base/include/hidl/HidlSupport.h - android_system_libhidl - Gitiles

 /*
  * Copyright (C) 2016 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.
  */

 #ifndef ANDROID_HIDL_SUPPORT_H
 #define ANDROID_HIDL_SUPPORT_H

 #include <algorithm>
 #include <dirent.h>
 #include <dlfcn.h>
 #include <iterator>
 #include <cutils/native_handle.h>
 #include <cutils/properties.h>
 #include <functional>
 #include <hidl/HidlInternal.h>
 #include <hidl/Status.h>
 #include <map>
 #include <tuple>
 #include <utils/Errors.h>
 #include <utils/RefBase.h>
 #include <utils/StrongPointer.h>
 #include <vector>

 namespace android {
 namespace hardware {

 // hidl_handle wraps a pointer to a native_handle_t in a hidl_pointer,
 // so that it can safely be transferred between 32-bit and 64-bit processes.
 struct hidl_handle {
     hidl_handle() {
         mHandle = nullptr;
     }
     ~hidl_handle() {
     }

     // copy constructors.
     hidl_handle(const native_handle_t *handle) {
         mHandle = handle;
     }

     hidl_handle(const hidl_handle &other) {
         mHandle = other.mHandle;
     }

     // move constructor.
     hidl_handle(hidl_handle &&other) {
         *this = std::move(other);
     }

     // assingment operators
     hidl_handle &operator=(const hidl_handle &other) {
         mHandle = other.mHandle;
         return *this;
     }

     hidl_handle &operator=(const native_handle_t *native_handle) {
         mHandle = native_handle;
         return *this;
     }

     hidl_handle &operator=(hidl_handle &&other) {
         mHandle = other.mHandle;
         other.mHandle = nullptr;
         return *this;
     }

     const native_handle_t* operator->() const {
         return mHandle;
     }
     // implicit conversion to const native_handle_t*
     operator const native_handle_t *() const {
         return mHandle;
     }
     // explicit conversion
     const native_handle_t *getNativeHandle() const {
         return mHandle;
     }
 private:
     details::hidl_pointer<const native_handle_t> mHandle;
 };

 struct hidl_string {
     hidl_string();
     ~hidl_string();

     // copy constructor.
     hidl_string(const hidl_string &);
     // copy from a C-style string.
     hidl_string(const char *);
     // copy from an std::string.
     hidl_string(const std::string &);

     // move constructor.
     hidl_string(hidl_string &&);

     const char *c_str() const;
     size_t size() const;
     bool empty() const;

     // copy assignment operator.
     hidl_string &operator=(const hidl_string &);
     // copy from a C-style string.
     hidl_string &operator=(const char *s);
     // copy from an std::string.
     hidl_string &operator=(const std::string &);
     // move assignment operator.
     hidl_string &operator=(hidl_string &&other);
     // cast to std::string.
     operator std::string() const;
     // cast to C-style string. Caller is responsible
     // to maintain this hidl_string alive.
     operator const char *() const;

     void clear();

     // Reference an external char array. Ownership is _not_ transferred.
     // Caller is responsible for ensuring that underlying memory is valid
     // for the lifetime of this hidl_string.
     void setToExternal(const char *data, size_t size);

     // offsetof(hidl_string, mBuffer) exposed since mBuffer is private.
     static const size_t kOffsetOfBuffer;

 private:
     details::hidl_pointer<const char> mBuffer;
     uint32_t mSize;  // NOT including the terminating '\0'.
     bool mOwnsBuffer; // if true then mBuffer is a mutable char *

     // copy from data with size. Assume that my memory is freed
     // (through clear(), for example)
     void copyFrom(const char *data, size_t size);
     // move from another hidl_string
     void moveFrom(hidl_string &&);
 };

 inline bool operator==(const hidl_string &hs1, const hidl_string &hs2) {
     return strcmp(hs1.c_str(), hs2.c_str()) == 0;
 }

 inline bool operator!=(const hidl_string &hs1, const hidl_string &hs2) {
     return !(hs1 == hs2);
 }

 inline bool operator==(const hidl_string &hs, const char *s) {
     return strcmp(hs.c_str(), s) == 0;
 }

 inline bool operator!=(const hidl_string &hs, const char *s) {
     return !(hs == s);
 }

 inline bool operator==(const char *s, const hidl_string &hs) {
     return strcmp(hs.c_str(), s) == 0;
 }

 inline bool operator!=(const char *s, const hidl_string &hs) {
     return !(s == hs);
 }

