package provisioner import ( "context" "crypto" "crypto/rsa" "crypto/subtle" "crypto/x509" "encoding/pem" "fmt" "net/http" "time" "github.com/pkg/errors" "go.step.sm/crypto/kms" kmsapi "go.step.sm/crypto/kms/apiv1" "go.step.sm/crypto/kms/uri" "go.step.sm/linkedca" "github.com/smallstep/certificates/webhook" ) // SCEP is the SCEP provisioner type, an entity that can authorize the // SCEP provisioning flow type SCEP struct { *base ID string `json:"-"` Type string `json:"type"` Name string `json:"name"` ForceCN bool `json:"forceCN,omitempty"` ChallengePassword string `json:"challenge,omitempty"` Capabilities []string `json:"capabilities,omitempty"` // IncludeRoot makes the provisioner return the CA root in addition to the // intermediate in the GetCACerts response IncludeRoot bool `json:"includeRoot,omitempty"` // ExcludeIntermediate makes the provisioner skip the intermediate CA in the // GetCACerts response ExcludeIntermediate bool `json:"excludeIntermediate,omitempty"` // MinimumPublicKeyLength is the minimum length for public keys in CSRs MinimumPublicKeyLength int `json:"minimumPublicKeyLength,omitempty"` // TODO(hs): also support a separate signer configuration? DecrypterCertificate []byte `json:"decrypterCertificate"` DecrypterKey string `json:"decrypterKey"` DecrypterKeyPassword string `json:"decrypterKeyPassword"` // Numerical identifier for the ContentEncryptionAlgorithm as defined in github.com/mozilla-services/pkcs7 // at https://github.com/mozilla-services/pkcs7/blob/33d05740a3526e382af6395d3513e73d4e66d1cb/encrypt.go#L63 // Defaults to 0, being DES-CBC EncryptionAlgorithmIdentifier int `json:"encryptionAlgorithmIdentifier,omitempty"` Options *Options `json:"options,omitempty"` Claims *Claims `json:"claims,omitempty"` ctl *Controller encryptionAlgorithm int challengeValidationController *challengeValidationController keyManager kmsapi.KeyManager decrypter crypto.Decrypter decrypterCertificate *x509.Certificate signer crypto.Signer signerCertificate *x509.Certificate } // GetID returns the provisioner unique identifier. func (s *SCEP) GetID() string { if s.ID != "" { return s.ID } return s.GetIDForToken() } // GetIDForToken returns an identifier that will be used to load the provisioner // from a token. func (s *SCEP) GetIDForToken() string { return "scep/" + s.Name } // GetName returns the name of the provisioner. func (s *SCEP) GetName() string { return s.Name } // GetType returns the type of provisioner. func (s *SCEP) GetType() Type { return TypeSCEP } // GetEncryptedKey returns the base provisioner encrypted key if it's defined. func (s *SCEP) GetEncryptedKey() (string, string, bool) { return "", "", false } // GetTokenID returns the identifier of the token. func (s *SCEP) GetTokenID(string) (string, error) { return "", errors.New("scep provisioner does not implement GetTokenID") } // GetOptions returns the configured provisioner options. func (s *SCEP) GetOptions() *Options { return s.Options } // DefaultTLSCertDuration returns the default TLS cert duration enforced by // the provisioner. func (s *SCEP) DefaultTLSCertDuration() time.Duration { return s.ctl.Claimer.DefaultTLSCertDuration() } type challengeValidationController struct { client *http.Client webhooks []*Webhook } // newChallengeValidationController creates a new challengeValidationController // that performs challenge validation through webhooks. func newChallengeValidationController(client *http.Client, webhooks []*Webhook) *challengeValidationController { scepHooks := []*Webhook{} for _, wh := range webhooks { if wh.Kind != linkedca.Webhook_SCEPCHALLENGE.String() { continue } if !isCertTypeOK(wh) { continue } scepHooks = append(scepHooks, wh) } return &challengeValidationController{ client: client, webhooks: scepHooks, } } var ( ErrSCEPChallengeInvalid = errors.New("webhook server did not allow request") ) // Validate executes zero or more configured webhooks to // validate the SCEP challenge. If at least one of them indicates // the challenge value is accepted, validation succeeds. In // that case, the other webhooks will be skipped. If none of // the webhooks indicates the value of the challenge was