ce_cdm/cdm/test/cdm_api_4_test.cpp

// Copyright 2013 Google Inc. All Rights Reserved.
//
// This source file provides a basic set of unit tests for the Content
// Decryption Module (CDM).  It exercises much of the API that will be
// required by the host application to get the license and keys for
// rendering protected content.

#include "cdm_test_config.h"
#include "test_host_4.h"
#include "test_util.h"

#include <getopt.h>

#include <gtest/gtest.h>

#include "cdm_client_property_set.h"
#include "clock.h"
#include "config_test_env.h"
#include "content_decryption_module.h"
#include "device_cert.h"
#include "license_request.h"
#include "log.h"
#include "properties.h"
#include "scoped_ptr.h"
#include "string_conversions.h"
#include "url_request.h"
#include "wv_content_decryption_module_4.h"

static const int kTestPolicyRenewalDelaySeconds = 180;
static const int kDelayWaitToForRenewalMessageSeconds = 2;
static const int kHttpOk = 200;
static const int kSessionId1 = 1;
static const int kSessionId2 = 2;
static const int kSessionId3 = 3;

namespace {

// Default key system identifier.
const char kKeySystemWidevine[] = "com.widevine.alpha";

// Default mime type for session creation.
const char kMimeType[] = "video/mp4";

// Known filename for certificate manipulation.
const std::string kCertFilename = "cert.bin";

// Key ID of key used to encrypt the test content.
// This is used to look up the content key.
const std::vector<uint8_t> kTestKeyId =
    wvcdm::a2b_hex("371ea35e1a985d75d198a7f41020dc23");

// Dummy encrypted data.
const std::vector<uint8_t> kInputVector1 = wvcdm::a2b_hex(
    "64ab17b3e3dfab47245c7cce4543d4fc7a26dcf248f19f9b59f3c92601440b36"
    "17c8ed0c96c656549e461f38708cd47a434066f8df28ccc28b79252eee3f9c2d"
    "7f6c68ebe40141fe818fe082ca523c03d69ddaf183a93c022327fedc5582c5ab"
    "ca9d342b71263a67f9cb2336f12108aaaef464f17177e44e9b0c4e56e61da53c"
    "2150b4405cc82d994dfd9bf4087c761956d6688a9705db4cf350381085f383c4"
    "9666d4aed135c519c1f0b5cba06e287feea96ea367bf54e7368dcf998276c6e4"
    "6497e0c50e20fef74e42cb518fe7f22ef27202428688f86404e8278587017012"
    "c1d65537c6cbd7dde04aae338d68115a9f430afc100ab83cdadf45dca39db685");
const std::vector<uint8_t> kIv1 =
    wvcdm::a2b_hex("f6f4b1e600a5b67813ed2bded913ba9f");

// Expected output for kInputVector1.
const std::vector<uint8_t> kOutputVector1 = wvcdm::a2b_hex(
    "217ce9bde99bd91e9733a1a00b9b557ac3a433dc92633546156817fae26b6e1c"
    "942ac20a89ff79f4c2f25fba99d6a44618a8c0420b27d54e3da17b77c9d43cca"
    "595d259a1e4a8b6d7744cd98c5d3f921adc252eb7d8af6b916044b676a574747"
    "8df21fdc42f166880d97a2225cd5c9ea5e7b752f4cf81bbdbe98e542ee10e1c6"
    "ad868a6ac55c10d564fc23b8acff407daaf4ed2743520e02cda9680d9ea88e91"
    "029359c4cf5906b6ab5bf60fbb3f1a1c7c59acfc7e4fb4ad8e623c04d503a3dd"
    "4884604c8da8a53ce33db9ff8f1c5bb6bb97f37b39906bf41596555c1bcce9ed"
    "08a899cd760ff0899a1170c2f224b9c52997a0785b7fe170805fd3e8b1127659");

// Dummy encrypted data.  This is a combination of clear and encrypted data.
const std::vector<uint8_t> kInputVector2 = wvcdm::a2b_hex(
    // subsample 0
    "abcdef"
    "53cc758763904ea5870458e6b23d36db1e6d7f7aaa2f3eeebb5393a7264991e7"
    "ce4f57b198326e1a208a821799b2a29c90567ab57321b06e51fc20dc9bc5fc55"
    "10720a8bb1f5e002c3e50ff70d2d806a9432cad237050d09581f5b0d59b00090"
    "b3ad69b4087f5a155b17e13c44d33fa007475d207fc4ac2ef3b571ecb9"
    // subsample 1
    "0123456789"
    "f3c852"
    "ce00dc4806f0c6856ae1732e20308096478e1d822d75c2bb768119565d3bd6e6"
    "901e36164f4802355ee758fc46ef6cf5f852dd5256c7b1e5f96d29"
    // subsample 2
    "deadbeefbaadf00d"
    "3b20525d5e"
    "78b8e5aa344d5c4e425e67ddf889ea7c4bb1d49af67eba67718b765e0a940402"
    "8d306f4ce693ad6dc0a931d507fa14fff4d293d4170280b3e0fca2d628f722e8"
);
const std::vector<uint8_t> kIv2 =
    wvcdm::a2b_hex("6ba18dd40f49da7f64c368e4db43fc88");