 ////////////////////////////////////////////////////////////////////////////////

 template<typename T>
 struct hidl_vec : private details::hidl_log_base {
     hidl_vec()
         : mBuffer(NULL),
           mSize(0),
           mOwnsBuffer(true) {
     }

     hidl_vec(const hidl_vec<T> &other) : hidl_vec() {
         *this = other;
     }

     hidl_vec(hidl_vec<T> &&other)
     : mOwnsBuffer(false) {
         *this = std::move(other);
     }

     hidl_vec(const std::initializer_list<T> list)
             : mSize(list.size()),
               mOwnsBuffer(true) {
         mBuffer = new T[mSize];

         size_t idx = 0;
         for (auto it = list.begin(); it != list.end(); ++it) {
             mBuffer[idx++] = *it;
         }
     }

     hidl_vec(const std::vector<T> &other) : hidl_vec() {
         *this = other;
     }

     ~hidl_vec() {
         if (mOwnsBuffer) {
             delete[] mBuffer;
         }
         mBuffer = NULL;
     }

     // Reference an existing array, optionally taking ownership. It is the
     // caller's responsibility to ensure that the underlying memory stays
     // valid for the lifetime of this hidl_vec.
     void setToExternal(T *data, size_t size, bool shouldOwn = false) {
         if (mOwnsBuffer) {
             delete [] mBuffer;
         }
         mBuffer = data;
         if (size > UINT32_MAX) {
             logAlwaysFatal("external vector size exceeds 2^32 elements.");
         }
         mSize = static_cast<uint32_t>(size);
         mOwnsBuffer = shouldOwn;
     }

     T *data() {
         return mBuffer;
     }

     const T *data() const {
         return mBuffer;
     }

     T *releaseData() {
         if (!mOwnsBuffer && mSize > 0) {
             resize(mSize);
         }
         mOwnsBuffer = false;
         return mBuffer;
     }

     hidl_vec &operator=(hidl_vec &&other) {
         if (mOwnsBuffer) {
             delete[] mBuffer;
         }
         mBuffer = other.mBuffer;
         mSize = other.mSize;
         mOwnsBuffer = other.mOwnsBuffer;
         other.mOwnsBuffer = false;
         return *this;
     }

     hidl_vec &operator=(const hidl_vec &other) {
         if (this != &other) {
             if (mOwnsBuffer) {
                 delete[] mBuffer;
             }
             copyFrom(other, other.mSize);
         }

         return *this;
     }

     // copy from an std::vector.
     hidl_vec &operator=(const std::vector<T> &other) {
         if (mOwnsBuffer) {
             delete[] mBuffer;
         }
         copyFrom(other, other.size());
         return *this;
     }

     // cast to an std::vector.
     operator std::vector<T>() const {
         std::vector<T> v(mSize);
         for (size_t i = 0; i < mSize; ++i) {
             v[i] = mBuffer[i];
         }
         return v;
     }

     size_t size() const {
         return mSize;
     }

     T &operator[](size_t index) {
         return mBuffer[index];
     }

     const T &operator[](size_t index) const {
         return mBuffer[index];
     }

     void resize(size_t size) {
         if (size > UINT32_MAX) {
             logAlwaysFatal("hidl_vec can't hold more than 2^32 elements.");
         }
         T *newBuffer = new T[size];

         for (size_t i = 0; i < std::min(static_cast<uint32_t>(size), mSize); ++i) {
             newBuffer[i] = mBuffer[i];
         }

         if (mOwnsBuffer) {
             delete[] mBuffer;
         }
         mBuffer = newBuffer;

         mSize = static_cast<uint32_t>(size);
         mOwnsBuffer = true;
     }

     // offsetof(hidl_string, mBuffer) exposed since mBuffer is private.
     static const size_t kOffsetOfBuffer;

     // Define std interator interface for walking the array contents
     // TODO:  it might be nice to implement a full featured random access iterator...
     class iterator : public std::iterator<std::bidirectional_iterator_tag, T>
     {
     public:
         iterator(T* ptr) : mPtr(ptr) { }
         iterator operator++()    { iterator i = *this; mPtr++; return i; }
         iterator operator++(int) { mPtr++; return *this; }
         iterator operator--()    { iterator i = *this; mPtr--; return i; }
         iterator operator--(int) { mPtr--; return *this; }
         T& operator*()  { return *mPtr; }
         T* operator->() { return mPtr; }
         bool operator==(const iterator& rhs) const { return mPtr == rhs.mPtr; }
         bool operator!=(const iterator& rhs) const { return mPtr != rhs.mPtr; }
     private:
         T* mPtr;
     };
     iterator begin() { return data(); }
     iterator end() { return data()+mSize; }

 private:
     details::hidl_pointer<T> mBuffer;
     uint32_t mSize;
     bool mOwnsBuffer;

