Ecto v2.1.1 Ecto.Query

Provides the Query DSL.

Queries are used to retrieve and manipulate data from a repository (see Ecto.Repo). Ecto queries come in two flavors: keyword-based and macro-based. Most examples will use the keyword-based syntax, the macro one will be explored in later sections.

Let’s see a sample query:

# Imports only from/2 of Ecto.Query
import Ecto.Query, only: [from: 2]

# Create a query
query = from u in "users",
          where: u.age > 18,
          select: u.name

# Send the query to the repository
Repo.all(query)

In the example above, we are directly querying the “users” table from the database.

Query expressions

Ecto allows a limited set of expressions inside queries. In the query below, for example, we use u.age to access a field, the > comparison operator and the literal 0:

query = from u in "users", where: u.age > 0, select: u.name

You can find the full list of operations in Ecto.Query.API. Besides the operations listed there, the following literals are supported in queries:

  • Integers: 1, 2, 3
  • Floats: 1.0, 2.0, 3.0
  • Booleans: true, false
  • Binaries: <<1, 2, 3>>
  • Strings: "foo bar", ~s(this is a string)
  • Arrays: [1, 2, 3], ~w(interpolate words)

All other types and dynamic values must be passed as a parameter using interpolation as explained below.

Interpolation and casting

External values and Elixir expressions can be injected into a query expression with ^:

def with_minimum(age, height_ft) do
  from u in "users",
    where: u.age > ^age and u.height > ^(height_ft * 3.28),
    select: u.name
end

with_minimum(18, 5.0)

When interpolating values, you may want to explicitly tell Ecto what is the expected type of the value being interpolated:

age = "18"
Repo.all(from u in "users",
          where: u.age > type(^age, :integer),
          select: u.name)

In the example above, Ecto will cast the age to type integer. When a value cannot be cast, Ecto.Query.CastError is raised.

To avoid the repetition of always specifying the types, you may define an Ecto.Schema. In such cases, Ecto will analyze your queries and automatically cast the interpolated “age” when compared to the u.age field, as long as the age field is defined with type :integer in your schema:

age = "18"
Repo.all(from u in User, where: u.age > ^age, select: u.name)

Another advantage of using schemas is that we no longer need to specify the select option in queries, as by default Ecto will retrieve all fields specified in the schema:

age = "18"
Repo.all(from u in User, where: u.age > ^age)

For this reason, we will use schemas on the remaining examples but remember Ecto does not require them in order to write queries.

Composition

Ecto queries are composable. For example, the query above can actually be defined in two parts:

# Create a query
query = from u in User, where: u.age > 18

# Extend the query
query = from u in query, select: u.name

Composing queries uses the same syntax as creating a query. The difference is that, instead of passing a schema like Weather on the right side of in, we passed the query itself.

Any value can be used on the right-side of in as long as it implements the Ecto.Queryable protocol. For now, we know such protocols is implemented for both atoms (like User) and strings (like “users”).

In any case, regardless if a schema has been given or not, Ecto queries are always composable thanks to its binding system.

Query bindings

On the left side of in we specify the query bindings. This is done inside from and join clauses. In the query below u is a binding and u.age is a field access using this binding.

query = from u in User, where: u.age > 18

Bindings are not exposed from the query. When composing queries you must specify bindings again for each refinement query. For example to further narrow-down above query we again need to tell Ecto what bindings to expect:

query = from u in query, select: u.city

Bindings in Ecto are positional, and the names do not have to be consistent between input and refinement queries. For example, the query above could also be written as:

query = from q in query, select: q.city

It would make no difference to Ecto. This is important because it allows developers to compose queries without caring about the bindings used in the initial query.

When using joins, the bindings should be matched in the order they are specified:

# Create a query
query = from p in Post,
          join: c in Comment, where: c.post_id == p.id

# Extend the query
query = from [p, c] in query,
          select: {p.title, c.body}

You are not required to specify all bindings when composing. For example, if we would like to order the results above by post insertion date, we could further extend it as:

query = from q in query, order_by: q.inserted_at

The example above will work if the input query has 1 or 10 bindings. In the example above, we will always sort by the inserted_at column from the from source.

Similarly, if you are interested only on the last binding (or the last bindings) in a query, you can use … to specify “all bindings before” and match on the last one.

