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chromium / chromium / src / efc9bd87274e3647537fc22f93f49022edde4e71 / . / net / base / host_resolver_impl_unittest.cc
blob: 3d7e02a353055c3dca7414bb2d5e31cca0f94dca [file] [log] [blame]
// 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_resolver_impl.h"
#include <string>
#include "base/compiler_specific.h"
#include "base/message_loop.h"
#include "base/ref_counted.h"
#include "base/string_util.h"
#include "net/base/address_list.h"
#include "net/base/completion_callback.h"
#include "net/base/mock_host_resolver.h"
#include "net/base/mock_network_change_notifier.h"
#include "net/base/net_errors.h"
#include "net/base/net_log_unittest.h"
#include "net/base/net_util.h"
#include "net/base/sys_addrinfo.h"
#include "net/base/test_completion_callback.h"
#include "testing/gtest/include/gtest/gtest.h"
// TODO(eroman):
// - Test mixing async with sync (in particular how does sync update the
// cache while an async is already pending).
namespace net {
namespace {
HostCache* CreateDefaultCache() {
return new HostCache(
100, // max cache entries.
base::TimeDelta::FromMinutes(1),
base::TimeDelta::FromSeconds(0));
}
static const size_t kMaxJobs = 10u;
HostResolverImpl* CreateHostResolverImpl(HostResolverProc* resolver_proc) {
return new HostResolverImpl(
resolver_proc,
CreateDefaultCache(),
NULL, // network_change_notifier
kMaxJobs);
}
// Helper to create a HostResolver::RequestInfo.
HostResolver::RequestInfo CreateResolverRequest(
const std::string& hostname,
RequestPriority priority) {
HostResolver::RequestInfo info(hostname, 80);
info.set_priority(priority);
return info;
}
// Helper to create a HostResolver::RequestInfo.
HostResolver::RequestInfo CreateResolverRequestForAddressFamily(
const std::string& hostname,
RequestPriority priority,
AddressFamily address_family) {
HostResolver::RequestInfo info(hostname, 80);
info.set_priority(priority);
info.set_address_family(address_family);
return info;
}
// A variant of WaitingHostResolverProc that pushes each host mapped into a
// list.
// (and uses a manual-reset event rather than auto-reset).
class CapturingHostResolverProc : public HostResolverProc {
public:
struct CaptureEntry {
CaptureEntry(const std::string& hostname, AddressFamily address_family)
: hostname(hostname), address_family(address_family) {}
std::string hostname;
AddressFamily address_family;
};
typedef std::vector<CaptureEntry> CaptureList;
explicit CapturingHostResolverProc(HostResolverProc* previous)
: HostResolverProc(previous), event_(true, false) {
}
void Signal() {
event_.Signal();
}
virtual int Resolve(const std::string& hostname,
AddressFamily address_family,
HostResolverFlags host_resolver_flags,
AddressList* addrlist,
int* os_error) {
event_.Wait();
{
AutoLock l(lock_);
capture_list_.push_back(CaptureEntry(hostname, address_family));
}
return ResolveUsingPrevious(hostname, address_family,
host_resolver_flags, addrlist, os_error);
}
CaptureList GetCaptureList() const {
CaptureList copy;
{
AutoLock l(lock_);
copy = capture_list_;
}
return copy;
}
private:
~CapturingHostResolverProc() {}
CaptureList capture_list_;
mutable Lock lock_;
base::WaitableEvent event_;
};
// This resolver function creates an IPv4 address, whose numeral value
// describes a hash of the requested hostname, and the value of the requested
// address_family.
//
// The resolved address for (hostname, address_family) will take the form:
// 192.x.y.z
//
// Where:
// x = length of hostname
// y = ASCII value of hostname[0]
// z = value of address_family
//
class EchoingHostResolverProc : public HostResolverProc {
public:
EchoingHostResolverProc() : HostResolverProc(NULL) {}
virtual int Resolve(const std::string& hostname,
AddressFamily address_family,
HostResolverFlags host_resolver_flags,
AddressList* addrlist,
int* os_error) {
// Encode the request's hostname and address_family in the output address.
std::string ip_literal = StringPrintf("192.%d.%d.%d",
static_cast<int>(hostname.size()),
static_cast<int>(hostname[0]),
static_cast<int>(address_family));
return SystemHostResolverProc(ip_literal,
ADDRESS_FAMILY_UNSPECIFIED,
host_resolver_flags,
addrlist, os_error);
}
};
// Helper that represents a single Resolve() result, used to inspect all the
// resolve results by forwarding them to Delegate.
class ResolveRequest {
public:
// Delegate interface, for notification when the ResolveRequest completes.
class Delegate {
public:
virtual ~Delegate() {}
virtual void OnCompleted(ResolveRequest* resolve) = 0;
};
ResolveRequest(HostResolver* resolver,
const std::string& hostname,
int port,
Delegate* delegate)
: info_(hostname, port), resolver_(resolver), delegate_(delegate),
ALLOW_THIS_IN_INITIALIZER_LIST(
callback_(this, &ResolveRequest::OnLookupFinished)) {
// Start the request.
int err = resolver->Resolve(info_, &addrlist_, &callback_, &req_,
BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, err);
}
ResolveRequest(HostResolver* resolver,
const HostResolver::RequestInfo& info,
Delegate* delegate)
: info_(info), resolver_(resolver), delegate_(delegate),
ALLOW_THIS_IN_INITIALIZER_LIST(
callback_(this, &ResolveRequest::OnLookupFinished)) {
// Start the request.
int err = resolver->Resolve(info, &addrlist_, &callback_, &req_,
BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, err);
}
void Cancel() {
resolver_->CancelRequest(req_);
}
const std::string& hostname() const {
return info_.hostname();
}
int port() const {
return info_.port();
}
int result() const {
return result_;
}
const AddressList& addrlist() const {
return addrlist_;
}
HostResolver* resolver() const {
return resolver_;
}
private:
void OnLookupFinished(int result) {
result_ = result;
delegate_->OnCompleted(this);
}
// The request details.
HostResolver::RequestInfo info_;
HostResolver::RequestHandle req_;
// The result of the resolve.
int result_;
AddressList addrlist_;
// We don't use a scoped_refptr, to simplify deleting shared resolver in
// DeleteWithinCallback test.