     // copy from an array-like object, assuming my resources are freed.
     template <typename Array>
     void copyFrom(const Array &data, size_t size) {
         mSize = size;
         mOwnsBuffer = true;
         if (mSize > 0) {
             mBuffer = new T[size];
             for (size_t i = 0; i < size; ++i) {
                 mBuffer[i] = data[i];
             }
         } else {
             mBuffer = NULL;
         }
     }
 };

 template <typename T>
 const size_t hidl_vec<T>::kOffsetOfBuffer = offsetof(hidl_vec<T>, mBuffer);

 ////////////////////////////////////////////////////////////////////////////////

 namespace details {

     template<size_t SIZE1, size_t... SIZES>
     struct product {
         static constexpr size_t value = SIZE1 * product<SIZES...>::value;
     };

     template<size_t SIZE1>
     struct product<SIZE1> {
         static constexpr size_t value = SIZE1;
     };

     template<typename T, size_t SIZE1, size_t... SIZES>
     struct accessor {
         explicit accessor(T *base)
             : mBase(base) {
         }

         accessor<T, SIZES...> operator[](size_t index) {
             return accessor<T, SIZES...>(
                     &mBase[index * product<SIZES...>::value]);
         }

     private:
         T *mBase;
     };

     template<typename T, size_t SIZE1>
     struct accessor<T, SIZE1> {
         explicit accessor(T *base)
             : mBase(base) {
         }

         T &operator[](size_t index) {
             return mBase[index];
         }

     private:
         T *mBase;
     };

     template<typename T, size_t SIZE1, size_t... SIZES>
     struct const_accessor {
         explicit const_accessor(const T *base)
             : mBase(base) {
         }

         const_accessor<T, SIZES...> operator[](size_t index) {
             return const_accessor<T, SIZES...>(
                     &mBase[index * product<SIZES...>::value]);
         }

     private:
         const T *mBase;
     };

     template<typename T, size_t SIZE1>
     struct const_accessor<T, SIZE1> {
         explicit const_accessor(const T *base)
             : mBase(base) {
         }

         const T &operator[](size_t index) const {
             return mBase[index];
         }

     private:
         const T *mBase;
     };

 }  // namespace details

 ////////////////////////////////////////////////////////////////////////////////

 template<typename T, size_t SIZE1, size_t... SIZES>
 struct hidl_array {
     hidl_array() = default;

     T *data() { return mBuffer; }
     const T *data() const { return mBuffer; }

     details::accessor<T, SIZES...> operator[](size_t index) {
         return details::accessor<T, SIZES...>(
                 &mBuffer[index * details::product<SIZES...>::value]);
     }

     details::const_accessor<T, SIZES...> operator[](size_t index) const {
         return details::const_accessor<T, SIZES...>(
                 &mBuffer[index * details::product<SIZES...>::value]);
     }

     using size_tuple_type = std::tuple<decltype(SIZE1), decltype(SIZES)...>;

     static constexpr size_tuple_type size() {
         return std::make_tuple(SIZE1, SIZES...);
     }

 private:
     T mBuffer[details::product<SIZE1, SIZES...>::value];
 };

 template<typename T, size_t SIZE1>
 struct hidl_array<T, SIZE1> {
     hidl_array() = default;
     hidl_array(const T *source) {
         memcpy(mBuffer, source, SIZE1 * sizeof(T));
     }

     T *data() { return mBuffer; }
     const T *data() const { return mBuffer; }

     T &operator[](size_t index) {
         return mBuffer[index];
     }

     const T &operator[](size_t index) const {
         return mBuffer[index];
     }

     static constexpr size_t size() { return SIZE1; }

 private:
     T mBuffer[SIZE1];
 };

