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// Copyright 2015 The Chromium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "verify_certificate_chain.h"
#include <algorithm>
#include <cassert>
#include "cert_error_params.h"
#include "cert_errors.h"
#include "common_cert_errors.h"
#include "extended_key_usage.h"
#include "name_constraints.h"
#include "parse_certificate.h"
#include "signature_algorithm.h"
#include "trust_store.h"
#include "verify_signed_data.h"
#include "input.h"
namespace bssl {
namespace {
bool IsHandledCriticalExtension(const ParsedExtension& extension,
const ParsedCertificate& cert) {
if (extension.oid == der::Input(kBasicConstraintsOid))
return true;
// Key Usage is NOT processed for end-entity certificates (this is the
// responsibility of callers), however it is considered "handled" here in
// order to allow being marked as critical.
if (extension.oid == der::Input(kKeyUsageOid))
return true;
if (extension.oid == der::Input(kExtKeyUsageOid))
return true;
if (extension.oid == der::Input(kNameConstraintsOid))
return true;
if (extension.oid == der::Input(kSubjectAltNameOid))
return true;
if (extension.oid == der::Input(kCertificatePoliciesOid)) {
// Policy qualifiers are skipped during processing, so if the
// extension is marked critical need to ensure there weren't any
// qualifiers other than User Notice / CPS.
//
// This follows from RFC 5280 section 4.2.1.4:
//
// If this extension is critical, the path validation software MUST
// be able to interpret this extension (including the optional
// qualifier), or MUST reject the certificate.
std::vector<der::Input> unused_policies;
CertErrors unused_errors;
return ParseCertificatePoliciesExtensionOids(
extension.value, true /*fail_parsing_unknown_qualifier_oids*/,
&unused_policies, &unused_errors);
// TODO(eroman): Give a better error message.
}
if (extension.oid == der::Input(kPolicyMappingsOid))
return true;
if (extension.oid == der::Input(kPolicyConstraintsOid))
return true;
if (extension.oid == der::Input(kInhibitAnyPolicyOid))
return true;
if (extension.oid == der::Input(kMSApplicationPoliciesOid)) {
// Per https://crbug.com/1439638 and
// https://learn.microsoft.com/en-us/windows/win32/seccertenroll/supported-extensions#msapplicationpolicies
// The MSApplicationPolicies extension may be ignored if the
// extendedKeyUsage extension is also present.
return cert.has_extended_key_usage();
}
return false;
}
// Adds errors to |errors| if the certificate contains unconsumed _critical_
// extensions.
void VerifyNoUnconsumedCriticalExtensions(const ParsedCertificate& cert,
CertErrors* errors) {
for (const auto& it : cert.extensions()) {
const ParsedExtension& extension = it.second;
if (extension.critical && !IsHandledCriticalExtension(extension, cert)) {
errors->AddError(cert_errors::kUnconsumedCriticalExtension,
CreateCertErrorParams2Der("oid", extension.oid, "value",
extension.value));
}
}
}
// Returns true if |cert| was self-issued. The definition of self-issuance
// comes from RFC 5280 section 6.1:
//
// A certificate is self-issued if the same DN appears in the subject
// and issuer fields (the two DNs are the same if they match according
// to the rules specified in Section 7.1). In general, the issuer and
// subject of the certificates that make up a path are different for
// each certificate. However, a CA may issue a certificate to itself to
// support key rollover or changes in certificate policies. These
// self-issued certificates are not counted when evaluating path length
// or name constraints.
[[nodiscard]] bool IsSelfIssued(const ParsedCertificate& cert) {
return cert.normalized_subject() == cert.normalized_issuer();
}
// Adds errors to |errors| if |cert| is not valid at time |time|.
//
// The certificate's validity requirements are described by RFC 5280 section
// 4.1.2.5:
//
// The validity period for a certificate is the period of time from
// notBefore through notAfter, inclusive.
void VerifyTimeValidity(const ParsedCertificate& cert,
const der::GeneralizedTime& time,
CertErrors* errors) {
if (time < cert.tbs().validity_not_before)
errors->AddError(cert_errors::kValidityFailedNotBefore);
if (cert.tbs().validity_not_after < time)
errors->AddError(cert_errors::kValidityFailedNotAfter);
}
// Adds errors to |errors| if |cert| has internally inconsistent signature
// algorithms.
//
// X.509 certificates contain two different signature algorithms:
// (1) The signatureAlgorithm field of Certificate
// (2) The signature field of TBSCertificate
//
// According to RFC 5280 section 4.1.1.2 and 4.1.2.3 these two fields must be
// equal:
//
// This field MUST contain the same algorithm identifier as the
// signature field in the sequence tbsCertificate (Section 4.1.2.3).
//
// The spec is not explicit about what "the same algorithm identifier" means.
// Our interpretation is that the two DER-encoded fields must be byte-for-byte
// identical.
//
// In practice however there are certificates which use different encodings for
// specifying RSA with SHA1 (different OIDs). This is special-cased for
// compatibility sake.
bool VerifySignatureAlgorithmsMatch(const ParsedCertificate& cert,
CertErrors* errors) {
const der::Input& alg1_tlv = cert.signature_algorithm_tlv();
const der::Input& alg2_tlv = cert.tbs().signature_algorithm_tlv;
// Ensure that the two DER-encoded signature algorithms are byte-for-byte
// equal.
if (alg1_tlv == alg2_tlv)
return true;
// But make a compatibility concession if alternate encodings are used
// TODO(eroman): Turn this warning into an error.
// TODO(eroman): Add a unit-test that exercises this case.
std::optional<SignatureAlgorithm> alg1 = ParseSignatureAlgorithm(alg1_tlv);
if (!alg1) {
errors->AddError(cert_errors::kUnacceptableSignatureAlgorithm);
return false;
}
std::optional<SignatureAlgorithm> alg2 = ParseSignatureAlgorithm(alg2_tlv);
if (!alg2) {
errors->AddError(cert_errors::kUnacceptableSignatureAlgorithm);
return false;
}
if (*alg1 == *alg2) {
errors->AddWarning(
cert_errors::kSignatureAlgorithmsDifferentEncoding,
CreateCertErrorParams2Der("Certificate.algorithm", alg1_tlv,
"TBSCertificate.signature", alg2_tlv));
return true;
}
errors->AddError(
cert_errors::kSignatureAlgorithmMismatch,
CreateCertErrorParams2Der("Certificate.algorithm", alg1_tlv,
"TBSCertificate.signature", alg2_tlv));
return false;
}
// Verify that |cert| can be used for |required_key_purpose|.
void VerifyExtendedKeyUsage(const ParsedCertificate& cert,
KeyPurpose required_key_purpose,
CertErrors* errors,
bool is_target_cert,
bool is_target_cert_issuer) {
// We treat a required KeyPurpose of ANY_EKU to mean "Do not check EKU"
if (required_key_purpose == KeyPurpose::ANY_EKU) {
return;
}
bool has_any_eku = false;
bool has_server_auth_eku = false;
bool has_client_auth_eku = false;
bool has_code_signing_eku = false;
bool has_time_stamping_eku = false;
bool has_ocsp_signing_eku = false;
bool has_nsgc = false;
if (cert.has_extended_key_usage()) {
for (const auto& key_purpose_oid : cert.extended_key_usage()) {
if (key_purpose_oid == der::Input(kAnyEKU)) {
has_any_eku = true;
}
if (key_purpose_oid == der::Input(kServerAuth)) {
has_server_auth_eku = true;
}
if (key_purpose_oid == der::Input(kClientAuth)) {
has_client_auth_eku = true;
}
if (key_purpose_oid == der::Input(kCodeSigning)) {
has_code_signing_eku = true;
}
if (key_purpose_oid == der::Input(kTimeStamping)) {
has_time_stamping_eku = true;
}
if (key_purpose_oid == der::Input(kOCSPSigning)) {
has_ocsp_signing_eku = true;
}
if (key_purpose_oid == der::Input(kNetscapeServerGatedCrypto)) {
has_nsgc = true;
}
}
}
auto add_error_if_strict = [&](CertErrorId id) {
if (required_key_purpose == KeyPurpose::SERVER_AUTH_STRICT ||
required_key_purpose == KeyPurpose::CLIENT_AUTH_STRICT) {
errors->AddError(id);
} else {
errors->AddWarning(id);
}
};
if (is_target_cert) {
// Loosely based upon CABF BR version 1.8.4, 7.1.2.3(f). We are more
// permissive in that we still allow EKU any to be present in a leaf
// certificate, but we ignore it for purposes of server or client auth. We
// are less permissive in that we prohibit Code Signing, OCSP Signing, and
// Time Stamping which are currently only a SHOULD NOT. The BR does
// explicitly allow Email authentication to be present, as this still exists
// in the wild (2022), so we do not prohibit Email authentication here (and
// by extension must allow it to be present in the signer, below).
