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f7666d1582
tls servers send a list of certificates for the connection. the first is the leaf certificate. that's the one for the server itself. that's the one we want to verify. the others are intermediate CA's. and possibly even the root CA certificate that it hopes is trusted at the client (though sending it doesn't make it trusted). with dane-ta, the public key of an intermediate or root CA certificate is listed in the TSLA record. when verifying, we add any intermediate/root CA that matches a dane-ta tlsa record to the trusted root CA certs. we should also have added CA certs that didn't match a TLSA record to the "intermediates" of x509.VerifyOptions. because we didn't, x509.Certificate.Verify couldn't verify the chain from the trusted dane-ta ca cert to the leaf cert. we would only properly verify a dane-ta connection correctly if the dane-ta-trusted ca cert was the one immediately following the leaf cert. not when there were one or more additional intermediate certs. this showed when connecting to mx.runbox.com. problem reported by robbo5000 on matrix, thanks!
517 lines
19 KiB
Go
517 lines
19 KiB
Go
// Package dane verifies TLS certificates through DNSSEC-verified TLSA records.
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//
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// On the internet, TLS certificates are commonly verified by checking if they are
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// signed by one of many commonly trusted Certificate Authorities (CAs). This is
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// PKIX or WebPKI. With DANE, TLS certificates are verified through
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// DNSSEC-protected DNS records of type TLSA. These TLSA records specify the rules
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// for verification ("usage") and whether a full certificate ("selector" cert) is
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// checked or only its "subject public key info" ("selector" spki). The (hash of)
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// the certificate or "spki" is included in the TLSA record ("matchtype").
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//
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// DANE SMTP connections have two allowed "usages" (verification rules):
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// - DANE-EE, which only checks if the certificate or spki match, without the
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// WebPKI verification of expiration, name or signed-by-trusted-party verification.
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// - DANE-TA, which does verification similar to PKIX/WebPKI, but verifies against
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// a certificate authority ("trust anchor", or "TA") specified in the TLSA record
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// instead of the CA pool.
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//
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// DANE has two more "usages", that may be used with protocols other than SMTP:
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// - PKIX-EE, which matches the certificate or spki, and also verifies the
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// certificate against the CA pool.
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// - PKIX-TA, which verifies the certificate or spki against a "trust anchor"
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// specified in the TLSA record, that also has to be trusted by the CA pool.
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//
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// TLSA records are looked up for a specific port number, protocol (tcp/udp) and
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// host name. Each port can have different TLSA records. TLSA records must be
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// signed and verified with DNSSEC before they can be trusted and used.
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//
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// TLSA records are looked up under "TLSA candidate base domains". The domain
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// where the TLSA records are found is the "TLSA base domain". If the host to
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// connect to is a CNAME that can be followed with DNSSEC protection, it is the
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// first TLSA candidate base domain. If no protected records are found, the
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// original host name is the second TLSA candidate base domain.
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//
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// For TLS connections, the TLSA base domain is used with SNI during the
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// handshake.
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//
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// For TLS certificate verification that requires PKIX/WebPKI/trusted-anchor
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// verification (all except DANE-EE), the potential second TLSA candidate base
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// domain name is also a valid hostname. With SMTP, additionally for hosts found in
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// MX records for a "next-hop domain", the "original next-hop domain" (domain of an
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// email address to deliver to) is also a valid name, as is the "CNAME-expanded
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// original next-hop domain", bringing the potential total allowed names to four
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// (if CNAMEs are followed for the MX hosts).
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package dane
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// todo: why is https://datatracker.ietf.org/doc/html/draft-barnes-dane-uks-00 not in use? sounds reasonable.
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// todo: add a DialSRV function that accepts a domain name, looks up srv records, dials the service, verifies dane certificate and returns the connection. for ../rfc/7673
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import (
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"bytes"
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"context"
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"crypto/sha256"
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"crypto/sha512"
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"crypto/tls"
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"crypto/x509"
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"errors"
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"fmt"
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"log/slog"
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"net"
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"strings"
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"time"
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"github.com/mjl-/adns"
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"github.com/mjl-/mox/dns"
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"github.com/mjl-/mox/mlog"
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"github.com/mjl-/mox/stub"
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)
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var (
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MetricVerify stub.Counter = stub.CounterIgnore{}
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MetricVerifyErrors stub.Counter = stub.CounterIgnore{}
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)
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var (
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// ErrNoRecords means no TLSA records were found and host has not opted into DANE.
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ErrNoRecords = errors.New("dane: no tlsa records")
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// ErrInsecure indicates insecure DNS responses were encountered while looking up
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// the host, CNAME records, or TLSA records.
