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cobalt / cobalt / 37ef7f8c0c60f95c9821b4d9f3273c9ef3666a79 / . / src / net / cert / ct_log_verifier_unittest.cc
blob: 5e2840a4622ae841f3953410be7dafbb1c72d6b3 [file] [log] [blame]
// Copyright 2013 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/cert/ct_log_verifier.h"
#include <memory>
#include <string>
#include <vector>
#include "base/macros.h"
#include "base/stl_util.h"
#include "base/strings/string_number_conversions.h"
#include "base/time/time.h"
#include "crypto/secure_hash.h"
#include "net/base/hash_value.h"
#include "net/cert/ct_log_verifier_util.h"
#include "net/cert/merkle_audit_proof.h"
#include "net/cert/merkle_consistency_proof.h"
#include "net/cert/signed_certificate_timestamp.h"
#include "net/cert/signed_tree_head.h"
#include "net/test/ct_test_util.h"
#include "starboard/memory.h"
#include "starboard/types.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace net {
namespace {
// Calculate the power of two nearest to, but less than, |n|.
// |n| must be at least 2.
size_t CalculateNearestPowerOfTwo(size_t n) {
DCHECK_GT(n, 1u);
size_t ret = size_t(1) << (sizeof(size_t) * 8 - 1);
while (ret >= n)
ret >>= 1;
return ret;
}
// All test data replicated from
// https://github.com/google/certificate-transparency/blob/c41b090ecc14ddd6b3531dc7e5ce36b21e253fdd/cpp/merkletree/merkle_tree_test.cc
// The SHA-256 hash of an empty Merkle tree.
const uint8_t kEmptyTreeHash[32] = {
0xe3, 0xb0, 0xc4, 0x42, 0x98, 0xfc, 0x1c, 0x14, 0x9a, 0xfb, 0xf4,
0xc8, 0x99, 0x6f, 0xb9, 0x24, 0x27, 0xae, 0x41, 0xe4, 0x64, 0x9b,
0x93, 0x4c, 0xa4, 0x95, 0x99, 0x1b, 0x78, 0x52, 0xb8, 0x55};
std::string GetEmptyTreeHash() {
return std::string(std::begin(kEmptyTreeHash), std::end(kEmptyTreeHash));
}
// SHA-256 Merkle leaf hashes for the sample tree that all of the other test
// data relates to (8 leaves).
const char* const kLeafHashes[8] = {
"6e340b9cffb37a989ca544e6bb780a2c78901d3fb33738768511a30617afa01d",
"96a296d224f285c67bee93c30f8a309157f0daa35dc5b87e410b78630a09cfc7",
"0298d122906dcfc10892cb53a73992fc5b9f493ea4c9badb27b791b4127a7fe7",
"07506a85fd9dd2f120eb694f86011e5bb4662e5c415a62917033d4a9624487e7",
"bc1a0643b12e4d2d7c77918f44e0f4f79a838b6cf9ec5b5c283e1f4d88599e6b",
"4271a26be0d8a84f0bd54c8c302e7cb3a3b5d1fa6780a40bcce2873477dab658",
"b08693ec2e721597130641e8211e7eedccb4c26413963eee6c1e2ed16ffb1a5f",
"46f6ffadd3d06a09ff3c5860d2755c8b9819db7df44251788c7d8e3180de8eb1"};
// SHA-256 Merkle root hashes from building the sample tree leaf-by-leaf.
// The first entry is the root when the tree contains 1 leaf, and the last is
// the root when the tree contains all 8 leaves.
const char* const kRootHashes[8] = {
"6e340b9cffb37a989ca544e6bb780a2c78901d3fb33738768511a30617afa01d",
"fac54203e7cc696cf0dfcb42c92a1d9dbaf70ad9e621f4bd8d98662f00e3c125",
"aeb6bcfe274b70a14fb067a5e5578264db0fa9b51af5e0ba159158f329e06e77",
"d37ee418976dd95753c1c73862b9398fa2a2cf9b4ff0fdfe8b30cd95209614b7",
"4e3bbb1f7b478dcfe71fb631631519a3bca12c9aefca1612bfce4c13a86264d4",
"76e67dadbcdf1e10e1b74ddc608abd2f98dfb16fbce75277b5232a127f2087ef",
"ddb89be403809e325750d3d263cd78929c2942b7942a34b77e122c9594a74c8c",
"5dc9da79a70659a9ad559cb701ded9a2ab9d823aad2f4960cfe370eff4604328"};
// A single consistency proof. Contains at most 3 proof nodes (all test proofs
// will be for a tree of size 8).
