Structured config

Structured configs are used to create OmegaConf configuration object with runtime type safety. In addition, they can be used with tools like mypy or your IDE for static type checking.

Two types of structures classes that are supported: dataclasses and attr classes.

  • dataclasses are standard as of Python 3.7 or newer and are available in Python 3.6 via the dataclasses pip package.
  • attrs Offset slightly cleaner syntax in some cases but depends on the attrs pip package.

This documentation will use dataclasses, but you can use the annotation @attr.s(auto_attribs=True) from attrs instead of @dataclass.

Basic usage involves passing in a structured config class or instance to OmegaConf.structured(), which will return an OmegaConf config that matches the values and types specified in the input. At runtine, OmegaConf will validate modifications to the created config object against the schema specified in the input class.

Simple types

Simple types include
  • int: numeric integers
  • float: numeric floating point values
  • bool: boolean values (True, False, On, Off etc)
  • str: Any string
  • Enums: User defined enums

The following class defines fields with all simple types:

>>> class Height(Enum):
...     SHORT = 0
...     TALL = 1

>>> @dataclass
... class SimpleTypes:
...     num: int = 10
...     pi: float = 3.1415
...     is_awesome: bool = True
...     height: Height = Height.SHORT
...     description: str = "text"

You can create a config based on the SimpleTypes class itself or an instance of it. Those would be equivalent by default, but the Object variant allows you to set the values of specific fields during construction.

>>> conf1 = OmegaConf.structured(SimpleTypes)
>>> conf2 = OmegaConf.structured(SimpleTypes())
>>> # The two configs are identical in this case
>>> assert conf1 == conf2
>>> # But the second form allow for easy customization of the values:
>>> conf3 = OmegaConf.structured(
...   SimpleTypes(num=20,
...   height=Height.TALL))
>>> print(OmegaConf.to_yaml(conf3))
num: 20
pi: 3.1415
is_awesome: true
height: TALL
description: text

The resulting object is a regular OmegaConf DictConfig, except that it will utilize the type information in the input class/object and will validate the data at runtime. The resulting object and will also rejects attempts to access or set fields that are not already defined (similarly to configs with their to Struct flag set, but not recursive).

>>> conf = OmegaConf.structured(SimpleTypes)
>>> with raises(AttributeError):
...    conf.does_not_exist

Static type checker support

Python type annotation can be used by static type checkers like Mypy/Pyre or by IDEs like PyCharm.

>>> conf: SimpleTypes = OmegaConf.structured(SimpleTypes)
>>> # Passes static type checking
>>> conf.description = "text"
>>> # Fails static type checking (but will also raise a Validation error)
>>> with raises(ValidationError):
...     conf.num = "foo"

This is duck-typing; the actual object type of conf is DictConfig. You can access the underlying type using OmegaConf.get_type():

>>> type(conf).__name__
'DictConfig'

>>> OmegaConf.get_type(conf).__name__
'SimpleTypes'

Runtime type validation and conversion

OmegaConf supports merging configs together, as well as overriding from the command line. This means some mistakes can not be identified by static type checkers, and runtime validation is required.

>>> # This is okay, the string "100" can be converted to an int
>>> # Note that static type checkers will not like it and you should
>>> # avoid such explicit mistyped assignments.
>>> conf.num = "100"
>>> assert conf.num == 100

>>> with raises(ValidationError):
...     # This will fail at runtime because num is an int
...     # and foo cannot be converted to an int
...     # Note that the static type checker can't help here.
...     conf.merge_with_dotlist(["num=foo"])

Runtime validation and conversion works for all supported types, including Enums:

>>> conf.height = Height.TALL
>>> assert conf.height == Height.TALL

>>> # The name of Height.TALL is TALL
>>> conf.height = "TALL"
>>> assert conf.height == Height.TALL

>>> # The ordinal of Height.TALL is 1
>>> conf.height = 1
>>> assert conf.height == Height.TALL

Nesting structured configs

Structured configs can be nested.

>>> @dataclass
... class User:
...     # A simple user class with two missing fields
...     name: str = MISSING
...     height: Height = MISSING
>>>
>>> @dataclass
... class DuperUser(User):
...     duper: bool = True
...
>>> # Group class contains two instances of User.
>>> @dataclass
... class Group:
...     name: str = MISSING
...     # data classes can be nested
...     admin: User = User()
...
...     # You can also specify different defaults for nested classes
...     manager: User = User(name="manager", height=Height.TALL)

>>> conf: Group = OmegaConf.structured(Group)
>>> print(OmegaConf.to_yaml(conf))
name: ???
admin:
  name: ???
  height: ???
manager:
  name: manager
  height: TALL

OmegaConf will validate that assignment of nested objects is of the correct type:

>>> with raises(ValidationError):
...     conf.manager = 10

You can assign subclasses:

>>> conf.manager = DuperUser()
>>> assert conf.manager.duper == True

Containers

Python container types are fully supported in Structured configs.

Lists

Structured Config fields annotated with typing.List or typing.Tuple can hold any type supported by OmegaConf (int, float. bool, str, Enum or Structured configs).

>>> from typing import List, Tuple
>>> @dataclass
... class User:
...     name: str = MISSING

>>> @dataclass
... class ListsExample:
...     # Typed list can hold Any, int, float, bool, str and Enums as well
...     # as arbitrary Structured configs
...     ints: List[int] = field(default_factory=lambda: [10, 20, 30])
...     bools: Tuple[bool, bool] = field(default_factory=lambda: (True, False))
...     users: List[User] = field(default_factory=lambda: [User(name="omry")])

OmegaConf verifies at runtime that your Lists contains only values of the correct type. In the example below, the OmegaConf object conf (which is actually an instance of DictConfig) is duck-typed as ListExample.

