ppapi/tests/test_instance_deprecated.cc - platform/external/chromium_org - 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_instance_deprecated.h"

 #include <assert.h>
 #include <iostream>

 #include "ppapi/c/ppb_var.h"
 #include "ppapi/cpp/module.h"
 #include "ppapi/cpp/dev/scriptable_object_deprecated.h"
 #include "ppapi/tests/testing_instance.h"

 namespace {

 static const char kSetValueFunction[] = "SetValue";
 static const char kSetExceptionFunction[] = "SetException";
 static const char kReturnValueFunction[] = "ReturnValue";

 // ScriptableObject used by instance.
 class InstanceSO : public pp::deprecated::ScriptableObject {
  public:
   explicit InstanceSO(TestInstance* i);
   virtual ~InstanceSO();

   // pp::deprecated::ScriptableObject overrides.
   bool HasMethod(const pp::Var& name, pp::Var* exception);
   pp::Var Call(const pp::Var& name,
                const std::vector<pp::Var>& args,
                pp::Var* exception);

  private:
   TestInstance* test_instance_;
   // For out-of-process, the InstanceSO might be deleted after the instance was
   // already destroyed, so we can't rely on test_instance_->testing_interface()
   // being valid. Therefore we store our own.
   const PPB_Testing_Private* testing_interface_;
 };

 InstanceSO::InstanceSO(TestInstance* i)
     : test_instance_(i),
       testing_interface_(i->testing_interface()) {
   // Set up a post-condition for the test so that we can ensure our destructor
   // is called. This only works reliably in-process. Out-of-process, it only
   // can work when the renderer stays alive a short while after the plugin
   // instance is destroyed. If the renderer is being shut down, too much happens
   // asynchronously for the out-of-process case to work reliably. In
   // particular:
   //   - The Var ReleaseObject message is asynchronous.
   //   - The PPB_Var_Deprecated host-side proxy posts a task to actually release
   //     the object when the ReleaseObject message is received.
   //   - The PPP_Class Deallocate message is asynchronous.
   // At time of writing this comment, if you modify the code so that the above
   // happens synchronously, and you remove the restriction that the plugin can't
   // be unblocked by a sync message, then this check actually passes reliably
   // for out-of-process. But we don't want to make any of those changes, so we
   // just skip the check.
   if (testing_interface_->IsOutOfProcess() == PP_FALSE) {
     i->instance()->AddPostCondition(
       "window.document.getElementById('container').instance_object_destroyed"
       );
   }
 }

 InstanceSO::~InstanceSO() {
   if (testing_interface_->IsOutOfProcess() == PP_FALSE) {
     // TODO(dmichael): It would probably be best to make in-process consistent
     //                 with out-of-process. That would mean that the instance
     //                 would already be destroyed at this point.
     pp::Var ret = test_instance_->instance()->ExecuteScript(
         "document.getElementById('container').instance_object_destroyed=true;");
   } else {
     // Out-of-process, this destructor might not actually get invoked. See the
     // comment in InstanceSO's constructor for an explanation. Also, instance()
     // has already been destroyed :-(. So we can't really do anything here.
   }
 }

 bool InstanceSO::HasMethod(const pp::Var& name, pp::Var* exception) {
   if (!name.is_string())
     return false;
   return name.AsString() == kSetValueFunction ||
          name.AsString() == kSetExceptionFunction ||
          name.AsString() == kReturnValueFunction;
 }

 pp::Var InstanceSO::Call(const pp::Var& method_name,
                          const std::vector<pp::Var>& args,
                          pp::Var* exception) {
   if (!method_name.is_string())
     return false;
   std::string name = method_name.AsString();

   if (name == kSetValueFunction) {
     if (args.size() != 1 || !args[0].is_string())
       *exception = pp::Var("Bad argument to SetValue(<string>)");
     else
       test_instance_->set_string(args[0].AsString());
   } else if (name == kSetExceptionFunction) {
     if (args.size() != 1 || !args[0].is_string())
       *exception = pp::Var("Bad argument to SetException(<string>)");
     else
       *exception = args[0];
   } else if (name == kReturnValueFunction) {
     if (args.size() != 1)
       *exception = pp::Var("Need single arg to call ReturnValue");
     else
       return args[0];
   } else {
     *exception = pp::Var("Bad function call");
   }

   return pp::Var();
 }

 }  // namespace

 REGISTER_TEST_CASE(Instance);