struct ConsistencyProofTestVector {
size_t old_tree_size;
size_t new_tree_size;
size_t proof_length;
const char* const proof[3];
};
// A collection of consistency proofs between various sub-trees of the sample
// tree.
const ConsistencyProofTestVector kConsistencyProofs[] = {
// Empty consistency proof between trees of the same size (1).
{1, 1, 0, {"", "", ""}},
// Consistency proof between tree of size 1 and tree of size 8, with 3
// nodes in the proof.
{1,
8,
3,
{"96a296d224f285c67bee93c30f8a309157f0daa35dc5b87e410b78630a09cfc7",
"5f083f0a1a33ca076a95279832580db3e0ef4584bdff1f54c8a360f50de3031e",
"6b47aaf29ee3c2af9af889bc1fb9254dabd31177f16232dd6aab035ca39bf6e4"}},
// Consistency proof between tree of size 6 and tree of size 8, with 3
// nodes in the proof.
{6,
8,
3,
{"0ebc5d3437fbe2db158b9f126a1d118e308181031d0a949f8dededebc558ef6a",
"ca854ea128ed050b41b35ffc1b87b8eb2bde461e9e3b5596ece6b9d5975a0ae0",
"d37ee418976dd95753c1c73862b9398fa2a2cf9b4ff0fdfe8b30cd95209614b7"}},
// Consistency proof between tree of size 2 and tree of size 5, with 2
// nodes in the proof.
{2,
5,
2,
{"5f083f0a1a33ca076a95279832580db3e0ef4584bdff1f54c8a360f50de3031e",
"bc1a0643b12e4d2d7c77918f44e0f4f79a838b6cf9ec5b5c283e1f4d88599e6b", ""}}};
// A single audit proof. Contains at most 3 proof nodes (all test proofs will be
// for a tree of size 8).
struct AuditProofTestVector {
size_t leaf;
size_t tree_size;
size_t proof_length;
const char* const proof[3];
};
// A collection of audit proofs for various leaves and sub-trees of the tree
// defined by |kRootHashes|.
const AuditProofTestVector kAuditProofs[] = {
{0, 1, 0, {"", "", ""}},
{0,
8,
3,
{"96a296d224f285c67bee93c30f8a309157f0daa35dc5b87e410b78630a09cfc7",
"5f083f0a1a33ca076a95279832580db3e0ef4584bdff1f54c8a360f50de3031e",
"6b47aaf29ee3c2af9af889bc1fb9254dabd31177f16232dd6aab035ca39bf6e4"}},
{5,
8,
3,
{"bc1a0643b12e4d2d7c77918f44e0f4f79a838b6cf9ec5b5c283e1f4d88599e6b",
"ca854ea128ed050b41b35ffc1b87b8eb2bde461e9e3b5596ece6b9d5975a0ae0",
"d37ee418976dd95753c1c73862b9398fa2a2cf9b4ff0fdfe8b30cd95209614b7"}},
{2,
3,
1,
{"fac54203e7cc696cf0dfcb42c92a1d9dbaf70ad9e621f4bd8d98662f00e3c125", "",
""}},
{1,
5,
3,
{"6e340b9cffb37a989ca544e6bb780a2c78901d3fb33738768511a30617afa01d",
"5f083f0a1a33ca076a95279832580db3e0ef4584bdff1f54c8a360f50de3031e",
"bc1a0643b12e4d2d7c77918f44e0f4f79a838b6cf9ec5b5c283e1f4d88599e6b"}}};
// Decodes a hexadecimal string into the binary data it represents.
std::string HexToBytes(const std::string& hex_data) {
std::vector<uint8_t> output;
std::string result;
if (base::HexStringToBytes(hex_data, &output))
result.assign(output.begin(), output.end());
return result;
}
// Constructs a consistency/audit proof from a test vector.
