Examples
Traversal
For the purpose of the example, we'll generate the following graph:
The first step is to generate the 3 schemas: Pet
, User
, Group
.
ent init Pet User Group
Add the necessary fields and edges for the schemas:
ent/schema/pet.go
// Pet holds the schema definition for the Pet entity.
type Pet struct {
ent.Schema
}
// Fields of the Pet.
func (Pet) Fields() []ent.Field {
return []ent.Field{
field.String("name"),
}
}
// Edges of the Pet.
func (Pet) Edges() []ent.Edge {
return []ent.Edge{
edge.To("friends", Pet.Type),
edge.From("owner", User.Type).
Ref("pets").
Unique(),
}
}
ent/schema/user.go
// User holds the schema definition for the User entity.
type User struct {
ent.Schema
}
// Fields of the User.
func (User) Fields() []ent.Field {
return []ent.Field{
field.Int("age"),
field.String("name"),
}
}
// Edges of the User.
func (User) Edges() []ent.Edge {
return []ent.Edge{
edge.To("pets", Pet.Type),
edge.To("friends", User.Type),
edge.From("groups", Group.Type).
Ref("users"),
}
}
ent/schema/group.go
// Group holds the schema definition for the Group entity.
type Group struct {
ent.Schema
}
// Fields of the Group.
func (Group) Fields() []ent.Field {
return []ent.Field{
field.String("name"),
}
}
// Edges of the Group.
func (Group) Edges() []ent.Edge {
return []ent.Edge{
edge.To("users", User.Type),
edge.To("admin", User.Type).
Unique(),
}
}
Let's write the code for populating the vertices and the edges to the graph:
func Gen(ctx context.Context, client *ent.Client) error {
hub, err := client.Group.
Create().
SetName("Github").
Save(ctx)
if err != nil {
return fmt.Errorf("failed creating the group: %v", err)
}
// Create the admin of the group.
// Unlike `Save`, `SaveX` panics if an error occurs.
dan := client.User.
Create().
SetAge(29).
SetName("Dan").
AddManage(hub).
SaveX(ctx)
// Create "Ariel" and its pets.
a8m := client.User.
Create().
SetAge(30).
SetName("Ariel").
AddGroups(hub).
AddFriends(dan).
SaveX(ctx)
pedro := client.Pet.
Create().
SetName("Pedro").
SetOwner(a8m).
SaveX(ctx)
xabi := client.Pet.
Create().
SetName("Xabi").
SetOwner(a8m).
SaveX(ctx)
// Create "Alex" and its pets.
alex := client.User.
Create().
SetAge(37).
SetName("Alex").
SaveX(ctx)
coco := client.Pet.
Create().
SetName("Coco").
SetOwner(alex).
AddFriends(pedro).
SaveX(ctx)
fmt.Println("Pets created:", pedro, xabi, coco)
// Output:
// Pets created: Pet(id=1, name=Pedro) Pet(id=2, name=Xabi) Pet(id=3, name=Coco)
return nil
}
Let's go over a few traversals, and show the code for them:
The traversal above starts from a Group
entity, continues to its admin
(edge),
continues to its friends
(edge), gets their pets
(edge), gets each pet's friends
(edge),
and requests their owners.
func Traverse(ctx context.Context, client *ent.Client) error {
owner, err := client.Group. // GroupClient.
Query(). // Query builder.
Where(group.Name("Github")). // Filter only Github group (only 1).
QueryAdmin(). // Getting Dan.
QueryFriends(). // Getting Dan's friends: [Ariel].
QueryPets(). // Their pets: [Pedro, Xabi].
QueryFriends(). // Pedro's friends: [Coco], Xabi's friends: [].
QueryOwner(). // Coco's owner: Alex.
Only(ctx) // Expect only one entity to return in the query.
if err != nil {
return fmt.Errorf("failed querying the owner: %v", err)
}
fmt.Println(owner)
// Output:
// User(id=3, age=37, name=Alex)
return nil
}
What about the following traversal?
We want to get all pets (entities) that have an owner
(edge
) that is a friend
(edge) of some group admin
(edge).
func Traverse(ctx context.Context, client *ent.Client) error {
pets, err := client.Pet.
Query().
Where(
pet.HasOwnerWith(
user.HasFriendsWith(
user.HasManage(),
),
),
).
All(ctx)
if err != nil {
return fmt.Errorf("failed querying the pets: %v", err)
}
fmt.Println(pets)
// Output:
// [Pet(id=1, name=Pedro) Pet(id=2, name=Xabi)]
return nil
}
The full example exists in GitHub.
