Hashie is a growing collection of tools that extend Hashes and make them more useful.
- Installation
- Stable Release
- Hash Extensions
- Logging
- StrictKeyAccess
- Mash
- Dash
- Trash
- Clash
- Rash
- Mascot
- Contributing
- Copyright
Hashie is available as a RubyGem:
$ gem install hashie
You're reading the documentation for the next release of Hashie, which should be 5.0.1. The current stable release is 5.0.0.
The library is broken up into a number of atomically includable Hash extension modules as described below. This provides maximum flexibility for users to mix and match functionality while maintaining feature parity with earlier versions of Hashie.
Any of the extensions listed below can be mixed into a class by include
-ing Hashie::Extensions::ExtensionName
.
Hashie has a built-in logger that you can override. By default, it logs to STDOUT
but can be replaced by any Logger
class. The logger is accessible on the Hashie module, as shown below:
# Set the logger to the Rails logger
Hashie.logger = Rails.logger
Coercions allow you to set up "coercion rules" based either on the key or the value type to massage data as it's being inserted into the Hash. Key coercions might be used, for example, in lightweight data modeling applications such as an API client:
class Tweet < Hash
include Hashie::Extensions::Coercion
include Hashie::Extensions::MergeInitializer
coerce_key :user, User
end
user_hash = { name: "Bob" }
Tweet.new(user: user_hash)
# => automatically calls User.coerce(user_hash) or
# User.new(user_hash) if that isn't present.
Value coercions, on the other hand, will coerce values based on the type of the value being inserted. This is useful if you are trying to build a Hash-like class that is self-propagating.
class SpecialHash < Hash
include Hashie::Extensions::Coercion
coerce_value Hash, SpecialHash
def initialize(hash = {})
super
hash.each_pair do |k,v|
self[k] = v
end
end
end
class Tweet < Hash
include Hashie::Extensions::Coercion
coerce_key :mentions, Array[User]
coerce_key :friends, Set[User]
end
user_hash = { name: "Bob" }
mentions_hash= [user_hash, user_hash]
friends_hash = [user_hash]
tweet = Tweet.new(mentions: mentions_hash, friends: friends_hash)
# => automatically calls User.coerce(user_hash) or
# User.new(user_hash) if that isn't present on each element of the array
tweet.mentions.map(&:class) # => [User, User]
tweet.friends.class # => Set
class Relation
def initialize(string)
@relation = string
end
end
class Tweet < Hash
include Hashie::Extensions::Coercion
coerce_key :relations, Hash[User => Relation]
end
user_hash = { name: "Bob" }
relations_hash= { user_hash => "father", user_hash => "friend" }
tweet = Tweet.new(relations: relations_hash)
tweet.relations.map { |k,v| [k.class, v.class] } # => [[User, Relation], [User, Relation]]
tweet.relations.class # => Hash
# => automatically calls User.coerce(user_hash) on each key
# and Relation.new on each value since Relation doesn't define the `coerce` class method
Hashie handles coercion to the following by using standard conversion methods:
type | method |
---|---|
Integer | #to_i |
Float | #to_f |
Complex | #to_c |
Rational | #to_r |
String | #to_s |
Symbol | #to_sym |
Note: The standard Ruby conversion methods are less strict than you may assume. For example, :foo.to_i
raises an error but "foo".to_i
returns 0.
You can also use coerce from the following supertypes with coerce_value
:
- Integer
- Numeric
Hashie does not have built-in support for coercing boolean values, since Ruby does not have a built-in boolean type or standard method for coercing to a boolean. You can coerce to booleans using a custom proc.
You can use a custom coercion proc on either #coerce_key
or #coerce_value
. This is useful for coercing to booleans or other simple types without creating a new class and coerce
method. For example:
class Tweet < Hash
include Hashie::Extensions::Coercion
coerce_key :retweeted, ->(v) do
case v
when String
!!(v =~ /\A(true|t|yes|y|1)\z/i)
when Numeric
!v.to_i.zero?
else
v == true
end
end
end
Since coerce_key
is a class-level method, you cannot have circular coercion without the use of a proc. For example:
class CategoryHash < Hash
include Hashie::Extensions::Coercion
include Hashie::Extensions::MergeInitializer
coerce_key :products, Array[ProductHash]
end
class ProductHash < Hash
include Hashie::Extensions::Coercion
include Hashie::Extensions::MergeInitializer
coerce_key :categories, Array[CategoriesHash]
end
This will fail with a NameError
for CategoryHash::ProductHash
because ProductHash
is not defined at the point that coerce_key
is happening for CategoryHash
.
