A hierarchical, NoSQL, in-memory data store with a RESTful API.

What is a hierarchical data store?

A hierarchical data store is a service which facilitates CRUD actions on data organized in a tree structure with a pre-determined depth.

An example domain may define these relationships:

• Continents have countries
• Countries may have states (or provinces)
• States have cities

The hierarchy is then defined as:

graph TD;
continents --> countries --> states --> cities

A hierarchical data store enforces rules to maintain the integrity of the tree structure. All elements need have a parent of the pre-defined type. In our example domain described above, countries cannot exist without a parent continent, and cities cannot be created as direct children of a country.

A hierarchical data store makes it easy to query the stored entities at any depth and retrieve the parent nodes or the children nodes in a single request. For example, to get a country's properties along with the states of that country and the cities in those states, send a request with the countries label, the country's ID and the depth parameter set to 2.

Why use a hierarchical data store?

Some applications can represent their data model as a hierarchy. A specialized data store can take advantage of optimized data structures for fast reads. A hierarchichal data store also provides a simple interface to write and query nodes in the hierarchy. This reduces code complexity and development time.

How does MonarchStore compare against a relational database?

Relational databases, such as MySQL or PostgreSQL, can be slow, since joins are computed at query time. Moreover, they often require the application to make a trade-off between making multiple round trips or repeating the joinned data when a query involves many tables. A hierarchical database can provide the data of an entire hierarchy with a single request, and keeps references to related entities in memory to bypass the join computation at query time.

How does MonarchStore compare against a graph database?

Graph databases, such as Neo4J or OrientDB, store hard-links between entities and don't have to compute joins at query time. Yet, graph databases provide too much flexibility. In a graph database, any vertex can be linked to any other vertex of any type and vertices can be created even without a parent vertex to attach to. A hierarchical data store enforces every newly created entity to have a parent unless they are meant to be directly under the root.

Applications querying a graph database must construct a query string. These graph queries, in essence, redundantly redeclare the relationships among the entities in the hierarchy. There is a neglible but existent step for the graph databases to parse this query on every request. Entities in a hierarchical data store can only have one parent and zero or more children, and this information only needs to be provided at creation time.

How does MonarchStore compare against a key-value store?

Key-Value stores, such as Redis or Riak KV, provide the fastest reads when all data is stored as a JSON blob, but frequently modifying a deeply nested value is inneficient. The application must pull the entire hierarchy from the root to the leaves, deserialize it, make changes, serialize it, and update the data store. A hierarchical data store allows applications to efficiently create or update a single nested entity without reading all other entities in the hierarchy.

How does MonarchStore compare against a document store?

Document stores, such as MongoDB or Elasticsearch, need to make multiple round trips to get the child entities. The alternative is to store all the data into a single, large, highly-nested document, which is inneficient to fetch and update, and so large that it becomes too difficult to handle.

MonarchStore Features

• Queries can return any entity in any of the hierarchy levels.
• Queries can specify the depth level of child entities to reduce the amount of data returned.
• Entities may have custom properties.
• Each entity can be updated independently of it's parent or child entities.
• In memory storage provides speedy reads and writes atomically.
• The RESTful HTTP interface combines the application relational logic and the data store. When there is no additional domain logic to add, putting MonarchStore behind a protected proxy makes writing REST APIs unnecessary. Application architectures can be reduced from a database server + application server to a MonarchStore single server.

Setting up MonarchStore

Prerequisites

Go > 1.8

Compiling into a binary

go get github.com/MonarchStore/monarchs
cd $GOPATH/github.com/MonarchStore/monarchs
go install

Running the database

$GOPATH/bin/monarchs

Environment

LISTEN_PORT=":6789"

CLI Options

  -addr string
        The binding address (default ":6789")

REST API

Sample Usage

Below are sample REST CRUD actions for a registry of continents -> countries -> states -> cities. These actions are available as a Postman collection.

Define the "locations" hierarchy

POST http://localhost:6789/locations

["continents", "countries", "states", "cities"]

View the "locations" hiearchy we just created

GET http://localhost:6789/locations

Create a "continent" document under the "root" document

POST http://localhost:6789/locations/continents/north_america?parent=root

{"name": "North America"}

Create a "country" document

POST http://localhost:6789/locations/countries/usa?parent=north_america

{"name": "United States of America", "capital": "Washington, DC", "code": "usa"}

Create a "state" document

POST http://localhost:6789/locations/states/ny?parent=usa

{"name": "New York", "abbr": "NY"}

Create another "state" document

POST http://localhost:6789/locations/states/ca?parent=usa

{"name": "California", "abbr": "CA"}

Create a "city" document

POST http://localhost:6789/locations/cities/nyc?parent=ny

{"name": "New York City"}

Update a "city" document

PUT http://localhost:6789/locations/cities/nyc

{"name": "New York City", "stats": {"population_in_millions": 8.491}}

Read the "root" document and all the elements in the hierarchy

GET http://localhost:6789/locations/root/root?depth=4

The steps above would result in this hierarchy:

graph LR;
root:::current
    --> north_america[North America]:::child
    --> usa[United States of America]:::child
    --> ny[New York State]:::child
    --> nyc[New York City]:::child

usa
    --> ca[California]:::child

classDef current fill:#E3371E
classDef child fill:#0593A2
classDef parent fill:#103778

Read a "country" document, with all of its "state" documents and "city" documents

GET http://localhost:6789/locations/countries/usa?depth=2

Which would result in this hierarchy:

graph LR;
usa[United States of America]:::current
    --> ny[New York State]:::child
    --> nyc[New York City]:::child

usa
    --> ca[California]:::child

classDef current fill:#E3371E
classDef child fill:#0593A2
classDef parent fill:#103778

Read a "city" document, and the parent "state" document, and the grandparent "country" document

GET http://localhost:6789/locations/cities/nyc?depth=0&parents=2

Which would result in this hierarchy:

graph LR;
usa[United States of America]:::parent
    --> ny[New York State]:::parent
    --> nyc[New York City]:::current

classDef current fill:#E3371E
classDef child fill:#0593A2
classDef parent fill:#103778

Read a "country" document, the parent "continent" document, and the children "state" documents

GET http://localhost:6789/locations/countries/usa?depth=1&parents=1

Which would result in this hierarchy:

graph LR;
north_america[North America]:::parent
    --> usa[United States of America]:::current
    --> ny[New York State]:::child
usa
    --> ca[California]:::child

classDef current fill:#E3371E
classDef child fill:#0593A2
classDef parent fill:#103778

Delete a "country" document. All children "state" documents and grandchilden "city" documents are deleted as well

DELETE http://localhost:6789/locations/countries/usa

Delete the "locations" hierarchy

DELETE http://localhost:6789/locations