Relationship
O2O Two Types
In this example, a user has only one credit-card, and a card has only one owner.
The User
schema defines an edge.To
card named card
, and the Card
schema
defines a back-reference to this edge using edge.From
named owner
.
ent/schema/user.go
// Edges of the user.
func (User) Edges() []ent.Edge {
return []ent.Edge{
edge.To("card", Card.Type).
Unique(),
}
}
ent/schema/card.go
// Edges of the user.
func (Card) Edges() []ent.Edge {
return []ent.Edge{
edge.From("owner", User.Type).
Ref("card").
Unique().
// We add the "Required" method to the builder
// to make this edge required on entity creation.
// i.e. Card cannot be created without its owner.
Required(),
}
}
The API for interacting with these edges is as follows:
func Do(ctx context.Context, client *ent.Client) error {
a8m, err := client.User.
Create().
SetAge(30).
SetName("Mashraki").
Save(ctx)
if err != nil {
return fmt.Errorf("creating user: %v", err)
}
log.Println("user:", a8m)
card1, err := client.Card.
Create().
SetOwner(a8m).
SetNumber("1020").
SetExpired(time.Now().Add(time.Minute)).
Save(ctx)
if err != nil {
return fmt.Errorf("creating card: %v", err)
}
log.Println("card:", card1)
// Only returns the card of the user,
// and expects that there's only one.
card2, err := a8m.QueryCard().Only(ctx)
if err != nil {
return fmt.Errorf("querying card: %v", err)
}
log.Println("card:", card2)
// The Card entity is able to query its owner using
// its back-reference.
owner, err := card2.QueryOwner().Only(ctx)
if err != nil {
return fmt.Errorf("querying owner: %v", err)
}
log.Println("owner:", owner)
return nil
}
The full example exists in GitHub.
O2O Same Type
In this linked-list example, we have a recursive relation named next
/prev
. Each node in the list can
have only one next
node. If a node A points (using next
) to node B, B can get its pointer using prev
(the back-reference edge).
ent/schema/node.go
// Edges of the Node.
func (Node) Edges() []ent.Edge {
return []ent.Edge{
edge.To("next", Node.Type).
Unique().
From("prev").
Unique(),
}
}
As you can see, in cases of relations of the same type, you can declare the edge and its
reference in the same builder.
func (Node) Edges() []ent.Edge {
return []ent.Edge{
+ edge.To("next", Node.Type).
+ Unique().
+ From("prev").
+ Unique(),
- edge.To("next", Node.Type).
- Unique(),
- edge.From("prev", Node.Type).
- Ref("next).
- Unique(),
}
}
The API for interacting with these edges is as follows:
func Do(ctx context.Context, client *ent.Client) error {
head, err := client.Node.
Create().
SetValue(1).
Save(ctx)
if err != nil {
return fmt.Errorf("creating the head: %v", err)
}
curr := head
// Generate the following linked-list: 1<->2<->3<->4<->5.
for i := 0; i < 4; i++ {
curr, err = client.Node.
Create().
SetValue(curr.Value + 1).
SetPrev(curr).
Save(ctx)
if err != nil {
return err
}
}
// Loop over the list and print it. `FirstX` panics if an error occur.
for curr = head; curr != nil; curr = curr.QueryNext().FirstX(ctx) {
fmt.Printf("%d ", curr.Value)
}
// Output: 1 2 3 4 5
// Make the linked-list circular:
// The tail of the list, has no "next".
tail, err := client.Node.
Query().
Where(node.Not(node.HasNext())).
Only(ctx)
if err != nil {
return fmt.Errorf("getting the tail of the list: %v", tail)
}
tail, err = tail.Update().SetNext(head).Save(ctx)
if err != nil {
return err
}
// Check that the change actually applied:
prev, err := head.QueryPrev().Only(ctx)
if err != nil {
return fmt.Errorf("getting head's prev: %v", err)
}
fmt.Printf("\n%v", prev.Value == tail.Value)
// Output: true
return nil
}
The full example exists in GitHub.
O2O Bidirectional
In this user-spouse example, we have a symmetric O2O relation named spouse
. Each user can have only one spouse.
If user A sets its spouse (using spouse
) to B, B can get its spouse using the spouse
edge.
Note that there are no owner/inverse terms in cases of bidirectional edges.
ent/schema/user.go
// Edges of the User.
func (User) Edges() []ent.Edge {
return []ent.Edge{
edge.To("spouse", User.Type).
