Ecto v2.1.1 Ecto.Changeset
Changesets allow filtering, casting, validation and definition of constraints when manipulating structs.
There is an example of working with changesets in the introductory
documentation in the Ecto
module. The functions cast/3
and
change/2
are the usual entry points for creating changesets.
The first one is used to cast and validate external parameters,
such as parameters sent through a form, API, command line, etc.
The second one is used to change data directly from your application.
The remaining functions in this module, such as validations, constraints, association handling, are about manipulating changesets. Let’s discuss some of this extra functionality.
Validations and constraints
Ecto changesets provide both validations and constraints which are ultimately turned into errors in case something goes wrong.
The difference between them is that validations can be executed without a need to interact with the database and, therefore, are always executed before attempting to insert or update the entry in the database.
However, constraints can only be checked in a safe way when performing the operation in the database. As a consequence, validations are always checked before constraints. Constraints won’t even be checked in case validations failed.
Let’s see an example:
defmodule User do
use Ecto.Schema
import Ecto.Changeset
schema "users" do
field :name
field :email
field :age, :integer
end
def changeset(user, params \\ %{}) do
user
|> cast(params, [:name, :email, :age])
|> validate_required([:name, :email])
|> validate_format(:email, ~r/@/)
|> validate_inclusion(:age, 18..100)
|> unique_constraint(:email)
end
end
In the changeset/2
function above, we define three validations.
They check that name
and email
fields are present in the
changeset, the e-mail is of the specified format, and the age is
between 18 and 100 - as well as a unique constraint in the email
field.
Let’s suppose the e-mail is given but the age is invalid. The changeset would have the following errors:
changeset = User.changeset(%User{}, %{age: 0, email: "mary@example.com"})
{:error, changeset} = Repo.insert(changeset)
changeset.errors #=> [age: {"is invalid", []}, name: {"can't be blank", []}]
In this case, we haven’t checked the unique constraint in the e-mail field because the data did not validate. Let’s fix the age and assume, however, that the e-mail already exists in the database:
changeset = User.changeset(%User{}, %{age: 42, email: "mary@example.com"})
{:error, changeset} = Repo.insert(changeset)
changeset.errors #=> [email: {"has already been taken", []}]
Validations and constraints define an explicit boundary when the check happens. By moving constraints to the database, we also provide a safe, correct and data-race free means of checking the user input.
Empty values
Many times, the data given on cast needs to be further pruned, specially
regarding empty values. For example, if you are gathering data to be
cast from the command line or through an HTML form or any other text-based
format, it is likely those means cannot express nil values. For
those reasons, changesets include the concept of empty values, which are
values that will be automatically converted to nil
on cast/3
. Those
values are stored in the changeset empty_values
field and default to
[""]
.
Assocs, embeds and on replace
Using changesets you can work with associations as well as with embedded
structs. Sometimes related data may be replaced by incoming data and by
default Ecto won’t allow such. Such behaviour can be changed when defining
the relation by setting :on_replace
option in your association/embed
definition according to the values below:
:raise
(default) - do not allow removing association or embedded data via parent changesets:mark_as_invalid
- if attempting to remove the association or embedded data via parent changeset - an error will be added to the parent changeset, and it will be marked as invalid:nilify
- sets owner reference column tonil
(available only for associations):update
- updates the association, available only for has_one and belongs_to. This option will update all the fields given to the changeset including the id for the association:delete
- removes the association or related data from the database. This option has to be used carefully
The :delete
option in particular must be used carefully as it would allow
users to delete any associated data. If you need deletion, it is often preferred
to add a separate boolean virtual field to the changeset function that will allow
you to manually mark it for deletion, as in the example below:
defmodule Comment do
use Ecto.Schema
import Ecto.Changeset
schema "comments" do
field :body, :string
field :delete, :boolean, virtual: true
end
def changeset(comment, params) do
cast(comment, params, [:body, :delete])
|> maybe_mark_for_deletion
end
defp maybe_mark_for_deletion(changeset) do
if get_change(changeset, :delete) do
%{changeset | action: :delete}
else
changeset
end
end
end
Schemaless changesets
In the changeset examples so far, we have always used changesets to
validate and cast data backed up by a struct, such as the %User{}
struct defined by the User
module.
However, changesets also run without a changeset, by passing a tuple containing both the data and the supported types as a tuple instead of a struct:
data = %{}
types = %{first_name: :string, last_name: :string, email: :string}
changeset =
{data, types}
|> Ecto.Changeset.cast(params["sign_up"], Map.keys(types))
|> validate_required(...)
|> validate_length(...)
