Datamodel (PostgreSQL)
Overview
The datamodel of your service configuration has two major roles:
- Define the underlying database schema (the models and fields are mapped to database tables).
- It is the foundation for the auto-generated CRUD operations of your Prisma client.
The datamodel is written using a subset of the GraphQL Schema Definition Language (SDL) and stored in one or more .prisma
-files. These .prisma
-files need to be referenced in your prisma.yml
under the datamodel
property. For example:
endpoint: __YOUR_PRISMA_ENDPOINT__ datamodel: datamodel.prisma
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Building blocks of the datamodel
There are several available building blocks to shape your datamodel:
- Types consist of multiple fields and typically represent entities from your application domain (e.g.
User
,Car
,Order
). Each type in your datamodel is mapped to a database table and CRUD operations are exposed in the generated Prisma client API. - Relations describe relationships between types.
- Directives covering different use cases such as type constraints or cascading delete behaviour.
Example
A simple example datamodel.prisma
file:
type Tweet {
id: ID! @id
createdAt: DateTime! @createdAt
text: String!
owner: User! @relation(link: INLINE)
location: Location!
}
type User {
id: ID! @id
createdAt: DateTime! @createdAt
updatedAt: DateTime! @updatedAt
handle: String! @unique
name: String
tweets: [Tweet!]!
}
type Location {
id: ID! @id
latitude: Float!
longitude: Float!
}
This example illustrates a few important concepts when working with your datamodel:
- The three types
Tweet
,User
andLocation
are mapped to database tables. - There is a bidirectional relation between
User
andTweet
(via theowner
andtweets
fields). The relation is represented via a foreign key on theTweet
type. - There is a unidirectional relation from
Tweet
toLocation
(via thelocation
field). - Except for the
name
field onUser
, all fields are required in the datamodel (as indicated by the!
following the type). - The fields annotated with the
@id
,@createdAt
and@updatedAt
directives are managed by Prisma and read-only in the exposed Prisma API. - The
@unique
directive expresses a unique constraint, meaning Prisma ensures that there never will be two records with the same values for the annotated field.
Creating and updating your datamodel is as simple as writing and saving the datamodel file. Once you're happy with your datamodel, you can save the file and apply the changes to your Prisma service by running prisma1 deploy
:
$ prisma1 deploy
Changes:
Tweet (Type)
+ Created type `Tweet`
+ Created field `id` of type `ID!`
+ Created field `createdAt` of type `DateTime!`
+ Created field `text` of type `String!`
+ Created field `owner` of type `User!`
+ Created field `location` of type `Location!`
User (Type)
+ Created type `User`
+ Created field `id` of type `ID!`
+ Created field `createdAt` of type `DateTime!`
+ Created field `updatedAt` of type `DateTime!`
+ Created field `handle` of type `String!`
+ Created field `name` of type `String`
+ Created field `tweets` of type `[Tweet!]!`
Location (Type)
+ Created type `Location`
+ Created field `id` of type `ID!`
+ Created field `latitude` of type `Float!`
+ Created field `longitude` of type `Float!`
TweetToUser (Relation)
+ Created an inline relation between `Tweet` and `User` in the column `owner` of table `Tweet`
LocationToTweet (Relation)
+ Created an inline relation between `Location` and `Tweet` in the column `location` of table `Tweet`
Applying changes 1.1s
Files
You can write your datamodel in a single .prisma
-file or split it accross multiple ones.
The .prisma
-files containing the datamodel need to be referenced in your prisma.yml
under the datamodel
property. For example:
datamodel:
- user.prisma
- order.prisma
If there is only a single file that defines the datamodel, it can be specified as follows:
datamodel: datamodel.prisma
Object types
An object type (or short type) defines the structure for one model in your datamodel. It is used to represent entities from your application domain.
Each object type is mapped to the database. For relational databases, one table is created per type. For schemaless databases, an equivalent structure is used (e.g. a document). Note that Prisma enforces a schema even for schemaless databases!
A type has a name and one or multiple fields. Type names can only contain alphanumeric characters and need to start with an uppercase letter. They can contain at most 64 characters.
An instantiation of a type is called a node. This term refers to a node inside your data graph.
Defining an object type
A object type is defined in the datamodel with the keyword type
:
type Article {
id: ID! @id
title: String!
text: String
isPublished: Boolean! @default(value: false)
}
The type defined above has the following properties:
- Name:
Article
- Fields:
id
,title
,text
andisPublished
(with the default valuefalse
)
id
and title
and isPublished
are required (non-nullable) as indicated by the !
following the type, text
is nullable.