 TestInstance::TestInstance(TestingInstance* instance) : TestCase(instance) {
 }

 bool TestInstance::Init() {
   return true;
 }

 TestInstance::~TestInstance() {
   // Save the fact that we were destroyed in sessionStorage. This tests that
   // we can ExecuteScript at instance destruction without crashing. It also
   // allows us to check that ExecuteScript will run and succeed in certain
   // cases. In particular, when the instance is destroyed by normal DOM
   // deletion, ExecuteScript will actually work. See
   // TestExecuteScriptInInstanceShutdown for that test. Note, however, that
   // ExecuteScript will *not* have an effect when the instance is destroyed
   // because the renderer was shut down.
   pp::Var ret = instance()->ExecuteScript(
       "sessionStorage.setItem('instance_destroyed', 'true');");
 }

 void TestInstance::RunTests(const std::string& filter) {
   RUN_TEST(ExecuteScript, filter);
   RUN_TEST(RecursiveObjects, filter);
   RUN_TEST(LeakedObjectDestructors, filter);
   RUN_TEST(SetupExecuteScriptAtInstanceShutdown, filter);
   RUN_TEST(ExecuteScriptAtInstanceShutdown, filter);
 }

 void TestInstance::LeakReferenceAndIgnore(const pp::Var& leaked) {
   static const PPB_Var* var_interface = static_cast<const PPB_Var*>(
         pp::Module::Get()->GetBrowserInterface(PPB_VAR_INTERFACE));
   var_interface->AddRef(leaked.pp_var());
   IgnoreLeakedVar(leaked.pp_var().value.as_id);
 }

 pp::deprecated::ScriptableObject* TestInstance::CreateTestObject() {
   return new InstanceSO(this);
 }

 std::string TestInstance::TestExecuteScript() {
   // Simple call back into the plugin.
   pp::Var exception;
   pp::Var ret = instance_->ExecuteScript(
       "document.getElementById('plugin').SetValue('hello, world');",
       &exception);
   ASSERT_TRUE(ret.is_undefined());
   ASSERT_TRUE(exception.is_undefined());
   ASSERT_TRUE(string_ == "hello, world");

   // Return values from the plugin should be returned.
   ret = instance_->ExecuteScript(
       "document.getElementById('plugin').ReturnValue('return value');",
       &exception);
   ASSERT_TRUE(ret.is_string() && ret.AsString() == "return value");
   ASSERT_TRUE(exception.is_undefined());

   // Exception thrown by the plugin should be caught.
   ret = instance_->ExecuteScript(
       "document.getElementById('plugin').SetException('plugin exception');",
       &exception);
   ASSERT_TRUE(ret.is_undefined());
   ASSERT_TRUE(exception.is_string());
   // Due to a limitation in the implementation of TryCatch, it doesn't actually
   // pass the strings up. Since this is a trusted only interface, we've decided
   // not to bother fixing this for now.

   // Exception caused by string evaluation should be caught.
   exception = pp::Var();
   ret = instance_->ExecuteScript("document.doesntExist()", &exception);
   ASSERT_TRUE(ret.is_undefined());
   ASSERT_TRUE(exception.is_string());  // Don't know exactly what it will say.

   PASS();
 }

 // A scriptable object that contains other scriptable objects recursively. This
 // is used to help verify that our scriptable object clean-up code works
 // properly.
 class ObjectWithChildren : public pp::deprecated::ScriptableObject {
  public:
   ObjectWithChildren(TestInstance* i, int num_descendents) {
     if (num_descendents > 0) {
       child_ = pp::VarPrivate(i->instance(),
                               new ObjectWithChildren(i, num_descendents - 1));
     }
   }
   struct IgnoreLeaks {};
   ObjectWithChildren(TestInstance* i, int num_descendents, IgnoreLeaks) {
     if (num_descendents > 0) {
       child_ = pp::VarPrivate(i->instance(),
                               new ObjectWithChildren(i, num_descendents - 1,
                                                      IgnoreLeaks()));
       i->IgnoreLeakedVar(child_.pp_var().value.as_id);
     }
   }
  private:
   pp::VarPrivate child_;
 };

 std::string TestInstance::TestRecursiveObjects() {
   // These should be deleted when we exit scope, so should not leak.
   pp::VarPrivate not_leaked(instance(), new ObjectWithChildren(this, 50));