Unique(),
}
}
The API for interacting with this edge is as follows:
func Do(ctx context.Context, client *ent.Client) error {
a8m, err := client.User.
Create().
SetAge(30).
SetName("a8m").
Save(ctx)
if err != nil {
return fmt.Errorf("creating user: %v", err)
}
nati, err := client.User.
Create().
SetAge(28).
SetName("nati").
SetSpouse(a8m).
Save(ctx)
if err != nil {
return fmt.Errorf("creating user: %v", err)
}
// Query the spouse edge.
// Unlike `Only`, `OnlyX` panics if an error occurs.
spouse := nati.QuerySpouse().OnlyX(ctx)
fmt.Println(spouse.Name)
// Output: a8m
spouse = a8m.QuerySpouse().OnlyX(ctx)
fmt.Println(spouse.Name)
// Output: nati
// Query how many users have a spouse.
// Unlike `Count`, `CountX` panics if an error occurs.
count := client.User.
Query().
Where(user.HasSpouse()).
CountX(ctx)
fmt.Println(count)
// Output: 2
// Get the user, that has a spouse with name="a8m".
spouse = client.User.
Query().
Where(user.HasSpouseWith(user.Name("a8m"))).
OnlyX(ctx)
fmt.Println(spouse.Name)
// Output: nati
return nil
}
The full example exists in GitHub.
O2M Two Types
In this user-pets example, we have a O2M relation between user and its pets.
Each user has many pets, and a pet has one owner.
If user A adds a pet B using the pets
edge, B can get its owner using the owner
edge (the back-reference edge).
Note that this relation is also a M2O (many-to-one) from the point of view of the Pet
schema.
ent/schema/user.go
// Edges of the User.
func (User) Edges() []ent.Edge {
return []ent.Edge{
edge.To("pets", Pet.Type),
}
}
ent/schema/pet.go
// Edges of the Pet.
func (Pet) Edges() []ent.Edge {
return []ent.Edge{
edge.From("owner", User.Type).
Ref("pets").
Unique(),
}
}
The API for interacting with these edges is as follows:
func Do(ctx context.Context, client *ent.Client) error {
// Create the 2 pets.
pedro, err := client.Pet.
Create().
SetName("pedro").
Save(ctx)
if err != nil {
return fmt.Errorf("creating pet: %v", err)
}
lola, err := client.Pet.
Create().
SetName("lola").
Save(ctx)
if err != nil {
return fmt.Errorf("creating pet: %v", err)
}
// Create the user, and add its pets on the creation.
a8m, err := client.User.
Create().
SetAge(30).
SetName("a8m").
AddPets(pedro, lola).
Save(ctx)
if err != nil {
return fmt.Errorf("creating user: %v", err)
}
fmt.Println("User created:", a8m)
// Output: User(id=1, age=30, name=a8m)
// Query the owner. Unlike `Only`, `OnlyX` panics if an error occurs.
owner := pedro.QueryOwner().OnlyX(ctx)
fmt.Println(owner.Name)
// Output: a8m
// Traverse the sub-graph. Unlike `Count`, `CountX` panics if an error occurs.
count := pedro.
QueryOwner(). // a8m
QueryPets(). // pedro, lola
CountX(ctx) // count
fmt.Println(count)
// Output: 2
return nil
}
The full example exists in GitHub.
O2M Same Type
In this example, we have a recursive O2M relation between tree's nodes and their children (or their parent).
Each node in the tree has many children, and has one parent. If node A adds B to its children,
B can get its owner using the owner
edge.
ent/schema/node.go
// Edges of the Node.
func (Node) Edges() []ent.Edge {
return []ent.Edge{
edge.To("children", Node.Type).
From("parent").
Unique(),
}
}
As you can see, in cases of relations of the same type, you can declare the edge and its
reference in the same builder.
func (Node) Edges() []ent.Edge {
return []ent.Edge{
+ edge.To("children", Node.Type).
+ From("parent").
+ Unique(),
- edge.To("children", Node.Type),
- edge.From("parent", Node.Type).
- Ref("children").
- Unique(),
}
}
The API for interacting with these edges is as follows:
func Do(ctx context.Context, client *ent.Client) error {
root, err := client.Node.
Create().
SetValue(2).
Save(ctx)
if err != nil {
return fmt.Errorf("creating the root: %v", err)
}
// Add additional nodes to the tree:
//
// 2
// / \
// 1 4
// / \
// 3 5
//
// Unlike `Save`, `SaveX` panics if an error occurs.
n1 := client.Node.
