forked from TrueCloudLab/certificates
269 lines
9.7 KiB
Go
Executable file
269 lines
9.7 KiB
Go
Executable file
package policy
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import (
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"crypto/x509"
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"crypto/x509/pkix"
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"fmt"
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"net"
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"net/url"
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"golang.org/x/crypto/ssh"
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"go.step.sm/crypto/x509util"
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)
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type NamePolicyReason int
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const (
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// NotAuthorizedForThisName results when an instance of
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// NamePolicyEngine determines that there's a constraint which
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// doesn't permit a DNS or another type of SAN to be signed
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// (or otherwise used).
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NotAuthorizedForThisName NamePolicyReason = iota
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// CannotParseDomain is returned when an error occurs
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// when parsing the domain part of SAN or subject.
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CannotParseDomain
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// CannotParseRFC822Name is returned when an error
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// occurs when parsing an email address.
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CannotParseRFC822Name
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// CannotMatch is the type of error returned when
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// an error happens when matching SAN types.
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CannotMatchNameToConstraint
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)
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type NamePolicyError struct {
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Reason NamePolicyReason
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Detail string
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}
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func (e *NamePolicyError) Error() string {
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switch e.Reason {
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case NotAuthorizedForThisName:
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return "not authorized to sign for this name: " + e.Detail
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case CannotParseDomain:
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return "cannot parse domain: " + e.Detail
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case CannotParseRFC822Name:
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return "cannot parse rfc822Name: " + e.Detail
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case CannotMatchNameToConstraint:
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return "error matching name to constraint: " + e.Detail
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default:
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return "unknown error: " + e.Detail
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}
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}
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// NamePolicyEngine can be used to check that a CSR or Certificate meets all allowed and
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// denied names before a CA creates and/or signs the Certificate.
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// TODO(hs): the X509 RFC also defines name checks on directory name; support that?
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// TODO(hs): implement Stringer interface: describe the contents of the NamePolicyEngine?
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// TODO(hs): implement matching URI schemes, paths, etc; not just the domain part of URI domains
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type NamePolicyEngine struct {
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// verifySubjectCommonName is set when Subject Common Name must be verified
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verifySubjectCommonName bool
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// allowLiteralWildcardNames allows literal wildcard DNS domains
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allowLiteralWildcardNames bool
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// permitted and exluded constraints similar to x509 Name Constraints
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permittedDNSDomains []string
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excludedDNSDomains []string
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permittedIPRanges []*net.IPNet
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excludedIPRanges []*net.IPNet
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permittedEmailAddresses []string
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excludedEmailAddresses []string
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permittedURIDomains []string
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excludedURIDomains []string
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permittedPrincipals []string
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excludedPrincipals []string
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// some internal counts for housekeeping
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numberOfDNSDomainConstraints int
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numberOfIPRangeConstraints int
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numberOfEmailAddressConstraints int
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numberOfURIDomainConstraints int
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numberOfPrincipalConstraints int
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totalNumberOfPermittedConstraints int
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totalNumberOfExcludedConstraints int
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totalNumberOfConstraints int
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}
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// NewNamePolicyEngine creates a new NamePolicyEngine with NamePolicyOptions
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func New(opts ...NamePolicyOption) (*NamePolicyEngine, error) {
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e := &NamePolicyEngine{}
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for _, option := range opts {
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if err := option(e); err != nil {
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return nil, err
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}
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}
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e.permittedDNSDomains = removeDuplicates(e.permittedDNSDomains)
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e.permittedIPRanges = removeDuplicateIPRanges(e.permittedIPRanges)
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e.permittedEmailAddresses = removeDuplicates(e.permittedEmailAddresses)
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e.permittedURIDomains = removeDuplicates(e.permittedURIDomains)
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e.permittedPrincipals = removeDuplicates(e.permittedPrincipals)
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e.excludedDNSDomains = removeDuplicates(e.excludedDNSDomains)
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e.excludedIPRanges = removeDuplicateIPRanges(e.excludedIPRanges)
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e.excludedEmailAddresses = removeDuplicates(e.excludedEmailAddresses)
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e.excludedURIDomains = removeDuplicates(e.excludedURIDomains)
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e.excludedPrincipals = removeDuplicates(e.excludedPrincipals)
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e.numberOfDNSDomainConstraints = len(e.permittedDNSDomains) + len(e.excludedDNSDomains)
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e.numberOfIPRangeConstraints = len(e.permittedIPRanges) + len(e.excludedIPRanges)
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e.numberOfEmailAddressConstraints = len(e.permittedEmailAddresses) + len(e.excludedEmailAddresses)
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e.numberOfURIDomainConstraints = len(e.permittedURIDomains) + len(e.excludedURIDomains)
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e.numberOfPrincipalConstraints = len(e.permittedPrincipals) + len(e.excludedPrincipals)
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e.totalNumberOfPermittedConstraints = len(e.permittedDNSDomains) + len(e.permittedIPRanges) +
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len(e.permittedEmailAddresses) + len(e.permittedURIDomains) + len(e.permittedPrincipals)
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e.totalNumberOfExcludedConstraints = len(e.excludedDNSDomains) + len(e.excludedIPRanges) +
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len(e.excludedEmailAddresses) + len(e.excludedURIDomains) + len(e.excludedPrincipals)
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e.totalNumberOfConstraints = e.totalNumberOfPermittedConstraints + e.totalNumberOfExcludedConstraints
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return e, nil
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}
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func removeDuplicates(strSlice []string) []string {
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if len(strSlice) == 0 {
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return nil
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}
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keys := make(map[string]bool)
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result := []string{}
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for _, item := range strSlice {
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if _, value := keys[item]; !value && item != "" { // skip empty constraints
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keys[item] = true
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result = append(result, item)
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}
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}
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return result
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}
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func removeDuplicateIPRanges(ipRanges []*net.IPNet) []*net.IPNet {
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if len(ipRanges) == 0 {
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return nil
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}
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keys := make(map[string]bool)
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result := []*net.IPNet{}
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for _, item := range ipRanges {
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key := item.String()
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if _, value := keys[key]; !value {
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keys[key] = true
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result = append(result, item)
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}
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}
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return result
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}
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// IsX509CertificateAllowed verifies that all SANs in a Certificate are allowed.