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ErrInsecure = errors.New("dane: dns lookups insecure")
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// ErrNoMatch means some TLSA records were found, but none can be verified against
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// the remote TLS certificate.
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ErrNoMatch = errors.New("dane: no match between certificate and tlsa records")
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)
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// VerifyError is an error encountered while verifying a DANE TLSA record. For
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// example, an error encountered with x509 certificate trusted-anchor verification.
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// A TLSA record that does not match a TLS certificate is not a VerifyError.
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type VerifyError struct {
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Err error // Underlying error, possibly from crypto/x509.
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Record adns.TLSA // Cause of error.
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}
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// Error returns a string explaining this is a dane verify error along with the
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// underlying error.
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func (e VerifyError) Error() string {
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return fmt.Sprintf("dane verify error: %s", e.Err)
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}
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// Unwrap returns the underlying error.
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func (e VerifyError) Unwrap() error {
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return e.Err
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}
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// Dial looks up DNSSEC-protected DANE TLSA records for the domain name and
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// port/service in address, checks for allowed usages, makes a network connection
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// and verifies the remote certificate against the TLSA records. If verification
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// succeeds, the verified record is returned.
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//
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// Different protocols require different usages. For example, SMTP with STARTTLS
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// for delivery only allows usages DANE-TA and DANE-EE. If allowedUsages is
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// non-nil, only the specified usages are taken into account when verifying, and
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// any others ignored.
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//
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// Errors that can be returned, possibly in wrapped form:
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// - ErrNoRecords, also in case the DNS response indicates "not found".
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// - adns.DNSError, potentially wrapping adns.ExtendedError of which some can
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// indicate DNSSEC errors.
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// - ErrInsecure
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// - VerifyError, potentially wrapping errors from crypto/x509.
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func Dial(ctx context.Context, elog *slog.Logger, resolver dns.Resolver, network, address string, allowedUsages []adns.TLSAUsage, pkixRoots *x509.CertPool) (net.Conn, adns.TLSA, error) {
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log := mlog.New("dane", elog)
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// Split host and port.
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host, portstr, err := net.SplitHostPort(address)
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if err != nil {
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return nil, adns.TLSA{}, fmt.Errorf("parsing address: %w", err)
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}
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port, err := resolver.LookupPort(ctx, network, portstr)
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if err != nil {
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return nil, adns.TLSA{}, fmt.Errorf("parsing port: %w", err)
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}
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hostDom, err := dns.ParseDomain(strings.TrimSuffix(host, "."))
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if err != nil {
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return nil, adns.TLSA{}, fmt.Errorf("parsing host: %w", err)
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}
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// ../rfc/7671:1015
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// First follow CNAMEs for host. If the path to the final name is secure, we must
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// lookup TLSA there first, then fallback to the original name. If the final name
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// is secure that's also the SNI server name we must use, with the original name as
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// allowed host during certificate name checks (for all TLSA usages other than
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// DANE-EE).
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cnameDom := hostDom
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cnameAuthentic := true
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for i := 0; ; i += 1 {
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if i == 10 {
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return nil, adns.TLSA{}, fmt.Errorf("too many cname lookups")
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}
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cname, cnameResult, err := resolver.LookupCNAME(ctx, cnameDom.ASCII+".")
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cnameAuthentic = cnameAuthentic && cnameResult.Authentic
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if !cnameResult.Authentic && i == 0 {
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return nil, adns.TLSA{}, fmt.Errorf("%w: cname lookup insecure", ErrInsecure)
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} else if dns.IsNotFound(err) {
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break
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} else if err != nil {
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return nil, adns.TLSA{}, fmt.Errorf("resolving cname %s: %w", cnameDom, err)
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} else if d, err := dns.ParseDomain(strings.TrimSuffix(cname, ".")); err != nil {
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return nil, adns.TLSA{}, fmt.Errorf("parsing cname: %w", err)
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} else {
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cnameDom = d
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}
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}
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// We lookup the IP.
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ipnetwork := "ip"
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if strings.HasSuffix(network, "4") {
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ipnetwork += "4"
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} else if strings.HasSuffix(network, "6") {
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ipnetwork += "6"
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}
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ips, _, err := resolver.LookupIP(ctx, ipnetwork, cnameDom.ASCII+".")
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// note: For SMTP with opportunistic DANE we would stop here with an insecure
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// response. But as long as long as we have a verified original tlsa base name, we
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// can continue with regular DANE.
