mirror of
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367 lines
13 KiB
C++
367 lines
13 KiB
C++
// Copyright 2013 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "net/cert/ct_log_verifier.h"
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#include <string.h>
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#include <vector>
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#include "base/logging.h"
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#include "crypto/openssl_util.h"
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#include "crypto/sha2.h"
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#include "net/cert/ct_log_verifier_util.h"
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#include "net/cert/ct_serialization.h"
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#include "net/cert/merkle_audit_proof.h"
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#include "net/cert/merkle_consistency_proof.h"
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#include "net/cert/signed_tree_head.h"
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#include "third_party/boringssl/src/include/openssl/bytestring.h"
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#include "third_party/boringssl/src/include/openssl/evp.h"
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namespace net {
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namespace {
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// The SHA-256 hash of the empty string.
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const unsigned char kSHA256EmptyStringHash[ct::kSthRootHashLength] = {
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0xe3, 0xb0, 0xc4, 0x42, 0x98, 0xfc, 0x1c, 0x14, 0x9a, 0xfb, 0xf4,
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0xc8, 0x99, 0x6f, 0xb9, 0x24, 0x27, 0xae, 0x41, 0xe4, 0x64, 0x9b,
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0x93, 0x4c, 0xa4, 0x95, 0x99, 0x1b, 0x78, 0x52, 0xb8, 0x55};
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bool IsPowerOfTwo(uint64_t n) {
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return n != 0 && (n & (n - 1)) == 0;
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}
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const EVP_MD* GetEvpAlg(ct::DigitallySigned::HashAlgorithm alg) {
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switch (alg) {
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case ct::DigitallySigned::HASH_ALGO_MD5:
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return EVP_md5();
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case ct::DigitallySigned::HASH_ALGO_SHA1:
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return EVP_sha1();
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case ct::DigitallySigned::HASH_ALGO_SHA224:
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return EVP_sha224();
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case ct::DigitallySigned::HASH_ALGO_SHA256:
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return EVP_sha256();
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case ct::DigitallySigned::HASH_ALGO_SHA384:
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return EVP_sha384();
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case ct::DigitallySigned::HASH_ALGO_SHA512:
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return EVP_sha512();
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case ct::DigitallySigned::HASH_ALGO_NONE:
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default:
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NOTREACHED();
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return NULL;
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}
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}
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} // namespace
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// static
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scoped_refptr<const CTLogVerifier> CTLogVerifier::Create(
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const base::StringPiece& public_key,
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const base::StringPiece& description,
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const base::StringPiece& url,
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const base::StringPiece& dns_domain) {
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GURL log_url(url);
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if (!log_url.is_valid())
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return nullptr;
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scoped_refptr<CTLogVerifier> result(
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new CTLogVerifier(description, log_url, dns_domain));
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if (!result->Init(public_key))
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return nullptr;
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return result;
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}
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CTLogVerifier::CTLogVerifier(const base::StringPiece& description,
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const GURL& url,
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const base::StringPiece& dns_domain)
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: description_(description.as_string()),
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url_(url),
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dns_domain_(dns_domain.as_string()),
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hash_algorithm_(ct::DigitallySigned::HASH_ALGO_NONE),
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signature_algorithm_(ct::DigitallySigned::SIG_ALGO_ANONYMOUS),
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public_key_(NULL) {
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DCHECK(url_.is_valid());
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DCHECK(!dns_domain_.empty());
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}
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bool CTLogVerifier::Verify(const ct::SignedEntryData& entry,
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const ct::SignedCertificateTimestamp& sct) const {
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if (sct.log_id != key_id()) {
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DVLOG(1) << "SCT is not signed by this log.";
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return false;
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}
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if (!SignatureParametersMatch(sct.signature))
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return false;
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std::string serialized_log_entry;
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if (!ct::EncodeSignedEntry(entry, &serialized_log_entry)) {
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DVLOG(1) << "Unable to serialize entry.";
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return false;
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}
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std::string serialized_data;
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if (!ct::EncodeV1SCTSignedData(sct.timestamp, serialized_log_entry,
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sct.extensions, &serialized_data)) {
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DVLOG(1) << "Unable to create SCT to verify.";
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return false;
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}
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return VerifySignature(serialized_data, sct.signature.signature_data);
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}
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bool CTLogVerifier::VerifySignedTreeHead(
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const ct::SignedTreeHead& signed_tree_head) const {
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if (!SignatureParametersMatch(signed_tree_head.signature))
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return false;
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std::string serialized_data;
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ct::EncodeTreeHeadSignature(signed_tree_head, &serialized_data);
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if (VerifySignature(serialized_data,
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signed_tree_head.signature.signature_data)) {
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if (signed_tree_head.tree_size == 0) {
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// Root hash must equate SHA256 hash of the empty string.
