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android / platform / external / open-vcdiff / refs/tags/android-4.4_r1.1.0.1 / . / src / addrcache_test.cc
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// Copyright 2007 Google Inc.
// Author: Lincoln Smith
//
// 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
//
// http://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 <config.h>
#include "addrcache.h"
#include <limits.h> // INT_MAX, INT_MIN
#include <stdint.h> // uint32_t
#include <stdlib.h> // rand, srand
#include <iostream>
#include <string>
#include <vector>
#include "testing.h"
#include "varint_bigendian.h"
#include "vcdiff_defs.h" // RESULT_ERROR
namespace open_vcdiff {
namespace {
// Provides an address_stream_ buffer and functions to manually encode
// values into the buffer, and to manually decode and verify test results
// from the buffer.
//
class VCDiffAddressCacheTest : public testing::Test {
public:
typedef std::string string;
VCDiffAddressCacheTest() : decode_position_(NULL),
decode_position_end_(NULL),
verify_encode_position_(NULL),
last_encode_size_(0),
last_decode_position_(NULL) { }
virtual ~VCDiffAddressCacheTest() { }
virtual void SetUp() {
EXPECT_TRUE(cache_.Init());
}
// Benchmarks for timing encode/decode operations
void BM_Setup(int test_size);
void BM_CacheEncode(int iterations, int test_size);
void BM_CacheDecode(int iterations, int test_size);
protected:
virtual void TestBody() { } // to allow instantiation of this class
void BeginDecode() {
decode_position_ = address_stream_.data();
EXPECT_TRUE(decode_position_ != NULL);
last_decode_position_ = decode_position_;
decode_position_end_ = decode_position_ + address_stream_.size();
}
void ExpectEncodedSizeInBytes(int n) {
EXPECT_EQ(last_encode_size_ + n, address_stream_.size());
last_encode_size_ = address_stream_.size();
}
void ExpectDecodedSizeInBytes(int n) {
EXPECT_EQ(last_decode_position_ + n, decode_position_);
last_decode_position_ = decode_position_;
}
void ManualEncodeVarint(VCDAddress value) {
VarintBE<VCDAddress>::AppendToString(value, &address_stream_);
}
void ManualEncodeByte(unsigned char byte) {
address_stream_.push_back(byte);
}
void ExpectEncodedVarint(VCDAddress expected_value, int expected_size) {
if (!verify_encode_position_) {
verify_encode_position_ = address_stream_.data();
}
EXPECT_EQ(expected_size, VarintBE<VCDAddress>::Length(expected_value));
VCDAddress output_val = VarintBE<VCDAddress>::Parse(
address_stream_.data() + address_stream_.size(),
&verify_encode_position_);
EXPECT_EQ(expected_value, output_val);
}
void ExpectEncodedByte(unsigned char expected_value) {
if (!verify_encode_position_) {
verify_encode_position_ = address_stream_.data();
}
EXPECT_EQ(expected_value, *verify_encode_position_);
++verify_encode_position_;
}
void TestEncode(VCDAddress address,
VCDAddress here_address,
unsigned char mode,
int size) {
VCDAddress encoded_addr = 0;
EXPECT_EQ(mode, cache_.EncodeAddress(address, here_address, &encoded_addr));
if (cache_.WriteAddressAsVarintForMode(mode)) {
ManualEncodeVarint(encoded_addr);
} else {
EXPECT_GT(256, encoded_addr);
ManualEncodeByte(static_cast<unsigned char>(encoded_addr));
}
ExpectEncodedSizeInBytes(size);
}
VCDiffAddressCache cache_;
string address_stream_;
const char* decode_position_;