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if err != nil {
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return nil, adns.TLSA{}, fmt.Errorf("resolving ips: %w", err)
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} else if len(ips) == 0 {
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return nil, adns.TLSA{}, &adns.DNSError{Err: "no ips for host", Name: cnameDom.ASCII, IsNotFound: true}
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}
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// Lookup TLSA records. If resolving CNAME was secure, we try that first. Otherwise
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// we try at the secure original domain.
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baseDom := hostDom
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if cnameAuthentic {
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baseDom = cnameDom
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}
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var records []adns.TLSA
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var result adns.Result
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for {
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var err error
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records, result, err = resolver.LookupTLSA(ctx, port, network, baseDom.ASCII+".")
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// If no (secure) records can be found at the final cname, and there is an original
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// name, try at original name.
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// ../rfc/7671:1015
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if baseDom != hostDom && (dns.IsNotFound(err) || !result.Authentic) {
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baseDom = hostDom
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continue
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}
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if !result.Authentic {
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return nil, adns.TLSA{}, ErrInsecure
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} else if dns.IsNotFound(err) {
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return nil, adns.TLSA{}, ErrNoRecords
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} else if err != nil {
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return nil, adns.TLSA{}, fmt.Errorf("lookup dane tlsa records: %w", err)
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}
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break
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}
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// Keep only the allowed usages.
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if allowedUsages != nil {
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o := 0
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for _, r := range records {
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for _, usage := range allowedUsages {
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if r.Usage == usage {
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records[o] = r
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o++
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break
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}
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}
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}
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records = records[:o]
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if len(records) == 0 {
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// No point in dialing when we know we won't be able to verify the remote TLS
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// certificate.
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return nil, adns.TLSA{}, fmt.Errorf("no usable tlsa records remaining: %w", ErrNoMatch)
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}
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}
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// We use the base domain for SNI, allowing the original domain as well.
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// ../rfc/7671:1021
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var moreAllowedHosts []dns.Domain
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if baseDom != hostDom {
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moreAllowedHosts = []dns.Domain{hostDom}
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}
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// Dial the remote host.
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timeout := 30 * time.Second
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if deadline, ok := ctx.Deadline(); ok && len(ips) > 0 {
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timeout = time.Until(deadline) / time.Duration(len(ips))
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}
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dialer := &net.Dialer{Timeout: timeout}
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var conn net.Conn
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var dialErrs []error
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for _, ip := range ips {
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addr := net.JoinHostPort(ip.String(), portstr)
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c, err := dialer.DialContext(ctx, network, addr)
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if err != nil {
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dialErrs = append(dialErrs, err)
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continue
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}
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conn = c
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break
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}
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if conn == nil {
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return nil, adns.TLSA{}, errors.Join(dialErrs...)
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}
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var verifiedRecord adns.TLSA
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config := TLSClientConfig(log.Logger, records, baseDom, moreAllowedHosts, &verifiedRecord, pkixRoots)
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tlsConn := tls.Client(conn, &config)
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if err := tlsConn.HandshakeContext(ctx); err != nil {
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conn.Close()
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return nil, adns.TLSA{}, err
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}
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return tlsConn, verifiedRecord, nil
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}
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// TLSClientConfig returns a tls.Config to be used for dialing/handshaking a
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// TLS connection with DANE verification.
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//
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// Callers should only pass records that are allowed for the intended use. DANE
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// with SMTP only allows DANE-EE and DANE-TA usages, not the PKIX-usages.
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//
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// The config has InsecureSkipVerify set to true, with a custom VerifyConnection
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// function for verifying DANE. Its VerifyConnection can return ErrNoMatch and
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// additionally one or more (wrapped) errors of type VerifyError.
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//
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// The TLS config uses allowedHost for SNI.
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//
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// If verifiedRecord is not nil, it is set to the record that was successfully
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// verified, if any.
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func TLSClientConfig(elog *slog.Logger, records []adns.TLSA, allowedHost dns.Domain, moreAllowedHosts []dns.Domain, verifiedRecord *adns.TLSA, pkixRoots *x509.CertPool) tls.Config {
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log := mlog.New("dane", elog)
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return tls.Config{
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ServerName: allowedHost.ASCII, // For SNI.
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InsecureSkipVerify: true,
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VerifyConnection: func(cs tls.ConnectionState) error {
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verified, record, err := Verify(log.Logger, records, cs, allowedHost, moreAllowedHosts, pkixRoots)
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log.Debugx("dane verification", err, slog.Bool("verified", verified), slog.Any("record", record))
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if verified {
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if verifiedRecord != nil {
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*verifiedRecord = record
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}
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return nil
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} else if err == nil {
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return ErrNoMatch
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}
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return fmt.Errorf("%w, and error(s) encountered during verification: %w", ErrNoMatch, err)
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},
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MinVersion: tls.VersionTLS12, // ../rfc/8996:31 ../rfc/8997:66
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}
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}
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// Verify checks if the TLS connection state can be verified against DANE TLSA
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// records.