Such functionality makes Ecto extremely useful to cast, validate and prune data even if it is not meant to be persisted to the database.
Changeset actions
Changesets have an action field which is usually set by Ecto.Repo
whenever one of the operations such as insert
or update
is called:
changeset = User.changeset(%User{}, %{age: 42, email: "mary@example.com"})
{:error, changeset} = Repo.insert(changeset)
changeset.action
#=> :insert
This means that when working with changesets that are not meant to be
persisted to the database, such as schemaless changesets, you may need
to explicitly set the action to one specific value. For example,
frameworks such as Phoenix uses the value of changeset.action
to
decide if errors should be shown or not on a given form. In such cases,
the following construct is recommended:
changeset = User.changeset(%User{}, %{age: 42, email: "mary@example.com"})
# Since we don't plan to call Repo.insert/2 or similar, we
# need to mimic part of its behaviour, which is to check if
# the changeset is valid and set its action accordingly if not.
if changeset.valid? do
... success case ...
else
changeset = %{changeset | action: :insert} # action can be anything
... failure case ...
end
The Ecto.Changeset struct
The fields are:
valid?
- Stores if the changeset is validdata
- The changeset source data, for example, a structparams
- The parameters as given on changeset creationchanges
- Thechanges
from parameters that were approved in castingerrors
- All errors from validationsvalidations
- All validations performed in the changesetconstraints
- All constraints defined in the changesetrequired
- All required fields as a list of atomsfilters
- Filters (as a map%{field => value}
) to narrow the scope of update/delete queriesaction
- The action to be performed with the changesettypes
- Cache of the data’s field typesrepo
- The repository applying the changeset (only set after a Repo function is called)empty_values
- A list of values to be considered empty
Summary
Functions
Adds an error to the changeset
Applies the changeset changes to the changeset data
Checks the associated field exists
Applies the given params
as changes for the given data
according to
the given set of keys. Returns a changeset
WARNING: This function is deprecated in favor of cast/3
+ validate_required/3
Casts the given association with the changeset parameters
Casts the given embed with the changeset parameters
Wraps the given data in a changeset or adds changes to a changeset
Checks for a check constraint in the given field
Deletes a change with the given key
Checks for an exclusion constraint in the given field
Fetches a change from the given changeset
Fetches the given field from changes or from the data
Forces a change on the given key
with value
Checks for foreign key constraint in the given field
Gets a change or returns a default value
Gets a field from changes or from the data
Merges two changesets
Checks the associated field does not exist
Applies optimistic locking to the changeset
Provides a function to run before emitting changes to the repository
Puts the given association as a change in the changeset
Puts a change on the given key
with value
Puts the given embed as a change in the changeset
Traverses changeset errors and applies the given function to error messages
Checks for a unique constraint in the given field
Updates a change
Validates the given parameter was given as true
Validates the given field
change
Stores the validation metadata
and validates the given field
change
Validates that the given field matches the confirmation parameter of that field
Validates a change is not included in the given enumerable
Validates a change has the given format
Validates a change is included in the given enumerable
Validates a change is a string or list of the given length
Validates the properties of a number
Validates that one or more fields are present in the changeset
Validates a change, of type enum, is a subset of the given enumerable. Like validate_inclusion/4 for lists
Types
constraint :: %{type: :unique, constraint: String.t, match: :exact | :suffix, field: atom, message: error}
t :: %Ecto.Changeset{action: action, changes: %{optional(atom) => term}, constraints: [constraint], data: Ecto.Schema.t | map | nil, empty_values: term, errors: [{atom, error}], filters: %{optional(atom) => term}, params: %{optional(String.t) => term} | nil, prepare: [(t -> t)], repo: atom | nil, required: [atom], types: nil | %{optional(atom) => Ecto.Type.t}, valid?: boolean, validations: Keyword.t}
Functions
Adds an error to the changeset.
An additional keyword list keys
can be passed to provide additional
contextual information for the error. This is useful when using
traverse_errors
Examples
iex> changeset = change(%Post{}, %{title: ""})
iex> changeset = add_error(changeset, :title, "empty")
iex> changeset.errors
[title: {"empty", []}]
iex> changeset.valid?
false
iex> changeset = change(%Post{}, %{title: ""})
iex> changeset = add_error(changeset, :title, "empty", additional: "info")
iex> changeset.errors
[title: {"empty", [additional: "info"]}]
iex> changeset.valid?
false
Applies the changeset changes to the changeset data.
This operation will return the underlying data with changes regardless if the changeset is valid or not.
Examples
apply_changes(changeset)
Checks the associated field exists.