const char* decode_position_end_;
string large_address_stream_;
std::vector<unsigned char> mode_stream_;
std::vector<VCDAddress> verify_stream_;
private:
const char* verify_encode_position_;
string::size_type last_encode_size_;
const char* last_decode_position_;
};
#ifdef GTEST_HAS_DEATH_TEST
// This synonym is needed for the tests that use ASSERT_DEATH
typedef VCDiffAddressCacheTest VCDiffAddressCacheDeathTest;
#endif // GTEST_HAS_DEATH_TEST
// Having either or both cache size == 0 is acceptable
TEST_F(VCDiffAddressCacheTest, ZeroCacheSizes) {
VCDiffAddressCache zero_cache(0, 0);
EXPECT_TRUE(zero_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, NegativeCacheSizes) {
VCDiffAddressCache negative_cache(-1, -1); // The constructor must not fail
EXPECT_FALSE(negative_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, OnlySameCacheSizeIsNegative) {
VCDiffAddressCache negative_cache(0, -1); // The constructor must not fail
EXPECT_FALSE(negative_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, ExtremePositiveCacheSizes) {
// The constructor must not fail
VCDiffAddressCache int_max_cache(INT_MAX, INT_MAX);
EXPECT_FALSE(int_max_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, ExtremeNegativeCacheSizes) {
// The constructor must not fail
VCDiffAddressCache int_min_cache(INT_MIN, INT_MIN);
EXPECT_FALSE(int_min_cache.Init());
}
// VCD_MAX_MODES is the maximum number of modes, including SAME and HERE modes.
// So neither the SAME cache nor the HERE cache can be larger than
// (VCD_MAX_MODES - 2).
TEST_F(VCDiffAddressCacheTest, NearCacheSizeIsTooBig) {
VCDiffAddressCache negative_cache(VCD_MAX_MODES - 1, 0);
EXPECT_FALSE(negative_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, SameCacheSizeIsTooBig) {
VCDiffAddressCache negative_cache(0, VCD_MAX_MODES - 1);
EXPECT_FALSE(negative_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, CombinedSizesAreTooBig) {
VCDiffAddressCache negative_cache((VCD_MAX_MODES / 2),
(VCD_MAX_MODES / 2) - 1);
EXPECT_FALSE(negative_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, MaxLegalNearCacheSize) {
VCDiffAddressCache negative_cache(VCD_MAX_MODES - 2, 0);
EXPECT_TRUE(negative_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, MaxLegalSameCacheSize) {
VCDiffAddressCache negative_cache(0, VCD_MAX_MODES - 2);
EXPECT_TRUE(negative_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, MaxLegalCombinedSizes) {
VCDiffAddressCache negative_cache((VCD_MAX_MODES / 2) - 1,
(VCD_MAX_MODES / 2) - 1);
EXPECT_TRUE(negative_cache.Init());
}
TEST_F(VCDiffAddressCacheTest, DestroyWithoutInitialization) {
VCDiffAddressCache no_init_cache(4, 3);
// Should be destroyed without crashing
}
TEST_F(VCDiffAddressCacheTest, DestroyDefaultWithoutInitialization) {
VCDiffAddressCache no_init_cache;
// Should be destroyed without crashing
}
TEST_F(VCDiffAddressCacheTest, CacheContentsInitiallyZero) {
VCDAddress test_address = 0;
// Check that caches are initially set to zero
for (test_address = 0; test_address < 4; ++test_address) {
EXPECT_EQ(0, cache_.NearAddress(test_address));
}
for (test_address = 0; test_address < 256 * 3; ++test_address) {
EXPECT_EQ(0, cache_.SameAddress(test_address));
}
}
// Inserts values 1, 2, ... , 10 into the cache and tests its entire
// contents for consistency.