 // ----------------------------------------------------------------------
 // Version functions
 struct hidl_version {
 public:
     constexpr hidl_version(uint16_t major, uint16_t minor) : mMajor(major), mMinor(minor) {}

     bool operator==(const hidl_version& other) const {
         return (mMajor == other.get_major() && mMinor == other.get_minor());
     }

     constexpr uint16_t get_major() const { return mMajor; }
     constexpr uint16_t get_minor() const { return mMinor; }

 private:
     uint16_t mMajor;
     uint16_t mMinor;
 };

 inline android::hardware::hidl_version make_hidl_version(uint16_t major, uint16_t minor) {
     return hidl_version(major,minor);
 }

 struct IBase : virtual public RefBase {
     virtual bool isRemote() const = 0;
     // HIDL reserved methods follow.
     virtual ::android::hardware::Return<void> interfaceChain(
             std::function<void(const hidl_vec<hidl_string>&)> _hidl_cb) = 0;
     // This method notifies the interface that one or more system properties have changed.
     // The default implementation calls report_sysprop_change() in libcutils, which in turn
     // calls a set of registered callbacks (eg to update trace tags).
     virtual ::android::hardware::Return<void> notifySyspropsChanged() = 0;
     // descriptor for HIDL reserved methods.
     static const char* descriptor;
 };

 #if defined(__LP64__)
 #define HAL_LIBRARY_PATH_SYSTEM "/system/lib64/hw/"
 #define HAL_LIBRARY_PATH_VENDOR "/vendor/lib64/hw/"
 #define HAL_LIBRARY_PATH_ODM "/odm/lib64/hw/"
 #else
 #define HAL_LIBRARY_PATH_SYSTEM "/system/lib/hw/"
 #define HAL_LIBRARY_PATH_VENDOR "/vendor/lib/hw/"
 #define HAL_LIBRARY_PATH_ODM "/odm/lib/hw/"
 #endif

 #define DECLARE_SERVICE_MANAGER_INTERACTIONS(INTERFACE)                                  \
     static ::android::sp<I##INTERFACE> getService(                                       \
             const std::string &serviceName, bool getStub=false);                         \
     ::android::status_t registerAsService(const std::string &serviceName);               \
     static bool registerForNotifications(                                                \
         const std::string &serviceName,                                                  \
         const ::android::sp<::android::hidl::manager::V1_0::IServiceNotification>        \
                   &notification);                                                        \

 // ----------------------------------------------------------------------
 // Class that provides Hidl instrumentation utilities.
 struct HidlInstrumentor {
     // Event that triggers the instrumentation. e.g. enter of an API call on
     // the server/client side, exit of an API call on the server/client side
     // etc.
     enum InstrumentationEvent {
         SERVER_API_ENTRY = 0,
         SERVER_API_EXIT,
         CLIENT_API_ENTRY,
         CLIENT_API_EXIT,
         SYNC_CALLBACK_ENTRY,
         SYNC_CALLBACK_EXIT,
         ASYNC_CALLBACK_ENTRY,
         ASYNC_CALLBACK_EXIT,
         PASSTHROUGH_ENTRY,
         PASSTHROUGH_EXIT,
     };

     // Signature of the instrumentation callback function.
     using InstrumentationCallback = std::function<void(
             const InstrumentationEvent event,
             const char *package,
             const char *version,
             const char *interface,
             const char *method,
             std::vector<void *> *args)>;

     explicit HidlInstrumentor(const std::string &prefix);
     virtual ~HidlInstrumentor();

  protected:
     // Function that lookup and dynamically loads the hidl instrumentation
     // libraries and registers the instrumentation callback functions.
     //
     // The instrumentation libraries should be stored under any of the following
     // directories: HAL_LIBRARY_PATH_SYSTEM, HAL_LIBRARY_PATH_VENDOR and
     // HAL_LIBRARY_PATH_ODM. The name of instrumentation libraries should
     // follow pattern: ^profilerPrefix(.*).profiler.so$
     //
     // Each instrumentation library is expected to implement the instrumentation
     // function called HIDL_INSTRUMENTATION_FUNCTION.
     //
     // A no-op for user build.
     void registerInstrumentationCallbacks(
             const std::string &profilerPrefix,
             std::vector<InstrumentationCallback> *instrumentationCallbacks);

     // Utility function to determine whether a give file is a instrumentation
     // library (i.e. the file name follow the expected pattern).
     bool isInstrumentationLib(
             const std::string &profilerPrefix,
             const dirent *file);
     // A list of registered instrumentation callbacks.
     std::vector<InstrumentationCallback> mInstrumentationCallbacks;
     // Flag whether to enable instrumentation.
     bool mEnableInstrumentation;
 };