To work around this, you can use a coercion proc. For example, you could do:
class CategoryHash < Hash
# ...
coerce_key :products, ->(value) do
return value.map { |v| ProductHash.new(v) } if value.respond_to?(:map)
ProductHash.new(value)
end
end
The KeyConversion extension gives you the convenience methods of symbolize_keys
and stringify_keys
along with their bang counterparts. You can also include just stringify or just symbolize with Hashie::Extensions::StringifyKeys
or Hashie::Extensions::SymbolizeKeys
.
Hashie also has a utility method for converting keys on a Hash without a mixin:
Hashie.symbolize_keys! hash # => Symbolizes all string keys of hash.
Hashie.symbolize_keys hash # => Returns a copy of hash with string keys symbolized.
Hashie.stringify_keys! hash # => Stringifies keys of hash.
Hashie.stringify_keys hash # => Returns a copy of hash with keys stringified.
The MergeInitializer extension simply makes it possible to initialize a Hash subclass with another Hash, giving you a quick short-hand.
The MethodAccess extension allows you to quickly build method-based reading, writing, and querying into your Hash descendant. It can also be included as individual modules, i.e. Hashie::Extensions::MethodReader
, Hashie::Extensions::MethodWriter
and Hashie::Extensions::MethodQuery
.
class MyHash < Hash
include Hashie::Extensions::MethodAccess
end
h = MyHash.new
h.abc = 'def'
h.abc # => 'def'
h.abc? # => true
The MethodAccessWithOverride extension is like the MethodAccess extension, except that it allows you to override Hash methods. It aliases any overridden method with two leading underscores. To include only this overriding functionality, you can include the single module Hashie::Extensions::MethodOverridingWriter
.
class MyHash < Hash
include Hashie::Extensions::MethodAccess
end
class MyOverridingHash < Hash
include Hashie::Extensions::MethodAccessWithOverride
end
non_overriding = MyHash.new
non_overriding.zip = 'a-dee-doo-dah'
non_overriding.zip #=> [[['zip', 'a-dee-doo-dah']]]
overriding = MyOverridingHash.new
overriding.zip = 'a-dee-doo-dah'
overriding.zip #=> 'a-dee-doo-dah'
overriding.__zip #=> [[['zip', 'a-dee-doo-dah']]]
The MethodOverridingInitializer extension will override hash methods if you pass in a normal hash to the constructor. It aliases any overridden method with two leading underscores. To include only this initializing functionality, you can include the single module Hashie::Extensions::MethodOverridingInitializer
.
class MyHash < Hash
end
class MyOverridingHash < Hash
include Hashie::Extensions::MethodOverridingInitializer
end
non_overriding = MyHash.new(zip: 'a-dee-doo-dah')
non_overriding.zip #=> []
overriding = MyOverridingHash.new(zip: 'a-dee-doo-dah')
overriding.zip #=> 'a-dee-doo-dah'
overriding.__zip #=> [[['zip', 'a-dee-doo-dah']]]
This extension can be mixed in to your Hash subclass to allow you to use Strings or Symbols interchangeably as keys; similar to the params
hash in Rails.
In addition, IndifferentAccess will also inject itself into sub-hashes so they behave the same.
class MyHash < Hash
include Hashie::Extensions::MergeInitializer
include Hashie::Extensions::IndifferentAccess
end
myhash = MyHash.new(:cat => 'meow', 'dog' => 'woof')
myhash['cat'] # => "meow"
myhash[:cat] # => "meow"
myhash[:dog] # => "woof"
myhash['dog'] # => "woof"
# Auto-Injecting into sub-hashes.
myhash['fishes'] = {}
myhash['fishes'].class # => Hash
myhash['fishes'][:food] = 'flakes'
myhash['fishes']['food'] # => "flakes"
To get back a normal, not-indifferent Hash, you can use #to_hash
on the indifferent hash. It exports the keys as strings, not symbols:
myhash = MyHash.new
myhash["foo"] = "bar"
myhash[:foo] #=> "bar"
normal_hash = myhash.to_hash
myhash["foo"] #=> "bar"
myhash[:foo] #=> nil
This extension can be mixed in to silently ignore undeclared properties on initialization instead of raising an error. This is useful when using a Trash to capture a subset of a larger hash.