//
TEST_F(VCDiffAddressCacheTest, InsertFirstTen) {
VCDAddress test_address = 0;
for (test_address = 1; test_address <= 10; ++test_address) {
cache_.UpdateCache(test_address);
}
EXPECT_EQ(9, cache_.NearAddress(0)); // slot 0: 1 => 5 => 9
EXPECT_EQ(10, cache_.NearAddress(1)); // slot 1: 2 => 6 => 10
EXPECT_EQ(7, cache_.NearAddress(2)); // slot 2: 3 => 7
EXPECT_EQ(8, cache_.NearAddress(3)); // slot 3: 4 => 8
EXPECT_EQ(0, cache_.SameAddress(0));
for (test_address = 1; test_address <= 10; ++test_address) {
EXPECT_EQ(test_address, cache_.SameAddress(test_address));
}
for (test_address = 11; test_address < 256 * 3; ++test_address) {
EXPECT_EQ(0, cache_.SameAddress(test_address));
}
}
TEST_F(VCDiffAddressCacheTest, InsertIntMax) {
cache_.UpdateCache(INT_MAX);
EXPECT_EQ(INT_MAX, cache_.NearAddress(0));
EXPECT_EQ(INT_MAX, cache_.SameAddress(INT_MAX % (256 * 3)));
EXPECT_EQ(0, cache_.SameAddress((INT_MAX - 256) % (256 * 3)));
EXPECT_EQ(0, cache_.SameAddress((INT_MAX - 512) % (256 * 3)));
}
// Exercises all four addressing mode types by encoding five values
// with EncodeAddress.
// Checks to see that the proper mode was selected in each case,
// and that the encoding is correct.
//
TEST_F(VCDiffAddressCacheTest, EncodeAddressModes) {
TestEncode(0x0000FFFF, 0x10000000, VCD_SELF_MODE, 3);
TestEncode(0x10000000, 0x10000010, VCD_HERE_MODE, 1);
TestEncode(0x10000004, 0x10000020, cache_.FirstNearMode() + 0x01, 1);
TestEncode(0x0FFFFFFE, 0x10000030, VCD_HERE_MODE, 1);
TestEncode(0x10000004, 0x10000040, cache_.FirstSameMode() + 0x01, 1);
ExpectEncodedVarint(0xFFFF, 3); // SELF mode: addr 0x0000FFFF
ExpectEncodedVarint(0x10, 1); // HERE mode: here - 0x10 = 0x10000000
ExpectEncodedVarint(0x04, 1); // NEAR cache #1:
// last addr + 0x4 = 0x10000004
ExpectEncodedVarint(0x32, 1); // HERE mode: here - 0x32 = 0x0FFFFFFE
ExpectEncodedByte(0x04); // SAME cache #1: 0x10000004 hits
}
// Exercises all four addressing mode types by manually encoding six values
// and calling DecodeAddress on each one.
//
TEST_F(VCDiffAddressCacheTest, DecodeAddressModes) {
ManualEncodeVarint(0xCAFE);
ManualEncodeVarint(0xCAFE);
ManualEncodeVarint(0x1000);
ManualEncodeByte(0xFE); // SAME mode uses a byte, not a Varint
ManualEncodeVarint(0xFE);
ManualEncodeVarint(0x1000);
BeginDecode();
EXPECT_EQ(0xCAFE,
cache_.DecodeAddress(0x10000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0xCAFE));
EXPECT_EQ(0x20000 - 0xCAFE,
cache_.DecodeAddress(0x20000,
VCD_HERE_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0xCAFE));
EXPECT_EQ(0xDAFE,
cache_.DecodeAddress(0x30000,
cache_.FirstNearMode(),
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0x1000));
EXPECT_EQ(0xCAFE,
cache_.DecodeAddress(0x40000,
cache_.FirstSameMode() + (0xCA % 3),
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(sizeof(unsigned char)); // a byte, not a Varint
EXPECT_EQ(0xFE,
cache_.DecodeAddress(0x50000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0xFE));
// NEAR mode #0 has been overwritten by fifth computed addr (wrap around)
EXPECT_EQ(0x10FE,
cache_.DecodeAddress(0x60000,
cache_.FirstNearMode(),
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0x1000));
}
// Test with both cache sizes == 0. The encoder should not choose
// a SAME or NEAR mode under these conditions.