if (!cert.has_extended_key_usage()) {
// This is added as a warning, an error will be added in STRICT modes
// if we then lack client or server auth due to this not being present.
errors->AddWarning(cert_errors::kEkuNotPresent);
} else {
if (has_code_signing_eku) {
add_error_if_strict(cert_errors::kEkuHasProhibitedCodeSigning);
}
if (has_ocsp_signing_eku) {
add_error_if_strict(cert_errors::kEkuHasProhibitedOCSPSigning);
}
if (has_time_stamping_eku) {
add_error_if_strict(cert_errors::kEkuHasProhibitedTimeStamping);
}
}
} else if (is_target_cert_issuer) {
// Handle the decision to overload EKU as a constraint on issuers.
//
// CABF BR version 1.8.4, 7.1.2.2(g) pertains to the case of "Certs used to
// issue TLS certificates", While the BR refers to the entire chain of
// intermediates, there are a number of exceptions regarding CA ownership
// and cross signing which are impossible for us to know or enforce here.
// Therefore, we can only enforce at the level of the intermediate that
// issued our target certificate. This means we we differ in the following
// ways:
// - We only enforce at the issuer of the TLS certificate.
// - We allow email protection to exist in the issuer, since without
// this it can not be allowed in the client (other than via EKU any))
// - As in the leaf certificate case, we allow EKU any to be present, but
// we ignore it for the purposes of server or client auth.
//
// At this time (until at least 2023) some intermediates are lacking EKU in
// the world at large from common CA's, so we allow the noEKU case to permit
// everything.
// TODO(bbe): enforce requiring EKU in the issuer when we can manage it.
if (cert.has_extended_key_usage()) {
if (has_code_signing_eku) {
add_error_if_strict(cert_errors::kEkuHasProhibitedCodeSigning);
}
if (has_time_stamping_eku) {
add_error_if_strict(cert_errors::kEkuHasProhibitedTimeStamping);
}
}
}
// Otherwise, we are a parent of an issuer of a TLS certificate. The CABF
// BR version 1.8.4, 7.1.2.2(g) goes as far as permitting EKU any in certain
// cases of Cross Signing and CA Ownership, having permitted cases where EKU
// is permitted to not be present at all. These cases are not practical to
// differentiate here and therefore we don't attempt to enforce any further
// EKU "constraints" on such certificates. Unlike the above cases we also
// allow the use of EKU any for client or server auth constraint purposes.
switch (required_key_purpose) {
case KeyPurpose::ANY_EKU:
assert(0); // NOTREACHED
return;
case KeyPurpose::SERVER_AUTH:
case KeyPurpose::SERVER_AUTH_STRICT: {
bool nsgc_hack = false;
if (has_any_eku && !has_server_auth_eku) {
if (is_target_cert || is_target_cert_issuer) {
errors->AddWarning(cert_errors::kEkuLacksServerAuthButHasAnyEKU);
} else {
// Accept anyEKU for server auth below target issuer.
has_server_auth_eku = true;
}
}
if (is_target_cert_issuer && !cert.has_extended_key_usage()) {
// Accept noEKU for server auth in target issuer.
// TODO(bbe): remove this once BR requirements catch up with CA's.
has_server_auth_eku = true;
}
if (has_nsgc && !has_server_auth_eku) {
errors->AddWarning(cert_errors::kEkuLacksServerAuthButHasGatedCrypto);
// Allow NSGC for legacy RSA SHA1 intermediates, for compatibility
// with platform verifiers.
//
// In practice the chain will be rejected with or without this
// compatibility hack. The difference is whether the final error will
// be ERR_CERT_WEAK_SIGNATURE_ALGORITHM (with compatibility hack) vs
// ERR_CERT_INVALID (without hack).
//
// TODO(https://crbug.com/843735): Remove this once error-for-error
// equivalence between builtin verifier and platform verifier is less
// important.
if ((cert.has_basic_constraints() && cert.basic_constraints().is_ca) &&
cert.signature_algorithm() == SignatureAlgorithm::kRsaPkcs1Sha1) {
nsgc_hack = true;
}
}
if (required_key_purpose == KeyPurpose::SERVER_AUTH) {
// Legacy compatible.
if (cert.has_extended_key_usage() && !has_server_auth_eku &&
!has_any_eku && !nsgc_hack) {
errors->AddError(cert_errors::kEkuLacksServerAuth);
}
} else {
if (!has_server_auth_eku) {
errors->AddError(cert_errors::kEkuLacksServerAuth);
}
}
break;
}
case KeyPurpose::CLIENT_AUTH:
case KeyPurpose::CLIENT_AUTH_STRICT: {
if (has_any_eku && !has_client_auth_eku) {
if (is_target_cert || is_target_cert_issuer) {
errors->AddWarning(cert_errors::kEkuLacksClientAuthButHasAnyEKU);
} else {
// accept anyEKU for client auth.
has_client_auth_eku = true;
}
}
if (required_key_purpose == KeyPurpose::CLIENT_AUTH) {
// Legacy-compatible.
if (cert.has_extended_key_usage() && !has_client_auth_eku &&
!has_any_eku) {
errors->AddError(cert_errors::kEkuLacksClientAuth);
}
} else {
if (!has_client_auth_eku) {
errors->AddError(cert_errors::kEkuLacksClientAuth);
}
}
break;
}
}
}
// Representation of RFC 5280's "valid_policy_tree", used to keep track of the
// valid policies and policy re-mappings. This structure is defined in
// section 6.1.2.
//
// ValidPolicyGraph differs from RFC 5280's description in that:
//
// (1) It does not track "qualifier_set". This is not needed as it is not
// output by this implementation.
//
// (2) It builds a directed acyclic graph, rather than a tree. When a given
// policy matches multiple parents, RFC 5280 makes a separate node for
// each parent. This representation condenses them into one node with
// multiple parents.
//
// (3) It does not track "expected_policy_set" or anyPolicy nodes directly.
// Rather it maintains, only for the most recent level, whether there is an
// anyPolicy node and an inverted map of all "expected_policy_set" values.
//
// (4) Some pruning steps are deferred to when policies are evaluated, as a
// reachability pass.
class ValidPolicyGraph {
public:
ValidPolicyGraph() = default;
ValidPolicyGraph(const ValidPolicyGraph&) = delete;
ValidPolicyGraph& operator=(const ValidPolicyGraph&) = delete;
// A Node is an entry in the policy graph. It contains information about some
// policy asserted by a certificate in the chain. The policy OID itself is
// omitted because it is the key in the Level map.
struct Node {
// The list of "valid_policy" values for all nodes which are a parent of
// this node, other than anyPolicy. If empty, this node has a single parent,
// anyPolicy.