HostResolver* resolver_;
Delegate* delegate_;
CompletionCallbackImpl<ResolveRequest> callback_;
DISALLOW_COPY_AND_ASSIGN(ResolveRequest);
};
class HostResolverImplTest : public testing::Test {
public:
HostResolverImplTest()
: callback_called_(false),
ALLOW_THIS_IN_INITIALIZER_LIST(
callback_(this, &HostResolverImplTest::OnLookupFinished)) {
}
protected:
bool callback_called_;
int callback_result_;
CompletionCallbackImpl<HostResolverImplTest> callback_;
private:
void OnLookupFinished(int result) {
callback_called_ = true;
callback_result_ = result;
MessageLoop::current()->Quit();
}
};
TEST_F(HostResolverImplTest, SynchronousLookup) {
AddressList adrlist;
const int kPortnum = 80;
scoped_refptr<RuleBasedHostResolverProc> resolver_proc =
new RuleBasedHostResolverProc(NULL);
resolver_proc->AddRule("just.testing", "192.168.1.42");
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
HostResolver::RequestInfo info("just.testing", kPortnum);
CapturingBoundNetLog log(CapturingNetLog::kUnbounded);
int err = host_resolver->Resolve(info, &adrlist, NULL, NULL, log.bound());
EXPECT_EQ(OK, err);
EXPECT_EQ(2u, log.entries().size());
EXPECT_TRUE(LogContainsBeginEvent(
log.entries(), 0, NetLog::TYPE_HOST_RESOLVER_IMPL));
EXPECT_TRUE(LogContainsEndEvent(
log.entries(), 1, NetLog::TYPE_HOST_RESOLVER_IMPL));
const struct addrinfo* ainfo = adrlist.head();
EXPECT_EQ(static_cast<addrinfo*>(NULL), ainfo->ai_next);
EXPECT_EQ(sizeof(struct sockaddr_in), ainfo->ai_addrlen);
const struct sockaddr* sa = ainfo->ai_addr;
const struct sockaddr_in* sa_in = (const struct sockaddr_in*) sa;
EXPECT_TRUE(htons(kPortnum) == sa_in->sin_port);
EXPECT_TRUE(htonl(0xc0a8012a) == sa_in->sin_addr.s_addr);
}
TEST_F(HostResolverImplTest, AsynchronousLookup) {
AddressList adrlist;
const int kPortnum = 80;
scoped_refptr<RuleBasedHostResolverProc> resolver_proc =
new RuleBasedHostResolverProc(NULL);
resolver_proc->AddRule("just.testing", "192.168.1.42");
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
HostResolver::RequestInfo info("just.testing", kPortnum);
CapturingBoundNetLog log(CapturingNetLog::kUnbounded);
int err = host_resolver->Resolve(info, &adrlist, &callback_, NULL,
log.bound());
EXPECT_EQ(ERR_IO_PENDING, err);
EXPECT_EQ(1u, log.entries().size());
EXPECT_TRUE(LogContainsBeginEvent(
log.entries(), 0, NetLog::TYPE_HOST_RESOLVER_IMPL));
MessageLoop::current()->Run();
ASSERT_TRUE(callback_called_);
ASSERT_EQ(OK, callback_result_);
EXPECT_EQ(2u, log.entries().size());
EXPECT_TRUE(LogContainsEndEvent(
log.entries(), 1, NetLog::TYPE_HOST_RESOLVER_IMPL));
const struct addrinfo* ainfo = adrlist.head();
EXPECT_EQ(static_cast<addrinfo*>(NULL), ainfo->ai_next);
EXPECT_EQ(sizeof(struct sockaddr_in), ainfo->ai_addrlen);
const struct sockaddr* sa = ainfo->ai_addr;
const struct sockaddr_in* sa_in = (const struct sockaddr_in*) sa;
EXPECT_TRUE(htons(kPortnum) == sa_in->sin_port);
EXPECT_TRUE(htonl(0xc0a8012a) == sa_in->sin_addr.s_addr);
}
TEST_F(HostResolverImplTest, CanceledAsynchronousLookup) {
scoped_refptr<WaitingHostResolverProc> resolver_proc =
new WaitingHostResolverProc(NULL);
CapturingBoundNetLog log(CapturingNetLog::kUnbounded);
{
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
AddressList adrlist;
const int kPortnum = 80;
HostResolver::RequestInfo info("just.testing", kPortnum);
int err = host_resolver->Resolve(info, &adrlist, &callback_, NULL,
log.bound());
EXPECT_EQ(ERR_IO_PENDING, err);
// Make sure we will exit the queue even when callback is not called.
MessageLoop::current()->PostDelayedTask(FROM_HERE,
new MessageLoop::QuitTask(),
1000);
MessageLoop::current()->Run();
}
resolver_proc->Signal();
EXPECT_EQ(3u, log.entries().size());
EXPECT_TRUE(LogContainsBeginEvent(
log.entries(), 0, NetLog::TYPE_HOST_RESOLVER_IMPL));
EXPECT_TRUE(LogContainsEvent(
log.entries(), 1, NetLog::TYPE_CANCELLED, NetLog::PHASE_NONE));
EXPECT_TRUE(LogContainsEndEvent(
log.entries(), 2, NetLog::TYPE_HOST_RESOLVER_IMPL));
EXPECT_FALSE(callback_called_);
}
TEST_F(HostResolverImplTest, NumericIPv4Address) {
// Stevens says dotted quads with AI_UNSPEC resolve to a single sockaddr_in.
scoped_refptr<RuleBasedHostResolverProc> resolver_proc =
new RuleBasedHostResolverProc(NULL);
resolver_proc->AllowDirectLookup("*");
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
AddressList adrlist;
const int kPortnum = 5555;
HostResolver::RequestInfo info("127.1.2.3", kPortnum);
int err = host_resolver->Resolve(info, &adrlist, NULL, NULL, BoundNetLog());
EXPECT_EQ(OK, err);
const struct addrinfo* ainfo = adrlist.head();
EXPECT_EQ(static_cast<addrinfo*>(NULL), ainfo->ai_next);
EXPECT_EQ(sizeof(struct sockaddr_in), ainfo->ai_addrlen);
const struct sockaddr* sa = ainfo->ai_addr;
const struct sockaddr_in* sa_in = (const struct sockaddr_in*) sa;
EXPECT_TRUE(htons(kPortnum) == sa_in->sin_port);
EXPECT_TRUE(htonl(0x7f010203) == sa_in->sin_addr.s_addr);
}
TEST_F(HostResolverImplTest, NumericIPv6Address) {
scoped_refptr<RuleBasedHostResolverProc> resolver_proc =
new RuleBasedHostResolverProc(NULL);
resolver_proc->AllowDirectLookup("*");
// Resolve a plain IPv6 address. Don't worry about [brackets], because
// the caller should have removed them.