 }  // namespace hardware
 }  // namespace android


 #endif  // ANDROID_HIDL_SUPPORT_H
	/*
	* Copyright (C) 2016 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.
	*/

	#ifndef ANDROID_HIDL_SUPPORT_H
	#define ANDROID_HIDL_SUPPORT_H

	#include <algorithm>
	#include <dirent.h>
	#include <dlfcn.h>
	#include <iterator>
	#include <cutils/native_handle.h>
	#include <cutils/properties.h>
	#include <functional>
	#include <hidl/HidlInternal.h>
	#include <hidl/Status.h>
	#include <map>
	#include <tuple>
	#include <utils/Errors.h>
	#include <utils/RefBase.h>
	#include <utils/StrongPointer.h>
	#include <vector>

	namespace android {
	namespace hardware {

	// hidl_handle wraps a pointer to a native_handle_t in a hidl_pointer,
	// so that it can safely be transferred between 32-bit and 64-bit processes.
	struct hidl_handle {
	hidl_handle() {
	mHandle = nullptr;
	}
	~hidl_handle() {
	}

	// copy constructors.
	hidl_handle(const native_handle_t *handle) {
	mHandle = handle;
	}

	hidl_handle(const hidl_handle &other) {
	mHandle = other.mHandle;
	}

	// move constructor.
	hidl_handle(hidl_handle &&other) {
	*this = std::move(other);
	}

	// assingment operators
	hidl_handle &operator=(const hidl_handle &other) {
	mHandle = other.mHandle;
	return *this;
	}

	hidl_handle &operator=(const native_handle_t *native_handle) {
	mHandle = native_handle;
	return *this;
	}

	hidl_handle &operator=(hidl_handle &&other) {
	mHandle = other.mHandle;
	other.mHandle = nullptr;
	return *this;
	}

	const native_handle_t* operator->() const {
	return mHandle;
	}
	// implicit conversion to const native_handle_t*
	operator const native_handle_t *() const {
	return mHandle;
	}
	// explicit conversion
	const native_handle_t *getNativeHandle() const {
	return mHandle;
	}
	private:
	details::hidl_pointer<const native_handle_t> mHandle;
	};

	struct hidl_string {
	hidl_string();
	~hidl_string();

	// copy constructor.
	hidl_string(const hidl_string &);
	// copy from a C-style string.
	hidl_string(const char *);
	// copy from an std::string.
	hidl_string(const std::string &);

	// move constructor.
	hidl_string(hidl_string &&);

	const char *c_str() const;
	size_t size() const;
	bool empty() const;

	// copy assignment operator.
	hidl_string &operator=(const hidl_string &);
	// copy from a C-style string.
	hidl_string &operator=(const char *s);
	// copy from an std::string.
	hidl_string &operator=(const std::string &);
	// move assignment operator.
	hidl_string &operator=(hidl_string &&other);
	// cast to std::string.
	operator std::string() const;
	// cast to C-style string. Caller is responsible
	// to maintain this hidl_string alive.
	operator const char *() const;

	void clear();

	// Reference an external char array. Ownership is _not_ transferred.
	// Caller is responsible for ensuring that underlying memory is valid
	// for the lifetime of this hidl_string.
	void setToExternal(const char *data, size_t size);

	// offsetof(hidl_string, mBuffer) exposed since mBuffer is private.
	static const size_t kOffsetOfBuffer;

	private:
	details::hidl_pointer<const char> mBuffer;
	uint32_t mSize; // NOT including the terminating '\0'.
	bool mOwnsBuffer; // if true then mBuffer is a mutable char *

	// copy from data with size. Assume that my memory is freed
	// (through clear(), for example)
	void copyFrom(const char *data, size_t size);
	// move from another hidl_string
	void moveFrom(hidl_string &&);
	};

	inline bool operator==(const hidl_string &hs1, const hidl_string &hs2) {
	return strcmp(hs1.c_str(), hs2.c_str()) == 0;
	}

	inline bool operator!=(const hidl_string &hs1, const hidl_string &hs2) {
	return !(hs1 == hs2);
	}

	inline bool operator==(const hidl_string &hs, const char *s) {
	return strcmp(hs.c_str(), s) == 0;
	}

	inline bool operator!=(const hidl_string &hs, const char *s) {
	return !(hs == s);
	}

	inline bool operator==(const char *s, const hidl_string &hs) {
	return strcmp(hs.c_str(), s) == 0;
	}

	inline bool operator!=(const char *s, const hidl_string &hs) {
	return !(s == hs);
	}