class Person < Trash
include Hashie::Extensions::IgnoreUndeclared
property :first_name
property :last_name
end
user_data = {
first_name: 'Freddy',
last_name: 'Nostrils',
email: '[email protected]'
}
p = Person.new(user_data) # 'email' is silently ignored
p.first_name # => 'Freddy'
p.last_name # => 'Nostrils'
p.email # => NoMethodError
This extension allows you to easily include a recursive merging system into any Hash descendant:
class MyHash < Hash
include Hashie::Extensions::DeepMerge
end
h1 = MyHash[{ x: { y: [4,5,6] }, z: [7,8,9] }]
h2 = MyHash[{ x: { y: [7,8,9] }, z: "xyz" }]
h1.deep_merge(h2) # => { x: { y: [7, 8, 9] }, z: "xyz" }
h2.deep_merge(h1) # => { x: { y: [4, 5, 6] }, z: [7, 8, 9] }
Like with Hash#merge in the standard library, a block can be provided to merge values:
class MyHash < Hash
include Hashie::Extensions::DeepMerge
end
h1 = MyHash[{ a: 100, b: 200, c: { c1: 100 } }]
h2 = MyHash[{ b: 250, c: { c1: 200 } }]
h1.deep_merge(h2) { |key, this_val, other_val| this_val + other_val }
# => { a: 100, b: 450, c: { c1: 300 } }
This extension can be mixed in to provide for safe and concise retrieval of deeply nested hash values. In the event that the requested key does not exist a block can be provided and its value will be returned.
Though this is a hash extension, it conveniently allows for arrays to be present in the nested structure. This feature makes the extension particularly useful for working with JSON API responses.
user = {
name: { first: 'Bob', last: 'Boberts' },
groups: [
{ name: 'Rubyists' },
{ name: 'Open source enthusiasts' }
]
}
user.extend Hashie::Extensions::DeepFetch
user.deep_fetch :name, :first # => 'Bob'
user.deep_fetch :name, :middle # => 'KeyError: Could not fetch middle'
# using a default block
user.deep_fetch(:name, :middle) { |key| 'default' } # => 'default'
# a nested array
user.deep_fetch :groups, 1, :name # => 'Open source enthusiasts'
This extension can be mixed in to provide for concise searching for keys within a deeply nested hash.
It can also search through any Enumerable contained within the hash for objects with the specified key.
Note: The searches are depth-first, so it is not guaranteed that a shallowly nested value will be found before a deeply nested value.
user = {
name: { first: 'Bob', last: 'Boberts' },
groups: [
{ name: 'Rubyists' },
{ name: 'Open source enthusiasts' }
]
}
user.extend Hashie::Extensions::DeepFind
user.deep_find(:name) #=> { first: 'Bob', last: 'Boberts' }
user.deep_detect(:name) #=> { first: 'Bob', last: 'Boberts' }
user.deep_find_all(:name) #=> [{ first: 'Bob', last: 'Boberts' }, 'Rubyists', 'Open source enthusiasts']
user.deep_select(:name) #=> [{ first: 'Bob', last: 'Boberts' }, 'Rubyists', 'Open source enthusiasts']
This extension can be mixed in to provide a depth first search based search for enumerables matching a given comparator callable.
It returns all enumerables which contain at least one element, for which the given comparator returns true
.
