smallstep-certificates/acme/order.go
2024-01-08 20:52:52 +01:00

544 lines
18 KiB
Go

package acme
import (
"bytes"
"context"
"crypto/subtle"
"crypto/x509"
"encoding/json"
"net"
"net/url"
"sort"
"strings"
"time"
"go.step.sm/crypto/keyutil"
"go.step.sm/crypto/x509util"
"github.com/smallstep/certificates/authority/provisioner"
"github.com/smallstep/certificates/wire"
)
type IdentifierType string
const (
// IP is the ACME ip identifier type
IP IdentifierType = "ip"
// DNS is the ACME dns identifier type
DNS IdentifierType = "dns"
// PermanentIdentifier is the ACME permanent-identifier identifier type
// defined in https://datatracker.ietf.org/doc/html/draft-bweeks-acme-device-attest-00
PermanentIdentifier IdentifierType = "permanent-identifier"
// WireID is the Wire user identifier type
WireID IdentifierType = "wireapp-id"
)
// Identifier encodes the type that an order pertains to.
type Identifier struct {
Type IdentifierType `json:"type"`
Value string `json:"value"`
}
// Order contains order metadata for the ACME protocol order type.
type Order struct {
ID string `json:"id"`
AccountID string `json:"-"`
ProvisionerID string `json:"-"`
Status Status `json:"status"`
ExpiresAt time.Time `json:"expires"`
Identifiers []Identifier `json:"identifiers"`
NotBefore time.Time `json:"notBefore"`
NotAfter time.Time `json:"notAfter"`
Error *Error `json:"error,omitempty"`
AuthorizationIDs []string `json:"-"`
AuthorizationURLs []string `json:"authorizations"`
FinalizeURL string `json:"finalize"`
CertificateID string `json:"-"`
CertificateURL string `json:"certificate,omitempty"`
}
// ToLog enables response logging.
func (o *Order) ToLog() (interface{}, error) {
b, err := json.Marshal(o)
if err != nil {
return nil, WrapErrorISE(err, "error marshaling order for logging")
}
return string(b), nil
}
// UpdateStatus updates the ACME Order Status if necessary.
// Changes to the order are saved using the database interface.
func (o *Order) UpdateStatus(ctx context.Context, db DB) error {
now := clock.Now()
switch o.Status {
case StatusInvalid:
return nil
case StatusValid:
return nil
case StatusReady:
// Check expiry
if now.After(o.ExpiresAt) {
o.Status = StatusInvalid
o.Error = NewError(ErrorMalformedType, "order has expired")
break
}
return nil
case StatusPending:
// Check expiry
if now.After(o.ExpiresAt) {
o.Status = StatusInvalid
o.Error = NewError(ErrorMalformedType, "order has expired")
break
}
var count = map[Status]int{
StatusValid: 0,
StatusInvalid: 0,
StatusPending: 0,
}
for _, azID := range o.AuthorizationIDs {
az, err := db.GetAuthorization(ctx, azID)
if err != nil {
return WrapErrorISE(err, "error getting authorization ID %s", azID)
}
if err = az.UpdateStatus(ctx, db); err != nil {
return WrapErrorISE(err, "error updating authorization ID %s", azID)
}
st := az.Status
count[st]++
}
switch {
case count[StatusInvalid] > 0:
o.Status = StatusInvalid
// No change in the order status, so just return the order as is -
// without writing any changes.
case count[StatusPending] > 0:
return nil
case count[StatusValid] == len(o.AuthorizationIDs):
o.Status = StatusReady
default:
return NewErrorISE("unexpected authz status")
}
default:
return NewErrorISE("unrecognized order status: %s", o.Status)
}
if err := db.UpdateOrder(ctx, o); err != nil {
return WrapErrorISE(err, "error updating order")
}
return nil
}
// getKeyFingerprint returns a fingerprint from the list of authorizations. This
// fingerprint is used on the device-attest-01 flow to verify the attestation
// certificate public key with the CSR public key.
//
// There's no point on reading all the authorizations as there will be only one
// for a permanent identifier.
func (o *Order) getAuthorizationFingerprint(ctx context.Context, db DB) (string, error) {
for _, azID := range o.AuthorizationIDs {
az, err := db.GetAuthorization(ctx, azID)
if err != nil {
return "", WrapErrorISE(err, "error getting authorization %q", azID)
}
// There's no point on reading all the authorizations as there will
// be only one for a permanent identifier.
if az.Fingerprint != "" {
return az.Fingerprint, nil
}
}
return "", nil
}
// Finalize signs a certificate if the necessary conditions for Order completion
// have been met.