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
AddressList adrlist;
const int kPortnum = 5555;
HostResolver::RequestInfo info("2001:db8::1", kPortnum);
int err = host_resolver->Resolve(info, &adrlist, NULL, NULL, BoundNetLog());
// On computers without IPv6 support, getaddrinfo cannot convert IPv6
// address literals to addresses (getaddrinfo returns EAI_NONAME). So this
// test has to allow host_resolver->Resolve to fail.
if (err == ERR_NAME_NOT_RESOLVED)
return;
EXPECT_EQ(OK, err);
const struct addrinfo* ainfo = adrlist.head();
EXPECT_EQ(static_cast<addrinfo*>(NULL), ainfo->ai_next);
EXPECT_EQ(sizeof(struct sockaddr_in6), ainfo->ai_addrlen);
const struct sockaddr* sa = ainfo->ai_addr;
const struct sockaddr_in6* sa_in6 = (const struct sockaddr_in6*) sa;
EXPECT_TRUE(htons(kPortnum) == sa_in6->sin6_port);
const uint8 expect_addr[] = {
0x20, 0x01, 0x0d, 0xb8, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01
};
for (int i = 0; i < 16; i++) {
EXPECT_EQ(expect_addr[i], sa_in6->sin6_addr.s6_addr[i]);
}
}
TEST_F(HostResolverImplTest, EmptyHost) {
scoped_refptr<RuleBasedHostResolverProc> resolver_proc =
new RuleBasedHostResolverProc(NULL);
resolver_proc->AllowDirectLookup("*");
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
AddressList adrlist;
const int kPortnum = 5555;
HostResolver::RequestInfo info("", kPortnum);
int err = host_resolver->Resolve(info, &adrlist, NULL, NULL, BoundNetLog());
EXPECT_EQ(ERR_NAME_NOT_RESOLVED, err);
}
// Helper class used by HostResolverImplTest.DeDupeRequests. It receives request
// completion notifications for all the resolves, so it can tally up and
// determine when we are done.
class DeDupeRequestsVerifier : public ResolveRequest::Delegate {
public:
explicit DeDupeRequestsVerifier(CapturingHostResolverProc* resolver_proc)
: count_a_(0), count_b_(0), resolver_proc_(resolver_proc) {}
// The test does 5 resolves (which can complete in any order).
virtual void OnCompleted(ResolveRequest* resolve) {
// Tally up how many requests we have seen.
if (resolve->hostname() == "a") {
count_a_++;
} else if (resolve->hostname() == "b") {
count_b_++;
} else {
FAIL() << "Unexpected hostname: " << resolve->hostname();
}
// Check that the port was set correctly.
EXPECT_EQ(resolve->port(), resolve->addrlist().GetPort());
// Check whether all the requests have finished yet.
int total_completions = count_a_ + count_b_;
if (total_completions == 5) {
EXPECT_EQ(2, count_a_);
EXPECT_EQ(3, count_b_);
// The resolver_proc should have been called only twice -- once with "a",
// once with "b".
CapturingHostResolverProc::CaptureList capture_list =
resolver_proc_->GetCaptureList();
EXPECT_EQ(2U, capture_list.size());
// End this test, we are done.
MessageLoop::current()->Quit();
}
}
private:
int count_a_;
int count_b_;
CapturingHostResolverProc* resolver_proc_;
DISALLOW_COPY_AND_ASSIGN(DeDupeRequestsVerifier);
};
TEST_F(HostResolverImplTest, DeDupeRequests) {
// Use a capturing resolver_proc, since the verifier needs to know what calls
// reached Resolve(). Also, the capturing resolver_proc is initially blocked.
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(NULL);
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
// The class will receive callbacks for when each resolve completes. It
// checks that the right things happened.
DeDupeRequestsVerifier verifier(resolver_proc.get());
// Start 5 requests, duplicating hosts "a" and "b". Since the resolver_proc is
// blocked, these should all pile up until we signal it.
ResolveRequest req1(host_resolver, "a", 80, &verifier);
ResolveRequest req2(host_resolver, "b", 80, &verifier);
ResolveRequest req3(host_resolver, "b", 81, &verifier);
ResolveRequest req4(host_resolver, "a", 82, &verifier);
ResolveRequest req5(host_resolver, "b", 83, &verifier);
// Ready, Set, GO!!!
resolver_proc->Signal();
// |verifier| will send quit message once all the requests have finished.
MessageLoop::current()->Run();
}
// Helper class used by HostResolverImplTest.CancelMultipleRequests.
class CancelMultipleRequestsVerifier : public ResolveRequest::Delegate {
public:
CancelMultipleRequestsVerifier() {}
// The cancels kill all but one request.
virtual void OnCompleted(ResolveRequest* resolve) {
EXPECT_EQ("a", resolve->hostname());
EXPECT_EQ(82, resolve->port());
// Check that the port was set correctly.
EXPECT_EQ(resolve->port(), resolve->addrlist().GetPort());
// End this test, we are done.
MessageLoop::current()->Quit();
}
private:
DISALLOW_COPY_AND_ASSIGN(CancelMultipleRequestsVerifier);
};
TEST_F(HostResolverImplTest, CancelMultipleRequests) {
// Use a capturing resolver_proc, since the verifier needs to know what calls
// reached Resolver(). Also, the capturing resolver_proc is initially
// blocked.
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(NULL);
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
// The class will receive callbacks for when each resolve completes. It
// checks that the right things happened.
CancelMultipleRequestsVerifier verifier;
// Start 5 requests, duplicating hosts "a" and "b". Since the resolver_proc is
// blocked, these should all pile up until we signal it.
ResolveRequest req1(host_resolver, "a", 80, &verifier);
ResolveRequest req2(host_resolver, "b", 80, &verifier);
ResolveRequest req3(host_resolver, "b", 81, &verifier);
ResolveRequest req4(host_resolver, "a", 82, &verifier);
ResolveRequest req5(host_resolver, "b", 83, &verifier);
// Cancel everything except request 4.
req1.Cancel();
req2.Cancel();
req3.Cancel();
req5.Cancel();
// Ready, Set, GO!!!
resolver_proc->Signal();
// |verifier| will send quit message once all the requests have finished.
MessageLoop::current()->Run();
}
// Helper class used by HostResolverImplTest.CancelWithinCallback.
class CancelWithinCallbackVerifier : public ResolveRequest::Delegate {
public:
CancelWithinCallbackVerifier()
: req_to_cancel1_(NULL), req_to_cancel2_(NULL), num_completions_(0) {
}
virtual void OnCompleted(ResolveRequest* resolve) {
num_completions_++;
// Port 80 is the first request that the callback will be invoked for.
// While we are executing within that callback, cancel the other requests
// in the job and start another request.
if (80 == resolve->port()) {
EXPECT_EQ("a", resolve->hostname());
req_to_cancel1_->Cancel();
req_to_cancel2_->Cancel();
// Start a request (so we can make sure the canceled requests don't
// complete before "finalrequest" finishes.
final_request_.reset(new ResolveRequest(
resolve->resolver(), "finalrequest", 70, this));
} else if (83 == resolve->port()) {
EXPECT_EQ("a", resolve->hostname());
} else if (resolve->hostname() == "finalrequest") {
EXPECT_EQ(70, resolve->addrlist().GetPort());
// End this test, we are done.