This is similar to foreign_key_constraint/3
except that the
field is inferred from the association definition. This is useful
to guarantee that a child will only be created if the parent exists
in the database too. Therefore, it only applies to belongs_to
associations.
As the name says, a constraint is required in the database for this function to work. Such constraint is often added as a reference to the child table:
create table(:comments) do
add :post_id, references(:posts)
end
Now, when inserting a comment, it is possible to forbid any comment to be added if the associated post does not exist:
comment
|> Ecto.Changeset.cast(params, [:post_id])
|> Ecto.Changeset.assoc_constraint(:post)
|> Repo.insert
Options
:message
- the message in case the constraint check fails, defaults to “does not exist”:name
- the constraint name. By default, the constraint name is inferred from the table + association field. May be required explicitly for complex cases
Applies the given params
as changes for the given data
according to
the given set of keys. Returns a changeset.
The given data
may be either a changeset, a struct or a {data, types}
tuple. The second argument is a map of params
that are cast according
to the type information from data
. params
is a map with string keys
or a map with atom keys containing potentially unsafe data.
During casting, all allowed
parameters will have their key name converted
to an atom and stored as a change in the :changes
field of the changeset.
All parameters that are not explicitly allowed are ignored.
If casting of all fields is successful, the changeset is returned as valid.
Examples
iex> changeset = cast(post, params, [:title])
iex> if changeset.valid? do
...> Repo.update!(changeset)
...> end
Passing a changeset as the first argument:
iex> changeset = cast(post, %{title: "Hello"}, [:title])
iex> new_changeset = cast(changeset, %{title: "Foo", body: "Bar"}, [:body])
iex> new_changeset.params
%{"title" => "Foo", "body" => "Bar"}
Or creating a changeset from a simple map with types:
iex> data = %{title: "hello"}
iex> types = %{title: :string}
iex> changeset = cast({data, types}, %{title: "world"}, [:title])
iex> apply_changes(changeset)
%{title: "world"}
Composing casts
cast/3
also accepts a changeset as its first argument. In such cases, all
the effects caused by the call to cast/3
(additional errors and changes)
are simply added to the ones already present in the argument changeset.
Parameters are merged (not deep-merged) and the ones passed to cast/3
take precedence over the ones already in the changeset.
WARNING: This function is deprecated in favor of cast/3
+ validate_required/3
.
Converts the given params
into a changeset for data
keeping only the set of required
and optional
keys.
Casts the given association with the changeset parameters.
This function requires the association to have been
preloaded in the changeset struct. Missing data will
invoke the :on_replace
behaviour defined on the association.
The parameters for the given association will be retrieved
from changeset.params
. Those parameters are expected to be
a map with attributes, similar to the ones passed to cast/3
.
Once parameters are retrieved, cast_assoc/3
will match those
parameters with the associations already in the changeset record.
For example, imagine a user has many addresses relationship where post data is sent as follows
%{"name" => "john doe", "addresses" => [
%{"street" => "somewhere", "country" => "brazil", "id" => 1},
%{"street" => "elsewhere", "country" => "poland"},
]}
and then
user
|> Repo.preload(:addresses)
|> Ecto.Changeset.cast(params, [])
|> Ecto.Changeset.cast_assoc(:addresses)
Once cast_assoc/3
is called, Ecto will compare those parameters
with the addresses already associated with the user and act as follows:
- If the parameter does not contain an ID, the parameter data
will be passed to
changeset/2
with a new struct and become an insert operation - If the parameter contains an ID and there is no associated child
with such ID, the parameter data will be passed to
changeset/2
with a new struct and become an insert operation - If the parameter contains an ID and there is an associated child
with such ID, the parameter data will be passed to
changeset/2
with the existing struct and become an update operation - If there is an associated child with an ID and its ID is not given
as parameter, the
:on_replace
callback for that association will be invoked (see the “On replace” section on the module documentation)
In other words, cast_assoc/3
is useful when the associated data is
managed alongside the parent struct, all at once. If each side of the
association is managed separately, it is preferable to use put_assoc/3
and directly instruct Ecto how the association should look like.
For example, imagine you are receiving a set of tags you want to
associate to an user. Those tags are meant to exist upfront. Using
cast_assoc/3
won’t work as desired because the tags are not managed
alongside the user. In such cases, put_assoc/3
will work as desired.
With the given parameters:
%{"name" => "john doe", "tags" => ["learner"]}
and then:
tags = Repo.all(from t in Tag, where: t.name in ^params["tags"])
user
|> Repo.preload(:tags)
|> Ecto.Changeset.cast(params) # No need to allow :tags as we put them directly
|> Ecto.Changeset.put_assoc(:tags, tags) # Explicitly set the tags
Note the changeset must have been previously cast
using cast/3
before this function is invoked.
