Package githubv4
is a client library for accessing GitHub GraphQL API v4 (https://developer.github.com/v4/).
If you're looking for a client library for GitHub REST API v3, the recommended package is github.com/google/go-github/github
.
Status: In research and development. The API will change when opportunities for improvement are discovered; it is not yet frozen.
- Friendly, simple and powerful API.
- Correctness, high performance and efficiency.
- Support all of GitHub GraphQL API v4 via code generation from schema.
githubv4
requires Go version 1.8 or later.
go get -u github.com/shurcooL/githubv4
GitHub GraphQL API v4 requires authentication. The githubv4
package does not directly handle authentication. Instead, when creating a new client, you're expected to pass an http.Client
that performs authentication. The easiest and recommended way to do this is to use the golang.org/x/oauth2
package. You'll need an OAuth token from GitHub (for example, a personal API token) with the right scopes. Then:
import "golang.org/x/oauth2"
func main() {
src := oauth2.StaticTokenSource(
&oauth2.Token{AccessToken: os.Getenv("GITHUB_TOKEN")},
)
httpClient := oauth2.NewClient(context.Background(), src)
client := githubv4.NewClient(httpClient)
// Use client...
}
If you are using GitHub Enterprise, use githubv4.NewEnterpriseClient
:
client := githubv4.NewEnterpriseClient(os.Getenv("GITHUB_ENDPOINT"), httpClient)
// Use client...
To make a query, you need to define a Go type that corresponds to the GitHub GraphQL schema, and contains the fields you're interested in querying. You can look up the GitHub GraphQL schema at https://developer.github.com/v4/query/.
For example, to make the following GraphQL query:
query {
viewer {
login
createdAt
}
}
You can define this variable:
var query struct {
Viewer struct {
Login githubv4.String
CreatedAt githubv4.DateTime
}
}
Then call client.Query
, passing a pointer to it:
err := client.Query(context.Background(), &query, nil)
if err != nil {
// Handle error.
}
fmt.Println(" Login:", query.Viewer.Login)
fmt.Println("CreatedAt:", query.Viewer.CreatedAt)
// Output:
// Login: gopher
// CreatedAt: 2017-05-26 21:17:14 +0000 UTC
For each scalar in the GitHub GraphQL schema listed at https://developer.github.com/v4/scalar/, there is a corresponding Go type in package githubv4
.
You can use these types when writing queries:
var query struct {
Viewer struct {
Login githubv4.String
CreatedAt githubv4.DateTime
IsBountyHunter githubv4.Boolean
BioHTML githubv4.HTML
WebsiteURL githubv4.URI
}
}
// Call client.Query() and use results in query...
However, depending on how you're planning to use the results of your query, it's often more convenient to use other Go types.
The encoding/json
rules are used for converting individual JSON-encoded fields from a GraphQL response into Go values. See https://godoc.org/encoding/json#Unmarshal for details. The json.Unmarshaler
interface is respected.
That means you can simplify the earlier query by using predeclared Go types:
// import "time"
var query struct {
Viewer struct {
Login string // E.g., "gopher".
CreatedAt time.Time // E.g., time.Date(2017, 5, 26, 21, 17, 14, 0, time.UTC).
IsBountyHunter bool // E.g., true.
BioHTML string // E.g., `I am learning <a href="https://graphql.org">GraphQL</a>!`.
WebsiteURL string // E.g., "https://golang.org".
}
}
// Call client.Query() and use results in query...
The DateTime
scalar is described as "an ISO-8601 encoded UTC date string". If you wanted to fetch in that form without parsing it into a time.Time
, you can use the string
type. For example, this would work:
// import "html/template"
type MyBoolean bool
var query struct {
Viewer struct {
Login string // E.g., "gopher".
CreatedAt string // E.g., "2017-05-26T21:17:14Z".
IsBountyHunter MyBoolean // E.g., MyBoolean(true).
BioHTML template.HTML // E.g., template.HTML(`I am learning <a href="https://graphql.org">GraphQL</a>!`).
WebsiteURL template.URL // E.g., template.URL("https://golang.org").
}
}
// Call client.Query() and use results in query...
Often, you'll want to specify arguments on some fields. You can use the graphql
struct field tag for this.
For example, to make the following GraphQL query:
{
repository(owner: "octocat", name: "Hello-World") {
description
}
}
You can define this variable:
var q struct {
Repository struct {
Description string
} `graphql:"repository(owner: \"octocat\", name: \"Hello-World\")"`
}
Then call client.Query
:
err := client.Query(context.Background(), &q, nil)
if err != nil {
// Handle error.
}
fmt.Println(q.Repository.Description)
// Output:
// My first repository on GitHub!
