ppapi/tests/test_utils.cc - chromium/src - 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 "ppapi/tests/test_utils.h"

 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #if defined(_MSC_VER)
 #include <windows.h>
 #else
 #include <unistd.h>
 #endif

 #include "ppapi/c/pp_errors.h"
 #include "ppapi/cpp/instance_handle.h"
 #include "ppapi/cpp/module.h"
 #include "ppapi/cpp/net_address.h"
 #include "ppapi/cpp/private/host_resolver_private.h"
 #include "ppapi/cpp/private/net_address_private.h"
 #include "ppapi/cpp/var.h"

 namespace {

 bool IsBigEndian() {
   union {
     uint32_t integer32;
     uint8_t integer8[4];
   } data = { 0x01020304 };

   return data.integer8[0] == 1;
 }

 }  // namespace

 const int kActionTimeoutMs = 10000;

 const PPB_Testing_Private* GetTestingInterface() {
   static const PPB_Testing_Private* g_testing_interface =
       static_cast<const PPB_Testing_Private*>(
           pp::Module::Get()->GetBrowserInterface(
               PPB_TESTING_PRIVATE_INTERFACE));
   return g_testing_interface;
 }

 std::string ReportError(const char* method, int32_t error) {
   char error_as_string[12];
   sprintf(error_as_string, "%d", static_cast<int>(error));
   std::string result = method + std::string(" failed with error: ") +
       error_as_string;
   return result;
 }

 void PlatformSleep(int duration_ms) {
 #if defined(_MSC_VER)
   ::Sleep(duration_ms);
 #else
   usleep(duration_ms * 1000);
 #endif
 }

 bool GetLocalHostPort(PP_Instance instance, std::string* host, uint16_t* port) {
   if (!host || !port)
     return false;

   const PPB_Testing_Private* testing = GetTestingInterface();
   if (!testing)
     return false;

   PP_URLComponents_Dev components;
   pp::Var pp_url(pp::PASS_REF,
                  testing->GetDocumentURL(instance, &components));
   if (!pp_url.is_string())
     return false;
   std::string url = pp_url.AsString();

   if (components.host.len < 0)
     return false;
   host->assign(url.substr(components.host.begin, components.host.len));

   if (components.port.len <= 0)
     return false;

   int i = atoi(url.substr(components.port.begin, components.port.len).c_str());
   if (i < 0 || i > 65535)
     return false;
   *port = static_cast<uint16_t>(i);

   return true;
 }

 uint16_t ConvertFromNetEndian16(uint16_t x) {
   if (IsBigEndian())
     return x;
   else
     return (x << 8) | (x >> 8);
 }

 uint16_t ConvertToNetEndian16(uint16_t x) {
   if (IsBigEndian())
     return x;
   else
     return (x << 8) | (x >> 8);
 }

 bool EqualNetAddress(const pp::NetAddress& addr1, const pp::NetAddress& addr2) {
   if (addr1.GetFamily() == PP_NETADDRESS_FAMILY_UNSPECIFIED ||
       addr2.GetFamily() == PP_NETADDRESS_FAMILY_UNSPECIFIED) {
     return false;
   }

   if (addr1.GetFamily() == PP_NETADDRESS_FAMILY_IPV4) {
     PP_NetAddress_IPv4 ipv4_addr1, ipv4_addr2;
     if (!addr1.DescribeAsIPv4Address(&ipv4_addr1) ||
         !addr2.DescribeAsIPv4Address(&ipv4_addr2)) {
       return false;
     }

     return ipv4_addr1.port == ipv4_addr2.port &&
            !memcmp(ipv4_addr1.addr, ipv4_addr2.addr, sizeof(ipv4_addr1.addr));
   } else {
     PP_NetAddress_IPv6 ipv6_addr1, ipv6_addr2;
     if (!addr1.DescribeAsIPv6Address(&ipv6_addr1) ||
         !addr2.DescribeAsIPv6Address(&ipv6_addr2)) {
       return false;
     }

     return ipv6_addr1.port == ipv6_addr2.port &&
            !memcmp(ipv6_addr1.addr, ipv6_addr2.addr, sizeof(ipv6_addr1.addr));
   }
 }

 bool ResolveHost(PP_Instance instance,
                  const std::string& host,
                  uint16_t port,
                  pp::NetAddress* addr) {
   // TODO(yzshen): Change to use the public host resolver once it is supported.
   pp::InstanceHandle instance_handle(instance);
   pp::HostResolverPrivate host_resolver(instance_handle);
   PP_HostResolver_Private_Hint hint =
       { PP_NETADDRESSFAMILY_PRIVATE_UNSPECIFIED, 0 };