// This is templated so that it can be used with both ConsistencyProofTestVector
// and AuditProofTestVector.
template <typename TestVectorType>
std::vector<std::string> GetProof(const TestVectorType& test_vector) {
std::vector<std::string> proof(test_vector.proof_length);
std::transform(test_vector.proof,
test_vector.proof + test_vector.proof_length, proof.begin(),
&HexToBytes);
return proof;
}
// Creates a ct::MerkleConsistencyProof from its arguments and returns the
// result of passing this to log.VerifyConsistencyProof().
bool VerifyConsistencyProof(const CTLogVerifier& log,
size_t old_tree_size,
const std::string& old_tree_root,
size_t new_tree_size,
const std::string& new_tree_root,
const std::vector<std::string>& proof) {
return log.VerifyConsistencyProof(
ct::MerkleConsistencyProof(log.key_id(), proof, old_tree_size,
new_tree_size),
old_tree_root, new_tree_root);
}
// Creates a ct::MerkleAuditProof from its arguments and returns the result of
// passing this to log.VerifyAuditProof().
bool VerifyAuditProof(const CTLogVerifier& log,
size_t leaf,
size_t tree_size,
const std::vector<std::string>& proof,
const std::string& tree_root,
const std::string& leaf_hash) {
return log.VerifyAuditProof(ct::MerkleAuditProof(leaf, tree_size, proof),
tree_root, leaf_hash);
}
class CTLogVerifierTest : public ::testing::Test {
public:
void SetUp() override {
log_ = CTLogVerifier::Create(ct::GetTestPublicKey(), "testlog",
"ct.example.com");
ASSERT_TRUE(log_);
EXPECT_EQ(ct::GetTestPublicKeyId(), log_->key_id());
EXPECT_EQ("ct.example.com", log_->dns_domain());
}
protected:
scoped_refptr<const CTLogVerifier> log_;
};
// Given an audit proof for a leaf in a Merkle tree, asserts that it verifies
// and no other combination of leaves, tree sizes and proof nodes verifies.
void CheckVerifyAuditProof(const CTLogVerifier& log,
size_t leaf,
size_t tree_size,
const std::vector<std::string>& proof,
const std::string& root_hash,
const std::string& leaf_hash) {
EXPECT_TRUE(
VerifyAuditProof(log, leaf, tree_size, proof, root_hash, leaf_hash))
<< "proof for leaf " << leaf << " did not pass verification";
EXPECT_FALSE(
VerifyAuditProof(log, leaf - 1, tree_size, proof, root_hash, leaf_hash))
<< "proof passed verification with wrong leaf index";
EXPECT_FALSE(
VerifyAuditProof(log, leaf + 1, tree_size, proof, root_hash, leaf_hash))
<< "proof passed verification with wrong leaf index";
EXPECT_FALSE(
VerifyAuditProof(log, leaf ^ 2, tree_size, proof, root_hash, leaf_hash))
<< "proof passed verification with wrong leaf index";
EXPECT_FALSE(
VerifyAuditProof(log, leaf, tree_size * 2, proof, root_hash, leaf_hash))
<< "proof passed verification with wrong tree height";
EXPECT_FALSE(VerifyAuditProof(log, leaf / 2, tree_size / 2, proof, root_hash,
leaf_hash))
<< "proof passed verification with wrong leaf index and tree height";
EXPECT_FALSE(
VerifyAuditProof(log, leaf, tree_size / 2, proof, root_hash, leaf_hash))
<< "proof passed verification with wrong tree height";
EXPECT_FALSE(VerifyAuditProof(log, leaf, tree_size, proof, GetEmptyTreeHash(),
leaf_hash))
<< "proof passed verification with wrong root hash";
std::vector<std::string> wrong_proof;
// Modify a single element on the proof.