For instance, imagine you wrote:

posts_with_comments =
  from p in query, join: c in Comment, where: c.post_id == p.id

And now we want to make sure to return both the post title and the comment body. Although we may not know how many bindings there are in the query, we are sure posts is the first binding and comments are the last one, so we can write:

from [p, ..., c] in posts_with_comments, select: {p.title, c.body}

In other words, ... will include all the binding between the first and the last, which may be no binding at all, one or many. Using ... can be handy from time to time but most of its uses can be avoided by relying on the keyword query syntax when writing queries.

Bindingless operations

Although bindings are extremely useful when working with joins, they are not necessary when the query has only the from clause. For such cases, Ecto supports a way for building queries without specifying the binding:

from Post,
  where: [category: "fresh and new"],
  order_by: [desc: :published_at],
  select: [:id, :title, :body]

The query above will select all posts with category “fresh and new”, order by the most recently published, and return Post structs with only the id, title and body fields set. It is equivalent to:

from p in Post,
  where: p.category == "fresh and new",
  order_by: [desc: p.published_at],
  select: struct(p, [:id, :title, :body])

One advantage of bindingless queries is that they are data-driven and therefore useful for dynamically building queries. For example, the query above could also be written as:

where = [category: "fresh and new"]
order_by = [desc: :published_at]
select = [:id, :title, :body]
from Post, where: ^where, order_by: ^order_by, select: ^select

This feature is very useful when queries need to be built based on some user input, like web search forms, CLIs and so on.

Fragments

If you need an escape hatch, Ecto provides fragments (see Ecto.Query.API.fragment/1) to inject SQL (and non-SQL) fragments into queries.

For example, to get all posts while running the “lower(?)” function in the database where p.title is interpolated in place of ?, one can write:

from p in Post,
  where: is_nil(p.published_at) and
         fragment("lower(?)", p.title) == ^title

Also, most adapters provide direct APIs for queries, like Ecto.Adapters.SQL.query/4, allowing developers to completely bypass Ecto queries.

Macro API

In all examples so far we have used the keywords query syntax to create a query:

import Ecto.Query
from u in "users", where: u.age > 18, select: u.name

Due to the prevalence of the pipe operator in Elixir, Ecto also supports a pipe-based syntax:

"users"
|> where([u], u.age > 18)
|> select([u], u.name)

The keyword-based and pipe-based examples are equivalent. The downside of using macros is that the binding must be specified for every operation. However, since keyword-based and pipe-based examples are equivalent, the bindingless syntax also works for macros:

"users"
|> where([u], u.age > 18)
|> select([:name])

Such allows developers to write queries using bindings only in more complex query expressions.

This module documents each of those macros, providing examples in both the keywords query and pipe expression formats.

Query Prefix

It is possible to set a prefix for the queries. For Postgres users, this will specify the schema where the table is located, while for MySQL users this will specify the database where the table is located. When no prefix is set, Postgres queries are assumed to be in the public schema, while MySQL queries are assumed to be in the database set in the config for the repo.

To set the prefix on a query:

results =
  query # May be User or an Ecto.Query itself
  |> Ecto.Queryable.to_query
  |> Map.put(:prefix, "foo")
  |> Repo.all

When a prefix is set in a query, all loaded structs will belong to that prefix, so operations like update and delete will be applied to the proper prefix. In case you want to manually set the prefix for new data, specially on insert, use Ecto.put_meta/2.

Summary

Functions

Resets a previously set field on a query

Restricts the query to return the first result ordered by primary key

Restricts the query to return the last result ordered by primary key

Converts a query into a subquery

Macros

A distinct query expression

Buids a dynamic query expression

Creates a query

A group by query expression

An AND having query expression

A limit query expression

A lock query expression

An offset query expression

An OR having query expression

An OR where query expression

An order by query expression

Preloads the associations into the given struct

A select query expression

An update query expression

An AND where query expression

Types

t()
t

Functions

exclude(query, field)

Resets a previously set field on a query.

It can reset any query field except the query source (from).

Example

query |> Ecto.Query.exclude(:select)
first(queryable, order_by \\ nil)

Restricts the query to return the first result ordered by primary key.

The query will be automatically ordered by the primary key unless order_by is given or order_by is set in the query. Limit is always set to 1.

Examples

Post |> first |> Repo.one
query |> first(:inserted_at) |> Repo.one
last(queryable, order_by \\ nil)

Restricts the query to return the last result ordered by primary key.

