Parametric

Declaratively define data schemas in your Ruby objects, and use them to whitelist, validate or transform inputs to your programs.

Useful for building self-documeting APIs, search or form objects. Or possibly as an alternative to Rails' strong parameters (it has no dependencies on Rails and can be used stand-alone).

Schema

Define a schema

schema = Parametric::Schema.new do
  field(:title).type(:string).present
  field(:status).options(["draft", "published"]).default("draft")
  field(:tags).type(:array)
end

Populate and use. Missing keys return defaults, if provided.

form = schema.resolve(title: "A new blog post", tags: ["tech"])

form.output # => {title: "A new blog post", tags: ["tech"], status: "draft"}
form.errors # => {}

Undeclared keys are ignored.

form = schema.resolve(foobar: "BARFOO", title: "A new blog post", tags: ["tech"])

form.output # => {title: "A new blog post", tags: ["tech"], status: "draft"}

Validations are run and errors returned

form = schema.resolve({})
form.errors # => {"$.title" => ["is required"]}

If options are defined, it validates that value is in options

form = schema.resolve({title: "A new blog post", status: "foobar"})
form.errors # => {"$.status" => ["expected one of draft, published but got foobar"]}

Nested schemas

A schema can have nested schemas, for example for defining complex forms.

person_schema = Parametric::Schema.new do
  field(:name).type(:string).required
  field(:age).type(:integer)
  field(:friends).type(:array).schema do
    field(:name).type(:string).required
    field(:email).policy(:email)
  end
end

It works as expected

results = person_schema.resolve(
  name: "Joe",
  age: "38",
  friends: [
    {name: "Jane", email: "jane@email.com"}
  ]
)

results.output # => {name: "Joe", age: 38, friends: [{name: "Jane", email: "jane@email.com"}]}

Validation errors use JSON path expressions to describe errors in nested structures

results = person_schema.resolve(
  name: "Joe",
  age: "38",
  friends: [
    {email: "jane@email.com"}
  ]
)

results.errors # => {"$.friends[0].name" => "is required"}

Reusing nested schemas

You can optionally use an existing schema instance as a nested schema:

FRIENDS_SCHEMA = Parametric::Schema.new do
  field(:friends).type(:array).schema do
    field(:name).type(:string).required
    field(:email).policy(:email)
  end
end

person_schema = Parametric::Schema.new do
  field(:name).type(:string).required
  field(:age).type(:integer)
  # Nest friends_schema
  field(:friends).type(:array).schema(FRIENDS_SCHEMA)
end

Note that person_schema's definition has access to FRIENDS_SCHEMA because it's a constant. Definition blocks are run in the context of the defining schema instance by default.

To preserve the original block's context, declare two arguments in your block, the defining schema sc and options has.

person_schema = Parametric::Schema.new do |sc, options|
  # this block now preserves its context. Call `sc.field` to add fields to the current schema.
  sc.field(:name).type(:string).required
  sc.field(:age).type(:integer)
  # We now have access to local variables
  sc.field(:friends).type(:array).schema(friends_schema)
end

Tagged One Of (multiple nested schemas, discriminated by payload key).

You can use Field#tagged_one_of to resolve a nested schema based on the value of a top-level field.

user_schema = Parametric::Schema.new do |sc, _|
  field(:name).type(:string).present
  field(:age).type(:integer).present
end

company_schema = Parametric::Schema.new do
  field(:name).type(:string).present
  field(:company_code).type(:string).present
end

schema = Parametric::Schema.new do |sc, _|
  # Use :type field to locate the sub-schema to use for :sub
  sc.field(:type).type(:string)

  # Use the :one_of policy to select the sub-schema based on the :type field above
  sc.field(:sub).type(:object).tagged_one_of do |sub|
    sub.index_by(:type)
    sub.on('user', user_schema)
    sub.on('company', company_schema)
  end
end

# The schema will now select the correct sub-schema based on the value of :type
result = schema.resolve(type: 'user', sub: { name: 'Joe', age: 30 })

# Instances can also be created separately and used as a policy:

UserOrCompany = Parametric::TaggedOneOf.new do |sc, _|
  sc.on('user', user_schema)
  sc.on('company', company_schema)
end

schema = Parametric::Schema.new do |sc, _|
  sc.field(:type).type(:string)
  sc.field(:sub).type(:object).policy(UserOrCompany.index_by(:type))
end

#index_by can take a block to decide what value to resolve schemas by:

sc.field(:sub).type(:object).tagged_one_of do |sub|
  sub.index_by { |payload| payload[:entity_type] }
  sub.on('user', user_schema)
  sub.on('company', company_schema)
end

Built-in policies

Type coercions (the type method) and validations (the validate method) are all policies.