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//
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// allowedHost along with the optional moreAllowedHosts are the host names that are
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// allowed during certificate verification (as used by PKIX-TA, PKIX-EE, DANE-TA,
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// but not DANE-EE). A typical connection would allow just one name, but some uses
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// of DANE allow multiple, like SMTP which allow up to four valid names for a TLS
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// certificate based on MX/CNAME/TLSA/DNSSEC lookup results.
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//
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// When one of the records matches, Verify returns true, along with the matching
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// record and a nil error.
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// If there is no match, then in the typical case Verify returns: false, a zero
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// record value and a nil error.
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// If an error is encountered while verifying a record, e.g. for x509
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// trusted-anchor verification, an error may be returned, typically one or more
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// (wrapped) errors of type VerifyError.
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//
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// Verify is useful when DANE verification and its results has to be done
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// separately from other validation, e.g. for MTA-STS. The caller can create a
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// tls.Config with a VerifyConnection function that checks DANE and MTA-STS
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// separately.
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func Verify(elog *slog.Logger, records []adns.TLSA, cs tls.ConnectionState, allowedHost dns.Domain, moreAllowedHosts []dns.Domain, pkixRoots *x509.CertPool) (verified bool, matching adns.TLSA, rerr error) {
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log := mlog.New("dane", elog)
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MetricVerify.Inc()
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if len(records) == 0 {
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MetricVerifyErrors.Inc()
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return false, adns.TLSA{}, fmt.Errorf("verify requires at least one tlsa record")
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}
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var errs []error
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for _, r := range records {
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ok, err := verifySingle(log, r, cs, allowedHost, moreAllowedHosts, pkixRoots)
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if err != nil {
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errs = append(errs, VerifyError{err, r})
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} else if ok {
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return true, r, nil
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}
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}
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MetricVerifyErrors.Inc()
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return false, adns.TLSA{}, errors.Join(errs...)
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}
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// verifySingle verifies the TLS connection against a single DANE TLSA record.
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//
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// If the remote TLS certificate matches with the TLSA record, true is
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// returned. Errors may be encountered while verifying, e.g. when checking one
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// of the allowed hosts against a TLSA record. A typical non-matching/verified
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// TLSA record returns a nil error. But in some cases, e.g. when encountering
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// errors while verifying certificates against a trust-anchor, an error can be
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// returned with one or more underlying x509 verification errors. A nil-nil error
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// is only returned when verified is false.
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func verifySingle(log mlog.Log, tlsa adns.TLSA, cs tls.ConnectionState, allowedHost dns.Domain, moreAllowedHosts []dns.Domain, pkixRoots *x509.CertPool) (verified bool, rerr error) {
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if len(cs.PeerCertificates) == 0 {
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return false, fmt.Errorf("no server certificate")
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}
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match := func(cert *x509.Certificate) bool {
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var buf []byte
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switch tlsa.Selector {
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case adns.TLSASelectorCert:
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buf = cert.Raw
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case adns.TLSASelectorSPKI:
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buf = cert.RawSubjectPublicKeyInfo
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default:
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return false
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}
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switch tlsa.MatchType {
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case adns.TLSAMatchTypeFull:
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case adns.TLSAMatchTypeSHA256:
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d := sha256.Sum256(buf)
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buf = d[:]
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case adns.TLSAMatchTypeSHA512:
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d := sha512.Sum512(buf)
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buf = d[:]
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default:
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return false
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}
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return bytes.Equal(buf, tlsa.CertAssoc)
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}
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pkixVerify := func(host dns.Domain) ([][]*x509.Certificate, error) {
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// Default Verify checks for expiration. We pass the host name to check. And we
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// configure the intermediates. The roots are filled in by the x509 package.
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opts := x509.VerifyOptions{
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DNSName: host.ASCII,
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Intermediates: x509.NewCertPool(),
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Roots: pkixRoots,
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}
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for _, cert := range cs.PeerCertificates[1:] {
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opts.Intermediates.AddCert(cert)
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}
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chains, err := cs.PeerCertificates[0].Verify(opts)
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return chains, err
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}
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switch tlsa.Usage {
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case adns.TLSAUsagePKIXTA:
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// We cannot get at the system trusted ca certificates to look for the trusted
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// anchor. So we just ask Go to verify, then see if any of the chains include the
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// ca certificate.
