chrome_elf/third_party_dlls/logs_unittest.cc - chromium/src - Git at Google

 // Copyright 2018 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 "chrome_elf/third_party_dlls/logs.h"

 #include <windows.h>

 #include <memory>
 #include <string>

 #include "base/macros.h"
 #include "base/stl_util.h"
 #include "base/synchronization/waitable_event.h"
 #include "base/time/time.h"
 #include "chrome_elf/sha1/sha1.h"
 #include "chrome_elf/third_party_dlls/public_api.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace third_party_dlls {
 namespace {

 enum { kWaitTimeoutMs = 3000 };

 // Argument for NotificationHandler().
 struct NotificationHandlerArguments {
   uint32_t logs_expected;
   std::unique_ptr<base::WaitableEvent> notification_event;
 };

 struct TestEntry {
   uint32_t image_size;
   uint32_t time_date_stamp;
 };

 // Sample TestEntries
 TestEntry kTestLogs[] = {
     {0x9901, 0x12345678}, {0x9902, 0x12345678}, {0x9903, 0x12345678},
     {0x9904, 0x12345678}, {0x9905, 0x12345678}, {0x9906, 0x12345678},
 };

 // Be sure to test the padding/alignment issues well here.
 const std::string kTestPaths[] = {
     "1", "123", "1234", "12345", "123456", "1234567",
 };

 static_assert(
     base::size(kTestLogs) == base::size(kTestPaths),
     "Some tests currently expect these two arrays to be the same size.");

 // Ensure |buffer_size| passed in is the actual bytes written by DrainLog().
 void VerifyBuffer(uint8_t* buffer, uint32_t buffer_size) {
   uint32_t total_logs = 0;
   size_t index = 0;
   size_t array_size = base::size(kTestLogs);

   // Verify against kTestLogs/kTestPaths.  Expect 2 * base::size(kTestLogs)
   // entries: first half are "blocked", second half are "allowed".
   LogEntry* entry = nullptr;
   uint8_t* tracker = buffer;
   while (tracker < buffer + buffer_size) {
     entry = reinterpret_cast<LogEntry*>(tracker);

     EXPECT_EQ(entry->module_size, kTestLogs[index].image_size);
     EXPECT_EQ(entry->time_date_stamp, kTestLogs[index].time_date_stamp);

     if (entry->path_len)
       EXPECT_STREQ(entry->path, kTestPaths[index].c_str());

     ++total_logs;
     tracker += GetLogEntrySize(entry->path_len);

     // Roll index back to 0 for second run through kTestLogs, else increment.
     index = (index == array_size - 1) ? 0 : index + 1;
   }
   EXPECT_EQ(total_logs, array_size * 2);
 }

 // Helper function to count the number of LogEntries in a buffer returned from
 // DrainLog().
 uint32_t GetLogCount(uint8_t* buffer, uint32_t bytes_written) {
   LogEntry* entry = nullptr;
   uint8_t* tracker = buffer;
   uint32_t counter = 0;

   while (tracker < buffer + bytes_written) {
     entry = reinterpret_cast<LogEntry*>(tracker);
     ++counter;
     tracker += GetLogEntrySize(entry->path_len);
   }

   return counter;
 }

 // A thread function used to test log notifications.
 // - |parameter| should be a NotificationHandlerArguments*.
 // - Returns 0 for successful retrieval of expected number of LogEntries.
 DWORD WINAPI NotificationHandler(LPVOID parameter) {
   NotificationHandlerArguments* args =
       reinterpret_cast<NotificationHandlerArguments*>(parameter);
   uint32_t log_counter = 0;

