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Guide to Super Graph
Without writing a line of code get an instant high-performance GraphQL API for your Ruby-on-Rails app. Super Graph will automatically understand your apps database and expose a secure, fast and complete GraphQL API for it. Built in support for Rails authentication and JWT tokens.
Features
- Works with Rails database schemas
- Automatically learns schemas and relationships
- Belongs-To, One-To-Many and Many-To-Many table relationships
- Full text search and Aggregations
- Rails Auth supported (Redis, Memcache, Cookie)
- JWT tokens supported (Auth0, etc)
- Join with remote REST APIs
- Highly optimized and fast Postgres SQL queries
- Configure with a simple config file
- High performance GO codebase
- Tiny docker image and low memory requirements
Try it out
# download super graph source
git clone https://github.com/dosco/super-graph.git
# setup the demo rails app & database and run it
./demo start
# signin to the demo app (user1@demo.com / 123456)
open http://localhost:3000
# try the super graph web ui
open http://localhost:8080
::: warning DEMO REQUIREMENTS
This demo requires docker
you can either install it using brew
or from the
docker website https://docs.docker.com/docker-for-mac/install/
:::
Trying out GraphQL
We currently support the query
action which is used for fetching data. Support for mutation
and subscriptions
is work in progress. For example the below GraphQL query would fetch two products that belong to the current user where the price is greater than 10
GQL Query
query {
users {
id
email
picture : avatar
password
full_name
products(limit: 2, where: { price: { gt: 10 } }) {
id
name
description
price
}
}
}
The above GraphQL query returns the JSON result below. It handles all kinds of complexity without you having to writing a line of code.
For example there is a while greater than gt
and a limit clause on a child field. And the avatar
field is renamed to picture
. The password
field is blocked and not returned. Finally the relationship between the users
table and the products
table is auto discovered and used.
JSON Result
{
"data": {
"users": [
{
"id": 1,
"email": "odilia@west.info",
"picture": "https://robohash.org/simur.png?size=300x300",
"full_name": "Edwin Orn",
"products": [
{
"id": 16,
"name": "Sierra Nevada Style Ale",
"description": "Belgian Abbey, 92 IBU, 4.7%, 17.4°Blg",
"price": 16.47
},
...
]
}
]
}
}
Try with an authenticated user
In development mode you can use the X-User-ID: 4
header to set a user id so you don't have to worries about cookies etc. This can be set using the HTTP Headers tab at the bottom of the web UI you'll see when you visit the above link. You can also directly run queries from the commandline like below.
Querying the GQL endpoint
# fetch the response json directly from the endpoint using user id 5
curl 'http://localhost:8080/api/v1/graphql' \
-H 'content-type: application/json' \
-H 'X-User-ID: 5' \
--data-binary '{"query":"{ products { name price users { email }}}"}'
How to GraphQL
GraphQL (GQL) is a simple query syntax that's fast replacing REST APIs. GQL is great since it allows web developers to fetch the exact data that they need without depending on changes to backend code. Also if you squint hard enough it looks a little bit like JSON 😃
The below query will fetch an users
name, email and avatar image (renamed as picture). If you also need the users id
then just add it to the query.
query {
user {
full_name
email
picture : avatar
}
}
Fetching data
To fetch a specific product
by it's ID you can use the id
argument. The real name id field will be resolved automatically so this query will work even if your id column is named something like product_id
.
query {
products(id: 3) {
name
}
}
Postgres also supports full text search using a TSV index. Super Graph makes it easy to use this full text search capability using the search
argument.
query {
products(search "amazing") {
name
}
}
Complex queries (Where)
Super Graph support complex queries where you can add filters, ordering,offsets and limits on the query.
