| // Copyright 2014 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 <limits.h> |
| #include <stddef.h> |
| #include <stdint.h> |
| |
| #include <memory> |
| #include <utility> |
| |
| #include "base/logging.h" |
| #include "base/values.h" |
| #include "components/webcrypto/algorithm_dispatch.h" |
| #include "components/webcrypto/algorithms/test_helpers.h" |
| #include "components/webcrypto/crypto_data.h" |
| #include "components/webcrypto/status.h" |
| #include "testing/gtest/include/gtest/gtest.h" |
| #include "third_party/blink/public/platform/web_crypto_algorithm_params.h" |
| #include "third_party/blink/public/platform/web_crypto_key_algorithm.h" |
| |
| namespace webcrypto { |
| |
| namespace { |
| |
| // Creates an HMAC algorithm whose parameters struct is compatible with key |
| // generation. It is an error to call this with a hash_id that is not a SHA*. |
| // The key_length_bits parameter is optional, with zero meaning unspecified. |
| blink::WebCryptoAlgorithm CreateHmacKeyGenAlgorithm( |
| blink::WebCryptoAlgorithmId hash_id, |
| unsigned int key_length_bits) { |
| DCHECK(blink::WebCryptoAlgorithm::IsHash(hash_id)); |
| // key_length_bytes == 0 means unspecified |
| return blink::WebCryptoAlgorithm::AdoptParamsAndCreate( |
| blink::kWebCryptoAlgorithmIdHmac, |
| new blink::WebCryptoHmacKeyGenParams( |
| CreateAlgorithm(hash_id), (key_length_bits != 0), key_length_bits)); |
| } |
| |
| blink::WebCryptoAlgorithm CreateHmacImportAlgorithmWithLength( |
| blink::WebCryptoAlgorithmId hash_id, |
| unsigned int length_bits) { |
| DCHECK(blink::WebCryptoAlgorithm::IsHash(hash_id)); |
| return blink::WebCryptoAlgorithm::AdoptParamsAndCreate( |
| blink::kWebCryptoAlgorithmIdHmac, |
| new blink::WebCryptoHmacImportParams(CreateAlgorithm(hash_id), true, |
| length_bits)); |
| } |
| |
| class WebCryptoHmacTest : public WebCryptoTestBase {}; |
| |
| TEST_F(WebCryptoHmacTest, HMACSampleSets) { |
| std::unique_ptr<base::ListValue> tests; |
| ASSERT_TRUE(ReadJsonTestFileToList("hmac.json", &tests)); |
| for (size_t test_index = 0; test_index < tests->GetSize(); ++test_index) { |
| SCOPED_TRACE(test_index); |
| base::DictionaryValue* test; |
| ASSERT_TRUE(tests->GetDictionary(test_index, &test)); |
| |
| blink::WebCryptoAlgorithm test_hash = GetDigestAlgorithm(test, "hash"); |
| const std::vector<uint8_t> test_key = GetBytesFromHexString(test, "key"); |
| const std::vector<uint8_t> test_message = |
| GetBytesFromHexString(test, "message"); |
| const std::vector<uint8_t> test_mac = GetBytesFromHexString(test, "mac"); |
| |
| blink::WebCryptoAlgorithm algorithm = |
| CreateAlgorithm(blink::kWebCryptoAlgorithmIdHmac); |
| |
| blink::WebCryptoAlgorithm import_algorithm = |
| CreateHmacImportAlgorithmNoLength(test_hash.Id()); |
| |
| blink::WebCryptoKey key = ImportSecretKeyFromRaw( |
| test_key, import_algorithm, |
| blink::kWebCryptoKeyUsageSign | blink::kWebCryptoKeyUsageVerify); |
| |
| EXPECT_EQ(test_hash.Id(), key.Algorithm().HmacParams()->GetHash().Id()); |