// Expected output for kInputVector2.
const std::vector<uint8_t> kOutputVector2 = wvcdm::a2b_hex(
    // subsample 0
    "abcdef"
    "52e65334501acadf78e2b26460def3ac973771ed7c64001a2e82917342a7eab3"
    "047f5e85449692fae8f677be425a47bdea850df5a3ffff17043afb1f2b437ab2"
    "b1d5e0784c4ed8f97fc24b8f565e85ed63fb7d1365980d9aea7b8b58f488f83c"
    "1ce80b6096c60f3b113c988ff185b26e798da8fc6f327e4ff00e4b3fbf"
    // subsample 1
    "0123456789"
    "b1ed0a"
    "a054bce40ccb0ebc70b181d1a12055f46ac55e29c7c2473a29d2a366d240ec48"
    "7cede274f012813a877f99159e7062b6a37cfc9327a7bc2195814e"
    // subsample 2
    "deadbeefbaadf00d"
    "653b818d1d"
    "4ab9a9128361d8ca6a9d2766df5c096ee29f4f5204febdf217a94a5b560cd692"
    "cc36d3e071df789fdeac2fb7ec6dcd7af94bb1f85c22025b25e702e38212b927"
);

// Dummy encrypted data.  This will be decrypted with a data_offset
// instead of subsamples.
const std::vector<uint8_t> kInputVector3 = wvcdm::a2b_hex(
    "64ab17b3e3dfab47245c7cce4543d4fc7a26dcf248f19f9b59f3c92601440b36"
    "17c8ed0c96c656549e461f38708cd47a434066f8df28ccc28b79252eee3f9c2d"
    "7f6c68ebe40141fe818fe082ca523c03d69ddaf183a93c022327fedc5582c5ab"
    "ca9d342b71263a67f9cb2336f12108aaaef464f17177e44e9b0c4e56e61da53c"
    "2150b4405cc82d994dfd9bf4087c761956d6688a9705db4cf350381085f383c4"
    "9666d4aed135c519c1f0b5cba06e287feea96ea367bf54e7368dcf998276c6e4"
    "6497e0c50e20fef74e42cb518fe7f22ef27202428688f86404e8278587017012"
    "c1d65537c6cbd7dde04aae338d68115a9f430afc100ab83cdadf45dca39db685");
const std::vector<uint8_t> kIv3 =
    wvcdm::a2b_hex("f6f4b1e600a5b67813ed2bded913ba9f");

// The data_offset for kInputVector3.
const uint32_t kInputOffset3 = 9;

// Expected output for kInputVector3 offset by kInputOffset3.
const std::vector<uint8_t> kOutputVector3 = wvcdm::a2b_hex(
    "19ab304b49908e2395b32f26bf471adf4a4bc92f9e999cca8476d24a257931b4"
    "c5fd177693ed55e31cd2b85dc196b2b722cd8854eb9334f3dab0b5bd26aa5e66"
    "a9d1cfbba877c9456b11dc99a6bdc7015ca1544f7ce66171a8179eca19efe515"
    "8c4c1d0612dff64100387065da108fdbfcc14738202ac3d27520eb48c020ddb7"
    "714dca22e5e2241aff6932dba1587a97ac1a952827d411d8582dfecc2e9e1494"
    "644046ca7044bc41c3c5e0a3a405d5551f3f5bdd6f36042e2f0f3693778b9277"
    "6ed8d106647a7539df7d30288803cd9ca1c274bebe688151c72b451f571a441f"
    "83d0ff77d8d57dcb395122e175f4944569917627d6c3dc");