   // Leak some, but tell TestCase to ignore the leaks. This test is run and then
   // reloaded (see ppapi_uitest.cc). If these aren't cleaned up when the first
   // run is torn down, they will show up as leaks in the second run.
   // NOTE: The ScriptableObjects are actually leaked, but they should be removed
   //       from the tracker. See below for a test that verifies that the
   //       destructor is not run.
   pp::VarPrivate leaked(
       instance(),
       new ObjectWithChildren(this, 50, ObjectWithChildren::IgnoreLeaks()));
   // Now leak a reference to the root object. This should force the root and
   // all its descendents to stay in the tracker.
   LeakReferenceAndIgnore(leaked);

   PASS();
 }

 // A scriptable object that should cause a crash if its destructor is run. We
 // don't run the destructor for objects which the plugin leaks. This is to
 // prevent them doing dangerous things at cleanup time, such as executing script
 // or creating new objects.
 class BadDestructorObject : public pp::deprecated::ScriptableObject {
  public:
   BadDestructorObject() {}
   ~BadDestructorObject() {
     assert(false);
   }
 };

 std::string TestInstance::TestLeakedObjectDestructors() {
   pp::VarPrivate leaked(instance(), new BadDestructorObject());
   // Leak a reference so it gets deleted on instance shutdown.
   LeakReferenceAndIgnore(leaked);
   PASS();
 }

 std::string TestInstance::TestSetupExecuteScriptAtInstanceShutdown() {
   // This test only exists so that it can be run before
   // TestExecuteScriptAtInstanceShutdown. See the comment for that test.
   pp::Var exception;
   pp::Var result = instance()->ExecuteScript(
       "sessionStorage.removeItem('instance_destroyed');", &exception);
   ASSERT_TRUE(exception.is_undefined());
   ASSERT_TRUE(result.is_undefined());
   PASS();
 }

 std::string TestInstance::TestExecuteScriptAtInstanceShutdown() {
   // This test relies on the previous test being run in the same browser
   // session, but in such a way that the instance is destroyed. See
   // chrome/test/ppapi/ppapi_browsertest.cc for how the navigation happens.
   //
   // Given those constraints, ~TestInstance should have been invoked to set
   // instance_destroyed in sessionStorage. So all we have to do is make sure
   // that it was set as expected.
   pp::Var result = instance()->ExecuteScript(
       "sessionStorage.getItem('instance_destroyed');");
   ASSERT_TRUE(result.is_string());
   ASSERT_EQ(std::string("true"), result.AsString());
   instance()->ExecuteScript("sessionStorage.removeItem('instance_destroyed');");

   PASS();
 }
	// 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_instance_deprecated.h"

	#include <assert.h>
	#include <iostream>

	#include "ppapi/c/ppb_var.h"
	#include "ppapi/cpp/module.h"
	#include "ppapi/cpp/dev/scriptable_object_deprecated.h"
	#include "ppapi/tests/testing_instance.h"

	namespace {

	static const char kSetValueFunction[] = "SetValue";
	static const char kSetExceptionFunction[] = "SetException";
	static const char kReturnValueFunction[] = "ReturnValue";

	// ScriptableObject used by instance.
	class InstanceSO : public pp::deprecated::ScriptableObject {
	public:
	explicit InstanceSO(TestInstance* i);
	virtual ~InstanceSO();

	// pp::deprecated::ScriptableObject overrides.
	bool HasMethod(const pp::Var& name, pp::Var* exception);
	pp::Var Call(const pp::Var& name,
	const std::vector<pp::Var>& args,
	pp::Var* exception);

	private:
	TestInstance* test_instance_;
	// For out-of-process, the InstanceSO might be deleted after the instance was
	// already destroyed, so we can't rely on test_instance_->testing_interface()
	// being valid. Therefore we store our own.
	const PPB_Testing_Private* testing_interface_;
	};

	InstanceSO::InstanceSO(TestInstance* i)
	: test_instance_(i),
	testing_interface_(i->testing_interface()) {
	// Set up a post-condition for the test so that we can ensure our destructor
	// is called. This only works reliably in-process. Out-of-process, it only
	// can work when the renderer stays alive a short while after the plugin
	// instance is destroyed. If the renderer is being shut down, too much happens
	// asynchronously for the out-of-process case to work reliably. In
	// particular:
	// - The Var ReleaseObject message is asynchronous.
	// - The PPB_Var_Deprecated host-side proxy posts a task to actually release
	// the object when the ReleaseObject message is received.
	// - The PPP_Class Deallocate message is asynchronous.
	// At time of writing this comment, if you modify the code so that the above
	// happens synchronously, and you remove the restriction that the plugin can't
	// be unblocked by a sync message, then this check actually passes reliably
	// for out-of-process. But we don't want to make any of those changes, so we
	// just skip the check.
	if (testing_interface_->IsOutOfProcess() == PP_FALSE) {
	i->instance()->AddPostCondition(
	"window.document.getElementById('container').instance_object_destroyed"
	);
	}
	}