MessageLoop::current()->Quit();
} else {
FAIL() << "Unexpected completion: " << resolve->hostname() << ", "
<< resolve->port();
}
}
void SetRequestsToCancel(ResolveRequest* req_to_cancel1,
ResolveRequest* req_to_cancel2) {
req_to_cancel1_ = req_to_cancel1;
req_to_cancel2_ = req_to_cancel2;
}
private:
scoped_ptr<ResolveRequest> final_request_;
ResolveRequest* req_to_cancel1_;
ResolveRequest* req_to_cancel2_;
int num_completions_;
DISALLOW_COPY_AND_ASSIGN(CancelWithinCallbackVerifier);
};
TEST_F(HostResolverImplTest, CancelWithinCallback) {
// Use a capturing resolver_proc, since the verifier needs to know what calls
// reached Resolver(). Also, the capturing resolver_proc is initially
// blocked.
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(NULL);
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(resolver_proc));
// The class will receive callbacks for when each resolve completes. It
// checks that the right things happened.
CancelWithinCallbackVerifier verifier;
// Start 4 requests, duplicating hosts "a". Since the resolver_proc is
// blocked, these should all pile up until we signal it.
ResolveRequest req1(host_resolver, "a", 80, &verifier);
ResolveRequest req2(host_resolver, "a", 81, &verifier);
ResolveRequest req3(host_resolver, "a", 82, &verifier);
ResolveRequest req4(host_resolver, "a", 83, &verifier);
// Once "a:80" completes, it will cancel "a:81" and "a:82".
verifier.SetRequestsToCancel(&req2, &req3);
// Ready, Set, GO!!!
resolver_proc->Signal();
// |verifier| will send quit message once all the requests have finished.
MessageLoop::current()->Run();
}
// Helper class used by HostResolverImplTest.DeleteWithinCallback.
class DeleteWithinCallbackVerifier : public ResolveRequest::Delegate {
public:
// |host_resolver| is the resolver that the the resolve requests were started
// with.
DeleteWithinCallbackVerifier(HostResolver* host_resolver)
: host_resolver_(host_resolver) {}
virtual void OnCompleted(ResolveRequest* resolve) {
EXPECT_EQ("a", resolve->hostname());
EXPECT_EQ(80, resolve->port());
// Release the last reference to the host resolver that started the
// requests.
host_resolver_ = NULL;
// Quit after returning from OnCompleted (to give it a chance at
// incorrectly running the cancelled tasks).
MessageLoop::current()->PostTask(FROM_HERE, new MessageLoop::QuitTask());
}
private:
scoped_refptr<HostResolver> host_resolver_;
DISALLOW_COPY_AND_ASSIGN(DeleteWithinCallbackVerifier);
};
TEST_F(HostResolverImplTest, DeleteWithinCallback) {
// Use a capturing resolver_proc, since the verifier needs to know what calls
// reached Resolver(). Also, the capturing resolver_proc is initially
// blocked.
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(NULL);
// The class will receive callbacks for when each resolve completes. It
// checks that the right things happened. Note that the verifier holds the
// only reference to |host_resolver|, so it can delete it within callback.
HostResolver* host_resolver =
CreateHostResolverImpl(resolver_proc);
DeleteWithinCallbackVerifier verifier(host_resolver);
// Start 4 requests, duplicating hosts "a". Since the resolver_proc is
// blocked, these should all pile up until we signal it.
ResolveRequest req1(host_resolver, "a", 80, &verifier);
ResolveRequest req2(host_resolver, "a", 81, &verifier);
ResolveRequest req3(host_resolver, "a", 82, &verifier);
ResolveRequest req4(host_resolver, "a", 83, &verifier);
// Ready, Set, GO!!!
resolver_proc->Signal();
// |verifier| will send quit message once all the requests have finished.
MessageLoop::current()->Run();
}
// Helper class used by HostResolverImplTest.StartWithinCallback.
class StartWithinCallbackVerifier : public ResolveRequest::Delegate {
public:
StartWithinCallbackVerifier() : num_requests_(0) {}
virtual void OnCompleted(ResolveRequest* resolve) {
EXPECT_EQ("a", resolve->hostname());
if (80 == resolve->port()) {
// On completing the first request, start another request for "a".
// Since caching is disabled, this will result in another async request.
final_request_.reset(new ResolveRequest(
resolve->resolver(), "a", 70, this));
}
if (++num_requests_ == 5) {
// Test is done.
MessageLoop::current()->Quit();
}
}
private:
int num_requests_;
scoped_ptr<ResolveRequest> final_request_;
DISALLOW_COPY_AND_ASSIGN(StartWithinCallbackVerifier);
};
TEST_F(HostResolverImplTest, StartWithinCallback) {
// Use a capturing resolver_proc, since the verifier needs to know what calls
// reached Resolver(). Also, the capturing resolver_proc is initially
// blocked.
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(NULL);
// Turn off caching for this host resolver.
scoped_refptr<HostResolver> host_resolver(
new HostResolverImpl(resolver_proc, NULL, NULL, kMaxJobs));
// The class will receive callbacks for when each resolve completes. It
// checks that the right things happened.
StartWithinCallbackVerifier verifier;
// Start 4 requests, duplicating hosts "a". Since the resolver_proc is
// blocked, these should all pile up until we signal it.
ResolveRequest req1(host_resolver, "a", 80, &verifier);
ResolveRequest req2(host_resolver, "a", 81, &verifier);
ResolveRequest req3(host_resolver, "a", 82, &verifier);
ResolveRequest req4(host_resolver, "a", 83, &verifier);
// Ready, Set, GO!!!
resolver_proc->Signal();
// |verifier| will send quit message once all the requests have finished.
MessageLoop::current()->Run();
}
// Helper class used by HostResolverImplTest.BypassCache.
class BypassCacheVerifier : public ResolveRequest::Delegate {
public:
BypassCacheVerifier() {}
virtual void OnCompleted(ResolveRequest* resolve) {
EXPECT_EQ("a", resolve->hostname());
HostResolver* resolver = resolve->resolver();
if (80 == resolve->port()) {
// On completing the first request, start another request for "a".
// Since caching is enabled, this should complete synchronously.
// Note that |junk_callback| shouldn't be used since we are going to
// complete synchronously. We can't specify NULL though since that would
// mean synchronous mode so we give it a value of 1.
CompletionCallback* junk_callback =
reinterpret_cast<CompletionCallback*> (1);
AddressList addrlist;
HostResolver::RequestInfo info("a", 70);
int error = resolver->Resolve(info, &addrlist, junk_callback, NULL,
BoundNetLog());
EXPECT_EQ(OK, error);
// Ok good. Now make sure that if we ask to bypass the cache, it can no
// longer service the request synchronously.
info = HostResolver::RequestInfo("a", 71);
info.set_allow_cached_response(false);
final_request_.reset(new ResolveRequest(resolver, info, this));
} else if (71 == resolve->port()) {
// Test is done.
MessageLoop::current()->Quit();
} else {
FAIL() << "Unexpected port number";
}
}
private:
scoped_ptr<ResolveRequest> final_request_;
DISALLOW_COPY_AND_ASSIGN(BypassCacheVerifier);
};
TEST_F(HostResolverImplTest, BypassCache) {
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(NULL));
// The class will receive callbacks for when each resolve completes. It
// checks that the right things happened.