   TestCompletionCallback callback(instance);
   callback.WaitForResult(
       host_resolver.Resolve(host, port, hint, callback.GetCallback()));

   PP_NetAddress_Private addr_private;
   if (callback.result() != PP_OK || host_resolver.GetSize() == 0 ||
       !host_resolver.GetNetAddress(0, &addr_private)) {
     return false;
   }

   switch (pp::NetAddressPrivate::GetFamily(addr_private)) {
     case PP_NETADDRESSFAMILY_PRIVATE_IPV4: {
       PP_NetAddress_IPv4 ipv4_addr;
       ipv4_addr.port = ConvertToNetEndian16(
           pp::NetAddressPrivate::GetPort(addr_private));
       if (!pp::NetAddressPrivate::GetAddress(addr_private, ipv4_addr.addr,
                                              sizeof(ipv4_addr.addr))) {
         return false;
       }
       *addr = pp::NetAddress(instance_handle, ipv4_addr);
       return true;
     }
     case PP_NETADDRESSFAMILY_PRIVATE_IPV6: {
       PP_NetAddress_IPv6 ipv6_addr;
       ipv6_addr.port = ConvertToNetEndian16(
           pp::NetAddressPrivate::GetPort(addr_private));
       if (!pp::NetAddressPrivate::GetAddress(addr_private, ipv6_addr.addr,
                                              sizeof(ipv6_addr.addr))) {
         return false;
       }
       *addr = pp::NetAddress(instance_handle, ipv6_addr);
       return true;
     }
     default: {
       return false;
     }
   }
 }

 bool ReplacePort(PP_Instance instance,
                  const pp::NetAddress& input_addr,
                  uint16_t port,
                  pp::NetAddress* output_addr) {
   switch (input_addr.GetFamily()) {
     case PP_NETADDRESS_FAMILY_IPV4: {
       PP_NetAddress_IPv4 ipv4_addr;
       if (!input_addr.DescribeAsIPv4Address(&ipv4_addr))
         return false;
       ipv4_addr.port = ConvertToNetEndian16(port);
       *output_addr = pp::NetAddress(pp::InstanceHandle(instance), ipv4_addr);
       return true;
     }
     case PP_NETADDRESS_FAMILY_IPV6: {
       PP_NetAddress_IPv6 ipv6_addr;
       if (!input_addr.DescribeAsIPv6Address(&ipv6_addr))
         return false;
       ipv6_addr.port = ConvertToNetEndian16(port);
       *output_addr = pp::NetAddress(pp::InstanceHandle(instance), ipv6_addr);
       return true;
     }
     default: {
       return false;
     }
   }
 }

 uint16_t GetPort(const pp::NetAddress& addr) {
   switch (addr.GetFamily()) {
     case PP_NETADDRESS_FAMILY_IPV4: {
       PP_NetAddress_IPv4 ipv4_addr;
       if (!addr.DescribeAsIPv4Address(&ipv4_addr))
         return 0;
       return ConvertFromNetEndian16(ipv4_addr.port);
     }
     case PP_NETADDRESS_FAMILY_IPV6: {
       PP_NetAddress_IPv6 ipv6_addr;
       if (!addr.DescribeAsIPv6Address(&ipv6_addr))
         return 0;
       return ConvertFromNetEndian16(ipv6_addr.port);
     }
     default: {
       return 0;
     }
   }
 }

 void NestedEvent::Wait() {
   PP_DCHECK(pp::Module::Get()->core()->IsMainThread());
   // Don't allow nesting more than once; it doesn't work with the code as-is,
   // and probably is a bad idea most of the time anyway.
   PP_DCHECK(!waiting_);
   if (signalled_)
     return;
   waiting_ = true;
   while (!signalled_)
     GetTestingInterface()->RunMessageLoop(instance_);
   waiting_ = false;
 }

 void NestedEvent::Signal() {
   if (pp::Module::Get()->core()->IsMainThread())
     SignalOnMainThread();
   else
     PostSignal(0);
 }