//
// Nodes whose parent is anyPolicy are root policies, and may be returned
// in the authorities-constrained-policy-set. Nodes with a concrete policy
// as a parent are derived from that policy in the issuer certificate,
// possibly with a policy mapping applied.
//
// Note it is not possible for a policy to have both anyPolicy and a
// concrete policy as a parent. Section 6.1.3, step d.1.ii only runs if
// there was no match in step d.1.i.
std::vector<der::Input> parent_policies;
// Whether this node matches a policy mapping in the certificate. If true,
// its "expected_policy_set" comes from the policy mappings extension. If
// false, its "expected_policy_set" is itself.
bool mapped = false;
// Whether this node is reachable from some valid policy in the end-entity
// certificate. Computed during GetValidRootPolicySet().
bool reachable = false;
};
// The policy graph is organized into "levels", each corresponding to a
// certificate in the chain. We maintain a map from "valid_policy" to the
// corresponding Node. This is the set of policies asserted by this
// certificate. The special anyPolicy OID is handled separately below.
using Level = std::map<der::Input, Node>;
// Additional per-level information that only needs to be maintained for the
// bottom-most level.
struct LevelDetails {
// Maintains the "expected_policy_set" values for nodes in a level of the
// graph, but the map is inverted from RFC 5280's formulation. For a given
// policy OID P, other than anyPolicy, this map gives the set of nodes where
// P appears in the node's "expected_policy_set". anyPolicy is handled
// separately below.
std::map<der::Input, std::vector<der::Input>> expected_policy_map;
// Whether there is a node at this level whose "valid_policy" is anyPolicy.
//
// Note anyPolicy's "expected_policy_set" always {anyPolicy}, and anyPolicy
// will never appear in the "expected_policy_set" of any other policy. That
// means this field also captures how anyPolicy appears in
// "expected_policy_set".
bool has_any_policy = false;
};
// Initializes the ValidPolicyGraph.
void Init() {
SetNull();
StartLevel();
AddAnyPolicyNode();
}
// In RFC 5280 valid_policy_tree may be set to null. That is represented here
// by emptiness.
bool IsNull() const {
return !current_level_.has_any_policy &&
(levels_.empty() || levels_.back().empty());
}
void SetNull() {
levels_.clear();
current_level_ = LevelDetails{};
}
// Completes the previous level, returning a corresponding LevelDetails
// structure, and starts a new level.
LevelDetails StartLevel() {
// Finish building expected_policy_map for the previous level.
if (!levels_.empty()) {
for (const auto& [policy, node] : levels_.back()) {
if (!node.mapped) {
current_level_.expected_policy_map[policy].push_back(policy);
}
}
}
LevelDetails prev_level = std::move(current_level_);
levels_.emplace_back();
current_level_ = LevelDetails{};
return prev_level;
}
// Gets the set of policies (in terms of root authority's policy domain) that
// are valid at the bottom level of the policy graph, intersected with
// |user_initial_policy_set|. This is what X.509 calls
// "user-constrained-policy-set".
//
// This method may only be called once, after the policy graph is constructed.
std::set<der::Input> GetUserConstrainedPolicySet(
const std::set<der::Input>& user_initial_policy_set) {
if (levels_.empty()) {
return {};
}
bool user_has_any_policy =
user_initial_policy_set.count(der::Input(kAnyPolicyOid)) != 0;
if (current_level_.has_any_policy) {
if (user_has_any_policy) {
return {der::Input(kAnyPolicyOid)};
}
return user_initial_policy_set;
}
// The root's policy domain is determined by nodes with anyPolicy as a
// parent. However, we must limit to those which are reachable from the
// end-entity certificate because we defer some pruning steps.
for (auto& [policy, node] : levels_.back()) {
// GCC before 8.1 tracks individual unused bindings and does not support
// marking them [[maybe_unused]].
(void)policy;
node.reachable = true;
}
std::set<der::Input> policy_set;
for (size_t i = levels_.size() - 1; i < levels_.size(); i--) {
for (auto& [policy, node] : levels_[i]) {
if (!node.reachable) {
continue;
}
if (node.parent_policies.empty()) {
// |node|'s parent is anyPolicy, so this is in the root policy domain.
// Add it to the set if it is also in user's list.
if (user_has_any_policy ||
user_initial_policy_set.count(policy) > 0) {
policy_set.insert(policy);
}
} else if (i > 0) {
// Otherwise, continue searching the previous level.
for (der::Input parent : node.parent_policies) {
auto iter = levels_[i - 1].find(parent);
if (iter != levels_[i - 1].end()) {
iter->second.reachable = true;
}
}
}
}
}
return policy_set;
}
// Adds a node with policy anyPolicy to the current level.
void AddAnyPolicyNode() {
assert(!levels_.empty());
current_level_.has_any_policy = true;
}
// Adds a node to the current level which is a child of |parent_policies| with
// the specified policy.
void AddNode(der::Input policy, std::vector<der::Input> parent_policies) {
assert(policy != der::Input(kAnyPolicyOid));
AddNodeReturningIterator(policy, std::move(parent_policies));
}
// Adds a node to the current level which is a child of anyPolicy with the
// specified policy.
void AddNodeWithParentAnyPolicy(der::Input policy) {
// An empty parent set represents a node parented by anyPolicy.
AddNode(policy, {});
}
// Maps |issuer_policy| to |subject_policy|, as in RFC 5280, section 6.1.4,
// step b.1.
void AddPolicyMapping(der::Input issuer_policy, der::Input subject_policy) {
assert(issuer_policy != der::Input(kAnyPolicyOid));
assert(subject_policy != der::Input(kAnyPolicyOid));
if (levels_.empty()) {
return;
}
// The mapping only applies if |issuer_policy| exists in the current level.
auto issuer_policy_iter = levels_.back().find(issuer_policy);
if (issuer_policy_iter == levels_.back().end()) {
// If there is no match, it can instead match anyPolicy.
if (!current_level_.has_any_policy) {
return;
}
// From RFC 5280, section 6.1.4, step b.1:
//
// If no node of depth i in the valid_policy_tree has a
// valid_policy of ID-P but there is a node of depth i with a
// valid_policy of anyPolicy, then generate a child node of
// the node of depth i-1 that has a valid_policy of anyPolicy
// as follows: [...]
//
// The anyPolicy node of depth i-1 is referring to the parent of the
// anyPolicy node of depth i. The parent of anyPolicy is always anyPolicy.
issuer_policy_iter = AddNodeReturningIterator(issuer_policy, {});
}
// Unmapped nodes have a singleton "expected_policy_set" containing their
// valid_policy. Track whether nodes have been mapped so this can be filled
// in at StartLevel().
issuer_policy_iter->second.mapped = true;
// Add |subject_policy| to |issuer_policy|'s "expected_policy_set".
current_level_.expected_policy_map[subject_policy].push_back(issuer_policy);
}
// Removes the node with the specified policy from the current level.
void DeleteNode(der::Input policy) {
if (!levels_.empty()) {
levels_.back().erase(policy);
}
}
private:
Level::iterator AddNodeReturningIterator(
der::Input policy,
std::vector<der::Input> parent_policies) {
assert(policy != der::Input(kAnyPolicyOid));
auto [iter, inserted] = levels_.back().insert(
std::pair{policy, Node{std::move(parent_policies)}});
// GCC before 8.1 tracks individual unused bindings and does not support
// marking them [[maybe_unused]].
(void)inserted;
assert(inserted);
return iter;
}
// The list of levels, starting from the root.
std::vector<Level> levels_;
// Additional information about the current level.