BypassCacheVerifier verifier;
// Start a request.
ResolveRequest req1(host_resolver, "a", 80, &verifier);
// |verifier| will send quit message once all the requests have finished.
MessageLoop::current()->Run();
}
bool operator==(const HostResolver::RequestInfo& a,
const HostResolver::RequestInfo& b) {
return a.hostname() == b.hostname() &&
a.port() == b.port() &&
a.allow_cached_response() == b.allow_cached_response() &&
a.priority() == b.priority() &&
a.is_speculative() == b.is_speculative() &&
a.referrer() == b.referrer();
}
// Observer that just makes note of how it was called. The test code can then
// inspect to make sure it was called with the right parameters.
class CapturingObserver : public HostResolver::Observer {
public:
// DnsResolutionObserver methods:
virtual void OnStartResolution(int id,
const HostResolver::RequestInfo& info) {
start_log.push_back(StartOrCancelEntry(id, info));
}
virtual void OnFinishResolutionWithStatus(
int id,
bool was_resolved,
const HostResolver::RequestInfo& info) {
finish_log.push_back(FinishEntry(id, was_resolved, info));
}
virtual void OnCancelResolution(int id,
const HostResolver::RequestInfo& info) {
cancel_log.push_back(StartOrCancelEntry(id, info));
}
// Tuple (id, info).
struct StartOrCancelEntry {
StartOrCancelEntry(int id, const HostResolver::RequestInfo& info)
: id(id), info(info) {}
bool operator==(const StartOrCancelEntry& other) const {
return id == other.id && info == other.info;
}
int id;
HostResolver::RequestInfo info;
};
// Tuple (id, was_resolved, info).
struct FinishEntry {
FinishEntry(int id, bool was_resolved,
const HostResolver::RequestInfo& info)
: id(id), was_resolved(was_resolved), info(info) {}
bool operator==(const FinishEntry& other) const {
return id == other.id &&
was_resolved == other.was_resolved &&
info == other.info;
}
int id;
bool was_resolved;
HostResolver::RequestInfo info;
};
std::vector<StartOrCancelEntry> start_log;
std::vector<FinishEntry> finish_log;
std::vector<StartOrCancelEntry> cancel_log;
};
// Test that registering, unregistering, and notifying of observers works.
// Does not test the cancellation notification since all resolves are
// synchronous.
TEST_F(HostResolverImplTest, Observers) {
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(NULL));
CapturingObserver observer;
host_resolver->AddObserver(&observer);
AddressList addrlist;
// Resolve "host1".
HostResolver::RequestInfo info1("host1", 70);
CapturingBoundNetLog log(CapturingNetLog::kUnbounded);
int rv = host_resolver->Resolve(info1, &addrlist, NULL, NULL, log.bound());
EXPECT_EQ(OK, rv);
EXPECT_EQ(2u, log.entries().size());
EXPECT_TRUE(LogContainsBeginEvent(
log.entries(), 0, NetLog::TYPE_HOST_RESOLVER_IMPL));
EXPECT_TRUE(LogContainsEndEvent(
log.entries(), 1, NetLog::TYPE_HOST_RESOLVER_IMPL));
EXPECT_EQ(1U, observer.start_log.size());
EXPECT_EQ(1U, observer.finish_log.size());
EXPECT_EQ(0U, observer.cancel_log.size());
EXPECT_TRUE(observer.start_log[0] ==
CapturingObserver::StartOrCancelEntry(0, info1));
EXPECT_TRUE(observer.finish_log[0] ==
CapturingObserver::FinishEntry(0, true, info1));
// Resolve "host1" again -- this time it will be served from cache, but it
// should still notify of completion.
TestCompletionCallback callback;
rv = host_resolver->Resolve(info1, &addrlist, &callback, NULL, BoundNetLog());
ASSERT_EQ(OK, rv); // Should complete synchronously.
EXPECT_EQ(2U, observer.start_log.size());
EXPECT_EQ(2U, observer.finish_log.size());
EXPECT_EQ(0U, observer.cancel_log.size());
EXPECT_TRUE(observer.start_log[1] ==
CapturingObserver::StartOrCancelEntry(1, info1));
EXPECT_TRUE(observer.finish_log[1] ==
CapturingObserver::FinishEntry(1, true, info1));
// Resolve "host2", setting referrer to "http://foobar.com"
HostResolver::RequestInfo info2("host2", 70);
info2.set_referrer(GURL("http://foobar.com"));
rv = host_resolver->Resolve(info2, &addrlist, NULL, NULL, BoundNetLog());
EXPECT_EQ(OK, rv);
EXPECT_EQ(3U, observer.start_log.size());
EXPECT_EQ(3U, observer.finish_log.size());
EXPECT_EQ(0U, observer.cancel_log.size());
EXPECT_TRUE(observer.start_log[2] ==
CapturingObserver::StartOrCancelEntry(2, info2));
EXPECT_TRUE(observer.finish_log[2] ==
CapturingObserver::FinishEntry(2, true, info2));
// Unregister the observer.
host_resolver->RemoveObserver(&observer);
// Resolve "host3"
HostResolver::RequestInfo info3("host3", 70);
host_resolver->Resolve(info3, &addrlist, NULL, NULL, BoundNetLog());
// No effect this time, since observer was removed.
EXPECT_EQ(3U, observer.start_log.size());
EXPECT_EQ(3U, observer.finish_log.size());
EXPECT_EQ(0U, observer.cancel_log.size());
}
// Tests that observers are sent OnCancelResolution() whenever a request is
// cancelled. There are two ways to cancel a request:
// (1) Delete the HostResolver while job is outstanding.
// (2) Call HostResolver::CancelRequest() while a request is outstanding.
TEST_F(HostResolverImplTest, CancellationObserver) {
CapturingObserver observer;
{
// Create a host resolver and attach an observer.
scoped_refptr<HostResolver> host_resolver(
CreateHostResolverImpl(NULL));
host_resolver->AddObserver(&observer);
TestCompletionCallback callback;
EXPECT_EQ(0U, observer.start_log.size());
EXPECT_EQ(0U, observer.finish_log.size());
EXPECT_EQ(0U, observer.cancel_log.size());
// Start an async resolve for (host1:70).