 void NestedEvent::PostSignal(int32_t wait_ms) {
   pp::Module::Get()->core()->CallOnMainThread(
       wait_ms,
       pp::CompletionCallback(&SignalThunk, this),
       0);
 }

 void NestedEvent::Reset() {
   PP_DCHECK(pp::Module::Get()->core()->IsMainThread());
   // It doesn't make sense to reset when we're still waiting.
   PP_DCHECK(!waiting_);
   signalled_ = false;
 }

 void NestedEvent::SignalOnMainThread() {
   PP_DCHECK(pp::Module::Get()->core()->IsMainThread());
   signalled_ = true;
   if (waiting_)
     GetTestingInterface()->QuitMessageLoop(instance_);
 }

 void NestedEvent::SignalThunk(void* event, int32_t /* result */) {
   static_cast<NestedEvent*>(event)->SignalOnMainThread();
 }

 TestCompletionCallback::TestCompletionCallback(PP_Instance instance)
     : wait_for_result_called_(false),
       have_result_(false),
       result_(PP_OK_COMPLETIONPENDING),
       // TODO(dmichael): The default should probably be PP_REQUIRED, but this is
       //                 what the tests currently expect.
       callback_type_(PP_OPTIONAL),
       post_quit_task_(false),
       instance_(instance),
       delegate_(NULL) {
 }

 TestCompletionCallback::TestCompletionCallback(PP_Instance instance,
                                                bool force_async)
     : wait_for_result_called_(false),
       have_result_(false),
       result_(PP_OK_COMPLETIONPENDING),
       callback_type_(force_async ? PP_REQUIRED : PP_OPTIONAL),
       post_quit_task_(false),
       instance_(instance),
       delegate_(NULL) {
 }

 TestCompletionCallback::TestCompletionCallback(PP_Instance instance,
                                                CallbackType callback_type)
     : wait_for_result_called_(false),
       have_result_(false),
       result_(PP_OK_COMPLETIONPENDING),
       callback_type_(callback_type),
       post_quit_task_(false),
       instance_(instance),
       delegate_(NULL) {
 }

 void TestCompletionCallback::WaitForResult(int32_t result) {
   PP_DCHECK(!wait_for_result_called_);
   wait_for_result_called_ = true;
   errors_.clear();
   if (result == PP_OK_COMPLETIONPENDING) {
     if (!have_result_) {
       post_quit_task_ = true;
       RunMessageLoop();
     }
     if (callback_type_ == PP_BLOCKING) {
       errors_.assign(
           ReportError("TestCompletionCallback: Call did not run synchronously "
                       "when passed a blocking completion callback!",
                       result_));
       return;
     }
   } else {
     result_ = result;
     have_result_ = true;
     if (callback_type_ == PP_REQUIRED) {
       errors_.assign(
           ReportError("TestCompletionCallback: Call ran synchronously when "
                       "passed a required completion callback!",
                       result_));
       return;
     }
   }
   PP_DCHECK(have_result_ == true);
 }

 void TestCompletionCallback::WaitForAbortResult(int32_t result) {
   WaitForResult(result);
   int32_t final_result = result_;
   if (result == PP_OK_COMPLETIONPENDING) {
     if (final_result != PP_ERROR_ABORTED) {
       errors_.assign(
           ReportError("TestCompletionCallback: Expected PP_ERROR_ABORTED or "
                       "PP_OK. Ran asynchronously.",
                       final_result));
       return;
     }
   } else if (result < PP_OK) {
     errors_.assign(
         ReportError("TestCompletionCallback: Expected PP_ERROR_ABORTED or "
                     "non-error response. Ran synchronously.",
                     result));
     return;
   }
 }

 pp::CompletionCallback TestCompletionCallback::GetCallback() {
   Reset();
   int32_t flags = 0;
   if (callback_type_ == PP_BLOCKING)
     return pp::CompletionCallback();
   else if (callback_type_ == PP_OPTIONAL)
     flags = PP_COMPLETIONCALLBACK_FLAG_OPTIONAL;
   target_loop_ = pp::MessageLoop::GetCurrent();
   return pp::CompletionCallback(&TestCompletionCallback::Handler,
                                 const_cast<TestCompletionCallback*>(this),
                                 flags);
 }

 void TestCompletionCallback::Reset() {
   wait_for_result_called_ = false;
   result_ = PP_OK_COMPLETIONPENDING;
   have_result_ = false;
   post_quit_task_ = false;
   delegate_ = NULL;
   errors_.clear();
 }