The query ordering will be automatically reversed, with ASC columns becoming DESC columns (and vice-versa) and limit is set to 1. If there is no ordering, the query will be automatically ordered decreasingly by primary key.

Examples

Post |> last |> Repo.one
query |> last(:inserted_at) |> Repo.one
subquery(subquery)

Converts a query into a subquery.

If a subquery is given, returns the subquery itself. If any other value is given, it is converted to a query via Ecto.Queryable and wrapped in the Ecto.SubQuery struct.

Subqueries are currently only supported in the from and join fields.

Examples

# Get the average salary of the top 10 highest salaries
query = from Employee, order_by: [desc: :salary], limit: 10
from e in subquery(query), select: avg(e.salary)

Macros

distinct(query, binding \\ [], expr)

A distinct query expression.

When true, only keeps distinct values from the resulting select expression.

If supported by your database, you can also pass query expressions to distinct and it will generate a query with DISTINCT ON. In such cases, distinct accepts exactly the same expressions as order_by and any distinct expression will be automatically prepended to the order_by expressions in case there is any order_by expression.

Keywords examples

# Returns the list of different categories in the Post schema
from(p in Post, distinct: true, select: p.category)

# If your database supports DISTINCT ON(),
# you can pass expressions to distinct too
from(p in Post,
   distinct: p.category,
   order_by: [p.date])

# The DISTINCT ON() also supports ordering similar to ORDER BY.
from(p in Post,
   distinct: [desc: p.category],
   order_by: [p.date])

# Using atoms
from(p in Post, distinct: :category, order_by: :date)

Expressions example

Post
|> distinct(true)
|> order_by([p], [p.category, p.author])
dynamic(binding \\ [], expr)

Buids a dynamic query expression.

Dynamic query expressions allows developers to build queries expression bit by bit so they are later interpolated in a query.

Examples

For example, imagine you have a set of conditions you want to build your query on:

dynamic = false

dynamic =
  if params["is_public"] do
    dynamic([p], p.is_public or ^dynamic)
  else
    dynamic
  end

dynamic =
  if params["allow_reviewers"] do
    dynamic([p, a], a.reviewer == true or ^dynamic)
  else
    dynamic
  end

from query, where: ^dynamic

In the example above, we were able to build the query expressions bit by bit, using different bindings, and later interpolate it all at once inside the query.

A dynamic expression can always be interpolated inside another dynamic expression or at the root of a where, having, update or a join’s on.

For example, the following is forbidden because it is not at the root of a where:

from q in query, where: q.some_condition and ^dynamic

Fortunately that’s easily solvable by simply rewriting it to:

dynamic = dynamic([q], q.some_condition and ^dynamic)
from query, where: ^dynamic
from(expr, kw \\ [])

Creates a query.

It can either be a keyword query or a query expression.

If it is a keyword query the first argument must be either an in expression, or a value that implements the Ecto.Queryable protocol. If the query needs a reference to the data source in any other part of the expression, then an in must be used to create a reference variable. The second argument should be a keyword query where the keys are expression types and the values are expressions.

If it is a query expression the first argument must be a value that implements the Ecto.Queryable protocol and the second argument the expression.

Keywords example

from(c in City, select: c)

Expressions example

City |> select([c], c)

Examples

def paginate(query, page, size) do
  from query,
    limit: ^size,
    offset: ^((page-1) * size)
end

The example above does not use in because limit and offset do not require a reference to the data source. However, extending the query with a where expression would require the use of in:

def published(query) do
  from p in query, where: not(is_nil(p.published_at))
end

Notice we have created a p variable to reference the query’s original data source. This assumes that the original query only had one source. When the given query has more than one source, a variable must be given for each in the order they were bound:

def published_multi(query) do
  from [p,o] in query,
  where: not(is_nil(p.published_at)) and not(is_nil(o.published_at))
end

Note the variables p and o can be named whatever you like as they have no importance in the query sent to the database.

group_by(query, binding \\ [], expr)

A group by query expression.

Groups together rows from the schema that have the same values in the given fields. Using group_by “groups” the query giving it different semantics in the select expression. If a query is grouped, only fields that were referenced in the group_by can be used in the select or if the field is given as an argument to an aggregate function.

group_by also accepts a list of atoms where each atom refers to a field in source.