	////////////////////////////////////////////////////////////////////////////////

	template<typename T>
	struct hidl_vec : private details::hidl_log_base {
	hidl_vec()
	: mBuffer(NULL),
	mSize(0),
	mOwnsBuffer(true) {
	}

	hidl_vec(const hidl_vec<T> &other) : hidl_vec() {
	*this = other;
	}

	hidl_vec(hidl_vec<T> &&other)
	: mOwnsBuffer(false) {
	*this = std::move(other);
	}

	hidl_vec(const std::initializer_list<T> list)
	: mSize(list.size()),
	mOwnsBuffer(true) {
	mBuffer = new T[mSize];

	size_t idx = 0;
	for (auto it = list.begin(); it != list.end(); ++it) {
	mBuffer[idx++] = *it;
	}
	}

	hidl_vec(const std::vector<T> &other) : hidl_vec() {
	*this = other;
	}

	~hidl_vec() {
	if (mOwnsBuffer) {
	delete[] mBuffer;
	}
	mBuffer = NULL;
	}

	// Reference an existing array, optionally taking ownership. It is the
	// caller's responsibility to ensure that the underlying memory stays
	// valid for the lifetime of this hidl_vec.
	void setToExternal(T *data, size_t size, bool shouldOwn = false) {
	if (mOwnsBuffer) {
	delete [] mBuffer;
	}
	mBuffer = data;
	if (size > UINT32_MAX) {
	logAlwaysFatal("external vector size exceeds 2^32 elements.");
	}
	mSize = static_cast<uint32_t>(size);
	mOwnsBuffer = shouldOwn;
	}

	T *data() {
	return mBuffer;
	}

	const T *data() const {
	return mBuffer;
	}

	T *releaseData() {
	if (!mOwnsBuffer && mSize > 0) {
	resize(mSize);
	}
	mOwnsBuffer = false;
	return mBuffer;
	}

	hidl_vec &operator=(hidl_vec &&other) {
	if (mOwnsBuffer) {
	delete[] mBuffer;
	}
	mBuffer = other.mBuffer;
	mSize = other.mSize;
	mOwnsBuffer = other.mOwnsBuffer;
	other.mOwnsBuffer = false;
	return *this;
	}

	hidl_vec &operator=(const hidl_vec &other) {
	if (this != &other) {
	if (mOwnsBuffer) {
	delete[] mBuffer;
	}
	copyFrom(other, other.mSize);
	}

	return *this;
	}

	// copy from an std::vector.
	hidl_vec &operator=(const std::vector<T> &other) {
	if (mOwnsBuffer) {
	delete[] mBuffer;
	}
	copyFrom(other, other.size());
	return *this;
	}

	// cast to an std::vector.
	operator std::vector<T>() const {
	std::vector<T> v(mSize);
	for (size_t i = 0; i < mSize; ++i) {
	v[i] = mBuffer[i];
	}
	return v;
	}

	size_t size() const {
	return mSize;
	}

	T &operator[](size_t index) {
	return mBuffer[index];
	}

	const T &operator[](size_t index) const {
	return mBuffer[index];
	}

	void resize(size_t size) {
	if (size > UINT32_MAX) {
	logAlwaysFatal("hidl_vec can't hold more than 2^32 elements.");
	}
	T *newBuffer = new T[size];

	for (size_t i = 0; i < std::min(static_cast<uint32_t>(size), mSize); ++i) {
	newBuffer[i] = mBuffer[i];
	}

	if (mOwnsBuffer) {
	delete[] mBuffer;
	}
	mBuffer = newBuffer;

	mSize = static_cast<uint32_t>(size);
	mOwnsBuffer = true;
	}

	// offsetof(hidl_string, mBuffer) exposed since mBuffer is private.
	static const size_t kOffsetOfBuffer;

	// Define std interator interface for walking the array contents
	// TODO: it might be nice to implement a full featured random access iterator...
	class iterator : public std::iterator<std::bidirectional_iterator_tag, T>
	{
	public:
	iterator(T* ptr) : mPtr(ptr) { }
	iterator operator++() { iterator i = *this; mPtr++; return i; }
	iterator operator++(int) { mPtr++; return *this; }
	iterator operator--() { iterator i = *this; mPtr--; return i; }
	iterator operator--(int) { mPtr--; return *this; }
	T& operator() { return mPtr; }
	T* operator->() { return mPtr; }
	bool operator==(const iterator& rhs) const { return mPtr == rhs.mPtr; }
	bool operator!=(const iterator& rhs) const { return mPtr != rhs.mPtr; }
	private:
	T* mPtr;
	};
	iterator begin() { return data(); }
	iterator end() { return data()+mSize; }

	private:
	details::hidl_pointer<T> mBuffer;
	uint32_t mSize;
	bool mOwnsBuffer;