LevelDetails current_level_;
};
// Class that encapsulates the state variables used by certificate path
// validation.
class PathVerifier {
public:
// Same parameters and meaning as VerifyCertificateChain().
void Run(const ParsedCertificateList& certs,
const CertificateTrust& last_cert_trust,
VerifyCertificateChainDelegate* delegate,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
InitialExplicitPolicy initial_explicit_policy,
const std::set<der::Input>& user_initial_policy_set,
InitialPolicyMappingInhibit initial_policy_mapping_inhibit,
InitialAnyPolicyInhibit initial_any_policy_inhibit,
std::set<der::Input>* user_constrained_policy_set,
CertPathErrors* errors);
private:
// Verifies and updates the valid policies. This corresponds with RFC 5280
// section 6.1.3 steps d-f.
void VerifyPolicies(const ParsedCertificate& cert,
bool is_target_cert,
CertErrors* errors);
// Applies the policy mappings. This corresponds with RFC 5280 section 6.1.4
// steps a-b.
void VerifyPolicyMappings(const ParsedCertificate& cert, CertErrors* errors);
// Applies policyConstraints and inhibitAnyPolicy. This corresponds with RFC
// 5280 section 6.1.4 steps i-j.
void ApplyPolicyConstraints(const ParsedCertificate& cert);
// This function corresponds to RFC 5280 section 6.1.3's "Basic Certificate
// Processing" procedure.
void BasicCertificateProcessing(const ParsedCertificate& cert,
bool is_target_cert,
bool is_target_cert_issuer,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
CertErrors* errors,
bool* shortcircuit_chain_validation);
// This function corresponds to RFC 5280 section 6.1.4's "Preparation for
// Certificate i+1" procedure. |cert| is expected to be an intermediate.
void PrepareForNextCertificate(const ParsedCertificate& cert,
CertErrors* errors);
// This function corresponds with RFC 5280 section 6.1.5's "Wrap-Up
// Procedure". It does processing for the final certificate (the target cert).
void WrapUp(const ParsedCertificate& cert,
KeyPurpose required_key_purpose,
const std::set<der::Input>& user_initial_policy_set,
CertErrors* errors);
// Enforces trust anchor constraints compatibile with RFC 5937.
//
// Note that the anchor constraints are encoded via the attached certificate
// itself.
void ApplyTrustAnchorConstraints(const ParsedCertificate& cert,
KeyPurpose required_key_purpose,
CertErrors* errors);
// Initializes the path validation algorithm given anchor constraints. This
// follows the description in RFC 5937
void ProcessRootCertificate(const ParsedCertificate& cert,
const CertificateTrust& trust,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
CertErrors* errors,
bool* shortcircuit_chain_validation);
// Processes verification when the input is a single certificate. This is not
// defined by any standard. We attempt to match the de-facto behaviour of
// Operating System verifiers.
void ProcessSingleCertChain(const ParsedCertificate& cert,
const CertificateTrust& trust,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
CertErrors* errors);
// Parses |spki| to an EVP_PKEY and checks whether the public key is accepted
// by |delegate_|. On failure parsing returns nullptr. If either parsing the
// key or key policy failed, adds a high-severity error to |errors|.
bssl::UniquePtr<EVP_PKEY> ParseAndCheckPublicKey(const der::Input& spki,
CertErrors* errors);
ValidPolicyGraph valid_policy_graph_;
std::set<der::Input> user_constrained_policy_set_;
// Will contain a NameConstraints for each previous cert in the chain which
// had nameConstraints. This corresponds to the permitted_subtrees and
// excluded_subtrees state variables from RFC 5280.
std::vector<const NameConstraints*> name_constraints_list_;
// |explicit_policy_| corresponds with the same named variable from RFC 5280
// section 6.1.2:
//
// explicit_policy: an integer that indicates if a non-NULL
// valid_policy_tree is required. The integer indicates the
// number of non-self-issued certificates to be processed before
// this requirement is imposed. Once set, this variable may be
// decreased, but may not be increased. That is, if a certificate in the
// path requires a non-NULL valid_policy_tree, a later certificate cannot
// remove this requirement. If initial-explicit-policy is set, then the
// initial value is 0, otherwise the initial value is n+1.
size_t explicit_policy_;
// |inhibit_any_policy_| corresponds with the same named variable from RFC
// 5280 section 6.1.2:
//
// inhibit_anyPolicy: an integer that indicates whether the
// anyPolicy policy identifier is considered a match. The
// integer indicates the number of non-self-issued certificates
// to be processed before the anyPolicy OID, if asserted in a
// certificate other than an intermediate self-issued
// certificate, is ignored. Once set, this variable may be
// decreased, but may not be increased. That is, if a
// certificate in the path inhibits processing of anyPolicy, a
// later certificate cannot permit it. If initial-any-policy-
// inhibit is set, then the initial value is 0, otherwise the
// initial value is n+1.
size_t inhibit_any_policy_;
// |policy_mapping_| corresponds with the same named variable from RFC 5280
// section 6.1.2:
//
// policy_mapping: an integer that indicates if policy mapping
// is permitted. The integer indicates the number of non-self-
// issued certificates to be processed before policy mapping is
// inhibited. Once set, this variable may be decreased, but may
// not be increased. That is, if a certificate in the path
// specifies that policy mapping is not permitted, it cannot be
// overridden by a later certificate. If initial-policy-
// mapping-inhibit is set, then the initial value is 0,
// otherwise the initial value is n+1.
size_t policy_mapping_;
// |working_public_key_| is an amalgamation of 3 separate variables from RFC
// 5280:
// * working_public_key
// * working_public_key_algorithm
// * working_public_key_parameters
//
// They are combined for simplicity since the signature verification takes an
// EVP_PKEY, and the parameter inheritence is not applicable for the supported
// key types. |working_public_key_| may be null if parsing failed.
//
// An approximate explanation of |working_public_key_| is this description
// from RFC 5280 section 6.1.2:
//
// working_public_key: the public key used to verify the
// signature of a certificate.
bssl::UniquePtr<EVP_PKEY> working_public_key_;
// |working_normalized_issuer_name_| is the normalized value of the
// working_issuer_name variable in RFC 5280 section 6.1.2:
//
// working_issuer_name: the issuer distinguished name expected
// in the next certificate in the chain.
der::Input working_normalized_issuer_name_;
// |max_path_length_| corresponds with the same named variable in RFC 5280
// section 6.1.2.
//
// max_path_length: this integer is initialized to n, is
// decremented for each non-self-issued certificate in the path,
// and may be reduced to the value in the path length constraint
// field within the basic constraints extension of a CA
// certificate.
size_t max_path_length_;
VerifyCertificateChainDelegate* delegate_;
};
void PathVerifier::VerifyPolicies(const ParsedCertificate& cert,
bool is_target_cert,
CertErrors* errors) {
// From RFC 5280 section 6.1.3:
//
// (d) If the certificate policies extension is present in the
// certificate and the valid_policy_tree is not NULL, process
// the policy information by performing the following steps in
// order:
if (cert.has_policy_oids() && !valid_policy_graph_.IsNull()) {
ValidPolicyGraph::LevelDetails previous_level =
valid_policy_graph_.StartLevel();
// (1) For each policy P not equal to anyPolicy in the
// certificate policies extension, let P-OID denote the OID
// for policy P and P-Q denote the qualifier set for policy
// P. Perform the following steps in order:
bool cert_has_any_policy = false;
for (const der::Input& p_oid : cert.policy_oids()) {
if (p_oid == der::Input(kAnyPolicyOid)) {
cert_has_any_policy = true;
continue;
}
// (i) For each node of depth i-1 in the valid_policy_tree
// where P-OID is in the expected_policy_set, create a
// child node as follows: set the valid_policy to P-OID,
// set the qualifier_set to P-Q, and set the
// expected_policy_set to {P-OID}.
auto iter = previous_level.expected_policy_map.find(p_oid);
if (iter != previous_level.expected_policy_map.end()) {
valid_policy_graph_.AddNode(
p_oid, /*parent_policies=*/std::move(iter->second));
previous_level.expected_policy_map.erase(iter);
} else if (previous_level.has_any_policy) {
// (ii) If there was no match in step (i) and the
// valid_policy_tree includes a node of depth i-1 with
// the valid_policy anyPolicy, generate a child node with
// the following values: set the valid_policy to P-OID,
// set the qualifier_set to P-Q, and set the
// expected_policy_set to {P-OID}.