   // Make a buffer big enough for any possible DrainLog call.
   uint32_t buffer_size = args->logs_expected * GetLogEntrySize(0);
   auto buffer = std::unique_ptr<uint8_t[]>(new uint8_t[buffer_size]);
   uint32_t bytes_written = 0;

   do {
     if (!args->notification_event->TimedWait(
             base::TimeDelta::FromMilliseconds(kWaitTimeoutMs)))
       break;

     bytes_written = DrainLog(&buffer[0], buffer_size, nullptr);
     log_counter += GetLogCount(&buffer[0], bytes_written);
   } while (log_counter < args->logs_expected);

   return (log_counter == args->logs_expected) ? 0 : 1;
 }

 //------------------------------------------------------------------------------
 // Third-party log tests
 //------------------------------------------------------------------------------

 // Test successful initialization and module lookup.
 TEST(ThirdParty, Logs) {
   // Init.
   ASSERT_EQ(InitLogs(), ThirdPartyStatus::kSuccess);

   for (size_t i = 0; i < base::size(kTestLogs); ++i) {
     // Add some blocked entries.
     LogLoadAttempt(LogType::kBlocked, kTestLogs[i].image_size,
                    kTestLogs[i].time_date_stamp, std::string());

     // Add some allowed entries.
     LogLoadAttempt(LogType::kAllowed, kTestLogs[i].image_size,
                    kTestLogs[i].time_date_stamp, kTestPaths[i]);
   }

   uint32_t initial_log = 0;
   DrainLog(nullptr, 0, &initial_log);
   ASSERT_TRUE(initial_log);

   auto buffer = std::unique_ptr<uint8_t[]>(new uint8_t[initial_log]);
   uint32_t remaining_log = 0;
   uint32_t bytes_written = DrainLog(&buffer[0], initial_log, &remaining_log);
   EXPECT_EQ(bytes_written, initial_log);
   EXPECT_EQ(remaining_log, uint32_t{0});

   VerifyBuffer(&buffer[0], bytes_written);

   DeinitLogs();
 }

 // Test notifications.
 TEST(ThirdParty, LogNotifications) {
   // Init.
   ASSERT_EQ(InitLogs(), ThirdPartyStatus::kSuccess);

   uint32_t initial_log = 0;
   DrainLog(nullptr, 0, &initial_log);
   EXPECT_EQ(initial_log, uint32_t{0});

   // Set up the required arguments for the test thread.
   NotificationHandlerArguments handler_data;
   handler_data.logs_expected = base::size(kTestLogs);
   handler_data.notification_event.reset(
       new base::WaitableEvent(base::WaitableEvent::ResetPolicy::AUTOMATIC,
                               base::WaitableEvent::InitialState::NOT_SIGNALED));

   // Register the event.
   ASSERT_TRUE(
       RegisterLogNotification(handler_data.notification_event->handle()));

   // Fire off a thread to handle the notifications.
   base::win::ScopedHandle thread(::CreateThread(
       nullptr, 0, &NotificationHandler, &handler_data, 0, nullptr));

   for (size_t i = 0; i < handler_data.logs_expected; ++i) {
     // Add blocked entries - type doesn't matter in this test.
     LogLoadAttempt(LogType::kBlocked, kTestLogs[i].image_size,
                    kTestLogs[i].time_date_stamp, std::string());
   }

   EXPECT_EQ(::WaitForSingleObject(thread.Get(), kWaitTimeoutMs * 2),
             WAIT_OBJECT_0);
   DWORD exit_code = 1;
   EXPECT_TRUE(::GetExitCodeThread(thread.Get(), &exit_code));
   EXPECT_EQ(exit_code, DWORD{0});

   DeinitLogs();
 }

 // Test that "spam", duplicate block logs are handled as expected across drains.
 TEST(ThirdParty, BlockedLogDuplicates) {
   // Init.
   ASSERT_EQ(InitLogs(), ThirdPartyStatus::kSuccess);

   for (size_t i = 0; i < base::size(kTestLogs); ++i) {
     // Add some blocked entries.
     LogLoadAttempt(LogType::kBlocked, kTestLogs[i].image_size,
                    kTestLogs[i].time_date_stamp, kTestPaths[i]);