Options
:with
- the function to build the changeset from params. Defaults to the changeset/2 function in the association module:required
- if the association is a required field:required_message
- the message on failure, defaults to “can’t be blank”:invalid_message
- the message on failure, defaults to “is invalid”
Casts the given embed with the changeset parameters.
The parameters for the given embed will be retrieved
from changeset.params
. Those parameters are expected to be
a map with attributes, similar to the ones passed to cast/3
.
Once parameters are retrieved, cast_embed/3
will match those
parameters with the embeds already in the changeset record.
See cast_assoc/3
for an example of working with casts and
associations which would also apply for embeds.
The changeset must have been previously cast
using
cast/3
before this function is invoked.
Options
:with
- the function to build the changeset from params. Defaults to the changeset/2 function in the embed module:required
- if the embed is a required field:required_message
- the message on failure, defaults to “can’t be blank”:invalid_message
- the message on failure, defaults to “is invalid”
Wraps the given data in a changeset or adds changes to a changeset.
Changed attributes will only be added if the change does not have the same value as the field in the data.
This function is useful for:
- wrapping a struct inside a changeset
- directly changing a struct without performing castings nor validations
- directly bulk-adding changes to a changeset
Since neither validation nor casting is performed, change/2
expects the keys in
changes
to be atoms. changes
can be a map as well as a keyword list.
When a changeset is passed as the first argument, the changes passed as the
second argument are merged over the changes already in the changeset if they
differ from the values in the struct. If changes
is an empty map, this
function is a no-op.
When a {data, types}
is passed as the first argument, a changeset is
created with the given data and types and marked as valid.
See cast/3
if you’d prefer to cast and validate external parameters.
Examples
iex> changeset = change(%Post{})
%Ecto.Changeset{...}
iex> changeset.valid?
true
iex> changeset.changes
%{}
iex> changeset = change(%Post{author: "bar"}, title: "title")
iex> changeset.changes
%{title: "title"}
iex> changeset = change(%Post{title: "title"}, title: "title")
iex> changeset.changes
%{}
iex> changeset = change(changeset, %{title: "new title", body: "body"})
iex> changeset.changes.title
"new title"
iex> changeset.changes.body
"body"
Checks for a check constraint in the given field.
The check constraint works by relying on the database to check if the check constraint has been violated or not and, if so, Ecto converts it into a changeset error.
Options
:message
- the message in case the constraint check fails. Defaults to “is invalid”:name
- the name of the constraint. Required.:match
- how the changeset constraint name it matched against the repo constraint, may be:exact
or:suffix
. Defaults to:exact
.:suffix
matches any repo constraint whichends_with?
:name
to this changeset constraint.
Deletes a change with the given key.
Examples
iex> changeset = change(%Post{}, %{title: "foo"})
iex> changeset = delete_change(changeset, :title)
iex> get_change(changeset, :title)
nil
Checks for an exclusion constraint in the given field.
The exclusion constraint works by relying on the database to check if the exclusion constraint has been violated or not and, if so, Ecto converts it into a changeset error.
Options
:message
- the message in case the constraint check fails, defaults to “violates an exclusion constraint”:name
- the constraint name. By default, the constraint name is inferred from the table + field. May be required explicitly for complex cases:match
- how the changeset constraint name it matched against the repo constraint, may be:exact
or:suffix
. Defaults to:exact
.:suffix
matches any repo constraint whichends_with?
:name
to this changeset constraint.
Fetches a change from the given changeset.
This function only looks at the :changes
field of the given changeset
and
returns {:ok, value}
if the change is present or :error
if it’s not.
Examples
iex> changeset = change(%Post{body: "foo"}, %{title: "bar"})
iex> fetch_change(changeset, :title)
{:ok, "bar"}
iex> fetch_change(changeset, :body)
:error
Fetches the given field from changes or from the data.
While fetch_change/2
only looks at the current changes
to retrieve a value, this function looks at the changes and
then falls back on the data, finally returning :error
if
no value is available.
For relations, these functions will return the changeset
original data with changes applied. To retrieve raw changesets,
please use fetch_change/2
.
Examples
iex> post = %Post{title: "Foo", body: "Bar baz bong"}
iex> changeset = change(post, %{title: "New title"})
iex> fetch_field(changeset, :title)
{:changes, "New title"}
iex> fetch_field(changeset, :body)
{:data, "Bar baz bong"}
iex> fetch_field(changeset, :not_a_field)
:error
Forces a change on the given key
with value
.
