crypto/hpke/hpke_test.cc - boringssl - Git at Google

 // Copyright 2020 The BoringSSL Authors
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     https://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #include <openssl/hpke.h>

 #include <cstdint>
 #include <limits>
 #include <string>
 #include <vector>

 #include <gtest/gtest.h>

 #include <openssl/base.h>
 #include <openssl/curve25519.h>
 #include <openssl/digest.h>
 #include <openssl/err.h>
 #include <openssl/evp.h>
 #include <openssl/rand.h>
 #include <openssl/sha.h>
 #include <openssl/span.h>

 #include "../test/file_test.h"
 #include "../test/test_util.h"


 BSSL_NAMESPACE_BEGIN
 namespace {

 const decltype(&EVP_hpke_x25519_hkdf_sha256) kAllKEMs[] = {
     &EVP_hpke_p256_hkdf_sha256,
     &EVP_hpke_x25519_hkdf_sha256,
 };

 const decltype(&EVP_hpke_aes_128_gcm) kAllAEADs[] = {
     &EVP_hpke_aes_128_gcm,
     &EVP_hpke_aes_256_gcm,
     &EVP_hpke_chacha20_poly1305,
 };

 const decltype(&EVP_hpke_hkdf_sha256) kAllKDFs[] = {
     &EVP_hpke_hkdf_sha256,
 };

 // HPKETestVector corresponds to one array member in the published
 // test-vectors.json.
 class HPKETestVector {
  public:
   explicit HPKETestVector() = default;
   ~HPKETestVector() = default;

   bool ReadFromFileTest(FileTest *t);

   void Verify() const {
     const EVP_HPKE_KEM *kem = GetKEM();
     const EVP_HPKE_AEAD *aead = GetAEAD();
     ASSERT_TRUE(aead);
     const EVP_HPKE_KDF *kdf = GetKDF();
     ASSERT_TRUE(kdf);

     // Test the sender.
     ScopedEVP_HPKE_CTX sender_ctx;
     uint8_t enc[EVP_HPKE_MAX_ENC_LENGTH];
     size_t enc_len = 0;

     // X25519 uses the secret key directly. P-256 uses the IKM to derive a key.
     bssl::Span<const uint8_t> secret_input = secret_key_e_;
     if (kem_id_ == EVP_HPKE_DHKEM_P256_HKDF_SHA256) {
       secret_input = ikm_e_;
     }

     switch (mode_) {
       case Mode::kBase:
         ASSERT_TRUE(EVP_HPKE_CTX_setup_sender_with_seed_for_testing(
             sender_ctx.get(), enc, &enc_len, sizeof(enc), kem, kdf, aead,
             public_key_r_.data(), public_key_r_.size(), info_.data(),
             info_.size(), secret_input.data(), secret_input.size()));
         break;
       case Mode::kAuth: {
         ScopedEVP_HPKE_KEY sender_key;
         ASSERT_TRUE(EVP_HPKE_KEY_init(
             sender_key.get(), kem, secret_key_s_.data(), secret_key_s_.size()));
         ASSERT_TRUE(EVP_HPKE_CTX_setup_auth_sender_with_seed_for_testing(
             sender_ctx.get(), enc, &enc_len, sizeof(enc), sender_key.get(), kdf,
             aead, public_key_r_.data(), public_key_r_.size(), info_.data(),
             info_.size(), secret_input.data(), secret_input.size()));
         break;
       }
     }

     EXPECT_EQ(Bytes(enc, enc_len), Bytes(public_key_e_));
     VerifySender(sender_ctx.get());

     // Test the recipient.
     ScopedEVP_HPKE_KEY base_key;
     ASSERT_TRUE(EVP_HPKE_KEY_init(base_key.get(), kem, secret_key_r_.data(),
                                   secret_key_r_.size()));

     enum class CopyMode { kOriginal, kCopy, kMove };
     for (CopyMode copy :
          {CopyMode::kOriginal, CopyMode::kCopy, CopyMode::kMove}) {
       SCOPED_TRACE(static_cast<int>(copy));
       const EVP_HPKE_KEY *key = base_key.get();
       ScopedEVP_HPKE_KEY key_copy;
       switch (copy) {
         case CopyMode::kOriginal:
           break;
         case CopyMode::kCopy:
           ASSERT_TRUE(EVP_HPKE_KEY_copy(key_copy.get(), base_key.get()));
           key = key_copy.get();
           break;
         case CopyMode::kMove:
           EVP_HPKE_KEY_move(key_copy.get(), base_key.get());
           key = key_copy.get();
           break;
       }

       uint8_t public_key[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
       size_t public_key_len;
       ASSERT_TRUE(EVP_HPKE_KEY_public_key(key, public_key, &public_key_len,
                                           sizeof(public_key)));
       EXPECT_EQ(Bytes(public_key, public_key_len), Bytes(public_key_r_));

       uint8_t private_key[EVP_HPKE_MAX_PRIVATE_KEY_LENGTH];
       size_t private_key_len;
       ASSERT_TRUE(EVP_HPKE_KEY_private_key(key, private_key, &private_key_len,
                                            sizeof(private_key)));
       EXPECT_EQ(Bytes(private_key, private_key_len), Bytes(secret_key_r_));

       // Set up the recipient.
       ScopedEVP_HPKE_CTX recipient_ctx;
       switch (mode_) {
         case Mode::kBase:
           ASSERT_TRUE(EVP_HPKE_CTX_setup_recipient(recipient_ctx.get(), key,
                                                    kdf, aead, enc, enc_len,
                                                    info_.data(), info_.size()));
           break;
         case Mode::kAuth:
           ASSERT_TRUE(EVP_HPKE_CTX_setup_auth_recipient(
               recipient_ctx.get(), key, kdf, aead, enc, enc_len, info_.data(),
               info_.size(), public_key_s_.data(), public_key_s_.size()));
           break;
       }

       VerifyRecipient(recipient_ctx.get());
     }
   }

  private:
   const EVP_HPKE_KEM *GetKEM() const {
     for (const auto kem : kAllKEMs) {
       if (EVP_HPKE_KEM_id(kem()) == kem_id_) {
         return kem();
       }
     }
     return nullptr;
   }

   const EVP_HPKE_AEAD *GetAEAD() const {
     for (const auto aead : kAllAEADs) {
       if (EVP_HPKE_AEAD_id(aead()) == aead_id_) {
         return aead();
       }
     }
     return nullptr;
   }

   const EVP_HPKE_KDF *GetKDF() const {
     for (const auto kdf : kAllKDFs) {
       if (EVP_HPKE_KDF_id(kdf()) == kdf_id_) {
         return kdf();
       }
     }
     return nullptr;
   }

   void VerifySender(EVP_HPKE_CTX *ctx) const {
     for (const Encryption &task : encryptions_) {
       std::vector<uint8_t> encrypted(task.plaintext.size() +
                                      EVP_HPKE_CTX_max_overhead(ctx));
       size_t encrypted_len;
       ASSERT_TRUE(EVP_HPKE_CTX_seal(ctx, encrypted.data(), &encrypted_len,
                                     encrypted.size(), task.plaintext.data(),
                                     task.plaintext.size(), task.aad.data(),
                                     task.aad.size()));

       ASSERT_EQ(Bytes(encrypted.data(), encrypted_len), Bytes(task.ciphertext));
     }
     VerifyExports(ctx);
   }

   void VerifyRecipient(EVP_HPKE_CTX *ctx) const {
     for (const Encryption &task : encryptions_) {
       std::vector<uint8_t> decrypted(task.ciphertext.size());
       size_t decrypted_len;
       ASSERT_TRUE(EVP_HPKE_CTX_open(ctx, decrypted.data(), &decrypted_len,
                                     decrypted.size(), task.ciphertext.data(),
                                     task.ciphertext.size(), task.aad.data(),
                                     task.aad.size()));

