src/net/quic/congestion_control/cubic_test.cc - cobalt - Git at Google

 // Copyright (c) 2012 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 "base/basictypes.h"
 #include "base/logging.h"
 #include "base/memory/scoped_ptr.h"
 #include "net/quic/congestion_control/cubic.h"
 #include "net/quic/test_tools/mock_clock.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace net {
 namespace testing {

 class CubicPeer : public Cubic {
  public:
   explicit CubicPeer(QuicClock* clock)
       : Cubic(clock) {
   }
   using Cubic::CubeRoot;
 };

 class CubicTest : public ::testing::Test {
  protected:
   CubicTest()
       : one_ms_(QuicTime::Delta::FromMilliseconds(1)),
         hundred_ms_(QuicTime::Delta::FromMilliseconds(100)) {
   }
   void SetUp() {
     cubic_.reset(new CubicPeer(&clock_));
   }
   const QuicTime::Delta one_ms_;
   const QuicTime::Delta hundred_ms_;
   MockClock clock_;
   scoped_ptr<CubicPeer> cubic_;
 };

 TEST_F(CubicTest, CubeRootLow) {
   for (uint32 i = 1; i < 256; ++i) {
     uint64 cube = i * i * i;
     uint8 cube_root = cubic_->CubeRoot(cube);
     EXPECT_EQ(i, cube_root);
   }
 }

 TEST_F(CubicTest, CubeRootHigh) {
   // Test the range we will opperate in, 1300 to 130 000.
   // We expect some loss in accuracy, accepting +-0.2%.
   for (uint64 i = 1300; i < 20000; i += 100) {
     uint64 cube = i * i * i;
     uint32 cube_root = cubic_->CubeRoot(cube);
     uint32 margin = cube_root >> 9;  // Calculate 0.2% roughly by
                                      // dividing by 512.
     EXPECT_LE(i - margin, cube_root);
     EXPECT_GE(i + margin, cube_root);
   }
   for (uint64 i = 20000; i < 130000; i *= 2) {
     uint64 cube = i * i * i;
     uint32 cube_root = cubic_->CubeRoot(cube);
     uint32 margin = cube_root >> 9;
     EXPECT_LE(i - margin, cube_root);
     EXPECT_GE(i + margin, cube_root);
   }
 }

 TEST_F(CubicTest, AboveOrgin) {
   // Convex growth.
   const QuicTime::Delta rtt_min = hundred_ms_;
   uint32 current_cwnd = 10;
   uint32 expected_cwnd = current_cwnd + 1;
   // Initialize the state.
   clock_.AdvanceTime(one_ms_);
   EXPECT_EQ(expected_cwnd,
             cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
   current_cwnd = expected_cwnd;
   // Normal TCP phase.
   for (int i = 0; i < 48; ++i) {
     for (uint32 n = 1; n < current_cwnd; ++n) {
       // Call once per ACK.
       EXPECT_EQ(current_cwnd,
                 cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
     }
     clock_.AdvanceTime(hundred_ms_);
     current_cwnd = cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min);
     EXPECT_EQ(expected_cwnd, current_cwnd);
     expected_cwnd++;
   }
   // Cubic phase.
   for (int j = 48; j < 100; ++j) {
     for (uint32 n = 1; n < current_cwnd; ++n) {
       // Call once per ACK.
       EXPECT_EQ(current_cwnd,
                 cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
     }
     clock_.AdvanceTime(hundred_ms_);
     current_cwnd = cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min);
   }
   float elapsed_time_s = 10.0f + 0.1f;  // We need to add the RTT here.
   expected_cwnd = 11 + (elapsed_time_s * elapsed_time_s * elapsed_time_s * 410)
       / 1024;
   EXPECT_EQ(expected_cwnd, current_cwnd);
 }

 TEST_F(CubicTest, LossEvents) {
   const QuicTime::Delta rtt_min = hundred_ms_;
   uint32 current_cwnd = 422;
   uint32 expected_cwnd = current_cwnd + 1;
   // Initialize the state.
   clock_.AdvanceTime(one_ms_);
   EXPECT_EQ(expected_cwnd,
             cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
   expected_cwnd = current_cwnd * 717 / 1024;
   EXPECT_EQ(expected_cwnd,
             cubic_->CongestionWindowAfterPacketLoss(current_cwnd));
   expected_cwnd = current_cwnd * 717 / 1024;
   EXPECT_EQ(expected_cwnd,
             cubic_->CongestionWindowAfterPacketLoss(current_cwnd));
 }

 TEST_F(CubicTest, BelowOrgin) {
   // Concave growth.
   const QuicTime::Delta rtt_min = hundred_ms_;
   uint32 current_cwnd = 422;
   uint32 expected_cwnd = current_cwnd + 1;
   // Initialize the state.
   clock_.AdvanceTime(one_ms_);
   EXPECT_EQ(expected_cwnd,
             cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
   expected_cwnd = current_cwnd * 717 / 1024;
   EXPECT_EQ(expected_cwnd,
             cubic_->CongestionWindowAfterPacketLoss(current_cwnd));
   current_cwnd = expected_cwnd;
   // First update after epoch.
   current_cwnd = cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min);
   // Cubic phase.
   for (int i = 0; i < 54; ++i) {
     for (uint32 n = 1; n < current_cwnd; ++n) {
       // Call once per ACK.
       EXPECT_EQ(current_cwnd,
                 cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
     }
     clock_.AdvanceTime(hundred_ms_);
     current_cwnd = cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min);
   }
   expected_cwnd = 422;
   EXPECT_EQ(expected_cwnd, current_cwnd);
 }