	// copy from an array-like object, assuming my resources are freed.
	template <typename Array>
	void copyFrom(const Array &data, size_t size) {
	mSize = size;
	mOwnsBuffer = true;
	if (mSize > 0) {
	mBuffer = new T[size];
	for (size_t i = 0; i < size; ++i) {
	mBuffer[i] = data[i];
	}
	} else {
	mBuffer = NULL;
	}
	}
	};

	template <typename T>
	const size_t hidl_vec<T>::kOffsetOfBuffer = offsetof(hidl_vec<T>, mBuffer);

	////////////////////////////////////////////////////////////////////////////////

	namespace details {

	template<size_t SIZE1, size_t... SIZES>
	struct product {
	static constexpr size_t value = SIZE1 * product<SIZES...>::value;
	};

	template<size_t SIZE1>
	struct product<SIZE1> {
	static constexpr size_t value = SIZE1;
	};

	template<typename T, size_t SIZE1, size_t... SIZES>
	struct accessor {
	explicit accessor(T *base)
	: mBase(base) {
	}

	accessor<T, SIZES...> operator[](size_t index) {
	return accessor<T, SIZES...>(
	&mBase[index * product<SIZES...>::value]);
	}

	private:
	T *mBase;
	};

	template<typename T, size_t SIZE1>
	struct accessor<T, SIZE1> {
	explicit accessor(T *base)
	: mBase(base) {
	}

	T &operator[](size_t index) {
	return mBase[index];
	}

	private:
	T *mBase;
	};

	template<typename T, size_t SIZE1, size_t... SIZES>
	struct const_accessor {
	explicit const_accessor(const T *base)
	: mBase(base) {
	}

	const_accessor<T, SIZES...> operator[](size_t index) {
	return const_accessor<T, SIZES...>(
	&mBase[index * product<SIZES...>::value]);
	}

	private:
	const T *mBase;
	};

	template<typename T, size_t SIZE1>
	struct const_accessor<T, SIZE1> {
	explicit const_accessor(const T *base)
	: mBase(base) {
	}

	const T &operator[](size_t index) const {
	return mBase[index];
	}

	private:
	const T *mBase;
	};

	} // namespace details

	////////////////////////////////////////////////////////////////////////////////

	template<typename T, size_t SIZE1, size_t... SIZES>
	struct hidl_array {
	hidl_array() = default;

	T *data() { return mBuffer; }
	const T *data() const { return mBuffer; }

	details::accessor<T, SIZES...> operator[](size_t index) {
	return details::accessor<T, SIZES...>(
	&mBuffer[index * details::product<SIZES...>::value]);
	}

	details::const_accessor<T, SIZES...> operator[](size_t index) const {
	return details::const_accessor<T, SIZES...>(
	&mBuffer[index * details::product<SIZES...>::value]);
	}

	using size_tuple_type = std::tuple<decltype(SIZE1), decltype(SIZES)...>;

	static constexpr size_tuple_type size() {
	return std::make_tuple(SIZE1, SIZES...);
	}

	private:
	T mBuffer[details::product<SIZE1, SIZES...>::value];
	};

	template<typename T, size_t SIZE1>
	struct hidl_array<T, SIZE1> {
	hidl_array() = default;
	hidl_array(const T *source) {
	memcpy(mBuffer, source, SIZE1 * sizeof(T));
	}

	T *data() { return mBuffer; }
	const T *data() const { return mBuffer; }

	T &operator[](size_t index) {
	return mBuffer[index];
	}

	const T &operator[](size_t index) const {
	return mBuffer[index];
	}

	static constexpr size_t size() { return SIZE1; }

	private:
	T mBuffer[SIZE1];
	};