Parametric ships with a number of built-in policies.

:string

Calls :to_s on the value

field(:title).type(:string)

:integer

Calls :to_i on the value

field(:age).type(:integer)

:number

Calls :to_f on the value

field(:price).type(:number)

:boolean

Returns true or false (nil is converted to false).

field(:published).type(:boolean)

:datetime

Attempts parsing value with Datetime.parse. If invalid, the error will be added to the output's errors object.

field(:expires_on).type(:datetime)

:format

Check value against custom regexp

field(:salutation).policy(:format, /^Mr\/s/)
# optional custom error message
field(:salutation).policy(:format, /^Mr\/s\./, "must start with Mr/s.")

:email

field(:business_email).policy(:email)

:required

Check that the key exists in the input.

field(:name).required

# same as
field(:name).policy(:required)

Note that required does not validate that the value is not empty. Use present for that.

:present

Check that the key exists and the value is not blank.

field(:name).present

# same as
field(:name).policy(:present)

If the value is a String, it validates that it's not blank. If an Array, it checks that it's not empty. Otherwise it checks that the value is not nil.

:declared

Check that a key exists in the input, or stop any further validations otherwise. This is useful when chained to other validations. For example:

field(:name).declared.present

The example above will check that the value is not empty, but only if the key exists. If the key doesn't exist no validations will run. Note that any defaults will still be returned.

field(:name).declared.present.default('return this')

:declared_no_default

Like :declared, it stops the policy chain if a key is not in input, but it also skips any default value.

field(:name).policy(:declared_no_default).present

:nullable

Check that key is present in input. If value is nil, processing and validations stop, but key is still included in output.

schema = Parametric::Schema.new do
  field(:age).nullable.type(:integer).policy(:gt: 21)
end

schema.resolve(age: '22').output[:age] # 22
schema.resolve(age: 10).errors[:age] # has error because < 21
schema.resolve(age: nil).output[:age] # nil, no errors
schema.resolve({}).output[:age] # nil, no errors

:gt

Validate that the value is greater than a number

field(:age).policy(:gt, 21)

:lt

Validate that the value is less than a number

field(:age).policy(:lt, 21)

:options

Pass allowed values for a field

field(:status).options(["draft", "published"])

# Same as
field(:status).policy(:options, ["draft", "published"])

:split

Split comma-separated string values into an array. Useful for parsing comma-separated query-string parameters.

field(:status).policy(:split) # turns "pending,confirmed" into ["pending", "confirmed"]

:value

A policy to return a static value

field(:currency).policy(:value, 'gbp') # this field always resolves to 'gbp'

Custom policies

You can also register your own custom policy objects. A policy consist of the following:

• A PolicyFactory interface:

class MyPolicy
  # Initializer signature is up to you.
  # These are the arguments passed to the policy when using in a Field,
  # ex. field(:name).policy(:my_policy, 'arg1', 'arg2')
  def initialize(arg1, arg2)
    @arg1, @arg2 = arg1, arg2
  end

  # @return [Hash]
  def meta_data
   { type: :string }
  end

  # Buld a Policy Runner, which is instantiated
  # for each field when resolving a schema
  # @param key [Symbol]
  # @param value [Any]
  # @option payload [Hash]
  # @option context [Parametric::Context]
  # @return [PolicyRunner]
  def build(key, value, payload:, context:)
    MyPolicyRunner.new(key, value, payload, context)
  end
end

• A PolicyRunner interface.

class MyPolicyRunner
  # Initializer is up to you. See `MyPolicy#build`
  def initialize(key, value, payload, context)

  end

  # Should this policy run at all?
  # returning [false] halts the field policy chain.
  # @return [Boolean]
  def eligible?
    true
  end

  # If this policy is not eligible, should the key and value be included in the output?
  # @return [Boolean]
  def include_non_eligible_in_ouput?
    true
  end

  # If [false], add [#message] to result errors and halt processing field.
  # @return [Boolean]
  def valid?
    true
  end

  # Coerce the value, or return as-is.
  # @return [Any]
  def value
    @value
  end

  # Error message for this policy
  # @return [String]
  def message
    "#{@value} is invalid"
  end
end

Then register your custom policy factory:

Parametric.policy :my_polict, MyPolicy

And then refer to it by name when declaring your schema fields

field(:title).policy(:my_policy, 'arg1', 'arg2')

You can chain custom policies with other policies.

field(:title).required.policy(:my_policy, 'arg1', 'arg2')

Note that you can also register instances.