 }  // namespace testing
 }  // namespace net
	// Copyright (c) 2012 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 "base/basictypes.h"
	#include "base/logging.h"
	#include "base/memory/scoped_ptr.h"
	#include "net/quic/congestion_control/cubic.h"
	#include "net/quic/test_tools/mock_clock.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace net {
	namespace testing {

	class CubicPeer : public Cubic {
	public:
	explicit CubicPeer(QuicClock* clock)
	: Cubic(clock) {
	}
	using Cubic::CubeRoot;
	};

	class CubicTest : public ::testing::Test {
	protected:
	CubicTest()
	: one_ms_(QuicTime::Delta::FromMilliseconds(1)),
	hundred_ms_(QuicTime::Delta::FromMilliseconds(100)) {
	}
	void SetUp() {
	cubic_.reset(new CubicPeer(&clock_));
	}
	const QuicTime::Delta one_ms_;
	const QuicTime::Delta hundred_ms_;
	MockClock clock_;
	scoped_ptr<CubicPeer> cubic_;
	};

	TEST_F(CubicTest, CubeRootLow) {
	for (uint32 i = 1; i < 256; ++i) {
	uint64 cube = i * i * i;
	uint8 cube_root = cubic_->CubeRoot(cube);
	EXPECT_EQ(i, cube_root);
	}
	}

	TEST_F(CubicTest, CubeRootHigh) {
	// Test the range we will opperate in, 1300 to 130 000.
	// We expect some loss in accuracy, accepting +-0.2%.
	for (uint64 i = 1300; i < 20000; i += 100) {
	uint64 cube = i * i * i;
	uint32 cube_root = cubic_->CubeRoot(cube);
	uint32 margin = cube_root >> 9; // Calculate 0.2% roughly by
	// dividing by 512.
	EXPECT_LE(i - margin, cube_root);
	EXPECT_GE(i + margin, cube_root);
	}
	for (uint64 i = 20000; i < 130000; i *= 2) {
	uint64 cube = i * i * i;
	uint32 cube_root = cubic_->CubeRoot(cube);
	uint32 margin = cube_root >> 9;
	EXPECT_LE(i - margin, cube_root);
	EXPECT_GE(i + margin, cube_root);
	}
	}

	TEST_F(CubicTest, AboveOrgin) {
	// Convex growth.
	const QuicTime::Delta rtt_min = hundred_ms_;
	uint32 current_cwnd = 10;
	uint32 expected_cwnd = current_cwnd + 1;
	// Initialize the state.
	clock_.AdvanceTime(one_ms_);
	EXPECT_EQ(expected_cwnd,
	cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
	current_cwnd = expected_cwnd;
	// Normal TCP phase.
	for (int i = 0; i < 48; ++i) {
	for (uint32 n = 1; n < current_cwnd; ++n) {
	// Call once per ACK.
	EXPECT_EQ(current_cwnd,
	cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
	}
	clock_.AdvanceTime(hundred_ms_);
	current_cwnd = cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min);
	EXPECT_EQ(expected_cwnd, current_cwnd);
	expected_cwnd++;
	}
	// Cubic phase.
	for (int j = 48; j < 100; ++j) {
	for (uint32 n = 1; n < current_cwnd; ++n) {
	// Call once per ACK.
	EXPECT_EQ(current_cwnd,
	cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
	}
	clock_.AdvanceTime(hundred_ms_);
	current_cwnd = cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min);
	}
	float elapsed_time_s = 10.0f + 0.1f; // We need to add the RTT here.
	expected_cwnd = 11 + (elapsed_time_s * elapsed_time_s * elapsed_time_s * 410)
	/ 1024;
	EXPECT_EQ(expected_cwnd, current_cwnd);
	}

	TEST_F(CubicTest, LossEvents) {
	const QuicTime::Delta rtt_min = hundred_ms_;
	uint32 current_cwnd = 422;
	uint32 expected_cwnd = current_cwnd + 1;
	// Initialize the state.
	clock_.AdvanceTime(one_ms_);
	EXPECT_EQ(expected_cwnd,
	cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
	expected_cwnd = current_cwnd * 717 / 1024;
	EXPECT_EQ(expected_cwnd,
	cubic_->CongestionWindowAfterPacketLoss(current_cwnd));
	expected_cwnd = current_cwnd * 717 / 1024;
	EXPECT_EQ(expected_cwnd,
	cubic_->CongestionWindowAfterPacketLoss(current_cwnd));
	}

	TEST_F(CubicTest, BelowOrgin) {
	// Concave growth.
	const QuicTime::Delta rtt_min = hundred_ms_;
	uint32 current_cwnd = 422;
	uint32 expected_cwnd = current_cwnd + 1;
	// Initialize the state.
	clock_.AdvanceTime(one_ms_);
	EXPECT_EQ(expected_cwnd,
	cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
	expected_cwnd = current_cwnd * 717 / 1024;
	EXPECT_EQ(expected_cwnd,
	cubic_->CongestionWindowAfterPacketLoss(current_cwnd));
	current_cwnd = expected_cwnd;
	// First update after epoch.
	current_cwnd = cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min);
	// Cubic phase.
	for (int i = 0; i < 54; ++i) {
	for (uint32 n = 1; n < current_cwnd; ++n) {
	// Call once per ACK.
	EXPECT_EQ(current_cwnd,
	cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min));
	}
	clock_.AdvanceTime(hundred_ms_);
	current_cwnd = cubic_->CongestionWindowAfterAck(current_cwnd, rtt_min);
	}
	expected_cwnd = 422;
	EXPECT_EQ(expected_cwnd, current_cwnd);
	}

	} // namespace testing
	} // namespace net