// Dummy data used as a server certificate. Not a real cert.
const std::vector<uint8_t> kFakeServerCertficiate = wvcdm::a2b_hex(
    "65393939a0e4a28fb07aa8237bdc9e2fd30fdf763061ed9ed91b368a2b78fc2d"
    "15f0b6add5d56d05f7e5852aeae67de6127d6b61b39bb5d6e9657f352ba75e72"
    "c436f334878568504f697ad01aa329efbadebc3b9aaf502ada9b8e6fcf066252"
    "76690a0f50cd3852dd39f7c5444402f86831d8bb2cbbd7cba11ab1caa35445fe"
    "35a332529845f2f4b5d5a0b1e2c0855fc2d644443eb967e1f9030fd0d9e6375b"
    "a5100a997ff8a958606d59a00151d251eaf69f9e00465b5aa4c23ef33a11b05b"
    "212c1ff830fcd095c681ef25a18db08d7bddfeee16763e9fec06daa8275de2b0"
    "554a0bec821fb7bb6fbda081d8cecce6c51195e6b6a1c0fcbb2470bcff2a962e"
    "57e767f83cc8b6c31d41d7c59526128f19cbf625fa4f5f382393a3bd2b76463a"
    "fe97e4a6f30f631c83308aa5fdccc2d1765c113d474bf2496e03c030c18e5ca8"
    "84cb98fa120804baa245682966926ccbf555450437de10e549afc088f8c36f63"
    "8a943178bdd58e4ef1f7d501e2296bbe2df57ce8816d6ae9e7ab18b1e01dac9b"
    "8c312298356cad58c6ed46b1cd3a895e496c66f5229da39e260a7c1f782653bd"
    "ade5f6132fc4771bb8caca80eb063abb47144abc44aaba8d23fcc721199291b3"
    "0b95bc7d310c3f90756916552151a6008feba73ddab87454822914732d6ee78a"
    "3587f33c698b0ab90f01b38a71abd01660a5ef1473e4556aa8c17d34679065c5"
    "689dd21026601e94146254346f4ccd979bc378046473b3de64b8654e18406e94"
    "b673dc13fdcc70213365bd098f212ed7a973ef35da18e16b1c118f8d4eda0b39"
    "ffb8084ca93a44923df8475e3feec6c0941a2a37d5df514e686dd182dc9ebbff"
    "41d8d80aa39d059de3b7849d4e5946b09937c6e7a6f6392ea5e9370ba1867553"
    "b716e31433c2e3ca3eff1e7c08a31b201fd18c363b8daeed59df7afb68ad5166"
    "659914a2e137c9d2e5940aaa921694c8d84d5ea1c83486e473e3021cb825c0ed"
    "f778c621598d35e44843cd53e32f90925e74bc8eb469889fb221a2c592b43d94"
    "2079d6393ab76e47d30dbf837fa5ca07d7186710973c5bb17c04b3207a85a166"
    "153053f6b0ec35c6b124efd43be274cdf8300234806a72231272d13b331cafd3"
    "dab01002b5e1961a5f3221d4c589fac3e42c1d1de9f244090e31a08999d3434d"
    "15a5159f09fa3307e0d9466ac40af63c0a62f8d2719e1df80bb24d4d7ab256f7"
    "0906ee342a47a9bd6805d796cf928f0d5251701ba8e6888675b1b6fd03e77df0"
    "8150495c778cb7942d8c060ace4b080ad22e44854988d5e2232f5dbcf2db559f"
    "24bae8667c33cea77f1c6a58d9dd010363c233cff6d5d26f5f77230ee681456c"
    "35a8f90d37c2fc0ab07a2a795431f829cca574fd37d8822e04fc500ba468f08a"
    "556e53ba8992dd1ccbd44559a7b93bebc27cec81a834755cf110bce183481e42");

void* GetCdmHost(int host_interface_version, void* user_data) {
  if (host_interface_version != cdm::Host_4::kVersion) return NULL;
  return user_data;
}

}  // namespace

namespace wvcdm {

class CdmApi4Test : public testing::Test {
 public:
  CdmApi4Test() : cdm_(NULL) {}
  ~CdmApi4Test() {}

 protected:
  virtual void SetUp() {
    // Create the Host.
    host_.reset(new TestHost_4());

    // Load the device cert that was already "saved" to the device.
    std::string cert(reinterpret_cast<const char*>(kDeviceCert),
                     sizeof(kDeviceCert));
    host_->file_store[kCertFilename] = cert;

    // Initialize the CDM module before creating a CDM instance.
    InitializeCdmModule();

    // Create the CDM.
    cdm_ =
        reinterpret_cast<cdm::ContentDecryptionModule_4*>(::CreateCdmInstance(
            cdm::ContentDecryptionModule_4::kVersion, kKeySystemWidevine,
            strlen(kKeySystemWidevine), GetCdmHost, host_.get()));

    if (cdm_ == NULL) {
      FAIL() << "Fatal CDM creation error!";
    }

    // Tell the Host about the CDM.
    host_->SetCdmPtr(cdm_);
  }

  void CreateSession(const uint32_t session_id, const std::string& init_data,
                     cdm::SessionType session_type) {
    cdm_->CreateSession(session_id, kMimeType, strlen(kMimeType),
                        reinterpret_cast<const uint8_t*>(init_data.data()),
                        init_data.length(), session_type);
  }

  void CreateSessionWithMimeType(const uint32_t session_id,
                                 const std::string& mime_type) {
    cdm_->CreateSession(session_id, mime_type.c_str(), mime_type.length(),
                        reinterpret_cast<const uint8_t*>(g_key_id.data()),
                        g_key_id.length(), cdm::kTemporary);
  }

  void LoadSession(uint32_t session_id, const std::string& web_session_id) {
    cdm_->LoadSession(session_id, web_session_id.data(),
                      web_session_id.length());
  }

  // posts a request and extracts the drm message from the response
  std::string GetKeyRequestResponse(
      const TestHost_4::SessionMessage& session_msg,
      const std::string& default_url, bool is_provision) {
    std::string url;
    if (session_msg.default_url.empty()) {
      url = default_url;
    } else {
      // Note that the client auth string is assumed to already be appended when
      // the CDM tells us what URL to use.
      url = session_msg.default_url;
    }