Keywords examples

# Returns the number of posts in each category
from(p in Post,
  group_by: p.category,
  select: {p.category, count(p.id)})

# Group on all fields on the Post schema
from(p in Post, group_by: p, select: p)

# Using atoms
from(p in Post, group_by: :category, select: {p.category, count(p.id)})

Expressions example

Post |> group_by([p], p.category) |> select([p], count(p.id))
having(query, binding \\ [], expr)

An AND having query expression.

Like where, having filters rows from the schema, but after the grouping is performed giving it the same semantics as select for a grouped query (see group_by/3). having groups the query even if the query has no group_by expression.

Keywords example

# Returns the number of posts in each category where the
# average number of comments is above ten
from(p in Post,
  group_by: p.category,
  having: avg(p.num_comments) > 10,
  select: {p.category, count(p.id)})

Expressions example

Post
|> group_by([p], p.category)
|> having([p], avg(p.num_comments) > 10)
|> select([p], count(p.id))
join(query, qual, binding \\ [], expr, on \\ nil)

A join query expression.

Receives a source that is to be joined to the query and a condition for the join. The join condition can be any expression that evaluates to a boolean value. The join is by default an inner join, the qualifier can be changed by giving the atoms: :inner, :left, :right, :cross or :full. For a keyword query the :join keyword can be changed to: :inner_join, :left_join, :right_join, :cross_join or :full_join.

Currently it is possible to join on:

  • an Ecto.Schema, such as p in Post
  • an Ecto query with zero or more where clauses, such as from "posts", where: [public: true]
  • an association, such as c in assoc(post, :comments)
  • a query fragment, such as c in fragment("SOME COMPLEX QUERY")
  • a subquery, such as c in subquery(another_query)

The fragment support exists mostly for handling lateral joins. See “Joining with fragments” below.

Keywords examples

from c in Comment,
  join: p in Post, on: p.id == c.post_id,
  select: {p.title, c.text}

from p in Post,
  left_join: c in assoc(p, :comments),
  select: {p, c}

Keywords can also be given or interpolated as part of on:

from c in Comment,
  join: p in Post, on: [id: c.post_id],
  select: {p.title, c.text}

Any key in on will apply to the currently joined expression.

It is also possible to interpolate an Ecto query on the right side of in. For example, the query above can also be written as:

posts = Post
from c in Comment,
  join: p in ^posts, on: [id: c.post_id],
  select: {p.title, c.text}

The above is specially useful to dynamically join on existing queries, for example, choosing between public posts or posts that have been recently published:

posts =
  if params["drafts"] do
    from p in Post, where: [drafts: true]
  else
    from p in Post, where: [public: true]
  end

from c in Comment,
  join: p in ^posts, on: [id: c.post_id],
  select: {p.title, c.text}

Only simple queries with where expressions can be interpolated in join.

Expressions examples

Comment
|> join(:inner, [c], p in Post, c.post_id == p.id)
|> select([c, p], {p.title, c.text})

Post
|> join(:left, [p], c in assoc(p, :comments))
|> select([p, c], {p, c})

Post
|> join(:left, [p], c in Comment, c.post_id == p.id and c.is_visible == true)
|> select([p, c], {p, c})

Joining with fragments

When you need to join on a complex query, Ecto supports fragments in joins:

Comment
|> join(:inner, [c], p in fragment("SOME COMPLEX QUERY", c.id, ^some_param))

Although using fragments in joins is discouraged in favor of Ecto Query syntax, they are necessary when writing lateral joins as lateral joins require a subquery that refer to previous bindings:

Game
|> join(:inner_lateral, [g], gs in fragment("SELECT * FROM games_sold AS gs WHERE gs.game_id = ? ORDER BY gs.sold_on LIMIT 2", g.id))
|> select([g, gs], {g.name, gs.sold_on})
limit(query, binding \\ [], expr)

A limit query expression.

Limits the number of rows returned from the result. Can be any expression but has to evaluate to an integer value and it can’t include any field.

If limit is given twice, it overrides the previous value.

Keywords example

from(u in User, where: u.id == ^current_user, limit: 1)

Expressions example

User |> where([u], u.id == ^current_user) |> limit(1)
lock(query, expr)

A lock query expression.

Provides support for row-level pessimistic locking using SELECT ... FOR UPDATE or other, database-specific, locking clauses. expr can be any expression but has to evaluate to a boolean value or to a string and it can’t include any fields.

If lock is used more than once, the last one used takes precedence.

