// Copyright (c) 2010 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 "net/base/host_cache.h"
#include "base/format_macros.h"
#include "base/stl_util-inl.h"
#include "base/string_util.h"
#include "base/stringprintf.h"
#include "net/base/net_errors.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace net {
namespace {
const int kMaxCacheEntries = 10;
const base::TimeDelta kSuccessEntryTTL = base::TimeDelta::FromSeconds(10);
const base::TimeDelta kFailureEntryTTL = base::TimeDelta::FromSeconds(0);
// Builds a key for |hostname|, defaulting the address family to unspecified.
HostCache::Key Key(const std::string& hostname) {
return HostCache::Key(hostname, ADDRESS_FAMILY_UNSPECIFIED, 0);
}
} // namespace
TEST(HostCacheTest, Basic) {
HostCache cache(kMaxCacheEntries, kSuccessEntryTTL, kFailureEntryTTL);
// Start at t=0.
base::TimeTicks now;
const HostCache::Entry* entry1 = NULL; // Entry for foobar.com.
const HostCache::Entry* entry2 = NULL; // Entry for foobar2.com.
EXPECT_EQ(0U, cache.size());
// Add an entry for "foobar.com" at t=0.
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), base::TimeTicks()) == NULL);
cache.Set(Key("foobar.com"), OK, AddressList(), now);
entry1 = cache.Lookup(Key("foobar.com"), base::TimeTicks());
EXPECT_FALSE(entry1 == NULL);
EXPECT_EQ(1U, cache.size());
// Advance to t=5.
now += base::TimeDelta::FromSeconds(5);
// Add an entry for "foobar2.com" at t=5.
EXPECT_TRUE(cache.Lookup(Key("foobar2.com"), base::TimeTicks()) == NULL);
cache.Set(Key("foobar2.com"), OK, AddressList(), now);
entry2 = cache.Lookup(Key("foobar2.com"), base::TimeTicks());
EXPECT_FALSE(NULL == entry1);
EXPECT_EQ(2U, cache.size());
// Advance to t=9
now += base::TimeDelta::FromSeconds(4);
// Verify that the entries we added are still retrievable, and usable.
EXPECT_EQ(entry1, cache.Lookup(Key("foobar.com"), now));
EXPECT_EQ(entry2, cache.Lookup(Key("foobar2.com"), now));
// Advance to t=10; entry1 is now expired.
now += base::TimeDelta::FromSeconds(1);
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), now) == NULL);
EXPECT_EQ(entry2, cache.Lookup(Key("foobar2.com"), now));
// Update entry1, so it is no longer expired.
cache.Set(Key("foobar.com"), OK, AddressList(), now);
// Re-uses existing entry storage.
EXPECT_EQ(entry1, cache.Lookup(Key("foobar.com"), now));
EXPECT_EQ(2U, cache.size());
// Both entries should still be retrievable and usable.
EXPECT_EQ(entry1, cache.Lookup(Key("foobar.com"), now));
EXPECT_EQ(entry2, cache.Lookup(Key("foobar2.com"), now));
// Advance to t=20; both entries are now expired.
now += base::TimeDelta::FromSeconds(10);
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), now) == NULL);
EXPECT_TRUE(cache.Lookup(Key("foobar2.com"), now) == NULL);
}
// Try caching entries for a failed resolve attempt -- since we set
// the TTL of such entries to 0 it won't work.
TEST(HostCacheTest, NoCacheNegative) {
HostCache cache(kMaxCacheEntries, kSuccessEntryTTL, kFailureEntryTTL);
// Set t=0.
base::TimeTicks now;
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), base::TimeTicks()) == NULL);
cache.Set(Key("foobar.com"), ERR_NAME_NOT_RESOLVED, AddressList(), now);
EXPECT_EQ(1U, cache.size());
// We disallow use of negative entries.
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), now) == NULL);
// Now overwrite with a valid entry, and then overwrite with negative entry
// again -- the valid entry should be kicked out.
cache.Set(Key("foobar.com"), OK, AddressList(), now);
EXPECT_FALSE(cache.Lookup(Key("foobar.com"), now) == NULL);
cache.Set(Key("foobar.com"), ERR_NAME_NOT_RESOLVED, AddressList(), now);
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), now) == NULL);
}
// Try caching entries for a failed resolves for 10 seconds.
TEST(HostCacheTest, CacheNegativeEntry) {
HostCache cache(kMaxCacheEntries,
base::TimeDelta::FromSeconds(0), // success entry TTL.
base::TimeDelta::FromSeconds(10)); // failure entry TTL.
// Start at t=0.
base::TimeTicks now;
const HostCache::Entry* entry1 = NULL; // Entry for foobar.com.
const HostCache::Entry* entry2 = NULL; // Entry for foobar2.com.
