services/inputflinger/InputManager.cpp - LeafOS-Project/android_frameworks_native - Gitiles

 /*
  * Copyright (C) 2010 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #define LOG_TAG "InputManager"

 //#define LOG_NDEBUG 0

 #include "InputManager.h"
 #include "InputDispatcherFactory.h"
 #include "InputReaderFactory.h"
 #include "UnwantedInteractionBlocker.h"

 #include <aidl/com/android/server/inputflinger/IInputFlingerRust.h>
 #include <android/binder_interface_utils.h>
 #include <android/sysprop/InputProperties.sysprop.h>
 #include <binder/IPCThreadState.h>
 #include <com_android_input_flags.h>
 #include <inputflinger_bootstrap.rs.h>
 #include <log/log.h>
 #include <private/android_filesystem_config.h>

 namespace input_flags = com::android::input::flags;

 namespace android {

 namespace {

 const bool ENABLE_INPUT_DEVICE_USAGE_METRICS =
         sysprop::InputProperties::enable_input_device_usage_metrics().value_or(true);

 const bool ENABLE_POINTER_CHOREOGRAPHER = input_flags::enable_pointer_choreographer();
 const bool ENABLE_INPUT_FILTER_RUST = input_flags::enable_input_filter_rust_impl();

 int32_t exceptionCodeFromStatusT(status_t status) {
     switch (status) {
         case OK:
             return binder::Status::EX_NONE;
         case INVALID_OPERATION:
             return binder::Status::EX_UNSUPPORTED_OPERATION;
         case BAD_VALUE:
         case BAD_TYPE:
         case NAME_NOT_FOUND:
             return binder::Status::EX_ILLEGAL_ARGUMENT;
         case NO_INIT:
             return binder::Status::EX_ILLEGAL_STATE;
         case PERMISSION_DENIED:
             return binder::Status::EX_SECURITY;
         default:
             return binder::Status::EX_TRANSACTION_FAILED;
     }
 }

 // Convert a binder interface into a raw pointer to an AIBinder.
 using IInputFlingerRustBootstrapCallback = aidl::com::android::server::inputflinger::
         IInputFlingerRust::IInputFlingerRustBootstrapCallback;
 IInputFlingerRustBootstrapCallbackAIBinder* binderToPointer(
         IInputFlingerRustBootstrapCallback& interface) {
     ndk::SpAIBinder spAIBinder = interface.asBinder();
     auto* ptr = spAIBinder.get();
     AIBinder_incStrong(ptr);
     return ptr;
 }

 // Create the Rust component of InputFlinger that uses AIDL interfaces as a the foreign function
 // interface (FFI). The bootstraping process for IInputFlingerRust is as follows:
 //   - Create BnInputFlingerRustBootstrapCallback in C++.
 //   - Use the cxxbridge ffi interface to call the Rust function `create_inputflinger_rust()`, and
 //     pass the callback binder object as a raw pointer.
 //   - The Rust implementation will create the implementation of IInputFlingerRust, and pass it
 //     to C++ through the callback.
 //   - After the Rust function returns, the binder interface provided to the callback will be the
 //     only strong reference to the IInputFlingerRust.
 std::shared_ptr<IInputFlingerRust> createInputFlingerRust() {
     using namespace aidl::com::android::server::inputflinger;

     class Callback : public IInputFlingerRust::BnInputFlingerRustBootstrapCallback {
         ndk::ScopedAStatus onProvideInputFlingerRust(
                 const std::shared_ptr<IInputFlingerRust>& inputFlingerRust) override {
             mService = inputFlingerRust;
             return ndk::ScopedAStatus::ok();
         }

     public:
         std::shared_ptr<IInputFlingerRust> consumeInputFlingerRust() {
             auto service = mService;
             mService.reset();
             return service;
         }

     private:
         std::shared_ptr<IInputFlingerRust> mService;
     };

     auto callback = ndk::SharedRefBase::make<Callback>();
     create_inputflinger_rust(binderToPointer(*callback));
     auto service = callback->consumeInputFlingerRust();
     LOG_ALWAYS_FATAL_IF(!service,
                         "create_inputflinger_rust did not provide the IInputFlingerRust "
                         "implementation through the callback.");
     return service;
 }