Create().
SetValue(1).
SetParent(root).
SaveX(ctx)
n4 := client.Node.
Create().
SetValue(4).
SetParent(root).
SaveX(ctx)
n3 := client.Node.
Create().
SetValue(3).
SetParent(n4).
SaveX(ctx)
n5 := client.Node.
Create().
SetValue(5).
SetParent(n4).
SaveX(ctx)
fmt.Println("Tree leafs", []int{n1.Value, n3.Value, n5.Value})
// Output: Tree leafs [1 3 5]
// Get all leafs (nodes without children).
// Unlike `Int`, `IntX` panics if an error occurs.
ints := client.Node.
Query(). // All nodes.
Where(node.Not(node.HasChildren())). // Only leafs.
Order(ent.Asc(node.FieldValue)). // Order by their `value` field.
GroupBy(node.FieldValue). // Extract only the `value` field.
IntsX(ctx)
fmt.Println(ints)
// Output: [1 3 5]
// Get orphan nodes (nodes without parent).
// Unlike `Only`, `OnlyX` panics if an error occurs.
orphan := client.Node.
Query().
Where(node.Not(node.HasParent())).
OnlyX(ctx)
fmt.Println(orphan)
// Output: Node(id=1, value=2)
return nil
}
The full example exists in GitHub.
M2M Two Types
In this groups-users example, we have a M2M relation between groups and their users.
Each group has many users, and each user can be joined to many groups.
ent/schema/group.go
// Edges of the Group.
func (Group) Edges() []ent.Edge {
return []ent.Edge{
edge.To("users", User.Type),
}
}
ent/schema/user.go
// Edges of the User.
func (User) Edges() []ent.Edge {
return []ent.Edge{
edge.From("groups", Group.Type).
Ref("users"),
}
}
The API for interacting with these edges is as follows:
func Do(ctx context.Context, client *ent.Client) error {
// Unlike `Save`, `SaveX` panics if an error occurs.
hub := client.Group.
Create().
SetName("GitHub").
SaveX(ctx)
lab := client.Group.
Create().
SetName("GitLab").
SaveX(ctx)
a8m := client.User.
Create().
SetAge(30).
SetName("a8m").
AddGroups(hub, lab).
SaveX(ctx)
nati := client.User.
Create().
SetAge(28).
SetName("nati").
AddGroups(hub).
SaveX(ctx)
// Query the edges.
groups, err := a8m.
QueryGroups().
All(ctx)
if err != nil {
return fmt.Errorf("querying a8m groups: %v", err)
}
fmt.Println(groups)
// Output: [Group(id=1, name=GitHub) Group(id=2, name=GitLab)]
groups, err = nati.
QueryGroups().
All(ctx)
if err != nil {
return fmt.Errorf("querying nati groups: %v", err)
}
fmt.Println(groups)
// Output: [Group(id=1, name=GitHub)]
// Traverse the graph.
users, err := a8m.
QueryGroups(). // [hub, lab]
Where(group.Not(group.HasUsersWith(user.Name("nati")))). // [lab]
QueryUsers(). // [a8m]
QueryGroups(). // [hub, lab]
QueryUsers(). // [a8m, nati]
All(ctx)
if err != nil {
return fmt.Errorf("traversing the graph: %v", err)
}
fmt.Println(users)
// Output: [User(id=1, age=30, name=a8m) User(id=2, age=28, name=nati)]
return nil
}
The full example exists in GitHub.
M2M Same Type
In this following-followers example, we have a M2M relation between users to their followers. Each user
can follow many users, and can have many followers.
ent/schema/user.go
// Edges of the User.
func (User) Edges() []ent.Edge {
return []ent.Edge{
edge.To("following", User.Type).
From("followers"),
}
}
As you can see, in cases of relations of the same type, you can declare the edge and its
reference in the same builder.
func (User) Edges() []ent.Edge {
return []ent.Edge{
+ edge.To("following", User.Type).
+ From("followers"),
- edge.To("following", User.Type),
- edge.From("followers", User.Type).
- Ref("following"),
}
}
The API for interacting with these edges is as follows:
func Do(ctx context.Context, client *ent.Client) error {
// Unlike `Save`, `SaveX` panics if an error occurs.
a8m := client.User.
Create().
SetAge(30).
SetName("a8m").
SaveX(ctx)
nati := client.User.
Create().
SetAge(28).
SetName("nati").