EXPECT_EQ(0U, cache.size());
// Add an entry for "foobar.com" at t=0.
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), base::TimeTicks()) == NULL);
cache.Set(Key("foobar.com"), ERR_NAME_NOT_RESOLVED, AddressList(), now);
entry1 = cache.Lookup(Key("foobar.com"), base::TimeTicks());
EXPECT_FALSE(entry1 == NULL);
EXPECT_EQ(1U, cache.size());
// Advance to t=5.
now += base::TimeDelta::FromSeconds(5);
// Add an entry for "foobar2.com" at t=5.
EXPECT_TRUE(cache.Lookup(Key("foobar2.com"), base::TimeTicks()) == NULL);
cache.Set(Key("foobar2.com"), ERR_NAME_NOT_RESOLVED, AddressList(), now);
entry2 = cache.Lookup(Key("foobar2.com"), base::TimeTicks());
EXPECT_FALSE(NULL == entry1);
EXPECT_EQ(2U, cache.size());
// Advance to t=9
now += base::TimeDelta::FromSeconds(4);
// Verify that the entries we added are still retrievable, and usable.
EXPECT_EQ(entry1, cache.Lookup(Key("foobar.com"), now));
EXPECT_EQ(entry2, cache.Lookup(Key("foobar2.com"), now));
// Advance to t=10; entry1 is now expired.
now += base::TimeDelta::FromSeconds(1);
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), now) == NULL);
EXPECT_EQ(entry2, cache.Lookup(Key("foobar2.com"), now));
// Update entry1, so it is no longer expired.
cache.Set(Key("foobar.com"), ERR_NAME_NOT_RESOLVED, AddressList(), now);
// Re-uses existing entry storage.
EXPECT_EQ(entry1, cache.Lookup(Key("foobar.com"), now));
EXPECT_EQ(2U, cache.size());
// Both entries should still be retrievable and usable.
EXPECT_EQ(entry1, cache.Lookup(Key("foobar.com"), now));
EXPECT_EQ(entry2, cache.Lookup(Key("foobar2.com"), now));
// Advance to t=20; both entries are now expired.
now += base::TimeDelta::FromSeconds(10);
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), now) == NULL);
EXPECT_TRUE(cache.Lookup(Key("foobar2.com"), now) == NULL);
}
TEST(HostCacheTest, Compact) {
// Initial entries limit is big enough to accomadate everything we add.
HostCache cache(kMaxCacheEntries, kSuccessEntryTTL, kFailureEntryTTL);
EXPECT_EQ(0U, cache.size());
// t=10
base::TimeTicks now = base::TimeTicks() + base::TimeDelta::FromSeconds(10);
// Add five valid entries at t=10.
for (int i = 0; i < 5; ++i) {
std::string hostname = base::StringPrintf("valid%d", i);
cache.Set(Key(hostname), OK, AddressList(), now);
}
EXPECT_EQ(5U, cache.size());
// Add 3 expired entries at t=0.
for (int i = 0; i < 3; ++i) {
std::string hostname = base::StringPrintf("expired%d", i);
base::TimeTicks t = now - base::TimeDelta::FromSeconds(10);
cache.Set(Key(hostname), OK, AddressList(), t);
}
EXPECT_EQ(8U, cache.size());
// Add 2 negative entries at t=10
for (int i = 0; i < 2; ++i) {
std::string hostname = base::StringPrintf("negative%d", i);
cache.Set(Key(hostname), ERR_NAME_NOT_RESOLVED, AddressList(), now);
}
EXPECT_EQ(10U, cache.size());
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid0")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid1")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid2")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid3")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid4")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("expired0")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("expired1")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("expired2")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("negative0")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("negative1")));
// Shrink the max constraints bound and compact. We expect the "negative"
// and "expired" entries to have been dropped.
cache.max_entries_ = 5;
cache.Compact(now, NULL);
EXPECT_EQ(5U, cache.entries_.size());
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid0")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid1")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid2")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid3")));
EXPECT_TRUE(ContainsKey(cache.entries_, Key("valid4")));
EXPECT_FALSE(ContainsKey(cache.entries_, Key("expired0")));
EXPECT_FALSE(ContainsKey(cache.entries_, Key("expired1")));
EXPECT_FALSE(ContainsKey(cache.entries_, Key("expired2")));
EXPECT_FALSE(ContainsKey(cache.entries_, Key("negative0")));
EXPECT_FALSE(ContainsKey(cache.entries_, Key("negative1")));
// Shrink further -- this time the compact will start dropping valid entries
// to make space.
cache.max_entries_ = 3;
cache.Compact(now, NULL);
EXPECT_EQ(3U, cache.size());
}
// Add entries while the cache is at capacity, causing evictions.