       ASSERT_EQ(Bytes(decrypted.data(), decrypted_len), Bytes(task.plaintext));
     }
     VerifyExports(ctx);
   }

   void VerifyExports(EVP_HPKE_CTX *ctx) const {
     for (const Export &task : exports_) {
       std::vector<uint8_t> exported_secret(task.export_length);

       ASSERT_TRUE(EVP_HPKE_CTX_export(
           ctx, exported_secret.data(), exported_secret.size(),
           task.exporter_context.data(), task.exporter_context.size()));
       ASSERT_EQ(Bytes(exported_secret), Bytes(task.exported_value));
     }
   }

   enum class Mode {
     kBase = 0,
     kAuth = 2,
   };

   struct Encryption {
     std::vector<uint8_t> aad;
     std::vector<uint8_t> ciphertext;
     std::vector<uint8_t> plaintext;
   };

   struct Export {
     std::vector<uint8_t> exporter_context;
     size_t export_length;
     std::vector<uint8_t> exported_value;
   };

   Mode mode_;
   uint16_t kem_id_;
   uint16_t kdf_id_;
   uint16_t aead_id_;
   std::vector<uint8_t> context_;
   std::vector<uint8_t> info_;
   std::vector<uint8_t> public_key_e_;
   std::vector<uint8_t> secret_key_e_;
   std::vector<uint8_t> ikm_e_;
   std::vector<uint8_t> public_key_r_;
   std::vector<uint8_t> secret_key_r_;
   std::vector<uint8_t> ikm_r_;
   std::vector<uint8_t> public_key_s_;
   std::vector<uint8_t> secret_key_s_;
   std::vector<Encryption> encryptions_;
   std::vector<Export> exports_;
 };

 // Match FileTest's naming scheme for duplicated attribute names.
 std::string BuildAttrName(const std::string &name, int iter) {
   return iter == 1 ? name : name + "/" + std::to_string(iter);
 }

 // Parses |s| as an unsigned integer of type T and writes the value to |out|.
 // Returns true on success. If the integer value exceeds the maximum T value,
 // returns false.
 template <typename T>
 bool ParseIntSafe(T *out, const std::string &s) {
   T value = 0;
   for (char c : s) {
     if (c < '0' || c > '9') {
       return false;
     }
     if (value > (std::numeric_limits<T>::max() - (c - '0')) / 10) {
       return false;
     }
     value = 10 * value + (c - '0');
   }
   *out = value;
   return true;
 }

 // Read the |key| attribute from |file_test| and convert it to an integer.
 template <typename T>
 bool FileTestReadInt(FileTest *file_test, T *out, const std::string &key) {
   std::string s;
   return file_test->GetAttribute(&s, key) && ParseIntSafe(out, s);
 }


 bool HPKETestVector::ReadFromFileTest(FileTest *t) {
   uint8_t mode = 0;
   if (!FileTestReadInt(t, &mode, "mode") ||
       !FileTestReadInt(t, &kem_id_, "kem_id") ||
       !FileTestReadInt(t, &kdf_id_, "kdf_id") ||
       !FileTestReadInt(t, &aead_id_, "aead_id") ||
       !t->GetBytes(&info_, "info") ||  //
       !t->GetBytes(&secret_key_r_, "skRm") ||
       !t->GetBytes(&public_key_r_, "pkRm") ||
       !t->GetBytes(&ikm_r_, "ikmR") ||  //
       !t->GetBytes(&secret_key_e_, "skEm") ||
       !t->GetBytes(&public_key_e_, "pkEm") ||  //
       !t->GetBytes(&ikm_e_, "ikmE")) {
     return false;
   }

   switch (mode) {
     case static_cast<int>(Mode::kBase):
       mode_ = Mode::kBase;
       break;
     case static_cast<int>(Mode::kAuth):
       mode_ = Mode::kAuth;
       if (!t->GetBytes(&secret_key_s_, "skSm") ||
           !t->GetBytes(&public_key_s_, "pkSm")) {
         return false;
       }
       break;
     default:
       return false;
   }

   for (int i = 1; t->HasAttribute(BuildAttrName("aad", i)); i++) {
     Encryption encryption;
     if (!t->GetBytes(&encryption.aad, BuildAttrName("aad", i)) ||
         !t->GetBytes(&encryption.ciphertext, BuildAttrName("ct", i)) ||
         !t->GetBytes(&encryption.plaintext, BuildAttrName("pt", i))) {
       return false;
     }
     encryptions_.push_back(std::move(encryption));
   }

   for (int i = 1; t->HasAttribute(BuildAttrName("exporter_context", i)); i++) {
     Export exp;
     if (!t->GetBytes(&exp.exporter_context,
                      BuildAttrName("exporter_context", i)) ||
         !FileTestReadInt(t, &exp.export_length, BuildAttrName("L", i)) ||
         !t->GetBytes(&exp.exported_value, BuildAttrName("exported_value", i))) {
       return false;
     }
     exports_.push_back(std::move(exp));
   }
   return true;
 }

 }  // namespace

 TEST(HPKETest, VerifyTestVectors) {
   FileTestGTest("crypto/hpke/hpke_test_vectors.txt", [](FileTest *t) {
     HPKETestVector test_vec;
     EXPECT_TRUE(test_vec.ReadFromFileTest(t));
     test_vec.Verify();
   });
 }

 // The test vectors used fixed sender ephemeral keys, while HPKE itself
 // generates new keys for each context. Test this codepath by checking we can
 // decrypt our own messages.
 TEST(HPKETest, RoundTrip) {
   const uint8_t info_a[] = {1, 1, 2, 3, 5, 8};
   const uint8_t info_b[] = {42, 42, 42};
   const uint8_t ad_a[] = {1, 2, 4, 8, 16};
   const uint8_t ad_b[] = {7};
   Span<const uint8_t> info_values[] = {{nullptr, 0}, info_a, info_b};
   Span<const uint8_t> ad_values[] = {{nullptr, 0}, ad_a, ad_b};

   for (const auto kem : kAllKEMs) {
     SCOPED_TRACE(EVP_HPKE_KEM_id(kem()));

     // Generate the recipient's keypair.
     ScopedEVP_HPKE_KEY key;
     ASSERT_TRUE(EVP_HPKE_KEY_generate(key.get(), kem()));
     uint8_t public_key_r[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
     size_t public_key_r_len;
     ASSERT_TRUE(EVP_HPKE_KEY_public_key(
         key.get(), public_key_r, &public_key_r_len, sizeof(public_key_r)));

     // Generate the sender's keypair, for auth modes.
     ScopedEVP_HPKE_KEY sender_key;
     ASSERT_TRUE(EVP_HPKE_KEY_generate(sender_key.get(), kem()));
     uint8_t public_key_s[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
     size_t public_key_s_len;
     ASSERT_TRUE(EVP_HPKE_KEY_public_key(sender_key.get(), public_key_s,
                                         &public_key_s_len,
                                         sizeof(public_key_s)));

     for (const auto kdf : kAllKDFs) {
       SCOPED_TRACE(EVP_HPKE_KDF_id(kdf()));
       for (const auto aead : kAllAEADs) {
         SCOPED_TRACE(EVP_HPKE_AEAD_id(aead()));
         for (const Span<const uint8_t> &info : info_values) {
           SCOPED_TRACE(Bytes(info));
           for (const Span<const uint8_t> &ad : ad_values) {
             SCOPED_TRACE(Bytes(ad));

             auto check_messages = [&](EVP_HPKE_CTX *sender_ctx,
                                       EVP_HPKE_CTX *recipient_ctx) {
               const char kCleartextPayload[] = "foobar";