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func (e *NamePolicyEngine) IsX509CertificateAllowed(cert *x509.Certificate) (bool, error) {
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dnsNames, ips, emails, uris := cert.DNSNames, cert.IPAddresses, cert.EmailAddresses, cert.URIs
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// when Subject Common Name must be verified in addition to the SANs, it is
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// added to the appropriate slice of names.
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if e.verifySubjectCommonName {
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appendSubjectCommonName(cert.Subject, &dnsNames, &ips, &emails, &uris)
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}
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if err := e.validateNames(dnsNames, ips, emails, uris, []string{}); err != nil {
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return false, err
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}
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return true, nil
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}
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// IsX509CertificateRequestAllowed verifies that all names in the CSR are allowed.
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func (e *NamePolicyEngine) IsX509CertificateRequestAllowed(csr *x509.CertificateRequest) (bool, error) {
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dnsNames, ips, emails, uris := csr.DNSNames, csr.IPAddresses, csr.EmailAddresses, csr.URIs
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// when Subject Common Name must be verified in addition to the SANs, it is
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// added to the appropriate slice of names.
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if e.verifySubjectCommonName {
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appendSubjectCommonName(csr.Subject, &dnsNames, &ips, &emails, &uris)
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}
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if err := e.validateNames(dnsNames, ips, emails, uris, []string{}); err != nil {
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return false, err
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}
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return true, nil
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}
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// AreSANSAllowed verifies that all names in the slice of SANs are allowed.
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// The SANs are first split into DNS names, IPs, email addresses and URIs.
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func (e *NamePolicyEngine) AreSANsAllowed(sans []string) (bool, error) {
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dnsNames, ips, emails, uris := x509util.SplitSANs(sans)
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if err := e.validateNames(dnsNames, ips, emails, uris, []string{}); err != nil {
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return false, err
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}
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return true, nil
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}
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// IsDNSAllowed verifies a single DNS domain is allowed.
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func (e *NamePolicyEngine) IsDNSAllowed(dns string) (bool, error) {
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if err := e.validateNames([]string{dns}, []net.IP{}, []string{}, []*url.URL{}, []string{}); err != nil {
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return false, err
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}
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return true, nil
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}
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// IsIPAllowed verifies a single IP domain is allowed.
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func (e *NamePolicyEngine) IsIPAllowed(ip net.IP) (bool, error) {
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if err := e.validateNames([]string{}, []net.IP{ip}, []string{}, []*url.URL{}, []string{}); err != nil {
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return false, err
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}
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return true, nil
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}
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// IsSSHCertificateAllowed verifies that all principals in an SSH certificate are allowed.
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func (e *NamePolicyEngine) IsSSHCertificateAllowed(cert *ssh.Certificate) (bool, error) {
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dnsNames, ips, emails, principals, err := splitSSHPrincipals(cert)
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if err != nil {
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return false, err
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}
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if err := e.validateNames(dnsNames, ips, emails, []*url.URL{}, principals); err != nil {
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return false, err
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}
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return true, nil
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}
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// appendSubjectCommonName appends the Subject Common Name to the appropriate slice of names. The logic is
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// similar as x509util.SplitSANs: if the subject can be parsed as an IP, it's added to the ips. If it can
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// be parsed as an URL, it is added to the URIs. If it contains an @, it is added to emails. When it's none
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// of these, it's added to the DNS names.
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func appendSubjectCommonName(subject pkix.Name, dnsNames *[]string, ips *[]net.IP, emails *[]string, uris *[]*url.URL) {
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commonName := subject.CommonName
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if commonName == "" {
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return
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}
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subjectDNSNames, subjectIPs, subjectEmails, subjectURIs := x509util.SplitSANs([]string{commonName})
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*dnsNames = append(*dnsNames, subjectDNSNames...)
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*ips = append(*ips, subjectIPs...)
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*emails = append(*emails, subjectEmails...)
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*uris = append(*uris, subjectURIs...)
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}
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// splitPrincipals splits SSH certificate principals into DNS names, emails and usernames.
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func splitSSHPrincipals(cert *ssh.Certificate) (dnsNames []string, ips []net.IP, emails, principals []string, err error) {
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dnsNames = []string{}
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ips = []net.IP{}
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emails = []string{}
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principals = []string{}
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var uris []*url.URL
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switch cert.CertType {
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case ssh.HostCert:
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dnsNames, ips, emails, uris = x509util.SplitSANs(cert.ValidPrincipals)
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if len(uris) > 0 {
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err = fmt.Errorf("URL principals %v not expected in SSH host certificate ", uris)
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}
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case ssh.UserCert:
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// re-using SplitSANs results in anything that can't be parsed as an IP, URI or email
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// to be considered a username principal. This allows usernames like h.slatman to be present
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// in the SSH certificate. We're exluding URIs, because they can be confusing
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// when used in a SSH user certificate.
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principals, ips, emails, uris = x509util.SplitSANs(cert.ValidPrincipals)
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if len(uris) > 0 {
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err = fmt.Errorf("URL principals %v not expected in SSH user certificate ", uris)
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}
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default:
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err = fmt.Errorf("unexpected SSH certificate type %d", cert.CertType)
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}
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return
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}
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