accepted, // an error is returned. func (c *challengeValidationController) Validate(ctx context.Context, challenge, transactionID string) error { for _, wh := range c.webhooks { req := &webhook.RequestBody{ SCEPChallenge: challenge, SCEPTransactionID: transactionID, } resp, err := wh.DoWithContext(ctx, c.client, req, nil) // TODO(hs): support templated URL? Requires some refactoring if err != nil { return fmt.Errorf("failed executing webhook request: %w", err) } if resp.Allow { return nil // return early when response is positive } } return ErrSCEPChallengeInvalid } // isCertTypeOK returns whether or not the webhook can be used // with the SCEP challenge validation webhook controller. func isCertTypeOK(wh *Webhook) bool { if wh.CertType == linkedca.Webhook_ALL.String() || wh.CertType == "" { return true } return linkedca.Webhook_X509.String() == wh.CertType } // Init initializes and validates the fields of a SCEP type. func (s *SCEP) Init(config Config) (err error) { switch { case s.Type == "": return errors.New("provisioner type cannot be empty") case s.Name == "": return errors.New("provisioner name cannot be empty") } // Default to 2048 bits minimum public key length (for CSRs) if not set if s.MinimumPublicKeyLength == 0 { s.MinimumPublicKeyLength = 2048 } if s.MinimumPublicKeyLength%8 != 0 { return errors.Errorf("%d bits is not exactly divisible by 8", s.MinimumPublicKeyLength) } // Set the encryption algorithm to use s.encryptionAlgorithm = s.EncryptionAlgorithmIdentifier // TODO(hs): we might want to upgrade the default security to AES-CBC? if s.encryptionAlgorithm < 0 || s.encryptionAlgorithm > 4 { return errors.New("only encryption algorithm identifiers from 0 to 4 are valid") } // Prepare the SCEP challenge validator s.challengeValidationController = newChallengeValidationController( config.WebhookClient, s.GetOptions().GetWebhooks(), ) if decryptionKey := s.DecrypterKey; decryptionKey != "" { u, err := uri.Parse(s.DecrypterKey) if err != nil { return fmt.Errorf("failed parsing decrypter key: %w", err) } var kmsType string switch { case u.Scheme != "": kmsType = u.Scheme default: kmsType = "softkms" } opts := kms.Options{ Type: kms.Type(kmsType), URI: s.DecrypterKey, } if s.keyManager, err = kms.New(context.Background(), opts); err != nil { return fmt.Errorf("failed initializing kms: %w", err) } kmsDecrypter, ok := s.keyManager.(kmsapi.Decrypter) if !ok { return fmt.Errorf("%q is not a kmsapi.Decrypter", opts.Type) } if kmsType != "softkms" { // TODO(hs): this should likely become more transparent? decryptionKey = u.Opaque } if s.decrypter, err = kmsDecrypter.CreateDecrypter(&kmsapi.CreateDecrypterRequest{ DecryptionKey: decryptionKey, Password: []byte(s.DecrypterKeyPassword), PasswordPrompter: kmsapi.NonInteractivePasswordPrompter, }); err != nil { return fmt.Errorf("failed creating decrypter: %w", err) } if s.signer, err = s.keyManager.CreateSigner(&kmsapi.CreateSignerRequest{ SigningKey: decryptionKey, // TODO(hs): support distinct signer key in the future? Password: []byte(s.DecrypterKeyPassword), PasswordPrompter: kmsapi.NonInteractivePasswordPrompter, }); err != nil { return fmt.Errorf("failed creating signer: %w", err) } } // parse the decrypter certificate contents if available if len(s.DecrypterCertificate) > 0 { block, rest := pem.Decode(s.DecrypterCertificate) if len(rest) > 0 { return errors.New("failed parsing decrypter certificate: trailing data") } if block == nil { return errors.New("failed parsing decrypter certificate: no PEM block found") } if s.decrypterCertificate, err = x509.ParseCertificate(block.Bytes); err != nil { return fmt.Errorf("failed parsing decrypter certificate: %w", err) } // the decrypter certificate is also the signer certificate s.signerCertificate = s.decrypterCertificate } // TODO(hs): alternatively, check if the KMS keyManager is a CertificateManager // and load the certificate corresponding to the decryption key? // Final validation for the decrypter. if s.decrypter != nil { decrypterPublicKey, ok := s.decrypter.Public().