     // Add some allowed entries.
     LogLoadAttempt(LogType::kAllowed, kTestLogs[i].image_size,
                    kTestLogs[i].time_date_stamp, kTestPaths[i]);
   }

   uint32_t initial_log = 0;
   DrainLog(nullptr, 0, &initial_log);
   ASSERT_TRUE(initial_log);

   auto buffer = std::unique_ptr<uint8_t[]>(new uint8_t[initial_log]);
   uint32_t remaining_log = 0;
   uint32_t bytes_written = DrainLog(&buffer[0], initial_log, &remaining_log);
   EXPECT_EQ(bytes_written, initial_log);
   EXPECT_EQ(remaining_log, uint32_t{0});

   // Validate that all of the logs have been drained.
   EXPECT_EQ(GetLogCount(&buffer[0], bytes_written), base::size(kTestLogs) * 2);

   // Now the real test.  Add the same log entries again, and expect that the
   // blocked logs will NOT be re-added and drained this time.
   for (size_t i = 0; i < base::size(kTestLogs); ++i) {
     // Add some blocked entries.
     LogLoadAttempt(LogType::kBlocked, kTestLogs[i].image_size,
                    kTestLogs[i].time_date_stamp, kTestPaths[i]);

     // Add some allowed entries.
     LogLoadAttempt(LogType::kAllowed, kTestLogs[i].image_size,
                    kTestLogs[i].time_date_stamp, kTestPaths[i]);
   }

   initial_log = 0;
   DrainLog(nullptr, 0, &initial_log);
   ASSERT_TRUE(initial_log);

   buffer = std::unique_ptr<uint8_t[]>(new uint8_t[initial_log]);
   remaining_log = 0;
   bytes_written = DrainLog(&buffer[0], initial_log, &remaining_log);
   EXPECT_EQ(bytes_written, initial_log);
   EXPECT_EQ(remaining_log, uint32_t{0});

   // Validate that only half of the logs have been drained.
   EXPECT_EQ(GetLogCount(&buffer[0], bytes_written), base::size(kTestLogs));

   DeinitLogs();
 }

 }  // namespace
 }  // namespace third_party_dlls
	// Copyright 2018 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 "chrome_elf/third_party_dlls/logs.h"

	#include <windows.h>

	#include <memory>
	#include <string>

	#include "base/macros.h"
	#include "base/stl_util.h"
	#include "base/synchronization/waitable_event.h"
	#include "base/time/time.h"
	#include "chrome_elf/sha1/sha1.h"
	#include "chrome_elf/third_party_dlls/public_api.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace third_party_dlls {
	namespace {

	enum { kWaitTimeoutMs = 3000 };

	// Argument for NotificationHandler().
	struct NotificationHandlerArguments {
	uint32_t logs_expected;
	std::unique_ptr<base::WaitableEvent> notification_event;
	};

	struct TestEntry {
	uint32_t image_size;
	uint32_t time_date_stamp;
	};

	// Sample TestEntries
	TestEntry kTestLogs[] = {
	{0x9901, 0x12345678}, {0x9902, 0x12345678}, {0x9903, 0x12345678},
	{0x9904, 0x12345678}, {0x9905, 0x12345678}, {0x9906, 0x12345678},
	};

	// Be sure to test the padding/alignment issues well here.
	const std::string kTestPaths[] = {
	"1", "123", "1234", "12345", "123456", "1234567",
	};

	static_assert(
	base::size(kTestLogs) == base::size(kTestPaths),
	"Some tests currently expect these two arrays to be the same size.");

	// Ensure \|buffer_size\| passed in is the actual bytes written by DrainLog().
	void VerifyBuffer(uint8_t* buffer, uint32_t buffer_size) {
	uint32_t total_logs = 0;
	size_t index = 0;
	size_t array_size = base::size(kTestLogs);

	// Verify against kTestLogs/kTestPaths. Expect 2 * base::size(kTestLogs)
	// entries: first half are "blocked", second half are "allowed".
	LogEntry* entry = nullptr;
	uint8_t* tracker = buffer;
	while (tracker < buffer + buffer_size) {
	entry = reinterpret_cast<LogEntry*>(tracker);