valid_policy_graph_.AddNodeWithParentAnyPolicy(p_oid);
}
}
// (2) If the certificate policies extension includes the policy
// anyPolicy with the qualifier set AP-Q and either (a)
// inhibit_anyPolicy is greater than 0 or (b) i<n and the
// certificate is self-issued, then:
//
// For each node in the valid_policy_tree of depth i-1, for
// each value in the expected_policy_set (including
// anyPolicy) that does not appear in a child node, create a
// child node with the following values: set the valid_policy
// to the value from the expected_policy_set in the parent
// node, set the qualifier_set to AP-Q, and set the
// expected_policy_set to the value in the valid_policy from
// this node.
if (cert_has_any_policy && ((inhibit_any_policy_ > 0) ||
(!is_target_cert && IsSelfIssued(cert)))) {
for (auto& [p_oid, parent_policies] :
previous_level.expected_policy_map) {
valid_policy_graph_.AddNode(p_oid, std::move(parent_policies));
}
if (previous_level.has_any_policy) {
valid_policy_graph_.AddAnyPolicyNode();
}
}
// (3) If there is a node in the valid_policy_tree of depth i-1
// or less without any child nodes, delete that node. Repeat
// this step until there are no nodes of depth i-1 or less
// without children.
//
// This implementation does this as part of GetUserConstrainedPolicySet().
// Only the current level needs to be pruned to compute the policy graph.
}
// (e) If the certificate policies extension is not present, set the
// valid_policy_tree to NULL.
if (!cert.has_policy_oids())
valid_policy_graph_.SetNull();
// (f) Verify that either explicit_policy is greater than 0 or the
// valid_policy_tree is not equal to NULL;
if (!((explicit_policy_ > 0) || !valid_policy_graph_.IsNull()))
errors->AddError(cert_errors::kNoValidPolicy);
}
void PathVerifier::VerifyPolicyMappings(const ParsedCertificate& cert,
CertErrors* errors) {
if (!cert.has_policy_mappings())
return;
// From RFC 5280 section 6.1.4:
//
// (a) If a policy mappings extension is present, verify that the
// special value anyPolicy does not appear as an
// issuerDomainPolicy or a subjectDomainPolicy.
for (const ParsedPolicyMapping& mapping : cert.policy_mappings()) {
if (mapping.issuer_domain_policy == der::Input(kAnyPolicyOid) ||
mapping.subject_domain_policy == der::Input(kAnyPolicyOid)) {
// Because this implementation continues processing certificates after
// this error, clear the valid policy graph to ensure the
// "user_constrained_policy_set" output upon failure is empty.
valid_policy_graph_.SetNull();
errors->AddError(cert_errors::kPolicyMappingAnyPolicy);
return;
}
}
// (b) If a policy mappings extension is present, then for each
// issuerDomainPolicy ID-P in the policy mappings extension:
//
// (1) If the policy_mapping variable is greater than 0, for each
// node in the valid_policy_tree of depth i where ID-P is the
// valid_policy, set expected_policy_set to the set of
// subjectDomainPolicy values that are specified as
// equivalent to ID-P by the policy mappings extension.
//
// If no node of depth i in the valid_policy_tree has a
// valid_policy of ID-P but there is a node of depth i with a
// valid_policy of anyPolicy, then generate a child node of
// the node of depth i-1 that has a valid_policy of anyPolicy
// as follows:
//
// (i) set the valid_policy to ID-P;
//
// (ii) set the qualifier_set to the qualifier set of the
// policy anyPolicy in the certificate policies
// extension of certificate i; and
//
// (iii) set the expected_policy_set to the set of
// subjectDomainPolicy values that are specified as
// equivalent to ID-P by the policy mappings extension.
//
if (policy_mapping_ > 0) {
for (const ParsedPolicyMapping& mapping : cert.policy_mappings()) {
valid_policy_graph_.AddPolicyMapping(mapping.issuer_domain_policy,
mapping.subject_domain_policy);
}
}
// (b) If a policy mappings extension is present, then for each
// issuerDomainPolicy ID-P in the policy mappings extension:
//
// ...
//
// (2) If the policy_mapping variable is equal to 0:
//
// (i) delete each node of depth i in the valid_policy_tree
// where ID-P is the valid_policy.
//
// (ii) If there is a node in the valid_policy_tree of depth
// i-1 or less without any child nodes, delete that
// node. Repeat this step until there are no nodes of
// depth i-1 or less without children.
//
// Step (ii) is deferred to part of GetUserConstrainedPolicySet().
if (policy_mapping_ == 0) {
for (const ParsedPolicyMapping& mapping : cert.policy_mappings()) {
valid_policy_graph_.DeleteNode(mapping.issuer_domain_policy);
}
}
}
void PathVerifier::ApplyPolicyConstraints(const ParsedCertificate& cert) {
// RFC 5280 section 6.1.4 step i-j:
// (i) If a policy constraints extension is included in the
// certificate, modify the explicit_policy and policy_mapping
// state variables as follows:
if (cert.has_policy_constraints()) {
// (1) If requireExplicitPolicy is present and is less than
// explicit_policy, set explicit_policy to the value of
// requireExplicitPolicy.
if (cert.policy_constraints().require_explicit_policy &&
cert.policy_constraints().require_explicit_policy.value() <
explicit_policy_) {
explicit_policy_ =
cert.policy_constraints().require_explicit_policy.value();
}
// (2) If inhibitPolicyMapping is present and is less than
// policy_mapping, set policy_mapping to the value of
// inhibitPolicyMapping.
if (cert.policy_constraints().inhibit_policy_mapping &&
cert.policy_constraints().inhibit_policy_mapping.value() <
policy_mapping_) {
policy_mapping_ =
cert.policy_constraints().inhibit_policy_mapping.value();
}
}
// (j) If the inhibitAnyPolicy extension is included in the
// certificate and is less than inhibit_anyPolicy, set
// inhibit_anyPolicy to the value of inhibitAnyPolicy.
if (cert.has_inhibit_any_policy() &&
cert.inhibit_any_policy() < inhibit_any_policy_) {
inhibit_any_policy_ = cert.inhibit_any_policy();
}
}
void PathVerifier::BasicCertificateProcessing(
const ParsedCertificate& cert,
bool is_target_cert,
bool is_target_cert_issuer,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
CertErrors* errors,
bool* shortcircuit_chain_validation) {
*shortcircuit_chain_validation = false;
// Check that the signature algorithms in Certificate vs TBSCertificate
// match. This isn't part of RFC 5280 section 6.1.3, but is mandated by
// sections 4.1.1.2 and 4.1.2.3.
if (!VerifySignatureAlgorithmsMatch(cert, errors)) {
CHECK(errors->ContainsAnyErrorWithSeverity(CertError::SEVERITY_HIGH));
*shortcircuit_chain_validation = true;
}
// Check whether this signature algorithm is allowed.
if (!cert.signature_algorithm().has_value() ||
!delegate_->IsSignatureAlgorithmAcceptable(*cert.signature_algorithm(),
errors)) {
*shortcircuit_chain_validation = true;
errors->AddError(cert_errors::kUnacceptableSignatureAlgorithm);
return;
}
if (working_public_key_) {
// Verify the digital signature using the previous certificate's key (RFC
// 5280 section 6.1.3 step a.1).
if (!VerifySignedData(*cert.signature_algorithm(),
cert.tbs_certificate_tlv(), cert.signature_value(),
working_public_key_.get(),
delegate_->GetVerifyCache())) {
*shortcircuit_chain_validation = true;
errors->AddError(cert_errors::kVerifySignedDataFailed);
}
}
if (*shortcircuit_chain_validation)
return;
// Check the time range for the certificate's validity, ensuring it is valid
// at |time|.
