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moby--moby/distribution/manifest.go

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package distribution
import (
"context"
"encoding/json"
"fmt"
"io"
"github.com/containerd/containerd/content"
"github.com/containerd/containerd/errdefs"
"github.com/containerd/containerd/log"
"github.com/containerd/containerd/remotes"
"github.com/docker/distribution"
"github.com/docker/distribution/manifest/manifestlist"
"github.com/docker/distribution/manifest/schema1"
"github.com/docker/distribution/manifest/schema2"
digest "github.com/opencontainers/go-digest"
specs "github.com/opencontainers/image-spec/specs-go/v1"
"github.com/pkg/errors"
)
// This is used by manifestStore to pare down the requirements to implement a
// full distribution.ManifestService, since `Get` is all we use here.
type manifestGetter interface {
Get(ctx context.Context, dgst digest.Digest, options ...distribution.ManifestServiceOption) (distribution.Manifest, error)
}
type manifestStore struct {
local ContentStore
remote manifestGetter
}
// ContentStore is the interface used to persist registry blobs
//
// Currently this is only used to persist manifests and manifest lists.
// It is exported because `distribution.Pull` takes one as an argument.
type ContentStore interface {
content.Ingester
content.Provider
Info(ctx context.Context, dgst digest.Digest) (content.Info, error)
Abort(ctx context.Context, ref string) error
}
func (m *manifestStore) getLocal(ctx context.Context, desc specs.Descriptor) (distribution.Manifest, error) {
ra, err := m.local.ReaderAt(ctx, desc)
if err != nil {
return nil, errors.Wrap(err, "error getting content store reader")
}
defer ra.Close()
r := io.NewSectionReader(ra, 0, ra.Size())
data, err := io.ReadAll(r)
if err != nil {
return nil, errors.Wrap(err, "error reading manifest from content store")
}
manifest, _, err := distribution.UnmarshalManifest(desc.MediaType, data)
if err != nil {
return nil, errors.Wrap(err, "error unmarshaling manifest from content store")
}
return manifest, nil
}
func (m *manifestStore) getMediaType(ctx context.Context, desc specs.Descriptor) (string, error) {
ra, err := m.local.ReaderAt(ctx, desc)
if err != nil {
return "", errors.Wrap(err, "error getting reader to detect media type")
}
defer ra.Close()
mt, err := detectManifestMediaType(ra)
if err != nil {
return "", errors.Wrap(err, "error detecting media type")
}
return mt, nil
}
func (m *manifestStore) Get(ctx context.Context, desc specs.Descriptor) (distribution.Manifest, error) {
l := log.G(ctx)
if desc.MediaType == "" {
// When pulling by digest we will not have the media type on the
// descriptor since we have not made a request to the registry yet
//
// We already have the digest, so we only lookup locally... by digest.
//
// Let's try to detect the media type so we can have a good ref key
// here. We may not even have the content locally, and this is fine, but
// if we do we should determine that.
mt, err := m.getMediaType(ctx, desc)
if err != nil && !errdefs.IsNotFound(err) {
l.WithError(err).Warn("Error looking up media type of content")
}
desc.MediaType = mt
}
key := remotes.MakeRefKey(ctx, desc)
// Here we open a writer to the requested content. This both gives us a
// reference to write to if indeed we need to persist it and increments the
// ref count on the content.
w, err := m.local.Writer(ctx, content.WithDescriptor(desc), content.WithRef(key))
if err != nil {
if errdefs.IsAlreadyExists(err) {
var manifest distribution.Manifest
if manifest, err = m.getLocal(ctx, desc); err == nil {
return manifest, nil
}
}
// always fallback to the remote if there is an error with the local store
}
if w != nil {
defer w.Close()
}
l.WithError(err).Debug("Fetching manifest from remote")
manifest, err := m.remote.Get(ctx, desc.Digest)
if err != nil {
if err := m.local.Abort(ctx, key); err != nil {
l.WithError(err).Warn("Error while attempting to abort content ingest")
}
return nil, err
}
if w != nil {
// if `w` is nil here, something happened with the content store, so don't bother trying to persist.