	InstanceSO::~InstanceSO() {
	if (testing_interface_->IsOutOfProcess() == PP_FALSE) {
	// TODO(dmichael): It would probably be best to make in-process consistent
	// with out-of-process. That would mean that the instance
	// would already be destroyed at this point.
	pp::Var ret = test_instance_->instance()->ExecuteScript(
	"document.getElementById('container').instance_object_destroyed=true;");
	} else {
	// Out-of-process, this destructor might not actually get invoked. See the
	// comment in InstanceSO's constructor for an explanation. Also, instance()
	// has already been destroyed :-(. So we can't really do anything here.
	}
	}

	bool InstanceSO::HasMethod(const pp::Var& name, pp::Var* exception) {
	if (!name.is_string())
	return false;
	return name.AsString() == kSetValueFunction \|\|
	name.AsString() == kSetExceptionFunction \|\|
	name.AsString() == kReturnValueFunction;
	}

	pp::Var InstanceSO::Call(const pp::Var& method_name,
	const std::vector<pp::Var>& args,
	pp::Var* exception) {
	if (!method_name.is_string())
	return false;
	std::string name = method_name.AsString();

	if (name == kSetValueFunction) {
	if (args.size() != 1 \|\| !args[0].is_string())
	*exception = pp::Var("Bad argument to SetValue(<string>)");
	else
	test_instance_->set_string(args[0].AsString());
	} else if (name == kSetExceptionFunction) {
	if (args.size() != 1 \|\| !args[0].is_string())
	*exception = pp::Var("Bad argument to SetException(<string>)");
	else
	*exception = args[0];
	} else if (name == kReturnValueFunction) {
	if (args.size() != 1)
	*exception = pp::Var("Need single arg to call ReturnValue");
	else
	return args[0];
	} else {
	*exception = pp::Var("Bad function call");
	}

	return pp::Var();
	}

	} // namespace

	REGISTER_TEST_CASE(Instance);

	TestInstance::TestInstance(TestingInstance* instance) : TestCase(instance) {
	}

	bool TestInstance::Init() {
	return true;
	}

	TestInstance::~TestInstance() {
	// Save the fact that we were destroyed in sessionStorage. This tests that
	// we can ExecuteScript at instance destruction without crashing. It also
	// allows us to check that ExecuteScript will run and succeed in certain
	// cases. In particular, when the instance is destroyed by normal DOM
	// deletion, ExecuteScript will actually work. See
	// TestExecuteScriptInInstanceShutdown for that test. Note, however, that
	// ExecuteScript will not have an effect when the instance is destroyed
	// because the renderer was shut down.
	pp::Var ret = instance()->ExecuteScript(
	"sessionStorage.setItem('instance_destroyed', 'true');");
	}

	void TestInstance::RunTests(const std::string& filter) {
	RUN_TEST(ExecuteScript, filter);
	RUN_TEST(RecursiveObjects, filter);
	RUN_TEST(LeakedObjectDestructors, filter);
	RUN_TEST(SetupExecuteScriptAtInstanceShutdown, filter);
	RUN_TEST(ExecuteScriptAtInstanceShutdown, filter);
	}

	void TestInstance::LeakReferenceAndIgnore(const pp::Var& leaked) {
	static const PPB_Var* var_interface = static_cast<const PPB_Var*>(
	pp::Module::Get()->GetBrowserInterface(PPB_VAR_INTERFACE));
	var_interface->AddRef(leaked.pp_var());
	IgnoreLeakedVar(leaked.pp_var().value.as_id);
	}

	pp::deprecated::ScriptableObject* TestInstance::CreateTestObject() {
	return new InstanceSO(this);
	}

	std::string TestInstance::TestExecuteScript() {
	// Simple call back into the plugin.
	pp::Var exception;
	pp::Var ret = instance_->ExecuteScript(
	"document.getElementById('plugin').SetValue('hello, world');",
	&exception);
	ASSERT_TRUE(ret.is_undefined());
	ASSERT_TRUE(exception.is_undefined());
	ASSERT_TRUE(string_ == "hello, world");

	// Return values from the plugin should be returned.
	ret = instance_->ExecuteScript(
	"document.getElementById('plugin').ReturnValue('return value');",
	&exception);
	ASSERT_TRUE(ret.is_string() && ret.AsString() == "return value");
	ASSERT_TRUE(exception.is_undefined());

	// Exception thrown by the plugin should be caught.
	ret = instance_->ExecuteScript(
	"document.getElementById('plugin').SetException('plugin exception');",
	&exception);
	ASSERT_TRUE(ret.is_undefined());
	ASSERT_TRUE(exception.is_string());
	// Due to a limitation in the implementation of TryCatch, it doesn't actually
	// pass the strings up. Since this is a trusted only interface, we've decided
	// not to bother fixing this for now.