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var errs []error
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for _, host := range append([]dns.Domain{allowedHost}, moreAllowedHosts...) {
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chains, err := pkixVerify(host)
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log.Debugx("pkix-ta verify", err)
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if err != nil {
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errs = append(errs, err)
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continue
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}
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// The chains by x509's Verify should include the longest possible match, so it is
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// sure to include the trusted anchor. ../rfc/7671:835
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for _, chain := range chains {
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// If pkix verified, check if any of the certificates match.
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for i := len(chain) - 1; i >= 0; i-- {
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if match(chain[i]) {
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return true, nil
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}
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}
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}
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}
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return false, errors.Join(errs...)
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case adns.TLSAUsagePKIXEE:
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|
// Check for a certificate match.
|
|
if !match(cs.PeerCertificates[0]) {
|
|
return false, nil
|
|
}
|
|
// And do regular pkix checks, ../rfc/7671:799
|
|
var errs []error
|
|
for _, host := range append([]dns.Domain{allowedHost}, moreAllowedHosts...) {
|
|
_, err := pkixVerify(host)
|
|
log.Debugx("pkix-ee verify", err)
|
|
if err == nil {
|
|
return true, nil
|
|
}
|
|
errs = append(errs, err)
|
|
}
|
|
return false, errors.Join(errs...)
|
|
|
|
case adns.TLSAUsageDANETA:
|
|
// We set roots, so the system defaults don't get used. Verify checks the host name
|
|
// (set below) and checks for expiration.
|
|
opts := x509.VerifyOptions{
|
|
Intermediates: x509.NewCertPool(),
|
|
Roots: x509.NewCertPool(),
|
|
}
|
|
|
|
// If the full certificate was included, we must add it to the valid roots, the TLS
|
|
// server may not send it. ../rfc/7671:692
|
|
var found bool
|
|
if tlsa.Selector == adns.TLSASelectorCert && tlsa.MatchType == adns.TLSAMatchTypeFull {
|
|
cert, err := x509.ParseCertificate(tlsa.CertAssoc)
|
|
if err != nil {
|
|
log.Debugx("parsing full exact certificate from tlsa record to use as root for usage dane-trusted-anchor", err)
|
|
// Continue anyway, perhaps the servers sends it again in a way that the tls package can parse? (unlikely)
|
|
} else {
|
|
opts.Roots.AddCert(cert)
|
|
found = true
|
|
}
|
|
}
|
|
|
|
for i, cert := range cs.PeerCertificates {
|
|
if match(cert) {
|
|
opts.Roots.AddCert(cert)
|
|
found = true
|
|
break
|
|
} else if i > 0 {
|
|
opts.Intermediates.AddCert(cert)
|
|
}
|
|
}
|
|
if !found {
|
|
// Trusted anchor was not found in TLS certificates so we won't be able to
|
|
// verify.
|
|
return false, nil
|
|
}
|
|
|
|
// Trusted anchor was found, still need to verify.
|
|
var errs []error
|
|
for _, host := range append([]dns.Domain{allowedHost}, moreAllowedHosts...) {
|
|
opts.DNSName = host.ASCII
|
|
_, err := cs.PeerCertificates[0].Verify(opts)
|
|
if err == nil {
|
|
return true, nil
|
|
}
|
|
errs = append(errs, err)
|
|
}
|
|
return false, errors.Join(errs...)
|
|
|
|
case adns.TLSAUsageDANEEE:
|
|
// ../rfc/7250 is about raw public keys instead of x.509 certificates in tls
|
|
// handshakes. Go's crypto/tls does not implement the extension (see
|
|
// crypto/tls/common.go, the extensions values don't appear in the
|
|
// rfc, but have values 19 and 20 according to
|
|
// https://www.iana.org/assignments/tls-extensiontype-values/tls-extensiontype-values.xhtml#tls-extensiontype-values-1
|
|
// ../rfc/7671:1148 mentions the raw public keys are allowed. It's still
|
|
// questionable that this is commonly implemented. For now the world can probably
|
|
// live with an ignored certificate wrapped around the subject public key info.
|
|
|
|
// We don't verify host name in certificate, ../rfc/7671:489
|
|
// And we don't check for expiration. ../rfc/7671:527
|
|
// The whole point of this type is to have simple secure infrastructure that
|
|
// doesn't automatically expire (at the most inconvenient times).
|
|
return match(cs.PeerCertificates[0]), nil
|
|
|
|
default:
|
|
// Unknown, perhaps defined in the future. Not an error.
|
|
log.Debug("unrecognized tlsa usage, skipping", slog.Any("tlsausage", tlsa.Usage))
|
|
return false, nil
|
|
}
|
|
}
|