Ecto v2.0.5 Ecto.Type behaviour
Defines functions and the Ecto.Type
behaviour for implementing
custom types.
A custom type expects 4 functions to be implemented, all documented and described below. We also provide two examples of how custom types can be used in Ecto to augment existing types or providing your own types.
Augmenting types
Imagine you want to support your id field to be looked up as a permalink. For example, you want the following query to work:
permalink = "10-how-to-be-productive-with-elixir"
from p in Post, where: p.id == ^permalink
If id
is an integer field, Ecto will fail in the query above
because it cannot cast the string to an integer. By using a
custom type, we can provide special casting behaviour while
still keeping the underlying Ecto type the same:
defmodule Permalink do
@behaviour Ecto.Type
def type, do: :integer
# Provide our own casting rules.
def cast(string) when is_binary(string) do
case Integer.parse(string) do
{int, _} -> {:ok, int}
:error -> :error
end
end
# We should still accept integers
def cast(integer) when is_integer(integer), do: {:ok, integer}
# Everything else is a failure though
def cast(_), do: :error
# When loading data from the database, we are guaranteed to
# receive an integer (as databases are strict) and we will
# just return it to be stored in the schema struct.
def load(integer) when is_integer(integer), do: {:ok, integer}
# When dumping data to the database, we *expect* an integer
# but any value could be inserted into the struct, so we need
# guard against them.
def dump(integer) when is_integer(integer), do: {:ok, integer}
def dump(_), do: :error
end
Now we can use our new field above as our primary key type in schemas:
defmodule Post do
use Ecto.Schema
@primary_key {:id, Permalink, autogenerate: true}
schema "posts" do
...
end
end
New types
In the previous example, we say we were augmenting an existing type because we were keeping the underlying representation the same, the value stored in the struct and the database was always an integer.
Ecto types also allow developers to dump and load new types. In order for this to work, callbacks should take care of encoding your custom Ecto type into its DB representation, as well as decoding it from the DB back into the Ecto type. Each callback should behave as follows:
type
should output the name of the DB typecast
should receive any type and output your custom Ecto typeload
should receive the DB type and output your custom Ecto typedump
should receive your custom Ecto type and output the DB type
Ecto.DateTime
is an example of a custom type. Developers often use
Ecto.DateTime
in their schemas and Ecto takes care of converting
between types whenever the schema information is available. Developers
may also implement Ecto.DataType
for Ecto.DateTime
, allowing
Ecto.DateTime
to behave as the database :datetime
even in the
absence of schema information.
Summary
Types
Custom types are represented by user-defined modules
Primitive Ecto types (handled by Ecto)
An Ecto type, primitive or custom
Functions
Checks if the given atom can be used as base type
Casts a value to the given type
Checks if the given atom can be used as composite type
Dumps a value to the given type
Loads a value with the given type
Checks if a given type matches with a primitive type that can be found in queries
Checks if we have a primitive type
Retrieves the underlying schema type for the given, possibly custom, type
Callbacks
Casts the given input to the custom type
Dumps the given term into an Ecto native type
Loads the given term into a custom type
Returns the underlying schema type for the custom type
Types
Functions
Specs
base?(atom) :: boolean
Checks if the given atom can be used as base type.
iex> base?(:string)
true
iex> base?(:array)
false
iex> base?(Custom)
false
Specs
cast(t, term) :: {:ok, term} | :error
Casts a value to the given type.
cast/2
is used by the finder queries and changesets
to cast outside values to specific types.
Note that nil can be cast to all primitive types as data stores allow nil to be set on any column.