HostResolver::RequestInfo info1("host1", 70);
HostResolver::RequestHandle req = NULL;
AddressList addrlist;
int rv = host_resolver->Resolve(info1, &addrlist, &callback, &req,
BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, rv);
EXPECT_TRUE(NULL != req);
EXPECT_EQ(1U, observer.start_log.size());
EXPECT_EQ(0U, observer.finish_log.size());
EXPECT_EQ(0U, observer.cancel_log.size());
EXPECT_TRUE(observer.start_log[0] ==
CapturingObserver::StartOrCancelEntry(0, info1));
// Cancel the request.
host_resolver->CancelRequest(req);
EXPECT_EQ(1U, observer.start_log.size());
EXPECT_EQ(0U, observer.finish_log.size());
EXPECT_EQ(1U, observer.cancel_log.size());
EXPECT_TRUE(observer.cancel_log[0] ==
CapturingObserver::StartOrCancelEntry(0, info1));
// Start an async request for (host2:60)
HostResolver::RequestInfo info2("host2", 60);
rv = host_resolver->Resolve(info2, &addrlist, &callback, NULL,
BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, rv);
EXPECT_TRUE(NULL != req);
EXPECT_EQ(2U, observer.start_log.size());
EXPECT_EQ(0U, observer.finish_log.size());
EXPECT_EQ(1U, observer.cancel_log.size());
EXPECT_TRUE(observer.start_log[1] ==
CapturingObserver::StartOrCancelEntry(1, info2));
// Upon exiting this scope, HostResolver is destroyed, so all requests are
// implicitly cancelled.
}
// Check that destroying the HostResolver sent a notification for
// cancellation of host2:60 request.
EXPECT_EQ(2U, observer.start_log.size());
EXPECT_EQ(0U, observer.finish_log.size());
EXPECT_EQ(2U, observer.cancel_log.size());
HostResolver::RequestInfo info("host2", 60);
EXPECT_TRUE(observer.cancel_log[1] ==
CapturingObserver::StartOrCancelEntry(1, info));
}
// Test that IP address changes flush the cache.
TEST_F(HostResolverImplTest, FlushCacheOnIPAddressChange) {
MockNetworkChangeNotifier mock_network_change_notifier;
scoped_refptr<HostResolver> host_resolver(
new HostResolverImpl(NULL, CreateDefaultCache(),
&mock_network_change_notifier,
kMaxJobs));
AddressList addrlist;
// Resolve "host1".
HostResolver::RequestInfo info1("host1", 70);
TestCompletionCallback callback;
int rv = host_resolver->Resolve(info1, &addrlist, &callback, NULL,
BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, rv);
EXPECT_EQ(OK, callback.WaitForResult());
// Resolve "host1" again -- this time it will be served from cache, but it
// should still notify of completion.
rv = host_resolver->Resolve(info1, &addrlist, &callback, NULL, BoundNetLog());
ASSERT_EQ(OK, rv); // Should complete synchronously.
// Flush cache by triggering an IP address change.
mock_network_change_notifier.NotifyIPAddressChange();
// Resolve "host1" again -- this time it won't be served from cache, so it
// will complete asynchronously.
rv = host_resolver->Resolve(info1, &addrlist, &callback, NULL, BoundNetLog());
ASSERT_EQ(ERR_IO_PENDING, rv); // Should complete asynchronously.
EXPECT_EQ(OK, callback.WaitForResult());
}
// Tests that when the maximum threads is set to 1, requests are dequeued
// in order of priority.
TEST_F(HostResolverImplTest, HigherPriorityRequestsStartedFirst) {
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(NULL);
// This HostResolverImpl will only allow 1 outstanding resolve at a time.
size_t kMaxJobs = 1u;
scoped_refptr<HostResolver> host_resolver(
new HostResolverImpl(resolver_proc, CreateDefaultCache(),
NULL, kMaxJobs));
CapturingObserver observer;
host_resolver->AddObserver(&observer);
// Note that at this point the CapturingHostResolverProc is blocked, so any
// requests we make will not complete.
HostResolver::RequestInfo req[] = {
CreateResolverRequest("req0", LOW),
CreateResolverRequest("req1", MEDIUM),
CreateResolverRequest("req2", MEDIUM),
CreateResolverRequest("req3", LOW),
CreateResolverRequest("req4", HIGHEST),
CreateResolverRequest("req5", LOW),
CreateResolverRequest("req6", LOW),
CreateResolverRequest("req5", HIGHEST),
};
TestCompletionCallback callback[arraysize(req)];
AddressList addrlist[arraysize(req)];
// Start all of the requests.
for (size_t i = 0; i < arraysize(req); ++i) {
int rv = host_resolver->Resolve(req[i], &addrlist[i],
&callback[i], NULL, BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, rv);
}
// Unblock the resolver thread so the requests can run.
resolver_proc->Signal();
// Wait for all the requests to complete succesfully.
for (size_t i = 0; i < arraysize(req); ++i) {
EXPECT_EQ(OK, callback[i].WaitForResult()) << "i=" << i;
}
host_resolver->RemoveObserver(&observer);
// Since we have restricted to a single concurrent thread in the jobpool,
// the requests should complete in order of priority (with the exception
// of the first request, which gets started right away, since there is
// nothing outstanding).
CapturingHostResolverProc::CaptureList capture_list =
resolver_proc->GetCaptureList();
ASSERT_EQ(7u, capture_list.size());
EXPECT_EQ("req0", capture_list[0].hostname);
EXPECT_EQ("req4", capture_list[1].hostname);
EXPECT_EQ("req5", capture_list[2].hostname);
EXPECT_EQ("req1", capture_list[3].hostname);
EXPECT_EQ("req2", capture_list[4].hostname);
EXPECT_EQ("req3", capture_list[5].hostname);
EXPECT_EQ("req6", capture_list[6].hostname);
// Also check using the observer's trace.
EXPECT_EQ(8U, observer.start_log.size());
EXPECT_EQ(8U, observer.finish_log.size());
EXPECT_EQ(0U, observer.cancel_log.size());
EXPECT_EQ("req0", observer.finish_log[0].info.hostname());
EXPECT_EQ("req4", observer.finish_log[1].info.hostname());
// There were two requests for "req5". The highest priority
// one should have been dispatched earlier.
EXPECT_EQ("req5", observer.finish_log[2].info.hostname());
EXPECT_EQ("req5", observer.finish_log[3].info.hostname());
EXPECT_EQ(HIGHEST, observer.finish_log[2].info.priority());
EXPECT_EQ(LOW, observer.finish_log[3].info.priority());
EXPECT_EQ("req1", observer.finish_log[4].info.hostname());
EXPECT_EQ("req2", observer.finish_log[5].info.hostname());
EXPECT_EQ("req3", observer.finish_log[6].info.hostname());
EXPECT_EQ("req6", observer.finish_log[7].info.hostname());
}
// Try cancelling a request which has not been attached to a job yet.
TEST_F(HostResolverImplTest, CancelPendingRequest) {
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(NULL);
// This HostResolverImpl will only allow 1 outstanding resolve at a time.
const size_t kMaxJobs = 1u;
scoped_refptr<HostResolver> host_resolver(
new HostResolverImpl(resolver_proc, CreateDefaultCache(),
NULL, kMaxJobs));
// Note that at this point the CapturingHostResolverProc is blocked, so any
// requests we make will not complete.