| EXPECT_EQ(test_key.size() * 8, key.Algorithm().HmacParams()->LengthBits()); |
| |
| // Verify exported raw key is identical to the imported data |
| std::vector<uint8_t> raw_key; |
| EXPECT_EQ(Status::Success(), |
| ExportKey(blink::kWebCryptoKeyFormatRaw, key, &raw_key)); |
| EXPECT_BYTES_EQ(test_key, raw_key); |
| |
| std::vector<uint8_t> output; |
| |
| ASSERT_EQ(Status::Success(), |
| Sign(algorithm, key, CryptoData(test_message), &output)); |
| |
| EXPECT_BYTES_EQ(test_mac, output); |
| |
| bool signature_match = false; |
| EXPECT_EQ(Status::Success(), |
| Verify(algorithm, key, CryptoData(output), |
| CryptoData(test_message), &signature_match)); |
| EXPECT_TRUE(signature_match); |
| |
| // Ensure truncated signature does not verify by passing one less byte. |
| EXPECT_EQ(Status::Success(), |
| Verify(algorithm, key, |
| CryptoData(output.data(), |
| static_cast<unsigned int>(output.size()) - 1), |
| CryptoData(test_message), &signature_match)); |
| EXPECT_FALSE(signature_match); |
| |
| // Ensure truncated signature does not verify by passing no bytes. |
| EXPECT_EQ(Status::Success(), |
| Verify(algorithm, key, CryptoData(), CryptoData(test_message), |
| &signature_match)); |
| EXPECT_FALSE(signature_match); |
| |
| // Ensure extra long signature does not cause issues and fails. |
| const unsigned char kLongSignature[1024] = {0}; |
| EXPECT_EQ(Status::Success(), |
| Verify(algorithm, key, |
| CryptoData(kLongSignature, sizeof(kLongSignature)), |
| CryptoData(test_message), &signature_match)); |
| EXPECT_FALSE(signature_match); |
| } |
| } |
| |
| TEST_F(WebCryptoHmacTest, GenerateKeyIsRandom) { |
| // Generate a small sample of HMAC keys. |
| std::vector<std::vector<uint8_t>> keys; |
| for (int i = 0; i < 16; ++i) { |
| std::vector<uint8_t> key_bytes; |
| blink::WebCryptoKey key; |
| blink::WebCryptoAlgorithm algorithm = |
| CreateHmacKeyGenAlgorithm(blink::kWebCryptoAlgorithmIdSha1, 512); |
| ASSERT_EQ(Status::Success(), |
| GenerateSecretKey(algorithm, true, blink::kWebCryptoKeyUsageSign, |
| &key)); |
| EXPECT_FALSE(key.IsNull()); |
| EXPECT_TRUE(key.Handle()); |
| EXPECT_EQ(blink::kWebCryptoKeyTypeSecret, key.GetType()); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdHmac, key.Algorithm().Id()); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdSha1, |
| key.Algorithm().HmacParams()->GetHash().Id()); |
| EXPECT_EQ(512u, key.Algorithm().HmacParams()->LengthBits()); |
| |
| std::vector<uint8_t> raw_key; |
| ASSERT_EQ(Status::Success(), |
| ExportKey(blink::kWebCryptoKeyFormatRaw, key, &raw_key)); |
| EXPECT_EQ(64U, raw_key.size()); |
| keys.push_back(raw_key); |
| } |
| // Ensure all entries in the key sample set are unique. This is a simplistic |
| // estimate of whether the generated keys appear random. |
| EXPECT_FALSE(CopiesExist(keys)); |
| } |
| |
| // If the key length is not provided, then the block size is used. |
| TEST_F(WebCryptoHmacTest, GenerateKeyNoLengthSha1) { |
| blink::WebCryptoKey key; |
| blink::WebCryptoAlgorithm algorithm = |
| CreateHmacKeyGenAlgorithm(blink::kWebCryptoAlgorithmIdSha1, 0); |