However, that'll only work if the arguments are constant and known in advance. Otherwise, you will need to make use of variables. Replace the constants in the struct field tag with variable names:
// fetchRepoDescription fetches description of repo with owner and name.
func fetchRepoDescription(ctx context.Context, owner, name string) (string, error) {
var q struct {
Repository struct {
Description string
} `graphql:"repository(owner: $owner, name: $name)"`
}
When sending variables to GraphQL, you need to use exact types that match GraphQL scalar types, otherwise the GraphQL server will return an error.
So, define a variables
map with their values that are converted to GraphQL scalar types:
variables := map[string]interface{}{
"owner": githubv4.String(owner),
"name": githubv4.String(name),
}
Finally, call client.Query
providing variables
:
err := client.Query(ctx, &q, variables)
return q.Repository.Description, err
}
Some GraphQL queries contain inline fragments. You can use the graphql
struct field tag to express them.
For example, to make the following GraphQL query:
{
repositoryOwner(login: "github") {
login
... on Organization {
description
}
... on User {
bio
}
}
}
You can define this variable:
var q struct {
RepositoryOwner struct {
Login string
Organization struct {
Description string
} `graphql:"... on Organization"`
User struct {
Bio string
} `graphql:"... on User"`
} `graphql:"repositoryOwner(login: \"github\")"`
}
Alternatively, you can define the struct types corresponding to inline fragments, and use them as embedded fields in your query:
type (
OrganizationFragment struct {
Description string
}
UserFragment struct {
Bio string
}
)
var q struct {
RepositoryOwner struct {
Login string
OrganizationFragment `graphql:"... on Organization"`
UserFragment `graphql:"... on User"`
} `graphql:"repositoryOwner(login: \"github\")"`
}
Then call client.Query
:
err := client.Query(context.Background(), &q, nil)
if err != nil {
// Handle error.
}
fmt.Println(q.RepositoryOwner.Login)
fmt.Println(q.RepositoryOwner.Description)
fmt.Println(q.RepositoryOwner.Bio)
// Output:
// github
// How people build software.
//
Imagine you wanted to get a complete list of comments in an issue, and not just the first 10 or so. To do that, you'll need to perform multiple queries and use pagination information. For example:
type comment struct {
Body string
Author struct {
Login string
AvatarURL string `graphql:"avatarUrl(size: 72)"`
}
ViewerCanReact bool
}
var q struct {
Repository struct {
Issue struct {
Comments struct {
Nodes []comment
PageInfo struct {
EndCursor githubv4.String
HasNextPage bool
}
} `graphql:"comments(first: 100, after: $commentsCursor)"` // 100 per page.
} `graphql:"issue(number: $issueNumber)"`
} `graphql:"repository(owner: $repositoryOwner, name: $repositoryName)"`
}
variables := map[string]interface{}{
"repositoryOwner": githubv4.String(owner),
"repositoryName": githubv4.String(name),
"issueNumber": githubv4.Int(issue),
"commentsCursor": (*githubv4.String)(nil), // Null after argument to get first page.
}
// Get comments from all pages.
var allComments []comment
for {
err := s.clQL.Query(ctx, &q, variables)
if err != nil {
return err
}
allComments = append(allComments, q.Repository.Issue.Comments.Nodes...)
if !q.Repository.Issue.Comments.PageInfo.HasNextPage {
break
}
variables["commentsCursor"] = githubv4.NewString(q.Repository.Issue.Comments.PageInfo.EndCursor)
}
There is more than one way to perform pagination. Consider additional fields inside PageInfo
object.
Mutations often require information that you can only find out by performing a query first. Let's suppose you've already done that.
For example, to make the following GraphQL mutation:
mutation($input: AddReactionInput!) {
addReaction(input: $input) {
reaction {
content
}
subject {
id
}
}
}
variables {
"input": {
"subjectId": "MDU6SXNzdWUyMTc5NTQ0OTc=",
"content": "HOORAY"
}
}
You can define:
var m struct {
AddReaction struct {
Reaction struct {
Content githubv4.ReactionContent
}
Subject struct {
ID githubv4.ID
}
} `graphql:"addReaction(input: $input)"`
}
input := githubv4.AddReactionInput{
SubjectID: targetIssue.ID, // ID of the target issue from a previous query.
Content: githubv4.ReactionContentHooray,
}
Then call client.Mutate
:
err := client.Mutate(context.Background(), &m, input, nil)
if err != nil {
// Handle error.
}
fmt.Printf("Added a %v reaction to subject with ID %#v!\n", m.AddReaction.Reaction.Content, m.AddReaction.Subject.ID)
// Output:
// Added a HOORAY reaction to subject with ID "MDU6SXNzdWUyMTc5NTQ0OTc="!
Path | Synopsis |
---|---|
example/githubv4dev | githubv4dev is a test program currently being used for developing githubv4 package. |