opportunities exist to integrate enterprise human-oriented data governance and meta-data platforms with data pipelines using serverless technologies.]
The need for Data Lakes
A data lake is a centralized repository that allows you to store all your structured and unstructured data at any scale. The data lake concept was created to address a number of issues with traditional data analytics and reporting solutions, specifically:
- the growing number of applications across an enterprise depending on a given dataset;
- business and regulatory drivers for governing dataset discovery, quality, creation and/or consumption;
- the increasing difficulty of IT teams to respond in a timely manner to growing business demand for access to high quality datasets.
The data lake allows data to be made available from its source without making any assumptions about its use. This is particularly critical when the data originates from batch extracts of load-sensitive OLTP databases, most of which are still operating on-premise. Streaming data pipelines, while growing in popularity, are not as common as batch-driven pipelines – although this should change over time as more digital platform architectures become more event-driven in nature.
Data lakes are a key component in data pipelines, a construct (or set of constructs) that provides consolidation of data from multiple sources and makes it available for use. A data pipeline can be orchestrated (via a scheduler) or choreographed (responding to events) – the more jobs a pipeline has to do, the more complex the orchestration or choreography, which has implications for supportability. So reducing the number of jobs a pipeline has to support is key to managing data pipeline complexity.
The Components of a Data Lake
A data lake consists of a few key components:
|A storage repository||Durable, resilient storage of data objects.||No||Yes|
|An ingestion mechanism||A means to upload content to the repository (no transformation)||No||Yes|
|A tagging & metadata mechanism||A means to associate metadata with data objects, including user-defined tags.||Yes||Yes|
|A metadata search mechanism||A means to search objects in the data lake based on metadata and tags (not content)||Yes||Yes|
|A query engine||A means to search the content of objects in the data lake||Yes||Partially|
|An access control mechanism||A means to ensure that users can only access datasets and parts of data sets that they are entitled to see, and to audit all activity.||Yes||Yes|
In effect, data lakes have become a kind of data warehouse – the main significant difference being that input sources into data lakes tend to be familiar files – CSVs, Avro, JSON, etc. from multiple sources rather than highly optimized domain-specific schemas – i.e., no assumptions are made about how (or why) the data in the data lake will be consumed. Data lakes also do not concern themselves with scheduling or orchestration.
Datawarehouses, datawarehouses everywhere…
For mature data use cases (i.e., situations where relatively stable, well-known data requirements exist), and where consistent high performance is material to meeting customer needs, data warehouses are still the best solution. A data warehouse stores and manages all of its data locally, and only relies on the data lake as an initial ingestion point.
A data warehouse will transform datasets to the form needed for the specific use cases it supports, and will optimize performance for the consumption of those datasets. Modern data warehouses will use ML/AI techniques to optimize performance rather than relying on human database specialists. But, as this approach is compute intensive, such solutions are more amenable to cloud environments than on-premise environments. Snowflake is an example of this model. As more traditional data warehouses (e.g., Oracle Exadata) move to the cloud, we can expect these to also get ‘smarter’ – however, data gravity will mean such solutions will need to be fundamentally multi-cloud compatible.
For on-premise data warehouses, the tendency is for business lines or functions to create ‘one data warehouse to rule them all’ – mainly because of the traditionally significant storage and compute infrastructure and resources necessary to support data warehouses. Consequently considerable effort is spent on defining and maintaining high performance, appropriately normalized, enterprise data models that can be used in as many enterprise use cases as possible.
In a hybrid/cloud world, multiple data warehouses become more feasible – and in fact, will be inevitable in larger organizations. As more enterprise data becomes available in these dynamically scalable, cloud-based (or HDFS/Hadoop based) data warehouses (such as AWS EMR, AWS Redshift, Snowflake, Google Big Query, Azure SQL Data Warehouse), ‘virtual data warehouses’ avoid the need to move data from its source for query handling, allowing data storage and egress costs to be kept to a minimum, especially if assisted by machine-learning techniques.
Virtual Data Warehouses
Virtual Data warehouse technologies have been around for a while, allowing users to manage and query multiple data sources through a common logical access point. For on-premise solutions, virtual data warehouses have limited use cases, as the cost/effort of scaling out in-house solutions can be prohibitive and not particularly agile in nature, precluding experimental use cases.
On hybrid or cloud environments, virtual data warehouses can leverage the scalability of cloud-native data warehouses, driving queries to the relevant engine for execution, and then leveraging its own scalable infrastructure for executing join queries.
Technologies like Dremio reflect the state of the art in cloud-based data warehouses, which push down queries to the source system where possible, but can process them in-memory directly from a data lake or other source if not.