 } // namespace

 /**
  * The event flow is via the "InputListener" interface, as follows:
  *   InputReader
  *     -> UnwantedInteractionBlocker
  *     -> InputFilter
  *     -> PointerChoreographer
  *     -> InputProcessor
  *     -> InputDeviceMetricsCollector
  *     -> InputDispatcher
  */
 InputManager::InputManager(const sp<InputReaderPolicyInterface>& readerPolicy,
                            InputDispatcherPolicyInterface& dispatcherPolicy,
                            PointerChoreographerPolicyInterface& choreographerPolicy,
                            InputFilterPolicyInterface& inputFilterPolicy) {
     mInputFlingerRust = createInputFlingerRust();

     mDispatcher = createInputDispatcher(dispatcherPolicy);
     mTracingStages.emplace_back(
             std::make_unique<TracedInputListener>("InputDispatcher", *mDispatcher));

     if (ENABLE_INPUT_FILTER_RUST) {
         mInputFilter = std::make_unique<InputFilter>(*mTracingStages.back(), *mInputFlingerRust,
                                                      inputFilterPolicy);
         mTracingStages.emplace_back(
                 std::make_unique<TracedInputListener>("InputFilter", *mInputFilter));
     }

     if (ENABLE_INPUT_DEVICE_USAGE_METRICS) {
         mCollector = std::make_unique<InputDeviceMetricsCollector>(*mTracingStages.back());
         mTracingStages.emplace_back(
                 std::make_unique<TracedInputListener>("MetricsCollector", *mCollector));
     }

     mProcessor = std::make_unique<InputProcessor>(*mTracingStages.back());
     mTracingStages.emplace_back(
             std::make_unique<TracedInputListener>("InputProcessor", *mProcessor));

     if (ENABLE_POINTER_CHOREOGRAPHER) {
         mChoreographer =
                 std::make_unique<PointerChoreographer>(*mTracingStages.back(), choreographerPolicy);
         mTracingStages.emplace_back(
                 std::make_unique<TracedInputListener>("PointerChoreographer", *mChoreographer));
     }

     mBlocker = std::make_unique<UnwantedInteractionBlocker>(*mTracingStages.back());
     mTracingStages.emplace_back(
             std::make_unique<TracedInputListener>("UnwantedInteractionBlocker", *mBlocker));

     mReader = createInputReader(readerPolicy, *mTracingStages.back());
 }

 InputManager::~InputManager() {
     stop();
 }

 status_t InputManager::start() {
     status_t result = mDispatcher->start();
     if (result) {
         ALOGE("Could not start InputDispatcher thread due to error %d.", result);
         return result;
     }

     result = mReader->start();
     if (result) {
         ALOGE("Could not start InputReader due to error %d.", result);

         mDispatcher->stop();
         return result;
     }

     return OK;
 }

 status_t InputManager::stop() {
     status_t status = OK;

     status_t result = mReader->stop();
     if (result) {
         ALOGW("Could not stop InputReader due to error %d.", result);
         status = result;
     }

     result = mDispatcher->stop();
     if (result) {
         ALOGW("Could not stop InputDispatcher thread due to error %d.", result);
         status = result;
     }

     return status;
 }

 InputReaderInterface& InputManager::getReader() {
     return *mReader;
 }

 PointerChoreographerInterface& InputManager::getChoreographer() {
     return *mChoreographer;
 }

 InputProcessorInterface& InputManager::getProcessor() {
     return *mProcessor;
 }

 InputDeviceMetricsCollectorInterface& InputManager::getMetricsCollector() {
     return *mCollector;
 }

 InputDispatcherInterface& InputManager::getDispatcher() {
     return *mDispatcher;
 }