Because the container objects are returned, the result elements can be modified in place. This way, one can perform modifications on deeply nested hashes without the need to know the exact paths.
books = [
{
title: "Ruby for beginners",
pages: 120
},
{
title: "CSS for intermediates",
pages: 80
},
{
title: "Collection of ruby books",
books: [
{
title: "Ruby for the rest of us",
pages: 576
}
]
}
]
books.extend(Hashie::Extensions::DeepLocate)
# for ruby 1.9 leave *no* space between the lambda rocket and the braces
# https://ruby-journal.com/becareful-with-space-in-lambda-hash-rocket-syntax-between-ruby-1-dot-9-and-2-dot-0/
books.deep_locate -> (key, value, object) { key == :title && value.include?("Ruby") }
# => [{:title=>"Ruby for beginners", :pages=>120}, {:title=>"Ruby for the rest of us", :pages=>576}]
books.deep_locate -> (key, value, object) { key == :pages && value <= 120 }
# => [{:title=>"Ruby for beginners", :pages=>120}, {:title=>"CSS for intermediates", :pages=>80}]
This extension can be mixed in to allow a Hash to raise an error when attempting to extract a value using a non-existent key.
class StrictKeyAccessHash < Hash
include Hashie::Extensions::StrictKeyAccess
end
>> hash = StrictKeyAccessHash[foo: "bar"]
=> {:foo=>"bar"}
>> hash[:foo]
=> "bar"
>> hash[:cow]
KeyError: key not found: :cow
Mash is an extended Hash that gives simple pseudo-object functionality that can be built from hashes and easily extended. It is intended to give the user easier access to the objects within the Mash through a property-like syntax, while still retaining all Hash functionality.
mash = Hashie::Mash.new
mash.name? # => false
mash.name # => nil
mash.name = "My Mash"
mash.name # => "My Mash"
mash.name? # => true
mash.inspect # => <Hashie::Mash name="My Mash">
mash = Hashie::Mash.new
# use bang methods for multi-level assignment
mash.author!.name = "Michael Bleigh"
mash.author # => <Hashie::Mash name="Michael Bleigh">
mash = Hashie::Mash.new
# use under-bang methods for multi-level testing
mash.author_.name? # => false
mash.inspect # => <Hashie::Mash>
Note: The ?
method will return false if a key has been set to false or nil. In order to check if a key has been set at all, use the mash.key?('some_key')
method instead.
How does Mash handle conflicts with pre-existing methods?
Please note that a Mash will not override methods through the use of the property-like syntax. This can lead to confusion if you expect to be able to access a Mash value through the property-like syntax for a key that conflicts with a method name. However, it protects users of your library from the unexpected behavior of those methods being overridden behind the scenes.
mash = Hashie::Mash.new
mash.name = "My Mash"
mash.zip = "Method Override?"
mash.zip # => [[["name", "My Mash"]], [["zip", "Method Override?"]]]
Since Mash gives you the ability to set arbitrary keys that then act as methods, Hashie logs when there is a conflict between a key and a pre-existing method. You can set the logger that this logs message to via the global Hashie logger:
Hashie.logger = Rails.logger
You can also disable the logging in subclasses of Mash:
class Response < Hashie::Mash
disable_warnings
end
The default is to disable logging for all methods that conflict. If you would like to only disable the logging for specific methods, you can include an array of method keys:
class Response < Hashie::Mash
disable_warnings :zip, :zap
end
This behavior is cumulative. The examples above and below behave identically.
class Response < Hashie::Mash
disable_warnings :zip
disable_warnings :zap
end
Disable warnings will honor the last disable_warnings
call. Calling without parameters will override the ignored methods list, and calling with parameters will create a new ignored methods list. This includes child classes that inherit from a class that disables warnings.
class Message < Hashie::Mash
disable_warnings :zip, :zap
disable_warnings
end
# No errors will be logged
Message.new(merge: 'true', compact: true)
class Message < Hashie::Mash
disable_warnings
end
class Response < Message
disable_warnings :zip, :zap
end
# 2 errors will be logged
Response.new(merge: 'true', compact: true, zip: '90210', zap: 'electric')
If you would like to create an anonymous subclass of a Hashie::Mash with key conflict warnings disabled:
Hashie::Mash.quiet.new(zip: '90210', compact: true) # no errors logged
Hashie::Mash.quiet(:zip).new(zip: '90210', compact: true) # error logged for compact
How does the wrapping of Mash sub-Hashes work?