 // static
 void TestCompletionCallback::Handler(void* user_data, int32_t result) {
   TestCompletionCallback* callback =
       static_cast<TestCompletionCallback*>(user_data);
   // If this check fails, it means that the callback was invoked twice or that
   // the PPAPI call completed synchronously, but also ran the callback.
   PP_DCHECK(!callback->have_result_);
   callback->result_ = result;
   callback->have_result_ = true;
   if (callback->delegate_)
     callback->delegate_->OnCallback(user_data, result);
   if (callback->post_quit_task_) {
     callback->post_quit_task_ = false;
     callback->QuitMessageLoop();
   }
   if (callback->target_loop_ != pp::MessageLoop::GetCurrent()) {
     // Note, in-process, loop_ and GetCurrent() will both be NULL, so should
     // still be equal.
     callback->errors_.assign(
         ReportError("TestCompletionCallback: Callback ran on the wrong message "
                     "loop!",
                     result));
   }
 }

 void TestCompletionCallback::RunMessageLoop() {
   pp::MessageLoop loop(pp::MessageLoop::GetCurrent());
   // If we don't have a message loop, we're probably running in process, where
   // PPB_MessageLoop is not supported. Just use the Testing message loop.
   if (loop.is_null() || loop == pp::MessageLoop::GetForMainThread())
     GetTestingInterface()->RunMessageLoop(instance_);
   else
     loop.Run();
 }

 void TestCompletionCallback::QuitMessageLoop() {
   pp::MessageLoop loop(pp::MessageLoop::GetCurrent());
   // If we don't have a message loop, we're probably running in process, where
   // PPB_MessageLoop is not supported. Just use the Testing message loop.
   if (loop.is_null() || loop == pp::MessageLoop::GetForMainThread()) {
     GetTestingInterface()->QuitMessageLoop(instance_);
   } else {
     const bool should_quit = false;
     loop.PostQuit(should_quit);
   }
 }
	// 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 "ppapi/tests/test_utils.h"

	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#if defined(_MSC_VER)
	#include <windows.h>
	#else
	#include <unistd.h>
	#endif

	#include "ppapi/c/pp_errors.h"
	#include "ppapi/cpp/instance_handle.h"
	#include "ppapi/cpp/module.h"
	#include "ppapi/cpp/net_address.h"
	#include "ppapi/cpp/private/host_resolver_private.h"
	#include "ppapi/cpp/private/net_address_private.h"
	#include "ppapi/cpp/var.h"

	namespace {

	bool IsBigEndian() {
	union {
	uint32_t integer32;
	uint8_t integer8[4];
	} data = { 0x01020304 };

	return data.integer8[0] == 1;
	}

	} // namespace

	const int kActionTimeoutMs = 10000;

	const PPB_Testing_Private* GetTestingInterface() {
	static const PPB_Testing_Private* g_testing_interface =
	static_cast<const PPB_Testing_Private*>(
	pp::Module::Get()->GetBrowserInterface(
	PPB_TESTING_PRIVATE_INTERFACE));
	return g_testing_interface;
	}

	std::string ReportError(const char* method, int32_t error) {
	char error_as_string[12];
	sprintf(error_as_string, "%d", static_cast<int>(error));
	std::string result = method + std::string(" failed with error: ") +
	error_as_string;
	return result;
	}

	void PlatformSleep(int duration_ms) {
	#if defined(_MSC_VER)
	::Sleep(duration_ms);
	#else
	usleep(duration_ms * 1000);
	#endif
	}

	bool GetLocalHostPort(PP_Instance instance, std::string* host, uint16_t* port) {
	if (!host \|\| !port)
	return false;

	const PPB_Testing_Private* testing = GetTestingInterface();
	if (!testing)
	return false;

