http2/adapter/window_manager_test.cc - quiche - Git at Google

 #include "http2/adapter/window_manager.h"

 #include <list>

 #include "absl/functional/bind_front.h"
 #include "http2/test_tools/http2_random.h"
 #include "common/platform/api/quiche_test.h"
 #include "common/platform/api/quiche_test_helpers.h"

 namespace http2 {
 namespace adapter {
 namespace test {

 // Use the peer to access private vars of WindowManager.
 class WindowManagerPeer {
  public:
   explicit WindowManagerPeer(const WindowManager& wm) : wm_(wm) {}

   size_t buffered() {
     return wm_.buffered_;
   }

  private:
   const WindowManager& wm_;
 };

 namespace {

 class WindowManagerTest : public ::testing::Test {
  protected:
   WindowManagerTest()
       : wm_(kDefaultLimit, absl::bind_front(&WindowManagerTest::OnCall, this)),
         peer_(wm_) {}

   void OnCall(size_t s) {
     call_sequence_.push_back(s);
   }

   const size_t kDefaultLimit = 32 * 1024 * 3;
   std::list<size_t> call_sequence_;
   WindowManager wm_;
   WindowManagerPeer peer_;
   ::http2::test::Http2Random random_;
 };

 // A few no-op calls.
 TEST_F(WindowManagerTest, NoOps) {
   wm_.SetWindowSizeLimit(kDefaultLimit);
   wm_.SetWindowSizeLimit(0);
   wm_.SetWindowSizeLimit(kDefaultLimit);
   wm_.MarkDataBuffered(0);
   wm_.MarkDataFlushed(0);
   EXPECT_TRUE(call_sequence_.empty());
 }

 // This test verifies that WindowManager does not notify its listener when data
 // is only buffered, and never flushed.
 TEST_F(WindowManagerTest, DataOnlyBuffered) {
   size_t total = 0;
   while (total < kDefaultLimit) {
     size_t s = std::min<size_t>(kDefaultLimit - total, random_.Uniform(1024));
     total += s;
     wm_.MarkDataBuffered(s);
   }
   EXPECT_THAT(call_sequence_, ::testing::IsEmpty());
 }

 // This test verifies that WindowManager does notify its listener when data is
 // buffered and subsequently flushed.
 TEST_F(WindowManagerTest, DataBufferedAndFlushed) {
   size_t total_buffered = 0;
   size_t total_flushed = 0;
   while (call_sequence_.empty()) {
     size_t buffered =
         std::min<size_t>(kDefaultLimit - total_buffered, random_.Uniform(1024));
     wm_.MarkDataBuffered(buffered);
     total_buffered += buffered;
     EXPECT_TRUE(call_sequence_.empty());
     size_t flushed = random_.Uniform(total_buffered - total_flushed);
     wm_.MarkDataFlushed(flushed);
     total_flushed += flushed;
   }
   // If WindowManager decided to send an update, at least one third of the
   // window must have been consumed by buffered data.
   EXPECT_GE(total_buffered, kDefaultLimit / 3);
 }

 // Window manager should avoid window underflow.
 TEST_F(WindowManagerTest, AvoidWindowUnderflow) {
   EXPECT_EQ(wm_.CurrentWindowSize(), wm_.WindowSizeLimit());
   // Don't buffer more than the total window!
   wm_.MarkDataBuffered(wm_.WindowSizeLimit() + 1);
   EXPECT_EQ(wm_.CurrentWindowSize(), 0u);
 }

 // Window manager should GFE_BUG and avoid buffered underflow.
 TEST_F(WindowManagerTest, AvoidBufferedUnderflow) {
   EXPECT_EQ(peer_.buffered(), 0u);
   // Don't flush more than has been buffered!
   EXPECT_QUICHE_BUG(wm_.MarkDataFlushed(1), "buffered underflow");
   EXPECT_EQ(peer_.buffered(), 0u);

   wm_.MarkDataBuffered(42);
   EXPECT_EQ(peer_.buffered(), 42u);
   // Don't flush more than has been buffered!
   EXPECT_QUICHE_BUG(wm_.MarkDataFlushed(43), "buffered underflow");
   EXPECT_EQ(peer_.buffered(), 0u);
 }

 // This test verifies that WindowManager notifies its listener when window is
 // consumed (data is ignored or immediately dropped).
 TEST_F(WindowManagerTest, WindowConsumed) {
   size_t consumed = kDefaultLimit / 3 - 1;
   wm_.MarkWindowConsumed(consumed);
   EXPECT_TRUE(call_sequence_.empty());
   const size_t extra = 1;
   wm_.MarkWindowConsumed(extra);
   EXPECT_THAT(call_sequence_, testing::ElementsAre(consumed + extra));
 }