>>> conf: ListsExample = OmegaConf.structured(ListsExample)

>>> # Okay, 10 is an int
>>> conf.ints.append(10)
>>> # Okay, "20" can be converted to an int
>>> conf.ints.append("20")

>>> conf.bools.append(True)
>>> conf.users.append(User(name="Joe"))
>>> # Not okay, 10 cannot be converted to a User
>>> with raises(ValidationError):
...     conf.users.append(10)

Dictionaries

Dictionaries are supported via annotation of structured config fields with typing.Dict. Keys must be typed as one of str, int, Enum, float, or bool. Values can be any of the types supported by OmegaConf (Any, int, float, bool, str and Enum as well as arbitrary Structured configs)

>>> from typing import Dict
>>> @dataclass
... class DictExample:
...     # Typed dict keys are strings; values can be typed as Any, int, float, bool, str and Enums or
...     # arbitrary Structured configs
...     ints: Dict[str, int] = field(default_factory=lambda: {"a": 10, "b": 20, "c": 30})
...     bools: Dict[str, bool] = field(default_factory=lambda: {"Uno": True, "Zoro": False})
...     users: Dict[str, User] = field(default_factory=lambda: {"omry": User(name="omry")})

Like with Lists, the types of values contained in Dicts are verified at runtime.

>>> conf: DictExample = OmegaConf.structured(DictExample)

>>> # Okay, correct type is assigned
>>> conf.ints["d"] = 10
>>> conf.bools["Dos"] = True
>>> conf.users["James"] = User(name="Bond")

>>> # Not okay, 10 cannot be assigned to a User
>>> with raises(ValidationError):
...     conf.users["Joe"] = 10

Misc

OmegaConf supports field modifiers such as MISSING and Optional.

>>> from typing import Optional
>>> from omegaconf import MISSING

>>> @dataclass
... class Modifiers:
...     num: int = 10
...     optional_num: Optional[int] = 10
...     another_num: int = MISSING

>>> conf: Modifiers = OmegaConf.structured(Modifiers)

Mandatory missing values

Fields assigned the constant MISSING do not have a value and the value must be set prior to accessing the field. Otherwise a MissingMandatoryValue exception is raised.

>>> with raises(MissingMandatoryValue):
...     x = conf.another_num
>>> conf.another_num = 20
>>> assert conf.another_num == 20

Optional fields

>>> with raises(ValidationError):
...     # regular fields cannot be assigned None
...     conf.num = None

>>> conf.optional_num = None
>>> assert conf.optional_num is None

Interpolations

Variable interpolation works normally with Structured configs, but static type checkers may object to you assigning a string to another type. To work around this, use the special functions omegaconf.SI and omegaconf.II described below.

>>> from omegaconf import SI, II
>>> @dataclass
... class Interpolation:
...     val: int = 100
...     # This will work, but static type checkers will complain
...     a: int = "${val}"
...     # This is equivalent to the above, but static type checkers
...     # will not complain
...     b: int = SI("${val}")
...     # This is syntactic sugar; the input string is
...     # wrapped with ${} automatically.
...     c: int = II("val")

>>> conf: Interpolation = OmegaConf.structured(Interpolation)
>>> assert conf.a == 100
>>> assert conf.b == 100
>>> assert conf.c == 100

Interpolated values are validated, and converted when possible, to the annotated type when the interpolation is accessed, e.g:

>>> from omegaconf import II
>>> @dataclass
... class Interpolation:
...     str_key: str = "string"
...     int_key: int = II("str_key")

>>> cfg = OmegaConf.structured(Interpolation)
>>> cfg.int_key  # fails due to type mismatch
Traceback (most recent call last):
  ...
omegaconf.errors.InterpolationValidationError: Value 'string' could not be converted to Integer
    full_key: int_key
    object_type=Interpolation
>>> cfg.str_key = "1234"  # string value
>>> assert cfg.int_key == 1234  # automatically convert str to int

Note however that this validation step is currently skipped for container node interpolations:

>>> @dataclass
... class NotValidated:
...     some_int: int = 0
...     some_dict: Dict[str, str] = II("some_int")

>>> cfg = OmegaConf.structured(NotValidated)
>>> assert cfg.some_dict == 0  # type mismatch, but no error

Frozen

Frozen dataclasses and attr classes are supported via OmegaConf Read-only flag, which makes the entire config node and all if it’s child nodes read-only.

>>> @dataclass(frozen=True)
... class FrozenClass:
...     x: int = 10
...     list: List = field(default_factory=lambda: [1, 2, 3])

>>> conf = OmegaConf.structured(FrozenClass)
>>> with raises(ReadonlyConfigError):
...    conf.x = 20

The read-only flag is recursive:

>>> with raises(ReadonlyConfigError):
...    conf.list[0] = 20

Merging with other configs

Once an OmegaConf object is created, it can be merged with others regardless of its source. OmegaConf configs created from Structured configs contains type information that is enforced at runtime. This can be used to validate config files based on a schema specified in a structured config class

example.yaml file:

server:
  port: 80
log:
  file: ???
  rotation: 3600
users:
  - user1
  - user2

A Schema for the above config can be defined like this.

>>> @dataclass
... class Server:
...     port: int = MISSING

>>> @dataclass
... class Log:
...     file: str = MISSING
...     rotation: int = MISSING

>>> @dataclass
... class MyConfig:
...     server: Server = Server()
...     log: Log = Log()
...     users: List[int] = field(default_factory=list)

I intentionally made an error in the type of the users list (List[int] should be List[str]). This will cause a validation error when merging the config from the file with that from the scheme.

>>> schema = OmegaConf.structured(MyConfig)
>>> conf = OmegaConf.load("source/example.yaml")
>>> with raises(ValidationError):
...     OmegaConf.merge(schema, conf)