	PP_URLComponents_Dev components;
	pp::Var pp_url(pp::PASS_REF,
	testing->GetDocumentURL(instance, &components));
	if (!pp_url.is_string())
	return false;
	std::string url = pp_url.AsString();

	if (components.host.len < 0)
	return false;
	host->assign(url.substr(components.host.begin, components.host.len));

	if (components.port.len <= 0)
	return false;

	int i = atoi(url.substr(components.port.begin, components.port.len).c_str());
	if (i < 0 \|\| i > 65535)
	return false;
	*port = static_cast<uint16_t>(i);

	return true;
	}

	uint16_t ConvertFromNetEndian16(uint16_t x) {
	if (IsBigEndian())
	return x;
	else
	return (x << 8) \| (x >> 8);
	}

	uint16_t ConvertToNetEndian16(uint16_t x) {
	if (IsBigEndian())
	return x;
	else
	return (x << 8) \| (x >> 8);
	}

	bool EqualNetAddress(const pp::NetAddress& addr1, const pp::NetAddress& addr2) {
	if (addr1.GetFamily() == PP_NETADDRESS_FAMILY_UNSPECIFIED \|\|
	addr2.GetFamily() == PP_NETADDRESS_FAMILY_UNSPECIFIED) {
	return false;
	}

	if (addr1.GetFamily() == PP_NETADDRESS_FAMILY_IPV4) {
	PP_NetAddress_IPv4 ipv4_addr1, ipv4_addr2;
	if (!addr1.DescribeAsIPv4Address(&ipv4_addr1) \|\|
	!addr2.DescribeAsIPv4Address(&ipv4_addr2)) {
	return false;
	}

	return ipv4_addr1.port == ipv4_addr2.port &&
	!memcmp(ipv4_addr1.addr, ipv4_addr2.addr, sizeof(ipv4_addr1.addr));
	} else {
	PP_NetAddress_IPv6 ipv6_addr1, ipv6_addr2;
	if (!addr1.DescribeAsIPv6Address(&ipv6_addr1) \|\|
	!addr2.DescribeAsIPv6Address(&ipv6_addr2)) {
	return false;
	}

	return ipv6_addr1.port == ipv6_addr2.port &&
	!memcmp(ipv6_addr1.addr, ipv6_addr2.addr, sizeof(ipv6_addr1.addr));
	}
	}

	bool ResolveHost(PP_Instance instance,
	const std::string& host,
	uint16_t port,
	pp::NetAddress* addr) {
	// TODO(yzshen): Change to use the public host resolver once it is supported.
	pp::InstanceHandle instance_handle(instance);
	pp::HostResolverPrivate host_resolver(instance_handle);
	PP_HostResolver_Private_Hint hint =
	{ PP_NETADDRESSFAMILY_PRIVATE_UNSPECIFIED, 0 };

	TestCompletionCallback callback(instance);
	callback.WaitForResult(
	host_resolver.Resolve(host, port, hint, callback.GetCallback()));

	PP_NetAddress_Private addr_private;
	if (callback.result() != PP_OK \|\| host_resolver.GetSize() == 0 \|\|
	!host_resolver.GetNetAddress(0, &addr_private)) {
	return false;
	}

	switch (pp::NetAddressPrivate::GetFamily(addr_private)) {
	case PP_NETADDRESSFAMILY_PRIVATE_IPV4: {
	PP_NetAddress_IPv4 ipv4_addr;
	ipv4_addr.port = ConvertToNetEndian16(
	pp::NetAddressPrivate::GetPort(addr_private));
	if (!pp::NetAddressPrivate::GetAddress(addr_private, ipv4_addr.addr,
	sizeof(ipv4_addr.addr))) {
	return false;
	}
	*addr = pp::NetAddress(instance_handle, ipv4_addr);
	return true;
	}
	case PP_NETADDRESSFAMILY_PRIVATE_IPV6: {
	PP_NetAddress_IPv6 ipv6_addr;
	ipv6_addr.port = ConvertToNetEndian16(
	pp::NetAddressPrivate::GetPort(addr_private));
	if (!pp::NetAddressPrivate::GetAddress(addr_private, ipv6_addr.addr,
	sizeof(ipv6_addr.addr))) {
	return false;
	}
	*addr = pp::NetAddress(instance_handle, ipv6_addr);
	return true;
	}
	default: {
	return false;
	}
	}
	}

