You are viewing the README for version 2 of Dynamoid. See the CHANGELOG for details on breaking changes since 1.3.x.
For version 1.3.x use the 1-3-stable branch.
Dynamoid is an ORM for Amazon's DynamoDB for Ruby applications. It provides similar functionality to ActiveRecord and improves on Amazon's existing HashModel by providing better searching tools and native association support.
DynamoDB is not like other document-based databases you might know, and is very different indeed from relational databases. It sacrifices anything beyond the simplest relational queries and transactional support to provide a fast, cost-efficient, and highly durable storage solution. If your database requires complicated relational queries and transaction support, then this modest Gem cannot provide them for you, and neither can DynamoDB. In those cases you would do better to look elsewhere for your database needs.
But if you want a fast, scalable, simple, easy-to-use database (and a Gem that supports it) then look no further!
Project | Dynamoid |
---|---|
gem name | dynamoid |
license | MIT |
download rank | |
version | |
dependencies | |
code quality | |
continuous integration | |
test coverage | |
triage helpers | |
homepage | https://github.com/Dynamoid/Dynamoid |
documentation | http://rdoc.info/github/Dynamoid/Dynamoid/frames |
Installing Dynamoid is pretty simple. First include the Gem in your Gemfile:
gem 'dynamoid', '~> 2'
Dynamoid depends on the aws-sdk, and this is tested on the current version of aws-sdk (~> 2), rails (>= 4). Hence the configuration as needed for aws to work will be dealt with by aws setup.
Here are the steps to setup aws-sdk.
gem 'aws-sdk', '~>2'
(or) include the aws-sdk in your Gemfile.
Make sure you are using the version for the right AWS SDK.
Dynamoid version | AWS SDK Version |
---|---|
0.x | 1.x |
1.x | 2.x |
2.x | 2.x |
3.x (unreleased) | 3.x |
Configure AWS access: Reference
For example, to configure AWS access:
Create config/initializers/aws.rb as follows:
Aws.config.update({
region: 'us-west-2',
credentials: Aws::Credentials.new('REPLACE_WITH_ACCESS_KEY_ID', 'REPLACE_WITH_SECRET_ACCESS_KEY'),
})
Alternatively, if you don't want Aws connection settings to be overwritten for you entire project, you can specify connection settings for Dynamoid only, by setting those in the Dynamoid.configure
clause:
Dynamoid.configure do |config|
config.access_key = 'REPLACE_WITH_ACCESS_KEY_ID'
config.secret_key = 'REPLACE_WITH_SECRET_ACCESS_KEY'
config.region = 'us-west-2'
end
For a full list of the DDB regions, you can go here.
Then you need to initialize Dynamoid config to get it going. Put code similar to this somewhere (a Rails initializer would be a great place for this if you're using Rails):
Dynamoid.configure do |config|
config.namespace = "dynamoid_app_development" # To namespace tables created by Dynamoid from other tables you might have. Set to nil to avoid namespacing.
config.endpoint = 'http://localhost:3000' # [Optional]. If provided, it communicates with the DB listening at the endpoint. This is useful for testing with [Amazon Local DB] (http://docs.aws.amazon.com/amazondynamodb/latest/developerguide/Tools.DynamoDBLocal.html).
end
Ruby / Active Record | 4.0.x | 4.1.x | 4.2.x | 5.0.x |
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2.0.0 | âś“ | âś“ | âś“ | |
2.1.x | âś“ | âś“ | âś“ | |
2.2.0-2.2.1 | âś“ | âś“ | âś“ | |
2.2.2+ | âś“ | âś“ | âś“ | âś“ |
2.3.x | âś“ | âś“ | âś“ | âś“ |
2.3.x | âś“ | âś“ | âś“ | âś“ |
2.4.x | âś“ | âś“ | ||
jruby-9.X | âś“ | âś“ | âś“ | âś“ |
You must include Dynamoid::Document
in every Dynamoid model.