TEST_F(VCDiffAddressCacheTest, EncodeAddressZeroCacheSizes) {
VCDAddress encoded_addr = 0;
VCDiffAddressCache zero_cache(0, 0);
EXPECT_TRUE(zero_cache.Init());
EXPECT_EQ(VCD_SELF_MODE,
zero_cache.EncodeAddress(0x0000FFFF, 0x10000000, &encoded_addr));
EXPECT_EQ(0xFFFF, encoded_addr);
EXPECT_EQ(VCD_HERE_MODE,
zero_cache.EncodeAddress(0x10000000, 0x10000010, &encoded_addr));
EXPECT_EQ(0x10, encoded_addr);
EXPECT_EQ(VCD_HERE_MODE,
zero_cache.EncodeAddress(0x10000004, 0x10000020, &encoded_addr));
EXPECT_EQ(0x1C, encoded_addr);
EXPECT_EQ(VCD_HERE_MODE,
zero_cache.EncodeAddress(0x0FFFFFFE, 0x10000030, &encoded_addr));
EXPECT_EQ(0x32, encoded_addr);
EXPECT_EQ(VCD_HERE_MODE,
zero_cache.EncodeAddress(0x10000004, 0x10000040, &encoded_addr));
EXPECT_EQ(0x3C, encoded_addr);
}
TEST_F(VCDiffAddressCacheTest, DecodeAddressZeroCacheSizes) {
VCDiffAddressCache zero_cache(0, 0);
EXPECT_TRUE(zero_cache.Init());
ManualEncodeVarint(0xCAFE);
ManualEncodeVarint(0xCAFE);
ManualEncodeVarint(0xDAFE);
BeginDecode();
EXPECT_EQ(0xCAFE, zero_cache.DecodeAddress(0x10000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0xCAFE));
EXPECT_EQ(0x20000 - 0xCAFE, zero_cache.DecodeAddress(0x20000,
VCD_HERE_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0xCAFE));
EXPECT_EQ(0xDAFE, zero_cache.DecodeAddress(0x30000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0xDAFE));
}
#ifdef GTEST_HAS_DEATH_TEST
TEST_F(VCDiffAddressCacheDeathTest, EncodeNegativeAddress) {
VCDAddress dummy_encoded_address = 0;
EXPECT_DEBUG_DEATH(cache_.EncodeAddress(-1, -1, &dummy_encoded_address),
"negative");
}
TEST_F(VCDiffAddressCacheDeathTest, EncodeAddressPastHereAddress) {
VCDAddress dummy_encoded_address = 0;
EXPECT_DEBUG_DEATH(cache_.EncodeAddress(0x100, 0x100, &dummy_encoded_address),
"address.*<.*here_address");
EXPECT_DEBUG_DEATH(cache_.EncodeAddress(0x200, 0x100, &dummy_encoded_address),
"address.*<.*here_address");
}
TEST_F(VCDiffAddressCacheDeathTest, DecodeInvalidMode) {
ManualEncodeVarint(0xCAFE);
BeginDecode();
EXPECT_DEBUG_DEATH(EXPECT_EQ(RESULT_ERROR,
cache_.DecodeAddress(0x10000000,
cache_.LastMode() + 1,
&decode_position_,
decode_position_end_)),
"mode");
EXPECT_DEBUG_DEATH(EXPECT_EQ(RESULT_ERROR,
cache_.DecodeAddress(0x10000000,
0xFF,
&decode_position_,
decode_position_end_)),
"mode");
ExpectDecodedSizeInBytes(0); // Should not modify decode_position_
}
TEST_F(VCDiffAddressCacheDeathTest, DecodeZeroOrNegativeHereAddress) {
ManualEncodeVarint(0xCAFE);
ManualEncodeVarint(0xCAFE);
BeginDecode();
// Using a Debug build, the check will fail; using a Release build,
// the check will not occur, and the SELF mode does not depend on
// the value of here_address, so DecodeAddress() will succeed.