    UrlRequest url_request(url);
    EXPECT_TRUE(url_request.is_connected());
    if (!url_request.is_connected()) {
      return "";
    }

    if (!is_provision) {
      url_request.PostRequest(session_msg.message);
    } else {
      url_request.PostCertRequestInQueryString(session_msg.message);
    }
    std::string response;
    int resp_bytes = url_request.GetResponse(&response);

    // Some license servers return 400 for invalid message, some
    // return 500; treat anything other than 200 as an invalid message.
    int status_code = url_request.GetStatusCode(response);
    EXPECT_EQ(kHttpOk, status_code);

    if (status_code != kHttpOk) {
      return "";
    } else {
      std::string drm_msg;
      LicenseRequest lic_request;
      lic_request.GetDrmMessage(response, drm_msg);
      LOGV("drm msg: %u bytes\n%s", drm_msg.size(),
           HexEncode(reinterpret_cast<const uint8_t*>(drm_msg.data()),
                     drm_msg.size()).c_str());
      return drm_msg;
    }
  }

  void ProcessKeyResponse(bool expect_url_in_message) {
    ProcessKeyResponse(expect_url_in_message, g_license_server + g_client_auth);
  }

  void ProcessKeyResponse(bool expect_url_in_message,
                          const std::string& default_url) {
    ProcessServerResponse(expect_url_in_message, false, default_url);
  }

  void ProcessProvisionResponse() { ProcessServerResponse(true, true, ""); }

  void ProcessServerResponse(bool expect_url_in_message, bool is_provision,
                             const std::string& default_url) {
    TestHost_4::SessionMessage session_msg = host_->GetLastSessionMessage();
    ASSERT_FALSE(session_msg.message.empty());
    // Use EXPECT_bool instead of EXPECT_EQ to get better error printing.
    if (expect_url_in_message) {
      EXPECT_FALSE(session_msg.default_url.empty());
    } else {
      EXPECT_TRUE(session_msg.default_url.empty());
    }
    std::string drm_msg =
        GetKeyRequestResponse(session_msg, default_url, is_provision);
    UpdateSession(session_msg.session_id, (const uint8_t*)drm_msg.c_str(),
                  drm_msg.length());
  }

  void ReleaseSession(uint32_t session_id) { cdm_->ReleaseSession(session_id); }

  void RemoveSession(uint32_t session_id, const std::string& web_session_id) {
    cdm_->RemoveSession(session_id, web_session_id.data(),
                        web_session_id.length());
  }

  void UpdateSession(uint32_t session_id, const uint8_t* response,
                     uint32_t response_size) {
    cdm_->UpdateSession(session_id, response, response_size);
  }

  cdm::Status UsePrivacyMode() { return cdm_->UsePrivacyMode(); }

  cdm::Status SetServerCertificate(const std::vector<uint8_t>& cert) {
    return cdm_->SetServerCertificate(&cert[0], cert.size());
  }

  bool SessionErrorPresent(uint32_t session_id) {
    TestHost_4::SessionError serr = host_->GetLastSessionError();
    if (serr.session_id == session_id) {
      return true;
    }
    return false;
  }

  bool SessionErrorPresent(uint32_t session_id, cdm::Status error_code) {
    TestHost_4::SessionError serr = host_->GetLastSessionError();
    if (serr.session_id == session_id && serr.error_code == error_code) {
      return true;
    }
    return false;
  }

  cdm::InputBuffer BuildInputBuffer(const std::vector<uint8_t>& encrypted,
                                    const std::vector<uint8_t>& iv) {
    cdm::InputBuffer buf;
    buf.data = &encrypted[0];
    buf.data_size = encrypted.size();
    buf.key_id = &kTestKeyId[0];
    buf.key_id_size = kTestKeyId.size();
    buf.iv = &iv[0];
    buf.iv_size = iv.size();
    buf.data_offset = 0;
    buf.timestamp = 10;
    return buf;
  }

  cdm::InputBuffer BuildInputBuffer(
      const std::vector<uint8_t>& encrypted, const std::vector<uint8_t>& iv,
      const std::vector<cdm::SubsampleEntry>& sub) {
    cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv);
    buf.subsamples = &sub[0];
    buf.num_subsamples = sub.size();
    return buf;
  }

  cdm::InputBuffer BuildInputBuffer(const std::vector<uint8_t>& encrypted,
                                    const std::vector<uint8_t>& iv,
                                    const uint32_t data_offset) {
    cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv);
    buf.data_offset = data_offset;
    return buf;
  }

  std::vector<cdm::SubsampleEntry> BuildMultipleSubsamples() {
    std::vector<cdm::SubsampleEntry> sub;
    sub.push_back(cdm::SubsampleEntry(3, 125));
    sub.push_back(cdm::SubsampleEntry(5, 62));
    sub.push_back(cdm::SubsampleEntry(8, 69));
    return sub;
  }

  std::vector<cdm::SubsampleEntry> BuildSingleSubsample(size_t size) {
    std::vector<cdm::SubsampleEntry> sub;
    sub.push_back(cdm::SubsampleEntry(0, size));
    return sub;
  }