// (RFC 5280 section 6.1.3 step a.2)
VerifyTimeValidity(cert, time, errors);
// RFC 5280 section 6.1.3 step a.3 calls for checking the certificate's
// revocation status here. In this implementation revocation checking is
// implemented separately from path validation.
// Verify the certificate's issuer name matches the issuing certificate's
// subject name. (RFC 5280 section 6.1.3 step a.4)
if (cert.normalized_issuer() != working_normalized_issuer_name_)
errors->AddError(cert_errors::kSubjectDoesNotMatchIssuer);
// Name constraints (RFC 5280 section 6.1.3 step b & c)
// If certificate i is self-issued and it is not the final certificate in the
// path, skip this step for certificate i.
if (!name_constraints_list_.empty() &&
(!IsSelfIssued(cert) || is_target_cert)) {
for (const NameConstraints* nc : name_constraints_list_) {
nc->IsPermittedCert(cert.normalized_subject(), cert.subject_alt_names(),
errors);
}
}
// RFC 5280 section 6.1.3 step d - f.
VerifyPolicies(cert, is_target_cert, errors);
// The key purpose is checked not just for the end-entity certificate, but
// also interpreted as a constraint when it appears in intermediates. This
// goes beyond what RFC 5280 describes, but is the de-facto standard. See
// https://wiki.mozilla.org/CA:CertificatePolicyV2.1#Frequently_Asked_Questions
VerifyExtendedKeyUsage(cert, required_key_purpose, errors, is_target_cert,
is_target_cert_issuer);
}
void PathVerifier::PrepareForNextCertificate(const ParsedCertificate& cert,
CertErrors* errors) {
// RFC 5280 section 6.1.4 step a-b
VerifyPolicyMappings(cert, errors);
// From RFC 5280 section 6.1.4 step c:
//
// Assign the certificate subject name to working_normalized_issuer_name.
working_normalized_issuer_name_ = cert.normalized_subject();
// From RFC 5280 section 6.1.4 step d:
//
// Assign the certificate subjectPublicKey to working_public_key.
working_public_key_ = ParseAndCheckPublicKey(cert.tbs().spki_tlv, errors);
// Note that steps e and f are omitted as they are handled by
// the assignment to |working_spki| above. See the definition
// of |working_spki|.
// From RFC 5280 section 6.1.4 step g:
if (cert.has_name_constraints())
name_constraints_list_.push_back(&cert.name_constraints());
// (h) If certificate i is not self-issued:
if (!IsSelfIssued(cert)) {
// (1) If explicit_policy is not 0, decrement explicit_policy by
// 1.
if (explicit_policy_ > 0)
explicit_policy_ -= 1;
// (2) If policy_mapping is not 0, decrement policy_mapping by 1.
if (policy_mapping_ > 0)
policy_mapping_ -= 1;
// (3) If inhibit_anyPolicy is not 0, decrement inhibit_anyPolicy
// by 1.
if (inhibit_any_policy_ > 0)
inhibit_any_policy_ -= 1;
}
// RFC 5280 section 6.1.4 step i-j:
ApplyPolicyConstraints(cert);
// From RFC 5280 section 6.1.4 step k:
//
// If certificate i is a version 3 certificate, verify that the
// basicConstraints extension is present and that cA is set to
// TRUE. (If certificate i is a version 1 or version 2
// certificate, then the application MUST either verify that
// certificate i is a CA certificate through out-of-band means
// or reject the certificate. Conforming implementations may
// choose to reject all version 1 and version 2 intermediate
// certificates.)
//
// This code implicitly rejects non version 3 intermediates, since they
// can't contain a BasicConstraints extension.
if (!cert.has_basic_constraints()) {
errors->AddError(cert_errors::kMissingBasicConstraints);
} else if (!cert.basic_constraints().is_ca) {
errors->AddError(cert_errors::kBasicConstraintsIndicatesNotCa);
}
// From RFC 5280 section 6.1.4 step l:
//
// If the certificate was not self-issued, verify that
// max_path_length is greater than zero and decrement
// max_path_length by 1.
if (!IsSelfIssued(cert)) {
if (max_path_length_ == 0) {
errors->AddError(cert_errors::kMaxPathLengthViolated);
} else {
--max_path_length_;
}
}
// From RFC 5280 section 6.1.4 step m:
//
// If pathLenConstraint is present in the certificate and is
// less than max_path_length, set max_path_length to the value
// of pathLenConstraint.
if (cert.has_basic_constraints() && cert.basic_constraints().has_path_len &&
cert.basic_constraints().path_len < max_path_length_) {
max_path_length_ = cert.basic_constraints().path_len;
}
// From RFC 5280 section 6.1.4 step n:
//
// If a key usage extension is present, verify that the
// keyCertSign bit is set.
if (cert.has_key_usage() &&
!cert.key_usage().AssertsBit(KEY_USAGE_BIT_KEY_CERT_SIGN)) {
errors->AddError(cert_errors::kKeyCertSignBitNotSet);
}
// From RFC 5280 section 6.1.4 step o:
//
// Recognize and process any other critical extension present in
// the certificate. Process any other recognized non-critical
// extension present in the certificate that is relevant to path
// processing.
VerifyNoUnconsumedCriticalExtensions(cert, errors);
}
// Checks if the target certificate has the CA bit set. If it does, add
// the appropriate error or warning to |errors|.
void VerifyTargetCertIsNotCA(const ParsedCertificate& cert,
KeyPurpose required_key_purpose,
CertErrors* errors) {
if (cert.has_basic_constraints() && cert.basic_constraints().is_ca) {
// In spite of RFC 5280 4.2.1.9 which says the CA properties MAY exist in
// an end entity certificate, the CABF Baseline Requirements version
// 1.8.4, 7.1.2.3(d) prohibit the CA bit being set in an end entity
// certificate.
switch (required_key_purpose) {
case KeyPurpose::ANY_EKU:
break;
case KeyPurpose::SERVER_AUTH:
case KeyPurpose::CLIENT_AUTH:
errors->AddWarning(cert_errors::kTargetCertShouldNotBeCa);
break;
case KeyPurpose::SERVER_AUTH_STRICT:
case KeyPurpose::CLIENT_AUTH_STRICT:
errors->AddError(cert_errors::kTargetCertShouldNotBeCa);
break;
}
}
}
void PathVerifier::WrapUp(const ParsedCertificate& cert,
KeyPurpose required_key_purpose,
const std::set<der::Input>& user_initial_policy_set,
CertErrors* errors) {
// From RFC 5280 section 6.1.5:
// (a) If explicit_policy is not 0, decrement explicit_policy by 1.
if (explicit_policy_ > 0)
explicit_policy_ -= 1;
// (b) If a policy constraints extension is included in the
// certificate and requireExplicitPolicy is present and has a
// value of 0, set the explicit_policy state variable to 0.
if (cert.has_policy_constraints() &&
cert.policy_constraints().require_explicit_policy.has_value() &&
cert.policy_constraints().require_explicit_policy == 0) {
explicit_policy_ = 0;
}
// Note step c-e are omitted as the verification function does
// not output the working public key.
// From RFC 5280 section 6.1.5 step f:
//
// Recognize and process any other critical extension present in
// the certificate n. Process any other recognized non-critical
// extension present in certificate n that is relevant to path
// processing.
//
// Note that this is duplicated by PrepareForNextCertificate() so as to
// directly match the procedures in RFC 5280's section 6.1.