	// Exception caused by string evaluation should be caught.
	exception = pp::Var();
	ret = instance_->ExecuteScript("document.doesntExist()", &exception);
	ASSERT_TRUE(ret.is_undefined());
	ASSERT_TRUE(exception.is_string()); // Don't know exactly what it will say.

	PASS();
	}

	// A scriptable object that contains other scriptable objects recursively. This
	// is used to help verify that our scriptable object clean-up code works
	// properly.
	class ObjectWithChildren : public pp::deprecated::ScriptableObject {
	public:
	ObjectWithChildren(TestInstance* i, int num_descendents) {
	if (num_descendents > 0) {
	child_ = pp::VarPrivate(i->instance(),
	new ObjectWithChildren(i, num_descendents - 1));
	}
	}
	struct IgnoreLeaks {};
	ObjectWithChildren(TestInstance* i, int num_descendents, IgnoreLeaks) {
	if (num_descendents > 0) {
	child_ = pp::VarPrivate(i->instance(),
	new ObjectWithChildren(i, num_descendents - 1,
	IgnoreLeaks()));
	i->IgnoreLeakedVar(child_.pp_var().value.as_id);
	}
	}
	private:
	pp::VarPrivate child_;
	};

	std::string TestInstance::TestRecursiveObjects() {
	// These should be deleted when we exit scope, so should not leak.
	pp::VarPrivate not_leaked(instance(), new ObjectWithChildren(this, 50));

	// Leak some, but tell TestCase to ignore the leaks. This test is run and then
	// reloaded (see ppapi_uitest.cc). If these aren't cleaned up when the first
	// run is torn down, they will show up as leaks in the second run.
	// NOTE: The ScriptableObjects are actually leaked, but they should be removed
	// from the tracker. See below for a test that verifies that the
	// destructor is not run.
	pp::VarPrivate leaked(
	instance(),
	new ObjectWithChildren(this, 50, ObjectWithChildren::IgnoreLeaks()));
	// Now leak a reference to the root object. This should force the root and
	// all its descendents to stay in the tracker.
	LeakReferenceAndIgnore(leaked);

	PASS();
	}

	// A scriptable object that should cause a crash if its destructor is run. We
	// don't run the destructor for objects which the plugin leaks. This is to
	// prevent them doing dangerous things at cleanup time, such as executing script
	// or creating new objects.
	class BadDestructorObject : public pp::deprecated::ScriptableObject {
	public:
	BadDestructorObject() {}
	~BadDestructorObject() {
	assert(false);
	}
	};

	std::string TestInstance::TestLeakedObjectDestructors() {
	pp::VarPrivate leaked(instance(), new BadDestructorObject());
	// Leak a reference so it gets deleted on instance shutdown.
	LeakReferenceAndIgnore(leaked);
	PASS();
	}

	std::string TestInstance::TestSetupExecuteScriptAtInstanceShutdown() {
	// This test only exists so that it can be run before
	// TestExecuteScriptAtInstanceShutdown. See the comment for that test.
	pp::Var exception;
	pp::Var result = instance()->ExecuteScript(
	"sessionStorage.removeItem('instance_destroyed');", &exception);
	ASSERT_TRUE(exception.is_undefined());
	ASSERT_TRUE(result.is_undefined());
	PASS();
	}

	std::string TestInstance::TestExecuteScriptAtInstanceShutdown() {
	// This test relies on the previous test being run in the same browser
	// session, but in such a way that the instance is destroyed. See
	// chrome/test/ppapi/ppapi_browsertest.cc for how the navigation happens.
	//
	// Given those constraints, ~TestInstance should have been invoked to set
	// instance_destroyed in sessionStorage. So all we have to do is make sure
	// that it was set as expected.
	pp::Var result = instance()->ExecuteScript(
	"sessionStorage.getItem('instance_destroyed');");
	ASSERT_TRUE(result.is_string());
	ASSERT_EQ(std::string("true"), result.AsString());
	instance()->ExecuteScript("sessionStorage.removeItem('instance_destroyed');");

	PASS();
	}