	// ----------------------------------------------------------------------
	// Version functions
	struct hidl_version {
	public:
	constexpr hidl_version(uint16_t major, uint16_t minor) : mMajor(major), mMinor(minor) {}

	bool operator==(const hidl_version& other) const {
	return (mMajor == other.get_major() && mMinor == other.get_minor());
	}

	constexpr uint16_t get_major() const { return mMajor; }
	constexpr uint16_t get_minor() const { return mMinor; }

	private:
	uint16_t mMajor;
	uint16_t mMinor;
	};

	inline android::hardware::hidl_version make_hidl_version(uint16_t major, uint16_t minor) {
	return hidl_version(major,minor);
	}

	struct IBase : virtual public RefBase {
	virtual bool isRemote() const = 0;
	// HIDL reserved methods follow.
	virtual ::android::hardware::Return<void> interfaceChain(
	std::function<void(const hidl_vec<hidl_string>&)> _hidl_cb) = 0;
	// This method notifies the interface that one or more system properties have changed.
	// The default implementation calls report_sysprop_change() in libcutils, which in turn
	// calls a set of registered callbacks (eg to update trace tags).
	virtual ::android::hardware::Return<void> notifySyspropsChanged() = 0;
	// descriptor for HIDL reserved methods.
	static const char* descriptor;
	};

	#if defined(__LP64__)
	#define HAL_LIBRARY_PATH_SYSTEM "/system/lib64/hw/"
	#define HAL_LIBRARY_PATH_VENDOR "/vendor/lib64/hw/"
	#define HAL_LIBRARY_PATH_ODM "/odm/lib64/hw/"
	#else
	#define HAL_LIBRARY_PATH_SYSTEM "/system/lib/hw/"
	#define HAL_LIBRARY_PATH_VENDOR "/vendor/lib/hw/"
	#define HAL_LIBRARY_PATH_ODM "/odm/lib/hw/"
	#endif

	#define DECLARE_SERVICE_MANAGER_INTERACTIONS(INTERFACE) \
	static ::android::sp<I##INTERFACE> getService( \
	const std::string &serviceName, bool getStub=false); \
	::android::status_t registerAsService(const std::string &serviceName); \
	static bool registerForNotifications( \
	const std::string &serviceName, \
	const ::android::sp<::android::hidl::manager::V1_0::IServiceNotification> \
	&notification); \

	// ----------------------------------------------------------------------
	// Class that provides Hidl instrumentation utilities.
	struct HidlInstrumentor {
	// Event that triggers the instrumentation. e.g. enter of an API call on
	// the server/client side, exit of an API call on the server/client side
	// etc.
	enum InstrumentationEvent {
	SERVER_API_ENTRY = 0,
	SERVER_API_EXIT,
	CLIENT_API_ENTRY,
	CLIENT_API_EXIT,
	SYNC_CALLBACK_ENTRY,
	SYNC_CALLBACK_EXIT,
	ASYNC_CALLBACK_ENTRY,
	ASYNC_CALLBACK_EXIT,
	PASSTHROUGH_ENTRY,
	PASSTHROUGH_EXIT,
	};

	// Signature of the instrumentation callback function.
	using InstrumentationCallback = std::function<void(
	const InstrumentationEvent event,
	const char *package,
	const char *version,
	const char *interface,
	const char *method,
	std::vector<void > args)>;

	explicit HidlInstrumentor(const std::string &prefix);
	virtual ~HidlInstrumentor();

	protected:
	// Function that lookup and dynamically loads the hidl instrumentation
	// libraries and registers the instrumentation callback functions.
	//
	// The instrumentation libraries should be stored under any of the following
	// directories: HAL_LIBRARY_PATH_SYSTEM, HAL_LIBRARY_PATH_VENDOR and
	// HAL_LIBRARY_PATH_ODM. The name of instrumentation libraries should
	// follow pattern: ^profilerPrefix(.*).profiler.so$
	//
	// Each instrumentation library is expected to implement the instrumentation
	// function called HIDL_INSTRUMENTATION_FUNCTION.
	//
	// A no-op for user build.
	void registerInstrumentationCallbacks(
	const std::string &profilerPrefix,
	std::vector<InstrumentationCallback> *instrumentationCallbacks);

	// Utility function to determine whether a give file is a instrumentation
	// library (i.e. the file name follow the expected pattern).
	bool isInstrumentationLib(
	const std::string &profilerPrefix,
	const dirent *file);
	// A list of registered instrumentation callbacks.
	std::vector<InstrumentationCallback> mInstrumentationCallbacks;
	// Flag whether to enable instrumentation.
	bool mEnableInstrumentation;
	};

	} // namespace hardware
	} // namespace android


	#endif // ANDROID_HIDL_SUPPORT_H