Generated API operations for types
The types in your datamodel affect the available operations in the Prisma API. Here is an overview of the generated CRUD and realtime operations for every type in your Prisma API:
- Queries let you fetch one or many nodes of that type
- Mutations let you create, update or delete nodes of that type
- Subscriptions let you get notified of changes to nodes of that type (i.e. new nodes are created or existing nodes are updated or deleted)
Fields
Fields are the building blocks of a type, giving a node its shape. Every field is referenced by its name and is either scalar or a relation field.
Field names can only contain alphanumeric characters and need to start with a lowercase letter. They can contain at most 64 characters.
Scalar fields
String
A String
holds text. This is the type you would use for a username, the content of a blog post or anything else that is best represented as text.
String values are currently limited to 256KB in size on Demo servers. This limit can be increased on other clusters using the cluster configuration.
Here is an example of a String
scalar definition:
type User {
name: String
}
Integer
An Int
is a number that cannot have decimals. Use this to store values such as the weight of an ingredient required for a recipe or the minimum age for an event.
Int
values range from -2147483648 to 2147483647.
Here is an example of an Int
scalar definition:
type User {
age: Int
}
Float
A Float
is a number that can have decimals. Use this to store values such as the price of an item in a store or the result of complex calculations.
In queries or mutations, Float
fields have to be specified without any enclosing characters and an optional decimal point: float: 42
, float: 4.2
.
Here is an example of a Float
scalar definition:
type Item {
price: Float
}
Boolean
A Boolean
can have the value true
or false
. This is useful to keep track of settings such as whether the user wants to receive an email newsletter or if a recipe is appropriate for vegetarians.
Here is an example of a Boolean
scalar definition:
type User {
overEighteen: Boolean
}
DateTime
The DateTime
type can be used to store date and/or time values. A good example might be a person's date of birth or the time/data when a specific event is happening.
Here is an example of a DateTime
scalar definition:
type User {
birthday: DateTime
}
When used as arguments in an operation, DateTime
fields have to be specified in ISO 8601 format and are typically passed as strings, here are a few examples:
"2015"
"2015-11"
"2015-11-22"
"2015-11-22T13:57:31.123Z"
.
Enum
Like a Boolean
an Enum can have one of a predefined set of values. The difference is that you can define the possible values (whereas for a Boolean
the options are restriced to true
and false
). For example you could specify how an article should be formatted by creating an Enum with the possible values COMPACT
, WIDE
and COVER
.
Enum values can only contain alphanumeric characters and underscores and need to start with an uppercase letter. The name of an enum value can be used in query filters and mutations. They can contain at most 191 characters.
Here is an example of an enum definition:
enum ArticleFormat {
COMPACT
WIDE
COVER
}
type Article {
format: ArticleFormat
}
Json
Sometimes you might need to store arbitrary JSON values for loosely structured data. The Json
type makes sure that it is actually valid JSON and returns the value as a parsed JSON object/array instead of a string.
Json values are currently limited to 256KB in size.
Here is an example of a Json
definition:
type Item {
data: Json
}
ID
An ID
value is a generated unique 25-character string based on cuid.
Fields of type ID
that are annotated with the @id
directive are system fields and maintained by Prisma. Only one ID
field per model can be annotated with @id
:
type User {
id: ID! @id
}
Type modifiers
In a field definition, a type can be annotated with a type modifier. SDL supports two type modifiers:
- Lists: Annotate the type with a pair of enclosing
[]
, e.g.friends: [User]
- Required fields: Annotate the type with a
!
, e.g.name: String!
List
Scalar fields can be marked with the list field type. A field of a relation that has the many multiplicity will also be marked as a list.
You will often find list definitions looking similar to this:
type Article {
tags: [String!]!
}
Notice the two !
type modifiers, here is what they express:
- The first
!
type modifier (right afterString
) means that no item in the list can benull
, e.g. this value fortags
would not be valid:["Software", null, "Prisma"]
- The second
!
type modifier (after the closing square bracket) means that the list itself can never benull
, it might be empty though. Consequently,null
is not a valid value for thetags
field but[]
is.
Required
Fields can be marked as required (also referred to as "non-nullable"). Required fields are marked using a !
after the field's type:
type User {
name: String!
}
Field constraints
Fields can be configured with field constraints to add further semantics and enforce certain rules in your datamodel.
Unique
Setting the unique constraint makes sure that two records of the model in question cannot have the same value for a certain field. The only exception is the null
value, meaning that multiple records can have the value null
without violating the constraint. Unique fields have a unique index applied in the underlying database.