	bool ReplacePort(PP_Instance instance,
	const pp::NetAddress& input_addr,
	uint16_t port,
	pp::NetAddress* output_addr) {
	switch (input_addr.GetFamily()) {
	case PP_NETADDRESS_FAMILY_IPV4: {
	PP_NetAddress_IPv4 ipv4_addr;
	if (!input_addr.DescribeAsIPv4Address(&ipv4_addr))
	return false;
	ipv4_addr.port = ConvertToNetEndian16(port);
	*output_addr = pp::NetAddress(pp::InstanceHandle(instance), ipv4_addr);
	return true;
	}
	case PP_NETADDRESS_FAMILY_IPV6: {
	PP_NetAddress_IPv6 ipv6_addr;
	if (!input_addr.DescribeAsIPv6Address(&ipv6_addr))
	return false;
	ipv6_addr.port = ConvertToNetEndian16(port);
	*output_addr = pp::NetAddress(pp::InstanceHandle(instance), ipv6_addr);
	return true;
	}
	default: {
	return false;
	}
	}
	}

	uint16_t GetPort(const pp::NetAddress& addr) {
	switch (addr.GetFamily()) {
	case PP_NETADDRESS_FAMILY_IPV4: {
	PP_NetAddress_IPv4 ipv4_addr;
	if (!addr.DescribeAsIPv4Address(&ipv4_addr))
	return 0;
	return ConvertFromNetEndian16(ipv4_addr.port);
	}
	case PP_NETADDRESS_FAMILY_IPV6: {
	PP_NetAddress_IPv6 ipv6_addr;
	if (!addr.DescribeAsIPv6Address(&ipv6_addr))
	return 0;
	return ConvertFromNetEndian16(ipv6_addr.port);
	}
	default: {
	return 0;
	}
	}
	}

	void NestedEvent::Wait() {
	PP_DCHECK(pp::Module::Get()->core()->IsMainThread());
	// Don't allow nesting more than once; it doesn't work with the code as-is,
	// and probably is a bad idea most of the time anyway.
	PP_DCHECK(!waiting_);
	if (signalled_)
	return;
	waiting_ = true;
	while (!signalled_)
	GetTestingInterface()->RunMessageLoop(instance_);
	waiting_ = false;
	}

	void NestedEvent::Signal() {
	if (pp::Module::Get()->core()->IsMainThread())
	SignalOnMainThread();
	else
	PostSignal(0);
	}

	void NestedEvent::PostSignal(int32_t wait_ms) {
	pp::Module::Get()->core()->CallOnMainThread(
	wait_ms,
	pp::CompletionCallback(&SignalThunk, this),
	0);
	}

	void NestedEvent::Reset() {
	PP_DCHECK(pp::Module::Get()->core()->IsMainThread());
	// It doesn't make sense to reset when we're still waiting.
	PP_DCHECK(!waiting_);
	signalled_ = false;
	}

	void NestedEvent::SignalOnMainThread() {
	PP_DCHECK(pp::Module::Get()->core()->IsMainThread());
	signalled_ = true;
	if (waiting_)
	GetTestingInterface()->QuitMessageLoop(instance_);
	}

	void NestedEvent::SignalThunk(void* event, int32_t /* result */) {
	static_cast<NestedEvent*>(event)->SignalOnMainThread();
	}

	TestCompletionCallback::TestCompletionCallback(PP_Instance instance)
	: wait_for_result_called_(false),
	have_result_(false),
	result_(PP_OK_COMPLETIONPENDING),
	// TODO(dmichael): The default should probably be PP_REQUIRED, but this is
	// what the tests currently expect.
	callback_type_(PP_OPTIONAL),
	post_quit_task_(false),
	instance_(instance),
	delegate_(NULL) {
	}

	TestCompletionCallback::TestCompletionCallback(PP_Instance instance,
	bool force_async)
	: wait_for_result_called_(false),
	have_result_(false),
	result_(PP_OK_COMPLETIONPENDING),
	callback_type_(force_async ? PP_REQUIRED : PP_OPTIONAL),
	post_quit_task_(false),
	instance_(instance),
	delegate_(NULL) {
	}