class User
include Dynamoid::Document
end
Dynamoid has some sensible defaults for you when you create a new table, including the table name and the primary key column. But you can change those if you like on table creation.
class User
include Dynamoid::Document
table :name => :awesome_users, :key => :user_id, :read_capacity => 5, :write_capacity => 5
end
These fields will not change an existing table: so specifying a new read_capacity and write_capacity here only works correctly for entirely new tables. Similarly, while Dynamoid will look for a table named awesome_users
in your namespace, it won't change any existing tables to use that name; and if it does find a table with the correct name, it won't change its hash key, which it expects will be user_id. If this table doesn't exist yet, however, Dynamoid will create it with these options.
You'll have to define all the fields on the model and the data type of each field. Every field on the object must be included here; if you miss any they'll be completely bypassed during DynamoDB's initialization and will not appear on the model objects.
By default, fields are assumed to be of type :string
. Other built-in types are
:integer
, :number
, :set
, :array
, :datetime
, date
, :boolean
, :raw
and :serialized
.
raw
type means you can store Ruby Array, Hash, String and numbers.
If built-in types do not suit you, you can use a custom field type represented by an arbitrary class, provided that the class supports a compatible serialization interface.
The primary use case for using a custom field type is to represent your business logic with high-level types, while ensuring portability or backward-compatibility of the serialized representation.
The boolean fields are stored as "t", "f"
strings by default. DynamoDB
supports boolean type natively. So if you want to use native boolean
type or already have table with native boolean attribute you can easily
achieve this with store_as_native_boolean
option:
class Document
include DynamoId::Document
field :active, :boolean, store_as_native_boolean: true
end
By default date fields are persisted as days count since 1 January 1970 like UNIX time. If you prefer dates to be stored as ISO-8601 formatted strings instead then set store_as_string
to true
class Document
include DynamoId::Document
field :sent_at, :datetime, store_as_string: true
end
By default datetime fields are persisted as UNIX timestamps with milisecond precission in DynamoDB. If you prefer datetimes to be stored as ISO-8601 formatted strings instead then set store_as_string
to true
class Document
include DynamoId::Document
field :sent_at, :datetime, store_as_string: true
end
You get magic columns of id (string), created_at (datetime), and updated_at (datetime) for free.
class User
include Dynamoid::Document
field :name
field :email
field :rank, :integer
field :number, :number
field :joined_at, :datetime
field :hash, :serialized
end
You can optionally set a default value on a field using either a plain value or a lambda:
field :actions_taken, :integer, {default: 0}
field :joined_at, :datetime, {default: ->(){Time.now}}
To use a custom type for a field, suppose you have a Money
type.
class Money
# ... your business logic ...
def dynamoid_dump
"serialized representation as a string"
end
def self.dynamoid_load(serialized_str)
# parse serialized representation and return a Money instance
Money.new(1.23)
end
end
class User
include Dynamoid::Document
field :balance, Money
end
If you want to use a third-party class (which does not support #dynamoid_dump
and .dynamoid_load
)
as your field type, you can use an adapter class providing .dynamoid_dump
and .dynamoid_load
class methods
for your third-party class. (.dynamoid_load
can remain the same from the previous example; here we just
add a level of indirection for serializing.) Example:
# Third-party Money class
class Money; end
class MoneyAdapter
def self.dynamoid_load(money_serialized_str)
Money.new(1.23)
end
def self.dynamoid_dump(money_obj)
money_obj.value.to_s
end
end
class User
include Dynamoid::Document
field :balance, MoneyAdapter
end
Lastly, you can control the data type of your custom-class-backed field at the DynamoDB level.
This is especially important if you want to use your custom field as a numeric range or for
number-oriented queries. By default custom fields are persisted as a string attribute, but
your custom class can override this with a .dynamoid_field_type
class method, which would
return either :string
or :number
.
DynamoDB may support some other attribute types that are not yet supported by Dynamoid.
Just like in ActiveRecord (or your other favorite ORM), Dynamoid uses associations to create links between models.