| ASSERT_EQ( |
| Status::Success(), |
| GenerateSecretKey(algorithm, true, blink::kWebCryptoKeyUsageSign, &key)); |
| EXPECT_TRUE(key.Handle()); |
| EXPECT_EQ(blink::kWebCryptoKeyTypeSecret, key.GetType()); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdHmac, key.Algorithm().Id()); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdSha1, |
| key.Algorithm().HmacParams()->GetHash().Id()); |
| EXPECT_EQ(512u, key.Algorithm().HmacParams()->LengthBits()); |
| std::vector<uint8_t> raw_key; |
| ASSERT_EQ(Status::Success(), |
| ExportKey(blink::kWebCryptoKeyFormatRaw, key, &raw_key)); |
| EXPECT_EQ(64U, raw_key.size()); |
| } |
| |
| // If the key length is not provided, then the block size is used. |
| TEST_F(WebCryptoHmacTest, GenerateKeyNoLengthSha512) { |
| blink::WebCryptoKey key; |
| blink::WebCryptoAlgorithm algorithm = |
| CreateHmacKeyGenAlgorithm(blink::kWebCryptoAlgorithmIdSha512, 0); |
| ASSERT_EQ( |
| Status::Success(), |
| GenerateSecretKey(algorithm, true, blink::kWebCryptoKeyUsageSign, &key)); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdHmac, key.Algorithm().Id()); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdSha512, |
| key.Algorithm().HmacParams()->GetHash().Id()); |
| EXPECT_EQ(1024u, key.Algorithm().HmacParams()->LengthBits()); |
| std::vector<uint8_t> raw_key; |
| ASSERT_EQ(Status::Success(), |
| ExportKey(blink::kWebCryptoKeyFormatRaw, key, &raw_key)); |
| EXPECT_EQ(128U, raw_key.size()); |
| } |
| |
| TEST_F(WebCryptoHmacTest, GenerateKeyEmptyUsage) { |
| blink::WebCryptoKey key; |
| blink::WebCryptoAlgorithm algorithm = |
| CreateHmacKeyGenAlgorithm(blink::kWebCryptoAlgorithmIdSha512, 0); |
| ASSERT_EQ(Status::ErrorCreateKeyEmptyUsages(), |
| GenerateSecretKey(algorithm, true, 0, &key)); |
| } |
| |
| // Generate a 1 bit key. The exported key is 1 byte long, and 7 of the bits are |
| // guaranteed to be zero. |
| TEST_F(WebCryptoHmacTest, Generate1BitKey) { |
| blink::WebCryptoKey key; |
| blink::WebCryptoAlgorithm algorithm = |
| CreateHmacKeyGenAlgorithm(blink::kWebCryptoAlgorithmIdSha1, 1); |
| |
| ASSERT_EQ( |
| Status::Success(), |
| GenerateSecretKey(algorithm, true, blink::kWebCryptoKeyUsageSign, &key)); |
| EXPECT_EQ(1u, key.Algorithm().HmacParams()->LengthBits()); |
| |
| std::vector<uint8_t> raw_key; |
| ASSERT_EQ(Status::Success(), |
| ExportKey(blink::kWebCryptoKeyFormatRaw, key, &raw_key)); |
| ASSERT_EQ(1U, raw_key.size()); |
| |
| EXPECT_FALSE(raw_key[0] & 0x7F); |
| } |
| |
| TEST_F(WebCryptoHmacTest, ImportKeyEmptyUsage) { |
| blink::WebCryptoKey key; |
| std::string key_raw_hex_in = "025a8cf3f08b4f6c5f33bbc76a471939"; |
| EXPECT_EQ(Status::ErrorCreateKeyEmptyUsages(), |
| ImportKey(blink::kWebCryptoKeyFormatRaw, |
| CryptoData(HexStringToBytes(key_raw_hex_in)), |
| CreateHmacImportAlgorithmNoLength( |
| blink::kWebCryptoAlgorithmIdSha1), |
| true, 0, &key)); |
| } |
| |
| TEST_F(WebCryptoHmacTest, ImportKeyJwkKeyOpsSignVerify) { |
| blink::WebCryptoKey key; |
| base::DictionaryValue dict; |