HostResolver::RequestInfo req[] = {
CreateResolverRequest("req0", LOWEST),
CreateResolverRequest("req1", HIGHEST), // Will cancel.
CreateResolverRequest("req2", MEDIUM),
CreateResolverRequest("req3", LOW),
CreateResolverRequest("req4", HIGHEST), // Will cancel.
CreateResolverRequest("req5", LOWEST), // Will cancel.
CreateResolverRequest("req6", MEDIUM),
};
TestCompletionCallback callback[arraysize(req)];
AddressList addrlist[arraysize(req)];
HostResolver::RequestHandle handle[arraysize(req)];
// Start all of the requests.
for (size_t i = 0; i < arraysize(req); ++i) {
int rv = host_resolver->Resolve(req[i], &addrlist[i],
&callback[i], &handle[i], BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, rv);
}
// Cancel some requests
host_resolver->CancelRequest(handle[1]);
host_resolver->CancelRequest(handle[4]);
host_resolver->CancelRequest(handle[5]);
handle[1] = handle[4] = handle[5] = NULL;
// Unblock the resolver thread so the requests can run.
resolver_proc->Signal();
// Wait for all the requests to complete succesfully.
for (size_t i = 0; i < arraysize(req); ++i) {
if (!handle[i])
continue; // Don't wait for the requests we cancelled.
EXPECT_EQ(OK, callback[i].WaitForResult());
}
// Verify that they called out the the resolver proc (which runs on the
// resolver thread) in the expected order.
CapturingHostResolverProc::CaptureList capture_list =
resolver_proc->GetCaptureList();
ASSERT_EQ(4u, capture_list.size());
EXPECT_EQ("req0", capture_list[0].hostname);
EXPECT_EQ("req2", capture_list[1].hostname);
EXPECT_EQ("req6", capture_list[2].hostname);
EXPECT_EQ("req3", capture_list[3].hostname);
}
// Test that when too many requests are enqueued, old ones start to be aborted.
TEST_F(HostResolverImplTest, QueueOverflow) {
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(NULL);
// This HostResolverImpl will only allow 1 outstanding resolve at a time.
const size_t kMaxOutstandingJobs = 1u;
scoped_refptr<HostResolverImpl> host_resolver(
new HostResolverImpl(resolver_proc, CreateDefaultCache(),
NULL, kMaxOutstandingJobs));
// Only allow up to 3 requests to be enqueued at a time.
const size_t kMaxPendingRequests = 3u;
host_resolver->SetPoolConstraints(HostResolverImpl::POOL_NORMAL,
kMaxOutstandingJobs,
kMaxPendingRequests);
// Note that at this point the CapturingHostResolverProc is blocked, so any
// requests we make will not complete.
HostResolver::RequestInfo req[] = {
CreateResolverRequest("req0", LOWEST),
CreateResolverRequest("req1", HIGHEST),
CreateResolverRequest("req2", MEDIUM),
CreateResolverRequest("req3", MEDIUM),
// At this point, there are 3 enqueued requests.
// Insertion of subsequent requests will cause evictions
// based on priority.
CreateResolverRequest("req4", LOW), // Evicts itself!
CreateResolverRequest("req5", MEDIUM), // Evicts req3
CreateResolverRequest("req6", HIGHEST), // Evicts req5.
CreateResolverRequest("req7", MEDIUM), // Evicts req2.
};
TestCompletionCallback callback[arraysize(req)];
AddressList addrlist[arraysize(req)];
HostResolver::RequestHandle handle[arraysize(req)];
// Start all of the requests.
for (size_t i = 0; i < arraysize(req); ++i) {
int rv = host_resolver->Resolve(req[i], &addrlist[i],
&callback[i], &handle[i], BoundNetLog());
if (i == 4u)
EXPECT_EQ(ERR_HOST_RESOLVER_QUEUE_TOO_LARGE, rv);
else
EXPECT_EQ(ERR_IO_PENDING, rv) << i;
}
// Unblock the resolver thread so the requests can run.
resolver_proc->Signal();
// Requests 3, 5, 2 will have been evicted due to queue overflow.
size_t reqs_expected_to_fail[] = { 2, 3, 5 };
for (size_t i = 0; i < arraysize(reqs_expected_to_fail); ++i) {
EXPECT_EQ(ERR_HOST_RESOLVER_QUEUE_TOO_LARGE,
callback[reqs_expected_to_fail[i]].WaitForResult());
}
// The rest should succeed.
size_t reqs_expected_to_succeed[] = { 0, 1, 6, 7 };
for (size_t i = 0; i < arraysize(reqs_expected_to_succeed); ++i) {
EXPECT_EQ(OK, callback[reqs_expected_to_succeed[i]].WaitForResult());
}
// Verify that they called out the the resolver proc (which runs on the
// resolver thread) in the expected order.
CapturingHostResolverProc::CaptureList capture_list =
resolver_proc->GetCaptureList();
ASSERT_EQ(4u, capture_list.size());
EXPECT_EQ("req0", capture_list[0].hostname);
EXPECT_EQ("req1", capture_list[1].hostname);
EXPECT_EQ("req6", capture_list[2].hostname);
EXPECT_EQ("req7", capture_list[3].hostname);
}
// Tests that after changing the default AddressFamily to IPV4, requests
// with UNSPECIFIED address family map to IPV4.
TEST_F(HostResolverImplTest, SetDefaultAddressFamily_IPv4) {
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(new EchoingHostResolverProc);
// This HostResolverImpl will only allow 1 outstanding resolve at a time.
const size_t kMaxOutstandingJobs = 1u;
scoped_refptr<HostResolverImpl> host_resolver(
new HostResolverImpl(resolver_proc, CreateDefaultCache(),
NULL, kMaxOutstandingJobs));
host_resolver->SetDefaultAddressFamily(ADDRESS_FAMILY_IPV4);
// Note that at this point the CapturingHostResolverProc is blocked, so any
// requests we make will not complete.
HostResolver::RequestInfo req[] = {
CreateResolverRequestForAddressFamily("h1", MEDIUM,
ADDRESS_FAMILY_UNSPECIFIED),
CreateResolverRequestForAddressFamily("h1", MEDIUM, ADDRESS_FAMILY_IPV4),
CreateResolverRequestForAddressFamily("h1", MEDIUM, ADDRESS_FAMILY_IPV6),
};
TestCompletionCallback callback[arraysize(req)];
AddressList addrlist[arraysize(req)];
HostResolver::RequestHandle handle[arraysize(req)];
// Start all of the requests.
for (size_t i = 0; i < arraysize(req); ++i) {
int rv = host_resolver->Resolve(req[i], &addrlist[i],
&callback[i], &handle[i], BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, rv) << i;
}
// Unblock the resolver thread so the requests can run.
resolver_proc->Signal();
// Wait for all the requests to complete.
for (size_t i = 0u; i < arraysize(req); ++i) {
EXPECT_EQ(OK, callback[i].WaitForResult());
}
// Since the requests all had the same priority and we limited the thread
// count to 1, they should have completed in the same order as they were
// requested. Moreover, request0 and request1 will have been serviced by
// the same job.