The only supported associations (so far) are has_many
, has_one
, has_and_belongs_to_many
, and belongs_to
. Associations are very simple to create: just specify the type, the name, and then any options you'd like to pass to the association. If there's an inverse association either inferred or specified directly, Dynamoid will update both objects to point at each other.
class User
include Dynamoid::Document
# ...
has_many :addresses
has_many :students, :class => User
belongs_to :teacher, :class_name => :user
belongs_to :group
belongs_to :group, :foreign_key => :group_id
has_one :role
has_and_belongs_to_many :friends, :inverse_of => :friending_users
end
class Address
include Dynamoid::Document
# ...
belongs_to :user # Automatically links up with the user model
end
Contrary to what you'd expect, association information is always contained on the object specifying the association, even if it seems like the association has a foreign key. This is a side effect of DynamoDB's structure: it's very difficult to find foreign keys without an index. Usually you won't find this to be a problem, but it does mean that association methods that build new models will not work correctly -- for example, user.addresses.new
returns an address that is not associated to the user. We'll be correcting this soon maybe someday, if we get a pull request.
Dynamoid bakes in ActiveModel validations, just like ActiveRecord does.
class User
include Dynamoid::Document
# ...
validates_presence_of :name
validates_format_of :email, :with => /@/
end
To see more usage and examples of ActiveModel validations, check out the ActiveModel validation documentation.
If you want to bypass model validation, pass validate: false
to save
call:
model.save(validate: false)
Dynamoid also employs ActiveModel callbacks. Right now, callbacks are defined on save
, update
, destroy
, which allows you to do before_
or after_
any of those.
class User
include Dynamoid::Document
# ...
before_save :set_default_password
after_create :notify_friends
after_destroy :delete_addresses
end
Dynamoid supports STI (Single Table Inheritance) like Active Record does. You need just specify type
field in a base class. Example:
class Animal
include Dynamoid::Document
field :name
field :type
end
class Cat < Animal
field :lives, :integer
end
cat = Cat.create(name: 'Morgan')
animal = Animal.find(cat.id)
animal.class
#=> Cat
Dynamoid's syntax is generally very similar to ActiveRecord's. Making new objects is simple:
u = User.new(:name => 'Josh')
u.email = '[email protected]'
u.save
Save forces persistence to the datastore: a unique ID is also assigned, but it is a string and not an auto-incrementing number.
u.id # => "3a9f7216-4726-4aea-9fbc-8554ae9292cb"
To use associations, you use association methods very similar to ActiveRecord's:
address = u.addresses.create
address.city = 'Chicago'
address.save
To create multiple documents at once:
User.create([{name: 'Josh'}, {name: 'Nick'}])
There is an efficient and low-level way to create multiple documents (without validation and callbacks running):
users = User.import([{name: 'Josh'}, {name: 'Nick'}])
Querying can be done in one of three ways:
Address.find(address.id) # Find directly by ID.
Address.where(:city => 'Chicago').all # Find by any number of matching criteria... though presently only "where" is supported.
Address.find_by_city('Chicago') # The same as above, but using ActiveRecord's older syntax.
And you can also query on associations:
u.addresses.where(:city => 'Chicago').all
But keep in mind Dynamoid -- and document-based storage systems in general -- are not drop-in replacements for existing relational databases. The above query does not efficiently perform a conditional join, but instead finds all the user's addresses and naively filters them in Ruby. For large associations this is a performance hit compared to relational database engines.
There are three types of limits that you can query with:
record_limit
- The number of evaluated records that are returned by the query.scan_limit
- The number of scanned records that DynamoDB will look at before returning.batch_size
- The number of records requested to DynamoDB per underlying request, good for large queries!
Using these in various combinations results in the underlying requests to be made in the smallest size possible and
the query returns once record_limit
or scan_limit
is satisfied. It will attempt to batch whenever possible.
You can thus limit the number of evaluated records, or select a record from which to start in order to support pagination.
