package dsig import ( "bytes" "crypto/rsa" "crypto/x509" "encoding/base64" "errors" "fmt" "regexp" "github.com/beevik/etree" "github.com/russellhaering/goxmldsig/etreeutils" "github.com/russellhaering/goxmldsig/types" ) var uriRegexp = regexp.MustCompile("^#[a-zA-Z_][\\w.-]*$") var whiteSpace = regexp.MustCompile("\\s+") var ( // ErrMissingSignature indicates that no enveloped signature was found referencing // the top level element passed for signature verification. ErrMissingSignature = errors.New("Missing signature referencing the top-level element") ) type ValidationContext struct { CertificateStore X509CertificateStore IdAttribute string Clock *Clock } func NewDefaultValidationContext(certificateStore X509CertificateStore) *ValidationContext { return &ValidationContext{ CertificateStore: certificateStore, IdAttribute: DefaultIdAttr, } } // TODO(russell_h): More flexible namespace support. This might barely work. func inNamespace(el *etree.Element, ns string) bool { for _, attr := range el.Attr { if attr.Value == ns { if attr.Space == "" && attr.Key == "xmlns" { return el.Space == "" } else if attr.Space == "xmlns" { return el.Space == attr.Key } } } return false } func childPath(space, tag string) string { if space == "" { return "./" + tag } else { return "./" + space + ":" + tag } } func mapPathToElement(tree, el *etree.Element) []int { for i, child := range tree.Child { if child == el { return []int{i} } } for i, child := range tree.Child { if childElement, ok := child.(*etree.Element); ok { childPath := mapPathToElement(childElement, el) if childElement != nil { return append([]int{i}, childPath...) } } } return nil } func removeElementAtPath(el *etree.Element, path []int) bool { if len(path) == 0 { return false } if len(el.Child) <= path[0] { return false } childElement, ok := el.Child[path[0]].(*etree.Element) if !ok { return false } if len(path) == 1 { el.RemoveChild(childElement) return true } return removeElementAtPath(childElement, path[1:]) } // Transform returns a new element equivalent to the passed root el, but with // the set of transformations described by the ref applied. // // The functionality of transform is currently very limited and purpose-specific. func (ctx *ValidationContext) transform( el *etree.Element, sig *types.Signature, ref *types.Reference) (*etree.Element, Canonicalizer, error) { transforms := ref.Transforms.Transforms if len(transforms) != 2 { return nil, nil, errors.New("Expected Enveloped and C14N transforms") } // map the path to the passed signature relative to the passed root, in // order to enable removal of the signature by an enveloped signature // transform signaturePath := mapPathToElement(el, sig.UnderlyingElement()) // make a copy of the passed root el = el.Copy() var canonicalizer Canonicalizer for _, transform := range transforms { algo := transform.Algorithm switch AlgorithmID(algo) { case EnvelopedSignatureAltorithmId: if !removeElementAtPath(el, signaturePath) { return nil, nil, errors.New("Error applying canonicalization transform: Signature not found") } case CanonicalXML10ExclusiveAlgorithmId: var prefixList string if transform.InclusiveNamespaces != nil { prefixList = transform.InclusiveNamespaces.PrefixList } canonicalizer = MakeC14N10ExclusiveCanonicalizerWithPrefixList(prefixList) case CanonicalXML11AlgorithmId: canonicalizer = MakeC14N11Canonicalizer() case CanonicalXML10RecAlgorithmId: canonicalizer = MakeC14N10RecCanonicalizer() case CanonicalXML10CommentAlgorithmId: canonicalizer = MakeC14N10CommentCanonicalizer() default: return nil, nil, errors.New("Unknown Transform Algorithm: " + algo) } } if canonicalizer == nil { return nil, nil, errors.New("Expected canonicalization transform") } return el, canonicalizer, nil } func (ctx *ValidationContext) digest(el *etree.Element, digestAlgorithmId string, canonicalizer Canonicalizer) ([]byte, error) { data, err := canonicalizer.Canonicalize(el) if