 // This test verifies that WindowManager notifies its listener when the window
 // size limit is increased.
 TEST_F(WindowManagerTest, ListenerCalledOnSizeUpdate) {
   wm_.SetWindowSizeLimit(kDefaultLimit - 1024);
   EXPECT_TRUE(call_sequence_.empty());
   wm_.SetWindowSizeLimit(kDefaultLimit * 5);
   // Because max(outstanding window, previous limit) is kDefaultLimit, it is
   // only appropriate to increase the window by kDefaultLimit * 4.
   EXPECT_THAT(call_sequence_, testing::ElementsAre(kDefaultLimit * 4));
 }

 // This test verifies that when data is buffered and then the limit is
 // decreased, WindowManager only notifies the listener once any outstanding
 // window has been consumed.
 TEST_F(WindowManagerTest, WindowUpdateAfterLimitDecreased) {
   wm_.MarkDataBuffered(kDefaultLimit - 1024);
   wm_.SetWindowSizeLimit(kDefaultLimit - 2048);

   // Now there are 2048 bytes of window outstanding beyond the current limit,
   // and we have 1024 bytes of data buffered beyond the current limit. This is
   // intentional, to be sure that WindowManager works properly if the limit is
   // decreased at runtime.

   wm_.MarkDataFlushed(512);
   EXPECT_TRUE(call_sequence_.empty());
   wm_.MarkDataFlushed(512);
   EXPECT_TRUE(call_sequence_.empty());
   wm_.MarkDataFlushed(512);
   EXPECT_TRUE(call_sequence_.empty());
   wm_.MarkDataFlushed(1024);
   EXPECT_THAT(call_sequence_, testing::ElementsAre(512));
 }

 // For normal behavior, we only call MaybeNotifyListener() when data is
 // flushed. But if window runs out entirely, we still need to call
 // MaybeNotifyListener() to avoid becoming artificially blocked when data isn't
 // being flushed.
 TEST_F(WindowManagerTest, ZeroWindowNotification) {
   // Consume a byte of window, but not enough to trigger an update.
   wm_.MarkWindowConsumed(1);

   // Buffer the remaining window.
   wm_.MarkDataBuffered(kDefaultLimit - 1);
   // Listener is notified of the remaining byte of possible window.
   EXPECT_THAT(call_sequence_, testing::ElementsAre(1));
 }

 }  // namespace
 }  // namespace test
 }  // namespace adapter
 }  // namespace http2
	#include "http2/adapter/window_manager.h"

	#include <list>

	#include "absl/functional/bind_front.h"
	#include "http2/test_tools/http2_random.h"
	#include "common/platform/api/quiche_test.h"
	#include "common/platform/api/quiche_test_helpers.h"

	namespace http2 {
	namespace adapter {
	namespace test {

	// Use the peer to access private vars of WindowManager.
	class WindowManagerPeer {
	public:
	explicit WindowManagerPeer(const WindowManager& wm) : wm_(wm) {}

	size_t buffered() {
	return wm_.buffered_;
	}

	private:
	const WindowManager& wm_;
	};

	namespace {

	class WindowManagerTest : public ::testing::Test {
	protected:
	WindowManagerTest()
	: wm_(kDefaultLimit, absl::bind_front(&WindowManagerTest::OnCall, this)),
	peer_(wm_) {}

	void OnCall(size_t s) {
	call_sequence_.push_back(s);
	}

	const size_t kDefaultLimit = 32 * 1024 * 3;
	std::list<size_t> call_sequence_;
	WindowManager wm_;
	WindowManagerPeer peer_;
	::http2::test::Http2Random random_;
	};

	// A few no-op calls.
	TEST_F(WindowManagerTest, NoOps) {
	wm_.SetWindowSizeLimit(kDefaultLimit);
	wm_.SetWindowSizeLimit(0);
	wm_.SetWindowSizeLimit(kDefaultLimit);
	wm_.MarkDataBuffered(0);
	wm_.MarkDataFlushed(0);
	EXPECT_TRUE(call_sequence_.empty());
	}

	// This test verifies that WindowManager does not notify its listener when data
	// is only buffered, and never flushed.
	TEST_F(WindowManagerTest, DataOnlyBuffered) {
	size_t total = 0;
	while (total < kDefaultLimit) {
	size_t s = std::min<size_t>(kDefaultLimit - total, random_.Uniform(1024));
	total += s;
	wm_.MarkDataBuffered(s);
	}
	EXPECT_THAT(call_sequence_, ::testing::IsEmpty());
	}