EXPECT_DEBUG_DEATH(cache_.DecodeAddress(-1,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_),
"negative");
// A zero value for here_address should not kill the decoder,
// but instead should return an error value. A delta file may contain
// a window that has no source segment and that (erroneously)
// uses a COPY instruction as its first instruction. This should
// cause an error to be reported, not a debug check failure.
EXPECT_EQ(RESULT_ERROR, cache_.DecodeAddress(0,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
}
#endif // GTEST_HAS_DEATH_TEST
TEST_F(VCDiffAddressCacheTest, DecodeAddressPastHereAddress) {
ManualEncodeVarint(0xCAFE);
BeginDecode();
EXPECT_EQ(RESULT_ERROR, cache_.DecodeAddress(0x1000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(0); // Should not modify decode_position_
}
TEST_F(VCDiffAddressCacheTest, HereModeAddressTooLarge) {
ManualEncodeVarint(0x10001); // here_address + 1
BeginDecode();
EXPECT_EQ(RESULT_ERROR, cache_.DecodeAddress(0x10000,
VCD_HERE_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(0); // Should not modify decode_position_
}
TEST_F(VCDiffAddressCacheTest, NearModeAddressOverflow) {
ManualEncodeVarint(0xCAFE);
ManualEncodeVarint(0x7FFFFFFF);
BeginDecode();
EXPECT_EQ(0xCAFE, cache_.DecodeAddress(0x10000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0xCAFE));
// Now decode a NEAR mode address of base address 0xCAFE
// (the first decoded address) + offset 0x7FFFFFFF. This will cause
// an integer overflow and should signal an error.
EXPECT_EQ(RESULT_ERROR, cache_.DecodeAddress(0x10000000,
cache_.FirstNearMode(),
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(0); // Should not modify decode_position_
}
// A Varint should contain at most 9 bytes that have their continuation bit
// (the uppermost, or 7 bit) set. A longer string of bytes that all have
// bit 7 set is not a valid Varint. Try to parse such a string as a Varint
// and confirm that it does not run off the end of the input buffer and
// it returns an error value (RESULT_ERROR).
//
TEST_F(VCDiffAddressCacheTest, DecodeInvalidVarint) {
address_stream_.clear();
// Write 512 0xFE bytes
address_stream_.append(512, static_cast<char>(0xFE));
BeginDecode();
EXPECT_EQ(RESULT_ERROR, cache_.DecodeAddress(0x10000000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(0); // Should not modify decode_position_
}
// If only part of a Varint appears in the data to be decoded,
// then DecodeAddress should return RESULT_END_OF_DATA,
// which means that the Varint *may* be valid if there is more
// data expected to be returned.
//
TEST_F(VCDiffAddressCacheTest, DecodePartialVarint) {
address_stream_.clear();
ManualEncodeByte(0xFE);
ManualEncodeByte(0xFE);
ManualEncodeByte(0xFE);
BeginDecode();
EXPECT_EQ(RESULT_END_OF_DATA,
cache_.DecodeAddress(0x10000000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(0); // Should not modify decode_position_
// Now add the missing last byte (supposedly read from a stream of data)
// and verify that the Varint is now valid.