A typical example would be an email
field on a User
models where the assumption is that every User
should have a globally unique email address.
Only the first 191 characters in a String field are considered for uniqueness and the unique check is case insensitive. Storing two different strings is not possible if the first 191 characters are the same or if they only differ in casing.
To mark a field as unique, simply append the @unique
directive to its definition:
type User {
id: ID! @id
email: String! @unique
name: String!
}
For every field that's annotated with @unique
, you're able to query the corresponding record by providing a value for that field as a query argument.
For example, considering the above datamodel, you can now retrieve a particular User
node by its email
address:
const user = await prisma.user({ email: 'alice@prisma.io', })
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More constraints
More database constraints will be added soon. Please join the discussion in this feature request if you have wish to see certain constraints implemented in Prisma.
Default value
You can set a default value for non-list scalar fields. The value will be applied to newly created records when no value was supplied during the create
-operation.
To specify a default value for a field, you can use the @default
directive:
type Story {
isPublished: Boolean @default(value: false)
someNumber: Int! @default(value: 42)
title: String! @default(value: "My New Post")
publishDate: DateTime! @default(value: "2018-01-26")
status: Status! @default(value: PUBLIC)
}
enum Status {
PRIVATE
PUBLIC
}
The @relation
directive
When defining relations between types, you can use the @relation
directive which provides meta-information about the relation. If a relation is ambiguous, you must use the @relation
directive to disambiguate it.
It can take three arguments:
name
: An identifier for this relation, provided as a string.link
: Specifies how the relation should be represented in the underlying database. The input values for this argument are defined as an enum with the following possible values:INLINE
: The relation is represented with foreign keys.TABLE
: The relation is represented via a dedicated relation table.
onDelete
: Specifies the deletion behaviour and enables cascading deletes. In case a node with related nodes gets deleted, the deletion behaviour determines what should happen to the related nodes. The input values for this argument are defined as an enum with the following possible values:SET_NULL
(default): Set the related node(s) tonull
.CASCADE
: Delete the related node(s). Note that is not possible to set both ends of a bidirectional relation toCASCADE
.
Here is an example of a datamodel where the @relation
directive is used:
type User {
id: ID! @id
stories: [Story!]! @relation(name: "StoriesByUser", onDelete: CASCADE)
}
type Story {
id: ID! @id
text: String!
author: User @relation(name: "StoriesByUser")
}
The relation is named StoriesByUser
and the deletion behaviour is as follows:
- When a
User
node gets deleted, all its relatedStory
nodes will be deleted as well. - When a
Story
node gets deleted, it will simply be removed from thestories
list on the relatedUser
node.
It is currently not possible to rename relations that are specified via the @relation
directive.
Omitting the @relation
directive
In the simplest case, where a relation between two types is unambiguous and the default deletion behaviour (SET_NULL
) should be applied, the corresponding relation fields do not have to be annotated with the @relation
directive.
Here we are defining a bidirectional one-to-many relation between the User
and Story
types. Since onDelete
has not been provided, the default deletion behaviour is used: SET_NULL
:
type User {
id: ID! @id
stories: [Story!]!
}
type Story {
id: ID! @id
text: String!
author: User
}
The deletion behaviour in this example is as follows:
- When a
User
node gets deleted, theauthor
field on all its relatedStory
nodes will be set tonull
. Note that if theauthor
field was marked as required, the operation would result in an error. - When a
Story
node gets deleted, it will simply be removed from thestories
list on the relatedUser
node.
Using the name
argument of the @relation
directive
In certain cases, your datamodel may contain ambiguous relations. For example, consider you not only want a relation to express the "author-relationship" between User
and Story
, but you also want a relation to express which Story
nodes have been liked by a User
.
In that case, you end up with two different relations between User
and Story
! In order to disambiguate them, you need to give the relation a name:
type User {
id: ID! @id
writtenStories: [Story!]! @relation(name: "WrittenStories")
likedStories: [Story!]! @relation(name: "LikedStories")
}
type Story {
id: ID! @id
text: String!
author: User! @relation(name: "WrittenStories")
likedBy: [User!]! @relation(name: "LikedStories")
}
If the name
wasn't provided in this case, there would be no way to decide whether writtenStories
should relate to the author
or the likedBy
field.
Using the onDelete
argument of the @relation
directive
As mentioned above, you can specify a dedicated deletion behaviour for the related nodes. That's what the onDelete
argument of the @relation
directive is for.