Parametric.policy :my_policy, MyPolicy.new('arg1', 'arg2')

For example, a policy that can be configured on a field-by-field basis:

class AddJobTitle
  def initialize(job_title)
    @job_title = job_title
  end

  def build(key, value, payload:, context:)
    Runner.new(@job_title, key, value, payload, context)
  end

  def meta_data
    {}
  end

  class Runner
    attr_reader :message

    def initialize(job_title, key, value, payload, _context)
      @job_title = job_title
      @key, @value, @payload = key, value, payload
      @message = 'is invalid'
    end

    def eligible?
      true
    end

    def valid?
      true
    end

    def value
      "#{@value}, #{@job_title}"
    end
  end
end

# Register it
Parametric.policy :job_title, AddJobTitle

Now you can reuse the same policy with different configuration

manager_schema = Parametric::Schema.new do
  field(:name).type(:string).policy(:job_title, "manager")
end

cto_schema = Parametric::Schema.new do
  field(:name).type(:string).policy(:job_title, "CTO")
end

manager_schema.resolve(name: "Joe Bloggs").output # => {name: "Joe Bloggs, manager"}
cto_schema.resolve(name: "Joe Bloggs").output # => {name: "Joe Bloggs, CTO"}

Custom policies, short version

For simple policies that don't need all policy methods, you can:

Parametric.policy :cto_job_title do
  coerce do |value, key, context|
    "#{value}, CTO"
  end
end

# use it
cto_schema = Parametric::Schema.new do
  field(:name).type(:string).policy(:cto_job_title)
end

Parametric.policy :over_21_and_under_25 do
  coerce do |age, key, context|
    age.to_i
  end

  validate do |age, key, context|
    age > 21 && age < 25
  end
end

Cloning schemas

The #clone method returns a new instance of a schema with all field definitions copied over.

new_schema = original_schema.clone

New copies can be further manipulated without affecting the original.

# See below for #policy and #ignore
new_schema = original_schema.clone.policy(:declared).ignore(:id) do |sc|
  field(:another_field).present
end

Merging schemas

The #merge method will merge field definitions in two schemas and produce a new schema instance.

basic_user_schema = Parametric::Schema.new do
  field(:name).type(:string).required
  field(:age).type(:integer)
end

friends_schema = Parametric::Schema.new do
  field(:friends).type(:array).schema do
    field(:name).required
    field(:email).policy(:email)
  end
end

user_with_friends_schema = basic_user_schema.merge(friends_schema)

results = user_with_friends_schema.resolve(input)

Fields defined in the merged schema will override fields with the same name in the original schema.

required_name_schema = Parametric::Schema.new do
  field(:name).required
  field(:age)
end

optional_name_schema = Parametric::Schema.new do
  field(:name)
end

# This schema now has :name and :age fields.
# :name has been redefined to not be required.
new_schema = required_name_schema.merge(optional_name_schema)

#meta

The #meta field method can be used to add custom meta data to field definitions. These meta data can be used later when instrospecting schemas (ie. to generate documentation or error notices).

create_user_schema = Parametric::Schema.do
  field(:name).required.type(:string).meta(label: "User's full name")
  field(:status).options(["published", "unpublished"]).default("published")
  field(:age).type(:integer).meta(label: "User's age")
  field(:friends).type(:array).meta(label: "User friends").schema do
    field(:name).type(:string).present.meta(label: "Friend full name")
    field(:email).policy(:email).meta(label: "Friend's email")
  end
end

#structure

A Schema instance has a #structure method that allows instrospecting schema meta data.

create_user_schema.structure[:name][:label] # => "User's full name"
create_user_schema.structure[:age][:label] # => "User's age"
create_user_schema.structure[:friends][:label] # => "User friends"
# Recursive schema structures
create_user_schema.structure[:friends].structure[:name].label # => "Friend full name"

Note that many field policies add field meta data.

create_user_schema.structure[:name][:type] # => :string
create_user_schema.structure[:name][:required] # => true
create_user_schema.structure[:status][:options] # => ["published", "unpublished"]
create_user_schema.structure[:status][:default] # => "published"

#walk

The #walk method can recursively walk a schema definition and extract meta data or field attributes.