Ecto also supports optimistic locking but not through queries. For more information on optimistic locking, have a look at the Ecto.Changeset.optimistic_lock/3 function

Keywords example

from(u in User, where: u.id == ^current_user, lock: "FOR SHARE NOWAIT")

Expressions example

User |> where(u.id == ^current_user) |> lock("FOR SHARE NOWAIT")
offset(query, binding \\ [], expr)

An offset query expression.

Offsets the number of rows selected from the result. Can be any expression but it must evaluate to an integer value and it can’t include any field.

If offset is given twice, it overrides the previous value.

Keywords example

# Get all posts on page 4
from(p in Post, limit: 10, offset: 30)

Expressions example

Post |> limit(10) |> offset(30)
or_having(query, binding \\ [], expr)

An OR having query expression.

Like having but combines with the previous expression by using OR. or_having behaves for having the same way or_where behaves for where.

Keywords example

# Augment a previous group_by with a having condition.
from(p in query, or_having: avg(p.num_comments) > 10)

Expressions example

# Augment a previous group_by with a having condition.
Post |> or_having([p], avg(p.num_comments) > 10)
or_where(query, binding \\ [], expr)

An OR where query expression.

Behaves exactly the same as where except it combines with any previous expression by using an OR. All expressions have to evaluate to a boolean value.

or_where also accepts a keyword list where each key is a field to be compared with the given value. Each key-value pair will be combined using AND, exactly as in where.

Keywords example

from(c in City, where: [country: "Sweden"], or_where: [country: "Brazil"])

If interpolating keyword lists, the keyword list entries are combined using ANDs and joined to any existing expression with an OR:

filters = [country: "USA", name: "New York"]
from(c in City, where: [country: "Sweden"], or_where: ^filters)

is equivalent to:

from c in City, where: (c.country == "Sweden") or
                       (c.country == "USA" and c.name == "New York")

The behaviour above is by design to keep the changes between where and or_where minimal. Plus, if you have a keyword list and you would like each pair to be combined using or, it can be easily done with Enum.reduce/3:

filters = [country: "USA", is_tax_exempt: true]
Enum.reduce(filters, City, fn {key, value}, query ->
  from q in query, or_where: field(q, ^key) == ^value
end)

which will be equivalent to:

from c in City, or_where: (c.country == "USA"), or_where: c.is_tax_exempt == true

Expressions example

City |> where([c], c.country == "Sweden") |> or_where([c], c.country == "Brazil")
order_by(query, binding \\ [], expr)

An order by query expression.

Orders the fields based on one or more fields. It accepts a single field or a list of fields. The default direction is ascending (:asc) and can be customized in a keyword list as shown in the examples. There can be several order by expressions in a query.

order_by also accepts a list of atoms where each atom refers to a field in source or a keyword list where the direction is given as key and the field to order as value.

Keywords examples

from(c in City, order_by: c.name, order_by: c.population)
from(c in City, order_by: [c.name, c.population])
from(c in City, order_by: [asc: c.name, desc: c.population])

from(c in City, order_by: [:name, :population])
from(c in City, order_by: [asc: :name, desc: :population])

A keyword list can also be interpolated:

values = [asc: :name, desc: :population]
from(c in City, order_by: ^values)

Expressions example

City |> order_by([c], asc: c.name, desc: c.population)
City |> order_by(asc: :name) # Sorts by the cities name
preload(query, bindings \\ [], expr)

Preloads the associations into the given struct.

Preloading allows developers to specify associations that are preloaded into the struct. Consider this example:

Repo.all from p in Post, preload: [:comments]

The example above will fetch all posts from the database and then do a separate query returning all comments associated with the given posts.

However, often times, you want posts and comments to be selected and filtered in the same query. For such cases, you can explicitly tell the association to be preloaded into the struct:

Repo.all from p in Post,
           join: c in assoc(p, :comments),
           where: c.published_at > p.updated_at,
           preload: [comments: c]

In the example above, instead of issuing a separate query to fetch comments, Ecto will fetch posts and comments in a single query.

Nested associations can also be preloaded in both formats:

Repo.all from p in Post,
           preload: [comments: :likes]

Repo.all from p in Post,
           join: c in assoc(p, :comments),
           join: l in assoc(c, :likes),
           where: l.inserted_at > c.updated_at,
           preload: [comments: {c, likes: l}]

Keep in mind neither format can be nested arbitrarily. For example, the query below is invalid because we cannot preload likes with the join association c.