| dict.SetString("kty", "oct"); |
| dict.SetString("k", "GADWrMRHwQfoNaXU5fZvTg"); |
| base::ListValue* key_ops = |
| dict.SetList("key_ops", std::make_unique<base::ListValue>()); |
| |
| key_ops->AppendString("sign"); |
| |
| EXPECT_EQ(Status::Success(), |
| ImportKeyJwkFromDict(dict, |
| CreateHmacImportAlgorithmNoLength( |
| blink::kWebCryptoAlgorithmIdSha256), |
| false, blink::kWebCryptoKeyUsageSign, &key)); |
| |
| EXPECT_EQ(blink::kWebCryptoKeyUsageSign, key.Usages()); |
| |
| key_ops->AppendString("verify"); |
| |
| EXPECT_EQ(Status::Success(), |
| ImportKeyJwkFromDict(dict, |
| CreateHmacImportAlgorithmNoLength( |
| blink::kWebCryptoAlgorithmIdSha256), |
| false, blink::kWebCryptoKeyUsageVerify, &key)); |
| |
| EXPECT_EQ(blink::kWebCryptoKeyUsageVerify, key.Usages()); |
| } |
| |
| // Test 'use' inconsistent with 'key_ops'. |
| TEST_F(WebCryptoHmacTest, ImportKeyJwkUseInconsisteWithKeyOps) { |
| blink::WebCryptoKey key; |
| base::DictionaryValue dict; |
| dict.SetString("kty", "oct"); |
| dict.SetString("k", "GADWrMRHwQfoNaXU5fZvTg"); |
| dict.SetString("alg", "HS256"); |
| dict.SetString("use", "sig"); |
| |
| auto key_ops = std::make_unique<base::ListValue>(); |
| key_ops->AppendString("sign"); |
| key_ops->AppendString("verify"); |
| key_ops->AppendString("encrypt"); |
| dict.Set("key_ops", std::move(key_ops)); |
| EXPECT_EQ( |
| Status::ErrorJwkUseAndKeyopsInconsistent(), |
| ImportKeyJwkFromDict( |
| dict, |
| CreateHmacImportAlgorithmNoLength(blink::kWebCryptoAlgorithmIdSha256), |
| false, |
| blink::kWebCryptoKeyUsageSign | blink::kWebCryptoKeyUsageVerify, |
| &key)); |
| } |
| |
| // Test JWK composite 'sig' use |
| TEST_F(WebCryptoHmacTest, ImportKeyJwkUseSig) { |
| blink::WebCryptoKey key; |
| base::DictionaryValue dict; |
| dict.SetString("kty", "oct"); |
| dict.SetString("k", "GADWrMRHwQfoNaXU5fZvTg"); |
| |
| dict.SetString("use", "sig"); |
| EXPECT_EQ( |
| Status::Success(), |
| ImportKeyJwkFromDict( |
| dict, |
| CreateHmacImportAlgorithmNoLength(blink::kWebCryptoAlgorithmIdSha256), |
| false, |
| blink::kWebCryptoKeyUsageSign | blink::kWebCryptoKeyUsageVerify, |
| &key)); |
| |
| EXPECT_EQ(blink::kWebCryptoKeyUsageSign | blink::kWebCryptoKeyUsageVerify, |
| key.Usages()); |
| } |
| |
| TEST_F(WebCryptoHmacTest, ImportJwkInputConsistency) { |
| // The Web Crypto spec says that if a JWK value is present, but is |
| // inconsistent with the input value, the operation must fail. |
| |
| // Consistency rules when JWK value is not present: Inputs should be used. |
| blink::WebCryptoKey key; |
| bool extractable = false; |
| blink::WebCryptoAlgorithm algorithm = |
| CreateHmacImportAlgorithmNoLength(blink::kWebCryptoAlgorithmIdSha256); |
| blink::WebCryptoKeyUsageMask usages = blink::kWebCryptoKeyUsageVerify; |
| base::DictionaryValue dict; |
| dict.SetString("kty", "oct"); |
| dict.SetString("k", "l3nZEgZCeX8XRwJdWyK3rGB8qwjhdY8vOkbIvh4lxTuMao9Y_--hdg"); |
| std::vector<uint8_t> json_vec = MakeJsonVector(dict); |
| EXPECT_EQ(Status::Success(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json_vec), |