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return (memcmp(signed_tree_head.sha256_root_hash, kSHA256EmptyStringHash,
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ct::kSthRootHashLength) == 0);
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}
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return true;
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}
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return false;
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}
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bool CTLogVerifier::SignatureParametersMatch(
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const ct::DigitallySigned& signature) const {
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if (!signature.SignatureParametersMatch(hash_algorithm_,
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signature_algorithm_)) {
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DVLOG(1) << "Mismatched hash or signature algorithm. Hash: "
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<< hash_algorithm_ << " vs " << signature.hash_algorithm
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<< " Signature: " << signature_algorithm_ << " vs "
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<< signature.signature_algorithm << ".";
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return false;
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}
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return true;
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}
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bool CTLogVerifier::VerifyConsistencyProof(
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const ct::MerkleConsistencyProof& proof,
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const std::string& old_tree_hash,
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const std::string& new_tree_hash) const {
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// Proof does not originate from this log.
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if (key_id_ != proof.log_id)
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return false;
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// Cannot prove consistency from a tree of a certain size to a tree smaller
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// than that - only the other way around.
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if (proof.first_tree_size > proof.second_tree_size)
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return false;
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// If the proof is between trees of the same size, then the 'proof'
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// is really just a statement that the tree hasn't changed. If this
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// is the case, there should be no proof nodes, and both the old
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// and new hash should be equivalent.
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if (proof.first_tree_size == proof.second_tree_size)
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return proof.nodes.empty() && old_tree_hash == new_tree_hash;
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// It is possible to call this method to prove consistency between the
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// initial state of a log (i.e. an empty tree) and a later root. In that
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// case, the only valid proof is an empty proof.
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if (proof.first_tree_size == 0)
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return proof.nodes.empty();
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// Implement the algorithm described in
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// https://tools.ietf.org/html/draft-ietf-trans-rfc6962-bis-12#section-9.4.2
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//
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// It maintains a pair of hashes |fr| and |sr|, initialized to the same
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// value. Each node in |proof| will be hashed to the left of both |fr| and
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// |sr| or to the right of only |sr|. The proof is then valid if |fr| is
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// |old_tree_hash| and |sr| is |new_tree_hash|, proving that tree nodes which
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// make up |old_tree_hash| are a prefix of |new_tree_hash|.
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// At this point, the algorithm's preconditions must be satisfied.
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DCHECK_LT(0u, proof.first_tree_size);
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DCHECK_LT(proof.first_tree_size, proof.second_tree_size);
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// 1. If "first" is an exact power of 2, then prepend "first_hash" to the
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// "consistency_path" array.
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base::StringPiece first_proof_node = old_tree_hash;
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std::vector<std::string>::const_iterator iter = proof.nodes.begin();
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if (!IsPowerOfTwo(proof.first_tree_size)) {
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if (iter == proof.nodes.end())
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return false;
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first_proof_node = *iter;
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++iter;
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}
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// iter now points to the second node in the modified proof.nodes.
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// 2. Set "fn" to "first - 1" and "sn" to "second - 1".
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uint64_t fn = proof.first_tree_size - 1;
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uint64_t sn = proof.second_tree_size - 1;
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// 3. If "LSB(fn)" is set, then right-shift both "fn" and "sn" equally until
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// "LSB(fn)" is not set.
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while (fn & 1) {
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fn >>= 1;
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sn >>= 1;
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}
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// 4. Set both "fr" and "sr" to the first value in the "consistency_path"
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// array.
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std::string fr = first_proof_node.as_string();
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std::string sr = first_proof_node.as_string();
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// 5. For each subsequent value "c" in the "consistency_path" array:
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for (; iter != proof.nodes.end(); ++iter) {
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// If "sn" is 0, stop the iteration and fail the proof verification.
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if (sn == 0)
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return false;
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// If "LSB(fn)" is set, or if "fn" is equal to "sn", then:
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if ((fn & 1) || fn == sn) {
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// 1. Set "fr" to "HASH(0x01 || c || fr)"
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// Set "sr" to "HASH(0x01 || c || sr)"
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fr = ct::internal::HashNodes(*iter, fr);
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sr = ct::internal::HashNodes(*iter, sr);
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// 2. If "LSB(fn)" is not set, then right-shift both "fn" and "sn" equally
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// until either "LSB(fn)" is set or "fn" is "0".
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while (!(fn & 1) && fn != 0) {
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fn >>= 1;
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sn >>= 1;
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}
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} else { // Otherwise:
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// Set "sr" to "HASH(0x01 || sr || c)"
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sr = ct::internal::HashNodes(sr, *iter);
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}
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// Finally, right-shift both "fn" and "sn" one time.
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fn >>= 1;
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sn >>= 1;
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}
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// 6. After completing iterating through the "consistency_path" array as
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// described above, verify that the "fr" calculated is equal to the
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// "first_hash" supplied, that the "sr" calculated is equal to the
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// "second_hash" supplied and that "sn" is 0.
