forked from TrueCloudLab/certificates
81 lines
3.2 KiB
Go
81 lines
3.2 KiB
Go
package scep
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import (
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"crypto"
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"crypto/rsa"
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"crypto/x509"
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"errors"
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)
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type Options struct {
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// Roots contains the (federated) CA roots certificate(s)
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Roots []*x509.Certificate `json:"-"`
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// Intermediates points issuer certificate, along with any other bundled certificates
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// to be returned in the chain for consumers.
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Intermediates []*x509.Certificate `json:"-"`
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// SignerCert points to the certificate of the CA signer. It usually is the same as the
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// first certificate in the CertificateChain.
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SignerCert *x509.Certificate `json:"-"`
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// Signer signs CSRs in SCEP. Configured in the ca.json key property.
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Signer crypto.Signer `json:"-"`
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// Decrypter decrypts encrypted SCEP messages. Configured in the ca.json key property.
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Decrypter crypto.Decrypter `json:"-"`
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// SCEPProvisionerNames contains the currently configured SCEP provioner names. These
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// are used to be able to load the provisioners when the SCEP authority is being
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// validated.
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SCEPProvisionerNames []string
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}
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type comparablePublicKey interface {
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Equal(crypto.PublicKey) bool
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}
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// Validate checks the fields in Options.
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func (o *Options) Validate() error {
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switch {
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case len(o.Intermediates) == 0:
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return errors.New("no intermediate certificate available for SCEP authority")
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case o.Signer == nil:
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return errors.New("no signer available for SCEP authority")
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case o.SignerCert == nil:
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return errors.New("no signer certificate available for SCEP authority")
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}
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// check if the signer (intermediate CA) certificate has the same public key as
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// the signer. According to the RFC it seems valid to have different keys for
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// the intermediate and the CA signing new certificates, so this might change
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// in the future.
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signerPublicKey := o.Signer.Public().(comparablePublicKey)
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if !signerPublicKey.Equal(o.SignerCert.PublicKey) {
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return errors.New("mismatch between signer certificate and public key")
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}
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// decrypter can be nil in case a signing only key is used; validation complete.
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if o.Decrypter == nil {
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return nil
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}
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// If a decrypter is available, check that it's backed by an RSA key. According to the
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// RFC: https://tools.ietf.org/html/rfc8894#section-3.1, SCEP can be used with something
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// different than RSA, but requires the encryption to be performed using the challenge
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// password in that case. An older version of specification states that only RSA is
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// supported: https://tools.ietf.org/html/draft-nourse-scep-23#section-2.1.1. Other
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// algorithms do not seem to be supported in certnanny/sscep, but it might work
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// in micromdm/scep. Currently only RSA is allowed, but it might be an option
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// to try other algorithms in the future.
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decrypterPublicKey, ok := o.Decrypter.Public().(*rsa.PublicKey)
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if !ok {
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return errors.New("only RSA keys are (currently) supported as decrypters")
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}
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// check if intermediate public key is the same as the decrypter public key.
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// In certnanny/sscep it's mentioned that the signing key can be different
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// from the decrypting (and encrypting) key. These options are only used and
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// validated when the intermediate CA is also used as the decrypter, though,
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// so they should match.
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if !decrypterPublicKey.Equal(o.SignerCert.PublicKey) {
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return errors.New("mismatch between certificate chain and decrypter public keys")
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}
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return nil
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}
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