AddFollowers(a8m).
SaveX(ctx)
// Query following/followers:
flw := a8m.QueryFollowing().AllX(ctx)
fmt.Println(flw)
// Output: [User(id=2, age=28, name=nati)]
flr := a8m.QueryFollowers().AllX(ctx)
fmt.Println(flr)
// Output: []
flw = nati.QueryFollowing().AllX(ctx)
fmt.Println(flw)
// Output: []
flr = nati.QueryFollowers().AllX(ctx)
fmt.Println(flr)
// Output: [User(id=1, age=30, name=a8m)]
// Traverse the graph:
ages := nati.
QueryFollowers(). // [a8m]
QueryFollowing(). // [nati]
GroupBy(user.FieldAge). // [28]
IntsX(ctx)
fmt.Println(ages)
// Output: [28]
names := client.User.
Query().
Where(user.Not(user.HasFollowers())).
GroupBy(user.FieldName).
StringsX(ctx)
fmt.Println(names)
// Output: [a8m]
return nil
}
The full example exists in GitHub.
M2M Bidirectional
In this user-friends example, we have a symmetric M2M relation named friends
.
Each user can have many friends. If user A becomes a friend of B, B is also a friend of A.
Note that there are no owner/inverse terms in cases of bidirectional edges.
ent/schema/user.go
// Edges of the User.
func (User) Edges() []ent.Edge {
return []ent.Edge{
edge.To("friends", User.Type),
}
}
The API for interacting with these edges is as follows:
func Do(ctx context.Context, client *ent.Client) error {
// Unlike `Save`, `SaveX` panics if an error occurs.
a8m := client.User.
Create().
SetAge(30).
SetName("a8m").
SaveX(ctx)
nati := client.User.
Create().
SetAge(28).
SetName("nati").
AddFriends(a8m).
SaveX(ctx)
// Query friends. Unlike `All`, `AllX` panics if an error occurs.
friends := nati.
QueryFriends().
AllX(ctx)
fmt.Println(friends)
// Output: [User(id=1, age=30, name=a8m)]
friends = a8m.
QueryFriends().
AllX(ctx)
fmt.Println(friends)
// Output: [User(id=2, age=28, name=nati)]
// Query the graph:
friends = client.User.
Query().
Where(user.HasFriends()).
AllX(ctx)
fmt.Println(friends)
// Output: [User(id=1, age=30, name=a8m) User(id=2, age=28, name=nati)]
return nil
}
The full example exists in GitHub.
Indexes
Index On Edges
Indexes can be configured on composition of fields and edges. The main use-case
is setting uniqueness on fields under a specific relation. Let's take an example:
In the example above, we have a City
with many Street
s, and we want to set the
street name to be unique under each city.
ent/schema/city.go
// City holds the schema definition for the City entity.
type City struct {
ent.Schema
}
// Fields of the City.
func (City) Fields() []ent.Field {
return []ent.Field{
field.String("name"),
}
}
// Edges of the City.
func (City) Edges() []ent.Edge {
return []ent.Edge{
edge.To("streets", Street.Type),
}
}
ent/schema/street.go
// Street holds the schema definition for the Street entity.
type Street struct {
ent.Schema
}
// Fields of the Street.
func (Street) Fields() []ent.Field {
return []ent.Field{
field.String("name"),
}
}
// Edges of the Street.
func (Street) Edges() []ent.Edge {
return []ent.Edge{
edge.From("city", City.Type).
Ref("streets").
Unique(),
}
}
// Indexes of the Street.
func (Street) Indexes() []ent.Index {
return []ent.Index{
index.Fields("name").
Edges("city").
Unique(),
}
}
example.go
func Do(ctx context.Context, client *ent.Client) error {
// Unlike `Save`, `SaveX` panics if an error occurs.
tlv := client.City.
Create().
SetName("TLV").
SaveX(ctx)
nyc := client.City.
Create().
SetName("NYC").
SaveX(ctx)
// Add a street "ST" to "TLV".
client.Street.
Create().
SetName("ST").
SetCity(tlv).
SaveX(ctx)
// This operation will fail because "ST"
// is already created under "TLV".
_, err := client.Street.
Create().
SetName("ST").
SetCity(tlv).
Save(ctx)
if err == nil {
return fmt.Errorf("expecting creation to fail")
}
// Add a street "ST" to "NYC".
client.Street.
Create().
SetName("ST").
SetCity(nyc).
SaveX(ctx)
return nil
}
The full example exists in GitHub.