If the change is already present, it is overridden with the new value.
Examples
iex> changeset = change(%Post{author: "bar"}, %{title: "foo"})
iex> changeset = force_change(changeset, :title, "bar")
iex> changeset.changes
%{title: "bar"}
iex> changeset = force_change(changeset, :author, "bar")
iex> changeset.changes
%{title: "bar", author: "bar"}
Checks for foreign key constraint in the given field.
The foreign key constraint works by relying on the database to check if the associated data exists or not. This is useful to guarantee that a child will only be created if the parent exists in the database too.
In order to use the foreign key constraint the first step is to define the foreign key in a migration. This is often done with references. For example, imagine you are creating a comments table that belongs to posts. One would have:
create table(:comments) do
add :post_id, references(:posts)
end
By default, Ecto will generate a foreign key constraint with name “comments_post_id_fkey” (the name is configurable).
Now that a constraint exists, when creating comments, we could annotate the changeset with foreign key constraint so Ecto knows how to convert it into an error message:
cast(comment, params, [:post_id])
|> foreign_key_constraint(:post_id)
Now, when invoking Repo.insert/2
or Repo.update/2
, if the
associated post does not exist, it will be converted into an
error and {:error, changeset}
returned by the repository.
Options
:message
- the message in case the constraint check fails, defaults to “does not exist”:name
- the constraint name. By default, the constraint name is inferred from the table + field. May be required explicitly for complex cases
Gets a change or returns a default value.
Examples
iex> changeset = change(%Post{body: "foo"}, %{title: "bar"})
iex> get_change(changeset, :title)
"bar"
iex> get_change(changeset, :body)
nil
Gets a field from changes or from the data.
While get_change/3
only looks at the current changes
to retrieve a value, this function looks at the changes and
then falls back on the data, finally returning default
if
no value is available.
For relations, these functions will return the changeset data
with changes applied. To retrieve raw changesets, please use get_change/3
.
iex> post = %Post{title: "A title", body: "My body is a cage"}
iex> changeset = change(post, %{title: "A new title"})
iex> get_field(changeset, :title)
"A new title"
iex> get_field(changeset, :not_a_field, "Told you, not a field!")
"Told you, not a field!"
Merges two changesets.
This function merges two changesets provided they have been applied to the
same data (their :data
field is equal); if the data differs, an
ArgumentError
exception is raised. If one of the changesets has a :repo
field which is not nil
, then the value of that field is used as the :repo
field of the resulting changeset; if both changesets have a non-nil
and
different :repo
field, an ArgumentError
exception is raised.
The other fields are merged with the following criteria:
params
- params are merged (not deep-merged) giving precedence to the params ofchangeset2
in case of a conflict. If both changesets have their:params
fields set tonil
, the resulting changeset will have its params set tonil
too.changes
- changes are merged giving precedence to thechangeset2
changes.errors
andvalidations
- they are simply concatenated.required
- required fields are merged; all the fields that appear in the required list of both changesets are moved to the required list of the resulting changeset.
Examples
iex> changeset1 = cast(%Post{}, %{title: "Title"}, [:title])
iex> changeset2 = cast(%Post{}, %{title: "New title", body: "Body"}, [:title, :body])
iex> changeset = merge(changeset1, changeset2)
iex> changeset.changes
%{body: "Body", title: "New title"}
iex> changeset1 = cast(%Post{body: "Body"}, %{title: "Title"}, [:title])
iex> changeset2 = cast(%Post{}, %{title: "New title"}, [:title])
iex> merge(changeset1, changeset2)
** (ArgumentError) different :data when merging changesets
Checks the associated field does not exist.
This is similar to foreign_key_constraint/3
except that the
field is inferred from the association definition. This is useful
to guarantee that parent can only be deleted (or have its primary
key changed) if no child exists in the database. Therefore, it only
applies to has_*
associations.
As the name says, a constraint is required in the database for this function to work. Such constraint is often added as a reference to the child table:
create table(:comments) do
add :post_id, references(:posts)
end
Now, when deleting the post, it is possible to forbid any post to be deleted if they still have comments attached to it:
post
|> Ecto.Changeset.change
|> Ecto.Changeset.no_assoc_constraint(:comments)
|> Repo.delete
Options
:message
- the message in case the constraint check fails, defaults to “is still associated with this entry” (for has_one) and “are still associated with this entry” (for has_many):name
- the constraint name. By default, the constraint name is inferred from the association table + association field. May be required explicitly for complex cases
optimistic_lock(Ecto.Schema.t | t, atom, (integer -> integer)) :: t | no_return
Applies optimistic locking to the changeset.