err != nil { return nil, err } digestAlgorithm, ok := digestAlgorithmsByIdentifier[digestAlgorithmId] if !ok { return nil, errors.New("Unknown digest algorithm: " + digestAlgorithmId) } hash := digestAlgorithm.New() _, err = hash.Write(data) if err != nil { return nil, err } return hash.Sum(nil), nil } func (ctx *ValidationContext) verifySignedInfo(sig *types.Signature, canonicalizer Canonicalizer, signatureMethodId string, cert *x509.Certificate, decodedSignature []byte) error { signatureElement := sig.UnderlyingElement() nsCtx, err := etreeutils.NSBuildParentContext(signatureElement) if err != nil { return err } signedInfo, err := etreeutils.NSFindOneChildCtx(nsCtx, signatureElement, Namespace, SignedInfoTag) if err != nil { return err } if signedInfo == nil { return errors.New("Missing SignedInfo") } // Canonicalize the xml canonical, err := canonicalSerialize(signedInfo) if err != nil { return err } signatureAlgorithm, ok := signatureMethodsByIdentifier[signatureMethodId] if !ok { return errors.New("Unknown signature method: " + signatureMethodId) } hash := signatureAlgorithm.New() _, err = hash.Write(canonical) if err != nil { return err } hashed := hash.Sum(nil) pubKey, ok := cert.PublicKey.(*rsa.PublicKey) if !ok { return errors.New("Invalid public key") } // Verify that the private key matching the public key from the cert was what was used to sign the 'SignedInfo' and produce the 'SignatureValue' err = rsa.VerifyPKCS1v15(pubKey, signatureAlgorithm, hashed[:], decodedSignature) if err != nil { return err } return nil } func (ctx *ValidationContext) validateSignature(el *etree.Element, sig *types.Signature, cert *x509.Certificate) (*etree.Element, error) { idAttr := el.SelectAttr(ctx.IdAttribute) if idAttr == nil || idAttr.Value == "" { return nil, errors.New("Missing ID attribute") } var ref *types.Reference // Find the first reference which references the top-level element for _, _ref := range sig.SignedInfo.References { if _ref.URI == "" || _ref.URI[1:] == idAttr.Value { ref = &_ref } } // Perform all transformations listed in the 'SignedInfo' // Basically, this means removing the 'SignedInfo' transformed, canonicalizer, err := ctx.transform(el, sig, ref) if err != nil { return nil, err } digestAlgorithm := ref.DigestAlgo.Algorithm // Digest the transformed XML and compare it to the 'DigestValue' from the 'SignedInfo' digest, err := ctx.digest(transformed, digestAlgorithm, canonicalizer) if err != nil { return nil, err } decodedDigestValue, err := base64.StdEncoding.DecodeString(ref.DigestValue) if err != nil { return nil, err } if !bytes.Equal(digest, decodedDigestValue) { return nil, errors.New("Signature could not be verified") } // Decode the 'SignatureValue' so we can compare against it decodedSignature, err := base64.StdEncoding.DecodeString(sig.SignatureValue.Data) if err != nil { return nil, errors.New("Could not decode signature") } // Actually verify the 'SignedInfo' was signed by a trusted source signatureMethod := sig.SignedInfo.SignatureMethod.Algorithm err = ctx.verifySignedInfo(sig, canonicalizer, signatureMethod, cert, decodedSignature) if err != nil { return nil, err } return transformed, nil } func contains(roots []*x509.Certificate, cert *x509.Certificate) bool { for _, root := range roots { if root.Equal(cert) { return true } } return false } // findSignature searches for a Signature element referencing the passed root element. func (ctx *ValidationContext) findSignature(el *etree.Element) (*types.Signature, error) { idAttr := el.SelectAttr(ctx.IdAttribute) if idAttr == nil || idAttr.Value == "" { return nil, errors.New("Missing ID attribute") } var sig *types.Signature // Traverse the tree looking for a Signature element err := etreeutils.NSFindIterate(el, Namespace, SignatureTag, func(ctx etreeutils.NSContext, el *etree.Element) error { found := false err := etreeutils.NSFindChildrenIterateCtx(ctx, el, Namespace, SignedInfoTag, func(ctx