ManualEncodeByte(0x01); // End the Varint with an additional byte
BeginDecode(); // Reset read position to start of data
EXPECT_EQ(0xFDFBF01,
cache_.DecodeAddress(0x10000000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(4); // ManualEncodeByte was called for 4 byte values
}
#ifdef GTEST_HAS_DEATH_TEST
TEST_F(VCDiffAddressCacheDeathTest, DecodeBadMode) {
ManualEncodeVarint(0xCAFE);
BeginDecode();
EXPECT_DEBUG_DEATH(EXPECT_EQ(RESULT_ERROR,
cache_.DecodeAddress(0x10000,
cache_.LastMode() + 1,
&decode_position_,
decode_position_end_)),
"maximum");
ExpectDecodedSizeInBytes(0);
}
#endif // GTEST_HAS_DEATH_TEST
TEST_F(VCDiffAddressCacheTest, DecodeInvalidHereAddress) {
ManualEncodeVarint(0x10001); // offset larger than here_address
BeginDecode();
EXPECT_EQ(RESULT_ERROR, cache_.DecodeAddress(0x10000,
VCD_HERE_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(0);
}
TEST_F(VCDiffAddressCacheTest, DecodeInvalidNearAddress) {
ManualEncodeVarint(0xCAFE);
ManualEncodeVarint(INT_MAX); // offset will cause integer overflow
BeginDecode();
EXPECT_EQ(0xCAFE,
cache_.DecodeAddress(0x10000,
VCD_SELF_MODE,
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(VarintBE<VCDAddress>::Length(0xCAFE));
EXPECT_EQ(RESULT_ERROR, cache_.DecodeAddress(0x10000,
cache_.FirstNearMode(),
&decode_position_,
decode_position_end_));
ExpectDecodedSizeInBytes(0);
}
void VCDiffAddressCacheTest::BM_Setup(int test_size) {
mode_stream_.resize(test_size);
verify_stream_.resize(test_size);
VCDAddress here_address = 1;
srand(1);
for (int i = 0; i < test_size; ++i) {
verify_stream_[i] = PortableRandomInRange(here_address - 1);
here_address += 4;
}
BM_CacheEncode(1, test_size); // populate large_address_stream_, mode_stream_
}
void VCDiffAddressCacheTest::BM_CacheEncode(int iterations, int test_size) {
VCDAddress here_address = 1;
VCDAddress encoded_addr = 0;
for (int test_iteration = 0; test_iteration < iterations; ++test_iteration) {
cache_.Init();
large_address_stream_.clear();
here_address = 1;
for (int i = 0; i < test_size; ++i) {
const unsigned char mode = cache_.EncodeAddress(verify_stream_[i],
here_address,
&encoded_addr);
if (cache_.WriteAddressAsVarintForMode(mode)) {
VarintBE<VCDAddress>::AppendToString(encoded_addr,
&large_address_stream_);
} else {
EXPECT_GT(256, encoded_addr);
large_address_stream_.push_back(
static_cast<unsigned char>(encoded_addr));
}
mode_stream_[i] = mode;
here_address += 4;
}
}
}
void VCDiffAddressCacheTest::BM_CacheDecode(int iterations, int test_size) {
VCDAddress here_address = 1;
for (int test_iteration = 0; test_iteration < iterations; ++test_iteration) {
cache_.Init();
const char* large_decode_pointer = large_address_stream_.data();
const char* const end_of_encoded_data =
large_decode_pointer + large_address_stream_.size();
here_address = 1;
for (int i = 0; i < test_size; ++i) {
EXPECT_EQ(verify_stream_[i],
cache_.DecodeAddress(here_address,
mode_stream_[i],
&large_decode_pointer,
end_of_encoded_data));
here_address += 4;
}
EXPECT_EQ(end_of_encoded_data, large_decode_pointer);
}
}
TEST_F(VCDiffAddressCacheTest, PerformanceTest) {
const int test_size = 20 * 1024; // 20K random encode/decode operations
const int num_iterations = 40; // run test 40 times and take average
BM_Setup(test_size);
{
CycleTimer encode_timer;
encode_timer.Start();
BM_CacheEncode(num_iterations, test_size);
encode_timer.Stop();
double encode_time_in_ms =
static_cast<double>(encode_timer.GetInUsec()) / 1000;
std::cout << "Time to encode: "
<< (encode_time_in_ms / num_iterations) << " ms" << std::endl;
}
{
CycleTimer decode_timer;
decode_timer.Start();
BM_CacheDecode(num_iterations, test_size);
decode_timer.Stop();
double decode_time_in_ms =
static_cast<double>(decode_timer.GetInUsec()) / 1000;
std::cout << "Time to decode: "
<< (decode_time_in_ms / num_iterations) << " ms" << std::endl;
}
}
} // unnamed namespace
} // namespace open_vcdiff