However, there is one thing that all data warehouses have in common: they leverage SQL and (implicitly) a relational view of the data. Standard ANSI SQL queries are generally supported by all data warehouses, but may mean that some data cannot be queried if it is not in tabular form amenable to SQL processing.
Extending SQL with PartiQL
Enter PartiQL, an open-source project sponsored by Amazon to drive extensions to standard SQL that can cope with non-relational data types, including structured, unstructured, nested, and schemaless (NoSQL, Document).
Historically, all data ingested into a data lake had to be transformed into a format that could be queried by SQL-like commands or processed by typical data warehouse bulk-upload tools. This adds complexity to data pipelines (i.e., more jobs), and may also force premature schema design (i.e., forcing the design of an optimal schema before all critical use cases are fully understood).
PartiQL potentially allows tools such as Snowflake, Dremio (as well as the tools AWS uses internally) to query data using SQL-like syntax, but to also include non-relational data in those queries so they can avoid those separate transformation steps, aiding pipeline complexity reduction.
PartiQL claims to be fully ANSI-compliant, but extended in specific ways to support alternate data formats. While not an official ISO/ANSI standard, it may have the ability to become a de-facto standard – especially as the language has already been used in anger with success within AWS. This will provide a skill path for relational data warehouse experts to become proficient in leveraging modern data pipelines without committing to one specific vendor’s technology.
Technologies like PartiQL will make it much easier to include event-sourced streams into a data pipeline, as events are defined as nested or other non-relational structures. As more data pipelines become event driven rather than batch-driven, having a standard like PartiQL will be key. (It will be interesting to see if Confluent’s KSQL and PartiQL will converge to a single event-stream query standard.)
As PartiQL has only just been released, it’s too soon to tell how the big data ecosystem or ISO/ANSI will respond. Expect more on this topic in the future. For now, virtual data warehouses must rely on their proprietary SQL extensions.
Non-SQL Data Processing
Considerable investment is being made by third party vendors on advanced technology focused on making distributed, scalable processing of SQL (or SQL-like) queries fast and reliable with little or no human tuning required. As such, it is wise to pick a vendor demonstrating a clear strategy in this space, and continuing to invest in SQL as the lingua-franca of transformation logic.
However, for use cases for which SQL is not appropriate, distributed computing platforms like Spark are still needed. The expectation here is that such platforms will ingest data from a data lake, and output results into a data lake. In some cases, the distributed computing platform offers its own storage (e.g., HDFS), but increasingly it is more appropriate to question whether data needs to reside permanently in a HDFS cluster rather than in a data lake. For example, Amazon’s EMR service allows Hadoop clusters to be created ephemerally, and to consume their initial dataset from AWS S3 repositories or other data sources,
Enforcing Enterprise Data Collaboration and Governance
Note that all data warehouse solutions (virtual or not) must support some form of meta-data tagging and management used by their SQL query engines – otherwise they cannot act as a virtual database source (generally an ODBC end-point that applications can connect directly to). This tagging can be automated if sources included meta-data (e.g., field headers, Avro schema definitions, etc) , but can be enhanced by human tagging, which is increasingly augmented by machine-learning to help identify, for example, where data may be sensitive, etc.
But data governance needs extend beyond the needs of the virtual data warehouse query engines, and this is where there are still gaps to be filled in the current enterprise data management tools.
Tools from vendors like Alation, Waterline, Informatica, Collibra etc were created to augment people’s ability to properly tag content in the data-lake with meaningful information to make it discoverable and governable. Consistent tagging in principle allows tag-based governance rules to be defined to automatically enforce data governance policies in data consumers. This data, coupled with schema information which can be derived directly from data-sources, is all the information needed to allow users (or developers) to source the data they need in a secure, compliant way.
But meta-data for data governance has humans as the primary user (e.g. CDOs, business/data analysts, process owners, etc) – or, as Alation describes it – meta-data for human collaboration.
Currently, there is no accepted standards for ensuring the consistency of ‘meta-data for human collaboration’ with ‘meta-data for query execution’.
Ideally, the human-oriented tools would generate standard events that tools in the data pipeline could pick up and act on (via, for example, something like AWS EventBridge), thereby avoiding the need for data governance personnel to oversee multiple data pipelines directly…
With the advent of cloud-based managed compute and data storage services, a multi-data warehouse and pipeline strategy is viable and may even be desirable, potentially involving multiple data lakes.
Solutions like PartiQL have the potential to eliminate many transformation job phases and greatly simplify data pipeline complexity in a standardized way, leveraging existing SQL skills rather than requiring new skills.
To ensure consistent governance across multiple data pipelines, a serverless event-based approach to connecting human data governance solutions with cloud-native data pipeline solutions may be the way forward – for example, using AWS EventBridge to action events originating from SaaS-based data governance services with data pipelines.