TEST(HostCacheTest, SetWithCompact) {
HostCache cache(3, kSuccessEntryTTL, kFailureEntryTTL);
// t=10
base::TimeTicks now = base::TimeTicks() + kSuccessEntryTTL;
cache.Set(Key("host1"), OK, AddressList(), now);
cache.Set(Key("host2"), OK, AddressList(), now);
cache.Set(Key("expired"), OK, AddressList(), now - kSuccessEntryTTL);
EXPECT_EQ(3U, cache.size());
// Should all be retrievable except "expired".
EXPECT_FALSE(NULL == cache.Lookup(Key("host1"), now));
EXPECT_FALSE(NULL == cache.Lookup(Key("host2"), now));
EXPECT_TRUE(NULL == cache.Lookup(Key("expired"), now));
// Adding the fourth entry will cause "expired" to be evicted.
cache.Set(Key("host3"), OK, AddressList(), now);
EXPECT_EQ(3U, cache.size());
EXPECT_TRUE(cache.Lookup(Key("expired"), now) == NULL);
EXPECT_FALSE(cache.Lookup(Key("host1"), now) == NULL);
EXPECT_FALSE(cache.Lookup(Key("host2"), now) == NULL);
EXPECT_FALSE(cache.Lookup(Key("host3"), now) == NULL);
// Add two more entries. Something should be evicted, however "host5"
// should definitely be in there (since it was last inserted).
cache.Set(Key("host4"), OK, AddressList(), now);
EXPECT_EQ(3U, cache.size());
cache.Set(Key("host5"), OK, AddressList(), now);
EXPECT_EQ(3U, cache.size());
EXPECT_FALSE(cache.Lookup(Key("host5"), now) == NULL);
}
// Tests that the same hostname can be duplicated in the cache, so long as
// the address family differs.
TEST(HostCacheTest, AddressFamilyIsPartOfKey) {
HostCache cache(kMaxCacheEntries, kSuccessEntryTTL, kFailureEntryTTL);
// t=0.
base::TimeTicks now;
HostCache::Key key1("foobar.com", ADDRESS_FAMILY_UNSPECIFIED, 0);
HostCache::Key key2("foobar.com", ADDRESS_FAMILY_IPV4, 0);
const HostCache::Entry* entry1 = NULL; // Entry for key1
const HostCache::Entry* entry2 = NULL; // Entry for key2
EXPECT_EQ(0U, cache.size());
// Add an entry for ("foobar.com", UNSPECIFIED) at t=0.
EXPECT_TRUE(cache.Lookup(key1, base::TimeTicks()) == NULL);
cache.Set(key1, OK, AddressList(), now);
entry1 = cache.Lookup(key1, base::TimeTicks());
EXPECT_FALSE(entry1 == NULL);
EXPECT_EQ(1U, cache.size());
// Add an entry for ("foobar.com", IPV4_ONLY) at t=0.
EXPECT_TRUE(cache.Lookup(key2, base::TimeTicks()) == NULL);
cache.Set(key2, OK, AddressList(), now);
entry2 = cache.Lookup(key2, base::TimeTicks());
EXPECT_FALSE(entry2 == NULL);
EXPECT_EQ(2U, cache.size());
// Even though the hostnames were the same, we should have two unique
// entries (because the address families differ).
EXPECT_NE(entry1, entry2);
}
// Tests that the same hostname can be duplicated in the cache, so long as
// the HostResolverFlags differ.
TEST(HostCacheTest, HostResolverFlagsArePartOfKey) {
HostCache cache(kMaxCacheEntries, kSuccessEntryTTL, kFailureEntryTTL);
// t=0.
base::TimeTicks now;
HostCache::Key key1("foobar.com", ADDRESS_FAMILY_IPV4, 0);
HostCache::Key key2("foobar.com", ADDRESS_FAMILY_IPV4,
HOST_RESOLVER_CANONNAME);
HostCache::Key key3("foobar.com", ADDRESS_FAMILY_IPV4,
HOST_RESOLVER_LOOPBACK_ONLY);
const HostCache::Entry* entry1 = NULL; // Entry for key1
const HostCache::Entry* entry2 = NULL; // Entry for key2
const HostCache::Entry* entry3 = NULL; // Entry for key3
EXPECT_EQ(0U, cache.size());
// Add an entry for ("foobar.com", IPV4, NONE) at t=0.
EXPECT_TRUE(cache.Lookup(key1, base::TimeTicks()) == NULL);
cache.Set(key1, OK, AddressList(), now);
entry1 = cache.Lookup(key1, base::TimeTicks());
EXPECT_FALSE(entry1 == NULL);
EXPECT_EQ(1U, cache.size());
// Add an entry for ("foobar.com", IPV4, CANONNAME) at t=0.