               // Have sender encrypt message for the recipient.
               std::vector<uint8_t> ciphertext(
                   sizeof(kCleartextPayload) +
                   EVP_HPKE_CTX_max_overhead(sender_ctx));
               size_t ciphertext_len;
               ASSERT_TRUE(EVP_HPKE_CTX_seal(
                   sender_ctx, ciphertext.data(), &ciphertext_len,
                   ciphertext.size(),
                   reinterpret_cast<const uint8_t *>(kCleartextPayload),
                   sizeof(kCleartextPayload), ad.data(), ad.size()));

               // Have recipient decrypt the message.
               std::vector<uint8_t> cleartext(ciphertext.size());
               size_t cleartext_len;
               ASSERT_TRUE(EVP_HPKE_CTX_open(recipient_ctx, cleartext.data(),
                                             &cleartext_len, cleartext.size(),
                                             ciphertext.data(), ciphertext_len,
                                             ad.data(), ad.size()));

               // Verify that decrypted message matches the original.
               ASSERT_EQ(Bytes(cleartext.data(), cleartext_len),
                         Bytes(kCleartextPayload, sizeof(kCleartextPayload)));
             };

             // Test the base mode.
             {
               ScopedEVP_HPKE_CTX sender_ctx;
               uint8_t enc[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
               size_t enc_len;
               ASSERT_TRUE(EVP_HPKE_CTX_setup_sender(
                   sender_ctx.get(), enc, &enc_len, sizeof(enc), kem(), kdf(),
                   aead(), public_key_r, public_key_r_len, info.data(),
                   info.size()));

               ScopedEVP_HPKE_CTX recipient_ctx;
               ASSERT_TRUE(EVP_HPKE_CTX_setup_recipient(
                   recipient_ctx.get(), key.get(), kdf(), aead(), enc, enc_len,
                   info.data(), info.size()));

               check_messages(sender_ctx.get(), recipient_ctx.get());
             }

             // Test the auth mode.
             {
               ScopedEVP_HPKE_CTX sender_ctx;
               uint8_t enc[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
               size_t enc_len;
               ASSERT_TRUE(EVP_HPKE_CTX_setup_auth_sender(
                   sender_ctx.get(), enc, &enc_len, sizeof(enc),
                   sender_key.get(), kdf(), aead(), public_key_r,
                   public_key_r_len, info.data(), info.size()));

               ScopedEVP_HPKE_CTX recipient_ctx;
               ASSERT_TRUE(EVP_HPKE_CTX_setup_auth_recipient(
                   recipient_ctx.get(), key.get(), kdf(), aead(), enc, enc_len,
                   info.data(), info.size(), public_key_s, public_key_s_len));

               check_messages(sender_ctx.get(), recipient_ctx.get());
             }
           }
         }
       }
     }
   }
 }

 // Verify that the DH operations inside Encap() and Decap() both fail when the
 // public key is on a small-order point in the curve.
 TEST(HPKETest, X25519EncapSmallOrderPoint) {
   // Borrowed from X25519Test.SmallOrder.
   static const uint8_t kSmallOrderPoint[32] = {
       0xe0, 0xeb, 0x7a, 0x7c, 0x3b, 0x41, 0xb8, 0xae, 0x16, 0x56, 0xe3,
       0xfa, 0xf1, 0x9f, 0xc4, 0x6a, 0xda, 0x09, 0x8d, 0xeb, 0x9c, 0x32,
       0xb1, 0xfd, 0x86, 0x62, 0x05, 0x16, 0x5f, 0x49, 0xb8,
   };
   static const uint8_t kValidPoint[32] = {
       0xe6, 0xdb, 0x68, 0x67, 0x58, 0x30, 0x30, 0xdb, 0x35, 0x94, 0xc1,
       0xa4, 0x24, 0xb1, 0x5f, 0x7c, 0x72, 0x66, 0x24, 0xec, 0x26, 0xb3,
       0x35, 0x3b, 0x10, 0xa9, 0x03, 0xa6, 0xd0, 0xab, 0x1c, 0x4c,
   };

   ScopedEVP_HPKE_KEY key;
   ASSERT_TRUE(EVP_HPKE_KEY_generate(key.get(), EVP_hpke_x25519_hkdf_sha256()));

   for (const auto kdf : kAllKDFs) {
     SCOPED_TRACE(EVP_HPKE_KDF_id(kdf()));
     for (const auto aead : kAllAEADs) {
       SCOPED_TRACE(EVP_HPKE_AEAD_id(aead()));
       // Set up the sender, passing in kSmallOrderPoint as |peer_public_key|.
       ScopedEVP_HPKE_CTX sender_ctx;
       uint8_t enc[X25519_PUBLIC_VALUE_LEN];
       size_t enc_len;
       EXPECT_FALSE(EVP_HPKE_CTX_setup_sender(
           sender_ctx.get(), enc, &enc_len, sizeof(enc),
           EVP_hpke_x25519_hkdf_sha256(), kdf(), aead(), kSmallOrderPoint,
           sizeof(kSmallOrderPoint), nullptr, 0));

       // Likewise with auth.
       EXPECT_FALSE(EVP_HPKE_CTX_setup_auth_sender(
           sender_ctx.get(), enc, &enc_len, sizeof(enc), key.get(), kdf(),
           aead(), kSmallOrderPoint, sizeof(kSmallOrderPoint), nullptr, 0));

       // Set up the recipient, passing in kSmallOrderPoint as |enc|.
       ScopedEVP_HPKE_CTX recipient_ctx;
       EXPECT_FALSE(EVP_HPKE_CTX_setup_recipient(
           recipient_ctx.get(), key.get(), kdf(), aead(), kSmallOrderPoint,
           sizeof(kSmallOrderPoint), nullptr, 0));

       // Likewise with auth. With auth, a small-order point could appear as
       // either |enc| or the peer public key.
       EXPECT_FALSE(EVP_HPKE_CTX_setup_auth_recipient(
           recipient_ctx.get(), key.get(), kdf(), aead(), kSmallOrderPoint,
           sizeof(kSmallOrderPoint), nullptr, 0, kValidPoint,
           sizeof(kValidPoint)));
       EXPECT_FALSE(EVP_HPKE_CTX_setup_auth_recipient(
           recipient_ctx.get(), key.get(), kdf(), aead(), kValidPoint,
           sizeof(kValidPoint), nullptr, 0, kSmallOrderPoint,
           sizeof(kSmallOrderPoint)));
     }
   }
 }

 // Test that Seal() fails when the context has been initialized as a recipient.
 TEST(HPKETest, RecipientInvalidSeal) {
   const uint8_t kMockEnc[X25519_PUBLIC_VALUE_LEN] = {0xff};
   const char kCleartextPayload[] = "foobar";

   ScopedEVP_HPKE_KEY key;
   ASSERT_TRUE(EVP_HPKE_KEY_generate(key.get(), EVP_hpke_x25519_hkdf_sha256()));

   // Set up the recipient.
   ScopedEVP_HPKE_CTX recipient_ctx;
   ASSERT_TRUE(EVP_HPKE_CTX_setup_recipient(
       recipient_ctx.get(), key.get(), EVP_hpke_hkdf_sha256(),
       EVP_hpke_aes_128_gcm(), kMockEnc, sizeof(kMockEnc), nullptr, 0));