CapturingHostResolverProc::CaptureList capture_list =
resolver_proc->GetCaptureList();
ASSERT_EQ(2u, capture_list.size());
EXPECT_EQ("h1", capture_list[0].hostname);
EXPECT_EQ(ADDRESS_FAMILY_IPV4, capture_list[0].address_family);
EXPECT_EQ("h1", capture_list[1].hostname);
EXPECT_EQ(ADDRESS_FAMILY_IPV6, capture_list[1].address_family);
// Now check that the correct resolved IP addresses were returned.
// Addresses take the form: 192.x.y.z
// x = length of hostname
// y = ASCII value of hostname[0]
// z = value of address family
EXPECT_EQ("192.2.104.1", NetAddressToString(addrlist[0].head()));
EXPECT_EQ("192.2.104.1", NetAddressToString(addrlist[1].head()));
EXPECT_EQ("192.2.104.2", NetAddressToString(addrlist[2].head()));
}
// This is the exact same test as SetDefaultAddressFamily_IPv4, except the order
// of requests 0 and 1 is flipped, and the default is set to IPv6 in place of
// IPv4.
TEST_F(HostResolverImplTest, SetDefaultAddressFamily_IPv6) {
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(new EchoingHostResolverProc);
// This HostResolverImpl will only allow 1 outstanding resolve at a time.
const size_t kMaxOutstandingJobs = 1u;
scoped_refptr<HostResolverImpl> host_resolver(
new HostResolverImpl(resolver_proc, CreateDefaultCache(),
NULL, kMaxOutstandingJobs));
host_resolver->SetDefaultAddressFamily(ADDRESS_FAMILY_IPV6);
// Note that at this point the CapturingHostResolverProc is blocked, so any
// requests we make will not complete.
HostResolver::RequestInfo req[] = {
CreateResolverRequestForAddressFamily("h1", MEDIUM, ADDRESS_FAMILY_IPV6),
CreateResolverRequestForAddressFamily("h1", MEDIUM,
ADDRESS_FAMILY_UNSPECIFIED),
CreateResolverRequestForAddressFamily("h1", MEDIUM, ADDRESS_FAMILY_IPV4),
};
TestCompletionCallback callback[arraysize(req)];
AddressList addrlist[arraysize(req)];
HostResolver::RequestHandle handle[arraysize(req)];
// Start all of the requests.
for (size_t i = 0; i < arraysize(req); ++i) {
int rv = host_resolver->Resolve(req[i], &addrlist[i],
&callback[i], &handle[i], BoundNetLog());
EXPECT_EQ(ERR_IO_PENDING, rv) << i;
}
// Unblock the resolver thread so the requests can run.
resolver_proc->Signal();
// Wait for all the requests to complete.
for (size_t i = 0u; i < arraysize(req); ++i) {
EXPECT_EQ(OK, callback[i].WaitForResult());
}
// Since the requests all had the same priority and we limited the thread
// count to 1, they should have completed in the same order as they were
// requested. Moreover, request0 and request1 will have been serviced by
// the same job.
CapturingHostResolverProc::CaptureList capture_list =
resolver_proc->GetCaptureList();
ASSERT_EQ(2u, capture_list.size());
EXPECT_EQ("h1", capture_list[0].hostname);
EXPECT_EQ(ADDRESS_FAMILY_IPV6, capture_list[0].address_family);
EXPECT_EQ("h1", capture_list[1].hostname);
EXPECT_EQ(ADDRESS_FAMILY_IPV4, capture_list[1].address_family);
// Now check that the correct resolved IP addresses were returned.
// Addresses take the form: 192.x.y.z
// x = length of hostname
// y = ASCII value of hostname[0]
// z = value of address family
EXPECT_EQ("192.2.104.2", NetAddressToString(addrlist[0].head()));
EXPECT_EQ("192.2.104.2", NetAddressToString(addrlist[1].head()));
EXPECT_EQ("192.2.104.1", NetAddressToString(addrlist[2].head()));
}
// This tests that the default address family is respected for synchronous
// resolutions.
TEST_F(HostResolverImplTest, SetDefaultAddressFamily_Synchronous) {
scoped_refptr<CapturingHostResolverProc> resolver_proc =
new CapturingHostResolverProc(new EchoingHostResolverProc);
const size_t kMaxOutstandingJobs = 10u;
scoped_refptr<HostResolverImpl> host_resolver(
new HostResolverImpl(resolver_proc, CreateDefaultCache(),
NULL, kMaxOutstandingJobs));
host_resolver->SetDefaultAddressFamily(ADDRESS_FAMILY_IPV4);
// Unblock the resolver thread so the requests can run.
resolver_proc->Signal();
HostResolver::RequestInfo req[] = {
CreateResolverRequestForAddressFamily("b", MEDIUM,
ADDRESS_FAMILY_UNSPECIFIED),
CreateResolverRequestForAddressFamily("b", MEDIUM, ADDRESS_FAMILY_IPV6),
CreateResolverRequestForAddressFamily("b", MEDIUM,
ADDRESS_FAMILY_UNSPECIFIED),
CreateResolverRequestForAddressFamily("b", MEDIUM, ADDRESS_FAMILY_IPV4),
};
AddressList addrlist[arraysize(req)];
// Start and run all of the requests synchronously.
for (size_t i = 0; i < arraysize(req); ++i) {
int rv = host_resolver->Resolve(req[i], &addrlist[i],
NULL, NULL, BoundNetLog());
EXPECT_EQ(OK, rv) << i;
}
// We should have sent 2 requests to the resolver --
// one for (b, IPv4), and one for (b, IPv6).
CapturingHostResolverProc::CaptureList capture_list =
resolver_proc->GetCaptureList();
ASSERT_EQ(2u, capture_list.size());
EXPECT_EQ("b", capture_list[0].hostname);
EXPECT_EQ(ADDRESS_FAMILY_IPV4, capture_list[0].address_family);
EXPECT_EQ("b", capture_list[1].hostname);
EXPECT_EQ(ADDRESS_FAMILY_IPV6, capture_list[1].address_family);
// Now check that the correct resolved IP addresses were returned.
// Addresses take the form: 192.x.y.z
// x = length of hostname
// y = ASCII value of hostname[0]
// z = value of address family
EXPECT_EQ("192.1.98.1", NetAddressToString(addrlist[0].head()));
EXPECT_EQ("192.1.98.2", NetAddressToString(addrlist[1].head()));
EXPECT_EQ("192.1.98.1", NetAddressToString(addrlist[2].head()));
EXPECT_EQ("192.1.98.1", NetAddressToString(addrlist[3].head()));
}
// TODO(cbentzel): Test a mix of requests with different HostResolverFlags.
} // namespace
} // namespace net