	EXPECT_EQ(entry->module_size, kTestLogs[index].image_size);
	EXPECT_EQ(entry->time_date_stamp, kTestLogs[index].time_date_stamp);

	if (entry->path_len)
	EXPECT_STREQ(entry->path, kTestPaths[index].c_str());

	++total_logs;
	tracker += GetLogEntrySize(entry->path_len);

	// Roll index back to 0 for second run through kTestLogs, else increment.
	index = (index == array_size - 1) ? 0 : index + 1;
	}
	EXPECT_EQ(total_logs, array_size * 2);
	}

	// Helper function to count the number of LogEntries in a buffer returned from
	// DrainLog().
	uint32_t GetLogCount(uint8_t* buffer, uint32_t bytes_written) {
	LogEntry* entry = nullptr;
	uint8_t* tracker = buffer;
	uint32_t counter = 0;

	while (tracker < buffer + bytes_written) {
	entry = reinterpret_cast<LogEntry*>(tracker);
	++counter;
	tracker += GetLogEntrySize(entry->path_len);
	}

	return counter;
	}

	// A thread function used to test log notifications.
	// - \|parameter\| should be a NotificationHandlerArguments*.
	// - Returns 0 for successful retrieval of expected number of LogEntries.
	DWORD WINAPI NotificationHandler(LPVOID parameter) {
	NotificationHandlerArguments* args =
	reinterpret_cast<NotificationHandlerArguments*>(parameter);
	uint32_t log_counter = 0;

	// Make a buffer big enough for any possible DrainLog call.
	uint32_t buffer_size = args->logs_expected * GetLogEntrySize(0);
	auto buffer = std::unique_ptr<uint8_t[]>(new uint8_t[buffer_size]);
	uint32_t bytes_written = 0;

	do {
	if (!args->notification_event->TimedWait(
	base::TimeDelta::FromMilliseconds(kWaitTimeoutMs)))
	break;

	bytes_written = DrainLog(&buffer[0], buffer_size, nullptr);
	log_counter += GetLogCount(&buffer[0], bytes_written);
	} while (log_counter < args->logs_expected);

	return (log_counter == args->logs_expected) ? 0 : 1;
	}

	//------------------------------------------------------------------------------
	// Third-party log tests
	//------------------------------------------------------------------------------

	// Test successful initialization and module lookup.
	TEST(ThirdParty, Logs) {
	// Init.
	ASSERT_EQ(InitLogs(), ThirdPartyStatus::kSuccess);

	for (size_t i = 0; i < base::size(kTestLogs); ++i) {
	// Add some blocked entries.
	LogLoadAttempt(LogType::kBlocked, kTestLogs[i].image_size,
	kTestLogs[i].time_date_stamp, std::string());

	// Add some allowed entries.
	LogLoadAttempt(LogType::kAllowed, kTestLogs[i].image_size,
	kTestLogs[i].time_date_stamp, kTestPaths[i]);
	}

	uint32_t initial_log = 0;
	DrainLog(nullptr, 0, &initial_log);
	ASSERT_TRUE(initial_log);

	auto buffer = std::unique_ptr<uint8_t[]>(new uint8_t[initial_log]);
	uint32_t remaining_log = 0;
	uint32_t bytes_written = DrainLog(&buffer[0], initial_log, &remaining_log);
	EXPECT_EQ(bytes_written, initial_log);
	EXPECT_EQ(remaining_log, uint32_t{0});

	VerifyBuffer(&buffer[0], bytes_written);

	DeinitLogs();
	}

	// Test notifications.
	TEST(ThirdParty, LogNotifications) {
	// Init.
	ASSERT_EQ(InitLogs(), ThirdPartyStatus::kSuccess);

	uint32_t initial_log = 0;
	DrainLog(nullptr, 0, &initial_log);
	EXPECT_EQ(initial_log, uint32_t{0});