   // Call Seal() on the recipient.
   size_t ciphertext_len;
   uint8_t ciphertext[100];
   ASSERT_FALSE(EVP_HPKE_CTX_seal(
       recipient_ctx.get(), ciphertext, &ciphertext_len, sizeof(ciphertext),
       reinterpret_cast<const uint8_t *>(kCleartextPayload),
       sizeof(kCleartextPayload), nullptr, 0));
 }

 // Test that Open() fails when the context has been initialized as a sender.
 TEST(HPKETest, SenderInvalidOpen) {
   const uint8_t kMockCiphertext[100] = {0xff};
   const size_t kMockCiphertextLen = 80;

   // Generate the recipient's keypair.
   uint8_t secret_key_r[X25519_PRIVATE_KEY_LEN];
   uint8_t public_key_r[X25519_PUBLIC_VALUE_LEN];
   X25519_keypair(public_key_r, secret_key_r);

   // Set up the sender.
   ScopedEVP_HPKE_CTX sender_ctx;
   uint8_t enc[X25519_PUBLIC_VALUE_LEN];
   size_t enc_len;
   ASSERT_TRUE(EVP_HPKE_CTX_setup_sender(
       sender_ctx.get(), enc, &enc_len, sizeof(enc),
       EVP_hpke_x25519_hkdf_sha256(), EVP_hpke_hkdf_sha256(),
       EVP_hpke_aes_128_gcm(), public_key_r, sizeof(public_key_r), nullptr, 0));

   // Call Open() on the sender.
   uint8_t cleartext[128];
   size_t cleartext_len;
   ASSERT_FALSE(EVP_HPKE_CTX_open(sender_ctx.get(), cleartext, &cleartext_len,
                                  sizeof(cleartext), kMockCiphertext,
                                  kMockCiphertextLen, nullptr, 0));
 }

 TEST(HPKETest, SetupSenderBufferTooSmall) {
   uint8_t secret_key_r[X25519_PRIVATE_KEY_LEN];
   uint8_t public_key_r[X25519_PUBLIC_VALUE_LEN];
   X25519_keypair(public_key_r, secret_key_r);

   ScopedEVP_HPKE_CTX sender_ctx;
   uint8_t enc[X25519_PUBLIC_VALUE_LEN - 1];
   size_t enc_len;
   ASSERT_FALSE(EVP_HPKE_CTX_setup_sender(
       sender_ctx.get(), enc, &enc_len, sizeof(enc),
       EVP_hpke_x25519_hkdf_sha256(), EVP_hpke_hkdf_sha256(),
       EVP_hpke_aes_128_gcm(), public_key_r, sizeof(public_key_r), nullptr, 0));
   EXPECT_TRUE(
       ErrorEquals(ERR_get_error(), ERR_LIB_EVP, EVP_R_INVALID_BUFFER_SIZE));
   ERR_clear_error();
 }

 TEST(HPKETest, SetupSenderBufferTooLarge) {
   uint8_t secret_key_r[X25519_PRIVATE_KEY_LEN];
   uint8_t public_key_r[X25519_PUBLIC_VALUE_LEN];
   X25519_keypair(public_key_r, secret_key_r);

   // Too large of an output buffer is fine because the function reports the
   // actual length.
   ScopedEVP_HPKE_CTX sender_ctx;
   uint8_t enc[X25519_PUBLIC_VALUE_LEN + 1];
   size_t enc_len;
   EXPECT_TRUE(EVP_HPKE_CTX_setup_sender(
       sender_ctx.get(), enc, &enc_len, sizeof(enc),
       EVP_hpke_x25519_hkdf_sha256(), EVP_hpke_hkdf_sha256(),
       EVP_hpke_aes_128_gcm(), public_key_r, sizeof(public_key_r), nullptr, 0));
   EXPECT_EQ(size_t{X25519_PUBLIC_VALUE_LEN}, enc_len);
 }

 TEST(HPKETest, SetupRecipientWrongLengthEnc) {
   ScopedEVP_HPKE_KEY key;
   ASSERT_TRUE(EVP_HPKE_KEY_generate(key.get(), EVP_hpke_x25519_hkdf_sha256()));

   const uint8_t bogus_enc[X25519_PUBLIC_VALUE_LEN + 5] = {0xff};

   ScopedEVP_HPKE_CTX recipient_ctx;
   ASSERT_FALSE(EVP_HPKE_CTX_setup_recipient(
       recipient_ctx.get(), key.get(), EVP_hpke_hkdf_sha256(),
       EVP_hpke_aes_128_gcm(), bogus_enc, sizeof(bogus_enc), nullptr, 0));
   EXPECT_TRUE(
       ErrorEquals(ERR_get_error(), ERR_LIB_EVP, EVP_R_INVALID_PEER_KEY));
   ERR_clear_error();
 }

 TEST(HPKETest, SetupSenderWrongLengthPeerPublicValue) {
   const uint8_t bogus_public_key_r[X25519_PRIVATE_KEY_LEN + 5] = {0xff};
   ScopedEVP_HPKE_CTX sender_ctx;
   uint8_t enc[X25519_PUBLIC_VALUE_LEN];
   size_t enc_len;
   ASSERT_FALSE(EVP_HPKE_CTX_setup_sender(
       sender_ctx.get(), enc, &enc_len, sizeof(enc),
       EVP_hpke_x25519_hkdf_sha256(), EVP_hpke_hkdf_sha256(),
       EVP_hpke_aes_128_gcm(), bogus_public_key_r, sizeof(bogus_public_key_r),
       nullptr, 0));
   EXPECT_TRUE(
       ErrorEquals(ERR_get_error(), ERR_LIB_EVP, EVP_R_INVALID_PEER_KEY));
   ERR_clear_error();
 }

 TEST(HPKETest, InvalidRecipientKey) {
   const uint8_t private_key[X25519_PUBLIC_VALUE_LEN + 5] = {0xff};
   ScopedEVP_HPKE_KEY key;
   EXPECT_FALSE(EVP_HPKE_KEY_init(key.get(), EVP_hpke_x25519_hkdf_sha256(),
                                  private_key, sizeof(private_key)));
 }

 TEST(HPKETest, InvalidP256PrivateKey) {
   const uint8_t zero_key[32] = {0};
   ScopedEVP_HPKE_KEY key;
   EXPECT_FALSE(EVP_HPKE_KEY_init(key.get(), EVP_hpke_p256_hkdf_sha256(),
                                  zero_key, sizeof(zero_key)));

   uint8_t all_ones_key[32];
   OPENSSL_memset(all_ones_key, 0xff, sizeof(all_ones_key));
   EXPECT_FALSE(EVP_HPKE_KEY_init(key.get(), EVP_hpke_p256_hkdf_sha256(),
                                  all_ones_key, sizeof(all_ones_key)));
 }

 TEST(HPKETest, InternalParseIntSafe) {
   uint8_t u8 = 0xff;
   ASSERT_FALSE(ParseIntSafe(&u8, "-1"));

   ASSERT_TRUE(ParseIntSafe(&u8, "0"));
   ASSERT_EQ(u8, 0);

   ASSERT_TRUE(ParseIntSafe(&u8, "255"));
   ASSERT_EQ(u8, 255);

   ASSERT_FALSE(ParseIntSafe(&u8, "256"));

   uint16_t u16 = 0xffff;
   ASSERT_TRUE(ParseIntSafe(&u16, "257"));
   ASSERT_EQ(u16, 257);

   ASSERT_TRUE(ParseIntSafe(&u16, "65535"));
   ASSERT_EQ(u16, 65535);