//
// TODO(mariano): Here or in the challenge validation we should perform some
// external validation using the identifier value and the attestation data. From
// a validation service we can get the list of SANs to set in the final
// certificate.
func (o *Order) Finalize(ctx context.Context, db DB, csr *x509.CertificateRequest, auth CertificateAuthority, p Provisioner) error {
if err := o.UpdateStatus(ctx, db); err != nil {
return err
}
switch o.Status {
case StatusInvalid:
return NewError(ErrorOrderNotReadyType, "order %s has been abandoned", o.ID)
case StatusValid:
return nil
case StatusPending:
return NewError(ErrorOrderNotReadyType, "order %s is not ready", o.ID)
case StatusReady:
break
default:
return NewErrorISE("unexpected status %s for order %s", o.Status, o.ID)
}
// Get key fingerprint if any. And then compare it with the CSR fingerprint.
//
// In device-attest-01 challenges we should check that the keys in the CSR
// and the attestation certificate are the same.
fingerprint, err := o.getAuthorizationFingerprint(ctx, db)
if err != nil {
return err
}
if fingerprint != "" {
fp, err := keyutil.Fingerprint(csr.PublicKey)
if err != nil {
return WrapErrorISE(err, "error calculating key fingerprint")
}
if subtle.ConstantTimeCompare([]byte(fingerprint), []byte(fp)) == 0 {
return NewError(ErrorUnauthorizedType, "order %s csr does not match the attested key", o.ID)
}
}
// canonicalize the CSR to allow for comparison
csr = canonicalize(csr)
// Template data
data := x509util.NewTemplateData()
subject, err := o.subject(csr)
if err != nil {
return err
}
data.SetSubject(subject)
// Custom sign options passed to authority.Sign
var extraOptions []provisioner.SignOption
// TODO: support for multiple identifiers?
var permanentIdentifier string
for i := range o.Identifiers {
if o.Identifiers[i].Type == PermanentIdentifier {
permanentIdentifier = o.Identifiers[i].Value
// the first (and only) Permanent Identifier that gets added to the certificate
// should be equal to the Subject Common Name if it's set. If not equal, the CSR
// is rejected, because the Common Name hasn't been challenged in that case. This
// could result in unauthorized access if a relying system relies on the Common
// Name in its authorization logic.
if csr.Subject.CommonName != "" && csr.Subject.CommonName != permanentIdentifier {
return NewError(ErrorBadCSRType, "CSR Subject Common Name does not match identifiers exactly: "+
"CSR Subject Common Name = %s, Order Permanent Identifier = %s", csr.Subject.CommonName, permanentIdentifier)
}
break
}
}
var defaultTemplate string
if permanentIdentifier != "" {
defaultTemplate = x509util.DefaultAttestedLeafTemplate
data.SetSubjectAlternativeNames(x509util.SubjectAlternativeName{
Type: x509util.PermanentIdentifierType,
Value: permanentIdentifier,
})
extraOptions = append(extraOptions, provisioner.AttestationData{
PermanentIdentifier: permanentIdentifier,
})
} else {
defaultTemplate = x509util.DefaultLeafTemplate
sans, err := o.sans(csr)
if err != nil {
return err
}
data.SetSubjectAlternativeNames(sans...)
}
// Get authorizations from the ACME provisioner.
ctx = provisioner.NewContextWithMethod(ctx, provisioner.SignMethod)
signOps, err := p.AuthorizeSign(ctx, "")
if err != nil {
return WrapErrorISE(err, "error retrieving authorization options from ACME provisioner")
}
// Unlike most of the provisioners, ACME's AuthorizeSign method doesn't
// define the templates, and the template data used in WebHooks is not
// available.
for _, signOp := range signOps {
if wc, ok := signOp.(*provisioner.WebhookController); ok {
wc.TemplateData = data
}
}
templateOptions, err := provisioner.CustomTemplateOptions(p.GetOptions(), data, defaultTemplate)
if err != nil {
return WrapErrorISE(err, "error creating template options from ACME provisioner")
}
// Build extra signing options.
signOps = append(signOps, templateOptions)
signOps = append(signOps, extraOptions...)
// Sign a new certificate.
certChain, err := auth.Sign(csr, provisioner.SignOptions{
NotBefore: provisioner.NewTimeDuration(o.NotBefore),
NotAfter: provisioner.NewTimeDuration(o.NotAfter),
}, signOps...)