etreeutils.NSContext, signedInfo *etree.Element) error { detachedSignedInfo, err := etreeutils.NSDetatch(ctx, signedInfo) if err != nil { return err } c14NMethod, err := etreeutils.NSFindOneChildCtx(ctx, detachedSignedInfo, Namespace, CanonicalizationMethodTag) if err != nil { return err } if c14NMethod == nil { return errors.New("missing CanonicalizationMethod on Signature") } c14NAlgorithm := c14NMethod.SelectAttrValue(AlgorithmAttr, "") var canonicalSignedInfo *etree.Element switch AlgorithmID(c14NAlgorithm) { case CanonicalXML10ExclusiveAlgorithmId: err := etreeutils.TransformExcC14n(detachedSignedInfo, "") if err != nil { return err } // NOTE: TransformExcC14n transforms the element in-place, // while canonicalPrep isn't meant to. Once we standardize // this behavior we can drop this, as well as the adding and // removing of elements below. canonicalSignedInfo = detachedSignedInfo case CanonicalXML11AlgorithmId: canonicalSignedInfo = canonicalPrep(detachedSignedInfo, map[string]struct{}{}) case CanonicalXML10RecAlgorithmId: canonicalSignedInfo = canonicalPrep(detachedSignedInfo, map[string]struct{}{}) case CanonicalXML10CommentAlgorithmId: canonicalSignedInfo = canonicalPrep(detachedSignedInfo, map[string]struct{}{}) default: return fmt.Errorf("invalid CanonicalizationMethod on Signature: %s", c14NAlgorithm) } el.RemoveChild(signedInfo) el.AddChild(canonicalSignedInfo) found = true return etreeutils.ErrTraversalHalted }) if err != nil { return err } if !found { return errors.New("Missing SignedInfo") } // Unmarshal the signature into a structured Signature type _sig := &types.Signature{} err = etreeutils.NSUnmarshalElement(ctx, el, _sig) if err != nil { return err } // Traverse references in the signature to determine whether it has at least // one reference to the top level element. If so, conclude the search. for _, ref := range _sig.SignedInfo.References { if ref.URI == "" || ref.URI[1:] == idAttr.Value { sig = _sig return etreeutils.ErrTraversalHalted } } return nil }) if err != nil { return nil, err } if sig == nil { return nil, ErrMissingSignature } return sig, nil } func (ctx *ValidationContext) verifyCertificate(sig *types.Signature) (*x509.Certificate, error) { now := ctx.Clock.Now() roots, err := ctx.CertificateStore.Certificates() if err != nil { return nil, err } var cert *x509.Certificate if sig.KeyInfo != nil { // If the Signature includes KeyInfo, extract the certificate from there if len(sig.KeyInfo.X509Data.X509Certificates) == 0 || sig.KeyInfo.X509Data.X509Certificates[0].Data == "" { return nil, errors.New("missing X509Certificate within KeyInfo") } certData, err := base64.StdEncoding.DecodeString( whiteSpace.ReplaceAllString(sig.KeyInfo.X509Data.X509Certificates[0].Data, "")) if err != nil { return nil, errors.New("Failed to parse certificate") } cert, err = x509.ParseCertificate(certData) if err != nil { return nil, err } } else { // If the Signature doesn't have KeyInfo, Use the root certificate if there is only one if len(roots) == 1 { cert = roots[0] } else { return nil, errors.New("Missing x509 Element") } } // Verify that the certificate is one we trust if !contains(roots, cert) { return nil, errors.New("Could not verify certificate against trusted certs") } if now.Before(cert.NotBefore) || now.After(cert.NotAfter) { return nil, errors.New("Cert is not valid at this time") } return cert, nil } // Validate verifies that the passed element contains a valid enveloped signature // matching a currently-valid certificate in the context's CertificateStore. func (ctx *ValidationContext) Validate(el *etree.Element) (*etree.Element, error) { // Make a copy of the element to avoid mutating the one we were passed. el = el.Copy() sig, err := ctx.findSignature(el) if err != nil { return nil, err } cert, err := ctx.verifyCertificate(sig) if err != nil { return nil, err } return ctx.validateSignature(el, sig, cert) }