   ASSERT_FALSE(ParseIntSafe(&u16, "65536"));
 }

 BSSL_NAMESPACE_END
	// Copyright 2020 The BoringSSL Authors
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// https://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#include <openssl/hpke.h>

	#include <cstdint>
	#include <limits>
	#include <string>
	#include <vector>

	#include <gtest/gtest.h>

	#include <openssl/base.h>
	#include <openssl/curve25519.h>
	#include <openssl/digest.h>
	#include <openssl/err.h>
	#include <openssl/evp.h>
	#include <openssl/rand.h>
	#include <openssl/sha.h>
	#include <openssl/span.h>

	#include "../test/file_test.h"
	#include "../test/test_util.h"


	BSSL_NAMESPACE_BEGIN
	namespace {

	const decltype(&EVP_hpke_x25519_hkdf_sha256) kAllKEMs[] = {
	&EVP_hpke_p256_hkdf_sha256,
	&EVP_hpke_x25519_hkdf_sha256,
	};

	const decltype(&EVP_hpke_aes_128_gcm) kAllAEADs[] = {
	&EVP_hpke_aes_128_gcm,
	&EVP_hpke_aes_256_gcm,
	&EVP_hpke_chacha20_poly1305,
	};

	const decltype(&EVP_hpke_hkdf_sha256) kAllKDFs[] = {
	&EVP_hpke_hkdf_sha256,
	};

	// HPKETestVector corresponds to one array member in the published
	// test-vectors.json.
	class HPKETestVector {
	public:
	explicit HPKETestVector() = default;
	~HPKETestVector() = default;

	bool ReadFromFileTest(FileTest *t);

	void Verify() const {
	const EVP_HPKE_KEM *kem = GetKEM();
	const EVP_HPKE_AEAD *aead = GetAEAD();
	ASSERT_TRUE(aead);
	const EVP_HPKE_KDF *kdf = GetKDF();
	ASSERT_TRUE(kdf);

	// Test the sender.
	ScopedEVP_HPKE_CTX sender_ctx;
	uint8_t enc[EVP_HPKE_MAX_ENC_LENGTH];
	size_t enc_len = 0;

	// X25519 uses the secret key directly. P-256 uses the IKM to derive a key.
	bssl::Span<const uint8_t> secret_input = secret_key_e_;
	if (kem_id_ == EVP_HPKE_DHKEM_P256_HKDF_SHA256) {
	secret_input = ikm_e_;
	}

	switch (mode_) {
	case Mode::kBase:
	ASSERT_TRUE(EVP_HPKE_CTX_setup_sender_with_seed_for_testing(
	sender_ctx.get(), enc, &enc_len, sizeof(enc), kem, kdf, aead,
	public_key_r_.data(), public_key_r_.size(), info_.data(),
	info_.size(), secret_input.data(), secret_input.size()));
	break;
	case Mode::kAuth: {
	ScopedEVP_HPKE_KEY sender_key;
	ASSERT_TRUE(EVP_HPKE_KEY_init(
	sender_key.get(), kem, secret_key_s_.data(), secret_key_s_.size()));
	ASSERT_TRUE(EVP_HPKE_CTX_setup_auth_sender_with_seed_for_testing(
	sender_ctx.get(), enc, &enc_len, sizeof(enc), sender_key.get(), kdf,
	aead, public_key_r_.data(), public_key_r_.size(), info_.data(),
	info_.size(), secret_input.data(), secret_input.size()));
	break;
	}
	}

	EXPECT_EQ(Bytes(enc, enc_len), Bytes(public_key_e_));
	VerifySender(sender_ctx.get());

	// Test the recipient.
	ScopedEVP_HPKE_KEY base_key;
	ASSERT_TRUE(EVP_HPKE_KEY_init(base_key.get(), kem, secret_key_r_.data(),
	secret_key_r_.size()));

	enum class CopyMode { kOriginal, kCopy, kMove };
	for (CopyMode copy :
	{CopyMode::kOriginal, CopyMode::kCopy, CopyMode::kMove}) {
	SCOPED_TRACE(static_cast<int>(copy));
	const EVP_HPKE_KEY *key = base_key.get();
	ScopedEVP_HPKE_KEY key_copy;
	switch (copy) {
	case CopyMode::kOriginal:
	break;
	case CopyMode::kCopy:
	ASSERT_TRUE(EVP_HPKE_KEY_copy(key_copy.get(), base_key.get()));
	key = key_copy.get();
	break;
	case CopyMode::kMove:
	EVP_HPKE_KEY_move(key_copy.get(), base_key.get());
	key = key_copy.get();
	break;
	}

	uint8_t public_key[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
	size_t public_key_len;
	ASSERT_TRUE(EVP_HPKE_KEY_public_key(key, public_key, &public_key_len,
	sizeof(public_key)));
	EXPECT_EQ(Bytes(public_key, public_key_len), Bytes(public_key_r_));

	uint8_t private_key[EVP_HPKE_MAX_PRIVATE_KEY_LENGTH];
	size_t private_key_len;
	ASSERT_TRUE(EVP_HPKE_KEY_private_key(key, private_key, &private_key_len,
	sizeof(private_key)));
	EXPECT_EQ(Bytes(private_key, private_key_len), Bytes(secret_key_r_));

	// Set up the recipient.
	ScopedEVP_HPKE_CTX recipient_ctx;
	switch (mode_) {
	case Mode::kBase:
	ASSERT_TRUE(EVP_HPKE_CTX_setup_recipient(recipient_ctx.get(), key,
	kdf, aead, enc, enc_len,
	info_.data(), info_.size()));
	break;
	case Mode::kAuth:
	ASSERT_TRUE(EVP_HPKE_CTX_setup_auth_recipient(
	recipient_ctx.get(), key, kdf, aead, enc, enc_len, info_.data(),
	info_.size(), public_key_s_.data(), public_key_s_.size()));
	break;
	}

	VerifyRecipient(recipient_ctx.get());
	}
	}

	private:
	const EVP_HPKE_KEM *GetKEM() const {
	for (const auto kem : kAllKEMs) {
	if (EVP_HPKE_KEM_id(kem()) == kem_id_) {
	return kem();
	}
	}
	return nullptr;
	}

	const EVP_HPKE_AEAD *GetAEAD() const {
	for (const auto aead : kAllAEADs) {
	if (EVP_HPKE_AEAD_id(aead()) == aead_id_) {
	return aead();
	}
	}
	return nullptr;
	}

	const EVP_HPKE_KDF *GetKDF() const {
	for (const auto kdf : kAllKDFs) {
	if (EVP_HPKE_KDF_id(kdf()) == kdf_id_) {
	return kdf();
	}
	}
	return nullptr;
	}

	void VerifySender(EVP_HPKE_CTX *ctx) const {
	for (const Encryption &task : encryptions_) {
	std::vector<uint8_t> encrypted(task.plaintext.size() +
	EVP_HPKE_CTX_max_overhead(ctx));
	size_t encrypted_len;
	ASSERT_TRUE(EVP_HPKE_CTX_seal(ctx, encrypted.data(), &encrypted_len,
	encrypted.size(), task.plaintext.data(),
	task.plaintext.size(), task.aad.data(),
	task.aad.size()));

	ASSERT_EQ(Bytes(encrypted.data(), encrypted_len), Bytes(task.ciphertext));
	}
	VerifyExports(ctx);
	}

	void VerifyRecipient(EVP_HPKE_CTX *ctx) const {
	for (const Encryption &task : encryptions_) {
	std::vector<uint8_t> decrypted(task.ciphertext.size());
	size_t decrypted_len;
	ASSERT_TRUE(EVP_HPKE_CTX_open(ctx, decrypted.data(), &decrypted_len,
	decrypted.size(), task.ciphertext.data(),
	task.ciphertext.size(), task.aad.data(),
	task.aad.size()));