Repo.all from p in Post,
           join: c in assoc(p, :comments),
           preload: [comments: {c, :likes}]

Preload queries

Preload also allows queries to be given, allowing you to filter or customize how the preloads are fetched:

comments_query = from c in Comment, order_by: c.published_at
Repo.all from p in Post, preload: [comments: ^comments_query]

The example above will issue two queries, one for loading posts and then another for loading the comments associated with the posts. Comments will be ordered by published_at.

Note: keep in mind operations like limit and offset in the preload query will affect the whole result set and not each association. For example, the query below:

comments_query = from c in Comment, order_by: c.popularity, limit: 5
Repo.all from p in Post, preload: [comments: ^comments_query]

won’t bring the top of comments per post. Rather, it will only bring the 5 top comments across all posts.

Preload functions

Preload also allows functions to be given. In such cases, the function receives the IDs to be fetched and it must return the associated data. This data will then be mapped and sorted:

Repo.all from p in Post, preload: [comments: fn _ -> previously_loaded_comments end]

This is useful when the whole dataset was already loaded or must be explicitly fetched from elsewhere.

Keywords example

# Returns all posts, their associated comments, and the associated
# likes for those comments.
from(p in Post,
  preload: [:comments, comments: :likes],
  select: p)

Expressions examples

Post |> preload(:comments) |> select([p], p)
Post |> join(:left, [p], c in assoc(p, :comments)) |> preload([p, c], [:user, comments: c]) |> select([p], p)
select(query, binding \\ [], expr)

A select query expression.

Selects which fields will be selected from the schema and any transformations that should be performed on the fields. Any expression that is accepted in a query can be a select field.

The sub-expressions in the query can be wrapped in lists, tuples or maps as shown in the examples. A full schema can also be selected.

There can only be one select expression in a query, if the select expression is omitted, the query will by default select the full schema.

select also accepts a list of atoms where each atom refers to a field in the source to be selected.

Keywords examples

from(c in City, select: c) # returns the schema as a struct
from(c in City, select: {c.name, c.population})
from(c in City, select: [c.name, c.county])
from(c in City, select: {c.name, ^to_string(40 + 2), 43})
from(c in City, select: %{n: c.name, answer: 42})

It is also possible to select a struct and limit the returned fields at the same time:

from(City, select: [:name])

The syntax above is equivalent to:

from(city in City, select: struct(city, [:name]))

You can also write:

from(city in City, select: map(city, [:name]))

If you want a map with only the selected fields to be returned. For more information, read the docs for Ecto.Query.API.struct/2 and Ecto.Query.API.map/2.

Expressions examples

City |> select([c], c)
City |> select([c], {c.name, c.country})
City |> select([c], %{"name" => c.name})
City |> select([:name])
City |> select([c], struct(c, [:name]))
City |> select([c], map(c, [:name]))
update(query, binding \\ [], expr)

An update query expression.

Updates are used to update the filtered entries. In order for updates to be applied, Ecto.Repo.update_all/3 must be invoked.

Keywords example

from(u in User, update: [set: [name: "new name"]])

Expressions example

User |> update([u], set: [name: "new name"])
User |> update(set: [name: "new name"])

Operators

The update expression in Ecto supports the following operators:

  • set - sets the given field in the table to the given value

    from(u in User, update: [set: [name: "new name"]])
  • inc - increments (or decrements if the value is negative) the given field in the table by the given value

    from(u in User, update: [inc: [accesses: 1]])
  • push - pushes (appends) the given value to the end of the array field

    from(u in User, update: [push: [tags: "cool"]])
  • pull - pulls (removes) the given value from the array field

    from(u in User, update: [pull: [tags: "not cool"]])
where(query, binding \\ [], expr)

An AND where query expression.

where expressions are used to filter the result set. If there is more than one where expression, they are combined with an and operator. All where expressions have to evaluate to a boolean value.

where also accepts a keyword list where the field given as key is going to be compared with the given value. The fields will always refer to the source given in from.

Keywords example

from(c in City, where: c.country == "Sweden")
from(c in City, where: [country: "Sweden"])

It is also possible to interpolate the whole keyword list, allowing you to dynamically filter the source:

filters = [country: "Sweden"]
from(c in City, where: ^filters)

Expressions example

City |> where([c], c.country == "Sweden")
City |> where(country: "Sweden")