Mash duplicates any sub-Hashes that you add to it and wraps them in a Mash. This allows for infinite chaining of nested Hashes within a Mash without modifying the object(s) that are passed into the Mash. When you subclass Mash, the subclass wraps any sub-Hashes in its own class. This preserves any extensions that you mixed into the Mash subclass and allows them to work within the sub-Hashes, in addition to the main containing Mash.
mash = Hashie::Mash.new(name: "Hashie", dependencies: { rake: "< 11", rspec: "~> 3.0" })
mash.dependencies.class #=> Hashie::Mash
class MyGem < Hashie::Mash; end
my_gem = MyGem.new(name: "Hashie", dependencies: { rake: "< 11", rspec: "~> 3.0" })
my_gem.dependencies.class #=> MyGem
How does Mash handle key types which cannot be symbolized?
Mash preserves keys which cannot be converted directly to both a string and a symbol, such as numeric keys. Since Mash is conceived to provide pseudo-object functionality, handling keys which cannot represent a method call falls outside its scope of value.
Hashie::Mash.new('1' => 'one string', :'1' => 'one sym', 1 => 'one num')
# => {"1"=>"one sym", 1=>"one num"}
The symbol key :'1'
is converted the string '1'
to support indifferent access and consequently its value 'one sym'
will override the previously set 'one string'
. However, the subsequent key of 1
cannot directly convert to a symbol and therefore not converted to the string '1'
that would otherwise override the previously set value of 'one sym'
.
What else can Mash do?
Mash allows you also to transform any files into a Mash objects.
#/etc/config/settings/twitter.yml
development:
api_key: 'api_key'
production:
api_key: <%= ENV['API_KEY'] %> #let's say that ENV['API_KEY'] is set to 'abcd'
mash = Mash.load('settings/twitter.yml')
mash.development.api_key # => 'localhost'
mash.development.api_key = "foo" # => <# RuntimeError can't modify frozen ...>
mash.development.api_key? # => true
You can also load with a Pathname
object:
mash = Mash.load(Pathname 'settings/twitter.yml')
mash.development.api_key # => 'localhost'
You can access a Mash from another class:
mash = Mash.load('settings/twitter.yml')[ENV['RACK_ENV']]
Twitter.extend mash.to_module # NOTE: if you want another name than settings, call: to_module('my_settings')
Twitter.settings.api_key # => 'abcd'
You can use another parser (by default: YamlErbParser):
#/etc/data/user.csv
id | name | lastname
---|------------- | -------------
1 |John | Doe
2 |Laurent | Garnier
mash = Mash.load('data/user.csv', parser: MyCustomCsvParser)
# => { 1 => { name: 'John', lastname: 'Doe'}, 2 => { name: 'Laurent', lastname: 'Garnier' } }
mash[1] #=> { name: 'John', lastname: 'Doe' }
The Mash#load
method calls YAML.safe_load(path, [], [], true)
.
Specify permitted_symbols
, permitted_classes
and aliases
options as needed.
Mash.load('data/user.csv', permitted_classes: [Symbol], permitted_symbols: [], aliases: false)
This extension can be mixed into a Mash to keep the form of any keys passed directly into the Mash. By default, Mash converts symbol keys to strings to give indifferent access. This extension still allows indifferent access, but keeps the form of the keys to eliminate confusion when you're not expecting the keys to change.
class KeepingMash < ::Hashie::Mash
include Hashie::Extensions::Mash::KeepOriginalKeys
end
mash = KeepingMash.new(:symbol_key => :symbol, 'string_key' => 'string')
mash.to_hash == { :symbol_key => :symbol, 'string_key' => 'string' } #=> true
mash.symbol_key #=> :symbol
mash[:symbol_key] #=> :symbol
mash['symbol_key'] #=> :symbol
mash.string_key #=> 'string'
mash['string_key'] #=> 'string'
mash[:string_key] #=> 'string'
By default, Mash only states that it responds to built-in methods, affixed methods (e.g. setters, underbangs, etc.), and keys that it currently contains. That means it won't state that it responds to a getter for an unset key, as in the following example:
mash = Hashie::Mash.new(a: 1)
mash.respond_to? :b #=> false
This means that by default Mash is not a perfect match for use with a SimpleDelegator since the delegator will not forward messages for unset keys to the Mash even though it can handle them.