Logical Operators
Name | Example | Explained |
---|---|---|
and | price : { and : { gt: 10.5, lt: 20 } | price > 10.5 AND price < 20 |
or | or : { price : { greater_than : 20 }, quantity: { gt : 0 } } | price >= 20 OR quantity > 0 |
not | not: { or : { quantity : { eq: 0 }, price : { eq: 0 } } } | NOT (quantity = 0 OR price = 0) |
Other conditions
Name | Example | Explained |
---|---|---|
eq, equals | id : { eq: 100 } | id = 100 |
neq, not_equals | id: { not_equals: 100 } | id != 100 |
gt, greater_than | id: { gt: 100 } | id > 100 |
lt, lesser_than | id: { gt: 100 } | id < 100 |
gte, greater_or_equals | id: { gte: 100 } | id >= 100 |
lte, lesser_or_equals | id: { lesser_or_equals: 100 } | id <= 100 |
in | status: { in: [ "A", "B", "C" ] } | status IN ('A', 'B', 'C) |
nin, not_in | status: { in: [ "A", "B", "C" ] } | status IN ('A', 'B', 'C) |
like | name: { like "phil%" } | Names starting with 'phil' |
nlike, not_like | name: { nlike "v%m" } | Not names starting with 'v' and ending with 'm' |
ilike | name: { ilike "%wOn" } | Names ending with 'won' case-insensitive |
nilike, not_ilike | name: { nilike "%wOn" } | Not names ending with 'won' case-insensitive |
similar | name: { similar: "%(b|d)%" } | Similar Docs |
nsimilar, not_similar | name: { nsimilar: "%(b|d)%" } | Not Similar Docs |
has_key | column: { has_key: 'b' } | Does JSON column contain this key |
has_key_any | column: { has_key_any: [ a, b ] } | Does JSON column contain any of these keys |
has_key_all | column: [ a, b ] | Does JSON column contain all of this keys |
contains | column: { contains: [1, 2, 4] } | Is this array/json column a subset of value |
contained_in | column: { contains: "{'a':1, 'b':2}" } | Is this array/json column a subset of these value |
is_null | column: { is_null: true } | Is column value null or not |
Aggregation (Max, Count, etc)
You will often find the need to fetch aggregated values from the database such as count
, max
, min
, etc. This is simple to do with GraphQL, just prefix the aggregation name to the field name that you want to aggregrate like count_id
. The below query will group products by name and find the minimum price for each group. Notice the min_price
field we're adding min_
to price.
query {
products {
name
min_price
}
}
Name | Explained |
---|---|
avg | Average value |
count | Count the values |
max | Maximum value |
min | Minimum value |
stddev | Standard Deviation |
stddev_pop | Population Standard Deviation |
stddev_samp | Sample Standard Deviation |
variance | Variance |
var_pop | Population Standard Variance |
var_samp | Sample Standard variance |
All kinds of queries are possible with GraphQL. Below is an example that uses a lot of the features available. Comments # hello
are also valid within queries.
query {
products(
# returns only 30 items
limit: 30,
# starts from item 10, commented out for now
# offset: 10,
# orders the response items by highest price
order_by: { price: desc },
# no duplicate prices returned
distinct: [ price ]
# only items with an id >= 30 and < 30 are returned
where: { id: { and: { greater_or_equals: 20, lt: 28 } } }) {
id
name
price
}
}
Using variables
Variables ($product_id
) and their values ("product_id": 5
) can be passed along side the GraphQL query. Using variables makes for better client side code as well as improved server side SQL query caching. The build-in web-ui also supports setting variables. Not having to manipulate your GraphQL query string to insert values into it makes for cleaner
and better client side code.