Optimistic locking (or optimistic concurrency control) is a technique that allows concurrent edits on a single record. While pessimistic locking works by locking a resource for an entire transaction, optimistic locking only checks if the resource changed before updating it.
This is done by regularly fetching the record from the database, then checking whether another user has made changes to the record only when updating the record. This behaviour is ideal in situations where the chances of concurrent updates to the same record are low; if they’re not, pessimistic locking or other concurrency patterns may be more suited.
Usage
Optimistic locking works by keeping a “version” counter for each record; this counter gets incremented each time a modification is made to a record. Hence, in order to use optimistic locking, a field must exist in your schema for versioning purpose. Such field is usually an integer but other types are supported.
Examples
Assuming we have a Post
schema (stored in the posts
table), the first step
is to add a version column to the posts
table:
alter table(:posts) do
add :lock_version, :integer, default: 1
end
The column name is arbitrary and doesn’t need to be :lock_version
. Now add
a field to the schema too:
defmodule Post do
use Ecto.Schema
schema "posts" do
field :title, :string
field :lock_version, :integer, default: 1
end
def changeset(:update, struct, params \\ %{}) do
struct
|> Ecto.Changeset.cast(params, [:title])
|> Ecto.Changeset.optimistic_lock(:lock_version)
end
end
Now let’s take optimistic locking for a spin:
iex> post = Repo.insert!(%Post{title: "foo"})
%Post{id: 1, title: "foo", lock_version: 1}
iex> valid_change = Post.changeset(:update, post, %{title: "bar"})
iex> stale_change = Post.changeset(:update, post, %{title: "baz"})
iex> Repo.update!(valid_change)
%Post{id: 1, title: "bar", lock_version: 2}
iex> Repo.update!(stale_change)
** (Ecto.StaleEntryError) attempted to update a stale entry:
%Post{id: 1, title: "baz", lock_version: 1}
When a conflict happens (a record which has been previously fetched is
being updated, but that same record has been modified since it was
fetched), an Ecto.StaleEntryError
exception is raised.
Optimistic locking also works with delete operations. Just call the
optimistic_lock
function with the data before delete:
iex> changeset = Ecto.Changeset.optimistic_lock(post, :lock_version)
iex> Repo.delete(changeset)
optimistic_lock/3
by default assumes the field
being used as a lock is an integer. If you want to use another type,
you need to pass the third argument customizing how the next value
is generated:
iex> Ecto.Changeset.optimistic_lock(post, :lock_uuid, fn _ -> Ecto.UUID.generate end)
Provides a function to run before emitting changes to the repository.
Such function receives the changeset and must return a changeset, allowing developers to do final adjustments to the changeset or to issue data consistency commands.
The given function is guaranteed to run inside the same transaction as the changeset operation for databases that do support transactions.
Example
A common use case is updating a counter cache, in this case updating a post’s comment count when a comment is created:
def create_comment(comment, params) do
comment
|> cast(params, [:body, :post_id])
|> prepare_changes(fn changeset ->
assoc(changeset.data, :post)
|> changeset.repo.update_all(inc: [comment_count: 1])
changeset
end)
end
We retrieve the repo and from the comment changeset itself, and use update_all to update the counter cache in one query. Finally, the original changeset must be returned.
Puts the given association as a change in the changeset.
This function requires the association to have been
preloaded in the changeset struct. Missing data will
invoke the :on_replace
behaviour defined on the association.
The given value may either be the association struct, a changeset for the given association or a map or keyword list of changes to be applied to the current association. If a map or keyword list are given and there is no association, one will be created.
If the association has no changes, it will be skipped. If the association is invalid, the changeset will be marked as invalid. If the given value is not an association struct or changeset, it will raise.
Also see cast_assoc/3
for a discussion of when to use
cast_assoc/3
and put_assoc/3
.
Puts a change on the given key
with value
.
If the change is already present, it is overridden with the new value, also, if the change has the same value as in the changeset data, it is not added to the list of changes.
Examples
iex> changeset = change(%Post{author: "bar"}, %{title: "foo"})
iex> changeset = put_change(changeset, :title, "bar")
iex> changeset.changes
%{title: "bar"}
iex> changeset = put_change(changeset, :author, "bar")
iex> changeset.changes
%{title: "bar"}
Puts the given embed as a change in the changeset.
The given value may either be the embed struct, a changeset for the given embed or a map or keyword list of changes to be applied to the current embed. If a map or keyword list are given and there is no embed, one will be created.