(*rsa.PublicKey) if !ok { return fmt.Errorf("only RSA keys are supported") } if s.decrypterCertificate == nil { return fmt.Errorf("provisioner %q does not have a decrypter certificate set", s.Name) } if !decrypterPublicKey.Equal(s.decrypterCertificate.PublicKey) { return errors.New("mismatch between decrypter certificate and decrypter public keys") } } // TODO: add other, SCEP specific, options? s.ctl, err = NewController(s, s.Claims, config, s.Options) return } // AuthorizeSign does not do any verification, because all verification is handled // in the SCEP protocol. This method returns a list of modifiers / constraints // on the resulting certificate. func (s *SCEP) AuthorizeSign(context.Context, string) ([]SignOption, error) { return []SignOption{ s, // modifiers / withOptions newProvisionerExtensionOption(TypeSCEP, s.Name, "").WithControllerOptions(s.ctl), newForceCNOption(s.ForceCN), profileDefaultDuration(s.ctl.Claimer.DefaultTLSCertDuration()), // validators newPublicKeyMinimumLengthValidator(s.MinimumPublicKeyLength), newValidityValidator(s.ctl.Claimer.MinTLSCertDuration(), s.ctl.Claimer.MaxTLSCertDuration()), newX509NamePolicyValidator(s.ctl.getPolicy().getX509()), s.ctl.newWebhookController(nil, linkedca.Webhook_X509), }, nil } // GetCapabilities returns the CA capabilities func (s *SCEP) GetCapabilities() []string { return s.Capabilities } // ShouldIncludeRootInChain indicates if the CA should // return its intermediate, which is currently used for // both signing and decryption, as well as the root in // its chain. func (s *SCEP) ShouldIncludeRootInChain() bool { return s.IncludeRoot } // ShouldIncludeIntermediateInChain indicates if the // CA should include the intermediate CA certificate in the // GetCACerts response. This is true by default, but can be // overriden through configuration in case SCEP clients // don't pick the right recipient. func (s *SCEP) ShouldIncludeIntermediateInChain() bool { return !s.ExcludeIntermediate } // GetContentEncryptionAlgorithm returns the numeric identifier // for the pkcs7 package encryption algorithm to use. func (s *SCEP) GetContentEncryptionAlgorithm() int { return s.encryptionAlgorithm } // ValidateChallenge validates the provided challenge. It starts by // selecting the validation method to use, then performs validation // according to that method. func (s *SCEP) ValidateChallenge(ctx context.Context, challenge, transactionID string) error { if s.challengeValidationController == nil { return fmt.Errorf("provisioner %q wasn't initialized", s.Name) } switch s.selectValidationMethod() { case validationMethodWebhook: return s.challengeValidationController.Validate(ctx, challenge, transactionID) default: if subtle.ConstantTimeCompare([]byte(s.ChallengePassword), []byte(challenge)) == 0 { return errors.New("invalid challenge password provided") } return nil } } type validationMethod string const ( validationMethodNone validationMethod = "none" validationMethodStatic validationMethod = "static" validationMethodWebhook validationMethod = "webhook" ) // selectValidationMethod returns the method to validate SCEP // challenges. If a webhook is configured with kind `SCEPCHALLENGE`, // the webhook method will be used. If a challenge password is set, // the static method is used. It will default to the `none` method. func (s *SCEP) selectValidationMethod() validationMethod { if len(s.challengeValidationController.webhooks) > 0 { return validationMethodWebhook } if s.ChallengePassword != "" { return validationMethodStatic } return validationMethodNone } // GetDecrypter returns the provisioner specific decrypter, // used to decrypt SCEP request messages sent by a SCEP client. // The decrypter consists of a crypto.Decrypter (a private key) // and a certificate for the public key corresponding to the // private key. func (s *SCEP) GetDecrypter() (*x509.Certificate, crypto.Decrypter) { return s.decrypterCertificate, s.decrypter } // GetSigner returns the provisioner specific signer, used to // sign SCEP response messages for the client. The signer consists // of a crypto.Signer and a certificate for the public key // corresponding to the private key. func (s *SCEP) GetSigner() (*x509.Certificate, crypto.Signer) { return s.signerCertificate, s.signer }