clair/worker/worker.go

211 lines
7.4 KiB
Go

// Copyright 2015 clair authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package worker implements the logic to extract useful informations from a
// container layer and store it in the database.
package worker
import (
"github.com/coreos/pkg/capnslog"
"github.com/coreos/clair/database"
"github.com/coreos/clair/utils"
cerrors "github.com/coreos/clair/utils/errors"
"github.com/coreos/clair/worker/detectors"
)
const (
// Version (integer) represents the worker version.
// Increased each time the engine changes.
Version = 2
// maxFileSize is the maximum size of a single file we should extract.
maxFileSize = 200 * 1024 * 1024 // 200 MiB
)
var (
log = capnslog.NewPackageLogger("github.com/coreos/clair", "worker")
// ErrUnsupported is the error that should be raised when an OS or package
// manager is not supported.
ErrUnsupported = cerrors.NewBadRequestError("worker: OS and/or package manager are not supported")
// ErrParentUnknown is the error that should be raised when a parent layer
// has yet to be processed for the current layer.
ErrParentUnknown = cerrors.NewBadRequestError("worker: parent layer is unknown, it must be processed first")
)
// Process detects the Namespace of a layer, the features it adds/removes, and
// then stores everything in the database.
// TODO(Quentin-M): We could have a goroutine that looks for layers that have been analyzed with an
// older engine version and that processes them.
func Process(datastore database.Datastore, imageFormat, name, parentName, path string, headers map[string]string) error {
// Verify parameters.
if name == "" {
return cerrors.NewBadRequestError("could not process a layer which does not have a name")
}
if path == "" {
return cerrors.NewBadRequestError("could not process a layer which does not have a path")
}
if imageFormat == "" {
return cerrors.NewBadRequestError("could not process a layer which does not have a format")
}
log.Debugf("layer %s: processing (Location: %s, Engine version: %d, Parent: %s, Format: %s)",
name, utils.CleanURL(path), Version, parentName, imageFormat)
// Check to see if the layer is already in the database.
layer, err := datastore.FindLayer(name, false, false)
if err != nil && err != cerrors.ErrNotFound {
return err
}
if err == cerrors.ErrNotFound {
// New layer case.
layer = database.Layer{Name: name, EngineVersion: Version}
// Retrieve the parent if it has one.
// We need to get it with its Features in order to diff them.
if parentName != "" {
parent, err := datastore.FindLayer(parentName, true, false)
if err != nil && err != cerrors.ErrNotFound {
return err
}
if err == cerrors.ErrNotFound {
log.Warningf("layer %s: the parent layer (%s) is unknown. it must be processed first", name,
parentName)
return ErrParentUnknown
}
layer.Parent = &parent
}
} else {
// The layer is already in the database, check if we need to update it.
if layer.EngineVersion >= Version {
log.Debugf(`layer %s: layer content has already been processed in the past with engine %d.
Current engine is %d. skipping analysis`, name, layer.EngineVersion, Version)
return nil
}
log.Debugf(`layer %s: layer content has been analyzed in the past with engine %d. Current
engine is %d. analyzing again`, name, layer.EngineVersion, Version)
}
// Analyze the content.
layer.Namespace, layer.Features, err = detectContent(imageFormat, name, path, headers, layer.Parent)
if err != nil {
return err
}
return datastore.InsertLayer(layer)
}
// detectContent downloads a layer's archive and extracts its Namespace and Features.
func detectContent(imageFormat, name, path string, headers map[string]string, parent *database.Layer) (namespace *database.Namespace, featureVersions []database.FeatureVersion, err error) {
data, err := detectors.DetectData(imageFormat, path, headers, append(detectors.GetRequiredFilesFeatures(), detectors.GetRequiredFilesNamespace()...), maxFileSize)
if err != nil {
log.Errorf("layer %s: failed to extract data from %s: %s", name, utils.CleanURL(path), err)
return
}
// Detect namespace.
namespace = detectNamespace(name, data, parent)
// Detect features.
featureVersions, err = detectFeatureVersions(name, data, namespace, parent)
if err != nil {
return
}
if len(featureVersions) > 0 {
log.Debugf("layer %s: detected %d features", name, len(featureVersions))
}
return
}
func detectNamespace(name string, data map[string][]byte, parent *database.Layer) (namespace *database.Namespace) {
// Use registered detectors to get the Namespace.
namespace = detectors.DetectNamespace(data)
if namespace != nil {
log.Debugf("layer %s: detected namespace %q", name, namespace.Name)
return
}
// Use the parent's Namespace.
if parent != nil {
namespace = parent.Namespace
if namespace != nil {
log.Debugf("layer %s: detected namespace %q (from parent)", name, namespace.Name)
return
}
}
return
}
func detectFeatureVersions(name string, data map[string][]byte, namespace *database.Namespace, parent *database.Layer) (features []database.FeatureVersion, err error) {
// TODO(Quentin-M): We need to pass the parent image to DetectFeatures because it's possible that
// some detectors would need it in order to produce the entire feature list (if they can only
// detect a diff). Also, we should probably pass the detected namespace so detectors could
// make their own decision.
features, err = detectors.DetectFeatures(data)
if err != nil {
return
}
// If there are no FeatureVersions, use parent's FeatureVersions if possible.
// TODO(Quentin-M): We eventually want to give the choice to each detectors to use none/some of
// their parent's FeatureVersions. It would be useful for detectors that can't find their entire
// result using one Layer.
if len(features) == 0 && parent != nil {
features = parent.Features
return
}
// Build a map of the namespaces for each FeatureVersion in our parent layer.
parentFeatureNamespaces := make(map[string]database.Namespace)
if parent != nil {
for _, parentFeature := range parent.Features {
parentFeatureNamespaces[parentFeature.Feature.Name+":"+parentFeature.Version.String()] = parentFeature.Feature.Namespace
}
}
// Ensure that each FeatureVersion has an associated Namespace.
for i, feature := range features {
if feature.Feature.Namespace.Name != "" {
// There is a Namespace associated.
continue
}
if parentFeatureNamespace, ok := parentFeatureNamespaces[feature.Feature.Name+":"+feature.Version.String()]; ok {
// The FeatureVersion is present in the parent layer; associate with their Namespace.
features[i].Feature.Namespace = parentFeatureNamespace
continue
}
if namespace != nil {
// The Namespace has been detected in this layer; associate it.
features[i].Feature.Namespace = *namespace
continue
}
log.Warningf("layer %s: Layer's namespace is unknown but non-namespaced features have been detected", name)
err = ErrUnsupported
return
}
return
}