| algorithm, extractable, usages, &key)); |
| EXPECT_TRUE(key.Handle()); |
| EXPECT_EQ(blink::kWebCryptoKeyTypeSecret, key.GetType()); |
| EXPECT_EQ(extractable, key.Extractable()); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdHmac, key.Algorithm().Id()); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdSha256, |
| key.Algorithm().HmacParams()->GetHash().Id()); |
| EXPECT_EQ(320u, key.Algorithm().HmacParams()->LengthBits()); |
| EXPECT_EQ(blink::kWebCryptoKeyUsageVerify, key.Usages()); |
| key = blink::WebCryptoKey::CreateNull(); |
| |
| // Consistency rules when JWK value exists: Fail if inconsistency is found. |
| |
| // Pass: All input values are consistent with the JWK values. |
| dict.Clear(); |
| dict.SetString("kty", "oct"); |
| dict.SetString("alg", "HS256"); |
| dict.SetString("use", "sig"); |
| dict.SetBoolean("ext", false); |
| dict.SetString("k", "l3nZEgZCeX8XRwJdWyK3rGB8qwjhdY8vOkbIvh4lxTuMao9Y_--hdg"); |
| json_vec = MakeJsonVector(dict); |
| EXPECT_EQ(Status::Success(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json_vec), |
| algorithm, extractable, usages, &key)); |
| |
| // Extractable cases: |
| // 1. input=T, JWK=F ==> fail (inconsistent) |
| // 4. input=F, JWK=F ==> pass, result extractable is F |
| // 2. input=T, JWK=T ==> pass, result extractable is T |
| // 3. input=F, JWK=T ==> pass, result extractable is F |
| EXPECT_EQ(Status::ErrorJwkExtInconsistent(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json_vec), |
| algorithm, true, usages, &key)); |
| EXPECT_EQ(Status::Success(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json_vec), |
| algorithm, false, usages, &key)); |
| EXPECT_FALSE(key.Extractable()); |
| dict.SetBoolean("ext", true); |
| EXPECT_EQ(Status::Success(), |
| ImportKeyJwkFromDict(dict, algorithm, true, usages, &key)); |
| EXPECT_TRUE(key.Extractable()); |
| EXPECT_EQ(Status::Success(), |
| ImportKeyJwkFromDict(dict, algorithm, false, usages, &key)); |
| EXPECT_FALSE(key.Extractable()); |
| dict.SetBoolean("ext", true); // restore previous value |
| |
| // Fail: Input algorithm (AES-CBC) is inconsistent with JWK value |
| // (HMAC SHA256). |
| dict.Clear(); |
| dict.SetString("kty", "oct"); |
| dict.SetString("alg", "HS256"); |
| dict.SetString("k", "l3nZEgZCeX8XRwJdWyK3rGB8qwjhdY8vOkbIvh4lxTuMao9Y_--hdg"); |
| EXPECT_EQ(Status::ErrorJwkAlgorithmInconsistent(), |
| ImportKeyJwkFromDict( |
| dict, CreateAlgorithm(blink::kWebCryptoAlgorithmIdAesCbc), |
| extractable, blink::kWebCryptoKeyUsageEncrypt, &key)); |
| // Fail: Input usage (encrypt) is inconsistent with JWK value (use=sig). |
| EXPECT_EQ(Status::ErrorJwkUseInconsistent(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json_vec), |
| CreateAlgorithm(blink::kWebCryptoAlgorithmIdAesCbc), |
| extractable, blink::kWebCryptoKeyUsageEncrypt, &key)); |
| |
| // Fail: Input algorithm (HMAC SHA1) is inconsistent with JWK value |
| // (HMAC SHA256). |
| EXPECT_EQ(Status::ErrorJwkAlgorithmInconsistent(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json_vec), |