// Define the request object keeping the query and the variables seperate
var req = {
query: '{ product(id: $product_id) { name } }' ,
variables: { "product_id": 5 }
}
// Use the fetch api to make the query
fetch('http://localhost:8080/api/v1/graphql', {
method: 'POST',
headers: { 'Content-Type': 'application/json' },
body: JSON.stringify(req),
})
.then(res => res.json())
.then(res => console.log(res.data));
Full text search
Every app these days needs search. Enought his often means reaching for something heavy like Solr. While this will work why add complexity to your infrastructure when Postgres has really great and fast full text search built-in. And since it's part of Postgres it's also available in Super Graph.
query {
products(
# Search for all products that contain 'ale' or some version of it
search: "ale"
# Return only matches where the price is less than 10
where: { price: { lt: 10 } }
# Use the search_rank to order from the best match to the worst
order_by: { search_rank: desc }) {
id
name
search_rank
search_headline_description
}
}
This query will use the tsvector
column in your database table to search for products that contain the query phrase or some version of it. To get the internal relevance ranking for the search results using the search_rank
field. And to get the highlighted context within any of the table columns you can use the search_headline_
field prefix. For example search_headline_name
will return the contents of the products name column which contains the matching query marked with the <b></b>
html tags.
{
"data": {
"products": [
{
"id": 11,
"name": "Maharaj",
"search_rank": 0.243171,
"search_headline_description": "Blue Moon, Vegetable Beer, Willamette, 1007 - German <b>Ale</b>, 48 IBU, 7.9%, 11.8°Blg"
},
{
"id": 12,
"name": "Schneider Aventinus",
"search_rank": 0.243171,
"search_headline_description": "Dos Equis, Wood-aged Beer, Magnum, 1099 - Whitbread <b>Ale</b>, 15 IBU, 9.5%, 13.0°Blg"
},
...
Adding search to your Rails app
It's really easy to enable Postgres search on any table within your database schema. All it takes is to create the following migration. In the below example we add a full-text search to the products
table.
class AddSearchColumn < ActiveRecord::Migration[5.1]
def self.up
add_column :products, :tsv, :tsvector
add_index :products, :tsv, using: "gin"
say_with_time("Adding trigger to update the ts_vector column") do
execute <<-SQL
CREATE FUNCTION products_tsv_trigger() RETURNS trigger AS $$
begin
new.tsv :=
setweight(to_tsvector('pg_catalog.english', coalesce(new.name,'')), 'A') ||
setweight(to_tsvector('pg_catalog.english', coalesce(new.description,'')), 'B');
return new;
end
$$ LANGUAGE plpgsql;
CREATE TRIGGER tsvectorupdate BEFORE INSERT OR UPDATE ON products FOR EACH ROW EXECUTE PROCEDURE products_tsv_trigger();
SQL
end
end
def self.down
say_with_time("Removing trigger to update the tsv column") do
execute <<-SQL
DROP TRIGGER tsvectorupdate
ON products
SQL
end
remove_index :products, :tsv
remove_column :products, :tsv
end
end
Join with remote REST APIs
It often happens that after fetching some data from the DB we need to call another API to fetch some more data and all this combined into a single JSON response. For example along with a list of users you need their last 5 payments from Stripe. This requires you to query your DB for the users and Stripe for the payments. Super Graph handles all this for you also only the fields you requested from the Stripe API are returned. All this is a very performance focused way.
For example you need to list the last 3 payments made by a user. You will first need to look up the user in the database and then call the Stripe API to fetch his last 3 payments. For this to work your user table in the db has a customer_id
column that contains his Stripe customer ID.
Similiarly you might also have the need to fetch the users last tweet and include that too. Super Graph can handle this for you using it's API Stitching
feature.
Stripe API example
The configuration is self explanatory. A payments
field has been added under the customers
table. This field is added to the remotes
subsection that defines fields associated with customers
that are remote and not real database columns.
The id
parameter maps a column from the customers
table to the $id
variable. In this case it maps $id
to the customer_id
column.
tables:
- name: customers
remotes:
- name: payments
id: stripe_id
url: http://rails_app:3000/stripe/$id
path: data
# pass_headers:
# - cookie
# - host
set_headers:
- name: Authorization
value: Bearer <stripe_api_key>
How do I make use of this?