if err != nil {
return WrapErrorISE(err, "error signing certificate for order %s", o.ID)
}
cert := &Certificate{
AccountID: o.AccountID,
OrderID: o.ID,
Leaf: certChain[0],
Intermediates: certChain[1:],
}
if err := db.CreateCertificate(ctx, cert); err != nil {
return WrapErrorISE(err, "error creating certificate for order %s", o.ID)
}
o.CertificateID = cert.ID
o.Status = StatusValid
if err = db.UpdateOrder(ctx, o); err != nil {
return WrapErrorISE(err, "error updating order %s", o.ID)
}
return nil
}
func (o *Order) subject(csr *x509.CertificateRequest) (subject x509util.Subject, err error) {
wireIDs, otherIDs := 0, 0
for _, identifier := range o.Identifiers {
switch identifier.Type {
case WireID:
wireID, err := wire.ParseID([]byte(identifier.Value))
if err != nil {
return subject, NewErrorISE("unmarshal wireID: %s", err)
}
if csr.Subject.CommonName != wireID.Name {
return subject, NewErrorISE("expected CN %v, found %v", wireID.Name, csr.Subject.CommonName)
}
if len(csr.Subject.Organization) == 0 || !strings.EqualFold(csr.Subject.Organization[0], wireID.Domain) {
return subject, NewErrorISE("expected Organiztion [%s], found %v", wireID.Domain, csr.Subject.Organization)
}
subject.CommonName = wireID.Name
subject.Organization = []string{wireID.Domain}
wireIDs++
default:
}
}
if wireIDs > 0 && otherIDs > 0 || wireIDs > 1 {
return subject, NewErrorISE("at most one WireID can be signed along with no other ID, found %d WireIDs and %d other IDs", wireIDs, otherIDs)
}
return
}
func (o *Order) sans(csr *x509.CertificateRequest) ([]x509util.SubjectAlternativeName, error) {
var sans []x509util.SubjectAlternativeName
if len(csr.EmailAddresses) > 0 {
return sans, NewError(ErrorBadCSRType, "Only DNS names and IP addresses are allowed")
}
// order the DNS names and IP addresses, so that they can be compared against the canonicalized CSR
orderNames := make([]string, numberOfIdentifierType(DNS, o.Identifiers)+2*numberOfIdentifierType(WireID, o.Identifiers))
orderIPs := make([]net.IP, numberOfIdentifierType(IP, o.Identifiers))
orderPIDs := make([]string, numberOfIdentifierType(PermanentIdentifier, o.Identifiers))
orderURIs := make([]string, 2*numberOfIdentifierType(WireID, o.Identifiers))
indexDNS, indexIP, indexPID, indexURI := 0, 0, 0, 0
for _, n := range o.Identifiers {
switch n.Type {
case DNS:
orderNames[indexDNS] = n.Value
indexDNS++
case IP:
orderIPs[indexIP] = net.ParseIP(n.Value) // NOTE: this assumes are all valid IPs at this time; or will result in nil entries
indexIP++
case PermanentIdentifier:
orderPIDs[indexPID] = n.Value
indexPID++
case WireID:
wireID, err := wire.ParseID([]byte(n.Value))
if err != nil {
return sans, NewErrorISE("unsupported identifier value in order: %s", n.Value)
}
orderNames[indexDNS] = wireID.Name
indexDNS++
orderURIs[indexURI] = wireID.ClientID
indexURI++
orderURIs[indexURI] = wireID.Handle
indexURI++
default:
return sans, NewErrorISE("unsupported identifier type in order: %s", n.Type)
}
}
orderNames = uniqueSortedLowerNames(orderNames)
orderIPs = uniqueSortedIPs(orderIPs)
orderURIs = uniqueSortedLowerNames(orderURIs)
totalNumberOfSANs := len(csr.DNSNames) + len(csr.IPAddresses) + len(csr.URIs)
sans = make([]x509util.SubjectAlternativeName, totalNumberOfSANs)
index := 0
// Validate identifier names against CSR alternative names.
//
// Note that with certificate templates we are not going to check for the
// absence of other SANs as they will only be set if the template allows
// them.
if len(csr.DNSNames) != len(orderNames) {
return sans, NewError(ErrorBadCSRType, "CSR names do not match identifiers exactly: "+
"CSR names = %v, Order names = %v", csr.DNSNames, orderNames)
}
for i := range csr.DNSNames {
if csr.DNSNames[i] != orderNames[i] {
return sans, NewError(ErrorBadCSRType, "CSR names do not match identifiers exactly: "+
"CSR names = %v, Order names = %v", csr.DNSNames, orderNames)
}
sans[index] = x509util.SubjectAlternativeName{
Type: x509util.DNSType,
Value: csr.DNSNames[i],
}
index++
}
if len(csr.IPAddresses) != len(orderIPs) {
return sans, NewError(ErrorBadCSRType, "CSR IPs do not match identifiers exactly: "+
"CSR IPs = %v, Order IPs = %v", csr.IPAddresses, orderIPs)
}
for i := range csr.IPAddresses {
if !ipsAreEqual(csr.IPAddresses[i], orderIPs[i]) {
return sans, NewError(ErrorBadCSRType, "CSR IPs do not match identifiers exactly: "+
"CSR IPs = %v, Order IPs = %v", csr.IPAddresses, orderIPs)
}
sans[index] = x509util.SubjectAlternativeName{
Type: x509util.IPType,
Value: csr.IPAddresses[i].String(),
}
index++
}
if len(csr.URIs) != len(orderURIs) {
return sans, NewError(ErrorBadCSRType, "CSR URIs do not match identifiers exactly: "+
"CSR URIs = %v, Order URIs = %v", csr.URIs, orderURIs)
}
// sort URI list
csrURIs := uniqueSortedURIStrings(csr.URIs)
for i := range csrURIs {
if csrURIs[i] != orderURIs[i] {
return sans, NewError(ErrorBadCSRType, "CSR URIs do not match identifiers exactly: "+
"CSR URIs = %v, Order URIs = %v", csr.URIs, orderURIs)
}
sans[index] = x509util.SubjectAlternativeName{
Type: x509util.URIType,
Value: orderURIs[i],
}
index++
}
return sans, nil
}
// numberOfIdentifierType returns the number of Identifiers that
// are of type typ.