	ASSERT_EQ(Bytes(decrypted.data(), decrypted_len), Bytes(task.plaintext));
	}
	VerifyExports(ctx);
	}

	void VerifyExports(EVP_HPKE_CTX *ctx) const {
	for (const Export &task : exports_) {
	std::vector<uint8_t> exported_secret(task.export_length);

	ASSERT_TRUE(EVP_HPKE_CTX_export(
	ctx, exported_secret.data(), exported_secret.size(),
	task.exporter_context.data(), task.exporter_context.size()));
	ASSERT_EQ(Bytes(exported_secret), Bytes(task.exported_value));
	}
	}

	enum class Mode {
	kBase = 0,
	kAuth = 2,
	};

	struct Encryption {
	std::vector<uint8_t> aad;
	std::vector<uint8_t> ciphertext;
	std::vector<uint8_t> plaintext;
	};

	struct Export {
	std::vector<uint8_t> exporter_context;
	size_t export_length;
	std::vector<uint8_t> exported_value;
	};

	Mode mode_;
	uint16_t kem_id_;
	uint16_t kdf_id_;
	uint16_t aead_id_;
	std::vector<uint8_t> context_;
	std::vector<uint8_t> info_;
	std::vector<uint8_t> public_key_e_;
	std::vector<uint8_t> secret_key_e_;
	std::vector<uint8_t> ikm_e_;
	std::vector<uint8_t> public_key_r_;
	std::vector<uint8_t> secret_key_r_;
	std::vector<uint8_t> ikm_r_;
	std::vector<uint8_t> public_key_s_;
	std::vector<uint8_t> secret_key_s_;
	std::vector<Encryption> encryptions_;
	std::vector<Export> exports_;
	};

	// Match FileTest's naming scheme for duplicated attribute names.
	std::string BuildAttrName(const std::string &name, int iter) {
	return iter == 1 ? name : name + "/" + std::to_string(iter);
	}

	// Parses \|s\| as an unsigned integer of type T and writes the value to \|out\|.
	// Returns true on success. If the integer value exceeds the maximum T value,
	// returns false.
	template <typename T>
	bool ParseIntSafe(T *out, const std::string &s) {
	T value = 0;
	for (char c : s) {
	if (c < '0' \|\| c > '9') {
	return false;
	}
	if (value > (std::numeric_limits<T>::max() - (c - '0')) / 10) {
	return false;
	}
	value = 10 * value + (c - '0');
	}
	*out = value;
	return true;
	}

	// Read the \|key\| attribute from \|file_test\| and convert it to an integer.
	template <typename T>
	bool FileTestReadInt(FileTest file_test, T out, const std::string &key) {
	std::string s;
	return file_test->GetAttribute(&s, key) && ParseIntSafe(out, s);
	}


	bool HPKETestVector::ReadFromFileTest(FileTest *t) {
	uint8_t mode = 0;
	if (!FileTestReadInt(t, &mode, "mode") \|\|
	!FileTestReadInt(t, &kem_id_, "kem_id") \|\|
	!FileTestReadInt(t, &kdf_id_, "kdf_id") \|\|
	!FileTestReadInt(t, &aead_id_, "aead_id") \|\|
	!t->GetBytes(&info_, "info") \|\| //
	!t->GetBytes(&secret_key_r_, "skRm") \|\|
	!t->GetBytes(&public_key_r_, "pkRm") \|\|
	!t->GetBytes(&ikm_r_, "ikmR") \|\| //
	!t->GetBytes(&secret_key_e_, "skEm") \|\|
	!t->GetBytes(&public_key_e_, "pkEm") \|\| //
	!t->GetBytes(&ikm_e_, "ikmE")) {
	return false;
	}

	switch (mode) {
	case static_cast<int>(Mode::kBase):
	mode_ = Mode::kBase;
	break;
	case static_cast<int>(Mode::kAuth):
	mode_ = Mode::kAuth;
	if (!t->GetBytes(&secret_key_s_, "skSm") \|\|
	!t->GetBytes(&public_key_s_, "pkSm")) {
	return false;
	}
	break;
	default:
	return false;
	}

	for (int i = 1; t->HasAttribute(BuildAttrName("aad", i)); i++) {
	Encryption encryption;
	if (!t->GetBytes(&encryption.aad, BuildAttrName("aad", i)) \|\|
	!t->GetBytes(&encryption.ciphertext, BuildAttrName("ct", i)) \|\|
	!t->GetBytes(&encryption.plaintext, BuildAttrName("pt", i))) {
	return false;
	}
	encryptions_.push_back(std::move(encryption));
	}

	for (int i = 1; t->HasAttribute(BuildAttrName("exporter_context", i)); i++) {
	Export exp;
	if (!t->GetBytes(&exp.exporter_context,
	BuildAttrName("exporter_context", i)) \|\|
	!FileTestReadInt(t, &exp.export_length, BuildAttrName("L", i)) \|\|
	!t->GetBytes(&exp.exported_value, BuildAttrName("exported_value", i))) {
	return false;
	}
	exports_.push_back(std::move(exp));
	}
	return true;
	}

	} // namespace

	TEST(HPKETest, VerifyTestVectors) {
	FileTestGTest("crypto/hpke/hpke_test_vectors.txt", [](FileTest *t) {
	HPKETestVector test_vec;
	EXPECT_TRUE(test_vec.ReadFromFileTest(t));
	test_vec.Verify();
	});
	}

	// The test vectors used fixed sender ephemeral keys, while HPKE itself
	// generates new keys for each context. Test this codepath by checking we can
	// decrypt our own messages.
	TEST(HPKETest, RoundTrip) {
	const uint8_t info_a[] = {1, 1, 2, 3, 5, 8};
	const uint8_t info_b[] = {42, 42, 42};
	const uint8_t ad_a[] = {1, 2, 4, 8, 16};
	const uint8_t ad_b[] = {7};
	Span<const uint8_t> info_values[] = {{nullptr, 0}, info_a, info_b};
	Span<const uint8_t> ad_values[] = {{nullptr, 0}, ad_a, ad_b};

	for (const auto kem : kAllKEMs) {
	SCOPED_TRACE(EVP_HPKE_KEM_id(kem()));

	// Generate the recipient's keypair.
	ScopedEVP_HPKE_KEY key;
	ASSERT_TRUE(EVP_HPKE_KEY_generate(key.get(), kem()));
	uint8_t public_key_r[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
	size_t public_key_r_len;
	ASSERT_TRUE(EVP_HPKE_KEY_public_key(
	key.get(), public_key_r, &public_key_r_len, sizeof(public_key_r)));

	// Generate the sender's keypair, for auth modes.
	ScopedEVP_HPKE_KEY sender_key;
	ASSERT_TRUE(EVP_HPKE_KEY_generate(sender_key.get(), kem()));
	uint8_t public_key_s[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
	size_t public_key_s_len;
	ASSERT_TRUE(EVP_HPKE_KEY_public_key(sender_key.get(), public_key_s,
	&public_key_s_len,
	sizeof(public_key_s)));

	for (const auto kdf : kAllKDFs) {
	SCOPED_TRACE(EVP_HPKE_KDF_id(kdf()));
	for (const auto aead : kAllAEADs) {
	SCOPED_TRACE(EVP_HPKE_AEAD_id(aead()));
	for (const Span<const uint8_t> &info : info_values) {
	SCOPED_TRACE(Bytes(info));
	for (const Span<const uint8_t> &ad : ad_values) {
	SCOPED_TRACE(Bytes(ad));

	auto check_messages = [&](EVP_HPKE_CTX *sender_ctx,
	EVP_HPKE_CTX *recipient_ctx) {
	const char kCleartextPayload[] = "foobar";