 InputFilterInterface& InputManager::getInputFilter() {
     return *mInputFilter;
 }

 void InputManager::monitor() {
     mReader->monitor();
     mBlocker->monitor();
     mProcessor->monitor();
     if (ENABLE_INPUT_DEVICE_USAGE_METRICS) {
         mCollector->monitor();
     }
     mDispatcher->monitor();
 }

 void InputManager::dump(std::string& dump) {
     mReader->dump(dump);
     dump += '\n';
     mBlocker->dump(dump);
     dump += '\n';
     if (ENABLE_POINTER_CHOREOGRAPHER) {
         mChoreographer->dump(dump);
         dump += '\n';
     }
     mProcessor->dump(dump);
     dump += '\n';
     if (ENABLE_INPUT_DEVICE_USAGE_METRICS) {
         mCollector->dump(dump);
         dump += '\n';
     }
     mDispatcher->dump(dump);
     dump += '\n';
 }

 // Used by tests only.
 binder::Status InputManager::createInputChannel(const std::string& name,
                                                 android::os::InputChannelCore* outChannel) {
     IPCThreadState* ipc = IPCThreadState::self();
     const uid_t uid = ipc->getCallingUid();
     if (uid != AID_SHELL && uid != AID_ROOT) {
         LOG(ERROR) << __func__ << " can only be called by SHELL or ROOT users, "
                    << "but was called from UID " << uid;
         return binder::Status::
                 fromExceptionCode(EX_SECURITY,
                                   "This uid is not allowed to call createInputChannel");
     }

     base::Result<std::unique_ptr<InputChannel>> channel = mDispatcher->createInputChannel(name);
     if (!channel.ok()) {
         return binder::Status::fromExceptionCode(exceptionCodeFromStatusT(channel.error().code()),
                                                  channel.error().message().c_str());
     }
     InputChannel::moveChannel(std::move(*channel), *outChannel);
     return binder::Status::ok();
 }

 binder::Status InputManager::removeInputChannel(const sp<IBinder>& connectionToken) {
     mDispatcher->removeInputChannel(connectionToken);
     return binder::Status::ok();
 }

 status_t InputManager::dump(int fd, const Vector<String16>& args) {
     std::string dump;

     dump += " InputFlinger dump\n";

     TEMP_FAILURE_RETRY(::write(fd, dump.c_str(), dump.size()));
     return NO_ERROR;
 }

 binder::Status InputManager::setFocusedWindow(const gui::FocusRequest& request) {
     mDispatcher->setFocusedWindow(request);
     return binder::Status::ok();
 }

 } // namespace android
	/*
	* Copyright (C) 2010 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#define LOG_TAG "InputManager"

	//#define LOG_NDEBUG 0

	#include "InputManager.h"
	#include "InputDispatcherFactory.h"
	#include "InputReaderFactory.h"
	#include "UnwantedInteractionBlocker.h"

	#include <aidl/com/android/server/inputflinger/IInputFlingerRust.h>
	#include <android/binder_interface_utils.h>
	#include <android/sysprop/InputProperties.sysprop.h>
	#include <binder/IPCThreadState.h>
	#include <com_android_input_flags.h>
	#include <inputflinger_bootstrap.rs.h>
	#include <log/log.h>
	#include <private/android_filesystem_config.h>

	namespace input_flags = com::android::input::flags;

	namespace android {

	namespace {

	const bool ENABLE_INPUT_DEVICE_USAGE_METRICS =
	sysprop::InputProperties::enable_input_device_usage_metrics().value_or(true);

	const bool ENABLE_POINTER_CHOREOGRAPHER = input_flags::enable_pointer_choreographer();
	const bool ENABLE_INPUT_FILTER_RUST = input_flags::enable_input_filter_rust_impl();

	int32_t exceptionCodeFromStatusT(status_t status) {
	switch (status) {
	case OK:
	return binder::Status::EX_NONE;
	case INVALID_OPERATION:
	return binder::Status::EX_UNSUPPORTED_OPERATION;
	case BAD_VALUE:
	case BAD_TYPE:
	case NAME_NOT_FOUND:
	return binder::Status::EX_ILLEGAL_ARGUMENT;
	case NO_INIT:
	return binder::Status::EX_ILLEGAL_STATE;
	case PERMISSION_DENIED:
	return binder::Status::EX_SECURITY;
	default:
	return binder::Status::EX_TRANSACTION_FAILED;
	}
	}