for (size_t j = 0; j < proof.size(); ++j) {
wrong_proof = proof;
wrong_proof[j] = GetEmptyTreeHash();
EXPECT_FALSE(VerifyAuditProof(log, leaf, tree_size, wrong_proof, root_hash,
leaf_hash))
<< "proof passed verification with one wrong node (node " << j << ")";
}
wrong_proof = proof;
wrong_proof.push_back(std::string());
EXPECT_FALSE(
VerifyAuditProof(log, leaf, tree_size, wrong_proof, root_hash, leaf_hash))
<< "proof passed verification with an empty node appended";
wrong_proof.back() = root_hash;
EXPECT_FALSE(
VerifyAuditProof(log, leaf, tree_size, wrong_proof, root_hash, leaf_hash))
<< "proof passed verification with an incorrect node appended";
wrong_proof.pop_back();
if (!wrong_proof.empty()) {
wrong_proof.pop_back();
EXPECT_FALSE(VerifyAuditProof(log, leaf, tree_size, wrong_proof, root_hash,
leaf_hash))
<< "proof passed verification with the last node missing";
}
wrong_proof.clear();
wrong_proof.push_back(std::string());
wrong_proof.insert(wrong_proof.end(), proof.begin(), proof.end());
EXPECT_FALSE(
VerifyAuditProof(log, leaf, tree_size, wrong_proof, root_hash, leaf_hash))
<< "proof passed verification with an empty node prepended";
wrong_proof[0] = root_hash;
EXPECT_FALSE(
VerifyAuditProof(log, leaf, tree_size, wrong_proof, root_hash, leaf_hash))
<< "proof passed verification with an incorrect node prepended";
}
// Given a consistency proof between two snapshots of the tree, asserts that it
// verifies and no other combination of tree sizes and proof nodes verifies.
void CheckVerifyConsistencyProof(const CTLogVerifier& log,
int old_tree_size,
int new_tree_size,
const std::string& old_root,
const std::string& new_root,
const std::vector<std::string>& proof) {
// Verify the original consistency proof.
EXPECT_TRUE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, new_root, proof))
<< "proof between trees of size " << old_tree_size << " and "
<< new_tree_size << " did not pass verification";
if (proof.empty()) {
// For simplicity test only non-trivial proofs that have old_root !=
// new_root
// old_tree_size != 0 and old_tree_size != new_tree_size.
return;
}
// Wrong tree size: The proof checking code should not accept as a valid proof
// a proof for a tree size different than the original size it was produced
// for. Test that this is not the case for off-by-one changes.
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size - 1, old_root,
new_tree_size, new_root, proof))
<< "proof passed verification with old tree size - 1";
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size + 1, old_root,
new_tree_size, new_root, proof))
<< "proof passed verification with old tree size + 1";
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size ^ 2, old_root,
new_tree_size, new_root, proof))
<< "proof passed verification with old tree size ^ 2";
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size * 2, new_root, proof))
<< "proof passed verification with new tree height + 1";
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size / 2, new_root, proof))
<< "proof passed verification with new tree height - 1";
const std::string wrong_root("WrongRoot");
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, wrong_root, proof))
<< "proof passed verification with wrong old root";
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, wrong_root,
new_tree_size, new_root, proof))
<< "proof passed verification with wrong new root";
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, new_root,
new_tree_size, old_root, proof))
<< "proof passed verification with old and new root swapped";
// Variations of wrong proofs, all of which should be rejected.
std::vector<std::string> wrong_proof;
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, new_root, wrong_proof))
<< "empty proof passed verification";
// Modify a single element in the proof.