func numberOfIdentifierType(typ IdentifierType, ids []Identifier) int {
c := 0
for _, id := range ids {
if id.Type == typ {
c++
}
}
return c
}
// canonicalize canonicalizes a CSR so that it can be compared against an Order
// NOTE: this effectively changes the order of SANs in the CSR, which may be OK,
// but may not be expected. It also adds a Subject Common Name to either the IP
// addresses or DNS names slice, depending on whether it can be parsed as an IP
// or not. This might result in an additional SAN in the final certificate.
func canonicalize(csr *x509.CertificateRequest) (canonicalized *x509.CertificateRequest) {
// for clarity only; we're operating on the same object by pointer
canonicalized = csr
// RFC8555: The CSR MUST indicate the exact same set of requested
// identifiers as the initial newOrder request. Identifiers of type "dns"
// MUST appear either in the commonName portion of the requested subject
// name or in an extensionRequest attribute [RFC2985] requesting a
// subjectAltName extension, or both. Subject Common Names that can be
// parsed as an IP are included as an IP address for the equality check.
// If these were excluded, a certificate could contain an IP as the
// common name without having been challenged.
if csr.Subject.CommonName != "" {
if ip := net.ParseIP(csr.Subject.CommonName); ip != nil {
canonicalized.IPAddresses = append(canonicalized.IPAddresses, ip)
} else {
canonicalized.DNSNames = append(canonicalized.DNSNames, csr.Subject.CommonName)
}
}
canonicalized.DNSNames = uniqueSortedLowerNames(canonicalized.DNSNames)
canonicalized.IPAddresses = uniqueSortedIPs(canonicalized.IPAddresses)
return canonicalized
}
// ipsAreEqual compares IPs to be equal. Nil values (i.e. invalid IPs) are
// not considered equal. IPv6 representations of IPv4 addresses are
// considered equal to the IPv4 address in this implementation, which is
// standard Go behavior. An example is "::ffff:192.168.42.42", which
// is equal to "192.168.42.42". This is considered a known issue within
// step and is tracked here too: https://github.com/golang/go/issues/37921.
func ipsAreEqual(x, y net.IP) bool {
if x == nil || y == nil {
return false
}
return x.Equal(y)
}
// uniqueSortedLowerNames returns the set of all unique names in the input after all
// of them are lowercased. The returned names will be in their lowercased form
// and sorted alphabetically.
func uniqueSortedLowerNames(names []string) (unique []string) {
nameMap := make(map[string]int, len(names))
for _, name := range names {
nameMap[strings.ToLower(name)] = 1
}
unique = make([]string, 0, len(nameMap))
for name := range nameMap {
unique = append(unique, name)
}
sort.Strings(unique)
return
}
func uniqueSortedURIStrings(uris []*url.URL) (unique []string) {
uriMap := make(map[string]struct{}, len(uris))
for _, name := range uris {
uriMap[name.String()] = struct{}{}
}
unique = make([]string, 0, len(uriMap))
for name := range uriMap {
unique = append(unique, name)
}
sort.Strings(unique)
return
}
// uniqueSortedIPs returns the set of all unique net.IPs in the input. They
// are sorted by their bytes (octet) representation.
func uniqueSortedIPs(ips []net.IP) (unique []net.IP) {
type entry struct {
ip net.IP
}
ipEntryMap := make(map[string]entry, len(ips))
for _, ip := range ips {
// reparsing the IP results in the IP being represented using 16 bytes
// for both IPv4 as well as IPv6, even when the ips slice contains IPs that
// are represented by 4 bytes. This ensures a fair comparison and thus ordering.
ipEntryMap[ip.String()] = entry{ip: net.ParseIP(ip.String())}
}
unique = make([]net.IP, 0, len(ipEntryMap))
for _, entry := range ipEntryMap {
unique = append(unique, entry.ip)
}
sort.Slice(unique, func(i, j int) bool {
return bytes.Compare(unique[i], unique[j]) < 0
})
return
}