	// This test verifies that WindowManager does notify its listener when data is
	// buffered and subsequently flushed.
	TEST_F(WindowManagerTest, DataBufferedAndFlushed) {
	size_t total_buffered = 0;
	size_t total_flushed = 0;
	while (call_sequence_.empty()) {
	size_t buffered =
	std::min<size_t>(kDefaultLimit - total_buffered, random_.Uniform(1024));
	wm_.MarkDataBuffered(buffered);
	total_buffered += buffered;
	EXPECT_TRUE(call_sequence_.empty());
	size_t flushed = random_.Uniform(total_buffered - total_flushed);
	wm_.MarkDataFlushed(flushed);
	total_flushed += flushed;
	}
	// If WindowManager decided to send an update, at least one third of the
	// window must have been consumed by buffered data.
	EXPECT_GE(total_buffered, kDefaultLimit / 3);
	}

	// Window manager should avoid window underflow.
	TEST_F(WindowManagerTest, AvoidWindowUnderflow) {
	EXPECT_EQ(wm_.CurrentWindowSize(), wm_.WindowSizeLimit());
	// Don't buffer more than the total window!
	wm_.MarkDataBuffered(wm_.WindowSizeLimit() + 1);
	EXPECT_EQ(wm_.CurrentWindowSize(), 0u);
	}

	// Window manager should GFE_BUG and avoid buffered underflow.
	TEST_F(WindowManagerTest, AvoidBufferedUnderflow) {
	EXPECT_EQ(peer_.buffered(), 0u);
	// Don't flush more than has been buffered!
	EXPECT_QUICHE_BUG(wm_.MarkDataFlushed(1), "buffered underflow");
	EXPECT_EQ(peer_.buffered(), 0u);

	wm_.MarkDataBuffered(42);
	EXPECT_EQ(peer_.buffered(), 42u);
	// Don't flush more than has been buffered!
	EXPECT_QUICHE_BUG(wm_.MarkDataFlushed(43), "buffered underflow");
	EXPECT_EQ(peer_.buffered(), 0u);
	}

	// This test verifies that WindowManager notifies its listener when window is
	// consumed (data is ignored or immediately dropped).
	TEST_F(WindowManagerTest, WindowConsumed) {
	size_t consumed = kDefaultLimit / 3 - 1;
	wm_.MarkWindowConsumed(consumed);
	EXPECT_TRUE(call_sequence_.empty());
	const size_t extra = 1;
	wm_.MarkWindowConsumed(extra);
	EXPECT_THAT(call_sequence_, testing::ElementsAre(consumed + extra));
	}

	// This test verifies that WindowManager notifies its listener when the window
	// size limit is increased.
	TEST_F(WindowManagerTest, ListenerCalledOnSizeUpdate) {
	wm_.SetWindowSizeLimit(kDefaultLimit - 1024);
	EXPECT_TRUE(call_sequence_.empty());
	wm_.SetWindowSizeLimit(kDefaultLimit * 5);
	// Because max(outstanding window, previous limit) is kDefaultLimit, it is
	// only appropriate to increase the window by kDefaultLimit * 4.
	EXPECT_THAT(call_sequence_, testing::ElementsAre(kDefaultLimit * 4));
	}

	// This test verifies that when data is buffered and then the limit is
	// decreased, WindowManager only notifies the listener once any outstanding
	// window has been consumed.
	TEST_F(WindowManagerTest, WindowUpdateAfterLimitDecreased) {
	wm_.MarkDataBuffered(kDefaultLimit - 1024);
	wm_.SetWindowSizeLimit(kDefaultLimit - 2048);

	// Now there are 2048 bytes of window outstanding beyond the current limit,
	// and we have 1024 bytes of data buffered beyond the current limit. This is
	// intentional, to be sure that WindowManager works properly if the limit is
	// decreased at runtime.

	wm_.MarkDataFlushed(512);
	EXPECT_TRUE(call_sequence_.empty());
	wm_.MarkDataFlushed(512);
	EXPECT_TRUE(call_sequence_.empty());
	wm_.MarkDataFlushed(512);
	EXPECT_TRUE(call_sequence_.empty());
	wm_.MarkDataFlushed(1024);
	EXPECT_THAT(call_sequence_, testing::ElementsAre(512));
	}

	// For normal behavior, we only call MaybeNotifyListener() when data is
	// flushed. But if window runs out entirely, we still need to call
	// MaybeNotifyListener() to avoid becoming artificially blocked when data isn't
	// being flushed.
	TEST_F(WindowManagerTest, ZeroWindowNotification) {
	// Consume a byte of window, but not enough to trigger an update.
	wm_.MarkWindowConsumed(1);

	// Buffer the remaining window.
	wm_.MarkDataBuffered(kDefaultLimit - 1);
	// Listener is notified of the remaining byte of possible window.
	EXPECT_THAT(call_sequence_, testing::ElementsAre(1));
	}

	} // namespace
	} // namespace test
	} // namespace adapter
	} // namespace http2