  void GetOfflineConfiguration(std::string* key_id, std::string* license_server,
                               std::string* client_auth) {
    // This method compares three different places settings could be found:
    //   1) A configuration object using the default settings.
    //   2) The global variables prefixed with g_.
    //   3) A configuration object configured for offline playback.
    // The desire is to use 3 unless the user customized the settings on the
    // command line, in which case we want to defer to them and use 2. The "if"
    // statements check if 1 and 2 are the same. If so, we know the user
    // did not customize the settings on the command line, and therefore we can
    // use 3. Otherwise, we use 2. This will never return the values from 1;
    // 1 is only used to check if 2 has been altered by the user.
    ConfigTestEnv std_config(kLicenseServerId);
    // TODO (juce): Switch this to kLicenseServerId once
    //              kContentProtectionServer is the default.
    ConfigTestEnv config(wvcdm::kContentProtectionServer, false);

    if (g_key_id.compare(a2bs_hex(std_config.key_id())) == 0)
      key_id->assign(wvcdm::a2bs_hex(config.key_id()));
    else
      key_id->assign(g_key_id);

    if (g_license_server.compare(std_config.license_server()) == 0)
      license_server->assign(config.license_server());
    else
      license_server->assign(g_license_server);

    if (g_client_auth.compare(std_config.client_auth()) == 0)
      client_auth->assign(config.client_auth());
    else
      client_auth->assign(g_client_auth);
  }

  cdm::ContentDecryptionModule_4* cdm_;  // owned by host_
  wvcdm::scoped_ptr<TestHost_4> host_;
};

namespace {

class DummyCDM : public cdm::ContentDecryptionModule_4 {
 public:
  DummyCDM() : timer_fired_(false), last_context_(NULL) {}

  virtual void CreateSession(uint32_t session_id,
                             const char* mime_type, uint32_t mime_type_size,
                             const uint8_t* init_data, uint32_t init_data_size,
                             cdm::SessionType session_type) OVERRIDE {}

  virtual void LoadSession(uint32_t session_id, const char* web_session_id,
                           uint32_t web_session_id_length) OVERRIDE {}

  virtual void UpdateSession(uint32_t session_id, const uint8_t* response,
                             uint32_t response_size) OVERRIDE {}

  virtual bool IsKeyValid(const uint8_t*, int) OVERRIDE { return false; }

  virtual void ReleaseSession(uint32_t session_id) OVERRIDE {}

  virtual void RemoveSession(uint32_t session_id, const char* web_session_id,
                             uint32_t web_session_id_length) {}

  virtual cdm::Status UsePrivacyMode() OVERRIDE { return cdm::kSuccess; }

  virtual cdm::Status SetServerCertificate(
      const uint8_t* server_certificate_data,
      uint32_t server_certificate_data_size) OVERRIDE {
    return cdm::kSuccess;
  }

  virtual void TimerExpired(void* context) OVERRIDE {
    timer_fired_ = true;
    last_context_ = context;
  }

  virtual cdm::Status Decrypt(const cdm::InputBuffer&,
                              cdm::DecryptedBlock*) OVERRIDE {
    return cdm::kSessionError;
  }

  virtual cdm::Status DecryptDecodeAndRender(
      const cdm::InputBuffer& encrypted_buffer,
      cdm::StreamType stream_type) OVERRIDE {
    return cdm::kDecryptError;
  }

  virtual void Destroy() OVERRIDE { delete this; }

  bool TimerFired() const { return timer_fired_; }

  void* LastTimerContext() const { return last_context_; }

  void ResetTimerStatus() {
    timer_fired_ = false;
    last_context_ = NULL;
  }

 private:
  bool timer_fired_;
  void* last_context_;
};

}  // namespace

TEST_F(CdmApi4Test, TestHostTimer) {
  // Validate that the TestHost timers are processed in the correct order.
  // To do this, we replace the cdm with a dummy that only tracks timers.
  DummyCDM* cdm = new DummyCDM();

  // The old CDM is destroyed by SetCdmPtr.
  cdm_ = cdm;
  host_->SetCdmPtr(cdm);

  const double kTimerDelaySeconds = 1.0;
  const int64_t kTimerDelayMs = kTimerDelaySeconds * 1000;
  void* kCtx1 = reinterpret_cast<void*>(0x1);
  void* kCtx2 = reinterpret_cast<void*>(0x2);

  host_->SetTimer(kTimerDelayMs * 1, kCtx1);
  host_->SetTimer(kTimerDelayMs * 2, kCtx2);

  host_->FastForwardTime(kTimerDelaySeconds);
  EXPECT_TRUE(cdm->TimerFired());
  EXPECT_EQ(kCtx1, cdm->LastTimerContext());
  cdm->ResetTimerStatus();

  host_->FastForwardTime(kTimerDelaySeconds);
  EXPECT_TRUE(cdm->TimerFired());
  EXPECT_EQ(kCtx2, cdm->LastTimerContext());
  cdm->ResetTimerStatus();

  host_->FastForwardTime(kTimerDelaySeconds);
  EXPECT_FALSE(cdm->TimerFired());
}

TEST_F(CdmApi4Test, DeviceCertificateTest) {
  if (Properties::use_certificates_as_identification()) {
    // Clear any existing certificates
    host_->file_store.erase(kCertFilename);

    CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
    ASSERT_TRUE(SessionErrorPresent(kSessionId1, cdm::kNeedsDeviceCertificate));

    // The Host must handle the certificate provisioning request.
    CreateSession(kSessionId2, "", cdm::kProvisioning);
    ASSERT_FALSE(SessionErrorPresent(kSessionId2));
    ProcessProvisionResponse();
    ASSERT_FALSE(SessionErrorPresent(kSessionId2));

    CreateSession(kSessionId3, g_key_id, cdm::kTemporary);
    ASSERT_FALSE(SessionErrorPresent(kSessionId3));
  } else {
    LOGI(
        "Skipping CdmApi4Test::DeviceCertificateTest because this platform "
        "does not support device certificates.");
  }
}

// Note that these tests, BaseMessageTest, NormalDecryption, TimeTest, and
// others are dependent on getting back a license from the license server where
// the url for the license server is defined in the conf_test_env.cpp.  If these
// tests fail immediately, verify that the license server URL is correct
// and works in your test environment.

TEST_F(CdmApi4Test, BaseMessageTest) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, NormalDecryption) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  // Level 1 / Level 2 payload comes back in the cpu memory as cleartext.
  std::vector<uint8_t> encrypted = kInputVector1;
  std::vector<uint8_t> iv = kIv1;
  std::vector<uint8_t> expected = kOutputVector1;
  std::vector<cdm::SubsampleEntry> sub = BuildSingleSubsample(encrypted.size());
  cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv, sub);

  TestDecryptedBlock output;
  cdm::Status status = cdm_->Decrypt(buf, &output);

  EXPECT_EQ(cdm::kSuccess, status);
  EXPECT_EQ(
      0, memcmp(output.DecryptedBuffer()->Data(), &expected[0], buf.data_size));

  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, NormalSubSampleDecryptionWithSubsampleInfo) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  // Level 1 / Level 2 payload comes back in the cpu memory as cleartext.
  std::vector<uint8_t> encrypted = kInputVector2;
  std::vector<uint8_t> iv = kIv2;
  std::vector<uint8_t> expected = kOutputVector2;
  std::vector<cdm::SubsampleEntry> sub = BuildMultipleSubsamples();
  cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv, sub);

  TestDecryptedBlock output;
  cdm::Status status = cdm_->Decrypt(buf, &output);

  EXPECT_EQ(cdm::kSuccess, status);
  EXPECT_EQ(
      0, memcmp(output.DecryptedBuffer()->Data(), &expected[0], buf.data_size));
  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, NormalSubSampleDecryptionWithMissingSubsampleInfo) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  std::vector<uint8_t> encrypted = kInputVector2;
  std::vector<uint8_t> iv = kIv2;
  std::vector<uint8_t> expected = kOutputVector2;
  std::vector<cdm::SubsampleEntry> sub = BuildMultipleSubsamples();

  // Don't add these subsamples yet!
  cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv);
  buf.num_subsamples = sub.size();

  TestDecryptedBlock output;

  cdm::Status status = cdm_->Decrypt(buf, &output);
  EXPECT_EQ(cdm::kDecryptError, status);

  // Add the subsamples pointer and expect success.
  buf.subsamples = &sub[0];
  status = cdm_->Decrypt(buf, &output);
  EXPECT_EQ(cdm::kSuccess, status);
  EXPECT_EQ(
      0, memcmp(output.DecryptedBuffer()->Data(), &expected[0], buf.data_size));

  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, DecryptWithDataOffset) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));

  std::vector<uint8_t> encrypted = kInputVector3;
  std::vector<uint8_t> iv = kIv3;
  std::vector<uint8_t> expected = kOutputVector3;
  cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv, kInputOffset3);

  TestDecryptedBlock output;
  cdm::Status status = cdm_->Decrypt(buf, &output);
  cdm::Buffer* output_buf = output.DecryptedBuffer();

  EXPECT_EQ(cdm::kSuccess, status);
  EXPECT_EQ(buf.data_size - buf.data_offset, output_buf->Size());
  EXPECT_EQ(0, memcmp(output.DecryptedBuffer()->Data(), &expected[0],
                      output_buf->Size()));

  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, DecryptReturnsSizedBuffer) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));

  std::vector<uint8_t> encrypted = kInputVector1;
  std::vector<uint8_t> iv = kIv1;
  std::vector<uint8_t> expected = kOutputVector1;

  std::vector<cdm::SubsampleEntry> sub = BuildSingleSubsample(encrypted.size());
  cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv, sub);

  TestDecryptedBlock output;
  cdm::Status status = cdm_->Decrypt(buf, &output);