EXPECT_TRUE(cache.Lookup(key2, base::TimeTicks()) == NULL);
cache.Set(key2, OK, AddressList(), now);
entry2 = cache.Lookup(key2, base::TimeTicks());
EXPECT_FALSE(entry2 == NULL);
EXPECT_EQ(2U, cache.size());
// Add an entry for ("foobar.com", IPV4, LOOPBACK_ONLY) at t=0.
EXPECT_TRUE(cache.Lookup(key3, base::TimeTicks()) == NULL);
cache.Set(key3, OK, AddressList(), now);
entry3 = cache.Lookup(key3, base::TimeTicks());
EXPECT_FALSE(entry3 == NULL);
EXPECT_EQ(3U, cache.size());
// Even though the hostnames were the same, we should have two unique
// entries (because the HostResolverFlags differ).
EXPECT_NE(entry1, entry2);
EXPECT_NE(entry1, entry3);
EXPECT_NE(entry2, entry3);
}
TEST(HostCacheTest, NoCache) {
// Disable caching.
HostCache cache(0, kSuccessEntryTTL, kFailureEntryTTL);
EXPECT_TRUE(cache.caching_is_disabled());
// Set t=0.
base::TimeTicks now;
// Lookup and Set should have no effect.
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), base::TimeTicks()) == NULL);
cache.Set(Key("foobar.com"), OK, AddressList(), now);
EXPECT_TRUE(cache.Lookup(Key("foobar.com"), base::TimeTicks()) == NULL);
EXPECT_EQ(0U, cache.size());
}
TEST(HostCacheTest, Clear) {
HostCache cache(kMaxCacheEntries, kSuccessEntryTTL, kFailureEntryTTL);
// Set t=0.
base::TimeTicks now;
EXPECT_EQ(0u, cache.size());
// Add three entries.
cache.Set(Key("foobar1.com"), OK, AddressList(), now);
cache.Set(Key("foobar2.com"), OK, AddressList(), now);
cache.Set(Key("foobar3.com"), OK, AddressList(), now);
EXPECT_EQ(3u, cache.size());
cache.clear();
EXPECT_EQ(0u, cache.size());
}
// Tests the less than and equal operators for HostCache::Key work.
TEST(HostCacheTest, KeyComparators) {
struct {
// Inputs.
HostCache::Key key1;
HostCache::Key key2;
// Expectation.
// -1 means key1 is less than key2
// 0 means key1 equals key2
// 1 means key1 is greater than key2
int expected_comparison;
} tests[] = {
{
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED, 0),
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED, 0),
0
},
{
HostCache::Key("host1", ADDRESS_FAMILY_IPV4, 0),
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED, 0),
1
},
{
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED, 0),
HostCache::Key("host1", ADDRESS_FAMILY_IPV4, 0),
-1
},
{
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED, 0),
HostCache::Key("host2", ADDRESS_FAMILY_UNSPECIFIED, 0),
-1
},
{
HostCache::Key("host1", ADDRESS_FAMILY_IPV4, 0),
HostCache::Key("host2", ADDRESS_FAMILY_UNSPECIFIED, 0),
1
},
{
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED, 0),
HostCache::Key("host2", ADDRESS_FAMILY_IPV4, 0),
-1
},
{
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED, 0),
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED,
HOST_RESOLVER_CANONNAME),
-1
},
{
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED,
HOST_RESOLVER_CANONNAME),
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED, 0),
1
},
{
HostCache::Key("host1", ADDRESS_FAMILY_UNSPECIFIED,
HOST_RESOLVER_CANONNAME),
HostCache::Key("host2", ADDRESS_FAMILY_UNSPECIFIED,
HOST_RESOLVER_CANONNAME),
-1
},
};
for (size_t i = 0; i < ARRAYSIZE_UNSAFE(tests); ++i) {
SCOPED_TRACE(base::StringPrintf("Test[%" PRIuS "]", i));
const HostCache::Key& key1 = tests[i].key1;
const HostCache::Key& key2 = tests[i].key2;
switch (tests[i].expected_comparison) {
case -1:
EXPECT_TRUE(key1 < key2);
EXPECT_FALSE(key2 < key1);
EXPECT_FALSE(key2 == key1);
break;
case 0:
EXPECT_FALSE(key1 < key2);
EXPECT_FALSE(key2 < key1);
EXPECT_TRUE(key2 == key1);
break;
case 1:
EXPECT_FALSE(key1 < key2);
EXPECT_TRUE(key2 < key1);
EXPECT_FALSE(key2 == key1);
break;
default:
FAIL() << "Invalid expectation. Can be only -1, 0, 1";
}
}
}
} // namespace net