VerifyNoUnconsumedCriticalExtensions(cert, errors);
// This calculates the intersection from RFC 5280 section 6.1.5 step g, as
// well as applying the deferred recursive node that were skipped earlier in
// the process.
user_constrained_policy_set_ =
valid_policy_graph_.GetUserConstrainedPolicySet(user_initial_policy_set);
// From RFC 5280 section 6.1.5 step g:
//
// If either (1) the value of explicit_policy variable is greater than
// zero or (2) the valid_policy_tree is not NULL, then path processing
// has succeeded.
if (explicit_policy_ == 0 && user_constrained_policy_set_.empty()) {
errors->AddError(cert_errors::kNoValidPolicy);
}
// The following check is NOT part of RFC 5280 6.1.5's "Wrap-Up Procedure",
// however is implied by RFC 5280 section 4.2.1.9, as well as CABF Base
// Requirements.
VerifyTargetCertIsNotCA(cert, required_key_purpose, errors);
// Check the public key for the target certificate. The public key for the
// other certificates is already checked by PrepareForNextCertificate().
// Note that this step is not part of RFC 5280 6.1.5.
ParseAndCheckPublicKey(cert.tbs().spki_tlv, errors);
}
void PathVerifier::ApplyTrustAnchorConstraints(const ParsedCertificate& cert,
KeyPurpose required_key_purpose,
CertErrors* errors) {
// If certificatePolicies is present, process the policies. This matches the
// handling for intermediates from RFC 5280 section 6.1.3.d (except that for
// intermediates it is non-optional). It intentionally deviates from RFC 5937
// section 3.2 which says to intersect with user-initial-policy-set, since
// processing as part of user-initial-policy-set has subtly different
// semantics from being handled as part of the chain processing (see
// https://crbug.com/1403258).
if (cert.has_policy_oids()) {
VerifyPolicies(cert, /*is_target_cert=*/false, errors);
}
// Process policyMappings, if present. This matches the handling for
// intermediates from RFC 5280 section 6.1.4 step a-b.
VerifyPolicyMappings(cert, errors);
// Process policyConstraints and inhibitAnyPolicy. This matches the
// handling for intermediates from RFC 5280 section 6.1.4 step i-j.
// This intentionally deviates from RFC 5937 section 3.2 which says to
// initialize the initial-any-policy-inhibit, initial-explicit-policy, and/or
// initial-policy-mapping-inhibit inputs to verification. Those are all
// bools, so they cannot properly represent the constraints encoded in the
// policyConstraints and inhibitAnyPolicy extensions.
ApplyPolicyConstraints(cert);
// If keyUsage is present, verify that |cert| has correct keyUsage bits for a
// CA. This matches the handling for intermediates from RFC 5280 section
// 6.1.4 step n.
if (cert.has_key_usage() &&
!cert.key_usage().AssertsBit(KEY_USAGE_BIT_KEY_CERT_SIGN)) {
errors->AddError(cert_errors::kKeyCertSignBitNotSet);
}
// This is not part of RFC 5937 nor RFC 5280, but matches the EKU handling
// done for intermediates (described in Web PKI's Baseline Requirements).
VerifyExtendedKeyUsage(cert, required_key_purpose, errors,
/*is_target_cert=*/false,
/*is_target_cert_issuer=*/false);
// The following enforcements follow from RFC 5937 (primarily section 3.2):
// Initialize name constraints initial-permitted/excluded-subtrees.
if (cert.has_name_constraints())
name_constraints_list_.push_back(&cert.name_constraints());
if (cert.has_basic_constraints()) {
// Enforce CA=true if basicConstraints is present. This matches behavior of
// other verifiers, and seems like a good thing to do to avoid a
// certificate being used in the wrong context if it was specifically
// marked as not being a CA.
if (!cert.basic_constraints().is_ca) {
errors->AddError(cert_errors::kBasicConstraintsIndicatesNotCa);
}
// From RFC 5937 section 3.2:
//
// If a basic constraints extension is associated with the trust
// anchor and contains a pathLenConstraint value, set the
// max_path_length state variable equal to the pathLenConstraint
// value from the basic constraints extension.
//
if (cert.basic_constraints().has_path_len) {
max_path_length_ = cert.basic_constraints().path_len;
}
}
// From RFC 5937 section 2:
//
// Extensions may be marked critical or not critical. When trust anchor
// constraints are enforced, clients MUST reject certification paths
// containing a trust anchor with unrecognized critical extensions.
VerifyNoUnconsumedCriticalExtensions(cert, errors);
}
void PathVerifier::ProcessRootCertificate(const ParsedCertificate& cert,
const CertificateTrust& trust,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
CertErrors* errors,
bool* shortcircuit_chain_validation) {
*shortcircuit_chain_validation = false;
switch (trust.type) {
case CertificateTrustType::UNSPECIFIED:
case CertificateTrustType::TRUSTED_LEAF:
// Doesn't chain to a trust anchor - implicitly distrusted
errors->AddError(cert_errors::kCertIsNotTrustAnchor);
*shortcircuit_chain_validation = true;
break;
case CertificateTrustType::DISTRUSTED:
// Chains to an actively distrusted certificate.
errors->AddError(cert_errors::kDistrustedByTrustStore);
*shortcircuit_chain_validation = true;
break;
case CertificateTrustType::TRUSTED_ANCHOR:
case CertificateTrustType::TRUSTED_ANCHOR_OR_LEAF:
break;
}
if (*shortcircuit_chain_validation)
return;
if (trust.enforce_anchor_expiry) {
VerifyTimeValidity(cert, time, errors);
}
if (trust.enforce_anchor_constraints) {
if (trust.require_anchor_basic_constraints &&
!cert.has_basic_constraints()) {
switch (cert.tbs().version) {
case CertificateVersion::V1:
case CertificateVersion::V2:
break;
case CertificateVersion::V3:
errors->AddError(cert_errors::kMissingBasicConstraints);
break;
}
}
ApplyTrustAnchorConstraints(cert, required_key_purpose, errors);
}
// Use the certificate's SPKI and subject when verifying the next certificate.
working_public_key_ = ParseAndCheckPublicKey(cert.tbs().spki_tlv, errors);
working_normalized_issuer_name_ = cert.normalized_subject();
}
void PathVerifier::ProcessSingleCertChain(const ParsedCertificate& cert,
const CertificateTrust& trust,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
CertErrors* errors) {
switch (trust.type) {
case CertificateTrustType::UNSPECIFIED:
case CertificateTrustType::TRUSTED_ANCHOR:
// Target doesn't have a chain and isn't a directly trusted leaf -
// implicitly distrusted.
errors->AddError(cert_errors::kCertIsNotTrustAnchor);
return;
case CertificateTrustType::DISTRUSTED:
// Target is directly distrusted.
errors->AddError(cert_errors::kDistrustedByTrustStore);
return;
case CertificateTrustType::TRUSTED_LEAF:
case CertificateTrustType::TRUSTED_ANCHOR_OR_LEAF:
break;
}
// Check the public key for the target certificate regardless of whether
// `require_leaf_selfsigned` is true. This matches the check in WrapUp and
// fulfills the documented behavior of the IsPublicKeyAcceptable delegate.
ParseAndCheckPublicKey(cert.tbs().spki_tlv, errors);
if (trust.require_leaf_selfsigned) {
if (!VerifyCertificateIsSelfSigned(cert, delegate_->GetVerifyCache(),
errors)) {
// VerifyCertificateIsSelfSigned should have added an error, but just
// double check to be safe.
if (!errors->ContainsAnyErrorWithSeverity(CertError::SEVERITY_HIGH)) {
errors->AddError(cert_errors::kInternalError);
}
return;
}
}
// There is no standard for what it means to verify a directly trusted leaf
// certificate, so this is basically just checking common sense things that
// also mirror what we observed to be enforced with the Operating System
// native verifiers.
VerifyTimeValidity(cert, time, errors);
VerifyExtendedKeyUsage(cert, required_key_purpose, errors,
/*is_target_cert=*/true,
/*is_target_cert_issuer=*/false);
// Checking for unknown critical extensions matches Windows, but is stricter
// than the Mac verifier.