In order to have a SimpleDelegator-compatible Mash, you can use the PermissiveRespondTo
extension to make Mash respond to anything.
class PermissiveMash < Hashie::Mash
include Hashie::Extensions::Mash::PermissiveRespondTo
end
mash = PermissiveMash.new(a: 1)
mash.respond_to? :b #=> true
This comes at the cost of approximately 20% performance for initialization and setters and 19KB of permanent memory growth for each such class that you create.
This extension can be mixed into a Mash to guard the attempted overwriting of methods by property setters. When mixed in, the Mash will raise an ArgumentError
if you attempt to write a property with the same name as an existing method.
class SafeMash < ::Hashie::Mash
include Hashie::Extensions::Mash::SafeAssignment
end
safe_mash = SafeMash.new
safe_mash.zip = 'Test' # => ArgumentError
safe_mash[:zip] = 'test' # => still ArgumentError
This extension can be mixed into a Mash to change the default behavior of converting keys to strings. After mixing this extension into a Mash, the Mash will convert all string keys to symbols. It can be useful to use with keywords argument, which required symbol keys.
class SymbolizedMash < ::Hashie::Mash
include Hashie::Extensions::Mash::SymbolizeKeys
end
symbol_mash = SymbolizedMash.new
symbol_mash['test'] = 'value'
symbol_mash.test #=> 'value'
symbol_mash.to_h #=> {test: 'value'}
def example(test:)
puts test
end
example(symbol_mash) #=> value
There is a major benefit and coupled with a major trade-off to this decision (at least on older Rubies). As a benefit, by using symbols as keys, you will be able to use the implicit conversion of a Mash via the #to_hash
method to destructure (or splat) the contents of a Mash out to a block. This can be handy for doing iterations through the Mash's keys and values, as follows:
symbol_mash = SymbolizedMash.new(id: 123, name: 'Rey')
symbol_mash.each do |key, value|
# key is :id, then :name
# value is 123, then 'Rey'
end
However, on Rubies less than 2.0, this means that every key you send to the Mash will generate a symbol. Since symbols are not garbage-collected on older versions of Ruby, this can cause a slow memory leak when using a symbolized Mash with data generated from user input.
This extension can be mixed into a Mash so it makes it behave like OpenStruct
. It reduces the overhead of method_missing?
magic by lazily defining field accessors when they're requested.
class MyHash < ::Hashie::Mash
include Hashie::Extensions::Mash::DefineAccessors
end
mash = MyHash.new
MyHash.method_defined?(:foo=) #=> false
mash.foo = 123
MyHash.method_defined?(:foo=) #=> true
MyHash.method_defined?(:foo) #=> false
mash.foo #=> 123
MyHash.method_defined?(:foo) #=> true
You can also extend the existing mash without defining a class:
mash = ::Hashie::Mash.new.with_accessors!
Dash is an extended Hash that has a discrete set of defined properties and only those properties may be set on the hash. Additionally, you can set defaults for each property. You can also flag a property as required. Required properties will raise an exception if unset. Another option is message for required properties, which allow you to add custom messages for required property. A property with a proc value will be evaluated lazily upon retrieval.
You can also conditionally require certain properties by passing a Proc or Symbol. If a Proc is provided, it will be run in the context of the Dash instance. If a Symbol is provided, the value returned for the property or method of the same name will be evaluated. The property will be required if the result of the conditional is truthy.
class Person < Hashie::Dash
property :name, required: true
property :age, required: true, message: 'must be set.'
property :email
property :phone, required: -> { email.nil? }, message: 'is required if email is not set.'
property :pants, required: :weekday?, message: 'are only required on weekdays.'
property :occupation, default: 'Rubyist'
property :genome
def weekday?