  EXPECT_EQ(cdm::kSuccess, status);
  cdm::Buffer* buffer = output.DecryptedBuffer();
  EXPECT_NE((void*)NULL, buffer);
  if (buffer) {
    EXPECT_EQ(expected.size(), output.DecryptedBuffer()->Size());
  }

  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, TimeTest) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  // We expect that by the time we've added a key, the CDM has set a timer.
  // Otherwise, it couldn't correctly handle renewal.
  EXPECT_NE(0, host_->NumTimers());
  host_->FastForwardTime(kTestPolicyRenewalDelaySeconds +
                         kDelayWaitToForRenewalMessageSeconds);
  // When the timer expired, we should have sent a renewal, so we can
  // add this renewed key now, assuming things are working as expected.
  ProcessKeyResponse(true);
  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, SecureDecryptionLevel1) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  // Level 1 passes encrypted payload straight through. By calling the CDM's
  // DecryptDecodeAndRender, OEMCrypto_DecryptCTR will be told to use Direct
  // Rendering.
  std::vector<uint8_t> encrypted = kInputVector1;
  std::vector<uint8_t> iv = kIv1;
  std::vector<cdm::SubsampleEntry> sub = BuildSingleSubsample(encrypted.size());
  cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv, sub);

  cdm::Status status;

  status = cdm_->DecryptDecodeAndRender(buf, cdm::kStreamTypeVideo);
  EXPECT_EQ(cdm::kSuccess, status);
  status = cdm_->DecryptDecodeAndRender(buf, cdm::kStreamTypeAudio);
  EXPECT_EQ(cdm::kSuccess, status);
  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, SecureDecryptionLevel1WithSubsampleInfo) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  // Level 1 passes encrypted payload straight through. By calling the
  // CDM's DecryptDecodeAndRender, OEMCrypto_DecryptCTR will be told
  // to use Direct Rendering.
  std::vector<uint8_t> encrypted = kInputVector2;
  std::vector<uint8_t> iv = kIv2;
  std::vector<cdm::SubsampleEntry> sub = BuildMultipleSubsamples();
  cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv, sub);

  cdm::Status status;

  status = cdm_->DecryptDecodeAndRender(buf, cdm::kStreamTypeVideo);
  EXPECT_EQ(cdm::kSuccess, status);
  status = cdm_->DecryptDecodeAndRender(buf, cdm::kStreamTypeAudio);
  EXPECT_EQ(cdm::kSuccess, status);
  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, SecureDecryptionLevel1WithMissingSubsampleInfo) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  std::vector<uint8_t> encrypted = kInputVector2;
  std::vector<uint8_t> iv = kIv2;
  std::vector<cdm::SubsampleEntry> sub = BuildMultipleSubsamples();

  // Don't add these subsamples yet!
  cdm::InputBuffer buf = BuildInputBuffer(encrypted, iv);
  buf.num_subsamples = sub.size();

  cdm::Status status;

  status = cdm_->DecryptDecodeAndRender(buf, cdm::kStreamTypeVideo);
  EXPECT_EQ(cdm::kDecryptError, status);
  status = cdm_->DecryptDecodeAndRender(buf, cdm::kStreamTypeAudio);
  EXPECT_EQ(cdm::kDecryptError, status);

  // Add the subsamples pointer and expect success.
  buf.subsamples = &sub[0];
  status = cdm_->DecryptDecodeAndRender(buf, cdm::kStreamTypeVideo);
  EXPECT_EQ(cdm::kSuccess, status);
  status = cdm_->DecryptDecodeAndRender(buf, cdm::kStreamTypeAudio);
  EXPECT_EQ(cdm::kSuccess, status);

  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, GenerateKeyRequestFailureSendsKeyError) {
  // Pass a bogus key id and expect failure.
  // Expect the CDM to pass a key error back to the host.
  CreateSession(kSessionId1, g_wrong_key_id, cdm::kTemporary);
  EXPECT_EQ(1, host_->SessionErrorsSize());
  EXPECT_EQ(0, host_->SessionMessagesSize());
  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, UpdateSessionFailureSendsKeyError) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  TestHost_4::SessionMessage session_msg = host_->GetLastSessionMessage();
  EXPECT_TRUE(session_msg.default_url.empty());
  std::string drm_msg = GetKeyRequestResponse(
      session_msg, g_license_server + g_client_auth, false);

  // Call UpdateSession with a bad session id, and expect the CDM to pass a key
  // error back to the host.
  UpdateSession(kSessionId2, reinterpret_cast<const uint8_t*>(drm_msg.c_str()),
                drm_msg.length());
  EXPECT_EQ(1, host_->SessionErrorsSize());

  // Call UpdateSession with a bad license, and expect the CDM to pass a key
  // error back to the host.
  static const std::string kBadLicense = "!kGoodLicense";
  UpdateSession(kSessionId1,
                reinterpret_cast<const uint8_t*>(kBadLicense.c_str()),
                kBadLicense.length());
  EXPECT_EQ(2, host_->SessionErrorsSize());