schema_documentation = create_user_schema.walk do |field|
  {type: field.meta_data[:type], label: field.meta_data[:label]}
end.output

# Returns

{
  name: {type: :string, label: "User's full name"},
  age: {type: :integer, label: "User's age"},
  status: {type: :string, label: nil},
  friends: [
    {
      name: {type: :string, label: "Friend full name"},
      email: {type: nil, label: "Friend email"}
    }
  ]
}

When passed a symbol, it will collect that key from field meta data.

schema_labels = create_user_schema.walk(:label).output

# returns

{
  name: "User's full name",
  age: "User's age",
  status: nil,
  friends: [
    {name: "Friend full name", email: "Friend email"}
  ]
}

Potential uses for this are generating documentation (HTML, or JSON Schema, Swagger, or maybe even mock API endpoints with example data.

Form objects DSL

You can use schemas and fields on their own, or include the DSL module in your own classes to define form objects.

require "parametric/dsl"

class CreateUserForm
  include Parametric::DSL

  schema do
    field(:name).type(:string).required
    field(:email).policy(:email).required
    field(:age).type(:integer)
  end

  attr_reader :params, :errors

  def initialize(input_data)
    results = self.class.schema.resolve(input_data)
    @params = results.output
    @errors = results.errors
  end

  def run!
    if !valid?
      raise InvalidFormError.new(errors)
    end

    run
  end

  def valid?
    !errors.any?
  end

  private

  def run
    User.create!(params)
  end
end

Form schemas can also be defined by passing another form or schema instance. This can be useful when building form classes in runtime.

UserSchema = Parametric::Schema.new do
  field(:name).type(:string).present
  field(:age).type(:integer)
end

class CreateUserForm
  include Parametric::DSL
  # copy from UserSchema
  schema UserSchema
end

Form object inheritance

Sub classes of classes using the DSL will inherit schemas defined on the parent class.

class UpdateUserForm < CreateUserForm
  # All field definitions in the parent are conserved.
  # New fields can be defined
  # or existing fields overriden
  schema do
    # make this field optional
    field(:name).declared.present
  end

  def initialize(user, input_data)
    super input_data
    @user = user
  end

  private
  def run
    @user.update params
  end
end

Schema-wide policies

Sometimes it's useful to apply the same policy to all fields in a schema.

For example, fields that are required when creating a record might be optional when updating the same record (ie. PATCH operations in APIs).

class UpdateUserForm < CreateUserForm
  schema.policy(:declared)
end

This will prefix the :declared policy to all fields inherited from the parent class. This means that only fields whose keys are present in the input will be validated.

Schemas with default policies can still define or re-define fields.

class UpdateUserForm < CreateUserForm
  schema.policy(:declared) do
    # Validation will only run if key exists
    field(:age).type(:integer).present
  end
end

Ignoring fields defined in the parent class

Sometimes you'll want a child class to inherit most fields from the parent, but ignoring some.

class CreateUserForm
  include Parametric::DSL

  schema do
    field(:uuid).present
    field(:status).required.options(["inactive", "active"])
    field(:name)
  end
end

The child class can use ignore(*fields) to ignore fields defined in the parent.

class UpdateUserForm < CreateUserForm
  schema.ignore(:uuid, :status) do
    # optionally add new fields here
  end
end

Schema options

Another way of modifying inherited schemas is by passing options.

class CreateUserForm
  include Parametric::DSL

  schema(default_policy: :noop) do |opts|
    field(:name).policy(opts[:default_policy]).type(:string).required
    field(:email).policy(opts[:default_policy).policy(:email).required
    field(:age).type(:integer)
  end

  # etc
end

The :noop policy does nothing. The sub-class can pass its own default_policy.

class UpdateUserForm < CreateUserForm
  # this will only run validations keys existing in the input
  schema(default_policy: :declared)
end

A pattern: changing schema policy on the fly.

You can use a combination of #clone and #policy to change schema-wide field policies on the fly.

For example, you might have a form object that supports creating a new user and defining mandatory fields.

class CreateUserForm
  include Parametric::DSL

  schema do
    field(:name).present
    field(:age).present
  end

  attr_reader :errors, :params

  def initialize(payload: {})
    results = self.class.schema.resolve(payload)
    @errors = results.errors
    @params = results.output
  end

  def run!
    User.create(params)
  end
end

Now you might want to use the same form object to update and existing user supporting partial updates. In this case, however, attributes should only be validated if the attributes exist in the payload. We need to apply the :declared policy to all schema fields, only if a user exists.