VerifyNoUnconsumedCriticalExtensions(cert, errors);
}
bssl::UniquePtr<EVP_PKEY> PathVerifier::ParseAndCheckPublicKey(
const der::Input& spki,
CertErrors* errors) {
// Parse the public key.
bssl::UniquePtr<EVP_PKEY> pkey;
if (!ParsePublicKey(spki, &pkey)) {
errors->AddError(cert_errors::kFailedParsingSpki);
return nullptr;
}
// Check if the key is acceptable by the delegate.
if (!delegate_->IsPublicKeyAcceptable(pkey.get(), errors))
errors->AddError(cert_errors::kUnacceptablePublicKey);
return pkey;
}
void PathVerifier::Run(
const ParsedCertificateList& certs,
const CertificateTrust& last_cert_trust,
VerifyCertificateChainDelegate* delegate,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
InitialExplicitPolicy initial_explicit_policy,
const std::set<der::Input>& user_initial_policy_set,
InitialPolicyMappingInhibit initial_policy_mapping_inhibit,
InitialAnyPolicyInhibit initial_any_policy_inhibit,
std::set<der::Input>* user_constrained_policy_set,
CertPathErrors* errors) {
// This implementation is structured to mimic the description of certificate
// path verification given by RFC 5280 section 6.1.
DCHECK(delegate);
DCHECK(errors);
delegate_ = delegate;
// An empty chain is necessarily invalid.
if (certs.empty()) {
errors->GetOtherErrors()->AddError(cert_errors::kChainIsEmpty);
return;
}
// Verifying a trusted leaf certificate isn't a well-specified operation, so
// it's handled separately from the RFC 5280 defined verification process.
if (certs.size() == 1) {
ProcessSingleCertChain(*certs.front(), last_cert_trust, time,
required_key_purpose, errors->GetErrorsForCert(0));
return;
}
// RFC 5280's "n" variable is the length of the path, which does not count
// the trust anchor. (Although in practice it doesn't really change behaviors
// if n is used in place of n+1).
const size_t n = certs.size() - 1;
valid_policy_graph_.Init();
// RFC 5280 section section 6.1.2:
//
// If initial-explicit-policy is set, then the initial value
// [of explicit_policy] is 0, otherwise the initial value is n+1.
explicit_policy_ =
initial_explicit_policy == InitialExplicitPolicy::kTrue ? 0 : n + 1;
// RFC 5280 section section 6.1.2:
//
// If initial-any-policy-inhibit is set, then the initial value
// [of inhibit_anyPolicy] is 0, otherwise the initial value is n+1.
inhibit_any_policy_ =
initial_any_policy_inhibit == InitialAnyPolicyInhibit::kTrue ? 0 : n + 1;
// RFC 5280 section section 6.1.2:
//
// If initial-policy-mapping-inhibit is set, then the initial value
// [of policy_mapping] is 0, otherwise the initial value is n+1.
policy_mapping_ =
initial_policy_mapping_inhibit == InitialPolicyMappingInhibit::kTrue
? 0
: n + 1;
// RFC 5280 section section 6.1.2:
//
// max_path_length: this integer is initialized to n, ...
max_path_length_ = n;
// Iterate over all the certificates in the reverse direction: starting from
// the root certificate and progressing towards the target certificate.
//
// * i=0 : Root certificate (i.e. trust anchor)
// * i=1 : Certificate issued by root
// * i=x : Certificate i=x is issued by certificate i=x-1
// * i=n : Target certificate.
for (size_t i = 0; i < certs.size(); ++i) {
const size_t index_into_certs = certs.size() - i - 1;
// |is_target_cert| is true if the current certificate is the target
// certificate being verified. The target certificate isn't necessarily an
// end-entity certificate.
const bool is_target_cert = index_into_certs == 0;
const bool is_target_cert_issuer = index_into_certs == 1;
const bool is_root_cert = i == 0;
const ParsedCertificate& cert = *certs[index_into_certs];
// Output errors for the current certificate into an error bucket that is
// associated with that certificate.
CertErrors* cert_errors = errors->GetErrorsForCert(index_into_certs);
if (is_root_cert) {
bool shortcircuit_chain_validation = false;
ProcessRootCertificate(cert, last_cert_trust, time, required_key_purpose,
cert_errors, &shortcircuit_chain_validation);
if (shortcircuit_chain_validation) {
// Chains that don't start from a trusted root should short-circuit the
// rest of the verification, as accumulating more errors from untrusted
// certificates would not be meaningful.
CHECK(cert_errors->ContainsAnyErrorWithSeverity(
CertError::SEVERITY_HIGH));
return;
}
// Don't do any other checks for root certificates.
continue;
}
bool shortcircuit_chain_validation = false;
// Per RFC 5280 section 6.1:
// * Do basic processing for each certificate
// * If it is the last certificate in the path (target certificate)
// - Then run "Wrap up"
// - Otherwise run "Prepare for Next cert"
BasicCertificateProcessing(cert, is_target_cert, is_target_cert_issuer,
time, required_key_purpose, cert_errors,
&shortcircuit_chain_validation);
if (shortcircuit_chain_validation) {
// Signature errors should short-circuit the rest of the verification, as
// accumulating more errors from untrusted certificates would not be
// meaningful.
CHECK(
cert_errors->ContainsAnyErrorWithSeverity(CertError::SEVERITY_HIGH));
return;
}
if (!is_target_cert) {
PrepareForNextCertificate(cert, cert_errors);
} else {
WrapUp(cert, required_key_purpose, user_initial_policy_set, cert_errors);
}
}
if (user_constrained_policy_set) {
*user_constrained_policy_set = user_constrained_policy_set_;
}
// TODO(eroman): RFC 5280 forbids duplicate certificates per section 6.1:
//
// A certificate MUST NOT appear more than once in a prospective
// certification path.
}
} // namespace
VerifyCertificateChainDelegate::~VerifyCertificateChainDelegate() = default;
void VerifyCertificateChain(
const ParsedCertificateList& certs,
const CertificateTrust& last_cert_trust,
VerifyCertificateChainDelegate* delegate,
const der::GeneralizedTime& time,
KeyPurpose required_key_purpose,
InitialExplicitPolicy initial_explicit_policy,
const std::set<der::Input>& user_initial_policy_set,
InitialPolicyMappingInhibit initial_policy_mapping_inhibit,
InitialAnyPolicyInhibit initial_any_policy_inhibit,
std::set<der::Input>* user_constrained_policy_set,
CertPathErrors* errors) {
PathVerifier verifier;
verifier.Run(certs, last_cert_trust, delegate, time, required_key_purpose,
initial_explicit_policy, user_initial_policy_set,
initial_policy_mapping_inhibit, initial_any_policy_inhibit,
user_constrained_policy_set, errors);
}
bool VerifyCertificateIsSelfSigned(const ParsedCertificate& cert,
SignatureVerifyCache* cache,
CertErrors* errors) {
if (cert.normalized_subject() != cert.normalized_issuer()) {
if (errors) {
errors->AddError(cert_errors::kSubjectDoesNotMatchIssuer);
}
return false;
}
// Note that we do not restrict the available algorithms when determining if
// something is a self-signed cert. The signature isn't very important on a
// self-signed cert so just allow any supported algorithm here, to avoid
// breakage.
if (!cert.signature_algorithm().has_value()) {
if (errors) {
errors->AddError(cert_errors::kUnacceptableSignatureAlgorithm);
}
return false;
}
if (!VerifySignedData(*cert.signature_algorithm(), cert.tbs_certificate_tlv(),
cert.signature_value(), cert.tbs().spki_tlv, cache)) {
if (errors) {
errors->AddError(cert_errors::kVerifySignedDataFailed);
}
return false;
}
return true;
}
} // namespace net