	// Convert a binder interface into a raw pointer to an AIBinder.
	using IInputFlingerRustBootstrapCallback = aidl::com::android::server::inputflinger::
	IInputFlingerRust::IInputFlingerRustBootstrapCallback;
	IInputFlingerRustBootstrapCallbackAIBinder* binderToPointer(
	IInputFlingerRustBootstrapCallback& interface) {
	ndk::SpAIBinder spAIBinder = interface.asBinder();
	auto* ptr = spAIBinder.get();
	AIBinder_incStrong(ptr);
	return ptr;
	}

	// Create the Rust component of InputFlinger that uses AIDL interfaces as a the foreign function
	// interface (FFI). The bootstraping process for IInputFlingerRust is as follows:
	// - Create BnInputFlingerRustBootstrapCallback in C++.
	// - Use the cxxbridge ffi interface to call the Rust function `create_inputflinger_rust()`, and
	// pass the callback binder object as a raw pointer.
	// - The Rust implementation will create the implementation of IInputFlingerRust, and pass it
	// to C++ through the callback.
	// - After the Rust function returns, the binder interface provided to the callback will be the
	// only strong reference to the IInputFlingerRust.
	std::shared_ptr<IInputFlingerRust> createInputFlingerRust() {
	using namespace aidl::com::android::server::inputflinger;

	class Callback : public IInputFlingerRust::BnInputFlingerRustBootstrapCallback {
	ndk::ScopedAStatus onProvideInputFlingerRust(
	const std::shared_ptr<IInputFlingerRust>& inputFlingerRust) override {
	mService = inputFlingerRust;
	return ndk::ScopedAStatus::ok();
	}

	public:
	std::shared_ptr<IInputFlingerRust> consumeInputFlingerRust() {
	auto service = mService;
	mService.reset();
	return service;
	}

	private:
	std::shared_ptr<IInputFlingerRust> mService;
	};

	auto callback = ndk::SharedRefBase::make<Callback>();
	create_inputflinger_rust(binderToPointer(*callback));
	auto service = callback->consumeInputFlingerRust();
	LOG_ALWAYS_FATAL_IF(!service,
	"create_inputflinger_rust did not provide the IInputFlingerRust "
	"implementation through the callback.");
	return service;
	}

	} // namespace

	/**
	* The event flow is via the "InputListener" interface, as follows:
	* InputReader
	* -> UnwantedInteractionBlocker
	* -> InputFilter
	* -> PointerChoreographer
	* -> InputProcessor
	* -> InputDeviceMetricsCollector
	* -> InputDispatcher
	*/
	InputManager::InputManager(const sp<InputReaderPolicyInterface>& readerPolicy,
	InputDispatcherPolicyInterface& dispatcherPolicy,
	PointerChoreographerPolicyInterface& choreographerPolicy,
	InputFilterPolicyInterface& inputFilterPolicy) {
	mInputFlingerRust = createInputFlingerRust();

	mDispatcher = createInputDispatcher(dispatcherPolicy);
	mTracingStages.emplace_back(
	std::make_unique<TracedInputListener>("InputDispatcher", *mDispatcher));

	if (ENABLE_INPUT_FILTER_RUST) {
	mInputFilter = std::make_unique<InputFilter>(mTracingStages.back(), mInputFlingerRust,
	inputFilterPolicy);
	mTracingStages.emplace_back(
	std::make_unique<TracedInputListener>("InputFilter", *mInputFilter));
	}

	if (ENABLE_INPUT_DEVICE_USAGE_METRICS) {
	mCollector = std::make_unique<InputDeviceMetricsCollector>(*mTracingStages.back());
	mTracingStages.emplace_back(
	std::make_unique<TracedInputListener>("MetricsCollector", *mCollector));
	}

	mProcessor = std::make_unique<InputProcessor>(*mTracingStages.back());
	mTracingStages.emplace_back(
	std::make_unique<TracedInputListener>("InputProcessor", *mProcessor));

	if (ENABLE_POINTER_CHOREOGRAPHER) {
	mChoreographer =
	std::make_unique<PointerChoreographer>(*mTracingStages.back(), choreographerPolicy);
	mTracingStages.emplace_back(
	std::make_unique<TracedInputListener>("PointerChoreographer", *mChoreographer));
	}