| CreateHmacImportAlgorithmNoLength( |
| blink::kWebCryptoAlgorithmIdSha1), |
| extractable, usages, &key)); |
| |
| // Pass: JWK alg missing but input algorithm specified: use input value |
| dict.Remove("alg", nullptr); |
| EXPECT_EQ(Status::Success(), |
| ImportKeyJwkFromDict(dict, |
| CreateHmacImportAlgorithmNoLength( |
| blink::kWebCryptoAlgorithmIdSha256), |
| extractable, usages, &key)); |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdHmac, algorithm.Id()); |
| dict.SetString("alg", "HS256"); |
| |
| // Fail: Input usages (encrypt) is not a subset of the JWK value |
| // (sign|verify). Moreover "encrypt" is not a valid usage for HMAC. |
| EXPECT_EQ( |
| Status::ErrorCreateKeyBadUsages(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json_vec), algorithm, |
| extractable, blink::kWebCryptoKeyUsageEncrypt, &key)); |
| |
| // Fail: Input usages (encrypt|sign|verify) is not a subset of the JWK |
| // value (sign|verify). Moreover "encrypt" is not a valid usage for HMAC. |
| usages = blink::kWebCryptoKeyUsageEncrypt | blink::kWebCryptoKeyUsageSign | |
| blink::kWebCryptoKeyUsageVerify; |
| EXPECT_EQ(Status::ErrorCreateKeyBadUsages(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json_vec), |
| algorithm, extractable, usages, &key)); |
| |
| // TODO(padolph): kty vs alg consistency tests: Depending on the kty value, |
| // only certain alg values are permitted. For example, when kty = "RSA" alg |
| // must be of the RSA family, or when kty = "oct" alg must be symmetric |
| // algorithm. |
| |
| // TODO(padolph): key_ops consistency tests |
| } |
| |
| TEST_F(WebCryptoHmacTest, ImportJwkHappy) { |
| // This test verifies the happy path of JWK import, including the application |
| // of the imported key material. |
| |
| blink::WebCryptoKey key; |
| bool extractable = false; |
| blink::WebCryptoAlgorithm algorithm = |
| CreateHmacImportAlgorithmNoLength(blink::kWebCryptoAlgorithmIdSha256); |
| blink::WebCryptoKeyUsageMask usages = blink::kWebCryptoKeyUsageSign; |
| |
| // Import a symmetric key JWK and HMAC-SHA256 sign() |
| // Uses the first SHA256 test vector from the HMAC sample set above. |
| |
| base::DictionaryValue dict; |
| dict.SetString("kty", "oct"); |
| dict.SetString("alg", "HS256"); |
| dict.SetString("use", "sig"); |
| dict.SetBoolean("ext", false); |
| dict.SetString("k", "l3nZEgZCeX8XRwJdWyK3rGB8qwjhdY8vOkbIvh4lxTuMao9Y_--hdg"); |
| |
| ASSERT_EQ(Status::Success(), |
| ImportKeyJwkFromDict(dict, algorithm, extractable, usages, &key)); |
| |
| EXPECT_EQ(blink::kWebCryptoAlgorithmIdSha256, |
| key.Algorithm().HmacParams()->GetHash().Id()); |
| |
| const std::vector<uint8_t> message_raw = HexStringToBytes( |
| "b1689c2591eaf3c9e66070f8a77954ffb81749f1b00346f9dfe0b2ee905dcc288baf4a" |
| "92de3f4001dd9f44c468c3d07d6c6ee82faceafc97c2fc0fc0601719d2dcd0aa2aec92" |
| "d1b0ae933c65eb06a03c9c935c2bad0459810241347ab87e9f11adb30415424c6c7f5f" |
| "22a003b8ab8de54f6ded0e3ab9245fa79568451dfa258e"); |
| |
| std::vector<uint8_t> output; |