Just include payments
like you would any other GraphQL selector under the customers
selector. Super Graph will call the configured API for you and stitch (merge) the JSON the API sends back with the JSON generated from the database query. GraphQL features like aliases and fields all work.
query {
customers {
id
email
payments {
customer_id
amount
billing_details
}
}
}
And voila here is the result. You get all of this advanced and honestly complex querying capability without writing a single line of code.
"data": {
"customers": [
{
"id": 1,
"email": "linseymertz@reilly.co",
"payments": [
{
"customer_id": "cus_YCj3ndB5Mz",
"amount": 100,
"billing_details": {
"address": "1 Infinity Drive",
"zipcode": "94024"
}
},
...
Even tracing data is availble in the Super Graph web UI if tracing is enabled in the config. By default it is for development.
Authentication
You can only have one type of auth enabled. You can either pick Rails or JWT.
Rails Auth (Devise / Warden)
Almost all Rails apps use Devise or Warden for authentication. Once the user is authenticated a session is created with the users ID. The session can either be stored in the users browser as a cookie, memcache or redis. If memcache or redis is used then a cookie is set in the users browser with just the session id.
Super Graph can handle all these variations including the old and new session formats. Just enable the right auth
config based on how your rails app is configured.
Cookie session store
auth:
type: rails
cookie: _app_session
rails:
# Rails version this is used for reading the
# various cookies formats.
version: 5.2
# Found in 'Rails.application.config.secret_key_base'
secret_key_base: 0a248500a64c01184edb4d7ad3a805488f8097ac761b76aaa6c17c01dcb7af03a2f18ba61b2868134b9c7b79a122bc0dadff4367414a2d173297bfea92be5566
Memcache session store
auth:
type: rails
cookie: _app_session
rails:
# Memcache remote cookie store.
url: memcache://127.0.0.1
Redis session store
auth:
type: rails
cookie: _app_session
rails:
# Redis remote cookie store
url: redis://127.0.0.1:6379
password: ""
max_idle: 80
max_active: 12000
JWT Token Auth
auth:
type: jwt
jwt:
# the two providers are 'auth0' and 'none'
provider: auth0
secret: abc335bfcfdb04e50db5bb0a4d67ab9
public_key_file: /secrets/public_key.pem
public_key_type: ecdsa #rsa
For JWT tokens we currently support tokens from a provider like Auth0
or if you have a custom solution then we look for the user_id
in the
subject
claim of of the id token
. If you pick Auth0 then we derive two variables from the token user_id
and user_id_provider
for to use in your filters.
We can get the JWT token either from the authorization
header where we expect it to be a bearer
token or if cookie
is specified then we look there.
For validation a secret
or a public key (ecdsa or rsa) is required. When using public keys they have to be in a PEM format file.
Easy to setup
Configuration files can either be in YAML or JSON their names are derived from the GO_ENV
variable, for example GO_ENV=prod
will cause the prod.yaml
config file to be used. or GO_ENV=dev
will use the dev.yaml
. A path to look for the config files in can be specified using the -path <folder>
command line argument.
We're tried to ensure that the config file is self documenting and easy to work with.
app_name: "Super Graph Development"
host_port: 0.0.0.0:8080
web_ui: true
debug_level: 1
# enabling tracing also disables query caching
enable_tracing: true
# Throw a 401 on auth failure for queries that need auth
# valid values: always, per_query, never
auth_fail_block: never
# Postgres related environment Variables
# SG_DATABASE_HOST
# SG_DATABASE_PORT
# SG_DATABASE_USER
# SG_DATABASE_PASSWORD
# Auth related environment Variables
# SG_AUTH_RAILS_COOKIE_SECRET_KEY_BASE
# SG_AUTH_RAILS_REDIS_URL
# SG_AUTH_RAILS_REDIS_PASSWORD
# SG_AUTH_JWT_PUBLIC_KEY_FILE
# inflections:
# person: people
# sheep: sheep
auth:
# Can be 'rails' or 'jwt'
type: rails
cookie: _app_session
# Comment this out if you want to disable setting
# the user_id via a header. Good for testing
header: X-User-ID
rails:
# Rails version this is used for reading the
# various cookies formats.
version: 5.2
# Found in 'Rails.application.config.secret_key_base'
secret_key_base: 0a248500a64c01184edb4d7ad3a805488f8097ac761b76aaa6c17c01dcb7af03a2f18ba61b2868134b9c7b79a122bc0dadff4367414a2d173297bfea92be5566
# Remote cookie store. (memcache or redis)
# url: redis://127.0.0.1:6379
# password: test
# max_idle: 80,
# max_active: 12000,
# In most cases you don't need these
# salt: "encrypted cookie"
# sign_salt: "signed encrypted cookie"
# auth_salt: "authenticated encrypted cookie"
# jwt:
# provider: auth0
# secret: abc335bfcfdb04e50db5bb0a4d67ab9
# public_key_file: /secrets/public_key.pem
# public_key_type: ecdsa #rsa
database:
type: postgres
host: db
port: 5432
dbname: app_development
user: postgres
password: ''
# pool_size: 10
# max_retries: 0
# log_level: "debug"
# Define variables here that you want to use in filters
variables:
account_id: "select account_id from users where id = $user_id"
# Define defaults to for the field key and values below
defaults:
filter: ["{ user_id: { eq: $user_id } }"]
# Field and table names that you wish to block
blacklist:
- ar_internal_metadata
- schema_migrations
- secret
- password
- encrypted
- token
tables:
- name: users
# This filter will overwrite defaults.filter
filter: ["{ id: { eq: $user_id } }"]
- name: products
# Multiple filters are AND'd together
filter: [
"{ price: { gt: 0 } }",
"{ price: { lt: 8 } }"
]
- name: customers
# No filter is used for this field not
# even defaults.filter
filter: none
remotes:
- name: payments
id: stripe_id
url: http://rails_app:3000/stripe/$id
path: data
# pass_headers:
# - cookie
# - host
set_headers:
- name: Authorization
value: Bearer <stripe_api_key>
- # You can create new fields that have a
# real db table backing them
name: me
table: users
filter: ["{ id: { eq: $user_id } }"]
# - name: posts
# filter: ["{ account_id: { _eq: $account_id } }"]
If deploying into environments like Kubernetes it's useful to be able to configure things like secrets and hosts though environment variables therfore we expose the below environment variables. This is escpecially useful for secrets since they are usually injected in via a secrets management framework ie. Kubernetes Secrets
Keep in mind any value can be overwritten using environment variables for example auth.jwt.public_key_type
converts to SG_AUTH_JWT_PUBLIC_KEY_TYPE
. In short prefix SG_
, upper case and all .
should changed to _
.
Postgres environment variables
SG_DATABASE_HOST
SG_DATABASE_PORT
SG_DATABASE_USER
SG_DATABASE_PASSWORD
Auth environment variables
SG_AUTH_RAILS_COOKIE_SECRET_KEY_BASE
SG_AUTH_RAILS_REDIS_URL
SG_AUTH_RAILS_REDIS_PASSWORD
SG_AUTH_JWT_PUBLIC_KEY_FILE
Developing Super Graph
If you want to build and run Super Graph from code then the below commands will build the web ui and launch Super Graph in developer mode with a watcher to rebuild on code changes. And the demo rails app is also launched to make it essier to test changes.
# yarn is needed to build the web ui
brew install yarn
# yarn install dependencies and build the web ui
(cd web && yarn install && yarn build)
# generate some stuff the go code needs
go generate ./...
# do this the only the time to setup the database
docker-compose run rails_app rake db:create db:migrate
# start super graph in development mode with a change watcher
docker-compose up
MIT License
MIT Licensed | Copyright © 2018-present Vikram Rangnekar