	mBlocker = std::make_unique<UnwantedInteractionBlocker>(*mTracingStages.back());
	mTracingStages.emplace_back(
	std::make_unique<TracedInputListener>("UnwantedInteractionBlocker", *mBlocker));

	mReader = createInputReader(readerPolicy, *mTracingStages.back());
	}

	InputManager::~InputManager() {
	stop();
	}

	status_t InputManager::start() {
	status_t result = mDispatcher->start();
	if (result) {
	ALOGE("Could not start InputDispatcher thread due to error %d.", result);
	return result;
	}

	result = mReader->start();
	if (result) {
	ALOGE("Could not start InputReader due to error %d.", result);

	mDispatcher->stop();
	return result;
	}

	return OK;
	}

	status_t InputManager::stop() {
	status_t status = OK;

	status_t result = mReader->stop();
	if (result) {
	ALOGW("Could not stop InputReader due to error %d.", result);
	status = result;
	}

	result = mDispatcher->stop();
	if (result) {
	ALOGW("Could not stop InputDispatcher thread due to error %d.", result);
	status = result;
	}

	return status;
	}

	InputReaderInterface& InputManager::getReader() {
	return *mReader;
	}

	PointerChoreographerInterface& InputManager::getChoreographer() {
	return *mChoreographer;
	}

	InputProcessorInterface& InputManager::getProcessor() {
	return *mProcessor;
	}

	InputDeviceMetricsCollectorInterface& InputManager::getMetricsCollector() {
	return *mCollector;
	}

	InputDispatcherInterface& InputManager::getDispatcher() {
	return *mDispatcher;
	}

	InputFilterInterface& InputManager::getInputFilter() {
	return *mInputFilter;
	}

	void InputManager::monitor() {
	mReader->monitor();
	mBlocker->monitor();
	mProcessor->monitor();
	if (ENABLE_INPUT_DEVICE_USAGE_METRICS) {
	mCollector->monitor();
	}
	mDispatcher->monitor();
	}

	void InputManager::dump(std::string& dump) {
	mReader->dump(dump);
	dump += '\n';
	mBlocker->dump(dump);
	dump += '\n';
	if (ENABLE_POINTER_CHOREOGRAPHER) {
	mChoreographer->dump(dump);
	dump += '\n';
	}
	mProcessor->dump(dump);
	dump += '\n';
	if (ENABLE_INPUT_DEVICE_USAGE_METRICS) {
	mCollector->dump(dump);
	dump += '\n';
	}
	mDispatcher->dump(dump);
	dump += '\n';
	}

	// Used by tests only.
	binder::Status InputManager::createInputChannel(const std::string& name,
	android::os::InputChannelCore* outChannel) {
	IPCThreadState* ipc = IPCThreadState::self();
	const uid_t uid = ipc->getCallingUid();
	if (uid != AID_SHELL && uid != AID_ROOT) {
	LOG(ERROR) << __func__ << " can only be called by SHELL or ROOT users, "
	<< "but was called from UID " << uid;
	return binder::Status::
	fromExceptionCode(EX_SECURITY,
	"This uid is not allowed to call createInputChannel");
	}

	base::Result<std::unique_ptr<InputChannel>> channel = mDispatcher->createInputChannel(name);
	if (!channel.ok()) {
	return binder::Status::fromExceptionCode(exceptionCodeFromStatusT(channel.error().code()),
	channel.error().message().c_str());
	}
	InputChannel::moveChannel(std::move(channel), outChannel);
	return binder::Status::ok();
	}

	binder::Status InputManager::removeInputChannel(const sp<IBinder>& connectionToken) {
	mDispatcher->removeInputChannel(connectionToken);
	return binder::Status::ok();
	}

	status_t InputManager::dump(int fd, const Vector<String16>& args) {
	std::string dump;

	dump += " InputFlinger dump\n";

	TEMP_FAILURE_RETRY(::write(fd, dump.c_str(), dump.size()));
	return NO_ERROR;
	}

	binder::Status InputManager::setFocusedWindow(const gui::FocusRequest& request) {
	mDispatcher->setFocusedWindow(request);
	return binder::Status::ok();
	}

	} // namespace android