	// Set up the required arguments for the test thread.
	NotificationHandlerArguments handler_data;
	handler_data.logs_expected = base::size(kTestLogs);
	handler_data.notification_event.reset(
	new base::WaitableEvent(base::WaitableEvent::ResetPolicy::AUTOMATIC,
	base::WaitableEvent::InitialState::NOT_SIGNALED));

	// Register the event.
	ASSERT_TRUE(
	RegisterLogNotification(handler_data.notification_event->handle()));

	// Fire off a thread to handle the notifications.
	base::win::ScopedHandle thread(::CreateThread(
	nullptr, 0, &NotificationHandler, &handler_data, 0, nullptr));

	for (size_t i = 0; i < handler_data.logs_expected; ++i) {
	// Add blocked entries - type doesn't matter in this test.
	LogLoadAttempt(LogType::kBlocked, kTestLogs[i].image_size,
	kTestLogs[i].time_date_stamp, std::string());
	}

	EXPECT_EQ(::WaitForSingleObject(thread.Get(), kWaitTimeoutMs * 2),
	WAIT_OBJECT_0);
	DWORD exit_code = 1;
	EXPECT_TRUE(::GetExitCodeThread(thread.Get(), &exit_code));
	EXPECT_EQ(exit_code, DWORD{0});

	DeinitLogs();
	}

	// Test that "spam", duplicate block logs are handled as expected across drains.
	TEST(ThirdParty, BlockedLogDuplicates) {
	// Init.
	ASSERT_EQ(InitLogs(), ThirdPartyStatus::kSuccess);

	for (size_t i = 0; i < base::size(kTestLogs); ++i) {
	// Add some blocked entries.
	LogLoadAttempt(LogType::kBlocked, kTestLogs[i].image_size,
	kTestLogs[i].time_date_stamp, kTestPaths[i]);

	// Add some allowed entries.
	LogLoadAttempt(LogType::kAllowed, kTestLogs[i].image_size,
	kTestLogs[i].time_date_stamp, kTestPaths[i]);
	}

	uint32_t initial_log = 0;
	DrainLog(nullptr, 0, &initial_log);
	ASSERT_TRUE(initial_log);

	auto buffer = std::unique_ptr<uint8_t[]>(new uint8_t[initial_log]);
	uint32_t remaining_log = 0;
	uint32_t bytes_written = DrainLog(&buffer[0], initial_log, &remaining_log);
	EXPECT_EQ(bytes_written, initial_log);
	EXPECT_EQ(remaining_log, uint32_t{0});

	// Validate that all of the logs have been drained.
	EXPECT_EQ(GetLogCount(&buffer[0], bytes_written), base::size(kTestLogs) * 2);

	// Now the real test. Add the same log entries again, and expect that the
	// blocked logs will NOT be re-added and drained this time.
	for (size_t i = 0; i < base::size(kTestLogs); ++i) {
	// Add some blocked entries.
	LogLoadAttempt(LogType::kBlocked, kTestLogs[i].image_size,
	kTestLogs[i].time_date_stamp, kTestPaths[i]);

	// Add some allowed entries.
	LogLoadAttempt(LogType::kAllowed, kTestLogs[i].image_size,
	kTestLogs[i].time_date_stamp, kTestPaths[i]);
	}

	initial_log = 0;
	DrainLog(nullptr, 0, &initial_log);
	ASSERT_TRUE(initial_log);

	buffer = std::unique_ptr<uint8_t[]>(new uint8_t[initial_log]);
	remaining_log = 0;
	bytes_written = DrainLog(&buffer[0], initial_log, &remaining_log);
	EXPECT_EQ(bytes_written, initial_log);
	EXPECT_EQ(remaining_log, uint32_t{0});

	// Validate that only half of the logs have been drained.
	EXPECT_EQ(GetLogCount(&buffer[0], bytes_written), base::size(kTestLogs));

	DeinitLogs();
	}

	} // namespace
	} // namespace third_party_dlls