| |
| ASSERT_EQ(Status::Success(), |
| Sign(CreateAlgorithm(blink::kWebCryptoAlgorithmIdHmac), key, |
| CryptoData(message_raw), &output)); |
| |
| const std::string mac_raw = |
| "769f00d3e6a6cc1fb426a14a4f76c6462e6149726e0dee0ec0cf97a16605ac8b"; |
| |
| EXPECT_BYTES_EQ_HEX(mac_raw, output); |
| |
| // TODO(padolph): Import an RSA public key JWK and use it |
| } |
| |
| TEST_F(WebCryptoHmacTest, ImportExportJwk) { |
| // HMAC SHA-1 |
| ImportExportJwkSymmetricKey( |
| 256, CreateHmacImportAlgorithmNoLength(blink::kWebCryptoAlgorithmIdSha1), |
| blink::kWebCryptoKeyUsageSign | blink::kWebCryptoKeyUsageVerify, "HS1"); |
| |
| // HMAC SHA-384 |
| ImportExportJwkSymmetricKey( |
| 384, |
| CreateHmacImportAlgorithmNoLength(blink::kWebCryptoAlgorithmIdSha384), |
| blink::kWebCryptoKeyUsageSign, "HS384"); |
| |
| // HMAC SHA-512 |
| ImportExportJwkSymmetricKey( |
| 512, |
| CreateHmacImportAlgorithmNoLength(blink::kWebCryptoAlgorithmIdSha512), |
| blink::kWebCryptoKeyUsageVerify, "HS512"); |
| } |
| |
| TEST_F(WebCryptoHmacTest, ExportJwkEmptyKey) { |
| blink::WebCryptoKeyUsageMask usages = blink::kWebCryptoKeyUsageSign; |
| |
| // Importing empty HMAC key is no longer allowed. However such a key can be |
| // created via de-serialization. |
| blink::WebCryptoKey key; |
| ASSERT_TRUE(DeserializeKeyForClone(blink::WebCryptoKeyAlgorithm::CreateHmac( |
| blink::kWebCryptoAlgorithmIdSha1, 0), |
| blink::kWebCryptoKeyTypeSecret, true, |
| usages, CryptoData(), &key)); |
| |
| // Export the key in JWK format and validate. |
| std::vector<uint8_t> json; |
| ASSERT_EQ(Status::Success(), |
| ExportKey(blink::kWebCryptoKeyFormatJwk, key, &json)); |
| EXPECT_TRUE(VerifySecretJwk(json, "HS1", "", usages)); |
| |
| // Now try re-importing the JWK key. |
| key = blink::WebCryptoKey::CreateNull(); |
| EXPECT_EQ(Status::ErrorHmacImportEmptyKey(), |
| ImportKey(blink::kWebCryptoKeyFormatJwk, CryptoData(json), |
| CreateHmacImportAlgorithmNoLength( |
| blink::kWebCryptoAlgorithmIdSha1), |
| true, usages, &key)); |
| } |
| |
| // Imports an HMAC key contaning no byte data. |
| TEST_F(WebCryptoHmacTest, ImportRawEmptyKey) { |
| const blink::WebCryptoAlgorithm import_algorithm = |
| CreateHmacImportAlgorithmNoLength(blink::kWebCryptoAlgorithmIdSha1); |
| |
| blink::WebCryptoKeyUsageMask usages = blink::kWebCryptoKeyUsageSign; |
| blink::WebCryptoKey key; |
| |
| ASSERT_EQ(Status::ErrorHmacImportEmptyKey(), |
| ImportKey(blink::kWebCryptoKeyFormatRaw, CryptoData(), |
| import_algorithm, true, usages, &key)); |
| } |
| |
| // Imports an HMAC key contaning 1 byte data, however the length was set to 0. |
| TEST_F(WebCryptoHmacTest, ImportRawKeyWithZeroLength) { |
| const blink::WebCryptoAlgorithm import_algorithm = |
| CreateHmacImportAlgorithm(blink::kWebCryptoAlgorithmIdSha1, 0); |
| |
| blink::WebCryptoKeyUsageMask usages = blink::kWebCryptoKeyUsageSign; |
| blink::WebCryptoKey key; |
| |
| std::vector<uint8_t> key_data(1); |
| ASSERT_EQ(Status::ErrorHmacImportBadLength(), |