for (size_t j = 0; j < proof.size(); ++j) {
wrong_proof = proof;
wrong_proof[j] = GetEmptyTreeHash();
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, new_root, wrong_proof))
<< "proof passed verification with incorrect node (node " << j << ")";
}
wrong_proof = proof;
wrong_proof.push_back(std::string());
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, new_root, wrong_proof))
<< "proof passed verification with empty node appended";
wrong_proof.back() = proof.back();
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, new_root, wrong_proof))
<< "proof passed verification with last node duplicated";
wrong_proof.pop_back();
wrong_proof.pop_back();
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, new_root, wrong_proof))
<< "proof passed verification with last node missing";
wrong_proof.clear();
wrong_proof.push_back(std::string());
wrong_proof.insert(wrong_proof.end(), proof.begin(), proof.end());
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, new_root, wrong_proof))
<< "proof passed verification with empty node prepended";
wrong_proof[0] = proof[0];
EXPECT_FALSE(VerifyConsistencyProof(log, old_tree_size, old_root,
new_tree_size, new_root, wrong_proof))
<< "proof passed verification with first node duplicated";
}
TEST_F(CTLogVerifierTest, VerifiesCertSCT) {
ct::SignedEntryData cert_entry;
ct::GetX509CertSignedEntry(&cert_entry);
scoped_refptr<ct::SignedCertificateTimestamp> cert_sct;
ct::GetX509CertSCT(&cert_sct);
EXPECT_TRUE(log_->Verify(cert_entry, *cert_sct.get()));
}
TEST_F(CTLogVerifierTest, VerifiesPrecertSCT) {
ct::SignedEntryData precert_entry;
ct::GetPrecertSignedEntry(&precert_entry);
scoped_refptr<ct::SignedCertificateTimestamp> precert_sct;
ct::GetPrecertSCT(&precert_sct);
EXPECT_TRUE(log_->Verify(precert_entry, *precert_sct.get()));
}
TEST_F(CTLogVerifierTest, FailsInvalidTimestamp) {
ct::SignedEntryData cert_entry;
ct::GetX509CertSignedEntry(&cert_entry);
scoped_refptr<ct::SignedCertificateTimestamp> cert_sct;
ct::GetX509CertSCT(&cert_sct);
// Mangle the timestamp, so that it should fail signature validation.
cert_sct->timestamp = base::Time::Now();
EXPECT_FALSE(log_->Verify(cert_entry, *cert_sct.get()));
}
TEST_F(CTLogVerifierTest, FailsInvalidLogID) {
ct::SignedEntryData cert_entry;
ct::GetX509CertSignedEntry(&cert_entry);
scoped_refptr<ct::SignedCertificateTimestamp> cert_sct;
ct::GetX509CertSCT(&cert_sct);
// Mangle the log ID, which should cause it to match a different log before
// attempting signature validation.
cert_sct->log_id.assign(cert_sct->log_id.size(), '\0');
EXPECT_FALSE(log_->Verify(cert_entry, *cert_sct.get()));
}
TEST_F(CTLogVerifierTest, VerifiesValidSTH) {
ct::SignedTreeHead sth;
ASSERT_TRUE(ct::GetSampleSignedTreeHead(&sth));
EXPECT_TRUE(log_->VerifySignedTreeHead(sth));
}
TEST_F(CTLogVerifierTest, DoesNotVerifyInvalidSTH) {
ct::SignedTreeHead sth;
ASSERT_TRUE(ct::GetSampleSignedTreeHead(&sth));
sth.sha256_root_hash[0] = '\x0';
EXPECT_FALSE(log_->VerifySignedTreeHead(sth));
}
TEST_F(CTLogVerifierTest, VerifiesValidEmptySTH) {
ct::SignedTreeHead sth;
ASSERT_TRUE(ct::GetSampleEmptySignedTreeHead(&sth));
EXPECT_TRUE(log_->VerifySignedTreeHead(sth));
}
TEST_F(CTLogVerifierTest, DoesNotVerifyInvalidEmptySTH) {
ct::SignedTreeHead sth;
ASSERT_TRUE(ct::GetBadEmptySignedTreeHead(&sth));
EXPECT_FALSE(log_->VerifySignedTreeHead(sth));
}
// Test that excess data after the public key is rejected.
TEST_F(CTLogVerifierTest, ExcessDataInPublicKey) {
std::string key = ct::GetTestPublicKey();
key += "extra";
scoped_refptr<const CTLogVerifier> log =
CTLogVerifier::Create(key, "testlog", "ct.example.com");
EXPECT_FALSE(log);
}
TEST_F(CTLogVerifierTest, VerifiesConsistencyProofEdgeCases_EmptyProof) {
std::vector<std::string> empty_proof;
std::string old_root(GetEmptyTreeHash()), new_root(GetEmptyTreeHash());
// Tree snapshots that are always consistent, because the proofs are either
// from an empty tree to a non-empty one or for trees of the same size.