	// Have sender encrypt message for the recipient.
	std::vector<uint8_t> ciphertext(
	sizeof(kCleartextPayload) +
	EVP_HPKE_CTX_max_overhead(sender_ctx));
	size_t ciphertext_len;
	ASSERT_TRUE(EVP_HPKE_CTX_seal(
	sender_ctx, ciphertext.data(), &ciphertext_len,
	ciphertext.size(),
	reinterpret_cast<const uint8_t *>(kCleartextPayload),
	sizeof(kCleartextPayload), ad.data(), ad.size()));

	// Have recipient decrypt the message.
	std::vector<uint8_t> cleartext(ciphertext.size());
	size_t cleartext_len;
	ASSERT_TRUE(EVP_HPKE_CTX_open(recipient_ctx, cleartext.data(),
	&cleartext_len, cleartext.size(),
	ciphertext.data(), ciphertext_len,
	ad.data(), ad.size()));

	// Verify that decrypted message matches the original.
	ASSERT_EQ(Bytes(cleartext.data(), cleartext_len),
	Bytes(kCleartextPayload, sizeof(kCleartextPayload)));
	};

	// Test the base mode.
	{
	ScopedEVP_HPKE_CTX sender_ctx;
	uint8_t enc[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
	size_t enc_len;
	ASSERT_TRUE(EVP_HPKE_CTX_setup_sender(
	sender_ctx.get(), enc, &enc_len, sizeof(enc), kem(), kdf(),
	aead(), public_key_r, public_key_r_len, info.data(),
	info.size()));

	ScopedEVP_HPKE_CTX recipient_ctx;
	ASSERT_TRUE(EVP_HPKE_CTX_setup_recipient(
	recipient_ctx.get(), key.get(), kdf(), aead(), enc, enc_len,
	info.data(), info.size()));

	check_messages(sender_ctx.get(), recipient_ctx.get());
	}

	// Test the auth mode.
	{
	ScopedEVP_HPKE_CTX sender_ctx;
	uint8_t enc[EVP_HPKE_MAX_PUBLIC_KEY_LENGTH];
	size_t enc_len;
	ASSERT_TRUE(EVP_HPKE_CTX_setup_auth_sender(
	sender_ctx.get(), enc, &enc_len, sizeof(enc),
	sender_key.get(), kdf(), aead(), public_key_r,
	public_key_r_len, info.data(), info.size()));

	ScopedEVP_HPKE_CTX recipient_ctx;
	ASSERT_TRUE(EVP_HPKE_CTX_setup_auth_recipient(
	recipient_ctx.get(), key.get(), kdf(), aead(), enc, enc_len,
	info.data(), info.size(), public_key_s, public_key_s_len));

	check_messages(sender_ctx.get(), recipient_ctx.get());
	}
	}
	}
	}
	}
	}
	}

	// Verify that the DH operations inside Encap() and Decap() both fail when the
	// public key is on a small-order point in the curve.
	TEST(HPKETest, X25519EncapSmallOrderPoint) {
	// Borrowed from X25519Test.SmallOrder.
	static const uint8_t kSmallOrderPoint[32] = {
	0xe0, 0xeb, 0x7a, 0x7c, 0x3b, 0x41, 0xb8, 0xae, 0x16, 0x56, 0xe3,
	0xfa, 0xf1, 0x9f, 0xc4, 0x6a, 0xda, 0x09, 0x8d, 0xeb, 0x9c, 0x32,
	0xb1, 0xfd, 0x86, 0x62, 0x05, 0x16, 0x5f, 0x49, 0xb8,
	};
	static const uint8_t kValidPoint[32] = {
	0xe6, 0xdb, 0x68, 0x67, 0x58, 0x30, 0x30, 0xdb, 0x35, 0x94, 0xc1,
	0xa4, 0x24, 0xb1, 0x5f, 0x7c, 0x72, 0x66, 0x24, 0xec, 0x26, 0xb3,
	0x35, 0x3b, 0x10, 0xa9, 0x03, 0xa6, 0xd0, 0xab, 0x1c, 0x4c,
	};

	ScopedEVP_HPKE_KEY key;
	ASSERT_TRUE(EVP_HPKE_KEY_generate(key.get(), EVP_hpke_x25519_hkdf_sha256()));

	for (const auto kdf : kAllKDFs) {
	SCOPED_TRACE(EVP_HPKE_KDF_id(kdf()));
	for (const auto aead : kAllAEADs) {
	SCOPED_TRACE(EVP_HPKE_AEAD_id(aead()));
	// Set up the sender, passing in kSmallOrderPoint as \|peer_public_key\|.
	ScopedEVP_HPKE_CTX sender_ctx;
	uint8_t enc[X25519_PUBLIC_VALUE_LEN];
	size_t enc_len;
	EXPECT_FALSE(EVP_HPKE_CTX_setup_sender(
	sender_ctx.get(), enc, &enc_len, sizeof(enc),
	EVP_hpke_x25519_hkdf_sha256(), kdf(), aead(), kSmallOrderPoint,
	sizeof(kSmallOrderPoint), nullptr, 0));

	// Likewise with auth.
	EXPECT_FALSE(EVP_HPKE_CTX_setup_auth_sender(
	sender_ctx.get(), enc, &enc_len, sizeof(enc), key.get(), kdf(),
	aead(), kSmallOrderPoint, sizeof(kSmallOrderPoint), nullptr, 0));

	// Set up the recipient, passing in kSmallOrderPoint as \|enc\|.
	ScopedEVP_HPKE_CTX recipient_ctx;
	EXPECT_FALSE(EVP_HPKE_CTX_setup_recipient(
	recipient_ctx.get(), key.get(), kdf(), aead(), kSmallOrderPoint,
	sizeof(kSmallOrderPoint), nullptr, 0));

	// Likewise with auth. With auth, a small-order point could appear as
	// either \|enc\| or the peer public key.
	EXPECT_FALSE(EVP_HPKE_CTX_setup_auth_recipient(
	recipient_ctx.get(), key.get(), kdf(), aead(), kSmallOrderPoint,
	sizeof(kSmallOrderPoint), nullptr, 0, kValidPoint,
	sizeof(kValidPoint)));
	EXPECT_FALSE(EVP_HPKE_CTX_setup_auth_recipient(
	recipient_ctx.get(), key.get(), kdf(), aead(), kValidPoint,
	sizeof(kValidPoint), nullptr, 0, kSmallOrderPoint,
	sizeof(kSmallOrderPoint)));
	}
	}
	}

	// Test that Seal() fails when the context has been initialized as a recipient.
	TEST(HPKETest, RecipientInvalidSeal) {
	const uint8_t kMockEnc[X25519_PUBLIC_VALUE_LEN] = {0xff};
	const char kCleartextPayload[] = "foobar";

	ScopedEVP_HPKE_KEY key;
	ASSERT_TRUE(EVP_HPKE_KEY_generate(key.get(), EVP_hpke_x25519_hkdf_sha256()));

	// Set up the recipient.
	ScopedEVP_HPKE_CTX recipient_ctx;
	ASSERT_TRUE(EVP_HPKE_CTX_setup_recipient(
	recipient_ctx.get(), key.get(), EVP_hpke_hkdf_sha256(),
	EVP_hpke_aes_128_gcm(), kMockEnc, sizeof(kMockEnc), nullptr, 0));