if err := m.Put(ctx, manifest, desc, w); err != nil {
if err := m.local.Abort(ctx, key); err != nil {
l.WithError(err).Warn("error aborting content ingest")
}
l.WithError(err).Warn("Error persisting manifest")
}
}
return manifest, nil
}
func (m *manifestStore) Put(ctx context.Context, manifest distribution.Manifest, desc specs.Descriptor, w content.Writer) error {
mt, payload, err := manifest.Payload()
if err != nil {
return err
}
desc.Size = int64(len(payload))
desc.MediaType = mt
if _, err = w.Write(payload); err != nil {
return errors.Wrap(err, "error writing manifest to content store")
}
if err := w.Commit(ctx, desc.Size, desc.Digest); err != nil {
return errors.Wrap(err, "error committing manifest to content store")
}
return nil
}
func detectManifestMediaType(ra content.ReaderAt) (string, error) {
dt := make([]byte, ra.Size())
if _, err := ra.ReadAt(dt, 0); err != nil {
return "", err
}
return detectManifestBlobMediaType(dt)
}
// This is used when the manifest store does not know the media type of a sha it
// was told to get. This would currently only happen when pulling by digest.
// The media type is needed so the blob can be unmarshalled properly.
func detectManifestBlobMediaType(dt []byte) (string, error) {
var mfst struct {
MediaType string `json:"mediaType"`
Manifests json.RawMessage `json:"manifests"` // oci index, manifest list
Config json.RawMessage `json:"config"` // schema2 Manifest
Layers json.RawMessage `json:"layers"` // schema2 Manifest
FSLayers json.RawMessage `json:"fsLayers"` // schema1 Manifest
}
if err := json.Unmarshal(dt, &mfst); err != nil {
return "", err
}
// We may have a media type specified in the json, in which case that should be used.
// Docker types should generally have a media type set.
// OCI (golang) types do not have a `mediaType` defined, and it is optional in the spec.
//
// `distribution.UnmarshalManifest`, which is used to unmarshal this for real, checks these media type values.
// If the specified media type does not match it will error, and in some cases (docker media types) it is required.
// So pretty much if we don't have a media type we can fall back to OCI.
// This does have a special fallback for schema1 manifests just because it is easy to detect.
switch mfst.MediaType {
case schema2.MediaTypeManifest, specs.MediaTypeImageManifest:
if mfst.Manifests != nil || mfst.FSLayers != nil {
return "", fmt.Errorf(`media-type: %q should not have "manifests" or "fsLayers"`, mfst.MediaType)
}
return mfst.MediaType, nil
case manifestlist.MediaTypeManifestList, specs.MediaTypeImageIndex:
if mfst.Config != nil || mfst.Layers != nil || mfst.FSLayers != nil {
return "", fmt.Errorf(`media-type: %q should not have "config", "layers", or "fsLayers"`, mfst.MediaType)
}
return mfst.MediaType, nil
case schema1.MediaTypeManifest:
if mfst.Manifests != nil || mfst.Layers != nil {
return "", fmt.Errorf(`media-type: %q should not have "manifests" or "layers"`, mfst.MediaType)
}
return mfst.MediaType, nil
default:
if mfst.MediaType != "" {
return mfst.MediaType, nil
}
}
switch {
case mfst.FSLayers != nil && mfst.Manifests == nil && mfst.Layers == nil && mfst.Config == nil:
return schema1.MediaTypeManifest, nil
case mfst.Config != nil && mfst.Manifests == nil && mfst.FSLayers == nil,
mfst.Layers != nil && mfst.Manifests == nil && mfst.FSLayers == nil:
return specs.MediaTypeImageManifest, nil
case mfst.Config == nil && mfst.Layers == nil && mfst.FSLayers == nil:
// fallback to index
return specs.MediaTypeImageIndex, nil
}
return "", errors.New("media-type: cannot determine")
}