If the embed has no changes, it will be skipped. If the embed is invalid, the changeset will be marked as invalid. If the given value is not an embed struct or changeset, it will raise.
Also see cast_assoc/3
for a discussion of when to use
cast_assoc/3
and put_assoc/3
which also applies to
put_embed/3
.
Traverses changeset errors and applies the given function to error messages.
This function is particularly useful when associations and embeds are cast in the changeset as it will traverse all associations and embeds and place all errors in a series of nested maps.
A changeset is supplied along with a function to apply to each
error message as the changeset is traversed. The error message
function receives an error tuple {msg, opts}
, for example:
{"should be at least %{count} characters", [count: 3, validation: :length, min: 3]}
Examples
iex> traverse_errors(changeset, fn {msg, opts} ->
...> Enum.reduce(opts, msg, fn {key, value}, acc ->
...> String.replace(acc, "%{#{key}}", to_string(value))
...> end)
...> end)
%{title: ["should be at least 3 characters"]}
Optionally function can accept three arguments: changeset
, field
and error tuple {msg, opts}
.
It is useful whenever you want to extract validations rules from changeset.validations
to build detailed error description.
Checks for a unique constraint in the given field.
The unique constraint works by relying on the database to check if the unique constraint has been violated or not and, if so, Ecto converts it into a changeset error.
In order to use the uniqueness constraint, the first step is to define the unique index in a migration:
create unique_index(:users, [:email])
Now that a constraint exists, when modifying users, we could annotate the changeset with unique constraint so Ecto knows how to convert it into an error message:
cast(user, params, [:email])
|> unique_constraint(:email)
Now, when invoking Repo.insert/2
or Repo.update/2
, if the
email already exists, it will be converted into an error and
{:error, changeset}
returned by the repository. Note that the error
will occur only after hitting the database so it will not be visible
until all other validations pass.
Options
:message
- the message in case the constraint check fails, defaults to “has already been taken”:name
- the constraint name. By default, the constraint name is inferred from the table + field. May be required explicitly for complex cases:match
- how the changeset constraint name it matched against the repo constraint, may be:exact
or:suffix
. Defaults to:exact
.:suffix
matches any repo constraint whichends_with?
:name
to this changeset constraint.
Complex constraints
Because the constraint logic is in the database, we can leverage all the database functionality when defining them. For example, let’s suppose the e-mails are scoped by company id. We would write in a migration:
create unique_index(:users, [:email, :company_id])
Because such indexes have usually more complex names, we need to explicitly tell the changeset which constraint name to use:
cast(user, params, [:email])
|> unique_constraint(:email, name: :posts_special_email_index)
Notice that the first param is just one of the unique index fields, this will
be used as the error key to the changeset errors keyword list. For example,
the above unique_constraint/3
would generate something like:
Repo.insert!(%User{email: "john@elixir.org", company_id: 1})
changeset = User.changeset(%User{}, %{email: "john@elixir.org", company_id: 1})
{:error, changeset} = Repo.insert(changeset)
changeset.errors #=> [email: {"has already been taken", []}]
Alternatively, you can give both unique_index
and unique_constraint
the same name:
# In the migration
create unique_index(:users, [:email, :company_id], name: :posts_email_company_id_index)
# In the changeset function
cast(user, params, [:email])
|> unique_constraint(:email, name: :posts_email_company_id_index)
Case sensitivity
Unfortunately, different databases provide different guarantees
when it comes to case-sensitiveness. For example, in MySQL, comparisons
are case-insensitive by default. In Postgres, users can define case
insensitive column by using the :citext
type/extension. In your migration:
execute "CREATE EXTENSION IF NOT EXISTS citext"
create table(:users) do
...
add :email, :citext
...
end
If for some reason your database does not support case insensitive columns, you can explicitly downcase values before inserting/updating them:
cast(data, params, [:email])
|> update_change(:email, &String.downcase/1)
|> unique_constraint(:email)
Updates a change.
The given function
is invoked with the change value only if there
is a change for the given key
. Note that the value of the change
can still be nil
(unless the field was marked as required on cast/3
).
Examples
iex> changeset = change(%Post{}, %{impressions: 1})
iex> changeset = update_change(changeset, :impressions, &(&1 + 1))
iex> changeset.changes.impressions
2
Validates the given parameter was given as true.
This validation is used to check for one specific parameter being true and as such does not require the field to effectively exist in the schema or the data being validated.
Options
:message
- the message on failure, defaults to “must be accepted”
Examples
validate_acceptance(changeset, :terms_of_service)
validate_acceptance(changeset, :rules, message: "please accept rules")
Validates the given field
change.