Address.record_limit(5).start(address) # Only 5 addresses starting at `address`
Where address
is an instance of the model or a hash {the_model_hash_key: 'value', the_model_range_key: 'value'}
:
Keep in mind that if you are passing a hash to .start()
you need to explicitly define all required keys in it including range keys, depending on table or secondary indexes signatures, otherwise you'll get an Aws::DynamoDB::Errors::ValidationException
either for Exclusive Start Key must have same size as table's key schema
or The provided starting key is invalid
If you are potentially running over a large data set and this is especially true when using certain filters, you may want to consider limiting the number of scanned records (the number of records DynamoDB infrastructure looks through when evaluating data to return):
Address.scan_limit(5).start(address) # Only scan at most 5 records and return what's found starting from `address`
For large queries that return many rows, Dynamoid can use AWS' support for requesting documents in batches:
# Do some maintenance on the entire table without flooding DynamoDB
Address.all(batch_size: 100).each { |address| address.do_some_work; sleep(0.01) }
Address.record_limit(10_000).batch(100). each { … } # Batch specified as part of a chain
The implication of batches is that the underlying requests are done in the batch sizes to make the request and responses
more manageable. Note that this batching is for Query
and Scans
and not BatchGetItem
commands.
You are able to optimize query with condition for sort key. Following operators are available: gt
, lt
, gte
, lte
,
begins_with
, between
as well as equality:
Address.where(latitude: 10212)
Address.where('latitude.gt' => 10212)
Address.where('latitude.lt' => 10212)
Address.where('latitude.gte' => 10212)
Address.where('latitude.lte' => 10212)
Address.where('city.begins_with' => 'Lon')
Address.where('latitude.between' => [10212, 20000])
You are able to filter results on the DynamoDB side and specify conditions for non-key fields.
Following operators are available: in
, contains
, not_contains
:
Address.where('city.in' => ['London', 'Edenburg', 'Birmingham'])
Address.where('city.contains' => [on])
Address.where('city.not_contains' => [ing])
Querying supports consistent reading. By default, DynamoDB reads are eventually consistent: if you do a write and then a read immediately afterwards, the results of the previous write may not be reflected. If you need to do a consistent read (that is, you need to read the results of a write immediately) you can do so, but keep in mind that consistent reads are twice as expensive as regular reads for DynamoDB.
Address.find(address.id, :consistent_read => true) # Find an address, ensure the read is consistent.
Address.where(:city => 'Chicago').consistent.all # Find all addresses where the city is Chicago, with a consistent read.
If you have a range index, Dynamoid provides a number of additional other convenience methods to make your life a little easier:
User.where("created_at.gt" => DateTime.now - 1.day).all
User.where("created_at.lt" => DateTime.now - 1.day).all
It also supports .gte and .lte. Turning those into symbols and allowing a Rails SQL-style string syntax is in the works. You can only have one range argument per query, because of DynamoDB's inherent limitations, so use it sensibly!
In order to delete some items delete_all
method should be used.
Any callback wont be called. Items delete in efficient way in batch.
Address.where(city: "London").delete_all
You can define index with global_secondary_index
:
class User
include Dynamoid::Document
field :name
field :age, :number
global_secondary_index hash_key: :age
end
There are following options:
hash_key
- is used as hash key of an index,range_key
- is used as range key of an index,projected_attributes
- list of fields to store in an index or has a predefiled value:keys_only
,:all
;:keys_only
is a default,name
- an index will be created with this name when a table is created; by default name is generated and contains table name and keys names,read_capacity
- is used when table creates and used as an index capacity; by default equalsDynamoid::Config.read_capacity
,write_capacity
- is used when table creates and used as an index capacity; by default equalsDynamoid::Config.write_capacity
The only mandatory option is name
.
To use index in Document.where
implicitly you need to project all the fields with option projected_attributes: :all
.
There are two ways to query Global Secondary Indexes (GSI).