[ Time.now.saturday?, Time.now.sunday? ].none?
end
end
p = Person.new # => ArgumentError: The property 'name' is required for this Dash.
p = Person.new(name: 'Bob') # => ArgumentError: The property 'age' must be set.
p = Person.new(name: "Bob", age: 18)
p.name # => 'Bob'
p.name = nil # => ArgumentError: The property 'name' is required for this Dash.
p.age # => 18
p.age = nil # => ArgumentError: The property 'age' must be set.
p.email = '[email protected]'
p.occupation # => 'Rubyist'
p.email # => '[email protected]'
p[:awesome] # => NoMethodError
p[:occupation] # => 'Rubyist'
p.update_attributes!(name: 'Trudy', occupation: 'Evil')
p.occupation # => 'Evil'
p.name # => 'Trudy'
p.update_attributes!(occupation: nil)
p.occupation # => 'Rubyist'
p.genome = -> { Genome.sequence } # Some expensive operation
p.genome # => 'GATTACA'
Properties defined as symbols are not the same thing as properties defined as strings.
class Tricky < Hashie::Dash
property :trick
property 'trick'
end
p = Tricky.new(trick: 'one', 'trick' => 'two')
p.trick # => 'one', always symbol version
p[:trick] # => 'one'
p['trick'] # => 'two'
Note that accessing a property as a method always uses the symbol version.
class Tricky < Hashie::Dash
property 'trick'
end
p = Tricky.new('trick' => 'two')
p.trick # => NoMethodError
If you would like to update a Dash and use any default values set in the case of a nil
value, use #update_attributes!
.
class WithDefaults < Hashie::Dash
property :description, default: 'none'
end
dash = WithDefaults.new
dash.description #=> 'none'
dash.description = 'You committed one of the classic blunders!'
dash.description #=> 'You committed one of the classic blunders!'
dash.description = nil
dash.description #=> nil
dash.description = 'Only slightly less known is ...'
dash.update_attributes!(description: nil)
dash.description #=> 'none'
Because Dashes are subclasses of the built-in Ruby Hash class, the double-splat operator takes the Dash as-is without any conversion. This can lead to strange behavior when you use the double-splat operator on a Dash as the first part of a keyword list or built Hash. For example:
class Foo < Hashie::Dash
property :bar
end
foo = Foo.new(bar: 'baz') #=> {:bar=>"baz"}
qux = { **foo, quux: 'corge' } #=> {:bar=> "baz", :quux=>"corge"}
qux.is_a?(Foo) #=> true
qux[:quux]
#=> raise NoMethodError, "The property 'quux' is not defined for Foo."
qux.key?(:quux) #=> true
You can work around this problem in two ways:
- Call
#to_h
on the resulting object to convert it into a Hash. - Use the double-splat operator on the Dash as the last argument in the Hash literal. This will cause the resulting object to be a Hash instead of a Dash, thereby circumventing the problem.
qux = { **foo, quux: 'corge' }.to_h #=> {:bar=> "baz", :quux=>"corge"}
qux.is_a?(Hash) #=> true
qux[:quux] #=> "corge"
qux = { quux: 'corge', **foo } #=> {:quux=>"corge", :bar=> "baz"}
qux.is_a?(Hash) #=> true
qux[:quux] #=> "corge"
The Hashie::Extensions::Dash::PropertyTranslation
mixin extends a Dash with
the ability to remap keys from a source hash.
Property translation is useful when you need to read data from another application -- such as a Java API -- where the keys are named differently from Ruby conventions.
class PersonHash < Hashie::Dash
include Hashie::Extensions::Dash::PropertyTranslation
property :first_name, from: :firstName
property :last_name, from: :lastName
property :first_name, from: :f_name
property :last_name, from: :l_name
end
person = PersonHash.new(firstName: 'Michael', l_name: 'Bleigh')
person[:first_name] #=> 'Michael'
person[:last_name] #=> 'Bleigh
You can also use a lambda to translate the value. This is particularly useful when you want to ensure the type of data you're wrapping.
class DataModelHash < Hashie::Dash
include Hashie::Extensions::Dash::PropertyTranslation
property :id, transform_with: ->(value) { value.to_i }
property :created_at, from: :created, with: ->(value) { Time.parse(value) }
end
model = DataModelHash.new(id: '123', created: '2014-04-25 22:35:28')
model.id.class #=> Integer (Fixnum if you are using Ruby 2.3 or lower)
model.created_at.class #=> Time
To enable compatibility with Rails 4 use the hashie-forbidden_attributes gem.