EXPECT_TRUE(
VerifyConsistencyProof(*log_, 0, old_root, 0, new_root, empty_proof));
EXPECT_TRUE(
VerifyConsistencyProof(*log_, 0, old_root, 1, new_root, empty_proof));
EXPECT_TRUE(
VerifyConsistencyProof(*log_, 1, old_root, 1, new_root, empty_proof));
// Invalid consistency proofs.
// Time travel to the past.
EXPECT_FALSE(
VerifyConsistencyProof(*log_, 1, old_root, 0, new_root, empty_proof));
EXPECT_FALSE(
VerifyConsistencyProof(*log_, 2, old_root, 1, new_root, empty_proof));
// Proof between two trees of different size can never be empty.
EXPECT_FALSE(
VerifyConsistencyProof(*log_, 1, old_root, 2, new_root, empty_proof));
}
TEST_F(CTLogVerifierTest, VerifiesConsistencyProofEdgeCases_MismatchingRoots) {
const std::string old_root(GetEmptyTreeHash());
std::string new_root;
std::vector<std::string> empty_proof;
// Roots don't match.
EXPECT_FALSE(
VerifyConsistencyProof(*log_, 0, old_root, 0, new_root, empty_proof));
EXPECT_FALSE(
VerifyConsistencyProof(*log_, 1, old_root, 1, new_root, empty_proof));
}
TEST_F(CTLogVerifierTest,
VerifiesConsistencyProofEdgeCases_MatchingRootsNonEmptyProof) {
const std::string empty_tree_hash(GetEmptyTreeHash());
std::vector<std::string> proof;
proof.push_back(empty_tree_hash);
// Roots match and the tree size is either the same or the old tree size is 0,
// but the proof is not empty (the verification code should not accept
// proofs with redundant nodes in this case).
proof.push_back(empty_tree_hash);
EXPECT_FALSE(VerifyConsistencyProof(*log_, 0, empty_tree_hash, 0,
empty_tree_hash, proof));
EXPECT_FALSE(VerifyConsistencyProof(*log_, 0, empty_tree_hash, 1,
empty_tree_hash, proof));
EXPECT_FALSE(VerifyConsistencyProof(*log_, 1, empty_tree_hash, 1,
empty_tree_hash, proof));
}
class CTLogVerifierConsistencyProofTest
: public CTLogVerifierTest,
public ::testing::WithParamInterface<size_t /* proof index */> {};
// Checks that a sample set of valid consistency proofs verify successfully.
TEST_P(CTLogVerifierConsistencyProofTest, VerifiesValidConsistencyProof) {
const ConsistencyProofTestVector& test_vector =
kConsistencyProofs[GetParam()];
const std::vector<std::string> proof = GetProof(test_vector);
const char* const old_root = kRootHashes[test_vector.old_tree_size - 1];
const char* const new_root = kRootHashes[test_vector.new_tree_size - 1];
CheckVerifyConsistencyProof(*log_, test_vector.old_tree_size,
test_vector.new_tree_size, HexToBytes(old_root),
HexToBytes(new_root), proof);
}
INSTANTIATE_TEST_CASE_P(KnownGoodProofs,
CTLogVerifierConsistencyProofTest,
::testing::Range(size_t(0),
base::size(kConsistencyProofs)));
class CTLogVerifierAuditProofTest
: public CTLogVerifierTest,
public ::testing::WithParamInterface<size_t /* proof index */> {};
// Checks that a sample set of valid audit proofs verify successfully.