We can do this by producing a clone of the class-level schema and applying any necessary policies on the fly.

class CreateUserForm
  include Parametric::DSL

  schema do
    field(:name).present
    field(:age).present
  end

  attr_reader :errors, :params

  def initialize(payload: {}, user: nil)
    @payload = payload
    @user = user

    # pick a policy based on user
    policy = user ? :declared : :noop
    # clone original schema and apply policy
    schema = self.class.schema.clone.policy(policy)

    # resolve params
    results = schema.resolve(params)
    @errors = results.errors
    @params = results.output
  end

  def run!
    if @user
      @user.update_attributes(params)
    else
      User.create(params)
    end
  end
end

Multiple schema definitions

Form objects can optionally define more than one schema by giving them names:

class UpdateUserForm
  include Parametric::DSL

  # a schema named :query
  # for example for query parameters
  schema(:query) do
    field(:user_id).type(:integer).present
  end

  # a schema for PUT body parameters
  schema(:payload) do
    field(:name).present
    field(:age).present
  end
end

Named schemas are inherited and can be extended and given options in the same way as the nameless version.

Named schemas can be retrieved by name, ie. UpdateUserForm.schema(:query).

If no name given, .schema uses :schema as default schema name.

Expanding fields dynamically

Sometimes you don't know the exact field names but you want to allow arbitrary fields depending on a given pattern.

# with this payload:
# {
#   title: "A title",
#   :"custom_attr_Color" => "red",
#   :"custom_attr_Material" => "leather"
# }

schema = Parametric::Schema.new do
  field(:title).type(:string).present
  # here we allow any field starting with /^custom_attr/
  # this yields a MatchData object to the block
  # where you can define a Field and validations on the fly
  # https://ruby-doc.org/core-2.2.0/MatchData.html
  expand(/^custom_attr_(.+)/) do |match|
    field(match[1]).type(:string).present
  end
end

results = schema.resolve({
  title: "A title",
  :"custom_attr_Color" => "red",
  :"custom_attr_Material" => "leather",
  :"custom_attr_Weight" => "",
})

results.ouput[:Color] # => "red"
results.ouput[:Material] # => "leather"
results.errors["$.Weight"] # => ["is required and value must be present"]

NOTES: dynamically expanded field names are not included in Schema#structure metadata, and they are only processes if fields with the given expressions are present in the payload. This means that validations applied to those fields only run if keys are present in the first place.

Before and after resolve hooks

Schema#before_resolve can be used to register blocks to modify the entire input payload before individual fields are validated and coerced. This can be useful when you need to pre-populate fields relative to other fields' values, or fetch extra data from other sources.

# This example computes the value of the :slug field based on :name
schema = Parametric::Schema.new do
  # Note1: These blocks run before field validations, so :name might be blank or invalid at this point.
  # Note2: Before hooks _must_ return a payload hash.
  before_resolve do |payload, context|
    payload.merge(
      slug: payload[:name].to_s.downcase.gsub(/\s+/, '-')
    )
  end

  # You still need to define the fields you want
  field(:name).type(:string).present
  field(:slug).type(:string).present
end

result = schema.resolve( name: 'Joe Bloggs' )
result.output # => { name: 'Joe Bloggs', slug: 'joe-bloggs' }

Before hooks can be added to nested schemas, too:

schema = Parametric::Schema.new do
  field(:friends).type(:array).schema do
    before_resolve do |friend_payload, context|
      friend_payload.merge(title: "Mr/Ms #{friend_payload[:name]}")
    end

    field(:name).type(:string)
    field(:title).type(:string)
  end
end

You can use inline blocks, but anything that responds to #call(payload, context) will work, too:

class SlugMaker
  def initialize(slug_field, from:)
    @slug_field, @from = slug_field, from
  end

  def call(payload, context)
    payload.merge(
      @slug_field => payload[@from].to_s.downcase.gsub(/\s+/, '-')
    )
  end
end

schema = Parametric::Schema.new do
  before_resolve SlugMaker.new(:slug, from: :name)

  field(:name).type(:string)
  field(:slug).type(:slug)
end

The context argument can be used to add custom validation errors in a before hook block.

schema = Parametric::Schema.new do
  before_resolve do |payload, context|
    # validate that there's no duplicate friend names
    friends = payload[:friends] || []
    if friends.any? && friends.map{ |fr| fr[:name] }.uniq.size < friends.size
      context.add_error 'friend names must be unique'
    end

    # don't forget to return the payload
    payload
  end

  field(:friends).type(:array).schema do
    field(:name).type(:string)
  end
end

result = schema.resolve(
  friends: [
    {name: 'Joe Bloggs'},
    {name: 'Joan Bloggs'},
    {name: 'Joe Bloggs'}
  ]
)

result.valid? # => false
result.errors # => {'$' => ['friend names must be unique']}

In most cases you should be validating individual fields using field policies. Only validate in before hooks in cases you have dependencies between fields.