iex> cast(:any, "whatever")
{:ok, "whatever"}
iex> cast(:any, nil)
{:ok, nil}
iex> cast(:string, nil)
{:ok, nil}
iex> cast(:integer, 1)
{:ok, 1}
iex> cast(:integer, "1")
{:ok, 1}
iex> cast(:integer, "1.0")
:error
iex> cast(:id, 1)
{:ok, 1}
iex> cast(:id, "1")
{:ok, 1}
iex> cast(:id, "1.0")
:error
iex> cast(:float, 1.0)
{:ok, 1.0}
iex> cast(:float, 1)
{:ok, 1.0}
iex> cast(:float, "1")
{:ok, 1.0}
iex> cast(:float, "1.0")
{:ok, 1.0}
iex> cast(:float, "1-foo")
:error
iex> cast(:boolean, true)
{:ok, true}
iex> cast(:boolean, false)
{:ok, false}
iex> cast(:boolean, "1")
{:ok, true}
iex> cast(:boolean, "0")
{:ok, false}
iex> cast(:boolean, "whatever")
:error
iex> cast(:string, "beef")
{:ok, "beef"}
iex> cast(:binary, "beef")
{:ok, "beef"}
iex> cast(:decimal, Decimal.new(1.0))
{:ok, Decimal.new(1.0)}
iex> cast(:decimal, Decimal.new("1.0"))
{:ok, Decimal.new(1.0)}
iex> cast({:array, :integer}, [1, 2, 3])
{:ok, [1, 2, 3]}
iex> cast({:array, :integer}, ["1", "2", "3"])
{:ok, [1, 2, 3]}
iex> cast({:array, :string}, [1, 2, 3])
:error
iex> cast(:string, [1, 2, 3])
:error
Specs
composite?(atom) :: boolean
Checks if the given atom can be used as composite type.
iex> composite?(:array)
true
iex> composite?(:string)
false
Dumps a value to the given type.
Opposite to casting, dumping requires the returned value to be a valid Ecto type, as it will be sent to the underlying data store.
iex> dump(:string, nil)
{:ok, nil}
iex> dump(:string, "foo")
{:ok, "foo"}
iex> dump(:integer, 1)
{:ok, 1}
iex> dump(:integer, "10")
:error
iex> dump(:binary, "foo")
{:ok, "foo"}
iex> dump(:binary, 1)
:error
iex> dump({:array, :integer}, [1, 2, 3])
{:ok, [1, 2, 3]}
iex> dump({:array, :integer}, [1, "2", 3])
:error
iex> dump({:array, :binary}, ["1", "2", "3"])
{:ok, ["1", "2", "3"]}
A dumper
function may be given for handling recursive types.
Loads a value with the given type.
iex> load(:string, nil)
{:ok, nil}
iex> load(:string, "foo")
{:ok, "foo"}
iex> load(:integer, 1)
{:ok, 1}
iex> load(:integer, "10")
:error
A loader
function may be given for handling recursive types.
Checks if a given type matches with a primitive type that can be found in queries.
iex> match?(:string, :any)
true
iex> match?(:any, :string)
true
iex> match?(:string, :string)
true
iex> match?({:array, :string}, {:array, :any})
true
iex> match?(Ecto.DateTime, :datetime)
true
iex> match?(Ecto.DateTime, :string)
false
Specs
primitive?(t) :: boolean
Checks if we have a primitive type.
iex> primitive?(:string)
true
iex> primitive?(Another)
false
iex> primitive?({:array, :string})
true
iex> primitive?({:array, Another})
true
Retrieves the underlying schema type for the given, possibly custom, type.
iex> type(:string)
:string
iex> type(Ecto.DateTime)
:datetime
iex> type({:array, :string})
{:array, :string}
iex> type({:array, Ecto.DateTime})
{:array, :datetime}
iex> type({:map, Ecto.DateTime})
{:map, :datetime}
Callbacks
Specs
cast(term) :: {:ok, term} | :error
Casts the given input to the custom type.
This callback is called on external input and can return any type,
as long as the dump/1
function is able to convert the returned
value back into an Ecto native type. There are two situations where
this callback is called:
- When casting values by
Ecto.Changeset
- When passing arguments to
Ecto.Query
Specs
dump(term) :: {:ok, term} | :error
Dumps the given term into an Ecto native type.
This callback is called with any term that was stored in the struct and it needs to validate them and convert it to an Ecto native type.
Specs
load(term) :: {:ok, term} | :error
Loads the given term into a custom type.
This callback is called when loading data from the database and
receive an Ecto native type. It can return any type, as long as
the dump/1
function is able to convert the returned value back
into an Ecto native type.
Specs
type :: t
Returns the underlying schema type for the custom type.
For example, if you want to provide your own datetime
structures, the type function should return :datetime
.
Note this function is not required to return Ecto primitive types, the type is only required to be known by the adapter.