If you want to use Hashie::Extensions::Coercion
together with Dash
then
you may probably want to use Hashie::Extensions::Dash::Coercion
instead.
This extension automatically includes Hashie::Extensions::Coercion
and also adds a convenient :coerce
option to property
so you can define coercion in one line
instead of using property
and coerce_key
separate:
class UserHash < Hashie::Dash
include Hashie::Extensions::Coercion
property :id
property :posts
coerce_key :posts, Array[PostHash]
end
This is the same as:
class UserHash < Hashie::Dash
include Hashie::Extensions::Dash::Coercion
property :id
property :posts, coerce: Array[PostHash]
end
The Hashie::Extensions::Dash::PredefinedValues
mixin extends a Dash with
the ability to accept predefined values on a property.
class UserHash < Hashie::Dash
include Hashie::Extensions::Dash::PredefinedValues
property :gender, values: %i[male female prefer_not_to_say]
property :age, values: (0..150)
end
A Trash is a Dash that allows you to translate keys on initialization. It mixes in the PropertyTranslation mixin by default and is used like so:
class Person < Hashie::Trash
property :first_name, from: :firstName
end
This will automatically translate the firstName key to first_name when it is initialized using a hash such as through:
Person.new(firstName: 'Bob')
Trash also supports translations using lambda, this could be useful when dealing with external API's. You can use it in this way:
class Result < Hashie::Trash
property :id, transform_with: lambda { |v| v.to_i }
property :created_at, from: :creation_date, with: lambda { |v| Time.parse(v) }
end
this will produce the following
result = Result.new(id: '123', creation_date: '2012-03-30 17:23:28')
result.id.class # => Integer (Fixnum if you are using Ruby 2.3 or lower)
result.created_at.class # => Time
Clash is a Chainable Lazy Hash that allows you to easily construct complex hashes using method notation chaining. This will allow you to use a more action-oriented approach to building options hashes.
Essentially, a Clash is a generalized way to provide much of the same kind of "chainability" that libraries like Arel or Rails 2.x's named_scopes provide.
c = Hashie::Clash.new
c.where(abc: 'def').order(:created_at)
c # => { where: { abc: 'def' }, order: :created_at }
# You can also use bang notation to chain into sub-hashes,
# jumping back up the chain with _end!
c = Hashie::Clash.new
c.where!.abc('def').ghi(123)._end!.order(:created_at)
c # => { where: { abc: 'def', ghi: 123 }, order: :created_at }
# Multiple hashes are merged automatically
c = Hashie::Clash.new
c.where(abc: 'def').where(hgi: 123)
c # => { where: { abc: 'def', hgi: 123 } }
Rash is a Hash whose keys can be Regexps or Ranges, which will map many input keys to a value.
A good use case for the Rash is an URL router for a web framework, where URLs need to be mapped to actions; the Rash's keys match URL patterns, while the values call the action which handles the URL.
If the Rash's value is a proc
, the proc
will be automatically called with the regexp's MatchData (matched groups) as a block argument.
# Mapping names to appropriate greetings
greeting = Hashie::Rash.new( /^Mr./ => "Hello sir!", /^Mrs./ => "Evening, madame." )
greeting["Mr. Steve Austin"] # => "Hello sir!"
greeting["Mrs. Steve Austin"] # => "Evening, madame."
# Mapping statements to saucy retorts
mapper = Hashie::Rash.new(
/I like (.+)/ => proc { |m| "Who DOESN'T like #{m[1]}?!" },
/Get off my (.+)!/ => proc { |m| "Forget your #{m[1]}, old man!" }
)
mapper["I like traffic lights"] # => "Who DOESN'T like traffic lights?!"
mapper["Get off my lawn!"] # => "Forget your lawn, old man!"
Note: The Rash is automatically optimized every 500 accesses (which means that it sorts the list of Regexps, putting the most frequently matched ones at the beginning).
If this value is too low or too high for your needs, you can tune it by setting: rash.optimize_every = n
.
Meet Hashie's "official" mascot, the eierlegende Wollmilchsau!
See CONTRIBUTING.md
Copyright (c) 2009-2020 Intridea, Inc., and contributors.
MIT License. See LICENSE for details.