It invokes the validator
function to perform the validation
only if a change for the given field
exists and the change
value is not nil
. The function must return a list of errors
(with an empty list meaning no errors).
In case there’s at least one error, the list of errors will be appended to the
:errors
field of the changeset and the :valid?
flag will be set to
false
.
Examples
iex> changeset = change(%Post{}, %{title: "foo"})
iex> changeset = validate_change changeset, :title, fn :title, title ->
...> # Value must not be "foo"!
...> if title == "foo" do
...> [title: "cannot be foo"]
...> else
...> []
...> end
...> end
iex> changeset.errors
[title: {"cannot be foo", []}]
Stores the validation metadata
and validates the given field
change.
Similar to validate_change/3
but stores the validation metadata
into the changeset validators. The validator metadata is often used
as a reflection mechanism, to automatically generate code based on
the available validations.
Examples
iex> changeset = change(%Post{}, %{title: "foo"})
iex> changeset = validate_change changeset, :title, :useless_validator, fn
...> _, _ -> []
...> end
iex> changeset.validations
[title: :useless_validator]
Validates that the given field matches the confirmation parameter of that field.
By calling validate_confirmation(changeset, :email)
, this
validation will check if both “email” and “email_confirmation”
in the parameter map matches.
Note that if the confirmation field is nil or missing, by default this does not add a validation error. You can specify that the confirmation field is required in the options (see below). Note “email_confirmation” does not need to be added as a virtual field in your schema.
Options
:message
- the message on failure, defaults to “does not match”:required
- boolean, sets whether existence of confirmation parameter is required for addition of error. Defaults to false
Examples
validate_confirmation(changeset, :email)
validate_confirmation(changeset, :password, message: "does not match password")
cast(data, params, [:password])
|> validate_confirmation(:password, message: "does not match password")
Validates a change is not included in the given enumerable.
Options
:message
- the message on failure, defaults to “is reserved”
Examples
validate_exclusion(changeset, :name, ~w(admin superadmin))
Validates a change has the given format.
The format has to be expressed as a regular expression.
Options
:message
- the message on failure, defaults to “has invalid format”
Examples
validate_format(changeset, :email, ~r/@/)
Validates a change is included in the given enumerable.
Options
:message
- the message on failure, defaults to “is invalid”
Examples
validate_inclusion(changeset, :gender, ["man", "woman", "other", "prefer not to say"])
validate_inclusion(changeset, :age, 0..99)
Validates a change is a string or list of the given length.
Options
:is
- the length must be exactly this value:min
- the length must be greater than or equal to this value:max
- the length must be less than or equal to this value:message
- the message on failure, depending on the validation, is one of:- for strings:
- “should be %{count} character(s)”
- “should be at least %{count} character(s)”
- “should be at most %{count} character(s)”
- for lists:
- “should have %{count} item(s)”
- “should have at least %{count} item(s)”
- “should have at most %{count} item(s)”
Examples
validate_length(changeset, :title, min: 3)
validate_length(changeset, :title, max: 100)
validate_length(changeset, :title, min: 3, max: 100)
validate_length(changeset, :code, is: 9)
validate_length(changeset, :topics, is: 2)
Validates the properties of a number.
Options
:less_than
:greater_than
:less_than_or_equal_to
:greater_than_or_equal_to
:equal_to
:message
- the message on failure, defaults to one of:- “must be less than %{number}”
- “must be greater than %{number}”
- “must be less than or equal to %{number}”
- “must be greater than or equal to %{number}”
- “must be equal to %{number}”
Examples
validate_number(changeset, :count, less_than: 3)
validate_number(changeset, :pi, greater_than: 3, less_than: 4)
validate_number(changeset, :the_answer_to_life_the_universe_and_everything, equal_to: 42)
Validates that one or more fields are present in the changeset.
If the value of a field is nil
or a string made only of whitespace,
the changeset is marked as invalid and an error is added. Note the
error won’t be added though if the field already has an error.
You can pass a single field name or a list of field names that are required.
Do not use this function to validate associations are required,
instead pass the :required
option to cast_assoc/3
.
Options
:message
- the message on failure, defaults to “can’t be blank”
Examples
validate_required(changeset, :title)
validate_required(changeset, [:title, :body])
Validates a change, of type enum, is a subset of the given enumerable. Like validate_inclusion/4 for lists.
Options
:message
- the message on failure, defaults to “has an invalid entry”
Examples
validate_subset(changeset, :pets, ["cat", "dog", "parrot"])
validate_subset(changeset, :lottery_numbers, 0..99)