@tinacms/datalayer
v1.3.9
Published
There's a serve and watch command, which are separate for now:
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Getting started
There's a serve and watch command, which are separate for now:
// terminal 1
cd packages/tina-graphql
yarn watch
// terminal 2
cd packages/tina-graphql
yarn serve
You can consume this from the graphiql
app:
// terminal 3
cd apps/graphiql
yarn start
Note that this app doesn't use anything from the client
package right now, it's just an interactive tool to see how things move from the graphql server into tina. That process has been improved in this package but will need to be merged back into the client
package before this is usable.
Running queries
By default the app will redirect to project1
and display the default query generated from the graphql-helpers
library - which consumes the fixtures from the project1
folder the the gql
package, any number of fixtures can be used if you want to add your own, just ensure the server.ts
file knows about them.
When you run the initial query, you should see the result along with the Tina sidebar toggle, this indicates that the Tina form has now been populated with the query values. If you change some values around and hit submit, the onSubmit
function will populate the GraphiQL editor instead of sending it off to the server, you can play around with the mutation before sending it off if you'd like.
Tests
The most valuable test right now is the builder.spec.ts
, it's sort of an integration of all the field-level builders. There are also field-level build tests, but not resolvers ones just yet. If you're making changes to the builder just run yarn test-watch
and hit p
to provide a pattern, then type "builder", this will isolate that test and if it's passing you probably didn't break anything.
Architecture
Builder
The builder service is responsible for building out the entire GraphQL schema for a given .tina
config. This service can run at any time (but needs to be re-run on each schema change) and it's output is a GraphQL schema which can be stored in the schema definition language (SDL) as a string in a database record or as a .graphql
file. At the top of the schema is a document
query, this query returns the document, which can be one of any number of templates defined in the .tina
config. From there, each field in the given template is used to build out the rest of the schema, so each template field is built by the type
in it's definition
Field-level builders
Field-level builders take a field definition and produce 4 different GraphQL types:
field
Builds the type which fits into Tina's field definition shape:
Given:
name: Title
label: title
type: text
text.build.field({ cache, field });
Produces
type TextField {
name: String
label: String
component: String
description: String
}
initialValue
Tina fields need an initial value when editing existing data. This builder is responsible for providing the shape of that value.
For most fields this is the same value as value
- but if you picture the schema as a "graph" - you can see how the "value" of a document reference (ie. a Post has an Author) is not helpful to Tina. Tina only cares about the stored document value of the reference (in this case /path/to/author.md
) so it's the initialValue
's role to provide what makes sense to Tina, regardless of the schema's relationships.
value
The value of the field, it's the role of this function to provide the shape of the data we should expect for a fully resolved graph.
For block
fields, this looks like an array of different shapes, which means it's the blocks.build.value
function's responsibility to return a union
array.
input
When a mutation is made, the shape of this mutation needs to fit the shape create by this function.
Resolvers
resolvers
can be thought of as the runtime siblings to builders
. While it's the job of builders to define the "graph", the resolvers are responsible for taking raw values (like those from a .md
file) and shaping them so they fit the schema.
Field-level resolvers
Again, similar to field-level builders, most of the work for resolving the data is passed on to the appropriate field to handle. So if you have a document like so:
---
title: Hello, World!
author: /authors/homer.md
---
It's template definition might look like:
label: Post
---
fields:
- name: title
label: Title
type: text
- name: author
label: Author
type: select
config:
source:
type: pages
section: authors
The text.resolver
object will be responsible for resolving the values related to title
:
field
The field
resolver provides the appropriate values for it's field
builder counterpart. In the example above the text.resolve.field
function would return:
{
"name": "title",
"label": "Title",
"component": "text"
}
This would then be passed on to Tina for rendering on the client.
initialValue
In the example above the text.resolve.initialValue
would return "Hello, World!"
For blocks we need to return the object along with a _template
key, this is used downstream to disambiguate which template the value comes from.
value
In the example above the text.resolve.value
would return "Hello, World!", and again, for document references this would return the entire document being referenced, which may or may not be used depending on the graph fields requested
input
Input resolvers don't do much (except in the case of blocks described later), since the GraphQL mutataion payload has all the necessary information, we just pass the value into these resolvers as a runtime type-check. In the future, this is where field-level validations can take place.
Caveats with blocks
: blocks
values are an array of unlike objects, meaning in order to enforce type-safe requests coming into the server, we need to use a somewhat awkward pattern (read more about the trade-offs here) which we sort of need to rearrange once it hits the server.
Architecture Diagram
Caveats
Why do we use GraphQLUnion
instead of GraphQLInterface
for fields?
Since component
, label
, & name
are common across all fields, we'd only use a fragment to gather what's unique to that field type, so field definitions using an interface would allow our queries to look like this:
fields {
component
label
name
...on SelectField {
options
}
}
Instead, we use a union - which requires us to load each key inside it's respective fragment:
fields {
... on TextareaField {
name
label
component
}
... on SelectField {
name
label
component
options
}
}
A GraphQL interface allows you to define a heterogeneous set of types, which have some fields in common. This is a textbook usecase for interfaces, and it's something that could change in the future. But the current reason we're using unions is because unions are exhaustive, and they allow us to scope down the possible field types for a given set of fields.
An interface would be too broad for our needs, a collection of fields should only contain the types which are possible for that given template config. So while an interface
would allow us to present all possible field types, a union
gives us the ability to scope down the field list to only allow what the template defines. Using unions
forces us to be explicit about that in a way that's clear (note: it may be possible to do this with interfaces but there would end up being an interface for each collection of possible fields - making the interface
term somewhat misleading). Using unions also allows our auto-querybuilder to know that they have populated all possible types of a field, something that seems like it might be more difficult with interfaces.