TEST_P(CTLogVerifierAuditProofTest, VerifiesValidAuditProofs) {
const AuditProofTestVector& test_vector = kAuditProofs[GetParam()];
const std::vector<std::string> proof = GetProof(test_vector);
const char* const root_hash = kRootHashes[test_vector.tree_size - 1];
CheckVerifyAuditProof(*log_, test_vector.leaf, test_vector.tree_size, proof,
HexToBytes(root_hash),
HexToBytes(kLeafHashes[test_vector.leaf]));
}
INSTANTIATE_TEST_CASE_P(KnownGoodProofs,
CTLogVerifierAuditProofTest,
::testing::Range(size_t(0), base::size(kAuditProofs)));
TEST_F(CTLogVerifierTest, VerifiesAuditProofEdgeCases_InvalidLeafIndex) {
std::vector<std::string> proof;
EXPECT_FALSE(
VerifyAuditProof(*log_, 1, 0, proof, std::string(), std::string()));
EXPECT_FALSE(
VerifyAuditProof(*log_, 2, 1, proof, std::string(), std::string()));
const std::string empty_hash = GetEmptyTreeHash();
EXPECT_FALSE(VerifyAuditProof(*log_, 1, 0, proof, empty_hash, std::string()));
EXPECT_FALSE(VerifyAuditProof(*log_, 2, 1, proof, empty_hash, std::string()));
}
// Functions that implement algorithms from RFC6962 necessary for constructing
// Merkle trees and proofs. This allows tests to generate a variety of trees
// for exhaustive testing.
namespace rfc6962 {
// Calculates the hash of a leaf in a Merkle tree, given its content.
// See RFC6962, section 2.1.
std::string HashLeaf(const std::string& leaf) {
const char kLeafPrefix[] = {'\x00'};
SHA256HashValue sha256;
SbMemorySet(sha256.data, 0, sizeof(sha256.data));
std::unique_ptr<crypto::SecureHash> hash(
crypto::SecureHash::Create(crypto::SecureHash::SHA256));
hash->Update(kLeafPrefix, 1);
hash->Update(leaf.data(), leaf.size());
hash->Finish(sha256.data, sizeof(sha256.data));
return std::string(reinterpret_cast<const char*>(sha256.data),
sizeof(sha256.data));
}
// Calculates the root hash of a Merkle tree, given its leaf data and size.
// See RFC6962, section 2.1.
std::string HashTree(std::string leaves[], size_t tree_size) {
if (tree_size == 0)
return GetEmptyTreeHash();
if (tree_size == 1)
return HashLeaf(leaves[0]);
// Find the index of the last leaf in the left sub-tree.
const size_t split = CalculateNearestPowerOfTwo(tree_size);
// Hash the left and right sub-trees, then hash the results.
return ct::internal::HashNodes(HashTree(leaves, split),
HashTree(&leaves[split], tree_size - split));
}
// Returns a Merkle audit proof for the leaf with index |leaf_index|.
// The tree consists of |leaves[0]| to |leaves[tree_size-1]|.
// If |leaf_index| is >= |tree_size|, an empty proof will be returned.
// See RFC6962, section 2.1.1, for more details.
std::vector<std::string> CreateAuditProof(std::string leaves[],
size_t tree_size,
size_t leaf_index) {
std::vector<std::string> proof;
if (leaf_index >= tree_size)
return proof;
if (tree_size == 1)
return proof;
// Find the index of the first leaf in the right sub-tree.
const size_t split = CalculateNearestPowerOfTwo(tree_size);
// Recurse down the correct branch of the tree (left or right) to reach the
// leaf with |leaf_index|. Add the hash of the branch not taken at each step
// on the way up to build the proof.
if (leaf_index < split) {
proof = CreateAuditProof(leaves, split, leaf_index);
proof.push_back(HashTree(&leaves[split], tree_size - split));
} else {
proof =
CreateAuditProof(&leaves[split], tree_size - split, leaf_index - split);
proof.push_back(HashTree(leaves, split));
}
return proof;
}
// Returns a Merkle consistency proof between two Merkle trees.
// The old tree contains |leaves[0]| to |leaves[old_tree_size-1]|.
// The new tree contains |leaves[0]| to |leaves[new_tree_size-1]|.
// Call with |contains_old_tree| = true.