Schema#after_resolve takes the sanitized input hash, and can be used to further validate fields that depend on eachother.

schema = Parametric::Schema.new do
  after_resolve do |payload, ctx|
    # Add a top level error using an arbitrary key name
    ctx.add_base_error('deposit', 'cannot be greater than house price') if payload[:deposit] > payload[:house_price]
    # Or add an error keyed after the current position in the schema
    # ctx.add_error('some error') if some_condition
    # after_resolve hooks must also return the payload, or a modified copy of it
    # note that any changes added here won't be validated.
    payload.merge(desc: 'hello')
  end

  field(:deposit).policy(:integer).present
  field(:house_price).policy(:integer).present
  field(:desc).policy(:string)
end

result = schema.resolve({ deposit: 1100, house_price: 1000 })
result.valid? # false
result.errors[:deposit] # ['cannot be greater than house price']
result.output[:deposit] # 1100
result.output[:house_price] # 1000
result.output[:desc] # 'hello'

Structs

Structs turn schema definitions into objects graphs with attribute readers.

Add optional Parametrict::Struct module to define struct-like objects with schema definitions.

require 'parametric/struct'

class User
  include Parametric::Struct

  schema do
    field(:name).type(:string).present
    field(:friends).type(:array).schema do
      field(:name).type(:string).present
      field(:age).type(:integer)
    end
  end
end

User objects can be instantiated with hash data, which will be coerced and validated as per the schema definition.

user = User.new(
  name: 'Joe',
  friends: [
    {name: 'Jane', age: 40},
    {name: 'John', age: 30},
  ]
)

# properties
user.name # => 'Joe'
user.friends.first.name # => 'Jane'
user.friends.last.age # => 30

Errors

Both the top-level and nested instances contain error information:

user = User.new(
  name: '', # invalid
  friends: [
    # friend name also invalid
    {name: '', age: 40},
  ]
)

user.valid? # false
user.errors['$.name'] # => "is required and must be present"
user.errors['$.friends[0].name'] # => "is required and must be present"

# also access error in nested instances directly
user.friends.first.valid? # false
user.friends.first.errors['$.name'] # "is required and must be valid"

.new!(hash)

Instantiating structs with .new!(hash) will raise a Parametric::InvalidStructError exception if the data is validations fail. It will return the struct instance otherwise.

Parametric::InvalidStructError includes an #errors property to inspect the errors raised.

begin
  user = User.new!(name: '')
rescue Parametric::InvalidStructError => e
  e.errors['$.name'] # "is required and must be present"
end

Nested structs

You can also pass separate struct classes in a nested schema definition.

class Friend
  include Parametric::Struct

  schema do
    field(:name).type(:string).present
    field(:age).type(:integer)
  end
end

class User
  include Parametric::Struct

  schema do
    field(:name).type(:string).present
    # here we use the Friend class
    field(:friends).type(:array).schema Friend
  end
end

Inheritance

Struct subclasses can add to inherited schemas, or override fields defined in the parent.

class AdminUser < User
  # inherits User schema, and can add stuff to its own schema
  schema do
    field(:permissions).type(:array)
  end
end

#to_h

Struct#to_h returns the ouput hash, with values coerced and any defaults populated.

class User
  include Parametrict::Struct
  schema do
    field(:name).type(:string)
    field(:age).type(:integer).default(30)
  end
end

user = User.new(name: "Joe")
user.to_h # {name: "Joe", age: 30}

Struct equality

Parametric::Struct implements #==() to compare two structs Hash representation (same as struct1.to_h.eql?(struct2.to_h).

Users can override #==() in their own classes to do whatever they need.

Installation

Add this line to your application's Gemfile:

gem 'parametric'

And then execute:

$ bundle

Or install it yourself as:

$ gem install parametric

Contributing

1. Fork it ( http://github.com/ismasan/parametric/fork )
2. Create your feature branch (git checkout -b my-new-feature)
3. Commit your changes (git commit -am 'Add some feature')
4. Push to the branch (git push origin my-new-feature)
5. Create new Pull Request