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return fr == old_tree_hash && sr == new_tree_hash && sn == 0;
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}
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bool CTLogVerifier::VerifyAuditProof(const ct::MerkleAuditProof& proof,
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const std::string& root_hash,
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const std::string& leaf_hash) const {
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// Implements the algorithm described in
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// https://tools.ietf.org/html/draft-ietf-trans-rfc6962-bis-19#section-10.4.1
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//
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// It maintains a hash |r|, initialized to |leaf_hash|, and hashes nodes from
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// |proof| into it. The proof is then valid if |r| is |root_hash|, proving
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// that |root_hash| includes |leaf_hash|.
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// 1. Compare "leaf_index" against "tree_size". If "leaf_index" is
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// greater than or equal to "tree_size" fail the proof verification.
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if (proof.leaf_index >= proof.tree_size)
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return false;
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// 2. Set "fn" to "leaf_index" and "sn" to "tree_size - 1".
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uint64_t fn = proof.leaf_index;
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uint64_t sn = proof.tree_size - 1;
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// 3. Set "r" to "hash".
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std::string r = leaf_hash;
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// 4. For each value "p" in the "inclusion_path" array:
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for (const std::string& p : proof.nodes) {
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// If "sn" is 0, stop the iteration and fail the proof verification.
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if (sn == 0)
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return false;
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// If "LSB(fn)" is set, or if "fn" is equal to "sn", then:
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if ((fn & 1) || fn == sn) {
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// 1. Set "r" to "HASH(0x01 || p || r)"
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r = ct::internal::HashNodes(p, r);
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// 2. If "LSB(fn)" is not set, then right-shift both "fn" and "sn"
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// equally until either "LSB(fn)" is set or "fn" is "0".
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while (!(fn & 1) && fn != 0) {
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fn >>= 1;
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sn >>= 1;
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}
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} else { // Otherwise:
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// Set "r" to "HASH(0x01 || r || p)"
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r = ct::internal::HashNodes(r, p);
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}
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// Finally, right-shift both "fn" and "sn" one time.
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fn >>= 1;
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sn >>= 1;
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}
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// 5. Compare "sn" to 0. Compare "r" against the "root_hash". If "sn"
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// is equal to 0, and "r" and the "root_hash" are equal, then the
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// log has proven the inclusion of "hash". Otherwise, fail the
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// proof verification.
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return sn == 0 && r == root_hash;
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}
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CTLogVerifier::~CTLogVerifier() {
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crypto::OpenSSLErrStackTracer err_tracer(FROM_HERE);
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if (public_key_)
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EVP_PKEY_free(public_key_);
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}
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bool CTLogVerifier::Init(const base::StringPiece& public_key) {
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crypto::OpenSSLErrStackTracer err_tracer(FROM_HERE);
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CBS cbs;
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CBS_init(&cbs, reinterpret_cast<const uint8_t*>(public_key.data()),
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public_key.size());
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public_key_ = EVP_parse_public_key(&cbs);
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if (!public_key_ || CBS_len(&cbs) != 0)
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return false;
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key_id_ = crypto::SHA256HashString(public_key);
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// Right now, only RSASSA-PKCS1v15 with SHA-256 and ECDSA with SHA-256 are
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// supported.
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switch (EVP_PKEY_type(public_key_->type)) {
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case EVP_PKEY_RSA:
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hash_algorithm_ = ct::DigitallySigned::HASH_ALGO_SHA256;
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signature_algorithm_ = ct::DigitallySigned::SIG_ALGO_RSA;
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break;
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case EVP_PKEY_EC:
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hash_algorithm_ = ct::DigitallySigned::HASH_ALGO_SHA256;
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signature_algorithm_ = ct::DigitallySigned::SIG_ALGO_ECDSA;
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break;
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default:
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DVLOG(1) << "Unsupported key type: " << EVP_PKEY_type(public_key_->type);
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return false;
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}
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// Extra sanity check: Require RSA keys of at least 2048 bits.
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// EVP_PKEY_size returns the size in bytes. 256 = 2048-bit RSA key.
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if (signature_algorithm_ == ct::DigitallySigned::SIG_ALGO_RSA &&
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EVP_PKEY_size(public_key_) < 256) {
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DVLOG(1) << "Too small a public key.";
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return false;
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}
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return true;
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}
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bool CTLogVerifier::VerifySignature(const base::StringPiece& data_to_sign,
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const base::StringPiece& signature) const {
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crypto::OpenSSLErrStackTracer err_tracer(FROM_HERE);
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const EVP_MD* hash_alg = GetEvpAlg(hash_algorithm_);
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if (hash_alg == NULL)
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return false;
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bssl::ScopedEVP_MD_CTX ctx;
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return EVP_DigestVerifyInit(ctx.get(), NULL, hash_alg, NULL, public_key_) &&
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EVP_DigestVerifyUpdate(ctx.get(), data_to_sign.data(),
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data_to_sign.size()) &&
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EVP_DigestVerifyFinal(
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ctx.get(), reinterpret_cast<const uint8_t*>(signature.data()),
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signature.size());
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}
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} // namespace net
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