| ImportKey(blink::kWebCryptoKeyFormatRaw, CryptoData(key_data), |
| import_algorithm, true, usages, &key)); |
| } |
| |
| // Import a huge hmac key (UINT_MAX bytes). This will fail before actually |
| // reading the bytes, as the key is too large. |
| TEST_F(WebCryptoHmacTest, ImportRawKeyTooLarge) { |
| CryptoData big_data(nullptr, UINT_MAX); // Invalid data of big length. |
| |
| blink::WebCryptoKey key; |
| EXPECT_EQ(Status::ErrorDataTooLarge(), |
| ImportKey(blink::kWebCryptoKeyFormatRaw, CryptoData(big_data), |
| CreateHmacImportAlgorithmNoLength( |
| blink::kWebCryptoAlgorithmIdSha1), |
| true, blink::kWebCryptoKeyUsageSign, &key)); |
| } |
| |
| // Import an HMAC key with 120 bits of data, however request 128 bits worth. |
| TEST_F(WebCryptoHmacTest, ImportRawKeyLengthTooLarge) { |
| blink::WebCryptoKey key; |
| EXPECT_EQ(Status::ErrorHmacImportBadLength(), |
| ImportKey(blink::kWebCryptoKeyFormatRaw, |
| CryptoData(std::vector<uint8_t>(15)), |
| CreateHmacImportAlgorithmWithLength( |
| blink::kWebCryptoAlgorithmIdSha1, 128), |
| true, blink::kWebCryptoKeyUsageSign, &key)); |
| } |
| |
| // Import an HMAC key with 128 bits of data, however request 120 bits worth. |
| TEST_F(WebCryptoHmacTest, ImportRawKeyLengthTooSmall) { |
| blink::WebCryptoKey key; |
| EXPECT_EQ(Status::ErrorHmacImportBadLength(), |
| ImportKey(blink::kWebCryptoKeyFormatRaw, |
| CryptoData(std::vector<uint8_t>(16)), |
| CreateHmacImportAlgorithmWithLength( |
| blink::kWebCryptoAlgorithmIdSha1, 120), |
| true, blink::kWebCryptoKeyUsageSign, &key)); |
| } |
| |
| // Import an HMAC key with 16 bits of data and request a 12 bit key, using the |
| // "raw" format. |
| TEST_F(WebCryptoHmacTest, ImportRawKeyTruncation) { |
| const std::vector<uint8_t> data = HexStringToBytes("b1ff"); |
| |
| blink::WebCryptoKey key; |
| EXPECT_EQ(Status::Success(), |
| ImportKey(blink::kWebCryptoKeyFormatRaw, CryptoData(data), |
| CreateHmacImportAlgorithmWithLength( |
| blink::kWebCryptoAlgorithmIdSha1, 12), |
| true, blink::kWebCryptoKeyUsageSign, &key)); |
| |
| // On export the last 4 bits has been set to zero. |
| std::vector<uint8_t> raw_key; |
| EXPECT_EQ(Status::Success(), |
| ExportKey(blink::kWebCryptoKeyFormatRaw, key, &raw_key)); |
| EXPECT_BYTES_EQ(HexStringToBytes("b1f0"), raw_key); |
| } |
| |
| // The same test as above, but using the JWK format. |
| TEST_F(WebCryptoHmacTest, ImportJwkKeyTruncation) { |
| base::DictionaryValue dict; |
| dict.SetString("kty", "oct"); |
| dict.SetString("k", "sf8"); // 0xB1FF |
| |
| blink::WebCryptoKey key; |
| EXPECT_EQ(Status::Success(), |
| ImportKeyJwkFromDict(dict, |
| CreateHmacImportAlgorithmWithLength( |
| blink::kWebCryptoAlgorithmIdSha1, 12), |
| true, blink::kWebCryptoKeyUsageSign, &key)); |
| |
| // On export the last 4 bits has been set to zero. |
| std::vector<uint8_t> raw_key; |
| EXPECT_EQ(Status::Success(), |
| ExportKey(blink::kWebCryptoKeyFormatRaw, key, &raw_key)); |
| EXPECT_BYTES_EQ(HexStringToBytes("b1f0"), raw_key); |
| } |
| |
| } // namespace |
| |
| } // namespace webcrypto |