	TestCompletionCallback::TestCompletionCallback(PP_Instance instance,
	CallbackType callback_type)
	: wait_for_result_called_(false),
	have_result_(false),
	result_(PP_OK_COMPLETIONPENDING),
	callback_type_(callback_type),
	post_quit_task_(false),
	instance_(instance),
	delegate_(NULL) {
	}

	void TestCompletionCallback::WaitForResult(int32_t result) {
	PP_DCHECK(!wait_for_result_called_);
	wait_for_result_called_ = true;
	errors_.clear();
	if (result == PP_OK_COMPLETIONPENDING) {
	if (!have_result_) {
	post_quit_task_ = true;
	RunMessageLoop();
	}
	if (callback_type_ == PP_BLOCKING) {
	errors_.assign(
	ReportError("TestCompletionCallback: Call did not run synchronously "
	"when passed a blocking completion callback!",
	result_));
	return;
	}
	} else {
	result_ = result;
	have_result_ = true;
	if (callback_type_ == PP_REQUIRED) {
	errors_.assign(
	ReportError("TestCompletionCallback: Call ran synchronously when "
	"passed a required completion callback!",
	result_));
	return;
	}
	}
	PP_DCHECK(have_result_ == true);
	}

	void TestCompletionCallback::WaitForAbortResult(int32_t result) {
	WaitForResult(result);
	int32_t final_result = result_;
	if (result == PP_OK_COMPLETIONPENDING) {
	if (final_result != PP_ERROR_ABORTED) {
	errors_.assign(
	ReportError("TestCompletionCallback: Expected PP_ERROR_ABORTED or "
	"PP_OK. Ran asynchronously.",
	final_result));
	return;
	}
	} else if (result < PP_OK) {
	errors_.assign(
	ReportError("TestCompletionCallback: Expected PP_ERROR_ABORTED or "
	"non-error response. Ran synchronously.",
	result));
	return;
	}
	}

	pp::CompletionCallback TestCompletionCallback::GetCallback() {
	Reset();
	int32_t flags = 0;
	if (callback_type_ == PP_BLOCKING)
	return pp::CompletionCallback();
	else if (callback_type_ == PP_OPTIONAL)
	flags = PP_COMPLETIONCALLBACK_FLAG_OPTIONAL;
	target_loop_ = pp::MessageLoop::GetCurrent();
	return pp::CompletionCallback(&TestCompletionCallback::Handler,
	const_cast<TestCompletionCallback*>(this),
	flags);
	}

	void TestCompletionCallback::Reset() {
	wait_for_result_called_ = false;
	result_ = PP_OK_COMPLETIONPENDING;
	have_result_ = false;
	post_quit_task_ = false;
	delegate_ = NULL;
	errors_.clear();
	}

	// static
	void TestCompletionCallback::Handler(void* user_data, int32_t result) {
	TestCompletionCallback* callback =
	static_cast<TestCompletionCallback*>(user_data);
	// If this check fails, it means that the callback was invoked twice or that
	// the PPAPI call completed synchronously, but also ran the callback.
	PP_DCHECK(!callback->have_result_);
	callback->result_ = result;
	callback->have_result_ = true;
	if (callback->delegate_)
	callback->delegate_->OnCallback(user_data, result);
	if (callback->post_quit_task_) {
	callback->post_quit_task_ = false;
	callback->QuitMessageLoop();
	}
	if (callback->target_loop_ != pp::MessageLoop::GetCurrent()) {
	// Note, in-process, loop_ and GetCurrent() will both be NULL, so should
	// still be equal.
	callback->errors_.assign(
	ReportError("TestCompletionCallback: Callback ran on the wrong message "
	"loop!",
	result));
	}
	}

	void TestCompletionCallback::RunMessageLoop() {
	pp::MessageLoop loop(pp::MessageLoop::GetCurrent());
	// If we don't have a message loop, we're probably running in process, where
	// PPB_MessageLoop is not supported. Just use the Testing message loop.
	if (loop.is_null() \|\| loop == pp::MessageLoop::GetForMainThread())
	GetTestingInterface()->RunMessageLoop(instance_);
	else
	loop.Run();
	}

	void TestCompletionCallback::QuitMessageLoop() {
	pp::MessageLoop loop(pp::MessageLoop::GetCurrent());
	// If we don't have a message loop, we're probably running in process, where
	// PPB_MessageLoop is not supported. Just use the Testing message loop.
	if (loop.is_null() \|\| loop == pp::MessageLoop::GetForMainThread()) {
	GetTestingInterface()->QuitMessageLoop(instance_);
	} else {
	const bool should_quit = false;
	loop.PostQuit(should_quit);
	}
	}