	// Call Seal() on the recipient.
	size_t ciphertext_len;
	uint8_t ciphertext[100];
	ASSERT_FALSE(EVP_HPKE_CTX_seal(
	recipient_ctx.get(), ciphertext, &ciphertext_len, sizeof(ciphertext),
	reinterpret_cast<const uint8_t *>(kCleartextPayload),
	sizeof(kCleartextPayload), nullptr, 0));
	}

	// Test that Open() fails when the context has been initialized as a sender.
	TEST(HPKETest, SenderInvalidOpen) {
	const uint8_t kMockCiphertext[100] = {0xff};
	const size_t kMockCiphertextLen = 80;

	// Generate the recipient's keypair.
	uint8_t secret_key_r[X25519_PRIVATE_KEY_LEN];
	uint8_t public_key_r[X25519_PUBLIC_VALUE_LEN];
	X25519_keypair(public_key_r, secret_key_r);

	// Set up the sender.
	ScopedEVP_HPKE_CTX sender_ctx;
	uint8_t enc[X25519_PUBLIC_VALUE_LEN];
	size_t enc_len;
	ASSERT_TRUE(EVP_HPKE_CTX_setup_sender(
	sender_ctx.get(), enc, &enc_len, sizeof(enc),
	EVP_hpke_x25519_hkdf_sha256(), EVP_hpke_hkdf_sha256(),
	EVP_hpke_aes_128_gcm(), public_key_r, sizeof(public_key_r), nullptr, 0));

	// Call Open() on the sender.
	uint8_t cleartext[128];
	size_t cleartext_len;
	ASSERT_FALSE(EVP_HPKE_CTX_open(sender_ctx.get(), cleartext, &cleartext_len,
	sizeof(cleartext), kMockCiphertext,
	kMockCiphertextLen, nullptr, 0));
	}

	TEST(HPKETest, SetupSenderBufferTooSmall) {
	uint8_t secret_key_r[X25519_PRIVATE_KEY_LEN];
	uint8_t public_key_r[X25519_PUBLIC_VALUE_LEN];
	X25519_keypair(public_key_r, secret_key_r);

	ScopedEVP_HPKE_CTX sender_ctx;
	uint8_t enc[X25519_PUBLIC_VALUE_LEN - 1];
	size_t enc_len;
	ASSERT_FALSE(EVP_HPKE_CTX_setup_sender(
	sender_ctx.get(), enc, &enc_len, sizeof(enc),
	EVP_hpke_x25519_hkdf_sha256(), EVP_hpke_hkdf_sha256(),
	EVP_hpke_aes_128_gcm(), public_key_r, sizeof(public_key_r), nullptr, 0));
	EXPECT_TRUE(
	ErrorEquals(ERR_get_error(), ERR_LIB_EVP, EVP_R_INVALID_BUFFER_SIZE));
	ERR_clear_error();
	}

	TEST(HPKETest, SetupSenderBufferTooLarge) {
	uint8_t secret_key_r[X25519_PRIVATE_KEY_LEN];
	uint8_t public_key_r[X25519_PUBLIC_VALUE_LEN];
	X25519_keypair(public_key_r, secret_key_r);

	// Too large of an output buffer is fine because the function reports the
	// actual length.
	ScopedEVP_HPKE_CTX sender_ctx;
	uint8_t enc[X25519_PUBLIC_VALUE_LEN + 1];
	size_t enc_len;
	EXPECT_TRUE(EVP_HPKE_CTX_setup_sender(
	sender_ctx.get(), enc, &enc_len, sizeof(enc),
	EVP_hpke_x25519_hkdf_sha256(), EVP_hpke_hkdf_sha256(),
	EVP_hpke_aes_128_gcm(), public_key_r, sizeof(public_key_r), nullptr, 0));
	EXPECT_EQ(size_t{X25519_PUBLIC_VALUE_LEN}, enc_len);
	}

	TEST(HPKETest, SetupRecipientWrongLengthEnc) {
	ScopedEVP_HPKE_KEY key;
	ASSERT_TRUE(EVP_HPKE_KEY_generate(key.get(), EVP_hpke_x25519_hkdf_sha256()));

	const uint8_t bogus_enc[X25519_PUBLIC_VALUE_LEN + 5] = {0xff};

	ScopedEVP_HPKE_CTX recipient_ctx;
	ASSERT_FALSE(EVP_HPKE_CTX_setup_recipient(
	recipient_ctx.get(), key.get(), EVP_hpke_hkdf_sha256(),
	EVP_hpke_aes_128_gcm(), bogus_enc, sizeof(bogus_enc), nullptr, 0));
	EXPECT_TRUE(
	ErrorEquals(ERR_get_error(), ERR_LIB_EVP, EVP_R_INVALID_PEER_KEY));
	ERR_clear_error();
	}

	TEST(HPKETest, SetupSenderWrongLengthPeerPublicValue) {
	const uint8_t bogus_public_key_r[X25519_PRIVATE_KEY_LEN + 5] = {0xff};
	ScopedEVP_HPKE_CTX sender_ctx;
	uint8_t enc[X25519_PUBLIC_VALUE_LEN];
	size_t enc_len;
	ASSERT_FALSE(EVP_HPKE_CTX_setup_sender(
	sender_ctx.get(), enc, &enc_len, sizeof(enc),
	EVP_hpke_x25519_hkdf_sha256(), EVP_hpke_hkdf_sha256(),
	EVP_hpke_aes_128_gcm(), bogus_public_key_r, sizeof(bogus_public_key_r),
	nullptr, 0));
	EXPECT_TRUE(
	ErrorEquals(ERR_get_error(), ERR_LIB_EVP, EVP_R_INVALID_PEER_KEY));
	ERR_clear_error();
	}

	TEST(HPKETest, InvalidRecipientKey) {
	const uint8_t private_key[X25519_PUBLIC_VALUE_LEN + 5] = {0xff};
	ScopedEVP_HPKE_KEY key;
	EXPECT_FALSE(EVP_HPKE_KEY_init(key.get(), EVP_hpke_x25519_hkdf_sha256(),
	private_key, sizeof(private_key)));
	}

	TEST(HPKETest, InvalidP256PrivateKey) {
	const uint8_t zero_key[32] = {0};
	ScopedEVP_HPKE_KEY key;
	EXPECT_FALSE(EVP_HPKE_KEY_init(key.get(), EVP_hpke_p256_hkdf_sha256(),
	zero_key, sizeof(zero_key)));

	uint8_t all_ones_key[32];
	OPENSSL_memset(all_ones_key, 0xff, sizeof(all_ones_key));
	EXPECT_FALSE(EVP_HPKE_KEY_init(key.get(), EVP_hpke_p256_hkdf_sha256(),
	all_ones_key, sizeof(all_ones_key)));
	}

	TEST(HPKETest, InternalParseIntSafe) {
	uint8_t u8 = 0xff;
	ASSERT_FALSE(ParseIntSafe(&u8, "-1"));

	ASSERT_TRUE(ParseIntSafe(&u8, "0"));
	ASSERT_EQ(u8, 0);

	ASSERT_TRUE(ParseIntSafe(&u8, "255"));
	ASSERT_EQ(u8, 255);

	ASSERT_FALSE(ParseIntSafe(&u8, "256"));

	uint16_t u16 = 0xffff;
	ASSERT_TRUE(ParseIntSafe(&u16, "257"));
	ASSERT_EQ(u16, 257);

	ASSERT_TRUE(ParseIntSafe(&u16, "65535"));
	ASSERT_EQ(u16, 65535);

	ASSERT_FALSE(ParseIntSafe(&u16, "65536"));
	}

	BSSL_NAMESPACE_END