The first way explicitly uses your GSI and utilizes the find_all_by_secondary_index
method which will lookup a valid
GSI to use based on the inputs, you MUST provide the correct keys to match the GSI you want:
find_all_by_secondary_index(
{
dynamo_primary_key_column_name => dynamo_primary_key_value
}, # The signature of find_all_by_secondary_index is ugly, so must be an explicit hash here
:range => {
"#{range_column}.#{range_modifier}" => range_value
},
# false is the same as DESC in SQL (newest timestamp first)
# true is the same as ASC in SQL (oldest timestamp first)
:scan_index_forward => false # or true
)
Where the range modifier is one of Dynamoid::Finders::RANGE_MAP.keys
, where the RANGE_MAP
is:
RANGE_MAP = {
'gt' => :range_greater_than,
'lt' => :range_less_than,
'gte' => :range_gte,
'lte' => :range_lte,
'begins_with' => :range_begins_with,
'between' => :range_between,
'eq' => :range_eq
}
Most range searches, like eq
, need a single value, and searches like between
, need an array with two values.
The second way implicitly uses your GSI through the where
clauses and deduces the index based on the query fields
provided. Another added benefit is that it is built into query chaining so you can use all the methods used in normal
querying. The explicit way from above would be rewritten as follows:
where(dynamo_primary_key_column_name => dynamo_primary_key_value,
"#{range_column}.#{range_modifier}" => range_value)
.scan_index_forward(false)
The only caveat with this method is that because it is also used for general querying, it WILL NOT use a GSI unless it
explicitly has defined projected_attributes: :all
on the GSI in your model. This is because GSIs that do not have all
attributes projected will only contain the index keys and therefore will not return objects with fully resolved field
values. It currently opts to provide the complete results rather than partial results unless you've explicitly looked up
the data.
Future TODO could involve implementing select
in chaining as well as resolving the fields with a second query against
the table since a query against GSI then a query on base table is still likely faster than scan on the base table
Listed below are all configuration options.
adapter
- usefull only for the gem developers to switch to a new adapter. Default and the only available value isaws_sdk_v2
namespace
- prefix for table names, default isdynamoid_#{application_name}_#{environment}
for Rails application anddynamoid
otherwiselogger
- by default it's aRails.logger
in Rails application andstdout
otherwise. You can disable logging by settingnil
orfalse
values. Settrue
value to use defaultsaccess_key
- DynamoDb custom credentials for AWS, override global AWS credentials if they presentsecret_key
- DynamoDb custom credentials for AWS, override global AWS credentials if they presentregion
- DynamoDb custom credentials for AWS, override global AWS credentials if they presentbatch_size
- when you try to load multiple items at once withbatch_get_item
call Dynamoid loads them not with one api call but piece by piece. Default is 100 itemsread_capacity
- is used at table or indices creation. Default is 100 (units)write_capacity
- is used at table or indices creation. Default is 20 (units)warn_on_scan
- log warnings when scan table. Default istrue
endpoint
- if provided, it communicates with the DynamoDB listening at the endpoint. This is useful for testing with [Amazon Local DB]identity_map
- ensures that each object gets loaded only once by keeping every loaded object in a map. Looks up objects using the map when referring to them. Isn't thread safe. Default isfalse
.Use Dynamoid::Middleware::IdentityMap
to clear identity map for each HTTP requesttimestamps
- by default Dynamoid setscreated_at
andupdated_at
fields for model at creation and updating. You can disable this behavior by settingfalse
valuesync_retry_max_times
- when Dynamoid creates or deletes table synchronously it checks for completion specified times. Default is 60 (times). It's a bit over 2 minutes by defaultsync_retry_wait_seconds
- time to wait between retries. Default is 2 (seconds)convert_big_decimal
- iftrue
then Dynamoid converts numbers stored inHash
inraw
field to float. Default isfalse
models_dir
-dynamoid:create_tables
rake task loads DynamoDb models from this directory. Default isapp/models
. In Rails application you should set./app/models
valueapplication_timezone
- Dynamoid converts alldatetime
fields to specified time zone when loads data from the storage. Acceptable values -utc
,local
(to use system time zone) and time zone name e.g.Eastern Time (US & Canada)
. Default islocal
store_datetime_as_string
- iftrue
then Dynamoid stores :datetime fields in ISO 8601 string format. Default isfalse
store_date_as_string
- iftrue
then Dynamoid stores :date fields in ISO 8601 string format. Default isfalse
Dynamoid supports basic, ActiveRecord-like optimistic locking on save operations. Simply add a lock_version
column to your table like so:
class MyTable
# ...
field :lock_version, :integer
# ...
end
In this example, all saves to MyTable
will raise an Dynamoid::Errors::StaleObjectError
if a concurrent process loaded, edited, and saved the same row. Your code should trap this exception, reload the row (so that it will pick up the newest values), and try the save again.
Calls to update
and update!
also increment the lock_version
, however they do not check the existing value. This guarantees that a update operation will raise an exception in a concurrent save operation, however a save operation will never cause an update to fail. Thus, update
is useful & safe only for doing atomic operations (e.g. increment a value, add/remove from a set, etc), but should not be used in a read-modify-write pattern.
rake dynamoid:create_tables
rake dynamoid:ping
In test environment you will most likely want to clean the database between test runs to keep tests completely isolated. This can be achieved like so
module DynamoidReset
def self.all
Dynamoid.adapter.list_tables.each do |table|
# Only delete tables in our namespace
if table =~ /^#{Dynamoid::Config.namespace}/
Dynamoid.adapter.delete_table(table)
end
end
Dynamoid.adapter.tables.clear
# Recreate all tables to avoid unexpected errors
Dynamoid.included_models.each(&:create_table)
end
end
# Reduce noise in test output
Dynamoid.logger.level = Logger::FATAL
If you're using RSpec you can invoke the above like so:
RSpec.configure do |config|
config.before(:each) do
DynamoidReset.all
end
end
In Rails, you may also want to ensure you do not delete non-test data accidentally by adding the following to your test environment setup:
raise "Tests should be run in 'test' environment only" if Rails.env != 'test'
Dynamoid.configure do |config|
config.namespace = "#{Rails.application.railtie_name}_#{Rails.env}"
end
Dynamoid borrows code, structure, and even its name very liberally from the truly amazing Mongoid. Without Mongoid to crib from none of this would have been possible, and I hope they don't mind me reusing their very awesome ideas to make DynamoDB just as accessible to the Ruby world as MongoDB.
Also, without contributors the project wouldn't be nearly as awesome. So many thanks to:
- Logan Bowers
- Lane LaRue
- Craig Heneveld
- Anantha Kumaran
- Jason Dew
- Luis Arias
- Stefan Neculai
- Philip White *
- Peeyush Kumar
- Sumanth Ravipati
- Pascal Corpet
- Brian Glusman *
- Peter Boling *
* Current Maintainers
Running the tests is fairly simple. You should have an instance of DynamoDB running locally. Follow these steps to setup your test environment.
-
First download and unpack the latest version of DynamoDB. We have a script that will do this for you if you use homebrew on a Mac.
bin/setup
-
Start the local instance of DynamoDB to listen in 8000 port
bin/start_dynamodblocal
-
and lastly, use
rake
to run the tests.rake
-
When you are done, remember to stop the local test instance of dynamodb
bin/stop_dynamodblocal
If you want to run all the specs that travis runs, use bundle exec wwtd
, but first you will need to setup all the rubies, for each of %w( 2.0.0-p648 2.1.10 2.2.6 2.3.3 2.4.1 jruby-9.1.8.0 )
. When you run bundle exec wwtd
it will take care of starting and stopping the local dynamodb instance.
rvm use 2.0.0-p648
gem install rubygems-update
gem install bundler
bundle install
Copyright (c) 2012 Josh Symonds.
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.