  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, IsKeyValidDetectsValidKey) {
  EXPECT_FALSE(cdm_->IsKeyValid(
      reinterpret_cast<const uint8_t*>(kTestKeyId.data()), kTestKeyId.size()));
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ProcessKeyResponse(false);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  EXPECT_TRUE(cdm_->IsKeyValid(
      reinterpret_cast<const uint8_t*>(kTestKeyId.data()), kTestKeyId.size()));
  ReleaseSession(kSessionId1);
  EXPECT_FALSE(cdm_->IsKeyValid(
      reinterpret_cast<const uint8_t*>(kTestKeyId.data()), kTestKeyId.size()));
}

TEST_F(CdmApi4Test, OfflineLicense) {
  // override default settings unless configured through the command line
  std::string key_id;
  std::string license_server;
  std::string client_auth;
  GetOfflineConfiguration(&key_id, &license_server, &client_auth);

  CreateSession(kSessionId1, key_id, cdm::kPersistent);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  ProcessKeyResponse(false, license_server + client_auth);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, RestoreOfflineLicense) {
  // override default settings unless configured through the command line
  std::string key_id;
  std::string license_server;
  std::string client_auth;
  GetOfflineConfiguration(&key_id, &license_server, &client_auth);

  CreateSession(kSessionId1, key_id, cdm::kPersistent);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  ProcessKeyResponse(false, license_server + client_auth);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));

  std::string web_session_id = host_->session_map[kSessionId1];
  EXPECT_FALSE(web_session_id.empty());
  ReleaseSession(kSessionId1);

  LoadSession(kSessionId2, web_session_id);
  ASSERT_FALSE(SessionErrorPresent(kSessionId2));
  ReleaseSession(kSessionId2);
}

TEST_F(CdmApi4Test, ReleaseOfflineLicense) {
  // override default settings unless configured through the command line
  std::string key_id;
  std::string license_server;
  std::string client_auth;
  GetOfflineConfiguration(&key_id, &license_server, &client_auth);

  CreateSession(kSessionId1, key_id, cdm::kPersistent);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  ProcessKeyResponse(false, license_server + client_auth);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  std::string web_session_id = host_->session_map[kSessionId1];
  EXPECT_FALSE(web_session_id.empty());
  ReleaseSession(kSessionId1);

  RemoveSession(kSessionId2, web_session_id);
  ProcessKeyResponse(true, license_server + client_auth);
  ASSERT_FALSE(SessionErrorPresent(kSessionId2));
}

TEST_F(CdmApi4Test, MimeTypeMatters) {
  CreateSessionWithMimeType(kSessionId1, "video/mp4");
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  ReleaseSession(kSessionId1);

  CreateSessionWithMimeType(kSessionId1, "video/webm");
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));
  ReleaseSession(kSessionId1);

  CreateSessionWithMimeType(kSessionId1, "video/blah");
  ASSERT_TRUE(SessionErrorPresent(kSessionId1));
}

TEST_F(CdmApi4Test, UsePrivacyMode) {
  ASSERT_EQ(cdm::kSuccess, UsePrivacyMode());

  const CdmClientPropertySet& property_set =
      reinterpret_cast<WvContentDecryptionModule_4*>(cdm_)->property_set_;
  EXPECT_TRUE(property_set.use_privacy_mode());
}

TEST_F(CdmApi4Test, UsePrivacyModeFailsWithOpenSessions) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));

  EXPECT_NE(cdm::kSuccess, UsePrivacyMode());
  const CdmClientPropertySet& property_set =
      reinterpret_cast<WvContentDecryptionModule_4*>(cdm_)->property_set_;
  EXPECT_FALSE(property_set.use_privacy_mode());

  ReleaseSession(kSessionId1);
}

TEST_F(CdmApi4Test, SetExplicitServerCertificate) {
  ASSERT_EQ(cdm::kSuccess, SetServerCertificate(kFakeServerCertficiate));

  const CdmClientPropertySet& property_set =
      reinterpret_cast<WvContentDecryptionModule_4*>(cdm_)->property_set_;
  EXPECT_TRUE(property_set.use_privacy_mode());
  const std::string& set_cert = property_set.service_certificate();
  ASSERT_EQ(kFakeServerCertficiate.size(), set_cert.size());
  EXPECT_EQ(0,
            memcmp(&kFakeServerCertficiate[0], &set_cert[0], set_cert.size()));
}

TEST_F(CdmApi4Test, SetServerCertificateFailsWithOpenSessions) {
  CreateSession(kSessionId1, g_key_id, cdm::kTemporary);
  ASSERT_FALSE(SessionErrorPresent(kSessionId1));

  EXPECT_NE(cdm::kSuccess, SetServerCertificate(kFakeServerCertficiate));
  const CdmClientPropertySet& property_set =
      reinterpret_cast<WvContentDecryptionModule_4*>(cdm_)->property_set_;
  EXPECT_FALSE(property_set.use_privacy_mode());

  ReleaseSession(kSessionId1);
}

}  // namespace wvcdm