Consider the following example:
type User {
id: ID! @id
comments: [Comment!]! @relation(name: "CommentAuthor", onDelete: CASCADE)
blog: Blog @relation(name: "BlogOwner", onDelete: CASCADE)
}
type Blog {
id: ID! @id
comments: [Comment!]! @relation(name: "Comments", onDelete: CASCADE)
owner: User! @relation(name: "BlogOwner", onDelete: SET_NULL)
}
type Comment {
id: ID! @id
blog: Blog! @relation(name: "Comments", onDelete: SET_NULL)
author: User @relation(name: "CommentAuthor", onDelete: SET_NULL)
}
Let's investigate the deletion behaviour for the three types:
When a
User
node gets deleted,- all related
Comment
nodes will be deleted. - the related
Blog
node will be deleted.
- all related
When a
Blog
node gets deleted,- all related
Comment
nodes will be deleted. - the related
User
node will have itsblog
field set tonull
.
- all related
When a
Comment
node gets deleted,- the related
Blog
node continues to exist and the deletedComment
node is removed from itscomments
list. - the related
User
node continues to exist and the deletedComment
node is removed from itscomments
list.
- the related
SDL directives
Directives are used to provide additional information and add specific behaviours to the types in your datamodel. They look like this: @name(argument: "value")
or simply @name
when there are no arguments.
@id
A record will automatically get assigned a globally unique identifier when it's created, this identifier is stored in the field annotated with the @id
directive:
type User {
id: ID! @id
}
An auto-generated id
has the following properties:
- Consists of 25 alphanumeric characters (letters are always lowercase)
- Always starts with a (lowercase) letter, e.g.
c
- Follows cuid (collision resistant unique identifiers) scheme
The type of an id
field can be:
ID
Int
UUID
@createdAt
and @updatedAt
The datamodel further provides two special field directives which you can add to your types:
createdAt: DateTime! @createdAt
: Stores the exact date and time for when a record of this object type was created.updatedAt: DateTime! @updatedAt
: Stores the exact date and time for when a record of this object type was last updated.
If you want to add this behaviour to your model, you can simply add the corresponding directives to the model definition, for example:
type User {
id: ID! @id
createdAt: DateTime! @createdAt
updatedAt: DateTime! @updatedAt
}
@unique
The @unique
directive marks a scalar field as unique. Unique fields will have a unique index applied in the underlying database.
type User {
email: String @unique
}
Find more info about the @unique
directive above.
@db
The @db
directive can be applied to types/fields to determine the name of the table/column in the underlying database. For example:
type User @db(name: "user") {
id: ID! @id
name: String! @db(name: "full_name")
}
In this case, the underlying table for the User
model is called user
and the column representing the name
field is called full_name
.
@default
The @default(value: String!)
directive sets a default value for a scalar field:
type Post {
title: String! @default(value: "New Post")
published: Boolean! @default(value: false)
someNumber: Int! @default(value: 42)
}
@scalarList
This @scalarList(strategy: STRATEGY!
) directive is required on any scalar list field. The only valid argument for the strategy
argument is RELATION
.
type Post {
tags: [String!]! @scalarList(strategy: RELATION)
}
@relation
The directive @relation(name: String, onDelete: ON_DELETE! = SET_NULL)
can be attached to a relation field.
See above for more information.
Naming conventions
Different objects you encounter in a Prisma service like types or relations follow separate naming conventions to help you distinguish them.
Types
The type name determines the name of derived queries and mutations as well as the argument names for nested mutations.
Here are the conventions for naming types:
Choose type names in singular:
- Yes:
type User { ... }
- No:
type Users { ... }
- Yes:
Scalar and relation fields
The name of a scalar field is used in queries and in query arguments of mutations. The name of relation fields follows the same conventions and determines the argument names for relation mutations.Relation field names can only contain alphanumeric characters and need to start with an uppercase letter. They can contain at most 64 characters.
Field names are unique per type.
Here are the conventions for naming fields:
Choose plural names for list fields:
- Yes:
friends: [User!]!
- No:
friendList: [User!]!
- Yes:
Choose singular names for non-list fields:
- Yes:
post: Post!
- No:
posts: Post!
- Yes:
More SDL features
In this section, we describe further SDL features that are not yet supported for data modeling with Prisma.
Interfaces
"Like many type systems, [SDL] supports interfaces. An interface is an abstract type that includes a certain set of fields that a type must include to implement the interface." From the official Documentation
To learn more about when and how interfaces are coming to Prisma, check out this feature request.
Union types
"Union types are very similar to interfaces, but they don't get to specify any common fields between the types." From the official Documentation
To learn more about when and how union types are coming to Prisma, check out this feature request.