// See RFC6962, section 2.1.2, for more details.
std::vector<std::string> CreateConsistencyProof(std::string leaves[],
size_t new_tree_size,
size_t old_tree_size,
bool contains_old_tree = true) {
std::vector<std::string> proof;
if (old_tree_size == 0 || old_tree_size > new_tree_size)
return proof;
if (old_tree_size == new_tree_size) {
// Consistency proof for two equal subtrees is empty.
if (!contains_old_tree) {
// Record the hash of this subtree unless it's the root for which
// the proof was originally requested. (This happens when the old tree is
// balanced).
proof.push_back(HashTree(leaves, old_tree_size));
}
return proof;
}
// Find the index of the last leaf in the left sub-tree.
const size_t split = CalculateNearestPowerOfTwo(new_tree_size);
if (old_tree_size <= split) {
// Root of the old tree is in the left subtree of the new tree.
// Prove that the left subtrees are consistent.
proof =
CreateConsistencyProof(leaves, split, old_tree_size, contains_old_tree);
// Record the hash of the right subtree (only present in the new tree).
proof.push_back(HashTree(&leaves[split], new_tree_size - split));
} else {
// The old tree root is at the same level as the new tree root.
// Prove that the right subtrees are consistent. The right subtree
// doesn't contain the root of the old tree, so set contains_old_tree =
// false.
proof = CreateConsistencyProof(&leaves[split], new_tree_size - split,
old_tree_size - split,
/* contains_old_tree = */ false);
// Record the hash of the left subtree (equal in both trees).
proof.push_back(HashTree(leaves, split));
}
return proof;
}
} // namespace rfc6962
class CTLogVerifierTestUsingGenerator
: public CTLogVerifierTest,
public ::testing::WithParamInterface<size_t /* tree_size */> {};
// Checks that valid consistency proofs for a range of generated Merkle trees
// verify successfully.
TEST_P(CTLogVerifierTestUsingGenerator, VerifiesValidConsistencyProof) {
const size_t tree_size = GetParam();
std::vector<std::string> tree_leaves(tree_size);
for (size_t i = 0; i < tree_size; ++i)
tree_leaves[i].push_back(static_cast<char>(i));
const std::string tree_root =
rfc6962::HashTree(tree_leaves.data(), tree_size);
// Check consistency proofs for every sub-tree.
for (size_t old_tree_size = 0; old_tree_size <= tree_size; ++old_tree_size) {
SCOPED_TRACE(old_tree_size);
const std::string old_tree_root =
rfc6962::HashTree(tree_leaves.data(), old_tree_size);
const std::vector<std::string> proof = rfc6962::CreateConsistencyProof(
tree_leaves.data(), tree_size, old_tree_size);
// Checks that the consistency proof verifies only with the correct tree
// sizes and root hashes.
CheckVerifyConsistencyProof(*log_, old_tree_size, tree_size, old_tree_root,
tree_root, proof);
}
}
// Checks that valid audit proofs for a range of generated Merkle trees verify
// successfully.
TEST_P(CTLogVerifierTestUsingGenerator, VerifiesValidAuditProofs) {
const size_t tree_size = GetParam();
std::vector<std::string> tree_leaves(tree_size);
for (size_t i = 0; i < tree_size; ++i)
tree_leaves[i].push_back(static_cast<char>(i));
const std::string root = rfc6962::HashTree(tree_leaves.data(), tree_size);
// Check audit proofs for every leaf in the tree.
for (size_t leaf = 0; leaf < tree_size; ++leaf) {
SCOPED_TRACE(leaf);
std::vector<std::string> proof =
rfc6962::CreateAuditProof(tree_leaves.data(), tree_size, leaf);
// Checks that the audit proof verifies only for this leaf data, index,
// hash, tree size and root hash.
CheckVerifyAuditProof(*log_, leaf, tree_size, proof, root,
rfc6962::HashLeaf(tree_leaves[leaf]));
}
}
// Test verification of consistency proofs and audit proofs for all tree sizes
// from 0 to 128.
INSTANTIATE_TEST_CASE_P(RangeOfTreeSizes,
CTLogVerifierTestUsingGenerator,
testing::Range(size_t(0), size_t(129)));
} // namespace
} // namespace net